src/compiler/ShaderLang.cpp - platform/external/chromium_org/third_party/angle_dx11 - Git at Google

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

 //
 // Implement the top-level of interface to the compiler/linker,
 // as defined in ShaderLang.h
 //

 #include "GLSLANG/ShaderLang.h"

 #include "compiler/Initialize.h"
 #include "compiler/InitializeDll.h"
 #include "compiler/ParseHelper.h"
 #include "compiler/ShHandle.h"
 #include "compiler/SymbolTable.h"

 //
 // A symbol table for each language.  Each has a different
 // set of built-ins, and we want to preserve that from
 // compile to compile.
 //
 TSymbolTable SymbolTables[EShLangCount];


 TPoolAllocator* PerProcessGPA = 0;
 //
 // This is the platform independent interface between an OGL driver
 // and the shading language compiler/linker.
 //

 //
 // Driver must call this first, once, before doing any other
 // compiler/linker operations.
 //
 int ShInitialize()
 {
     TInfoSink infoSink;
     bool ret = true;

     if (!InitProcess())
         return 0;

     // This method should be called once per process. If its called by multiple threads, then
     // we need to have thread synchronization code around the initialization of per process
     // global pool allocator
     if (!PerProcessGPA) {
         TPoolAllocator *builtInPoolAllocator = new TPoolAllocator(true);
         builtInPoolAllocator->push();
         TPoolAllocator* gPoolAllocator = &GlobalPoolAllocator;
         SetGlobalPoolAllocatorPtr(builtInPoolAllocator);

         TSymbolTable symTables[EShLangCount];
         GenerateBuiltInSymbolTable(0, infoSink, symTables);

         PerProcessGPA = new TPoolAllocator(true);
         PerProcessGPA->push();
         SetGlobalPoolAllocatorPtr(PerProcessGPA);

         SymbolTables[EShLangVertex].copyTable(symTables[EShLangVertex]);
         SymbolTables[EShLangFragment].copyTable(symTables[EShLangFragment]);

         SetGlobalPoolAllocatorPtr(gPoolAllocator);

         symTables[EShLangVertex].pop();
         symTables[EShLangFragment].pop();

         builtInPoolAllocator->popAll();
         delete builtInPoolAllocator;

     }

     return ret ? 1 : 0;
 }

 //
 // Driver calls these to create and destroy compiler/linker
 // objects.
 //

 ShHandle ShConstructCompiler(const EShLanguage language, int debugOptions)
 {
     if (!InitThread())
         return 0;

     TShHandleBase* base = static_cast<TShHandleBase*>(ConstructCompiler(language, debugOptions));

     return reinterpret_cast<void*>(base);
 }

 ShHandle ShConstructLinker(const EShExecutable executable, int debugOptions)
 {
     if (!InitThread())
         return 0;

     TShHandleBase* base = static_cast<TShHandleBase*>(ConstructLinker(executable, debugOptions));

     return reinterpret_cast<void*>(base);
 }

 ShHandle ShConstructUniformMap()
 {
     if (!InitThread())
         return 0;

     TShHandleBase* base = static_cast<TShHandleBase*>(ConstructUniformMap());

     return reinterpret_cast<void*>(base);
 }

 void ShDestruct(ShHandle handle)
 {
     if (handle == 0)
         return;

     TShHandleBase* base = static_cast<TShHandleBase*>(handle);

     if (base->getAsCompiler())
         DeleteCompiler(base->getAsCompiler());
     else if (base->getAsLinker())
         DeleteLinker(base->getAsLinker());
     else if (base->getAsUniformMap())
         DeleteUniformMap(base->getAsUniformMap());
 }

 //
 // Cleanup symbol tables
 //
 int __fastcall ShFinalize()
 {
   if (PerProcessGPA) {
     PerProcessGPA->popAll();
     delete PerProcessGPA;
   }
   return 1;
 }

 bool GenerateBuiltInSymbolTable(const TBuiltInResource* resources, TInfoSink& infoSink, TSymbolTable* symbolTables, EShLanguage language)
 {
     TBuiltIns builtIns;

 	if (resources) {
 		builtIns.initialize(*resources);
 		InitializeSymbolTable(builtIns.getBuiltInStrings(), language, infoSink, resources, symbolTables);
 	} else {
 		builtIns.initialize();
 		InitializeSymbolTable(builtIns.getBuiltInStrings(), EShLangVertex, infoSink, resources, symbolTables);
 		InitializeSymbolTable(builtIns.getBuiltInStrings(), EShLangFragment, infoSink, resources, symbolTables);
 	}

     return true;
 }

 bool InitializeSymbolTable(TBuiltInStrings* BuiltInStrings, EShLanguage language, TInfoSink& infoSink, const TBuiltInResource* resources, TSymbolTable* symbolTables)
 {
     TIntermediate intermediate(infoSink);
     TSymbolTable* symbolTable;

 	if (resources)
 		symbolTable = symbolTables;
 	else
 		symbolTable = &symbolTables[language];

     TParseContext parseContext(*symbolTable, intermediate, language, infoSink);

     GlobalParseContext = &parseContext;

     setInitialState();

     assert(symbolTable->isEmpty() || symbolTable->atSharedBuiltInLevel());

     //
     // Parse the built-ins.  This should only happen once per
     // language symbol table.
     //
     // Push the symbol table to give it an initial scope.  This
     // push should not have a corresponding pop, so that built-ins
     // are preserved, and the test for an empty table fails.
     //

     symbolTable->push();

     //Initialize the Preprocessor
     int ret = InitPreprocessor();
     if (ret) {
         infoSink.info.message(EPrefixInternalError,  "Unable to intialize the Preprocessor");
         return false;
     }

     for (TBuiltInStrings::iterator i  = BuiltInStrings[parseContext.language].begin();
                                     i != BuiltInStrings[parseContext.language].end();
                                     ++i) {
         const char* builtInShaders[1];
         int builtInLengths[1];

         builtInShaders[0] = (*i).c_str();
         builtInLengths[0] = (int) (*i).size();

         if (PaParseStrings(const_cast<char**>(builtInShaders), builtInLengths, 1, parseContext) != 0) {
             infoSink.info.message(EPrefixInternalError, "Unable to parse built-ins");
             return false;
         }
     }

 	if (resources) {
 		IdentifyBuiltIns(parseContext.language, *symbolTable, *resources);
 	} else {
 		IdentifyBuiltIns(parseContext.language, *symbolTable);
 	}

     FinalizePreprocessor();

     return true;
 }

 //
 // Do an actual compile on the given strings.  The result is left
 // in the given compile object.
 //
 // Return:  The return value of ShCompile is really boolean, indicating
 // success or failure.
 //
 int ShCompile(
     const ShHandle handle,
     const char* const shaderStrings[],
     const int numStrings,
     const EShOptimizationLevel optLevel,
     const TBuiltInResource* resources,
     int debugOptions
     )
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return 0;

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
     TCompiler* compiler = base->getAsCompiler();
     if (compiler == 0)
         return 0;

     GlobalPoolAllocator.push();
     TInfoSink& infoSink = compiler->infoSink;
     infoSink.info.erase();
     infoSink.debug.erase();
     infoSink.obj.erase();

     if (numStrings == 0)
         return 1;

     TIntermediate intermediate(infoSink);
     TSymbolTable symbolTable(SymbolTables[compiler->getLanguage()]);

     GenerateBuiltInSymbolTable(resources, infoSink, &symbolTable, compiler->getLanguage());

     TParseContext parseContext(symbolTable, intermediate, compiler->getLanguage(), infoSink);
     parseContext.initializeExtensionBehavior();

     GlobalParseContext = &parseContext;

     setInitialState();

     InitPreprocessor();
     //
     // Parse the application's shaders.  All the following symbol table
     // work will be throw-away, so push a new allocation scope that can
     // be thrown away, then push a scope for the current shader's globals.
     //
     bool success = true;

     symbolTable.push();
     if (!symbolTable.atGlobalLevel())
         parseContext.infoSink.info.message(EPrefixInternalError, "Wrong symbol table level");

     int ret = PaParseStrings(const_cast<char**>(shaderStrings), 0, numStrings, parseContext);
     if (ret)
         success = false;

     if (success && parseContext.treeRoot) {
         if (optLevel == EShOptNoGeneration)
             parseContext.infoSink.info.message(EPrefixNone, "No errors.  No code generation or linking was requested.");
         else {
             success = intermediate.postProcess(parseContext.treeRoot, parseContext.language);

             if (success) {

                 if (debugOptions & EDebugOpIntermediate)
                     intermediate.outputTree(parseContext.treeRoot);

                 //
                 // Call the machine dependent compiler
                 //
                 if (!compiler->compile(parseContext.treeRoot))
                     success = false;
             }
         }
     } else if (!success) {
         parseContext.infoSink.info.prefix(EPrefixError);
         parseContext.infoSink.info << parseContext.numErrors << " compilation errors.  No code generated.\n\n";
         success = false;
         if (debugOptions & EDebugOpIntermediate)
             intermediate.outputTree(parseContext.treeRoot);
     } else if (!parseContext.treeRoot) {
         parseContext.error(1, "Unexpected end of file.", "", "");
         parseContext.infoSink.info << parseContext.numErrors << " compilation errors.  No code generated.\n\n";
         success = false;
         if (debugOptions & EDebugOpIntermediate)
             intermediate.outputTree(parseContext.treeRoot);
     }

     intermediate.remove(parseContext.treeRoot);

     //
     // Ensure symbol table is returned to the built-in level,
     // throwing away all but the built-ins.
     //
     while (! symbolTable.atSharedBuiltInLevel())
         symbolTable.pop();

     FinalizePreprocessor();
     //
     // Throw away all the temporary memory used by the compilation process.
     //
     GlobalPoolAllocator.pop();

     return success ? 1 : 0;
 }

 //
 // Do an actual link on the given compile objects.
 //
 // Return:  The return value of is really boolean, indicating
 // success or failure.
 //
 int ShLink(
     const ShHandle linkHandle,
     const ShHandle compHandles[],
     const int numHandles,
     ShHandle uniformMapHandle,
     short int** uniformsAccessed,
     int* numUniformsAccessed)

 {
     if (!InitThread())
         return 0;

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(linkHandle);
     TLinker* linker = static_cast<TLinker*>(base->getAsLinker());
     if (linker == 0)
         return 0;

     int returnValue;
     GlobalPoolAllocator.push();
     returnValue = ShLinkExt(linkHandle, compHandles, numHandles);
     GlobalPoolAllocator.pop();

     if (returnValue)
         return 1;

     return 0;
 }
 //
 // This link method will be eventually used once the ICD supports the new linker interface
 //
 int ShLinkExt(
     const ShHandle linkHandle,
     const ShHandle compHandles[],
     const int numHandles)
 {
     if (linkHandle == 0 || numHandles == 0)
         return 0;

     THandleList cObjects;

     {// support MSVC++6.0
         for (int i = 0; i < numHandles; ++i) {
             if (compHandles[i] == 0)
                 return 0;
             TShHandleBase* base = reinterpret_cast<TShHandleBase*>(compHandles[i]);
             if (base->getAsLinker()) {
                 cObjects.push_back(base->getAsLinker());
             }
             if (base->getAsCompiler())
                 cObjects.push_back(base->getAsCompiler());


             if (cObjects[i] == 0)
                 return 0;
         }
     }

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(linkHandle);
     TLinker* linker = static_cast<TLinker*>(base->getAsLinker());

     if (linker == 0)
         return 0;

     linker->infoSink.info.erase();
     linker->infoSink.obj.erase();

     {// support MSVC++6.0
         for (int i = 0; i < numHandles; ++i) {
             if (cObjects[i]->getAsCompiler()) {
                 if (! cObjects[i]->getAsCompiler()->linkable()) {
                     linker->infoSink.info.message(EPrefixError, "Not all shaders have valid object code.");
                     return 0;
                 }
             }
         }
     }

     bool ret = linker->link(cObjects);

     return ret ? 1 : 0;
 }

 //
 // ShSetEncrpytionMethod is a place-holder for specifying
 // how source code is encrypted.
 //
 void ShSetEncryptionMethod(ShHandle handle)
 {
     if (handle == 0)
         return;
 }

 //
 // Return any compiler/linker/uniformmap log of messages for the application.
 //
 const char* ShGetInfoLog(const ShHandle handle)
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return 0;

     TShHandleBase* base = static_cast<TShHandleBase*>(handle);
     TInfoSink* infoSink;

     if (base->getAsCompiler())
         infoSink = &(base->getAsCompiler()->getInfoSink());
     else if (base->getAsLinker())
         infoSink = &(base->getAsLinker()->getInfoSink());

     infoSink->info << infoSink->debug.c_str();
     return infoSink->info.c_str();
 }

 //
 // Return any unlinked object code.
 //
 const char* ShGetObjectCode(const ShHandle handle)
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return 0;

     TShHandleBase* base = static_cast<TShHandleBase*>(handle);
     TInfoSink* infoSink;

     if (base->getAsCompiler())
         infoSink = &(base->getAsCompiler()->getInfoSink());

     return infoSink->obj.c_str();
 }

 //
 // Return the resulting binary code from the link process.  Structure
 // is machine dependent.
 //
 const void* ShGetExecutable(const ShHandle handle)
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return 0;

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);

     TLinker* linker = static_cast<TLinker*>(base->getAsLinker());
     if (linker == 0)
         return 0;

     return linker->getObjectCode();
 }

 //
 // Let the linker know where the application said it's attributes are bound.
 // The linker does not use these values, they are remapped by the ICD or
 // hardware.  It just needs them to know what's aliased.
 //
 // Return:  The return value of is really boolean, indicating
 // success or failure.
 //
 int ShSetVirtualAttributeBindings(const ShHandle handle, const ShBindingTable* table)
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return 0;

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
     TLinker* linker = static_cast<TLinker*>(base->getAsLinker());

     if (linker == 0)
         return 0;

     linker->setAppAttributeBindings(table);

     return 1;
 }

 //
 // Let the linker know where the predefined attributes have to live.
 //
 int ShSetFixedAttributeBindings(const ShHandle handle, const ShBindingTable* table)
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return 0;

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
     TLinker* linker = static_cast<TLinker*>(base->getAsLinker());

     if (linker == 0)
         return 0;

     linker->setFixedAttributeBindings(table);
     return 1;
 }

 //
 // Some attribute locations are off-limits to the linker...
 //
 int ShExcludeAttributes(const ShHandle handle, int *attributes, int count)
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return 0;

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
     TLinker* linker = static_cast<TLinker*>(base->getAsLinker());
     if (linker == 0)
         return 0;

     linker->setExcludedAttributes(attributes, count);

     return 1;
 }

 //
 // Return the index for OpenGL to use for knowing where a uniform lives.
 //
 // Return:  The return value of is really boolean, indicating
 // success or failure.
 //
 int ShGetUniformLocation(const ShHandle handle, const char* name)
 {
     if (!InitThread())
         return 0;

     if (handle == 0)
         return -1;

     TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
     TUniformMap* uniformMap= base->getAsUniformMap();
     if (uniformMap == 0)
         return -1;

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

	//
	// Implement the top-level of interface to the compiler/linker,
	// as defined in ShaderLang.h
	//

	#include "GLSLANG/ShaderLang.h"

	#include "compiler/Initialize.h"
	#include "compiler/InitializeDll.h"
	#include "compiler/ParseHelper.h"
	#include "compiler/ShHandle.h"
	#include "compiler/SymbolTable.h"

	//
	// A symbol table for each language. Each has a different
	// set of built-ins, and we want to preserve that from
	// compile to compile.
	//
	TSymbolTable SymbolTables[EShLangCount];


	TPoolAllocator* PerProcessGPA = 0;
	//
	// This is the platform independent interface between an OGL driver
	// and the shading language compiler/linker.
	//

	//
	// Driver must call this first, once, before doing any other
	// compiler/linker operations.
	//
	int ShInitialize()
	{
	TInfoSink infoSink;
	bool ret = true;

	if (!InitProcess())
	return 0;

	// This method should be called once per process. If its called by multiple threads, then
	// we need to have thread synchronization code around the initialization of per process
	// global pool allocator
	if (!PerProcessGPA) {
	TPoolAllocator *builtInPoolAllocator = new TPoolAllocator(true);
	builtInPoolAllocator->push();
	TPoolAllocator* gPoolAllocator = &GlobalPoolAllocator;
	SetGlobalPoolAllocatorPtr(builtInPoolAllocator);

	TSymbolTable symTables[EShLangCount];
	GenerateBuiltInSymbolTable(0, infoSink, symTables);

	PerProcessGPA = new TPoolAllocator(true);
	PerProcessGPA->push();
	SetGlobalPoolAllocatorPtr(PerProcessGPA);

	SymbolTables[EShLangVertex].copyTable(symTables[EShLangVertex]);
	SymbolTables[EShLangFragment].copyTable(symTables[EShLangFragment]);

	SetGlobalPoolAllocatorPtr(gPoolAllocator);

	symTables[EShLangVertex].pop();
	symTables[EShLangFragment].pop();

	builtInPoolAllocator->popAll();
	delete builtInPoolAllocator;

	}

	return ret ? 1 : 0;
	}

	//
	// Driver calls these to create and destroy compiler/linker
	// objects.
	//

	ShHandle ShConstructCompiler(const EShLanguage language, int debugOptions)
	{
	if (!InitThread())
	return 0;

	TShHandleBase* base = static_cast<TShHandleBase*>(ConstructCompiler(language, debugOptions));

	return reinterpret_cast<void*>(base);
	}

	ShHandle ShConstructLinker(const EShExecutable executable, int debugOptions)
	{
	if (!InitThread())
	return 0;

	TShHandleBase* base = static_cast<TShHandleBase*>(ConstructLinker(executable, debugOptions));

	return reinterpret_cast<void*>(base);
	}

	ShHandle ShConstructUniformMap()
	{
	if (!InitThread())
	return 0;

	TShHandleBase* base = static_cast<TShHandleBase*>(ConstructUniformMap());

	return reinterpret_cast<void*>(base);
	}

	void ShDestruct(ShHandle handle)
	{
	if (handle == 0)
	return;

	TShHandleBase* base = static_cast<TShHandleBase*>(handle);

	if (base->getAsCompiler())
	DeleteCompiler(base->getAsCompiler());
	else if (base->getAsLinker())
	DeleteLinker(base->getAsLinker());
	else if (base->getAsUniformMap())
	DeleteUniformMap(base->getAsUniformMap());
	}

	//
	// Cleanup symbol tables
	//
	int __fastcall ShFinalize()
	{
	if (PerProcessGPA) {
	PerProcessGPA->popAll();
	delete PerProcessGPA;
	}
	return 1;
	}

	bool GenerateBuiltInSymbolTable(const TBuiltInResource* resources, TInfoSink& infoSink, TSymbolTable* symbolTables, EShLanguage language)
	{
	TBuiltIns builtIns;

	if (resources) {
	builtIns.initialize(*resources);
	InitializeSymbolTable(builtIns.getBuiltInStrings(), language, infoSink, resources, symbolTables);
	} else {
	builtIns.initialize();
	InitializeSymbolTable(builtIns.getBuiltInStrings(), EShLangVertex, infoSink, resources, symbolTables);
	InitializeSymbolTable(builtIns.getBuiltInStrings(), EShLangFragment, infoSink, resources, symbolTables);
	}

	return true;
	}

	bool InitializeSymbolTable(TBuiltInStrings* BuiltInStrings, EShLanguage language, TInfoSink& infoSink, const TBuiltInResource* resources, TSymbolTable* symbolTables)
	{
	TIntermediate intermediate(infoSink);
	TSymbolTable* symbolTable;

	if (resources)
	symbolTable = symbolTables;
	else
	symbolTable = &symbolTables[language];

	TParseContext parseContext(*symbolTable, intermediate, language, infoSink);

	GlobalParseContext = &parseContext;

	setInitialState();

	assert(symbolTable->isEmpty() \|\| symbolTable->atSharedBuiltInLevel());

	//
	// Parse the built-ins. This should only happen once per
	// language symbol table.
	//
	// Push the symbol table to give it an initial scope. This
	// push should not have a corresponding pop, so that built-ins
	// are preserved, and the test for an empty table fails.
	//

	symbolTable->push();

	//Initialize the Preprocessor
	int ret = InitPreprocessor();
	if (ret) {
	infoSink.info.message(EPrefixInternalError, "Unable to intialize the Preprocessor");
	return false;
	}

	for (TBuiltInStrings::iterator i = BuiltInStrings[parseContext.language].begin();
	i != BuiltInStrings[parseContext.language].end();
	++i) {
	const char* builtInShaders[1];
	int builtInLengths[1];

	builtInShaders[0] = (*i).c_str();
	builtInLengths[0] = (int) (*i).size();

	if (PaParseStrings(const_cast<char**>(builtInShaders), builtInLengths, 1, parseContext) != 0) {
	infoSink.info.message(EPrefixInternalError, "Unable to parse built-ins");
	return false;
	}
	}

	if (resources) {
	IdentifyBuiltIns(parseContext.language, symbolTable, resources);
	} else {
	IdentifyBuiltIns(parseContext.language, *symbolTable);
	}

	FinalizePreprocessor();

	return true;
	}

	//
	// Do an actual compile on the given strings. The result is left
	// in the given compile object.
	//
	// Return: The return value of ShCompile is really boolean, indicating
	// success or failure.
	//
	int ShCompile(
	const ShHandle handle,
	const char* const shaderStrings[],
	const int numStrings,
	const EShOptimizationLevel optLevel,
	const TBuiltInResource* resources,
	int debugOptions
	)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return 0;

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
	TCompiler* compiler = base->getAsCompiler();
	if (compiler == 0)
	return 0;

	GlobalPoolAllocator.push();
	TInfoSink& infoSink = compiler->infoSink;
	infoSink.info.erase();
	infoSink.debug.erase();
	infoSink.obj.erase();

	if (numStrings == 0)
	return 1;

	TIntermediate intermediate(infoSink);
	TSymbolTable symbolTable(SymbolTables[compiler->getLanguage()]);

	GenerateBuiltInSymbolTable(resources, infoSink, &symbolTable, compiler->getLanguage());

	TParseContext parseContext(symbolTable, intermediate, compiler->getLanguage(), infoSink);
	parseContext.initializeExtensionBehavior();

	GlobalParseContext = &parseContext;

	setInitialState();

	InitPreprocessor();
	//
	// Parse the application's shaders. All the following symbol table
	// work will be throw-away, so push a new allocation scope that can
	// be thrown away, then push a scope for the current shader's globals.
	//
	bool success = true;

	symbolTable.push();
	if (!symbolTable.atGlobalLevel())
	parseContext.infoSink.info.message(EPrefixInternalError, "Wrong symbol table level");

	int ret = PaParseStrings(const_cast<char**>(shaderStrings), 0, numStrings, parseContext);
	if (ret)
	success = false;

	if (success && parseContext.treeRoot) {
	if (optLevel == EShOptNoGeneration)
	parseContext.infoSink.info.message(EPrefixNone, "No errors. No code generation or linking was requested.");
	else {
	success = intermediate.postProcess(parseContext.treeRoot, parseContext.language);

	if (success) {

	if (debugOptions & EDebugOpIntermediate)
	intermediate.outputTree(parseContext.treeRoot);

	//
	// Call the machine dependent compiler
	//
	if (!compiler->compile(parseContext.treeRoot))
	success = false;
	}
	}
	} else if (!success) {
	parseContext.infoSink.info.prefix(EPrefixError);
	parseContext.infoSink.info << parseContext.numErrors << " compilation errors. No code generated.\n\n";
	success = false;
	if (debugOptions & EDebugOpIntermediate)
	intermediate.outputTree(parseContext.treeRoot);
	} else if (!parseContext.treeRoot) {
	parseContext.error(1, "Unexpected end of file.", "", "");
	parseContext.infoSink.info << parseContext.numErrors << " compilation errors. No code generated.\n\n";
	success = false;
	if (debugOptions & EDebugOpIntermediate)
	intermediate.outputTree(parseContext.treeRoot);
	}

	intermediate.remove(parseContext.treeRoot);

	//
	// Ensure symbol table is returned to the built-in level,
	// throwing away all but the built-ins.
	//
	while (! symbolTable.atSharedBuiltInLevel())
	symbolTable.pop();

	FinalizePreprocessor();
	//
	// Throw away all the temporary memory used by the compilation process.
	//
	GlobalPoolAllocator.pop();

	return success ? 1 : 0;
	}

	//
	// Do an actual link on the given compile objects.
	//
	// Return: The return value of is really boolean, indicating
	// success or failure.
	//
	int ShLink(
	const ShHandle linkHandle,
	const ShHandle compHandles[],
	const int numHandles,
	ShHandle uniformMapHandle,
	short int** uniformsAccessed,
	int* numUniformsAccessed)

	{
	if (!InitThread())
	return 0;

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(linkHandle);
	TLinker* linker = static_cast<TLinker*>(base->getAsLinker());
	if (linker == 0)
	return 0;

	int returnValue;
	GlobalPoolAllocator.push();
	returnValue = ShLinkExt(linkHandle, compHandles, numHandles);
	GlobalPoolAllocator.pop();

	if (returnValue)
	return 1;

	return 0;
	}
	//
	// This link method will be eventually used once the ICD supports the new linker interface
	//
	int ShLinkExt(
	const ShHandle linkHandle,
	const ShHandle compHandles[],
	const int numHandles)
	{
	if (linkHandle == 0 \|\| numHandles == 0)
	return 0;

	THandleList cObjects;

	{// support MSVC++6.0
	for (int i = 0; i < numHandles; ++i) {
	if (compHandles[i] == 0)
	return 0;
	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(compHandles[i]);
	if (base->getAsLinker()) {
	cObjects.push_back(base->getAsLinker());
	}
	if (base->getAsCompiler())
	cObjects.push_back(base->getAsCompiler());


	if (cObjects[i] == 0)
	return 0;
	}
	}

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(linkHandle);
	TLinker* linker = static_cast<TLinker*>(base->getAsLinker());

	if (linker == 0)
	return 0;

	linker->infoSink.info.erase();
	linker->infoSink.obj.erase();

	{// support MSVC++6.0
	for (int i = 0; i < numHandles; ++i) {
	if (cObjects[i]->getAsCompiler()) {
	if (! cObjects[i]->getAsCompiler()->linkable()) {
	linker->infoSink.info.message(EPrefixError, "Not all shaders have valid object code.");
	return 0;
	}
	}
	}
	}

	bool ret = linker->link(cObjects);

	return ret ? 1 : 0;
	}

	//
	// ShSetEncrpytionMethod is a place-holder for specifying
	// how source code is encrypted.
	//
	void ShSetEncryptionMethod(ShHandle handle)
	{
	if (handle == 0)
	return;
	}

	//
	// Return any compiler/linker/uniformmap log of messages for the application.
	//
	const char* ShGetInfoLog(const ShHandle handle)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return 0;

	TShHandleBase* base = static_cast<TShHandleBase*>(handle);
	TInfoSink* infoSink;

	if (base->getAsCompiler())
	infoSink = &(base->getAsCompiler()->getInfoSink());
	else if (base->getAsLinker())
	infoSink = &(base->getAsLinker()->getInfoSink());

	infoSink->info << infoSink->debug.c_str();
	return infoSink->info.c_str();
	}

	//
	// Return any unlinked object code.
	//
	const char* ShGetObjectCode(const ShHandle handle)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return 0;

	TShHandleBase* base = static_cast<TShHandleBase*>(handle);
	TInfoSink* infoSink;

	if (base->getAsCompiler())
	infoSink = &(base->getAsCompiler()->getInfoSink());

	return infoSink->obj.c_str();
	}

	//
	// Return the resulting binary code from the link process. Structure
	// is machine dependent.
	//
	const void* ShGetExecutable(const ShHandle handle)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return 0;

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);

	TLinker* linker = static_cast<TLinker*>(base->getAsLinker());
	if (linker == 0)
	return 0;

	return linker->getObjectCode();
	}

	//
	// Let the linker know where the application said it's attributes are bound.
	// The linker does not use these values, they are remapped by the ICD or
	// hardware. It just needs them to know what's aliased.
	//
	// Return: The return value of is really boolean, indicating
	// success or failure.
	//
	int ShSetVirtualAttributeBindings(const ShHandle handle, const ShBindingTable* table)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return 0;

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
	TLinker* linker = static_cast<TLinker*>(base->getAsLinker());

	if (linker == 0)
	return 0;

	linker->setAppAttributeBindings(table);

	return 1;
	}

	//
	// Let the linker know where the predefined attributes have to live.
	//
	int ShSetFixedAttributeBindings(const ShHandle handle, const ShBindingTable* table)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return 0;

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
	TLinker* linker = static_cast<TLinker*>(base->getAsLinker());

	if (linker == 0)
	return 0;

	linker->setFixedAttributeBindings(table);
	return 1;
	}

	//
	// Some attribute locations are off-limits to the linker...
	//
	int ShExcludeAttributes(const ShHandle handle, int *attributes, int count)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return 0;

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
	TLinker* linker = static_cast<TLinker*>(base->getAsLinker());
	if (linker == 0)
	return 0;

	linker->setExcludedAttributes(attributes, count);

	return 1;
	}

	//
	// Return the index for OpenGL to use for knowing where a uniform lives.
	//
	// Return: The return value of is really boolean, indicating
	// success or failure.
	//
	int ShGetUniformLocation(const ShHandle handle, const char* name)
	{
	if (!InitThread())
	return 0;

	if (handle == 0)
	return -1;

	TShHandleBase* base = reinterpret_cast<TShHandleBase*>(handle);
	TUniformMap* uniformMap= base->getAsUniformMap();
	if (uniformMap == 0)
	return -1;

	return uniformMap->getLocation(name);
	}