//===------ MachOPlatform.cpp - Utilities for executing MachO in Orc ------===// // // 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 // //===----------------------------------------------------------------------===// #include "llvm/ExecutionEngine/Orc/MachOPlatform.h" #include "llvm/BinaryFormat/MachO.h" #include "llvm/ExecutionEngine/JITLink/x86_64.h" #include "llvm/ExecutionEngine/Orc/DebugUtils.h" #include "llvm/ExecutionEngine/Orc/ExecutionUtils.h" #include "llvm/ExecutionEngine/Orc/LookupAndRecordAddrs.h" #include "llvm/Support/BinaryByteStream.h" #include "llvm/Support/Debug.h" #include #define DEBUG_TYPE "orc" using namespace llvm; using namespace llvm::orc; using namespace llvm::orc::shared; namespace llvm { namespace orc { namespace shared { using SPSMachOJITDylibDepInfo = SPSTuple>; using SPSMachOJITDylibDepInfoMap = SPSSequence>; template <> class SPSSerializationTraits { public: static size_t size(const MachOPlatform::MachOJITDylibDepInfo &DDI) { return SPSMachOJITDylibDepInfo::AsArgList::size(DDI.Sealed, DDI.DepHeaders); } static bool serialize(SPSOutputBuffer &OB, const MachOPlatform::MachOJITDylibDepInfo &DDI) { return SPSMachOJITDylibDepInfo::AsArgList::serialize(OB, DDI.Sealed, DDI.DepHeaders); } static bool deserialize(SPSInputBuffer &IB, MachOPlatform::MachOJITDylibDepInfo &DDI) { return SPSMachOJITDylibDepInfo::AsArgList::deserialize(IB, DDI.Sealed, DDI.DepHeaders); } }; } // namespace shared } // namespace orc } // namespace llvm namespace { std::unique_ptr createPlatformGraph(MachOPlatform &MOP, std::string Name) { unsigned PointerSize; support::endianness Endianness; const auto &TT = MOP.getExecutionSession().getExecutorProcessControl().getTargetTriple(); switch (TT.getArch()) { case Triple::aarch64: case Triple::x86_64: PointerSize = 8; Endianness = support::endianness::little; break; default: llvm_unreachable("Unrecognized architecture"); } return std::make_unique(std::move(Name), TT, PointerSize, Endianness, jitlink::getGenericEdgeKindName); } // Generates a MachO header. class MachOHeaderMaterializationUnit : public MaterializationUnit { public: MachOHeaderMaterializationUnit(MachOPlatform &MOP, const SymbolStringPtr &HeaderStartSymbol) : MaterializationUnit(createHeaderInterface(MOP, HeaderStartSymbol)), MOP(MOP) {} StringRef getName() const override { return "MachOHeaderMU"; } void materialize(std::unique_ptr R) override { auto G = createPlatformGraph(MOP, ""); addMachOHeader(*G, MOP, R->getInitializerSymbol()); MOP.getObjectLinkingLayer().emit(std::move(R), std::move(G)); } void discard(const JITDylib &JD, const SymbolStringPtr &Sym) override {} static void addMachOHeader(jitlink::LinkGraph &G, MachOPlatform &MOP, const SymbolStringPtr &InitializerSymbol) { auto &HeaderSection = G.createSection("__header", MemProt::Read); auto &HeaderBlock = createHeaderBlock(G, HeaderSection); // Init symbol is header-start symbol. G.addDefinedSymbol(HeaderBlock, 0, *InitializerSymbol, HeaderBlock.getSize(), jitlink::Linkage::Strong, jitlink::Scope::Default, false, true); for (auto &HS : AdditionalHeaderSymbols) G.addDefinedSymbol(HeaderBlock, HS.Offset, HS.Name, HeaderBlock.getSize(), jitlink::Linkage::Strong, jitlink::Scope::Default, false, true); } private: struct HeaderSymbol { const char *Name; uint64_t Offset; }; static constexpr HeaderSymbol AdditionalHeaderSymbols[] = { {"___mh_executable_header", 0}}; static jitlink::Block &createHeaderBlock(jitlink::LinkGraph &G, jitlink::Section &HeaderSection) { MachO::mach_header_64 Hdr; Hdr.magic = MachO::MH_MAGIC_64; switch (G.getTargetTriple().getArch()) { case Triple::aarch64: Hdr.cputype = MachO::CPU_TYPE_ARM64; Hdr.cpusubtype = MachO::CPU_SUBTYPE_ARM64_ALL; break; case Triple::x86_64: Hdr.cputype = MachO::CPU_TYPE_X86_64; Hdr.cpusubtype = MachO::CPU_SUBTYPE_X86_64_ALL; break; default: llvm_unreachable("Unrecognized architecture"); } Hdr.filetype = MachO::MH_DYLIB; // Custom file type? Hdr.ncmds = 0; Hdr.sizeofcmds = 0; Hdr.flags = 0; Hdr.reserved = 0; if (G.getEndianness() != support::endian::system_endianness()) MachO::swapStruct(Hdr); auto HeaderContent = G.allocateString( StringRef(reinterpret_cast(&Hdr), sizeof(Hdr))); return G.createContentBlock(HeaderSection, HeaderContent, ExecutorAddr(), 8, 0); } static MaterializationUnit::Interface createHeaderInterface(MachOPlatform &MOP, const SymbolStringPtr &HeaderStartSymbol) { SymbolFlagsMap HeaderSymbolFlags; HeaderSymbolFlags[HeaderStartSymbol] = JITSymbolFlags::Exported; for (auto &HS : AdditionalHeaderSymbols) HeaderSymbolFlags[MOP.getExecutionSession().intern(HS.Name)] = JITSymbolFlags::Exported; return MaterializationUnit::Interface(std::move(HeaderSymbolFlags), HeaderStartSymbol); } MachOPlatform &MOP; }; constexpr MachOHeaderMaterializationUnit::HeaderSymbol MachOHeaderMaterializationUnit::AdditionalHeaderSymbols[]; // Creates a Bootstrap-Complete LinkGraph to run deferred actions. class MachOPlatformCompleteBootstrapMaterializationUnit : public MaterializationUnit { public: MachOPlatformCompleteBootstrapMaterializationUnit( MachOPlatform &MOP, StringRef PlatformJDName, SymbolStringPtr CompleteBootstrapSymbol, shared::AllocActions DeferredAAs, ExecutorAddr PlatformBootstrap, ExecutorAddr PlatformShutdown, ExecutorAddr RegisterJITDylib, ExecutorAddr DeregisterJITDylib, ExecutorAddr MachOHeaderAddr) : MaterializationUnit( {{{CompleteBootstrapSymbol, JITSymbolFlags::None}}, nullptr}), MOP(MOP), PlatformJDName(PlatformJDName), CompleteBootstrapSymbol(std::move(CompleteBootstrapSymbol)), DeferredAAs(std::move(DeferredAAs)), PlatformBootstrap(PlatformBootstrap), PlatformShutdown(PlatformShutdown), RegisterJITDylib(RegisterJITDylib), DeregisterJITDylib(DeregisterJITDylib), MachOHeaderAddr(MachOHeaderAddr) {} StringRef getName() const override { return "MachOPlatformCompleteBootstrap"; } void materialize(std::unique_ptr R) override { using namespace jitlink; auto G = createPlatformGraph(MOP, ""); auto &PlaceholderSection = G->createSection("__orc_rt_cplt_bs", MemProt::Read); auto &PlaceholderBlock = G->createZeroFillBlock(PlaceholderSection, 1, ExecutorAddr(), 1, 0); G->addDefinedSymbol(PlaceholderBlock, 0, *CompleteBootstrapSymbol, 1, Linkage::Strong, Scope::Hidden, false, true); // Reserve space for the stolen actions, plus two extras. G->allocActions().reserve(DeferredAAs.size() + 2); // 1. Bootstrap the platform support code. G->allocActions().push_back( {cantFail(WrapperFunctionCall::Create>(PlatformBootstrap)), cantFail( WrapperFunctionCall::Create>(PlatformShutdown))}); // 2. Register the platform JITDylib. G->allocActions().push_back( {cantFail(WrapperFunctionCall::Create< SPSArgList>( RegisterJITDylib, PlatformJDName, MachOHeaderAddr)), cantFail(WrapperFunctionCall::Create>( DeregisterJITDylib, MachOHeaderAddr))}); // 3. Add the deferred actions to the graph. std::move(DeferredAAs.begin(), DeferredAAs.end(), std::back_inserter(G->allocActions())); MOP.getObjectLinkingLayer().emit(std::move(R), std::move(G)); } void discard(const JITDylib &JD, const SymbolStringPtr &Sym) override {} private: MachOPlatform &MOP; StringRef PlatformJDName; SymbolStringPtr CompleteBootstrapSymbol; shared::AllocActions DeferredAAs; ExecutorAddr PlatformBootstrap; ExecutorAddr PlatformShutdown; ExecutorAddr RegisterJITDylib; ExecutorAddr DeregisterJITDylib; ExecutorAddr MachOHeaderAddr; }; StringRef DataCommonSectionName = "__DATA,__common"; StringRef DataDataSectionName = "__DATA,__data"; StringRef EHFrameSectionName = "__TEXT,__eh_frame"; StringRef CompactUnwindInfoSectionName = "__TEXT,__unwind_info"; StringRef ModInitFuncSectionName = "__DATA,__mod_init_func"; StringRef ObjCClassListSectionName = "__DATA,__objc_classlist"; StringRef ObjCImageInfoSectionName = "__DATA,__objc_image_info"; StringRef ObjCSelRefsSectionName = "__DATA,__objc_selrefs"; StringRef Swift5ProtoSectionName = "__TEXT,__swift5_proto"; StringRef Swift5ProtosSectionName = "__TEXT,__swift5_protos"; StringRef Swift5TypesSectionName = "__TEXT,__swift5_types"; StringRef ThreadBSSSectionName = "__DATA,__thread_bss"; StringRef ThreadDataSectionName = "__DATA,__thread_data"; StringRef ThreadVarsSectionName = "__DATA,__thread_vars"; StringRef InitSectionNames[] = { ModInitFuncSectionName, ObjCSelRefsSectionName, ObjCClassListSectionName, Swift5ProtosSectionName, Swift5ProtoSectionName, Swift5TypesSectionName}; } // end anonymous namespace namespace llvm { namespace orc { Expected> MachOPlatform::Create(ExecutionSession &ES, ObjectLinkingLayer &ObjLinkingLayer, JITDylib &PlatformJD, const char *OrcRuntimePath, std::optional RuntimeAliases) { auto &EPC = ES.getExecutorProcessControl(); // If the target is not supported then bail out immediately. if (!supportedTarget(EPC.getTargetTriple())) return make_error("Unsupported MachOPlatform triple: " + EPC.getTargetTriple().str(), inconvertibleErrorCode()); // Create default aliases if the caller didn't supply any. if (!RuntimeAliases) RuntimeAliases = standardPlatformAliases(ES); // Define the aliases. if (auto Err = PlatformJD.define(symbolAliases(std::move(*RuntimeAliases)))) return std::move(Err); // Add JIT-dispatch function support symbols. if (auto Err = PlatformJD.define(absoluteSymbols( {{ES.intern("___orc_rt_jit_dispatch"), {EPC.getJITDispatchInfo().JITDispatchFunction.getValue(), JITSymbolFlags::Exported}}, {ES.intern("___orc_rt_jit_dispatch_ctx"), {EPC.getJITDispatchInfo().JITDispatchContext.getValue(), JITSymbolFlags::Exported}}}))) return std::move(Err); // Create a generator for the ORC runtime archive. auto OrcRuntimeArchiveGenerator = StaticLibraryDefinitionGenerator::Load( ObjLinkingLayer, OrcRuntimePath, EPC.getTargetTriple()); if (!OrcRuntimeArchiveGenerator) return OrcRuntimeArchiveGenerator.takeError(); // Create the instance. Error Err = Error::success(); auto P = std::unique_ptr( new MachOPlatform(ES, ObjLinkingLayer, PlatformJD, std::move(*OrcRuntimeArchiveGenerator), Err)); if (Err) return std::move(Err); return std::move(P); } Error MachOPlatform::setupJITDylib(JITDylib &JD) { if (auto Err = JD.define(std::make_unique( *this, MachOHeaderStartSymbol))) return Err; return ES.lookup({&JD}, MachOHeaderStartSymbol).takeError(); } Error MachOPlatform::teardownJITDylib(JITDylib &JD) { std::lock_guard Lock(PlatformMutex); auto I = JITDylibToHeaderAddr.find(&JD); if (I != JITDylibToHeaderAddr.end()) { assert(HeaderAddrToJITDylib.count(I->second) && "HeaderAddrToJITDylib missing entry"); HeaderAddrToJITDylib.erase(I->second); JITDylibToHeaderAddr.erase(I); } JITDylibToPThreadKey.erase(&JD); return Error::success(); } Error MachOPlatform::notifyAdding(ResourceTracker &RT, const MaterializationUnit &MU) { auto &JD = RT.getJITDylib(); const auto &InitSym = MU.getInitializerSymbol(); if (!InitSym) return Error::success(); RegisteredInitSymbols[&JD].add(InitSym, SymbolLookupFlags::WeaklyReferencedSymbol); LLVM_DEBUG({ dbgs() << "MachOPlatform: Registered init symbol " << *InitSym << " for MU " << MU.getName() << "\n"; }); return Error::success(); } Error MachOPlatform::notifyRemoving(ResourceTracker &RT) { llvm_unreachable("Not supported yet"); } static void addAliases(ExecutionSession &ES, SymbolAliasMap &Aliases, ArrayRef> AL) { for (auto &KV : AL) { auto AliasName = ES.intern(KV.first); assert(!Aliases.count(AliasName) && "Duplicate symbol name in alias map"); Aliases[std::move(AliasName)] = {ES.intern(KV.second), JITSymbolFlags::Exported}; } } SymbolAliasMap MachOPlatform::standardPlatformAliases(ExecutionSession &ES) { SymbolAliasMap Aliases; addAliases(ES, Aliases, requiredCXXAliases()); addAliases(ES, Aliases, standardRuntimeUtilityAliases()); return Aliases; } ArrayRef> MachOPlatform::requiredCXXAliases() { static const std::pair RequiredCXXAliases[] = { {"___cxa_atexit", "___orc_rt_macho_cxa_atexit"}}; return ArrayRef>(RequiredCXXAliases); } ArrayRef> MachOPlatform::standardRuntimeUtilityAliases() { static const std::pair StandardRuntimeUtilityAliases[] = { {"___orc_rt_run_program", "___orc_rt_macho_run_program"}, {"___orc_rt_jit_dlerror", "___orc_rt_macho_jit_dlerror"}, {"___orc_rt_jit_dlopen", "___orc_rt_macho_jit_dlopen"}, {"___orc_rt_jit_dlclose", "___orc_rt_macho_jit_dlclose"}, {"___orc_rt_jit_dlsym", "___orc_rt_macho_jit_dlsym"}, {"___orc_rt_log_error", "___orc_rt_log_error_to_stderr"}}; return ArrayRef>( StandardRuntimeUtilityAliases); } bool MachOPlatform::isInitializerSection(StringRef SegName, StringRef SectName) { for (auto &Name : InitSectionNames) { if (Name.startswith(SegName) && Name.substr(7) == SectName) return true; } return false; } bool MachOPlatform::supportedTarget(const Triple &TT) { switch (TT.getArch()) { case Triple::aarch64: case Triple::x86_64: return true; default: return false; } } MachOPlatform::MachOPlatform( ExecutionSession &ES, ObjectLinkingLayer &ObjLinkingLayer, JITDylib &PlatformJD, std::unique_ptr OrcRuntimeGenerator, Error &Err) : ES(ES), PlatformJD(PlatformJD), ObjLinkingLayer(ObjLinkingLayer) { ErrorAsOutParameter _(&Err); ObjLinkingLayer.addPlugin(std::make_unique(*this)); PlatformJD.addGenerator(std::move(OrcRuntimeGenerator)); BootstrapInfo BI; Bootstrap = &BI; // Bootstrap process -- here be phase-ordering dragons. // // The MachOPlatform class uses allocation actions to register metadata // sections with the ORC runtime, however the runtime contains metadata // registration functions that have their own metadata that they need to // register (e.g. the frame-info registration functions have frame-info). // We can't use an ordinary lookup to find these registration functions // because their address is needed during the link of the containing graph // itself (to build the allocation actions that will call the registration // functions). Further complicating the situation (a) the graph containing // the registration functions is allowed to depend on other graphs (e.g. the // graph containing the ORC runtime RTTI support) so we need to handle with // an unknown set of dependencies during bootstrap, and (b) these graphs may // be linked concurrently if the user has installed a concurrent dispatcher. // // We satisfy these constraint by implementing a bootstrap phase during which // allocation actions generated by MachOPlatform are appended to a list of // deferred allocation actions, rather than to the graphs themselves. At the // end of the bootstrap process the deferred actions are attached to a final // "complete-bootstrap" graph that causes them to be run. // // The bootstrap steps are as follows: // // 1. Request the graph containing the mach header. This graph is guaranteed // not to have any metadata so the fact that the registration functions // are not available yet is not a problem. // // 2. Look up the registration functions and discard the results. This will // trigger linking of the graph containing these functions, and // consequently any graphs that it depends on. We do not use the lookup // result to find the addresses of the functions requested (as described // above the lookup will return too late for that), instead we capture the // addresses in a post-allocation pass injected by the platform runtime // during bootstrap only. // // 3. During bootstrap the MachOPlatformPlugin keeps a count of the number of // graphs being linked (potentially concurrently), and we block until all // of these graphs have completed linking. This is to avoid a race on the // deferred-actions vector: the lookup for the runtime registration // functions may return while some functions (those that are being // incidentally linked in, but aren't reachable via the runtime functions) // are still being linked, and we need to capture any allocation actions // for this incidental code before we proceed. // // 4. Once all active links are complete we transfer the deferred actions to // a newly added CompleteBootstrap graph and then request a symbol from // the CompleteBootstrap graph to trigger materialization. This will cause // all deferred actions to be run, and once this lookup returns we can // proceed. // // 5. Finally, we associate runtime support methods in MachOPlatform with // the corresponding jit-dispatch tag variables in the ORC runtime to make // the support methods callable. The bootstrap is now complete. // Step (1) Add header materialization unit and request. if ((Err = PlatformJD.define(std::make_unique( *this, MachOHeaderStartSymbol)))) return; if ((Err = ES.lookup(&PlatformJD, MachOHeaderStartSymbol).takeError())) return; // Step (2) Request runtime registration functions to trigger // materialization.. if ((Err = ES.lookup(makeJITDylibSearchOrder(&PlatformJD), SymbolLookupSet( {PlatformBootstrap.Name, PlatformShutdown.Name, RegisterJITDylib.Name, DeregisterJITDylib.Name, RegisterObjectPlatformSections.Name, DeregisterObjectPlatformSections.Name, CreatePThreadKey.Name})) .takeError())) return; // Step (3) Wait for any incidental linker work to complete. { std::unique_lock Lock(BI.Mutex); BI.CV.wait(Lock, [&]() { return BI.ActiveGraphs == 0; }); Bootstrap = nullptr; } // Step (4) Add complete-bootstrap materialization unit and request. auto BootstrapCompleteSymbol = ES.intern("__orc_rt_macho_complete_bootstrap"); if ((Err = PlatformJD.define( std::make_unique( *this, PlatformJD.getName(), BootstrapCompleteSymbol, std::move(BI.DeferredAAs), PlatformBootstrap.Addr, PlatformShutdown.Addr, RegisterJITDylib.Addr, DeregisterJITDylib.Addr, BI.MachOHeaderAddr)))) return; if ((Err = ES.lookup(makeJITDylibSearchOrder( &PlatformJD, JITDylibLookupFlags::MatchAllSymbols), std::move(BootstrapCompleteSymbol)) .takeError())) return; // (5) Associate runtime support functions. if ((Err = associateRuntimeSupportFunctions())) return; } Error MachOPlatform::associateRuntimeSupportFunctions() { ExecutionSession::JITDispatchHandlerAssociationMap WFs; using PushInitializersSPSSig = SPSExpected(SPSExecutorAddr); WFs[ES.intern("___orc_rt_macho_push_initializers_tag")] = ES.wrapAsyncWithSPS( this, &MachOPlatform::rt_pushInitializers); using LookupSymbolSPSSig = SPSExpected(SPSExecutorAddr, SPSString); WFs[ES.intern("___orc_rt_macho_symbol_lookup_tag")] = ES.wrapAsyncWithSPS(this, &MachOPlatform::rt_lookupSymbol); return ES.registerJITDispatchHandlers(PlatformJD, std::move(WFs)); } void MachOPlatform::pushInitializersLoop( PushInitializersSendResultFn SendResult, JITDylibSP JD) { DenseMap NewInitSymbols; DenseMap> JDDepMap; SmallVector Worklist({JD.get()}); ES.runSessionLocked([&]() { while (!Worklist.empty()) { // FIXME: Check for defunct dylibs. auto DepJD = Worklist.back(); Worklist.pop_back(); // If we've already visited this JITDylib on this iteration then continue. if (JDDepMap.count(DepJD)) continue; // Add dep info. auto &DM = JDDepMap[DepJD]; DepJD->withLinkOrderDo([&](const JITDylibSearchOrder &O) { for (auto &KV : O) { if (KV.first == DepJD) continue; DM.push_back(KV.first); Worklist.push_back(KV.first); } }); // Add any registered init symbols. auto RISItr = RegisteredInitSymbols.find(DepJD); if (RISItr != RegisteredInitSymbols.end()) { NewInitSymbols[DepJD] = std::move(RISItr->second); RegisteredInitSymbols.erase(RISItr); } } }); // If there are no further init symbols to look up then send the link order // (as a list of header addresses) to the caller. if (NewInitSymbols.empty()) { // To make the list intelligible to the runtime we need to convert all // JITDylib pointers to their header addresses. Only include JITDylibs // that appear in the JITDylibToHeaderAddr map (i.e. those that have been // through setupJITDylib) -- bare JITDylibs aren't managed by the platform. DenseMap HeaderAddrs; HeaderAddrs.reserve(JDDepMap.size()); { std::lock_guard Lock(PlatformMutex); for (auto &KV : JDDepMap) { auto I = JITDylibToHeaderAddr.find(KV.first); if (I != JITDylibToHeaderAddr.end()) HeaderAddrs[KV.first] = I->second; } } // Build the dep info map to return. MachOJITDylibDepInfoMap DIM; DIM.reserve(JDDepMap.size()); for (auto &KV : JDDepMap) { auto HI = HeaderAddrs.find(KV.first); // Skip unmanaged JITDylibs. if (HI == HeaderAddrs.end()) continue; auto H = HI->second; MachOJITDylibDepInfo DepInfo; for (auto &Dep : KV.second) { auto HJ = HeaderAddrs.find(Dep); if (HJ != HeaderAddrs.end()) DepInfo.DepHeaders.push_back(HJ->second); } DIM.push_back(std::make_pair(H, std::move(DepInfo))); } SendResult(DIM); return; } // Otherwise issue a lookup and re-run this phase when it completes. lookupInitSymbolsAsync( [this, SendResult = std::move(SendResult), JD](Error Err) mutable { if (Err) SendResult(std::move(Err)); else pushInitializersLoop(std::move(SendResult), JD); }, ES, std::move(NewInitSymbols)); } void MachOPlatform::rt_pushInitializers(PushInitializersSendResultFn SendResult, ExecutorAddr JDHeaderAddr) { JITDylibSP JD; { std::lock_guard Lock(PlatformMutex); auto I = HeaderAddrToJITDylib.find(JDHeaderAddr); if (I != HeaderAddrToJITDylib.end()) JD = I->second; } LLVM_DEBUG({ dbgs() << "MachOPlatform::rt_pushInitializers(" << JDHeaderAddr << ") "; if (JD) dbgs() << "pushing initializers for " << JD->getName() << "\n"; else dbgs() << "No JITDylib for header address.\n"; }); if (!JD) { SendResult( make_error("No JITDylib with header addr " + formatv("{0:x}", JDHeaderAddr.getValue()), inconvertibleErrorCode())); return; } pushInitializersLoop(std::move(SendResult), JD); } void MachOPlatform::rt_lookupSymbol(SendSymbolAddressFn SendResult, ExecutorAddr Handle, StringRef SymbolName) { LLVM_DEBUG({ dbgs() << "MachOPlatform::rt_lookupSymbol(\"" << formatv("{0:x}", Handle.getValue()) << "\")\n"; }); JITDylib *JD = nullptr; { std::lock_guard Lock(PlatformMutex); auto I = HeaderAddrToJITDylib.find(Handle); if (I != HeaderAddrToJITDylib.end()) JD = I->second; } if (!JD) { LLVM_DEBUG({ dbgs() << " No JITDylib for handle " << formatv("{0:x}", Handle.getValue()) << "\n"; }); SendResult(make_error("No JITDylib associated with handle " + formatv("{0:x}", Handle.getValue()), inconvertibleErrorCode())); return; } // Use functor class to work around XL build compiler issue on AIX. class RtLookupNotifyComplete { public: RtLookupNotifyComplete(SendSymbolAddressFn &&SendResult) : SendResult(std::move(SendResult)) {} void operator()(Expected Result) { if (Result) { assert(Result->size() == 1 && "Unexpected result map count"); SendResult(ExecutorAddr(Result->begin()->second.getAddress())); } else { SendResult(Result.takeError()); } } private: SendSymbolAddressFn SendResult; }; // FIXME: Proper mangling. auto MangledName = ("_" + SymbolName).str(); ES.lookup( LookupKind::DLSym, {{JD, JITDylibLookupFlags::MatchExportedSymbolsOnly}}, SymbolLookupSet(ES.intern(MangledName)), SymbolState::Ready, RtLookupNotifyComplete(std::move(SendResult)), NoDependenciesToRegister); } Expected MachOPlatform::createPThreadKey() { if (!CreatePThreadKey.Addr) return make_error( "Attempting to create pthread key in target, but runtime support has " "not been loaded yet", inconvertibleErrorCode()); Expected Result(0); if (auto Err = ES.callSPSWrapper(void)>( CreatePThreadKey.Addr, Result)) return std::move(Err); return Result; } void MachOPlatform::MachOPlatformPlugin::modifyPassConfig( MaterializationResponsibility &MR, jitlink::LinkGraph &LG, jitlink::PassConfiguration &Config) { using namespace jitlink; bool InBootstrapPhase = &MR.getTargetJITDylib() == &MP.PlatformJD && MP.Bootstrap; // If we're in the bootstrap phase then increment the active graphs. if (InBootstrapPhase) { Config.PrePrunePasses.push_back( [this](LinkGraph &G) { return bootstrapPipelineStart(G); }); Config.PostAllocationPasses.push_back([this](LinkGraph &G) { return bootstrapPipelineRecordRuntimeFunctions(G); }); } // --- Handle Initializers --- if (auto InitSymbol = MR.getInitializerSymbol()) { // If the initializer symbol is the MachOHeader start symbol then just // register it and then bail out -- the header materialization unit // definitely doesn't need any other passes. if (InitSymbol == MP.MachOHeaderStartSymbol && !InBootstrapPhase) { Config.PostAllocationPasses.push_back([this, &MR](LinkGraph &G) { return associateJITDylibHeaderSymbol(G, MR); }); return; } // If the object contains an init symbol other than the header start symbol // then add passes to preserve, process and register the init // sections/symbols. Config.PrePrunePasses.push_back([this, &MR](LinkGraph &G) { if (auto Err = preserveInitSections(G, MR)) return Err; return processObjCImageInfo(G, MR); }); } // Insert TLV lowering at the start of the PostPrunePasses, since we want // it to run before GOT/PLT lowering. Config.PostPrunePasses.insert( Config.PostPrunePasses.begin(), [this, &JD = MR.getTargetJITDylib()](LinkGraph &G) { return fixTLVSectionsAndEdges(G, JD); }); // Add a pass to register the final addresses of any special sections in the // object with the runtime. Config.PostAllocationPasses.push_back( [this, &JD = MR.getTargetJITDylib(), InBootstrapPhase](LinkGraph &G) { return registerObjectPlatformSections(G, JD, InBootstrapPhase); }); // If we're in the bootstrap phase then steal allocation actions and then // decrement the active graphs. if (InBootstrapPhase) Config.PostFixupPasses.push_back( [this](LinkGraph &G) { return bootstrapPipelineEnd(G); }); } ObjectLinkingLayer::Plugin::SyntheticSymbolDependenciesMap MachOPlatform::MachOPlatformPlugin::getSyntheticSymbolDependencies( MaterializationResponsibility &MR) { std::lock_guard Lock(PluginMutex); auto I = InitSymbolDeps.find(&MR); if (I != InitSymbolDeps.end()) { SyntheticSymbolDependenciesMap Result; Result[MR.getInitializerSymbol()] = std::move(I->second); InitSymbolDeps.erase(&MR); return Result; } return SyntheticSymbolDependenciesMap(); } Error MachOPlatform::MachOPlatformPlugin::bootstrapPipelineStart( jitlink::LinkGraph &G) { // Increment the active graphs count in BootstrapInfo. std::lock_guard Lock(MP.Bootstrap.load()->Mutex); ++MP.Bootstrap.load()->ActiveGraphs; return Error::success(); } Error MachOPlatform::MachOPlatformPlugin:: bootstrapPipelineRecordRuntimeFunctions(jitlink::LinkGraph &G) { // Record bootstrap function names. std::pair RuntimeSymbols[] = { {*MP.MachOHeaderStartSymbol, &MP.Bootstrap.load()->MachOHeaderAddr}, {*MP.PlatformBootstrap.Name, &MP.PlatformBootstrap.Addr}, {*MP.PlatformShutdown.Name, &MP.PlatformShutdown.Addr}, {*MP.RegisterJITDylib.Name, &MP.RegisterJITDylib.Addr}, {*MP.DeregisterJITDylib.Name, &MP.DeregisterJITDylib.Addr}, {*MP.RegisterObjectPlatformSections.Name, &MP.RegisterObjectPlatformSections.Addr}, {*MP.DeregisterObjectPlatformSections.Name, &MP.DeregisterObjectPlatformSections.Addr}, {*MP.CreatePThreadKey.Name, &MP.CreatePThreadKey.Addr}}; bool RegisterMachOHeader = false; for (auto *Sym : G.defined_symbols()) { for (auto &RTSym : RuntimeSymbols) { if (Sym->hasName() && Sym->getName() == RTSym.first) { if (*RTSym.second) return make_error( "Duplicate " + RTSym.first + " detected during MachOPlatform bootstrap", inconvertibleErrorCode()); if (Sym->getName() == *MP.MachOHeaderStartSymbol) RegisterMachOHeader = true; *RTSym.second = Sym->getAddress(); } } } if (RegisterMachOHeader) { // If this graph defines the macho header symbol then create the internal // mapping between it and PlatformJD. std::lock_guard Lock(MP.PlatformMutex); MP.JITDylibToHeaderAddr[&MP.PlatformJD] = MP.Bootstrap.load()->MachOHeaderAddr; MP.HeaderAddrToJITDylib[MP.Bootstrap.load()->MachOHeaderAddr] = &MP.PlatformJD; } return Error::success(); } Error MachOPlatform::MachOPlatformPlugin::bootstrapPipelineEnd( jitlink::LinkGraph &G) { std::lock_guard Lock(MP.Bootstrap.load()->Mutex); assert(MP.Bootstrap && "DeferredAAs reset before bootstrap completed"); --MP.Bootstrap.load()->ActiveGraphs; // Notify Bootstrap->CV while holding the mutex because the mutex is // also keeping Bootstrap->CV alive. if (MP.Bootstrap.load()->ActiveGraphs == 0) MP.Bootstrap.load()->CV.notify_all(); return Error::success(); } Error MachOPlatform::MachOPlatformPlugin::associateJITDylibHeaderSymbol( jitlink::LinkGraph &G, MaterializationResponsibility &MR) { auto I = llvm::find_if(G.defined_symbols(), [this](jitlink::Symbol *Sym) { return Sym->getName() == *MP.MachOHeaderStartSymbol; }); assert(I != G.defined_symbols().end() && "Missing MachO header start symbol"); auto &JD = MR.getTargetJITDylib(); std::lock_guard Lock(MP.PlatformMutex); auto HeaderAddr = (*I)->getAddress(); MP.JITDylibToHeaderAddr[&JD] = HeaderAddr; MP.HeaderAddrToJITDylib[HeaderAddr] = &JD; // We can unconditionally add these actions to the Graph because this pass // isn't used during bootstrap. G.allocActions().push_back( {cantFail( WrapperFunctionCall::Create>( MP.RegisterJITDylib.Addr, JD.getName(), HeaderAddr)), cantFail(WrapperFunctionCall::Create>( MP.DeregisterJITDylib.Addr, HeaderAddr))}); return Error::success(); } Error MachOPlatform::MachOPlatformPlugin::preserveInitSections( jitlink::LinkGraph &G, MaterializationResponsibility &MR) { JITLinkSymbolSet InitSectionSymbols; for (auto &InitSectionName : InitSectionNames) { // Skip non-init sections. auto *InitSection = G.findSectionByName(InitSectionName); if (!InitSection) continue; // Make a pass over live symbols in the section: those blocks are already // preserved. DenseSet AlreadyLiveBlocks; for (auto &Sym : InitSection->symbols()) { auto &B = Sym->getBlock(); if (Sym->isLive() && Sym->getOffset() == 0 && Sym->getSize() == B.getSize() && !AlreadyLiveBlocks.count(&B)) { InitSectionSymbols.insert(Sym); AlreadyLiveBlocks.insert(&B); } } // Add anonymous symbols to preserve any not-already-preserved blocks. for (auto *B : InitSection->blocks()) if (!AlreadyLiveBlocks.count(B)) InitSectionSymbols.insert( &G.addAnonymousSymbol(*B, 0, B->getSize(), false, true)); } if (!InitSectionSymbols.empty()) { std::lock_guard Lock(PluginMutex); InitSymbolDeps[&MR] = std::move(InitSectionSymbols); } return Error::success(); } Error MachOPlatform::MachOPlatformPlugin::processObjCImageInfo( jitlink::LinkGraph &G, MaterializationResponsibility &MR) { // If there's an ObjC imagine info then either // (1) It's the first __objc_imageinfo we've seen in this JITDylib. In // this case we name and record it. // OR // (2) We already have a recorded __objc_imageinfo for this JITDylib, // in which case we just verify it. auto *ObjCImageInfo = G.findSectionByName(ObjCImageInfoSectionName); if (!ObjCImageInfo) return Error::success(); auto ObjCImageInfoBlocks = ObjCImageInfo->blocks(); // Check that the section is not empty if present. if (ObjCImageInfoBlocks.empty()) return make_error("Empty " + ObjCImageInfoSectionName + " section in " + G.getName(), inconvertibleErrorCode()); // Check that there's only one block in the section. if (std::next(ObjCImageInfoBlocks.begin()) != ObjCImageInfoBlocks.end()) return make_error("Multiple blocks in " + ObjCImageInfoSectionName + " section in " + G.getName(), inconvertibleErrorCode()); // Check that the __objc_imageinfo section is unreferenced. // FIXME: We could optimize this check if Symbols had a ref-count. for (auto &Sec : G.sections()) { if (&Sec != ObjCImageInfo) for (auto *B : Sec.blocks()) for (auto &E : B->edges()) if (E.getTarget().isDefined() && &E.getTarget().getBlock().getSection() == ObjCImageInfo) return make_error(ObjCImageInfoSectionName + " is referenced within file " + G.getName(), inconvertibleErrorCode()); } auto &ObjCImageInfoBlock = **ObjCImageInfoBlocks.begin(); auto *ObjCImageInfoData = ObjCImageInfoBlock.getContent().data(); auto Version = support::endian::read32(ObjCImageInfoData, G.getEndianness()); auto Flags = support::endian::read32(ObjCImageInfoData + 4, G.getEndianness()); // Lock the mutex while we verify / update the ObjCImageInfos map. std::lock_guard Lock(PluginMutex); auto ObjCImageInfoItr = ObjCImageInfos.find(&MR.getTargetJITDylib()); if (ObjCImageInfoItr != ObjCImageInfos.end()) { // We've already registered an __objc_imageinfo section. Verify the // content of this new section matches, then delete it. if (ObjCImageInfoItr->second.first != Version) return make_error( "ObjC version in " + G.getName() + " does not match first registered version", inconvertibleErrorCode()); if (ObjCImageInfoItr->second.second != Flags) return make_error("ObjC flags in " + G.getName() + " do not match first registered flags", inconvertibleErrorCode()); // __objc_imageinfo is valid. Delete the block. for (auto *S : ObjCImageInfo->symbols()) G.removeDefinedSymbol(*S); G.removeBlock(ObjCImageInfoBlock); } else { // We haven't registered an __objc_imageinfo section yet. Register and // move on. The section should already be marked no-dead-strip. ObjCImageInfos[&MR.getTargetJITDylib()] = std::make_pair(Version, Flags); } return Error::success(); } Error MachOPlatform::MachOPlatformPlugin::fixTLVSectionsAndEdges( jitlink::LinkGraph &G, JITDylib &JD) { // Rename external references to __tlv_bootstrap to ___orc_rt_tlv_get_addr. for (auto *Sym : G.external_symbols()) if (Sym->getName() == "__tlv_bootstrap") { Sym->setName("___orc_rt_macho_tlv_get_addr"); break; } // Store key in __thread_vars struct fields. if (auto *ThreadDataSec = G.findSectionByName(ThreadVarsSectionName)) { std::optional Key; { std::lock_guard Lock(MP.PlatformMutex); auto I = MP.JITDylibToPThreadKey.find(&JD); if (I != MP.JITDylibToPThreadKey.end()) Key = I->second; } if (!Key) { if (auto KeyOrErr = MP.createPThreadKey()) Key = *KeyOrErr; else return KeyOrErr.takeError(); } uint64_t PlatformKeyBits = support::endian::byte_swap(*Key, G.getEndianness()); for (auto *B : ThreadDataSec->blocks()) { if (B->getSize() != 3 * G.getPointerSize()) return make_error("__thread_vars block at " + formatv("{0:x}", B->getAddress()) + " has unexpected size", inconvertibleErrorCode()); auto NewBlockContent = G.allocateBuffer(B->getSize()); llvm::copy(B->getContent(), NewBlockContent.data()); memcpy(NewBlockContent.data() + G.getPointerSize(), &PlatformKeyBits, G.getPointerSize()); B->setContent(NewBlockContent); } } // Transform any TLV edges into GOT edges. for (auto *B : G.blocks()) for (auto &E : B->edges()) if (E.getKind() == jitlink::x86_64::RequestTLVPAndTransformToPCRel32TLVPLoadREXRelaxable) E.setKind(jitlink::x86_64:: RequestGOTAndTransformToPCRel32GOTLoadREXRelaxable); return Error::success(); } std::optional MachOPlatform::MachOPlatformPlugin::findUnwindSectionInfo( jitlink::LinkGraph &G) { using namespace jitlink; UnwindSections US; // ScanSection records a section range and adds any executable blocks that // that section points to to the CodeBlocks vector. SmallVector CodeBlocks; auto ScanUnwindInfoSection = [&](Section &Sec, ExecutorAddrRange &SecRange) { if (Sec.blocks().empty()) return; SecRange = (*Sec.blocks().begin())->getRange(); for (auto *B : Sec.blocks()) { auto R = B->getRange(); SecRange.Start = std::min(SecRange.Start, R.Start); SecRange.End = std::max(SecRange.End, R.End); for (auto &E : B->edges()) { if (!E.getTarget().isDefined()) continue; auto &TargetBlock = E.getTarget().getBlock(); auto &TargetSection = TargetBlock.getSection(); if ((TargetSection.getMemProt() & MemProt::Exec) == MemProt::Exec) CodeBlocks.push_back(&TargetBlock); } } }; if (Section *EHFrameSec = G.findSectionByName(EHFrameSectionName)) ScanUnwindInfoSection(*EHFrameSec, US.DwarfSection); if (Section *CUInfoSec = G.findSectionByName(CompactUnwindInfoSectionName)) ScanUnwindInfoSection(*CUInfoSec, US.CompactUnwindSection); // If we didn't find any pointed-to code-blocks then there's no need to // register any info. if (CodeBlocks.empty()) return std::nullopt; // We have info to register. Sort the code blocks into address order and // build a list of contiguous address ranges covering them all. llvm::sort(CodeBlocks, [](const Block *LHS, const Block *RHS) { return LHS->getAddress() < RHS->getAddress(); }); for (auto *B : CodeBlocks) { if (US.CodeRanges.empty() || US.CodeRanges.back().End != B->getAddress()) US.CodeRanges.push_back(B->getRange()); else US.CodeRanges.back().End = B->getRange().End; } LLVM_DEBUG({ dbgs() << "MachOPlatform identified unwind info in " << G.getName() << ":\n" << " DWARF: "; if (US.DwarfSection.Start) dbgs() << US.DwarfSection << "\n"; else dbgs() << "none\n"; dbgs() << " Compact-unwind: "; if (US.CompactUnwindSection.Start) dbgs() << US.CompactUnwindSection << "\n"; else dbgs() << "none\n" << "for code ranges:\n"; for (auto &CR : US.CodeRanges) dbgs() << " " << CR << "\n"; if (US.CodeRanges.size() >= G.sections_size()) dbgs() << "WARNING: High number of discontiguous code ranges! " "Padding may be interfering with coalescing.\n"; }); return US; } Error MachOPlatform::MachOPlatformPlugin::registerObjectPlatformSections( jitlink::LinkGraph &G, JITDylib &JD, bool InBootstrapPhase) { // Get a pointer to the thread data section if there is one. It will be used // below. jitlink::Section *ThreadDataSection = G.findSectionByName(ThreadDataSectionName); // Handle thread BSS section if there is one. if (auto *ThreadBSSSection = G.findSectionByName(ThreadBSSSectionName)) { // If there's already a thread data section in this graph then merge the // thread BSS section content into it, otherwise just treat the thread // BSS section as the thread data section. if (ThreadDataSection) G.mergeSections(*ThreadDataSection, *ThreadBSSSection); else ThreadDataSection = ThreadBSSSection; } SmallVector, 8> MachOPlatformSecs; // Collect data sections to register. StringRef DataSections[] = {DataDataSectionName, DataCommonSectionName, EHFrameSectionName}; for (auto &SecName : DataSections) { if (auto *Sec = G.findSectionByName(SecName)) { jitlink::SectionRange R(*Sec); if (!R.empty()) MachOPlatformSecs.push_back({SecName, R.getRange()}); } } // Having merged thread BSS (if present) and thread data (if present), // record the resulting section range. if (ThreadDataSection) { jitlink::SectionRange R(*ThreadDataSection); if (!R.empty()) MachOPlatformSecs.push_back({ThreadDataSectionName, R.getRange()}); } // If any platform sections were found then add an allocation action to call // the registration function. StringRef PlatformSections[] = { ModInitFuncSectionName, ObjCClassListSectionName, ObjCImageInfoSectionName, ObjCSelRefsSectionName, Swift5ProtoSectionName, Swift5ProtosSectionName, Swift5TypesSectionName, }; for (auto &SecName : PlatformSections) { auto *Sec = G.findSectionByName(SecName); if (!Sec) continue; jitlink::SectionRange R(*Sec); if (R.empty()) continue; MachOPlatformSecs.push_back({SecName, R.getRange()}); } std::optional, ExecutorAddrRange, ExecutorAddrRange>> UnwindInfo; if (auto UI = findUnwindSectionInfo(G)) UnwindInfo = std::make_tuple(std::move(UI->CodeRanges), UI->DwarfSection, UI->CompactUnwindSection); if (!MachOPlatformSecs.empty() || UnwindInfo) { ExecutorAddr HeaderAddr; { std::lock_guard Lock(MP.PlatformMutex); auto I = MP.JITDylibToHeaderAddr.find(&JD); assert(I != MP.JITDylibToHeaderAddr.end() && "Missing header for JITDylib"); HeaderAddr = I->second; } // Dump the scraped inits. LLVM_DEBUG({ dbgs() << "MachOPlatform: Scraped " << G.getName() << " init sections:\n"; for (auto &KV : MachOPlatformSecs) dbgs() << " " << KV.first << ": " << KV.second << "\n"; }); using SPSRegisterObjectPlatformSectionsArgs = SPSArgList< SPSExecutorAddr, SPSOptional, SPSExecutorAddrRange, SPSExecutorAddrRange>>, SPSSequence>>; shared::AllocActions &allocActions = LLVM_LIKELY(!InBootstrapPhase) ? G.allocActions() : MP.Bootstrap.load()->DeferredAAs; allocActions.push_back( {cantFail( WrapperFunctionCall::Create( MP.RegisterObjectPlatformSections.Addr, HeaderAddr, UnwindInfo, MachOPlatformSecs)), cantFail( WrapperFunctionCall::Create( MP.DeregisterObjectPlatformSections.Addr, HeaderAddr, UnwindInfo, MachOPlatformSecs))}); } return Error::success(); } } // End namespace orc. } // End namespace llvm.