//===--- PTHLexer.cpp - Lex from a token stream ---------------------------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file implements the PTHLexer interface. // //===----------------------------------------------------------------------===// #include "clang/Basic/TokenKinds.h" #include "clang/Basic/FileManager.h" #include "clang/Basic/IdentifierTable.h" #include "clang/Lex/PTHLexer.h" #include "clang/Lex/Preprocessor.h" #include "clang/Lex/PTHManager.h" #include "clang/Lex/Token.h" #include "clang/Lex/Preprocessor.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/ADT/StringMap.h" #include "llvm/ADT/OwningPtr.h" using namespace clang; PTHLexer::PTHLexer(Preprocessor& pp, SourceLocation fileloc, const char* D, PTHManager& PM) : PreprocessorLexer(&pp, fileloc), TokBuf(D), CurTokenIdx(0), PTHMgr(PM), NeedsFetching(true) { // Make sure the EofToken is completely clean. EofToken.startToken(); } Token PTHLexer::GetToken() { // Read the next token, or if we haven't advanced yet, get the last // token read. if (NeedsFetching) { NeedsFetching = false; ReadToken(LastFetched); } Token Tok = LastFetched; // If we are in raw mode, zero out identifier pointers. This is // needed for 'pragma poison'. Note that this requires that the Preprocessor // can go back to the original source when it calls getSpelling(). if (LexingRawMode && Tok.is(tok::identifier)) Tok.setIdentifierInfo(0); return Tok; } void PTHLexer::Lex(Token& Tok) { LexNextToken: Tok = GetToken(); if (AtLastToken()) { Preprocessor *PPCache = PP; if (LexEndOfFile(Tok)) return; assert(PPCache && "Raw buffer::LexEndOfFile should return a token"); return PPCache->Lex(Tok); } // Don't advance to the next token yet. Check if we are at the // start of a new line and we're processing a directive. If so, we // consume this token twice, once as an tok::eom. if (Tok.isAtStartOfLine() && ParsingPreprocessorDirective) { ParsingPreprocessorDirective = false; Tok.setKind(tok::eom); MIOpt.ReadToken(); return; } // Advance to the next token. AdvanceToken(); if (Tok.is(tok::hash)) { if (Tok.isAtStartOfLine() && !LexingRawMode) { PP->HandleDirective(Tok); if (PP->isCurrentLexer(this)) goto LexNextToken; return PP->Lex(Tok); } } MIOpt.ReadToken(); if (Tok.is(tok::identifier)) { if (LexingRawMode) return; return PP->HandleIdentifier(Tok); } } bool PTHLexer::LexEndOfFile(Token &Tok) { if (ParsingPreprocessorDirective) { ParsingPreprocessorDirective = false; Tok.setKind(tok::eom); MIOpt.ReadToken(); return true; // Have a token. } if (LexingRawMode) { MIOpt.ReadToken(); return true; // Have an eof token. } // FIXME: Issue diagnostics similar to Lexer. return PP->HandleEndOfFile(Tok, false); } void PTHLexer::setEOF(Token& Tok) { assert(!EofToken.is(tok::eof)); Tok = EofToken; } void PTHLexer::DiscardToEndOfLine() { assert(ParsingPreprocessorDirective && ParsingFilename == false && "Must be in a preprocessing directive!"); // Already at end-of-file? if (AtLastToken()) return; // Find the first token that is not the start of the *current* line. Token T; for (Lex(T); !AtLastToken(); Lex(T)) if (GetToken().isAtStartOfLine()) return; } //===----------------------------------------------------------------------===// // Utility methods for reading from the mmap'ed PTH file. //===----------------------------------------------------------------------===// static inline uint8_t Read8(const char*& data) { return (uint8_t) *(data++); } static inline uint32_t Read32(const char*& data) { uint32_t V = (uint32_t) Read8(data); V |= (((uint32_t) Read8(data)) << 8); V |= (((uint32_t) Read8(data)) << 16); V |= (((uint32_t) Read8(data)) << 24); return V; } //===----------------------------------------------------------------------===// // Token reconstruction from the PTH file. //===----------------------------------------------------------------------===// void PTHLexer::ReadToken(Token& T) { // Clear the token. // FIXME: Setting the flags directly should obviate this step. T.startToken(); // Read the type of the token. T.setKind((tok::TokenKind) Read8(TokBuf)); // Set flags. This is gross, since we are really setting multiple flags. T.setFlag((Token::TokenFlags) Read8(TokBuf)); // Set the IdentifierInfo* (if any). T.setIdentifierInfo(PTHMgr.ReadIdentifierInfo(TokBuf)); // Set the SourceLocation. Since all tokens are constructed using a // raw lexer, they will all be offseted from the same FileID. T.setLocation(SourceLocation::getFileLoc(FileID, Read32(TokBuf))); // Finally, read and set the length of the token. T.setLength(Read32(TokBuf)); } //===----------------------------------------------------------------------===// // Internal Data Structures for PTH file lookup and resolving identifiers. //===----------------------------------------------------------------------===// /// PTHFileLookup - This internal data structure is used by the PTHManager /// to map from FileEntry objects managed by FileManager to offsets within /// the PTH file. namespace { class VISIBILITY_HIDDEN PTHFileLookup { public: class Val { uint32_t v; public: Val() : v(~0) {} Val(uint32_t x) : v(x) {} operator uint32_t() const { assert(v != ~((uint32_t)0) && "PTHFileLookup entry initialized."); return v; } Val& operator=(uint32_t x) { v = x; return *this; } bool isValid() const { return v != ~((uint32_t)0); } }; private: llvm::StringMap FileMap; public: PTHFileLookup() {}; Val Lookup(const FileEntry* FE) { const char* s = FE->getName(); unsigned size = strlen(s); return FileMap.GetOrCreateValue(s, s+size).getValue(); } void ReadTable(const char* D) { uint32_t N = Read32(D); // Read the length of the table. for ( ; N > 0; --N) { // The rest of the data is the table itself. uint32_t len = Read32(D); const char* s = D; D += len; FileMap.GetOrCreateValue(s, s+len).getValue() = Read32(D); } } }; } // end anonymous namespace //===----------------------------------------------------------------------===// // PTHManager methods. //===----------------------------------------------------------------------===// PTHManager::PTHManager(const llvm::MemoryBuffer* buf, void* fileLookup, const char* idDataTable, void* perIDCache, Preprocessor& pp) : Buf(buf), PerIDCache(perIDCache), FileLookup(fileLookup), IdDataTable(idDataTable), ITable(pp.getIdentifierTable()), PP(pp) {} PTHManager::~PTHManager() { delete Buf; delete (PTHFileLookup*) FileLookup; free(PerIDCache); } PTHManager* PTHManager::Create(const std::string& file, Preprocessor& PP) { // Memory map the PTH file. llvm::OwningPtr File(llvm::MemoryBuffer::getFile(file.c_str())); if (!File) return 0; // Get the buffer ranges and check if there are at least three 32-bit // words at the end of the file. const char* BufBeg = File->getBufferStart(); const char* BufEnd = File->getBufferEnd(); if(!(BufEnd > BufBeg + sizeof(uint32_t)*3)) { assert(false && "Invalid PTH file."); return 0; // FIXME: Proper error diagnostic? } // Compute the address of the index table at the end of the PTH file. // This table contains the offset of the file lookup table, the // persistent ID -> identifer data table. const char* EndTable = BufEnd - sizeof(uint32_t)*3; // Construct the file lookup table. This will be used for mapping from // FileEntry*'s to cached tokens. const char* FileTableOffset = EndTable + sizeof(uint32_t)*2; const char* FileTable = BufBeg + Read32(FileTableOffset); if (!(FileTable > BufBeg && FileTable < BufEnd)) { assert(false && "Invalid PTH file."); return 0; // FIXME: Proper error diagnostic? } llvm::OwningPtr FL(new PTHFileLookup()); FL->ReadTable(FileTable); // Get the location of the table mapping from persistent ids to the // data needed to reconstruct identifiers. const char* IDTableOffset = EndTable + sizeof(uint32_t)*1; const char* IData = BufBeg + Read32(IDTableOffset); if (!(IData > BufBeg && IData < BufEnd)) { assert(false && "Invalid PTH file."); return 0; // FIXME: Proper error diagnostic? } // Get the number of IdentifierInfos and pre-allocate the identifier cache. uint32_t NumIds = Read32(IData); // Pre-allocate the peristent ID -> IdentifierInfo* cache. We use calloc() // so that we in the best case only zero out memory once when the OS returns // us new pages. IdentifierInfo** PerIDCache = (IdentifierInfo**) calloc(NumIds, sizeof(*PerIDCache)); if (!PerIDCache) { assert(false && "Could not allocate Persistent ID cache."); return 0; } // Create the new lexer. return new PTHManager(File.take(), FL.take(), IData, PerIDCache, PP); } IdentifierInfo* PTHManager::ReadIdentifierInfo(const char*& D) { // Read the persistent ID from the PTH file. uint32_t persistentID = Read32(D); // A persistent ID of '0' always maps to NULL. if (!persistentID) return 0; // Adjust the persistent ID by subtracting '1' so that it can be used // as an index within a table in the PTH file. --persistentID; // Check if the IdentifierInfo has already been resolved. IdentifierInfo*& II = ((IdentifierInfo**) PerIDCache)[persistentID]; if (II) return II; // Look in the PTH file for the string data for the IdentifierInfo object. const char* TableEntry = IdDataTable + sizeof(uint32_t) * persistentID; const char* IDData = Buf->getBufferStart() + Read32(TableEntry); assert(IDData < Buf->getBufferEnd()); // Read the length of the string. uint32_t len = Read32(IDData); // Get the IdentifierInfo* with the specified string. II = &ITable.get(IDData, IDData+len); return II; } PTHLexer* PTHManager::CreateLexer(unsigned FileID, const FileEntry* FE) { if (!FE) return 0; // Lookup the FileEntry object in our file lookup data structure. It will // return a variant that indicates whether or not there is an offset within // the PTH file that contains cached tokens. PTHFileLookup::Val Off = ((PTHFileLookup*) FileLookup)->Lookup(FE); if (!Off.isValid()) // No tokens available. return 0; // Compute the offset of the token data within the buffer. const char* data = Buf->getBufferStart() + Off; assert(data < Buf->getBufferEnd()); return new PTHLexer(PP, SourceLocation::getFileLoc(FileID, 0), data, *this); }