//===- RTDyldObjectLinkingLayer.h - RTDyld-based jit linking ---*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Contains the definition for an RTDyld-based, in-process object linking layer.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_EXECUTIONENGINE_ORC_RTDYLDOBJECTLINKINGLAYER_H
#define LLVM_EXECUTIONENGINE_ORC_RTDYLDOBJECTLINKINGLAYER_H
#include "llvm/ADT/STLExtras.h"
#include "llvm/ADT/StringMap.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/ExecutionEngine/JITSymbol.h"
#include "llvm/ExecutionEngine/Orc/Core.h"
#include "llvm/ExecutionEngine/Orc/Layer.h"
#include "llvm/ExecutionEngine/Orc/Legacy.h"
#include "llvm/ExecutionEngine/RuntimeDyld.h"
#include "llvm/Object/ObjectFile.h"
#include "llvm/Support/Error.h"
#include <algorithm>
#include <cassert>
#include <functional>
#include <list>
#include <memory>
#include <string>
#include <utility>
#include <vector>
namespace llvm {
namespace orc {
class RTDyldObjectLinkingLayer : public ObjectLayer {
public:
/// Functor for receiving object-loaded notifications.
using NotifyLoadedFunction =
std::function<void(VModuleKey, const object::ObjectFile &Obj,
const RuntimeDyld::LoadedObjectInfo &)>;
/// Functor for receiving finalization notifications.
using NotifyEmittedFunction = std::function<void(VModuleKey)>;
using GetMemoryManagerFunction =
std::function<std::unique_ptr<RuntimeDyld::MemoryManager>()>;
/// Construct an ObjectLinkingLayer with the given NotifyLoaded,
/// and NotifyEmitted functors.
RTDyldObjectLinkingLayer(
ExecutionSession &ES, GetMemoryManagerFunction GetMemoryManager,
NotifyLoadedFunction NotifyLoaded = NotifyLoadedFunction(),
NotifyEmittedFunction NotifyEmitted = NotifyEmittedFunction());
/// Emit the object.
void emit(MaterializationResponsibility R,
std::unique_ptr<MemoryBuffer> O) override;
/// Set the 'ProcessAllSections' flag.
///
/// If set to true, all sections in each object file will be allocated using
/// the memory manager, rather than just the sections required for execution.
///
/// This is kludgy, and may be removed in the future.
RTDyldObjectLinkingLayer &setProcessAllSections(bool ProcessAllSections) {
this->ProcessAllSections = ProcessAllSections;
return *this;
}
/// Instructs this RTDyldLinkingLayer2 instance to override the symbol flags
/// returned by RuntimeDyld for any given object file with the flags supplied
/// by the MaterializationResponsibility instance. This is a workaround to
/// support symbol visibility in COFF, which does not use the libObject's
/// SF_Exported flag. Use only when generating / adding COFF object files.
///
/// FIXME: We should be able to remove this if/when COFF properly tracks
/// exported symbols.
RTDyldObjectLinkingLayer &
setOverrideObjectFlagsWithResponsibilityFlags(bool OverrideObjectFlags) {
this->OverrideObjectFlags = OverrideObjectFlags;
return *this;
}
/// If set, this RTDyldObjectLinkingLayer instance will claim responsibility
/// for any symbols provided by a given object file that were not already in
/// the MaterializationResponsibility instance. Setting this flag allows
/// higher-level program representations (e.g. LLVM IR) to be added based on
/// only a subset of the symbols they provide, without having to write
/// intervening layers to scan and add the additional symbols. This trades
/// diagnostic quality for convenience however: If all symbols are enumerated
/// up-front then clashes can be detected and reported early (and usually
/// deterministically). If this option is set, clashes for the additional
/// symbols may not be detected until late, and detection may depend on
/// the flow of control through JIT'd code. Use with care.
RTDyldObjectLinkingLayer &
setAutoClaimResponsibilityForObjectSymbols(bool AutoClaimObjectSymbols) {
this->AutoClaimObjectSymbols = AutoClaimObjectSymbols;
return *this;
}
private:
Error onObjLoad(VModuleKey K, MaterializationResponsibility &R,
object::ObjectFile &Obj,
std::unique_ptr<RuntimeDyld::LoadedObjectInfo> LoadedObjInfo,
std::map<StringRef, JITEvaluatedSymbol> Resolved,
std::set<StringRef> &InternalSymbols);
void onObjEmit(VModuleKey K, MaterializationResponsibility &R, Error Err);
mutable std::mutex RTDyldLayerMutex;
GetMemoryManagerFunction GetMemoryManager;
NotifyLoadedFunction NotifyLoaded;
NotifyEmittedFunction NotifyEmitted;
bool ProcessAllSections = false;
bool OverrideObjectFlags = false;
bool AutoClaimObjectSymbols = false;
std::vector<std::unique_ptr<RuntimeDyld::MemoryManager>> MemMgrs;
};
class LegacyRTDyldObjectLinkingLayerBase {
public:
using ObjectPtr = std::unique_ptr<MemoryBuffer>;
protected:
/// Holds an object to be allocated/linked as a unit in the JIT.
///
/// An instance of this class will be created for each object added
/// via JITObjectLayer::addObject. Deleting the instance (via
/// removeObject) frees its memory, removing all symbol definitions that
/// had been provided by this instance. Higher level layers are responsible
/// for taking any action required to handle the missing symbols.
class LinkedObject {
public:
LinkedObject() = default;
LinkedObject(const LinkedObject&) = delete;
void operator=(const LinkedObject&) = delete;
virtual ~LinkedObject() = default;
virtual Error finalize() = 0;
virtual JITSymbol::GetAddressFtor
getSymbolMaterializer(std::string Name) = 0;
virtual void mapSectionAddress(const void *LocalAddress,
JITTargetAddress TargetAddr) const = 0;
JITSymbol getSymbol(StringRef Name, bool ExportedSymbolsOnly) {
auto SymEntry = SymbolTable.find(Name);
if (SymEntry == SymbolTable.end())
return nullptr;
if (!SymEntry->second.getFlags().isExported() && ExportedSymbolsOnly)
return nullptr;
if (!Finalized)
return JITSymbol(getSymbolMaterializer(Name),
SymEntry->second.getFlags());
return JITSymbol(SymEntry->second);
}
protected:
StringMap<JITEvaluatedSymbol> SymbolTable;
bool Finalized = false;
};
};
/// Bare bones object linking layer.
///
/// This class is intended to be used as the base layer for a JIT. It allows
/// object files to be loaded into memory, linked, and the addresses of their
/// symbols queried. All objects added to this layer can see each other's
/// symbols.
class LegacyRTDyldObjectLinkingLayer : public LegacyRTDyldObjectLinkingLayerBase {
public:
using LegacyRTDyldObjectLinkingLayerBase::ObjectPtr;
/// Functor for receiving object-loaded notifications.
using NotifyLoadedFtor =
std::function<void(VModuleKey, const object::ObjectFile &Obj,
const RuntimeDyld::LoadedObjectInfo &)>;
/// Functor for receiving finalization notifications.
using NotifyFinalizedFtor =
std::function<void(VModuleKey, const object::ObjectFile &Obj,
const RuntimeDyld::LoadedObjectInfo &)>;
/// Functor for receiving deallocation notifications.
using NotifyFreedFtor = std::function<void(VModuleKey, const object::ObjectFile &Obj)>;
private:
using OwnedObject = object::OwningBinary<object::ObjectFile>;
template <typename MemoryManagerPtrT>
class ConcreteLinkedObject : public LinkedObject {
public:
ConcreteLinkedObject(LegacyRTDyldObjectLinkingLayer &Parent, VModuleKey K,
OwnedObject Obj, MemoryManagerPtrT MemMgr,
std::shared_ptr<SymbolResolver> Resolver,
bool ProcessAllSections)
: K(std::move(K)),
Parent(Parent),
MemMgr(std::move(MemMgr)),
PFC(llvm::make_unique<PreFinalizeContents>(
std::move(Obj), std::move(Resolver),
ProcessAllSections)) {
buildInitialSymbolTable(PFC->Obj);
}
~ConcreteLinkedObject() override {
if (this->Parent.NotifyFreed && ObjForNotify.getBinary())
this->Parent.NotifyFreed(K, *ObjForNotify.getBinary());
MemMgr->deregisterEHFrames();
}
Error finalize() override {
assert(PFC && "mapSectionAddress called on finalized LinkedObject");
JITSymbolResolverAdapter ResolverAdapter(Parent.ES, *PFC->Resolver,
nullptr);
PFC->RTDyld = llvm::make_unique<RuntimeDyld>(*MemMgr, ResolverAdapter);
PFC->RTDyld->setProcessAllSections(PFC->ProcessAllSections);
Finalized = true;
std::unique_ptr<RuntimeDyld::LoadedObjectInfo> Info =
PFC->RTDyld->loadObject(*PFC->Obj.getBinary());
// Copy the symbol table out of the RuntimeDyld instance.
{
auto SymTab = PFC->RTDyld->getSymbolTable();
for (auto &KV : SymTab)
SymbolTable[KV.first] = KV.second;
}
if (Parent.NotifyLoaded)
Parent.NotifyLoaded(K, *PFC->Obj.getBinary(), *Info);
PFC->RTDyld->finalizeWithMemoryManagerLocking();
if (PFC->RTDyld->hasError())
return make_error<StringError>(PFC->RTDyld->getErrorString(),
inconvertibleErrorCode());
if (Parent.NotifyFinalized)
Parent.NotifyFinalized(K, *PFC->Obj.getBinary(), *Info);
// Release resources.
if (this->Parent.NotifyFreed)
ObjForNotify = std::move(PFC->Obj); // needed for callback
PFC = nullptr;
return Error::success();
}
JITSymbol::GetAddressFtor getSymbolMaterializer(std::string Name) override {
return [this, Name]() -> Expected<JITTargetAddress> {
// The symbol may be materialized between the creation of this lambda
// and its execution, so we need to double check.
if (!this->Finalized)
if (auto Err = this->finalize())
return std::move(Err);
return this->getSymbol(Name, false).getAddress();
};
}
void mapSectionAddress(const void *LocalAddress,
JITTargetAddress TargetAddr) const override {
assert(PFC && "mapSectionAddress called on finalized LinkedObject");
assert(PFC->RTDyld && "mapSectionAddress called on raw LinkedObject");
PFC->RTDyld->mapSectionAddress(LocalAddress, TargetAddr);
}
private:
void buildInitialSymbolTable(const OwnedObject &Obj) {
for (auto &Symbol : Obj.getBinary()->symbols()) {
if (Symbol.getFlags() & object::SymbolRef::SF_Undefined)
continue;
Expected<StringRef> SymbolName = Symbol.getName();
// FIXME: Raise an error for bad symbols.
if (!SymbolName) {
consumeError(SymbolName.takeError());
continue;
}
// FIXME: Raise an error for bad symbols.
auto Flags = JITSymbolFlags::fromObjectSymbol(Symbol);
if (!Flags) {
consumeError(Flags.takeError());
continue;
}
SymbolTable.insert(
std::make_pair(*SymbolName, JITEvaluatedSymbol(0, *Flags)));
}
}
// Contains the information needed prior to finalization: the object files,
// memory manager, resolver, and flags needed for RuntimeDyld.
struct PreFinalizeContents {
PreFinalizeContents(OwnedObject Obj,
std::shared_ptr<SymbolResolver> Resolver,
bool ProcessAllSections)
: Obj(std::move(Obj)),
Resolver(std::move(Resolver)),
ProcessAllSections(ProcessAllSections) {}
OwnedObject Obj;
std::shared_ptr<SymbolResolver> Resolver;
bool ProcessAllSections;
std::unique_ptr<RuntimeDyld> RTDyld;
};
VModuleKey K;
LegacyRTDyldObjectLinkingLayer &Parent;
MemoryManagerPtrT MemMgr;
OwnedObject ObjForNotify;
std::unique_ptr<PreFinalizeContents> PFC;
};
template <typename MemoryManagerPtrT>
std::unique_ptr<ConcreteLinkedObject<MemoryManagerPtrT>>
createLinkedObject(LegacyRTDyldObjectLinkingLayer &Parent, VModuleKey K,
OwnedObject Obj, MemoryManagerPtrT MemMgr,
std::shared_ptr<SymbolResolver> Resolver,
bool ProcessAllSections) {
using LOS = ConcreteLinkedObject<MemoryManagerPtrT>;
return llvm::make_unique<LOS>(Parent, std::move(K), std::move(Obj),
std::move(MemMgr), std::move(Resolver),
ProcessAllSections);
}
public:
struct Resources {
std::shared_ptr<RuntimeDyld::MemoryManager> MemMgr;
std::shared_ptr<SymbolResolver> Resolver;
};
using ResourcesGetter = std::function<Resources(VModuleKey)>;
/// Construct an ObjectLinkingLayer with the given NotifyLoaded,
/// and NotifyFinalized functors.
LegacyRTDyldObjectLinkingLayer(
ExecutionSession &ES, ResourcesGetter GetResources,
NotifyLoadedFtor NotifyLoaded = NotifyLoadedFtor(),
NotifyFinalizedFtor NotifyFinalized = NotifyFinalizedFtor(),
NotifyFreedFtor NotifyFreed = NotifyFreedFtor())
: ES(ES), GetResources(std::move(GetResources)),
NotifyLoaded(std::move(NotifyLoaded)),
NotifyFinalized(std::move(NotifyFinalized)),
NotifyFreed(std::move(NotifyFreed)),
ProcessAllSections(false) {
}
/// Set the 'ProcessAllSections' flag.
///
/// If set to true, all sections in each object file will be allocated using
/// the memory manager, rather than just the sections required for execution.
///
/// This is kludgy, and may be removed in the future.
void setProcessAllSections(bool ProcessAllSections) {
this->ProcessAllSections = ProcessAllSections;
}
/// Add an object to the JIT.
Error addObject(VModuleKey K, ObjectPtr ObjBuffer) {
auto Obj =
object::ObjectFile::createObjectFile(ObjBuffer->getMemBufferRef());
if (!Obj)
return Obj.takeError();
assert(!LinkedObjects.count(K) && "VModuleKey already in use");
auto R = GetResources(K);
LinkedObjects[K] = createLinkedObject(
*this, K, OwnedObject(std::move(*Obj), std::move(ObjBuffer)),
std::move(R.MemMgr), std::move(R.Resolver), ProcessAllSections);
return Error::success();
}
/// Remove the object associated with VModuleKey K.
///
/// All memory allocated for the object will be freed, and the sections and
/// symbols it provided will no longer be available. No attempt is made to
/// re-emit the missing symbols, and any use of these symbols (directly or
/// indirectly) will result in undefined behavior. If dependence tracking is
/// required to detect or resolve such issues it should be added at a higher
/// layer.
Error removeObject(VModuleKey K) {
assert(LinkedObjects.count(K) && "VModuleKey not associated with object");
// How do we invalidate the symbols in H?
LinkedObjects.erase(K);
return Error::success();
}
/// Search for the given named symbol.
/// @param Name The name of the symbol to search for.
/// @param ExportedSymbolsOnly If true, search only for exported symbols.
/// @return A handle for the given named symbol, if it exists.
JITSymbol findSymbol(StringRef Name, bool ExportedSymbolsOnly) {
for (auto &KV : LinkedObjects)
if (auto Sym = KV.second->getSymbol(Name, ExportedSymbolsOnly))
return Sym;
else if (auto Err = Sym.takeError())
return std::move(Err);
return nullptr;
}
/// Search for the given named symbol in the context of the loaded
/// object represented by the VModuleKey K.
/// @param K The VModuleKey for the object to search in.
/// @param Name The name of the symbol to search for.
/// @param ExportedSymbolsOnly If true, search only for exported symbols.
/// @return A handle for the given named symbol, if it is found in the
/// given object.
JITSymbol findSymbolIn(VModuleKey K, StringRef Name,
bool ExportedSymbolsOnly) {
assert(LinkedObjects.count(K) && "VModuleKey not associated with object");
return LinkedObjects[K]->getSymbol(Name, ExportedSymbolsOnly);
}
/// Map section addresses for the object associated with the
/// VModuleKey K.
void mapSectionAddress(VModuleKey K, const void *LocalAddress,
JITTargetAddress TargetAddr) {
assert(LinkedObjects.count(K) && "VModuleKey not associated with object");
LinkedObjects[K]->mapSectionAddress(LocalAddress, TargetAddr);
}
/// Immediately emit and finalize the object represented by the given
/// VModuleKey.
/// @param K VModuleKey for object to emit/finalize.
Error emitAndFinalize(VModuleKey K) {
assert(LinkedObjects.count(K) && "VModuleKey not associated with object");
return LinkedObjects[K]->finalize();
}
private:
ExecutionSession &ES;
std::map<VModuleKey, std::unique_ptr<LinkedObject>> LinkedObjects;
ResourcesGetter GetResources;
NotifyLoadedFtor NotifyLoaded;
NotifyFinalizedFtor NotifyFinalized;
NotifyFreedFtor NotifyFreed;
bool ProcessAllSections = false;
};
} // end namespace orc
} // end namespace llvm
#endif // LLVM_EXECUTIONENGINE_ORC_RTDYLDOBJECTLINKINGLAYER_H