// // Copyright (c) 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. // // StructureHLSL.cpp: // HLSL translation of GLSL constructors and structures. // #include "compiler/translator/StructureHLSL.h" #include "common/utilities.h" #include "compiler/translator/OutputHLSL.h" #include "compiler/translator/Types.h" #include "compiler/translator/UtilsHLSL.h" #include "compiler/translator/util.h" namespace sh { namespace { TString Define(const TStructure &structure, bool useHLSLRowMajorPacking, bool useStd140Packing, Std140PaddingHelper *padHelper) { const TFieldList &fields = structure.fields(); const bool isNameless = (structure.symbolType() == SymbolType::Empty); const TString &structName = QualifiedStructNameString(structure, useHLSLRowMajorPacking, useStd140Packing); const TString declareString = (isNameless ? "struct" : "struct " + structName); TString string; string += declareString + "\n" "{\n"; for (const TField *field : fields) { const TType &fieldType = *field->type(); if (!IsSampler(fieldType.getBasicType())) { const TStructure *fieldStruct = fieldType.getStruct(); const TString &fieldTypeString = fieldStruct ? QualifiedStructNameString(*fieldStruct, useHLSLRowMajorPacking, useStd140Packing) : TypeString(fieldType); if (padHelper) { string += padHelper->prePaddingString(fieldType); } string += " " + fieldTypeString + " " + DecorateField(field->name(), structure) + ArrayString(fieldType).data() + ";\n"; if (padHelper) { string += padHelper->postPaddingString(fieldType, useHLSLRowMajorPacking); } } } // Nameless structs do not finish with a semicolon and newline, to leave room for an instance // variable string += (isNameless ? "} " : "};\n"); return string; } TString WriteParameterList(const std::vector ¶meters) { TString parameterList; for (size_t parameter = 0u; parameter < parameters.size(); parameter++) { const TType ¶mType = parameters[parameter]; parameterList += TypeString(paramType) + " x" + str(parameter) + ArrayString(paramType).data(); if (parameter < parameters.size() - 1u) { parameterList += ", "; } } return parameterList; } } // anonymous namespace Std140PaddingHelper::Std140PaddingHelper(const std::map &structElementIndexes, unsigned *uniqueCounter) : mPaddingCounter(uniqueCounter), mElementIndex(0), mStructElementIndexes(&structElementIndexes) {} Std140PaddingHelper::Std140PaddingHelper(const Std140PaddingHelper &other) : mPaddingCounter(other.mPaddingCounter), mElementIndex(other.mElementIndex), mStructElementIndexes(other.mStructElementIndexes) {} Std140PaddingHelper &Std140PaddingHelper::operator=(const Std140PaddingHelper &other) { mPaddingCounter = other.mPaddingCounter; mElementIndex = other.mElementIndex; mStructElementIndexes = other.mStructElementIndexes; return *this; } TString Std140PaddingHelper::next() { unsigned value = (*mPaddingCounter)++; return str(value); } int Std140PaddingHelper::prePadding(const TType &type) { if (type.getBasicType() == EbtStruct || type.isMatrix() || type.isArray()) { // no padding needed, HLSL will align the field to a new register mElementIndex = 0; return 0; } const GLenum glType = GLVariableType(type); const int numComponents = gl::VariableComponentCount(glType); if (numComponents >= 4) { // no padding needed, HLSL will align the field to a new register mElementIndex = 0; return 0; } if (mElementIndex + numComponents > 4) { // no padding needed, HLSL will align the field to a new register mElementIndex = numComponents; return 0; } const int alignment = numComponents == 3 ? 4 : numComponents; const int paddingOffset = (mElementIndex % alignment); const int paddingCount = (paddingOffset != 0 ? (alignment - paddingOffset) : 0); mElementIndex += paddingCount; mElementIndex += numComponents; mElementIndex %= 4; return paddingCount; } TString Std140PaddingHelper::prePaddingString(const TType &type) { int paddingCount = prePadding(type); TString padding; for (int paddingIndex = 0; paddingIndex < paddingCount; paddingIndex++) { padding += " float pad_" + next() + ";\n"; } return padding; } TString Std140PaddingHelper::postPaddingString(const TType &type, bool useHLSLRowMajorPacking) { if (!type.isMatrix() && !type.isArray() && type.getBasicType() != EbtStruct) { return ""; } int numComponents = 0; const TStructure *structure = type.getStruct(); if (type.isMatrix()) { // This method can also be called from structureString, which does not use layout // qualifiers. // Thus, use the method parameter for determining the matrix packing. // // Note HLSL row major packing corresponds to GL API column-major, and vice-versa, since we // wish to always transpose GL matrices to play well with HLSL's matrix array indexing. // const bool isRowMajorMatrix = !useHLSLRowMajorPacking; const GLenum glType = GLVariableType(type); numComponents = gl::MatrixComponentCount(glType, isRowMajorMatrix); } else if (structure) { const TString &structName = QualifiedStructNameString(*structure, useHLSLRowMajorPacking, true); numComponents = mStructElementIndexes->find(structName)->second; if (numComponents == 0) { return ""; } } else { const GLenum glType = GLVariableType(type); numComponents = gl::VariableComponentCount(glType); } TString padding; for (int paddingOffset = numComponents; paddingOffset < 4; paddingOffset++) { padding += " float pad_" + next() + ";\n"; } return padding; } StructureHLSL::StructureHLSL() : mUniquePaddingCounter(0) {} Std140PaddingHelper StructureHLSL::getPaddingHelper() { return Std140PaddingHelper(mStd140StructElementIndexes, &mUniquePaddingCounter); } TString StructureHLSL::defineQualified(const TStructure &structure, bool useHLSLRowMajorPacking, bool useStd140Packing) { if (useStd140Packing) { Std140PaddingHelper padHelper = getPaddingHelper(); return Define(structure, useHLSLRowMajorPacking, useStd140Packing, &padHelper); } else { return Define(structure, useHLSLRowMajorPacking, useStd140Packing, nullptr); } } TString StructureHLSL::defineNameless(const TStructure &structure) { return Define(structure, false, false, nullptr); } StructureHLSL::DefinedStructs::iterator StructureHLSL::defineVariants(const TStructure &structure, const TString &name) { ASSERT(mDefinedStructs.find(name) == mDefinedStructs.end()); for (const TField *field : structure.fields()) { const TType *fieldType = field->type(); if (fieldType->getBasicType() == EbtStruct) { ensureStructDefined(*fieldType->getStruct()); } } DefinedStructs::iterator addedStruct = mDefinedStructs.insert(std::make_pair(name, new TStructProperties())).first; // Add element index storeStd140ElementIndex(structure, false); storeStd140ElementIndex(structure, true); const TString &structString = defineQualified(structure, false, false); ASSERT(std::find(mStructDeclarations.begin(), mStructDeclarations.end(), structString) == mStructDeclarations.end()); // Add row-major packed struct for interface blocks TString rowMajorString = "#pragma pack_matrix(row_major)\n" + defineQualified(structure, true, false) + "#pragma pack_matrix(column_major)\n"; TString std140String = defineQualified(structure, false, true); TString std140RowMajorString = "#pragma pack_matrix(row_major)\n" + defineQualified(structure, true, true) + "#pragma pack_matrix(column_major)\n"; mStructDeclarations.push_back(structString); mStructDeclarations.push_back(rowMajorString); mStructDeclarations.push_back(std140String); mStructDeclarations.push_back(std140RowMajorString); return addedStruct; } void StructureHLSL::ensureStructDefined(const TStructure &structure) { const TString name = StructNameString(structure); if (name == "") { return; // Nameless structures are not defined } if (mDefinedStructs.find(name) == mDefinedStructs.end()) { defineVariants(structure, name); } } TString StructureHLSL::addStructConstructor(const TStructure &structure) { const TString name = StructNameString(structure); if (name == "") { return TString(); // Nameless structures don't have constructors } auto definedStruct = mDefinedStructs.find(name); if (definedStruct == mDefinedStructs.end()) { definedStruct = defineVariants(structure, name); } const TString constructorFunctionName = TString(name) + "_ctor"; TString *constructor = &definedStruct->second->constructor; if (!constructor->empty()) { return constructorFunctionName; // Already added } *constructor += name + " " + constructorFunctionName + "("; std::vector ctorParameters; const TFieldList &fields = structure.fields(); for (const TField *field : fields) { const TType *fieldType = field->type(); if (!IsSampler(fieldType->getBasicType())) { ctorParameters.push_back(*fieldType); } } // Structs that have sampler members should not have constructor calls, and otherwise structs // are guaranteed to be non-empty by the grammar. Structs can't contain empty declarations // either. ASSERT(!ctorParameters.empty()); *constructor += WriteParameterList(ctorParameters); *constructor += ")\n" "{\n" " " + name + " structure = { "; for (size_t parameterIndex = 0u; parameterIndex < ctorParameters.size(); ++parameterIndex) { *constructor += "x" + str(parameterIndex); if (parameterIndex < ctorParameters.size() - 1u) { *constructor += ", "; } } *constructor += "};\n" " return structure;\n" "}\n"; return constructorFunctionName; } TString StructureHLSL::addBuiltInConstructor(const TType &type, const TIntermSequence *parameters) { ASSERT(!type.isArray()); ASSERT(type.getStruct() == nullptr); ASSERT(parameters); TType ctorType = type; ctorType.setPrecision(EbpHigh); ctorType.setQualifier(EvqTemporary); const TString constructorFunctionName = TString(type.getBuiltInTypeNameString()) + "_ctor" + DisambiguateFunctionName(parameters); TString constructor = TypeString(ctorType) + " " + constructorFunctionName + "("; std::vector ctorParameters; for (auto parameter : *parameters) { const TType ¶mType = parameter->getAsTyped()->getType(); ASSERT(!paramType.isArray()); ctorParameters.push_back(paramType); } constructor += WriteParameterList(ctorParameters); constructor += ")\n" "{\n" " return " + TypeString(ctorType) + "("; if (ctorType.isMatrix() && ctorParameters.size() == 1) { int rows = ctorType.getRows(); int cols = ctorType.getCols(); const TType ¶meter = ctorParameters[0]; if (parameter.isScalar()) { for (int col = 0; col < cols; col++) { for (int row = 0; row < rows; row++) { constructor += TString((row == col) ? "x0" : "0.0"); if (row < rows - 1 || col < cols - 1) { constructor += ", "; } } } } else if (parameter.isMatrix()) { for (int col = 0; col < cols; col++) { for (int row = 0; row < rows; row++) { if (row < parameter.getRows() && col < parameter.getCols()) { constructor += TString("x0") + "[" + str(col) + "][" + str(row) + "]"; } else { constructor += TString((row == col) ? "1.0" : "0.0"); } if (row < rows - 1 || col < cols - 1) { constructor += ", "; } } } } else { ASSERT(rows == 2 && cols == 2 && parameter.isVector() && parameter.getNominalSize() == 4); constructor += "x0"; } } else { size_t remainingComponents = ctorType.getObjectSize(); size_t parameterIndex = 0; while (remainingComponents > 0) { const TType ¶meter = ctorParameters[parameterIndex]; const size_t parameterSize = parameter.getObjectSize(); bool moreParameters = parameterIndex + 1 < ctorParameters.size(); constructor += "x" + str(parameterIndex); if (parameter.isScalar()) { remainingComponents -= parameter.getObjectSize(); } else if (parameter.isVector()) { if (remainingComponents == parameterSize || moreParameters) { ASSERT(parameterSize <= remainingComponents); remainingComponents -= parameterSize; } else if (remainingComponents < static_cast(parameter.getNominalSize())) { switch (remainingComponents) { case 1: constructor += ".x"; break; case 2: constructor += ".xy"; break; case 3: constructor += ".xyz"; break; case 4: constructor += ".xyzw"; break; default: UNREACHABLE(); } remainingComponents = 0; } else UNREACHABLE(); } else if (parameter.isMatrix()) { int column = 0; while (remainingComponents > 0 && column < parameter.getCols()) { constructor += "[" + str(column) + "]"; if (remainingComponents < static_cast(parameter.getRows())) { switch (remainingComponents) { case 1: constructor += ".x"; break; case 2: constructor += ".xy"; break; case 3: constructor += ".xyz"; break; default: UNREACHABLE(); } remainingComponents = 0; } else { remainingComponents -= parameter.getRows(); if (remainingComponents > 0) { constructor += ", x" + str(parameterIndex); } } column++; } } else { UNREACHABLE(); } if (moreParameters) { parameterIndex++; } if (remainingComponents) { constructor += ", "; } } } constructor += ");\n" "}\n"; mBuiltInConstructors.insert(constructor); return constructorFunctionName; } std::string StructureHLSL::structsHeader() const { TInfoSinkBase out; for (auto &declaration : mStructDeclarations) { out << declaration; } for (auto &structure : mDefinedStructs) { out << structure.second->constructor; } for (auto &constructor : mBuiltInConstructors) { out << constructor; } return out.str(); } void StructureHLSL::storeStd140ElementIndex(const TStructure &structure, bool useHLSLRowMajorPacking) { Std140PaddingHelper padHelper = getPaddingHelper(); const TFieldList &fields = structure.fields(); for (const TField *field : fields) { padHelper.prePadding(*field->type()); } // Add remaining element index to the global map, for use with nested structs in standard // layouts const TString &structName = QualifiedStructNameString(structure, useHLSLRowMajorPacking, true); mStd140StructElementIndexes[structName] = padHelper.elementIndex(); } } // namespace sh