// Copyright (c) 2018 Google LLC // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "source/opt/const_folding_rules.h" #include "source/opt/ir_context.h" namespace spvtools { namespace opt { namespace { constexpr uint32_t kExtractCompositeIdInIdx = 0; // Returns a constants with the value NaN of the given type. Only works for // 32-bit and 64-bit float point types. Returns |nullptr| if an error occurs. const analysis::Constant* GetNan(const analysis::Type* type, analysis::ConstantManager* const_mgr) { const analysis::Float* float_type = type->AsFloat(); if (float_type == nullptr) { return nullptr; } switch (float_type->width()) { case 32: return const_mgr->GetFloatConst(std::numeric_limits::quiet_NaN()); case 64: return const_mgr->GetDoubleConst( std::numeric_limits::quiet_NaN()); default: return nullptr; } } // Returns a constants with the value INF of the given type. Only works for // 32-bit and 64-bit float point types. Returns |nullptr| if an error occurs. const analysis::Constant* GetInf(const analysis::Type* type, analysis::ConstantManager* const_mgr) { const analysis::Float* float_type = type->AsFloat(); if (float_type == nullptr) { return nullptr; } switch (float_type->width()) { case 32: return const_mgr->GetFloatConst(std::numeric_limits::infinity()); case 64: return const_mgr->GetDoubleConst(std::numeric_limits::infinity()); default: return nullptr; } } // Returns true if |type| is Float or a vector of Float. bool HasFloatingPoint(const analysis::Type* type) { if (type->AsFloat()) { return true; } else if (const analysis::Vector* vec_type = type->AsVector()) { return vec_type->element_type()->AsFloat() != nullptr; } return false; } // Returns a constants with the value |-val| of the given type. Only works for // 32-bit and 64-bit float point types. Returns |nullptr| if an error occurs. const analysis::Constant* NegateFPConst(const analysis::Type* result_type, const analysis::Constant* val, analysis::ConstantManager* const_mgr) { const analysis::Float* float_type = result_type->AsFloat(); assert(float_type != nullptr); if (float_type->width() == 32) { float fa = val->GetFloat(); return const_mgr->GetFloatConst(-fa); } else if (float_type->width() == 64) { double da = val->GetDouble(); return const_mgr->GetDoubleConst(-da); } return nullptr; } // Folds an OpcompositeExtract where input is a composite constant. ConstantFoldingRule FoldExtractWithConstants() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { const analysis::Constant* c = constants[kExtractCompositeIdInIdx]; if (c == nullptr) { return nullptr; } for (uint32_t i = 1; i < inst->NumInOperands(); ++i) { uint32_t element_index = inst->GetSingleWordInOperand(i); if (c->AsNullConstant()) { // Return Null for the return type. analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); return const_mgr->GetConstant(type_mgr->GetType(inst->type_id()), {}); } auto cc = c->AsCompositeConstant(); assert(cc != nullptr); auto components = cc->GetComponents(); // Protect against invalid IR. Refuse to fold if the index is out // of bounds. if (element_index >= components.size()) return nullptr; c = components[element_index]; } return c; }; } // Folds an OpcompositeInsert where input is a composite constant. ConstantFoldingRule FoldInsertWithConstants() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { analysis::ConstantManager* const_mgr = context->get_constant_mgr(); const analysis::Constant* object = constants[0]; const analysis::Constant* composite = constants[1]; if (object == nullptr || composite == nullptr) { return nullptr; } // If there is more than 1 index, then each additional constant used by the // index will need to be recreated to use the inserted object. std::vector chain; std::vector components; const analysis::Type* type = nullptr; const uint32_t final_index = (inst->NumInOperands() - 1); // Work down hierarchy of all indexes for (uint32_t i = 2; i < inst->NumInOperands(); ++i) { type = composite->type(); if (composite->AsNullConstant()) { // Make new composite so it can be inserted in the index with the // non-null value if (const auto new_composite = const_mgr->GetNullCompositeConstant(type)) { // Keep track of any indexes along the way to last index if (i != final_index) { chain.push_back(new_composite); } components = new_composite->AsCompositeConstant()->GetComponents(); } else { // Unsupported input type (such as structs) return nullptr; } } else { // Keep track of any indexes along the way to last index if (i != final_index) { chain.push_back(composite); } components = composite->AsCompositeConstant()->GetComponents(); } const uint32_t index = inst->GetSingleWordInOperand(i); composite = components[index]; } // Final index in hierarchy is inserted with new object. const uint32_t final_operand = inst->GetSingleWordInOperand(final_index); std::vector ids; for (size_t i = 0; i < components.size(); i++) { const analysis::Constant* constant = (i == final_operand) ? object : components[i]; Instruction* member_inst = const_mgr->GetDefiningInstruction(constant); ids.push_back(member_inst->result_id()); } const analysis::Constant* new_constant = const_mgr->GetConstant(type, ids); // Work backwards up the chain and replace each index with new constant. for (size_t i = chain.size(); i > 0; i--) { // Need to insert any previous instruction into the module first. // Can't just insert in types_values_begin() because it will move above // where the types are declared. // Can't compare with location of inst because not all new added // instructions are added to types_values_ auto iter = context->types_values_end(); Module::inst_iterator* pos = &iter; const_mgr->BuildInstructionAndAddToModule(new_constant, pos); composite = chain[i - 1]; components = composite->AsCompositeConstant()->GetComponents(); type = composite->type(); ids.clear(); for (size_t k = 0; k < components.size(); k++) { const uint32_t index = inst->GetSingleWordInOperand(1 + static_cast(i)); const analysis::Constant* constant = (k == index) ? new_constant : components[k]; const uint32_t constant_id = const_mgr->FindDeclaredConstant(constant, 0); ids.push_back(constant_id); } new_constant = const_mgr->GetConstant(type, ids); } // If multiple constants were created, only need to return the top index. return new_constant; }; } ConstantFoldingRule FoldVectorShuffleWithConstants() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { assert(inst->opcode() == spv::Op::OpVectorShuffle); const analysis::Constant* c1 = constants[0]; const analysis::Constant* c2 = constants[1]; if (c1 == nullptr || c2 == nullptr) { return nullptr; } analysis::ConstantManager* const_mgr = context->get_constant_mgr(); const analysis::Type* element_type = c1->type()->AsVector()->element_type(); std::vector c1_components; if (const analysis::VectorConstant* vec_const = c1->AsVectorConstant()) { c1_components = vec_const->GetComponents(); } else { assert(c1->AsNullConstant()); const analysis::Constant* element = const_mgr->GetConstant(element_type, {}); c1_components.resize(c1->type()->AsVector()->element_count(), element); } std::vector c2_components; if (const analysis::VectorConstant* vec_const = c2->AsVectorConstant()) { c2_components = vec_const->GetComponents(); } else { assert(c2->AsNullConstant()); const analysis::Constant* element = const_mgr->GetConstant(element_type, {}); c2_components.resize(c2->type()->AsVector()->element_count(), element); } std::vector ids; const uint32_t undef_literal_value = 0xffffffff; for (uint32_t i = 2; i < inst->NumInOperands(); ++i) { uint32_t index = inst->GetSingleWordInOperand(i); if (index == undef_literal_value) { // Don't fold shuffle with undef literal value. return nullptr; } else if (index < c1_components.size()) { Instruction* member_inst = const_mgr->GetDefiningInstruction(c1_components[index]); ids.push_back(member_inst->result_id()); } else { Instruction* member_inst = const_mgr->GetDefiningInstruction( c2_components[index - c1_components.size()]); ids.push_back(member_inst->result_id()); } } analysis::TypeManager* type_mgr = context->get_type_mgr(); return const_mgr->GetConstant(type_mgr->GetType(inst->type_id()), ids); }; } ConstantFoldingRule FoldVectorTimesScalar() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { assert(inst->opcode() == spv::Op::OpVectorTimesScalar); analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); if (!inst->IsFloatingPointFoldingAllowed()) { if (HasFloatingPoint(type_mgr->GetType(inst->type_id()))) { return nullptr; } } const analysis::Constant* c1 = constants[0]; const analysis::Constant* c2 = constants[1]; if (c1 && c1->IsZero()) { return c1; } if (c2 && c2->IsZero()) { // Get or create the NullConstant for this type. std::vector ids; return const_mgr->GetConstant(type_mgr->GetType(inst->type_id()), ids); } if (c1 == nullptr || c2 == nullptr) { return nullptr; } // Check result type. const analysis::Type* result_type = type_mgr->GetType(inst->type_id()); const analysis::Vector* vector_type = result_type->AsVector(); assert(vector_type != nullptr); const analysis::Type* element_type = vector_type->element_type(); assert(element_type != nullptr); const analysis::Float* float_type = element_type->AsFloat(); assert(float_type != nullptr); // Check types of c1 and c2. assert(c1->type()->AsVector() == vector_type); assert(c1->type()->AsVector()->element_type() == element_type && c2->type() == element_type); // Get a float vector that is the result of vector-times-scalar. std::vector c1_components = c1->GetVectorComponents(const_mgr); std::vector ids; if (float_type->width() == 32) { float scalar = c2->GetFloat(); for (uint32_t i = 0; i < c1_components.size(); ++i) { utils::FloatProxy result(c1_components[i]->GetFloat() * scalar); std::vector words = result.GetWords(); const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } else if (float_type->width() == 64) { double scalar = c2->GetDouble(); for (uint32_t i = 0; i < c1_components.size(); ++i) { utils::FloatProxy result(c1_components[i]->GetDouble() * scalar); std::vector words = result.GetWords(); const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } return nullptr; }; } ConstantFoldingRule FoldVectorTimesMatrix() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { assert(inst->opcode() == spv::Op::OpVectorTimesMatrix); analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); if (!inst->IsFloatingPointFoldingAllowed()) { if (HasFloatingPoint(type_mgr->GetType(inst->type_id()))) { return nullptr; } } const analysis::Constant* c1 = constants[0]; const analysis::Constant* c2 = constants[1]; if (c1 == nullptr || c2 == nullptr) { return nullptr; } // Check result type. const analysis::Type* result_type = type_mgr->GetType(inst->type_id()); const analysis::Vector* vector_type = result_type->AsVector(); assert(vector_type != nullptr); const analysis::Type* element_type = vector_type->element_type(); assert(element_type != nullptr); const analysis::Float* float_type = element_type->AsFloat(); assert(float_type != nullptr); // Check types of c1 and c2. assert(c1->type()->AsVector() == vector_type); assert(c1->type()->AsVector()->element_type() == element_type && c2->type()->AsMatrix()->element_type() == vector_type); // Get a float vector that is the result of vector-times-matrix. std::vector c1_components = c1->GetVectorComponents(const_mgr); std::vector c2_components = c2->AsMatrixConstant()->GetComponents(); uint32_t resultVectorSize = result_type->AsVector()->element_count(); std::vector ids; if ((c1 && c1->IsZero()) || (c2 && c2->IsZero())) { std::vector words(float_type->width() / 32, 0); for (uint32_t i = 0; i < resultVectorSize; ++i) { const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } if (float_type->width() == 32) { for (uint32_t i = 0; i < resultVectorSize; ++i) { float result_scalar = 0.0f; if (!c2_components[i]->AsNullConstant()) { const analysis::VectorConstant* c2_vec = c2_components[i]->AsVectorConstant(); for (uint32_t j = 0; j < c2_vec->GetComponents().size(); ++j) { float c1_scalar = c1_components[j]->GetFloat(); float c2_scalar = c2_vec->GetComponents()[j]->GetFloat(); result_scalar += c1_scalar * c2_scalar; } } utils::FloatProxy result(result_scalar); std::vector words = result.GetWords(); const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } else if (float_type->width() == 64) { for (uint32_t i = 0; i < c2_components.size(); ++i) { double result_scalar = 0.0; if (!c2_components[i]->AsNullConstant()) { const analysis::VectorConstant* c2_vec = c2_components[i]->AsVectorConstant(); for (uint32_t j = 0; j < c2_vec->GetComponents().size(); ++j) { double c1_scalar = c1_components[j]->GetDouble(); double c2_scalar = c2_vec->GetComponents()[j]->GetDouble(); result_scalar += c1_scalar * c2_scalar; } } utils::FloatProxy result(result_scalar); std::vector words = result.GetWords(); const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } return nullptr; }; } ConstantFoldingRule FoldMatrixTimesVector() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { assert(inst->opcode() == spv::Op::OpMatrixTimesVector); analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); if (!inst->IsFloatingPointFoldingAllowed()) { if (HasFloatingPoint(type_mgr->GetType(inst->type_id()))) { return nullptr; } } const analysis::Constant* c1 = constants[0]; const analysis::Constant* c2 = constants[1]; if (c1 == nullptr || c2 == nullptr) { return nullptr; } // Check result type. const analysis::Type* result_type = type_mgr->GetType(inst->type_id()); const analysis::Vector* vector_type = result_type->AsVector(); assert(vector_type != nullptr); const analysis::Type* element_type = vector_type->element_type(); assert(element_type != nullptr); const analysis::Float* float_type = element_type->AsFloat(); assert(float_type != nullptr); // Check types of c1 and c2. assert(c1->type()->AsMatrix()->element_type() == vector_type); assert(c2->type()->AsVector()->element_type() == element_type); // Get a float vector that is the result of matrix-times-vector. std::vector c1_components = c1->AsMatrixConstant()->GetComponents(); std::vector c2_components = c2->GetVectorComponents(const_mgr); uint32_t resultVectorSize = result_type->AsVector()->element_count(); std::vector ids; if ((c1 && c1->IsZero()) || (c2 && c2->IsZero())) { std::vector words(float_type->width() / 32, 0); for (uint32_t i = 0; i < resultVectorSize; ++i) { const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } if (float_type->width() == 32) { for (uint32_t i = 0; i < resultVectorSize; ++i) { float result_scalar = 0.0f; for (uint32_t j = 0; j < c1_components.size(); ++j) { if (!c1_components[j]->AsNullConstant()) { float c1_scalar = c1_components[j] ->AsVectorConstant() ->GetComponents()[i] ->GetFloat(); float c2_scalar = c2_components[j]->GetFloat(); result_scalar += c1_scalar * c2_scalar; } } utils::FloatProxy result(result_scalar); std::vector words = result.GetWords(); const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } else if (float_type->width() == 64) { for (uint32_t i = 0; i < resultVectorSize; ++i) { double result_scalar = 0.0; for (uint32_t j = 0; j < c1_components.size(); ++j) { if (!c1_components[j]->AsNullConstant()) { double c1_scalar = c1_components[j] ->AsVectorConstant() ->GetComponents()[i] ->GetDouble(); double c2_scalar = c2_components[j]->GetDouble(); result_scalar += c1_scalar * c2_scalar; } } utils::FloatProxy result(result_scalar); std::vector words = result.GetWords(); const analysis::Constant* new_elem = const_mgr->GetConstant(float_type, words); ids.push_back(const_mgr->GetDefiningInstruction(new_elem)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } return nullptr; }; } ConstantFoldingRule FoldCompositeWithConstants() { // Folds an OpCompositeConstruct where all of the inputs are constants to a // constant. A new constant is created if necessary. return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); const analysis::Type* new_type = type_mgr->GetType(inst->type_id()); Instruction* type_inst = context->get_def_use_mgr()->GetDef(inst->type_id()); std::vector ids; for (uint32_t i = 0; i < constants.size(); ++i) { const analysis::Constant* element_const = constants[i]; if (element_const == nullptr) { return nullptr; } uint32_t component_type_id = 0; if (type_inst->opcode() == spv::Op::OpTypeStruct) { component_type_id = type_inst->GetSingleWordInOperand(i); } else if (type_inst->opcode() == spv::Op::OpTypeArray) { component_type_id = type_inst->GetSingleWordInOperand(0); } uint32_t element_id = const_mgr->FindDeclaredConstant(element_const, component_type_id); if (element_id == 0) { return nullptr; } ids.push_back(element_id); } return const_mgr->GetConstant(new_type, ids); }; } // The interface for a function that returns the result of applying a scalar // floating-point binary operation on |a| and |b|. The type of the return value // will be |type|. The input constants must also be of type |type|. using UnaryScalarFoldingRule = std::function; // The interface for a function that returns the result of applying a scalar // floating-point binary operation on |a| and |b|. The type of the return value // will be |type|. The input constants must also be of type |type|. using BinaryScalarFoldingRule = std::function; // Returns a |ConstantFoldingRule| that folds unary floating point scalar ops // using |scalar_rule| and unary float point vectors ops by applying // |scalar_rule| to the elements of the vector. The |ConstantFoldingRule| // that is returned assumes that |constants| contains 1 entry. If they are // not |nullptr|, then their type is either |Float| or |Integer| or a |Vector| // whose element type is |Float| or |Integer|. ConstantFoldingRule FoldFPUnaryOp(UnaryScalarFoldingRule scalar_rule) { return [scalar_rule](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); const analysis::Type* result_type = type_mgr->GetType(inst->type_id()); const analysis::Vector* vector_type = result_type->AsVector(); if (!inst->IsFloatingPointFoldingAllowed()) { return nullptr; } const analysis::Constant* arg = (inst->opcode() == spv::Op::OpExtInst) ? constants[1] : constants[0]; if (arg == nullptr) { return nullptr; } if (vector_type != nullptr) { std::vector a_components; std::vector results_components; a_components = arg->GetVectorComponents(const_mgr); // Fold each component of the vector. for (uint32_t i = 0; i < a_components.size(); ++i) { results_components.push_back(scalar_rule(vector_type->element_type(), a_components[i], const_mgr)); if (results_components[i] == nullptr) { return nullptr; } } // Build the constant object and return it. std::vector ids; for (const analysis::Constant* member : results_components) { ids.push_back(const_mgr->GetDefiningInstruction(member)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } else { return scalar_rule(result_type, arg, const_mgr); } }; } // Returns the result of folding the constants in |constants| according the // |scalar_rule|. If |result_type| is a vector, then |scalar_rule| is applied // per component. const analysis::Constant* FoldFPBinaryOp( BinaryScalarFoldingRule scalar_rule, uint32_t result_type_id, const std::vector& constants, IRContext* context) { analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); const analysis::Type* result_type = type_mgr->GetType(result_type_id); const analysis::Vector* vector_type = result_type->AsVector(); if (constants[0] == nullptr || constants[1] == nullptr) { return nullptr; } if (vector_type != nullptr) { std::vector a_components; std::vector b_components; std::vector results_components; a_components = constants[0]->GetVectorComponents(const_mgr); b_components = constants[1]->GetVectorComponents(const_mgr); // Fold each component of the vector. for (uint32_t i = 0; i < a_components.size(); ++i) { results_components.push_back(scalar_rule(vector_type->element_type(), a_components[i], b_components[i], const_mgr)); if (results_components[i] == nullptr) { return nullptr; } } // Build the constant object and return it. std::vector ids; for (const analysis::Constant* member : results_components) { ids.push_back(const_mgr->GetDefiningInstruction(member)->result_id()); } return const_mgr->GetConstant(vector_type, ids); } else { return scalar_rule(result_type, constants[0], constants[1], const_mgr); } } // Returns a |ConstantFoldingRule| that folds floating point scalars using // |scalar_rule| and vectors of floating point by applying |scalar_rule| to the // elements of the vector. The |ConstantFoldingRule| that is returned assumes // that |constants| contains 2 entries. If they are not |nullptr|, then their // type is either |Float| or a |Vector| whose element type is |Float|. ConstantFoldingRule FoldFPBinaryOp(BinaryScalarFoldingRule scalar_rule) { return [scalar_rule](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { if (!inst->IsFloatingPointFoldingAllowed()) { return nullptr; } if (inst->opcode() == spv::Op::OpExtInst) { return FoldFPBinaryOp(scalar_rule, inst->type_id(), {constants[1], constants[2]}, context); } return FoldFPBinaryOp(scalar_rule, inst->type_id(), constants, context); }; } // This macro defines a |UnaryScalarFoldingRule| that performs float to // integer conversion. // TODO(greg-lunarg): Support for 64-bit integer types. UnaryScalarFoldingRule FoldFToIOp() { return [](const analysis::Type* result_type, const analysis::Constant* a, analysis::ConstantManager* const_mgr) -> const analysis::Constant* { assert(result_type != nullptr && a != nullptr); const analysis::Integer* integer_type = result_type->AsInteger(); const analysis::Float* float_type = a->type()->AsFloat(); assert(float_type != nullptr); assert(integer_type != nullptr); if (integer_type->width() != 32) return nullptr; if (float_type->width() == 32) { float fa = a->GetFloat(); uint32_t result = integer_type->IsSigned() ? static_cast(static_cast(fa)) : static_cast(fa); std::vector words = {result}; return const_mgr->GetConstant(result_type, words); } else if (float_type->width() == 64) { double fa = a->GetDouble(); uint32_t result = integer_type->IsSigned() ? static_cast(static_cast(fa)) : static_cast(fa); std::vector words = {result}; return const_mgr->GetConstant(result_type, words); } return nullptr; }; } // This function defines a |UnaryScalarFoldingRule| that performs integer to // float conversion. // TODO(greg-lunarg): Support for 64-bit integer types. UnaryScalarFoldingRule FoldIToFOp() { return [](const analysis::Type* result_type, const analysis::Constant* a, analysis::ConstantManager* const_mgr) -> const analysis::Constant* { assert(result_type != nullptr && a != nullptr); const analysis::Integer* integer_type = a->type()->AsInteger(); const analysis::Float* float_type = result_type->AsFloat(); assert(float_type != nullptr); assert(integer_type != nullptr); if (integer_type->width() != 32) return nullptr; uint32_t ua = a->GetU32(); if (float_type->width() == 32) { float result_val = integer_type->IsSigned() ? static_cast(static_cast(ua)) : static_cast(ua); utils::FloatProxy result(result_val); std::vector words = {result.data()}; return const_mgr->GetConstant(result_type, words); } else if (float_type->width() == 64) { double result_val = integer_type->IsSigned() ? static_cast(static_cast(ua)) : static_cast(ua); utils::FloatProxy result(result_val); std::vector words = result.GetWords(); return const_mgr->GetConstant(result_type, words); } return nullptr; }; } // This defines a |UnaryScalarFoldingRule| that performs |OpQuantizeToF16|. UnaryScalarFoldingRule FoldQuantizeToF16Scalar() { return [](const analysis::Type* result_type, const analysis::Constant* a, analysis::ConstantManager* const_mgr) -> const analysis::Constant* { assert(result_type != nullptr && a != nullptr); const analysis::Float* float_type = a->type()->AsFloat(); assert(float_type != nullptr); if (float_type->width() != 32) { return nullptr; } float fa = a->GetFloat(); utils::HexFloat> orignal(fa); utils::HexFloat> quantized(0); utils::HexFloat> result(0.0f); orignal.castTo(quantized, utils::round_direction::kToZero); quantized.castTo(result, utils::round_direction::kToZero); std::vector words = {result.getBits()}; return const_mgr->GetConstant(result_type, words); }; } // This macro defines a |BinaryScalarFoldingRule| that applies |op|. The // operator |op| must work for both float and double, and use syntax "f1 op f2". #define FOLD_FPARITH_OP(op) \ [](const analysis::Type* result_type_in_macro, const analysis::Constant* a, \ const analysis::Constant* b, \ analysis::ConstantManager* const_mgr_in_macro) \ -> const analysis::Constant* { \ assert(result_type_in_macro != nullptr && a != nullptr && b != nullptr); \ assert(result_type_in_macro == a->type() && \ result_type_in_macro == b->type()); \ const analysis::Float* float_type_in_macro = \ result_type_in_macro->AsFloat(); \ assert(float_type_in_macro != nullptr); \ if (float_type_in_macro->width() == 32) { \ float fa = a->GetFloat(); \ float fb = b->GetFloat(); \ utils::FloatProxy result_in_macro(fa op fb); \ std::vector words_in_macro = result_in_macro.GetWords(); \ return const_mgr_in_macro->GetConstant(result_type_in_macro, \ words_in_macro); \ } else if (float_type_in_macro->width() == 64) { \ double fa = a->GetDouble(); \ double fb = b->GetDouble(); \ utils::FloatProxy result_in_macro(fa op fb); \ std::vector words_in_macro = result_in_macro.GetWords(); \ return const_mgr_in_macro->GetConstant(result_type_in_macro, \ words_in_macro); \ } \ return nullptr; \ } // Define the folding rule for conversion between floating point and integer ConstantFoldingRule FoldFToI() { return FoldFPUnaryOp(FoldFToIOp()); } ConstantFoldingRule FoldIToF() { return FoldFPUnaryOp(FoldIToFOp()); } ConstantFoldingRule FoldQuantizeToF16() { return FoldFPUnaryOp(FoldQuantizeToF16Scalar()); } // Define the folding rules for subtraction, addition, multiplication, and // division for floating point values. ConstantFoldingRule FoldFSub() { return FoldFPBinaryOp(FOLD_FPARITH_OP(-)); } ConstantFoldingRule FoldFAdd() { return FoldFPBinaryOp(FOLD_FPARITH_OP(+)); } ConstantFoldingRule FoldFMul() { return FoldFPBinaryOp(FOLD_FPARITH_OP(*)); } // Returns the constant that results from evaluating |numerator| / 0.0. Returns // |nullptr| if the result could not be evaluated. const analysis::Constant* FoldFPScalarDivideByZero( const analysis::Type* result_type, const analysis::Constant* numerator, analysis::ConstantManager* const_mgr) { if (numerator == nullptr) { return nullptr; } if (numerator->IsZero()) { return GetNan(result_type, const_mgr); } const analysis::Constant* result = GetInf(result_type, const_mgr); if (result == nullptr) { return nullptr; } if (numerator->AsFloatConstant()->GetValueAsDouble() < 0.0) { result = NegateFPConst(result_type, result, const_mgr); } return result; } // Returns the result of folding |numerator| / |denominator|. Returns |nullptr| // if it cannot be folded. const analysis::Constant* FoldScalarFPDivide( const analysis::Type* result_type, const analysis::Constant* numerator, const analysis::Constant* denominator, analysis::ConstantManager* const_mgr) { if (denominator == nullptr) { return nullptr; } if (denominator->IsZero()) { return FoldFPScalarDivideByZero(result_type, numerator, const_mgr); } const analysis::FloatConstant* denominator_float = denominator->AsFloatConstant(); if (denominator_float && denominator->GetValueAsDouble() == -0.0) { const analysis::Constant* result = FoldFPScalarDivideByZero(result_type, numerator, const_mgr); if (result != nullptr) result = NegateFPConst(result_type, result, const_mgr); return result; } else { return FOLD_FPARITH_OP(/)(result_type, numerator, denominator, const_mgr); } } // Returns the constant folding rule to fold |OpFDiv| with two constants. ConstantFoldingRule FoldFDiv() { return FoldFPBinaryOp(FoldScalarFPDivide); } bool CompareFloatingPoint(bool op_result, bool op_unordered, bool need_ordered) { if (need_ordered) { // operands are ordered and Operand 1 is |op| Operand 2 return !op_unordered && op_result; } else { // operands are unordered or Operand 1 is |op| Operand 2 return op_unordered || op_result; } } // This macro defines a |BinaryScalarFoldingRule| that applies |op|. The // operator |op| must work for both float and double, and use syntax "f1 op f2". #define FOLD_FPCMP_OP(op, ord) \ [](const analysis::Type* result_type, const analysis::Constant* a, \ const analysis::Constant* b, \ analysis::ConstantManager* const_mgr) -> const analysis::Constant* { \ assert(result_type != nullptr && a != nullptr && b != nullptr); \ assert(result_type->AsBool()); \ assert(a->type() == b->type()); \ const analysis::Float* float_type = a->type()->AsFloat(); \ assert(float_type != nullptr); \ if (float_type->width() == 32) { \ float fa = a->GetFloat(); \ float fb = b->GetFloat(); \ bool result = CompareFloatingPoint( \ fa op fb, std::isnan(fa) || std::isnan(fb), ord); \ std::vector words = {uint32_t(result)}; \ return const_mgr->GetConstant(result_type, words); \ } else if (float_type->width() == 64) { \ double fa = a->GetDouble(); \ double fb = b->GetDouble(); \ bool result = CompareFloatingPoint( \ fa op fb, std::isnan(fa) || std::isnan(fb), ord); \ std::vector words = {uint32_t(result)}; \ return const_mgr->GetConstant(result_type, words); \ } \ return nullptr; \ } // Define the folding rules for ordered and unordered comparison for floating // point values. ConstantFoldingRule FoldFOrdEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(==, true)); } ConstantFoldingRule FoldFUnordEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(==, false)); } ConstantFoldingRule FoldFOrdNotEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(!=, true)); } ConstantFoldingRule FoldFUnordNotEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(!=, false)); } ConstantFoldingRule FoldFOrdLessThan() { return FoldFPBinaryOp(FOLD_FPCMP_OP(<, true)); } ConstantFoldingRule FoldFUnordLessThan() { return FoldFPBinaryOp(FOLD_FPCMP_OP(<, false)); } ConstantFoldingRule FoldFOrdGreaterThan() { return FoldFPBinaryOp(FOLD_FPCMP_OP(>, true)); } ConstantFoldingRule FoldFUnordGreaterThan() { return FoldFPBinaryOp(FOLD_FPCMP_OP(>, false)); } ConstantFoldingRule FoldFOrdLessThanEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(<=, true)); } ConstantFoldingRule FoldFUnordLessThanEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(<=, false)); } ConstantFoldingRule FoldFOrdGreaterThanEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(>=, true)); } ConstantFoldingRule FoldFUnordGreaterThanEqual() { return FoldFPBinaryOp(FOLD_FPCMP_OP(>=, false)); } // Folds an OpDot where all of the inputs are constants to a // constant. A new constant is created if necessary. ConstantFoldingRule FoldOpDotWithConstants() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::TypeManager* type_mgr = context->get_type_mgr(); const analysis::Type* new_type = type_mgr->GetType(inst->type_id()); assert(new_type->AsFloat() && "OpDot should have a float return type."); const analysis::Float* float_type = new_type->AsFloat(); if (!inst->IsFloatingPointFoldingAllowed()) { return nullptr; } // If one of the operands is 0, then the result is 0. bool has_zero_operand = false; for (int i = 0; i < 2; ++i) { if (constants[i]) { if (constants[i]->AsNullConstant() || constants[i]->AsVectorConstant()->IsZero()) { has_zero_operand = true; break; } } } if (has_zero_operand) { if (float_type->width() == 32) { utils::FloatProxy result(0.0f); std::vector words = result.GetWords(); return const_mgr->GetConstant(float_type, words); } if (float_type->width() == 64) { utils::FloatProxy result(0.0); std::vector words = result.GetWords(); return const_mgr->GetConstant(float_type, words); } return nullptr; } if (constants[0] == nullptr || constants[1] == nullptr) { return nullptr; } std::vector a_components; std::vector b_components; a_components = constants[0]->GetVectorComponents(const_mgr); b_components = constants[1]->GetVectorComponents(const_mgr); utils::FloatProxy result(0.0); std::vector words = result.GetWords(); const analysis::Constant* result_const = const_mgr->GetConstant(float_type, words); for (uint32_t i = 0; i < a_components.size() && result_const != nullptr; ++i) { if (a_components[i] == nullptr || b_components[i] == nullptr) { return nullptr; } const analysis::Constant* component = FOLD_FPARITH_OP(*)( new_type, a_components[i], b_components[i], const_mgr); if (component == nullptr) { return nullptr; } result_const = FOLD_FPARITH_OP(+)(new_type, result_const, component, const_mgr); } return result_const; }; } // This function defines a |UnaryScalarFoldingRule| that subtracts the constant // from zero. UnaryScalarFoldingRule FoldFNegateOp() { return [](const analysis::Type* result_type, const analysis::Constant* a, analysis::ConstantManager* const_mgr) -> const analysis::Constant* { assert(result_type != nullptr && a != nullptr); assert(result_type == a->type()); return NegateFPConst(result_type, a, const_mgr); }; } ConstantFoldingRule FoldFNegate() { return FoldFPUnaryOp(FoldFNegateOp()); } ConstantFoldingRule FoldFClampFeedingCompare(spv::Op cmp_opcode) { return [cmp_opcode](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { analysis::ConstantManager* const_mgr = context->get_constant_mgr(); analysis::DefUseManager* def_use_mgr = context->get_def_use_mgr(); if (!inst->IsFloatingPointFoldingAllowed()) { return nullptr; } uint32_t non_const_idx = (constants[0] ? 1 : 0); uint32_t operand_id = inst->GetSingleWordInOperand(non_const_idx); Instruction* operand_inst = def_use_mgr->GetDef(operand_id); analysis::TypeManager* type_mgr = context->get_type_mgr(); const analysis::Type* operand_type = type_mgr->GetType(operand_inst->type_id()); if (!operand_type->AsFloat()) { return nullptr; } if (operand_type->AsFloat()->width() != 32 && operand_type->AsFloat()->width() != 64) { return nullptr; } if (operand_inst->opcode() != spv::Op::OpExtInst) { return nullptr; } if (operand_inst->GetSingleWordInOperand(1) != GLSLstd450FClamp) { return nullptr; } if (constants[1] == nullptr && constants[0] == nullptr) { return nullptr; } uint32_t max_id = operand_inst->GetSingleWordInOperand(4); const analysis::Constant* max_const = const_mgr->FindDeclaredConstant(max_id); uint32_t min_id = operand_inst->GetSingleWordInOperand(3); const analysis::Constant* min_const = const_mgr->FindDeclaredConstant(min_id); bool found_result = false; bool result = false; switch (cmp_opcode) { case spv::Op::OpFOrdLessThan: case spv::Op::OpFUnordLessThan: case spv::Op::OpFOrdGreaterThanEqual: case spv::Op::OpFUnordGreaterThanEqual: if (constants[0]) { if (min_const) { if (constants[0]->GetValueAsDouble() < min_const->GetValueAsDouble()) { found_result = true; result = (cmp_opcode == spv::Op::OpFOrdLessThan || cmp_opcode == spv::Op::OpFUnordLessThan); } } if (max_const) { if (constants[0]->GetValueAsDouble() >= max_const->GetValueAsDouble()) { found_result = true; result = !(cmp_opcode == spv::Op::OpFOrdLessThan || cmp_opcode == spv::Op::OpFUnordLessThan); } } } if (constants[1]) { if (max_const) { if (max_const->GetValueAsDouble() < constants[1]->GetValueAsDouble()) { found_result = true; result = (cmp_opcode == spv::Op::OpFOrdLessThan || cmp_opcode == spv::Op::OpFUnordLessThan); } } if (min_const) { if (min_const->GetValueAsDouble() >= constants[1]->GetValueAsDouble()) { found_result = true; result = !(cmp_opcode == spv::Op::OpFOrdLessThan || cmp_opcode == spv::Op::OpFUnordLessThan); } } } break; case spv::Op::OpFOrdGreaterThan: case spv::Op::OpFUnordGreaterThan: case spv::Op::OpFOrdLessThanEqual: case spv::Op::OpFUnordLessThanEqual: if (constants[0]) { if (min_const) { if (constants[0]->GetValueAsDouble() <= min_const->GetValueAsDouble()) { found_result = true; result = (cmp_opcode == spv::Op::OpFOrdLessThanEqual || cmp_opcode == spv::Op::OpFUnordLessThanEqual); } } if (max_const) { if (constants[0]->GetValueAsDouble() > max_const->GetValueAsDouble()) { found_result = true; result = !(cmp_opcode == spv::Op::OpFOrdLessThanEqual || cmp_opcode == spv::Op::OpFUnordLessThanEqual); } } } if (constants[1]) { if (max_const) { if (max_const->GetValueAsDouble() <= constants[1]->GetValueAsDouble()) { found_result = true; result = (cmp_opcode == spv::Op::OpFOrdLessThanEqual || cmp_opcode == spv::Op::OpFUnordLessThanEqual); } } if (min_const) { if (min_const->GetValueAsDouble() > constants[1]->GetValueAsDouble()) { found_result = true; result = !(cmp_opcode == spv::Op::OpFOrdLessThanEqual || cmp_opcode == spv::Op::OpFUnordLessThanEqual); } } } break; default: return nullptr; } if (!found_result) { return nullptr; } const analysis::Type* bool_type = context->get_type_mgr()->GetType(inst->type_id()); const analysis::Constant* result_const = const_mgr->GetConstant(bool_type, {static_cast(result)}); assert(result_const); return result_const; }; } ConstantFoldingRule FoldFMix() { return [](IRContext* context, Instruction* inst, const std::vector& constants) -> const analysis::Constant* { analysis::ConstantManager* const_mgr = context->get_constant_mgr(); assert(inst->opcode() == spv::Op::OpExtInst && "Expecting an extended instruction."); assert(inst->GetSingleWordInOperand(0) == context->get_feature_mgr()->GetExtInstImportId_GLSLstd450() && "Expecting a GLSLstd450 extended instruction."); assert(inst->GetSingleWordInOperand(1) == GLSLstd450FMix && "Expecting and FMix instruction."); if (!inst->IsFloatingPointFoldingAllowed()) { return nullptr; } // Make sure all FMix operands are constants. for (uint32_t i = 1; i < 4; i++) { if (constants[i] == nullptr) { return nullptr; } } const analysis::Constant* one; bool is_vector = false; const analysis::Type* result_type = constants[1]->type(); const analysis::Type* base_type = result_type; if (base_type->AsVector()) { is_vector = true; base_type = base_type->AsVector()->element_type(); } assert(base_type->AsFloat() != nullptr && "FMix is suppose to act on floats or vectors of floats."); if (base_type->AsFloat()->width() == 32) { one = const_mgr->GetConstant(base_type, utils::FloatProxy(1.0f).GetWords()); } else { one = const_mgr->GetConstant(base_type, utils::FloatProxy(1.0).GetWords()); } if (is_vector) { uint32_t one_id = const_mgr->GetDefiningInstruction(one)->result_id(); one = const_mgr->GetConstant(result_type, std::vector(4, one_id)); } const analysis::Constant* temp1 = FoldFPBinaryOp( FOLD_FPARITH_OP(-), inst->type_id(), {one, constants[3]}, context); if (temp1 == nullptr) { return nullptr; } const analysis::Constant* temp2 = FoldFPBinaryOp( FOLD_FPARITH_OP(*), inst->type_id(), {constants[1], temp1}, context); if (temp2 == nullptr) { return nullptr; } const analysis::Constant* temp3 = FoldFPBinaryOp(FOLD_FPARITH_OP(*), inst->type_id(), {constants[2], constants[3]}, context); if (temp3 == nullptr) { return nullptr; } return FoldFPBinaryOp(FOLD_FPARITH_OP(+), inst->type_id(), {temp2, temp3}, context); }; } const analysis::Constant* FoldMin(const analysis::Type* result_type, const analysis::Constant* a, const analysis::Constant* b, analysis::ConstantManager*) { if (const analysis::Integer* int_type = result_type->AsInteger()) { if (int_type->width() == 32) { if (int_type->IsSigned()) { int32_t va = a->GetS32(); int32_t vb = b->GetS32(); return (va < vb ? a : b); } else { uint32_t va = a->GetU32(); uint32_t vb = b->GetU32(); return (va < vb ? a : b); } } else if (int_type->width() == 64) { if (int_type->IsSigned()) { int64_t va = a->GetS64(); int64_t vb = b->GetS64(); return (va < vb ? a : b); } else { uint64_t va = a->GetU64(); uint64_t vb = b->GetU64(); return (va < vb ? a : b); } } } else if (const analysis::Float* float_type = result_type->AsFloat()) { if (float_type->width() == 32) { float va = a->GetFloat(); float vb = b->GetFloat(); return (va < vb ? a : b); } else if (float_type->width() == 64) { double va = a->GetDouble(); double vb = b->GetDouble(); return (va < vb ? a : b); } } return nullptr; } const analysis::Constant* FoldMax(const analysis::Type* result_type, const analysis::Constant* a, const analysis::Constant* b, analysis::ConstantManager*) { if (const analysis::Integer* int_type = result_type->AsInteger()) { if (int_type->width() == 32) { if (int_type->IsSigned()) { int32_t va = a->GetS32(); int32_t vb = b->GetS32(); return (va > vb ? a : b); } else { uint32_t va = a->GetU32(); uint32_t vb = b->GetU32(); return (va > vb ? a : b); } } else if (int_type->width() == 64) { if (int_type->IsSigned()) { int64_t va = a->GetS64(); int64_t vb = b->GetS64(); return (va > vb ? a : b); } else { uint64_t va = a->GetU64(); uint64_t vb = b->GetU64(); return (va > vb ? a : b); } } } else if (const analysis::Float* float_type = result_type->AsFloat()) { if (float_type->width() == 32) { float va = a->GetFloat(); float vb = b->GetFloat(); return (va > vb ? a : b); } else if (float_type->width() == 64) { double va = a->GetDouble(); double vb = b->GetDouble(); return (va > vb ? a : b); } } return nullptr; } // Fold an clamp instruction when all three operands are constant. const analysis::Constant* FoldClamp1( IRContext* context, Instruction* inst, const std::vector& constants) { assert(inst->opcode() == spv::Op::OpExtInst && "Expecting an extended instruction."); assert(inst->GetSingleWordInOperand(0) == context->get_feature_mgr()->GetExtInstImportId_GLSLstd450() && "Expecting a GLSLstd450 extended instruction."); // Make sure all Clamp operands are constants. for (uint32_t i = 1; i < 4; i++) { if (constants[i] == nullptr) { return nullptr; } } const analysis::Constant* temp = FoldFPBinaryOp( FoldMax, inst->type_id(), {constants[1], constants[2]}, context); if (temp == nullptr) { return nullptr; } return FoldFPBinaryOp(FoldMin, inst->type_id(), {temp, constants[3]}, context); } // Fold a clamp instruction when |x <= min_val|. const analysis::Constant* FoldClamp2( IRContext* context, Instruction* inst, const std::vector& constants) { assert(inst->opcode() == spv::Op::OpExtInst && "Expecting an extended instruction."); assert(inst->GetSingleWordInOperand(0) == context->get_feature_mgr()->GetExtInstImportId_GLSLstd450() && "Expecting a GLSLstd450 extended instruction."); const analysis::Constant* x = constants[1]; const analysis::Constant* min_val = constants[2]; if (x == nullptr || min_val == nullptr) { return nullptr; } const analysis::Constant* temp = FoldFPBinaryOp(FoldMax, inst->type_id(), {x, min_val}, context); if (temp == min_val) { // We can assume that |min_val| is less than |max_val|. Therefore, if the // result of the max operation is |min_val|, we know the result of the min // operation, even if |max_val| is not a constant. return min_val; } return nullptr; } // Fold a clamp instruction when |x >= max_val|. const analysis::Constant* FoldClamp3( IRContext* context, Instruction* inst, const std::vector& constants) { assert(inst->opcode() == spv::Op::OpExtInst && "Expecting an extended instruction."); assert(inst->GetSingleWordInOperand(0) == context->get_feature_mgr()->GetExtInstImportId_GLSLstd450() && "Expecting a GLSLstd450 extended instruction."); const analysis::Constant* x = constants[1]; const analysis::Constant* max_val = constants[3]; if (x == nullptr || max_val == nullptr) { return nullptr; } const analysis::Constant* temp = FoldFPBinaryOp(FoldMin, inst->type_id(), {x, max_val}, context); if (temp == max_val) { // We can assume that |min_val| is less than |max_val|. Therefore, if the // result of the max operation is |min_val|, we know the result of the min // operation, even if |max_val| is not a constant. return max_val; } return nullptr; } UnaryScalarFoldingRule FoldFTranscendentalUnary(double (*fp)(double)) { return [fp](const analysis::Type* result_type, const analysis::Constant* a, analysis::ConstantManager* const_mgr) -> const analysis::Constant* { assert(result_type != nullptr && a != nullptr); const analysis::Float* float_type = a->type()->AsFloat(); assert(float_type != nullptr); assert(float_type == result_type->AsFloat()); if (float_type->width() == 32) { float fa = a->GetFloat(); float res = static_cast(fp(fa)); utils::FloatProxy result(res); std::vector words = result.GetWords(); return const_mgr->GetConstant(result_type, words); } else if (float_type->width() == 64) { double fa = a->GetDouble(); double res = fp(fa); utils::FloatProxy result(res); std::vector words = result.GetWords(); return const_mgr->GetConstant(result_type, words); } return nullptr; }; } BinaryScalarFoldingRule FoldFTranscendentalBinary(double (*fp)(double, double)) { return [fp](const analysis::Type* result_type, const analysis::Constant* a, const analysis::Constant* b, analysis::ConstantManager* const_mgr) -> const analysis::Constant* { assert(result_type != nullptr && a != nullptr); const analysis::Float* float_type = a->type()->AsFloat(); assert(float_type != nullptr); assert(float_type == result_type->AsFloat()); assert(float_type == b->type()->AsFloat()); if (float_type->width() == 32) { float fa = a->GetFloat(); float fb = b->GetFloat(); float res = static_cast(fp(fa, fb)); utils::FloatProxy result(res); std::vector words = result.GetWords(); return const_mgr->GetConstant(result_type, words); } else if (float_type->width() == 64) { double fa = a->GetDouble(); double fb = b->GetDouble(); double res = fp(fa, fb); utils::FloatProxy result(res); std::vector words = result.GetWords(); return const_mgr->GetConstant(result_type, words); } return nullptr; }; } } // namespace void ConstantFoldingRules::AddFoldingRules() { // Add all folding rules to the list for the opcodes to which they apply. // Note that the order in which rules are added to the list matters. If a rule // applies to the instruction, the rest of the rules will not be attempted. // Take that into consideration. rules_[spv::Op::OpCompositeConstruct].push_back(FoldCompositeWithConstants()); rules_[spv::Op::OpCompositeExtract].push_back(FoldExtractWithConstants()); rules_[spv::Op::OpCompositeInsert].push_back(FoldInsertWithConstants()); rules_[spv::Op::OpConvertFToS].push_back(FoldFToI()); rules_[spv::Op::OpConvertFToU].push_back(FoldFToI()); rules_[spv::Op::OpConvertSToF].push_back(FoldIToF()); rules_[spv::Op::OpConvertUToF].push_back(FoldIToF()); rules_[spv::Op::OpDot].push_back(FoldOpDotWithConstants()); rules_[spv::Op::OpFAdd].push_back(FoldFAdd()); rules_[spv::Op::OpFDiv].push_back(FoldFDiv()); rules_[spv::Op::OpFMul].push_back(FoldFMul()); rules_[spv::Op::OpFSub].push_back(FoldFSub()); rules_[spv::Op::OpFOrdEqual].push_back(FoldFOrdEqual()); rules_[spv::Op::OpFUnordEqual].push_back(FoldFUnordEqual()); rules_[spv::Op::OpFOrdNotEqual].push_back(FoldFOrdNotEqual()); rules_[spv::Op::OpFUnordNotEqual].push_back(FoldFUnordNotEqual()); rules_[spv::Op::OpFOrdLessThan].push_back(FoldFOrdLessThan()); rules_[spv::Op::OpFOrdLessThan].push_back( FoldFClampFeedingCompare(spv::Op::OpFOrdLessThan)); rules_[spv::Op::OpFUnordLessThan].push_back(FoldFUnordLessThan()); rules_[spv::Op::OpFUnordLessThan].push_back( FoldFClampFeedingCompare(spv::Op::OpFUnordLessThan)); rules_[spv::Op::OpFOrdGreaterThan].push_back(FoldFOrdGreaterThan()); rules_[spv::Op::OpFOrdGreaterThan].push_back( FoldFClampFeedingCompare(spv::Op::OpFOrdGreaterThan)); rules_[spv::Op::OpFUnordGreaterThan].push_back(FoldFUnordGreaterThan()); rules_[spv::Op::OpFUnordGreaterThan].push_back( FoldFClampFeedingCompare(spv::Op::OpFUnordGreaterThan)); rules_[spv::Op::OpFOrdLessThanEqual].push_back(FoldFOrdLessThanEqual()); rules_[spv::Op::OpFOrdLessThanEqual].push_back( FoldFClampFeedingCompare(spv::Op::OpFOrdLessThanEqual)); rules_[spv::Op::OpFUnordLessThanEqual].push_back(FoldFUnordLessThanEqual()); rules_[spv::Op::OpFUnordLessThanEqual].push_back( FoldFClampFeedingCompare(spv::Op::OpFUnordLessThanEqual)); rules_[spv::Op::OpFOrdGreaterThanEqual].push_back(FoldFOrdGreaterThanEqual()); rules_[spv::Op::OpFOrdGreaterThanEqual].push_back( FoldFClampFeedingCompare(spv::Op::OpFOrdGreaterThanEqual)); rules_[spv::Op::OpFUnordGreaterThanEqual].push_back( FoldFUnordGreaterThanEqual()); rules_[spv::Op::OpFUnordGreaterThanEqual].push_back( FoldFClampFeedingCompare(spv::Op::OpFUnordGreaterThanEqual)); rules_[spv::Op::OpVectorShuffle].push_back(FoldVectorShuffleWithConstants()); rules_[spv::Op::OpVectorTimesScalar].push_back(FoldVectorTimesScalar()); rules_[spv::Op::OpVectorTimesMatrix].push_back(FoldVectorTimesMatrix()); rules_[spv::Op::OpMatrixTimesVector].push_back(FoldMatrixTimesVector()); rules_[spv::Op::OpFNegate].push_back(FoldFNegate()); rules_[spv::Op::OpQuantizeToF16].push_back(FoldQuantizeToF16()); // Add rules for GLSLstd450 FeatureManager* feature_manager = context_->get_feature_mgr(); uint32_t ext_inst_glslstd450_id = feature_manager->GetExtInstImportId_GLSLstd450(); if (ext_inst_glslstd450_id != 0) { ext_rules_[{ext_inst_glslstd450_id, GLSLstd450FMix}].push_back(FoldFMix()); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450SMin}].push_back( FoldFPBinaryOp(FoldMin)); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450UMin}].push_back( FoldFPBinaryOp(FoldMin)); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450FMin}].push_back( FoldFPBinaryOp(FoldMin)); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450SMax}].push_back( FoldFPBinaryOp(FoldMax)); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450UMax}].push_back( FoldFPBinaryOp(FoldMax)); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450FMax}].push_back( FoldFPBinaryOp(FoldMax)); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450UClamp}].push_back( FoldClamp1); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450UClamp}].push_back( FoldClamp2); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450UClamp}].push_back( FoldClamp3); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450SClamp}].push_back( FoldClamp1); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450SClamp}].push_back( FoldClamp2); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450SClamp}].push_back( FoldClamp3); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450FClamp}].push_back( FoldClamp1); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450FClamp}].push_back( FoldClamp2); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450FClamp}].push_back( FoldClamp3); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Sin}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::sin))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Cos}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::cos))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Tan}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::tan))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Asin}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::asin))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Acos}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::acos))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Atan}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::atan))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Exp}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::exp))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Log}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::log))); #ifdef __ANDROID__ // Android NDK r15c targeting ABI 15 doesn't have full support for C++11 // (no std::exp2/log2). ::exp2 is available from C99 but ::log2 isn't // available up until ABI 18 so we use a shim auto log2_shim = [](double v) -> double { return log(v) / log(2.0); }; ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Exp2}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(::exp2))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Log2}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(log2_shim))); #else ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Exp2}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::exp2))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Log2}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::log2))); #endif ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Sqrt}].push_back( FoldFPUnaryOp(FoldFTranscendentalUnary(std::sqrt))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Atan2}].push_back( FoldFPBinaryOp(FoldFTranscendentalBinary(std::atan2))); ext_rules_[{ext_inst_glslstd450_id, GLSLstd450Pow}].push_back( FoldFPBinaryOp(FoldFTranscendentalBinary(std::pow))); } } } // namespace opt } // namespace spvtools