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kc3-lang/angle/src/compiler/translator/IntermNode.cpp
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Author :
Olli Etuaho
Date : 2017-01-02 17:34:40
Hash : d68924e5
Message : Use GetOperatorString when writing GLSL unary built-in calls GetOperatorString is now used when writing GLSL for built-in calls that fall under TIntermUnary. Component-wise not TOperator enum is renamed for consistency. This also cleans up some unnecessary creation of string objects when writing built-in functions. BUG=angleproject:1682 TEST=angle_unittests, angle_end2end_tests, WebGL conformance tests Change-Id: I89b2ef222bf5af479d4977417f320789b58ace85 Reviewed-on: https://chromium-review.googlesource.com/424552 Commit-Queue: Olli Etuaho <oetuaho@nvidia.com> Reviewed-by: Jamie Madill <jmadill@chromium.org>
- src/compiler/translator/IntermNode.cpp
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// // 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. // // // Build the intermediate representation. // #include <float.h> #include <limits.h> #include <math.h> #include <stdlib.h> #include <algorithm> #include <vector> #include "common/mathutil.h" #include "common/matrix_utils.h" #include "compiler/translator/Diagnostics.h" #include "compiler/translator/HashNames.h" #include "compiler/translator/IntermNode.h" #include "compiler/translator/SymbolTable.h" #include "compiler/translator/util.h" namespace sh { namespace { const float kPi = 3.14159265358979323846f; const float kDegreesToRadiansMultiplier = kPi / 180.0f; const float kRadiansToDegreesMultiplier = 180.0f / kPi; TPrecision GetHigherPrecision(TPrecision left, TPrecision right) { return left > right ? left : right; } TConstantUnion *Vectorize(const TConstantUnion &constant, size_t size) { TConstantUnion *constUnion = new TConstantUnion[size]; for (unsigned int i = 0; i < size; ++i) constUnion[i] = constant; return constUnion; } void UndefinedConstantFoldingError(const TSourceLoc &loc, TOperator op, TBasicType basicType, TDiagnostics *diagnostics, TConstantUnion *result) { diagnostics->warning(loc, "operation result is undefined for the values passed in", GetOperatorString(op)); switch (basicType) { case EbtFloat: result->setFConst(0.0f); break; case EbtInt: result->setIConst(0); break; case EbtUInt: result->setUConst(0u); break; case EbtBool: result->setBConst(false); break; default: break; } } float VectorLength(const TConstantUnion *paramArray, size_t paramArraySize) { float result = 0.0f; for (size_t i = 0; i < paramArraySize; i++) { float f = paramArray[i].getFConst(); result += f * f; } return sqrtf(result); } float VectorDotProduct(const TConstantUnion *paramArray1, const TConstantUnion *paramArray2, size_t paramArraySize) { float result = 0.0f; for (size_t i = 0; i < paramArraySize; i++) result += paramArray1[i].getFConst() * paramArray2[i].getFConst(); return result; } TIntermTyped *CreateFoldedNode(const TConstantUnion *constArray, const TIntermTyped *originalNode, TQualifier qualifier) { if (constArray == nullptr) { return nullptr; } TIntermTyped *folded = new TIntermConstantUnion(constArray, originalNode->getType()); folded->getTypePointer()->setQualifier(qualifier); folded->setLine(originalNode->getLine()); return folded; } angle::Matrix<float> GetMatrix(const TConstantUnion *paramArray, const unsigned int &rows, const unsigned int &cols) { std::vector<float> elements; for (size_t i = 0; i < rows * cols; i++) elements.push_back(paramArray[i].getFConst()); // Transpose is used since the Matrix constructor expects arguments in row-major order, // whereas the paramArray is in column-major order. Rows/cols parameters are also flipped below // so that the created matrix will have the expected dimensions after the transpose. return angle::Matrix<float>(elements, cols, rows).transpose(); } angle::Matrix<float> GetMatrix(const TConstantUnion *paramArray, const unsigned int &size) { std::vector<float> elements; for (size_t i = 0; i < size * size; i++) elements.push_back(paramArray[i].getFConst()); // Transpose is used since the Matrix constructor expects arguments in row-major order, // whereas the paramArray is in column-major order. return angle::Matrix<float>(elements, size).transpose(); } void SetUnionArrayFromMatrix(const angle::Matrix<float> &m, TConstantUnion *resultArray) { // Transpose is used since the input Matrix is in row-major order, // whereas the actual result should be in column-major order. angle::Matrix<float> result = m.transpose(); std::vector<float> resultElements = result.elements(); for (size_t i = 0; i < resultElements.size(); i++) resultArray[i].setFConst(resultElements[i]); } } // namespace anonymous //////////////////////////////////////////////////////////////// // // Member functions of the nodes used for building the tree. // //////////////////////////////////////////////////////////////// void TIntermTyped::setTypePreservePrecision(const TType &t) { TPrecision precision = getPrecision(); mType = t; ASSERT(mType.getBasicType() != EbtBool || precision == EbpUndefined); mType.setPrecision(precision); } #define REPLACE_IF_IS(node, type, original, replacement) \ if (node == original) \ { \ node = static_cast<type *>(replacement); \ return true; \ } bool TIntermLoop::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { ASSERT(original != nullptr); // This risks replacing multiple children. REPLACE_IF_IS(mInit, TIntermNode, original, replacement); REPLACE_IF_IS(mCond, TIntermTyped, original, replacement); REPLACE_IF_IS(mExpr, TIntermTyped, original, replacement); REPLACE_IF_IS(mBody, TIntermBlock, original, replacement); return false; } bool TIntermBranch::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mExpression, TIntermTyped, original, replacement); return false; } bool TIntermSwizzle::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { ASSERT(original->getAsTyped()->getType() == replacement->getAsTyped()->getType()); REPLACE_IF_IS(mOperand, TIntermTyped, original, replacement); return false; } bool TIntermBinary::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mLeft, TIntermTyped, original, replacement); REPLACE_IF_IS(mRight, TIntermTyped, original, replacement); return false; } bool TIntermUnary::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { ASSERT(original->getAsTyped()->getType() == replacement->getAsTyped()->getType()); REPLACE_IF_IS(mOperand, TIntermTyped, original, replacement); return false; } bool TIntermInvariantDeclaration::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mSymbol, TIntermSymbol, original, replacement); return false; } bool TIntermFunctionDefinition::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mParameters, TIntermAggregate, original, replacement); REPLACE_IF_IS(mBody, TIntermBlock, original, replacement); return false; } bool TIntermAggregate::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { return replaceChildNodeInternal(original, replacement); } bool TIntermBlock::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { return replaceChildNodeInternal(original, replacement); } bool TIntermDeclaration::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { return replaceChildNodeInternal(original, replacement); } bool TIntermAggregateBase::replaceChildNodeInternal(TIntermNode *original, TIntermNode *replacement) { for (size_t ii = 0; ii < getSequence()->size(); ++ii) { REPLACE_IF_IS((*getSequence())[ii], TIntermNode, original, replacement); } return false; } bool TIntermAggregateBase::replaceChildNodeWithMultiple(TIntermNode *original, const TIntermSequence &replacements) { for (auto it = getSequence()->begin(); it < getSequence()->end(); ++it) { if (*it == original) { it = getSequence()->erase(it); getSequence()->insert(it, replacements.begin(), replacements.end()); return true; } } return false; } bool TIntermAggregateBase::insertChildNodes(TIntermSequence::size_type position, const TIntermSequence &insertions) { if (position > getSequence()->size()) { return false; } auto it = getSequence()->begin() + position; getSequence()->insert(it, insertions.begin(), insertions.end()); return true; } bool TIntermAggregate::areChildrenConstQualified() { for (TIntermNode *&child : mSequence) { TIntermTyped *typed = child->getAsTyped(); if (typed && typed->getQualifier() != EvqConst) { return false; } } return true; } void TIntermAggregate::setPrecisionFromChildren() { mGotPrecisionFromChildren = true; if (getBasicType() == EbtBool) { mType.setPrecision(EbpUndefined); return; } TPrecision precision = EbpUndefined; TIntermSequence::iterator childIter = mSequence.begin(); while (childIter != mSequence.end()) { TIntermTyped *typed = (*childIter)->getAsTyped(); if (typed) precision = GetHigherPrecision(typed->getPrecision(), precision); ++childIter; } mType.setPrecision(precision); } void TIntermAggregate::setBuiltInFunctionPrecision() { // All built-ins returning bool should be handled as ops, not functions. ASSERT(getBasicType() != EbtBool); TPrecision precision = EbpUndefined; TIntermSequence::iterator childIter = mSequence.begin(); while (childIter != mSequence.end()) { TIntermTyped *typed = (*childIter)->getAsTyped(); // ESSL spec section 8: texture functions get their precision from the sampler. if (typed && IsSampler(typed->getBasicType())) { precision = typed->getPrecision(); break; } ++childIter; } // ESSL 3.0 spec section 8: textureSize always gets highp precision. // All other functions that take a sampler are assumed to be texture functions. if (mFunctionInfo.getName().find("textureSize") == 0) mType.setPrecision(EbpHigh); else mType.setPrecision(precision); } void TIntermBlock::appendStatement(TIntermNode *statement) { // Declaration nodes with no children can appear if all the declarators just added constants to // the symbol table instead of generating code. They're no-ops so they aren't added to blocks. if (statement != nullptr && (statement->getAsDeclarationNode() == nullptr || !statement->getAsDeclarationNode()->getSequence()->empty())) { mStatements.push_back(statement); } } void TIntermDeclaration::appendDeclarator(TIntermTyped *declarator) { ASSERT(declarator != nullptr); ASSERT(declarator->getAsSymbolNode() != nullptr || (declarator->getAsBinaryNode() != nullptr && declarator->getAsBinaryNode()->getOp() == EOpInitialize)); ASSERT(mDeclarators.empty() || declarator->getType().sameElementType(mDeclarators.back()->getAsTyped()->getType())); mDeclarators.push_back(declarator); } bool TIntermTernary::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mCondition, TIntermTyped, original, replacement); REPLACE_IF_IS(mTrueExpression, TIntermTyped, original, replacement); REPLACE_IF_IS(mFalseExpression, TIntermTyped, original, replacement); return false; } bool TIntermIfElse::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mCondition, TIntermTyped, original, replacement); REPLACE_IF_IS(mTrueBlock, TIntermBlock, original, replacement); REPLACE_IF_IS(mFalseBlock, TIntermBlock, original, replacement); return false; } bool TIntermSwitch::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mInit, TIntermTyped, original, replacement); REPLACE_IF_IS(mStatementList, TIntermBlock, original, replacement); return false; } bool TIntermCase::replaceChildNode(TIntermNode *original, TIntermNode *replacement) { REPLACE_IF_IS(mCondition, TIntermTyped, original, replacement); return false; } TIntermTyped::TIntermTyped(const TIntermTyped &node) : TIntermNode(), mType(node.mType) { // Copy constructor is disallowed for TIntermNode in order to disallow it for subclasses that // don't explicitly allow it, so normal TIntermNode constructor is used to construct the copy. // We need to manually copy any fields of TIntermNode besides handling fields in TIntermTyped. mLine = node.mLine; } bool TIntermTyped::isConstructorWithOnlyConstantUnionParameters() { TIntermAggregate *constructor = getAsAggregate(); if (!constructor || !constructor->isConstructor()) { return false; } for (TIntermNode *&node : *constructor->getSequence()) { if (!node->getAsConstantUnion()) return false; } return true; } // static TIntermTyped *TIntermTyped::CreateIndexNode(int index) { TConstantUnion *u = new TConstantUnion[1]; u[0].setIConst(index); TType type(EbtInt, EbpUndefined, EvqConst, 1); TIntermConstantUnion *node = new TIntermConstantUnion(u, type); return node; } // static TIntermTyped *TIntermTyped::CreateZero(const TType &type) { TType constType(type); constType.setQualifier(EvqConst); if (!type.isArray() && type.getBasicType() != EbtStruct) { ASSERT(type.isScalar() || type.isVector() || type.isMatrix()); size_t size = constType.getObjectSize(); TConstantUnion *u = new TConstantUnion[size]; for (size_t i = 0; i < size; ++i) { switch (type.getBasicType()) { case EbtFloat: u[i].setFConst(0.0f); break; case EbtInt: u[i].setIConst(0); break; case EbtUInt: u[i].setUConst(0u); break; case EbtBool: u[i].setBConst(false); break; default: UNREACHABLE(); return nullptr; } } TIntermConstantUnion *node = new TIntermConstantUnion(u, constType); return node; } TIntermAggregate *constructor = new TIntermAggregate(sh::TypeToConstructorOperator(type)); constructor->setType(constType); if (type.isArray()) { TType elementType(type); elementType.clearArrayness(); size_t arraySize = type.getArraySize(); for (size_t i = 0; i < arraySize; ++i) { constructor->getSequence()->push_back(CreateZero(elementType)); } } else { ASSERT(type.getBasicType() == EbtStruct); TStructure *structure = type.getStruct(); for (const auto &field : structure->fields()) { constructor->getSequence()->push_back(CreateZero(*field->type())); } } return constructor; } // static TIntermTyped *TIntermTyped::CreateBool(bool value) { TConstantUnion *u = new TConstantUnion[1]; u[0].setBConst(value); TType type(EbtBool, EbpUndefined, EvqConst, 1); TIntermConstantUnion *node = new TIntermConstantUnion(u, type); return node; } TIntermConstantUnion::TIntermConstantUnion(const TIntermConstantUnion &node) : TIntermTyped(node) { mUnionArrayPointer = node.mUnionArrayPointer; } void TFunctionSymbolInfo::setFromFunction(const TFunction &function) { setName(function.getMangledName()); setId(function.getUniqueId()); } TIntermAggregate::TIntermAggregate(const TIntermAggregate &node) : TIntermOperator(node), mUserDefined(node.mUserDefined), mUseEmulatedFunction(node.mUseEmulatedFunction), mGotPrecisionFromChildren(node.mGotPrecisionFromChildren), mFunctionInfo(node.mFunctionInfo) { for (TIntermNode *child : node.mSequence) { TIntermTyped *typedChild = child->getAsTyped(); ASSERT(typedChild != nullptr); TIntermTyped *childCopy = typedChild->deepCopy(); mSequence.push_back(childCopy); } } TIntermSwizzle::TIntermSwizzle(const TIntermSwizzle &node) : TIntermTyped(node) { TIntermTyped *operandCopy = node.mOperand->deepCopy(); ASSERT(operandCopy != nullptr); mOperand = operandCopy; } TIntermBinary::TIntermBinary(const TIntermBinary &node) : TIntermOperator(node), mAddIndexClamp(node.mAddIndexClamp) { TIntermTyped *leftCopy = node.mLeft->deepCopy(); TIntermTyped *rightCopy = node.mRight->deepCopy(); ASSERT(leftCopy != nullptr && rightCopy != nullptr); mLeft = leftCopy; mRight = rightCopy; } TIntermUnary::TIntermUnary(const TIntermUnary &node) : TIntermOperator(node), mUseEmulatedFunction(node.mUseEmulatedFunction) { TIntermTyped *operandCopy = node.mOperand->deepCopy(); ASSERT(operandCopy != nullptr); mOperand = operandCopy; } TIntermTernary::TIntermTernary(const TIntermTernary &node) : TIntermTyped(node) { TIntermTyped *conditionCopy = node.mCondition->deepCopy(); TIntermTyped *trueCopy = node.mTrueExpression->deepCopy(); TIntermTyped *falseCopy = node.mFalseExpression->deepCopy(); ASSERT(conditionCopy != nullptr && trueCopy != nullptr && falseCopy != nullptr); mCondition = conditionCopy; mTrueExpression = trueCopy; mFalseExpression = falseCopy; } bool TIntermOperator::isAssignment() const { return IsAssignment(mOp); } bool TIntermOperator::isMultiplication() const { switch (mOp) { case EOpMul: case EOpMatrixTimesMatrix: case EOpMatrixTimesVector: case EOpMatrixTimesScalar: case EOpVectorTimesMatrix: case EOpVectorTimesScalar: return true; default: return false; } } // // returns true if the operator is for one of the constructors // bool TIntermOperator::isConstructor() const { switch (mOp) { case EOpConstructVec2: case EOpConstructVec3: case EOpConstructVec4: case EOpConstructMat2: case EOpConstructMat2x3: case EOpConstructMat2x4: case EOpConstructMat3x2: case EOpConstructMat3: case EOpConstructMat3x4: case EOpConstructMat4x2: case EOpConstructMat4x3: case EOpConstructMat4: case EOpConstructFloat: case EOpConstructIVec2: case EOpConstructIVec3: case EOpConstructIVec4: case EOpConstructInt: case EOpConstructUVec2: case EOpConstructUVec3: case EOpConstructUVec4: case EOpConstructUInt: case EOpConstructBVec2: case EOpConstructBVec3: case EOpConstructBVec4: case EOpConstructBool: case EOpConstructStruct: return true; default: return false; } } TOperator TIntermBinary::GetMulOpBasedOnOperands(const TType &left, const TType &right) { if (left.isMatrix()) { if (right.isMatrix()) { return EOpMatrixTimesMatrix; } else { if (right.isVector()) { return EOpMatrixTimesVector; } else { return EOpMatrixTimesScalar; } } } else { if (right.isMatrix()) { if (left.isVector()) { return EOpVectorTimesMatrix; } else { return EOpMatrixTimesScalar; } } else { // Neither operand is a matrix. if (left.isVector() == right.isVector()) { // Leave as component product. return EOpMul; } else { return EOpVectorTimesScalar; } } } } TOperator TIntermBinary::GetMulAssignOpBasedOnOperands(const TType &left, const TType &right) { if (left.isMatrix()) { if (right.isMatrix()) { return EOpMatrixTimesMatrixAssign; } else { // right should be scalar, but this may not be validated yet. return EOpMatrixTimesScalarAssign; } } else { if (right.isMatrix()) { // Left should be a vector, but this may not be validated yet. return EOpVectorTimesMatrixAssign; } else { // Neither operand is a matrix. if (left.isVector() == right.isVector()) { // Leave as component product. return EOpMulAssign; } else { // left should be vector and right should be scalar, but this may not be validated // yet. return EOpVectorTimesScalarAssign; } } } } // // Make sure the type of a unary operator is appropriate for its // combination of operation and operand type. // void TIntermUnary::promote() { TQualifier resultQualifier = EvqTemporary; if (mOperand->getQualifier() == EvqConst) resultQualifier = EvqConst; unsigned char operandPrimarySize = static_cast<unsigned char>(mOperand->getType().getNominalSize()); switch (mOp) { case EOpFloatBitsToInt: setType(TType(EbtInt, EbpHigh, resultQualifier, operandPrimarySize)); break; case EOpFloatBitsToUint: setType(TType(EbtUInt, EbpHigh, resultQualifier, operandPrimarySize)); break; case EOpIntBitsToFloat: case EOpUintBitsToFloat: setType(TType(EbtFloat, EbpHigh, resultQualifier, operandPrimarySize)); break; case EOpPackSnorm2x16: case EOpPackUnorm2x16: case EOpPackHalf2x16: setType(TType(EbtUInt, EbpHigh, resultQualifier)); break; case EOpUnpackSnorm2x16: case EOpUnpackUnorm2x16: setType(TType(EbtFloat, EbpHigh, resultQualifier, 2)); break; case EOpUnpackHalf2x16: setType(TType(EbtFloat, EbpMedium, resultQualifier, 2)); break; case EOpAny: case EOpAll: setType(TType(EbtBool, EbpUndefined, resultQualifier)); break; case EOpLength: case EOpDeterminant: setType(TType(EbtFloat, mOperand->getType().getPrecision(), resultQualifier)); break; case EOpTranspose: setType(TType(EbtFloat, mOperand->getType().getPrecision(), resultQualifier, static_cast<unsigned char>(mOperand->getType().getRows()), static_cast<unsigned char>(mOperand->getType().getCols()))); break; case EOpIsInf: case EOpIsNan: setType(TType(EbtBool, EbpUndefined, resultQualifier, operandPrimarySize)); break; default: setType(mOperand->getType()); mType.setQualifier(resultQualifier); break; } } TIntermSwizzle::TIntermSwizzle(TIntermTyped *operand, const TVector<int> &swizzleOffsets) : TIntermTyped(TType(EbtFloat, EbpUndefined)), mOperand(operand), mSwizzleOffsets(swizzleOffsets) { ASSERT(mSwizzleOffsets.size() <= 4); promote(); } TIntermUnary::TIntermUnary(TOperator op, TIntermTyped *operand) : TIntermOperator(op), mOperand(operand), mUseEmulatedFunction(false) { promote(); } TIntermBinary::TIntermBinary(TOperator op, TIntermTyped *left, TIntermTyped *right) : TIntermOperator(op), mLeft(left), mRight(right), mAddIndexClamp(false) { promote(); } TIntermInvariantDeclaration::TIntermInvariantDeclaration(TIntermSymbol *symbol, const TSourceLoc &line) : TIntermNode(), mSymbol(symbol) { ASSERT(symbol); setLine(line); } TIntermTernary::TIntermTernary(TIntermTyped *cond, TIntermTyped *trueExpression, TIntermTyped *falseExpression) : TIntermTyped(trueExpression->getType()), mCondition(cond), mTrueExpression(trueExpression), mFalseExpression(falseExpression) { getTypePointer()->setQualifier( TIntermTernary::DetermineQualifier(cond, trueExpression, falseExpression)); } // static TQualifier TIntermTernary::DetermineQualifier(TIntermTyped *cond, TIntermTyped *trueExpression, TIntermTyped *falseExpression) { if (cond->getQualifier() == EvqConst && trueExpression->getQualifier() == EvqConst && falseExpression->getQualifier() == EvqConst) { return EvqConst; } return EvqTemporary; } void TIntermSwizzle::promote() { TQualifier resultQualifier = EvqTemporary; if (mOperand->getQualifier() == EvqConst) resultQualifier = EvqConst; auto numFields = mSwizzleOffsets.size(); setType(TType(mOperand->getBasicType(), mOperand->getPrecision(), resultQualifier, static_cast<unsigned char>(numFields))); } bool TIntermSwizzle::hasDuplicateOffsets() const { int offsetCount[4] = {0u, 0u, 0u, 0u}; for (const auto offset : mSwizzleOffsets) { offsetCount[offset]++; if (offsetCount[offset] > 1) { return true; } } return false; } bool TIntermSwizzle::offsetsMatch(int offset) const { return mSwizzleOffsets.size() == 1 && mSwizzleOffsets[0] == offset; } void TIntermSwizzle::writeOffsetsAsXYZW(TInfoSinkBase *out) const { for (const int offset : mSwizzleOffsets) { switch (offset) { case 0: *out << "x"; break; case 1: *out << "y"; break; case 2: *out << "z"; break; case 3: *out << "w"; break; default: UNREACHABLE(); } } } TQualifier TIntermBinary::GetCommaQualifier(int shaderVersion, const TIntermTyped *left, const TIntermTyped *right) { // ESSL3.00 section 12.43: The result of a sequence operator is not a constant-expression. if (shaderVersion >= 300 || left->getQualifier() != EvqConst || right->getQualifier() != EvqConst) { return EvqTemporary; } return EvqConst; } // Establishes the type of the result of the binary operation. void TIntermBinary::promote() { ASSERT(!isMultiplication() || mOp == GetMulOpBasedOnOperands(mLeft->getType(), mRight->getType())); // Comma is handled as a special case. if (mOp == EOpComma) { setType(mRight->getType()); return; } // Base assumption: just make the type the same as the left // operand. Then only deviations from this need be coded. setType(mLeft->getType()); TQualifier resultQualifier = EvqConst; // Binary operations results in temporary variables unless both // operands are const. if (mLeft->getQualifier() != EvqConst || mRight->getQualifier() != EvqConst) { resultQualifier = EvqTemporary; getTypePointer()->setQualifier(EvqTemporary); } // Handle indexing ops. switch (mOp) { case EOpIndexDirect: case EOpIndexIndirect: if (mLeft->isArray()) { mType.clearArrayness(); } else if (mLeft->isMatrix()) { setType(TType(mLeft->getBasicType(), mLeft->getPrecision(), resultQualifier, static_cast<unsigned char>(mLeft->getRows()))); } else if (mLeft->isVector()) { setType(TType(mLeft->getBasicType(), mLeft->getPrecision(), resultQualifier)); } else { UNREACHABLE(); } return; case EOpIndexDirectStruct: { const TFieldList &fields = mLeft->getType().getStruct()->fields(); const int i = mRight->getAsConstantUnion()->getIConst(0); setType(*fields[i]->type()); getTypePointer()->setQualifier(resultQualifier); return; } case EOpIndexDirectInterfaceBlock: { const TFieldList &fields = mLeft->getType().getInterfaceBlock()->fields(); const int i = mRight->getAsConstantUnion()->getIConst(0); setType(*fields[i]->type()); getTypePointer()->setQualifier(resultQualifier); return; } default: break; } ASSERT(mLeft->isArray() == mRight->isArray()); // The result gets promoted to the highest precision. TPrecision higherPrecision = GetHigherPrecision(mLeft->getPrecision(), mRight->getPrecision()); getTypePointer()->setPrecision(higherPrecision); const int nominalSize = std::max(mLeft->getNominalSize(), mRight->getNominalSize()); // // All scalars or structs. Code after this test assumes this case is removed! // if (nominalSize == 1) { switch (mOp) { // // Promote to conditional // case EOpEqual: case EOpNotEqual: case EOpLessThan: case EOpGreaterThan: case EOpLessThanEqual: case EOpGreaterThanEqual: setType(TType(EbtBool, EbpUndefined, resultQualifier)); break; // // And and Or operate on conditionals // case EOpLogicalAnd: case EOpLogicalXor: case EOpLogicalOr: ASSERT(mLeft->getBasicType() == EbtBool && mRight->getBasicType() == EbtBool); setType(TType(EbtBool, EbpUndefined, resultQualifier)); break; default: break; } return; } // If we reach here, at least one of the operands is vector or matrix. // The other operand could be a scalar, vector, or matrix. TBasicType basicType = mLeft->getBasicType(); switch (mOp) { case EOpMul: break; case EOpMatrixTimesScalar: if (mRight->isMatrix()) { setType(TType(basicType, higherPrecision, resultQualifier, static_cast<unsigned char>(mRight->getCols()), static_cast<unsigned char>(mRight->getRows()))); } break; case EOpMatrixTimesVector: setType(TType(basicType, higherPrecision, resultQualifier, static_cast<unsigned char>(mLeft->getRows()), 1)); break; case EOpMatrixTimesMatrix: setType(TType(basicType, higherPrecision, resultQualifier, static_cast<unsigned char>(mRight->getCols()), static_cast<unsigned char>(mLeft->getRows()))); break; case EOpVectorTimesScalar: setType(TType(basicType, higherPrecision, resultQualifier, static_cast<unsigned char>(nominalSize), 1)); break; case EOpVectorTimesMatrix: setType(TType(basicType, higherPrecision, resultQualifier, static_cast<unsigned char>(mRight->getCols()), 1)); break; case EOpMulAssign: case EOpVectorTimesScalarAssign: case EOpVectorTimesMatrixAssign: case EOpMatrixTimesScalarAssign: case EOpMatrixTimesMatrixAssign: ASSERT(mOp == GetMulAssignOpBasedOnOperands(mLeft->getType(), mRight->getType())); break; case EOpAssign: case EOpInitialize: ASSERT((mLeft->getNominalSize() == mRight->getNominalSize()) && (mLeft->getSecondarySize() == mRight->getSecondarySize())); break; case EOpAdd: case EOpSub: case EOpDiv: case EOpIMod: case EOpBitShiftLeft: case EOpBitShiftRight: case EOpBitwiseAnd: case EOpBitwiseXor: case EOpBitwiseOr: case EOpAddAssign: case EOpSubAssign: case EOpDivAssign: case EOpIModAssign: case EOpBitShiftLeftAssign: case EOpBitShiftRightAssign: case EOpBitwiseAndAssign: case EOpBitwiseXorAssign: case EOpBitwiseOrAssign: { const int secondarySize = std::max(mLeft->getSecondarySize(), mRight->getSecondarySize()); setType(TType(basicType, higherPrecision, resultQualifier, static_cast<unsigned char>(nominalSize), static_cast<unsigned char>(secondarySize))); ASSERT(!mLeft->isArray() && !mRight->isArray()); break; } case EOpEqual: case EOpNotEqual: case EOpLessThan: case EOpGreaterThan: case EOpLessThanEqual: case EOpGreaterThanEqual: ASSERT((mLeft->getNominalSize() == mRight->getNominalSize()) && (mLeft->getSecondarySize() == mRight->getSecondarySize())); setType(TType(EbtBool, EbpUndefined, resultQualifier)); break; case EOpIndexDirect: case EOpIndexIndirect: case EOpIndexDirectInterfaceBlock: case EOpIndexDirectStruct: // These ops should be already fully handled. UNREACHABLE(); break; default: UNREACHABLE(); break; } } const TConstantUnion *TIntermConstantUnion::foldIndexing(int index) { if (isArray()) { ASSERT(index < static_cast<int>(getType().getArraySize())); TType arrayElementType = getType(); arrayElementType.clearArrayness(); size_t arrayElementSize = arrayElementType.getObjectSize(); return &mUnionArrayPointer[arrayElementSize * index]; } else if (isMatrix()) { ASSERT(index < getType().getCols()); int size = getType().getRows(); return &mUnionArrayPointer[size * index]; } else if (isVector()) { ASSERT(index < getType().getNominalSize()); return &mUnionArrayPointer[index]; } else { UNREACHABLE(); return nullptr; } } TIntermTyped *TIntermSwizzle::fold() { TIntermConstantUnion *operandConstant = mOperand->getAsConstantUnion(); if (operandConstant == nullptr) { return nullptr; } TConstantUnion *constArray = new TConstantUnion[mSwizzleOffsets.size()]; for (size_t i = 0; i < mSwizzleOffsets.size(); ++i) { constArray[i] = *operandConstant->foldIndexing(mSwizzleOffsets.at(i)); } return CreateFoldedNode(constArray, this, mType.getQualifier()); } TIntermTyped *TIntermBinary::fold(TDiagnostics *diagnostics) { TIntermConstantUnion *leftConstant = mLeft->getAsConstantUnion(); TIntermConstantUnion *rightConstant = mRight->getAsConstantUnion(); switch (mOp) { case EOpIndexDirect: { if (leftConstant == nullptr || rightConstant == nullptr) { return nullptr; } int index = rightConstant->getIConst(0); const TConstantUnion *constArray = leftConstant->foldIndexing(index); return CreateFoldedNode(constArray, this, mType.getQualifier()); } case EOpIndexDirectStruct: { if (leftConstant == nullptr || rightConstant == nullptr) { return nullptr; } const TFieldList &fields = mLeft->getType().getStruct()->fields(); size_t index = static_cast<size_t>(rightConstant->getIConst(0)); size_t previousFieldsSize = 0; for (size_t i = 0; i < index; ++i) { previousFieldsSize += fields[i]->type()->getObjectSize(); } const TConstantUnion *constArray = leftConstant->getUnionArrayPointer(); return CreateFoldedNode(constArray + previousFieldsSize, this, mType.getQualifier()); } case EOpIndexIndirect: case EOpIndexDirectInterfaceBlock: // Can never be constant folded. return nullptr; default: { if (leftConstant == nullptr || rightConstant == nullptr) { return nullptr; } TConstantUnion *constArray = leftConstant->foldBinary(mOp, rightConstant, diagnostics, mLeft->getLine()); // Nodes may be constant folded without being qualified as constant. return CreateFoldedNode(constArray, this, mType.getQualifier()); } } } TIntermTyped *TIntermUnary::fold(TDiagnostics *diagnostics) { TIntermConstantUnion *operandConstant = mOperand->getAsConstantUnion(); if (operandConstant == nullptr) { return nullptr; } TConstantUnion *constArray = nullptr; switch (mOp) { case EOpAny: case EOpAll: case EOpLength: case EOpTranspose: case EOpDeterminant: case EOpInverse: case EOpPackSnorm2x16: case EOpUnpackSnorm2x16: case EOpPackUnorm2x16: case EOpUnpackUnorm2x16: case EOpPackHalf2x16: case EOpUnpackHalf2x16: constArray = operandConstant->foldUnaryNonComponentWise(mOp); break; default: constArray = operandConstant->foldUnaryComponentWise(mOp, diagnostics); break; } // Nodes may be constant folded without being qualified as constant. return CreateFoldedNode(constArray, this, mType.getQualifier()); } TIntermTyped *TIntermAggregate::fold(TDiagnostics *diagnostics) { // Make sure that all params are constant before actual constant folding. for (auto *param : *getSequence()) { if (param->getAsConstantUnion() == nullptr) { return nullptr; } } TConstantUnion *constArray = nullptr; if (isConstructor()) constArray = TIntermConstantUnion::FoldAggregateConstructor(this); else constArray = TIntermConstantUnion::FoldAggregateBuiltIn(this, diagnostics); // Nodes may be constant folded without being qualified as constant. TQualifier resultQualifier = areChildrenConstQualified() ? EvqConst : EvqTemporary; return CreateFoldedNode(constArray, this, resultQualifier); } // // The fold functions see if an operation on a constant can be done in place, // without generating run-time code. // // Returns the constant value to keep using or nullptr. // TConstantUnion *TIntermConstantUnion::foldBinary(TOperator op, TIntermConstantUnion *rightNode, TDiagnostics *diagnostics, const TSourceLoc &line) { const TConstantUnion *leftArray = getUnionArrayPointer(); const TConstantUnion *rightArray = rightNode->getUnionArrayPointer(); ASSERT(leftArray && rightArray); size_t objectSize = getType().getObjectSize(); // for a case like float f = vec4(2, 3, 4, 5) + 1.2; if (rightNode->getType().getObjectSize() == 1 && objectSize > 1) { rightArray = Vectorize(*rightNode->getUnionArrayPointer(), objectSize); } else if (rightNode->getType().getObjectSize() > 1 && objectSize == 1) { // for a case like float f = 1.2 + vec4(2, 3, 4, 5); leftArray = Vectorize(*getUnionArrayPointer(), rightNode->getType().getObjectSize()); objectSize = rightNode->getType().getObjectSize(); } TConstantUnion *resultArray = nullptr; switch (op) { case EOpAdd: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = TConstantUnion::add(leftArray[i], rightArray[i], diagnostics, line); break; case EOpSub: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = TConstantUnion::sub(leftArray[i], rightArray[i], diagnostics, line); break; case EOpMul: case EOpVectorTimesScalar: case EOpMatrixTimesScalar: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = TConstantUnion::mul(leftArray[i], rightArray[i], diagnostics, line); break; case EOpMatrixTimesMatrix: { // TODO(jmadll): This code should check for overflows. ASSERT(getType().getBasicType() == EbtFloat && rightNode->getBasicType() == EbtFloat); const int leftCols = getCols(); const int leftRows = getRows(); const int rightCols = rightNode->getType().getCols(); const int rightRows = rightNode->getType().getRows(); const int resultCols = rightCols; const int resultRows = leftRows; resultArray = new TConstantUnion[resultCols * resultRows]; for (int row = 0; row < resultRows; row++) { for (int column = 0; column < resultCols; column++) { resultArray[resultRows * column + row].setFConst(0.0f); for (int i = 0; i < leftCols; i++) { resultArray[resultRows * column + row].setFConst( resultArray[resultRows * column + row].getFConst() + leftArray[i * leftRows + row].getFConst() * rightArray[column * rightRows + i].getFConst()); } } } } break; case EOpDiv: case EOpIMod: { resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) { switch (getType().getBasicType()) { case EbtFloat: { ASSERT(op == EOpDiv); float dividend = leftArray[i].getFConst(); float divisor = rightArray[i].getFConst(); if (divisor == 0.0f) { if (dividend == 0.0f) { diagnostics->warning( getLine(), "Zero divided by zero during constant folding generated NaN", "/"); resultArray[i].setFConst(std::numeric_limits<float>::quiet_NaN()); } else { diagnostics->warning(getLine(), "Divide by zero during constant folding", "/"); bool negativeResult = std::signbit(dividend) != std::signbit(divisor); resultArray[i].setFConst( negativeResult ? -std::numeric_limits<float>::infinity() : std::numeric_limits<float>::infinity()); } } else if (gl::isInf(dividend) && gl::isInf(divisor)) { diagnostics->warning(getLine(), "Infinity divided by infinity during constant " "folding generated NaN", "/"); resultArray[i].setFConst(std::numeric_limits<float>::quiet_NaN()); } else { float result = dividend / divisor; if (!gl::isInf(dividend) && gl::isInf(result)) { diagnostics->warning( getLine(), "Constant folded division overflowed to infinity", "/"); } resultArray[i].setFConst(result); } break; } case EbtInt: if (rightArray[i] == 0) { diagnostics->warning( getLine(), "Divide by zero error during constant folding", "/"); resultArray[i].setIConst(INT_MAX); } else { int lhs = leftArray[i].getIConst(); int divisor = rightArray[i].getIConst(); if (op == EOpDiv) { // Check for the special case where the minimum representable number // is // divided by -1. If left alone this leads to integer overflow in // C++. // ESSL 3.00.6 section 4.1.3 Integers: // "However, for the case where the minimum representable value is // divided by -1, it is allowed to return either the minimum // representable value or the maximum representable value." if (lhs == -0x7fffffff - 1 && divisor == -1) { resultArray[i].setIConst(0x7fffffff); } else { resultArray[i].setIConst(lhs / divisor); } } else { ASSERT(op == EOpIMod); if (lhs < 0 || divisor < 0) { // ESSL 3.00.6 section 5.9: Results of modulus are undefined // when // either one of the operands is negative. diagnostics->warning(getLine(), "Negative modulus operator operand " "encountered during constant folding", "%"); resultArray[i].setIConst(0); } else { resultArray[i].setIConst(lhs % divisor); } } } break; case EbtUInt: if (rightArray[i] == 0) { diagnostics->warning( getLine(), "Divide by zero error during constant folding", "/"); resultArray[i].setUConst(UINT_MAX); } else { if (op == EOpDiv) { resultArray[i].setUConst(leftArray[i].getUConst() / rightArray[i].getUConst()); } else { ASSERT(op == EOpIMod); resultArray[i].setUConst(leftArray[i].getUConst() % rightArray[i].getUConst()); } } break; default: UNREACHABLE(); return nullptr; } } } break; case EOpMatrixTimesVector: { // TODO(jmadll): This code should check for overflows. ASSERT(rightNode->getBasicType() == EbtFloat); const int matrixCols = getCols(); const int matrixRows = getRows(); resultArray = new TConstantUnion[matrixRows]; for (int matrixRow = 0; matrixRow < matrixRows; matrixRow++) { resultArray[matrixRow].setFConst(0.0f); for (int col = 0; col < matrixCols; col++) { resultArray[matrixRow].setFConst( resultArray[matrixRow].getFConst() + leftArray[col * matrixRows + matrixRow].getFConst() * rightArray[col].getFConst()); } } } break; case EOpVectorTimesMatrix: { // TODO(jmadll): This code should check for overflows. ASSERT(getType().getBasicType() == EbtFloat); const int matrixCols = rightNode->getType().getCols(); const int matrixRows = rightNode->getType().getRows(); resultArray = new TConstantUnion[matrixCols]; for (int matrixCol = 0; matrixCol < matrixCols; matrixCol++) { resultArray[matrixCol].setFConst(0.0f); for (int matrixRow = 0; matrixRow < matrixRows; matrixRow++) { resultArray[matrixCol].setFConst( resultArray[matrixCol].getFConst() + leftArray[matrixRow].getFConst() * rightArray[matrixCol * matrixRows + matrixRow].getFConst()); } } } break; case EOpLogicalAnd: { resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) { resultArray[i] = leftArray[i] && rightArray[i]; } } break; case EOpLogicalOr: { resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) { resultArray[i] = leftArray[i] || rightArray[i]; } } break; case EOpLogicalXor: { ASSERT(getType().getBasicType() == EbtBool); resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) { resultArray[i].setBConst(leftArray[i] != rightArray[i]); } } break; case EOpBitwiseAnd: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = leftArray[i] & rightArray[i]; break; case EOpBitwiseXor: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = leftArray[i] ^ rightArray[i]; break; case EOpBitwiseOr: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = leftArray[i] | rightArray[i]; break; case EOpBitShiftLeft: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = TConstantUnion::lshift(leftArray[i], rightArray[i], diagnostics, line); break; case EOpBitShiftRight: resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) resultArray[i] = TConstantUnion::rshift(leftArray[i], rightArray[i], diagnostics, line); break; case EOpLessThan: ASSERT(objectSize == 1); resultArray = new TConstantUnion[1]; resultArray->setBConst(*leftArray < *rightArray); break; case EOpGreaterThan: ASSERT(objectSize == 1); resultArray = new TConstantUnion[1]; resultArray->setBConst(*leftArray > *rightArray); break; case EOpLessThanEqual: ASSERT(objectSize == 1); resultArray = new TConstantUnion[1]; resultArray->setBConst(!(*leftArray > *rightArray)); break; case EOpGreaterThanEqual: ASSERT(objectSize == 1); resultArray = new TConstantUnion[1]; resultArray->setBConst(!(*leftArray < *rightArray)); break; case EOpEqual: case EOpNotEqual: { resultArray = new TConstantUnion[1]; bool equal = true; for (size_t i = 0; i < objectSize; i++) { if (leftArray[i] != rightArray[i]) { equal = false; break; // break out of for loop } } if (op == EOpEqual) { resultArray->setBConst(equal); } else { resultArray->setBConst(!equal); } } break; default: UNREACHABLE(); return nullptr; } return resultArray; } // The fold functions do operations on a constant at GLSL compile time, without generating run-time // code. Returns the constant value to keep using. Nullptr should not be returned. TConstantUnion *TIntermConstantUnion::foldUnaryNonComponentWise(TOperator op) { // Do operations where the return type may have a different number of components compared to the // operand type. const TConstantUnion *operandArray = getUnionArrayPointer(); ASSERT(operandArray); size_t objectSize = getType().getObjectSize(); TConstantUnion *resultArray = nullptr; switch (op) { case EOpAny: ASSERT(getType().getBasicType() == EbtBool); resultArray = new TConstantUnion(); resultArray->setBConst(false); for (size_t i = 0; i < objectSize; i++) { if (operandArray[i].getBConst()) { resultArray->setBConst(true); break; } } break; case EOpAll: ASSERT(getType().getBasicType() == EbtBool); resultArray = new TConstantUnion(); resultArray->setBConst(true); for (size_t i = 0; i < objectSize; i++) { if (!operandArray[i].getBConst()) { resultArray->setBConst(false); break; } } break; case EOpLength: ASSERT(getType().getBasicType() == EbtFloat); resultArray = new TConstantUnion(); resultArray->setFConst(VectorLength(operandArray, objectSize)); break; case EOpTranspose: { ASSERT(getType().getBasicType() == EbtFloat); resultArray = new TConstantUnion[objectSize]; angle::Matrix<float> result = GetMatrix(operandArray, getType().getRows(), getType().getCols()).transpose(); SetUnionArrayFromMatrix(result, resultArray); break; } case EOpDeterminant: { ASSERT(getType().getBasicType() == EbtFloat); unsigned int size = getType().getNominalSize(); ASSERT(size >= 2 && size <= 4); resultArray = new TConstantUnion(); resultArray->setFConst(GetMatrix(operandArray, size).determinant()); break; } case EOpInverse: { ASSERT(getType().getBasicType() == EbtFloat); unsigned int size = getType().getNominalSize(); ASSERT(size >= 2 && size <= 4); resultArray = new TConstantUnion[objectSize]; angle::Matrix<float> result = GetMatrix(operandArray, size).inverse(); SetUnionArrayFromMatrix(result, resultArray); break; } case EOpPackSnorm2x16: ASSERT(getType().getBasicType() == EbtFloat); ASSERT(getType().getNominalSize() == 2); resultArray = new TConstantUnion(); resultArray->setUConst( gl::packSnorm2x16(operandArray[0].getFConst(), operandArray[1].getFConst())); break; case EOpUnpackSnorm2x16: { ASSERT(getType().getBasicType() == EbtUInt); resultArray = new TConstantUnion[2]; float f1, f2; gl::unpackSnorm2x16(operandArray[0].getUConst(), &f1, &f2); resultArray[0].setFConst(f1); resultArray[1].setFConst(f2); break; } case EOpPackUnorm2x16: ASSERT(getType().getBasicType() == EbtFloat); ASSERT(getType().getNominalSize() == 2); resultArray = new TConstantUnion(); resultArray->setUConst( gl::packUnorm2x16(operandArray[0].getFConst(), operandArray[1].getFConst())); break; case EOpUnpackUnorm2x16: { ASSERT(getType().getBasicType() == EbtUInt); resultArray = new TConstantUnion[2]; float f1, f2; gl::unpackUnorm2x16(operandArray[0].getUConst(), &f1, &f2); resultArray[0].setFConst(f1); resultArray[1].setFConst(f2); break; } case EOpPackHalf2x16: ASSERT(getType().getBasicType() == EbtFloat); ASSERT(getType().getNominalSize() == 2); resultArray = new TConstantUnion(); resultArray->setUConst( gl::packHalf2x16(operandArray[0].getFConst(), operandArray[1].getFConst())); break; case EOpUnpackHalf2x16: { ASSERT(getType().getBasicType() == EbtUInt); resultArray = new TConstantUnion[2]; float f1, f2; gl::unpackHalf2x16(operandArray[0].getUConst(), &f1, &f2); resultArray[0].setFConst(f1); resultArray[1].setFConst(f2); break; } default: UNREACHABLE(); break; } return resultArray; } TConstantUnion *TIntermConstantUnion::foldUnaryComponentWise(TOperator op, TDiagnostics *diagnostics) { // Do unary operations where each component of the result is computed based on the corresponding // component of the operand. Also folds normalize, though the divisor in that case takes all // components into account. const TConstantUnion *operandArray = getUnionArrayPointer(); ASSERT(operandArray); size_t objectSize = getType().getObjectSize(); TConstantUnion *resultArray = new TConstantUnion[objectSize]; for (size_t i = 0; i < objectSize; i++) { switch (op) { case EOpNegative: switch (getType().getBasicType()) { case EbtFloat: resultArray[i].setFConst(-operandArray[i].getFConst()); break; case EbtInt: if (operandArray[i] == std::numeric_limits<int>::min()) { // The minimum representable integer doesn't have a positive // counterpart, rather the negation overflows and in ESSL is supposed to // wrap back to the minimum representable integer. Make sure that we // don't actually let the negation overflow, which has undefined // behavior in C++. resultArray[i].setIConst(std::numeric_limits<int>::min()); } else { resultArray[i].setIConst(-operandArray[i].getIConst()); } break; case EbtUInt: if (operandArray[i] == 0x80000000u) { resultArray[i].setUConst(0x80000000u); } else { resultArray[i].setUConst(static_cast<unsigned int>( -static_cast<int>(operandArray[i].getUConst()))); } break; default: UNREACHABLE(); return nullptr; } break; case EOpPositive: switch (getType().getBasicType()) { case EbtFloat: resultArray[i].setFConst(operandArray[i].getFConst()); break; case EbtInt: resultArray[i].setIConst(operandArray[i].getIConst()); break; case EbtUInt: resultArray[i].setUConst(static_cast<unsigned int>( static_cast<int>(operandArray[i].getUConst()))); break; default: UNREACHABLE(); return nullptr; } break; case EOpLogicalNot: switch (getType().getBasicType()) { case EbtBool: resultArray[i].setBConst(!operandArray[i].getBConst()); break; default: UNREACHABLE(); return nullptr; } break; case EOpBitwiseNot: switch (getType().getBasicType()) { case EbtInt: resultArray[i].setIConst(~operandArray[i].getIConst()); break; case EbtUInt: resultArray[i].setUConst(~operandArray[i].getUConst()); break; default: UNREACHABLE(); return nullptr; } break; case EOpRadians: ASSERT(getType().getBasicType() == EbtFloat); resultArray[i].setFConst(kDegreesToRadiansMultiplier * operandArray[i].getFConst()); break; case EOpDegrees: ASSERT(getType().getBasicType() == EbtFloat); resultArray[i].setFConst(kRadiansToDegreesMultiplier * operandArray[i].getFConst()); break; case EOpSin: foldFloatTypeUnary(operandArray[i], &sinf, &resultArray[i]); break; case EOpCos: foldFloatTypeUnary(operandArray[i], &cosf, &resultArray[i]); break; case EOpTan: foldFloatTypeUnary(operandArray[i], &tanf, &resultArray[i]); break; case EOpAsin: // For asin(x), results are undefined if |x| > 1, we are choosing to set result to // 0. if (fabsf(operandArray[i].getFConst()) > 1.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else foldFloatTypeUnary(operandArray[i], &asinf, &resultArray[i]); break; case EOpAcos: // For acos(x), results are undefined if |x| > 1, we are choosing to set result to // 0. if (fabsf(operandArray[i].getFConst()) > 1.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else foldFloatTypeUnary(operandArray[i], &acosf, &resultArray[i]); break; case EOpAtan: foldFloatTypeUnary(operandArray[i], &atanf, &resultArray[i]); break; case EOpSinh: foldFloatTypeUnary(operandArray[i], &sinhf, &resultArray[i]); break; case EOpCosh: foldFloatTypeUnary(operandArray[i], &coshf, &resultArray[i]); break; case EOpTanh: foldFloatTypeUnary(operandArray[i], &tanhf, &resultArray[i]); break; case EOpAsinh: foldFloatTypeUnary(operandArray[i], &asinhf, &resultArray[i]); break; case EOpAcosh: // For acosh(x), results are undefined if x < 1, we are choosing to set result to 0. if (operandArray[i].getFConst() < 1.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else foldFloatTypeUnary(operandArray[i], &acoshf, &resultArray[i]); break; case EOpAtanh: // For atanh(x), results are undefined if |x| >= 1, we are choosing to set result to // 0. if (fabsf(operandArray[i].getFConst()) >= 1.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else foldFloatTypeUnary(operandArray[i], &atanhf, &resultArray[i]); break; case EOpAbs: switch (getType().getBasicType()) { case EbtFloat: resultArray[i].setFConst(fabsf(operandArray[i].getFConst())); break; case EbtInt: resultArray[i].setIConst(abs(operandArray[i].getIConst())); break; default: UNREACHABLE(); return nullptr; } break; case EOpSign: switch (getType().getBasicType()) { case EbtFloat: { float fConst = operandArray[i].getFConst(); float fResult = 0.0f; if (fConst > 0.0f) fResult = 1.0f; else if (fConst < 0.0f) fResult = -1.0f; resultArray[i].setFConst(fResult); break; } case EbtInt: { int iConst = operandArray[i].getIConst(); int iResult = 0; if (iConst > 0) iResult = 1; else if (iConst < 0) iResult = -1; resultArray[i].setIConst(iResult); break; } default: UNREACHABLE(); return nullptr; } break; case EOpFloor: foldFloatTypeUnary(operandArray[i], &floorf, &resultArray[i]); break; case EOpTrunc: foldFloatTypeUnary(operandArray[i], &truncf, &resultArray[i]); break; case EOpRound: foldFloatTypeUnary(operandArray[i], &roundf, &resultArray[i]); break; case EOpRoundEven: { ASSERT(getType().getBasicType() == EbtFloat); float x = operandArray[i].getFConst(); float result; float fractPart = modff(x, &result); if (fabsf(fractPart) == 0.5f) result = 2.0f * roundf(x / 2.0f); else result = roundf(x); resultArray[i].setFConst(result); break; } case EOpCeil: foldFloatTypeUnary(operandArray[i], &ceilf, &resultArray[i]); break; case EOpFract: { ASSERT(getType().getBasicType() == EbtFloat); float x = operandArray[i].getFConst(); resultArray[i].setFConst(x - floorf(x)); break; } case EOpIsNan: ASSERT(getType().getBasicType() == EbtFloat); resultArray[i].setBConst(gl::isNaN(operandArray[0].getFConst())); break; case EOpIsInf: ASSERT(getType().getBasicType() == EbtFloat); resultArray[i].setBConst(gl::isInf(operandArray[0].getFConst())); break; case EOpFloatBitsToInt: ASSERT(getType().getBasicType() == EbtFloat); resultArray[i].setIConst(gl::bitCast<int32_t>(operandArray[0].getFConst())); break; case EOpFloatBitsToUint: ASSERT(getType().getBasicType() == EbtFloat); resultArray[i].setUConst(gl::bitCast<uint32_t>(operandArray[0].getFConst())); break; case EOpIntBitsToFloat: ASSERT(getType().getBasicType() == EbtInt); resultArray[i].setFConst(gl::bitCast<float>(operandArray[0].getIConst())); break; case EOpUintBitsToFloat: ASSERT(getType().getBasicType() == EbtUInt); resultArray[i].setFConst(gl::bitCast<float>(operandArray[0].getUConst())); break; case EOpExp: foldFloatTypeUnary(operandArray[i], &expf, &resultArray[i]); break; case EOpLog: // For log(x), results are undefined if x <= 0, we are choosing to set result to 0. if (operandArray[i].getFConst() <= 0.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else foldFloatTypeUnary(operandArray[i], &logf, &resultArray[i]); break; case EOpExp2: foldFloatTypeUnary(operandArray[i], &exp2f, &resultArray[i]); break; case EOpLog2: // For log2(x), results are undefined if x <= 0, we are choosing to set result to 0. // And log2f is not available on some plarforms like old android, so just using // log(x)/log(2) here. if (operandArray[i].getFConst() <= 0.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else { foldFloatTypeUnary(operandArray[i], &logf, &resultArray[i]); resultArray[i].setFConst(resultArray[i].getFConst() / logf(2.0f)); } break; case EOpSqrt: // For sqrt(x), results are undefined if x < 0, we are choosing to set result to 0. if (operandArray[i].getFConst() < 0.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else foldFloatTypeUnary(operandArray[i], &sqrtf, &resultArray[i]); break; case EOpInverseSqrt: // There is no stdlib built-in function equavalent for GLES built-in inversesqrt(), // so getting the square root first using builtin function sqrt() and then taking // its inverse. // Also, for inversesqrt(x), results are undefined if x <= 0, we are choosing to set // result to 0. if (operandArray[i].getFConst() <= 0.0f) UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); else { foldFloatTypeUnary(operandArray[i], &sqrtf, &resultArray[i]); resultArray[i].setFConst(1.0f / resultArray[i].getFConst()); } break; case EOpLogicalNotComponentWise: ASSERT(getType().getBasicType() == EbtBool); resultArray[i].setBConst(!operandArray[i].getBConst()); break; case EOpNormalize: { ASSERT(getType().getBasicType() == EbtFloat); float x = operandArray[i].getFConst(); float length = VectorLength(operandArray, objectSize); if (length) resultArray[i].setFConst(x / length); else UndefinedConstantFoldingError(getLine(), op, getType().getBasicType(), diagnostics, &resultArray[i]); break; } case EOpDFdx: case EOpDFdy: case EOpFwidth: ASSERT(getType().getBasicType() == EbtFloat); // Derivatives of constant arguments should be 0. resultArray[i].setFConst(0.0f); break; default: return nullptr; } } return resultArray; } void TIntermConstantUnion::foldFloatTypeUnary(const TConstantUnion ¶meter, FloatTypeUnaryFunc builtinFunc, TConstantUnion *result) const { ASSERT(builtinFunc); ASSERT(getType().getBasicType() == EbtFloat); result->setFConst(builtinFunc(parameter.getFConst())); } // static TConstantUnion *TIntermConstantUnion::FoldAggregateConstructor(TIntermAggregate *aggregate) { ASSERT(aggregate->getSequence()->size() > 0u); size_t resultSize = aggregate->getType().getObjectSize(); TConstantUnion *resultArray = new TConstantUnion[resultSize]; TBasicType basicType = aggregate->getBasicType(); size_t resultIndex = 0u; if (aggregate->getSequence()->size() == 1u) { TIntermNode *argument = aggregate->getSequence()->front(); TIntermConstantUnion *argumentConstant = argument->getAsConstantUnion(); const TConstantUnion *argumentUnionArray = argumentConstant->getUnionArrayPointer(); // Check the special case of constructing a matrix diagonal from a single scalar, // or a vector from a single scalar. if (argumentConstant->getType().getObjectSize() == 1u) { if (aggregate->isMatrix()) { int resultCols = aggregate->getType().getCols(); int resultRows = aggregate->getType().getRows(); for (int col = 0; col < resultCols; ++col) { for (int row = 0; row < resultRows; ++row) { if (col == row) { resultArray[resultIndex].cast(basicType, argumentUnionArray[0]); } else { resultArray[resultIndex].setFConst(0.0f); } ++resultIndex; } } } else { while (resultIndex < resultSize) { resultArray[resultIndex].cast(basicType, argumentUnionArray[0]); ++resultIndex; } } ASSERT(resultIndex == resultSize); return resultArray; } else if (aggregate->isMatrix() && argumentConstant->isMatrix()) { // The special case of constructing a matrix from a matrix. int argumentCols = argumentConstant->getType().getCols(); int argumentRows = argumentConstant->getType().getRows(); int resultCols = aggregate->getType().getCols(); int resultRows = aggregate->getType().getRows(); for (int col = 0; col < resultCols; ++col) { for (int row = 0; row < resultRows; ++row) { if (col < argumentCols && row < argumentRows) { resultArray[resultIndex].cast(basicType, argumentUnionArray[col * argumentRows + row]); } else if (col == row) { resultArray[resultIndex].setFConst(1.0f); } else { resultArray[resultIndex].setFConst(0.0f); } ++resultIndex; } } ASSERT(resultIndex == resultSize); return resultArray; } } for (TIntermNode *&argument : *aggregate->getSequence()) { TIntermConstantUnion *argumentConstant = argument->getAsConstantUnion(); size_t argumentSize = argumentConstant->getType().getObjectSize(); const TConstantUnion *argumentUnionArray = argumentConstant->getUnionArrayPointer(); for (size_t i = 0u; i < argumentSize; ++i) { if (resultIndex >= resultSize) break; resultArray[resultIndex].cast(basicType, argumentUnionArray[i]); ++resultIndex; } } ASSERT(resultIndex == resultSize); return resultArray; } // static TConstantUnion *TIntermConstantUnion::FoldAggregateBuiltIn(TIntermAggregate *aggregate, TDiagnostics *diagnostics) { TOperator op = aggregate->getOp(); TIntermSequence *sequence = aggregate->getSequence(); unsigned int paramsCount = static_cast<unsigned int>(sequence->size()); std::vector<const TConstantUnion *> unionArrays(paramsCount); std::vector<size_t> objectSizes(paramsCount); size_t maxObjectSize = 0; TBasicType basicType = EbtVoid; TSourceLoc loc; for (unsigned int i = 0; i < paramsCount; i++) { TIntermConstantUnion *paramConstant = (*sequence)[i]->getAsConstantUnion(); ASSERT(paramConstant != nullptr); // Should be checked already. if (i == 0) { basicType = paramConstant->getType().getBasicType(); loc = paramConstant->getLine(); } unionArrays[i] = paramConstant->getUnionArrayPointer(); objectSizes[i] = paramConstant->getType().getObjectSize(); if (objectSizes[i] > maxObjectSize) maxObjectSize = objectSizes[i]; } if (!(*sequence)[0]->getAsTyped()->isMatrix() && aggregate->getOp() != EOpOuterProduct) { for (unsigned int i = 0; i < paramsCount; i++) if (objectSizes[i] != maxObjectSize) unionArrays[i] = Vectorize(*unionArrays[i], maxObjectSize); } TConstantUnion *resultArray = nullptr; if (paramsCount == 2) { // // Binary built-in // switch (op) { case EOpAtan: { ASSERT(basicType == EbtFloat); resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { float y = unionArrays[0][i].getFConst(); float x = unionArrays[1][i].getFConst(); // Results are undefined if x and y are both 0. if (x == 0.0f && y == 0.0f) UndefinedConstantFoldingError(loc, op, basicType, diagnostics, &resultArray[i]); else resultArray[i].setFConst(atan2f(y, x)); } break; } case EOpPow: { ASSERT(basicType == EbtFloat); resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { float x = unionArrays[0][i].getFConst(); float y = unionArrays[1][i].getFConst(); // Results are undefined if x < 0. // Results are undefined if x = 0 and y <= 0. if (x < 0.0f) UndefinedConstantFoldingError(loc, op, basicType, diagnostics, &resultArray[i]); else if (x == 0.0f && y <= 0.0f) UndefinedConstantFoldingError(loc, op, basicType, diagnostics, &resultArray[i]); else resultArray[i].setFConst(powf(x, y)); } break; } case EOpMod: { ASSERT(basicType == EbtFloat); resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { float x = unionArrays[0][i].getFConst(); float y = unionArrays[1][i].getFConst(); resultArray[i].setFConst(x - y * floorf(x / y)); } break; } case EOpMin: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setFConst(std::min(unionArrays[0][i].getFConst(), unionArrays[1][i].getFConst())); break; case EbtInt: resultArray[i].setIConst(std::min(unionArrays[0][i].getIConst(), unionArrays[1][i].getIConst())); break; case EbtUInt: resultArray[i].setUConst(std::min(unionArrays[0][i].getUConst(), unionArrays[1][i].getUConst())); break; default: UNREACHABLE(); break; } } break; } case EOpMax: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setFConst(std::max(unionArrays[0][i].getFConst(), unionArrays[1][i].getFConst())); break; case EbtInt: resultArray[i].setIConst(std::max(unionArrays[0][i].getIConst(), unionArrays[1][i].getIConst())); break; case EbtUInt: resultArray[i].setUConst(std::max(unionArrays[0][i].getUConst(), unionArrays[1][i].getUConst())); break; default: UNREACHABLE(); break; } } break; } case EOpStep: { ASSERT(basicType == EbtFloat); resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) resultArray[i].setFConst( unionArrays[1][i].getFConst() < unionArrays[0][i].getFConst() ? 0.0f : 1.0f); break; } case EOpLessThanComponentWise: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setBConst(unionArrays[0][i].getFConst() < unionArrays[1][i].getFConst()); break; case EbtInt: resultArray[i].setBConst(unionArrays[0][i].getIConst() < unionArrays[1][i].getIConst()); break; case EbtUInt: resultArray[i].setBConst(unionArrays[0][i].getUConst() < unionArrays[1][i].getUConst()); break; default: UNREACHABLE(); break; } } break; } case EOpLessThanEqualComponentWise: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setBConst(unionArrays[0][i].getFConst() <= unionArrays[1][i].getFConst()); break; case EbtInt: resultArray[i].setBConst(unionArrays[0][i].getIConst() <= unionArrays[1][i].getIConst()); break; case EbtUInt: resultArray[i].setBConst(unionArrays[0][i].getUConst() <= unionArrays[1][i].getUConst()); break; default: UNREACHABLE(); break; } } break; } case EOpGreaterThanComponentWise: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setBConst(unionArrays[0][i].getFConst() > unionArrays[1][i].getFConst()); break; case EbtInt: resultArray[i].setBConst(unionArrays[0][i].getIConst() > unionArrays[1][i].getIConst()); break; case EbtUInt: resultArray[i].setBConst(unionArrays[0][i].getUConst() > unionArrays[1][i].getUConst()); break; default: UNREACHABLE(); break; } } break; } case EOpGreaterThanEqualComponentWise: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setBConst(unionArrays[0][i].getFConst() >= unionArrays[1][i].getFConst()); break; case EbtInt: resultArray[i].setBConst(unionArrays[0][i].getIConst() >= unionArrays[1][i].getIConst()); break; case EbtUInt: resultArray[i].setBConst(unionArrays[0][i].getUConst() >= unionArrays[1][i].getUConst()); break; default: UNREACHABLE(); break; } } } break; case EOpEqualComponentWise: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setBConst(unionArrays[0][i].getFConst() == unionArrays[1][i].getFConst()); break; case EbtInt: resultArray[i].setBConst(unionArrays[0][i].getIConst() == unionArrays[1][i].getIConst()); break; case EbtUInt: resultArray[i].setBConst(unionArrays[0][i].getUConst() == unionArrays[1][i].getUConst()); break; case EbtBool: resultArray[i].setBConst(unionArrays[0][i].getBConst() == unionArrays[1][i].getBConst()); break; default: UNREACHABLE(); break; } } break; } case EOpNotEqualComponentWise: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: resultArray[i].setBConst(unionArrays[0][i].getFConst() != unionArrays[1][i].getFConst()); break; case EbtInt: resultArray[i].setBConst(unionArrays[0][i].getIConst() != unionArrays[1][i].getIConst()); break; case EbtUInt: resultArray[i].setBConst(unionArrays[0][i].getUConst() != unionArrays[1][i].getUConst()); break; case EbtBool: resultArray[i].setBConst(unionArrays[0][i].getBConst() != unionArrays[1][i].getBConst()); break; default: UNREACHABLE(); break; } } break; } case EOpDistance: { ASSERT(basicType == EbtFloat); TConstantUnion *distanceArray = new TConstantUnion[maxObjectSize]; resultArray = new TConstantUnion(); for (size_t i = 0; i < maxObjectSize; i++) { float x = unionArrays[0][i].getFConst(); float y = unionArrays[1][i].getFConst(); distanceArray[i].setFConst(x - y); } resultArray->setFConst(VectorLength(distanceArray, maxObjectSize)); break; } case EOpDot: ASSERT(basicType == EbtFloat); resultArray = new TConstantUnion(); resultArray->setFConst( VectorDotProduct(unionArrays[0], unionArrays[1], maxObjectSize)); break; case EOpCross: { ASSERT(basicType == EbtFloat && maxObjectSize == 3); resultArray = new TConstantUnion[maxObjectSize]; float x0 = unionArrays[0][0].getFConst(); float x1 = unionArrays[0][1].getFConst(); float x2 = unionArrays[0][2].getFConst(); float y0 = unionArrays[1][0].getFConst(); float y1 = unionArrays[1][1].getFConst(); float y2 = unionArrays[1][2].getFConst(); resultArray[0].setFConst(x1 * y2 - y1 * x2); resultArray[1].setFConst(x2 * y0 - y2 * x0); resultArray[2].setFConst(x0 * y1 - y0 * x1); break; } case EOpReflect: { ASSERT(basicType == EbtFloat); // genType reflect (genType I, genType N) : // For the incident vector I and surface orientation N, returns the reflection // direction: // I - 2 * dot(N, I) * N. resultArray = new TConstantUnion[maxObjectSize]; float dotProduct = VectorDotProduct(unionArrays[1], unionArrays[0], maxObjectSize); for (size_t i = 0; i < maxObjectSize; i++) { float result = unionArrays[0][i].getFConst() - 2.0f * dotProduct * unionArrays[1][i].getFConst(); resultArray[i].setFConst(result); } break; } case EOpMulMatrixComponentWise: { ASSERT(basicType == EbtFloat && (*sequence)[0]->getAsTyped()->isMatrix() && (*sequence)[1]->getAsTyped()->isMatrix()); // Perform component-wise matrix multiplication. resultArray = new TConstantUnion[maxObjectSize]; int size = (*sequence)[0]->getAsTyped()->getNominalSize(); angle::Matrix<float> result = GetMatrix(unionArrays[0], size).compMult(GetMatrix(unionArrays[1], size)); SetUnionArrayFromMatrix(result, resultArray); break; } case EOpOuterProduct: { ASSERT(basicType == EbtFloat); size_t numRows = (*sequence)[0]->getAsTyped()->getType().getObjectSize(); size_t numCols = (*sequence)[1]->getAsTyped()->getType().getObjectSize(); resultArray = new TConstantUnion[numRows * numCols]; angle::Matrix<float> result = GetMatrix(unionArrays[0], static_cast<int>(numRows), 1) .outerProduct(GetMatrix(unionArrays[1], 1, static_cast<int>(numCols))); SetUnionArrayFromMatrix(result, resultArray); break; } default: UNREACHABLE(); // TODO: Add constant folding support for other built-in operations that take 2 // parameters and not handled above. return nullptr; } } else if (paramsCount == 3) { // // Ternary built-in // switch (op) { case EOpClamp: { resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { switch (basicType) { case EbtFloat: { float x = unionArrays[0][i].getFConst(); float min = unionArrays[1][i].getFConst(); float max = unionArrays[2][i].getFConst(); // Results are undefined if min > max. if (min > max) UndefinedConstantFoldingError(loc, op, basicType, diagnostics, &resultArray[i]); else resultArray[i].setFConst(gl::clamp(x, min, max)); break; } case EbtInt: { int x = unionArrays[0][i].getIConst(); int min = unionArrays[1][i].getIConst(); int max = unionArrays[2][i].getIConst(); // Results are undefined if min > max. if (min > max) UndefinedConstantFoldingError(loc, op, basicType, diagnostics, &resultArray[i]); else resultArray[i].setIConst(gl::clamp(x, min, max)); break; } case EbtUInt: { unsigned int x = unionArrays[0][i].getUConst(); unsigned int min = unionArrays[1][i].getUConst(); unsigned int max = unionArrays[2][i].getUConst(); // Results are undefined if min > max. if (min > max) UndefinedConstantFoldingError(loc, op, basicType, diagnostics, &resultArray[i]); else resultArray[i].setUConst(gl::clamp(x, min, max)); break; } default: UNREACHABLE(); break; } } break; } case EOpMix: { ASSERT(basicType == EbtFloat); resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { float x = unionArrays[0][i].getFConst(); float y = unionArrays[1][i].getFConst(); TBasicType type = (*sequence)[2]->getAsTyped()->getType().getBasicType(); if (type == EbtFloat) { // Returns the linear blend of x and y, i.e., x * (1 - a) + y * a. float a = unionArrays[2][i].getFConst(); resultArray[i].setFConst(x * (1.0f - a) + y * a); } else // 3rd parameter is EbtBool { ASSERT(type == EbtBool); // Selects which vector each returned component comes from. // For a component of a that is false, the corresponding component of x is // returned. // For a component of a that is true, the corresponding component of y is // returned. bool a = unionArrays[2][i].getBConst(); resultArray[i].setFConst(a ? y : x); } } break; } case EOpSmoothStep: { ASSERT(basicType == EbtFloat); resultArray = new TConstantUnion[maxObjectSize]; for (size_t i = 0; i < maxObjectSize; i++) { float edge0 = unionArrays[0][i].getFConst(); float edge1 = unionArrays[1][i].getFConst(); float x = unionArrays[2][i].getFConst(); // Results are undefined if edge0 >= edge1. if (edge0 >= edge1) { UndefinedConstantFoldingError(loc, op, basicType, diagnostics, &resultArray[i]); } else { // Returns 0.0 if x <= edge0 and 1.0 if x >= edge1 and performs smooth // Hermite interpolation between 0 and 1 when edge0 < x < edge1. float t = gl::clamp((x - edge0) / (edge1 - edge0), 0.0f, 1.0f); resultArray[i].setFConst(t * t * (3.0f - 2.0f * t)); } } break; } case EOpFaceForward: { ASSERT(basicType == EbtFloat); // genType faceforward(genType N, genType I, genType Nref) : // If dot(Nref, I) < 0 return N, otherwise return -N. resultArray = new TConstantUnion[maxObjectSize]; float dotProduct = VectorDotProduct(unionArrays[2], unionArrays[1], maxObjectSize); for (size_t i = 0; i < maxObjectSize; i++) { if (dotProduct < 0) resultArray[i].setFConst(unionArrays[0][i].getFConst()); else resultArray[i].setFConst(-unionArrays[0][i].getFConst()); } break; } case EOpRefract: { ASSERT(basicType == EbtFloat); // genType refract(genType I, genType N, float eta) : // For the incident vector I and surface normal N, and the ratio of indices of // refraction eta, // return the refraction vector. The result is computed by // k = 1.0 - eta * eta * (1.0 - dot(N, I) * dot(N, I)) // if (k < 0.0) // return genType(0.0) // else // return eta * I - (eta * dot(N, I) + sqrt(k)) * N resultArray = new TConstantUnion[maxObjectSize]; float dotProduct = VectorDotProduct(unionArrays[1], unionArrays[0], maxObjectSize); for (size_t i = 0; i < maxObjectSize; i++) { float eta = unionArrays[2][i].getFConst(); float k = 1.0f - eta * eta * (1.0f - dotProduct * dotProduct); if (k < 0.0f) resultArray[i].setFConst(0.0f); else resultArray[i].setFConst(eta * unionArrays[0][i].getFConst() - (eta * dotProduct + sqrtf(k)) * unionArrays[1][i].getFConst()); } break; } default: UNREACHABLE(); // TODO: Add constant folding support for other built-in operations that take 3 // parameters and not handled above. return nullptr; } } return resultArray; } // static TString TIntermTraverser::hash(const TString &name, ShHashFunction64 hashFunction) { if (hashFunction == NULL || name.empty()) return name; khronos_uint64_t number = (*hashFunction)(name.c_str(), name.length()); TStringStream stream; stream << HASHED_NAME_PREFIX << std::hex << number; TString hashedName = stream.str(); return hashedName; } void TIntermTraverser::updateTree() { for (size_t ii = 0; ii < mInsertions.size(); ++ii) { const NodeInsertMultipleEntry &insertion = mInsertions[ii]; ASSERT(insertion.parent); if (!insertion.insertionsAfter.empty()) { bool inserted = insertion.parent->insertChildNodes(insertion.position + 1, insertion.insertionsAfter); ASSERT(inserted); } if (!insertion.insertionsBefore.empty()) { bool inserted = insertion.parent->insertChildNodes(insertion.position, insertion.insertionsBefore); ASSERT(inserted); } } for (size_t ii = 0; ii < mReplacements.size(); ++ii) { const NodeUpdateEntry &replacement = mReplacements[ii]; ASSERT(replacement.parent); bool replaced = replacement.parent->replaceChildNode(replacement.original, replacement.replacement); ASSERT(replaced); if (!replacement.originalBecomesChildOfReplacement) { // In AST traversing, a parent is visited before its children. // After we replace a node, if its immediate child is to // be replaced, we need to make sure we don't update the replaced // node; instead, we update the replacement node. for (size_t jj = ii + 1; jj < mReplacements.size(); ++jj) { NodeUpdateEntry &replacement2 = mReplacements[jj]; if (replacement2.parent == replacement.original) replacement2.parent = replacement.replacement; } } } for (size_t ii = 0; ii < mMultiReplacements.size(); ++ii) { const NodeReplaceWithMultipleEntry &replacement = mMultiReplacements[ii]; ASSERT(replacement.parent); bool replaced = replacement.parent->replaceChildNodeWithMultiple(replacement.original, replacement.replacements); ASSERT(replaced); } clearReplacementQueue(); } void TIntermTraverser::clearReplacementQueue() { mReplacements.clear(); mMultiReplacements.clear(); mInsertions.clear(); } void TIntermTraverser::queueReplacement(TIntermNode *original, TIntermNode *replacement, OriginalNode originalStatus) { queueReplacementWithParent(getParentNode(), original, replacement, originalStatus); } void TIntermTraverser::queueReplacementWithParent(TIntermNode *parent, TIntermNode *original, TIntermNode *replacement, OriginalNode originalStatus) { bool originalBecomesChild = (originalStatus == OriginalNode::BECOMES_CHILD); mReplacements.push_back(NodeUpdateEntry(parent, original, replacement, originalBecomesChild)); } } // namespace sh