lib/ExecutionEngine/RuntimeDyld/RuntimeDyldMachO.cpp - llvm - Git at Google

 //===-- RuntimeDyldMachO.cpp - Run-time dynamic linker for MC-JIT ------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // Implementation of the MC-JIT runtime dynamic linker.
 //
 //===----------------------------------------------------------------------===//

 #define DEBUG_TYPE "dyld"
 #include "llvm/ADT/OwningPtr.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/ADT/STLExtras.h"
 #include "RuntimeDyldImpl.h"
 using namespace llvm;
 using namespace llvm::object;

 namespace llvm {

 bool RuntimeDyldMachO::
 resolveRelocation(uint8_t *Address, uint8_t *Value, bool isPCRel,
                   unsigned Type, unsigned Size) {
   // This just dispatches to the proper target specific routine.
   switch (CPUType) {
   default: assert(0 && "Unsupported CPU type!");
   case mach::CTM_x86_64:
     return resolveX86_64Relocation((uintptr_t)Address, (uintptr_t)Value,
                                    isPCRel, Type, Size);
   case mach::CTM_ARM:
     return resolveARMRelocation((uintptr_t)Address, (uintptr_t)Value,
                                 isPCRel, Type, Size);
   }
   llvm_unreachable("");
 }

 bool RuntimeDyldMachO::
 resolveX86_64Relocation(uintptr_t Address, uintptr_t Value,
                         bool isPCRel, unsigned Type,
                         unsigned Size) {
   // If the relocation is PC-relative, the value to be encoded is the
   // pointer difference.
   if (isPCRel)
     // FIXME: It seems this value needs to be adjusted by 4 for an effective PC
     // address. Is that expected? Only for branches, perhaps?
     Value -= Address + 4;

   switch(Type) {
   default:
     llvm_unreachable("Invalid relocation type!");
   case macho::RIT_X86_64_Unsigned:
   case macho::RIT_X86_64_Branch: {
     // Mask in the target value a byte at a time (we don't have an alignment
     // guarantee for the target address, so this is safest).
     uint8_t *p = (uint8_t*)Address;
     for (unsigned i = 0; i < Size; ++i) {
       *p++ = (uint8_t)Value;
       Value >>= 8;
     }
     return false;
   }
   case macho::RIT_X86_64_Signed:
   case macho::RIT_X86_64_GOTLoad:
   case macho::RIT_X86_64_GOT:
   case macho::RIT_X86_64_Subtractor:
   case macho::RIT_X86_64_Signed1:
   case macho::RIT_X86_64_Signed2:
   case macho::RIT_X86_64_Signed4:
   case macho::RIT_X86_64_TLV:
     return Error("Relocation type not implemented yet!");
   }
   return false;
 }

 bool RuntimeDyldMachO::resolveARMRelocation(uintptr_t Address, uintptr_t Value,
                                          bool isPCRel, unsigned Type,
                                          unsigned Size) {
   // If the relocation is PC-relative, the value to be encoded is the
   // pointer difference.
   if (isPCRel) {
     Value -= Address;
     // ARM PCRel relocations have an effective-PC offset of two instructions
     // (four bytes in Thumb mode, 8 bytes in ARM mode).
     // FIXME: For now, assume ARM mode.
     Value -= 8;
   }

   switch(Type) {
   default:
     llvm_unreachable("Invalid relocation type!");
   case macho::RIT_Vanilla: {
     llvm_unreachable("Invalid relocation type!");
     // Mask in the target value a byte at a time (we don't have an alignment
     // guarantee for the target address, so this is safest).
     uint8_t *p = (uint8_t*)Address;
     for (unsigned i = 0; i < Size; ++i) {
       *p++ = (uint8_t)Value;
       Value >>= 8;
     }
     break;
   }
   case macho::RIT_ARM_Branch24Bit: {
     // Mask the value into the target address. We know instructions are
     // 32-bit aligned, so we can do it all at once.
     uint32_t *p = (uint32_t*)Address;
     // The low two bits of the value are not encoded.
     Value >>= 2;
     // Mask the value to 24 bits.
     Value &= 0xffffff;
     // FIXME: If the destination is a Thumb function (and the instruction
     // is a non-predicated BL instruction), we need to change it to a BLX
     // instruction instead.

     // Insert the value into the instruction.
     *p = (*p & ~0xffffff) | Value;
     break;
   }
   case macho::RIT_ARM_ThumbBranch22Bit:
   case macho::RIT_ARM_ThumbBranch32Bit:
   case macho::RIT_ARM_Half:
   case macho::RIT_ARM_HalfDifference:
   case macho::RIT_Pair:
   case macho::RIT_Difference:
   case macho::RIT_ARM_LocalDifference:
   case macho::RIT_ARM_PreboundLazyPointer:
     return Error("Relocation type not implemented yet!");
   }
   return false;
 }

 bool RuntimeDyldMachO::
 loadSegment32(const MachOObject *Obj,
               const MachOObject::LoadCommandInfo *SegmentLCI,
               const InMemoryStruct<macho::SymtabLoadCommand> &SymtabLC) {
   InMemoryStruct<macho::SegmentLoadCommand> SegmentLC;
   Obj->ReadSegmentLoadCommand(*SegmentLCI, SegmentLC);
   if (!SegmentLC)
     return Error("unable to load segment load command");

   for (unsigned SectNum = 0; SectNum != SegmentLC->NumSections; ++SectNum) {
     InMemoryStruct<macho::Section> Sect;
     Obj->ReadSection(*SegmentLCI, SectNum, Sect);
     if (!Sect)
       return Error("unable to load section: '" + Twine(SectNum) + "'");

     // FIXME: For the time being, we're only loading text segments.
     if (Sect->Flags != 0x80000400)
       continue;

     // Address and names of symbols in the section.
     typedef std::pair<uint64_t, StringRef> SymbolEntry;
     SmallVector<SymbolEntry, 64> Symbols;
     // Index of all the names, in this section or not. Used when we're
     // dealing with relocation entries.
     SmallVector<StringRef, 64> SymbolNames;
     for (unsigned i = 0; i != SymtabLC->NumSymbolTableEntries; ++i) {
       InMemoryStruct<macho::SymbolTableEntry> STE;
       Obj->ReadSymbolTableEntry(SymtabLC->SymbolTableOffset, i, STE);
       if (!STE)
         return Error("unable to read symbol: '" + Twine(i) + "'");
       if (STE->SectionIndex > SegmentLC->NumSections)
         return Error("invalid section index for symbol: '" + Twine(i) + "'");
       // Get the symbol name.
       StringRef Name = Obj->getStringAtIndex(STE->StringIndex);
       SymbolNames.push_back(Name);

       // Just skip symbols not defined in this section.
       if ((unsigned)STE->SectionIndex - 1 != SectNum)
         continue;

       // FIXME: Check the symbol type and flags.
       if (STE->Type != 0xF)  // external, defined in this section.
         continue;
       // Flags == 0x8 marks a thumb function for ARM, which is fine as it
       // doesn't require any special handling here.
       if (STE->Flags != 0x0 && STE->Flags != 0x8)
         continue;

       // Remember the symbol.
       Symbols.push_back(SymbolEntry(STE->Value, Name));

       DEBUG(dbgs() << "Function sym: '" << Name << "' @ " <<
             (Sect->Address + STE->Value) << "\n");
     }
     // Sort the symbols by address, just in case they didn't come in that way.
     array_pod_sort(Symbols.begin(), Symbols.end());

     // If there weren't any functions (odd, but just in case...)
     if (!Symbols.size())
       continue;

     // Extract the function data.
     uint8_t *Base = (uint8_t*)Obj->getData(SegmentLC->FileOffset,
                                            SegmentLC->FileSize).data();
     for (unsigned i = 0, e = Symbols.size() - 1; i != e; ++i) {
       uint64_t StartOffset = Sect->Address + Symbols[i].first;
       uint64_t EndOffset = Symbols[i + 1].first - 1;
       DEBUG(dbgs() << "Extracting function: " << Symbols[i].second
                    << " from [" << StartOffset << ", " << EndOffset << "]\n");
       extractFunction(Symbols[i].second, Base + StartOffset, Base + EndOffset);
     }
     // The last symbol we do after since the end address is calculated
     // differently because there is no next symbol to reference.
     uint64_t StartOffset = Symbols[Symbols.size() - 1].first;
     uint64_t EndOffset = Sect->Size - 1;
     DEBUG(dbgs() << "Extracting function: " << Symbols[Symbols.size()-1].second
                  << " from [" << StartOffset << ", " << EndOffset << "]\n");
     extractFunction(Symbols[Symbols.size()-1].second,
                     Base + StartOffset, Base + EndOffset);

     // Now extract the relocation information for each function and process it.
     for (unsigned j = 0; j != Sect->NumRelocationTableEntries; ++j) {
       InMemoryStruct<macho::RelocationEntry> RE;
       Obj->ReadRelocationEntry(Sect->RelocationTableOffset, j, RE);
       if (RE->Word0 & macho::RF_Scattered)
         return Error("NOT YET IMPLEMENTED: scattered relocations.");
       // Word0 of the relocation is the offset into the section where the
       // relocation should be applied. We need to translate that into an
       // offset into a function since that's our atom.
       uint32_t Offset = RE->Word0;
       // Look for the function containing the address. This is used for JIT
       // code, so the number of functions in section is almost always going
       // to be very small (usually just one), so until we have use cases
       // where that's not true, just use a trivial linear search.
       unsigned SymbolNum;
       unsigned NumSymbols = Symbols.size();
       assert(NumSymbols > 0 && Symbols[0].first <= Offset &&
              "No symbol containing relocation!");
       for (SymbolNum = 0; SymbolNum < NumSymbols - 1; ++SymbolNum)
         if (Symbols[SymbolNum + 1].first > Offset)
           break;
       // Adjust the offset to be relative to the symbol.
       Offset -= Symbols[SymbolNum].first;
       // Get the name of the symbol containing the relocation.
       StringRef TargetName = SymbolNames[SymbolNum];

       bool isExtern = (RE->Word1 >> 27) & 1;
       // Figure out the source symbol of the relocation. If isExtern is true,
       // this relocation references the symbol table, otherwise it references
       // a section in the same object, numbered from 1 through NumSections
       // (SectionBases is [0, NumSections-1]).
       // FIXME: Some targets (ARM) use internal relocations even for
       // externally visible symbols, if the definition is in the same
       // file as the reference. We need to convert those back to by-name
       // references. We can resolve the address based on the section
       // offset and see if we have a symbol at that address. If we do,
       // use that; otherwise, puke.
       if (!isExtern)
         return Error("Internal relocations not supported.");
       uint32_t SourceNum = RE->Word1 & 0xffffff; // 24-bit value
       StringRef SourceName = SymbolNames[SourceNum];

       // FIXME: Get the relocation addend from the target address.

       // Now store the relocation information. Associate it with the source
       // symbol.
       Relocations[SourceName].push_back(RelocationEntry(TargetName,
                                                         Offset,
                                                         RE->Word1,
                                                         0 /*Addend*/));
       DEBUG(dbgs() << "Relocation at '" << TargetName << "' + " << Offset
                    << " from '" << SourceName << "(Word1: "
                    << format("0x%x", RE->Word1) << ")\n");
     }
   }
   return false;
 }


 bool RuntimeDyldMachO::
 loadSegment64(const MachOObject *Obj,
               const MachOObject::LoadCommandInfo *SegmentLCI,
               const InMemoryStruct<macho::SymtabLoadCommand> &SymtabLC) {
   InMemoryStruct<macho::Segment64LoadCommand> Segment64LC;
   Obj->ReadSegment64LoadCommand(*SegmentLCI, Segment64LC);
   if (!Segment64LC)
     return Error("unable to load segment load command");

   for (unsigned SectNum = 0; SectNum != Segment64LC->NumSections; ++SectNum) {
     InMemoryStruct<macho::Section64> Sect;
     Obj->ReadSection64(*SegmentLCI, SectNum, Sect);
     if (!Sect)
       return Error("unable to load section: '" + Twine(SectNum) + "'");

     // FIXME: For the time being, we're only loading text segments.
     if (Sect->Flags != 0x80000400)
       continue;

     // Address and names of symbols in the section.
     typedef std::pair<uint64_t, StringRef> SymbolEntry;
     SmallVector<SymbolEntry, 64> Symbols;
     // Index of all the names, in this section or not. Used when we're
     // dealing with relocation entries.
     SmallVector<StringRef, 64> SymbolNames;
     for (unsigned i = 0; i != SymtabLC->NumSymbolTableEntries; ++i) {
       InMemoryStruct<macho::Symbol64TableEntry> STE;
       Obj->ReadSymbol64TableEntry(SymtabLC->SymbolTableOffset, i, STE);
       if (!STE)
         return Error("unable to read symbol: '" + Twine(i) + "'");
       if (STE->SectionIndex > Segment64LC->NumSections)
         return Error("invalid section index for symbol: '" + Twine(i) + "'");
       // Get the symbol name.
       StringRef Name = Obj->getStringAtIndex(STE->StringIndex);
       SymbolNames.push_back(Name);

       // Just skip symbols not defined in this section.
       if ((unsigned)STE->SectionIndex - 1 != SectNum)
         continue;

       // FIXME: Check the symbol type and flags.
       if (STE->Type != 0xF)  // external, defined in this section.
         continue;
       if (STE->Flags != 0x0)
         continue;

       // Remember the symbol.
       Symbols.push_back(SymbolEntry(STE->Value, Name));

       DEBUG(dbgs() << "Function sym: '" << Name << "' @ " <<
             (Sect->Address + STE->Value) << "\n");
     }
     // Sort the symbols by address, just in case they didn't come in that way.
     array_pod_sort(Symbols.begin(), Symbols.end());

     // If there weren't any functions (odd, but just in case...)
     if (!Symbols.size())
       continue;

     // Extract the function data.
     uint8_t *Base = (uint8_t*)Obj->getData(Segment64LC->FileOffset,
                                            Segment64LC->FileSize).data();
     for (unsigned i = 0, e = Symbols.size() - 1; i != e; ++i) {
       uint64_t StartOffset = Sect->Address + Symbols[i].first;
       uint64_t EndOffset = Symbols[i + 1].first - 1;
       DEBUG(dbgs() << "Extracting function: " << Symbols[i].second
                    << " from [" << StartOffset << ", " << EndOffset << "]\n");
       extractFunction(Symbols[i].second, Base + StartOffset, Base + EndOffset);
     }
     // The last symbol we do after since the end address is calculated
     // differently because there is no next symbol to reference.
     uint64_t StartOffset = Symbols[Symbols.size() - 1].first;
     uint64_t EndOffset = Sect->Size - 1;
     DEBUG(dbgs() << "Extracting function: " << Symbols[Symbols.size()-1].second
                  << " from [" << StartOffset << ", " << EndOffset << "]\n");
     extractFunction(Symbols[Symbols.size()-1].second,
                     Base + StartOffset, Base + EndOffset);

     // Now extract the relocation information for each function and process it.
     for (unsigned j = 0; j != Sect->NumRelocationTableEntries; ++j) {
       InMemoryStruct<macho::RelocationEntry> RE;
       Obj->ReadRelocationEntry(Sect->RelocationTableOffset, j, RE);
       if (RE->Word0 & macho::RF_Scattered)
         return Error("NOT YET IMPLEMENTED: scattered relocations.");
       // Word0 of the relocation is the offset into the section where the
       // relocation should be applied. We need to translate that into an
       // offset into a function since that's our atom.
       uint32_t Offset = RE->Word0;
       // Look for the function containing the address. This is used for JIT
       // code, so the number of functions in section is almost always going
       // to be very small (usually just one), so until we have use cases
       // where that's not true, just use a trivial linear search.
       unsigned SymbolNum;
       unsigned NumSymbols = Symbols.size();
       assert(NumSymbols > 0 && Symbols[0].first <= Offset &&
              "No symbol containing relocation!");
       for (SymbolNum = 0; SymbolNum < NumSymbols - 1; ++SymbolNum)
         if (Symbols[SymbolNum + 1].first > Offset)
           break;
       // Adjust the offset to be relative to the symbol.
       Offset -= Symbols[SymbolNum].first;
       // Get the name of the symbol containing the relocation.
       StringRef TargetName = SymbolNames[SymbolNum];

       bool isExtern = (RE->Word1 >> 27) & 1;
       // Figure out the source symbol of the relocation. If isExtern is true,
       // this relocation references the symbol table, otherwise it references
       // a section in the same object, numbered from 1 through NumSections
       // (SectionBases is [0, NumSections-1]).
       if (!isExtern)
         return Error("Internal relocations not supported.");
       uint32_t SourceNum = RE->Word1 & 0xffffff; // 24-bit value
       StringRef SourceName = SymbolNames[SourceNum];

       // FIXME: Get the relocation addend from the target address.

       // Now store the relocation information. Associate it with the source
       // symbol.
       Relocations[SourceName].push_back(RelocationEntry(TargetName,
                                                         Offset,
                                                         RE->Word1,
                                                         0 /*Addend*/));
       DEBUG(dbgs() << "Relocation at '" << TargetName << "' + " << Offset
                    << " from '" << SourceName << "(Word1: "
                    << format("0x%x", RE->Word1) << ")\n");
     }
   }
   return false;
 }

 bool RuntimeDyldMachO::loadObject(MemoryBuffer *InputBuffer) {
   // If the linker is in an error state, don't do anything.
   if (hasError())
     return true;
   // Load the Mach-O wrapper object.
   std::string ErrorStr;
   OwningPtr<MachOObject> Obj(
     MachOObject::LoadFromBuffer(InputBuffer, &ErrorStr));
   if (!Obj)
     return Error("unable to load object: '" + ErrorStr + "'");

   // Get the CPU type information from the header.
   const macho::Header &Header = Obj->getHeader();

   // FIXME: Error checking that the loaded object is compatible with
   //        the system we're running on.
   CPUType = Header.CPUType;
   CPUSubtype = Header.CPUSubtype;

   // Validate that the load commands match what we expect.
   const MachOObject::LoadCommandInfo *SegmentLCI = 0, *SymtabLCI = 0,
     *DysymtabLCI = 0;
   for (unsigned i = 0; i != Header.NumLoadCommands; ++i) {
     const MachOObject::LoadCommandInfo &LCI = Obj->getLoadCommandInfo(i);
     switch (LCI.Command.Type) {
     case macho::LCT_Segment:
     case macho::LCT_Segment64:
       if (SegmentLCI)
         return Error("unexpected input object (multiple segments)");
       SegmentLCI = &LCI;
       break;
     case macho::LCT_Symtab:
       if (SymtabLCI)
         return Error("unexpected input object (multiple symbol tables)");
       SymtabLCI = &LCI;
       break;
     case macho::LCT_Dysymtab:
       if (DysymtabLCI)
         return Error("unexpected input object (multiple symbol tables)");
       DysymtabLCI = &LCI;
       break;
     default:
       return Error("unexpected input object (unexpected load command");
     }
   }

   if (!SymtabLCI)
     return Error("no symbol table found in object");
   if (!SegmentLCI)
     return Error("no symbol table found in object");

   // Read and register the symbol table data.
   InMemoryStruct<macho::SymtabLoadCommand> SymtabLC;
   Obj->ReadSymtabLoadCommand(*SymtabLCI, SymtabLC);
   if (!SymtabLC)
     return Error("unable to load symbol table load command");
   Obj->RegisterStringTable(*SymtabLC);

   // Read the dynamic link-edit information, if present (not present in static
   // objects).
   if (DysymtabLCI) {
     InMemoryStruct<macho::DysymtabLoadCommand> DysymtabLC;
     Obj->ReadDysymtabLoadCommand(*DysymtabLCI, DysymtabLC);
     if (!DysymtabLC)
       return Error("unable to load dynamic link-exit load command");

     // FIXME: We don't support anything interesting yet.
 //    if (DysymtabLC->LocalSymbolsIndex != 0)
 //      return Error("NOT YET IMPLEMENTED: local symbol entries");
 //    if (DysymtabLC->ExternalSymbolsIndex != 0)
 //      return Error("NOT YET IMPLEMENTED: non-external symbol entries");
 //    if (DysymtabLC->UndefinedSymbolsIndex != SymtabLC->NumSymbolTableEntries)
 //      return Error("NOT YET IMPLEMENTED: undefined symbol entries");
   }

   // Load the segment load command.
   if (SegmentLCI->Command.Type == macho::LCT_Segment) {
     if (loadSegment32(Obj.get(), SegmentLCI, SymtabLC))
       return true;
   } else {
     if (loadSegment64(Obj.get(), SegmentLCI, SymtabLC))
       return true;
   }

   return false;
 }

 // Assign an address to a symbol name and resolve all the relocations
 // associated with it.
 void RuntimeDyldMachO::reassignSymbolAddress(StringRef Name, uint8_t *Addr) {
   // Assign the address in our symbol table.
   SymbolTable[Name] = Addr;

   RelocationList &Relocs = Relocations[Name];
   for (unsigned i = 0, e = Relocs.size(); i != e; ++i) {
     RelocationEntry &RE = Relocs[i];
     uint8_t *Target = SymbolTable[RE.Target] + RE.Offset;
     bool isPCRel = (RE.Data >> 24) & 1;
     unsigned Type = (RE.Data >> 28) & 0xf;
     unsigned Size = 1 << ((RE.Data >> 25) & 3);

     DEBUG(dbgs() << "Resolving relocation at '" << RE.Target
           << "' + " << RE.Offset << " (" << format("%p", Target) << ")"
           << " from '" << Name << " (" << format("%p", Addr) << ")"
           << "(" << (isPCRel ? "pcrel" : "absolute")
           << ", type: " << Type << ", Size: " << Size << ").\n");

     resolveRelocation(Target, Addr, isPCRel, Type, Size);
     RE.isResolved = true;
   }
 }

 bool RuntimeDyldMachO::isKnownFormat(const MemoryBuffer *InputBuffer) {
   StringRef Magic = InputBuffer->getBuffer().slice(0, 4);
   if (Magic == "\xFE\xED\xFA\xCE") return true;
   if (Magic == "\xCE\xFA\xED\xFE") return true;
   if (Magic == "\xFE\xED\xFA\xCF") return true;
   if (Magic == "\xCF\xFA\xED\xFE") return true;
   return false;
 }

 } // end namespace llvm
	//===-- RuntimeDyldMachO.cpp - Run-time dynamic linker for MC-JIT ------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Implementation of the MC-JIT runtime dynamic linker.
	//
	//===----------------------------------------------------------------------===//

	#define DEBUG_TYPE "dyld"
	#include "llvm/ADT/OwningPtr.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/ADT/STLExtras.h"
	#include "RuntimeDyldImpl.h"
	using namespace llvm;
	using namespace llvm::object;

	namespace llvm {

	bool RuntimeDyldMachO::
	resolveRelocation(uint8_t Address, uint8_t Value, bool isPCRel,
	unsigned Type, unsigned Size) {
	// This just dispatches to the proper target specific routine.
	switch (CPUType) {
	default: assert(0 && "Unsupported CPU type!");
	case mach::CTM_x86_64:
	return resolveX86_64Relocation((uintptr_t)Address, (uintptr_t)Value,
	isPCRel, Type, Size);
	case mach::CTM_ARM:
	return resolveARMRelocation((uintptr_t)Address, (uintptr_t)Value,
	isPCRel, Type, Size);
	}
	llvm_unreachable("");
	}

	bool RuntimeDyldMachO::
	resolveX86_64Relocation(uintptr_t Address, uintptr_t Value,
	bool isPCRel, unsigned Type,
	unsigned Size) {
	// If the relocation is PC-relative, the value to be encoded is the
	// pointer difference.
	if (isPCRel)
	// FIXME: It seems this value needs to be adjusted by 4 for an effective PC
	// address. Is that expected? Only for branches, perhaps?
	Value -= Address + 4;

	switch(Type) {
	default:
	llvm_unreachable("Invalid relocation type!");
	case macho::RIT_X86_64_Unsigned:
	case macho::RIT_X86_64_Branch: {
	// Mask in the target value a byte at a time (we don't have an alignment
	// guarantee for the target address, so this is safest).
	uint8_t p = (uint8_t)Address;
	for (unsigned i = 0; i < Size; ++i) {
	*p++ = (uint8_t)Value;
	Value >>= 8;
	}
	return false;
	}
	case macho::RIT_X86_64_Signed:
	case macho::RIT_X86_64_GOTLoad:
	case macho::RIT_X86_64_GOT:
	case macho::RIT_X86_64_Subtractor:
	case macho::RIT_X86_64_Signed1:
	case macho::RIT_X86_64_Signed2:
	case macho::RIT_X86_64_Signed4:
	case macho::RIT_X86_64_TLV:
	return Error("Relocation type not implemented yet!");
	}
	return false;
	}

	bool RuntimeDyldMachO::resolveARMRelocation(uintptr_t Address, uintptr_t Value,
	bool isPCRel, unsigned Type,
	unsigned Size) {
	// If the relocation is PC-relative, the value to be encoded is the
	// pointer difference.
	if (isPCRel) {
	Value -= Address;
	// ARM PCRel relocations have an effective-PC offset of two instructions
	// (four bytes in Thumb mode, 8 bytes in ARM mode).
	// FIXME: For now, assume ARM mode.
	Value -= 8;
	}

	switch(Type) {
	default:
	llvm_unreachable("Invalid relocation type!");
	case macho::RIT_Vanilla: {
	llvm_unreachable("Invalid relocation type!");
	// Mask in the target value a byte at a time (we don't have an alignment
	// guarantee for the target address, so this is safest).
	uint8_t p = (uint8_t)Address;
	for (unsigned i = 0; i < Size; ++i) {
	*p++ = (uint8_t)Value;
	Value >>= 8;
	}
	break;
	}
	case macho::RIT_ARM_Branch24Bit: {
	// Mask the value into the target address. We know instructions are
	// 32-bit aligned, so we can do it all at once.
	uint32_t p = (uint32_t)Address;
	// The low two bits of the value are not encoded.
	Value >>= 2;
	// Mask the value to 24 bits.
	Value &= 0xffffff;
	// FIXME: If the destination is a Thumb function (and the instruction
	// is a non-predicated BL instruction), we need to change it to a BLX
	// instruction instead.

	// Insert the value into the instruction.
	p = (p & ~0xffffff) \| Value;
	break;
	}
	case macho::RIT_ARM_ThumbBranch22Bit:
	case macho::RIT_ARM_ThumbBranch32Bit:
	case macho::RIT_ARM_Half:
	case macho::RIT_ARM_HalfDifference:
	case macho::RIT_Pair:
	case macho::RIT_Difference:
	case macho::RIT_ARM_LocalDifference:
	case macho::RIT_ARM_PreboundLazyPointer:
	return Error("Relocation type not implemented yet!");
	}
	return false;
	}

	bool RuntimeDyldMachO::
	loadSegment32(const MachOObject *Obj,
	const MachOObject::LoadCommandInfo *SegmentLCI,
	const InMemoryStruct<macho::SymtabLoadCommand> &SymtabLC) {
	InMemoryStruct<macho::SegmentLoadCommand> SegmentLC;
	Obj->ReadSegmentLoadCommand(*SegmentLCI, SegmentLC);
	if (!SegmentLC)
	return Error("unable to load segment load command");

	for (unsigned SectNum = 0; SectNum != SegmentLC->NumSections; ++SectNum) {
	InMemoryStruct<macho::Section> Sect;
	Obj->ReadSection(*SegmentLCI, SectNum, Sect);
	if (!Sect)
	return Error("unable to load section: '" + Twine(SectNum) + "'");

	// FIXME: For the time being, we're only loading text segments.
	if (Sect->Flags != 0x80000400)
	continue;

	// Address and names of symbols in the section.
	typedef std::pair<uint64_t, StringRef> SymbolEntry;
	SmallVector<SymbolEntry, 64> Symbols;
	// Index of all the names, in this section or not. Used when we're
	// dealing with relocation entries.
	SmallVector<StringRef, 64> SymbolNames;
	for (unsigned i = 0; i != SymtabLC->NumSymbolTableEntries; ++i) {
	InMemoryStruct<macho::SymbolTableEntry> STE;
	Obj->ReadSymbolTableEntry(SymtabLC->SymbolTableOffset, i, STE);
	if (!STE)
	return Error("unable to read symbol: '" + Twine(i) + "'");
	if (STE->SectionIndex > SegmentLC->NumSections)
	return Error("invalid section index for symbol: '" + Twine(i) + "'");
	// Get the symbol name.
	StringRef Name = Obj->getStringAtIndex(STE->StringIndex);
	SymbolNames.push_back(Name);

	// Just skip symbols not defined in this section.
	if ((unsigned)STE->SectionIndex - 1 != SectNum)
	continue;

	// FIXME: Check the symbol type and flags.
	if (STE->Type != 0xF) // external, defined in this section.
	continue;
	// Flags == 0x8 marks a thumb function for ARM, which is fine as it
	// doesn't require any special handling here.
	if (STE->Flags != 0x0 && STE->Flags != 0x8)
	continue;

	// Remember the symbol.
	Symbols.push_back(SymbolEntry(STE->Value, Name));

	DEBUG(dbgs() << "Function sym: '" << Name << "' @ " <<
	(Sect->Address + STE->Value) << "\n");
	}
	// Sort the symbols by address, just in case they didn't come in that way.
	array_pod_sort(Symbols.begin(), Symbols.end());

	// If there weren't any functions (odd, but just in case...)
	if (!Symbols.size())
	continue;

	// Extract the function data.
	uint8_t Base = (uint8_t)Obj->getData(SegmentLC->FileOffset,
	SegmentLC->FileSize).data();
	for (unsigned i = 0, e = Symbols.size() - 1; i != e; ++i) {
	uint64_t StartOffset = Sect->Address + Symbols[i].first;
	uint64_t EndOffset = Symbols[i + 1].first - 1;
	DEBUG(dbgs() << "Extracting function: " << Symbols[i].second
	<< " from [" << StartOffset << ", " << EndOffset << "]\n");
	extractFunction(Symbols[i].second, Base + StartOffset, Base + EndOffset);
	}
	// The last symbol we do after since the end address is calculated
	// differently because there is no next symbol to reference.
	uint64_t StartOffset = Symbols[Symbols.size() - 1].first;
	uint64_t EndOffset = Sect->Size - 1;
	DEBUG(dbgs() << "Extracting function: " << Symbols[Symbols.size()-1].second
	<< " from [" << StartOffset << ", " << EndOffset << "]\n");
	extractFunction(Symbols[Symbols.size()-1].second,
	Base + StartOffset, Base + EndOffset);

	// Now extract the relocation information for each function and process it.
	for (unsigned j = 0; j != Sect->NumRelocationTableEntries; ++j) {
	InMemoryStruct<macho::RelocationEntry> RE;
	Obj->ReadRelocationEntry(Sect->RelocationTableOffset, j, RE);
	if (RE->Word0 & macho::RF_Scattered)
	return Error("NOT YET IMPLEMENTED: scattered relocations.");
	// Word0 of the relocation is the offset into the section where the
	// relocation should be applied. We need to translate that into an
	// offset into a function since that's our atom.
	uint32_t Offset = RE->Word0;
	// Look for the function containing the address. This is used for JIT
	// code, so the number of functions in section is almost always going
	// to be very small (usually just one), so until we have use cases
	// where that's not true, just use a trivial linear search.
	unsigned SymbolNum;
	unsigned NumSymbols = Symbols.size();
	assert(NumSymbols > 0 && Symbols[0].first <= Offset &&
	"No symbol containing relocation!");
	for (SymbolNum = 0; SymbolNum < NumSymbols - 1; ++SymbolNum)
	if (Symbols[SymbolNum + 1].first > Offset)
	break;
	// Adjust the offset to be relative to the symbol.
	Offset -= Symbols[SymbolNum].first;
	// Get the name of the symbol containing the relocation.
	StringRef TargetName = SymbolNames[SymbolNum];

	bool isExtern = (RE->Word1 >> 27) & 1;
	// Figure out the source symbol of the relocation. If isExtern is true,
	// this relocation references the symbol table, otherwise it references
	// a section in the same object, numbered from 1 through NumSections
	// (SectionBases is [0, NumSections-1]).
	// FIXME: Some targets (ARM) use internal relocations even for
	// externally visible symbols, if the definition is in the same
	// file as the reference. We need to convert those back to by-name
	// references. We can resolve the address based on the section
	// offset and see if we have a symbol at that address. If we do,
	// use that; otherwise, puke.
	if (!isExtern)
	return Error("Internal relocations not supported.");
	uint32_t SourceNum = RE->Word1 & 0xffffff; // 24-bit value
	StringRef SourceName = SymbolNames[SourceNum];

	// FIXME: Get the relocation addend from the target address.

	// Now store the relocation information. Associate it with the source
	// symbol.
	Relocations[SourceName].push_back(RelocationEntry(TargetName,
	Offset,
	RE->Word1,
	0 /Addend/));
	DEBUG(dbgs() << "Relocation at '" << TargetName << "' + " << Offset
	<< " from '" << SourceName << "(Word1: "
	<< format("0x%x", RE->Word1) << ")\n");
	}
	}
	return false;
	}


	bool RuntimeDyldMachO::
	loadSegment64(const MachOObject *Obj,
	const MachOObject::LoadCommandInfo *SegmentLCI,
	const InMemoryStruct<macho::SymtabLoadCommand> &SymtabLC) {
	InMemoryStruct<macho::Segment64LoadCommand> Segment64LC;
	Obj->ReadSegment64LoadCommand(*SegmentLCI, Segment64LC);
	if (!Segment64LC)
	return Error("unable to load segment load command");

	for (unsigned SectNum = 0; SectNum != Segment64LC->NumSections; ++SectNum) {
	InMemoryStruct<macho::Section64> Sect;
	Obj->ReadSection64(*SegmentLCI, SectNum, Sect);
	if (!Sect)
	return Error("unable to load section: '" + Twine(SectNum) + "'");

	// FIXME: For the time being, we're only loading text segments.
	if (Sect->Flags != 0x80000400)
	continue;

	// Address and names of symbols in the section.
	typedef std::pair<uint64_t, StringRef> SymbolEntry;
	SmallVector<SymbolEntry, 64> Symbols;
	// Index of all the names, in this section or not. Used when we're
	// dealing with relocation entries.
	SmallVector<StringRef, 64> SymbolNames;
	for (unsigned i = 0; i != SymtabLC->NumSymbolTableEntries; ++i) {
	InMemoryStruct<macho::Symbol64TableEntry> STE;
	Obj->ReadSymbol64TableEntry(SymtabLC->SymbolTableOffset, i, STE);
	if (!STE)
	return Error("unable to read symbol: '" + Twine(i) + "'");
	if (STE->SectionIndex > Segment64LC->NumSections)
	return Error("invalid section index for symbol: '" + Twine(i) + "'");
	// Get the symbol name.
	StringRef Name = Obj->getStringAtIndex(STE->StringIndex);
	SymbolNames.push_back(Name);

	// Just skip symbols not defined in this section.
	if ((unsigned)STE->SectionIndex - 1 != SectNum)
	continue;

	// FIXME: Check the symbol type and flags.
	if (STE->Type != 0xF) // external, defined in this section.
	continue;
	if (STE->Flags != 0x0)
	continue;

	// Remember the symbol.
	Symbols.push_back(SymbolEntry(STE->Value, Name));

	DEBUG(dbgs() << "Function sym: '" << Name << "' @ " <<
	(Sect->Address + STE->Value) << "\n");
	}
	// Sort the symbols by address, just in case they didn't come in that way.
	array_pod_sort(Symbols.begin(), Symbols.end());

	// If there weren't any functions (odd, but just in case...)
	if (!Symbols.size())
	continue;

	// Extract the function data.
	uint8_t Base = (uint8_t)Obj->getData(Segment64LC->FileOffset,
	Segment64LC->FileSize).data();
	for (unsigned i = 0, e = Symbols.size() - 1; i != e; ++i) {
	uint64_t StartOffset = Sect->Address + Symbols[i].first;
	uint64_t EndOffset = Symbols[i + 1].first - 1;
	DEBUG(dbgs() << "Extracting function: " << Symbols[i].second
	<< " from [" << StartOffset << ", " << EndOffset << "]\n");
	extractFunction(Symbols[i].second, Base + StartOffset, Base + EndOffset);
	}
	// The last symbol we do after since the end address is calculated
	// differently because there is no next symbol to reference.
	uint64_t StartOffset = Symbols[Symbols.size() - 1].first;
	uint64_t EndOffset = Sect->Size - 1;
	DEBUG(dbgs() << "Extracting function: " << Symbols[Symbols.size()-1].second
	<< " from [" << StartOffset << ", " << EndOffset << "]\n");
	extractFunction(Symbols[Symbols.size()-1].second,
	Base + StartOffset, Base + EndOffset);

	// Now extract the relocation information for each function and process it.
	for (unsigned j = 0; j != Sect->NumRelocationTableEntries; ++j) {
	InMemoryStruct<macho::RelocationEntry> RE;
	Obj->ReadRelocationEntry(Sect->RelocationTableOffset, j, RE);
	if (RE->Word0 & macho::RF_Scattered)
	return Error("NOT YET IMPLEMENTED: scattered relocations.");
	// Word0 of the relocation is the offset into the section where the
	// relocation should be applied. We need to translate that into an
	// offset into a function since that's our atom.
	uint32_t Offset = RE->Word0;
	// Look for the function containing the address. This is used for JIT
	// code, so the number of functions in section is almost always going
	// to be very small (usually just one), so until we have use cases
	// where that's not true, just use a trivial linear search.
	unsigned SymbolNum;
	unsigned NumSymbols = Symbols.size();
	assert(NumSymbols > 0 && Symbols[0].first <= Offset &&
	"No symbol containing relocation!");
	for (SymbolNum = 0; SymbolNum < NumSymbols - 1; ++SymbolNum)
	if (Symbols[SymbolNum + 1].first > Offset)
	break;
	// Adjust the offset to be relative to the symbol.
	Offset -= Symbols[SymbolNum].first;
	// Get the name of the symbol containing the relocation.
	StringRef TargetName = SymbolNames[SymbolNum];

	bool isExtern = (RE->Word1 >> 27) & 1;
	// Figure out the source symbol of the relocation. If isExtern is true,
	// this relocation references the symbol table, otherwise it references
	// a section in the same object, numbered from 1 through NumSections
	// (SectionBases is [0, NumSections-1]).
	if (!isExtern)
	return Error("Internal relocations not supported.");
	uint32_t SourceNum = RE->Word1 & 0xffffff; // 24-bit value
	StringRef SourceName = SymbolNames[SourceNum];

	// FIXME: Get the relocation addend from the target address.

	// Now store the relocation information. Associate it with the source
	// symbol.
	Relocations[SourceName].push_back(RelocationEntry(TargetName,
	Offset,
	RE->Word1,
	0 /Addend/));
	DEBUG(dbgs() << "Relocation at '" << TargetName << "' + " << Offset
	<< " from '" << SourceName << "(Word1: "
	<< format("0x%x", RE->Word1) << ")\n");
	}
	}
	return false;
	}

	bool RuntimeDyldMachO::loadObject(MemoryBuffer *InputBuffer) {
	// If the linker is in an error state, don't do anything.
	if (hasError())
	return true;
	// Load the Mach-O wrapper object.
	std::string ErrorStr;
	OwningPtr<MachOObject> Obj(
	MachOObject::LoadFromBuffer(InputBuffer, &ErrorStr));
	if (!Obj)
	return Error("unable to load object: '" + ErrorStr + "'");

	// Get the CPU type information from the header.
	const macho::Header &Header = Obj->getHeader();

	// FIXME: Error checking that the loaded object is compatible with
	// the system we're running on.
	CPUType = Header.CPUType;
	CPUSubtype = Header.CPUSubtype;

	// Validate that the load commands match what we expect.
	const MachOObject::LoadCommandInfo SegmentLCI = 0, SymtabLCI = 0,
	*DysymtabLCI = 0;
	for (unsigned i = 0; i != Header.NumLoadCommands; ++i) {
	const MachOObject::LoadCommandInfo &LCI = Obj->getLoadCommandInfo(i);
	switch (LCI.Command.Type) {
	case macho::LCT_Segment:
	case macho::LCT_Segment64:
	if (SegmentLCI)
	return Error("unexpected input object (multiple segments)");
	SegmentLCI = &LCI;
	break;
	case macho::LCT_Symtab:
	if (SymtabLCI)
	return Error("unexpected input object (multiple symbol tables)");
	SymtabLCI = &LCI;
	break;
	case macho::LCT_Dysymtab:
	if (DysymtabLCI)
	return Error("unexpected input object (multiple symbol tables)");
	DysymtabLCI = &LCI;
	break;
	default:
	return Error("unexpected input object (unexpected load command");
	}
	}

	if (!SymtabLCI)
	return Error("no symbol table found in object");
	if (!SegmentLCI)
	return Error("no symbol table found in object");

	// Read and register the symbol table data.
	InMemoryStruct<macho::SymtabLoadCommand> SymtabLC;
	Obj->ReadSymtabLoadCommand(*SymtabLCI, SymtabLC);
	if (!SymtabLC)
	return Error("unable to load symbol table load command");
	Obj->RegisterStringTable(*SymtabLC);

	// Read the dynamic link-edit information, if present (not present in static
	// objects).
	if (DysymtabLCI) {
	InMemoryStruct<macho::DysymtabLoadCommand> DysymtabLC;
	Obj->ReadDysymtabLoadCommand(*DysymtabLCI, DysymtabLC);
	if (!DysymtabLC)
	return Error("unable to load dynamic link-exit load command");

	// FIXME: We don't support anything interesting yet.
	// if (DysymtabLC->LocalSymbolsIndex != 0)
	// return Error("NOT YET IMPLEMENTED: local symbol entries");
	// if (DysymtabLC->ExternalSymbolsIndex != 0)
	// return Error("NOT YET IMPLEMENTED: non-external symbol entries");
	// if (DysymtabLC->UndefinedSymbolsIndex != SymtabLC->NumSymbolTableEntries)
	// return Error("NOT YET IMPLEMENTED: undefined symbol entries");
	}

	// Load the segment load command.
	if (SegmentLCI->Command.Type == macho::LCT_Segment) {
	if (loadSegment32(Obj.get(), SegmentLCI, SymtabLC))
	return true;
	} else {
	if (loadSegment64(Obj.get(), SegmentLCI, SymtabLC))
	return true;
	}

	return false;
	}

	// Assign an address to a symbol name and resolve all the relocations
	// associated with it.
	void RuntimeDyldMachO::reassignSymbolAddress(StringRef Name, uint8_t *Addr) {
	// Assign the address in our symbol table.
	SymbolTable[Name] = Addr;

	RelocationList &Relocs = Relocations[Name];
	for (unsigned i = 0, e = Relocs.size(); i != e; ++i) {
	RelocationEntry &RE = Relocs[i];
	uint8_t *Target = SymbolTable[RE.Target] + RE.Offset;
	bool isPCRel = (RE.Data >> 24) & 1;
	unsigned Type = (RE.Data >> 28) & 0xf;
	unsigned Size = 1 << ((RE.Data >> 25) & 3);

	DEBUG(dbgs() << "Resolving relocation at '" << RE.Target
	<< "' + " << RE.Offset << " (" << format("%p", Target) << ")"
	<< " from '" << Name << " (" << format("%p", Addr) << ")"
	<< "(" << (isPCRel ? "pcrel" : "absolute")
	<< ", type: " << Type << ", Size: " << Size << ").\n");

	resolveRelocation(Target, Addr, isPCRel, Type, Size);
	RE.isResolved = true;
	}
	}

	bool RuntimeDyldMachO::isKnownFormat(const MemoryBuffer *InputBuffer) {
	StringRef Magic = InputBuffer->getBuffer().slice(0, 4);
	if (Magic == "\xFE\xED\xFA\xCE") return true;
	if (Magic == "\xCE\xFA\xED\xFE") return true;
	if (Magic == "\xFE\xED\xFA\xCF") return true;
	if (Magic == "\xCF\xFA\xED\xFE") return true;
	return false;
	}

	} // end namespace llvm