// // Copyright (c) 2002-2014 The ANGLE Project Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // #include "compiler/translator/OutputHLSL.h" #include #include #include #include "common/angleutils.h" #include "common/debug.h" #include "common/utilities.h" #include "compiler/translator/BuiltInFunctionEmulator.h" #include "compiler/translator/BuiltInFunctionEmulatorHLSL.h" #include "compiler/translator/ImageFunctionHLSL.h" #include "compiler/translator/InfoSink.h" #include "compiler/translator/NodeSearch.h" #include "compiler/translator/RemoveSwitchFallThrough.h" #include "compiler/translator/SearchSymbol.h" #include "compiler/translator/StructureHLSL.h" #include "compiler/translator/TextureFunctionHLSL.h" #include "compiler/translator/TranslatorHLSL.h" #include "compiler/translator/UniformHLSL.h" #include "compiler/translator/UtilsHLSL.h" #include "compiler/translator/blocklayout.h" #include "compiler/translator/util.h" namespace sh { namespace { TString ArrayHelperFunctionName(const char *prefix, const TType &type) { TStringStream fnName; fnName << prefix << "_"; if (type.isArray()) { for (unsigned int arraySize : *type.getArraySizes()) { fnName << arraySize << "_"; } } fnName << TypeString(type); return fnName.str(); } bool IsDeclarationWrittenOut(TIntermDeclaration *node) { TIntermSequence *sequence = node->getSequence(); TIntermTyped *variable = (*sequence)[0]->getAsTyped(); ASSERT(sequence->size() == 1); ASSERT(variable); return (variable->getQualifier() == EvqTemporary || variable->getQualifier() == EvqGlobal || variable->getQualifier() == EvqConst); } bool IsInStd140InterfaceBlock(TIntermTyped *node) { TIntermBinary *binaryNode = node->getAsBinaryNode(); if (binaryNode) { return IsInStd140InterfaceBlock(binaryNode->getLeft()); } const TType &type = node->getType(); // determine if we are in the standard layout const TInterfaceBlock *interfaceBlock = type.getInterfaceBlock(); if (interfaceBlock) { return (interfaceBlock->blockStorage() == EbsStd140); } return false; } } // anonymous namespace void OutputHLSL::writeFloat(TInfoSinkBase &out, float f) { // This is known not to work for NaN on all drivers but make the best effort to output NaNs // regardless. if ((gl::isInf(f) || gl::isNaN(f)) && mShaderVersion >= 300 && mOutputType == SH_HLSL_4_1_OUTPUT) { out << "asfloat(" << gl::bitCast(f) << "u)"; } else { out << std::min(FLT_MAX, std::max(-FLT_MAX, f)); } } void OutputHLSL::writeSingleConstant(TInfoSinkBase &out, const TConstantUnion *const constUnion) { ASSERT(constUnion != nullptr); switch (constUnion->getType()) { case EbtFloat: writeFloat(out, constUnion->getFConst()); break; case EbtInt: out << constUnion->getIConst(); break; case EbtUInt: out << constUnion->getUConst(); break; case EbtBool: out << constUnion->getBConst(); break; default: UNREACHABLE(); } } const TConstantUnion *OutputHLSL::writeConstantUnionArray(TInfoSinkBase &out, const TConstantUnion *const constUnion, const size_t size) { const TConstantUnion *constUnionIterated = constUnion; for (size_t i = 0; i < size; i++, constUnionIterated++) { writeSingleConstant(out, constUnionIterated); if (i != size - 1) { out << ", "; } } return constUnionIterated; } OutputHLSL::OutputHLSL(sh::GLenum shaderType, int shaderVersion, const TExtensionBehavior &extensionBehavior, const char *sourcePath, ShShaderOutput outputType, int numRenderTargets, const std::vector &uniforms, ShCompileOptions compileOptions, TSymbolTable *symbolTable, PerformanceDiagnostics *perfDiagnostics) : TIntermTraverser(true, true, true, symbolTable), mShaderType(shaderType), mShaderVersion(shaderVersion), mExtensionBehavior(extensionBehavior), mSourcePath(sourcePath), mOutputType(outputType), mCompileOptions(compileOptions), mNumRenderTargets(numRenderTargets), mCurrentFunctionMetadata(nullptr), mPerfDiagnostics(perfDiagnostics) { mInsideFunction = false; mUsesFragColor = false; mUsesFragData = false; mUsesDepthRange = false; mUsesFragCoord = false; mUsesPointCoord = false; mUsesFrontFacing = false; mUsesPointSize = false; mUsesInstanceID = false; mHasMultiviewExtensionEnabled = IsExtensionEnabled(mExtensionBehavior, TExtension::OVR_multiview); mUsesViewID = false; mUsesVertexID = false; mUsesFragDepth = false; mUsesNumWorkGroups = false; mUsesWorkGroupID = false; mUsesLocalInvocationID = false; mUsesGlobalInvocationID = false; mUsesLocalInvocationIndex = false; mUsesXor = false; mUsesDiscardRewriting = false; mUsesNestedBreak = false; mRequiresIEEEStrictCompiling = false; mUniqueIndex = 0; mOutputLod0Function = false; mInsideDiscontinuousLoop = false; mNestedLoopDepth = 0; mExcessiveLoopIndex = nullptr; mStructureHLSL = new StructureHLSL; mUniformHLSL = new UniformHLSL(shaderType, mStructureHLSL, outputType, uniforms); mTextureFunctionHLSL = new TextureFunctionHLSL; mImageFunctionHLSL = new ImageFunctionHLSL; if (mOutputType == SH_HLSL_3_0_OUTPUT) { // Fragment shaders need dx_DepthRange, dx_ViewCoords and dx_DepthFront. // Vertex shaders need a slightly different set: dx_DepthRange, dx_ViewCoords and // dx_ViewAdjust. // In both cases total 3 uniform registers need to be reserved. mUniformHLSL->reserveUniformRegisters(3); } // Reserve registers for the default uniform block and driver constants mUniformHLSL->reserveUniformBlockRegisters(2); } OutputHLSL::~OutputHLSL() { SafeDelete(mStructureHLSL); SafeDelete(mUniformHLSL); SafeDelete(mTextureFunctionHLSL); SafeDelete(mImageFunctionHLSL); for (auto &eqFunction : mStructEqualityFunctions) { SafeDelete(eqFunction); } for (auto &eqFunction : mArrayEqualityFunctions) { SafeDelete(eqFunction); } } void OutputHLSL::output(TIntermNode *treeRoot, TInfoSinkBase &objSink) { BuiltInFunctionEmulator builtInFunctionEmulator; InitBuiltInFunctionEmulatorForHLSL(&builtInFunctionEmulator); if ((mCompileOptions & SH_EMULATE_ISNAN_FLOAT_FUNCTION) != 0) { InitBuiltInIsnanFunctionEmulatorForHLSLWorkarounds(&builtInFunctionEmulator, mShaderVersion); } builtInFunctionEmulator.markBuiltInFunctionsForEmulation(treeRoot); // Now that we are done changing the AST, do the analyses need for HLSL generation CallDAG::InitResult success = mCallDag.init(treeRoot, nullptr); ASSERT(success == CallDAG::INITDAG_SUCCESS); mASTMetadataList = CreateASTMetadataHLSL(treeRoot, mCallDag); const std::vector std140Structs = FlagStd140Structs(treeRoot); // TODO(oetuaho): The std140Structs could be filtered based on which ones actually get used in // the shader code. When we add shader storage blocks we might also consider an alternative // solution, since the struct mapping won't work very well for shader storage blocks. // Output the body and footer first to determine what has to go in the header mInfoSinkStack.push(&mBody); treeRoot->traverse(this); mInfoSinkStack.pop(); mInfoSinkStack.push(&mFooter); mInfoSinkStack.pop(); mInfoSinkStack.push(&mHeader); header(mHeader, std140Structs, &builtInFunctionEmulator); mInfoSinkStack.pop(); objSink << mHeader.c_str(); objSink << mBody.c_str(); objSink << mFooter.c_str(); builtInFunctionEmulator.cleanup(); } const std::map &OutputHLSL::getUniformBlockRegisterMap() const { return mUniformHLSL->getUniformBlockRegisterMap(); } const std::map &OutputHLSL::getUniformRegisterMap() const { return mUniformHLSL->getUniformRegisterMap(); } TString OutputHLSL::structInitializerString(int indent, const TType &type, const TString &name) const { TString init; TString indentString; for (int spaces = 0; spaces < indent; spaces++) { indentString += " "; } if (type.isArray()) { init += indentString + "{\n"; for (unsigned int arrayIndex = 0u; arrayIndex < type.getOutermostArraySize(); ++arrayIndex) { TStringStream indexedString; indexedString << name << "[" << arrayIndex << "]"; TType elementType = type; elementType.toArrayElementType(); init += structInitializerString(indent + 1, elementType, indexedString.str()); if (arrayIndex < type.getOutermostArraySize() - 1) { init += ","; } init += "\n"; } init += indentString + "}"; } else if (type.getBasicType() == EbtStruct) { init += indentString + "{\n"; const TStructure &structure = *type.getStruct(); const TFieldList &fields = structure.fields(); for (unsigned int fieldIndex = 0; fieldIndex < fields.size(); fieldIndex++) { const TField &field = *fields[fieldIndex]; const TString &fieldName = name + "." + Decorate(field.name()); const TType &fieldType = *field.type(); init += structInitializerString(indent + 1, fieldType, fieldName); if (fieldIndex < fields.size() - 1) { init += ","; } init += "\n"; } init += indentString + "}"; } else { init += indentString + name; } return init; } TString OutputHLSL::generateStructMapping(const std::vector &std140Structs) const { TString mappedStructs; for (auto &mappedStruct : std140Structs) { TInterfaceBlock *interfaceBlock = mappedStruct.blockDeclarator->getType().getInterfaceBlock(); const TString &interfaceBlockName = interfaceBlock->name(); const TName &instanceName = mappedStruct.blockDeclarator->getName(); if (mReferencedUniformBlocks.count(interfaceBlockName) == 0 && (instanceName.getString() == "" || mReferencedUniformBlocks.count(instanceName.getString()) == 0)) { continue; } unsigned int instanceCount = 1u; bool isInstanceArray = mappedStruct.blockDeclarator->isArray(); if (isInstanceArray) { instanceCount = mappedStruct.blockDeclarator->getOutermostArraySize(); } for (unsigned int instanceArrayIndex = 0; instanceArrayIndex < instanceCount; ++instanceArrayIndex) { TString originalName; TString mappedName("map"); if (instanceName.getString() != "") { unsigned int instanceStringArrayIndex = GL_INVALID_INDEX; if (isInstanceArray) instanceStringArrayIndex = instanceArrayIndex; TString instanceString = mUniformHLSL->uniformBlockInstanceString( *interfaceBlock, instanceStringArrayIndex); originalName += instanceString; mappedName += instanceString; originalName += "."; mappedName += "_"; } TString fieldName = Decorate(mappedStruct.field->name()); originalName += fieldName; mappedName += fieldName; TType *structType = mappedStruct.field->type(); mappedStructs += "static " + Decorate(structType->getStruct()->name()) + " " + mappedName; if (structType->isArray()) { mappedStructs += ArrayString(*mappedStruct.field->type()); } mappedStructs += " =\n"; mappedStructs += structInitializerString(0, *structType, originalName); mappedStructs += ";\n"; } } return mappedStructs; } void OutputHLSL::header(TInfoSinkBase &out, const std::vector &std140Structs, const BuiltInFunctionEmulator *builtInFunctionEmulator) const { TString varyings; TString attributes; TString mappedStructs = generateStructMapping(std140Structs); for (ReferencedSymbols::const_iterator varying = mReferencedVaryings.begin(); varying != mReferencedVaryings.end(); varying++) { const TType &type = varying->second->getType(); const TString &name = varying->second->getSymbol(); // Program linking depends on this exact format varyings += "static " + InterpolationString(type.getQualifier()) + " " + TypeString(type) + " " + Decorate(name) + ArrayString(type) + " = " + initializer(type) + ";\n"; } for (ReferencedSymbols::const_iterator attribute = mReferencedAttributes.begin(); attribute != mReferencedAttributes.end(); attribute++) { const TType &type = attribute->second->getType(); const TString &name = attribute->second->getSymbol(); attributes += "static " + TypeString(type) + " " + Decorate(name) + ArrayString(type) + " = " + initializer(type) + ";\n"; } out << mStructureHLSL->structsHeader(); mUniformHLSL->uniformsHeader(out, mOutputType, mReferencedUniforms, mSymbolTable); out << mUniformHLSL->uniformBlocksHeader(mReferencedUniformBlocks); if (!mEqualityFunctions.empty()) { out << "\n// Equality functions\n\n"; for (const auto &eqFunction : mEqualityFunctions) { out << eqFunction->functionDefinition << "\n"; } } if (!mArrayAssignmentFunctions.empty()) { out << "\n// Assignment functions\n\n"; for (const auto &assignmentFunction : mArrayAssignmentFunctions) { out << assignmentFunction.functionDefinition << "\n"; } } if (!mArrayConstructIntoFunctions.empty()) { out << "\n// Array constructor functions\n\n"; for (const auto &constructIntoFunction : mArrayConstructIntoFunctions) { out << constructIntoFunction.functionDefinition << "\n"; } } if (mUsesDiscardRewriting) { out << "#define ANGLE_USES_DISCARD_REWRITING\n"; } if (mUsesNestedBreak) { out << "#define ANGLE_USES_NESTED_BREAK\n"; } if (mRequiresIEEEStrictCompiling) { out << "#define ANGLE_REQUIRES_IEEE_STRICT_COMPILING\n"; } out << "#ifdef ANGLE_ENABLE_LOOP_FLATTEN\n" "#define LOOP [loop]\n" "#define FLATTEN [flatten]\n" "#else\n" "#define LOOP\n" "#define FLATTEN\n" "#endif\n"; if (mShaderType == GL_FRAGMENT_SHADER) { const bool usingMRTExtension = IsExtensionEnabled(mExtensionBehavior, TExtension::EXT_draw_buffers); out << "// Varyings\n"; out << varyings; out << "\n"; if (mShaderVersion >= 300) { for (ReferencedSymbols::const_iterator outputVariableIt = mReferencedOutputVariables.begin(); outputVariableIt != mReferencedOutputVariables.end(); outputVariableIt++) { const TString &variableName = outputVariableIt->first; const TType &variableType = outputVariableIt->second->getType(); out << "static " + TypeString(variableType) + " out_" + variableName + ArrayString(variableType) + " = " + initializer(variableType) + ";\n"; } } else { const unsigned int numColorValues = usingMRTExtension ? mNumRenderTargets : 1; out << "static float4 gl_Color[" << numColorValues << "] =\n" "{\n"; for (unsigned int i = 0; i < numColorValues; i++) { out << " float4(0, 0, 0, 0)"; if (i + 1 != numColorValues) { out << ","; } out << "\n"; } out << "};\n"; } if (mUsesFragDepth) { out << "static float gl_Depth = 0.0;\n"; } if (mUsesFragCoord) { out << "static float4 gl_FragCoord = float4(0, 0, 0, 0);\n"; } if (mUsesPointCoord) { out << "static float2 gl_PointCoord = float2(0.5, 0.5);\n"; } if (mUsesFrontFacing) { out << "static bool gl_FrontFacing = false;\n"; } out << "\n"; if (mUsesDepthRange) { out << "struct gl_DepthRangeParameters\n" "{\n" " float near;\n" " float far;\n" " float diff;\n" "};\n" "\n"; } if (mOutputType == SH_HLSL_4_1_OUTPUT || mOutputType == SH_HLSL_4_0_FL9_3_OUTPUT) { out << "cbuffer DriverConstants : register(b1)\n" "{\n"; if (mUsesDepthRange) { out << " float3 dx_DepthRange : packoffset(c0);\n"; } if (mUsesFragCoord) { out << " float4 dx_ViewCoords : packoffset(c1);\n"; } if (mUsesFragCoord || mUsesFrontFacing) { out << " float3 dx_DepthFront : packoffset(c2);\n"; } if (mUsesFragCoord) { // dx_ViewScale is only used in the fragment shader to correct // the value for glFragCoord if necessary out << " float2 dx_ViewScale : packoffset(c3);\n"; } if (mHasMultiviewExtensionEnabled) { // We have to add a value which we can use to keep track of which multi-view code // path is to be selected in the GS. out << " float multiviewSelectViewportIndex : packoffset(c3.z);\n"; } if (mOutputType == SH_HLSL_4_1_OUTPUT) { mUniformHLSL->samplerMetadataUniforms(out, "c4"); } out << "};\n"; } else { if (mUsesDepthRange) { out << "uniform float3 dx_DepthRange : register(c0);"; } if (mUsesFragCoord) { out << "uniform float4 dx_ViewCoords : register(c1);\n"; } if (mUsesFragCoord || mUsesFrontFacing) { out << "uniform float3 dx_DepthFront : register(c2);\n"; } } out << "\n"; if (mUsesDepthRange) { out << "static gl_DepthRangeParameters gl_DepthRange = {dx_DepthRange.x, " "dx_DepthRange.y, dx_DepthRange.z};\n" "\n"; } if (!mappedStructs.empty()) { out << "// Structures from std140 blocks with padding removed\n"; out << "\n"; out << mappedStructs; out << "\n"; } if (usingMRTExtension && mNumRenderTargets > 1) { out << "#define GL_USES_MRT\n"; } if (mUsesFragColor) { out << "#define GL_USES_FRAG_COLOR\n"; } if (mUsesFragData) { out << "#define GL_USES_FRAG_DATA\n"; } } else if (mShaderType == GL_VERTEX_SHADER) { out << "// Attributes\n"; out << attributes; out << "\n" "static float4 gl_Position = float4(0, 0, 0, 0);\n"; if (mUsesPointSize) { out << "static float gl_PointSize = float(1);\n"; } if (mUsesInstanceID) { out << "static int gl_InstanceID;"; } if (mUsesVertexID) { out << "static int gl_VertexID;"; } out << "\n" "// Varyings\n"; out << varyings; out << "\n"; if (mUsesDepthRange) { out << "struct gl_DepthRangeParameters\n" "{\n" " float near;\n" " float far;\n" " float diff;\n" "};\n" "\n"; } if (mOutputType == SH_HLSL_4_1_OUTPUT || mOutputType == SH_HLSL_4_0_FL9_3_OUTPUT) { out << "cbuffer DriverConstants : register(b1)\n" "{\n"; if (mUsesDepthRange) { out << " float3 dx_DepthRange : packoffset(c0);\n"; } // dx_ViewAdjust and dx_ViewCoords will only be used in Feature Level 9 // shaders. However, we declare it for all shaders (including Feature Level 10+). // The bytecode is the same whether we declare it or not, since D3DCompiler removes it // if it's unused. out << " float4 dx_ViewAdjust : packoffset(c1);\n"; out << " float2 dx_ViewCoords : packoffset(c2);\n"; out << " float2 dx_ViewScale : packoffset(c3);\n"; if (mHasMultiviewExtensionEnabled) { // We have to add a value which we can use to keep track of which multi-view code // path is to be selected in the GS. out << " float multiviewSelectViewportIndex : packoffset(c3.z);\n"; } if (mOutputType == SH_HLSL_4_1_OUTPUT) { mUniformHLSL->samplerMetadataUniforms(out, "c4"); } out << "};\n" "\n"; } else { if (mUsesDepthRange) { out << "uniform float3 dx_DepthRange : register(c0);\n"; } out << "uniform float4 dx_ViewAdjust : register(c1);\n"; out << "uniform float2 dx_ViewCoords : register(c2);\n" "\n"; } if (mUsesDepthRange) { out << "static gl_DepthRangeParameters gl_DepthRange = {dx_DepthRange.x, " "dx_DepthRange.y, dx_DepthRange.z};\n" "\n"; } if (!mappedStructs.empty()) { out << "// Structures from std140 blocks with padding removed\n"; out << "\n"; out << mappedStructs; out << "\n"; } } else // Compute shader { ASSERT(mShaderType == GL_COMPUTE_SHADER); out << "cbuffer DriverConstants : register(b1)\n" "{\n"; if (mUsesNumWorkGroups) { out << " uint3 gl_NumWorkGroups : packoffset(c0);\n"; } ASSERT(mOutputType == SH_HLSL_4_1_OUTPUT); mUniformHLSL->samplerMetadataUniforms(out, "c1"); out << "};\n"; // Follow built-in variables would be initialized in // DynamicHLSL::generateComputeShaderLinkHLSL, if they // are used in compute shader. if (mUsesWorkGroupID) { out << "static uint3 gl_WorkGroupID = uint3(0, 0, 0);\n"; } if (mUsesLocalInvocationID) { out << "static uint3 gl_LocalInvocationID = uint3(0, 0, 0);\n"; } if (mUsesGlobalInvocationID) { out << "static uint3 gl_GlobalInvocationID = uint3(0, 0, 0);\n"; } if (mUsesLocalInvocationIndex) { out << "static uint gl_LocalInvocationIndex = uint(0);\n"; } } bool getDimensionsIgnoresBaseLevel = (mCompileOptions & SH_HLSL_GET_DIMENSIONS_IGNORES_BASE_LEVEL) != 0; mTextureFunctionHLSL->textureFunctionHeader(out, mOutputType, getDimensionsIgnoresBaseLevel); mImageFunctionHLSL->imageFunctionHeader(out); if (mUsesFragCoord) { out << "#define GL_USES_FRAG_COORD\n"; } if (mUsesPointCoord) { out << "#define GL_USES_POINT_COORD\n"; } if (mUsesFrontFacing) { out << "#define GL_USES_FRONT_FACING\n"; } if (mUsesPointSize) { out << "#define GL_USES_POINT_SIZE\n"; } if (mHasMultiviewExtensionEnabled) { out << "#define GL_ANGLE_MULTIVIEW_ENABLED\n"; } if (mUsesViewID) { out << "#define GL_USES_VIEW_ID\n"; } if (mUsesFragDepth) { out << "#define GL_USES_FRAG_DEPTH\n"; } if (mUsesDepthRange) { out << "#define GL_USES_DEPTH_RANGE\n"; } if (mUsesNumWorkGroups) { out << "#define GL_USES_NUM_WORK_GROUPS\n"; } if (mUsesWorkGroupID) { out << "#define GL_USES_WORK_GROUP_ID\n"; } if (mUsesLocalInvocationID) { out << "#define GL_USES_LOCAL_INVOCATION_ID\n"; } if (mUsesGlobalInvocationID) { out << "#define GL_USES_GLOBAL_INVOCATION_ID\n"; } if (mUsesLocalInvocationIndex) { out << "#define GL_USES_LOCAL_INVOCATION_INDEX\n"; } if (mUsesXor) { out << "bool xor(bool p, bool q)\n" "{\n" " return (p || q) && !(p && q);\n" "}\n" "\n"; } builtInFunctionEmulator->outputEmulatedFunctions(out); } void OutputHLSL::visitSymbol(TIntermSymbol *node) { TInfoSinkBase &out = getInfoSink(); // Handle accessing std140 structs by value if (IsInStd140InterfaceBlock(node) && node->getBasicType() == EbtStruct) { out << "map"; } TString name = node->getSymbol(); if (name == "gl_DepthRange") { mUsesDepthRange = true; out << name; } else { const TType &nodeType = node->getType(); TQualifier qualifier = node->getQualifier(); ensureStructDefined(nodeType); if (qualifier == EvqUniform) { const TInterfaceBlock *interfaceBlock = nodeType.getInterfaceBlock(); if (interfaceBlock) { mReferencedUniformBlocks[interfaceBlock->name()] = node; } else { mReferencedUniforms[name] = node; } out << DecorateVariableIfNeeded(node->getName()); } else if (qualifier == EvqAttribute || qualifier == EvqVertexIn) { mReferencedAttributes[name] = node; out << Decorate(name); } else if (IsVarying(qualifier)) { mReferencedVaryings[name] = node; out << Decorate(name); if (name == "ViewID_OVR") { mUsesViewID = true; } } else if (qualifier == EvqFragmentOut) { mReferencedOutputVariables[name] = node; out << "out_" << name; } else if (qualifier == EvqFragColor) { out << "gl_Color[0]"; mUsesFragColor = true; } else if (qualifier == EvqFragData) { out << "gl_Color"; mUsesFragData = true; } else if (qualifier == EvqFragCoord) { mUsesFragCoord = true; out << name; } else if (qualifier == EvqPointCoord) { mUsesPointCoord = true; out << name; } else if (qualifier == EvqFrontFacing) { mUsesFrontFacing = true; out << name; } else if (qualifier == EvqPointSize) { mUsesPointSize = true; out << name; } else if (qualifier == EvqInstanceID) { mUsesInstanceID = true; out << name; } else if (qualifier == EvqVertexID) { mUsesVertexID = true; out << name; } else if (name == "gl_FragDepthEXT" || name == "gl_FragDepth") { mUsesFragDepth = true; out << "gl_Depth"; } else if (qualifier == EvqNumWorkGroups) { mUsesNumWorkGroups = true; out << name; } else if (qualifier == EvqWorkGroupID) { mUsesWorkGroupID = true; out << name; } else if (qualifier == EvqLocalInvocationID) { mUsesLocalInvocationID = true; out << name; } else if (qualifier == EvqGlobalInvocationID) { mUsesGlobalInvocationID = true; out << name; } else if (qualifier == EvqLocalInvocationIndex) { mUsesLocalInvocationIndex = true; out << name; } else { out << DecorateVariableIfNeeded(node->getName()); } } } void OutputHLSL::visitRaw(TIntermRaw *node) { getInfoSink() << node->getRawText(); } void OutputHLSL::outputEqual(Visit visit, const TType &type, TOperator op, TInfoSinkBase &out) { if (type.isScalar() && !type.isArray()) { if (op == EOpEqual) { outputTriplet(out, visit, "(", " == ", ")"); } else { outputTriplet(out, visit, "(", " != ", ")"); } } else { if (visit == PreVisit && op == EOpNotEqual) { out << "!"; } if (type.isArray()) { const TString &functionName = addArrayEqualityFunction(type); outputTriplet(out, visit, (functionName + "(").c_str(), ", ", ")"); } else if (type.getBasicType() == EbtStruct) { const TStructure &structure = *type.getStruct(); const TString &functionName = addStructEqualityFunction(structure); outputTriplet(out, visit, (functionName + "(").c_str(), ", ", ")"); } else { ASSERT(type.isMatrix() || type.isVector()); outputTriplet(out, visit, "all(", " == ", ")"); } } } void OutputHLSL::outputAssign(Visit visit, const TType &type, TInfoSinkBase &out) { if (type.isArray()) { const TString &functionName = addArrayAssignmentFunction(type); outputTriplet(out, visit, (functionName + "(").c_str(), ", ", ")"); } else { outputTriplet(out, visit, "(", " = ", ")"); } } bool OutputHLSL::ancestorEvaluatesToSamplerInStruct() { for (unsigned int n = 0u; getAncestorNode(n) != nullptr; ++n) { TIntermNode *ancestor = getAncestorNode(n); const TIntermBinary *ancestorBinary = ancestor->getAsBinaryNode(); if (ancestorBinary == nullptr) { return false; } switch (ancestorBinary->getOp()) { case EOpIndexDirectStruct: { const TStructure *structure = ancestorBinary->getLeft()->getType().getStruct(); const TIntermConstantUnion *index = ancestorBinary->getRight()->getAsConstantUnion(); const TField *field = structure->fields()[index->getIConst(0)]; if (IsSampler(field->type()->getBasicType())) { return true; } break; } case EOpIndexDirect: break; default: // Returning a sampler from indirect indexing is not supported. return false; } } return false; } bool OutputHLSL::visitSwizzle(Visit visit, TIntermSwizzle *node) { TInfoSinkBase &out = getInfoSink(); if (visit == PostVisit) { out << "."; node->writeOffsetsAsXYZW(&out); } return true; } bool OutputHLSL::visitBinary(Visit visit, TIntermBinary *node) { TInfoSinkBase &out = getInfoSink(); switch (node->getOp()) { case EOpComma: outputTriplet(out, visit, "(", ", ", ")"); break; case EOpAssign: if (node->isArray()) { TIntermAggregate *rightAgg = node->getRight()->getAsAggregate(); if (rightAgg != nullptr && rightAgg->isConstructor()) { const TString &functionName = addArrayConstructIntoFunction(node->getType()); out << functionName << "("; node->getLeft()->traverse(this); TIntermSequence *seq = rightAgg->getSequence(); for (auto &arrayElement : *seq) { out << ", "; arrayElement->traverse(this); } out << ")"; return false; } // ArrayReturnValueToOutParameter should have eliminated expressions where a // function call is assigned. ASSERT(rightAgg == nullptr); } outputAssign(visit, node->getType(), out); break; case EOpInitialize: if (visit == PreVisit) { TIntermSymbol *symbolNode = node->getLeft()->getAsSymbolNode(); ASSERT(symbolNode); TIntermTyped *expression = node->getRight(); // Global initializers must be constant at this point. ASSERT(symbolNode->getQualifier() != EvqGlobal || canWriteAsHLSLLiteral(expression)); // GLSL allows to write things like "float x = x;" where a new variable x is defined // and the value of an existing variable x is assigned. HLSL uses C semantics (the // new variable is created before the assignment is evaluated), so we need to // convert // this to "float t = x, x = t;". if (writeSameSymbolInitializer(out, symbolNode, expression)) { // Skip initializing the rest of the expression return false; } else if (writeConstantInitialization(out, symbolNode, expression)) { return false; } } else if (visit == InVisit) { out << " = "; } break; case EOpAddAssign: outputTriplet(out, visit, "(", " += ", ")"); break; case EOpSubAssign: outputTriplet(out, visit, "(", " -= ", ")"); break; case EOpMulAssign: outputTriplet(out, visit, "(", " *= ", ")"); break; case EOpVectorTimesScalarAssign: outputTriplet(out, visit, "(", " *= ", ")"); break; case EOpMatrixTimesScalarAssign: outputTriplet(out, visit, "(", " *= ", ")"); break; case EOpVectorTimesMatrixAssign: if (visit == PreVisit) { out << "("; } else if (visit == InVisit) { out << " = mul("; node->getLeft()->traverse(this); out << ", transpose("; } else { out << ")))"; } break; case EOpMatrixTimesMatrixAssign: if (visit == PreVisit) { out << "("; } else if (visit == InVisit) { out << " = transpose(mul(transpose("; node->getLeft()->traverse(this); out << "), transpose("; } else { out << "))))"; } break; case EOpDivAssign: outputTriplet(out, visit, "(", " /= ", ")"); break; case EOpIModAssign: outputTriplet(out, visit, "(", " %= ", ")"); break; case EOpBitShiftLeftAssign: outputTriplet(out, visit, "(", " <<= ", ")"); break; case EOpBitShiftRightAssign: outputTriplet(out, visit, "(", " >>= ", ")"); break; case EOpBitwiseAndAssign: outputTriplet(out, visit, "(", " &= ", ")"); break; case EOpBitwiseXorAssign: outputTriplet(out, visit, "(", " ^= ", ")"); break; case EOpBitwiseOrAssign: outputTriplet(out, visit, "(", " |= ", ")"); break; case EOpIndexDirect: { const TType &leftType = node->getLeft()->getType(); if (leftType.isInterfaceBlock()) { if (visit == PreVisit) { TInterfaceBlock *interfaceBlock = leftType.getInterfaceBlock(); const int arrayIndex = node->getRight()->getAsConstantUnion()->getIConst(0); mReferencedUniformBlocks[interfaceBlock->instanceName()] = node->getLeft()->getAsSymbolNode(); out << mUniformHLSL->uniformBlockInstanceString(*interfaceBlock, arrayIndex); return false; } } else if (ancestorEvaluatesToSamplerInStruct()) { // All parts of an expression that access a sampler in a struct need to use _ as // separator to access the sampler variable that has been moved out of the struct. outputTriplet(out, visit, "", "_", ""); } else { outputTriplet(out, visit, "", "[", "]"); } } break; case EOpIndexIndirect: // We do not currently support indirect references to interface blocks ASSERT(node->getLeft()->getBasicType() != EbtInterfaceBlock); outputTriplet(out, visit, "", "[", "]"); break; case EOpIndexDirectStruct: { const TStructure *structure = node->getLeft()->getType().getStruct(); const TIntermConstantUnion *index = node->getRight()->getAsConstantUnion(); const TField *field = structure->fields()[index->getIConst(0)]; // In cases where indexing returns a sampler, we need to access the sampler variable // that has been moved out of the struct. bool indexingReturnsSampler = IsSampler(field->type()->getBasicType()); if (visit == PreVisit && indexingReturnsSampler) { // Samplers extracted from structs have "angle" prefix to avoid name conflicts. // This prefix is only output at the beginning of the indexing expression, which // may have multiple parts. out << "angle"; } if (!indexingReturnsSampler) { // All parts of an expression that access a sampler in a struct need to use _ as // separator to access the sampler variable that has been moved out of the struct. indexingReturnsSampler = ancestorEvaluatesToSamplerInStruct(); } if (visit == InVisit) { if (indexingReturnsSampler) { out << "_" + field->name(); } else { out << "." + DecorateField(field->name(), *structure); } return false; } } break; case EOpIndexDirectInterfaceBlock: { bool structInStd140Block = node->getBasicType() == EbtStruct && IsInStd140InterfaceBlock(node->getLeft()); if (visit == PreVisit && structInStd140Block) { out << "map"; } if (visit == InVisit) { const TInterfaceBlock *interfaceBlock = node->getLeft()->getType().getInterfaceBlock(); const TIntermConstantUnion *index = node->getRight()->getAsConstantUnion(); const TField *field = interfaceBlock->fields()[index->getIConst(0)]; if (structInStd140Block) { out << "_"; } else { out << "."; } out << Decorate(field->name()); return false; } break; } case EOpAdd: outputTriplet(out, visit, "(", " + ", ")"); break; case EOpSub: outputTriplet(out, visit, "(", " - ", ")"); break; case EOpMul: outputTriplet(out, visit, "(", " * ", ")"); break; case EOpDiv: outputTriplet(out, visit, "(", " / ", ")"); break; case EOpIMod: outputTriplet(out, visit, "(", " % ", ")"); break; case EOpBitShiftLeft: outputTriplet(out, visit, "(", " << ", ")"); break; case EOpBitShiftRight: outputTriplet(out, visit, "(", " >> ", ")"); break; case EOpBitwiseAnd: outputTriplet(out, visit, "(", " & ", ")"); break; case EOpBitwiseXor: outputTriplet(out, visit, "(", " ^ ", ")"); break; case EOpBitwiseOr: outputTriplet(out, visit, "(", " | ", ")"); break; case EOpEqual: case EOpNotEqual: outputEqual(visit, node->getLeft()->getType(), node->getOp(), out); break; case EOpLessThan: outputTriplet(out, visit, "(", " < ", ")"); break; case EOpGreaterThan: outputTriplet(out, visit, "(", " > ", ")"); break; case EOpLessThanEqual: outputTriplet(out, visit, "(", " <= ", ")"); break; case EOpGreaterThanEqual: outputTriplet(out, visit, "(", " >= ", ")"); break; case EOpVectorTimesScalar: outputTriplet(out, visit, "(", " * ", ")"); break; case EOpMatrixTimesScalar: outputTriplet(out, visit, "(", " * ", ")"); break; case EOpVectorTimesMatrix: outputTriplet(out, visit, "mul(", ", transpose(", "))"); break; case EOpMatrixTimesVector: outputTriplet(out, visit, "mul(transpose(", "), ", ")"); break; case EOpMatrixTimesMatrix: outputTriplet(out, visit, "transpose(mul(transpose(", "), transpose(", ")))"); break; case EOpLogicalOr: // HLSL doesn't short-circuit ||, so we assume that || affected by short-circuiting have // been unfolded. ASSERT(!node->getRight()->hasSideEffects()); outputTriplet(out, visit, "(", " || ", ")"); return true; case EOpLogicalXor: mUsesXor = true; outputTriplet(out, visit, "xor(", ", ", ")"); break; case EOpLogicalAnd: // HLSL doesn't short-circuit &&, so we assume that && affected by short-circuiting have // been unfolded. ASSERT(!node->getRight()->hasSideEffects()); outputTriplet(out, visit, "(", " && ", ")"); return true; default: UNREACHABLE(); } return true; } bool OutputHLSL::visitUnary(Visit visit, TIntermUnary *node) { TInfoSinkBase &out = getInfoSink(); switch (node->getOp()) { case EOpNegative: outputTriplet(out, visit, "(-", "", ")"); break; case EOpPositive: outputTriplet(out, visit, "(+", "", ")"); break; case EOpLogicalNot: outputTriplet(out, visit, "(!", "", ")"); break; case EOpBitwiseNot: outputTriplet(out, visit, "(~", "", ")"); break; case EOpPostIncrement: outputTriplet(out, visit, "(", "", "++)"); break; case EOpPostDecrement: outputTriplet(out, visit, "(", "", "--)"); break; case EOpPreIncrement: outputTriplet(out, visit, "(++", "", ")"); break; case EOpPreDecrement: outputTriplet(out, visit, "(--", "", ")"); break; case EOpRadians: outputTriplet(out, visit, "radians(", "", ")"); break; case EOpDegrees: outputTriplet(out, visit, "degrees(", "", ")"); break; case EOpSin: outputTriplet(out, visit, "sin(", "", ")"); break; case EOpCos: outputTriplet(out, visit, "cos(", "", ")"); break; case EOpTan: outputTriplet(out, visit, "tan(", "", ")"); break; case EOpAsin: outputTriplet(out, visit, "asin(", "", ")"); break; case EOpAcos: outputTriplet(out, visit, "acos(", "", ")"); break; case EOpAtan: outputTriplet(out, visit, "atan(", "", ")"); break; case EOpSinh: outputTriplet(out, visit, "sinh(", "", ")"); break; case EOpCosh: outputTriplet(out, visit, "cosh(", "", ")"); break; case EOpTanh: outputTriplet(out, visit, "tanh(", "", ")"); break; case EOpAsinh: case EOpAcosh: case EOpAtanh: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpExp: outputTriplet(out, visit, "exp(", "", ")"); break; case EOpLog: outputTriplet(out, visit, "log(", "", ")"); break; case EOpExp2: outputTriplet(out, visit, "exp2(", "", ")"); break; case EOpLog2: outputTriplet(out, visit, "log2(", "", ")"); break; case EOpSqrt: outputTriplet(out, visit, "sqrt(", "", ")"); break; case EOpInverseSqrt: outputTriplet(out, visit, "rsqrt(", "", ")"); break; case EOpAbs: outputTriplet(out, visit, "abs(", "", ")"); break; case EOpSign: outputTriplet(out, visit, "sign(", "", ")"); break; case EOpFloor: outputTriplet(out, visit, "floor(", "", ")"); break; case EOpTrunc: outputTriplet(out, visit, "trunc(", "", ")"); break; case EOpRound: outputTriplet(out, visit, "round(", "", ")"); break; case EOpRoundEven: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpCeil: outputTriplet(out, visit, "ceil(", "", ")"); break; case EOpFract: outputTriplet(out, visit, "frac(", "", ")"); break; case EOpIsNan: if (node->getUseEmulatedFunction()) writeEmulatedFunctionTriplet(out, visit, node->getOp()); else outputTriplet(out, visit, "isnan(", "", ")"); mRequiresIEEEStrictCompiling = true; break; case EOpIsInf: outputTriplet(out, visit, "isinf(", "", ")"); break; case EOpFloatBitsToInt: outputTriplet(out, visit, "asint(", "", ")"); break; case EOpFloatBitsToUint: outputTriplet(out, visit, "asuint(", "", ")"); break; case EOpIntBitsToFloat: outputTriplet(out, visit, "asfloat(", "", ")"); break; case EOpUintBitsToFloat: outputTriplet(out, visit, "asfloat(", "", ")"); break; case EOpPackSnorm2x16: case EOpPackUnorm2x16: case EOpPackHalf2x16: case EOpUnpackSnorm2x16: case EOpUnpackUnorm2x16: case EOpUnpackHalf2x16: case EOpPackUnorm4x8: case EOpPackSnorm4x8: case EOpUnpackUnorm4x8: case EOpUnpackSnorm4x8: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpLength: outputTriplet(out, visit, "length(", "", ")"); break; case EOpNormalize: outputTriplet(out, visit, "normalize(", "", ")"); break; case EOpDFdx: if (mInsideDiscontinuousLoop || mOutputLod0Function) { outputTriplet(out, visit, "(", "", ", 0.0)"); } else { outputTriplet(out, visit, "ddx(", "", ")"); } break; case EOpDFdy: if (mInsideDiscontinuousLoop || mOutputLod0Function) { outputTriplet(out, visit, "(", "", ", 0.0)"); } else { outputTriplet(out, visit, "ddy(", "", ")"); } break; case EOpFwidth: if (mInsideDiscontinuousLoop || mOutputLod0Function) { outputTriplet(out, visit, "(", "", ", 0.0)"); } else { outputTriplet(out, visit, "fwidth(", "", ")"); } break; case EOpTranspose: outputTriplet(out, visit, "transpose(", "", ")"); break; case EOpDeterminant: outputTriplet(out, visit, "determinant(transpose(", "", "))"); break; case EOpInverse: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpAny: outputTriplet(out, visit, "any(", "", ")"); break; case EOpAll: outputTriplet(out, visit, "all(", "", ")"); break; case EOpLogicalNotComponentWise: outputTriplet(out, visit, "(!", "", ")"); break; case EOpBitfieldReverse: outputTriplet(out, visit, "reversebits(", "", ")"); break; case EOpBitCount: outputTriplet(out, visit, "countbits(", "", ")"); break; case EOpFindLSB: // Note that it's unclear from the HLSL docs what this returns for 0, but this is tested // in GLSLTest and results are consistent with GL. outputTriplet(out, visit, "firstbitlow(", "", ")"); break; case EOpFindMSB: // Note that it's unclear from the HLSL docs what this returns for 0 or -1, but this is // tested in GLSLTest and results are consistent with GL. outputTriplet(out, visit, "firstbithigh(", "", ")"); break; default: UNREACHABLE(); } return true; } TString OutputHLSL::samplerNamePrefixFromStruct(TIntermTyped *node) { if (node->getAsSymbolNode()) { return node->getAsSymbolNode()->getSymbol(); } TIntermBinary *nodeBinary = node->getAsBinaryNode(); switch (nodeBinary->getOp()) { case EOpIndexDirect: { int index = nodeBinary->getRight()->getAsConstantUnion()->getIConst(0); TInfoSinkBase prefixSink; prefixSink << samplerNamePrefixFromStruct(nodeBinary->getLeft()) << "_" << index; return TString(prefixSink.c_str()); } case EOpIndexDirectStruct: { const TStructure *s = nodeBinary->getLeft()->getAsTyped()->getType().getStruct(); int index = nodeBinary->getRight()->getAsConstantUnion()->getIConst(0); const TField *field = s->fields()[index]; TInfoSinkBase prefixSink; prefixSink << samplerNamePrefixFromStruct(nodeBinary->getLeft()) << "_" << field->name(); return TString(prefixSink.c_str()); } default: UNREACHABLE(); return TString(""); } } bool OutputHLSL::visitBlock(Visit visit, TIntermBlock *node) { TInfoSinkBase &out = getInfoSink(); if (mInsideFunction) { outputLineDirective(out, node->getLine().first_line); out << "{\n"; } for (TIntermNode *statement : *node->getSequence()) { outputLineDirective(out, statement->getLine().first_line); statement->traverse(this); // Don't output ; after case labels, they're terminated by : // This is needed especially since outputting a ; after a case statement would turn empty // case statements into non-empty case statements, disallowing fall-through from them. // Also the output code is clearer if we don't output ; after statements where it is not // needed: // * if statements // * switch statements // * blocks // * function definitions // * loops (do-while loops output the semicolon in VisitLoop) // * declarations that don't generate output. if (statement->getAsCaseNode() == nullptr && statement->getAsIfElseNode() == nullptr && statement->getAsBlock() == nullptr && statement->getAsLoopNode() == nullptr && statement->getAsSwitchNode() == nullptr && statement->getAsFunctionDefinition() == nullptr && (statement->getAsDeclarationNode() == nullptr || IsDeclarationWrittenOut(statement->getAsDeclarationNode())) && statement->getAsInvariantDeclarationNode() == nullptr) { out << ";\n"; } } if (mInsideFunction) { outputLineDirective(out, node->getLine().last_line); out << "}\n"; } return false; } bool OutputHLSL::visitFunctionDefinition(Visit visit, TIntermFunctionDefinition *node) { TInfoSinkBase &out = getInfoSink(); ASSERT(mCurrentFunctionMetadata == nullptr); size_t index = mCallDag.findIndex(node->getFunctionSymbolInfo()); ASSERT(index != CallDAG::InvalidIndex); mCurrentFunctionMetadata = &mASTMetadataList[index]; out << TypeString(node->getFunctionPrototype()->getType()) << " "; TIntermSequence *parameters = node->getFunctionPrototype()->getSequence(); if (node->getFunctionSymbolInfo()->isMain()) { out << "gl_main("; } else { out << DecorateFunctionIfNeeded(node->getFunctionSymbolInfo()->getNameObj()) << DisambiguateFunctionName(parameters) << (mOutputLod0Function ? "Lod0(" : "("); } for (unsigned int i = 0; i < parameters->size(); i++) { TIntermSymbol *symbol = (*parameters)[i]->getAsSymbolNode(); if (symbol) { ensureStructDefined(symbol->getType()); out << argumentString(symbol); if (i < parameters->size() - 1) { out << ", "; } } else UNREACHABLE(); } out << ")\n"; mInsideFunction = true; // The function body node will output braces. node->getBody()->traverse(this); mInsideFunction = false; mCurrentFunctionMetadata = nullptr; bool needsLod0 = mASTMetadataList[index].mNeedsLod0; if (needsLod0 && !mOutputLod0Function && mShaderType == GL_FRAGMENT_SHADER) { ASSERT(!node->getFunctionSymbolInfo()->isMain()); mOutputLod0Function = true; node->traverse(this); mOutputLod0Function = false; } return false; } bool OutputHLSL::visitDeclaration(Visit visit, TIntermDeclaration *node) { if (visit == PreVisit) { TIntermSequence *sequence = node->getSequence(); TIntermTyped *variable = (*sequence)[0]->getAsTyped(); ASSERT(sequence->size() == 1); ASSERT(variable); if (IsDeclarationWrittenOut(node)) { TInfoSinkBase &out = getInfoSink(); ensureStructDefined(variable->getType()); if (!variable->getAsSymbolNode() || variable->getAsSymbolNode()->getSymbol() != "") // Variable declaration { if (!mInsideFunction) { out << "static "; } out << TypeString(variable->getType()) + " "; TIntermSymbol *symbol = variable->getAsSymbolNode(); if (symbol) { symbol->traverse(this); out << ArrayString(symbol->getType()); out << " = " + initializer(symbol->getType()); } else { variable->traverse(this); } } else if (variable->getAsSymbolNode() && variable->getAsSymbolNode()->getSymbol() == "") // Type (struct) declaration { ASSERT(variable->getBasicType() == EbtStruct); // ensureStructDefined has already been called. } else UNREACHABLE(); } else if (IsVaryingOut(variable->getQualifier())) { TIntermSymbol *symbol = variable->getAsSymbolNode(); ASSERT(symbol); // Varying declarations can't have initializers. // Vertex outputs which are declared but not written to should still be declared to // allow successful linking. mReferencedVaryings[symbol->getSymbol()] = symbol; } } return false; } bool OutputHLSL::visitInvariantDeclaration(Visit visit, TIntermInvariantDeclaration *node) { // Do not do any translation return false; } bool OutputHLSL::visitFunctionPrototype(Visit visit, TIntermFunctionPrototype *node) { TInfoSinkBase &out = getInfoSink(); ASSERT(visit == PreVisit); size_t index = mCallDag.findIndex(node->getFunctionSymbolInfo()); // Skip the prototype if it is not implemented (and thus not used) if (index == CallDAG::InvalidIndex) { return false; } TIntermSequence *arguments = node->getSequence(); TString name = DecorateFunctionIfNeeded(node->getFunctionSymbolInfo()->getNameObj()); out << TypeString(node->getType()) << " " << name << DisambiguateFunctionName(arguments) << (mOutputLod0Function ? "Lod0(" : "("); for (unsigned int i = 0; i < arguments->size(); i++) { TIntermSymbol *symbol = (*arguments)[i]->getAsSymbolNode(); ASSERT(symbol != nullptr); out << argumentString(symbol); if (i < arguments->size() - 1) { out << ", "; } } out << ");\n"; // Also prototype the Lod0 variant if needed bool needsLod0 = mASTMetadataList[index].mNeedsLod0; if (needsLod0 && !mOutputLod0Function && mShaderType == GL_FRAGMENT_SHADER) { mOutputLod0Function = true; node->traverse(this); mOutputLod0Function = false; } return false; } bool OutputHLSL::visitAggregate(Visit visit, TIntermAggregate *node) { TInfoSinkBase &out = getInfoSink(); switch (node->getOp()) { case EOpCallBuiltInFunction: case EOpCallFunctionInAST: case EOpCallInternalRawFunction: { TIntermSequence *arguments = node->getSequence(); bool lod0 = mInsideDiscontinuousLoop || mOutputLod0Function; if (node->getOp() == EOpCallFunctionInAST) { if (node->isArray()) { UNIMPLEMENTED(); } size_t index = mCallDag.findIndex(node->getFunctionSymbolInfo()); ASSERT(index != CallDAG::InvalidIndex); lod0 &= mASTMetadataList[index].mNeedsLod0; out << DecorateFunctionIfNeeded(node->getFunctionSymbolInfo()->getNameObj()); out << DisambiguateFunctionName(node->getSequence()); out << (lod0 ? "Lod0(" : "("); } else if (node->getOp() == EOpCallInternalRawFunction) { // This path is used for internal functions that don't have their definitions in the // AST, such as precision emulation functions. out << DecorateFunctionIfNeeded(node->getFunctionSymbolInfo()->getNameObj()) << "("; } else if (node->getFunctionSymbolInfo()->isImageFunction()) { TString name = node->getFunctionSymbolInfo()->getName(); TType type = (*arguments)[0]->getAsTyped()->getType(); TString imageFunctionName = mImageFunctionHLSL->useImageFunction( name, type.getBasicType(), type.getLayoutQualifier().imageInternalFormat, type.getMemoryQualifier().readonly); out << imageFunctionName << "("; } else { const TString &name = node->getFunctionSymbolInfo()->getName(); TBasicType samplerType = (*arguments)[0]->getAsTyped()->getType().getBasicType(); int coords = 0; // textureSize(gsampler2DMS) doesn't have a second argument. if (arguments->size() > 1) { coords = (*arguments)[1]->getAsTyped()->getNominalSize(); } TString textureFunctionName = mTextureFunctionHLSL->useTextureFunction( name, samplerType, coords, arguments->size(), lod0, mShaderType); out << textureFunctionName << "("; } for (TIntermSequence::iterator arg = arguments->begin(); arg != arguments->end(); arg++) { TIntermTyped *typedArg = (*arg)->getAsTyped(); if (mOutputType == SH_HLSL_4_0_FL9_3_OUTPUT && IsSampler(typedArg->getBasicType())) { out << "texture_"; (*arg)->traverse(this); out << ", sampler_"; } (*arg)->traverse(this); if (typedArg->getType().isStructureContainingSamplers()) { const TType &argType = typedArg->getType(); TVector samplerSymbols; TString structName = samplerNamePrefixFromStruct(typedArg); argType.createSamplerSymbols("angle_" + structName, "", &samplerSymbols, nullptr, mSymbolTable); for (const TIntermSymbol *sampler : samplerSymbols) { if (mOutputType == SH_HLSL_4_0_FL9_3_OUTPUT) { out << ", texture_" << sampler->getSymbol(); out << ", sampler_" << sampler->getSymbol(); } else { // In case of HLSL 4.1+, this symbol is the sampler index, and in case // of D3D9, it's the sampler variable. out << ", " + sampler->getSymbol(); } } } if (arg < arguments->end() - 1) { out << ", "; } } out << ")"; return false; } case EOpConstruct: outputConstructor(out, visit, node); break; case EOpEqualComponentWise: outputTriplet(out, visit, "(", " == ", ")"); break; case EOpNotEqualComponentWise: outputTriplet(out, visit, "(", " != ", ")"); break; case EOpLessThanComponentWise: outputTriplet(out, visit, "(", " < ", ")"); break; case EOpGreaterThanComponentWise: outputTriplet(out, visit, "(", " > ", ")"); break; case EOpLessThanEqualComponentWise: outputTriplet(out, visit, "(", " <= ", ")"); break; case EOpGreaterThanEqualComponentWise: outputTriplet(out, visit, "(", " >= ", ")"); break; case EOpMod: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpModf: outputTriplet(out, visit, "modf(", ", ", ")"); break; case EOpPow: outputTriplet(out, visit, "pow(", ", ", ")"); break; case EOpAtan: ASSERT(node->getSequence()->size() == 2); // atan(x) is a unary operator ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpMin: outputTriplet(out, visit, "min(", ", ", ")"); break; case EOpMax: outputTriplet(out, visit, "max(", ", ", ")"); break; case EOpClamp: outputTriplet(out, visit, "clamp(", ", ", ")"); break; case EOpMix: { TIntermTyped *lastParamNode = (*(node->getSequence()))[2]->getAsTyped(); if (lastParamNode->getType().getBasicType() == EbtBool) { // There is no HLSL equivalent for ESSL3 built-in "genType mix (genType x, genType // y, genBType a)", // so use emulated version. ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); } else { outputTriplet(out, visit, "lerp(", ", ", ")"); } break; } case EOpStep: outputTriplet(out, visit, "step(", ", ", ")"); break; case EOpSmoothStep: outputTriplet(out, visit, "smoothstep(", ", ", ")"); break; case EOpFrexp: case EOpLdexp: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpDistance: outputTriplet(out, visit, "distance(", ", ", ")"); break; case EOpDot: outputTriplet(out, visit, "dot(", ", ", ")"); break; case EOpCross: outputTriplet(out, visit, "cross(", ", ", ")"); break; case EOpFaceforward: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpReflect: outputTriplet(out, visit, "reflect(", ", ", ")"); break; case EOpRefract: outputTriplet(out, visit, "refract(", ", ", ")"); break; case EOpOuterProduct: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; case EOpMulMatrixComponentWise: outputTriplet(out, visit, "(", " * ", ")"); break; case EOpBitfieldExtract: case EOpBitfieldInsert: case EOpUaddCarry: case EOpUsubBorrow: case EOpUmulExtended: case EOpImulExtended: ASSERT(node->getUseEmulatedFunction()); writeEmulatedFunctionTriplet(out, visit, node->getOp()); break; default: UNREACHABLE(); } return true; } void OutputHLSL::writeIfElse(TInfoSinkBase &out, TIntermIfElse *node) { out << "if ("; node->getCondition()->traverse(this); out << ")\n"; outputLineDirective(out, node->getLine().first_line); bool discard = false; if (node->getTrueBlock()) { // The trueBlock child node will output braces. node->getTrueBlock()->traverse(this); // Detect true discard discard = (discard || FindDiscard::search(node->getTrueBlock())); } else { // TODO(oetuaho): Check if the semicolon inside is necessary. // It's there as a result of conservative refactoring of the output. out << "{;}\n"; } outputLineDirective(out, node->getLine().first_line); if (node->getFalseBlock()) { out << "else\n"; outputLineDirective(out, node->getFalseBlock()->getLine().first_line); // The falseBlock child node will output braces. node->getFalseBlock()->traverse(this); outputLineDirective(out, node->getFalseBlock()->getLine().first_line); // Detect false discard discard = (discard || FindDiscard::search(node->getFalseBlock())); } // ANGLE issue 486: Detect problematic conditional discard if (discard) { mUsesDiscardRewriting = true; } } bool OutputHLSL::visitTernary(Visit, TIntermTernary *) { // Ternary ops should have been already converted to something else in the AST. HLSL ternary // operator doesn't short-circuit, so it's not the same as the GLSL ternary operator. UNREACHABLE(); return false; } bool OutputHLSL::visitIfElse(Visit visit, TIntermIfElse *node) { TInfoSinkBase &out = getInfoSink(); ASSERT(mInsideFunction); // D3D errors when there is a gradient operation in a loop in an unflattened if. if (mShaderType == GL_FRAGMENT_SHADER && mCurrentFunctionMetadata->hasGradientLoop(node)) { out << "FLATTEN "; } writeIfElse(out, node); return false; } bool OutputHLSL::visitSwitch(Visit visit, TIntermSwitch *node) { TInfoSinkBase &out = getInfoSink(); ASSERT(node->getStatementList()); if (visit == PreVisit) { node->setStatementList(RemoveSwitchFallThrough(node->getStatementList(), mPerfDiagnostics)); } outputTriplet(out, visit, "switch (", ") ", ""); // The curly braces get written when visiting the statementList block. return true; } bool OutputHLSL::visitCase(Visit visit, TIntermCase *node) { TInfoSinkBase &out = getInfoSink(); if (node->hasCondition()) { outputTriplet(out, visit, "case (", "", "):\n"); return true; } else { out << "default:\n"; return false; } } void OutputHLSL::visitConstantUnion(TIntermConstantUnion *node) { TInfoSinkBase &out = getInfoSink(); writeConstantUnion(out, node->getType(), node->getUnionArrayPointer()); } bool OutputHLSL::visitLoop(Visit visit, TIntermLoop *node) { mNestedLoopDepth++; bool wasDiscontinuous = mInsideDiscontinuousLoop; mInsideDiscontinuousLoop = mInsideDiscontinuousLoop || mCurrentFunctionMetadata->mDiscontinuousLoops.count(node) > 0; TInfoSinkBase &out = getInfoSink(); if (mOutputType == SH_HLSL_3_0_OUTPUT) { if (handleExcessiveLoop(out, node)) { mInsideDiscontinuousLoop = wasDiscontinuous; mNestedLoopDepth--; return false; } } const char *unroll = mCurrentFunctionMetadata->hasGradientInCallGraph(node) ? "LOOP" : ""; if (node->getType() == ELoopDoWhile) { out << "{" << unroll << " do\n"; outputLineDirective(out, node->getLine().first_line); } else { out << "{" << unroll << " for("; if (node->getInit()) { node->getInit()->traverse(this); } out << "; "; if (node->getCondition()) { node->getCondition()->traverse(this); } out << "; "; if (node->getExpression()) { node->getExpression()->traverse(this); } out << ")\n"; outputLineDirective(out, node->getLine().first_line); } if (node->getBody()) { // The loop body node will output braces. node->getBody()->traverse(this); } else { // TODO(oetuaho): Check if the semicolon inside is necessary. // It's there as a result of conservative refactoring of the output. out << "{;}\n"; } outputLineDirective(out, node->getLine().first_line); if (node->getType() == ELoopDoWhile) { outputLineDirective(out, node->getCondition()->getLine().first_line); out << "while ("; node->getCondition()->traverse(this); out << ");\n"; } out << "}\n"; mInsideDiscontinuousLoop = wasDiscontinuous; mNestedLoopDepth--; return false; } bool OutputHLSL::visitBranch(Visit visit, TIntermBranch *node) { if (visit == PreVisit) { TInfoSinkBase &out = getInfoSink(); switch (node->getFlowOp()) { case EOpKill: out << "discard"; break; case EOpBreak: if (mNestedLoopDepth > 1) { mUsesNestedBreak = true; } if (mExcessiveLoopIndex) { out << "{Break"; mExcessiveLoopIndex->traverse(this); out << " = true; break;}\n"; } else { out << "break"; } break; case EOpContinue: out << "continue"; break; case EOpReturn: if (node->getExpression()) { out << "return "; } else { out << "return"; } break; default: UNREACHABLE(); } } return true; } // Handle loops with more than 254 iterations (unsupported by D3D9) by splitting them // (The D3D documentation says 255 iterations, but the compiler complains at anything more than // 254). bool OutputHLSL::handleExcessiveLoop(TInfoSinkBase &out, TIntermLoop *node) { const int MAX_LOOP_ITERATIONS = 254; // Parse loops of the form: // for(int index = initial; index [comparator] limit; index += increment) TIntermSymbol *index = nullptr; TOperator comparator = EOpNull; int initial = 0; int limit = 0; int increment = 0; // Parse index name and intial value if (node->getInit()) { TIntermDeclaration *init = node->getInit()->getAsDeclarationNode(); if (init) { TIntermSequence *sequence = init->getSequence(); TIntermTyped *variable = (*sequence)[0]->getAsTyped(); if (variable && variable->getQualifier() == EvqTemporary) { TIntermBinary *assign = variable->getAsBinaryNode(); if (assign->getOp() == EOpInitialize) { TIntermSymbol *symbol = assign->getLeft()->getAsSymbolNode(); TIntermConstantUnion *constant = assign->getRight()->getAsConstantUnion(); if (symbol && constant) { if (constant->getBasicType() == EbtInt && constant->isScalar()) { index = symbol; initial = constant->getIConst(0); } } } } } } // Parse comparator and limit value if (index != nullptr && node->getCondition()) { TIntermBinary *test = node->getCondition()->getAsBinaryNode(); if (test && test->getLeft()->getAsSymbolNode()->getId() == index->getId()) { TIntermConstantUnion *constant = test->getRight()->getAsConstantUnion(); if (constant) { if (constant->getBasicType() == EbtInt && constant->isScalar()) { comparator = test->getOp(); limit = constant->getIConst(0); } } } } // Parse increment if (index != nullptr && comparator != EOpNull && node->getExpression()) { TIntermBinary *binaryTerminal = node->getExpression()->getAsBinaryNode(); TIntermUnary *unaryTerminal = node->getExpression()->getAsUnaryNode(); if (binaryTerminal) { TOperator op = binaryTerminal->getOp(); TIntermConstantUnion *constant = binaryTerminal->getRight()->getAsConstantUnion(); if (constant) { if (constant->getBasicType() == EbtInt && constant->isScalar()) { int value = constant->getIConst(0); switch (op) { case EOpAddAssign: increment = value; break; case EOpSubAssign: increment = -value; break; default: UNIMPLEMENTED(); } } } } else if (unaryTerminal) { TOperator op = unaryTerminal->getOp(); switch (op) { case EOpPostIncrement: increment = 1; break; case EOpPostDecrement: increment = -1; break; case EOpPreIncrement: increment = 1; break; case EOpPreDecrement: increment = -1; break; default: UNIMPLEMENTED(); } } } if (index != nullptr && comparator != EOpNull && increment != 0) { if (comparator == EOpLessThanEqual) { comparator = EOpLessThan; limit += 1; } if (comparator == EOpLessThan) { int iterations = (limit - initial) / increment; if (iterations <= MAX_LOOP_ITERATIONS) { return false; // Not an excessive loop } TIntermSymbol *restoreIndex = mExcessiveLoopIndex; mExcessiveLoopIndex = index; out << "{int "; index->traverse(this); out << ";\n" "bool Break"; index->traverse(this); out << " = false;\n"; bool firstLoopFragment = true; while (iterations > 0) { int clampedLimit = initial + increment * std::min(MAX_LOOP_ITERATIONS, iterations); if (!firstLoopFragment) { out << "if (!Break"; index->traverse(this); out << ") {\n"; } if (iterations <= MAX_LOOP_ITERATIONS) // Last loop fragment { mExcessiveLoopIndex = nullptr; // Stops setting the Break flag } // for(int index = initial; index < clampedLimit; index += increment) const char *unroll = mCurrentFunctionMetadata->hasGradientInCallGraph(node) ? "LOOP" : ""; out << unroll << " for("; index->traverse(this); out << " = "; out << initial; out << "; "; index->traverse(this); out << " < "; out << clampedLimit; out << "; "; index->traverse(this); out << " += "; out << increment; out << ")\n"; outputLineDirective(out, node->getLine().first_line); out << "{\n"; if (node->getBody()) { node->getBody()->traverse(this); } outputLineDirective(out, node->getLine().first_line); out << ";}\n"; if (!firstLoopFragment) { out << "}\n"; } firstLoopFragment = false; initial += MAX_LOOP_ITERATIONS * increment; iterations -= MAX_LOOP_ITERATIONS; } out << "}"; mExcessiveLoopIndex = restoreIndex; return true; } else UNIMPLEMENTED(); } return false; // Not handled as an excessive loop } void OutputHLSL::outputTriplet(TInfoSinkBase &out, Visit visit, const char *preString, const char *inString, const char *postString) { if (visit == PreVisit) { out << preString; } else if (visit == InVisit) { out << inString; } else if (visit == PostVisit) { out << postString; } } void OutputHLSL::outputLineDirective(TInfoSinkBase &out, int line) { if ((mCompileOptions & SH_LINE_DIRECTIVES) && (line > 0)) { out << "\n"; out << "#line " << line; if (mSourcePath) { out << " \"" << mSourcePath << "\""; } out << "\n"; } } TString OutputHLSL::argumentString(const TIntermSymbol *symbol) { TQualifier qualifier = symbol->getQualifier(); const TType &type = symbol->getType(); const TName &name = symbol->getName(); TString nameStr; if (name.getString().empty()) // HLSL demands named arguments, also for prototypes { nameStr = "x" + str(mUniqueIndex++); } else { nameStr = DecorateVariableIfNeeded(name); } if (IsSampler(type.getBasicType())) { if (mOutputType == SH_HLSL_4_1_OUTPUT) { // Samplers are passed as indices to the sampler array. ASSERT(qualifier != EvqOut && qualifier != EvqInOut); return "const uint " + nameStr + ArrayString(type); } if (mOutputType == SH_HLSL_4_0_FL9_3_OUTPUT) { return QualifierString(qualifier) + " " + TextureString(type.getBasicType()) + " texture_" + nameStr + ArrayString(type) + ", " + QualifierString(qualifier) + " " + SamplerString(type.getBasicType()) + " sampler_" + nameStr + ArrayString(type); } } TStringStream argString; argString << QualifierString(qualifier) << " " << TypeString(type) << " " << nameStr << ArrayString(type); // If the structure parameter contains samplers, they need to be passed into the function as // separate parameters. HLSL doesn't natively support samplers in structs. if (type.isStructureContainingSamplers()) { ASSERT(qualifier != EvqOut && qualifier != EvqInOut); TVector samplerSymbols; type.createSamplerSymbols("angle" + nameStr, "", &samplerSymbols, nullptr, mSymbolTable); for (const TIntermSymbol *sampler : samplerSymbols) { const TType &samplerType = sampler->getType(); if (mOutputType == SH_HLSL_4_1_OUTPUT) { argString << ", const uint " << sampler->getSymbol() << ArrayString(samplerType); } else if (mOutputType == SH_HLSL_4_0_FL9_3_OUTPUT) { ASSERT(IsSampler(samplerType.getBasicType())); argString << ", " << QualifierString(qualifier) << " " << TextureString(samplerType.getBasicType()) << " texture_" << sampler->getSymbol() << ArrayString(samplerType) << ", " << QualifierString(qualifier) << " " << SamplerString(samplerType.getBasicType()) << " sampler_" << sampler->getSymbol() << ArrayString(samplerType); } else { ASSERT(IsSampler(samplerType.getBasicType())); argString << ", " << QualifierString(qualifier) << " " << TypeString(samplerType) << " " << sampler->getSymbol() << ArrayString(samplerType); } } } return argString.str(); } TString OutputHLSL::initializer(const TType &type) { TString string; size_t size = type.getObjectSize(); for (size_t component = 0; component < size; component++) { string += "0"; if (component + 1 < size) { string += ", "; } } return "{" + string + "}"; } void OutputHLSL::outputConstructor(TInfoSinkBase &out, Visit visit, TIntermAggregate *node) { // Array constructors should have been already pruned from the code. ASSERT(!node->getType().isArray()); if (visit == PreVisit) { TString constructorName; if (node->getBasicType() == EbtStruct) { constructorName = mStructureHLSL->addStructConstructor(*node->getType().getStruct()); } else { constructorName = mStructureHLSL->addBuiltInConstructor(node->getType(), node->getSequence()); } out << constructorName << "("; } else if (visit == InVisit) { out << ", "; } else if (visit == PostVisit) { out << ")"; } } const TConstantUnion *OutputHLSL::writeConstantUnion(TInfoSinkBase &out, const TType &type, const TConstantUnion *const constUnion) { const TConstantUnion *constUnionIterated = constUnion; const TStructure *structure = type.getStruct(); if (structure) { out << mStructureHLSL->addStructConstructor(*structure) << "("; const TFieldList &fields = structure->fields(); for (size_t i = 0; i < fields.size(); i++) { const TType *fieldType = fields[i]->type(); constUnionIterated = writeConstantUnion(out, *fieldType, constUnionIterated); if (i != fields.size() - 1) { out << ", "; } } out << ")"; } else { size_t size = type.getObjectSize(); bool writeType = size > 1; if (writeType) { out << TypeString(type) << "("; } constUnionIterated = writeConstantUnionArray(out, constUnionIterated, size); if (writeType) { out << ")"; } } return constUnionIterated; } void OutputHLSL::writeEmulatedFunctionTriplet(TInfoSinkBase &out, Visit visit, TOperator op) { if (visit == PreVisit) { const char *opStr = GetOperatorString(op); BuiltInFunctionEmulator::WriteEmulatedFunctionName(out, opStr); out << "("; } else { outputTriplet(out, visit, nullptr, ", ", ")"); } } bool OutputHLSL::writeSameSymbolInitializer(TInfoSinkBase &out, TIntermSymbol *symbolNode, TIntermTyped *expression) { sh::SearchSymbol searchSymbol(symbolNode->getSymbol()); expression->traverse(&searchSymbol); if (searchSymbol.foundMatch()) { // Type already printed out << "t" + str(mUniqueIndex) + " = "; expression->traverse(this); out << ", "; symbolNode->traverse(this); out << " = t" + str(mUniqueIndex); mUniqueIndex++; return true; } return false; } bool OutputHLSL::canWriteAsHLSLLiteral(TIntermTyped *expression) { // We support writing constant unions and constructors that only take constant unions as // parameters as HLSL literals. return !expression->getType().isArrayOfArrays() && (expression->getAsConstantUnion() || expression->isConstructorWithOnlyConstantUnionParameters()); } bool OutputHLSL::writeConstantInitialization(TInfoSinkBase &out, TIntermSymbol *symbolNode, TIntermTyped *initializer) { if (canWriteAsHLSLLiteral(initializer)) { symbolNode->traverse(this); ASSERT(!symbolNode->getType().isArrayOfArrays()); if (symbolNode->getType().isArray()) { out << "[" << symbolNode->getType().getOutermostArraySize() << "]"; } out << " = {"; if (initializer->getAsConstantUnion()) { TIntermConstantUnion *nodeConst = initializer->getAsConstantUnion(); const TConstantUnion *constUnion = nodeConst->getUnionArrayPointer(); writeConstantUnionArray(out, constUnion, nodeConst->getType().getObjectSize()); } else { TIntermAggregate *constructor = initializer->getAsAggregate(); ASSERT(constructor != nullptr); for (TIntermNode *&node : *constructor->getSequence()) { TIntermConstantUnion *nodeConst = node->getAsConstantUnion(); ASSERT(nodeConst); const TConstantUnion *constUnion = nodeConst->getUnionArrayPointer(); writeConstantUnionArray(out, constUnion, nodeConst->getType().getObjectSize()); if (node != constructor->getSequence()->back()) { out << ", "; } } } out << "}"; return true; } return false; } TString OutputHLSL::addStructEqualityFunction(const TStructure &structure) { const TFieldList &fields = structure.fields(); for (const auto &eqFunction : mStructEqualityFunctions) { if (eqFunction->structure == &structure) { return eqFunction->functionName; } } const TString &structNameString = StructNameString(structure); StructEqualityFunction *function = new StructEqualityFunction(); function->structure = &structure; function->functionName = "angle_eq_" + structNameString; TInfoSinkBase fnOut; fnOut << "bool " << function->functionName << "(" << structNameString << " a, " << structNameString + " b)\n" << "{\n" " return "; for (size_t i = 0; i < fields.size(); i++) { const TField *field = fields[i]; const TType *fieldType = field->type(); const TString &fieldNameA = "a." + Decorate(field->name()); const TString &fieldNameB = "b." + Decorate(field->name()); if (i > 0) { fnOut << " && "; } fnOut << "("; outputEqual(PreVisit, *fieldType, EOpEqual, fnOut); fnOut << fieldNameA; outputEqual(InVisit, *fieldType, EOpEqual, fnOut); fnOut << fieldNameB; outputEqual(PostVisit, *fieldType, EOpEqual, fnOut); fnOut << ")"; } fnOut << ";\n" << "}\n"; function->functionDefinition = fnOut.c_str(); mStructEqualityFunctions.push_back(function); mEqualityFunctions.push_back(function); return function->functionName; } TString OutputHLSL::addArrayEqualityFunction(const TType &type) { for (const auto &eqFunction : mArrayEqualityFunctions) { if (eqFunction->type == type) { return eqFunction->functionName; } } TType elementType(type); elementType.toArrayElementType(); ArrayHelperFunction *function = new ArrayHelperFunction(); function->type = type; function->functionName = ArrayHelperFunctionName("angle_eq", type); TInfoSinkBase fnOut; const TString &typeName = TypeString(type); fnOut << "bool " << function->functionName << "(" << typeName << " a" << ArrayString(type) << ", " << typeName << " b" << ArrayString(type) << ")\n" << "{\n" " for (int i = 0; i < " << type.getOutermostArraySize() << "; ++i)\n" " {\n" " if ("; outputEqual(PreVisit, elementType, EOpNotEqual, fnOut); fnOut << "a[i]"; outputEqual(InVisit, elementType, EOpNotEqual, fnOut); fnOut << "b[i]"; outputEqual(PostVisit, elementType, EOpNotEqual, fnOut); fnOut << ") { return false; }\n" " }\n" " return true;\n" "}\n"; function->functionDefinition = fnOut.c_str(); mArrayEqualityFunctions.push_back(function); mEqualityFunctions.push_back(function); return function->functionName; } TString OutputHLSL::addArrayAssignmentFunction(const TType &type) { for (const auto &assignFunction : mArrayAssignmentFunctions) { if (assignFunction.type == type) { return assignFunction.functionName; } } TType elementType(type); elementType.toArrayElementType(); ArrayHelperFunction function; function.type = type; function.functionName = ArrayHelperFunctionName("angle_assign", type); TInfoSinkBase fnOut; const TString &typeName = TypeString(type); fnOut << "void " << function.functionName << "(out " << typeName << " a" << ArrayString(type) << ", " << typeName << " b" << ArrayString(type) << ")\n" << "{\n" " for (int i = 0; i < " << type.getOutermostArraySize() << "; ++i)\n" " {\n" " "; outputAssign(PreVisit, elementType, fnOut); fnOut << "a[i]"; outputAssign(InVisit, elementType, fnOut); fnOut << "b[i]"; outputAssign(PostVisit, elementType, fnOut); fnOut << ";\n" " }\n" "}\n"; function.functionDefinition = fnOut.c_str(); mArrayAssignmentFunctions.push_back(function); return function.functionName; } TString OutputHLSL::addArrayConstructIntoFunction(const TType &type) { for (const auto &constructIntoFunction : mArrayConstructIntoFunctions) { if (constructIntoFunction.type == type) { return constructIntoFunction.functionName; } } TType elementType(type); elementType.toArrayElementType(); ArrayHelperFunction function; function.type = type; function.functionName = ArrayHelperFunctionName("angle_construct_into", type); TInfoSinkBase fnOut; const TString &typeName = TypeString(type); fnOut << "void " << function.functionName << "(out " << typeName << " a" << ArrayString(type); for (unsigned int i = 0u; i < type.getOutermostArraySize(); ++i) { fnOut << ", " << typeName << " b" << i << ArrayString(elementType); } fnOut << ")\n" "{\n"; for (unsigned int i = 0u; i < type.getOutermostArraySize(); ++i) { fnOut << " "; outputAssign(PreVisit, elementType, fnOut); fnOut << "a[" << i << "]"; outputAssign(InVisit, elementType, fnOut); fnOut << "b" << i; outputAssign(PostVisit, elementType, fnOut); fnOut << ";\n"; } fnOut << "}\n"; function.functionDefinition = fnOut.c_str(); mArrayConstructIntoFunctions.push_back(function); return function.functionName; } void OutputHLSL::ensureStructDefined(const TType &type) { const TStructure *structure = type.getStruct(); if (structure) { ASSERT(type.getBasicType() == EbtStruct); mStructureHLSL->ensureStructDefined(*structure); } } } // namespace sh