//===------ JITLinkGeneric.h - Generic JIT linker utilities -----*- 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 // //===----------------------------------------------------------------------===// // // Generic JITLinker utilities. E.g. graph pruning, eh-frame parsing. // //===----------------------------------------------------------------------===// #ifndef LIB_EXECUTIONENGINE_JITLINK_JITLINKGENERIC_H #define LIB_EXECUTIONENGINE_JITLINK_JITLINKGENERIC_H #include "llvm/ExecutionEngine/JITLink/JITLink.h" #define DEBUG_TYPE "jitlink" namespace llvm { namespace jitlink { /// Base class for a JIT linker. /// /// A JITLinkerBase instance links one object file into an ongoing JIT /// session. Symbol resolution and finalization operations are pluggable, /// and called using continuation passing (passing a continuation for the /// remaining linker work) to allow them to be performed asynchronously. class JITLinkerBase { public: JITLinkerBase(std::unique_ptr Ctx, std::unique_ptr G, PassConfiguration Passes) : Ctx(std::move(Ctx)), G(std::move(G)), Passes(std::move(Passes)) { assert(this->Ctx && "Ctx can not be null"); assert(this->G && "G can not be null"); } virtual ~JITLinkerBase(); protected: using InFlightAlloc = JITLinkMemoryManager::InFlightAlloc; using AllocResult = Expected>; using FinalizeResult = Expected; // Returns a reference to the graph being linked. LinkGraph &getGraph() { return *G; } // Returns true if the context says that the linker should add default // passes. This can be used by JITLinkerBase implementations when deciding // whether they should add default passes. bool shouldAddDefaultTargetPasses(const Triple &TT) { return Ctx->shouldAddDefaultTargetPasses(TT); } // Returns the PassConfiguration for this instance. This can be used by // JITLinkerBase implementations to add late passes that reference their // own data structures (e.g. for ELF implementations to locate / construct // a GOT start symbol prior to fixup). PassConfiguration &getPassConfig() { return Passes; } // Phase 1: // 1.1: Run pre-prune passes // 1.2: Prune graph // 1.3: Run post-prune passes // 1.4: Allocate memory. void linkPhase1(std::unique_ptr Self); // Phase 2: // 2.2: Run post-allocation passes // 2.3: Notify context of final assigned symbol addresses // 2.4: Identify external symbols and make an async call to resolve void linkPhase2(std::unique_ptr Self, AllocResult AR); // Phase 3: // 3.1: Apply resolution results // 3.2: Run pre-fixup passes // 3.3: Fix up block contents // 3.4: Run post-fixup passes // 3.5: Make an async call to transfer and finalize memory. void linkPhase3(std::unique_ptr Self, Expected LookupResult); // Phase 4: // 4.1: Call OnFinalized callback, handing off allocation. void linkPhase4(std::unique_ptr Self, FinalizeResult FR); private: // Run all passes in the given pass list, bailing out immediately if any pass // returns an error. Error runPasses(LinkGraphPassList &Passes); // Copy block contents and apply relocations. // Implemented in JITLinker. virtual Error fixUpBlocks(LinkGraph &G) const = 0; JITLinkContext::LookupMap getExternalSymbolNames() const; void applyLookupResult(AsyncLookupResult LR); void abandonAllocAndBailOut(std::unique_ptr Self, Error Err); std::unique_ptr Ctx; std::unique_ptr G; PassConfiguration Passes; std::unique_ptr Alloc; }; template class JITLinker : public JITLinkerBase { public: using JITLinkerBase::JITLinkerBase; /// Link constructs a LinkerImpl instance and calls linkPhase1. /// Link should be called with the constructor arguments for LinkerImpl, which /// will be forwarded to the constructor. template static void link(ArgTs &&... Args) { auto L = std::make_unique(std::forward(Args)...); // Ownership of the linker is passed into the linker's doLink function to // allow it to be passed on to async continuations. // // FIXME: Remove LTmp once we have c++17. // C++17 sequencing rules guarantee that function name expressions are // sequenced before arguments, so L->linkPhase1(std::move(L), ...) will be // well formed. auto <mp = *L; LTmp.linkPhase1(std::move(L)); } private: const LinkerImpl &impl() const { return static_cast(*this); } Error fixUpBlocks(LinkGraph &G) const override { LLVM_DEBUG(dbgs() << "Fixing up blocks:\n"); for (auto &Sec : G.sections()) { bool NoAllocSection = Sec.getMemLifetime() == orc::MemLifetime::NoAlloc; for (auto *B : Sec.blocks()) { LLVM_DEBUG(dbgs() << " " << *B << ":\n"); // Copy Block data and apply fixups. LLVM_DEBUG(dbgs() << " Applying fixups.\n"); assert((!B->isZeroFill() || all_of(B->edges(), [](const Edge &E) { return E.getKind() == Edge::KeepAlive; })) && "Non-KeepAlive edges in zero-fill block?"); // If this is a no-alloc section then copy the block content into // memory allocated on the Graph's allocator (if it hasn't been // already). if (NoAllocSection) (void)B->getMutableContent(G); for (auto &E : B->edges()) { // Skip non-relocation edges. if (!E.isRelocation()) continue; // If B is a block in a Standard or Finalize section then make sure // that no edges point to symbols in NoAlloc sections. assert((NoAllocSection || !E.getTarget().isDefined() || E.getTarget().getBlock().getSection().getMemLifetime() != orc::MemLifetime::NoAlloc) && "Block in allocated section has edge pointing to no-alloc " "section"); // Dispatch to LinkerImpl for fixup. if (auto Err = impl().applyFixup(G, *B, E)) return Err; } } } return Error::success(); } }; /// Removes dead symbols/blocks/addressables. /// /// Finds the set of symbols and addressables reachable from any symbol /// initially marked live. All symbols/addressables not marked live at the end /// of this process are removed. void prune(LinkGraph &G); } // end namespace jitlink } // end namespace llvm #undef DEBUG_TYPE // "jitlink" #endif // LIB_EXECUTIONENGINE_JITLINK_JITLINKGENERIC_H