Basic/SourceManager.cpp - fp2-dev/platform/external/clang - Gitiles

 //===--- SourceManager.cpp - Track and cache source files -----------------===//
 //
 //                     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 SourceManager interface.
 //
 //===----------------------------------------------------------------------===//

 #include "clang/Basic/SourceManager.h"
 #include "clang/Basic/FileManager.h"
 #include "llvm/Config/config.h"
 #include "llvm/Support/Compiler.h"
 #include "llvm/Support/MemoryBuffer.h"
 #include "llvm/System/Path.h"
 #include "llvm/Bitcode/Serialize.h"
 #include "llvm/Bitcode/Deserialize.h"
 #include "llvm/Support/Streams.h"
 #include <algorithm>
 #include <fcntl.h>
 using namespace clang;
 using namespace SrcMgr;
 using llvm::MemoryBuffer;

 ContentCache::~ContentCache() {
   delete Buffer;
   delete [] SourceLineCache;
 }

 // FIXME: REMOVE THESE
 #include <unistd.h>
 #include <sys/types.h>
 #if !defined(_MSC_VER) && !defined(__MINGW32__)
 #include <sys/uio.h>
 #include <sys/fcntl.h>
 #else
 #include <io.h>
 #endif
 #include <cerrno>

 static const MemoryBuffer *ReadFileFast(const FileEntry *FileEnt) {
 #if 0
   // FIXME: Reintroduce this and zap this function once the common llvm stuff
   // is fast for the small case.
   return MemoryBuffer::getFile(FileEnt->getName(), strlen(FileEnt->getName()),
                                FileEnt->getSize());
 #endif

   // If the file is larger than some threshold, use 'read', otherwise use mmap.
   if (FileEnt->getSize() >= 4096*4)
     return MemoryBuffer::getFile(FileEnt->getName(), strlen(FileEnt->getName()),
                                  0, FileEnt->getSize());

   MemoryBuffer *SB = MemoryBuffer::getNewUninitMemBuffer(FileEnt->getSize(),
                                                          FileEnt->getName());
   char *BufPtr = const_cast<char*>(SB->getBufferStart());

 #if defined(LLVM_ON_WIN32)
   int FD = ::open(FileEnt->getName(), O_RDONLY|O_BINARY);
 #else
   int FD = ::open(FileEnt->getName(), O_RDONLY);
 #endif
   if (FD == -1) {
     delete SB;
     return 0;
   }

   unsigned BytesLeft = FileEnt->getSize();
   while (BytesLeft) {
     ssize_t NumRead = ::read(FD, BufPtr, BytesLeft);
     if (NumRead != -1) {
       BytesLeft -= NumRead;
       BufPtr += NumRead;
     } else if (errno == EINTR) {
       // try again
     } else {
       // error reading.
       close(FD);
       delete SB;
       return 0;
     }
   }
   close(FD);

   return SB;
 }


 /// getFileInfo - Create or return a cached FileInfo for the specified file.
 ///
 const ContentCache* SourceManager::getContentCache(const FileEntry *FileEnt) {

   assert(FileEnt && "Didn't specify a file entry to use?");
   // Do we already have information about this file?
   std::set<ContentCache>::iterator I =
     FileInfos.lower_bound(ContentCache(FileEnt));

   if (I != FileInfos.end() && I->Entry == FileEnt)
     return &*I;

   // Nope, get information.
   const MemoryBuffer *File = ReadFileFast(FileEnt);
   if (File == 0)
     return 0;

   ContentCache& Entry = const_cast<ContentCache&>(*FileInfos.insert(I,FileEnt));

   Entry.Buffer = File;
   Entry.SourceLineCache = 0;
   Entry.NumLines = 0;
   return &Entry;
 }


 /// createMemBufferContentCache - Create a new ContentCache for the specified
 ///  memory buffer.  This does no caching.
 const ContentCache*
 SourceManager::createMemBufferContentCache(const MemoryBuffer *Buffer) {
   // Add a new ContentCache to the MemBufferInfos list and return it.  We
   // must default construct the object first that the instance actually
   // stored within MemBufferInfos actually owns the Buffer, and not any
   // temporary we would use in the call to "push_back".
   MemBufferInfos.push_back(ContentCache());
   ContentCache& Entry = const_cast<ContentCache&>(MemBufferInfos.back());
   Entry.Buffer = Buffer;
   return &Entry;
 }


 /// createFileID - Create a new fileID for the specified ContentCache and
 /// include position.  This works regardless of whether the ContentCache
 /// corresponds to a file or some other input source.
 unsigned SourceManager::createFileID(const ContentCache *File,
                                      SourceLocation IncludePos) {
   // If FileEnt is really large (e.g. it's a large .i file), we may not be able
   // to fit an arbitrary position in the file in the FilePos field.  To handle
   // this, we create one FileID for each chunk of the file that fits in a
   // FilePos field.
   unsigned FileSize = File->Buffer->getBufferSize();
   if (FileSize+1 < (1 << SourceLocation::FilePosBits)) {
     FileIDs.push_back(FileIDInfo::get(IncludePos, 0, File));
     assert(FileIDs.size() < (1 << SourceLocation::FileIDBits) &&
            "Ran out of file ID's!");
     return FileIDs.size();
   }

   // Create one FileID for each chunk of the file.
   unsigned Result = FileIDs.size()+1;

   unsigned ChunkNo = 0;
   while (1) {
     FileIDs.push_back(FileIDInfo::get(IncludePos, ChunkNo++, File));

     if (FileSize+1 < (1 << SourceLocation::FilePosBits)) break;
     FileSize -= (1 << SourceLocation::FilePosBits);
   }

   assert(FileIDs.size() < (1 << SourceLocation::FileIDBits) &&
          "Ran out of file ID's!");
   return Result;
 }

 /// getInstantiationLoc - Return a new SourceLocation that encodes the fact
 /// that a token from physloc PhysLoc should actually be referenced from
 /// InstantiationLoc.
 SourceLocation SourceManager::getInstantiationLoc(SourceLocation PhysLoc,
                                                   SourceLocation InstantLoc) {
   // The specified source location may be a mapped location, due to a macro
   // instantiation or #line directive.  Strip off this information to find out
   // where the characters are actually located.
   PhysLoc = getPhysicalLoc(PhysLoc);

   // Resolve InstantLoc down to a real logical location.
   InstantLoc = getLogicalLoc(InstantLoc);


   // If the last macro id is close to the currently requested location, try to
   // reuse it.  This implements a small cache.
   for (int i = MacroIDs.size()-1, e = MacroIDs.size()-6; i >= 0 && i != e; --i){
     MacroIDInfo &LastOne = MacroIDs[i];

     // The instanitation point and source physloc have to exactly match to reuse
     // (for now).  We could allow "nearby" instantiations in the future.
     if (LastOne.getVirtualLoc() != InstantLoc ||
         LastOne.getPhysicalLoc().getFileID() != PhysLoc.getFileID())
       continue;

     // Check to see if the physloc of the token came from near enough to reuse.
     int PhysDelta = PhysLoc.getRawFilePos() -
                     LastOne.getPhysicalLoc().getRawFilePos();
     if (SourceLocation::isValidMacroPhysOffs(PhysDelta))
       return SourceLocation::getMacroLoc(i, PhysDelta, false, false);
   }


   MacroIDs.push_back(MacroIDInfo::get(InstantLoc, PhysLoc));
   return SourceLocation::getMacroLoc(MacroIDs.size()-1, 0, false, false);
 }

 /// getBufferData - Return a pointer to the start and end of the character
 /// data for the specified FileID.
 std::pair<const char*, const char*>
 SourceManager::getBufferData(unsigned FileID) const {
   const llvm::MemoryBuffer *Buf = getBuffer(FileID);
   return std::make_pair(Buf->getBufferStart(), Buf->getBufferEnd());
 }


 /// getCharacterData - Return a pointer to the start of the specified location
 /// in the appropriate MemoryBuffer.
 const char *SourceManager::getCharacterData(SourceLocation SL) const {
   // Note that this is a hot function in the getSpelling() path, which is
   // heavily used by -E mode.
   SL = getPhysicalLoc(SL);

   return getContentCache(SL.getFileID())->Buffer->getBufferStart() +
          getFullFilePos(SL);
 }


 /// getColumnNumber - Return the column # for the specified file position.
 /// this is significantly cheaper to compute than the line number.  This returns
 /// zero if the column number isn't known.
 unsigned SourceManager::getColumnNumber(SourceLocation Loc) const {
   unsigned FileID = Loc.getFileID();
   if (FileID == 0) return 0;

   unsigned FilePos = getFullFilePos(Loc);
   const MemoryBuffer *Buffer = getBuffer(FileID);
   const char *Buf = Buffer->getBufferStart();

   unsigned LineStart = FilePos;
   while (LineStart && Buf[LineStart-1] != '\n' && Buf[LineStart-1] != '\r')
     --LineStart;
   return FilePos-LineStart+1;
 }

 /// getSourceName - This method returns the name of the file or buffer that
 /// the SourceLocation specifies.  This can be modified with #line directives,
 /// etc.
 const char *SourceManager::getSourceName(SourceLocation Loc) const {
   unsigned FileID = Loc.getFileID();
   if (FileID == 0) return "";
   return getContentCache(FileID)->Buffer->getBufferIdentifier();
 }

 static void ComputeLineNumbers(ContentCache* FI) DISABLE_INLINE;
 static void ComputeLineNumbers(ContentCache* FI) {
   const MemoryBuffer *Buffer = FI->Buffer;

   // Find the file offsets of all of the *physical* source lines.  This does
   // not look at trigraphs, escaped newlines, or anything else tricky.
   std::vector<unsigned> LineOffsets;

   // Line #1 starts at char 0.
   LineOffsets.push_back(0);

   const unsigned char *Buf = (const unsigned char *)Buffer->getBufferStart();
   const unsigned char *End = (const unsigned char *)Buffer->getBufferEnd();
   unsigned Offs = 0;
   while (1) {
     // Skip over the contents of the line.
     // TODO: Vectorize this?  This is very performance sensitive for programs
     // with lots of diagnostics and in -E mode.
     const unsigned char *NextBuf = (const unsigned char *)Buf;
     while (*NextBuf != '\n' && *NextBuf != '\r' && *NextBuf != '\0')
       ++NextBuf;
     Offs += NextBuf-Buf;
     Buf = NextBuf;

     if (Buf[0] == '\n' || Buf[0] == '\r') {
       // If this is \n\r or \r\n, skip both characters.
       if ((Buf[1] == '\n' || Buf[1] == '\r') && Buf[0] != Buf[1])
         ++Offs, ++Buf;
       ++Offs, ++Buf;
       LineOffsets.push_back(Offs);
     } else {
       // Otherwise, this is a null.  If end of file, exit.
       if (Buf == End) break;
       // Otherwise, skip the null.
       ++Offs, ++Buf;
     }
   }
   LineOffsets.push_back(Offs);

   // Copy the offsets into the FileInfo structure.
   FI->NumLines = LineOffsets.size();
   FI->SourceLineCache = new unsigned[LineOffsets.size()];
   std::copy(LineOffsets.begin(), LineOffsets.end(), FI->SourceLineCache);
 }

 /// getLineNumber - Given a SourceLocation, return the physical line number
 /// for the position indicated.  This requires building and caching a table of
 /// line offsets for the MemoryBuffer, so this is not cheap: use only when
 /// about to emit a diagnostic.
 unsigned SourceManager::getLineNumber(SourceLocation Loc) {
   unsigned FileID = Loc.getFileID();
   if (FileID == 0) return 0;

   ContentCache* Content;

   if (LastLineNoFileIDQuery == FileID)
     Content = LastLineNoContentCache;
   else
     Content = const_cast<ContentCache*>(getContentCache(FileID));

   // If this is the first use of line information for this buffer, compute the
   /// SourceLineCache for it on demand.
   if (Content->SourceLineCache == 0)
     ComputeLineNumbers(Content);

   // Okay, we know we have a line number table.  Do a binary search to find the
   // line number that this character position lands on.
   unsigned *SourceLineCache = Content->SourceLineCache;
   unsigned *SourceLineCacheStart = SourceLineCache;
   unsigned *SourceLineCacheEnd = SourceLineCache + Content->NumLines;

   unsigned QueriedFilePos = getFullFilePos(Loc)+1;

   // If the previous query was to the same file, we know both the file pos from
   // that query and the line number returned.  This allows us to narrow the
   // search space from the entire file to something near the match.
   if (LastLineNoFileIDQuery == FileID) {
     if (QueriedFilePos >= LastLineNoFilePos) {
       SourceLineCache = SourceLineCache+LastLineNoResult-1;

       // The query is likely to be nearby the previous one.  Here we check to
       // see if it is within 5, 10 or 20 lines.  It can be far away in cases
       // where big comment blocks and vertical whitespace eat up lines but
       // contribute no tokens.
       if (SourceLineCache+5 < SourceLineCacheEnd) {
         if (SourceLineCache[5] > QueriedFilePos)
           SourceLineCacheEnd = SourceLineCache+5;
         else if (SourceLineCache+10 < SourceLineCacheEnd) {
           if (SourceLineCache[10] > QueriedFilePos)
             SourceLineCacheEnd = SourceLineCache+10;
           else if (SourceLineCache+20 < SourceLineCacheEnd) {
             if (SourceLineCache[20] > QueriedFilePos)
               SourceLineCacheEnd = SourceLineCache+20;
           }
         }
       }
     } else {
       SourceLineCacheEnd = SourceLineCache+LastLineNoResult+1;
     }
   }

   // If the spread is large, do a "radix" test as our initial guess, based on
   // the assumption that lines average to approximately the same length.
   // NOTE: This is currently disabled, as it does not appear to be profitable in
   // initial measurements.
   if (0 && SourceLineCacheEnd-SourceLineCache > 20) {
     unsigned FileLen = Content->SourceLineCache[Content->NumLines-1];

     // Take a stab at guessing where it is.
     unsigned ApproxPos = Content->NumLines*QueriedFilePos / FileLen;

     // Check for -10 and +10 lines.
     unsigned LowerBound = std::max(int(ApproxPos-10), 0);
     unsigned UpperBound = std::min(ApproxPos+10, FileLen);

     // If the computed lower bound is less than the query location, move it in.
     if (SourceLineCache < SourceLineCacheStart+LowerBound &&
         SourceLineCacheStart[LowerBound] < QueriedFilePos)
       SourceLineCache = SourceLineCacheStart+LowerBound;

     // If the computed upper bound is greater than the query location, move it.
     if (SourceLineCacheEnd > SourceLineCacheStart+UpperBound &&
         SourceLineCacheStart[UpperBound] >= QueriedFilePos)
       SourceLineCacheEnd = SourceLineCacheStart+UpperBound;
   }

   unsigned *Pos
     = std::lower_bound(SourceLineCache, SourceLineCacheEnd, QueriedFilePos);
   unsigned LineNo = Pos-SourceLineCacheStart;

   LastLineNoFileIDQuery = FileID;
   LastLineNoContentCache = Content;
   LastLineNoFilePos = QueriedFilePos;
   LastLineNoResult = LineNo;
   return LineNo;
 }

 /// PrintStats - Print statistics to stderr.
 ///
 void SourceManager::PrintStats() const {
   llvm::cerr << "\n*** Source Manager Stats:\n";
   llvm::cerr << FileInfos.size() << " files mapped, " << MemBufferInfos.size()
              << " mem buffers mapped, " << FileIDs.size()
              << " file ID's allocated.\n";
   llvm::cerr << "  " << FileIDs.size() << " normal buffer FileID's, "
              << MacroIDs.size() << " macro expansion FileID's.\n";

   unsigned NumLineNumsComputed = 0;
   unsigned NumFileBytesMapped = 0;
   for (std::set<ContentCache>::const_iterator I =
        FileInfos.begin(), E = FileInfos.end(); I != E; ++I) {
     NumLineNumsComputed += I->SourceLineCache != 0;
     NumFileBytesMapped  += I->Buffer->getBufferSize();
   }

   llvm::cerr << NumFileBytesMapped << " bytes of files mapped, "
              << NumLineNumsComputed << " files with line #'s computed.\n";
 }

 //===----------------------------------------------------------------------===//
 // Serialization.
 //===----------------------------------------------------------------------===//

 void ContentCache::Emit(llvm::Serializer& S) const {
   S.FlushRecord();
   S.EmitPtr(this);

   if (Entry) {
     llvm::sys::Path Fname(Buffer->getBufferIdentifier());

     if (Fname.isAbsolute())
       S.EmitCStr(Fname.c_str());
     else {
       // Create an absolute path.
       // FIXME: This will potentially contain ".." and "." in the path.
       llvm::sys::Path path = llvm::sys::Path::GetCurrentDirectory();
       path.appendComponent(Fname.c_str());
       S.EmitCStr(path.c_str());
     }
   }
   else {
     const char* p = Buffer->getBufferStart();
     const char* e = Buffer->getBufferEnd();

     S.EmitInt(e-p);

     for ( ; p != e; ++p)
       S.EmitInt(*p);
   }

   S.FlushRecord();
 }

 void ContentCache::ReadToSourceManager(llvm::Deserializer& D,
                                        SourceManager& SMgr,
                                        FileManager* FMgr,
                                        std::vector<char>& Buf) {
   if (FMgr) {
     llvm::SerializedPtrID PtrID = D.ReadPtrID();
     D.ReadCStr(Buf,false);

     // Create/fetch the FileEntry.
     const char* start = &Buf[0];
     const FileEntry* E = FMgr->getFile(start,start+Buf.size());

     // FIXME: Ideally we want a lazy materialization of the ContentCache
     //  anyway, because we don't want to read in source files unless this
     //  is absolutely needed.
     if (!E)
       D.RegisterPtr(PtrID,NULL);
     else
       // Get the ContextCache object and register it with the deserializer.
       D.RegisterPtr(PtrID,SMgr.getContentCache(E));
   }
   else {
     // Register the ContextCache object with the deserializer.
     SMgr.MemBufferInfos.push_back(ContentCache());
     ContentCache& Entry = const_cast<ContentCache&>(SMgr.MemBufferInfos.back());
     D.RegisterPtr(&Entry);

     // Create the buffer.
     unsigned Size = D.ReadInt();
     Entry.Buffer = MemoryBuffer::getNewUninitMemBuffer(Size);

     // Read the contents of the buffer.
     char* p = const_cast<char*>(Entry.Buffer->getBufferStart());
     for (unsigned i = 0; i < Size ; ++i)
       p[i] = D.ReadInt();
   }
 }

 void FileIDInfo::Emit(llvm::Serializer& S) const {
   S.Emit(IncludeLoc);
   S.EmitInt(ChunkNo);
   S.EmitPtr(Content);
 }

 FileIDInfo FileIDInfo::ReadVal(llvm::Deserializer& D) {
   FileIDInfo I;
   I.IncludeLoc = SourceLocation::ReadVal(D);
   I.ChunkNo = D.ReadInt();
   D.ReadPtr(I.Content,false);
   return I;
 }

 void MacroIDInfo::Emit(llvm::Serializer& S) const {
   S.Emit(VirtualLoc);
   S.Emit(PhysicalLoc);
 }

 MacroIDInfo MacroIDInfo::ReadVal(llvm::Deserializer& D) {
   MacroIDInfo I;
   I.VirtualLoc = SourceLocation::ReadVal(D);
   I.PhysicalLoc = SourceLocation::ReadVal(D);
   return I;
 }

 void SourceManager::Emit(llvm::Serializer& S) const {
   S.EnterBlock();
   S.EmitPtr(this);
   S.EmitInt(MainFileID);

   // Emit: FileInfos.  Just emit the file name.
   S.EnterBlock();

   std::for_each(FileInfos.begin(),FileInfos.end(),
                 S.MakeEmitter<ContentCache>());

   S.ExitBlock();

   // Emit: MemBufferInfos
   S.EnterBlock();

   std::for_each(MemBufferInfos.begin(), MemBufferInfos.end(),
                 S.MakeEmitter<ContentCache>());

   S.ExitBlock();

   // Emit: FileIDs
   S.EmitInt(FileIDs.size());
   std::for_each(FileIDs.begin(), FileIDs.end(), S.MakeEmitter<FileIDInfo>());

   // Emit: MacroIDs
   S.EmitInt(MacroIDs.size());
   std::for_each(MacroIDs.begin(), MacroIDs.end(), S.MakeEmitter<MacroIDInfo>());

   S.ExitBlock();
 }

 SourceManager*
 SourceManager::CreateAndRegister(llvm::Deserializer& D, FileManager& FMgr){
   SourceManager *M = new SourceManager();
   D.RegisterPtr(M);

   // Read: the FileID of the main source file of the translation unit.
   M->MainFileID = D.ReadInt();

   std::vector<char> Buf;

   { // Read: FileInfos.
     llvm::Deserializer::Location BLoc = D.getCurrentBlockLocation();
     while (!D.FinishedBlock(BLoc))
     ContentCache::ReadToSourceManager(D,*M,&FMgr,Buf);
   }

   { // Read: MemBufferInfos.
     llvm::Deserializer::Location BLoc = D.getCurrentBlockLocation();
     while (!D.FinishedBlock(BLoc))
     ContentCache::ReadToSourceManager(D,*M,NULL,Buf);
   }

   // Read: FileIDs.
   unsigned Size = D.ReadInt();
   M->FileIDs.reserve(Size);
   for (; Size > 0 ; --Size)
     M->FileIDs.push_back(FileIDInfo::ReadVal(D));

   // Read: MacroIDs.
   Size = D.ReadInt();
   M->MacroIDs.reserve(Size);
   for (; Size > 0 ; --Size)
     M->MacroIDs.push_back(MacroIDInfo::ReadVal(D));

   return M;
 }
	//===--- SourceManager.cpp - Track and cache source files -----------------===//
	//
	// 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 SourceManager interface.
	//
	//===----------------------------------------------------------------------===//

	#include "clang/Basic/SourceManager.h"
	#include "clang/Basic/FileManager.h"
	#include "llvm/Config/config.h"
	#include "llvm/Support/Compiler.h"
	#include "llvm/Support/MemoryBuffer.h"
	#include "llvm/System/Path.h"
	#include "llvm/Bitcode/Serialize.h"
	#include "llvm/Bitcode/Deserialize.h"
	#include "llvm/Support/Streams.h"
	#include <algorithm>
	#include <fcntl.h>
	using namespace clang;
	using namespace SrcMgr;
	using llvm::MemoryBuffer;

	ContentCache::~ContentCache() {
	delete Buffer;
	delete [] SourceLineCache;
	}

	// FIXME: REMOVE THESE
	#include <unistd.h>
	#include <sys/types.h>
	#if !defined(_MSC_VER) && !defined(__MINGW32__)
	#include <sys/uio.h>
	#include <sys/fcntl.h>
	#else
	#include <io.h>
	#endif
	#include <cerrno>

	static const MemoryBuffer ReadFileFast(const FileEntry FileEnt) {
	#if 0
	// FIXME: Reintroduce this and zap this function once the common llvm stuff
	// is fast for the small case.
	return MemoryBuffer::getFile(FileEnt->getName(), strlen(FileEnt->getName()),
	FileEnt->getSize());
	#endif

	// If the file is larger than some threshold, use 'read', otherwise use mmap.
	if (FileEnt->getSize() >= 4096*4)
	return MemoryBuffer::getFile(FileEnt->getName(), strlen(FileEnt->getName()),
	0, FileEnt->getSize());

	MemoryBuffer *SB = MemoryBuffer::getNewUninitMemBuffer(FileEnt->getSize(),
	FileEnt->getName());
	char BufPtr = const_cast<char>(SB->getBufferStart());

	#if defined(LLVM_ON_WIN32)
	int FD = ::open(FileEnt->getName(), O_RDONLY\|O_BINARY);
	#else
	int FD = ::open(FileEnt->getName(), O_RDONLY);
	#endif
	if (FD == -1) {
	delete SB;
	return 0;
	}

	unsigned BytesLeft = FileEnt->getSize();
	while (BytesLeft) {
	ssize_t NumRead = ::read(FD, BufPtr, BytesLeft);
	if (NumRead != -1) {
	BytesLeft -= NumRead;
	BufPtr += NumRead;
	} else if (errno == EINTR) {
	// try again
	} else {
	// error reading.
	close(FD);
	delete SB;
	return 0;
	}
	}
	close(FD);

	return SB;
	}


	/// getFileInfo - Create or return a cached FileInfo for the specified file.
	///
	const ContentCache* SourceManager::getContentCache(const FileEntry *FileEnt) {

	assert(FileEnt && "Didn't specify a file entry to use?");
	// Do we already have information about this file?
	std::set<ContentCache>::iterator I =
	FileInfos.lower_bound(ContentCache(FileEnt));

	if (I != FileInfos.end() && I->Entry == FileEnt)
	return &*I;

	// Nope, get information.
	const MemoryBuffer *File = ReadFileFast(FileEnt);
	if (File == 0)
	return 0;

	ContentCache& Entry = const_cast<ContentCache&>(*FileInfos.insert(I,FileEnt));

	Entry.Buffer = File;
	Entry.SourceLineCache = 0;
	Entry.NumLines = 0;
	return &Entry;
	}


	/// createMemBufferContentCache - Create a new ContentCache for the specified
	/// memory buffer. This does no caching.
	const ContentCache*
	SourceManager::createMemBufferContentCache(const MemoryBuffer *Buffer) {
	// Add a new ContentCache to the MemBufferInfos list and return it. We
	// must default construct the object first that the instance actually
	// stored within MemBufferInfos actually owns the Buffer, and not any
	// temporary we would use in the call to "push_back".
	MemBufferInfos.push_back(ContentCache());
	ContentCache& Entry = const_cast<ContentCache&>(MemBufferInfos.back());
	Entry.Buffer = Buffer;
	return &Entry;
	}


	/// createFileID - Create a new fileID for the specified ContentCache and
	/// include position. This works regardless of whether the ContentCache
	/// corresponds to a file or some other input source.
	unsigned SourceManager::createFileID(const ContentCache *File,
	SourceLocation IncludePos) {
	// If FileEnt is really large (e.g. it's a large .i file), we may not be able
	// to fit an arbitrary position in the file in the FilePos field. To handle
	// this, we create one FileID for each chunk of the file that fits in a
	// FilePos field.
	unsigned FileSize = File->Buffer->getBufferSize();
	if (FileSize+1 < (1 << SourceLocation::FilePosBits)) {
	FileIDs.push_back(FileIDInfo::get(IncludePos, 0, File));
	assert(FileIDs.size() < (1 << SourceLocation::FileIDBits) &&
	"Ran out of file ID's!");
	return FileIDs.size();
	}

	// Create one FileID for each chunk of the file.
	unsigned Result = FileIDs.size()+1;

	unsigned ChunkNo = 0;
	while (1) {
	FileIDs.push_back(FileIDInfo::get(IncludePos, ChunkNo++, File));

	if (FileSize+1 < (1 << SourceLocation::FilePosBits)) break;
	FileSize -= (1 << SourceLocation::FilePosBits);
	}

	assert(FileIDs.size() < (1 << SourceLocation::FileIDBits) &&
	"Ran out of file ID's!");
	return Result;
	}

	/// getInstantiationLoc - Return a new SourceLocation that encodes the fact
	/// that a token from physloc PhysLoc should actually be referenced from
	/// InstantiationLoc.
	SourceLocation SourceManager::getInstantiationLoc(SourceLocation PhysLoc,
	SourceLocation InstantLoc) {
	// The specified source location may be a mapped location, due to a macro
	// instantiation or #line directive. Strip off this information to find out
	// where the characters are actually located.
	PhysLoc = getPhysicalLoc(PhysLoc);

	// Resolve InstantLoc down to a real logical location.
	InstantLoc = getLogicalLoc(InstantLoc);


	// If the last macro id is close to the currently requested location, try to
	// reuse it. This implements a small cache.
	for (int i = MacroIDs.size()-1, e = MacroIDs.size()-6; i >= 0 && i != e; --i){
	MacroIDInfo &LastOne = MacroIDs[i];

	// The instanitation point and source physloc have to exactly match to reuse
	// (for now). We could allow "nearby" instantiations in the future.
	if (LastOne.getVirtualLoc() != InstantLoc \|\|
	LastOne.getPhysicalLoc().getFileID() != PhysLoc.getFileID())
	continue;

	// Check to see if the physloc of the token came from near enough to reuse.
	int PhysDelta = PhysLoc.getRawFilePos() -
	LastOne.getPhysicalLoc().getRawFilePos();
	if (SourceLocation::isValidMacroPhysOffs(PhysDelta))
	return SourceLocation::getMacroLoc(i, PhysDelta, false, false);
	}


	MacroIDs.push_back(MacroIDInfo::get(InstantLoc, PhysLoc));
	return SourceLocation::getMacroLoc(MacroIDs.size()-1, 0, false, false);
	}

	/// getBufferData - Return a pointer to the start and end of the character
	/// data for the specified FileID.
	std::pair<const char, const char>
	SourceManager::getBufferData(unsigned FileID) const {
	const llvm::MemoryBuffer *Buf = getBuffer(FileID);
	return std::make_pair(Buf->getBufferStart(), Buf->getBufferEnd());
	}


	/// getCharacterData - Return a pointer to the start of the specified location
	/// in the appropriate MemoryBuffer.
	const char *SourceManager::getCharacterData(SourceLocation SL) const {
	// Note that this is a hot function in the getSpelling() path, which is
	// heavily used by -E mode.
	SL = getPhysicalLoc(SL);

	return getContentCache(SL.getFileID())->Buffer->getBufferStart() +
	getFullFilePos(SL);
	}


	/// getColumnNumber - Return the column # for the specified file position.
	/// this is significantly cheaper to compute than the line number. This returns
	/// zero if the column number isn't known.
	unsigned SourceManager::getColumnNumber(SourceLocation Loc) const {
	unsigned FileID = Loc.getFileID();
	if (FileID == 0) return 0;

	unsigned FilePos = getFullFilePos(Loc);
	const MemoryBuffer *Buffer = getBuffer(FileID);
	const char *Buf = Buffer->getBufferStart();

	unsigned LineStart = FilePos;
	while (LineStart && Buf[LineStart-1] != '\n' && Buf[LineStart-1] != '\r')
	--LineStart;
	return FilePos-LineStart+1;
	}

	/// getSourceName - This method returns the name of the file or buffer that
	/// the SourceLocation specifies. This can be modified with #line directives,
	/// etc.
	const char *SourceManager::getSourceName(SourceLocation Loc) const {
	unsigned FileID = Loc.getFileID();
	if (FileID == 0) return "";
	return getContentCache(FileID)->Buffer->getBufferIdentifier();
	}

	static void ComputeLineNumbers(ContentCache* FI) DISABLE_INLINE;
	static void ComputeLineNumbers(ContentCache* FI) {
	const MemoryBuffer *Buffer = FI->Buffer;

	// Find the file offsets of all of the physical source lines. This does
	// not look at trigraphs, escaped newlines, or anything else tricky.
	std::vector<unsigned> LineOffsets;

	// Line #1 starts at char 0.
	LineOffsets.push_back(0);

	const unsigned char Buf = (const unsigned char )Buffer->getBufferStart();
	const unsigned char End = (const unsigned char )Buffer->getBufferEnd();
	unsigned Offs = 0;
	while (1) {
	// Skip over the contents of the line.
	// TODO: Vectorize this? This is very performance sensitive for programs
	// with lots of diagnostics and in -E mode.
	const unsigned char NextBuf = (const unsigned char )Buf;
	while (NextBuf != '\n' && NextBuf != '\r' && *NextBuf != '\0')
	++NextBuf;
	Offs += NextBuf-Buf;
	Buf = NextBuf;

	if (Buf[0] == '\n' \|\| Buf[0] == '\r') {
	// If this is \n\r or \r\n, skip both characters.
	if ((Buf[1] == '\n' \|\| Buf[1] == '\r') && Buf[0] != Buf[1])
	++Offs, ++Buf;
	++Offs, ++Buf;
	LineOffsets.push_back(Offs);
	} else {
	// Otherwise, this is a null. If end of file, exit.
	if (Buf == End) break;
	// Otherwise, skip the null.
	++Offs, ++Buf;
	}
	}
	LineOffsets.push_back(Offs);

	// Copy the offsets into the FileInfo structure.
	FI->NumLines = LineOffsets.size();
	FI->SourceLineCache = new unsigned[LineOffsets.size()];
	std::copy(LineOffsets.begin(), LineOffsets.end(), FI->SourceLineCache);
	}

	/// getLineNumber - Given a SourceLocation, return the physical line number
	/// for the position indicated. This requires building and caching a table of
	/// line offsets for the MemoryBuffer, so this is not cheap: use only when
	/// about to emit a diagnostic.
	unsigned SourceManager::getLineNumber(SourceLocation Loc) {
	unsigned FileID = Loc.getFileID();
	if (FileID == 0) return 0;

	ContentCache* Content;

	if (LastLineNoFileIDQuery == FileID)
	Content = LastLineNoContentCache;
	else
	Content = const_cast<ContentCache*>(getContentCache(FileID));

	// If this is the first use of line information for this buffer, compute the
	/// SourceLineCache for it on demand.
	if (Content->SourceLineCache == 0)
	ComputeLineNumbers(Content);

	// Okay, we know we have a line number table. Do a binary search to find the
	// line number that this character position lands on.
	unsigned *SourceLineCache = Content->SourceLineCache;
	unsigned *SourceLineCacheStart = SourceLineCache;
	unsigned *SourceLineCacheEnd = SourceLineCache + Content->NumLines;

	unsigned QueriedFilePos = getFullFilePos(Loc)+1;

	// If the previous query was to the same file, we know both the file pos from
	// that query and the line number returned. This allows us to narrow the
	// search space from the entire file to something near the match.
	if (LastLineNoFileIDQuery == FileID) {
	if (QueriedFilePos >= LastLineNoFilePos) {
	SourceLineCache = SourceLineCache+LastLineNoResult-1;

	// The query is likely to be nearby the previous one. Here we check to
	// see if it is within 5, 10 or 20 lines. It can be far away in cases
	// where big comment blocks and vertical whitespace eat up lines but
	// contribute no tokens.
	if (SourceLineCache+5 < SourceLineCacheEnd) {
	if (SourceLineCache[5] > QueriedFilePos)
	SourceLineCacheEnd = SourceLineCache+5;
	else if (SourceLineCache+10 < SourceLineCacheEnd) {
	if (SourceLineCache[10] > QueriedFilePos)
	SourceLineCacheEnd = SourceLineCache+10;
	else if (SourceLineCache+20 < SourceLineCacheEnd) {
	if (SourceLineCache[20] > QueriedFilePos)
	SourceLineCacheEnd = SourceLineCache+20;
	}
	}
	}
	} else {
	SourceLineCacheEnd = SourceLineCache+LastLineNoResult+1;
	}
	}

	// If the spread is large, do a "radix" test as our initial guess, based on
	// the assumption that lines average to approximately the same length.
	// NOTE: This is currently disabled, as it does not appear to be profitable in
	// initial measurements.
	if (0 && SourceLineCacheEnd-SourceLineCache > 20) {
	unsigned FileLen = Content->SourceLineCache[Content->NumLines-1];

	// Take a stab at guessing where it is.
	unsigned ApproxPos = Content->NumLines*QueriedFilePos / FileLen;

	// Check for -10 and +10 lines.
	unsigned LowerBound = std::max(int(ApproxPos-10), 0);
	unsigned UpperBound = std::min(ApproxPos+10, FileLen);

	// If the computed lower bound is less than the query location, move it in.
	if (SourceLineCache < SourceLineCacheStart+LowerBound &&
	SourceLineCacheStart[LowerBound] < QueriedFilePos)
	SourceLineCache = SourceLineCacheStart+LowerBound;

	// If the computed upper bound is greater than the query location, move it.
	if (SourceLineCacheEnd > SourceLineCacheStart+UpperBound &&
	SourceLineCacheStart[UpperBound] >= QueriedFilePos)
	SourceLineCacheEnd = SourceLineCacheStart+UpperBound;
	}

	unsigned *Pos
	= std::lower_bound(SourceLineCache, SourceLineCacheEnd, QueriedFilePos);
	unsigned LineNo = Pos-SourceLineCacheStart;

	LastLineNoFileIDQuery = FileID;
	LastLineNoContentCache = Content;
	LastLineNoFilePos = QueriedFilePos;
	LastLineNoResult = LineNo;
	return LineNo;
	}

	/// PrintStats - Print statistics to stderr.
	///
	void SourceManager::PrintStats() const {
	llvm::cerr << "\n*** Source Manager Stats:\n";
	llvm::cerr << FileInfos.size() << " files mapped, " << MemBufferInfos.size()
	<< " mem buffers mapped, " << FileIDs.size()
	<< " file ID's allocated.\n";
	llvm::cerr << " " << FileIDs.size() << " normal buffer FileID's, "
	<< MacroIDs.size() << " macro expansion FileID's.\n";

	unsigned NumLineNumsComputed = 0;
	unsigned NumFileBytesMapped = 0;
	for (std::set<ContentCache>::const_iterator I =
	FileInfos.begin(), E = FileInfos.end(); I != E; ++I) {
	NumLineNumsComputed += I->SourceLineCache != 0;
	NumFileBytesMapped += I->Buffer->getBufferSize();
	}

	llvm::cerr << NumFileBytesMapped << " bytes of files mapped, "
	<< NumLineNumsComputed << " files with line #'s computed.\n";
	}

	//===----------------------------------------------------------------------===//
	// Serialization.
	//===----------------------------------------------------------------------===//

	void ContentCache::Emit(llvm::Serializer& S) const {
	S.FlushRecord();
	S.EmitPtr(this);

	if (Entry) {
	llvm::sys::Path Fname(Buffer->getBufferIdentifier());

	if (Fname.isAbsolute())
	S.EmitCStr(Fname.c_str());
	else {
	// Create an absolute path.
	// FIXME: This will potentially contain ".." and "." in the path.
	llvm::sys::Path path = llvm::sys::Path::GetCurrentDirectory();
	path.appendComponent(Fname.c_str());
	S.EmitCStr(path.c_str());
	}
	}
	else {
	const char* p = Buffer->getBufferStart();
	const char* e = Buffer->getBufferEnd();

	S.EmitInt(e-p);

	for ( ; p != e; ++p)
	S.EmitInt(*p);
	}

	S.FlushRecord();
	}

	void ContentCache::ReadToSourceManager(llvm::Deserializer& D,
	SourceManager& SMgr,
	FileManager* FMgr,
	std::vector<char>& Buf) {
	if (FMgr) {
	llvm::SerializedPtrID PtrID = D.ReadPtrID();
	D.ReadCStr(Buf,false);

	// Create/fetch the FileEntry.
	const char* start = &Buf[0];
	const FileEntry* E = FMgr->getFile(start,start+Buf.size());

	// FIXME: Ideally we want a lazy materialization of the ContentCache
	// anyway, because we don't want to read in source files unless this
	// is absolutely needed.
	if (!E)
	D.RegisterPtr(PtrID,NULL);
	else
	// Get the ContextCache object and register it with the deserializer.
	D.RegisterPtr(PtrID,SMgr.getContentCache(E));
	}
	else {
	// Register the ContextCache object with the deserializer.
	SMgr.MemBufferInfos.push_back(ContentCache());
	ContentCache& Entry = const_cast<ContentCache&>(SMgr.MemBufferInfos.back());
	D.RegisterPtr(&Entry);

	// Create the buffer.
	unsigned Size = D.ReadInt();
	Entry.Buffer = MemoryBuffer::getNewUninitMemBuffer(Size);

	// Read the contents of the buffer.
	char* p = const_cast<char*>(Entry.Buffer->getBufferStart());
	for (unsigned i = 0; i < Size ; ++i)
	p[i] = D.ReadInt();
	}
	}

	void FileIDInfo::Emit(llvm::Serializer& S) const {
	S.Emit(IncludeLoc);
	S.EmitInt(ChunkNo);
	S.EmitPtr(Content);
	}

	FileIDInfo FileIDInfo::ReadVal(llvm::Deserializer& D) {
	FileIDInfo I;
	I.IncludeLoc = SourceLocation::ReadVal(D);
	I.ChunkNo = D.ReadInt();
	D.ReadPtr(I.Content,false);
	return I;
	}

	void MacroIDInfo::Emit(llvm::Serializer& S) const {
	S.Emit(VirtualLoc);
	S.Emit(PhysicalLoc);
	}

	MacroIDInfo MacroIDInfo::ReadVal(llvm::Deserializer& D) {
	MacroIDInfo I;
	I.VirtualLoc = SourceLocation::ReadVal(D);
	I.PhysicalLoc = SourceLocation::ReadVal(D);
	return I;
	}

	void SourceManager::Emit(llvm::Serializer& S) const {
	S.EnterBlock();
	S.EmitPtr(this);
	S.EmitInt(MainFileID);

	// Emit: FileInfos. Just emit the file name.
	S.EnterBlock();

	std::for_each(FileInfos.begin(),FileInfos.end(),
	S.MakeEmitter<ContentCache>());

	S.ExitBlock();

	// Emit: MemBufferInfos
	S.EnterBlock();

	std::for_each(MemBufferInfos.begin(), MemBufferInfos.end(),
	S.MakeEmitter<ContentCache>());

	S.ExitBlock();

	// Emit: FileIDs
	S.EmitInt(FileIDs.size());
	std::for_each(FileIDs.begin(), FileIDs.end(), S.MakeEmitter<FileIDInfo>());

	// Emit: MacroIDs
	S.EmitInt(MacroIDs.size());
	std::for_each(MacroIDs.begin(), MacroIDs.end(), S.MakeEmitter<MacroIDInfo>());

	S.ExitBlock();
	}

	SourceManager*
	SourceManager::CreateAndRegister(llvm::Deserializer& D, FileManager& FMgr){
	SourceManager *M = new SourceManager();
	D.RegisterPtr(M);

	// Read: the FileID of the main source file of the translation unit.
	M->MainFileID = D.ReadInt();

	std::vector<char> Buf;

	{ // Read: FileInfos.
	llvm::Deserializer::Location BLoc = D.getCurrentBlockLocation();
	while (!D.FinishedBlock(BLoc))
	ContentCache::ReadToSourceManager(D,*M,&FMgr,Buf);
	}

	{ // Read: MemBufferInfos.
	llvm::Deserializer::Location BLoc = D.getCurrentBlockLocation();
	while (!D.FinishedBlock(BLoc))
	ContentCache::ReadToSourceManager(D,*M,NULL,Buf);
	}

	// Read: FileIDs.
	unsigned Size = D.ReadInt();
	M->FileIDs.reserve(Size);
	for (; Size > 0 ; --Size)
	M->FileIDs.push_back(FileIDInfo::ReadVal(D));

	// Read: MacroIDs.
	Size = D.ReadInt();
	M->MacroIDs.reserve(Size);
	for (; Size > 0 ; --Size)
	M->MacroIDs.push_back(MacroIDInfo::ReadVal(D));

	return M;
	}