//===- PDBFile.cpp - Low level interface to a PDB file ----------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "llvm/DebugInfo/PDB/Native/PDBFile.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/STLExtras.h" #include "llvm/DebugInfo/MSF/MSFCommon.h" #include "llvm/DebugInfo/MSF/MappedBlockStream.h" #include "llvm/DebugInfo/PDB/Native/DbiStream.h" #include "llvm/DebugInfo/PDB/Native/GlobalsStream.h" #include "llvm/DebugInfo/PDB/Native/InfoStream.h" #include "llvm/DebugInfo/PDB/Native/InjectedSourceStream.h" #include "llvm/DebugInfo/PDB/Native/PDBStringTable.h" #include "llvm/DebugInfo/PDB/Native/PublicsStream.h" #include "llvm/DebugInfo/PDB/Native/RawError.h" #include "llvm/DebugInfo/PDB/Native/SymbolStream.h" #include "llvm/DebugInfo/PDB/Native/TpiStream.h" #include "llvm/Support/BinaryStream.h" #include "llvm/Support/BinaryStreamArray.h" #include "llvm/Support/BinaryStreamReader.h" #include "llvm/Support/Endian.h" #include "llvm/Support/Error.h" #include "llvm/Support/Path.h" #include #include #include using namespace llvm; using namespace llvm::codeview; using namespace llvm::msf; using namespace llvm::pdb; namespace { typedef FixedStreamArray ulittle_array; } // end anonymous namespace PDBFile::PDBFile(StringRef Path, std::unique_ptr PdbFileBuffer, BumpPtrAllocator &Allocator) : FilePath(std::string(Path)), Allocator(Allocator), Buffer(std::move(PdbFileBuffer)) {} PDBFile::~PDBFile() = default; StringRef PDBFile::getFilePath() const { return FilePath; } StringRef PDBFile::getFileDirectory() const { return sys::path::parent_path(FilePath); } uint32_t PDBFile::getBlockSize() const { return ContainerLayout.SB->BlockSize; } uint32_t PDBFile::getFreeBlockMapBlock() const { return ContainerLayout.SB->FreeBlockMapBlock; } uint32_t PDBFile::getBlockCount() const { return ContainerLayout.SB->NumBlocks; } uint32_t PDBFile::getNumDirectoryBytes() const { return ContainerLayout.SB->NumDirectoryBytes; } uint32_t PDBFile::getBlockMapIndex() const { return ContainerLayout.SB->BlockMapAddr; } uint32_t PDBFile::getUnknown1() const { return ContainerLayout.SB->Unknown1; } uint32_t PDBFile::getNumDirectoryBlocks() const { return msf::bytesToBlocks(ContainerLayout.SB->NumDirectoryBytes, ContainerLayout.SB->BlockSize); } uint64_t PDBFile::getBlockMapOffset() const { return (uint64_t)ContainerLayout.SB->BlockMapAddr * ContainerLayout.SB->BlockSize; } uint32_t PDBFile::getNumStreams() const { return ContainerLayout.StreamSizes.size(); } uint32_t PDBFile::getMaxStreamSize() const { return *std::max_element(ContainerLayout.StreamSizes.begin(), ContainerLayout.StreamSizes.end()); } uint32_t PDBFile::getStreamByteSize(uint32_t StreamIndex) const { return ContainerLayout.StreamSizes[StreamIndex]; } ArrayRef PDBFile::getStreamBlockList(uint32_t StreamIndex) const { return ContainerLayout.StreamMap[StreamIndex]; } uint64_t PDBFile::getFileSize() const { return Buffer->getLength(); } Expected> PDBFile::getBlockData(uint32_t BlockIndex, uint32_t NumBytes) const { uint64_t StreamBlockOffset = msf::blockToOffset(BlockIndex, getBlockSize()); ArrayRef Result; if (auto EC = Buffer->readBytes(StreamBlockOffset, NumBytes, Result)) return std::move(EC); return Result; } Error PDBFile::setBlockData(uint32_t BlockIndex, uint32_t Offset, ArrayRef Data) const { return make_error(raw_error_code::not_writable, "PDBFile is immutable"); } Error PDBFile::parseFileHeaders() { BinaryStreamReader Reader(*Buffer); // Initialize SB. const msf::SuperBlock *SB = nullptr; if (auto EC = Reader.readObject(SB)) { consumeError(std::move(EC)); return make_error(raw_error_code::corrupt_file, "MSF superblock is missing"); } if (auto EC = msf::validateSuperBlock(*SB)) return EC; if (Buffer->getLength() % SB->BlockSize != 0) return make_error(raw_error_code::corrupt_file, "File size is not a multiple of block size"); ContainerLayout.SB = SB; // Initialize Free Page Map. ContainerLayout.FreePageMap.resize(SB->NumBlocks); // The Fpm exists either at block 1 or block 2 of the MSF. However, this // allows for a maximum of getBlockSize() * 8 blocks bits in the Fpm, and // thusly an equal number of total blocks in the file. For a block size // of 4KiB (very common), this would yield 32KiB total blocks in file, for a // maximum file size of 32KiB * 4KiB = 128MiB. Obviously this won't do, so // the Fpm is split across the file at `getBlockSize()` intervals. As a // result, every block whose index is of the form |{1,2} + getBlockSize() * k| // for any non-negative integer k is an Fpm block. In theory, we only really // need to reserve blocks of the form |{1,2} + getBlockSize() * 8 * k|, but // current versions of the MSF format already expect the Fpm to be arranged // at getBlockSize() intervals, so we have to be compatible. // See the function fpmPn() for more information: // https://github.com/Microsoft/microsoft-pdb/blob/master/PDB/msf/msf.cpp#L489 auto FpmStream = MappedBlockStream::createFpmStream(ContainerLayout, *Buffer, Allocator); BinaryStreamReader FpmReader(*FpmStream); ArrayRef FpmBytes; if (auto EC = FpmReader.readBytes(FpmBytes, FpmReader.bytesRemaining())) return EC; uint32_t BlocksRemaining = getBlockCount(); uint32_t BI = 0; for (auto Byte : FpmBytes) { uint32_t BlocksThisByte = std::min(BlocksRemaining, 8U); for (uint32_t I = 0; I < BlocksThisByte; ++I) { if (Byte & (1 << I)) ContainerLayout.FreePageMap[BI] = true; --BlocksRemaining; ++BI; } } Reader.setOffset(getBlockMapOffset()); if (auto EC = Reader.readArray(ContainerLayout.DirectoryBlocks, getNumDirectoryBlocks())) return EC; return Error::success(); } Error PDBFile::parseStreamData() { assert(ContainerLayout.SB); if (DirectoryStream) return Error::success(); uint32_t NumStreams = 0; // Normally you can't use a MappedBlockStream without having fully parsed the // PDB file, because it accesses the directory and various other things, which // is exactly what we are attempting to parse. By specifying a custom // subclass of IPDBStreamData which only accesses the fields that have already // been parsed, we can avoid this and reuse MappedBlockStream. auto DS = MappedBlockStream::createDirectoryStream(ContainerLayout, *Buffer, Allocator); BinaryStreamReader Reader(*DS); if (auto EC = Reader.readInteger(NumStreams)) return EC; if (auto EC = Reader.readArray(ContainerLayout.StreamSizes, NumStreams)) return EC; for (uint32_t I = 0; I < NumStreams; ++I) { uint32_t StreamSize = getStreamByteSize(I); // FIXME: What does StreamSize ~0U mean? uint64_t NumExpectedStreamBlocks = StreamSize == UINT32_MAX ? 0 : msf::bytesToBlocks(StreamSize, ContainerLayout.SB->BlockSize); // For convenience, we store the block array contiguously. This is because // if someone calls setStreamMap(), it is more convenient to be able to call // it with an ArrayRef instead of setting up a StreamRef. Since the // DirectoryStream is cached in the class and thus lives for the life of the // class, we can be guaranteed that readArray() will return a stable // reference, even if it has to allocate from its internal pool. ArrayRef Blocks; if (auto EC = Reader.readArray(Blocks, NumExpectedStreamBlocks)) return EC; for (uint32_t Block : Blocks) { uint64_t BlockEndOffset = (uint64_t)(Block + 1) * ContainerLayout.SB->BlockSize; if (BlockEndOffset > getFileSize()) return make_error(raw_error_code::corrupt_file, "Stream block map is corrupt."); } ContainerLayout.StreamMap.push_back(Blocks); } // We should have read exactly SB->NumDirectoryBytes bytes. assert(Reader.bytesRemaining() == 0); DirectoryStream = std::move(DS); return Error::success(); } ArrayRef PDBFile::getDirectoryBlockArray() const { return ContainerLayout.DirectoryBlocks; } std::unique_ptr PDBFile::createIndexedStream(uint16_t SN) const { if (SN == kInvalidStreamIndex) return nullptr; return MappedBlockStream::createIndexedStream(ContainerLayout, *Buffer, SN, Allocator); } MSFStreamLayout PDBFile::getStreamLayout(uint32_t StreamIdx) const { MSFStreamLayout Result; auto Blocks = getStreamBlockList(StreamIdx); Result.Blocks.assign(Blocks.begin(), Blocks.end()); Result.Length = getStreamByteSize(StreamIdx); return Result; } msf::MSFStreamLayout PDBFile::getFpmStreamLayout() const { return msf::getFpmStreamLayout(ContainerLayout); } Expected PDBFile::getPDBGlobalsStream() { if (!Globals) { auto DbiS = getPDBDbiStream(); if (!DbiS) return DbiS.takeError(); auto GlobalS = safelyCreateIndexedStream(DbiS->getGlobalSymbolStreamIndex()); if (!GlobalS) return GlobalS.takeError(); auto TempGlobals = std::make_unique(std::move(*GlobalS)); if (auto EC = TempGlobals->reload()) return std::move(EC); Globals = std::move(TempGlobals); } return *Globals; } Expected PDBFile::getPDBInfoStream() { if (!Info) { auto InfoS = safelyCreateIndexedStream(StreamPDB); if (!InfoS) return InfoS.takeError(); auto TempInfo = std::make_unique(std::move(*InfoS)); if (auto EC = TempInfo->reload()) return std::move(EC); Info = std::move(TempInfo); } return *Info; } Expected PDBFile::getPDBDbiStream() { if (!Dbi) { auto DbiS = safelyCreateIndexedStream(StreamDBI); if (!DbiS) return DbiS.takeError(); auto TempDbi = std::make_unique(std::move(*DbiS)); if (auto EC = TempDbi->reload(this)) return std::move(EC); Dbi = std::move(TempDbi); } return *Dbi; } Expected PDBFile::getPDBTpiStream() { if (!Tpi) { auto TpiS = safelyCreateIndexedStream(StreamTPI); if (!TpiS) return TpiS.takeError(); auto TempTpi = std::make_unique(*this, std::move(*TpiS)); if (auto EC = TempTpi->reload()) return std::move(EC); Tpi = std::move(TempTpi); } return *Tpi; } Expected PDBFile::getPDBIpiStream() { if (!Ipi) { if (!hasPDBIpiStream()) return make_error(raw_error_code::no_stream); auto IpiS = safelyCreateIndexedStream(StreamIPI); if (!IpiS) return IpiS.takeError(); auto TempIpi = std::make_unique(*this, std::move(*IpiS)); if (auto EC = TempIpi->reload()) return std::move(EC); Ipi = std::move(TempIpi); } return *Ipi; } Expected PDBFile::getPDBPublicsStream() { if (!Publics) { auto DbiS = getPDBDbiStream(); if (!DbiS) return DbiS.takeError(); auto PublicS = safelyCreateIndexedStream(DbiS->getPublicSymbolStreamIndex()); if (!PublicS) return PublicS.takeError(); auto TempPublics = std::make_unique(std::move(*PublicS)); if (auto EC = TempPublics->reload()) return std::move(EC); Publics = std::move(TempPublics); } return *Publics; } Expected PDBFile::getPDBSymbolStream() { if (!Symbols) { auto DbiS = getPDBDbiStream(); if (!DbiS) return DbiS.takeError(); uint32_t SymbolStreamNum = DbiS->getSymRecordStreamIndex(); auto SymbolS = safelyCreateIndexedStream(SymbolStreamNum); if (!SymbolS) return SymbolS.takeError(); auto TempSymbols = std::make_unique(std::move(*SymbolS)); if (auto EC = TempSymbols->reload()) return std::move(EC); Symbols = std::move(TempSymbols); } return *Symbols; } Expected PDBFile::getStringTable() { if (!Strings) { auto NS = safelyCreateNamedStream("/names"); if (!NS) return NS.takeError(); auto N = std::make_unique(); BinaryStreamReader Reader(**NS); if (auto EC = N->reload(Reader)) return std::move(EC); assert(Reader.bytesRemaining() == 0); StringTableStream = std::move(*NS); Strings = std::move(N); } return *Strings; } Expected PDBFile::getInjectedSourceStream() { if (!InjectedSources) { auto IJS = safelyCreateNamedStream("/src/headerblock"); if (!IJS) return IJS.takeError(); auto Strings = getStringTable(); if (!Strings) return Strings.takeError(); auto IJ = std::make_unique(std::move(*IJS)); if (auto EC = IJ->reload(*Strings)) return std::move(EC); InjectedSources = std::move(IJ); } return *InjectedSources; } uint32_t PDBFile::getPointerSize() { auto DbiS = getPDBDbiStream(); if (!DbiS) return 0; PDB_Machine Machine = DbiS->getMachineType(); if (Machine == PDB_Machine::Amd64) return 8; return 4; } bool PDBFile::hasPDBDbiStream() const { return StreamDBI < getNumStreams() && getStreamByteSize(StreamDBI) > 0; } bool PDBFile::hasPDBGlobalsStream() { auto DbiS = getPDBDbiStream(); if (!DbiS) { consumeError(DbiS.takeError()); return false; } return DbiS->getGlobalSymbolStreamIndex() < getNumStreams(); } bool PDBFile::hasPDBInfoStream() const { return StreamPDB < getNumStreams(); } bool PDBFile::hasPDBIpiStream() const { if (!hasPDBInfoStream()) return false; if (StreamIPI >= getNumStreams()) return false; auto &InfoStream = cantFail(const_cast(this)->getPDBInfoStream()); return InfoStream.containsIdStream(); } bool PDBFile::hasPDBPublicsStream() { auto DbiS = getPDBDbiStream(); if (!DbiS) { consumeError(DbiS.takeError()); return false; } return DbiS->getPublicSymbolStreamIndex() < getNumStreams(); } bool PDBFile::hasPDBSymbolStream() { auto DbiS = getPDBDbiStream(); if (!DbiS) return false; return DbiS->getSymRecordStreamIndex() < getNumStreams(); } bool PDBFile::hasPDBTpiStream() const { return StreamTPI < getNumStreams(); } bool PDBFile::hasPDBStringTable() { auto IS = getPDBInfoStream(); if (!IS) return false; Expected ExpectedNSI = IS->getNamedStreamIndex("/names"); if (!ExpectedNSI) { consumeError(ExpectedNSI.takeError()); return false; } assert(*ExpectedNSI < getNumStreams()); return true; } bool PDBFile::hasPDBInjectedSourceStream() { auto IS = getPDBInfoStream(); if (!IS) return false; Expected ExpectedNSI = IS->getNamedStreamIndex("/src/headerblock"); if (!ExpectedNSI) { consumeError(ExpectedNSI.takeError()); return false; } assert(*ExpectedNSI < getNumStreams()); return true; } /// Wrapper around MappedBlockStream::createIndexedStream() that checks if a /// stream with that index actually exists. If it does not, the return value /// will have an MSFError with code msf_error_code::no_stream. Else, the return /// value will contain the stream returned by createIndexedStream(). Expected> PDBFile::safelyCreateIndexedStream(uint32_t StreamIndex) const { if (StreamIndex >= getNumStreams()) // This rejects kInvalidStreamIndex with an error as well. return make_error(raw_error_code::no_stream); return createIndexedStream(StreamIndex); } Expected> PDBFile::safelyCreateNamedStream(StringRef Name) { auto IS = getPDBInfoStream(); if (!IS) return IS.takeError(); Expected ExpectedNSI = IS->getNamedStreamIndex(Name); if (!ExpectedNSI) return ExpectedNSI.takeError(); uint32_t NameStreamIndex = *ExpectedNSI; return safelyCreateIndexedStream(NameStreamIndex); }