llvm/lib/ExecutionEngine/Orc/DebugObjectManagerPlugin.cpp - llvm-project - Git at Google

 //===------- DebugObjectManagerPlugin.cpp - JITLink debug objects ---------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // FIXME: Update Plugin to poke the debug object into a new JITLink section,
 //        rather than creating a new allocation.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/ExecutionEngine/Orc/DebugObjectManagerPlugin.h"

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/StringMap.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/BinaryFormat/ELF.h"
 #include "llvm/ExecutionEngine/JITLink/JITLinkDylib.h"
 #include "llvm/ExecutionEngine/JITLink/JITLinkMemoryManager.h"
 #include "llvm/ExecutionEngine/JITSymbol.h"
 #include "llvm/Object/ELFObjectFile.h"
 #include "llvm/Object/ObjectFile.h"
 #include "llvm/Support/Errc.h"
 #include "llvm/Support/MSVCErrorWorkarounds.h"
 #include "llvm/Support/MemoryBuffer.h"
 #include "llvm/Support/Process.h"
 #include "llvm/Support/raw_ostream.h"

 #include <set>

 #define DEBUG_TYPE "orc"

 using namespace llvm::jitlink;
 using namespace llvm::object;

 namespace llvm {
 namespace orc {

 class DebugObjectSection {
 public:
   virtual void setTargetMemoryRange(SectionRange Range) = 0;
   virtual void dump(raw_ostream &OS, StringRef Name) {}
   virtual ~DebugObjectSection() {}
 };

 template <typename ELFT>
 class ELFDebugObjectSection : public DebugObjectSection {
 public:
   // BinaryFormat ELF is not meant as a mutable format. We can only make changes
   // that don't invalidate the file structure.
   ELFDebugObjectSection(const typename ELFT::Shdr *Header)
       : Header(const_cast<typename ELFT::Shdr *>(Header)) {}

   void setTargetMemoryRange(SectionRange Range) override;
   void dump(raw_ostream &OS, StringRef Name) override;

   Error validateInBounds(StringRef Buffer, const char *Name) const;

 private:
   typename ELFT::Shdr *Header;

   bool isTextOrDataSection() const;
 };

 template <typename ELFT>
 void ELFDebugObjectSection<ELFT>::setTargetMemoryRange(SectionRange Range) {
   // Only patch load-addresses for executable and data sections.
   if (isTextOrDataSection()) {
     Header->sh_addr = static_cast<typename ELFT::uint>(Range.getStart());
   }
 }

 template <typename ELFT>
 bool ELFDebugObjectSection<ELFT>::isTextOrDataSection() const {
   switch (Header->sh_type) {
   case ELF::SHT_PROGBITS:
   case ELF::SHT_X86_64_UNWIND:
     return Header->sh_flags & (ELF::SHF_EXECINSTR | ELF::SHF_ALLOC);
   }
   return false;
 }

 template <typename ELFT>
 Error ELFDebugObjectSection<ELFT>::validateInBounds(StringRef Buffer,
                                                     const char *Name) const {
   const uint8_t *Start = Buffer.bytes_begin();
   const uint8_t *End = Buffer.bytes_end();
   const uint8_t *HeaderPtr = reinterpret_cast<uint8_t *>(Header);
   if (HeaderPtr < Start || HeaderPtr + sizeof(typename ELFT::Shdr) > End)
     return make_error<StringError>(
         formatv("{0} section header at {1:x16} not within bounds of the "
                 "given debug object buffer [{2:x16} - {3:x16}]",
                 Name, &Header->sh_addr, Start, End),
         inconvertibleErrorCode());
   if (Header->sh_offset + Header->sh_size > Buffer.size())
     return make_error<StringError>(
         formatv("{0} section data [{1:x16} - {2:x16}] not within bounds of "
                 "the given debug object buffer [{3:x16} - {4:x16}]",
                 Name, Start + Header->sh_offset,
                 Start + Header->sh_offset + Header->sh_size, Start, End),
         inconvertibleErrorCode());
   return Error::success();
 }

 template <typename ELFT>
 void ELFDebugObjectSection<ELFT>::dump(raw_ostream &OS, StringRef Name) {
   if (auto Addr = static_cast<JITTargetAddress>(Header->sh_addr)) {
     OS << formatv("  {0:x16} {1}\n", Addr, Name);
   } else {
     OS << formatv("                     {0}\n", Name);
   }
 }

 enum class Requirement {
   // Request final target memory load-addresses for all sections.
   ReportFinalSectionLoadAddresses,
 };

 /// The plugin creates a debug object from when JITLink starts processing the
 /// corresponding LinkGraph. It provides access to the pass configuration of
 /// the LinkGraph and calls the finalization function, once the resulting link
 /// artifact was emitted.
 ///
 class DebugObject {
 public:
   DebugObject(JITLinkMemoryManager &MemMgr, const JITLinkDylib *JD,
               ExecutionSession &ES)
       : MemMgr(MemMgr), JD(JD), ES(ES) {}

   void set(Requirement Req) { Reqs.insert(Req); }
   bool has(Requirement Req) const { return Reqs.count(Req) > 0; }

   using FinalizeContinuation = std::function<void(Expected<ExecutorAddrRange>)>;

   void finalizeAsync(FinalizeContinuation OnFinalize);

   virtual ~DebugObject() {
     if (Alloc) {
       std::vector<FinalizedAlloc> Allocs;
       Allocs.push_back(std::move(Alloc));
       if (Error Err = MemMgr.deallocate(std::move(Allocs)))
         ES.reportError(std::move(Err));
     }
   }

   virtual void reportSectionTargetMemoryRange(StringRef Name,
                                               SectionRange TargetMem) {}

 protected:
   using InFlightAlloc = JITLinkMemoryManager::InFlightAlloc;
   using FinalizedAlloc = JITLinkMemoryManager::FinalizedAlloc;

   virtual Expected<SimpleSegmentAlloc> finalizeWorkingMemory() = 0;

   JITLinkMemoryManager &MemMgr;
   const JITLinkDylib *JD = nullptr;

 private:
   ExecutionSession &ES;
   std::set<Requirement> Reqs;
   FinalizedAlloc Alloc;
 };

 // Finalize working memory and take ownership of the resulting allocation. Start
 // copying memory over to the target and pass on the result once we're done.
 // Ownership of the allocation remains with us for the rest of our lifetime.
 void DebugObject::finalizeAsync(FinalizeContinuation OnFinalize) {
   assert(!Alloc && "Cannot finalize more than once");

   if (auto SimpleSegAlloc = finalizeWorkingMemory()) {
     auto ROSeg = SimpleSegAlloc->getSegInfo(MemProt::Read);
     ExecutorAddrRange DebugObjRange(ExecutorAddr(ROSeg.Addr),
                                     ExecutorAddrDiff(ROSeg.WorkingMem.size()));
     SimpleSegAlloc->finalize(
         [this, DebugObjRange,
          OnFinalize = std::move(OnFinalize)](Expected<FinalizedAlloc> FA) {
           if (FA) {
             Alloc = std::move(*FA);
             OnFinalize(DebugObjRange);
           } else
             OnFinalize(FA.takeError());
         });
   } else
     OnFinalize(SimpleSegAlloc.takeError());
 }

 /// The current implementation of ELFDebugObject replicates the approach used in
 /// RuntimeDyld: It patches executable and data section headers in the given
 /// object buffer with load-addresses of their corresponding sections in target
 /// memory.
 ///
 class ELFDebugObject : public DebugObject {
 public:
   static Expected<std::unique_ptr<DebugObject>>
   Create(MemoryBufferRef Buffer, JITLinkContext &Ctx, ExecutionSession &ES);

   void reportSectionTargetMemoryRange(StringRef Name,
                                       SectionRange TargetMem) override;

   StringRef getBuffer() const { return Buffer->getMemBufferRef().getBuffer(); }

 protected:
   Expected<SimpleSegmentAlloc> finalizeWorkingMemory() override;

   template <typename ELFT>
   Error recordSection(StringRef Name,
                       std::unique_ptr<ELFDebugObjectSection<ELFT>> Section);
   DebugObjectSection *getSection(StringRef Name);

 private:
   template <typename ELFT>
   static Expected<std::unique_ptr<ELFDebugObject>>
   CreateArchType(MemoryBufferRef Buffer, JITLinkMemoryManager &MemMgr,
                  const JITLinkDylib *JD, ExecutionSession &ES);

   static std::unique_ptr<WritableMemoryBuffer>
   CopyBuffer(MemoryBufferRef Buffer, Error &Err);

   ELFDebugObject(std::unique_ptr<WritableMemoryBuffer> Buffer,
                  JITLinkMemoryManager &MemMgr, const JITLinkDylib *JD,
                  ExecutionSession &ES)
       : DebugObject(MemMgr, JD, ES), Buffer(std::move(Buffer)) {
     set(Requirement::ReportFinalSectionLoadAddresses);
   }

   std::unique_ptr<WritableMemoryBuffer> Buffer;
   StringMap<std::unique_ptr<DebugObjectSection>> Sections;
 };

 static const std::set<StringRef> DwarfSectionNames = {
 #define HANDLE_DWARF_SECTION(ENUM_NAME, ELF_NAME, CMDLINE_NAME, OPTION)        \
   ELF_NAME,
 #include "llvm/BinaryFormat/Dwarf.def"
 #undef HANDLE_DWARF_SECTION
 };

 static bool isDwarfSection(StringRef SectionName) {
   return DwarfSectionNames.count(SectionName) == 1;
 }

 std::unique_ptr<WritableMemoryBuffer>
 ELFDebugObject::CopyBuffer(MemoryBufferRef Buffer, Error &Err) {
   ErrorAsOutParameter _(&Err);
   size_t Size = Buffer.getBufferSize();
   StringRef Name = Buffer.getBufferIdentifier();
   if (auto Copy = WritableMemoryBuffer::getNewUninitMemBuffer(Size, Name)) {
     memcpy(Copy->getBufferStart(), Buffer.getBufferStart(), Size);
     return Copy;
   }

   Err = errorCodeToError(make_error_code(errc::not_enough_memory));
   return nullptr;
 }

 template <typename ELFT>
 Expected<std::unique_ptr<ELFDebugObject>>
 ELFDebugObject::CreateArchType(MemoryBufferRef Buffer,
                                JITLinkMemoryManager &MemMgr,
                                const JITLinkDylib *JD, ExecutionSession &ES) {
   using SectionHeader = typename ELFT::Shdr;

   Error Err = Error::success();
   std::unique_ptr<ELFDebugObject> DebugObj(
       new ELFDebugObject(CopyBuffer(Buffer, Err), MemMgr, JD, ES));
   if (Err)
     return std::move(Err);

   Expected<ELFFile<ELFT>> ObjRef = ELFFile<ELFT>::create(DebugObj->getBuffer());
   if (!ObjRef)
     return ObjRef.takeError();

   // TODO: Add support for other architectures.
   uint16_t TargetMachineArch = ObjRef->getHeader().e_machine;
   if (TargetMachineArch != ELF::EM_X86_64)
     return nullptr;

   Expected<ArrayRef<SectionHeader>> Sections = ObjRef->sections();
   if (!Sections)
     return Sections.takeError();

   bool HasDwarfSection = false;
   for (const SectionHeader &Header : *Sections) {
     Expected<StringRef> Name = ObjRef->getSectionName(Header);
     if (!Name)
       return Name.takeError();
     if (Name->empty())
       continue;
     HasDwarfSection |= isDwarfSection(*Name);

     auto Wrapped = std::make_unique<ELFDebugObjectSection<ELFT>>(&Header);
     if (Error Err = DebugObj->recordSection(*Name, std::move(Wrapped)))
       return std::move(Err);
   }

   if (!HasDwarfSection) {
     LLVM_DEBUG(dbgs() << "Aborting debug registration for LinkGraph \""
                       << DebugObj->Buffer->getBufferIdentifier()
                       << "\": input object contains no debug info\n");
     return nullptr;
   }

   return std::move(DebugObj);
 }

 Expected<std::unique_ptr<DebugObject>>
 ELFDebugObject::Create(MemoryBufferRef Buffer, JITLinkContext &Ctx,
                        ExecutionSession &ES) {
   unsigned char Class, Endian;
   std::tie(Class, Endian) = getElfArchType(Buffer.getBuffer());

   if (Class == ELF::ELFCLASS32) {
     if (Endian == ELF::ELFDATA2LSB)
       return CreateArchType<ELF32LE>(Buffer, Ctx.getMemoryManager(),
                                      Ctx.getJITLinkDylib(), ES);
     if (Endian == ELF::ELFDATA2MSB)
       return CreateArchType<ELF32BE>(Buffer, Ctx.getMemoryManager(),
                                      Ctx.getJITLinkDylib(), ES);
     return nullptr;
   }
   if (Class == ELF::ELFCLASS64) {
     if (Endian == ELF::ELFDATA2LSB)
       return CreateArchType<ELF64LE>(Buffer, Ctx.getMemoryManager(),
                                      Ctx.getJITLinkDylib(), ES);
     if (Endian == ELF::ELFDATA2MSB)
       return CreateArchType<ELF64BE>(Buffer, Ctx.getMemoryManager(),
                                      Ctx.getJITLinkDylib(), ES);
     return nullptr;
   }
   return nullptr;
 }

 Expected<SimpleSegmentAlloc> ELFDebugObject::finalizeWorkingMemory() {
   LLVM_DEBUG({
     dbgs() << "Section load-addresses in debug object for \""
            << Buffer->getBufferIdentifier() << "\":\n";
     for (const auto &KV : Sections)
       KV.second->dump(dbgs(), KV.first());
   });

   // TODO: This works, but what actual alignment requirements do we have?
   unsigned PageSize = sys::Process::getPageSizeEstimate();
   size_t Size = Buffer->getBufferSize();

   // Allocate working memory for debug object in read-only segment.
   auto Alloc = SimpleSegmentAlloc::Create(
       MemMgr, JD, {{MemProt::Read, {Size, Align(PageSize)}}});
   if (!Alloc)
     return Alloc;

   // Initialize working memory with a copy of our object buffer.
   auto SegInfo = Alloc->getSegInfo(MemProt::Read);
   memcpy(SegInfo.WorkingMem.data(), Buffer->getBufferStart(), Size);
   Buffer.reset();

   return Alloc;
 }

 void ELFDebugObject::reportSectionTargetMemoryRange(StringRef Name,
                                                     SectionRange TargetMem) {
   if (auto *DebugObjSection = getSection(Name))
     DebugObjSection->setTargetMemoryRange(TargetMem);
 }

 template <typename ELFT>
 Error ELFDebugObject::recordSection(
     StringRef Name, std::unique_ptr<ELFDebugObjectSection<ELFT>> Section) {
   if (Error Err = Section->validateInBounds(this->getBuffer(), Name.data()))
     return Err;
   auto ItInserted = Sections.try_emplace(Name, std::move(Section));
   if (!ItInserted.second)
     return make_error<StringError>("Duplicate section",
                                    inconvertibleErrorCode());
   return Error::success();
 }

 DebugObjectSection *ELFDebugObject::getSection(StringRef Name) {
   auto It = Sections.find(Name);
   return It == Sections.end() ? nullptr : It->second.get();
 }

 /// Creates a debug object based on the input object file from
 /// ObjectLinkingLayerJITLinkContext.
 ///
 static Expected<std::unique_ptr<DebugObject>>
 createDebugObjectFromBuffer(ExecutionSession &ES, LinkGraph &G,
                             JITLinkContext &Ctx, MemoryBufferRef ObjBuffer) {
   switch (G.getTargetTriple().getObjectFormat()) {
   case Triple::ELF:
     return ELFDebugObject::Create(ObjBuffer, Ctx, ES);

   default:
     // TODO: Once we add support for other formats, we might want to split this
     // into multiple files.
     return nullptr;
   }
 }

 DebugObjectManagerPlugin::DebugObjectManagerPlugin(
     ExecutionSession &ES, std::unique_ptr<DebugObjectRegistrar> Target)
     : ES(ES), Target(std::move(Target)) {}

 DebugObjectManagerPlugin::~DebugObjectManagerPlugin() = default;

 void DebugObjectManagerPlugin::notifyMaterializing(
     MaterializationResponsibility &MR, LinkGraph &G, JITLinkContext &Ctx,
     MemoryBufferRef ObjBuffer) {
   std::lock_guard<std::mutex> Lock(PendingObjsLock);
   assert(PendingObjs.count(&MR) == 0 &&
          "Cannot have more than one pending debug object per "
          "MaterializationResponsibility");

   if (auto DebugObj = createDebugObjectFromBuffer(ES, G, Ctx, ObjBuffer)) {
     // Not all link artifacts allow debugging.
     if (*DebugObj != nullptr)
       PendingObjs[&MR] = std::move(*DebugObj);
   } else {
     ES.reportError(DebugObj.takeError());
   }
 }

 void DebugObjectManagerPlugin::modifyPassConfig(
     MaterializationResponsibility &MR, LinkGraph &G,
     PassConfiguration &PassConfig) {
   // Not all link artifacts have associated debug objects.
   std::lock_guard<std::mutex> Lock(PendingObjsLock);
   auto It = PendingObjs.find(&MR);
   if (It == PendingObjs.end())
     return;

   DebugObject &DebugObj = *It->second;
   if (DebugObj.has(Requirement::ReportFinalSectionLoadAddresses)) {
     PassConfig.PostAllocationPasses.push_back(
         [&DebugObj](LinkGraph &Graph) -> Error {
           for (const Section &GraphSection : Graph.sections())
             DebugObj.reportSectionTargetMemoryRange(GraphSection.getName(),
                                                     SectionRange(GraphSection));
           return Error::success();
         });
   }
 }

 Error DebugObjectManagerPlugin::notifyEmitted(
     MaterializationResponsibility &MR) {
   std::lock_guard<std::mutex> Lock(PendingObjsLock);
   auto It = PendingObjs.find(&MR);
   if (It == PendingObjs.end())
     return Error::success();

   // During finalization the debug object is registered with the target.
   // Materialization must wait for this process to finish. Otherwise we might
   // start running code before the debugger processed the corresponding debug
   // info.
   std::promise<MSVCPError> FinalizePromise;
   std::future<MSVCPError> FinalizeErr = FinalizePromise.get_future();

   It->second->finalizeAsync(
       [this, &FinalizePromise, &MR](Expected<ExecutorAddrRange> TargetMem) {
         // Any failure here will fail materialization.
         if (!TargetMem) {
           FinalizePromise.set_value(TargetMem.takeError());
           return;
         }
         if (Error Err = Target->registerDebugObject(*TargetMem)) {
           FinalizePromise.set_value(std::move(Err));
           return;
         }

         // Once our tracking info is updated, notifyEmitted() can return and
         // finish materialization.
         FinalizePromise.set_value(MR.withResourceKeyDo([&](ResourceKey K) {
           assert(PendingObjs.count(&MR) && "We still hold PendingObjsLock");
           std::lock_guard<std::mutex> Lock(RegisteredObjsLock);
           RegisteredObjs[K].push_back(std::move(PendingObjs[&MR]));
           PendingObjs.erase(&MR);
         }));
       });

   return FinalizeErr.get();
 }

 Error DebugObjectManagerPlugin::notifyFailed(
     MaterializationResponsibility &MR) {
   std::lock_guard<std::mutex> Lock(PendingObjsLock);
   PendingObjs.erase(&MR);
   return Error::success();
 }

 void DebugObjectManagerPlugin::notifyTransferringResources(ResourceKey DstKey,
                                                            ResourceKey SrcKey) {
   // Debug objects are stored by ResourceKey only after registration.
   // Thus, pending objects don't need to be updated here.
   std::lock_guard<std::mutex> Lock(RegisteredObjsLock);
   auto SrcIt = RegisteredObjs.find(SrcKey);
   if (SrcIt != RegisteredObjs.end()) {
     // Resources from distinct MaterializationResponsibilitys can get merged
     // after emission, so we can have multiple debug objects per resource key.
     for (std::unique_ptr<DebugObject> &DebugObj : SrcIt->second)
       RegisteredObjs[DstKey].push_back(std::move(DebugObj));
     RegisteredObjs.erase(SrcIt);
   }
 }

 Error DebugObjectManagerPlugin::notifyRemovingResources(ResourceKey Key) {
   // Removing the resource for a pending object fails materialization, so they
   // get cleaned up in the notifyFailed() handler.
   std::lock_guard<std::mutex> Lock(RegisteredObjsLock);
   RegisteredObjs.erase(Key);

   // TODO: Implement unregister notifications.
   return Error::success();
 }

 } // namespace orc
 } // namespace llvm
	//===------- DebugObjectManagerPlugin.cpp - JITLink debug objects ---------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// FIXME: Update Plugin to poke the debug object into a new JITLink section,
	// rather than creating a new allocation.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/ExecutionEngine/Orc/DebugObjectManagerPlugin.h"

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/StringMap.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/BinaryFormat/ELF.h"
	#include "llvm/ExecutionEngine/JITLink/JITLinkDylib.h"
	#include "llvm/ExecutionEngine/JITLink/JITLinkMemoryManager.h"
	#include "llvm/ExecutionEngine/JITSymbol.h"
	#include "llvm/Object/ELFObjectFile.h"
	#include "llvm/Object/ObjectFile.h"
	#include "llvm/Support/Errc.h"
	#include "llvm/Support/MSVCErrorWorkarounds.h"
	#include "llvm/Support/MemoryBuffer.h"
	#include "llvm/Support/Process.h"
	#include "llvm/Support/raw_ostream.h"

	#include <set>

	#define DEBUG_TYPE "orc"

	using namespace llvm::jitlink;
	using namespace llvm::object;

	namespace llvm {
	namespace orc {

	class DebugObjectSection {
	public:
	virtual void setTargetMemoryRange(SectionRange Range) = 0;
	virtual void dump(raw_ostream &OS, StringRef Name) {}
	virtual ~DebugObjectSection() {}
	};

	template <typename ELFT>
	class ELFDebugObjectSection : public DebugObjectSection {
	public:
	// BinaryFormat ELF is not meant as a mutable format. We can only make changes
	// that don't invalidate the file structure.
	ELFDebugObjectSection(const typename ELFT::Shdr *Header)
	: Header(const_cast<typename ELFT::Shdr *>(Header)) {}

	void setTargetMemoryRange(SectionRange Range) override;
	void dump(raw_ostream &OS, StringRef Name) override;

	Error validateInBounds(StringRef Buffer, const char *Name) const;

	private:
	typename ELFT::Shdr *Header;

	bool isTextOrDataSection() const;
	};

	template <typename ELFT>
	void ELFDebugObjectSection<ELFT>::setTargetMemoryRange(SectionRange Range) {
	// Only patch load-addresses for executable and data sections.
	if (isTextOrDataSection()) {
	Header->sh_addr = static_cast<typename ELFT::uint>(Range.getStart());
	}
	}

	template <typename ELFT>
	bool ELFDebugObjectSection<ELFT>::isTextOrDataSection() const {
	switch (Header->sh_type) {
	case ELF::SHT_PROGBITS:
	case ELF::SHT_X86_64_UNWIND:
	return Header->sh_flags & (ELF::SHF_EXECINSTR \| ELF::SHF_ALLOC);
	}
	return false;
	}

	template <typename ELFT>
	Error ELFDebugObjectSection<ELFT>::validateInBounds(StringRef Buffer,
	const char *Name) const {
	const uint8_t *Start = Buffer.bytes_begin();
	const uint8_t *End = Buffer.bytes_end();
	const uint8_t HeaderPtr = reinterpret_cast<uint8_t >(Header);
	if (HeaderPtr < Start \|\| HeaderPtr + sizeof(typename ELFT::Shdr) > End)
	return make_error<StringError>(
	formatv("{0} section header at {1:x16} not within bounds of the "
	"given debug object buffer [{2:x16} - {3:x16}]",
	Name, &Header->sh_addr, Start, End),
	inconvertibleErrorCode());
	if (Header->sh_offset + Header->sh_size > Buffer.size())
	return make_error<StringError>(
	formatv("{0} section data [{1:x16} - {2:x16}] not within bounds of "
	"the given debug object buffer [{3:x16} - {4:x16}]",
	Name, Start + Header->sh_offset,
	Start + Header->sh_offset + Header->sh_size, Start, End),
	inconvertibleErrorCode());
	return Error::success();
	}

	template <typename ELFT>
	void ELFDebugObjectSection<ELFT>::dump(raw_ostream &OS, StringRef Name) {
	if (auto Addr = static_cast<JITTargetAddress>(Header->sh_addr)) {
	OS << formatv(" {0:x16} {1}\n", Addr, Name);
	} else {
	OS << formatv(" {0}\n", Name);
	}
	}

	enum class Requirement {
	// Request final target memory load-addresses for all sections.
	ReportFinalSectionLoadAddresses,
	};

	/// The plugin creates a debug object from when JITLink starts processing the
	/// corresponding LinkGraph. It provides access to the pass configuration of
	/// the LinkGraph and calls the finalization function, once the resulting link
	/// artifact was emitted.
	///
	class DebugObject {
	public:
	DebugObject(JITLinkMemoryManager &MemMgr, const JITLinkDylib *JD,
	ExecutionSession &ES)
	: MemMgr(MemMgr), JD(JD), ES(ES) {}

	void set(Requirement Req) { Reqs.insert(Req); }
	bool has(Requirement Req) const { return Reqs.count(Req) > 0; }

	using FinalizeContinuation = std::function<void(Expected<ExecutorAddrRange>)>;

	void finalizeAsync(FinalizeContinuation OnFinalize);

	virtual ~DebugObject() {
	if (Alloc) {
	std::vector<FinalizedAlloc> Allocs;
	Allocs.push_back(std::move(Alloc));
	if (Error Err = MemMgr.deallocate(std::move(Allocs)))
	ES.reportError(std::move(Err));
	}
	}

	virtual void reportSectionTargetMemoryRange(StringRef Name,
	SectionRange TargetMem) {}

	protected:
	using InFlightAlloc = JITLinkMemoryManager::InFlightAlloc;
	using FinalizedAlloc = JITLinkMemoryManager::FinalizedAlloc;

	virtual Expected<SimpleSegmentAlloc> finalizeWorkingMemory() = 0;

	JITLinkMemoryManager &MemMgr;
	const JITLinkDylib *JD = nullptr;

	private:
	ExecutionSession &ES;
	std::set<Requirement> Reqs;
	FinalizedAlloc Alloc;
	};

	// Finalize working memory and take ownership of the resulting allocation. Start
	// copying memory over to the target and pass on the result once we're done.
	// Ownership of the allocation remains with us for the rest of our lifetime.
	void DebugObject::finalizeAsync(FinalizeContinuation OnFinalize) {
	assert(!Alloc && "Cannot finalize more than once");

	if (auto SimpleSegAlloc = finalizeWorkingMemory()) {
	auto ROSeg = SimpleSegAlloc->getSegInfo(MemProt::Read);
	ExecutorAddrRange DebugObjRange(ExecutorAddr(ROSeg.Addr),
	ExecutorAddrDiff(ROSeg.WorkingMem.size()));
	SimpleSegAlloc->finalize(
	[this, DebugObjRange,
	OnFinalize = std::move(OnFinalize)](Expected<FinalizedAlloc> FA) {
	if (FA) {
	Alloc = std::move(*FA);
	OnFinalize(DebugObjRange);
	} else
	OnFinalize(FA.takeError());
	});
	} else
	OnFinalize(SimpleSegAlloc.takeError());
	}

	/// The current implementation of ELFDebugObject replicates the approach used in
	/// RuntimeDyld: It patches executable and data section headers in the given
	/// object buffer with load-addresses of their corresponding sections in target
	/// memory.
	///
	class ELFDebugObject : public DebugObject {
	public:
	static Expected<std::unique_ptr<DebugObject>>
	Create(MemoryBufferRef Buffer, JITLinkContext &Ctx, ExecutionSession &ES);

	void reportSectionTargetMemoryRange(StringRef Name,
	SectionRange TargetMem) override;

	StringRef getBuffer() const { return Buffer->getMemBufferRef().getBuffer(); }

	protected:
	Expected<SimpleSegmentAlloc> finalizeWorkingMemory() override;

	template <typename ELFT>
	Error recordSection(StringRef Name,
	std::unique_ptr<ELFDebugObjectSection<ELFT>> Section);
	DebugObjectSection *getSection(StringRef Name);

	private:
	template <typename ELFT>
	static Expected<std::unique_ptr<ELFDebugObject>>
	CreateArchType(MemoryBufferRef Buffer, JITLinkMemoryManager &MemMgr,
	const JITLinkDylib *JD, ExecutionSession &ES);

	static std::unique_ptr<WritableMemoryBuffer>
	CopyBuffer(MemoryBufferRef Buffer, Error &Err);

	ELFDebugObject(std::unique_ptr<WritableMemoryBuffer> Buffer,
	JITLinkMemoryManager &MemMgr, const JITLinkDylib *JD,
	ExecutionSession &ES)
	: DebugObject(MemMgr, JD, ES), Buffer(std::move(Buffer)) {
	set(Requirement::ReportFinalSectionLoadAddresses);
	}

	std::unique_ptr<WritableMemoryBuffer> Buffer;
	StringMap<std::unique_ptr<DebugObjectSection>> Sections;
	};

	static const std::set<StringRef> DwarfSectionNames = {
	#define HANDLE_DWARF_SECTION(ENUM_NAME, ELF_NAME, CMDLINE_NAME, OPTION) \
	ELF_NAME,
	#include "llvm/BinaryFormat/Dwarf.def"
	#undef HANDLE_DWARF_SECTION
	};

	static bool isDwarfSection(StringRef SectionName) {
	return DwarfSectionNames.count(SectionName) == 1;
	}

	std::unique_ptr<WritableMemoryBuffer>
	ELFDebugObject::CopyBuffer(MemoryBufferRef Buffer, Error &Err) {
	ErrorAsOutParameter _(&Err);
	size_t Size = Buffer.getBufferSize();
	StringRef Name = Buffer.getBufferIdentifier();
	if (auto Copy = WritableMemoryBuffer::getNewUninitMemBuffer(Size, Name)) {
	memcpy(Copy->getBufferStart(), Buffer.getBufferStart(), Size);
	return Copy;
	}

	Err = errorCodeToError(make_error_code(errc::not_enough_memory));
	return nullptr;
	}

	template <typename ELFT>
	Expected<std::unique_ptr<ELFDebugObject>>
	ELFDebugObject::CreateArchType(MemoryBufferRef Buffer,
	JITLinkMemoryManager &MemMgr,
	const JITLinkDylib *JD, ExecutionSession &ES) {
	using SectionHeader = typename ELFT::Shdr;

	Error Err = Error::success();
	std::unique_ptr<ELFDebugObject> DebugObj(
	new ELFDebugObject(CopyBuffer(Buffer, Err), MemMgr, JD, ES));
	if (Err)
	return std::move(Err);

	Expected<ELFFile<ELFT>> ObjRef = ELFFile<ELFT>::create(DebugObj->getBuffer());
	if (!ObjRef)
	return ObjRef.takeError();

	// TODO: Add support for other architectures.
	uint16_t TargetMachineArch = ObjRef->getHeader().e_machine;
	if (TargetMachineArch != ELF::EM_X86_64)
	return nullptr;

	Expected<ArrayRef<SectionHeader>> Sections = ObjRef->sections();
	if (!Sections)
	return Sections.takeError();

	bool HasDwarfSection = false;
	for (const SectionHeader &Header : *Sections) {
	Expected<StringRef> Name = ObjRef->getSectionName(Header);
	if (!Name)
	return Name.takeError();
	if (Name->empty())
	continue;
	HasDwarfSection \|= isDwarfSection(*Name);

	auto Wrapped = std::make_unique<ELFDebugObjectSection<ELFT>>(&Header);
	if (Error Err = DebugObj->recordSection(*Name, std::move(Wrapped)))
	return std::move(Err);
	}

	if (!HasDwarfSection) {
	LLVM_DEBUG(dbgs() << "Aborting debug registration for LinkGraph \""
	<< DebugObj->Buffer->getBufferIdentifier()
	<< "\": input object contains no debug info\n");
	return nullptr;
	}

	return std::move(DebugObj);
	}

	Expected<std::unique_ptr<DebugObject>>
	ELFDebugObject::Create(MemoryBufferRef Buffer, JITLinkContext &Ctx,
	ExecutionSession &ES) {
	unsigned char Class, Endian;
	std::tie(Class, Endian) = getElfArchType(Buffer.getBuffer());

	if (Class == ELF::ELFCLASS32) {
	if (Endian == ELF::ELFDATA2LSB)
	return CreateArchType<ELF32LE>(Buffer, Ctx.getMemoryManager(),
	Ctx.getJITLinkDylib(), ES);
	if (Endian == ELF::ELFDATA2MSB)
	return CreateArchType<ELF32BE>(Buffer, Ctx.getMemoryManager(),
	Ctx.getJITLinkDylib(), ES);
	return nullptr;
	}
	if (Class == ELF::ELFCLASS64) {
	if (Endian == ELF::ELFDATA2LSB)
	return CreateArchType<ELF64LE>(Buffer, Ctx.getMemoryManager(),
	Ctx.getJITLinkDylib(), ES);
	if (Endian == ELF::ELFDATA2MSB)
	return CreateArchType<ELF64BE>(Buffer, Ctx.getMemoryManager(),
	Ctx.getJITLinkDylib(), ES);
	return nullptr;
	}
	return nullptr;
	}

	Expected<SimpleSegmentAlloc> ELFDebugObject::finalizeWorkingMemory() {
	LLVM_DEBUG({
	dbgs() << "Section load-addresses in debug object for \""
	<< Buffer->getBufferIdentifier() << "\":\n";
	for (const auto &KV : Sections)
	KV.second->dump(dbgs(), KV.first());
	});

	// TODO: This works, but what actual alignment requirements do we have?
	unsigned PageSize = sys::Process::getPageSizeEstimate();
	size_t Size = Buffer->getBufferSize();

	// Allocate working memory for debug object in read-only segment.
	auto Alloc = SimpleSegmentAlloc::Create(
	MemMgr, JD, {{MemProt::Read, {Size, Align(PageSize)}}});
	if (!Alloc)
	return Alloc;

	// Initialize working memory with a copy of our object buffer.
	auto SegInfo = Alloc->getSegInfo(MemProt::Read);
	memcpy(SegInfo.WorkingMem.data(), Buffer->getBufferStart(), Size);
	Buffer.reset();

	return Alloc;
	}

	void ELFDebugObject::reportSectionTargetMemoryRange(StringRef Name,
	SectionRange TargetMem) {
	if (auto *DebugObjSection = getSection(Name))
	DebugObjSection->setTargetMemoryRange(TargetMem);
	}

	template <typename ELFT>
	Error ELFDebugObject::recordSection(
	StringRef Name, std::unique_ptr<ELFDebugObjectSection<ELFT>> Section) {
	if (Error Err = Section->validateInBounds(this->getBuffer(), Name.data()))
	return Err;
	auto ItInserted = Sections.try_emplace(Name, std::move(Section));
	if (!ItInserted.second)
	return make_error<StringError>("Duplicate section",
	inconvertibleErrorCode());
	return Error::success();
	}

	DebugObjectSection *ELFDebugObject::getSection(StringRef Name) {
	auto It = Sections.find(Name);
	return It == Sections.end() ? nullptr : It->second.get();
	}

	/// Creates a debug object based on the input object file from
	/// ObjectLinkingLayerJITLinkContext.
	///
	static Expected<std::unique_ptr<DebugObject>>
	createDebugObjectFromBuffer(ExecutionSession &ES, LinkGraph &G,
	JITLinkContext &Ctx, MemoryBufferRef ObjBuffer) {
	switch (G.getTargetTriple().getObjectFormat()) {
	case Triple::ELF:
	return ELFDebugObject::Create(ObjBuffer, Ctx, ES);

	default:
	// TODO: Once we add support for other formats, we might want to split this
	// into multiple files.
	return nullptr;
	}
	}

	DebugObjectManagerPlugin::DebugObjectManagerPlugin(
	ExecutionSession &ES, std::unique_ptr<DebugObjectRegistrar> Target)
	: ES(ES), Target(std::move(Target)) {}

	DebugObjectManagerPlugin::~DebugObjectManagerPlugin() = default;

	void DebugObjectManagerPlugin::notifyMaterializing(
	MaterializationResponsibility &MR, LinkGraph &G, JITLinkContext &Ctx,
	MemoryBufferRef ObjBuffer) {
	std::lock_guard<std::mutex> Lock(PendingObjsLock);
	assert(PendingObjs.count(&MR) == 0 &&
	"Cannot have more than one pending debug object per "
	"MaterializationResponsibility");

	if (auto DebugObj = createDebugObjectFromBuffer(ES, G, Ctx, ObjBuffer)) {
	// Not all link artifacts allow debugging.
	if (*DebugObj != nullptr)
	PendingObjs[&MR] = std::move(*DebugObj);
	} else {
	ES.reportError(DebugObj.takeError());
	}
	}

	void DebugObjectManagerPlugin::modifyPassConfig(
	MaterializationResponsibility &MR, LinkGraph &G,
	PassConfiguration &PassConfig) {
	// Not all link artifacts have associated debug objects.
	std::lock_guard<std::mutex> Lock(PendingObjsLock);
	auto It = PendingObjs.find(&MR);
	if (It == PendingObjs.end())
	return;

	DebugObject &DebugObj = *It->second;
	if (DebugObj.has(Requirement::ReportFinalSectionLoadAddresses)) {
	PassConfig.PostAllocationPasses.push_back(
	[&DebugObj](LinkGraph &Graph) -> Error {
	for (const Section &GraphSection : Graph.sections())
	DebugObj.reportSectionTargetMemoryRange(GraphSection.getName(),
	SectionRange(GraphSection));
	return Error::success();
	});
	}
	}

	Error DebugObjectManagerPlugin::notifyEmitted(
	MaterializationResponsibility &MR) {
	std::lock_guard<std::mutex> Lock(PendingObjsLock);
	auto It = PendingObjs.find(&MR);
	if (It == PendingObjs.end())
	return Error::success();

	// During finalization the debug object is registered with the target.
	// Materialization must wait for this process to finish. Otherwise we might
	// start running code before the debugger processed the corresponding debug
	// info.
	std::promise<MSVCPError> FinalizePromise;
	std::future<MSVCPError> FinalizeErr = FinalizePromise.get_future();

	It->second->finalizeAsync(
	[this, &FinalizePromise, &MR](Expected<ExecutorAddrRange> TargetMem) {
	// Any failure here will fail materialization.
	if (!TargetMem) {
	FinalizePromise.set_value(TargetMem.takeError());
	return;
	}
	if (Error Err = Target->registerDebugObject(*TargetMem)) {
	FinalizePromise.set_value(std::move(Err));
	return;
	}

	// Once our tracking info is updated, notifyEmitted() can return and
	// finish materialization.
	FinalizePromise.set_value(MR.withResourceKeyDo([&](ResourceKey K) {
	assert(PendingObjs.count(&MR) && "We still hold PendingObjsLock");
	std::lock_guard<std::mutex> Lock(RegisteredObjsLock);
	RegisteredObjs[K].push_back(std::move(PendingObjs[&MR]));
	PendingObjs.erase(&MR);
	}));
	});

	return FinalizeErr.get();
	}

	Error DebugObjectManagerPlugin::notifyFailed(
	MaterializationResponsibility &MR) {
	std::lock_guard<std::mutex> Lock(PendingObjsLock);
	PendingObjs.erase(&MR);
	return Error::success();
	}

	void DebugObjectManagerPlugin::notifyTransferringResources(ResourceKey DstKey,
	ResourceKey SrcKey) {
	// Debug objects are stored by ResourceKey only after registration.
	// Thus, pending objects don't need to be updated here.
	std::lock_guard<std::mutex> Lock(RegisteredObjsLock);
	auto SrcIt = RegisteredObjs.find(SrcKey);
	if (SrcIt != RegisteredObjs.end()) {
	// Resources from distinct MaterializationResponsibilitys can get merged
	// after emission, so we can have multiple debug objects per resource key.
	for (std::unique_ptr<DebugObject> &DebugObj : SrcIt->second)
	RegisteredObjs[DstKey].push_back(std::move(DebugObj));
	RegisteredObjs.erase(SrcIt);
	}
	}

	Error DebugObjectManagerPlugin::notifyRemovingResources(ResourceKey Key) {
	// Removing the resource for a pending object fails materialization, so they
	// get cleaned up in the notifyFailed() handler.
	std::lock_guard<std::mutex> Lock(RegisteredObjsLock);
	RegisteredObjs.erase(Key);

	// TODO: Implement unregister notifications.
	return Error::success();
	}

	} // namespace orc
	} // namespace llvm