third_party/llvm-16.0/llvm/lib/ProfileData/RawMemProfReader.cpp - SwiftShader - Git at Google

 //===- RawMemProfReader.cpp - Instrumented memory profiling reader --------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains support for reading MemProf profiling data.
 //
 //===----------------------------------------------------------------------===//

 #include <algorithm>
 #include <cstdint>
 #include <memory>
 #include <type_traits>

 #include "llvm/ADT/ArrayRef.h"
 #include "llvm/ADT/DenseMap.h"
 #include "llvm/ADT/SetVector.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/StringExtras.h"
 #include "llvm/DebugInfo/DWARF/DWARFContext.h"
 #include "llvm/DebugInfo/Symbolize/SymbolizableModule.h"
 #include "llvm/DebugInfo/Symbolize/SymbolizableObjectFile.h"
 #include "llvm/Object/Binary.h"
 #include "llvm/Object/ELFObjectFile.h"
 #include "llvm/Object/ObjectFile.h"
 #include "llvm/ProfileData/InstrProf.h"
 #include "llvm/ProfileData/MemProf.h"
 #include "llvm/ProfileData/MemProfData.inc"
 #include "llvm/ProfileData/RawMemProfReader.h"
 #include "llvm/Support/Endian.h"
 #include "llvm/Support/Path.h"

 #define DEBUG_TYPE "memprof"

 namespace llvm {
 namespace memprof {
 namespace {
 template <class T = uint64_t> inline T alignedRead(const char *Ptr) {
   static_assert(std::is_pod<T>::value, "Not a pod type.");
   assert(reinterpret_cast<size_t>(Ptr) % sizeof(T) == 0 && "Unaligned Read");
   return *reinterpret_cast<const T *>(Ptr);
 }

 Error checkBuffer(const MemoryBuffer &Buffer) {
   if (!RawMemProfReader::hasFormat(Buffer))
     return make_error<InstrProfError>(instrprof_error::bad_magic);

   if (Buffer.getBufferSize() == 0)
     return make_error<InstrProfError>(instrprof_error::empty_raw_profile);

   if (Buffer.getBufferSize() < sizeof(Header)) {
     return make_error<InstrProfError>(instrprof_error::truncated);
   }

   // The size of the buffer can be > header total size since we allow repeated
   // serialization of memprof profiles to the same file.
   uint64_t TotalSize = 0;
   const char *Next = Buffer.getBufferStart();
   while (Next < Buffer.getBufferEnd()) {
     auto *H = reinterpret_cast<const Header *>(Next);
     if (H->Version != MEMPROF_RAW_VERSION) {
       return make_error<InstrProfError>(instrprof_error::unsupported_version);
     }

     TotalSize += H->TotalSize;
     Next += H->TotalSize;
   }

   if (Buffer.getBufferSize() != TotalSize) {
     return make_error<InstrProfError>(instrprof_error::malformed);
   }
   return Error::success();
 }

 llvm::SmallVector<SegmentEntry> readSegmentEntries(const char *Ptr) {
   using namespace support;

   const uint64_t NumItemsToRead =
       endian::readNext<uint64_t, little, unaligned>(Ptr);
   llvm::SmallVector<SegmentEntry> Items;
   for (uint64_t I = 0; I < NumItemsToRead; I++) {
     Items.push_back(*reinterpret_cast<const SegmentEntry *>(
         Ptr + I * sizeof(SegmentEntry)));
   }
   return Items;
 }

 llvm::SmallVector<std::pair<uint64_t, MemInfoBlock>>
 readMemInfoBlocks(const char *Ptr) {
   using namespace support;

   const uint64_t NumItemsToRead =
       endian::readNext<uint64_t, little, unaligned>(Ptr);
   llvm::SmallVector<std::pair<uint64_t, MemInfoBlock>> Items;
   for (uint64_t I = 0; I < NumItemsToRead; I++) {
     const uint64_t Id = endian::readNext<uint64_t, little, unaligned>(Ptr);
     const MemInfoBlock MIB = *reinterpret_cast<const MemInfoBlock *>(Ptr);
     Items.push_back({Id, MIB});
     // Only increment by size of MIB since readNext implicitly increments.
     Ptr += sizeof(MemInfoBlock);
   }
   return Items;
 }

 CallStackMap readStackInfo(const char *Ptr) {
   using namespace support;

   const uint64_t NumItemsToRead =
       endian::readNext<uint64_t, little, unaligned>(Ptr);
   CallStackMap Items;

   for (uint64_t I = 0; I < NumItemsToRead; I++) {
     const uint64_t StackId = endian::readNext<uint64_t, little, unaligned>(Ptr);
     const uint64_t NumPCs = endian::readNext<uint64_t, little, unaligned>(Ptr);

     SmallVector<uint64_t> CallStack;
     for (uint64_t J = 0; J < NumPCs; J++) {
       CallStack.push_back(endian::readNext<uint64_t, little, unaligned>(Ptr));
     }

     Items[StackId] = CallStack;
   }
   return Items;
 }

 // Merges the contents of stack information in \p From to \p To. Returns true if
 // any stack ids observed previously map to a different set of program counter
 // addresses.
 bool mergeStackMap(const CallStackMap &From, CallStackMap &To) {
   for (const auto &IdStack : From) {
     auto I = To.find(IdStack.first);
     if (I == To.end()) {
       To[IdStack.first] = IdStack.second;
     } else {
       // Check that the PCs are the same (in order).
       if (IdStack.second != I->second)
         return true;
     }
   }
   return false;
 }

 Error report(Error E, const StringRef Context) {
   return joinErrors(createStringError(inconvertibleErrorCode(), Context),
                     std::move(E));
 }

 bool isRuntimePath(const StringRef Path) {
   return StringRef(llvm::sys::path::convert_to_slash(Path))
       .contains("memprof/memprof_");
 }

 std::string getBuildIdString(const SegmentEntry &Entry) {
   constexpr size_t Size = sizeof(Entry.BuildId) / sizeof(uint8_t);
   constexpr uint8_t Zeros[Size] = {0};
   // If the build id is unset print a helpful string instead of all zeros.
   if (memcmp(Entry.BuildId, Zeros, Size) == 0)
     return "<None>";

   std::string Str;
   raw_string_ostream OS(Str);
   for (size_t I = 0; I < Size; I++) {
     OS << format_hex_no_prefix(Entry.BuildId[I], 2);
   }
   return OS.str();
 }
 } // namespace

 Expected<std::unique_ptr<RawMemProfReader>>
 RawMemProfReader::create(const Twine &Path, const StringRef ProfiledBinary,
                          bool KeepName) {
   auto BufferOr = MemoryBuffer::getFileOrSTDIN(Path);
   if (std::error_code EC = BufferOr.getError())
     return report(errorCodeToError(EC), Path.getSingleStringRef());

   std::unique_ptr<MemoryBuffer> Buffer(BufferOr.get().release());
   if (Error E = checkBuffer(*Buffer))
     return report(std::move(E), Path.getSingleStringRef());

   if (ProfiledBinary.empty())
     return report(
         errorCodeToError(make_error_code(std::errc::invalid_argument)),
         "Path to profiled binary is empty!");

   auto BinaryOr = llvm::object::createBinary(ProfiledBinary);
   if (!BinaryOr) {
     return report(BinaryOr.takeError(), ProfiledBinary);
   }

   // Use new here since constructor is private.
   std::unique_ptr<RawMemProfReader> Reader(
       new RawMemProfReader(std::move(BinaryOr.get()), KeepName));
   if (Error E = Reader->initialize(std::move(Buffer))) {
     return std::move(E);
   }
   return std::move(Reader);
 }

 bool RawMemProfReader::hasFormat(const StringRef Path) {
   auto BufferOr = MemoryBuffer::getFileOrSTDIN(Path);
   if (!BufferOr)
     return false;

   std::unique_ptr<MemoryBuffer> Buffer(BufferOr.get().release());
   return hasFormat(*Buffer);
 }

 bool RawMemProfReader::hasFormat(const MemoryBuffer &Buffer) {
   if (Buffer.getBufferSize() < sizeof(uint64_t))
     return false;
   // Aligned read to sanity check that the buffer was allocated with at least 8b
   // alignment.
   const uint64_t Magic = alignedRead(Buffer.getBufferStart());
   return Magic == MEMPROF_RAW_MAGIC_64;
 }

 void RawMemProfReader::printYAML(raw_ostream &OS) {
   uint64_t NumAllocFunctions = 0, NumMibInfo = 0;
   for (const auto &KV : FunctionProfileData) {
     const size_t NumAllocSites = KV.second.AllocSites.size();
     if (NumAllocSites > 0) {
       NumAllocFunctions++;
       NumMibInfo += NumAllocSites;
     }
   }

   OS << "MemprofProfile:\n";
   OS << "  Summary:\n";
   OS << "    Version: " << MEMPROF_RAW_VERSION << "\n";
   OS << "    NumSegments: " << SegmentInfo.size() << "\n";
   OS << "    NumMibInfo: " << NumMibInfo << "\n";
   OS << "    NumAllocFunctions: " << NumAllocFunctions << "\n";
   OS << "    NumStackOffsets: " << StackMap.size() << "\n";
   // Print out the segment information.
   OS << "  Segments:\n";
   for (const auto &Entry : SegmentInfo) {
     OS << "  -\n";
     OS << "    BuildId: " << getBuildIdString(Entry) << "\n";
     OS << "    Start: 0x" << llvm::utohexstr(Entry.Start) << "\n";
     OS << "    End: 0x" << llvm::utohexstr(Entry.End) << "\n";
     OS << "    Offset: 0x" << llvm::utohexstr(Entry.Offset) << "\n";
   }
   // Print out the merged contents of the profiles.
   OS << "  Records:\n";
   for (const auto &Entry : *this) {
     OS << "  -\n";
     OS << "    FunctionGUID: " << Entry.first << "\n";
     Entry.second.print(OS);
   }
 }

 Error RawMemProfReader::initialize(std::unique_ptr<MemoryBuffer> DataBuffer) {
   const StringRef FileName = Binary.getBinary()->getFileName();

   auto *ElfObject = dyn_cast<object::ELFObjectFileBase>(Binary.getBinary());
   if (!ElfObject) {
     return report(make_error<StringError>(Twine("Not an ELF file: "),
                                           inconvertibleErrorCode()),
                   FileName);
   }

   // Check whether the profiled binary was built with position independent code
   // (PIC). For now we provide a error message until symbolization support
   // is added for pic.
   auto* Elf64LEObject = llvm::cast<llvm::object::ELF64LEObjectFile>(ElfObject);
   const llvm::object::ELF64LEFile& ElfFile = Elf64LEObject->getELFFile();
   auto PHdrsOr = ElfFile.program_headers();
   if(!PHdrsOr)
     return report(make_error<StringError>(Twine("Could not read program headers: "),
                                           inconvertibleErrorCode()),
                   FileName);
   auto FirstLoadHeader = PHdrsOr->begin();
   while (FirstLoadHeader->p_type != llvm::ELF::PT_LOAD)
     ++FirstLoadHeader;
   if(FirstLoadHeader->p_vaddr == 0)
     return report(make_error<StringError>(Twine("Unsupported position independent code"),
                                           inconvertibleErrorCode()),
                   FileName);

   auto Triple = ElfObject->makeTriple();
   if (!Triple.isX86())
     return report(make_error<StringError>(Twine("Unsupported target: ") +
                                               Triple.getArchName(),
                                           inconvertibleErrorCode()),
                   FileName);

   auto *Object = cast<object::ObjectFile>(Binary.getBinary());
   std::unique_ptr<DIContext> Context = DWARFContext::create(
       *Object, DWARFContext::ProcessDebugRelocations::Process);

   auto SOFOr = symbolize::SymbolizableObjectFile::create(
       Object, std::move(Context), /*UntagAddresses=*/false);
   if (!SOFOr)
     return report(SOFOr.takeError(), FileName);
   Symbolizer = std::move(SOFOr.get());

   if (Error E = readRawProfile(std::move(DataBuffer)))
     return E;

   if (Error E = symbolizeAndFilterStackFrames())
     return E;

   return mapRawProfileToRecords();
 }

 Error RawMemProfReader::mapRawProfileToRecords() {
   // Hold a mapping from function to each callsite location we encounter within
   // it that is part of some dynamic allocation context. The location is stored
   // as a pointer to a symbolized list of inline frames.
   using LocationPtr = const llvm::SmallVector<FrameId> *;
   llvm::MapVector<GlobalValue::GUID, llvm::SetVector<LocationPtr>>
       PerFunctionCallSites;

   // Convert the raw profile callstack data into memprof records. While doing so
   // keep track of related contexts so that we can fill these in later.
   for (const auto &Entry : CallstackProfileData) {
     const uint64_t StackId = Entry.first;

     auto It = StackMap.find(StackId);
     if (It == StackMap.end())
       return make_error<InstrProfError>(
           instrprof_error::malformed,
           "memprof callstack record does not contain id: " + Twine(StackId));

     // Construct the symbolized callstack.
     llvm::SmallVector<FrameId> Callstack;
     Callstack.reserve(It->getSecond().size());

     llvm::ArrayRef<uint64_t> Addresses = It->getSecond();
     for (size_t I = 0; I < Addresses.size(); I++) {
       const uint64_t Address = Addresses[I];
       assert(SymbolizedFrame.count(Address) > 0 &&
              "Address not found in SymbolizedFrame map");
       const SmallVector<FrameId> &Frames = SymbolizedFrame[Address];

       assert(!idToFrame(Frames.back()).IsInlineFrame &&
              "The last frame should not be inlined");

       // Record the callsites for each function. Skip the first frame of the
       // first address since it is the allocation site itself that is recorded
       // as an alloc site.
       for (size_t J = 0; J < Frames.size(); J++) {
         if (I == 0 && J == 0)
           continue;
         // We attach the entire bottom-up frame here for the callsite even
         // though we only need the frames up to and including the frame for
         // Frames[J].Function. This will enable better deduplication for
         // compression in the future.
         const GlobalValue::GUID Guid = idToFrame(Frames[J]).Function;
         PerFunctionCallSites[Guid].insert(&Frames);
       }

       // Add all the frames to the current allocation callstack.
       Callstack.append(Frames.begin(), Frames.end());
     }

     // We attach the memprof record to each function bottom-up including the
     // first non-inline frame.
     for (size_t I = 0; /*Break out using the condition below*/; I++) {
       const Frame &F = idToFrame(Callstack[I]);
       auto Result =
           FunctionProfileData.insert({F.Function, IndexedMemProfRecord()});
       IndexedMemProfRecord &Record = Result.first->second;
       Record.AllocSites.emplace_back(Callstack, Entry.second);

       if (!F.IsInlineFrame)
         break;
     }
   }

   // Fill in the related callsites per function.
   for (const auto &[Id, Locs] : PerFunctionCallSites) {
     // Some functions may have only callsite data and no allocation data. Here
     // we insert a new entry for callsite data if we need to.
     auto Result = FunctionProfileData.insert({Id, IndexedMemProfRecord()});
     IndexedMemProfRecord &Record = Result.first->second;
     for (LocationPtr Loc : Locs) {
       Record.CallSites.push_back(*Loc);
     }
   }

   return Error::success();
 }

 Error RawMemProfReader::symbolizeAndFilterStackFrames() {
   // The specifier to use when symbolization is requested.
   const DILineInfoSpecifier Specifier(
       DILineInfoSpecifier::FileLineInfoKind::RawValue,
       DILineInfoSpecifier::FunctionNameKind::LinkageName);

   // For entries where all PCs in the callstack are discarded, we erase the
   // entry from the stack map.
   llvm::SmallVector<uint64_t> EntriesToErase;
   // We keep track of all prior discarded entries so that we can avoid invoking
   // the symbolizer for such entries.
   llvm::DenseSet<uint64_t> AllVAddrsToDiscard;
   for (auto &Entry : StackMap) {
     for (const uint64_t VAddr : Entry.getSecond()) {
       // Check if we have already symbolized and cached the result or if we
       // don't want to attempt symbolization since we know this address is bad.
       // In this case the address is also removed from the current callstack.
       if (SymbolizedFrame.count(VAddr) > 0 ||
           AllVAddrsToDiscard.contains(VAddr))
         continue;

       Expected<DIInliningInfo> DIOr = Symbolizer->symbolizeInlinedCode(
           getModuleOffset(VAddr), Specifier, /*UseSymbolTable=*/false);
       if (!DIOr)
         return DIOr.takeError();
       DIInliningInfo DI = DIOr.get();

       // Drop frames which we can't symbolize or if they belong to the runtime.
       if (DI.getFrame(0).FunctionName == DILineInfo::BadString ||
           isRuntimePath(DI.getFrame(0).FileName)) {
         AllVAddrsToDiscard.insert(VAddr);
         continue;
       }

       for (size_t I = 0, NumFrames = DI.getNumberOfFrames(); I < NumFrames;
            I++) {
         const auto &DIFrame = DI.getFrame(I);
         const uint64_t Guid =
             IndexedMemProfRecord::getGUID(DIFrame.FunctionName);
         const Frame F(Guid, DIFrame.Line - DIFrame.StartLine, DIFrame.Column,
                       // Only the last entry is not an inlined location.
                       I != NumFrames - 1);
         // Here we retain a mapping from the GUID to symbol name instead of
         // adding it to the frame object directly to reduce memory overhead.
         // This is because there can be many unique frames, particularly for
         // callsite frames.
         if (KeepSymbolName)
           GuidToSymbolName.insert({Guid, DIFrame.FunctionName});

         const FrameId Hash = F.hash();
         IdToFrame.insert({Hash, F});
         SymbolizedFrame[VAddr].push_back(Hash);
       }
     }

     auto &CallStack = Entry.getSecond();
     llvm::erase_if(CallStack, [&AllVAddrsToDiscard](const uint64_t A) {
       return AllVAddrsToDiscard.contains(A);
     });
     if (CallStack.empty())
       EntriesToErase.push_back(Entry.getFirst());
   }

   // Drop the entries where the callstack is empty.
   for (const uint64_t Id : EntriesToErase) {
     StackMap.erase(Id);
     CallstackProfileData.erase(Id);
   }

   if (StackMap.empty())
     return make_error<InstrProfError>(
         instrprof_error::malformed,
         "no entries in callstack map after symbolization");

   return Error::success();
 }

 Error RawMemProfReader::readRawProfile(
     std::unique_ptr<MemoryBuffer> DataBuffer) {
   const char *Next = DataBuffer->getBufferStart();

   while (Next < DataBuffer->getBufferEnd()) {
     auto *Header = reinterpret_cast<const memprof::Header *>(Next);

     // Read in the segment information, check whether its the same across all
     // profiles in this binary file.
     const llvm::SmallVector<SegmentEntry> Entries =
         readSegmentEntries(Next + Header->SegmentOffset);
     if (!SegmentInfo.empty() && SegmentInfo != Entries) {
       // We do not expect segment information to change when deserializing from
       // the same binary profile file. This can happen if dynamic libraries are
       // loaded/unloaded between profile dumping.
       return make_error<InstrProfError>(
           instrprof_error::malformed,
           "memprof raw profile has different segment information");
     }
     SegmentInfo.assign(Entries.begin(), Entries.end());

     // Read in the MemInfoBlocks. Merge them based on stack id - we assume that
     // raw profiles in the same binary file are from the same process so the
     // stackdepot ids are the same.
     for (const auto &Value : readMemInfoBlocks(Next + Header->MIBOffset)) {
       if (CallstackProfileData.count(Value.first)) {
         CallstackProfileData[Value.first].Merge(Value.second);
       } else {
         CallstackProfileData[Value.first] = Value.second;
       }
     }

     // Read in the callstack for each ids. For multiple raw profiles in the same
     // file, we expect that the callstack is the same for a unique id.
     const CallStackMap CSM = readStackInfo(Next + Header->StackOffset);
     if (StackMap.empty()) {
       StackMap = CSM;
     } else {
       if (mergeStackMap(CSM, StackMap))
         return make_error<InstrProfError>(
             instrprof_error::malformed,
             "memprof raw profile got different call stack for same id");
     }

     Next += Header->TotalSize;
   }

   return Error::success();
 }

 object::SectionedAddress
 RawMemProfReader::getModuleOffset(const uint64_t VirtualAddress) {
   LLVM_DEBUG({
   SegmentEntry *ContainingSegment = nullptr;
   for (auto &SE : SegmentInfo) {
     if (VirtualAddress > SE.Start && VirtualAddress <= SE.End) {
       ContainingSegment = &SE;
     }
   }

   // Ensure that the virtual address is valid.
   assert(ContainingSegment && "Could not find a segment entry");
   });

   // TODO: Compute the file offset based on the maps and program headers. For
   // now this only works for non PIE binaries.
   return object::SectionedAddress{VirtualAddress};
 }

 Error RawMemProfReader::readNextRecord(GuidMemProfRecordPair &GuidRecord) {
   if (FunctionProfileData.empty())
     return make_error<InstrProfError>(instrprof_error::empty_raw_profile);

   if (Iter == FunctionProfileData.end())
     return make_error<InstrProfError>(instrprof_error::eof);

   auto IdToFrameCallback = [this](const FrameId Id) {
     Frame F = this->idToFrame(Id);
     if (!this->KeepSymbolName)
       return F;
     auto Iter = this->GuidToSymbolName.find(F.Function);
     assert(Iter != this->GuidToSymbolName.end());
     F.SymbolName = Iter->getSecond();
     return F;
   };

   const IndexedMemProfRecord &IndexedRecord = Iter->second;
   GuidRecord = {Iter->first, MemProfRecord(IndexedRecord, IdToFrameCallback)};
   Iter++;
   return Error::success();
 }
 } // namespace memprof
 } // namespace llvm
	//===- RawMemProfReader.cpp - Instrumented memory profiling reader --------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains support for reading MemProf profiling data.
	//
	//===----------------------------------------------------------------------===//

	#include <algorithm>
	#include <cstdint>
	#include <memory>
	#include <type_traits>

	#include "llvm/ADT/ArrayRef.h"
	#include "llvm/ADT/DenseMap.h"
	#include "llvm/ADT/SetVector.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/StringExtras.h"
	#include "llvm/DebugInfo/DWARF/DWARFContext.h"
	#include "llvm/DebugInfo/Symbolize/SymbolizableModule.h"
	#include "llvm/DebugInfo/Symbolize/SymbolizableObjectFile.h"
	#include "llvm/Object/Binary.h"
	#include "llvm/Object/ELFObjectFile.h"
	#include "llvm/Object/ObjectFile.h"
	#include "llvm/ProfileData/InstrProf.h"
	#include "llvm/ProfileData/MemProf.h"
	#include "llvm/ProfileData/MemProfData.inc"
	#include "llvm/ProfileData/RawMemProfReader.h"
	#include "llvm/Support/Endian.h"
	#include "llvm/Support/Path.h"

	#define DEBUG_TYPE "memprof"

	namespace llvm {
	namespace memprof {
	namespace {
	template <class T = uint64_t> inline T alignedRead(const char *Ptr) {
	static_assert(std::is_pod<T>::value, "Not a pod type.");
	assert(reinterpret_cast<size_t>(Ptr) % sizeof(T) == 0 && "Unaligned Read");
	return reinterpret_cast<const T >(Ptr);
	}

	Error checkBuffer(const MemoryBuffer &Buffer) {
	if (!RawMemProfReader::hasFormat(Buffer))
	return make_error<InstrProfError>(instrprof_error::bad_magic);

	if (Buffer.getBufferSize() == 0)
	return make_error<InstrProfError>(instrprof_error::empty_raw_profile);

	if (Buffer.getBufferSize() < sizeof(Header)) {
	return make_error<InstrProfError>(instrprof_error::truncated);
	}

	// The size of the buffer can be > header total size since we allow repeated
	// serialization of memprof profiles to the same file.
	uint64_t TotalSize = 0;
	const char *Next = Buffer.getBufferStart();
	while (Next < Buffer.getBufferEnd()) {
	auto H = reinterpret_cast<const Header >(Next);
	if (H->Version != MEMPROF_RAW_VERSION) {
	return make_error<InstrProfError>(instrprof_error::unsupported_version);
	}

	TotalSize += H->TotalSize;
	Next += H->TotalSize;
	}

	if (Buffer.getBufferSize() != TotalSize) {
	return make_error<InstrProfError>(instrprof_error::malformed);
	}
	return Error::success();
	}

	llvm::SmallVector<SegmentEntry> readSegmentEntries(const char *Ptr) {
	using namespace support;

	const uint64_t NumItemsToRead =
	endian::readNext<uint64_t, little, unaligned>(Ptr);
	llvm::SmallVector<SegmentEntry> Items;
	for (uint64_t I = 0; I < NumItemsToRead; I++) {
	Items.push_back(reinterpret_cast<const SegmentEntry >(
	Ptr + I * sizeof(SegmentEntry)));
	}
	return Items;
	}

	llvm::SmallVector<std::pair<uint64_t, MemInfoBlock>>
	readMemInfoBlocks(const char *Ptr) {
	using namespace support;

	const uint64_t NumItemsToRead =
	endian::readNext<uint64_t, little, unaligned>(Ptr);
	llvm::SmallVector<std::pair<uint64_t, MemInfoBlock>> Items;
	for (uint64_t I = 0; I < NumItemsToRead; I++) {
	const uint64_t Id = endian::readNext<uint64_t, little, unaligned>(Ptr);
	const MemInfoBlock MIB = reinterpret_cast<const MemInfoBlock >(Ptr);
	Items.push_back({Id, MIB});
	// Only increment by size of MIB since readNext implicitly increments.
	Ptr += sizeof(MemInfoBlock);
	}
	return Items;
	}

	CallStackMap readStackInfo(const char *Ptr) {
	using namespace support;

	const uint64_t NumItemsToRead =
	endian::readNext<uint64_t, little, unaligned>(Ptr);
	CallStackMap Items;

	for (uint64_t I = 0; I < NumItemsToRead; I++) {
	const uint64_t StackId = endian::readNext<uint64_t, little, unaligned>(Ptr);
	const uint64_t NumPCs = endian::readNext<uint64_t, little, unaligned>(Ptr);

	SmallVector<uint64_t> CallStack;
	for (uint64_t J = 0; J < NumPCs; J++) {
	CallStack.push_back(endian::readNext<uint64_t, little, unaligned>(Ptr));
	}

	Items[StackId] = CallStack;
	}
	return Items;
	}

	// Merges the contents of stack information in \p From to \p To. Returns true if
	// any stack ids observed previously map to a different set of program counter
	// addresses.
	bool mergeStackMap(const CallStackMap &From, CallStackMap &To) {
	for (const auto &IdStack : From) {
	auto I = To.find(IdStack.first);
	if (I == To.end()) {
	To[IdStack.first] = IdStack.second;
	} else {
	// Check that the PCs are the same (in order).
	if (IdStack.second != I->second)
	return true;
	}
	}
	return false;
	}

	Error report(Error E, const StringRef Context) {
	return joinErrors(createStringError(inconvertibleErrorCode(), Context),
	std::move(E));
	}

	bool isRuntimePath(const StringRef Path) {
	return StringRef(llvm::sys::path::convert_to_slash(Path))
	.contains("memprof/memprof_");
	}

	std::string getBuildIdString(const SegmentEntry &Entry) {
	constexpr size_t Size = sizeof(Entry.BuildId) / sizeof(uint8_t);
	constexpr uint8_t Zeros[Size] = {0};
	// If the build id is unset print a helpful string instead of all zeros.
	if (memcmp(Entry.BuildId, Zeros, Size) == 0)
	return "<None>";

	std::string Str;
	raw_string_ostream OS(Str);
	for (size_t I = 0; I < Size; I++) {
	OS << format_hex_no_prefix(Entry.BuildId[I], 2);
	}
	return OS.str();
	}
	} // namespace

	Expected<std::unique_ptr<RawMemProfReader>>
	RawMemProfReader::create(const Twine &Path, const StringRef ProfiledBinary,
	bool KeepName) {
	auto BufferOr = MemoryBuffer::getFileOrSTDIN(Path);
	if (std::error_code EC = BufferOr.getError())
	return report(errorCodeToError(EC), Path.getSingleStringRef());

	std::unique_ptr<MemoryBuffer> Buffer(BufferOr.get().release());
	if (Error E = checkBuffer(*Buffer))
	return report(std::move(E), Path.getSingleStringRef());

	if (ProfiledBinary.empty())
	return report(
	errorCodeToError(make_error_code(std::errc::invalid_argument)),
	"Path to profiled binary is empty!");

	auto BinaryOr = llvm::object::createBinary(ProfiledBinary);
	if (!BinaryOr) {
	return report(BinaryOr.takeError(), ProfiledBinary);
	}

	// Use new here since constructor is private.
	std::unique_ptr<RawMemProfReader> Reader(
	new RawMemProfReader(std::move(BinaryOr.get()), KeepName));
	if (Error E = Reader->initialize(std::move(Buffer))) {
	return std::move(E);
	}
	return std::move(Reader);
	}

	bool RawMemProfReader::hasFormat(const StringRef Path) {
	auto BufferOr = MemoryBuffer::getFileOrSTDIN(Path);
	if (!BufferOr)
	return false;

	std::unique_ptr<MemoryBuffer> Buffer(BufferOr.get().release());
	return hasFormat(*Buffer);
	}

	bool RawMemProfReader::hasFormat(const MemoryBuffer &Buffer) {
	if (Buffer.getBufferSize() < sizeof(uint64_t))
	return false;
	// Aligned read to sanity check that the buffer was allocated with at least 8b
	// alignment.
	const uint64_t Magic = alignedRead(Buffer.getBufferStart());
	return Magic == MEMPROF_RAW_MAGIC_64;
	}

	void RawMemProfReader::printYAML(raw_ostream &OS) {
	uint64_t NumAllocFunctions = 0, NumMibInfo = 0;
	for (const auto &KV : FunctionProfileData) {
	const size_t NumAllocSites = KV.second.AllocSites.size();
	if (NumAllocSites > 0) {
	NumAllocFunctions++;
	NumMibInfo += NumAllocSites;
	}
	}

	OS << "MemprofProfile:\n";
	OS << " Summary:\n";
	OS << " Version: " << MEMPROF_RAW_VERSION << "\n";
	OS << " NumSegments: " << SegmentInfo.size() << "\n";
	OS << " NumMibInfo: " << NumMibInfo << "\n";
	OS << " NumAllocFunctions: " << NumAllocFunctions << "\n";
	OS << " NumStackOffsets: " << StackMap.size() << "\n";
	// Print out the segment information.
	OS << " Segments:\n";
	for (const auto &Entry : SegmentInfo) {
	OS << " -\n";
	OS << " BuildId: " << getBuildIdString(Entry) << "\n";
	OS << " Start: 0x" << llvm::utohexstr(Entry.Start) << "\n";
	OS << " End: 0x" << llvm::utohexstr(Entry.End) << "\n";
	OS << " Offset: 0x" << llvm::utohexstr(Entry.Offset) << "\n";
	}
	// Print out the merged contents of the profiles.
	OS << " Records:\n";
	for (const auto &Entry : *this) {
	OS << " -\n";
	OS << " FunctionGUID: " << Entry.first << "\n";
	Entry.second.print(OS);
	}
	}

	Error RawMemProfReader::initialize(std::unique_ptr<MemoryBuffer> DataBuffer) {
	const StringRef FileName = Binary.getBinary()->getFileName();

	auto *ElfObject = dyn_cast<object::ELFObjectFileBase>(Binary.getBinary());
	if (!ElfObject) {
	return report(make_error<StringError>(Twine("Not an ELF file: "),
	inconvertibleErrorCode()),
	FileName);
	}

	// Check whether the profiled binary was built with position independent code
	// (PIC). For now we provide a error message until symbolization support
	// is added for pic.
	auto* Elf64LEObject = llvm::cast<llvm::object::ELF64LEObjectFile>(ElfObject);
	const llvm::object::ELF64LEFile& ElfFile = Elf64LEObject->getELFFile();
	auto PHdrsOr = ElfFile.program_headers();
	if(!PHdrsOr)
	return report(make_error<StringError>(Twine("Could not read program headers: "),
	inconvertibleErrorCode()),
	FileName);
	auto FirstLoadHeader = PHdrsOr->begin();
	while (FirstLoadHeader->p_type != llvm::ELF::PT_LOAD)
	++FirstLoadHeader;
	if(FirstLoadHeader->p_vaddr == 0)
	return report(make_error<StringError>(Twine("Unsupported position independent code"),
	inconvertibleErrorCode()),
	FileName);

	auto Triple = ElfObject->makeTriple();
	if (!Triple.isX86())
	return report(make_error<StringError>(Twine("Unsupported target: ") +
	Triple.getArchName(),
	inconvertibleErrorCode()),
	FileName);

	auto *Object = cast<object::ObjectFile>(Binary.getBinary());
	std::unique_ptr<DIContext> Context = DWARFContext::create(
	*Object, DWARFContext::ProcessDebugRelocations::Process);

	auto SOFOr = symbolize::SymbolizableObjectFile::create(
	Object, std::move(Context), /UntagAddresses=/false);
	if (!SOFOr)
	return report(SOFOr.takeError(), FileName);
	Symbolizer = std::move(SOFOr.get());

	if (Error E = readRawProfile(std::move(DataBuffer)))
	return E;

	if (Error E = symbolizeAndFilterStackFrames())
	return E;

	return mapRawProfileToRecords();
	}

	Error RawMemProfReader::mapRawProfileToRecords() {
	// Hold a mapping from function to each callsite location we encounter within
	// it that is part of some dynamic allocation context. The location is stored
	// as a pointer to a symbolized list of inline frames.
	using LocationPtr = const llvm::SmallVector<FrameId> *;
	llvm::MapVector<GlobalValue::GUID, llvm::SetVector<LocationPtr>>
	PerFunctionCallSites;

	// Convert the raw profile callstack data into memprof records. While doing so
	// keep track of related contexts so that we can fill these in later.
	for (const auto &Entry : CallstackProfileData) {
	const uint64_t StackId = Entry.first;

	auto It = StackMap.find(StackId);
	if (It == StackMap.end())
	return make_error<InstrProfError>(
	instrprof_error::malformed,
	"memprof callstack record does not contain id: " + Twine(StackId));

	// Construct the symbolized callstack.
	llvm::SmallVector<FrameId> Callstack;
	Callstack.reserve(It->getSecond().size());

	llvm::ArrayRef<uint64_t> Addresses = It->getSecond();
	for (size_t I = 0; I < Addresses.size(); I++) {
	const uint64_t Address = Addresses[I];
	assert(SymbolizedFrame.count(Address) > 0 &&
	"Address not found in SymbolizedFrame map");
	const SmallVector<FrameId> &Frames = SymbolizedFrame[Address];

	assert(!idToFrame(Frames.back()).IsInlineFrame &&
	"The last frame should not be inlined");

	// Record the callsites for each function. Skip the first frame of the
	// first address since it is the allocation site itself that is recorded
	// as an alloc site.
	for (size_t J = 0; J < Frames.size(); J++) {
	if (I == 0 && J == 0)
	continue;
	// We attach the entire bottom-up frame here for the callsite even
	// though we only need the frames up to and including the frame for
	// Frames[J].Function. This will enable better deduplication for
	// compression in the future.
	const GlobalValue::GUID Guid = idToFrame(Frames[J]).Function;
	PerFunctionCallSites[Guid].insert(&Frames);
	}

	// Add all the frames to the current allocation callstack.
	Callstack.append(Frames.begin(), Frames.end());
	}

	// We attach the memprof record to each function bottom-up including the
	// first non-inline frame.
	for (size_t I = 0; /Break out using the condition below/; I++) {
	const Frame &F = idToFrame(Callstack[I]);
	auto Result =
	FunctionProfileData.insert({F.Function, IndexedMemProfRecord()});
	IndexedMemProfRecord &Record = Result.first->second;
	Record.AllocSites.emplace_back(Callstack, Entry.second);

	if (!F.IsInlineFrame)
	break;
	}
	}

	// Fill in the related callsites per function.
	for (const auto &[Id, Locs] : PerFunctionCallSites) {
	// Some functions may have only callsite data and no allocation data. Here
	// we insert a new entry for callsite data if we need to.
	auto Result = FunctionProfileData.insert({Id, IndexedMemProfRecord()});
	IndexedMemProfRecord &Record = Result.first->second;
	for (LocationPtr Loc : Locs) {
	Record.CallSites.push_back(*Loc);
	}
	}

	return Error::success();
	}

	Error RawMemProfReader::symbolizeAndFilterStackFrames() {
	// The specifier to use when symbolization is requested.
	const DILineInfoSpecifier Specifier(
	DILineInfoSpecifier::FileLineInfoKind::RawValue,
	DILineInfoSpecifier::FunctionNameKind::LinkageName);

	// For entries where all PCs in the callstack are discarded, we erase the
	// entry from the stack map.
	llvm::SmallVector<uint64_t> EntriesToErase;
	// We keep track of all prior discarded entries so that we can avoid invoking
	// the symbolizer for such entries.
	llvm::DenseSet<uint64_t> AllVAddrsToDiscard;
	for (auto &Entry : StackMap) {
	for (const uint64_t VAddr : Entry.getSecond()) {
	// Check if we have already symbolized and cached the result or if we
	// don't want to attempt symbolization since we know this address is bad.
	// In this case the address is also removed from the current callstack.
	if (SymbolizedFrame.count(VAddr) > 0 \|\|
	AllVAddrsToDiscard.contains(VAddr))
	continue;

	Expected<DIInliningInfo> DIOr = Symbolizer->symbolizeInlinedCode(
	getModuleOffset(VAddr), Specifier, /UseSymbolTable=/false);
	if (!DIOr)
	return DIOr.takeError();
	DIInliningInfo DI = DIOr.get();

	// Drop frames which we can't symbolize or if they belong to the runtime.
	if (DI.getFrame(0).FunctionName == DILineInfo::BadString \|\|
	isRuntimePath(DI.getFrame(0).FileName)) {
	AllVAddrsToDiscard.insert(VAddr);
	continue;
	}

	for (size_t I = 0, NumFrames = DI.getNumberOfFrames(); I < NumFrames;
	I++) {
	const auto &DIFrame = DI.getFrame(I);
	const uint64_t Guid =
	IndexedMemProfRecord::getGUID(DIFrame.FunctionName);
	const Frame F(Guid, DIFrame.Line - DIFrame.StartLine, DIFrame.Column,
	// Only the last entry is not an inlined location.
	I != NumFrames - 1);
	// Here we retain a mapping from the GUID to symbol name instead of
	// adding it to the frame object directly to reduce memory overhead.
	// This is because there can be many unique frames, particularly for
	// callsite frames.
	if (KeepSymbolName)
	GuidToSymbolName.insert({Guid, DIFrame.FunctionName});

	const FrameId Hash = F.hash();
	IdToFrame.insert({Hash, F});
	SymbolizedFrame[VAddr].push_back(Hash);
	}
	}

	auto &CallStack = Entry.getSecond();
	llvm::erase_if(CallStack, [&AllVAddrsToDiscard](const uint64_t A) {
	return AllVAddrsToDiscard.contains(A);
	});
	if (CallStack.empty())
	EntriesToErase.push_back(Entry.getFirst());
	}

	// Drop the entries where the callstack is empty.
	for (const uint64_t Id : EntriesToErase) {
	StackMap.erase(Id);
	CallstackProfileData.erase(Id);
	}

	if (StackMap.empty())
	return make_error<InstrProfError>(
	instrprof_error::malformed,
	"no entries in callstack map after symbolization");

	return Error::success();
	}

	Error RawMemProfReader::readRawProfile(
	std::unique_ptr<MemoryBuffer> DataBuffer) {
	const char *Next = DataBuffer->getBufferStart();

	while (Next < DataBuffer->getBufferEnd()) {
	auto Header = reinterpret_cast<const memprof::Header >(Next);

	// Read in the segment information, check whether its the same across all
	// profiles in this binary file.
	const llvm::SmallVector<SegmentEntry> Entries =
	readSegmentEntries(Next + Header->SegmentOffset);
	if (!SegmentInfo.empty() && SegmentInfo != Entries) {
	// We do not expect segment information to change when deserializing from
	// the same binary profile file. This can happen if dynamic libraries are
	// loaded/unloaded between profile dumping.
	return make_error<InstrProfError>(
	instrprof_error::malformed,
	"memprof raw profile has different segment information");
	}
	SegmentInfo.assign(Entries.begin(), Entries.end());

	// Read in the MemInfoBlocks. Merge them based on stack id - we assume that
	// raw profiles in the same binary file are from the same process so the
	// stackdepot ids are the same.
	for (const auto &Value : readMemInfoBlocks(Next + Header->MIBOffset)) {
	if (CallstackProfileData.count(Value.first)) {
	CallstackProfileData[Value.first].Merge(Value.second);
	} else {
	CallstackProfileData[Value.first] = Value.second;
	}
	}

	// Read in the callstack for each ids. For multiple raw profiles in the same
	// file, we expect that the callstack is the same for a unique id.
	const CallStackMap CSM = readStackInfo(Next + Header->StackOffset);
	if (StackMap.empty()) {
	StackMap = CSM;
	} else {
	if (mergeStackMap(CSM, StackMap))
	return make_error<InstrProfError>(
	instrprof_error::malformed,
	"memprof raw profile got different call stack for same id");
	}

	Next += Header->TotalSize;
	}

	return Error::success();
	}

	object::SectionedAddress
	RawMemProfReader::getModuleOffset(const uint64_t VirtualAddress) {
	LLVM_DEBUG({
	SegmentEntry *ContainingSegment = nullptr;
	for (auto &SE : SegmentInfo) {
	if (VirtualAddress > SE.Start && VirtualAddress <= SE.End) {
	ContainingSegment = &SE;
	}
	}

	// Ensure that the virtual address is valid.
	assert(ContainingSegment && "Could not find a segment entry");
	});

	// TODO: Compute the file offset based on the maps and program headers. For
	// now this only works for non PIE binaries.
	return object::SectionedAddress{VirtualAddress};
	}

	Error RawMemProfReader::readNextRecord(GuidMemProfRecordPair &GuidRecord) {
	if (FunctionProfileData.empty())
	return make_error<InstrProfError>(instrprof_error::empty_raw_profile);

	if (Iter == FunctionProfileData.end())
	return make_error<InstrProfError>(instrprof_error::eof);

	auto IdToFrameCallback = [this](const FrameId Id) {
	Frame F = this->idToFrame(Id);
	if (!this->KeepSymbolName)
	return F;
	auto Iter = this->GuidToSymbolName.find(F.Function);
	assert(Iter != this->GuidToSymbolName.end());
	F.SymbolName = Iter->getSecond();
	return F;
	};

	const IndexedMemProfRecord &IndexedRecord = Iter->second;
	GuidRecord = {Iter->first, MemProfRecord(IndexedRecord, IdToFrameCallback)};
	Iter++;
	return Error::success();
	}
	} // namespace memprof
	} // namespace llvm