llvm-project/llvm/tools/llvm-objdump/MachODump.cpp

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//===-- MachODump.cpp - Object file dumping utility for llvm --------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the MachO-specific dumper for llvm-objdump.
//
//===----------------------------------------------------------------------===//
#include "llvm-objdump.h"
#include "llvm-c/Disassembler.h"
#include "llvm/ADT/STLExtras.h"
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
#include "llvm/ADT/StringExtras.h"
#include "llvm/ADT/Triple.h"
#include "llvm/Config/config.h"
#include "llvm/DebugInfo/DIContext.h"
#include "llvm/DebugInfo/DWARF/DWARFContext.h"
#include "llvm/MC/MCAsmInfo.h"
#include "llvm/MC/MCContext.h"
#include "llvm/MC/MCDisassembler.h"
#include "llvm/MC/MCInst.h"
#include "llvm/MC/MCInstPrinter.h"
#include "llvm/MC/MCInstrDesc.h"
#include "llvm/MC/MCInstrInfo.h"
#include "llvm/MC/MCRegisterInfo.h"
#include "llvm/MC/MCSubtargetInfo.h"
#include "llvm/Object/MachO.h"
#include "llvm/Object/MachOUniversal.h"
#include "llvm/Support/Casting.h"
#include "llvm/Support/CommandLine.h"
#include "llvm/Support/Debug.h"
#include "llvm/Support/Endian.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/FormattedStream.h"
#include "llvm/Support/GraphWriter.h"
#include "llvm/Support/LEB128.h"
#include "llvm/Support/MachO.h"
#include "llvm/Support/MemoryBuffer.h"
#include "llvm/Support/TargetRegistry.h"
#include "llvm/Support/TargetSelect.h"
#include "llvm/Support/raw_ostream.h"
#include <algorithm>
#include <cstring>
#include <system_error>
#if HAVE_CXXABI_H
#include <cxxabi.h>
#endif
using namespace llvm;
using namespace object;
static cl::opt<bool>
UseDbg("g",
cl::desc("Print line information from debug info if available"));
static cl::opt<std::string> DSYMFile("dsym",
cl::desc("Use .dSYM file for debug info"));
static cl::opt<bool> FullLeadingAddr("full-leading-addr",
cl::desc("Print full leading address"));
static cl::opt<bool> NoLeadingAddr("no-leading-addr",
cl::desc("Print no leading address"));
cl::opt<bool> llvm::UniversalHeaders("universal-headers",
cl::desc("Print Mach-O universal headers "
"(requires -macho)"));
cl::opt<bool>
llvm::ArchiveHeaders("archive-headers",
cl::desc("Print archive headers for Mach-O archives "
"(requires -macho)"));
cl::opt<bool>
ArchiveMemberOffsets("archive-member-offsets",
cl::desc("Print the offset to each archive member for "
"Mach-O archives (requires -macho and "
"-archive-headers)"));
cl::opt<bool>
llvm::IndirectSymbols("indirect-symbols",
cl::desc("Print indirect symbol table for Mach-O "
"objects (requires -macho)"));
cl::opt<bool>
llvm::DataInCode("data-in-code",
cl::desc("Print the data in code table for Mach-O objects "
"(requires -macho)"));
cl::opt<bool>
llvm::LinkOptHints("link-opt-hints",
cl::desc("Print the linker optimization hints for "
"Mach-O objects (requires -macho)"));
cl::list<std::string>
llvm::DumpSections("section",
cl::desc("Prints the specified segment,section for "
"Mach-O objects (requires -macho)"));
cl::opt<bool> llvm::Raw("raw",
cl::desc("Have -section dump the raw binary contents"));
cl::opt<bool>
llvm::InfoPlist("info-plist",
cl::desc("Print the info plist section as strings for "
"Mach-O objects (requires -macho)"));
cl::opt<bool>
llvm::DylibsUsed("dylibs-used",
cl::desc("Print the shared libraries used for linked "
"Mach-O files (requires -macho)"));
cl::opt<bool>
llvm::DylibId("dylib-id",
cl::desc("Print the shared library's id for the dylib Mach-O "
"file (requires -macho)"));
cl::opt<bool>
llvm::NonVerbose("non-verbose",
cl::desc("Print the info for Mach-O objects in "
"non-verbose or numeric form (requires -macho)"));
cl::opt<bool>
llvm::ObjcMetaData("objc-meta-data",
cl::desc("Print the Objective-C runtime meta data for "
"Mach-O files (requires -macho)"));
cl::opt<std::string> llvm::DisSymName(
"dis-symname",
cl::desc("disassemble just this symbol's instructions (requires -macho"));
static cl::opt<bool> NoSymbolicOperands(
"no-symbolic-operands",
cl::desc("do not symbolic operands when disassembling (requires -macho)"));
static cl::list<std::string>
ArchFlags("arch", cl::desc("architecture(s) from a Mach-O file to dump"),
cl::ZeroOrMore);
bool ArchAll = false;
static std::string ThumbTripleName;
static const Target *GetTarget(const MachOObjectFile *MachOObj,
const char **McpuDefault,
const Target **ThumbTarget) {
// Figure out the target triple.
if (TripleName.empty()) {
llvm::Triple TT("unknown-unknown-unknown");
llvm::Triple ThumbTriple = Triple();
TT = MachOObj->getArch(McpuDefault, &ThumbTriple);
TripleName = TT.str();
ThumbTripleName = ThumbTriple.str();
}
// Get the target specific parser.
std::string Error;
const Target *TheTarget = TargetRegistry::lookupTarget(TripleName, Error);
if (TheTarget && ThumbTripleName.empty())
return TheTarget;
*ThumbTarget = TargetRegistry::lookupTarget(ThumbTripleName, Error);
if (*ThumbTarget)
return TheTarget;
errs() << "llvm-objdump: error: unable to get target for '";
if (!TheTarget)
errs() << TripleName;
else
errs() << ThumbTripleName;
errs() << "', see --version and --triple.\n";
return nullptr;
}
struct SymbolSorter {
bool operator()(const SymbolRef &A, const SymbolRef &B) {
uint64_t AAddr = (A.getType() != SymbolRef::ST_Function) ? 0 : A.getValue();
uint64_t BAddr = (B.getType() != SymbolRef::ST_Function) ? 0 : B.getValue();
return AAddr < BAddr;
}
};
// Types for the storted data in code table that is built before disassembly
// and the predicate function to sort them.
typedef std::pair<uint64_t, DiceRef> DiceTableEntry;
typedef std::vector<DiceTableEntry> DiceTable;
typedef DiceTable::iterator dice_table_iterator;
// This is used to search for a data in code table entry for the PC being
// disassembled. The j parameter has the PC in j.first. A single data in code
// table entry can cover many bytes for each of its Kind's. So if the offset,
// aka the i.first value, of the data in code table entry plus its Length
// covers the PC being searched for this will return true. If not it will
// return false.
static bool compareDiceTableEntries(const DiceTableEntry &i,
const DiceTableEntry &j) {
uint16_t Length;
i.second.getLength(Length);
return j.first >= i.first && j.first < i.first + Length;
}
static uint64_t DumpDataInCode(const uint8_t *bytes, uint64_t Length,
unsigned short Kind) {
uint32_t Value, Size = 1;
switch (Kind) {
default:
case MachO::DICE_KIND_DATA:
if (Length >= 4) {
if (!NoShowRawInsn)
dumpBytes(ArrayRef<uint8_t>(bytes, 4), outs());
Value = bytes[3] << 24 | bytes[2] << 16 | bytes[1] << 8 | bytes[0];
outs() << "\t.long " << Value;
Size = 4;
} else if (Length >= 2) {
if (!NoShowRawInsn)
dumpBytes(ArrayRef<uint8_t>(bytes, 2), outs());
Value = bytes[1] << 8 | bytes[0];
outs() << "\t.short " << Value;
Size = 2;
} else {
if (!NoShowRawInsn)
dumpBytes(ArrayRef<uint8_t>(bytes, 2), outs());
Value = bytes[0];
outs() << "\t.byte " << Value;
Size = 1;
}
if (Kind == MachO::DICE_KIND_DATA)
outs() << "\t@ KIND_DATA\n";
else
outs() << "\t@ data in code kind = " << Kind << "\n";
break;
case MachO::DICE_KIND_JUMP_TABLE8:
if (!NoShowRawInsn)
dumpBytes(ArrayRef<uint8_t>(bytes, 1), outs());
Value = bytes[0];
outs() << "\t.byte " << format("%3u", Value) << "\t@ KIND_JUMP_TABLE8\n";
Size = 1;
break;
case MachO::DICE_KIND_JUMP_TABLE16:
if (!NoShowRawInsn)
dumpBytes(ArrayRef<uint8_t>(bytes, 2), outs());
Value = bytes[1] << 8 | bytes[0];
outs() << "\t.short " << format("%5u", Value & 0xffff)
<< "\t@ KIND_JUMP_TABLE16\n";
Size = 2;
break;
case MachO::DICE_KIND_JUMP_TABLE32:
case MachO::DICE_KIND_ABS_JUMP_TABLE32:
if (!NoShowRawInsn)
dumpBytes(ArrayRef<uint8_t>(bytes, 4), outs());
Value = bytes[3] << 24 | bytes[2] << 16 | bytes[1] << 8 | bytes[0];
outs() << "\t.long " << Value;
if (Kind == MachO::DICE_KIND_JUMP_TABLE32)
outs() << "\t@ KIND_JUMP_TABLE32\n";
else
outs() << "\t@ KIND_ABS_JUMP_TABLE32\n";
Size = 4;
break;
}
return Size;
}
static void getSectionsAndSymbols(MachOObjectFile *MachOObj,
std::vector<SectionRef> &Sections,
std::vector<SymbolRef> &Symbols,
SmallVectorImpl<uint64_t> &FoundFns,
uint64_t &BaseSegmentAddress) {
for (const SymbolRef &Symbol : MachOObj->symbols()) {
ErrorOr<StringRef> SymName = Symbol.getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
if (!SymName->startswith("ltmp"))
Symbols.push_back(Symbol);
}
for (const SectionRef &Section : MachOObj->sections()) {
StringRef SectName;
Section.getName(SectName);
Sections.push_back(Section);
}
bool BaseSegmentAddressSet = false;
for (const auto &Command : MachOObj->load_commands()) {
if (Command.C.cmd == MachO::LC_FUNCTION_STARTS) {
// We found a function starts segment, parse the addresses for later
// consumption.
MachO::linkedit_data_command LLC =
MachOObj->getLinkeditDataLoadCommand(Command);
MachOObj->ReadULEB128s(LLC.dataoff, FoundFns);
} else if (Command.C.cmd == MachO::LC_SEGMENT) {
MachO::segment_command SLC = MachOObj->getSegmentLoadCommand(Command);
StringRef SegName = SLC.segname;
if (!BaseSegmentAddressSet && SegName != "__PAGEZERO") {
BaseSegmentAddressSet = true;
BaseSegmentAddress = SLC.vmaddr;
}
}
}
}
static void PrintIndirectSymbolTable(MachOObjectFile *O, bool verbose,
uint32_t n, uint32_t count,
uint32_t stride, uint64_t addr) {
MachO::dysymtab_command Dysymtab = O->getDysymtabLoadCommand();
uint32_t nindirectsyms = Dysymtab.nindirectsyms;
if (n > nindirectsyms)
outs() << " (entries start past the end of the indirect symbol "
"table) (reserved1 field greater than the table size)";
else if (n + count > nindirectsyms)
outs() << " (entries extends past the end of the indirect symbol "
"table)";
outs() << "\n";
uint32_t cputype = O->getHeader().cputype;
if (cputype & MachO::CPU_ARCH_ABI64)
outs() << "address index";
else
outs() << "address index";
if (verbose)
outs() << " name\n";
else
outs() << "\n";
for (uint32_t j = 0; j < count && n + j < nindirectsyms; j++) {
if (cputype & MachO::CPU_ARCH_ABI64)
outs() << format("0x%016" PRIx64, addr + j * stride) << " ";
else
outs() << format("0x%08" PRIx32, addr + j * stride) << " ";
MachO::dysymtab_command Dysymtab = O->getDysymtabLoadCommand();
uint32_t indirect_symbol = O->getIndirectSymbolTableEntry(Dysymtab, n + j);
if (indirect_symbol == MachO::INDIRECT_SYMBOL_LOCAL) {
outs() << "LOCAL\n";
continue;
}
if (indirect_symbol ==
(MachO::INDIRECT_SYMBOL_LOCAL | MachO::INDIRECT_SYMBOL_ABS)) {
outs() << "LOCAL ABSOLUTE\n";
continue;
}
if (indirect_symbol == MachO::INDIRECT_SYMBOL_ABS) {
outs() << "ABSOLUTE\n";
continue;
}
outs() << format("%5u ", indirect_symbol);
if (verbose) {
MachO::symtab_command Symtab = O->getSymtabLoadCommand();
if (indirect_symbol < Symtab.nsyms) {
symbol_iterator Sym = O->getSymbolByIndex(indirect_symbol);
SymbolRef Symbol = *Sym;
ErrorOr<StringRef> SymName = Symbol.getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
outs() << *SymName;
} else {
outs() << "?";
}
}
outs() << "\n";
}
}
static void PrintIndirectSymbols(MachOObjectFile *O, bool verbose) {
for (const auto &Load : O->load_commands()) {
if (Load.C.cmd == MachO::LC_SEGMENT_64) {
MachO::segment_command_64 Seg = O->getSegment64LoadCommand(Load);
for (unsigned J = 0; J < Seg.nsects; ++J) {
MachO::section_64 Sec = O->getSection64(Load, J);
uint32_t section_type = Sec.flags & MachO::SECTION_TYPE;
if (section_type == MachO::S_NON_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_DYLIB_SYMBOL_POINTERS ||
section_type == MachO::S_THREAD_LOCAL_VARIABLE_POINTERS ||
section_type == MachO::S_SYMBOL_STUBS) {
uint32_t stride;
if (section_type == MachO::S_SYMBOL_STUBS)
stride = Sec.reserved2;
else
stride = 8;
if (stride == 0) {
outs() << "Can't print indirect symbols for (" << Sec.segname << ","
<< Sec.sectname << ") "
<< "(size of stubs in reserved2 field is zero)\n";
continue;
}
uint32_t count = Sec.size / stride;
outs() << "Indirect symbols for (" << Sec.segname << ","
<< Sec.sectname << ") " << count << " entries";
uint32_t n = Sec.reserved1;
PrintIndirectSymbolTable(O, verbose, n, count, stride, Sec.addr);
}
}
} else if (Load.C.cmd == MachO::LC_SEGMENT) {
MachO::segment_command Seg = O->getSegmentLoadCommand(Load);
for (unsigned J = 0; J < Seg.nsects; ++J) {
MachO::section Sec = O->getSection(Load, J);
uint32_t section_type = Sec.flags & MachO::SECTION_TYPE;
if (section_type == MachO::S_NON_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_DYLIB_SYMBOL_POINTERS ||
section_type == MachO::S_THREAD_LOCAL_VARIABLE_POINTERS ||
section_type == MachO::S_SYMBOL_STUBS) {
uint32_t stride;
if (section_type == MachO::S_SYMBOL_STUBS)
stride = Sec.reserved2;
else
stride = 4;
if (stride == 0) {
outs() << "Can't print indirect symbols for (" << Sec.segname << ","
<< Sec.sectname << ") "
<< "(size of stubs in reserved2 field is zero)\n";
continue;
}
uint32_t count = Sec.size / stride;
outs() << "Indirect symbols for (" << Sec.segname << ","
<< Sec.sectname << ") " << count << " entries";
uint32_t n = Sec.reserved1;
PrintIndirectSymbolTable(O, verbose, n, count, stride, Sec.addr);
}
}
}
}
}
static void PrintDataInCodeTable(MachOObjectFile *O, bool verbose) {
MachO::linkedit_data_command DIC = O->getDataInCodeLoadCommand();
uint32_t nentries = DIC.datasize / sizeof(struct MachO::data_in_code_entry);
outs() << "Data in code table (" << nentries << " entries)\n";
outs() << "offset length kind\n";
for (dice_iterator DI = O->begin_dices(), DE = O->end_dices(); DI != DE;
++DI) {
uint32_t Offset;
DI->getOffset(Offset);
outs() << format("0x%08" PRIx32, Offset) << " ";
uint16_t Length;
DI->getLength(Length);
outs() << format("%6u", Length) << " ";
uint16_t Kind;
DI->getKind(Kind);
if (verbose) {
switch (Kind) {
case MachO::DICE_KIND_DATA:
outs() << "DATA";
break;
case MachO::DICE_KIND_JUMP_TABLE8:
outs() << "JUMP_TABLE8";
break;
case MachO::DICE_KIND_JUMP_TABLE16:
outs() << "JUMP_TABLE16";
break;
case MachO::DICE_KIND_JUMP_TABLE32:
outs() << "JUMP_TABLE32";
break;
case MachO::DICE_KIND_ABS_JUMP_TABLE32:
outs() << "ABS_JUMP_TABLE32";
break;
default:
outs() << format("0x%04" PRIx32, Kind);
break;
}
} else
outs() << format("0x%04" PRIx32, Kind);
outs() << "\n";
}
}
static void PrintLinkOptHints(MachOObjectFile *O) {
MachO::linkedit_data_command LohLC = O->getLinkOptHintsLoadCommand();
const char *loh = O->getData().substr(LohLC.dataoff, 1).data();
uint32_t nloh = LohLC.datasize;
outs() << "Linker optimiztion hints (" << nloh << " total bytes)\n";
for (uint32_t i = 0; i < nloh;) {
unsigned n;
uint64_t identifier = decodeULEB128((const uint8_t *)(loh + i), &n);
i += n;
outs() << " identifier " << identifier << " ";
if (i >= nloh)
return;
switch (identifier) {
case 1:
outs() << "AdrpAdrp\n";
break;
case 2:
outs() << "AdrpLdr\n";
break;
case 3:
outs() << "AdrpAddLdr\n";
break;
case 4:
outs() << "AdrpLdrGotLdr\n";
break;
case 5:
outs() << "AdrpAddStr\n";
break;
case 6:
outs() << "AdrpLdrGotStr\n";
break;
case 7:
outs() << "AdrpAdd\n";
break;
case 8:
outs() << "AdrpLdrGot\n";
break;
default:
outs() << "Unknown identifier value\n";
break;
}
uint64_t narguments = decodeULEB128((const uint8_t *)(loh + i), &n);
i += n;
outs() << " narguments " << narguments << "\n";
if (i >= nloh)
return;
for (uint32_t j = 0; j < narguments; j++) {
uint64_t value = decodeULEB128((const uint8_t *)(loh + i), &n);
i += n;
outs() << "\tvalue " << format("0x%" PRIx64, value) << "\n";
if (i >= nloh)
return;
}
}
}
static void PrintDylibs(MachOObjectFile *O, bool JustId) {
unsigned Index = 0;
for (const auto &Load : O->load_commands()) {
if ((JustId && Load.C.cmd == MachO::LC_ID_DYLIB) ||
(!JustId && (Load.C.cmd == MachO::LC_ID_DYLIB ||
Load.C.cmd == MachO::LC_LOAD_DYLIB ||
Load.C.cmd == MachO::LC_LOAD_WEAK_DYLIB ||
Load.C.cmd == MachO::LC_REEXPORT_DYLIB ||
Load.C.cmd == MachO::LC_LAZY_LOAD_DYLIB ||
Load.C.cmd == MachO::LC_LOAD_UPWARD_DYLIB))) {
MachO::dylib_command dl = O->getDylibIDLoadCommand(Load);
if (dl.dylib.name < dl.cmdsize) {
const char *p = (const char *)(Load.Ptr) + dl.dylib.name;
if (JustId)
outs() << p << "\n";
else {
outs() << "\t" << p;
outs() << " (compatibility version "
<< ((dl.dylib.compatibility_version >> 16) & 0xffff) << "."
<< ((dl.dylib.compatibility_version >> 8) & 0xff) << "."
<< (dl.dylib.compatibility_version & 0xff) << ",";
outs() << " current version "
<< ((dl.dylib.current_version >> 16) & 0xffff) << "."
<< ((dl.dylib.current_version >> 8) & 0xff) << "."
<< (dl.dylib.current_version & 0xff) << ")\n";
}
} else {
outs() << "\tBad offset (" << dl.dylib.name << ") for name of ";
if (Load.C.cmd == MachO::LC_ID_DYLIB)
outs() << "LC_ID_DYLIB ";
else if (Load.C.cmd == MachO::LC_LOAD_DYLIB)
outs() << "LC_LOAD_DYLIB ";
else if (Load.C.cmd == MachO::LC_LOAD_WEAK_DYLIB)
outs() << "LC_LOAD_WEAK_DYLIB ";
else if (Load.C.cmd == MachO::LC_LAZY_LOAD_DYLIB)
outs() << "LC_LAZY_LOAD_DYLIB ";
else if (Load.C.cmd == MachO::LC_REEXPORT_DYLIB)
outs() << "LC_REEXPORT_DYLIB ";
else if (Load.C.cmd == MachO::LC_LOAD_UPWARD_DYLIB)
outs() << "LC_LOAD_UPWARD_DYLIB ";
else
outs() << "LC_??? ";
outs() << "command " << Index++ << "\n";
}
}
}
}
typedef DenseMap<uint64_t, StringRef> SymbolAddressMap;
static void CreateSymbolAddressMap(MachOObjectFile *O,
SymbolAddressMap *AddrMap) {
// Create a map of symbol addresses to symbol names.
for (const SymbolRef &Symbol : O->symbols()) {
SymbolRef::Type ST = Symbol.getType();
if (ST == SymbolRef::ST_Function || ST == SymbolRef::ST_Data ||
ST == SymbolRef::ST_Other) {
uint64_t Address = Symbol.getValue();
ErrorOr<StringRef> SymNameOrErr = Symbol.getName();
if (std::error_code EC = SymNameOrErr.getError())
report_fatal_error(EC.message());
StringRef SymName = *SymNameOrErr;
if (!SymName.startswith(".objc"))
(*AddrMap)[Address] = SymName;
}
}
}
// GuessSymbolName is passed the address of what might be a symbol and a
// pointer to the SymbolAddressMap. It returns the name of a symbol
// with that address or nullptr if no symbol is found with that address.
static const char *GuessSymbolName(uint64_t value, SymbolAddressMap *AddrMap) {
const char *SymbolName = nullptr;
// A DenseMap can't lookup up some values.
if (value != 0xffffffffffffffffULL && value != 0xfffffffffffffffeULL) {
StringRef name = AddrMap->lookup(value);
if (!name.empty())
SymbolName = name.data();
}
return SymbolName;
}
static void DumpCstringChar(const char c) {
char p[2];
p[0] = c;
p[1] = '\0';
outs().write_escaped(p);
}
static void DumpCstringSection(MachOObjectFile *O, const char *sect,
uint32_t sect_size, uint64_t sect_addr,
bool print_addresses) {
for (uint32_t i = 0; i < sect_size; i++) {
if (print_addresses) {
if (O->is64Bit())
outs() << format("%016" PRIx64, sect_addr + i) << " ";
else
outs() << format("%08" PRIx64, sect_addr + i) << " ";
}
for (; i < sect_size && sect[i] != '\0'; i++)
DumpCstringChar(sect[i]);
if (i < sect_size && sect[i] == '\0')
outs() << "\n";
}
}
static void DumpLiteral4(uint32_t l, float f) {
outs() << format("0x%08" PRIx32, l);
if ((l & 0x7f800000) != 0x7f800000)
outs() << format(" (%.16e)\n", f);
else {
if (l == 0x7f800000)
outs() << " (+Infinity)\n";
else if (l == 0xff800000)
outs() << " (-Infinity)\n";
else if ((l & 0x00400000) == 0x00400000)
outs() << " (non-signaling Not-a-Number)\n";
else
outs() << " (signaling Not-a-Number)\n";
}
}
static void DumpLiteral4Section(MachOObjectFile *O, const char *sect,
uint32_t sect_size, uint64_t sect_addr,
bool print_addresses) {
for (uint32_t i = 0; i < sect_size; i += sizeof(float)) {
if (print_addresses) {
if (O->is64Bit())
outs() << format("%016" PRIx64, sect_addr + i) << " ";
else
outs() << format("%08" PRIx64, sect_addr + i) << " ";
}
float f;
memcpy(&f, sect + i, sizeof(float));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(f);
uint32_t l;
memcpy(&l, sect + i, sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(l);
DumpLiteral4(l, f);
}
}
static void DumpLiteral8(MachOObjectFile *O, uint32_t l0, uint32_t l1,
double d) {
outs() << format("0x%08" PRIx32, l0) << " " << format("0x%08" PRIx32, l1);
uint32_t Hi, Lo;
if (O->isLittleEndian()) {
Hi = l1;
Lo = l0;
} else {
Hi = l0;
Lo = l1;
}
// Hi is the high word, so this is equivalent to if(isfinite(d))
if ((Hi & 0x7ff00000) != 0x7ff00000)
outs() << format(" (%.16e)\n", d);
else {
if (Hi == 0x7ff00000 && Lo == 0)
outs() << " (+Infinity)\n";
else if (Hi == 0xfff00000 && Lo == 0)
outs() << " (-Infinity)\n";
else if ((Hi & 0x00080000) == 0x00080000)
outs() << " (non-signaling Not-a-Number)\n";
else
outs() << " (signaling Not-a-Number)\n";
}
}
static void DumpLiteral8Section(MachOObjectFile *O, const char *sect,
uint32_t sect_size, uint64_t sect_addr,
bool print_addresses) {
for (uint32_t i = 0; i < sect_size; i += sizeof(double)) {
if (print_addresses) {
if (O->is64Bit())
outs() << format("%016" PRIx64, sect_addr + i) << " ";
else
outs() << format("%08" PRIx64, sect_addr + i) << " ";
}
double d;
memcpy(&d, sect + i, sizeof(double));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(d);
uint32_t l0, l1;
memcpy(&l0, sect + i, sizeof(uint32_t));
memcpy(&l1, sect + i + sizeof(uint32_t), sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost) {
sys::swapByteOrder(l0);
sys::swapByteOrder(l1);
}
DumpLiteral8(O, l0, l1, d);
}
}
static void DumpLiteral16(uint32_t l0, uint32_t l1, uint32_t l2, uint32_t l3) {
outs() << format("0x%08" PRIx32, l0) << " ";
outs() << format("0x%08" PRIx32, l1) << " ";
outs() << format("0x%08" PRIx32, l2) << " ";
outs() << format("0x%08" PRIx32, l3) << "\n";
}
static void DumpLiteral16Section(MachOObjectFile *O, const char *sect,
uint32_t sect_size, uint64_t sect_addr,
bool print_addresses) {
for (uint32_t i = 0; i < sect_size; i += 16) {
if (print_addresses) {
if (O->is64Bit())
outs() << format("%016" PRIx64, sect_addr + i) << " ";
else
outs() << format("%08" PRIx64, sect_addr + i) << " ";
}
uint32_t l0, l1, l2, l3;
memcpy(&l0, sect + i, sizeof(uint32_t));
memcpy(&l1, sect + i + sizeof(uint32_t), sizeof(uint32_t));
memcpy(&l2, sect + i + 2 * sizeof(uint32_t), sizeof(uint32_t));
memcpy(&l3, sect + i + 3 * sizeof(uint32_t), sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost) {
sys::swapByteOrder(l0);
sys::swapByteOrder(l1);
sys::swapByteOrder(l2);
sys::swapByteOrder(l3);
}
DumpLiteral16(l0, l1, l2, l3);
}
}
static void DumpLiteralPointerSection(MachOObjectFile *O,
const SectionRef &Section,
const char *sect, uint32_t sect_size,
uint64_t sect_addr,
bool print_addresses) {
// Collect the literal sections in this Mach-O file.
std::vector<SectionRef> LiteralSections;
for (const SectionRef &Section : O->sections()) {
DataRefImpl Ref = Section.getRawDataRefImpl();
uint32_t section_type;
if (O->is64Bit()) {
const MachO::section_64 Sec = O->getSection64(Ref);
section_type = Sec.flags & MachO::SECTION_TYPE;
} else {
const MachO::section Sec = O->getSection(Ref);
section_type = Sec.flags & MachO::SECTION_TYPE;
}
if (section_type == MachO::S_CSTRING_LITERALS ||
section_type == MachO::S_4BYTE_LITERALS ||
section_type == MachO::S_8BYTE_LITERALS ||
section_type == MachO::S_16BYTE_LITERALS)
LiteralSections.push_back(Section);
}
// Set the size of the literal pointer.
uint32_t lp_size = O->is64Bit() ? 8 : 4;
// Collect the external relocation symbols for the literal pointers.
std::vector<std::pair<uint64_t, SymbolRef>> Relocs;
for (const RelocationRef &Reloc : Section.relocations()) {
DataRefImpl Rel;
MachO::any_relocation_info RE;
bool isExtern = false;
Rel = Reloc.getRawDataRefImpl();
RE = O->getRelocation(Rel);
isExtern = O->getPlainRelocationExternal(RE);
if (isExtern) {
uint64_t RelocOffset = Reloc.getOffset();
symbol_iterator RelocSym = Reloc.getSymbol();
Relocs.push_back(std::make_pair(RelocOffset, *RelocSym));
}
}
array_pod_sort(Relocs.begin(), Relocs.end());
// Dump each literal pointer.
for (uint32_t i = 0; i < sect_size; i += lp_size) {
if (print_addresses) {
if (O->is64Bit())
outs() << format("%016" PRIx64, sect_addr + i) << " ";
else
outs() << format("%08" PRIx64, sect_addr + i) << " ";
}
uint64_t lp;
if (O->is64Bit()) {
memcpy(&lp, sect + i, sizeof(uint64_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(lp);
} else {
uint32_t li;
memcpy(&li, sect + i, sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(li);
lp = li;
}
// First look for an external relocation entry for this literal pointer.
auto Reloc = std::find_if(
Relocs.begin(), Relocs.end(),
[&](const std::pair<uint64_t, SymbolRef> &P) { return P.first == i; });
if (Reloc != Relocs.end()) {
symbol_iterator RelocSym = Reloc->second;
ErrorOr<StringRef> SymName = RelocSym->getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
outs() << "external relocation entry for symbol:" << *SymName << "\n";
continue;
}
// For local references see what the section the literal pointer points to.
auto Sect = std::find_if(LiteralSections.begin(), LiteralSections.end(),
[&](const SectionRef &R) {
return lp >= R.getAddress() &&
lp < R.getAddress() + R.getSize();
});
if (Sect == LiteralSections.end()) {
outs() << format("0x%" PRIx64, lp) << " (not in a literal section)\n";
continue;
}
uint64_t SectAddress = Sect->getAddress();
uint64_t SectSize = Sect->getSize();
StringRef SectName;
Sect->getName(SectName);
DataRefImpl Ref = Sect->getRawDataRefImpl();
StringRef SegmentName = O->getSectionFinalSegmentName(Ref);
outs() << SegmentName << ":" << SectName << ":";
uint32_t section_type;
if (O->is64Bit()) {
const MachO::section_64 Sec = O->getSection64(Ref);
section_type = Sec.flags & MachO::SECTION_TYPE;
} else {
const MachO::section Sec = O->getSection(Ref);
section_type = Sec.flags & MachO::SECTION_TYPE;
}
StringRef BytesStr;
Sect->getContents(BytesStr);
const char *Contents = reinterpret_cast<const char *>(BytesStr.data());
switch (section_type) {
case MachO::S_CSTRING_LITERALS:
for (uint64_t i = lp - SectAddress; i < SectSize && Contents[i] != '\0';
i++) {
DumpCstringChar(Contents[i]);
}
outs() << "\n";
break;
case MachO::S_4BYTE_LITERALS:
float f;
memcpy(&f, Contents + (lp - SectAddress), sizeof(float));
uint32_t l;
memcpy(&l, Contents + (lp - SectAddress), sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost) {
sys::swapByteOrder(f);
sys::swapByteOrder(l);
}
DumpLiteral4(l, f);
break;
case MachO::S_8BYTE_LITERALS: {
double d;
memcpy(&d, Contents + (lp - SectAddress), sizeof(double));
uint32_t l0, l1;
memcpy(&l0, Contents + (lp - SectAddress), sizeof(uint32_t));
memcpy(&l1, Contents + (lp - SectAddress) + sizeof(uint32_t),
sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost) {
sys::swapByteOrder(f);
sys::swapByteOrder(l0);
sys::swapByteOrder(l1);
}
DumpLiteral8(O, l0, l1, d);
break;
}
case MachO::S_16BYTE_LITERALS: {
uint32_t l0, l1, l2, l3;
memcpy(&l0, Contents + (lp - SectAddress), sizeof(uint32_t));
memcpy(&l1, Contents + (lp - SectAddress) + sizeof(uint32_t),
sizeof(uint32_t));
memcpy(&l2, Contents + (lp - SectAddress) + 2 * sizeof(uint32_t),
sizeof(uint32_t));
memcpy(&l3, Contents + (lp - SectAddress) + 3 * sizeof(uint32_t),
sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost) {
sys::swapByteOrder(l0);
sys::swapByteOrder(l1);
sys::swapByteOrder(l2);
sys::swapByteOrder(l3);
}
DumpLiteral16(l0, l1, l2, l3);
break;
}
}
}
}
static void DumpInitTermPointerSection(MachOObjectFile *O, const char *sect,
uint32_t sect_size, uint64_t sect_addr,
SymbolAddressMap *AddrMap,
bool verbose) {
uint32_t stride;
if (O->is64Bit())
stride = sizeof(uint64_t);
else
stride = sizeof(uint32_t);
for (uint32_t i = 0; i < sect_size; i += stride) {
const char *SymbolName = nullptr;
if (O->is64Bit()) {
outs() << format("0x%016" PRIx64, sect_addr + i * stride) << " ";
uint64_t pointer_value;
memcpy(&pointer_value, sect + i, stride);
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(pointer_value);
outs() << format("0x%016" PRIx64, pointer_value);
if (verbose)
SymbolName = GuessSymbolName(pointer_value, AddrMap);
} else {
outs() << format("0x%08" PRIx64, sect_addr + i * stride) << " ";
uint32_t pointer_value;
memcpy(&pointer_value, sect + i, stride);
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(pointer_value);
outs() << format("0x%08" PRIx32, pointer_value);
if (verbose)
SymbolName = GuessSymbolName(pointer_value, AddrMap);
}
if (SymbolName)
outs() << " " << SymbolName;
outs() << "\n";
}
}
static void DumpRawSectionContents(MachOObjectFile *O, const char *sect,
uint32_t size, uint64_t addr) {
uint32_t cputype = O->getHeader().cputype;
if (cputype == MachO::CPU_TYPE_I386 || cputype == MachO::CPU_TYPE_X86_64) {
uint32_t j;
for (uint32_t i = 0; i < size; i += j, addr += j) {
if (O->is64Bit())
outs() << format("%016" PRIx64, addr) << "\t";
else
outs() << format("%08" PRIx64, addr) << "\t";
for (j = 0; j < 16 && i + j < size; j++) {
uint8_t byte_word = *(sect + i + j);
outs() << format("%02" PRIx32, (uint32_t)byte_word) << " ";
}
outs() << "\n";
}
} else {
uint32_t j;
for (uint32_t i = 0; i < size; i += j, addr += j) {
if (O->is64Bit())
outs() << format("%016" PRIx64, addr) << "\t";
else
outs() << format("%08" PRIx64, sect) << "\t";
for (j = 0; j < 4 * sizeof(int32_t) && i + j < size;
j += sizeof(int32_t)) {
if (i + j + sizeof(int32_t) < size) {
uint32_t long_word;
memcpy(&long_word, sect + i + j, sizeof(int32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(long_word);
outs() << format("%08" PRIx32, long_word) << " ";
} else {
for (uint32_t k = 0; i + j + k < size; k++) {
uint8_t byte_word = *(sect + i + j);
outs() << format("%02" PRIx32, (uint32_t)byte_word) << " ";
}
}
}
outs() << "\n";
}
}
}
static void DisassembleMachO(StringRef Filename, MachOObjectFile *MachOOF,
StringRef DisSegName, StringRef DisSectName);
static void DumpProtocolSection(MachOObjectFile *O, const char *sect,
uint32_t size, uint32_t addr);
static void DumpSectionContents(StringRef Filename, MachOObjectFile *O,
bool verbose) {
SymbolAddressMap AddrMap;
if (verbose)
CreateSymbolAddressMap(O, &AddrMap);
for (unsigned i = 0; i < DumpSections.size(); ++i) {
StringRef DumpSection = DumpSections[i];
std::pair<StringRef, StringRef> DumpSegSectName;
DumpSegSectName = DumpSection.split(',');
StringRef DumpSegName, DumpSectName;
if (DumpSegSectName.second.size()) {
DumpSegName = DumpSegSectName.first;
DumpSectName = DumpSegSectName.second;
} else {
DumpSegName = "";
DumpSectName = DumpSegSectName.first;
}
for (const SectionRef &Section : O->sections()) {
StringRef SectName;
Section.getName(SectName);
DataRefImpl Ref = Section.getRawDataRefImpl();
StringRef SegName = O->getSectionFinalSegmentName(Ref);
if ((DumpSegName.empty() || SegName == DumpSegName) &&
(SectName == DumpSectName)) {
uint32_t section_flags;
if (O->is64Bit()) {
const MachO::section_64 Sec = O->getSection64(Ref);
section_flags = Sec.flags;
} else {
const MachO::section Sec = O->getSection(Ref);
section_flags = Sec.flags;
}
uint32_t section_type = section_flags & MachO::SECTION_TYPE;
StringRef BytesStr;
Section.getContents(BytesStr);
const char *sect = reinterpret_cast<const char *>(BytesStr.data());
uint32_t sect_size = BytesStr.size();
uint64_t sect_addr = Section.getAddress();
if (Raw) {
outs().write(BytesStr.data(), BytesStr.size());
continue;
}
outs() << "Contents of (" << SegName << "," << SectName
<< ") section\n";
if (verbose) {
if ((section_flags & MachO::S_ATTR_PURE_INSTRUCTIONS) ||
(section_flags & MachO::S_ATTR_SOME_INSTRUCTIONS)) {
DisassembleMachO(Filename, O, SegName, SectName);
continue;
}
if (SegName == "__TEXT" && SectName == "__info_plist") {
outs() << sect;
continue;
}
if (SegName == "__OBJC" && SectName == "__protocol") {
DumpProtocolSection(O, sect, sect_size, sect_addr);
continue;
}
switch (section_type) {
case MachO::S_REGULAR:
DumpRawSectionContents(O, sect, sect_size, sect_addr);
break;
case MachO::S_ZEROFILL:
outs() << "zerofill section and has no contents in the file\n";
break;
case MachO::S_CSTRING_LITERALS:
DumpCstringSection(O, sect, sect_size, sect_addr, !NoLeadingAddr);
break;
case MachO::S_4BYTE_LITERALS:
DumpLiteral4Section(O, sect, sect_size, sect_addr, !NoLeadingAddr);
break;
case MachO::S_8BYTE_LITERALS:
DumpLiteral8Section(O, sect, sect_size, sect_addr, !NoLeadingAddr);
break;
case MachO::S_16BYTE_LITERALS:
DumpLiteral16Section(O, sect, sect_size, sect_addr, !NoLeadingAddr);
break;
case MachO::S_LITERAL_POINTERS:
DumpLiteralPointerSection(O, Section, sect, sect_size, sect_addr,
!NoLeadingAddr);
break;
case MachO::S_MOD_INIT_FUNC_POINTERS:
case MachO::S_MOD_TERM_FUNC_POINTERS:
DumpInitTermPointerSection(O, sect, sect_size, sect_addr, &AddrMap,
verbose);
break;
default:
outs() << "Unknown section type ("
<< format("0x%08" PRIx32, section_type) << ")\n";
DumpRawSectionContents(O, sect, sect_size, sect_addr);
break;
}
} else {
if (section_type == MachO::S_ZEROFILL)
outs() << "zerofill section and has no contents in the file\n";
else
DumpRawSectionContents(O, sect, sect_size, sect_addr);
}
}
}
}
}
static void DumpInfoPlistSectionContents(StringRef Filename,
MachOObjectFile *O) {
for (const SectionRef &Section : O->sections()) {
StringRef SectName;
Section.getName(SectName);
DataRefImpl Ref = Section.getRawDataRefImpl();
StringRef SegName = O->getSectionFinalSegmentName(Ref);
if (SegName == "__TEXT" && SectName == "__info_plist") {
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
StringRef BytesStr;
Section.getContents(BytesStr);
const char *sect = reinterpret_cast<const char *>(BytesStr.data());
outs() << sect;
return;
}
}
}
// checkMachOAndArchFlags() checks to see if the ObjectFile is a Mach-O file
// and if it is and there is a list of architecture flags is specified then
// check to make sure this Mach-O file is one of those architectures or all
// architectures were specified. If not then an error is generated and this
// routine returns false. Else it returns true.
static bool checkMachOAndArchFlags(ObjectFile *O, StringRef Filename) {
if (isa<MachOObjectFile>(O) && !ArchAll && ArchFlags.size() != 0) {
MachOObjectFile *MachO = dyn_cast<MachOObjectFile>(O);
bool ArchFound = false;
MachO::mach_header H;
MachO::mach_header_64 H_64;
Triple T;
if (MachO->is64Bit()) {
H_64 = MachO->MachOObjectFile::getHeader64();
T = MachOObjectFile::getArch(H_64.cputype, H_64.cpusubtype);
} else {
H = MachO->MachOObjectFile::getHeader();
T = MachOObjectFile::getArch(H.cputype, H.cpusubtype);
}
unsigned i;
for (i = 0; i < ArchFlags.size(); ++i) {
if (ArchFlags[i] == T.getArchName())
ArchFound = true;
break;
}
if (!ArchFound) {
errs() << "llvm-objdump: file: " + Filename + " does not contain "
<< "architecture: " + ArchFlags[i] + "\n";
return false;
}
}
return true;
}
static void printObjcMetaData(MachOObjectFile *O, bool verbose);
// ProcessMachO() is passed a single opened Mach-O file, which may be an
// archive member and or in a slice of a universal file. It prints the
// the file name and header info and then processes it according to the
// command line options.
static void ProcessMachO(StringRef Filename, MachOObjectFile *MachOOF,
StringRef ArchiveMemberName = StringRef(),
StringRef ArchitectureName = StringRef()) {
// If we are doing some processing here on the Mach-O file print the header
// info. And don't print it otherwise like in the case of printing the
// UniversalHeaders or ArchiveHeaders.
if (Disassemble || PrivateHeaders || ExportsTrie || Rebase || Bind ||
LazyBind || WeakBind || IndirectSymbols || DataInCode || LinkOptHints ||
DylibsUsed || DylibId || ObjcMetaData ||
(DumpSections.size() != 0 && !Raw)) {
outs() << Filename;
if (!ArchiveMemberName.empty())
outs() << '(' << ArchiveMemberName << ')';
if (!ArchitectureName.empty())
outs() << " (architecture " << ArchitectureName << ")";
outs() << ":\n";
}
if (Disassemble)
DisassembleMachO(Filename, MachOOF, "__TEXT", "__text");
if (IndirectSymbols)
PrintIndirectSymbols(MachOOF, !NonVerbose);
if (DataInCode)
PrintDataInCodeTable(MachOOF, !NonVerbose);
if (LinkOptHints)
PrintLinkOptHints(MachOOF);
if (Relocations)
PrintRelocations(MachOOF);
if (SectionHeaders)
PrintSectionHeaders(MachOOF);
if (SectionContents)
PrintSectionContents(MachOOF);
if (DumpSections.size() != 0)
DumpSectionContents(Filename, MachOOF, !NonVerbose);
if (InfoPlist)
DumpInfoPlistSectionContents(Filename, MachOOF);
if (DylibsUsed)
PrintDylibs(MachOOF, false);
if (DylibId)
PrintDylibs(MachOOF, true);
if (SymbolTable)
PrintSymbolTable(MachOOF);
if (UnwindInfo)
printMachOUnwindInfo(MachOOF);
if (PrivateHeaders)
printMachOFileHeader(MachOOF);
if (ObjcMetaData)
printObjcMetaData(MachOOF, !NonVerbose);
if (ExportsTrie)
printExportsTrie(MachOOF);
if (Rebase)
printRebaseTable(MachOOF);
if (Bind)
printBindTable(MachOOF);
if (LazyBind)
printLazyBindTable(MachOOF);
if (WeakBind)
printWeakBindTable(MachOOF);
}
// printUnknownCPUType() helps print_fat_headers for unknown CPU's.
static void printUnknownCPUType(uint32_t cputype, uint32_t cpusubtype) {
outs() << " cputype (" << cputype << ")\n";
outs() << " cpusubtype (" << cpusubtype << ")\n";
}
// printCPUType() helps print_fat_headers by printing the cputype and
// pusubtype (symbolically for the one's it knows about).
static void printCPUType(uint32_t cputype, uint32_t cpusubtype) {
switch (cputype) {
case MachO::CPU_TYPE_I386:
switch (cpusubtype) {
case MachO::CPU_SUBTYPE_I386_ALL:
outs() << " cputype CPU_TYPE_I386\n";
outs() << " cpusubtype CPU_SUBTYPE_I386_ALL\n";
break;
default:
printUnknownCPUType(cputype, cpusubtype);
break;
}
break;
case MachO::CPU_TYPE_X86_64:
switch (cpusubtype) {
case MachO::CPU_SUBTYPE_X86_64_ALL:
outs() << " cputype CPU_TYPE_X86_64\n";
outs() << " cpusubtype CPU_SUBTYPE_X86_64_ALL\n";
break;
case MachO::CPU_SUBTYPE_X86_64_H:
outs() << " cputype CPU_TYPE_X86_64\n";
outs() << " cpusubtype CPU_SUBTYPE_X86_64_H\n";
break;
default:
printUnknownCPUType(cputype, cpusubtype);
break;
}
break;
case MachO::CPU_TYPE_ARM:
switch (cpusubtype) {
case MachO::CPU_SUBTYPE_ARM_ALL:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_ALL\n";
break;
case MachO::CPU_SUBTYPE_ARM_V4T:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V4T\n";
break;
case MachO::CPU_SUBTYPE_ARM_V5TEJ:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V5TEJ\n";
break;
case MachO::CPU_SUBTYPE_ARM_XSCALE:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_XSCALE\n";
break;
case MachO::CPU_SUBTYPE_ARM_V6:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V6\n";
break;
case MachO::CPU_SUBTYPE_ARM_V6M:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V6M\n";
break;
case MachO::CPU_SUBTYPE_ARM_V7:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V7\n";
break;
case MachO::CPU_SUBTYPE_ARM_V7EM:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V7EM\n";
break;
case MachO::CPU_SUBTYPE_ARM_V7K:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V7K\n";
break;
case MachO::CPU_SUBTYPE_ARM_V7M:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V7M\n";
break;
case MachO::CPU_SUBTYPE_ARM_V7S:
outs() << " cputype CPU_TYPE_ARM\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM_V7S\n";
break;
default:
printUnknownCPUType(cputype, cpusubtype);
break;
}
break;
case MachO::CPU_TYPE_ARM64:
switch (cpusubtype & ~MachO::CPU_SUBTYPE_MASK) {
case MachO::CPU_SUBTYPE_ARM64_ALL:
outs() << " cputype CPU_TYPE_ARM64\n";
outs() << " cpusubtype CPU_SUBTYPE_ARM64_ALL\n";
break;
default:
printUnknownCPUType(cputype, cpusubtype);
break;
}
break;
default:
printUnknownCPUType(cputype, cpusubtype);
break;
}
}
static void printMachOUniversalHeaders(const object::MachOUniversalBinary *UB,
bool verbose) {
outs() << "Fat headers\n";
if (verbose)
outs() << "fat_magic FAT_MAGIC\n";
else
outs() << "fat_magic " << format("0x%" PRIx32, MachO::FAT_MAGIC) << "\n";
uint32_t nfat_arch = UB->getNumberOfObjects();
StringRef Buf = UB->getData();
uint64_t size = Buf.size();
uint64_t big_size = sizeof(struct MachO::fat_header) +
nfat_arch * sizeof(struct MachO::fat_arch);
outs() << "nfat_arch " << UB->getNumberOfObjects();
if (nfat_arch == 0)
outs() << " (malformed, contains zero architecture types)\n";
else if (big_size > size)
outs() << " (malformed, architectures past end of file)\n";
else
outs() << "\n";
for (uint32_t i = 0; i < nfat_arch; ++i) {
MachOUniversalBinary::ObjectForArch OFA(UB, i);
uint32_t cputype = OFA.getCPUType();
uint32_t cpusubtype = OFA.getCPUSubType();
outs() << "architecture ";
for (uint32_t j = 0; i != 0 && j <= i - 1; j++) {
MachOUniversalBinary::ObjectForArch other_OFA(UB, j);
uint32_t other_cputype = other_OFA.getCPUType();
uint32_t other_cpusubtype = other_OFA.getCPUSubType();
if (cputype != 0 && cpusubtype != 0 && cputype == other_cputype &&
(cpusubtype & ~MachO::CPU_SUBTYPE_MASK) ==
(other_cpusubtype & ~MachO::CPU_SUBTYPE_MASK)) {
outs() << "(illegal duplicate architecture) ";
break;
}
}
if (verbose) {
outs() << OFA.getArchTypeName() << "\n";
printCPUType(cputype, cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
} else {
outs() << i << "\n";
outs() << " cputype " << cputype << "\n";
outs() << " cpusubtype " << (cpusubtype & ~MachO::CPU_SUBTYPE_MASK)
<< "\n";
}
if (verbose &&
(cpusubtype & MachO::CPU_SUBTYPE_MASK) == MachO::CPU_SUBTYPE_LIB64)
outs() << " capabilities CPU_SUBTYPE_LIB64\n";
else
outs() << " capabilities "
<< format("0x%" PRIx32,
(cpusubtype & MachO::CPU_SUBTYPE_MASK) >> 24) << "\n";
outs() << " offset " << OFA.getOffset();
if (OFA.getOffset() > size)
outs() << " (past end of file)";
if (OFA.getOffset() % (1 << OFA.getAlign()) != 0)
outs() << " (not aligned on it's alignment (2^" << OFA.getAlign() << ")";
outs() << "\n";
outs() << " size " << OFA.getSize();
big_size = OFA.getOffset() + OFA.getSize();
if (big_size > size)
outs() << " (past end of file)";
outs() << "\n";
outs() << " align 2^" << OFA.getAlign() << " (" << (1 << OFA.getAlign())
<< ")\n";
}
}
static void printArchiveChild(Archive::Child &C, bool verbose,
bool print_offset) {
if (print_offset)
outs() << C.getChildOffset() << "\t";
sys::fs::perms Mode = C.getAccessMode();
if (verbose) {
// FIXME: this first dash, "-", is for (Mode & S_IFMT) == S_IFREG.
// But there is nothing in sys::fs::perms for S_IFMT or S_IFREG.
outs() << "-";
if (Mode & sys::fs::owner_read)
outs() << "r";
else
outs() << "-";
if (Mode & sys::fs::owner_write)
outs() << "w";
else
outs() << "-";
if (Mode & sys::fs::owner_exe)
outs() << "x";
else
outs() << "-";
if (Mode & sys::fs::group_read)
outs() << "r";
else
outs() << "-";
if (Mode & sys::fs::group_write)
outs() << "w";
else
outs() << "-";
if (Mode & sys::fs::group_exe)
outs() << "x";
else
outs() << "-";
if (Mode & sys::fs::others_read)
outs() << "r";
else
outs() << "-";
if (Mode & sys::fs::others_write)
outs() << "w";
else
outs() << "-";
if (Mode & sys::fs::others_exe)
outs() << "x";
else
outs() << "-";
} else {
outs() << format("0%o ", Mode);
}
unsigned UID = C.getUID();
outs() << format("%3d/", UID);
unsigned GID = C.getGID();
outs() << format("%-3d ", GID);
uint64_t Size = C.getRawSize();
outs() << format("%5" PRId64, Size) << " ";
StringRef RawLastModified = C.getRawLastModified();
if (verbose) {
unsigned Seconds;
if (RawLastModified.getAsInteger(10, Seconds))
outs() << "(date: \"%s\" contains non-decimal chars) " << RawLastModified;
else {
// Since cime(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));
}
} else {
outs() << RawLastModified << " ";
}
if (verbose) {
ErrorOr<StringRef> NameOrErr = C.getName();
if (NameOrErr.getError()) {
StringRef RawName = C.getRawName();
outs() << RawName << "\n";
} else {
StringRef Name = NameOrErr.get();
outs() << Name << "\n";
}
} else {
StringRef RawName = C.getRawName();
outs() << RawName << "\n";
}
}
static void printArchiveHeaders(Archive *A, bool verbose, bool print_offset) {
if (A->hasSymbolTable()) {
Archive::child_iterator S = A->getSymbolTableChild();
Archive::Child C = *S;
printArchiveChild(C, verbose, print_offset);
}
for (Archive::child_iterator I = A->child_begin(), E = A->child_end(); I != E;
++I) {
Archive::Child C = *I;
printArchiveChild(C, verbose, print_offset);
}
}
// ParseInputMachO() parses the named Mach-O file in Filename and handles the
// -arch flags selecting just those slices as specified by them and also parses
// archive files. Then for each individual Mach-O file ProcessMachO() is
// called to process the file based on the command line options.
void llvm::ParseInputMachO(StringRef Filename) {
// Check for -arch all and verifiy the -arch flags are valid.
for (unsigned i = 0; i < ArchFlags.size(); ++i) {
if (ArchFlags[i] == "all") {
ArchAll = true;
} else {
if (!MachOObjectFile::isValidArch(ArchFlags[i])) {
errs() << "llvm-objdump: Unknown architecture named '" + ArchFlags[i] +
"'for the -arch option\n";
return;
}
}
}
// Attempt to open the binary.
ErrorOr<OwningBinary<Binary>> BinaryOrErr = createBinary(Filename);
if (std::error_code EC = BinaryOrErr.getError()) {
errs() << "llvm-objdump: '" << Filename << "': " << EC.message() << ".\n";
return;
}
Binary &Bin = *BinaryOrErr.get().getBinary();
if (Archive *A = dyn_cast<Archive>(&Bin)) {
outs() << "Archive : " << Filename << "\n";
if (ArchiveHeaders)
printArchiveHeaders(A, !NonVerbose, ArchiveMemberOffsets);
for (Archive::child_iterator I = A->child_begin(), E = A->child_end();
I != E; ++I) {
ErrorOr<std::unique_ptr<Binary>> ChildOrErr = I->getAsBinary();
if (ChildOrErr.getError())
continue;
if (MachOObjectFile *O = dyn_cast<MachOObjectFile>(&*ChildOrErr.get())) {
if (!checkMachOAndArchFlags(O, Filename))
return;
ProcessMachO(Filename, O, O->getFileName());
}
}
return;
}
if (UniversalHeaders) {
if (MachOUniversalBinary *UB = dyn_cast<MachOUniversalBinary>(&Bin))
printMachOUniversalHeaders(UB, !NonVerbose);
}
if (MachOUniversalBinary *UB = dyn_cast<MachOUniversalBinary>(&Bin)) {
// If we have a list of architecture flags specified dump only those.
if (!ArchAll && ArchFlags.size() != 0) {
// Look for a slice in the universal binary that matches each ArchFlag.
bool ArchFound;
for (unsigned i = 0; i < ArchFlags.size(); ++i) {
ArchFound = false;
for (MachOUniversalBinary::object_iterator I = UB->begin_objects(),
E = UB->end_objects();
I != E; ++I) {
if (ArchFlags[i] == I->getArchTypeName()) {
ArchFound = true;
ErrorOr<std::unique_ptr<ObjectFile>> ObjOrErr =
I->getAsObjectFile();
std::string ArchitectureName = "";
if (ArchFlags.size() > 1)
ArchitectureName = I->getArchTypeName();
if (ObjOrErr) {
ObjectFile &O = *ObjOrErr.get();
if (MachOObjectFile *MachOOF = dyn_cast<MachOObjectFile>(&O))
ProcessMachO(Filename, MachOOF, "", ArchitectureName);
} else if (ErrorOr<std::unique_ptr<Archive>> AOrErr =
I->getAsArchive()) {
std::unique_ptr<Archive> &A = *AOrErr;
outs() << "Archive : " << Filename;
if (!ArchitectureName.empty())
outs() << " (architecture " << ArchitectureName << ")";
outs() << "\n";
if (ArchiveHeaders)
printArchiveHeaders(A.get(), !NonVerbose, ArchiveMemberOffsets);
for (Archive::child_iterator AI = A->child_begin(),
AE = A->child_end();
AI != AE; ++AI) {
ErrorOr<std::unique_ptr<Binary>> ChildOrErr = AI->getAsBinary();
if (ChildOrErr.getError())
continue;
if (MachOObjectFile *O =
dyn_cast<MachOObjectFile>(&*ChildOrErr.get()))
ProcessMachO(Filename, O, O->getFileName(), ArchitectureName);
}
}
}
}
if (!ArchFound) {
errs() << "llvm-objdump: file: " + Filename + " does not contain "
<< "architecture: " + ArchFlags[i] + "\n";
return;
}
}
return;
}
// No architecture flags were specified so if this contains a slice that
// matches the host architecture dump only that.
if (!ArchAll) {
for (MachOUniversalBinary::object_iterator I = UB->begin_objects(),
E = UB->end_objects();
I != E; ++I) {
if (MachOObjectFile::getHostArch().getArchName() ==
I->getArchTypeName()) {
ErrorOr<std::unique_ptr<ObjectFile>> ObjOrErr = I->getAsObjectFile();
std::string ArchiveName;
ArchiveName.clear();
if (ObjOrErr) {
ObjectFile &O = *ObjOrErr.get();
if (MachOObjectFile *MachOOF = dyn_cast<MachOObjectFile>(&O))
ProcessMachO(Filename, MachOOF);
} else if (ErrorOr<std::unique_ptr<Archive>> AOrErr =
I->getAsArchive()) {
std::unique_ptr<Archive> &A = *AOrErr;
outs() << "Archive : " << Filename << "\n";
if (ArchiveHeaders)
printArchiveHeaders(A.get(), !NonVerbose, ArchiveMemberOffsets);
for (Archive::child_iterator AI = A->child_begin(),
AE = A->child_end();
AI != AE; ++AI) {
ErrorOr<std::unique_ptr<Binary>> ChildOrErr = AI->getAsBinary();
if (ChildOrErr.getError())
continue;
if (MachOObjectFile *O =
dyn_cast<MachOObjectFile>(&*ChildOrErr.get()))
ProcessMachO(Filename, O, O->getFileName());
}
}
return;
}
}
}
// Either all architectures have been specified or none have been specified
// and this does not contain the host architecture so dump all the slices.
bool moreThanOneArch = UB->getNumberOfObjects() > 1;
for (MachOUniversalBinary::object_iterator I = UB->begin_objects(),
E = UB->end_objects();
I != E; ++I) {
ErrorOr<std::unique_ptr<ObjectFile>> ObjOrErr = I->getAsObjectFile();
std::string ArchitectureName = "";
if (moreThanOneArch)
ArchitectureName = I->getArchTypeName();
if (ObjOrErr) {
ObjectFile &Obj = *ObjOrErr.get();
if (MachOObjectFile *MachOOF = dyn_cast<MachOObjectFile>(&Obj))
ProcessMachO(Filename, MachOOF, "", ArchitectureName);
} else if (ErrorOr<std::unique_ptr<Archive>> AOrErr = I->getAsArchive()) {
std::unique_ptr<Archive> &A = *AOrErr;
outs() << "Archive : " << Filename;
if (!ArchitectureName.empty())
outs() << " (architecture " << ArchitectureName << ")";
outs() << "\n";
if (ArchiveHeaders)
printArchiveHeaders(A.get(), !NonVerbose, ArchiveMemberOffsets);
for (Archive::child_iterator AI = A->child_begin(), AE = A->child_end();
AI != AE; ++AI) {
ErrorOr<std::unique_ptr<Binary>> ChildOrErr = AI->getAsBinary();
if (ChildOrErr.getError())
continue;
if (MachOObjectFile *O =
dyn_cast<MachOObjectFile>(&*ChildOrErr.get())) {
if (MachOObjectFile *MachOOF = dyn_cast<MachOObjectFile>(O))
ProcessMachO(Filename, MachOOF, MachOOF->getFileName(),
ArchitectureName);
}
}
}
}
return;
}
if (ObjectFile *O = dyn_cast<ObjectFile>(&Bin)) {
if (!checkMachOAndArchFlags(O, Filename))
return;
if (MachOObjectFile *MachOOF = dyn_cast<MachOObjectFile>(&*O)) {
ProcessMachO(Filename, MachOOF);
} else
errs() << "llvm-objdump: '" << Filename << "': "
<< "Object is not a Mach-O file type.\n";
} else
errs() << "llvm-objdump: '" << Filename << "': "
<< "Unrecognized file type.\n";
}
typedef std::pair<uint64_t, const char *> BindInfoEntry;
typedef std::vector<BindInfoEntry> BindTable;
typedef BindTable::iterator bind_table_iterator;
// The block of info used by the Symbolizer call backs.
struct DisassembleInfo {
bool verbose;
MachOObjectFile *O;
SectionRef S;
SymbolAddressMap *AddrMap;
std::vector<SectionRef> *Sections;
const char *class_name;
const char *selector_name;
char *method;
char *demangled_name;
uint64_t adrp_addr;
uint32_t adrp_inst;
BindTable *bindtable;
};
// SymbolizerGetOpInfo() is the operand information call back function.
// This is called to get the symbolic information for operand(s) of an
// instruction when it is being done. This routine does this from
// the relocation information, symbol table, etc. That block of information
// is a pointer to the struct DisassembleInfo that was passed when the
// disassembler context was created and passed to back to here when
// called back by the disassembler for instruction operands that could have
// relocation information. The address of the instruction containing operand is
// at the Pc parameter. The immediate value the operand has is passed in
// op_info->Value and is at Offset past the start of the instruction and has a
// byte Size of 1, 2 or 4. The symbolc information is returned in TagBuf is the
// LLVMOpInfo1 struct defined in the header "llvm-c/Disassembler.h" as symbol
// names and addends of the symbolic expression to add for the operand. The
// value of TagType is currently 1 (for the LLVMOpInfo1 struct). If symbolic
// information is returned then this function returns 1 else it returns 0.
static int SymbolizerGetOpInfo(void *DisInfo, uint64_t Pc, uint64_t Offset,
uint64_t Size, int TagType, void *TagBuf) {
struct DisassembleInfo *info = (struct DisassembleInfo *)DisInfo;
struct LLVMOpInfo1 *op_info = (struct LLVMOpInfo1 *)TagBuf;
uint64_t value = op_info->Value;
// Make sure all fields returned are zero if we don't set them.
memset((void *)op_info, '\0', sizeof(struct LLVMOpInfo1));
op_info->Value = value;
// If the TagType is not the value 1 which it code knows about or if no
// verbose symbolic information is wanted then just return 0, indicating no
// information is being returned.
if (TagType != 1 || !info->verbose)
return 0;
unsigned int Arch = info->O->getArch();
if (Arch == Triple::x86) {
if (Size != 1 && Size != 2 && Size != 4 && Size != 0)
return 0;
// First search the section's relocation entries (if any) for an entry
// for this section offset.
uint32_t sect_addr = info->S.getAddress();
uint32_t sect_offset = (Pc + Offset) - sect_addr;
bool reloc_found = false;
DataRefImpl Rel;
MachO::any_relocation_info RE;
bool isExtern = false;
SymbolRef Symbol;
bool r_scattered = false;
uint32_t r_value, pair_r_value, r_type;
for (const RelocationRef &Reloc : info->S.relocations()) {
uint64_t RelocOffset = Reloc.getOffset();
if (RelocOffset == sect_offset) {
Rel = Reloc.getRawDataRefImpl();
RE = info->O->getRelocation(Rel);
r_type = info->O->getAnyRelocationType(RE);
r_scattered = info->O->isRelocationScattered(RE);
if (r_scattered) {
r_value = info->O->getScatteredRelocationValue(RE);
if (r_type == MachO::GENERIC_RELOC_SECTDIFF ||
r_type == MachO::GENERIC_RELOC_LOCAL_SECTDIFF) {
DataRefImpl RelNext = Rel;
info->O->moveRelocationNext(RelNext);
MachO::any_relocation_info RENext;
RENext = info->O->getRelocation(RelNext);
if (info->O->isRelocationScattered(RENext))
pair_r_value = info->O->getScatteredRelocationValue(RENext);
else
return 0;
}
} else {
isExtern = info->O->getPlainRelocationExternal(RE);
if (isExtern) {
symbol_iterator RelocSym = Reloc.getSymbol();
Symbol = *RelocSym;
}
}
reloc_found = true;
break;
}
}
if (reloc_found && isExtern) {
ErrorOr<StringRef> SymName = Symbol.getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
const char *name = SymName->data();
op_info->AddSymbol.Present = 1;
op_info->AddSymbol.Name = name;
// For i386 extern relocation entries the value in the instruction is
// the offset from the symbol, and value is already set in op_info->Value.
return 1;
}
if (reloc_found && (r_type == MachO::GENERIC_RELOC_SECTDIFF ||
r_type == MachO::GENERIC_RELOC_LOCAL_SECTDIFF)) {
const char *add = GuessSymbolName(r_value, info->AddrMap);
const char *sub = GuessSymbolName(pair_r_value, info->AddrMap);
uint32_t offset = value - (r_value - pair_r_value);
op_info->AddSymbol.Present = 1;
if (add != nullptr)
op_info->AddSymbol.Name = add;
else
op_info->AddSymbol.Value = r_value;
op_info->SubtractSymbol.Present = 1;
if (sub != nullptr)
op_info->SubtractSymbol.Name = sub;
else
op_info->SubtractSymbol.Value = pair_r_value;
op_info->Value = offset;
return 1;
}
// TODO:
// Second search the external relocation entries of a fully linked image
// (if any) for an entry that matches this segment offset.
// uint32_t seg_offset = (Pc + Offset);
return 0;
}
if (Arch == Triple::x86_64) {
if (Size != 1 && Size != 2 && Size != 4 && Size != 0)
return 0;
// First search the section's relocation entries (if any) for an entry
// for this section offset.
uint64_t sect_addr = info->S.getAddress();
uint64_t sect_offset = (Pc + Offset) - sect_addr;
bool reloc_found = false;
DataRefImpl Rel;
MachO::any_relocation_info RE;
bool isExtern = false;
SymbolRef Symbol;
for (const RelocationRef &Reloc : info->S.relocations()) {
uint64_t RelocOffset = Reloc.getOffset();
if (RelocOffset == sect_offset) {
Rel = Reloc.getRawDataRefImpl();
RE = info->O->getRelocation(Rel);
// NOTE: Scattered relocations don't exist on x86_64.
isExtern = info->O->getPlainRelocationExternal(RE);
if (isExtern) {
symbol_iterator RelocSym = Reloc.getSymbol();
Symbol = *RelocSym;
}
reloc_found = true;
break;
}
}
if (reloc_found && isExtern) {
// The Value passed in will be adjusted by the Pc if the instruction
// adds the Pc. But for x86_64 external relocation entries the Value
// is the offset from the external symbol.
if (info->O->getAnyRelocationPCRel(RE))
op_info->Value -= Pc + Offset + Size;
ErrorOr<StringRef> SymName = Symbol.getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
const char *name = SymName->data();
unsigned Type = info->O->getAnyRelocationType(RE);
if (Type == MachO::X86_64_RELOC_SUBTRACTOR) {
DataRefImpl RelNext = Rel;
info->O->moveRelocationNext(RelNext);
MachO::any_relocation_info RENext = info->O->getRelocation(RelNext);
unsigned TypeNext = info->O->getAnyRelocationType(RENext);
bool isExternNext = info->O->getPlainRelocationExternal(RENext);
unsigned SymbolNum = info->O->getPlainRelocationSymbolNum(RENext);
if (TypeNext == MachO::X86_64_RELOC_UNSIGNED && isExternNext) {
op_info->SubtractSymbol.Present = 1;
op_info->SubtractSymbol.Name = name;
symbol_iterator RelocSymNext = info->O->getSymbolByIndex(SymbolNum);
Symbol = *RelocSymNext;
ErrorOr<StringRef> SymNameNext = Symbol.getName();
if (std::error_code EC = SymNameNext.getError())
report_fatal_error(EC.message());
name = SymNameNext->data();
}
}
// TODO: add the VariantKinds to op_info->VariantKind for relocation types
// like: X86_64_RELOC_TLV, X86_64_RELOC_GOT_LOAD and X86_64_RELOC_GOT.
op_info->AddSymbol.Present = 1;
op_info->AddSymbol.Name = name;
return 1;
}
// TODO:
// Second search the external relocation entries of a fully linked image
// (if any) for an entry that matches this segment offset.
// uint64_t seg_offset = (Pc + Offset);
return 0;
}
if (Arch == Triple::arm) {
if (Offset != 0 || (Size != 4 && Size != 2))
return 0;
// First search the section's relocation entries (if any) for an entry
// for this section offset.
uint32_t sect_addr = info->S.getAddress();
uint32_t sect_offset = (Pc + Offset) - sect_addr;
DataRefImpl Rel;
MachO::any_relocation_info RE;
bool isExtern = false;
SymbolRef Symbol;
bool r_scattered = false;
uint32_t r_value, pair_r_value, r_type, r_length, other_half;
auto Reloc =
std::find_if(info->S.relocations().begin(), info->S.relocations().end(),
[&](const RelocationRef &Reloc) {
uint64_t RelocOffset = Reloc.getOffset();
return RelocOffset == sect_offset;
});
if (Reloc == info->S.relocations().end())
return 0;
Rel = Reloc->getRawDataRefImpl();
RE = info->O->getRelocation(Rel);
r_length = info->O->getAnyRelocationLength(RE);
r_scattered = info->O->isRelocationScattered(RE);
if (r_scattered) {
r_value = info->O->getScatteredRelocationValue(RE);
r_type = info->O->getScatteredRelocationType(RE);
} else {
r_type = info->O->getAnyRelocationType(RE);
isExtern = info->O->getPlainRelocationExternal(RE);
if (isExtern) {
symbol_iterator RelocSym = Reloc->getSymbol();
Symbol = *RelocSym;
}
}
if (r_type == MachO::ARM_RELOC_HALF ||
r_type == MachO::ARM_RELOC_SECTDIFF ||
r_type == MachO::ARM_RELOC_LOCAL_SECTDIFF ||
r_type == MachO::ARM_RELOC_HALF_SECTDIFF) {
DataRefImpl RelNext = Rel;
info->O->moveRelocationNext(RelNext);
MachO::any_relocation_info RENext;
RENext = info->O->getRelocation(RelNext);
other_half = info->O->getAnyRelocationAddress(RENext) & 0xffff;
if (info->O->isRelocationScattered(RENext))
pair_r_value = info->O->getScatteredRelocationValue(RENext);
}
if (isExtern) {
ErrorOr<StringRef> SymName = Symbol.getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
const char *name = SymName->data();
op_info->AddSymbol.Present = 1;
op_info->AddSymbol.Name = name;
switch (r_type) {
case MachO::ARM_RELOC_HALF:
if ((r_length & 0x1) == 1) {
op_info->Value = value << 16 | other_half;
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM_HI16;
} else {
op_info->Value = other_half << 16 | value;
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM_LO16;
}
break;
default:
break;
}
return 1;
}
// If we have a branch that is not an external relocation entry then
// return 0 so the code in tryAddingSymbolicOperand() can use the
// SymbolLookUp call back with the branch target address to look up the
// symbol and possiblity add an annotation for a symbol stub.
if (isExtern == 0 && (r_type == MachO::ARM_RELOC_BR24 ||
r_type == MachO::ARM_THUMB_RELOC_BR22))
return 0;
uint32_t offset = 0;
if (r_type == MachO::ARM_RELOC_HALF ||
r_type == MachO::ARM_RELOC_HALF_SECTDIFF) {
if ((r_length & 0x1) == 1)
value = value << 16 | other_half;
else
value = other_half << 16 | value;
}
if (r_scattered && (r_type != MachO::ARM_RELOC_HALF &&
r_type != MachO::ARM_RELOC_HALF_SECTDIFF)) {
offset = value - r_value;
value = r_value;
}
if (r_type == MachO::ARM_RELOC_HALF_SECTDIFF) {
if ((r_length & 0x1) == 1)
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM_HI16;
else
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM_LO16;
const char *add = GuessSymbolName(r_value, info->AddrMap);
const char *sub = GuessSymbolName(pair_r_value, info->AddrMap);
int32_t offset = value - (r_value - pair_r_value);
op_info->AddSymbol.Present = 1;
if (add != nullptr)
op_info->AddSymbol.Name = add;
else
op_info->AddSymbol.Value = r_value;
op_info->SubtractSymbol.Present = 1;
if (sub != nullptr)
op_info->SubtractSymbol.Name = sub;
else
op_info->SubtractSymbol.Value = pair_r_value;
op_info->Value = offset;
return 1;
}
op_info->AddSymbol.Present = 1;
op_info->Value = offset;
if (r_type == MachO::ARM_RELOC_HALF) {
if ((r_length & 0x1) == 1)
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM_HI16;
else
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM_LO16;
}
const char *add = GuessSymbolName(value, info->AddrMap);
if (add != nullptr) {
op_info->AddSymbol.Name = add;
return 1;
}
op_info->AddSymbol.Value = value;
return 1;
}
if (Arch == Triple::aarch64) {
if (Offset != 0 || Size != 4)
return 0;
// First search the section's relocation entries (if any) for an entry
// for this section offset.
uint64_t sect_addr = info->S.getAddress();
uint64_t sect_offset = (Pc + Offset) - sect_addr;
auto Reloc =
std::find_if(info->S.relocations().begin(), info->S.relocations().end(),
[&](const RelocationRef &Reloc) {
uint64_t RelocOffset = Reloc.getOffset();
return RelocOffset == sect_offset;
});
if (Reloc == info->S.relocations().end())
return 0;
DataRefImpl Rel = Reloc->getRawDataRefImpl();
MachO::any_relocation_info RE = info->O->getRelocation(Rel);
uint32_t r_type = info->O->getAnyRelocationType(RE);
if (r_type == MachO::ARM64_RELOC_ADDEND) {
DataRefImpl RelNext = Rel;
info->O->moveRelocationNext(RelNext);
MachO::any_relocation_info RENext = info->O->getRelocation(RelNext);
if (value == 0) {
value = info->O->getPlainRelocationSymbolNum(RENext);
op_info->Value = value;
}
}
// NOTE: Scattered relocations don't exist on arm64.
if (!info->O->getPlainRelocationExternal(RE))
return 0;
ErrorOr<StringRef> SymName = Reloc->getSymbol()->getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
const char *name = SymName->data();
op_info->AddSymbol.Present = 1;
op_info->AddSymbol.Name = name;
switch (r_type) {
case MachO::ARM64_RELOC_PAGE21:
/* @page */
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM64_PAGE;
break;
case MachO::ARM64_RELOC_PAGEOFF12:
/* @pageoff */
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM64_PAGEOFF;
break;
case MachO::ARM64_RELOC_GOT_LOAD_PAGE21:
/* @gotpage */
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM64_GOTPAGE;
break;
case MachO::ARM64_RELOC_GOT_LOAD_PAGEOFF12:
/* @gotpageoff */
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM64_GOTPAGEOFF;
break;
case MachO::ARM64_RELOC_TLVP_LOAD_PAGE21:
/* @tvlppage is not implemented in llvm-mc */
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM64_TLVP;
break;
case MachO::ARM64_RELOC_TLVP_LOAD_PAGEOFF12:
/* @tvlppageoff is not implemented in llvm-mc */
op_info->VariantKind = LLVMDisassembler_VariantKind_ARM64_TLVOFF;
break;
default:
case MachO::ARM64_RELOC_BRANCH26:
op_info->VariantKind = LLVMDisassembler_VariantKind_None;
break;
}
return 1;
}
return 0;
}
// GuessCstringPointer is passed the address of what might be a pointer to a
// literal string in a cstring section. If that address is in a cstring section
// it returns a pointer to that string. Else it returns nullptr.
static const char *GuessCstringPointer(uint64_t ReferenceValue,
struct DisassembleInfo *info) {
for (const auto &Load : info->O->load_commands()) {
if (Load.C.cmd == MachO::LC_SEGMENT_64) {
MachO::segment_command_64 Seg = info->O->getSegment64LoadCommand(Load);
for (unsigned J = 0; J < Seg.nsects; ++J) {
MachO::section_64 Sec = info->O->getSection64(Load, J);
uint32_t section_type = Sec.flags & MachO::SECTION_TYPE;
if (section_type == MachO::S_CSTRING_LITERALS &&
ReferenceValue >= Sec.addr &&
ReferenceValue < Sec.addr + Sec.size) {
uint64_t sect_offset = ReferenceValue - Sec.addr;
uint64_t object_offset = Sec.offset + sect_offset;
StringRef MachOContents = info->O->getData();
uint64_t object_size = MachOContents.size();
const char *object_addr = (const char *)MachOContents.data();
if (object_offset < object_size) {
const char *name = object_addr + object_offset;
return name;
} else {
return nullptr;
}
}
}
} else if (Load.C.cmd == MachO::LC_SEGMENT) {
MachO::segment_command Seg = info->O->getSegmentLoadCommand(Load);
for (unsigned J = 0; J < Seg.nsects; ++J) {
MachO::section Sec = info->O->getSection(Load, J);
uint32_t section_type = Sec.flags & MachO::SECTION_TYPE;
if (section_type == MachO::S_CSTRING_LITERALS &&
ReferenceValue >= Sec.addr &&
ReferenceValue < Sec.addr + Sec.size) {
uint64_t sect_offset = ReferenceValue - Sec.addr;
uint64_t object_offset = Sec.offset + sect_offset;
StringRef MachOContents = info->O->getData();
uint64_t object_size = MachOContents.size();
const char *object_addr = (const char *)MachOContents.data();
if (object_offset < object_size) {
const char *name = object_addr + object_offset;
return name;
} else {
return nullptr;
}
}
}
}
}
return nullptr;
}
// GuessIndirectSymbol returns the name of the indirect symbol for the
// ReferenceValue passed in or nullptr. This is used when ReferenceValue maybe
// an address of a symbol stub or a lazy or non-lazy pointer to associate the
// symbol name being referenced by the stub or pointer.
static const char *GuessIndirectSymbol(uint64_t ReferenceValue,
struct DisassembleInfo *info) {
MachO::dysymtab_command Dysymtab = info->O->getDysymtabLoadCommand();
MachO::symtab_command Symtab = info->O->getSymtabLoadCommand();
for (const auto &Load : info->O->load_commands()) {
if (Load.C.cmd == MachO::LC_SEGMENT_64) {
MachO::segment_command_64 Seg = info->O->getSegment64LoadCommand(Load);
for (unsigned J = 0; J < Seg.nsects; ++J) {
MachO::section_64 Sec = info->O->getSection64(Load, J);
uint32_t section_type = Sec.flags & MachO::SECTION_TYPE;
if ((section_type == MachO::S_NON_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_DYLIB_SYMBOL_POINTERS ||
section_type == MachO::S_THREAD_LOCAL_VARIABLE_POINTERS ||
section_type == MachO::S_SYMBOL_STUBS) &&
ReferenceValue >= Sec.addr &&
ReferenceValue < Sec.addr + Sec.size) {
uint32_t stride;
if (section_type == MachO::S_SYMBOL_STUBS)
stride = Sec.reserved2;
else
stride = 8;
if (stride == 0)
return nullptr;
uint32_t index = Sec.reserved1 + (ReferenceValue - Sec.addr) / stride;
if (index < Dysymtab.nindirectsyms) {
uint32_t indirect_symbol =
info->O->getIndirectSymbolTableEntry(Dysymtab, index);
if (indirect_symbol < Symtab.nsyms) {
symbol_iterator Sym = info->O->getSymbolByIndex(indirect_symbol);
SymbolRef Symbol = *Sym;
ErrorOr<StringRef> SymName = Symbol.getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
const char *name = SymName->data();
return name;
}
}
}
}
} else if (Load.C.cmd == MachO::LC_SEGMENT) {
MachO::segment_command Seg = info->O->getSegmentLoadCommand(Load);
for (unsigned J = 0; J < Seg.nsects; ++J) {
MachO::section Sec = info->O->getSection(Load, J);
uint32_t section_type = Sec.flags & MachO::SECTION_TYPE;
if ((section_type == MachO::S_NON_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_DYLIB_SYMBOL_POINTERS ||
section_type == MachO::S_THREAD_LOCAL_VARIABLE_POINTERS ||
section_type == MachO::S_SYMBOL_STUBS) &&
ReferenceValue >= Sec.addr &&
ReferenceValue < Sec.addr + Sec.size) {
uint32_t stride;
if (section_type == MachO::S_SYMBOL_STUBS)
stride = Sec.reserved2;
else
stride = 4;
if (stride == 0)
return nullptr;
uint32_t index = Sec.reserved1 + (ReferenceValue - Sec.addr) / stride;
if (index < Dysymtab.nindirectsyms) {
uint32_t indirect_symbol =
info->O->getIndirectSymbolTableEntry(Dysymtab, index);
if (indirect_symbol < Symtab.nsyms) {
symbol_iterator Sym = info->O->getSymbolByIndex(indirect_symbol);
SymbolRef Symbol = *Sym;
ErrorOr<StringRef> SymName = Symbol.getName();
if (std::error_code EC = SymName.getError())
report_fatal_error(EC.message());
const char *name = SymName->data();
return name;
}
}
}
}
}
}
return nullptr;
}
// method_reference() is called passing it the ReferenceName that might be
// a reference it to an Objective-C method call. If so then it allocates and
// assembles a method call string with the values last seen and saved in
// the DisassembleInfo's class_name and selector_name fields. This is saved
// into the method field of the info and any previous string is free'ed.
// Then the class_name field in the info is set to nullptr. The method call
// string is set into ReferenceName and ReferenceType is set to
// LLVMDisassembler_ReferenceType_Out_Objc_Message. If this not a method call
// then both ReferenceType and ReferenceName are left unchanged.
static void method_reference(struct DisassembleInfo *info,
uint64_t *ReferenceType,
const char **ReferenceName) {
unsigned int Arch = info->O->getArch();
if (*ReferenceName != nullptr) {
if (strcmp(*ReferenceName, "_objc_msgSend") == 0) {
if (info->selector_name != nullptr) {
if (info->method != nullptr)
free(info->method);
if (info->class_name != nullptr) {
info->method = (char *)malloc(5 + strlen(info->class_name) +
strlen(info->selector_name));
if (info->method != nullptr) {
strcpy(info->method, "+[");
strcat(info->method, info->class_name);
strcat(info->method, " ");
strcat(info->method, info->selector_name);
strcat(info->method, "]");
*ReferenceName = info->method;
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_Message;
}
} else {
info->method = (char *)malloc(9 + strlen(info->selector_name));
if (info->method != nullptr) {
if (Arch == Triple::x86_64)
strcpy(info->method, "-[%rdi ");
else if (Arch == Triple::aarch64)
strcpy(info->method, "-[x0 ");
else
strcpy(info->method, "-[r? ");
strcat(info->method, info->selector_name);
strcat(info->method, "]");
*ReferenceName = info->method;
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_Message;
}
}
info->class_name = nullptr;
}
} else if (strcmp(*ReferenceName, "_objc_msgSendSuper2") == 0) {
if (info->selector_name != nullptr) {
if (info->method != nullptr)
free(info->method);
info->method = (char *)malloc(17 + strlen(info->selector_name));
if (info->method != nullptr) {
if (Arch == Triple::x86_64)
strcpy(info->method, "-[[%rdi super] ");
else if (Arch == Triple::aarch64)
strcpy(info->method, "-[[x0 super] ");
else
strcpy(info->method, "-[[r? super] ");
strcat(info->method, info->selector_name);
strcat(info->method, "]");
*ReferenceName = info->method;
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_Message;
}
info->class_name = nullptr;
}
}
}
}
// GuessPointerPointer() is passed the address of what might be a pointer to
// a reference to an Objective-C class, selector, message ref or cfstring.
// If so the value of the pointer is returned and one of the booleans are set
// to true. If not zero is returned and all the booleans are set to false.
static uint64_t GuessPointerPointer(uint64_t ReferenceValue,
struct DisassembleInfo *info,
bool &classref, bool &selref, bool &msgref,
bool &cfstring) {
classref = false;
selref = false;
msgref = false;
cfstring = false;
for (const auto &Load : info->O->load_commands()) {
if (Load.C.cmd == MachO::LC_SEGMENT_64) {
MachO::segment_command_64 Seg = info->O->getSegment64LoadCommand(Load);
for (unsigned J = 0; J < Seg.nsects; ++J) {
MachO::section_64 Sec = info->O->getSection64(Load, J);
if ((strncmp(Sec.sectname, "__objc_selrefs", 16) == 0 ||
strncmp(Sec.sectname, "__objc_classrefs", 16) == 0 ||
strncmp(Sec.sectname, "__objc_superrefs", 16) == 0 ||
strncmp(Sec.sectname, "__objc_msgrefs", 16) == 0 ||
strncmp(Sec.sectname, "__cfstring", 16) == 0) &&
ReferenceValue >= Sec.addr &&
ReferenceValue < Sec.addr + Sec.size) {
uint64_t sect_offset = ReferenceValue - Sec.addr;
uint64_t object_offset = Sec.offset + sect_offset;
StringRef MachOContents = info->O->getData();
uint64_t object_size = MachOContents.size();
const char *object_addr = (const char *)MachOContents.data();
if (object_offset < object_size) {
uint64_t pointer_value;
memcpy(&pointer_value, object_addr + object_offset,
sizeof(uint64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(pointer_value);
if (strncmp(Sec.sectname, "__objc_selrefs", 16) == 0)
selref = true;
else if (strncmp(Sec.sectname, "__objc_classrefs", 16) == 0 ||
strncmp(Sec.sectname, "__objc_superrefs", 16) == 0)
classref = true;
else if (strncmp(Sec.sectname, "__objc_msgrefs", 16) == 0 &&
ReferenceValue + 8 < Sec.addr + Sec.size) {
msgref = true;
memcpy(&pointer_value, object_addr + object_offset + 8,
sizeof(uint64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(pointer_value);
} else if (strncmp(Sec.sectname, "__cfstring", 16) == 0)
cfstring = true;
return pointer_value;
} else {
return 0;
}
}
}
}
// TODO: Look for LC_SEGMENT for 32-bit Mach-O files.
}
return 0;
}
// get_pointer_64 returns a pointer to the bytes in the object file at the
// Address from a section in the Mach-O file. And indirectly returns the
// offset into the section, number of bytes left in the section past the offset
// and which section is was being referenced. If the Address is not in a
// section nullptr is returned.
static const char *get_pointer_64(uint64_t Address, uint32_t &offset,
uint32_t &left, SectionRef &S,
DisassembleInfo *info,
bool objc_only = false) {
offset = 0;
left = 0;
S = SectionRef();
for (unsigned SectIdx = 0; SectIdx != info->Sections->size(); SectIdx++) {
uint64_t SectAddress = ((*(info->Sections))[SectIdx]).getAddress();
uint64_t SectSize = ((*(info->Sections))[SectIdx]).getSize();
if (objc_only) {
StringRef SectName;
((*(info->Sections))[SectIdx]).getName(SectName);
DataRefImpl Ref = ((*(info->Sections))[SectIdx]).getRawDataRefImpl();
StringRef SegName = info->O->getSectionFinalSegmentName(Ref);
if (SegName != "__OBJC" && SectName != "__cstring")
continue;
}
if (Address >= SectAddress && Address < SectAddress + SectSize) {
S = (*(info->Sections))[SectIdx];
offset = Address - SectAddress;
left = SectSize - offset;
StringRef SectContents;
((*(info->Sections))[SectIdx]).getContents(SectContents);
return SectContents.data() + offset;
}
}
return nullptr;
}
static const char *get_pointer_32(uint32_t Address, uint32_t &offset,
uint32_t &left, SectionRef &S,
DisassembleInfo *info,
bool objc_only = false) {
return get_pointer_64(Address, offset, left, S, info, objc_only);
}
// get_symbol_64() returns the name of a symbol (or nullptr) and the address of
// the symbol indirectly through n_value. Based on the relocation information
// for the specified section offset in the specified section reference.
// If no relocation information is found and a non-zero ReferenceValue for the
// symbol is passed, look up that address in the info's AddrMap.
static const char *get_symbol_64(uint32_t sect_offset, SectionRef S,
DisassembleInfo *info, uint64_t &n_value,
uint64_t ReferenceValue = UnknownAddress) {
n_value = 0;
if (!info->verbose)
return nullptr;
// See if there is an external relocation entry at the sect_offset.
bool reloc_found = false;
DataRefImpl Rel;
MachO::any_relocation_info RE;
bool isExtern = false;
SymbolRef Symbol;
for (const RelocationRef &Reloc : S.relocations()) {
uint64_t RelocOffset = Reloc.getOffset();
if (RelocOffset == sect_offset) {
Rel = Reloc.getRawDataRefImpl();
RE = info->O->getRelocation(Rel);
if (info->O->isRelocationScattered(RE))
continue;
isExtern = info->O->getPlainRelocationExternal(RE);
if (isExtern) {
symbol_iterator RelocSym = Reloc.getSymbol();
Symbol = *RelocSym;
}
reloc_found = true;
break;
}
}
// If there is an external relocation entry for a symbol in this section
// at this section_offset then use that symbol's value for the n_value
// and return its name.
const char *SymbolName = nullptr;
if (reloc_found && isExtern) {
n_value = Symbol.getValue();
if (n_value == UnknownAddress)
n_value = 0;
ErrorOr<StringRef> NameOrError = Symbol.getName();
if (std::error_code EC = NameOrError.getError())
report_fatal_error(EC.message());
StringRef Name = *NameOrError;
if (!Name.empty()) {
SymbolName = Name.data();
return SymbolName;
}
}
// TODO: For fully linked images, look through the external relocation
// entries off the dynamic symtab command. For these the r_offset is from the
// start of the first writeable segment in the Mach-O file. So the offset
// to this section from that segment is passed to this routine by the caller,
// as the database_offset. Which is the difference of the section's starting
// address and the first writable segment.
//
// NOTE: need add passing the database_offset to this routine.
// We did not find an external relocation entry so look up the ReferenceValue
// as an address of a symbol and if found return that symbol's name.
if (ReferenceValue != UnknownAddress)
SymbolName = GuessSymbolName(ReferenceValue, info->AddrMap);
return SymbolName;
}
static const char *get_symbol_32(uint32_t sect_offset, SectionRef S,
DisassembleInfo *info,
uint32_t ReferenceValue) {
uint64_t n_value64;
return get_symbol_64(sect_offset, S, info, n_value64, ReferenceValue);
}
// These are structs in the Objective-C meta data and read to produce the
// comments for disassembly. While these are part of the ABI they are no
// public defintions. So the are here not in include/llvm/Support/MachO.h .
// The cfstring object in a 64-bit Mach-O file.
struct cfstring64_t {
uint64_t isa; // class64_t * (64-bit pointer)
uint64_t flags; // flag bits
uint64_t characters; // char * (64-bit pointer)
uint64_t length; // number of non-NULL characters in above
};
// The class object in a 64-bit Mach-O file.
struct class64_t {
uint64_t isa; // class64_t * (64-bit pointer)
uint64_t superclass; // class64_t * (64-bit pointer)
uint64_t cache; // Cache (64-bit pointer)
uint64_t vtable; // IMP * (64-bit pointer)
uint64_t data; // class_ro64_t * (64-bit pointer)
};
struct class32_t {
uint32_t isa; /* class32_t * (32-bit pointer) */
uint32_t superclass; /* class32_t * (32-bit pointer) */
uint32_t cache; /* Cache (32-bit pointer) */
uint32_t vtable; /* IMP * (32-bit pointer) */
uint32_t data; /* class_ro32_t * (32-bit pointer) */
};
struct class_ro64_t {
uint32_t flags;
uint32_t instanceStart;
uint32_t instanceSize;
uint32_t reserved;
uint64_t ivarLayout; // const uint8_t * (64-bit pointer)
uint64_t name; // const char * (64-bit pointer)
uint64_t baseMethods; // const method_list_t * (64-bit pointer)
uint64_t baseProtocols; // const protocol_list_t * (64-bit pointer)
uint64_t ivars; // const ivar_list_t * (64-bit pointer)
uint64_t weakIvarLayout; // const uint8_t * (64-bit pointer)
uint64_t baseProperties; // const struct objc_property_list (64-bit pointer)
};
struct class_ro32_t {
uint32_t flags;
uint32_t instanceStart;
uint32_t instanceSize;
uint32_t ivarLayout; /* const uint8_t * (32-bit pointer) */
uint32_t name; /* const char * (32-bit pointer) */
uint32_t baseMethods; /* const method_list_t * (32-bit pointer) */
uint32_t baseProtocols; /* const protocol_list_t * (32-bit pointer) */
uint32_t ivars; /* const ivar_list_t * (32-bit pointer) */
uint32_t weakIvarLayout; /* const uint8_t * (32-bit pointer) */
uint32_t baseProperties; /* const struct objc_property_list *
(32-bit pointer) */
};
/* Values for class_ro{64,32}_t->flags */
#define RO_META (1 << 0)
#define RO_ROOT (1 << 1)
#define RO_HAS_CXX_STRUCTORS (1 << 2)
struct method_list64_t {
uint32_t entsize;
uint32_t count;
/* struct method64_t first; These structures follow inline */
};
struct method_list32_t {
uint32_t entsize;
uint32_t count;
/* struct method32_t first; These structures follow inline */
};
struct method64_t {
uint64_t name; /* SEL (64-bit pointer) */
uint64_t types; /* const char * (64-bit pointer) */
uint64_t imp; /* IMP (64-bit pointer) */
};
struct method32_t {
uint32_t name; /* SEL (32-bit pointer) */
uint32_t types; /* const char * (32-bit pointer) */
uint32_t imp; /* IMP (32-bit pointer) */
};
struct protocol_list64_t {
uint64_t count; /* uintptr_t (a 64-bit value) */
/* struct protocol64_t * list[0]; These pointers follow inline */
};
struct protocol_list32_t {
uint32_t count; /* uintptr_t (a 32-bit value) */
/* struct protocol32_t * list[0]; These pointers follow inline */
};
struct protocol64_t {
uint64_t isa; /* id * (64-bit pointer) */
uint64_t name; /* const char * (64-bit pointer) */
uint64_t protocols; /* struct protocol_list64_t *
(64-bit pointer) */
uint64_t instanceMethods; /* method_list_t * (64-bit pointer) */
uint64_t classMethods; /* method_list_t * (64-bit pointer) */
uint64_t optionalInstanceMethods; /* method_list_t * (64-bit pointer) */
uint64_t optionalClassMethods; /* method_list_t * (64-bit pointer) */
uint64_t instanceProperties; /* struct objc_property_list *
(64-bit pointer) */
};
struct protocol32_t {
uint32_t isa; /* id * (32-bit pointer) */
uint32_t name; /* const char * (32-bit pointer) */
uint32_t protocols; /* struct protocol_list_t *
(32-bit pointer) */
uint32_t instanceMethods; /* method_list_t * (32-bit pointer) */
uint32_t classMethods; /* method_list_t * (32-bit pointer) */
uint32_t optionalInstanceMethods; /* method_list_t * (32-bit pointer) */
uint32_t optionalClassMethods; /* method_list_t * (32-bit pointer) */
uint32_t instanceProperties; /* struct objc_property_list *
(32-bit pointer) */
};
struct ivar_list64_t {
uint32_t entsize;
uint32_t count;
/* struct ivar64_t first; These structures follow inline */
};
struct ivar_list32_t {
uint32_t entsize;
uint32_t count;
/* struct ivar32_t first; These structures follow inline */
};
struct ivar64_t {
uint64_t offset; /* uintptr_t * (64-bit pointer) */
uint64_t name; /* const char * (64-bit pointer) */
uint64_t type; /* const char * (64-bit pointer) */
uint32_t alignment;
uint32_t size;
};
struct ivar32_t {
uint32_t offset; /* uintptr_t * (32-bit pointer) */
uint32_t name; /* const char * (32-bit pointer) */
uint32_t type; /* const char * (32-bit pointer) */
uint32_t alignment;
uint32_t size;
};
struct objc_property_list64 {
uint32_t entsize;
uint32_t count;
/* struct objc_property64 first; These structures follow inline */
};
struct objc_property_list32 {
uint32_t entsize;
uint32_t count;
/* struct objc_property32 first; These structures follow inline */
};
struct objc_property64 {
uint64_t name; /* const char * (64-bit pointer) */
uint64_t attributes; /* const char * (64-bit pointer) */
};
struct objc_property32 {
uint32_t name; /* const char * (32-bit pointer) */
uint32_t attributes; /* const char * (32-bit pointer) */
};
struct category64_t {
uint64_t name; /* const char * (64-bit pointer) */
uint64_t cls; /* struct class_t * (64-bit pointer) */
uint64_t instanceMethods; /* struct method_list_t * (64-bit pointer) */
uint64_t classMethods; /* struct method_list_t * (64-bit pointer) */
uint64_t protocols; /* struct protocol_list_t * (64-bit pointer) */
uint64_t instanceProperties; /* struct objc_property_list *
(64-bit pointer) */
};
struct category32_t {
uint32_t name; /* const char * (32-bit pointer) */
uint32_t cls; /* struct class_t * (32-bit pointer) */
uint32_t instanceMethods; /* struct method_list_t * (32-bit pointer) */
uint32_t classMethods; /* struct method_list_t * (32-bit pointer) */
uint32_t protocols; /* struct protocol_list_t * (32-bit pointer) */
uint32_t instanceProperties; /* struct objc_property_list *
(32-bit pointer) */
};
struct objc_image_info64 {
uint32_t version;
uint32_t flags;
};
struct objc_image_info32 {
uint32_t version;
uint32_t flags;
};
struct imageInfo_t {
uint32_t version;
uint32_t flags;
};
/* masks for objc_image_info.flags */
#define OBJC_IMAGE_IS_REPLACEMENT (1 << 0)
#define OBJC_IMAGE_SUPPORTS_GC (1 << 1)
struct message_ref64 {
uint64_t imp; /* IMP (64-bit pointer) */
uint64_t sel; /* SEL (64-bit pointer) */
};
struct message_ref32 {
uint32_t imp; /* IMP (32-bit pointer) */
uint32_t sel; /* SEL (32-bit pointer) */
};
// Objective-C 1 (32-bit only) meta data structs.
struct objc_module_t {
uint32_t version;
uint32_t size;
uint32_t name; /* char * (32-bit pointer) */
uint32_t symtab; /* struct objc_symtab * (32-bit pointer) */
};
struct objc_symtab_t {
uint32_t sel_ref_cnt;
uint32_t refs; /* SEL * (32-bit pointer) */
uint16_t cls_def_cnt;
uint16_t cat_def_cnt;
// uint32_t defs[1]; /* void * (32-bit pointer) variable size */
};
struct objc_class_t {
uint32_t isa; /* struct objc_class * (32-bit pointer) */
uint32_t super_class; /* struct objc_class * (32-bit pointer) */
uint32_t name; /* const char * (32-bit pointer) */
int32_t version;
int32_t info;
int32_t instance_size;
uint32_t ivars; /* struct objc_ivar_list * (32-bit pointer) */
uint32_t methodLists; /* struct objc_method_list ** (32-bit pointer) */
uint32_t cache; /* struct objc_cache * (32-bit pointer) */
uint32_t protocols; /* struct objc_protocol_list * (32-bit pointer) */
};
#define CLS_GETINFO(cls, infomask) ((cls)->info & (infomask))
// class is not a metaclass
#define CLS_CLASS 0x1
// class is a metaclass
#define CLS_META 0x2
struct objc_category_t {
uint32_t category_name; /* char * (32-bit pointer) */
uint32_t class_name; /* char * (32-bit pointer) */
uint32_t instance_methods; /* struct objc_method_list * (32-bit pointer) */
uint32_t class_methods; /* struct objc_method_list * (32-bit pointer) */
uint32_t protocols; /* struct objc_protocol_list * (32-bit ptr) */
};
struct objc_ivar_t {
uint32_t ivar_name; /* char * (32-bit pointer) */
uint32_t ivar_type; /* char * (32-bit pointer) */
int32_t ivar_offset;
};
struct objc_ivar_list_t {
int32_t ivar_count;
// struct objc_ivar_t ivar_list[1]; /* variable length structure */
};
struct objc_method_list_t {
uint32_t obsolete; /* struct objc_method_list * (32-bit pointer) */
int32_t method_count;
// struct objc_method_t method_list[1]; /* variable length structure */
};
struct objc_method_t {
uint32_t method_name; /* SEL, aka struct objc_selector * (32-bit pointer) */
uint32_t method_types; /* char * (32-bit pointer) */
uint32_t method_imp; /* IMP, aka function pointer, (*IMP)(id, SEL, ...)
(32-bit pointer) */
};
struct objc_protocol_list_t {
uint32_t next; /* struct objc_protocol_list * (32-bit pointer) */
int32_t count;
// uint32_t list[1]; /* Protocol *, aka struct objc_protocol_t *
// (32-bit pointer) */
};
struct objc_protocol_t {
uint32_t isa; /* struct objc_class * (32-bit pointer) */
uint32_t protocol_name; /* char * (32-bit pointer) */
uint32_t protocol_list; /* struct objc_protocol_list * (32-bit pointer) */
uint32_t instance_methods; /* struct objc_method_description_list *
(32-bit pointer) */
uint32_t class_methods; /* struct objc_method_description_list *
(32-bit pointer) */
};
struct objc_method_description_list_t {
int32_t count;
// struct objc_method_description_t list[1];
};
struct objc_method_description_t {
uint32_t name; /* SEL, aka struct objc_selector * (32-bit pointer) */
uint32_t types; /* char * (32-bit pointer) */
};
inline void swapStruct(struct cfstring64_t &cfs) {
sys::swapByteOrder(cfs.isa);
sys::swapByteOrder(cfs.flags);
sys::swapByteOrder(cfs.characters);
sys::swapByteOrder(cfs.length);
}
inline void swapStruct(struct class64_t &c) {
sys::swapByteOrder(c.isa);
sys::swapByteOrder(c.superclass);
sys::swapByteOrder(c.cache);
sys::swapByteOrder(c.vtable);
sys::swapByteOrder(c.data);
}
inline void swapStruct(struct class32_t &c) {
sys::swapByteOrder(c.isa);
sys::swapByteOrder(c.superclass);
sys::swapByteOrder(c.cache);
sys::swapByteOrder(c.vtable);
sys::swapByteOrder(c.data);
}
inline void swapStruct(struct class_ro64_t &cro) {
sys::swapByteOrder(cro.flags);
sys::swapByteOrder(cro.instanceStart);
sys::swapByteOrder(cro.instanceSize);
sys::swapByteOrder(cro.reserved);
sys::swapByteOrder(cro.ivarLayout);
sys::swapByteOrder(cro.name);
sys::swapByteOrder(cro.baseMethods);
sys::swapByteOrder(cro.baseProtocols);
sys::swapByteOrder(cro.ivars);
sys::swapByteOrder(cro.weakIvarLayout);
sys::swapByteOrder(cro.baseProperties);
}
inline void swapStruct(struct class_ro32_t &cro) {
sys::swapByteOrder(cro.flags);
sys::swapByteOrder(cro.instanceStart);
sys::swapByteOrder(cro.instanceSize);
sys::swapByteOrder(cro.ivarLayout);
sys::swapByteOrder(cro.name);
sys::swapByteOrder(cro.baseMethods);
sys::swapByteOrder(cro.baseProtocols);
sys::swapByteOrder(cro.ivars);
sys::swapByteOrder(cro.weakIvarLayout);
sys::swapByteOrder(cro.baseProperties);
}
inline void swapStruct(struct method_list64_t &ml) {
sys::swapByteOrder(ml.entsize);
sys::swapByteOrder(ml.count);
}
inline void swapStruct(struct method_list32_t &ml) {
sys::swapByteOrder(ml.entsize);
sys::swapByteOrder(ml.count);
}
inline void swapStruct(struct method64_t &m) {
sys::swapByteOrder(m.name);
sys::swapByteOrder(m.types);
sys::swapByteOrder(m.imp);
}
inline void swapStruct(struct method32_t &m) {
sys::swapByteOrder(m.name);
sys::swapByteOrder(m.types);
sys::swapByteOrder(m.imp);
}
inline void swapStruct(struct protocol_list64_t &pl) {
sys::swapByteOrder(pl.count);
}
inline void swapStruct(struct protocol_list32_t &pl) {
sys::swapByteOrder(pl.count);
}
inline void swapStruct(struct protocol64_t &p) {
sys::swapByteOrder(p.isa);
sys::swapByteOrder(p.name);
sys::swapByteOrder(p.protocols);
sys::swapByteOrder(p.instanceMethods);
sys::swapByteOrder(p.classMethods);
sys::swapByteOrder(p.optionalInstanceMethods);
sys::swapByteOrder(p.optionalClassMethods);
sys::swapByteOrder(p.instanceProperties);
}
inline void swapStruct(struct protocol32_t &p) {
sys::swapByteOrder(p.isa);
sys::swapByteOrder(p.name);
sys::swapByteOrder(p.protocols);
sys::swapByteOrder(p.instanceMethods);
sys::swapByteOrder(p.classMethods);
sys::swapByteOrder(p.optionalInstanceMethods);
sys::swapByteOrder(p.optionalClassMethods);
sys::swapByteOrder(p.instanceProperties);
}
inline void swapStruct(struct ivar_list64_t &il) {
sys::swapByteOrder(il.entsize);
sys::swapByteOrder(il.count);
}
inline void swapStruct(struct ivar_list32_t &il) {
sys::swapByteOrder(il.entsize);
sys::swapByteOrder(il.count);
}
inline void swapStruct(struct ivar64_t &i) {
sys::swapByteOrder(i.offset);
sys::swapByteOrder(i.name);
sys::swapByteOrder(i.type);
sys::swapByteOrder(i.alignment);
sys::swapByteOrder(i.size);
}
inline void swapStruct(struct ivar32_t &i) {
sys::swapByteOrder(i.offset);
sys::swapByteOrder(i.name);
sys::swapByteOrder(i.type);
sys::swapByteOrder(i.alignment);
sys::swapByteOrder(i.size);
}
inline void swapStruct(struct objc_property_list64 &pl) {
sys::swapByteOrder(pl.entsize);
sys::swapByteOrder(pl.count);
}
inline void swapStruct(struct objc_property_list32 &pl) {
sys::swapByteOrder(pl.entsize);
sys::swapByteOrder(pl.count);
}
inline void swapStruct(struct objc_property64 &op) {
sys::swapByteOrder(op.name);
sys::swapByteOrder(op.attributes);
}
inline void swapStruct(struct objc_property32 &op) {
sys::swapByteOrder(op.name);
sys::swapByteOrder(op.attributes);
}
inline void swapStruct(struct category64_t &c) {
sys::swapByteOrder(c.name);
sys::swapByteOrder(c.cls);
sys::swapByteOrder(c.instanceMethods);
sys::swapByteOrder(c.classMethods);
sys::swapByteOrder(c.protocols);
sys::swapByteOrder(c.instanceProperties);
}
inline void swapStruct(struct category32_t &c) {
sys::swapByteOrder(c.name);
sys::swapByteOrder(c.cls);
sys::swapByteOrder(c.instanceMethods);
sys::swapByteOrder(c.classMethods);
sys::swapByteOrder(c.protocols);
sys::swapByteOrder(c.instanceProperties);
}
inline void swapStruct(struct objc_image_info64 &o) {
sys::swapByteOrder(o.version);
sys::swapByteOrder(o.flags);
}
inline void swapStruct(struct objc_image_info32 &o) {
sys::swapByteOrder(o.version);
sys::swapByteOrder(o.flags);
}
inline void swapStruct(struct imageInfo_t &o) {
sys::swapByteOrder(o.version);
sys::swapByteOrder(o.flags);
}
inline void swapStruct(struct message_ref64 &mr) {
sys::swapByteOrder(mr.imp);
sys::swapByteOrder(mr.sel);
}
inline void swapStruct(struct message_ref32 &mr) {
sys::swapByteOrder(mr.imp);
sys::swapByteOrder(mr.sel);
}
inline void swapStruct(struct objc_module_t &module) {
sys::swapByteOrder(module.version);
sys::swapByteOrder(module.size);
sys::swapByteOrder(module.name);
sys::swapByteOrder(module.symtab);
}
inline void swapStruct(struct objc_symtab_t &symtab) {
sys::swapByteOrder(symtab.sel_ref_cnt);
sys::swapByteOrder(symtab.refs);
sys::swapByteOrder(symtab.cls_def_cnt);
sys::swapByteOrder(symtab.cat_def_cnt);
}
inline void swapStruct(struct objc_class_t &objc_class) {
sys::swapByteOrder(objc_class.isa);
sys::swapByteOrder(objc_class.super_class);
sys::swapByteOrder(objc_class.name);
sys::swapByteOrder(objc_class.version);
sys::swapByteOrder(objc_class.info);
sys::swapByteOrder(objc_class.instance_size);
sys::swapByteOrder(objc_class.ivars);
sys::swapByteOrder(objc_class.methodLists);
sys::swapByteOrder(objc_class.cache);
sys::swapByteOrder(objc_class.protocols);
}
inline void swapStruct(struct objc_category_t &objc_category) {
sys::swapByteOrder(objc_category.category_name);
sys::swapByteOrder(objc_category.class_name);
sys::swapByteOrder(objc_category.instance_methods);
sys::swapByteOrder(objc_category.class_methods);
sys::swapByteOrder(objc_category.protocols);
}
inline void swapStruct(struct objc_ivar_list_t &objc_ivar_list) {
sys::swapByteOrder(objc_ivar_list.ivar_count);
}
inline void swapStruct(struct objc_ivar_t &objc_ivar) {
sys::swapByteOrder(objc_ivar.ivar_name);
sys::swapByteOrder(objc_ivar.ivar_type);
sys::swapByteOrder(objc_ivar.ivar_offset);
}
inline void swapStruct(struct objc_method_list_t &method_list) {
sys::swapByteOrder(method_list.obsolete);
sys::swapByteOrder(method_list.method_count);
}
inline void swapStruct(struct objc_method_t &method) {
sys::swapByteOrder(method.method_name);
sys::swapByteOrder(method.method_types);
sys::swapByteOrder(method.method_imp);
}
inline void swapStruct(struct objc_protocol_list_t &protocol_list) {
sys::swapByteOrder(protocol_list.next);
sys::swapByteOrder(protocol_list.count);
}
inline void swapStruct(struct objc_protocol_t &protocol) {
sys::swapByteOrder(protocol.isa);
sys::swapByteOrder(protocol.protocol_name);
sys::swapByteOrder(protocol.protocol_list);
sys::swapByteOrder(protocol.instance_methods);
sys::swapByteOrder(protocol.class_methods);
}
inline void swapStruct(struct objc_method_description_list_t &mdl) {
sys::swapByteOrder(mdl.count);
}
inline void swapStruct(struct objc_method_description_t &md) {
sys::swapByteOrder(md.name);
sys::swapByteOrder(md.types);
}
static const char *get_dyld_bind_info_symbolname(uint64_t ReferenceValue,
struct DisassembleInfo *info);
// get_objc2_64bit_class_name() is used for disassembly and is passed a pointer
// to an Objective-C class and returns the class name. It is also passed the
// address of the pointer, so when the pointer is zero as it can be in an .o
// file, that is used to look for an external relocation entry with a symbol
// name.
static const char *get_objc2_64bit_class_name(uint64_t pointer_value,
uint64_t ReferenceValue,
struct DisassembleInfo *info) {
const char *r;
uint32_t offset, left;
SectionRef S;
// The pointer_value can be 0 in an object file and have a relocation
// entry for the class symbol at the ReferenceValue (the address of the
// pointer).
if (pointer_value == 0) {
r = get_pointer_64(ReferenceValue, offset, left, S, info);
if (r == nullptr || left < sizeof(uint64_t))
return nullptr;
uint64_t n_value;
const char *symbol_name = get_symbol_64(offset, S, info, n_value);
if (symbol_name == nullptr)
return nullptr;
const char *class_name = strrchr(symbol_name, '$');
if (class_name != nullptr && class_name[1] == '_' && class_name[2] != '\0')
return class_name + 2;
else
return nullptr;
}
// The case were the pointer_value is non-zero and points to a class defined
// in this Mach-O file.
r = get_pointer_64(pointer_value, offset, left, S, info);
if (r == nullptr || left < sizeof(struct class64_t))
return nullptr;
struct class64_t c;
memcpy(&c, r, sizeof(struct class64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(c);
if (c.data == 0)
return nullptr;
r = get_pointer_64(c.data, offset, left, S, info);
if (r == nullptr || left < sizeof(struct class_ro64_t))
return nullptr;
struct class_ro64_t cro;
memcpy(&cro, r, sizeof(struct class_ro64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(cro);
if (cro.name == 0)
return nullptr;
const char *name = get_pointer_64(cro.name, offset, left, S, info);
return name;
}
// get_objc2_64bit_cfstring_name is used for disassembly and is passed a
// pointer to a cfstring and returns its name or nullptr.
static const char *get_objc2_64bit_cfstring_name(uint64_t ReferenceValue,
struct DisassembleInfo *info) {
const char *r, *name;
uint32_t offset, left;
SectionRef S;
struct cfstring64_t cfs;
uint64_t cfs_characters;
r = get_pointer_64(ReferenceValue, offset, left, S, info);
if (r == nullptr || left < sizeof(struct cfstring64_t))
return nullptr;
memcpy(&cfs, r, sizeof(struct cfstring64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(cfs);
if (cfs.characters == 0) {
uint64_t n_value;
const char *symbol_name = get_symbol_64(
offset + offsetof(struct cfstring64_t, characters), S, info, n_value);
if (symbol_name == nullptr)
return nullptr;
cfs_characters = n_value;
} else
cfs_characters = cfs.characters;
name = get_pointer_64(cfs_characters, offset, left, S, info);
return name;
}
// get_objc2_64bit_selref() is used for disassembly and is passed a the address
// of a pointer to an Objective-C selector reference when the pointer value is
// zero as in a .o file and is likely to have a external relocation entry with
// who's symbol's n_value is the real pointer to the selector name. If that is
// the case the real pointer to the selector name is returned else 0 is
// returned
static uint64_t get_objc2_64bit_selref(uint64_t ReferenceValue,
struct DisassembleInfo *info) {
uint32_t offset, left;
SectionRef S;
const char *r = get_pointer_64(ReferenceValue, offset, left, S, info);
if (r == nullptr || left < sizeof(uint64_t))
return 0;
uint64_t n_value;
const char *symbol_name = get_symbol_64(offset, S, info, n_value);
if (symbol_name == nullptr)
return 0;
return n_value;
}
static const SectionRef get_section(MachOObjectFile *O, const char *segname,
const char *sectname) {
for (const SectionRef &Section : O->sections()) {
StringRef SectName;
Section.getName(SectName);
DataRefImpl Ref = Section.getRawDataRefImpl();
StringRef SegName = O->getSectionFinalSegmentName(Ref);
if (SegName == segname && SectName == sectname)
return Section;
}
return SectionRef();
}
static void
walk_pointer_list_64(const char *listname, const SectionRef S,
MachOObjectFile *O, struct DisassembleInfo *info,
void (*func)(uint64_t, struct DisassembleInfo *info)) {
if (S == SectionRef())
return;
StringRef SectName;
S.getName(SectName);
DataRefImpl Ref = S.getRawDataRefImpl();
StringRef SegName = O->getSectionFinalSegmentName(Ref);
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
StringRef BytesStr;
S.getContents(BytesStr);
const char *Contents = reinterpret_cast<const char *>(BytesStr.data());
for (uint32_t i = 0; i < S.getSize(); i += sizeof(uint64_t)) {
uint32_t left = S.getSize() - i;
uint32_t size = left < sizeof(uint64_t) ? left : sizeof(uint64_t);
uint64_t p = 0;
memcpy(&p, Contents + i, size);
if (i + sizeof(uint64_t) > S.getSize())
outs() << listname << " list pointer extends past end of (" << SegName
<< "," << SectName << ") section\n";
outs() << format("%016" PRIx64, S.getAddress() + i) << " ";
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(p);
uint64_t n_value = 0;
const char *name = get_symbol_64(i, S, info, n_value, p);
if (name == nullptr)
name = get_dyld_bind_info_symbolname(S.getAddress() + i, info);
if (n_value != 0) {
outs() << format("0x%" PRIx64, n_value);
if (p != 0)
outs() << " + " << format("0x%" PRIx64, p);
} else
outs() << format("0x%" PRIx64, p);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
p += n_value;
if (func)
func(p, info);
}
}
static void
walk_pointer_list_32(const char *listname, const SectionRef S,
MachOObjectFile *O, struct DisassembleInfo *info,
void (*func)(uint32_t, struct DisassembleInfo *info)) {
if (S == SectionRef())
return;
StringRef SectName;
S.getName(SectName);
DataRefImpl Ref = S.getRawDataRefImpl();
StringRef SegName = O->getSectionFinalSegmentName(Ref);
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
StringRef BytesStr;
S.getContents(BytesStr);
const char *Contents = reinterpret_cast<const char *>(BytesStr.data());
for (uint32_t i = 0; i < S.getSize(); i += sizeof(uint32_t)) {
uint32_t left = S.getSize() - i;
uint32_t size = left < sizeof(uint32_t) ? left : sizeof(uint32_t);
uint32_t p = 0;
memcpy(&p, Contents + i, size);
if (i + sizeof(uint32_t) > S.getSize())
outs() << listname << " list pointer extends past end of (" << SegName
<< "," << SectName << ") section\n";
uint32_t Address = S.getAddress() + i;
outs() << format("%08" PRIx32, Address) << " ";
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(p);
outs() << format("0x%" PRIx32, p);
const char *name = get_symbol_32(i, S, info, p);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
if (func)
func(p, info);
}
}
static void print_layout_map(const char *layout_map, uint32_t left) {
outs() << " layout map: ";
do {
outs() << format("0x%02" PRIx32, (*layout_map) & 0xff) << " ";
left--;
layout_map++;
} while (*layout_map != '\0' && left != 0);
outs() << "\n";
}
static void print_layout_map64(uint64_t p, struct DisassembleInfo *info) {
uint32_t offset, left;
SectionRef S;
const char *layout_map;
if (p == 0)
return;
layout_map = get_pointer_64(p, offset, left, S, info);
print_layout_map(layout_map, left);
}
static void print_layout_map32(uint32_t p, struct DisassembleInfo *info) {
uint32_t offset, left;
SectionRef S;
const char *layout_map;
if (p == 0)
return;
layout_map = get_pointer_32(p, offset, left, S, info);
print_layout_map(layout_map, left);
}
static void print_method_list64_t(uint64_t p, struct DisassembleInfo *info,
const char *indent) {
struct method_list64_t ml;
struct method64_t m;
const char *r;
uint32_t offset, xoffset, left, i;
SectionRef S, xS;
const char *name, *sym_name;
uint64_t n_value;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&ml, '\0', sizeof(struct method_list64_t));
if (left < sizeof(struct method_list64_t)) {
memcpy(&ml, r, left);
outs() << " (method_list_t entends past the end of the section)\n";
} else
memcpy(&ml, r, sizeof(struct method_list64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(ml);
outs() << indent << "\t\t entsize " << ml.entsize << "\n";
outs() << indent << "\t\t count " << ml.count << "\n";
p += sizeof(struct method_list64_t);
offset += sizeof(struct method_list64_t);
for (i = 0; i < ml.count; i++) {
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&m, '\0', sizeof(struct method64_t));
if (left < sizeof(struct method64_t)) {
memcpy(&ml, r, left);
outs() << indent << " (method_t entends past the end of the section)\n";
} else
memcpy(&m, r, sizeof(struct method64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(m);
outs() << indent << "\t\t name ";
sym_name = get_symbol_64(offset + offsetof(struct method64_t, name), S,
info, n_value, m.name);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (m.name != 0)
outs() << " + " << format("0x%" PRIx64, m.name);
} else
outs() << format("0x%" PRIx64, m.name);
name = get_pointer_64(m.name + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << indent << "\t\t types ";
sym_name = get_symbol_64(offset + offsetof(struct method64_t, types), S,
info, n_value, m.types);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (m.types != 0)
outs() << " + " << format("0x%" PRIx64, m.types);
} else
outs() << format("0x%" PRIx64, m.types);
name = get_pointer_64(m.types + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << indent << "\t\t imp ";
name = get_symbol_64(offset + offsetof(struct method64_t, imp), S, info,
n_value, m.imp);
if (info->verbose && name == nullptr) {
if (n_value != 0) {
outs() << format("0x%" PRIx64, n_value) << " ";
if (m.imp != 0)
outs() << "+ " << format("0x%" PRIx64, m.imp) << " ";
} else
outs() << format("0x%" PRIx64, m.imp) << " ";
}
if (name != nullptr)
outs() << name;
outs() << "\n";
p += sizeof(struct method64_t);
offset += sizeof(struct method64_t);
}
}
static void print_method_list32_t(uint64_t p, struct DisassembleInfo *info,
const char *indent) {
struct method_list32_t ml;
struct method32_t m;
const char *r, *name;
uint32_t offset, xoffset, left, i;
SectionRef S, xS;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&ml, '\0', sizeof(struct method_list32_t));
if (left < sizeof(struct method_list32_t)) {
memcpy(&ml, r, left);
outs() << " (method_list_t entends past the end of the section)\n";
} else
memcpy(&ml, r, sizeof(struct method_list32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(ml);
outs() << indent << "\t\t entsize " << ml.entsize << "\n";
outs() << indent << "\t\t count " << ml.count << "\n";
p += sizeof(struct method_list32_t);
offset += sizeof(struct method_list32_t);
for (i = 0; i < ml.count; i++) {
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&m, '\0', sizeof(struct method32_t));
if (left < sizeof(struct method32_t)) {
memcpy(&ml, r, left);
outs() << indent << " (method_t entends past the end of the section)\n";
} else
memcpy(&m, r, sizeof(struct method32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(m);
outs() << indent << "\t\t name " << format("0x%" PRIx32, m.name);
name = get_pointer_32(m.name, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << indent << "\t\t types " << format("0x%" PRIx32, m.types);
name = get_pointer_32(m.types, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << indent << "\t\t imp " << format("0x%" PRIx32, m.imp);
name = get_symbol_32(offset + offsetof(struct method32_t, imp), S, info,
m.imp);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
p += sizeof(struct method32_t);
offset += sizeof(struct method32_t);
}
}
static bool print_method_list(uint32_t p, struct DisassembleInfo *info) {
uint32_t offset, left, xleft;
SectionRef S;
struct objc_method_list_t method_list;
struct objc_method_t method;
const char *r, *methods, *name, *SymbolName;
int32_t i;
r = get_pointer_32(p, offset, left, S, info, true);
if (r == nullptr)
return true;
outs() << "\n";
if (left > sizeof(struct objc_method_list_t)) {
memcpy(&method_list, r, sizeof(struct objc_method_list_t));
} else {
outs() << "\t\t objc_method_list extends past end of the section\n";
memset(&method_list, '\0', sizeof(struct objc_method_list_t));
memcpy(&method_list, r, left);
}
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(method_list);
outs() << "\t\t obsolete "
<< format("0x%08" PRIx32, method_list.obsolete) << "\n";
outs() << "\t\t method_count " << method_list.method_count << "\n";
methods = r + sizeof(struct objc_method_list_t);
for (i = 0; i < method_list.method_count; i++) {
if ((i + 1) * sizeof(struct objc_method_t) > left) {
outs() << "\t\t remaining method's extend past the of the section\n";
break;
}
memcpy(&method, methods + i * sizeof(struct objc_method_t),
sizeof(struct objc_method_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(method);
outs() << "\t\t method_name "
<< format("0x%08" PRIx32, method.method_name);
if (info->verbose) {
name = get_pointer_32(method.method_name, offset, xleft, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", xleft, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t\t method_types "
<< format("0x%08" PRIx32, method.method_types);
if (info->verbose) {
name = get_pointer_32(method.method_types, offset, xleft, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", xleft, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t\t method_imp "
<< format("0x%08" PRIx32, method.method_imp) << " ";
if (info->verbose) {
SymbolName = GuessSymbolName(method.method_imp, info->AddrMap);
if (SymbolName != nullptr)
outs() << SymbolName;
}
outs() << "\n";
}
return false;
}
static void print_protocol_list64_t(uint64_t p, struct DisassembleInfo *info) {
struct protocol_list64_t pl;
uint64_t q, n_value;
struct protocol64_t pc;
const char *r;
uint32_t offset, xoffset, left, i;
SectionRef S, xS;
const char *name, *sym_name;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&pl, '\0', sizeof(struct protocol_list64_t));
if (left < sizeof(struct protocol_list64_t)) {
memcpy(&pl, r, left);
outs() << " (protocol_list_t entends past the end of the section)\n";
} else
memcpy(&pl, r, sizeof(struct protocol_list64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(pl);
outs() << " count " << pl.count << "\n";
p += sizeof(struct protocol_list64_t);
offset += sizeof(struct protocol_list64_t);
for (i = 0; i < pl.count; i++) {
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
q = 0;
if (left < sizeof(uint64_t)) {
memcpy(&q, r, left);
outs() << " (protocol_t * entends past the end of the section)\n";
} else
memcpy(&q, r, sizeof(uint64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(q);
outs() << "\t\t list[" << i << "] ";
sym_name = get_symbol_64(offset, S, info, n_value, q);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (q != 0)
outs() << " + " << format("0x%" PRIx64, q);
} else
outs() << format("0x%" PRIx64, q);
outs() << " (struct protocol_t *)\n";
r = get_pointer_64(q + n_value, offset, left, S, info);
if (r == nullptr)
return;
memset(&pc, '\0', sizeof(struct protocol64_t));
if (left < sizeof(struct protocol64_t)) {
memcpy(&pc, r, left);
outs() << " (protocol_t entends past the end of the section)\n";
} else
memcpy(&pc, r, sizeof(struct protocol64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(pc);
outs() << "\t\t\t isa " << format("0x%" PRIx64, pc.isa) << "\n";
outs() << "\t\t\t name ";
sym_name = get_symbol_64(offset + offsetof(struct protocol64_t, name), S,
info, n_value, pc.name);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (pc.name != 0)
outs() << " + " << format("0x%" PRIx64, pc.name);
} else
outs() << format("0x%" PRIx64, pc.name);
name = get_pointer_64(pc.name + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\tprotocols " << format("0x%" PRIx64, pc.protocols) << "\n";
outs() << "\t\t instanceMethods ";
sym_name =
get_symbol_64(offset + offsetof(struct protocol64_t, instanceMethods),
S, info, n_value, pc.instanceMethods);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (pc.instanceMethods != 0)
outs() << " + " << format("0x%" PRIx64, pc.instanceMethods);
} else
outs() << format("0x%" PRIx64, pc.instanceMethods);
outs() << " (struct method_list_t *)\n";
if (pc.instanceMethods + n_value != 0)
print_method_list64_t(pc.instanceMethods + n_value, info, "\t");
outs() << "\t\t classMethods ";
sym_name =
get_symbol_64(offset + offsetof(struct protocol64_t, classMethods), S,
info, n_value, pc.classMethods);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (pc.classMethods != 0)
outs() << " + " << format("0x%" PRIx64, pc.classMethods);
} else
outs() << format("0x%" PRIx64, pc.classMethods);
outs() << " (struct method_list_t *)\n";
if (pc.classMethods + n_value != 0)
print_method_list64_t(pc.classMethods + n_value, info, "\t");
outs() << "\t optionalInstanceMethods "
<< format("0x%" PRIx64, pc.optionalInstanceMethods) << "\n";
outs() << "\t optionalClassMethods "
<< format("0x%" PRIx64, pc.optionalClassMethods) << "\n";
outs() << "\t instanceProperties "
<< format("0x%" PRIx64, pc.instanceProperties) << "\n";
p += sizeof(uint64_t);
offset += sizeof(uint64_t);
}
}
static void print_protocol_list32_t(uint32_t p, struct DisassembleInfo *info) {
struct protocol_list32_t pl;
uint32_t q;
struct protocol32_t pc;
const char *r;
uint32_t offset, xoffset, left, i;
SectionRef S, xS;
const char *name;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&pl, '\0', sizeof(struct protocol_list32_t));
if (left < sizeof(struct protocol_list32_t)) {
memcpy(&pl, r, left);
outs() << " (protocol_list_t entends past the end of the section)\n";
} else
memcpy(&pl, r, sizeof(struct protocol_list32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(pl);
outs() << " count " << pl.count << "\n";
p += sizeof(struct protocol_list32_t);
offset += sizeof(struct protocol_list32_t);
for (i = 0; i < pl.count; i++) {
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
q = 0;
if (left < sizeof(uint32_t)) {
memcpy(&q, r, left);
outs() << " (protocol_t * entends past the end of the section)\n";
} else
memcpy(&q, r, sizeof(uint32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(q);
outs() << "\t\t list[" << i << "] " << format("0x%" PRIx32, q)
<< " (struct protocol_t *)\n";
r = get_pointer_32(q, offset, left, S, info);
if (r == nullptr)
return;
memset(&pc, '\0', sizeof(struct protocol32_t));
if (left < sizeof(struct protocol32_t)) {
memcpy(&pc, r, left);
outs() << " (protocol_t entends past the end of the section)\n";
} else
memcpy(&pc, r, sizeof(struct protocol32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(pc);
outs() << "\t\t\t isa " << format("0x%" PRIx32, pc.isa) << "\n";
outs() << "\t\t\t name " << format("0x%" PRIx32, pc.name);
name = get_pointer_32(pc.name, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\tprotocols " << format("0x%" PRIx32, pc.protocols) << "\n";
outs() << "\t\t instanceMethods "
<< format("0x%" PRIx32, pc.instanceMethods)
<< " (struct method_list_t *)\n";
if (pc.instanceMethods != 0)
print_method_list32_t(pc.instanceMethods, info, "\t");
outs() << "\t\t classMethods " << format("0x%" PRIx32, pc.classMethods)
<< " (struct method_list_t *)\n";
if (pc.classMethods != 0)
print_method_list32_t(pc.classMethods, info, "\t");
outs() << "\t optionalInstanceMethods "
<< format("0x%" PRIx32, pc.optionalInstanceMethods) << "\n";
outs() << "\t optionalClassMethods "
<< format("0x%" PRIx32, pc.optionalClassMethods) << "\n";
outs() << "\t instanceProperties "
<< format("0x%" PRIx32, pc.instanceProperties) << "\n";
p += sizeof(uint32_t);
offset += sizeof(uint32_t);
}
}
static void print_indent(uint32_t indent) {
for (uint32_t i = 0; i < indent;) {
if (indent - i >= 8) {
outs() << "\t";
i += 8;
} else {
for (uint32_t j = i; j < indent; j++)
outs() << " ";
return;
}
}
}
static bool print_method_description_list(uint32_t p, uint32_t indent,
struct DisassembleInfo *info) {
uint32_t offset, left, xleft;
SectionRef S;
struct objc_method_description_list_t mdl;
struct objc_method_description_t md;
const char *r, *list, *name;
int32_t i;
r = get_pointer_32(p, offset, left, S, info, true);
if (r == nullptr)
return true;
outs() << "\n";
if (left > sizeof(struct objc_method_description_list_t)) {
memcpy(&mdl, r, sizeof(struct objc_method_description_list_t));
} else {
print_indent(indent);
outs() << " objc_method_description_list extends past end of the section\n";
memset(&mdl, '\0', sizeof(struct objc_method_description_list_t));
memcpy(&mdl, r, left);
}
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(mdl);
print_indent(indent);
outs() << " count " << mdl.count << "\n";
list = r + sizeof(struct objc_method_description_list_t);
for (i = 0; i < mdl.count; i++) {
if ((i + 1) * sizeof(struct objc_method_description_t) > left) {
print_indent(indent);
outs() << " remaining list entries extend past the of the section\n";
break;
}
print_indent(indent);
outs() << " list[" << i << "]\n";
memcpy(&md, list + i * sizeof(struct objc_method_description_t),
sizeof(struct objc_method_description_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(md);
print_indent(indent);
outs() << " name " << format("0x%08" PRIx32, md.name);
if (info->verbose) {
name = get_pointer_32(md.name, offset, xleft, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", xleft, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
print_indent(indent);
outs() << " types " << format("0x%08" PRIx32, md.types);
if (info->verbose) {
name = get_pointer_32(md.types, offset, xleft, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", xleft, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
}
return false;
}
static bool print_protocol_list(uint32_t p, uint32_t indent,
struct DisassembleInfo *info);
static bool print_protocol(uint32_t p, uint32_t indent,
struct DisassembleInfo *info) {
uint32_t offset, left;
SectionRef S;
struct objc_protocol_t protocol;
const char *r, *name;
r = get_pointer_32(p, offset, left, S, info, true);
if (r == nullptr)
return true;
outs() << "\n";
if (left >= sizeof(struct objc_protocol_t)) {
memcpy(&protocol, r, sizeof(struct objc_protocol_t));
} else {
print_indent(indent);
outs() << " Protocol extends past end of the section\n";
memset(&protocol, '\0', sizeof(struct objc_protocol_t));
memcpy(&protocol, r, left);
}
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(protocol);
print_indent(indent);
outs() << " isa " << format("0x%08" PRIx32, protocol.isa)
<< "\n";
print_indent(indent);
outs() << " protocol_name "
<< format("0x%08" PRIx32, protocol.protocol_name);
if (info->verbose) {
name = get_pointer_32(protocol.protocol_name, offset, left, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", left, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
print_indent(indent);
outs() << " protocol_list "
<< format("0x%08" PRIx32, protocol.protocol_list);
if (print_protocol_list(protocol.protocol_list, indent + 4, info))
outs() << " (not in an __OBJC section)\n";
print_indent(indent);
outs() << " instance_methods "
<< format("0x%08" PRIx32, protocol.instance_methods);
if (print_method_description_list(protocol.instance_methods, indent, info))
outs() << " (not in an __OBJC section)\n";
print_indent(indent);
outs() << " class_methods "
<< format("0x%08" PRIx32, protocol.class_methods);
if (print_method_description_list(protocol.class_methods, indent, info))
outs() << " (not in an __OBJC section)\n";
return false;
}
static bool print_protocol_list(uint32_t p, uint32_t indent,
struct DisassembleInfo *info) {
uint32_t offset, left, l;
SectionRef S;
struct objc_protocol_list_t protocol_list;
const char *r, *list;
int32_t i;
r = get_pointer_32(p, offset, left, S, info, true);
if (r == nullptr)
return true;
outs() << "\n";
if (left > sizeof(struct objc_protocol_list_t)) {
memcpy(&protocol_list, r, sizeof(struct objc_protocol_list_t));
} else {
outs() << "\t\t objc_protocol_list_t extends past end of the section\n";
memset(&protocol_list, '\0', sizeof(struct objc_protocol_list_t));
memcpy(&protocol_list, r, left);
}
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(protocol_list);
print_indent(indent);
outs() << " next " << format("0x%08" PRIx32, protocol_list.next)
<< "\n";
print_indent(indent);
outs() << " count " << protocol_list.count << "\n";
list = r + sizeof(struct objc_protocol_list_t);
for (i = 0; i < protocol_list.count; i++) {
if ((i + 1) * sizeof(uint32_t) > left) {
outs() << "\t\t remaining list entries extend past the of the section\n";
break;
}
memcpy(&l, list + i * sizeof(uint32_t), sizeof(uint32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(l);
print_indent(indent);
outs() << " list[" << i << "] " << format("0x%08" PRIx32, l);
if (print_protocol(l, indent, info))
outs() << "(not in an __OBJC section)\n";
}
return false;
}
static void print_ivar_list64_t(uint64_t p, struct DisassembleInfo *info) {
struct ivar_list64_t il;
struct ivar64_t i;
const char *r;
uint32_t offset, xoffset, left, j;
SectionRef S, xS;
const char *name, *sym_name, *ivar_offset_p;
uint64_t ivar_offset, n_value;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&il, '\0', sizeof(struct ivar_list64_t));
if (left < sizeof(struct ivar_list64_t)) {
memcpy(&il, r, left);
outs() << " (ivar_list_t entends past the end of the section)\n";
} else
memcpy(&il, r, sizeof(struct ivar_list64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(il);
outs() << " entsize " << il.entsize << "\n";
outs() << " count " << il.count << "\n";
p += sizeof(struct ivar_list64_t);
offset += sizeof(struct ivar_list64_t);
for (j = 0; j < il.count; j++) {
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&i, '\0', sizeof(struct ivar64_t));
if (left < sizeof(struct ivar64_t)) {
memcpy(&i, r, left);
outs() << " (ivar_t entends past the end of the section)\n";
} else
memcpy(&i, r, sizeof(struct ivar64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(i);
outs() << "\t\t\t offset ";
sym_name = get_symbol_64(offset + offsetof(struct ivar64_t, offset), S,
info, n_value, i.offset);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (i.offset != 0)
outs() << " + " << format("0x%" PRIx64, i.offset);
} else
outs() << format("0x%" PRIx64, i.offset);
ivar_offset_p = get_pointer_64(i.offset + n_value, xoffset, left, xS, info);
if (ivar_offset_p != nullptr && left >= sizeof(*ivar_offset_p)) {
memcpy(&ivar_offset, ivar_offset_p, sizeof(ivar_offset));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(ivar_offset);
outs() << " " << ivar_offset << "\n";
} else
outs() << "\n";
outs() << "\t\t\t name ";
sym_name = get_symbol_64(offset + offsetof(struct ivar64_t, name), S, info,
n_value, i.name);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (i.name != 0)
outs() << " + " << format("0x%" PRIx64, i.name);
} else
outs() << format("0x%" PRIx64, i.name);
name = get_pointer_64(i.name + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\t type ";
sym_name = get_symbol_64(offset + offsetof(struct ivar64_t, type), S, info,
n_value, i.name);
name = get_pointer_64(i.type + n_value, xoffset, left, xS, info);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (i.type != 0)
outs() << " + " << format("0x%" PRIx64, i.type);
} else
outs() << format("0x%" PRIx64, i.type);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\talignment " << i.alignment << "\n";
outs() << "\t\t\t size " << i.size << "\n";
p += sizeof(struct ivar64_t);
offset += sizeof(struct ivar64_t);
}
}
static void print_ivar_list32_t(uint32_t p, struct DisassembleInfo *info) {
struct ivar_list32_t il;
struct ivar32_t i;
const char *r;
uint32_t offset, xoffset, left, j;
SectionRef S, xS;
const char *name, *ivar_offset_p;
uint32_t ivar_offset;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&il, '\0', sizeof(struct ivar_list32_t));
if (left < sizeof(struct ivar_list32_t)) {
memcpy(&il, r, left);
outs() << " (ivar_list_t entends past the end of the section)\n";
} else
memcpy(&il, r, sizeof(struct ivar_list32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(il);
outs() << " entsize " << il.entsize << "\n";
outs() << " count " << il.count << "\n";
p += sizeof(struct ivar_list32_t);
offset += sizeof(struct ivar_list32_t);
for (j = 0; j < il.count; j++) {
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&i, '\0', sizeof(struct ivar32_t));
if (left < sizeof(struct ivar32_t)) {
memcpy(&i, r, left);
outs() << " (ivar_t entends past the end of the section)\n";
} else
memcpy(&i, r, sizeof(struct ivar32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(i);
outs() << "\t\t\t offset " << format("0x%" PRIx32, i.offset);
ivar_offset_p = get_pointer_32(i.offset, xoffset, left, xS, info);
if (ivar_offset_p != nullptr && left >= sizeof(*ivar_offset_p)) {
memcpy(&ivar_offset, ivar_offset_p, sizeof(ivar_offset));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(ivar_offset);
outs() << " " << ivar_offset << "\n";
} else
outs() << "\n";
outs() << "\t\t\t name " << format("0x%" PRIx32, i.name);
name = get_pointer_32(i.name, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\t type " << format("0x%" PRIx32, i.type);
name = get_pointer_32(i.type, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\talignment " << i.alignment << "\n";
outs() << "\t\t\t size " << i.size << "\n";
p += sizeof(struct ivar32_t);
offset += sizeof(struct ivar32_t);
}
}
static void print_objc_property_list64(uint64_t p,
struct DisassembleInfo *info) {
struct objc_property_list64 opl;
struct objc_property64 op;
const char *r;
uint32_t offset, xoffset, left, j;
SectionRef S, xS;
const char *name, *sym_name;
uint64_t n_value;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&opl, '\0', sizeof(struct objc_property_list64));
if (left < sizeof(struct objc_property_list64)) {
memcpy(&opl, r, left);
outs() << " (objc_property_list entends past the end of the section)\n";
} else
memcpy(&opl, r, sizeof(struct objc_property_list64));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(opl);
outs() << " entsize " << opl.entsize << "\n";
outs() << " count " << opl.count << "\n";
p += sizeof(struct objc_property_list64);
offset += sizeof(struct objc_property_list64);
for (j = 0; j < opl.count; j++) {
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&op, '\0', sizeof(struct objc_property64));
if (left < sizeof(struct objc_property64)) {
memcpy(&op, r, left);
outs() << " (objc_property entends past the end of the section)\n";
} else
memcpy(&op, r, sizeof(struct objc_property64));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(op);
outs() << "\t\t\t name ";
sym_name = get_symbol_64(offset + offsetof(struct objc_property64, name), S,
info, n_value, op.name);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (op.name != 0)
outs() << " + " << format("0x%" PRIx64, op.name);
} else
outs() << format("0x%" PRIx64, op.name);
name = get_pointer_64(op.name + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\tattributes ";
sym_name =
get_symbol_64(offset + offsetof(struct objc_property64, attributes), S,
info, n_value, op.attributes);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (op.attributes != 0)
outs() << " + " << format("0x%" PRIx64, op.attributes);
} else
outs() << format("0x%" PRIx64, op.attributes);
name = get_pointer_64(op.attributes + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
p += sizeof(struct objc_property64);
offset += sizeof(struct objc_property64);
}
}
static void print_objc_property_list32(uint32_t p,
struct DisassembleInfo *info) {
struct objc_property_list32 opl;
struct objc_property32 op;
const char *r;
uint32_t offset, xoffset, left, j;
SectionRef S, xS;
const char *name;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&opl, '\0', sizeof(struct objc_property_list32));
if (left < sizeof(struct objc_property_list32)) {
memcpy(&opl, r, left);
outs() << " (objc_property_list entends past the end of the section)\n";
} else
memcpy(&opl, r, sizeof(struct objc_property_list32));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(opl);
outs() << " entsize " << opl.entsize << "\n";
outs() << " count " << opl.count << "\n";
p += sizeof(struct objc_property_list32);
offset += sizeof(struct objc_property_list32);
for (j = 0; j < opl.count; j++) {
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&op, '\0', sizeof(struct objc_property32));
if (left < sizeof(struct objc_property32)) {
memcpy(&op, r, left);
outs() << " (objc_property entends past the end of the section)\n";
} else
memcpy(&op, r, sizeof(struct objc_property32));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(op);
outs() << "\t\t\t name " << format("0x%" PRIx32, op.name);
name = get_pointer_32(op.name, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << "\t\t\tattributes " << format("0x%" PRIx32, op.attributes);
name = get_pointer_32(op.attributes, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
p += sizeof(struct objc_property32);
offset += sizeof(struct objc_property32);
}
}
static void print_class_ro64_t(uint64_t p, struct DisassembleInfo *info,
bool &is_meta_class) {
struct class_ro64_t cro;
const char *r;
uint32_t offset, xoffset, left;
SectionRef S, xS;
const char *name, *sym_name;
uint64_t n_value;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr || left < sizeof(struct class_ro64_t))
return;
memset(&cro, '\0', sizeof(struct class_ro64_t));
if (left < sizeof(struct class_ro64_t)) {
memcpy(&cro, r, left);
outs() << " (class_ro_t entends past the end of the section)\n";
} else
memcpy(&cro, r, sizeof(struct class_ro64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(cro);
outs() << " flags " << format("0x%" PRIx32, cro.flags);
if (cro.flags & RO_META)
outs() << " RO_META";
if (cro.flags & RO_ROOT)
outs() << " RO_ROOT";
if (cro.flags & RO_HAS_CXX_STRUCTORS)
outs() << " RO_HAS_CXX_STRUCTORS";
outs() << "\n";
outs() << " instanceStart " << cro.instanceStart << "\n";
outs() << " instanceSize " << cro.instanceSize << "\n";
outs() << " reserved " << format("0x%" PRIx32, cro.reserved)
<< "\n";
outs() << " ivarLayout " << format("0x%" PRIx64, cro.ivarLayout)
<< "\n";
print_layout_map64(cro.ivarLayout, info);
outs() << " name ";
sym_name = get_symbol_64(offset + offsetof(struct class_ro64_t, name), S,
info, n_value, cro.name);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (cro.name != 0)
outs() << " + " << format("0x%" PRIx64, cro.name);
} else
outs() << format("0x%" PRIx64, cro.name);
name = get_pointer_64(cro.name + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << " baseMethods ";
sym_name = get_symbol_64(offset + offsetof(struct class_ro64_t, baseMethods),
S, info, n_value, cro.baseMethods);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (cro.baseMethods != 0)
outs() << " + " << format("0x%" PRIx64, cro.baseMethods);
} else
outs() << format("0x%" PRIx64, cro.baseMethods);
outs() << " (struct method_list_t *)\n";
if (cro.baseMethods + n_value != 0)
print_method_list64_t(cro.baseMethods + n_value, info, "");
outs() << " baseProtocols ";
sym_name =
get_symbol_64(offset + offsetof(struct class_ro64_t, baseProtocols), S,
info, n_value, cro.baseProtocols);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (cro.baseProtocols != 0)
outs() << " + " << format("0x%" PRIx64, cro.baseProtocols);
} else
outs() << format("0x%" PRIx64, cro.baseProtocols);
outs() << "\n";
if (cro.baseProtocols + n_value != 0)
print_protocol_list64_t(cro.baseProtocols + n_value, info);
outs() << " ivars ";
sym_name = get_symbol_64(offset + offsetof(struct class_ro64_t, ivars), S,
info, n_value, cro.ivars);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (cro.ivars != 0)
outs() << " + " << format("0x%" PRIx64, cro.ivars);
} else
outs() << format("0x%" PRIx64, cro.ivars);
outs() << "\n";
if (cro.ivars + n_value != 0)
print_ivar_list64_t(cro.ivars + n_value, info);
outs() << " weakIvarLayout ";
sym_name =
get_symbol_64(offset + offsetof(struct class_ro64_t, weakIvarLayout), S,
info, n_value, cro.weakIvarLayout);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (cro.weakIvarLayout != 0)
outs() << " + " << format("0x%" PRIx64, cro.weakIvarLayout);
} else
outs() << format("0x%" PRIx64, cro.weakIvarLayout);
outs() << "\n";
print_layout_map64(cro.weakIvarLayout + n_value, info);
outs() << " baseProperties ";
sym_name =
get_symbol_64(offset + offsetof(struct class_ro64_t, baseProperties), S,
info, n_value, cro.baseProperties);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (cro.baseProperties != 0)
outs() << " + " << format("0x%" PRIx64, cro.baseProperties);
} else
outs() << format("0x%" PRIx64, cro.baseProperties);
outs() << "\n";
if (cro.baseProperties + n_value != 0)
print_objc_property_list64(cro.baseProperties + n_value, info);
is_meta_class = (cro.flags & RO_META) ? true : false;
}
static void print_class_ro32_t(uint32_t p, struct DisassembleInfo *info,
bool &is_meta_class) {
struct class_ro32_t cro;
const char *r;
uint32_t offset, xoffset, left;
SectionRef S, xS;
const char *name;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&cro, '\0', sizeof(struct class_ro32_t));
if (left < sizeof(struct class_ro32_t)) {
memcpy(&cro, r, left);
outs() << " (class_ro_t entends past the end of the section)\n";
} else
memcpy(&cro, r, sizeof(struct class_ro32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(cro);
outs() << " flags " << format("0x%" PRIx32, cro.flags);
if (cro.flags & RO_META)
outs() << " RO_META";
if (cro.flags & RO_ROOT)
outs() << " RO_ROOT";
if (cro.flags & RO_HAS_CXX_STRUCTORS)
outs() << " RO_HAS_CXX_STRUCTORS";
outs() << "\n";
outs() << " instanceStart " << cro.instanceStart << "\n";
outs() << " instanceSize " << cro.instanceSize << "\n";
outs() << " ivarLayout " << format("0x%" PRIx32, cro.ivarLayout)
<< "\n";
print_layout_map32(cro.ivarLayout, info);
outs() << " name " << format("0x%" PRIx32, cro.name);
name = get_pointer_32(cro.name, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << " baseMethods "
<< format("0x%" PRIx32, cro.baseMethods)
<< " (struct method_list_t *)\n";
if (cro.baseMethods != 0)
print_method_list32_t(cro.baseMethods, info, "");
outs() << " baseProtocols "
<< format("0x%" PRIx32, cro.baseProtocols) << "\n";
if (cro.baseProtocols != 0)
print_protocol_list32_t(cro.baseProtocols, info);
outs() << " ivars " << format("0x%" PRIx32, cro.ivars)
<< "\n";
if (cro.ivars != 0)
print_ivar_list32_t(cro.ivars, info);
outs() << " weakIvarLayout "
<< format("0x%" PRIx32, cro.weakIvarLayout) << "\n";
print_layout_map32(cro.weakIvarLayout, info);
outs() << " baseProperties "
<< format("0x%" PRIx32, cro.baseProperties) << "\n";
if (cro.baseProperties != 0)
print_objc_property_list32(cro.baseProperties, info);
is_meta_class = (cro.flags & RO_META) ? true : false;
}
static void print_class64_t(uint64_t p, struct DisassembleInfo *info) {
struct class64_t c;
const char *r;
uint32_t offset, left;
SectionRef S;
const char *name;
uint64_t isa_n_value, n_value;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr || left < sizeof(struct class64_t))
return;
memset(&c, '\0', sizeof(struct class64_t));
if (left < sizeof(struct class64_t)) {
memcpy(&c, r, left);
outs() << " (class_t entends past the end of the section)\n";
} else
memcpy(&c, r, sizeof(struct class64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(c);
outs() << " isa " << format("0x%" PRIx64, c.isa);
name = get_symbol_64(offset + offsetof(struct class64_t, isa), S, info,
isa_n_value, c.isa);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " superclass " << format("0x%" PRIx64, c.superclass);
name = get_symbol_64(offset + offsetof(struct class64_t, superclass), S, info,
n_value, c.superclass);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " cache " << format("0x%" PRIx64, c.cache);
name = get_symbol_64(offset + offsetof(struct class64_t, cache), S, info,
n_value, c.cache);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " vtable " << format("0x%" PRIx64, c.vtable);
name = get_symbol_64(offset + offsetof(struct class64_t, vtable), S, info,
n_value, c.vtable);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
name = get_symbol_64(offset + offsetof(struct class64_t, data), S, info,
n_value, c.data);
outs() << " data ";
if (n_value != 0) {
if (info->verbose && name != nullptr)
outs() << name;
else
outs() << format("0x%" PRIx64, n_value);
if (c.data != 0)
outs() << " + " << format("0x%" PRIx64, c.data);
} else
outs() << format("0x%" PRIx64, c.data);
outs() << " (struct class_ro_t *)";
// This is a Swift class if some of the low bits of the pointer are set.
if ((c.data + n_value) & 0x7)
outs() << " Swift class";
outs() << "\n";
bool is_meta_class;
print_class_ro64_t((c.data + n_value) & ~0x7, info, is_meta_class);
if (is_meta_class == false) {
outs() << "Meta Class\n";
print_class64_t(c.isa + isa_n_value, info);
}
}
static void print_class32_t(uint32_t p, struct DisassembleInfo *info) {
struct class32_t c;
const char *r;
uint32_t offset, left;
SectionRef S;
const char *name;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&c, '\0', sizeof(struct class32_t));
if (left < sizeof(struct class32_t)) {
memcpy(&c, r, left);
outs() << " (class_t entends past the end of the section)\n";
} else
memcpy(&c, r, sizeof(struct class32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(c);
outs() << " isa " << format("0x%" PRIx32, c.isa);
name =
get_symbol_32(offset + offsetof(struct class32_t, isa), S, info, c.isa);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " superclass " << format("0x%" PRIx32, c.superclass);
name = get_symbol_32(offset + offsetof(struct class32_t, superclass), S, info,
c.superclass);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " cache " << format("0x%" PRIx32, c.cache);
name = get_symbol_32(offset + offsetof(struct class32_t, cache), S, info,
c.cache);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " vtable " << format("0x%" PRIx32, c.vtable);
name = get_symbol_32(offset + offsetof(struct class32_t, vtable), S, info,
c.vtable);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
name =
get_symbol_32(offset + offsetof(struct class32_t, data), S, info, c.data);
outs() << " data " << format("0x%" PRIx32, c.data)
<< " (struct class_ro_t *)";
// This is a Swift class if some of the low bits of the pointer are set.
if (c.data & 0x3)
outs() << " Swift class";
outs() << "\n";
bool is_meta_class;
print_class_ro32_t(c.data & ~0x3, info, is_meta_class);
if (is_meta_class == false) {
outs() << "Meta Class\n";
print_class32_t(c.isa, info);
}
}
static void print_objc_class_t(struct objc_class_t *objc_class,
struct DisassembleInfo *info) {
uint32_t offset, left, xleft;
const char *name, *p, *ivar_list;
SectionRef S;
int32_t i;
struct objc_ivar_list_t objc_ivar_list;
struct objc_ivar_t ivar;
outs() << "\t\t isa " << format("0x%08" PRIx32, objc_class->isa);
if (info->verbose && CLS_GETINFO(objc_class, CLS_META)) {
name = get_pointer_32(objc_class->isa, offset, left, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", left, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t super_class "
<< format("0x%08" PRIx32, objc_class->super_class);
if (info->verbose) {
name = get_pointer_32(objc_class->super_class, offset, left, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", left, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t\t name " << format("0x%08" PRIx32, objc_class->name);
if (info->verbose) {
name = get_pointer_32(objc_class->name, offset, left, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", left, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t\t version " << format("0x%08" PRIx32, objc_class->version)
<< "\n";
outs() << "\t\t info " << format("0x%08" PRIx32, objc_class->info);
if (info->verbose) {
if (CLS_GETINFO(objc_class, CLS_CLASS))
outs() << " CLS_CLASS";
else if (CLS_GETINFO(objc_class, CLS_META))
outs() << " CLS_META";
}
outs() << "\n";
outs() << "\t instance_size "
<< format("0x%08" PRIx32, objc_class->instance_size) << "\n";
p = get_pointer_32(objc_class->ivars, offset, left, S, info, true);
outs() << "\t\t ivars " << format("0x%08" PRIx32, objc_class->ivars);
if (p != nullptr) {
if (left > sizeof(struct objc_ivar_list_t)) {
outs() << "\n";
memcpy(&objc_ivar_list, p, sizeof(struct objc_ivar_list_t));
} else {
outs() << " (entends past the end of the section)\n";
memset(&objc_ivar_list, '\0', sizeof(struct objc_ivar_list_t));
memcpy(&objc_ivar_list, p, left);
}
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(objc_ivar_list);
outs() << "\t\t ivar_count " << objc_ivar_list.ivar_count << "\n";
ivar_list = p + sizeof(struct objc_ivar_list_t);
for (i = 0; i < objc_ivar_list.ivar_count; i++) {
if ((i + 1) * sizeof(struct objc_ivar_t) > left) {
outs() << "\t\t remaining ivar's extend past the of the section\n";
break;
}
memcpy(&ivar, ivar_list + i * sizeof(struct objc_ivar_t),
sizeof(struct objc_ivar_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(ivar);
outs() << "\t\t\tivar_name " << format("0x%08" PRIx32, ivar.ivar_name);
if (info->verbose) {
name = get_pointer_32(ivar.ivar_name, offset, xleft, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", xleft, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t\t\tivar_type " << format("0x%08" PRIx32, ivar.ivar_type);
if (info->verbose) {
name = get_pointer_32(ivar.ivar_type, offset, xleft, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", xleft, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t\t ivar_offset "
<< format("0x%08" PRIx32, ivar.ivar_offset) << "\n";
}
} else {
outs() << " (not in an __OBJC section)\n";
}
outs() << "\t\t methods " << format("0x%08" PRIx32, objc_class->methodLists);
if (print_method_list(objc_class->methodLists, info))
outs() << " (not in an __OBJC section)\n";
outs() << "\t\t cache " << format("0x%08" PRIx32, objc_class->cache)
<< "\n";
outs() << "\t\tprotocols " << format("0x%08" PRIx32, objc_class->protocols);
if (print_protocol_list(objc_class->protocols, 16, info))
outs() << " (not in an __OBJC section)\n";
}
static void print_objc_objc_category_t(struct objc_category_t *objc_category,
struct DisassembleInfo *info) {
uint32_t offset, left;
const char *name;
SectionRef S;
outs() << "\t category name "
<< format("0x%08" PRIx32, objc_category->category_name);
if (info->verbose) {
name = get_pointer_32(objc_category->category_name, offset, left, S, info,
true);
if (name != nullptr)
outs() << format(" %.*s", left, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t\t class name "
<< format("0x%08" PRIx32, objc_category->class_name);
if (info->verbose) {
name =
get_pointer_32(objc_category->class_name, offset, left, S, info, true);
if (name != nullptr)
outs() << format(" %.*s", left, name);
else
outs() << " (not in an __OBJC section)";
}
outs() << "\n";
outs() << "\t instance methods "
<< format("0x%08" PRIx32, objc_category->instance_methods);
if (print_method_list(objc_category->instance_methods, info))
outs() << " (not in an __OBJC section)\n";
outs() << "\t class methods "
<< format("0x%08" PRIx32, objc_category->class_methods);
if (print_method_list(objc_category->class_methods, info))
outs() << " (not in an __OBJC section)\n";
}
static void print_category64_t(uint64_t p, struct DisassembleInfo *info) {
struct category64_t c;
const char *r;
uint32_t offset, xoffset, left;
SectionRef S, xS;
const char *name, *sym_name;
uint64_t n_value;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&c, '\0', sizeof(struct category64_t));
if (left < sizeof(struct category64_t)) {
memcpy(&c, r, left);
outs() << " (category_t entends past the end of the section)\n";
} else
memcpy(&c, r, sizeof(struct category64_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(c);
outs() << " name ";
sym_name = get_symbol_64(offset + offsetof(struct category64_t, name), S,
info, n_value, c.name);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (c.name != 0)
outs() << " + " << format("0x%" PRIx64, c.name);
} else
outs() << format("0x%" PRIx64, c.name);
name = get_pointer_64(c.name + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
outs() << " cls ";
sym_name = get_symbol_64(offset + offsetof(struct category64_t, cls), S, info,
n_value, c.cls);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (c.cls != 0)
outs() << " + " << format("0x%" PRIx64, c.cls);
} else
outs() << format("0x%" PRIx64, c.cls);
outs() << "\n";
if (c.cls + n_value != 0)
print_class64_t(c.cls + n_value, info);
outs() << " instanceMethods ";
sym_name =
get_symbol_64(offset + offsetof(struct category64_t, instanceMethods), S,
info, n_value, c.instanceMethods);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (c.instanceMethods != 0)
outs() << " + " << format("0x%" PRIx64, c.instanceMethods);
} else
outs() << format("0x%" PRIx64, c.instanceMethods);
outs() << "\n";
if (c.instanceMethods + n_value != 0)
print_method_list64_t(c.instanceMethods + n_value, info, "");
outs() << " classMethods ";
sym_name = get_symbol_64(offset + offsetof(struct category64_t, classMethods),
S, info, n_value, c.classMethods);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (c.classMethods != 0)
outs() << " + " << format("0x%" PRIx64, c.classMethods);
} else
outs() << format("0x%" PRIx64, c.classMethods);
outs() << "\n";
if (c.classMethods + n_value != 0)
print_method_list64_t(c.classMethods + n_value, info, "");
outs() << " protocols ";
sym_name = get_symbol_64(offset + offsetof(struct category64_t, protocols), S,
info, n_value, c.protocols);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (c.protocols != 0)
outs() << " + " << format("0x%" PRIx64, c.protocols);
} else
outs() << format("0x%" PRIx64, c.protocols);
outs() << "\n";
if (c.protocols + n_value != 0)
print_protocol_list64_t(c.protocols + n_value, info);
outs() << "instanceProperties ";
sym_name =
get_symbol_64(offset + offsetof(struct category64_t, instanceProperties),
S, info, n_value, c.instanceProperties);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (c.instanceProperties != 0)
outs() << " + " << format("0x%" PRIx64, c.instanceProperties);
} else
outs() << format("0x%" PRIx64, c.instanceProperties);
outs() << "\n";
if (c.instanceProperties + n_value != 0)
print_objc_property_list64(c.instanceProperties + n_value, info);
}
static void print_category32_t(uint32_t p, struct DisassembleInfo *info) {
struct category32_t c;
const char *r;
uint32_t offset, left;
SectionRef S, xS;
const char *name;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&c, '\0', sizeof(struct category32_t));
if (left < sizeof(struct category32_t)) {
memcpy(&c, r, left);
outs() << " (category_t entends past the end of the section)\n";
} else
memcpy(&c, r, sizeof(struct category32_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(c);
outs() << " name " << format("0x%" PRIx32, c.name);
name = get_symbol_32(offset + offsetof(struct category32_t, name), S, info,
c.name);
if (name != NULL)
outs() << " " << name;
outs() << "\n";
outs() << " cls " << format("0x%" PRIx32, c.cls) << "\n";
if (c.cls != 0)
print_class32_t(c.cls, info);
outs() << " instanceMethods " << format("0x%" PRIx32, c.instanceMethods)
<< "\n";
if (c.instanceMethods != 0)
print_method_list32_t(c.instanceMethods, info, "");
outs() << " classMethods " << format("0x%" PRIx32, c.classMethods)
<< "\n";
if (c.classMethods != 0)
print_method_list32_t(c.classMethods, info, "");
outs() << " protocols " << format("0x%" PRIx32, c.protocols) << "\n";
if (c.protocols != 0)
print_protocol_list32_t(c.protocols, info);
outs() << "instanceProperties " << format("0x%" PRIx32, c.instanceProperties)
<< "\n";
if (c.instanceProperties != 0)
print_objc_property_list32(c.instanceProperties, info);
}
static void print_message_refs64(SectionRef S, struct DisassembleInfo *info) {
uint32_t i, left, offset, xoffset;
uint64_t p, n_value;
struct message_ref64 mr;
const char *name, *sym_name;
const char *r;
SectionRef xS;
if (S == SectionRef())
return;
StringRef SectName;
S.getName(SectName);
DataRefImpl Ref = S.getRawDataRefImpl();
StringRef SegName = info->O->getSectionFinalSegmentName(Ref);
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
offset = 0;
for (i = 0; i < S.getSize(); i += sizeof(struct message_ref64)) {
p = S.getAddress() + i;
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&mr, '\0', sizeof(struct message_ref64));
if (left < sizeof(struct message_ref64)) {
memcpy(&mr, r, left);
outs() << " (message_ref entends past the end of the section)\n";
} else
memcpy(&mr, r, sizeof(struct message_ref64));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(mr);
outs() << " imp ";
name = get_symbol_64(offset + offsetof(struct message_ref64, imp), S, info,
n_value, mr.imp);
if (n_value != 0) {
outs() << format("0x%" PRIx64, n_value) << " ";
if (mr.imp != 0)
outs() << "+ " << format("0x%" PRIx64, mr.imp) << " ";
} else
outs() << format("0x%" PRIx64, mr.imp) << " ";
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " sel ";
sym_name = get_symbol_64(offset + offsetof(struct message_ref64, sel), S,
info, n_value, mr.sel);
if (n_value != 0) {
if (info->verbose && sym_name != nullptr)
outs() << sym_name;
else
outs() << format("0x%" PRIx64, n_value);
if (mr.sel != 0)
outs() << " + " << format("0x%" PRIx64, mr.sel);
} else
outs() << format("0x%" PRIx64, mr.sel);
name = get_pointer_64(mr.sel + n_value, xoffset, left, xS, info);
if (name != nullptr)
outs() << format(" %.*s", left, name);
outs() << "\n";
offset += sizeof(struct message_ref64);
}
}
static void print_message_refs32(SectionRef S, struct DisassembleInfo *info) {
uint32_t i, left, offset, xoffset, p;
struct message_ref32 mr;
const char *name, *r;
SectionRef xS;
if (S == SectionRef())
return;
StringRef SectName;
S.getName(SectName);
DataRefImpl Ref = S.getRawDataRefImpl();
StringRef SegName = info->O->getSectionFinalSegmentName(Ref);
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
offset = 0;
for (i = 0; i < S.getSize(); i += sizeof(struct message_ref64)) {
p = S.getAddress() + i;
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&mr, '\0', sizeof(struct message_ref32));
if (left < sizeof(struct message_ref32)) {
memcpy(&mr, r, left);
outs() << " (message_ref entends past the end of the section)\n";
} else
memcpy(&mr, r, sizeof(struct message_ref32));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(mr);
outs() << " imp " << format("0x%" PRIx32, mr.imp);
name = get_symbol_32(offset + offsetof(struct message_ref32, imp), S, info,
mr.imp);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
outs() << " sel " << format("0x%" PRIx32, mr.sel);
name = get_pointer_32(mr.sel, xoffset, left, xS, info);
if (name != nullptr)
outs() << " " << name;
outs() << "\n";
offset += sizeof(struct message_ref32);
}
}
static void print_image_info64(SectionRef S, struct DisassembleInfo *info) {
uint32_t left, offset, swift_version;
uint64_t p;
struct objc_image_info64 o;
const char *r;
StringRef SectName;
S.getName(SectName);
DataRefImpl Ref = S.getRawDataRefImpl();
StringRef SegName = info->O->getSectionFinalSegmentName(Ref);
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
p = S.getAddress();
r = get_pointer_64(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&o, '\0', sizeof(struct objc_image_info64));
if (left < sizeof(struct objc_image_info64)) {
memcpy(&o, r, left);
outs() << " (objc_image_info entends past the end of the section)\n";
} else
memcpy(&o, r, sizeof(struct objc_image_info64));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(o);
outs() << " version " << o.version << "\n";
outs() << " flags " << format("0x%" PRIx32, o.flags);
if (o.flags & OBJC_IMAGE_IS_REPLACEMENT)
outs() << " OBJC_IMAGE_IS_REPLACEMENT";
if (o.flags & OBJC_IMAGE_SUPPORTS_GC)
outs() << " OBJC_IMAGE_SUPPORTS_GC";
swift_version = (o.flags >> 8) & 0xff;
if (swift_version != 0) {
if (swift_version == 1)
outs() << " Swift 1.0";
else if (swift_version == 2)
outs() << " Swift 1.1";
else
outs() << " unknown future Swift version (" << swift_version << ")";
}
outs() << "\n";
}
static void print_image_info32(SectionRef S, struct DisassembleInfo *info) {
uint32_t left, offset, swift_version, p;
struct objc_image_info32 o;
const char *r;
StringRef SectName;
S.getName(SectName);
DataRefImpl Ref = S.getRawDataRefImpl();
StringRef SegName = info->O->getSectionFinalSegmentName(Ref);
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
p = S.getAddress();
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&o, '\0', sizeof(struct objc_image_info32));
if (left < sizeof(struct objc_image_info32)) {
memcpy(&o, r, left);
outs() << " (objc_image_info entends past the end of the section)\n";
} else
memcpy(&o, r, sizeof(struct objc_image_info32));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(o);
outs() << " version " << o.version << "\n";
outs() << " flags " << format("0x%" PRIx32, o.flags);
if (o.flags & OBJC_IMAGE_IS_REPLACEMENT)
outs() << " OBJC_IMAGE_IS_REPLACEMENT";
if (o.flags & OBJC_IMAGE_SUPPORTS_GC)
outs() << " OBJC_IMAGE_SUPPORTS_GC";
swift_version = (o.flags >> 8) & 0xff;
if (swift_version != 0) {
if (swift_version == 1)
outs() << " Swift 1.0";
else if (swift_version == 2)
outs() << " Swift 1.1";
else
outs() << " unknown future Swift version (" << swift_version << ")";
}
outs() << "\n";
}
static void print_image_info(SectionRef S, struct DisassembleInfo *info) {
uint32_t left, offset, p;
struct imageInfo_t o;
const char *r;
StringRef SectName;
S.getName(SectName);
DataRefImpl Ref = S.getRawDataRefImpl();
StringRef SegName = info->O->getSectionFinalSegmentName(Ref);
outs() << "Contents of (" << SegName << "," << SectName << ") section\n";
p = S.getAddress();
r = get_pointer_32(p, offset, left, S, info);
if (r == nullptr)
return;
memset(&o, '\0', sizeof(struct imageInfo_t));
if (left < sizeof(struct imageInfo_t)) {
memcpy(&o, r, left);
outs() << " (imageInfo entends past the end of the section)\n";
} else
memcpy(&o, r, sizeof(struct imageInfo_t));
if (info->O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(o);
outs() << " version " << o.version << "\n";
outs() << " flags " << format("0x%" PRIx32, o.flags);
if (o.flags & 0x1)
outs() << " F&C";
if (o.flags & 0x2)
outs() << " GC";
if (o.flags & 0x4)
outs() << " GC-only";
else
outs() << " RR";
outs() << "\n";
}
static void printObjc2_64bit_MetaData(MachOObjectFile *O, bool verbose) {
SymbolAddressMap AddrMap;
if (verbose)
CreateSymbolAddressMap(O, &AddrMap);
std::vector<SectionRef> Sections;
for (const SectionRef &Section : O->sections()) {
StringRef SectName;
Section.getName(SectName);
Sections.push_back(Section);
}
struct DisassembleInfo info;
// Set up the block of info used by the Symbolizer call backs.
info.verbose = verbose;
info.O = O;
info.AddrMap = &AddrMap;
info.Sections = &Sections;
info.class_name = nullptr;
info.selector_name = nullptr;
info.method = nullptr;
info.demangled_name = nullptr;
info.bindtable = nullptr;
info.adrp_addr = 0;
info.adrp_inst = 0;
const SectionRef CL = get_section(O, "__OBJC2", "__class_list");
if (CL != SectionRef()) {
info.S = CL;
walk_pointer_list_64("class", CL, O, &info, print_class64_t);
} else {
const SectionRef CL = get_section(O, "__DATA", "__objc_classlist");
info.S = CL;
walk_pointer_list_64("class", CL, O, &info, print_class64_t);
}
const SectionRef CR = get_section(O, "__OBJC2", "__class_refs");
if (CR != SectionRef()) {
info.S = CR;
walk_pointer_list_64("class refs", CR, O, &info, nullptr);
} else {
const SectionRef CR = get_section(O, "__DATA", "__objc_classrefs");
info.S = CR;
walk_pointer_list_64("class refs", CR, O, &info, nullptr);
}
const SectionRef SR = get_section(O, "__OBJC2", "__super_refs");
if (SR != SectionRef()) {
info.S = SR;
walk_pointer_list_64("super refs", SR, O, &info, nullptr);
} else {
const SectionRef SR = get_section(O, "__DATA", "__objc_superrefs");
info.S = SR;
walk_pointer_list_64("super refs", SR, O, &info, nullptr);
}
const SectionRef CA = get_section(O, "__OBJC2", "__category_list");
if (CA != SectionRef()) {
info.S = CA;
walk_pointer_list_64("category", CA, O, &info, print_category64_t);
} else {
const SectionRef CA = get_section(O, "__DATA", "__objc_catlist");
info.S = CA;
walk_pointer_list_64("category", CA, O, &info, print_category64_t);
}
const SectionRef PL = get_section(O, "__OBJC2", "__protocol_list");
if (PL != SectionRef()) {
info.S = PL;
walk_pointer_list_64("protocol", PL, O, &info, nullptr);
} else {
const SectionRef PL = get_section(O, "__DATA", "__objc_protolist");
info.S = PL;
walk_pointer_list_64("protocol", PL, O, &info, nullptr);
}
const SectionRef MR = get_section(O, "__OBJC2", "__message_refs");
if (MR != SectionRef()) {
info.S = MR;
print_message_refs64(MR, &info);
} else {
const SectionRef MR = get_section(O, "__DATA", "__objc_msgrefs");
info.S = MR;
print_message_refs64(MR, &info);
}
const SectionRef II = get_section(O, "__OBJC2", "__image_info");
if (II != SectionRef()) {
info.S = II;
print_image_info64(II, &info);
} else {
const SectionRef II = get_section(O, "__DATA", "__objc_imageinfo");
info.S = II;
print_image_info64(II, &info);
}
if (info.bindtable != nullptr)
delete info.bindtable;
}
static void printObjc2_32bit_MetaData(MachOObjectFile *O, bool verbose) {
SymbolAddressMap AddrMap;
if (verbose)
CreateSymbolAddressMap(O, &AddrMap);
std::vector<SectionRef> Sections;
for (const SectionRef &Section : O->sections()) {
StringRef SectName;
Section.getName(SectName);
Sections.push_back(Section);
}
struct DisassembleInfo info;
// Set up the block of info used by the Symbolizer call backs.
info.verbose = verbose;
info.O = O;
info.AddrMap = &AddrMap;
info.Sections = &Sections;
info.class_name = nullptr;
info.selector_name = nullptr;
info.method = nullptr;
info.demangled_name = nullptr;
info.bindtable = nullptr;
info.adrp_addr = 0;
info.adrp_inst = 0;
const SectionRef CL = get_section(O, "__OBJC2", "__class_list");
if (CL != SectionRef()) {
info.S = CL;
walk_pointer_list_32("class", CL, O, &info, print_class32_t);
} else {
const SectionRef CL = get_section(O, "__DATA", "__objc_classlist");
info.S = CL;
walk_pointer_list_32("class", CL, O, &info, print_class32_t);
}
const SectionRef CR = get_section(O, "__OBJC2", "__class_refs");
if (CR != SectionRef()) {
info.S = CR;
walk_pointer_list_32("class refs", CR, O, &info, nullptr);
} else {
const SectionRef CR = get_section(O, "__DATA", "__objc_classrefs");
info.S = CR;
walk_pointer_list_32("class refs", CR, O, &info, nullptr);
}
const SectionRef SR = get_section(O, "__OBJC2", "__super_refs");
if (SR != SectionRef()) {
info.S = SR;
walk_pointer_list_32("super refs", SR, O, &info, nullptr);
} else {
const SectionRef SR = get_section(O, "__DATA", "__objc_superrefs");
info.S = SR;
walk_pointer_list_32("super refs", SR, O, &info, nullptr);
}
const SectionRef CA = get_section(O, "__OBJC2", "__category_list");
if (CA != SectionRef()) {
info.S = CA;
walk_pointer_list_32("category", CA, O, &info, print_category32_t);
} else {
const SectionRef CA = get_section(O, "__DATA", "__objc_catlist");
info.S = CA;
walk_pointer_list_32("category", CA, O, &info, print_category32_t);
}
const SectionRef PL = get_section(O, "__OBJC2", "__protocol_list");
if (PL != SectionRef()) {
info.S = PL;
walk_pointer_list_32("protocol", PL, O, &info, nullptr);
} else {
const SectionRef PL = get_section(O, "__DATA", "__objc_protolist");
info.S = PL;
walk_pointer_list_32("protocol", PL, O, &info, nullptr);
}
const SectionRef MR = get_section(O, "__OBJC2", "__message_refs");
if (MR != SectionRef()) {
info.S = MR;
print_message_refs32(MR, &info);
} else {
const SectionRef MR = get_section(O, "__DATA", "__objc_msgrefs");
info.S = MR;
print_message_refs32(MR, &info);
}
const SectionRef II = get_section(O, "__OBJC2", "__image_info");
if (II != SectionRef()) {
info.S = II;
print_image_info32(II, &info);
} else {
const SectionRef II = get_section(O, "__DATA", "__objc_imageinfo");
info.S = II;
print_image_info32(II, &info);
}
}
static bool printObjc1_32bit_MetaData(MachOObjectFile *O, bool verbose) {
uint32_t i, j, p, offset, xoffset, left, defs_left, def;
const char *r, *name, *defs;
struct objc_module_t module;
SectionRef S, xS;
struct objc_symtab_t symtab;
struct objc_class_t objc_class;
struct objc_category_t objc_category;
outs() << "Objective-C segment\n";
S = get_section(O, "__OBJC", "__module_info");
if (S == SectionRef())
return false;
SymbolAddressMap AddrMap;
if (verbose)
CreateSymbolAddressMap(O, &AddrMap);
std::vector<SectionRef> Sections;
for (const SectionRef &Section : O->sections()) {
StringRef SectName;
Section.getName(SectName);
Sections.push_back(Section);
}
struct DisassembleInfo info;
// Set up the block of info used by the Symbolizer call backs.
info.verbose = verbose;
info.O = O;
info.AddrMap = &AddrMap;
info.Sections = &Sections;
info.class_name = nullptr;
info.selector_name = nullptr;
info.method = nullptr;
info.demangled_name = nullptr;
info.bindtable = nullptr;
info.adrp_addr = 0;
info.adrp_inst = 0;
for (i = 0; i < S.getSize(); i += sizeof(struct objc_module_t)) {
p = S.getAddress() + i;
r = get_pointer_32(p, offset, left, S, &info, true);
if (r == nullptr)
return true;
memset(&module, '\0', sizeof(struct objc_module_t));
if (left < sizeof(struct objc_module_t)) {
memcpy(&module, r, left);
outs() << " (module extends past end of __module_info section)\n";
} else
memcpy(&module, r, sizeof(struct objc_module_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(module);
outs() << "Module " << format("0x%" PRIx32, p) << "\n";
outs() << " version " << module.version << "\n";
outs() << " size " << module.size << "\n";
outs() << " name ";
name = get_pointer_32(module.name, xoffset, left, xS, &info, true);
if (name != nullptr)
outs() << format("%.*s", left, name);
else
outs() << format("0x%08" PRIx32, module.name)
<< "(not in an __OBJC section)";
outs() << "\n";
r = get_pointer_32(module.symtab, xoffset, left, xS, &info, true);
if (module.symtab == 0 || r == nullptr) {
outs() << " symtab " << format("0x%08" PRIx32, module.symtab)
<< " (not in an __OBJC section)\n";
continue;
}
outs() << " symtab " << format("0x%08" PRIx32, module.symtab) << "\n";
memset(&symtab, '\0', sizeof(struct objc_symtab_t));
defs_left = 0;
defs = nullptr;
if (left < sizeof(struct objc_symtab_t)) {
memcpy(&symtab, r, left);
outs() << "\tsymtab extends past end of an __OBJC section)\n";
} else {
memcpy(&symtab, r, sizeof(struct objc_symtab_t));
if (left > sizeof(struct objc_symtab_t)) {
defs_left = left - sizeof(struct objc_symtab_t);
defs = r + sizeof(struct objc_symtab_t);
}
}
if (O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(symtab);
outs() << "\tsel_ref_cnt " << symtab.sel_ref_cnt << "\n";
r = get_pointer_32(symtab.refs, xoffset, left, xS, &info, true);
outs() << "\trefs " << format("0x%08" PRIx32, symtab.refs);
if (r == nullptr)
outs() << " (not in an __OBJC section)";
outs() << "\n";
outs() << "\tcls_def_cnt " << symtab.cls_def_cnt << "\n";
outs() << "\tcat_def_cnt " << symtab.cat_def_cnt << "\n";
if (symtab.cls_def_cnt > 0)
outs() << "\tClass Definitions\n";
for (j = 0; j < symtab.cls_def_cnt; j++) {
if ((j + 1) * sizeof(uint32_t) > defs_left) {
outs() << "\t(remaining class defs entries entends past the end of the "
<< "section)\n";
break;
}
memcpy(&def, defs + j * sizeof(uint32_t), sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(def);
r = get_pointer_32(def, xoffset, left, xS, &info, true);
outs() << "\tdefs[" << j << "] " << format("0x%08" PRIx32, def);
if (r != nullptr) {
if (left > sizeof(struct objc_class_t)) {
outs() << "\n";
memcpy(&objc_class, r, sizeof(struct objc_class_t));
} else {
outs() << " (entends past the end of the section)\n";
memset(&objc_class, '\0', sizeof(struct objc_class_t));
memcpy(&objc_class, r, left);
}
if (O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(objc_class);
print_objc_class_t(&objc_class, &info);
} else {
outs() << "(not in an __OBJC section)\n";
}
if (CLS_GETINFO(&objc_class, CLS_CLASS)) {
outs() << "\tMeta Class";
r = get_pointer_32(objc_class.isa, xoffset, left, xS, &info, true);
if (r != nullptr) {
if (left > sizeof(struct objc_class_t)) {
outs() << "\n";
memcpy(&objc_class, r, sizeof(struct objc_class_t));
} else {
outs() << " (entends past the end of the section)\n";
memset(&objc_class, '\0', sizeof(struct objc_class_t));
memcpy(&objc_class, r, left);
}
if (O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(objc_class);
print_objc_class_t(&objc_class, &info);
} else {
outs() << "(not in an __OBJC section)\n";
}
}
}
if (symtab.cat_def_cnt > 0)
outs() << "\tCategory Definitions\n";
for (j = 0; j < symtab.cat_def_cnt; j++) {
if ((j + symtab.cls_def_cnt + 1) * sizeof(uint32_t) > defs_left) {
outs() << "\t(remaining category defs entries entends past the end of "
<< "the section)\n";
break;
}
memcpy(&def, defs + (j + symtab.cls_def_cnt) * sizeof(uint32_t),
sizeof(uint32_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
sys::swapByteOrder(def);
r = get_pointer_32(def, xoffset, left, xS, &info, true);
outs() << "\tdefs[" << j + symtab.cls_def_cnt << "] "
<< format("0x%08" PRIx32, def);
if (r != nullptr) {
if (left > sizeof(struct objc_category_t)) {
outs() << "\n";
memcpy(&objc_category, r, sizeof(struct objc_category_t));
} else {
outs() << " (entends past the end of the section)\n";
memset(&objc_category, '\0', sizeof(struct objc_category_t));
memcpy(&objc_category, r, left);
}
if (O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(objc_category);
print_objc_objc_category_t(&objc_category, &info);
} else {
outs() << "(not in an __OBJC section)\n";
}
}
}
const SectionRef II = get_section(O, "__OBJC", "__image_info");
if (II != SectionRef())
print_image_info(II, &info);
return true;
}
static void DumpProtocolSection(MachOObjectFile *O, const char *sect,
uint32_t size, uint32_t addr) {
SymbolAddressMap AddrMap;
CreateSymbolAddressMap(O, &AddrMap);
std::vector<SectionRef> Sections;
for (const SectionRef &Section : O->sections()) {
StringRef SectName;
Section.getName(SectName);
Sections.push_back(Section);
}
struct DisassembleInfo info;
// Set up the block of info used by the Symbolizer call backs.
info.verbose = true;
info.O = O;
info.AddrMap = &AddrMap;
info.Sections = &Sections;
info.class_name = nullptr;
info.selector_name = nullptr;
info.method = nullptr;
info.demangled_name = nullptr;
info.bindtable = nullptr;
info.adrp_addr = 0;
info.adrp_inst = 0;
const char *p;
struct objc_protocol_t protocol;
uint32_t left, paddr;
for (p = sect; p < sect + size; p += sizeof(struct objc_protocol_t)) {
memset(&protocol, '\0', sizeof(struct objc_protocol_t));
left = size - (p - sect);
if (left < sizeof(struct objc_protocol_t)) {
outs() << "Protocol extends past end of __protocol section\n";
memcpy(&protocol, p, left);
} else
memcpy(&protocol, p, sizeof(struct objc_protocol_t));
if (O->isLittleEndian() != sys::IsLittleEndianHost)
swapStruct(protocol);
paddr = addr + (p - sect);
outs() << "Protocol " << format("0x%" PRIx32, paddr);
if (print_protocol(paddr, 0, &info))
outs() << "(not in an __OBJC section)\n";
}
}
static void printObjcMetaData(MachOObjectFile *O, bool verbose) {
if (O->is64Bit())
printObjc2_64bit_MetaData(O, verbose);
else {
MachO::mach_header H;
H = O->getHeader();
if (H.cputype == MachO::CPU_TYPE_ARM)
printObjc2_32bit_MetaData(O, verbose);
else {
// This is the 32-bit non-arm cputype case. Which is normally
// the first Objective-C ABI. But it may be the case of a
// binary for the iOS simulator which is the second Objective-C
// ABI. In that case printObjc1_32bit_MetaData() will determine that
// and return false.
if (printObjc1_32bit_MetaData(O, verbose) == false)
printObjc2_32bit_MetaData(O, verbose);
}
}
}
// GuessLiteralPointer returns a string which for the item in the Mach-O file
// for the address passed in as ReferenceValue for printing as a comment with
// the instruction and also returns the corresponding type of that item
// indirectly through ReferenceType.
//
// If ReferenceValue is an address of literal cstring then a pointer to the
// cstring is returned and ReferenceType is set to
// LLVMDisassembler_ReferenceType_Out_LitPool_CstrAddr .
//
// If ReferenceValue is an address of an Objective-C CFString, Selector ref or
// Class ref that name is returned and the ReferenceType is set accordingly.
//
// Lastly, literals which are Symbol address in a literal pool are looked for
// and if found the symbol name is returned and ReferenceType is set to
// LLVMDisassembler_ReferenceType_Out_LitPool_SymAddr .
//
// If there is no item in the Mach-O file for the address passed in as
// ReferenceValue nullptr is returned and ReferenceType is unchanged.
static const char *GuessLiteralPointer(uint64_t ReferenceValue,
uint64_t ReferencePC,
uint64_t *ReferenceType,
struct DisassembleInfo *info) {
// First see if there is an external relocation entry at the ReferencePC.
uint64_t sect_addr = info->S.getAddress();
uint64_t sect_offset = ReferencePC - sect_addr;
bool reloc_found = false;
DataRefImpl Rel;
MachO::any_relocation_info RE;
bool isExtern = false;
SymbolRef Symbol;
for (const RelocationRef &Reloc : info->S.relocations()) {
uint64_t RelocOffset = Reloc.getOffset();
if (RelocOffset == sect_offset) {
Rel = Reloc.getRawDataRefImpl();
RE = info->O->getRelocation(Rel);
if (info->O->isRelocationScattered(RE))
continue;
isExtern = info->O->getPlainRelocationExternal(RE);
if (isExtern) {
symbol_iterator RelocSym = Reloc.getSymbol();
Symbol = *RelocSym;
}
reloc_found = true;
break;
}
}
// If there is an external relocation entry for a symbol in a section
// then used that symbol's value for the value of the reference.
if (reloc_found && isExtern) {
if (info->O->getAnyRelocationPCRel(RE)) {
unsigned Type = info->O->getAnyRelocationType(RE);
if (Type == MachO::X86_64_RELOC_SIGNED) {
ReferenceValue = Symbol.getValue();
}
}
}
// Look for literals such as Objective-C CFStrings refs, Selector refs,
// Message refs and Class refs.
bool classref, selref, msgref, cfstring;
uint64_t pointer_value = GuessPointerPointer(ReferenceValue, info, classref,
selref, msgref, cfstring);
if (classref && pointer_value == 0) {
// Note the ReferenceValue is a pointer into the __objc_classrefs section.
// And the pointer_value in that section is typically zero as it will be
// set by dyld as part of the "bind information".
const char *name = get_dyld_bind_info_symbolname(ReferenceValue, info);
if (name != nullptr) {
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_Class_Ref;
const char *class_name = strrchr(name, '$');
if (class_name != nullptr && class_name[1] == '_' &&
class_name[2] != '\0') {
info->class_name = class_name + 2;
return name;
}
}
}
if (classref) {
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_Class_Ref;
const char *name =
get_objc2_64bit_class_name(pointer_value, ReferenceValue, info);
if (name != nullptr)
info->class_name = name;
else
name = "bad class ref";
return name;
}
if (cfstring) {
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_CFString_Ref;
const char *name = get_objc2_64bit_cfstring_name(ReferenceValue, info);
return name;
}
if (selref && pointer_value == 0)
pointer_value = get_objc2_64bit_selref(ReferenceValue, info);
if (pointer_value != 0)
ReferenceValue = pointer_value;
const char *name = GuessCstringPointer(ReferenceValue, info);
if (name) {
if (pointer_value != 0 && selref) {
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_Selector_Ref;
info->selector_name = name;
} else if (pointer_value != 0 && msgref) {
info->class_name = nullptr;
*ReferenceType = LLVMDisassembler_ReferenceType_Out_Objc_Message_Ref;
info->selector_name = name;
} else
*ReferenceType = LLVMDisassembler_ReferenceType_Out_LitPool_CstrAddr;
return name;
}
// Lastly look for an indirect symbol with this ReferenceValue which is in
// a literal pool. If found return that symbol name.
name = GuessIndirectSymbol(ReferenceValue, info);
if (name) {
*ReferenceType = LLVMDisassembler_ReferenceType_Out_LitPool_SymAddr;
return name;
}
return nullptr;
}
// SymbolizerSymbolLookUp is the symbol lookup function passed when creating
// the Symbolizer. It looks up the ReferenceValue using the info passed via the
// pointer to the struct DisassembleInfo that was passed when MCSymbolizer
// is created and returns the symbol name that matches the ReferenceValue or
// nullptr if none. The ReferenceType is passed in for the IN type of
// reference the instruction is making from the values in defined in the header
// "llvm-c/Disassembler.h". On return the ReferenceType can set to a specific
// Out type and the ReferenceName will also be set which is added as a comment
// to the disassembled instruction.
//
#if HAVE_CXXABI_H
// If the symbol name is a C++ mangled name then the demangled name is
// returned through ReferenceName and ReferenceType is set to
// LLVMDisassembler_ReferenceType_DeMangled_Name .
#endif
//
// When this is called to get a symbol name for a branch target then the
// ReferenceType will be LLVMDisassembler_ReferenceType_In_Branch and then
// SymbolValue will be looked for in the indirect symbol table to determine if
// it is an address for a symbol stub. If so then the symbol name for that
// stub is returned indirectly through ReferenceName and then ReferenceType is
// set to LLVMDisassembler_ReferenceType_Out_SymbolStub.
//
// When this is called with an value loaded via a PC relative load then
// ReferenceType will be LLVMDisassembler_ReferenceType_In_PCrel_Load then the
// SymbolValue is checked to be an address of literal pointer, symbol pointer,
// or an Objective-C meta data reference. If so the output ReferenceType is
// set to correspond to that as well as setting the ReferenceName.
static const char *SymbolizerSymbolLookUp(void *DisInfo,
uint64_t ReferenceValue,
uint64_t *ReferenceType,
uint64_t ReferencePC,
const char **ReferenceName) {
struct DisassembleInfo *info = (struct DisassembleInfo *)DisInfo;
// If no verbose symbolic information is wanted then just return nullptr.
if (!info->verbose) {
*ReferenceName = nullptr;
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
return nullptr;
}
const char *SymbolName = GuessSymbolName(ReferenceValue, info->AddrMap);
if (*ReferenceType == LLVMDisassembler_ReferenceType_In_Branch) {
*ReferenceName = GuessIndirectSymbol(ReferenceValue, info);
if (*ReferenceName != nullptr) {
method_reference(info, ReferenceType, ReferenceName);
if (*ReferenceType != LLVMDisassembler_ReferenceType_Out_Objc_Message)
*ReferenceType = LLVMDisassembler_ReferenceType_Out_SymbolStub;
} else
#if HAVE_CXXABI_H
if (SymbolName != nullptr && strncmp(SymbolName, "__Z", 3) == 0) {
if (info->demangled_name != nullptr)
free(info->demangled_name);
int status;
info->demangled_name =
abi::__cxa_demangle(SymbolName + 1, nullptr, nullptr, &status);
if (info->demangled_name != nullptr) {
*ReferenceName = info->demangled_name;
*ReferenceType = LLVMDisassembler_ReferenceType_DeMangled_Name;
} else
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
} else
#endif
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
} else if (*ReferenceType == LLVMDisassembler_ReferenceType_In_PCrel_Load) {
*ReferenceName =
GuessLiteralPointer(ReferenceValue, ReferencePC, ReferenceType, info);
if (*ReferenceName)
method_reference(info, ReferenceType, ReferenceName);
else
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
// If this is arm64 and the reference is an adrp instruction save the
// instruction, passed in ReferenceValue and the address of the instruction
// for use later if we see and add immediate instruction.
} else if (info->O->getArch() == Triple::aarch64 &&
*ReferenceType == LLVMDisassembler_ReferenceType_In_ARM64_ADRP) {
info->adrp_inst = ReferenceValue;
info->adrp_addr = ReferencePC;
SymbolName = nullptr;
*ReferenceName = nullptr;
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
// If this is arm64 and reference is an add immediate instruction and we
// have
// seen an adrp instruction just before it and the adrp's Xd register
// matches
// this add's Xn register reconstruct the value being referenced and look to
// see if it is a literal pointer. Note the add immediate instruction is
// passed in ReferenceValue.
} else if (info->O->getArch() == Triple::aarch64 &&
*ReferenceType == LLVMDisassembler_ReferenceType_In_ARM64_ADDXri &&
ReferencePC - 4 == info->adrp_addr &&
(info->adrp_inst & 0x9f000000) == 0x90000000 &&
(info->adrp_inst & 0x1f) == ((ReferenceValue >> 5) & 0x1f)) {
uint32_t addxri_inst;
uint64_t adrp_imm, addxri_imm;
adrp_imm =
((info->adrp_inst & 0x00ffffe0) >> 3) | ((info->adrp_inst >> 29) & 0x3);
if (info->adrp_inst & 0x0200000)
adrp_imm |= 0xfffffffffc000000LL;
addxri_inst = ReferenceValue;
addxri_imm = (addxri_inst >> 10) & 0xfff;
if (((addxri_inst >> 22) & 0x3) == 1)
addxri_imm <<= 12;
ReferenceValue = (info->adrp_addr & 0xfffffffffffff000LL) +
(adrp_imm << 12) + addxri_imm;
*ReferenceName =
GuessLiteralPointer(ReferenceValue, ReferencePC, ReferenceType, info);
if (*ReferenceName == nullptr)
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
// If this is arm64 and the reference is a load register instruction and we
// have seen an adrp instruction just before it and the adrp's Xd register
// matches this add's Xn register reconstruct the value being referenced and
// look to see if it is a literal pointer. Note the load register
// instruction is passed in ReferenceValue.
} else if (info->O->getArch() == Triple::aarch64 &&
*ReferenceType == LLVMDisassembler_ReferenceType_In_ARM64_LDRXui &&
ReferencePC - 4 == info->adrp_addr &&
(info->adrp_inst & 0x9f000000) == 0x90000000 &&
(info->adrp_inst & 0x1f) == ((ReferenceValue >> 5) & 0x1f)) {
uint32_t ldrxui_inst;
uint64_t adrp_imm, ldrxui_imm;
adrp_imm =
((info->adrp_inst & 0x00ffffe0) >> 3) | ((info->adrp_inst >> 29) & 0x3);
if (info->adrp_inst & 0x0200000)
adrp_imm |= 0xfffffffffc000000LL;
ldrxui_inst = ReferenceValue;
ldrxui_imm = (ldrxui_inst >> 10) & 0xfff;
ReferenceValue = (info->adrp_addr & 0xfffffffffffff000LL) +
(adrp_imm << 12) + (ldrxui_imm << 3);
*ReferenceName =
GuessLiteralPointer(ReferenceValue, ReferencePC, ReferenceType, info);
if (*ReferenceName == nullptr)
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
}
// If this arm64 and is an load register (PC-relative) instruction the
// ReferenceValue is the PC plus the immediate value.
else if (info->O->getArch() == Triple::aarch64 &&
(*ReferenceType == LLVMDisassembler_ReferenceType_In_ARM64_LDRXl ||
*ReferenceType == LLVMDisassembler_ReferenceType_In_ARM64_ADR)) {
*ReferenceName =
GuessLiteralPointer(ReferenceValue, ReferencePC, ReferenceType, info);
if (*ReferenceName == nullptr)
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
}
#if HAVE_CXXABI_H
else if (SymbolName != nullptr && strncmp(SymbolName, "__Z", 3) == 0) {
if (info->demangled_name != nullptr)
free(info->demangled_name);
int status;
info->demangled_name =
abi::__cxa_demangle(SymbolName + 1, nullptr, nullptr, &status);
if (info->demangled_name != nullptr) {
*ReferenceName = info->demangled_name;
*ReferenceType = LLVMDisassembler_ReferenceType_DeMangled_Name;
}
}
#endif
else {
*ReferenceName = nullptr;
*ReferenceType = LLVMDisassembler_ReferenceType_InOut_None;
}
return SymbolName;
}
/// \brief Emits the comments that are stored in the CommentStream.
/// Each comment in the CommentStream must end with a newline.
static void emitComments(raw_svector_ostream &CommentStream,
SmallString<128> &CommentsToEmit,
formatted_raw_ostream &FormattedOS,
const MCAsmInfo &MAI) {
// Flush the stream before taking its content.
CommentStream.flush();
StringRef Comments = CommentsToEmit.str();
// Get the default information for printing a comment.
const char *CommentBegin = MAI.getCommentString();
unsigned CommentColumn = MAI.getCommentColumn();
bool IsFirst = true;
while (!Comments.empty()) {
if (!IsFirst)
FormattedOS << '\n';
// Emit a line of comments.
FormattedOS.PadToColumn(CommentColumn);
size_t Position = Comments.find('\n');
FormattedOS << CommentBegin << ' ' << Comments.substr(0, Position);
// Move after the newline character.
Comments = Comments.substr(Position + 1);
IsFirst = false;
}
FormattedOS.flush();
// Tell the comment stream that the vector changed underneath it.
CommentsToEmit.clear();
CommentStream.resync();
}
static void DisassembleMachO(StringRef Filename, MachOObjectFile *MachOOF,
StringRef DisSegName, StringRef DisSectName) {
const char *McpuDefault = nullptr;
const Target *ThumbTarget = nullptr;
const Target *TheTarget = GetTarget(MachOOF, &McpuDefault, &ThumbTarget);
if (!TheTarget) {
// GetTarget prints out stuff.
return;
}
if (MCPU.empty() && McpuDefault)
MCPU = McpuDefault;
std::unique_ptr<const MCInstrInfo> InstrInfo(TheTarget->createMCInstrInfo());
std::unique_ptr<const MCInstrInfo> ThumbInstrInfo;
if (ThumbTarget)
ThumbInstrInfo.reset(ThumbTarget->createMCInstrInfo());
// Package up features to be passed to target/subtarget
std::string FeaturesStr;
if (MAttrs.size()) {
SubtargetFeatures Features;
for (unsigned i = 0; i != MAttrs.size(); ++i)
Features.AddFeature(MAttrs[i]);
FeaturesStr = Features.getString();
}
// Set up disassembler.
std::unique_ptr<const MCRegisterInfo> MRI(
TheTarget->createMCRegInfo(TripleName));
std::unique_ptr<const MCAsmInfo> AsmInfo(
TheTarget->createMCAsmInfo(*MRI, TripleName));
std::unique_ptr<const MCSubtargetInfo> STI(
TheTarget->createMCSubtargetInfo(TripleName, MCPU, FeaturesStr));
MCContext Ctx(AsmInfo.get(), MRI.get(), nullptr);
std::unique_ptr<MCDisassembler> DisAsm(
TheTarget->createMCDisassembler(*STI, Ctx));
std::unique_ptr<MCSymbolizer> Symbolizer;
struct DisassembleInfo SymbolizerInfo;
std::unique_ptr<MCRelocationInfo> RelInfo(
TheTarget->createMCRelocationInfo(TripleName, Ctx));
if (RelInfo) {
Symbolizer.reset(TheTarget->createMCSymbolizer(
TripleName, SymbolizerGetOpInfo, SymbolizerSymbolLookUp,
&SymbolizerInfo, &Ctx, std::move(RelInfo)));
DisAsm->setSymbolizer(std::move(Symbolizer));
}
int AsmPrinterVariant = AsmInfo->getAssemblerDialect();
std::unique_ptr<MCInstPrinter> IP(TheTarget->createMCInstPrinter(
Triple(TripleName), AsmPrinterVariant, *AsmInfo, *InstrInfo, *MRI));
// Set the display preference for hex vs. decimal immediates.
IP->setPrintImmHex(PrintImmHex);
// Comment stream and backing vector.
SmallString<128> CommentsToEmit;
raw_svector_ostream CommentStream(CommentsToEmit);
// FIXME: Setting the CommentStream in the InstPrinter is problematic in that
// if it is done then arm64 comments for string literals don't get printed
// and some constant get printed instead and not setting it causes intel
// (32-bit and 64-bit) comments printed with different spacing before the
// comment causing different diffs with the 'C' disassembler library API.
// IP->setCommentStream(CommentStream);
if (!AsmInfo || !STI || !DisAsm || !IP) {
errs() << "error: couldn't initialize disassembler for target "
<< TripleName << '\n';
return;
}
// Set up thumb disassembler.
std::unique_ptr<const MCRegisterInfo> ThumbMRI;
std::unique_ptr<const MCAsmInfo> ThumbAsmInfo;
std::unique_ptr<const MCSubtargetInfo> ThumbSTI;
std::unique_ptr<MCDisassembler> ThumbDisAsm;
std::unique_ptr<MCInstPrinter> ThumbIP;
std::unique_ptr<MCContext> ThumbCtx;
std::unique_ptr<MCSymbolizer> ThumbSymbolizer;
struct DisassembleInfo ThumbSymbolizerInfo;
std::unique_ptr<MCRelocationInfo> ThumbRelInfo;
if (ThumbTarget) {
ThumbMRI.reset(ThumbTarget->createMCRegInfo(ThumbTripleName));
ThumbAsmInfo.reset(
ThumbTarget->createMCAsmInfo(*ThumbMRI, ThumbTripleName));
ThumbSTI.reset(
ThumbTarget->createMCSubtargetInfo(ThumbTripleName, MCPU, FeaturesStr));
ThumbCtx.reset(new MCContext(ThumbAsmInfo.get(), ThumbMRI.get(), nullptr));
ThumbDisAsm.reset(ThumbTarget->createMCDisassembler(*ThumbSTI, *ThumbCtx));
MCContext *PtrThumbCtx = ThumbCtx.get();
ThumbRelInfo.reset(
ThumbTarget->createMCRelocationInfo(ThumbTripleName, *PtrThumbCtx));
if (ThumbRelInfo) {
ThumbSymbolizer.reset(ThumbTarget->createMCSymbolizer(
ThumbTripleName, SymbolizerGetOpInfo, SymbolizerSymbolLookUp,
&ThumbSymbolizerInfo, PtrThumbCtx, std::move(ThumbRelInfo)));
ThumbDisAsm->setSymbolizer(std::move(ThumbSymbolizer));
}
int ThumbAsmPrinterVariant = ThumbAsmInfo->getAssemblerDialect();
ThumbIP.reset(ThumbTarget->createMCInstPrinter(
Triple(ThumbTripleName), ThumbAsmPrinterVariant, *ThumbAsmInfo,
*ThumbInstrInfo, *ThumbMRI));
// Set the display preference for hex vs. decimal immediates.
ThumbIP->setPrintImmHex(PrintImmHex);
}
if (ThumbTarget && (!ThumbAsmInfo || !ThumbSTI || !ThumbDisAsm || !ThumbIP)) {
errs() << "error: couldn't initialize disassembler for target "
<< ThumbTripleName << '\n';
return;
}
MachO::mach_header Header = MachOOF->getHeader();
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
// FIXME: Using the -cfg command line option, this code used to be able to
// annotate relocations with the referenced symbol's name, and if this was
// inside a __[cf]string section, the data it points to. This is now replaced
// by the upcoming MCSymbolizer, which needs the appropriate setup done above.
std::vector<SectionRef> Sections;
std::vector<SymbolRef> Symbols;
SmallVector<uint64_t, 8> FoundFns;
uint64_t BaseSegmentAddress;
getSectionsAndSymbols(MachOOF, Sections, Symbols, FoundFns,
BaseSegmentAddress);
// Sort the symbols by address, just in case they didn't come in that way.
std::sort(Symbols.begin(), Symbols.end(), SymbolSorter());
// Build a data in code table that is sorted on by the address of each entry.
uint64_t BaseAddress = 0;
if (Header.filetype == MachO::MH_OBJECT)
BaseAddress = Sections[0].getAddress();
else
BaseAddress = BaseSegmentAddress;
DiceTable Dices;
for (dice_iterator DI = MachOOF->begin_dices(), DE = MachOOF->end_dices();
DI != DE; ++DI) {
uint32_t Offset;
DI->getOffset(Offset);
Dices.push_back(std::make_pair(BaseAddress + Offset, *DI));
}
array_pod_sort(Dices.begin(), Dices.end());
#ifndef NDEBUG
raw_ostream &DebugOut = DebugFlag ? dbgs() : nulls();
#else
raw_ostream &DebugOut = nulls();
#endif
std::unique_ptr<DIContext> diContext;
ObjectFile *DbgObj = MachOOF;
// Try to find debug info and set up the DIContext for it.
if (UseDbg) {
// A separate DSym file path was specified, parse it as a macho file,
// get the sections and supply it to the section name parsing machinery.
if (!DSYMFile.empty()) {
ErrorOr<std::unique_ptr<MemoryBuffer>> BufOrErr =
MemoryBuffer::getFileOrSTDIN(DSYMFile);
if (std::error_code EC = BufOrErr.getError()) {
errs() << "llvm-objdump: " << Filename << ": " << EC.message() << '\n';
return;
}
DbgObj =
ObjectFile::createMachOObjectFile(BufOrErr.get()->getMemBufferRef())
.get()
.release();
}
// Setup the DIContext
diContext.reset(new DWARFContextInMemory(*DbgObj));
}
if (DumpSections.size() == 0)
outs() << "(" << DisSegName << "," << DisSectName << ") section\n";
for (unsigned SectIdx = 0; SectIdx != Sections.size(); SectIdx++) {
StringRef SectName;
if (Sections[SectIdx].getName(SectName) || SectName != DisSectName)
continue;
DataRefImpl DR = Sections[SectIdx].getRawDataRefImpl();
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
StringRef SegmentName = MachOOF->getSectionFinalSegmentName(DR);
if (SegmentName != DisSegName)
continue;
StringRef BytesStr;
Sections[SectIdx].getContents(BytesStr);
ArrayRef<uint8_t> Bytes(reinterpret_cast<const uint8_t *>(BytesStr.data()),
BytesStr.size());
uint64_t SectAddress = Sections[SectIdx].getAddress();
bool symbolTableWorked = false;
// Parse relocations.
std::vector<std::pair<uint64_t, SymbolRef>> Relocs;
for (const RelocationRef &Reloc : Sections[SectIdx].relocations()) {
uint64_t RelocOffset = Reloc.getOffset();
uint64_t SectionAddress = Sections[SectIdx].getAddress();
RelocOffset -= SectionAddress;
symbol_iterator RelocSym = Reloc.getSymbol();
Relocs.push_back(std::make_pair(RelocOffset, *RelocSym));
}
array_pod_sort(Relocs.begin(), Relocs.end());
// Create a map of symbol addresses to symbol names for use by
// the SymbolizerSymbolLookUp() routine.
SymbolAddressMap AddrMap;
bool DisSymNameFound = false;
for (const SymbolRef &Symbol : MachOOF->symbols()) {
SymbolRef::Type ST = Symbol.getType();
if (ST == SymbolRef::ST_Function || ST == SymbolRef::ST_Data ||
ST == SymbolRef::ST_Other) {
uint64_t Address = Symbol.getValue();
ErrorOr<StringRef> SymNameOrErr = Symbol.getName();
if (std::error_code EC = SymNameOrErr.getError())
report_fatal_error(EC.message());
StringRef SymName = *SymNameOrErr;
AddrMap[Address] = SymName;
if (!DisSymName.empty() && DisSymName == SymName)
DisSymNameFound = true;
}
}
if (!DisSymName.empty() && !DisSymNameFound) {
outs() << "Can't find -dis-symname: " << DisSymName << "\n";
return;
}
// Set up the block of info used by the Symbolizer call backs.
SymbolizerInfo.verbose = !NoSymbolicOperands;
SymbolizerInfo.O = MachOOF;
SymbolizerInfo.S = Sections[SectIdx];
SymbolizerInfo.AddrMap = &AddrMap;
SymbolizerInfo.Sections = &Sections;
SymbolizerInfo.class_name = nullptr;
SymbolizerInfo.selector_name = nullptr;
SymbolizerInfo.method = nullptr;
SymbolizerInfo.demangled_name = nullptr;
SymbolizerInfo.bindtable = nullptr;
SymbolizerInfo.adrp_addr = 0;
SymbolizerInfo.adrp_inst = 0;
// Same for the ThumbSymbolizer
ThumbSymbolizerInfo.verbose = !NoSymbolicOperands;
ThumbSymbolizerInfo.O = MachOOF;
ThumbSymbolizerInfo.S = Sections[SectIdx];
ThumbSymbolizerInfo.AddrMap = &AddrMap;
ThumbSymbolizerInfo.Sections = &Sections;
ThumbSymbolizerInfo.class_name = nullptr;
ThumbSymbolizerInfo.selector_name = nullptr;
ThumbSymbolizerInfo.method = nullptr;
ThumbSymbolizerInfo.demangled_name = nullptr;
ThumbSymbolizerInfo.bindtable = nullptr;
ThumbSymbolizerInfo.adrp_addr = 0;
ThumbSymbolizerInfo.adrp_inst = 0;
// Disassemble symbol by symbol.
for (unsigned SymIdx = 0; SymIdx != Symbols.size(); SymIdx++) {
ErrorOr<StringRef> SymNameOrErr = Symbols[SymIdx].getName();
if (std::error_code EC = SymNameOrErr.getError())
report_fatal_error(EC.message());
StringRef SymName = *SymNameOrErr;
SymbolRef::Type ST = Symbols[SymIdx].getType();
if (ST != SymbolRef::ST_Function)
continue;
// Make sure the symbol is defined in this section.
bool containsSym = Sections[SectIdx].containsSymbol(Symbols[SymIdx]);
if (!containsSym)
continue;
// If we are only disassembling one symbol see if this is that symbol.
if (!DisSymName.empty() && DisSymName != SymName)
continue;
// Start at the address of the symbol relative to the section's address.
uint64_t Start = Symbols[SymIdx].getValue();
uint64_t SectionAddress = Sections[SectIdx].getAddress();
Start -= SectionAddress;
// Stop disassembling either at the beginning of the next symbol or at
// the end of the section.
bool containsNextSym = false;
uint64_t NextSym = 0;
uint64_t NextSymIdx = SymIdx + 1;
while (Symbols.size() > NextSymIdx) {
SymbolRef::Type NextSymType = Symbols[NextSymIdx].getType();
if (NextSymType == SymbolRef::ST_Function) {
containsNextSym =
Sections[SectIdx].containsSymbol(Symbols[NextSymIdx]);
NextSym = Symbols[NextSymIdx].getValue();
NextSym -= SectionAddress;
break;
}
++NextSymIdx;
}
uint64_t SectSize = Sections[SectIdx].getSize();
uint64_t End = containsNextSym ? NextSym : SectSize;
uint64_t Size;
symbolTableWorked = true;
DataRefImpl Symb = Symbols[SymIdx].getRawDataRefImpl();
bool isThumb =
(MachOOF->getSymbolFlags(Symb) & SymbolRef::SF_Thumb) && ThumbTarget;
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
outs() << SymName << ":\n";
DILineInfo lastLine;
for (uint64_t Index = Start; Index < End; Index += Size) {
MCInst Inst;
uint64_t PC = SectAddress + Index;
if (!NoLeadingAddr) {
if (FullLeadingAddr) {
if (MachOOF->is64Bit())
outs() << format("%016" PRIx64, PC);
else
outs() << format("%08" PRIx64, PC);
} else {
outs() << format("%8" PRIx64 ":", PC);
}
}
if (!NoShowRawInsn)
outs() << "\t";
// Check the data in code table here to see if this is data not an
// instruction to be disassembled.
DiceTable Dice;
Dice.push_back(std::make_pair(PC, DiceRef()));
dice_table_iterator DTI =
std::search(Dices.begin(), Dices.end(), Dice.begin(), Dice.end(),
compareDiceTableEntries);
if (DTI != Dices.end()) {
uint16_t Length;
DTI->second.getLength(Length);
uint16_t Kind;
DTI->second.getKind(Kind);
Size = DumpDataInCode(Bytes.data() + Index, Length, Kind);
if ((Kind == MachO::DICE_KIND_JUMP_TABLE8) &&
(PC == (DTI->first + Length - 1)) && (Length & 1))
Size++;
continue;
}
SmallVector<char, 64> AnnotationsBytes;
raw_svector_ostream Annotations(AnnotationsBytes);
bool gotInst;
if (isThumb)
gotInst = ThumbDisAsm->getInstruction(Inst, Size, Bytes.slice(Index),
PC, DebugOut, Annotations);
else
gotInst = DisAsm->getInstruction(Inst, Size, Bytes.slice(Index), PC,
DebugOut, Annotations);
if (gotInst) {
if (!NoShowRawInsn) {
dumpBytes(ArrayRef<uint8_t>(Bytes.data() + Index, Size), outs());
}
formatted_raw_ostream FormattedOS(outs());
Annotations.flush();
StringRef AnnotationsStr = Annotations.str();
if (isThumb)
ThumbIP->printInst(&Inst, FormattedOS, AnnotationsStr, *ThumbSTI);
else
IP->printInst(&Inst, FormattedOS, AnnotationsStr, *STI);
emitComments(CommentStream, CommentsToEmit, FormattedOS, *AsmInfo);
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
// Print debug info.
if (diContext) {
DILineInfo dli = diContext->getLineInfoForAddress(PC);
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
// Print valid line info if it changed.
if (dli != lastLine && dli.Line != 0)
outs() << "\t## " << dli.FileName << ':' << dli.Line << ':'
<< dli.Column;
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
lastLine = dli;
}
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
outs() << "\n";
} else {
unsigned int Arch = MachOOF->getArch();
if (Arch == Triple::x86_64 || Arch == Triple::x86) {
outs() << format("\t.byte 0x%02x #bad opcode\n",
*(Bytes.data() + Index) & 0xff);
Size = 1; // skip exactly one illegible byte and move on.
} else if (Arch == Triple::aarch64) {
uint32_t opcode = (*(Bytes.data() + Index) & 0xff) |
(*(Bytes.data() + Index + 1) & 0xff) << 8 |
(*(Bytes.data() + Index + 2) & 0xff) << 16 |
(*(Bytes.data() + Index + 3) & 0xff) << 24;
outs() << format("\t.long\t0x%08x\n", opcode);
Size = 4;
} else {
errs() << "llvm-objdump: warning: invalid instruction encoding\n";
if (Size == 0)
Size = 1; // skip illegible bytes
}
}
}
}
MC: Disassembled CFG reconstruction. This patch builds on some existing code to do CFG reconstruction from a disassembled binary: - MCModule represents the binary, and has a list of MCAtoms. - MCAtom represents either disassembled instructions (MCTextAtom), or contiguous data (MCDataAtom), and covers a specific range of addresses. - MCBasicBlock and MCFunction form the reconstructed CFG. An MCBB is backed by an MCTextAtom, and has the usual successors/predecessors. - MCObjectDisassembler creates a module from an ObjectFile using a disassembler. It first builds an atom for each section. It can also construct the CFG, and this splits the text atoms into basic blocks. MCModule and MCAtom were only sketched out; MCFunction and MCBB were implemented under the experimental "-cfg" llvm-objdump -macho option. This cleans them up for further use; llvm-objdump -d -cfg now generates graphviz files for each function found in the binary. In the future, MCObjectDisassembler may be the right place to do "intelligent" disassembly: for example, handling constant islands is just a matter of splitting the atom, using information that may be available in the ObjectFile. Also, better initial atom formation than just using sections is possible using symbols (and things like Mach-O's function_starts load command). This brings two minor regressions in llvm-objdump -macho -cfg: - The printing of a relocation's referenced symbol. - An annotation on loop BBs, i.e., which are their own successor. Relocation printing is replaced by the MCSymbolizer; the basic CFG annotation will be superseded by more related functionality. llvm-svn: 182628
2013-05-24 09:07:04 +08:00
if (!symbolTableWorked) {
// Reading the symbol table didn't work, disassemble the whole section.
uint64_t SectAddress = Sections[SectIdx].getAddress();
uint64_t SectSize = Sections[SectIdx].getSize();
uint64_t InstSize;
for (uint64_t Index = 0; Index < SectSize; Index += InstSize) {
2012-07-19 08:17:40 +08:00
MCInst Inst;
uint64_t PC = SectAddress + Index;
if (DisAsm->getInstruction(Inst, InstSize, Bytes.slice(Index), PC,
DebugOut, nulls())) {
if (!NoLeadingAddr) {
if (FullLeadingAddr) {
if (MachOOF->is64Bit())
outs() << format("%016" PRIx64, PC);
else
outs() << format("%08" PRIx64, PC);
} else {
outs() << format("%8" PRIx64 ":", PC);
}
}
if (!NoShowRawInsn) {
outs() << "\t";
dumpBytes(ArrayRef<uint8_t>(Bytes.data() + Index, InstSize), outs());
}
IP->printInst(&Inst, outs(), "", *STI);
2012-07-19 08:17:40 +08:00
outs() << "\n";
} else {
unsigned int Arch = MachOOF->getArch();
if (Arch == Triple::x86_64 || Arch == Triple::x86) {
outs() << format("\t.byte 0x%02x #bad opcode\n",
*(Bytes.data() + Index) & 0xff);
InstSize = 1; // skip exactly one illegible byte and move on.
} else {
errs() << "llvm-objdump: warning: invalid instruction encoding\n";
if (InstSize == 0)
InstSize = 1; // skip illegible bytes
}
2012-07-19 08:17:40 +08:00
}
}
}
// The TripleName's need to be reset if we are called again for a different
// archtecture.
TripleName = "";
ThumbTripleName = "";
if (SymbolizerInfo.method != nullptr)
free(SymbolizerInfo.method);
if (SymbolizerInfo.demangled_name != nullptr)
free(SymbolizerInfo.demangled_name);
if (SymbolizerInfo.bindtable != nullptr)
delete SymbolizerInfo.bindtable;
if (ThumbSymbolizerInfo.method != nullptr)
free(ThumbSymbolizerInfo.method);
if (ThumbSymbolizerInfo.demangled_name != nullptr)
free(ThumbSymbolizerInfo.demangled_name);
if (ThumbSymbolizerInfo.bindtable != nullptr)
delete ThumbSymbolizerInfo.bindtable;
}
}
//===----------------------------------------------------------------------===//
// __compact_unwind section dumping
//===----------------------------------------------------------------------===//
namespace {
template <typename T> static uint64_t readNext(const char *&Buf) {
using llvm::support::little;
using llvm::support::unaligned;
uint64_t Val = support::endian::read<T, little, unaligned>(Buf);
Buf += sizeof(T);
return Val;
}
struct CompactUnwindEntry {
uint32_t OffsetInSection;
uint64_t FunctionAddr;
uint32_t Length;
uint32_t CompactEncoding;
uint64_t PersonalityAddr;
uint64_t LSDAAddr;
RelocationRef FunctionReloc;
RelocationRef PersonalityReloc;
RelocationRef LSDAReloc;
CompactUnwindEntry(StringRef Contents, unsigned Offset, bool Is64)
: OffsetInSection(Offset) {
if (Is64)
read<uint64_t>(Contents.data() + Offset);
else
read<uint32_t>(Contents.data() + Offset);
}
private:
template <typename UIntPtr> void read(const char *Buf) {
FunctionAddr = readNext<UIntPtr>(Buf);
Length = readNext<uint32_t>(Buf);
CompactEncoding = readNext<uint32_t>(Buf);
PersonalityAddr = readNext<UIntPtr>(Buf);
LSDAAddr = readNext<UIntPtr>(Buf);
}
};
}
/// Given a relocation from __compact_unwind, consisting of the RelocationRef
/// and data being relocated, determine the best base Name and Addend to use for
/// display purposes.
///
/// 1. An Extern relocation will directly reference a symbol (and the data is
/// then already an addend), so use that.
/// 2. Otherwise the data is an offset in the object file's layout; try to find
// a symbol before it in the same section, and use the offset from there.
/// 3. Finally, if all that fails, fall back to an offset from the start of the
/// referenced section.
static void findUnwindRelocNameAddend(const MachOObjectFile *Obj,
std::map<uint64_t, SymbolRef> &Symbols,
const RelocationRef &Reloc, uint64_t Addr,
StringRef &Name, uint64_t &Addend) {
if (Reloc.getSymbol() != Obj->symbol_end()) {
ErrorOr<StringRef> NameOrErr = Reloc.getSymbol()->getName();
if (std::error_code EC = NameOrErr.getError())
report_fatal_error(EC.message());
Name = *NameOrErr;
Addend = Addr;
return;
}
auto RE = Obj->getRelocation(Reloc.getRawDataRefImpl());
SectionRef RelocSection = Obj->getAnyRelocationSection(RE);
uint64_t SectionAddr = RelocSection.getAddress();
auto Sym = Symbols.upper_bound(Addr);
if (Sym == Symbols.begin()) {
// The first symbol in the object is after this reference, the best we can
// do is section-relative notation.
RelocSection.getName(Name);
Addend = Addr - SectionAddr;
return;
}
// Go back one so that SymbolAddress <= Addr.
--Sym;
section_iterator SymSection = Obj->section_end();
Sym->second.getSection(SymSection);
if (RelocSection == *SymSection) {
// There's a valid symbol in the same section before this reference.
ErrorOr<StringRef> NameOrErr = Sym->second.getName();
if (std::error_code EC = NameOrErr.getError())
report_fatal_error(EC.message());
Name = *NameOrErr;
Addend = Addr - Sym->first;
return;
}
// There is a symbol before this reference, but it's in a different
// section. Probably not helpful to mention it, so use the section name.
RelocSection.getName(Name);
Addend = Addr - SectionAddr;
}
static void printUnwindRelocDest(const MachOObjectFile *Obj,
std::map<uint64_t, SymbolRef> &Symbols,
const RelocationRef &Reloc, uint64_t Addr) {
StringRef Name;
uint64_t Addend;
if (!Reloc.getObject())
return;
findUnwindRelocNameAddend(Obj, Symbols, Reloc, Addr, Name, Addend);
outs() << Name;
if (Addend)
outs() << " + " << format("0x%" PRIx64, Addend);
}
static void
printMachOCompactUnwindSection(const MachOObjectFile *Obj,
std::map<uint64_t, SymbolRef> &Symbols,
const SectionRef &CompactUnwind) {
assert(Obj->isLittleEndian() &&
"There should not be a big-endian .o with __compact_unwind");
bool Is64 = Obj->is64Bit();
uint32_t PointerSize = Is64 ? sizeof(uint64_t) : sizeof(uint32_t);
uint32_t EntrySize = 3 * PointerSize + 2 * sizeof(uint32_t);
StringRef Contents;
CompactUnwind.getContents(Contents);
SmallVector<CompactUnwindEntry, 4> CompactUnwinds;
// First populate the initial raw offsets, encodings and so on from the entry.
for (unsigned Offset = 0; Offset < Contents.size(); Offset += EntrySize) {
CompactUnwindEntry Entry(Contents.data(), Offset, Is64);
CompactUnwinds.push_back(Entry);
}
// Next we need to look at the relocations to find out what objects are
// actually being referred to.
for (const RelocationRef &Reloc : CompactUnwind.relocations()) {
uint64_t RelocAddress = Reloc.getOffset();
uint32_t EntryIdx = RelocAddress / EntrySize;
uint32_t OffsetInEntry = RelocAddress - EntryIdx * EntrySize;
CompactUnwindEntry &Entry = CompactUnwinds[EntryIdx];
if (OffsetInEntry == 0)
Entry.FunctionReloc = Reloc;
else if (OffsetInEntry == PointerSize + 2 * sizeof(uint32_t))
Entry.PersonalityReloc = Reloc;
else if (OffsetInEntry == 2 * PointerSize + 2 * sizeof(uint32_t))
Entry.LSDAReloc = Reloc;
else
llvm_unreachable("Unexpected relocation in __compact_unwind section");
}
// Finally, we're ready to print the data we've gathered.
outs() << "Contents of __compact_unwind section:\n";
for (auto &Entry : CompactUnwinds) {
outs() << " Entry at offset "
<< format("0x%" PRIx32, Entry.OffsetInSection) << ":\n";
// 1. Start of the region this entry applies to.
outs() << " start: " << format("0x%" PRIx64,
Entry.FunctionAddr) << ' ';
printUnwindRelocDest(Obj, Symbols, Entry.FunctionReloc, Entry.FunctionAddr);
outs() << '\n';
// 2. Length of the region this entry applies to.
outs() << " length: " << format("0x%" PRIx32, Entry.Length)
<< '\n';
// 3. The 32-bit compact encoding.
outs() << " compact encoding: "
<< format("0x%08" PRIx32, Entry.CompactEncoding) << '\n';
// 4. The personality function, if present.
if (Entry.PersonalityReloc.getObject()) {
outs() << " personality function: "
<< format("0x%" PRIx64, Entry.PersonalityAddr) << ' ';
printUnwindRelocDest(Obj, Symbols, Entry.PersonalityReloc,
Entry.PersonalityAddr);
outs() << '\n';
}
// 5. This entry's language-specific data area.
if (Entry.LSDAReloc.getObject()) {
outs() << " LSDA: " << format("0x%" PRIx64,
Entry.LSDAAddr) << ' ';
printUnwindRelocDest(Obj, Symbols, Entry.LSDAReloc, Entry.LSDAAddr);
outs() << '\n';
}
}
}
//===----------------------------------------------------------------------===//
// __unwind_info section dumping
//===----------------------------------------------------------------------===//
static void printRegularSecondLevelUnwindPage(const char *PageStart) {
const char *Pos = PageStart;
uint32_t Kind = readNext<uint32_t>(Pos);
(void)Kind;
assert(Kind == 2 && "kind for a regular 2nd level index should be 2");
uint16_t EntriesStart = readNext<uint16_t>(Pos);
uint16_t NumEntries = readNext<uint16_t>(Pos);
Pos = PageStart + EntriesStart;
for (unsigned i = 0; i < NumEntries; ++i) {
uint32_t FunctionOffset = readNext<uint32_t>(Pos);
uint32_t Encoding = readNext<uint32_t>(Pos);
outs() << " [" << i << "]: "
<< "function offset=" << format("0x%08" PRIx32, FunctionOffset)
<< ", "
<< "encoding=" << format("0x%08" PRIx32, Encoding) << '\n';
}
}
static void printCompressedSecondLevelUnwindPage(
const char *PageStart, uint32_t FunctionBase,
const SmallVectorImpl<uint32_t> &CommonEncodings) {
const char *Pos = PageStart;
uint32_t Kind = readNext<uint32_t>(Pos);
(void)Kind;
assert(Kind == 3 && "kind for a compressed 2nd level index should be 3");
uint16_t EntriesStart = readNext<uint16_t>(Pos);
uint16_t NumEntries = readNext<uint16_t>(Pos);
uint16_t EncodingsStart = readNext<uint16_t>(Pos);
readNext<uint16_t>(Pos);
const auto *PageEncodings = reinterpret_cast<const support::ulittle32_t *>(
PageStart + EncodingsStart);
Pos = PageStart + EntriesStart;
for (unsigned i = 0; i < NumEntries; ++i) {
uint32_t Entry = readNext<uint32_t>(Pos);
uint32_t FunctionOffset = FunctionBase + (Entry & 0xffffff);
uint32_t EncodingIdx = Entry >> 24;
uint32_t Encoding;
if (EncodingIdx < CommonEncodings.size())
Encoding = CommonEncodings[EncodingIdx];
else
Encoding = PageEncodings[EncodingIdx - CommonEncodings.size()];
outs() << " [" << i << "]: "
<< "function offset=" << format("0x%08" PRIx32, FunctionOffset)
<< ", "
<< "encoding[" << EncodingIdx
<< "]=" << format("0x%08" PRIx32, Encoding) << '\n';
}
}
static void printMachOUnwindInfoSection(const MachOObjectFile *Obj,
std::map<uint64_t, SymbolRef> &Symbols,
const SectionRef &UnwindInfo) {
assert(Obj->isLittleEndian() &&
"There should not be a big-endian .o with __unwind_info");
outs() << "Contents of __unwind_info section:\n";
StringRef Contents;
UnwindInfo.getContents(Contents);
const char *Pos = Contents.data();
//===----------------------------------
// Section header
//===----------------------------------
uint32_t Version = readNext<uint32_t>(Pos);
outs() << " Version: "
<< format("0x%" PRIx32, Version) << '\n';
assert(Version == 1 && "only understand version 1");
uint32_t CommonEncodingsStart = readNext<uint32_t>(Pos);
outs() << " Common encodings array section offset: "
<< format("0x%" PRIx32, CommonEncodingsStart) << '\n';
uint32_t NumCommonEncodings = readNext<uint32_t>(Pos);
outs() << " Number of common encodings in array: "
<< format("0x%" PRIx32, NumCommonEncodings) << '\n';
uint32_t PersonalitiesStart = readNext<uint32_t>(Pos);
outs() << " Personality function array section offset: "
<< format("0x%" PRIx32, PersonalitiesStart) << '\n';
uint32_t NumPersonalities = readNext<uint32_t>(Pos);
outs() << " Number of personality functions in array: "
<< format("0x%" PRIx32, NumPersonalities) << '\n';
uint32_t IndicesStart = readNext<uint32_t>(Pos);
outs() << " Index array section offset: "
<< format("0x%" PRIx32, IndicesStart) << '\n';
uint32_t NumIndices = readNext<uint32_t>(Pos);
outs() << " Number of indices in array: "
<< format("0x%" PRIx32, NumIndices) << '\n';
//===----------------------------------
// A shared list of common encodings
//===----------------------------------
// These occupy indices in the range [0, N] whenever an encoding is referenced
// from a compressed 2nd level index table. In practice the linker only
// creates ~128 of these, so that indices are available to embed encodings in
// the 2nd level index.
SmallVector<uint32_t, 64> CommonEncodings;
outs() << " Common encodings: (count = " << NumCommonEncodings << ")\n";
Pos = Contents.data() + CommonEncodingsStart;
for (unsigned i = 0; i < NumCommonEncodings; ++i) {
uint32_t Encoding = readNext<uint32_t>(Pos);
CommonEncodings.push_back(Encoding);
outs() << " encoding[" << i << "]: " << format("0x%08" PRIx32, Encoding)
<< '\n';
}
//===----------------------------------
// Personality functions used in this executable
//===----------------------------------
// There should be only a handful of these (one per source language,
// roughly). Particularly since they only get 2 bits in the compact encoding.
outs() << " Personality functions: (count = " << NumPersonalities << ")\n";
Pos = Contents.data() + PersonalitiesStart;
for (unsigned i = 0; i < NumPersonalities; ++i) {
uint32_t PersonalityFn = readNext<uint32_t>(Pos);
outs() << " personality[" << i + 1
<< "]: " << format("0x%08" PRIx32, PersonalityFn) << '\n';
}
//===----------------------------------
// The level 1 index entries
//===----------------------------------
// These specify an approximate place to start searching for the more detailed
// information, sorted by PC.
struct IndexEntry {
uint32_t FunctionOffset;
uint32_t SecondLevelPageStart;
uint32_t LSDAStart;
};
SmallVector<IndexEntry, 4> IndexEntries;
outs() << " Top level indices: (count = " << NumIndices << ")\n";
Pos = Contents.data() + IndicesStart;
for (unsigned i = 0; i < NumIndices; ++i) {
IndexEntry Entry;
Entry.FunctionOffset = readNext<uint32_t>(Pos);
Entry.SecondLevelPageStart = readNext<uint32_t>(Pos);
Entry.LSDAStart = readNext<uint32_t>(Pos);
IndexEntries.push_back(Entry);
outs() << " [" << i << "]: "
<< "function offset=" << format("0x%08" PRIx32, Entry.FunctionOffset)
<< ", "
<< "2nd level page offset="
<< format("0x%08" PRIx32, Entry.SecondLevelPageStart) << ", "
<< "LSDA offset=" << format("0x%08" PRIx32, Entry.LSDAStart) << '\n';
}
//===----------------------------------
// Next come the LSDA tables
//===----------------------------------
// The LSDA layout is rather implicit: it's a contiguous array of entries from
// the first top-level index's LSDAOffset to the last (sentinel).
outs() << " LSDA descriptors:\n";
Pos = Contents.data() + IndexEntries[0].LSDAStart;
int NumLSDAs = (IndexEntries.back().LSDAStart - IndexEntries[0].LSDAStart) /
(2 * sizeof(uint32_t));
for (int i = 0; i < NumLSDAs; ++i) {
uint32_t FunctionOffset = readNext<uint32_t>(Pos);
uint32_t LSDAOffset = readNext<uint32_t>(Pos);
outs() << " [" << i << "]: "
<< "function offset=" << format("0x%08" PRIx32, FunctionOffset)
<< ", "
<< "LSDA offset=" << format("0x%08" PRIx32, LSDAOffset) << '\n';
}
//===----------------------------------
// Finally, the 2nd level indices
//===----------------------------------
// Generally these are 4K in size, and have 2 possible forms:
// + Regular stores up to 511 entries with disparate encodings
// + Compressed stores up to 1021 entries if few enough compact encoding
// values are used.
outs() << " Second level indices:\n";
for (unsigned i = 0; i < IndexEntries.size() - 1; ++i) {
// The final sentinel top-level index has no associated 2nd level page
if (IndexEntries[i].SecondLevelPageStart == 0)
break;
outs() << " Second level index[" << i << "]: "
<< "offset in section="
<< format("0x%08" PRIx32, IndexEntries[i].SecondLevelPageStart)
<< ", "
<< "base function offset="
<< format("0x%08" PRIx32, IndexEntries[i].FunctionOffset) << '\n';
Pos = Contents.data() + IndexEntries[i].SecondLevelPageStart;
uint32_t Kind = *reinterpret_cast<const support::ulittle32_t *>(Pos);
if (Kind == 2)
printRegularSecondLevelUnwindPage(Pos);
else if (Kind == 3)
printCompressedSecondLevelUnwindPage(Pos, IndexEntries[i].FunctionOffset,
CommonEncodings);
else
llvm_unreachable("Do not know how to print this kind of 2nd level page");
}
}
void llvm::printMachOUnwindInfo(const MachOObjectFile *Obj) {
std::map<uint64_t, SymbolRef> Symbols;
for (const SymbolRef &SymRef : Obj->symbols()) {
// Discard any undefined or absolute symbols. They're not going to take part
// in the convenience lookup for unwind info and just take up resources.
section_iterator Section = Obj->section_end();
SymRef.getSection(Section);
if (Section == Obj->section_end())
continue;
uint64_t Addr = SymRef.getValue();
Symbols.insert(std::make_pair(Addr, SymRef));
}
for (const SectionRef &Section : Obj->sections()) {
StringRef SectName;
Section.getName(SectName);
if (SectName == "__compact_unwind")
printMachOCompactUnwindSection(Obj, Symbols, Section);
else if (SectName == "__unwind_info")
printMachOUnwindInfoSection(Obj, Symbols, Section);
else if (SectName == "__eh_frame")
outs() << "llvm-objdump: warning: unhandled __eh_frame section\n";
}
}
static void PrintMachHeader(uint32_t magic, uint32_t cputype,
uint32_t cpusubtype, uint32_t filetype,
uint32_t ncmds, uint32_t sizeofcmds, uint32_t flags,
bool verbose) {
outs() << "Mach header\n";
outs() << " magic cputype cpusubtype caps filetype ncmds "
"sizeofcmds flags\n";
if (verbose) {
if (magic == MachO::MH_MAGIC)
outs() << " MH_MAGIC";
else if (magic == MachO::MH_MAGIC_64)
outs() << "MH_MAGIC_64";
else
outs() << format(" 0x%08" PRIx32, magic);
switch (cputype) {
case MachO::CPU_TYPE_I386:
outs() << " I386";
switch (cpusubtype & ~MachO::CPU_SUBTYPE_MASK) {
case MachO::CPU_SUBTYPE_I386_ALL:
outs() << " ALL";
break;
default:
outs() << format(" %10d", cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
break;
}
break;
case MachO::CPU_TYPE_X86_64:
outs() << " X86_64";
switch (cpusubtype & ~MachO::CPU_SUBTYPE_MASK) {
case MachO::CPU_SUBTYPE_X86_64_ALL:
outs() << " ALL";
break;
case MachO::CPU_SUBTYPE_X86_64_H:
outs() << " Haswell";
break;
default:
outs() << format(" %10d", cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
break;
}
break;
case MachO::CPU_TYPE_ARM:
outs() << " ARM";
switch (cpusubtype & ~MachO::CPU_SUBTYPE_MASK) {
case MachO::CPU_SUBTYPE_ARM_ALL:
outs() << " ALL";
break;
case MachO::CPU_SUBTYPE_ARM_V4T:
outs() << " V4T";
break;
case MachO::CPU_SUBTYPE_ARM_V5TEJ:
outs() << " V5TEJ";
break;
case MachO::CPU_SUBTYPE_ARM_XSCALE:
outs() << " XSCALE";
break;
case MachO::CPU_SUBTYPE_ARM_V6:
outs() << " V6";
break;
case MachO::CPU_SUBTYPE_ARM_V6M:
outs() << " V6M";
break;
case MachO::CPU_SUBTYPE_ARM_V7:
outs() << " V7";
break;
case MachO::CPU_SUBTYPE_ARM_V7EM:
outs() << " V7EM";
break;
case MachO::CPU_SUBTYPE_ARM_V7K:
outs() << " V7K";
break;
case MachO::CPU_SUBTYPE_ARM_V7M:
outs() << " V7M";
break;
case MachO::CPU_SUBTYPE_ARM_V7S:
outs() << " V7S";
break;
default:
outs() << format(" %10d", cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
break;
}
break;
case MachO::CPU_TYPE_ARM64:
outs() << " ARM64";
switch (cpusubtype & ~MachO::CPU_SUBTYPE_MASK) {
case MachO::CPU_SUBTYPE_ARM64_ALL:
outs() << " ALL";
break;
default:
outs() << format(" %10d", cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
break;
}
break;
case MachO::CPU_TYPE_POWERPC:
outs() << " PPC";
switch (cpusubtype & ~MachO::CPU_SUBTYPE_MASK) {
case MachO::CPU_SUBTYPE_POWERPC_ALL:
outs() << " ALL";
break;
default:
outs() << format(" %10d", cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
break;
}
break;
case MachO::CPU_TYPE_POWERPC64:
outs() << " PPC64";
switch (cpusubtype & ~MachO::CPU_SUBTYPE_MASK) {
case MachO::CPU_SUBTYPE_POWERPC_ALL:
outs() << " ALL";
break;
default:
outs() << format(" %10d", cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
break;
}
break;
}
if ((cpusubtype & MachO::CPU_SUBTYPE_MASK) == MachO::CPU_SUBTYPE_LIB64) {
outs() << " LIB64";
} else {
outs() << format(" 0x%02" PRIx32,
(cpusubtype & MachO::CPU_SUBTYPE_MASK) >> 24);
}
switch (filetype) {
case MachO::MH_OBJECT:
outs() << " OBJECT";
break;
case MachO::MH_EXECUTE:
outs() << " EXECUTE";
break;
case MachO::MH_FVMLIB:
outs() << " FVMLIB";
break;
case MachO::MH_CORE:
outs() << " CORE";
break;
case MachO::MH_PRELOAD:
outs() << " PRELOAD";
break;
case MachO::MH_DYLIB:
outs() << " DYLIB";
break;
case MachO::MH_DYLIB_STUB:
outs() << " DYLIB_STUB";
break;
case MachO::MH_DYLINKER:
outs() << " DYLINKER";
break;
case MachO::MH_BUNDLE:
outs() << " BUNDLE";
break;
case MachO::MH_DSYM:
outs() << " DSYM";
break;
case MachO::MH_KEXT_BUNDLE:
outs() << " KEXTBUNDLE";
break;
default:
outs() << format(" %10u", filetype);
break;
}
outs() << format(" %5u", ncmds);
outs() << format(" %10u", sizeofcmds);
uint32_t f = flags;
if (f & MachO::MH_NOUNDEFS) {
outs() << " NOUNDEFS";
f &= ~MachO::MH_NOUNDEFS;
}
if (f & MachO::MH_INCRLINK) {
outs() << " INCRLINK";
f &= ~MachO::MH_INCRLINK;
}
if (f & MachO::MH_DYLDLINK) {
outs() << " DYLDLINK";
f &= ~MachO::MH_DYLDLINK;
}
if (f & MachO::MH_BINDATLOAD) {
outs() << " BINDATLOAD";
f &= ~MachO::MH_BINDATLOAD;
}
if (f & MachO::MH_PREBOUND) {
outs() << " PREBOUND";
f &= ~MachO::MH_PREBOUND;
}
if (f & MachO::MH_SPLIT_SEGS) {
outs() << " SPLIT_SEGS";
f &= ~MachO::MH_SPLIT_SEGS;
}
if (f & MachO::MH_LAZY_INIT) {
outs() << " LAZY_INIT";
f &= ~MachO::MH_LAZY_INIT;
}
if (f & MachO::MH_TWOLEVEL) {
outs() << " TWOLEVEL";
f &= ~MachO::MH_TWOLEVEL;
}
if (f & MachO::MH_FORCE_FLAT) {
outs() << " FORCE_FLAT";
f &= ~MachO::MH_FORCE_FLAT;
}
if (f & MachO::MH_NOMULTIDEFS) {
outs() << " NOMULTIDEFS";
f &= ~MachO::MH_NOMULTIDEFS;
}
if (f & MachO::MH_NOFIXPREBINDING) {
outs() << " NOFIXPREBINDING";
f &= ~MachO::MH_NOFIXPREBINDING;
}
if (f & MachO::MH_PREBINDABLE) {
outs() << " PREBINDABLE";
f &= ~MachO::MH_PREBINDABLE;
}
if (f & MachO::MH_ALLMODSBOUND) {
outs() << " ALLMODSBOUND";
f &= ~MachO::MH_ALLMODSBOUND;
}
if (f & MachO::MH_SUBSECTIONS_VIA_SYMBOLS) {
outs() << " SUBSECTIONS_VIA_SYMBOLS";
f &= ~MachO::MH_SUBSECTIONS_VIA_SYMBOLS;
}
if (f & MachO::MH_CANONICAL) {
outs() << " CANONICAL";
f &= ~MachO::MH_CANONICAL;
}
if (f & MachO::MH_WEAK_DEFINES) {
outs() << " WEAK_DEFINES";
f &= ~MachO::MH_WEAK_DEFINES;
}
if (f & MachO::MH_BINDS_TO_WEAK) {
outs() << " BINDS_TO_WEAK";
f &= ~MachO::MH_BINDS_TO_WEAK;
}
if (f & MachO::MH_ALLOW_STACK_EXECUTION) {
outs() << " ALLOW_STACK_EXECUTION";
f &= ~MachO::MH_ALLOW_STACK_EXECUTION;
}
if (f & MachO::MH_DEAD_STRIPPABLE_DYLIB) {
outs() << " DEAD_STRIPPABLE_DYLIB";
f &= ~MachO::MH_DEAD_STRIPPABLE_DYLIB;
}
if (f & MachO::MH_PIE) {
outs() << " PIE";
f &= ~MachO::MH_PIE;
}
if (f & MachO::MH_NO_REEXPORTED_DYLIBS) {
outs() << " NO_REEXPORTED_DYLIBS";
f &= ~MachO::MH_NO_REEXPORTED_DYLIBS;
}
if (f & MachO::MH_HAS_TLV_DESCRIPTORS) {
outs() << " MH_HAS_TLV_DESCRIPTORS";
f &= ~MachO::MH_HAS_TLV_DESCRIPTORS;
}
if (f & MachO::MH_NO_HEAP_EXECUTION) {
outs() << " MH_NO_HEAP_EXECUTION";
f &= ~MachO::MH_NO_HEAP_EXECUTION;
}
if (f & MachO::MH_APP_EXTENSION_SAFE) {
outs() << " APP_EXTENSION_SAFE";
f &= ~MachO::MH_APP_EXTENSION_SAFE;
}
if (f != 0 || flags == 0)
outs() << format(" 0x%08" PRIx32, f);
} else {
outs() << format(" 0x%08" PRIx32, magic);
outs() << format(" %7d", cputype);
outs() << format(" %10d", cpusubtype & ~MachO::CPU_SUBTYPE_MASK);
outs() << format(" 0x%02" PRIx32,
(cpusubtype & MachO::CPU_SUBTYPE_MASK) >> 24);
outs() << format(" %10u", filetype);
outs() << format(" %5u", ncmds);
outs() << format(" %10u", sizeofcmds);
outs() << format(" 0x%08" PRIx32, flags);
}
outs() << "\n";
}
static void PrintSegmentCommand(uint32_t cmd, uint32_t cmdsize,
StringRef SegName, uint64_t vmaddr,
uint64_t vmsize, uint64_t fileoff,
uint64_t filesize, uint32_t maxprot,
uint32_t initprot, uint32_t nsects,
uint32_t flags, uint32_t object_size,
bool verbose) {
uint64_t expected_cmdsize;
if (cmd == MachO::LC_SEGMENT) {
outs() << " cmd LC_SEGMENT\n";
expected_cmdsize = nsects;
expected_cmdsize *= sizeof(struct MachO::section);
expected_cmdsize += sizeof(struct MachO::segment_command);
} else {
outs() << " cmd LC_SEGMENT_64\n";
expected_cmdsize = nsects;
expected_cmdsize *= sizeof(struct MachO::section_64);
expected_cmdsize += sizeof(struct MachO::segment_command_64);
}
outs() << " cmdsize " << cmdsize;
if (cmdsize != expected_cmdsize)
outs() << " Inconsistent size\n";
else
outs() << "\n";
outs() << " segname " << SegName << "\n";
if (cmd == MachO::LC_SEGMENT_64) {
outs() << " vmaddr " << format("0x%016" PRIx64, vmaddr) << "\n";
outs() << " vmsize " << format("0x%016" PRIx64, vmsize) << "\n";
} else {
outs() << " vmaddr " << format("0x%08" PRIx64, vmaddr) << "\n";
outs() << " vmsize " << format("0x%08" PRIx64, vmsize) << "\n";
}
outs() << " fileoff " << fileoff;
if (fileoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " filesize " << filesize;
if (fileoff + filesize > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
if (verbose) {
if ((maxprot &
~(MachO::VM_PROT_READ | MachO::VM_PROT_WRITE |
MachO::VM_PROT_EXECUTE)) != 0)
outs() << " maxprot ?" << format("0x%08" PRIx32, maxprot) << "\n";
else {
if (maxprot & MachO::VM_PROT_READ)
outs() << " maxprot r";
else
outs() << " maxprot -";
if (maxprot & MachO::VM_PROT_WRITE)
outs() << "w";
else
outs() << "-";
if (maxprot & MachO::VM_PROT_EXECUTE)
outs() << "x\n";
else
outs() << "-\n";
}
if ((initprot &
~(MachO::VM_PROT_READ | MachO::VM_PROT_WRITE |
MachO::VM_PROT_EXECUTE)) != 0)
outs() << " initprot ?" << format("0x%08" PRIx32, initprot) << "\n";
else {
if (initprot & MachO::VM_PROT_READ)
outs() << " initprot r";
else
outs() << " initprot -";
if (initprot & MachO::VM_PROT_WRITE)
outs() << "w";
else
outs() << "-";
if (initprot & MachO::VM_PROT_EXECUTE)
outs() << "x\n";
else
outs() << "-\n";
}
} else {
outs() << " maxprot " << format("0x%08" PRIx32, maxprot) << "\n";
outs() << " initprot " << format("0x%08" PRIx32, initprot) << "\n";
}
outs() << " nsects " << nsects << "\n";
if (verbose) {
outs() << " flags";
if (flags == 0)
outs() << " (none)\n";
else {
if (flags & MachO::SG_HIGHVM) {
outs() << " HIGHVM";
flags &= ~MachO::SG_HIGHVM;
}
if (flags & MachO::SG_FVMLIB) {
outs() << " FVMLIB";
flags &= ~MachO::SG_FVMLIB;
}
if (flags & MachO::SG_NORELOC) {
outs() << " NORELOC";
flags &= ~MachO::SG_NORELOC;
}
if (flags & MachO::SG_PROTECTED_VERSION_1) {
outs() << " PROTECTED_VERSION_1";
flags &= ~MachO::SG_PROTECTED_VERSION_1;
}
if (flags)
outs() << format(" 0x%08" PRIx32, flags) << " (unknown flags)\n";
else
outs() << "\n";
}
} else {
outs() << " flags " << format("0x%" PRIx32, flags) << "\n";
}
}
static void PrintSection(const char *sectname, const char *segname,
uint64_t addr, uint64_t size, uint32_t offset,
uint32_t align, uint32_t reloff, uint32_t nreloc,
uint32_t flags, uint32_t reserved1, uint32_t reserved2,
uint32_t cmd, const char *sg_segname,
uint32_t filetype, uint32_t object_size,
bool verbose) {
outs() << "Section\n";
outs() << " sectname " << format("%.16s\n", sectname);
outs() << " segname " << format("%.16s", segname);
if (filetype != MachO::MH_OBJECT && strncmp(sg_segname, segname, 16) != 0)
outs() << " (does not match segment)\n";
else
outs() << "\n";
if (cmd == MachO::LC_SEGMENT_64) {
outs() << " addr " << format("0x%016" PRIx64, addr) << "\n";
outs() << " size " << format("0x%016" PRIx64, size);
} else {
outs() << " addr " << format("0x%08" PRIx64, addr) << "\n";
outs() << " size " << format("0x%08" PRIx64, size);
}
if ((flags & MachO::S_ZEROFILL) != 0 && offset + size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " offset " << offset;
if (offset > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
uint32_t align_shifted = 1 << align;
outs() << " align 2^" << align << " (" << align_shifted << ")\n";
outs() << " reloff " << reloff;
if (reloff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " nreloc " << nreloc;
if (reloff + nreloc * sizeof(struct MachO::relocation_info) > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
uint32_t section_type = flags & MachO::SECTION_TYPE;
if (verbose) {
outs() << " type";
if (section_type == MachO::S_REGULAR)
outs() << " S_REGULAR\n";
else if (section_type == MachO::S_ZEROFILL)
outs() << " S_ZEROFILL\n";
else if (section_type == MachO::S_CSTRING_LITERALS)
outs() << " S_CSTRING_LITERALS\n";
else if (section_type == MachO::S_4BYTE_LITERALS)
outs() << " S_4BYTE_LITERALS\n";
else if (section_type == MachO::S_8BYTE_LITERALS)
outs() << " S_8BYTE_LITERALS\n";
else if (section_type == MachO::S_16BYTE_LITERALS)
outs() << " S_16BYTE_LITERALS\n";
else if (section_type == MachO::S_LITERAL_POINTERS)
outs() << " S_LITERAL_POINTERS\n";
else if (section_type == MachO::S_NON_LAZY_SYMBOL_POINTERS)
outs() << " S_NON_LAZY_SYMBOL_POINTERS\n";
else if (section_type == MachO::S_LAZY_SYMBOL_POINTERS)
outs() << " S_LAZY_SYMBOL_POINTERS\n";
else if (section_type == MachO::S_SYMBOL_STUBS)
outs() << " S_SYMBOL_STUBS\n";
else if (section_type == MachO::S_MOD_INIT_FUNC_POINTERS)
outs() << " S_MOD_INIT_FUNC_POINTERS\n";
else if (section_type == MachO::S_MOD_TERM_FUNC_POINTERS)
outs() << " S_MOD_TERM_FUNC_POINTERS\n";
else if (section_type == MachO::S_COALESCED)
outs() << " S_COALESCED\n";
else if (section_type == MachO::S_INTERPOSING)
outs() << " S_INTERPOSING\n";
else if (section_type == MachO::S_DTRACE_DOF)
outs() << " S_DTRACE_DOF\n";
else if (section_type == MachO::S_LAZY_DYLIB_SYMBOL_POINTERS)
outs() << " S_LAZY_DYLIB_SYMBOL_POINTERS\n";
else if (section_type == MachO::S_THREAD_LOCAL_REGULAR)
outs() << " S_THREAD_LOCAL_REGULAR\n";
else if (section_type == MachO::S_THREAD_LOCAL_ZEROFILL)
outs() << " S_THREAD_LOCAL_ZEROFILL\n";
else if (section_type == MachO::S_THREAD_LOCAL_VARIABLES)
outs() << " S_THREAD_LOCAL_VARIABLES\n";
else if (section_type == MachO::S_THREAD_LOCAL_VARIABLE_POINTERS)
outs() << " S_THREAD_LOCAL_VARIABLE_POINTERS\n";
else if (section_type == MachO::S_THREAD_LOCAL_INIT_FUNCTION_POINTERS)
outs() << " S_THREAD_LOCAL_INIT_FUNCTION_POINTERS\n";
else
outs() << format("0x%08" PRIx32, section_type) << "\n";
outs() << "attributes";
uint32_t section_attributes = flags & MachO::SECTION_ATTRIBUTES;
if (section_attributes & MachO::S_ATTR_PURE_INSTRUCTIONS)
outs() << " PURE_INSTRUCTIONS";
if (section_attributes & MachO::S_ATTR_NO_TOC)
outs() << " NO_TOC";
if (section_attributes & MachO::S_ATTR_STRIP_STATIC_SYMS)
outs() << " STRIP_STATIC_SYMS";
if (section_attributes & MachO::S_ATTR_NO_DEAD_STRIP)
outs() << " NO_DEAD_STRIP";
if (section_attributes & MachO::S_ATTR_LIVE_SUPPORT)
outs() << " LIVE_SUPPORT";
if (section_attributes & MachO::S_ATTR_SELF_MODIFYING_CODE)
outs() << " SELF_MODIFYING_CODE";
if (section_attributes & MachO::S_ATTR_DEBUG)
outs() << " DEBUG";
if (section_attributes & MachO::S_ATTR_SOME_INSTRUCTIONS)
outs() << " SOME_INSTRUCTIONS";
if (section_attributes & MachO::S_ATTR_EXT_RELOC)
outs() << " EXT_RELOC";
if (section_attributes & MachO::S_ATTR_LOC_RELOC)
outs() << " LOC_RELOC";
if (section_attributes == 0)
outs() << " (none)";
outs() << "\n";
} else
outs() << " flags " << format("0x%08" PRIx32, flags) << "\n";
outs() << " reserved1 " << reserved1;
if (section_type == MachO::S_SYMBOL_STUBS ||
section_type == MachO::S_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_LAZY_DYLIB_SYMBOL_POINTERS ||
section_type == MachO::S_NON_LAZY_SYMBOL_POINTERS ||
section_type == MachO::S_THREAD_LOCAL_VARIABLE_POINTERS)
outs() << " (index into indirect symbol table)\n";
else
outs() << "\n";
outs() << " reserved2 " << reserved2;
if (section_type == MachO::S_SYMBOL_STUBS)
outs() << " (size of stubs)\n";
else
outs() << "\n";
}
static void PrintSymtabLoadCommand(MachO::symtab_command st, bool Is64Bit,
uint32_t object_size) {
outs() << " cmd LC_SYMTAB\n";
outs() << " cmdsize " << st.cmdsize;
if (st.cmdsize != sizeof(struct MachO::symtab_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " symoff " << st.symoff;
if (st.symoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " nsyms " << st.nsyms;
uint64_t big_size;
if (Is64Bit) {
big_size = st.nsyms;
big_size *= sizeof(struct MachO::nlist_64);
big_size += st.symoff;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
} else {
big_size = st.nsyms;
big_size *= sizeof(struct MachO::nlist);
big_size += st.symoff;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
}
outs() << " stroff " << st.stroff;
if (st.stroff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " strsize " << st.strsize;
big_size = st.stroff;
big_size += st.strsize;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
}
static void PrintDysymtabLoadCommand(MachO::dysymtab_command dyst,
uint32_t nsyms, uint32_t object_size,
bool Is64Bit) {
outs() << " cmd LC_DYSYMTAB\n";
outs() << " cmdsize " << dyst.cmdsize;
if (dyst.cmdsize != sizeof(struct MachO::dysymtab_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " ilocalsym " << dyst.ilocalsym;
if (dyst.ilocalsym > nsyms)
outs() << " (greater than the number of symbols)\n";
else
outs() << "\n";
outs() << " nlocalsym " << dyst.nlocalsym;
uint64_t big_size;
big_size = dyst.ilocalsym;
big_size += dyst.nlocalsym;
if (big_size > nsyms)
outs() << " (past the end of the symbol table)\n";
else
outs() << "\n";
outs() << " iextdefsym " << dyst.iextdefsym;
if (dyst.iextdefsym > nsyms)
outs() << " (greater than the number of symbols)\n";
else
outs() << "\n";
outs() << " nextdefsym " << dyst.nextdefsym;
big_size = dyst.iextdefsym;
big_size += dyst.nextdefsym;
if (big_size > nsyms)
outs() << " (past the end of the symbol table)\n";
else
outs() << "\n";
outs() << " iundefsym " << dyst.iundefsym;
if (dyst.iundefsym > nsyms)
outs() << " (greater than the number of symbols)\n";
else
outs() << "\n";
outs() << " nundefsym " << dyst.nundefsym;
big_size = dyst.iundefsym;
big_size += dyst.nundefsym;
if (big_size > nsyms)
outs() << " (past the end of the symbol table)\n";
else
outs() << "\n";
outs() << " tocoff " << dyst.tocoff;
if (dyst.tocoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " ntoc " << dyst.ntoc;
big_size = dyst.ntoc;
big_size *= sizeof(struct MachO::dylib_table_of_contents);
big_size += dyst.tocoff;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " modtaboff " << dyst.modtaboff;
if (dyst.modtaboff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " nmodtab " << dyst.nmodtab;
uint64_t modtabend;
if (Is64Bit) {
modtabend = dyst.nmodtab;
modtabend *= sizeof(struct MachO::dylib_module_64);
modtabend += dyst.modtaboff;
} else {
modtabend = dyst.nmodtab;
modtabend *= sizeof(struct MachO::dylib_module);
modtabend += dyst.modtaboff;
}
if (modtabend > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " extrefsymoff " << dyst.extrefsymoff;
if (dyst.extrefsymoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " nextrefsyms " << dyst.nextrefsyms;
big_size = dyst.nextrefsyms;
big_size *= sizeof(struct MachO::dylib_reference);
big_size += dyst.extrefsymoff;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " indirectsymoff " << dyst.indirectsymoff;
if (dyst.indirectsymoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " nindirectsyms " << dyst.nindirectsyms;
big_size = dyst.nindirectsyms;
big_size *= sizeof(uint32_t);
big_size += dyst.indirectsymoff;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " extreloff " << dyst.extreloff;
if (dyst.extreloff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " nextrel " << dyst.nextrel;
big_size = dyst.nextrel;
big_size *= sizeof(struct MachO::relocation_info);
big_size += dyst.extreloff;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " locreloff " << dyst.locreloff;
if (dyst.locreloff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " nlocrel " << dyst.nlocrel;
big_size = dyst.nlocrel;
big_size *= sizeof(struct MachO::relocation_info);
big_size += dyst.locreloff;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
}
static void PrintDyldInfoLoadCommand(MachO::dyld_info_command dc,
uint32_t object_size) {
if (dc.cmd == MachO::LC_DYLD_INFO)
outs() << " cmd LC_DYLD_INFO\n";
else
outs() << " cmd LC_DYLD_INFO_ONLY\n";
outs() << " cmdsize " << dc.cmdsize;
if (dc.cmdsize != sizeof(struct MachO::dyld_info_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " rebase_off " << dc.rebase_off;
if (dc.rebase_off > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " rebase_size " << dc.rebase_size;
uint64_t big_size;
big_size = dc.rebase_off;
big_size += dc.rebase_size;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " bind_off " << dc.bind_off;
if (dc.bind_off > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " bind_size " << dc.bind_size;
big_size = dc.bind_off;
big_size += dc.bind_size;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " weak_bind_off " << dc.weak_bind_off;
if (dc.weak_bind_off > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " weak_bind_size " << dc.weak_bind_size;
big_size = dc.weak_bind_off;
big_size += dc.weak_bind_size;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " lazy_bind_off " << dc.lazy_bind_off;
if (dc.lazy_bind_off > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " lazy_bind_size " << dc.lazy_bind_size;
big_size = dc.lazy_bind_off;
big_size += dc.lazy_bind_size;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " export_off " << dc.export_off;
if (dc.export_off > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " export_size " << dc.export_size;
big_size = dc.export_off;
big_size += dc.export_size;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
}
static void PrintDyldLoadCommand(MachO::dylinker_command dyld,
const char *Ptr) {
if (dyld.cmd == MachO::LC_ID_DYLINKER)
outs() << " cmd LC_ID_DYLINKER\n";
else if (dyld.cmd == MachO::LC_LOAD_DYLINKER)
outs() << " cmd LC_LOAD_DYLINKER\n";
else if (dyld.cmd == MachO::LC_DYLD_ENVIRONMENT)
outs() << " cmd LC_DYLD_ENVIRONMENT\n";
else
outs() << " cmd ?(" << dyld.cmd << ")\n";
outs() << " cmdsize " << dyld.cmdsize;
if (dyld.cmdsize < sizeof(struct MachO::dylinker_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
if (dyld.name >= dyld.cmdsize)
outs() << " name ?(bad offset " << dyld.name << ")\n";
else {
const char *P = (const char *)(Ptr) + dyld.name;
outs() << " name " << P << " (offset " << dyld.name << ")\n";
}
}
static void PrintUuidLoadCommand(MachO::uuid_command uuid) {
outs() << " cmd LC_UUID\n";
outs() << " cmdsize " << uuid.cmdsize;
if (uuid.cmdsize != sizeof(struct MachO::uuid_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " uuid ";
outs() << format("%02" PRIX32, uuid.uuid[0]);
outs() << format("%02" PRIX32, uuid.uuid[1]);
outs() << format("%02" PRIX32, uuid.uuid[2]);
outs() << format("%02" PRIX32, uuid.uuid[3]);
outs() << "-";
outs() << format("%02" PRIX32, uuid.uuid[4]);
outs() << format("%02" PRIX32, uuid.uuid[5]);
outs() << "-";
outs() << format("%02" PRIX32, uuid.uuid[6]);
outs() << format("%02" PRIX32, uuid.uuid[7]);
outs() << "-";
outs() << format("%02" PRIX32, uuid.uuid[8]);
outs() << format("%02" PRIX32, uuid.uuid[9]);
outs() << "-";
outs() << format("%02" PRIX32, uuid.uuid[10]);
outs() << format("%02" PRIX32, uuid.uuid[11]);
outs() << format("%02" PRIX32, uuid.uuid[12]);
outs() << format("%02" PRIX32, uuid.uuid[13]);
outs() << format("%02" PRIX32, uuid.uuid[14]);
outs() << format("%02" PRIX32, uuid.uuid[15]);
outs() << "\n";
}
static void PrintRpathLoadCommand(MachO::rpath_command rpath, const char *Ptr) {
outs() << " cmd LC_RPATH\n";
outs() << " cmdsize " << rpath.cmdsize;
if (rpath.cmdsize < sizeof(struct MachO::rpath_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
if (rpath.path >= rpath.cmdsize)
outs() << " path ?(bad offset " << rpath.path << ")\n";
else {
const char *P = (const char *)(Ptr) + rpath.path;
outs() << " path " << P << " (offset " << rpath.path << ")\n";
}
}
static void PrintVersionMinLoadCommand(MachO::version_min_command vd) {
if (vd.cmd == MachO::LC_VERSION_MIN_MACOSX)
outs() << " cmd LC_VERSION_MIN_MACOSX\n";
else if (vd.cmd == MachO::LC_VERSION_MIN_IPHONEOS)
outs() << " cmd LC_VERSION_MIN_IPHONEOS\n";
else
outs() << " cmd " << vd.cmd << " (?)\n";
outs() << " cmdsize " << vd.cmdsize;
if (vd.cmdsize != sizeof(struct MachO::version_min_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " version " << ((vd.version >> 16) & 0xffff) << "."
<< ((vd.version >> 8) & 0xff);
if ((vd.version & 0xff) != 0)
outs() << "." << (vd.version & 0xff);
outs() << "\n";
if (vd.sdk == 0)
outs() << " sdk n/a";
else {
outs() << " sdk " << ((vd.sdk >> 16) & 0xffff) << "."
<< ((vd.sdk >> 8) & 0xff);
}
if ((vd.sdk & 0xff) != 0)
outs() << "." << (vd.sdk & 0xff);
outs() << "\n";
}
static void PrintSourceVersionCommand(MachO::source_version_command sd) {
outs() << " cmd LC_SOURCE_VERSION\n";
outs() << " cmdsize " << sd.cmdsize;
if (sd.cmdsize != sizeof(struct MachO::source_version_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
uint64_t a = (sd.version >> 40) & 0xffffff;
uint64_t b = (sd.version >> 30) & 0x3ff;
uint64_t c = (sd.version >> 20) & 0x3ff;
uint64_t d = (sd.version >> 10) & 0x3ff;
uint64_t e = sd.version & 0x3ff;
outs() << " version " << a << "." << b;
if (e != 0)
outs() << "." << c << "." << d << "." << e;
else if (d != 0)
outs() << "." << c << "." << d;
else if (c != 0)
outs() << "." << c;
outs() << "\n";
}
static void PrintEntryPointCommand(MachO::entry_point_command ep) {
outs() << " cmd LC_MAIN\n";
outs() << " cmdsize " << ep.cmdsize;
if (ep.cmdsize != sizeof(struct MachO::entry_point_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " entryoff " << ep.entryoff << "\n";
outs() << " stacksize " << ep.stacksize << "\n";
}
static void PrintEncryptionInfoCommand(MachO::encryption_info_command ec,
uint32_t object_size) {
outs() << " cmd LC_ENCRYPTION_INFO\n";
outs() << " cmdsize " << ec.cmdsize;
if (ec.cmdsize != sizeof(struct MachO::encryption_info_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " cryptoff " << ec.cryptoff;
if (ec.cryptoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " cryptsize " << ec.cryptsize;
if (ec.cryptsize > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " cryptid " << ec.cryptid << "\n";
}
static void PrintEncryptionInfoCommand64(MachO::encryption_info_command_64 ec,
uint32_t object_size) {
outs() << " cmd LC_ENCRYPTION_INFO_64\n";
outs() << " cmdsize " << ec.cmdsize;
if (ec.cmdsize != sizeof(struct MachO::encryption_info_command_64))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " cryptoff " << ec.cryptoff;
if (ec.cryptoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " cryptsize " << ec.cryptsize;
if (ec.cryptsize > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " cryptid " << ec.cryptid << "\n";
outs() << " pad " << ec.pad << "\n";
}
static void PrintLinkerOptionCommand(MachO::linker_option_command lo,
const char *Ptr) {
outs() << " cmd LC_LINKER_OPTION\n";
outs() << " cmdsize " << lo.cmdsize;
if (lo.cmdsize < sizeof(struct MachO::linker_option_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " count " << lo.count << "\n";
const char *string = Ptr + sizeof(struct MachO::linker_option_command);
uint32_t left = lo.cmdsize - sizeof(struct MachO::linker_option_command);
uint32_t i = 0;
while (left > 0) {
while (*string == '\0' && left > 0) {
string++;
left--;
}
if (left > 0) {
i++;
outs() << " string #" << i << " " << format("%.*s\n", left, string);
uint32_t NullPos = StringRef(string, left).find('\0');
uint32_t len = std::min(NullPos, left) + 1;
string += len;
left -= len;
}
}
if (lo.count != i)
outs() << " count " << lo.count << " does not match number of strings "
<< i << "\n";
}
static void PrintSubFrameworkCommand(MachO::sub_framework_command sub,
const char *Ptr) {
outs() << " cmd LC_SUB_FRAMEWORK\n";
outs() << " cmdsize " << sub.cmdsize;
if (sub.cmdsize < sizeof(struct MachO::sub_framework_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
if (sub.umbrella < sub.cmdsize) {
const char *P = Ptr + sub.umbrella;
outs() << " umbrella " << P << " (offset " << sub.umbrella << ")\n";
} else {
outs() << " umbrella ?(bad offset " << sub.umbrella << ")\n";
}
}
static void PrintSubUmbrellaCommand(MachO::sub_umbrella_command sub,
const char *Ptr) {
outs() << " cmd LC_SUB_UMBRELLA\n";
outs() << " cmdsize " << sub.cmdsize;
if (sub.cmdsize < sizeof(struct MachO::sub_umbrella_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
if (sub.sub_umbrella < sub.cmdsize) {
const char *P = Ptr + sub.sub_umbrella;
outs() << " sub_umbrella " << P << " (offset " << sub.sub_umbrella << ")\n";
} else {
outs() << " sub_umbrella ?(bad offset " << sub.sub_umbrella << ")\n";
}
}
static void PrintSubLibraryCommand(MachO::sub_library_command sub,
const char *Ptr) {
outs() << " cmd LC_SUB_LIBRARY\n";
outs() << " cmdsize " << sub.cmdsize;
if (sub.cmdsize < sizeof(struct MachO::sub_library_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
if (sub.sub_library < sub.cmdsize) {
const char *P = Ptr + sub.sub_library;
outs() << " sub_library " << P << " (offset " << sub.sub_library << ")\n";
} else {
outs() << " sub_library ?(bad offset " << sub.sub_library << ")\n";
}
}
static void PrintSubClientCommand(MachO::sub_client_command sub,
const char *Ptr) {
outs() << " cmd LC_SUB_CLIENT\n";
outs() << " cmdsize " << sub.cmdsize;
if (sub.cmdsize < sizeof(struct MachO::sub_client_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
if (sub.client < sub.cmdsize) {
const char *P = Ptr + sub.client;
outs() << " client " << P << " (offset " << sub.client << ")\n";
} else {
outs() << " client ?(bad offset " << sub.client << ")\n";
}
}
static void PrintRoutinesCommand(MachO::routines_command r) {
outs() << " cmd LC_ROUTINES\n";
outs() << " cmdsize " << r.cmdsize;
if (r.cmdsize != sizeof(struct MachO::routines_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " init_address " << format("0x%08" PRIx32, r.init_address) << "\n";
outs() << " init_module " << r.init_module << "\n";
outs() << " reserved1 " << r.reserved1 << "\n";
outs() << " reserved2 " << r.reserved2 << "\n";
outs() << " reserved3 " << r.reserved3 << "\n";
outs() << " reserved4 " << r.reserved4 << "\n";
outs() << " reserved5 " << r.reserved5 << "\n";
outs() << " reserved6 " << r.reserved6 << "\n";
}
static void PrintRoutinesCommand64(MachO::routines_command_64 r) {
outs() << " cmd LC_ROUTINES_64\n";
outs() << " cmdsize " << r.cmdsize;
if (r.cmdsize != sizeof(struct MachO::routines_command_64))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " init_address " << format("0x%016" PRIx64, r.init_address) << "\n";
outs() << " init_module " << r.init_module << "\n";
outs() << " reserved1 " << r.reserved1 << "\n";
outs() << " reserved2 " << r.reserved2 << "\n";
outs() << " reserved3 " << r.reserved3 << "\n";
outs() << " reserved4 " << r.reserved4 << "\n";
outs() << " reserved5 " << r.reserved5 << "\n";
outs() << " reserved6 " << r.reserved6 << "\n";
}
static void Print_x86_thread_state64_t(MachO::x86_thread_state64_t &cpu64) {
outs() << " rax " << format("0x%016" PRIx64, cpu64.rax);
outs() << " rbx " << format("0x%016" PRIx64, cpu64.rbx);
outs() << " rcx " << format("0x%016" PRIx64, cpu64.rcx) << "\n";
outs() << " rdx " << format("0x%016" PRIx64, cpu64.rdx);
outs() << " rdi " << format("0x%016" PRIx64, cpu64.rdi);
outs() << " rsi " << format("0x%016" PRIx64, cpu64.rsi) << "\n";
outs() << " rbp " << format("0x%016" PRIx64, cpu64.rbp);
outs() << " rsp " << format("0x%016" PRIx64, cpu64.rsp);
outs() << " r8 " << format("0x%016" PRIx64, cpu64.r8) << "\n";
outs() << " r9 " << format("0x%016" PRIx64, cpu64.r9);
outs() << " r10 " << format("0x%016" PRIx64, cpu64.r10);
outs() << " r11 " << format("0x%016" PRIx64, cpu64.r11) << "\n";
outs() << " r12 " << format("0x%016" PRIx64, cpu64.r12);
outs() << " r13 " << format("0x%016" PRIx64, cpu64.r13);
outs() << " r14 " << format("0x%016" PRIx64, cpu64.r14) << "\n";
outs() << " r15 " << format("0x%016" PRIx64, cpu64.r15);
outs() << " rip " << format("0x%016" PRIx64, cpu64.rip) << "\n";
outs() << "rflags " << format("0x%016" PRIx64, cpu64.rflags);
outs() << " cs " << format("0x%016" PRIx64, cpu64.cs);
outs() << " fs " << format("0x%016" PRIx64, cpu64.fs) << "\n";
outs() << " gs " << format("0x%016" PRIx64, cpu64.gs) << "\n";
}
static void Print_mmst_reg(MachO::mmst_reg_t &r) {
uint32_t f;
outs() << "\t mmst_reg ";
for (f = 0; f < 10; f++)
outs() << format("%02" PRIx32, (r.mmst_reg[f] & 0xff)) << " ";
outs() << "\n";
outs() << "\t mmst_rsrv ";
for (f = 0; f < 6; f++)
outs() << format("%02" PRIx32, (r.mmst_rsrv[f] & 0xff)) << " ";
outs() << "\n";
}
static void Print_xmm_reg(MachO::xmm_reg_t &r) {
uint32_t f;
outs() << "\t xmm_reg ";
for (f = 0; f < 16; f++)
outs() << format("%02" PRIx32, (r.xmm_reg[f] & 0xff)) << " ";
outs() << "\n";
}
static void Print_x86_float_state_t(MachO::x86_float_state64_t &fpu) {
outs() << "\t fpu_reserved[0] " << fpu.fpu_reserved[0];
outs() << " fpu_reserved[1] " << fpu.fpu_reserved[1] << "\n";
outs() << "\t control: invalid " << fpu.fpu_fcw.invalid;
outs() << " denorm " << fpu.fpu_fcw.denorm;
outs() << " zdiv " << fpu.fpu_fcw.zdiv;
outs() << " ovrfl " << fpu.fpu_fcw.ovrfl;
outs() << " undfl " << fpu.fpu_fcw.undfl;
outs() << " precis " << fpu.fpu_fcw.precis << "\n";
outs() << "\t\t pc ";
if (fpu.fpu_fcw.pc == MachO::x86_FP_PREC_24B)
outs() << "FP_PREC_24B ";
else if (fpu.fpu_fcw.pc == MachO::x86_FP_PREC_53B)
outs() << "FP_PREC_53B ";
else if (fpu.fpu_fcw.pc == MachO::x86_FP_PREC_64B)
outs() << "FP_PREC_64B ";
else
outs() << fpu.fpu_fcw.pc << " ";
outs() << "rc ";
if (fpu.fpu_fcw.rc == MachO::x86_FP_RND_NEAR)
outs() << "FP_RND_NEAR ";
else if (fpu.fpu_fcw.rc == MachO::x86_FP_RND_DOWN)
outs() << "FP_RND_DOWN ";
else if (fpu.fpu_fcw.rc == MachO::x86_FP_RND_UP)
outs() << "FP_RND_UP ";
else if (fpu.fpu_fcw.rc == MachO::x86_FP_CHOP)
outs() << "FP_CHOP ";
outs() << "\n";
outs() << "\t status: invalid " << fpu.fpu_fsw.invalid;
outs() << " denorm " << fpu.fpu_fsw.denorm;
outs() << " zdiv " << fpu.fpu_fsw.zdiv;
outs() << " ovrfl " << fpu.fpu_fsw.ovrfl;
outs() << " undfl " << fpu.fpu_fsw.undfl;
outs() << " precis " << fpu.fpu_fsw.precis;
outs() << " stkflt " << fpu.fpu_fsw.stkflt << "\n";
outs() << "\t errsumm " << fpu.fpu_fsw.errsumm;
outs() << " c0 " << fpu.fpu_fsw.c0;
outs() << " c1 " << fpu.fpu_fsw.c1;
outs() << " c2 " << fpu.fpu_fsw.c2;
outs() << " tos " << fpu.fpu_fsw.tos;
outs() << " c3 " << fpu.fpu_fsw.c3;
outs() << " busy " << fpu.fpu_fsw.busy << "\n";
outs() << "\t fpu_ftw " << format("0x%02" PRIx32, fpu.fpu_ftw);
outs() << " fpu_rsrv1 " << format("0x%02" PRIx32, fpu.fpu_rsrv1);
outs() << " fpu_fop " << format("0x%04" PRIx32, fpu.fpu_fop);
outs() << " fpu_ip " << format("0x%08" PRIx32, fpu.fpu_ip) << "\n";
outs() << "\t fpu_cs " << format("0x%04" PRIx32, fpu.fpu_cs);
outs() << " fpu_rsrv2 " << format("0x%04" PRIx32, fpu.fpu_rsrv2);
outs() << " fpu_dp " << format("0x%08" PRIx32, fpu.fpu_dp);
outs() << " fpu_ds " << format("0x%04" PRIx32, fpu.fpu_ds) << "\n";
outs() << "\t fpu_rsrv3 " << format("0x%04" PRIx32, fpu.fpu_rsrv3);
outs() << " fpu_mxcsr " << format("0x%08" PRIx32, fpu.fpu_mxcsr);
outs() << " fpu_mxcsrmask " << format("0x%08" PRIx32, fpu.fpu_mxcsrmask);
outs() << "\n";
outs() << "\t fpu_stmm0:\n";
Print_mmst_reg(fpu.fpu_stmm0);
outs() << "\t fpu_stmm1:\n";
Print_mmst_reg(fpu.fpu_stmm1);
outs() << "\t fpu_stmm2:\n";
Print_mmst_reg(fpu.fpu_stmm2);
outs() << "\t fpu_stmm3:\n";
Print_mmst_reg(fpu.fpu_stmm3);
outs() << "\t fpu_stmm4:\n";
Print_mmst_reg(fpu.fpu_stmm4);
outs() << "\t fpu_stmm5:\n";
Print_mmst_reg(fpu.fpu_stmm5);
outs() << "\t fpu_stmm6:\n";
Print_mmst_reg(fpu.fpu_stmm6);
outs() << "\t fpu_stmm7:\n";
Print_mmst_reg(fpu.fpu_stmm7);
outs() << "\t fpu_xmm0:\n";
Print_xmm_reg(fpu.fpu_xmm0);
outs() << "\t fpu_xmm1:\n";
Print_xmm_reg(fpu.fpu_xmm1);
outs() << "\t fpu_xmm2:\n";
Print_xmm_reg(fpu.fpu_xmm2);
outs() << "\t fpu_xmm3:\n";
Print_xmm_reg(fpu.fpu_xmm3);
outs() << "\t fpu_xmm4:\n";
Print_xmm_reg(fpu.fpu_xmm4);
outs() << "\t fpu_xmm5:\n";
Print_xmm_reg(fpu.fpu_xmm5);
outs() << "\t fpu_xmm6:\n";
Print_xmm_reg(fpu.fpu_xmm6);
outs() << "\t fpu_xmm7:\n";
Print_xmm_reg(fpu.fpu_xmm7);
outs() << "\t fpu_xmm8:\n";
Print_xmm_reg(fpu.fpu_xmm8);
outs() << "\t fpu_xmm9:\n";
Print_xmm_reg(fpu.fpu_xmm9);
outs() << "\t fpu_xmm10:\n";
Print_xmm_reg(fpu.fpu_xmm10);
outs() << "\t fpu_xmm11:\n";
Print_xmm_reg(fpu.fpu_xmm11);
outs() << "\t fpu_xmm12:\n";
Print_xmm_reg(fpu.fpu_xmm12);
outs() << "\t fpu_xmm13:\n";
Print_xmm_reg(fpu.fpu_xmm13);
outs() << "\t fpu_xmm14:\n";
Print_xmm_reg(fpu.fpu_xmm14);
outs() << "\t fpu_xmm15:\n";
Print_xmm_reg(fpu.fpu_xmm15);
outs() << "\t fpu_rsrv4:\n";
for (uint32_t f = 0; f < 6; f++) {
outs() << "\t ";
for (uint32_t g = 0; g < 16; g++)
outs() << format("%02" PRIx32, fpu.fpu_rsrv4[f * g]) << " ";
outs() << "\n";
}
outs() << "\t fpu_reserved1 " << format("0x%08" PRIx32, fpu.fpu_reserved1);
outs() << "\n";
}
static void Print_x86_exception_state_t(MachO::x86_exception_state64_t &exc64) {
outs() << "\t trapno " << format("0x%08" PRIx32, exc64.trapno);
outs() << " err " << format("0x%08" PRIx32, exc64.err);
outs() << " faultvaddr " << format("0x%016" PRIx64, exc64.faultvaddr) << "\n";
}
static void PrintThreadCommand(MachO::thread_command t, const char *Ptr,
bool isLittleEndian, uint32_t cputype) {
if (t.cmd == MachO::LC_THREAD)
outs() << " cmd LC_THREAD\n";
else if (t.cmd == MachO::LC_UNIXTHREAD)
outs() << " cmd LC_UNIXTHREAD\n";
else
outs() << " cmd " << t.cmd << " (unknown)\n";
outs() << " cmdsize " << t.cmdsize;
if (t.cmdsize < sizeof(struct MachO::thread_command) + 2 * sizeof(uint32_t))
outs() << " Incorrect size\n";
else
outs() << "\n";
const char *begin = Ptr + sizeof(struct MachO::thread_command);
const char *end = Ptr + t.cmdsize;
uint32_t flavor, count, left;
if (cputype == MachO::CPU_TYPE_X86_64) {
while (begin < end) {
if (end - begin > (ptrdiff_t)sizeof(uint32_t)) {
memcpy((char *)&flavor, begin, sizeof(uint32_t));
begin += sizeof(uint32_t);
} else {
flavor = 0;
begin = end;
}
if (isLittleEndian != sys::IsLittleEndianHost)
sys::swapByteOrder(flavor);
if (end - begin > (ptrdiff_t)sizeof(uint32_t)) {
memcpy((char *)&count, begin, sizeof(uint32_t));
begin += sizeof(uint32_t);
} else {
count = 0;
begin = end;
}
if (isLittleEndian != sys::IsLittleEndianHost)
sys::swapByteOrder(count);
if (flavor == MachO::x86_THREAD_STATE64) {
outs() << " flavor x86_THREAD_STATE64\n";
if (count == MachO::x86_THREAD_STATE64_COUNT)
outs() << " count x86_THREAD_STATE64_COUNT\n";
else
outs() << " count " << count
<< " (not x86_THREAD_STATE64_COUNT)\n";
MachO::x86_thread_state64_t cpu64;
left = end - begin;
if (left >= sizeof(MachO::x86_thread_state64_t)) {
memcpy(&cpu64, begin, sizeof(MachO::x86_thread_state64_t));
begin += sizeof(MachO::x86_thread_state64_t);
} else {
memset(&cpu64, '\0', sizeof(MachO::x86_thread_state64_t));
memcpy(&cpu64, begin, left);
begin += left;
}
if (isLittleEndian != sys::IsLittleEndianHost)
swapStruct(cpu64);
Print_x86_thread_state64_t(cpu64);
} else if (flavor == MachO::x86_THREAD_STATE) {
outs() << " flavor x86_THREAD_STATE\n";
if (count == MachO::x86_THREAD_STATE_COUNT)
outs() << " count x86_THREAD_STATE_COUNT\n";
else
outs() << " count " << count
<< " (not x86_THREAD_STATE_COUNT)\n";
struct MachO::x86_thread_state_t ts;
left = end - begin;
if (left >= sizeof(MachO::x86_thread_state_t)) {
memcpy(&ts, begin, sizeof(MachO::x86_thread_state_t));
begin += sizeof(MachO::x86_thread_state_t);
} else {
memset(&ts, '\0', sizeof(MachO::x86_thread_state_t));
memcpy(&ts, begin, left);
begin += left;
}
if (isLittleEndian != sys::IsLittleEndianHost)
swapStruct(ts);
if (ts.tsh.flavor == MachO::x86_THREAD_STATE64) {
outs() << "\t tsh.flavor x86_THREAD_STATE64 ";
if (ts.tsh.count == MachO::x86_THREAD_STATE64_COUNT)
outs() << "tsh.count x86_THREAD_STATE64_COUNT\n";
else
outs() << "tsh.count " << ts.tsh.count
<< " (not x86_THREAD_STATE64_COUNT\n";
Print_x86_thread_state64_t(ts.uts.ts64);
} else {
outs() << "\t tsh.flavor " << ts.tsh.flavor << " tsh.count "
<< ts.tsh.count << "\n";
}
} else if (flavor == MachO::x86_FLOAT_STATE) {
outs() << " flavor x86_FLOAT_STATE\n";
if (count == MachO::x86_FLOAT_STATE_COUNT)
outs() << " count x86_FLOAT_STATE_COUNT\n";
else
outs() << " count " << count << " (not x86_FLOAT_STATE_COUNT)\n";
struct MachO::x86_float_state_t fs;
left = end - begin;
if (left >= sizeof(MachO::x86_float_state_t)) {
memcpy(&fs, begin, sizeof(MachO::x86_float_state_t));
begin += sizeof(MachO::x86_float_state_t);
} else {
memset(&fs, '\0', sizeof(MachO::x86_float_state_t));
memcpy(&fs, begin, left);
begin += left;
}
if (isLittleEndian != sys::IsLittleEndianHost)
swapStruct(fs);
if (fs.fsh.flavor == MachO::x86_FLOAT_STATE64) {
outs() << "\t fsh.flavor x86_FLOAT_STATE64 ";
if (fs.fsh.count == MachO::x86_FLOAT_STATE64_COUNT)
outs() << "fsh.count x86_FLOAT_STATE64_COUNT\n";
else
outs() << "fsh.count " << fs.fsh.count
<< " (not x86_FLOAT_STATE64_COUNT\n";
Print_x86_float_state_t(fs.ufs.fs64);
} else {
outs() << "\t fsh.flavor " << fs.fsh.flavor << " fsh.count "
<< fs.fsh.count << "\n";
}
} else if (flavor == MachO::x86_EXCEPTION_STATE) {
outs() << " flavor x86_EXCEPTION_STATE\n";
if (count == MachO::x86_EXCEPTION_STATE_COUNT)
outs() << " count x86_EXCEPTION_STATE_COUNT\n";
else
outs() << " count " << count
<< " (not x86_EXCEPTION_STATE_COUNT)\n";
struct MachO::x86_exception_state_t es;
left = end - begin;
if (left >= sizeof(MachO::x86_exception_state_t)) {
memcpy(&es, begin, sizeof(MachO::x86_exception_state_t));
begin += sizeof(MachO::x86_exception_state_t);
} else {
memset(&es, '\0', sizeof(MachO::x86_exception_state_t));
memcpy(&es, begin, left);
begin += left;
}
if (isLittleEndian != sys::IsLittleEndianHost)
swapStruct(es);
if (es.esh.flavor == MachO::x86_EXCEPTION_STATE64) {
outs() << "\t esh.flavor x86_EXCEPTION_STATE64\n";
if (es.esh.count == MachO::x86_EXCEPTION_STATE64_COUNT)
outs() << "\t esh.count x86_EXCEPTION_STATE64_COUNT\n";
else
outs() << "\t esh.count " << es.esh.count
<< " (not x86_EXCEPTION_STATE64_COUNT\n";
Print_x86_exception_state_t(es.ues.es64);
} else {
outs() << "\t esh.flavor " << es.esh.flavor << " esh.count "
<< es.esh.count << "\n";
}
} else {
outs() << " flavor " << flavor << " (unknown)\n";
outs() << " count " << count << "\n";
outs() << " state (unknown)\n";
begin += count * sizeof(uint32_t);
}
}
} else {
while (begin < end) {
if (end - begin > (ptrdiff_t)sizeof(uint32_t)) {
memcpy((char *)&flavor, begin, sizeof(uint32_t));
begin += sizeof(uint32_t);
} else {
flavor = 0;
begin = end;
}
if (isLittleEndian != sys::IsLittleEndianHost)
sys::swapByteOrder(flavor);
if (end - begin > (ptrdiff_t)sizeof(uint32_t)) {
memcpy((char *)&count, begin, sizeof(uint32_t));
begin += sizeof(uint32_t);
} else {
count = 0;
begin = end;
}
if (isLittleEndian != sys::IsLittleEndianHost)
sys::swapByteOrder(count);
outs() << " flavor " << flavor << "\n";
outs() << " count " << count << "\n";
outs() << " state (Unknown cputype/cpusubtype)\n";
begin += count * sizeof(uint32_t);
}
}
}
static void PrintDylibCommand(MachO::dylib_command dl, const char *Ptr) {
if (dl.cmd == MachO::LC_ID_DYLIB)
outs() << " cmd LC_ID_DYLIB\n";
else if (dl.cmd == MachO::LC_LOAD_DYLIB)
outs() << " cmd LC_LOAD_DYLIB\n";
else if (dl.cmd == MachO::LC_LOAD_WEAK_DYLIB)
outs() << " cmd LC_LOAD_WEAK_DYLIB\n";
else if (dl.cmd == MachO::LC_REEXPORT_DYLIB)
outs() << " cmd LC_REEXPORT_DYLIB\n";
else if (dl.cmd == MachO::LC_LAZY_LOAD_DYLIB)
outs() << " cmd LC_LAZY_LOAD_DYLIB\n";
else if (dl.cmd == MachO::LC_LOAD_UPWARD_DYLIB)
outs() << " cmd LC_LOAD_UPWARD_DYLIB\n";
else
outs() << " cmd " << dl.cmd << " (unknown)\n";
outs() << " cmdsize " << dl.cmdsize;
if (dl.cmdsize < sizeof(struct MachO::dylib_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
if (dl.dylib.name < dl.cmdsize) {
const char *P = (const char *)(Ptr) + dl.dylib.name;
outs() << " name " << P << " (offset " << dl.dylib.name << ")\n";
} else {
outs() << " name ?(bad offset " << dl.dylib.name << ")\n";
}
outs() << " time stamp " << dl.dylib.timestamp << " ";
time_t t = dl.dylib.timestamp;
outs() << ctime(&t);
outs() << " current version ";
if (dl.dylib.current_version == 0xffffffff)
outs() << "n/a\n";
else
outs() << ((dl.dylib.current_version >> 16) & 0xffff) << "."
<< ((dl.dylib.current_version >> 8) & 0xff) << "."
<< (dl.dylib.current_version & 0xff) << "\n";
outs() << "compatibility version ";
if (dl.dylib.compatibility_version == 0xffffffff)
outs() << "n/a\n";
else
outs() << ((dl.dylib.compatibility_version >> 16) & 0xffff) << "."
<< ((dl.dylib.compatibility_version >> 8) & 0xff) << "."
<< (dl.dylib.compatibility_version & 0xff) << "\n";
}
static void PrintLinkEditDataCommand(MachO::linkedit_data_command ld,
uint32_t object_size) {
if (ld.cmd == MachO::LC_CODE_SIGNATURE)
outs() << " cmd LC_FUNCTION_STARTS\n";
else if (ld.cmd == MachO::LC_SEGMENT_SPLIT_INFO)
outs() << " cmd LC_SEGMENT_SPLIT_INFO\n";
else if (ld.cmd == MachO::LC_FUNCTION_STARTS)
outs() << " cmd LC_FUNCTION_STARTS\n";
else if (ld.cmd == MachO::LC_DATA_IN_CODE)
outs() << " cmd LC_DATA_IN_CODE\n";
else if (ld.cmd == MachO::LC_DYLIB_CODE_SIGN_DRS)
outs() << " cmd LC_DYLIB_CODE_SIGN_DRS\n";
else if (ld.cmd == MachO::LC_LINKER_OPTIMIZATION_HINT)
outs() << " cmd LC_LINKER_OPTIMIZATION_HINT\n";
else
outs() << " cmd " << ld.cmd << " (?)\n";
outs() << " cmdsize " << ld.cmdsize;
if (ld.cmdsize != sizeof(struct MachO::linkedit_data_command))
outs() << " Incorrect size\n";
else
outs() << "\n";
outs() << " dataoff " << ld.dataoff;
if (ld.dataoff > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
outs() << " datasize " << ld.datasize;
uint64_t big_size = ld.dataoff;
big_size += ld.datasize;
if (big_size > object_size)
outs() << " (past end of file)\n";
else
outs() << "\n";
}
static void PrintLoadCommands(const MachOObjectFile *Obj, uint32_t filetype,
uint32_t cputype, bool verbose) {
StringRef Buf = Obj->getData();
unsigned Index = 0;
for (const auto &Command : Obj->load_commands()) {
outs() << "Load command " << Index++ << "\n";
if (Command.C.cmd == MachO::LC_SEGMENT) {
MachO::segment_command SLC = Obj->getSegmentLoadCommand(Command);
const char *sg_segname = SLC.segname;
PrintSegmentCommand(SLC.cmd, SLC.cmdsize, SLC.segname, SLC.vmaddr,
SLC.vmsize, SLC.fileoff, SLC.filesize, SLC.maxprot,
SLC.initprot, SLC.nsects, SLC.flags, Buf.size(),
verbose);
for (unsigned j = 0; j < SLC.nsects; j++) {
MachO::section S = Obj->getSection(Command, j);
PrintSection(S.sectname, S.segname, S.addr, S.size, S.offset, S.align,
S.reloff, S.nreloc, S.flags, S.reserved1, S.reserved2,
SLC.cmd, sg_segname, filetype, Buf.size(), verbose);
}
} else if (Command.C.cmd == MachO::LC_SEGMENT_64) {
MachO::segment_command_64 SLC_64 = Obj->getSegment64LoadCommand(Command);
const char *sg_segname = SLC_64.segname;
PrintSegmentCommand(SLC_64.cmd, SLC_64.cmdsize, SLC_64.segname,
SLC_64.vmaddr, SLC_64.vmsize, SLC_64.fileoff,
SLC_64.filesize, SLC_64.maxprot, SLC_64.initprot,
SLC_64.nsects, SLC_64.flags, Buf.size(), verbose);
for (unsigned j = 0; j < SLC_64.nsects; j++) {
MachO::section_64 S_64 = Obj->getSection64(Command, j);
PrintSection(S_64.sectname, S_64.segname, S_64.addr, S_64.size,
S_64.offset, S_64.align, S_64.reloff, S_64.nreloc,
S_64.flags, S_64.reserved1, S_64.reserved2, SLC_64.cmd,
sg_segname, filetype, Buf.size(), verbose);
}
} else if (Command.C.cmd == MachO::LC_SYMTAB) {
MachO::symtab_command Symtab = Obj->getSymtabLoadCommand();
PrintSymtabLoadCommand(Symtab, Obj->is64Bit(), Buf.size());
} else if (Command.C.cmd == MachO::LC_DYSYMTAB) {
MachO::dysymtab_command Dysymtab = Obj->getDysymtabLoadCommand();
MachO::symtab_command Symtab = Obj->getSymtabLoadCommand();
PrintDysymtabLoadCommand(Dysymtab, Symtab.nsyms, Buf.size(),
Obj->is64Bit());
} else if (Command.C.cmd == MachO::LC_DYLD_INFO ||
Command.C.cmd == MachO::LC_DYLD_INFO_ONLY) {
MachO::dyld_info_command DyldInfo = Obj->getDyldInfoLoadCommand(Command);
PrintDyldInfoLoadCommand(DyldInfo, Buf.size());
} else if (Command.C.cmd == MachO::LC_LOAD_DYLINKER ||
Command.C.cmd == MachO::LC_ID_DYLINKER ||
Command.C.cmd == MachO::LC_DYLD_ENVIRONMENT) {
MachO::dylinker_command Dyld = Obj->getDylinkerCommand(Command);
PrintDyldLoadCommand(Dyld, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_UUID) {
MachO::uuid_command Uuid = Obj->getUuidCommand(Command);
PrintUuidLoadCommand(Uuid);
} else if (Command.C.cmd == MachO::LC_RPATH) {
MachO::rpath_command Rpath = Obj->getRpathCommand(Command);
PrintRpathLoadCommand(Rpath, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_VERSION_MIN_MACOSX ||
Command.C.cmd == MachO::LC_VERSION_MIN_IPHONEOS) {
MachO::version_min_command Vd = Obj->getVersionMinLoadCommand(Command);
PrintVersionMinLoadCommand(Vd);
} else if (Command.C.cmd == MachO::LC_SOURCE_VERSION) {
MachO::source_version_command Sd = Obj->getSourceVersionCommand(Command);
PrintSourceVersionCommand(Sd);
} else if (Command.C.cmd == MachO::LC_MAIN) {
MachO::entry_point_command Ep = Obj->getEntryPointCommand(Command);
PrintEntryPointCommand(Ep);
} else if (Command.C.cmd == MachO::LC_ENCRYPTION_INFO) {
MachO::encryption_info_command Ei =
Obj->getEncryptionInfoCommand(Command);
PrintEncryptionInfoCommand(Ei, Buf.size());
} else if (Command.C.cmd == MachO::LC_ENCRYPTION_INFO_64) {
MachO::encryption_info_command_64 Ei =
Obj->getEncryptionInfoCommand64(Command);
PrintEncryptionInfoCommand64(Ei, Buf.size());
} else if (Command.C.cmd == MachO::LC_LINKER_OPTION) {
MachO::linker_option_command Lo =
Obj->getLinkerOptionLoadCommand(Command);
PrintLinkerOptionCommand(Lo, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_SUB_FRAMEWORK) {
MachO::sub_framework_command Sf = Obj->getSubFrameworkCommand(Command);
PrintSubFrameworkCommand(Sf, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_SUB_UMBRELLA) {
MachO::sub_umbrella_command Sf = Obj->getSubUmbrellaCommand(Command);
PrintSubUmbrellaCommand(Sf, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_SUB_LIBRARY) {
MachO::sub_library_command Sl = Obj->getSubLibraryCommand(Command);
PrintSubLibraryCommand(Sl, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_SUB_CLIENT) {
MachO::sub_client_command Sc = Obj->getSubClientCommand(Command);
PrintSubClientCommand(Sc, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_ROUTINES) {
MachO::routines_command Rc = Obj->getRoutinesCommand(Command);
PrintRoutinesCommand(Rc);
} else if (Command.C.cmd == MachO::LC_ROUTINES_64) {
MachO::routines_command_64 Rc = Obj->getRoutinesCommand64(Command);
PrintRoutinesCommand64(Rc);
} else if (Command.C.cmd == MachO::LC_THREAD ||
Command.C.cmd == MachO::LC_UNIXTHREAD) {
MachO::thread_command Tc = Obj->getThreadCommand(Command);
PrintThreadCommand(Tc, Command.Ptr, Obj->isLittleEndian(), cputype);
} else if (Command.C.cmd == MachO::LC_LOAD_DYLIB ||
Command.C.cmd == MachO::LC_ID_DYLIB ||
Command.C.cmd == MachO::LC_LOAD_WEAK_DYLIB ||
Command.C.cmd == MachO::LC_REEXPORT_DYLIB ||
Command.C.cmd == MachO::LC_LAZY_LOAD_DYLIB ||
Command.C.cmd == MachO::LC_LOAD_UPWARD_DYLIB) {
MachO::dylib_command Dl = Obj->getDylibIDLoadCommand(Command);
PrintDylibCommand(Dl, Command.Ptr);
} else if (Command.C.cmd == MachO::LC_CODE_SIGNATURE ||
Command.C.cmd == MachO::LC_SEGMENT_SPLIT_INFO ||
Command.C.cmd == MachO::LC_FUNCTION_STARTS ||
Command.C.cmd == MachO::LC_DATA_IN_CODE ||
Command.C.cmd == MachO::LC_DYLIB_CODE_SIGN_DRS ||
Command.C.cmd == MachO::LC_LINKER_OPTIMIZATION_HINT) {
MachO::linkedit_data_command Ld =
Obj->getLinkeditDataLoadCommand(Command);
PrintLinkEditDataCommand(Ld, Buf.size());
} else {
outs() << " cmd ?(" << format("0x%08" PRIx32, Command.C.cmd)
<< ")\n";
outs() << " cmdsize " << Command.C.cmdsize << "\n";
// TODO: get and print the raw bytes of the load command.
}
// TODO: print all the other kinds of load commands.
}
}
static void getAndPrintMachHeader(const MachOObjectFile *Obj,
uint32_t &filetype, uint32_t &cputype,
bool verbose) {
if (Obj->is64Bit()) {
MachO::mach_header_64 H_64;
H_64 = Obj->getHeader64();
PrintMachHeader(H_64.magic, H_64.cputype, H_64.cpusubtype, H_64.filetype,
H_64.ncmds, H_64.sizeofcmds, H_64.flags, verbose);
filetype = H_64.filetype;
cputype = H_64.cputype;
} else {
MachO::mach_header H;
H = Obj->getHeader();
PrintMachHeader(H.magic, H.cputype, H.cpusubtype, H.filetype, H.ncmds,
H.sizeofcmds, H.flags, verbose);
filetype = H.filetype;
cputype = H.cputype;
}
}
void llvm::printMachOFileHeader(const object::ObjectFile *Obj) {
const MachOObjectFile *file = dyn_cast<const MachOObjectFile>(Obj);
uint32_t filetype = 0;
uint32_t cputype = 0;
getAndPrintMachHeader(file, filetype, cputype, !NonVerbose);
PrintLoadCommands(file, filetype, cputype, !NonVerbose);
}
//===----------------------------------------------------------------------===//
// export trie dumping
//===----------------------------------------------------------------------===//
void llvm::printMachOExportsTrie(const object::MachOObjectFile *Obj) {
2014-09-03 02:50:24 +08:00
for (const llvm::object::ExportEntry &Entry : Obj->exports()) {
uint64_t Flags = Entry.flags();
bool ReExport = (Flags & MachO::EXPORT_SYMBOL_FLAGS_REEXPORT);
bool WeakDef = (Flags & MachO::EXPORT_SYMBOL_FLAGS_WEAK_DEFINITION);
bool ThreadLocal = ((Flags & MachO::EXPORT_SYMBOL_FLAGS_KIND_MASK) ==
MachO::EXPORT_SYMBOL_FLAGS_KIND_THREAD_LOCAL);
bool Abs = ((Flags & MachO::EXPORT_SYMBOL_FLAGS_KIND_MASK) ==
MachO::EXPORT_SYMBOL_FLAGS_KIND_ABSOLUTE);
bool Resolver = (Flags & MachO::EXPORT_SYMBOL_FLAGS_STUB_AND_RESOLVER);
if (ReExport)
outs() << "[re-export] ";
else
outs() << format("0x%08llX ",
Entry.address()); // FIXME:add in base address
2014-09-03 02:50:24 +08:00
outs() << Entry.name();
if (WeakDef || ThreadLocal || Resolver || Abs) {
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bool NeedsComma = false;
outs() << " [";
if (WeakDef) {
outs() << "weak_def";
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NeedsComma = true;
}
if (ThreadLocal) {
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if (NeedsComma)
outs() << ", ";
outs() << "per-thread";
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NeedsComma = true;
}
if (Abs) {
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if (NeedsComma)
outs() << ", ";
outs() << "absolute";
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NeedsComma = true;
}
if (Resolver) {
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if (NeedsComma)
outs() << ", ";
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outs() << format("resolver=0x%08llX", Entry.other());
NeedsComma = true;
}
outs() << "]";
}
if (ReExport) {
StringRef DylibName = "unknown";
2014-09-03 02:50:24 +08:00
int Ordinal = Entry.other() - 1;
Obj->getLibraryShortNameByIndex(Ordinal, DylibName);
if (Entry.otherName().empty())
outs() << " (from " << DylibName << ")";
else
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outs() << " (" << Entry.otherName() << " from " << DylibName << ")";
}
outs() << "\n";
}
}
//===----------------------------------------------------------------------===//
// rebase table dumping
//===----------------------------------------------------------------------===//
namespace {
class SegInfo {
public:
SegInfo(const object::MachOObjectFile *Obj);
StringRef segmentName(uint32_t SegIndex);
StringRef sectionName(uint32_t SegIndex, uint64_t SegOffset);
uint64_t address(uint32_t SegIndex, uint64_t SegOffset);
private:
struct SectionInfo {
uint64_t Address;
uint64_t Size;
StringRef SectionName;
StringRef SegmentName;
uint64_t OffsetInSegment;
uint64_t SegmentStartAddress;
uint32_t SegmentIndex;
};
const SectionInfo &findSection(uint32_t SegIndex, uint64_t SegOffset);
SmallVector<SectionInfo, 32> Sections;
};
}
SegInfo::SegInfo(const object::MachOObjectFile *Obj) {
// Build table of sections so segIndex/offset pairs can be translated.
uint32_t CurSegIndex = Obj->hasPageZeroSegment() ? 1 : 0;
StringRef CurSegName;
uint64_t CurSegAddress;
for (const SectionRef &Section : Obj->sections()) {
SectionInfo Info;
if (error(Section.getName(Info.SectionName)))
return;
Info.Address = Section.getAddress();
Info.Size = Section.getSize();
Info.SegmentName =
Obj->getSectionFinalSegmentName(Section.getRawDataRefImpl());
if (!Info.SegmentName.equals(CurSegName)) {
++CurSegIndex;
CurSegName = Info.SegmentName;
CurSegAddress = Info.Address;
}
Info.SegmentIndex = CurSegIndex - 1;
Info.OffsetInSegment = Info.Address - CurSegAddress;
Info.SegmentStartAddress = CurSegAddress;
Sections.push_back(Info);
}
}
StringRef SegInfo::segmentName(uint32_t SegIndex) {
for (const SectionInfo &SI : Sections) {
if (SI.SegmentIndex == SegIndex)
return SI.SegmentName;
}
llvm_unreachable("invalid segIndex");
}
const SegInfo::SectionInfo &SegInfo::findSection(uint32_t SegIndex,
uint64_t OffsetInSeg) {
for (const SectionInfo &SI : Sections) {
if (SI.SegmentIndex != SegIndex)
continue;
if (SI.OffsetInSegment > OffsetInSeg)
continue;
if (OffsetInSeg >= (SI.OffsetInSegment + SI.Size))
continue;
return SI;
}
llvm_unreachable("segIndex and offset not in any section");
}
StringRef SegInfo::sectionName(uint32_t SegIndex, uint64_t OffsetInSeg) {
return findSection(SegIndex, OffsetInSeg).SectionName;
}
uint64_t SegInfo::address(uint32_t SegIndex, uint64_t OffsetInSeg) {
const SectionInfo &SI = findSection(SegIndex, OffsetInSeg);
return SI.SegmentStartAddress + OffsetInSeg;
}
void llvm::printMachORebaseTable(const object::MachOObjectFile *Obj) {
// Build table of sections so names can used in final output.
SegInfo sectionTable(Obj);
outs() << "segment section address type\n";
for (const llvm::object::MachORebaseEntry &Entry : Obj->rebaseTable()) {
uint32_t SegIndex = Entry.segmentIndex();
uint64_t OffsetInSeg = Entry.segmentOffset();
StringRef SegmentName = sectionTable.segmentName(SegIndex);
StringRef SectionName = sectionTable.sectionName(SegIndex, OffsetInSeg);
uint64_t Address = sectionTable.address(SegIndex, OffsetInSeg);
// Table lines look like: __DATA __nl_symbol_ptr 0x0000F00C pointer
outs() << format("%-8s %-18s 0x%08" PRIX64 " %s\n",
SegmentName.str().c_str(), SectionName.str().c_str(),
Address, Entry.typeName().str().c_str());
}
}
static StringRef ordinalName(const object::MachOObjectFile *Obj, int Ordinal) {
StringRef DylibName;
switch (Ordinal) {
case MachO::BIND_SPECIAL_DYLIB_SELF:
return "this-image";
case MachO::BIND_SPECIAL_DYLIB_MAIN_EXECUTABLE:
return "main-executable";
case MachO::BIND_SPECIAL_DYLIB_FLAT_LOOKUP:
return "flat-namespace";
default:
if (Ordinal > 0) {
std::error_code EC =
Obj->getLibraryShortNameByIndex(Ordinal - 1, DylibName);
if (EC)
return "<<bad library ordinal>>";
return DylibName;
}
}
return "<<unknown special ordinal>>";
}
//===----------------------------------------------------------------------===//
// bind table dumping
//===----------------------------------------------------------------------===//
void llvm::printMachOBindTable(const object::MachOObjectFile *Obj) {
// Build table of sections so names can used in final output.
SegInfo sectionTable(Obj);
outs() << "segment section address type "
"addend dylib symbol\n";
for (const llvm::object::MachOBindEntry &Entry : Obj->bindTable()) {
uint32_t SegIndex = Entry.segmentIndex();
uint64_t OffsetInSeg = Entry.segmentOffset();
StringRef SegmentName = sectionTable.segmentName(SegIndex);
StringRef SectionName = sectionTable.sectionName(SegIndex, OffsetInSeg);
uint64_t Address = sectionTable.address(SegIndex, OffsetInSeg);
// Table lines look like:
// __DATA __got 0x00012010 pointer 0 libSystem ___stack_chk_guard
StringRef Attr;
if (Entry.flags() & MachO::BIND_SYMBOL_FLAGS_WEAK_IMPORT)
Attr = " (weak_import)";
outs() << left_justify(SegmentName, 8) << " "
<< left_justify(SectionName, 18) << " "
<< format_hex(Address, 10, true) << " "
<< left_justify(Entry.typeName(), 8) << " "
<< format_decimal(Entry.addend(), 8) << " "
<< left_justify(ordinalName(Obj, Entry.ordinal()), 16) << " "
<< Entry.symbolName() << Attr << "\n";
}
}
//===----------------------------------------------------------------------===//
// lazy bind table dumping
//===----------------------------------------------------------------------===//
void llvm::printMachOLazyBindTable(const object::MachOObjectFile *Obj) {
// Build table of sections so names can used in final output.
SegInfo sectionTable(Obj);
outs() << "segment section address "
"dylib symbol\n";
for (const llvm::object::MachOBindEntry &Entry : Obj->lazyBindTable()) {
uint32_t SegIndex = Entry.segmentIndex();
uint64_t OffsetInSeg = Entry.segmentOffset();
StringRef SegmentName = sectionTable.segmentName(SegIndex);
StringRef SectionName = sectionTable.sectionName(SegIndex, OffsetInSeg);
uint64_t Address = sectionTable.address(SegIndex, OffsetInSeg);
// Table lines look like:
// __DATA __got 0x00012010 libSystem ___stack_chk_guard
outs() << left_justify(SegmentName, 8) << " "
<< left_justify(SectionName, 18) << " "
<< format_hex(Address, 10, true) << " "
<< left_justify(ordinalName(Obj, Entry.ordinal()), 16) << " "
<< Entry.symbolName() << "\n";
}
}
//===----------------------------------------------------------------------===//
// weak bind table dumping
//===----------------------------------------------------------------------===//
void llvm::printMachOWeakBindTable(const object::MachOObjectFile *Obj) {
// Build table of sections so names can used in final output.
SegInfo sectionTable(Obj);
outs() << "segment section address "
"type addend symbol\n";
for (const llvm::object::MachOBindEntry &Entry : Obj->weakBindTable()) {
// Strong symbols don't have a location to update.
if (Entry.flags() & MachO::BIND_SYMBOL_FLAGS_NON_WEAK_DEFINITION) {
outs() << " strong "
<< Entry.symbolName() << "\n";
continue;
}
uint32_t SegIndex = Entry.segmentIndex();
uint64_t OffsetInSeg = Entry.segmentOffset();
StringRef SegmentName = sectionTable.segmentName(SegIndex);
StringRef SectionName = sectionTable.sectionName(SegIndex, OffsetInSeg);
uint64_t Address = sectionTable.address(SegIndex, OffsetInSeg);
// Table lines look like:
// __DATA __data 0x00001000 pointer 0 _foo
outs() << left_justify(SegmentName, 8) << " "
<< left_justify(SectionName, 18) << " "
<< format_hex(Address, 10, true) << " "
<< left_justify(Entry.typeName(), 8) << " "
<< format_decimal(Entry.addend(), 8) << " " << Entry.symbolName()
<< "\n";
}
}
// get_dyld_bind_info_symbolname() is used for disassembly and passed an
// address, ReferenceValue, in the Mach-O file and looks in the dyld bind
// information for that address. If the address is found its binding symbol
// name is returned. If not nullptr is returned.
static const char *get_dyld_bind_info_symbolname(uint64_t ReferenceValue,
struct DisassembleInfo *info) {
if (info->bindtable == nullptr) {
info->bindtable = new (BindTable);
SegInfo sectionTable(info->O);
for (const llvm::object::MachOBindEntry &Entry : info->O->bindTable()) {
uint32_t SegIndex = Entry.segmentIndex();
uint64_t OffsetInSeg = Entry.segmentOffset();
uint64_t Address = sectionTable.address(SegIndex, OffsetInSeg);
const char *SymbolName = nullptr;
StringRef name = Entry.symbolName();
if (!name.empty())
SymbolName = name.data();
info->bindtable->push_back(std::make_pair(Address, SymbolName));
}
}
for (bind_table_iterator BI = info->bindtable->begin(),
BE = info->bindtable->end();
BI != BE; ++BI) {
uint64_t Address = BI->first;
if (ReferenceValue == Address) {
const char *SymbolName = BI->second;
return SymbolName;
}
}
return nullptr;
}