src/gpu/GrGpu.cpp - platform/external/skia - Gitiles


 /*
  * Copyright 2010 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */


 #include "GrGpu.h"

 #include "GrBufferAllocPool.h"
 #include "GrContext.h"
 #include "GrIndexBuffer.h"
 #include "GrStencilBuffer.h"
 #include "GrVertexBuffer.h"

 // probably makes no sense for this to be less than a page
 static const size_t VERTEX_POOL_VB_SIZE = 1 << 18;
 static const int VERTEX_POOL_VB_COUNT = 4;
 static const size_t INDEX_POOL_IB_SIZE = 1 << 16;
 static const int INDEX_POOL_IB_COUNT = 4;

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

 extern void gr_run_unittests();

 #define DEBUG_INVAL_BUFFER    0xdeadcafe
 #define DEBUG_INVAL_START_IDX -1

 GrGpu::GrGpu()
     : fContext(NULL)
     , fResetTimestamp(kExpiredTimestamp+1)
     , fVertexPool(NULL)
     , fIndexPool(NULL)
     , fVertexPoolUseCnt(0)
     , fIndexPoolUseCnt(0)
     , fQuadIndexBuffer(NULL)
     , fUnitSquareVertexBuffer(NULL)
     , fContextIsDirty(true) {

     fClipMaskManager.setGpu(this);

 #if GR_DEBUG
     //gr_run_unittests();
 #endif

     fGeomPoolStateStack.push_back();
 #if GR_DEBUG
     GeometryPoolState& poolState = fGeomPoolStateStack.back();
     poolState.fPoolVertexBuffer = (GrVertexBuffer*)DEBUG_INVAL_BUFFER;
     poolState.fPoolStartVertex = DEBUG_INVAL_START_IDX;
     poolState.fPoolIndexBuffer = (GrIndexBuffer*)DEBUG_INVAL_BUFFER;
     poolState.fPoolStartIndex = DEBUG_INVAL_START_IDX;
 #endif

     for (int i = 0; i < kGrPixelConfigCount; ++i) {
         fConfigRenderSupport[i] = false;
     };
 }

 GrGpu::~GrGpu() {
     this->releaseResources();
 }

 void GrGpu::abandonResources() {

     fClipMaskManager.releaseResources();

     while (NULL != fResourceList.head()) {
         fResourceList.head()->abandon();
     }

     GrAssert(NULL == fQuadIndexBuffer || !fQuadIndexBuffer->isValid());
     GrAssert(NULL == fUnitSquareVertexBuffer ||
              !fUnitSquareVertexBuffer->isValid());
     GrSafeSetNull(fQuadIndexBuffer);
     GrSafeSetNull(fUnitSquareVertexBuffer);
     delete fVertexPool;
     fVertexPool = NULL;
     delete fIndexPool;
     fIndexPool = NULL;
 }

 void GrGpu::releaseResources() {

     fClipMaskManager.releaseResources();

     while (NULL != fResourceList.head()) {
         fResourceList.head()->release();
     }

     GrAssert(NULL == fQuadIndexBuffer || !fQuadIndexBuffer->isValid());
     GrAssert(NULL == fUnitSquareVertexBuffer ||
              !fUnitSquareVertexBuffer->isValid());
     GrSafeSetNull(fQuadIndexBuffer);
     GrSafeSetNull(fUnitSquareVertexBuffer);
     delete fVertexPool;
     fVertexPool = NULL;
     delete fIndexPool;
     fIndexPool = NULL;
 }

 void GrGpu::insertResource(GrResource* resource) {
     GrAssert(NULL != resource);
     GrAssert(this == resource->getGpu());

     fResourceList.addToHead(resource);
 }

 void GrGpu::removeResource(GrResource* resource) {
     GrAssert(NULL != resource);
     GrAssert(this == resource->getGpu());

     fResourceList.remove(resource);
 }


 void GrGpu::unimpl(const char msg[]) {
 #if GR_DEBUG
     GrPrintf("--- GrGpu unimplemented(\"%s\")\n", msg);
 #endif
 }

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

 GrTexture* GrGpu::createTexture(const GrTextureDesc& desc,
                                 const void* srcData, size_t rowBytes) {
     this->handleDirtyContext();
     GrTexture* tex = this->onCreateTexture(desc, srcData, rowBytes);
     if (NULL != tex &&
         (kRenderTarget_GrTextureFlagBit & desc.fFlags) &&
         !(kNoStencil_GrTextureFlagBit & desc.fFlags)) {
         GrAssert(NULL != tex->asRenderTarget());
         // TODO: defer this and attach dynamically
         if (!this->attachStencilBufferToRenderTarget(tex->asRenderTarget())) {
             tex->unref();
             return NULL;
         }
     }
     return tex;
 }

 bool GrGpu::attachStencilBufferToRenderTarget(GrRenderTarget* rt) {
     GrAssert(NULL == rt->getStencilBuffer());
     GrStencilBuffer* sb =
         this->getContext()->findStencilBuffer(rt->width(),
                                               rt->height(),
                                               rt->numSamples());
     if (NULL != sb) {
         rt->setStencilBuffer(sb);
         bool attached = this->attachStencilBufferToRenderTarget(sb, rt);
         if (!attached) {
             rt->setStencilBuffer(NULL);
         }
         return attached;
     }
     if (this->createStencilBufferForRenderTarget(rt,
                                                  rt->width(), rt->height())) {
         // Right now we're clearing the stencil buffer here after it is
         // attached to an RT for the first time. When we start matching
         // stencil buffers with smaller color targets this will no longer
         // be correct because it won't be guaranteed to clear the entire
         // sb.
         // We used to clear down in the GL subclass using a special purpose
         // FBO. But iOS doesn't allow a stencil-only FBO. It reports unsupported
         // FBO status.
         GrDrawState::AutoRenderTargetRestore artr(this->drawState(), rt);
         this->clearStencil();
         return true;
     } else {
         return false;
     }
 }

 GrTexture* GrGpu::wrapBackendTexture(const GrBackendTextureDesc& desc) {
     this->handleDirtyContext();
     GrTexture* tex = this->onWrapBackendTexture(desc);
     if (NULL == tex) {
         return NULL;
     }
     // TODO: defer this and attach dynamically
     GrRenderTarget* tgt = tex->asRenderTarget();
     if (NULL != tgt &&
         !this->attachStencilBufferToRenderTarget(tgt)) {
         tex->unref();
         return NULL;
     } else {
         return tex;
     }
 }

 GrRenderTarget* GrGpu::wrapBackendRenderTarget(const GrBackendRenderTargetDesc& desc) {
     this->handleDirtyContext();
     return this->onWrapBackendRenderTarget(desc);
 }

 GrVertexBuffer* GrGpu::createVertexBuffer(uint32_t size, bool dynamic) {
     this->handleDirtyContext();
     return this->onCreateVertexBuffer(size, dynamic);
 }

 GrIndexBuffer* GrGpu::createIndexBuffer(uint32_t size, bool dynamic) {
     this->handleDirtyContext();
     return this->onCreateIndexBuffer(size, dynamic);
 }

 GrPath* GrGpu::createPath(const SkPath& path) {
     GrAssert(fCaps.pathStencilingSupport());
     this->handleDirtyContext();
     return this->onCreatePath(path);
 }

 void GrGpu::clear(const GrIRect* rect,
                   GrColor color,
                   GrRenderTarget* renderTarget) {
     GrDrawState::AutoRenderTargetRestore art;
     if (NULL != renderTarget) {
         art.set(this->drawState(), renderTarget);
     }
     if (NULL == this->getDrawState().getRenderTarget()) {
         return;
     }
     this->handleDirtyContext();
     this->onClear(rect, color);
 }

 void GrGpu::forceRenderTargetFlush() {
     this->handleDirtyContext();
     this->onForceRenderTargetFlush();
 }

 bool GrGpu::readPixels(GrRenderTarget* target,
                        int left, int top, int width, int height,
                        GrPixelConfig config, void* buffer,
                        size_t rowBytes, bool invertY) {
     this->handleDirtyContext();
     return this->onReadPixels(target, left, top, width, height,
                               config, buffer, rowBytes, invertY);
 }

 void GrGpu::writeTexturePixels(GrTexture* texture,
                                int left, int top, int width, int height,
                                GrPixelConfig config, const void* buffer,
                                size_t rowBytes) {
     this->handleDirtyContext();
     this->onWriteTexturePixels(texture, left, top, width, height,
                                config, buffer, rowBytes);
 }

 void GrGpu::resolveRenderTarget(GrRenderTarget* target) {
     GrAssert(target);
     this->handleDirtyContext();
     this->onResolveRenderTarget(target);
 }


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

 static const int MAX_QUADS = 1 << 12; // max possible: (1 << 14) - 1;

 GR_STATIC_ASSERT(4 * MAX_QUADS <= 65535);

 static inline void fill_indices(uint16_t* indices, int quadCount) {
     for (int i = 0; i < quadCount; ++i) {
         indices[6 * i + 0] = 4 * i + 0;
         indices[6 * i + 1] = 4 * i + 1;
         indices[6 * i + 2] = 4 * i + 2;
         indices[6 * i + 3] = 4 * i + 0;
         indices[6 * i + 4] = 4 * i + 2;
         indices[6 * i + 5] = 4 * i + 3;
     }
 }

 const GrIndexBuffer* GrGpu::getQuadIndexBuffer() const {
     if (NULL == fQuadIndexBuffer) {
         static const int SIZE = sizeof(uint16_t) * 6 * MAX_QUADS;
         GrGpu* me = const_cast<GrGpu*>(this);
         fQuadIndexBuffer = me->createIndexBuffer(SIZE, false);
         if (NULL != fQuadIndexBuffer) {
             uint16_t* indices = (uint16_t*)fQuadIndexBuffer->lock();
             if (NULL != indices) {
                 fill_indices(indices, MAX_QUADS);
                 fQuadIndexBuffer->unlock();
             } else {
                 indices = (uint16_t*)GrMalloc(SIZE);
                 fill_indices(indices, MAX_QUADS);
                 if (!fQuadIndexBuffer->updateData(indices, SIZE)) {
                     fQuadIndexBuffer->unref();
                     fQuadIndexBuffer = NULL;
                     GrCrash("Can't get indices into buffer!");
                 }
                 GrFree(indices);
             }
         }
     }

     return fQuadIndexBuffer;
 }

 const GrVertexBuffer* GrGpu::getUnitSquareVertexBuffer() const {
     if (NULL == fUnitSquareVertexBuffer) {

         static const GrPoint DATA[] = {
             { 0,            0 },
             { GR_Scalar1,   0 },
             { GR_Scalar1,   GR_Scalar1 },
             { 0,            GR_Scalar1 }
 #if 0
             GrPoint(0,         0),
             GrPoint(GR_Scalar1,0),
             GrPoint(GR_Scalar1,GR_Scalar1),
             GrPoint(0,         GR_Scalar1)
 #endif
         };
         static const size_t SIZE = sizeof(DATA);

         GrGpu* me = const_cast<GrGpu*>(this);
         fUnitSquareVertexBuffer = me->createVertexBuffer(SIZE, false);
         if (NULL != fUnitSquareVertexBuffer) {
             if (!fUnitSquareVertexBuffer->updateData(DATA, SIZE)) {
                 fUnitSquareVertexBuffer->unref();
                 fUnitSquareVertexBuffer = NULL;
                 GrCrash("Can't get vertices into buffer!");
             }
         }
     }

     return fUnitSquareVertexBuffer;
 }

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

 bool GrGpu::setupClipAndFlushState(DrawType type) {

     if (!fClipMaskManager.setupClipping(fClip)) {
         return false;
     }

     if (!this->flushGraphicsState(type)) {
         return false;
     }

     return true;
 }

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

 void GrGpu::geometrySourceWillPush() {
     const GeometrySrcState& geoSrc = this->getGeomSrc();
     if (kArray_GeometrySrcType == geoSrc.fVertexSrc ||
         kReserved_GeometrySrcType == geoSrc.fVertexSrc) {
         this->finalizeReservedVertices();
     }
     if (kArray_GeometrySrcType == geoSrc.fIndexSrc ||
         kReserved_GeometrySrcType == geoSrc.fIndexSrc) {
         this->finalizeReservedIndices();
     }
     GeometryPoolState& newState = fGeomPoolStateStack.push_back();
 #if GR_DEBUG
     newState.fPoolVertexBuffer = (GrVertexBuffer*)DEBUG_INVAL_BUFFER;
     newState.fPoolStartVertex = DEBUG_INVAL_START_IDX;
     newState.fPoolIndexBuffer = (GrIndexBuffer*)DEBUG_INVAL_BUFFER;
     newState.fPoolStartIndex = DEBUG_INVAL_START_IDX;
 #endif
 }

 void GrGpu::geometrySourceWillPop(const GeometrySrcState& restoredState) {
     // if popping last entry then pops are unbalanced with pushes
     GrAssert(fGeomPoolStateStack.count() > 1);
     fGeomPoolStateStack.pop_back();
 }

 void GrGpu::onDrawIndexed(GrPrimitiveType type,
                           int startVertex,
                           int startIndex,
                           int vertexCount,
                           int indexCount) {

     this->handleDirtyContext();

     if (!this->setupClipAndFlushState(PrimTypeToDrawType(type))) {
         return;
     }

     int sVertex = startVertex;
     int sIndex = startIndex;
     setupGeometry(&sVertex, &sIndex, vertexCount, indexCount);

     this->onGpuDrawIndexed(type, sVertex, sIndex,
                            vertexCount, indexCount);
 }

 void GrGpu::onDrawNonIndexed(GrPrimitiveType type,
                              int startVertex,
                              int vertexCount) {
     this->handleDirtyContext();

     if (!this->setupClipAndFlushState(PrimTypeToDrawType(type))) {
         return;
     }

     int sVertex = startVertex;
     setupGeometry(&sVertex, NULL, vertexCount, 0);

     this->onGpuDrawNonIndexed(type, sVertex, vertexCount);
 }

 void GrGpu::onStencilPath(const GrPath* path, GrPathFill fill) {
     this->handleDirtyContext();

     // TODO: make this more effecient (don't copy and copy back)
     GrAutoTRestore<GrStencilSettings> asr(this->drawState()->stencil());

     this->setStencilPathSettings(*path, fill, this->drawState()->stencil());
     if (!this->setupClipAndFlushState(kStencilPath_DrawType)) {
         return;
     }

     this->onGpuStencilPath(path, fill);
 }

 void GrGpu::finalizeReservedVertices() {
     GrAssert(NULL != fVertexPool);
     fVertexPool->unlock();
 }

 void GrGpu::finalizeReservedIndices() {
     GrAssert(NULL != fIndexPool);
     fIndexPool->unlock();
 }

 void GrGpu::prepareVertexPool() {
     if (NULL == fVertexPool) {
         GrAssert(0 == fVertexPoolUseCnt);
         fVertexPool = SkNEW_ARGS(GrVertexBufferAllocPool, (this, true,
                                                   VERTEX_POOL_VB_SIZE,
                                                   VERTEX_POOL_VB_COUNT));
         fVertexPool->releaseGpuRef();
     } else if (!fVertexPoolUseCnt) {
         // the client doesn't have valid data in the pool
         fVertexPool->reset();
     }
 }

 void GrGpu::prepareIndexPool() {
     if (NULL == fIndexPool) {
         GrAssert(0 == fIndexPoolUseCnt);
         fIndexPool = SkNEW_ARGS(GrIndexBufferAllocPool, (this, true,
                                                 INDEX_POOL_IB_SIZE,
                                                 INDEX_POOL_IB_COUNT));
         fIndexPool->releaseGpuRef();
     } else if (!fIndexPoolUseCnt) {
         // the client doesn't have valid data in the pool
         fIndexPool->reset();
     }
 }

 bool GrGpu::onReserveVertexSpace(GrVertexLayout vertexLayout,
                                  int vertexCount,
                                  void** vertices) {
     GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();

     GrAssert(vertexCount > 0);
     GrAssert(NULL != vertices);

     this->prepareVertexPool();

     *vertices = fVertexPool->makeSpace(vertexLayout,
                                        vertexCount,
                                        &geomPoolState.fPoolVertexBuffer,
                                        &geomPoolState.fPoolStartVertex);
     if (NULL == *vertices) {
         return false;
     }
     ++fVertexPoolUseCnt;
     return true;
 }

 bool GrGpu::onReserveIndexSpace(int indexCount, void** indices) {
     GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();

     GrAssert(indexCount > 0);
     GrAssert(NULL != indices);

     this->prepareIndexPool();

     *indices = fIndexPool->makeSpace(indexCount,
                                      &geomPoolState.fPoolIndexBuffer,
                                      &geomPoolState.fPoolStartIndex);
     if (NULL == *indices) {
         return false;
     }
     ++fIndexPoolUseCnt;
     return true;
 }

 void GrGpu::releaseReservedVertexSpace() {
     const GeometrySrcState& geoSrc = this->getGeomSrc();
     GrAssert(kReserved_GeometrySrcType == geoSrc.fVertexSrc);
     size_t bytes = geoSrc.fVertexCount * VertexSize(geoSrc.fVertexLayout);
     fVertexPool->putBack(bytes);
     --fVertexPoolUseCnt;
 }

 void GrGpu::releaseReservedIndexSpace() {
     const GeometrySrcState& geoSrc = this->getGeomSrc();
     GrAssert(kReserved_GeometrySrcType == geoSrc.fIndexSrc);
     size_t bytes = geoSrc.fIndexCount * sizeof(uint16_t);
     fIndexPool->putBack(bytes);
     --fIndexPoolUseCnt;
 }

 void GrGpu::onSetVertexSourceToArray(const void* vertexArray, int vertexCount) {
     this->prepareVertexPool();
     GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();
 #if GR_DEBUG
     bool success =
 #endif
     fVertexPool->appendVertices(this->getVertexLayout(),
                                 vertexCount,
                                 vertexArray,
                                 &geomPoolState.fPoolVertexBuffer,
                                 &geomPoolState.fPoolStartVertex);
     ++fVertexPoolUseCnt;
     GR_DEBUGASSERT(success);
 }

 void GrGpu::onSetIndexSourceToArray(const void* indexArray, int indexCount) {
     this->prepareIndexPool();
     GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();
 #if GR_DEBUG
     bool success =
 #endif
     fIndexPool->appendIndices(indexCount,
                               indexArray,
                               &geomPoolState.fPoolIndexBuffer,
                               &geomPoolState.fPoolStartIndex);
     ++fIndexPoolUseCnt;
     GR_DEBUGASSERT(success);
 }

 void GrGpu::releaseVertexArray() {
     // if vertex source was array, we stowed data in the pool
     const GeometrySrcState& geoSrc = this->getGeomSrc();
     GrAssert(kArray_GeometrySrcType == geoSrc.fVertexSrc);
     size_t bytes = geoSrc.fVertexCount * VertexSize(geoSrc.fVertexLayout);
     fVertexPool->putBack(bytes);
     --fVertexPoolUseCnt;
 }

 void GrGpu::releaseIndexArray() {
     // if index source was array, we stowed data in the pool
     const GeometrySrcState& geoSrc = this->getGeomSrc();
     GrAssert(kArray_GeometrySrcType == geoSrc.fIndexSrc);
     size_t bytes = geoSrc.fIndexCount * sizeof(uint16_t);
     fIndexPool->putBack(bytes);
     --fIndexPoolUseCnt;
 }

	/*
	* Copyright 2010 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/


	#include "GrGpu.h"

	#include "GrBufferAllocPool.h"
	#include "GrContext.h"
	#include "GrIndexBuffer.h"
	#include "GrStencilBuffer.h"
	#include "GrVertexBuffer.h"

	// probably makes no sense for this to be less than a page
	static const size_t VERTEX_POOL_VB_SIZE = 1 << 18;
	static const int VERTEX_POOL_VB_COUNT = 4;
	static const size_t INDEX_POOL_IB_SIZE = 1 << 16;
	static const int INDEX_POOL_IB_COUNT = 4;

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

	extern void gr_run_unittests();

	#define DEBUG_INVAL_BUFFER 0xdeadcafe
	#define DEBUG_INVAL_START_IDX -1

	GrGpu::GrGpu()
	: fContext(NULL)
	, fResetTimestamp(kExpiredTimestamp+1)
	, fVertexPool(NULL)
	, fIndexPool(NULL)
	, fVertexPoolUseCnt(0)
	, fIndexPoolUseCnt(0)
	, fQuadIndexBuffer(NULL)
	, fUnitSquareVertexBuffer(NULL)
	, fContextIsDirty(true) {

	fClipMaskManager.setGpu(this);

	#if GR_DEBUG
	//gr_run_unittests();
	#endif

	fGeomPoolStateStack.push_back();
	#if GR_DEBUG
	GeometryPoolState& poolState = fGeomPoolStateStack.back();
	poolState.fPoolVertexBuffer = (GrVertexBuffer*)DEBUG_INVAL_BUFFER;
	poolState.fPoolStartVertex = DEBUG_INVAL_START_IDX;
	poolState.fPoolIndexBuffer = (GrIndexBuffer*)DEBUG_INVAL_BUFFER;
	poolState.fPoolStartIndex = DEBUG_INVAL_START_IDX;
	#endif

	for (int i = 0; i < kGrPixelConfigCount; ++i) {
	fConfigRenderSupport[i] = false;
	};
	}

	GrGpu::~GrGpu() {
	this->releaseResources();
	}

	void GrGpu::abandonResources() {

	fClipMaskManager.releaseResources();

	while (NULL != fResourceList.head()) {
	fResourceList.head()->abandon();
	}

	GrAssert(NULL == fQuadIndexBuffer \|\| !fQuadIndexBuffer->isValid());
	GrAssert(NULL == fUnitSquareVertexBuffer \|\|
	!fUnitSquareVertexBuffer->isValid());
	GrSafeSetNull(fQuadIndexBuffer);
	GrSafeSetNull(fUnitSquareVertexBuffer);
	delete fVertexPool;
	fVertexPool = NULL;
	delete fIndexPool;
	fIndexPool = NULL;
	}

	void GrGpu::releaseResources() {

	fClipMaskManager.releaseResources();

	while (NULL != fResourceList.head()) {
	fResourceList.head()->release();
	}

	GrAssert(NULL == fQuadIndexBuffer \|\| !fQuadIndexBuffer->isValid());
	GrAssert(NULL == fUnitSquareVertexBuffer \|\|
	!fUnitSquareVertexBuffer->isValid());
	GrSafeSetNull(fQuadIndexBuffer);
	GrSafeSetNull(fUnitSquareVertexBuffer);
	delete fVertexPool;
	fVertexPool = NULL;
	delete fIndexPool;
	fIndexPool = NULL;
	}

	void GrGpu::insertResource(GrResource* resource) {
	GrAssert(NULL != resource);
	GrAssert(this == resource->getGpu());

	fResourceList.addToHead(resource);
	}

	void GrGpu::removeResource(GrResource* resource) {
	GrAssert(NULL != resource);
	GrAssert(this == resource->getGpu());

	fResourceList.remove(resource);
	}


	void GrGpu::unimpl(const char msg[]) {
	#if GR_DEBUG
	GrPrintf("--- GrGpu unimplemented(\"%s\")\n", msg);
	#endif
	}

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

	GrTexture* GrGpu::createTexture(const GrTextureDesc& desc,
	const void* srcData, size_t rowBytes) {
	this->handleDirtyContext();
	GrTexture* tex = this->onCreateTexture(desc, srcData, rowBytes);
	if (NULL != tex &&
	(kRenderTarget_GrTextureFlagBit & desc.fFlags) &&
	!(kNoStencil_GrTextureFlagBit & desc.fFlags)) {
	GrAssert(NULL != tex->asRenderTarget());
	// TODO: defer this and attach dynamically
	if (!this->attachStencilBufferToRenderTarget(tex->asRenderTarget())) {
	tex->unref();
	return NULL;
	}
	}
	return tex;
	}

	bool GrGpu::attachStencilBufferToRenderTarget(GrRenderTarget* rt) {
	GrAssert(NULL == rt->getStencilBuffer());
	GrStencilBuffer* sb =
	this->getContext()->findStencilBuffer(rt->width(),
	rt->height(),
	rt->numSamples());
	if (NULL != sb) {
	rt->setStencilBuffer(sb);
	bool attached = this->attachStencilBufferToRenderTarget(sb, rt);
	if (!attached) {
	rt->setStencilBuffer(NULL);
	}
	return attached;
	}
	if (this->createStencilBufferForRenderTarget(rt,
	rt->width(), rt->height())) {
	// Right now we're clearing the stencil buffer here after it is
	// attached to an RT for the first time. When we start matching
	// stencil buffers with smaller color targets this will no longer
	// be correct because it won't be guaranteed to clear the entire
	// sb.
	// We used to clear down in the GL subclass using a special purpose
	// FBO. But iOS doesn't allow a stencil-only FBO. It reports unsupported
	// FBO status.
	GrDrawState::AutoRenderTargetRestore artr(this->drawState(), rt);
	this->clearStencil();
	return true;
	} else {
	return false;
	}
	}

	GrTexture* GrGpu::wrapBackendTexture(const GrBackendTextureDesc& desc) {
	this->handleDirtyContext();
	GrTexture* tex = this->onWrapBackendTexture(desc);
	if (NULL == tex) {
	return NULL;
	}
	// TODO: defer this and attach dynamically
	GrRenderTarget* tgt = tex->asRenderTarget();
	if (NULL != tgt &&
	!this->attachStencilBufferToRenderTarget(tgt)) {
	tex->unref();
	return NULL;
	} else {
	return tex;
	}
	}

	GrRenderTarget* GrGpu::wrapBackendRenderTarget(const GrBackendRenderTargetDesc& desc) {
	this->handleDirtyContext();
	return this->onWrapBackendRenderTarget(desc);
	}

	GrVertexBuffer* GrGpu::createVertexBuffer(uint32_t size, bool dynamic) {
	this->handleDirtyContext();
	return this->onCreateVertexBuffer(size, dynamic);
	}

	GrIndexBuffer* GrGpu::createIndexBuffer(uint32_t size, bool dynamic) {
	this->handleDirtyContext();
	return this->onCreateIndexBuffer(size, dynamic);
	}

	GrPath* GrGpu::createPath(const SkPath& path) {
	GrAssert(fCaps.pathStencilingSupport());
	this->handleDirtyContext();
	return this->onCreatePath(path);
	}

	void GrGpu::clear(const GrIRect* rect,
	GrColor color,
	GrRenderTarget* renderTarget) {
	GrDrawState::AutoRenderTargetRestore art;
	if (NULL != renderTarget) {
	art.set(this->drawState(), renderTarget);
	}
	if (NULL == this->getDrawState().getRenderTarget()) {
	return;
	}
	this->handleDirtyContext();
	this->onClear(rect, color);
	}

	void GrGpu::forceRenderTargetFlush() {
	this->handleDirtyContext();
	this->onForceRenderTargetFlush();
	}

	bool GrGpu::readPixels(GrRenderTarget* target,
	int left, int top, int width, int height,
	GrPixelConfig config, void* buffer,
	size_t rowBytes, bool invertY) {
	this->handleDirtyContext();
	return this->onReadPixels(target, left, top, width, height,
	config, buffer, rowBytes, invertY);
	}

	void GrGpu::writeTexturePixels(GrTexture* texture,
	int left, int top, int width, int height,
	GrPixelConfig config, const void* buffer,
	size_t rowBytes) {
	this->handleDirtyContext();
	this->onWriteTexturePixels(texture, left, top, width, height,
	config, buffer, rowBytes);
	}

	void GrGpu::resolveRenderTarget(GrRenderTarget* target) {
	GrAssert(target);
	this->handleDirtyContext();
	this->onResolveRenderTarget(target);
	}


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

	static const int MAX_QUADS = 1 << 12; // max possible: (1 << 14) - 1;

	GR_STATIC_ASSERT(4 * MAX_QUADS <= 65535);

	static inline void fill_indices(uint16_t* indices, int quadCount) {
	for (int i = 0; i < quadCount; ++i) {
	indices[6 * i + 0] = 4 * i + 0;
	indices[6 * i + 1] = 4 * i + 1;
	indices[6 * i + 2] = 4 * i + 2;
	indices[6 * i + 3] = 4 * i + 0;
	indices[6 * i + 4] = 4 * i + 2;
	indices[6 * i + 5] = 4 * i + 3;
	}
	}

	const GrIndexBuffer* GrGpu::getQuadIndexBuffer() const {
	if (NULL == fQuadIndexBuffer) {
	static const int SIZE = sizeof(uint16_t) * 6 * MAX_QUADS;
	GrGpu* me = const_cast<GrGpu*>(this);
	fQuadIndexBuffer = me->createIndexBuffer(SIZE, false);
	if (NULL != fQuadIndexBuffer) {
	uint16_t* indices = (uint16_t*)fQuadIndexBuffer->lock();
	if (NULL != indices) {
	fill_indices(indices, MAX_QUADS);
	fQuadIndexBuffer->unlock();
	} else {
	indices = (uint16_t*)GrMalloc(SIZE);
	fill_indices(indices, MAX_QUADS);
	if (!fQuadIndexBuffer->updateData(indices, SIZE)) {
	fQuadIndexBuffer->unref();
	fQuadIndexBuffer = NULL;
	GrCrash("Can't get indices into buffer!");
	}
	GrFree(indices);
	}
	}
	}

	return fQuadIndexBuffer;
	}

	const GrVertexBuffer* GrGpu::getUnitSquareVertexBuffer() const {
	if (NULL == fUnitSquareVertexBuffer) {

	static const GrPoint DATA[] = {
	{ 0, 0 },
	{ GR_Scalar1, 0 },
	{ GR_Scalar1, GR_Scalar1 },
	{ 0, GR_Scalar1 }
	#if 0
	GrPoint(0, 0),
	GrPoint(GR_Scalar1,0),
	GrPoint(GR_Scalar1,GR_Scalar1),
	GrPoint(0, GR_Scalar1)
	#endif
	};
	static const size_t SIZE = sizeof(DATA);

	GrGpu* me = const_cast<GrGpu*>(this);
	fUnitSquareVertexBuffer = me->createVertexBuffer(SIZE, false);
	if (NULL != fUnitSquareVertexBuffer) {
	if (!fUnitSquareVertexBuffer->updateData(DATA, SIZE)) {
	fUnitSquareVertexBuffer->unref();
	fUnitSquareVertexBuffer = NULL;
	GrCrash("Can't get vertices into buffer!");
	}
	}
	}

	return fUnitSquareVertexBuffer;
	}

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

	bool GrGpu::setupClipAndFlushState(DrawType type) {

	if (!fClipMaskManager.setupClipping(fClip)) {
	return false;
	}

	if (!this->flushGraphicsState(type)) {
	return false;
	}

	return true;
	}

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

	void GrGpu::geometrySourceWillPush() {
	const GeometrySrcState& geoSrc = this->getGeomSrc();
	if (kArray_GeometrySrcType == geoSrc.fVertexSrc \|\|
	kReserved_GeometrySrcType == geoSrc.fVertexSrc) {
	this->finalizeReservedVertices();
	}
	if (kArray_GeometrySrcType == geoSrc.fIndexSrc \|\|
	kReserved_GeometrySrcType == geoSrc.fIndexSrc) {
	this->finalizeReservedIndices();
	}
	GeometryPoolState& newState = fGeomPoolStateStack.push_back();
	#if GR_DEBUG
	newState.fPoolVertexBuffer = (GrVertexBuffer*)DEBUG_INVAL_BUFFER;
	newState.fPoolStartVertex = DEBUG_INVAL_START_IDX;
	newState.fPoolIndexBuffer = (GrIndexBuffer*)DEBUG_INVAL_BUFFER;
	newState.fPoolStartIndex = DEBUG_INVAL_START_IDX;
	#endif
	}

	void GrGpu::geometrySourceWillPop(const GeometrySrcState& restoredState) {
	// if popping last entry then pops are unbalanced with pushes
	GrAssert(fGeomPoolStateStack.count() > 1);
	fGeomPoolStateStack.pop_back();
	}

	void GrGpu::onDrawIndexed(GrPrimitiveType type,
	int startVertex,
	int startIndex,
	int vertexCount,
	int indexCount) {

	this->handleDirtyContext();

	if (!this->setupClipAndFlushState(PrimTypeToDrawType(type))) {
	return;
	}

	int sVertex = startVertex;
	int sIndex = startIndex;
	setupGeometry(&sVertex, &sIndex, vertexCount, indexCount);

	this->onGpuDrawIndexed(type, sVertex, sIndex,
	vertexCount, indexCount);
	}

	void GrGpu::onDrawNonIndexed(GrPrimitiveType type,
	int startVertex,
	int vertexCount) {
	this->handleDirtyContext();

	if (!this->setupClipAndFlushState(PrimTypeToDrawType(type))) {
	return;
	}

	int sVertex = startVertex;
	setupGeometry(&sVertex, NULL, vertexCount, 0);

	this->onGpuDrawNonIndexed(type, sVertex, vertexCount);
	}

	void GrGpu::onStencilPath(const GrPath* path, GrPathFill fill) {
	this->handleDirtyContext();

	// TODO: make this more effecient (don't copy and copy back)
	GrAutoTRestore<GrStencilSettings> asr(this->drawState()->stencil());

	this->setStencilPathSettings(*path, fill, this->drawState()->stencil());
	if (!this->setupClipAndFlushState(kStencilPath_DrawType)) {
	return;
	}

	this->onGpuStencilPath(path, fill);
	}

	void GrGpu::finalizeReservedVertices() {
	GrAssert(NULL != fVertexPool);
	fVertexPool->unlock();
	}

	void GrGpu::finalizeReservedIndices() {
	GrAssert(NULL != fIndexPool);
	fIndexPool->unlock();
	}

	void GrGpu::prepareVertexPool() {
	if (NULL == fVertexPool) {
	GrAssert(0 == fVertexPoolUseCnt);
	fVertexPool = SkNEW_ARGS(GrVertexBufferAllocPool, (this, true,
	VERTEX_POOL_VB_SIZE,
	VERTEX_POOL_VB_COUNT));
	fVertexPool->releaseGpuRef();
	} else if (!fVertexPoolUseCnt) {
	// the client doesn't have valid data in the pool
	fVertexPool->reset();
	}
	}

	void GrGpu::prepareIndexPool() {
	if (NULL == fIndexPool) {
	GrAssert(0 == fIndexPoolUseCnt);
	fIndexPool = SkNEW_ARGS(GrIndexBufferAllocPool, (this, true,
	INDEX_POOL_IB_SIZE,
	INDEX_POOL_IB_COUNT));
	fIndexPool->releaseGpuRef();
	} else if (!fIndexPoolUseCnt) {
	// the client doesn't have valid data in the pool
	fIndexPool->reset();
	}
	}

	bool GrGpu::onReserveVertexSpace(GrVertexLayout vertexLayout,
	int vertexCount,
	void** vertices) {
	GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();

	GrAssert(vertexCount > 0);
	GrAssert(NULL != vertices);

	this->prepareVertexPool();

	*vertices = fVertexPool->makeSpace(vertexLayout,
	vertexCount,
	&geomPoolState.fPoolVertexBuffer,
	&geomPoolState.fPoolStartVertex);
	if (NULL == *vertices) {
	return false;
	}
	++fVertexPoolUseCnt;
	return true;
	}

	bool GrGpu::onReserveIndexSpace(int indexCount, void** indices) {
	GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();

	GrAssert(indexCount > 0);
	GrAssert(NULL != indices);

	this->prepareIndexPool();

	*indices = fIndexPool->makeSpace(indexCount,
	&geomPoolState.fPoolIndexBuffer,
	&geomPoolState.fPoolStartIndex);
	if (NULL == *indices) {
	return false;
	}
	++fIndexPoolUseCnt;
	return true;
	}

	void GrGpu::releaseReservedVertexSpace() {
	const GeometrySrcState& geoSrc = this->getGeomSrc();
	GrAssert(kReserved_GeometrySrcType == geoSrc.fVertexSrc);
	size_t bytes = geoSrc.fVertexCount * VertexSize(geoSrc.fVertexLayout);
	fVertexPool->putBack(bytes);
	--fVertexPoolUseCnt;
	}

	void GrGpu::releaseReservedIndexSpace() {
	const GeometrySrcState& geoSrc = this->getGeomSrc();
	GrAssert(kReserved_GeometrySrcType == geoSrc.fIndexSrc);
	size_t bytes = geoSrc.fIndexCount * sizeof(uint16_t);
	fIndexPool->putBack(bytes);
	--fIndexPoolUseCnt;
	}

	void GrGpu::onSetVertexSourceToArray(const void* vertexArray, int vertexCount) {
	this->prepareVertexPool();
	GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();
	#if GR_DEBUG
	bool success =
	#endif
	fVertexPool->appendVertices(this->getVertexLayout(),
	vertexCount,
	vertexArray,
	&geomPoolState.fPoolVertexBuffer,
	&geomPoolState.fPoolStartVertex);
	++fVertexPoolUseCnt;
	GR_DEBUGASSERT(success);
	}

	void GrGpu::onSetIndexSourceToArray(const void* indexArray, int indexCount) {
	this->prepareIndexPool();
	GeometryPoolState& geomPoolState = fGeomPoolStateStack.back();
	#if GR_DEBUG
	bool success =
	#endif
	fIndexPool->appendIndices(indexCount,
	indexArray,
	&geomPoolState.fPoolIndexBuffer,
	&geomPoolState.fPoolStartIndex);
	++fIndexPoolUseCnt;
	GR_DEBUGASSERT(success);
	}

	void GrGpu::releaseVertexArray() {
	// if vertex source was array, we stowed data in the pool
	const GeometrySrcState& geoSrc = this->getGeomSrc();
	GrAssert(kArray_GeometrySrcType == geoSrc.fVertexSrc);
	size_t bytes = geoSrc.fVertexCount * VertexSize(geoSrc.fVertexLayout);
	fVertexPool->putBack(bytes);
	--fVertexPoolUseCnt;
	}

	void GrGpu::releaseIndexArray() {
	// if index source was array, we stowed data in the pool
	const GeometrySrcState& geoSrc = this->getGeomSrc();
	GrAssert(kArray_GeometrySrcType == geoSrc.fIndexSrc);
	size_t bytes = geoSrc.fIndexCount * sizeof(uint16_t);
	fIndexPool->putBack(bytes);
	--fIndexPoolUseCnt;
	}