kc3-lang/angle/src/compiler/translator/IntermTraverse.cpp

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• Hash : 1ecd14b8
  Author :
  Date : 2017-01-26T13:54:15
  

  Fold user-definedness of function nodes into TOperator
  
  Whether a function call is user-defined is not orthogonal to TOperator
  associated with the call node - other ops than function calls can't be
  user-defined. Because of this it makes sense to store the user-
  definedness by having different TOperator enums for different types of
  calls.
  
  This patch also tags internal helper functions that have a raw
  definition outside the AST with a separate TOperator enum. This way
  they can be handled with logic that is easy to understand. Before this,
  function calls like this left the user-defined bit unset, despite not
  really being built-ins either. The EmulatePrecision traverser uses
  this. This is also something that could be used to clean up built-in
  emulation in the future.
  
  BUG=angleproject:1490
  TEST=angle_unittests
  
  Change-Id: I597fcd9789d0cc22b689ef3ce5a0cc3f621d4859
  Reviewed-on: https://chromium-review.googlesource.com/433443
  Reviewed-by: Corentin Wallez <cwallez@chromium.org>
  Commit-Queue: Olli Etuaho <oetuaho@nvidia.com>
  

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• src/compiler/translator/IntermTraverse.cpp

• //
  // 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"
  #include "compiler/translator/SymbolTable.h"
  
  namespace sh
  {
  
  void TIntermSymbol::traverse(TIntermTraverser *it)
  {
      it->traverseSymbol(this);
  }
  
  void TIntermRaw::traverse(TIntermTraverser *it)
  {
      it->traverseRaw(this);
  }
  
  void TIntermConstantUnion::traverse(TIntermTraverser *it)
  {
      it->traverseConstantUnion(this);
  }
  
  void TIntermSwizzle::traverse(TIntermTraverser *it)
  {
      it->traverseSwizzle(this);
  }
  
  void TIntermBinary::traverse(TIntermTraverser *it)
  {
      it->traverseBinary(this);
  }
  
  void TIntermUnary::traverse(TIntermTraverser *it)
  {
      it->traverseUnary(this);
  }
  
  void TIntermTernary::traverse(TIntermTraverser *it)
  {
      it->traverseTernary(this);
  }
  
  void TIntermIfElse::traverse(TIntermTraverser *it)
  {
      it->traverseIfElse(this);
  }
  
  void TIntermSwitch::traverse(TIntermTraverser *it)
  {
      it->traverseSwitch(this);
  }
  
  void TIntermCase::traverse(TIntermTraverser *it)
  {
      it->traverseCase(this);
  }
  
  void TIntermFunctionDefinition::traverse(TIntermTraverser *it)
  {
      it->traverseFunctionDefinition(this);
  }
  
  void TIntermBlock::traverse(TIntermTraverser *it)
  {
      it->traverseBlock(this);
  }
  
  void TIntermInvariantDeclaration::traverse(TIntermTraverser *it)
  {
      it->traverseInvariantDeclaration(this);
  }
  
  void TIntermDeclaration::traverse(TIntermTraverser *it)
  {
      it->traverseDeclaration(this);
  }
  
  void TIntermFunctionPrototype::traverse(TIntermTraverser *it)
  {
      it->traverseFunctionPrototype(this);
  }
  
  void TIntermAggregate::traverse(TIntermTraverser *it)
  {
      it->traverseAggregate(this);
  }
  
  void TIntermLoop::traverse(TIntermTraverser *it)
  {
      it->traverseLoop(this);
  }
  
  void TIntermBranch::traverse(TIntermTraverser *it)
  {
      it->traverseBranch(this);
  }
  
  TIntermTraverser::TIntermTraverser(bool preVisit, bool inVisit, bool postVisit)
      : preVisit(preVisit),
        inVisit(inVisit),
        postVisit(postVisit),
        mDepth(-1),
        mMaxDepth(0),
        mInGlobalScope(true),
        mTemporaryIndex(nullptr)
  {
  }
  
  TIntermTraverser::~TIntermTraverser()
  {
  }
  
  void TIntermTraverser::pushParentBlock(TIntermBlock *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)
  {
      TIntermSequence emptyInsertionsAfter;
      insertStatementsInParentBlock(insertions, emptyInsertionsAfter);
  }
  
  void TIntermTraverser::insertStatementsInParentBlock(const TIntermSequence &insertionsBefore,
                                                       const TIntermSequence &insertionsAfter)
  {
      ASSERT(!mParentBlockStack.empty());
      ParentBlock &parentBlock = mParentBlockStack.back();
      if (mPath.back() == parentBlock.node)
      {
          ASSERT(mParentBlockStack.size() >= 2u);
          // The current node is a block node, so the parent block is not the topmost one in the block
          // stack, but the one below that.
          parentBlock = mParentBlockStack.at(mParentBlockStack.size() - 2u);
      }
      NodeInsertMultipleEntry insert(parentBlock.node, parentBlock.pos, insertionsBefore,
                                     insertionsAfter);
      mInsertions.push_back(insert);
  }
  
  void TIntermTraverser::insertStatementInParentBlock(TIntermNode *statement)
  {
      TIntermSequence insertions;
      insertions.push_back(statement);
      insertStatementsInParentBlock(insertions);
  }
  
  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);
  
      ASSERT(qualifier == EvqTemporary || qualifier == EvqConst || qualifier == EvqGlobal);
      node->getTypePointer()->setQualifier(qualifier);
      // TODO(oetuaho): Might be useful to sanitize layout qualifier etc. on the type of the created
      // symbol. This might need to be done in other places as well.
      return node;
  }
  
  TIntermSymbol *TIntermTraverser::createTempSymbol(const TType &type)
  {
      return createTempSymbol(type, EvqTemporary);
  }
  
  TIntermDeclaration *TIntermTraverser::createTempDeclaration(const TType &type)
  {
      TIntermDeclaration *tempDeclaration = new TIntermDeclaration();
      tempDeclaration->appendDeclarator(createTempSymbol(type));
      return tempDeclaration;
  }
  
  TIntermDeclaration *TIntermTraverser::createTempInitDeclaration(TIntermTyped *initializer,
                                                                  TQualifier qualifier)
  {
      ASSERT(initializer != nullptr);
      TIntermSymbol *tempSymbol           = createTempSymbol(initializer->getType(), qualifier);
      TIntermDeclaration *tempDeclaration = new TIntermDeclaration();
      TIntermBinary *tempInit             = new TIntermBinary(EOpInitialize, tempSymbol, initializer);
      tempDeclaration->appendDeclarator(tempInit);
      return tempDeclaration;
  }
  
  TIntermDeclaration *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, tempSymbol, rightNode);
      return assignment;
  }
  
  void TIntermTraverser::useTemporaryIndex(unsigned int *temporaryIndex)
  {
      mTemporaryIndex = temporaryIndex;
  }
  
  void TIntermTraverser::nextTemporaryIndex()
  {
      ASSERT(mTemporaryIndex != nullptr);
      ++(*mTemporaryIndex);
  }
  
  void TLValueTrackingTraverser::addToFunctionMap(const TName &name, TIntermSequence *paramSequence)
  {
      mFunctionMap[name] = paramSequence;
  }
  
  bool TLValueTrackingTraverser::isInFunctionMap(const TIntermAggregate *callNode) const
  {
      ASSERT(callNode->getOp() == EOpCallFunctionInAST);
      return (mFunctionMap.find(callNode->getFunctionSymbolInfo()->getNameObj()) !=
              mFunctionMap.end());
  }
  
  TIntermSequence *TLValueTrackingTraverser::getFunctionParameters(const TIntermAggregate *callNode)
  {
      ASSERT(isInFunctionMap(callNode));
      return mFunctionMap[callNode->getFunctionSymbolInfo()->getNameObj()];
  }
  
  void TLValueTrackingTraverser::setInFunctionCallOutParameter(bool inOutParameter)
  {
      mInFunctionCallOutParameter = inOutParameter;
  }
  
  bool TLValueTrackingTraverser::isInFunctionCallOutParameter() const
  {
      return mInFunctionCallOutParameter;
  }
  
  //
  // 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 TIntermTraverser::traverseSymbol(TIntermSymbol *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
      visitSymbol(node);
  }
  
  void TIntermTraverser::traverseConstantUnion(TIntermConstantUnion *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
      visitConstantUnion(node);
  }
  
  void TIntermTraverser::traverseSwizzle(TIntermSwizzle *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitSwizzle(PreVisit, node);
  
      if (visit)
      {
          node->getOperand()->traverse(this);
      }
  
      if (visit && postVisit)
          visitSwizzle(PostVisit, node);
  }
  
  //
  // Traverse a binary node.
  //
  void TIntermTraverser::traverseBinary(TIntermBinary *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      //
      // visit the node before children if pre-visiting.
      //
      if (preVisit)
          visit = visitBinary(PreVisit, node);
  
      //
      // Visit the children, in the right order.
      //
      if (visit)
      {
          if (node->getLeft())
              node->getLeft()->traverse(this);
  
          if (inVisit)
              visit = visitBinary(InVisit, node);
  
          if (visit && node->getRight())
              node->getRight()->traverse(this);
      }
  
      //
      // Visit the node after the children, if requested and the traversal
      // hasn't been cancelled yet.
      //
      if (visit && postVisit)
          visitBinary(PostVisit, node);
  }
  
  void TLValueTrackingTraverser::traverseBinary(TIntermBinary *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      //
      // visit the node before children if pre-visiting.
      //
      if (preVisit)
          visit = visitBinary(PreVisit, node);
  
      //
      // Visit the children, in the right order.
      //
      if (visit)
      {
          // Some binary operations like indexing can be inside an expression which must be an
          // l-value.
          bool parentOperatorRequiresLValue     = operatorRequiresLValue();
          bool parentInFunctionCallOutParameter = isInFunctionCallOutParameter();
          if (node->isAssignment())
          {
              ASSERT(!isLValueRequiredHere());
              setOperatorRequiresLValue(true);
          }
  
          if (node->getLeft())
              node->getLeft()->traverse(this);
  
          if (inVisit)
              visit = visitBinary(InVisit, node);
  
          if (node->isAssignment())
              setOperatorRequiresLValue(false);
  
          // Index is not required to be an l-value even when the surrounding expression is required
          // to be an l-value.
          TOperator op = node->getOp();
          if (op == EOpIndexDirect || op == EOpIndexDirectInterfaceBlock ||
              op == EOpIndexDirectStruct || op == EOpIndexIndirect)
          {
              setOperatorRequiresLValue(false);
              setInFunctionCallOutParameter(false);
          }
  
          if (visit && node->getRight())
              node->getRight()->traverse(this);
  
          setOperatorRequiresLValue(parentOperatorRequiresLValue);
          setInFunctionCallOutParameter(parentInFunctionCallOutParameter);
      }
  
      //
      // Visit the node after the children, if requested and the traversal
      // hasn't been cancelled yet.
      //
      if (visit && postVisit)
          visitBinary(PostVisit, node);
  }
  
  //
  // Traverse a unary node.  Same comments in binary node apply here.
  //
  void TIntermTraverser::traverseUnary(TIntermUnary *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitUnary(PreVisit, node);
  
      if (visit)
      {
          node->getOperand()->traverse(this);
      }
  
      if (visit && postVisit)
          visitUnary(PostVisit, node);
  }
  
  void TLValueTrackingTraverser::traverseUnary(TIntermUnary *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitUnary(PreVisit, node);
  
      if (visit)
      {
          ASSERT(!operatorRequiresLValue());
          switch (node->getOp())
          {
              case EOpPostIncrement:
              case EOpPostDecrement:
              case EOpPreIncrement:
              case EOpPreDecrement:
                  setOperatorRequiresLValue(true);
                  break;
              default:
                  break;
          }
  
          node->getOperand()->traverse(this);
  
          setOperatorRequiresLValue(false);
      }
  
      if (visit && postVisit)
          visitUnary(PostVisit, node);
  }
  
  // Traverse a function definition node.
  void TIntermTraverser::traverseFunctionDefinition(TIntermFunctionDefinition *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitFunctionDefinition(PreVisit, node);
  
      if (visit)
      {
          mInGlobalScope = false;
  
          node->getFunctionPrototype()->traverse(this);
          if (inVisit)
              visit = visitFunctionDefinition(InVisit, node);
          node->getBody()->traverse(this);
  
          mInGlobalScope = true;
      }
  
      if (visit && postVisit)
          visitFunctionDefinition(PostVisit, node);
  }
  
  // Traverse a block node.
  void TIntermTraverser::traverseBlock(TIntermBlock *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
      pushParentBlock(node);
  
      bool visit = true;
  
      TIntermSequence *sequence = node->getSequence();
  
      if (preVisit)
          visit = visitBlock(PreVisit, node);
  
      if (visit)
      {
          for (auto *child : *sequence)
          {
              child->traverse(this);
              if (visit && inVisit)
              {
                  if (child != sequence->back())
                      visit = visitBlock(InVisit, node);
              }
  
              incrementParentBlockPos();
          }
      }
  
      if (visit && postVisit)
          visitBlock(PostVisit, node);
  
      popParentBlock();
  }
  
  void TIntermTraverser::traverseInvariantDeclaration(TIntermInvariantDeclaration *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
      {
          visit = visitInvariantDeclaration(PreVisit, node);
      }
  
      if (visit)
      {
          node->getSymbol()->traverse(this);
          if (postVisit)
          {
              visitInvariantDeclaration(PostVisit, node);
          }
      }
  }
  
  // Traverse a declaration node.
  void TIntermTraverser::traverseDeclaration(TIntermDeclaration *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      TIntermSequence *sequence = node->getSequence();
  
      if (preVisit)
          visit = visitDeclaration(PreVisit, node);
  
      if (visit)
      {
          for (auto *child : *sequence)
          {
              child->traverse(this);
              if (visit && inVisit)
              {
                  if (child != sequence->back())
                      visit = visitDeclaration(InVisit, node);
              }
          }
      }
  
      if (visit && postVisit)
          visitDeclaration(PostVisit, node);
  }
  
  void TIntermTraverser::traverseFunctionPrototype(TIntermFunctionPrototype *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      TIntermSequence *sequence = node->getSequence();
  
      if (preVisit)
          visit = visitFunctionPrototype(PreVisit, node);
  
      if (visit)
      {
          for (auto *child : *sequence)
          {
              child->traverse(this);
              if (visit && inVisit)
              {
                  if (child != sequence->back())
                      visit = visitFunctionPrototype(InVisit, node);
              }
          }
      }
  
      if (visit && postVisit)
          visitFunctionPrototype(PostVisit, node);
  }
  
  // Traverse an aggregate node.  Same comments in binary node apply here.
  void TIntermTraverser::traverseAggregate(TIntermAggregate *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      TIntermSequence *sequence = node->getSequence();
  
      if (preVisit)
          visit = visitAggregate(PreVisit, node);
  
      if (visit)
      {
          for (auto *child : *sequence)
          {
              child->traverse(this);
              if (visit && inVisit)
              {
                  if (child != sequence->back())
                      visit = visitAggregate(InVisit, node);
              }
          }
      }
  
      if (visit && postVisit)
          visitAggregate(PostVisit, node);
  }
  
  void TLValueTrackingTraverser::traverseFunctionPrototype(TIntermFunctionPrototype *node)
  {
      TIntermSequence *sequence = node->getSequence();
      addToFunctionMap(node->getFunctionSymbolInfo()->getNameObj(), sequence);
  
      TIntermTraverser::traverseFunctionPrototype(node);
  }
  
  void TLValueTrackingTraverser::traverseAggregate(TIntermAggregate *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      TIntermSequence *sequence = node->getSequence();
  
      if (preVisit)
          visit = visitAggregate(PreVisit, node);
  
      if (visit)
      {
          if (node->getOp() == EOpCallFunctionInAST)
          {
              if (isInFunctionMap(node))
              {
                  TIntermSequence *params             = getFunctionParameters(node);
                  TIntermSequence::iterator paramIter = params->begin();
                  for (auto *child : *sequence)
                  {
                      ASSERT(paramIter != params->end());
                      TQualifier qualifier = (*paramIter)->getAsTyped()->getQualifier();
                      setInFunctionCallOutParameter(qualifier == EvqOut || qualifier == EvqInOut);
  
                      child->traverse(this);
                      if (visit && inVisit)
                      {
                          if (child != sequence->back())
                              visit = visitAggregate(InVisit, node);
                      }
  
                      ++paramIter;
                  }
              }
              else
              {
                  // The node might not be in the function map in case we're in the middle of
                  // transforming the AST, and have inserted function call nodes without inserting the
                  // function definitions yet.
                  setInFunctionCallOutParameter(false);
                  for (auto *child : *sequence)
                  {
                      child->traverse(this);
                      if (visit && inVisit)
                      {
                          if (child != sequence->back())
                              visit = visitAggregate(InVisit, node);
                      }
                  }
              }
  
              setInFunctionCallOutParameter(false);
          }
          else
          {
              // Find the built-in function corresponding to this op so that we can determine the
              // in/out qualifiers of its parameters.
              TFunction *builtInFunc = nullptr;
              if (!node->isFunctionCall() && !node->isConstructor())
              {
                  builtInFunc = mSymbolTable.findBuiltInOp(node, mShaderVersion);
              }
  
              size_t paramIndex = 0;
  
              for (auto *child : *sequence)
              {
                  // This assumes that raw functions called with
                  // EOpCallInternalRawFunction don't have out parameters.
                  TQualifier qualifier = EvqIn;
                  if (builtInFunc != nullptr)
                      qualifier = builtInFunc->getParam(paramIndex).type->getQualifier();
                  setInFunctionCallOutParameter(qualifier == EvqOut || qualifier == EvqInOut);
                  child->traverse(this);
  
                  if (visit && inVisit)
                  {
                      if (child != sequence->back())
                          visit = visitAggregate(InVisit, node);
                  }
  
                  ++paramIndex;
              }
  
              setInFunctionCallOutParameter(false);
          }
      }
  
      if (visit && postVisit)
          visitAggregate(PostVisit, node);
  }
  
  //
  // Traverse a ternary node.  Same comments in binary node apply here.
  //
  void TIntermTraverser::traverseTernary(TIntermTernary *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitTernary(PreVisit, node);
  
      if (visit)
      {
          node->getCondition()->traverse(this);
          if (node->getTrueExpression())
              node->getTrueExpression()->traverse(this);
          if (node->getFalseExpression())
              node->getFalseExpression()->traverse(this);
      }
  
      if (visit && postVisit)
          visitTernary(PostVisit, node);
  }
  
  // Traverse an if-else node.  Same comments in binary node apply here.
  void TIntermTraverser::traverseIfElse(TIntermIfElse *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitIfElse(PreVisit, node);
  
      if (visit)
      {
          node->getCondition()->traverse(this);
          if (node->getTrueBlock())
              node->getTrueBlock()->traverse(this);
          if (node->getFalseBlock())
              node->getFalseBlock()->traverse(this);
      }
  
      if (visit && postVisit)
          visitIfElse(PostVisit, node);
  }
  
  //
  // Traverse a switch node.  Same comments in binary node apply here.
  //
  void TIntermTraverser::traverseSwitch(TIntermSwitch *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitSwitch(PreVisit, node);
  
      if (visit)
      {
          node->getInit()->traverse(this);
          if (inVisit)
              visit = visitSwitch(InVisit, node);
          if (visit && node->getStatementList())
              node->getStatementList()->traverse(this);
      }
  
      if (visit && postVisit)
          visitSwitch(PostVisit, node);
  }
  
  //
  // Traverse a case node.  Same comments in binary node apply here.
  //
  void TIntermTraverser::traverseCase(TIntermCase *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitCase(PreVisit, node);
  
      if (visit && node->getCondition())
      {
          node->getCondition()->traverse(this);
      }
  
      if (visit && postVisit)
          visitCase(PostVisit, node);
  }
  
  //
  // Traverse a loop node.  Same comments in binary node apply here.
  //
  void TIntermTraverser::traverseLoop(TIntermLoop *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitLoop(PreVisit, node);
  
      if (visit)
      {
          if (node->getInit())
              node->getInit()->traverse(this);
  
          if (node->getCondition())
              node->getCondition()->traverse(this);
  
          if (node->getBody())
              node->getBody()->traverse(this);
  
          if (node->getExpression())
              node->getExpression()->traverse(this);
      }
  
      if (visit && postVisit)
          visitLoop(PostVisit, node);
  }
  
  //
  // Traverse a branch node.  Same comments in binary node apply here.
  //
  void TIntermTraverser::traverseBranch(TIntermBranch *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
  
      bool visit = true;
  
      if (preVisit)
          visit = visitBranch(PreVisit, node);
  
      if (visit && node->getExpression())
      {
          node->getExpression()->traverse(this);
      }
  
      if (visit && postVisit)
          visitBranch(PostVisit, node);
  }
  
  void TIntermTraverser::traverseRaw(TIntermRaw *node)
  {
      ScopedNodeInTraversalPath addToPath(this, node);
      visitRaw(node);
  }
  
  }  // namespace sh
  

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