//===------- ObjectLinkingLayer.cpp - JITLink backed ORC ObjectLayer ------===// // // 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/ObjectLinkingLayer.h" #include "llvm/ExecutionEngine/JITLink/EHFrameSupport.h" #include "llvm/ExecutionEngine/JITLink/aarch32.h" #include "llvm/ExecutionEngine/Orc/DebugUtils.h" #include "llvm/ExecutionEngine/Orc/Shared/ObjectFormats.h" #include "llvm/Support/MemoryBuffer.h" #include #define DEBUG_TYPE "orc" using namespace llvm; using namespace llvm::jitlink; using namespace llvm::orc; namespace { bool hasInitializerSection(jitlink::LinkGraph &G) { bool IsMachO = G.getTargetTriple().isOSBinFormatMachO(); bool IsElf = G.getTargetTriple().isOSBinFormatELF(); if (!IsMachO && !IsElf) return false; for (auto &Sec : G.sections()) { if (IsMachO && isMachOInitializerSection(Sec.getName())) return true; if (IsElf && isELFInitializerSection(Sec.getName())) return true; } return false; } ExecutorAddr getJITSymbolPtrForSymbol(Symbol &Sym, const Triple &TT) { switch (TT.getArch()) { case Triple::arm: case Triple::armeb: case Triple::thumb: case Triple::thumbeb: if (hasTargetFlags(Sym, aarch32::ThumbSymbol)) { // Set LSB to indicate thumb target assert(Sym.isCallable() && "Only callable symbols can have thumb flag"); assert((Sym.getAddress().getValue() & 0x01) == 0 && "LSB is clear"); return Sym.getAddress() + 0x01; } return Sym.getAddress(); default: return Sym.getAddress(); } } JITSymbolFlags getJITSymbolFlagsForSymbol(Symbol &Sym) { JITSymbolFlags Flags; if (Sym.getLinkage() == Linkage::Weak) Flags |= JITSymbolFlags::Weak; if (Sym.getScope() == Scope::Default) Flags |= JITSymbolFlags::Exported; else if (Sym.getScope() == Scope::SideEffectsOnly) Flags |= JITSymbolFlags::MaterializationSideEffectsOnly; if (Sym.isCallable()) Flags |= JITSymbolFlags::Callable; return Flags; } class LinkGraphMaterializationUnit : public MaterializationUnit { public: static std::unique_ptr Create(ObjectLinkingLayer &ObjLinkingLayer, std::unique_ptr G) { auto LGI = scanLinkGraph(ObjLinkingLayer.getExecutionSession(), *G); return std::unique_ptr( new LinkGraphMaterializationUnit(ObjLinkingLayer, std::move(G), std::move(LGI))); } StringRef getName() const override { return G->getName(); } void materialize(std::unique_ptr MR) override { ObjLinkingLayer.emit(std::move(MR), std::move(G)); } private: static Interface scanLinkGraph(ExecutionSession &ES, LinkGraph &G) { Interface LGI; auto AddSymbol = [&](Symbol *Sym) { // Skip local symbols. if (Sym->getScope() == Scope::Local) return; assert(Sym->hasName() && "Anonymous non-local symbol?"); LGI.SymbolFlags[ES.intern(Sym->getName())] = getJITSymbolFlagsForSymbol(*Sym); }; for (auto *Sym : G.defined_symbols()) AddSymbol(Sym); for (auto *Sym : G.absolute_symbols()) AddSymbol(Sym); if (hasInitializerSection(G)) LGI.InitSymbol = makeInitSymbol(ES, G); return LGI; } static SymbolStringPtr makeInitSymbol(ExecutionSession &ES, LinkGraph &G) { std::string InitSymString; raw_string_ostream(InitSymString) << "$." << G.getName() << ".__inits" << Counter++; return ES.intern(InitSymString); } LinkGraphMaterializationUnit(ObjectLinkingLayer &ObjLinkingLayer, std::unique_ptr G, Interface LGI) : MaterializationUnit(std::move(LGI)), ObjLinkingLayer(ObjLinkingLayer), G(std::move(G)) {} void discard(const JITDylib &JD, const SymbolStringPtr &Name) override { for (auto *Sym : G->defined_symbols()) if (Sym->getName() == *Name) { assert(Sym->getLinkage() == Linkage::Weak && "Discarding non-weak definition"); G->makeExternal(*Sym); break; } } ObjectLinkingLayer &ObjLinkingLayer; std::unique_ptr G; static std::atomic Counter; }; std::atomic LinkGraphMaterializationUnit::Counter{0}; } // end anonymous namespace namespace llvm { namespace orc { class ObjectLinkingLayerJITLinkContext final : public JITLinkContext { public: ObjectLinkingLayerJITLinkContext( ObjectLinkingLayer &Layer, std::unique_ptr MR, std::unique_ptr ObjBuffer) : JITLinkContext(&MR->getTargetJITDylib()), Layer(Layer), MR(std::move(MR)), ObjBuffer(std::move(ObjBuffer)) { std::lock_guard Lock(Layer.LayerMutex); Plugins = Layer.Plugins; } ~ObjectLinkingLayerJITLinkContext() { // If there is an object buffer return function then use it to // return ownership of the buffer. if (Layer.ReturnObjectBuffer && ObjBuffer) Layer.ReturnObjectBuffer(std::move(ObjBuffer)); } JITLinkMemoryManager &getMemoryManager() override { return Layer.MemMgr; } void notifyMaterializing(LinkGraph &G) { for (auto &P : Plugins) P->notifyMaterializing(*MR, G, *this, ObjBuffer ? ObjBuffer->getMemBufferRef() : MemoryBufferRef()); } void notifyFailed(Error Err) override { for (auto &P : Plugins) Err = joinErrors(std::move(Err), P->notifyFailed(*MR)); Layer.getExecutionSession().reportError(std::move(Err)); MR->failMaterialization(); } void lookup(const LookupMap &Symbols, std::unique_ptr LC) override { JITDylibSearchOrder LinkOrder; MR->getTargetJITDylib().withLinkOrderDo( [&](const JITDylibSearchOrder &LO) { LinkOrder = LO; }); auto &ES = Layer.getExecutionSession(); SymbolLookupSet LookupSet; for (auto &KV : Symbols) { orc::SymbolLookupFlags LookupFlags; switch (KV.second) { case jitlink::SymbolLookupFlags::RequiredSymbol: LookupFlags = orc::SymbolLookupFlags::RequiredSymbol; break; case jitlink::SymbolLookupFlags::WeaklyReferencedSymbol: LookupFlags = orc::SymbolLookupFlags::WeaklyReferencedSymbol; break; } LookupSet.add(ES.intern(KV.first), LookupFlags); } // OnResolve -- De-intern the symbols and pass the result to the linker. auto OnResolve = [LookupContinuation = std::move(LC)](Expected Result) mutable { if (!Result) LookupContinuation->run(Result.takeError()); else { AsyncLookupResult LR; for (auto &KV : *Result) LR[*KV.first] = KV.second; LookupContinuation->run(std::move(LR)); } }; ES.lookup(LookupKind::Static, LinkOrder, std::move(LookupSet), SymbolState::Resolved, std::move(OnResolve), [this](const SymbolDependenceMap &Deps) { // Translate LookupDeps map to SymbolSourceJD. for (auto &[DepJD, Deps] : Deps) for (auto &DepSym : Deps) SymbolSourceJDs[NonOwningSymbolStringPtr(DepSym)] = DepJD; }); } Error notifyResolved(LinkGraph &G) override { auto &ES = Layer.getExecutionSession(); SymbolFlagsMap ExtraSymbolsToClaim; bool AutoClaim = Layer.AutoClaimObjectSymbols; SymbolMap InternedResult; for (auto *Sym : G.defined_symbols()) if (Sym->getScope() < Scope::SideEffectsOnly) { auto InternedName = ES.intern(Sym->getName()); auto Ptr = getJITSymbolPtrForSymbol(*Sym, G.getTargetTriple()); auto Flags = getJITSymbolFlagsForSymbol(*Sym); InternedResult[InternedName] = {Ptr, Flags}; if (AutoClaim && !MR->getSymbols().count(InternedName)) { assert(!ExtraSymbolsToClaim.count(InternedName) && "Duplicate symbol to claim?"); ExtraSymbolsToClaim[InternedName] = Flags; } } for (auto *Sym : G.absolute_symbols()) if (Sym->getScope() < Scope::SideEffectsOnly) { auto InternedName = ES.intern(Sym->getName()); auto Ptr = getJITSymbolPtrForSymbol(*Sym, G.getTargetTriple()); auto Flags = getJITSymbolFlagsForSymbol(*Sym); InternedResult[InternedName] = {Ptr, Flags}; if (AutoClaim && !MR->getSymbols().count(InternedName)) { assert(!ExtraSymbolsToClaim.count(InternedName) && "Duplicate symbol to claim?"); ExtraSymbolsToClaim[InternedName] = Flags; } } if (!ExtraSymbolsToClaim.empty()) if (auto Err = MR->defineMaterializing(ExtraSymbolsToClaim)) return Err; { // Check that InternedResult matches up with MR->getSymbols(), overriding // flags if requested. // This guards against faulty transformations / compilers / object caches. // First check that there aren't any missing symbols. size_t NumMaterializationSideEffectsOnlySymbols = 0; SymbolNameVector MissingSymbols; for (auto &[Sym, Flags] : MR->getSymbols()) { auto I = InternedResult.find(Sym); // If this is a materialization-side-effects only symbol then bump // the counter and remove in from the result, otherwise make sure that // it's defined. if (Flags.hasMaterializationSideEffectsOnly()) ++NumMaterializationSideEffectsOnlySymbols; else if (I == InternedResult.end()) MissingSymbols.push_back(Sym); else if (Layer.OverrideObjectFlags) I->second.setFlags(Flags); } // If there were missing symbols then report the error. if (!MissingSymbols.empty()) return make_error( Layer.getExecutionSession().getSymbolStringPool(), G.getName(), std::move(MissingSymbols)); // If there are more definitions than expected, add them to the // ExtraSymbols vector. SymbolNameVector ExtraSymbols; if (InternedResult.size() > MR->getSymbols().size() - NumMaterializationSideEffectsOnlySymbols) { for (auto &KV : InternedResult) if (!MR->getSymbols().count(KV.first)) ExtraSymbols.push_back(KV.first); } // If there were extra definitions then report the error. if (!ExtraSymbols.empty()) return make_error( Layer.getExecutionSession().getSymbolStringPool(), G.getName(), std::move(ExtraSymbols)); } if (auto Err = MR->notifyResolved(InternedResult)) return Err; notifyLoaded(); return Error::success(); } void notifyFinalized(JITLinkMemoryManager::FinalizedAlloc A) override { if (auto Err = notifyEmitted(std::move(A))) { Layer.getExecutionSession().reportError(std::move(Err)); MR->failMaterialization(); return; } if (auto Err = MR->notifyEmitted(SymbolDepGroups)) { Layer.getExecutionSession().reportError(std::move(Err)); MR->failMaterialization(); } } LinkGraphPassFunction getMarkLivePass(const Triple &TT) const override { return [this](LinkGraph &G) { return markResponsibilitySymbolsLive(G); }; } Error modifyPassConfig(LinkGraph &LG, PassConfiguration &Config) override { // Add passes to mark duplicate defs as should-discard, and to walk the // link graph to build the symbol dependence graph. Config.PrePrunePasses.push_back([this](LinkGraph &G) { return claimOrExternalizeWeakAndCommonSymbols(G); }); for (auto &P : Plugins) P->modifyPassConfig(*MR, LG, Config); Config.PreFixupPasses.push_back( [this](LinkGraph &G) { return registerDependencies(G); }); return Error::success(); } void notifyLoaded() { for (auto &P : Plugins) P->notifyLoaded(*MR); } Error notifyEmitted(jitlink::JITLinkMemoryManager::FinalizedAlloc FA) { Error Err = Error::success(); for (auto &P : Plugins) Err = joinErrors(std::move(Err), P->notifyEmitted(*MR)); if (Err) { if (FA) Err = joinErrors(std::move(Err), Layer.MemMgr.deallocate(std::move(FA))); return Err; } if (FA) return Layer.recordFinalizedAlloc(*MR, std::move(FA)); return Error::success(); } private: Error claimOrExternalizeWeakAndCommonSymbols(LinkGraph &G) { auto &ES = Layer.getExecutionSession(); SymbolFlagsMap NewSymbolsToClaim; std::vector> NameToSym; auto ProcessSymbol = [&](Symbol *Sym) { if (Sym->hasName() && Sym->getLinkage() == Linkage::Weak && Sym->getScope() != Scope::Local) { auto Name = ES.intern(Sym->getName()); if (!MR->getSymbols().count(ES.intern(Sym->getName()))) { NewSymbolsToClaim[Name] = getJITSymbolFlagsForSymbol(*Sym) | JITSymbolFlags::Weak; NameToSym.push_back(std::make_pair(std::move(Name), Sym)); } } }; for (auto *Sym : G.defined_symbols()) ProcessSymbol(Sym); for (auto *Sym : G.absolute_symbols()) ProcessSymbol(Sym); // Attempt to claim all weak defs that we're not already responsible for. // This may fail if the resource tracker has become defunct, but should // always succeed otherwise. if (auto Err = MR->defineMaterializing(std::move(NewSymbolsToClaim))) return Err; // Walk the list of symbols that we just tried to claim. Symbols that we're // responsible for are marked live. Symbols that we're not responsible for // are turned into external references. for (auto &KV : NameToSym) { if (MR->getSymbols().count(KV.first)) KV.second->setLive(true); else G.makeExternal(*KV.second); } return Error::success(); } Error markResponsibilitySymbolsLive(LinkGraph &G) const { auto &ES = Layer.getExecutionSession(); for (auto *Sym : G.defined_symbols()) if (Sym->hasName() && MR->getSymbols().count(ES.intern(Sym->getName()))) Sym->setLive(true); return Error::success(); } Error registerDependencies(LinkGraph &G) { struct BlockInfo { bool InWorklist = false; DenseSet Defs; DenseSet SymbolDeps; DenseSet AnonEdges, AnonBackEdges; }; DenseMap BlockInfos; // Reserve space so that BlockInfos doesn't need to resize. This is // essential to avoid invalidating pointers to entries below. { size_t NumBlocks = 0; for (auto &Sec : G.sections()) NumBlocks += Sec.blocks_size(); BlockInfos.reserve(NumBlocks); } // Identify non-locally-scoped symbols defined by each block. for (auto *Sym : G.defined_symbols()) { if (Sym->getScope() != Scope::Local) BlockInfos[&Sym->getBlock()].Defs.insert(Sym); } // Identify the symbolic and anonymous-block dependencies for each block. for (auto *B : G.blocks()) { auto &BI = BlockInfos[B]; for (auto &E : B->edges()) { // External symbols are trivially depended on. if (E.getTarget().isExternal()) { BI.SymbolDeps.insert(&E.getTarget()); continue; } // Anonymous symbols aren't depended on at all (they're assumed to be // already available). if (E.getTarget().isAbsolute()) continue; // If we get here then we depend on a symbol defined by some other // block. auto &TgtBI = BlockInfos[&E.getTarget().getBlock()]; // If that block has any definitions then use the first one as the // "effective" dependence here (all symbols in TgtBI will become // ready at the same time, and chosing a single symbol to represent // the block keeps the SymbolDepGroup size small). if (!TgtBI.Defs.empty()) { BI.SymbolDeps.insert(*TgtBI.Defs.begin()); continue; } // Otherwise we've got a dependence on an anonymous block. Record it // here for back-propagating symbol dependencies below. BI.AnonEdges.insert(&E.getTarget().getBlock()); TgtBI.AnonBackEdges.insert(B); } } // Prune anonymous blocks. { std::vector BlocksToRemove; for (auto &[B, BI] : BlockInfos) { // Skip blocks with defs. We only care about anonyous blocks. if (!BI.Defs.empty()) continue; BlocksToRemove.push_back(B); for (auto *FB : BI.AnonEdges) BlockInfos[FB].AnonBackEdges.erase(B); for (auto *BB : BI.AnonBackEdges) BlockInfos[BB].AnonEdges.erase(B); for (auto *FB : BI.AnonEdges) { auto &FBI = BlockInfos[FB]; for (auto *BB : BI.AnonBackEdges) FBI.AnonBackEdges.insert(BB); } for (auto *BB : BI.AnonBackEdges) { auto &BBI = BlockInfos[BB]; for (auto *SD : BI.SymbolDeps) BBI.SymbolDeps.insert(SD); for (auto *FB : BI.AnonEdges) BBI.AnonEdges.insert(FB); } } for (auto *B : BlocksToRemove) BlockInfos.erase(B); } // Build the initial dependence propagation worklist. std::deque Worklist; for (auto &[B, BI] : BlockInfos) { if (!BI.SymbolDeps.empty() && !BI.AnonBackEdges.empty()) { Worklist.push_back(B); BI.InWorklist = true; } } // Propagate symbol deps through the graph. while (!Worklist.empty()) { auto *B = Worklist.front(); Worklist.pop_front(); auto &BI = BlockInfos[B]; BI.InWorklist = false; for (auto *DB : BI.AnonBackEdges) { auto &DBI = BlockInfos[DB]; for (auto *Sym : BI.SymbolDeps) { if (DBI.SymbolDeps.insert(Sym).second && !DBI.InWorklist) { Worklist.push_back(DB); DBI.InWorklist = true; } } } } // Transform our local dependence information into a list of // SymbolDependenceGroups (in the SymbolDepGroups member), ready for use in // the upcoming notifyFinalized call. auto &TargetJD = MR->getTargetJITDylib(); auto &ES = TargetJD.getExecutionSession(); DenseMap InternedNames; auto GetInternedName = [&](Symbol *S) { auto &Name = InternedNames[S]; if (!Name) Name = ES.intern(S->getName()); return Name; }; for (auto &[B, BI] : BlockInfos) { if (!BI.Defs.empty()) { SymbolDepGroups.push_back(SymbolDependenceGroup()); auto &SDG = SymbolDepGroups.back(); for (auto *Def : BI.Defs) SDG.Symbols.insert(GetInternedName(Def)); for (auto *Dep : BI.SymbolDeps) { auto DepName = GetInternedName(Dep); if (Dep->isDefined()) SDG.Dependencies[&TargetJD].insert(std::move(DepName)); else { auto SourceJDItr = SymbolSourceJDs.find(NonOwningSymbolStringPtr(DepName)); if (SourceJDItr != SymbolSourceJDs.end()) SDG.Dependencies[SourceJDItr->second].insert(std::move(DepName)); } } } } return Error::success(); } ObjectLinkingLayer &Layer; std::vector> Plugins; std::unique_ptr MR; std::unique_ptr ObjBuffer; DenseMap SymbolSourceJDs; std::vector SymbolDepGroups; }; ObjectLinkingLayer::Plugin::~Plugin() = default; char ObjectLinkingLayer::ID; using BaseT = RTTIExtends; ObjectLinkingLayer::ObjectLinkingLayer(ExecutionSession &ES) : BaseT(ES), MemMgr(ES.getExecutorProcessControl().getMemMgr()) { ES.registerResourceManager(*this); } ObjectLinkingLayer::ObjectLinkingLayer(ExecutionSession &ES, JITLinkMemoryManager &MemMgr) : BaseT(ES), MemMgr(MemMgr) { ES.registerResourceManager(*this); } ObjectLinkingLayer::ObjectLinkingLayer( ExecutionSession &ES, std::unique_ptr MemMgr) : BaseT(ES), MemMgr(*MemMgr), MemMgrOwnership(std::move(MemMgr)) { ES.registerResourceManager(*this); } ObjectLinkingLayer::~ObjectLinkingLayer() { assert(Allocs.empty() && "Layer destroyed with resources still attached"); getExecutionSession().deregisterResourceManager(*this); } Error ObjectLinkingLayer::add(ResourceTrackerSP RT, std::unique_ptr G) { auto &JD = RT->getJITDylib(); return JD.define(LinkGraphMaterializationUnit::Create(*this, std::move(G)), std::move(RT)); } void ObjectLinkingLayer::emit(std::unique_ptr R, std::unique_ptr O) { assert(O && "Object must not be null"); MemoryBufferRef ObjBuffer = O->getMemBufferRef(); auto Ctx = std::make_unique( *this, std::move(R), std::move(O)); if (auto G = createLinkGraphFromObject(ObjBuffer)) { Ctx->notifyMaterializing(**G); link(std::move(*G), std::move(Ctx)); } else { Ctx->notifyFailed(G.takeError()); } } void ObjectLinkingLayer::emit(std::unique_ptr R, std::unique_ptr G) { auto Ctx = std::make_unique( *this, std::move(R), nullptr); Ctx->notifyMaterializing(*G); link(std::move(G), std::move(Ctx)); } Error ObjectLinkingLayer::recordFinalizedAlloc( MaterializationResponsibility &MR, FinalizedAlloc FA) { auto Err = MR.withResourceKeyDo( [&](ResourceKey K) { Allocs[K].push_back(std::move(FA)); }); if (Err) Err = joinErrors(std::move(Err), MemMgr.deallocate(std::move(FA))); return Err; } Error ObjectLinkingLayer::handleRemoveResources(JITDylib &JD, ResourceKey K) { { Error Err = Error::success(); for (auto &P : Plugins) Err = joinErrors(std::move(Err), P->notifyRemovingResources(JD, K)); if (Err) return Err; } std::vector AllocsToRemove; getExecutionSession().runSessionLocked([&] { auto I = Allocs.find(K); if (I != Allocs.end()) { std::swap(AllocsToRemove, I->second); Allocs.erase(I); } }); if (AllocsToRemove.empty()) return Error::success(); return MemMgr.deallocate(std::move(AllocsToRemove)); } void ObjectLinkingLayer::handleTransferResources(JITDylib &JD, ResourceKey DstKey, ResourceKey SrcKey) { if (Allocs.contains(SrcKey)) { // DstKey may not be in the DenseMap yet, so the following line may resize // the container and invalidate iterators and value references. auto &DstAllocs = Allocs[DstKey]; auto &SrcAllocs = Allocs[SrcKey]; DstAllocs.reserve(DstAllocs.size() + SrcAllocs.size()); for (auto &Alloc : SrcAllocs) DstAllocs.push_back(std::move(Alloc)); Allocs.erase(SrcKey); } for (auto &P : Plugins) P->notifyTransferringResources(JD, DstKey, SrcKey); } EHFrameRegistrationPlugin::EHFrameRegistrationPlugin( ExecutionSession &ES, std::unique_ptr Registrar) : ES(ES), Registrar(std::move(Registrar)) {} void EHFrameRegistrationPlugin::modifyPassConfig( MaterializationResponsibility &MR, LinkGraph &G, PassConfiguration &PassConfig) { PassConfig.PostFixupPasses.push_back(createEHFrameRecorderPass( G.getTargetTriple(), [this, &MR](ExecutorAddr Addr, size_t Size) { if (Addr) { std::lock_guard Lock(EHFramePluginMutex); assert(!InProcessLinks.count(&MR) && "Link for MR already being tracked?"); InProcessLinks[&MR] = {Addr, Size}; } })); } Error EHFrameRegistrationPlugin::notifyEmitted( MaterializationResponsibility &MR) { ExecutorAddrRange EmittedRange; { std::lock_guard Lock(EHFramePluginMutex); auto EHFrameRangeItr = InProcessLinks.find(&MR); if (EHFrameRangeItr == InProcessLinks.end()) return Error::success(); EmittedRange = EHFrameRangeItr->second; assert(EmittedRange.Start && "eh-frame addr to register can not be null"); InProcessLinks.erase(EHFrameRangeItr); } if (auto Err = MR.withResourceKeyDo( [&](ResourceKey K) { EHFrameRanges[K].push_back(EmittedRange); })) return Err; return Registrar->registerEHFrames(EmittedRange); } Error EHFrameRegistrationPlugin::notifyFailed( MaterializationResponsibility &MR) { std::lock_guard Lock(EHFramePluginMutex); InProcessLinks.erase(&MR); return Error::success(); } Error EHFrameRegistrationPlugin::notifyRemovingResources(JITDylib &JD, ResourceKey K) { std::vector RangesToRemove; ES.runSessionLocked([&] { auto I = EHFrameRanges.find(K); if (I != EHFrameRanges.end()) { RangesToRemove = std::move(I->second); EHFrameRanges.erase(I); } }); Error Err = Error::success(); while (!RangesToRemove.empty()) { auto RangeToRemove = RangesToRemove.back(); RangesToRemove.pop_back(); assert(RangeToRemove.Start && "Untracked eh-frame range must not be null"); Err = joinErrors(std::move(Err), Registrar->deregisterEHFrames(RangeToRemove)); } return Err; } void EHFrameRegistrationPlugin::notifyTransferringResources( JITDylib &JD, ResourceKey DstKey, ResourceKey SrcKey) { auto SI = EHFrameRanges.find(SrcKey); if (SI == EHFrameRanges.end()) return; auto DI = EHFrameRanges.find(DstKey); if (DI != EHFrameRanges.end()) { auto &SrcRanges = SI->second; auto &DstRanges = DI->second; DstRanges.reserve(DstRanges.size() + SrcRanges.size()); for (auto &SrcRange : SrcRanges) DstRanges.push_back(std::move(SrcRange)); EHFrameRanges.erase(SI); } else { // We need to move SrcKey's ranges over without invalidating the SI // iterator. auto Tmp = std::move(SI->second); EHFrameRanges.erase(SI); EHFrameRanges[DstKey] = std::move(Tmp); } } } // End namespace orc. } // End namespace llvm.