// 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. #include "DirectiveParser.h" #include <algorithm> #include <cassert> #include <cstdlib> #include <sstream> #include "DiagnosticsBase.h" #include "DirectiveHandlerBase.h" #include "ExpressionParser.h" #include "MacroExpander.h" #include "Token.h" #include "Tokenizer.h" namespace { enum DirectiveType { DIRECTIVE_NONE, DIRECTIVE_DEFINE, DIRECTIVE_UNDEF, DIRECTIVE_IF, DIRECTIVE_IFDEF, DIRECTIVE_IFNDEF, DIRECTIVE_ELSE, DIRECTIVE_ELIF, DIRECTIVE_ENDIF, DIRECTIVE_ERROR, DIRECTIVE_PRAGMA, DIRECTIVE_EXTENSION, DIRECTIVE_VERSION, DIRECTIVE_LINE }; } // namespace static DirectiveType getDirective(const pp::Token *token) { static const std::string kDirectiveDefine("define"); static const std::string kDirectiveUndef("undef"); static const std::string kDirectiveIf("if"); static const std::string kDirectiveIfdef("ifdef"); static const std::string kDirectiveIfndef("ifndef"); static const std::string kDirectiveElse("else"); static const std::string kDirectiveElif("elif"); static const std::string kDirectiveEndif("endif"); static const std::string kDirectiveError("error"); static const std::string kDirectivePragma("pragma"); static const std::string kDirectiveExtension("extension"); static const std::string kDirectiveVersion("version"); static const std::string kDirectiveLine("line"); if (token->type != pp::Token::IDENTIFIER) return DIRECTIVE_NONE; if (token->text == kDirectiveDefine) return DIRECTIVE_DEFINE; else if (token->text == kDirectiveUndef) return DIRECTIVE_UNDEF; else if (token->text == kDirectiveIf) return DIRECTIVE_IF; else if (token->text == kDirectiveIfdef) return DIRECTIVE_IFDEF; else if (token->text == kDirectiveIfndef) return DIRECTIVE_IFNDEF; else if (token->text == kDirectiveElse) return DIRECTIVE_ELSE; else if (token->text == kDirectiveElif) return DIRECTIVE_ELIF; else if (token->text == kDirectiveEndif) return DIRECTIVE_ENDIF; else if (token->text == kDirectiveError) return DIRECTIVE_ERROR; else if (token->text == kDirectivePragma) return DIRECTIVE_PRAGMA; else if (token->text == kDirectiveExtension) return DIRECTIVE_EXTENSION; else if (token->text == kDirectiveVersion) return DIRECTIVE_VERSION; else if (token->text == kDirectiveLine) return DIRECTIVE_LINE; return DIRECTIVE_NONE; } static bool isConditionalDirective(DirectiveType directive) { switch (directive) { case DIRECTIVE_IF: case DIRECTIVE_IFDEF: case DIRECTIVE_IFNDEF: case DIRECTIVE_ELSE: case DIRECTIVE_ELIF: case DIRECTIVE_ENDIF: return true; default: return false; } } // Returns true if the token represents End Of Directive. static bool isEOD(const pp::Token *token) { return (token->type == '\n') || (token->type == pp::Token::LAST); } static void skipUntilEOD(pp::Lexer *lexer, pp::Token *token) { while(!isEOD(token)) { lexer->lex(token); } } static bool isMacroNameReserved(const std::string& name) { // Names prefixed with "GL_" are reserved. return (name.substr(0, 3) == "GL_"); } bool hasDoubleUnderscores(const std::string &name) { return (name.find("__") != std::string::npos); } static bool isMacroPredefined(const std::string& name, const pp::MacroSet& macroSet) { pp::MacroSet::const_iterator iter = macroSet.find(name); return iter != macroSet.end() ? iter->second->predefined : false; } namespace pp { class DefinedParser : public Lexer { public: DefinedParser(Lexer *lexer, const MacroSet *macroSet, Diagnostics *diagnostics) : mLexer(lexer), mMacroSet(macroSet), mDiagnostics(diagnostics) { } protected: void lex(Token *token) override { const char kDefined[] = "defined"; mLexer->lex(token); if (token->type != Token::IDENTIFIER) return; if (token->text != kDefined) return; bool paren = false; mLexer->lex(token); if (token->type == '(') { paren = true; mLexer->lex(token); } if (token->type != Token::IDENTIFIER) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mLexer, token); return; } MacroSet::const_iterator iter = mMacroSet->find(token->text); std::string expression = iter != mMacroSet->end() ? "1" : "0"; if (paren) { mLexer->lex(token); if (token->type != ')') { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mLexer, token); return; } } // We have a valid defined operator. // Convert the current token into a CONST_INT token. token->type = Token::CONST_INT; token->text = expression; } private: Lexer *mLexer; const MacroSet *mMacroSet; Diagnostics *mDiagnostics; }; DirectiveParser::DirectiveParser(Tokenizer *tokenizer, MacroSet *macroSet, Diagnostics *diagnostics, DirectiveHandler *directiveHandler, int maxMacroExpansionDepth) : mPastFirstStatement(false), mSeenNonPreprocessorToken(false), mTokenizer(tokenizer), mMacroSet(macroSet), mDiagnostics(diagnostics), mDirectiveHandler(directiveHandler), mShaderVersion(100), mMaxMacroExpansionDepth(maxMacroExpansionDepth) { } DirectiveParser::~DirectiveParser() { } void DirectiveParser::lex(Token *token) { do { mTokenizer->lex(token); if (token->type == Token::PP_HASH) { parseDirective(token); mPastFirstStatement = true; } else if (!isEOD(token)) { mSeenNonPreprocessorToken = true; } if (token->type == Token::LAST) { if (!mConditionalStack.empty()) { const ConditionalBlock &block = mConditionalStack.back(); mDiagnostics->report(Diagnostics::PP_CONDITIONAL_UNTERMINATED, block.location, block.type); } break; } } while (skipping() || (token->type == '\n')); mPastFirstStatement = true; } void DirectiveParser::parseDirective(Token *token) { assert(token->type == Token::PP_HASH); mTokenizer->lex(token); if (isEOD(token)) { // Empty Directive. return; } DirectiveType directive = getDirective(token); // While in an excluded conditional block/group, // we only parse conditional directives. if (skipping() && !isConditionalDirective(directive)) { skipUntilEOD(mTokenizer, token); return; } switch(directive) { case DIRECTIVE_NONE: mDiagnostics->report(Diagnostics::PP_DIRECTIVE_INVALID_NAME, token->location, token->text); skipUntilEOD(mTokenizer, token); break; case DIRECTIVE_DEFINE: parseDefine(token); break; case DIRECTIVE_UNDEF: parseUndef(token); break; case DIRECTIVE_IF: parseIf(token); break; case DIRECTIVE_IFDEF: parseIfdef(token); break; case DIRECTIVE_IFNDEF: parseIfndef(token); break; case DIRECTIVE_ELSE: parseElse(token); break; case DIRECTIVE_ELIF: parseElif(token); break; case DIRECTIVE_ENDIF: parseEndif(token); break; case DIRECTIVE_ERROR: parseError(token); break; case DIRECTIVE_PRAGMA: parsePragma(token); break; case DIRECTIVE_EXTENSION: parseExtension(token); break; case DIRECTIVE_VERSION: parseVersion(token); break; case DIRECTIVE_LINE: parseLine(token); break; default: assert(false); break; } skipUntilEOD(mTokenizer, token); if (token->type == Token::LAST) { mDiagnostics->report(Diagnostics::PP_EOF_IN_DIRECTIVE, token->location, token->text); } } void DirectiveParser::parseDefine(Token *token) { assert(getDirective(token) == DIRECTIVE_DEFINE); mTokenizer->lex(token); if (token->type != Token::IDENTIFIER) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); return; } if (isMacroPredefined(token->text, *mMacroSet)) { mDiagnostics->report(Diagnostics::PP_MACRO_PREDEFINED_REDEFINED, token->location, token->text); return; } if (isMacroNameReserved(token->text)) { mDiagnostics->report(Diagnostics::PP_MACRO_NAME_RESERVED, token->location, token->text); return; } // Using double underscores is allowed, but may result in unintended // behavior, so a warning is issued. At the time of writing this was // specified in ESSL 3.10, but the intent judging from Khronos // discussions and dEQP tests was that double underscores should be // allowed in earlier ESSL versions too. if (hasDoubleUnderscores(token->text)) { mDiagnostics->report(Diagnostics::PP_WARNING_MACRO_NAME_RESERVED, token->location, token->text); } std::shared_ptr<Macro> macro = std::make_shared<Macro>(); macro->type = Macro::kTypeObj; macro->name = token->text; mTokenizer->lex(token); if (token->type == '(' && !token->hasLeadingSpace()) { // Function-like macro. Collect arguments. macro->type = Macro::kTypeFunc; do { mTokenizer->lex(token); if (token->type != Token::IDENTIFIER) break; if (std::find(macro->parameters.begin(), macro->parameters.end(), token->text) != macro->parameters.end()) { mDiagnostics->report(Diagnostics::PP_MACRO_DUPLICATE_PARAMETER_NAMES, token->location, token->text); return; } macro->parameters.push_back(token->text); mTokenizer->lex(token); // Get ','. } while (token->type == ','); if (token->type != ')') { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); return; } mTokenizer->lex(token); // Get ')'. } while ((token->type != '\n') && (token->type != Token::LAST)) { // Reset the token location because it is unnecessary in replacement // list. Resetting it also allows us to reuse Token::equals() to // compare macros. token->location = SourceLocation(); macro->replacements.push_back(*token); mTokenizer->lex(token); } if (!macro->replacements.empty()) { // Whitespace preceding the replacement list is not considered part of // the replacement list for either form of macro. macro->replacements.front().setHasLeadingSpace(false); } // Check for macro redefinition. MacroSet::const_iterator iter = mMacroSet->find(macro->name); if (iter != mMacroSet->end() && !macro->equals(*iter->second)) { mDiagnostics->report(Diagnostics::PP_MACRO_REDEFINED, token->location, macro->name); return; } mMacroSet->insert(std::make_pair(macro->name, macro)); } void DirectiveParser::parseUndef(Token *token) { assert(getDirective(token) == DIRECTIVE_UNDEF); mTokenizer->lex(token); if (token->type != Token::IDENTIFIER) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); return; } MacroSet::iterator iter = mMacroSet->find(token->text); if (iter != mMacroSet->end()) { if (iter->second->predefined) { mDiagnostics->report(Diagnostics::PP_MACRO_PREDEFINED_UNDEFINED, token->location, token->text); return; } else if (iter->second->expansionCount > 0) { mDiagnostics->report(Diagnostics::PP_MACRO_UNDEFINED_WHILE_INVOKED, token->location, token->text); return; } else { mMacroSet->erase(iter); } } mTokenizer->lex(token); if (!isEOD(token)) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mTokenizer, token); } } void DirectiveParser::parseIf(Token *token) { assert(getDirective(token) == DIRECTIVE_IF); parseConditionalIf(token); } void DirectiveParser::parseIfdef(Token *token) { assert(getDirective(token) == DIRECTIVE_IFDEF); parseConditionalIf(token); } void DirectiveParser::parseIfndef(Token *token) { assert(getDirective(token) == DIRECTIVE_IFNDEF); parseConditionalIf(token); } void DirectiveParser::parseElse(Token *token) { assert(getDirective(token) == DIRECTIVE_ELSE); if (mConditionalStack.empty()) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_ELSE_WITHOUT_IF, token->location, token->text); skipUntilEOD(mTokenizer, token); return; } ConditionalBlock &block = mConditionalStack.back(); if (block.skipBlock) { // No diagnostics. Just skip the whole line. skipUntilEOD(mTokenizer, token); return; } if (block.foundElseGroup) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_ELSE_AFTER_ELSE, token->location, token->text); skipUntilEOD(mTokenizer, token); return; } block.foundElseGroup = true; block.skipGroup = block.foundValidGroup; block.foundValidGroup = true; // Check if there are extra tokens after #else. mTokenizer->lex(token); if (!isEOD(token)) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mTokenizer, token); } } void DirectiveParser::parseElif(Token *token) { assert(getDirective(token) == DIRECTIVE_ELIF); if (mConditionalStack.empty()) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_ELIF_WITHOUT_IF, token->location, token->text); skipUntilEOD(mTokenizer, token); return; } ConditionalBlock &block = mConditionalStack.back(); if (block.skipBlock) { // No diagnostics. Just skip the whole line. skipUntilEOD(mTokenizer, token); return; } if (block.foundElseGroup) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_ELIF_AFTER_ELSE, token->location, token->text); skipUntilEOD(mTokenizer, token); return; } if (block.foundValidGroup) { // Do not parse the expression. // Also be careful not to emit a diagnostic. block.skipGroup = true; skipUntilEOD(mTokenizer, token); return; } int expression = parseExpressionIf(token); block.skipGroup = expression == 0; block.foundValidGroup = expression != 0; } void DirectiveParser::parseEndif(Token *token) { assert(getDirective(token) == DIRECTIVE_ENDIF); if (mConditionalStack.empty()) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_ENDIF_WITHOUT_IF, token->location, token->text); skipUntilEOD(mTokenizer, token); return; } mConditionalStack.pop_back(); // Check if there are tokens after #endif. mTokenizer->lex(token); if (!isEOD(token)) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mTokenizer, token); } } void DirectiveParser::parseError(Token *token) { assert(getDirective(token) == DIRECTIVE_ERROR); std::ostringstream stream; mTokenizer->lex(token); while ((token->type != '\n') && (token->type != Token::LAST)) { stream << *token; mTokenizer->lex(token); } mDirectiveHandler->handleError(token->location, stream.str()); } // Parses pragma of form: #pragma name[(value)]. void DirectiveParser::parsePragma(Token *token) { assert(getDirective(token) == DIRECTIVE_PRAGMA); enum State { PRAGMA_NAME, LEFT_PAREN, PRAGMA_VALUE, RIGHT_PAREN }; bool valid = true; std::string name, value; int state = PRAGMA_NAME; mTokenizer->lex(token); bool stdgl = token->text == "STDGL"; if (stdgl) { mTokenizer->lex(token); } while ((token->type != '\n') && (token->type != Token::LAST)) { switch(state++) { case PRAGMA_NAME: name = token->text; valid = valid && (token->type == Token::IDENTIFIER); break; case LEFT_PAREN: valid = valid && (token->type == '('); break; case PRAGMA_VALUE: value = token->text; valid = valid && (token->type == Token::IDENTIFIER); break; case RIGHT_PAREN: valid = valid && (token->type == ')'); break; default: valid = false; break; } mTokenizer->lex(token); } valid = valid && ((state == PRAGMA_NAME) || // Empty pragma. (state == LEFT_PAREN) || // Without value. (state == RIGHT_PAREN + 1)); // With value. if (!valid) { mDiagnostics->report(Diagnostics::PP_UNRECOGNIZED_PRAGMA, token->location, name); } else if (state > PRAGMA_NAME) // Do not notify for empty pragma. { mDirectiveHandler->handlePragma(token->location, name, value, stdgl); } } void DirectiveParser::parseExtension(Token *token) { assert(getDirective(token) == DIRECTIVE_EXTENSION); enum State { EXT_NAME, COLON, EXT_BEHAVIOR }; bool valid = true; std::string name, behavior; int state = EXT_NAME; mTokenizer->lex(token); while ((token->type != '\n') && (token->type != Token::LAST)) { switch (state++) { case EXT_NAME: if (valid && (token->type != Token::IDENTIFIER)) { mDiagnostics->report(Diagnostics::PP_INVALID_EXTENSION_NAME, token->location, token->text); valid = false; } if (valid) name = token->text; break; case COLON: if (valid && (token->type != ':')) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); valid = false; } break; case EXT_BEHAVIOR: if (valid && (token->type != Token::IDENTIFIER)) { mDiagnostics->report(Diagnostics::PP_INVALID_EXTENSION_BEHAVIOR, token->location, token->text); valid = false; } if (valid) behavior = token->text; break; default: if (valid) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); valid = false; } break; } mTokenizer->lex(token); } if (valid && (state != EXT_BEHAVIOR + 1)) { mDiagnostics->report(Diagnostics::PP_INVALID_EXTENSION_DIRECTIVE, token->location, token->text); valid = false; } if (valid && mSeenNonPreprocessorToken) { if (mShaderVersion >= 300) { mDiagnostics->report(Diagnostics::PP_NON_PP_TOKEN_BEFORE_EXTENSION_ESSL3, token->location, token->text); valid = false; } else { mDiagnostics->report(Diagnostics::PP_NON_PP_TOKEN_BEFORE_EXTENSION_ESSL1, token->location, token->text); } } if (valid) mDirectiveHandler->handleExtension(token->location, name, behavior); } void DirectiveParser::parseVersion(Token *token) { assert(getDirective(token) == DIRECTIVE_VERSION); if (mPastFirstStatement) { mDiagnostics->report(Diagnostics::PP_VERSION_NOT_FIRST_STATEMENT, token->location, token->text); skipUntilEOD(mTokenizer, token); return; } enum State { VERSION_NUMBER, VERSION_PROFILE, VERSION_ENDLINE }; bool valid = true; int version = 0; int state = VERSION_NUMBER; mTokenizer->lex(token); while (valid && (token->type != '\n') && (token->type != Token::LAST)) { switch (state) { case VERSION_NUMBER: if (token->type != Token::CONST_INT) { mDiagnostics->report(Diagnostics::PP_INVALID_VERSION_NUMBER, token->location, token->text); valid = false; } if (valid && !token->iValue(&version)) { mDiagnostics->report(Diagnostics::PP_INTEGER_OVERFLOW, token->location, token->text); valid = false; } if (valid) { state = (version < 300) ? VERSION_ENDLINE : VERSION_PROFILE; } break; case VERSION_PROFILE: if (token->type != Token::IDENTIFIER || token->text != "es") { mDiagnostics->report(Diagnostics::PP_INVALID_VERSION_DIRECTIVE, token->location, token->text); valid = false; } state = VERSION_ENDLINE; break; default: mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); valid = false; break; } mTokenizer->lex(token); } if (valid && (state != VERSION_ENDLINE)) { mDiagnostics->report(Diagnostics::PP_INVALID_VERSION_DIRECTIVE, token->location, token->text); valid = false; } if (valid && version >= 300 && token->location.line > 1) { mDiagnostics->report(Diagnostics::PP_VERSION_NOT_FIRST_LINE_ESSL3, token->location, token->text); valid = false; } if (valid) { mDirectiveHandler->handleVersion(token->location, version); mShaderVersion = version; PredefineMacro(mMacroSet, "__VERSION__", version); } } void DirectiveParser::parseLine(Token *token) { assert(getDirective(token) == DIRECTIVE_LINE); bool valid = true; bool parsedFileNumber = false; int line = 0, file = 0; MacroExpander macroExpander(mTokenizer, mMacroSet, mDiagnostics, false, mMaxMacroExpansionDepth); // Lex the first token after "#line" so we can check it for EOD. macroExpander.lex(token); if (isEOD(token)) { mDiagnostics->report(Diagnostics::PP_INVALID_LINE_DIRECTIVE, token->location, token->text); valid = false; } else { ExpressionParser expressionParser(¯oExpander, mDiagnostics); ExpressionParser::ErrorSettings errorSettings; // See GLES3 section 12.42 errorSettings.integerLiteralsMustFit32BitSignedRange = true; errorSettings.unexpectedIdentifier = Diagnostics::PP_INVALID_LINE_NUMBER; // The first token was lexed earlier to check if it was EOD. Include // the token in parsing for a second time by setting the // parsePresetToken flag to true. expressionParser.parse(token, &line, true, errorSettings, &valid); if (!isEOD(token) && valid) { errorSettings.unexpectedIdentifier = Diagnostics::PP_INVALID_FILE_NUMBER; // After parsing the line expression expressionParser has also // advanced to the first token of the file expression - this is the // token that makes the parser reduce the "input" rule for the line // expression and stop. So we're using parsePresetToken = true here // as well. expressionParser.parse(token, &file, true, errorSettings, &valid); parsedFileNumber = true; } if (!isEOD(token)) { if (valid) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); valid = false; } skipUntilEOD(mTokenizer, token); } } if (valid) { mTokenizer->setLineNumber(line); if (parsedFileNumber) mTokenizer->setFileNumber(file); } } bool DirectiveParser::skipping() const { if (mConditionalStack.empty()) return false; const ConditionalBlock &block = mConditionalStack.back(); return block.skipBlock || block.skipGroup; } void DirectiveParser::parseConditionalIf(Token *token) { ConditionalBlock block; block.type = token->text; block.location = token->location; if (skipping()) { // This conditional block is inside another conditional group // which is skipped. As a consequence this whole block is skipped. // Be careful not to parse the conditional expression that might // emit a diagnostic. skipUntilEOD(mTokenizer, token); block.skipBlock = true; } else { DirectiveType directive = getDirective(token); int expression = 0; switch (directive) { case DIRECTIVE_IF: expression = parseExpressionIf(token); break; case DIRECTIVE_IFDEF: expression = parseExpressionIfdef(token); break; case DIRECTIVE_IFNDEF: expression = parseExpressionIfdef(token) == 0 ? 1 : 0; break; default: assert(false); break; } block.skipGroup = expression == 0; block.foundValidGroup = expression != 0; } mConditionalStack.push_back(block); } int DirectiveParser::parseExpressionIf(Token *token) { assert((getDirective(token) == DIRECTIVE_IF) || (getDirective(token) == DIRECTIVE_ELIF)); DefinedParser definedParser(mTokenizer, mMacroSet, mDiagnostics); MacroExpander macroExpander(&definedParser, mMacroSet, mDiagnostics, true, mMaxMacroExpansionDepth); ExpressionParser expressionParser(¯oExpander, mDiagnostics); int expression = 0; ExpressionParser::ErrorSettings errorSettings; errorSettings.integerLiteralsMustFit32BitSignedRange = false; errorSettings.unexpectedIdentifier = Diagnostics::PP_CONDITIONAL_UNEXPECTED_TOKEN; bool valid = true; expressionParser.parse(token, &expression, false, errorSettings, &valid); // Check if there are tokens after #if expression. if (!isEOD(token)) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mTokenizer, token); } return expression; } int DirectiveParser::parseExpressionIfdef(Token* token) { assert((getDirective(token) == DIRECTIVE_IFDEF) || (getDirective(token) == DIRECTIVE_IFNDEF)); mTokenizer->lex(token); if (token->type != Token::IDENTIFIER) { mDiagnostics->report(Diagnostics::PP_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mTokenizer, token); return 0; } MacroSet::const_iterator iter = mMacroSet->find(token->text); int expression = iter != mMacroSet->end() ? 1 : 0; // Check if there are tokens after #ifdef expression. mTokenizer->lex(token); if (!isEOD(token)) { mDiagnostics->report(Diagnostics::PP_CONDITIONAL_UNEXPECTED_TOKEN, token->location, token->text); skipUntilEOD(mTokenizer, token); } return expression; } } // namespace pp