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<body class="book">
<div id="header">
<h1>The OpenCL Specification</h1>
<span id="author">Khronos OpenCL Working Group</span><br>
<span id="revnumber">version v2.2-3</span>
<div id="toc">
<div id="toctitle">Table of Contents</div>
<noscript><p><b>JavaScript must be enabled in your browser to display the table of contents.</b></p></noscript>
</div>
</div>
<div id="content">
<div id="preamble">
<div class="sectionbody">
<div class="paragraph"><p>Copyright 2008-2017 The Khronos Group.</p></div>
<div class="paragraph"><p>This specification is protected by copyright laws and contains material proprietary
to the Khronos Group, Inc. Except as described by these terms, it or any components
may not be reproduced, republished, distributed, transmitted, displayed, broadcast
or otherwise exploited in any manner without the express prior written permission
of Khronos Group.</p></div>
<div class="paragraph"><p>Khronos Group grants a conditional copyright license to use and reproduce the
unmodified specification for any purpose, without fee or royalty, EXCEPT no licenses
to any patent, trademark or other intellectual property rights are granted under
these terms. Parties desiring to implement the specification and make use of
Khronos trademarks in relation to that implementation, and receive reciprocal patent
license protection under the Khronos IP Policy must become Adopters and confirm the
implementation as conformant under the process defined by Khronos for this
specification; see <a href="https://www.khronos.org/adopters">https://www.khronos.org/adopters</a>.</p></div>
<div class="paragraph"><p>Khronos Group makes no, and expressly disclaims any, representations or warranties,
express or implied, regarding this specification, including, without limitation:
merchantability, fitness for a particular purpose, non-infringement of any
intellectual property, correctness, accuracy, completeness, timeliness, and
reliability. Under no circumstances will the Khronos Group, or any of its Promoters,
Contributors or Members, or their respective partners, officers, directors,
employees, agents or representatives be liable for any damages, whether direct,
indirect, special or consequential damages for lost revenues, lost profits, or
otherwise, arising from or in connection with these materials.</p></div>
<div class="paragraph"><p>Vulkan is a registered trademark and Khronos, OpenXR, SPIR, SPIR-V, SYCL, WebGL,
WebCL, OpenVX, OpenVG, EGL, COLLADA, glTF, NNEF, OpenKODE, OpenKCAM, StreamInput,
OpenWF, OpenSL ES, OpenMAX, OpenMAX AL, OpenMAX IL, OpenMAX DL, OpenML and DevU are
trademarks of the Khronos Group Inc. ASTC is a trademark of ARM Holdings PLC,
OpenCL is a trademark of Apple Inc. and OpenGL and OpenML are registered trademarks
and the OpenGL ES and OpenGL SC logos are trademarks of Silicon Graphics
International used under license by Khronos. All other product names, trademarks,
and/or company names are used solely for identification and belong to their
respective owners.</p></div>
<div style="page-break-after:always"></div>
<div class="paragraph"><p><strong>Acknowledgements</strong></p></div>
<div class="paragraph"><p>The OpenCL specification is the result of the contributions of many
people, representing a cross section of the desktop, hand-held, and
embedded computer industry. Following is a partial list of the
contributors, including the company that they represented at the time of
their contribution:</p></div>
<div class="paragraph"><p>Chuck Rose, Adobe<br>
Eric Berdahl, Adobe<br>
Shivani Gupta, Adobe<br>
Bill Licea Kane, AMD<br>
Ed Buckingham, AMD<br>
Jan Civlin, AMD<br>
Laurent Morichetti, AMD<br>
Mark Fowler, AMD<br>
Marty Johnson, AMD<br>
Michael Mantor, AMD<br>
Norm Rubin, AMD<br>
Ofer Rosenberg, AMD<br>
Brian Sumner, AMD<br>
Victor Odintsov, AMD<br>
Aaftab Munshi, Apple<br>
Abe Stephens, Apple<br>
Alexandre Namaan, Apple<br>
Anna Tikhonova, Apple<br>
Chendi Zhang, Apple<br>
Eric Bainville, Apple<br>
David Hayward, Apple<br>
Giridhar Murthy, Apple<br>
Ian Ollmann, Apple<br>
Inam Rahman, Apple<br>
James Shearer, Apple<br>
MonPing Wang, Apple<br>
Tanya Lattner, Apple<br>
Mikael Bourges-Sevenier, Aptina<br>
Anton Lokhmotov, ARM<br>
Dave Shreiner, ARM<br>
Hedley Francis, ARM<br>
Robert Elliott, ARM<br>
Scott Moyers, ARM<br>
Tom Olson, ARM<br>
Anastasia Stulova, ARM<br>
Christopher Thompson-Walsh, Broadcom<br>
Holger Waechtler, Broadcom<br>
Norman Rink, Broadcom<br>
Andrew Richards, Codeplay<br>
Maria Rovatsou, Codeplay<br>
Alistair Donaldson, Codeplay<br>
Alastair Murray, Codeplay<br>
Stephen Frye, Electronic Arts<br>
Eric Schenk, Electronic Arts<br>
Daniel Laroche, Freescale<br>
David Neto, Google<br>
Robin Grosman, Huawei<br>
Craig Davies, Huawei<br>
Brian Horton, IBM<br>
Brian Watt, IBM<br>
Gordon Fossum, IBM<br>
Greg Bellows, IBM<br>
Joaquin Madruga, IBM<br>
Mark Nutter, IBM<br>
Mike Perks, IBM<br>
Sean Wagner, IBM<br>
Jon Parr, Imagination Technologies<br>
Robert Quill, Imagination Technologies<br>
James McCarthy, Imagination Technologie<br>
Aaron Kunze, Intel<br>
Aaron Lefohn, Intel<br>
Adam Lake, Intel<br>
Alexey Bader, Intel<br>
Allen Hux, Intel<br>
Andrew Brownsword, Intel<br>
Andrew Lauritzen, Intel<br>
Bartosz Sochacki, Intel<br>
Ben Ashbaugh, Intel<br>
Brian Lewis, Intel<br>
Geoff Berry, Intel<br>
Hong Jiang, Intel<br>
Jayanth Rao, Intel<br>
Josh Fryman, Intel<br>
Larry Seiler, Intel<br>
Mike MacPherson, Intel<br>
Murali Sundaresan, Intel<br>
Paul Lalonde, Intel<br>
Raun Krisch, Intel<br>
Stephen Junkins, Intel<br>
Tim Foley, Intel<br>
Timothy Mattson, Intel<br>
Yariv Aridor, Intel<br>
Michael Kinsner, Intel<br>
Kevin Stevens, Intel<br>
Jon Leech, Khronos<br>
Benjamin Bergen, Los Alamos National Laboratory<br>
Roy Ju, Mediatek<br>
Bor-Sung Liang, Mediatek<br>
Rahul Agarwal, Mediatek<br>
Michal Witaszek, Mobica<br>
JenqKuen Lee, NTHU<br>
Amit Rao, NVIDIA<br>
Ashish Srivastava, NVIDIA<br>
Bastiaan Aarts, NVIDIA<br>
Chris Cameron, NVIDIA<br>
Christopher Lamb, NVIDIA<br>
Dibyapran Sanyal, NVIDIA<br>
Guatam Chakrabarti, NVIDIA<br>
Ian Buck, NVIDIA<br>
Jaydeep Marathe, NVIDIA<br>
Jian-Zhong Wang, NVIDIA<br>
Karthik Raghavan Ravi, NVIDIA<br>
Kedar Patil, NVIDIA<br>
Manjunath Kudlur, NVIDIA<br>
Mark Harris, NVIDIA<br>
Michael Gold, NVIDIA<br>
Neil Trevett, NVIDIA<br>
Richard Johnson, NVIDIA<br>
Sean Lee, NVIDIA<br>
Tushar Kashalikar, NVIDIA<br>
Vinod Grover, NVIDIA<br>
Xiangyun Kong, NVIDIA<br>
Yogesh Kini, NVIDIA<br>
Yuan Lin, NVIDIA<br>
Mayuresh Pise, NVIDIA<br>
Allan Tzeng, QUALCOMM<br>
Alex Bourd, QUALCOMM<br>
Anirudh Acharya, QUALCOMM<br>
Andrew Gruber, QUALCOMM<br>
Andrzej Mamona, QUALCOMM<br>
Benedict Gaster, QUALCOMM<br>
Bill Torzewski, QUALCOMM<br>
Bob Rychlik, QUALCOMM<br>
Chihong Zhang, QUALCOMM<br>
Chris Mei, QUALCOMM<br>
Colin Sharp, QUALCOMM<br>
David Garcia, QUALCOMM<br>
David Ligon, QUALCOMM<br>
Jay Yun, QUALCOMM<br>
Lee Howes, QUALCOMM<br>
Richard Ruigrok, QUALCOMM<br>
Robert J. Simpson, QUALCOMM<br>
Sumesh Udayakumaran, QUALCOMM<br>
Vineet Goel, QUALCOMM<br>
Lihan Bin, QUALCOMM<br>
Vlad Shimanskiy, QUALCOMM<br>
Jian Liu, QUALCOMM<br>
Tasneem Brutch, Samsung<br>
Yoonseo Choi, Samsung<br>
Dennis Adams, Sony<br>
Pr-Anders Aronsson, Sony<br>
Jim Rasmusson, Sony<br>
Thierry Lepley, STMicroelectronics<br>
Anton Gorenko, StreamComputing<br>
Jakub Szuppe, StreamComputing<br>
Vincent Hindriksen, StreamComputing<br>
Alan Ward, Texas Instruments<br>
Yuan Zhao, Texas Instruments<br>
Pete Curry, Texas Instruments<br>
Simon McIntosh-Smith, University of Bristol<br>
James Price, University of Bristol<br>
Paul Preney, University of Windsor<br>
Shane Peelar, University of Windsor<br>
Brian Hutsell, Vivante<br>
Mike Cai, Vivante<br>
Sumeet Kumar, Vivante<br>
Wei-Lun Kao, Vivante<br>
Xing Wang, Vivante<br>
Jeff Fifield, Xilinx<br>
Hem C. Neema, Xilinx<br>
Henry Styles, Xilinx<br>
Ralph Wittig, Xilinx<br>
Ronan Keryell, Xilinx<br>
AJ Guillon, YetiWare Inc<br></p></div>
<div style="page-break-after:always"></div>
</div>
</div>
<div class="sect1">
<h2 id="_introduction">1. Introduction</h2>
<div class="sectionbody">
<div class="paragraph"><p>Modern processor architectures have embraced parallelism as an important
pathway to increased performance. Facing technical challenges with
higher clock speeds in a fixed power envelope, Central Processing Units
(CPUs) now improve performance by adding multiple cores. Graphics
Processing Units (GPUs) have also evolved from fixed function rendering
devices into programmable parallel processors. As todays computer
systems often include highly parallel CPUs, GPUs and other types of
processors, it is important to enable software developers to take full
advantage of these heterogeneous processing platforms.
<br>
<br>
Creating applications for heterogeneous parallel processing platforms is
challenging as traditional programming approaches for multi-core CPUs
and GPUs are very different. CPU-based parallel programming models are
typically based on standards but usually assume a shared address space
and do not encompass vector operations. General purpose GPU
programming models address complex memory hierarchies and vector
operations but are traditionally platform-, vendor- or
hardware-specific. These limitations make it difficult for a developer
to access the compute power of heterogeneous CPUs, GPUs and other types
of processors from a single, multi-platform source code base. More than
ever, there is a need to enable software developers to effectively take
full advantage of heterogeneous processing platforms from high
performance compute servers, through desktop computer systems to
handheld devices - that include a diverse mix of parallel CPUs, GPUs and
other processors such as DSPs and the Cell/B.E. processor.
<br>
<br>
<strong>OpenCL</strong> (Open Computing Language) is an open royalty-free standard for
general purpose parallel programming across CPUs, GPUs and other
processors, giving software developers portable and efficient access to
the power of these heterogeneous processing platforms.
<br>
<br>
OpenCL supports a wide range of applications, ranging from embedded and
consumer software to HPC solutions, through a low-level,
high-performance, portable abstraction. By creating an efficient,
close-to-the-metal programming interface, OpenCL will form the
foundation layer of a parallel computing ecosystem of
platform-independent tools, middleware and applications. OpenCL is
particularly suited to play an increasingly significant role in emerging
interactive graphics applications that combine general parallel compute
algorithms with graphics rendering pipelines.
<br>
<br>
OpenCL consists of an API for coordinating parallel computation across
heterogeneous processors; and a cross-platform intermediate language
with a well-specified computation environment. The OpenCL standard:</p></div>
<div class="ulist"><ul>
<li>
<p>
Supports both data- and
task-based parallel programming models
</p>
</li>
<li>
<p>
Utilizes a portable and
self-contained intermediate representation with support for parallel
execution
</p>
</li>
<li>
<p>
Defines consistent
numerical requirements based on IEEE 754
</p>
</li>
<li>
<p>
Defines a configuration
profile for handheld and embedded devices
</p>
</li>
<li>
<p>
Efficiently interoperates
with OpenGL, OpenGL ES and other graphics APIs
</p>
</li>
</ul></div>
<div class="paragraph"><p>This document begins with an overview of basic concepts and the
architecture of OpenCL, followed by a detailed description of its
execution model, memory model and synchronization support. It then
discusses the OpenCL__platform and runtime API. Some examples are given
that describe sample compute use-cases and how they would be written in
OpenCL. The specification is divided into a core specification that any
OpenCL compliant implementation must support; a handheld/embedded
profile which relaxes the OpenCL compliance requirements for handheld
and embedded devices; and a set of optional extensions that are likely
to move into the core specification in later revisions of the OpenCL
specification.</p></div>
</div>
</div>
<div class="sect1">
<h2 id="_glossary">2. Glossary</h2>
<div class="sectionbody">
<div class="paragraph"><p><strong>Application</strong>: The combination of the program running on the host and
OpenCL devices.
<br>
<br>
<strong>Acquire semantics</strong>: One of the memory order semantics defined for
synchronization operations.  Acquire semantics apply to atomic
operations that load from memory.  Given two units of execution, <strong>A</strong> and
<strong>B</strong>, acting on a shared atomic object <strong>M</strong>, if <strong>A</strong> uses an atomic load of
<strong>M</strong> with acquire semantics to synchronize-with an atomic store to <strong>M</strong> by
<strong>B</strong> that used release semantics, then <strong>A</strong>'s atomic load will occur before
any subsequent operations by <strong>A</strong>.  Note that the memory orders
<em>release</em>, <em>sequentially consistent</em>, and <em>acquire_release</em> all include
<em>release semantics</em> and effectively pair with a load using acquire
semantics.
<br>
<br>
<strong>Acquire release semantics</strong>: A memory order semantics for
synchronization operations (such as atomic operations) that has the
properties of both acquire and release memory orders. It is used with
read-modify-write operations.
<br>
<br>
<strong>Atomic operations</strong>: Operations that at any point, and from any
perspective, have either occurred completely, or not at all. Memory
orders associated with atomic operations may constrain the visibility of
loads and stores with respect to the atomic operations (see <em>relaxed
semantics</em>, <em>acquire semantics</em>, <em>release semantics</em> or <em>acquire release
semantics</em>).
<br>
<br>
<strong>Blocking and Non-Blocking Enqueue API calls</strong>: A <em>non-blocking enqueue
API call</em> places a <em>command</em> on a <em>command-queue</em> and returns
immediately to the host. The <em>blocking-mode enqueue API calls</em> do not
return to the host until the command has completed.
<br>
<br>
<strong>Barrier</strong>: There are three types of <em>barriers</em> a command-queue barrier,
a work-group barrier and a sub-group barrier.</p></div>
<div class="ulist"><ul>
<li>
<p>
The OpenCL API provides a
function to enqueue a <em>command-queue</em> <em>barrier</em> command. This <em>barrier</em>
command ensures that all previously enqueued commands to a command-queue
have finished execution before any following <em>commands</em> enqueued in the
<em>command-queue</em> can begin execution.
</p>
</li>
<li>
<p>
The OpenCL kernel
execution model provides built-in <em>work-group barrier</em> functionality.
This <em>barrier</em> built-in function can be used by a <em>kernel</em> executing on
a <em>device</em> to perform synchronization between <em>work-items</em> in a
<em>work-group</em> executing the <em>kernel</em>. All the <em>work-items</em> of a
<em>work-group</em> must execute the <em>barrier</em> construct before any are allowed
to continue execution beyond the <em>barrier</em>.
</p>
</li>
<li>
<p>
The OpenCL kernel
execution model provides built-in <em>sub-group barrier</em> functionality.
This <em>barrier</em> built-in function can be used by a <em>kernel</em> executing on
a <em>device</em> to perform synchronization between <em>work-items</em> in a
<em>sub-group</em> executing the <em>kernel</em>. All the <em>work-items</em> of a
<em>sub-group</em> must execute the <em>barrier</em> construct before any are allowed
to continue execution beyond the <em>barrier</em>.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>Buffer Object</strong>: A memory object that stores a linear collection of
bytes. Buffer objects are accessible using a pointer in a <em>kernel</em>
executing on a <em>device</em>. Buffer objects can be manipulated by the host
using OpenCL API calls. A <em>buffer object</em> encapsulates the following
information:</p></div>
<div class="ulist"><ul>
<li>
<p>
Size in bytes.
</p>
</li>
<li>
<p>
Properties that describe
usage information and which region to allocate from.
</p>
</li>
<li>
<p>
Buffer data.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>Built-in Kernel</strong>: A <em>built-in kernel</em> is a <em>kernel</em> that is executed on
an OpenCL <em>device</em> or <em>custom device</em> by fixed-function hardware or in
firmware. <em>Applications</em> can query the <em>built-in kernels</em> supported by
a <em>device</em> or <em>custom device</em>. A <em>program object</em> can only contain
<em>kernels</em> written in OpenCL C or <em>built-in kernels</em> but not both. See
also <em>Kernel</em> and <em>Program</em>.
<br>
<br>
<strong>Child kernel</strong>: see <em>device-side enqueue.</em>
<br>
<br>
<strong>Command</strong>: The OpenCL operations that are submitted to a <em>command-queue</em>
for execution. For example, OpenCL commands issue kernels for execution
on a compute device, manipulate memory objects, etc.
<br>
<br>
<strong>Command-queue</strong>: An object that holds <em>commands</em> that will be executed on
a specific <em>device</em>. The <em>command-queue</em> is created on a specific
<em>device</em> in a <em>context</em>. <em>Commands</em> to a <em>command-queue</em> are queued
in-order but may be executed in-order or out-of-order. <em>Refer to
In-order Execution_and_Out-of-order Execution</em>.
<br>
<br>
<strong>Command-queue Barrier</strong>. See <em>Barrier</em>.
<br>
<br>
<strong>Command synchronization</strong>: Constraints on the order that commands are
launched for execution on a device defined in terms of the
synchronization points that occur between commands in host
command-queues and between commands in device-side command-queues. See
<em>synchronization points</em>.
<br>
<br>
<strong>Complete</strong>: The final state in the six state model for the execution of
a command. The transition into this state occurs is signaled through
event objects or callback functions associated with a command.
<br>
<br>
<strong>Compute Device Memory</strong>: This refers to one or more memories attached
to the compute device.
<br>
<br>
<strong>Compute Unit</strong>: An OpenCL <em>device</em> has one or more <em>compute units</em>. A
<em>work-group</em> executes on a single <em>compute unit</em>. A <em>compute unit</em> is
composed of one or more <em>processing elements</em> and <em>local memory</em>. A
<em>compute unit</em> may also include dedicated texture filter units that can
be accessed by its processing elements.
<br>
<br>
<strong>Concurrency</strong>: A property of a system in which a set of tasks in a system
can remain active and make progress at the same time. To utilize
concurrent execution when running a program, a programmer must identify
the concurrency in their problem, expose it within the source code, and
then exploit it using a notation that supports concurrency.
<br>
<br>
<strong>Constant Memory</strong>: A region of <em>global memory</em> that remains constant
during the execution of a <em>kernel</em>. The <em>host</em> allocates and
initializes memory objects placed into <em>constant memory</em>.</p></div>
<div class="paragraph"><p><strong>Context</strong>: The environment within which the kernels execute and the
domain in which synchronization and memory management is defined. The
<em>context</em> includes a set of <em>devices</em>, the memory accessible to those
<em>devices</em>, the corresponding memory properties and one or more
<em>command-queues</em> used to schedule execution of a <em>kernel(s)</em> or
operations on <em>memory objects</em>.
<br>
<br>
<strong>Control flow</strong>: The flow of instructions executed by a work-item.
Multiple logically related work items may or may not execute the same
control flow. The control flow is said to be <em>converged</em> if all the
work-items in the set execution the same stream of instructions. In a
<em>diverged</em> control flow, the work-items in the set execute different
instructions. At a later point, if a diverged control flow becomes
converged, it is said to be a re-converged control flow.
<br>
<br>
<strong>Converged control flow</strong>: see <strong>control flow</strong>.
<br>
<br>
<strong>Custom Device</strong>: An OpenCL <em>device</em> that fully implements the OpenCL
Runtime but does not support <em>programs</em> written in OpenCL C.  A custom
device may be specialized non-programmable hardware that is very power
efficient and performant for directed tasks or hardware with limited
programmable capabilities such as specialized DSPs. Custom devices are
not OpenCL conformant. Custom devices may support an online compiler.  
Programs for custom devices can be created using the OpenCL runtime APIs
that allow OpenCL programs to be created from source (if an online
compiler is supported) and/or binary, or from <em>built-in
kernels_supported by the _device</em>.  See also <em>Device</em>.
<br>
<br>
<strong>Data Parallel Programming Model</strong>: Traditionally, this term refers to a
programming model where concurrency is expressed as instructions from a
single program applied to multiple elements within a set of data
structures.  The term has been generalized in OpenCL to refer to a model
wherein a set of  instructions from a single program are applied
concurrently to each point within an abstract domain of indices.
<br>
<br>
<strong>Data race</strong>: The execution of a program contains a data race if it
contains two actions in different work items or host threads where (1)
one action modifies a memory location and the other action reads or
modifies the same memory location, and (2) at least one of these actions
is not atomic, or the corresponding memory scopes are not inclusive, and
(3) the actions are global actions unordered by the
global-happens-before relation or are local actions unordered by the
local-happens before relation.
<br>
<br>
<strong>Deprecation</strong>: existing features are marked as deprecated if their usage is not recommended as that feature is being de-emphasized, superseded and may be removed from a future version of the specification.[BA2] 
<br>
<br>
<strong>Device</strong>: A <em>device</em> is a collection of <em>compute units</em>. A
<em>command-queue</em> is used to queue <em>commands</em> to a <em>device</em>. Examples of
<em>commands</em> include executing <em>kernels</em>, or reading and writing <em>memory
objects</em>. OpenCL devices typically correspond to a GPU, a multi-core
CPU, and other processors such as DSPs and the Cell/B.E. processor.
<br>
<br>
<strong>Device-side enqueue</strong>: A mechanism whereby a kernel-instance is enqueued
by a kernel-instance running on a device without direct involvement by
the host program. This produces <em>nested parallelism</em>; i.e. additional
levels of concurrency are nested inside a running kernel-instance. The
kernel-instance executing on a device (the <em>parent kernel</em>) enqueues a
kernel-instance (the <em>child kernel</em>) to a device-side command queue.
Child and parent kernels execute asynchronously though a parent kernel
does not complete until all of its child-kernels have completed.
<br>
<br>
<strong>Diverged control flow</strong>: see <em>control flow</em>.
<br>
<br>
<strong>Ended</strong>: The fifth state in the six state model for the execution of a
command. The transition into this state occurs when execution of a
command has ended. When a Kernel-enqueue command ends, all of the
work-groups associated with that command have finished their execution.
<br>
<br>
<strong>Event Object</strong>: An <em>event</em> <em>object_encapsulates the status of an
operation such as a _command</em>. It can be used to synchronize operations
in a context.
<br>
<br>
<strong>Event Wait List</strong>: An <em>event wait list</em> is a list of <em>event objects</em> that
can be used to control when a particular <em>command</em> begins execution.
<br>
<br>
<strong>Fence</strong>: A memory ordering operation without an associated atomic
object. A fence can use the <em>acquire semantics, release semantics</em>, or
<em>acquire release semantics</em>.
<br>
<br>
<strong>Framework</strong>: A software system that contains the set of components to
support software development and execution. A <em>framework</em> typically
includes libraries, APIs, runtime systems, compilers, etc.
<br>
<br>
<strong>Generic address space</strong>: An address space that include the <em>private</em>,
<em>local</em>, and <em>global</em> address spaces available to a device. The generic
address space supports conversion of pointers to and from private, local
and global address spaces, and hence lets a programmer write a single
function that at compile time can take arguments from any of the three
named address spaces.
<br>
<br>
<strong>Global Happens before</strong>: see <em>happens before</em>.
<br>
<br>
<strong>Global ID</strong>: A <em>global ID</em> is used to uniquely identify a <em>work-item</em> and
is derived from the number of <em>global work-items</em> specified when
executing a <em>kernel</em>. The <em>global ID</em> is a N-dimensional value that
starts at (0, 0, 0). See also <em>Local ID</em>.
<br>
<br>
<strong>Global Memory</strong>: A memory region accessible to all <em>work-items</em> executing
in a <em>context</em>. It is accessible to the <em>host</em> using <em>commands</em> such as
read, write and map. <em>Global memory</em> is included within the <em>generic
address space</em> that includes the private and local address spaces.
<br>
<br>
<strong>GL share group</strong>: A <em>GL share group</em> object manages shared OpenGL or
OpenGL ES resources
such as textures, buffers, framebuffers, and renderbuffers and is
associated with one or more GL context objects. The <em>GL share group</em> is
typically an opaque object and not directly accessible.
<br>
<br>
<strong>Handle</strong>: An opaque type that references an <em>object</em> allocated by
OpenCL. Any operation on an <em>object</em> occurs by reference to that
objects handle.
<br>
<br>
<strong>Happens before</strong>: An ordering relationship between operations that
execute on multiple units of execution. If an operation A happens-before
operation B then A must occur before B; in particular, any value written
by A will be visible to B.We define two separate happens before
relations: <em>global-happens-before</em> and <em>local-happens-before</em>. These are
defined in section 3.3.6.
<br>
<br>
<strong>Host</strong>: The <em>host</em> interacts with the <em>context</em> using the OpenCL API.
<br>
<br>
<strong>Host-thread</strong>: the unit of execution that executes the statements in the
Host program.
<br>
<br>
<strong>Host pointer</strong>: A pointer to memory that is in the virtual address space
on the <em>host</em>.
<br>
<br>
<strong>Illegal</strong>: Behavior of a system that is explicitly not allowed and will
be reported as an error when encountered by OpenCL.
<br>
<br>
<strong>Image Object</strong>: A <em>memory object</em> that stores a two- or three-
dimensional structured array. Image data can only be accessed with read
and write functions. The read functions use a <em>sampler</em>.
<br>
<br>
The <em>image object</em> encapsulates the following information:</p></div>
<div class="ulist"><ul>
<li>
<p>
Dimensions of the image.
</p>
</li>
<li>
<p>
Description of each
element in the image.
</p>
</li>
<li>
<p>
Properties that describe
usage information and which region to allocate from.
</p>
</li>
<li>
<p>
Image data.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The elements of an image are selected from a list of predefined image
formats.
<br>
<br>
<strong>Implementation Defined</strong>: Behavior that is explicitly allowed to vary
between conforming implementations of OpenCL. An OpenCL implementor is
required to document the implementation-defined behavior.
<br>
<br>
<strong>Independent Forward Progress</strong>: If an entity supports independent forward
progress, then if it is otherwise not dependent on any actions due to be
performed by any other entity (for example it does not wait on a lock
held by, and thus that must be released by, any other entity), then its
execution cannot be blocked by the execution of any other entity in the
system (it will not be starved). Work items in a subgroup, for example,
typically do not support independent forward progress, so one work item
in a subgroup may be completely blocked (starved) if a different work
item in the same subgroup enters a spin loop.
<br>
<br>
<strong>In-order Execution</strong>: A model of execution in OpenCL where the <em>commands</em>
in a <em>command-queue_ are executed in order of submission with each
_command</em> running to completion before the next one begins. See
Out-of-order Execution.
<br>
<br>
<strong>Intermediate Language</strong>: A lower-level language that may be used to
create programs. SPIR-V is a required IL for OpenCL 2.2 runtimes.
Additional ILs may be accepted on an implementation-defined basis.
<br>
<br>
<strong>Kernel</strong>: A <em>kernel</em> is a function declared in a <em>program</em> and executed
on an OpenCL <em>device</em>. A <em>kernel</em> is identified by the kernel or
kernel qualifier applied to any function defined in a <em>program</em>.
<br>
<br>
<strong>Kernel-instance</strong>: The work carried out by an OpenCL program occurs
through the execution of kernel-instances on devices. The kernel
instance is the <em>kernel object</em>, the values associated with the
arguments to the kernel, and the parameters that define the <em>NDRange</em>
index space.
<br>
<br>
<strong>Kernel Object</strong>: A <em>kernel object</em> encapsulates a specific <em>kernel
function declared in a <em>program</em> and the argument values to be used when
executing this </em>kernel function.
<br>
<br>
<strong>Kernel Language</strong>: A language that is used to create source code for kernel.
Supported kernel languages include OpenCL C, OpenCL C++, and OpenCL dialect of SPIR-V.
<br>
<br>
<strong>Launch</strong>: The transition of a command from the <em>submitted</em> state to the
<em>ready</em> state. See <em>Ready</em>.
<br>
<br>
<strong>Local ID</strong>: A <em>local ID</em> specifies a unique <em>work-item ID</em> within a given
<em>work-group</em> that is executing a <em>kernel</em>. The <em>local ID</em> is a
N-dimensional value that starts at (0, 0, 0). See also <em>Global ID</em>.
<br>
<br>
<strong>Local Memory</strong>: A memory region associated with a <em>work-group</em> and
accessible only by <em>work-items</em> in that <em>work-group</em>. <em>Local memory</em> is
included within the <em>generic address space</em> that includes the private
and global address spaces.
<br>
<br>
<strong>Marker</strong>: A <em>command</em> queued in a <em>command-queue</em> that can be used to
tag all <em>commands</em> queued before the <em>marker</em> in the <em>command-queue</em>.
The <em>marker</em> command returns an <em>event</em> which can be used by the
<em>application</em> to queue a wait on the marker event i.e. wait for all
commands queued before the <em>marker</em> command to complete.
<br>
<br>
<strong>Memory Consistency Model</strong>: Rules that define which values are observed
when multiple units of execution load data from any shared memory plus
the synchronization operations that constrain the order of memory
operations and define synchronization relationships. The memory
consistency model in OpenCL is based on the memory model from the ISO
C11 programming language.
<br>
<br>
<strong>Memory Objects</strong>: A <em>memory object</em> is a handle to a reference counted
region of <em>global memory</em>. Also see_Buffer Object_and_Image Object_.
<br>
<br>
<strong>Memory Regions (or Pools)</strong>: A distinct address space in OpenCL. <em>Memory
regions</em> may overlap in physical memory though OpenCL will treat them as
logically distinct. The <em>memory regions</em> are denoted as <em>private</em>,
<em>local</em>, <em>constant,</em> and <em>global</em>.
<br>
<br>
<strong>Memory Scopes</strong>: These memory scopes define a hierarchy of visibilities
when analyzing the ordering constraints of memory operations. They are
defined by the values of the memory_scope enumeration constant. Current
values are <strong>memory_scope_work_item</strong>(memory constraints only apply to a
single work-item and in practice apply only to image operations)<strong>,
memory_scope_sub_group</strong> (memory-ordering constraints only apply to
work-items executing in a sub-group), <strong>memory_scope_work_group</strong>
(memory-ordering constraints only apply to work-items executing in a
work-group), <strong>memory_scope_device</strong> (memory-ordering constraints only
apply to work-items executing on a single device) and
<strong>memory_scope_all_svm_devices</strong> (memory-ordering constraints only apply
to work-items executing across multiple devices and when using shared
virtual memory).
<br>
<br>
<strong>Modification Order</strong>:All modifications to a particular atomic object M
occur in some particular <strong>total order</strong>, called the <strong>modification
order</strong> of M. If A and B are modifications of an atomic object M, and A
happens-before B, then A shall precede B in the modification order of M.
Note that the modification order of an atomic object M is independent of
whether M is in local or global memory.
<br>
<br>
<strong>Nested Parallelism</strong>: See <em>device-side enqueue</em>.
<br>
<br>
<strong>Object</strong>: Objects are abstract representation of the resources that can
be manipulated by the OpenCL API. Examples include <em>program objects</em>,
<em>kernel objects</em>, and <em>memory objects</em>.
<br>
<br>
<strong>Out-of-Order Execution</strong>: A model of execution in which <em>commands</em> placed
in the <em>work queue</em> may begin and complete execution in any order
consistent with constraints imposed by <em>event wait
lists_and_command-queue barrier</em>. See <em>In-order Execution</em>.
<br>
<br>
<strong>Parent device</strong>: The OpenCL <em>device</em> which is partitioned to create
<em>sub-devices</em>. Not all <em>parent devices_are _root devices</em>. A <em>root
device</em> might be partitioned and the <em>sub-devices</em> partitioned again.
In this case, the first set of <em>sub-devices</em> would be <em>parent devices</em>
of the second set, but not the <em>root devices</em>. Also see <em>device</em>,
<em>parent device</em> and <em>root device</em>.
<br>
<br>
<strong>Parent kernel</strong>: see <em>device-side enqueue</em>.
<br>
<br>
<strong>Pipe</strong>: The <em>pipe</em> memory object conceptually is an ordered sequence of
data items. A pipe has two endpoints: a write endpoint into which data
items are inserted, and a read endpoint from which data items are
removed. At any one time, only one kernel instance may write into a
pipe, and only one kernel instance may read from a pipe. To support the
producer consumer design pattern, one kernel instance connects to the
write endpoint (the producer) while another kernel instance connects to
the reading endpoint (the consumer).
<br>
<br>
<strong>Platform</strong>: The <em>host</em> plus a collection of <em>devices</em> managed by the
OpenCL <em>framework</em> that allow an application to share <em>resources</em> and
execute <em>kernels</em> on <em>devices</em> in the <em>platform</em>.
<br>
<br>
<strong>Private Memory</strong>: A region of memory private to a <em>work-item</em>. Variables
defined in one <em>work-items</em> <em>private memory</em> are not visible to another
<em>work-item</em>.
<br>
<br>
<strong>Processing Element</strong>: A virtual scalar processor. A work-item may
execute on one or more processing elements.
<br>
<br>
<strong>Program</strong>: An OpenCL <em>program</em> consists of a set of <em>kernels</em>.
<em>Programs</em> may also contain auxiliary functions called by the <em>_kernel
functions and constant data.
<br>
<br>
<strong>Program Object</strong>: A _program object</em> encapsulates the following
information:</p></div>
<div class="ulist"><ul>
<li>
<p>
A reference to an
associated <em>context</em>.
</p>
</li>
<li>
<p>
A <em>program</em> source or
binary.
</p>
</li>
<li>
<p>
The latest successfully
built program executable, the list of <em>devices</em> for which the program
executable is built, the build options used and a build log.
</p>
</li>
<li>
<p>
The number of <em>kernel
objects</em> currently attached.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>Queued</strong>: The first state in the six state model for the execution of a
command. The transition into this state occurs when the command is
enqueued into a command-queue.
<br>
<br>
<strong>Ready</strong>: The third state in the six state model for the execution of a
command. The transition into this state occurs when pre-requisites
constraining execution of a command have been met; i.e. the command has
been launched. When a Kernel-enqueue command is launched, work-groups
associated with the command are placed in a devices work-pool from
which they are scheduled for execution.
<br>
<br>
<strong>Re-converged Control Flow</strong>: see <em>control flow</em>.
<br>
<br>
<strong>Reference Count</strong>: The life span of an OpenCL object is determined by its
<em>reference count_an internal count of the number of references to the
object. When you create an object in OpenCL, its _reference count</em> is
set to one. Subsequent calls to the appropriate <em>retain</em> API (such as
clRetainContext, clRetainCommandQueue) increment the <em>reference count</em>.
Calls to the appropriate <em>release</em> API (such as clReleaseContext,
clReleaseCommandQueue) decrement the <em>reference count</em>.
Implementations may also modify the <em>reference count</em>, e.g. to track
attached objects or to ensure correct operation of in-progress or
scheduled activities. The object becomes inaccessible to host code when
the number of <em>release</em> operations performed matches the number of
<em>retain</em> operations plus the allocation of the object. At this point the
reference count may be zero but this is not guaranteed.
<br>
<br>
<strong>Relaxed Consistency</strong>: A memory consistency model in which the contents
of memory visible to different <em>work-items</em> or <em>commands</em> may be
different except at a <em>barrier</em> or other explicit synchronization
points.
<br>
<br>
<strong>Relaxed Semantics</strong>: A memory order semantics for atomic operations that
implies no order constraints. The operation is <em>atomic</em> but it has no
impact on the order of memory operations.
<br>
<br>
<strong>Release Semantics</strong>: One of the memory order semantics defined for
synchronization operations.  Release semantics apply to atomic
operations that store to memory.  Given two units of execution, <strong>A</strong> and
<strong>B</strong>, acting on a shared atomic object <strong>M</strong>, if <strong>A</strong> uses an atomic store
of <strong>M</strong> with release semantics to synchronize-with an atomic load to <strong>M</strong>
by <strong>B*that used acquire semantics, then *A*s atomic store will occur
<em>after</em> any prior operations by *A</strong>. Note that the memory orders
<em>acquire</em>, <em>sequentialy consistent</em>, and <em>acquire_release</em> all include
<em>acquire semantics</em> and effectively pair with a store using release
semantics.
<br>
<br>
<strong>Remainder work-groups</strong>: When the work-groups associated with a
kernel-instance are defined, the sizes of a work-group in each dimension
may not evenly divide the size of the NDRange in the corresponding
dimensions. The result is a collection of work-groups on the boundaries
of the NDRange that are smaller than the base work-group size. These are
known as <em>remainder work-groups</em>.
<br>
<br>
<strong>Running</strong>: The fourth state in the six state model for the execution of
a command. The transition into this state occurs when the execution of
the command starts. When a Kernel-enqueue command starts, one or more
work-groups associated with the command start to execute.
<br>
<br>
<strong>Root device</strong>: A <em>root device</em> is an OpenCL <em>device</em> that has not been
partitioned. Also see <em>device</em>, <em>parent device</em> and <em>root device</em>.
<br>
<br>
<strong>Resource</strong>: A class of <em>objects</em> defined by OpenCL. An instance of a
<em>resource</em> is an <em>object</em>. The most common <em>resources</em> are the
<em>context</em>, <em>command-queue</em>, <em>program objects</em>, <em>kernel objects</em>, and
<em>memory objects</em>. Computational resources are hardware elements that
participate in the action of advancing a program counter. Examples
include the <em>host</em>, <em>devices</em>, <em>compute units</em> and <em>processing
elements</em>.
<br>
<br>
<strong>Retain</strong>, Release: The action of incrementing (retain) and decrementing
(release) the reference count using an OpenCL <em>object</em>. This is a book
keeping functionality to make sure the system doesnt remove an <em>object</em>
before all instances that use this <em>object</em> have finished. Refer to
<em>Reference Count</em>.
<br>
<br>
<strong>Sampler</strong>: An <em>object</em> that describes how to sample an image when the
image is read in the <em>kernel</em>. The image read functions take a
<em>sampler</em> as an argument. The <em>sampler</em> specifies the image
addressing-mode i.e. how out-of-range image coordinates are handled, the
filter mode, and whether the input image coordinate is a normalized or
unnormalized value.
<br>
<br>
<strong>Scope inclusion</strong>: Two actions <strong>A</strong> and <strong>B</strong> are defined to have an
inclusive scope if they have the same scope <strong>P</strong> such that: (1) if <strong>P</strong> is
memory_scope_sub_group, and <strong>A</strong> and <strong>B</strong> are executed by work-items
within the same sub-group, or (2) if <strong>P</strong> is memory_scope_work_group, and
<strong>A</strong> and <strong>B</strong> are executed by work-items within the same work-group, or
(3) if <strong>P</strong> is memory_scope_device, and <strong>A</strong> and <strong>B</strong> are executed by
work-items on the same device, or (4) if <strong>P</strong> is
memory_scope_all_svm_devices, if <strong>A</strong> and <strong>B</strong> are executed by host
threads or by work-items on one or more devices that can share SVM
memory with each other and the host process.
<br>
<br>
<strong>Sequenced before</strong>: A relation between evaluations executed by a single
unit of execution. Sequenced-before is an asymmetric, transitive,
pair-wise relation that induces a partial order between evaluations.
Given any two evaluations A and B, if A is sequenced-before B, then the
execution of A shall precede the execution of B.
<br>
<br>
<strong>Sequential consistency</strong>: Sequential consistency interleaves the steps
executed by each unit of execution. Each access to a memory location
sees the last assignment to that location in that interleaving.
<br>
<br>
<strong>Sequentially consistent semantics</strong>: One of the memory order semantics
defined for synchronization operations. When using
sequentially-consistent synchronization operations, the loads and stores
within one unit of execution appear to execute in program order (i.e.,
the sequenced-before order), and loads and stores from different units
of execution appear to be simply interleaved.
<br>
<br>
<strong>Shared Virtual Memory (SVM)</strong>: An address space exposed to both the host
and the devices within a context. SVM causes addresses to be meaningful
between the host and all of the devices within a context and therefore
supports the use of pointer based data structures in OpenCL kernels. It
logically extends a portion of the global memory into the host address
space therefore giving work-items access to the host address space.
There are three types of SVM in OpenCL <strong>Coarse-Grained buffer SVM</strong>:
Sharing occurs at the granularity of regions of OpenCL buffer memory
objects. <strong>Fine-Grained buffer SVM</strong>: Sharing occurs at the granularity
of individual loads/stores into bytes within OpenCL buffer memory
objects. <strong>Fine-Grained system SVM</strong>: Sharing occurs at the granularity of
individual loads/stores into bytes occurring anywhere within the host
memory.
<br>
<br>
<strong>SIMD</strong>: Single Instruction Multiple Data. A programming model where a
<em>kernel</em> is executed concurrently on multiple <em>processing elements</em> each
with its own data and a shared program counter. All <em>processing
elements</em> execute a strictly identical set of instructions.
<br>
<br>
<strong>Specialization constants</strong>: Specialization is intended for constant
objects that will not have known constant values until after initial
generation of a SPIR-V module. Such objects are called specialization
constants. Application might provide values for
the specialization constants that will be used when SPIR-V program is
built. Specialization constants that do not receive a value from an
application shall use default value as defined in SPIR-V specification.
<br>
<br>
<strong>SPMD</strong>: Single Program Multiple Data. A programming model where a
<em>kernel</em> is executed concurrently on multiple <em>processing elements</em> each
with its own data and its own program counter. Hence, while all
computational resources run the same <em>kernel</em> they maintain their own
instruction counter and due to branches in a <em>kernel</em>, the actual
sequence of instructions can be quite different across the set of
<em>processing elements</em>.
<br>
<br>
<strong>Sub-device</strong>: An OpenCL <em>device</em> can be partitioned into multiple
<em>sub-devices</em>. The new <em>sub-devices</em> alias specific collections of
compute units within the parent <em>device</em>, according to a partition
scheme. The <em>sub-devices</em> may be used in any situation that their
parent <em>device</em> may be used. Partitioning a <em>device</em> does not destroy
the parent <em>device</em>, which may continue to be used along side and
intermingled with its child <em>sub-devices</em>. Also see <em>device</em>, <em>parent
device</em> and <em>root device</em>.
<br>
<br>
<strong>Sub-group</strong>: Sub-groups are an implementation-dependent grouping of
work-items within a work-group.   The size and number of sub-groups is
implementation-defined.
<br>
<br>
<strong>Sub-group Barrier</strong>. See <em>Barrier</em>.
<br>
<br>
<strong>Submitted</strong>: The second state in the six state model for the execution
of a command. The transition into this state occurs when the command is
flushed from the command-queue and submitted for execution on the
device. Once submitted, a programmer can assume a command will execute
once its prerequisites have been met.
<br>
<br>
<strong>SVM Buffer</strong>: A memory allocation enabled to work with Shared Virtual
Memory (SVM). Depending on how the SVM buffer is created, it can be a
coarse-grained or fine-grained SVM buffer. Optionally it may be wrapped
by a Buffer Object. See <em>Shared Virtual Memory (SVM)</em>.
<br>
<br>
<strong>Synchronization</strong>: Synchronization refers to mechanisms that constrain
the order of execution and the visibility of memory operations between
two or more units of execution.
<br>
<br>
<strong>Synchronization operations</strong>: Operations that define memory order
constraints in a program. They play a special role in controlling how
memory operations in one unit of execution (such as work-items or, when
using SVM a host thread) are made visible to another. Synchronization
operations in OpenCL include <em>atomic operations</em> and <em>fences</em>.
<br>
<br>
<strong>Synchronization point</strong>: A synchronization point between a pair of
commands (A and B) assures that results of command A happens-before
command B is launched (i.e. enters the ready state) .
<br>
<br>
<strong>Synchronizes with</strong>: A relation between operations in two different
units of execution that defines a memory order constraint in global
memory (<em>global-synchronizes-with</em>) or local memory
(<em>local-synchronizes-with</em>).
<br>
<br>
<strong>Task Parallel Programming Model</strong>: A programming model in which
computations are expressed in terms of multiple concurrent tasks
executing in one or more <em>command-queues</em>. The concurrent tasks can be
running different <em>kernels</em>.
<br>
<br>
<strong>Thread-safe</strong>: An OpenCL API call is considered to be <em>thread-safe</em> if
the internal state as managed by OpenCL remains consistent when called
simultaneously by multiple <em>host</em> threads. OpenCL API calls that are
<em>thread-safe</em> allow an application to call these functions in multiple
<em>host</em> threads without having to implement mutual exclusion across these
<em>host</em> threads i.e. they are also re-entrant-safe.
<br>
<br>
<strong>Undefined</strong>: The behavior of an OpenCL API call, built-in function used
inside a <em>kernel</em> or execution of a <em>kernel</em> that is explicitly not
defined by OpenCL. A conforming implementation is not required to
specify what occurs when an undefined construct is encountered in
OpenCL.
<br>
<br>
<strong>Unit of execution</strong>: a generic term for a process, OS managed thread
running on the host (a host-thread), kernel-instance, host program,
work-item or any other executable agent that advances the work
associated with a program.
<br>
<br>
<strong>Work-group</strong>: A collection of related <em>work-items</em> that execute on a
single <em>compute unit</em>. The <em>work-items</em> in the group execute the same
<em>kernel-instance</em> and share <em>local</em> <em>memory</em> and <em>work-group functions</em>.
<br>
<br>
<strong>Work-group Barrier</strong>. See <em>Barrier</em>.
<br>
<br>
<strong>Work-group Function</strong>: A function that carries out collective operations
across all the work-items in a work-group. Available collective
operations are a barrier, reduction, broadcast, prefix sum, and
evaluation of a predicate. A work-group function must occur within a
<em>converged control flow</em>; i.e. all work-items in the work-group must
encounter precisely the same work-group function.
<br>
<br>
<strong>Work-group Synchronization</strong>: Constraints on the order of execution for
work-items in a single work-group.
<br>
<br>
<strong>Work-pool</strong>: A logical pool associated with a device that holds commands
and work-groups from kernel-instances that are ready to execute. OpenCL
does not constrain the order that commands and work-groups are scheduled
for execution from the work-pool; i.e. a programmer must assume that
they could be interleaved. There is one work-pool per device used by
all command-queues associated with that device. The work-pool may be
implemented in any manner as long as it assures that work-groups placed
in the pool will eventually execute.
<br>
<br>
<strong>Work-item</strong>: One of a collection of parallel executions of a <em>kernel</em>
invoked on a <em>device</em> by a <em>command</em>. A <em>work-item</em> is executed by one
or more <em>processing elements</em> as part of a <em>work-group</em> executing on a
<em>compute unit</em>. A <em>work-item</em> is distinguished from other work-items by
its <em>global ID</em> or the combination of its <em>work-group</em> ID and its <em>local
ID</em> within a <em>work-group</em>.</p></div>
<div class="paragraph"><p> </p></div>
</div>
</div>
<div class="sect1">
<h2 id="_the_opencl_architecture">3. The OpenCL Architecture</h2>
<div class="sectionbody">
<div class="paragraph"><p><strong>OpenCL</strong> is an open industry standard for programming a heterogeneous
collection of CPUs, GPUs and other discrete computing devices organized
into a single platform. It is more than a language. OpenCL is a
framework for parallel programming and includes a language, API,
libraries and a runtime system to support software development. Using
OpenCL, for example, a programmer can write general purpose programs
that execute on GPUs without the need to map their algorithms onto a 3D
graphics API such as OpenGL or DirectX.
<br>
<br>
The target of OpenCL is expert programmers wanting to write portable yet
efficient code. This includes library writers, middleware vendors, and
performance oriented application programmers. Therefore OpenCL provides
a low-level hardware abstraction plus a framework to support programming
and many details of the underlying hardware are exposed.
<br>
<br>
To describe the core ideas behind OpenCL, we will use a hierarchy of
models:</p></div>
<div class="ulist"><ul>
<li>
<p>
Platform Model
</p>
</li>
<li>
<p>
Memory Model
</p>
</li>
<li>
<p>
Execution Model
</p>
</li>
<li>
<p>
Programming Model
</p>
</li>
</ul></div>
<div class="sect2">
<h3 id="_platform_model">3.1. Platform Model</h3>
<div class="paragraph"><p>The Platform model for OpenCL is defined in <em>figure 3.1</em>. The model
consists of a <strong>host</strong> connected to one or more <strong>OpenCL devices</strong>. An OpenCL
device is divided into one or more <strong>compute units</strong> (CUs) which are further
divided into one or more <strong>processing elements</strong> (PEs). Computations on a
device occur within the processing elements.
<br>
<br>
An OpenCL application is implemented as both host code and device kernel
code.  The host code portion of an OpenCL application runs on a host
processor according to the models native to the host platform. The
OpenCL application host code submits the kernel code as commands from
the host to OpenCL devices.  An OpenCL device executes the commands
computation on the processing elements within the device. 
<br>
<br>
An OpenCL device has considerable latitude on how computations are
mapped onto the devices processing elements.  When processing elements
within a compute unit execute the same sequence of statements across the
processing elements, the control flow is said to be <em>converged.</em>
Hardware optimized for executing a single stream of instructions over
multiple processing elements is well suited to converged control
flows. When the control flow varies from one processing element to
another, it is said to be <em>diverged.</em> While a kernel always begins
execution with a converged control flow, due to branching statements
within a kernel, converged and diverged control flows may occur within a
single kernel. This provides a great deal of flexibility in the
algorithms that can be implemented with OpenCL.
<br>
<br></p></div>
<div class="paragraph"><p><span class="image">
<img src="opencl22-API_files/image004_new.png" alt="opencl22-API_files/image004_new.png" width="320" height="180">
</span></p></div>
<div class="paragraph"><p><strong>Figure 3.1</strong>: <em>Platform model &#8230; one host plus one or more compute devices each
with one or more compute units composed of one or more processing elements</em>.
<br>
<br>
Programmers provide programs in the form of SPIR-V source binaries,
OpenCL C or OpenCL C++ source strings or implementation-defined binary objects. The
OpenCL platform provides a compiler to translate program input of either
form into executable program objects. The device code compiler may be
<em>online</em> or <em>offline</em>. An <em>online</em> <em>compiler</em> is available during host
program execution using standard APIs. An <em>offline compiler</em> is
invoked outside of host program control, using platform-specific
methods. The OpenCL runtime allows developers to get a previously
compiled device program executable and be able to load and execute a
previously compiled device program executable.
<br>
<br>
OpenCL defines two kinds of platform profiles: a <em>full profile</em> and a
reduced-functionality <em>embedded profile</em>. A full profile platform must
provide an online compiler for all its devices. An embedded platform
may provide an online compiler, but is not required to do so.
<br>
<br>
A device may expose special purpose functionality as a <em>built-in
function</em>. The platform provides APIs for enumerating and invoking the
built-in functions offered by a device, but otherwise does not define
their construction or semantics. A <em>custom device</em> supports only
built-in functions, and cannot be programmed via a kernel language.
<br>
<br>
All device types support the OpenCL execution model, the OpenCL memory
model, and the APIs used in OpenCL to manage devices.
<br>
<br>
The platform model is an abstraction describing how OpenCL views the
hardware. The relationship between the elements of the platform model
and the hardware in a system may be a fixed property of a device or it
may be a dynamic feature of a program dependent on how a compiler
optimizes code to best utilize physical hardware.</p></div>
</div>
<div class="sect2">
<h3 id="_execution_model">3.2. Execution Model</h3>
<div class="paragraph"><p>The OpenCL execution model is defined in terms of two distinct units of
execution: <strong>kernels</strong> that execute on one or more OpenCL devices and a
<strong>host program</strong> that executes on the host. With regard to OpenCL, the
kernels are where the "work" associated with a computation occurs. This
work occurs through <strong>work-items</strong> that execute in groups (<strong>work-groups</strong>).
<br>
<br>
A kernel executes within a well-defined context managed by the host.
The context defines the environment within which kernels execute. It
includes the following resources:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Devices</strong>: One or
more devices exposed by the OpenCL platform.
</p>
</li>
<li>
<p>
<strong>Kernel Objects</strong>:The
OpenCL functions with their associated argument values that run on
OpenCL devices.
</p>
</li>
<li>
<p>
<strong>Program Objects</strong>:The
program source and executable that implement the kernels.
</p>
</li>
<li>
<p>
<strong>Memory
Objects</strong>:Variables visible to the host and the OpenCL devices.
Instances of kernels operate on these objects as they execute.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The host program uses the OpenCL API to create and manage the context.
Functions from the OpenCL API enable the host to interact with a device
through a <em>command-queue</em>. Each command-queue is associated with a
single device. The commands placed into the command-queue fall into
one of three types:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Kernel-enqueue commands</strong>:
Enqueue a kernel for execution on a device.
</p>
</li>
<li>
<p>
<strong>Memory commands</strong>:
Transfer data between the host and device memory, between memory
objects, or map and unmap memory objects from the host address space.
</p>
</li>
<li>
<p>
<strong>Synchronization
commands</strong>: Explicit synchronization points that define order constraints
between commands.
</p>
</li>
</ul></div>
<div class="paragraph"><p>In addition to commands submitted from the host command-queue, a kernel
running on a device can enqueue commands to a device-side command queue.
This results in <em>child kernels</em> enqueued by a kernel executing on a
device (the <em>parent kernel</em>). Regardless of whether the command-queue
resides on the host or a device, each command passes through six states.</p></div>
<div class="olist arabic"><ol class="arabic">
<li>
<p>
<strong>Queued</strong>: The command is enqueued to a command-queue. A
command may reside in the queue until it is flushed either explicitly (a
call to clFlush) or implicitly by some other command.
</p>
</li>
<li>
<p>
<strong>Submitted</strong>: The command is flushed from the command-queue and
submitted for execution on the device. Once flushed from the
command-queue, a command will execute after any prerequisites for
execution are met.
</p>
</li>
<li>
<p>
<strong>Ready</strong>: All prerequisites constraining execution of a command
have been met. The command, or for a kernel-enqueue command the
collection of work groups associated with a command, is placed in a
device work-pool from which it is scheduled for execution.
</p>
</li>
<li>
<p>
<strong>Running</strong>: Execution of the command starts. For the case of a
kernel-enqueue command, one or more work-groups associated with the
command start to execute.
</p>
</li>
<li>
<p>
<strong>Ended</strong>: Execution of a command ends. When a Kernel-enqueue
command ends, all of the work-groups associated with that command have
finished their execution. <em>Immediate side effects</em>, i.e. those
associated with the kernel but not necessarily with its child kernels,
are visible to other units of execution. These side effects include
updates to values in global memory.
</p>
</li>
<li>
<p>
<strong>Complete</strong>: The command and its child commands have finished
execution and the status of the event object, if any, associated with
the command is set to CL_COMPLETE.
</p>
</li>
</ol></div>
<div class="paragraph"><p>The execution states and the transitions between them are summarized in
Figure 3-2. These states and the concept of a device work-pool are
conceptual elements of the execution model. An implementation of OpenCL
has considerable freedom in how these are exposed to a program. Five of
the transitions, however, are directly observable through a profiling
interface. These profiled states are shown in Figure 3-2.</p></div>
<div class="paragraph"><p><span class="image">
<img src="opencl22-API_files/image006.jpg" alt="image">
</span></p></div>
<div class="paragraph"><p><strong>Figure 3-2: The states and transitions between states defined in the
OpenCL execution model. A subset of these transitions is exposed
through the profiling interface (see section 5.14).</strong></p></div>
<div class="paragraph"><p>Commands communicate their status through <em>Event objects</em>. Successful
completion is indicated by setting the event status associated with a
command to CL_COMPLETE. Unsuccessful completion results in abnormal
termination of the command which is indicated by setting the event
status to a negative value. In this case, the command-queue associated
with the abnormally terminated command and all other command-queues in
the same context may no longer be available and their behavior is
implementation defined.
<br>
<br>
A command submitted to a device will not launch until prerequisites that
constrain the order of commands have been resolved. These
prerequisites have three sources:</p></div>
<div class="ulist"><ul>
<li>
<p>
They may arise from
commands submitted to a command-queue that constrain the order in which
commands are launched. For example, commands that follow a command queue
barrier will not launch until all commands prior to the barrier are
complete.
</p>
</li>
<li>
<p>
The second source of
prerequisites is dependencies between commands expressed through events.
A command may include an optional list of events. The command will wait
and not launch until all the events in the list are in the state CL
COMPLETE. By this mechanism, event objects define order constraints
between commands and coordinate execution between the host and one or
more devices.
</p>
</li>
<li>
<p>
The third source of
prerequisities can be the presence of non-trivial C initializers or C<span class="monospaced">
constructors for program scope global variables. In this case, OpenCL
C/C</span> compiler shall generate program initialization kernels that
perform C initialization or C<span class="monospaced"> construction. These kernels must be
executed by OpenCL runtime on a device before any kernel from the same
program can be executed on the same device. The ND-range for any program
initialization kernel is (1,1,1). When multiple programs are linked
together, the order of execution of program initialization kernels
that belong to different programs is undefined.
<br>
<br>
Program clean up may result in the execution of one or more program
clean up kernels by the OpenCL runtime. This is due to the presence of
non-trivial C\</span> destructors for program scope variables. The ND-range
for executing any program clean up kernel is (1,1,1). The order of
execution of clean up kernels from different programs (that are linked
together) is undefined.
<br>
<br>
Note that C initializers, C<span class="monospaced"> constructors, or C</span> destructors for
program scope variables cannot use pointers to coarse grain and fine
grain SVM allocations.
<br>
<br>
A command may be submitted to a device and yet have no visible side effects
outside of waiting on and satisfying event dependences. Examples include
markers, kernels executed over ranges of no work-items or copy
operations with zero sizes. Such commands may pass directly from the
<em>ready</em> state to the <em>ended</em> state.
<br>
<br>
Command execution can be blocking or non-blocking. Consider a sequence
of OpenCL commands. For blocking commands, the OpenCL API functions
that enqueue commands don&#8217;t return until the command has completed.
Alternatively, OpenCL functions that enqueue non-blocking commands
return immediately and require that a programmer defines dependencies
between enqueued commands to ensure that enqueued commands are not
launched before needed resources are available. In both cases, the
actual execution of the command may occur asynchronously with execution
of the host program.
<br>
<br>
Commands within a single command-queue execute relative to each other in
one of two modes:
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>In-order Execution</strong>:
Commands and any side effects associated with commands appear to the
OpenCL application as if they execute in the same order they are
enqueued to a command-queue.
</p>
</li>
<li>
<p>
<strong>Out-of-order Execution</strong>:
Commands execute in any order constrained only by explicit
synchronization points (e.g. through command queue barriers) or explicit
dependencies on events.
<br>
<br>
Multiple command-queues can be present within a single context.
Multiple command-queues execute commands independently. Event objects
visible to the host program can be used to define synchronization points
between commands in multiple command queues. If such synchronization
points are established between commands in multiple command-queues, an
implementation must assure that the command-queues progress concurrently
and correctly account for the dependencies established by the
synchronization points. For a detailed explanation of synchronization
points, see section 3.2.4.
<br>
<br>
The core of the OpenCL execution model is defined by how the kernels
execute. When a kernel-enqueue command submits a kernel for execution,
an index space is defined. The kernel, the argument values associated
with the arguments to the kernel, and the parameters that define the
index space define a <em>kernel-instance</em>. When a kernel-instance executes
on a device, the kernel function executes for each point in the defined
index space. Each of these executing kernel functions is called a
<em>work-item</em>. The work-items associated with a given kernel-instance are
managed by the device in groups called <em>work-groups</em>. These work-groups
define a coarse grained decomposition of the Index space. Work-groups
are further divided into <em>sub-groups</em>, which provide an additional level
of control over execution.
<br>
<br>
Work-items have a global ID based on their coordinates within the Index
space. They can also be defined in terms of their work-group and the
local ID within a work-group. The details of this mapping are described
in the following section.
</p>
</li>
</ul></div>
<div class="sect3">
<h4 id="_execution_model_mapping_work_items_onto_an_ndrange">3.2.1. Execution Model: Mapping work-items onto an NDRange</h4>
<div class="paragraph"><p>The index space supported by OpenCL is called an NDRange. An NDRange is
an N-dimensional index space, where N is one, two or three. The NDRange
is decomposed into work-groups forming blocks that cover the Index
space. An NDRange is defined by three integer arrays of length N:</p></div>
<div class="ulist"><ul>
<li>
<p>
The extent of the index
space (or global size) in each dimension.
</p>
</li>
<li>
<p>
An offset index F
indicating the initial value of the indices in each dimension (zero by
default).
</p>
</li>
<li>
<p>
The size of a work-group
(local size) in each dimension.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Each work-items global ID is an N-dimensional tuple. The global ID
components are values in the range from F, to F plus the number of
elements in that dimension minus one.
<br>
<br>
If a kernel is created from OpenCL C 2.0 or SPIR-V, the size of work-groups
in an NDRange (the local size) need not be the same for all work-groups.
In this case, any single dimension for which the global size is not
divisible by the local size will be partitioned into two regions. One
region will have work-groups that have the same number of work items as
was specified for that dimension by the programmer (the local size). The
other region will have work-groups with less than the number of work
items specified by the local size parameter in that dimension (the
<em>remainder work-groups</em>). Work-group sizes could be non-uniform in
multiple dimensions, potentially producing work-groups of up to 4
different sizes in a 2D range and 8 different sizes in a 3D range.
<br>
<br>
Each work-item is assigned to a work-group and given a local ID to
represent its position within the work-group. A work-item&#8217;s local ID is
an N-dimensional tuple with components in the range from zero to the
size of the work-group in that dimension minus one.
<br>
<br>
Work-groups are assigned IDs similarly. The number of work-groups in
each dimension is not directly defined but is inferred from the local
and global NDRanges provided when a kernel-instance is enqueued. A
work-group&#8217;s ID is an N-dimensional tuple with components in the range 0
to the ceiling of the global size in that dimension divided by the local
size in the same dimension. As a result, the combination of a
work-group ID and the local-ID within a work-group uniquely defines a
work-item. Each work-item is identifiable in two ways; in terms of a
global index, and in terms of a work-group index plus a local index
within a work group.
<br>
<br>
For example, consider the 2-dimensional index space in figure 3-3. We
input the index space for the work-items (G<sub>x</sub>, G<sub>y</sub>), the size of each
work-group (S<sub>x</sub>, S<sub>y</sub>) and the global ID offset (F<sub>x</sub>, F<sub>y</sub>). The
global indices define an G<sub>x</sub>by G<sub>y</sub> index space where the total number
of work-items is the product of G<sub>x</sub> and G<sub>y</sub>. The local indices define
an S<sub>x</sub> by S<sub>y</sub> index space where the number of work-items in a single
work-group is the product of S<sub>x</sub> and S<sub>y</sub>. Given the size of each
work-group and the total number of work-items we can compute the number
of work-groups. A 2-dimensional index space is used to uniquely identify
a work-group. Each work-item is identified by its global ID (<em>g</em><sub>x</sub>,
<em>g</em><sub>y</sub>) or by the combination of the work-group ID (<em>w</em><sub>x</sub>, <em>w</em><sub>y</sub>), the
size of each work-group (S<sub>x</sub>,S<sub>y</sub>) and the local ID (s<sub>x</sub>, s<sub>y</sub>) inside
the work-group such that
<br></p></div>
<div class="paragraph"><p>&#160; &#160; &#160; &#160; (g<sub>x</sub> , g<sub>y</sub>) = (w<sub>x</sub> * S<sub>x</sub> + s<sub>x</sub> + F<sub>x</sub>, w<sub>y</sub> * S<sub>y</sub> + s<sub>y</sub> + F<sub>y</sub>)
<br>
<br>
The number of work-groups can be computed as:
<br></p></div>
<div class="paragraph"><p>&#160; &#160; &#160; &#160; (W<sub>x</sub>, W<sub>y</sub>) = (ceil(G<sub>x</sub> / S<sub>x</sub>),ceil( G<sub>y</sub> / S<sub>y</sub>))
<br>
<br>
Given a global ID and the work-group size, the work-group ID for a
work-item is computed as:
<br></p></div>
<div class="paragraph"><p>&#160; &#160; &#160; &#160; (w<sub>x</sub>, w<sub>y</sub>) = ( (g<sub>x</sub> s<sub>x</sub> F<sub>x</sub>) / S<sub>x</sub>, (g<sub>y</sub> s<sub>y</sub> F<sub>y</sub>) /
S<sub>y</sub> )</p></div>
<div class="paragraph"><p><span class="image">
<img src="opencl22-API_files/image007.jpg" alt="image">
</span></p></div>
<div class="paragraph"><p><strong>Figure 3-3: An example of an NDRange index space showing work-items,
their global IDs and their mapping onto the pair of work-group and local
IDs. In this case, we assume that in each dimension, the size of the
work-group evenly divides the global NDRange size (i.e. all work-groups
have the same size) and that the offset is equal to zero.</strong>
<br>
<br>
Within a work-group work-items may be divided into sub-groups. The
mapping of work-items to sub-groups is implementation-defined and may be
queried at runtime. While sub-groups may be used in multi-dimensional
work-groups, each sub-group is 1-dimensional and any given work-item may
query which sub-group it is a member of.
<br>
<br>
Work items are mapped into sub-groups through a combination of
compile-time decisions and the parameters of the dispatch. The mapping
to sub-groups is invariant for the duration of a kernels execution,
across dispatches of a given kernel with the same work-group dimensions,
between dispatches and query operations consistent with the dispatch
parameterization, and from one work-group to another within the dispatch
(excluding the trailing edge work-groups in the presence of non-uniform
work-group sizes). In addition, all sub-groups within a work-group will
be the same size, apart from the sub-group with the maximum index which
may be smaller if the size of the work-group is not evenly divisible by
the size of the sub-groups.
<br>
<br>
In the degenerate case, a single sub-group must be supported for each
work-group. In this situation all sub-group scope functions are
equivalent to their work-group level equivalents.</p></div>
</div>
<div class="sect3">
<h4 id="_execution_model_execution_of_kernel_instances">3.2.2. Execution Model: Execution of kernel-instances</h4>
<div class="paragraph"><p>The work carried out by an OpenCL program occurs through the execution
of kernel-instances on compute devices. To understand the details of
OpenCLs execution model, we need to consider how a kernel object moves
from the kernel-enqueue command, into a command-queue, executes on a
device, and completes.
<br>
<br>
A kernel-object is defined from a function within the program object and
a collection of arguments connecting the kernel to a set of argument
values. The host program enqueues a kernel-object to the command queue
along with the NDRange, and the work-group decomposition. These define
a <em>kernel-instance</em>. In addition, an optional set of events may be
defined when the kernel is enqueued. The events associated with a
particular kernel-instance are used to constrain when the
kernel-instance is launched with respect to other commands in the queue
or to commands in other queues within the same context.
<br>
<br>
A kernel-instance is submitted to a device. For an in-order command
queue, the kernel instances appear to launch and then execute in that
same order; where we use the term appear to emphasize that when there
are no dependencies between commands and hence differences in the order
that commands execute cannot be observed in a program, an implementation
can reorder commands even in an in-order command queue. For an out of
order command-queue, kernel-instances wait to be launched until:</p></div>
<div class="ulist"><ul>
<li>
<p>
Synchronization commands
enqueued prior to the kernel-instance are satisfied.
</p>
</li>
<li>
<p>
Each of the events in an
optional event list defined when the kernel-instance was enqueued are
set to CL_COMPLETE.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Once these conditions are met, the kernel-instance is launched and the
work-groups associated with the kernel-instance are placed into a pool
of ready to execute work-groups. This pool is called a <em>work-pool</em>.
The work-pool may be implemented in any manner as long as it assures
that work-groups placed in the pool will eventually execute. The
device schedules work-groups from the work-pool for execution on the
compute units of the device. The kernel-enqueue command is complete when
all work-groups associated with the kernel-instance end their execution,
updates to global memory associated with a command are visible globally,
and the device signals successful completion by setting the event
associated with the kernel-enqueue command to CL_COMPLETE.
<br>
<br>
While a command-queue is associated with only one device, a single
device may be associated with multiple command-queues all feeding into
the single work-pool. A device may also be associated with command
queues associated with different contexts within the same platform,
again all feeding into the single work-pool. The device will pull
work-groups from the work-pool and execute them on one or several
compute units in any order; possibly interleaving execution of
work-groups from multiple commands. A conforming implementation may
choose to serialize the work-groups so a correct algorithm cannot assume
that work-groups will execute in parallel. There is no safe and
portable way to synchronize across the independent execution of
work-groups since once in the work-pool, they can execute in any order.
<br>
<br>
The work-items within a single sub-group execute concurrently but not
necessarily in parallel (i.e. they are not guaranteed to make
independent forward progress). Therefore, only high-level
synchronization constructs (e.g. sub-group functions such as barriers)
that apply to all the work-items in a sub-group are well defined and
included in OpenCL.
<br>
<br>
Sub-groups execute concurrently within a given work-group and with
appropriate device support (<em>see Section__4.2</em>) may make independent
forward progress with respect to each other, with respect to host
threads and with respect to any entities external to the OpenCL system
but running on an OpenCL device, even in the absence of work-group
barrier operations. In this situation, sub-groups are able to internally
synchronize using barrier operations without synchronizing with each
other and may perform operations that rely on runtime dependencies on
operations other sub-groups perform.
<br>
<br>
The work-items within a single work-group execute concurrently but are
only guaranteed to make independent progress in the presence of
sub-groups and device support. In the absence of this capability, only
high-level synchronization constructs (e.g. work-group functions such as
barriers) that apply to all the work-items in a work-group are well
defined and included in OpenCL for synchronization within the
work-group.
<br>
<br>
In the absence of synchronization functions (e.g. a barrier), work-items
within a sub-group may be serialized. In the presence of sub -group
functions, work-items within a sub -group may be serialized before any
given sub -group function, between dynamically encountered pairs of sub
-group functions and between a work-group function and the end of the
kernel.
<br>
<br>
In the absence of independent forward progress of constituent
sub-groups, work-items within a work-group may be serialized before,
after or between work-group synchronization functions.</p></div>
</div>
<div class="sect3">
<h4 id="_execution_model_device_side_enqueue">3.2.3. Execution Model: Device-side enqueue</h4>
<div class="paragraph"><p>Algorithms may need to generate additional work as they execute. In
many cases, this additional work cannot be determined statically; so the
work associated with a kernel only emerges at runtime as the
kernel-instance executes. This capability could be implemented in logic
running within the host program, but involvement of the host may add
significant overhead and/or complexity to the application control
flow. A more efficient approach would be to nest kernel-enqueue
commands from inside other kernels. This <strong>nested parallelism</strong> can be
realized by supporting the enqueuing of kernels on a device without
direct involvement by the host program; so-called <strong>device-side
enqueue</strong>.
<br>
<br>
Device-side kernel-enqueue commands are similar to host-side
kernel-enqueue commands. The kernel executing on a device (the <strong>parent
kernel</strong>) enqueues a kernel-instance (the <strong>child kernel</strong>) to a
device-side command queue. This is an out-of-order command-queue and
follows the same behavior as the out-of-order command-queues exposed to
the host program. Commands enqueued to a device side command-queue
generate and use events to enforce order constraints just as for the
command-queue on the host. These events, however, are only visible to
the parent kernel running on the device. When these prerequisite
events take on the value CL_COMPLETE, the work-groups associated with
the child kernel are launched into the devices work pool. The device
then schedules them for execution on the compute units of the device.
Child and parent kernels execute asynchronously. However, a parent will
not indicate that it is complete by setting its event to CL_COMPLETE
until all child kernels have ended execution and have signaled
completion by setting any associated events to the value CL_COMPLETE.
Should any child kernel complete with an event status set to a negative
value (i.e. abnormally terminate), the parent kernel will abnormally
terminate and propagate the childs negative event value as the value of
the parents event. If there are multiple children that have an event
status set to a negative value, the selection of which childs negative
event value is propagated is implementation-defined.</p></div>
</div>
<div class="sect3">
<h4 id="_execution_model_synchronization">3.2.4. Execution Model: Synchronization</h4>
<div class="paragraph"><p>Synchronization refers to mechanisms that constrain the order of
execution between two or more units of execution. Consider the
following three domains of synchronization in OpenCL:</p></div>
<div class="ulist"><ul>
<li>
<p>
Work-group
synchronization: Constraints on the order of execution for work-items in
a single work-group
</p>
</li>
<li>
<p>
Sub-group synchronization:
Contraints on the order of execution for work-items in a single
sub-group
</p>
</li>
<li>
<p>
Command synchronization:
Constraints on the order of commands launched for execution
</p>
</li>
</ul></div>
<div class="paragraph"><p>Synchronization across all work-items within a single work-group is
carried out using a <em>work-group function</em>. These functions carry out
collective operations across all the work-items in a work-group.
Available collective operations are: barrier, reduction, broadcast,
prefix sum, and evaluation of a predicate. A work-group function must
occur within a converged control flow; i.e. all work-items in the
work-group must encounter precisely the same work-group function. For
example, if a work-group function occurs within a loop, the work-items
must encounter the same work-group function in the same loop
iterations. All the work-items of a work-group must execute the
work-group function and complete reads and writes to memory before any
are allowed to continue execution beyond the work-group function.
Work-group functions that apply between work-groups are not provided in
OpenCL since OpenCL does not define forward-progress or ordering
relations between work-groups, hence collective synchronization
operations are not well defined.
<br>
<br>
Synchronization across all work-items within a single sub-group is
carried out using a <em>sub-group function</em>. These functions carry out
collective operations across all the work-items in a sub-group.
Available collective operations are: barrier, reduction, broadcast,
prefix sum, and evaluation of a predicate. A sub-group function must
occur within a converged control flow; i.e. all work-items in the
sub-group must encounter precisely the same sub-group function. For
example, if a work-group function occurs within a loop, the work-items
must encounter the same sub-group function in the same loop iterations.
All the work-items of a sub-group must execute the sub-group function
and complete reads and writes to memory before any are allowed to
continue execution beyond the sub-group function. Synchronization
between sub-groups must either be performed using work-group functions,
or through memory operations. Using memory operations for sub-group
synchronization should be used carefully as forward progress of
sub-groups relative to each other is only supported optionally by OpenCL
implementations.
<br>
<br>
Command synchronization is defined in terms of distinct <strong>synchronization
points</strong>. The synchronization points occur between commands in host
command-queues and between commands in device-side command-queues. The
synchronization points defined in OpenCL include:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Launching a command:</strong> A
kernel-instance is launched onto a device after all events that kernel
is waiting-on have been set to CL_COMPLETE.
</p>
</li>
<li>
<p>
<strong>Ending a command:</strong> Child
kernels may be enqueued such that they wait for the parent kernel to
reach the <em>end</em> state before they can be launched. In this case, the
ending of the parent command defines a synchronization point.
</p>
</li>
<li>
<p>
<strong>Completion of a command:</strong>
A kernel-instance is complete after all of the work-groups in the kernel
and all of its child kernels have completed. This is signaled to the
host, a parent kernel or other kernels within command queues by setting
the value of the event associated with a kernel to CL_COMPLETE.
</p>
</li>
<li>
<p>
<strong>Blocking Commands:</strong> A
blocking command defines a synchronization point between the unit of
execution that calls the blocking API function and the enqueued command
reaching the complete state.
</p>
</li>
<li>
<p>
<strong>Command-queue barrier:</strong>
The command-queue barrier ensures that all previously enqueued commands
have completed before subsequently enqueued commands can be launched.
</p>
</li>
<li>
<p>
<strong>clFinish:</strong> This function
blocks until all previously enqueued commands in the command queue have
completed after which clFinish defines a synchronization point and the
clFinish function returns.
</p>
</li>
</ul></div>
<div class="paragraph"><p>A synchronization point between a pair of commands (A and B) assures
that results of command A happens-before command B is launched. This
requires that any updates to memory from command A complete and are made
available to other commands before the synchronization point completes.
Likewise, this requires that command B waits until after the
synchronization point before loading values from global memory. The
concept of a synchronization point works in a similar fashion for
commands such as a barrier that apply to two sets of commands. All the
commands prior to the barrier must complete and make their results
available to following commands. Furthermore, any commands following
the barrier must wait for the commands prior to the barrier before
loading values and continuing their execution.
<br>
<br>
These <em>happens-before</em> relationships are a fundamental part of the
OpenCL memory model. When applied at the level of commands, they are
straightforward to define at a language level in terms of ordering
relationships between different commands. Ordering memory operations
inside different commands, however, requires rules more complex than can
be captured by the high level concept of a synchronization point.
These rules are described in detail in section 3.3.6.</p></div>
</div>
<div class="sect3">
<h4 id="_execution_model_categories_of_kernels">3.2.5. Execution Model: Categories of Kernels</h4>
<div class="paragraph"><p>The OpenCL execution model supports three types of kernels:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>OpenCL kernels</strong> are
managed by the OpenCL API as kernel-objects associated with kernel
functions within program-objects. OpenCL kernels are provided via a
kernel language.
All OpenCL implementations must support OpenCL kernels supplied in the
standard SPIR-V intermediate language with the appropriate environment
specification, and the OpenCL C programming language defined in earlier
versions of the OpenCL specification. Implementations must also support
OpenCL kernels in
SPIR-V intermediate language. SPIR-V binaries nay be
generated from an
OpenCL kernel language or by a third party compiler from an
alternative input.
</p>
</li>
<li>
<p>
<strong>Native kernels</strong> are
accessed through a host function pointer. Native kernels are queued for
execution along with OpenCL kernels on a device and share memory objects
with OpenCL kernels. For example, these native kernels could be
functions defined in application code or exported from a library. The
ability to execute native kernels is optional within OpenCL and the
semantics of native kernels are implementation-defined. The OpenCL API
includes functions to query capabilities of a device(s) and determine if
this capability is supported.
</p>
</li>
<li>
<p>
<strong>Built-in kernels</strong> are tied
to particular device and are not built at runtime from source code in a
program object. The common use of built in kernels is to expose
fixed-function hardware or firmware associated with a particular OpenCL
device or custom device. The semantics of a built-in kernel may be
defined outside of OpenCL and hence are implementation defined.
</p>
</li>
</ul></div>
<div class="paragraph"><p>All three types of kernels are manipulated through the OpenCL command
queues and must conform to the synchronization points defined in the
OpenCL execution model.</p></div>
</div>
</div>
<div class="sect2">
<h3 id="_memory_model">3.3. Memory Model</h3>
<div class="paragraph"><p>The OpenCL memory model describes the structure, contents, and behavior
of the memory exposed by an OpenCL platform as an OpenCL program runs.
The model allows a programmer to reason about values in memory as the
host program and multiple kernel-instances execute.
<br>
<br>
An OpenCL program defines a context that includes a host, one or more
devices, command-queues, and memory exposed within the context.
Consider the units of execution involved with such a program. The host
program runs as one or more host threads managed by the operating system
running on the host (the details of which are defined outside of
OpenCL). There may be multiple devices in a single context which all
have access to memory objects defined by OpenCL. On a single device,
multiple work-groups may execute in parallel with potentially
overlapping updates to memory. Finally, within a single work-group,
multiple work-items concurrently execute, once again with potentially
overlapping updates to memory.
<br>
<br>
The memory model must precisely define how the values in memory as seen
from each of these units of execution interact so a programmer can
reason about the correctness of OpenCL programs. We define the memory
model in four parts.</p></div>
<div class="ulist"><ul>
<li>
<p>
Memory regions: The
distinct memories visible to the host and the devices that share a
context.
</p>
</li>
<li>
<p>
Memory objects: The
objects defined by the OpenCL API and their management by the host and
devices.
</p>
</li>
<li>
<p>
Shared Virtual Memory: A
virtual address space exposed to both the host and the devices within a
context.
</p>
</li>
<li>
<p>
Consistency Model: Rules
that define which values are observed when multiple units of execution
load data from memory plus the atomic/fence operations that constrain
the order of memory operations and define synchronization relationships.
</p>
</li>
</ul></div>
<div class="sect3">
<h4 id="_memory_model_fundamental_memory_regions">3.3.1. Memory Model: Fundamental Memory Regions</h4>
<div class="paragraph"><p>Memory in OpenCL is divided into two parts.</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Host Memory:</strong> The memory
directly available to the host. The detailed behavior of host memory is
defined outside of OpenCL. Memory objects move between the Host and the
devices through functions within the OpenCL API or through a shared
virtual memory interface.
</p>
</li>
<li>
<p>
<strong>Device Memory:</strong> Memory
directly available to kernels executing on OpenCL devices.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Device memory consists of four named address spaces or <em>memory regions</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Global Memory:</strong> This
memory region permits read/write access to all work-items in all
work-groups running on any device within a context. Work-items can read
from or write to any element of a memory object. Reads and writes to
global memory may be cached depending on the capabilities of the device.
</p>
</li>
<li>
<p>
<strong>Constant Memory</strong>: A
region of global memory that remains constant during the execution of a
kernel-instance. The host allocates and initializes memory objects
placed into constant memory.
</p>
</li>
<li>
<p>
<strong>Local Memory</strong>: A memory
region local to a work-group. This memory region can be used to allocate
variables that are shared by all work-items in that work-group.
</p>
</li>
<li>
<p>
<strong>Private Memory</strong>: A region
of memory private to a work-item. Variables defined in one work-items
private memory are not visible to another work-item.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The memory regions and their relationship to the OpenCL Platform model
are summarized in figure 3-4. Local and private memories are always
associated with a particular device. The global and constant memories,
however, are shared between all devices within a given context. An
OpenCL device may include a cache to support efficient access to these
shared memories
<br>
<br>
To understand memory in OpenCL, it is important to appreciate the
relationships between these named address spaces.   The four named
address spaces available to a device are disjoint meaning they do not
overlap.   This is a logical relationship, however, and an
implementation may choose to let these disjoint named address spaces
share physical memory.
<br>
<br>
Programmers often need functions callable from kernels where the
pointers manipulated by those functions can point to multiple named
address spaces. This saves a programmer from the error-prone and
wasteful practice of creating multiple copies of functions; one for each
named address space. Therefore the global, local and private address
spaces belong to a single <em>generic address space</em>. This is closely
modeled after the concept of a generic address space used in the
embedded C standard (ISO/IEC 9899:1999). Since they all belong to a
single generic address space, the following properties are supported for
pointers to named address spaces in device memory:</p></div>
<div class="ulist"><ul>
<li>
<p>
A pointer to the generic
address space can be cast to a pointer to a global, local or private
address space
</p>
</li>
<li>
<p>
A pointer to a global,
local or private address space can be cast to a pointer to the generic
address space.
</p>
</li>
<li>
<p>
A pointer to a global,
local or private address space can be implicitly converted to a pointer
to the generic address space, but the converse is not allowed.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The constant address space is disjoint from the generic address space.
<br>
<br>
The addresses of memory associated with memory objects in Global memory
are not preserved between kernel instances, between a device and the
host, and between devices. In this regard global memory acts as a global
pool of memory objects rather than an address space. This restriction is
relaxed when shared virtual memory (SVM) is used.
<br>
<br>
SVM causes addresses to be meaningful between the host and all of the
devices within a context hence supporting the use of pointer based data
structures in OpenCL kernels. It logically extends a portion of the
global memory into the host address space giving work-items access to
the host address space. On platforms with hardware support for a shared
address space between the host and one or more devices, SVM may also
provide a more efficient way to share data between devices and the host.
Details about SVM are presented in section 3.3.3.</p></div>
<div class="paragraph"><p><span class="image">
<img src="opencl22-API_files/image008.jpg" alt="image">
</span></p></div>
<div class="paragraph"><p><strong>Figure 3-4: The named address spaces exposed in an OpenCL Platform.
Global and Constant memories are shared between the one or more devices
within a context, while local and private memories are associated with a
single device. Each device may include an optional cache to support
efficient access to their view of the global and constant address
spaces.</strong></p></div>
<div class="paragraph"><p>A programmer may use the features of the memory consistency model
(section 3.3.4) to manage safe access to global memory from multiple
work-items potentially running on one or more devices. In addition, when
using shared virtual memory (SVM), the memory consistency model may also
be used to ensure that host threads safely access memory locations in
the shared memory region.</p></div>
</div>
<div class="sect3">
<h4 id="_memory_model_memory_objects">3.3.2. Memory Model: Memory Objects</h4>
<div class="paragraph"><p>The contents of global memory are <em>memory objects</em>. A memory object is
a handle to a reference counted region of global memory. Memory objects
use the OpenCL type <em>cl_mem</em> and fall into three distinct classes.</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Buffer</strong>: A memory object
stored as a block of contiguous memory and used as a general purpose
object to hold data used in an OpenCL program. The types of the values
within a buffer may be any of the built in types (such as int, float),
vector types, or user-defined structures. The buffer can be
manipulated through pointers much as one would with any block of memory
in C.
</p>
</li>
<li>
<p>
<strong>Image</strong>: An image memory
object holds one, two or three dimensional images. The formats are
based on the standard image formats used in graphics applications. An
image is an opaque data structure managed by functions defined in the
OpenCL API. To optimize the manipulation of images stored in the
texture memories found in many GPUs, OpenCL kernels have traditionally
been disallowed from both reading and writing a single image. In OpenCL
2.0, however, we have relaxed this restriction by providing
synchronization and fence operations that let programmers properly
synchronize their code to safely allow a kernel to read and write a
single image.
</p>
</li>
<li>
<p>
<strong>Pipe</strong>: The <em>pipe</em> memory
object conceptually is an ordered sequence of data items. A pipe has
two endpoints: a write endpoint into which data items are inserted, and
a read endpoint from which data items are removed. At any one time,
only one kernel instance may write into a pipe, and only one kernel
instance may read from a pipe. To support the producer consumer design
pattern, one kernel instance connects to the write endpoint (the
producer) while another kernel instance connects to the reading endpoint
(the consumer).
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Memory objects are allocated by host APIs. The host program can provide
the runtime with a pointer to a block of continuous memory to hold the
memory object when the object is created (CL_MEM_USE_HOST_PTR).
Alternatively, the physical memory can be managed by the OpenCL runtime
and not be directly accessible to the host program.
<br>
<br>
Allocation and access to memory objects within the different memory
regions varies between the host and work-items running on a device.
This is summarized in table 3.1 which__describes whether the kernel or
the host can allocate from a memory region, the type of allocation
(static at compile time vs. dynamic at runtime) and the type of access
allowed (i.e. whether the kernel or the host can read and/or write to a
memory region).</p></div>
<div style="page-break-after:always"></div>
<table class="tableblock frame-all grid-all"
style="
width:80%;
">
<col style="width:20%;">
<col style="width:20%;">
<col style="width:20%;">
<col style="width:20%;">
<col style="width:20%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Global</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Constant</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Local</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Private</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" rowspan="2" ><p class="tableblock">Host</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Dynamic Allocation</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Dynamic Allocation</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Dynamic Allocation</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">No Allocation</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Read/Write access to buffers and images but not pipes</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Read/Write access</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">No access</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">No access</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" rowspan="2" ><p class="tableblock">Kernel</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Static Allocation for program scope variables</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Static Allocation</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Static Allocation. Dynamic allocation for child kernel</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Static Allocation</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Read/Write access</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Read-only access</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Read/Write access. No access to child&#8217;s local memory.</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Read/Write access</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>Table 3 1: The different memory regions in
OpenCL and how memory objects are allocated and accessed by the host and
by an executing instance of a kernel. For the case of kernels, we
distinguish between the behavior of local memory with respect to a
kernel (self) and its child kernels.</strong></p></div>
<div class="paragraph"><p>Once allocated, a memory object is made available to kernel-instances
running on one or more devices. In addition to shared virtual memory
(section 3.3.3) there are three basic ways to manage the contents of
buffers between the host and devices.</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Read/Write/Fill
commands</strong>: The data associated with a memory object is explicitly read
and written between the host and global memory regions using commands
enqueued to an OpenCL command queue.
</p>
</li>
<li>
<p>
<strong>Map/Unmap commands</strong>: Data
from the memory object is mapped into a contiguous block of memory
accessed through a host accessible pointer. The host program enqueues a
<em>map</em> command on block of a memory object before it can be safely
manipulated by the host program. When the host program is finished
working with the block of memory, the host program enqueues an <em>unmap</em>
command to allow a kernel-instance to safely read and/or write the
buffer.**
</p>
</li>
<li>
<p>
<strong>Copy commands:</strong> The data
associated with a memory object is copied between two buffers, each of
which may reside either on the host or on the device.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In both cases, the commands to transfer data between devices and the
host can be blocking or non-blocking operations. The OpenCL function
call for a blocking memory transfer returns once the associated memory
resources on the host can be safely reused. For a non-blocking memory
transfer, the OpenCL function call returns as soon as the command is
enqueued.
<br>
<br>
Memory objects are bound to a context and hence can appear in multiple
kernel-instances running on more than one physical device. The OpenCL
platform must support a large range of hardware platforms including
systems that do not support a single shared address space in hardware;
hence the ways memory objects can be shared between kernel-instances is
restricted. The basic principle is that multiple read operations on
memory objects from multiple kernel-instances that overlap in time are
allowed, but mixing overlapping reads and writes into the same memory
objects from different kernel instances is only allowed when fine
grained synchronization is used with shared virtual memory (see section
3.3.3).
<br>
<br>
When global memory is manipulated by multiple kernel-instances running
on multiple devices, the OpenCL runtime system must manage the
association of memory objects with a given device. In most cases the
OpenCL runtime will implicitly associate a memory object with a device.
A kernel instance is naturally associated with the command queue to
which the kernel was submitted. Since a command-queue can only access a
single device, the queue uniquely defines which device is involved with
any given kernel-instance; hence defining a clear association between
memory objects, kernel-instances and devices. Programmers may
anticipate these associations in their programs and explicitly manage
association of memory objects with devices in order to improve
performance.</p></div>
</div>
<div class="sect3">
<h4 id="_memory_model_shared_virtual_memory">3.3.3. Memory Model: Shared Virtual Memory</h4>
<div class="paragraph"><p>OpenCL extends the global memory region into the host memory region
through a shared virtual memory (SVM) mechanism. There are three types
of SVM in OpenCL</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>Coarse-Grained buffer
SVM</strong>: Sharing occurs at the granularity of regions of OpenCL buffer
memory objects. Consistency is enforced at synchronization points and
with map/unmap commands to drive updates between the host and the
device. This form of SVM is similar to non-SVM use of memory; however,
it lets kernel-instances share pointer-based data structures (such as
linked-lists) with the host program. Program scope global variables are
treated as per-device coarse-grained SVM for addressing and sharing
purposes.
</p>
</li>
<li>
<p>
<strong>Fine-Grained buffer
SVM</strong>: Sharing occurs at the granularity of individual loads/stores into
bytes within OpenCL buffer memory objects. Loads and stores may be
cached. This means consistency is guaranteed at synchronization points.
If the optional OpenCL atomics are supported, they can be used to
provide fine-grained control of memory consistency.
</p>
</li>
<li>
<p>
<strong>Fine-Grained system SVM</strong>:
Sharing occurs at the granularity of individual loads/stores into bytes
occurring anywhere within the host memory. Loads and stores may be
cached so consistency is guaranteed at synchronization points. If the
optional OpenCL atomics are supported, they can be used to provide
fine-grained control of memory consistency.
</p>
</li>
</ul></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 1. <strong>A summary of shared virtual memory (SVM) options in OpenCL</strong></caption>
<col style="width:20%;">
<col style="width:20%;">
<col style="width:20%;">
<col style="width:20%;">
<col style="width:20%;">
<tbody>
<tr>
<td class="tableblock halign-center valign-top" ><p class="tableblock"></p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Granularity of sharing</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Memory Allocation</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Mechanisms to enforce Consistency</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Explicit updates
between host and device</p></td>
</tr>
<tr>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Non-SVM buffers</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">OpenCL Memory objects(buffer)</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">clCreateBuffer</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Host synchronization points on the same or between
devices.</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">yes, through Map and Unmap commands.</p></td>
</tr>
<tr>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Coarse-Grained buffer SVM</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">OpenCL Memory objects (buffer)</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">clSVMAlloc</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Host synchronization points
between devices</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">yes, through Map and Unmap commands.</p></td>
</tr>
<tr>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Fine Grained buffer SVM</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Bytes within OpenCL Memory objects (buffer)</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">clSVMAlloc</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Synchronization points plus atomics (if supported)</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">No</p></td>
</tr>
<tr>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Fine-Grained system SVM</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Bytes within Host memory (system)</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Host memory allocation mechanisms (e.g. malloc)</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">Synchronization points plus atomics (if
supported)</p></td>
<td class="tableblock halign-center valign-top" ><p class="tableblock">No</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>Coarse-Grained buffer SVM is required in the core OpenCL specification.
The two finer grained approaches are optional features in OpenCL. The
various SVM mechanisms to access host memory from the work-items
associated with a kernel instance are summarized in table 3-2.</p></div>
</div>
<div class="sect3">
<h4 id="_memory_model_memory_consistency_model">3.3.4. Memory Model: Memory Consistency Model</h4>
<div class="paragraph"><p>The OpenCL memory model tells programmers what they can expect from an
OpenCL implementation; which memory operations are guaranteed to happen
in which order and which memory values each read operation will return.
The memory model tells compiler writers which restrictions they must
follow when implementing compiler optimizations; which variables they
can cache in registers and when they can move reads or writes around a
barrier or atomic operation. The memory model also tells hardware
designers about limitations on hardware optimizations; for example, when
they must flush or invalidate hardware caches.
<br>
<br>
The memory consistency model in OpenCL is based on the memory model from
the ISO C11 programming language. To help make the presentation more
precise and self-contained, we include modified paragraphs taken
verbatim from the ISO C11 international standard. When a paragraph is
taken or modified from the C11 standard, it is identified as such along
with its original location in the C11 standard.
<br>
<br>
For programmers, the most intuitive model is the <em>sequential
consistency</em> memory model. Sequential consistency interleaves the steps
executed by each of the units of execution. Each access to a memory
location sees the last assignment to that location in that
interleaving. While sequential consistency is relatively
straightforward for a programmer to reason about, implementing
sequential consistency is expensive. Therefore, OpenCL implements a
relaxed memory consistency model; i.e. it is possible to write programs
where the loads from memory violate sequential consistency. Fortunately,
if a program does not contain any races and if the program only uses
atomic operations that utilize the sequentially consistent memory order
(the default memory ordering for OpenCL), OpenCL programs appear to
execute with sequential consistency.
<br>
<br>
Programmers can to some degree control how the memory model is relaxed by choosing the memory order for synchronization operations. The precise semantics of synchronization and the memory orders are formally defined in section 3.3.6. Here, we give a high level description of how these memory orders apply to atomic operations on atomic objects shared between units of execution. OpenCL memory_order choices are based on those from the ANSI C11 standard memory model. They are specified in certain OpenCL functions through the following enumeration constants:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>memory_order_relaxed</strong>:
implies no order constraints. This memory order can be used safely to
increment counters that are concurrently incremented, but it doesnt
guarantee anything about the ordering with respect to operations to
other memory locations. It can also be used, for example, to do ticket
allocation and by expert programmers implementing lock-free algorithms.
</p>
</li>
<li>
<p>
<strong>memory_order_acquire</strong>: A
synchronization operation (fence or atomic) that has acquire semantics
"acquires" side-effects from a release operation that synchronises with
it: if an acquire synchronises with a release, the acquiring unit of
execution will see all side-effects preceding that release (and possibly
subsequent side-effects.) As part of carefully-designed protocols,
programmers can use an "acquire" to safely observe the work of another
unit of execution.
</p>
</li>
<li>
<p>
<strong>memory_order_release</strong>: A
synchronization operation (fence or atomic operation) that has release
semantics "releases" side effects to an acquire operation that
synchronises with it. All side effects that precede the release are
included in the release. As part of carefully-designed protocols,
programmers can use a "release" to make changes made in one unit of
execution visible to other units of execution.
</p>
</li>
</ul></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">In general, no acquire must <em>always</em> synchronise with any
particular release. However, synchronisation can be forced by certain
executions. See 3.3.6.2 for detailed rules for when synchronisation
must occur.</td>
</tr></table>
</div>
<div class="ulist"><ul>
<li>
<p>
<strong>memory_order_acq_rel</strong>: A
synchronization operation with acquire-release semantics has the
properties of both the acquire and release memory orders. It is
typically used to order read-modify-write operations.
</p>
</li>
<li>
<p>
<strong>memory_order_seq_cst</strong>:
The loads and stores of each unit of execution appear to execute in
program (i.e., sequenced-before) order, and the loads and stores from
different units of execution appear to be simply interleaved.
<br>
<br>
Regardless of which memory_order is specified, resolving constraints on
memory operations across a heterogeneous platform adds considerable
overhead to the execution of a program. An OpenCL platform may be able
to optimize certain operations that depend on the features of the memory
consistency model by restricting the scope of the memory operations.
Distinct memory scopes are defined by the values of the memory_scope
enumeration constant:
</p>
</li>
<li>
<p>
<strong>memory_scope_work_item</strong>:
memory-ordering constraints only apply within the
work-item.<span class="footnote"><br>[This value for memory_scope can only be used with atomic_work_item_fence with flags set
to LCK_IMAGE_MEM_FENCE.]<br></span>.
</p>
</li>
<li>
<p>
<strong>memory_scope_sub_group</strong>:memory-ordering constraints only apply within
the sub-group.
</p>
</li>
<li>
<p>
<strong>memory_scope_work_group</strong>:
memory-ordering constraints only apply to work-items executing within a
single work-group.
</p>
</li>
<li>
<p>
<strong>memory_scope_device:</strong>
memory-ordering constraints only apply to work-items executing on a
single device
</p>
</li>
<li>
<p>
<strong>memory_scope_all_svm_devices</strong>: memory-ordering constraints apply to
work-items executing across multiple devices and (when using SVM) the
host. A release performed with <strong>memory_scope_all_svm_devices</strong> to a
buffer that does not have the CL_MEM_SVM_ATOMICS flag set will commit to
at least <strong>memory_scope_device</strong> visibility, with full synchronization of
the buffer at a queue synchronization point (e.g. an OpenCL event).
<br>
<br>
These memory scopes define a hierarchy of visibilities when analyzing
the ordering constraints of memory operations. For example if a
programmer knows that a sequence of memory operations will only be
associated with a collection of work-items from a single work-group (and
hence will run on a single device), the implementation is spared the
overhead of managing the memory orders across other devices within the
same context. This can substantially reduce overhead in a program. All
memory scopes are valid when used on global memory or local memory. For
local memory, all visibility is constrained to within a given work-group
and scopes wider than <strong>memory_scope_work_group</strong> carry no additional
meaning.
<br>
<br>
In the following subsections (leading up to section 3.4), we will
explain the synchronization constructs and detailed rules needed to use
OpenCLs relaxed memory models. It is important to appreciate,
however, that many programs do not benefit from relaxed memory models.
Even expert programmers have a difficult time using atomics and fences
to write correct programs with relaxed memory models. A large number of
OpenCL programs can be written using a simplified memory model. This is
accomplished by following these guidelines.
</p>
</li>
<li>
<p>
Write programs that manage
safe sharing of global memory objects through the synchronization points
defined by the command queues.
</p>
</li>
<li>
<p>
Restrict low level
synchronization inside work-groups to the work-group functions such as
barrier.
</p>
</li>
<li>
<p>
If you want sequential
consistency behavior with system allocations or fine-grain SVM buffers
with atomics support, use only memory_order_seq_cst operations with the
scope memory_scope_all_svm_devices.
</p>
</li>
<li>
<p>
If you want sequential
consistency behavior when not using system allocations or fine-grain SVM
buffers with atomics support, use only memory_order_seq_cst operations
with the scope memory_scope_device or memory_scope_all_svm_devices.
</p>
</li>
<li>
<p>
Ensure your program has no
races.
<br>
<br>
If these guidelines are followed in your OpenCL programs, you can skip
the detailed rules behind the relaxed memory models and go directly to
section 3.4.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_memory_model_overview_of_atomic_and_fence_operations">3.3.5. Memory Model: Overview of atomic and fence operations</h4>
<div class="paragraph"><p>The OpenCL 2.0 specification defines a number of <em>synchronization
operations</em> that are used to define memory order constraints in a
program. They play a special role in controlling how memory operations
in one unit of execution (such as work-items or, when using SVM a host
thread) are made visible to another. There are two types of
synchronization operations in OpenCL; <em>atomic operations</em> and <em>fences</em>.
<br>
<br>
Atomic operations are indivisible. They either occur completely or not
at all. These operations are used to order memory operations between
units of execution and hence they are parameterized with the
memory_order and memory_scope parameters defined by the OpenCL memory
consistency model. The atomic operations for OpenCL kernel languages
are similar to the corresponding operations defined
by the C11 standard.
<br>
<br>
The OpenCL 2.0 atomic operations apply to variables of an atomic type (a
subset of those in the C11 standard) including atomic versions of the
int, uint, long, ulong, float, double, half, intptr_t, uintptr_t,
size_t, and ptrdiff_t types. However, support for some of these atomic
types depends on support for the corresponding regular types.
<br>
<br>
An atomic operation on one or more memory locations is either an acquire
operation, a release operation, or both an acquire and release
operation. An atomic operation without an associated memory location is
a fence and can be either an acquire fence, a release fence, or both an
acquire and release fence. In addition, there are relaxed atomic
operations, which do not have synchronization properties, and atomic
read-modify-write operations, which have special characteristics. [C11
standard, Section 5.1.2.4, paragraph 5, modified]
<br>
<br>
The orders memory_order_acquire (used for reads), memory_order_release
(used for writes), and memory_order_acq_rel (used for read-modify-write
operations) are used for simple communication between units of execution
using shared variables. Informally, executing a memory_order_release on
an atomic object A makes all previous side effects visible to any unit
of execution that later executes a memory_order_acquire on A. The orders
memory_order_acquire, memory_order_release, and memory_order_acq_rel do
not provide sequential consistency for race-free programs because they
will not ensure that atomic stores followed by atomic loads become
visible to other threads in that order.
<br>
<br>
The fence operation is atomic_work_item_fence, which includes a
memory_order argument as well as the memory_scope and cl_mem_fence_flags
arguments. Depending on the memory_order argument, this operation:</p></div>
<div class="ulist"><ul>
<li>
<p>
has no effects, if
memory_order_relaxed;
</p>
</li>
<li>
<p>
is an acquire fence, if
memory_order_acquire;
</p>
</li>
<li>
<p>
is a release fence, if
memory_order_release;
</p>
</li>
<li>
<p>
is both an acquire fence
and a release fence, if memory_order_acq_rel;
</p>
</li>
<li>
<p>
is a
sequentially-consistent fence with both acquire and release semantics,
if memory_order_seq_cst.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>If specified, the cl_mem_fence_flags argument must be
CLK_IMAGE_MEM_FENCE, CLK_GLOBAL_MEM_FENCE, CLK_LOCAL_MEM_FENCE, or
CLK_GLOBAL_MEM_FENCE | CLK_LOCAL_MEM_FENCE.
<br>
<br>
The atomic_work_item_fence(CLK_IMAGE_MEM_FENCE) built-in function must
be
<br>
<br>
used to make sure that sampler-less writes are visible to later reads by
the same work-item. Without use of the atomic_work_item_fence function,
write-read coherence on image objects is not guaranteed: if a work-item
reads from an image to which it has previously written without an
intervening atomic_work_item_fence, it is not guaranteed that those
previous writes are visible to the work-item.
<br>
<br>
The synchronization operations in OpenCL can be parameterized by a
memory_scope. Memory scopes control the extent that an atomic operation
or fence is visible with respect to the memory model. These memory
scopes may be used when performing atomic operations and fences on
global memory and local memory. When used on global memory visibility
is bounded by the capabilities of that memory. When used on a
fine-grained non-atomic SVM buffer, a coarse-grained SVM buffer, or a
non-SVM buffer, operations parameterized with
memory_scope_all_svm_devices will behave as if they were parameterized
with memory_scope_device. When used on local memory, visibility is
bounded by the work-group and, as a result, memory_scope with wider
visibility than memory_scope_work_group will be reduced to
memory_scope_work_group.</p></div>
<div class="paragraph"><p>Two actions <strong>A</strong> and <strong>B</strong> are defined to have an inclusive scope if they
have the same scope <strong>P</strong> such that:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>P</strong> is memory_scope_sub_group and <strong>A</strong> and <strong>B</strong> are executed by
work-items within the same sub-group.
</p>
</li>
<li>
<p>
<strong>P</strong> is memory_scope_work_group and <strong>A</strong> and <strong>B</strong> are executed by
work-items within the same work-group.
</p>
</li>
<li>
<p>
<strong>P</strong> is memory_scope_device and <strong>A</strong> and <strong>B</strong> are executed by
work-items on the same device when <strong>A</strong> and <strong>B</strong> apply to an SVM
allocation or <strong>A</strong> and <strong>B</strong> are executed by work-items in the same kernel
or one of its children when <strong>A</strong> and <strong>B</strong> apply to a cl_mem buffer.
</p>
</li>
<li>
<p>
<strong>P</strong> is memory_scope_all_svm_devices if <strong>A</strong> and <strong>B</strong> are
executed by host threads or by work-items on one or more devices that
can share SVM memory with each other and the host process.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_memory_model_memory_ordering_rules">3.3.6. Memory Model: Memory Ordering Rules</h4>
<div class="paragraph"><p>Fundamentally, the issue in a memory model is to understand the
orderings in time of modifications to objects in memory. Modifying an
object or calling a function that modifies an object are side effects,
i.e. changes in the state of the execution environment. Evaluation of an
expression in general includes both value computations and initiation of
side effects. Value computation for an lvalue expression includes
determining the identity of the designated object. [C11 standard,
Section 5.1.2.3, paragraph 2, modified]
<br>
<br>
We assume that the OpenCL kernel language and host
programming languages have a sequenced-before relation between the
evaluations executed by a single unit of execution. This
sequenced-before relation is an asymmetric, transitive, pair-wise
relation between those evaluations, which induces a partial order among
them. Given any two evaluations <strong>A</strong> and <strong>B</strong>, if <strong>A</strong> is sequenced-before
<strong>B</strong>, then the execution of <strong>A</strong> shall precede the execution of <strong>B</strong>.
(Conversely, if <strong>A</strong> is sequenced-before <strong>B</strong>, then <strong>B</strong> is sequenced-after
<strong>A</strong>.) If <strong>A</strong> is not sequenced-before or sequenced-after <strong>B</strong>, then <strong>A</strong>
and <strong>B</strong> are unsequenced. Evaluations <strong>A</strong> and <strong>B</strong> are indeterminately
sequenced when <strong>A</strong> is either sequenced-before or sequenced-after <strong>B</strong>,
but it is unspecified which. [C11 standard, Section 5.1.2.3, paragraph
3, modified]
<br>
<br>
NOTE: sequenced-before is a partial order of the operations executed by
a single unit of execution (e.g. a host thread or work-item). It
generally corresponds to the source program order of those operations,
and is partial because of the undefined argument evaluation order of
OpenCLs kernel C language.
<br>
<br>
In an OpenCL kernel language, the value of an object
visible to a work-item W at a particular point is the initial value of
the object, a value stored in the object by W, or a value stored in the
object by another work-item or host thread, according to the rules
below. Depending on details of the host programming language, the value
of an object visible to a host thread may also be the value stored in
that object by another work-item or host thread. [C11 standard, Section
5.1.2.4, paragraph 2, modified]
<br>
<br>
Two expression evaluations conflict if one of them modifies a memory
location and the other one reads or modifies the same memory location. [C11 standard, Section 5.1.2.4, paragraph 4]
<br>
<br>
All modifications to a particular atomic object <strong>M</strong> occur in some
particular total order, called the modification order of <strong>M</strong>. If <strong>A</strong> and
<strong>B</strong> are modifications of an atomic object <strong>M</strong>, and <strong>A</strong> happens-before
<strong>B</strong>, then <strong>A</strong> shall precede <strong>B</strong> in the modification order of <strong>M</strong>, which
is defined below. Note that the modification order of an atomic object
<strong>M</strong> is independent of whether <strong>M</strong> is in local or global memory. [C11
standard, Section 5.1.2.4, paragraph 7, modified]
<br>
<br>
A release sequence begins with a release operation <strong>A</strong> on an atomic
object <strong>M</strong> and is the maximal contiguous sub-sequence of side effects
in the modification order of <strong>M</strong>, where the first operation is <strong>A</strong> and
every subsequent operation either is performed by the same work-item or
host thread that performed the release or is an atomic
read-modify-write operation. [C11 standard, Section 5.1.2.4, paragraph
10, modified]
<br>
<br>
OpenCLs local and global memories are disjoint. Kernels may access both
kinds of memory while host threads may only access global memory.
Furthermore, the <em>flags</em> argument of OpenCLs work_group_barrier
function specifies which memory operations the function will make
visible: these memory operations can be, for example, just the ones to
local memory, or the ones to global memory, or both. Since the
visibility of memory operations can be specified for local memory
separately from global memory, we define two related but independent
relations, <em>global-synchronizes-with</em> and <em>local-synchronizes-with</em>.
Certain operations on global memory may global-synchronize-with other
operations performed by another work-item or host thread. An example is
a release atomic operation in one work- item that
global-synchronizes-with an acquire atomic operation in a second
work-item. Similarly, certain atomic operations on local objects in
kernels can local-synchronize- with other atomic operations on those
local objects. [C11 standard, Section 5.1.2.4, paragraph 11, modified]
<br>
<br>
We define two separate happens-before relations: global-happens-before
and local-happens-before.</p></div>
<div class="paragraph"><p>A global memory action <strong>A</strong> global-happens-before a global memory action
*B*__if</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>A</strong> is sequenced before
<strong>B</strong>, or
</p>
</li>
<li>
<p>
<strong>A</strong>
global-synchronizes-with <strong>B</strong>, or
</p>
</li>
<li>
<p>
For some global memory
action <strong>C</strong>, <strong>A</strong> global-happens-before <strong>C</strong> and <strong>C</strong> global-happens-before
<strong>B</strong>.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A local memory action <strong>A</strong> local-happens-before a local memory action
*B*__if</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>A</strong> is sequenced before
<strong>B</strong>, or
</p>
</li>
<li>
<p>
<strong>A</strong>
local-synchronizes-with <strong>B</strong>, or
</p>
</li>
<li>
<p>
For some local memory
action <strong>C</strong><strong>A</strong> local-happens-before <strong>C</strong> and <strong>C</strong> local-happens-before
<strong>B</strong>.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>An OpenCL implementation shall ensure that no program execution
demonstrates a cycle in either the local-happens-before relation or
the global-happens-before relation.
<br>
<br>
NOTE: The global- and local-happens-before relations are critical to
defining what values are read and when data races occur. The
global-happens-before relation, for example, defines what global memory
operations definitely happen before what other global memory operations.
If an operation <strong>A</strong> global-happens-before operation <strong>B</strong> then <strong>A</strong> must
occur before <strong>B</strong>; in particular, any write done by <strong>A</strong> will be visible
to <strong>B</strong>. The local-happens-before relation has similar properties for
local memory. Programmers can use the local- and global-happens-before
relations to reason about the order of program actions.
<br>
<br>
A visible side effect <strong>A</strong> on a global object <strong>M</strong> with respect to a value
computation <strong>B</strong> of <strong>M</strong> satisfies the conditions:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>A</strong> global-happens-before
<strong>B</strong>, and
</p>
</li>
<li>
<p>
there is no other side
effect <strong>X</strong> to <strong>M</strong> such that <strong>A</strong> global-happens-before <strong>X</strong> and <strong>X</strong>
global-happens-before <strong>B</strong>.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>We define visible side effects for local objects <strong>M</strong> similarly. The
value of a non-atomic scalar object <strong>M</strong>, as determined by evaluation
<strong>B</strong>, shall be the value stored by the visible side effect <strong>A</strong>. [C11
standard, Section 5.1.2.4, paragraph 19, modified]
<br>
<br>
The execution of a program contains a data race if it contains two
conflicting actions A and B in different units of execution, and</p></div>
<div class="ulist"><ul>
<li>
<p>
(1) at least one of <strong>A</strong> or
<strong>B</strong> is not atomic, or <strong>A</strong> and <strong>B</strong> do not have inclusive memory scope,
and
</p>
</li>
<li>
<p>
(2) the actions are global
actions unordered by the global-happens-before relation or are local
actions unordered by the local-happens-before relation.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Any such data race results in undefined behavior. [C11 standard, Section
5.1.2.4, paragraph 25, modified]
<br>
<br>
We also define the visible sequence of side effects on local and global
atomic objects. The remaining paragraphs of this subsection define this
sequence for a global atomic object <strong>M</strong>; the visible sequence of side
effects for a local atomic object is defined similarly by using the
local-happens-before relation.
<br>
<br>
The visible sequence of side effects on a global atomic object <strong>M</strong>, with
respect to a value computation <strong>B</strong> of <strong>M</strong>, is a maximal contiguous
sub-sequence of side effects in the modification order of <strong>M</strong>, where the
first side effect is visible with respect to <strong>B</strong>, and for every side
effect, it is not the case that <strong>B</strong> global-happens-before it. The value
of*M*, as determined by evaluation <strong>B</strong>, shall be the value stored by
some operation in the visible sequence of <strong>M</strong> with respect to <strong>B</strong>. [C11
standard, Section 5.1.2.4, paragraph 22, modified]
<br>
<br>
If an operation <strong>A</strong> that modifies an atomic object <strong>M</strong> global-happens
before an operation <strong>B</strong> that modifies <strong>M</strong>, then <strong>A</strong> shall be earlier
than <strong>B</strong> in the modification order of <strong>M</strong>. This requirement is known as
write-write coherence.
<br>
<br>
If a value computation <strong>A</strong> of an atomic object <strong>M</strong> global-happens-before
a value computation <strong>B</strong> of <strong>M</strong>, and <strong>A</strong> takes its value from a side
effect <strong>X</strong> on <strong>M</strong>, then the value computed by <strong>B</strong> shall either equal the
value stored by <strong>X</strong>, or be the value stored by a side effect <strong>Y</strong> on <strong>M</strong>,
where <strong>Y</strong> follows <strong>X</strong> in the modification order of <strong>M</strong>. This requirement
is known as read-read coherence. [C11 standard, Section 5.1.2.4,
paragraph 22, modified]
<br>
<br>
If a value computation <strong>A</strong> of an atomic object <strong>M</strong> global-happens-before
an operation <strong>B</strong> on <strong>M</strong>, then <strong>A</strong> shall take its value from a side
effect <strong>X</strong> on <strong>M</strong>, where <strong>X</strong> precedes <strong>B</strong> in the modification order of
<strong>M</strong>. This requirement is known as read-write coherence.
<br>
<br>
If a side effect <strong>X</strong> on an atomic object <strong>M</strong> global-happens-before a
value computation <strong>B</strong> of <strong>M</strong>, then the evaluation <strong>B</strong> shall take its
value from <strong>X</strong> or from a side effect <strong>Y</strong> that follows <strong>X*in the
modification order of *M</strong>. This requirement is known as write-read
coherence.</p></div>
<div class="sect4">
<h5 id="_memory_ordering_rules_atomic_operations">Memory Ordering Rules: Atomic Operations</h5>
<div class="paragraph"><p>This and following sections describe how different program actions in
kernel C code and the host program contribute to the local- and
global-happens-before relations. This section discusses ordering rules
for OpenCL 2.0s atomic operations.</p></div>
<div class="paragraph"><p>Section 3.2.3 defined the enumerated type memory_order.</p></div>
<div class="ulist"><ul>
<li>
<p>
For memory_order_relaxed,
no operation orders memory.
</p>
</li>
<li>
<p>
For memory_order_release,
memory_order_acq_rel, and memory_order_seq_cst, a store operation
performs a release operation on the affected memory location.
</p>
</li>
<li>
<p>
For memory_order_acquire,
memory_order_acq_rel, and memory_order_seq_cst, a load operation
performs an acquire operation on the affected memory location. [C11
standard, Section 7.17.3, paragraphs 2-4, modified]
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Certain built-in functions synchronize with other built-in functions
performed by another unit of execution. This is true for pairs of
release and acquire operations under specific circumstances. An atomic
operation <strong>A</strong> that performs a release operation on a global object <strong>M</strong>
global-synchronizes-with an atomic operation <strong>B</strong> that performs an
acquire operation on <strong>M</strong> and reads a value written by any side effect in
the release sequence headed by <strong>A</strong>. A similar rule holds for atomic
operations on objects in local memory: an atomic operation <strong>A</strong> that
performs a release operation on a local object <strong>M</strong>
local-synchronizes-with an atomic operation <strong>B</strong> that performs an acquire
operation on <strong>M</strong> and reads a value written by any side effect in the
release sequence headed by <strong>A</strong>. [C11 standard, Section 5.1.2.4,
paragraph 11, modified]
<br>
<br>
NOTE: Atomic operations specifying memory_order_relaxed are relaxed only
with respect to memory ordering. Implementations must still guarantee
that any given atomic access to a particular atomic object be
indivisible with respect to all other atomic accesses to that object.
<br>
<br>
There shall exist a single total order <strong>S</strong> for all memory_order_seq_cst
operations that is consistent with the modification orders for all
affected locations, as well as the appropriate global-happens-before and
local-happens-before orders for those locations, such that each
memory_order_seq operation <strong>B</strong> that loads a value from an atomic object
<strong>M</strong> in global or local memory observes one of the following values:</p></div>
<div class="ulist"><ul>
<li>
<p>
the result of the last
modification <strong>A</strong> of <strong>M</strong> that precedes <strong>B</strong> in <strong>S</strong>, if it exists, or
</p>
</li>
<li>
<p>
if <strong>A</strong> exists, the result
of some modification of <strong>M</strong> in the visible sequence of side effects
with respect to <strong>B</strong> that is not memory_order_seq_cst and that does not
happen before <strong>A</strong>, or
</p>
</li>
<li>
<p>
if <strong>A</strong> does not exist, the
result of some modification of <strong>M</strong> in the visible sequence of side
effects with respect to <strong>B</strong> that is not memory_order_seq_cst. [C11
standard, Section 7.17.3, paragraph 6, modified]
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Let X and Y be two memory_order_seq_cst operations. If X
local-synchronizes-with or global-synchronizes-with Y then X both
local-synchronizes-with Y and global-synchronizes-with Y.
<br>
<br>
If the total order <strong>S</strong> exists, the following rules hold:</p></div>
<div class="ulist"><ul>
<li>
<p>
For an atomic operation
<strong>B</strong> that reads the value of an atomic object <strong>M</strong>, if there is a
memory_order_seq_cst fence <strong>X</strong> sequenced-before <strong>B</strong>, then <strong>B</strong> observes
either the last memory_order_seq_cst modification of <strong>M</strong> preceding <strong>X</strong>
in the total order <strong>S</strong> or a later modification of <strong>M</strong> in its
modification order. [C11 standard, Section 7.17.3, paragraph 9]
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
For atomic operations <strong>A</strong>
and <strong>B</strong> on an atomic object <strong>M</strong>, where <strong>A</strong> modifies <strong>M</strong> and <strong>B</strong> takes
its value, if there is a memory_order_seq_cst fence <strong>X</strong> such that <strong>A</strong> is
sequenced-before <strong>X</strong> and <strong>B</strong> follows <strong>X</strong> in <strong>S</strong>, then <strong>B</strong> observes
either the effects of <strong>A</strong> or a later modification of <strong>M</strong> in its
modification order. [C11 standard, Section 7.17.3, paragraph 10]
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
For atomic operations <strong>A</strong>
and <strong>B</strong> on an atomic object <strong>M</strong>, where <strong>A*modifies *M</strong> and <strong>B</strong> takes its
value, if there are memory_order_seq_cst fences <strong>X</strong> and <strong>Y</strong> such that
<strong>A</strong> is sequenced-before <strong>X</strong>, <strong>Y</strong> is sequenced-before <strong>B</strong>, and <strong>X</strong>
precedes <strong>Y</strong> in <strong>S</strong>, then <strong>B</strong> observes either the effects of <strong>A</strong> or a
later modification of <strong>M</strong> in its modification order. [C11 standard,
Section 7.17.3, paragraph 11]
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
For atomic operations <strong>A</strong>
and <strong>B</strong> on an atomic object <strong>M</strong>, if there are memory_order_seq_cst
fences <strong>X</strong> and <strong>Y</strong> such that <strong>A</strong> is sequenced-before <strong>X</strong>, <strong>Y</strong> is
sequenced-before <strong>B</strong>, and <strong>X</strong> precedes <strong>Y</strong> in <strong>S</strong>, then <strong>B</strong> occurs later
than <strong>A</strong> in the modification order of <strong>M</strong>.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">memory_order_seq_cst ensures sequential consistency only for a
program that is (1) free of data races, and (2) exclusively uses
memory_order_seq_cst synchronization operations. Any use of weaker
ordering will invalidate this guarantee unless extreme care is used. In
particular, memory_order_seq_cst fences ensure a total order only for
the fences themselves. Fences cannot, in general, be used to restore
sequential consistency for atomic operations with weaker ordering
specifications.
<br>
<br>
Atomic read-modify-write operations should always read the last value
(in the modification order) stored before the write associated with the
read-modify-write operation. [C11 standard, Section 7.17.3, paragraph
12]</td>
</tr></table>
</div>
<div class="paragraph"><p><span class="underline">Implementations should ensure that no "out-of-thin-air" values are computed that circularly depend on their own computation.</span></p></div>
<div class="paragraph"><p>Note: Under the rules described above, and independent to the previously
footnoted C++ issue, it is known that <em>x == y == 42</em> is a valid final
state in the following problematic example:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>global atomic_int x = ATOMIC_VAR_INIT(0);
local atomic_int y = ATOMIC_VAR_INIT(0);
unit_of_execution_1:
... [execution not reading or writing x or y, leading up to:]
int t = atomic_load_explicit(&amp;y, memory_order_acquire);
atomic_store_explicit(&amp;x, t, memory_order_release);
unit_of_execution_2:
... [execution not reading or writing x or y, leading up to:]
int t = atomic_load_explicit(&amp;x, memory_order_acquire);
atomic_store_explicit(&amp;y, t,
memory_order_release);link:#_msocom_6[[BA6]] </pre>
</div></div>
<div class="paragraph"><p>This is not useful behavior and implementations should not exploit this
phenomenon. It should be expected that in the future this may be
disallowed by appropriate updates to the memory model description by the
OpenCL committee.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Implementations should make atomic stores visible to atomic loads within
a reasonable amount of time. [C11 standard, Section 7.17.3, paragraph
16]</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>As long as the following conditions are met, a host program sharing SVM
memory with a kernel executing on one or more OpenCL devices may use
atomic and synchronization operations to ensure that its assignments,
and those of the kernel, are visible to each other:</p></div>
<div class="olist arabic"><ol class="arabic">
<li>
<p>
Either fine-grained buffer or fine-grained system SVM must be
used to share memory. While coarse-grained buffer SVM allocations may
support atomic operations, visibility on these allocations is not
guaranteed except at map and unmap operations.
</p>
</li>
<li>
<p>
The optional OpenCL 2.0 SVM atomic-controlled visibility
specified by provision of the CL_MEM_SVM_ATOMICS flag must be supported
by the device and the flag provided to the SVM buffer on allocation.
</p>
</li>
<li>
<p>
The host atomic and synchronization operations must be
compatible with those of an OpenCL kernel language. This
requires that the size and representation of the data types that the
host atomic operations act on be consistent with the OpenCL kernel language atomic
types.
</p>
</li>
</ol></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>If these conditions are met, the host operations will apply at
all_svm_devices scope.</p></div>
</div>
<div class="sect4">
<h5 id="_memory_ordering_rules_fence_operations">Memory Ordering Rules: Fence Operations</h5>
<div class="paragraph"><p>This section describes how the OpenCL 2.0 fence operations contribute to
the local- and global-happens-before relations.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Earlier, we introduced synchronization primitives called fences. Fences
can utilize the acquire memory_order, release memory_order, or both. A
fence with acquire semantics is called an acquire fence; a fence with
release semantics is called a release fence.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A global release fence <strong>A</strong> global-synchronizes-with a global acquire
fence <strong>B</strong> if there exist atomic operations <strong>X</strong> and <strong>Y</strong>, both operating
on some global atomic object <strong>M</strong>, such that <strong>A</strong> is sequenced-before <strong>X</strong>,
<strong>X</strong> modifies <strong>M</strong>, <strong>Y</strong> is sequenced-before <strong>B</strong>, <strong>Y</strong> reads the value
written by <strong>X</strong> or a value written by any side effect in the hypothetical
release sequence <strong>X</strong> would head if it were a release operation, and that
the scopes of <strong>A</strong>, <strong>B</strong> are inclusive. [C11 standard, Section 7.17.4,
paragraph 2, modified.]</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A global release fence <strong>A</strong> global-synchronizes-with an atomic operation
<strong>B</strong> that performs an acquire operation on a global atomic object <strong>M</strong> if
there exists an atomic operation <strong>X</strong> such that <strong>A</strong> is sequenced-before
<strong>X</strong>, <strong>X</strong> modifies <strong>M</strong>, <strong>B</strong> reads the value written by <strong>X</strong> or a value
written by any side effect in the hypothetical release sequence <strong>X</strong>
would head if it were a release operation, and the scopes of <strong>A</strong> and <strong>B</strong>
are inclusive. [C11 standard, Section 7.17.4, paragraph 3, modified.]</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>An atomic operation <strong>A</strong> that is a release operation on a global atomic
object <strong>M</strong> global-synchronizes-with a global acquire fence <strong>B</strong> if there
exists some atomic operation <strong>X</strong> on <strong>M</strong> such that <strong>X</strong> is
sequenced-before <strong>B</strong> and reads the value written by <strong>A</strong> or a value
written by any side effect in the release sequence headed by <strong>A</strong>, and
the scopes of <strong>A</strong> and <strong>B</strong> are inclusive. [C11 standard, Section 7.17.4,
paragraph 4, modified.]</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A local release fence <strong>A</strong> local-synchronizes-with a local acquire fence
<strong>B</strong> if there exist atomic operations <strong>X</strong> and <strong>Y</strong>, both operating on some
local atomic object <strong>M</strong>, such that <strong>A</strong> is sequenced-before <strong>X</strong>, <strong>X</strong>
modifies <strong>M</strong>, <strong>Y</strong> is sequenced-before <strong>B</strong>, and <strong>Y</strong> reads the value
written by <strong>X</strong> or a value written by any side effect in the hypothetical
release sequence <strong>X</strong> would head if it were a</p></div>
<div class="paragraph"><p>release operation, and the scopes of <strong>A</strong> and <strong>B</strong> are inclusive. [C11
standard, Section 7.17.4, paragraph 2, modified.]</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A local release fence <strong>A</strong> local-synchronizes-with an atomic operation
<strong>B</strong> that performs an acquire operation on a local atomic object <strong>M</strong> if
there exists an atomic operation <strong>X</strong> such that <strong>A</strong> is sequenced-before
<strong>X</strong>, <strong>X</strong> modifies <strong>M</strong>, and <strong>B</strong> reads the value written by <strong>X</strong> or a value
written by any side effect in the hypothetical release sequence <strong>X</strong>
would head if it were a release operation, and</p></div>
<div class="paragraph"><p>the scopes of <strong>A</strong> and <strong>B</strong> are inclusive. [C11 standard, Section 7.17.4,
paragraph 3, modified.]</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>An atomic operation <strong>A</strong> that is a release operation on a local atomic
object <strong>M</strong> local-synchronizes-with a local acquire fence <strong>B</strong> if there
exists some atomic operation <strong>X</strong> on <strong>M</strong> such that <strong>X</strong> is
sequenced-before <strong>B</strong> and reads the value written by <strong>A</strong> or a value
written by any side effect in the release sequence headed by <strong>A</strong>, and
the scopes of <strong>A</strong> and <strong>B</strong> are inclusive. [C11 standard, Section 7.17.4,
paragraph 4, modified.]</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Let <strong>X</strong> and <strong>Y</strong> be two work item fences that each have both the
CLK_GLOBAL_MEM_FENCE and CLK_LOCAL_MEM_FENCE flags set. <strong>X</strong>
global-synchronizes-with <strong>Y</strong> and <strong>X</strong> local synchronizes with <strong>Y</strong> if the
conditions required for <strong>X</strong> to global-synchronize with <strong>Y</strong> are met, the
conditions required for <strong>X</strong> to local-synchronize-with <strong>Y</strong> are met, or
both sets of conditions are met.</p></div>
</div>
<div class="sect4">
<h5 id="_memory_ordering_rules_work_group_functions">Memory Ordering Rules: Work-group Functions</h5>
<div class="paragraph"><p>The OpenCL kernel execution model includes collective operations across
the work-items within a single work-group. These are called work-group
functions. Besides the work-group barrier function, they include the
scan, reduction and pipe work-group functions described in the SPIR-V IL
specifications . We will first discuss the work-group barrier. The other
work-group functions are discussed afterwards.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The barrier function provides a mechanism for a kernel to synchronize
the work-items within a single work-group: informally, each work-item of
the work-group must execute the barrier before any are allowed to
proceed. It also orders memory operations to a specified combination of
one or more address spaces such as local memory or global memory, in a
similar manner to a fence.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>To precisely specify the memory ordering semantics for barrier, we need
to distinguish between a dynamic and a static instance of the call to a
barrier. A call to a barrier can appear in a loop, for example, and each
execution of the same static barrier call results in a new dynamic
instance of the barrier that will independently synchronize a
work-groups work-items.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A work-item executing a dynamic instance of a barrier results in two
operations, both fences, that are called the entry and exit fences.
These fences obey all the rules for fences specified elsewhere in this
chapter as well as the following:</p></div>
<div class="ulist"><ul>
<li>
<p>
The entry fence is a
release fence with the same flags and scope as requested for the
barrier.
</p>
</li>
<li>
<p>
The exit fence is an
acquire fence with the same flags and scope as requested for the
barrier.
</p>
</li>
<li>
<p>
For each work-item the
entry fence is sequenced before the exit fence.
</p>
</li>
<li>
<p>
If the flags have
CLK_GLOBAL_MEM_FENCE set then for each work-item the entry fence
global-synchronizes-with the exit fence of all other work-items in the
same work-group.
</p>
</li>
<li>
<p>
If the flags have
CLK_LOCAL_MEM_FENCE set then for each work-item the entry fence
local-synchronizes-with the exit fence of all other work-items in the
same work-group.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The other work-group functions include such functions as
work_group_all() and work_group_broadcast() and are described in the
kernel language and IL specifications. The use of these work-group
functions implies sequenced-before relationships between statements
within the execution of a single work-item in order to satisfy data
dependencies. For example, a work item that provides a value to a
work-group function must behave as if it generates that value before
beginning execution of that work-group function. Furthermore, the
programmer must ensure that all work items in a work group must execute
the same work-group function call site, or dynamic work-group function
instance.</p></div>
</div>
<div class="sect4">
<h5 id="_memory_ordering_rules_sub_group_functions">Memory Ordering Rules: Sub-group Functions</h5>
<div class="paragraph"><p>The OpenCL kernel execution model includes collective operations across
the work-items within a single sub-group. These are called sub-group
functions. Besides the sub-group-barrier function, they include the
scan, reduction and pipe sub-group functions described in the SPIR-V IL
specification. We will first discuss the sub-group barrier. The other
sub-group functions are discussed afterwards.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The barrier function provides a mechanism for a kernel to synchronize
the work-items within a single sub-group: informally, each work-item of
the sub-group must execute the barrier before any are allowed to
proceed. It also orders memory operations to a specified combination of
one or more address spaces such as local memory or global memory, in a
similar manner to a fence.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>To precisely specify the memory ordering semantics for barrier, we need
to distinguish between a dynamic and a static instance of the call to a
barrier. A call to a barrier can appear in a loop, for example, and each
execution of the same static barrier call results in a new dynamic
instance of the barrier that will independently synchronize a
sub-groups work-items.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A work-item executing a dynamic instance of a barrier results in two
operations, both fences, that are called the entry and exit fences.
These fences obey all the rules for fences specified elsewhere in this
chapter as well as the following:</p></div>
<div class="ulist"><ul>
<li>
<p>
The entry fence is a
release fence with the same flags and scope as requested for the
barrier.
</p>
</li>
<li>
<p>
The exit fence is an
acquire fence with the same flags and scope as requested for the
barrier.
</p>
</li>
<li>
<p>
For each work-item the
entry fence is sequenced before the exit fence.
</p>
</li>
<li>
<p>
If the flags have
CLK_GLOBAL_MEM_FENCE set then for each work-item the entry fence
global-synchronizes-with the exit fence of all other work-items in the
same sub-group.
</p>
</li>
<li>
<p>
If the flags have
CLK_LOCAL_MEM_FENCE set then for each work-item the entry fence
local-synchronizes-with the exit fence of all other work-items in the
same sub-group.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The other sub-group functions include such functions as sub_group_all()
and sub_group_broadcast() and are described in OpenCL kernel
languages specifications. The use of these sub-group functions
implies sequenced-before relationships between statements within the
execution of a single work-item in order to satisfy data dependencies.
For example, a work item that provides a value to a sub-group function
must behave as if it generates that value before beginning execution of
that sub-group function. Furthermore, the programmer must ensure that
all work items in a sub-group must execute the same sub-group function
call site, or dynamic sub-group function instance.</p></div>
</div>
<div class="sect4">
<h5 id="_memory_ordering_rules_host_side_and_device_side_commands">Memory Ordering Rules: Host-side and Device-side Commands</h5>
<div class="paragraph"><p>This section describes how the OpenCL API functions associated with
command-queues contribute to happens-before relations. There are two
types of command queues and associated API functions in OpenCL 2.0;
<em>host command-queues</em> and <em>device command-queues</em>. The interaction of
these command queues with the memory model are for the most part
equivalent. In a few cases, the rules only applies to the host
command-queue. We will indicate these special cases by specifically
denoting the host command-queue in the memory ordering rule. SVM memory
consistency in such instances is implied only with respect to
synchronizing host commands.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Memory ordering rules in this section apply to all memory objects
(buffers, images and pipes) as well as to SVM allocations where no
earlier, and more fine-grained, rules apply.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In the remainder of this section, we assume that each command <strong>C</strong>
enqueued onto a command-queue has an associated event object <strong>E</strong> that
signals its execution status, regardless of whether <strong>E*was returned to
the unit of execution that enqueued *C</strong>. We also distinguish between
the API function call that enqueues a command <strong>C</strong> and creates an event
<strong>E</strong>, the execution of <strong>C</strong>, and the completion of <strong>C</strong>(which marks the
event <strong>E</strong> as complete).</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The ordering and synchronization rules for API commands are defined as
following:</p></div>
<div class="olist arabic"><ol class="arabic">
<li>
<p>
If an API function call <strong>X</strong> enqueues a command <strong>C</strong>, then <strong>X</strong>
global-synchronizes-with <strong>C</strong>. For example, a host API function to
enqueue a kernel global-synchronizes-with the start of that
kernel-instances execution, so that memory updates sequenced-before the
enqueue kernel function call will global-happen-before any kernel reads
or writes to those same memory locations. For a device-side enqueue,
global memory updates sequenced before <strong>X</strong> happens-before <strong>C</strong> reads or
writes to those memory locations only in the case of fine-grained SVM.
</p>
</li>
<li>
<p>
If <strong>E</strong> is an event upon which a command <strong>C</strong> waits, then <strong>E</strong>
global-synchronizes-with <strong>C</strong>. In particular, if <strong>C</strong> waits on an event
<strong>E</strong> that is tracking the execution status of the command <strong>C1</strong>, then
memory operations done by <strong>C1</strong> will global-happen-before memory
operations done by <strong>C</strong>. As an example, assume we have an OpenCL program
using coarse-grain SVM sharing that enqueues a kernel to a host
command-queue to manipulate the contents of a region of a buffer that
the host thread then accesses after the kernel completes. To do this,
the host thread can call clEnqueueMapBuffer to enqueue a blocking-mode
map command to map that buffer region, specifying that the map command
must wait on an event signaling the kernels completion. When
clEnqueueMapBuffer returns, any memory operations performed by the
kernel to that buffer region will global- happen-before subsequent
memory operations made by the host thread.
</p>
</li>
<li>
<p>
If a command <strong>C</strong> has an event <strong>E</strong> that signals its completion,
then <strong>C</strong> global- synchronizes-with <strong>E</strong>.
</p>
</li>
<li>
<p>
For a command <strong>C</strong> enqueued to a host-side command queue, if <strong>C</strong>
has an event <strong>E</strong> that signals its completion, then <strong>E</strong> global-
synchronizes-with an API call <strong>X</strong> that waits on <strong>E</strong>. For example, if a
host thread or kernel-instance calls the wait-for-events function on
<strong>E</strong>(e.g. the clWaitForEvents function called from a host thread)<strong>,*then
*E</strong> global-synchronizes-with that wait-for-events function call.
</p>
</li>
<li>
<p>
If commands <strong>C</strong> and <strong>C1</strong> are enqueued in that sequence onto an
in-order command-queue, then the event (including the event implied
between <strong>C</strong> and <strong>C1*due to the in-order queue) signaling *C*s
completion global-synchronizes-with *C1</strong>. Note that in OpenCL 2.0, only
a host command-queue can be configured as an in-order queue.
</p>
</li>
<li>
<p>
If an API call enqueues a marker command <strong>C</strong> with an empty list
of events upon which <strong>C</strong> should wait, then the events of all commands
enqueued prior to <strong>C</strong> in the command-queue global-synchronize-with*C*.
</p>
</li>
<li>
<p>
If a host API call enqueues a command-queue barrier command <strong>C</strong>
with an empty list of events on which <strong>C</strong> should wait, then the events
of all commands enqueued prior to <strong>C</strong> in the command-queue
global-synchronize-with <strong>C</strong>. In addition, the event signaling the
completion of <strong>C</strong> global-synchronizes-with all commands enqueued after
<strong>C</strong> in the command-queue.
</p>
</li>
<li>
<p>
If a host thread executes a clFinish call <strong>X</strong>, then the events
of all commands enqueued prior to <strong>X</strong> in the command-queue
global-synchronizes-with <strong>X</strong>.
</p>
</li>
<li>
<p>
The start of a kernel-instance <strong>K</strong> global-synchronizes-with all
operations in the work items of <strong>K</strong>. Note that this includes the
execution of any atomic operations by the work items in a program using
fine-grain SVM.
</p>
</li>
<li>
<p>
All operations of all work items of a kernel-instance <strong>K</strong>
global-synchronizes-with the event signaling the completion of <strong>K</strong>. Note
that this also includes the execution of any atomic operations by the
work items in a program using fine-grain SVM.
</p>
</li>
<li>
<p>
If a callback procedure <strong>P</strong> is registered on an event <strong>E</strong>, then <strong>E</strong>
global-synchronizes-with all operations of <strong>P</strong>. Note that callback
procedures are only defined for commands within host command-queues.
</p>
</li>
<li>
<p>
If <strong>C</strong> is a command that waits for an event <strong>E</strong>'s completion, and
API function call <strong>X</strong> sets the status of a user event <strong>E</strong>'s status to
CL_COMPLETE (for example, from a host thread using a
clSetUserEventStatus function), then <strong>X</strong> global-synchronizes-with <strong>C</strong>.
</p>
</li>
<li>
<p>
If a device enqueues a command <strong>C</strong> with the
CLK_ENQUEUE_FLAGS_WAIT_KERNEL flag, then the end state of the parent
kernel instance global-synchronizes with <strong>C</strong>.
</p>
</li>
<li>
<p>
If a work-group enqueues a command <strong>C</strong> with the
CLK_ENQUEUE_FLAGS_WAIT_WORK_GROUP flag, then the end state of the
work-group global-synchronizes with <strong>C</strong>.
</p>
</li>
</ol></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>When using an out-of-order command queue, a wait on an event or a marker
or command-queue barrier command can be used to ensure the correct
ordering of dependent commands. In those cases, the wait for the event
or the marker or barrier command will provide the necessary
global-synchronizes-with relation.</p></div>
<div class="paragraph"><p>In this situation:</p></div>
<div class="ulist"><ul>
<li>
<p>
access to shared locations
or disjoint locations in a single cl_mem object when using atomic
operations from different kernel instances enqueued from the host such
that one or more of the atomic operations is a write is
implementation-defined and correct behavior is not guaranteed except
at synchronization points.
</p>
</li>
<li>
<p>
access to shared locations
or disjoint locations in a single cl_mem object when using atomic
operations from different kernel instances consisting of a parent kernel
and any number of child kernels enqueued by that kernel is guaranteed
under the memory ordering rules described earlier in this section.
</p>
</li>
<li>
<p>
access to shared locations
or disjoint locations in a single program scope global variable,
coarse-grained SVM allocation or fine-grained SVM allocation when using
atomic operations from different kernel instances enqueued from the host
to a single device is guaranteed under the memory ordering rules
described earlier in this section.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>If fine-grain SVM is used but without support for the OpenCL 2.0 atomic
operations, then the host and devices can concurrently read the same
memory locations and can concurrently update non-overlapping memory
regions, but attempts to update the same memory locations are
undefined. Memory consistency is guaranteed at the OpenCL
synchronization points without the need for calls to clEnqueueMapBuffer
and clEnqueueUnmapMemObject. For fine-grained SVM buffers it is
guaranteed that at synchronization points only values written by the
kernel will be updated. No writes to fine-grained SVM buffers can be
introduced that were not in the original program.
 </p></div>
<div class="paragraph"><p>In the remainder of this section, we discuss a few points regarding the
ordering rules for commands with a host command queue.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The OpenCL 1.2 standard describes a synchronization point as a
kernel-instance or host program location where the contents of memory
visible to different work-items or command-queue commands are the same.
It also says that waiting on an event and a command-queue barrier are
synchronization points between commands in command- queues. Four of the
rules listed above (2, 4, 7, and 8) cover these OpenCL synchronization
points.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>A map operation (clEnqueueMapBuffer or clEnqueueMapImage) performed on a
non-SVM buffer or a coarse-grained SVM buffer is allowed to overwrite
the entire target region with the latest runtime view of the data as
seen by the command with which the map operation synchronizes, whether
the values were written by the executing kernels or not. Any values
that were changed within this region by another kernel or host thread
while the kernel synchronizing with the map operation was executing may
be overwritten by the map operation.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Access to non-SVM cl_mem buffers and coarse-grained SVM allocations is
ordered at synchronization points between host commands. In the presence
of an out-of-order command queue or a set of command queues mapped to
the same device, multiple kernel instances may execute concurrently on
the same device.</p></div>
</div>
</div>
</div>
<div class="sect2">
<h3 id="_the_opencl_framework">3.4. The OpenCL Framework</h3>
<div class="paragraph"><p>The OpenCL framework allows applications to use a host and one or more
OpenCL devices as a single heterogeneous parallel computer system. The
framework contains the following components:</p></div>
<div class="ulist"><ul>
<li>
<p>
OpenCL Platform layer: The
platform layer allows the host program to discover OpenCL devices and
their capabilities and to create contexts.
</p>
</li>
<li>
<p>
OpenCL Runtime: The
runtime allows the host program to manipulate contexts once they have
been created.
</p>
</li>
<li>
<p>
OpenCL Compiler: The
OpenCL compiler creates program executables that contain OpenCL kernels.
SPIR-V intermediate language, OpenCL C, OpenCL C++, and OpenCL C language versions from earlier
OpenCL specifications are supported by the compiler. Other input
languages may be supported by some implementations.
</p>
</li>
</ul></div>
<div class="sect3">
<h4 id="_opencl_framework_mixed_version_support">3.4.1. OpenCL Framework: Mixed Version Support</h4>
<div class="paragraph"><p>OpenCL supports devices with different capabilities under a single
platform. This includes devices which conform to different versions of
the OpenCL specification. There are three version identifiers to
consider for an OpenCL system: the platform version, the version of a
device, and the version(s) of the kernel language or IL supported on a
device.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The platform version indicates the version of the OpenCL runtime that is
supported. This includes all of the APIs that the host can use to
interact with resources exposed by the OpenCL runtime; including
contexts, memory objects, devices, and command queues.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The device version is an indication of the device&#8217;s capabilities
separate from the runtime and compiler as represented by the device info
returned by <strong>clGetDeviceInfo</strong>. Examples of attributes associated with
the device version are resource limits (e.g., minimum size of local
memory per compute unit) and extended functionality (e.g., list of
supported KHR extensions). The version returned corresponds to the
highest version of the OpenCL specification for which the device is
conformant, but is not higher than the platform version.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The language version for a device represents the OpenCL programming
language features a developer can assume are supported on a given
device. The version reported is the highest version of the language
supported.</p></div>
<div class="paragraph"><p>Backwards compatibility is an important goal for the OpenCL standard.
Backwards compatibility is expected such that a device will consume
earlier versions of the SPIR-V and OpenCL C programming languages with
the following minimum requirements:</p></div>
<div class="olist arabic"><ol class="arabic">
<li>
<p>
An OpenCL 1.x device must support at least one 1.x version of
the OpenCL C programming language.
</p>
</li>
<li>
<p>
An OpenCL 2.0 device must support all the requirements of an
OpenCL 1.x device in addition to the OpenCL C 2.0 programming language.
If multiple language versions are supported, the compiler defaults to
using the highest OpenCL 1.x language version supported for the device
(typically OpenCL 1.2). To utilize the OpenCL 2.0 Kernel programming
language, a programmer must specifically set the appropriate compiler
flag (-cl-std=CL2.0). The language version must not be higher than the
platform version, but may exceed the device version (see section
5.8.4.5).
</p>
</li>
<li>
<p>
An OpenCL 2.1 device must support all the requirements of an
OpenCL 2.0 device in addition to the SPIR-V intermediate language at
version 1.0 or above. Intermediate language versioning is encoded as
part of the binary object and no flags are required to be passed to the
compiler.
</p>
</li>
<li>
<p>
An OpenCL 2.2 device must support all the requirements of an
OpenCL 2.0 device in addition to the SPIR-V intermediate language at
version 1.2 or above. Intermediate language
is encoded as a part of the binary
object and no flags are required to be passed to the compiler.
</p>
</li>
</ol></div>
</div>
</div>
</div>
</div>
<div class="sect1">
<h2 id="_the_opencl_platform_layer">4. The OpenCL Platform Layer</h2>
<div class="sectionbody">
<div class="paragraph"><p>This section describes the OpenCL platform layer which implements
platform-specific features that allow applications to query OpenCL
devices, device configuration information, and to create OpenCL contexts
using one or more devices.</p></div>
<div class="sect2">
<h3 id="_querying_platform_info">4.1. Querying Platform Info</h3>
<div class="paragraph"><p>The list of platforms available can be obtained using the following
function.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetPlatformIDs(cl_uint num_entries,
cl_platform_id *platforms,
cl_uint *num_platforms)</pre>
</div></div>
<div class="paragraph"><p><em>num_entries</em> is the number of cl_platform_id entries that can be added
to <em>platforms._If _platforms</em> is not NULL, the <em>num_entries</em> must be
greater than zero.
<br>
<br>
<em>platforms</em> returns a list of OpenCL platforms found. The
cl_platform_id values returned in <em>platforms_can be used to identify a
specific OpenCL platform. If _platforms</em> argument is NULL, this
argument is ignored. The number of OpenCL platforms returned is the
minimum of the value specified by <em>num_entries</em> or the number of OpenCL
platforms available.
<br>
<br>
<em>num_platforms</em> returns the number of OpenCL platforms available. If
<em>num_platforms</em> is NULL, this argument is ignored.
<br>
<br>
<strong>clGetPlatformIDs</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_VALUE if
<em>num_entries</em> is equal to zero and <em>platforms</em> is not NULL or if both
<em>num_platforms</em> and <em>platforms</em> are NULL.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetPlatformInfo(cl_platform_id platform,
cl_platform_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>gets specific information about the OpenCL platform. The information
that can be queried using <strong>clGetPlatformInfo</strong> is specified in <em>table
4.1</em>.
<br>
<br>
<em>platform</em> refers to the platform ID returned by <strong>clGetPlatformIDs</strong> or
can be NULL. If <em>platform</em> is NULL, the behavior is
implementation-defined.
<br>
<br>
<em>param_name</em> is an enumeration constant that identifies the platform
information being queried. It can be one of the following values as
specified in <em>table 4.1</em>.
<br>
<br>
<em>param_value</em> is a pointer to memory location where appropriate values
for a given <em>param_name</em> as specified in <em>table</em> <em>4.1</em> will be
returned. If <em>param_value</em> is NULL, it is ignored.
<br>
<br>
<em>param_value_size</em> specifies the size in bytes of memory pointed to by
<em>param_value</em>. This size in bytes must be &gt;= size of return type
specified in <em>table 4.1.</em>
<br>
<br>
<em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 2. <em>OpenCL Platform Queries</em></caption>
<col style="width:50%;">
<col style="width:10%;">
<col style="width:40%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_platform_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PLATFORM_PROFILE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]<span class="footnote"><br>[A null terminated string is returned by OpenCL query function calls if the return type of the information being queried is a char[].]<br></span></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">OpenCL profile string. Returns the
profile name supported by the
implementation. The profile name
returned can be one of the following
strings:
<br>
<br>
FULL_PROFILE – if the implementation
supports the OpenCL specification
(functionality defined as part of the core
specification and does not require any
extensions to be supported).
<br>
<br>
EMBEDDED_PROFILE - if the
CL_PLATFORM_VERSION
char[]
implementation supports the OpenCL
embedded profile. The embedded profile
is defined to be a subset for each version
of OpenCL. The embedded profile for
OpenCL 2.2 is described in <em>section 7</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PLATFORM_VERSION</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">OpenCL version string. Returns the
OpenCL version supported by the
implementation. This version string has
the following format:
<br>
<br>
<em>OpenCL&lt;space&gt;&lt;major_version.minor_
version&gt;&lt;space&gt;&lt;platform-specific
information&gt;</em>
<br>
<br>
The <em>major_version.minor_version</em> value
returned will be 2.2.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PLATFORM_NAME</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Platform name string.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PLATFORM_VENDOR</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Platform vendor string.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PLATFORM_EXTENSIONS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns a space separated list of extension
names (the extension names themselves
do not contain any spaces) supported by
the platform. Each extension that is
supported by all devices associated with
this platform must be reported here.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PLATFORM_HOST_TIMER_RESOLUTION</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the resolution
of the host timer in nanoseconds as used by <strong>clGetDeviceAndHostTimer</strong>.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetPlatformInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following
errors.<span class="footnote"><br>[The OpenCL specification does not describe the order of precedence for error codes returned by API calls.]<br></span>:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_PLATFORM if
<em>platform</em> is not a valid platform.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>param_name</em> is not one of the supported values or if size in bytes
specified by <em>param_value_size</em> is &lt; size of return type as specified in
<em>table 4.1</em> and <em>param_value</em> is not a NULL value.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect2">
<h3 id="_querying_devices">4.2. Querying Devices</h3>
<div class="paragraph"><p>The list of devices available on a platform can be obtained using the
following function.<span class="footnote"><br>[<strong>clGetDeviceIDs</strong> may returnal all or a subset of the actual physical devices present in the platform and that maths <em>device_type</em>]<br></span>.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetDeviceIDs(cl_platform_id platform,
cl_device_type device_type,
cl_uint num_entries,
cl_device_id * devices,
cl_uint *num_devices)</pre>
</div></div>
<div class="paragraph"><p><em>platform</em> refers to the platform ID returned by <strong>clGetPlatformIDs</strong> or
can be NULL. If <em>platform</em> is NULL, the behavior is
implementation-defined.</p></div>
<div class="paragraph"><p><em>device_type</em> is a bitfield that identifies the type of OpenCL device.
The <em>device_type</em> can be used to query specific OpenCL devices or all
OpenCL devices available. The valid values for <em>device_type</em> are
specified in <em>table 4.2</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_device_type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_TYPE_CPU</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">An OpenCL device that is the host processor. The
host processor runs the OpenCL implementations and is a single or
multi-core CPU.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_TYPE_GPU</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">An OpenCL device that is a GPU. By this we mean
that the device can also be used to accelerate a 3D API such as OpenGL
or DirectX.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_TYPE_ACCELERATOR</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Dedicated OpenCL accelerators (for
example the IBM CELL Blade). These devices communicate with the host
processor using a peripheral interconnect such as PCIe.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_TYPE_CUSTOM</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Dedicated accelerators that do not support
programs written in an OpenCL kernel language,</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_TYPE_DEFAULT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The default OpenCL device in the system.
The default device cannot be a <strong>CL_DEVICE_TYPE_CUSTOM</strong> device.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_TYPE_ALL</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">All OpenCL devices available in the system except
<strong>CL_DEVICE_TYPE_CUSTOM</strong> devices..</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><em>num_entries</em> is the number of cl_device_id entries that can be added to
<em>devices._If _devices</em> is not NULL, the <em>num_entries</em> must be greater
than zero.
<br>
<br>
<em>devices</em> returns a list of OpenCL devices found. The cl_device_id
values returned in <em>devices_can be used to identify a specific OpenCL
device. If _devices</em> argument is NULL, this argument is ignored. The
number of OpenCL devices returned is the minimum of the value specified
by <em>num_entries</em> or the number of OpenCL devices whose type matches
<em>device_type</em>.
<br>
<br>
<em>num_devices</em> returns the number of OpenCL devices available that match
<em>device_type</em>. If <em>num_devices</em> is NULL, this argument is ignored.</p></div>
<div class="paragraph"><p><strong>clGetDeviceIDs</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_PLATFORM if
<em>platform</em> is not a valid platform.
</p>
</li>
<li>
<p>
CL_INVALID_DEVICE_TYPE if
<em>device_type</em> is not a valid value.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>num_entries</em> is equal to zero and <em>devices</em> is not NULL or if both
<em>num_devices</em> and <em>devices</em> are NULL.
</p>
</li>
<li>
<p>
CL_DEVICE_NOT_FOUND if no
OpenCL devices that matched <em>device_type</em> were found.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The application can query specific capabilities of the OpenCL device(s)
returned by <strong>clGetDeviceIDs</strong>. This can be used by the application to
determine which device(s) to use.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetDeviceInfo(cl_device_id device,
cl_device_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>gets specific information about an OpenCL device.
<br>
<br>
<em>device</em> may be a device returned by <strong>clGetDeviceIDs</strong> or a sub-device
created by <strong>clCreateSubDevices</strong>. If <em>device</em> is a sub-device, the
specific information for the sub-device will be returned. The
information that can be queried using <strong>clGetDeviceInfo</strong> is specified in
<em>table 4.3</em>.
<br>
<br>
<em>param_name</em> is an enumeration constant that identifies the device
information being queried. It can be one of the following values as
specified in <em>table 4.3</em>.
<br>
<br>
<em>param_value</em> is a pointer to memory location where appropriate values
for a given <em>param_name</em> as specified in <em>table</em> <em>4.3</em> will be
returned. If <em>param_value</em> is NULL, it is ignored.
<br>
<br>
<em>param_value_size</em> specifies the size in bytes of memory pointed to by
<em>param_value</em>. This size in bytes must be &gt;= size of return type
specified in <em>table 4.3.</em>
<br>
<br>
<em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 3. <em>OpenCL Device Queries</em></caption>
<col style="width:30%;">
<col style="width:20%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_device_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_TYPE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_type</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The OpenCL device type. Currently supported values are:
<br>
<br>
CL_DEVICE_TYPE_CPU,
CL_DEVICE_TYPE_GPU, CL_DEVICE_TYPE_ACCELERATOR, CL_DEVICE_TYPE_DEFAULT, a combination of the above types or
CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_VENDOR_ID</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A unique device vendor identifier. An example of a unique device identifier could be the PCIe ID.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ COMPUTE_UNITS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The number of parallel compute
units on the OpenCL device. A work-group executes on a single compute
unit. The minimum value is 1.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEIVCE_MAX_ WORK_ITEM_DIMENSIONS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum dimensions that specify the global and
local work-item IDs used by the data parallel execution model. (Refer to
<strong>clEnqueueNDRangeKernel</strong>). The minimum value is 3 for devices that are
not of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ WORK_ITEM_SIZES</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t []</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum number of work-items that can
be specified in each dimension of the work-group to <strong>clEnqueueNDRangeKernel</strong>.
<br>
<br>
Returns n size_t entries, where n is the
value returned by the query for
CL_DEVICE_MAX_WORK_ITEM_DIMEN
SIONS.
<br>
<br>
The minimum value is (1, 1, 1) for devices
that are not of type
CL_DEVICE_TYPE_CUSTOM .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ WORK_GROUP_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum number of work-items in a
work-group that a device is capable of
executing on a single compute unit, for any
given kernel-instance running on the
device. (Refer also to
<strong>clEnqueueNDRangeKernel and CL_KERNEL_WORK_GROUP_SIZE</strong> ). The minimum value is 1.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PREFERRED_ VECTOR_WIDTH_CHAR
<br>
<br>
CL_DEVICE_PREFERRED_
VECTOR_WIDTH_SHORT
<br>
<br>
CL_DEVICE_PREFERRED_
VECTOR_WIDTH_INT
<br>
<br>
CL_DEVICE_PREFERRED_
VECTOR_WIDTH_LONG
<br>
<br>
CL_DEVICE_PREFERRED_
VECTOR_WIDTH_FLOAT
<br>
<br>
CL_DEVICE_PREFERRED_
VECTOR_WIDTH_DOUBLE
<br>
<br>
CL_DEVICE_PREFERRED_
VECTOR_WIDTH_HALF</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Preferred native vector width size for built-
in scalar types that can be put into vectors.
The vector width is defined as the number
of scalar elements that can be stored in the
vector.
<br>
<br>
If double precision is not supported,CL_DEVICE_PREFERRED_VECTOR_WIDTH_
DOUBLE must return 0.
<br>
<br>
If the <strong>cl_khr_fp16</strong> extension is not supported,
CL_DEVICE_PREFERRED_VECTOR_WIDTH_
HALF must return 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_NATIVE_ VECTOR_WIDTH_CHAR
<br>
<br>
CL_DEVICE_NATIVE_
VECTOR_WIDTH_SHORT
<br>
<br>
CL_DEVICE_NATIVE_
VECTOR_WIDTH_INT
<br>
<br>
CL_DEVICE_NATIVE_
VECTOR_WIDTH_LONG
<br>
<br>
CL_DEVICE_NATIVE_
VECTOR_WIDTH_FLOAT
<br>
<br>
CL_DEVICE_NATIVE_
VECTOR_WIDTH_DOUBLE
<br>
<br>
CL_DEVICE_NATIVE_
VECTOR_WIDTH_HALF</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the native ISA vector width. The
vector width is defined as the number of
scalar elements that can be stored in the
vector.
<br>
<br>
If double precision is not supported,
CL_DEVICE_NATIVE_VECTOR_WIDTH_DOUBLE must return 0.
<br>
<br>
If the <strong>cl_khr_fp16</strong> extension is not supported,
CL_DEVICE_NATIVE_VECTOR_WIDTH_
HALF must return 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ CLOCK_FREQUENCY</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Clock frequency of the device in MHz. The
meaning of this value is implementation-
defined. For devices with multiple clock
domains, the clock frequency for any of the
clock domains may be returned. For
devices that dynamically change frequency
for power or thermal reasons, the returned
clock frequency may be any valid
frequency.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_ADDRESS_BITS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The default compute device address
space size of the global address space specified as an unsigned integer
value in bits. Currently supported values are 32 or 64 bits.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ MEM_ALLOC_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max size of memory object
allocation in bytes. The minimum value is max (min(1024*1024*1024,
1/4<sup>th</sup> of <strong>CL_DEVICE_GLOBAL_MEM_SIZE</strong>), 32*1024*1024) for devices that
are not of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE_ SUPPORT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_TRUE if images are supported
by the OpenCL device and CL_FALSE otherwise.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ READ_IMAGE_ARGS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of image objects
arguments of a kernel declared with the read_only qualifier. The
minimum value is 128 if CL_DEVICE_IMAGE_SUPPORT is CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ WRITE_IMAGE_ARGS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of image objects
arguments of a kernel declared with the write_only qualifier. The
minimum value is 64 if CL_DEVICE_IMAGE_SUPPORT is CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ READ_WRITE_IMAGE_ARGS<span class="footnote"><br>[NOTE: <strong>CL_DEVICE_MAX_WRITE_IMAGE_ARGS</strong> is only there for backward compatibility.
<strong>CL_DEVICE_MAX_READ_WRITE_IMAGE_ARGS</strong> should be used instead.]<br></span></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of image objects arguments
of a kernel declared with the
write_only or read_write qualifier.
The minimum value is 64 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IL_VERSION</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The intermediate languages that can be
supported by <strong>clCreateProgramWithIL</strong> for this device. Returns a
space-separated list of IL version strings of the form
&lt;IL_Prefix&gt;_&lt;Major_Version&gt;.&lt;Minor_Version&gt;. For OpenCL 2.2, SPIR-V is
a required IL prefix.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE2D_ MAX_WIDTH</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max width of 2D image or 1D image not
created from a buffer object in pixels.
<br>
<br>
The minimum value is 16384 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE2D_ MAX_HEIGHT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max height of 2D image in pixels.
<br>
<br>
The minimum value is 16384 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE3D_ MAX_WIDTH</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max width of 3D image in pixels.
<br>
<br>
The minimum value is 2048 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE3D_ MAX_HEIGHT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max height of 3D image in pixels.
<br>
<br>
The minimum value is 2048 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE3D_ MAX_DEPTH</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max depth of 3D image in pixels.
<br>
<br>
The minimum value is 2048 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE_ MAX_BUFFER_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of pixels for a 1D image
created from a buffer object.
<br>
<br>
The minimum value is 65536 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE_ MAX_ARRAY_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of images in a 1D or 2D
image array.
<br>
<br>
The minimum value is 2048 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ SAMPLERS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum number of samplers that can be
used in a kernel.
<br>
<br>
The minimum value is 16 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE_ PITCH_ALIGNMENT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The row pitch alignment size in pixels for
2D images created from a buffer. The
value returned must be a power of 2.
<br>
<br>
If the device does not support images, this
value must be 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_IMAGE_ BASE_ADDRESS_ ALIGNMENT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This query should be used when a 2D
image is created from a buffer which was
created using CL_MEM_USE_HOST_PTR. The value returned must be a power of 2.
<br>
<br>
This query specifies the minimum
alignment in pixels of the host_ptr
specified to <strong>clCreateBuffer</strong>.
<br>
<br>
If the device does not support images, this
value must be 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ PIPE_ARGS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The maximum number of pipe objects
that can be passed as arguments to a kernel. The minimum value is 16.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PIPE_ MAX_ACTIVE_RESERVATIONS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The maximum number of reservations that can be
active for a pipe per work-item in a kernel. A work-group reservation
is counted as one reservation per work-item. The minimum value is 1.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PIPE_ MAX_PACKET_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The maximum size of pipe
packet in bytes. The minimum value is 1024 bytes.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ PARAMETER_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max size in bytes of all arguments that can
be passed to a kernel.
<br>
<br>
The minimum value is 1024 for devices
that are not of type
CL_DEVICE_TYPE_CUSTOM . For this
minimum value, only a maximum of 128
arguments can be passed to a kernel</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MEM_ BASE_ADDR_ALIGN</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Alignment requirement (in
bits) for sub-buffer offsets. The minimum value is the size (in bits) of
the largest OpenCL built-in data type supported by the device (long16 in
FULL profile,
long16 or int16 in EMBEDDED profile) for devices that are
not of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_SINGLE_ FP_CONFIG<span class="footnote"><br>[The optional rounding modes should be included as a device capability only if it is supported natively. All explicit
conversion functions with specific rounding modes must still operate correctly.]<br></span></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_
fp_config</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes single precision floating-point
capability of the device. This is a bit-field
that describes one or more of the following values:
CL_FP_DENORM – denorms are supported
<br>
<br>
CL_FP_INF_NAN – INF and quiet NaNs are
supported.
<br>
<br>
CL_FP_ROUND_TO_NEAREST– round to
nearest even rounding mode supported
<br>
<br>
CL_FP_ROUND_TO_ZERO – round to zero
rounding mode supported
<br>
<br>
CL_FP_ROUND_TO_INF – round to positive
and negative infinity rounding modes
supported
<br>
<br>
CL_FP_FMA – IEEE754-2008 fused multiply-
add is supported.
<br>
<br>
CL_FP_CORRECTLY_ROUNDED_DIVIDE
_SQRT – divide and sqrt are correctly rounded
as defined by the IEEE754 specification.
<br>
<br>
CL_FP_SOFT_FLOAT – Basic floating-point
operations (such as addition, subtraction,
multiplication) are implemented in software.
<br>
<br>
For the full profile, the mandated minimum
floating-point capability for devices that
are not of type
CL_DEVICE_TYPE_CUSTOM is:
CL_FP_ROUND_TO_NEAREST |
CL_FP_INF_NAN.
<br>
<br>
For the embedded profile, see section 10.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_DOUBLE_ FP_CONFIG<span class="footnote"><br>[The optional rounding modes should be included as a device capability only if it is supported natively. All explicit
conversion functions with specific rounding modes must still operate correctly.]<br></span></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_
fp_config</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes double precision floating-point
capability of the OpenCL device. This is a
bit-field that describes one or more of the
following values:
<br>
<br>
CL_FP_DENORM – denorms are supported
<br>
<br>
CL_FP_INF_NAN – INF and NaNs are
supported.
<br>
<br>
CL_FP_ROUND_TO_NEAREST – round to
nearest even rounding mode supported.
<br>
<br>
CL_FP_ROUND_TO_ZERO – round to zero
rounding mode supported.
<br>
<br>
CL_FP_ROUND_TO_INF – round to
positive and negative infinity rounding
modes supported.
<br>
<br>
CP_FP_FMA – IEEE754-2008 fused
multiply-add is supported.
<br>
<br>
CL_FP_SOFT_FLOAT – Basic floating-point
operations (such as addition, subtraction,
multiplication) are implemented in software.
Double precision is an optional feature so
the mandated minimum double precision
floating-point capability is 0.
If double precision is supported by the
device, then the minimum double precision
floating-point capability must be:
CL_FP_FMA |
CL_FP_ROUND_TO_NEAREST |
CL_FP_INF_NAN |
CL_FP_DENORM .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_GLOBAL_ MEM_CACHE_TYPE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_mem_
cache_type</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Type of global memory cache supported.
Valid values are:
CL_NONE,
CL_READ_ONLY_CACHE and
CL_READ_WRITE_CACHE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_GLOBAL_ MEM_CACHELINE_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Size of global memory
cache line in bytes.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_GLOBAL_ MEM_CACHE_
SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Size of global memory cache in
bytes.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_GLOBAL_ MEM_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Size of global device memory in
bytes.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ CONSTANT_BUFFER_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max size in bytes of a constant
buffer allocation. The minimum value is 64 KB for devices that are not
of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ CONSTANT_ARGS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of arguments
declared with the __constant qualifier in a kernel. The minimum value
is 8 for devices that are not of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ GLOBAL_VARIABLE_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The maximum number of bytes of storage
that may be allocated for any single
variable in program scope or inside a
function in an OpenCL kernel language declared in the
global address space.
<br>
<br>
The minimum value is 64 KB.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_GLOBAL_ VARIABLE_PREFERRED_ TOTAL_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum
preferred total size, in bytes, of all program variables in the global
address space. This is a performance hint. An implementation may place
such variables in storage with optimized device access. This query
returns the capacity of such storage. The minimum value is 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_LOCAL_ MEM_TYPE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_ local_mem_type</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Type of local memory supported. This can
be set to CL_LOCAL implying dedicated
local memory storage such as SRAM , or
CL_GLOBAL .
<br>
<br>
For custom devices, CL_NONE can also be
returned indicating no local memory
support.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_LOCAL_ MEM_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Size of local memory region in
bytes. The minimum value is 32 KB for devices that are not of type
CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_ERROR_ CORRECTION_SUPPORT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_TRUE if the device implements
error correction for all accesses to compute device memory (global and
constant). Is CL_FALSE if the device does not implement such error
correction.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PROFILING_ TIMER_RESOLUTION</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes the resolution of device
timer. This is measured in nanoseconds. Refer to <em>section 5.14</em> for
details.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_ENDIAN_LITTLE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_TRUE if the OpenCL device is a
little endian device and CL_FALSE
otherwise</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_AVAILABLE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_TRUE if the device is available
and CL_FALSE otherwise. A device is considered to be available if the
device can be expected to successfully execute commands enqueued to the
device.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_COMPILER_ AVAILABLE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_FALSE if the implementation does
not have a compiler available to compile
the program source.
<br>
<br>
Is CL_TRUE if the compiler is available.
This can be CL_FALSE for the embedded
platform profile only.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_LINKER_ AVAILABLE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_FALSE if the implementation does
not have a linker available.
Is CL_TRUE if the linker is available.
<br>
<br>
This can be CL_FALSE for the embedded
platform profile only.
<br>
<br>
This must be CL_TRUE if
CL_DEVICE_COMPILER_AVAILABLE
is
CL_TRUE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_EXECUTION_ CAPABILITIES</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_exec_ capabilities</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes the execution capabilities of the
device. This is a bit-field that describes
one or more of the following values:
<br>
<br>
CL_EXEC_KERNEL –
The OpenCL device
can execute OpenCL kernels.
<br>
<br>
CL_EXEC_NATIVE_KERNEL – The OpenCL
device can execute native kernels.
<br>
<br>
The mandated minimum capability is:
CL_EXEC_KERNEL .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_QUEUE_ ON_HOST_PROPERTIES<span class="footnote"><br>[CL_DEVICE_QUEUE_PROPERTIES is deprecated and replaced by
CL_DEVICE_QUEUE_ON_HOST_PROPERTIES.]<br></span></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_command_ queue_properties</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes the on host command-queue
properties supported by the device. This is
a bit-field that describes one or more of the
following values:
<br>
<br>
CL_QUEUE_OUT_OF_ORDER_EXEC_
MODE_ENABLE
<br>
<br>
CL_QUEUE_PROFILING_ENABLE
<br>
<br>
These properties are described in table 5.1.
<br>
<br>
The mandated minimum capability is:
CL_QUEUE_PROFILING_ENABLE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_QUEUE_ ON_DEVICE_PROPERTIES</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_command_ queue_properties</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes the on device command-queue properties supported by the device. This is
a bit-field that describes one or more of the
following values:
<br>
<br>
CL_QUEUE_OUT_OF_ORDER_EXEC_
MODE_ENABLE
<br>
<br>
CL_QUEUE_PROFILING_ENABLE
<br>
<br>
These properties are described in table 5.1.
The mandated minimum capability is:
CL_QUEUE_OUT_OF_ORDER_EXEC_
MODE_ENABLE |
CL_QUEUE_PROFILING_ENABLE .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_QUEUE_ ON_DEVICE_PREFERRED_ SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The size of the device queue in bytes
preferred by the implementation.
Applications should use this size for the
device queue to ensure good performance.
<br>
<br>
The minimum value is 16 KB</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_QUEUE_ ON_DEVICE_MAX_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The max. size of the device queue in bytes.
<br>
<br>
The minimum value is 256 KB for the full
profile and 64 KB for the embedded profile</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ ON_DEVICE_QUEUES</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The maximum number of device queues
that can be created for this device in a
single context.
<br>
<br>
The minimum value is 1.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ ON_DEVICE_EVENTS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The maximum number of events in use by
a device queue. These refer to events
returned by the enqueue_ built-in
functions to a device queue or user events
returned by the create_user_event
built-in function that have not been
released.
<br>
<br>
The minimum value is 1024.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_BUILT_IN_ KERNELS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A semi-colon separated list of
built-in kernels supported by the device. An empty string is returned
if no built-in kernels are supported by the device.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PLATFORM</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_platform_id</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The platform associated with this
device.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_NAME</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Device name string.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_VENDOR</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Vendor name string.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DRIVER_VERSION</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">OpenCL software driver version string.
Follows a vendor-specific format.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PROFILE<span class="footnote"><br>[The platform profile returns the profile that is implemented by the OpenCL framework. If the platform profile
returned is FULL_PROFILE, the OpenCL framework will support devices that are FULL_PROFILE and may also
support devices that are EMBEDDED_PROFILE. The compiler must be available for all devices i.e.
CL_DEVICE_COMPILER_AVAILABLE is CL_TRUE. If the platform profile returned is
EMBEDDED_PROFILE, then devices that are only EMBEDDED_PROFILE are supported.]<br></span></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">[OpenCL profile string. Returns the profile
name supported by the device. The profile
name returned can be one of the following
strings:
<br>
<br>
FULL_PROFILE – if the device supports
the OpenCL specification (functionality
defined as part of the core specification and
does not require any extensions to be
supported).
<br>
<br>
EMBEDDED_PROFILE - if the device supports the OpenCL embedded profile.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_VERSION</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">OpenCL version string. Returns the
OpenCL version supported by the device.
This version string has the following
format:
<br>
<br>
<em>OpenCL&lt;space&gt;&lt;major_version.minor_v
ersion&gt;&lt;space&gt;&lt;vendor-specific
information&gt;</em>
<br>
<br>
The major_version.minor_version value
returned will be 2.2.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_OPENCL_C_ VERSION</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">OpenCL C version string. Returns the
highest OpenCL C version supported by
the compiler for this device that is not of
type CL_DEVICE_TYPE_CUSTOM . This
version string has the following format:
<br>
<br>
<em>OpenCL&lt;space&gt;C&lt;space&gt;&lt;major_versio
n.minor_version&gt;&lt;space&gt;&lt;vendor-
specific information&gt;</em>
<br>
<br>
The major_version.minor_version value
returned must be 2.0 if
CL_DEVICE_VERSION is OpenCL 2.0.
<br>
<br>
The major_version.minor_version value
returned must be 1.2 if
CL_DEVICE_VERSION is OpenCL 1.2.
<br>
<br>
The major_version.minor_version value
returned must be 1.1 if
CL_DEVICE_VERSION is OpenCL 1.1.
<br>
<br>
The major_version.minor_version value
returned can be 1.0 or 1.1 if
CL_DEVICE_VERSION is OpenCL 1.0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_EXTENSIONS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns a space separated list of extension
names (the extension names themselves do
not contain any spaces) supported by the
device. The list of extension names
returned can be vendor supported extension
names and one or more of the following
Khronos approved extension names:
<br>
<br>
<strong>cl_khr_int64_base_atomics
cl_khr_int64_extended_atomics
cl_khr_fp16
cl_khr_gl_sharing
cl_khr_gl_event
cl_khr_d3d10_sharing
cl_khr_dx9_media_sharing
cl_khr_d3d11_sharing
cl_khr_gl_depth_images
cl_khr_gl_msaa_sharing
cl_khr_initialize_memory
cl_khr_terminate_context
cl_khr_spir
cl_khr_srgb_image_writes</strong>
<br>
<br>
<strong>The following approved Khronos extension
names must be returned by all devices that
support OpenCL C 2.0:</strong>
<br>
<br>
<strong>cl_khr_byte_addressable_store
cl_khr_fp64 (for backward compatibility if
double precision is supported)
cl_khr_3d_image_writes
cl_khr_image2d_from_buffer
cl_khr_depth_images</strong>
<br>
<br>
Please refer to the OpenCL 2.0 Extension
Specification for a detailed description of
these extensions.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PRINTF_ BUFFER_SIZE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum size in bytes of the
internal buffer that holds the output of printf calls from a kernel.
The minimum value for the FULL profile is 1 MB.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PREFERRED_ INTEROP_USER_SYNC</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_TRUE if the devices preference is for the
user to be responsible for synchronization, when sharing memory objects
between OpenCL and other APIs such as DirectX, CL_FALSE if the device /
implementation has a performant path for performing synchronization of
memory object shared between OpenCL and other APIs such as DirectX.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PARENT_ DEVICE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_id</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the cl_device_id of
the parent device to which this sub-device belongs. If <em>device</em> is a
root-level device, a NULL value is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PARTITION_ MAX_SUB_DEVICES</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the maximum number of sub-
devices that can be created when a device
is partitioned.
<br>
<br>
The value returned cannot exceed
CL_DEVICE_MAX_COMPUTE_UNITS .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PARTITION_ PROPERTIES</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_partition_ property[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the list of partition types supported
by <em>device</em>. The is an array of
cl_device_partition_property values drawn
from the following list:
<br>
<br>
CL_DEVICE_PARTITION_EQUALLY
CL_DEVICE_PARTITION_BY_COUNTS
CL_DEVICE_PARTITION_BY_AFFINITY_DOMAIN
<br>
<br>
If the device cannot be partitioned (i.e.
there is no partitioning scheme supported
by the device that will return at least two
subdevices), a value of 0 will be returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PARTITION_ AFFINITY_DOMAIN</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_affinity_ domain</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the list of supported affinity
domains for partitioning the device using
CL_DEVICE_PARTITION_BY_AFFINITY_DOMAIN .
This is a bit-field that describes one or
more of the following values:
<br>
<br>
CL_DEVICE_AFFINITY_DOMAIN_NUMA
CL_DEVICE_AFFINITY_DOMAIN_L4_CACHE
CL_DEVICE_AFFINITY_DOMAIN_L3_CACHE
CL_DEVICE_AFFINITY_DOMAIN_L2_CACHE
CL_DEVICE_AFFINITY_DOMAIN_L1_CACHE
CL_DEVICE_AFFINITY_DOMAIN_NEXT_PARTITI
ONABLE
<br>
<br>
If the device does not support any affinity
domains, a value of 0 will be returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PARTITION_ TYPE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_partition_ property[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the properties argument specified
in <strong>clCreateSubDevices</strong> if device is a sub-
device. In the case where the properties
argument to <strong>clCreateSubDevices</strong> is
CL_DEVICE_PARTITION_BY_AFFINITY_DOMAIN ,
CL_DEVICE_AFFINITY_DOMAIN_NEXT_PARTITI
ONABLE , the affinity domain used to
perform the partition will be returned. This
can be one of the following values:
<br>
<br>
CL_DEVICE_AFFINITY_DOMAIN_NUMA
CL_DEVICE_AFFINITY_DOMAIN_L4_CACHE
CL_DEVICE_AFFINITY_DOMAIN_L3_CACHE
CL_DEVICE_AFFINITY_DOMAIN_L2_CACHE
CL_DEVICE_AFFINITY_DOMAIN_L1_CACHE
<br>
<br>
Otherwise the implementation may either
return a <em>param_value_size_ret</em> of 0 i.e.
there is no partition type associated with
device or can return a property value of 0
(where 0 is used to terminate the partition
property list) in the memory that
<em>param_value</em> points to.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_REFERENCE_ COUNT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the <em>device</em> reference
count. If the device is a root-level device, a reference count of one
is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_SVM_ CAPABILITIES</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_svm_ capabilities</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes the various shared virtual
memory (a.k.a. SVM) memory allocation
types the device supports. Coarse-grain
SVM allocations are required to be
supported by all OpenCL 2.0 devices. This
is a bit-field that describes a combination
of the following values:
<br>
<br>
CL_DEVICE_SVM_COARSE_GRAIN_
BUFFER – Support for coarse-grain buffer
sharing using <strong>clSVMAlloc</strong>. Memory
consistency is guaranteed at
synchronization points and the host must
use calls to <strong>clEnqueueMapBuffer</strong> and
<strong>clEnqueueUnmapMemObject</strong>.
<br>
<br>
CL_DEVICE_SVM_FINE_GRAIN_BUFFER
– Support for fine-grain buffer sharing
using <strong>clSVMAlloc</strong>. Memory consistency
is guaranteed at synchronization points
without need for <strong>clEnqueueMapBuffer</strong>
and <strong>clEnqueueUnmapMemObject</strong>.
<br>
<br>
CL_DEVICE_SVM_FINE_GRAIN_SYSTEM
– Support for sharing the host’s entire
virtual memory including memory
allocated using <strong>malloc</strong>. Memory
consistency is guaranteed at
synchronization points.
<br>
<br>
CL_DEVICE_SVM_ATOMICS – Support
for the OpenCL 2.0 atomic operations that
provide memory consistency across the
host and all OpenCL devices supporting
fine-grain SVM allocations.
<br>
<br>
The mandated minimum capability is
CL_DEVICE_SVM_COARSE_GRAIN_BUFFER.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PREFERRED_ PLATFORM_ATOMIC_ ALIGNMENT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the value representing the
preferred alignment in bytes for OpenCL 2.0 fine-grained SVM atomic
types. This query can return 0 which indicates that the preferred
alignment is aligned to the natural size of the type.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PREFERRED_ GLOBAL_ATOMIC_ ALIGNMENT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the value representing the
preferred alignment in bytes for OpenCL 2.0 atomic types to global
memory. This query can return 0 which indicates that the preferred
alignment is aligned to the natural size of the type.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_PREFERRED_ LOCAL_ATOMIC_ ALIGNMENT</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the
value representing the preferred alignment in bytes for OpenCL 2.0
atomic types to local memory. This query can return 0 which indicates
that the preferred alignment is aligned to the natural size of the type.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_MAX_ NUM_SUB_GROUPS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum number of sub-groups
in a work-group that a device is capable of executing on a single
compute unit, for any given kernel-instance running on the device. The
minimum value is 1. (Refer also to <strong>clGetKernelSubGroupInfo</strong>.)</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEVICE_SUB_ GROUP_INDEPENDENT_ FORWARD_PROGRESS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_TRUE
if this device supports independent forward progress of sub-groups,
CL_FALSE otherwise. If cl_khr_subgroups is supported by the device this
must return CL_TRUE.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>The device queries described in <em>table 4.3</em> should return the same
information for a root-level device i.e. a device returned by
<strong>clGetDeviceIDs</strong> and any sub-devices created from this device except for
the following queries:</p></div>
<div class="paragraph"><p> </p></div>
<div class="literalblock">
<div class="content monospaced">
<pre>CL_DEVICE_GLOBAL_MEM_CACHE_SIZE
CL_DEVICE_BUILT_IN_KERNELS
CL_DEVICE_PARENT_DEVICE
CL_DEVICE_PARTITION_TYPE
CL_DEVICE_REFERENCE_COUNT</pre>
</div></div>
<div class="paragraph"><p><strong>clGetDeviceInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_DEVICE if
<em>device</em> is not valid.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>param_name</em> is not one of the supported values or if size in bytes
specified by <em>param_value_size_is &lt; size of return type as specified in
_table 4.3</em> and <em>param_value</em> is not a NULL value or if <em>param_name</em> is
a value that is available as an extension and the corresponding
extension is not supported by the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetDeviceAndHostTimer(cl_device_id device,
cl_ulong* device_timestamp,
cl_ulong* host_timestamp)</pre>
</div></div>
<div class="paragraph"><p>Returns a reasonably synchronized pair of timestamps from the device
timer and the host timer as seen by <em>device</em>. Implementations may need
to execute this query with a high latency in order to provide reasonable
synchronization of the timestamps. The host timestamp and device
timestamp returned by this function and <strong>clGetHostTimer</strong> each have an
implementation defined timebase. The timestamps will always be in their
respective timebases regardless of which query function is used. The
timestamp returned from <strong>clGetEventProfilingInfo</strong> for an event on a
device and a device timestamp queried from the same device will always
be in the same timebase.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>device</em> is a device returned by <strong>clGetDeviceIDs</strong>.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>device_timestamp</em> will be updated with the value of the device timer in
nanoseconds. The resolution of the timer is the same as the device
profiling timer returned by *clGetDeviceInfo*and the
CL_DEVICE_PROFILING_TIMER_RESOLUTION query.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>host_timestamp</em> will be updated with the value of the host timer in
nanoseconds at the closest possible point in time to that at which
<em>device_timer</em> was returned. The resolution of the timer may be queried
via <strong>clGetPlatformInfo</strong> and the flag CL_PLATFORM_HOST_TIMER_RESOLUTION.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>clGetDeviceAndHostTimer</strong> will return CL_SUCCESS with a time value in
<em>host_timestamp</em> if provided. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_DEVICE if
<em>device</em> is not a valid OpenCL device.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>host_timestamp</em> or _device_timestamp_is NULL.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetHostTimer(cl_device_id device,
cl_ulong* host_timestamp)</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Return the current value of the host clock as seen by <em>device</em>. This
value is in the same timebase as the host_timestamp returned from
<strong>clGetDeviceAndHostTimer</strong>. The implementation will return with as low a
latency as possible to allow a correlation with a subsequent application
sampled time. The host timestamp and device timestamp returned by this
function and <strong>clGetDeviceAndHostTimer</strong> each have an implementation
defined timebase. The timestamps will always be in their respective
timebases regardless of which query function is used. The timestamp
returned from <strong>clGetEventProfilingInfo</strong> for an event on a device and a
device timestamp queried from the same device will always be in the same
timebase.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>device</em> is a device returned by <strong>clGetDeviceIDs</strong>.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>host_timestamp</em> will be updated with the value of the current timer in
nanoseconds. The resolution of the timer may be queried via
<strong>clGetPlatformInfo</strong> and the flag CL_PLATFORM_HOST_TIMER_RESOLUTION.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>clGetHostTimer</strong> will return CL_SUCCESS with a time value in
<em>host_timestamp</em> if provided. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_DEVICE if
<em>device</em> is not a valid OpenCL device.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
_host_timestamp_is NULL.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect2">
<h3 id="_partitioning_a_device">4.3. Partitioning a Device</h3>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clCreateSubDevices(cl_device_id in_device,
const cl_device_partition_property *properties,
cl_uint num_devices,
cl_device_id *out_devices,
cl_uint *num_devices_ret)</pre>
</div></div>
<div class="paragraph"><p>creates an array of sub-devices that each reference a non-intersecting
set of compute units within in_device, according to a partition scheme
given by <em>properties</em>. The output sub-devices may be used in every way
that the root (or parent) device can be used, including creating
contexts, building programs, further calls to <strong>clCreateSubDevices</strong> and
creating command-queues. When a command-queue is created against a
sub-device, the commands enqueued on the queue are executed only on the
sub-device.</p></div>
<div class="paragraph"><p><em>in_device</em> is the device to be partitioned.</p></div>
<div class="paragraph"><p><em>properties</em> specifies how <em>in_device</em> is to be partition described by a
partition name and its corresponding value. Each partition name is
immediately followed by the corresponding desired value. The list is
terminated with 0. The list of supported partitioning schemes is
described in <em>table 4.4</em>. Only one of the listed partitioning schemes
can be specified in <em>properties</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 4. <em>List of supported partition schemes by</em> <strong>clCreateSubDevices</strong></caption>
<col style="width:30%;">
<col style="width:20%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_device_partition_property enum</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Partition value</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_PARTITION_ EQUALLY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Split the aggregate device
into as many smaller aggregate devices as can be created, each
containing <em>n</em> compute units. The value <em>n</em> is passed as the value
accompanying this property. If <em>n</em> does not divide evenly into
CL_DEVICE_PARTITION_MAX_COMPUTE_UNITS, then the remaining compute units
are not used.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_PARTITION_ BY_COUNTS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This property is followed by a
CL_DEVICE_PARTITION_BY_COUNTS_LIST_END
terminated list of compute unit counts. For each non-
zero count <em>m</em> in the list, a sub-device is created with
<em>m</em> compute units in it.
CL_DEVICE_PARTITION_BY_COUNTS_LIST_END
is defined to be 0.
<br>
<br>
The number of non-zero count entries in the list may
not exceed
CL_DEVICE_PARTITION_MAX_SUB_DEVICES.
<br>
<br>
The total number of compute units specified may not
exceed
CL_DEVICE_PARTITION_MAX_COMPUTE_UNITS .</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_PARTITION_ BY_AFFINITY_DOMAIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_affinity_ domain</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Split the device into smaller aggregate devices
containing one or more compute units that all share
part of a cache hierarchy. The value accompanying
this property may be drawn from the following list:
<br>
<br>
CL_DEVICE_AFFINITY_DOMAIN_NUMA – Split the
device into sub-devices comprised of compute units
that share a NUMA node.
<br>
<br>
CL_DEVICE_AFFINITY_DOMAIN_L4_CACHE –
Split the device into sub-devices comprised of
compute units that share a level 4 data cache.
<br>
<br>
CL_DEVICE_AFFINITY_DOMAIN_L3_CACHE –
Split the device into sub-devices comprised of
compute units that share a level 3 data cache.
<br>
<br>
CL_DEVICE_AFFINITY_DOMAIN_L2_CACHE –
Split the device into sub-devices comprised of
compute units that share a level 2 data cache.
<br>
<br>
CL_DEVICE_AFFINITY_DOMAIN_L1_CACHE –
Split the device into sub-devices comprised of
compute units that share a level 1 data cache.
<br>
<br>
CL_DEVICE_AFFINITY_ DOMAIN_NEXT_ PARTITIO
NABLE – Split the device along the next partitionable
affinity domain. The implementation shall find the
first level along which the device or sub-device may
be further subdivided in the order NUMA, L4, L3,
L2, L1, and partition the device into sub-devices
comprised of compute units that share memory
subsystems at this level.
<br>
<br>
The user may determine what happened by calling
clGetDeviceInfo( CL_DEVICE_PARTITION_TYPE )
on the sub-devices.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><em>num_devices</em> is the size of memory pointed to by <em>out_devices</em>
specified as the number of cl_device_id entries.</p></div>
<div class="paragraph"><p><em>out_devices</em> is the buffer where the OpenCL sub-devices will be
returned. If <em>out_devices_is NULL, this argument is ignored. If
_out_devices</em> is not NULL, <em>num_devices</em> must be greater than or equal
to the number of sub-devices that <em>device</em> may be partitioned into
according to the partitioning scheme specified in <em>properties</em>.</p></div>
<div class="paragraph"><p><em>num_devices_ret</em> returns the number of sub-devices that <em>device</em> may be
partitioned into according to the partitioning scheme specified in
<em>properties</em>. If <em>num_devices_ret</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><strong>clCreateSubDevices</strong> returns CL_SUCCESS if the partition is created
successfully. Otherwise, it returns a NULL value with the following
error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_DEVICE if
<em>in_device</em> is not valid.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if values
specified in <em>properties</em> are not valid or if values specified in
<em>properties</em> are valid but not supported by the device.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>out_devices</em> is not NULL and <em>num_devices</em> is less than the number of
sub-devices created by the partition scheme.
</p>
</li>
<li>
<p>
CL_DEVICE_PARTITION_FAILED
if the partition name is supported by the implementation but in_device
could not be further partitioned.
</p>
</li>
<li>
<p>
CL_INVALID_DEVICE_PARTITION_COUNT if the partition name specified in
<em>properties</em> is CL_DEVICE_PARTITION_BY_COUNTS and the number of
sub-devices requested exceeds CL_DEVICE_PARTITION_MAX_SUB_DEVICES or the
total number of compute units requested exceeds
CL_DEVICE_PARTITION_MAX_COMPUTE_UNITS for <em>in_device</em>, or the number of
compute units requested for one or more sub-devices is less than zero or
the number of sub-devices requested exceeds
CL_DEVICE_PARTITION_MAX_COMPUTE_UNITS for <em>in_device</em>.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>A few examples that describe how to specify partition properties in
<em>properties</em> argument to <strong>clCreateSubDevices</strong> are given below:</p></div>
<div class="paragraph"><p>To partition a device containing 16 compute units into two sub-devices,
each containing 8 compute units, pass the following in <em>properties</em>:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>{ CL_DEVICE_PARTITION_EQUALLY, 8, 0 }</pre>
</div></div>
<div class="paragraph"><p>To partition a device with four compute units into two sub-devices with
one sub-device containing 3 compute units and the other sub-device 1
compute unit, pass the following in properties argument:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>{ CL_DEVICE_PARTITION_BY_COUNTS,
3, 1, CL_DEVICE_PARTITION_BY_COUNTS_LIST_END, 0 }</pre>
</div></div>
<div class="paragraph"><p>To split a device along the outermost cache line (if any), pass the
following in properties argument:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>{ CL_DEVICE_PARTITION_BY_AFFINITY_DOMAIN,
CL_DEVICE_AFFINITY_DOMAIN_NEXT_PARTITIONABLE,
0 }</pre>
</div></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainDevice(cl_device_id device)</pre>
</div></div>
<div class="paragraph"><p>increments the <em>device</em> reference count if <em>device</em> is a valid
sub-device created by a call to <strong>clCreateSubDevices</strong>. If <em>device</em> is a
root level device i.e. a cl_device_id returned by <strong>clGetDeviceIDs</strong>, the
<em>device</em> reference count remains unchanged. <strong>clRetainDevice</strong> returns
CL_SUCCESS if the function is executed successfully or the device is a
root-level device. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_DEVICE if
<em>device</em> is not a valid sub-device created by a call to
<strong>clCreateSubDevices</strong>.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
 
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseDevice(cl_device_id device)</pre>
</div></div>
<div class="paragraph"><p>decrements the <em>device</em> reference count if device is a valid sub-device
created by a call to <strong>clCreateSubDevices</strong>. If <em>device</em> is a root level
device i.e. a cl_device_id returned by <strong>clGetDeviceIDs</strong>, the <em>device</em>
reference count remains unchanged. <strong>clReleaseDevice</strong> returns CL_SUCCESS
if the function is executed successfully. Otherwise, it returns one of
the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_DEVICE if <em>device</em> is not a valid sub-device created by a call to
<strong>clCreateSubDevices</strong>.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>After the <em>device</em> reference count becomes zero and all the objects
attached to <em>device</em> (such as command-queues) are released, the <em>device</em>
object is deleted. Using this function to release a reference that was
not obtained by creating the object or by calling <strong>clRetainDevice</strong>
causes undefined behavior.</p></div>
</div>
<div class="sect2">
<h3 id="_contexts">4.4. Contexts</h3>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_context clCreateContext(const cl_context_properties *properties,
cl_uint num_devices,
const cl_device_id *devices,
void(CL_CALLBACK *pfn_notify)
(const char *errinfo,
const void *private_info,
size_t cb,
void *user_data),
void *user_data,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates an OpenCL context. An OpenCL context is created with one or
more devices. Contexts are used by the OpenCL runtime for managing
objects such as command-queues, memory, program and kernel objects and
for executing kernels on one or more devices specified in the context.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>properties_specifies a list of context property names and their
corresponding values. Each property name is immediately followed by the
corresponding desired value. The list is terminated with 0. The list of
supported properties is described in _table 4.5.</em> <em>properties</em> can be
NULL in which case the platform that is selected is
implementation-defined.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 5. <em>List of supported properties by</em> <strong>clCreateContext</strong></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_context_properties enum</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Property value</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CONTEXT_PLATFORM</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_platform_id</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Specifies the platform to use.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CONTEXT_INTEROP_ USER_SYNC</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Specifies whether the user is
responsible for synchronization
between OpenCL and other APIs.
Please refer to the specific sections
in the OpenCL 2.0 extension
specification that describe sharing
with other APIs for restrictions on
using this flag.
<br>
<br>
If CL_CONTEXT_INTEROP_USER_
SYNC is not specified, a default of
CL_FALSE is assumed.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><em>num_devices</em> is the number of devices specified in the <em>devices</em>
argument.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>devices</em> is a pointer to a list of unique deviceslink<span class="footnote"><br>[Duplicate devices specified in <em>devices</em> are ignored.]<br></span>
returned by <strong>clGetDeviceIDs</strong> or sub-devices created by
<strong>clCreateSubDevices</strong> for a platform.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>pfn_notify</em> is a callback function that can be registered by the
application. This callback function will be used by the OpenCL
implementation to report information on errors during context creation
as well as errors that occur at runtime in this context. This callback
function may be called asynchronously by the OpenCL implementation. It
is the applications responsibility to ensure that the callback function
is thread-safe. The parameters to this callback function are:</p></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
<em>errinfo</em> is a pointer to
an error string.
</p>
</li>
<li>
<p>
<em>private_info</em> and <em>cb</em>
represent a pointer to binary data that is returned by the OpenCL
implementation that can be used to log additional information helpful in
debugging the error.
</p>
</li>
<li>
<p>
<em>user_data</em> is a pointer
to user supplied data.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>If <em>pfn_notify</em> is NULL, no callback function is registered.</p></div>
<div class="paragraph"><p> </p></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">There are a number of cases where error notifications need to be
delivered due to an error that occurs outside a context. Such
notifications may not be delivered through the <em>pfn_notify</em> callback.
 Where these notifications go is implementation-defined.</td>
</tr></table>
</div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>user_data</em> will be passed as the <em>user_data</em> argument when <em>pfn_notify</em>
is called. <em>user_data</em> can be NULL.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>clCreateContext</strong> returns a valid non-zero context and <em>errcode_ret</em> is
set to CL_SUCCESS if the context is created successfully. Otherwise, it
returns a NULL value with the following error values returned in
<em>errcode_ret</em>:</p></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_PLATFORM if
<em>properties_is NULL and no platform could be selected or if platform
value specified in _properties</em> is not a valid platform.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_PROPERTY if
context property name in <em>properties</em> is not a supported property name,
if the value specified for a supported property name is not valid, or if
the same property name is specified more than once.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
_devices_is NULL.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
_num_devices_is equal to zero.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>pfn_notify</em> is NULL but <em>user_data</em> is not NULL.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_DEVICE if
<em>devices</em> contains an invalid device.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_DEVICE_NOT_AVAILABLE if
a device in <em>devices</em> is currently not available even though the device
was returned by <strong>clGetDeviceIDs</strong>.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function<span class="footnote"><br>[<strong>clCreateContextfromType</strong> may return all or a subset of the actual physical devices present in the platform and
that match device_type.]<br></span></p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_context clCreateContextFromType(const cl_context_properties *properties,
cl_device_type device_type,
void(CL_CALLBACK *pfn_notify)
(const char *errinfo,
const void *private_info,
size_t cb,
void *user_data),
void *user_data,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates an OpenCL context from a device type that identifies the
specific device(s) to use. Only devices that are returned by
<strong>clGetDeviceIDs</strong> for <em>device_type</em> are used to create the context. The
context does not reference any sub-devices that may have been created
from these devices.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>properties_specifies a list of context property names and their
corresponding values. Each property name is immediately followed by the
corresponding desired value. The list of supported properties is
described in _table 4.5</em>. <em>properties</em> can also be NULL in which case
the platform that is selected is implementation-defined.</p></div>
<div class="paragraph"><p><em>device_type</em> is a bit-field that identifies the type of device and is
described in <em>table 4.2</em> in <em>section 4.2</em>.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>pfn_notify</em> and <em>user_data</em> are described in <strong>clCreateContext</strong>.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>clCreateContextFromType</strong> returns a valid non-zero context and
<em>errcode_ret</em> is set to CL_SUCCESS if the context is created
successfully. Otherwise, it returns a NULL value with the following
error values returned in <em>errcode_ret</em>:</p></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_PLATFORM if
<em>properties_is NULL and no platform could be selected or if platform
value specified in _properties</em> is not a valid platform.
</p>
</li>
<li>
<p>
CL_INVALID_PROPERTY if
context property name in <em>properties</em> is not a supported property name,
if the value specified for a supported property name is not valid, or if
the same property name is specified more than once.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>pfn_notify</em> is NULL but <em>user_data</em> is not NULL.
</p>
</li>
<li>
<p>
CL_INVALID_DEVICE_TYPE if
<em>device_type</em> is not a valid value.
</p>
</li>
<li>
<p>
CL_DEVICE_NOT_AVAILABLE if
no devices that match <em>device_type</em> and property values specified in
<em>properties</em> are currently available.
</p>
</li>
<li>
<p>
CL_DEVICE_NOT_FOUND if no
devices that match <em>device_type</em> and property values specified in
<em>properties</em> were found.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainContext(cl_context context)</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>increments the <em>context</em> reference count. <strong>clRetainContext</strong> returns
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_CONTEXT if
<em>context</em> is not a valid OpenCL context.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>clCreateContext*and*clCreateContextFromType</strong> perform an implicit
retain. This is very helpful for 3<sup>rd</sup> party libraries, which typically
get a context passed to them by the application. However, it is
possible that the application may delete the context without informing
the library. Allowing functions to attach to (i.e. retain) and release
a context solves the problem of a context being used by a library no
longer being valid.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The function</p></div>
<div class="paragraph"><p> </p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseContext(cl_context context)</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>decrements the <em>context</em> reference count. <strong>clReleaseContext</strong> returns
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_CONTEXT if
<em>context</em> is not a valid OpenCL context.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>After the <em>context</em> reference count becomes zero and all the objects
attached to <em>context</em> (such as memory objects, command-queues) are
released, the <em>context</em> is deleted. Using this function to release a
reference that was not obtained by creating the object or by calling
*clRetainContext*causes undefined behavior.
The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetContextInfo(cl_context context,
cl_context_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>can be used to query information about a context.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>context</em> specifies the OpenCL context being queried.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>param_name</em> is an enumeration constant that specifies the information
to query.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>param_value_size</em> specifies the size in bytes of memory pointed to by
<em>param_value</em>. This size must be greater than or equal to the size of
return type as described in <em>table 4.6</em>.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The list of supported <em>param_name_values and the information returned in
_param_value</em> by <strong>clGetContextInfo</strong> is described in <em>table 4.6</em>.</p></div>
<div class="paragraph"><div class="title">List of supported param_names</div><p>by <strong>clGetContextInfo</strong></p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_context_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Information returned in param_value</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CONTEXT_ REFERENCE_COUNT</strong> <span class="footnote"><br>[The reference count returned should be considered immediately stale. It is unsuitable for general use in
applications. This feature is provided for identifying memory leaks.]<br></span></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the <em>context</em> reference
count.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CONTEXT_NUM_DEVICES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the number of devices in <em>context</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CONTEXT_DEVICES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_id[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the list of devices and
sub-devices in <em>context</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CONTEXT_PROPERTIES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_context_properties[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the properties argument
specified in <strong>clCreateContext</strong> or
<strong>clCreateContextFromType</strong>.
<br>
<br>
If the <em>properties</em> argument specified
in <strong>clCreateContext</strong> or
<strong>clCreateContextFromType</strong> used
to create <em>context</em> is not NULL , the
implementation must return the
values specified in the properties
argument.
<br>
<br>
If the <em>properties</em> argument specified
in <strong>clCreateContext</strong> or
<strong>clCreateContextFromType</strong> used
to create <em>context</em> is NULL , the
implementation may return either a
<em>param_value_size_ret</em> of 0 i.e. there
is no context property value to be
returned or can return a context
property value of 0 (where 0 is used
to terminate the context properties
list) in the memory that
<em>param_value</em> points to.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetContextInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="paragraph"><p> </p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_CONTEXT if
<em>context</em> is not a valid context.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>param_name</em> is not one of the supported values or if size in bytes
specified by <em>param_value_size_is &lt; size of return type as specified in
_table 4.6</em> and <em>param_value</em> is not a NULL value.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
</div>
</div>
</div>
<div class="sect1">
<h2 id="_the_opencl_runtime">5. The OpenCL Runtime</h2>
<div class="sectionbody">
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In this section we describe the API calls that manage OpenCL objects
such as command-queues, memory objects, program objects, kernel objects
for kernel functions in a program and calls that allow you to enqueue
commands to a command-queue such as executing a kernel, reading, or
writing a memory object.</p></div>
<div class="sect2">
<h3 id="_command_queues">5.1. Command Queues</h3>
<div class="paragraph"><p>OpenCL objects such as memory, program and kernel objects are created
using a context. Operations on these objects are performed using a
command-queue. The command-queue can be used to queue a set of
operations (referred to as commands) in order. Having multiple
command-queues allows applications to queue multiple independent
commands without requiring synchronization. Note that this should work
as long as these objects are not being shared. Sharing of objects
across multiple command-queues will require the application to perform
appropriate synchronization. This is described in <em>Appendix A</em>.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_command_queue clCreateCommandQueueWithProperties(
cl_context context,
cl_device_id device,
const cl_queue_properties *properties,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates a host or device command-queue on a specific device.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>device</em> must be a device or sub-device associated with <em>context</em>. It
can either be in the list of devices and sub-devices specified when
<em>context</em> is created using <strong>clCreateContext  or
be a root device with the same device type as specified when <em>context</em>
is created using *clCreateContextFromType</strong>.</p></div>
<div class="paragraph"><p><em>properties</em> specifies a list of properties for the command-queue and
their corresponding values. Each property name is immediately followed
by the corresponding desired value. The list is terminated with 0. The
list of supported properties is described in the table below_._ If a
supported property and its value is not specified in <em>properties</em>, its
default value will be used. <em>properties</em> can be NULL in which case the
default values for supported command-queue properties will be used.
 </p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 6. <em>List of supported cl_queue_properties values and description</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Queue Properties</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Property Value</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_QUEUE_PROPERTIES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bitfield</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This is a bitfield and can be set to a
CL_QUEUE_OUT_OF_ORDER_ EXEC_MODE_ENABLE
– Determines whether the
commands queued in the command-queue are executed in-order or out-of-order. If
set, the commands in the command-queue are executed out-of-order. Otherwise,
commands are executed in-order.
<br>
<br>
CL_QUEUE_PROFILING_ENABLE – Enable or disable profiling of commands in
the command-queue. If set, the profiling of commands is enabled. Otherwise profiling
of commands is disabled.
<br>
<br>
CL_QUEUE_ON_DEVICE – Indicates that this is a device queue. If
<br>
<br>
CL_QUEUE_ON_DEVICE is set, CL_QUEUE_OUT_OF_ORDER_ EXEC_MODE_ENABLE<span class="footnote"><br>[Only out-of-order device queues are supported.]<br></span>: must also be set.
<br>
<br>
CL_QUEUE_ ON_DEVICE_DEFAULT<span class="footnote"><br>[The application must create the default device queue if any kernels containing calls to get_default_queue are
enqueued. There can only be one default device queue for each device within a context.
clCreateCommandQueueWithProperties with CL_QUEUE_PROPERTIES set to CL_QUEUE_ON_DEVICE or
CL_QUEUE_ON_DEVICE_DEFAULT will return the default device queue that has already been created and
increment its retain count by 1.]<br></span>:–indicates that this is the default device
queue. This can only be used with CL_QUEUE_ON_DEVICE.
<br>
<br>
If CL_QUEUE_PROPERTIES is not specified an in-order host command queue
is created for the specified device</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_QUEUE_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Specifies the size of the device queue in bytes.
<br>
<br>
This can only be specified if CL_QUEUE_ON_DEVICE is set in CL_QUEUE_PROPERTIES.
This must be a value &#8656; CL_DEVICE_QUEUE_ ON_DEVICE_MAX_SIZE.
<br>
<br>
For best performance, this should be &#8656; CL_DEVICE_QUEUE_ ON_DEVICE_PREFERRED_SIZE.
<br>
<br>
If CL_QUEUE_SIZE is not specified, the device queue is created with
CL_DEVICE_QUEUE_ ON_DEVICE_PREFERRED_SIZE as the size of the queue.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> 
<em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateCommandQueueWithProperties</strong> returns a valid non-zero
command-queue and <em>errcode_ret</em> is set to CL_SUCCESS if the
command-queue is created successfully. Otherwise, it returns a NULL
value with one of the following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
CL_INVALID_DEVICE if
<em>device_is not a valid device or is not associated with _context</em>.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if values
specified in <em>properties</em> are not valid.
</p>
</li>
<li>
<p>
CL_INVALID_QUEUE_PROPERTIES if values specified in <em>properties</em> are
valid but are not supported by the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetDefaultDeviceCommandQueue(cl_context context,
cl_device_id device,
cl_command_queue command_queue)</pre>
</div></div>
<div class="paragraph"><p>replaces the default command queue on the <em>device</em>.</p></div>
<div class="paragraph"><p><strong>clSetDefaultDeviceCommandQueue</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_CONTEXT if <em>context</em> is not a valid context.
</p>
</li>
<li>
<p>
CL_INVALID_DEVICE if <em>device</em> is not a valid device or is not associated with <em>context</em>.
</p>
</li>
<li>
<p>
CL_INVALID_COMMAND_QUEUE if <em>command_queue</em> is not a valid command-queue for <em>device</em>.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>clSetDefaultDeviceCommandQueue</strong> may be used to replace a default device
command queue created with <strong>clCreateCommandQueueWithProperties</strong> and the
CL_QUEUE_ON_DEVICE_DEFAULT flag.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainCommandQueue(cl_command_queue command_queue)</pre>
</div></div>
<div class="paragraph"><p>increments the <em>command_queue</em> reference count. <strong>clRetainCommandQueue</strong>
returns CL_SUCCESS if the function is executed successfully. Otherwise,
it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_COMMAND_QUEUE if <em>command_queue</em> is not a valid command-queue.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>clCreateCommandQueueWithProperties</strong> performs an implicit retain. This
is very helpful for 3<sup>rd</sup> party libraries, which typically get a
command-queue passed to them by the application. However, it is
possible that the application may delete the command-queue without
informing the library. Allowing functions to attach to (i.e. retain)
and release a command-queue solves the problem of a command-queue being
used by a library no longer being valid.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseCommandQueue(cl_command_queue command_queue)</pre>
</div></div>
<div class="paragraph"><p>decrements the <em>command_queue</em> reference count. <strong>clReleaseCommandQueue</strong>
returns CL_SUCCESS if the function is executed successfully. Otherwise,
it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_COMMAND_QUEUE if <em>command_queue</em> is not a valid command-queue.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>After the <em>command_queue</em> reference count becomes zero and all commands
queued to <em>command_queue</em> have finished (eg. kernel-instances, memory
object updates etc.), the command-queue is deleted.</p></div>
<div class="paragraph"><p><strong>clReleaseCommandQueue</strong> performs an implicit flush to issue any
previously queued OpenCL commands in <em>command_queue</em>. Using this
function to release a reference that was not obtained by creating the
object or by calling <strong>clRetainCommandQueue</strong> causes undefined behavior.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetCommandQueueInfo(cl_command_queue command_queue,
cl_command_queue_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>can be used to query information about a command-queue.</p></div>
<div class="paragraph"><p><em>command_queue</em> specifies the command-queue being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.2</em>. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<div class="paragraph"><p>The list of supported <em>param_name_values and the information returned in
_param_value</em> by <strong>clGetCommandQueueInfo</strong> is described in <em>table 5.2</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 7. <em>List of supported param_names by clGetCommandQueueInfo</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_command_queue_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Information returned in
param_value</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_QUEUE_CONTEXT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_context</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the context specified when the
command-queue is created.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_QUEUE_DEVICE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_id</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the device specified when the
command-queue is created.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_QUEUE_REFERENCE_COUNT<span class="footnote"><br>[The reference count returned should be considered immediately stale. It is unsuitable for general use in
applications. This feature is provided for identifying memory leaks.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the command-queue reference count.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_QUEUE_PROPERTIES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_command_queue_properties</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the currently specified properties for the
command-queue. These properties are specified by the value associated
with the CL_COMMAND_QUEUE_ PROPERTIES passed in <em>properties</em> argument in
<strong>clCreateCommandQueueWithProperties.</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_QUEUE_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the currently specified size for the
device command-queue. This query is only supported for device command
queues.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_QUEUE_DEVICE_DEFAULT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_command_queue</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the current default
command queue for the underlying device.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetCommandQueueInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_COMMAND_QUEUE if <em>command_queue</em> is not a valid command-queue.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if <em>param_name</em> is not one of the supported values or if size in bytes
specified by <em>param_value_size_is &lt; size of return type as specified in
_table 5.2</em> and <em>param_value</em> is not a NULL value.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>NOTE</strong></p></div>
<div class="paragraph"><p>It is possible that a device(s) becomes unavailable after a context and
command-queues that use this device(s) have been created and commands
have been queued to command-queues. In this case the behavior of OpenCL
API calls that use this context (and command-queues) are considered to
be implementation-defined. The user callback function, if specified,
when the context is created can be used to record appropriate
information in the <em>errinfo</em>, <em>private_info</em> arguments passed to the
callback function when the device becomes unavailable.</p></div>
</div>
<div class="sect2">
<h3 id="_buffer_objects">5.2. Buffer Objects</h3>
<div class="paragraph"><p>A <em>buffer</em> object stores a one-dimensional collection of elements.
Elements of a <em>buffer</em> object can be a scalar data type (such as an int,
float), vector data type, or a user-defined structure.</p></div>
<div class="sect3">
<h4 id="_creating_buffer_objects">5.2.1. Creating Buffer Objects</h4>
<div class="paragraph"><p>A <strong>buffer object</strong> is created using the following function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_mem clCreateBuffer(cl_context context,
cl_mem_flags flags,
size_t size,
void *host_ptr,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p><em>context</em> is a valid OpenCL context used to create the buffer object.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify allocation and usage
information such as the memory arena that should be used to allocate the
buffer object and how it will be used. <em>Table 5.3</em> describes the
possible values for <em>flags</em>. If value specified for <em>flags</em> is 0, the
default is used which is CL_MEM_READ_WRITE.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 8. <em>List of supported cl_mem_flags values</em></caption>
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_mem_flags</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_READ_WRITE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the memory object will be read
and written by a kernel. This is the default.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_WRITE_ONLY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the memory object will be
written but not read by a kernel.
<br>
<br>
Reading from a buffer or image object created with
CL_MEM_WRITE_ONLY inside a kernel is undefined.
<br>
<br>
CL_MEM_READ_WRITE and
CL_MEM_WRITE_ONLY are mutually exclusive.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_READ_ONLY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the memory object is a readonly memory object when used inside a kernel.
<br>
<br>
Writing to a buffer or image object created with
CL_MEM_READ_ONLY inside a kernel is undefined.
<br>
<br>
CL_MEM_READ_WRITE or CL_MEM_WRITE_ONLY
and CL_MEM_READ_ONLY are mutually exclusive.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_USE_HOST_PTR</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag is valid only if host_ptr is not NULL. If
specified, it indicates that the application wants the
OpenCL implementation to use memory referenced by
host_ptr as the storage bits for the memory object.
<br>
<br>
OpenCL implementations are allowed to cache the
buffer contents pointed to by host_ptr in device
memory. This cached copy can be used when kernels
are executed on a device.
<br>
<br>
The result of OpenCL commands that operate on
multiple buffer objects created with the same host_ptr
or from overlapping host or SVM regions is
considered to be undefined.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_ALLOC_HOST_PTR</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the application wants the
OpenCL implementation to allocate memory from
host accessible memory.
<br>
<br>
CL_MEM_ALLOC_HOST_PTR and
CL_MEM_USE_HOST_PTR are mutually exclusive.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_COPY_HOST_PTR</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag is valid only if host_ptr is not NULL. If
specified, it indicates that the application wants the
OpenCL implementation to allocate memory for the
memory object and copy the data from memory
referenced by host_ptr. The implementation will copy
the memory immediately and host_ptr is available for
reuse by the application when the clCreateBuffer or
clCreateImage operation returns.
<br>
<br>
CL_MEM_COPY_HOST_PTR and
CL_MEM_USE_HOST_PTR are mutually exclusive.
<br>
<br>
CL_MEM_COPY_HOST_PTR can be used with
CL_MEM_ALLOC_HOST_PTR to initialize the
contents of the cl_mem object allocated using hostaccessible (e.g. PCIe) memory.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_HOST_WRITE_ONLY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the host will only
write to the memory object (using OpenCL APIs that enqueue a write or a
map for write). This can be used to optimize write access from the host
(e.g. enable write-combined allocations for memory objects for devices
that communicate with the host over a system bus such as PCIe).</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_HOST_READ_ONLY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the host will only read the
memory object (using OpenCL APIs that enqueue a
read or a map for read).
<br>
<br>
CL_MEM_HOST_WRITE_ONLY and
CL_MEM_HOST_READ_ONLY are mutually
exclusive.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_HOST_NO_ACCESS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the host will not read or write
the memory object.
<br>
<br>
CL_MEM_HOST_WRITE_ONLY or
CL_MEM_HOST_READ_ONLY and
CL_MEM_HOST_NO_ACCESS are mutually
exclusive.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><em>size</em> is the size in bytes of the buffer memory object to be allocated.</p></div>
<div class="paragraph"><p><em>host_ptr</em> is a pointer to the buffer data that may already be allocated
by the application. The size of the buffer that <em>host_ptr</em> points to
must be &gt;= <em>size</em> bytes.</p></div>
<div class="paragraph"><p>The user is responsible for ensuring that data passed into and out of
OpenCL images are natively aligned relative to the start of the buffer
as per kernel language or IL requirements. OpenCL buffers created with
CL_MEM_USE_HOST_PTR need to provide an appropriately aligned host memory
pointer that is aligned to the data types used to access these buffers
in a kernel(s).</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p>If <strong>clCreateBuffer</strong> is called with a pointer returned by <strong>clSVMAlloc</strong> as
its <em>host_ptr</em> argument, and CL_MEM_USE_HOST_PTR is set in its <em>flags</em>
argument, <strong>clCreateBuffer</strong> will succeed and return a valid non-zero
buffer object as long as the <em>size</em> argument to <strong>clCreateBuffer</strong> is no
larger than the <em>size</em> argument passed in the original <strong>clSVMAlloc</strong>
call. The new buffer object returned has the shared memory as the
underlying storage. Locations in the buffers underlying shared memory
can be operated on using atomic operations to the devices level of
support as defined in the memory model.</p></div>
<div class="paragraph"><p><strong>clCreateBuffer</strong> returns a valid non-zero buffer object and
<em>errcode_ret</em> is set to CL_SUCCESS if the buffer object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_CONTEXT if _context_is not a valid context.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if values specified in <em>flags_are not valid as defined in _table 5.3</em>.
</p>
</li>
<li>
<p>
CL_INVALID_BUFFER_SIZE if <em>size</em> is 0<span class="footnote"><br>[Implementations may return CL_INVALID_BUFFER_SIZE if size is greater than
CL_DEVICE_MAX_MEM_ALLOC_SIZE value specified in <em>table 4.3</em> for all devices in context. ]<br></span>:.
</p>
</li>
<li>
<p>
CL_INVALID_HOST_PTR if <em>host_ptr</em> is NULL and CL_MEM_USE_HOST_PTR or CL_MEM_COPY_HOST_PTR are
set in <em>flags</em> or if <em>host_ptr</em> is not NULL but CL_MEM_COPY_HOST_PTR or
CL_MEM_USE_HOST_PTR are not set in <em>flags</em>.
</p>
</li>
<li>
<p>
CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for buffer object.
</p>
</li>
<li>
<p>
CL_OUT_OF_RESOURCES if there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
CL_OUT_OF_HOST_MEMORY if there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_mem clCreateSubBuffer(cl_mem buffer,
cl_mem_flags flags,
cl_buffer_create_type buffer_create_type,
const void *buffer_create_info,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>can be used to create a new buffer object (referred to as a sub-buffer
object) from an existing buffer object.</p></div>
<div class="paragraph"><p><em>buffer</em> must be a valid buffer object and cannot be a sub-buffer
object.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify allocation and usage
information about the sub-buffer memory object being created and is
described in <em>table 5.3</em>. If the CL_MEM_READ_WRITE, CL_MEM_READ_ONLY or
CL_MEM_WRITE_ONLY values are not specified in <em>flags</em>, they are
inherited from the corresponding memory access qualifers associated with
<em>buffer</em>. The CL_MEM_USE_HOST_PTR, CL_MEM_ALLOC_HOST_PTR and
CL_MEM_COPY_HOST_PTR values cannot be specified in <em>flags</em> but are
inherited from the corresponding memory access qualifiers associated
with <em>buffer</em>. If CL_MEM_COPY_HOST_PTR is specified in the memory
access qualifier values associated with <em>buffer</em> it does not imply any
additional copies when the sub-buffer is created from <em>buffer</em>. If the
CL_MEM_HOST_WRITE_ONLY, CL_MEM_HOST_READ_ONLY or CL_MEM_HOST_NO_ACCESS
values are not specified in <em>flags</em>, they are inherited from the
corresponding memory access qualifiers associated with <em>buffer</em>.</p></div>
<div class="paragraph"><p><em>buffer_create_type_and _buffer_create_info</em> describe the type of buffer
object to be created. The list of supported values for
<em>buffer_create_type</em> and corresponding descriptor that
<em>buffer_create_info</em> points to is described in <em>table 5.4</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 9. <em>List of supported names and values in clCreateSubBuffer</em></caption>
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_buffer_create_type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_BUFFER_CREATE_TYPE_REGION</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Create a buffer object that represents a specific
region in buffer.
<br>
<br>
buffer_create_info is a pointer to the following
structure:
typedef struct _cl_buffer_region {
size_t origin;
size_t size;
} cl_buffer_region;
<br>
<br>
(origin, size) defines the offset and size in bytes in
buffer.
<br>
<br>
If buffer is created with
CL_MEM_USE_HOST_PTR, the host_ptr
associated with the buffer object returned is
host_ptr + origin.
<br>
<br>
The buffer object returned references the data store
allocated for buffer and points to a specific region
given by (origin, size) in this data store.
<br>
<br>
CL_INVALID_VALUE is returned in errcode_ret if
the region specified by (origin, size) is out of
bounds in buffer.
<br>
<br>
CL_INVALID_BUFFER_SIZE if size is 0.
<br>
<br>
CL_MISALIGNED_SUB_BUFFER_OFFSET is
returned in errcode_ret if there are no devices in
context associated with buffer for which the origin
value is aligned to the
CL_DEVICE_MEM_BASE_ADDR_ALIGN value.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clCreateSubBuffer</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors in
<em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_MEM_OBJECT if
<em>buffer</em> is not a valid buffer object or is a sub-buffer object.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>buffer</em> was created with CL_MEM_WRITE_ONLY and <em>flags</em> specifies
CL_MEM_READ_WRITE or CL_MEM_READ_ONLY, or if <em>buffer</em> was created with
CL_MEM_READ_ONLY and <em>flags</em> specifies CL_MEM_READ_WRITE or
CL_MEM_WRITE_ONLY, or if <em>flags</em> specifies CL_MEM_USE_HOST_PTR or
CL_MEM_ALLOC_HOST_PTR or CL_MEM_COPY_HOST_PTR.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
<em>buffer</em> was created with CL_MEM_HOST_WRITE_ONLY and <em>flags</em> specify
CL_MEM_HOST_READ_ONLY, or if <em>buffer</em> was created with
CL_MEM_HOST_READ_ONLY and <em>flags</em> specify CL_MEM_HOST_WRITE_ONLY, or if
<em>buffer</em> was created with CL_MEM_HOST_NO_ACCESS and <em>flags</em> specify
CL_MEM_HOST_READ_ONLY or CL_MEM_HOST_WRITE_ONLY.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if value
specified in _buffer_create_type_is not valid.
</p>
</li>
<li>
<p>
CL_INVALID_VALUE if
value(s) specified in <em>buffer_create_info</em> (for a given
<em>buffer_create_type</em>) is not valid or if <em>buffer_create_info</em> is NULL.
</p>
</li>
<li>
<p>
CL_INVALID_BUFFER_SIZE if <em>size</em> is 0.
</p>
</li>
<li>
<p>
CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for sub-buffer object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>NOTE:</p></div>
<div class="paragraph"><p>Concurrent reading from, writing to and copying between both a buffer
object and its sub-buffer object(s) is undefined. Concurrent reading
from, writing to and copying between overlapping sub-buffer objects
created with the same buffer object is undefined. Only reading from
both a buffer object and its sub-buffer objects or reading from multiple
overlapping sub-buffer objects is defined.</p></div>
</div>
<div class="sect3">
<h4 id="_reading_writing_and_copying_buffer_objects">5.2.2. Reading, Writing and Copying Buffer Objects</h4>
<div class="paragraph"><p>The following functions enqueue commands to read from a buffer object to
host memory or write to a buffer object from host memory.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueReadBuffer(cl_command_queue command_queue,
cl_mem buffer,
cl_bool blocking_read,
size_t offset,
size_t size,
void *ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueWriteBuffer(cl_command_queue command_queue,
cl_mem buffer,
cl_bool blocking_write,
size_t offset,
size_t size,
const void *ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command-queue in which the read / write
command will be queued. <em>command_queue</em> and <em>buffer</em> must be created
with the same OpenCL context.</p></div>
<div class="paragraph"><p><em>buffer</em> refers to a valid buffer object.</p></div>
<div class="paragraph"><p><em>blocking_read</em> and <em>blocking_write</em> indicate if the read and write
operations are <em>blocking</em> or <em>non-blocking</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_read</em> is CL_TRUE i.e. the read command is blocking,
<strong>clEnqueueReadBuffer</strong> does not return until the buffer data has been
read and copied into memory pointed to by <em>ptr</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_read</em> is CL_FALSE i.e. the read command is non-blocking,
<strong>clEnqueueReadBuffer</strong> queues a non-blocking read command and returns.
The contents of the buffer that <em>ptr</em> points to cannot be used until the
read command has completed. The <em>event</em> argument returns an event
object which can be used to query the execution status of the read
command. When the read command has completed, the contents of the
buffer that _ptr_points to__can be used by the application.</p></div>
<div class="paragraph"><p>If <em>blocking_write_is CL_TRUE, the OpenCL implementation copies the data
referred to by _ptr</em> and enqueues the write operation in the
command-queue. The memory pointed to by <em>ptr</em> can be reused by the
application after the <strong>clEnqueueWriteBuffer</strong> call returns.</p></div>
<div class="paragraph"><p>If <em>blocking_write</em> is CL_FALSE, the OpenCL implementation will use
<em>ptr</em> to perform a non-blocking write. As the write is non-blocking the
implementation can return immediately. The memory pointed to by <em>ptr</em>
cannot be reused by the application after the call returns. The <em>event</em>
argument returns an event object which can be used to query the
execution status of the write command. When the write command has
completed, the memory pointed to by <em>ptr</em> can then be reused by the
application.</p></div>
<div class="paragraph"><p><em>offset</em> is the offset in bytes in the buffer object to read from or
write to.</p></div>
<div class="paragraph"><p><em>size</em> is the size in bytes of data being read or written.</p></div>
<div class="paragraph"><p><em>ptr</em> is the pointer to buffer in host memory where data is to be read
into or to be written from.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular read /
write command and can be used to query or queue a wait for this
particular command to complete. <em>event</em> can be NULL in which case it
will not be possible for the application to query the status of this
command or queue a wait for this command to complete. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueReadBuffer</strong> and <strong>clEnqueueWriteBuffer</strong> return CL_SUCCESS if
the function is executed successfully. Otherwise, it returns one of the
following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_INVALID_COMMAND_QUEUE if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
CL_INVALID_CONTEXT if the context associated with <em>command_queue</em> and <em>buffer</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>buffer</em> is not a valid buffer object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
region being read or written specified by (<em>offset</em>, <em>size</em>) is out of
bounds or if <em>ptr</em> is a NULL value.
</p>
</li>
<li>
<p>
CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>buffer</em> is a sub-buffer object and
<em>offset</em> specified when the sub-buffer object is created is not aligned
to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the read and write
operations are blocking and the execution status of any of the events in
<em>event_wait_list</em> is a negative integer value.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>buffer</em>.
</p>
</li>
<li>
<p>
     CL_INVALID_OPERATION if
<strong>clEnqueueReadBuffer</strong> is called on <em>buffer</em> which has been created with
CL_MEM_HOST_WRITE_ONLY or CL_MEM_HOST_NO_ACCESS.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
<strong>clEnqueueWriteBuffer</strong> is called on <em>buffer</em> which has been created with
CL_MEM_HOST_READ_ONLY or CL_MEM_HOST_NO_ACCESS.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following functions enqueue commands to read a 2D or 3D rectangular
region from a buffer object to host memory or write a 2D or 3D
rectangular region to a buffer object from host memory.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueReadBufferRect(cl_command_queue command_queue,
cl_mem buffer,
cl_bool blocking_read,
const size_t *buffer_origin,
const size_t *host_origin,
const size_t *region,
size_t buffer_row_pitch,
size_t buffer_slice_pitch,
size_t host_row_pitch,
size_t host_slice_pitch,
void *ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueWriteBufferRect(cl_command_queue command_queue,
cl_mem buffer,
cl_bool blocking_write,
const size_t *buffer_origin,
const size_t *host_origin,
const size_t *region,
size_t buffer_row_pitch,
size_t buffer_slice_pitch,
size_t host_row_pitch,
size_t host_slice_pitch,
const void *ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p><em>command_queue</em> refers is a valid host command-queue in which the read /
write command will be queued. <em>command_queue</em> and <em>buffer</em> must be
created with the same OpenCL context.</p></div>
<div class="paragraph"><p><em>buffer</em> refers to a valid buffer object.</p></div>
<div class="paragraph"><p><em>blocking_read</em> and <em>blocking_write</em> indicate if the read and write
operations are <em>blocking</em> or <em>non-blocking</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_read</em> is CL_TRUE i.e. the read command is blocking,
<strong>clEnqueueReadBufferRect</strong> does not return until the buffer data has been
read and copied into memory pointed to by <em>ptr</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_read</em> is CL_FALSE i.e. the read command is non-blocking,
<strong>clEnqueueReadBufferRect</strong> queues a non-blocking read command and
returns. The contents of the buffer that <em>ptr</em> points to cannot be used
until the read command has completed. The <em>event</em> argument returns an
event object which can be used to query the execution status of the read
command. When the read command has completed, the contents of the
buffer that _ptr_points to__can be used by the application.</p></div>
<div class="paragraph"><p>If <em>blocking_write_is CL_TRUE, the OpenCL implementation copies the data
referred to by _ptr</em> and enqueues the write operation in the
command-queue. The memory pointed to by <em>ptr</em> can be reused by the
application after the <strong>clEnqueueWriteBufferRect</strong> call returns.</p></div>
<div class="paragraph"><p>If <em>blocking_write</em> is CL_FALSE, the OpenCL implementation will use
<em>ptr</em> to perform a non-blocking write. As the write is non-blocking the
implementation can return immediately. The memory pointed to by <em>ptr</em>
cannot be reused by the application after the call returns. The <em>event</em>
argument returns an event object which can be used to query the
execution status of the write command. When the write command has
completed, the memory pointed to by <em>ptr</em> can then be reused by the
application.</p></div>
<div class="paragraph"><p><em>buffer_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in the memory region
associated with <em>buffer</em>. For a 2D rectangle region, the <em>z</em> value
given by <em>buffer_origin</em>[2] should be 0. The offset in bytes is
computed as <em>buffer_origin</em>[2] * <em>buffer_slice_pitch</em><br>
<em>buffer_origin</em>[1] * <em>buffer_row_pitch</em> + <em>buffer_origin</em>[0].</p></div>
<div class="paragraph"><p><em>host_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in the memory region
pointed to by <em>ptr</em>. For a 2D rectangle region, the <em>z</em> value given by
<em>host_origin</em>[2] should be 0. The offset in bytes is computed as
<em>host_origin</em>[2] * <em>host_slice_pitch</em> + <em>host_origin</em>[1] *
<em>host_row_pitch</em> + <em>host_origin</em>[0].</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em> in bytes, <em>height</em> in rows_,_ <em>depth_in
slices) of the 2D or 3D rectangle being read or written. For a 2D
rectangle copy, the _depth</em> value given by <em>region</em>[2] should be 1. The
values in region cannot be 0.</p></div>
<div class="paragraph"><p><em>buffer_row_pitch</em> is the length of each row in bytes to be used for the
memory region associated with <em>buffer</em>. If <em>buffer_row_pitch</em> is 0,
<em>buffer_row_pitch</em> is computed as <em>region</em>[0].</p></div>
<div class="paragraph"><p><em>buffer_slice_pitch</em> is the length of each 2D slice in bytes to be used
for the memory region associated with <em>buffer</em>. If <em>buffer_slice_pitch</em>
is 0, <em>buffer_slice_pitch</em> is computed as <em>region</em>[1] *
<em>buffer_row_pitch</em>.</p></div>
<div class="paragraph"><p><em>host_row_pitch</em> is the length of each row in bytes to be used for the
memory region pointed to by <em>ptr</em>. If <em>host_row_pitch</em> is 0,
<em>host_row_pitch</em> is computed as <em>region</em>[0].</p></div>
<div class="paragraph"><p><em>host_slice_pitch</em> is the length of each 2D slice in bytes to be used
for the memory region pointed to by <em>ptr</em>. If <em>host_slice_pitch</em> is 0,
<em>host_slice_pitch</em> is computed as <em>region</em>[1] * <em>host_row_pitch</em>.</p></div>
<div class="paragraph"><p><em>ptr</em> is the pointer to buffer in host memory where data is to be read
into or to be written from.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular read /
write command and can be used to query or queue a wait for this
particular command to complete. <em>event</em> can be NULL in which case it
will not be possible for the application to query the status of this
command or queue a wait for this command to complete. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueReadBufferRect</strong> and <strong>clEnqueueWriteBufferRect</strong> return
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em> and <em>buffer</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>buffer</em> is not a valid buffer object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
region being read or written specified by (<em>buffer_origin</em>, <em>region,
buffer_row_pitch, buffer_slice_pitch</em>) is out of bounds.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if <em>ptr</em>
is a NULL value.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if any
<em>region</em> array element is 0.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>buffer_row_pitch</em> is not 0 and is less than <em>region</em>[0].
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>host_row_pitch</em> is not 0 and is less than <em>region</em>[0].
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>buffer_slice_pitch</em> is not 0 and is less than <em>region</em>[1] *
<em>buffer_row_pitch</em> and not a multiple of <em>buffer_row_pitch</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>host_slice_pitch</em> is not 0 and is less than <em>region</em>[1] *
<em>host_row_pitch</em> and not a multiple of <em>host_row_pitch</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>buffer</em> is a sub-buffer object and
<em>offset</em> specified when the sub-buffer object is created is not aligned
to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the read and write
operations are blocking and the execution status of any of the events in
<em>event_wait_list</em> is a negative integer value.
 
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>buffer</em>.
</p>
</li>
<li>
<p>
     CL_INVALID_OPERATION if
<strong>clEnqueueReadBufferRect</strong> is called on <em>buffer</em> which has been created
with CL_MEM_HOST_WRITE_ONLY or CL_MEM_HOST_NO_ACCESS.
</p>
</li>
<li>
<p>
     CL_INVALID_OPERATION if
<strong>clEnqueueWriteBufferRect</strong> is called on <em>buffer</em> which has been created
with CL_MEM_HOST_READ_ONLY or CL_MEM_HOST_NO_ACCESS.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>NOTE:</p></div>
<div class="paragraph"><p>Calling <strong>clEnqueueReadBuffer</strong> to read a region of the buffer object with
the <em>ptr</em> argument value set to <em>host_ptr</em> + <em>offset</em>, where <em>host_ptr</em>
is a pointer to the memory region specified when the buffer object being
read is created with CL_MEM_USE_HOST_PTR, must meet the following
requirements in order to avoid undefined behavior:</p></div>
<div class="ulist"><ul>
<li>
<p>
All commands that use this buffer object or a memory object (buffer or
image) created from this buffer object have finished execution before
the read command begins execution.
</p>
</li>
<li>
<p>
The buffer object or memory objects created from this buffer object
are not mapped.
</p>
</li>
<li>
<p>
The buffer object or memory objects created from this buffer object
are not used by any command-queue until the read command has finished
execution.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Calling <strong>clEnqueueReadBufferRect</strong> to read a region of the buffer object
with the <em>ptr</em> argument value set to <em>host_ptr</em> and <em>host_origin</em>,
<em>buffer_origin</em> values are the same, where <em>host_ptr</em> is a pointer to
the memory region specified when the buffer object being read is created
with CL_MEM_USE_HOST_PTR, must meet the same requirements given above
for <strong>clEnqueueReadBuffer</strong>.</p></div>
<div class="paragraph"><p>Calling <strong>clEnqueueWriteBuffer</strong> to update the latest bits in a region of
the buffer object with the <em>ptr</em> argument value set to <em>host_ptr</em><br>
<em>offset</em>, where <em>host_ptr</em> is a pointer to the memory region specified
when the buffer object being written is created with
CL_MEM_USE_HOST_PTR, must meet the following requirements in order to
avoid undefined behavior:</p></div>
<div class="ulist"><ul>
<li>
<p>
The host memory region given by (<em>host_ptr</em> + <em>offset</em>, <em>cb</em>) contains
the latest bits when the enqueued write command begins execution.
</p>
</li>
<li>
<p>
The buffer object or memory objects created from this buffer object
are not mapped.
</p>
</li>
<li>
<p>
The buffer object or memory objects created from this buffer object
are not used by any command-queue until the write command has finished
execution.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Calling*clEnqueueWriteBufferRect* to update the latest bits in a region
of the buffer object with the <em>ptr</em> argument value set to <em>host_ptr</em> and
<em>host_origin</em>, <em>buffer_origin</em> values are the same, where <em>host_ptr</em> is
a pointer to the memory region specified when the buffer object being
written is created with CL_MEM_USE_HOST_PTR, must meet the following
requirements in order to avoid undefined behavior:</p></div>
<div class="ulist"><ul>
<li>
<p>
The host memory region given by (<em>buffer_origin region</em>) contains the
latest bits when the enqueued write command begins execution.
</p>
</li>
<li>
<p>
The buffer object or memory objects created from this buffer object
are not mapped.
</p>
</li>
<li>
<p>
The buffer object or memory objects created from this buffer object
are not used by any command-queue until the write command has finished
execution.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueCopyBuffer(cl_command_queue command_queue,
cl_mem src_buffer,
cl_mem dst_buffer,
size_t src_offset,
size_t dst_offset,
size_t size,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to copy a buffer object identified by <em>src_buffer</em> to
another buffer object identified by <em>dst_buffer</em>.</p></div>
<div class="paragraph"><p><em>command_queue</em> refers to a host command-queue in which the copy command
will be queued. The OpenCL context associated with <em>command_queue</em>,
<em>src_buffer</em> and <em>dst_buffer</em> must be the same.</p></div>
<div class="paragraph"><p><em>src_offset</em> refers to the offset where to begin copying data from
<em>src_buffer</em>.</p></div>
<div class="paragraph"><p><em>dst_offset</em> refers to the offset where to begin copying data into
<em>dst_buffer</em>.</p></div>
<div class="paragraph"><p><em>size</em> refers to the size in bytes to copy.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular copy
command and can be used to query or queue a wait for this particular
command to complete. <em>event</em> can be NULL in which case it will not be
possible for the application to query the status of this command or
queue a wait for this command to complete.
<strong>clEnqueueBarrierWithWaitList</strong> can be used instead. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueCopyBuffer</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em>, <em>src_buffer</em> and <em>dst_buffer</em>
are not the same or if the context associated with <em>command_queue</em> and
events in <em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>src_buffer</em> and <em>dst_buffer</em> are not valid buffer objects.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>src_offset</em>, <em>dst_offset</em>, <em>size</em>, <em>src_offset</em> + <em>size</em> or
<em>dst_offset</em> + <em>size</em> require accessing elements outside the
<em>src_buffer</em> and <em>dst_buffer</em> buffer objects respectively.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
     
CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>src_buffer</em> is a sub-buffer object
and <em>offset</em> specified when the sub-buffer object is created is not
aligned to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated
with <em>queue</em>.
</p>
</li>
<li>
<p>
     
CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>dst_buffer</em> is a sub-buffer object
and <em>offset</em> specified when the sub-buffer object is created is not
aligned to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated
with <em>queue</em>.
</p>
</li>
<li>
<p>
      CL_MEM_COPY_OVERLAP if
<em>src_buffer</em> and <em>dst_buffer</em> are the same buffer or sub-buffer object
and the source and destination regions overlap or if <em>src_buffer</em> and
<em>dst_buffer</em> are different sub-buffers of the same associated buffer
object and they overlap. The regions overlap if <em>src_offset</em> &#8656;
<em>dst_offset</em> &#8656; <em>src_offset</em> + <em>size</em> 1 or if <em>dst_offset</em> &#8656;
<em>src_offset</em> &#8656; <em>dst_offset</em> + <em>size</em> 1.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>src_buffer</em> or <em>dst_buffer</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueCopyBufferRect(cl_command_queue command_queue,
cl_mem src_buffer,
cl_mem dst_buffer,
const size_t *src_origin,
const size_t *dst_origin,
const size_t *region,
size_t src_row_pitch,
size_t src_slice_pitch,
size_t dst_row_pitch,
size_t dst_slice_pitch,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to copy a 2D or 3D rectangular region from the buffer
object identified by <em>src_buffer_to a 2D or 3D region in the buffer
object identified by _dst_buffer</em>. Copying begins at the source offset
and destination offset which are computed as described below in the
description for <em>src_origin</em> and <em>dst_origin</em>. Each byte of the
region&#8217;s width is copied from the source offset to the destination
offset. After copying each width, the source and destination offsets
are incremented by their respective source and destination row pitches.
After copying each 2D rectangle, the source and destination offsets are
incremented by their respective source and destination slice pitches.</p></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">If <em>src_buffer</em> and <em>dst_buffer</em> are the same buffer object,
<em>src_row_pitch</em> must equal <em>dst_row_pitch</em> and <em>src_slice_pitch</em> must
equal <em>dst_slice_pitch</em>.</td>
</tr></table>
</div>
<div class="paragraph"><p><em>command_queue</em> refers to the host command-queue in which the copy
command will be queued. The OpenCL context associated with
<em>command_queue</em>, <em>src_buffer</em> and <em>dst_buffer</em> must be the same.</p></div>
<div class="paragraph"><p><em>src_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in the memory region
associated with <em>src_buffer</em>. For a 2D rectangle region, the <em>z</em> value
given by <em>src_origin</em>[2] should be 0. The offset in bytes is computed
as <em>src_origin</em>[2] * <em>src_slice_pitch</em> + <em>src_origin</em>[1] *
<em>src_row_pitch</em> + <em>src_origin</em>[0].</p></div>
<div class="paragraph"><p><em>dst_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in the memory region
associated with <em>dst_buffer</em>. For a 2D rectangle region, the <em>z</em> value
given by <em>dst_origin</em>[2] should be 0. The offset in bytes is computed
as <em>dst_origin</em>[2] * <em>dst_slice_pitch</em> + <em>dst_origin</em>[1] *
<em>dst_row_pitch</em> + <em>dst_origin</em>[0].</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em> in bytes, <em>height</em> in rows_,_ <em>depth_in
slices) of the 2D or 3D rectangle being copied. For a 2D rectangle, the
_depth</em> value given by <em>region</em>[2] should be 1. The values in region
cannot be 0.</p></div>
<div class="paragraph"><p><em>src_row_pitch</em> is the length of each row in bytes to be used for the
memory region associated with <em>src_buffer</em>. If <em>src_row_pitch</em> is 0,
<em>src_row_pitch</em> is computed as <em>region</em>[0].</p></div>
<div class="paragraph"><p><em>src_slice_pitch</em> is the length of each 2D slice in bytes to be used for
the memory region associated with <em>src_buffer</em>. If <em>src_slice_pitch</em> is
0, <em>src_slice_pitch</em> is computed as <em>region</em>[1] * <em>src_row_pitch</em>.</p></div>
<div class="paragraph"><p><em>dst_row_pitch</em> is the length of each row in bytes to be used for the
memory region associated with <em>dst_buffer</em>. If <em>dst_row_pitch</em> is 0,
<em>dst_row_pitch</em> is computed as <em>region</em>[0].</p></div>
<div class="paragraph"><p><em>dst_slice_pitch</em> is the length of each 2D slice in bytes to be used for
the memory region associated with <em>dst_buffer</em>. If <em>dst_slice_pitch</em> is
0, <em>dst_slice_pitch</em> is computed as <em>region</em>[1] * <em>dst_row_pitch</em>.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular copy
command and can be used to query or queue a wait for this particular
command to complete. <em>event</em> can be NULL in which case it will not be
possible for the application to query the status of this command or
queue a wait for this command to complete.
<strong>clEnqueueBarrierWithWaitList</strong> can be used instead. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueCopyBufferRect</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em>, <em>src_buffer</em> and <em>dst_buffer</em>
are not the same or if the context associated with <em>command_queue</em> and
events in <em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>src_buffer</em> and <em>dst_buffer</em> are not valid buffer objects.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
(<em>src_origin, region, src_row_pitch, src_slice_pitch</em>) or (<em>dst_origin,
region, dst_row_pitch, dst_slice_pitch</em>) require accessing elements
outside the <em>src_buffer</em> and <em>dst_buffer</em> buffer objects respectively.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if any
<em>region</em> array element is 0.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>src_row_pitch</em> is not 0 and is less than <em>region</em>[0].
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>dst_row_pitch</em> is not 0 and is less than <em>region</em>[0].
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>src_slice_pitch</em> is not 0 and is less than <em>region</em>[1] *
<em>src_row_pitch</em> or if <em>src_slice_pitch</em> is not 0 and is not a multiple
of <em>src_row_pitch</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>dst_slice_pitch</em> is not 0 and is less than <em>region</em>[1] *
<em>dst_row_pitch</em> or if <em>dst_slice_pitch</em> is not 0 and is not a multiple
of <em>dst_row_pitch</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>src_buffer</em> and <em>dst_buffer</em> are the same buffer object and
<em>src_slice_pitch</em> is not equal to <em>dst_slice_pitch</em> and <em>src_row_pitch</em>
is not equal to <em>dst_row_pitch</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_MEM_COPY_OVERLAP if
<em>src_buffer</em> and <em>dst_buffer</em> are the same buffer or sub-buffer object
and the source and destination regions overlap or if <em>src_buffer</em> and
<em>dst_buffer</em> are different sub-buffers of the same associated buffer
object and they overlap. Refer to Appendix D for details on how to
determine if source and destination regions overlap.
</p>
</li>
<li>
<p>
     
CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>src_buffer</em> is a sub-buffer object
and <em>offset</em> specified when the sub-buffer object is created is not
aligned to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated
with <em>queue</em>.
</p>
</li>
<li>
<p>
     CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>dst_buffer</em> is a sub-buffer object
and <em>offset</em> specified when the sub-buffer object is created is not
aligned to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated
with <em>queue</em>.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>src_buffer</em> or <em>dst_buffer</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_filling_buffer_objects">5.2.3. Filling Buffer Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueFillBuffer(cl_command_queue command_queue,
cl_mem buffer,
const void *pattern,
size_t pattern_size,
size_t offset,
size_t size,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to fill a buffer object with a pattern of a given
pattern size. The usage information which indicates whether the memory
object can be read or written by a kernel and/or the host and is given
by the cl_mem_flags argument value specified when <em>buffer</em> is created is
ignored by <strong>clEnqueueFillBuffer</strong>.</p></div>
<div class="paragraph"><p><em>command_queue</em> refers to the host command-queue in which the fill
command will be queued. The OpenCL context associated with
<em>command_queue</em> and <em>buffer</em> must be the same.</p></div>
<div class="paragraph"><p><em>buffer</em> is a valid buffer object.</p></div>
<div class="paragraph"><p><em>pattern</em> is a pointer to the data pattern of size <em>pattern_size</em> in
bytes. <em>pattern</em> will be used to fill a region in <em>buffer</em> starting at
<em>offset</em> and is <em>size</em> bytes in size. The data pattern must be a scalar
or vector integer or floating-point data type supported by OpenCL as
described in <em>sections 6.1.1</em> and <em>6.1.2</em>. For example, if <em>buffer</em> is
to be filled with a pattern of float4 values, then <em>pattern</em> will be a
pointer to a cl_float4 value and <em>pattern_size</em> will be
sizeof(cl_float4). The maximum value of <em>pattern_size</em> is the size of
the largest integer or floating-point vector data type supported by the
OpenCL device. The memory associated with <em>pattern</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>offset</em> is the location in bytes of the region being filled in <em>buffer</em>
and must be a multiple of <em>pattern_size</em>.</p></div>
<div class="paragraph"><p><em>size</em> is the size in bytes of region being filled in <em>buffer</em> and must
be a multiple of <em>pattern_size</em>.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. <strong>clEnqueueBarrierWithWaitList</strong> can be used
instead. If the <em>event_wait_list</em> and the <em>event</em> arguments are not
NULL, the <em>event</em> argument should not refer to an element of the
<em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueFillBuffer</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em> and <em>buffer</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>buffer</em> is not a valid buffer object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>offset</em> or <em>offset</em> + <em>size</em> require accessing elements outside the
<em>buffer</em> buffer object respectively.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pattern</em> is NULL or if <em>pattern_size</em> is 0 or if <em>pattern_size</em> is not
one of {1, 2, 4, 8, 16, 32, 64, 128}.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>offset</em> and <em>size</em> are not a multiple of <em>pattern_size</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
     
CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>buffer</em> is a sub-buffer object and
offset specified when the sub-buffer object is created is not aligned to
CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated with <em>queue</em>.
</p>
</li>
<li>
<p>
     
CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>buffer</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_mapping_buffer_objects">5.2.4. Mapping Buffer Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>void clEnqueueMapBuffer(cl_command_queue command_queue,
cl_mem buffer,
cl_bool blocking_map,
cl_map_flags map_flags,
size_t offset,
size_t size,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to map a region of the buffer object given by
<em>buffer</em> into the host address space and returns a pointer to this
mapped region.</p></div>
<div class="paragraph"><p><em>command_queue</em> must be a valid host command-queue.</p></div>
<div class="paragraph"><p><em>blocking_map</em> indicates if the map operation is <em>blocking</em> or
<em>non-blocking</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_map</em> is CL_TRUE, <strong>clEnqueueMapBuffer</strong> does not return until
the specified region in <em>buffer</em> is mapped into the host address space
and the application can access the contents of the mapped region using
the pointer returned by <strong>clEnqueueMapBuffer</strong>.</p></div>
<div class="paragraph"><p>If <em>blocking_map</em> is CL_FALSE i.e. map operation is non-blocking, the
pointer to the mapped region returned by <strong>clEnqueueMapBuffer</strong> cannot be
used until the map command has completed. The <em>event</em> argument returns
an event object which can be used to query the execution status of the
map command. When the map command is completed, the application can
access the contents of the mapped region using the pointer returned by
<strong>clEnqueueMapBuffer</strong>.</p></div>
<div class="paragraph"><p><em>map_flags</em> is a bit-field and is described in <em>table 5.5</em>.</p></div>
<div class="paragraph"><p><em>buffer</em> is a valid buffer object. The OpenCL context associated with
<em>command_queue</em> and <em>buffer</em> must be the same.</p></div>
<div class="paragraph"><p><em>offset</em> and <em>size</em> are the offset in bytes and the size of the region
in the buffer object that is being mapped.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. If the <em>event_wait_list</em> and the <em>event</em>
arguments are not NULL, the <em>event</em> argument should not refer to an
element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clEnqueueMapBuffer</strong> will return a pointer to the mapped region. The
<em>errcode_ret</em> is set to CL_SUCCESS.</p></div>
<div class="paragraph"><p>A NULL pointer is returned otherwise with one of the following error
values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if _command_queue_is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue_and _buffer</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>buffer</em> is not a valid buffer object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if region
being mapped given by (<em>offset</em>, <em>size</em>) is out of bounds or if <em>size</em>
is 0 or if values specified in _map_flags_are not valid.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
     CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>buffer</em> is a sub-buffer object and
<em>offset</em> specified when the sub-buffer object is created is not aligned
to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for the device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
      CL_MAP_FAILURE if there is
a failure to map the requested region into the host address space. This
error cannot occur for buffer objects created with CL_MEM_USE_HOST_PTR
or CL_MEM_ALLOC_HOST_PTR.
</p>
</li>
<li>
<p>
     CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the map operation is
blocking and the execution status of any of the events in
<em>event_wait_list</em> is a negative integer value.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>buffer</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
buffer_ has been created with CL_MEM_HOST_WRITE_ONLY or
CL_MEM_HOST_NO_ACCESS and CL_MAP_READ is set in <em>map_flags</em> or if
<em>buffer</em> has been created with CL_MEM_HOST_READ_ONLY or
CL_MEM_HOST_NO_ACCESS and CL_MAP_WRITE or CL_MAP_WRITE_INVALIDATE_REGION
is set in <em>map_flags</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
mapping would lead to overlapping regions being mapped for writing.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The pointer returned maps a region starting at <em>offset</em> and is at least
<em>size</em> bytes in size. The result of a memory access outside this region
is undefined.</p></div>
<div class="paragraph"><p>If the buffer object is created with CL_MEM_USE_HOST_PTR set in
<em>mem_flags</em>, the following will be true:</p></div>
<div class="ulist"><ul>
<li>
<p>
      The <em>host_ptr</em> specified
in <strong>clCreateBuffer</strong> to contain the latest bits in the
region being mapped when the <strong>clEnqueueMapBuffer</strong> command has completed.
</p>
</li>
<li>
<p>
      The pointer value returned
by <strong>clEnqueueMapBuffer</strong> will be derived from the <em>host_ptr</em> specified
when the buffer object is created.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Mapped buffer objects are unmapped using <strong>clEnqueueUnmapMemObject</strong>.
This is described in <em>section 5.5.2</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 10. <em>List of supported cl_map_flags values</em></caption>
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_map_flags</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MAP_READ</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the region being mapped
in the memory object is being mapped for
reading.
<br>
<br>
The pointer returned by clEnqueueMapBuffer (clEnqueueMapImage) is guaranteed
to contain the latest bits in the region being
mapped when the clEnqueueMapBuffer (clEnqueueMapImage) command has completed.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MAP_WRITE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the region being mapped
in the memory object is being mapped for
writing.
<br>
<br>
The pointer returned by
clEnqueueMap{Buffer</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Image} is guaranteed
to contain the latest bits in the region being
mapped when the clEnqueueMapBuffer (clEnqueueMapImage) command has completed</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MAP_WRITE_INVALIDATE_REGION</strong></p></td>
</tr>
</tbody>
</table>
</div>
</div>
<div class="sect2">
<h3 id="_image_objects">5.3. Image Objects</h3>
<div class="paragraph"><p>An <em>image</em> object is used to store a one-, two- or three- dimensional
texture, frame-buffer or image. The elements of an image object are
selected from a list of predefined image formats. The minimum number of
elements in a memory object is one.</p></div>
<div class="sect3">
<h4 id="_creating_image_objects">5.3.1. Creating Image Objects</h4>
<div class="paragraph"><p>A <strong>1D image</strong>,<strong>1D image buffer, 1D image array</strong>,<strong>2D image</strong>,<strong>2D image
array and 3D image object</strong> can be created using the following function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_mem clCreateImage(cl_context context,
cl_mem_flags flags,
const cl_image_format *image_format,
const cl_image_desc *image_desc,
void *host_ptr,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p><em>context</em> is a valid OpenCL context on which the image object is to be
created.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify allocation and usage
information about the image memory object being created and is described
in <em>table 5.3</em>.</p></div>
<div class="paragraph"><p>For all image types except CL_MEM_OBJECT_IMAGE1D_BUFFER, if value
specified for <em>flags</em> is 0, the default is used which is
CL_MEM_READ_WRITE.</p></div>
<div class="paragraph"><p>For CL_MEM_OBJECT_IMAGE1D_BUFFER image type, or an image created from
another memory object (image or buffer), if the CL_MEM_READ_WRITE,
CL_MEM_READ_ONLY or CL_MEM_WRITE_ONLY values are not specified in
<em>flags</em>, they are inherited from the corresponding memory access
qualifers associated with <em>mem_object</em>. The CL_MEM_USE_HOST_PTR,
CL_MEM_ALLOC_HOST_PTR and CL_MEM_COPY_HOST_PTR values cannot be
specified in <em>flags</em> but are inherited from the corresponding memory
access qualifiers associated with <em>mem_object</em>. If CL_MEM_COPY_HOST_PTR
is specified in the memory access qualifier values associated with
<em>mem_object</em> it does not imply any additional copies when the image is
created from <em>mem_object</em>. If the CL_MEM_HOST_WRITE_ONLY,
CL_MEM_HOST_READ_ONLY or CL_MEM_HOST_NO_ACCESS values are not specified
in <em>flags</em>, they are inherited from the corresponding memory access
qualifiers associated with <em>mem_object</em>.</p></div>
<div class="paragraph"><p><em>image_format</em> is a pointer to a structure that describes format
properties of the image to be allocated. A 1D image buffer or 2D image
can belink:#<em>msocom_12<a id="BA12"></a>  created from a buffer by specifying a
buffer object in the _image_desc&#8594;mem_object</em>. A 2D image can be
created from another 2D image object by specifyging an image object in
the <em>image_desc&#8594;mem_object</em>. Refer to <em>section 5.3.1.1</em> for a detailed
description of the image format descriptor.</p></div>
<div class="paragraph"><p><em>image_desc</em> is a pointer to a structure that describes type and
dimensions of the image to be allocated. Refer to <em>section 5.3.1.2</em> for
a detailed description of the image descriptor.</p></div>
<div class="paragraph"><p><em>host_ptr</em> is a pointer to the image data that may already be allocated
by the application. It is only used to initialize the image, and can be
freed after the call to <strong>clCreateImage</strong>. Refer to table below for a
description of how large the buffer that <em>host_ptr</em> points to must be.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Image Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Size of buffer that <em>host_ptr</em> points to</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_OBJECT_IMAGE1D</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&gt;= image_row_pitch</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_OBJECT_IMAGE1D_BUFFER</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&gt;= image_row_pitch</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_OBJECT_IMAGE2D</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&gt;= image_row_pitch * image_height</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_OBJECT_IMAGE3D</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&gt;= image_slice_pitch * image_depth</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_OBJECT_IMAGE1D_ARRAY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&gt;= image_slice_pitch * image_array_size</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_OBJECT_IMAGE2D_ARRAY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&gt;= image_slice_pitch * image_array_size</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>For a 3D image or 2D image array, the image data specified by <em>host_ptr</em>
is stored as a linear sequence of adjacent 2D image slices or 2D images
respectively. Each 2D image is a linear sequence of adjacent
scanlines. Each scanline is a linear sequence of image elements.</p></div>
<div class="paragraph"><p>For a 2D image, the image data specified by <em>host_ptr</em> is stored as a
linear sequence of adjacent scanlines. Each scanline is a linear
sequence of image elements.</p></div>
<div class="paragraph"><p>For a 1D image array, the image data specified by <em>host_ptr</em> is stored
as a linear sequence of adjacent 1D images. Each 1D image is stored as
a single scanline which is a linear sequence of adjacent elements.</p></div>
<div class="paragraph"><p>For 1D image or 1D image buffer, the image data specified by <em>host_ptr</em>
is stored as a single scanline which is a linear sequence of adjacent
elements.</p></div>
<div class="paragraph"><p>Image elements are stored according to their image format as described
in section 5.3.1.1</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateImage</strong> returns a valid non-zero image object created and the
<em>errcode_ret</em> is set to CL_SUCCESS if the image object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
specified in _flags_are not valid.
</p>
</li>
<li>
<p>
 CL_INVALID_IMAGE_FORMAT_DESCRIPTOR if values specified in
<em>image_format_are not valid or if _image_format</em> is NULL.
</p>
</li>
<li>
<p>
 CL_INVALID_IMAGE_FORMAT_DESCRIPTOR if a 2D image is created from a
buffer and the row pitch and base address alignment does not follow the
rules described for creating a 2D image from a buffer.
</p>
</li>
<li>
<p>
  CL_INVALID_IMAGE_FORMAT_DESCRIPTOR if a 2D image is created from a 2D
image object and the rules described above are not followed.
</p>
</li>
<li>
<p>
CL_INVALID_IMAGE_DESCRIPTOR if values specified in <em>image_desc_are not
valid or if _image_desc</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
image dimensions specified in <em>image_desc</em> exceed the maximum image
dimensions described in <em>table 4.3</em> for all devices in_context_.
</p>
</li>
<li>
<p>
      CL_INVALID_HOST_PTR if
<em>host_ptr</em> is NULL and CL_MEM_USE_HOST_PTR or CL_MEM_COPY_HOST_PTR are
set in <em>flags</em> or if <em>host_ptr</em> is not NULL but CL_MEM_COPY_HOST_PTR or
CL_MEM_USE_HOST_PTR are not set in <em>flags</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if an
image is being created from another memory object (buffer or image)
under one of the following circumstances: 1) <em>mem_object</em> was created
with CL_MEM_WRITE_ONLY and <em>flags</em> specifies CL_MEM_READ_WRITE or
CL_MEM_READ_ONLY, 2) <em>mem_object</em> was created with CL_MEM_READ_ONLY and
<em>flags</em> specifies CL_MEM_READ_WRITE or CL_MEM_WRITE_ONLY, 3) <em>flags</em>
specifies CL_MEM_USE_HOST_PTR or CL_MEM_ALLOC_HOST_PTR or
CL_MEM_COPY_HOST_PTR.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if an
image is being created from another memory object (buffer or image) and
<em>mem_object</em> object was created with CL_MEM_HOST_WRITE_ONLY and <em>flags</em>
specifies CL_MEM_HOST_READ_ONLY, or if <em>mem_object</em> was created with
CL_MEM_HOST_READ_ONLY and <em>flags</em> specifies CL_MEM_HOST_WRITE_ONLY, or
if <em>mem_object</em> was created with CL_MEM_HOST_NO_ACCESS and_flags_
specifies CL_MEM_HOST_READ_ONLY or CL_MEM_HOST_WRITE_ONLY.
</p>
</li>
<li>
<p>
CL_IMAGE_FORMAT_NOT_SUPPORTED if the <em>image_format</em> is not supported.
</p>
</li>
<li>
<p>
CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for image object.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
there are no devices in <em>context</em> that support images (i.e.
CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_FALSE).
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="sect4">
<h5 id="_image_format_descriptor">Image Format Descriptor</h5>
<div class="paragraph"><p>The image format descriptor structure is defined as</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>typedef struct cl_image_format {
cl_channel_order image_channel_order;
cl_channel_type image_channel_data_type;
} cl_image_format;</pre>
</div></div>
<div class="paragraph"><p>image_channel_order specifies the number of channels and the channel
layout i.e. the memory layout in which channels are stored in the
image. Valid values are described in <em>table 5.6.</em></p></div>
<div class="paragraph"><p>image_channel_data_type describes the size of the channel data type.
The list of supported values is described in <em>table 5.7</em>. The number of
bits per element determined by the image_channel_data_type and
image_channel_order must be a power of two.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 11. <em>List of supported Image Channel Order Values</em></caption>
<col style="width:100%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Enum values that can be specified in channel_order</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_R</strong>, <strong>CL_Rx</strong> or <strong>CL_A</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_INTENSITY</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_LUMINANCE</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEPTH</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_RG</strong>, <strong>CL_RGx</strong> or <strong>CL_RA</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_RGB</strong> or <strong>CL_RGBx</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_RGBA</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_sRGB, CL_sRGBx, CL_sRGBA, CL_sBGRA</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_ARGB, CL_BGRA, CL_ABGR</strong></p></td>
</tr>
</tbody>
</table>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 12. <em>List of supported Image Channel Data Types</em></caption>
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Image Channel Data Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SNORM_INT8</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is a normalized signed 8-bit
integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SNORM_INT16</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is a normalized signed 16-bit
integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNORM_INT8</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is a normalized unsigned 8-bit
integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNORM_INT16</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is a normalized unsigned
16-bit integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNORM_SHORT_565</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Represents a normalized 5-6-5 3-channel RGB
image. The channel order must be CL_RGB or CL_RGBx.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNORM_SHORT_555</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Represents a normalized x-5-5-5 4-channel xRGB
image. The channel order must be CL_RGB or CL_RGBx.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNORM_INT_101010</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Represents a normalized x-10-10-10 4-channel
xRGB image. The channel order must be CL_RGB or CL_RGBx.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNORM_INT_101010_2</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Represents a normalized 10-10-10-2
four-channel RGBA image. The channel order must be CL_RGBA.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SIGNED_INT8</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is an unnormalized signed
8-bit integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SIGNED_INT16</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is an unnormalized signed
16-bit integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SIGNED_INT32</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is an unnormalized signed
32-bit integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNSIGNED_INT8</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is an unnormalized unsigned
8-bit integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNSIGNED_INT16</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is an unnormalized unsigned
16-bit integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UNSIGNED_INT32</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is an unnormalized unsigned
32-bit integer value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_HALF_FLOAT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is a 16-bit half-float value</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLOAT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Each channel component is a single precision floating-point value</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>For example, to specify a normalized unsigned 8-bit / channel RGBA
image, image_channel_order = CL_RGBA, and__image_channel_data_type =
CL_UNORM_INT8. The memory layout of this image format is described
below:</p></div>
<table class="tableblock frame-all grid-all"
style="
width:60%;
">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:60%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">R</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">G</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">B</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&#8230;</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>with the corresponding byte offsets</p></div>
<table class="tableblock frame-all grid-all"
style="
width:60%;
">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:60%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">1</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">2</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">3</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&#8230;</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>Similar, if image_channel_order = CL_RGBA and image_channel_data_type =
CL_SIGNED_INT16, the memory layout of this image format is described
below:</p></div>
<table class="tableblock frame-all grid-all"
style="
width:60%;
">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:60%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">R</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">G</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">B</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&#8230;</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>with the corresponding byte offsets</p></div>
<table class="tableblock frame-all grid-all"
style="
width:60%;
">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:10%;">
<col style="width:60%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">2</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">4</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">6</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">&#8230;</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>image_channel_data_type values of CL_UNORM_SHORT_565,
CL_UNORM_SHORT_555, CL_UNORM_INT_101010 and CL_UNORM_INT_101010_2 are
special cases of packed image formats where the channels of each element
are packed into a single unsigned short or unsigned int. For these
special packed image formats, the channels are normally packed with the
first channel in the most significant bits of the bitfield, and successive
channels occupying progressively less significant locations. For
CL_UNORM_SHORT_565, R is in bits 15:11, G is in bits 10:5 and B is in
bits 4:0. For CL_UNORM_SHORT_555, bit 15 is undefined, R is in bits
14:10, G in bits 9:5 and B in bits 4:0. For CL_UNORM_INT_101010, bits
31:30 are undefined, R is in bits 29:20, G in bits 19:10 and B in bits
9:0. For CL_UNORM_INT_101010_2, R is in bits 31:22, G in bits 21:12, B
in bits 11:2 and A in bits 1:0.</p></div>
<div class="paragraph"><p>OpenCL implementations must maintain the minimum precision specified by
the number of bits in image_channel_data_type. If the image format
specified by image_channel_order, and image_channel_data_type cannot be
supported by the OpenCL implementation, then the call to <strong>clCreateImage</strong>
will return a NULL memory object.</p></div>
</div>
<div class="sect4">
<h5 id="_image_descriptor">Image Descriptor</h5>
<div class="paragraph"><p>The image descriptor structure describes the type and dimensions of the
image or image array and is defined as:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>typedef struct cl_image_desc {
cl_mem_object_type image_type,
size_t image_width;
size_t image_height;
size_t image_depth;
size_t image_array_size;
size_t image_row_pitch;
size_t image_slice_pitch;
cl_uint num_mip_levels;
cl_uint num_samples;
cl_mem mem_object;
} cl_image_desc;</pre>
</div></div>
<div class="paragraph"><p>image_type describes the image type and must be either
CL_MEM_OBJECT_IMAGE1D, CL_MEM_OBJECT_IMAGE1D_BUFFER,
CL_MEM_OBJECT_IMAGE1D_ARRAY, CL_MEM_OBJECT_IMAGE2D,
CL_MEM_OBJECT_IMAGE2D_ARRAY or CL_MEM_OBJECT_IMAGE3D.</p></div>
<div class="paragraph"><p>image_width is the width of the image in pixels. For a 2D image and
image array, the image width must be a value &gt;= 1 and &#8656;
CL_DEVICE_IMAGE2D_MAX_WIDTH. For a 3D image, the image width must be a
value &gt;=1 and &#8656; CL_DEVICE_IMAGE3D_MAX_WIDTH. For a 1D image buffer,
the image width must be a value &gt;=1 and &#8656;
CL_DEVICE_IMAGE_MAX_BUFFER_SIZE. For a 1D image and 1D image array, the
image width must be a value &gt;=1 and &#8656; CL_DEVICE_IMAGE2D_MAX_WIDTH.</p></div>
<div class="paragraph"><p>image_height is height of the image in pixels. This is only used if the
image is a 2D or 3D image, or a 2D image array. For a 2D image or image
array, the image height must be a value &gt;=1 and &#8656;
CL_DEVICE_IMAGE2D_MAX_HEIGHT. For a 3D image, the image height must be
a value &gt;=1 and &#8656; CL_DEVICE_IMAGE3D_MAX_HEIGHT.</p></div>
<div class="paragraph"><p>image_depth is the depth of the image in pixels. This is only used if
the image is a 3D image and must be a value &gt;= 1 and &#8656;
CL_DEVICE_IMAGE3D_MAX_DEPTH.</p></div>
<div class="paragraph"><p>image_array_size<span class="footnote"><br>[Note that reading and writing 2D image arrays from a kernel with image_array_size =1 may be lower
performance than 2D images]<br></span>: is the number of images in the image
array. This is only used if the image is a 1D or 2D image array. The
values for image_array_size, if specified, must be a value &gt;= 1 and &#8656;
CL_DEVICE_IMAGE_MAX_ARRAY_SIZE.</p></div>
<div class="paragraph"><p>image_row_pitch is the scan-line pitch in bytes. This must be 0 if
<em>host_ptr</em> is NULL and can be either 0 or &gt;= image_width * size of
element in bytes if <em>host_ptr</em> is not NULL. If <em>host_ptr</em> is not NULL
and image_row_pitch__= 0, image_row_pitch is calculated as image_width *
size of element in bytes. If image_row_pitch is not 0, it must be a
multiple of the image element size in bytes. For a 2D image created
from a buffer, the pitch specified (or computed if pitch specified is 0)
must be a multiple of the maximum of the
CL_DEVICE_IMAGE_PITCH_ALIGNMENT value for all devices in the context
associated with image_desc&#8594;mem_object and that support images.</p></div>
<div class="paragraph"><p>image_slice_pitch is the size in bytes of each 2D slice in the 3D image
or the size in bytes of each image in a 1D or 2D image array. This must
be 0 if <em>host_ptr</em> is NULL. If <em>host_ptr</em> is not NULL,
image_slice_pitch can be either 0 or &gt;= image_row_pitch * image_height
for a 2D image array or 3D image and can be either 0 or &gt;=
image_row_pitch for a 1D image array. If <em>host_ptr</em> is not NULL and
image_slice_pitch<em>= 0, image_slice_pitch is calculated as
image_row_pitch * image_height for a 2D image array or 3D image and
image_row_pitch for a 1D image array. If image_slice_pitch</em>is not 0,
it must be a multiple of the image_row_pitch.</p></div>
<div class="paragraph"><p>num_mip_levels and num_samples must be 0.</p></div>
<div class="paragraph"><p>mem_object may refer to a valid buffer or image memory object.
mem_object can be a buffer memory object if image_type is
CL_MEM_OBJECT_IMAGE1D_BUFFER or
CL_MEM_OBJECT_IMAGE2D<span class="footnote"><br>[To create a 2D image from a buffer object that share the data store between the image and buffer object]<br></span>:. mem_object can be an image
object if image_type is CL_MEM_OBJECT_IMAGE2D<span class="footnote"><br>[To create an image object from another image object that share the data store between these image objects.]<br></span>:.
Otherwise it must be NULL. The image pixels are taken from the memory
objects data store. When the contents of the specified memory objects
data store are modified, those changes are reflected in the contents of
the image object and vice-versa at corresponding synchronization points.</p></div>
<div class="paragraph"><p>For a 1D image buffer create from a buffer object, the image_width *
size of element in bytes must be &#8656; size of the buffer object. The
image data in the buffer object is stored as a single scanline which is
a linear sequence of adjacent elements. </p></div>
<div class="paragraph"><p>For a 2D image created from a buffer object, the image_row_pitch *
image_height must be &#8656; size of the buffer object specified by
mem_object. The image data in the buffer object is stored as a linear
sequence of adjacent scanlines. Each scanline is a linear sequence of
image elements padded to image_row_pitch bytes. </p></div>
<div class="paragraph"><p>For an image object created from another image object, the values
specified in the image descriptor except for mem_object must match the
image descriptor information associated with mem_object. </p></div>
<div class="paragraph"><p>Image elements are stored according to their image format as described
in section 5.3.1.1. </p></div>
<div class="paragraph"><p>If the buffer object specified by mem_object is created with
CL_MEM_USE_HOST_PTR, the <em>host_ptr</em> specified to <strong>clCreateBuffer</strong> must
be aligned to the minimum of the
<strong>CL_DEVICE_IMAGE_BASE_ADDRESS_ALIGNMENT</strong> value for all devices in the
context associated with the buffer specified by mem_object and that
support images.</p></div>
<div class="paragraph"><p>Creating a 2D image object from another 2D image object allows users to
create a new image object that shares the image data store with
mem_object but views the pixels in the image with a different channel
order. The restrictions are:</p></div>
<div class="ulist"><ul>
<li>
<p>
      all the values specified
in image_desc except for mem_object must match the image descriptor
information associated with mem_object.
</p>
</li>
<li>
<p>
      The <em>image_desc</em> used for
creation of <em>mem_object</em> may not be equivalent to image descriptor
information associated with mem_object. To ensure the values in
<em>image_desc</em> will match one can query mem_object for associated
information using <strong>clGetImageInfo</strong> function described in section 5.3.7.
</p>
</li>
<li>
<p>
      the channel data type
specified in image_format must match the channel data type associated
with mem_object. The channel order values<span class="footnote"><br>[This allows developers to create a sRGB view of the image from a linear RGB view or vice-versa i.e. the pixels
stored in the image can be accessed as linear RGB or sRGB values. ]<br></span>: supported
are:
</p>
</li>
</ul></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>image_channel_order specified in image_format</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>image channel order
of mem_object</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sBGRA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_BGRA</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_BGRA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sBGRA</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sRGBA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGBA</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGBA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sRGBA</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sRGB</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGB</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGB</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sRGB</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sRGBx</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGBx</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGBx</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sRGBx</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEPTH</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_R</p></td>
</tr>
</tbody>
</table>
<div class="ulist"><ul>
<li>
<p>
      the channel order
specified must have the same number of channels as the channel order of
mem_object.
</p>
</li>
</ul></div>
<div class="paragraph"><p>NOTE:</p></div>
<div class="paragraph"><p>Concurrent reading from, writing to and copying between both a buffer
object and 1D image buffer or 2D image object associated with the buffer
object is undefined. Only reading from both a buffer object and 1D
image buffer or 2D image object associated with the buffer object is
defined.</p></div>
<div class="paragraph"><p>Writing to an image created from a buffer and then reading from this
buffer in a kernel even if appropriate synchronization operations (such
as a barrier) are performed between the writes and reads is undefined.
Similarly, writing to the buffer and reading from the image created from
this buffer with appropriate synchronization between the writes and
reads is undefined.</p></div>
</div>
</div>
<div class="sect3">
<h4 id="_querying_list_of_supported_image_formats">5.3.2. Querying List of Supported Image Formats</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetSupportedImageFormats(cl_context context,
cl_mem_flags flags,
cl_mem_object_type image_type,
cl_uint num_entries,
cl_image_format *image_formats,
cl_uint *num_image_formats)</pre>
</div></div>
<div class="paragraph"><p>can be used to get the list of image formats supported by an OpenCL
implementation when the following information about an image memory
object is specified:</p></div>
<div class="ulist"><ul>
<li>
<p>
      Context
</p>
</li>
<li>
<p>
      Image type 1D, 2D, or 3D
image, 1D image buffer, 1D or 2D image array.
</p>
</li>
<li>
<p>
      Image object allocation
information
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>clGetSupportedImageFormats</strong> returns a union of image formats supported
by all devices in the context.</p></div>
<div class="paragraph"><p><em>context</em> is a valid OpenCL context on which the image object(s) will be
created.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify allocation and usage
information about the image memory object being queried and is described
in <em>table 5.3</em>. To get a list of supported image formats that can be
read from or written to by a kernel, <em>flags</em> must be set to
CL_MEM_READ_WRITE (get a list of images that can be read from and
written to by different kernel instances when correctly ordered by event
dependencies), CL_MEM_READ_ONLY (list of images that can be read from by
a kernel) or CL_MEM_WRITE_ONLY (list of images that can be written to by
a kernel). To get a list of supported image formats that can be both
read from and written to by the same kernel instance, <em>flags</em> must be
set to CL_MEM_KERNEL_READ_AND_WRITE. Please see section 5.3.2.2 for
clarification.</p></div>
<div class="paragraph"><p><em>image_type</em> describes the image type and must be either
CL_MEM_OBJECT_IMAGE1D, CL_MEM_OBJECT_IMAGE1D_BUFFER,
CL_MEM_OBJECT_IMAGE2D, CL_MEM_OBJECT_IMAGE3D,
CL_MEM_OBJECT_IMAGE1D_ARRAY or CL_MEM_OBJECT_IMAGE2D_ARRAY.
 
<em>num_entries</em> specifies the number of entries that can be returned in
the memory location given by <em>image_formats</em>.</p></div>
<div class="paragraph"><p><em>image_formats</em> is a pointer to a memory location where the list of
supported image formats are returned. Each entry describes a
<em>cl_image_format</em> structure supported by the OpenCL implementation. If
<em>image_formats</em> is NULL, it is ignored.
 
<em>num_image_formats</em> is the actual number of supported image formats for
a specific <em>context</em> and values specified by <em>flags</em>. If
<em>num_image_formats</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><strong>clGetSupportedImageFormats</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
<em>context</em> is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>flags</em> or <em>image_type</em> are not valid, or if <em>num_entries</em> is 0 and
<em>image_formats</em> is not NULL. 
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
 
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>If CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_TRUE, the
values assigned to CL_DEVICE_MAX_READ_IMAGE_ARGS,
CL_DEVICE_MAX_WRITE_IMAGE_ARGS, CL_DEVICE_IMAGE2D_MAX_WIDTH,
CL_DEVICE_IMAGE2D_MAX_HEIGHT, CL_DEVICE_IMAGE3D_MAX_WIDTH,
CL_DEVICE_IMAGE3D_MAX_HEIGHT, CL_DEVICE_IMAGE3D_MAX_DEPTH and
CL_DEVICE_MAX_SAMPLERS by the implementation must be greater than or
equal to the minimum values specified in <em>table 4.3</em>.</p></div>
<div class="sect4">
<h5 id="_minimum_list_of_supported_image_formats">Minimum List of Supported Image Formats</h5>
<div class="paragraph"><p>For 1D, 1D image from buffer, 2D, 3D image objects, 1D and 2D image
array objects, the mandated minimum list of image formats that can be
read from and written to by different kernel instances when correctly
ordered by event dependencies and that must be supported by all devices
that support images is described in <em>table 5.8</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 13. <em>Min. list of supported image formats kernel read or write</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>num_channels</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>channel_order</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>channel_data_type</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">1</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_R</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT8
CL_UNORM_INT16
CL_SNORM_INT8
CL_SNORM_INT16
CL_SIGNED_INT8
CL_SIGNED_INT16
CL_SIGNED_INT32
CL_UNSIGNED_INT8
CL_UNSIGNED_INT16
CL_UNSIGNED_INT32
CL_HALF_FLOAT
CL_FLOAT</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">1</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_DEPTH<span class="footnote"><br>[CL_DEPTH channel order is supported only for 2D image and 2D image array objects.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT16 CL_FLOAT</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">2</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RG</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT8
CL_UNORM_INT16
CL_SNORM_INT8
CL_SNORM_INT16
CL_SIGNED_INT8
CL_SIGNED_INT16
CL_SIGNED_INT32
CL_UNSIGNED_INT8
CL_UNSIGNED_INT16
CL_UNSIGNED_INT32
CL_HALF_FLOAT
CL_FLOAT</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">4</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGBA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT8
CL_UNORM_INT16
CL_SNORM_INT8
CL_SNORM_INT16
CL_SIGNED_INT8
CL_SIGNED_INT16 CL_SIGNED_INT32
CL_UNSIGNED_INT8
CL_UNSIGNED_INT16
CL_UNSIGNED_INT32
CL_HALF_FLOAT
CL_FLOAT</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">4</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_BGRA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT8</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">4</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_sRGBA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT8<span class="footnote"><br>[sRGB channel order support is not required for 1D image buffers. Writes to images with sRGB channel orders
requires device support of the cl_khr_srgb_image_writes extension.]<br></span>:]</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>For 1D, 1D image from buffer, 2D, 3D image objects, 1D and 2D image
array objects, the mandated minimum list of image formats that can be
read from and written to by the same kernel instance and that must be
supported by all devices that support images is described in <em>table
5.9</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 14. <em>Min. list of supported image formats kernel read and write</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>num_channels</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>channel_order</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>channel_data_type</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">1</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_R</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT8
CL_SIGNED_INT8
CL_SIGNED_INT16
CL_SIGNED_INT32
CL_UNSIGNED_INT8
CL_UNSIGNED_INT16
CL_UNSIGNED_INT32
CL_HALF_FLOAT
CL_FLOAT</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">4</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_RGBA</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_UNORM_INT8
CL_SIGNED_INT8
CL_SIGNED_INT16
CL_SIGNED_INT32
CL_UNSIGNED_INT8
CL_UNSIGNED_INT16
CL_UNSIGNED_INT32
CL_HALF_FLOAT
CL_FLOAT</p></td>
</tr>
</tbody>
</table>
</div>
<div class="sect4">
<h5 id="_image_format_mapping_to_opencl_kernel_language_image_access_qualifiers">Image format mapping to OpenCL kernel language image access qualifiers</h5>
<div class="paragraph"><p>Image arguments to kernels may have the read_only, write_only or
read_write qualifier. Not all image formats supported by the device and
platform are valid to be passed to all of these access qualifiers. For
each access qualifier, only images whose format is in the list of
formats returned by clGetSupportedImageFormats with the given flag
arguments in <em>table 5.9</em> are permitted. It is not valid to pass an image
supporting writing as both a read_only image and a write_only image
parameter, or to a read_write image parameter and any other image
parameter.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 15. <em>Mapping from format flags passed to clGetSupportedImageFormats to OpenCL kernel language image access qualifiers</em></caption>
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Access Qualifier</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_mem_flags</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>read_only</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_MEM_READ_ONLY, CL_MEM_READ_WRITE, CL_MEM_KERNEL_READ_AND_WRITE</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>write_only</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_MEM_WRITE_ONLY, CL_MEM_READ_WRITE, CL_MEM_KERNEL_READ_AND_WRITE</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>read_write</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_MEM_KERNEL_READ_AND_WRITE</p></td>
</tr>
</tbody>
</table>
</div>
</div>
<div class="sect3">
<h4 id="_reading_writing_and_copying_image_objects">5.3.3. Reading, Writing and Copying Image Objects</h4>
<div class="paragraph"><p>The following functions enqueue commands to read from an image or image
array object to host memory or write to an image or image array object
from host memory.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueReadImage(cl_command_queue command_queue,
cl_mem image,
cl_bool blocking_read,
const size_t *origin,
const size_t *region,
size_t row_pitch,
size_t slice_pitch,
void *ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueWriteImage(cl_command_queue command_queue,
cl_mem image,
cl_bool blocking_write,
const size_t *origin,
const size_t *region,
size_t input_row_pitch,
size_t input_slice_pitch,
const void *ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p><em>command_queue</em> refers to the host command-queue in which the read /
write command will be queued. <em>command_queue</em> and <em>image</em> must be
created with the same OpenCL context.</p></div>
<div class="paragraph"><p><em>image</em> refers to a valid image or image array object.</p></div>
<div class="paragraph"><p><em>blocking_read</em> and <em>blocking_write</em> indicate if the read and write
operations are <em>blocking</em> or <em>non-blocking</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_read</em> is CL_TRUE i.e. the read command is blocking,
<strong>clEnqueueReadImage</strong> does not return until the buffer data has been read
and copied into memory pointed to by <em>ptr</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_read</em> is CL_FALSE i.e. the read command is non-blocking,
<strong>clEnqueueReadImage</strong> queues a non-blocking read command and returns. The
contents of the buffer that <em>ptr</em> points to cannot be used until the
read command has completed. The <em>event</em> argument returns an event
object which can be used to query the execution status of the read
command. When the read command has completed, the contents of the
buffer that _ptr_points to__can be used by the application.</p></div>
<div class="paragraph"><p>If <em>blocking_write_is CL_TRUE, the OpenCL implementation copies the data
referred to by _ptr</em> and enqueues the write command in the
command-queue. The memory pointed to by <em>ptr</em> can be reused by the
application after the <strong>clEnqueueWriteImage</strong> call returns.</p></div>
<div class="paragraph"><p>If <em>blocking_write</em> is CL_FALSE, the OpenCL implementation will use
<em>ptr</em> to perform a non-blocking write. As the write is non-blocking the
implementation can return immediately. The memory pointed to by <em>ptr</em>
cannot be reused by the application after the call returns. The <em>event</em>
argument returns an event object which can be used to query the
execution status of the write command. When the write command has
completed, the memory pointed to by <em>ptr</em> can then be reused by the
application.</p></div>
<div class="paragraph"><p><em>origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in pixels in the 1D, 2D or
3D image, the (<em>x</em>, <em>y</em>) offset and the image index in the 2D image
array or the (<em>x</em>) offset and the image index in the 1D image array. If
<em>image</em> is a 2D image object, <em>origin</em>[2] must be 0. If <em>image</em> is a 1D
image or 1D image buffer object, <em>origin</em>[1] and <em>origin</em>[2] must be 0.
If <em>image</em> is a 1D image array object, <em>origin</em>[2] must be 0. If
<em>image</em> is a 1D image array object, <em>origin</em>[1] describes the image
index in the 1D image array. If <em>image</em> is a 2D image array object,
<em>origin</em>[2] describes the image index in the 2D image array.</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em>, <em>height,</em> <em>depth</em>) in pixels of the 1D,
2D or 3D rectangle, the (<em>width</em>, <em>height</em>) in pixels of the 2D
rectangle and the number of images of a 2D image array or the (<em>width</em>)
in pixels of the 1D rectangle and the number of images of a 1D image
array. If <em>image</em> is a 2D image object, <em>region</em>[2] must be 1. If
<em>image</em> is a 1D image or 1D image buffer object, <em>region</em>[1] and
<em>region</em>[2] must be 1. If <em>image</em> is a 1D image array object,
<em>region</em>[2] must be 1. The values in <em>region</em> cannot be 0.</p></div>
<div class="paragraph"><p><em>row_pitch</em> in <strong>clEnqueueReadImage</strong> and <em>input_row_pitch</em> in
<strong>clEnqueueWriteImage</strong> is the length of each row in bytes. This value
must be greater than or equal to the element size in bytes * <em>width</em>.
If <em>row_pitch</em> (or <em>input_row_pitch</em>) is set to 0, the appropriate row
pitch is calculated based on the size of each element in bytes
multiplied by <em>width</em>.</p></div>
<div class="paragraph"><p><em>slice_pitch</em> in <strong>clEnqueueReadImage</strong> and <em>input_slice_pitch</em> in
<strong>clEnqueueWriteImage</strong> is the size in bytes of the 2D slice of the 3D
region of a 3D image or each image of a 1D or 2D image array being read
or written respectively. This must be 0 if <em>image</em> is a 1D or 2D
image. Otherwise this value must be greater than or equal to
<em>row_pitch</em> * <em>height</em>. If <em>slice_pitch</em> (or <em>input_slice_pitch</em>) is
set to 0, the appropriate slice pitch is calculated based on the
<em>row_pitch</em> * <em>height</em>.</p></div>
<div class="paragraph"><p><em>ptr</em> is the pointer to a buffer in host memory where image data is to be read from or to be written to. The alignment requirements for ptr are specified in section C.3.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular read /
write command and can be used to query or queue a wait for this
particular command to complete. <em>event</em> can be NULL in which case it
will not be possible for the application to query the status of this
command or queue a wait for this command to complete. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueReadImage</strong> and <strong>clEnqueueWriteImage</strong> return CL_SUCCESS if the
function is executed successfully. Otherwise, it returns one of the
following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em> and <em>image</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
i_mage_ is not a valid image object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
region being read or written specified by <em>origin</em> and <em>region</em> is out
of bounds or if <em>ptr</em> is a NULL value.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
in <em>origin</em> and <em>region</em> do not follow rules described in the argument
description for <em>origin</em> and <em>region</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
image dimensions (image width, height, specified or compute row and/or
slice pitch) for <em>image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_IMAGE_FORMAT_NOT_SUPPORTED if image format (image channel order and
data type) for <em>image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>image</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the device associated with <em>command_queue</em> does not support images (i.e.
CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_FALSE).
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
<strong>clEnqueueReadImage</strong> is called on <em>image</em> which has been created with
CL_MEM_HOST_WRITE_ONLY or CL_MEM_HOST_NO_ACCESS.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
<strong>clEnqueueWriteImage</strong> is called on <em>image</em> which has been created with
CL_MEM_HOST_READ_ONLY or CL_MEM_HOST_NO_ACCESS.
</p>
</li>
<li>
<p>
     CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the read and write
operations are blocking and the execution status of any of the events in
<em>event_wait_list</em> is a negative integer value.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>NOTE:</p></div>
<div class="paragraph"><p>Calling <strong>clEnqueueReadImage</strong> to read a region of the <em>image</em> with the
<em>ptr</em> argument value set to <em>host_ptr</em> + (<em>origin[2]</em>*<em>image slice pitch
+ origin[1]</em>*<em>image row pitch + origin[0]</em>*<em>bytes per pixel</em>)<em>,</em> where
<em>host_ptr</em> is a pointer to the memory region specified when the <em>image</em>
being read is created with CL_MEM_USE_HOST_PTR, must meet the following
requirements in order to avoid undefined behavior:</p></div>
<div class="ulist"><ul>
<li>
<p>
All commands that use this image object have finished execution before
the read command begins execution.
</p>
</li>
<li>
<p>
The <em>row_pitch</em> and <em>slice_pitch</em> argument values in
<strong>clEnqueueReadImage</strong> must be set to the image row pitch and slice pitch.
</p>
</li>
<li>
<p>
The image object is not mapped.
</p>
</li>
<li>
<p>
The image object is not used by any command-queue until the read
command has finished execution.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Calling <strong>clEnqueueWriteImage</strong> to update the latest bits in a region of
the <em>image</em> with the <em>ptr</em> argument value set to <em>host_ptr</em><br>
(<em>origin[2]</em>*<em>image slice pitch + origin[1]</em>*<em>image row pitch<br>
origin[0]</em>*<em>bytes per pixel</em>), where <em>host_ptr</em> is a pointer to the
memory region specified when the <em>image</em> being written is created with
CL_MEM_USE_HOST_PTR, must meet the following requirements in order to
avoid undefined behavior:</p></div>
<div class="ulist"><ul>
<li>
<p>
The host memory region being written contains the latest bits when the
enqueued write command begins execution.
</p>
</li>
<li>
<p>
The <em>input_row_pitch</em> and <em>input_slice_pitch</em> argument values in
<strong>clEnqueueWriteImage</strong> must be set to the image row pitch and slice
pitch.
</p>
</li>
<li>
<p>
The image object is not mapped.
</p>
</li>
<li>
<p>
The image object is not used by any command-queue until the write
command has finished execution.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueCopyImage(cl_command_queue command_queue,
cl_mem src_image,
cl_mem dst_image,
const size_t *src_origin,
const size_t *dst_origin,
const size_t *region,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to copy image objects. <em>src_image</em> and <em>dst_image</em>
can be 1D, 2D, 3D image or a 1D, 2D image array objects. It is
possible to copy subregions between any combinations of source and
destination types, provided that the dimensions of the subregions are
the same e.g., one can copy a rectangular region from a 2D image to a
slice of a 3D image.</p></div>
<div class="paragraph"><p><em>command_queue</em> refers to the host command-queue in which the copy
command will be queued. The OpenCL context associated with
<em>command_queue</em>, <em>src_image</em> and <em>dst_image</em> must be the same.</p></div>
<div class="paragraph"><p><em>src_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in pixels in the 1D, 2D
or 3D image, the (<em>x</em>, <em>y</em>) offset and the image index in the 2D image
array or the (<em>x</em>) offset and the image index in the 1D image array. If
<em>image</em> is a 2D image object, <em>src_origin</em>[2] must be 0. If <em>src_image</em>
is a 1D image object, <em>src_origin</em>[1] and <em>src_origin</em>[2] must be 0. If
<em>src_image</em> is a 1D image array object, <em>src_origin</em>[2] must be 0. If
<em>src_image</em> is a 1D image array object, <em>src_origin</em>[1] describes the
image index in the 1D image array. If <em>src_image</em> is a 2D image array
object, <em>src_origin</em>[2] describes the image index in the 2D image array.</p></div>
<div class="paragraph"><p><em>dst_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in pixels in the 1D, 2D
or 3D image, the (<em>x</em>, <em>y</em>) offset and the image index in the 2D image
array or the (<em>x</em>) offset and the image index in the 1D image array. If
<em>dst_image</em> is a 2D image object, <em>dst_origin</em>[2] must be 0. If
<em>dst_image</em> is a 1D image or 1D image buffer object, <em>dst_origin</em>[1] and
<em>dst_origin</em>[2] must be 0. If <em>dst_image</em> is a 1D image array object,
<em>dst_origin</em>[2] must be 0. If <em>dst_image</em> is a 1D image array object,
<em>dst_origin</em>[1] describes the image index in the 1D image array. If
<em>dst_image</em> is a 2D image array object, <em>dst_origin</em>[2] describes the
image index in the 2D image array.</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em>, <em>height,</em> <em>depth</em>) in pixels of the 1D,
2D or 3D rectangle, the (<em>width</em>, <em>height</em>) in pixels of the 2D
rectangle and the number of images of a 2D image array or the (<em>width</em>)
in pixels of the 1D rectangle and the number of images of a 1D image
array. If <em>src_image</em> or <em>dst_image</em> is a 2D image object, <em>region</em>[2]
must be 1. If <em>src_image</em> or <em>dst_image</em> is a 1D image or 1D image
buffer object, <em>region</em>[1] and <em>region</em>[2] must be 1. If <em>src_image</em> or
<em>dst_image</em> is a 1D image array object, <em>region</em>[2] must be 1. The
values in <em>region</em> cannot be 0.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular copy
command and can be used to query or queue a wait for this particular
command to complete. <em>event</em> can be NULL in which case it will not be
possible for the application to query the status of this command or
queue a wait for this command to complete.
<strong>clEnqueueBarrierWithWaitList</strong> can be used instead. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p>It is currently a requirement that the <em>src_image</em> and <em>dst_image</em> image
memory objects for <strong>clEnqueueCopyImage</strong> must have the exact same image
format (i.e. the cl_image_format descriptor specified when <em>src_image</em>
and <em>dst_image</em> are created must match).</p></div>
<div class="paragraph"><p><strong>clEnqueueCopyImage</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em>, <em>src_image</em> and <em>dst_image</em> are
not the same or if the context associated with <em>command_queue</em> and
events in <em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>src_image</em> and <em>dst_image</em> are not valid image objects.
</p>
</li>
<li>
<p>
      CL_IMAGE_FORMAT_MISMATCH
if <em>src_image</em> and <em>dst_image</em> do not use the same image format.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the 2D
or 3D rectangular region specified by <em>src_origin</em> and <em>src_origin</em><br>
<em>region</em> refers to a region outside <em>src_image</em>, or if the 2D or 3D
rectangular region specified by <em>dst_origin</em> and <em>dst_origin</em> + <em>region</em>
refers to a region outside <em>dst_image</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
in <em>src_origin</em>, <em>dst_origin</em> and <em>region</em> do not follow rules described
in the argument description for <em>src_origin</em>, <em>dst_origin</em> and <em>region</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
image dimensions (image width, height, specified or compute row and/or
slice pitch) for <em>src_image</em> or <em>dst_image</em> are not supported by device
associated with <em>queue</em>.
</p>
</li>
<li>
<p>
     CL_IMAGE_FORMAT_NOT_SUPPORTED if image format (image channel order and
data type) for <em>src_image</em> or <em>dst_image</em> are not supported by device
associated with <em>queue</em>.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>src_image</em> or <em>dst_image</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the device associated with <em>command_queue</em> does not support images (i.e.
CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_FALSE).
</p>
</li>
<li>
<p>
      CL_MEM_COPY_OVERLAP if
<em>src_image</em> and <em>dst_image</em> are the same image object and the source and
destination regions overlap.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_filling_image_objects">5.3.4. Filling Image Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueFillImage*(cl_command_queue command_queue,
cl_mem image,
const void *fill_color,
const size_t *origin,
const size_t *region,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to fill an image object with a specified color. The
usage information which indicates whether the memory object can be read
or written by a kernel and/or the host and is given by the cl_mem_flags
argument value specified when <em>image</em> is created is ignored by
<strong>clEnqueueFillImage</strong>.</p></div>
<div class="paragraph"><p><em>command_queue</em> refers to the host command-queue in which the fill
command will be queued. The OpenCL context associated with
<em>command_queue</em> and <em>image</em> must be the same.</p></div>
<div class="paragraph"><p><em>image</em> is a valid image object.</p></div>
<div class="paragraph"><p><em>fill_color</em> is the color used to fill the image. The fill color is a
single floating point value if the channel order is CL_DEPTH. Otherwise,
the fill color is a four component RGBA floating-point color value if
the <em>image</em> channel data type is not an unnormalized signed or unsigned
integer type, is a four component signed integer value if the <em>image</em>
channel data type is an unnormalized signed integer type and is a four
component unsigned integer value if the <em>image</em> channel data type is an
unnormalized unsigned integer type. The fill color will be converted to
the appropriate image channel format and order associated with <em>image</em>
as described in <em>sections 6.12.14</em> and <em>8.3</em>.</p></div>
<div class="paragraph"><p><em>origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in pixels in the 1D, 2D or
3D image, the (<em>x</em>, <em>y</em>) offset and the image index in the 2D image
array or the (<em>x</em>) offset and the image index in the 1D image array. If
<em>image</em> is a 2D image object, <em>origin</em>[2] must be 0. If <em>image</em> is a 1D
image or 1D image buffer object, <em>origin</em>[1] and <em>origin</em>[2] must be 0.
If <em>image</em> is a 1D image array object, <em>origin</em>[2] must be 0. If
<em>image</em> is a 1D image array object, <em>origin</em>[1] describes the image
index in the 1D image array. If <em>image</em> is a 2D image array object,
<em>origin</em>[2] describes the image index in the 2D image array.</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em>, <em>height,</em> <em>depth</em>) in pixels of the 1D,
2D or 3D rectangle, the (<em>width</em>, <em>height</em>) in pixels of the 2D
rectangle and the number of images of a 2D image array or the (<em>width</em>)
in pixels of the 1D rectangle and the number of images of a 1D image
array. If <em>image</em> is a 2D image object, <em>region</em>[2] must be 1. If
<em>image</em> is a 1D image or 1D image buffer object, <em>region</em>[1] and
<em>region</em>[2] must be 1. If <em>image</em> is a 1D image array object,
<em>region</em>[2] must be 1. The values in <em>region</em> cannot be 0.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. <strong>clEnqueueBarrierWithWaitList</strong> can be used
instead. If the <em>event_wait_list</em> and the <em>event</em> arguments are not
NULL, the <em>event</em> argument should not refer to an element of the
<em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueFillImage</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em> and <em>image</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>image</em> is not a valid image object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>fill_color</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
region being filled as specified by <em>origin</em> and <em>region</em> is out of
bounds or if <em>ptr</em> is a NULL value.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
in <em>origin</em> and <em>region</em> do not follow rules described in the argument
description for <em>origin</em> and <em>region</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
image dimensions (image width, height, specified or compute row and/or
slice pitch) for <em>image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_IMAGE_FORMAT_NOT_SUPPORTED if image format (image channel order and
data type) for <em>image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>image</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_copying_between_image_and_buffer_objects">5.3.5. Copying between Image and Buffer Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueCopyImageToBuffer(cl_command_queue command_queue,
cl_mem src_image,
cl_mem dst_buffer,
const size_t *src_origin,
const size_t *region,
size_t dst_offset,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to copy an image object to a buffer object.</p></div>
<div class="paragraph"><p><em>command_queue</em> must be a valid host command-queue. The OpenCL context
associated with <em>command_queue</em>, <em>src_image</em> and <em>dst_buffer</em> must be
the same.</p></div>
<div class="paragraph"><p><em>src_image</em> is a valid image object.</p></div>
<div class="paragraph"><p><em>dst_buffer</em> is a valid buffer object.</p></div>
<div class="paragraph"><p><em>src_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in pixels in the 1D, 2D
or 3D image, the (<em>x</em>, <em>y</em>) offset and the image index in the 2D image
array or the (<em>x</em>) offset and the image index in the 1D image array. If
<em>src_image</em> is a 2D image object, <em>src_origin</em>[2] must be 0. If
<em>src_image</em> is a 1D image or 1D image buffer object, <em>src_origin</em>[1] and
<em>src_origin</em>[2] must be 0. If <em>src_image</em> is a 1D image array object,
<em>src_origin</em>[2] must be 0. If <em>src_image</em> is a 1D image array object,
<em>src_origin</em>[1] describes the image index in the 1D image array. If
<em>src_image</em> is a 2D image array object, <em>src_origin</em>[2] describes the
image index in the 2D image array.</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em>, <em>height,</em> <em>depth</em>) in pixels of the 1D,
2D or 3D rectangle, the (<em>width</em>, <em>height</em>) in pixels of the 2D
rectangle and the number of images of a 2D image array or the (<em>width</em>)
in pixels of the 1D rectangle and the number of images of a 1D image
array. If <em>src_image</em> is a 2D image object, <em>region</em>[2] must be 1. If
<em>src_image</em> is a 1D image or 1D image buffer object, <em>region</em>[1] and
<em>region</em>[2] must be 1. If <em>src_image</em> is a 1D image array object,
<em>region</em>[2] must be 1. The values in <em>region</em> cannot be 0.</p></div>
<div class="paragraph"><p><em>dst_offset</em> refers to the offset where to begin copying data into
<em>dst_buffer</em>. The size in bytes of the region to be copied referred to
as <em>dst_cb</em> is computed as <em>width</em> * <em>height</em> * <em>depth</em> * <em>bytes/image
element</em> if <em>src_image</em> is a 3D image object, is computed as <em>width</em> *
<em>height</em> * <em>bytes/image element</em> if <em>src_image</em> is a 2D image, is
computed as <em>width</em> * <em>height</em> * <em>arraysize</em> * <em>bytes/image element</em> if
<em>src_image</em> is a 2D image array object, is computed as <em>width</em> *
<em>bytes/image element</em> if <em>src_image</em> is a 1D image or 1D image buffer
object and is computed as <em>width</em> * <em>arraysize</em> * <em>bytes/image element</em>
if <em>src_image</em> is a 1D image array object.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular copy
command and can be used to query or queue a wait for this particular
command to complete. <em>event</em> can be NULL in which case it will not be
possible for the application to query the status of this command or
queue a wait for this command to complete.
<strong>clEnqueueBarrierWithWaitList</strong> can be used instead. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueCopyImageToBuffer</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em>, <em>src_image</em> and <em>dst_buffer</em>
are not the same or if the context associated with <em>command_queue</em> and
events in <em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>src_image</em> is not a valid image object or <em>dst_buffer</em> is not a valid
buffer object or if <em>src_image</em> is a 1D image buffer object created from
<em>dst_buffer</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
1D, 2D or 3D rectangular region specified by <em>src_origin</em> and
<em>src_origin</em> + <em>region</em> refers to a region outside <em>src_image</em>, or if
the region specified by <em>dst_offset</em> and <em>dst_offset</em> + <em>dst_cb</em> to a
region outside <em>dst_buffer</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
in <em>src_origin</em> and <em>region</em> do not follow rules described in the
argument description for <em>src_origin</em> and <em>region</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
     CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>dst_buffer</em> is a sub-buffer object
and <em>offset</em> specified when the sub-buffer object is created is not
aligned to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated
with <em>queue</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
image dimensions (image width, height, specified or compute row and/or
slice pitch) for <em>src_image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_IMAGE_FORMAT_NOT_SUPPORTED if image format (image channel order and
data type) for <em>src_image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>src_image</em> or <em>dst_buffer</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the device associated with <em>command_queue</em> does not support images (i.e.
CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_FALSE).
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueCopyBufferToImage(cl_command_queue command_queue,
cl_mem src_buffer,
cl_mem dst_image,
size_t src_offset,
const size_t *dst_origin,
const size_t *region,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to copy a buffer object to an image object.</p></div>
<div class="paragraph"><p><em>command_queue</em> must be a valid host command-queue. The OpenCL context
associated with <em>command_queue</em>, <em>src_buffer</em> and <em>dst_image</em> must be
the same.</p></div>
<div class="paragraph"><p><em>src_buffer</em> is a valid buffer object.</p></div>
<div class="paragraph"><p><em>dst_image</em> is a valid image object.</p></div>
<div class="paragraph"><p><em>src_offset</em> refers to the offset where to begin copying data from
<em>src_buffer</em>.</p></div>
<div class="paragraph"><p><em>dst_origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in pixels in the 1D, 2D
or 3D image, the (<em>x</em>, <em>y</em>) offset and the image index in the 2D image
array or the (<em>x</em>) offset and the image index in the 1D image array. If
<em>dst_image</em> is a 2D image object, <em>dst_origin</em>[2] must be 0. If
<em>dst_image</em> is a 1D image or 1D image buffer object, <em>dst_origin</em>[1] and
<em>dst_origin</em>[2] must be 0. If <em>dst_image</em> is a 1D image array object,
<em>dst_origin</em>[2] must be 0. If <em>dst_image</em> is a 1D image array object,
<em>dst_origin</em>[1] describes the image index in the 1D image array. If
<em>dst_image</em> is a 2D image array object, <em>dst_origin</em>[2] describes the
image index in the 2D image array.</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em>, <em>height,</em> <em>depth</em>) in pixels of the 1D,
2D or 3D rectangle, the (<em>width</em>, <em>height</em>) in pixels of the 2D
rectangle and the number of images of a 2D image array or the (<em>width</em>)
in pixels of the 1D rectangle and the number of images of a 1D image
array. If <em>dst_image</em> is a 2D image object, <em>region</em>[2] must be 1. If
<em>dst_image</em> is a 1D image or 1D image buffer object, <em>region</em>[1] and
<em>region</em>[2] must be 1. If <em>dst_image</em> is a 1D image array object,
<em>region</em>[2] must be 1. The values in <em>region</em> cannot be 0.</p></div>
<div class="paragraph"><p>The size in bytes of the region to be copied from <em>src_buffer</em> referred
to as <em>src_cb</em> is computed as <em>width</em> * <em>height</em> * <em>depth</em> *
<em>bytes/image element</em> if <em>dst_image</em> is a 3D image object, is computed
as <em>width</em> * <em>height</em> * <em>bytes/image element</em> if <em>dst_image</em> is a 2D
image, is computed as <em>width</em> * <em>height</em> * <em>arraysize</em> * <em>bytes/image
element</em> if <em>dst_image</em> is a 2D image array object, is computed as
<em>width</em> * <em>bytes/image element</em> if <em>dst_image</em> is a 1D image or 1D image
buffer object and is computed as <em>width</em> * <em>arraysize</em> * <em>bytes/image
element</em> if <em>dst_image</em> is a 1D image array object.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular copy
command and can be used to query or queue a wait for this particular
command to complete. <em>event</em> can be NULL in which case it will not be
possible for the application to query the status of this command or
queue a wait for this command to complete.
<strong>clEnqueueBarrierWithWaitList</strong> can be used instead. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueCopyBufferToImage</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em>, <em>src_buffer</em> and <em>dst_image</em>
are not the same or if the context associated with <em>command_queue</em> and
events in <em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>src_buffer</em> is not a valid buffer object or <em>dst_image</em> is not a valid
image object or if <em>dst_image</em> is a 1D image buffer object created from
<em>src_buffer</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
1D, 2D or 3D rectangular region specified by <em>dst_origin</em> and
<em>dst_origin</em> + <em>region</em> refer to a region outside <em>dst_image</em>, or if the
region specified by <em>src_offset</em> and <em>src_offset</em> + <em>src_cb</em> refer to a
region outside <em>src_buffer</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
in <em>dst_origin</em> and <em>region</em> do not follow rules described in the
argument description for <em>dst_origin</em> and <em>region</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
     CL_MISALIGNED_SUB_BUFFER_OFFSET if <em>src_buffer</em> is a sub-buffer object
and <em>offset</em> specified when the sub-buffer object is created is not
aligned to CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated
with <em>queue</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
image dimensions (image width, height, specified or compute row and/or
slice pitch) for <em>dst_image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_IMAGE_FORMAT_NOT_SUPPORTED if image format (image channel order and
data type) for <em>dst_image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>src_buffer</em> or <em>dst_image</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the device associated with <em>command_queue</em> does not support images (i.e.
CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_FALSE).
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_mapping_image_objects">5.3.6. Mapping Image Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>void clEnqueueMapImage(cl_command_queue command_queue,
cl_mem image,
cl_bool blocking_map,
cl_map_flags map_flags,
const size_t *origin,
const size_t *region,
size_t *image_row_pitch,
size_t *image_slice_pitch,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to map a region in the image object given by <em>image</em>
into the host address space and returns a pointer to this mapped region.</p></div>
<div class="paragraph"><p><em>command_queue</em> must be a valid host command-queue.</p></div>
<div class="paragraph"><p><em>image</em> is a valid image object. The OpenCL context associated with
<em>command_queue</em> and <em>image</em> must be the same.</p></div>
<div class="paragraph"><p><em>blocking_map</em> indicates if the map operation is <em>blocking</em> or
<em>non-blocking</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_map</em> is CL_TRUE, <strong>clEnqueueMapImage</strong> does not return until
the specified region in <em>image</em> is mapped into the host address space
and the application can access the contents of the mapped region using
the pointer returned by <strong>clEnqueueMapImage</strong>.</p></div>
<div class="paragraph"><p>If <em>blocking_map</em> is CL_FALSE i.e. map operation is non-blocking, the
pointer to the mapped region returned by <strong>clEnqueueMapImage</strong> cannot be
used until the map command has completed. The <em>event</em> argument returns
an event object which can be used to query the execution status of the
map command. When the map command is completed, the application can
access the contents of the mapped region using the pointer returned by
<strong>clEnqueueMapImage</strong>.</p></div>
<div class="paragraph"><p><em>map_flags</em> is a bit-field and is described in <em>table 5.5</em>.</p></div>
<div class="paragraph"><p><em>origin</em> defines the (<em>x</em>, <em>y</em>, <em>z</em>) offset in pixels in the 1D, 2D or
3D image, the (<em>x</em>, <em>y</em>) offset and the image index in the 2D image
array or the (<em>x</em>) offset and the image index in the 1D image array. If
<em>image</em> is a 2D image object, <em>origin</em>[2] must be 0. If <em>image</em> is a 1D
image or 1D image buffer object, <em>origin</em>[1] and <em>origin</em>[2] must be 0.
If <em>image</em> is a 1D image array object, <em>origin</em>[2] must be 0. If
<em>image</em> is a 1D image array object, <em>origin</em>[1] describes the image
index in the 1D image array. If <em>image</em> is a 2D image array object,
<em>origin</em>[2] describes the image index in the 2D image array.</p></div>
<div class="paragraph"><p><em>region_defines the_</em>(<em>width</em>, <em>height,</em> <em>depth</em>) in pixels of the 1D,
2D or 3D rectangle, the (<em>width</em>, <em>height</em>) in pixels of the 2D
rectangle and the number of images of a 2D image array or the (<em>width</em>)
in pixels of the 1D rectangle and the number of images of a 1D image
array. If <em>image</em> is a 2D image object, <em>region</em>[2] must be 1. If
<em>image</em> is a 1D image or 1D image buffer object, <em>region</em>[1] and
<em>region</em>[2] must be 1. If <em>image</em> is a 1D image array object,
<em>region</em>[2] must be 1. The values in <em>region</em> cannot be 0.</p></div>
<div class="paragraph"><p><em>image_row_pitch</em> returns the scan-line pitch in bytes for the mapped
region. This must be a non-NULL value.</p></div>
<div class="paragraph"><p><em>image_slice_pitch</em> returns the size in bytes of each 2D slice of a 3D
image or the size of each 1D or 2D image in a 1D or 2D image array for
the mapped region. For a 1D and 2D image, zero is returned if this
argument is not NULL. For a 3D image, 1D and 2D image array,
<em>image_slice_pitch</em> must be a non-NULL value.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before <strong>clEnqueueMapImage</strong> can be executed. If
<em>event_wait_list</em> is NULL, then <strong>clEnqueueMapImage</strong> does not wait on any
event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. If the <em>event_wait_list</em> and the <em>event</em>
arguments are not NULL, the <em>event</em> argument should not refer to an
element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clEnqueueMapImage</strong> will return a pointer to the mapped region. The
<em>errcode_ret</em> is set to CL_SUCCESS.</p></div>
<div class="paragraph"><p>A NULL pointer is returned otherwise with one of the following error
values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if _command_queue_is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue_and _image</em> are not the same or
if context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>image</em> is not a valid image object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if region
being mapped given by (<em>origin</em>, <em>origin+region</em>) is out of bounds or if
values specified in _map_flags_are not valid.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
in <em>origin</em> and <em>region</em> do not follow rules described in the argument
description for <em>origin</em> and <em>region</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>image_row_pitch</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>image</em> is a 3D image, 1D or 2D image array object and
<em>image_slice_pitch</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
image dimensions (image width, height, specified or compute row and/or
slice pitch) for <em>image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
     CL_IMAGE_FORMAT_NOT_SUPPORTED if image format (image channel order and
data type) for <em>image</em> are not supported by device associated with
<em>queue</em>.
</p>
</li>
<li>
<p>
      CL_MAP_FAILURE if there is
a failure to map the requested region into the host address space. This
error cannot occur for image objects created with CL_MEM_USE_HOST_PTR or
CL_MEM_ALLOC_HOST_PTR.
</p>
</li>
<li>
<p>
     CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the map operation is
blocking and the execution status of any of the events in
<em>event_wait_list</em> is a negative integer value.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with <em>image</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the device associated with <em>command_queue</em> does not support images (i.e.
CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_FALSE).
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
<em>image</em> has been created with CL_MEM_HOST_WRITE_ONLY or
CL_MEM_HOST_NO_ACCESS and CL_MAP_READ is set in <em>map_flags</em> or if
<em>image</em> has been created with CL_MEM_HOST_READ_ONLY or
CL_MEM_HOST_NO_ACCESS and CL_MAP_WRITE or CL_MAP_WRITE_INVALIDATE_REGION
is set in <em>map_flags</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
mapping would lead to overlapping regions being mapped for writing.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The pointer returned maps a 1D, 2D or 3D region starting at <em>origin</em> and
is at least <em>region[0]</em> pixels in size for a 1D image, 1D image buffer
or 1D image array, (<em>image_row_pitch * region[1])</em> pixels in size for a
2D image or 2D image array, and (<em>image_slice_pitch * region[2])</em> pixels
in size for a 3D image. The result of a memory access outside this
region is undefined.</p></div>
<div class="paragraph"><p>If the image object is created with CL_MEM_USE_HOST_PTR set in
<em>mem_flags</em>, the following will be true:</p></div>
<div class="ulist"><ul>
<li>
<p>
      The <em>host_ptr</em> specified
in <strong>clCreateImage</strong> is guaranteed to contain the latest bits in the
region being mapped when the <strong>clEnqueueMapImage</strong> command has completed.
</p>
</li>
<li>
<p>
      The pointer value returned
by <strong>clEnqueueMapImage</strong> will be derived from the <em>host_ptr</em> specified
when the image object is created.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Mapped image objects are unmapped using <strong>clEnqueueUnmapMemObject</strong>. This
is described in <em>section 5.5.2</em>.</p></div>
</div>
<div class="sect3">
<h4 id="_image_object_queries">5.3.7. Image Object Queries</h4>
<div class="paragraph"><p>To get information that is common to all memory objects, use the
<strong>clGetMemObjectInfo</strong> function described in <em>section 5.5.5</em>.</p></div>
<div class="paragraph"><p>To get information specific to an image object created with
<strong>clCreateImage</strong>, use the following function
 </p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetImageInfo(cl_mem image,
cl_image_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p><em>image</em> specifies the image object being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetImageInfo</strong> is described in <em>table 5.10</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.10</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<div class="paragraph"><p><strong>clGetImageInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table
5.10_and _param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>image</em> is a not a valid image object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 16. <em>List of supported param_names by clGetImageInfo</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_image_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_FORMAT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_image_format</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return image format descriptor
specified when <em>image</em> is created with <strong>clCreateImage</strong>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_ELEMENT_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return size of each element of the
image memory object given by <em>image</em> in bytes. An element is made up of
<em>n</em> channels. The value of <em>n</em> is given in <em>cl_image_format</em>
descriptor.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_ROW_PITCH</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return calculated row pitch in bytes of a
row of elements of the image object given by <em>image</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_SLICE_PITCH</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return calculated slice pitch in bytes
of a 2D slice for the 3D image object or size of each image in a 1D or
2D image array given by <em>image</em>. For a 1D image, 1D image buffer and 2D
image object return 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_WIDTH</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return width of the image in pixels.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_HEIGHT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return height of the image in pixels. For a
1D image, 1D image buffer and 1D image array object, height = 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_DEPTH</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return depth of the image in pixels. For a
1D image, 1D image buffer, 2D image or 1D and 2D image array object,
depth = 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_ARRAY_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return number of images in the image
array. If <em>image</em> is not an image array, 0 is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_NUM_MIP_<br>
LEVELS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return num_mip_levels associated with <em>image</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_IMAGE_NUM_SAMPLES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return num_samples associated with
<em>image</em>.</p></td>
</tr>
</tbody>
</table>
</div>
</div>
<div class="sect2">
<h3 id="_pipes">5.4. Pipes</h3>
<div class="paragraph"><p>A <em>pipe</em> is a memory object that stores data organized as a FIFO. Pipe
objects can only be accessed using built-in functions that read from and
write to a pipe. Pipe objects are not accessible from the host. A pipe
object encapsulates the following information:</p></div>
<div class="ulist"><ul>
<li>
<p>
      Packet size in bytes
</p>
</li>
<li>
<p>
      Maximum capacity in packets
</p>
</li>
<li>
<p>
      Information about the number of packets currently in the pipe
</p>
</li>
<li>
<p>
      Data packets
</p>
</li>
</ul></div>
<div class="sect3">
<h4 id="_creating_pipe_objects">5.4.1. Creating Pipe Objects</h4>
<div class="paragraph"><p>A <strong>pipe object</strong> is created using the following function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_mem clCreatePipe(cl_context context,
cl_mem_flags flags,
cl_uint pipe_packet_size,
cl_uint pipe_max_packets,
const cl_pipe_properties *properties,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p><em>context</em> is a valid OpenCL context used to create the pipe object.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify allocation and usage
information such as the memory arena that should be used to allocate the
pipe object and how it will be used. <em>Table 5.3</em> describes the possible
values for <em>flags</em>. Only CL_MEM_READ_WRITE and CL_MEM_HOST_NO_ACCESS
can be specified when creating a pipe object. If the value specified for
<em>flags</em> is 0, the default is used which is CL_MEM_READ_WRITE |
CL_MEM_HOST_NO_ACCESS.</p></div>
<div class="paragraph"><p><em>pipe_packet_size</em> is the size in bytes of a pipe packet.</p></div>
<div class="paragraph"><p><em>pipe_max_packets</em> specifies the pipe capacity by specifying the maximum
number of packets the pipe can hold.</p></div>
<div class="paragraph"><p><em>properties</em> specifies a list of properties for the pipe and their
corresponding values. Each property name is immediately followed by the
corresponding desired value. The list is terminated with 0. In OpenCL
2.2, <em>properties</em> must be NULL.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreatePipe</strong> returns a valid non-zero pipe object and <em>errcode_ret</em> is
set to CL_SUCCESS if the pipe object is created successfully.
Otherwise, it returns a NULL value with one of the following error
values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if values
specified in _flags_are not as defined above.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>properties</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_PIPE_SIZE if
<em>pipe_packet_size</em> is 0 or the <em>pipe_packet_size</em> exceeds
CL_DEVICE_PIPE_MAX_PACKET_SIZE value specified in <em>table 4.3</em> for all
devices in <em>context_or if _pipe_max_packets</em> is 0.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for the pipe object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Pipes follow the same memory consistency model as defined for buffer and
image objects. The pipe state i.e. contents of the pipe across
kernel-instances (on the same or different devices) is enforced at a
synchronization point.</p></div>
</div>
<div class="sect3">
<h4 id="_pipe_object_queries">5.4.2. Pipe Object Queries</h4>
<div class="paragraph"><p>To get information that is common to all memory objects, use the
<strong>clGetMemObjectInfo</strong> function described in <em>section 5.5.5</em>.</p></div>
<div class="paragraph"><p>To get information specific to a pipe object created with
<strong>clCreatePipe</strong>, use the following function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetPipeInfo(cl_mem pipe,
cl_pipe_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p><em>pipe</em> specifies the pipe object being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetPipeInfo</strong> is described in <em>table 5.11</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.11</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<div class="paragraph"><p><strong>clGetPipeInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table
5.11_and _param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>pipe</em> is a not a valid pipe object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 17. <em>List of supported param_names by clGetPipeInfo</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_pipe_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PIPE_PACKET_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return pipe packet size specified when
<em>pipe</em> is created with <strong>clCreatePipe</strong>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PIPE_MAX_PACKETS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return max. number of packets specified
when <em>pipe</em> is created with <strong>clCreatePipe</strong>.</p></td>
</tr>
</tbody>
</table>
</div>
</div>
<div class="sect2">
<h3 id="_handling_memory_objects">5.5. Handling Memory Objects</h3>
<div class="sect3">
<h4 id="_retaining_and_releasing_memory_objects">5.5.1. Retaining and Releasing Memory Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainMemObject(cl_mem memobj)</pre>
</div></div>
<div class="paragraph"><p>increments the <em>memobj</em> reference count. <strong>clRetainMemObject</strong> returns
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>memobj</em> is not a valid memory object (buffer or image object).
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>clCreateBuffer</strong>, <strong>clCreateSubBuffer</strong>, <strong>clCreateImage</strong> and
<strong>clCreatePipe</strong> perform an implicit retain.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseMemObject(cl_mem memobj)</pre>
</div></div>
<div class="paragraph"><p>decrements the <em>memobj</em> reference count. <strong>clReleaseMemObject</strong> returns
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>memobj</em> is not a valid memory object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>After the <em>memobj</em> reference count becomes zero and commands queued for
execution on a command-queue(s) that use <em>memobj</em> have finished, the
memory object is deleted. If <em>memobj</em> is a buffer object, <em>memobj</em>
cannot be deleted until all sub-buffer objects associated with <em>memobj</em>
are deleted. Using this function to release a reference that was not
obtained by creating the object or by calling <strong>clRetainMemObject</strong> causes
undefined behavior.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetMemObjectDestructorCallback
(cl_mem memobj,
void (CL_CALLBACK *pfn_notify)(cl_mem memobj,void *user_data),
void *user_data)</pre>
</div></div>
<div class="paragraph"><p>registers a user callback function with a memory object. Each call to
<strong>clSetMemObjectDestructorCallback</strong> registers the specified user callback
function on a callback stack associated with <em>memobj</em>. The registered
user callback functions are called in the reverse order in which they
were registered. The user callback functions are called and then the
memory objects resources are freed and the memory object is deleted.
This provides a mechanism for the application (and libraries) using
<em>memobj</em> to be notified when the memory referenced by <em>host_ptr</em>,
specified when the memory object is created and used as the storage bits
for the memory object, can be reused or freed.</p></div>
<div class="paragraph"><p><em>memobj</em> is a valid memory object.</p></div>
<div class="paragraph"><p><em>pfn_notify</em> is the callback function that can be registered by the
application. This callback function may be called asynchronously by the
OpenCL implementation. It is the applications responsibility to ensure
that the callback function is thread-safe. The parameters to this
callback function are:</p></div>
<div class="ulist"><ul>
<li>
<p>
      <em>memobj_is the memory
object being deleted. When the user callback is called by the
implementation, this memory object is not longer valid. _memobj</em> is
only provided for reference purposes.
</p>
</li>
<li>
<p>
      _user_data_is a pointer to
user supplied data.
</p>
</li>
</ul></div>
<div class="paragraph"><p>_user_data_will be passed as the _user_data_argument when _pfn_notify_is
called. _user_data_can be NULL.</p></div>
<div class="paragraph"><p><strong>clSetMemObjectDestructorCallback</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>memobj</em> is not a valid memory object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pfn_notify</em> is NULL.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">When the user callback function is called by the implementation,
the contents of the memory region pointed to by <em>host_ptr</em> (if the
memory object is created with CL_MEM_USE_HOST_PTR) are undefined. The
callback function is typically used by the application to either free or
reuse the memory region pointed to by <em>host_ptr</em>.</td>
</tr></table>
</div>
<div class="paragraph"><p>The behavior of calling expensive system routines, OpenCL API calls to
create contexts or command-queues, or blocking OpenCL operations from
the following list below, in a callback is undefined.</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>clFinish</strong>
</p>
</li>
<li>
<p>
<strong>clWaitForEvents</strong>
</p>
</li>
<li>
<p>
blocking calls to <strong>clEnqueueReadBuffer</strong>, <strong>clEnqueueReadBufferRect</strong>,
</p>
</li>
<li>
<p>
<strong>clEnqueueWriteBuffer</strong>,<strong>clEnqueueWriteBufferRect,</strong>
</p>
</li>
<li>
<p>
blocking calls to <strong>clEnqueueReadImage</strong> and *clEnqueueWriteImage, *
</p>
</li>
<li>
<p>
blocking calls to <strong>clEnqueueMapBuffer,</strong>
</p>
</li>
<li>
<p>
<strong>clEnqueueMapImage</strong>,
</p>
</li>
<li>
<p>
blocking calls to <strong>clBuildProgram</strong>, <strong>clCompileProgram</strong> or <strong>clLinkProgram</strong>
</p>
</li>
</ul></div>
<div class="paragraph"><p>If an application needs to wait for completion of a routine from the
above list in a callback, please use the non-blocking form of the
function, and assign a completion callback to it to do the remainder of
your work.  Note that when a callback (or other code) enqueues commands
to a command-queue, the commands are not required to begin execution
until the queue is flushed. In standard usage, blocking enqueue calls
serve this role by implicitly flushing the queue. Since blocking calls
are not permitted in callbacks, those callbacks that enqueue commands on
a command queue should either call <strong>clFlush</strong> on the queue before
returning or arrange for <strong>clFlush</strong> to be called later on another thread.</p></div>
<div class="paragraph"><p>The user callback function may not call OpenCL APIs with the memory
object for which the callback function is invoked and for such cases the
behavior of OpenCL APIs is considered to be undefined.</p></div>
</div>
<div class="sect3">
<h4 id="_unmapping_mapped_memory_objects">5.5.2. Unmapping Mapped Memory Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueUnmapMemObject(cl_command_queue command_queue,
cl_mem memobj,
void *mapped_ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to unmap a previously mapped region of a memory
object. Reads or writes from the host using the pointer returned by
<strong>clEnqueueMapBuffer</strong> or *clEnqueueMapImage*are considered to be complete.</p></div>
<div class="paragraph"><p><em>command_queue</em> must be a valid host command-queue.</p></div>
<div class="paragraph"><p><em>memobj</em> is a valid memory (buffer or image) object. The OpenCL context
associated with <em>command_queue</em> and <em>memobj</em> must be the same.</p></div>
<div class="paragraph"><p><em>mapped_ptr</em> is the host address returned by a previous call to
<strong>clEnqueueMapBuffer</strong>, or <strong>clEnqueueMapImage</strong> for <em>memobj</em>.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before <strong>clEnqueueUnmapMemObject</strong> can be executed. If
<em>event_wait_list</em> is NULL, then <strong>clEnqueueUnmapMemObject</strong> does not wait
on any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. <strong>clEnqueueBarrierWithWaitList</strong> can be used
instead. If the <em>event_wait_list</em> and the <em>event</em> arguments are not
NULL, the <em>event</em> argument should not refer to an element of the
<em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueUnmapMemObject</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>memobj</em> is not a valid memory object or is a pipe object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>mapped_ptr</em> is not a valid pointer returned by
<strong>clEnqueueMapBuffer</strong> or <strong>clEnqueueMapImage</strong> for <em>memobj</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or if
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and <em>memobj</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>clEnqueueMapBuffer</strong> and <strong>clEnqueueMapImage</strong> increment the mapped count
of the memory object. The initial mapped count value of the memory
object is zero. Multiple calls to
<strong>clEnqueueMapBuffer</strong>, or <strong>clEnqueueMapImage</strong> on the same memory object
will increment this mapped count by appropriate number of calls.
*clEnqueueUnmapMemObject*decrements the mapped count of the memory
object.</p></div>
<div class="paragraph"><p><strong>clEnqueueMapBuffer</strong>, and <strong>clEnqueueMapImage</strong> act as synchronization
points for a region of the buffer object being mapped.</p></div>
</div>
<div class="sect3">
<h4 id="_accessing_mapped_regions_of_a_memory_object">5.5.3. Accessing mapped regions of a memory object</h4>
<div class="paragraph"><p>This section describes the behavior of OpenCL commands that access
mapped regions of a memory object.</p></div>
<div class="paragraph"><p>The contents of the region of a memory object and associated memory
objects (sub-buffer objects or 1D image buffer objects that overlap this
region) mapped for writing (i.e. CL_MAP_WRITE or
CL_MAP_WRITE_INVALIDATE_REGION is set in <em>map_flags</em> argument to
<strong>clEnqueueMapBuffer</strong>, or <strong>clEnqueueMapImage</strong>) are considered to be
undefined until this region is unmapped.</p></div>
<div class="paragraph"><p>Multiple commands in command-queues can map a region or overlapping
regions of a memory object and associated memory objects (sub-buffer
objects or 1D image buffer objects that overlap this region) for reading
(i.e. <em>map_flags</em> = CL_MAP_READ). The contents of the regions of a
memory object mapped for reading can also be read by kernels and other
OpenCL commands (such as <strong>clEnqueueCopyBuffer</strong>) executing on a
device(s).</p></div>
<div class="paragraph"><p>Mapping (and unmapping) overlapped regions in a memory object and/or
associated memory objects (sub-buffer objects or 1D image buffer objects
that overlap this region) for writing is an error and will result in
CL_INVALID_OPERATION error returned by <strong>clEnqueueMapBuffer</strong>, or
<strong>clEnqueueMapImage</strong>.</p></div>
<div class="paragraph"><p>If a memory object is currently mapped for writing, the application must
ensure that the memory object is unmapped before any enqueued kernels or
commands that read from or write to this memory object or any of its
associated memory objects (sub-buffer or 1D image buffer objects) or its
parent object (if the memory object is a sub-buffer or 1D image buffer
object) begin execution; otherwise the behavior is undefined.</p></div>
<div class="paragraph"><p>If a memory object is currently mapped for reading, the application must
ensure that the memory object is unmapped before any enqueued kernels or
commands that write to this memory object or any of its associated
memory objects (sub-buffer or 1D image buffer objects) or its parent
object (if the memory object is a sub-buffer or 1D image buffer object)
begin execution; otherwise the behavior is undefined.</p></div>
<div class="paragraph"><p>A memory object is considered as mapped if there are one or more active
mappings for the memory object irrespective of whether the mapped
regions span the entire memory object.</p></div>
<div class="paragraph"><p>Accessing the contents of the memory region referred to by the mapped
pointer that has been unmapped is undefined.</p></div>
<div class="paragraph"><p>The mapped pointer returned by <strong>clEnqueueMapBuffer</strong> or
<strong>clEnqueueMapImage</strong> can be used as <em>ptr</em> argument value to
<strong>clEnqueue{Read | Write}Buffer</strong>, <strong>clEnqeue{Read | Write}BufferRect</strong>,
<strong>clEnqueue{Read | Write}Image</strong> provided the rules described above are
adhered to.</p></div>
</div>
<div class="sect3">
<h4 id="_migrating_memory_objects">5.5.4. Migrating Memory Objects</h4>
<div class="paragraph"><p>This section describes a mechanism for assigning which device an OpenCL
memory object resides. A user may wish to have more explicit control
over the location of their memory objects on creation. This could be
used to:</p></div>
<div class="ulist"><ul>
<li>
<p>
      Ensure that an object is
allocated on a specific device prior to usage.
</p>
</li>
<li>
<p>
      Preemptively migrate an
object from one device to another.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueMigrateMemObjects(cl_command_queue command_queue,
cl_uint num_mem_objects,
const cl_mem *mem_objects,
cl_mem_migration_flags flags,
cl_uint num_events_in_wait_list
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to indicate which device a set of memory objects
should be associated with. Typically, memory objects are implicitly
migrated to a device for which enqueued commands, using the memory
object, are targeted. <strong>clEnqueueMigrateMemObjects</strong> allows this
migration to be explicitly performed ahead of the dependent commands.
This allows a user to preemptively change the association of a memory
object, through regular command queue scheduling, in order to prepare
for another upcoming command. This also permits an application to
overlap the placement of memory objects with other unrelated operations
before these memory objects are needed potentially hiding transfer
latencies. Once the event, returned from <strong>clEnqueueMigrateMemObjects</strong>,
has been marked CL_COMPLETE the memory objects specified in
<em>mem_objects</em> have been successfully migrated to the device associated
with <em>command_queue</em>. The migrated memory object shall remain resident
on the device until another command is enqueued that either implicitly
or explicitly migrates it away.</p></div>
<div class="paragraph"><p><strong>clEnqueueMigrateMemObjects</strong> can also be used to direct the initial
placement of a memory object, after creation, possibly avoiding the
initial overhead of instantiating the object on the first enqueued
command to use it.</p></div>
<div class="paragraph"><p>The user is responsible for managing the event dependencies, associated
with this command, in order to avoid overlapping access to memory
objects. Improperly specified event dependencies passed to
<strong>clEnqueueMigrateMemObjects</strong> could result in undefined results.</p></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command-queue. The specified set of
memory objects in <em>mem_objects</em> will be migrated to the OpenCL device
associated with <em>command_queue</em> or to the host if the
CL_MIGRATE_MEM_OBJECT_HOST has been specified.</p></div>
<div class="paragraph"><p><em>num_mem_objects_is the number of memory objects specified in
_mem_objects</em>.</p></div>
<div class="paragraph"><p><em>mem_objects</em> is a pointer to a list of memory objects.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify migration options. The
<em>table 5.12</em> describes the possible values for flags.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 18. <em>Supported values for cl_mem_migration_flags</em></caption>
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_mem_migration flags</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MIGRATE_MEM_OBJECT_HOST</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag indicates that the specified
set of memory objects are to be migrated to the host, regardless of the
target command-queue.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MIGRATE_MEM_OBJECT_<br>
CONTENT_UNDEFINED</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag indicates that the contents of the set of
memory objects are undefined after migration. The specified set of
memory objects are migrated to the device associated with
_command_queue_without incurring the overhead of migrating their
contents.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. If the <em>event_wait_list</em> and the <em>event</em>
arguments are not NULL, the <em>event</em> argument should not refer to an
element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueMigrateMemObjects</strong> return CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em> and memory objects in
<em>mem_objects</em> are not the same or if the context associated with
<em>command_queue</em> and events in <em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
any of the memory objects in <em>mem_objects</em> is not a valid memory object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>num_mem_objects</em> is zero or if <em>mem_objects</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>flags</em> is not 0 or is not any of the values described in the table
above.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for the specified set of memory objects in <em>mem_objects</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_memory_object_queries">5.5.5. Memory Object Queries</h4>
<div class="paragraph"><p>To get information that is common to all memory objects (buffer and
image objects), use the following function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetMemObjectInfo(cl_mem memobj,
cl_mem_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p><em>memobj</em> specifies the memory object being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetMemObjectInfo</strong> is described in <em>table 5.13</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.13</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<div class="paragraph"><p><strong>clGetMemObjectInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table 5.13</em>
and <em>param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
<em>memobj</em> is a not a valid memory object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
 
</p>
</li>
</ul></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 19. <em>List of supported param_names by clGetMemObjectInfo</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_mem_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_TYPE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_mem_object_type</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns one of the following values:
<br>
<br>
CL_MEM_OBJECT_BUFFER if memobj
is created with clCreateBuffer or
clCreateSubBuffer.
<br>
<br>
cl_image_desc.image_type argument
value if memobj is created with
clCreateImage.
<br>
<br>
CL_MEM_OBJECT_PIPE if memobj is
created with clCreatePipe.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_FLAGS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_mem_flags</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the flags argument value specified
when memobj is created with
clCreateBuffer,
clCreateSubBuffer,
clCreateImage or
clCreatePipe.
<br>
<br>
If memobj is a sub-buffer the memory
access qualifiers inherited from parent
buffer is also returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return actual size of the data store associated
with <em>memobj</em> in bytes.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_HOST_PTR</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">void *</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">If memobj is created with
clCreateBuffer or clCreateImage and
CL_MEM_USE_HOST_PTR is specified
in mem_flags, return the host_ptr
argument value specified when memobj
is created. Otherwise a NULL value is
returned.
<br>
<br>
If memobj is created with
clCreateSubBuffer, return the host_ptr
+ origin value specified when memobj is
created. host_ptr is the argument value
specified to clCreateBuffer and
CL_MEM_USE_HOST_PTR is specified
in mem_flags for memory object from
which memobj is created. Otherwise a
NULL value is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_MEM_MAP_COUNT*<span class="footnote"><br>[The map count returned should be considered immediately stale. It is unsuitable for general use in applications.
This feature is provided for debugging.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Map count.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_MEM_REFERENCE_COUNT*<span class="footnote"><br>[The reference count returned should be considered immediately stale. It is unsuitable for general use in
applications. This feature is provided for identifying memory leaks.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return <em>memobj</em> reference count.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_CONTEXT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_context</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return context specified when memory
object is created. If <em>memobj</em> is created using <strong>clCreateSubBuffer</strong>,
the context associated with the memory object specified as the <em>buffer</em>
argument to <strong>clCreateSubBuffer</strong> is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_ASSOCIATED_ MEMOBJECT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_mem</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return memory object from which
memobj is created. This returns the memory object specified
as buffer argument to
clCreateSubBuffer if memobj is a subbuffer object created using
clCreateSubBuffer.
<br>
<br>
This returns the mem_object specified in
cl_image_desc if memobj is an image
object.
<br>
<br>
Otherwise a NULL value is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_OFFSET</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return offset if memobj is a sub-buffer
object created using clCreateSubBuffer.
<br>
<br>
This return 0 if memobj is not a subbuffer object.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_USES_SVM_ POINTER</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return CL_TRUE if <em>memobj</em> is a buffer object that
was created with CL_MEM_USE_HOST_PTR or is a sub-buffer object of a
buffer object that was created with CL_MEM_USE_HOST_PTR and the
<em>host_ptr</em> specified when the buffer object was created is a SVM
pointer; otherwise returns CL_FALSE.</p></td>
</tr>
</tbody>
</table>
</div>
</div>
<div class="sect2">
<h3 id="_shared_virtual_memory">5.6. Shared Virtual Memory</h3>
<div class="paragraph"><p>OpenCL 2.2 adds support for shared virtual memory (a.k.a. SVM). SVM
allows the host and kernels executing on devices to directly share
complex, pointer-containing data structures such as trees and linked
lists. It also eliminates the need to marshal data between the host and
devices. As a result, SVM substantially simplifies OpenCL programming
and may improve performance.</p></div>
<div class="sect3">
<h4 id="_svm_sharing_granularity_coarse_and_fine_grained_sharing">5.6.1. SVM sharing granularity: coarse- and fine- grained sharing</h4>
<div class="paragraph"><p>OpenCL maintains memory consistency in a coarse-grained fashion in
regions of buffers. We call this coarse-grained sharing. Many platforms
such as those with integrated CPU-GPU processors and ones using the
SVM-related PCI-SIG IOMMU services can do better, and can support
sharing at a granularity smaller than a buffer. We call this
fine-grained sharing. OpenCL 2.0 requires that the host and all OpenCL
2.2 devices support coarse-grained sharing at a minimum.</p></div>
<div class="ulist"><ul>
<li>
<p>
      Coarse-grained sharing:
Coarse-grain sharing may be used for memory and virtual pointer sharing
between multiple devices as well as between the host and one or more
devices. The shared memory region is a memory buffer allocated using
<strong>clSVMAlloc</strong>. Memory consistency is guaranteed at synchronization points
and the host can use calls to <strong>clEnqueueSVMMap</strong> and <strong>clEnqueueSVMUnmap</strong>
or create a cl_mem buffer object using the SVM pointer and use OpenCLs
existing host API functions <strong>clEnqueueMapBuffer</strong> and
<strong>clEnqueueUnmapMemObject</strong> to update regions of the buffer. What
coarse-grain buffer SVM adds to OpenCLs earlier buffer support are the
ability to share virtual memory pointers and a guarantee that concurrent
access to the same memory allocation from multiple kernels on a single
device is valid. The coarse-grain buffer SVM provides a memory
consistency model similar to the global memory consistency model
described in <em>sections 3.3.1</em> and <em>3.4.3</em> of the OpenCL 1.2
specification. This memory consistency applies to the regions of buffers
being shared in a coarse-grained fashion. It is enforced at the
synchronization points between commands enqueued to command queues in a
single context with the additional consideration that multiple kernels
concurrently running on the same device may safely share the data.
</p>
</li>
<li>
<p>
      Fine-grained sharing:
Shared virtual memory where memory consistency is maintained at a
granularity smaller than a buffer. How fine-grained SVM is used depends
on whether the device supports SVM atomic operations.
</p>
</li>
</ul></div>
<div class="paragraph"><p>o   If SVM atomic operations are supported, they provide memory
consistency for loads and stores by the host and kernels executing on
devices supporting SVM. This means that the host and devices can
concurrently read and update the same memory. The consistency provided
by SVM atomics is in addition to the consistency provided at
synchronization points. There is no need for explicit calls to
<strong>clEnqueueSVMMap</strong> and <strong>clEnqueueSVMUnmap</strong> or <strong>clEnqueueMapBuffer</strong> and
<strong>clEnqueueUnmapMemObject</strong> on a cl_mem buffer object created using the
SVM pointer.</p></div>
<div class="paragraph"><p>o   If SVM atomic operations are not supported, the host and devices can
concurrently read the same memory locations and can concurrently update
non-overlapping memory regions, but attempts to update the same memory
locations are undefined. Memory consistency is guaranteed at
synchronization points without the need for explicit calls to to
<strong>clEnqueueSVMMap</strong> and <strong>clEnqueueSVMUnmap</strong> or <strong>clEnqueueMapBuffer</strong> and
<strong>clEnqueueUnmapMemObject</strong> on a cl_mem buffer object created using the
SVM pointer.</p></div>
<div class="paragraph"><p>There are two kinds of fine-grain sharing support. Devices may support
either fine-grain buffer sharing or fine-grain system sharing.</p></div>
<div class="paragraph"><p>o   Fine-grain buffer sharing provides fine-grain SVM only within
buffers and is an extension of coarse-grain sharing. To support
fine-grain buffer sharing in an OpenCL context, all devices in the
context must support CL_DEVICE_SVM_FINE_GRAIN_BUFFER.</p></div>
<div class="paragraph"><p>o   Fine-grain system sharing enables fine-grain sharing of the hosts
entire virtual memory, including memory regions allocated by the system
<strong>malloc</strong> API. OpenCL buffer objects are unnecessary and programmers can
pass pointers allocated using <strong>malloc</strong> to OpenCL kernels.</p></div>
<div class="paragraph"><p>As an illustration of fine-grain SVM using SVM atomic operations to
maintain memory consistency, consider the following example. The host
and a set of devices can simultaneously access and update a shared
work-queue data structure holding work-items to be done. The host can
use atomic operations to insert new work-items into the queue at the
same time as the devices using similar atomic operations to remove
work-items for processing.</p></div>
<div class="paragraph"><p>It is the programmers responsibility to ensure that no host code or
executing kernels attempt to access a shared memory region after that
memory is freed. We require the SVM implementation to work with either
32- or 64- bit host applications subject to the following requirement:
the address space size must be the same for the host and all OpenCL
devices in the context.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>void* clSVMAlloc(cl_context context,
cl_svm_mem_flags flags,
size_t size,
cl_uint alignment)</pre>
</div></div>
<div class="paragraph"><p>allocates a shared virtual memory buffer (referred to as a SVM buffer)
that can be shared by the host and all devices in an OpenCL context that
support shared virtual memory.</p></div>
<div class="paragraph"><p><em>context</em> is a valid OpenCL context used to create the SVM buffer.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify allocation and usage
information. <em>Table 5.14</em> describes the possible values for <em>flags</em>.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 20. <em>List of supported cl_svm_mem_flags_values</em></caption>
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_svm_mem_flags</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_READ_WRITE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the SVM buffer will be read
and written by a kernel. This is the default.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_WRITE_ONLY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the SVM buffer will be written
but not read by a kernel.
<br>
<br>
Reading from a SVM buffer created with
CL_MEM_WRITE_ONLY inside a kernel is undefined.
<br>
<br>
CL_MEM_READ_WRITE and
CL_MEM_WRITE_ONLY are mutually exclusive.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_READ_ONLY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag specifies that the SVM buffer object is a
read-only memory object when used inside a kernel.
<br>
<br>
Writing to a SVM buffer created with
CL_MEM_READ_ONLY inside a kernel is undefined.
<br>
<br>
CL_MEM_READ_WRITE or CL_MEM_WRITE_ONLY
and CL_MEM_READ_ONLY are mutually exclusive.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_SVM_FINE_GRAIN_<br>
BUFFER</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This specifies that the application wants the OpenCL
implementation to do a fine-grained allocation.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MEM_SVM_ATOMICS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag is valid only if
CL_MEM_SVM_FINE_GRAIN_BUFFER is specified in flags. It is used to
indicate that SVM atomic operations can control visibility of memory
accesses in this SVM buffer.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>If CL_MEM_SVM_FINE_GRAIN_BUFFER is not specified, the buffer can be
created as a coarse grained SVM allocation. Similarly, if
CL_MEM_SVM_ATOMICS is not specified, the buffer can be created without
support for SVM atomic operations (refer to an OpenCL kernel
language specifications).</p></div>
<div class="paragraph"><p><em>size</em> is the size in bytes of the SVM buffer to be allocated.</p></div>
<div class="paragraph"><p><em>alignment</em> is the minimum alignment in bytes that is required for the
newly created buffers memory region. It must be a power of two up to
the largest data type supported by the OpenCL device. For the full
profile, the largest data type is long16. For the embedded profile, it
is long16 if the device supports 64-bit integers; otherwise it is
int16. If alignment is 0, a default alignment will be used that is
equal to the size of largest data type supported by the OpenCL
implementation.</p></div>
<div class="paragraph"><p><strong>clSVMAlloc</strong> returns a valid non-NULL shared virtual memory address if
the SVM buffer is successfully allocated. Otherwise, like <strong>malloc</strong>, it
returns a NULL pointer value. <strong>clSVMAlloc</strong> will fail if</p></div>
<div class="ulist"><ul>
<li>
<p>
      <em>context</em> is not a valid context.
</p>
</li>
<li>
<p>
      <em>flags</em> does not contain
CL_MEM_SVM_FINE_GRAIN_BUFFER but does contain CL_MEM_SVM_ATOMICS.
</p>
</li>
<li>
<p>
      Values specified in
<em>flags</em> do not follow rules described for supported values in <em>table
5.14</em>.
</p>
</li>
<li>
<p>
     CL_MEM_SVM_FINE_GRAIN_BUFFER or CL_MEM_SVM_ATOMICS is specified in
<em>flags</em> and these are not supported by at least one device in <em>context</em>.
</p>
</li>
<li>
<p>
      The values specified in
<em>flags</em> are not valid i.e. dont match those defined in <em>table 5.14</em>.
</p>
</li>
<li>
<p>
      <em>size</em> is 0 or &gt;
CL_DEVICE_MAX_MEM_ALLOC_SIZE value for any device in <em>context</em>.
</p>
</li>
<li>
<p>
      <em>alignment</em> is not a power
of two or the OpenCL implementation cannot support the specified
alignment for at least one device in <em>context</em>.
</p>
</li>
<li>
<p>
      There was a failure to
allocate resources.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Calling <strong>clSVMAlloc</strong> does not itself provide consistency for the shared
memory region. When the host cant use the SVM atomic operations, it
must rely on OpenCLs guaranteed memory consistency at synchronization
points.</p></div>
<div class="paragraph"><p>For SVM to be used efficiently, the host and any devices sharing a
buffer containing virtual memory pointers should have the same
endianness. If the context passed to <strong>clSVMAlloc</strong> has devices with
mixed endianness and the OpenCL implementation is unable to implement
SVM because of that mixed endianness, <strong>clSVMAlloc</strong> will fail and return
NULL.</p></div>
<div class="paragraph"><p>Although SVM is generally not supported for image objects,
<strong>clCreateImage</strong> may create an image from a buffer (a 1D image from a
buffer or a 2D image from buffer) if the buffer specified in its image
description parameter is a SVM buffer. Such images have a linear memory
representation so their memory can be shared using SVM. However, fine
grained sharing and atomics are not supported for image reads and writes
in a kernel.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>void clSVMFree(cl_context context,
void * svm_pointer)</pre>
</div></div>
<div class="paragraph"><p>frees a shared virtual memory buffer allocated using <strong>clSVMAlloc</strong>.</p></div>
<div class="paragraph"><p><em>context</em> is a valid OpenCL context used to create the SVM buffer.</p></div>
<div class="paragraph"><p><em>svm_pointer</em> must be the value returned by a call to <strong>clSVMAlloc</strong>. If
a NULL pointer is passed in <em>svm_pointer</em>, no action occurs.</p></div>
<div class="paragraph"><p>Note that <strong>clSVMFree</strong> does not wait for previously enqueued commands
that may be using <em>svm_pointer</em> to finish before freeing
<em>svm_pointer</em>. It is the responsibility of the application to make
sure that enqueued commands that use <em>svm_pointer</em> have finished before
freeing <em>svm_pointer</em>. This can be done by enqueuing a blocking
operation such as <strong>clFinish</strong>, <strong>clWaitForEvents</strong>, <strong>clEnqueueReadBuffer</strong>
or by registering a callback with the events associated with enqueued
commands and when the last enqueued comamnd has finished freeing
<em>svm_pointer</em>.</p></div>
<div class="paragraph"><p>The behavior of using <em>svm_pointer</em> after it has been freed is
undefined. In addition, if a buffer object is created using
<strong>clCreateBuffer</strong> with <em>svm_pointer</em>, the buffer object must first be
released before the <em>svm_pointer</em> is freed.</p></div>
<div class="paragraph"><p>The <strong>clEnqueueSVMFree</strong> API can also be used to enqueue a callback to
free the shared virtual memory buffer allocated using <strong>clSVMAlloc</strong> or a
shared system memory pointer.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueSVMFree(cl_command_queue command_queue,
cl_uint num_svm_pointers,
void *svm_pointers[],
void (CL_CALLBACK *_pfn_free_func_)
(cl_command_queue queue,
cl_uint num_svm_pointers,
void *svm_pointers[],
void *user_data),
void *user_data,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to free the shared virtual memory allocated using
<strong>clSVMAlloc</strong> or a shared system memory pointer.</p></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command-queue.</p></div>
<div class="paragraph"><p><em>svm_pointers</em> and <em>num_svm_pointers</em> specify shared virtual memory
pointers to be freed. Each pointer in <em>svm_pointers</em> that was allocated
using <strong>clSVMAlloc</strong> must have been allocated from the same context from
which <em>command_queue</em> was created. The memory associated with
<em>svm_pointers</em> can be reused or freed after the function returns.</p></div>
<div class="paragraph"><p><em>pfn_free_func</em> specifies the callback function to be called to free the
SVM pointers. <em>pfn_free_func</em> takes four arguments: <em>queue</em> which is
the command queue in which <strong>clEnqueueSVMFree</strong> was enqueued, the count
and list of SVM pointers to free and <em>user_data</em> which is a pointer to
user specified data. If <em>pfn_free_func</em> is NULL, all pointers
specified in <em>svm_pointers</em> must be allocated using <strong>clSVMAlloc</strong> and the
OpenCL implementation will free these SVM pointers. <em>pfn_free_func</em>
must be a valid callback function if any SVM pointer to be freed is a
shared system memory pointer i.e. not allocated using <strong>clSVMAlloc</strong>. If
<em>pfn_free_func</em> is a valid callback function, the OpenCL implementation
will call <em>pfn_free_func</em> to free all the SVM pointers specified in
<em>svm_pointers</em>.</p></div>
<div class="paragraph"><p><em>user_data</em> will be passed as the user_data argument when
<em>pfn_free_func</em> is called. <em>user_data</em> can be NULL.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before <strong>clEnqueueSVMFree</strong> can be executed. If
<em>event_wait_list</em> is NULL, then <strong>clEnqueueSVMFree</strong> does not wait on any
event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. If the <em>event_wait_list</em> and the <em>event</em>
arguments are not NULL, the <em>event</em> argument should not refer to an
element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueSVMFree</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>num_svm_pointers</em> is 0 and <em>svm_pointers_is non-NULL, _or</em> if
<em>svm_pointers</em> is NULL and _num_svm_pointers_is not 0.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following function enqueues a command to do a memcpy operation.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueSVMMemcpy(cl_command_queue command_queue,
cl_bool blocking_copy,
void *dst_ptr,
const void *src_ptr,
size_t size,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p><em>command_queue</em> refers to the host command-queue in which the read /
write command will be queued. If either <em>dst_ptr</em> or <em>src_ptr</em> is
allocated using clSVMAlloc then the OpenCL context allocated against
must match that of <em>command_queue</em>.</p></div>
<div class="paragraph"><p><em>blocking_copy</em> indicates if the copy operation is <em>blocking</em> or
<em>non-blocking</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_copy</em> is CL_TRUE i.e. the copy command is blocking,
<strong>clEnqueueSVMMemcpy</strong> does not return until the buffer data has been
copied into memory pointed to by <em>dst_ptr</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_copy</em> is CL_FALSE i.e. the copy command is non-blocking,
<strong>clEnqueueSVMMemcpy</strong> queues a non-blocking copy command and returns.
The contents of the buffer that <em>dst_ptr</em> point to cannot be used until
the copy command has completed. The <em>event</em> argument returns an event
object which can be used to query the execution status of the read
command. When the copy command has completed, the contents of the
buffer that _dst_ptr_points to__can be used by the application.</p></div>
<div class="paragraph"><p><em>size</em> is the size in bytes of data being copied.</p></div>
<div class="paragraph"><p><em>dst_ptr</em> is the pointer to a host or SVM memory allocation where data
is copied to.</p></div>
<div class="paragraph"><p><em>src_ptr</em> is the pointer to a host or SVM memory allocation where data
is copied from.</p></div>
<div class="paragraph"><p>If the memory allocation(s) containing <em>dst_ptr</em> and/or <em>src_ptr</em> are
allocated using <strong>clSVMAlloc</strong> and either is not allocated from the same
context from which <em>command_queue</em> was created the behavior is
undefined.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular read /
write command and can be used to query or queue a wait for this
particular command to complete. <em>event</em> can be NULL in which case it
will not be possible for the application to query the status of this
command or queue a wait for this command to complete. If the
<em>event_wait_list</em> and the <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueSVMMemcpy</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
  CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the copy operation is
blocking and the execution status of any of the events in
<em>event_wait_list</em> is a negative integer value.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>dst_ptr</em> or <em>src_ptr</em> are NULL.
</p>
</li>
<li>
<p>
      CL_MEM_COPY_OVERLAP if the
values specified for <em>dst_ptr</em>, <em>src_ptr</em> and <em>size</em> result in an
overlapping copy.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueSVMMemFill(cl_command_queue command_queue,
void *svm_ptr,
const void *pattern,
size_t pattern_size,
size_t size,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to fill a region in memory with a pattern of a given
pattern size.</p></div>
<div class="paragraph"><p><em>command_queue</em> refers to the host command-queue in which the fill
command will be queued. The OpenCL context associated with
<em>command_queue</em> and SVM pointer referred to by <em>svm_ptr</em> must be the
same.</p></div>
<div class="paragraph"><p><em>svm_ptr</em> is a pointer to a memory region that will be filled with
<em>pattern</em>. It must be aligned to <em>pattern_size</em> bytes. If <em>svm_ptr</em> is
allocated using <strong>clSVMAlloc</strong> then it must be allocated from the same
context from which <em>command_queue</em> was created. Otherwise the behavior
is undefined.</p></div>
<div class="paragraph"><p><em>pattern</em> is a pointer to the data pattern of size <em>pattern_size</em> in
bytes. <em>pattern</em> will be used to fill a region in <em>buffer</em> starting at
<em>svm_ptr</em> and is <em>size</em> bytes in size. The data pattern must be a
scalar or vector integer or floating-point data type supported by OpenCL
as described in <em>sections 6.1.1</em> and <em>6.1.2</em>. For example, if region
pointed to by <em>svm_ptr</em> is to be filled with a pattern of float4 values,
then <em>pattern</em> will be a pointer to a cl_float4 value and <em>pattern_size</em>
will be sizeof(cl_float4). The maximum value of <em>pattern_size</em> is the
size of the largest integer or floating-point vector data type supported
by the OpenCL device. The memory associated with <em>pattern</em> can be
reused or freed after the function returns.</p></div>
<div class="paragraph"><p><em>size</em> is the size in bytes of region being filled starting with
<em>svm_ptr</em> and must be a multiple of <em>pattern_size</em>.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. <strong>clEnqueueBarrierWithWaitList</strong> can be used
instead. If the <em>event_wait_list</em> and the <em>event</em> arguments are not
NULL, the <em>event</em> argument should not refer to an element of the
<em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueSVMMemFill</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if the
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>svm_ptr</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>svm_ptr</em> is not aligned to <em>pattern_size</em> bytes.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pattern</em> is NULL or if <em>pattern_size</em> is 0 or if <em>pattern_size</em> is not
one of {1, 2, 4, 8, 16, 32, 64, 128}.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if <em>size</em>
is not a multiple of <em>pattern_size</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueSVMMap(cl_command_queue command_queue,
cl_bool blocking_map,
cl_map_flags map_flags,
void *svm_ptr,
size_t size,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command that will allow the host to update a region of a SVM
buffer. Note that since we are enqueuing a command with a SVM buffer,
the region is already mapped in the host address space.</p></div>
<div class="paragraph"><p><em>command_queue</em> must be a valid host command-queue.</p></div>
<div class="paragraph"><p><em>blocking_map</em> indicates if the map operation is <em>blocking</em> or
<em>non-blocking</em>.</p></div>
<div class="paragraph"><p>If <em>blocking_map</em> is CL_TRUE, <strong>clEnqueueSVMMap</strong> does not return until
the application can access the contents of the SVM region specified by
<em>svm_ptr</em> and <em>size</em> on the host.</p></div>
<div class="paragraph"><p>If <em>blocking_map</em> is CL_FALSE i.e. map operation is non-blocking, the
region specified by <em>svm_ptr</em> and <em>size</em> cannot be used until the map
command has completed. The <em>event</em> argument returns an event object
which can be used to query the execution status of the map command.
When the map command is completed, the application can access the
contents of the region specified by <em>svm_ptr</em> and <em>size</em>.</p></div>
<div class="paragraph"><p><em>map_flags</em> is a bit-field and is described in <em>table 5.5</em>.</p></div>
<div class="paragraph"><p><em>svm_ptr</em> and <em>size</em> are a pointer to a memory region and size in bytes
that will be updated by the host. If <em>svm_ptr</em> is allocated using
<strong>clSVMAlloc</strong> then it must be allocated from the same context from which
<em>command_queue</em> was created. Otherwise the behavior is undefined.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. <strong>clEnqueueBarrierWithWaitList</strong> can be used
instead. If the <em>event_wait_list</em> and the <em>event</em> arguments are not
NULL, the <em>event</em> argument should not refer to an element of the
<em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueSVMMap</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if _command_queue_is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>svm_ptr</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if <em>size</em>
is 0 or if values specified in _map_flags_are not valid.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
  CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the map operation is
blocking and the execution status of any of the events in
<em>event_wait_list</em> is a negative integer value.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueSVMUnmap(cl_command_queue command_queue,
void *svm_ptr,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to indicate that the host has completed updating the
region given by <em>svm_ptr</em> and which was specified in a previous call to
<strong>clEnqueueSVMMap</strong>.</p></div>
<div class="paragraph"><p><em>command_queue</em> must be a valid host command-queue.</p></div>
<div class="paragraph"><p><em>svm_ptr</em> is a pointer that was specified in a previous call to
<strong>clEnqueueSVMMap</strong>. If <em>svm_ptr</em> is allocated using <strong>clSVMAlloc</strong> then it
must be allocated from the same context from which <em>command_queue</em> was
created. Otherwise the behavior is undefined.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before <strong>clEnqueueSVMUnmap</strong> can be executed. If
<em>event_wait_list</em> is NULL, then <strong>clEnqueueUnmap</strong> does not wait on any
event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue a wait for
this command to complete. <strong>clEnqueueBarrierWithWaitList</strong> can be used
instead. If the <em>event_wait_list</em> and the <em>event</em> arguments are not
NULL, the <em>event</em> argument should not refer to an element of the
<em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueSVMUnmap</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>svm_ptr</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or if
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>clEnqueueSVMMap</strong> and <strong>clEnqueueSVMUnmap</strong> act as synchronization points
for the region of the SVM buffer specified in these calls.</p></div>
<div class="paragraph"><p>NOTE:</p></div>
<div class="paragraph"><p>If a coarse-grained SVM buffer is currently mapped for writing, the
application must ensure that the SVM buffer is unmapped before any
enqueued kernels or commands that read from or write to this SVM buffer
or any of its associated cl_mem buffer objects begin execution;
otherwise the behavior is undefined.</p></div>
<div class="paragraph"><p>If a coarse-grained SVM buffer is currently mapped for reading, the
application must ensure that the SVM buffer is unmapped before any
enqueued kernels or commands that write to this memory object or any of
its associated cl_mem buffer objects begin execution; otherwise the
behavior is undefined.</p></div>
<div class="paragraph"><p>A SVM buffer is considered as mapped if there are one or more active
mappings for the SVM buffer irrespective of whether the mapped regions
span the entire SVM buffer.</p></div>
<div class="paragraph"><p>The above note does not apply to fine-grained SVM buffers (fine-grained
buffers allocated using <strong>clSVMAlloc</strong> or fine-grained system
allocations).</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueSVMMigrateMem(cl_command_queue command_queue,
cl_uint num_svm_pointers,
const void **svm_pointers,
const size_t *sizes,
cl_mem_migration_flags flags,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to indicate which device a set of ranges of SVM
allocations should be associated with. Once the event returned by
<strong>clEnqueueSVMMigrateMem</strong> has become CL_COMPLETE, the ranges specified by
svm pointers and sizes have been successfully migrated to the device
associated with command queue.</p></div>
<div class="paragraph"><p>The user is responsible for managing the event dependencies associated
with this command in order to avoid overlapping access to SVM
allocations. Improperly specified event dependencies passed to
<strong>clEnqueueSVMMigrateMem</strong> could result in undefined results.</p></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command queue. The specified set of
allocation ranges will be migrated to the OpenCL device associated with
<em>command_queue</em>.</p></div>
<div class="paragraph"><p><em>num_svm_pointers</em> is the number of pointers in the specified
<em>svm_pointers</em> array, and the number of sizes in the <em>sizes</em> array, if
_sizes_is not NULL.</p></div>
<div class="paragraph"><p><em>svm_pointers</em> is a pointer to an array of pointers. Each pointer in
this array must be within an allocation produced by a call to
<strong>clSVMAlloc</strong>.</p></div>
<div class="paragraph"><p><em>sizes</em> is an array of sizes. The pair <em>svm_pointers</em>[i] and <em>sizes</em>[i]
together define the starting address and number of bytes in a range to
be migrated. <em>sizes</em> may be NULL indicating that every allocation
containing any <em>svm_pointer</em>[i] is to be migrated. Also, if <em>sizes</em>[i]
is zero, then the entire allocation containing <em>svm_pointer</em>[i] is
migrated.</p></div>
<div class="paragraph"><p><em>flags</em> is a bit-field that is used to specify migration options. <em>Table
5.12</em> describes the possible values for <em>flags</em>.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular command
and can be used to query or queue a wait for this particular command to
complete. <em>event</em> can be NULL in which case it will not be possible for
the application to query the status of this command or queue another
command that waits for this command to complete. If the
<em>event_wait_list</em> and <em>event</em> arguments are not NULL, the <em>event</em>
argument should not refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueSVMMigrateMem</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
_num_svm_pointers is zero_or_svm_pointers_is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>sizes</em><em><span class="i">is non-zero</span></em>range [<em>svm_pointers</em>[i],
<em>svm_pointers</em>[i]+<em>sizes</em>[i]) is not contained within an existing
<strong>clSVMAlloc</strong> allocation.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or if
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_memory_consistency_for_svm_allocations">5.6.2. Memory consistency for SVM allocations</h4>
<div class="paragraph"><p>To ensure memory consistency in SVM allocations, the program can rely on
the guaranteed memory consistency at synchronization points. This
consistency support already exists in OpenCL 1.x and can be used for
coarse-grained SVM allocations or for fine-grained buffer SVM
allocations; what SVM adds is the ability to share pointers between the
host and all SVM devices.</p></div>
<div class="paragraph"><p>In addition, sub-buffers can also be used to ensure that each device
gets a consistent view of a SVM buffers memory when it is shared by
multiple devices. For example, assume that two devices share a SVM
pointer. The host can create a cl_mem buffer object using
<strong>clCreateBuffer</strong> with CL_MEM_USE_HOST_PTR and <em>host_ptr</em> set to the SVM
pointer and then create two disjoint sub-buffers with starting virtual
addresses <em>sb1_ptr</em> and <em>sb2_ptr</em>. These pointers (<em>sb1_ptr</em> and
<em>sb2_ptr</em>) can be passed to kernels executing on the two devices.
<strong>clEnqueueMapBuffer</strong> and <strong>clEnqueueUnmapMemObject</strong> and the existing
access rules for memory objects (in <em>section 5.5.3</em>) can be used to
ensure consistency for buffer regions (<em>sb1_ptr</em> and <em>sb2_ptr</em>) read and
written by these kernels.</p></div>
<div class="paragraph"><p>When the host and devices are able to use SVM atomic operations (i.e.
CL_DEVICE_SVM_ATOMICS is set in CL_DEVICE_SVM_CAPABILITIES), these
atomic operations can be used to provide memory consistency at a fine
grain in a shared memory region. The effect of these operations is
visible to the host and all devices with which that memory is shared.</p></div>
</div>
</div>
<div class="sect2">
<h3 id="_sampler_objects">5.7. Sampler Objects</h3>
<div class="paragraph"><p>A sampler object describes how to sample an image when the image is read
in the kernel. The built-in functions to read from an image in a kernel
take a sampler as an argument. The sampler arguments to the image read
function can be sampler objects created using OpenCL functions and
passed as argument values to the kernel or can be samplers declared
inside a kernel. In this section we discuss how sampler objects are
created using OpenCL functions.</p></div>
<div class="sect3">
<h4 id="_creating_sampler_objects">5.7.1. Creating Sampler Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_sampler clCreateSamplerWithProperties(cl_context context,
const cl_sampler_properties *sampler_properties,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates a sampler object.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>sampler_properties</em> specifies a list of sampler property names and
their corresponding values. Each sampler property name is immediately
followed by the corresponding desired value. The list is terminated
with 0. The list of supported properties is described in <em>table 5.15</em>.
If a supported property and its value is not specified in
<em>sampler_properties</em>, its default value will be used.
<em>sampler_properties</em> can be NULL in which case the default values for
supported sampler properties will be used.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 21. <em>List of supported cl_sampler_properties values and description</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_sampler_properties <br>
enum</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Property Value</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SAMPLER_NORMALIZED_ COORDS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A boolean value that specifies
whether the image coordinates
specified are normalized or not.
<br>
<br>
The default value (i.e. the value used
if this property is not specified in
sampler_properties) is CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SAMPLER_ADDRESSING_ MODE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_addressing_ + mode</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Specifies how out-of-range image
coordinates are handled when reading
from an image.
<br>
<br>
Valid values are:
<br>
<br>
CL_ADDRESS_MIRRORED_REPEAT
CL_ADDRESS_REPEAT
CL_ADDRESS_CLAMP_
CL_ADDRESS_CLAMP
CL_ADDRESS_NONE
<br>
<br>
The default is
CL_ADDRESS_CLAMP.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SAMPLER_FILTER_MODE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_filter_mode</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Specifies the type of filter that must
be applied when reading an image.
Valid values are:
<br>
<br>
CL_FILTER_NEAREST
CL_FILTER_LINEAR
<br>
<br>
The default value is
CL_FILTER_NEAREST.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateSamplerWithProperties</strong> returns a valid non-zero sampler object
and <em>errcode_ret</em> is set to CL_SUCCESS if the sampler object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
property name in <em>sampler_properties</em> is not a supported property name,
if the value specified for a supported property name is not valid, or if
the same property name is specified more than once.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
images are not supported by any device associated with <em>context</em> (i.e.
CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_FALSE).
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainSampler(cl_sampler sampler)</pre>
</div></div>
<div class="paragraph"><p>increments the <em>sampler</em> reference count.
<strong>clCreateSamplerWithProperties</strong> performs an implicit retain.
<strong>clRetainSampler</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_SAMPLER if
<em>sampler</em> is not a valid sampler object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseSampler(cl_sampler sampler)</pre>
</div></div>
<div class="paragraph"><p>decrements the <em>sampler</em> reference count. The sampler object is deleted
after the reference count becomes zero and commands queued for execution
on a command-queue(s) that use <em>sampler</em> have finished.
<strong>clReleaseSampler</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_SAMPLER if
<em>sampler</em> is not a valid sampler object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Using this function to release a reference that was not obtained by
creating the object or by calling <strong>clRetainSampler</strong> causes undefined
behavior.</p></div>
</div>
<div class="sect3">
<h4 id="_sampler_object_queries">5.7.2. Sampler Object Queries</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetSamplerInfo(cl_sampler sampler,
cl_sampler_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns information about the sampler object.</p></div>
<div class="paragraph"><p><em>sampler</em> specifies the sampler being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetSamplerInfo</strong> is described in <em>table 5.16</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.16.</em></p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.
 </p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 22. <em>clGetSamplerInfo</em> <em>parameter queries</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_sampler_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_SAMPLER_REFERENCE_ COUNT*<span class="footnote"><br>[The reference count returned should be considered immediately stale. It is unsuitable for general use in
applications. This feature is provided for identifying memory leaks.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the <em>sampler</em> reference
count.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SAMPLER_CONTEXT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_context</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the context specified when the
sampler is created.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SAMPLER_NORMALIZED_ COORDS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the normalized coords value
associated with <em>sampler</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SAMPLER_ADDRESSING_ MODE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_addressing_mode</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the
addressing mode value associated with <em>sampler</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SAMPLER_FILTER_MODE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_filter_mode</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the filter mode value
associated with <em>sampler</em>.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetSamplerInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table
5.16_and _param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_SAMPLER if
<em>sampler</em> is a not a valid sampler object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
</div>
<div class="sect2">
<h3 id="_program_objects">5.8. Program Objects</h3>
<div class="paragraph"><p>An OpenCL program consists of a set of kernels that are identified as
functions declared with the <em>kernel qualifier in the program source.
OpenCL programs may also contain auxiliary functions and constant data
that can be used by </em>kernel functions. The program executable can be
generated <em>online</em> or <em>offline</em> by the OpenCL compiler for the
appropriate target device(s).</p></div>
<div class="paragraph"><p>A program object encapsulates the following information:</p></div>
<div class="ulist"><ul>
<li>
<p>
      An associated context.
</p>
</li>
<li>
<p>
      A program source or binary.
</p>
</li>
<li>
<p>
      The latest successfully
built program executable, library or compiled binary, the list of
devices for which the program executable, library or compiled binary is
built, the build options used and a build log.
</p>
</li>
<li>
<p>
      The number of kernel objects currently attached.
</p>
</li>
</ul></div>
<div class="sect3">
<h4 id="_creating_program_objects">5.8.1. Creating Program Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_program clCreateProgramWithSource(cl_context context,
cl_uint count,
const char **strings,
const size_t *lengths,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates a program object for a context, and loads the source code
specified by the text strings in the <em>strings</em> array into the program
object. The devices associated with the program object are the devices
associated with <em>context</em>. The source code specified by <em>strings</em> is
either an OpenCL C program source, header or implementation-defined
source for custom devices that support an online compiler. OpenCL C++ is
not supported as an online-compiled kernel language through this
interface.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>strings</em> is an array of <em>count</em> pointers to optionally null-terminated
character strings that make up the source code.</p></div>
<div class="paragraph"><p>The <em>lengths</em> argument is an array with the number of chars in each
string (the string length). If an element in <em>lengths</em> is zero, its
accompanying string is null-terminated. If <em>lengths</em> is NULL, all
strings in the <em>strings</em> argument are considered null-terminated. Any
length value passed in that is greater than zero excludes the null
terminator in its count.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateProgramWithSource</strong> returns a valid non-zero program object and
<em>errcode_ret</em> is set to CL_SUCCESS if the program object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>count</em> is zero or if <em>strings</em> or any entry in <em>strings</em> is NULL.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_program clCreateProgramWithIL(cl_context context,
const void *il,
size_t length,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates a program object for a context, and loads the IL pointed to by
_il_and with length in bytes _length_into the program object.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>il_is a pointer to a _length</em>-byte block of memory containing SPIR-V or
an implementation-defined intermediate language.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateProgramWithIL</strong> returns a valid non-zero program object and
<em>errcode_ret</em> is set to CL_SUCCESS if the program object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if <em>il</em>
is NULL or if _length_is zero.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
<em>length</em>-byte memory pointed to by <em>il</em> does not contain well-formed
intermediate language input that can be consumed by the OpenCL runtime.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_program clCreateProgramWithBinary(cl_context context,
cl_uint num_devices,
const cl_device_id *device_list,
const size_t *lengths,
const unsigned char **binaries,
cl_int *binary_status,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates a program object for a context, and loads the binary bits
specified by <em>binary</em> into the program object.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>device_list</em> is a pointer to a list of devices that are in <em>context</em>.
<em>device_list</em> must be a non-NULL value. The binaries are loaded for
devices specified in this list.</p></div>
<div class="paragraph"><p><em>num_devices_is the number of devices listed in _device_list</em>.</p></div>
<div class="paragraph"><p>The devices associated with the program object will be the list of
devices specified by <em>device_list</em>. The list of devices specified by
<em>device_list</em> must be devices associated with <em>context</em>.</p></div>
<div class="paragraph"><p><em>lengths</em> is an array of the size in bytes of the program binaries to be
loaded for devices specified by <em>device_list</em>.</p></div>
<div class="paragraph"><p><em>binaries</em> is an array of pointers to program binaries to be loaded for
devices specified by <em>device_list</em>. For each device given by
<em>device_list</em>[i], the pointer to the program binary for that device is
given by <em>binaries</em>[i] and the length of this corresponding binary is
given by <em>lengths</em>[i]. <em>lengths</em>[i] cannot be zero and <em>binaries</em>[i]
cannot be a NULL pointer.</p></div>
<div class="paragraph"><p>The program binaries specified by <em>binaries</em> contain the bits that
describe one of the following:</p></div>
<div class="ulist"><ul>
<li>
<p>
      a program executable to be
run on the device(s) associated with <em>context</em>,
</p>
</li>
<li>
<p>
      a compiled program for
device(s) associated with <em>context</em>, or
</p>
</li>
<li>
<p>
      a library of compiled
programs for device(s) associated with <em>context</em>.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The program binary can consist of either or both:</p></div>
<div class="ulist"><ul>
<li>
<p>
      Device-specific code and/or,
</p>
</li>
<li>
<p>
      Implementation-specific
intermediate representation (IR) which will be converted to the
device-specific code.
</p>
</li>
</ul></div>
<div class="paragraph"><p><em>binary_status</em> returns whether the program binary for each device
specified in <em>device_list</em> was loaded successfully or not. It is an
array of <em>num_devices</em> entries and returns CL_SUCCESS in
<em>binary_status[i]</em> if binary was successfully loaded for device
specified by <em>device_list[i]</em>; otherwise returns CL_INVALID_VALUE if
<em>lengths[i]</em> is zero or if <em>binaries[i]</em> is a NULL value or
CL_INVALID_BINARY in <em>binary_status[i]</em> if program binary is not a valid
binary for the specified device. If <em>binary_status</em> is NULL, it is
ignored.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateProgramWithBinary</strong> returns a valid non-zero program object and
<em>errcode_ret</em> is set to CL_SUCCESS if the program object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>device_list</em> is NULL or <em>num_devices</em> is zero.
</p>
</li>
<li>
<p>
      CL_INVALID_DEVICE if
OpenCL devices listed in <em>device_list</em> are not in the list of devices
associated with <em>context</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>lengths</em> or <em>binaries</em> are NULL or if any entry in <em>lengths</em>[i] is zero
or <em>binaries</em>[i] is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_BINARY if an
invalid program binary was encountered for any device. <em>binary_status</em>
will return specific status for each device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>OpenCL allows applications to create a program object using the program
source or binary and build appropriate program executables. This can be
very useful as it allows applications to load program source and then
compile and link to generate a program executable online on its first
instance for appropriate OpenCL devices in the system. These
executables can now be queried and cached by the application.
The cached executables can be read
and loaded by the application, which can help significantly reduce the
application initialization time.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_program clCreateProgramWithBuiltInKernels(cl_context context,
cl_uint num_devices,
const cl_device_id *device_list,
const char *kernel_names,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates a program object for a context, and loads the information
related to the built-in kernels into a program object.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>num_devices_is the number of devices listed in _device_list</em>.</p></div>
<div class="paragraph"><p><em>device_list</em> is a pointer to a list of devices that are in <em>context</em>.
<em>device_list</em> must be a non-NULL value. The built-in kernels are
loaded for devices specified in this list.</p></div>
<div class="paragraph"><p>The devices associated with the program object will be the list of
devices specified by <em>device_list</em>. The list of devices specified by
<em>device_list</em> must be devices associated with <em>context</em>.</p></div>
<div class="paragraph"><p><em>kernel_names</em> is a semi-colon separated list of built-in kernel names.</p></div>
<div class="paragraph"><p><strong>clCreateProgramWithBuiltInKernels</strong> returns a valid non-zero program
object and <em>errcode_ret</em> is set to CL_SUCCESS if the program object is
created successfully. Otherwise, it returns a NULL value with one of
the following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>device_list</em> is NULL or <em>num_devices</em> is zero.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>kernel_names</em> is NULL or <em>kernel_names</em> contains a kernel name that is
not supported by any of the devices in <em>device_list</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_DEVICE if
devices listed in <em>device_list</em> are not in the list of devices
associated with <em>context</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_retaining_and_releasing_program_objects">5.8.2. Retaining and Releasing Program Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainProgram(cl_program program)</pre>
</div></div>
<div class="paragraph"><p>increments the <em>program</em> reference count. All <strong>clCreateProgram</strong> APIs
do an implicit retain. <strong>clRetainProgram</strong> returns CL_SUCCESS if the
function is executed successfully. Otherwise, it returns one of the
following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is not a valid program object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseProgram(cl_program program)</pre>
</div></div>
<div class="paragraph"><p>decrements the <em>program</em> reference count. The program object is deleted
after all kernel objects associated with <em>program</em> have been deleted and
the <em>program</em> reference count becomes zero. <strong>clReleaseProgram</strong> returns
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is not a valid program object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Using this function to release a reference that was not obtained by
creating the object or by calling <strong>clRetainProgram</strong> causes undefined
behavior.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetProgramReleaseCallback(cl_program program,
void (CL_CALLBACK *pfn_notify)
(cl_program prog,
void *user_data),
void *user_data)</pre>
</div></div>
<div class="paragraph"><p>registers a user callback function with a program object. Each call to
<strong>clSetProgramReleaseCallback</strong> registers the specified user callback
function on a callback stack associated with program. The registered
user callback functions are called in the reverse order in which they
were registered. The user callback functions are called after
destructors (if any) for program scope global variables (if any) are
called and before the program is released. This provides a mechanism for
the application (and libraries) to be notified when destructors are
complete.</p></div>
<div class="paragraph"><p><em>program</em> is a valid program object</p></div>
<div class="paragraph"><p><em>pfn_notify</em> is the callback function that can be registered by the
application. This callback function may be called asynchronously by the
OpenCL implementation. It is the applications responsibility to ensure
that the callback function is thread safe. The parameters to this
callback function are:</p></div>
<div class="paragraph"><p><em>prog</em> is the program object whose destructors are being called. When
the user callback is called by the implementation, this program object
is not longer valid. prog is only provided for reference purposes.</p></div>
<div class="paragraph"><p><em>user_data</em> is a pointer to user supplied data. <em>user_data</em> will be
passed as the <em>user_data</em> argument when <em>pfn_notify</em> is called. user
data can be NULL.</p></div>
<div class="paragraph"><p><strong>clSetProgramReleaseCallback</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is not a valid program object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pfn_notify</em> is NULL.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_setting_spir_v_specialization_constants">5.8.3. Setting SPIR-V specialization constants</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetProgramSpecializationConstant(cl_program program,
cl_uint spec_id,
size_t spec_size,
const void *spec_value)</pre>
</div></div>
<div class="paragraph"><p>sets the values of a SPIR-V specialization constants.</p></div>
<div class="paragraph"><p><em>program</em> must be a valid OpenCL program created from a SPIR-V module.</p></div>
<div class="paragraph"><p><em>spec</em> id_ identifies the SPIR-V specialization constant whose value
will be set.</p></div>
<div class="paragraph"><p><em>spec_size</em> specifies the size in bytes of the data pointed to by
<em>spec_value</em>. This should be 1 for boolean constants. For all other
constant types this should match the size of the specialization constant
in the SPIR-V module.</p></div>
<div class="paragraph"><p><em>spec_value</em> is a pointer to the memory location that contains the value
of the specialization constant. The data pointed to by <em>spec_value</em> are
copied and can be safely reused by the application after
<strong>clSetProgramSpecializationConstant</strong> returns. This specialization value
will be used by subsequent calls to <strong>clBuildProgram</strong> until another call
to <strong>clSetProgramSpecializationConstant</strong> changes it. If a specialization
constant is a boolean constant, _spec value_should be a pointer to a
cl_uchar value. A value of zero will set the specialization constant to
false; any other value will set it to true.</p></div>
<div class="paragraph"><p>Calling this function multiple times for the same specialization
constant shall cause the last provided value to override any previously
specified value. The values are used by a subsequent <strong>clBuildProgram</strong>
call for the <em>program</em>.</p></div>
<div class="paragraph"><p>Application is not required to provide values for every specialization
constant contained in SPIR-V module. SPIR-V provides default values for
all specialization constants.</p></div>
<div class="paragraph"><p><strong>clSetProgramSpecializationConstant</strong> returns CL_SUCCESS if the function
is executed successfully.</p></div>
<div class="paragraph"><p>Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is not a valid program object created from a SPIR-V module.
</p>
</li>
<li>
<p>
      CL_INVALID_SPEC_ID if
<em>spec_id</em> is not a valid specialization constant ID
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>spec_size</em> does not match the size of the specialization constant in
the SPIR-V module, or if <em>spec_value</em> is NULL.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_building_program_executables">5.8.4. Building Program Executables</h4>
<div class="paragraph"><p> 
The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clBuildProgram(cl_program program,
cl_uint num_devices,
const cl_device_id *device_list,
const char *options,
void (CL_CALLBACK *pfn_notify)
(cl_program program,
void *user_data),
void *user_data)</pre>
</div></div>
<div class="paragraph"><p>builds (compiles &amp; links) a program executable from the program source
or binary for all the devices or a specific device(s) in the OpenCL
context associated with <em>program</em>. OpenCL allows program executables to
be built using the source or the binary. <strong>clBuildProgram</strong> must be
called for <em>program</em> created using <strong>clCreateProgramWithSource</strong>,
<strong>clCreateProgramWithIL</strong> or <strong>clCreateProgramWithBinary</strong> to build the
program executable for one or more devices associated with <em>program</em>.
If <em>program</em> is created with <strong>clCreateProgramWithBinary</strong>, then the
program binary must be an executable binary (not a compiled binary or
library).</p></div>
<div class="paragraph"><p>The executable binary can be queried using <strong>clGetProgramInfo</strong>(<em>program</em>,
CL_PROGRAM_BINARIES, ) and can be specified to
<strong>clCreateProgramWithBinary</strong> to create a new program object.</p></div>
<div class="paragraph"><p><em>program</em> is the program object.</p></div>
<div class="paragraph"><p><em>device_list</em> is a pointer to a list of devices associated with
<em>program</em>. If <em>device_list</em> is a NULL value, the program executable is
built for all devices associated with <em>program</em> for which a source or
binary has been loaded. If <em>device_list</em> is a non-NULL value, the
program executable is built for devices specified in this list for which
a source or binary has been loaded.</p></div>
<div class="paragraph"><p><em>num_devices_is the number of devices listed in _device_list</em>.</p></div>
<div class="paragraph"><p><em>options</em> is a pointer to a null-terminated string of characters that
describes the build options to be used for building the program
executable. The list of supported options is described <em>in section 5.8.6</em>.
If the program was created using clCreateProgramWithBinary and <em>options</em> is
a NULL pointer,
the program will be built as if options were the same as when the program binary
was originally built.
If the program was created using clCreateProgramWithBinary and <em>options</em> string contains
anything other than the same options in the same order (whitespace ignored) as when
the program binary was originally built, then the behavior is implementation defined.</p></div>
<div class="paragraph"><p><em>pfn_notify</em> is a function pointer to a notification routine. The
notification routine is a callback function that an application can
register and which will be called when the program executable has been
built (successfully or unsuccessfully). If <em>pfn_notify</em> is not NULL,
<strong>clBuildProgram</strong> does not need to wait for the build to complete and can
return immediately once the build operation can begin. The build
operation can begin if the context, program whose sources are being
compiled and linked, list of devices and build options specified are all
valid and appropriate host and device resources needed to perform the
build are available. If <em>pfn_notify</em> is NULL, <strong>clBuildProgram</strong> does not
return until the build has completed. This callback function may be
called asynchronously by the OpenCL implementation. It is the
applications responsibility to ensure that the callback function is
thread-safe.</p></div>
<div class="paragraph"><p><em>user_data</em> will be passed as an argument when <em>pfn_notify</em> is called.
<em>user_data</em> can be NULL.</p></div>
<div class="paragraph"><p><strong>clBuildProgram</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is not a valid program object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>device_list</em> is NULL and <em>num_devices</em> is greater than zero, or if
<em>device_list</em> is not NULL and <em>num_devices</em> is zero.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pfn_notify</em> is NULL but <em>user_data</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_DEVICE if
OpenCL devices listed in <em>device_list</em> are not in the list of devices
associated with <em>program</em>
</p>
</li>
<li>
<p>
      CL_INVALID_BINARY if
<em>program</em> is created with <strong>clCreateProgramWithBinary</strong> and devices listed
in <em>device_list</em> do not have a valid program binary loaded.
</p>
</li>
<li>
<p>
      CL_INVALID_BUILD_OPTIONS
if the build options specified by <em>options</em> are invalid.
</p>
</li>
<li>
<p>
      CL_COMPILER_NOT_AVAILABLE
if <em>program</em> is created with <strong>clCreateProgramWithSource</strong> and a compiler
is not available i.e. CL_DEVICE_COMPILER_AVAILABLE specified in <em>table
4.3</em> is set to CL_FALSE.
</p>
</li>
<li>
<p>
      CL_BUILD_PROGRAM_FAILURE
if there is a failure to build the program executable. This error will
be returned if <strong>clBuildProgram</strong> does not return until the build has
completed.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the build of a program executable for any of the devices listed in
<em>device_list</em> by a previous call to <strong>clBuildProgram</strong> for <em>program</em> has
not completed.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
there are kernel objects attached to <em>program</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
<em>program</em> was not created with <strong>clCreateProgramWithSource,
clCreateProgramWithIL</strong> or <strong>clCreateProgramWithBinary</strong>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_separate_compilation_and_linking_of_programs">5.8.5. Separate Compilation and Linking of Programs</h4>
<div class="paragraph"><p>OpenCL programs are compiled and linked to support the following:</p></div>
<div class="ulist"><ul>
<li>
<p>
      Separate compilation and
link stages. Program sources can be compiled to generate a compiled
binary object and linked in a separate stage with other compiled program
objects to the program exectuable.
</p>
</li>
<li>
<p>
      Embedded headers. In
OpenCL 1.0 and 1.1, the I build option could be used to specify the
list of directories to be searched for headers files that are included
by a program source(s). OpenCL 1.2 extends this by allowing the header
sources to come from program objects instead of just header files.
</p>
</li>
<li>
<p>
      Libraries. The linker can
be used to link compiled objects and libraries into a program executable
or to create a library of compiled binaries.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clCompileProgram(cl_program program,
cl_uint num_devices,
const cl_device_id *device_list,
const char *options,
cl_uint num_input_headers,
const cl_program *input_headers,
const char **header_include_names,
void (CL_CALLBACK *pfn_notify)
(cl_program program,
void *user_data),
void *user_data)</pre>
</div></div>
<div class="paragraph"><p>compiles a programs source for all the devices or a specific device(s)
in the OpenCL context associated with <em>program</em>. The pre-processor runs
before the program sources are compiled. The compiled binary is built
for all devices associated with <em>program</em> or the list of devices
specified. The compiled binary can be queried using
<strong>clGetProgramInfo</strong>(<em>program</em>, CL_PROGRAM_BINARIES, ) and can be passed
to <strong>clCreateProgramWithBinary</strong> to create a new program object.</p></div>
<div class="paragraph"><p><em>program</em> is the program object that is the compilation target.</p></div>
<div class="paragraph"><p><em>device_list</em> is a pointer to a list of devices associated with
<em>program</em>. If <em>device_list</em> is a NULL value, the compile is performed
for all devices associated with <em>program</em>. If <em>device_list</em> is a
non-NULL value, the compile is performed for devices specified in this
list.</p></div>
<div class="paragraph"><p><em>num_devices_is the number of devices listed in _device_list</em>.</p></div>
<div class="paragraph"><p><em>options</em> is a pointer to a null-terminated string of characters that
describes the compilation options to be used for building the program
executable. Certain options are ignored when program is created with IL.
The list of supported options is as described <em>in section 5.8.4</em>.</p></div>
<div class="paragraph"><p><em>num_input_headers</em> specifies the number of programs that describe
headers in the array referenced by <em>input_headers</em>.</p></div>
<div class="paragraph"><p><em>input_headers</em> is an array of program embedded headers created with
<strong>clCreateProgramWithSource</strong>.</p></div>
<div class="paragraph"><p><em>header_include_names</em> is an array that has a one to one correspondence
with <em>input_headers</em>. Each entry in <em>header_include_names</em> specifies
the include name used by source in <em>program</em> that comes from an embedded
header. The corresponding entry in <em>input_headers</em> identifies the
program object which contains the header source to be used. The
embedded headers are first searched before the headers in the list of
directories specified by the I compile option (as described in <em>section
5.8.4.1</em>). If multiple entries in <em>header_include_names</em> refer to the
same header name, the first one encountered will be used.</p></div>
<div class="paragraph"><p>If <em>program</em> was created using clCreateProgramWithIL, then
<em>num_input_headers</em>, <em>input_headers</em>, and <em>header_include_names</em> are
ignored.</p></div>
<div class="paragraph"><p>For example, consider the following program source:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre> #include &lt;foo.h&gt;
#include &lt;mydir/myinc.h&gt;
__kernel void
image_filter (int n, int m,
__constant float *filter_weights,
__read_only image2d_t src_image,
__write_only image2d_t dst_image)
{
...
}</pre>
</div></div>
<div class="paragraph"><p>This kernel includes two headers foo.h and mydir/myinc.h. The following
describes how these headers can be passed as embedded headers in program
objects:
 </p></div>
<div class="listingblock">
<div class="content monospaced">
<pre> cl_program foo_pg = clCreateProgramWithSource(context,
1, &amp;foo_header_src, NULL, &amp;err);
cl_program myinc_pg = clCreateProgramWithSource(context,
1, &amp;myinc_header_src, NULL, &amp;err);
// lets assume the program source described above is given
// by program_A and is loaded via clCreateProgramWithSource
cl_program input_headers[2] = \{ foo_pg, myinc_pg };
char * input_header_names[2] = \{ foo.h, mydir/myinc.h };
clCompileProgram(program_A,
0, NULL, // num_devices &amp; device_list
NULL, // compile_options
2, // num_input_headers
input_headers,
input_header_names,
NULL, NULL); // pfn_notify &amp; user_data</pre>
</div></div>
<div class="paragraph"><p><em>pfn_notify</em> is a function pointer to a notification routine. The
notification routine is a callback function that an application can
register and which will be called when the program executable has been
built (successfully or unsuccessfully). If <em>pfn_notify</em> is not NULL,
<strong>clCompileProgram</strong> does not need to wait for the compiler to complete
and can return immediately once the compilation can begin. The
compilation can begin if the context, program whose sources are being
compiled, list of devices, input headers, programs that describe input
headers and compiler options specified are all valid and appropriate
host and device resources needed to perform the compile are available.
If <em>pfn_notify</em> is NULL, <strong>clCompileProgram</strong> does not return until the
compiler has completed. This callback function may be called
asynchronously by the OpenCL implementation. It is the applications
responsibility to ensure that the callback function is thread-safe.</p></div>
<div class="paragraph"><p><em>user_data</em> will be passed as an argument when <em>pfn_notify</em> is called.
<em>user_data</em> can be NULL.</p></div>
<div class="paragraph"><p><strong>clCompileProgram</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is not a valid program object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>device_list</em> is NULL and <em>num_devices</em> is greater than zero, or if
<em>device_list</em> is not NULL and <em>num_devices</em> is zero.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>num_input_headers</em> is zero and <em>header_include_names</em> or
<em>input_headers</em> are not NULL or if <em>num_input_headers</em> is not zero and
<em>header_include_names</em> or <em>input_headers</em> are NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pfn_notify</em> is NULL but <em>user_data</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_DEVICE if
OpenCL devices listed in <em>device_list</em> are not in the list of devices
associated with <em>program</em>
</p>
</li>
<li>
<p>
     CL_INVALID_COMPILER_OPTIONS if the compiler options specified by
<em>options</em> are invalid.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the compilation or build of a program executable for any of the devices
listed in <em>device_list</em> by a previous call to <strong>clCompileProgram</strong> or
<strong>clBuildProgram</strong> for <em>program</em> has not completed.
</p>
</li>
<li>
<p>
      CL_COMPILER_NOT_AVAILABLE
if a compiler is not available i.e. CL_DEVICE_COMPILER_AVAILABLE
specified in <em>table 4.3</em> is set to CL_FALSE.
</p>
</li>
<li>
<p>
      CL_COMPILE_PROGRAM_FAILURE
if there is a failure to compile the program source. This error will be
returned if <strong>clCompileProgram</strong> does not return until the compile has
completed.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
there are kernel objects attached to <em>program</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
<em>program</em> has no source or IL available, i.e. it has not been created
with <strong>clCreateProgramWithSource</strong> or <strong>clCreateProgramWithIL</strong>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_program clLinkProgram(cl_context context,
cl_uint num_devices,
const cl_device_id *device_list,
const char *options,
cl_uint num_input_programs,
const cl_program *input_programs,
void (CL_CALLBACK *pfn_notify)
(cl_program program,
void *user_data),
void *user_data,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>links a set of compiled program objects and libraries for all the
devices or a specific device(s) in the OpenCL context and creates a
library or executable. <strong>clLinkProgram</strong> creates a new program object
which contains the library or executable. The library or executable
binary can be queried using <strong>clGetProgramInfo</strong>(<em>program</em>,
CL_PROGRAM_BINARIES, ) and can be specified to
<strong>clCreateProgramWithBinary</strong> to create a new program object.</p></div>
<div class="paragraph"><p>The devices associated with the returned program object will be the list
of devices specified by_device_list_ or if <em>device_list</em> is NULL it will
be the list of devices associated with <em>context</em>.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>device_list</em> is a pointer to a list of devices that are in <em>context</em>.
If <em>device_list</em> is a NULL value, the link is performed for all devices
associated with <em>context</em> for which a compiled object is available. If
<em>device_list</em> is a non-NULL value, the link is performed for devices
specified in this list for which a compiled object is available.</p></div>
<div class="paragraph"><p><em>num_devices_is the number of devices listed in _device_list</em>.</p></div>
<div class="paragraph"><p><em>options</em> is a pointer to a null-terminated string of characters that
describes the link options to be used for building the program
executable. The list of supported options is as described <em>in section
5.8.7</em>.
If the program was created using clCreateProgramWithBinary and <em>options</em> is
a NULL pointer,
the program will be linked as if options were the same as when the program binary
was originally built.
If the program was created using clCreateProgramWithBinary and <em>options</em> string contains
anything other than the same options in the same order (whitespace ignored)
as when the program binary
was originally built, then the behavior is implementation defined.</p></div>
<div class="paragraph"><p><em>num_input_programs</em> specifies the number of programs in array
referenced by <em>input_programs</em>.</p></div>
<div class="paragraph"><p><em>input_programs</em> is an array of program objects that are compiled
binaries or libraries that are to be linked to create the program
executable. For each device in <em>device_list</em> or if <em>device_list</em> is
NULL the list of devices associated with context, the following cases
occur:</p></div>
<div class="ulist"><ul>
<li>
<p>
      All programs specified by
<em>input_programs</em> contain a compiled binary or library for the device.
In this case, a link is performed to generate a program executable for
this device.
</p>
</li>
<li>
<p>
      None of the programs
contain a compiled binary or library for that device. In this case, no
link is performed and there will be no program executable generated for
this device.
</p>
</li>
<li>
<p>
      All other cases will
return a CL_INVALID_OPERATION error.
</p>
</li>
</ul></div>
<div class="paragraph"><p><em>pfn_notify</em> is a function pointer to a notification routine. The
notification routine is a callback function that an application can
register and which will be called when the program executable has been
built (successfully or unsuccessfully).</p></div>
<div class="paragraph"><p>If <em>pfn_notify</em> is not NULL, <strong>clLinkProgram</strong> does not need to wait for
the linker to complete and can return immediately once the linking
operation can begin. Once the linker has completed, the <em>pfn_notify</em>
callback function is called which returns the program object returned by
<strong>clLinkProgram</strong>. The application can query the link status and log for
this program object. This callback function may be called asynchronously
by the OpenCL implementation. It is the applications responsibility to
ensure that the callback function is thread-safe.</p></div>
<div class="paragraph"><p>If <em>pfn_notify</em> is NULL, <strong>clLinkProgram</strong> does not return until the
linker has completed.</p></div>
<div class="paragraph"><p><em>user_data</em> will be passed as an argument when <em>pfn_notify</em> is called.
<em>user_data</em> can be NULL.</p></div>
<div class="paragraph"><p>The linking operation can begin if the context, list of devices, input
programs and linker options specified are all valid and appropriate host
and device resources needed to perform the link are available. If the
linking operation can begin, <strong>clLinkProgram</strong> returns a valid non-zero
program object.</p></div>
<div class="paragraph"><p>If <em>pfn_notify</em> is NULL, the <em>errcode_ret</em> will be set to CL_SUCCESS if
the link operation was successful and CL_LINK_FAILURE if there is a
failure to link the compiled binaries and/or libraries.</p></div>
<div class="paragraph"><p>If <em>pfn_notify</em> is not NULL, <strong>clLinkProgram</strong> does not have to wait until
the linker to complete and can return CL_SUCCESS in <em>errcode_ret</em> if the
linking operation can begin. The <em>pfn_notify</em> callback function will
return a CL_SUCCESS or CL_LINK_FAILURE if the linking operation was
successful or not.</p></div>
<div class="paragraph"><p>Otherwise <strong>clLinkProgram</strong> returns a NULL program object with an
appropriate error in <em>errcode_ret</em>. The application should query the
linker status of this program object to check if the link was successful
or not. The list of errors that can be returned are:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
<em>context</em> is not a valid context.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>device_list</em> is NULL and <em>num_devices</em> is greater than zero, or if
<em>device_list</em> is not NULL and <em>num_devices</em> is zero.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>num_input_programs</em> is zero and <em>input_programs</em> is NULL__or
if_num_input_programs_ is zero and <em>input_programs</em> is not NULL or if
<em>num_input_programs</em> is not zero and <em>input_programs</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_PROGRAM if
programs specified in <em>input_programs</em> are not valid program objects.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pfn_notify</em> is NULL but <em>user_data</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_DEVICE if
OpenCL devices listed in <em>device_list</em> are not in the list of devices
associated with <em>context</em>
</p>
</li>
<li>
<p>
      CL_INVALID_LINKER_OPTIONS
if the linker options specified by <em>options</em> are invalid.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the compilation or build of a program executable for any of the devices
listed in <em>device_list</em> by a previous call to <strong>clCompileProgram</strong> or
<strong>clBuildProgram</strong> for <em>program</em> has not completed.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the rules for devices containing compiled binaries or libraries as
described in <em>input_programs</em> argument above are not followed.
</p>
</li>
<li>
<p>
      CL_LINKER_NOT_AVAILABLE if
a linker is not available i.e. CL_DEVICE_LINKER_AVAILABLE specified in
<em>table 4.3</em> is set to CL_FALSE.
</p>
</li>
<li>
<p>
      CL_LINK_PROGRAM_FAILURE if
there is a failure to link the compiled binaries and/or libraries.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_compiler_options">5.8.6. Compiler Options</h4>
<div class="paragraph"><p>The compiler options are categorized as pre-processor options, options
for math intrinsics, options that control optimization and miscellaneous
options. This specification defines a standard set of options that must
be supported by the compiler when building program executables online or
offline from OpenCL C/C++ or, where relevant, from an IL. These may be
extended by a set of vendor- or platform-specific options.</p></div>
<div class="sect4">
<h5 id="_preprocessor_options">Preprocessor options</h5>
<div class="paragraph"><p>These options control the OpenCL C/C++ preprocessor which is run on each
program source before actual compilation. These options are ignored for
programs created with IL.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-D _name_</pre>
</div></div>
<div class="paragraph"><p>Predefine <em>name</em> as a macro, with definition 1.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-D _name_=_definition_</pre>
</div></div>
<div class="paragraph"><p>The contents of <em>definition</em> are tokenized and processed as if they
appeared during</p></div>
<div class="paragraph"><p>translation phase three in a &#8216;#define&#8217; directive. In particular, the
definition will be</p></div>
<div class="paragraph"><p>truncated by embedded newline characters.</p></div>
<div class="paragraph"><p>-D options are processed in the order they are given in the <em>options</em>
argument to <strong>clBuildProgram</strong> or <strong>clCompileProgram</strong>. Note that a space is
required between the -D option and the symbol it defines, otherwise
behavior is implementation defined.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-I _dir_</pre>
</div></div>
<div class="paragraph"><p>Add the directory <em>dir</em> to the list of directories to be searched for
header files. <em>dir</em> can optionally be enclosed in double quotes.</p></div>
<div class="paragraph"><p>This option is not portable due to its dependency on host file system and host operating
system. It is supported for backwards compatibility with previous OpenCL versions.
Developers are encouraged to create and use explicit header objects by means of
clCompileProgram followed by clLinkProgram.</p></div>
</div>
<div class="sect4">
<h5 id="_math_intrinsics_options">Math Intrinsics Options</h5>
<div class="paragraph"><p>These options control compiler behavior regarding floating-point
arithmetic. These options trade off between speed and correctness.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-single-precision-constant</pre>
</div></div>
<div class="paragraph"><p>Treat double precision floating-point constant as single precision
constant. This option is ignored for programs created with IL.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-denorms-are-zero</pre>
</div></div>
<div class="paragraph"><p>This option controls how single precision and double precision
denormalized numbers are handled. If specified as a build option, the
single precision denormalized numbers may be flushed to zero; double
precision denormalized numbers may also be flushed to zero if the
optional extension for double precision is supported. This is intended
to be a performance hint and the OpenCL compiler can choose not to flush
denorms to zero if the device supports single precision (or double
precision) denormalized numbers.</p></div>
<div class="paragraph"><p>This option is ignored for single precision numbers if the device does
not support single precision denormalized numbers i.e. CL_FP_DENORM bit
is not set in CL_DEVICE_SINGLE_FP_CONFIG.</p></div>
<div class="paragraph"><p>This option is ignored for double precision numbers if the device does
not support double precision or if it does support double precision but
not double precision denormalized numbers i.e. CL_FP_DENORM bit is not
set in CL_DEVICE_DOUBLE_FP_CONFIG.</p></div>
<div class="paragraph"><p>This flag only applies for scalar and vector single precision
floating-point variables and computations on these floating-point
variables inside a program. It does not apply to reading from or
writing to image objects.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-fp32-correctly-rounded-divide-sqrt</pre>
</div></div>
<div class="paragraph"><p>The -cl-fp32-correctly-rounded-divide-sqrt build option to
<strong>clBuildProgram</strong> or</p></div>
<div class="paragraph"><p><strong>clCompileProgram</strong> allows an application to specify that single
precision floating-point</p></div>
<div class="paragraph"><p>divide (x/y and 1/x) and sqrt used in the program source are correctly
rounded. If</p></div>
<div class="paragraph"><p>this build option is not specified, te minimum numerical accuracy of
single precision</p></div>
<div class="paragraph"><p>floating-point divide and sqrt are as defined in the SPIR-V OpenCL
environment specification.</p></div>
<div class="paragraph"><p>This build option can only be specified if the
CL_FP_CORRECTLY_ROUNDED_DIVIDE_SQRT is set in CL_DEVICE_SINGLE_FP_CONFIG
(as defined in <em>table 4.3</em>) for devices that the program is being
build. <strong>clBuildProgram</strong> or <strong>clCompileProgram</strong> will fail to compile the
program for a device if the -cl-fp32-correctly-rounded-divide-sqrt
option is specified and CL_FP_CORRECTLY_ROUNDED_DIVIDE_SQRT is not set
for the device.</p></div>
</div>
<div class="sect4">
<h5 id="_optimization_options">Optimization Options</h5>
<div class="paragraph"><p>These options control various sorts of optimizations. Turning on
optimization flags makes the compiler attempt to improve the performance
and/or code size at the expense of compilation time and possibly the
ability to debug the program.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-opt-disable</pre>
</div></div>
<div class="literalblock">
<div class="content monospaced">
<pre> This option disables all optimizations. The default is
optimizations are enabled.</pre>
</div></div>
<div class="paragraph"><p>The following options control compiler behavior regarding floating-point
arithmetic. These options trade off between performance and correctness
and must be specifically enabled. These options are not turned on by
default since it can result in incorrect output for programs which
depend on an exact implementation of IEEE 754 rules/specifications for
math functions.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-mad-enable</pre>
</div></div>
<div class="paragraph"><p>Allow a * b + c to be replaced by a mad. The mad computes a * b + c
with</p></div>
<div class="paragraph"><p>reduced accuracy. For example, some OpenCL devices implement mad as
truncate the</p></div>
<div class="paragraph"><p>result of a * b before adding it to c.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-no-signed-zeros</pre>
</div></div>
<div class="paragraph"><p>Allow optimizations for floating-point arithmetic that ignore the
signedness of zero.</p></div>
<div class="paragraph"><p>IEEE 754 arithmetic specifies the distinct behavior of +0.0 and -0.0
values, which then prohibits simplification of expressions such as x+0.0
or 0.0*x (even with -cl-finite-math only). This option implies that the
sign of a zero result isn&#8217;t significant.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-unsafe-math-optimizations</pre>
</div></div>
<div class="paragraph"><p>Allow optimizations for floating-point arithmetic that (a) assume that
arguments and results are valid, (b) may violate IEEE 754 standard and
(c) may violate the OpenCL numerical compliance requirements as defined
in the SPIR-V OpenCL environment specification for single precision and
double precision floating-point, and edge case behavior in the SPIR-V
OpenCL environment specification. This option includes the
-cl-no-signed-zeros and -cl-mad-enable options.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-finite-math-only</pre>
</div></div>
<div class="paragraph"><p>Allow optimizations for floating-point arithmetic that assume that
arguments and results</p></div>
<div class="paragraph"><p>are not NaNs, +Inf, -Inf. This option may violate the OpenCL numerical
compliance requirements for single precision and double precision
floating-point, as well as edge case behavior. The original and modified
values are defined in the SPIR-V OpenCL environment specification</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-fast-relaxed-math</pre>
</div></div>
<div class="paragraph"><p>Sets the optimization options -cl-finite-math-only and
-cl-unsafe-math-optimizations.</p></div>
<div class="paragraph"><p>This allows optimizations for floating-point arithmetic that may violate
the IEEE 754
standard and the OpenCL numerical compliance requirements for single
precision and double precision floating-point, as well as floating point
edge case behavior. This option also relaxes the precision of commonly
used math functions. This option causes the preprocessor macro
<em>FAST_RELAXED_MATH</em> to be defined in the OpenCL program. The original
and modified values are defined in the SPIR-V OpenCL environment
specification</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-uniform-work-group-size</pre>
</div></div>
<div class="paragraph"><p>This requires that the global work-size be a multiple of the work-group
size specified to
<strong>clEnqueueNDRangeKernel</strong>. Allow optimizations that are made possible by
this restriction.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-no-subgroup-ifp</pre>
</div></div>
<div class="paragraph"><p>This indicates that kernels in this program do not require subgroups to
make independent forward progress. Allows optimizations that are made
possible by this restriction. This option has no effect for devices
that do not support independent forward progress for subgroups.</p></div>
</div>
<div class="sect4">
<h5 id="_options_to_request_or_suppress_warnings">Options to Request or Suppress Warnings</h5>
<div class="paragraph"><p>Warnings are diagnostic messages that report constructions which are not
inherently erroneous but which are risky or suggest there may have been
an error. The following language-independent options do not enable
specific warnings but control the kinds of diagnostics produced by the
OpenCL compiler. These options are ignored for programs created with IL.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-w</pre>
</div></div>
<div class="paragraph"><p>Inhibit all warning messages.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-Werror</pre>
</div></div>
<div class="paragraph"><p>Make all warnings into errors.</p></div>
</div>
<div class="sect4">
<h5 id="_options_controlling_the_opencl_c_version">Options Controlling the OpenCL C version</h5>
<div class="paragraph"><p>The following option controls the version of OpenCL C that the compiler
accepts. These options are ignored for programs created with IL.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-std=</pre>
</div></div>
<div class="paragraph"><p>Determine the OpenCL C language version to use. A value for this
option must be provided. Valid values are:</p></div>
<div class="ulist"><ul>
<li>
<p>
CL1.1 Support all OpenCL C programs that use the OpenCL C language
features defined in <em>section 6</em> of the OpenCL 1.1 specification.
</p>
</li>
<li>
<p>
CL1.2 Support all OpenCL C programs that use the OpenCL C language
features defined in <em>section 6</em> of the OpenCL 1.2 specification.
</p>
</li>
<li>
<p>
CL2.0 Support all OpenCL C programs that use the OpenCL C language
features defined in <em>section 6</em> OpenCL C 2.0 specification.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Calls to <strong>clBuildProgram</strong> or <strong>clCompileProgram</strong> with the -cl-std=CL1.1
option <strong>will fail</strong> to compile the program for any devices with
CL_DEVICE_OPENCL_C_VERSION = OpenCL C 1.0.</p></div>
<div class="paragraph"><p>Calls to <strong>clBuildProgram</strong> or <strong>clCompileProgram</strong> with the -cl-std=CL1.2
option <strong>will fail</strong> to compile the program for any devices with
CL_DEVICE_OPENCL_C_VERSION = OpenCL C 1.0.</p></div>
<div class="paragraph"><p>Calls to <strong>clBuildProgram</strong> or <strong>clCompileProgram</strong> with the -cl-std=CL2.0
option <strong>will fail</strong> to compile the program for any devices with
CL_DEVICE_OPENCL_C_VERSION = OpenCL C 1.0, OpenCL C 1.1 or OpenCL C 1.2.</p></div>
<div class="paragraph"><p>If the cl-std build option is not specified, the highest OpenCL C 1.x
language version supported by each device is used when compiling the
program for each device. Applications are required to specify the
cl-std=CL2.0 option if they want to compile or build their programs
with OpenCL C 2.0.</p></div>
</div>
<div class="sect4">
<h5 id="_options_for_querying_kernel_argument_information">Options for Querying Kernel Argument Information</h5>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-kernel-arg-info</pre>
</div></div>
<div class="paragraph"><p>This option allows the compiler to store information about the arguments
of a kernel(s) in</p></div>
<div class="paragraph"><p>the program executable. The argument information stored includes the
argument name,</p></div>
<div class="paragraph"><p>its type, the address space and access qualifiers used. Refer to
description of</p></div>
<div class="paragraph"><p><strong>clGetKernelArgInfo</strong> on how to query this information.</p></div>
</div>
<div class="sect4">
<h5 id="_options_for_debugging_your_program">Options for debugging your program</h5>
<div class="paragraph"><p>The following option is available.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-g</pre>
</div></div>
<div class="paragraph"><p>This option can currently be used to generate additional errors for the
built-in functions that allow you to enqueue commands on a device (refer
to OpenCL kernel languages specifications).</p></div>
</div>
</div>
<div class="sect3">
<h4 id="_linker_options">5.8.7. Linker Options</h4>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>This specification defines a standard set of linker options that must be
supported by the OpenCL C compiler when linking compiled programs online
or offline. These linker options are categorized as library linking
options and program linking options. These may be extended by a set of
vendor- or platform-specific options.</p></div>
<div class="sect4">
<h5 id="_library_linking_options">Library Linking Options</h5>
<div class="paragraph"><p>The following options can be specified when creating a library of
compiled binaries.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-create-library</pre>
</div></div>
<div class="paragraph"><p>Create a library of compiled binaries specified in <em>input_programs</em>
argument to <strong>clLinkProgram</strong>.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-enable-link-options</pre>
</div></div>
<div class="paragraph"><p>Allows the linker to modify the library behavior based on one or more
link options</p></div>
<div class="paragraph"><p>(described in <em>section 5.8.5.2</em>) when this library is linked with a
program executable. This</p></div>
<div class="paragraph"><p>option must be specified with the create-library option.</p></div>
</div>
<div class="sect4">
<h5 id="_program_linking_options">Program Linking Options</h5>
<div class="paragraph"><p>The following options can be specified when linking a program
executable.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>-cl-denorms-are-zero
-cl-no-signed-zeroes
-cl-unsafe-math-optimizations
-cl-finite-math-only
-cl-fast-relaxed-math
-cl-no-subgroup-ifp</pre>
</div></div>
<div class="paragraph"><p>The options are described in <em>section 5.8.4.2</em> and <em>section 5.8.4.3</em>.
The linker may apply these options to all compiled program objects
specified to <strong>clLinkProgram</strong>. The linker may apply these options only
to libraries which were created with the enable-link-option.</p></div>
</div>
</div>
<div class="sect3">
<h4 id="_unloading_the_opencl_compiler">5.8.8. Unloading the OpenCL Compiler</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clUnloadPlatformCompiler(cl_platform_id platform)</pre>
</div></div>
<div class="paragraph"><p>allows the implementation to release the resources allocated by the
OpenCL compiler for <em>platform</em>. This is a hint from the application and
does not guarantee that the compiler will not be used in the future or
that the compiler will actually be unloaded by the implementation.
Calls to <strong>clBuildProgram</strong>, <strong>clCompileProgram</strong> or <strong>clLinkProgram</strong> after
<strong>clUnloadPlatformCompiler</strong> will reload the compiler, if necessary, to
build the appropriate program executable.</p></div>
<div class="paragraph"><p><strong>clUnloadPlatformCompiler</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PLATFORM if
<em>platform</em> is not a valid platform.
</p>
</li>
</ul></div>
</div>
<div class="sect3">
<h4 id="_program_object_queries">5.8.9. Program Object Queries</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetProgramInfo(cl_program program,
cl_program_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns information about the program object.</p></div>
<div class="paragraph"><p><em>program</em> specifies the program object being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetProgramInfo</strong> is described in <em>table 5.17</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.17.</em></p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 23. <em>clGetProgramInfo parameter queries</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_program_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_PROGRAM_REFERENCE_ COUNT*<span class="footnote"><br>[The reference count returned should be considered immediately stale. It is unsuitable for general use in
applications. This feature is provided for identifying memory leaks.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the <em>program</em> reference count.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_CONTEXT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_context</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the context specified when the
program object is created</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_NUM_DEVICES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the number of devices
associated with <em>program</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_DEVICES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_id[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the list of devices
associated with the program object. This can be the devices associated
with context on which the program object has been created or can be a
subset of devices that are specified when a progam object is created
using <strong>clCreateProgramWithBinary</strong>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_SOURCE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the program source code specified
by clCreateProgramWithSource. The
source string returned is a concatenation of
all source strings specified to
clCreateProgramWithSource with a null
terminator. The concatenation strips any
nulls in the original source strings.
<br>
<br>
If program is created using
clCreateProgramWithBinary,
clCreateProgramWithIL or
clCreateProgramWithBuiltinKernels, a
null string or the appropriate program
source code is returned depending on
whether or not the program source code is
stored in the binary.
<br>
<br>
The actual number of characters that
represents the program source code
including the null terminator is returned in
param_value_size_ret.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_IL</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the program IL for programs created
with clCreateProgramWithIL.
<br>
<br>
If program is created with
clCreateProgramWithSource,
clCreateProgramWithBinary or
clCreateProgramWithBuiltinKernels the
memory pointed to by param_value will be
unchanged and param_value_size_retwill be
set to 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_BINARY_SIZES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns an array that contains the size in
bytes of the program binary (could be an
executable binary, compiled binary or
library binary) for each device associated
with program. The size of the array is the
number of devices associated with
program. If a binary is not available for a
device(s), a size of zero is returned.
<br>
<br>
If program is created using
clCreateProgramWithBuiltinKernels,
the implementation may return zero in any
entries of the returned array.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_BINARIES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">unsigned <br>
char *[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the program binaries (could be an
executable binary, compiled binary or
library binary) for all devices associated
with program. For each device in
program, the binary returned can be the
binary specified for the device when
program is created with
clCreateProgramWithBinary or it can be
the executable binary generated by
clBuildProgram or clLinkProgram. If
program is created with
clCreateProgramWithSource or
clCreateProgramWithIL, the binary
returned is the binary generated by
clBuildProgram, clCompileProgram or
clLinkProgram. The bits returned can be
an implementation-specific intermediate
representation (a.k.a. IR) or device specific
executable bits or both. The decision on
which information is returned in the binary
is up to the OpenCL implementation.
<br>
<br>
param_value points to an array of n
pointers allocated by the caller, where n is
the number of devices associated with
program. The buffer sizes needed to
allocate the memory that these n pointers
refer to can be queried using the
CL_PROGRAM_BINARY_SIZES query as
described in this table.
<br>
<br>
Each entry in this array is used by the
implementation as the location in memory
where to copy the program binary for a
specific device, if there is a binary
available. To find out which device the
program binary in the array refers to, use
the CL_PROGRAM_DEVICES query to get
the list of devices. There is a one-to-one
correspondence between the array of n
pointers returned by
CL_PROGRAM_BINARIES and array of
devices returned by
CL_PROGRAM_DEVICES.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_NUM_KERNELS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the number of kernels
declared in <em>program</em> that can be created with <strong>clCreateKernel</strong>. This
information is only available after a successful program executable has
been built for at least one device in the list of devices associated
with <em>program</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_KERNEL_ NAMES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns a semi-colon separated list
of kernel names in <em>program</em> that can be created with <strong>clCreateKernel</strong>.
This information is only available after a successful program executable
has been built for at least one device in the list of devices associated
with <em>program</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_SCOPE_ GLOBAL_CTORS_PRESENT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This indicates that
the <em>program</em> object contains non-trivial constructor(s) that will be
executed by runtime before any kernel from the program is executed.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_SCOPE_ GLOBAL_DTORS_PRESENT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This indicates that
the program object contains non-trivial destructor(s) that will be
executed by runtime when <em>program</em> is
destroyed. </p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><strong>clGetProgramInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table
5.17_and _param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is a not a valid program object.
</p>
</li>
<li>
<p>
     
CL_INVALID_PROGRAM_EXECUTABLE if <em>param_name</em> is CL_PROGRAM_NUM_KERNELS
or CL_PROGRAM_KERNEL_NAMES and a successful program executable has not
been built for at least one device in the list of devices associated
with <em>program</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetProgramBuildInfo(cl_program program,
cl_device_id device,
cl_program_build_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns build information for each device in the program object.</p></div>
<div class="paragraph"><p><em>program</em> specifies the program object being queried.</p></div>
<div class="paragraph"><p><em>device</em> specifies the device for which build information is being
queried. <em>device</em> must be a valid device associated with <em>program</em>.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetProgramBuildInfo</strong> is described in <em>table 5.18</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.18.</em></p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 24. <em>clGetProgramBuildInfo</em> <em>parameter queries.</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_program_build_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in
<em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_PROGRAM_BUILD_<br>
STATUS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_build_status</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the build, compile or link status,
whichever was performed last on program for
device.
<br>
<br>
This can be one of the following:
<br>
<br>
CL_BUILD_NONE. The build status returned if
no clBuildProgram, clCompileProgram or
clLinkProgram has been performed on the
specified program object for device.
<br>
<br>
CL_BUILD_ERROR. The build status returned
if clBuildProgram, clCompileProgram or
clLinkProgram whichever was performed last
on the specified program object for device
generated an error.
<br>
<br>
CL_BUILD_SUCCESS. The build status
returned if clBuildProgram,
clCompileProgram or clLinkProgram
whichever was performed last on the specified
program object for device was successful.
<br>
<br>
CL_BUILD_IN_PROGRESS. The build status
returned if clBuildProgram,
clCompileProgram or clLinkProgram
whichever was performed last on the specified
program object for device has not finished.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_PROGRAM_BUILD_<br>
OPTIONS</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the build, compile or link options
specified by the options argument in
clBuildProgram, clCompileProgram or
clLinkProgram, whichever was performed last
on program for device.
<br>
<br>
If build status of program for device is
CL_BUILD_NONE, an empty string is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_PROGRAM_BUILD_<br>
LOG</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the build or compile log for
clBuildProgram or clCompileProgram
whichever was performed last on program for
device.
<br>
<br>
If build status of program for device is
CL_BUILD_NONE, an empty string is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">CL_PROGRAM_BINARY_<br>
TYPE</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_program_<br>
binary_type</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the program binary type for device.
This can be one of the following values:
<br>
<br>
CL_PROGRAM_BINARY_TYPE_NONE – There
is no binary associated with device.
<br>
<br>
CL_PROGRAM_BINARY_TYPE_
COMPILED_OBJECT – A compiled binary is
associated with device. This is the case if
program was created using
clCreateProgramWithSource and compiled
using clCompileProgram or a compiled binary
is loaded using clCreateProgramWithBinary.
<br>
<br>
CL_PROGRAM_BINARY_TYPE_
LIBRARY – A library binary is associated with
device. This is the case if program was created
by clLinkProgram which is called with the –
create-library link option or if a library binary is
loaded using clCreateProgramWithBinary.
<br>
<br>
CL_PROGRAM_BINARY_TYPE_
EXECUTABLE – An executable binary is
associated with device. This is the case if
program was created by clLinkProgram
without the –create-library link option or
program was created by clBuildProgram or an
executable binary is loaded using
clCreateProgramWithBinary.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROGRAM_BUILD_<br>
GLOBAL_VARIABLE_<br>
TOTAL_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The total amount of storage, in bytes, used by
program variables in the global address space.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetProgramBuildInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_DEVICE if
<em>device</em> is not in the list of devices associated with <em>program</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table 5.18</em>
and <em>param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is a not a valid program object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>NOTE:</p></div>
<div class="paragraph"><p>A program binary (compiled binary, library binary or executable binary)
built for a parent device can be used by all its sub-devices. If a
program binary has not been built for a sub-device, the program binary
associated with the parent device will be used.</p></div>
<div class="paragraph"><p>A program binary for a device specified with <strong>clCreateProgramWithBinary</strong>
or queried using <strong>clGetProgramInfo</strong> can be used as the binary for the
associated root device, and all sub-devices created from the root-level
device or sub-devices thereof.</p></div>
</div>
</div>
<div class="sect2">
<h3 id="_kernel_objects">5.9. Kernel Objects</h3>
<div class="paragraph"><p>A kernel is a function declared in a program. A kernel is identified
by the <em>kernel qualifier applied to any function in a program. A
kernel object encapsulates the specific </em>kernel function declared in a
program and the argument values to be used when executing this __kernel
function.</p></div>
<div class="sect3">
<h4 id="_creating_kernel_objects">5.9.1. Creating Kernel Objects</h4>
<div class="paragraph"><p>To create a kernel object, use the function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_kernel clCreateKernel(cl_program program,
const char *kernel_name,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p><em>program</em> is a program object with a successfully built executable.</p></div>
<div class="paragraph"><p><em>kernel_name</em> is a function name in the program declared with the
__kernel qualifier.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateKernel</strong> returns a valid non-zero kernel object and
<em>errcode_ret</em> is set to CL_SUCCESS if the kernel object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in <em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
_program_is not a valid program object.
</p>
</li>
<li>
<p>
  CL_INVALID_PROGRAM_EXECUTABLE if there is no successfully built
executable for <em>program</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_KERNEL_NAME if
<em>kernel_name</em> is not found in <em>program</em>.
</p>
</li>
<li>
<p>
  CL_INVALID_KERNEL_DEFINITION if the function definition for <em>_kernel
function given by _kernel_name</em> such as the number of arguments, the
argument types are not the same for all devices for which the <em>program</em>
executable has been built.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>kernel_name</em> is NULL.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clCreateKernelsInProgram(cl_program program,
cl_uint num_kernels,
cl_kernel *kernels,
cl_uint *num_kernels_ret)</pre>
</div></div>
<div class="paragraph"><p>creates kernel objects for all kernel functions in <em>program</em>. Kernel
objects are not created for any <em>_kernel functions in _program</em> that do
not have the same function definition across all devices for which a
program executable has been successfully built.</p></div>
<div class="paragraph"><p><em>program</em> is a program object with a successfully built executable.</p></div>
<div class="paragraph"><p><em>num_kernels</em> is the size of memory pointed to by <em>kernels</em> specified as
the number of cl_kernel entries.</p></div>
<div class="paragraph"><p><em>kernels</em> is the buffer where the kernel objects for kernels in
<em>program</em> will be returned. If <em>kernels</em> is NULL, it is ignored. If
<em>kernels</em> is not NULL, <em>num_kernels</em> must be greater than or equal to
the number of kernels in <em>program</em>.</p></div>
<div class="paragraph"><p><em>num_kernels_ret</em> is the number of kernels in <em>program</em>. If
<em>num_kernels_ret</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><strong>clCreateKernelsInProgram</strong> will return CL_SUCCESS if the kernel objects
were successfully allocated. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_PROGRAM if
<em>program</em> is not a valid program object.
</p>
</li>
<li>
<p>
     CL_INVALID_PROGRAM_EXECUTABLE if there is no successfully built
executable for any device in <em>program</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>kernels</em> is not NULL and <em>num_kernels</em> is less than the number of
kernels in <em>program</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Kernel objects can only be created once you have a program object with a
valid program source or binary loaded into the program object and the
program executable has been successfully built for one or more devices
associated with program. No changes to the program executable are
allowed while there are kernel objects associated with a program
object. This means that calls to <strong>clBuildProgram</strong> and
<strong>clCompileProgram</strong> return CL_INVALID_OPERATION if there are kernel
objects attached to a program object. The OpenCL context associated
with <em>program</em> will be the context associated with <em>kernel</em>. The list
of devices associated with <em>program</em> are the devices associated with
<em>kernel</em>. Devices associated with a program object for which a valid
program executable has been built can be used to execute kernels
declared in the program object.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainKernel(cl_kernel kernel)</pre>
</div></div>
<div class="paragraph"><p>increments the <em>kernel</em> reference count. <strong>clRetainKernel</strong> returns
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>clCreateKernel</strong> or <strong>clCreateKernelsInProgram</strong> do an implicit retain.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseKernel(cl_kernel kernel)</pre>
</div></div>
<div class="paragraph"><p>decrements the <em>kernel</em> reference count. <strong>clReleaseKernel</strong> returns
CL_SUCCESS if the function is executed successfully. Otherwise, it
returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The kernel object is deleted once the number of instances that are
retained to <em>kernel</em> become zero and the kernel object is no longer
needed by any enqueued commands that use <em>kernel</em>. Using this function
to release a reference that was not obtained by creating the object or
by calling <strong>clRetainKernel</strong> causes undefined behavior.</p></div>
</div>
<div class="sect3">
<h4 id="_setting_kernel_arguments">5.9.2. Setting Kernel Arguments</h4>
<div class="paragraph"><p>To execute a kernel, the kernel arguments must be set.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetKernelArg(cl_kernel kernel,
cl_uint arg_index,
size_t arg_size,
const void *arg_value)</pre>
</div></div>
<div class="paragraph"><p>is used to set the argument value for a specific argument of a kernel.</p></div>
<div class="paragraph"><p><em>kernel</em> is a valid kernel object.</p></div>
<div class="paragraph"><p><em>arg_index</em> is the argument index. Arguments to the kernel are referred
by indices that go from 0 for the leftmost argument to <em>n</em> - 1, where
<em>n</em> is the total number of arguments declared by a kernel.</p></div>
<div class="paragraph"><p>For example, consider the following kernel:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre> kernel void image_filter (int n,
int m,
constant float *filter_weights,
read_only image2d_t src_image,
write_only image2d_t dst_image)
{
...
}</pre>
</div></div>
<div class="paragraph"><p>Argument index values for image_filter will be 0 for n, 1 for m, 2 for
filter_weights, 3 for src_image and 4 for dst_image.</p></div>
<div class="paragraph"><p><em>arg_value</em> is a pointer to data that should be used as the argument
value for argument specified by <em>arg_index</em>. The argument data pointed
to by_arg_value_ is copied and the <em>arg_value</em> pointer can therefore be
reused by the application after <strong>clSetKernelArg</strong> returns. The argument
value specified is the value used by all API calls that enqueue <em>kernel</em>
(<strong>clEnqueueNDRangeKernel</strong>) until the argument value is changed by a call
to <strong>clSetKernelArg</strong> for <em>kernel</em>.</p></div>
<div class="paragraph"><p>If the argument is a memory object (buffer, pipe, image or image array),
the <em>arg_value</em> entry will be a pointer to the appropriate buffer, pipe,
image or image array object. The memory object must be created with the
context associated with the kernel object. If the argument is a buffer
object, the <em>arg_value</em> pointer can be NULL or point to a NULL value in
which case a NULL value will be used as the value for the argument
declared as a pointer to global or constant memory in the kernel. If
the argument is declared with the local qualifier, the <em>arg_value</em> entry
must be NULL. If the argument is of type <em>sampler_t</em>, the <em>arg_value</em>
entry must be a pointer to the sampler object. If the argument is of
type <em>queue_t</em>, the <em>arg_value</em> entry must be a pointer to the device
queue object.</p></div>
<div class="paragraph"><p>If the argument is declared to be a pointer of a built-in scalar or
vector type, or a user defined structure type in the global or constant
address space, the memory object specified as argument value must be a
buffer object (or NULL). If the argument is declared with the constant
qualifier, the size in bytes of the memory object cannot exceed
CL_DEVICE_MAX_CONSTANT_BUFFER_SIZE and the number of arguments declared
as pointers to <em>constant</em> memory cannot exceed
CL_DEVICE_MAX_CONSTANT_ARGS.</p></div>
<div class="paragraph"><p>The memory object specified as argument value must be a pipe object if
the argument is declared with the <em>pipe</em> qualifier.</p></div>
<div class="paragraph"><p>The memory object specified as argument value must be a 2D image object
if the argument is declared to be of type <em>image2d_t</em>. The memory
object specified as argument value must be a 2D image object with image
channel order = CL_DEPTH if the argument is declared to be of type
<em>image2d_depth_t</em>. The memory object specified as argument value must
be a 3D image object if argument is declared to be of type <em>image3d_t</em>.
The memory object specified as argument value must be a 1D image object
if the argument is declared to be of type <em>image1d_t</em>. The memory
object specified as argument value must be a 1D image buffer object if
the argument is declared to be of type <em>image1d_buffer_t</em>. The memory
object specified as argument value must be a 1D image array object if
argument is declared to be of type <em>image1d_array_t</em>. The memory object
specified as argument value must be a 2D image array object if argument
is declared to be of type <em>image2d_array_t</em>. The memory object
specified as argument value must be a 2D image array object with image
channel order = CL_DEPTH if argument is declared to be of type
<em>image2d_array_depth_t</em>.</p></div>
<div class="paragraph"><p>For all other kernel arguments, the <em>arg_value</em> entry must be a pointer
to the actual data to be used as argument value.</p></div>
<div class="paragraph"><p><em>arg_size</em> specifies the size of the argument value. If the argument is
a memory object, the size is the size of the memory object. For
arguments declared with the local qualifier, the size specified will be
the size in bytes of the buffer that must be allocated for the local
argument. If the argument is of type <em>sampler_t</em>, the <em>arg_size</em> value
must be equal to sizeof(cl_sampler). If the argument is of type
<em>queue_t</em>, the <em>arg_size</em> value must be equal to
sizeof(cl_command_queue). For all other arguments, the size will be the
size of argument type.</p></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">A kernel object does not update the reference count for objects
such as memory, sampler objects specified as argument values by
<strong>clSetKernelArg</strong>, Users may not rely on a kernel object to retain
objects specified as argument values to the kernel<span class="footnote"><br>[Implementations shall not allow cl_kernel objects to hold reference counts to cl_kernel arguments, because no
mechanism is provided for the user to tell the kernel to release that ownership right. If the kernel holds ownership rights on kernel args, that would make it impossible for the user to tell with certainty when he may safel y release
user allocated resources associated with OpenCL objects such as the cl_mem backing store used with
CL_MEM_USE_HOST_PTR.]<br></span>:.</td>
</tr></table>
</div>
<div class="paragraph"><p><strong>clSetKernelArg</strong> returns CL_SUCCESS if the function was executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_INVALID_ARG_INDEX if
<em>arg_index</em> is not a valid argument index.
</p>
</li>
<li>
<p>
      CL_INVALID_ARG_VALUE if
<em>arg_value</em> specified is not a valid value.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT for
an argument declared to be a memory object when the specified
<em>arg_value</em> is not a valid memory object.
</p>
</li>
<li>
<p>
      CL_INVALID_SAMPLER for an
argument declared to be of type <em>sampler_t</em> when the specified
<em>arg_value</em> is not a valid sampler object.
</p>
</li>
<li>
<p>
      CL_INVALID_DEVICE_QUEUE
for an argument declared to be of type <em>queue_t</em> when the specified
<em>arg_value</em> is not a valid device queue object.
</p>
</li>
<li>
<p>
      CL_INVALID_ARG_SIZE if
<em>arg_size</em> does not match the size of the data type for an argument that
is not a memory object or if the argument is a memory object and
<em>arg_size</em> != sizeof(cl_mem) or if <em>arg_size</em> is zero and the argument
is declared with the local qualifier or if the argument is a sampler and
<em>arg_size</em> != sizeof(cl_sampler).
</p>
</li>
<li>
<p>
     CL_MAX_SIZE_RESTRICTION_EXCEEDED if the size in bytes of the memory
object (if the argument was declared with constant qualifier) or
<em>arg_size</em> (if the argument was declared with local qualifier) exceed
the maximum size restriction that was set with
the optional language attribute. The optional attribute can be
cl::max_size defined in OpenCL 2.2 C++ Kernel Languange specification or
SpvDecorationMaxByteOffset defined in SPIR-V 1.2 Specification.
</p>
</li>
<li>
<p>
      CL_INVALID_ARG_VALUE if
the argument is an image declared with the read_only qualifier and
<em>arg_value</em> refers to an image object created with <em>cl_mem_flags</em> of
CL_MEM_WRITE or if the image argument is declared with the write_only
qualifier and <em>arg_value</em> refers to an image object created with
<em>cl_mem_flags</em> of CL_MEM_READ.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetKernelArgSVMPointer(cl_kernel kernel,
cl_uint arg_index,
const void *arg_value)</pre>
</div></div>
<div class="paragraph"><p>is used to set a SVM pointer as the argument value for a specific
argument of a kernel.</p></div>
<div class="paragraph"><p><em>kernel</em> is a valid kernel object.</p></div>
<div class="paragraph"><p><em>arg_index</em> is the argument index. Arguments to the kernel are referred
by indices that go from 0 for the leftmost argument to <em>n</em> - 1, where
<em>n</em> is the total number of arguments declared by a kernel.</p></div>
<div class="paragraph"><p><em>arg_value</em> is the SVM pointer that should be used as the argument value
for argument specified by <em>arg_index</em>. The SVM pointer specified is the
value used by all API calls that enqueue <em>kernel</em>
(<strong>clEnqueueNDRangeKernel</strong>) until the argument value is changed by a call
to <strong>clSetKernelArgSVMPointer</strong> for <em>kernel</em>. The SVM pointer can only be
used for arguments that are declared to be a pointer to global or
constant memory. The SVM pointer value must be aligned according to the
arguments type. For example, if the argument is declared to be global
float4 p, the SVM pointer value passed for p must be at a minimum
aligned to a float4. The SVM pointer value specified as the argument
value can be the pointer returned by <strong>clSVMAlloc</strong> or can be a pointer offset into the SVM region.</p></div>
<div class="paragraph"><p><strong>clSetKernelArgSVMPointer</strong> returns CL_SUCCESS if the function was
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_INVALID_ARG_INDEX if
<em>arg_index</em> is not a valid argument index.
</p>
</li>
<li>
<p>
      CL_INVALID_ARG_VALUE if
<em>arg_value</em> specified is not a valid value.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetKernelExecInfo(cl_kernel kernel,
cl_kernel_exec_info param_name,
size_t param_value_size,
const void *param_value)</pre>
</div></div>
<div class="paragraph"><p>can be used to pass additional information other than argument values to
a kernel.</p></div>
<div class="paragraph"><p><em>kernel</em> specifies the kernel object being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to be passed to kernel. The list
of supported <em>param_name</em> types and the corresponding values passed in
<em>param_value</em> is described in <em>table 5.19</em>.</p></div>
<div class="paragraph"><p><em>param_value_size</em> specifies the size in bytes of the memory pointed to
by <em>param_value</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate values
determined by <em>param_name</em> are specified.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 25. <em>clSetKernelExecInfo</em> <em>parameter values.</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_kernel_exec_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_EXEC_INFO_ SVM_PTRS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">void *[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">SVM pointers must reference
locations contained entirely within
buffers that are passed to kernel as
arguments, or that are passed through
the execution information.
<br>
<br>
Non-argument SVM buffers must be
specified by passing pointers to those
buffers via clSetKernelExecInfo for
coarse-grain and fine-grain buffer
SVM allocations but not for finegrain system SVM allocations.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_EXEC_INFO_ SVM_FINE_GRAIN_SYSTEM</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This flag
indicates whether the kernel uses pointers that are fine grain system
SVM allocations. These fine grain system SVM pointers may be passed as
arguments or defined in SVM buffers that are passed as arguments to
<em>kernel</em>.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clSetKernelExecInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is a not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, if <em>param_value</em> is NULL or if the size
specified by <em>param_value_size</em> is not valid.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
<em>param_name</em> = CL_KERNEL_EXEC_INFO_SVM_FINE_GRAIN_SYSTEM and
<em>param_value</em> = CL_TRUE but no devices in context associated with
<em>kernel</em> support fine-grain system SVM allocations.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>NOTES</p></div>
<div class="paragraph"><p>Coarse-grain or fine-grain buffer SVM pointers used by a kernel
which are not passed as a kernel arguments must be specified using
<strong>clSetKernelExecInfo</strong> with CL_KERNEL_EXEC_INFO_SVM_PTRS. For example,
if SVM buffer A contains a pointer to another SVM buffer B, and the
kernel dereferences that pointer, then a pointer to B must either be
passed as an argument in the call to that kernel or it must be made
available to the kernel using <strong>clSetKernelExecInfo</strong>. For example, we
might pass extra SVM pointers as follows:
 </p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>clSetKernelExecInfo(kernel,
CL_KERNEL_EXEC_INFO_SVM_PTRS,
num_ptrs * sizeof(void *),
extra_svm_ptr_list);</pre>
</div></div>
<div class="paragraph"><p>Here num_ptrs specifies the number of additional SVM pointers while
extra_svm_ptr_list specifies a pointer to memory containing those SVM
pointers.</p></div>
<div class="paragraph"><p>When calling <strong>clSetKernelExecInfo</strong> with CL_KERNEL_EXEC_INFO_SVM_PTRS to
specify pointers to non-argument SVM buffers as extra arguments to a
kernel, each of these pointers can be the SVM pointer returned by
<strong>clSVMAlloc</strong> or can be a pointer + offset into the SVM region. It is
sufficient to provide one pointer for each SVM buffer used.</p></div>
<div class="paragraph"><p>CL_KERNEL_EXEC_INFO_SVM_FINE_GRAIN_SYSTEM is used to indicate
whether SVM pointers used by a kernel will refer to system allocations
or not.</p></div>
<div class="paragraph"><p>CL_KERNEL_EXEC_INFO_SVM_FINE_GRAIN_SYSTEM = CL_FALSE indicates that the
OpenCL implementation may assume that system pointers are not passed as
kernel arguments and are not stored inside SVM allocations passed as
kernel arguments.</p></div>
<div class="paragraph"><p>CL_KERNEL_EXEC_INFO_SVM_FINE_GRAIN_SYSTEM = CL_TRUE indicates that the
OpenCL implementation must assume that system pointers might be passed
as kernel arguments and/or stored inside SVM allocations passed as
kernel arguments. In this case, if the device to which the kernel is
enqueued does not support system SVM pointers, <strong>clEnqueueNDRangeKernel</strong>
will return a CL_INVALID_OPERATION error. If none of the devices in the
context associated with kernel support fine-grain system SVM
allocations, <strong>clSetKernelExecInfo</strong> will return a CL_INVALID_OPERATION
error.</p></div>
<div class="paragraph"><p>If <strong>clSetKernelExecInfo</strong> has not been called with a value for
<strong>CL_KERNEL_EXEC_INFO_SVM_FINE_GRAIN_SYSTEM</strong>, the default value is used
for this kernel attribute. The default value depends on whether the
device on which the kernel is enqueued supports fine-grain system SVM
allocations. If so, the default value used is CL_TRUE (system pointers
might be passed); otherwise, the default is CL_FALSE.</p></div>
<div class="paragraph"><p>A call to <strong>clSetKernelExecInfo</strong> for a given value of <em>param_name</em>
replaces any prior value passed for that value of <em>param_name</em>. Only one
<em>param_value</em> will be stored for each value of <em>param_name</em>.
 </p></div>
</div>
<div class="sect3">
<h4 id="_copying_kernel_objects">5.9.3. Copying Kernel Objects</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_kernel clCloneKernel(cl_kernel source_kernel,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>is used to make a shallow copy of the kernel object, its arguments and
any information passed to the kernel object using <strong>clSetKernelExecInfo</strong>.
If the kernel object was ready to be enqueued before copying it, the
clone of the kernel object is ready to enqueue.</p></div>
<div class="paragraph"><p><em>source_kernel</em> is a valid cl_kernel object that will be copied.
_source_kernel_will not be modified in any way by this function.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will be assigned an appropriate error code. If
_errcode_ret_is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCloneKernel</strong> returns a valid non-zero kernel object and <em>errcode_ret</em>
is set to CL_SUCCESS if the kernel is successfully copied. Otherwise it
returns a NULL value with one of the following error values returned in
<em>errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The returned kernel object is an exact copy of <em>source_kernel</em>, with one
caveat: the reference count on the returned kernel object is set as if
it had been returned by <strong>clCreateKernel</strong>. The reference count of
<em>source_kernel will</em> not be changed.</p></div>
<div class="paragraph"><p>The resulting kernel will be in the same state as if <strong>clCreateKernel</strong> is
called to create the resultant kernel with the same arguments as those
used to create <em>source_kernel</em>, the latest call to <strong>clSetKernelArg</strong> or
<strong>clSetKernelArgSVMPointer</strong> for each argument index applied to kernel and
the last call to <strong>clSetKernelExecInfo</strong> for each value of the param name
parameter are applied to the new kernel object.</p></div>
<div class="paragraph"><p>All arguments of the new kernel object must be intact and it may be
correctly used in the same situations as kernel except those that assume
a pre-existing reference count. Setting arguments on the new kernel
object will not affect <em>source_kernel</em> except insofar as the argument
points to a shared underlying entity and in that situation behavior is
as if two kernel objects had been created and the same argument applied
to each. Only the data stored in the kernel object is copied; data
referenced by the kernels arguments are not copied. For example, if a
buffer or pointer argument is set on a kernel object, the pointer is
copied but the underlying memory allocation is not.</p></div>
</div>
<div class="sect3">
<h4 id="_kernel_object_queries">5.9.4. Kernel Object Queries</h4>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetKernelInfo*(cl_kernel kernel,
cl_kernel_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns information about the kernel object.</p></div>
<div class="paragraph"><p><em>kernel</em> specifies the kernel object being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetKernelInfo</strong> is described in <em>table 5.20</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.20</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.
 </p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 26. <em>clGetKernelInfo</em> <em>parameter queries.</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_kernel_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_FUNCTION_NAME</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the kernel function name.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_NUM_ARGS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the number of arguments to
kernel.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_KERNEL_REFERENCE_ COUNT*<span class="footnote"><br>[The reference count returned should be considered immediately stale. It is unsuitable for general use in
applications. This feature is provided for identifying memory leaks. ]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the <em>kernel</em> reference
count.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_CONTEXT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_context</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the context associated with
<em>kernel</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_PROGRAM</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_program</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the program object associated
with kernel.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_ATTRIBUTES</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns any attributes specified using
the <em>attribute</em> OpenCL Cqualifier (or using an OpenCL C++ qualifier syntax [[]] ) with the
kernel function declaration in the
program source. These attributes
include attributes described in the
earlier OpenCL C kernel language
specifications and other attributes
supported by an implementation.
<br>
<br>
Attributes are returned as they were
declared inside <em>attribute</em>&#8230;,
with any surrounding whitespace and
embedded newlines removed. When
multiple attributes are present, they
are returned as a single, space
delimited string.
<br>
<br>
For kernels not created from OpenCL
C source and the
clCreateProgramWithSource API
call the string returned from this
query will be empty.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetKernelInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table
5.20_and _param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is a not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetKernelWorkGroupInfo(cl_kernel kernel,
cl_device_id device,
cl_kernel_work_group_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns information about the kernel object that may be specific to a
device.</p></div>
<div class="paragraph"><p><em>kernel</em> specifies the kernel object being queried.</p></div>
<div class="paragraph"><p><em>device</em> identifies a specific device in the list of devices associated
with <em>kernel</em>. The list of devices is the list of devices in the OpenCL
context that is associated with <em>kernel</em>. If the list of devices
associated with <em>kernel</em> is a single device, <em>device</em> can be a NULL
value.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetKernelWorkGroupInfo</strong> is described in <em>table 5.21</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.21</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 27. <em>clGetKernelWorkGroupInfo</em> <em>parameter queries.</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_kernel_work_group_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in
<em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_GLOBAL_ WORK_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t[3]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This provides a mechanism for the
application to query the maximum global size that can be used to execute a kernel
(i.e. global_work_size argument to
clEnqueueNDRangeKernel) on a custom
device given by device or a built-in kernel
on an OpenCL device given by device.
<br>
<br>
If device is not a custom device and kernel
is not a built-in kernel,
clGetKernelWorkGroupInfo returns the
error CL_INVALID_VALUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_WORK_ GROUP_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This provides a mechanism for the
application to query the maximum workgroup size that can be used to execute the
kernel on a specific device given by
device. The OpenCL implementation uses
the resource requirements of the kernel
(register usage etc.) to determine what this
work-group size should be.
<br>
<br>
As a result and unlike
CL_DEVICE_MAX_WORK_GROUP_
SIZE this value may vary from one kernel
to another as well as one device to
another.
<br>
<br>
CL_KERNEL_WORK_GROUP_SIZE
will be less than or equal to
CL_DEVICE_MAX_WORK_GROUP_SI
ZE for a given kernel object.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_COMPILE_<br>
WORK_GROUP_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t[3]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the work-group size specified in
the kernel source or IL.
<br>
<br>
If the work-group size is not specified in
the kernel source or IL, (0, 0, 0) is
returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_LOCAL_<br>
MEM_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the amount of local memory in
bytes being used by a kernel. This
includes local memory that may be needed
by an implementation to execute the
kernel, variables declared inside the kernel
with the <em>local address qualifier and
local memory to be allocated for
arguments to the kernel declared as
pointers with the </em>local address
qualifier and whose size is specified with
clSetKernelArg.
<br>
<br>
If the local memory size, for any pointer
argument to the kernel declared with the
__local address qualifier, is not
specified, its size is assumed to be 0.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_PREFERRED_<br>
WORK_GROUP_SIZE_MULTIPLE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the preferred multiple of
work-group size for launch. This is a performance hint. Specifying a
work-group size that is not a multiple of the value returned by this
query as the value of the local work size argument to
<strong>clEnqueueNDRangeKernel</strong> will not fail to enqueue the kernel for
execution unless the work-group size specified is larger than the device
maximum.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_PRIVATE_<br>
MEM_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the minimum amount of
private memory, in bytes, used by each work-item in the kernel. This
value may include any private memory needed by an implementation to
execute the kernel, including that used by the language built-ins and
variable declared inside the kernel with the __private qualifier.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetKernelWorkGroupInfo</strong> returns CL_SUCCESS if the function is
executed successfully. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_DEVICE if
<em>device</em> is not in the list of devices associated with <em>kernel</em> or if
<em>device</em> is NULL but there is more than one device associated with
<em>kernel</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table
5.21_and _param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is CL_KERNEL_GLOBAL_WORK_SIZE and <em>device</em> is not a custom
device and <em>kernel</em> is not a built-in kernel.
</p>
</li>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is a not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetKernelSubGroupInfo(cl_kernel kernel,
cl_device_id device,
cl_kernel_sub_group_info param_name,
size_t input_value_size,
const void *input_value,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns information about the kernel object.</p></div>
<div class="paragraph"><p><em>kernel</em> specifies the kernel object being queried.</p></div>
<div class="paragraph"><p><em>device</em> identifies a specific device in the list of devices associated
with <em>kernel</em>. The list of devices is the list of devices in the OpenCL
context that is associated with <em>kernel</em>. If the list of devices
associated with <em>kernel</em> is a single device, <em>device</em> can be a NULL
value.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetKernelSubGroupInfo</strong> is described in <em>table 5.22</em>.</p></div>
<div class="paragraph"><p><em>input_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>input_value</em>. This size must be == size of input type as
described in the table below.</p></div>
<div class="paragraph"><p><em>input_value</em> is a pointer to memory where the appropriate
parameterization of the query is passed from. If <em>input_value</em> is
NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.22</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 28. <em>clGetKernelSubGroupInfo</em> <em>parameter queries.</em></caption>
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_kernel_sub_group_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Input Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info.
returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_MAX_ SUB_GROUP_SIZE_ FOR_NDRANGE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t *</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the maximum sub-group size
for this kernel. All sub-groups must
be the same size, while the last subgroup in any work-group (i.e. the subgroup with the maximum index) could
be the same or smaller size.
<br>
<br>
The input_value must be an array of
size_t values corresponding to the
local work size parameter of the
intended dispatch. The number of
dimensions in the ND-range will be
inferred from the value specified for
input_value_size.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_SUB_ GROUP_COUNT_ FOR_NDRANGE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t *</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the number of sub-groups that
will be present in each work-group for
a given local work size. All workgroups, apart from the last work-group
in each dimension in the presence of
non-uniform work-group sizes, will
have the same number of sub-groups.
<br>
<br>
The input_value must be an array of
size_t values corresponding to the
local work size parameter of the
intended dispatch. The number of
dimensions in the ND-range will be
inferred from the value specified for
input_value_size.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_LOCAL_ SIZE_FOR_SUB_ GROUP_COUNT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns
the local size that will generate the requested number of sub-groups for
the kernel. The output array must be an array of size_t values
corresponding to the local size parameter. Any returned work-group will
have one dimension. Other dimensions inferred from the value specified
for param_value_size will be filled with the value 1. The returned value
will produce an exact number of sub-groups and result in no partial
groups for an executing kernel except in the case where the last
work-group in a dimension has a size different from that of the other
groups. If no work-group size can accommodate the requested number of
sub-groups, 0 will be returned in each element of the return array.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_MAX_ NUM_SUB_GROUPS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">ignored</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">This provides a
mechanism for the application to query the maximum number of sub-groups
that may make up each work-group to execute a kernel on a specific device
given by device. The OpenCL implementation uses the resource
requirements of the kernel (register usage etc.) to determine what this
work-group size should be. The returned value may be used to compute a
work-group size to enqueue the kernel with to give a round number of
sub-groups for an enqueue.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_ COMPILE_NUM_ SUB_GROUPS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">ignored</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the number
of sub-groups specified in the kernel source or IL. If the sub-group
count is not specified using the above attribute then 0 is returned.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetKernelSubGroupInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_DEVICE if
<em>device</em> is not in the list of devices associated with <em>kernel</em> or if
<em>device</em> is NULL but there is more than one device associated with
<em>kernel</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table 5.22</em>
and <em>param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is CL_KERNEL_SUB_GROUP_SIZE_FOR_NDRANGE and the size in
bytes specified by <em>input_value_size</em> is not valid or if <em>input_value</em>
is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is a not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetKernelArgInfo(cl_kernel kernel,
cl_uint arg_indx,
cl_kernel_arg_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns information about the arguments of a kernel.</p></div>
<div class="paragraph"><p>Kernel argument information is only available if the program object
associated with <em>kernel</em> is created with <strong>clCreateProgramWithSource</strong> and
the program executable was built with the -cl-kernel-arg-info option
specified in options argument to <strong>clBuildProgram</strong> or <strong>clCompileProgram</strong>.</p></div>
<div class="paragraph"><p><em>kernel</em> specifies the kernel object being queried.</p></div>
<div class="paragraph"><p><em>arg_indx</em> is the argument index. Arguments to the kernel are referred
by indices that go from 0 for the leftmost argument to <em>n</em> - 1, where
<em>n</em> is the total number of arguments declared by a kernel.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the argument information to query. The list of
supported <em>param_name</em> types and the information returned in
<em>param_value_by <strong>clGetKernelArgInfo</strong> is described in _table__5.23</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt; size of return type as
described in <em>table__5.23</em>.</p></div>
<div class="paragraph"><p><em>param_value_size ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 29. <em>clGetKernelArgInfo</em> <em>parameter queries.</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_kernel_arg_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_ARG_<br>
ADDRESS_QUALIFIER</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_kernel_arg_<br>
address_qualifier</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the address qualifier specified for the
argument given by arg_indx. This can be one of the
following values:
CL_KERNEL_ARG_ADDRESS_ GLOBAL
CL_KERNEL_ARG_ADDRESS_ LOCAL
CL_KERNEL_ARG_ADDRESS_ CONSTANT
CL_KERNEL_ARG_ADDRESS_ PRIVATE
<br>
<br>
If no address qualifier is specified, the default
address qualifier which is
CL_KERNEL_ARG_ADDRESS_PRIVATE is
returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_ARG_<br>
ACCESS_QUALIFIER</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_kernel_arg_<br>
access_qualifier</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the access qualifier specified for the
argument given by arg_indx. This can be one of the
following values:
CL_KERNEL_ARG_ACCESS_ READ_ONLY
CL_KERNEL_ARG_ACCESS_ WRITE_ONLY
CL_KERNEL_ARG_ACCESS_ READ_WRITE
CL_KERNEL_ARG_ACCESS_ NONE
<br>
<br>
If argument is not an image type and is not declared
with the pipe qualifier,
CL_KERNEL_ARG_ACCESS_NONE is returned. If
argument is an image type, the access qualifier
specified or the default access qualifier is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_ARG_TYPE_<br>
NAME</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the type name specified for the argument given
by <em>arg_indx</em>. The type name returned will be the argument type name as
it was declared with any whitespace removed. If argument type name is
an unsigned scalar type (i.e. unsigned char, unsigned short, unsigned
int, unsigned long), uchar, ushort, uint and ulong will be returned.
The argument type name returned does not include any type qualifiers.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_ARG_TYPE_<br>
QUALIFIER</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_kernel_arg_<br>
type_qualifier</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the type qualifier specified for the argument
given by arg_indx. The returned value can be:
CL_KERNEL_ARG_TYPE_ CONST
CL_KERNEL_ARG_TYPE_ RESTRICT
CL_KERNEL_ARG_TYPE_ VOLATILE, a
combination of the above enums,
CL_KERNEL_ARG_TYPE_PIPE or
CL_KERNEL_ARG_TYPE_NONE
<br>
<br>
NOTE: CL_KERNEL_ARG_ TYPE_VOLATILE is
returned if the argument is a pointer and the
referenced type is declared with the volatile
qualifier. For example, a kernel argument declared
as global int volatile *x returns
CL_KERNEL_ARG_TYPE_ VOLATILE but
a kernel argument declared as global int *
volatile x does not. Similarly,
CL_KERNEL_ARG_TYPE_CONST is returned if the
argument is a pointer and the referenced type is
declared with the restrict or const qualifier. For
example, a kernel argument declared as global
int const *x returns
CL_KERNEL_ARG_TYPE_CONST but
a kernel argument declared as global int *
const x does not.
CL_KERNEL_ARG_TYPE_ RESTRICT will be returned
if the pointer type is marked restrict. For example,
global int * restrict x returns
CL_KERNEL_ARG_TYPE_ RESTRICT.
<br>
<br>
If the argument is declared with the constant address
space qualifier, the
CL_KERNEL_ARG_TYPE_CONST type qualifier
will be set.
<br>
<br>
CL_KERNEL_ARG_TYPE_NONE is returned for all parameters passed by value.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_KERNEL_ARG_NAME</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">char[]</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Returns the name specified for the
argument given by <em>arg_indx</em>.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p><strong>clGetKernelArgInfo</strong> returns CL SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_ARG_INDEX if
<em>arg_indx</em> is not a valid argument index.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value</em> size is &lt; size of return type as described in_table 5.23_
and <em>param_value</em> is not NULL.
</p>
</li>
<li>
<p>
     
CL_KERNEL_ARG_INFO_NOT_AVAILABLE if the argument information is not
available for kernel.
</p>
</li>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is a not a valid kernel object.
</p>
</li>
</ul></div>
</div>
</div>
<div class="sect2">
<h3 id="_executing_kernels">5.10. Executing Kernels</h3>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueNDRangeKernel(cl_command_queue command_queue,
cl_kernel kernel,
cl_uint work_dim,
const size_t *global_work_offset,
const size_t *global_work_size,
const size_t *local_work_size,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to execute a kernel on a device.</p></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command-queue. The kernel will be
queued for execution on the device associated with <em>command_queue</em>.</p></div>
<div class="paragraph"><p><em>kernel</em> is a valid kernel object. The OpenCL context associated with
<em>kernel</em> and <em>command-queue</em> must be the same.</p></div>
<div class="paragraph"><p><em>work_dim</em> is the number of dimensions used to specify the global
work-items and work-items in the work-group. <em>work_dim</em> must be
greater than zero and less than or equal to
CL_DEVICE_MAX_WORK_ITEM_DIMENSIONS. If <em>global_work_size_is NULL, or the
value in any passed dimension is 0 then the kernel command will
trivially succeed after its event dependencies are satisfied and
subsequently update its completion event. The behavior in this situation
is similar to that of an enqueued marker, except that unlike a marker,
an enqueued kernel with no events passed to _event_wait_list</em> may run at
any time.</p></div>
<div class="paragraph"><p><em>global_work_offset</em> can be used to specify an array of <em>work_dim</em>
unsigned values that describe the offset used to calculate the global ID
of a work-item. If <em>global_work_offset</em> is NULL, the global IDs start
at offset (0, 0, 0).</p></div>
<div class="paragraph"><p><em>global_work_size</em> points to an array of <em>work_dim</em> unsigned values that
describe the number of global work-items in <em>work_dim</em> dimensions that
will execute the kernel function. The total number of global work-items
is computed as <em>global_work_size</em>[0] * &#8230; * <em>global_work_size</em>[<em>work_dim</em> - 1].</p></div>
<div class="paragraph"><p><em>local_work_size</em> points to an array of <em>work_dim</em> unsigned values that
describe the number of work-items that make up a work-group (also
referred to as the size of the work-group) that will execute the kernel
specified by <em>kernel</em>. The total number of work-items in a work-group
is computed as <em>local_work_size</em>[0] * &#8230; * <em>local_work_size</em>[<em>work_dim</em>
- 1]. The total number of work-items in the work-group must be less than
or equal to the CL_KERNEL_WORK_GROUP_SIZE value specified in <em>table
5.21</em> and the number of work-items specified in <em>local_work_size</em>[0], &#8230;,
<em>local_work_size</em>[<em>work_dim</em> - 1] must be less than or equal to the
corresponding values specified by CL_DEVICE_MAX_WORK_ITEM_SIZES[0], &#8230;,
CL_DEVICE_MAX_WORK_ITEM_SIZES[<em>work_dim</em> -1]. The explicitly specified
<em>local_work_size</em> will be used to determine how to break the global
work-items specified by <em>global_work_size</em> into appropriate work-group
instances.</p></div>
<div class="paragraph"><p>Enabling non-uniform work-groups requires the <em>kernel</em>'s program to be
compiled without the -cl-uniform-work-group-size flag. If the program
was created with clCreateProgramWithSource, non-uniform work-groups
are enabled only if the program was compiled with the -cl-std=CL2.0
flag and without the -cl-uniform-work-group-size flag.
If the program was created using clLinkProgram and any of the linked
programs were compiled in a way that only supports uniform work-group
sizes, the linked program only supports uniform work group sizes. If
<em>local_work_size</em> is specified and the OpenCL <em>kernel</em> is compiled without
non-uniform work-groups enabled, the values specified in
<em>global_work_size</em>[0], &#8230;, <em>global_work_size</em>[<em>work_dim</em> - 1] must be evenly
divisible by the corresponding values specified in <em>local_work_size</em>[0],
&#8230;, <em>local_work_size</em>[<em>work_dim</em> - 1].</p></div>
<div class="paragraph"><p>If non-uniform work-groups are enabled for the kernel, any single
dimension for which the global size is not divisible by the local size
will be partitioned into two regions. One region will have work-groups
that have the same number of work items as was specified by the local
size parameter in that dimension. The other region will have work-groups
with less than the number of work items specified by the local size
parameter in that dimension. The global IDs and group IDs of the work
items in the first region will be numerically lower than those in the
second, and the second region will be at most one work-group wide in
that dimension. Work-group sizes could be non-uniform in multiple
dimensions, potentially producing work-groups of up to 4 different sizes
in a 2D range and 8 different sizes in a 3D range.</p></div>
<div class="paragraph"><p>If <em>local_work_size_is NULL and the kernel is compiled without support
for non-uniform work-groups, the OpenCL runtime will implement the
ND-range with uniform work-group sizes. If _local_work_size</em> is NULL and
non-uniform-work-groups are enabled, the OpenCL runtime is free to
implement the ND-range using uniform or non-uniform work-group sizes,
regardless of the divisibility of the global work size. If the ND-range
is implemented using non-uniform work-group sizes, the work-group sizes,
global IDs and group IDs will follow the same pattern as described in
above paragraph.</p></div>
<div class="paragraph"><p>The work-group size to be used for <em>kernel</em> can also be specified in the
program source or intermediate language. In this case the size of work
group specified by <em>local_work_size</em> must match the value specified in
the program source.</p></div>
<div class="paragraph"><p>These work-group instances are executed in parallel across multiple
compute units or concurrently on the same compute unit.</p></div>
<div class="paragraph"><p>Each work-item is uniquely identified by a global identifier. The
global ID, which can be read inside the kernel, is computed using the
value given by <em>global_work_size_and_global_work_offset</em>. In addition,
a work-item is also identified within a work-group by a unique local
ID. The local ID, which can also be read by the kernel, is computed
using the value given by <em>local_work_size</em>. The starting local ID is
always (0, 0, 0).</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed. If
<em>event_wait_list</em> is NULL, then this particular command does not wait on
any event to complete. If <em>event_wait_list</em> is NULL,
<em>num_events_in_wait_list</em> must be 0. If <em>event_wait_list</em> is not NULL,
the list of events pointed to by <em>event_wait_list</em> must be valid and
<em>num_events_in_wait_list</em> must be greater than 0. The events specified
in <em>event_wait_list</em> act as synchronization points. The context
associated with events in <em>event_wait_list</em> and <em>command_queue</em> must be
the same. The memory associated with <em>event_wait_list</em> can be reused or
freed after the function returns.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular
kernel-instance. Event objects are unique and can be used to identify a
particular kernel-instance later on. If <em>event</em> is NULL, no event will
be created for this kernel-instance and therefore it will not be
possible for the application to query or queue a wait for this
particular kernel-instance. If the <em>event_wait_list</em> and the <em>event</em>
arguments are not NULL, the <em>event</em> argument should not refer to an
element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueNDRangeKernel</strong> returns CL_SUCCESS if the kernel-instance was
successfully queued. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
     CL_INVALID_PROGRAM_EXECUTABLE if there is no successfully built program
executable available for device associated with <em>command_queue</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_KERNEL if
<em>kernel</em> is not a valid kernel object.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and <em>kernel</em> are not the same or
if the context associated with <em>command_queue</em> and events in
<em>event_wait_list</em> are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_KERNEL_ARGS if
the kernel argument values have not been specified or if a kernel
argument declared to be a pointer to a type does not point to a named
address space.
</p>
</li>
<li>
<p>
      CL_INVALID_WORK_DIMENSION
if <em>work_dim</em> is not a valid value (i.e. a value between 1 and 3).
</p>
</li>
<li>
<p>
     CL_INVALID_GLOBAL_WORK_SIZE if any of the values specified in
<em>global_work_size</em>[0], <em>global_work_size</em>[<em>work_dim</em> 1] exceed the
maximum value representable by size_t on the device on which the
kernel-instance will be enqueued.
</p>
</li>
<li>
<p>
      CL_INVALID_GLOBAL_OFFSET
if the value specified in <em>global_work_size</em> + the corresponding values
in <em>global_work_offset</em> for any dimensions is greater than the maximum
value representable by size t on the device on which the kernel-instance
will be enqueued.
</p>
</li>
<li>
<p>
      CL_INVALID_WORK_GROUP_SIZE
if <em>local_work_size</em> is specified and does not match the required
work-group size for <em>kernel</em> in the program source.
</p>
</li>
<li>
<p>
      CL_INVALID_WORK_GROUP_SIZE
if <em>local_work_size</em> is specified and is not consistent with the
required number of sub-groups for <em>kernel</em> in the program source.
</p>
</li>
<li>
<p>
      CL_INVALID_WORK_GROUP_SIZE
if <em>local_work_size</em> is specified and the total number of work-items in
the work-group computed as <em>local_work_size</em>[0] *
<em>local_work_size</em>[<em>work_dim</em> 1] is greater than the value specified by
CL_KERNEL_WORK_GROUP_SIZE in <em>table 5.21</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_WORK_GROUP_SIZE
if the program was compiled with cl-uniform-work-group-size and the
number of work-items specified by <em>global_work_size</em> is not evenly
divisible by size of work-group given by <em>local_work_size</em> or by the
required work-group size specified in the kernel source.
</p>
</li>
<li>
<p>
      CL_INVALID_WORK_ITEM_SIZE
if the number of work-items specified in any of <em>local_work_size</em>[0],
<em>local_work_size</em>[<em>work_dim</em> 1] is greater than the corresponding
values specified by CL_DEVICE_MAX_WORK_ITEM_SIZES[0], .
CL_DEVICE_MAX_WORK_ITEM_SIZES[<em>work_dim</em> 1].
</p>
</li>
<li>
<p>
     CL_MISALIGNED_SUB_BUFFER_OFFSET if a sub-buffer object is specified as
the value for an argument that is a buffer object and the <em>offset</em>
specified when the sub-buffer object is created is not aligned to
CL_DEVICE_MEM_BASE_ADDR_ALIGN value for device associated with <em>queue</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_IMAGE_SIZE if
an image object is specified as an argument value and the image
dimensions (image width, height, specified or compute row and/or slice
pitch) are not supported by device associated with <em>queue</em>.
</p>
</li>
<li>
<p>
    CL_IMAGE_FORMAT_NOT_SUPPORTED if an image object is specified as an
argument value and the image format (image channel order and data type)
is not supported by device associated with <em>queue</em>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to queue the execution instance of <em>kernel</em> on the
command-queue because of insufficient resources needed to execute the
kernel. For example, the explicitly specified <em>local_work_size</em> causes
a failure to execute the kernel because of insufficient resources such
as registers or local memory. Another example would be the number of
read-only image args used in <em>kernel</em> exceed the
CL_DEVICE_MAX_READ_IMAGE_ARGS value for device or the number of
write-only and read-write image args used in <em>kernel</em> exceed the
CL_DEVICE_MAX_READ_WRITE_IMAGE_ARGS value for device or the number of
samplers used in <em>kernel</em> exceed CL_DEVICE_MAX_SAMPLERS for device.
</p>
</li>
<li>
<p>
    CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with image or buffer objects specified
as arguments to <em>kernel</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
SVM pointers are passed as arguments to a kernel and the device does not
support SVM or if system pointers are passed as arguments to a kernel
and/or stored inside SVM allocations passed as kernel arguments and the
device does not support fine grain system SVM allocations.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueNativeKernel(cl_command_queue command_queue,
void (CL_CALLBACK *user_func)(void *),
void *args,
size_t cb_args,
cl_uint num_mem_objects,
const cl_mem *mem_list,
const void **args_mem_loc,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a command to execute a native C/C++ function not compiled using
the OpenCL compiler.</p></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command-queue. A native user function
can only be executed on a command-queue created on a device that has
CL_EXEC_NATIVE_KERNEL capability set in CL_DEVICE_EXECUTION_CAPABILITIES
as specified in <em>table 4.3</em>.</p></div>
<div class="paragraph"><p><em>user_func</em> is a pointer to a host-callable user function.</p></div>
<div class="paragraph"><p><em>args</em> is a pointer to the args list that <em>user_func</em> should be called
with.</p></div>
<div class="paragraph"><p><em>cb_args</em> is the size in bytes of the args list that <em>args</em> points to.</p></div>
<div class="paragraph"><p>The data pointed to by <em>args</em> and <em>cb_args</em> bytes in size will be copied
and a pointer to this copied region will be passed to <em>user_func</em>. The
copy needs to be done because the memory objects (cl_mem values) that
<em>args</em> may contain need to be modified and replaced by appropriate
pointers to global memory. When <strong>clEnqueueNativeKernel</strong> returns, the
memory region pointed to by <em>args</em> can be reused by the application.</p></div>
<div class="paragraph"><p><em>num_mem_objects</em> is the number of buffer objects that are passed in
<em>args</em>.</p></div>
<div class="paragraph"><p><em>mem_list</em> is a list of valid buffer objects, if <em>num_mem_objects</em> &gt; 0.
The buffer object values specified in <em>mem_list</em> are memory object
handles (cl_mem values) returned by <strong>clCreateBuffer</strong> or NULL.</p></div>
<div class="paragraph"><p><em>args_mem_loc</em> is a pointer to appropriate locations that <em>args</em> points
to where memory object handles (cl_mem values) are stored. Before the
user function is executed, the memory object handles are replaced by
pointers to global memory.</p></div>
<div class="paragraph"><p><em>event_wait_list, num_events_in_wait_list and</em> <em>event</em> are as described
in <strong>clEnqueueNDRangeKernel</strong>.</p></div>
<div class="paragraph"><p><strong>clEnqueueNativeKernel</strong> returns CL_SUCCESS if the user function
execution instance was successfully queued. Otherwise, it returns one
of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>user_func</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if <em>args</em>
is a NULL value and <em>cb_args</em> &gt; 0, or if <em>args</em> is a NULL value and
<em>num_mem_objects</em> &gt; 0.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>args</em> is not NULL and <em>cb_args</em> is 0.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>num_mem_objects</em> &gt; 0 and <em>mem_list</em> or <em>args_mem_loc</em> are NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>num_mem_objects</em> = 0 and <em>mem_list</em> or <em>args_mem_loc</em> are not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the device associated with <em>command_queue</em> cannot execute the native
kernel.
</p>
</li>
<li>
<p>
      CL_INVALID_MEM_OBJECT if
one or more memory objects specified in <em>mem_list</em> are not valid or are
not buffer objects.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to queue the execution instance of <em>kernel</em> on the
command-queue because of insufficient resources needed to execute the
kernel.
</p>
</li>
<li>
<p>
     CL_MEM_OBJECT_ALLOCATION_FAILURE if there is a failure to allocate
memory for data store associated with buffer objects specified as
arguments to <em>kernel</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
SVM pointers are passed as arguments to a kernel and the device does not
support SVM or if system pointers are passed as arguments to a kernel
and/or stored inside SVM allocations passed as kernel arguments and the
device does not support fine grain system SVM allocations.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>NOTE:</p></div>
<div class="paragraph"><p>The total number of read-only images specified as arguments to a kernel
cannot exceed CL_DEVICE_MAX_READ_IMAGE_ARGS. Each image array argument
to a kernel declared with the read_only qualifier counts as one image.
The total number of write-only images specified as arguments to a kernel
cannot exceed CL_DEVICE_MAX_WRITE_IMAGE_ARGS. Each image array argument to a kernel
declared with the write_only qualifier counts as one image.</p></div>
<div class="paragraph"><p>The total number of read-write images specified as arguments to a kernel
cannot exceed CL_DEVICE_MAX_READ_WRITE_IMAGE_ARGS. Each image array
argument to a kernel declared with the read_write qualifier counts as
one image.</p></div>
</div>
<div class="sect2">
<h3 id="_event_objects">5.11. Event Objects</h3>
<div class="paragraph"><p>Event objects can be used to refer to a kernel-instance command
(<strong>clEnqueueNDRangeKernel, clEnqueueNativeKernel</strong>), read, write, map and
copy commands on memory objects (<strong>clEnqueue{Read|Write|Map}Buffer,
clEnqueueUnmapMemObject</strong>, <strong>clEnqueue{Read|Write}BufferRect</strong>,
<strong>clEnqueue{Read|Write|Map}Image</strong>, <strong>clEnqueueCopy{Buffer|Image}</strong>,
<strong>clEnqueueCopyBufferRect</strong>, <strong>clEnqueueCopyBufferToImage</strong>,
<strong>clEnqueueCopyImageToBuffer),</strong> <strong>clEnqueueSVMMemcpy</strong>,
<strong>clEnqueueSVMMemFill</strong>, <strong>clEnqueueSVMMap</strong>, <strong>clEnqueueSVMUnmap</strong>,
<strong>clEnqueueSVMFree</strong>,
<strong>clEnqueueMarkerWithWaitList</strong>,<strong>clEnqueueBarrierWithWaitList</strong>(refer to
<em>section 5.12</em>) or user events.</p></div>
<div class="paragraph"><p>An event object can be used to track the execution status of a command.
The API calls that enqueue commands to a command-queue create a new
event object that is returned in the <em>event</em> argument. In case of an
error enqueuing the command in the command-queue the event argument does
not return an event object.</p></div>
<div class="paragraph"><p>The execution status of an enqueued command at any given point in time
can be one of the following:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_QUEUED This indicates
that the command has been enqueued in a command-queue. This is the
initial state of all events except user events.
</p>
</li>
<li>
<p>
      CL_SUBMITTED This is the
initial state for all user events. For all other events, this indicates
that the command has been submitted by the host to the device.
</p>
</li>
<li>
<p>
      CL_RUNNING This
indicates that the device has started executing this command. In order
for the execution status of an enqueued command to change from
CL_SUBMITTED to CL_RUNNING, all events that this command is waiting on
must have completed successfully i.e. their execution status must be
CL_COMPLETE.
</p>
</li>
<li>
<p>
      CL_COMPLETE This
indicates that the command has successfully completed.
</p>
</li>
<li>
<p>
      Error code The error
code is a negative integer value and indicates that the command was
abnormally terminated. Abnormal termination may occur for a number of
reasons such as a bad memory access.
</p>
</li>
</ul></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">A command is considered to be complete if its execution status is
CL_COMPLETE or is a negative integer value.</td>
</tr></table>
</div>
<div class="paragraph"><p>If the execution of a command is terminated, the command-queue
associated with this terminated command, and the associated context (and
all other command-queues in this context) may no longer be available.
The behavior of OpenCL API calls that use this context (and
command-queues associated with this context) are now considered to be
implementation-defined. The user registered callback function specified
when context is created can be used to report appropriate error
information.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_event clCreateUserEvent(cl_context context,
cl_int *errcode_ret)</pre>
</div></div>
<div class="paragraph"><p>creates a user event object. User events allow applications to enqueue
commands that wait on a user event to finish before the command is
executed by the device.</p></div>
<div class="paragraph"><p><em>context</em> must be a valid OpenCL context.</p></div>
<div class="paragraph"><p><em>errcode_ret</em> will return an appropriate error code. If <em>errcode_ret</em>
is NULL, no error code is returned.</p></div>
<div class="paragraph"><p><strong>clCreateUserEvent</strong> returns a valid non-zero event object and
<em>errcode_ret_is set to CL_SUCCESS if the user event object is created
successfully. Otherwise, it returns a NULL value with one of the
following error values returned in _errcode_ret</em>:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_CONTEXT if
_context_is not a valid context.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The execution status of the user event object created is set to
CL_SUBMITTED.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetUserEventStatus(cl_event event,
cl_int execution_status)</pre>
</div></div>
<div class="paragraph"><p>sets the execution status of a user event object.</p></div>
<div class="paragraph"><p><em>event</em> is a user event object created using <strong>clCreateUserEvent</strong>.</p></div>
<div class="paragraph"><p><em>execution_status</em> specifies the new execution status to be set and can
be CL_COMPLETE or a negative integer value to indicate an error. A
negative integer value causes all enqueued commands that wait on this
user event to be terminated. <strong>clSetUserEventStatus</strong> can only be called
once to change the execution status of <em>event</em>.</p></div>
<div class="paragraph"><p><strong>clSetUserEventStatus</strong> returns CL_SUCCESS if the function was executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_EVENT if
<em>event</em> is not a valid user event object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if the
<em>execution_status</em> is not CL_COMPLETE or a negative integer value.
</p>
</li>
<li>
<p>
      CL_INVALID_OPERATION if
the <em>execution_status</em> for <em>event</em> has already been changed by a
previous call to <strong>clSetUserEventStatus</strong>.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">If there are enqueued commands with user events in the
<em>event_wait_list</em> argument of <strong>clEnqueue</strong> commands, the user must
ensure that the status of these user events being waited on are set
using <strong>clSetUserEventStatus</strong> before any OpenCL APIs that release OpenCL
objects except for event objects are called; otherwise the behavior is
undefined.</td>
</tr></table>
</div>
<div class="paragraph"><p>For example, the following code sequence will result in undefined
behavior of <strong>clReleaseMemObject</strong>.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>ev1 = clCreateUserEvent(ctx, NULL);
clEnqueueWriteBuffer(cq, buf1, CL_FALSE, ..., 1, &amp;ev1, NULL);
clEnqueueWriteBuffer(cq, buf2, CL_FALSE,...);
clReleaseMemObject(buf2);
clSetUserEventStatus(ev1, CL_COMPLETE);</pre>
</div></div>
<div class="paragraph"><p>The following code sequence, however, works correctly.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>ev1 = clCreateUserEvent(ctx, NULL);
clEnqueueWriteBuffer(cq, buf1, CL_FALSE, ...,1, &amp;ev1, NULL);
clEnqueueWriteBuffer(cq, buf2, CL_FALSE,...);
clSetUserEventStatus(ev1, CL_COMPLETE);
clReleaseMemObject(buf2);</pre>
</div></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clWaitForEvents(cl_uint num_events,
const cl_event *event_list)</pre>
</div></div>
<div class="paragraph"><p>waits on the host thread for commands identified by event objects in
<em>event_list</em> to complete. A command is considered complete if its
execution status is CL_COMPLETE or a negative value. The events
specified in <em>event_list</em> act as synchronization points.</p></div>
<div class="paragraph"><p><strong>clWaitForEvents</strong> returns CL_SUCCESS if the execution status of all
events in <em>event_list</em> is CL_COMPLETE. Otherwise, it returns one of the
following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>num_events</em> is zero or <em>event_list</em> is NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
events specified in <em>event_list</em> do not belong to the same context.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT if event
objects specified in <em>event_list</em> are not valid event objects.
</p>
</li>
<li>
<p>
  CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST if the execution status of
any of the events in <em>event_list</em> is a negative integer value.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetEventInfo(cl_event event,
cl_event_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns information about the event object.</p></div>
<div class="paragraph"><p><em>event</em> specifies the event object being queried.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the information to query. The list of supported
<em>param_name</em> types and the information returned in <em>param_value</em> by
<strong>clGetEventInfo</strong> is described in <em>table 5.24</em>.</p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.24</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 30. <em>clGetEventInfo</em> <em>parameter queries.</em></caption>
<col style="width:30%;">
<col style="width:33%;">
<col style="width:37%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_event_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_EVENT_COMMAND_<br>
QUEUE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_command_<br>
queue</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the command-queue associated with <em>event</em>. For user
event objects, a NULL value is returned.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_EVENT_CONTEXT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_context</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the context associated with
<em>event</em>.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_EVENT_COMMAND_<br>
TYPE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_command_type</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the command associated with event.
Can be one of the following values:
CL_COMMAND_NDRANGE_KERNEL
CL_COMMAND_NATIVE_KERNEL
CL_COMMAND_READ_BUFFER
CL_COMMAND_WRITE_BUFFER
CL_COMMAND_COPY_BUFFER
CL_COMMAND_READ_IMAGE
CL_COMMAND_WRITE_IMAGE
CL_COMMAND_COPY_IMAGE
CL_COMMAND_COPY_BUFFER_ TO_IMAGE
CL_COMMAND_COPY_IMAGE_ TO_BUFFER
CL_COMMAND_MAP_BUFFER
CL_COMMAND_MAP_IMAGE
CL_COMMAND_UNMAP_MEM_ OBJECT
CL_COMMAND_MARKER
CL_COMMAND_ACQUIRE_ GL_OBJECTS
CL_COMMAND_RELEASE_ GL_OBJECTS
CL_COMMAND_READ_ BUFFER_RECT
CL_COMMAND_WRITE_ BUFFER_RECT
CL_COMMAND_COPY_ BUFFER_RECT
CL_COMMAND_USER
CL_COMMAND_BARRIER
CL_COMMAND_MIGRATE_ MEM_OBJECTS
CL_COMMAND_FILL_BUFFER
CL_COMMAND_FILL_IMAGE
CL_COMMAND_SVM_FREE
CL_COMMAND_SVM_MEMCPY
CL_COMMAND_SVM_MEMFILL
CL_COMMAND_SVM_MAP
CL_COMMAND_SVM_UNMAP</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_EVENT_COMMAND_ EXECUTION_STATUS*<span class="footnote"><br>[The error code values are negative, and event state values are positive. The event state values are ordered from
the largest value (CL_QUEUED) for the first or initial state to the smallest value (CL_COMPLETE or negative
integer value) for the last or complete state. The value of CL_COMPLETE and CL_SUCCESS are the same.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_int</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the execution status of the command
identified by event.
Valid values are:
<br>
<br>
CL_QUEUED (command has been enqueued n the command-queue),
<br>
<br>
CL_SUBMITTED (enqueued command has
been submitted by the host to the device
associated with the command-queue),
<br>
<br>
CL_RUNNING (device is currently executing
this command),
<br>
<br>
CL_COMPLETE (the command has
completed), or
<br>
<br>
Error code given by a negative integer value.
(command was abnormally terminated – this
may be caused by a bad memory access etc.).
These error codes come from the same set of
error codes that are returned from the
platform or runtime API calls as return
values or errcode_ret values.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">*CL_EVENT_REFERENCE_ COUNT*<span class="footnote"><br>[The reference count returned should be considered immediately stale. It is unsuitable for general use in
applications. This feature is provided for identifying memory leaks.]<br></span>:</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Return the <em>event</em> reference
count.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>Using <strong>clGetEventInfo</strong> to determine if a command identified by <em>event</em>
has finished execution (i.e. CL_EVENT_COMMAND_EXECUTION_STATUS returns
CL_COMPLETE) is not a synchronization point. There are no guarantees
that the memory objects being modified by command associated with
<em>event</em> will be visible to other enqueued commands.</p></div>
<div class="paragraph"><p><strong>clGetEventInfo</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table 5.23</em>
and <em>param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
information to query given in <em>param_name</em> cannot be queried for
<em>event</em>.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT if
<em>event</em> is a not a valid event object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clSetEventCallback(cl_event event,
cl_int command_exec_callback_type,
void (CL_CALLBACK *pfn_event_notify)(
cl_event event,
cl_int event_command_exec_status,
void *user_data),
void *user_data)</pre>
</div></div>
<div class="paragraph"><p>registers a user callback function for a specific command execution
status. The registered callback function will be called when the
execution status of command associated with <em>event</em> changes to an
execution status equal to or past the status specified by
<em>command_exec_status</em>.</p></div>
<div class="paragraph"><p>Each call to <strong>clSetEventCallback</strong> registers the specified user callback
function on a callback stack associated with <em>event</em>. The order in
which the registered user callback functions are called is undefined.</p></div>
<div class="paragraph"><p><em>event</em> is a valid event object.</p></div>
<div class="paragraph"><p><em>command_exec_callback_type</em> specifies the command execution status for
which the callback is registered. The command execution callback
values for which a callback can be registered are: CL_SUBMITTED,
CL_RUNNING or CL_COMPLETE<span class="footnote"><br>[The callback function registered for a command_exec_callback_type value of CL_COMPLETE will be called
when the command has completed successfully or is abnormally terminated.]<br></span>:. There is no guarantee that
the callback functions registered for various execution status values
for an event will be called in the exact order that the execution status
of a command changes. Furthermore, it should be noted that receiving a
call back for an event with a status other than CL_COMPLETE, in no way
implies that the memory model or execution model as defined by the
OpenCL specification has changed. For example, it is not valid to assume
that a corresponding memory transfer has completed unless the event is
in a state CL_COMPLETE.</p></div>
<div class="paragraph"><p><em>pfn_event_notify</em> is the event callback function that can be registered
by the application. This callback function may be called asynchronously
by the OpenCL implementation. It is the applications responsibility to
ensure that the callback function is thread-safe. The parameters to
this callback function are:</p></div>
<div class="ulist"><ul>
<li>
<p>
      <em>event</em> is the event
object for which the callback function is invoked.
</p>
</li>
<li>
<p>
     <em>event_command_ _exec_status</em> is equal to the
<em>command_exec_callback_type</em> used while registering the callback. Refer
to table 5.23 for the command execution status values. If the callback
is called as the result of the command associated with event being
abnormally terminated, an appropriate error code for the error that
caused the termination will be passed to <em>event_command_exec_status</em>
instead.
</p>
</li>
<li>
<p>
      <em>user_data</em> is a pointer to user supplied data.
</p>
</li>
</ul></div>
<div class="paragraph"><p><em>user_data</em> will be passed as the <em>user_data</em> argument when <em>pfn_notify</em>
is called. <em>user_data</em> can be NULL.</p></div>
<div class="paragraph"><p>All callbacks registered for an event object must be called. All
enqueued callbacks shall be called before the event object is
destroyed. Callbacks must return promptly.   The behavior of calling
expensive system routines, OpenCL API calls to create contexts or
command-queues, or blocking OpenCL operations from the following list
below, in a callback is undefined.</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>clFinish</strong>
</p>
</li>
<li>
<p>
<strong>clWaitForEvents</strong>
</p>
</li>
<li>
<p>
blocking calls to <strong>clEnqueueReadBuffer</strong>, <strong>clEnqueueReadBufferRect</strong>,
</p>
</li>
<li>
<p>
<strong>clEnqueueWriteBuffer</strong>, <strong>clEnqueueWriteBufferRect</strong>,
</p>
</li>
<li>
<p>
blocking calls to <strong>clEnqueueReadImage</strong> and <strong>clEnqueueWriteImage</strong>,
</p>
</li>
<li>
<p>
blocking calls to <strong>clEnqueueMapBuffer</strong> and <strong>clEnqueueMapImage</strong>,
</p>
</li>
<li>
<p>
blocking calls to <strong>clBuildProgram</strong>, <strong>clCompileProgram</strong> or <strong>clLinkProgram</strong>,
</p>
</li>
<li>
<p>
blocking calls to <strong>clEnqueueSVMMemcpy</strong> or <strong>clEnqueueSVMMap</strong>
</p>
</li>
</ul></div>
<div class="paragraph"><p>If an application needs to wait for completion of a routine from the
above list in a callback, please use the non-blocking form of the
function, and assign a completion callback to it to do the remainder of
your work.  Note that when a callback (or other code) enqueues commands
to a command-queue, the commands are not required to begin execution
until the queue is flushed. In standard usage, blocking enqueue calls
serve this role by implicitly flushing the queue. Since blocking calls
are not permitted in callbacks, those callbacks that enqueue commands on
a command queue should either call <strong>clFlush</strong> on the queue before
returning or arrange for <strong>clFlush</strong> to be called later on another thread.</p></div>
<div class="paragraph"><p><strong>clSetEventCallback</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_EVENT if
<em>event</em> is not a valid event object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>pfn_event_notify</em> is NULL or if <em>command_exec_callback_type</em> is not
CL_SUBMITTED, CL_RUNNING or CL_COMPLETE.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clRetainEvent(cl_event event)</pre>
</div></div>
<div class="paragraph"><p>increments the <em>event</em> reference count. The OpenCL commands that return
an event perform an implicit retain.</p></div>
<div class="paragraph"><p><strong>clRetainEvent</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_EVENT if
<em>event</em> is not a valid event object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>To release an event, use the following function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clReleaseEvent(cl_event event)</pre>
</div></div>
<div class="paragraph"><p>decrements the <em>event</em> reference count.</p></div>
<div class="paragraph"><p><strong>clReleaseEvent</strong> returns CL_SUCCESS if the function is executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_EVENT if
<em>event</em> is not a valid event object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The event object is deleted once the reference count becomes zero, the
specific command identified by this event has completed (or terminated)
and there are no commands in the command-queues of a context that
require a wait for this event to complete. Using this function to
release a reference that was not obtained by creating the object or by
calling <strong>clRetainEvent</strong> causes undefined behavior.</p></div>
<div class="admonitionblock">
<table><tr>
<td class="icon">
<div class="title">Note</div>
</td>
<td class="content">Developers should be careful when releasing their last reference
count on events created by <strong>clCreateUserEvent</strong> that have not yet been
set to status of CL_COMPLETE or an error. If the user event was used in
the event_wait_list argument passed to a <strong>clEnqueue</strong> API or another
application host thread is waiting for it in <strong>clWaitForEvents</strong>, those
commands and host threads will continue to wait for the event status to
reach CL_COMPLETE or error, even after the application has released the
object. Since in this scenario the application has released its last
reference count to the user event, it would be in principle no longer
valid for the application to change the status of the event to unblock
all the other machinery. As a result the waiting tasks will wait
forever, and associated events, cl_mem objects, command queues and
contexts are likely to leak. In-order command queues caught up in this
deadlock may cease to do any work.</td>
</tr></table>
</div>
</div>
<div class="sect2">
<h3 id="_markers_barriers_and_waiting_for_events">5.12. Markers, Barriers and Waiting for Events</h3>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueMarkerWithWaitList(cl_command_queue command_queue,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a marker command which waits for either a list of events to
complete, or if the list is empty it waits for all commands previously
enqueued in <em>command_queue</em> to complete before it completes. This
command returns an <em>event</em> which can be waited on, i.e. this event can
be waited on to insure that all events either in the <em>event_wait_list</em>
or all previously enqueued commands, queued before this command to
<em>command_queue</em>, have completed.</p></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command-queue.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed.</p></div>
<div class="paragraph"><p>If <em>event_wait_list</em> is NULL, <em>num_events_in_wait_list</em> must be 0. If
<em>event_wait_list</em> is not NULL, the list of events pointed to by
<em>event_wait_list</em> must be valid and <em>num_events_in_wait_list</em> must be
greater than 0. The events specified in <em>event_wait_list</em> act as
synchronization points. The context associated with events in
<em>event_wait_list</em> and <em>command_queue</em> must be the same. The memory
associated with <em>event_wait_list</em> can be reused or freed after the
function returns.</p></div>
<div class="paragraph"><p>If <em>event_wait_list</em> is NULL, then this particular command waits until
all previous enqueued commands to <em>command_queue</em> have completed.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular
command. Event objects are unique and can be used to identify this
marker command later on. <em>event</em> can be NULL in which case it will not
be possible for the application to query the status of this command or
queue a wait for this command to complete. If the <em>event_wait_list</em> and
the <em>event</em> arguments are not NULL, the <em>event</em> argument should not
refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueMarkerWithWaitList</strong> returns CL_SUCCESS if the function is
successfully executed. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events. <br>
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clEnqueueBarrierWithWaitList(cl_command_queue command_queue,
cl_uint num_events_in_wait_list,
const cl_event *event_wait_list,
cl_event *event)</pre>
</div></div>
<div class="paragraph"><p>enqueues a barrier command which waits for either a list of events to
complete, or if the list is empty it waits for all commands previously
enqueued in <em>command_queue</em> to complete before it completes. This
command blocks command execution, that is, any following commands
enqueued after it do not execute until it completes. This command
returns an <em>event</em> which can be waited on, i.e. this event can be waited
on to insure that all events either in the <em>event_wait_list</em> or all
previously enqueued commands, queued before this command to
<em>command_queue</em>, have completed</p></div>
<div class="paragraph"><p><em>command_queue</em> is a valid host command-queue.</p></div>
<div class="paragraph"><p><em>event_wait_list</em> and <em>num_events_in_wait_list</em> specify events that need
to complete before this particular command can be executed.</p></div>
<div class="paragraph"><p>If <em>event_wait_list</em> is NULL, <em>num_events_in_wait_list</em> must be 0. If
<em>event_wait_list</em> is not NULL, the list of events pointed to by
<em>event_wait_list</em> must be valid and <em>num_events_in_wait_list</em> must be
greater than 0. The events specified in <em>event_wait_list</em> act as
synchronization points. The context associated with events in
<em>event_wait_list</em> and <em>command_queue</em> must be the same. The memory
associated with <em>event_wait_list</em> can be reused or freed after the
function returns.</p></div>
<div class="paragraph"><p>If <em>event_wait_list</em> is NULL, then this particular command waits until
all previous enqueued commands to <em>command_queue</em> have completed.</p></div>
<div class="paragraph"><p><em>event</em> returns an event object that identifies this particular
command. Event objects are unique and can be used to identify this
barrier command later on. <em>event</em> can be NULL in which case it will not
be possible for the application to query the status of this command or
queue a wait for this command to complete. If the <em>event_wait_list</em> and
the <em>event</em> arguments are not NULL, the <em>event</em> argument should not
refer to an element of the <em>event_wait_list</em> array.</p></div>
<div class="paragraph"><p><strong>clEnqueueBarrierWithWaitList</strong> returns CL_SUCCESS if the function is
successfully executed. Otherwise, it returns one of the following
errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_INVALID_CONTEXT if
context associated with <em>command_queue</em> and events in <em>event_wait_list</em>
are not the same.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT_WAIT_LIST
if <em>event_wait_list</em> is NULL and <em>num_events_in_wait_list</em> &gt; 0, or
<em>event_wait_list</em> is not NULL and <em>num_events_in_wait_list</em> is 0, or if
event objects in <em>event_wait_list</em> are not valid events.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect2">
<h3 id="_out_of_order_execution_of_kernels_and_memory_object_commands">5.13. Out-of-order Execution of Kernels and Memory Object Commands</h3>
<div class="paragraph"><p>The OpenCL functions that are submitted to a command-queue are enqueued
in the order the calls are made but can be configured to execute
in-order or out-of-order. The _properties_argument in
<strong>clCreateCommandQueueWithProperties</strong> can be used to specify the
execution order.</p></div>
<div class="paragraph"><p>If the CL_QUEUE_OUT_OF_ORDER_EXEC_MODE_ENABLE property of a
command-queue is not set, the commands enqueued to a command-queue
execute in order. For example, if an application calls
<strong>clEnqueueNDRangeKernel</strong> to execute kernel A followed by a
<strong>clEnqueueNDRangeKernel</strong> to execute kernel B, the application can assume
that kernel A finishes first and then kernel B is executed. If the
memory objects output by kernel A are inputs to kernel B then kernel B
will see the correct data in memory objects produced by execution of
kernel A. If the CL_QUEUE_OUT_OF_ORDER_EXEC_MODE_ENABLE property of a
command-queue is set, then there is no guarantee that kernel A will
finish before kernel B starts execution.</p></div>
<div class="paragraph"><p>Applications can configure the commands enqueued to a command-queue to
execute out-of-order by setting the
CL_QUEUE_OUT_OF_ORDER_EXEC_MODE_ENABLE property of the command-queue.
This can be specified when the command-queue is created. In
out-of-order execution mode there is no guarantee that the enqueued
commands will finish execution in the order they were queued. As there
is no guarantee that kernels will be executed in order, i.e. based on
when the <strong>clEnqueueNDRangeKernel</strong> calls are made within a
command-queue, it is therefore possible that an earlier
<strong>clEnqueueNDRangeKernel</strong> call to execute kernel A identified by event A
may execute and/or finish later than a <strong>clEnqueueNDRangeKernel</strong> call to
execute kernel B which was called by the application at a later point in
time. To guarantee a specific order of execution of kernels, a wait on
a particular event (in this case event A) can be used. The wait for
event A can be specified in the <em>event_wait_list</em> argument to
<strong>clEnqueueNDRangeKernel</strong> for kernel B.</p></div>
<div class="paragraph"><p>In addition, a marker (<strong>clEnqueueMarkerWithWaitList</strong>) or a barrier
(<strong>clEnqueueBarrierWithWaitList</strong>) command can be enqueued to the
command-queue. The marker command ensures that previously enqueued
commands identified by the list of events to wait for (or all previous
commands) have finished. A barrier command is similar to a marker
command, but additionally guarantees that no later-enqueued commands
will execute until the waited-for commands have executed.</p></div>
<div class="paragraph"><p>Similarly, commands to read, write, copy or map memory objects that are
enqueued after <strong>clEnqueueNDRangeKernel</strong> or <strong>clEnqueueNativeKernel</strong>
commands are not guaranteed to wait for kernels scheduled for execution
to have completed (if the CL_QUEUE_OUT_OF_ORDER_EXEC_MODE_ENABLE
property is set). To ensure correct ordering of commands, the event
object returned by <strong>clEnqueueNDRangeKernel</strong> or <strong>clEnqueueNativeKernel</strong>
can be used to enqueue a wait for event or a barrier command can be
enqueued that must complete before reads or writes to the memory
object(s) occur.</p></div>
</div>
<div class="sect2">
<h3 id="_profiling_operations_on_memory_objects_and_kernels">5.14. Profiling Operations on Memory Objects and Kernels</h3>
<div class="paragraph"><p>This section describes profiling of OpenCL functions that are enqueued
as commands to a command-queue. The specific
functions<span class="footnote"><br>[clEnqueueAcquireGLObjects and clEnqueueReleaseGLObjects defined in section 9.6.6 of the
OpenCL 2.0 Extension Specification are also included.]<br></span>: being referred to are:
<strong>clEnqueue{Read|Write|Map}Buffer, clEnqueue{Read|Write}BufferRect,
clEnqueue{Read|Write|Map}Image,
clEnqueueUnmapMemObject</strong>,<strong>clEnqueueSVMMemcpy</strong>, <strong>clEnqueueSVMMemFill</strong>,
<strong>clEnqueueSVMMap</strong>, <strong>clEnqueueSVMUnmap</strong>,
<strong>clEnqueueSVMFree</strong>,<strong>clEnqueueCopyBuffer, clEnqueueCopyBufferRect,
clEnqueueCopyImage, clEnqueueCopyImageToBuffer,
clEnqueueCopyBufferToImage,</strong> <strong>clEnqueueNDRangeKernel</strong> and
<strong>clEnqueueNativeKernel</strong>. These enqueued commands are identified by
unique event objects.</p></div>
<div class="paragraph"><p>Event objects can be used to capture profiling information that measure
execution time of a command. Profiling of OpenCL commands can be
enabled either by using a command-queue created with
CL_QUEUE_PROFILING_ENABLE flag set in _properties_argument to
<strong>clCreateCommandQueueWithProperties</strong>.</p></div>
<div class="paragraph"><p>If profiling is enabled, the function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clGetEventProfilingInfo(cl_event event,
cl_profiling_info param_name,
size_t param_value_size,
void *param_value,
size_t *param_value_size_ret)</pre>
</div></div>
<div class="paragraph"><p>returns profiling information for the command associated with event.</p></div>
<div class="paragraph"><p><em>event</em> specifies the event object.</p></div>
<div class="paragraph"><p><em>param_name</em> specifies the profiling data to query. The list of
supported <em>param_name</em> types and the information returned in
<em>param_value</em> by <strong>clGetEventProfilingInfo</strong> is described in <em>table 5.25</em></p></div>
<div class="paragraph"><p><em>param_value</em> is a pointer to memory where the appropriate result being
queried is returned. If <em>param_value</em> is NULL, it is ignored.</p></div>
<div class="paragraph"><p><em>param_value_size</em> is used to specify the size in bytes of memory
pointed to by <em>param_value</em>. This size must be &gt;= size of return type
as described in <em>table 5.25</em>.</p></div>
<div class="paragraph"><p><em>param_value_size_ret</em> returns the actual size in bytes of data being
queried by <em>param_name</em>. If <em>param_value_size_ret</em> is NULL, it is
ignored.</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<caption class="title">Table 31. <em>clGetEventProfilingInfo</em> <em>parameter queries.</em></caption>
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_profiling_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Info. returned in <em>param_value</em></strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROFILING_COMMAND_ QUEUED</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A 64-bit value that describes the
current device time counter in
nanoseconds when the command
identified by event is enqueued in a
command-queue by the host.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROFILING_COMMAND_ SUBMIT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A 64-bit value that describes the
current device time counter in
nanoseconds when the command
identified by event that has been
enqueued is submitted by the host to
the device associated with the
command-queue.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROFILING_COMMAND_ START</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A 64-bit value that describes the
current device time counter in
nanoseconds when the command
identified by event starts execution on
the device.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROFILING_COMMAND_ END</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A 64-bit value that describes the
current device time counter in
nanoseconds when the command
identified by event has finished
execution on the device.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_PROFILING_COMMAND_ COMPLETE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">A 64-bit value that describes the current device
time counter in nanoseconds when the command identified by event and any
child commands enqueued by this command on the device have finished
execution.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> 
The unsigned 64-bit values returned can be used to measure the time in
nano-seconds consumed by OpenCL commands.</p></div>
<div class="paragraph"><p>OpenCL devices are required to correctly track time across changes in
device frequency and power states. The
CL_DEVICE_PROFILING_TIMER_RESOLUTION specifies the resolution of the
timer i.e. the number of nanoseconds elapsed before the timer is
incremented.</p></div>
<div class="paragraph"><p><strong>clGetEventProfilingInfo</strong> returns CL_SUCCESS if the function is executed
successfully and the profiling information has been recorded.
Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
     CL_PROFILING_INFO_NOT_AVAILABLE if the CL_QUEUE_PROFILING_ENABLE flag is
not set for the command-queue, if the execution status of the command
identified by <em>event</em> is not CL_COMPLETE or if <em>event</em> refers to the
<strong>clEnqueueSVMFree</strong> command or is a user event object.
</p>
</li>
<li>
<p>
      CL_INVALID_VALUE if
<em>param_name</em> is not valid, or if size in bytes specified by
<em>param_value_size</em> is &lt; size of return type as described in <em>table 5.25</em>
and <em>param_value</em> is not NULL.
</p>
</li>
<li>
<p>
      CL_INVALID_EVENT if
<em>event</em> is a not a valid event object.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
<div class="sect2">
<h3 id="_flush_and_finish">5.15. Flush and Finish</h3>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clFlush(cl_command_queue command_queue)</pre>
</div></div>
<div class="paragraph"><p>issues all previously queued OpenCL commands in <em>command_queue_to the
device associated with_command_queue</em>. <strong>clFlush</strong> only guarantees that
all queued commands to <em>command_queue</em> will eventually be submitted to
the appropriate device. There is no guarantee that they will be
complete after <strong>clFlush</strong> returns.</p></div>
<div class="paragraph"><p><strong>clFlush</strong> returns CL_SUCCESS if the function call was executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
<div class="paragraph"><p>Any blocking commands queued in a command-queue and
<strong>clReleaseCommandQueue</strong> perform an implicit flush of the command-queue.
These blocking commands are <strong>clEnqueueReadBuffer</strong>,
<strong>clEnqueueReadBufferRect</strong>, <strong>clEnqueueReadImage</strong>, with <em>blocking_read</em>
set to CL_TRUE;
<strong>clEnqueueWriteBuffer</strong>,<strong>clEnqueueWriteBufferRect</strong>,<strong>clEnqueueWriteImage</strong>
with <em>blocking_write</em> set to CL_TRUE; <strong>clEnqueueMapBuffer</strong>,
<strong>clEnqueueMapImage</strong> with <em>blocking_map</em> set to CL_TRUE;
<strong>clEnqueueSVMMemcpy</strong> with <em>blocking_copy</em> set to CL_TRUE;
<strong>clEnqueueSVMMap</strong> with <em>blocking_map</em> set to CL_TRUE or
<strong>clWaitForEvents</strong>.</p></div>
<div class="paragraph"><p>To use event objects that refer to commands enqueued in a command-queue
as event objects to wait on by commands enqueued in a different
command-queue, the application must call a <strong>clFlush</strong> or any blocking
commands that perform an implicit flush of the command-queue where the
commands that refer to these event objects are enqueued.</p></div>
<div class="paragraph"><p>The function</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_int clFinish(cl_command_queue command_queue)</pre>
</div></div>
<div class="paragraph"><p>blocks until all previously queued OpenCL commands in <em>command_queue</em>
are issued to the associated device and have completed. <strong>clFinish</strong> does
not return until all previously queued commands in <em>command_queue</em> have
been processed and completed. <strong>clFinish</strong> is also a synchronization
point.</p></div>
<div class="paragraph"><p><strong>clFinish</strong> returns CL_SUCCESS if the function call was executed
successfully. Otherwise, it returns one of the following errors:</p></div>
<div class="ulist"><ul>
<li>
<p>
      CL_INVALID_COMMAND_QUEUE
if <em>command_queue</em> is not a valid host command-queue.
</p>
</li>
<li>
<p>
      CL_OUT_OF_RESOURCES if
there is a failure to allocate resources required by the OpenCL
implementation on the device.
</p>
</li>
<li>
<p>
      CL_OUT_OF_HOST_MEMORY if
there is a failure to allocate resources required by the OpenCL
implementation on the host.
</p>
</li>
</ul></div>
</div>
</div>
</div>
<div class="sect1">
<h2 id="_associated_opencl_specification">6. Associated OpenCL specification</h2>
<div class="sectionbody">
<div class="sect2">
<h3 id="_spir_v_intermediate_language">6.1. SPIR-V Intermediate language</h3>
<div class="paragraph"><p>The OpenCL 2.2 specification requires support for the SPIR-V
intermediate language that allows offline, or linked online, compilation
to a binary format that may be consumed by the <strong>clCreateProgramWithIL</strong>
interface.</p></div>
<div class="paragraph"><p>The OpenCL specification includes a specification for the SPIR-V 1.2
intermediate language as a cross-platform input language. In addition,
platform vendors may support their own IL if this is appropriate. The
OpenCL runtime will return a list of supported IL versions using the
<strong>CL_DEVICE_IL_VERSION</strong> parameter to the *clGetDeviceInfo*query.</p></div>
</div>
<div class="sect2">
<h3 id="_extensions_to_opencl">6.2. Extensions to OpenCL</h3>
<div class="paragraph"><p>In addition to the specification of core features, OpenCL provides a
number of extensions to the API, kernel language or intermediate
representation. These features are defined in the OpenCL 2.2 extensions
specification document.</p></div>
<div class="paragraph"><p>Extensions defined against earlier versions of the OpenCL
specifications, whether the API or language specification, are defined
in the matching versions of the extension specification document.</p></div>
</div>
<div class="sect2">
<h3 id="_support_for_earlier_opencl_c_kernel_languages">6.3. Support for earlier OpenCL C kernel languages</h3>
<div class="paragraph"><p>The OpenCL C kernel language is not defined in the OpenCL 2.2
specification. New language features are described in the OpenCL C++
specification as well as the SPIR-V 1.2 specification and in kernel
languages that target it. A kernel language defined by any of the OpenCL
1.0, OpenCL 1.1, OpenCL 1.2 and OpenCL 2.0 kernel language
specifications as well as kernels language extensions defined by the
matching versions of OpenCL extension specifications are valid to pass
to <strong>clCreateProgramWithSource</strong> executing against an OpenCL 2.2 runtime.</p></div>
</div>
</div>
</div>
<div class="sect1">
<h2 id="_opencl_embedded_profile">7. OpenCL Embedded Profile</h2>
<div class="sectionbody">
<div class="paragraph"><p>The OpenCL 2.2specification describes the feature requirements for
desktop platforms. This section describes the OpenCL 2.2embedded
profile that allows us to target a subset of the OpenCL 2.2specification
for handheld and embedded platforms. The optional extensions defined in
the OpenCL 2.2Extension Specification apply to both profiles.</p></div>
<div class="paragraph"><p>The OpenCL 2.2 embedded profile has the following restrictions:</p></div>
<div class="olist arabic"><ol class="arabic">
<li>
<p>
64 bit integers i.e. long, ulong including the appropriate vector
data types and operations on 64-bit integers are optional. The
*cles_khr_int64<span class="footnote"><br>[Note that the performance of 64-bit integer arithmetic
can vary significantly between embedded devices.]<br></span>: extension string will be reported
if the embedded profile implementation supports 64-bit integers.
</p>
</li>
<li>
<p>
[line-through] Support for 3D images is optional.
</p>
</li>
<li>
<p>
If [line-through] <strong>CL_DEVICE_IMAGE3D_MAX_WIDTH</strong>, [line-through] <strong>CL_DEVICE_IMAGE3D_MAX_HEIGHT</strong>
and [line-through] <strong>CL_DEVICE_IMAGE3D_MAX_DEPTH</strong> are zero, the call to
<strong>clCreateImage</strong> in the embedded profile will fail to create the 3D
image. The <em>errcode_ret</em> argument in <strong>clCreateImage</strong>
returns [line-through] CL_INVALID_OPERATION. Declaring arguments of
type*[line-through]*image3d_t in a kernel will result in a compilation
error.
</p>
</li>
</ol></div>
<div class="paragraph"><p>If
[line-through] <strong>CL_DEVICE_IMAGE3D_MAX_WIDTH</strong>, [line-through] <strong>CL_DEVICE_IMAGE3D_HEIGHT</strong> and
[line-through] CL_DEVICE_IMAGE3D_MAX_DEPTH &gt; 0, 3D images are supported by the OpenCL embedded profile implementation.
[line-through] <strong>clCreateImage</strong> will work as defined by the OpenCL specification. The
[line-through] image3d_t data type can be used in a kernel(s).</p></div>
<div class="olist arabic"><ol class="arabic">
<li>
<p>
[line-through] Support for 2D image array writes is optional. If the <strong>cles_khr_2d_image_array_writes</strong> extension is supported by the
[line-through] embedded profile, writes to 2D image arrays are supported.
</p>
</li>
<li>
<p>
[line-through] Image and image arrays created with an
[line-through] image_channel_data_type value of
[line-through] CL_FLOAT or
[line-through] CL_HALF_FLOAT can only be used with samplers that use a filter mode of
[line-through] CL_FILTER_NEAREST. The values returned by <strong>read_imagef</strong> and *read_imageh*<span class="footnote"><br>[If cl_khr_fp16 extension is supported.]<br></span>: for 2D and 3D images if
[line-through] image_channel_data_type value is
[line-through] CL_FLOAT or
[line-through] CL_HALF_FLOAT and sampler with
[line-through] filter_mode =CL_FILTER_LINEAR are undefined.
</p>
</li>
<li>
<p>
The mandated minimum single precision floating-point capability
given by CL_DEVICE_SINGLE_FP_CONFIG is CL_FP_ROUND_TO_ZERO or
CL_FP_ROUND_TO_NEAREST. If CL_FP_ROUND_TO_NEAREST is supported, the
default rounding mode will be round to nearest even; otherwise the
default rounding mode will be round to zero. <br>
</p>
</li>
<li>
<p>
The single precision floating-point operations (addition,
subtraction and multiplication) shall be correctly rounded. Zero
results may always be positive 0.0. The accuracy of division and sqrt
are given in the SPIR-V OpenCL environment specification.
</p>
</li>
</ol></div>
<div class="paragraph"><p>If CL_FP_INF_NAN is not set in CL_DEVICE_SINGLE_FP_CONFIG, and one of
the operands or the result of addition, subtraction, multiplication or
division would signal the overflow or invalid exception (see IEEE 754
specification), the value of the result is implementation-defined.
Likewise, single precision comparison operators (&lt;, &gt;, &#8656;, &gt;=, ==, !=)
return implementation-defined values when one or more operands is a
NaN.</p></div>
<div class="paragraph"><p>In all cases, conversions (see the SPIR-V OpenCL environment
specification) shall be correctly rounded as described for the
FULL_PROFILE, including those that consume or produce an INF or NaN.
The built-in math functions shall behave as described for the
FULL_PROFILE, including edge case behavior but with slightly different
accuracy rules. Edge case behavior and accuracy rules are described in
the SPIR-V OpenCL environment specification. <br></p></div>
<div class="dlist"><dl>
<dt class="hdlist1">
NOTE
</dt>
<dd>
<p>
If addition, subtraction and multiplication have default round
to zero rounding mode, then <strong>fract</strong>, <strong>fma</strong> and <strong>fdim</strong> shall produce the
correctly rounded result for round to zero rounding mode.
</p>
</dd>
</dl></div>
<div class="paragraph"><p>This relaxation of the requirement to adhere to IEEE 754 requirements
for basic floating-point operations, though extremely undesirable, is to
provide flexibility for embedded devices that have lot stricter
requirements on hardware area budgets.</p></div>
<div class="olist arabic"><ol class="arabic">
<li>
<p>
Denormalized numbers for the half data type which may be generated
when converting a float to a half using variants of the <strong>vstore_half</strong>
function or when converting from a half to a float using variants of the
<strong>vload_half</strong> function can be flushed to zero. The SPIR-V environment
specification for details.
</p>
</li>
<li>
<p>
The precision of conversions from CL_UNORM_INT8, CL_SNORM_INT8,
CL_UNORM_INT16, CL_SNORM_INT16, CL_UNORM_INT_101010 and
CL_UNORM_INT_101010_2 to float is &#8656; 2 ulp for the embedded profile
instead of &#8656; 1.5 ulp as defined in the full profile. The exception
cases described in the full profile and given below apply to the
embedded profile.
</p>
</li>
</ol></div>
<div class="paragraph"><p>For CL_UNORM_INT8</p></div>
<div class="ulist"><ul>
<li>
<p>
0 must convert to 0.0f and
</p>
</li>
<li>
<p>
255 must convert to 1.0f
</p>
</li>
</ul></div>
<div class="paragraph"><p>For CL_UNORM_INT16</p></div>
<div class="ulist"><ul>
<li>
<p>
0 must convert to 0.0f and
</p>
</li>
<li>
<p>
65535 must convert to 1.0f
</p>
</li>
</ul></div>
<div class="paragraph"><p>For CL_SNORM_INT8</p></div>
<div class="ulist"><ul>
<li>
<p>
-128 and -127 must convert to -1.0f,
</p>
</li>
<li>
<p>
0 must convert to 0.0f and
</p>
</li>
<li>
<p>
127 must convert to 1.0f
</p>
</li>
</ul></div>
<div class="paragraph"><p>For CL_SNORM_INT16</p></div>
<div class="ulist"><ul>
<li>
<p>
-32768 and -32767 must convert to -1.0f,
</p>
</li>
<li>
<p>
0 must convert to 0.0f and
</p>
</li>
<li>
<p>
32767 must convert to 1.0f
</p>
</li>
</ul></div>
<div class="paragraph"><p>For CL_UNORM_INT_101010</p></div>
<div class="ulist"><ul>
<li>
<p>
0 must convert to 0.0f and
</p>
</li>
<li>
<p>
1023 must convert to 1.0f
</p>
</li>
</ul></div>
<div class="paragraph"><p>For CL_UNORM_INT_101010_2</p></div>
<div class="ulist"><ul>
<li>
<p>
0 must convert to 0.0f and
</p>
</li>
<li>
<p>
1023 must convert to 1.0f (for RGB)
</p>
</li>
<li>
<p>
3 must convert to 1.0f (for A)
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following optional extensions defined in the OpenCL 2.2 Extension
Specification are available to the embedded profile:</p></div>
<div class="paragraph"><p><strong>cl_khr_int64_base_atomics</strong></p></div>
<div class="paragraph"><p><strong>cl_khr_int64_extended_atomics</strong></p></div>
<div class="paragraph"><p><strong>cl_khr_fp16</strong></p></div>
<div class="paragraph"><p><strong>cles_khr_int64</strong>.</p></div>
<div class="paragraph"><p>If double precision is supported i.e. CL_DEVICE_DOUBLE_FP_CONFIG is not
zero, then cles_khr_int64 must also be supported.</p></div>
<div class="paragraph"><p>CL_PLATFORM_PROFILE defined in <em>table 4.1</em> will return the string
EMBEDDED_PROFILE if the OpenCL implementation supports the embedded
profile only.</p></div>
<div class="paragraph"><p>The minimum maximum values specified in <em>table 4.3</em> that have been
modified for the OpenCL embedded profile are listed below:</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:34%;">
<col style="width:33%;">
<col style="width:33%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>cl_device_info</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Return Type</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>Description</strong></p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_MAX_READ_ IMAGE_ARGS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of image objects
arguments of a kernel declared with the read_only qualifier. The
minimum value is 8 if CL_DEVICE_IMAGE_SUPPORT is CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_MAX_WRITE_ IMAGE_ARGS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of image objects
arguments of a kernel declared with the write_only qualifier. The
minimum value is 8 if CL_DEVICE_IMAGE_SUPPORT is CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_MAX_READ_ WRITE_IMAGE_ARGS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of image
objects arguments of a kernel declared with the write_only or read_write
qualifier. The minimum value is 8 if CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_IMAGE2D_ MAX_WIDTH</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max width of 2D image in
pixels. The minimum value is 2048 if CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_IMAGE2D_ MAX_HEIGHT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max height of 2D image in
pixels. The minimum value is 2048 if CL_DEVICE_IMAGE_SUPPORT is CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_IMAGE3D_ MAX_WIDTH</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max width of 3D image in
pixels. The minimum value is 2048 if CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_IMAGE3D_ MAX_HEIGHT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max height of 3D image in
pixels. The minimum value is 2048.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_IMAGE3D_ MAX_DEPTH</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max depth of 3D image in pixels.
The minimum value is 2048.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_IMAGE_ MAX_BUFFER_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of pixels for a 1D image
created from a buffer object.
<br>
<br>
The minimum value is 2048 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_IMAGE_ MAX_ARRAY_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of images in a 1D or 2D
image array.
<br>
<br>
The minimum value is 256 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_MAX_SAMPLERS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum number of samplers that
can be used in a kernel.
<br>
<br>
The minimum value is 8 if
CL_DEVICE_IMAGE_SUPPORT is
CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_MAX_ PARAMETER_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max size in bytes of all
arguments that can be passed to a kernel. The minimum value is 256
bytes for devices that are not of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_SINGLE_ FP_CONFIG</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_device_<br>
fp_config</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Describes single precision floatingpoint capability of the device. This is
a bit-field that describes one or more
of the following values:
<br>
<br>
CL_FP_DENORM – denorms are supported
<br>
<br>
CL_FP_INF_NAN – INF and quiet NaNs are
supported.
<br>
<br>
CL_FP_ROUND_TO_NEAREST– round to
nearest even rounding mode supported
<br>
<br>
CL_FP_ROUND_TO_ZERO – round to zero
rounding mode supported
<br>
<br>
CL_FP_ROUND_TO_INF – round to positive
and negative infinity rounding modes
supported
<br>
<br>
CL_FP_FMA – IEEE754-2008 fused
multiply-add is supported.
<br>
<br>
CL_FP_CORRECTLY_ ROUNDED_DIVIDE
_SQRT – divide and sqrt are correctly
rounded as defined by the IEEE754
specification.
<br>
<br>
CL_FP_SOFT_FLOAT – Basic floatingpoint operations (such as addition, subtraction,
multiplication) are implemented in software.
<br>
<br>
The mandated minimum floating-point
capability is:
CL_FP_ROUND_TO_ZERO or
CL_FP_ROUND_TO_NEAREST
for devices that are not of type
CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_MAX_CONSTANT_ BUFFER_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max size in bytes
of a constant buffer allocation. The minimum value is 1 KB for devices
that are not of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_MAX_CONSTANT_ ARGS</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Max number of arguments
declared with the __constant qualifier in a kernel. The minimum value
is 4 for devices that are not of type CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_LOCAL_MEM_ SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_ulong</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Size of local memory arena in
bytes. The minimum value is 1 KB for devices that are not of type
CL_DEVICE_TYPE_CUSTOM.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_COMPILER_ AVAILABLE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_FALSE if the implementation
does not have a compiler available to
compile the program source.
<br>
<br>
Is CL_TRUE if the compiler is
available.
This can be CL_FALSE for the
embedded platform profile only.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_LINKER_ AVAILABLE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_bool</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Is CL_FALSE if the implementation
does not have a linker available.
Is CL_TRUE if the linker is available.
<br>
<br>
This can be CL_FALSE for the
embedded platform profile only.
<br>
<br>
This must be CL_TRUE if
CL_DEVICE_COMPILER_ AVAILABLE is CL_TRUE.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_QUEUE_ON_ DEVICE_MAX_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">cl_uint</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">The max. size of the
device queue in bytes. The minimum value is 64 KB for the embedded
profile</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DEVICE_PRINTF_ BUFFER_SIZE</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">size_t</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum size in bytes of the
internal buffer that holds the output of printf calls from a kernel.
The minimum value for the EMBEDDED profile is 1 KB.</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>If CL_DEVICE_IMAGE_SUPPORT specified in <em>table 4.3</em> is CL_TRUE, the
values assigned to CL_DEVICE_MAX_READ_IMAGE_ARGS,
CL_DEVICE_MAX_WRITE_IMAGE_ARGS, CL_DEVICE_IMAGE2D_MAX_WIDTH,
CL_DEVICE_IMAGE2D_MAX_HEIGHT, CL_DEVICE_IMAGE3D_MAX_WIDTH,
CL_DEVICE_IMAGE3D_MAX_HEIGHT, CL_DEVICE_IMAGE3D_MAX_DEPTH and
CL_DEVICE_MAX_SAMPLERS by the implementation must be greater than or
equal to the minimum values specified in the embedded profile version of
<em>table 4.3</em> given above.</p></div>
</div>
</div>
<div class="sect1">
<h2 id="_appendix_a">8. Appendix A</h2>
<div class="sectionbody">
<div class="sect2">
<h3 id="_a_1_shared_opencl_objects">8.1. A.1 Shared OpenCL Objects</h3>
<div class="paragraph"><p>This section describes which objects can be shared across multiple
command-queues created within a host process.</p></div>
<div class="paragraph"><p>OpenCL memory objects, program objects and kernel objects are created
using a context and can be shared across multiple command-queues created
using the same context. Event objects can be created when a command is
queued to a command-queue. These event objects can be shared across
multiple command-queues created using the same context.</p></div>
<div class="paragraph"><p>The application needs to implement appropriate synchronization across
threads on the host processor to ensure that the changes to the state of
a shared object (such as a command-queue object, memory object, program
or kernel object) happen in the correct order (deemed correct by the
application) when multiple command-queues in multiple threads are making
changes to the state of a shared object.</p></div>
<div class="paragraph"><p>A command-queue can cache changes to the state of a memory object on the
device associated with the command-queue. To synchronize changes to a
memory object across command-queues, the application must do the
following:</p></div>
<div class="paragraph"><p>In the command-queue that includes commands that modify the state of a
memory object, the application must do the following:</p></div>
<div class="ulist"><ul>
<li>
<p>
Get appropriate event objects for commands that modify the state of the shared memory object.
</p>
</li>
<li>
<p>
Call the <strong>clFlush</strong> (or <strong>clFinish</strong>) API to issue any outstanding commands from this command-queue.
 
</p>
</li>
</ul></div>
<div class="paragraph"><p>In the command-queue that wants to synchronize to the latest state of a
memory object, commands queued by the application must use the
appropriate event objects that represent commands that modify the state
of the shared memory object as event objects to wait on. This is to
ensure that commands that use this shared memory object complete in the
previous command-queue before the memory objects are used by commands
executing in this command-queue.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The results of modifying a shared resource in one command-queue while it
is being used by another command-queue are undefined.
 </p></div>
</div>
<div class="sect2">
<h3 id="_a_2_multiple_host_threads">8.2. A.2 Multiple Host Threads</h3>
<div class="paragraph"><p>All OpenCL API calls are thread-safe<span class="footnote"><br>[Please refer to the OpenCL glossary
for the OpenCL definition of thread -safe. This definition may be different
from usage of the term in other contexts.]<br></span>: except those that
modify the state of cl_kernel objects: <strong>clSetKernelArg,
clSetKernelArgSVMPointer, clSetKernelExecInfo*and *clCloneKernel</strong>.
<strong>clSetKernelArg</strong> , <strong>clSetKernelArgSVMPointer</strong>, <strong>clSetKernelExecInfo</strong>
and <strong>clCloneKernel*are safe to call from any host thread, and safe to
call re-entrantly so long as concurrent calls to any combination of
these API calls operate on different cl_kernel objects. The state of
the cl_kernel object is undefined if *clSetKernelArg</strong>,
<strong>clSetKernelArgSVMPointer</strong>, <strong>clSetKernelExecInfo</strong> or *clCloneKernel*are
called from multiple host threads on the same cl_kernel object at the
same time<span class="footnote"><br>[There is an inherent race condition in the design of OpenCL that occurs between setting a kernel argument and
using the kernel with clEnqueueNDRangeKernel. Another host thread might change the kernel arguments between
when a host thread sets the kernel arguments and then enqueues the kernel, causing the wrong kernel arguments to
be enqueued. Rather than attempt to share cl_kernel objects among multiple host threads, applications are strongly
encouraged to make additional cl_kernel objects for kernel functions for each host thread.]<br></span>:. Please note that there are additional
limitations as to which OpenCL APIs may be called from OpenCL callback
functions&#8201;&#8212;&#8201;please see <em>section 5.11</em>.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The behavior of OpenCL APIs called from an interrupt or signal handler
is implementation-defined</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The OpenCL implementation should be able to create multiple
command-queues for a given OpenCL context and multiple OpenCL contexts
in an application running on the host processor.</p></div>
</div>
</div>
</div>
<div class="sect1">
<h2 id="_appendix_b_portability">9. Appendix B Portability</h2>
<div class="sectionbody">
<div class="paragraph"><p>OpenCL is designed to be portable to other architectures and hardware
designs. OpenCL has used at its core a C99 based programming language
and follows rules based on that heritage. Floating-point arithmetic is
based on the <strong>IEEE-754</strong> and <strong>IEEE-754-2008</strong> standards. The memory
objects, pointer qualifiers and weakly ordered memory are designed to
provide maximum compatibility with discrete memory architectures
implemented by OpenCL devices.   Command-queues and barriers allow for
synchronization between the host and OpenCL devices. The design,
capabilities and limitations of OpenCL are very much a reflection of the
capabilities of underlying hardware. </p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Unfortunately, there are a number of areas where idiosyncrasies of one
hardware platform may allow it to do some things that do not work on
another. By virtue of the rich operating system resident on the CPU, on
some implementations the kernels executing on a CPU may be able to call
out to system services whereas the same calls on the GPU will likely
fail for now. Since there is some advantage to having these services
available for debugging purposes, implementations can use the OpenCL
extension mechanism to implement these services.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Likewise, the heterogeneity of computing architectures might mean that a
particular loop construct might execute at an acceptable speed on the
CPU but very poorly on a GPU, for example. CPUs are designed in general
to work well on latency sensitive algorithms on single threaded tasks,
whereas common GPUs may encounter extremely long latencies, potentially
orders of magnitude worse. A developer interested in writing portable
code may find that it is necessary to test his design on a diversity of
hardware designs to make sure that key algorithms are structured in a
way that works well on a diversity of hardware.  We suggest favoring
more work-items over fewer. It is anticipated that over the coming
months and years experience will produce a set of best practices that
will help foster a uniformly favorable experience on a diversity of
computing devices.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Of somewhat more concern is the topic of endianness. Since a majority
of devices supported by the initial implementation of OpenCL are
little-endian, developers need to make sure that their kernels are
tested on both big-endian and little-endian devices to ensure source
compatibility with OpenCL devices now and in the future. The endian
attribute qualifier is supported by the SPIR-V IL to allow developers to
specify whether the data uses the endianness of the host or the OpenCL
device. This allows the OpenCL compiler to do appropriate
endian-conversion on load and store operations from or to this data.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>We also describe how endianness can leak into an implementation causing
kernels to produce unintended results:</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>When a big-endian vector machine (e.g. AltiVec, CELL SPE) loads a
vector, the order of the data is retained. That is both the order of
the bytes within each element and the order of the elements in the
vector are the same as in memory.  When a little-endian vector machine
(e.g. SSE) loads a vector, the order of the data in register (where all
the work is done) is reversed. *Both* the order of the bytes within
each element and the order of the elements with respect to one another
in the vector are reversed. </p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Memory:</p></div>
<div class="paragraph"><p>uint4 a =</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x00010203</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x04050607</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x08090A0B</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0C0D0E0F</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>In register (big-endian):</p></div>
<div class="paragraph"><p>uint4 a =</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x00010203</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x04050607</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x08090A0B</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0C0D0E0F</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In register (little-endian):</p></div>
<div class="paragraph"><p>uint4 a =</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0F0E0D0C</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0B0A0908</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x07060504</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x03020100</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>This allows little-endian machines to use a single vector load to load
little-endian data, regardless of how large each piece of data is in the
vector. That is the transformation is equally valid whether that vector
was a uchar16 or a ulong2.  Of course, as is well known, little-endian
machines actually<span class="footnote"><br>[Note that we are talking about the programming model here. In reality, little endian systems might choose to
simply address their bytes from "the right" or reverse the "order" of the bits in the byte. Either of these choices
would mean that no big swap would need to occur in hardware.]<br></span>: store their data in reverse byte
order to compensate for the little-endian storage format of the array
elements:</p></div>
<div class="paragraph"><p>Memory (big-endian):</p></div>
<div class="paragraph"><p>uint4 a =</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x00010203</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x04050607</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x08090A0B</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0C0D0E0F</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p>Memory (little-endian):</p></div>
<div class="paragraph"><p>uint4 a =</p></div>
<div class="paragraph"><p> </p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x03020100</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x07060504</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0B0A0908</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0F0E0D0C</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Once that data is loaded into a vector, we end up with this:</p></div>
<div class="paragraph"><p>In register (big-endian):</p></div>
<div class="paragraph"><p>uint4 a =  </p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x00010203</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x04050607</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x08090A0B</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0C0D0E0F</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In register (little-endian):</p></div>
<div class="paragraph"><p>uint4 a =</p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<col style="width:25%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x0C0D0E0F</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x08090A0B</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x04050607</p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">0x00010203</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>That is, in the process of correcting the endianness of the bytes within
each element, the machine ends up reversing the order that the elements
appear in the vector with respect to each other within the vector.
0x00010203 appears at the left of the big-endian vector and at the
right of the little-endian vector.</p></div>
<div class="paragraph"><p>When the host and device have different endianness, the developer must
ensure that kernel argument values are processed correctly. The
implementation may or may not automatically convert endianness of kernel
arguments. Developers should consult vendor documentation for guidance
on how to handle kernel arguments in these situations.</p></div>
<div class="paragraph"><p>OpenCL provides a consistent programming model across architectures by
numbering elements according to their order in memory. Concepts such as
even/odd and high/low follow accordingly.  Once the data is loaded into
registers, we find that element 0 is at the left of the big-endian
vector and element 0 is at the right of the little-endian vector:</p></div>
<div class="paragraph"><p> </p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>float x[4];
float4 v = vload4( 0, x );</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Big-endian:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>v contains { x[0], x[1], x[2], x[3] }</pre>
</div></div>
<div class="paragraph"><p>Little-endian:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>v contains { x[3], x[2], x[1], x[0] }</pre>
</div></div>
<div class="paragraph"><p>The compiler is aware that this swap occurs and references elements
accordingly. So long as we refer to them by a numeric index such as
.s0123456789abcdef or by descriptors such as .xyzw, .hi, .lo, .even and
.odd, everything works transparently. Any ordering reversal is undone
when the data is stored back to memory. The developer should be able to
work with a big endian programming model and ignore the element ordering
problem in the vector &#8230; for most problems. This mechanism relies on
the fact that we can rely on a consistent element numbering. Once we
change numbering system, for example by conversion-free casting (using
as_type_n_) a vector to another vector of the same size but a different
number of elements, then we get different results on different
implementations depending on whether the system is big- endian, or
little-endian or indeed has no vector unit at all. (Thus, the behavior
of bitcasts to vectors of different numbers of elements is
implementation-defined, see section 1.2.4 of OpenCL 2.0C specification)</p></div>
<div class="paragraph"><p>An example follows:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>float x[4] = { 0.0f, 1.0f, 2.0f, 3.0f };
float4 v = vload4( 0, x );
uint4 y = as_uint4(v); legal, portable 
ushort8 z = as_ushort8(v); legal, not portable  
element size changed</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Big-endian:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>v contains { 0.0f, 1.0f, 2.0f, 3.0f }</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>y contains { 0x00000000, 0x3f800000, 0x40000000, 0x40400000 }</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>z contains { 0x0000, 0x0000, *0x3f80*, 0x0000, 0x4000, 0x0000, 0x4040, 0x0000 }</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>z.z is 0x3f80</pre>
</div></div>
<div class="paragraph"><p>Little-endian:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>v contains { 3.0f, 2.0f, 1.0f, 0.0f }</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>y contains { 0x40400000, 0x40000000, 0x3f800000, 0x00000000 }</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>z contains { 0x4040, 0x0000, 0x4000, 0x0000, 0x3f80, *0x0000*, 0x0000, 0x0000 }</pre>
</div></div>
<div class="listingblock">
<div class="content monospaced">
<pre>z.z is 0</pre>
</div></div>
<div class="paragraph"><p>Here, the value in z.z is not the same between big- and little-endian
vector machines </p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>OpenCL could have made it illegal to do a conversion free cast that
changes the number of elements in the name of portability. However,
while OpenCL provides a common set of operators drawing from the set
that are typically found on vector machines, it can not provide access
to everything every ISA may offer in a consistent uniform portable
manner. Many vector ISAs provide special purpose instructions that
greatly accelerate specific operations such as DCT, SAD, or 3D
geometry. It is not intended for OpenCL to be so heavy handed that
time-critical performance sensitive algorithms can not be written by
knowledgeable developers to perform at near peak performance. Developers
willing to throw away portability should be able to use the
platform-specific instructions in their code. For this reason, OpenCL is
designed to allow traditional vector C language programming extensions,
such as the AltiVec C Programming Interface or the Intel C programming
interfaces (such as those found in emmintrin.h) to be used directly in
OpenCL with OpenCL data types as an extension to OpenCL.  As these
interfaces rely on the ability to do conversion-free casts that change
the number of elements in the vector to function properly, OpenCL allows
them too. </p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>As a general rule, any operation that operates on vector types in
segments that are not the same size as the vector element size may break
on other hardware with different endianness or different vector
architecture.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Examples might include:</p></div>
<div class="ulist"><ul>
<li>
<p>
Combining two uchar8&#8217;s containing high and low bytes of a ushort, to make a ushort8 using
.even and .odd operators  (please use <strong>upsample()</strong> for this)
</p>
</li>
<li>
<p>
Any bitcast that changes
the number of elements in the vector. (Operations on the new type are
non-portable.)
</p>
</li>
</ul></div>
<div class="paragraph"><p>* Swizzle operations that
change the order of data using chunk sizes that are not the same as the
element size</p></div>
<div class="paragraph"><p>Examples of operations that are portable:</p></div>
<div class="ulist"><ul>
<li>
<p>
Combining two uint8&#8217;s to
make a uchar16 using .even and .odd operators. For example to
interleave left and right audio streams.
</p>
</li>
<li>
<p>
Any bitcast that does not
change the number of elements (e.g.  (float4) unit4&#8201;&#8212;&#8201;we define the
storage format for floating-point types)
</p>
</li>
<li>
<p>
Swizzle operations that
swizzle elements of the same size as the elements of the vector.
</p>
</li>
</ul></div>
<div class="paragraph"><p>OpenCL has made some additions to C to make application behavior more
dependable than C. Most notably in a few cases OpenCL defines the
behavior of some operations that are undefined in C99:</p></div>
<div class="ulist"><ul>
<li>
<p>
OpenCL provides convert_
operators for conversion between all types. C99 does not define what
happens when a floating-point type is converted to integer type and the
floating-point value lies outside the representable range of the integer
type after rounding. When the <em>sat variant of the conversion is used,
the float shall be converted to the nearest representable integer value.
 Similarly, OpenCL also makes recommendations about what should happen
with NaN. Hardware manufacturers that provide the saturated conversion
in hardware may use the saturated conversion hardware for both the
saturated and non-saturated versions of the OpenCL convert</em> operator.
OpenCL does not define what happens for the non-saturated conversions
when floating-point operands are outside the range representable
integers after rounding.
</p>
</li>
<li>
<p>
The format of half, float,
and double types is defined to be the binary16, binary32 and binary64
formats in the draft IEEE-754 standard. (The latter two are identical to
the existing IEEE-754 standard.) You may depend on the positioning and
meaning of the bits in these types.
</p>
</li>
<li>
<p>
OpenCL defines behavior
for oversized shift values. Shift operations that shift greater than or
equal to the number of bits in the first operand reduce the shift value
modulo the number of bits in the element. For example,  if we shift an
int4 left by 33 bits, OpenCL treats this as shift left by 33%32 = 1 bit.
</p>
</li>
<li>
<p>
A number of edge cases for
math library functions are more rigorously defined than in C99. Please
see _section 3.5_of the OpenCL 2.0 C specification.
</p>
</li>
</ul></div>
<div class="paragraph"><p> </p></div>
</div>
</div>
<div class="sect1">
<h2 id="_appendix_c_application_data_types">10. Appendix C Application Data Types</h2>
<div class="sectionbody">
<div class="paragraph"><p>This section documents the provided host application types and constant
definitions. The documented material describes the commonly defined
data structures, types and constant values available to all platforms
and architectures. The addition of these details demonstrates our
commitment to maintaining a portable programming environment and
potentially deters changes to the supplied headers.</p></div>
<div class="sect2">
<h3 id="_c_1_shared_application_scalar_data_types">10.1. C.1 Shared Application Scalar Data Types</h3>
<div class="paragraph"><p>The following application scalar types are provided for application
convenience.</p></div>
<div class="paragraph"><p>cl_char</p></div>
<div class="paragraph"><p>cl_uchar</p></div>
<div class="paragraph"><p>cl_short</p></div>
<div class="paragraph"><p>cl_ushort</p></div>
<div class="paragraph"><p>cl_int</p></div>
<div class="paragraph"><p>cl_uint</p></div>
<div class="paragraph"><p>cl_long</p></div>
<div class="paragraph"><p>cl_ulong</p></div>
<div class="paragraph"><p>cl_half</p></div>
<div class="paragraph"><p>cl_float</p></div>
<div class="paragraph"><p>cl_double</p></div>
<div class="paragraph"><p> </p></div>
</div>
<div class="sect2">
<h3 id="_c_2_supported_application_vector_data_types">10.2. C.2 Supported Application Vector Data Types</h3>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Application vector types are unions used to create vectors of the above
application scalar types. The following application vector types are
provided for application convenience.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>cl_char_n_</p></div>
<div class="paragraph"><p>cl_uchar_n_</p></div>
<div class="paragraph"><p>cl_short_n_</p></div>
<div class="paragraph"><p>cl_ushort_n_</p></div>
<div class="paragraph"><p>cl_int_n_</p></div>
<div class="paragraph"><p>cl_uint_n_</p></div>
<div class="paragraph"><p>cl_long_n_</p></div>
<div class="paragraph"><p>cl_ulong_n_</p></div>
<div class="paragraph"><p>cl_half_n_</p></div>
<div class="paragraph"><p>cl_float_n_</p></div>
<div class="paragraph"><p>cl_double_n_</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p><em>n</em> can be 2, 3, 4, 8 or 16.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The application scalar and vector data types are defined in the
<strong>cl_platform.h</strong> header file.</p></div>
<div class="paragraph"><p> </p></div>
</div>
<div class="sect2">
<h3 id="_c_3_alignment_of_application_data_types">10.3. C.3 Alignment of Application Data Types</h3>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The user is responsible for ensuring that pointers passed into and out
of OpenCL kernels are natively aligned relative to the data type of the
parameter as defined in the kernel language and SPIR-V specifications.  
This implies that OpenCL buffers created with CL_MEM_USE_HOST_PTR need
to provide an appropriately aligned host memory pointer that is aligned
to the data types used to access these buffers in a kernel(s), that SVM
allocations must correctly align and that pointers into SVM allocations
must also be correctly aligned. The user is also responsible for
ensuring image data passed is aligned to the granularity of the data
representing a single pixel (e.g. image_num_channels *
sizeof(image_channel_data_type)) except for CL_RGB and CL_RGBx images
where the data must be aligned to the granularity of a single channel in
a pixel (i.e. sizeof(image_channel_data_type)). This implies that OpenCL
images created with CL_MEM_USE_HOST_PTR must align correctly. The image
alignment value can be queried using the
CL_DEVICE_IMAGE_BASE_ADDRESS_ALIGNMENT query. In addition,</p></div>
<div class="paragraph"><p>source pointers for clEnqueueWriteImage and other operations that copy
to the OpenCL runtime, as well as destination pointers for
clEnqueueReadImage and other operations that copy from the OpenCL
runtime must follow the same alignment rules.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>OpenCL makes no requirement about the alignment of OpenCL application
defined data types outside of buffers and images, except that the
underlying vector primitives (e.g. <em>_cl_float4) where defined shall be
directly accessible as such using appropriate named fields in the
cl_type union (see _section C.5</em>). Nevertheless, it is recommended that
the <strong>cl_platform.h</strong> header should attempt to naturally align OpenCL
defined application data types (e.g. cl_float4) according to their type.</p></div>
</div>
<div class="sect2">
<h3 id="_c_4_vector_literals">10.4. C.4 Vector Literals</h3>
<div class="paragraph"><p>Application vector literals may be used in assignments of individual
vector components. Literal usage follows the convention of the
underlying application compiler.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>cl_float2 foo = { .s[1] = 2.0f };
cl_int8 bar = {{ 2, 4, 6, 8, 10, 12, 14, 16 }};</pre>
</div></div>
</div>
<div class="sect2">
<h3 id="_c_5_vector_components">10.5. C.5 Vector Components</h3>
<div class="paragraph"><p>The components of application vector types can be addressed using the
&lt;vector_name&gt;.s[&lt;index&gt;] notation.</p></div>
<div class="paragraph"><p>For example:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>foo.s[0] = 1.0f; // Sets the 1st vector component of foo
pos.s[6] = 2; // Sets the 7th vector component of bar</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In some cases vector components may also be accessed using the following
notations. These notations are not guaranteed to be supported on all
implementations, so their use should be accompanied by a check of the
corresponding preprocessor symbol.</p></div>
<div class="paragraph"><p> </p></div>
<div class="sect3">
<h4 id="_c_5_1_named_vector_components_notation">10.5.1. C.5.1 Named vector components notation</h4>
<div class="paragraph"><p>Vector data type components may be accessed using the .sN, .sn or .xyzw
field naming convention, similar to how they are used within the OpenCL
language. Use of the .xyzw field naming convention only allows
accessing of the first 4 component fields. Support of these notations
is identified by the CL_HAS_NAMED_VECTOR_FIELDS preprocessor symbol.
For example:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>#ifdef CL_HAS_NAMED_VECTOR_FIELDS
cl_float4 foo;
cl_int16 bar;
foo.x = 1.0f; // Set first component
foo.s0 = 1.0f; // Same as above
bar.z = 3; // Set third component
bar.se = 11; // Same as bar.s[0xe]
bar.sD = 12; // Same as bar.s[0xd]
#endif</pre>
</div></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Unlike the OpenCL language type usage of named vector fields, only one
component field may be accessed at a time. This restriction prevents
the ability to swizzle or replicate components as is possible with the
OpenCL language types. Attempting to access beyond the number of
components for a type also results in a failure.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>foo.xy // illegal - illegal field name combination
bar.s1234 // illegal - illegal field name combination
foo.s7 // illegal - no component s7</pre>
</div></div>
<div class="paragraph"><p> </p></div>
</div>
<div class="sect3">
<h4 id="_c_5_2_high_low_vector_component_notation">10.5.2. C.5.2 High/Low vector component notation</h4>
<div class="paragraph"><p>Vector data type components may be accessed using the .hi and .lo
notation similar to that supported within the language types. Support
of this notation is identified by the CL_HAS_HI_LO_VECTOR_FIELDS
preprocessor symbol. For example:</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>#ifdef CL_HAS_HI_LO_VECTOR_FIELDS
cl_float4 foo;
cl_float2 new_hi = 2.0f, new_lo = 4.0f;
foo.hi = new_hi;
foo.lo = new_lo;
#endif</pre>
</div></div>
</div>
<div class="sect3">
<h4 id="_c_5_3_native_vector_type_notation">10.5.3. C.5.3 Native vector type notation</h4>
<div class="paragraph"><p>Certain native vector types are defined for providing a mapping of
vector types to architecturally builtin vector types. Unlike the above
described application vector types, these native types are supported on
a limited basis depending on the supporting architecture and compiler.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>These types are not unions, but rather convenience mappings to the
underlying architectures' builtin vector types. The native types share
the name of their application counterparts but are preceded by a double
underscore "__".</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>For example, <em>cl_float4 is the native builtin vector type equivalent of
the cl_float4 application vector type. The </em>cl_float4 type may provide
direct access to the architectural builtin __m128 or vector float type,
whereas the cl_float4 is treated as a union.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In addition, the above described application data types may have native
vector data type members for access convenience. The native components
are accessed using the .vN sub-vector notation, where N is the number of
elements in the sub-vector. In cases where the native type is a subset
of a larger type (more components), the notation becomes an index based
array of the sub-vector type.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Support of the native vector types is identified by a <em>CL_TYPEN</em>
preprocessor symbol matching the native type name. For example:</p></div>
<div class="paragraph"><p> </p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>#ifdef __CL_FLOAT4__ // Check for native cl_float4 type
cl_float8 foo;
__cl_float4 bar; // Use of native type
bar = foo.v4[1]; // Access the second native float4 vector
#endif</pre>
</div></div>
<div class="paragraph"><p> </p></div>
</div>
</div>
<div class="sect2">
<h3 id="_c_6_implicit_conversions">10.6. C.6 Implicit Conversions</h3>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Implicit conversions between application vector types are not supported.</p></div>
<div class="paragraph"><p> </p></div>
</div>
<div class="sect2">
<h3 id="_c_7_explicit_casts">10.7. C.7 Explicit Casts</h3>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>Explicit casting of application vector types (cl_typen) is not
supported. Explicit casting of native vector types (__cl_typen) is
defined by the external compiler.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p> </p></div>
</div>
<div class="sect2">
<h3 id="_c_8_other_operators_and_functions">10.8. C.8 Other operators and functions</h3>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The behavior of standard operators and function on both application
vector types (cl_typen) and native vector types (__cl_typen) is defined
by the external compiler.</p></div>
<div class="paragraph"><p> </p></div>
</div>
<div class="sect2">
<h3 id="_c_9_application_constant_definitions">10.9. C.9 Application constant definitions</h3>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>In addition to the above application type definitions, the following
literal defintions are also available.</p></div>
<div class="paragraph"><p> </p></div>
<table class="tableblock frame-all grid-all"
style="
width:100%;
">
<col style="width:50%;">
<col style="width:50%;">
<tbody>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CHAR_BIT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Bit width of a character</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SCHAR_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_char</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SCHAR_MIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum value of a type cl_char</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CHAR_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_char</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_CHAR_MIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum value of a type cl_char</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UCHAR_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_uchar</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SHORT_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_short</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_SHORT_MIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum value of a type cl_short</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_USHORT_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_ushort</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_INT_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_int</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_INT_MIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum value of a type cl_int</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_UINT_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_uint</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_LONG_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_long</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_LONG_MIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum value of a type cl_long</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_ULONG_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of a type cl_ulong</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock"> </p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_DIAG</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Number of decimal digits of precision for the type
cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_MANT_DIG</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Number of digits in the mantissa of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_MAX_10_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum positive integer such that 10 raised to
this power minus one can be represented as a normalized floating-point
number of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_MAX_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum exponent value of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_MIN_10_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum negative integer such that 10 raised to
this power minus one can be represented as a normalized floating-point
number of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_MIN_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum exponent value of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_RADIX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Base value of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_MIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum value of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_FLT_EPSILON</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum positive floating-point number of type
cl_float such that 1.0 + CL_FLT_EPSILON != 1 is true.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_DIG</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Number of decimal digits of precision for the type
cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_MANT_DIG</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Number of digits in the mantissa of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_MAX_10_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum positive integer such that 10 raised to
this power minus one can be represented as a normalized floating-point
number of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_MAX_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum exponent value of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_MIN_10_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum negative integer such that 10 raised to
this power minus one can be represented as a normalized floating-point
number of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_MIN_EXP</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum exponent value of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_RADIX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Base value of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_MAX</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_MIN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum value of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_DBL_EPSILON</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Minimum positive floating-point number of type
cl_double such that 1.0 + CL_DBL_EPSILON != 1 is true.</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_NAN</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Macro expanding to a value representing NaN</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_HUGE_VALF</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Largest representative value of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_HUGE_VAL</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Largest representative value of type cl_double</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_MAXFLOAT</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Maximum value of type cl_float</p></td>
</tr>
<tr>
<td class="tableblock halign-left valign-top" ><p class="tableblock"><strong>CL_INFINITY</strong></p></td>
<td class="tableblock halign-left valign-top" ><p class="tableblock">Macro expanding to a value represnting infinity</p></td>
</tr>
</tbody>
</table>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>These literal definitions are defined in the <strong>cl_platform.h</strong> header.</p></div>
<div class="paragraph"><p> </p></div>
</div>
</div>
</div>
<div class="sect1">
<h2 id="_appendix_d_cl_mem_copy_overlap">11. Appendix D CL_MEM_COPY_OVERLAP</h2>
<div class="sectionbody">
<div class="paragraph"><p>The following code describes how to determine if there is overlap
between the source and destination rectangles specified to
<strong>clEnqueueCopyBufferRect</strong> provided the source and destination buffers
refer to the same buffer object.</p></div>
<div class="listingblock">
<div class="content monospaced">
<pre>unsigned int
check_copy_overlap(const size_t src_origin[],
const size_t dst_origin[],
const size_t region[],
const size_t row_pitch,
const size_t slice_pitch )
{
const size_t slice_size = (region[1] - 1) * row_pitch + region[0];
const size_t block_size = (region[2] - 1) * slice_pitch + slice_size;
const size_t src_start = src_origin[2] * slice_pitch +
src_origin[1] * row_pitch +
src_origin[0];
const size_t src_end = src_start + block_size;
const size_t dst_start = dst_origin[2] * slice_pitch
+ dst_origin[1] * row_pitch
+ dst_origin[0];
F const size_t dst_end = dst_start + block_size;
/* No overlap if dst ends before src starts or if src ends
* before dst starts.
*/
if( (dst_end &lt;= src_start) || (src_end &lt;= dst_start) ){
return 0;
}
/* No overlap if region[0] for dst or src fits in the gap
* between region[0] and row_pitch.
*/
{
const size_t src_dx = src_origin[0] % row_pitch;
const size_t dst_dx = dst_origin[0] % row_pitch;
if( ((dst_dx &gt;= src_dx + region[0]) &amp;&amp;
(dst_dx + region[0] &lt;= src_dx + row_pitch)) ||
((src_dx &gt;= dst_dx + region[0]) &amp;&amp;
(src_dx + region[0] &lt;= dst_dx + row_pitch)) )
{
return 0;
}
}
 
/* No overlap if region[1] for dst or src fits in the gap
* between region[1] and slice_pitch.
*/
{
const size_t src_dy =
(src_origin[1] * row_pitch + src_origin[0]) % slice_pitch;
const size_t dst_dy =
(dst_origin[1] * row_pitch + dst_origin[0]) % slice_pitch;
if( ((dst_dy &gt;= src_dy + slice_size) &amp;&amp;
(dst_dy + slice_size &lt;= src_dy + slice_pitch)) ||
((src_dy &gt;= dst_dy + slice_size) &amp;&amp;
(src_dy + slice_size &lt;= dst_dy + slice_pitch)) ) {
return 0;
}
}
 
/* Otherwise src and dst overlap. */
return 1;
}</pre>
</div></div>
</div>
</div>
<div class="sect1">
<h2 id="_appendix_e_changes">12. Appendix E Changes</h2>
<div class="sectionbody">
<div class="sect2">
<h3 id="_e_1_summary_of_changes_from_opencl_1_0">12.1. E.1 Summary of changes from OpenCL 1.0</h3>
<div class="paragraph"><p>The following features are added to the OpenCL 1.1 platform layer and
runtime (<em>sections 4 and 5</em>):</p></div>
<div class="ulist"><ul>
<li>
<p>
Following queries to <em>table 4.3</em>
</p>
</li>
</ul></div>
<div class="paragraph"><p>o   CL_DEVICE_NATIVE_VECTOR_WIDTH_{CHAR | SHORT | INT | LONG | FLOAT |
DOUBLE | HALF}</p></div>
<div class="paragraph"><p>o   CL_DEVICE_HOST_UNIFIED_MEMORY</p></div>
<div class="paragraph"><p>o   CL_DEVICE_OPENCL_C_VERSION</p></div>
<div class="ulist"><ul>
<li>
<p>
CL_CONTEXT_NUM_DEVICES to
the list of queries specified to <strong>clGetContextInfo</strong>.
</p>
</li>
<li>
<p>
Optional image formats: CL_Rx, CL_RGx and CL_RGBx.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong> Support for sub-buffer objects ability to create a buffer object that refers to a specific
region in another buffer object using *clCreateSubBuffer</strong>.</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>clEnqueueReadBufferRect</strong>, <strong>clEnqueueWriteBufferRect</strong> and <strong>clEnqueueCopyBufferRect</strong> APIs to read
from, write to and copy a rectangular region of a buffer object
respectively.
</p>
</li>
<li>
<p>
<strong>clSetMemObjectDestructorCallback</strong> API to allow a user to register a
callback function that will be called when the memory object is deleted
and its resources freed.
</p>
</li>
<li>
<p>
Options that control the
OpenCL C version used when building a program executable. These are
described in <em>section 5.8.4.5</em>.
</p>
</li>
<li>
<p>
CL_KERNEL_PREFERRED_WORK_GROUP_SIZE_MULTIPLE to the list of queries
specified to <strong>clGetKernelWorkGroupInfo</strong>.
</p>
</li>
<li>
<p>
Support for user events.
User events allow applications to enqueue commands that wait on a user
event to finish before the command is executed by the device. Following
new APIs are added*- clCreateUserEvent*and <strong>clSetUserEventStatus</strong>.
</p>
</li>
<li>
<p>
<strong>clSetEventCallback</strong> API to register a callback function for a specific command execution status.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following modifications are made to the OpenCL 1.1 platform layer
and runtime (<em>sections 4 and 5</em>):</p></div>
<div class="ulist"><ul>
<li>
<p>
Following queries in <em>table 4.3</em>
</p>
</li>
</ul></div>
<div class="paragraph"><p>o   CL_DEVICE_MAX_PARAMETER_SIZE from 256 to 1024 bytes</p></div>
<div class="paragraph"><p>o   CL_DEVICE_LOCAL_MEM_SIZE from 16 KB to 32 KB.</p></div>
<div class="ulist"><ul>
<li>
<p>
The <em>global_work_offset</em> argument in <strong>clEnqueueNDRangeKernel</strong> can be a non-NULL value.
</p>
</li>
<li>
<p>
All API calls except <strong>clSetKernelArg</strong> are thread-safe.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following features are added to the OpenCL C programming language
(<em>section 6</em>) in OpenCL 1.1:</p></div>
<div class="ulist"><ul>
<li>
<p>
3-component vector data types.
</p>
</li>
<li>
<p>
New built-in functions
</p>
</li>
</ul></div>
<div class="paragraph"><p>o   <strong>get_global_offset</strong> work-item function defined in section <em>6.12.1</em>.</p></div>
<div class="paragraph"><p>o   <strong>minmag</strong>, <strong>maxmag</strong> math functions defined in section <em>6.12.2</em>.</p></div>
<div class="paragraph"><p>o   <strong>clamp</strong> integer function defined in <em>section 6.12.3</em>.</p></div>
<div class="paragraph"><p>o   (vector, scalar) variant of integer functions <strong>min</strong> and <strong>max</strong> in
<em>section 6.12.3</em>.</p></div>
<div class="paragraph"><p>o   <strong>async_work_group_strided_copy</strong> defined in section <em>6.12.10</em>.</p></div>
<div class="paragraph"><p>o   <strong>vec_step</strong>, <strong>shuffle</strong> and <strong>shuffle2</strong> defined in section <em>6.12.12</em>.</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>cl_khr_byte_addressable_store</strong> extension is a core feature.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>     *cl_khr_global_int32_base_atomics</strong>,
<strong>cl_khr_global_int32_extended_atomics</strong>,
<strong>cl_khr_local_int32_base_atomics</strong> and
<strong>cl_khr_local_int32_extended_atomics*extensions are core features. The
built-in atomic function names are changed to use the *atomic_</strong> prefix
instead of <strong>atom_</strong>.</p></div>
<div class="ulist"><ul>
<li>
<p>
Macros CL_VERSION_1_0 and CL_VERSION_1_1.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following features in OpenCL 1.0 are deprecated (see glossary) in
OpenCL 1.1:</p></div>
<div class="ulist"><ul>
<li>
<p>
The <strong>clSetCommandQueueProperty</strong> API is no longer supported in OpenCL 1.1.
</p>
</li>
<li>
<p>
The <em>ROUNDING_MODE</em> macro is no longer supported in OpenCL C 1.1.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong>      The cl-strict-aliasing
option that can be specified in <em>options</em> argument to *clBuildProgram</strong>
is no longer supported in OpenCL 1.1.</p></div>
<div class="paragraph"><p>The following new extensions are added to <em>section 9</em> in OpenCL 1.1:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>cl_khr_gl_event</strong> for creating a CL event object from a GL sync object.
</p>
</li>
<li>
<p>
<strong>cl_khr_d3d10_sharing</strong> for sharing memory objects with Direct3D 10.
 
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following modifications are made to the OpenCL ES Profile described
in <em>section 10</em> in OpenCL 1.1:</p></div>
<div class="ulist"><ul>
<li>
<p>
64-bit integer support is optional.
</p>
</li>
</ul></div>
</div>
<div class="sect2">
<h3 id="_e_2_summary_of_changes_from_opencl_1_1">12.2. E.2 Summary of changes from OpenCL 1.1</h3>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p>The following features are added to the OpenCL 1.2 platform layer and
runtime (<em>sections 4 and 5</em>):</p></div>
<div class="ulist"><ul>
<li>
<p>
Custom devices and built-in kernels are supported.
</p>
</li>
<li>
<p>
Device partitioning that
allows a device to be partitioned based on a number of partitioning
schemes supported by the device.
</p>
</li>
</ul></div>
<div class="paragraph"><p>* Extend <em>cl_mem_flags</em> to
describe how the host accesses the data in a cl_mem object.</p></div>
<div class="paragraph"><p><strong> *clEnqueueFillBuffer</strong> and
<strong>clEnqueueFillImage</strong> to support filling a buffer with a pattern or an
image with a color.</p></div>
<div class="ulist"><ul>
<li>
<p>
Add
CL_MAP_WRITE_INVALIDATE_REGION to <em>cl_map_flags</em>. Appropriate
clarification to the behavior of CL_MAP_WRITE has been added to the
spec.
</p>
</li>
<li>
<p>
New image types: 1D image,
1D image from a buffer object, 1D image array and 2D image arrays.
</p>
</li>
<li>
<p>
<strong>clCreateImage</strong> to create
an image object.
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong> *clEnqueueMigrateMemObjects</strong> API that allows a developer to have
explicit control over the location of memory objects or to migrate a
memory object from one device to another.</p></div>
<div class="paragraph"><p>* Support separate compilation and linking of programs.</p></div>
<div class="ulist"><ul>
<li>
<p>
Additional queries to get
the number of kernels and kernel names in a program have been added to
<strong>clGetProgramInfo</strong>.
</p>
</li>
<li>
<p>
Additiional queries to get
the compile and link status and options have been added to
<strong>clGetProgramBuildInfo</strong>.
</p>
</li>
<li>
<p>
<strong>clGetKernelArgInfo</strong> API
that returns information about the arguments of a kernel.
</p>
</li>
<li>
<p>
<strong>clEnqueueMarkerWithWaitList</strong> and <strong>clEnqueueBarrierWithWaitList</strong> APIs.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following features are added to the OpenCL C programming language
(<em>section 6</em>) in OpenCL 1.2:</p></div>
<div class="ulist"><ul>
<li>
<p>
Double-precision is now an optional core feature instead of an extension.
</p>
</li>
<li>
<p>
New built in image types: <strong>image1d_t</strong> , <strong>image1d_array_t</strong> and <strong>image2d_array_t</strong> .
</p>
</li>
<li>
<p>
New built-in functions
</p>
</li>
</ul></div>
<div class="paragraph"><p>o   Functions to read from and write to a 1D image, 1D and 2D image
arrays described in <em>sections 6.12.14.2</em>, <em>6.12.14.3</em> and <em>6.12.14.4</em>.</p></div>
<div class="paragraph"><p>o   Sampler-less image read functions described in <em>section 6.12.14.3</em>.</p></div>
<div class="paragraph"><p>o   <strong>popcount</strong> integer function described in <em>section 6.12.3</em>.</p></div>
<div class="paragraph"><p>o   <strong>printf</strong> function described in <em>section 6.12.13</em>.</p></div>
<div class="ulist"><ul>
<li>
<p>
Storage class specifiers extern and static as described in <em>section 6.8</em>.
</p>
</li>
<li>
<p>
Macros CL_VERSION_1_2 and <em>OPENCL_C_VERSION</em>.
 
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following APIs in OpenCL 1.1 are deprecated (see glossary) in OpenCL
1.2:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>clEnqueueMarker</strong>, <strong>clEnqueueBarrier</strong> and <strong>clEnqueueWaitForEvents</strong>
</p>
</li>
<li>
<p>
<strong>clCreateImage2D</strong> and <strong>clCreateImage3D</strong>
</p>
</li>
<li>
<p>
<strong>clUnloadCompiler*and*clGetExtensionFunctionAddress</strong>
</p>
</li>
</ul></div>
<div class="paragraph"><p><strong> *clCreateFromGLTexture2D</strong> and <strong>clCreateFromGLTexture3D</strong>
 </p></div>
<div class="paragraph"><p>The following queries are deprecated (see glossary) in OpenCL 1.2:</p></div>
<div class="paragraph"><p><strong> *CL_DEVICE_MIN_DATA_TYPE_ALIGN_SIZE</strong> in <em>table 4.3</em> queried using <strong>clGetDeviceInfo</strong>.</p></div>
<div class="paragraph"><p> </p></div>
</div>
<div class="sect2">
<h3 id="_e_3_summary_of_changes_from_opencl_1_2">12.3. E.3 Summary of changes from OpenCL 1.2</h3>
<div class="paragraph"><p>The following features are added to the OpenCL 2.0 platform layer and
runtime (<em>sections 4 and 5</em>):</p></div>
<div class="ulist"><ul>
<li>
<p>
Shared virtual memory.
</p>
</li>
<li>
<p>
Device queues used to enqueue kernels on the device.
</p>
</li>
<li>
<p>
Pipes.
</p>
</li>
<li>
<p>
Images support for 2D image from buffer, depth images and sRGB images.
 
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following modifications are made to the OpenCL 2.0 platform layer
and runtime (sections 4 and 5):
<strong>      All API calls except
*clSetKernelArg</strong>, <strong>clSetKernelArgSVMPointer</strong> and <strong>clSetKernelExecInfo</strong>
are thread-safe.
 </p></div>
<div class="paragraph"><p>The following features are added to the OpenCL C programming language
(<em>section 6</em>) in OpenCL 2.0:</p></div>
<div class="ulist"><ul>
<li>
<p>
Clang Blocks.
</p>
</li>
<li>
<p>
Kernels enqueing kernels to a device queue.
</p>
</li>
<li>
<p>
Program scope variables in global address space.
</p>
</li>
<li>
<p>
Generic address space.
</p>
</li>
<li>
<p>
C1x atomics.
</p>
</li>
<li>
<p>
New built-in functions (sections 6.13.9, 6.13.11, 6.13.15 and 6.14).
</p>
</li>
<li>
<p>
Support images with the read_write qualifier.
</p>
</li>
<li>
<p>
3D image writes are a core feature.
</p>
</li>
<li>
<p>
The CL_VERSION_2_0 macro.
 
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following APIs are deprecated (see glossary) in OpenCL 2.0:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>clCreateCommandQueue</strong> , <strong>clCreateSampler</strong> and <strong>clEnqueueTask</strong>
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following queries are deprecated (see glossary) in OpenCL 2.0:</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>CL_DEVICE_HOST_UNIFIED_MEMORY</strong> in <em>table 4.3</em> queried using
<strong>clGetDeviceInfo</strong>.
</p>
</li>
<li>
<p>
<strong>CL_IMAGE_BUFFER</strong> in <em>table 5.10</em> is deprecated.
</p>
</li>
<li>
<p>
<strong>CL_DEVICE_QUEUE_PROPERTIES*is replaced by *CL_DEVICE_QUEUE_ON_HOST_PROPERTIES</strong>.
</p>
</li>
<li>
<p>
The explicit memory fence functions defined in section 6.12.9 of the OpenCL 1.2 specification.
</p>
</li>
<li>
<p>
The OpenCL 1.2 atomic built-in functions for 32-bit integer and floating-point data types
defined in section 6.12.11 of the OpenCL 1.2 specification.
</p>
</li>
</ul></div>
</div>
<div class="sect2">
<h3 id="_e_4_summary_of_changes_from_opencl_2_0">12.4. E.4 Summary of changes from OpenCL 2.0</h3>
<div class="paragraph"><p>The following features are added to the OpenCL 2.1 platform layer and
runtime (<em>sections 4 and 5</em>):</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>clGetKernelSubGroupInfo</strong> API call.
</p>
</li>
<li>
<p>
<strong>CL_KERNEL_MAX_NUM_SUB_GROUPS</strong>, <strong>CL_KERNEL_COMPILE_NUM_SUB_GROUPS</strong> additions to table 5.21 of the API specification.
</p>
</li>
<li>
<p>
<strong>clCreateProgramWithIL</strong> API call.
</p>
</li>
<li>
<p>
<strong>clGetHostTimer</strong> and <strong>clGetDeviceAndHostTimer</strong> API calls.
</p>
</li>
<li>
<p>
<strong>clEnqueueSVMMigrateMem</strong> API call.
</p>
</li>
<li>
<p>
<strong>clCloneKernel</strong> API call.
</p>
</li>
<li>
<p>
<strong>clSetDefaultDeviceCommandQueue</strong> API call.
</p>
</li>
<li>
<p>
<strong>CL_PLATFORM_HOST_TIMER_RESOLUTION</strong> added to table 4.1 of the API specification.
</p>
</li>
<li>
<p>
<strong>CL_DEVICE_IL_VERSION</strong>, <strong>CL_DEVICE_MAX_NUM_SUB_GROUPS</strong>, <strong>CL_DEVICE_SUB_GROUP_INDEPENDENT_FORWARD_PROGRESS</strong> added
to table 4.3 of the API specification.
</p>
</li>
<li>
<p>
*CL_PROGRAM_IL*to table 5.17 of the API specification.
</p>
</li>
<li>
<p>
<strong>CL_QUEUE_DEVICE_DEFAULT</strong> added to table 5.2 of the API specification.
</p>
</li>
<li>
<p>
Added table 5.22 to the API specification with the enums: <strong>CL_KERNEL_MAX_SUB_GROUP_SIZE_FOR_NDRANGE</strong> ,
<strong>CL_KERNEL_SUB_GROUP_COUNT_FOR_NDRANGE</strong> and <strong>CL_KERNEL_LOCAL_SIZE_FOR_SUB_GROUP_COUNT</strong>
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following modifications are made to the OpenCL 2.1 platform layer
and runtime (sections 4 and 5):</p></div>
<div class="ulist"><ul>
<li>
<p>
All API calls except <strong>clSetKernelArg</strong> , <strong>clSetKernelArgSVMPointer</strong> , <strong>clSetKernelExecInfo</strong> and
*clCloneKernel*are thread-safe.
</p>
</li>
</ul></div>
<div class="paragraph"><p>The OpenCL C kernel language is no longer chapter 6. The OpenCL C kernel
language is not updated for OpenCL 2.1. The OpenCL 2.0 kernel language
will still be consumed by OpenCL 2.1 runtimes.</p></div>
<div class="paragraph"><p>The SPIR-V IL specification has been added.</p></div>
</div>
<div class="sect2">
<h3 id="_e_5_summary_of_changes_from_opencl_2_1">12.5. E.5 Summary of changes from OpenCL 2.1</h3>
<div class="paragraph"><p>The following changes have been made to the OpenCL 2.2 execution model
(section 3)</p></div>
<div class="ulist"><ul>
<li>
<p>
Added the third prerequisite (executing non-trivial constructors for program scope global variables).
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following features are added to the OpenCL 2.2 platform layer and
runtime (<em>sections 4 and 5</em>):</p></div>
<div class="ulist"><ul>
<li>
<p>
<strong>clSetProgramSpecializationConstant</strong> API call
</p>
</li>
<li>
<p>
<strong>clSetProgramReleaseCallback</strong> API call
</p>
</li>
<li>
<p>
Queries for CL_PROGRAM_SCOPE_GLOBAL_CTORS_PRESENT, CL_PROGRAM_SCOPE_GLOBAL_DTORS_PRESENT
</p>
</li>
</ul></div>
<div class="paragraph"><p>The following modifications are made to the OpenCL 2.2 platform layer
and runtime (section 4 and 5):</p></div>
<div class="ulist"><ul>
<li>
<p>
Modified description of CL_DEVICE_MAX_CLOCK_FREQUENCY query.
</p>
</li>
<li>
<p>
Added a new error code CL_MAX_SIZE_RESTRICTION_EXCEEDED to <strong>clSetKernelArg</strong> API call
</p>
</li>
</ul></div>
<div class="paragraph"><p>Added definition of Deprecation and Specialization constants to the
glossary.</p></div>
<div class="paragraph"><p> </p></div>
<div class="paragraph"><p> </p></div>
</div>
</div>
</div>
</div>
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