#include "LLVMWrapper.h" #include "llvm/Object/Archive.h" #include "llvm/Object/ArchiveWriter.h" #include "llvm/Support/Path.h" using namespace llvm; using namespace llvm::object; struct RustArchiveMember { const char *Filename; const char *Name; Archive::Child Child; RustArchiveMember() : Filename(nullptr), Name(nullptr), Child(nullptr, nullptr, nullptr) { } ~RustArchiveMember() {} }; struct RustArchiveIterator { bool First; Archive::child_iterator Cur; Archive::child_iterator End; std::unique_ptr Err; RustArchiveIterator(Archive::child_iterator Cur, Archive::child_iterator End, std::unique_ptr Err) : First(true), Cur(Cur), End(End), Err(std::move(Err)) {} }; enum class LLVMRustArchiveKind { GNU, BSD, DARWIN, COFF, }; static Archive::Kind fromRust(LLVMRustArchiveKind Kind) { switch (Kind) { case LLVMRustArchiveKind::GNU: return Archive::K_GNU; case LLVMRustArchiveKind::BSD: return Archive::K_BSD; case LLVMRustArchiveKind::DARWIN: return Archive::K_DARWIN; case LLVMRustArchiveKind::COFF: return Archive::K_COFF; default: report_fatal_error("Bad ArchiveKind."); } } typedef OwningBinary *LLVMRustArchiveRef; typedef RustArchiveMember *LLVMRustArchiveMemberRef; typedef Archive::Child *LLVMRustArchiveChildRef; typedef Archive::Child const *LLVMRustArchiveChildConstRef; typedef RustArchiveIterator *LLVMRustArchiveIteratorRef; extern "C" LLVMRustArchiveRef LLVMRustOpenArchive(char *Path) { ErrorOr> BufOr = MemoryBuffer::getFile(Path, -1, false); if (!BufOr) { LLVMRustSetLastError(BufOr.getError().message().c_str()); return nullptr; } Expected> ArchiveOr = Archive::create(BufOr.get()->getMemBufferRef()); if (!ArchiveOr) { LLVMRustSetLastError(toString(ArchiveOr.takeError()).c_str()); return nullptr; } OwningBinary *Ret = new OwningBinary( std::move(ArchiveOr.get()), std::move(BufOr.get())); return Ret; } extern "C" void LLVMRustDestroyArchive(LLVMRustArchiveRef RustArchive) { delete RustArchive; } extern "C" LLVMRustArchiveIteratorRef LLVMRustArchiveIteratorNew(LLVMRustArchiveRef RustArchive) { Archive *Archive = RustArchive->getBinary(); std::unique_ptr Err = std::make_unique(Error::success()); auto Cur = Archive->child_begin(*Err); if (*Err) { LLVMRustSetLastError(toString(std::move(*Err)).c_str()); return nullptr; } auto End = Archive->child_end(); return new RustArchiveIterator(Cur, End, std::move(Err)); } extern "C" LLVMRustArchiveChildConstRef LLVMRustArchiveIteratorNext(LLVMRustArchiveIteratorRef RAI) { if (RAI->Cur == RAI->End) return nullptr; // Advancing the iterator validates the next child, and this can // uncover an error. LLVM requires that we check all Errors, // so we only advance the iterator if we actually need to fetch // the next child. // This means we must not advance the iterator in the *first* call, // but instead advance it *before* fetching the child in all later calls. if (!RAI->First) { ++RAI->Cur; if (*RAI->Err) { LLVMRustSetLastError(toString(std::move(*RAI->Err)).c_str()); return nullptr; } } else { RAI->First = false; } if (RAI->Cur == RAI->End) return nullptr; const Archive::Child &Child = *RAI->Cur.operator->(); Archive::Child *Ret = new Archive::Child(Child); return Ret; } extern "C" void LLVMRustArchiveChildFree(LLVMRustArchiveChildRef Child) { delete Child; } extern "C" void LLVMRustArchiveIteratorFree(LLVMRustArchiveIteratorRef RAI) { delete RAI; } extern "C" const char * LLVMRustArchiveChildName(LLVMRustArchiveChildConstRef Child, size_t *Size) { Expected NameOrErr = Child->getName(); if (!NameOrErr) { // rustc_codegen_llvm currently doesn't use this error string, but it might be // useful in the future, and in the mean time this tells LLVM that the // error was not ignored and that it shouldn't abort the process. LLVMRustSetLastError(toString(NameOrErr.takeError()).c_str()); return nullptr; } StringRef Name = NameOrErr.get(); *Size = Name.size(); return Name.data(); } extern "C" const char *LLVMRustArchiveChildData(LLVMRustArchiveChildRef Child, size_t *Size) { StringRef Buf; Expected BufOrErr = Child->getBuffer(); if (!BufOrErr) { LLVMRustSetLastError(toString(BufOrErr.takeError()).c_str()); return nullptr; } Buf = BufOrErr.get(); *Size = Buf.size(); return Buf.data(); } extern "C" LLVMRustArchiveMemberRef LLVMRustArchiveMemberNew(char *Filename, char *Name, LLVMRustArchiveChildRef Child) { RustArchiveMember *Member = new RustArchiveMember; Member->Filename = Filename; Member->Name = Name; if (Child) Member->Child = *Child; return Member; } extern "C" void LLVMRustArchiveMemberFree(LLVMRustArchiveMemberRef Member) { delete Member; } extern "C" LLVMRustResult LLVMRustWriteArchive(char *Dst, size_t NumMembers, const LLVMRustArchiveMemberRef *NewMembers, bool WriteSymbtab, LLVMRustArchiveKind RustKind) { std::vector Members; auto Kind = fromRust(RustKind); for (size_t I = 0; I < NumMembers; I++) { auto Member = NewMembers[I]; assert(Member->Name); if (Member->Filename) { Expected MOrErr = NewArchiveMember::getFile(Member->Filename, true); if (!MOrErr) { LLVMRustSetLastError(toString(MOrErr.takeError()).c_str()); return LLVMRustResult::Failure; } MOrErr->MemberName = sys::path::filename(MOrErr->MemberName); Members.push_back(std::move(*MOrErr)); } else { Expected MOrErr = NewArchiveMember::getOldMember(Member->Child, true); if (!MOrErr) { LLVMRustSetLastError(toString(MOrErr.takeError()).c_str()); return LLVMRustResult::Failure; } Members.push_back(std::move(*MOrErr)); } } auto Result = writeArchive(Dst, Members, WriteSymbtab, Kind, true, false); if (!Result) return LLVMRustResult::Success; LLVMRustSetLastError(toString(std::move(Result)).c_str()); return LLVMRustResult::Failure; }