src/gpu/vk/GrVkResourceProvider.h - skia - Git at Google

 /*
 * Copyright 2016 Google Inc.
 *
 * Use of this source code is governed by a BSD-style license that can be
 * found in the LICENSE file.
 */

 #ifndef GrVkResourceProvider_DEFINED
 #define GrVkResourceProvider_DEFINED

 #include "include/gpu/vk/GrVkTypes.h"
 #include "include/private/SkTArray.h"
 #include "src/core/SkLRUCache.h"
 #include "src/core/SkTDynamicHash.h"
 #include "src/core/SkTInternalLList.h"
 #include "src/gpu/GrResourceHandle.h"
 #include "src/gpu/vk/GrVkDescriptorPool.h"
 #include "src/gpu/vk/GrVkDescriptorSetManager.h"
 #include "src/gpu/vk/GrVkPipelineStateBuilder.h"
 #include "src/gpu/vk/GrVkRenderPass.h"
 #include "src/gpu/vk/GrVkResource.h"
 #include "src/gpu/vk/GrVkSampler.h"
 #include "src/gpu/vk/GrVkSamplerYcbcrConversion.h"
 #include "src/gpu/vk/GrVkUtil.h"

 #include <mutex>
 #include <thread>

 class GrVkCommandPool;
 class GrVkGpu;
 class GrVkPipeline;
 class GrVkPipelineState;
 class GrVkPrimaryCommandBuffer;
 class GrVkRenderTarget;
 class GrVkSecondaryCommandBuffer;
 class GrVkUniformHandler;

 class GrVkResourceProvider {
 public:
     GrVkResourceProvider(GrVkGpu* gpu);
     ~GrVkResourceProvider();

     // Set up any initial vk objects
     void init();

     GrVkPipeline* createPipeline(const GrProgramInfo&,
                                  const GrStencilSettings& stencil,
                                  VkPipelineShaderStageCreateInfo* shaderStageInfo,
                                  int shaderStageCount,
                                  GrPrimitiveType primitiveType,
                                  VkRenderPass compatibleRenderPass,
                                  VkPipelineLayout layout);

     GR_DEFINE_RESOURCE_HANDLE_CLASS(CompatibleRPHandle);

     // Finds or creates a simple render pass that matches the target, increments the refcount,
     // and returns. The caller can optionally pass in a pointer to a CompatibleRPHandle. If this is
     // non null it will be set to a handle that can be used in the furutre to quickly return a
     // compatible GrVkRenderPasses without the need inspecting a GrVkRenderTarget.
     const GrVkRenderPass* findCompatibleRenderPass(const GrVkRenderTarget& target,
                                                    CompatibleRPHandle* compatibleHandle = nullptr);
     // The CompatibleRPHandle must be a valid handle previously set by a call to
     // findCompatibleRenderPass(GrVkRenderTarget&, CompatibleRPHandle*).
     const GrVkRenderPass* findCompatibleRenderPass(const CompatibleRPHandle& compatibleHandle);

     const GrVkRenderPass* findCompatibleExternalRenderPass(VkRenderPass,
                                                            uint32_t colorAttachmentIndex);

     // Finds or creates a render pass that matches the target and LoadStoreOps, increments the
     // refcount, and returns. The caller can optionally pass in a pointer to a CompatibleRPHandle.
     // If this is non null it will be set to a handle that can be used in the furutre to quickly
     // return a GrVkRenderPasses without the need inspecting a GrVkRenderTarget.
     const GrVkRenderPass* findRenderPass(const GrVkRenderTarget& target,
                                          const GrVkRenderPass::LoadStoreOps& colorOps,
                                          const GrVkRenderPass::LoadStoreOps& stencilOps,
                                          CompatibleRPHandle* compatibleHandle = nullptr);

     // The CompatibleRPHandle must be a valid handle previously set by a call to findRenderPass or
     // findCompatibleRenderPass.
     const GrVkRenderPass* findRenderPass(const CompatibleRPHandle& compatibleHandle,
                                          const GrVkRenderPass::LoadStoreOps& colorOps,
                                          const GrVkRenderPass::LoadStoreOps& stencilOps);

     GrVkCommandPool* findOrCreateCommandPool();

     void checkCommandBuffers();

     // We must add the finishedProc to all active command buffers since we may have flushed work
     // that the client cares about before they explicitly called flush and the GPU may reorder
     // command execution. So we make sure all previously submitted work finishes before we call the
     // finishedProc.
     void addFinishedProcToActiveCommandBuffers(GrGpuFinishedProc finishedProc,
                                                GrGpuFinishedContext finishedContext);

     // Finds or creates a compatible GrVkDescriptorPool for the requested type and count.
     // The refcount is incremented and a pointer returned.
     // TODO: Currently this will just create a descriptor pool without holding onto a ref itself
     //       so we currently do not reuse them. Rquires knowing if another draw is currently using
     //       the GrVkDescriptorPool, the ability to reset pools, and the ability to purge pools out
     //       of our cache of GrVkDescriptorPools.
     GrVkDescriptorPool* findOrCreateCompatibleDescriptorPool(VkDescriptorType type, uint32_t count);

     // Finds or creates a compatible GrVkSampler based on the GrSamplerState and
     // GrVkYcbcrConversionInfo. The refcount is incremented and a pointer returned.
     GrVkSampler* findOrCreateCompatibleSampler(const GrSamplerState&,
                                                const GrVkYcbcrConversionInfo& ycbcrInfo);

     // Finds or creates a compatible GrVkSamplerYcbcrConversion based on the GrSamplerState and
     // GrVkYcbcrConversionInfo. The refcount is incremented and a pointer returned.
     GrVkSamplerYcbcrConversion* findOrCreateCompatibleSamplerYcbcrConversion(
             const GrVkYcbcrConversionInfo& ycbcrInfo);

     GrVkPipelineState* findOrCreateCompatiblePipelineState(
             GrRenderTarget*,
             const GrProgramInfo&,
             GrPrimitiveType,
             VkRenderPass compatibleRenderPass);

     void getSamplerDescriptorSetHandle(VkDescriptorType type,
                                        const GrVkUniformHandler&,
                                        GrVkDescriptorSetManager::Handle* handle);
     void getSamplerDescriptorSetHandle(VkDescriptorType type,
                                        const SkTArray<uint32_t>& visibilities,
                                        GrVkDescriptorSetManager::Handle* handle);

     // Returns the compatible VkDescriptorSetLayout to use for uniform buffers. The caller does not
     // own the VkDescriptorSetLayout and thus should not delete it. This function should be used
     // when the caller needs the layout to create a VkPipelineLayout.
     VkDescriptorSetLayout getUniformDSLayout() const;

     // Returns the compatible VkDescriptorSetLayout to use for a specific sampler handle. The caller
     // does not own the VkDescriptorSetLayout and thus should not delete it. This function should be
     // used when the caller needs the layout to create a VkPipelineLayout.
     VkDescriptorSetLayout getSamplerDSLayout(const GrVkDescriptorSetManager::Handle&) const;

     // Returns a GrVkDescriptorSet that can be used for uniform buffers. The GrVkDescriptorSet
     // is already reffed for the caller.
     const GrVkDescriptorSet* getUniformDescriptorSet();

     // Returns a GrVkDescriptorSet that can be used for sampler descriptors that are compatible with
     // the GrVkDescriptorSetManager::Handle passed in. The GrVkDescriptorSet is already reffed for
     // the caller.
     const GrVkDescriptorSet* getSamplerDescriptorSet(const GrVkDescriptorSetManager::Handle&);


     // Signals that the descriptor set passed it, which is compatible with the passed in handle,
     // can be reused by the next allocation request.
     void recycleDescriptorSet(const GrVkDescriptorSet* descSet,
                               const GrVkDescriptorSetManager::Handle&);

     // Creates or finds free uniform buffer resources of size GrVkUniformBuffer::kStandardSize.
     // Anything larger will need to be created and released by the client.
     const GrVkResource* findOrCreateStandardUniformBufferResource();

     // Signals that the resource passed to it (which should be a uniform buffer resource)
     // can be reused by the next uniform buffer resource request.
     void recycleStandardUniformBufferResource(const GrVkResource*);

     void storePipelineCacheData();

     // Destroy any cached resources. To be called before destroying the VkDevice.
     // The assumption is that all queues are idle and all command buffers are finished.
     // For resource tracing to work properly, this should be called after unrefing all other
     // resource usages.
     // If deviceLost is true, then resources will not be checked to see if they've finished
     // before deleting (see section 4.2.4 of the Vulkan spec).
     void destroyResources(bool deviceLost);

     // Abandon any cached resources. To be used when the context/VkDevice is lost.
     // For resource tracing to work properly, this should be called after unrefing all other
     // resource usages.
     void abandonResources();

     void backgroundReset(GrVkCommandPool* pool);

     void reset(GrVkCommandPool* pool);

 #if GR_TEST_UTILS
     void resetShaderCacheForTesting() const { fPipelineStateCache->release(); }
 #endif

 private:

 #ifdef SK_DEBUG
 #define GR_PIPELINE_STATE_CACHE_STATS
 #endif

     class PipelineStateCache : public ::SkNoncopyable {
     public:
         PipelineStateCache(GrVkGpu* gpu);
         ~PipelineStateCache();

         void abandon();
         void release();
         GrVkPipelineState* refPipelineState(GrRenderTarget*,
                                             const GrProgramInfo&,
                                             GrPrimitiveType,
                                             VkRenderPass compatibleRenderPass);

     private:
         struct Entry;

         struct DescHash {
             uint32_t operator()(const GrProgramDesc& desc) const {
                 return SkOpts::hash_fn(desc.asKey(), desc.keyLength(), 0);
             }
         };

         SkLRUCache<const GrVkPipelineStateBuilder::Desc, std::unique_ptr<Entry>, DescHash> fMap;

         GrVkGpu*                    fGpu;

 #ifdef GR_PIPELINE_STATE_CACHE_STATS
         int                         fTotalRequests;
         int                         fCacheMisses;
 #endif
     };

     class CompatibleRenderPassSet {
     public:
         // This will always construct the basic load store render pass (all attachments load and
         // store their data) so that there is at least one compatible VkRenderPass that can be used
         // with this set.
         CompatibleRenderPassSet(const GrVkGpu* gpu, const GrVkRenderTarget& target);

         bool isCompatible(const GrVkRenderTarget& target) const;

         GrVkRenderPass* getCompatibleRenderPass() const {
             // The first GrVkRenderpass should always exist since we create the basic load store
             // render pass on create
             SkASSERT(fRenderPasses[0]);
             return fRenderPasses[0];
         }

         GrVkRenderPass* getRenderPass(const GrVkGpu* gpu,
                                       const GrVkRenderPass::LoadStoreOps& colorOps,
                                       const GrVkRenderPass::LoadStoreOps& stencilOps);

         void releaseResources(GrVkGpu* gpu);
         void abandonResources();

     private:
         SkSTArray<4, GrVkRenderPass*> fRenderPasses;
         int                           fLastReturnedIndex;
     };

     VkPipelineCache pipelineCache();

     GrVkGpu* fGpu;

     // Central cache for creating pipelines
     VkPipelineCache fPipelineCache;

     SkSTArray<4, CompatibleRenderPassSet> fRenderPassArray;

     SkTArray<const GrVkRenderPass*> fExternalRenderPasses;

     // Array of command pools that we are waiting on
     SkSTArray<4, GrVkCommandPool*, true> fActiveCommandPools;

     // Array of available command pools that are not in flight
     SkSTArray<4, GrVkCommandPool*, true> fAvailableCommandPools;

     // Array of available uniform buffer resources
     SkSTArray<16, const GrVkResource*, true> fAvailableUniformBufferResources;

     // Stores GrVkSampler objects that we've already created so we can reuse them across multiple
     // GrVkPipelineStates
     SkTDynamicHash<GrVkSampler, GrVkSampler::Key> fSamplers;

     // Stores GrVkSamplerYcbcrConversion objects that we've already created so we can reuse them.
     SkTDynamicHash<GrVkSamplerYcbcrConversion, GrVkSamplerYcbcrConversion::Key> fYcbcrConversions;

     // Cache of GrVkPipelineStates
     PipelineStateCache* fPipelineStateCache;

     SkSTArray<4, std::unique_ptr<GrVkDescriptorSetManager>> fDescriptorSetManagers;

     GrVkDescriptorSetManager::Handle fUniformDSHandle;

     std::recursive_mutex fBackgroundMutex;
 };

 #endif
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrVkResourceProvider_DEFINED
	#define GrVkResourceProvider_DEFINED

	#include "include/gpu/vk/GrVkTypes.h"
	#include "include/private/SkTArray.h"
	#include "src/core/SkLRUCache.h"
	#include "src/core/SkTDynamicHash.h"
	#include "src/core/SkTInternalLList.h"
	#include "src/gpu/GrResourceHandle.h"
	#include "src/gpu/vk/GrVkDescriptorPool.h"
	#include "src/gpu/vk/GrVkDescriptorSetManager.h"
	#include "src/gpu/vk/GrVkPipelineStateBuilder.h"
	#include "src/gpu/vk/GrVkRenderPass.h"
	#include "src/gpu/vk/GrVkResource.h"
	#include "src/gpu/vk/GrVkSampler.h"
	#include "src/gpu/vk/GrVkSamplerYcbcrConversion.h"
	#include "src/gpu/vk/GrVkUtil.h"

	#include <mutex>
	#include <thread>

	class GrVkCommandPool;
	class GrVkGpu;
	class GrVkPipeline;
	class GrVkPipelineState;
	class GrVkPrimaryCommandBuffer;
	class GrVkRenderTarget;
	class GrVkSecondaryCommandBuffer;
	class GrVkUniformHandler;

	class GrVkResourceProvider {
	public:
	GrVkResourceProvider(GrVkGpu* gpu);
	~GrVkResourceProvider();

	// Set up any initial vk objects
	void init();

	GrVkPipeline* createPipeline(const GrProgramInfo&,
	const GrStencilSettings& stencil,
	VkPipelineShaderStageCreateInfo* shaderStageInfo,
	int shaderStageCount,
	GrPrimitiveType primitiveType,
	VkRenderPass compatibleRenderPass,
	VkPipelineLayout layout);

	GR_DEFINE_RESOURCE_HANDLE_CLASS(CompatibleRPHandle);

	// Finds or creates a simple render pass that matches the target, increments the refcount,
	// and returns. The caller can optionally pass in a pointer to a CompatibleRPHandle. If this is
	// non null it will be set to a handle that can be used in the furutre to quickly return a
	// compatible GrVkRenderPasses without the need inspecting a GrVkRenderTarget.
	const GrVkRenderPass* findCompatibleRenderPass(const GrVkRenderTarget& target,
	CompatibleRPHandle* compatibleHandle = nullptr);
	// The CompatibleRPHandle must be a valid handle previously set by a call to
	// findCompatibleRenderPass(GrVkRenderTarget&, CompatibleRPHandle*).
	const GrVkRenderPass* findCompatibleRenderPass(const CompatibleRPHandle& compatibleHandle);

	const GrVkRenderPass* findCompatibleExternalRenderPass(VkRenderPass,
	uint32_t colorAttachmentIndex);

	// Finds or creates a render pass that matches the target and LoadStoreOps, increments the
	// refcount, and returns. The caller can optionally pass in a pointer to a CompatibleRPHandle.
	// If this is non null it will be set to a handle that can be used in the furutre to quickly
	// return a GrVkRenderPasses without the need inspecting a GrVkRenderTarget.
	const GrVkRenderPass* findRenderPass(const GrVkRenderTarget& target,
	const GrVkRenderPass::LoadStoreOps& colorOps,
	const GrVkRenderPass::LoadStoreOps& stencilOps,
	CompatibleRPHandle* compatibleHandle = nullptr);

	// The CompatibleRPHandle must be a valid handle previously set by a call to findRenderPass or
	// findCompatibleRenderPass.
	const GrVkRenderPass* findRenderPass(const CompatibleRPHandle& compatibleHandle,
	const GrVkRenderPass::LoadStoreOps& colorOps,
	const GrVkRenderPass::LoadStoreOps& stencilOps);

	GrVkCommandPool* findOrCreateCommandPool();

	void checkCommandBuffers();

	// We must add the finishedProc to all active command buffers since we may have flushed work
	// that the client cares about before they explicitly called flush and the GPU may reorder
	// command execution. So we make sure all previously submitted work finishes before we call the
	// finishedProc.
	void addFinishedProcToActiveCommandBuffers(GrGpuFinishedProc finishedProc,
	GrGpuFinishedContext finishedContext);

	// Finds or creates a compatible GrVkDescriptorPool for the requested type and count.
	// The refcount is incremented and a pointer returned.
	// TODO: Currently this will just create a descriptor pool without holding onto a ref itself
	// so we currently do not reuse them. Rquires knowing if another draw is currently using
	// the GrVkDescriptorPool, the ability to reset pools, and the ability to purge pools out
	// of our cache of GrVkDescriptorPools.
	GrVkDescriptorPool* findOrCreateCompatibleDescriptorPool(VkDescriptorType type, uint32_t count);

	// Finds or creates a compatible GrVkSampler based on the GrSamplerState and
	// GrVkYcbcrConversionInfo. The refcount is incremented and a pointer returned.
	GrVkSampler* findOrCreateCompatibleSampler(const GrSamplerState&,
	const GrVkYcbcrConversionInfo& ycbcrInfo);

	// Finds or creates a compatible GrVkSamplerYcbcrConversion based on the GrSamplerState and
	// GrVkYcbcrConversionInfo. The refcount is incremented and a pointer returned.
	GrVkSamplerYcbcrConversion* findOrCreateCompatibleSamplerYcbcrConversion(
	const GrVkYcbcrConversionInfo& ycbcrInfo);

	GrVkPipelineState* findOrCreateCompatiblePipelineState(
	GrRenderTarget*,
	const GrProgramInfo&,
	GrPrimitiveType,
	VkRenderPass compatibleRenderPass);

	void getSamplerDescriptorSetHandle(VkDescriptorType type,
	const GrVkUniformHandler&,
	GrVkDescriptorSetManager::Handle* handle);
	void getSamplerDescriptorSetHandle(VkDescriptorType type,
	const SkTArray<uint32_t>& visibilities,
	GrVkDescriptorSetManager::Handle* handle);

	// Returns the compatible VkDescriptorSetLayout to use for uniform buffers. The caller does not
	// own the VkDescriptorSetLayout and thus should not delete it. This function should be used
	// when the caller needs the layout to create a VkPipelineLayout.
	VkDescriptorSetLayout getUniformDSLayout() const;

	// Returns the compatible VkDescriptorSetLayout to use for a specific sampler handle. The caller
	// does not own the VkDescriptorSetLayout and thus should not delete it. This function should be
	// used when the caller needs the layout to create a VkPipelineLayout.
	VkDescriptorSetLayout getSamplerDSLayout(const GrVkDescriptorSetManager::Handle&) const;

	// Returns a GrVkDescriptorSet that can be used for uniform buffers. The GrVkDescriptorSet
	// is already reffed for the caller.
	const GrVkDescriptorSet* getUniformDescriptorSet();

	// Returns a GrVkDescriptorSet that can be used for sampler descriptors that are compatible with
	// the GrVkDescriptorSetManager::Handle passed in. The GrVkDescriptorSet is already reffed for
	// the caller.
	const GrVkDescriptorSet* getSamplerDescriptorSet(const GrVkDescriptorSetManager::Handle&);


	// Signals that the descriptor set passed it, which is compatible with the passed in handle,
	// can be reused by the next allocation request.
	void recycleDescriptorSet(const GrVkDescriptorSet* descSet,
	const GrVkDescriptorSetManager::Handle&);

	// Creates or finds free uniform buffer resources of size GrVkUniformBuffer::kStandardSize.
	// Anything larger will need to be created and released by the client.
	const GrVkResource* findOrCreateStandardUniformBufferResource();

	// Signals that the resource passed to it (which should be a uniform buffer resource)
	// can be reused by the next uniform buffer resource request.
	void recycleStandardUniformBufferResource(const GrVkResource*);

	void storePipelineCacheData();

	// Destroy any cached resources. To be called before destroying the VkDevice.
	// The assumption is that all queues are idle and all command buffers are finished.
	// For resource tracing to work properly, this should be called after unrefing all other
	// resource usages.
	// If deviceLost is true, then resources will not be checked to see if they've finished
	// before deleting (see section 4.2.4 of the Vulkan spec).
	void destroyResources(bool deviceLost);

	// Abandon any cached resources. To be used when the context/VkDevice is lost.
	// For resource tracing to work properly, this should be called after unrefing all other
	// resource usages.
	void abandonResources();

	void backgroundReset(GrVkCommandPool* pool);

	void reset(GrVkCommandPool* pool);

	#if GR_TEST_UTILS
	void resetShaderCacheForTesting() const { fPipelineStateCache->release(); }
	#endif

	private:

	#ifdef SK_DEBUG
	#define GR_PIPELINE_STATE_CACHE_STATS
	#endif

	class PipelineStateCache : public ::SkNoncopyable {
	public:
	PipelineStateCache(GrVkGpu* gpu);
	~PipelineStateCache();

	void abandon();
	void release();
	GrVkPipelineState* refPipelineState(GrRenderTarget*,
	const GrProgramInfo&,
	GrPrimitiveType,
	VkRenderPass compatibleRenderPass);

	private:
	struct Entry;

	struct DescHash {
	uint32_t operator()(const GrProgramDesc& desc) const {
	return SkOpts::hash_fn(desc.asKey(), desc.keyLength(), 0);
	}
	};

	SkLRUCache<const GrVkPipelineStateBuilder::Desc, std::unique_ptr<Entry>, DescHash> fMap;

	GrVkGpu* fGpu;

	#ifdef GR_PIPELINE_STATE_CACHE_STATS
	int fTotalRequests;
	int fCacheMisses;
	#endif
	};

	class CompatibleRenderPassSet {
	public:
	// This will always construct the basic load store render pass (all attachments load and
	// store their data) so that there is at least one compatible VkRenderPass that can be used
	// with this set.
	CompatibleRenderPassSet(const GrVkGpu* gpu, const GrVkRenderTarget& target);

	bool isCompatible(const GrVkRenderTarget& target) const;

	GrVkRenderPass* getCompatibleRenderPass() const {
	// The first GrVkRenderpass should always exist since we create the basic load store
	// render pass on create
	SkASSERT(fRenderPasses[0]);
	return fRenderPasses[0];
	}

	GrVkRenderPass* getRenderPass(const GrVkGpu* gpu,
	const GrVkRenderPass::LoadStoreOps& colorOps,
	const GrVkRenderPass::LoadStoreOps& stencilOps);

	void releaseResources(GrVkGpu* gpu);
	void abandonResources();

	private:
	SkSTArray<4, GrVkRenderPass*> fRenderPasses;
	int fLastReturnedIndex;
	};

	VkPipelineCache pipelineCache();

	GrVkGpu* fGpu;

	// Central cache for creating pipelines
	VkPipelineCache fPipelineCache;

	SkSTArray<4, CompatibleRenderPassSet> fRenderPassArray;

	SkTArray<const GrVkRenderPass*> fExternalRenderPasses;

	// Array of command pools that we are waiting on
	SkSTArray<4, GrVkCommandPool*, true> fActiveCommandPools;

	// Array of available command pools that are not in flight
	SkSTArray<4, GrVkCommandPool*, true> fAvailableCommandPools;

	// Array of available uniform buffer resources
	SkSTArray<16, const GrVkResource*, true> fAvailableUniformBufferResources;

	// Stores GrVkSampler objects that we've already created so we can reuse them across multiple
	// GrVkPipelineStates
	SkTDynamicHash<GrVkSampler, GrVkSampler::Key> fSamplers;

	// Stores GrVkSamplerYcbcrConversion objects that we've already created so we can reuse them.
	SkTDynamicHash<GrVkSamplerYcbcrConversion, GrVkSamplerYcbcrConversion::Key> fYcbcrConversions;

	// Cache of GrVkPipelineStates
	PipelineStateCache* fPipelineStateCache;

	SkSTArray<4, std::unique_ptr<GrVkDescriptorSetManager>> fDescriptorSetManagers;

	GrVkDescriptorSetManager::Handle fUniformDSHandle;

	std::recursive_mutex fBackgroundMutex;
	};

	#endif