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llvm-mirror/lib/Object/ArchiveWriter.cpp
Andrew Ng 168234fec6 [llvm-ar][Object] Fix detection of need for 64-bit archive symbol tables
The code to detect the requirement for 64-bit offsets in the archive
symbol table was not correctly accounting for the archive file signature
and the size of all the contents of the symbol table itself, e.g. the
symbol table's header and string table. Also was not considering the
variation in symbol table formats. This could result in the creation of
large archives with a corrupt symbol table.

Change the testing environment variable SYM64_THRESHOLD to be an
absolute value rather than a power of 2 in order to enable precise
testing of this detection code.

Differential Revision: https://reviews.llvm.org/D89891
2020-10-26 12:29:28 +00:00

703 lines
25 KiB
C++

//===- ArchiveWriter.cpp - ar File Format implementation --------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
//
// This file defines the writeArchive function.
//
//===----------------------------------------------------------------------===//
#include "llvm/Object/ArchiveWriter.h"
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/BinaryFormat/Magic.h"
#include "llvm/IR/LLVMContext.h"
#include "llvm/Object/Archive.h"
#include "llvm/Object/Error.h"
#include "llvm/Object/ObjectFile.h"
#include "llvm/Object/SymbolicFile.h"
#include "llvm/Support/Alignment.h"
#include "llvm/Support/EndianStream.h"
#include "llvm/Support/Errc.h"
#include "llvm/Support/ErrorHandling.h"
#include "llvm/Support/Format.h"
#include "llvm/Support/Path.h"
#include "llvm/Support/SmallVectorMemoryBuffer.h"
#include "llvm/Support/ToolOutputFile.h"
#include "llvm/Support/raw_ostream.h"
#include <map>
#if !defined(_MSC_VER) && !defined(__MINGW32__)
#include <unistd.h>
#else
#include <io.h>
#endif
using namespace llvm;
NewArchiveMember::NewArchiveMember(MemoryBufferRef BufRef)
: Buf(MemoryBuffer::getMemBuffer(BufRef, false)),
MemberName(BufRef.getBufferIdentifier()) {}
Expected<NewArchiveMember>
NewArchiveMember::getOldMember(const object::Archive::Child &OldMember,
bool Deterministic) {
Expected<llvm::MemoryBufferRef> BufOrErr = OldMember.getMemoryBufferRef();
if (!BufOrErr)
return BufOrErr.takeError();
NewArchiveMember M;
M.Buf = MemoryBuffer::getMemBuffer(*BufOrErr, false);
M.MemberName = M.Buf->getBufferIdentifier();
if (!Deterministic) {
auto ModTimeOrErr = OldMember.getLastModified();
if (!ModTimeOrErr)
return ModTimeOrErr.takeError();
M.ModTime = ModTimeOrErr.get();
Expected<unsigned> UIDOrErr = OldMember.getUID();
if (!UIDOrErr)
return UIDOrErr.takeError();
M.UID = UIDOrErr.get();
Expected<unsigned> GIDOrErr = OldMember.getGID();
if (!GIDOrErr)
return GIDOrErr.takeError();
M.GID = GIDOrErr.get();
Expected<sys::fs::perms> AccessModeOrErr = OldMember.getAccessMode();
if (!AccessModeOrErr)
return AccessModeOrErr.takeError();
M.Perms = AccessModeOrErr.get();
}
return std::move(M);
}
Expected<NewArchiveMember> NewArchiveMember::getFile(StringRef FileName,
bool Deterministic) {
sys::fs::file_status Status;
auto FDOrErr = sys::fs::openNativeFileForRead(FileName);
if (!FDOrErr)
return FDOrErr.takeError();
sys::fs::file_t FD = *FDOrErr;
assert(FD != sys::fs::kInvalidFile);
if (auto EC = sys::fs::status(FD, Status))
return errorCodeToError(EC);
// Opening a directory doesn't make sense. Let it fail.
// Linux cannot open directories with open(2), although
// cygwin and *bsd can.
if (Status.type() == sys::fs::file_type::directory_file)
return errorCodeToError(make_error_code(errc::is_a_directory));
ErrorOr<std::unique_ptr<MemoryBuffer>> MemberBufferOrErr =
MemoryBuffer::getOpenFile(FD, FileName, Status.getSize(), false);
if (!MemberBufferOrErr)
return errorCodeToError(MemberBufferOrErr.getError());
if (auto EC = sys::fs::closeFile(FD))
return errorCodeToError(EC);
NewArchiveMember M;
M.Buf = std::move(*MemberBufferOrErr);
M.MemberName = M.Buf->getBufferIdentifier();
if (!Deterministic) {
M.ModTime = std::chrono::time_point_cast<std::chrono::seconds>(
Status.getLastModificationTime());
M.UID = Status.getUser();
M.GID = Status.getGroup();
M.Perms = Status.permissions();
}
return std::move(M);
}
template <typename T>
static void printWithSpacePadding(raw_ostream &OS, T Data, unsigned Size) {
uint64_t OldPos = OS.tell();
OS << Data;
unsigned SizeSoFar = OS.tell() - OldPos;
assert(SizeSoFar <= Size && "Data doesn't fit in Size");
OS.indent(Size - SizeSoFar);
}
static bool isDarwin(object::Archive::Kind Kind) {
return Kind == object::Archive::K_DARWIN ||
Kind == object::Archive::K_DARWIN64;
}
static bool isBSDLike(object::Archive::Kind Kind) {
switch (Kind) {
case object::Archive::K_GNU:
case object::Archive::K_GNU64:
return false;
case object::Archive::K_BSD:
case object::Archive::K_DARWIN:
case object::Archive::K_DARWIN64:
return true;
case object::Archive::K_COFF:
break;
}
llvm_unreachable("not supported for writting");
}
template <class T>
static void print(raw_ostream &Out, object::Archive::Kind Kind, T Val) {
support::endian::write(Out, Val,
isBSDLike(Kind) ? support::little : support::big);
}
static void printRestOfMemberHeader(
raw_ostream &Out, const sys::TimePoint<std::chrono::seconds> &ModTime,
unsigned UID, unsigned GID, unsigned Perms, uint64_t Size) {
printWithSpacePadding(Out, sys::toTimeT(ModTime), 12);
// The format has only 6 chars for uid and gid. Truncate if the provided
// values don't fit.
printWithSpacePadding(Out, UID % 1000000, 6);
printWithSpacePadding(Out, GID % 1000000, 6);
printWithSpacePadding(Out, format("%o", Perms), 8);
printWithSpacePadding(Out, Size, 10);
Out << "`\n";
}
static void
printGNUSmallMemberHeader(raw_ostream &Out, StringRef Name,
const sys::TimePoint<std::chrono::seconds> &ModTime,
unsigned UID, unsigned GID, unsigned Perms,
uint64_t Size) {
printWithSpacePadding(Out, Twine(Name) + "/", 16);
printRestOfMemberHeader(Out, ModTime, UID, GID, Perms, Size);
}
static void
printBSDMemberHeader(raw_ostream &Out, uint64_t Pos, StringRef Name,
const sys::TimePoint<std::chrono::seconds> &ModTime,
unsigned UID, unsigned GID, unsigned Perms, uint64_t Size) {
uint64_t PosAfterHeader = Pos + 60 + Name.size();
// Pad so that even 64 bit object files are aligned.
unsigned Pad = offsetToAlignment(PosAfterHeader, Align(8));
unsigned NameWithPadding = Name.size() + Pad;
printWithSpacePadding(Out, Twine("#1/") + Twine(NameWithPadding), 16);
printRestOfMemberHeader(Out, ModTime, UID, GID, Perms,
NameWithPadding + Size);
Out << Name;
while (Pad--)
Out.write(uint8_t(0));
}
static bool useStringTable(bool Thin, StringRef Name) {
return Thin || Name.size() >= 16 || Name.contains('/');
}
static bool is64BitKind(object::Archive::Kind Kind) {
switch (Kind) {
case object::Archive::K_GNU:
case object::Archive::K_BSD:
case object::Archive::K_DARWIN:
case object::Archive::K_COFF:
return false;
case object::Archive::K_DARWIN64:
case object::Archive::K_GNU64:
return true;
}
llvm_unreachable("not supported for writting");
}
static void
printMemberHeader(raw_ostream &Out, uint64_t Pos, raw_ostream &StringTable,
StringMap<uint64_t> &MemberNames, object::Archive::Kind Kind,
bool Thin, const NewArchiveMember &M,
sys::TimePoint<std::chrono::seconds> ModTime, uint64_t Size) {
if (isBSDLike(Kind))
return printBSDMemberHeader(Out, Pos, M.MemberName, ModTime, M.UID, M.GID,
M.Perms, Size);
if (!useStringTable(Thin, M.MemberName))
return printGNUSmallMemberHeader(Out, M.MemberName, ModTime, M.UID, M.GID,
M.Perms, Size);
Out << '/';
uint64_t NamePos;
if (Thin) {
NamePos = StringTable.tell();
StringTable << M.MemberName << "/\n";
} else {
auto Insertion = MemberNames.insert({M.MemberName, uint64_t(0)});
if (Insertion.second) {
Insertion.first->second = StringTable.tell();
StringTable << M.MemberName << "/\n";
}
NamePos = Insertion.first->second;
}
printWithSpacePadding(Out, NamePos, 15);
printRestOfMemberHeader(Out, ModTime, M.UID, M.GID, M.Perms, Size);
}
namespace {
struct MemberData {
std::vector<unsigned> Symbols;
std::string Header;
StringRef Data;
StringRef Padding;
};
} // namespace
static MemberData computeStringTable(StringRef Names) {
unsigned Size = Names.size();
unsigned Pad = offsetToAlignment(Size, Align(2));
std::string Header;
raw_string_ostream Out(Header);
printWithSpacePadding(Out, "//", 48);
printWithSpacePadding(Out, Size + Pad, 10);
Out << "`\n";
Out.flush();
return {{}, std::move(Header), Names, Pad ? "\n" : ""};
}
static sys::TimePoint<std::chrono::seconds> now(bool Deterministic) {
using namespace std::chrono;
if (!Deterministic)
return time_point_cast<seconds>(system_clock::now());
return sys::TimePoint<seconds>();
}
static bool isArchiveSymbol(const object::BasicSymbolRef &S) {
Expected<uint32_t> SymFlagsOrErr = S.getFlags();
if (!SymFlagsOrErr)
// TODO: Actually report errors helpfully.
report_fatal_error(SymFlagsOrErr.takeError());
if (*SymFlagsOrErr & object::SymbolRef::SF_FormatSpecific)
return false;
if (!(*SymFlagsOrErr & object::SymbolRef::SF_Global))
return false;
if (*SymFlagsOrErr & object::SymbolRef::SF_Undefined)
return false;
return true;
}
static void printNBits(raw_ostream &Out, object::Archive::Kind Kind,
uint64_t Val) {
if (is64BitKind(Kind))
print<uint64_t>(Out, Kind, Val);
else
print<uint32_t>(Out, Kind, Val);
}
static uint64_t computeSymbolTableSize(object::Archive::Kind Kind,
uint64_t NumSyms, uint64_t OffsetSize,
StringRef StringTable,
uint32_t *Padding = nullptr) {
assert((OffsetSize == 4 || OffsetSize == 8) && "Unsupported OffsetSize");
uint64_t Size = OffsetSize; // Number of entries
if (isBSDLike(Kind))
Size += NumSyms * OffsetSize * 2; // Table
else
Size += NumSyms * OffsetSize; // Table
if (isBSDLike(Kind))
Size += OffsetSize; // byte count
Size += StringTable.size();
// ld64 expects the members to be 8-byte aligned for 64-bit content and at
// least 4-byte aligned for 32-bit content. Opt for the larger encoding
// uniformly.
// We do this for all bsd formats because it simplifies aligning members.
uint32_t Pad = offsetToAlignment(Size, Align(isBSDLike(Kind) ? 8 : 2));
Size += Pad;
if (Padding)
*Padding = Pad;
return Size;
}
static void writeSymbolTableHeader(raw_ostream &Out, object::Archive::Kind Kind,
bool Deterministic, uint64_t Size) {
if (isBSDLike(Kind)) {
const char *Name = is64BitKind(Kind) ? "__.SYMDEF_64" : "__.SYMDEF";
printBSDMemberHeader(Out, Out.tell(), Name, now(Deterministic), 0, 0, 0,
Size);
} else {
const char *Name = is64BitKind(Kind) ? "/SYM64" : "";
printGNUSmallMemberHeader(Out, Name, now(Deterministic), 0, 0, 0, Size);
}
}
static void writeSymbolTable(raw_ostream &Out, object::Archive::Kind Kind,
bool Deterministic, ArrayRef<MemberData> Members,
StringRef StringTable) {
// We don't write a symbol table on an archive with no members -- except on
// Darwin, where the linker will abort unless the archive has a symbol table.
if (StringTable.empty() && !isDarwin(Kind))
return;
unsigned NumSyms = 0;
for (const MemberData &M : Members)
NumSyms += M.Symbols.size();
uint64_t OffsetSize = is64BitKind(Kind) ? 8 : 4;
uint32_t Pad;
uint64_t Size = computeSymbolTableSize(Kind, NumSyms, OffsetSize, StringTable, &Pad);
writeSymbolTableHeader(Out, Kind, Deterministic, Size);
uint64_t Pos = Out.tell() + Size;
if (isBSDLike(Kind))
printNBits(Out, Kind, NumSyms * 2 * OffsetSize);
else
printNBits(Out, Kind, NumSyms);
for (const MemberData &M : Members) {
for (unsigned StringOffset : M.Symbols) {
if (isBSDLike(Kind))
printNBits(Out, Kind, StringOffset);
printNBits(Out, Kind, Pos); // member offset
}
Pos += M.Header.size() + M.Data.size() + M.Padding.size();
}
if (isBSDLike(Kind))
// byte count of the string table
printNBits(Out, Kind, StringTable.size());
Out << StringTable;
while (Pad--)
Out.write(uint8_t(0));
}
static Expected<std::vector<unsigned>>
getSymbols(MemoryBufferRef Buf, raw_ostream &SymNames, bool &HasObject) {
std::vector<unsigned> Ret;
// In the scenario when LLVMContext is populated SymbolicFile will contain a
// reference to it, thus SymbolicFile should be destroyed first.
LLVMContext Context;
std::unique_ptr<object::SymbolicFile> Obj;
const file_magic Type = identify_magic(Buf.getBuffer());
// Treat unsupported file types as having no symbols.
if (!object::SymbolicFile::isSymbolicFile(Type, &Context))
return Ret;
if (Type == file_magic::bitcode) {
auto ObjOrErr = object::SymbolicFile::createSymbolicFile(
Buf, file_magic::bitcode, &Context);
if (!ObjOrErr)
return ObjOrErr.takeError();
Obj = std::move(*ObjOrErr);
} else {
auto ObjOrErr = object::SymbolicFile::createSymbolicFile(Buf);
if (!ObjOrErr)
return ObjOrErr.takeError();
Obj = std::move(*ObjOrErr);
}
HasObject = true;
for (const object::BasicSymbolRef &S : Obj->symbols()) {
if (!isArchiveSymbol(S))
continue;
Ret.push_back(SymNames.tell());
if (Error E = S.printName(SymNames))
return std::move(E);
SymNames << '\0';
}
return Ret;
}
static Expected<std::vector<MemberData>>
computeMemberData(raw_ostream &StringTable, raw_ostream &SymNames,
object::Archive::Kind Kind, bool Thin, bool Deterministic,
bool NeedSymbols, ArrayRef<NewArchiveMember> NewMembers) {
static char PaddingData[8] = {'\n', '\n', '\n', '\n', '\n', '\n', '\n', '\n'};
// This ignores the symbol table, but we only need the value mod 8 and the
// symbol table is aligned to be a multiple of 8 bytes
uint64_t Pos = 0;
std::vector<MemberData> Ret;
bool HasObject = false;
// Deduplicate long member names in the string table and reuse earlier name
// offsets. This especially saves space for COFF Import libraries where all
// members have the same name.
StringMap<uint64_t> MemberNames;
// UniqueTimestamps is a special case to improve debugging on Darwin:
//
// The Darwin linker does not link debug info into the final
// binary. Instead, it emits entries of type N_OSO in in the output
// binary's symbol table, containing references to the linked-in
// object files. Using that reference, the debugger can read the
// debug data directly from the object files. Alternatively, an
// invocation of 'dsymutil' will link the debug data from the object
// files into a dSYM bundle, which can be loaded by the debugger,
// instead of the object files.
//
// For an object file, the N_OSO entries contain the absolute path
// path to the file, and the file's timestamp. For an object
// included in an archive, the path is formatted like
// "/absolute/path/to/archive.a(member.o)", and the timestamp is the
// archive member's timestamp, rather than the archive's timestamp.
//
// However, this doesn't always uniquely identify an object within
// an archive -- an archive file can have multiple entries with the
// same filename. (This will happen commonly if the original object
// files started in different directories.) The only way they get
// distinguished, then, is via the timestamp. But this process is
// unable to find the correct object file in the archive when there
// are two files of the same name and timestamp.
//
// Additionally, timestamp==0 is treated specially, and causes the
// timestamp to be ignored as a match criteria.
//
// That will "usually" work out okay when creating an archive not in
// deterministic timestamp mode, because the objects will probably
// have been created at different timestamps.
//
// To ameliorate this problem, in deterministic archive mode (which
// is the default), on Darwin we will emit a unique non-zero
// timestamp for each entry with a duplicated name. This is still
// deterministic: the only thing affecting that timestamp is the
// order of the files in the resultant archive.
//
// See also the functions that handle the lookup:
// in lldb: ObjectContainerBSDArchive::Archive::FindObject()
// in llvm/tools/dsymutil: BinaryHolder::GetArchiveMemberBuffers().
bool UniqueTimestamps = Deterministic && isDarwin(Kind);
std::map<StringRef, unsigned> FilenameCount;
if (UniqueTimestamps) {
for (const NewArchiveMember &M : NewMembers)
FilenameCount[M.MemberName]++;
for (auto &Entry : FilenameCount)
Entry.second = Entry.second > 1 ? 1 : 0;
}
for (const NewArchiveMember &M : NewMembers) {
std::string Header;
raw_string_ostream Out(Header);
MemoryBufferRef Buf = M.Buf->getMemBufferRef();
StringRef Data = Thin ? "" : Buf.getBuffer();
// ld64 expects the members to be 8-byte aligned for 64-bit content and at
// least 4-byte aligned for 32-bit content. Opt for the larger encoding
// uniformly. This matches the behaviour with cctools and ensures that ld64
// is happy with archives that we generate.
unsigned MemberPadding =
isDarwin(Kind) ? offsetToAlignment(Data.size(), Align(8)) : 0;
unsigned TailPadding =
offsetToAlignment(Data.size() + MemberPadding, Align(2));
StringRef Padding = StringRef(PaddingData, MemberPadding + TailPadding);
sys::TimePoint<std::chrono::seconds> ModTime;
if (UniqueTimestamps)
// Increment timestamp for each file of a given name.
ModTime = sys::toTimePoint(FilenameCount[M.MemberName]++);
else
ModTime = M.ModTime;
uint64_t Size = Buf.getBufferSize() + MemberPadding;
if (Size > object::Archive::MaxMemberSize) {
std::string StringMsg =
"File " + M.MemberName.str() + " exceeds size limit";
return make_error<object::GenericBinaryError>(
std::move(StringMsg), object::object_error::parse_failed);
}
printMemberHeader(Out, Pos, StringTable, MemberNames, Kind, Thin, M,
ModTime, Size);
Out.flush();
std::vector<unsigned> Symbols;
if (NeedSymbols) {
Expected<std::vector<unsigned>> SymbolsOrErr =
getSymbols(Buf, SymNames, HasObject);
if (auto E = SymbolsOrErr.takeError())
return std::move(E);
Symbols = std::move(*SymbolsOrErr);
}
Pos += Header.size() + Data.size() + Padding.size();
Ret.push_back({std::move(Symbols), std::move(Header), Data, Padding});
}
// If there are no symbols, emit an empty symbol table, to satisfy Solaris
// tools, older versions of which expect a symbol table in a non-empty
// archive, regardless of whether there are any symbols in it.
if (HasObject && SymNames.tell() == 0)
SymNames << '\0' << '\0' << '\0';
return Ret;
}
namespace llvm {
static ErrorOr<SmallString<128>> canonicalizePath(StringRef P) {
SmallString<128> Ret = P;
std::error_code Err = sys::fs::make_absolute(Ret);
if (Err)
return Err;
sys::path::remove_dots(Ret, /*removedotdot*/ true);
return Ret;
}
// Compute the relative path from From to To.
Expected<std::string> computeArchiveRelativePath(StringRef From, StringRef To) {
ErrorOr<SmallString<128>> PathToOrErr = canonicalizePath(To);
ErrorOr<SmallString<128>> DirFromOrErr = canonicalizePath(From);
if (!PathToOrErr || !DirFromOrErr)
return errorCodeToError(std::error_code(errno, std::generic_category()));
const SmallString<128> &PathTo = *PathToOrErr;
const SmallString<128> &DirFrom = sys::path::parent_path(*DirFromOrErr);
// Can't construct a relative path between different roots
if (sys::path::root_name(PathTo) != sys::path::root_name(DirFrom))
return sys::path::convert_to_slash(PathTo);
// Skip common prefixes
auto FromTo =
std::mismatch(sys::path::begin(DirFrom), sys::path::end(DirFrom),
sys::path::begin(PathTo));
auto FromI = FromTo.first;
auto ToI = FromTo.second;
// Construct relative path
SmallString<128> Relative;
for (auto FromE = sys::path::end(DirFrom); FromI != FromE; ++FromI)
sys::path::append(Relative, sys::path::Style::posix, "..");
for (auto ToE = sys::path::end(PathTo); ToI != ToE; ++ToI)
sys::path::append(Relative, sys::path::Style::posix, *ToI);
return std::string(Relative.str());
}
static Error writeArchiveToStream(raw_ostream &Out,
ArrayRef<NewArchiveMember> NewMembers,
bool WriteSymtab, object::Archive::Kind Kind,
bool Deterministic, bool Thin) {
assert((!Thin || !isBSDLike(Kind)) && "Only the gnu format has a thin mode");
SmallString<0> SymNamesBuf;
raw_svector_ostream SymNames(SymNamesBuf);
SmallString<0> StringTableBuf;
raw_svector_ostream StringTable(StringTableBuf);
Expected<std::vector<MemberData>> DataOrErr =
computeMemberData(StringTable, SymNames, Kind, Thin, Deterministic,
WriteSymtab, NewMembers);
if (Error E = DataOrErr.takeError())
return E;
std::vector<MemberData> &Data = *DataOrErr;
if (!StringTableBuf.empty())
Data.insert(Data.begin(), computeStringTable(StringTableBuf));
// We would like to detect if we need to switch to a 64-bit symbol table.
if (WriteSymtab) {
uint64_t MaxOffset = 8; // For the file signature.
uint64_t LastOffset = MaxOffset;
uint64_t NumSyms = 0;
for (const auto &M : Data) {
// Record the start of the member's offset
LastOffset = MaxOffset;
// Account for the size of each part associated with the member.
MaxOffset += M.Header.size() + M.Data.size() + M.Padding.size();
NumSyms += M.Symbols.size();
}
// We assume 32-bit offsets to see if 32-bit symbols are possible or not.
uint64_t SymtabSize = computeSymbolTableSize(Kind, NumSyms, 4, SymNamesBuf);
auto computeSymbolTableHeaderSize =
[=] {
SmallString<0> TmpBuf;
raw_svector_ostream Tmp(TmpBuf);
writeSymbolTableHeader(Tmp, Kind, Deterministic, SymtabSize);
return TmpBuf.size();
};
LastOffset += computeSymbolTableHeaderSize() + SymtabSize;
// The SYM64 format is used when an archive's member offsets are larger than
// 32-bits can hold. The need for this shift in format is detected by
// writeArchive. To test this we need to generate a file with a member that
// has an offset larger than 32-bits but this demands a very slow test. To
// speed the test up we use this environment variable to pretend like the
// cutoff happens before 32-bits and instead happens at some much smaller
// value.
uint64_t Sym64Threshold = 1ULL << 32;
const char *Sym64Env = std::getenv("SYM64_THRESHOLD");
if (Sym64Env)
StringRef(Sym64Env).getAsInteger(10, Sym64Threshold);
// If LastOffset isn't going to fit in a 32-bit varible we need to switch
// to 64-bit. Note that the file can be larger than 4GB as long as the last
// member starts before the 4GB offset.
if (LastOffset >= Sym64Threshold) {
if (Kind == object::Archive::K_DARWIN)
Kind = object::Archive::K_DARWIN64;
else
Kind = object::Archive::K_GNU64;
}
}
if (Thin)
Out << "!<thin>\n";
else
Out << "!<arch>\n";
if (WriteSymtab)
writeSymbolTable(Out, Kind, Deterministic, Data, SymNamesBuf);
for (const MemberData &M : Data)
Out << M.Header << M.Data << M.Padding;
Out.flush();
return Error::success();
}
Error writeArchive(StringRef ArcName, ArrayRef<NewArchiveMember> NewMembers,
bool WriteSymtab, object::Archive::Kind Kind,
bool Deterministic, bool Thin,
std::unique_ptr<MemoryBuffer> OldArchiveBuf) {
Expected<sys::fs::TempFile> Temp =
sys::fs::TempFile::create(ArcName + ".temp-archive-%%%%%%%.a");
if (!Temp)
return Temp.takeError();
raw_fd_ostream Out(Temp->FD, false);
if (Error E = writeArchiveToStream(Out, NewMembers, WriteSymtab, Kind,
Deterministic, Thin)) {
if (Error DiscardError = Temp->discard())
return joinErrors(std::move(E), std::move(DiscardError));
return E;
}
// At this point, we no longer need whatever backing memory
// was used to generate the NewMembers. On Windows, this buffer
// could be a mapped view of the file we want to replace (if
// we're updating an existing archive, say). In that case, the
// rename would still succeed, but it would leave behind a
// temporary file (actually the original file renamed) because
// a file cannot be deleted while there's a handle open on it,
// only renamed. So by freeing this buffer, this ensures that
// the last open handle on the destination file, if any, is
// closed before we attempt to rename.
OldArchiveBuf.reset();
return Temp->keep(ArcName);
}
Expected<std::unique_ptr<MemoryBuffer>>
writeArchiveToBuffer(ArrayRef<NewArchiveMember> NewMembers, bool WriteSymtab,
object::Archive::Kind Kind, bool Deterministic,
bool Thin) {
SmallVector<char, 0> ArchiveBufferVector;
raw_svector_ostream ArchiveStream(ArchiveBufferVector);
if (Error E = writeArchiveToStream(ArchiveStream, NewMembers, WriteSymtab,
Kind, Deterministic, Thin))
return std::move(E);
return std::make_unique<SmallVectorMemoryBuffer>(
std::move(ArchiveBufferVector));
}
} // namespace llvm