//===---- ExecutionUtils.cpp - Utilities for executing functions in Orc ---===//
//
// 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/ExecutionUtils.h"
#include "llvm/ExecutionEngine/JITLink/x86_64.h"
#include "llvm/ExecutionEngine/Orc/Layer.h"
#include "llvm/ExecutionEngine/Orc/ObjectFileInterface.h"
#include "llvm/IR/Constants.h"
#include "llvm/IR/Function.h"
#include "llvm/IR/GlobalVariable.h"
#include "llvm/IR/Module.h"
#include "llvm/MC/TargetRegistry.h"
#include "llvm/Object/MachOUniversal.h"
#include "llvm/Support/FormatVariadic.h"
#include "llvm/Support/StringSaver.h"
#include "llvm/Target/TargetMachine.h"
#include <string>
namespace llvm {
namespace orc {
CtorDtorIterator::CtorDtorIterator(const GlobalVariable *GV, bool End)
: InitList(
GV ? dyn_cast_or_null<ConstantArray>(GV->getInitializer()) : nullptr),
I((InitList && End) ? InitList->getNumOperands() : 0) {
}
bool CtorDtorIterator::operator==(const CtorDtorIterator &Other) const {
assert(InitList == Other.InitList && "Incomparable iterators.");
return I == Other.I;
}
bool CtorDtorIterator::operator!=(const CtorDtorIterator &Other) const {
return !(*this == Other);
}
CtorDtorIterator& CtorDtorIterator::operator++() {
++I;
return *this;
}
CtorDtorIterator CtorDtorIterator::operator++(int) {
CtorDtorIterator Temp = *this;
++I;
return Temp;
}
CtorDtorIterator::Element CtorDtorIterator::operator*() const {
ConstantStruct *CS = dyn_cast<ConstantStruct>(InitList->getOperand(I));
assert(CS && "Unrecognized type in llvm.global_ctors/llvm.global_dtors");
Constant *FuncC = CS->getOperand(1);
Function *Func = nullptr;
// Extract function pointer, pulling off any casts.
while (FuncC) {
if (Function *F = dyn_cast_or_null<Function>(FuncC)) {
Func = F;
break;
} else if (ConstantExpr *CE = dyn_cast_or_null<ConstantExpr>(FuncC)) {
if (CE->isCast())
FuncC = CE->getOperand(0);
else
break;
} else {
// This isn't anything we recognize. Bail out with Func left set to null.
break;
}
}
auto *Priority = cast<ConstantInt>(CS->getOperand(0));
Value *Data = CS->getNumOperands() == 3 ? CS->getOperand(2) : nullptr;
if (Data && !isa<GlobalValue>(Data))
Data = nullptr;
return Element(Priority->getZExtValue(), Func, Data);
}
iterator_range<CtorDtorIterator> getConstructors(const Module &M) {
const GlobalVariable *CtorsList = M.getNamedGlobal("llvm.global_ctors");
return make_range(CtorDtorIterator(CtorsList, false),
CtorDtorIterator(CtorsList, true));
}
iterator_range<CtorDtorIterator> getDestructors(const Module &M) {
const GlobalVariable *DtorsList = M.getNamedGlobal("llvm.global_dtors");
return make_range(CtorDtorIterator(DtorsList, false),
CtorDtorIterator(DtorsList, true));
}
bool StaticInitGVIterator::isStaticInitGlobal(GlobalValue &GV) {
if (GV.isDeclaration())
return false;
if (GV.hasName() && (GV.getName() == "llvm.global_ctors" ||
GV.getName() == "llvm.global_dtors"))
return true;
if (ObjFmt == Triple::MachO) {
// FIXME: These section checks are too strict: We should match first and
// second word split by comma.
if (GV.hasSection() &&
(GV.getSection().starts_with("__DATA,__objc_classlist") ||
GV.getSection().starts_with("__DATA,__objc_selrefs")))
return true;
}
return false;
}
void CtorDtorRunner::add(iterator_range<CtorDtorIterator> CtorDtors) {
if (CtorDtors.empty())
return;
MangleAndInterner Mangle(
JD.getExecutionSession(),
(*CtorDtors.begin()).Func->getDataLayout());
for (auto CtorDtor : CtorDtors) {
assert(CtorDtor.Func && CtorDtor.Func->hasName() &&
"Ctor/Dtor function must be named to be runnable under the JIT");
// FIXME: Maybe use a symbol promoter here instead.
if (CtorDtor.Func->hasLocalLinkage()) {
CtorDtor.Func->setLinkage(GlobalValue::ExternalLinkage);
CtorDtor.Func->setVisibility(GlobalValue::HiddenVisibility);
}
if (CtorDtor.Data && cast<GlobalValue>(CtorDtor.Data)->isDeclaration()) {
dbgs() << " Skipping because why now?\n";
continue;
}
CtorDtorsByPriority[CtorDtor.Priority].push_back(
Mangle(CtorDtor.Func->getName()));
}
}
Error CtorDtorRunner::run() {
using CtorDtorTy = void (*)();
SymbolLookupSet LookupSet;
for (auto &KV : CtorDtorsByPriority)
for (auto &Name : KV.second)
LookupSet.add(Name);
assert(!LookupSet.containsDuplicates() &&
"Ctor/Dtor list contains duplicates");
auto &ES = JD.getExecutionSession();
if (auto CtorDtorMap = ES.lookup(
makeJITDylibSearchOrder(&JD, JITDylibLookupFlags::MatchAllSymbols),
std::move(LookupSet))) {
for (auto &KV : CtorDtorsByPriority) {
for (auto &Name : KV.second) {
assert(CtorDtorMap->count(Name) && "No entry for Name");
auto CtorDtor = (*CtorDtorMap)[Name].getAddress().toPtr<CtorDtorTy>();
CtorDtor();
}
}
CtorDtorsByPriority.clear();
return Error::success();
} else
return CtorDtorMap.takeError();
}
void LocalCXXRuntimeOverridesBase::runDestructors() {
auto& CXXDestructorDataPairs = DSOHandleOverride;
for (auto &P : CXXDestructorDataPairs)
P.first(P.second);
CXXDestructorDataPairs.clear();
}
int LocalCXXRuntimeOverridesBase::CXAAtExitOverride(DestructorPtr Destructor,
void *Arg,
void *DSOHandle) {
auto& CXXDestructorDataPairs =
*reinterpret_cast<CXXDestructorDataPairList*>(DSOHandle);
CXXDestructorDataPairs.push_back(std::make_pair(Destructor, Arg));
return 0;
}
Error LocalCXXRuntimeOverrides::enable(JITDylib &JD,
MangleAndInterner &Mangle) {
SymbolMap RuntimeInterposes;
RuntimeInterposes[Mangle("__dso_handle")] = {
ExecutorAddr::fromPtr(&DSOHandleOverride), JITSymbolFlags::Exported};
RuntimeInterposes[Mangle("__cxa_atexit")] = {
ExecutorAddr::fromPtr(&CXAAtExitOverride), JITSymbolFlags::Exported};
return JD.define(absoluteSymbols(std::move(RuntimeInterposes)));
}
void ItaniumCXAAtExitSupport::registerAtExit(void (*F)(void *), void *Ctx,
void *DSOHandle) {
std::lock_guard<std::mutex> Lock(AtExitsMutex);
AtExitRecords[DSOHandle].push_back({F, Ctx});
}
void ItaniumCXAAtExitSupport::runAtExits(void *DSOHandle) {
std::vector<AtExitRecord> AtExitsToRun;
{
std::lock_guard<std::mutex> Lock(AtExitsMutex);
auto I = AtExitRecords.find(DSOHandle);
if (I != AtExitRecords.end()) {
AtExitsToRun = std::move(I->second);
AtExitRecords.erase(I);
}
}
while (!AtExitsToRun.empty()) {
AtExitsToRun.back().F(AtExitsToRun.back().Ctx);
AtExitsToRun.pop_back();
}
}
DynamicLibrarySearchGenerator::DynamicLibrarySearchGenerator(
sys::DynamicLibrary Dylib, char GlobalPrefix, SymbolPredicate Allow,
AddAbsoluteSymbolsFn AddAbsoluteSymbols)
: Dylib(std::move(Dylib)), Allow(std::move(Allow)),
AddAbsoluteSymbols(std::move(AddAbsoluteSymbols)),
GlobalPrefix(GlobalPrefix) {}
Expected<std::unique_ptr<DynamicLibrarySearchGenerator>>
DynamicLibrarySearchGenerator::Load(const char *FileName, char GlobalPrefix,
SymbolPredicate Allow,
AddAbsoluteSymbolsFn AddAbsoluteSymbols) {
std::string ErrMsg;
auto Lib = sys::DynamicLibrary::getPermanentLibrary(FileName, &ErrMsg);
if (!Lib.isValid())
return make_error<StringError>(std::move(ErrMsg), inconvertibleErrorCode());
return std::make_unique<DynamicLibrarySearchGenerator>(
std::move(Lib), GlobalPrefix, std::move(Allow),
std::move(AddAbsoluteSymbols));
}
Error DynamicLibrarySearchGenerator::tryToGenerate(
LookupState &LS, LookupKind K, JITDylib &JD,
JITDylibLookupFlags JDLookupFlags, const SymbolLookupSet &Symbols) {
orc::SymbolMap NewSymbols;
bool HasGlobalPrefix = (GlobalPrefix != '\0');
for (auto &KV : Symbols) {
auto &Name = KV.first;
if ((*Name).empty())
continue;
if (Allow && !Allow(Name))
continue;
if (HasGlobalPrefix && (*Name).front() != GlobalPrefix)
continue;
std::string Tmp((*Name).data() + HasGlobalPrefix,
(*Name).size() - HasGlobalPrefix);
if (void *P = Dylib.getAddressOfSymbol(Tmp.c_str()))
NewSymbols[Name] = {ExecutorAddr::fromPtr(P), JITSymbolFlags::Exported};
}
if (NewSymbols.empty())
return Error::success();
if (AddAbsoluteSymbols)
return AddAbsoluteSymbols(JD, std::move(NewSymbols));
return JD.define(absoluteSymbols(std::move(NewSymbols)));
}
Expected<std::unique_ptr<StaticLibraryDefinitionGenerator>>
StaticLibraryDefinitionGenerator::Load(
ObjectLayer &L, const char *FileName,
GetObjectFileInterface GetObjFileInterface) {
auto B = object::createBinary(FileName);
if (!B)
return createFileError(FileName, B.takeError());
// If this is a regular archive then create an instance from it.
if (isa<object::Archive>(B->getBinary())) {
auto [Archive, ArchiveBuffer] = B->takeBinary();
return Create(L, std::move(ArchiveBuffer),
std::unique_ptr<object::Archive>(
static_cast<object::Archive *>(Archive.release())),
std::move(GetObjFileInterface));
}
// If this is a universal binary then search for a slice matching the given
// Triple.
if (auto *UB = dyn_cast<object::MachOUniversalBinary>(B->getBinary())) {
const auto &TT = L.getExecutionSession().getTargetTriple();
auto SliceRange = getSliceRangeForArch(*UB, TT);
if (!SliceRange)
return SliceRange.takeError();
auto SliceBuffer = MemoryBuffer::getFileSlice(FileName, SliceRange->second,
SliceRange->first);
if (!SliceBuffer)
return make_error<StringError>(
Twine("Could not create buffer for ") + TT.str() + " slice of " +
FileName + ": [ " + formatv("{0:x}", SliceRange->first) + " .. " +
formatv("{0:x}", SliceRange->first + SliceRange->second) + ": " +
SliceBuffer.getError().message(),
SliceBuffer.getError());
return Create(L, std::move(*SliceBuffer), std::move(GetObjFileInterface));
}
return make_error<StringError>(Twine("Unrecognized file type for ") +
FileName,
inconvertibleErrorCode());
}
Expected<std::unique_ptr<StaticLibraryDefinitionGenerator>>
StaticLibraryDefinitionGenerator::Create(
ObjectLayer &L, std::unique_ptr<MemoryBuffer> ArchiveBuffer,
std::unique_ptr<object::Archive> Archive,
GetObjectFileInterface GetObjFileInterface) {
Error Err = Error::success();
std::unique_ptr<StaticLibraryDefinitionGenerator> ADG(
new StaticLibraryDefinitionGenerator(
L, std::move(ArchiveBuffer), std::move(Archive),
std::move(GetObjFileInterface), Err));
if (Err)
return std::move(Err);
return std::move(ADG);
}
Expected<std::unique_ptr<StaticLibraryDefinitionGenerator>>
StaticLibraryDefinitionGenerator::Create(
ObjectLayer &L, std::unique_ptr<MemoryBuffer> ArchiveBuffer,
GetObjectFileInterface GetObjFileInterface) {
auto B = object::createBinary(ArchiveBuffer->getMemBufferRef());
if (!B)
return B.takeError();
// If this is a regular archive then create an instance from it.
if (isa<object::Archive>(*B))
return Create(L, std::move(ArchiveBuffer),
std::unique_ptr<object::Archive>(
static_cast<object::Archive *>(B->release())),
std::move(GetObjFileInterface));
// If this is a universal binary then search for a slice matching the given
// Triple.
if (auto *UB = dyn_cast<object::MachOUniversalBinary>(B->get())) {
const auto &TT = L.getExecutionSession().getTargetTriple();
auto SliceRange = getSliceRangeForArch(*UB, TT);
if (!SliceRange)
return SliceRange.takeError();
MemoryBufferRef SliceRef(
StringRef(ArchiveBuffer->getBufferStart() + SliceRange->first,
SliceRange->second),
ArchiveBuffer->getBufferIdentifier());
auto Archive = object::Archive::create(SliceRef);
if (!Archive)
return Archive.takeError();
return Create(L, std::move(ArchiveBuffer), std::move(*Archive),
std::move(GetObjFileInterface));
}
return make_error<StringError>(Twine("Unrecognized file type for ") +
ArchiveBuffer->getBufferIdentifier(),
inconvertibleErrorCode());
}
Error StaticLibraryDefinitionGenerator::tryToGenerate(
LookupState &LS, LookupKind K, JITDylib &JD,
JITDylibLookupFlags JDLookupFlags, const SymbolLookupSet &Symbols) {
// Don't materialize symbols from static archives unless this is a static
// lookup.
if (K != LookupKind::Static)
return Error::success();
// Bail out early if we've already freed the archive.
if (!Archive)
return Error::success();
DenseSet<std::pair<StringRef, StringRef>> ChildBufferInfos;
for (const auto &KV : Symbols) {
const auto &Name = KV.first;
if (!ObjectFilesMap.count(Name))
continue;
auto ChildBuffer = ObjectFilesMap[Name];
ChildBufferInfos.insert(
{ChildBuffer.getBuffer(), ChildBuffer.getBufferIdentifier()});
}
for (auto ChildBufferInfo : ChildBufferInfos) {
MemoryBufferRef ChildBufferRef(ChildBufferInfo.first,
ChildBufferInfo.second);
auto I = GetObjFileInterface(L.getExecutionSession(), ChildBufferRef);
if (!I)
return I.takeError();
if (auto Err = L.add(JD, MemoryBuffer::getMemBuffer(ChildBufferRef, false),
std::move(*I)))
return Err;
}
return Error::success();
}
Error StaticLibraryDefinitionGenerator::buildObjectFilesMap() {
DenseMap<uint64_t, MemoryBufferRef> MemoryBuffers;
DenseSet<uint64_t> Visited;
DenseSet<uint64_t> Excluded;
StringSaver FileNames(ObjFileNameStorage);
for (auto &S : Archive->symbols()) {
StringRef SymName = S.getName();
auto Member = S.getMember();
if (!Member)
return Member.takeError();
auto DataOffset = Member->getDataOffset();
if (!Visited.count(DataOffset)) {
Visited.insert(DataOffset);
auto Child = Member->getAsBinary();
if (!Child)
return Child.takeError();
if ((*Child)->isCOFFImportFile()) {
ImportedDynamicLibraries.insert((*Child)->getFileName().str());
Excluded.insert(DataOffset);
continue;
}
// Give members of the archive a name that contains the archive path so
// that they can be differentiated from a member with the same name in a
// different archive. This also ensure initializer symbols names will be
// unique within a JITDylib.
StringRef FullName = FileNames.save(Archive->getFileName() + "(" +
(*Child)->getFileName() + ")");
MemoryBufferRef MemBuffer((*Child)->getMemoryBufferRef().getBuffer(),
FullName);
MemoryBuffers[DataOffset] = MemBuffer;
}
if (!Excluded.count(DataOffset))
ObjectFilesMap[L.getExecutionSession().intern(SymName)] =
MemoryBuffers[DataOffset];
}
return Error::success();
}
Expected<std::pair<size_t, size_t>>
StaticLibraryDefinitionGenerator::getSliceRangeForArch(
object::MachOUniversalBinary &UB, const Triple &TT) {
for (const auto &Obj : UB.objects()) {
auto ObjTT = Obj.getTriple();
if (ObjTT.getArch() == TT.getArch() &&
ObjTT.getSubArch() == TT.getSubArch() &&
(TT.getVendor() == Triple::UnknownVendor ||
ObjTT.getVendor() == TT.getVendor())) {
// We found a match. Return the range for the slice.
return std::make_pair(Obj.getOffset(), Obj.getSize());
}
}
return make_error<StringError>(Twine("Universal binary ") + UB.getFileName() +
" does not contain a slice for " +
TT.str(),
inconvertibleErrorCode());
}
StaticLibraryDefinitionGenerator::StaticLibraryDefinitionGenerator(
ObjectLayer &L, std::unique_ptr<MemoryBuffer> ArchiveBuffer,
std::unique_ptr<object::Archive> Archive,
GetObjectFileInterface GetObjFileInterface, Error &Err)
: L(L), GetObjFileInterface(std::move(GetObjFileInterface)),
ArchiveBuffer(std::move(ArchiveBuffer)), Archive(std::move(Archive)) {
ErrorAsOutParameter _(&Err);
if (!this->GetObjFileInterface)
this->GetObjFileInterface = getObjectFileInterface;
if (!Err)
Err = buildObjectFilesMap();
}
std::unique_ptr<DLLImportDefinitionGenerator>
DLLImportDefinitionGenerator::Create(ExecutionSession &ES,
ObjectLinkingLayer &L) {
return std::unique_ptr<DLLImportDefinitionGenerator>(
new DLLImportDefinitionGenerator(ES, L));
}
Error DLLImportDefinitionGenerator::tryToGenerate(
LookupState &LS, LookupKind K, JITDylib &JD,
JITDylibLookupFlags JDLookupFlags, const SymbolLookupSet &Symbols) {
JITDylibSearchOrder LinkOrder;
JD.withLinkOrderDo([&](const JITDylibSearchOrder &LO) {
LinkOrder.reserve(LO.size());
for (auto &KV : LO) {
if (KV.first == &JD)
continue;
LinkOrder.push_back(KV);
}
});
// FIXME: if regular symbol name start with __imp_ we have to issue lookup of
// both __imp_ and stripped name and use the lookup information to resolve the
// real symbol name.
SymbolLookupSet LookupSet;
DenseMap<StringRef, SymbolLookupFlags> ToLookUpSymbols;
for (auto &KV : Symbols) {
StringRef Deinterned = *KV.first;
if (Deinterned.starts_with(getImpPrefix()))
Deinterned = Deinterned.drop_front(StringRef(getImpPrefix()).size());
// Don't degrade the required state
if (ToLookUpSymbols.count(Deinterned) &&
ToLookUpSymbols[Deinterned] == SymbolLookupFlags::RequiredSymbol)
continue;
ToLookUpSymbols[Deinterned] = KV.second;
}
for (auto &KV : ToLookUpSymbols)
LookupSet.add(ES.intern(KV.first), KV.second);
auto Resolved =
ES.lookup(LinkOrder, LookupSet, LookupKind::DLSym, SymbolState::Resolved);
if (!Resolved)
return Resolved.takeError();
auto G = createStubsGraph(*Resolved);
if (!G)
return G.takeError();
return L.add(JD, std::move(*G));
}
Expected<unsigned>
DLLImportDefinitionGenerator::getTargetPointerSize(const Triple &TT) {
switch (TT.getArch()) {
case Triple::x86_64:
return 8;
default:
return make_error<StringError>(
"architecture unsupported by DLLImportDefinitionGenerator",
inconvertibleErrorCode());
}
}
Expected<llvm::endianness>
DLLImportDefinitionGenerator::getEndianness(const Triple &TT) {
switch (TT.getArch()) {
case Triple::x86_64:
return llvm::endianness::little;
default:
return make_error<StringError>(
"architecture unsupported by DLLImportDefinitionGenerator",
inconvertibleErrorCode());
}
}
Expected<std::unique_ptr<jitlink::LinkGraph>>
DLLImportDefinitionGenerator::createStubsGraph(const SymbolMap &Resolved) {
Triple TT = ES.getTargetTriple();
auto PointerSize = getTargetPointerSize(TT);
if (!PointerSize)
return PointerSize.takeError();
auto Endianness = getEndianness(TT);
if (!Endianness)
return Endianness.takeError();
auto G = std::make_unique<jitlink::LinkGraph>(
"<DLLIMPORT_STUBS>", TT, *PointerSize, *Endianness,
jitlink::getGenericEdgeKindName);
jitlink::Section &Sec =
G->createSection(getSectionName(), MemProt::Read | MemProt::Exec);
for (auto &KV : Resolved) {
jitlink::Symbol &Target = G->addAbsoluteSymbol(
*KV.first, KV.second.getAddress(), *PointerSize,
jitlink::Linkage::Strong, jitlink::Scope::Local, false);
// Create __imp_ symbol
jitlink::Symbol &Ptr =
jitlink::x86_64::createAnonymousPointer(*G, Sec, &Target);
auto NameCopy = G->allocateContent(Twine(getImpPrefix()) + *KV.first);
StringRef NameCopyRef = StringRef(NameCopy.data(), NameCopy.size());
Ptr.setName(NameCopyRef);
Ptr.setLinkage(jitlink::Linkage::Strong);
Ptr.setScope(jitlink::Scope::Default);
// Create PLT stub
// FIXME: check PLT stub of data symbol is not accessed
jitlink::Block &StubBlock =
jitlink::x86_64::createPointerJumpStubBlock(*G, Sec, Ptr);
G->addDefinedSymbol(StubBlock, 0, *KV.first, StubBlock.getSize(),
jitlink::Linkage::Strong, jitlink::Scope::Default, true,
false);
}
return std::move(G);
}
} // End namespace orc.
} // End namespace llvm.