src/OpenGL/compiler/intermediate.h - SwiftShader - Git at Google

 // Copyright 2016 The SwiftShader Authors. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //    http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 //
 // 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 __INTERMEDIATE_H
 #define __INTERMEDIATE_H

 #include "Common.h"
 #include "Types.h"
 #include "ConstantUnion.h"

 //
 // Operators used by the high-level (parse tree) representation.
 //
 enum TOperator {
 	EOpNull,            // if in a node, should only mean a node is still being built
 	EOpSequence,        // denotes a list of statements, or parameters, etc.
 	EOpFunctionCall,
 	EOpFunction,        // For function definition
 	EOpParameters,      // an aggregate listing the parameters to a function

 	EOpDeclaration,
 	EOpInvariantDeclaration, // Specialized declarations for attributing invariance
 	EOpPrototype,

 	//
 	// Unary operators
 	//

 	EOpNegative,
 	EOpLogicalNot,
 	EOpVectorLogicalNot,
 	EOpBitwiseNot,

 	EOpPostIncrement,
 	EOpPostDecrement,
 	EOpPreIncrement,
 	EOpPreDecrement,

 	//
 	// binary operations
 	//

 	EOpAdd,
 	EOpSub,
 	EOpMul,
 	EOpDiv,
 	EOpEqual,
 	EOpNotEqual,
 	EOpVectorEqual,
 	EOpVectorNotEqual,
 	EOpLessThan,
 	EOpGreaterThan,
 	EOpLessThanEqual,
 	EOpGreaterThanEqual,
 	EOpComma,

 	EOpOuterProduct,
 	EOpTranspose,
 	EOpDeterminant,
 	EOpInverse,

 	EOpVectorTimesScalar,
 	EOpVectorTimesMatrix,
 	EOpMatrixTimesVector,
 	EOpMatrixTimesScalar,

 	EOpLogicalOr,
 	EOpLogicalXor,
 	EOpLogicalAnd,

 	EOpIMod,
 	EOpBitShiftLeft,
 	EOpBitShiftRight,
 	EOpBitwiseAnd,
 	EOpBitwiseXor,
 	EOpBitwiseOr,

 	EOpIndexDirect,
 	EOpIndexIndirect,
 	EOpIndexDirectStruct,
 	EOpIndexDirectInterfaceBlock,

 	EOpVectorSwizzle,

 	//
 	// Built-in functions potentially mapped to operators
 	//

 	EOpRadians,
 	EOpDegrees,
 	EOpSin,
 	EOpCos,
 	EOpTan,
 	EOpAsin,
 	EOpAcos,
 	EOpAtan,
 	EOpSinh,
 	EOpCosh,
 	EOpTanh,
 	EOpAsinh,
 	EOpAcosh,
 	EOpAtanh,

 	EOpPow,
 	EOpExp,
 	EOpLog,
 	EOpExp2,
 	EOpLog2,
 	EOpSqrt,
 	EOpInverseSqrt,

 	EOpAbs,
 	EOpSign,
 	EOpFloor,
 	EOpTrunc,
 	EOpRound,
 	EOpRoundEven,
 	EOpCeil,
 	EOpFract,
 	EOpMod,
 	EOpModf,
 	EOpMin,
 	EOpMax,
 	EOpClamp,
 	EOpMix,
 	EOpStep,
 	EOpSmoothStep,
 	EOpIsNan,
 	EOpIsInf,
 	EOpFloatBitsToInt,
 	EOpFloatBitsToUint,
 	EOpIntBitsToFloat,
 	EOpUintBitsToFloat,
 	EOpPackSnorm2x16,
 	EOpPackUnorm2x16,
 	EOpPackHalf2x16,
 	EOpUnpackSnorm2x16,
 	EOpUnpackUnorm2x16,
 	EOpUnpackHalf2x16,

 	EOpLength,
 	EOpDistance,
 	EOpDot,
 	EOpCross,
 	EOpNormalize,
 	EOpFaceForward,
 	EOpReflect,
 	EOpRefract,

 	EOpDFdx,            // Fragment only, OES_standard_derivatives extension
 	EOpDFdy,            // Fragment only, OES_standard_derivatives extension
 	EOpFwidth,          // Fragment only, OES_standard_derivatives extension

 	EOpMatrixTimesMatrix,

 	EOpAny,
 	EOpAll,

 	//
 	// Branch
 	//

 	EOpKill,            // Fragment only
 	EOpReturn,
 	EOpBreak,
 	EOpContinue,

 	//
 	// Constructors
 	//

 	EOpConstructInt,
 	EOpConstructUInt,
 	EOpConstructBool,
 	EOpConstructFloat,
 	EOpConstructVec2,
 	EOpConstructVec3,
 	EOpConstructVec4,
 	EOpConstructBVec2,
 	EOpConstructBVec3,
 	EOpConstructBVec4,
 	EOpConstructIVec2,
 	EOpConstructIVec3,
 	EOpConstructIVec4,
 	EOpConstructUVec2,
 	EOpConstructUVec3,
 	EOpConstructUVec4,
 	EOpConstructMat2,
 	EOpConstructMat2x3,
 	EOpConstructMat2x4,
 	EOpConstructMat3x2,
 	EOpConstructMat3,
 	EOpConstructMat3x4,
 	EOpConstructMat4x2,
 	EOpConstructMat4x3,
 	EOpConstructMat4,
 	EOpConstructStruct,

 	//
 	// moves
 	//

 	EOpAssign,
 	EOpInitialize,
 	EOpAddAssign,
 	EOpSubAssign,
 	EOpMulAssign,
 	EOpVectorTimesMatrixAssign,
 	EOpVectorTimesScalarAssign,
 	EOpMatrixTimesScalarAssign,
 	EOpMatrixTimesMatrixAssign,
 	EOpDivAssign,
 	EOpIModAssign,
 	EOpBitShiftLeftAssign,
 	EOpBitShiftRightAssign,
 	EOpBitwiseAndAssign,
 	EOpBitwiseXorAssign,
 	EOpBitwiseOrAssign
 };

 extern TOperator TypeToConstructorOperator(const TType &type);
 extern const char* getOperatorString(TOperator op);

 class TIntermTraverser;
 class TIntermAggregate;
 class TIntermBinary;
 class TIntermUnary;
 class TIntermConstantUnion;
 class TIntermSelection;
 class TIntermTyped;
 class TIntermSymbol;
 class TIntermLoop;
 class TIntermBranch;
 class TInfoSink;
 class TIntermSwitch;
 class TIntermCase;

 //
 // Base class for the tree nodes
 //
 class TIntermNode {
 public:
 	POOL_ALLOCATOR_NEW_DELETE()

 	TIntermNode()
 	{
 		// TODO: Move this to TSourceLoc constructor
 		// after getting rid of TPublicType.
 		line.first_file = line.last_file = 0;
 		line.first_line = line.last_line = 0;
 	}

 	const TSourceLoc& getLine() const { return line; }
 	void setLine(const TSourceLoc& l) { line = 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 TIntermSelection* getAsSelectionNode() { return 0; }
 	virtual TIntermSymbol* getAsSymbolNode() { return 0; }
 	virtual TIntermLoop* getAsLoopNode() { return 0; }
 	virtual TIntermBranch* getAsBranchNode() { return 0; }
 	virtual TIntermSwitch *getAsSwitchNode() { return 0; }
 	virtual TIntermCase *getAsCaseNode() { return 0; }
 	virtual ~TIntermNode() { }

 protected:
 	TSourceLoc line;
 };

 //
 // 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) : type(t)  { }
 	virtual TIntermTyped* getAsTyped() { return this; }

 	virtual void setType(const TType& t) { type = t; }
 	const TType& getType() const { return type; }
 	TType* getTypePointer() { return &type; }

 	TBasicType getBasicType() const { return type.getBasicType(); }
 	TQualifier getQualifier() const { return type.getQualifier(); }
 	TPrecision getPrecision() const { return type.getPrecision(); }
 	int getNominalSize() const { return type.getNominalSize(); }
 	int getSecondarySize() const { return type.getSecondarySize(); }

 	bool isInterfaceBlock() const { return type.isInterfaceBlock(); }
 	bool isMatrix() const { return type.isMatrix(); }
 	bool isArray()  const { return type.isArray(); }
 	bool isVector() const { return type.isVector(); }
 	bool isScalar() const { return type.isScalar(); }
 	bool isScalarInt() const { return type.isScalarInt(); }
 	bool isRegister() const { return type.isRegister(); }   // Fits in a 4-element register
 	bool isStruct() const { return type.isStruct(); }
 	const char* getBasicString() const { return type.getBasicString(); }
 	const char* getQualifierString() const { return type.getQualifierString(); }
 	TString getCompleteString() const { return type.getCompleteString(); }

 	int totalRegisterCount() const { return type.totalRegisterCount(); }
 	int blockRegisterCount(bool samplersOnly) const { return samplersOnly ? type.totalSamplerRegisterCount() : type.blockRegisterCount(); }
 	int elementRegisterCount() const { return type.elementRegisterCount(); }
 	int registerSize() const { return type.registerSize(); }
 	int getArraySize() const { return type.getArraySize(); }

 	static TIntermTyped *CreateIndexNode(int index);
 protected:
 	TType type;
 };

 //
 // Handle for, do-while, and while loops.
 //
 enum TLoopType {
 	ELoopFor,
 	ELoopWhile,
 	ELoopDoWhile
 };

 class TIntermLoop : public TIntermNode {
 public:
 	TIntermLoop(TLoopType aType,
 	            TIntermNode *aInit, TIntermTyped* aCond, TIntermTyped* aExpr,
 	            TIntermNode* aBody) :
 			type(aType),
 			init(aInit),
 			cond(aCond),
 			expr(aExpr),
 			body(aBody),
 			unrollFlag(false) { }

 	virtual TIntermLoop* getAsLoopNode() { return this; }
 	virtual void traverse(TIntermTraverser*);

 	TLoopType getType() const { return type; }
 	TIntermNode* getInit() { return init; }
 	TIntermTyped* getCondition() { return cond; }
 	TIntermTyped* getExpression() { return expr; }
 	TIntermNode* getBody() { return body; }

 	void setUnrollFlag(bool flag) { unrollFlag = flag; }
 	bool getUnrollFlag() { return unrollFlag; }

 protected:
 	TLoopType type;
 	TIntermNode* init;  // for-loop initialization
 	TIntermTyped* cond; // loop exit condition
 	TIntermTyped* expr; // for-loop expression
 	TIntermNode* body;  // loop body

 	bool unrollFlag; // Whether the loop should be unrolled or not.
 };

 //
 // Handle break, continue, return, and kill.
 //
 class TIntermBranch : public TIntermNode {
 public:
 	TIntermBranch(TOperator op, TIntermTyped* e) :
 			flowOp(op),
 			expression(e) { }

 	virtual TIntermBranch* getAsBranchNode() { return this; }
 	virtual void traverse(TIntermTraverser*);

 	TOperator getFlowOp() { return flowOp; }
 	TIntermTyped* getExpression() { return expression; }

 protected:
 	TOperator flowOp;
 	TIntermTyped* expression;  // 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 i, const TString& sym, const TType& t) :
 			TIntermTyped(t), id(i)  { symbol = sym; }

 	int getId() const { return id; }
 	const TString& getSymbol() const { return symbol; }

 	void setId(int newId) { id = newId; }

 	virtual void traverse(TIntermTraverser*);
 	virtual TIntermSymbol* getAsSymbolNode() { return this; }

 protected:
 	int id;
 	TString symbol;
 };

 class TIntermConstantUnion : public TIntermTyped {
 public:
 	TIntermConstantUnion(ConstantUnion *unionPointer, const TType& t) : TIntermTyped(t), unionArrayPointer(unionPointer)
 	{
 		getTypePointer()->setQualifier(EvqConstExpr);
 	}

 	ConstantUnion* getUnionArrayPointer() const { return unionArrayPointer; }

 	int getIConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getIConst() : 0; }
 	int getUConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getUConst() : 0; }
 	float getFConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getFConst() : 0.0f; }
 	bool getBConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getBConst() : false; }

 	// Previous union pointer freed on pool deallocation.
 	void replaceConstantUnion(ConstantUnion *safeConstantUnion) { unionArrayPointer = safeConstantUnion; }

 	virtual TIntermConstantUnion* getAsConstantUnion()  { return this; }
 	virtual void traverse(TIntermTraverser*);

 	TIntermTyped* fold(TOperator, TIntermTyped*, TInfoSink&);

 protected:
 	ConstantUnion *unionArrayPointer;
 };

 //
 // Intermediate class for node types that hold operators.
 //
 class TIntermOperator : public TIntermTyped {
 public:
 	TOperator getOp() const { return op; }
 	void setOp(TOperator o) { op = o; }

 	bool modifiesState() const;
 	bool isConstructor() const;

 protected:
 	TIntermOperator(TOperator o) : TIntermTyped(TType(EbtFloat, EbpUndefined)), op(o) {}
 	TIntermOperator(TOperator o, TType& t) : TIntermTyped(t), op(o) {}
 	TOperator op;
 };

 //
 // Nodes for all the basic binary math operators.
 //
 class TIntermBinary : public TIntermOperator {
 public:
 	TIntermBinary(TOperator o) : TIntermOperator(o) {}

 	TIntermBinary* getAsBinaryNode() override { return this; }
 	void traverse(TIntermTraverser*) override;

 	void setType(const TType &t) override
 	{
 		type = t;

 		if(left->getQualifier() == EvqConstExpr && right->getQualifier() == EvqConstExpr)
 		{
 			type.setQualifier(EvqConstExpr);
 		}
 	}

 	void setLeft(TIntermTyped* n) { left = n; }
 	void setRight(TIntermTyped* n) { right = n; }
 	TIntermTyped* getLeft() const { return left; }
 	TIntermTyped* getRight() const { return right; }
 	bool promote(TInfoSink&);

 protected:
 	TIntermTyped* left;
 	TIntermTyped* right;
 };

 //
 // Nodes for unary math operators.
 //
 class TIntermUnary : public TIntermOperator {
 public:
 	TIntermUnary(TOperator o, TType& t) : TIntermOperator(o, t), operand(0) {}
 	TIntermUnary(TOperator o) : TIntermOperator(o), operand(0) {}

 	void setType(const TType &t) override
 	{
 		type = t;

 		if(operand->getQualifier() == EvqConstExpr)
 		{
 			type.setQualifier(EvqConstExpr);
 		}
 	}

 	void traverse(TIntermTraverser*) override;
 	TIntermUnary* getAsUnaryNode() override { return this; }

 	void setOperand(TIntermTyped* o) { operand = o; }
 	TIntermTyped* getOperand() { return operand; }
 	bool promote(TInfoSink&, const TType *funcReturnType);

 protected:
 	TIntermTyped* operand;
 };

 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), userDefined(false) { endLine = { 0, 0, 0, 0 }; }
 	TIntermAggregate(TOperator o) : TIntermOperator(o), userDefined(false) { endLine = { 0, 0, 0, 0 }; }
 	~TIntermAggregate() { }

 	TIntermAggregate* getAsAggregate() override { return this; }
 	void traverse(TIntermTraverser*) override;

 	TIntermSequence& getSequence() { return sequence; }

 	void setType(const TType &t) override
 	{
 		type = t;

 		if(op != EOpFunctionCall)
 		{
 			for(TIntermNode *node : sequence)
 			{
 				if(!node->getAsTyped() || node->getAsTyped()->getQualifier() != EvqConstExpr)
 				{
 					return;
 				}
 			}

 			type.setQualifier(EvqConstExpr);
 		}
 	}

 	void setName(const TString& n) { name = n; }
 	const TString& getName() const { return name; }

 	void setUserDefined() { userDefined = true; }
 	bool isUserDefined() const { return userDefined; }

 	void setOptimize(bool o) { optimize = o; }
 	bool getOptimize() { return optimize; }
 	void setDebug(bool d) { debug = d; }
 	bool getDebug() { return debug; }

 	void setEndLine(const TSourceLoc& line) { endLine = line; }
 	const TSourceLoc& getEndLine() const { return endLine; }

 	bool isConstantFoldable()
 	{
 		for(TIntermNode *node : sequence)
 		{
 			if(!node->getAsConstantUnion() || !node->getAsConstantUnion()->getUnionArrayPointer())
 			{
 				return false;
 			}
 		}

 		return true;
 	}

 protected:
 	TIntermAggregate(const TIntermAggregate&); // disallow copy constructor
 	TIntermAggregate& operator=(const TIntermAggregate&); // disallow assignment operator
 	TIntermSequence sequence;
 	TString name;
 	bool userDefined; // used for user defined function names

 	bool optimize;
 	bool debug;
 	TSourceLoc endLine;
 };

 //
 // For if tests.  Simplified since there is no switch statement.
 //
 class TIntermSelection : public TIntermTyped {
 public:
 	TIntermSelection(TIntermTyped* cond, TIntermNode* trueB, TIntermNode* falseB) :
 			TIntermTyped(TType(EbtVoid, EbpUndefined)), condition(cond), trueBlock(trueB), falseBlock(falseB) {}
 	TIntermSelection(TIntermTyped* cond, TIntermNode* trueB, TIntermNode* falseB, const TType& type) :
 			TIntermTyped(type), condition(cond), trueBlock(trueB), falseBlock(falseB)
 	{
 		this->type.setQualifier(EvqTemporary);
 	}

 	virtual void traverse(TIntermTraverser*);

 	bool usesTernaryOperator() const { return getBasicType() != EbtVoid; }
 	TIntermTyped* getCondition() const { return condition; }
 	TIntermNode* getTrueBlock() const { return trueBlock; }
 	TIntermNode* getFalseBlock() const { return falseBlock; }
 	TIntermSelection* getAsSelectionNode() { return this; }

 protected:
 	TIntermTyped* condition;
 	TIntermNode* trueBlock;
 	TIntermNode* falseBlock;
 };

 //
 // Switch statement.
 //
 class TIntermSwitch : public TIntermNode
 {
 public:
 	TIntermSwitch(TIntermTyped *init, TIntermAggregate *statementList)
 		: TIntermNode(), mInit(init), mStatementList(statementList)
 	{}

 	void traverse(TIntermTraverser *it);

 	TIntermSwitch *getAsSwitchNode() { 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);

 	TIntermCase *getAsCaseNode() { 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,
 // put their traversal specific data in it, and then pass
 // it to a Traverse method.
 //
 // 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
 {
 public:
 	POOL_ALLOCATOR_NEW_DELETE()
 	TIntermTraverser(bool preVisit = true, bool inVisit = false, bool postVisit = false, bool rightToLeft = false) :
 			preVisit(preVisit),
 			inVisit(inVisit),
 			postVisit(postVisit),
 			rightToLeft(rightToLeft),
 			mDepth(0) {}
 	virtual ~TIntermTraverser() {}

 	virtual void visitSymbol(TIntermSymbol*) {}
 	virtual void visitConstantUnion(TIntermConstantUnion*) {}
 	virtual bool visitBinary(Visit visit, TIntermBinary*) {return true;}
 	virtual bool visitUnary(Visit visit, TIntermUnary*) {return true;}
 	virtual bool visitSelection(Visit visit, TIntermSelection*) {return true;}
 	virtual bool visitAggregate(Visit visit, TIntermAggregate*) {return true;}
 	virtual bool visitLoop(Visit visit, TIntermLoop*) {return true;}
 	virtual bool visitBranch(Visit visit, TIntermBranch*) {return true;}
 	virtual bool visitSwitch(Visit, TIntermSwitch*) { return true; }
 	virtual bool visitCase(Visit, TIntermCase*) { return true; }

 	void incrementDepth(TIntermNode *current)
 	{
 		mDepth++;
 		mPath.push_back(current);
 	}

 	void decrementDepth()
 	{
 		mDepth--;
 		mPath.pop_back();
 	}

 	TIntermNode *getParentNode()
 	{
 		return mPath.size() == 0 ? nullptr : mPath.back();
 	}

 	const bool preVisit;
 	const bool inVisit;
 	const bool postVisit;
 	const bool rightToLeft;

 protected:
 	int mDepth;

 	// All the nodes from root to the current node's parent during traversing.
 	TVector<TIntermNode *> mPath;

 private:
 	struct ParentBlock
 	{
 		ParentBlock(TIntermAggregate *nodeIn, TIntermSequence::size_type posIn)
 		: node(nodeIn), pos(posIn)
 		{}

 		TIntermAggregate *node;
 		TIntermSequence::size_type pos;
 	};
 	// All the code blocks from the root to the current node's parent during traversal.
 	std::vector<ParentBlock> mParentBlockStack;
 };

 #endif // __INTERMEDIATE_H
	// Copyright 2016 The SwiftShader Authors. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	//
	// 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 __INTERMEDIATE_H
	#define __INTERMEDIATE_H

	#include "Common.h"
	#include "Types.h"
	#include "ConstantUnion.h"

	//
	// Operators used by the high-level (parse tree) representation.
	//
	enum TOperator {
	EOpNull, // if in a node, should only mean a node is still being built
	EOpSequence, // denotes a list of statements, or parameters, etc.
	EOpFunctionCall,
	EOpFunction, // For function definition
	EOpParameters, // an aggregate listing the parameters to a function

	EOpDeclaration,
	EOpInvariantDeclaration, // Specialized declarations for attributing invariance
	EOpPrototype,

	//
	// Unary operators
	//

	EOpNegative,
	EOpLogicalNot,
	EOpVectorLogicalNot,
	EOpBitwiseNot,

	EOpPostIncrement,
	EOpPostDecrement,
	EOpPreIncrement,
	EOpPreDecrement,

	//
	// binary operations
	//

	EOpAdd,
	EOpSub,
	EOpMul,
	EOpDiv,
	EOpEqual,
	EOpNotEqual,
	EOpVectorEqual,
	EOpVectorNotEqual,
	EOpLessThan,
	EOpGreaterThan,
	EOpLessThanEqual,
	EOpGreaterThanEqual,
	EOpComma,

	EOpOuterProduct,
	EOpTranspose,
	EOpDeterminant,
	EOpInverse,

	EOpVectorTimesScalar,
	EOpVectorTimesMatrix,
	EOpMatrixTimesVector,
	EOpMatrixTimesScalar,

	EOpLogicalOr,
	EOpLogicalXor,
	EOpLogicalAnd,

	EOpIMod,
	EOpBitShiftLeft,
	EOpBitShiftRight,
	EOpBitwiseAnd,
	EOpBitwiseXor,
	EOpBitwiseOr,

	EOpIndexDirect,
	EOpIndexIndirect,
	EOpIndexDirectStruct,
	EOpIndexDirectInterfaceBlock,

	EOpVectorSwizzle,

	//
	// Built-in functions potentially mapped to operators
	//

	EOpRadians,
	EOpDegrees,
	EOpSin,
	EOpCos,
	EOpTan,
	EOpAsin,
	EOpAcos,
	EOpAtan,
	EOpSinh,
	EOpCosh,
	EOpTanh,
	EOpAsinh,
	EOpAcosh,
	EOpAtanh,

	EOpPow,
	EOpExp,
	EOpLog,
	EOpExp2,
	EOpLog2,
	EOpSqrt,
	EOpInverseSqrt,

	EOpAbs,
	EOpSign,
	EOpFloor,
	EOpTrunc,
	EOpRound,
	EOpRoundEven,
	EOpCeil,
	EOpFract,
	EOpMod,
	EOpModf,
	EOpMin,
	EOpMax,
	EOpClamp,
	EOpMix,
	EOpStep,
	EOpSmoothStep,
	EOpIsNan,
	EOpIsInf,
	EOpFloatBitsToInt,
	EOpFloatBitsToUint,
	EOpIntBitsToFloat,
	EOpUintBitsToFloat,
	EOpPackSnorm2x16,
	EOpPackUnorm2x16,
	EOpPackHalf2x16,
	EOpUnpackSnorm2x16,
	EOpUnpackUnorm2x16,
	EOpUnpackHalf2x16,

	EOpLength,
	EOpDistance,
	EOpDot,
	EOpCross,
	EOpNormalize,
	EOpFaceForward,
	EOpReflect,
	EOpRefract,

	EOpDFdx, // Fragment only, OES_standard_derivatives extension
	EOpDFdy, // Fragment only, OES_standard_derivatives extension
	EOpFwidth, // Fragment only, OES_standard_derivatives extension

	EOpMatrixTimesMatrix,

	EOpAny,
	EOpAll,

	//
	// Branch
	//

	EOpKill, // Fragment only
	EOpReturn,
	EOpBreak,
	EOpContinue,

	//
	// Constructors
	//

	EOpConstructInt,
	EOpConstructUInt,
	EOpConstructBool,
	EOpConstructFloat,
	EOpConstructVec2,
	EOpConstructVec3,
	EOpConstructVec4,
	EOpConstructBVec2,
	EOpConstructBVec3,
	EOpConstructBVec4,
	EOpConstructIVec2,
	EOpConstructIVec3,
	EOpConstructIVec4,
	EOpConstructUVec2,
	EOpConstructUVec3,
	EOpConstructUVec4,
	EOpConstructMat2,
	EOpConstructMat2x3,
	EOpConstructMat2x4,
	EOpConstructMat3x2,
	EOpConstructMat3,
	EOpConstructMat3x4,
	EOpConstructMat4x2,
	EOpConstructMat4x3,
	EOpConstructMat4,
	EOpConstructStruct,

	//
	// moves
	//

	EOpAssign,
	EOpInitialize,
	EOpAddAssign,
	EOpSubAssign,
	EOpMulAssign,
	EOpVectorTimesMatrixAssign,
	EOpVectorTimesScalarAssign,
	EOpMatrixTimesScalarAssign,
	EOpMatrixTimesMatrixAssign,
	EOpDivAssign,
	EOpIModAssign,
	EOpBitShiftLeftAssign,
	EOpBitShiftRightAssign,
	EOpBitwiseAndAssign,
	EOpBitwiseXorAssign,
	EOpBitwiseOrAssign
	};

	extern TOperator TypeToConstructorOperator(const TType &type);
	extern const char* getOperatorString(TOperator op);

	class TIntermTraverser;
	class TIntermAggregate;
	class TIntermBinary;
	class TIntermUnary;
	class TIntermConstantUnion;
	class TIntermSelection;
	class TIntermTyped;
	class TIntermSymbol;
	class TIntermLoop;
	class TIntermBranch;
	class TInfoSink;
	class TIntermSwitch;
	class TIntermCase;

	//
	// Base class for the tree nodes
	//
	class TIntermNode {
	public:
	POOL_ALLOCATOR_NEW_DELETE()

	TIntermNode()
	{
	// TODO: Move this to TSourceLoc constructor
	// after getting rid of TPublicType.
	line.first_file = line.last_file = 0;
	line.first_line = line.last_line = 0;
	}

	const TSourceLoc& getLine() const { return line; }
	void setLine(const TSourceLoc& l) { line = 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 TIntermSelection* getAsSelectionNode() { return 0; }
	virtual TIntermSymbol* getAsSymbolNode() { return 0; }
	virtual TIntermLoop* getAsLoopNode() { return 0; }
	virtual TIntermBranch* getAsBranchNode() { return 0; }
	virtual TIntermSwitch *getAsSwitchNode() { return 0; }
	virtual TIntermCase *getAsCaseNode() { return 0; }
	virtual ~TIntermNode() { }

	protected:
	TSourceLoc line;
	};

	//
	// 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) : type(t) { }
	virtual TIntermTyped* getAsTyped() { return this; }

	virtual void setType(const TType& t) { type = t; }
	const TType& getType() const { return type; }
	TType* getTypePointer() { return &type; }

	TBasicType getBasicType() const { return type.getBasicType(); }
	TQualifier getQualifier() const { return type.getQualifier(); }
	TPrecision getPrecision() const { return type.getPrecision(); }
	int getNominalSize() const { return type.getNominalSize(); }
	int getSecondarySize() const { return type.getSecondarySize(); }

	bool isInterfaceBlock() const { return type.isInterfaceBlock(); }
	bool isMatrix() const { return type.isMatrix(); }
	bool isArray() const { return type.isArray(); }
	bool isVector() const { return type.isVector(); }
	bool isScalar() const { return type.isScalar(); }
	bool isScalarInt() const { return type.isScalarInt(); }
	bool isRegister() const { return type.isRegister(); } // Fits in a 4-element register
	bool isStruct() const { return type.isStruct(); }
	const char* getBasicString() const { return type.getBasicString(); }
	const char* getQualifierString() const { return type.getQualifierString(); }
	TString getCompleteString() const { return type.getCompleteString(); }

	int totalRegisterCount() const { return type.totalRegisterCount(); }
	int blockRegisterCount(bool samplersOnly) const { return samplersOnly ? type.totalSamplerRegisterCount() : type.blockRegisterCount(); }
	int elementRegisterCount() const { return type.elementRegisterCount(); }
	int registerSize() const { return type.registerSize(); }
	int getArraySize() const { return type.getArraySize(); }

	static TIntermTyped *CreateIndexNode(int index);
	protected:
	TType type;
	};

	//
	// Handle for, do-while, and while loops.
	//
	enum TLoopType {
	ELoopFor,
	ELoopWhile,
	ELoopDoWhile
	};

	class TIntermLoop : public TIntermNode {
	public:
	TIntermLoop(TLoopType aType,
	TIntermNode aInit, TIntermTyped aCond, TIntermTyped* aExpr,
	TIntermNode* aBody) :
	type(aType),
	init(aInit),
	cond(aCond),
	expr(aExpr),
	body(aBody),
	unrollFlag(false) { }

	virtual TIntermLoop* getAsLoopNode() { return this; }
	virtual void traverse(TIntermTraverser*);

	TLoopType getType() const { return type; }
	TIntermNode* getInit() { return init; }
	TIntermTyped* getCondition() { return cond; }
	TIntermTyped* getExpression() { return expr; }
	TIntermNode* getBody() { return body; }

	void setUnrollFlag(bool flag) { unrollFlag = flag; }
	bool getUnrollFlag() { return unrollFlag; }

	protected:
	TLoopType type;
	TIntermNode* init; // for-loop initialization
	TIntermTyped* cond; // loop exit condition
	TIntermTyped* expr; // for-loop expression
	TIntermNode* body; // loop body

	bool unrollFlag; // Whether the loop should be unrolled or not.
	};

	//
	// Handle break, continue, return, and kill.
	//
	class TIntermBranch : public TIntermNode {
	public:
	TIntermBranch(TOperator op, TIntermTyped* e) :
	flowOp(op),
	expression(e) { }

	virtual TIntermBranch* getAsBranchNode() { return this; }
	virtual void traverse(TIntermTraverser*);

	TOperator getFlowOp() { return flowOp; }
	TIntermTyped* getExpression() { return expression; }

	protected:
	TOperator flowOp;
	TIntermTyped* expression; // 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 i, const TString& sym, const TType& t) :
	TIntermTyped(t), id(i) { symbol = sym; }

	int getId() const { return id; }
	const TString& getSymbol() const { return symbol; }

	void setId(int newId) { id = newId; }

	virtual void traverse(TIntermTraverser*);
	virtual TIntermSymbol* getAsSymbolNode() { return this; }

	protected:
	int id;
	TString symbol;
	};

	class TIntermConstantUnion : public TIntermTyped {
	public:
	TIntermConstantUnion(ConstantUnion *unionPointer, const TType& t) : TIntermTyped(t), unionArrayPointer(unionPointer)
	{
	getTypePointer()->setQualifier(EvqConstExpr);
	}

	ConstantUnion* getUnionArrayPointer() const { return unionArrayPointer; }

	int getIConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getIConst() : 0; }
	int getUConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getUConst() : 0; }
	float getFConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getFConst() : 0.0f; }
	bool getBConst(int index) const { return unionArrayPointer ? unionArrayPointer[index].getBConst() : false; }

	// Previous union pointer freed on pool deallocation.
	void replaceConstantUnion(ConstantUnion *safeConstantUnion) { unionArrayPointer = safeConstantUnion; }

	virtual TIntermConstantUnion* getAsConstantUnion() { return this; }
	virtual void traverse(TIntermTraverser*);

	TIntermTyped* fold(TOperator, TIntermTyped*, TInfoSink&);

	protected:
	ConstantUnion *unionArrayPointer;
	};

	//
	// Intermediate class for node types that hold operators.
	//
	class TIntermOperator : public TIntermTyped {
	public:
	TOperator getOp() const { return op; }
	void setOp(TOperator o) { op = o; }

	bool modifiesState() const;
	bool isConstructor() const;

	protected:
	TIntermOperator(TOperator o) : TIntermTyped(TType(EbtFloat, EbpUndefined)), op(o) {}
	TIntermOperator(TOperator o, TType& t) : TIntermTyped(t), op(o) {}
	TOperator op;
	};

	//
	// Nodes for all the basic binary math operators.
	//
	class TIntermBinary : public TIntermOperator {
	public:
	TIntermBinary(TOperator o) : TIntermOperator(o) {}

	TIntermBinary* getAsBinaryNode() override { return this; }
	void traverse(TIntermTraverser*) override;

	void setType(const TType &t) override
	{
	type = t;

	if(left->getQualifier() == EvqConstExpr && right->getQualifier() == EvqConstExpr)
	{
	type.setQualifier(EvqConstExpr);
	}
	}

	void setLeft(TIntermTyped* n) { left = n; }
	void setRight(TIntermTyped* n) { right = n; }
	TIntermTyped* getLeft() const { return left; }
	TIntermTyped* getRight() const { return right; }
	bool promote(TInfoSink&);

	protected:
	TIntermTyped* left;
	TIntermTyped* right;
	};

	//
	// Nodes for unary math operators.
	//
	class TIntermUnary : public TIntermOperator {
	public:
	TIntermUnary(TOperator o, TType& t) : TIntermOperator(o, t), operand(0) {}
	TIntermUnary(TOperator o) : TIntermOperator(o), operand(0) {}

	void setType(const TType &t) override
	{
	type = t;

	if(operand->getQualifier() == EvqConstExpr)
	{
	type.setQualifier(EvqConstExpr);
	}
	}

	void traverse(TIntermTraverser*) override;
	TIntermUnary* getAsUnaryNode() override { return this; }

	void setOperand(TIntermTyped* o) { operand = o; }
	TIntermTyped* getOperand() { return operand; }
	bool promote(TInfoSink&, const TType *funcReturnType);

	protected:
	TIntermTyped* operand;
	};

	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), userDefined(false) { endLine = { 0, 0, 0, 0 }; }
	TIntermAggregate(TOperator o) : TIntermOperator(o), userDefined(false) { endLine = { 0, 0, 0, 0 }; }
	~TIntermAggregate() { }

	TIntermAggregate* getAsAggregate() override { return this; }
	void traverse(TIntermTraverser*) override;

	TIntermSequence& getSequence() { return sequence; }

	void setType(const TType &t) override
	{
	type = t;

	if(op != EOpFunctionCall)
	{
	for(TIntermNode *node : sequence)
	{
	if(!node->getAsTyped() \|\| node->getAsTyped()->getQualifier() != EvqConstExpr)
	{
	return;
	}
	}

	type.setQualifier(EvqConstExpr);
	}
	}

	void setName(const TString& n) { name = n; }
	const TString& getName() const { return name; }

	void setUserDefined() { userDefined = true; }
	bool isUserDefined() const { return userDefined; }

	void setOptimize(bool o) { optimize = o; }
	bool getOptimize() { return optimize; }
	void setDebug(bool d) { debug = d; }
	bool getDebug() { return debug; }

	void setEndLine(const TSourceLoc& line) { endLine = line; }
	const TSourceLoc& getEndLine() const { return endLine; }

	bool isConstantFoldable()
	{
	for(TIntermNode *node : sequence)
	{
	if(!node->getAsConstantUnion() \|\| !node->getAsConstantUnion()->getUnionArrayPointer())
	{
	return false;
	}
	}

	return true;
	}

	protected:
	TIntermAggregate(const TIntermAggregate&); // disallow copy constructor
	TIntermAggregate& operator=(const TIntermAggregate&); // disallow assignment operator
	TIntermSequence sequence;
	TString name;
	bool userDefined; // used for user defined function names

	bool optimize;
	bool debug;
	TSourceLoc endLine;
	};

	//
	// For if tests. Simplified since there is no switch statement.
	//
	class TIntermSelection : public TIntermTyped {
	public:
	TIntermSelection(TIntermTyped* cond, TIntermNode* trueB, TIntermNode* falseB) :
	TIntermTyped(TType(EbtVoid, EbpUndefined)), condition(cond), trueBlock(trueB), falseBlock(falseB) {}
	TIntermSelection(TIntermTyped* cond, TIntermNode* trueB, TIntermNode* falseB, const TType& type) :
	TIntermTyped(type), condition(cond), trueBlock(trueB), falseBlock(falseB)
	{
	this->type.setQualifier(EvqTemporary);
	}

	virtual void traverse(TIntermTraverser*);

	bool usesTernaryOperator() const { return getBasicType() != EbtVoid; }
	TIntermTyped* getCondition() const { return condition; }
	TIntermNode* getTrueBlock() const { return trueBlock; }
	TIntermNode* getFalseBlock() const { return falseBlock; }
	TIntermSelection* getAsSelectionNode() { return this; }

	protected:
	TIntermTyped* condition;
	TIntermNode* trueBlock;
	TIntermNode* falseBlock;
	};

	//
	// Switch statement.
	//
	class TIntermSwitch : public TIntermNode
	{
	public:
	TIntermSwitch(TIntermTyped init, TIntermAggregate statementList)
	: TIntermNode(), mInit(init), mStatementList(statementList)
	{}

	void traverse(TIntermTraverser *it);

	TIntermSwitch *getAsSwitchNode() { 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);

	TIntermCase *getAsCaseNode() { 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,
	// put their traversal specific data in it, and then pass
	// it to a Traverse method.
	//
	// 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
	{
	public:
	POOL_ALLOCATOR_NEW_DELETE()
	TIntermTraverser(bool preVisit = true, bool inVisit = false, bool postVisit = false, bool rightToLeft = false) :
	preVisit(preVisit),
	inVisit(inVisit),
	postVisit(postVisit),
	rightToLeft(rightToLeft),
	mDepth(0) {}
	virtual ~TIntermTraverser() {}

	virtual void visitSymbol(TIntermSymbol*) {}
	virtual void visitConstantUnion(TIntermConstantUnion*) {}
	virtual bool visitBinary(Visit visit, TIntermBinary*) {return true;}
	virtual bool visitUnary(Visit visit, TIntermUnary*) {return true;}
	virtual bool visitSelection(Visit visit, TIntermSelection*) {return true;}
	virtual bool visitAggregate(Visit visit, TIntermAggregate*) {return true;}
	virtual bool visitLoop(Visit visit, TIntermLoop*) {return true;}
	virtual bool visitBranch(Visit visit, TIntermBranch*) {return true;}
	virtual bool visitSwitch(Visit, TIntermSwitch*) { return true; }
	virtual bool visitCase(Visit, TIntermCase*) { return true; }

	void incrementDepth(TIntermNode *current)
	{
	mDepth++;
	mPath.push_back(current);
	}

	void decrementDepth()
	{
	mDepth--;
	mPath.pop_back();
	}

	TIntermNode *getParentNode()
	{
	return mPath.size() == 0 ? nullptr : mPath.back();
	}

	const bool preVisit;
	const bool inVisit;
	const bool postVisit;
	const bool rightToLeft;

	protected:
	int mDepth;

	// All the nodes from root to the current node's parent during traversing.
	TVector<TIntermNode *> mPath;

	private:
	struct ParentBlock
	{
	ParentBlock(TIntermAggregate *nodeIn, TIntermSequence::size_type posIn)
	: node(nodeIn), pos(posIn)
	{}

	TIntermAggregate *node;
	TIntermSequence::size_type pos;
	};
	// All the code blocks from the root to the current node's parent during traversal.
	std::vector<ParentBlock> mParentBlockStack;
	};

	#endif // __INTERMEDIATE_H