/* * Copyright 2017 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "GrTextureOp.h" #include "GrAppliedClip.h" #include "GrCaps.h" #include "GrDrawOpTest.h" #include "GrGeometryProcessor.h" #include "GrMeshDrawOp.h" #include "GrOpFlushState.h" #include "GrQuad.h" #include "GrResourceProvider.h" #include "GrShaderCaps.h" #include "GrTexture.h" #include "GrTexturePriv.h" #include "GrTextureProxy.h" #include "SkGr.h" #include "SkMathPriv.h" #include "glsl/GrGLSLColorSpaceXformHelper.h" #include "glsl/GrGLSLGeometryProcessor.h" #include "glsl/GrGLSLVarying.h" namespace { /** * Geometry Processor that draws a texture modulated by a vertex color (though, this is meant to be * the same value across all vertices of a quad and uses flat interpolation when available). This is * used by TextureOp below. */ class TextureGeometryProcessor : public GrGeometryProcessor { public: struct Vertex { SkPoint fPosition; SkPoint fTextureCoords; GrColor fColor; }; struct MultiTextureVertex { SkPoint fPosition; int fTextureIdx; SkPoint fTextureCoords; GrColor fColor; }; // Maximum number of textures supported by this op. Must also be checked against the caps // limit. These numbers were based on some limited experiments on a HP Z840 and Pixel XL 2016 // and could probably use more tuning. #ifdef SK_BUILD_FOR_ANDROID static constexpr int kMaxTextures = 4; #else static constexpr int kMaxTextures = 8; #endif static int SupportsMultitexture(const GrShaderCaps& caps) { return caps.integerSupport(); } static sk_sp Make(sk_sp proxies[], int proxyCnt, sk_sp csxf, const GrSamplerState::Filter filters[], const GrShaderCaps& caps) { // We use placement new to avoid always allocating space for kMaxTextures TextureSampler // instances. int samplerCnt = NumSamplersToUse(proxyCnt, caps); size_t size = sizeof(TextureGeometryProcessor) + sizeof(TextureSampler) * (samplerCnt - 1); void* mem = GrGeometryProcessor::operator new(size); return sk_sp(new (mem) TextureGeometryProcessor( proxies, proxyCnt, samplerCnt, std::move(csxf), filters, caps)); } ~TextureGeometryProcessor() override { int cnt = this->numTextureSamplers(); for (int i = 1; i < cnt; ++i) { fSamplers[i].~TextureSampler(); } } const char* name() const override { return "TextureGeometryProcessor"; } void getGLSLProcessorKey(const GrShaderCaps&, GrProcessorKeyBuilder* b) const override { b->add32(GrColorSpaceXform::XformKey(fColorSpaceXform.get())); } GrGLSLPrimitiveProcessor* createGLSLInstance(const GrShaderCaps& caps) const override { class GLSLProcessor : public GrGLSLGeometryProcessor { public: void setData(const GrGLSLProgramDataManager& pdman, const GrPrimitiveProcessor& proc, FPCoordTransformIter&& transformIter) override { const auto& textureGP = proc.cast(); this->setTransformDataHelper(SkMatrix::I(), pdman, &transformIter); if (fColorSpaceXformHelper.isValid()) { fColorSpaceXformHelper.setData(pdman, textureGP.fColorSpaceXform.get()); } } private: void onEmitCode(EmitArgs& args, GrGPArgs* gpArgs) override { const auto& textureGP = args.fGP.cast(); fColorSpaceXformHelper.emitCode( args.fUniformHandler, textureGP.fColorSpaceXform.get()); args.fVaryingHandler->setNoPerspective(); args.fVaryingHandler->emitAttributes(textureGP); this->writeOutputPosition(args.fVertBuilder, gpArgs, textureGP.fPositions.fName); this->emitTransforms(args.fVertBuilder, args.fVaryingHandler, args.fUniformHandler, gpArgs->fPositionVar, textureGP.fTextureCoords.fName, args.fFPCoordTransformHandler); if (args.fShaderCaps->flatInterpolationSupport()) { args.fVaryingHandler->addFlatPassThroughAttribute(&textureGP.fColors, args.fOutputColor); } else { args.fVaryingHandler->addPassThroughAttribute(&textureGP.fColors, args.fOutputColor); } args.fFragBuilder->codeAppend("highp float2 texCoord;"); args.fVaryingHandler->addPassThroughAttribute(&textureGP.fTextureCoords, "texCoord", kHigh_GrSLPrecision); if (textureGP.numTextureSamplers() > 1) { SkASSERT(args.fShaderCaps->integerSupport()); args.fFragBuilder->codeAppend("int texIdx;"); if (args.fShaderCaps->flatInterpolationSupport()) { args.fVaryingHandler->addFlatPassThroughAttribute(&textureGP.fTextureIdx, "texIdx"); } else { args.fVaryingHandler->addPassThroughAttribute(&textureGP.fTextureIdx, "texIdx"); } args.fFragBuilder->codeAppend("switch (texIdx) {"); for (int i = 0; i < textureGP.numTextureSamplers(); ++i) { args.fFragBuilder->codeAppendf("case %d: %s = ", i, args.fOutputColor); args.fFragBuilder->appendTextureLookupAndModulate(args.fOutputColor, args.fTexSamplers[i], "texCoord", kVec2f_GrSLType, &fColorSpaceXformHelper); args.fFragBuilder->codeAppend("; break;"); } args.fFragBuilder->codeAppend("}"); } else { args.fFragBuilder->codeAppendf("%s = ", args.fOutputColor); args.fFragBuilder->appendTextureLookupAndModulate(args.fOutputColor, args.fTexSamplers[0], "texCoord", kVec2f_GrSLType, &fColorSpaceXformHelper); } args.fFragBuilder->codeAppend(";"); args.fFragBuilder->codeAppendf("%s = float4(1);", args.fOutputCoverage); } GrGLSLColorSpaceXformHelper fColorSpaceXformHelper; }; return new GLSLProcessor; } private: // This exists to reduce the number of shaders generated. It does some rounding of sampler // counts. static int NumSamplersToUse(int numRealProxies, const GrShaderCaps& caps) { SkASSERT(numRealProxies > 0 && numRealProxies <= kMaxTextures && numRealProxies <= caps.maxFragmentSamplers()); if (1 == numRealProxies) { return 1; } if (numRealProxies <= 4) { return 4; } // Round to the next power of 2 and then clamp to kMaxTextures and the max allowed by caps. return SkTMin(SkNextPow2(numRealProxies), SkTMin(kMaxTextures, caps.maxFragmentSamplers())); } TextureGeometryProcessor(sk_sp proxies[], int proxyCnt, int samplerCnt, sk_sp csxf, const GrSamplerState::Filter filters[], const GrShaderCaps& caps) : fColorSpaceXform(std::move(csxf)) { SkASSERT(proxyCnt > 0 && samplerCnt >= proxyCnt); this->initClassID(); fPositions = this->addVertexAttrib("position", kVec2f_GrVertexAttribType, kHigh_GrSLPrecision); fSamplers[0].reset(std::move(proxies[0]), filters[0]); this->addTextureSampler(&fSamplers[0]); for (int i = 1; i < proxyCnt; ++i) { // This class has one sampler built in, the rest come from memory this processor was // placement-newed into and so haven't been constructed. new (&fSamplers[i]) TextureSampler(std::move(proxies[i]), filters[i]); this->addTextureSampler(&fSamplers[i]); } if (samplerCnt > 1) { // Here we initialize any extra samplers by repeating the last one samplerCnt - proxyCnt // times. GrTextureProxy* dupeProxy = fSamplers[proxyCnt - 1].proxy(); for (int i = proxyCnt; i < samplerCnt; ++i) { new (&fSamplers[i]) TextureSampler(sk_ref_sp(dupeProxy), filters[proxyCnt - 1]); this->addTextureSampler(&fSamplers[i]); } SkASSERT(caps.integerSupport()); fTextureIdx = this->addVertexAttrib("textureIdx", kInt_GrVertexAttribType); } fTextureCoords = this->addVertexAttrib("textureCoords", kVec2f_GrVertexAttribType, kHigh_GrSLPrecision); fColors = this->addVertexAttrib("color", kVec4ub_GrVertexAttribType); } Attribute fPositions; Attribute fTextureIdx; Attribute fTextureCoords; Attribute fColors; sk_sp fColorSpaceXform; TextureSampler fSamplers[1]; }; /** * Op that implements GrTextureOp::Make. It draws textured quads. Each quad can modulate against a * the texture by color. The blend with the destination is always src-over. The edges are non-AA. */ class TextureOp final : public GrMeshDrawOp { public: static std::unique_ptr Make(sk_sp proxy, GrSamplerState::Filter filter, GrColor color, const SkRect srcRect, const SkRect dstRect, const SkMatrix& viewMatrix, sk_sp csxf, bool allowSRBInputs) { return std::unique_ptr(new TextureOp(std::move(proxy), filter, color, srcRect, dstRect, viewMatrix, std::move(csxf), allowSRBInputs)); } ~TextureOp() override { if (fFinalized) { auto proxies = this->proxies(); for (int i = 0; i < fProxyCnt; ++i) { proxies[i]->completedRead(); } if (fProxyCnt > 1) { delete[] reinterpret_cast(proxies); } } else { SkASSERT(1 == fProxyCnt); fProxy0->unref(); } } const char* name() const override { return "TextureOp"; } SkString dumpInfo() const override { SkString str; str.appendf("AllowSRGBInputs: %d\n", fAllowSRGBInputs); str.appendf("# draws: %d\n", fDraws.count()); auto proxies = this->proxies(); for (int i = 0; i < fProxyCnt; ++i) { str.appendf("Proxy ID %d: %d, Filter: %d\n", i, proxies[i]->uniqueID().asUInt(), static_cast(this->filters()[i])); } for (int i = 0; i < fDraws.count(); ++i) { const Draw& draw = fDraws[i]; str.appendf( "%d: Color: 0x%08x, ProxyIdx: %d, TexRect [L: %.2f, T: %.2f, R: %.2f, B: %.2f] " "Quad [(%.2f, %.2f), (%.2f, %.2f), (%.2f, %.2f), (%.2f, %.2f)]\n", i, draw.fColor, draw.fTextureIdx, draw.fSrcRect.fLeft, draw.fSrcRect.fTop, draw.fSrcRect.fRight, draw.fSrcRect.fBottom, draw.fQuad.points()[0].fX, draw.fQuad.points()[0].fY, draw.fQuad.points()[1].fX, draw.fQuad.points()[1].fY, draw.fQuad.points()[2].fX, draw.fQuad.points()[2].fY, draw.fQuad.points()[3].fX, draw.fQuad.points()[3].fY); } str += INHERITED::dumpInfo(); return str; } RequiresDstTexture finalize(const GrCaps& caps, const GrAppliedClip* clip) override { SkASSERT(!fFinalized); SkASSERT(1 == fProxyCnt); fFinalized = true; fProxy0->addPendingRead(); fProxy0->unref(); return RequiresDstTexture::kNo; } FixedFunctionFlags fixedFunctionFlags() const override { return FixedFunctionFlags::kNone; } DEFINE_OP_CLASS_ID private: static constexpr int kMaxTextures = TextureGeometryProcessor::kMaxTextures; TextureOp(sk_sp proxy, GrSamplerState::Filter filter, GrColor color, const SkRect& srcRect, const SkRect& dstRect, const SkMatrix& viewMatrix, sk_sp csxf, bool allowSRGBInputs) : INHERITED(ClassID()) , fColorSpaceXform(std::move(csxf)) , fProxy0(proxy.release()) , fFilter0(filter) , fProxyCnt(1) , fFinalized(false) , fAllowSRGBInputs(allowSRGBInputs) { Draw& draw = fDraws.push_back(); draw.fSrcRect = srcRect; draw.fTextureIdx = 0; draw.fColor = color; draw.fQuad.setFromMappedRect(dstRect, viewMatrix); SkRect bounds; bounds.setBounds(draw.fQuad.points(), 4); this->setBounds(bounds, HasAABloat::kNo, IsZeroArea::kNo); } void onPrepareDraws(Target* target) override { sk_sp proxiesSPs[kMaxTextures]; auto proxies = this->proxies(); auto filters = this->filters(); for (int i = 0; i < fProxyCnt; ++i) { if (!proxies[i]->instantiate(target->resourceProvider())) { return; } proxiesSPs[i] = sk_ref_sp(proxies[i]); } sk_sp gp = TextureGeometryProcessor::Make(proxiesSPs, fProxyCnt, std::move(fColorSpaceXform), filters, *target->caps().shaderCaps()); GrPipeline::InitArgs args; args.fProxy = target->proxy(); args.fCaps = &target->caps(); args.fResourceProvider = target->resourceProvider(); args.fFlags = fAllowSRGBInputs ? GrPipeline::kAllowSRGBInputs_Flag : 0; const GrPipeline* pipeline = target->allocPipeline(args, GrProcessorSet::MakeEmptySet(), target->detachAppliedClip()); int vstart; const GrBuffer* vbuffer; void* vdata = target->makeVertexSpace(gp->getVertexStride(), 4 * fDraws.count(), &vbuffer, &vstart); if (!vdata) { SkDebugf("Could not allocate vertices\n"); return; } sk_sp ibuffer; if (fDraws.count() > 1) { ibuffer.reset(target->resourceProvider()->refQuadIndexBuffer()); if (!ibuffer) { SkDebugf("Could not allocate quad indices\n"); return; } } if (fDraws.count() > 1) { if (1 == fProxyCnt) { SkASSERT(gp->getVertexStride() == sizeof(TextureGeometryProcessor::Vertex)); for (int i = 0; i < fDraws.count(); ++i) { auto vertices = static_cast(vdata); GrTexture* texture = proxies[0]->priv().peekTexture(); float iw = 1.f / texture->width(); float ih = 1.f / texture->height(); float tl = iw * fDraws[i].fSrcRect.fLeft; float tr = iw * fDraws[i].fSrcRect.fRight; float tt = ih * fDraws[i].fSrcRect.fTop; float tb = ih * fDraws[i].fSrcRect.fBottom; if (proxies[0]->origin() == kBottomLeft_GrSurfaceOrigin) { tt = 1.f - tt; tb = 1.f - tb; } vertices[0 + 4 * i].fPosition = fDraws[i].fQuad.points()[0]; vertices[0 + 4 * i].fTextureCoords = {tl, tt}; vertices[0 + 4 * i].fColor = fDraws[i].fColor; vertices[1 + 4 * i].fPosition = fDraws[i].fQuad.points()[1]; vertices[1 + 4 * i].fTextureCoords = {tl, tb}; vertices[1 + 4 * i].fColor = fDraws[i].fColor; vertices[2 + 4 * i].fPosition = fDraws[i].fQuad.points()[2]; vertices[2 + 4 * i].fTextureCoords = {tr, tb}; vertices[2 + 4 * i].fColor = fDraws[i].fColor; vertices[3 + 4 * i].fPosition = fDraws[i].fQuad.points()[3]; vertices[3 + 4 * i].fTextureCoords = {tr, tt}; vertices[3 + 4 * i].fColor = fDraws[i].fColor; } } else { SkASSERT(gp->getVertexStride() == sizeof(TextureGeometryProcessor::MultiTextureVertex)); GrTexture* textures[kMaxTextures]; float iw[kMaxTextures]; float ih[kMaxTextures]; for (int t = 0; t < fProxyCnt; ++t) { textures[t] = proxies[t]->priv().peekTexture(); iw[t] = 1.f / textures[t]->width(); ih[t] = 1.f / textures[t]->height(); } for (int i = 0; i < fDraws.count(); ++i) { int t = fDraws[i].fTextureIdx; auto vertices = static_cast(vdata); float tl = iw[t] * fDraws[i].fSrcRect.fLeft; float tr = iw[t] * fDraws[i].fSrcRect.fRight; float tt = ih[t] * fDraws[i].fSrcRect.fTop; float tb = ih[t] * fDraws[i].fSrcRect.fBottom; if (proxies[t]->origin() == kBottomLeft_GrSurfaceOrigin) { tt = 1.f - tt; tb = 1.f - tb; } vertices[0 + 4 * i].fPosition = fDraws[i].fQuad.points()[0]; vertices[0 + 4 * i].fTextureIdx = t; vertices[0 + 4 * i].fTextureCoords = {tl, tt}; vertices[0 + 4 * i].fColor = fDraws[i].fColor; vertices[1 + 4 * i].fPosition = fDraws[i].fQuad.points()[1]; vertices[1 + 4 * i].fTextureIdx = t; vertices[1 + 4 * i].fTextureCoords = {tl, tb}; vertices[1 + 4 * i].fColor = fDraws[i].fColor; vertices[2 + 4 * i].fPosition = fDraws[i].fQuad.points()[2]; vertices[2 + 4 * i].fTextureIdx = t; vertices[2 + 4 * i].fTextureCoords = {tr, tb}; vertices[2 + 4 * i].fColor = fDraws[i].fColor; vertices[3 + 4 * i].fPosition = fDraws[i].fQuad.points()[3]; vertices[3 + 4 * i].fTextureIdx = t; vertices[3 + 4 * i].fTextureCoords = {tr, tt}; vertices[3 + 4 * i].fColor = fDraws[i].fColor; } } GrMesh mesh(GrPrimitiveType::kTriangles); mesh.setIndexedPatterned(ibuffer.get(), 6, 4, fDraws.count(), GrResourceProvider::QuadCountOfQuadBuffer()); mesh.setVertexData(vbuffer, vstart); target->draw(gp.get(), pipeline, mesh); } else { // If there is only one draw then there can only be one proxy. SkASSERT(1 == fProxyCnt); SkASSERT(gp->getVertexStride() == sizeof(TextureGeometryProcessor::Vertex)); auto vertices = static_cast(vdata); GrTexture* texture = proxies[0]->priv().peekTexture(); float iw = 1.f / texture->width(); float ih = 1.f / texture->height(); float tl = iw * fDraws[0].fSrcRect.fLeft; float tr = iw * fDraws[0].fSrcRect.fRight; float tt = ih * fDraws[0].fSrcRect.fTop; float tb = ih * fDraws[0].fSrcRect.fBottom; if (proxies[0]->origin() == kBottomLeft_GrSurfaceOrigin) { tt = 1.f - tt; tb = 1.f - tb; } vertices[0].fPosition = fDraws[0].fQuad.points()[0]; vertices[0].fTextureCoords = {tl, tt}; vertices[0].fColor = fDraws[0].fColor; vertices[1].fPosition = fDraws[0].fQuad.points()[3]; vertices[1].fTextureCoords = {tr, tt}; vertices[1].fColor = fDraws[0].fColor; vertices[2].fPosition = fDraws[0].fQuad.points()[1]; vertices[2].fTextureCoords = {tl, tb}; vertices[2].fColor = fDraws[0].fColor; vertices[3].fPosition = fDraws[0].fQuad.points()[2]; vertices[3].fTextureCoords = {tr, tb}; vertices[3].fColor = fDraws[0].fColor; GrMesh mesh(GrPrimitiveType::kTriangleStrip); mesh.setNonIndexedNonInstanced(4); mesh.setVertexData(vbuffer, vstart); target->draw(gp.get(), pipeline, mesh); } } bool onCombineIfPossible(GrOp* t, const GrCaps& caps) override { const auto* that = t->cast(); if (!GrColorSpaceXform::Equals(fColorSpaceXform.get(), that->fColorSpaceXform.get())) { return false; } if (TextureGeometryProcessor::SupportsMultitexture(*caps.shaderCaps())) { int map[kMaxTextures]; int numNewProxies = this->mergeProxies(that, map, *caps.shaderCaps()); if (numNewProxies < 0) { return false; } if (1 == fProxyCnt && numNewProxies) { void* mem = new char[(sizeof(GrSamplerState::Filter) + sizeof(GrTextureProxy*)) * kMaxTextures]; auto proxies = reinterpret_cast(mem); auto filters = reinterpret_cast(proxies + kMaxTextures); proxies[0] = fProxy0; filters[0] = fFilter0; fProxyArray = proxies; } fProxyCnt += numNewProxies; auto thisProxies = fProxyArray; auto thatProxies = that->proxies(); auto thatFilters = that->filters(); auto thisFilters = reinterpret_cast(thisProxies + kMaxTextures); for (int i = 0; i < that->fProxyCnt; ++i) { if (map[i] < 0) { thatProxies[i]->addPendingRead(); thisProxies[-map[i]] = thatProxies[i]; thisFilters[-map[i]] = thatFilters[i]; map[i] = -map[i]; } } int firstNewDraw = fDraws.count(); fDraws.push_back_n(that->fDraws.count(), that->fDraws.begin()); for (int i = firstNewDraw; i < fDraws.count(); ++i) { fDraws[i].fTextureIdx = map[fDraws[i].fTextureIdx]; } } else { if (fProxy0->uniqueID() != that->fProxy0->uniqueID() || fFilter0 != that->fFilter0) { return false; } fDraws.push_back_n(that->fDraws.count(), that->fDraws.begin()); } this->joinBounds(*that); return true; } /** * Determines a mapping of indices from that's proxy array to this's proxy array. A negative map * value means that's proxy should be added to this's proxy array at the absolute value of * the map entry. If it is determined that the ops shouldn't combine their proxies then a * negative value is returned. Otherwise, return value indicates the number of proxies that have * to be added to this op or, equivalently, the number of negative entries in map. */ int mergeProxies(const TextureOp* that, int map[kMaxTextures], const GrShaderCaps& caps) const { std::fill_n(map, kMaxTextures, -kMaxTextures); int sharedProxyCnt = 0; auto thisProxies = this->proxies(); auto thisFilters = this->filters(); auto thatProxies = that->proxies(); auto thatFilters = that->filters(); for (int i = 0; i < fProxyCnt; ++i) { for (int j = 0; j < that->fProxyCnt; ++j) { if (thisProxies[i]->uniqueID() == thatProxies[j]->uniqueID()) { if (thisFilters[i] != thatFilters[j]) { // In GL we don't currently support using the same texture with different // samplers. If we added support for sampler objects and a cap bit to know // it's ok to use different filter modes then we could support this. // Otherwise, we could also only allow a single filter mode for each op // instance. return -1; } map[j] = i; ++sharedProxyCnt; break; } } } int actualMaxTextures = SkTMin(caps.maxFragmentImageStorages(), kMaxTextures); int newProxyCnt = that->fProxyCnt - sharedProxyCnt; if (newProxyCnt + fProxyCnt > actualMaxTextures) { return -1; } GrPixelConfig config = thisProxies[0]->config(); int nextSlot = fProxyCnt; for (int j = 0; j < that->fProxyCnt; ++j) { // We want to avoid making many shaders because of different permutations of shader // based swizzle and sampler types. The approach taken here is to require the configs to // be the same and to only allow already instantiated proxies that have the most // common sampler type. Otherwise we don't merge. if (thatProxies[j]->config() != config) { return -1; } if (GrTexture* tex = thatProxies[j]->priv().peekTexture()) { if (tex->texturePriv().samplerType() != kTexture2DSampler_GrSLType) { return -1; } } if (map[j] < 0) { map[j] = -(nextSlot++); } } return newProxyCnt; } GrTextureProxy* const* proxies() const { return fProxyCnt > 1 ? fProxyArray : &fProxy0; } const GrSamplerState::Filter* filters() const { if (fProxyCnt > 1) { return reinterpret_cast(fProxyArray + kMaxTextures); } return &fFilter0; } struct Draw { SkRect fSrcRect; int fTextureIdx; GrQuad fQuad; GrColor fColor; }; SkSTArray<1, Draw, true> fDraws; sk_sp fColorSpaceXform; // Initially we store a single proxy ptr and a single filter. If we grow to have more than // one proxy we instead store pointers to dynamically allocated arrays of size kMaxTextures // followed by kMaxTextures filters. union { GrTextureProxy* fProxy0; GrTextureProxy** fProxyArray; }; // The next four members should pack. GrSamplerState::Filter fFilter0; uint8_t fProxyCnt; // Used to track whether fProxy is ref'ed or has a pending IO after finalize() is called. uint8_t fFinalized; uint8_t fAllowSRGBInputs; typedef GrMeshDrawOp INHERITED; }; constexpr int TextureGeometryProcessor::kMaxTextures; constexpr int TextureOp::kMaxTextures; } // anonymous namespace namespace GrTextureOp { std::unique_ptr Make(sk_sp proxy, GrSamplerState::Filter filter, GrColor color, const SkRect& srcRect, const SkRect& dstRect, const SkMatrix& viewMatrix, sk_sp csxf, bool allowSRGBInputs) { SkASSERT(!viewMatrix.hasPerspective()); return TextureOp::Make(std::move(proxy), filter, color, srcRect, dstRect, viewMatrix, std::move(csxf), allowSRGBInputs); } } // namespace GrTextureOp #if GR_TEST_UTILS #include "GrContext.h" GR_DRAW_OP_TEST_DEFINE(TextureOp) { GrSurfaceDesc desc; desc.fConfig = kRGBA_8888_GrPixelConfig; desc.fHeight = random->nextULessThan(90) + 10; desc.fWidth = random->nextULessThan(90) + 10; desc.fOrigin = random->nextBool() ? kTopLeft_GrSurfaceOrigin : kBottomLeft_GrSurfaceOrigin; SkBackingFit fit = random->nextBool() ? SkBackingFit::kApprox : SkBackingFit::kExact; auto proxy = GrSurfaceProxy::MakeDeferred(context->resourceProvider(), desc, fit, SkBudgeted::kNo); SkRect rect = GrTest::TestRect(random); SkRect srcRect; srcRect.fLeft = random->nextRangeScalar(0.f, proxy->width() / 2.f); srcRect.fRight = random->nextRangeScalar(0.f, proxy->width()) + proxy->width() / 2.f; srcRect.fTop = random->nextRangeScalar(0.f, proxy->height() / 2.f); srcRect.fBottom = random->nextRangeScalar(0.f, proxy->height()) + proxy->height() / 2.f; SkMatrix viewMatrix = GrTest::TestMatrixPreservesRightAngles(random); GrColor color = SkColorToPremulGrColor(random->nextU()); GrSamplerState::Filter filter = (GrSamplerState::Filter)random->nextULessThan( static_cast(GrSamplerState::Filter::kMipMap) + 1); auto csxf = GrTest::TestColorXform(random); bool allowSRGBInputs = random->nextBool(); return GrTextureOp::Make(std::move(proxy), filter, color, srcRect, rect, viewMatrix, std::move(csxf), allowSRGBInputs); } #endif