third_party/angle/src/compiler/translator/tree_util/IntermNode_util.cpp - cobalt - Git at Google

 //
 // Copyright 2017 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.
 //
 // IntermNode_util.cpp: High-level utilities for creating AST nodes and node hierarchies. Mostly
 // meant to be used in AST transforms.

 #include "compiler/translator/tree_util/IntermNode_util.h"

 #include "compiler/translator/FunctionLookup.h"
 #include "compiler/translator/SymbolTable.h"

 namespace sh
 {

 namespace
 {

 const TFunction *LookUpBuiltInFunction(const char *name,
                                        const TIntermSequence *arguments,
                                        const TSymbolTable &symbolTable,
                                        int shaderVersion)
 {
     const ImmutableString &mangledName = TFunctionLookup::GetMangledName(name, *arguments);
     const TSymbol *symbol              = symbolTable.findBuiltIn(mangledName, shaderVersion);
     if (symbol)
     {
         ASSERT(symbol->isFunction());
         return static_cast<const TFunction *>(symbol);
     }
     return nullptr;
 }

 }  // anonymous namespace

 TIntermFunctionPrototype *CreateInternalFunctionPrototypeNode(const TFunction &func)
 {
     return new TIntermFunctionPrototype(&func);
 }

 TIntermFunctionDefinition *CreateInternalFunctionDefinitionNode(const TFunction &func,
                                                                 TIntermBlock *functionBody)
 {
     return new TIntermFunctionDefinition(new TIntermFunctionPrototype(&func), functionBody);
 }

 TIntermTyped *CreateZeroNode(const TType &type)
 {
     TType constType(type);
     constType.setQualifier(EvqConst);

     if (!type.isArray() && type.getBasicType() != EbtStruct)
     {
         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:
                     // CreateZeroNode is called by ParseContext that keeps parsing even when an
                     // error occurs, so it is possible for CreateZeroNode to be called with
                     // non-basic types. This happens only on error condition but CreateZeroNode
                     // needs to return a value with the correct type to continue the typecheck.
                     // That's why we handle non-basic type by setting whatever value, we just need
                     // the type to be right.
                     u[i].setIConst(42);
                     break;
             }
         }

         TIntermConstantUnion *node = new TIntermConstantUnion(u, constType);
         return node;
     }

     TIntermSequence *arguments = new TIntermSequence();

     if (type.isArray())
     {
         TType elementType(type);
         elementType.toArrayElementType();

         size_t arraySize = type.getOutermostArraySize();
         for (size_t i = 0; i < arraySize; ++i)
         {
             arguments->push_back(CreateZeroNode(elementType));
         }
     }
     else
     {
         ASSERT(type.getBasicType() == EbtStruct);

         const TStructure *structure = type.getStruct();
         for (const auto &field : structure->fields())
         {
             arguments->push_back(CreateZeroNode(*field->type()));
         }
     }

     return TIntermAggregate::CreateConstructor(constType, arguments);
 }

 TIntermConstantUnion *CreateFloatNode(float value)
 {
     TConstantUnion *u = new TConstantUnion[1];
     u[0].setFConst(value);

     TType type(EbtFloat, EbpUndefined, EvqConst, 1);
     return new TIntermConstantUnion(u, type);
 }

 TIntermConstantUnion *CreateIndexNode(int index)
 {
     TConstantUnion *u = new TConstantUnion[1];
     u[0].setIConst(index);

     TType type(EbtInt, EbpUndefined, EvqConst, 1);
     return new TIntermConstantUnion(u, type);
 }

 TIntermConstantUnion *CreateBoolNode(bool value)
 {
     TConstantUnion *u = new TConstantUnion[1];
     u[0].setBConst(value);

     TType type(EbtBool, EbpUndefined, EvqConst, 1);
     return new TIntermConstantUnion(u, type);
 }

 TVariable *CreateTempVariable(TSymbolTable *symbolTable, const TType *type)
 {
     ASSERT(symbolTable != nullptr);
     // TODO(oetuaho): Might be useful to sanitize layout qualifier etc. on the type of the created
     // variable. This might need to be done in other places as well.
     return new TVariable(symbolTable, kEmptyImmutableString, type, SymbolType::AngleInternal);
 }

 TVariable *CreateTempVariable(TSymbolTable *symbolTable, const TType *type, TQualifier qualifier)
 {
     ASSERT(symbolTable != nullptr);
     if (type->getQualifier() == qualifier)
     {
         return CreateTempVariable(symbolTable, type);
     }
     TType *typeWithQualifier = new TType(*type);
     typeWithQualifier->setQualifier(qualifier);
     return CreateTempVariable(symbolTable, typeWithQualifier);
 }

 TIntermSymbol *CreateTempSymbolNode(const TVariable *tempVariable)
 {
     ASSERT(tempVariable->symbolType() == SymbolType::AngleInternal);
     ASSERT(tempVariable->getType().getQualifier() == EvqTemporary ||
            tempVariable->getType().getQualifier() == EvqConst ||
            tempVariable->getType().getQualifier() == EvqGlobal);
     return new TIntermSymbol(tempVariable);
 }

 TIntermDeclaration *CreateTempDeclarationNode(const TVariable *tempVariable)
 {
     TIntermDeclaration *tempDeclaration = new TIntermDeclaration();
     tempDeclaration->appendDeclarator(CreateTempSymbolNode(tempVariable));
     return tempDeclaration;
 }

 TIntermDeclaration *CreateTempInitDeclarationNode(const TVariable *tempVariable,
                                                   TIntermTyped *initializer)
 {
     ASSERT(initializer != nullptr);
     TIntermSymbol *tempSymbol           = CreateTempSymbolNode(tempVariable);
     TIntermDeclaration *tempDeclaration = new TIntermDeclaration();
     TIntermBinary *tempInit             = new TIntermBinary(EOpInitialize, tempSymbol, initializer);
     tempDeclaration->appendDeclarator(tempInit);
     return tempDeclaration;
 }

 TIntermBinary *CreateTempAssignmentNode(const TVariable *tempVariable, TIntermTyped *rightNode)
 {
     ASSERT(rightNode != nullptr);
     TIntermSymbol *tempSymbol = CreateTempSymbolNode(tempVariable);
     return new TIntermBinary(EOpAssign, tempSymbol, rightNode);
 }

 TVariable *DeclareTempVariable(TSymbolTable *symbolTable,
                                const TType *type,
                                TQualifier qualifier,
                                TIntermDeclaration **declarationOut)
 {
     TVariable *variable = CreateTempVariable(symbolTable, type, qualifier);
     *declarationOut     = CreateTempDeclarationNode(variable);
     return variable;
 }

 TVariable *DeclareTempVariable(TSymbolTable *symbolTable,
                                TIntermTyped *initializer,
                                TQualifier qualifier,
                                TIntermDeclaration **declarationOut)
 {
     TVariable *variable =
         CreateTempVariable(symbolTable, new TType(initializer->getType()), qualifier);
     *declarationOut = CreateTempInitDeclarationNode(variable, initializer);
     return variable;
 }

 const TVariable *DeclareInterfaceBlock(TIntermBlock *root,
                                        TSymbolTable *symbolTable,
                                        TFieldList *fieldList,
                                        TQualifier qualifier,
                                        const TMemoryQualifier &memoryQualifier,
                                        uint32_t arraySize,
                                        const ImmutableString &blockTypeName,
                                        const ImmutableString &blockVariableName)
 {
     // Define an interface block.
     TLayoutQualifier layoutQualifier = TLayoutQualifier::Create();
     TInterfaceBlock *interfaceBlock  = new TInterfaceBlock(
         symbolTable, blockTypeName, fieldList, layoutQualifier, SymbolType::AngleInternal);

     // Turn the inteface block into a declaration.
     TType *interfaceBlockType = new TType(interfaceBlock, qualifier, layoutQualifier);
     interfaceBlockType->setMemoryQualifier(memoryQualifier);
     if (arraySize > 0)
     {
         interfaceBlockType->makeArray(arraySize);
     }

     TIntermDeclaration *interfaceBlockDecl = new TIntermDeclaration;
     TVariable *interfaceBlockVar = new TVariable(symbolTable, blockVariableName, interfaceBlockType,
                                                  SymbolType::AngleInternal);
     TIntermSymbol *interfaceBlockDeclarator = new TIntermSymbol(interfaceBlockVar);
     interfaceBlockDecl->appendDeclarator(interfaceBlockDeclarator);

     // Insert the declarations before the first function.
     TIntermSequence *insertSequence = new TIntermSequence;
     insertSequence->push_back(interfaceBlockDecl);

     size_t firstFunctionIndex = FindFirstFunctionDefinitionIndex(root);
     root->insertChildNodes(firstFunctionIndex, *insertSequence);

     return interfaceBlockVar;
 }

 TIntermBlock *EnsureBlock(TIntermNode *node)
 {
     if (node == nullptr)
         return nullptr;
     TIntermBlock *blockNode = node->getAsBlock();
     if (blockNode != nullptr)
         return blockNode;

     blockNode = new TIntermBlock();
     blockNode->setLine(node->getLine());
     blockNode->appendStatement(node);
     return blockNode;
 }

 TIntermSymbol *ReferenceGlobalVariable(const ImmutableString &name, const TSymbolTable &symbolTable)
 {
     const TVariable *var = static_cast<const TVariable *>(symbolTable.findGlobal(name));
     ASSERT(var);
     return new TIntermSymbol(var);
 }

 TIntermSymbol *ReferenceBuiltInVariable(const ImmutableString &name,
                                         const TSymbolTable &symbolTable,
                                         int shaderVersion)
 {
     const TVariable *var =
         static_cast<const TVariable *>(symbolTable.findBuiltIn(name, shaderVersion));
     ASSERT(var);
     return new TIntermSymbol(var);
 }

 TIntermTyped *CreateBuiltInFunctionCallNode(const char *name,
                                             TIntermSequence *arguments,
                                             const TSymbolTable &symbolTable,
                                             int shaderVersion)
 {
     const TFunction *fn = LookUpBuiltInFunction(name, arguments, symbolTable, shaderVersion);
     ASSERT(fn);
     TOperator op = fn->getBuiltInOp();
     if (op != EOpCallBuiltInFunction && arguments->size() == 1)
     {
         return new TIntermUnary(op, arguments->at(0)->getAsTyped(), fn);
     }
     return TIntermAggregate::CreateBuiltInFunctionCall(*fn, arguments);
 }

 }  // namespace sh
	//
	// Copyright 2017 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.
	//
	// IntermNode_util.cpp: High-level utilities for creating AST nodes and node hierarchies. Mostly
	// meant to be used in AST transforms.

	#include "compiler/translator/tree_util/IntermNode_util.h"

	#include "compiler/translator/FunctionLookup.h"
	#include "compiler/translator/SymbolTable.h"

	namespace sh
	{

	namespace
	{

	const TFunction LookUpBuiltInFunction(const char name,
	const TIntermSequence *arguments,
	const TSymbolTable &symbolTable,
	int shaderVersion)
	{
	const ImmutableString &mangledName = TFunctionLookup::GetMangledName(name, *arguments);
	const TSymbol *symbol = symbolTable.findBuiltIn(mangledName, shaderVersion);
	if (symbol)
	{
	ASSERT(symbol->isFunction());
	return static_cast<const TFunction *>(symbol);
	}
	return nullptr;
	}

	} // anonymous namespace

	TIntermFunctionPrototype *CreateInternalFunctionPrototypeNode(const TFunction &func)
	{
	return new TIntermFunctionPrototype(&func);
	}

	TIntermFunctionDefinition *CreateInternalFunctionDefinitionNode(const TFunction &func,
	TIntermBlock *functionBody)
	{
	return new TIntermFunctionDefinition(new TIntermFunctionPrototype(&func), functionBody);
	}

	TIntermTyped *CreateZeroNode(const TType &type)
	{
	TType constType(type);
	constType.setQualifier(EvqConst);

	if (!type.isArray() && type.getBasicType() != EbtStruct)
	{
	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:
	// CreateZeroNode is called by ParseContext that keeps parsing even when an
	// error occurs, so it is possible for CreateZeroNode to be called with
	// non-basic types. This happens only on error condition but CreateZeroNode
	// needs to return a value with the correct type to continue the typecheck.
	// That's why we handle non-basic type by setting whatever value, we just need
	// the type to be right.
	u[i].setIConst(42);
	break;
	}
	}

	TIntermConstantUnion *node = new TIntermConstantUnion(u, constType);
	return node;
	}

	TIntermSequence *arguments = new TIntermSequence();

	if (type.isArray())
	{
	TType elementType(type);
	elementType.toArrayElementType();

	size_t arraySize = type.getOutermostArraySize();
	for (size_t i = 0; i < arraySize; ++i)
	{
	arguments->push_back(CreateZeroNode(elementType));
	}
	}
	else
	{
	ASSERT(type.getBasicType() == EbtStruct);

	const TStructure *structure = type.getStruct();
	for (const auto &field : structure->fields())
	{
	arguments->push_back(CreateZeroNode(*field->type()));
	}
	}

	return TIntermAggregate::CreateConstructor(constType, arguments);
	}

	TIntermConstantUnion *CreateFloatNode(float value)
	{
	TConstantUnion *u = new TConstantUnion[1];
	u[0].setFConst(value);

	TType type(EbtFloat, EbpUndefined, EvqConst, 1);
	return new TIntermConstantUnion(u, type);
	}

	TIntermConstantUnion *CreateIndexNode(int index)
	{
	TConstantUnion *u = new TConstantUnion[1];
	u[0].setIConst(index);

	TType type(EbtInt, EbpUndefined, EvqConst, 1);
	return new TIntermConstantUnion(u, type);
	}

	TIntermConstantUnion *CreateBoolNode(bool value)
	{
	TConstantUnion *u = new TConstantUnion[1];
	u[0].setBConst(value);

	TType type(EbtBool, EbpUndefined, EvqConst, 1);
	return new TIntermConstantUnion(u, type);
	}

	TVariable CreateTempVariable(TSymbolTable symbolTable, const TType *type)
	{
	ASSERT(symbolTable != nullptr);
	// TODO(oetuaho): Might be useful to sanitize layout qualifier etc. on the type of the created
	// variable. This might need to be done in other places as well.
	return new TVariable(symbolTable, kEmptyImmutableString, type, SymbolType::AngleInternal);
	}

	TVariable CreateTempVariable(TSymbolTable symbolTable, const TType *type, TQualifier qualifier)
	{
	ASSERT(symbolTable != nullptr);
	if (type->getQualifier() == qualifier)
	{
	return CreateTempVariable(symbolTable, type);
	}
	TType typeWithQualifier = new TType(type);
	typeWithQualifier->setQualifier(qualifier);
	return CreateTempVariable(symbolTable, typeWithQualifier);
	}

	TIntermSymbol CreateTempSymbolNode(const TVariable tempVariable)
	{
	ASSERT(tempVariable->symbolType() == SymbolType::AngleInternal);
	ASSERT(tempVariable->getType().getQualifier() == EvqTemporary \|\|
	tempVariable->getType().getQualifier() == EvqConst \|\|
	tempVariable->getType().getQualifier() == EvqGlobal);
	return new TIntermSymbol(tempVariable);
	}

	TIntermDeclaration CreateTempDeclarationNode(const TVariable tempVariable)
	{
	TIntermDeclaration *tempDeclaration = new TIntermDeclaration();
	tempDeclaration->appendDeclarator(CreateTempSymbolNode(tempVariable));
	return tempDeclaration;
	}

	TIntermDeclaration CreateTempInitDeclarationNode(const TVariable tempVariable,
	TIntermTyped *initializer)
	{
	ASSERT(initializer != nullptr);
	TIntermSymbol *tempSymbol = CreateTempSymbolNode(tempVariable);
	TIntermDeclaration *tempDeclaration = new TIntermDeclaration();
	TIntermBinary *tempInit = new TIntermBinary(EOpInitialize, tempSymbol, initializer);
	tempDeclaration->appendDeclarator(tempInit);
	return tempDeclaration;
	}

	TIntermBinary CreateTempAssignmentNode(const TVariable tempVariable, TIntermTyped *rightNode)
	{
	ASSERT(rightNode != nullptr);
	TIntermSymbol *tempSymbol = CreateTempSymbolNode(tempVariable);
	return new TIntermBinary(EOpAssign, tempSymbol, rightNode);
	}

	TVariable DeclareTempVariable(TSymbolTable symbolTable,
	const TType *type,
	TQualifier qualifier,
	TIntermDeclaration **declarationOut)
	{
	TVariable *variable = CreateTempVariable(symbolTable, type, qualifier);
	*declarationOut = CreateTempDeclarationNode(variable);
	return variable;
	}

	TVariable DeclareTempVariable(TSymbolTable symbolTable,
	TIntermTyped *initializer,
	TQualifier qualifier,
	TIntermDeclaration **declarationOut)
	{
	TVariable *variable =
	CreateTempVariable(symbolTable, new TType(initializer->getType()), qualifier);
	*declarationOut = CreateTempInitDeclarationNode(variable, initializer);
	return variable;
	}

	const TVariable DeclareInterfaceBlock(TIntermBlock root,
	TSymbolTable *symbolTable,
	TFieldList *fieldList,
	TQualifier qualifier,
	const TMemoryQualifier &memoryQualifier,
	uint32_t arraySize,
	const ImmutableString &blockTypeName,
	const ImmutableString &blockVariableName)
	{
	// Define an interface block.
	TLayoutQualifier layoutQualifier = TLayoutQualifier::Create();
	TInterfaceBlock *interfaceBlock = new TInterfaceBlock(
	symbolTable, blockTypeName, fieldList, layoutQualifier, SymbolType::AngleInternal);

	// Turn the inteface block into a declaration.
	TType *interfaceBlockType = new TType(interfaceBlock, qualifier, layoutQualifier);
	interfaceBlockType->setMemoryQualifier(memoryQualifier);
	if (arraySize > 0)
	{
	interfaceBlockType->makeArray(arraySize);
	}

	TIntermDeclaration *interfaceBlockDecl = new TIntermDeclaration;
	TVariable *interfaceBlockVar = new TVariable(symbolTable, blockVariableName, interfaceBlockType,
	SymbolType::AngleInternal);
	TIntermSymbol *interfaceBlockDeclarator = new TIntermSymbol(interfaceBlockVar);
	interfaceBlockDecl->appendDeclarator(interfaceBlockDeclarator);

	// Insert the declarations before the first function.
	TIntermSequence *insertSequence = new TIntermSequence;
	insertSequence->push_back(interfaceBlockDecl);

	size_t firstFunctionIndex = FindFirstFunctionDefinitionIndex(root);
	root->insertChildNodes(firstFunctionIndex, *insertSequence);

	return interfaceBlockVar;
	}

	TIntermBlock EnsureBlock(TIntermNode node)
	{
	if (node == nullptr)
	return nullptr;
	TIntermBlock *blockNode = node->getAsBlock();
	if (blockNode != nullptr)
	return blockNode;

	blockNode = new TIntermBlock();
	blockNode->setLine(node->getLine());
	blockNode->appendStatement(node);
	return blockNode;
	}

	TIntermSymbol *ReferenceGlobalVariable(const ImmutableString &name, const TSymbolTable &symbolTable)
	{
	const TVariable var = static_cast<const TVariable >(symbolTable.findGlobal(name));
	ASSERT(var);
	return new TIntermSymbol(var);
	}

	TIntermSymbol *ReferenceBuiltInVariable(const ImmutableString &name,
	const TSymbolTable &symbolTable,
	int shaderVersion)
	{
	const TVariable *var =
	static_cast<const TVariable *>(symbolTable.findBuiltIn(name, shaderVersion));
	ASSERT(var);
	return new TIntermSymbol(var);
	}

	TIntermTyped CreateBuiltInFunctionCallNode(const char name,
	TIntermSequence *arguments,
	const TSymbolTable &symbolTable,
	int shaderVersion)
	{
	const TFunction *fn = LookUpBuiltInFunction(name, arguments, symbolTable, shaderVersion);
	ASSERT(fn);
	TOperator op = fn->getBuiltInOp();
	if (op != EOpCallBuiltInFunction && arguments->size() == 1)
	{
	return new TIntermUnary(op, arguments->at(0)->getAsTyped(), fn);
	}
	return TIntermAggregate::CreateBuiltInFunctionCall(*fn, arguments);
	}

	} // namespace sh