#pragma once #ifdef __GNUC__ #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wunused-parameter" #endif //===-- MachOPlatform.h - Utilities for executing MachO in Orc --*- 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 // //===----------------------------------------------------------------------===// // // Utilities for executing JIT'd MachO in Orc. // //===----------------------------------------------------------------------===// #ifndef LLVM_EXECUTIONENGINE_ORC_MACHOPLATFORM_H #define LLVM_EXECUTIONENGINE_ORC_MACHOPLATFORM_H #include "llvm/ADT/StringRef.h" #include "llvm/ExecutionEngine/Orc/Core.h" #include "llvm/ExecutionEngine/Orc/ExecutorProcessControl.h" #include "llvm/ExecutionEngine/Orc/ObjectLinkingLayer.h" #include "llvm/ExecutionEngine/Orc/Shared/ExecutorAddress.h" #include #include #include namespace llvm { namespace orc { /// Mediates between MachO initialization and ExecutionSession state. class MachOPlatform : public Platform { public: // Used internally by MachOPlatform, but made public to enable serialization. struct MachOJITDylibDepInfo { bool Sealed = false; std::vector DepHeaders; }; // Used internally by MachOPlatform, but made public to enable serialization. using MachOJITDylibDepInfoMap = std::vector>; /// Try to create a MachOPlatform instance, adding the ORC runtime to the /// given JITDylib. /// /// The ORC runtime requires access to a number of symbols in libc++, and /// requires access to symbols in libobjc, and libswiftCore to support /// Objective-C and Swift code. It is up to the caller to ensure that the /// requried symbols can be referenced by code added to PlatformJD. The /// standard way to achieve this is to first attach dynamic library search /// generators for either the given process, or for the specific required /// libraries, to PlatformJD, then to create the platform instance: /// /// \code{.cpp} /// auto &PlatformJD = ES.createBareJITDylib("stdlib"); /// PlatformJD.addGenerator( /// ExitOnErr(EPCDynamicLibrarySearchGenerator /// ::GetForTargetProcess(EPC))); /// ES.setPlatform( /// ExitOnErr(MachOPlatform::Create(ES, ObjLayer, EPC, PlatformJD, /// "/path/to/orc/runtime"))); /// \endcode /// /// Alternatively, these symbols could be added to another JITDylib that /// PlatformJD links against. /// /// Clients are also responsible for ensuring that any JIT'd code that /// depends on runtime functions (including any code using TLV or static /// destructors) can reference the runtime symbols. This is usually achieved /// by linking any JITDylibs containing regular code against /// PlatformJD. /// /// By default, MachOPlatform will add the set of aliases returned by the /// standardPlatformAliases function. This includes both required aliases /// (e.g. __cxa_atexit -> __orc_rt_macho_cxa_atexit for static destructor /// support), and optional aliases that provide JIT versions of common /// functions (e.g. dlopen -> __orc_rt_macho_jit_dlopen). Clients can /// override these defaults by passing a non-None value for the /// RuntimeAliases function, in which case the client is responsible for /// setting up all aliases (including the required ones). static Expected> Create(ExecutionSession &ES, ObjectLinkingLayer &ObjLinkingLayer, JITDylib &PlatformJD, const char *OrcRuntimePath, std::optional RuntimeAliases = std::nullopt); ExecutionSession &getExecutionSession() const { return ES; } ObjectLinkingLayer &getObjectLinkingLayer() const { return ObjLinkingLayer; } Error setupJITDylib(JITDylib &JD) override; Error teardownJITDylib(JITDylib &JD) override; Error notifyAdding(ResourceTracker &RT, const MaterializationUnit &MU) override; Error notifyRemoving(ResourceTracker &RT) override; /// Returns an AliasMap containing the default aliases for the MachOPlatform. /// This can be modified by clients when constructing the platform to add /// or remove aliases. static SymbolAliasMap standardPlatformAliases(ExecutionSession &ES); /// Returns the array of required CXX aliases. static ArrayRef> requiredCXXAliases(); /// Returns the array of standard runtime utility aliases for MachO. static ArrayRef> standardRuntimeUtilityAliases(); /// Returns true if the given section name is an initializer section. static bool isInitializerSection(StringRef SegName, StringRef SectName); private: // Data needed for bootstrap only. struct BootstrapInfo { std::mutex Mutex; std::condition_variable CV; size_t ActiveGraphs = 0; shared::AllocActions DeferredAAs; ExecutorAddr MachOHeaderAddr; }; // The MachOPlatformPlugin scans/modifies LinkGraphs to support MachO // platform features including initializers, exceptions, TLV, and language // runtime registration. class MachOPlatformPlugin : public ObjectLinkingLayer::Plugin { public: MachOPlatformPlugin(MachOPlatform &MP) : MP(MP) {} void modifyPassConfig(MaterializationResponsibility &MR, jitlink::LinkGraph &G, jitlink::PassConfiguration &Config) override; SyntheticSymbolDependenciesMap getSyntheticSymbolDependencies(MaterializationResponsibility &MR) override; // FIXME: We should be tentatively tracking scraped sections and discarding // if the MR fails. Error notifyFailed(MaterializationResponsibility &MR) override { return Error::success(); } Error notifyRemovingResources(JITDylib &JD, ResourceKey K) override { return Error::success(); } void notifyTransferringResources(JITDylib &JD, ResourceKey DstKey, ResourceKey SrcKey) override {} private: using InitSymbolDepMap = DenseMap; struct UnwindSections { SmallVector CodeRanges; ExecutorAddrRange DwarfSection; ExecutorAddrRange CompactUnwindSection; }; Error bootstrapPipelineStart(jitlink::LinkGraph &G); Error bootstrapPipelineRecordRuntimeFunctions(jitlink::LinkGraph &G); Error bootstrapPipelineEnd(jitlink::LinkGraph &G); Error recordRuntimeRegistrationFunctions(jitlink::LinkGraph &G); Error associateJITDylibHeaderSymbol(jitlink::LinkGraph &G, MaterializationResponsibility &MR); Error preserveInitSections(jitlink::LinkGraph &G, MaterializationResponsibility &MR); Error processObjCImageInfo(jitlink::LinkGraph &G, MaterializationResponsibility &MR); Error fixTLVSectionsAndEdges(jitlink::LinkGraph &G, JITDylib &JD); std::optional findUnwindSectionInfo(jitlink::LinkGraph &G); Error registerObjectPlatformSections(jitlink::LinkGraph &G, JITDylib &JD, bool InBootstrapPhase); std::mutex PluginMutex; MachOPlatform ∓ // FIXME: ObjCImageInfos and HeaderAddrs need to be cleared when // JITDylibs are removed. DenseMap> ObjCImageInfos; DenseMap HeaderAddrs; InitSymbolDepMap InitSymbolDeps; }; using GetJITDylibHeaderSendResultFn = unique_function)>; using GetJITDylibNameSendResultFn = unique_function)>; using PushInitializersSendResultFn = unique_function)>; using SendSymbolAddressFn = unique_function)>; static bool supportedTarget(const Triple &TT); MachOPlatform(ExecutionSession &ES, ObjectLinkingLayer &ObjLinkingLayer, JITDylib &PlatformJD, std::unique_ptr OrcRuntimeGenerator, Error &Err); // Associate MachOPlatform JIT-side runtime support functions with handlers. Error associateRuntimeSupportFunctions(); // Implements rt_pushInitializers by making repeat async lookups for // initializer symbols (each lookup may spawn more initializer symbols if // it pulls in new materializers, e.g. from objects in a static library). void pushInitializersLoop(PushInitializersSendResultFn SendResult, JITDylibSP JD); // Handle requests from the ORC runtime to push MachO initializer info. void rt_pushInitializers(PushInitializersSendResultFn SendResult, ExecutorAddr JDHeaderAddr); // Handle requests for symbol addresses from the ORC runtime. void rt_lookupSymbol(SendSymbolAddressFn SendResult, ExecutorAddr Handle, StringRef SymbolName); // Call the ORC runtime to create a pthread key. Expected createPThreadKey(); ExecutionSession &ES; JITDylib &PlatformJD; ObjectLinkingLayer &ObjLinkingLayer; SymbolStringPtr MachOHeaderStartSymbol = ES.intern("___dso_handle"); struct RuntimeFunction { RuntimeFunction(SymbolStringPtr Name) : Name(std::move(Name)) {} SymbolStringPtr Name; ExecutorAddr Addr; }; RuntimeFunction PlatformBootstrap{ ES.intern("___orc_rt_macho_platform_bootstrap")}; RuntimeFunction PlatformShutdown{ ES.intern("___orc_rt_macho_platform_shutdown")}; RuntimeFunction RegisterEHFrameSection{ ES.intern("___orc_rt_macho_register_ehframe_section")}; RuntimeFunction DeregisterEHFrameSection{ ES.intern("___orc_rt_macho_deregister_ehframe_section")}; RuntimeFunction RegisterJITDylib{ ES.intern("___orc_rt_macho_register_jitdylib")}; RuntimeFunction DeregisterJITDylib{ ES.intern("___orc_rt_macho_deregister_jitdylib")}; RuntimeFunction RegisterObjectPlatformSections{ ES.intern("___orc_rt_macho_register_object_platform_sections")}; RuntimeFunction DeregisterObjectPlatformSections{ ES.intern("___orc_rt_macho_deregister_object_platform_sections")}; RuntimeFunction CreatePThreadKey{ ES.intern("___orc_rt_macho_create_pthread_key")}; DenseMap RegisteredInitSymbols; std::mutex PlatformMutex; DenseMap JITDylibToHeaderAddr; DenseMap HeaderAddrToJITDylib; DenseMap JITDylibToPThreadKey; std::atomic Bootstrap; }; namespace shared { using SPSNamedExecutorAddrRangeSequence = SPSSequence>; } // end namespace shared } // end namespace orc } // end namespace llvm #endif // LLVM_EXECUTIONENGINE_ORC_MACHOPLATFORM_H #ifdef __GNUC__ #pragma GCC diagnostic pop #endif