src/OpenGL/compiler/SymbolTable.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.

 #ifndef _SYMBOL_TABLE_INCLUDED_
 #define _SYMBOL_TABLE_INCLUDED_

 //
 // Symbol table for parsing.  Has these design characteristics:
 //
 // * Same symbol table can be used to compile many shaders, to preserve
 //   effort of creating and loading with the large numbers of built-in
 //   symbols.
 //
 // * Name mangling will be used to give each function a unique name
 //   so that symbol table lookups are never ambiguous.  This allows
 //   a simpler symbol table structure.
 //
 // * Pushing and popping of scope, so symbol table will really be a stack
 //   of symbol tables.  Searched from the top, with new inserts going into
 //   the top.
 //
 // * Constants:  Compile time constant symbols will keep their values
 //   in the symbol table.  The parser can substitute constants at parse
 //   time, including doing constant folding and constant propagation.
 //
 // * No temporaries:  Temporaries made from operations (+, --, .xy, etc.)
 //   are tracked in the intermediate representation, not the symbol table.
 //

 #if defined(__ANDROID__) && !defined(ANDROID_HOST_BUILD) && !defined(ANDROID_NDK_BUILD)
 #include "../../Common/DebugAndroid.hpp"
 #else
 #include <assert.h>
 #endif

 #include "InfoSink.h"
 #include "intermediate.h"
 #include <set>

 //
 // Symbol base class.  (Can build functions or variables out of these...)
 //
 class TSymbol
 {
 public:
 	POOL_ALLOCATOR_NEW_DELETE()
 	TSymbol(const TString *n) :  name(n) { }
 	virtual ~TSymbol() { /* don't delete name, it's from the pool */ }

 	const TString& getName() const { return *name; }
 	virtual const TString& getMangledName() const { return getName(); }
 	virtual bool isFunction() const { return false; }
 	virtual bool isVariable() const { return false; }
 	void setUniqueId(int id) { uniqueId = id; }
 	int getUniqueId() const { return uniqueId; }
 	TSymbol(const TSymbol&);

 protected:
 	const TString *name;
 	unsigned int uniqueId;      // For real comparing during code generation
 };

 //
 // Variable class, meaning a symbol that's not a function.
 //
 // There could be a separate class heirarchy for Constant variables;
 // Only one of int, bool, or float, (or none) is correct for
 // any particular use, but it's easy to do this way, and doesn't
 // seem worth having separate classes, and "getConst" can't simply return
 // different values for different types polymorphically, so this is
 // just simple and pragmatic.
 //
 class TVariable : public TSymbol
 {
 public:
 	TVariable(const TString *name, const TType& t, bool uT = false ) : TSymbol(name), type(t), userType(uT), unionArray(0), arrayInformationType(0) { }
 	virtual ~TVariable() { }
 	virtual bool isVariable() const { return true; }
 	TType& getType() { return type; }
 	const TType& getType() const { return type; }
 	bool isUserType() const { return userType; }
 	void setQualifier(TQualifier qualifier) { type.setQualifier(qualifier); }
 	void updateArrayInformationType(TType *t) { arrayInformationType = t; }
 	TType* getArrayInformationType() { return arrayInformationType; }

 	ConstantUnion* getConstPointer()
 	{
 		if (!unionArray)
 			unionArray = new ConstantUnion[type.getObjectSize()];

 		return unionArray;
 	}

 	ConstantUnion* getConstPointer() const { return unionArray; }
 	bool isConstant() const { return unionArray != nullptr; }

 	void shareConstPointer( ConstantUnion *constArray)
 	{
 		if (unionArray == constArray)
 			return;

 		delete[] unionArray;
 		unionArray = constArray;
 	}

 protected:
 	TType type;
 	bool userType;
 	// we are assuming that Pool Allocator will free the memory allocated to unionArray
 	// when this object is destroyed
 	ConstantUnion *unionArray;
 	TType *arrayInformationType;  // this is used for updating maxArraySize in all the references to a given symbol
 };

 //
 // The function sub-class of symbols and the parser will need to
 // share this definition of a function parameter.
 //
 struct TParameter
 {
 	TString *name;
 	TType *type;
 };

 //
 // The function sub-class of a symbol.
 //
 class TFunction : public TSymbol
 {
 public:
 	TFunction(TOperator o) :
 		TSymbol(0),
 		returnType(TType(EbtVoid, EbpUndefined)),
 		op(o),
 		defined(false),
 		prototypeDeclaration(false) { }
 	TFunction(const TString *name, const TType& retType, TOperator tOp = EOpNull, const char *ext = "") :
 		TSymbol(name),
 		returnType(retType),
 		mangledName(TFunction::mangleName(*name)),
 		op(tOp),
 		extension(ext),
 		defined(false),
 		prototypeDeclaration(false) { }
 	virtual ~TFunction();
 	virtual bool isFunction() const { return true; }

 	static TString mangleName(const TString& name) { return name + '('; }
 	static TString unmangleName(const TString& mangledName)
 	{
 		return TString(mangledName.c_str(), mangledName.find_first_of('('));
 	}

 	void addParameter(TParameter& p)
 	{
 		parameters.push_back(p);
 		mangledName = mangledName + p.type->getMangledName();
 	}

 	const TString& getMangledName() const { return mangledName; }
 	const TType& getReturnType() const { return returnType; }

 	TOperator getBuiltInOp() const { return op; }
 	const TString& getExtension() const { return extension; }

 	void setDefined() { defined = true; }
 	bool isDefined() { return defined; }
 	void setHasPrototypeDeclaration() { prototypeDeclaration = true; }
 	bool hasPrototypeDeclaration() const { return prototypeDeclaration; }

 	size_t getParamCount() const { return parameters.size(); }
 	const TParameter& getParam(int i) const { return parameters[i]; }

 protected:
 	typedef TVector<TParameter> TParamList;
 	TParamList parameters;
 	TType returnType;
 	TString mangledName;
 	TOperator op;
 	TString extension;
 	bool defined;
 	bool prototypeDeclaration;
 };


 class TSymbolTableLevel
 {
 public:
 	typedef TMap<TString, TSymbol*> tLevel;
 	typedef tLevel::const_iterator const_iterator;
 	typedef const tLevel::value_type tLevelPair;
 	typedef std::pair<tLevel::iterator, bool> tInsertResult;

 	POOL_ALLOCATOR_NEW_DELETE()
 	TSymbolTableLevel() { }
 	~TSymbolTableLevel();

 	bool insert(TSymbol *symbol);

 	// Insert a function using its unmangled name as the key.
 	bool insertUnmangled(TFunction *function);

 	TSymbol *find(const TString &name) const;

 	static int nextUniqueId()
 	{
 		return ++uniqueId;
 	}

 protected:
 	tLevel level;
 	static int uniqueId;     // for unique identification in code generation
 };

 enum ESymbolLevel
 {
 	COMMON_BUILTINS,
 	ESSL1_BUILTINS,
 	ESSL3_BUILTINS,
 	LAST_BUILTIN_LEVEL = ESSL3_BUILTINS,
 	GLOBAL_LEVEL
 };

 inline bool IsGenType(const TType *type)
 {
 	if(type)
 	{
 		TBasicType basicType = type->getBasicType();
 		return basicType == EbtGenType || basicType == EbtGenIType || basicType == EbtGenUType || basicType == EbtGenBType;
 	}

 	return false;
 }

 inline bool IsVecType(const TType *type)
 {
 	if(type)
 	{
 		TBasicType basicType = type->getBasicType();
 		return basicType == EbtVec || basicType == EbtIVec || basicType == EbtUVec || basicType == EbtBVec;
 	}

 	return false;
 }

 inline TType *GenType(TType *type, int size)
 {
 	ASSERT(size >= 1 && size <= 4);

 	if(!type)
 	{
 		return nullptr;
 	}

 	ASSERT(!IsVecType(type));

 	switch(type->getBasicType())
 	{
 	case EbtGenType:  return new TType(EbtFloat, size);
 	case EbtGenIType: return new TType(EbtInt, size);
 	case EbtGenUType: return new TType(EbtUInt, size);
 	case EbtGenBType: return new TType(EbtBool, size);
 	default: return type;
 	}
 }

 inline TType *VecType(TType *type, int size)
 {
 	ASSERT(size >= 2 && size <= 4);

 	if(!type)
 	{
 		return nullptr;
 	}

 	ASSERT(!IsGenType(type));

 	switch(type->getBasicType())
 	{
 	case EbtVec:  return new TType(EbtFloat, size);
 	case EbtIVec: return new TType(EbtInt, size);
 	case EbtUVec: return new TType(EbtUInt, size);
 	case EbtBVec: return new TType(EbtBool, size);
 	default: return type;
 	}
 }

 class TSymbolTable
 {
 public:
 	TSymbolTable()
 		: mGlobalInvariant(false)
 	{
 		//
 		// The symbol table cannot be used until push() is called, but
 		// the lack of an initial call to push() can be used to detect
 		// that the symbol table has not been preloaded with built-ins.
 		//
 	}

 	~TSymbolTable()
 	{
 		while(currentLevel() > LAST_BUILTIN_LEVEL)
 		{
 			pop();
 		}
 	}

 	bool isEmpty() { return table.empty(); }
 	bool atBuiltInLevel() { return currentLevel() <= LAST_BUILTIN_LEVEL; }
 	bool atGlobalLevel() { return currentLevel() <= GLOBAL_LEVEL; }
 	void push()
 	{
 		table.push_back(new TSymbolTableLevel);
 		precisionStack.push_back( PrecisionStackLevel() );
 	}

 	void pop()
 	{
 		delete table[currentLevel()];
 		table.pop_back();
 		precisionStack.pop_back();
 	}

 	bool declare(TSymbol *symbol)
 	{
 		return insert(currentLevel(), symbol);
 	}

 	bool insert(ESymbolLevel level, TSymbol *symbol)
 	{
 		return table[level]->insert(symbol);
 	}

 	bool insertConstInt(ESymbolLevel level, const char *name, int value)
 	{
 		TVariable *constant = new TVariable(NewPoolTString(name), TType(EbtInt, EbpUndefined, EvqConstExpr, 1));
 		constant->getConstPointer()->setIConst(value);
 		return insert(level, constant);
 	}

 	void insertBuiltIn(ESymbolLevel level, TOperator op, const char *ext, TType *rvalue, const char *name, TType *ptype1, TType *ptype2 = 0, TType *ptype3 = 0, TType *ptype4 = 0, TType *ptype5 = 0)
 	{
 		if(ptype1->getBasicType() == EbtGSampler2D)
 		{
 			insertUnmangledBuiltIn(name);
 			bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
 			insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSampler2D), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISampler2D), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSampler2D), ptype2, ptype3, ptype4, ptype5);
 		}
 		else if(ptype1->getBasicType() == EbtGSampler3D)
 		{
 			insertUnmangledBuiltIn(name);
 			bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
 			insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSampler3D), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISampler3D), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSampler3D), ptype2, ptype3, ptype4, ptype5);
 		}
 		else if(ptype1->getBasicType() == EbtGSamplerCube)
 		{
 			insertUnmangledBuiltIn(name);
 			bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
 			insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSamplerCube), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISamplerCube), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSamplerCube), ptype2, ptype3, ptype4, ptype5);
 		}
 		else if(ptype1->getBasicType() == EbtGSampler2DArray)
 		{
 			insertUnmangledBuiltIn(name);
 			bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
 			insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSampler2DArray), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISampler2DArray), ptype2, ptype3, ptype4, ptype5);
 			insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSampler2DArray), ptype2, ptype3, ptype4, ptype5);
 		}
 		else if(IsGenType(rvalue) || IsGenType(ptype1) || IsGenType(ptype2) || IsGenType(ptype3))
 		{
 			ASSERT(!ptype4);
 			insertUnmangledBuiltIn(name);
 			insertBuiltIn(level, op, ext, GenType(rvalue, 1), name, GenType(ptype1, 1), GenType(ptype2, 1), GenType(ptype3, 1));
 			insertBuiltIn(level, op, ext, GenType(rvalue, 2), name, GenType(ptype1, 2), GenType(ptype2, 2), GenType(ptype3, 2));
 			insertBuiltIn(level, op, ext, GenType(rvalue, 3), name, GenType(ptype1, 3), GenType(ptype2, 3), GenType(ptype3, 3));
 			insertBuiltIn(level, op, ext, GenType(rvalue, 4), name, GenType(ptype1, 4), GenType(ptype2, 4), GenType(ptype3, 4));
 		}
 		else if(IsVecType(rvalue) || IsVecType(ptype1) || IsVecType(ptype2) || IsVecType(ptype3))
 		{
 			ASSERT(!ptype4);
 			insertUnmangledBuiltIn(name);
 			insertBuiltIn(level, op, ext, VecType(rvalue, 2), name, VecType(ptype1, 2), VecType(ptype2, 2), VecType(ptype3, 2));
 			insertBuiltIn(level, op, ext, VecType(rvalue, 3), name, VecType(ptype1, 3), VecType(ptype2, 3), VecType(ptype3, 3));
 			insertBuiltIn(level, op, ext, VecType(rvalue, 4), name, VecType(ptype1, 4), VecType(ptype2, 4), VecType(ptype3, 4));
 		}
 		else
 		{
 			TFunction *function = new TFunction(NewPoolTString(name), *rvalue, op, ext);

 			TParameter param1 = {0, ptype1};
 			function->addParameter(param1);

 			if(ptype2)
 			{
 				TParameter param2 = {0, ptype2};
 				function->addParameter(param2);
 			}

 			if(ptype3)
 			{
 				TParameter param3 = {0, ptype3};
 				function->addParameter(param3);
 			}

 			if(ptype4)
 			{
 				TParameter param4 = {0, ptype4};
 				function->addParameter(param4);
 			}

 			if(ptype5)
 			{
 				TParameter param5 = {0, ptype5};
 				function->addParameter(param5);
 			}

 			ASSERT(hasUnmangledBuiltIn(name));
 			insert(level, function);
 		}
 	}

 	void insertBuiltIn(ESymbolLevel level, TOperator op, TType *rvalue, const char *name, TType *ptype1, TType *ptype2 = 0, TType *ptype3 = 0, TType *ptype4 = 0, TType *ptype5 = 0)
 	{
 		insertUnmangledBuiltIn(name);
 		insertBuiltIn(level, op, "", rvalue, name, ptype1, ptype2, ptype3, ptype4, ptype5);
 	}

 	void insertBuiltIn(ESymbolLevel level, TType *rvalue, const char *name, TType *ptype1, TType *ptype2 = 0, TType *ptype3 = 0, TType *ptype4 = 0, TType *ptype5 = 0)
 	{
 		insertUnmangledBuiltIn(name);
 		insertBuiltIn(level, EOpNull, rvalue, name, ptype1, ptype2, ptype3, ptype4, ptype5);
 	}

 	TSymbol *find(const TString &name, int shaderVersion, bool *builtIn = nullptr, bool *sameScope = nullptr) const;
 	TSymbol *findBuiltIn(const TString &name, int shaderVersion) const;

 	TSymbolTableLevel *getOuterLevel() const
 	{
 		assert(currentLevel() >= 1);
 		return table[currentLevel() - 1];
 	}

 	bool setDefaultPrecision(const TPublicType &type, TPrecision prec)
 	{
 		if (IsSampler(type.type))
 			return true;  // Skip sampler types for the time being
 		if (type.type != EbtFloat && type.type != EbtInt)
 			return false; // Only set default precision for int/float
 		if (type.primarySize > 1 || type.secondarySize > 1 || type.array)
 			return false; // Not allowed to set for aggregate types
 		int indexOfLastElement = static_cast<int>(precisionStack.size()) - 1;
 		precisionStack[indexOfLastElement][type.type] = prec; // Uses map operator [], overwrites the current value
 		return true;
 	}

 	// Searches down the precisionStack for a precision qualifier for the specified TBasicType
 	TPrecision getDefaultPrecision( TBasicType type)
 	{
 		// unsigned integers use the same precision as signed
 		if (type == EbtUInt) type = EbtInt;

 		if( type != EbtFloat && type != EbtInt ) return EbpUndefined;
 		int level = static_cast<int>(precisionStack.size()) - 1;
 		assert( level >= 0); // Just to be safe. Should not happen.
 		PrecisionStackLevel::iterator it;
 		TPrecision prec = EbpUndefined; // If we dont find anything we return this. Should we error check this?
 		while( level >= 0 ){
 			it = precisionStack[level].find( type );
 			if( it != precisionStack[level].end() ){
 				prec = (*it).second;
 				break;
 			}
 			level--;
 		}
 		return prec;
 	}

 	// This records invariant varyings declared through
 	// "invariant varying_name;".
 	void addInvariantVarying(const std::string &originalName)
 	{
 		mInvariantVaryings.insert(originalName);
 	}
 	// If this returns false, the varying could still be invariant
 	// if it is set as invariant during the varying variable
 	// declaration - this piece of information is stored in the
 	// variable's type, not here.
 	bool isVaryingInvariant(const std::string &originalName) const
 	{
 		return (mGlobalInvariant ||
 			mInvariantVaryings.count(originalName) > 0);
 	}

 	void setGlobalInvariant() { mGlobalInvariant = true; }
 	bool getGlobalInvariant() const { return mGlobalInvariant; }

 	bool hasUnmangledBuiltIn(const char *name) { return mUnmangledBuiltinNames.count(std::string(name)) > 0; }

 private:
 	// Used to insert unmangled functions to check redeclaration of built-ins in ESSL 3.00.
 	void insertUnmangledBuiltIn(const char *name) { mUnmangledBuiltinNames.insert(std::string(name)); }

 protected:
 	ESymbolLevel currentLevel() const { return static_cast<ESymbolLevel>(table.size() - 1); }

 	std::vector<TSymbolTableLevel*> table;
 	typedef std::map< TBasicType, TPrecision > PrecisionStackLevel;
 	std::vector< PrecisionStackLevel > precisionStack;

 	std::set<std::string> mUnmangledBuiltinNames;

 	std::set<std::string> mInvariantVaryings;
 	bool mGlobalInvariant;
 };

 #endif // _SYMBOL_TABLE_INCLUDED_
	// 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.

	#ifndef _SYMBOL_TABLE_INCLUDED_
	#define _SYMBOL_TABLE_INCLUDED_

	//
	// Symbol table for parsing. Has these design characteristics:
	//
	// * Same symbol table can be used to compile many shaders, to preserve
	// effort of creating and loading with the large numbers of built-in
	// symbols.
	//
	// * Name mangling will be used to give each function a unique name
	// so that symbol table lookups are never ambiguous. This allows
	// a simpler symbol table structure.
	//
	// * Pushing and popping of scope, so symbol table will really be a stack
	// of symbol tables. Searched from the top, with new inserts going into
	// the top.
	//
	// * Constants: Compile time constant symbols will keep their values
	// in the symbol table. The parser can substitute constants at parse
	// time, including doing constant folding and constant propagation.
	//
	// * No temporaries: Temporaries made from operations (+, --, .xy, etc.)
	// are tracked in the intermediate representation, not the symbol table.
	//

	#if defined(__ANDROID__) && !defined(ANDROID_HOST_BUILD) && !defined(ANDROID_NDK_BUILD)
	#include "../../Common/DebugAndroid.hpp"
	#else
	#include <assert.h>
	#endif

	#include "InfoSink.h"
	#include "intermediate.h"
	#include <set>

	//
	// Symbol base class. (Can build functions or variables out of these...)
	//
	class TSymbol
	{
	public:
	POOL_ALLOCATOR_NEW_DELETE()
	TSymbol(const TString *n) : name(n) { }
	virtual ~TSymbol() { /* don't delete name, it's from the pool */ }

	const TString& getName() const { return *name; }
	virtual const TString& getMangledName() const { return getName(); }
	virtual bool isFunction() const { return false; }
	virtual bool isVariable() const { return false; }
	void setUniqueId(int id) { uniqueId = id; }
	int getUniqueId() const { return uniqueId; }
	TSymbol(const TSymbol&);

	protected:
	const TString *name;
	unsigned int uniqueId; // For real comparing during code generation
	};

	//
	// Variable class, meaning a symbol that's not a function.
	//
	// There could be a separate class heirarchy for Constant variables;
	// Only one of int, bool, or float, (or none) is correct for
	// any particular use, but it's easy to do this way, and doesn't
	// seem worth having separate classes, and "getConst" can't simply return
	// different values for different types polymorphically, so this is
	// just simple and pragmatic.
	//
	class TVariable : public TSymbol
	{
	public:
	TVariable(const TString *name, const TType& t, bool uT = false ) : TSymbol(name), type(t), userType(uT), unionArray(0), arrayInformationType(0) { }
	virtual ~TVariable() { }
	virtual bool isVariable() const { return true; }
	TType& getType() { return type; }
	const TType& getType() const { return type; }
	bool isUserType() const { return userType; }
	void setQualifier(TQualifier qualifier) { type.setQualifier(qualifier); }
	void updateArrayInformationType(TType *t) { arrayInformationType = t; }
	TType* getArrayInformationType() { return arrayInformationType; }

	ConstantUnion* getConstPointer()
	{
	if (!unionArray)
	unionArray = new ConstantUnion[type.getObjectSize()];

	return unionArray;
	}

	ConstantUnion* getConstPointer() const { return unionArray; }
	bool isConstant() const { return unionArray != nullptr; }

	void shareConstPointer( ConstantUnion *constArray)
	{
	if (unionArray == constArray)
	return;

	delete[] unionArray;
	unionArray = constArray;
	}

	protected:
	TType type;
	bool userType;
	// we are assuming that Pool Allocator will free the memory allocated to unionArray
	// when this object is destroyed
	ConstantUnion *unionArray;
	TType *arrayInformationType; // this is used for updating maxArraySize in all the references to a given symbol
	};

	//
	// The function sub-class of symbols and the parser will need to
	// share this definition of a function parameter.
	//
	struct TParameter
	{
	TString *name;
	TType *type;
	};

	//
	// The function sub-class of a symbol.
	//
	class TFunction : public TSymbol
	{
	public:
	TFunction(TOperator o) :
	TSymbol(0),
	returnType(TType(EbtVoid, EbpUndefined)),
	op(o),
	defined(false),
	prototypeDeclaration(false) { }
	TFunction(const TString name, const TType& retType, TOperator tOp = EOpNull, const char ext = "") :
	TSymbol(name),
	returnType(retType),
	mangledName(TFunction::mangleName(*name)),
	op(tOp),
	extension(ext),
	defined(false),
	prototypeDeclaration(false) { }
	virtual ~TFunction();
	virtual bool isFunction() const { return true; }

	static TString mangleName(const TString& name) { return name + '('; }
	static TString unmangleName(const TString& mangledName)
	{
	return TString(mangledName.c_str(), mangledName.find_first_of('('));
	}

	void addParameter(TParameter& p)
	{
	parameters.push_back(p);
	mangledName = mangledName + p.type->getMangledName();
	}

	const TString& getMangledName() const { return mangledName; }
	const TType& getReturnType() const { return returnType; }

	TOperator getBuiltInOp() const { return op; }
	const TString& getExtension() const { return extension; }

	void setDefined() { defined = true; }
	bool isDefined() { return defined; }
	void setHasPrototypeDeclaration() { prototypeDeclaration = true; }
	bool hasPrototypeDeclaration() const { return prototypeDeclaration; }

	size_t getParamCount() const { return parameters.size(); }
	const TParameter& getParam(int i) const { return parameters[i]; }

	protected:
	typedef TVector<TParameter> TParamList;
	TParamList parameters;
	TType returnType;
	TString mangledName;
	TOperator op;
	TString extension;
	bool defined;
	bool prototypeDeclaration;
	};


	class TSymbolTableLevel
	{
	public:
	typedef TMap<TString, TSymbol*> tLevel;
	typedef tLevel::const_iterator const_iterator;
	typedef const tLevel::value_type tLevelPair;
	typedef std::pair<tLevel::iterator, bool> tInsertResult;

	POOL_ALLOCATOR_NEW_DELETE()
	TSymbolTableLevel() { }
	~TSymbolTableLevel();

	bool insert(TSymbol *symbol);

	// Insert a function using its unmangled name as the key.
	bool insertUnmangled(TFunction *function);

	TSymbol *find(const TString &name) const;

	static int nextUniqueId()
	{
	return ++uniqueId;
	}

	protected:
	tLevel level;
	static int uniqueId; // for unique identification in code generation
	};

	enum ESymbolLevel
	{
	COMMON_BUILTINS,
	ESSL1_BUILTINS,
	ESSL3_BUILTINS,
	LAST_BUILTIN_LEVEL = ESSL3_BUILTINS,
	GLOBAL_LEVEL
	};

	inline bool IsGenType(const TType *type)
	{
	if(type)
	{
	TBasicType basicType = type->getBasicType();
	return basicType == EbtGenType \|\| basicType == EbtGenIType \|\| basicType == EbtGenUType \|\| basicType == EbtGenBType;
	}

	return false;
	}

	inline bool IsVecType(const TType *type)
	{
	if(type)
	{
	TBasicType basicType = type->getBasicType();
	return basicType == EbtVec \|\| basicType == EbtIVec \|\| basicType == EbtUVec \|\| basicType == EbtBVec;
	}

	return false;
	}

	inline TType GenType(TType type, int size)
	{
	ASSERT(size >= 1 && size <= 4);

	if(!type)
	{
	return nullptr;
	}

	ASSERT(!IsVecType(type));

	switch(type->getBasicType())
	{
	case EbtGenType: return new TType(EbtFloat, size);
	case EbtGenIType: return new TType(EbtInt, size);
	case EbtGenUType: return new TType(EbtUInt, size);
	case EbtGenBType: return new TType(EbtBool, size);
	default: return type;
	}
	}

	inline TType VecType(TType type, int size)
	{
	ASSERT(size >= 2 && size <= 4);

	if(!type)
	{
	return nullptr;
	}

	ASSERT(!IsGenType(type));

	switch(type->getBasicType())
	{
	case EbtVec: return new TType(EbtFloat, size);
	case EbtIVec: return new TType(EbtInt, size);
	case EbtUVec: return new TType(EbtUInt, size);
	case EbtBVec: return new TType(EbtBool, size);
	default: return type;
	}
	}

	class TSymbolTable
	{
	public:
	TSymbolTable()
	: mGlobalInvariant(false)
	{
	//
	// The symbol table cannot be used until push() is called, but
	// the lack of an initial call to push() can be used to detect
	// that the symbol table has not been preloaded with built-ins.
	//
	}

	~TSymbolTable()
	{
	while(currentLevel() > LAST_BUILTIN_LEVEL)
	{
	pop();
	}
	}

	bool isEmpty() { return table.empty(); }
	bool atBuiltInLevel() { return currentLevel() <= LAST_BUILTIN_LEVEL; }
	bool atGlobalLevel() { return currentLevel() <= GLOBAL_LEVEL; }
	void push()
	{
	table.push_back(new TSymbolTableLevel);
	precisionStack.push_back( PrecisionStackLevel() );
	}

	void pop()
	{
	delete table[currentLevel()];
	table.pop_back();
	precisionStack.pop_back();
	}

	bool declare(TSymbol *symbol)
	{
	return insert(currentLevel(), symbol);
	}

	bool insert(ESymbolLevel level, TSymbol *symbol)
	{
	return table[level]->insert(symbol);
	}

	bool insertConstInt(ESymbolLevel level, const char *name, int value)
	{
	TVariable *constant = new TVariable(NewPoolTString(name), TType(EbtInt, EbpUndefined, EvqConstExpr, 1));
	constant->getConstPointer()->setIConst(value);
	return insert(level, constant);
	}

	void insertBuiltIn(ESymbolLevel level, TOperator op, const char ext, TType rvalue, const char name, TType ptype1, TType ptype2 = 0, TType ptype3 = 0, TType ptype4 = 0, TType ptype5 = 0)
	{
	if(ptype1->getBasicType() == EbtGSampler2D)
	{
	insertUnmangledBuiltIn(name);
	bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
	insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSampler2D), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISampler2D), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSampler2D), ptype2, ptype3, ptype4, ptype5);
	}
	else if(ptype1->getBasicType() == EbtGSampler3D)
	{
	insertUnmangledBuiltIn(name);
	bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
	insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSampler3D), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISampler3D), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSampler3D), ptype2, ptype3, ptype4, ptype5);
	}
	else if(ptype1->getBasicType() == EbtGSamplerCube)
	{
	insertUnmangledBuiltIn(name);
	bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
	insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSamplerCube), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISamplerCube), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSamplerCube), ptype2, ptype3, ptype4, ptype5);
	}
	else if(ptype1->getBasicType() == EbtGSampler2DArray)
	{
	insertUnmangledBuiltIn(name);
	bool gvec4 = (rvalue->getBasicType() == EbtGVec4);
	insertBuiltIn(level, gvec4 ? new TType(EbtFloat, 4) : rvalue, name, new TType(EbtSampler2DArray), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtInt, 4) : rvalue, name, new TType(EbtISampler2DArray), ptype2, ptype3, ptype4, ptype5);
	insertBuiltIn(level, gvec4 ? new TType(EbtUInt, 4) : rvalue, name, new TType(EbtUSampler2DArray), ptype2, ptype3, ptype4, ptype5);
	}
	else if(IsGenType(rvalue) \|\| IsGenType(ptype1) \|\| IsGenType(ptype2) \|\| IsGenType(ptype3))
	{
	ASSERT(!ptype4);
	insertUnmangledBuiltIn(name);
	insertBuiltIn(level, op, ext, GenType(rvalue, 1), name, GenType(ptype1, 1), GenType(ptype2, 1), GenType(ptype3, 1));
	insertBuiltIn(level, op, ext, GenType(rvalue, 2), name, GenType(ptype1, 2), GenType(ptype2, 2), GenType(ptype3, 2));
	insertBuiltIn(level, op, ext, GenType(rvalue, 3), name, GenType(ptype1, 3), GenType(ptype2, 3), GenType(ptype3, 3));
	insertBuiltIn(level, op, ext, GenType(rvalue, 4), name, GenType(ptype1, 4), GenType(ptype2, 4), GenType(ptype3, 4));
	}
	else if(IsVecType(rvalue) \|\| IsVecType(ptype1) \|\| IsVecType(ptype2) \|\| IsVecType(ptype3))
	{
	ASSERT(!ptype4);
	insertUnmangledBuiltIn(name);
	insertBuiltIn(level, op, ext, VecType(rvalue, 2), name, VecType(ptype1, 2), VecType(ptype2, 2), VecType(ptype3, 2));
	insertBuiltIn(level, op, ext, VecType(rvalue, 3), name, VecType(ptype1, 3), VecType(ptype2, 3), VecType(ptype3, 3));
	insertBuiltIn(level, op, ext, VecType(rvalue, 4), name, VecType(ptype1, 4), VecType(ptype2, 4), VecType(ptype3, 4));
	}
	else
	{
	TFunction function = new TFunction(NewPoolTString(name), rvalue, op, ext);

	TParameter param1 = {0, ptype1};
	function->addParameter(param1);

	if(ptype2)
	{
	TParameter param2 = {0, ptype2};
	function->addParameter(param2);
	}

	if(ptype3)
	{
	TParameter param3 = {0, ptype3};
	function->addParameter(param3);
	}

	if(ptype4)
	{
	TParameter param4 = {0, ptype4};
	function->addParameter(param4);
	}

	if(ptype5)
	{
	TParameter param5 = {0, ptype5};
	function->addParameter(param5);
	}

	ASSERT(hasUnmangledBuiltIn(name));
	insert(level, function);
	}
	}

	void insertBuiltIn(ESymbolLevel level, TOperator op, TType rvalue, const char name, TType ptype1, TType ptype2 = 0, TType ptype3 = 0, TType ptype4 = 0, TType *ptype5 = 0)
	{
	insertUnmangledBuiltIn(name);
	insertBuiltIn(level, op, "", rvalue, name, ptype1, ptype2, ptype3, ptype4, ptype5);
	}

	void insertBuiltIn(ESymbolLevel level, TType rvalue, const char name, TType ptype1, TType ptype2 = 0, TType ptype3 = 0, TType ptype4 = 0, TType *ptype5 = 0)
	{
	insertUnmangledBuiltIn(name);
	insertBuiltIn(level, EOpNull, rvalue, name, ptype1, ptype2, ptype3, ptype4, ptype5);
	}

	TSymbol find(const TString &name, int shaderVersion, bool builtIn = nullptr, bool *sameScope = nullptr) const;
	TSymbol *findBuiltIn(const TString &name, int shaderVersion) const;

	TSymbolTableLevel *getOuterLevel() const
	{
	assert(currentLevel() >= 1);
	return table[currentLevel() - 1];
	}

	bool setDefaultPrecision(const TPublicType &type, TPrecision prec)
	{
	if (IsSampler(type.type))
	return true; // Skip sampler types for the time being
	if (type.type != EbtFloat && type.type != EbtInt)
	return false; // Only set default precision for int/float
	if (type.primarySize > 1 \|\| type.secondarySize > 1 \|\| type.array)
	return false; // Not allowed to set for aggregate types
	int indexOfLastElement = static_cast<int>(precisionStack.size()) - 1;
	precisionStack[indexOfLastElement][type.type] = prec; // Uses map operator [], overwrites the current value
	return true;
	}

	// Searches down the precisionStack for a precision qualifier for the specified TBasicType
	TPrecision getDefaultPrecision( TBasicType type)
	{
	// unsigned integers use the same precision as signed
	if (type == EbtUInt) type = EbtInt;

	if( type != EbtFloat && type != EbtInt ) return EbpUndefined;
	int level = static_cast<int>(precisionStack.size()) - 1;
	assert( level >= 0); // Just to be safe. Should not happen.
	PrecisionStackLevel::iterator it;
	TPrecision prec = EbpUndefined; // If we dont find anything we return this. Should we error check this?
	while( level >= 0 ){
	it = precisionStack[level].find( type );
	if( it != precisionStack[level].end() ){
	prec = (*it).second;
	break;
	}
	level--;
	}
	return prec;
	}

	// This records invariant varyings declared through
	// "invariant varying_name;".
	void addInvariantVarying(const std::string &originalName)
	{
	mInvariantVaryings.insert(originalName);
	}
	// If this returns false, the varying could still be invariant
	// if it is set as invariant during the varying variable
	// declaration - this piece of information is stored in the
	// variable's type, not here.
	bool isVaryingInvariant(const std::string &originalName) const
	{
	return (mGlobalInvariant \|\|
	mInvariantVaryings.count(originalName) > 0);
	}

	void setGlobalInvariant() { mGlobalInvariant = true; }
	bool getGlobalInvariant() const { return mGlobalInvariant; }

	bool hasUnmangledBuiltIn(const char *name) { return mUnmangledBuiltinNames.count(std::string(name)) > 0; }

	private:
	// Used to insert unmangled functions to check redeclaration of built-ins in ESSL 3.00.
	void insertUnmangledBuiltIn(const char *name) { mUnmangledBuiltinNames.insert(std::string(name)); }

	protected:
	ESymbolLevel currentLevel() const { return static_cast<ESymbolLevel>(table.size() - 1); }

	std::vector<TSymbolTableLevel*> table;
	typedef std::map< TBasicType, TPrecision > PrecisionStackLevel;
	std::vector< PrecisionStackLevel > precisionStack;

	std::set<std::string> mUnmangledBuiltinNames;

	std::set<std::string> mInvariantVaryings;
	bool mGlobalInvariant;
	};

	#endif // _SYMBOL_TABLE_INCLUDED_