// // Copyright (C) 2013 LunarG, Inc. // Copyright (C) 2015-2018 Google, Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions // are met: // // Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // // Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following // disclaimer in the documentation and/or other materials provided // with the distribution. // // Neither the name of 3Dlabs Inc. 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IN NO EVENT SHALL NVIDIA BE LIABLE FOR ANY SPECIAL, INDIRECT, INCIDENTAL, EXEMPLARY, CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, LOST PROFITS; PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) OR ARISING IN ANY WAY OUT OF THE USE, REPRODUCTION, MODIFICATION AND/OR DISTRIBUTION OF THE NVIDIA SOFTWARE, HOWEVER CAUSED AND WHETHER UNDER THEORY OF CONTRACT, TORT (INCLUDING NEGLIGENCE), STRICT LIABILITY OR OTHERWISE, EVEN IF NVIDIA HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. \****************************************************************************/ #ifndef PPCONTEXT_H #define PPCONTEXT_H #include #include #include #include "../ParseHelper.h" #include "PpTokens.h" /* windows only pragma */ #ifdef _MSC_VER #pragma warning(disable : 4127) #endif namespace glslang { class TPpToken { public: TPpToken() { clear(); } void clear() { space = false; i64val = 0; loc.init(); name[0] = 0; } // Used for comparing macro definitions, so checks what is relevant for that. bool operator==(const TPpToken& right) const { return space == right.space && ival == right.ival && dval == right.dval && i64val == right.i64val && strncmp(name, right.name, MaxTokenLength) == 0; } bool operator!=(const TPpToken& right) const { return ! operator==(right); } TSourceLoc loc; // True if a space (for white space or a removed comment) should also be // recognized, in front of the token returned: bool space; // Numeric value of the token: union { int ival; double dval; long long i64val; }; // Text string of the token: char name[MaxTokenLength + 1]; }; class TStringAtomMap { // // Implementation is in PpAtom.cpp // // Maintain a bi-directional mapping between relevant preprocessor strings and // "atoms" which a unique integers (small, contiguous, not hash-like) per string. // public: TStringAtomMap(); // Map string -> atom. // Return 0 if no existing string. int getAtom(const char* s) const { auto it = atomMap.find(s); return it == atomMap.end() ? 0 : it->second; } // Map a new or existing string -> atom, inventing a new atom if necessary. int getAddAtom(const char* s) { int atom = getAtom(s); if (atom == 0) { atom = nextAtom++; addAtomFixed(s, atom); } return atom; } // Map atom -> string. const char* getString(int atom) const { return stringMap[atom]->c_str(); } protected: TStringAtomMap(TStringAtomMap&); TStringAtomMap& operator=(TStringAtomMap&); TUnorderedMap atomMap; TVector stringMap; // these point into the TString in atomMap int nextAtom; // Bad source characters can lead to bad atoms, so gracefully handle those by // pre-filling the table with them (to avoid if tests later). TString badToken; // Add bi-directional mappings: // - string -> atom // - atom -> string void addAtomFixed(const char* s, int atom) { auto it = atomMap.insert(std::pair(s, atom)).first; if (stringMap.size() < (size_t)atom + 1) stringMap.resize(atom + 100, &badToken); stringMap[atom] = &it->first; } }; class TInputScanner; enum MacroExpandResult { MacroExpandNotStarted, // macro not expanded, which might not be an error MacroExpandError, // a clear error occurred while expanding, no expansion MacroExpandStarted, // macro expansion process has started MacroExpandUndef // macro is undefined and will be expanded }; // This class is the result of turning a huge pile of C code communicating through globals // into a class. This was done to allowing instancing to attain thread safety. // Don't expect too much in terms of OO design. class TPpContext { public: TPpContext(TParseContextBase&, const std::string& rootFileName, TShader::Includer&); virtual ~TPpContext(); void setPreamble(const char* preamble, size_t length); int tokenize(TPpToken& ppToken); int tokenPaste(int token, TPpToken&); class tInput { public: tInput(TPpContext* p) : done(false), pp(p) { } virtual ~tInput() { } virtual int scan(TPpToken*) = 0; virtual int getch() = 0; virtual void ungetch() = 0; virtual bool peekPasting() { return false; } // true when about to see ## virtual bool peekContinuedPasting(int) { return false; } // true when non-spaced tokens can paste virtual bool endOfReplacementList() { return false; } // true when at the end of a macro replacement list (RHS of #define) virtual bool isMacroInput() { return false; } // Will be called when we start reading tokens from this instance virtual void notifyActivated() {} // Will be called when we do not read tokens from this instance anymore virtual void notifyDeleted() {} protected: bool done; TPpContext* pp; }; void setInput(TInputScanner& input, bool versionWillBeError); void pushInput(tInput* in) { inputStack.push_back(in); in->notifyActivated(); } void popInput() { inputStack.back()->notifyDeleted(); delete inputStack.back(); inputStack.pop_back(); } // // From PpTokens.cpp // // Capture the needed parts of a token stream for macro recording/playback. class TokenStream { public: // Manage a stream of these 'Token', which capture the relevant parts // of a TPpToken, plus its atom. class Token { public: Token(int atom, const TPpToken& ppToken) : atom(atom), space(ppToken.space), i64val(ppToken.i64val), name(ppToken.name) { } int get(TPpToken& ppToken) { ppToken.clear(); ppToken.space = space; ppToken.i64val = i64val; snprintf(ppToken.name, sizeof(ppToken.name), "%s", name.c_str()); return atom; } bool isAtom(int a) const { return atom == a; } int getAtom() const { return atom; } bool nonSpaced() const { return !space; } protected: Token() {} int atom; bool space; // did a space precede the token? long long i64val; TString name; }; TokenStream() : currentPos(0) { } void putToken(int token, TPpToken* ppToken); bool peekToken(int atom) { return !atEnd() && stream[currentPos].isAtom(atom); } bool peekContinuedPasting(int atom) { // This is basically necessary because, for example, the PP // tokenizer only accepts valid numeric-literals plus suffixes, so // separates numeric-literals plus bad suffix into two tokens, which // should get both pasted together as one token when token pasting. // // The following code is a bit more generalized than the above example. if (!atEnd() && atom == PpAtomIdentifier && stream[currentPos].nonSpaced()) { switch(stream[currentPos].getAtom()) { case PpAtomConstInt: case PpAtomConstUint: case PpAtomConstInt64: case PpAtomConstUint64: case PpAtomConstInt16: case PpAtomConstUint16: case PpAtomConstFloat: case PpAtomConstDouble: case PpAtomConstFloat16: case PpAtomConstString: case PpAtomIdentifier: return true; default: break; } } return false; } int getToken(TParseContextBase&, TPpToken*); bool atEnd() { return currentPos >= stream.size(); } bool peekTokenizedPasting(bool lastTokenPastes); bool peekUntokenizedPasting(); void reset() { currentPos = 0; } protected: TVector stream; size_t currentPos; }; // // From Pp.cpp // struct MacroSymbol { MacroSymbol() : functionLike(0), busy(0), undef(0) { } TVector args; TokenStream body; unsigned functionLike : 1; // 0 means object-like, 1 means function-like unsigned busy : 1; unsigned undef : 1; }; typedef TMap TSymbolMap; TSymbolMap macroDefs; // map atoms to macro definitions MacroSymbol* lookupMacroDef(int atom) { auto existingMacroIt = macroDefs.find(atom); return (existingMacroIt == macroDefs.end()) ? nullptr : &(existingMacroIt->second); } void addMacroDef(int atom, MacroSymbol& macroDef) { macroDefs[atom] = macroDef; } protected: TPpContext(TPpContext&); TPpContext& operator=(TPpContext&); TStringAtomMap atomStrings; char* preamble; // string to parse, all before line 1 of string 0, it is 0 if no preamble int preambleLength; char** strings; // official strings of shader, starting a string 0 line 1 size_t* lengths; int numStrings; // how many official strings there are int currentString; // which string we're currently parsing (-1 for preamble) // Scanner data: int previous_token; TParseContextBase& parseContext; // Get the next token from *stack* of input sources, popping input sources // that are out of tokens, down until an input source is found that has a token. // Return EndOfInput when there are no more tokens to be found by doing this. int scanToken(TPpToken* ppToken) { int token = EndOfInput; while (! inputStack.empty()) { token = inputStack.back()->scan(ppToken); if (token != EndOfInput || inputStack.empty()) break; popInput(); } return token; } int getChar() { return inputStack.back()->getch(); } void ungetChar() { inputStack.back()->ungetch(); } bool peekPasting() { return !inputStack.empty() && inputStack.back()->peekPasting(); } bool peekContinuedPasting(int a) { return !inputStack.empty() && inputStack.back()->peekContinuedPasting(a); } bool endOfReplacementList() { return inputStack.empty() || inputStack.back()->endOfReplacementList(); } bool isMacroInput() { return inputStack.size() > 0 && inputStack.back()->isMacroInput(); } static const int maxIfNesting = 65; int ifdepth; // current #if-#else-#endif nesting in the cpp.c file (pre-processor) bool elseSeen[maxIfNesting]; // Keep a track of whether an else has been seen at a particular depth int elsetracker; // #if-#else and #endif constructs...Counter. class tMacroInput : public tInput { public: tMacroInput(TPpContext* pp) : tInput(pp), prepaste(false), postpaste(false) { } virtual ~tMacroInput() { for (size_t i = 0; i < args.size(); ++i) delete args[i]; for (size_t i = 0; i < expandedArgs.size(); ++i) delete expandedArgs[i]; } virtual int scan(TPpToken*) override; virtual int getch() override { assert(0); return EndOfInput; } virtual void ungetch() override { assert(0); } bool peekPasting() override { return prepaste; } bool peekContinuedPasting(int a) override { return mac->body.peekContinuedPasting(a); } bool endOfReplacementList() override { return mac->body.atEnd(); } bool isMacroInput() override { return true; } MacroSymbol *mac; TVector args; TVector expandedArgs; protected: bool prepaste; // true if we are just before ## bool postpaste; // true if we are right after ## }; class tMarkerInput : public tInput { public: tMarkerInput(TPpContext* pp) : tInput(pp) { } virtual int scan(TPpToken*) override { if (done) return EndOfInput; done = true; return marker; } virtual int getch() override { assert(0); return EndOfInput; } virtual void ungetch() override { assert(0); } static const int marker = -3; }; class tZeroInput : public tInput { public: tZeroInput(TPpContext* pp) : tInput(pp) { } virtual int scan(TPpToken*) override; virtual int getch() override { assert(0); return EndOfInput; } virtual void ungetch() override { assert(0); } }; std::vector inputStack; bool errorOnVersion; bool versionSeen; // // from Pp.cpp // // Used to obtain #include content. TShader::Includer& includer; int CPPdefine(TPpToken * ppToken); int CPPundef(TPpToken * ppToken); int CPPelse(int matchelse, TPpToken * ppToken); int extraTokenCheck(int atom, TPpToken* ppToken, int token); int eval(int token, int precedence, bool shortCircuit, int& res, bool& err, TPpToken * ppToken); int evalToToken(int token, bool shortCircuit, int& res, bool& err, TPpToken * ppToken); int CPPif (TPpToken * ppToken); int CPPifdef(int defined, TPpToken * ppToken); int CPPinclude(TPpToken * ppToken); int CPPline(TPpToken * ppToken); int CPPerror(TPpToken * ppToken); int CPPpragma(TPpToken * ppToken); int CPPversion(TPpToken * ppToken); int CPPextension(TPpToken * ppToken); int readCPPline(TPpToken * ppToken); int scanHeaderName(TPpToken* ppToken, char delimit); TokenStream* PrescanMacroArg(TokenStream&, TPpToken*, bool newLineOkay); MacroExpandResult MacroExpand(TPpToken* ppToken, bool expandUndef, bool newLineOkay); // // From PpTokens.cpp // void pushTokenStreamInput(TokenStream&, bool pasting = false); void UngetToken(int token, TPpToken*); class tTokenInput : public tInput { public: tTokenInput(TPpContext* pp, TokenStream* t, bool prepasting) : tInput(pp), tokens(t), lastTokenPastes(prepasting) { } virtual int scan(TPpToken *ppToken) override { return tokens->getToken(pp->parseContext, ppToken); } virtual int getch() override { assert(0); return EndOfInput; } virtual void ungetch() override { assert(0); } virtual bool peekPasting() override { return tokens->peekTokenizedPasting(lastTokenPastes); } bool peekContinuedPasting(int a) override { return tokens->peekContinuedPasting(a); } protected: TokenStream* tokens; bool lastTokenPastes; // true if the last token in the input is to be pasted, rather than consumed as a token }; class tUngotTokenInput : public tInput { public: tUngotTokenInput(TPpContext* pp, int t, TPpToken* p) : tInput(pp), token(t), lval(*p) { } virtual int scan(TPpToken *) override; virtual int getch() override { assert(0); return EndOfInput; } virtual void ungetch() override { assert(0); } protected: int token; TPpToken lval; }; // // From PpScanner.cpp // class tStringInput : public tInput { public: tStringInput(TPpContext* pp, TInputScanner& i) : tInput(pp), input(&i) { } virtual int scan(TPpToken*) override; // Scanner used to get source stream characters. // - Escaped newlines are handled here, invisibly to the caller. // - All forms of newline are handled, and turned into just a '\n'. int getch() override { int ch = input->get(); if (ch == '\\') { // Move past escaped newlines, as many as sequentially exist do { if (input->peek() == '\r' || input->peek() == '\n') { bool allowed = pp->parseContext.lineContinuationCheck(input->getSourceLoc(), pp->inComment); if (! allowed && pp->inComment) return '\\'; // escape one newline now ch = input->get(); int nextch = input->get(); if (ch == '\r' && nextch == '\n') ch = input->get(); else ch = nextch; } else return '\\'; } while (ch == '\\'); } // handle any non-escaped newline if (ch == '\r' || ch == '\n') { if (ch == '\r' && input->peek() == '\n') input->get(); return '\n'; } return ch; } // Scanner used to backup the source stream characters. Newlines are // handled here, invisibly to the caller, meaning have to undo exactly // what getch() above does (e.g., don't leave things in the middle of a // sequence of escaped newlines). void ungetch() override { input->unget(); do { int ch = input->peek(); if (ch == '\r' || ch == '\n') { if (ch == '\n') { // correct for two-character newline input->unget(); if (input->peek() != '\r') input->get(); } // now in front of a complete newline, move past an escape character input->unget(); if (input->peek() == '\\') input->unget(); else { input->get(); break; } } else break; } while (true); } protected: TInputScanner* input; }; // Holds a reference to included file data, as well as a // prologue and an epilogue string. This can be scanned using the tInput // interface and acts as a single source string. class TokenizableIncludeFile : public tInput { public: // Copies prologue and epilogue. The includedFile must remain valid // until this TokenizableIncludeFile is no longer used. TokenizableIncludeFile(const TSourceLoc& startLoc, const std::string& prologue, TShader::Includer::IncludeResult* includedFile, const std::string& epilogue, TPpContext* pp) : tInput(pp), prologue_(prologue), epilogue_(epilogue), includedFile_(includedFile), scanner(3, strings, lengths, nullptr, 0, 0, true), prevScanner(nullptr), stringInput(pp, scanner) { strings[0] = prologue_.data(); strings[1] = includedFile_->headerData; strings[2] = epilogue_.data(); lengths[0] = prologue_.size(); lengths[1] = includedFile_->headerLength; lengths[2] = epilogue_.size(); scanner.setLine(startLoc.line); scanner.setString(startLoc.string); scanner.setFile(startLoc.getFilenameStr(), 0); scanner.setFile(startLoc.getFilenameStr(), 1); scanner.setFile(startLoc.getFilenameStr(), 2); } // tInput methods: int scan(TPpToken* t) override { return stringInput.scan(t); } int getch() override { return stringInput.getch(); } void ungetch() override { stringInput.ungetch(); } void notifyActivated() override { prevScanner = pp->parseContext.getScanner(); pp->parseContext.setScanner(&scanner); pp->push_include(includedFile_); } void notifyDeleted() override { pp->parseContext.setScanner(prevScanner); pp->pop_include(); } private: TokenizableIncludeFile& operator=(const TokenizableIncludeFile&); // Stores the prologue for this string. const std::string prologue_; // Stores the epilogue for this string. const std::string epilogue_; // Points to the IncludeResult that this TokenizableIncludeFile represents. TShader::Includer::IncludeResult* includedFile_; // Will point to prologue_, includedFile_->headerData and epilogue_ // This is passed to scanner constructor. // These do not own the storage and it must remain valid until this // object has been destroyed. const char* strings[3]; // Length of str_, passed to scanner constructor. size_t lengths[3]; // Scans over str_. TInputScanner scanner; // The previous effective scanner before the scanner in this instance // has been activated. TInputScanner* prevScanner; // Delegate object implementing the tInput interface. tStringInput stringInput; }; int ScanFromString(char* s); void missingEndifCheck(); int lFloatConst(int len, int ch, TPpToken* ppToken); int characterLiteral(TPpToken* ppToken); void push_include(TShader::Includer::IncludeResult* result) { currentSourceFile = result->headerName; includeStack.push(result); } void pop_include() { TShader::Includer::IncludeResult* include = includeStack.top(); includeStack.pop(); includer.releaseInclude(include); if (includeStack.empty()) { currentSourceFile = rootFileName; } else { currentSourceFile = includeStack.top()->headerName; } } bool inComment; std::string rootFileName; std::stack includeStack; std::string currentSourceFile; std::istringstream strtodStream; bool disableEscapeSequences; }; } // end namespace glslang #endif // PPCONTEXT_H