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//===- MachOUniversalWriter.cpp - MachO universal binary writer---*- C++-*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// Defines the Slice class and writeUniversalBinary function for writing a MachO
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// universal binary file.
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//
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//===----------------------------------------------------------------------===//
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#include "llvm/Object/MachOUniversalWriter.h"
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#include "llvm/ADT/STLExtras.h"
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#include "llvm/ADT/SmallVector.h"
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#include "llvm/Object/Archive.h"
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#include "llvm/Object/Binary.h"
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#include "llvm/Object/IRObjectFile.h"
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#include "llvm/Object/MachO.h"
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#include "llvm/Object/MachOUniversal.h"
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#include "llvm/Support/Casting.h"
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#include "llvm/Support/ErrorHandling.h"
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#include "llvm/Support/FileSystem.h"
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#include "llvm/Support/MathExtras.h"
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#include "llvm/Support/MemoryBufferRef.h"
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#include "llvm/Support/SwapByteOrder.h"
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#include "llvm/Support/raw_ostream.h"
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#include "llvm/TargetParser/Triple.h"
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using namespace llvm;
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using namespace object;
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// For compatibility with cctools lipo, a file's alignment is calculated as the
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// minimum aligment of all segments. For object files, the file's alignment is
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// the maximum alignment of its sections.
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static uint32_t calculateFileAlignment(const MachOObjectFile &O) {
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  uint32_t P2CurrentAlignment;
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  uint32_t P2MinAlignment = MachOUniversalBinary::MaxSectionAlignment;
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  const bool Is64Bit = O.is64Bit();
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  for (const auto &LC : O.load_commands()) {
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    if (LC.C.cmd != (Is64Bit ? MachO::LC_SEGMENT_64 : MachO::LC_SEGMENT))
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      continue;
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    if (O.getHeader().filetype == MachO::MH_OBJECT) {
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      unsigned NumberOfSections =
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          (Is64Bit ? O.getSegment64LoadCommand(LC).nsects
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                   : O.getSegmentLoadCommand(LC).nsects);
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      P2CurrentAlignment = NumberOfSections ? 2 : P2MinAlignment;
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      for (unsigned SI = 0; SI < NumberOfSections; ++SI) {
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        P2CurrentAlignment = std::max(P2CurrentAlignment,
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                                      (Is64Bit ? O.getSection64(LC, SI).align
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                                               : O.getSection(LC, SI).align));
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      }
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    } else {
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      P2CurrentAlignment =
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          llvm::countr_zero(Is64Bit ? O.getSegment64LoadCommand(LC).vmaddr
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                                    : O.getSegmentLoadCommand(LC).vmaddr);
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    }
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    P2MinAlignment = std::min(P2MinAlignment, P2CurrentAlignment);
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  }
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  // return a value >= 4 byte aligned, and less than MachO MaxSectionAlignment
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  return std::max(
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      static_cast<uint32_t>(2),
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      std::min(P2MinAlignment, static_cast<uint32_t>(
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                                   MachOUniversalBinary::MaxSectionAlignment)));
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}
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static uint32_t calculateAlignment(const MachOObjectFile &ObjectFile) {
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  switch (ObjectFile.getHeader().cputype) {
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  case MachO::CPU_TYPE_I386:
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  case MachO::CPU_TYPE_X86_64:
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  case MachO::CPU_TYPE_POWERPC:
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  case MachO::CPU_TYPE_POWERPC64:
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    return 12; // log2 value of page size(4k) for x86 and PPC
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  case MachO::CPU_TYPE_ARM:
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  case MachO::CPU_TYPE_ARM64:
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  case MachO::CPU_TYPE_ARM64_32:
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    return 14; // log2 value of page size(16k) for Darwin ARM
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  default:
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    return calculateFileAlignment(ObjectFile);
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  }
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}
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Slice::Slice(const Archive &A, uint32_t CPUType, uint32_t CPUSubType,
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             std::string ArchName, uint32_t Align)
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    : B(&A), CPUType(CPUType), CPUSubType(CPUSubType),
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      ArchName(std::move(ArchName)), P2Alignment(Align) {}
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Slice::Slice(const MachOObjectFile &O, uint32_t Align)
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    : B(&O), CPUType(O.getHeader().cputype),
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      CPUSubType(O.getHeader().cpusubtype),
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      ArchName(std::string(O.getArchTriple().getArchName())),
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      P2Alignment(Align) {}
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Slice::Slice(const IRObjectFile &IRO, uint32_t CPUType, uint32_t CPUSubType,
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             std::string ArchName, uint32_t Align)
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    : B(&IRO), CPUType(CPUType), CPUSubType(CPUSubType),
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      ArchName(std::move(ArchName)), P2Alignment(Align) {}
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Slice::Slice(const MachOObjectFile &O) : Slice(O, calculateAlignment(O)) {}
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using MachoCPUTy = std::pair<uint32_t, uint32_t>;
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static Expected<MachoCPUTy> getMachoCPUFromTriple(Triple TT) {
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  auto CPU = std::make_pair(MachO::getCPUType(TT), MachO::getCPUSubType(TT));
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  if (!CPU.first) {
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    return CPU.first.takeError();
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  }
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  if (!CPU.second) {
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    return CPU.second.takeError();
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  }
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  return std::make_pair(*CPU.first, *CPU.second);
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}
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static Expected<MachoCPUTy> getMachoCPUFromTriple(StringRef TT) {
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  return getMachoCPUFromTriple(Triple{TT});
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}
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static MachoCPUTy getMachoCPUFromObjectFile(const MachOObjectFile &O) {
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  return std::make_pair(O.getHeader().cputype, O.getHeader().cpusubtype);
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}
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Expected<Slice> Slice::create(const Archive &A, LLVMContext *LLVMCtx) {
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  Error Err = Error::success();
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  std::unique_ptr<MachOObjectFile> MFO = nullptr;
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  std::unique_ptr<IRObjectFile> IRFO = nullptr;
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  std::optional<MachoCPUTy> CPU = std::nullopt;
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  for (const Archive::Child &Child : A.children(Err)) {
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    Expected<std::unique_ptr<Binary>> ChildOrErr = Child.getAsBinary(LLVMCtx);
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    if (!ChildOrErr)
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      return createFileError(A.getFileName(), ChildOrErr.takeError());
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    Binary *Bin = ChildOrErr.get().get();
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    if (Bin->isMachOUniversalBinary())
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      return createStringError(std::errc::invalid_argument,
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                               ("archive member " + Bin->getFileName() +
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                                " is a fat file (not allowed in an archive)")
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                                   .str()
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                                   .c_str());
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    if (Bin->isMachO()) {
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      MachOObjectFile *O = cast<MachOObjectFile>(Bin);
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      MachoCPUTy ObjectCPU = getMachoCPUFromObjectFile(*O);
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      if (CPU && CPU != ObjectCPU) {
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        // If CPU != nullptr, one of MFO, IRFO will be != nullptr.
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        StringRef PreviousName = MFO ? MFO->getFileName() : IRFO->getFileName();
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        return createStringError(
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            std::errc::invalid_argument,
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            ("archive member " + O->getFileName() + " cputype (" +
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             Twine(ObjectCPU.first) + ") and cpusubtype(" +
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             Twine(ObjectCPU.second) +
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             ") does not match previous archive members cputype (" +
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             Twine(CPU->first) + ") and cpusubtype(" + Twine(CPU->second) +
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             ") (all members must match) " + PreviousName)
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                .str()
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                .c_str());
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      }
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      if (!MFO) {
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        ChildOrErr.get().release();
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        MFO.reset(O);
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        if (!CPU)
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          CPU.emplace(ObjectCPU);
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      }
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    } else if (Bin->isIR()) {
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      IRObjectFile *O = cast<IRObjectFile>(Bin);
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      Expected<MachoCPUTy> ObjectCPU =
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          getMachoCPUFromTriple(O->getTargetTriple());
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      if (!ObjectCPU)
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        return ObjectCPU.takeError();
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      if (CPU && CPU != *ObjectCPU) {
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        // If CPU != nullptr, one of MFO, IRFO will be != nullptr.
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        StringRef PreviousName =
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            IRFO ? IRFO->getFileName() : MFO->getFileName();
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        return createStringError(
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            std::errc::invalid_argument,
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            ("archive member " + O->getFileName() + " cputype (" +
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             Twine(ObjectCPU->first) + ") and cpusubtype(" +
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             Twine(ObjectCPU->second) +
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             ") does not match previous archive members cputype (" +
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             Twine(CPU->first) + ") and cpusubtype(" + Twine(CPU->second) +
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             ") (all members must match) " + PreviousName)
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                .str()
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                .c_str());
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      }
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      if (!IRFO) {
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        ChildOrErr.get().release();
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        IRFO.reset(O);
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        if (!CPU)
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          CPU.emplace(*ObjectCPU);
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      }
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    } else
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      return createStringError(std::errc::invalid_argument,
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                               ("archive member " + Bin->getFileName() +
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                                " is neither a MachO file or an LLVM IR file "
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                                "(not allowed in an archive)")
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                                   .str()
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                                   .c_str());
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  }
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  if (Err)
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    return createFileError(A.getFileName(), std::move(Err));
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  if (!MFO && !IRFO)
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    return createStringError(
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        std::errc::invalid_argument,
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        ("empty archive with no architecture specification: " +
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         A.getFileName() + " (can't determine architecture for it)")
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            .str()
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            .c_str());
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  if (MFO) {
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    Slice ArchiveSlice(*(MFO), MFO->is64Bit() ? 3 : 2);
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    ArchiveSlice.B = &A;
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    return ArchiveSlice;
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  }
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  // For IR objects
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  Expected<Slice> ArchiveSliceOrErr = Slice::create(*IRFO, 0);
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  if (!ArchiveSliceOrErr)
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    return createFileError(A.getFileName(), ArchiveSliceOrErr.takeError());
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  auto &ArchiveSlice = ArchiveSliceOrErr.get();
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  ArchiveSlice.B = &A;
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  return std::move(ArchiveSlice);
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}
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Expected<Slice> Slice::create(const IRObjectFile &IRO, uint32_t Align) {
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  Expected<MachoCPUTy> CPUOrErr = getMachoCPUFromTriple(IRO.getTargetTriple());
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  if (!CPUOrErr)
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    return CPUOrErr.takeError();
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  unsigned CPUType, CPUSubType;
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  std::tie(CPUType, CPUSubType) = CPUOrErr.get();
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  // We don't directly use the architecture name of the target triple T, as,
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  // for instance, thumb is treated as ARM by the MachOUniversal object.
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  std::string ArchName(
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      MachOObjectFile::getArchTriple(CPUType, CPUSubType).getArchName());
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  return Slice{IRO, CPUType, CPUSubType, std::move(ArchName), Align};
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}
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template <typename FatArchTy> struct FatArchTraits {
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  static const uint64_t OffsetLimit;
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  static const std::string StructName;
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  static const uint8_t BitCount;
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};
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template <> struct FatArchTraits<MachO::fat_arch> {
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  static const uint64_t OffsetLimit = UINT32_MAX;
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  static const std::string StructName;
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  static const uint8_t BitCount = 32;
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};
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const std::string FatArchTraits<MachO::fat_arch>::StructName = "fat_arch";
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template <> struct FatArchTraits<MachO::fat_arch_64> {
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  static const uint64_t OffsetLimit = UINT64_MAX;
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  static const std::string StructName;
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  static const uint8_t BitCount = 64;
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};
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const std::string FatArchTraits<MachO::fat_arch_64>::StructName = "fat_arch_64";
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template <typename FatArchTy>
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static Expected<SmallVector<FatArchTy, 2>>
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buildFatArchList(ArrayRef<Slice> Slices) {
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  SmallVector<FatArchTy, 2> FatArchList;
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  uint64_t Offset =
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      sizeof(MachO::fat_header) + Slices.size() * sizeof(FatArchTy);
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  for (const auto &S : Slices) {
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    Offset = alignTo(Offset, 1ull << S.getP2Alignment());
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    if (Offset > FatArchTraits<FatArchTy>::OffsetLimit)
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      return createStringError(
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          std::errc::invalid_argument,
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          ("fat file too large to be created because the offset field in the "
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           "struct " +
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           Twine(FatArchTraits<FatArchTy>::StructName) + " is only " +
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           Twine(FatArchTraits<FatArchTy>::BitCount) + "-bits and the offset " +
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           Twine(Offset) + " for " + S.getBinary()->getFileName() +
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           " for architecture " + S.getArchString() + "exceeds that.")
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              .str()
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              .c_str());
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    FatArchTy FatArch = {};
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    FatArch.cputype = S.getCPUType();
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    FatArch.cpusubtype = S.getCPUSubType();
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    FatArch.offset = Offset;
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    FatArch.size = S.getBinary()->getMemoryBufferRef().getBufferSize();
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    FatArch.align = S.getP2Alignment();
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    Offset += FatArch.size;
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    FatArchList.push_back(FatArch);
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  }
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  return FatArchList;
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}
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template <typename FatArchTy>
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static Error writeUniversalArchsToStream(MachO::fat_header FatHeader,
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                                         ArrayRef<Slice> Slices,
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                                         raw_ostream &Out) {
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  Expected<SmallVector<FatArchTy, 2>> FatArchListOrErr =
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      buildFatArchList<FatArchTy>(Slices);
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  if (!FatArchListOrErr)
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    return FatArchListOrErr.takeError();
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  SmallVector<FatArchTy, 2> FatArchList = *FatArchListOrErr;
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  if (sys::IsLittleEndianHost)
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    MachO::swapStruct(FatHeader);
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  Out.write(reinterpret_cast<const char *>(&FatHeader),
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            sizeof(MachO::fat_header));
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  if (sys::IsLittleEndianHost)
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    for (FatArchTy &FA : FatArchList)
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      MachO::swapStruct(FA);
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  Out.write(reinterpret_cast<const char *>(FatArchList.data()),
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            sizeof(FatArchTy) * FatArchList.size());
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  if (sys::IsLittleEndianHost)
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    for (FatArchTy &FA : FatArchList)
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      MachO::swapStruct(FA);
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  size_t Offset =
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      sizeof(MachO::fat_header) + sizeof(FatArchTy) * FatArchList.size();
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  for (size_t Index = 0, Size = Slices.size(); Index < Size; ++Index) {
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    MemoryBufferRef BufferRef = Slices[Index].getBinary()->getMemoryBufferRef();
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    assert((Offset <= FatArchList[Index].offset) && "Incorrect slice offset");
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    Out.write_zeros(FatArchList[Index].offset - Offset);
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    Out.write(BufferRef.getBufferStart(), BufferRef.getBufferSize());
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    Offset = FatArchList[Index].offset + BufferRef.getBufferSize();
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  }
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  Out.flush();
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  return Error::success();
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}
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Error object::writeUniversalBinaryToStream(ArrayRef<Slice> Slices,
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                                           raw_ostream &Out,
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                                           FatHeaderType HeaderType) {
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  MachO::fat_header FatHeader;
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  FatHeader.nfat_arch = Slices.size();
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  switch (HeaderType) {
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  case FatHeaderType::Fat64Header:
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    FatHeader.magic = MachO::FAT_MAGIC_64;
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    return writeUniversalArchsToStream<MachO::fat_arch_64>(FatHeader, Slices,
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                                                           Out);
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    break;
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  case FatHeaderType::FatHeader:
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    FatHeader.magic = MachO::FAT_MAGIC;
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    return writeUniversalArchsToStream<MachO::fat_arch>(FatHeader, Slices, Out);
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    break;
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  }
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  llvm_unreachable("Invalid fat header type");
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}
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Error object::writeUniversalBinary(ArrayRef<Slice> Slices,
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                                   StringRef OutputFileName,
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                                   FatHeaderType HeaderType) {
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  const bool IsExecutable = any_of(Slices, [](Slice S) {
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    return sys::fs::can_execute(S.getBinary()->getFileName());
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  });
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  unsigned Mode = sys::fs::all_read | sys::fs::all_write;
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  if (IsExecutable)
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    Mode |= sys::fs::all_exe;
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  Expected<sys::fs::TempFile> Temp = sys::fs::TempFile::create(
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      OutputFileName + ".temp-universal-%%%%%%", Mode);
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  if (!Temp)
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    return Temp.takeError();
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  raw_fd_ostream Out(Temp->FD, false);
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  if (Error E = writeUniversalBinaryToStream(Slices, Out, HeaderType)) {
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    if (Error DiscardError = Temp->discard())
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      return joinErrors(std::move(E), std::move(DiscardError));
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    return E;
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  }
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  return Temp->keep(OutputFileName);
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}
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