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/*
* Copyright 2015 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef GrDrawingManager_DEFINED
#define GrDrawingManager_DEFINED
#include "include/core/SkSpan.h"
#include "include/core/SkSurface.h"
#include "include/private/base/SkTArray.h"
#include "src/core/SkTHash.h"
#include "src/gpu/ganesh/GrBufferAllocPool.h"
#include "src/gpu/ganesh/GrDeferredUpload.h"
#include "src/gpu/ganesh/GrHashMapWithCache.h"
#include "src/gpu/ganesh/GrResourceCache.h"
#include "src/gpu/ganesh/GrSamplerState.h"
#include "src/gpu/ganesh/GrSurfaceProxy.h"
#include "src/gpu/ganesh/PathRenderer.h"
#include "src/gpu/ganesh/PathRendererChain.h"
// Enabling this will print out which path renderers are being chosen
#define GR_PATH_RENDERER_SPEW 0
class GrArenas;
class GrDeferredDisplayList;
class GrGpuBuffer;
class GrOnFlushCallbackObject;
class GrOpFlushState;
class GrRecordingContext;
class GrRenderTargetProxy;
class GrRenderTask;
class GrResourceAllocator;
class GrSemaphore;
class GrSurfaceProxyView;
class GrTextureResolveRenderTask;
namespace skgpu {
namespace ganesh {
class OpsTask;
class SoftwarePathRenderer;
} // namespace ganesh
} // namespace skgpu
class GrDrawingManager {
public:
~GrDrawingManager();
void freeGpuResources();
// OpsTasks created at flush time are stored and handled different from the others.
sk_sp<skgpu::ganesh::OpsTask> newOpsTask(GrSurfaceProxyView, sk_sp<GrArenas> arenas);
// Adds 'atlasTask' to the DAG and leaves it open.
//
// If 'previousAtlasTask' is provided, closes it and configures dependencies to guarantee
// previousAtlasTask and all its users are completely out of service before atlasTask executes.
void addAtlasTask(sk_sp<GrRenderTask> atlasTask, GrRenderTask* previousAtlasTask);
// Create a render task that can resolve MSAA and/or regenerate mipmap levels on proxies. This
// method will only add the new render task to the list. However, it adds the task before the
// last task in the list. It is up to the caller to call addProxy() on the returned object.
GrTextureResolveRenderTask* newTextureResolveRenderTaskBefore(const GrCaps&);
// Creates a render task that can resolve MSAA and/or regenerate mimap levels on the passed in
// proxy. The task is appended to the end of the current list of tasks.
void newTextureResolveRenderTask(sk_sp<GrSurfaceProxy> proxy,
GrSurfaceProxy::ResolveFlags,
const GrCaps&);
// Create a new render task that will cause the gpu to wait on semaphores before executing any
// more RenderTasks that target proxy. It is possible for this wait to also block additional
// work (even to other proxies) that has already been recorded or will be recorded later. The
// only guarantee is that future work to the passed in proxy will wait on the semaphores to be
// signaled.
void newWaitRenderTask(const sk_sp<GrSurfaceProxy>& proxy,
std::unique_ptr<std::unique_ptr<GrSemaphore>[]>,
int numSemaphores);
// Create a new render task which copies the pixels from the srcProxy into the dstBuffer. This
// is used to support the asynchronous readback API. The srcRect is the region of the srcProxy
// to be copied. The surfaceColorType says how we should interpret the data when reading back
// from the source. DstColorType describes how the data should be stored in the dstBuffer.
// DstOffset is the offset into the dstBuffer where we will start writing data.
void newTransferFromRenderTask(const sk_sp<GrSurfaceProxy>& srcProxy, const SkIRect& srcRect,
GrColorType surfaceColorType, GrColorType dstColorType,
sk_sp<GrGpuBuffer> dstBuffer, size_t dstOffset);
// Creates a new render task which copies a pixel rectangle from srcView into dstView. The src
// pixels copied are specified by srcRect. They are copied to the dstRect in dstProxy. Some
// backends and formats may require dstRect to have the same size as srcRect. Regardless,
// srcRect must be contained by src's dimensions and dstRect must be contained by dst's
// dimensions. Any clipping, aspect-ratio adjustment, etc. must be handled prior to this call.
//
// This method is not guaranteed to succeed depending on the type of surface, formats, etc, and
// the backend-specific limitations. On success the task is returned so that the caller may mark
// it skippable if the copy is later deemed unnecessary.
sk_sp<GrRenderTask> newCopyRenderTask(sk_sp<GrSurfaceProxy> dst,
SkIRect dstRect,
const sk_sp<GrSurfaceProxy>& src,
SkIRect srcRect,
GrSamplerState::Filter filter,
GrSurfaceOrigin);
// Adds a render task that copies the range [srcOffset, srcOffset + size] from src to
// [dstOffset, dstOffset + size] in dst. The src buffer must have type kXferCpuToGpu and the
// dst must NOT have type kXferCpuToGpu. Neither buffer may be mapped when this executes.
// Because this is used to insert transfers to vertex/index buffers between draws and we don't
// track dependencies with buffers, this task is a hard boundary for task reordering.
void newBufferTransferTask(sk_sp<GrGpuBuffer> src,
size_t srcOffset,
sk_sp<GrGpuBuffer> dst,
size_t dstOffset,
size_t size);
// Adds a render task that copies the src SkData to [dstOffset, dstOffset + src->size()] in dst.
// The dst must not have type kXferCpuToGpu and must not be mapped. Because this is used to
// insert updata to vertex/index buffers between draws and we don't track dependencies with
// buffers, this task is a hard boundary for task reordering.
void newBufferUpdateTask(sk_sp<SkData> src, sk_sp<GrGpuBuffer> dst, size_t dstOffset);
// Adds a task that writes the data from the passed GrMipLevels to dst. The lifetime of the
// pixel data in the levels should be tied to the passed SkData or the caller must flush the
// context before the data may become invalid. srcColorType is the color type of the
// GrMipLevels. dstColorType is the color type being used with dst and must be compatible with
// dst's format according to GrCaps::areColorTypeAndFormatCompatible().
bool newWritePixelsTask(sk_sp<GrSurfaceProxy> dst,
SkIRect rect,
GrColorType srcColorType,
GrColorType dstColorType,
const GrMipLevel[],
int levelCount);
GrRecordingContext* getContext() { return fContext; }
using PathRenderer = skgpu::ganesh::PathRenderer;
using PathRendererChain = skgpu::ganesh::PathRendererChain;
PathRenderer* getPathRenderer(const PathRenderer::CanDrawPathArgs&,
bool allowSW,
PathRendererChain::DrawType,
PathRenderer::StencilSupport* = nullptr);
PathRenderer* getSoftwarePathRenderer();
// Returns a direct pointer to the atlas path renderer, or null if it is not supported and
// turned on.
skgpu::ganesh::AtlasPathRenderer* getAtlasPathRenderer();
// Returns a direct pointer to the tessellation path renderer, or null if it is not supported
// and turned on.
PathRenderer* getTessellationPathRenderer();
void flushIfNecessary();
static bool ProgramUnitTest(GrDirectContext*, int maxStages, int maxLevels);
GrSemaphoresSubmitted flushSurfaces(SkSpan<GrSurfaceProxy*>,
SkSurfaces::BackendSurfaceAccess,
const GrFlushInfo&,
const skgpu::MutableTextureState* newState);
void addOnFlushCallbackObject(GrOnFlushCallbackObject*);
#if defined(GR_TEST_UTILS)
void testingOnly_removeOnFlushCallbackObject(GrOnFlushCallbackObject*);
PathRendererChain::Options testingOnly_getOptionsForPathRendererChain() {
return fOptionsForPathRendererChain;
}
#endif
GrRenderTask* getLastRenderTask(const GrSurfaceProxy*) const;
skgpu::ganesh::OpsTask* getLastOpsTask(const GrSurfaceProxy*) const;
void setLastRenderTask(const GrSurfaceProxy*, GrRenderTask*);
void moveRenderTasksToDDL(GrDeferredDisplayList* ddl);
void createDDLTask(sk_sp<const GrDeferredDisplayList>,
sk_sp<GrRenderTargetProxy> newDest);
// This is public so it can be called by an SkImage factory (in SkImages namespace).
// It is not meant to be directly called in other situations.
bool flush(SkSpan<GrSurfaceProxy*> proxies,
SkSurfaces::BackendSurfaceAccess access,
const GrFlushInfo&,
const skgpu::MutableTextureState* newState);
private:
GrDrawingManager(GrRecordingContext*,
const PathRendererChain::Options&,
bool reduceOpsTaskSplitting);
bool wasAbandoned() const;
void closeActiveOpsTask();
// return true if any GrRenderTasks were actually executed; false otherwise
bool executeRenderTasks(GrOpFlushState*);
void removeRenderTasks();
void sortTasks();
// Attempt to reorder tasks to reduce render passes, and check the memory budget of the
// resulting intervals. Returns whether the reordering was successful & the memory budget
// acceptable. If it returns true, fDAG has been updated to reflect the reordered tasks.
bool reorderTasks(GrResourceAllocator*);
void closeAllTasks();
GrRenderTask* appendTask(sk_sp<GrRenderTask>);
GrRenderTask* insertTaskBeforeLast(sk_sp<GrRenderTask>);
bool submitToGpu(GrSyncCpu sync);
SkDEBUGCODE(void validate() const;)
friend class GrDirectContext; // access to: flush & cleanup
friend class GrOnFlushResourceProvider; // this is just a shallow wrapper around this class
friend class GrRecordingContext; // access to: ctor
static const int kNumPixelGeometries = 5; // The different pixel geometries
static const int kNumDFTOptions = 2; // DFT or no DFT
GrRecordingContext* fContext;
// This cache is used by both the vertex and index pools. It reuses memory across multiple
// flushes.
sk_sp<GrBufferAllocPool::CpuBufferCache> fCpuBufferCache;
skia_private::TArray<sk_sp<GrRenderTask>> fDAG;
std::vector<int> fReorderBlockerTaskIndices;
skgpu::ganesh::OpsTask* fActiveOpsTask = nullptr;
PathRendererChain::Options fOptionsForPathRendererChain;
std::unique_ptr<PathRendererChain> fPathRendererChain;
sk_sp<skgpu::ganesh::SoftwarePathRenderer> fSoftwarePathRenderer;
skgpu::TokenTracker fTokenTracker;
bool fFlushing = false;
const bool fReduceOpsTaskSplitting;
skia_private::TArray<GrOnFlushCallbackObject*> fOnFlushCBObjects;
struct SurfaceIDKeyTraits {
static uint32_t GetInvalidKey() {
return GrSurfaceProxy::UniqueID::InvalidID().asUInt();
}
};
GrHashMapWithCache<uint32_t, GrRenderTask*, SurfaceIDKeyTraits, GrCheapHash> fLastRenderTasks;
};
#endif