//===-- llvm-objdump.cpp - Object file dumping utility for llvm -----------===// // // 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 // //===----------------------------------------------------------------------===// // // This program is a utility that works like binutils "objdump", that is, it // dumps out a plethora of information about an object file depending on the // flags. // // The flags and output of this program should be near identical to those of // binutils objdump. // //===----------------------------------------------------------------------===// #include "llvm-objdump.h" #include "COFFDump.h" #include "ELFDump.h" #include "MachODump.h" #include "WasmDump.h" #include "XCOFFDump.h" #include "llvm/ADT/IndexedMap.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/STLExtras.h" #include "llvm/ADT/SetOperations.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringSet.h" #include "llvm/ADT/Triple.h" #include "llvm/CodeGen/FaultMaps.h" #include "llvm/DebugInfo/DWARF/DWARFContext.h" #include "llvm/DebugInfo/Symbolize/Symbolize.h" #include "llvm/Demangle/Demangle.h" #include "llvm/MC/MCAsmInfo.h" #include "llvm/MC/MCContext.h" #include "llvm/MC/MCDisassembler/MCDisassembler.h" #include "llvm/MC/MCDisassembler/MCRelocationInfo.h" #include "llvm/MC/MCInst.h" #include "llvm/MC/MCInstPrinter.h" #include "llvm/MC/MCInstrAnalysis.h" #include "llvm/MC/MCInstrInfo.h" #include "llvm/MC/MCObjectFileInfo.h" #include "llvm/MC/MCRegisterInfo.h" #include "llvm/MC/MCSubtargetInfo.h" #include "llvm/MC/MCTargetOptions.h" #include "llvm/Object/Archive.h" #include "llvm/Object/COFF.h" #include "llvm/Object/COFFImportFile.h" #include "llvm/Object/ELFObjectFile.h" #include "llvm/Object/MachO.h" #include "llvm/Object/MachOUniversal.h" #include "llvm/Object/ObjectFile.h" #include "llvm/Object/Wasm.h" #include "llvm/Support/Casting.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/Errc.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/Format.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/GraphWriter.h" #include "llvm/Support/Host.h" #include "llvm/Support/InitLLVM.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/SourceMgr.h" #include "llvm/Support/StringSaver.h" #include "llvm/Support/TargetRegistry.h" #include "llvm/Support/TargetSelect.h" #include "llvm/Support/WithColor.h" #include "llvm/Support/raw_ostream.h" #include #include #include #include #include #include using namespace llvm; using namespace llvm::object; using namespace llvm::objdump; #define DEBUG_TYPE "objdump" static cl::OptionCategory ObjdumpCat("llvm-objdump Options"); static cl::opt AdjustVMA( "adjust-vma", cl::desc("Increase the displayed address by the specified offset"), cl::value_desc("offset"), cl::init(0), cl::cat(ObjdumpCat)); static cl::opt AllHeaders("all-headers", cl::desc("Display all available header information"), cl::cat(ObjdumpCat)); static cl::alias AllHeadersShort("x", cl::desc("Alias for --all-headers"), cl::NotHidden, cl::Grouping, cl::aliasopt(AllHeaders)); static cl::opt ArchName("arch-name", cl::desc("Target arch to disassemble for, " "see -version for available targets"), cl::cat(ObjdumpCat)); cl::opt objdump::ArchiveHeaders("archive-headers", cl::desc("Display archive header information"), cl::cat(ObjdumpCat)); static cl::alias ArchiveHeadersShort("a", cl::desc("Alias for --archive-headers"), cl::NotHidden, cl::Grouping, cl::aliasopt(ArchiveHeaders)); cl::opt objdump::Demangle("demangle", cl::desc("Demangle symbols names"), cl::init(false), cl::cat(ObjdumpCat)); static cl::alias DemangleShort("C", cl::desc("Alias for --demangle"), cl::NotHidden, cl::Grouping, cl::aliasopt(Demangle)); cl::opt objdump::Disassemble( "disassemble", cl::desc("Display assembler mnemonics for the machine instructions"), cl::cat(ObjdumpCat)); static cl::alias DisassembleShort("d", cl::desc("Alias for --disassemble"), cl::NotHidden, cl::Grouping, cl::aliasopt(Disassemble)); cl::opt objdump::DisassembleAll( "disassemble-all", cl::desc("Display assembler mnemonics for the machine instructions"), cl::cat(ObjdumpCat)); static cl::alias DisassembleAllShort("D", cl::desc("Alias for --disassemble-all"), cl::NotHidden, cl::Grouping, cl::aliasopt(DisassembleAll)); cl::opt objdump::SymbolDescription( "symbol-description", cl::desc("Add symbol description for disassembly. This " "option is for XCOFF files only"), cl::init(false), cl::cat(ObjdumpCat)); static cl::list DisassembleSymbols("disassemble-symbols", cl::CommaSeparated, cl::desc("List of symbols to disassemble. " "Accept demangled names when --demangle is " "specified, otherwise accept mangled names"), cl::cat(ObjdumpCat)); static cl::opt DisassembleZeroes( "disassemble-zeroes", cl::desc("Do not skip blocks of zeroes when disassembling"), cl::cat(ObjdumpCat)); static cl::alias DisassembleZeroesShort("z", cl::desc("Alias for --disassemble-zeroes"), cl::NotHidden, cl::Grouping, cl::aliasopt(DisassembleZeroes)); static cl::list DisassemblerOptions("disassembler-options", cl::desc("Pass target specific disassembler options"), cl::value_desc("options"), cl::CommaSeparated, cl::cat(ObjdumpCat)); static cl::alias DisassemblerOptionsShort("M", cl::desc("Alias for --disassembler-options"), cl::NotHidden, cl::Grouping, cl::Prefix, cl::CommaSeparated, cl::aliasopt(DisassemblerOptions)); cl::opt objdump::DwarfDumpType( "dwarf", cl::init(DIDT_Null), cl::desc("Dump of dwarf debug sections:"), cl::values(clEnumValN(DIDT_DebugFrame, "frames", ".debug_frame")), cl::cat(ObjdumpCat)); static cl::opt DynamicRelocations( "dynamic-reloc", cl::desc("Display the dynamic relocation entries in the file"), cl::cat(ObjdumpCat)); static cl::alias DynamicRelocationShort("R", cl::desc("Alias for --dynamic-reloc"), cl::NotHidden, cl::Grouping, cl::aliasopt(DynamicRelocations)); static cl::opt FaultMapSection("fault-map-section", cl::desc("Display contents of faultmap section"), cl::cat(ObjdumpCat)); static cl::opt FileHeaders("file-headers", cl::desc("Display the contents of the overall file header"), cl::cat(ObjdumpCat)); static cl::alias FileHeadersShort("f", cl::desc("Alias for --file-headers"), cl::NotHidden, cl::Grouping, cl::aliasopt(FileHeaders)); cl::opt objdump::SectionContents("full-contents", cl::desc("Display the content of each section"), cl::cat(ObjdumpCat)); static cl::alias SectionContentsShort("s", cl::desc("Alias for --full-contents"), cl::NotHidden, cl::Grouping, cl::aliasopt(SectionContents)); static cl::list InputFilenames(cl::Positional, cl::desc(""), cl::ZeroOrMore, cl::cat(ObjdumpCat)); static cl::opt PrintLines("line-numbers", cl::desc("Display source line numbers with " "disassembly. Implies disassemble object"), cl::cat(ObjdumpCat)); static cl::alias PrintLinesShort("l", cl::desc("Alias for --line-numbers"), cl::NotHidden, cl::Grouping, cl::aliasopt(PrintLines)); static cl::opt MachOOpt("macho", cl::desc("Use MachO specific object file parser"), cl::cat(ObjdumpCat)); static cl::alias MachOm("m", cl::desc("Alias for --macho"), cl::NotHidden, cl::Grouping, cl::aliasopt(MachOOpt)); cl::opt objdump::MCPU( "mcpu", cl::desc("Target a specific cpu type (-mcpu=help for details)"), cl::value_desc("cpu-name"), cl::init(""), cl::cat(ObjdumpCat)); cl::list objdump::MAttrs("mattr", cl::CommaSeparated, cl::desc("Target specific attributes"), cl::value_desc("a1,+a2,-a3,..."), cl::cat(ObjdumpCat)); cl::opt objdump::NoShowRawInsn( "no-show-raw-insn", cl::desc( "When disassembling instructions, do not print the instruction bytes."), cl::cat(ObjdumpCat)); cl::opt objdump::NoLeadingAddr("no-leading-addr", cl::desc("Print no leading address"), cl::cat(ObjdumpCat)); static cl::opt RawClangAST( "raw-clang-ast", cl::desc("Dump the raw binary contents of the clang AST section"), cl::cat(ObjdumpCat)); cl::opt objdump::Relocations("reloc", cl::desc("Display the relocation entries in the file"), cl::cat(ObjdumpCat)); static cl::alias RelocationsShort("r", cl::desc("Alias for --reloc"), cl::NotHidden, cl::Grouping, cl::aliasopt(Relocations)); cl::opt objdump::PrintImmHex("print-imm-hex", cl::desc("Use hex format for immediate values"), cl::cat(ObjdumpCat)); cl::opt objdump::PrivateHeaders("private-headers", cl::desc("Display format specific file headers"), cl::cat(ObjdumpCat)); static cl::alias PrivateHeadersShort("p", cl::desc("Alias for --private-headers"), cl::NotHidden, cl::Grouping, cl::aliasopt(PrivateHeaders)); cl::list objdump::FilterSections("section", cl::desc("Operate on the specified sections only. " "With -macho dump segment,section"), cl::cat(ObjdumpCat)); static cl::alias FilterSectionsj("j", cl::desc("Alias for --section"), cl::NotHidden, cl::Grouping, cl::Prefix, cl::aliasopt(FilterSections)); cl::opt objdump::SectionHeaders( "section-headers", cl::desc("Display summaries of the headers for each section."), cl::cat(ObjdumpCat)); static cl::alias SectionHeadersShort("headers", cl::desc("Alias for --section-headers"), cl::NotHidden, cl::aliasopt(SectionHeaders)); static cl::alias SectionHeadersShorter("h", cl::desc("Alias for --section-headers"), cl::NotHidden, cl::Grouping, cl::aliasopt(SectionHeaders)); static cl::opt ShowLMA("show-lma", cl::desc("Display LMA column when dumping ELF section headers"), cl::cat(ObjdumpCat)); static cl::opt PrintSource( "source", cl::desc( "Display source inlined with disassembly. Implies disassemble object"), cl::cat(ObjdumpCat)); static cl::alias PrintSourceShort("S", cl::desc("Alias for -source"), cl::NotHidden, cl::Grouping, cl::aliasopt(PrintSource)); static cl::opt StartAddress("start-address", cl::desc("Disassemble beginning at address"), cl::value_desc("address"), cl::init(0), cl::cat(ObjdumpCat)); static cl::opt StopAddress("stop-address", cl::desc("Stop disassembly at address"), cl::value_desc("address"), cl::init(UINT64_MAX), cl::cat(ObjdumpCat)); cl::opt objdump::SymbolTable("syms", cl::desc("Display the symbol table"), cl::cat(ObjdumpCat)); static cl::alias SymbolTableShort("t", cl::desc("Alias for --syms"), cl::NotHidden, cl::Grouping, cl::aliasopt(SymbolTable)); static cl::opt DynamicSymbolTable( "dynamic-syms", cl::desc("Display the contents of the dynamic symbol table"), cl::cat(ObjdumpCat)); static cl::alias DynamicSymbolTableShort("T", cl::desc("Alias for --dynamic-syms"), cl::NotHidden, cl::Grouping, cl::aliasopt(DynamicSymbolTable)); cl::opt objdump::TripleName( "triple", cl::desc( "Target triple to disassemble for, see -version for available targets"), cl::cat(ObjdumpCat)); cl::opt objdump::UnwindInfo("unwind-info", cl::desc("Display unwind information"), cl::cat(ObjdumpCat)); static cl::alias UnwindInfoShort("u", cl::desc("Alias for --unwind-info"), cl::NotHidden, cl::Grouping, cl::aliasopt(UnwindInfo)); static cl::opt Wide("wide", cl::desc("Ignored for compatibility with GNU objdump"), cl::cat(ObjdumpCat)); static cl::alias WideShort("w", cl::Grouping, cl::aliasopt(Wide)); enum DebugVarsFormat { DVDisabled, DVUnicode, DVASCII, }; static cl::opt DbgVariables( "debug-vars", cl::init(DVDisabled), cl::desc("Print the locations (in registers or memory) of " "source-level variables alongside disassembly"), cl::ValueOptional, cl::values(clEnumValN(DVUnicode, "", "unicode"), clEnumValN(DVUnicode, "unicode", "unicode"), clEnumValN(DVASCII, "ascii", "unicode")), cl::cat(ObjdumpCat)); static cl::opt DbgIndent("debug-vars-indent", cl::init(40), cl::desc("Distance to indent the source-level variable display, " "relative to the start of the disassembly"), cl::cat(ObjdumpCat)); static cl::extrahelp HelpResponse("\nPass @FILE as argument to read options from FILE.\n"); static StringSet<> DisasmSymbolSet; StringSet<> objdump::FoundSectionSet; static StringRef ToolName; namespace { struct FilterResult { // True if the section should not be skipped. bool Keep; // True if the index counter should be incremented, even if the section should // be skipped. For example, sections may be skipped if they are not included // in the --section flag, but we still want those to count toward the section // count. bool IncrementIndex; }; } // namespace static FilterResult checkSectionFilter(object::SectionRef S) { if (FilterSections.empty()) return {/*Keep=*/true, /*IncrementIndex=*/true}; Expected SecNameOrErr = S.getName(); if (!SecNameOrErr) { consumeError(SecNameOrErr.takeError()); return {/*Keep=*/false, /*IncrementIndex=*/false}; } StringRef SecName = *SecNameOrErr; // StringSet does not allow empty key so avoid adding sections with // no name (such as the section with index 0) here. if (!SecName.empty()) FoundSectionSet.insert(SecName); // Only show the section if it's in the FilterSections list, but always // increment so the indexing is stable. return {/*Keep=*/is_contained(FilterSections, SecName), /*IncrementIndex=*/true}; } SectionFilter objdump::ToolSectionFilter(object::ObjectFile const &O, uint64_t *Idx) { // Start at UINT64_MAX so that the first index returned after an increment is // zero (after the unsigned wrap). if (Idx) *Idx = UINT64_MAX; return SectionFilter( [Idx](object::SectionRef S) { FilterResult Result = checkSectionFilter(S); if (Idx != nullptr && Result.IncrementIndex) *Idx += 1; return Result.Keep; }, O); } std::string objdump::getFileNameForError(const object::Archive::Child &C, unsigned Index) { Expected NameOrErr = C.getName(); if (NameOrErr) return std::string(NameOrErr.get()); // If we have an error getting the name then we print the index of the archive // member. Since we are already in an error state, we just ignore this error. consumeError(NameOrErr.takeError()); return ""; } void objdump::reportWarning(Twine Message, StringRef File) { // Output order between errs() and outs() matters especially for archive // files where the output is per member object. outs().flush(); WithColor::warning(errs(), ToolName) << "'" << File << "': " << Message << "\n"; } LLVM_ATTRIBUTE_NORETURN void objdump::reportError(StringRef File, Twine Message) { outs().flush(); WithColor::error(errs(), ToolName) << "'" << File << "': " << Message << "\n"; exit(1); } LLVM_ATTRIBUTE_NORETURN void objdump::reportError(Error E, StringRef FileName, StringRef ArchiveName, StringRef ArchitectureName) { assert(E); outs().flush(); WithColor::error(errs(), ToolName); if (ArchiveName != "") errs() << ArchiveName << "(" << FileName << ")"; else errs() << "'" << FileName << "'"; if (!ArchitectureName.empty()) errs() << " (for architecture " << ArchitectureName << ")"; errs() << ": "; logAllUnhandledErrors(std::move(E), errs()); exit(1); } static void reportCmdLineWarning(Twine Message) { WithColor::warning(errs(), ToolName) << Message << "\n"; } LLVM_ATTRIBUTE_NORETURN static void reportCmdLineError(Twine Message) { WithColor::error(errs(), ToolName) << Message << "\n"; exit(1); } static void warnOnNoMatchForSections() { SetVector MissingSections; for (StringRef S : FilterSections) { if (FoundSectionSet.count(S)) return; // User may specify a unnamed section. Don't warn for it. if (!S.empty()) MissingSections.insert(S); } // Warn only if no section in FilterSections is matched. for (StringRef S : MissingSections) reportCmdLineWarning("section '" + S + "' mentioned in a -j/--section option, but not " "found in any input file"); } static const Target *getTarget(const ObjectFile *Obj) { // Figure out the target triple. Triple TheTriple("unknown-unknown-unknown"); if (TripleName.empty()) { TheTriple = Obj->makeTriple(); } else { TheTriple.setTriple(Triple::normalize(TripleName)); auto Arch = Obj->getArch(); if (Arch == Triple::arm || Arch == Triple::armeb) Obj->setARMSubArch(TheTriple); } // Get the target specific parser. std::string Error; const Target *TheTarget = TargetRegistry::lookupTarget(ArchName, TheTriple, Error); if (!TheTarget) reportError(Obj->getFileName(), "can't find target: " + Error); // Update the triple name and return the found target. TripleName = TheTriple.getTriple(); return TheTarget; } bool objdump::isRelocAddressLess(RelocationRef A, RelocationRef B) { return A.getOffset() < B.getOffset(); } static Error getRelocationValueString(const RelocationRef &Rel, SmallVectorImpl &Result) { const ObjectFile *Obj = Rel.getObject(); if (auto *ELF = dyn_cast(Obj)) return getELFRelocationValueString(ELF, Rel, Result); if (auto *COFF = dyn_cast(Obj)) return getCOFFRelocationValueString(COFF, Rel, Result); if (auto *Wasm = dyn_cast(Obj)) return getWasmRelocationValueString(Wasm, Rel, Result); if (auto *MachO = dyn_cast(Obj)) return getMachORelocationValueString(MachO, Rel, Result); if (auto *XCOFF = dyn_cast(Obj)) return getXCOFFRelocationValueString(XCOFF, Rel, Result); llvm_unreachable("unknown object file format"); } /// Indicates whether this relocation should hidden when listing /// relocations, usually because it is the trailing part of a multipart /// relocation that will be printed as part of the leading relocation. static bool getHidden(RelocationRef RelRef) { auto *MachO = dyn_cast(RelRef.getObject()); if (!MachO) return false; unsigned Arch = MachO->getArch(); DataRefImpl Rel = RelRef.getRawDataRefImpl(); uint64_t Type = MachO->getRelocationType(Rel); // On arches that use the generic relocations, GENERIC_RELOC_PAIR // is always hidden. if (Arch == Triple::x86 || Arch == Triple::arm || Arch == Triple::ppc) return Type == MachO::GENERIC_RELOC_PAIR; if (Arch == Triple::x86_64) { // On x86_64, X86_64_RELOC_UNSIGNED is hidden only when it follows // an X86_64_RELOC_SUBTRACTOR. if (Type == MachO::X86_64_RELOC_UNSIGNED && Rel.d.a > 0) { DataRefImpl RelPrev = Rel; RelPrev.d.a--; uint64_t PrevType = MachO->getRelocationType(RelPrev); if (PrevType == MachO::X86_64_RELOC_SUBTRACTOR) return true; } } return false; } namespace { /// Get the column at which we want to start printing the instruction /// disassembly, taking into account anything which appears to the left of it. unsigned getInstStartColumn(const MCSubtargetInfo &STI) { return NoShowRawInsn ? 16 : STI.getTargetTriple().isX86() ? 40 : 24; } /// Stores a single expression representing the location of a source-level /// variable, along with the PC range for which that expression is valid. struct LiveVariable { DWARFLocationExpression LocExpr; const char *VarName; DWARFUnit *Unit; const DWARFDie FuncDie; LiveVariable(const DWARFLocationExpression &LocExpr, const char *VarName, DWARFUnit *Unit, const DWARFDie FuncDie) : LocExpr(LocExpr), VarName(VarName), Unit(Unit), FuncDie(FuncDie) {} bool liveAtAddress(object::SectionedAddress Addr) { if (LocExpr.Range == None) return false; return LocExpr.Range->SectionIndex == Addr.SectionIndex && LocExpr.Range->LowPC <= Addr.Address && LocExpr.Range->HighPC > Addr.Address; } void print(raw_ostream &OS, const MCRegisterInfo &MRI) const { DataExtractor Data({LocExpr.Expr.data(), LocExpr.Expr.size()}, Unit->getContext().isLittleEndian(), 0); DWARFExpression Expression(Data, Unit->getAddressByteSize()); Expression.printCompact(OS, MRI); } }; /// Helper class for printing source variable locations alongside disassembly. class LiveVariablePrinter { // Information we want to track about one column in which we are printing a // variable live range. struct Column { unsigned VarIdx = NullVarIdx; bool LiveIn = false; bool LiveOut = false; bool MustDrawLabel = false; bool isActive() const { return VarIdx != NullVarIdx; } static constexpr unsigned NullVarIdx = std::numeric_limits::max(); }; // All live variables we know about in the object/image file. std::vector LiveVariables; // The columns we are currently drawing. IndexedMap ActiveCols; const MCRegisterInfo &MRI; const MCSubtargetInfo &STI; void addVariable(DWARFDie FuncDie, DWARFDie VarDie) { uint64_t FuncLowPC, FuncHighPC, SectionIndex; FuncDie.getLowAndHighPC(FuncLowPC, FuncHighPC, SectionIndex); const char *VarName = VarDie.getName(DINameKind::ShortName); DWARFUnit *U = VarDie.getDwarfUnit(); Expected Locs = VarDie.getLocations(dwarf::DW_AT_location); if (!Locs) { // If the variable doesn't have any locations, just ignore it. We don't // report an error or warning here as that could be noisy on optimised // code. consumeError(Locs.takeError()); return; } for (const DWARFLocationExpression &LocExpr : *Locs) { if (LocExpr.Range) { LiveVariables.emplace_back(LocExpr, VarName, U, FuncDie); } else { // If the LocExpr does not have an associated range, it is valid for // the whole of the function. // TODO: technically it is not valid for any range covered by another // LocExpr, does that happen in reality? DWARFLocationExpression WholeFuncExpr{ DWARFAddressRange(FuncLowPC, FuncHighPC, SectionIndex), LocExpr.Expr}; LiveVariables.emplace_back(WholeFuncExpr, VarName, U, FuncDie); } } } void addFunction(DWARFDie D) { for (const DWARFDie &Child : D.children()) { if (Child.getTag() == dwarf::DW_TAG_variable || Child.getTag() == dwarf::DW_TAG_formal_parameter) addVariable(D, Child); else addFunction(Child); } } // Get the column number (in characters) at which the first live variable // line should be printed. unsigned getIndentLevel() const { return DbgIndent + getInstStartColumn(STI); } // Indent to the first live-range column to the right of the currently // printed line, and return the index of that column. // TODO: formatted_raw_ostream uses "column" to mean a number of characters // since the last \n, and we use it to mean the number of slots in which we // put live variable lines. Pick a less overloaded word. unsigned moveToFirstVarColumn(formatted_raw_ostream &OS) { // Logical column number: column zero is the first column we print in, each // logical column is 2 physical columns wide. unsigned FirstUnprintedLogicalColumn = std::max((int)(OS.getColumn() - getIndentLevel() + 1) / 2, 0); // Physical column number: the actual column number in characters, with // zero being the left-most side of the screen. unsigned FirstUnprintedPhysicalColumn = getIndentLevel() + FirstUnprintedLogicalColumn * 2; if (FirstUnprintedPhysicalColumn > OS.getColumn()) OS.PadToColumn(FirstUnprintedPhysicalColumn); return FirstUnprintedLogicalColumn; } unsigned findFreeColumn() { for (unsigned ColIdx = 0; ColIdx < ActiveCols.size(); ++ColIdx) if (!ActiveCols[ColIdx].isActive()) return ColIdx; size_t OldSize = ActiveCols.size(); ActiveCols.grow(std::max(OldSize * 2, 1)); return OldSize; } public: LiveVariablePrinter(const MCRegisterInfo &MRI, const MCSubtargetInfo &STI) : LiveVariables(), ActiveCols(Column()), MRI(MRI), STI(STI) {} void dump() const { for (const LiveVariable &LV : LiveVariables) { dbgs() << LV.VarName << " @ " << LV.LocExpr.Range << ": "; LV.print(dbgs(), MRI); dbgs() << "\n"; } } void addCompileUnit(DWARFDie D) { if (D.getTag() == dwarf::DW_TAG_subprogram) addFunction(D); else for (const DWARFDie &Child : D.children()) addFunction(Child); } /// Update to match the state of the instruction between ThisAddr and /// NextAddr. In the common case, any live range active at ThisAddr is /// live-in to the instruction, and any live range active at NextAddr is /// live-out of the instruction. If IncludeDefinedVars is false, then live /// ranges starting at NextAddr will be ignored. void update(object::SectionedAddress ThisAddr, object::SectionedAddress NextAddr, bool IncludeDefinedVars) { // First, check variables which have already been assigned a column, so // that we don't change their order. SmallSet CheckedVarIdxs; for (unsigned ColIdx = 0, End = ActiveCols.size(); ColIdx < End; ++ColIdx) { if (!ActiveCols[ColIdx].isActive()) continue; CheckedVarIdxs.insert(ActiveCols[ColIdx].VarIdx); LiveVariable &LV = LiveVariables[ActiveCols[ColIdx].VarIdx]; ActiveCols[ColIdx].LiveIn = LV.liveAtAddress(ThisAddr); ActiveCols[ColIdx].LiveOut = LV.liveAtAddress(NextAddr); LLVM_DEBUG(dbgs() << "pass 1, " << ThisAddr.Address << "-" << NextAddr.Address << ", " << LV.VarName << ", Col " << ColIdx << ": LiveIn=" << ActiveCols[ColIdx].LiveIn << ", LiveOut=" << ActiveCols[ColIdx].LiveOut << "\n"); if (!ActiveCols[ColIdx].LiveIn && !ActiveCols[ColIdx].LiveOut) ActiveCols[ColIdx].VarIdx = Column::NullVarIdx; } // Next, look for variables which don't already have a column, but which // are now live. if (IncludeDefinedVars) { for (unsigned VarIdx = 0, End = LiveVariables.size(); VarIdx < End; ++VarIdx) { if (CheckedVarIdxs.count(VarIdx)) continue; LiveVariable &LV = LiveVariables[VarIdx]; bool LiveIn = LV.liveAtAddress(ThisAddr); bool LiveOut = LV.liveAtAddress(NextAddr); if (!LiveIn && !LiveOut) continue; unsigned ColIdx = findFreeColumn(); LLVM_DEBUG(dbgs() << "pass 2, " << ThisAddr.Address << "-" << NextAddr.Address << ", " << LV.VarName << ", Col " << ColIdx << ": LiveIn=" << LiveIn << ", LiveOut=" << LiveOut << "\n"); ActiveCols[ColIdx].VarIdx = VarIdx; ActiveCols[ColIdx].LiveIn = LiveIn; ActiveCols[ColIdx].LiveOut = LiveOut; ActiveCols[ColIdx].MustDrawLabel = true; } } } enum class LineChar { RangeStart, RangeMid, RangeEnd, LabelVert, LabelCornerNew, LabelCornerActive, LabelHoriz, }; const char *getLineChar(LineChar C) const { bool IsASCII = DbgVariables == DVASCII; switch (C) { case LineChar::RangeStart: return IsASCII ? "^" : u8"\u2548"; case LineChar::RangeMid: return IsASCII ? "|" : u8"\u2503"; case LineChar::RangeEnd: return IsASCII ? "v" : u8"\u253b"; case LineChar::LabelVert: return IsASCII ? "|" : u8"\u2502"; case LineChar::LabelCornerNew: return IsASCII ? "/" : u8"\u250c"; case LineChar::LabelCornerActive: return IsASCII ? "|" : u8"\u2520"; case LineChar::LabelHoriz: return IsASCII ? "-" : u8"\u2500"; } llvm_unreachable("Unhandled LineChar enum"); } /// Print live ranges to the right of an existing line. This assumes the /// line is not an instruction, so doesn't start or end any live ranges, so /// we only need to print active ranges or empty columns. If AfterInst is /// true, this is being printed after the last instruction fed to update(), /// otherwise this is being printed before it. void printAfterOtherLine(formatted_raw_ostream &OS, bool AfterInst) { if (ActiveCols.size()) { unsigned FirstUnprintedColumn = moveToFirstVarColumn(OS); for (size_t ColIdx = FirstUnprintedColumn, End = ActiveCols.size(); ColIdx < End; ++ColIdx) { if (ActiveCols[ColIdx].isActive()) { if ((AfterInst && ActiveCols[ColIdx].LiveOut) || (!AfterInst && ActiveCols[ColIdx].LiveIn)) OS << getLineChar(LineChar::RangeMid); else if (!AfterInst && ActiveCols[ColIdx].LiveOut) OS << getLineChar(LineChar::LabelVert); else OS << " "; } OS << " "; } } OS << "\n"; } /// Print any live variable range info needed to the right of a /// non-instruction line of disassembly. This is where we print the variable /// names and expressions, with thin line-drawing characters connecting them /// to the live range which starts at the next instruction. If MustPrint is /// true, we have to print at least one line (with the continuation of any /// already-active live ranges) because something has already been printed /// earlier on this line. void printBetweenInsts(formatted_raw_ostream &OS, bool MustPrint) { bool PrintedSomething = false; for (unsigned ColIdx = 0, End = ActiveCols.size(); ColIdx < End; ++ColIdx) { if (ActiveCols[ColIdx].isActive() && ActiveCols[ColIdx].MustDrawLabel) { // First we need to print the live range markers for any active // columns to the left of this one. OS.PadToColumn(getIndentLevel()); for (unsigned ColIdx2 = 0; ColIdx2 < ColIdx; ++ColIdx2) { if (ActiveCols[ColIdx2].isActive()) { if (ActiveCols[ColIdx2].MustDrawLabel && !ActiveCols[ColIdx2].LiveIn) OS << getLineChar(LineChar::LabelVert) << " "; else OS << getLineChar(LineChar::RangeMid) << " "; } else OS << " "; } // Then print the variable name and location of the new live range, // with box drawing characters joining it to the live range line. OS << getLineChar(ActiveCols[ColIdx].LiveIn ? LineChar::LabelCornerActive : LineChar::LabelCornerNew) << getLineChar(LineChar::LabelHoriz) << " "; WithColor(OS, raw_ostream::GREEN) << LiveVariables[ActiveCols[ColIdx].VarIdx].VarName; OS << " = "; { WithColor ExprColor(OS, raw_ostream::CYAN); LiveVariables[ActiveCols[ColIdx].VarIdx].print(OS, MRI); } // If there are any columns to the right of the expression we just // printed, then continue their live range lines. unsigned FirstUnprintedColumn = moveToFirstVarColumn(OS); for (unsigned ColIdx2 = FirstUnprintedColumn, End = ActiveCols.size(); ColIdx2 < End; ++ColIdx2) { if (ActiveCols[ColIdx2].isActive() && ActiveCols[ColIdx2].LiveIn) OS << getLineChar(LineChar::RangeMid) << " "; else OS << " "; } OS << "\n"; PrintedSomething = true; } } for (unsigned ColIdx = 0, End = ActiveCols.size(); ColIdx < End; ++ColIdx) if (ActiveCols[ColIdx].isActive()) ActiveCols[ColIdx].MustDrawLabel = false; // If we must print something (because we printed a line/column number), // but don't have any new variables to print, then print a line which // just continues any existing live ranges. if (MustPrint && !PrintedSomething) printAfterOtherLine(OS, false); } /// Print the live variable ranges to the right of a disassembled instruction. void printAfterInst(formatted_raw_ostream &OS) { if (!ActiveCols.size()) return; unsigned FirstUnprintedColumn = moveToFirstVarColumn(OS); for (unsigned ColIdx = FirstUnprintedColumn, End = ActiveCols.size(); ColIdx < End; ++ColIdx) { if (!ActiveCols[ColIdx].isActive()) OS << " "; else if (ActiveCols[ColIdx].LiveIn && ActiveCols[ColIdx].LiveOut) OS << getLineChar(LineChar::RangeMid) << " "; else if (ActiveCols[ColIdx].LiveOut) OS << getLineChar(LineChar::RangeStart) << " "; else if (ActiveCols[ColIdx].LiveIn) OS << getLineChar(LineChar::RangeEnd) << " "; else llvm_unreachable("var must be live in or out!"); } } }; class SourcePrinter { protected: DILineInfo OldLineInfo; const ObjectFile *Obj = nullptr; std::unique_ptr Symbolizer; // File name to file contents of source. std::unordered_map> SourceCache; // Mark the line endings of the cached source. std::unordered_map> LineCache; // Keep track of missing sources. StringSet<> MissingSources; // Only emit 'no debug info' warning once. bool WarnedNoDebugInfo; private: bool cacheSource(const DILineInfo& LineInfoFile); void printLines(formatted_raw_ostream &OS, const DILineInfo &LineInfo, StringRef Delimiter, LiveVariablePrinter &LVP); void printSources(formatted_raw_ostream &OS, const DILineInfo &LineInfo, StringRef ObjectFilename, StringRef Delimiter, LiveVariablePrinter &LVP); public: SourcePrinter() = default; SourcePrinter(const ObjectFile *Obj, StringRef DefaultArch) : Obj(Obj), WarnedNoDebugInfo(false) { symbolize::LLVMSymbolizer::Options SymbolizerOpts; SymbolizerOpts.PrintFunctions = DILineInfoSpecifier::FunctionNameKind::LinkageName; SymbolizerOpts.Demangle = Demangle; SymbolizerOpts.DefaultArch = std::string(DefaultArch); Symbolizer.reset(new symbolize::LLVMSymbolizer(SymbolizerOpts)); } virtual ~SourcePrinter() = default; virtual void printSourceLine(formatted_raw_ostream &OS, object::SectionedAddress Address, StringRef ObjectFilename, LiveVariablePrinter &LVP, StringRef Delimiter = "; "); }; bool SourcePrinter::cacheSource(const DILineInfo &LineInfo) { std::unique_ptr Buffer; if (LineInfo.Source) { Buffer = MemoryBuffer::getMemBuffer(*LineInfo.Source); } else { auto BufferOrError = MemoryBuffer::getFile(LineInfo.FileName); if (!BufferOrError) { if (MissingSources.insert(LineInfo.FileName).second) reportWarning("failed to find source " + LineInfo.FileName, Obj->getFileName()); return false; } Buffer = std::move(*BufferOrError); } // Chomp the file to get lines const char *BufferStart = Buffer->getBufferStart(), *BufferEnd = Buffer->getBufferEnd(); std::vector &Lines = LineCache[LineInfo.FileName]; const char *Start = BufferStart; for (const char *I = BufferStart; I != BufferEnd; ++I) if (*I == '\n') { Lines.emplace_back(Start, I - Start - (BufferStart < I && I[-1] == '\r')); Start = I + 1; } if (Start < BufferEnd) Lines.emplace_back(Start, BufferEnd - Start); SourceCache[LineInfo.FileName] = std::move(Buffer); return true; } void SourcePrinter::printSourceLine(formatted_raw_ostream &OS, object::SectionedAddress Address, StringRef ObjectFilename, LiveVariablePrinter &LVP, StringRef Delimiter) { if (!Symbolizer) return; DILineInfo LineInfo = DILineInfo(); auto ExpectedLineInfo = Symbolizer->symbolizeCode(*Obj, Address); std::string ErrorMessage; if (!ExpectedLineInfo) ErrorMessage = toString(ExpectedLineInfo.takeError()); else LineInfo = *ExpectedLineInfo; if (LineInfo.FileName == DILineInfo::BadString) { if (!WarnedNoDebugInfo) { std::string Warning = "failed to parse debug information for " + ObjectFilename.str(); if (!ErrorMessage.empty()) Warning += ": " + ErrorMessage; reportWarning(Warning, ObjectFilename); WarnedNoDebugInfo = true; } } if (PrintLines) printLines(OS, LineInfo, Delimiter, LVP); if (PrintSource) printSources(OS, LineInfo, ObjectFilename, Delimiter, LVP); OldLineInfo = LineInfo; } void SourcePrinter::printLines(formatted_raw_ostream &OS, const DILineInfo &LineInfo, StringRef Delimiter, LiveVariablePrinter &LVP) { bool PrintFunctionName = LineInfo.FunctionName != DILineInfo::BadString && LineInfo.FunctionName != OldLineInfo.FunctionName; if (PrintFunctionName) { OS << Delimiter << LineInfo.FunctionName; // If demangling is successful, FunctionName will end with "()". Print it // only if demangling did not run or was unsuccessful. if (!StringRef(LineInfo.FunctionName).endswith("()")) OS << "()"; OS << ":\n"; } if (LineInfo.FileName != DILineInfo::BadString && LineInfo.Line != 0 && (OldLineInfo.Line != LineInfo.Line || OldLineInfo.FileName != LineInfo.FileName || PrintFunctionName)) { OS << Delimiter << LineInfo.FileName << ":" << LineInfo.Line; LVP.printBetweenInsts(OS, true); } } void SourcePrinter::printSources(formatted_raw_ostream &OS, const DILineInfo &LineInfo, StringRef ObjectFilename, StringRef Delimiter, LiveVariablePrinter &LVP) { if (LineInfo.FileName == DILineInfo::BadString || LineInfo.Line == 0 || (OldLineInfo.Line == LineInfo.Line && OldLineInfo.FileName == LineInfo.FileName)) return; if (SourceCache.find(LineInfo.FileName) == SourceCache.end()) if (!cacheSource(LineInfo)) return; auto LineBuffer = LineCache.find(LineInfo.FileName); if (LineBuffer != LineCache.end()) { if (LineInfo.Line > LineBuffer->second.size()) { reportWarning( formatv( "debug info line number {0} exceeds the number of lines in {1}", LineInfo.Line, LineInfo.FileName), ObjectFilename); return; } // Vector begins at 0, line numbers are non-zero OS << Delimiter << LineBuffer->second[LineInfo.Line - 1]; LVP.printBetweenInsts(OS, true); } } static bool isAArch64Elf(const ObjectFile *Obj) { const auto *Elf = dyn_cast(Obj); return Elf && Elf->getEMachine() == ELF::EM_AARCH64; } static bool isArmElf(const ObjectFile *Obj) { const auto *Elf = dyn_cast(Obj); return Elf && Elf->getEMachine() == ELF::EM_ARM; } static bool hasMappingSymbols(const ObjectFile *Obj) { return isArmElf(Obj) || isAArch64Elf(Obj); } static void printRelocation(formatted_raw_ostream &OS, StringRef FileName, const RelocationRef &Rel, uint64_t Address, bool Is64Bits) { StringRef Fmt = Is64Bits ? "\t\t%016" PRIx64 ": " : "\t\t\t%08" PRIx64 ": "; SmallString<16> Name; SmallString<32> Val; Rel.getTypeName(Name); if (Error E = getRelocationValueString(Rel, Val)) reportError(std::move(E), FileName); OS << format(Fmt.data(), Address) << Name << "\t" << Val; } class PrettyPrinter { public: virtual ~PrettyPrinter() = default; virtual void printInst(MCInstPrinter &IP, const MCInst *MI, ArrayRef Bytes, object::SectionedAddress Address, formatted_raw_ostream &OS, StringRef Annot, MCSubtargetInfo const &STI, SourcePrinter *SP, StringRef ObjectFilename, std::vector *Rels, LiveVariablePrinter &LVP) { if (SP && (PrintSource || PrintLines)) SP->printSourceLine(OS, Address, ObjectFilename, LVP); LVP.printBetweenInsts(OS, false); size_t Start = OS.tell(); if (!NoLeadingAddr) OS << format("%8" PRIx64 ":", Address.Address); if (!NoShowRawInsn) { OS << ' '; dumpBytes(Bytes, OS); } // The output of printInst starts with a tab. Print some spaces so that // the tab has 1 column and advances to the target tab stop. unsigned TabStop = getInstStartColumn(STI); unsigned Column = OS.tell() - Start; OS.indent(Column < TabStop - 1 ? TabStop - 1 - Column : 7 - Column % 8); if (MI) { // See MCInstPrinter::printInst. On targets where a PC relative immediate // is relative to the next instruction and the length of a MCInst is // difficult to measure (x86), this is the address of the next // instruction. uint64_t Addr = Address.Address + (STI.getTargetTriple().isX86() ? Bytes.size() : 0); IP.printInst(MI, Addr, "", STI, OS); } else OS << "\t"; } }; PrettyPrinter PrettyPrinterInst; class HexagonPrettyPrinter : public PrettyPrinter { public: void printLead(ArrayRef Bytes, uint64_t Address, formatted_raw_ostream &OS) { uint32_t opcode = (Bytes[3] << 24) | (Bytes[2] << 16) | (Bytes[1] << 8) | Bytes[0]; if (!NoLeadingAddr) OS << format("%8" PRIx64 ":", Address); if (!NoShowRawInsn) { OS << "\t"; dumpBytes(Bytes.slice(0, 4), OS); OS << format("\t%08" PRIx32, opcode); } } void printInst(MCInstPrinter &IP, const MCInst *MI, ArrayRef Bytes, object::SectionedAddress Address, formatted_raw_ostream &OS, StringRef Annot, MCSubtargetInfo const &STI, SourcePrinter *SP, StringRef ObjectFilename, std::vector *Rels, LiveVariablePrinter &LVP) override { if (SP && (PrintSource || PrintLines)) SP->printSourceLine(OS, Address, ObjectFilename, LVP, ""); if (!MI) { printLead(Bytes, Address.Address, OS); OS << " "; return; } std::string Buffer; { raw_string_ostream TempStream(Buffer); IP.printInst(MI, Address.Address, "", STI, TempStream); } StringRef Contents(Buffer); // Split off bundle attributes auto PacketBundle = Contents.rsplit('\n'); // Split off first instruction from the rest auto HeadTail = PacketBundle.first.split('\n'); auto Preamble = " { "; auto Separator = ""; // Hexagon's packets require relocations to be inline rather than // clustered at the end of the packet. std::vector::const_iterator RelCur = Rels->begin(); std::vector::const_iterator RelEnd = Rels->end(); auto PrintReloc = [&]() -> void { while ((RelCur != RelEnd) && (RelCur->getOffset() <= Address.Address)) { if (RelCur->getOffset() == Address.Address) { printRelocation(OS, ObjectFilename, *RelCur, Address.Address, false); return; } ++RelCur; } }; while (!HeadTail.first.empty()) { OS << Separator; Separator = "\n"; if (SP && (PrintSource || PrintLines)) SP->printSourceLine(OS, Address, ObjectFilename, LVP, ""); printLead(Bytes, Address.Address, OS); OS << Preamble; Preamble = " "; StringRef Inst; auto Duplex = HeadTail.first.split('\v'); if (!Duplex.second.empty()) { OS << Duplex.first; OS << "; "; Inst = Duplex.second; } else Inst = HeadTail.first; OS << Inst; HeadTail = HeadTail.second.split('\n'); if (HeadTail.first.empty()) OS << " } " << PacketBundle.second; PrintReloc(); Bytes = Bytes.slice(4); Address.Address += 4; } } }; HexagonPrettyPrinter HexagonPrettyPrinterInst; class AMDGCNPrettyPrinter : public PrettyPrinter { public: void printInst(MCInstPrinter &IP, const MCInst *MI, ArrayRef Bytes, object::SectionedAddress Address, formatted_raw_ostream &OS, StringRef Annot, MCSubtargetInfo const &STI, SourcePrinter *SP, StringRef ObjectFilename, std::vector *Rels, LiveVariablePrinter &LVP) override { if (SP && (PrintSource || PrintLines)) SP->printSourceLine(OS, Address, ObjectFilename, LVP); if (MI) { SmallString<40> InstStr; raw_svector_ostream IS(InstStr); IP.printInst(MI, Address.Address, "", STI, IS); OS << left_justify(IS.str(), 60); } else { // an unrecognized encoding - this is probably data so represent it // using the .long directive, or .byte directive if fewer than 4 bytes // remaining if (Bytes.size() >= 4) { OS << format("\t.long 0x%08" PRIx32 " ", support::endian::read32(Bytes.data())); OS.indent(42); } else { OS << format("\t.byte 0x%02" PRIx8, Bytes[0]); for (unsigned int i = 1; i < Bytes.size(); i++) OS << format(", 0x%02" PRIx8, Bytes[i]); OS.indent(55 - (6 * Bytes.size())); } } OS << format("// %012" PRIX64 ":", Address.Address); if (Bytes.size() >= 4) { // D should be casted to uint32_t here as it is passed by format to // snprintf as vararg. for (uint32_t D : makeArrayRef( reinterpret_cast(Bytes.data()), Bytes.size() / 4)) OS << format(" %08" PRIX32, D); } else { for (unsigned char B : Bytes) OS << format(" %02" PRIX8, B); } if (!Annot.empty()) OS << " // " << Annot; } }; AMDGCNPrettyPrinter AMDGCNPrettyPrinterInst; class BPFPrettyPrinter : public PrettyPrinter { public: void printInst(MCInstPrinter &IP, const MCInst *MI, ArrayRef Bytes, object::SectionedAddress Address, formatted_raw_ostream &OS, StringRef Annot, MCSubtargetInfo const &STI, SourcePrinter *SP, StringRef ObjectFilename, std::vector *Rels, LiveVariablePrinter &LVP) override { if (SP && (PrintSource || PrintLines)) SP->printSourceLine(OS, Address, ObjectFilename, LVP); if (!NoLeadingAddr) OS << format("%8" PRId64 ":", Address.Address / 8); if (!NoShowRawInsn) { OS << "\t"; dumpBytes(Bytes, OS); } if (MI) IP.printInst(MI, Address.Address, "", STI, OS); else OS << "\t"; } }; BPFPrettyPrinter BPFPrettyPrinterInst; PrettyPrinter &selectPrettyPrinter(Triple const &Triple) { switch(Triple.getArch()) { default: return PrettyPrinterInst; case Triple::hexagon: return HexagonPrettyPrinterInst; case Triple::amdgcn: return AMDGCNPrettyPrinterInst; case Triple::bpfel: case Triple::bpfeb: return BPFPrettyPrinterInst; } } } static uint8_t getElfSymbolType(const ObjectFile *Obj, const SymbolRef &Sym) { assert(Obj->isELF()); if (auto *Elf32LEObj = dyn_cast(Obj)) return Elf32LEObj->getSymbol(Sym.getRawDataRefImpl())->getType(); if (auto *Elf64LEObj = dyn_cast(Obj)) return Elf64LEObj->getSymbol(Sym.getRawDataRefImpl())->getType(); if (auto *Elf32BEObj = dyn_cast(Obj)) return Elf32BEObj->getSymbol(Sym.getRawDataRefImpl())->getType(); if (auto *Elf64BEObj = cast(Obj)) return Elf64BEObj->getSymbol(Sym.getRawDataRefImpl())->getType(); llvm_unreachable("Unsupported binary format"); } template static void addDynamicElfSymbols(const ELFObjectFile *Obj, std::map &AllSymbols) { for (auto Symbol : Obj->getDynamicSymbolIterators()) { uint8_t SymbolType = Symbol.getELFType(); if (SymbolType == ELF::STT_SECTION) continue; uint64_t Address = unwrapOrError(Symbol.getAddress(), Obj->getFileName()); // ELFSymbolRef::getAddress() returns size instead of value for common // symbols which is not desirable for disassembly output. Overriding. if (SymbolType == ELF::STT_COMMON) Address = Obj->getSymbol(Symbol.getRawDataRefImpl())->st_value; StringRef Name = unwrapOrError(Symbol.getName(), Obj->getFileName()); if (Name.empty()) continue; section_iterator SecI = unwrapOrError(Symbol.getSection(), Obj->getFileName()); if (SecI == Obj->section_end()) continue; AllSymbols[*SecI].emplace_back(Address, Name, SymbolType); } } static void addDynamicElfSymbols(const ObjectFile *Obj, std::map &AllSymbols) { assert(Obj->isELF()); if (auto *Elf32LEObj = dyn_cast(Obj)) addDynamicElfSymbols(Elf32LEObj, AllSymbols); else if (auto *Elf64LEObj = dyn_cast(Obj)) addDynamicElfSymbols(Elf64LEObj, AllSymbols); else if (auto *Elf32BEObj = dyn_cast(Obj)) addDynamicElfSymbols(Elf32BEObj, AllSymbols); else if (auto *Elf64BEObj = cast(Obj)) addDynamicElfSymbols(Elf64BEObj, AllSymbols); else llvm_unreachable("Unsupported binary format"); } static void addPltEntries(const ObjectFile *Obj, std::map &AllSymbols, StringSaver &Saver) { Optional Plt = None; for (const SectionRef &Section : Obj->sections()) { Expected SecNameOrErr = Section.getName(); if (!SecNameOrErr) { consumeError(SecNameOrErr.takeError()); continue; } if (*SecNameOrErr == ".plt") Plt = Section; } if (!Plt) return; if (auto *ElfObj = dyn_cast(Obj)) { for (auto PltEntry : ElfObj->getPltAddresses()) { SymbolRef Symbol(PltEntry.first, ElfObj); uint8_t SymbolType = getElfSymbolType(Obj, Symbol); StringRef Name = unwrapOrError(Symbol.getName(), Obj->getFileName()); if (!Name.empty()) AllSymbols[*Plt].emplace_back( PltEntry.second, Saver.save((Name + "@plt").str()), SymbolType); } } } // Normally the disassembly output will skip blocks of zeroes. This function // returns the number of zero bytes that can be skipped when dumping the // disassembly of the instructions in Buf. static size_t countSkippableZeroBytes(ArrayRef Buf) { // Find the number of leading zeroes. size_t N = 0; while (N < Buf.size() && !Buf[N]) ++N; // We may want to skip blocks of zero bytes, but unless we see // at least 8 of them in a row. if (N < 8) return 0; // We skip zeroes in multiples of 4 because do not want to truncate an // instruction if it starts with a zero byte. return N & ~0x3; } // Returns a map from sections to their relocations. static std::map> getRelocsMap(object::ObjectFile const &Obj) { std::map> Ret; uint64_t I = (uint64_t)-1; for (SectionRef Sec : Obj.sections()) { ++I; Expected RelocatedOrErr = Sec.getRelocatedSection(); if (!RelocatedOrErr) reportError(Obj.getFileName(), "section (" + Twine(I) + "): failed to get a relocated section: " + toString(RelocatedOrErr.takeError())); section_iterator Relocated = *RelocatedOrErr; if (Relocated == Obj.section_end() || !checkSectionFilter(*Relocated).Keep) continue; std::vector &V = Ret[*Relocated]; for (const RelocationRef &R : Sec.relocations()) V.push_back(R); // Sort relocations by address. llvm::stable_sort(V, isRelocAddressLess); } return Ret; } // Used for --adjust-vma to check if address should be adjusted by the // specified value for a given section. // For ELF we do not adjust non-allocatable sections like debug ones, // because they are not loadable. // TODO: implement for other file formats. static bool shouldAdjustVA(const SectionRef &Section) { const ObjectFile *Obj = Section.getObject(); if (Obj->isELF()) return ELFSectionRef(Section).getFlags() & ELF::SHF_ALLOC; return false; } typedef std::pair MappingSymbolPair; static char getMappingSymbolKind(ArrayRef MappingSymbols, uint64_t Address) { auto It = partition_point(MappingSymbols, [Address](const MappingSymbolPair &Val) { return Val.first <= Address; }); // Return zero for any address before the first mapping symbol; this means // we should use the default disassembly mode, depending on the target. if (It == MappingSymbols.begin()) return '\x00'; return (It - 1)->second; } static uint64_t dumpARMELFData(uint64_t SectionAddr, uint64_t Index, uint64_t End, const ObjectFile *Obj, ArrayRef Bytes, ArrayRef MappingSymbols, raw_ostream &OS) { support::endianness Endian = Obj->isLittleEndian() ? support::little : support::big; OS << format("%8" PRIx64 ":\t", SectionAddr + Index); if (Index + 4 <= End) { dumpBytes(Bytes.slice(Index, 4), OS); OS << "\t.word\t" << format_hex(support::endian::read32(Bytes.data() + Index, Endian), 10); return 4; } if (Index + 2 <= End) { dumpBytes(Bytes.slice(Index, 2), OS); OS << "\t\t.short\t" << format_hex(support::endian::read16(Bytes.data() + Index, Endian), 6); return 2; } dumpBytes(Bytes.slice(Index, 1), OS); OS << "\t\t.byte\t" << format_hex(Bytes[0], 4); return 1; } static void dumpELFData(uint64_t SectionAddr, uint64_t Index, uint64_t End, ArrayRef Bytes) { // print out data up to 8 bytes at a time in hex and ascii uint8_t AsciiData[9] = {'\0'}; uint8_t Byte; int NumBytes = 0; for (; Index < End; ++Index) { if (NumBytes == 0) outs() << format("%8" PRIx64 ":", SectionAddr + Index); Byte = Bytes.slice(Index)[0]; outs() << format(" %02x", Byte); AsciiData[NumBytes] = isPrint(Byte) ? Byte : '.'; uint8_t IndentOffset = 0; NumBytes++; if (Index == End - 1 || NumBytes > 8) { // Indent the space for less than 8 bytes data. // 2 spaces for byte and one for space between bytes IndentOffset = 3 * (8 - NumBytes); for (int Excess = NumBytes; Excess < 8; Excess++) AsciiData[Excess] = '\0'; NumBytes = 8; } if (NumBytes == 8) { AsciiData[8] = '\0'; outs() << std::string(IndentOffset, ' ') << " "; outs() << reinterpret_cast(AsciiData); outs() << '\n'; NumBytes = 0; } } } SymbolInfoTy objdump::createSymbolInfo(const ObjectFile *Obj, const SymbolRef &Symbol) { const StringRef FileName = Obj->getFileName(); const uint64_t Addr = unwrapOrError(Symbol.getAddress(), FileName); const StringRef Name = unwrapOrError(Symbol.getName(), FileName); if (Obj->isXCOFF() && SymbolDescription) { const auto *XCOFFObj = cast(Obj); DataRefImpl SymbolDRI = Symbol.getRawDataRefImpl(); const uint32_t SymbolIndex = XCOFFObj->getSymbolIndex(SymbolDRI.p); Optional Smc = getXCOFFSymbolCsectSMC(XCOFFObj, Symbol); return SymbolInfoTy(Addr, Name, Smc, SymbolIndex, isLabel(XCOFFObj, Symbol)); } else return SymbolInfoTy(Addr, Name, Obj->isELF() ? getElfSymbolType(Obj, Symbol) : (uint8_t)ELF::STT_NOTYPE); } static SymbolInfoTy createDummySymbolInfo(const ObjectFile *Obj, const uint64_t Addr, StringRef &Name, uint8_t Type) { if (Obj->isXCOFF() && SymbolDescription) return SymbolInfoTy(Addr, Name, None, None, false); else return SymbolInfoTy(Addr, Name, Type); } static void disassembleObject(const Target *TheTarget, const ObjectFile *Obj, MCContext &Ctx, MCDisassembler *PrimaryDisAsm, MCDisassembler *SecondaryDisAsm, const MCInstrAnalysis *MIA, MCInstPrinter *IP, const MCSubtargetInfo *PrimarySTI, const MCSubtargetInfo *SecondarySTI, PrettyPrinter &PIP, SourcePrinter &SP, bool InlineRelocs) { const MCSubtargetInfo *STI = PrimarySTI; MCDisassembler *DisAsm = PrimaryDisAsm; bool PrimaryIsThumb = false; if (isArmElf(Obj)) PrimaryIsThumb = STI->checkFeatures("+thumb-mode"); std::map> RelocMap; if (InlineRelocs) RelocMap = getRelocsMap(*Obj); bool Is64Bits = Obj->getBytesInAddress() > 4; // Create a mapping from virtual address to symbol name. This is used to // pretty print the symbols while disassembling. std::map AllSymbols; SectionSymbolsTy AbsoluteSymbols; const StringRef FileName = Obj->getFileName(); const MachOObjectFile *MachO = dyn_cast(Obj); for (const SymbolRef &Symbol : Obj->symbols()) { StringRef Name = unwrapOrError(Symbol.getName(), FileName); if (Name.empty() && !(Obj->isXCOFF() && SymbolDescription)) continue; if (Obj->isELF() && getElfSymbolType(Obj, Symbol) == ELF::STT_SECTION) continue; // Don't ask a Mach-O STAB symbol for its section unless you know that // STAB symbol's section field refers to a valid section index. Otherwise // the symbol may error trying to load a section that does not exist. if (MachO) { DataRefImpl SymDRI = Symbol.getRawDataRefImpl(); uint8_t NType = (MachO->is64Bit() ? MachO->getSymbol64TableEntry(SymDRI).n_type: MachO->getSymbolTableEntry(SymDRI).n_type); if (NType & MachO::N_STAB) continue; } section_iterator SecI = unwrapOrError(Symbol.getSection(), FileName); if (SecI != Obj->section_end()) AllSymbols[*SecI].push_back(createSymbolInfo(Obj, Symbol)); else AbsoluteSymbols.push_back(createSymbolInfo(Obj, Symbol)); } if (AllSymbols.empty() && Obj->isELF()) addDynamicElfSymbols(Obj, AllSymbols); BumpPtrAllocator A; StringSaver Saver(A); addPltEntries(Obj, AllSymbols, Saver); // Create a mapping from virtual address to section. An empty section can // cause more than one section at the same address. Sort such sections to be // before same-addressed non-empty sections so that symbol lookups prefer the // non-empty section. std::vector> SectionAddresses; for (SectionRef Sec : Obj->sections()) SectionAddresses.emplace_back(Sec.getAddress(), Sec); llvm::stable_sort(SectionAddresses, [](const auto &LHS, const auto &RHS) { if (LHS.first != RHS.first) return LHS.first < RHS.first; return LHS.second.getSize() < RHS.second.getSize(); }); // Linked executables (.exe and .dll files) typically don't include a real // symbol table but they might contain an export table. if (const auto *COFFObj = dyn_cast(Obj)) { for (const auto &ExportEntry : COFFObj->export_directories()) { StringRef Name; if (Error E = ExportEntry.getSymbolName(Name)) reportError(std::move(E), Obj->getFileName()); if (Name.empty()) continue; uint32_t RVA; if (Error E = ExportEntry.getExportRVA(RVA)) reportError(std::move(E), Obj->getFileName()); uint64_t VA = COFFObj->getImageBase() + RVA; auto Sec = partition_point( SectionAddresses, [VA](const std::pair &O) { return O.first <= VA; }); if (Sec != SectionAddresses.begin()) { --Sec; AllSymbols[Sec->second].emplace_back(VA, Name, ELF::STT_NOTYPE); } else AbsoluteSymbols.emplace_back(VA, Name, ELF::STT_NOTYPE); } } // Sort all the symbols, this allows us to use a simple binary search to find // Multiple symbols can have the same address. Use a stable sort to stabilize // the output. StringSet<> FoundDisasmSymbolSet; for (std::pair &SecSyms : AllSymbols) stable_sort(SecSyms.second); stable_sort(AbsoluteSymbols); std::unique_ptr DICtx; LiveVariablePrinter LVP(*Ctx.getRegisterInfo(), *STI); if (DbgVariables != DVDisabled) { DICtx = DWARFContext::create(*Obj); for (const std::unique_ptr &CU : DICtx->compile_units()) LVP.addCompileUnit(CU->getUnitDIE(false)); } LLVM_DEBUG(LVP.dump()); for (const SectionRef &Section : ToolSectionFilter(*Obj)) { if (FilterSections.empty() && !DisassembleAll && (!Section.isText() || Section.isVirtual())) continue; uint64_t SectionAddr = Section.getAddress(); uint64_t SectSize = Section.getSize(); if (!SectSize) continue; // Get the list of all the symbols in this section. SectionSymbolsTy &Symbols = AllSymbols[Section]; std::vector MappingSymbols; if (hasMappingSymbols(Obj)) { for (const auto &Symb : Symbols) { uint64_t Address = Symb.Addr; StringRef Name = Symb.Name; if (Name.startswith("$d")) MappingSymbols.emplace_back(Address - SectionAddr, 'd'); if (Name.startswith("$x")) MappingSymbols.emplace_back(Address - SectionAddr, 'x'); if (Name.startswith("$a")) MappingSymbols.emplace_back(Address - SectionAddr, 'a'); if (Name.startswith("$t")) MappingSymbols.emplace_back(Address - SectionAddr, 't'); } } llvm::sort(MappingSymbols); if (Obj->isELF() && Obj->getArch() == Triple::amdgcn) { // AMDGPU disassembler uses symbolizer for printing labels std::unique_ptr RelInfo( TheTarget->createMCRelocationInfo(TripleName, Ctx)); if (RelInfo) { std::unique_ptr Symbolizer( TheTarget->createMCSymbolizer( TripleName, nullptr, nullptr, &Symbols, &Ctx, std::move(RelInfo))); DisAsm->setSymbolizer(std::move(Symbolizer)); } } StringRef SegmentName = ""; if (MachO) { DataRefImpl DR = Section.getRawDataRefImpl(); SegmentName = MachO->getSectionFinalSegmentName(DR); } StringRef SectionName = unwrapOrError(Section.getName(), Obj->getFileName()); // If the section has no symbol at the start, just insert a dummy one. if (Symbols.empty() || Symbols[0].Addr != 0) { Symbols.insert(Symbols.begin(), createDummySymbolInfo(Obj, SectionAddr, SectionName, Section.isText() ? ELF::STT_FUNC : ELF::STT_OBJECT)); } SmallString<40> Comments; raw_svector_ostream CommentStream(Comments); ArrayRef Bytes = arrayRefFromStringRef( unwrapOrError(Section.getContents(), Obj->getFileName())); uint64_t VMAAdjustment = 0; if (shouldAdjustVA(Section)) VMAAdjustment = AdjustVMA; uint64_t Size; uint64_t Index; bool PrintedSection = false; std::vector Rels = RelocMap[Section]; std::vector::const_iterator RelCur = Rels.begin(); std::vector::const_iterator RelEnd = Rels.end(); // Disassemble symbol by symbol. for (unsigned SI = 0, SE = Symbols.size(); SI != SE; ++SI) { std::string SymbolName = Symbols[SI].Name.str(); if (Demangle) SymbolName = demangle(SymbolName); // Skip if --disassemble-symbols is not empty and the symbol is not in // the list. if (!DisasmSymbolSet.empty() && !DisasmSymbolSet.count(SymbolName)) continue; uint64_t Start = Symbols[SI].Addr; if (Start < SectionAddr || StopAddress <= Start) continue; else FoundDisasmSymbolSet.insert(SymbolName); // The end is the section end, the beginning of the next symbol, or // --stop-address. uint64_t End = std::min(SectionAddr + SectSize, StopAddress); if (SI + 1 < SE) End = std::min(End, Symbols[SI + 1].Addr); if (Start >= End || End <= StartAddress) continue; Start -= SectionAddr; End -= SectionAddr; if (!PrintedSection) { PrintedSection = true; outs() << "\nDisassembly of section "; if (!SegmentName.empty()) outs() << SegmentName << ","; outs() << SectionName << ":\n"; } if (Obj->isELF() && Obj->getArch() == Triple::amdgcn) { if (Symbols[SI].Type == ELF::STT_AMDGPU_HSA_KERNEL) { // skip amd_kernel_code_t at the begining of kernel symbol (256 bytes) Start += 256; } if (SI == SE - 1 || Symbols[SI + 1].Type == ELF::STT_AMDGPU_HSA_KERNEL) { // cut trailing zeroes at the end of kernel // cut up to 256 bytes const uint64_t EndAlign = 256; const auto Limit = End - (std::min)(EndAlign, End - Start); while (End > Limit && *reinterpret_cast(&Bytes[End - 4]) == 0) End -= 4; } } outs() << '\n'; if (!NoLeadingAddr) outs() << format(Is64Bits ? "%016" PRIx64 " " : "%08" PRIx64 " ", SectionAddr + Start + VMAAdjustment); if (Obj->isXCOFF() && SymbolDescription) { outs() << getXCOFFSymbolDescription(Symbols[SI], SymbolName) << ":\n"; } else outs() << '<' << SymbolName << ">:\n"; // Don't print raw contents of a virtual section. A virtual section // doesn't have any contents in the file. if (Section.isVirtual()) { outs() << "...\n"; continue; } auto Status = DisAsm->onSymbolStart(Symbols[SI], Size, Bytes.slice(Start, End - Start), SectionAddr + Start, CommentStream); // To have round trippable disassembly, we fall back to decoding the // remaining bytes as instructions. // // If there is a failure, we disassemble the failed region as bytes before // falling back. The target is expected to print nothing in this case. // // If there is Success or SoftFail i.e no 'real' failure, we go ahead by // Size bytes before falling back. // So if the entire symbol is 'eaten' by the target: // Start += Size // Now Start = End and we will never decode as // // instructions // // Right now, most targets return None i.e ignore to treat a symbol // separately. But WebAssembly decodes preludes for some symbols. // if (Status.hasValue()) { if (Status.getValue() == MCDisassembler::Fail) { outs() << "// Error in decoding " << SymbolName << " : Decoding failed region as bytes.\n"; for (uint64_t I = 0; I < Size; ++I) { outs() << "\t.byte\t " << format_hex(Bytes[I], 1, /*Upper=*/true) << "\n"; } } } else { Size = 0; } Start += Size; Index = Start; if (SectionAddr < StartAddress) Index = std::max(Index, StartAddress - SectionAddr); // If there is a data/common symbol inside an ELF text section and we are // only disassembling text (applicable all architectures), we are in a // situation where we must print the data and not disassemble it. if (Obj->isELF() && !DisassembleAll && Section.isText()) { uint8_t SymTy = Symbols[SI].Type; if (SymTy == ELF::STT_OBJECT || SymTy == ELF::STT_COMMON) { dumpELFData(SectionAddr, Index, End, Bytes); Index = End; } } bool CheckARMELFData = hasMappingSymbols(Obj) && Symbols[SI].Type != ELF::STT_OBJECT && !DisassembleAll; bool DumpARMELFData = false; formatted_raw_ostream FOS(outs()); while (Index < End) { // ARM and AArch64 ELF binaries can interleave data and text in the // same section. We rely on the markers introduced to understand what // we need to dump. If the data marker is within a function, it is // denoted as a word/short etc. if (CheckARMELFData) { char Kind = getMappingSymbolKind(MappingSymbols, Index); DumpARMELFData = Kind == 'd'; if (SecondarySTI) { if (Kind == 'a') { STI = PrimaryIsThumb ? SecondarySTI : PrimarySTI; DisAsm = PrimaryIsThumb ? SecondaryDisAsm : PrimaryDisAsm; } else if (Kind == 't') { STI = PrimaryIsThumb ? PrimarySTI : SecondarySTI; DisAsm = PrimaryIsThumb ? PrimaryDisAsm : SecondaryDisAsm; } } } if (DumpARMELFData) { Size = dumpARMELFData(SectionAddr, Index, End, Obj, Bytes, MappingSymbols, FOS); } else { // When -z or --disassemble-zeroes are given we always dissasemble // them. Otherwise we might want to skip zero bytes we see. if (!DisassembleZeroes) { uint64_t MaxOffset = End - Index; // For --reloc: print zero blocks patched by relocations, so that // relocations can be shown in the dump. if (RelCur != RelEnd) MaxOffset = RelCur->getOffset() - Index; if (size_t N = countSkippableZeroBytes(Bytes.slice(Index, MaxOffset))) { FOS << "\t\t..." << '\n'; Index += N; continue; } } // Disassemble a real instruction or a data when disassemble all is // provided MCInst Inst; bool Disassembled = DisAsm->getInstruction(Inst, Size, Bytes.slice(Index), SectionAddr + Index, CommentStream); if (Size == 0) Size = 1; LVP.update({Index, Section.getIndex()}, {Index + Size, Section.getIndex()}, Index + Size != End); PIP.printInst( *IP, Disassembled ? &Inst : nullptr, Bytes.slice(Index, Size), {SectionAddr + Index + VMAAdjustment, Section.getIndex()}, FOS, "", *STI, &SP, Obj->getFileName(), &Rels, LVP); FOS << CommentStream.str(); Comments.clear(); // If disassembly has failed, avoid analysing invalid/incomplete // instruction information. Otherwise, try to resolve the target // address (jump target or memory operand address) and print it on the // right of the instruction. if (Disassembled && MIA) { uint64_t Target; bool PrintTarget = MIA->evaluateBranch(Inst, SectionAddr + Index, Size, Target); if (!PrintTarget) if (Optional MaybeTarget = MIA->evaluateMemoryOperandAddress( Inst, SectionAddr + Index, Size)) { Target = *MaybeTarget; PrintTarget = true; FOS << " # " << Twine::utohexstr(Target); } if (PrintTarget) { // In a relocatable object, the target's section must reside in // the same section as the call instruction or it is accessed // through a relocation. // // In a non-relocatable object, the target may be in any section. // In that case, locate the section(s) containing the target // address and find the symbol in one of those, if possible. // // N.B. We don't walk the relocations in the relocatable case yet. std::vector TargetSectionSymbols; if (!Obj->isRelocatableObject()) { auto It = llvm::partition_point( SectionAddresses, [=](const std::pair &O) { return O.first <= Target; }); uint64_t TargetSecAddr = 0; while (It != SectionAddresses.begin()) { --It; if (TargetSecAddr == 0) TargetSecAddr = It->first; if (It->first != TargetSecAddr) break; TargetSectionSymbols.push_back(&AllSymbols[It->second]); } } else { TargetSectionSymbols.push_back(&Symbols); } TargetSectionSymbols.push_back(&AbsoluteSymbols); // Find the last symbol in the first candidate section whose // offset is less than or equal to the target. If there are no // such symbols, try in the next section and so on, before finally // using the nearest preceding absolute symbol (if any), if there // are no other valid symbols. const SymbolInfoTy *TargetSym = nullptr; for (const SectionSymbolsTy *TargetSymbols : TargetSectionSymbols) { auto It = llvm::partition_point( *TargetSymbols, [=](const SymbolInfoTy &O) { return O.Addr <= Target; }); if (It != TargetSymbols->begin()) { TargetSym = &*(It - 1); break; } } if (TargetSym != nullptr) { uint64_t TargetAddress = TargetSym->Addr; std::string TargetName = TargetSym->Name.str(); if (Demangle) TargetName = demangle(TargetName); FOS << " <" << TargetName; uint64_t Disp = Target - TargetAddress; if (Disp) FOS << "+0x" << Twine::utohexstr(Disp); FOS << '>'; } } } } LVP.printAfterInst(FOS); FOS << "\n"; // Hexagon does this in pretty printer if (Obj->getArch() != Triple::hexagon) { // Print relocation for instruction and data. while (RelCur != RelEnd) { uint64_t Offset = RelCur->getOffset(); // If this relocation is hidden, skip it. if (getHidden(*RelCur) || SectionAddr + Offset < StartAddress) { ++RelCur; continue; } // Stop when RelCur's offset is past the disassembled // instruction/data. Note that it's possible the disassembled data // is not the complete data: we might see the relocation printed in // the middle of the data, but this matches the binutils objdump // output. if (Offset >= Index + Size) break; // When --adjust-vma is used, update the address printed. if (RelCur->getSymbol() != Obj->symbol_end()) { Expected SymSI = RelCur->getSymbol()->getSection(); if (SymSI && *SymSI != Obj->section_end() && shouldAdjustVA(**SymSI)) Offset += AdjustVMA; } printRelocation(FOS, Obj->getFileName(), *RelCur, SectionAddr + Offset, Is64Bits); LVP.printAfterOtherLine(FOS, true); ++RelCur; } } Index += Size; } } } StringSet<> MissingDisasmSymbolSet = set_difference(DisasmSymbolSet, FoundDisasmSymbolSet); for (StringRef Sym : MissingDisasmSymbolSet.keys()) reportWarning("failed to disassemble missing symbol " + Sym, FileName); } static void disassembleObject(const ObjectFile *Obj, bool InlineRelocs) { const Target *TheTarget = getTarget(Obj); // Package up features to be passed to target/subtarget SubtargetFeatures Features = Obj->getFeatures(); if (!MAttrs.empty()) for (unsigned I = 0; I != MAttrs.size(); ++I) Features.AddFeature(MAttrs[I]); std::unique_ptr MRI( TheTarget->createMCRegInfo(TripleName)); if (!MRI) reportError(Obj->getFileName(), "no register info for target " + TripleName); // Set up disassembler. MCTargetOptions MCOptions; std::unique_ptr AsmInfo( TheTarget->createMCAsmInfo(*MRI, TripleName, MCOptions)); if (!AsmInfo) reportError(Obj->getFileName(), "no assembly info for target " + TripleName); std::unique_ptr STI( TheTarget->createMCSubtargetInfo(TripleName, MCPU, Features.getString())); if (!STI) reportError(Obj->getFileName(), "no subtarget info for target " + TripleName); std::unique_ptr MII(TheTarget->createMCInstrInfo()); if (!MII) reportError(Obj->getFileName(), "no instruction info for target " + TripleName); MCObjectFileInfo MOFI; MCContext Ctx(AsmInfo.get(), MRI.get(), &MOFI); // FIXME: for now initialize MCObjectFileInfo with default values MOFI.InitMCObjectFileInfo(Triple(TripleName), false, Ctx); std::unique_ptr DisAsm( TheTarget->createMCDisassembler(*STI, Ctx)); if (!DisAsm) reportError(Obj->getFileName(), "no disassembler for target " + TripleName); // If we have an ARM object file, we need a second disassembler, because // ARM CPUs have two different instruction sets: ARM mode, and Thumb mode. // We use mapping symbols to switch between the two assemblers, where // appropriate. std::unique_ptr SecondaryDisAsm; std::unique_ptr SecondarySTI; if (isArmElf(Obj) && !STI->checkFeatures("+mclass")) { if (STI->checkFeatures("+thumb-mode")) Features.AddFeature("-thumb-mode"); else Features.AddFeature("+thumb-mode"); SecondarySTI.reset(TheTarget->createMCSubtargetInfo(TripleName, MCPU, Features.getString())); SecondaryDisAsm.reset(TheTarget->createMCDisassembler(*SecondarySTI, Ctx)); } std::unique_ptr MIA( TheTarget->createMCInstrAnalysis(MII.get())); int AsmPrinterVariant = AsmInfo->getAssemblerDialect(); std::unique_ptr IP(TheTarget->createMCInstPrinter( Triple(TripleName), AsmPrinterVariant, *AsmInfo, *MII, *MRI)); if (!IP) reportError(Obj->getFileName(), "no instruction printer for target " + TripleName); IP->setPrintImmHex(PrintImmHex); IP->setPrintBranchImmAsAddress(true); PrettyPrinter &PIP = selectPrettyPrinter(Triple(TripleName)); SourcePrinter SP(Obj, TheTarget->getName()); for (StringRef Opt : DisassemblerOptions) if (!IP->applyTargetSpecificCLOption(Opt)) reportError(Obj->getFileName(), "Unrecognized disassembler option: " + Opt); disassembleObject(TheTarget, Obj, Ctx, DisAsm.get(), SecondaryDisAsm.get(), MIA.get(), IP.get(), STI.get(), SecondarySTI.get(), PIP, SP, InlineRelocs); } void objdump::printRelocations(const ObjectFile *Obj) { StringRef Fmt = Obj->getBytesInAddress() > 4 ? "%016" PRIx64 : "%08" PRIx64; // Regular objdump doesn't print relocations in non-relocatable object // files. if (!Obj->isRelocatableObject()) return; // Build a mapping from relocation target to a vector of relocation // sections. Usually, there is an only one relocation section for // each relocated section. MapVector> SecToRelSec; uint64_t Ndx; for (const SectionRef &Section : ToolSectionFilter(*Obj, &Ndx)) { if (Section.relocation_begin() == Section.relocation_end()) continue; Expected SecOrErr = Section.getRelocatedSection(); if (!SecOrErr) reportError(Obj->getFileName(), "section (" + Twine(Ndx) + "): unable to get a relocation target: " + toString(SecOrErr.takeError())); SecToRelSec[**SecOrErr].push_back(Section); } for (std::pair> &P : SecToRelSec) { StringRef SecName = unwrapOrError(P.first.getName(), Obj->getFileName()); outs() << "RELOCATION RECORDS FOR [" << SecName << "]:\n"; uint32_t OffsetPadding = (Obj->getBytesInAddress() > 4 ? 16 : 8); uint32_t TypePadding = 24; outs() << left_justify("OFFSET", OffsetPadding) << " " << left_justify("TYPE", TypePadding) << " " << "VALUE\n"; for (SectionRef Section : P.second) { for (const RelocationRef &Reloc : Section.relocations()) { uint64_t Address = Reloc.getOffset(); SmallString<32> RelocName; SmallString<32> ValueStr; if (Address < StartAddress || Address > StopAddress || getHidden(Reloc)) continue; Reloc.getTypeName(RelocName); if (Error E = getRelocationValueString(Reloc, ValueStr)) reportError(std::move(E), Obj->getFileName()); outs() << format(Fmt.data(), Address) << " " << left_justify(RelocName, TypePadding) << " " << ValueStr << "\n"; } } outs() << "\n"; } } void objdump::printDynamicRelocations(const ObjectFile *Obj) { // For the moment, this option is for ELF only if (!Obj->isELF()) return; const auto *Elf = dyn_cast(Obj); if (!Elf || Elf->getEType() != ELF::ET_DYN) { reportError(Obj->getFileName(), "not a dynamic object"); return; } std::vector DynRelSec = Obj->dynamic_relocation_sections(); if (DynRelSec.empty()) return; outs() << "DYNAMIC RELOCATION RECORDS\n"; StringRef Fmt = Obj->getBytesInAddress() > 4 ? "%016" PRIx64 : "%08" PRIx64; for (const SectionRef &Section : DynRelSec) for (const RelocationRef &Reloc : Section.relocations()) { uint64_t Address = Reloc.getOffset(); SmallString<32> RelocName; SmallString<32> ValueStr; Reloc.getTypeName(RelocName); if (Error E = getRelocationValueString(Reloc, ValueStr)) reportError(std::move(E), Obj->getFileName()); outs() << format(Fmt.data(), Address) << " " << RelocName << " " << ValueStr << "\n"; } } // Returns true if we need to show LMA column when dumping section headers. We // show it only when the platform is ELF and either we have at least one section // whose VMA and LMA are different and/or when --show-lma flag is used. static bool shouldDisplayLMA(const ObjectFile *Obj) { if (!Obj->isELF()) return false; for (const SectionRef &S : ToolSectionFilter(*Obj)) if (S.getAddress() != getELFSectionLMA(S)) return true; return ShowLMA; } static size_t getMaxSectionNameWidth(const ObjectFile *Obj) { // Default column width for names is 13 even if no names are that long. size_t MaxWidth = 13; for (const SectionRef &Section : ToolSectionFilter(*Obj)) { StringRef Name = unwrapOrError(Section.getName(), Obj->getFileName()); MaxWidth = std::max(MaxWidth, Name.size()); } return MaxWidth; } void objdump::printSectionHeaders(const ObjectFile *Obj) { size_t NameWidth = getMaxSectionNameWidth(Obj); size_t AddressWidth = 2 * Obj->getBytesInAddress(); bool HasLMAColumn = shouldDisplayLMA(Obj); if (HasLMAColumn) outs() << "Sections:\n" "Idx " << left_justify("Name", NameWidth) << " Size " << left_justify("VMA", AddressWidth) << " " << left_justify("LMA", AddressWidth) << " Type\n"; else outs() << "Sections:\n" "Idx " << left_justify("Name", NameWidth) << " Size " << left_justify("VMA", AddressWidth) << " Type\n"; uint64_t Idx; for (const SectionRef &Section : ToolSectionFilter(*Obj, &Idx)) { StringRef Name = unwrapOrError(Section.getName(), Obj->getFileName()); uint64_t VMA = Section.getAddress(); if (shouldAdjustVA(Section)) VMA += AdjustVMA; uint64_t Size = Section.getSize(); std::string Type = Section.isText() ? "TEXT" : ""; if (Section.isData()) Type += Type.empty() ? "DATA" : " DATA"; if (Section.isBSS()) Type += Type.empty() ? "BSS" : " BSS"; if (HasLMAColumn) outs() << format("%3" PRIu64 " %-*s %08" PRIx64 " ", Idx, NameWidth, Name.str().c_str(), Size) << format_hex_no_prefix(VMA, AddressWidth) << " " << format_hex_no_prefix(getELFSectionLMA(Section), AddressWidth) << " " << Type << "\n"; else outs() << format("%3" PRIu64 " %-*s %08" PRIx64 " ", Idx, NameWidth, Name.str().c_str(), Size) << format_hex_no_prefix(VMA, AddressWidth) << " " << Type << "\n"; } outs() << "\n"; } void objdump::printSectionContents(const ObjectFile *Obj) { for (const SectionRef &Section : ToolSectionFilter(*Obj)) { StringRef Name = unwrapOrError(Section.getName(), Obj->getFileName()); uint64_t BaseAddr = Section.getAddress(); uint64_t Size = Section.getSize(); if (!Size) continue; outs() << "Contents of section " << Name << ":\n"; if (Section.isBSS()) { outs() << format("\n", BaseAddr, BaseAddr + Size); continue; } StringRef Contents = unwrapOrError(Section.getContents(), Obj->getFileName()); // Dump out the content as hex and printable ascii characters. for (std::size_t Addr = 0, End = Contents.size(); Addr < End; Addr += 16) { outs() << format(" %04" PRIx64 " ", BaseAddr + Addr); // Dump line of hex. for (std::size_t I = 0; I < 16; ++I) { if (I != 0 && I % 4 == 0) outs() << ' '; if (Addr + I < End) outs() << hexdigit((Contents[Addr + I] >> 4) & 0xF, true) << hexdigit(Contents[Addr + I] & 0xF, true); else outs() << " "; } // Print ascii. outs() << " "; for (std::size_t I = 0; I < 16 && Addr + I < End; ++I) { if (isPrint(static_cast(Contents[Addr + I]) & 0xFF)) outs() << Contents[Addr + I]; else outs() << "."; } outs() << "\n"; } } } void objdump::printSymbolTable(const ObjectFile *O, StringRef ArchiveName, StringRef ArchitectureName, bool DumpDynamic) { if (O->isCOFF() && !DumpDynamic) { outs() << "SYMBOL TABLE:\n"; printCOFFSymbolTable(cast(O)); return; } const StringRef FileName = O->getFileName(); if (!DumpDynamic) { outs() << "SYMBOL TABLE:\n"; for (auto I = O->symbol_begin(); I != O->symbol_end(); ++I) printSymbol(O, *I, FileName, ArchiveName, ArchitectureName, DumpDynamic); return; } outs() << "DYNAMIC SYMBOL TABLE:\n"; if (!O->isELF()) { reportWarning( "this operation is not currently supported for this file format", FileName); return; } const ELFObjectFileBase *ELF = cast(O); for (auto I = ELF->getDynamicSymbolIterators().begin(); I != ELF->getDynamicSymbolIterators().end(); ++I) printSymbol(O, *I, FileName, ArchiveName, ArchitectureName, DumpDynamic); } void objdump::printSymbol(const ObjectFile *O, const SymbolRef &Symbol, StringRef FileName, StringRef ArchiveName, StringRef ArchitectureName, bool DumpDynamic) { const MachOObjectFile *MachO = dyn_cast(O); uint64_t Address = unwrapOrError(Symbol.getAddress(), FileName, ArchiveName, ArchitectureName); if ((Address < StartAddress) || (Address > StopAddress)) return; SymbolRef::Type Type = unwrapOrError(Symbol.getType(), FileName, ArchiveName, ArchitectureName); uint32_t Flags = unwrapOrError(Symbol.getFlags(), FileName, ArchiveName, ArchitectureName); // Don't ask a Mach-O STAB symbol for its section unless you know that // STAB symbol's section field refers to a valid section index. Otherwise // the symbol may error trying to load a section that does not exist. bool IsSTAB = false; if (MachO) { DataRefImpl SymDRI = Symbol.getRawDataRefImpl(); uint8_t NType = (MachO->is64Bit() ? MachO->getSymbol64TableEntry(SymDRI).n_type : MachO->getSymbolTableEntry(SymDRI).n_type); if (NType & MachO::N_STAB) IsSTAB = true; } section_iterator Section = IsSTAB ? O->section_end() : unwrapOrError(Symbol.getSection(), FileName, ArchiveName, ArchitectureName); StringRef Name; if (Type == SymbolRef::ST_Debug && Section != O->section_end()) { if (Expected NameOrErr = Section->getName()) Name = *NameOrErr; else consumeError(NameOrErr.takeError()); } else { Name = unwrapOrError(Symbol.getName(), FileName, ArchiveName, ArchitectureName); } bool Global = Flags & SymbolRef::SF_Global; bool Weak = Flags & SymbolRef::SF_Weak; bool Absolute = Flags & SymbolRef::SF_Absolute; bool Common = Flags & SymbolRef::SF_Common; bool Hidden = Flags & SymbolRef::SF_Hidden; char GlobLoc = ' '; if ((Section != O->section_end() || Absolute) && !Weak) GlobLoc = Global ? 'g' : 'l'; char IFunc = ' '; if (O->isELF()) { if (ELFSymbolRef(Symbol).getELFType() == ELF::STT_GNU_IFUNC) IFunc = 'i'; if (ELFSymbolRef(Symbol).getBinding() == ELF::STB_GNU_UNIQUE) GlobLoc = 'u'; } char Debug = ' '; if (DumpDynamic) Debug = 'D'; else if (Type == SymbolRef::ST_Debug || Type == SymbolRef::ST_File) Debug = 'd'; char FileFunc = ' '; if (Type == SymbolRef::ST_File) FileFunc = 'f'; else if (Type == SymbolRef::ST_Function) FileFunc = 'F'; else if (Type == SymbolRef::ST_Data) FileFunc = 'O'; const char *Fmt = O->getBytesInAddress() > 4 ? "%016" PRIx64 : "%08" PRIx64; outs() << format(Fmt, Address) << " " << GlobLoc // Local -> 'l', Global -> 'g', Neither -> ' ' << (Weak ? 'w' : ' ') // Weak? << ' ' // Constructor. Not supported yet. << ' ' // Warning. Not supported yet. << IFunc // Indirect reference to another symbol. << Debug // Debugging (d) or dynamic (D) symbol. << FileFunc // Name of function (F), file (f) or object (O). << ' '; if (Absolute) { outs() << "*ABS*"; } else if (Common) { outs() << "*COM*"; } else if (Section == O->section_end()) { outs() << "*UND*"; } else { if (MachO) { DataRefImpl DR = Section->getRawDataRefImpl(); StringRef SegmentName = MachO->getSectionFinalSegmentName(DR); outs() << SegmentName << ","; } StringRef SectionName = unwrapOrError(Section->getName(), FileName); outs() << SectionName; } if (Common || O->isELF()) { uint64_t Val = Common ? Symbol.getAlignment() : ELFSymbolRef(Symbol).getSize(); outs() << '\t' << format(Fmt, Val); } if (O->isELF()) { uint8_t Other = ELFSymbolRef(Symbol).getOther(); switch (Other) { case ELF::STV_DEFAULT: break; case ELF::STV_INTERNAL: outs() << " .internal"; break; case ELF::STV_HIDDEN: outs() << " .hidden"; break; case ELF::STV_PROTECTED: outs() << " .protected"; break; default: outs() << format(" 0x%02x", Other); break; } } else if (Hidden) { outs() << " .hidden"; } if (Demangle) outs() << ' ' << demangle(std::string(Name)) << '\n'; else outs() << ' ' << Name << '\n'; } static void printUnwindInfo(const ObjectFile *O) { outs() << "Unwind info:\n\n"; if (const COFFObjectFile *Coff = dyn_cast(O)) printCOFFUnwindInfo(Coff); else if (const MachOObjectFile *MachO = dyn_cast(O)) printMachOUnwindInfo(MachO); else // TODO: Extract DWARF dump tool to objdump. WithColor::error(errs(), ToolName) << "This operation is only currently supported " "for COFF and MachO object files.\n"; } /// Dump the raw contents of the __clangast section so the output can be piped /// into llvm-bcanalyzer. static void printRawClangAST(const ObjectFile *Obj) { if (outs().is_displayed()) { WithColor::error(errs(), ToolName) << "The -raw-clang-ast option will dump the raw binary contents of " "the clang ast section.\n" "Please redirect the output to a file or another program such as " "llvm-bcanalyzer.\n"; return; } StringRef ClangASTSectionName("__clangast"); if (Obj->isCOFF()) { ClangASTSectionName = "clangast"; } Optional ClangASTSection; for (auto Sec : ToolSectionFilter(*Obj)) { StringRef Name; if (Expected NameOrErr = Sec.getName()) Name = *NameOrErr; else consumeError(NameOrErr.takeError()); if (Name == ClangASTSectionName) { ClangASTSection = Sec; break; } } if (!ClangASTSection) return; StringRef ClangASTContents = unwrapOrError( ClangASTSection.getValue().getContents(), Obj->getFileName()); outs().write(ClangASTContents.data(), ClangASTContents.size()); } static void printFaultMaps(const ObjectFile *Obj) { StringRef FaultMapSectionName; if (Obj->isELF()) { FaultMapSectionName = ".llvm_faultmaps"; } else if (Obj->isMachO()) { FaultMapSectionName = "__llvm_faultmaps"; } else { WithColor::error(errs(), ToolName) << "This operation is only currently supported " "for ELF and Mach-O executable files.\n"; return; } Optional FaultMapSection; for (auto Sec : ToolSectionFilter(*Obj)) { StringRef Name; if (Expected NameOrErr = Sec.getName()) Name = *NameOrErr; else consumeError(NameOrErr.takeError()); if (Name == FaultMapSectionName) { FaultMapSection = Sec; break; } } outs() << "FaultMap table:\n"; if (!FaultMapSection.hasValue()) { outs() << "\n"; return; } StringRef FaultMapContents = unwrapOrError(FaultMapSection.getValue().getContents(), Obj->getFileName()); FaultMapParser FMP(FaultMapContents.bytes_begin(), FaultMapContents.bytes_end()); outs() << FMP; } static void printPrivateFileHeaders(const ObjectFile *O, bool OnlyFirst) { if (O->isELF()) { printELFFileHeader(O); printELFDynamicSection(O); printELFSymbolVersionInfo(O); return; } if (O->isCOFF()) return printCOFFFileHeader(O); if (O->isWasm()) return printWasmFileHeader(O); if (O->isMachO()) { printMachOFileHeader(O); if (!OnlyFirst) printMachOLoadCommands(O); return; } reportError(O->getFileName(), "Invalid/Unsupported object file format"); } static void printFileHeaders(const ObjectFile *O) { if (!O->isELF() && !O->isCOFF()) reportError(O->getFileName(), "Invalid/Unsupported object file format"); Triple::ArchType AT = O->getArch(); outs() << "architecture: " << Triple::getArchTypeName(AT) << "\n"; uint64_t Address = unwrapOrError(O->getStartAddress(), O->getFileName()); StringRef Fmt = O->getBytesInAddress() > 4 ? "%016" PRIx64 : "%08" PRIx64; outs() << "start address: " << "0x" << format(Fmt.data(), Address) << "\n\n"; } static void printArchiveChild(StringRef Filename, const Archive::Child &C) { Expected ModeOrErr = C.getAccessMode(); if (!ModeOrErr) { WithColor::error(errs(), ToolName) << "ill-formed archive entry.\n"; consumeError(ModeOrErr.takeError()); return; } sys::fs::perms Mode = ModeOrErr.get(); outs() << ((Mode & sys::fs::owner_read) ? "r" : "-"); outs() << ((Mode & sys::fs::owner_write) ? "w" : "-"); outs() << ((Mode & sys::fs::owner_exe) ? "x" : "-"); outs() << ((Mode & sys::fs::group_read) ? "r" : "-"); outs() << ((Mode & sys::fs::group_write) ? "w" : "-"); outs() << ((Mode & sys::fs::group_exe) ? "x" : "-"); outs() << ((Mode & sys::fs::others_read) ? "r" : "-"); outs() << ((Mode & sys::fs::others_write) ? "w" : "-"); outs() << ((Mode & sys::fs::others_exe) ? "x" : "-"); outs() << " "; outs() << format("%d/%d %6" PRId64 " ", unwrapOrError(C.getUID(), Filename), unwrapOrError(C.getGID(), Filename), unwrapOrError(C.getRawSize(), Filename)); StringRef RawLastModified = C.getRawLastModified(); unsigned Seconds; if (RawLastModified.getAsInteger(10, Seconds)) outs() << "(date: \"" << RawLastModified << "\" contains non-decimal chars) "; else { // Since ctime(3) returns a 26 character string of the form: // "Sun Sep 16 01:03:52 1973\n\0" // just print 24 characters. time_t t = Seconds; outs() << format("%.24s ", ctime(&t)); } StringRef Name = ""; Expected NameOrErr = C.getName(); if (!NameOrErr) { consumeError(NameOrErr.takeError()); Name = unwrapOrError(C.getRawName(), Filename); } else { Name = NameOrErr.get(); } outs() << Name << "\n"; } // For ELF only now. static bool shouldWarnForInvalidStartStopAddress(ObjectFile *Obj) { if (const auto *Elf = dyn_cast(Obj)) { if (Elf->getEType() != ELF::ET_REL) return true; } return false; } static void checkForInvalidStartStopAddress(ObjectFile *Obj, uint64_t Start, uint64_t Stop) { if (!shouldWarnForInvalidStartStopAddress(Obj)) return; for (const SectionRef &Section : Obj->sections()) if (ELFSectionRef(Section).getFlags() & ELF::SHF_ALLOC) { uint64_t BaseAddr = Section.getAddress(); uint64_t Size = Section.getSize(); if ((Start < BaseAddr + Size) && Stop > BaseAddr) return; } if (StartAddress.getNumOccurrences() == 0) reportWarning("no section has address less than 0x" + Twine::utohexstr(Stop) + " specified by --stop-address", Obj->getFileName()); else if (StopAddress.getNumOccurrences() == 0) reportWarning("no section has address greater than or equal to 0x" + Twine::utohexstr(Start) + " specified by --start-address", Obj->getFileName()); else reportWarning("no section overlaps the range [0x" + Twine::utohexstr(Start) + ",0x" + Twine::utohexstr(Stop) + ") specified by --start-address/--stop-address", Obj->getFileName()); } static void dumpObject(ObjectFile *O, const Archive *A = nullptr, const Archive::Child *C = nullptr) { // Avoid other output when using a raw option. if (!RawClangAST) { outs() << '\n'; if (A) outs() << A->getFileName() << "(" << O->getFileName() << ")"; else outs() << O->getFileName(); outs() << ":\tfile format " << O->getFileFormatName().lower() << "\n\n"; } if (StartAddress.getNumOccurrences() || StopAddress.getNumOccurrences()) checkForInvalidStartStopAddress(O, StartAddress, StopAddress); // Note: the order here matches GNU objdump for compatability. StringRef ArchiveName = A ? A->getFileName() : ""; if (ArchiveHeaders && !MachOOpt && C) printArchiveChild(ArchiveName, *C); if (FileHeaders) printFileHeaders(O); if (PrivateHeaders || FirstPrivateHeader) printPrivateFileHeaders(O, FirstPrivateHeader); if (SectionHeaders) printSectionHeaders(O); if (SymbolTable) printSymbolTable(O, ArchiveName); if (DynamicSymbolTable) printSymbolTable(O, ArchiveName, /*ArchitectureName=*/"", /*DumpDynamic=*/true); if (DwarfDumpType != DIDT_Null) { std::unique_ptr DICtx = DWARFContext::create(*O); // Dump the complete DWARF structure. DIDumpOptions DumpOpts; DumpOpts.DumpType = DwarfDumpType; DICtx->dump(outs(), DumpOpts); } if (Relocations && !Disassemble) printRelocations(O); if (DynamicRelocations) printDynamicRelocations(O); if (SectionContents) printSectionContents(O); if (Disassemble) disassembleObject(O, Relocations); if (UnwindInfo) printUnwindInfo(O); // Mach-O specific options: if (ExportsTrie) printExportsTrie(O); if (Rebase) printRebaseTable(O); if (Bind) printBindTable(O); if (LazyBind) printLazyBindTable(O); if (WeakBind) printWeakBindTable(O); // Other special sections: if (RawClangAST) printRawClangAST(O); if (FaultMapSection) printFaultMaps(O); } static void dumpObject(const COFFImportFile *I, const Archive *A, const Archive::Child *C = nullptr) { StringRef ArchiveName = A ? A->getFileName() : ""; // Avoid other output when using a raw option. if (!RawClangAST) outs() << '\n' << ArchiveName << "(" << I->getFileName() << ")" << ":\tfile format COFF-import-file" << "\n\n"; if (ArchiveHeaders && !MachOOpt && C) printArchiveChild(ArchiveName, *C); if (SymbolTable) printCOFFSymbolTable(I); } /// Dump each object file in \a a; static void dumpArchive(const Archive *A) { Error Err = Error::success(); unsigned I = -1; for (auto &C : A->children(Err)) { ++I; Expected> ChildOrErr = C.getAsBinary(); if (!ChildOrErr) { if (auto E = isNotObjectErrorInvalidFileType(ChildOrErr.takeError())) reportError(std::move(E), getFileNameForError(C, I), A->getFileName()); continue; } if (ObjectFile *O = dyn_cast(&*ChildOrErr.get())) dumpObject(O, A, &C); else if (COFFImportFile *I = dyn_cast(&*ChildOrErr.get())) dumpObject(I, A, &C); else reportError(errorCodeToError(object_error::invalid_file_type), A->getFileName()); } if (Err) reportError(std::move(Err), A->getFileName()); } /// Open file and figure out how to dump it. static void dumpInput(StringRef file) { // If we are using the Mach-O specific object file parser, then let it parse // the file and process the command line options. So the -arch flags can // be used to select specific slices, etc. if (MachOOpt) { parseInputMachO(file); return; } // Attempt to open the binary. OwningBinary OBinary = unwrapOrError(createBinary(file), file); Binary &Binary = *OBinary.getBinary(); if (Archive *A = dyn_cast(&Binary)) dumpArchive(A); else if (ObjectFile *O = dyn_cast(&Binary)) dumpObject(O); else if (MachOUniversalBinary *UB = dyn_cast(&Binary)) parseInputMachO(UB); else reportError(errorCodeToError(object_error::invalid_file_type), file); } int main(int argc, char **argv) { using namespace llvm; InitLLVM X(argc, argv); const cl::OptionCategory *OptionFilters[] = {&ObjdumpCat, &MachOCat}; cl::HideUnrelatedOptions(OptionFilters); // Initialize targets and assembly printers/parsers. InitializeAllTargetInfos(); InitializeAllTargetMCs(); InitializeAllDisassemblers(); // Register the target printer for --version. cl::AddExtraVersionPrinter(TargetRegistry::printRegisteredTargetsForVersion); cl::ParseCommandLineOptions(argc, argv, "llvm object file dumper\n", nullptr, /*EnvVar=*/nullptr, /*LongOptionsUseDoubleDash=*/true); if (StartAddress >= StopAddress) reportCmdLineError("start address should be less than stop address"); ToolName = argv[0]; // Defaults to a.out if no filenames specified. if (InputFilenames.empty()) InputFilenames.push_back("a.out"); if (AllHeaders) ArchiveHeaders = FileHeaders = PrivateHeaders = Relocations = SectionHeaders = SymbolTable = true; if (DisassembleAll || PrintSource || PrintLines || !DisassembleSymbols.empty()) Disassemble = true; if (!ArchiveHeaders && !Disassemble && DwarfDumpType == DIDT_Null && !DynamicRelocations && !FileHeaders && !PrivateHeaders && !RawClangAST && !Relocations && !SectionHeaders && !SectionContents && !SymbolTable && !DynamicSymbolTable && !UnwindInfo && !FaultMapSection && !(MachOOpt && (Bind || DataInCode || DylibId || DylibsUsed || ExportsTrie || FirstPrivateHeader || IndirectSymbols || InfoPlist || LazyBind || LinkOptHints || ObjcMetaData || Rebase || UniversalHeaders || WeakBind || !FilterSections.empty()))) { cl::PrintHelpMessage(); return 2; } DisasmSymbolSet.insert(DisassembleSymbols.begin(), DisassembleSymbols.end()); llvm::for_each(InputFilenames, dumpInput); warnOnNoMatchForSections(); return EXIT_SUCCESS; }