src/third_party/skia/tests/GLProgramsTest.cpp - cobalt - Git at Google


 /*
  * Copyright 2011 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 // This is a GPU-backend specific test. It relies on static intializers to work

 #include "SkTypes.h"

 #if SK_SUPPORT_GPU && SK_ALLOW_STATIC_GLOBAL_INITIALIZERS

 #include "GrBackendProcessorFactory.h"
 #include "GrContextFactory.h"
 #include "GrOptDrawState.h"
 #include "effects/GrConfigConversionEffect.h"
 #include "gl/GrGLPathRendering.h"
 #include "gl/GrGpuGL.h"
 #include "SkChecksum.h"
 #include "SkRandom.h"
 #include "Test.h"

 static void get_stage_stats(const GrFragmentStage stage, bool* readsDst,
                             bool* readsFragPosition, bool* requiresVertexShader) {
     if (stage.getFragmentProcessor()->willReadDstColor()) {
         *readsDst = true;
     }
     if (stage.getProcessor()->willReadFragmentPosition()) {
         *readsFragPosition = true;
     }
 }

 bool GrGLProgramDesc::setRandom(SkRandom* random,
                                 GrGpuGL* gpu,
                                 const GrRenderTarget* dstRenderTarget,
                                 const GrTexture* dstCopyTexture,
                                 const GrGeometryStage* geometryProcessor,
                                 const GrFragmentStage* stages[],
                                 int numColorStages,
                                 int numCoverageStages,
                                 int currAttribIndex,
                                 GrGpu::DrawType drawType) {
     bool isPathRendering = GrGpu::IsPathRenderingDrawType(drawType);
     bool useLocalCoords = !isPathRendering &&
                           random->nextBool() &&
                           currAttribIndex < GrDrawState::kMaxVertexAttribCnt;

     int numStages = numColorStages + numCoverageStages;
     fKey.reset();

     GR_STATIC_ASSERT(0 == kEffectKeyOffsetsAndLengthOffset % sizeof(uint32_t));

     // Make room for everything up to and including the array of offsets to effect keys.
     fKey.push_back_n(kEffectKeyOffsetsAndLengthOffset + 2 * sizeof(uint16_t) * (numStages +
             (geometryProcessor ? 1 : 0)));

     bool dstRead = false;
     bool fragPos = false;
     bool vertexShader = SkToBool(geometryProcessor);
     int offset = 0;
     if (geometryProcessor) {
         const GrGeometryStage* stage = geometryProcessor;
         uint16_t* offsetAndSize = reinterpret_cast<uint16_t*>(fKey.begin() +
                                                               kEffectKeyOffsetsAndLengthOffset +
                                                               offset * 2 * sizeof(uint16_t));
         uint32_t effectKeyOffset = fKey.count();
         if (effectKeyOffset > SK_MaxU16) {
             fKey.reset();
             return false;
         }
         GrProcessorKeyBuilder b(&fKey);
         uint16_t effectKeySize;
         if (!GetProcessorKey(*stage, gpu->glCaps(), useLocalCoords, &b, &effectKeySize)) {
             fKey.reset();
             return false;
         }
         vertexShader = true;
         fragPos = stage->getProcessor()->willReadFragmentPosition();
         offsetAndSize[0] = effectKeyOffset;
         offsetAndSize[1] = effectKeySize;
         offset++;
     }

     for (int s = 0; s < numStages; ++s, ++offset) {
         const GrFragmentStage* stage = stages[s];
         uint16_t* offsetAndSize = reinterpret_cast<uint16_t*>(fKey.begin() +
                                                               kEffectKeyOffsetsAndLengthOffset +
                                                               offset * 2 * sizeof(uint16_t));
         uint32_t effectKeyOffset = fKey.count();
         if (effectKeyOffset > SK_MaxU16) {
             fKey.reset();
             return false;
         }
         GrProcessorKeyBuilder b(&fKey);
         uint16_t effectKeySize;
         if (!GetProcessorKey(*stages[s], gpu->glCaps(), useLocalCoords, &b, &effectKeySize)) {
             fKey.reset();
             return false;
         }
         get_stage_stats(*stage, &dstRead, &fragPos, &vertexShader);
         offsetAndSize[0] = effectKeyOffset;
         offsetAndSize[1] = effectKeySize;
     }

     KeyHeader* header = this->header();
     memset(header, 0, kHeaderSize);
     header->fEmitsPointSize = random->nextBool();

     header->fPositionAttributeIndex = 0;

     // if the effects have used up all off the available attributes,
     // don't try to use color or coverage attributes as input
     do {
         header->fColorInput = static_cast<GrGLProgramDesc::ColorInput>(
                                      random->nextULessThan(kColorInputCnt));
     } while ((GrDrawState::kMaxVertexAttribCnt <= currAttribIndex || isPathRendering) &&
              kAttribute_ColorInput == header->fColorInput);
     header->fColorAttributeIndex = (header->fColorInput == kAttribute_ColorInput) ?
                                         currAttribIndex++ :
                                         -1;

     do {
         header->fCoverageInput = static_cast<GrGLProgramDesc::ColorInput>(
                                      random->nextULessThan(kColorInputCnt));
     } while ((GrDrawState::kMaxVertexAttribCnt <= currAttribIndex || isPathRendering)  &&
              kAttribute_ColorInput == header->fCoverageInput);
     header->fCoverageAttributeIndex = (header->fCoverageInput == kAttribute_ColorInput) ?
                                         currAttribIndex++ :
                                         -1;
     bool useGS = random->nextBool();
 #if GR_GL_EXPERIMENTAL_GS
     header->fExperimentalGS = gpu->caps()->geometryShaderSupport() && useGS;
 #else
     (void) useGS;
 #endif

     header->fLocalCoordAttributeIndex = useLocalCoords ? currAttribIndex++ : -1;

     header->fColorEffectCnt = numColorStages;
     header->fCoverageEffectCnt = numCoverageStages;

     if (dstRead) {
         header->fDstReadKey = SkToU8(GrGLFragmentShaderBuilder::KeyForDstRead(dstCopyTexture,
                                                                       gpu->glCaps()));
     } else {
         header->fDstReadKey = 0;
     }
     if (fragPos) {
         header->fFragPosKey = SkToU8(GrGLFragmentShaderBuilder::KeyForFragmentPosition(dstRenderTarget,
                                                                                gpu->glCaps()));
     } else {
         header->fFragPosKey = 0;
     }

     header->fUseFragShaderOnly = isPathRendering && gpu->glPathRendering()->texturingMode() ==
                                                     GrGLPathRendering::FixedFunction_TexturingMode;
     header->fHasGeometryProcessor = vertexShader;

     GrOptDrawState::PrimaryOutputType primaryOutput;
     GrOptDrawState::SecondaryOutputType secondaryOutput;
     if (!dstRead) {
         primaryOutput = GrOptDrawState::kModulate_PrimaryOutputType;
     } else {
         primaryOutput = static_cast<GrOptDrawState::PrimaryOutputType>(
             random->nextULessThan(GrOptDrawState::kPrimaryOutputTypeCnt));
     }

     if (GrOptDrawState::kCombineWithDst_PrimaryOutputType == primaryOutput ||
         !gpu->caps()->dualSourceBlendingSupport()) {
         secondaryOutput = GrOptDrawState::kNone_SecondaryOutputType;
     } else {
         secondaryOutput = static_cast<GrOptDrawState::SecondaryOutputType>(
             random->nextULessThan(GrOptDrawState::kSecondaryOutputTypeCnt));
     }

     header->fPrimaryOutputType = primaryOutput;
     header->fSecondaryOutputType = secondaryOutput;

     this->finalize();
     return true;
 }

 // TODO clean this up, we have to do this to test geometry processors but there has got to be
 // a better way.  In the mean time, we actually fill out these generic vertex attribs below with
 // the correct vertex attribs from the GP.  We have to ensure, however, we don't try to add more
 // than two attributes.
 GrVertexAttrib genericVertexAttribs[] = {
     { kVec2f_GrVertexAttribType, 0,   kPosition_GrVertexAttribBinding },
     { kVec2f_GrVertexAttribType, 0,   kGeometryProcessor_GrVertexAttribBinding },
     { kVec2f_GrVertexAttribType, 0,   kGeometryProcessor_GrVertexAttribBinding }
 };

 /*
  * convert sl type to vertexattrib type, not a complete implementation, only use for debugging
  */
 GrVertexAttribType convert_sltype_to_attribtype(GrSLType type) {
     switch (type) {
         case kFloat_GrSLType:
             return kFloat_GrVertexAttribType;
         case kVec2f_GrSLType:
             return kVec2f_GrVertexAttribType;
         case kVec3f_GrSLType:
             return kVec3f_GrVertexAttribType;
         case kVec4f_GrSLType:
             return kVec4f_GrVertexAttribType;
         default:
             SkFAIL("Type isn't convertible");
             return kFloat_GrVertexAttribType;
     }
 }
 // TODO end test hack


 bool GrGpuGL::programUnitTest(int maxStages) {

     GrTextureDesc dummyDesc;
     dummyDesc.fFlags = kRenderTarget_GrTextureFlagBit;
     dummyDesc.fConfig = kSkia8888_GrPixelConfig;
     dummyDesc.fWidth = 34;
     dummyDesc.fHeight = 18;
     SkAutoTUnref<GrTexture> dummyTexture1(this->createTexture(dummyDesc, NULL, 0));
     dummyDesc.fFlags = kNone_GrTextureFlags;
     dummyDesc.fConfig = kAlpha_8_GrPixelConfig;
     dummyDesc.fWidth = 16;
     dummyDesc.fHeight = 22;
     SkAutoTUnref<GrTexture> dummyTexture2(this->createTexture(dummyDesc, NULL, 0));

     if (!dummyTexture1 || ! dummyTexture2) {
         return false;
     }

     static const int NUM_TESTS = 512;

     SkRandom random;
     for (int t = 0; t < NUM_TESTS; ++t) {

 #if 0
         GrPrintf("\nTest Program %d\n-------------\n", t);
         static const int stop = -1;
         if (t == stop) {
             int breakpointhere = 9;
         }
 #endif

         GrGLProgramDesc pdesc;

         int currAttribIndex = 1;  // we need to always leave room for position
         int currTextureCoordSet = 0;
         GrTexture* dummyTextures[] = {dummyTexture1.get(), dummyTexture2.get()};

         int numStages = random.nextULessThan(maxStages + 1);
         int numColorStages = random.nextULessThan(numStages + 1);
         int numCoverageStages = numStages - numColorStages;

         SkAutoSTMalloc<8, const GrFragmentStage*> stages(numStages);

         bool usePathRendering = this->glCaps().pathRenderingSupport() && random.nextBool();

         GrGpu::DrawType drawType = usePathRendering ? GrGpu::kDrawPath_DrawType :
                                                       GrGpu::kDrawPoints_DrawType;

         SkAutoTDelete<GrGeometryStage> geometryProcessor;
         bool hasGeometryProcessor = usePathRendering ? false : random.nextBool();
         if (hasGeometryProcessor) {
             while (true) {
                 SkAutoTUnref<const GrGeometryProcessor> effect(
                         GrProcessorTestFactory<GrGeometryProcessor>::CreateStage(&random, this->getContext(), *this->caps(),
                                                          dummyTextures));
                 SkASSERT(effect);
                 // Only geometryProcessor can use vertex shader
                 GrGeometryStage* stage = SkNEW_ARGS(GrGeometryStage, (effect.get()));
                 geometryProcessor.reset(stage);

                 // we have to set dummy vertex attribs
                 const GrGeometryProcessor::VertexAttribArray& v = effect->getVertexAttribs();
                 int numVertexAttribs = v.count();

                 SkASSERT(GrGeometryProcessor::kMaxVertexAttribs == 2 &&
                          GrGeometryProcessor::kMaxVertexAttribs >= numVertexAttribs);
                 size_t runningStride = GrVertexAttribTypeSize(genericVertexAttribs[0].fType);
                 for (int i = 0; i < numVertexAttribs; i++) {
                     genericVertexAttribs[i + 1].fOffset = runningStride;
                     genericVertexAttribs[i + 1].fType =
                             convert_sltype_to_attribtype(v[i].getType());
                     runningStride += GrVertexAttribTypeSize(genericVertexAttribs[i + 1].fType);
                 }

                 // update the vertex attributes with the ds
                 GrDrawState* ds = this->drawState();
                 ds->setVertexAttribs<genericVertexAttribs>(numVertexAttribs + 1, runningStride);
                 currAttribIndex = numVertexAttribs + 1;
                 break;
             }
         }
         for (int s = 0; s < numStages;) {
             SkAutoTUnref<const GrFragmentProcessor> effect(
                     GrProcessorTestFactory<GrFragmentProcessor>::CreateStage(
                                                                             &random,
                                                                             this->getContext(),
                                                                             *this->caps(),
                                                                             dummyTextures));
             SkASSERT(effect);

             // If adding this effect would exceed the max texture coord set count then generate a
             // new random effect.
             if (usePathRendering && this->glPathRendering()->texturingMode() ==
                                     GrGLPathRendering::FixedFunction_TexturingMode) {;
                 int numTransforms = effect->numTransforms();
                 if (currTextureCoordSet + numTransforms > this->glCaps().maxFixedFunctionTextureCoords()) {
                     continue;
                 }
                 currTextureCoordSet += numTransforms;
             }
             GrFragmentStage* stage = SkNEW_ARGS(GrFragmentStage, (effect.get()));

             stages[s] = stage;
             ++s;
         }
         const GrTexture* dstTexture = random.nextBool() ? dummyTextures[0] : dummyTextures[1];
         if (!pdesc.setRandom(&random,
                              this,
                              dummyTextures[0]->asRenderTarget(),
                              dstTexture,
                              geometryProcessor.get(),
                              stages.get(),
                              numColorStages,
                              numCoverageStages,
                              currAttribIndex,
                              drawType)) {
             return false;
         }

         SkAutoTUnref<GrGLProgram> program(GrGLProgram::Create(this,
                                                               pdesc,
                                                               geometryProcessor.get(),
                                                               stages,
                                                               stages + numColorStages));
         for (int s = 0; s < numStages; ++s) {
             SkDELETE(stages[s]);
         }
         if (NULL == program.get()) {
             return false;
         }

         // We have to reset the drawstate because we might have added a gp
         this->drawState()->reset();
     }
     return true;
 }

 DEF_GPUTEST(GLPrograms, reporter, factory) {
     for (int type = 0; type < GrContextFactory::kLastGLContextType; ++type) {
         GrContext* context = factory->get(static_cast<GrContextFactory::GLContextType>(type));
         if (context) {
             GrGpuGL* gpu = static_cast<GrGpuGL*>(context->getGpu());
             int maxStages = 6;
 #if SK_ANGLE
             // Some long shaders run out of temporary registers in the D3D compiler on ANGLE.
             if (type == GrContextFactory::kANGLE_GLContextType) {
                 maxStages = 3;
             }
 #endif
             REPORTER_ASSERT(reporter, gpu->programUnitTest(maxStages));
         }
     }
 }

 // This is evil evil evil. The linker may throw away whole translation units as dead code if it
 // thinks none of the functions are called. It will do this even if there are static initializers
 // in the unit that could pass pointers to functions from the unit out to other translation units!
 // We force some of the effects that would otherwise be discarded to link here.

 #include "SkAlphaThresholdFilter.h"
 #include "SkColorMatrixFilter.h"
 #include "SkLightingImageFilter.h"
 #include "SkMagnifierImageFilter.h"

 void forceLinking();

 void forceLinking() {
     SkLightingImageFilter::CreateDistantLitDiffuse(SkPoint3(0,0,0), 0, 0, 0);
     SkAlphaThresholdFilter::Create(SkRegion(), .5f, .5f);
     SkAutoTUnref<SkImageFilter> mag(SkMagnifierImageFilter::Create(
         SkRect::MakeWH(SK_Scalar1, SK_Scalar1), SK_Scalar1));
     GrConfigConversionEffect::Create(NULL,
                                      false,
                                      GrConfigConversionEffect::kNone_PMConversion,
                                      SkMatrix::I());
     SkScalar matrix[20];
     SkAutoTUnref<SkColorMatrixFilter> cmf(SkColorMatrixFilter::Create(matrix));
 }

 #endif

	/*
	* Copyright 2011 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	// This is a GPU-backend specific test. It relies on static intializers to work

	#include "SkTypes.h"

	#if SK_SUPPORT_GPU && SK_ALLOW_STATIC_GLOBAL_INITIALIZERS

	#include "GrBackendProcessorFactory.h"
	#include "GrContextFactory.h"
	#include "GrOptDrawState.h"
	#include "effects/GrConfigConversionEffect.h"
	#include "gl/GrGLPathRendering.h"
	#include "gl/GrGpuGL.h"
	#include "SkChecksum.h"
	#include "SkRandom.h"
	#include "Test.h"

	static void get_stage_stats(const GrFragmentStage stage, bool* readsDst,
	bool* readsFragPosition, bool* requiresVertexShader) {
	if (stage.getFragmentProcessor()->willReadDstColor()) {
	*readsDst = true;
	}
	if (stage.getProcessor()->willReadFragmentPosition()) {
	*readsFragPosition = true;
	}
	}

	bool GrGLProgramDesc::setRandom(SkRandom* random,
	GrGpuGL* gpu,
	const GrRenderTarget* dstRenderTarget,
	const GrTexture* dstCopyTexture,
	const GrGeometryStage* geometryProcessor,
	const GrFragmentStage* stages[],
	int numColorStages,
	int numCoverageStages,
	int currAttribIndex,
	GrGpu::DrawType drawType) {
	bool isPathRendering = GrGpu::IsPathRenderingDrawType(drawType);
	bool useLocalCoords = !isPathRendering &&
	random->nextBool() &&
	currAttribIndex < GrDrawState::kMaxVertexAttribCnt;

	int numStages = numColorStages + numCoverageStages;
	fKey.reset();

	GR_STATIC_ASSERT(0 == kEffectKeyOffsetsAndLengthOffset % sizeof(uint32_t));

	// Make room for everything up to and including the array of offsets to effect keys.
	fKey.push_back_n(kEffectKeyOffsetsAndLengthOffset + 2 * sizeof(uint16_t) * (numStages +
	(geometryProcessor ? 1 : 0)));

	bool dstRead = false;
	bool fragPos = false;
	bool vertexShader = SkToBool(geometryProcessor);
	int offset = 0;
	if (geometryProcessor) {
	const GrGeometryStage* stage = geometryProcessor;
	uint16_t* offsetAndSize = reinterpret_cast<uint16_t*>(fKey.begin() +
	kEffectKeyOffsetsAndLengthOffset +
	offset * 2 * sizeof(uint16_t));
	uint32_t effectKeyOffset = fKey.count();
	if (effectKeyOffset > SK_MaxU16) {
	fKey.reset();
	return false;
	}
	GrProcessorKeyBuilder b(&fKey);
	uint16_t effectKeySize;
	if (!GetProcessorKey(*stage, gpu->glCaps(), useLocalCoords, &b, &effectKeySize)) {
	fKey.reset();
	return false;
	}
	vertexShader = true;
	fragPos = stage->getProcessor()->willReadFragmentPosition();
	offsetAndSize[0] = effectKeyOffset;
	offsetAndSize[1] = effectKeySize;
	offset++;
	}

	for (int s = 0; s < numStages; ++s, ++offset) {
	const GrFragmentStage* stage = stages[s];
	uint16_t* offsetAndSize = reinterpret_cast<uint16_t*>(fKey.begin() +
	kEffectKeyOffsetsAndLengthOffset +
	offset * 2 * sizeof(uint16_t));
	uint32_t effectKeyOffset = fKey.count();
	if (effectKeyOffset > SK_MaxU16) {
	fKey.reset();
	return false;
	}
	GrProcessorKeyBuilder b(&fKey);
	uint16_t effectKeySize;
	if (!GetProcessorKey(*stages[s], gpu->glCaps(), useLocalCoords, &b, &effectKeySize)) {
	fKey.reset();
	return false;
	}
	get_stage_stats(*stage, &dstRead, &fragPos, &vertexShader);
	offsetAndSize[0] = effectKeyOffset;
	offsetAndSize[1] = effectKeySize;
	}

	KeyHeader* header = this->header();
	memset(header, 0, kHeaderSize);
	header->fEmitsPointSize = random->nextBool();

	header->fPositionAttributeIndex = 0;

	// if the effects have used up all off the available attributes,
	// don't try to use color or coverage attributes as input
	do {
	header->fColorInput = static_cast<GrGLProgramDesc::ColorInput>(
	random->nextULessThan(kColorInputCnt));
	} while ((GrDrawState::kMaxVertexAttribCnt <= currAttribIndex \|\| isPathRendering) &&
	kAttribute_ColorInput == header->fColorInput);
	header->fColorAttributeIndex = (header->fColorInput == kAttribute_ColorInput) ?
	currAttribIndex++ :
	-1;

	do {
	header->fCoverageInput = static_cast<GrGLProgramDesc::ColorInput>(
	random->nextULessThan(kColorInputCnt));
	} while ((GrDrawState::kMaxVertexAttribCnt <= currAttribIndex \|\| isPathRendering) &&
	kAttribute_ColorInput == header->fCoverageInput);
	header->fCoverageAttributeIndex = (header->fCoverageInput == kAttribute_ColorInput) ?
	currAttribIndex++ :
	-1;
	bool useGS = random->nextBool();
	#if GR_GL_EXPERIMENTAL_GS
	header->fExperimentalGS = gpu->caps()->geometryShaderSupport() && useGS;
	#else
	(void) useGS;
	#endif

	header->fLocalCoordAttributeIndex = useLocalCoords ? currAttribIndex++ : -1;

	header->fColorEffectCnt = numColorStages;
	header->fCoverageEffectCnt = numCoverageStages;

	if (dstRead) {
	header->fDstReadKey = SkToU8(GrGLFragmentShaderBuilder::KeyForDstRead(dstCopyTexture,
	gpu->glCaps()));
	} else {
	header->fDstReadKey = 0;
	}
	if (fragPos) {
	header->fFragPosKey = SkToU8(GrGLFragmentShaderBuilder::KeyForFragmentPosition(dstRenderTarget,
	gpu->glCaps()));
	} else {
	header->fFragPosKey = 0;
	}

	header->fUseFragShaderOnly = isPathRendering && gpu->glPathRendering()->texturingMode() ==
	GrGLPathRendering::FixedFunction_TexturingMode;
	header->fHasGeometryProcessor = vertexShader;

	GrOptDrawState::PrimaryOutputType primaryOutput;
	GrOptDrawState::SecondaryOutputType secondaryOutput;
	if (!dstRead) {
	primaryOutput = GrOptDrawState::kModulate_PrimaryOutputType;
	} else {
	primaryOutput = static_cast<GrOptDrawState::PrimaryOutputType>(
	random->nextULessThan(GrOptDrawState::kPrimaryOutputTypeCnt));
	}

	if (GrOptDrawState::kCombineWithDst_PrimaryOutputType == primaryOutput \|\|
	!gpu->caps()->dualSourceBlendingSupport()) {
	secondaryOutput = GrOptDrawState::kNone_SecondaryOutputType;
	} else {
	secondaryOutput = static_cast<GrOptDrawState::SecondaryOutputType>(
	random->nextULessThan(GrOptDrawState::kSecondaryOutputTypeCnt));
	}

	header->fPrimaryOutputType = primaryOutput;
	header->fSecondaryOutputType = secondaryOutput;

	this->finalize();
	return true;
	}

	// TODO clean this up, we have to do this to test geometry processors but there has got to be
	// a better way. In the mean time, we actually fill out these generic vertex attribs below with
	// the correct vertex attribs from the GP. We have to ensure, however, we don't try to add more
	// than two attributes.
	GrVertexAttrib genericVertexAttribs[] = {
	{ kVec2f_GrVertexAttribType, 0, kPosition_GrVertexAttribBinding },
	{ kVec2f_GrVertexAttribType, 0, kGeometryProcessor_GrVertexAttribBinding },
	{ kVec2f_GrVertexAttribType, 0, kGeometryProcessor_GrVertexAttribBinding }
	};

	/*
	* convert sl type to vertexattrib type, not a complete implementation, only use for debugging
	*/
	GrVertexAttribType convert_sltype_to_attribtype(GrSLType type) {
	switch (type) {
	case kFloat_GrSLType:
	return kFloat_GrVertexAttribType;
	case kVec2f_GrSLType:
	return kVec2f_GrVertexAttribType;
	case kVec3f_GrSLType:
	return kVec3f_GrVertexAttribType;
	case kVec4f_GrSLType:
	return kVec4f_GrVertexAttribType;
	default:
	SkFAIL("Type isn't convertible");
	return kFloat_GrVertexAttribType;
	}
	}
	// TODO end test hack


	bool GrGpuGL::programUnitTest(int maxStages) {

	GrTextureDesc dummyDesc;
	dummyDesc.fFlags = kRenderTarget_GrTextureFlagBit;
	dummyDesc.fConfig = kSkia8888_GrPixelConfig;
	dummyDesc.fWidth = 34;
	dummyDesc.fHeight = 18;
	SkAutoTUnref<GrTexture> dummyTexture1(this->createTexture(dummyDesc, NULL, 0));
	dummyDesc.fFlags = kNone_GrTextureFlags;
	dummyDesc.fConfig = kAlpha_8_GrPixelConfig;
	dummyDesc.fWidth = 16;
	dummyDesc.fHeight = 22;
	SkAutoTUnref<GrTexture> dummyTexture2(this->createTexture(dummyDesc, NULL, 0));

	if (!dummyTexture1 \|\| ! dummyTexture2) {
	return false;
	}

	static const int NUM_TESTS = 512;

	SkRandom random;
	for (int t = 0; t < NUM_TESTS; ++t) {

	#if 0
	GrPrintf("\nTest Program %d\n-------------\n", t);
	static const int stop = -1;
	if (t == stop) {
	int breakpointhere = 9;
	}
	#endif

	GrGLProgramDesc pdesc;

	int currAttribIndex = 1; // we need to always leave room for position
	int currTextureCoordSet = 0;
	GrTexture* dummyTextures[] = {dummyTexture1.get(), dummyTexture2.get()};

	int numStages = random.nextULessThan(maxStages + 1);
	int numColorStages = random.nextULessThan(numStages + 1);
	int numCoverageStages = numStages - numColorStages;

	SkAutoSTMalloc<8, const GrFragmentStage*> stages(numStages);

	bool usePathRendering = this->glCaps().pathRenderingSupport() && random.nextBool();

	GrGpu::DrawType drawType = usePathRendering ? GrGpu::kDrawPath_DrawType :
	GrGpu::kDrawPoints_DrawType;

	SkAutoTDelete<GrGeometryStage> geometryProcessor;
	bool hasGeometryProcessor = usePathRendering ? false : random.nextBool();
	if (hasGeometryProcessor) {
	while (true) {
	SkAutoTUnref<const GrGeometryProcessor> effect(
	GrProcessorTestFactory<GrGeometryProcessor>::CreateStage(&random, this->getContext(), *this->caps(),
	dummyTextures));
	SkASSERT(effect);
	// Only geometryProcessor can use vertex shader
	GrGeometryStage* stage = SkNEW_ARGS(GrGeometryStage, (effect.get()));
	geometryProcessor.reset(stage);

	// we have to set dummy vertex attribs
	const GrGeometryProcessor::VertexAttribArray& v = effect->getVertexAttribs();
	int numVertexAttribs = v.count();

	SkASSERT(GrGeometryProcessor::kMaxVertexAttribs == 2 &&
	GrGeometryProcessor::kMaxVertexAttribs >= numVertexAttribs);
	size_t runningStride = GrVertexAttribTypeSize(genericVertexAttribs[0].fType);
	for (int i = 0; i < numVertexAttribs; i++) {
	genericVertexAttribs[i + 1].fOffset = runningStride;
	genericVertexAttribs[i + 1].fType =
	convert_sltype_to_attribtype(v[i].getType());
	runningStride += GrVertexAttribTypeSize(genericVertexAttribs[i + 1].fType);
	}

	// update the vertex attributes with the ds
	GrDrawState* ds = this->drawState();
	ds->setVertexAttribs<genericVertexAttribs>(numVertexAttribs + 1, runningStride);
	currAttribIndex = numVertexAttribs + 1;
	break;
	}
	}
	for (int s = 0; s < numStages;) {
	SkAutoTUnref<const GrFragmentProcessor> effect(
	GrProcessorTestFactory<GrFragmentProcessor>::CreateStage(
	&random,
	this->getContext(),
	*this->caps(),
	dummyTextures));
	SkASSERT(effect);

	// If adding this effect would exceed the max texture coord set count then generate a
	// new random effect.
	if (usePathRendering && this->glPathRendering()->texturingMode() ==
	GrGLPathRendering::FixedFunction_TexturingMode) {;
	int numTransforms = effect->numTransforms();
	if (currTextureCoordSet + numTransforms > this->glCaps().maxFixedFunctionTextureCoords()) {
	continue;
	}
	currTextureCoordSet += numTransforms;
	}
	GrFragmentStage* stage = SkNEW_ARGS(GrFragmentStage, (effect.get()));

	stages[s] = stage;
	++s;
	}
	const GrTexture* dstTexture = random.nextBool() ? dummyTextures[0] : dummyTextures[1];
	if (!pdesc.setRandom(&random,
	this,
	dummyTextures[0]->asRenderTarget(),
	dstTexture,
	geometryProcessor.get(),
	stages.get(),
	numColorStages,
	numCoverageStages,
	currAttribIndex,
	drawType)) {
	return false;
	}

	SkAutoTUnref<GrGLProgram> program(GrGLProgram::Create(this,
	pdesc,
	geometryProcessor.get(),
	stages,
	stages + numColorStages));
	for (int s = 0; s < numStages; ++s) {
	SkDELETE(stages[s]);
	}
	if (NULL == program.get()) {
	return false;
	}

	// We have to reset the drawstate because we might have added a gp
	this->drawState()->reset();
	}
	return true;
	}

	DEF_GPUTEST(GLPrograms, reporter, factory) {
	for (int type = 0; type < GrContextFactory::kLastGLContextType; ++type) {
	GrContext* context = factory->get(static_cast<GrContextFactory::GLContextType>(type));
	if (context) {
	GrGpuGL* gpu = static_cast<GrGpuGL*>(context->getGpu());
	int maxStages = 6;
	#if SK_ANGLE
	// Some long shaders run out of temporary registers in the D3D compiler on ANGLE.
	if (type == GrContextFactory::kANGLE_GLContextType) {
	maxStages = 3;
	}
	#endif
	REPORTER_ASSERT(reporter, gpu->programUnitTest(maxStages));
	}
	}
	}

	// This is evil evil evil. The linker may throw away whole translation units as dead code if it
	// thinks none of the functions are called. It will do this even if there are static initializers
	// in the unit that could pass pointers to functions from the unit out to other translation units!
	// We force some of the effects that would otherwise be discarded to link here.

	#include "SkAlphaThresholdFilter.h"
	#include "SkColorMatrixFilter.h"
	#include "SkLightingImageFilter.h"
	#include "SkMagnifierImageFilter.h"

	void forceLinking();

	void forceLinking() {
	SkLightingImageFilter::CreateDistantLitDiffuse(SkPoint3(0,0,0), 0, 0, 0);
	SkAlphaThresholdFilter::Create(SkRegion(), .5f, .5f);
	SkAutoTUnref<SkImageFilter> mag(SkMagnifierImageFilter::Create(
	SkRect::MakeWH(SK_Scalar1, SK_Scalar1), SK_Scalar1));
	GrConfigConversionEffect::Create(NULL,
	false,
	GrConfigConversionEffect::kNone_PMConversion,
	SkMatrix::I());
	SkScalar matrix[20];
	SkAutoTUnref<SkColorMatrixFilter> cmf(SkColorMatrixFilter::Create(matrix));
	}

	#endif