//===------- 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/ADT/Optional.h" #include "llvm/ExecutionEngine/JITLink/EHFrameSupport.h" #include #define DEBUG_TYPE "orc" using namespace llvm; using namespace llvm::jitlink; using namespace llvm::orc; namespace llvm { namespace orc { class ObjectLinkingLayerJITLinkContext final : public JITLinkContext { public: ObjectLinkingLayerJITLinkContext(ObjectLinkingLayer &Layer, MaterializationResponsibility MR, std::unique_ptr ObjBuffer) : Layer(Layer), MR(std::move(MR)), ObjBuffer(std::move(ObjBuffer)) {} ~ObjectLinkingLayerJITLinkContext() { // If there is an object buffer return function then use it to // return ownership of the buffer. if (Layer.ReturnObjectBuffer) Layer.ReturnObjectBuffer(std::move(ObjBuffer)); } JITLinkMemoryManager &getMemoryManager() override { return *Layer.MemMgr; } MemoryBufferRef getObjectBuffer() const override { return ObjBuffer->getMemBufferRef(); } void notifyFailed(Error Err) override { 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 = [this, LookupContinuation = std::move(LC)]( Expected Result) mutable { auto Main = Layer.getExecutionSession().intern("_main"); if (!Result) LookupContinuation->run(Result.takeError()); else { AsyncLookupResult LR; for (auto &KV : *Result) LR[*KV.first] = KV.second; LookupContinuation->run(std::move(LR)); } }; for (auto &KV : InternalNamedSymbolDeps) { SymbolDependenceMap InternalDeps; InternalDeps[&MR.getTargetJITDylib()] = std::move(KV.second); MR.addDependencies(KV.first, InternalDeps); } ES.lookup(LookupKind::Static, LinkOrder, std::move(LookupSet), SymbolState::Resolved, std::move(OnResolve), [this](const SymbolDependenceMap &Deps) { registerDependencies(Deps); }); } void notifyResolved(LinkGraph &G) override { auto &ES = Layer.getExecutionSession(); SymbolFlagsMap ExtraSymbolsToClaim; bool AutoClaim = Layer.AutoClaimObjectSymbols; SymbolMap InternedResult; for (auto *Sym : G.defined_symbols()) if (Sym->hasName() && Sym->getScope() != Scope::Local) { auto InternedName = ES.intern(Sym->getName()); JITSymbolFlags Flags; if (Sym->isCallable()) Flags |= JITSymbolFlags::Callable; if (Sym->getScope() == Scope::Default) Flags |= JITSymbolFlags::Exported; InternedResult[InternedName] = JITEvaluatedSymbol(Sym->getAddress(), 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->hasName()) { auto InternedName = ES.intern(Sym->getName()); JITSymbolFlags Flags; Flags |= JITSymbolFlags::Absolute; if (Sym->isCallable()) Flags |= JITSymbolFlags::Callable; if (Sym->getLinkage() == Linkage::Weak) Flags |= JITSymbolFlags::Weak; InternedResult[InternedName] = JITEvaluatedSymbol(Sym->getAddress(), 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 notifyFailed(std::move(Err)); { // Check that InternedResult matches up with MR.getSymbols(). // This guards against faulty transformations / compilers / object caches. // First check that there aren't any missing symbols. size_t NumMaterializationSideEffectsOnlySymbols = 0; SymbolNameVector ExtraSymbols; SymbolNameVector MissingSymbols; for (auto &KV : MR.getSymbols()) { // If this is a materialization-side-effects only symbol then bump // the counter and make sure it's *not* defined, otherwise make // sure that it is defined. if (KV.second.hasMaterializationSideEffectsOnly()) { ++NumMaterializationSideEffectsOnlySymbols; if (InternedResult.count(KV.first)) ExtraSymbols.push_back(KV.first); continue; } else if (!InternedResult.count(KV.first)) MissingSymbols.push_back(KV.first); } // If there were missing symbols then report the error. if (!MissingSymbols.empty()) { ES.reportError(make_error( G.getName(), std::move(MissingSymbols))); MR.failMaterialization(); return; } // If there are more definitions than expected, add them to the // ExtraSymbols vector. 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()) { ES.reportError(make_error( G.getName(), std::move(ExtraSymbols))); MR.failMaterialization(); return; } } if (auto Err = MR.notifyResolved(InternedResult)) { Layer.getExecutionSession().reportError(std::move(Err)); MR.failMaterialization(); return; } Layer.notifyLoaded(MR); } void notifyFinalized( std::unique_ptr A) override { if (auto Err = Layer.notifyEmitted(MR, std::move(A))) { Layer.getExecutionSession().reportError(std::move(Err)); MR.failMaterialization(); return; } if (auto Err = MR.notifyEmitted()) { Layer.getExecutionSession().reportError(std::move(Err)); MR.failMaterialization(); } } LinkGraphPassFunction getMarkLivePass(const Triple &TT) const override { return [this](LinkGraph &G) { return markResponsibilitySymbolsLive(G); }; } Error modifyPassConfig(const Triple &TT, 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 externalizeWeakAndCommonSymbols(G); }); Layer.modifyPassConfig(MR, TT, Config); Config.PostPrunePasses.push_back( [this](LinkGraph &G) { return computeNamedSymbolDependencies(G); }); return Error::success(); } private: struct LocalSymbolNamedDependencies { SymbolNameSet Internal, External; }; using LocalSymbolNamedDependenciesMap = DenseMap; Error externalizeWeakAndCommonSymbols(LinkGraph &G) { auto &ES = Layer.getExecutionSession(); for (auto *Sym : G.defined_symbols()) if (Sym->hasName() && Sym->getLinkage() == Linkage::Weak) { if (!MR.getSymbols().count(ES.intern(Sym->getName()))) G.makeExternal(*Sym); } for (auto *Sym : G.absolute_symbols()) if (Sym->hasName() && Sym->getLinkage() == Linkage::Weak) { if (!MR.getSymbols().count(ES.intern(Sym->getName()))) G.makeExternal(*Sym); } 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 computeNamedSymbolDependencies(LinkGraph &G) { auto &ES = MR.getTargetJITDylib().getExecutionSession(); auto LocalDeps = computeLocalDeps(G); // Compute dependencies for symbols defined in the JITLink graph. for (auto *Sym : G.defined_symbols()) { // Skip local symbols: we do not track dependencies for these. if (Sym->getScope() == Scope::Local) continue; assert(Sym->hasName() && "Defined non-local jitlink::Symbol should have a name"); SymbolNameSet ExternalSymDeps, InternalSymDeps; // Find internal and external named symbol dependencies. for (auto &E : Sym->getBlock().edges()) { auto &TargetSym = E.getTarget(); if (TargetSym.getScope() != Scope::Local) { if (TargetSym.isExternal()) ExternalSymDeps.insert(ES.intern(TargetSym.getName())); else if (&TargetSym != Sym) InternalSymDeps.insert(ES.intern(TargetSym.getName())); } else { assert(TargetSym.isDefined() && "local symbols must be defined"); auto I = LocalDeps.find(&TargetSym); if (I != LocalDeps.end()) { for (auto &S : I->second.External) ExternalSymDeps.insert(S); for (auto &S : I->second.Internal) InternalSymDeps.insert(S); } } } if (ExternalSymDeps.empty() && InternalSymDeps.empty()) continue; auto SymName = ES.intern(Sym->getName()); if (!ExternalSymDeps.empty()) ExternalNamedSymbolDeps[SymName] = std::move(ExternalSymDeps); if (!InternalSymDeps.empty()) InternalNamedSymbolDeps[SymName] = std::move(InternalSymDeps); } for (auto &P : Layer.Plugins) { auto SyntheticLocalDeps = P->getSyntheticSymbolLocalDependencies(MR); if (SyntheticLocalDeps.empty()) continue; for (auto &KV : SyntheticLocalDeps) { auto &Name = KV.first; auto &LocalDepsForName = KV.second; for (auto *Local : LocalDepsForName) { assert(Local->getScope() == Scope::Local && "Dependence on non-local symbol"); auto LocalNamedDepsItr = LocalDeps.find(Local); if (LocalNamedDepsItr == LocalDeps.end()) continue; for (auto &S : LocalNamedDepsItr->second.Internal) InternalNamedSymbolDeps[Name].insert(S); for (auto &S : LocalNamedDepsItr->second.External) ExternalNamedSymbolDeps[Name].insert(S); } } } return Error::success(); } LocalSymbolNamedDependenciesMap computeLocalDeps(LinkGraph &G) { DenseMap> DepMap; // For all local symbols: // (1) Add their named dependencies. // (2) Add them to the worklist for further iteration if they have any // depend on any other local symbols. struct WorklistEntry { WorklistEntry(Symbol *Sym, DenseSet LocalDeps) : Sym(Sym), LocalDeps(std::move(LocalDeps)) {} Symbol *Sym = nullptr; DenseSet LocalDeps; }; std::vector Worklist; for (auto *Sym : G.defined_symbols()) if (Sym->getScope() == Scope::Local) { auto &SymNamedDeps = DepMap[Sym]; DenseSet LocalDeps; for (auto &E : Sym->getBlock().edges()) { auto &TargetSym = E.getTarget(); if (TargetSym.getScope() != Scope::Local) SymNamedDeps.insert(&TargetSym); else { assert(TargetSym.isDefined() && "local symbols must be defined"); LocalDeps.insert(&TargetSym); } } if (!LocalDeps.empty()) Worklist.push_back(WorklistEntry(Sym, std::move(LocalDeps))); } // Loop over all local symbols with local dependencies, propagating // their respective non-local dependencies. Iterate until we hit a stable // state. bool Changed; do { Changed = false; for (auto &WLEntry : Worklist) { auto *Sym = WLEntry.Sym; auto &NamedDeps = DepMap[Sym]; auto &LocalDeps = WLEntry.LocalDeps; for (auto *TargetSym : LocalDeps) { auto I = DepMap.find(TargetSym); if (I != DepMap.end()) for (const auto &S : I->second) Changed |= NamedDeps.insert(S).second; } } } while (Changed); // Intern the results to produce a mapping of jitlink::Symbol* to internal // and external symbol names. auto &ES = Layer.getExecutionSession(); LocalSymbolNamedDependenciesMap Result; for (auto &KV : DepMap) { auto *Local = KV.first; assert(Local->getScope() == Scope::Local && "DepMap keys should all be local symbols"); auto &LocalNamedDeps = Result[Local]; for (auto *Named : KV.second) { assert(Named->getScope() != Scope::Local && "DepMap values should all be non-local symbol sets"); if (Named->isExternal()) LocalNamedDeps.External.insert(ES.intern(Named->getName())); else LocalNamedDeps.Internal.insert(ES.intern(Named->getName())); } } return Result; } void registerDependencies(const SymbolDependenceMap &QueryDeps) { for (auto &NamedDepsEntry : ExternalNamedSymbolDeps) { auto &Name = NamedDepsEntry.first; auto &NameDeps = NamedDepsEntry.second; SymbolDependenceMap SymbolDeps; for (const auto &QueryDepsEntry : QueryDeps) { JITDylib &SourceJD = *QueryDepsEntry.first; const SymbolNameSet &Symbols = QueryDepsEntry.second; auto &DepsForJD = SymbolDeps[&SourceJD]; for (const auto &S : Symbols) if (NameDeps.count(S)) DepsForJD.insert(S); if (DepsForJD.empty()) SymbolDeps.erase(&SourceJD); } MR.addDependencies(Name, SymbolDeps); } } ObjectLinkingLayer &Layer; MaterializationResponsibility MR; std::unique_ptr ObjBuffer; DenseMap ExternalNamedSymbolDeps; DenseMap InternalNamedSymbolDeps; }; ObjectLinkingLayer::Plugin::~Plugin() {} ObjectLinkingLayer::ObjectLinkingLayer( ExecutionSession &ES, std::unique_ptr MemMgr) : ObjectLayer(ES), MemMgr(std::move(MemMgr)) {} ObjectLinkingLayer::~ObjectLinkingLayer() { if (auto Err = removeAllModules()) getExecutionSession().reportError(std::move(Err)); } void ObjectLinkingLayer::emit(MaterializationResponsibility R, std::unique_ptr O) { assert(O && "Object must not be null"); jitLink(std::make_unique( *this, std::move(R), std::move(O))); } void ObjectLinkingLayer::modifyPassConfig(MaterializationResponsibility &MR, const Triple &TT, PassConfiguration &PassConfig) { for (auto &P : Plugins) P->modifyPassConfig(MR, TT, PassConfig); } void ObjectLinkingLayer::notifyLoaded(MaterializationResponsibility &MR) { for (auto &P : Plugins) P->notifyLoaded(MR); } Error ObjectLinkingLayer::notifyEmitted(MaterializationResponsibility &MR, AllocPtr Alloc) { Error Err = Error::success(); for (auto &P : Plugins) Err = joinErrors(std::move(Err), P->notifyEmitted(MR)); if (Err) return Err; { std::lock_guard Lock(LayerMutex); UntrackedAllocs.push_back(std::move(Alloc)); } return Error::success(); } Error ObjectLinkingLayer::removeModule(VModuleKey K) { Error Err = Error::success(); for (auto &P : Plugins) Err = joinErrors(std::move(Err), P->notifyRemovingModule(K)); AllocPtr Alloc; { std::lock_guard Lock(LayerMutex); auto AllocItr = TrackedAllocs.find(K); Alloc = std::move(AllocItr->second); TrackedAllocs.erase(AllocItr); } assert(Alloc && "No allocation for key K"); return joinErrors(std::move(Err), Alloc->deallocate()); } Error ObjectLinkingLayer::removeAllModules() { Error Err = Error::success(); for (auto &P : Plugins) Err = joinErrors(std::move(Err), P->notifyRemovingAllModules()); std::vector Allocs; { std::lock_guard Lock(LayerMutex); Allocs = std::move(UntrackedAllocs); for (auto &KV : TrackedAllocs) Allocs.push_back(std::move(KV.second)); TrackedAllocs.clear(); } while (!Allocs.empty()) { Err = joinErrors(std::move(Err), Allocs.back()->deallocate()); Allocs.pop_back(); } return Err; } EHFrameRegistrationPlugin::EHFrameRegistrationPlugin( EHFrameRegistrar &Registrar) : Registrar(Registrar) {} void EHFrameRegistrationPlugin::modifyPassConfig( MaterializationResponsibility &MR, const Triple &TT, PassConfiguration &PassConfig) { PassConfig.PostFixupPasses.push_back(createEHFrameRecorderPass( TT, [this, &MR](JITTargetAddress 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) { std::lock_guard Lock(EHFramePluginMutex); auto EHFrameRangeItr = InProcessLinks.find(&MR); if (EHFrameRangeItr == InProcessLinks.end()) return Error::success(); auto EHFrameRange = EHFrameRangeItr->second; assert(EHFrameRange.Addr && "eh-frame addr to register can not be null"); InProcessLinks.erase(EHFrameRangeItr); if (auto Key = MR.getVModuleKey()) TrackedEHFrameRanges[Key] = EHFrameRange; else UntrackedEHFrameRanges.push_back(EHFrameRange); return Registrar.registerEHFrames(EHFrameRange.Addr, EHFrameRange.Size); } Error EHFrameRegistrationPlugin::notifyRemovingModule(VModuleKey K) { std::lock_guard Lock(EHFramePluginMutex); auto EHFrameRangeItr = TrackedEHFrameRanges.find(K); if (EHFrameRangeItr == TrackedEHFrameRanges.end()) return Error::success(); auto EHFrameRange = EHFrameRangeItr->second; assert(EHFrameRange.Addr && "Tracked eh-frame range must not be null"); TrackedEHFrameRanges.erase(EHFrameRangeItr); return Registrar.deregisterEHFrames(EHFrameRange.Addr, EHFrameRange.Size); } Error EHFrameRegistrationPlugin::notifyRemovingAllModules() { std::lock_guard Lock(EHFramePluginMutex); std::vector EHFrameRanges = std::move(UntrackedEHFrameRanges); EHFrameRanges.reserve(EHFrameRanges.size() + TrackedEHFrameRanges.size()); for (auto &KV : TrackedEHFrameRanges) EHFrameRanges.push_back(KV.second); TrackedEHFrameRanges.clear(); Error Err = Error::success(); while (!EHFrameRanges.empty()) { auto EHFrameRange = EHFrameRanges.back(); assert(EHFrameRange.Addr && "Untracked eh-frame range must not be null"); EHFrameRanges.pop_back(); Err = joinErrors(std::move(Err), Registrar.deregisterEHFrames(EHFrameRange.Addr, EHFrameRange.Size)); } return Err; } } // End namespace orc. } // End namespace llvm.