third_party/angle/src/compiler/preprocessor/MacroExpander.cpp - cobalt - Git at Google

 //
 // Copyright 2011 The ANGLE Project Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //

 #include "compiler/preprocessor/MacroExpander.h"

 #include <GLSLANG/ShaderLang.h>
 #include <algorithm>

 #include "common/debug.h"
 #include "compiler/preprocessor/DiagnosticsBase.h"
 #include "compiler/preprocessor/Token.h"

 namespace angle
 {

 namespace pp
 {

 namespace
 {

 const size_t kMaxContextTokens = 10000;

 class TokenLexer : public Lexer
 {
   public:
     typedef std::vector<Token> TokenVector;

     TokenLexer(TokenVector *tokens)
     {
         tokens->swap(mTokens);
         mIter = mTokens.begin();
     }

     void lex(Token *token) override
     {
         if (mIter == mTokens.end())
         {
             token->reset();
             token->type = Token::LAST;
         }
         else
         {
             *token = *mIter++;
         }
     }

   private:
     TokenVector mTokens;
     TokenVector::const_iterator mIter;
 };

 }  // anonymous namespace

 class MacroExpander::ScopedMacroReenabler final : angle::NonCopyable
 {
   public:
     ScopedMacroReenabler(MacroExpander *expander);
     ~ScopedMacroReenabler();

   private:
     MacroExpander *mExpander;
 };

 MacroExpander::ScopedMacroReenabler::ScopedMacroReenabler(MacroExpander *expander)
     : mExpander(expander)
 {
     mExpander->mDeferReenablingMacros = true;
 }

 MacroExpander::ScopedMacroReenabler::~ScopedMacroReenabler()
 {
     mExpander->mDeferReenablingMacros = false;
     for (const std::shared_ptr<Macro> &macro : mExpander->mMacrosToReenable)
     {
         // Copying the string here by using substr is a check for use-after-free. It detects
         // use-after-free more reliably than just toggling the disabled flag.
         ASSERT(macro->name.substr() != "");
         macro->disabled = false;
     }
     mExpander->mMacrosToReenable.clear();
 }

 MacroExpander::MacroExpander(Lexer *lexer,
                              MacroSet *macroSet,
                              Diagnostics *diagnostics,
                              const PreprocessorSettings &settings,
                              bool parseDefined)
     : mLexer(lexer),
       mMacroSet(macroSet),
       mDiagnostics(diagnostics),
       mParseDefined(parseDefined),
       mTotalTokensInContexts(0),
       mSettings(settings),
       mDeferReenablingMacros(false)
 {}

 MacroExpander::~MacroExpander()
 {
     ASSERT(mMacrosToReenable.empty());
     for (MacroContext *context : mContextStack)
     {
         delete context;
     }
 }

 void MacroExpander::lex(Token *token)
 {
     while (true)
     {
         getToken(token);

         if (token->type != Token::IDENTIFIER)
             break;

         // Defined operator is parsed here since it may be generated by macro expansion.
         // Defined operator produced by macro expansion has undefined behavior according to C++
         // spec, which the GLSL spec references (see C++14 draft spec section 16.1.4), but this
         // behavior is needed for passing dEQP tests, which enforce stricter compatibility between
         // implementations.
         if (mParseDefined && token->text == kDefined)
         {
             // Defined inside a macro is forbidden in WebGL.
             if (!mContextStack.empty() && sh::IsWebGLBasedSpec(mSettings.shaderSpec))
                 break;

             bool paren = false;
             getToken(token);
             if (token->type == '(')
             {
                 paren = true;
                 getToken(token);
             }
             if (token->type != Token::IDENTIFIER)
             {
                 mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location,
                                      token->text);
                 break;
             }
             auto iter              = mMacroSet->find(token->text);
             std::string expression = iter != mMacroSet->end() ? "1" : "0";

             if (paren)
             {
                 getToken(token);
                 if (token->type != ')')
                 {
                     mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location,
                                          token->text);
                     break;
                 }
             }

             // We have a valid defined operator.
             // Convert the current token into a CONST_INT token.
             token->type = Token::CONST_INT;
             token->text = expression;
             break;
         }

         if (token->expansionDisabled())
             break;

         MacroSet::const_iterator iter = mMacroSet->find(token->text);
         if (iter == mMacroSet->end())
             break;

         std::shared_ptr<Macro> macro = iter->second;
         if (macro->disabled)
         {
             // If a particular token is not expanded, it is never expanded.
             token->setExpansionDisabled(true);
             break;
         }

         // Bump the expansion count before peeking if the next token is a '('
         // otherwise there could be a #undef of the macro before the next token.
         macro->expansionCount++;
         if ((macro->type == Macro::kTypeFunc) && !isNextTokenLeftParen())
         {
             // If the token immediately after the macro name is not a '(',
             // this macro should not be expanded.
             macro->expansionCount--;
             break;
         }

         pushMacro(macro, *token);
     }
 }

 void MacroExpander::getToken(Token *token)
 {
     if (mReserveToken.get())
     {
         *token = *mReserveToken;
         mReserveToken.reset();
         return;
     }

     // First pop all empty macro contexts.
     while (!mContextStack.empty() && mContextStack.back()->empty())
     {
         popMacro();
     }

     if (!mContextStack.empty())
     {
         *token = mContextStack.back()->get();
     }
     else
     {
         ASSERT(mTotalTokensInContexts == 0);
         mLexer->lex(token);
     }
 }

 void MacroExpander::ungetToken(const Token &token)
 {
     if (!mContextStack.empty())
     {
         MacroContext *context = mContextStack.back();
         context->unget();
         ASSERT(context->replacements[context->index] == token);
     }
     else
     {
         ASSERT(!mReserveToken.get());
         mReserveToken.reset(new Token(token));
     }
 }

 bool MacroExpander::isNextTokenLeftParen()
 {
     Token token;
     getToken(&token);

     bool lparen = token.type == '(';
     ungetToken(token);

     return lparen;
 }

 bool MacroExpander::pushMacro(std::shared_ptr<Macro> macro, const Token &identifier)
 {
     ASSERT(!macro->disabled);
     ASSERT(!identifier.expansionDisabled());
     ASSERT(identifier.type == Token::IDENTIFIER);
     ASSERT(identifier.text == macro->name);

     std::vector<Token> replacements;
     if (!expandMacro(*macro, identifier, &replacements))
         return false;

     // Macro is disabled for expansion until it is popped off the stack.
     macro->disabled = true;

     MacroContext *context = new MacroContext;
     context->macro        = macro;
     context->replacements.swap(replacements);
     mContextStack.push_back(context);
     mTotalTokensInContexts += context->replacements.size();
     return true;
 }

 void MacroExpander::popMacro()
 {
     ASSERT(!mContextStack.empty());

     MacroContext *context = mContextStack.back();
     mContextStack.pop_back();

     ASSERT(context->empty());
     ASSERT(context->macro->disabled);
     ASSERT(context->macro->expansionCount > 0);
     if (mDeferReenablingMacros)
     {
         mMacrosToReenable.push_back(context->macro);
     }
     else
     {
         context->macro->disabled = false;
     }
     context->macro->expansionCount--;
     mTotalTokensInContexts -= context->replacements.size();
     delete context;
 }

 bool MacroExpander::expandMacro(const Macro &macro,
                                 const Token &identifier,
                                 std::vector<Token> *replacements)
 {
     replacements->clear();

     // In the case of an object-like macro, the replacement list gets its location
     // from the identifier, but in the case of a function-like macro, the replacement
     // list gets its location from the closing parenthesis of the macro invocation.
     // This is tested by dEQP-GLES3.functional.shaders.preprocessor.predefined_macros.*
     SourceLocation replacementLocation = identifier.location;
     if (macro.type == Macro::kTypeObj)
     {
         replacements->assign(macro.replacements.begin(), macro.replacements.end());

         if (macro.predefined)
         {
             const char kLine[] = "__LINE__";
             const char kFile[] = "__FILE__";

             ASSERT(replacements->size() == 1);
             Token &repl = replacements->front();
             if (macro.name == kLine)
             {
                 repl.text = ToString(identifier.location.line);
             }
             else if (macro.name == kFile)
             {
                 repl.text = ToString(identifier.location.file);
             }
         }
     }
     else
     {
         ASSERT(macro.type == Macro::kTypeFunc);
         std::vector<MacroArg> args;
         args.reserve(macro.parameters.size());
         if (!collectMacroArgs(macro, identifier, &args, &replacementLocation))
             return false;

         replaceMacroParams(macro, args, replacements);
     }

     for (std::size_t i = 0; i < replacements->size(); ++i)
     {
         Token &repl = replacements->at(i);
         if (i == 0)
         {
             // The first token in the replacement list inherits the padding
             // properties of the identifier token.
             repl.setAtStartOfLine(identifier.atStartOfLine());
             repl.setHasLeadingSpace(identifier.hasLeadingSpace());
         }
         repl.location = replacementLocation;
     }
     return true;
 }

 bool MacroExpander::collectMacroArgs(const Macro &macro,
                                      const Token &identifier,
                                      std::vector<MacroArg> *args,
                                      SourceLocation *closingParenthesisLocation)
 {
     Token token;
     getToken(&token);
     ASSERT(token.type == '(');

     args->push_back(MacroArg());

     // Defer reenabling macros until args collection is finished to avoid the possibility of
     // infinite recursion. Otherwise infinite recursion might happen when expanding the args after
     // macros have been popped from the context stack when parsing the args.
     ScopedMacroReenabler deferReenablingMacros(this);

     int openParens = 1;
     while (openParens != 0)
     {
         getToken(&token);

         if (token.type == Token::LAST)
         {
             mDiagnostics->report(Diagnostics::PP_MACRO_UNTERMINATED_INVOCATION, identifier.location,
                                  identifier.text);
             // Do not lose EOF token.
             ungetToken(token);
             return false;
         }

         bool isArg = false;  // True if token is part of the current argument.
         switch (token.type)
         {
             case '(':
                 ++openParens;
                 isArg = true;
                 break;
             case ')':
                 --openParens;
                 isArg                       = openParens != 0;
                 *closingParenthesisLocation = token.location;
                 break;
             case ',':
                 // The individual arguments are separated by comma tokens, but
                 // the comma tokens between matching inner parentheses do not
                 // seperate arguments.
                 if (openParens == 1)
                     args->push_back(MacroArg());
                 isArg = openParens != 1;
                 break;
             default:
                 isArg = true;
                 break;
         }
         if (isArg)
         {
             MacroArg &arg = args->back();
             // Initial whitespace is not part of the argument.
             if (arg.empty())
                 token.setHasLeadingSpace(false);
             arg.push_back(token);
         }
     }

     const Macro::Parameters &params = macro.parameters;
     // If there is only one empty argument, it is equivalent to no argument.
     if (params.empty() && (args->size() == 1) && args->front().empty())
     {
         args->clear();
     }
     // Validate the number of arguments.
     if (args->size() != params.size())
     {
         Diagnostics::ID id = args->size() < macro.parameters.size()
                                  ? Diagnostics::PP_MACRO_TOO_FEW_ARGS
                                  : Diagnostics::PP_MACRO_TOO_MANY_ARGS;
         mDiagnostics->report(id, identifier.location, identifier.text);
         return false;
     }

     // Pre-expand each argument before substitution.
     // This step expands each argument individually before they are
     // inserted into the macro body.
     size_t numTokens = 0;
     for (auto &arg : *args)
     {
         TokenLexer lexer(&arg);
         if (mSettings.maxMacroExpansionDepth < 1)
         {
             mDiagnostics->report(Diagnostics::PP_MACRO_INVOCATION_CHAIN_TOO_DEEP, token.location,
                                  token.text);
             return false;
         }
         PreprocessorSettings nestedSettings(mSettings.shaderSpec);
         nestedSettings.maxMacroExpansionDepth = mSettings.maxMacroExpansionDepth - 1;
         MacroExpander expander(&lexer, mMacroSet, mDiagnostics, nestedSettings, mParseDefined);

         arg.clear();
         expander.lex(&token);
         while (token.type != Token::LAST)
         {
             arg.push_back(token);
             expander.lex(&token);
             numTokens++;
             if (numTokens + mTotalTokensInContexts > kMaxContextTokens)
             {
                 mDiagnostics->report(Diagnostics::PP_OUT_OF_MEMORY, token.location, token.text);
                 return false;
             }
         }
     }
     return true;
 }

 void MacroExpander::replaceMacroParams(const Macro &macro,
                                        const std::vector<MacroArg> &args,
                                        std::vector<Token> *replacements)
 {
     for (std::size_t i = 0; i < macro.replacements.size(); ++i)
     {
         if (!replacements->empty() &&
             replacements->size() + mTotalTokensInContexts > kMaxContextTokens)
         {
             const Token &token = replacements->back();
             mDiagnostics->report(Diagnostics::PP_OUT_OF_MEMORY, token.location, token.text);
             return;
         }

         const Token &repl = macro.replacements[i];
         if (repl.type != Token::IDENTIFIER)
         {
             replacements->push_back(repl);
             continue;
         }

         // TODO(alokp): Optimize this.
         // There is no need to search for macro params every time.
         // The param index can be cached with the replacement token.
         Macro::Parameters::const_iterator iter =
             std::find(macro.parameters.begin(), macro.parameters.end(), repl.text);
         if (iter == macro.parameters.end())
         {
             replacements->push_back(repl);
             continue;
         }

         std::size_t iArg    = std::distance(macro.parameters.begin(), iter);
         const MacroArg &arg = args[iArg];
         if (arg.empty())
         {
             continue;
         }
         std::size_t iRepl = replacements->size();
         replacements->insert(replacements->end(), arg.begin(), arg.end());
         // The replacement token inherits padding properties from
         // macro replacement token.
         replacements->at(iRepl).setHasLeadingSpace(repl.hasLeadingSpace());
     }
 }

 MacroExpander::MacroContext::MacroContext() : macro(0), index(0) {}

 MacroExpander::MacroContext::~MacroContext() {}

 bool MacroExpander::MacroContext::empty() const
 {
     return index == replacements.size();
 }

 const Token &MacroExpander::MacroContext::get()
 {
     return replacements[index++];
 }

 void MacroExpander::MacroContext::unget()
 {
     ASSERT(index > 0);
     --index;
 }

 }  // namespace pp

 }  // namespace angle
	//
	// Copyright 2011 The ANGLE Project Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//

	#include "compiler/preprocessor/MacroExpander.h"

	#include <GLSLANG/ShaderLang.h>
	#include <algorithm>

	#include "common/debug.h"
	#include "compiler/preprocessor/DiagnosticsBase.h"
	#include "compiler/preprocessor/Token.h"

	namespace angle
	{

	namespace pp
	{

	namespace
	{

	const size_t kMaxContextTokens = 10000;

	class TokenLexer : public Lexer
	{
	public:
	typedef std::vector<Token> TokenVector;

	TokenLexer(TokenVector *tokens)
	{
	tokens->swap(mTokens);
	mIter = mTokens.begin();
	}

	void lex(Token *token) override
	{
	if (mIter == mTokens.end())
	{
	token->reset();
	token->type = Token::LAST;
	}
	else
	{
	token = mIter++;
	}
	}

	private:
	TokenVector mTokens;
	TokenVector::const_iterator mIter;
	};

	} // anonymous namespace

	class MacroExpander::ScopedMacroReenabler final : angle::NonCopyable
	{
	public:
	ScopedMacroReenabler(MacroExpander *expander);
	~ScopedMacroReenabler();

	private:
	MacroExpander *mExpander;
	};

	MacroExpander::ScopedMacroReenabler::ScopedMacroReenabler(MacroExpander *expander)
	: mExpander(expander)
	{
	mExpander->mDeferReenablingMacros = true;
	}

	MacroExpander::ScopedMacroReenabler::~ScopedMacroReenabler()
	{
	mExpander->mDeferReenablingMacros = false;
	for (const std::shared_ptr<Macro> &macro : mExpander->mMacrosToReenable)
	{
	// Copying the string here by using substr is a check for use-after-free. It detects
	// use-after-free more reliably than just toggling the disabled flag.
	ASSERT(macro->name.substr() != "");
	macro->disabled = false;
	}
	mExpander->mMacrosToReenable.clear();
	}

	MacroExpander::MacroExpander(Lexer *lexer,
	MacroSet *macroSet,
	Diagnostics *diagnostics,
	const PreprocessorSettings &settings,
	bool parseDefined)
	: mLexer(lexer),
	mMacroSet(macroSet),
	mDiagnostics(diagnostics),
	mParseDefined(parseDefined),
	mTotalTokensInContexts(0),
	mSettings(settings),
	mDeferReenablingMacros(false)
	{}

	MacroExpander::~MacroExpander()
	{
	ASSERT(mMacrosToReenable.empty());
	for (MacroContext *context : mContextStack)
	{
	delete context;
	}
	}

	void MacroExpander::lex(Token *token)
	{
	while (true)
	{
	getToken(token);

	if (token->type != Token::IDENTIFIER)
	break;

	// Defined operator is parsed here since it may be generated by macro expansion.
	// Defined operator produced by macro expansion has undefined behavior according to C++
	// spec, which the GLSL spec references (see C++14 draft spec section 16.1.4), but this
	// behavior is needed for passing dEQP tests, which enforce stricter compatibility between
	// implementations.
	if (mParseDefined && token->text == kDefined)
	{
	// Defined inside a macro is forbidden in WebGL.
	if (!mContextStack.empty() && sh::IsWebGLBasedSpec(mSettings.shaderSpec))
	break;

	bool paren = false;
	getToken(token);
	if (token->type == '(')
	{
	paren = true;
	getToken(token);
	}
	if (token->type != Token::IDENTIFIER)
	{
	mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location,
	token->text);
	break;
	}
	auto iter = mMacroSet->find(token->text);
	std::string expression = iter != mMacroSet->end() ? "1" : "0";

	if (paren)
	{
	getToken(token);
	if (token->type != ')')
	{
	mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location,
	token->text);
	break;
	}
	}

	// We have a valid defined operator.
	// Convert the current token into a CONST_INT token.
	token->type = Token::CONST_INT;
	token->text = expression;
	break;
	}

	if (token->expansionDisabled())
	break;

	MacroSet::const_iterator iter = mMacroSet->find(token->text);
	if (iter == mMacroSet->end())
	break;

	std::shared_ptr<Macro> macro = iter->second;
	if (macro->disabled)
	{
	// If a particular token is not expanded, it is never expanded.
	token->setExpansionDisabled(true);
	break;
	}

	// Bump the expansion count before peeking if the next token is a '('
	// otherwise there could be a #undef of the macro before the next token.
	macro->expansionCount++;
	if ((macro->type == Macro::kTypeFunc) && !isNextTokenLeftParen())
	{
	// If the token immediately after the macro name is not a '(',
	// this macro should not be expanded.
	macro->expansionCount--;
	break;
	}

	pushMacro(macro, *token);
	}
	}

	void MacroExpander::getToken(Token *token)
	{
	if (mReserveToken.get())
	{
	token = mReserveToken;
	mReserveToken.reset();
	return;
	}

	// First pop all empty macro contexts.
	while (!mContextStack.empty() && mContextStack.back()->empty())
	{
	popMacro();
	}

	if (!mContextStack.empty())
	{
	*token = mContextStack.back()->get();
	}
	else
	{
	ASSERT(mTotalTokensInContexts == 0);
	mLexer->lex(token);
	}
	}

	void MacroExpander::ungetToken(const Token &token)
	{
	if (!mContextStack.empty())
	{
	MacroContext *context = mContextStack.back();
	context->unget();
	ASSERT(context->replacements[context->index] == token);
	}
	else
	{
	ASSERT(!mReserveToken.get());
	mReserveToken.reset(new Token(token));
	}
	}

	bool MacroExpander::isNextTokenLeftParen()
	{
	Token token;
	getToken(&token);

	bool lparen = token.type == '(';
	ungetToken(token);

	return lparen;
	}

	bool MacroExpander::pushMacro(std::shared_ptr<Macro> macro, const Token &identifier)
	{
	ASSERT(!macro->disabled);
	ASSERT(!identifier.expansionDisabled());
	ASSERT(identifier.type == Token::IDENTIFIER);
	ASSERT(identifier.text == macro->name);

	std::vector<Token> replacements;
	if (!expandMacro(*macro, identifier, &replacements))
	return false;

	// Macro is disabled for expansion until it is popped off the stack.
	macro->disabled = true;

	MacroContext *context = new MacroContext;
	context->macro = macro;
	context->replacements.swap(replacements);
	mContextStack.push_back(context);
	mTotalTokensInContexts += context->replacements.size();
	return true;
	}

	void MacroExpander::popMacro()
	{
	ASSERT(!mContextStack.empty());

	MacroContext *context = mContextStack.back();
	mContextStack.pop_back();

	ASSERT(context->empty());
	ASSERT(context->macro->disabled);
	ASSERT(context->macro->expansionCount > 0);
	if (mDeferReenablingMacros)
	{
	mMacrosToReenable.push_back(context->macro);
	}
	else
	{
	context->macro->disabled = false;
	}
	context->macro->expansionCount--;
	mTotalTokensInContexts -= context->replacements.size();
	delete context;
	}

	bool MacroExpander::expandMacro(const Macro &macro,
	const Token &identifier,
	std::vector<Token> *replacements)
	{
	replacements->clear();

	// In the case of an object-like macro, the replacement list gets its location
	// from the identifier, but in the case of a function-like macro, the replacement
	// list gets its location from the closing parenthesis of the macro invocation.
	// This is tested by dEQP-GLES3.functional.shaders.preprocessor.predefined_macros.*
	SourceLocation replacementLocation = identifier.location;
	if (macro.type == Macro::kTypeObj)
	{
	replacements->assign(macro.replacements.begin(), macro.replacements.end());

	if (macro.predefined)
	{
	const char kLine[] = "__LINE__";
	const char kFile[] = "__FILE__";

	ASSERT(replacements->size() == 1);
	Token &repl = replacements->front();
	if (macro.name == kLine)
	{
	repl.text = ToString(identifier.location.line);
	}
	else if (macro.name == kFile)
	{
	repl.text = ToString(identifier.location.file);
	}
	}
	}
	else
	{
	ASSERT(macro.type == Macro::kTypeFunc);
	std::vector<MacroArg> args;
	args.reserve(macro.parameters.size());
	if (!collectMacroArgs(macro, identifier, &args, &replacementLocation))
	return false;

	replaceMacroParams(macro, args, replacements);
	}

	for (std::size_t i = 0; i < replacements->size(); ++i)
	{
	Token &repl = replacements->at(i);
	if (i == 0)
	{
	// The first token in the replacement list inherits the padding
	// properties of the identifier token.
	repl.setAtStartOfLine(identifier.atStartOfLine());
	repl.setHasLeadingSpace(identifier.hasLeadingSpace());
	}
	repl.location = replacementLocation;
	}
	return true;
	}

	bool MacroExpander::collectMacroArgs(const Macro &macro,
	const Token &identifier,
	std::vector<MacroArg> *args,
	SourceLocation *closingParenthesisLocation)
	{
	Token token;
	getToken(&token);
	ASSERT(token.type == '(');

	args->push_back(MacroArg());

	// Defer reenabling macros until args collection is finished to avoid the possibility of
	// infinite recursion. Otherwise infinite recursion might happen when expanding the args after
	// macros have been popped from the context stack when parsing the args.
	ScopedMacroReenabler deferReenablingMacros(this);

	int openParens = 1;
	while (openParens != 0)
	{
	getToken(&token);

	if (token.type == Token::LAST)
	{
	mDiagnostics->report(Diagnostics::PP_MACRO_UNTERMINATED_INVOCATION, identifier.location,
	identifier.text);
	// Do not lose EOF token.
	ungetToken(token);
	return false;
	}

	bool isArg = false; // True if token is part of the current argument.
	switch (token.type)
	{
	case '(':
	++openParens;
	isArg = true;
	break;
	case ')':
	--openParens;
	isArg = openParens != 0;
	*closingParenthesisLocation = token.location;
	break;
	case ',':
	// The individual arguments are separated by comma tokens, but
	// the comma tokens between matching inner parentheses do not
	// seperate arguments.
	if (openParens == 1)
	args->push_back(MacroArg());
	isArg = openParens != 1;
	break;
	default:
	isArg = true;
	break;
	}
	if (isArg)
	{
	MacroArg &arg = args->back();
	// Initial whitespace is not part of the argument.
	if (arg.empty())
	token.setHasLeadingSpace(false);
	arg.push_back(token);
	}
	}

	const Macro::Parameters &params = macro.parameters;
	// If there is only one empty argument, it is equivalent to no argument.
	if (params.empty() && (args->size() == 1) && args->front().empty())
	{
	args->clear();
	}
	// Validate the number of arguments.
	if (args->size() != params.size())
	{
	Diagnostics::ID id = args->size() < macro.parameters.size()
	? Diagnostics::PP_MACRO_TOO_FEW_ARGS
	: Diagnostics::PP_MACRO_TOO_MANY_ARGS;
	mDiagnostics->report(id, identifier.location, identifier.text);
	return false;
	}

	// Pre-expand each argument before substitution.
	// This step expands each argument individually before they are
	// inserted into the macro body.
	size_t numTokens = 0;
	for (auto &arg : *args)
	{
	TokenLexer lexer(&arg);
	if (mSettings.maxMacroExpansionDepth < 1)
	{
	mDiagnostics->report(Diagnostics::PP_MACRO_INVOCATION_CHAIN_TOO_DEEP, token.location,
	token.text);
	return false;
	}
	PreprocessorSettings nestedSettings(mSettings.shaderSpec);
	nestedSettings.maxMacroExpansionDepth = mSettings.maxMacroExpansionDepth - 1;
	MacroExpander expander(&lexer, mMacroSet, mDiagnostics, nestedSettings, mParseDefined);

	arg.clear();
	expander.lex(&token);
	while (token.type != Token::LAST)
	{
	arg.push_back(token);
	expander.lex(&token);
	numTokens++;
	if (numTokens + mTotalTokensInContexts > kMaxContextTokens)
	{
	mDiagnostics->report(Diagnostics::PP_OUT_OF_MEMORY, token.location, token.text);
	return false;
	}
	}
	}
	return true;
	}

	void MacroExpander::replaceMacroParams(const Macro &macro,
	const std::vector<MacroArg> &args,
	std::vector<Token> *replacements)
	{
	for (std::size_t i = 0; i < macro.replacements.size(); ++i)
	{
	if (!replacements->empty() &&
	replacements->size() + mTotalTokensInContexts > kMaxContextTokens)
	{
	const Token &token = replacements->back();
	mDiagnostics->report(Diagnostics::PP_OUT_OF_MEMORY, token.location, token.text);
	return;
	}

	const Token &repl = macro.replacements[i];
	if (repl.type != Token::IDENTIFIER)
	{
	replacements->push_back(repl);
	continue;
	}

	// TODO(alokp): Optimize this.
	// There is no need to search for macro params every time.
	// The param index can be cached with the replacement token.
	Macro::Parameters::const_iterator iter =
	std::find(macro.parameters.begin(), macro.parameters.end(), repl.text);
	if (iter == macro.parameters.end())
	{
	replacements->push_back(repl);
	continue;
	}

	std::size_t iArg = std::distance(macro.parameters.begin(), iter);
	const MacroArg &arg = args[iArg];
	if (arg.empty())
	{
	continue;
	}
	std::size_t iRepl = replacements->size();
	replacements->insert(replacements->end(), arg.begin(), arg.end());
	// The replacement token inherits padding properties from
	// macro replacement token.
	replacements->at(iRepl).setHasLeadingSpace(repl.hasLeadingSpace());
	}
	}

	MacroExpander::MacroContext::MacroContext() : macro(0), index(0) {}

	MacroExpander::MacroContext::~MacroContext() {}

	bool MacroExpander::MacroContext::empty() const
	{
	return index == replacements.size();
	}

	const Token &MacroExpander::MacroContext::get()
	{
	return replacements[index++];
	}

	void MacroExpander::MacroContext::unget()
	{
	ASSERT(index > 0);
	--index;
	}

	} // namespace pp

	} // namespace angle