//=--------- MachOLinkGraphBuilder.cpp - MachO LinkGraph builder ----------===// // // 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 // //===----------------------------------------------------------------------===// // // Generic MachO LinkGraph buliding code. // //===----------------------------------------------------------------------===// #include "MachOLinkGraphBuilder.h" #include #define DEBUG_TYPE "jitlink" static const char *CommonSectionName = "__common"; namespace llvm { namespace jitlink { MachOLinkGraphBuilder::~MachOLinkGraphBuilder() = default; Expected> MachOLinkGraphBuilder::buildGraph() { // We only operate on relocatable objects. if (!Obj.isRelocatableObject()) return make_error("Object is not a relocatable MachO"); if (auto Err = createNormalizedSections()) return std::move(Err); if (auto Err = createNormalizedSymbols()) return std::move(Err); if (auto Err = graphifyRegularSymbols()) return std::move(Err); if (auto Err = graphifySectionsWithCustomParsers()) return std::move(Err); if (auto Err = addRelocations()) return std::move(Err); return std::move(G); } MachOLinkGraphBuilder::MachOLinkGraphBuilder( const object::MachOObjectFile &Obj, Triple TT, LinkGraph::GetEdgeKindNameFunction GetEdgeKindName) : Obj(Obj), G(std::make_unique( std::string(Obj.getFileName()), std::move(TT), getPointerSize(Obj), getEndianness(Obj), std::move(GetEdgeKindName))) { auto &MachHeader = Obj.getHeader64(); SubsectionsViaSymbols = MachHeader.flags & MachO::MH_SUBSECTIONS_VIA_SYMBOLS; } void MachOLinkGraphBuilder::addCustomSectionParser( StringRef SectionName, SectionParserFunction Parser) { assert(!CustomSectionParserFunctions.count(SectionName) && "Custom parser for this section already exists"); CustomSectionParserFunctions[SectionName] = std::move(Parser); } Linkage MachOLinkGraphBuilder::getLinkage(uint16_t Desc) { if ((Desc & MachO::N_WEAK_DEF) || (Desc & MachO::N_WEAK_REF)) return Linkage::Weak; return Linkage::Strong; } Scope MachOLinkGraphBuilder::getScope(StringRef Name, uint8_t Type) { if (Type & MachO::N_EXT) { if ((Type & MachO::N_PEXT) || Name.startswith("l")) return Scope::Hidden; else return Scope::Default; } return Scope::Local; } bool MachOLinkGraphBuilder::isAltEntry(const NormalizedSymbol &NSym) { return NSym.Desc & MachO::N_ALT_ENTRY; } bool MachOLinkGraphBuilder::isDebugSection(const NormalizedSection &NSec) { return (NSec.Flags & MachO::S_ATTR_DEBUG && strcmp(NSec.SegName, "__DWARF") == 0); } bool MachOLinkGraphBuilder::isZeroFillSection(const NormalizedSection &NSec) { switch (NSec.Flags & MachO::SECTION_TYPE) { case MachO::S_ZEROFILL: case MachO::S_GB_ZEROFILL: case MachO::S_THREAD_LOCAL_ZEROFILL: return true; default: return false; } } unsigned MachOLinkGraphBuilder::getPointerSize(const object::MachOObjectFile &Obj) { return Obj.is64Bit() ? 8 : 4; } support::endianness MachOLinkGraphBuilder::getEndianness(const object::MachOObjectFile &Obj) { return Obj.isLittleEndian() ? support::little : support::big; } Section &MachOLinkGraphBuilder::getCommonSection() { if (!CommonSection) CommonSection = &G->createSection(CommonSectionName, orc::MemProt::Read | orc::MemProt::Write); return *CommonSection; } Error MachOLinkGraphBuilder::createNormalizedSections() { // Build normalized sections. Verifies that section data is in-range (for // sections with content) and that address ranges are non-overlapping. LLVM_DEBUG(dbgs() << "Creating normalized sections...\n"); for (auto &SecRef : Obj.sections()) { NormalizedSection NSec; uint32_t DataOffset = 0; auto SecIndex = Obj.getSectionIndex(SecRef.getRawDataRefImpl()); if (Obj.is64Bit()) { const MachO::section_64 &Sec64 = Obj.getSection64(SecRef.getRawDataRefImpl()); memcpy(&NSec.SectName, &Sec64.sectname, 16); NSec.SectName[16] = '\0'; memcpy(&NSec.SegName, Sec64.segname, 16); NSec.SegName[16] = '\0'; NSec.Address = orc::ExecutorAddr(Sec64.addr); NSec.Size = Sec64.size; NSec.Alignment = 1ULL << Sec64.align; NSec.Flags = Sec64.flags; DataOffset = Sec64.offset; } else { const MachO::section &Sec32 = Obj.getSection(SecRef.getRawDataRefImpl()); memcpy(&NSec.SectName, &Sec32.sectname, 16); NSec.SectName[16] = '\0'; memcpy(&NSec.SegName, Sec32.segname, 16); NSec.SegName[16] = '\0'; NSec.Address = orc::ExecutorAddr(Sec32.addr); NSec.Size = Sec32.size; NSec.Alignment = 1ULL << Sec32.align; NSec.Flags = Sec32.flags; DataOffset = Sec32.offset; } LLVM_DEBUG({ dbgs() << " " << NSec.SegName << "," << NSec.SectName << ": " << formatv("{0:x16}", NSec.Address) << " -- " << formatv("{0:x16}", NSec.Address + NSec.Size) << ", align: " << NSec.Alignment << ", index: " << SecIndex << "\n"; }); // Get the section data if any. if (!isZeroFillSection(NSec)) { if (DataOffset + NSec.Size > Obj.getData().size()) return make_error( "Section data extends past end of file"); NSec.Data = Obj.getData().data() + DataOffset; } // Get prot flags. // FIXME: Make sure this test is correct (it's probably missing cases // as-is). orc::MemProt Prot; if (NSec.Flags & MachO::S_ATTR_PURE_INSTRUCTIONS) Prot = orc::MemProt::Read | orc::MemProt::Exec; else Prot = orc::MemProt::Read | orc::MemProt::Write; auto FullyQualifiedName = G->allocateString(StringRef(NSec.SegName) + "," + NSec.SectName); NSec.GraphSection = &G->createSection( StringRef(FullyQualifiedName.data(), FullyQualifiedName.size()), Prot); IndexToSection.insert(std::make_pair(SecIndex, std::move(NSec))); } std::vector Sections; Sections.reserve(IndexToSection.size()); for (auto &KV : IndexToSection) Sections.push_back(&KV.second); // If we didn't end up creating any sections then bail out. The code below // assumes that we have at least one section. if (Sections.empty()) return Error::success(); llvm::sort(Sections, [](const NormalizedSection *LHS, const NormalizedSection *RHS) { assert(LHS && RHS && "Null section?"); if (LHS->Address != RHS->Address) return LHS->Address < RHS->Address; return LHS->Size < RHS->Size; }); for (unsigned I = 0, E = Sections.size() - 1; I != E; ++I) { auto &Cur = *Sections[I]; auto &Next = *Sections[I + 1]; if (Next.Address < Cur.Address + Cur.Size) return make_error( "Address range for section " + formatv("\"{0}/{1}\" [ {2:x16} -- {3:x16} ] ", Cur.SegName, Cur.SectName, Cur.Address, Cur.Address + Cur.Size) + "overlaps section \"" + Next.SegName + "/" + Next.SectName + "\"" + formatv("\"{0}/{1}\" [ {2:x16} -- {3:x16} ] ", Next.SegName, Next.SectName, Next.Address, Next.Address + Next.Size)); } return Error::success(); } Error MachOLinkGraphBuilder::createNormalizedSymbols() { LLVM_DEBUG(dbgs() << "Creating normalized symbols...\n"); for (auto &SymRef : Obj.symbols()) { unsigned SymbolIndex = Obj.getSymbolIndex(SymRef.getRawDataRefImpl()); uint64_t Value; uint32_t NStrX; uint8_t Type; uint8_t Sect; uint16_t Desc; if (Obj.is64Bit()) { const MachO::nlist_64 &NL64 = Obj.getSymbol64TableEntry(SymRef.getRawDataRefImpl()); Value = NL64.n_value; NStrX = NL64.n_strx; Type = NL64.n_type; Sect = NL64.n_sect; Desc = NL64.n_desc; } else { const MachO::nlist &NL32 = Obj.getSymbolTableEntry(SymRef.getRawDataRefImpl()); Value = NL32.n_value; NStrX = NL32.n_strx; Type = NL32.n_type; Sect = NL32.n_sect; Desc = NL32.n_desc; } // Skip stabs. // FIXME: Are there other symbols we should be skipping? if (Type & MachO::N_STAB) continue; std::optional Name; if (NStrX) { if (auto NameOrErr = SymRef.getName()) Name = *NameOrErr; else return NameOrErr.takeError(); } LLVM_DEBUG({ dbgs() << " "; if (!Name) dbgs() << ""; else dbgs() << *Name; dbgs() << ": value = " << formatv("{0:x16}", Value) << ", type = " << formatv("{0:x2}", Type) << ", desc = " << formatv("{0:x4}", Desc) << ", sect = "; if (Sect) dbgs() << static_cast(Sect - 1); else dbgs() << "none"; dbgs() << "\n"; }); // If this symbol has a section, verify that the addresses line up. if (Sect != 0) { auto NSec = findSectionByIndex(Sect - 1); if (!NSec) return NSec.takeError(); if (orc::ExecutorAddr(Value) < NSec->Address || orc::ExecutorAddr(Value) > NSec->Address + NSec->Size) return make_error("Address " + formatv("{0:x}", Value) + " for symbol " + *Name + " does not fall within section"); if (!NSec->GraphSection) { LLVM_DEBUG({ dbgs() << " Skipping: Symbol is in section " << NSec->SegName << "/" << NSec->SectName << " which has no associated graph section.\n"; }); continue; } } IndexToSymbol[SymbolIndex] = &createNormalizedSymbol(*Name, Value, Type, Sect, Desc, getLinkage(Desc), getScope(*Name, Type)); } return Error::success(); } void MachOLinkGraphBuilder::addSectionStartSymAndBlock( unsigned SecIndex, Section &GraphSec, orc::ExecutorAddr Address, const char *Data, orc::ExecutorAddrDiff Size, uint32_t Alignment, bool IsLive) { Block &B = Data ? G->createContentBlock(GraphSec, ArrayRef(Data, Size), Address, Alignment, 0) : G->createZeroFillBlock(GraphSec, Size, Address, Alignment, 0); auto &Sym = G->addAnonymousSymbol(B, 0, Size, false, IsLive); auto SecI = IndexToSection.find(SecIndex); assert(SecI != IndexToSection.end() && "SecIndex invalid"); auto &NSec = SecI->second; assert(!NSec.CanonicalSymbols.count(Sym.getAddress()) && "Anonymous block start symbol clashes with existing symbol address"); NSec.CanonicalSymbols[Sym.getAddress()] = &Sym; } Error MachOLinkGraphBuilder::graphifyRegularSymbols() { LLVM_DEBUG(dbgs() << "Creating graph symbols...\n"); /// We only have 256 section indexes: Use a vector rather than a map. std::vector> SecIndexToSymbols; SecIndexToSymbols.resize(256); // Create commons, externs, and absolutes, and partition all other symbols by // section. for (auto &KV : IndexToSymbol) { auto &NSym = *KV.second; switch (NSym.Type & MachO::N_TYPE) { case MachO::N_UNDF: if (NSym.Value) { if (!NSym.Name) return make_error("Anonymous common symbol at index " + Twine(KV.first)); NSym.GraphSymbol = &G->addDefinedSymbol( G->createZeroFillBlock(getCommonSection(), orc::ExecutorAddrDiff(NSym.Value), orc::ExecutorAddr(), 1ull << MachO::GET_COMM_ALIGN(NSym.Desc), 0), 0, *NSym.Name, orc::ExecutorAddrDiff(NSym.Value), Linkage::Strong, NSym.S, false, NSym.Desc & MachO::N_NO_DEAD_STRIP); } else { if (!NSym.Name) return make_error("Anonymous external symbol at " "index " + Twine(KV.first)); NSym.GraphSymbol = &G->addExternalSymbol( *NSym.Name, 0, (NSym.Desc & MachO::N_WEAK_REF) != 0); } break; case MachO::N_ABS: if (!NSym.Name) return make_error("Anonymous absolute symbol at index " + Twine(KV.first)); NSym.GraphSymbol = &G->addAbsoluteSymbol( *NSym.Name, orc::ExecutorAddr(NSym.Value), 0, Linkage::Strong, getScope(*NSym.Name, NSym.Type), NSym.Desc & MachO::N_NO_DEAD_STRIP); break; case MachO::N_SECT: SecIndexToSymbols[NSym.Sect - 1].push_back(&NSym); break; case MachO::N_PBUD: return make_error( "Unupported N_PBUD symbol " + (NSym.Name ? ("\"" + *NSym.Name + "\"") : Twine("")) + " at index " + Twine(KV.first)); case MachO::N_INDR: return make_error( "Unupported N_INDR symbol " + (NSym.Name ? ("\"" + *NSym.Name + "\"") : Twine("")) + " at index " + Twine(KV.first)); default: return make_error( "Unrecognized symbol type " + Twine(NSym.Type & MachO::N_TYPE) + " for symbol " + (NSym.Name ? ("\"" + *NSym.Name + "\"") : Twine("")) + " at index " + Twine(KV.first)); } } // Loop over sections performing regular graphification for those that // don't have custom parsers. for (auto &KV : IndexToSection) { auto SecIndex = KV.first; auto &NSec = KV.second; if (!NSec.GraphSection) { LLVM_DEBUG({ dbgs() << " " << NSec.SegName << "/" << NSec.SectName << " has no graph section. Skipping.\n"; }); continue; } // Skip sections with custom parsers. if (CustomSectionParserFunctions.count(NSec.GraphSection->getName())) { LLVM_DEBUG({ dbgs() << " Skipping section " << NSec.GraphSection->getName() << " as it has a custom parser.\n"; }); continue; } else if ((NSec.Flags & MachO::SECTION_TYPE) == MachO::S_CSTRING_LITERALS) { if (auto Err = graphifyCStringSection( NSec, std::move(SecIndexToSymbols[SecIndex]))) return Err; continue; } else LLVM_DEBUG({ dbgs() << " Graphifying regular section " << NSec.GraphSection->getName() << "...\n"; }); bool SectionIsNoDeadStrip = NSec.Flags & MachO::S_ATTR_NO_DEAD_STRIP; bool SectionIsText = NSec.Flags & MachO::S_ATTR_PURE_INSTRUCTIONS; auto &SecNSymStack = SecIndexToSymbols[SecIndex]; // If this section is non-empty but there are no symbols covering it then // create one block and anonymous symbol to cover the entire section. if (SecNSymStack.empty()) { if (NSec.Size > 0) { LLVM_DEBUG({ dbgs() << " Section non-empty, but contains no symbols. " "Creating anonymous block to cover " << formatv("{0:x16}", NSec.Address) << " -- " << formatv("{0:x16}", NSec.Address + NSec.Size) << "\n"; }); addSectionStartSymAndBlock(SecIndex, *NSec.GraphSection, NSec.Address, NSec.Data, NSec.Size, NSec.Alignment, SectionIsNoDeadStrip); } else LLVM_DEBUG({ dbgs() << " Section empty and contains no symbols. Skipping.\n"; }); continue; } // Sort the symbol stack in by address, alt-entry status, scope, and name. // We sort in reverse order so that symbols will be visited in the right // order when we pop off the stack below. llvm::sort(SecNSymStack, [](const NormalizedSymbol *LHS, const NormalizedSymbol *RHS) { if (LHS->Value != RHS->Value) return LHS->Value > RHS->Value; if (isAltEntry(*LHS) != isAltEntry(*RHS)) return isAltEntry(*RHS); if (LHS->S != RHS->S) return static_cast(LHS->S) < static_cast(RHS->S); return LHS->Name < RHS->Name; }); // The first symbol in a section can not be an alt-entry symbol. if (!SecNSymStack.empty() && isAltEntry(*SecNSymStack.back())) return make_error( "First symbol in " + NSec.GraphSection->getName() + " is alt-entry"); // If the section is non-empty but there is no symbol covering the start // address then add an anonymous one. if (orc::ExecutorAddr(SecNSymStack.back()->Value) != NSec.Address) { auto AnonBlockSize = orc::ExecutorAddr(SecNSymStack.back()->Value) - NSec.Address; LLVM_DEBUG({ dbgs() << " Section start not covered by symbol. " << "Creating anonymous block to cover [ " << NSec.Address << " -- " << (NSec.Address + AnonBlockSize) << " ]\n"; }); addSectionStartSymAndBlock(SecIndex, *NSec.GraphSection, NSec.Address, NSec.Data, AnonBlockSize, NSec.Alignment, SectionIsNoDeadStrip); } // Visit section symbols in order by popping off the reverse-sorted stack, // building graph symbols as we go. // // If MH_SUBSECTIONS_VIA_SYMBOLS is set we'll build a block for each // alt-entry chain. // // If MH_SUBSECTIONS_VIA_SYMBOLS is not set then we'll just build one block // for the whole section. while (!SecNSymStack.empty()) { SmallVector BlockSyms; // Get the symbols in this alt-entry chain, or the whole section (if // !SubsectionsViaSymbols). BlockSyms.push_back(SecNSymStack.back()); SecNSymStack.pop_back(); while (!SecNSymStack.empty() && (isAltEntry(*SecNSymStack.back()) || SecNSymStack.back()->Value == BlockSyms.back()->Value || !SubsectionsViaSymbols)) { BlockSyms.push_back(SecNSymStack.back()); SecNSymStack.pop_back(); } // BlockNSyms now contains the block symbols in reverse canonical order. auto BlockStart = orc::ExecutorAddr(BlockSyms.front()->Value); orc::ExecutorAddr BlockEnd = SecNSymStack.empty() ? NSec.Address + NSec.Size : orc::ExecutorAddr(SecNSymStack.back()->Value); orc::ExecutorAddrDiff BlockOffset = BlockStart - NSec.Address; orc::ExecutorAddrDiff BlockSize = BlockEnd - BlockStart; LLVM_DEBUG({ dbgs() << " Creating block for " << formatv("{0:x16}", BlockStart) << " -- " << formatv("{0:x16}", BlockEnd) << ": " << NSec.GraphSection->getName() << " + " << formatv("{0:x16}", BlockOffset) << " with " << BlockSyms.size() << " symbol(s)...\n"; }); Block &B = NSec.Data ? G->createContentBlock( *NSec.GraphSection, ArrayRef(NSec.Data + BlockOffset, BlockSize), BlockStart, NSec.Alignment, BlockStart % NSec.Alignment) : G->createZeroFillBlock(*NSec.GraphSection, BlockSize, BlockStart, NSec.Alignment, BlockStart % NSec.Alignment); std::optional LastCanonicalAddr; auto SymEnd = BlockEnd; while (!BlockSyms.empty()) { auto &NSym = *BlockSyms.back(); BlockSyms.pop_back(); bool SymLive = (NSym.Desc & MachO::N_NO_DEAD_STRIP) || SectionIsNoDeadStrip; auto &Sym = createStandardGraphSymbol( NSym, B, SymEnd - orc::ExecutorAddr(NSym.Value), SectionIsText, SymLive, LastCanonicalAddr != orc::ExecutorAddr(NSym.Value)); if (LastCanonicalAddr != Sym.getAddress()) { if (LastCanonicalAddr) SymEnd = *LastCanonicalAddr; LastCanonicalAddr = Sym.getAddress(); } } } } return Error::success(); } Symbol &MachOLinkGraphBuilder::createStandardGraphSymbol(NormalizedSymbol &NSym, Block &B, size_t Size, bool IsText, bool IsNoDeadStrip, bool IsCanonical) { LLVM_DEBUG({ dbgs() << " " << formatv("{0:x16}", NSym.Value) << " -- " << formatv("{0:x16}", NSym.Value + Size) << ": "; if (!NSym.Name) dbgs() << ""; else dbgs() << NSym.Name; if (IsText) dbgs() << " [text]"; if (IsNoDeadStrip) dbgs() << " [no-dead-strip]"; if (!IsCanonical) dbgs() << " [non-canonical]"; dbgs() << "\n"; }); auto SymOffset = orc::ExecutorAddr(NSym.Value) - B.getAddress(); auto &Sym = NSym.Name ? G->addDefinedSymbol(B, SymOffset, *NSym.Name, Size, NSym.L, NSym.S, IsText, IsNoDeadStrip) : G->addAnonymousSymbol(B, SymOffset, Size, IsText, IsNoDeadStrip); NSym.GraphSymbol = &Sym; if (IsCanonical) setCanonicalSymbol(getSectionByIndex(NSym.Sect - 1), Sym); return Sym; } Error MachOLinkGraphBuilder::graphifySectionsWithCustomParsers() { // Graphify special sections. for (auto &KV : IndexToSection) { auto &NSec = KV.second; // Skip non-graph sections. if (!NSec.GraphSection) continue; auto HI = CustomSectionParserFunctions.find(NSec.GraphSection->getName()); if (HI != CustomSectionParserFunctions.end()) { auto &Parse = HI->second; if (auto Err = Parse(NSec)) return Err; } } return Error::success(); } Error MachOLinkGraphBuilder::graphifyCStringSection( NormalizedSection &NSec, std::vector NSyms) { assert(NSec.GraphSection && "C string literal section missing graph section"); assert(NSec.Data && "C string literal section has no data"); LLVM_DEBUG({ dbgs() << " Graphifying C-string literal section " << NSec.GraphSection->getName() << "\n"; }); if (NSec.Data[NSec.Size - 1] != '\0') return make_error("C string literal section " + NSec.GraphSection->getName() + " does not end with null terminator"); /// Sort into reverse order to use as a stack. llvm::sort(NSyms, [](const NormalizedSymbol *LHS, const NormalizedSymbol *RHS) { if (LHS->Value != RHS->Value) return LHS->Value > RHS->Value; if (LHS->L != RHS->L) return LHS->L > RHS->L; if (LHS->S != RHS->S) return LHS->S > RHS->S; if (RHS->Name) { if (!LHS->Name) return true; return *LHS->Name > *RHS->Name; } return false; }); bool SectionIsNoDeadStrip = NSec.Flags & MachO::S_ATTR_NO_DEAD_STRIP; bool SectionIsText = NSec.Flags & MachO::S_ATTR_PURE_INSTRUCTIONS; orc::ExecutorAddrDiff BlockStart = 0; // Scan section for null characters. for (size_t I = 0; I != NSec.Size; ++I) if (NSec.Data[I] == '\0') { size_t BlockSize = I + 1 - BlockStart; // Create a block for this null terminated string. auto &B = G->createContentBlock(*NSec.GraphSection, {NSec.Data + BlockStart, BlockSize}, NSec.Address + BlockStart, NSec.Alignment, BlockStart % NSec.Alignment); LLVM_DEBUG({ dbgs() << " Created block " << B.getRange() << ", align = " << B.getAlignment() << ", align-ofs = " << B.getAlignmentOffset() << " for \""; for (size_t J = 0; J != std::min(B.getSize(), size_t(16)); ++J) switch (B.getContent()[J]) { case '\0': break; case '\n': dbgs() << "\\n"; break; case '\t': dbgs() << "\\t"; break; default: dbgs() << B.getContent()[J]; break; } if (B.getSize() > 16) dbgs() << "..."; dbgs() << "\"\n"; }); // If there's no symbol at the start of this block then create one. if (NSyms.empty() || orc::ExecutorAddr(NSyms.back()->Value) != B.getAddress()) { auto &S = G->addAnonymousSymbol(B, 0, BlockSize, false, false); setCanonicalSymbol(NSec, S); LLVM_DEBUG({ dbgs() << " Adding symbol for c-string block " << B.getRange() << ": at offset 0\n"; }); } // Process any remaining symbols that point into this block. auto LastCanonicalAddr = B.getAddress() + BlockSize; while (!NSyms.empty() && orc::ExecutorAddr(NSyms.back()->Value) < B.getAddress() + BlockSize) { auto &NSym = *NSyms.back(); size_t SymSize = (B.getAddress() + BlockSize) - orc::ExecutorAddr(NSyms.back()->Value); bool SymLive = (NSym.Desc & MachO::N_NO_DEAD_STRIP) || SectionIsNoDeadStrip; bool IsCanonical = false; if (LastCanonicalAddr != orc::ExecutorAddr(NSym.Value)) { IsCanonical = true; LastCanonicalAddr = orc::ExecutorAddr(NSym.Value); } auto &Sym = createStandardGraphSymbol(NSym, B, SymSize, SectionIsText, SymLive, IsCanonical); (void)Sym; LLVM_DEBUG({ dbgs() << " Adding symbol for c-string block " << B.getRange() << ": " << (Sym.hasName() ? Sym.getName() : "") << " at offset " << formatv("{0:x}", Sym.getOffset()) << "\n"; }); NSyms.pop_back(); } BlockStart += BlockSize; } return Error::success(); } Error CompactUnwindSplitter::operator()(LinkGraph &G) { auto *CUSec = G.findSectionByName(CompactUnwindSectionName); if (!CUSec) return Error::success(); if (!G.getTargetTriple().isOSBinFormatMachO()) return make_error( "Error linking " + G.getName() + ": compact unwind splitting not supported on non-macho target " + G.getTargetTriple().str()); unsigned CURecordSize = 0; unsigned PersonalityEdgeOffset = 0; unsigned LSDAEdgeOffset = 0; switch (G.getTargetTriple().getArch()) { case Triple::aarch64: case Triple::x86_64: // 64-bit compact-unwind record format: // Range start: 8 bytes. // Range size: 4 bytes. // CU encoding: 4 bytes. // Personality: 8 bytes. // LSDA: 8 bytes. CURecordSize = 32; PersonalityEdgeOffset = 16; LSDAEdgeOffset = 24; break; default: return make_error( "Error linking " + G.getName() + ": compact unwind splitting not supported on " + G.getTargetTriple().getArchName()); } std::vector OriginalBlocks(CUSec->blocks().begin(), CUSec->blocks().end()); LLVM_DEBUG({ dbgs() << "In " << G.getName() << " splitting compact unwind section " << CompactUnwindSectionName << " containing " << OriginalBlocks.size() << " initial blocks...\n"; }); while (!OriginalBlocks.empty()) { auto *B = OriginalBlocks.back(); OriginalBlocks.pop_back(); if (B->getSize() == 0) { LLVM_DEBUG({ dbgs() << " Skipping empty block at " << formatv("{0:x16}", B->getAddress()) << "\n"; }); continue; } LLVM_DEBUG({ dbgs() << " Splitting block at " << formatv("{0:x16}", B->getAddress()) << " into " << (B->getSize() / CURecordSize) << " compact unwind record(s)\n"; }); if (B->getSize() % CURecordSize) return make_error( "Error splitting compact unwind record in " + G.getName() + ": block at " + formatv("{0:x}", B->getAddress()) + " has size " + formatv("{0:x}", B->getSize()) + " (not a multiple of CU record size of " + formatv("{0:x}", CURecordSize) + ")"); unsigned NumBlocks = B->getSize() / CURecordSize; LinkGraph::SplitBlockCache C; for (unsigned I = 0; I != NumBlocks; ++I) { auto &CURec = G.splitBlock(*B, CURecordSize, &C); bool AddedKeepAlive = false; for (auto &E : CURec.edges()) { if (E.getOffset() == 0) { LLVM_DEBUG({ dbgs() << " Updating compact unwind record at " << formatv("{0:x16}", CURec.getAddress()) << " to point to " << (E.getTarget().hasName() ? E.getTarget().getName() : StringRef()) << " (at " << formatv("{0:x16}", E.getTarget().getAddress()) << ")\n"; }); if (E.getTarget().isExternal()) return make_error( "Error adding keep-alive edge for compact unwind record at " + formatv("{0:x}", CURec.getAddress()) + ": target " + E.getTarget().getName() + " is an external symbol"); auto &TgtBlock = E.getTarget().getBlock(); auto &CURecSym = G.addAnonymousSymbol(CURec, 0, CURecordSize, false, false); TgtBlock.addEdge(Edge::KeepAlive, 0, CURecSym, 0); AddedKeepAlive = true; } else if (E.getOffset() != PersonalityEdgeOffset && E.getOffset() != LSDAEdgeOffset) return make_error("Unexpected edge at offset " + formatv("{0:x}", E.getOffset()) + " in compact unwind record at " + formatv("{0:x}", CURec.getAddress())); } if (!AddedKeepAlive) return make_error( "Error adding keep-alive edge for compact unwind record at " + formatv("{0:x}", CURec.getAddress()) + ": no outgoing target edge at offset 0"); } } return Error::success(); } } // end namespace jitlink } // end namespace llvm