src/gpu/GrOpFlushState.cpp - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/gpu/GrOpFlushState.h"

 #include "include/gpu/GrTexture.h"
 #include "src/core/SkConvertPixels.h"
 #include "src/gpu/GrContextPriv.h"
 #include "src/gpu/GrDrawOpAtlas.h"
 #include "src/gpu/GrGpu.h"
 #include "src/gpu/GrResourceProvider.h"

 //////////////////////////////////////////////////////////////////////////////

 GrOpFlushState::GrOpFlushState(GrGpu* gpu, GrResourceProvider* resourceProvider,
                                GrTokenTracker* tokenTracker,
                                sk_sp<GrBufferAllocPool::CpuBufferCache> cpuBufferCache)
         : fVertexPool(gpu, cpuBufferCache)
         , fIndexPool(gpu, std::move(cpuBufferCache))
         , fGpu(gpu)
         , fResourceProvider(resourceProvider)
         , fTokenTracker(tokenTracker)
         , fDeinstantiateProxyTracker() {}

 const GrCaps& GrOpFlushState::caps() const {
     return *fGpu->caps();
 }

 GrGpuRTCommandBuffer* GrOpFlushState::rtCommandBuffer() {
     return fCommandBuffer->asRTCommandBuffer();
 }

 void GrOpFlushState::executeDrawsAndUploadsForMeshDrawOp(
         const GrOp* op, const SkRect& chainBounds, GrProcessorSet&& processorSet,
         GrPipeline::InputFlags pipelineFlags, const GrUserStencilSettings* stencilSettings) {
     SkASSERT(this->rtCommandBuffer());

     GrPipeline::InitArgs pipelineArgs;
     pipelineArgs.fInputFlags = pipelineFlags;
     pipelineArgs.fDstProxy = this->dstProxy();
     pipelineArgs.fCaps = &this->caps();
     pipelineArgs.fUserStencil = stencilSettings;
     pipelineArgs.fOutputSwizzle = this->drawOpArgs().fOutputSwizzle;
     GrPipeline* pipeline = this->allocator()->make<GrPipeline>(pipelineArgs,
                                                                std::move(processorSet),
                                                                this->detachAppliedClip());

     while (fCurrDraw != fDraws.end() && fCurrDraw->fOp == op) {
         GrDeferredUploadToken drawToken = fTokenTracker->nextTokenToFlush();
         while (fCurrUpload != fInlineUploads.end() &&
                fCurrUpload->fUploadBeforeToken == drawToken) {
             this->rtCommandBuffer()->inlineUpload(this, fCurrUpload->fUpload);
             ++fCurrUpload;
         }
         this->rtCommandBuffer()->draw(
                 *fCurrDraw->fGeometryProcessor, *pipeline, fCurrDraw->fFixedDynamicState,
                 fCurrDraw->fDynamicStateArrays, fCurrDraw->fMeshes, fCurrDraw->fMeshCnt,
                 chainBounds);
         fTokenTracker->flushToken();
         ++fCurrDraw;
     }
 }

 void GrOpFlushState::preExecuteDraws() {
     fVertexPool.unmap();
     fIndexPool.unmap();
     for (auto& upload : fASAPUploads) {
         this->doUpload(upload);
     }
     // Setup execution iterators.
     fCurrDraw = fDraws.begin();
     fCurrUpload = fInlineUploads.begin();
 }

 void GrOpFlushState::reset() {
     SkASSERT(fCurrDraw == fDraws.end());
     SkASSERT(fCurrUpload == fInlineUploads.end());
     fVertexPool.reset();
     fIndexPool.reset();
     fArena.reset();
     fASAPUploads.reset();
     fInlineUploads.reset();
     fDraws.reset();
     fBaseDrawToken = GrDeferredUploadToken::AlreadyFlushedToken();
 }

 void GrOpFlushState::doUpload(GrDeferredTextureUploadFn& upload) {
     GrDeferredTextureUploadWritePixelsFn wp = [this](GrTextureProxy* dstProxy, int left, int top,
                                                      int width, int height, GrColorType colorType,
                                                      const void* buffer, size_t rowBytes) {
         GrSurface* dstSurface = dstProxy->peekSurface();
         if (!fGpu->caps()->surfaceSupportsWritePixels(dstSurface)) {
             return false;
         }
         GrCaps::SupportedWrite supportedWrite = fGpu->caps()->supportedWritePixelsColorType(
                 colorType, dstSurface->backendFormat(), colorType);
         size_t tightRB = width * GrColorTypeBytesPerPixel(supportedWrite.fColorType);
         SkASSERT(rowBytes >= tightRB);
         std::unique_ptr<char[]> tmpPixels;
         if (supportedWrite.fColorType != colorType ||
             (!fGpu->caps()->writePixelsRowBytesSupport() && rowBytes != tightRB)) {
             tmpPixels.reset(new char[height * tightRB]);
             // Use kUnpremul to ensure no alpha type conversions or clamping occur.
             static constexpr auto kAT = kUnpremul_SkAlphaType;
             GrPixelInfo srcInfo(colorType, kAT, nullptr, width, height);
             GrPixelInfo tmpInfo(supportedWrite.fColorType, kAT, nullptr, width,
                                 height);
             if (!GrConvertPixels(tmpInfo, tmpPixels.get(), tightRB, srcInfo, buffer, rowBytes)) {
                 return false;
             }
             rowBytes = tightRB;
             buffer = tmpPixels.get();
         }
         return this->fGpu->writePixels(dstSurface, left, top, width, height, colorType,
                                        supportedWrite.fColorType, buffer, rowBytes);
     };
     upload(wp);
 }

 GrDeferredUploadToken GrOpFlushState::addInlineUpload(GrDeferredTextureUploadFn&& upload) {
     return fInlineUploads.append(&fArena, std::move(upload), fTokenTracker->nextDrawToken())
             .fUploadBeforeToken;
 }

 GrDeferredUploadToken GrOpFlushState::addASAPUpload(GrDeferredTextureUploadFn&& upload) {
     fASAPUploads.append(&fArena, std::move(upload));
     return fTokenTracker->nextTokenToFlush();
 }

 void GrOpFlushState::recordDraw(
         sk_sp<const GrGeometryProcessor> gp, const GrMesh meshes[], int meshCnt,
         const GrPipeline::FixedDynamicState* fixedDynamicState,
         const GrPipeline::DynamicStateArrays* dynamicStateArrays) {
     SkASSERT(fOpArgs);
     SkASSERT(fOpArgs->fOp);
     bool firstDraw = fDraws.begin() == fDraws.end();
     auto& draw = fDraws.append(&fArena);
     GrDeferredUploadToken token = fTokenTracker->issueDrawToken();
     if (fixedDynamicState && fixedDynamicState->fPrimitiveProcessorTextures) {
         for (int i = 0; i < gp->numTextureSamplers(); ++i) {
             fixedDynamicState->fPrimitiveProcessorTextures[i]->ref();
         }
     }
     if (dynamicStateArrays && dynamicStateArrays->fPrimitiveProcessorTextures) {
         int n = gp->numTextureSamplers() * meshCnt;
         for (int i = 0; i < n; ++i) {
             dynamicStateArrays->fPrimitiveProcessorTextures[i]->ref();
         }
     }
     draw.fGeometryProcessor = std::move(gp);
     draw.fFixedDynamicState = fixedDynamicState;
     draw.fDynamicStateArrays = dynamicStateArrays;
     draw.fMeshes = meshes;
     draw.fMeshCnt = meshCnt;
     draw.fOp = fOpArgs->fOp;
     if (firstDraw) {
         fBaseDrawToken = token;
     }
 }

 void* GrOpFlushState::makeVertexSpace(size_t vertexSize, int vertexCount,
                                       sk_sp<const GrBuffer>* buffer, int* startVertex) {
     return fVertexPool.makeSpace(vertexSize, vertexCount, buffer, startVertex);
 }

 uint16_t* GrOpFlushState::makeIndexSpace(int indexCount, sk_sp<const GrBuffer>* buffer,
                                          int* startIndex) {
     return reinterpret_cast<uint16_t*>(fIndexPool.makeSpace(indexCount, buffer, startIndex));
 }

 void* GrOpFlushState::makeVertexSpaceAtLeast(size_t vertexSize, int minVertexCount,
                                              int fallbackVertexCount, sk_sp<const GrBuffer>* buffer,
                                              int* startVertex, int* actualVertexCount) {
     return fVertexPool.makeSpaceAtLeast(vertexSize, minVertexCount, fallbackVertexCount, buffer,
                                         startVertex, actualVertexCount);
 }

 uint16_t* GrOpFlushState::makeIndexSpaceAtLeast(int minIndexCount, int fallbackIndexCount,
                                                 sk_sp<const GrBuffer>* buffer, int* startIndex,
                                                 int* actualIndexCount) {
     return reinterpret_cast<uint16_t*>(fIndexPool.makeSpaceAtLeast(
             minIndexCount, fallbackIndexCount, buffer, startIndex, actualIndexCount));
 }

 void GrOpFlushState::putBackIndices(int indexCount) {
     fIndexPool.putBack(indexCount * sizeof(uint16_t));
 }

 void GrOpFlushState::putBackVertices(int vertices, size_t vertexStride) {
     fVertexPool.putBack(vertices * vertexStride);
 }

 GrAppliedClip GrOpFlushState::detachAppliedClip() {
     return fOpArgs->fAppliedClip ? std::move(*fOpArgs->fAppliedClip) : GrAppliedClip();
 }

 GrStrikeCache* GrOpFlushState::glyphCache() const {
     return fGpu->getContext()->priv().getGrStrikeCache();
 }

 GrAtlasManager* GrOpFlushState::atlasManager() const {
     return fGpu->getContext()->priv().getAtlasManager();
 }

 //////////////////////////////////////////////////////////////////////////////

 GrOpFlushState::Draw::~Draw() {
     if (fFixedDynamicState && fFixedDynamicState->fPrimitiveProcessorTextures) {
         for (int i = 0; i < fGeometryProcessor->numTextureSamplers(); ++i) {
             fFixedDynamicState->fPrimitiveProcessorTextures[i]->unref();
         }
     }
     if (fDynamicStateArrays && fDynamicStateArrays->fPrimitiveProcessorTextures) {
         int n = fGeometryProcessor->numTextureSamplers() * fMeshCnt;
         const auto* textures = fDynamicStateArrays->fPrimitiveProcessorTextures;
         for (int i = 0; i < n; ++i) {
             textures[i]->unref();
         }
     }
 }
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/gpu/GrOpFlushState.h"

	#include "include/gpu/GrTexture.h"
	#include "src/core/SkConvertPixels.h"
	#include "src/gpu/GrContextPriv.h"
	#include "src/gpu/GrDrawOpAtlas.h"
	#include "src/gpu/GrGpu.h"
	#include "src/gpu/GrResourceProvider.h"

	//////////////////////////////////////////////////////////////////////////////

	GrOpFlushState::GrOpFlushState(GrGpu* gpu, GrResourceProvider* resourceProvider,
	GrTokenTracker* tokenTracker,
	sk_sp<GrBufferAllocPool::CpuBufferCache> cpuBufferCache)
	: fVertexPool(gpu, cpuBufferCache)
	, fIndexPool(gpu, std::move(cpuBufferCache))
	, fGpu(gpu)
	, fResourceProvider(resourceProvider)
	, fTokenTracker(tokenTracker)
	, fDeinstantiateProxyTracker() {}

	const GrCaps& GrOpFlushState::caps() const {
	return *fGpu->caps();
	}

	GrGpuRTCommandBuffer* GrOpFlushState::rtCommandBuffer() {
	return fCommandBuffer->asRTCommandBuffer();
	}

	void GrOpFlushState::executeDrawsAndUploadsForMeshDrawOp(
	const GrOp* op, const SkRect& chainBounds, GrProcessorSet&& processorSet,
	GrPipeline::InputFlags pipelineFlags, const GrUserStencilSettings* stencilSettings) {
	SkASSERT(this->rtCommandBuffer());

	GrPipeline::InitArgs pipelineArgs;
	pipelineArgs.fInputFlags = pipelineFlags;
	pipelineArgs.fDstProxy = this->dstProxy();
	pipelineArgs.fCaps = &this->caps();
	pipelineArgs.fUserStencil = stencilSettings;
	pipelineArgs.fOutputSwizzle = this->drawOpArgs().fOutputSwizzle;
	GrPipeline* pipeline = this->allocator()->make<GrPipeline>(pipelineArgs,
	std::move(processorSet),
	this->detachAppliedClip());

	while (fCurrDraw != fDraws.end() && fCurrDraw->fOp == op) {
	GrDeferredUploadToken drawToken = fTokenTracker->nextTokenToFlush();
	while (fCurrUpload != fInlineUploads.end() &&
	fCurrUpload->fUploadBeforeToken == drawToken) {
	this->rtCommandBuffer()->inlineUpload(this, fCurrUpload->fUpload);
	++fCurrUpload;
	}
	this->rtCommandBuffer()->draw(
	fCurrDraw->fGeometryProcessor, pipeline, fCurrDraw->fFixedDynamicState,
	fCurrDraw->fDynamicStateArrays, fCurrDraw->fMeshes, fCurrDraw->fMeshCnt,
	chainBounds);
	fTokenTracker->flushToken();
	++fCurrDraw;
	}
	}

	void GrOpFlushState::preExecuteDraws() {
	fVertexPool.unmap();
	fIndexPool.unmap();
	for (auto& upload : fASAPUploads) {
	this->doUpload(upload);
	}
	// Setup execution iterators.
	fCurrDraw = fDraws.begin();
	fCurrUpload = fInlineUploads.begin();
	}

	void GrOpFlushState::reset() {
	SkASSERT(fCurrDraw == fDraws.end());
	SkASSERT(fCurrUpload == fInlineUploads.end());
	fVertexPool.reset();
	fIndexPool.reset();
	fArena.reset();
	fASAPUploads.reset();
	fInlineUploads.reset();
	fDraws.reset();
	fBaseDrawToken = GrDeferredUploadToken::AlreadyFlushedToken();
	}

	void GrOpFlushState::doUpload(GrDeferredTextureUploadFn& upload) {
	GrDeferredTextureUploadWritePixelsFn wp = [this](GrTextureProxy* dstProxy, int left, int top,
	int width, int height, GrColorType colorType,
	const void* buffer, size_t rowBytes) {
	GrSurface* dstSurface = dstProxy->peekSurface();
	if (!fGpu->caps()->surfaceSupportsWritePixels(dstSurface)) {
	return false;
	}
	GrCaps::SupportedWrite supportedWrite = fGpu->caps()->supportedWritePixelsColorType(
	colorType, dstSurface->backendFormat(), colorType);
	size_t tightRB = width * GrColorTypeBytesPerPixel(supportedWrite.fColorType);
	SkASSERT(rowBytes >= tightRB);
	std::unique_ptr<char[]> tmpPixels;
	if (supportedWrite.fColorType != colorType \|\|
	(!fGpu->caps()->writePixelsRowBytesSupport() && rowBytes != tightRB)) {
	tmpPixels.reset(new char[height * tightRB]);
	// Use kUnpremul to ensure no alpha type conversions or clamping occur.
	static constexpr auto kAT = kUnpremul_SkAlphaType;
	GrPixelInfo srcInfo(colorType, kAT, nullptr, width, height);
	GrPixelInfo tmpInfo(supportedWrite.fColorType, kAT, nullptr, width,
	height);
	if (!GrConvertPixels(tmpInfo, tmpPixels.get(), tightRB, srcInfo, buffer, rowBytes)) {
	return false;
	}
	rowBytes = tightRB;
	buffer = tmpPixels.get();
	}
	return this->fGpu->writePixels(dstSurface, left, top, width, height, colorType,
	supportedWrite.fColorType, buffer, rowBytes);
	};
	upload(wp);
	}

	GrDeferredUploadToken GrOpFlushState::addInlineUpload(GrDeferredTextureUploadFn&& upload) {
	return fInlineUploads.append(&fArena, std::move(upload), fTokenTracker->nextDrawToken())
	.fUploadBeforeToken;
	}

	GrDeferredUploadToken GrOpFlushState::addASAPUpload(GrDeferredTextureUploadFn&& upload) {
	fASAPUploads.append(&fArena, std::move(upload));
	return fTokenTracker->nextTokenToFlush();
	}

	void GrOpFlushState::recordDraw(
	sk_sp<const GrGeometryProcessor> gp, const GrMesh meshes[], int meshCnt,
	const GrPipeline::FixedDynamicState* fixedDynamicState,
	const GrPipeline::DynamicStateArrays* dynamicStateArrays) {
	SkASSERT(fOpArgs);
	SkASSERT(fOpArgs->fOp);
	bool firstDraw = fDraws.begin() == fDraws.end();
	auto& draw = fDraws.append(&fArena);
	GrDeferredUploadToken token = fTokenTracker->issueDrawToken();
	if (fixedDynamicState && fixedDynamicState->fPrimitiveProcessorTextures) {
	for (int i = 0; i < gp->numTextureSamplers(); ++i) {
	fixedDynamicState->fPrimitiveProcessorTextures[i]->ref();
	}
	}
	if (dynamicStateArrays && dynamicStateArrays->fPrimitiveProcessorTextures) {
	int n = gp->numTextureSamplers() * meshCnt;
	for (int i = 0; i < n; ++i) {
	dynamicStateArrays->fPrimitiveProcessorTextures[i]->ref();
	}
	}
	draw.fGeometryProcessor = std::move(gp);
	draw.fFixedDynamicState = fixedDynamicState;
	draw.fDynamicStateArrays = dynamicStateArrays;
	draw.fMeshes = meshes;
	draw.fMeshCnt = meshCnt;
	draw.fOp = fOpArgs->fOp;
	if (firstDraw) {
	fBaseDrawToken = token;
	}
	}

	void* GrOpFlushState::makeVertexSpace(size_t vertexSize, int vertexCount,
	sk_sp<const GrBuffer>* buffer, int* startVertex) {
	return fVertexPool.makeSpace(vertexSize, vertexCount, buffer, startVertex);
	}

	uint16_t* GrOpFlushState::makeIndexSpace(int indexCount, sk_sp<const GrBuffer>* buffer,
	int* startIndex) {
	return reinterpret_cast<uint16_t*>(fIndexPool.makeSpace(indexCount, buffer, startIndex));
	}

	void* GrOpFlushState::makeVertexSpaceAtLeast(size_t vertexSize, int minVertexCount,
	int fallbackVertexCount, sk_sp<const GrBuffer>* buffer,
	int* startVertex, int* actualVertexCount) {
	return fVertexPool.makeSpaceAtLeast(vertexSize, minVertexCount, fallbackVertexCount, buffer,
	startVertex, actualVertexCount);
	}

	uint16_t* GrOpFlushState::makeIndexSpaceAtLeast(int minIndexCount, int fallbackIndexCount,
	sk_sp<const GrBuffer>* buffer, int* startIndex,
	int* actualIndexCount) {
	return reinterpret_cast<uint16_t*>(fIndexPool.makeSpaceAtLeast(
	minIndexCount, fallbackIndexCount, buffer, startIndex, actualIndexCount));
	}

	void GrOpFlushState::putBackIndices(int indexCount) {
	fIndexPool.putBack(indexCount * sizeof(uint16_t));
	}

	void GrOpFlushState::putBackVertices(int vertices, size_t vertexStride) {
	fVertexPool.putBack(vertices * vertexStride);
	}

	GrAppliedClip GrOpFlushState::detachAppliedClip() {
	return fOpArgs->fAppliedClip ? std::move(*fOpArgs->fAppliedClip) : GrAppliedClip();
	}

	GrStrikeCache* GrOpFlushState::glyphCache() const {
	return fGpu->getContext()->priv().getGrStrikeCache();
	}

	GrAtlasManager* GrOpFlushState::atlasManager() const {
	return fGpu->getContext()->priv().getAtlasManager();
	}

	//////////////////////////////////////////////////////////////////////////////

	GrOpFlushState::Draw::~Draw() {
	if (fFixedDynamicState && fFixedDynamicState->fPrimitiveProcessorTextures) {
	for (int i = 0; i < fGeometryProcessor->numTextureSamplers(); ++i) {
	fFixedDynamicState->fPrimitiveProcessorTextures[i]->unref();
	}
	}
	if (fDynamicStateArrays && fDynamicStateArrays->fPrimitiveProcessorTextures) {
	int n = fGeometryProcessor->numTextureSamplers() * fMeshCnt;
	const auto* textures = fDynamicStateArrays->fPrimitiveProcessorTextures;
	for (int i = 0; i < n; ++i) {
	textures[i]->unref();
	}
	}
	}