/* * 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 "SkArenaAlloc.h" #include "SkBitmapProcShader.h" #include "SkBitmapProcState.h" #include "SkColor.h" #include "SkEmptyShader.h" #include "SkLightingShader.h" #include "SkMathPriv.h" #include "SkNormalSource.h" #include "SkPoint3.h" #include "SkReadBuffer.h" #include "SkWriteBuffer.h" //////////////////////////////////////////////////////////////////////////// /* SkLightingShader TODOs: support different light types support multiple lights fix non-opaque diffuse textures To Test: A8 diffuse textures down & upsampled draws */ /** \class SkLightingShaderImpl This subclass of shader applies lighting. */ class SkLightingShaderImpl : public SkShader { public: /** Create a new lighting shader that uses the provided normal map and lights to light the diffuse bitmap. @param diffuseShader the shader that provides the diffuse colors @param normalSource the source of normals for lighting computation @param lights the lights applied to the geometry */ SkLightingShaderImpl(sk_sp diffuseShader, sk_sp normalSource, sk_sp lights) : fDiffuseShader(std::move(diffuseShader)) , fNormalSource(std::move(normalSource)) , fLights(std::move(lights)) {} bool isOpaque() const override; #if SK_SUPPORT_GPU sk_sp asFragmentProcessor(const AsFPArgs&) const override; #endif class LightingShaderContext : public SkShader::Context { public: // The context takes ownership of the context and provider. It will call their destructors // and then indirectly free their memory by calling free() on heapAllocated LightingShaderContext(const SkLightingShaderImpl&, const ContextRec&, SkShader::Context* diffuseContext, SkNormalSource::Provider*, void* heapAllocated); void shadeSpan(int x, int y, SkPMColor[], int count) override; uint32_t getFlags() const override { return fFlags; } private: SkShader::Context* fDiffuseContext; SkNormalSource::Provider* fNormalProvider; SkColor fPaintColor; uint32_t fFlags; typedef SkShader::Context INHERITED; }; SK_TO_STRING_OVERRIDE() SK_DECLARE_PUBLIC_FLATTENABLE_DESERIALIZATION_PROCS(SkLightingShaderImpl) protected: void flatten(SkWriteBuffer&) const override; Context* onMakeContext(const ContextRec&, SkArenaAlloc*) const override; private: sk_sp fDiffuseShader; sk_sp fNormalSource; sk_sp fLights; friend class SkLightingShader; typedef SkShader INHERITED; }; //////////////////////////////////////////////////////////////////////////// #if SK_SUPPORT_GPU #include "GrCoordTransform.h" #include "GrFragmentProcessor.h" #include "glsl/GrGLSLFragmentProcessor.h" #include "glsl/GrGLSLFragmentShaderBuilder.h" #include "glsl/GrGLSLProgramDataManager.h" #include "glsl/GrGLSLUniformHandler.h" #include "SkGr.h" // This FP expects a premul'd color input for its diffuse color. Premul'ing of the paint's color is // handled by the asFragmentProcessor() factory, but shaders providing diffuse color must output it // premul'd. class LightingFP : public GrFragmentProcessor { public: LightingFP(sk_sp normalFP, sk_sp lights) : INHERITED(kPreservesOpaqueInput_OptimizationFlag) { // fuse all ambient lights into a single one fAmbientColor = lights->ambientLightColor(); for (int i = 0; i < lights->numLights(); ++i) { if (SkLights::Light::kDirectional_LightType == lights->light(i).type()) { fDirectionalLights.push_back(lights->light(i)); // TODO get the handle to the shadow map if there is one } else { SkDEBUGFAIL("Unimplemented Light Type passed to LightingFP"); } } this->registerChildProcessor(std::move(normalFP)); this->initClassID(); } class GLSLLightingFP : public GrGLSLFragmentProcessor { public: GLSLLightingFP() { fAmbientColor.fX = 0.0f; } void emitCode(EmitArgs& args) override { GrGLSLFragmentBuilder* fragBuilder = args.fFragBuilder; GrGLSLUniformHandler* uniformHandler = args.fUniformHandler; const LightingFP& lightingFP = args.fFp.cast(); const char *lightDirsUniName = nullptr; const char *lightColorsUniName = nullptr; if (lightingFP.fDirectionalLights.count() != 0) { fLightDirsUni = uniformHandler->addUniformArray( kFragment_GrShaderFlag, kVec3f_GrSLType, kDefault_GrSLPrecision, "LightDir", lightingFP.fDirectionalLights.count(), &lightDirsUniName); fLightColorsUni = uniformHandler->addUniformArray( kFragment_GrShaderFlag, kVec3f_GrSLType, kDefault_GrSLPrecision, "LightColor", lightingFP.fDirectionalLights.count(), &lightColorsUniName); } const char* ambientColorUniName = nullptr; fAmbientColorUni = uniformHandler->addUniform(kFragment_GrShaderFlag, kVec3f_GrSLType, kDefault_GrSLPrecision, "AmbientColor", &ambientColorUniName); fragBuilder->codeAppendf("vec4 diffuseColor = %s;", args.fInputColor); SkString dstNormalName("dstNormal"); this->emitChild(0, nullptr, &dstNormalName, args); fragBuilder->codeAppendf("vec3 normal = %s.xyz;", dstNormalName.c_str()); fragBuilder->codeAppend( "vec3 result = vec3(0.0);"); // diffuse light if (lightingFP.fDirectionalLights.count() != 0) { fragBuilder->codeAppendf("for (int i = 0; i < %d; i++) {", lightingFP.fDirectionalLights.count()); // TODO: modulate the contribution from each light based on the shadow map fragBuilder->codeAppendf(" float NdotL = clamp(dot(normal, %s[i]), 0.0, 1.0);", lightDirsUniName); fragBuilder->codeAppendf(" result += %s[i]*diffuseColor.rgb*NdotL;", lightColorsUniName); fragBuilder->codeAppend("}"); } // ambient light fragBuilder->codeAppendf("result += %s * diffuseColor.rgb;", ambientColorUniName); // Clamping to alpha (equivalent to an unpremul'd clamp to 1.0) fragBuilder->codeAppendf("%s = vec4(clamp(result.rgb, 0.0, diffuseColor.a), " "diffuseColor.a);", args.fOutputColor); } static void GenKey(const GrProcessor& proc, const GrShaderCaps&, GrProcessorKeyBuilder* b) { const LightingFP& lightingFP = proc.cast(); b->add32(lightingFP.fDirectionalLights.count()); } protected: void onSetData(const GrGLSLProgramDataManager& pdman, const GrFragmentProcessor& proc) override { const LightingFP& lightingFP = proc.cast(); const SkTArray& directionalLights = lightingFP.directionalLights(); if (directionalLights != fDirectionalLights) { SkTArray lightDirs(directionalLights.count()); SkTArray lightColors(directionalLights.count()); for (const SkLights::Light& light : directionalLights) { lightDirs.push_back(light.dir()); lightColors.push_back(light.color()); } pdman.set3fv(fLightDirsUni, directionalLights.count(), &(lightDirs[0].fX)); pdman.set3fv(fLightColorsUni, directionalLights.count(), &(lightColors[0].fX)); fDirectionalLights = directionalLights; } const SkColor3f& ambientColor = lightingFP.ambientColor(); if (ambientColor != fAmbientColor) { pdman.set3fv(fAmbientColorUni, 1, &ambientColor.fX); fAmbientColor = ambientColor; } } private: SkTArray fDirectionalLights; GrGLSLProgramDataManager::UniformHandle fLightDirsUni; GrGLSLProgramDataManager::UniformHandle fLightColorsUni; SkColor3f fAmbientColor; GrGLSLProgramDataManager::UniformHandle fAmbientColorUni; }; void onGetGLSLProcessorKey(const GrShaderCaps& caps, GrProcessorKeyBuilder* b) const override { GLSLLightingFP::GenKey(*this, caps, b); } const char* name() const override { return "LightingFP"; } const SkTArray& directionalLights() const { return fDirectionalLights; } const SkColor3f& ambientColor() const { return fAmbientColor; } private: GrGLSLFragmentProcessor* onCreateGLSLInstance() const override { return new GLSLLightingFP; } bool onIsEqual(const GrFragmentProcessor& proc) const override { const LightingFP& lightingFP = proc.cast(); return fDirectionalLights == lightingFP.fDirectionalLights && fAmbientColor == lightingFP.fAmbientColor; } SkTArray fDirectionalLights; SkColor3f fAmbientColor; typedef GrFragmentProcessor INHERITED; }; //////////////////////////////////////////////////////////////////////////// sk_sp SkLightingShaderImpl::asFragmentProcessor(const AsFPArgs& args) const { sk_sp normalFP(fNormalSource->asFragmentProcessor(args)); if (!normalFP) { return nullptr; } if (fDiffuseShader) { sk_sp fpPipeline[] = { fDiffuseShader->asFragmentProcessor(args), sk_make_sp(std::move(normalFP), fLights) }; if(!fpPipeline[0]) { return nullptr; } sk_sp innerLightFP = GrFragmentProcessor::RunInSeries(fpPipeline, 2); // FP is wrapped because paint's alpha needs to be applied to output return GrFragmentProcessor::MulOutputByInputAlpha(std::move(innerLightFP)); } else { // FP is wrapped because paint comes in unpremul'd to fragment shader, but LightingFP // expects premul'd color. return GrFragmentProcessor::PremulInput(sk_make_sp(std::move(normalFP), fLights)); } } #endif //////////////////////////////////////////////////////////////////////////// bool SkLightingShaderImpl::isOpaque() const { return (fDiffuseShader ? fDiffuseShader->isOpaque() : false); } SkLightingShaderImpl::LightingShaderContext::LightingShaderContext( const SkLightingShaderImpl& shader, const ContextRec& rec, SkShader::Context* diffuseContext, SkNormalSource::Provider* normalProvider, void* heapAllocated) : INHERITED(shader, rec) , fDiffuseContext(diffuseContext) , fNormalProvider(normalProvider) { bool isOpaque = shader.isOpaque(); // update fFlags uint32_t flags = 0; if (isOpaque && (255 == this->getPaintAlpha())) { flags |= kOpaqueAlpha_Flag; } fPaintColor = rec.fPaint->getColor(); fFlags = flags; } static inline SkPMColor convert(SkColor3f color, U8CPU a) { if (color.fX <= 0.0f) { color.fX = 0.0f; } else if (color.fX >= 255.0f) { color.fX = 255.0f; } if (color.fY <= 0.0f) { color.fY = 0.0f; } else if (color.fY >= 255.0f) { color.fY = 255.0f; } if (color.fZ <= 0.0f) { color.fZ = 0.0f; } else if (color.fZ >= 255.0f) { color.fZ = 255.0f; } return SkPreMultiplyARGB(a, (int) color.fX, (int) color.fY, (int) color.fZ); } // larger is better (fewer times we have to loop), but we shouldn't // take up too much stack-space (each one here costs 16 bytes) #define BUFFER_MAX 16 void SkLightingShaderImpl::LightingShaderContext::shadeSpan(int x, int y, SkPMColor result[], int count) { const SkLightingShaderImpl& lightShader = static_cast(fShader); SkPMColor diffuse[BUFFER_MAX]; SkPoint3 normals[BUFFER_MAX]; SkColor diffColor = fPaintColor; do { int n = SkTMin(count, BUFFER_MAX); fNormalProvider->fillScanLine(x, y, normals, n); if (fDiffuseContext) { fDiffuseContext->shadeSpan(x, y, diffuse, n); } for (int i = 0; i < n; ++i) { if (fDiffuseContext) { diffColor = SkUnPreMultiply::PMColorToColor(diffuse[i]); } SkColor3f accum = SkColor3f::Make(0.0f, 0.0f, 0.0f); // Adding ambient light accum.fX += lightShader.fLights->ambientLightColor().fX * SkColorGetR(diffColor); accum.fY += lightShader.fLights->ambientLightColor().fY * SkColorGetG(diffColor); accum.fZ += lightShader.fLights->ambientLightColor().fZ * SkColorGetB(diffColor); // This is all done in linear unpremul color space (each component 0..255.0f though) for (int l = 0; l < lightShader.fLights->numLights(); ++l) { const SkLights::Light& light = lightShader.fLights->light(l); SkScalar illuminanceScalingFactor = 1.0f; if (SkLights::Light::kDirectional_LightType == light.type()) { illuminanceScalingFactor = normals[i].dot(light.dir()); if (illuminanceScalingFactor < 0.0f) { illuminanceScalingFactor = 0.0f; } } accum.fX += light.color().fX * SkColorGetR(diffColor) * illuminanceScalingFactor; accum.fY += light.color().fY * SkColorGetG(diffColor) * illuminanceScalingFactor; accum.fZ += light.color().fZ * SkColorGetB(diffColor) * illuminanceScalingFactor; } // convert() premultiplies the accumulate color with alpha result[i] = convert(accum, SkColorGetA(diffColor)); } result += n; x += n; count -= n; } while (count > 0); } //////////////////////////////////////////////////////////////////////////// #ifndef SK_IGNORE_TO_STRING void SkLightingShaderImpl::toString(SkString* str) const { str->appendf("LightingShader: ()"); } #endif sk_sp SkLightingShaderImpl::CreateProc(SkReadBuffer& buf) { // Discarding SkShader flattenable params bool hasLocalMatrix = buf.readBool(); SkAssertResult(!hasLocalMatrix); sk_sp lights = SkLights::MakeFromBuffer(buf); sk_sp normalSource(buf.readFlattenable()); bool hasDiffuse = buf.readBool(); sk_sp diffuseShader = nullptr; if (hasDiffuse) { diffuseShader = buf.readFlattenable(); } return sk_make_sp(std::move(diffuseShader), std::move(normalSource), std::move(lights)); } void SkLightingShaderImpl::flatten(SkWriteBuffer& buf) const { this->INHERITED::flatten(buf); fLights->flatten(buf); buf.writeFlattenable(fNormalSource.get()); buf.writeBool(fDiffuseShader); if (fDiffuseShader) { buf.writeFlattenable(fDiffuseShader.get()); } } SkShader::Context* SkLightingShaderImpl::onMakeContext( const ContextRec& rec, SkArenaAlloc* alloc) const { SkShader::Context *diffuseContext = nullptr; if (fDiffuseShader) { diffuseContext = fDiffuseShader->makeContext(rec, alloc); if (!diffuseContext) { return nullptr; } } SkNormalSource::Provider* normalProvider = fNormalSource->asProvider(rec, alloc); if (!normalProvider) { return nullptr; } return alloc->make(*this, rec, diffuseContext, normalProvider, nullptr); } /////////////////////////////////////////////////////////////////////////////// sk_sp SkLightingShader::Make(sk_sp diffuseShader, sk_sp normalSource, sk_sp lights) { SkASSERT(lights); if (!normalSource) { normalSource = SkNormalSource::MakeFlat(); } return sk_make_sp(std::move(diffuseShader), std::move(normalSource), std::move(lights)); } /////////////////////////////////////////////////////////////////////////////// SK_DEFINE_FLATTENABLE_REGISTRAR_GROUP_START(SkLightingShader) SK_DEFINE_FLATTENABLE_REGISTRAR_ENTRY(SkLightingShaderImpl) SK_DEFINE_FLATTENABLE_REGISTRAR_GROUP_END ///////////////////////////////////////////////////////////////////////////////