//===- GsymCreator.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/GSYM/GsymCreator.h" #include "llvm/DebugInfo/GSYM/FileWriter.h" #include "llvm/DebugInfo/GSYM/Header.h" #include "llvm/DebugInfo/GSYM/LineTable.h" #include "llvm/DebugInfo/GSYM/OutputAggregator.h" #include "llvm/MC/StringTableBuilder.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include using namespace llvm; using namespace gsym; GsymCreator::GsymCreator(bool Quiet) : StrTab(StringTableBuilder::ELF), Quiet(Quiet) { insertFile(StringRef()); } uint32_t GsymCreator::insertFile(StringRef Path, llvm::sys::path::Style Style) { llvm::StringRef directory = llvm::sys::path::parent_path(Path, Style); llvm::StringRef filename = llvm::sys::path::filename(Path, Style); // We must insert the strings first, then call the FileEntry constructor. // If we inline the insertString() function call into the constructor, the // call order is undefined due to parameter lists not having any ordering // requirements. const uint32_t Dir = insertString(directory); const uint32_t Base = insertString(filename); return insertFileEntry(FileEntry(Dir, Base)); } uint32_t GsymCreator::insertFileEntry(FileEntry FE) { std::lock_guard Guard(Mutex); const auto NextIndex = Files.size(); // Find FE in hash map and insert if not present. auto R = FileEntryToIndex.insert(std::make_pair(FE, NextIndex)); if (R.second) Files.emplace_back(FE); return R.first->second; } uint32_t GsymCreator::copyFile(const GsymCreator &SrcGC, uint32_t FileIdx) { // File index zero is reserved for a FileEntry with no directory and no // filename. Any other file and we need to copy the strings for the directory // and filename. if (FileIdx == 0) return 0; const FileEntry SrcFE = SrcGC.Files[FileIdx]; // Copy the strings for the file and then add the newly converted file entry. uint32_t Dir = SrcFE.Dir == 0 ? 0 : StrTab.add(SrcGC.StringOffsetMap.find(SrcFE.Dir)->second); uint32_t Base = StrTab.add(SrcGC.StringOffsetMap.find(SrcFE.Base)->second); FileEntry DstFE(Dir, Base); return insertFileEntry(DstFE); } llvm::Error GsymCreator::save(StringRef Path, llvm::endianness ByteOrder, std::optional SegmentSize) const { if (SegmentSize) return saveSegments(Path, ByteOrder, *SegmentSize); std::error_code EC; raw_fd_ostream OutStrm(Path, EC); if (EC) return llvm::errorCodeToError(EC); FileWriter O(OutStrm, ByteOrder); return encode(O); } llvm::Error GsymCreator::encode(FileWriter &O) const { std::lock_guard Guard(Mutex); if (Funcs.empty()) return createStringError(std::errc::invalid_argument, "no functions to encode"); if (!Finalized) return createStringError(std::errc::invalid_argument, "GsymCreator wasn't finalized prior to encoding"); if (Funcs.size() > UINT32_MAX) return createStringError(std::errc::invalid_argument, "too many FunctionInfos"); std::optional BaseAddress = getBaseAddress(); // Base address should be valid if we have any functions. if (!BaseAddress) return createStringError(std::errc::invalid_argument, "invalid base address"); Header Hdr; Hdr.Magic = GSYM_MAGIC; Hdr.Version = GSYM_VERSION; Hdr.AddrOffSize = getAddressOffsetSize(); Hdr.UUIDSize = static_cast(UUID.size()); Hdr.BaseAddress = *BaseAddress; Hdr.NumAddresses = static_cast(Funcs.size()); Hdr.StrtabOffset = 0; // We will fix this up later. Hdr.StrtabSize = 0; // We will fix this up later. memset(Hdr.UUID, 0, sizeof(Hdr.UUID)); if (UUID.size() > sizeof(Hdr.UUID)) return createStringError(std::errc::invalid_argument, "invalid UUID size %u", (uint32_t)UUID.size()); // Copy the UUID value if we have one. if (UUID.size() > 0) memcpy(Hdr.UUID, UUID.data(), UUID.size()); // Write out the header. llvm::Error Err = Hdr.encode(O); if (Err) return Err; const uint64_t MaxAddressOffset = getMaxAddressOffset(); // Write out the address offsets. O.alignTo(Hdr.AddrOffSize); for (const auto &FuncInfo : Funcs) { uint64_t AddrOffset = FuncInfo.startAddress() - Hdr.BaseAddress; // Make sure we calculated the address offsets byte size correctly by // verifying the current address offset is within ranges. We have seen bugs // introduced when the code changes that can cause problems here so it is // good to catch this during testing. assert(AddrOffset <= MaxAddressOffset); (void)MaxAddressOffset; switch (Hdr.AddrOffSize) { case 1: O.writeU8(static_cast(AddrOffset)); break; case 2: O.writeU16(static_cast(AddrOffset)); break; case 4: O.writeU32(static_cast(AddrOffset)); break; case 8: O.writeU64(AddrOffset); break; } } // Write out all zeros for the AddrInfoOffsets. O.alignTo(4); const off_t AddrInfoOffsetsOffset = O.tell(); for (size_t i = 0, n = Funcs.size(); i < n; ++i) O.writeU32(0); // Write out the file table O.alignTo(4); assert(!Files.empty()); assert(Files[0].Dir == 0); assert(Files[0].Base == 0); size_t NumFiles = Files.size(); if (NumFiles > UINT32_MAX) return createStringError(std::errc::invalid_argument, "too many files"); O.writeU32(static_cast(NumFiles)); for (auto File : Files) { O.writeU32(File.Dir); O.writeU32(File.Base); } // Write out the string table. const off_t StrtabOffset = O.tell(); StrTab.write(O.get_stream()); const off_t StrtabSize = O.tell() - StrtabOffset; std::vector AddrInfoOffsets; // Write out the address infos for each function info. for (const auto &FuncInfo : Funcs) { if (Expected OffsetOrErr = FuncInfo.encode(O)) AddrInfoOffsets.push_back(OffsetOrErr.get()); else return OffsetOrErr.takeError(); } // Fixup the string table offset and size in the header O.fixup32((uint32_t)StrtabOffset, offsetof(Header, StrtabOffset)); O.fixup32((uint32_t)StrtabSize, offsetof(Header, StrtabSize)); // Fixup all address info offsets uint64_t Offset = 0; for (auto AddrInfoOffset : AddrInfoOffsets) { O.fixup32(AddrInfoOffset, AddrInfoOffsetsOffset + Offset); Offset += 4; } return ErrorSuccess(); } llvm::Error GsymCreator::finalize(OutputAggregator &Out) { std::lock_guard Guard(Mutex); if (Finalized) return createStringError(std::errc::invalid_argument, "already finalized"); Finalized = true; // Don't let the string table indexes change by finalizing in order. StrTab.finalizeInOrder(); // Remove duplicates function infos that have both entries from debug info // (DWARF or Breakpad) and entries from the SymbolTable. // // Also handle overlapping function. Usually there shouldn't be any, but they // can and do happen in some rare cases. // // (a) (b) (c) // ^ ^ ^ ^ // |X |Y |X ^ |X // | | | |Y | ^ // | | | v v |Y // v v v v // // In (a) and (b), Y is ignored and X will be reported for the full range. // In (c), both functions will be included in the result and lookups for an // address in the intersection will return Y because of binary search. // // Note that in case of (b), we cannot include Y in the result because then // we wouldn't find any function for range (end of Y, end of X) // with binary search const auto NumBefore = Funcs.size(); // Only sort and unique if this isn't a segment. If this is a segment we // already finalized the main GsymCreator with all of the function infos // and then the already sorted and uniqued function infos were added to this // object. if (!IsSegment) { if (NumBefore > 1) { // Sort function infos so we can emit sorted functions. llvm::sort(Funcs); std::vector FinalizedFuncs; FinalizedFuncs.reserve(Funcs.size()); FinalizedFuncs.emplace_back(std::move(Funcs.front())); for (size_t Idx=1; Idx < NumBefore; ++Idx) { FunctionInfo &Prev = FinalizedFuncs.back(); FunctionInfo &Curr = Funcs[Idx]; // Empty ranges won't intersect, but we still need to // catch the case where we have multiple symbols at the // same address and coalesce them. const bool ranges_equal = Prev.Range == Curr.Range; if (ranges_equal || Prev.Range.intersects(Curr.Range)) { // Overlapping ranges or empty identical ranges. if (ranges_equal) { // Same address range. Check if one is from debug // info and the other is from a symbol table. If // so, then keep the one with debug info. Our // sorting guarantees that entries with matching // address ranges that have debug info are last in // the sort. if (!(Prev == Curr)) { if (Prev.hasRichInfo() && Curr.hasRichInfo()) Out.Report( "Duplicate address ranges with different debug info.", [&](raw_ostream &OS) { OS << "warning: same address range contains " "different debug " << "info. Removing:\n" << Prev << "\nIn favor of this one:\n" << Curr << "\n"; }); // We want to swap the current entry with the previous since // later entries with the same range always have more debug info // or different debug info. std::swap(Prev, Curr); } } else { Out.Report("Overlapping function ranges", [&](raw_ostream &OS) { // print warnings about overlaps OS << "warning: function ranges overlap:\n" << Prev << "\n" << Curr << "\n"; }); FinalizedFuncs.emplace_back(std::move(Curr)); } } else { if (Prev.Range.size() == 0 && Curr.Range.contains(Prev.Range.start())) { // Symbols on macOS don't have address ranges, so if the range // doesn't match and the size is zero, then we replace the empty // symbol function info with the current one. std::swap(Prev, Curr); } else { FinalizedFuncs.emplace_back(std::move(Curr)); } } } std::swap(Funcs, FinalizedFuncs); } // If our last function info entry doesn't have a size and if we have valid // text ranges, we should set the size of the last entry since any search for // a high address might match our last entry. By fixing up this size, we can // help ensure we don't cause lookups to always return the last symbol that // has no size when doing lookups. if (!Funcs.empty() && Funcs.back().Range.size() == 0 && ValidTextRanges) { if (auto Range = ValidTextRanges->getRangeThatContains(Funcs.back().Range.start())) { Funcs.back().Range = {Funcs.back().Range.start(), Range->end()}; } } Out << "Pruned " << NumBefore - Funcs.size() << " functions, ended with " << Funcs.size() << " total\n"; } return Error::success(); } uint32_t GsymCreator::copyString(const GsymCreator &SrcGC, uint32_t StrOff) { // String offset at zero is always the empty string, no copying needed. if (StrOff == 0) return 0; return StrTab.add(SrcGC.StringOffsetMap.find(StrOff)->second); } uint32_t GsymCreator::insertString(StringRef S, bool Copy) { if (S.empty()) return 0; // The hash can be calculated outside the lock. CachedHashStringRef CHStr(S); std::lock_guard Guard(Mutex); if (Copy) { // We need to provide backing storage for the string if requested // since StringTableBuilder stores references to strings. Any string // that comes from a section in an object file doesn't need to be // copied, but any string created by code will need to be copied. // This allows GsymCreator to be really fast when parsing DWARF and // other object files as most strings don't need to be copied. if (!StrTab.contains(CHStr)) CHStr = CachedHashStringRef{StringStorage.insert(S).first->getKey(), CHStr.hash()}; } const uint32_t StrOff = StrTab.add(CHStr); // Save a mapping of string offsets to the cached string reference in case // we need to segment the GSYM file and copy string from one string table to // another. if (StringOffsetMap.count(StrOff) == 0) StringOffsetMap.insert(std::make_pair(StrOff, CHStr)); return StrOff; } void GsymCreator::addFunctionInfo(FunctionInfo &&FI) { std::lock_guard Guard(Mutex); Funcs.emplace_back(std::move(FI)); } void GsymCreator::forEachFunctionInfo( std::function const &Callback) { std::lock_guard Guard(Mutex); for (auto &FI : Funcs) { if (!Callback(FI)) break; } } void GsymCreator::forEachFunctionInfo( std::function const &Callback) const { std::lock_guard Guard(Mutex); for (const auto &FI : Funcs) { if (!Callback(FI)) break; } } size_t GsymCreator::getNumFunctionInfos() const { std::lock_guard Guard(Mutex); return Funcs.size(); } bool GsymCreator::IsValidTextAddress(uint64_t Addr) const { if (ValidTextRanges) return ValidTextRanges->contains(Addr); return true; // No valid text ranges has been set, so accept all ranges. } std::optional GsymCreator::getFirstFunctionAddress() const { // If we have finalized then Funcs are sorted. If we are a segment then // Funcs will be sorted as well since function infos get added from an // already finalized GsymCreator object where its functions were sorted and // uniqued. if ((Finalized || IsSegment) && !Funcs.empty()) return std::optional(Funcs.front().startAddress()); return std::nullopt; } std::optional GsymCreator::getLastFunctionAddress() const { // If we have finalized then Funcs are sorted. If we are a segment then // Funcs will be sorted as well since function infos get added from an // already finalized GsymCreator object where its functions were sorted and // uniqued. if ((Finalized || IsSegment) && !Funcs.empty()) return std::optional(Funcs.back().startAddress()); return std::nullopt; } std::optional GsymCreator::getBaseAddress() const { if (BaseAddress) return BaseAddress; return getFirstFunctionAddress(); } uint64_t GsymCreator::getMaxAddressOffset() const { switch (getAddressOffsetSize()) { case 1: return UINT8_MAX; case 2: return UINT16_MAX; case 4: return UINT32_MAX; case 8: return UINT64_MAX; } llvm_unreachable("invalid address offset"); } uint8_t GsymCreator::getAddressOffsetSize() const { const std::optional BaseAddress = getBaseAddress(); const std::optional LastFuncAddr = getLastFunctionAddress(); if (BaseAddress && LastFuncAddr) { const uint64_t AddrDelta = *LastFuncAddr - *BaseAddress; if (AddrDelta <= UINT8_MAX) return 1; else if (AddrDelta <= UINT16_MAX) return 2; else if (AddrDelta <= UINT32_MAX) return 4; return 8; } return 1; } uint64_t GsymCreator::calculateHeaderAndTableSize() const { uint64_t Size = sizeof(Header); const size_t NumFuncs = Funcs.size(); // Add size of address offset table Size += NumFuncs * getAddressOffsetSize(); // Add size of address info offsets which are 32 bit integers in version 1. Size += NumFuncs * sizeof(uint32_t); // Add file table size Size += Files.size() * sizeof(FileEntry); // Add string table size Size += StrTab.getSize(); return Size; } // This function takes a InlineInfo class that was copy constructed from an // InlineInfo from the \a SrcGC and updates all members that point to strings // and files to point to strings and files from this GsymCreator. void GsymCreator::fixupInlineInfo(const GsymCreator &SrcGC, InlineInfo &II) { II.Name = copyString(SrcGC, II.Name); II.CallFile = copyFile(SrcGC, II.CallFile); for (auto &ChildII: II.Children) fixupInlineInfo(SrcGC, ChildII); } uint64_t GsymCreator::copyFunctionInfo(const GsymCreator &SrcGC, size_t FuncIdx) { // To copy a function info we need to copy any files and strings over into // this GsymCreator and then copy the function info and update the string // table offsets to match the new offsets. const FunctionInfo &SrcFI = SrcGC.Funcs[FuncIdx]; FunctionInfo DstFI; DstFI.Range = SrcFI.Range; DstFI.Name = copyString(SrcGC, SrcFI.Name); // Copy the line table if there is one. if (SrcFI.OptLineTable) { // Copy the entire line table. DstFI.OptLineTable = LineTable(SrcFI.OptLineTable.value()); // Fixup all LineEntry::File entries which are indexes in the the file table // from SrcGC and must be converted to file indexes from this GsymCreator. LineTable &DstLT = DstFI.OptLineTable.value(); const size_t NumLines = DstLT.size(); for (size_t I=0; I Guard(Mutex); Funcs.emplace_back(DstFI); return Funcs.back().cacheEncoding(); } llvm::Error GsymCreator::saveSegments(StringRef Path, llvm::endianness ByteOrder, uint64_t SegmentSize) const { if (SegmentSize == 0) return createStringError(std::errc::invalid_argument, "invalid segment size zero"); size_t FuncIdx = 0; const size_t NumFuncs = Funcs.size(); while (FuncIdx < NumFuncs) { llvm::Expected> ExpectedGC = createSegment(SegmentSize, FuncIdx); if (ExpectedGC) { GsymCreator *GC = ExpectedGC->get(); if (GC == NULL) break; // We had not more functions to encode. // Don't collect any messages at all OutputAggregator Out(nullptr); llvm::Error Err = GC->finalize(Out); if (Err) return Err; std::string SegmentedGsymPath; raw_string_ostream SGP(SegmentedGsymPath); std::optional FirstFuncAddr = GC->getFirstFunctionAddress(); if (FirstFuncAddr) { SGP << Path << "-" << llvm::format_hex(*FirstFuncAddr, 1); SGP.flush(); Err = GC->save(SegmentedGsymPath, ByteOrder, std::nullopt); if (Err) return Err; } } else { return ExpectedGC.takeError(); } } return Error::success(); } llvm::Expected> GsymCreator::createSegment(uint64_t SegmentSize, size_t &FuncIdx) const { // No function entries, return empty unique pointer if (FuncIdx >= Funcs.size()) return std::unique_ptr(); std::unique_ptr GC(new GsymCreator(/*Quiet=*/true)); // Tell the creator that this is a segment. GC->setIsSegment(); // Set the base address if there is one. if (BaseAddress) GC->setBaseAddress(*BaseAddress); // Copy the UUID value from this object into the new creator. GC->setUUID(UUID); const size_t NumFuncs = Funcs.size(); // Track how big the function infos are for the current segment so we can // emit segments that are close to the requested size. It is quick math to // determine the current header and tables sizes, so we can do that each loop. uint64_t SegmentFuncInfosSize = 0; for (; FuncIdx < NumFuncs; ++FuncIdx) { const uint64_t HeaderAndTableSize = GC->calculateHeaderAndTableSize(); if (HeaderAndTableSize + SegmentFuncInfosSize >= SegmentSize) { if (SegmentFuncInfosSize == 0) return createStringError(std::errc::invalid_argument, "a segment size of %" PRIu64 " is to small to " "fit any function infos, specify a larger value", SegmentSize); break; } SegmentFuncInfosSize += alignTo(GC->copyFunctionInfo(*this, FuncIdx), 4); } return std::move(GC); }