//===-- Speculation.h - Speculative Compilation --*- 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 // //===----------------------------------------------------------------------===// // // Contains the definition to support speculative compilation when laziness is // enabled. //===----------------------------------------------------------------------===// #ifndef LLVM_EXECUTIONENGINE_ORC_SPECULATION_H #define LLVM_EXECUTIONENGINE_ORC_SPECULATION_H #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/Optional.h" #include "llvm/ExecutionEngine/Orc/Core.h" #include "llvm/ExecutionEngine/Orc/DebugUtils.h" #include "llvm/ExecutionEngine/Orc/IRCompileLayer.h" #include "llvm/Support/Debug.h" #include #include #include namespace llvm { namespace orc { class Speculator; // Track the Impls (JITDylib,Symbols) of Symbols while lazy call through // trampolines are created. Operations are guarded by locks tp ensure that Imap // stays in consistent state after read/write class ImplSymbolMap { friend class Speculator; public: using AliaseeDetails = std::pair; using Alias = SymbolStringPtr; using ImapTy = DenseMap; void trackImpls(SymbolAliasMap ImplMaps, JITDylib *SrcJD); private: // FIX ME: find a right way to distinguish the pre-compile Symbols, and update // the callsite Optional getImplFor(const SymbolStringPtr &StubSymbol) { std::lock_guard Lockit(ConcurrentAccess); auto Position = Maps.find(StubSymbol); if (Position != Maps.end()) return Position->getSecond(); else return None; } std::mutex ConcurrentAccess; ImapTy Maps; }; // Defines Speculator Concept, class Speculator { public: using TargetFAddr = JITTargetAddress; using FunctionCandidatesMap = DenseMap; using StubAddrLikelies = DenseMap; private: void registerSymbolsWithAddr(TargetFAddr ImplAddr, SymbolNameSet likelySymbols) { std::lock_guard Lockit(ConcurrentAccess); GlobalSpecMap.insert({ImplAddr, std::move(likelySymbols)}); } void launchCompile(JITTargetAddress FAddr) { SymbolNameSet CandidateSet; // Copy CandidateSet is necessary, to avoid unsynchronized access to // the datastructure. { std::lock_guard Lockit(ConcurrentAccess); auto It = GlobalSpecMap.find(FAddr); if (It == GlobalSpecMap.end()) return; CandidateSet = It->getSecond(); } SymbolDependenceMap SpeculativeLookUpImpls; for (auto &Callee : CandidateSet) { auto ImplSymbol = AliaseeImplTable.getImplFor(Callee); // try to distinguish already compiled & library symbols if (!ImplSymbol.hasValue()) continue; const auto &ImplSymbolName = ImplSymbol.getPointer()->first; JITDylib *ImplJD = ImplSymbol.getPointer()->second; auto &SymbolsInJD = SpeculativeLookUpImpls[ImplJD]; SymbolsInJD.insert(ImplSymbolName); } DEBUG_WITH_TYPE("orc", { for (auto &I : SpeculativeLookUpImpls) { llvm::dbgs() << "\n In " << I.first->getName() << " JITDylib "; for (auto &N : I.second) llvm::dbgs() << "\n Likely Symbol : " << N; } }); // for a given symbol, there may be no symbol qualified for speculatively // compile try to fix this before jumping to this code if possible. for (auto &LookupPair : SpeculativeLookUpImpls) ES.lookup( LookupKind::Static, makeJITDylibSearchOrder(LookupPair.first, JITDylibLookupFlags::MatchAllSymbols), SymbolLookupSet(LookupPair.second), SymbolState::Ready, [this](Expected Result) { if (auto Err = Result.takeError()) ES.reportError(std::move(Err)); }, NoDependenciesToRegister); } public: Speculator(ImplSymbolMap &Impl, ExecutionSession &ref) : AliaseeImplTable(Impl), ES(ref), GlobalSpecMap(0) {} Speculator(const Speculator &) = delete; Speculator(Speculator &&) = delete; Speculator &operator=(const Speculator &) = delete; Speculator &operator=(Speculator &&) = delete; /// Define symbols for this Speculator object (__orc_speculator) and the /// speculation runtime entry point symbol (__orc_speculate_for) in the /// given JITDylib. Error addSpeculationRuntime(JITDylib &JD, MangleAndInterner &Mangle); // Speculatively compile likely functions for the given Stub Address. // destination of __orc_speculate_for jump void speculateFor(TargetFAddr StubAddr) { launchCompile(StubAddr); } // FIXME : Register with Stub Address, after JITLink Fix. void registerSymbols(FunctionCandidatesMap Candidates, JITDylib *JD) { for (auto &SymPair : Candidates) { auto Target = SymPair.first; auto Likely = SymPair.second; auto OnReadyFixUp = [Likely, Target, this](Expected ReadySymbol) { if (ReadySymbol) { auto RAddr = (*ReadySymbol)[Target].getAddress(); registerSymbolsWithAddr(RAddr, std::move(Likely)); } else this->getES().reportError(ReadySymbol.takeError()); }; // Include non-exported symbols also. ES.lookup( LookupKind::Static, makeJITDylibSearchOrder(JD, JITDylibLookupFlags::MatchAllSymbols), SymbolLookupSet(Target, SymbolLookupFlags::WeaklyReferencedSymbol), SymbolState::Ready, OnReadyFixUp, NoDependenciesToRegister); } } ExecutionSession &getES() { return ES; } private: static void speculateForEntryPoint(Speculator *Ptr, uint64_t StubId); std::mutex ConcurrentAccess; ImplSymbolMap &AliaseeImplTable; ExecutionSession &ES; StubAddrLikelies GlobalSpecMap; }; class IRSpeculationLayer : public IRLayer { public: using IRlikiesStrRef = Optional>>; using ResultEval = std::function; using TargetAndLikelies = DenseMap; IRSpeculationLayer(ExecutionSession &ES, IRCompileLayer &BaseLayer, Speculator &Spec, MangleAndInterner &Mangle, ResultEval Interpreter) : IRLayer(ES, BaseLayer.getManglingOptions()), NextLayer(BaseLayer), S(Spec), Mangle(Mangle), QueryAnalysis(Interpreter) {} void emit(std::unique_ptr R, ThreadSafeModule TSM) override; private: TargetAndLikelies internToJITSymbols(DenseMap> IRNames) { assert(!IRNames.empty() && "No IRNames received to Intern?"); TargetAndLikelies InternedNames; for (auto &NamePair : IRNames) { DenseSet TargetJITNames; for (auto &TargetNames : NamePair.second) TargetJITNames.insert(Mangle(TargetNames)); InternedNames[Mangle(NamePair.first)] = std::move(TargetJITNames); } return InternedNames; } IRCompileLayer &NextLayer; Speculator &S; MangleAndInterner &Mangle; ResultEval QueryAnalysis; }; } // namespace orc } // namespace llvm #endif // LLVM_EXECUTIONENGINE_ORC_SPECULATION_H