src/compiler/translator/IntermTraverse.cpp - platform/external/angle - Gitiles

 //
 // Copyright (c) 2002-2010 The ANGLE Project Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //

 #include "compiler/translator/IntermNode.h"
 #include "compiler/translator/InfoSink.h"

 void TIntermTraverser::pushParentBlock(TIntermAggregate *node)
 {
     mParentBlockStack.push_back(ParentBlock(node, 0));
 }

 void TIntermTraverser::incrementParentBlockPos()
 {
     ++mParentBlockStack.back().pos;
 }

 void TIntermTraverser::popParentBlock()
 {
     ASSERT(!mParentBlockStack.empty());
     mParentBlockStack.pop_back();
 }

 void TIntermTraverser::insertStatementsInParentBlock(const TIntermSequence &insertions)
 {
     ASSERT(!mParentBlockStack.empty());
     NodeInsertMultipleEntry insert(mParentBlockStack.back().node, mParentBlockStack.back().pos, insertions);
     mInsertions.push_back(insert);
 }

 TIntermSymbol *TIntermTraverser::createTempSymbol(const TType &type, TQualifier qualifier)
 {
     // Each traversal uses at most one temporary variable, so the index stays the same within a single traversal.
     TInfoSinkBase symbolNameOut;
     ASSERT(mTemporaryIndex != nullptr);
     symbolNameOut << "s" << (*mTemporaryIndex);
     TString symbolName = symbolNameOut.c_str();

     TIntermSymbol *node = new TIntermSymbol(0, symbolName, type);
     node->setInternal(true);
     node->getTypePointer()->setQualifier(qualifier);
     return node;
 }

 TIntermSymbol *TIntermTraverser::createTempSymbol(const TType &type)
 {
     return createTempSymbol(type, EvqTemporary);
 }

 TIntermAggregate *TIntermTraverser::createTempDeclaration(const TType &type)
 {
     TIntermAggregate *tempDeclaration = new TIntermAggregate(EOpDeclaration);
     tempDeclaration->getSequence()->push_back(createTempSymbol(type));
     return tempDeclaration;
 }

 TIntermAggregate *TIntermTraverser::createTempInitDeclaration(TIntermTyped *initializer, TQualifier qualifier)
 {
     ASSERT(initializer != nullptr);
     TIntermSymbol *tempSymbol = createTempSymbol(initializer->getType(), qualifier);
     TIntermAggregate *tempDeclaration = new TIntermAggregate(EOpDeclaration);
     TIntermBinary *tempInit = new TIntermBinary(EOpInitialize);
     tempInit->setLeft(tempSymbol);
     tempInit->setRight(initializer);
     tempInit->setType(tempSymbol->getType());
     tempDeclaration->getSequence()->push_back(tempInit);
     return tempDeclaration;
 }

 TIntermAggregate *TIntermTraverser::createTempInitDeclaration(TIntermTyped *initializer)
 {
     return createTempInitDeclaration(initializer, EvqTemporary);
 }

 TIntermBinary *TIntermTraverser::createTempAssignment(TIntermTyped *rightNode)
 {
     ASSERT(rightNode != nullptr);
     TIntermSymbol *tempSymbol = createTempSymbol(rightNode->getType());
     TIntermBinary *assignment = new TIntermBinary(EOpAssign);
     assignment->setLeft(tempSymbol);
     assignment->setRight(rightNode);
     assignment->setType(tempSymbol->getType());
     return assignment;
 }

 void TIntermTraverser::useTemporaryIndex(unsigned int *temporaryIndex)
 {
     mTemporaryIndex = temporaryIndex;
 }

 void TIntermTraverser::nextTemporaryIndex()
 {
     ASSERT(mTemporaryIndex != nullptr);
     ++(*mTemporaryIndex);
 }

 void TIntermTraverser::addToFunctionMap(const TString &name, TIntermSequence *paramSequence)
 {
     mFunctionMap[name] = paramSequence;
 }

 bool TIntermTraverser::isInFunctionMap(const TIntermAggregate *callNode) const
 {
     ASSERT(callNode->getOp() == EOpFunctionCall || callNode->getOp() == EOpInternalFunctionCall);
     return (mFunctionMap.find(callNode->getName()) != mFunctionMap.end());
 }

 TIntermSequence *TIntermTraverser::getFunctionParameters(const TIntermAggregate *callNode)
 {
     ASSERT(isInFunctionMap(callNode));
     return mFunctionMap[callNode->getName()];
 }

 void TIntermTraverser::setInFunctionCallOutParameter(bool inOutParameter)
 {
     mInFunctionCallOutParameter = inOutParameter;
 }

 //
 // Traverse the intermediate representation tree, and
 // call a node type specific function for each node.
 // Done recursively through the member function Traverse().
 // Node types can be skipped if their function to call is 0,
 // but their subtree will still be traversed.
 // Nodes with children can have their whole subtree skipped
 // if preVisit is turned on and the type specific function
 // returns false.
 //

 //
 // Traversal functions for terminals are straighforward....
 //
 void TIntermSymbol::traverse(TIntermTraverser *it)
 {
     it->visitSymbol(this);
 }

 void TIntermConstantUnion::traverse(TIntermTraverser *it)
 {
     it->visitConstantUnion(this);
 }

 //
 // Traverse a binary node.
 //
 void TIntermBinary::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     //
     // visit the node before children if pre-visiting.
     //
     if (it->preVisit)
         visit = it->visitBinary(PreVisit, this);

     //
     // Visit the children, in the right order.
     //
     if (visit)
     {
         it->incrementDepth(this);

         if (isAssignment())
         {
             // Some binary operations like indexing can be inside an l-value.
             // TODO(oetuaho@nvidia.com): Now the code doesn't unset operatorRequiresLValue for the
             // index, fix this.
             it->setOperatorRequiresLValue(true);
         }

         if (mLeft)
             mLeft->traverse(it);

         if (it->inVisit)
             visit = it->visitBinary(InVisit, this);

         if (isAssignment())
             it->setOperatorRequiresLValue(false);

         if (visit && mRight)
             mRight->traverse(it);

         it->decrementDepth();
     }

     //
     // Visit the node after the children, if requested and the traversal
     // hasn't been cancelled yet.
     //
     if (visit && it->postVisit)
         it->visitBinary(PostVisit, this);
 }

 //
 // Traverse a unary node.  Same comments in binary node apply here.
 //
 void TIntermUnary::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     if (it->preVisit)
         visit = it->visitUnary(PreVisit, this);

     if (visit)
     {
         it->incrementDepth(this);

         switch (getOp())
         {
             case EOpPostIncrement:
             case EOpPostDecrement:
             case EOpPreIncrement:
             case EOpPreDecrement:
                 it->setOperatorRequiresLValue(true);
                 break;
             default:
                 break;
         }

         mOperand->traverse(it);

         it->setOperatorRequiresLValue(false);

         it->decrementDepth();
     }

     if (visit && it->postVisit)
         it->visitUnary(PostVisit, this);
 }

 //
 // Traverse an aggregate node.  Same comments in binary node apply here.
 //
 void TIntermAggregate::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     switch (mOp)
     {
         case EOpFunction:
         {
             TIntermAggregate *params = mSequence.front()->getAsAggregate();
             ASSERT(params != nullptr);
             ASSERT(params->getOp() == EOpParameters);
             it->addToFunctionMap(mName, params->getSequence());
             break;
         }
         case EOpPrototype:
             it->addToFunctionMap(mName, &mSequence);
             break;
         default:
             break;
     }

     if (it->preVisit)
         visit = it->visitAggregate(PreVisit, this);

     if (visit)
     {
         bool inFunctionMap = false;
         if (mOp == EOpFunctionCall)
         {
             inFunctionMap = it->isInFunctionMap(this);
             if (!inFunctionMap)
             {
                 // The function is not user-defined - it is likely built-in texture function.
                 // Assume that those do not have out parameters.
                 it->setInFunctionCallOutParameter(false);
             }
         }

         it->incrementDepth(this);

         if (inFunctionMap)
         {
             TIntermSequence *params             = it->getFunctionParameters(this);
             TIntermSequence::iterator paramIter = params->begin();
             for (auto *child : mSequence)
             {
                 ASSERT(paramIter != params->end());
                 TQualifier qualifier = (*paramIter)->getAsTyped()->getQualifier();
                 it->setInFunctionCallOutParameter(qualifier == EvqOut || qualifier == EvqInOut);

                 child->traverse(it);
                 if (visit && it->inVisit)
                 {
                     if (child != mSequence.back())
                         visit = it->visitAggregate(InVisit, this);
                 }

                 ++paramIter;
             }

             it->setInFunctionCallOutParameter(false);
         }
         else
         {
             if (mOp == EOpSequence)
                 it->pushParentBlock(this);

             for (auto *child : mSequence)
             {
                 child->traverse(it);
                 if (visit && it->inVisit)
                 {
                     if (child != mSequence.back())
                         visit = it->visitAggregate(InVisit, this);
                 }

                 if (mOp == EOpSequence)
                     it->incrementParentBlockPos();
             }

             if (mOp == EOpSequence)
                 it->popParentBlock();
         }

         it->decrementDepth();
     }

     if (visit && it->postVisit)
         it->visitAggregate(PostVisit, this);
 }

 //
 // Traverse a selection node.  Same comments in binary node apply here.
 //
 void TIntermSelection::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     if (it->preVisit)
         visit = it->visitSelection(PreVisit, this);

     if (visit)
     {
         it->incrementDepth(this);
         mCondition->traverse(it);
         if (mTrueBlock)
             mTrueBlock->traverse(it);
         if (mFalseBlock)
             mFalseBlock->traverse(it);
         it->decrementDepth();
     }

     if (visit && it->postVisit)
         it->visitSelection(PostVisit, this);
 }

 //
 // Traverse a switch node.  Same comments in binary node apply here.
 //
 void TIntermSwitch::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     if (it->preVisit)
         visit = it->visitSwitch(PreVisit, this);

     if (visit)
     {
         it->incrementDepth(this);
         mInit->traverse(it);
         if (it->inVisit)
             visit = it->visitSwitch(InVisit, this);
         if (visit && mStatementList)
             mStatementList->traverse(it);
         it->decrementDepth();
     }

     if (visit && it->postVisit)
         it->visitSwitch(PostVisit, this);
 }

 //
 // Traverse a switch node.  Same comments in binary node apply here.
 //
 void TIntermCase::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     if (it->preVisit)
         visit = it->visitCase(PreVisit, this);

     if (visit && mCondition)
         mCondition->traverse(it);

     if (visit && it->postVisit)
         it->visitCase(PostVisit, this);
 }

 //
 // Traverse a loop node.  Same comments in binary node apply here.
 //
 void TIntermLoop::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     if (it->preVisit)
         visit = it->visitLoop(PreVisit, this);

     if (visit)
     {
         it->incrementDepth(this);

         if (mInit)
             mInit->traverse(it);

         if (mCond)
             mCond->traverse(it);

         if (mBody)
             mBody->traverse(it);

         if (mExpr)
             mExpr->traverse(it);

         it->decrementDepth();
     }

     if (visit && it->postVisit)
         it->visitLoop(PostVisit, this);
 }

 //
 // Traverse a branch node.  Same comments in binary node apply here.
 //
 void TIntermBranch::traverse(TIntermTraverser *it)
 {
     bool visit = true;

     if (it->preVisit)
         visit = it->visitBranch(PreVisit, this);

     if (visit && mExpression) {
         it->incrementDepth(this);
         mExpression->traverse(it);
         it->decrementDepth();
     }

     if (visit && it->postVisit)
         it->visitBranch(PostVisit, this);
 }

 void TIntermRaw::traverse(TIntermTraverser *it)
 {
     it->visitRaw(this);
 }
	//
	// Copyright (c) 2002-2010 The ANGLE Project Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//

	#include "compiler/translator/IntermNode.h"
	#include "compiler/translator/InfoSink.h"

	void TIntermTraverser::pushParentBlock(TIntermAggregate *node)
	{
	mParentBlockStack.push_back(ParentBlock(node, 0));
	}

	void TIntermTraverser::incrementParentBlockPos()
	{
	++mParentBlockStack.back().pos;
	}

	void TIntermTraverser::popParentBlock()
	{
	ASSERT(!mParentBlockStack.empty());
	mParentBlockStack.pop_back();
	}

	void TIntermTraverser::insertStatementsInParentBlock(const TIntermSequence &insertions)
	{
	ASSERT(!mParentBlockStack.empty());
	NodeInsertMultipleEntry insert(mParentBlockStack.back().node, mParentBlockStack.back().pos, insertions);
	mInsertions.push_back(insert);
	}

	TIntermSymbol *TIntermTraverser::createTempSymbol(const TType &type, TQualifier qualifier)
	{
	// Each traversal uses at most one temporary variable, so the index stays the same within a single traversal.
	TInfoSinkBase symbolNameOut;
	ASSERT(mTemporaryIndex != nullptr);
	symbolNameOut << "s" << (*mTemporaryIndex);
	TString symbolName = symbolNameOut.c_str();

	TIntermSymbol *node = new TIntermSymbol(0, symbolName, type);
	node->setInternal(true);
	node->getTypePointer()->setQualifier(qualifier);
	return node;
	}

	TIntermSymbol *TIntermTraverser::createTempSymbol(const TType &type)
	{
	return createTempSymbol(type, EvqTemporary);
	}

	TIntermAggregate *TIntermTraverser::createTempDeclaration(const TType &type)
	{
	TIntermAggregate *tempDeclaration = new TIntermAggregate(EOpDeclaration);
	tempDeclaration->getSequence()->push_back(createTempSymbol(type));
	return tempDeclaration;
	}

	TIntermAggregate TIntermTraverser::createTempInitDeclaration(TIntermTyped initializer, TQualifier qualifier)
	{
	ASSERT(initializer != nullptr);
	TIntermSymbol *tempSymbol = createTempSymbol(initializer->getType(), qualifier);
	TIntermAggregate *tempDeclaration = new TIntermAggregate(EOpDeclaration);
	TIntermBinary *tempInit = new TIntermBinary(EOpInitialize);
	tempInit->setLeft(tempSymbol);
	tempInit->setRight(initializer);
	tempInit->setType(tempSymbol->getType());
	tempDeclaration->getSequence()->push_back(tempInit);
	return tempDeclaration;
	}

	TIntermAggregate TIntermTraverser::createTempInitDeclaration(TIntermTyped initializer)
	{
	return createTempInitDeclaration(initializer, EvqTemporary);
	}

	TIntermBinary TIntermTraverser::createTempAssignment(TIntermTyped rightNode)
	{
	ASSERT(rightNode != nullptr);
	TIntermSymbol *tempSymbol = createTempSymbol(rightNode->getType());
	TIntermBinary *assignment = new TIntermBinary(EOpAssign);
	assignment->setLeft(tempSymbol);
	assignment->setRight(rightNode);
	assignment->setType(tempSymbol->getType());
	return assignment;
	}

	void TIntermTraverser::useTemporaryIndex(unsigned int *temporaryIndex)
	{
	mTemporaryIndex = temporaryIndex;
	}

	void TIntermTraverser::nextTemporaryIndex()
	{
	ASSERT(mTemporaryIndex != nullptr);
	++(*mTemporaryIndex);
	}

	void TIntermTraverser::addToFunctionMap(const TString &name, TIntermSequence *paramSequence)
	{
	mFunctionMap[name] = paramSequence;
	}

	bool TIntermTraverser::isInFunctionMap(const TIntermAggregate *callNode) const
	{
	ASSERT(callNode->getOp() == EOpFunctionCall \|\| callNode->getOp() == EOpInternalFunctionCall);
	return (mFunctionMap.find(callNode->getName()) != mFunctionMap.end());
	}

	TIntermSequence TIntermTraverser::getFunctionParameters(const TIntermAggregate callNode)
	{
	ASSERT(isInFunctionMap(callNode));
	return mFunctionMap[callNode->getName()];
	}

	void TIntermTraverser::setInFunctionCallOutParameter(bool inOutParameter)
	{
	mInFunctionCallOutParameter = inOutParameter;
	}

	//
	// Traverse the intermediate representation tree, and
	// call a node type specific function for each node.
	// Done recursively through the member function Traverse().
	// Node types can be skipped if their function to call is 0,
	// but their subtree will still be traversed.
	// Nodes with children can have their whole subtree skipped
	// if preVisit is turned on and the type specific function
	// returns false.
	//

	//
	// Traversal functions for terminals are straighforward....
	//
	void TIntermSymbol::traverse(TIntermTraverser *it)
	{
	it->visitSymbol(this);
	}

	void TIntermConstantUnion::traverse(TIntermTraverser *it)
	{
	it->visitConstantUnion(this);
	}

	//
	// Traverse a binary node.
	//
	void TIntermBinary::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	//
	// visit the node before children if pre-visiting.
	//
	if (it->preVisit)
	visit = it->visitBinary(PreVisit, this);

	//
	// Visit the children, in the right order.
	//
	if (visit)
	{
	it->incrementDepth(this);

	if (isAssignment())
	{
	// Some binary operations like indexing can be inside an l-value.
	// TODO(oetuaho@nvidia.com): Now the code doesn't unset operatorRequiresLValue for the
	// index, fix this.
	it->setOperatorRequiresLValue(true);
	}

	if (mLeft)
	mLeft->traverse(it);

	if (it->inVisit)
	visit = it->visitBinary(InVisit, this);

	if (isAssignment())
	it->setOperatorRequiresLValue(false);

	if (visit && mRight)
	mRight->traverse(it);

	it->decrementDepth();
	}

	//
	// Visit the node after the children, if requested and the traversal
	// hasn't been cancelled yet.
	//
	if (visit && it->postVisit)
	it->visitBinary(PostVisit, this);
	}

	//
	// Traverse a unary node. Same comments in binary node apply here.
	//
	void TIntermUnary::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	if (it->preVisit)
	visit = it->visitUnary(PreVisit, this);

	if (visit)
	{
	it->incrementDepth(this);

	switch (getOp())
	{
	case EOpPostIncrement:
	case EOpPostDecrement:
	case EOpPreIncrement:
	case EOpPreDecrement:
	it->setOperatorRequiresLValue(true);
	break;
	default:
	break;
	}

	mOperand->traverse(it);

	it->setOperatorRequiresLValue(false);

	it->decrementDepth();
	}

	if (visit && it->postVisit)
	it->visitUnary(PostVisit, this);
	}

	//
	// Traverse an aggregate node. Same comments in binary node apply here.
	//
	void TIntermAggregate::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	switch (mOp)
	{
	case EOpFunction:
	{
	TIntermAggregate *params = mSequence.front()->getAsAggregate();
	ASSERT(params != nullptr);
	ASSERT(params->getOp() == EOpParameters);
	it->addToFunctionMap(mName, params->getSequence());
	break;
	}
	case EOpPrototype:
	it->addToFunctionMap(mName, &mSequence);
	break;
	default:
	break;
	}

	if (it->preVisit)
	visit = it->visitAggregate(PreVisit, this);

	if (visit)
	{
	bool inFunctionMap = false;
	if (mOp == EOpFunctionCall)
	{
	inFunctionMap = it->isInFunctionMap(this);
	if (!inFunctionMap)
	{
	// The function is not user-defined - it is likely built-in texture function.
	// Assume that those do not have out parameters.
	it->setInFunctionCallOutParameter(false);
	}
	}

	it->incrementDepth(this);

	if (inFunctionMap)
	{
	TIntermSequence *params = it->getFunctionParameters(this);
	TIntermSequence::iterator paramIter = params->begin();
	for (auto *child : mSequence)
	{
	ASSERT(paramIter != params->end());
	TQualifier qualifier = (*paramIter)->getAsTyped()->getQualifier();
	it->setInFunctionCallOutParameter(qualifier == EvqOut \|\| qualifier == EvqInOut);

	child->traverse(it);
	if (visit && it->inVisit)
	{
	if (child != mSequence.back())
	visit = it->visitAggregate(InVisit, this);
	}

	++paramIter;
	}

	it->setInFunctionCallOutParameter(false);
	}
	else
	{
	if (mOp == EOpSequence)
	it->pushParentBlock(this);

	for (auto *child : mSequence)
	{
	child->traverse(it);
	if (visit && it->inVisit)
	{
	if (child != mSequence.back())
	visit = it->visitAggregate(InVisit, this);
	}

	if (mOp == EOpSequence)
	it->incrementParentBlockPos();
	}

	if (mOp == EOpSequence)
	it->popParentBlock();
	}

	it->decrementDepth();
	}

	if (visit && it->postVisit)
	it->visitAggregate(PostVisit, this);
	}

	//
	// Traverse a selection node. Same comments in binary node apply here.
	//
	void TIntermSelection::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	if (it->preVisit)
	visit = it->visitSelection(PreVisit, this);

	if (visit)
	{
	it->incrementDepth(this);
	mCondition->traverse(it);
	if (mTrueBlock)
	mTrueBlock->traverse(it);
	if (mFalseBlock)
	mFalseBlock->traverse(it);
	it->decrementDepth();
	}

	if (visit && it->postVisit)
	it->visitSelection(PostVisit, this);
	}

	//
	// Traverse a switch node. Same comments in binary node apply here.
	//
	void TIntermSwitch::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	if (it->preVisit)
	visit = it->visitSwitch(PreVisit, this);

	if (visit)
	{
	it->incrementDepth(this);
	mInit->traverse(it);
	if (it->inVisit)
	visit = it->visitSwitch(InVisit, this);
	if (visit && mStatementList)
	mStatementList->traverse(it);
	it->decrementDepth();
	}

	if (visit && it->postVisit)
	it->visitSwitch(PostVisit, this);
	}

	//
	// Traverse a switch node. Same comments in binary node apply here.
	//
	void TIntermCase::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	if (it->preVisit)
	visit = it->visitCase(PreVisit, this);

	if (visit && mCondition)
	mCondition->traverse(it);

	if (visit && it->postVisit)
	it->visitCase(PostVisit, this);
	}

	//
	// Traverse a loop node. Same comments in binary node apply here.
	//
	void TIntermLoop::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	if (it->preVisit)
	visit = it->visitLoop(PreVisit, this);

	if (visit)
	{
	it->incrementDepth(this);

	if (mInit)
	mInit->traverse(it);

	if (mCond)
	mCond->traverse(it);

	if (mBody)
	mBody->traverse(it);

	if (mExpr)
	mExpr->traverse(it);

	it->decrementDepth();
	}

	if (visit && it->postVisit)
	it->visitLoop(PostVisit, this);
	}

	//
	// Traverse a branch node. Same comments in binary node apply here.
	//
	void TIntermBranch::traverse(TIntermTraverser *it)
	{
	bool visit = true;

	if (it->preVisit)
	visit = it->visitBranch(PreVisit, this);

	if (visit && mExpression) {
	it->incrementDepth(this);
	mExpression->traverse(it);
	it->decrementDepth();
	}

	if (visit && it->postVisit)
	it->visitBranch(PostVisit, this);
	}

	void TIntermRaw::traverse(TIntermTraverser *it)
	{
	it->visitRaw(this);
	}