//===------- EPCIndirectionUtils.cpp -- EPC based indirection APIs --------===// // // 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/EPCIndirectionUtils.h" #include "llvm/ExecutionEngine/Orc/ExecutorProcessControl.h" #include "llvm/Support/MathExtras.h" #include using namespace llvm; using namespace llvm::orc; namespace llvm { namespace orc { class EPCIndirectionUtilsAccess { public: using IndirectStubInfo = EPCIndirectionUtils::IndirectStubInfo; using IndirectStubInfoVector = EPCIndirectionUtils::IndirectStubInfoVector; static Expected getIndirectStubs(EPCIndirectionUtils &EPCIU, unsigned NumStubs) { return EPCIU.getIndirectStubs(NumStubs); }; }; } // end namespace orc } // end namespace llvm namespace { class EPCTrampolinePool : public TrampolinePool { public: EPCTrampolinePool(EPCIndirectionUtils &EPCIU); Error deallocatePool(); protected: Error grow() override; using FinalizedAlloc = jitlink::JITLinkMemoryManager::FinalizedAlloc; EPCIndirectionUtils &EPCIU; unsigned TrampolineSize = 0; unsigned TrampolinesPerPage = 0; std::vector TrampolineBlocks; }; class EPCIndirectStubsManager : public IndirectStubsManager, private EPCIndirectionUtilsAccess { public: EPCIndirectStubsManager(EPCIndirectionUtils &EPCIU) : EPCIU(EPCIU) {} Error deallocateStubs(); Error createStub(StringRef StubName, JITTargetAddress StubAddr, JITSymbolFlags StubFlags) override; Error createStubs(const StubInitsMap &StubInits) override; JITEvaluatedSymbol findStub(StringRef Name, bool ExportedStubsOnly) override; JITEvaluatedSymbol findPointer(StringRef Name) override; Error updatePointer(StringRef Name, JITTargetAddress NewAddr) override; private: using StubInfo = std::pair; std::mutex ISMMutex; EPCIndirectionUtils &EPCIU; StringMap StubInfos; }; EPCTrampolinePool::EPCTrampolinePool(EPCIndirectionUtils &EPCIU) : EPCIU(EPCIU) { auto &EPC = EPCIU.getExecutorProcessControl(); auto &ABI = EPCIU.getABISupport(); TrampolineSize = ABI.getTrampolineSize(); TrampolinesPerPage = (EPC.getPageSize() - ABI.getPointerSize()) / TrampolineSize; } Error EPCTrampolinePool::deallocatePool() { std::promise DeallocResultP; auto DeallocResultF = DeallocResultP.get_future(); EPCIU.getExecutorProcessControl().getMemMgr().deallocate( std::move(TrampolineBlocks), [&](Error Err) { DeallocResultP.set_value(std::move(Err)); }); return DeallocResultF.get(); } Error EPCTrampolinePool::grow() { using namespace jitlink; assert(AvailableTrampolines.empty() && "Grow called with trampolines still available"); auto ResolverAddress = EPCIU.getResolverBlockAddress(); assert(ResolverAddress && "Resolver address can not be null"); auto &EPC = EPCIU.getExecutorProcessControl(); auto PageSize = EPC.getPageSize(); auto Alloc = SimpleSegmentAlloc::Create( EPC.getMemMgr(), nullptr, {{MemProt::Read | MemProt::Exec, {PageSize, Align(PageSize)}}}); if (!Alloc) return Alloc.takeError(); unsigned NumTrampolines = TrampolinesPerPage; auto SegInfo = Alloc->getSegInfo(MemProt::Read | MemProt::Exec); EPCIU.getABISupport().writeTrampolines(SegInfo.WorkingMem.data(), SegInfo.Addr.getValue(), ResolverAddress, NumTrampolines); for (unsigned I = 0; I < NumTrampolines; ++I) AvailableTrampolines.push_back(SegInfo.Addr.getValue() + (I * TrampolineSize)); auto FA = Alloc->finalize(); if (!FA) return FA.takeError(); TrampolineBlocks.push_back(std::move(*FA)); return Error::success(); } Error EPCIndirectStubsManager::createStub(StringRef StubName, JITTargetAddress StubAddr, JITSymbolFlags StubFlags) { StubInitsMap SIM; SIM[StubName] = std::make_pair(StubAddr, StubFlags); return createStubs(SIM); } Error EPCIndirectStubsManager::createStubs(const StubInitsMap &StubInits) { auto AvailableStubInfos = getIndirectStubs(EPCIU, StubInits.size()); if (!AvailableStubInfos) return AvailableStubInfos.takeError(); { std::lock_guard Lock(ISMMutex); unsigned ASIdx = 0; for (auto &SI : StubInits) { auto &A = (*AvailableStubInfos)[ASIdx++]; StubInfos[SI.first()] = std::make_pair(A, SI.second.second); } } auto &MemAccess = EPCIU.getExecutorProcessControl().getMemoryAccess(); switch (EPCIU.getABISupport().getPointerSize()) { case 4: { unsigned ASIdx = 0; std::vector PtrUpdates; for (auto &SI : StubInits) PtrUpdates.push_back( {ExecutorAddr((*AvailableStubInfos)[ASIdx++].PointerAddress), static_cast(SI.second.first)}); return MemAccess.writeUInt32s(PtrUpdates); } case 8: { unsigned ASIdx = 0; std::vector PtrUpdates; for (auto &SI : StubInits) PtrUpdates.push_back( {ExecutorAddr((*AvailableStubInfos)[ASIdx++].PointerAddress), static_cast(SI.second.first)}); return MemAccess.writeUInt64s(PtrUpdates); } default: return make_error("Unsupported pointer size", inconvertibleErrorCode()); } } JITEvaluatedSymbol EPCIndirectStubsManager::findStub(StringRef Name, bool ExportedStubsOnly) { std::lock_guard Lock(ISMMutex); auto I = StubInfos.find(Name); if (I == StubInfos.end()) return nullptr; return {I->second.first.StubAddress, I->second.second}; } JITEvaluatedSymbol EPCIndirectStubsManager::findPointer(StringRef Name) { std::lock_guard Lock(ISMMutex); auto I = StubInfos.find(Name); if (I == StubInfos.end()) return nullptr; return {I->second.first.PointerAddress, I->second.second}; } Error EPCIndirectStubsManager::updatePointer(StringRef Name, JITTargetAddress NewAddr) { JITTargetAddress PtrAddr = 0; { std::lock_guard Lock(ISMMutex); auto I = StubInfos.find(Name); if (I == StubInfos.end()) return make_error("Unknown stub name", inconvertibleErrorCode()); PtrAddr = I->second.first.PointerAddress; } auto &MemAccess = EPCIU.getExecutorProcessControl().getMemoryAccess(); switch (EPCIU.getABISupport().getPointerSize()) { case 4: { tpctypes::UInt32Write PUpdate(ExecutorAddr(PtrAddr), NewAddr); return MemAccess.writeUInt32s(PUpdate); } case 8: { tpctypes::UInt64Write PUpdate(ExecutorAddr(PtrAddr), NewAddr); return MemAccess.writeUInt64s(PUpdate); } default: return make_error("Unsupported pointer size", inconvertibleErrorCode()); } } } // end anonymous namespace. namespace llvm { namespace orc { EPCIndirectionUtils::ABISupport::~ABISupport() = default; Expected> EPCIndirectionUtils::Create(ExecutorProcessControl &EPC) { const auto &TT = EPC.getTargetTriple(); switch (TT.getArch()) { default: return make_error( std::string("No EPCIndirectionUtils available for ") + TT.str(), inconvertibleErrorCode()); case Triple::aarch64: case Triple::aarch64_32: return CreateWithABI(EPC); case Triple::x86: return CreateWithABI(EPC); case Triple::loongarch64: return CreateWithABI(EPC); case Triple::mips: return CreateWithABI(EPC); case Triple::mipsel: return CreateWithABI(EPC); case Triple::mips64: case Triple::mips64el: return CreateWithABI(EPC); case Triple::riscv64: return CreateWithABI(EPC); case Triple::x86_64: if (TT.getOS() == Triple::OSType::Win32) return CreateWithABI(EPC); else return CreateWithABI(EPC); } } Error EPCIndirectionUtils::cleanup() { auto &MemMgr = EPC.getMemMgr(); auto Err = MemMgr.deallocate(std::move(IndirectStubAllocs)); if (TP) Err = joinErrors(std::move(Err), static_cast(*TP).deallocatePool()); if (ResolverBlock) Err = joinErrors(std::move(Err), MemMgr.deallocate(std::move(ResolverBlock))); return Err; } Expected EPCIndirectionUtils::writeResolverBlock(JITTargetAddress ReentryFnAddr, JITTargetAddress ReentryCtxAddr) { using namespace jitlink; assert(ABI && "ABI can not be null"); auto ResolverSize = ABI->getResolverCodeSize(); auto Alloc = SimpleSegmentAlloc::Create(EPC.getMemMgr(), nullptr, {{MemProt::Read | MemProt::Exec, {ResolverSize, Align(EPC.getPageSize())}}}); if (!Alloc) return Alloc.takeError(); auto SegInfo = Alloc->getSegInfo(MemProt::Read | MemProt::Exec); ResolverBlockAddr = SegInfo.Addr.getValue(); ABI->writeResolverCode(SegInfo.WorkingMem.data(), ResolverBlockAddr, ReentryFnAddr, ReentryCtxAddr); auto FA = Alloc->finalize(); if (!FA) return FA.takeError(); ResolverBlock = std::move(*FA); return ResolverBlockAddr; } std::unique_ptr EPCIndirectionUtils::createIndirectStubsManager() { return std::make_unique(*this); } TrampolinePool &EPCIndirectionUtils::getTrampolinePool() { if (!TP) TP = std::make_unique(*this); return *TP; } LazyCallThroughManager &EPCIndirectionUtils::createLazyCallThroughManager( ExecutionSession &ES, JITTargetAddress ErrorHandlerAddr) { assert(!LCTM && "createLazyCallThroughManager can not have been called before"); LCTM = std::make_unique(ES, ErrorHandlerAddr, &getTrampolinePool()); return *LCTM; } EPCIndirectionUtils::EPCIndirectionUtils(ExecutorProcessControl &EPC, std::unique_ptr ABI) : EPC(EPC), ABI(std::move(ABI)) { assert(this->ABI && "ABI can not be null"); assert(EPC.getPageSize() > getABISupport().getStubSize() && "Stubs larger than one page are not supported"); } Expected EPCIndirectionUtils::getIndirectStubs(unsigned NumStubs) { using namespace jitlink; std::lock_guard Lock(EPCUIMutex); // If there aren't enough stubs available then allocate some more. if (NumStubs > AvailableIndirectStubs.size()) { auto NumStubsToAllocate = NumStubs; auto PageSize = EPC.getPageSize(); auto StubBytes = alignTo(NumStubsToAllocate * ABI->getStubSize(), PageSize); NumStubsToAllocate = StubBytes / ABI->getStubSize(); auto PtrBytes = alignTo(NumStubsToAllocate * ABI->getPointerSize(), PageSize); auto StubProt = MemProt::Read | MemProt::Exec; auto PtrProt = MemProt::Read | MemProt::Write; auto Alloc = SimpleSegmentAlloc::Create( EPC.getMemMgr(), nullptr, {{StubProt, {static_cast(StubBytes), Align(PageSize)}}, {PtrProt, {static_cast(PtrBytes), Align(PageSize)}}}); if (!Alloc) return Alloc.takeError(); auto StubSeg = Alloc->getSegInfo(StubProt); auto PtrSeg = Alloc->getSegInfo(PtrProt); ABI->writeIndirectStubsBlock(StubSeg.WorkingMem.data(), StubSeg.Addr.getValue(), PtrSeg.Addr.getValue(), NumStubsToAllocate); auto FA = Alloc->finalize(); if (!FA) return FA.takeError(); IndirectStubAllocs.push_back(std::move(*FA)); auto StubExecutorAddr = StubSeg.Addr; auto PtrExecutorAddr = PtrSeg.Addr; for (unsigned I = 0; I != NumStubsToAllocate; ++I) { AvailableIndirectStubs.push_back(IndirectStubInfo( StubExecutorAddr.getValue(), PtrExecutorAddr.getValue())); StubExecutorAddr += ABI->getStubSize(); PtrExecutorAddr += ABI->getPointerSize(); } } assert(NumStubs <= AvailableIndirectStubs.size() && "Sufficient stubs should have been allocated above"); IndirectStubInfoVector Result; while (NumStubs--) { Result.push_back(AvailableIndirectStubs.back()); AvailableIndirectStubs.pop_back(); } return std::move(Result); } static JITTargetAddress reentry(JITTargetAddress LCTMAddr, JITTargetAddress TrampolineAddr) { auto &LCTM = *jitTargetAddressToPointer(LCTMAddr); std::promise LandingAddrP; auto LandingAddrF = LandingAddrP.get_future(); LCTM.resolveTrampolineLandingAddress( TrampolineAddr, [&](JITTargetAddress Addr) { LandingAddrP.set_value(Addr); }); return LandingAddrF.get(); } Error setUpInProcessLCTMReentryViaEPCIU(EPCIndirectionUtils &EPCIU) { auto &LCTM = EPCIU.getLazyCallThroughManager(); return EPCIU .writeResolverBlock(pointerToJITTargetAddress(&reentry), pointerToJITTargetAddress(&LCTM)) .takeError(); } } // end namespace orc } // end namespace llvm