kc3-lang/angle/src/compiler/translator/IntermNode.h

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• Hash : d0bad2c7
  Author :
  Date : 2016-09-09T18:01:16
  

  Split ternary node class from TIntermSelection
  
  Ternary operator nodes are typed parts of expressions, they always
  have two children and the children are also guaranteed to be
  TIntermTyped. "If" selection nodes can't be a part of an expression,
  they can have either one or two children and the children are code
  blocks. Due to all of these differences it makes sense to store these
  using two different AST node classes.
  
  BUG=angleproject:1490
  TEST=angle_unittests
  
  Change-Id: I913ab1d806e3cdb5c21106f078cc9c0b6c72ac54
  Reviewed-on: https://chromium-review.googlesource.com/384512
  Commit-Queue: Olli Etuaho <oetuaho@nvidia.com>
  Reviewed-by: Corentin Wallez <cwallez@chromium.org>
  

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• src/compiler/translator/IntermNode.h

• //
  // Copyright (c) 2002-2014 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  
  //
  // Definition of the in-memory high-level intermediate representation
  // of shaders.  This is a tree that parser creates.
  //
  // Nodes in the tree are defined as a hierarchy of classes derived from
  // TIntermNode. Each is a node in a tree.  There is no preset branching factor;
  // each node can have it's own type of list of children.
  //
  
  #ifndef COMPILER_TRANSLATOR_INTERMNODE_H_
  #define COMPILER_TRANSLATOR_INTERMNODE_H_
  
  #include "GLSLANG/ShaderLang.h"
  
  #include <algorithm>
  #include <queue>
  
  #include "common/angleutils.h"
  #include "compiler/translator/Common.h"
  #include "compiler/translator/ConstantUnion.h"
  #include "compiler/translator/Operator.h"
  #include "compiler/translator/Types.h"
  
  class TDiagnostics;
  
  class TIntermTraverser;
  class TIntermAggregate;
  class TIntermBinary;
  class TIntermUnary;
  class TIntermConstantUnion;
  class TIntermTernary;
  class TIntermSelection;
  class TIntermSwitch;
  class TIntermCase;
  class TIntermTyped;
  class TIntermSymbol;
  class TIntermLoop;
  class TInfoSink;
  class TInfoSinkBase;
  class TIntermRaw;
  class TIntermBranch;
  
  class TSymbolTable;
  
  // Encapsulate an identifier string and track whether it is coming from the original shader code
  // (not internal) or from ANGLE (internal). Usually internal names shouldn't be decorated or hashed.
  class TName
  {
    public:
      POOL_ALLOCATOR_NEW_DELETE();
      explicit TName(const TString &name) : mName(name), mIsInternal(false) {}
      TName() : mName(), mIsInternal(false) {}
      TName(const TName &) = default;
      TName &operator=(const TName &) = default;
  
      const TString &getString() const { return mName; }
      void setString(const TString &string) { mName = string; }
      bool isInternal() const { return mIsInternal; }
      void setInternal(bool isInternal) { mIsInternal = isInternal; }
  
    private:
      TString mName;
      bool mIsInternal;
  };
  
  //
  // Base class for the tree nodes
  //
  class TIntermNode : angle::NonCopyable
  {
    public:
      POOL_ALLOCATOR_NEW_DELETE();
      TIntermNode()
      {
          // TODO: Move this to TSourceLoc constructor
          // after getting rid of TPublicType.
          mLine.first_file = mLine.last_file = 0;
          mLine.first_line = mLine.last_line = 0;
      }
      virtual ~TIntermNode() { }
  
      const TSourceLoc &getLine() const { return mLine; }
      void setLine(const TSourceLoc &l) { mLine = l; }
  
      virtual void traverse(TIntermTraverser *) = 0;
      virtual TIntermTyped *getAsTyped() { return 0; }
      virtual TIntermConstantUnion *getAsConstantUnion() { return 0; }
      virtual TIntermAggregate *getAsAggregate() { return 0; }
      virtual TIntermBinary *getAsBinaryNode() { return 0; }
      virtual TIntermUnary *getAsUnaryNode() { return 0; }
      virtual TIntermTernary *getAsTernaryNode() { return nullptr; }
      virtual TIntermSelection *getAsSelectionNode() { return 0; }
      virtual TIntermSwitch *getAsSwitchNode() { return 0; }
      virtual TIntermCase *getAsCaseNode() { return 0; }
      virtual TIntermSymbol *getAsSymbolNode() { return 0; }
      virtual TIntermLoop *getAsLoopNode() { return 0; }
      virtual TIntermRaw *getAsRawNode() { return 0; }
      virtual TIntermBranch *getAsBranchNode() { return 0; }
  
      // Replace a child node. Return true if |original| is a child
      // node and it is replaced; otherwise, return false.
      virtual bool replaceChildNode(
          TIntermNode *original, TIntermNode *replacement) = 0;
  
    protected:
      TSourceLoc mLine;
  };
  
  //
  // This is just to help yacc.
  //
  struct TIntermNodePair
  {
      TIntermNode *node1;
      TIntermNode *node2;
  };
  
  //
  // Intermediate class for nodes that have a type.
  //
  class TIntermTyped : public TIntermNode
  {
    public:
      TIntermTyped(const TType &t) : mType(t)  { }
  
      virtual TIntermTyped *deepCopy() const = 0;
  
      TIntermTyped *getAsTyped() override { return this; }
  
      virtual bool hasSideEffects() const = 0;
  
      void setType(const TType &t) { mType = t; }
      void setTypePreservePrecision(const TType &t);
      const TType &getType() const { return mType; }
      TType *getTypePointer() { return &mType; }
  
      TBasicType getBasicType() const { return mType.getBasicType(); }
      TQualifier getQualifier() const { return mType.getQualifier(); }
      TPrecision getPrecision() const { return mType.getPrecision(); }
      int getCols() const { return mType.getCols(); }
      int getRows() const { return mType.getRows(); }
      int getNominalSize() const { return mType.getNominalSize(); }
      int getSecondarySize() const { return mType.getSecondarySize(); }
  
      bool isInterfaceBlock() const { return mType.isInterfaceBlock(); }
      bool isMatrix() const { return mType.isMatrix(); }
      bool isArray()  const { return mType.isArray(); }
      bool isVector() const { return mType.isVector(); }
      bool isScalar() const { return mType.isScalar(); }
      bool isScalarInt() const { return mType.isScalarInt(); }
      const char *getBasicString() const { return mType.getBasicString(); }
      TString getCompleteString() const { return mType.getCompleteString(); }
  
      unsigned int getArraySize() const { return mType.getArraySize(); }
  
      bool isConstructorWithOnlyConstantUnionParameters();
  
      static TIntermTyped *CreateIndexNode(int index);
      static TIntermTyped *CreateZero(const TType &type);
  
    protected:
      TType mType;
  
      TIntermTyped(const TIntermTyped &node);
  };
  
  //
  // Handle for, do-while, and while loops.
  //
  enum TLoopType
  {
      ELoopFor,
      ELoopWhile,
      ELoopDoWhile
  };
  
  class TIntermLoop : public TIntermNode
  {
    public:
      TIntermLoop(TLoopType type,
                  TIntermNode *init,
                  TIntermTyped *cond,
                  TIntermTyped *expr,
                  TIntermAggregate *body)
          : mType(type), mInit(init), mCond(cond), mExpr(expr), mBody(body), mUnrollFlag(false)
      {
      }
  
      TIntermLoop *getAsLoopNode() override { return this; }
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(TIntermNode *original, TIntermNode *replacement) override;
  
      TLoopType getType() const { return mType; }
      TIntermNode *getInit() { return mInit; }
      TIntermTyped *getCondition() { return mCond; }
      TIntermTyped *getExpression() { return mExpr; }
      TIntermAggregate *getBody() { return mBody; }
  
      void setCondition(TIntermTyped *condition) { mCond = condition; }
      void setExpression(TIntermTyped *expression) { mExpr = expression; }
      void setBody(TIntermAggregate *body) { mBody = body; }
  
      void setUnrollFlag(bool flag) { mUnrollFlag = flag; }
      bool getUnrollFlag() const { return mUnrollFlag; }
  
    protected:
      TLoopType mType;
      TIntermNode *mInit;  // for-loop initialization
      TIntermTyped *mCond; // loop exit condition
      TIntermTyped *mExpr; // for-loop expression
      TIntermAggregate *mBody;  // loop body
  
      bool mUnrollFlag; // Whether the loop should be unrolled or not.
  };
  
  //
  // Handle break, continue, return, and kill.
  //
  class TIntermBranch : public TIntermNode
  {
    public:
      TIntermBranch(TOperator op, TIntermTyped *e)
          : mFlowOp(op),
            mExpression(e) { }
  
      void traverse(TIntermTraverser *it) override;
      TIntermBranch *getAsBranchNode() override { return this; }
      bool replaceChildNode(TIntermNode *original, TIntermNode *replacement) override;
  
      TOperator getFlowOp() { return mFlowOp; }
      TIntermTyped* getExpression() { return mExpression; }
  
  protected:
      TOperator mFlowOp;
      TIntermTyped *mExpression;  // non-zero except for "return exp;" statements
  };
  
  //
  // Nodes that correspond to symbols or constants in the source code.
  //
  class TIntermSymbol : public TIntermTyped
  {
    public:
      // if symbol is initialized as symbol(sym), the memory comes from the poolallocator of sym.
      // If sym comes from per process globalpoolallocator, then it causes increased memory usage
      // per compile it is essential to use "symbol = sym" to assign to symbol
      TIntermSymbol(int id, const TString &symbol, const TType &type)
          : TIntermTyped(type), mId(id), mSymbol(symbol)
      {
      }
  
      TIntermTyped *deepCopy() const override { return new TIntermSymbol(*this); }
  
      bool hasSideEffects() const override { return false; }
  
      int getId() const { return mId; }
      const TString &getSymbol() const { return mSymbol.getString(); }
      const TName &getName() const { return mSymbol; }
  
      void setId(int newId) { mId = newId; }
  
      void setInternal(bool internal) { mSymbol.setInternal(internal); }
  
      void traverse(TIntermTraverser *it) override;
      TIntermSymbol *getAsSymbolNode() override { return this; }
      bool replaceChildNode(TIntermNode *, TIntermNode *) override { return false; }
  
    protected:
      int mId;
      TName mSymbol;
  
    private:
      TIntermSymbol(const TIntermSymbol &) = default;  // Note: not deleted, just private!
  };
  
  // A Raw node stores raw code, that the translator will insert verbatim
  // into the output stream. Useful for transformation operations that make
  // complex code that might not fit naturally into the GLSL model.
  class TIntermRaw : public TIntermTyped
  {
    public:
      TIntermRaw(const TType &type, const TString &rawText)
          : TIntermTyped(type),
            mRawText(rawText) { }
      TIntermRaw(const TIntermRaw &) = delete;
  
      TIntermTyped *deepCopy() const override
      {
          UNREACHABLE();
          return nullptr;
      }
  
      bool hasSideEffects() const override { return false; }
  
      TString getRawText() const { return mRawText; }
  
      void traverse(TIntermTraverser *it) override;
  
      TIntermRaw *getAsRawNode() override { return this; }
      bool replaceChildNode(TIntermNode *, TIntermNode *) override { return false; }
  
    protected:
      TString mRawText;
  };
  
  // Constant folded node.
  // Note that nodes may be constant folded and not be constant expressions with the EvqConst
  // qualifier. This happens for example when the following expression is processed:
  // "true ? 1.0 : non_constant"
  // Other nodes than TIntermConstantUnion may also be constant expressions.
  //
  class TIntermConstantUnion : public TIntermTyped
  {
    public:
      TIntermConstantUnion(const TConstantUnion *unionPointer, const TType &type)
          : TIntermTyped(type), mUnionArrayPointer(unionPointer)
      {
          ASSERT(unionPointer);
      }
  
      TIntermTyped *deepCopy() const override { return new TIntermConstantUnion(*this); }
  
      bool hasSideEffects() const override { return false; }
  
      const TConstantUnion *getUnionArrayPointer() const { return mUnionArrayPointer; }
  
      int getIConst(size_t index) const
      {
          return mUnionArrayPointer ? mUnionArrayPointer[index].getIConst() : 0;
      }
      unsigned int getUConst(size_t index) const
      {
          return mUnionArrayPointer ? mUnionArrayPointer[index].getUConst() : 0;
      }
      float getFConst(size_t index) const
      {
          return mUnionArrayPointer ? mUnionArrayPointer[index].getFConst() : 0.0f;
      }
      bool getBConst(size_t index) const
      {
          return mUnionArrayPointer ? mUnionArrayPointer[index].getBConst() : false;
      }
  
      void replaceConstantUnion(const TConstantUnion *safeConstantUnion)
      {
          ASSERT(safeConstantUnion);
          // Previous union pointer freed on pool deallocation.
          mUnionArrayPointer = safeConstantUnion;
      }
  
      TIntermConstantUnion *getAsConstantUnion() override { return this; }
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(TIntermNode *, TIntermNode *) override { return false; }
  
      TConstantUnion *foldBinary(TOperator op,
                                 TIntermConstantUnion *rightNode,
                                 TDiagnostics *diagnostics);
      const TConstantUnion *foldIndexing(int index);
      TConstantUnion *foldUnaryNonComponentWise(TOperator op);
      TConstantUnion *foldUnaryComponentWise(TOperator op, TDiagnostics *diagnostics);
  
      static TConstantUnion *FoldAggregateConstructor(TIntermAggregate *aggregate);
      static TConstantUnion *FoldAggregateBuiltIn(TIntermAggregate *aggregate,
                                                  TDiagnostics *diagnostics);
  
    protected:
      // Same data may be shared between multiple constant unions, so it can't be modified.
      const TConstantUnion *mUnionArrayPointer;
  
    private:
      typedef float(*FloatTypeUnaryFunc) (float);
      void foldFloatTypeUnary(const TConstantUnion &parameter,
                              FloatTypeUnaryFunc builtinFunc,
                              TConstantUnion *result) const;
  
      TIntermConstantUnion(const TIntermConstantUnion &node);  // Note: not deleted, just private!
  };
  
  //
  // Intermediate class for node types that hold operators.
  //
  class TIntermOperator : public TIntermTyped
  {
    public:
      TOperator getOp() const { return mOp; }
  
      bool isAssignment() const;
      bool isMultiplication() const;
      bool isConstructor() const;
  
      bool hasSideEffects() const override { return isAssignment(); }
  
    protected:
      TIntermOperator(TOperator op)
          : TIntermTyped(TType(EbtFloat, EbpUndefined)),
            mOp(op) {}
      TIntermOperator(TOperator op, const TType &type)
          : TIntermTyped(type),
            mOp(op) {}
  
      TIntermOperator(const TIntermOperator &) = default;
  
      TOperator mOp;
  };
  
  //
  // Nodes for all the basic binary math operators.
  //
  class TIntermBinary : public TIntermOperator
  {
    public:
      // This constructor determines the type of the binary node based on the operands and op.
      TIntermBinary(TOperator op, TIntermTyped *left, TIntermTyped *right);
  
      TIntermTyped *deepCopy() const override { return new TIntermBinary(*this); }
  
      static TOperator GetMulOpBasedOnOperands(const TType &left, const TType &right);
      static TOperator GetMulAssignOpBasedOnOperands(const TType &left, const TType &right);
  
      TIntermBinary *getAsBinaryNode() override { return this; };
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(TIntermNode *original, TIntermNode *replacement) override;
  
      bool hasSideEffects() const override
      {
          return isAssignment() || mLeft->hasSideEffects() || mRight->hasSideEffects();
      }
  
      TIntermTyped *getLeft() const { return mLeft; }
      TIntermTyped *getRight() const { return mRight; }
      TIntermTyped *fold(TDiagnostics *diagnostics);
  
      void setAddIndexClamp() { mAddIndexClamp = true; }
      bool getAddIndexClamp() { return mAddIndexClamp; }
  
    protected:
      TIntermTyped* mLeft;
      TIntermTyped* mRight;
  
      // If set to true, wrap any EOpIndexIndirect with a clamp to bounds.
      bool mAddIndexClamp;
  
    private:
      void promote();
  
      TIntermBinary(const TIntermBinary &node);  // Note: not deleted, just private!
  };
  
  //
  // Nodes for unary math operators.
  //
  class TIntermUnary : public TIntermOperator
  {
    public:
      TIntermUnary(TOperator op, TIntermTyped *operand);
  
      TIntermTyped *deepCopy() const override { return new TIntermUnary(*this); }
  
      void traverse(TIntermTraverser *it) override;
      TIntermUnary *getAsUnaryNode() override { return this; }
      bool replaceChildNode(TIntermNode *original, TIntermNode *replacement) override;
  
      bool hasSideEffects() const override { return isAssignment() || mOperand->hasSideEffects(); }
  
      TIntermTyped *getOperand() { return mOperand; }
      TIntermTyped *fold(TDiagnostics *diagnostics);
  
      void setUseEmulatedFunction() { mUseEmulatedFunction = true; }
      bool getUseEmulatedFunction() { return mUseEmulatedFunction; }
  
    protected:
      TIntermTyped *mOperand;
  
      // If set to true, replace the built-in function call with an emulated one
      // to work around driver bugs.
      bool mUseEmulatedFunction;
  
    private:
      void promote();
  
      TIntermUnary(const TIntermUnary &node);  // note: not deleted, just private!
  };
  
  typedef TVector<TIntermNode *> TIntermSequence;
  typedef TVector<int> TQualifierList;
  
  //
  // Nodes that operate on an arbitrary sized set of children.
  //
  class TIntermAggregate : public TIntermOperator
  {
    public:
      TIntermAggregate()
          : TIntermOperator(EOpNull),
            mUserDefined(false),
            mFunctionId(0),
            mUseEmulatedFunction(false),
            mGotPrecisionFromChildren(false)
      {
      }
      TIntermAggregate(TOperator op)
          : TIntermOperator(op),
            mUserDefined(false),
            mFunctionId(0),
            mUseEmulatedFunction(false),
            mGotPrecisionFromChildren(false)
      {
      }
      ~TIntermAggregate() { }
  
      // Note: only supported for nodes that can be a part of an expression.
      TIntermTyped *deepCopy() const override { return new TIntermAggregate(*this); }
  
      void setOp(TOperator op) { mOp = op; }
  
      TIntermAggregate *getAsAggregate() override { return this; }
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(TIntermNode *original, TIntermNode *replacement) override;
      bool replaceChildNodeWithMultiple(TIntermNode *original, TIntermSequence replacements);
      bool insertChildNodes(TIntermSequence::size_type position, TIntermSequence insertions);
      // Conservatively assume function calls and other aggregate operators have side-effects
      bool hasSideEffects() const override { return true; }
      TIntermTyped *fold(TDiagnostics *diagnostics);
  
      TIntermSequence *getSequence() { return &mSequence; }
      const TIntermSequence *getSequence() const { return &mSequence; }
  
      void setNameObj(const TName &name) { mName = name; }
      const TName &getNameObj() const { return mName; }
  
      void setName(const TString &name) { mName.setString(name); }
      const TString &getName() const { return mName.getString(); }
  
      void setUserDefined() { mUserDefined = true; }
      bool isUserDefined() const { return mUserDefined; }
  
      void setFunctionId(int functionId) { mFunctionId = functionId; }
      int getFunctionId() const { return mFunctionId; }
  
      void setUseEmulatedFunction() { mUseEmulatedFunction = true; }
      bool getUseEmulatedFunction() { return mUseEmulatedFunction; }
  
      bool areChildrenConstQualified();
      void setPrecisionFromChildren();
      void setBuiltInFunctionPrecision();
  
      // Returns true if changing parameter precision may affect the return value.
      bool gotPrecisionFromChildren() const { return mGotPrecisionFromChildren; }
  
    protected:
      TIntermSequence mSequence;
      TName mName;
      bool mUserDefined; // used for user defined function names
      int mFunctionId;
  
      // If set to true, replace the built-in function call with an emulated one
      // to work around driver bugs.
      bool mUseEmulatedFunction;
  
      bool mGotPrecisionFromChildren;
  
    private:
      TIntermAggregate(const TIntermAggregate &node);  // note: not deleted, just private!
  };
  
  // For ternary operators like a ? b : c.
  class TIntermTernary : public TIntermTyped
  {
    public:
      TIntermTernary(TIntermTyped *cond, TIntermTyped *trueExpression, TIntermTyped *falseExpression);
  
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(TIntermNode *original, TIntermNode *replacement) override;
  
      TIntermTyped *getCondition() const { return mCondition; }
      TIntermTyped *getTrueExpression() const { return mTrueExpression; }
      TIntermTyped *getFalseExpression() const { return mFalseExpression; }
      TIntermTernary *getAsTernaryNode() override { return this; }
  
      TIntermTyped *deepCopy() const override { return new TIntermTernary(*this); }
  
      bool hasSideEffects() const override
      {
          return mCondition->hasSideEffects() || mTrueExpression->hasSideEffects() ||
                 mFalseExpression->hasSideEffects();
      }
  
      static TQualifier DetermineQualifier(TIntermTyped *cond,
                                           TIntermTyped *trueExpression,
                                           TIntermTyped *falseExpression);
  
    private:
      TIntermTernary(const TIntermTernary &node);  // Note: not deleted, just private!
  
      TIntermTyped *mCondition;
      TIntermTyped *mTrueExpression;
      TIntermTyped *mFalseExpression;
  };
  
  // For if tests.
  class TIntermSelection : public TIntermNode
  {
    public:
      TIntermSelection(TIntermTyped *cond, TIntermNode *trueB, TIntermNode *falseB)
          : TIntermNode(), mCondition(cond), mTrueBlock(trueB), mFalseBlock(falseB)
      {
      }
  
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(TIntermNode *original, TIntermNode *replacement) override;
  
      TIntermTyped *getCondition() const { return mCondition; }
      TIntermNode *getTrueBlock() const { return mTrueBlock; }
      TIntermNode *getFalseBlock() const { return mFalseBlock; }
      TIntermSelection *getAsSelectionNode() override { return this; }
  
    protected:
      TIntermTyped *mCondition;
      TIntermNode *mTrueBlock;
      TIntermNode *mFalseBlock;
  };
  
  //
  // Switch statement.
  //
  class TIntermSwitch : public TIntermNode
  {
    public:
      TIntermSwitch(TIntermTyped *init, TIntermAggregate *statementList)
          : TIntermNode(),
            mInit(init),
            mStatementList(statementList)
      {
      }
  
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(
          TIntermNode *original, TIntermNode *replacement) override;
  
      TIntermSwitch *getAsSwitchNode() override { return this; }
  
      TIntermTyped *getInit() { return mInit; }
      TIntermAggregate *getStatementList() { return mStatementList; }
      void setStatementList(TIntermAggregate *statementList) { mStatementList = statementList; }
  
    protected:
      TIntermTyped *mInit;
      TIntermAggregate *mStatementList;
  };
  
  //
  // Case label.
  //
  class TIntermCase : public TIntermNode
  {
    public:
      TIntermCase(TIntermTyped *condition)
          : TIntermNode(),
            mCondition(condition)
      {
      }
  
      void traverse(TIntermTraverser *it) override;
      bool replaceChildNode(
          TIntermNode *original, TIntermNode *replacement) override;
  
      TIntermCase *getAsCaseNode() override { return this; }
  
      bool hasCondition() const { return mCondition != nullptr; }
      TIntermTyped *getCondition() const { return mCondition; }
  
    protected:
      TIntermTyped *mCondition;
  };
  
  enum Visit
  {
      PreVisit,
      InVisit,
      PostVisit
  };
  
  //
  // For traversing the tree.  User should derive from this class overriding the visit functions,
  // and then pass an object of the subclass to a traverse method of a node.
  //
  // The traverse*() functions may also be overridden do other bookkeeping on the tree to provide
  // contextual information to the visit functions, such as whether the node is the target of an
  // assignment.
  //
  // When using this, just fill in the methods for nodes you want visited.
  // Return false from a pre-visit to skip visiting that node's subtree.
  //
  class TIntermTraverser : angle::NonCopyable
  {
    public:
      POOL_ALLOCATOR_NEW_DELETE();
      TIntermTraverser(bool preVisit, bool inVisit, bool postVisit);
      virtual ~TIntermTraverser();
  
      virtual void visitSymbol(TIntermSymbol *node) {}
      virtual void visitRaw(TIntermRaw *node) {}
      virtual void visitConstantUnion(TIntermConstantUnion *node) {}
      virtual bool visitBinary(Visit visit, TIntermBinary *node) { return true; }
      virtual bool visitUnary(Visit visit, TIntermUnary *node) { return true; }
      virtual bool visitTernary(Visit visit, TIntermTernary *node) { return true; }
      virtual bool visitSelection(Visit visit, TIntermSelection *node) { return true; }
      virtual bool visitSwitch(Visit visit, TIntermSwitch *node) { return true; }
      virtual bool visitCase(Visit visit, TIntermCase *node) { return true; }
      virtual bool visitAggregate(Visit visit, TIntermAggregate *node) { return true; }
      virtual bool visitLoop(Visit visit, TIntermLoop *node) { return true; }
      virtual bool visitBranch(Visit visit, TIntermBranch *node) { return true; }
  
      // The traverse functions contain logic for iterating over the children of the node
      // and calling the visit functions in the appropriate places. They also track some
      // context that may be used by the visit functions.
      virtual void traverseSymbol(TIntermSymbol *node);
      virtual void traverseRaw(TIntermRaw *node);
      virtual void traverseConstantUnion(TIntermConstantUnion *node);
      virtual void traverseBinary(TIntermBinary *node);
      virtual void traverseUnary(TIntermUnary *node);
      virtual void traverseTernary(TIntermTernary *node);
      virtual void traverseSelection(TIntermSelection *node);
      virtual void traverseSwitch(TIntermSwitch *node);
      virtual void traverseCase(TIntermCase *node);
      virtual void traverseAggregate(TIntermAggregate *node);
      virtual void traverseLoop(TIntermLoop *node);
      virtual void traverseBranch(TIntermBranch *node);
  
      int getMaxDepth() const { return mMaxDepth; }
  
      // Return the original name if hash function pointer is NULL;
      // otherwise return the hashed name.
      static TString hash(const TString &name, ShHashFunction64 hashFunction);
  
      // If traversers need to replace nodes, they can add the replacements in
      // mReplacements/mMultiReplacements during traversal and the user of the traverser should call
      // this function after traversal to perform them.
      void updateTree();
  
      // Start creating temporary symbols from the given temporary symbol index + 1.
      void useTemporaryIndex(unsigned int *temporaryIndex);
  
    protected:
      void incrementDepth(TIntermNode *current)
      {
          mDepth++;
          mMaxDepth = std::max(mMaxDepth, mDepth);
          mPath.push_back(current);
      }
  
      void decrementDepth()
      {
          mDepth--;
          mPath.pop_back();
      }
  
      TIntermNode *getParentNode()
      {
          return mPath.size() == 0 ? NULL : mPath.back();
      }
  
      // Return the nth ancestor of the node being traversed. getAncestorNode(0) == getParentNode()
      TIntermNode *getAncestorNode(unsigned int n)
      {
          if (mPath.size() > n)
          {
              return mPath[mPath.size() - n - 1u];
          }
          return nullptr;
      }
  
      void pushParentBlock(TIntermAggregate *node);
      void incrementParentBlockPos();
      void popParentBlock();
  
      bool parentNodeIsBlock()
      {
          return !mParentBlockStack.empty() && getParentNode() == mParentBlockStack.back().node;
      }
  
      // To replace a single node with multiple nodes on the parent aggregate node
      struct NodeReplaceWithMultipleEntry
      {
          NodeReplaceWithMultipleEntry(TIntermAggregate *_parent, TIntermNode *_original, TIntermSequence _replacements)
              : parent(_parent),
                original(_original),
                replacements(_replacements)
          {
          }
  
          TIntermAggregate *parent;
          TIntermNode *original;
          TIntermSequence replacements;
      };
  
      // To insert multiple nodes on the parent aggregate node
      struct NodeInsertMultipleEntry
      {
          NodeInsertMultipleEntry(TIntermAggregate *_parent,
                                  TIntermSequence::size_type _position,
                                  TIntermSequence _insertionsBefore,
                                  TIntermSequence _insertionsAfter)
              : parent(_parent),
                position(_position),
                insertionsBefore(_insertionsBefore),
                insertionsAfter(_insertionsAfter)
          {
          }
  
          TIntermAggregate *parent;
          TIntermSequence::size_type position;
          TIntermSequence insertionsBefore;
          TIntermSequence insertionsAfter;
      };
  
      // Helper to insert statements in the parent block (sequence) of the node currently being traversed.
      // The statements will be inserted before the node being traversed once updateTree is called.
      // Should only be called during PreVisit or PostVisit from sequence nodes.
      // Note that inserting more than one set of nodes to the same parent node on a single updateTree call is not
      // supported.
      void insertStatementsInParentBlock(const TIntermSequence &insertions);
  
      // Same as above, but supports simultaneous insertion of statements before and after the node
      // currently being traversed.
      void insertStatementsInParentBlock(const TIntermSequence &insertionsBefore,
                                         const TIntermSequence &insertionsAfter);
  
      // Helper to insert a single statement.
      void insertStatementInParentBlock(TIntermNode *statement);
  
      // Helper to create a temporary symbol node with the given qualifier.
      TIntermSymbol *createTempSymbol(const TType &type, TQualifier qualifier);
      // Helper to create a temporary symbol node.
      TIntermSymbol *createTempSymbol(const TType &type);
      // Create a node that declares but doesn't initialize a temporary symbol.
      TIntermAggregate *createTempDeclaration(const TType &type);
      // Create a node that initializes the current temporary symbol with initializer having the given qualifier.
      TIntermAggregate *createTempInitDeclaration(TIntermTyped *initializer, TQualifier qualifier);
      // Create a node that initializes the current temporary symbol with initializer.
      TIntermAggregate *createTempInitDeclaration(TIntermTyped *initializer);
      // Create a node that assigns rightNode to the current temporary symbol.
      TIntermBinary *createTempAssignment(TIntermTyped *rightNode);
      // Increment temporary symbol index.
      void nextTemporaryIndex();
  
      enum class OriginalNode
      {
          BECOMES_CHILD,
          IS_DROPPED
      };
  
      void clearReplacementQueue();
      void queueReplacement(TIntermNode *original,
                            TIntermNode *replacement,
                            OriginalNode originalStatus);
      void queueReplacementWithParent(TIntermNode *parent,
                                      TIntermNode *original,
                                      TIntermNode *replacement,
                                      OriginalNode originalStatus);
  
      const bool preVisit;
      const bool inVisit;
      const bool postVisit;
  
      int mDepth;
      int mMaxDepth;
  
      // All the nodes from root to the current node's parent during traversing.
      TVector<TIntermNode *> mPath;
  
      bool mInGlobalScope;
  
      // During traversing, save all the changes that need to happen into
      // mReplacements/mMultiReplacements, then do them by calling updateTree().
      // Multi replacements are processed after single replacements.
      std::vector<NodeReplaceWithMultipleEntry> mMultiReplacements;
      std::vector<NodeInsertMultipleEntry> mInsertions;
  
    private:
      // To replace a single node with another on the parent node
      struct NodeUpdateEntry
      {
          NodeUpdateEntry(TIntermNode *_parent,
                          TIntermNode *_original,
                          TIntermNode *_replacement,
                          bool _originalBecomesChildOfReplacement)
              : parent(_parent),
                original(_original),
                replacement(_replacement),
                originalBecomesChildOfReplacement(_originalBecomesChildOfReplacement)
          {
          }
  
          TIntermNode *parent;
          TIntermNode *original;
          TIntermNode *replacement;
          bool originalBecomesChildOfReplacement;
      };
  
      struct ParentBlock
      {
          ParentBlock(TIntermAggregate *nodeIn, TIntermSequence::size_type posIn)
              : node(nodeIn),
                pos(posIn)
          {
          }
  
          TIntermAggregate *node;
          TIntermSequence::size_type pos;
      };
  
      std::vector<NodeUpdateEntry> mReplacements;
  
      // All the code blocks from the root to the current node's parent during traversal.
      std::vector<ParentBlock> mParentBlockStack;
  
      unsigned int *mTemporaryIndex;
  };
  
  // Traverser parent class that tracks where a node is a destination of a write operation and so is
  // required to be an l-value.
  class TLValueTrackingTraverser : public TIntermTraverser
  {
    public:
      TLValueTrackingTraverser(bool preVisit,
                               bool inVisit,
                               bool postVisit,
                               const TSymbolTable &symbolTable,
                               int shaderVersion)
          : TIntermTraverser(preVisit, inVisit, postVisit),
            mOperatorRequiresLValue(false),
            mInFunctionCallOutParameter(false),
            mSymbolTable(symbolTable),
            mShaderVersion(shaderVersion)
      {
      }
      virtual ~TLValueTrackingTraverser() {}
  
      void traverseBinary(TIntermBinary *node) final;
      void traverseUnary(TIntermUnary *node) final;
      void traverseAggregate(TIntermAggregate *node) final;
  
    protected:
      bool isLValueRequiredHere() const
      {
          return mOperatorRequiresLValue || mInFunctionCallOutParameter;
      }
  
      // Return true if the prototype or definition of the function being called has been encountered
      // during traversal.
      bool isInFunctionMap(const TIntermAggregate *callNode) const;
  
    private:
      // Track whether an l-value is required in the node that is currently being traversed by the
      // surrounding operator.
      // Use isLValueRequiredHere to check all conditions which require an l-value.
      void setOperatorRequiresLValue(bool lValueRequired)
      {
          mOperatorRequiresLValue = lValueRequired;
      }
      bool operatorRequiresLValue() const { return mOperatorRequiresLValue; }
  
      // Add a function encountered during traversal to the function map.
      void addToFunctionMap(const TName &name, TIntermSequence *paramSequence);
  
      // Return the parameters sequence from the function definition or prototype.
      TIntermSequence *getFunctionParameters(const TIntermAggregate *callNode);
  
      // Track whether an l-value is required inside a function call.
      void setInFunctionCallOutParameter(bool inOutParameter);
      bool isInFunctionCallOutParameter() const;
  
      bool mOperatorRequiresLValue;
      bool mInFunctionCallOutParameter;
  
      struct TNameComparator
      {
          bool operator()(const TName &a, const TName &b) const
          {
              int compareResult = a.getString().compare(b.getString());
              if (compareResult != 0)
                  return compareResult < 0;
              // Internal functions may have same names as non-internal functions.
              return !a.isInternal() && b.isInternal();
          }
      };
  
      // Map from mangled function names to their parameter sequences
      TMap<TName, TIntermSequence *, TNameComparator> mFunctionMap;
  
      const TSymbolTable &mSymbolTable;
      const int mShaderVersion;
  };
  
  //
  // For traversing the tree, and computing max depth.
  // Takes a maximum depth limit to prevent stack overflow.
  //
  class TMaxDepthTraverser : public TIntermTraverser
  {
    public:
      POOL_ALLOCATOR_NEW_DELETE();
      TMaxDepthTraverser(int depthLimit)
          : TIntermTraverser(true, true, false),
            mDepthLimit(depthLimit) { }
  
      bool visitBinary(Visit, TIntermBinary *) override { return depthCheck(); }
      bool visitUnary(Visit, TIntermUnary *) override { return depthCheck(); }
      bool visitTernary(Visit, TIntermTernary *) override { return depthCheck(); }
      bool visitSelection(Visit, TIntermSelection *) override { return depthCheck(); }
      bool visitAggregate(Visit, TIntermAggregate *) override { return depthCheck(); }
      bool visitLoop(Visit, TIntermLoop *) override { return depthCheck(); }
      bool visitBranch(Visit, TIntermBranch *) override { return depthCheck(); }
  
    protected:
      bool depthCheck() const { return mMaxDepth < mDepthLimit; }
  
      int mDepthLimit;
  };
  
  #endif  // COMPILER_TRANSLATOR_INTERMNODE_H_
  

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