//===- MSFBuilder.cpp -----------------------------------------------------===// // // 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/MSF/MSFBuilder.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/DebugInfo/MSF/MSFError.h" #include "llvm/DebugInfo/MSF/MappedBlockStream.h" #include "llvm/Support/BinaryByteStream.h" #include "llvm/Support/BinaryStreamWriter.h" #include "llvm/Support/Endian.h" #include "llvm/Support/Error.h" #include "llvm/Support/FileOutputBuffer.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/TimeProfiler.h" #include #include #include #include #include #include #include using namespace llvm; using namespace llvm::msf; using namespace llvm::support; static const uint32_t kSuperBlockBlock = 0; static const uint32_t kFreePageMap0Block = 1; static const uint32_t kFreePageMap1Block = 2; static const uint32_t kNumReservedPages = 3; static const uint32_t kDefaultFreePageMap = kFreePageMap1Block; static const uint32_t kDefaultBlockMapAddr = kNumReservedPages; MSFBuilder::MSFBuilder(uint32_t BlockSize, uint32_t MinBlockCount, bool CanGrow, BumpPtrAllocator &Allocator) : Allocator(Allocator), IsGrowable(CanGrow), FreePageMap(kDefaultFreePageMap), BlockSize(BlockSize), BlockMapAddr(kDefaultBlockMapAddr), FreeBlocks(MinBlockCount, true) { FreeBlocks[kSuperBlockBlock] = false; FreeBlocks[kFreePageMap0Block] = false; FreeBlocks[kFreePageMap1Block] = false; FreeBlocks[BlockMapAddr] = false; } Expected MSFBuilder::create(BumpPtrAllocator &Allocator, uint32_t BlockSize, uint32_t MinBlockCount, bool CanGrow) { if (!isValidBlockSize(BlockSize)) return make_error(msf_error_code::invalid_format, "The requested block size is unsupported"); return MSFBuilder(BlockSize, std::max(MinBlockCount, msf::getMinimumBlockCount()), CanGrow, Allocator); } Error MSFBuilder::setBlockMapAddr(uint32_t Addr) { if (Addr == BlockMapAddr) return Error::success(); if (Addr >= FreeBlocks.size()) { if (!IsGrowable) return make_error(msf_error_code::insufficient_buffer, "Cannot grow the number of blocks"); FreeBlocks.resize(Addr + 1, true); } if (!isBlockFree(Addr)) return make_error( msf_error_code::block_in_use, "Requested block map address is already in use"); FreeBlocks[BlockMapAddr] = true; FreeBlocks[Addr] = false; BlockMapAddr = Addr; return Error::success(); } void MSFBuilder::setFreePageMap(uint32_t Fpm) { FreePageMap = Fpm; } void MSFBuilder::setUnknown1(uint32_t Unk1) { Unknown1 = Unk1; } Error MSFBuilder::setDirectoryBlocksHint(ArrayRef DirBlocks) { for (auto B : DirectoryBlocks) FreeBlocks[B] = true; for (auto B : DirBlocks) { if (!isBlockFree(B)) { return make_error(msf_error_code::unspecified, "Attempt to reuse an allocated block"); } FreeBlocks[B] = false; } DirectoryBlocks = DirBlocks; return Error::success(); } Error MSFBuilder::allocateBlocks(uint32_t NumBlocks, MutableArrayRef Blocks) { if (NumBlocks == 0) return Error::success(); uint32_t NumFreeBlocks = FreeBlocks.count(); if (NumFreeBlocks < NumBlocks) { if (!IsGrowable) return make_error(msf_error_code::insufficient_buffer, "There are no free Blocks in the file"); uint32_t AllocBlocks = NumBlocks - NumFreeBlocks; uint32_t OldBlockCount = FreeBlocks.size(); uint32_t NewBlockCount = AllocBlocks + OldBlockCount; uint32_t NextFpmBlock = alignTo(OldBlockCount, BlockSize) + 1; FreeBlocks.resize(NewBlockCount, true); // If we crossed over an fpm page, we actually need to allocate 2 extra // blocks for each FPM group crossed and mark both blocks from the group as // used. FPM blocks are marked as allocated regardless of whether or not // they ultimately describe the status of blocks in the file. This means // that not only are extraneous blocks at the end of the main FPM marked as // allocated, but also blocks from the alternate FPM are always marked as // allocated. while (NextFpmBlock < NewBlockCount) { NewBlockCount += 2; FreeBlocks.resize(NewBlockCount, true); FreeBlocks.reset(NextFpmBlock, NextFpmBlock + 2); NextFpmBlock += BlockSize; } } int I = 0; int Block = FreeBlocks.find_first(); do { assert(Block != -1 && "We ran out of Blocks!"); uint32_t NextBlock = static_cast(Block); Blocks[I++] = NextBlock; FreeBlocks.reset(NextBlock); Block = FreeBlocks.find_next(Block); } while (--NumBlocks > 0); return Error::success(); } uint32_t MSFBuilder::getNumUsedBlocks() const { return getTotalBlockCount() - getNumFreeBlocks(); } uint32_t MSFBuilder::getNumFreeBlocks() const { return FreeBlocks.count(); } uint32_t MSFBuilder::getTotalBlockCount() const { return FreeBlocks.size(); } bool MSFBuilder::isBlockFree(uint32_t Idx) const { return FreeBlocks[Idx]; } Expected MSFBuilder::addStream(uint32_t Size, ArrayRef Blocks) { // Add a new stream mapped to the specified blocks. Verify that the specified // blocks are both necessary and sufficient for holding the requested number // of bytes, and verify that all requested blocks are free. uint32_t ReqBlocks = bytesToBlocks(Size, BlockSize); if (ReqBlocks != Blocks.size()) return make_error( msf_error_code::invalid_format, "Incorrect number of blocks for requested stream size"); for (auto Block : Blocks) { if (Block >= FreeBlocks.size()) FreeBlocks.resize(Block + 1, true); if (!FreeBlocks.test(Block)) return make_error( msf_error_code::unspecified, "Attempt to re-use an already allocated block"); } // Mark all the blocks occupied by the new stream as not free. for (auto Block : Blocks) { FreeBlocks.reset(Block); } StreamData.push_back(std::make_pair(Size, Blocks)); return StreamData.size() - 1; } Expected MSFBuilder::addStream(uint32_t Size) { uint32_t ReqBlocks = bytesToBlocks(Size, BlockSize); std::vector NewBlocks; NewBlocks.resize(ReqBlocks); if (auto EC = allocateBlocks(ReqBlocks, NewBlocks)) return std::move(EC); StreamData.push_back(std::make_pair(Size, NewBlocks)); return StreamData.size() - 1; } Error MSFBuilder::setStreamSize(uint32_t Idx, uint32_t Size) { uint32_t OldSize = getStreamSize(Idx); if (OldSize == Size) return Error::success(); uint32_t NewBlocks = bytesToBlocks(Size, BlockSize); uint32_t OldBlocks = bytesToBlocks(OldSize, BlockSize); if (NewBlocks > OldBlocks) { uint32_t AddedBlocks = NewBlocks - OldBlocks; // If we're growing, we have to allocate new Blocks. std::vector AddedBlockList; AddedBlockList.resize(AddedBlocks); if (auto EC = allocateBlocks(AddedBlocks, AddedBlockList)) return EC; auto &CurrentBlocks = StreamData[Idx].second; llvm::append_range(CurrentBlocks, AddedBlockList); } else if (OldBlocks > NewBlocks) { // For shrinking, free all the Blocks in the Block map, update the stream // data, then shrink the directory. uint32_t RemovedBlocks = OldBlocks - NewBlocks; auto CurrentBlocks = ArrayRef(StreamData[Idx].second); auto RemovedBlockList = CurrentBlocks.drop_front(NewBlocks); for (auto P : RemovedBlockList) FreeBlocks[P] = true; StreamData[Idx].second = CurrentBlocks.drop_back(RemovedBlocks); } StreamData[Idx].first = Size; return Error::success(); } uint32_t MSFBuilder::getNumStreams() const { return StreamData.size(); } uint32_t MSFBuilder::getStreamSize(uint32_t StreamIdx) const { return StreamData[StreamIdx].first; } ArrayRef MSFBuilder::getStreamBlocks(uint32_t StreamIdx) const { return StreamData[StreamIdx].second; } uint32_t MSFBuilder::computeDirectoryByteSize() const { // The directory has the following layout, where each item is a ulittle32_t: // NumStreams // StreamSizes[NumStreams] // StreamBlocks[NumStreams][] uint32_t Size = sizeof(ulittle32_t); // NumStreams Size += StreamData.size() * sizeof(ulittle32_t); // StreamSizes for (const auto &D : StreamData) { uint32_t ExpectedNumBlocks = bytesToBlocks(D.first, BlockSize); assert(ExpectedNumBlocks == D.second.size() && "Unexpected number of blocks"); Size += ExpectedNumBlocks * sizeof(ulittle32_t); } return Size; } Expected MSFBuilder::generateLayout() { llvm::TimeTraceScope timeScope("MSF: Generate layout"); SuperBlock *SB = Allocator.Allocate(); MSFLayout L; L.SB = SB; std::memcpy(SB->MagicBytes, Magic, sizeof(Magic)); SB->BlockMapAddr = BlockMapAddr; SB->BlockSize = BlockSize; SB->NumDirectoryBytes = computeDirectoryByteSize(); SB->FreeBlockMapBlock = FreePageMap; SB->Unknown1 = Unknown1; uint32_t NumDirectoryBlocks = bytesToBlocks(SB->NumDirectoryBytes, BlockSize); if (NumDirectoryBlocks > DirectoryBlocks.size()) { // Our hint wasn't enough to satisfy the entire directory. Allocate // remaining pages. std::vector ExtraBlocks; uint32_t NumExtraBlocks = NumDirectoryBlocks - DirectoryBlocks.size(); ExtraBlocks.resize(NumExtraBlocks); if (auto EC = allocateBlocks(NumExtraBlocks, ExtraBlocks)) return std::move(EC); llvm::append_range(DirectoryBlocks, ExtraBlocks); } else if (NumDirectoryBlocks < DirectoryBlocks.size()) { uint32_t NumUnnecessaryBlocks = DirectoryBlocks.size() - NumDirectoryBlocks; for (auto B : ArrayRef(DirectoryBlocks).drop_back(NumUnnecessaryBlocks)) FreeBlocks[B] = true; DirectoryBlocks.resize(NumDirectoryBlocks); } // Don't set the number of blocks in the file until after allocating Blocks // for the directory, since the allocation might cause the file to need to // grow. SB->NumBlocks = FreeBlocks.size(); ulittle32_t *DirBlocks = Allocator.Allocate(NumDirectoryBlocks); std::uninitialized_copy_n(DirectoryBlocks.begin(), NumDirectoryBlocks, DirBlocks); L.DirectoryBlocks = ArrayRef(DirBlocks, NumDirectoryBlocks); // The stream sizes should be re-allocated as a stable pointer and the stream // map should have each of its entries allocated as a separate stable pointer. if (!StreamData.empty()) { ulittle32_t *Sizes = Allocator.Allocate(StreamData.size()); L.StreamSizes = ArrayRef(Sizes, StreamData.size()); L.StreamMap.resize(StreamData.size()); for (uint32_t I = 0; I < StreamData.size(); ++I) { Sizes[I] = StreamData[I].first; ulittle32_t *BlockList = Allocator.Allocate(StreamData[I].second.size()); std::uninitialized_copy_n(StreamData[I].second.begin(), StreamData[I].second.size(), BlockList); L.StreamMap[I] = ArrayRef(BlockList, StreamData[I].second.size()); } } L.FreePageMap = FreeBlocks; return L; } static void commitFpm(WritableBinaryStream &MsfBuffer, const MSFLayout &Layout, BumpPtrAllocator &Allocator) { auto FpmStream = WritableMappedBlockStream::createFpmStream(Layout, MsfBuffer, Allocator); // We only need to create the alt fpm stream so that it gets initialized. WritableMappedBlockStream::createFpmStream(Layout, MsfBuffer, Allocator, true); uint32_t BI = 0; BinaryStreamWriter FpmWriter(*FpmStream); while (BI < Layout.SB->NumBlocks) { uint8_t ThisByte = 0; for (uint32_t I = 0; I < 8; ++I) { bool IsFree = (BI < Layout.SB->NumBlocks) ? Layout.FreePageMap.test(BI) : true; uint8_t Mask = uint8_t(IsFree) << I; ThisByte |= Mask; ++BI; } cantFail(FpmWriter.writeObject(ThisByte)); } assert(FpmWriter.bytesRemaining() == 0); } Expected MSFBuilder::commit(StringRef Path, MSFLayout &Layout) { llvm::TimeTraceScope timeScope("Commit MSF"); Expected L = generateLayout(); if (!L) return L.takeError(); Layout = std::move(*L); uint64_t FileSize = uint64_t(Layout.SB->BlockSize) * Layout.SB->NumBlocks; // Ensure that the file size is under the limit for the specified block size. if (FileSize > getMaxFileSizeFromBlockSize(Layout.SB->BlockSize)) { msf_error_code error_code = [](uint32_t BlockSize) { switch (BlockSize) { case 8192: return msf_error_code::size_overflow_8192; case 16384: return msf_error_code::size_overflow_16384; case 32768: return msf_error_code::size_overflow_32768; default: return msf_error_code::size_overflow_4096; } }(Layout.SB->BlockSize); return make_error( error_code, formatv("File size {0,1:N} too large for current PDB page size {1}", FileSize, Layout.SB->BlockSize)); } uint64_t NumDirectoryBlocks = bytesToBlocks(Layout.SB->NumDirectoryBytes, Layout.SB->BlockSize); uint64_t DirectoryBlockMapSize = NumDirectoryBlocks * sizeof(support::ulittle32_t); if (DirectoryBlockMapSize > Layout.SB->BlockSize) { return make_error(msf_error_code::stream_directory_overflow, formatv("The directory block map ({0} bytes) " "doesn't fit in a block ({1} bytes)", DirectoryBlockMapSize, Layout.SB->BlockSize)); } auto OutFileOrError = FileOutputBuffer::create(Path, FileSize); if (auto EC = OutFileOrError.takeError()) return std::move(EC); FileBufferByteStream Buffer(std::move(*OutFileOrError), llvm::endianness::little); BinaryStreamWriter Writer(Buffer); if (auto EC = Writer.writeObject(*Layout.SB)) return std::move(EC); commitFpm(Buffer, Layout, Allocator); uint32_t BlockMapOffset = msf::blockToOffset(Layout.SB->BlockMapAddr, Layout.SB->BlockSize); Writer.setOffset(BlockMapOffset); if (auto EC = Writer.writeArray(Layout.DirectoryBlocks)) return std::move(EC); auto DirStream = WritableMappedBlockStream::createDirectoryStream( Layout, Buffer, Allocator); BinaryStreamWriter DW(*DirStream); if (auto EC = DW.writeInteger(Layout.StreamSizes.size())) return std::move(EC); if (auto EC = DW.writeArray(Layout.StreamSizes)) return std::move(EC); for (const auto &Blocks : Layout.StreamMap) { if (auto EC = DW.writeArray(Blocks)) return std::move(EC); } return std::move(Buffer); }