compiler-rt/lib/memprof/memprof_rawprofile.cpp - llvm-project - Git at Google

 #include <stdint.h>
 #include <stdlib.h>
 #include <string.h>

 #include "memprof_meminfoblock.h"
 #include "memprof_rawprofile.h"
 #include "profile/MemProfData.inc"
 #include "sanitizer_common/sanitizer_allocator_internal.h"
 #include "sanitizer_common/sanitizer_linux.h"
 #include "sanitizer_common/sanitizer_procmaps.h"
 #include "sanitizer_common/sanitizer_stackdepot.h"
 #include "sanitizer_common/sanitizer_stackdepotbase.h"
 #include "sanitizer_common/sanitizer_stacktrace.h"
 #include "sanitizer_common/sanitizer_vector.h"

 namespace __memprof {
 using ::__sanitizer::Vector;
 using SegmentEntry = ::llvm::memprof::SegmentEntry;
 using Header = ::llvm::memprof::Header;

 namespace {
 template <class T> char *WriteBytes(T Pod, char *&Buffer) {
   *(T *)Buffer = Pod;
   return Buffer + sizeof(T);
 }

 void RecordStackId(const uptr Key, UNUSED LockedMemInfoBlock *const &MIB,
                    void *Arg) {
   // No need to touch the MIB value here since we are only recording the key.
   auto *StackIds = reinterpret_cast<Vector<u64> *>(Arg);
   StackIds->PushBack(Key);
 }
 } // namespace

 u64 SegmentSizeBytes(MemoryMappingLayoutBase &Layout) {
   u64 NumSegmentsToRecord = 0;
   MemoryMappedSegment segment;
   for (Layout.Reset(); Layout.Next(&segment);)
     if (segment.IsReadable() && segment.IsExecutable())
       NumSegmentsToRecord++;

   return sizeof(u64) // A header which stores the number of records.
          + sizeof(SegmentEntry) * NumSegmentsToRecord;
 }

 // The segment section uses the following format:
 // ---------- Segment Info
 // Num Entries
 // ---------- Segment Entry
 // Start
 // End
 // Offset
 // BuildID 32B
 // ----------
 // ...
 void SerializeSegmentsToBuffer(MemoryMappingLayoutBase &Layout,
                                const u64 ExpectedNumBytes, char *&Buffer) {
   char *Ptr = Buffer;
   // Reserve space for the final count.
   Ptr += sizeof(u64);

   u64 NumSegmentsRecorded = 0;
   MemoryMappedSegment segment;

   for (Layout.Reset(); Layout.Next(&segment);) {
     if (segment.IsReadable() && segment.IsExecutable()) {
       SegmentEntry Entry{};
       Entry.Start = segment.start;
       Entry.End = segment.end;
       Entry.Offset = segment.offset;
       memcpy(Entry.BuildId, segment.uuid, sizeof(segment.uuid));
       memcpy(Ptr, &Entry, sizeof(SegmentEntry));
       Ptr += sizeof(SegmentEntry);
       NumSegmentsRecorded++;
     }
   }

   // Store the number of segments we recorded in the space we reserved.
   *((u64 *)Buffer) = NumSegmentsRecorded;
   CHECK(ExpectedNumBytes == static_cast<u64>(Ptr - Buffer) &&
         "Expected num bytes != actual bytes written");
 }

 u64 StackSizeBytes(const Vector<u64> &StackIds) {
   u64 NumBytesToWrite = sizeof(u64);

   const u64 NumIds = StackIds.Size();
   for (unsigned k = 0; k < NumIds; ++k) {
     const u64 Id = StackIds[k];
     // One entry for the id and then one more for the number of stack pcs.
     NumBytesToWrite += 2 * sizeof(u64);
     const StackTrace St = StackDepotGet(Id);

     CHECK(St.trace != nullptr && St.size > 0 && "Empty stack trace");
     for (uptr i = 0; i < St.size && St.trace[i] != 0; i++) {
       NumBytesToWrite += sizeof(u64);
     }
   }
   return NumBytesToWrite;
 }

 // The stack info section uses the following format:
 //
 // ---------- Stack Info
 // Num Entries
 // ---------- Stack Entry
 // Num Stacks
 // PC1
 // PC2
 // ...
 // ----------
 void SerializeStackToBuffer(const Vector<u64> &StackIds,
                             const u64 ExpectedNumBytes, char *&Buffer) {
   const u64 NumIds = StackIds.Size();
   char *Ptr = Buffer;
   Ptr = WriteBytes(static_cast<u64>(NumIds), Ptr);

   for (unsigned k = 0; k < NumIds; ++k) {
     const u64 Id = StackIds[k];
     Ptr = WriteBytes(Id, Ptr);
     Ptr += sizeof(u64); // Bump it by u64, we will fill this in later.
     u64 Count = 0;
     const StackTrace St = StackDepotGet(Id);
     for (uptr i = 0; i < St.size && St.trace[i] != 0; i++) {
       // PCs in stack traces are actually the return addresses, that is,
       // addresses of the next instructions after the call.
       uptr pc = StackTrace::GetPreviousInstructionPc(St.trace[i]);
       Ptr = WriteBytes(static_cast<u64>(pc), Ptr);
       ++Count;
     }
     // Store the count in the space we reserved earlier.
     *(u64 *)(Ptr - (Count + 1) * sizeof(u64)) = Count;
   }

   CHECK(ExpectedNumBytes == static_cast<u64>(Ptr - Buffer) &&
         "Expected num bytes != actual bytes written");
 }

 // The MIB section has the following format:
 // ---------- MIB Info
 // Num Entries
 // ---------- MIB Entry 0
 // Alloc Count
 // ...
 // ---------- MIB Entry 1
 // Alloc Count
 // ...
 // ----------
 void SerializeMIBInfoToBuffer(MIBMapTy &MIBMap, const Vector<u64> &StackIds,
                               const u64 ExpectedNumBytes, char *&Buffer) {
   char *Ptr = Buffer;
   const u64 NumEntries = StackIds.Size();
   Ptr = WriteBytes(NumEntries, Ptr);

   for (u64 i = 0; i < NumEntries; i++) {
     const u64 Key = StackIds[i];
     MIBMapTy::Handle h(&MIBMap, Key, /*remove=*/true, /*create=*/false);
     CHECK(h.exists());
     Ptr = WriteBytes(Key, Ptr);
     Ptr = WriteBytes((*h)->mib, Ptr);
   }

   CHECK(ExpectedNumBytes == static_cast<u64>(Ptr - Buffer) &&
         "Expected num bytes != actual bytes written");
 }

 // Format
 // ---------- Header
 // Magic
 // Version
 // Total Size
 // Segment Offset
 // MIB Info Offset
 // Stack Offset
 // ---------- Segment Info
 // Num Entries
 // ---------- Segment Entry
 // Start
 // End
 // Offset
 // BuildID 32B
 // ----------
 // ...
 // ---------- MIB Info
 // Num Entries
 // ---------- MIB Entry
 // Alloc Count
 // ...
 // ---------- Stack Info
 // Num Entries
 // ---------- Stack Entry
 // Num Stacks
 // PC1
 // PC2
 // ...
 // ----------
 // ...
 u64 SerializeToRawProfile(MIBMapTy &MIBMap, MemoryMappingLayoutBase &Layout,
                           char *&Buffer) {
   const u64 NumSegmentBytes = SegmentSizeBytes(Layout);

   Vector<u64> StackIds;
   MIBMap.ForEach(RecordStackId, reinterpret_cast<void *>(&StackIds));
   // The first 8b are for the total number of MIB records. Each MIB record is
   // preceded by a 8b stack id which is associated with stack frames in the next
   // section.
   const u64 NumMIBInfoBytes =
       sizeof(u64) + StackIds.Size() * (sizeof(u64) + sizeof(MemInfoBlock));

   const u64 NumStackBytes = StackSizeBytes(StackIds);

   const u64 TotalSizeBytes =
       sizeof(Header) + NumSegmentBytes + NumStackBytes + NumMIBInfoBytes;

   // Allocate the memory for the entire buffer incl. info blocks.
   Buffer = (char *)InternalAlloc(TotalSizeBytes);
   char *Ptr = Buffer;

   Header header{MEMPROF_RAW_MAGIC_64,
                 MEMPROF_RAW_VERSION,
                 static_cast<u64>(TotalSizeBytes),
                 sizeof(Header),
                 sizeof(Header) + NumSegmentBytes,
                 sizeof(Header) + NumSegmentBytes + NumMIBInfoBytes};
   Ptr = WriteBytes(header, Ptr);

   SerializeSegmentsToBuffer(Layout, NumSegmentBytes, Ptr);
   Ptr += NumSegmentBytes;

   SerializeMIBInfoToBuffer(MIBMap, StackIds, NumMIBInfoBytes, Ptr);
   Ptr += NumMIBInfoBytes;

   SerializeStackToBuffer(StackIds, NumStackBytes, Ptr);

   return TotalSizeBytes;
 }

 } // namespace __memprof
	#include <stdint.h>
	#include <stdlib.h>
	#include <string.h>

	#include "memprof_meminfoblock.h"
	#include "memprof_rawprofile.h"
	#include "profile/MemProfData.inc"
	#include "sanitizer_common/sanitizer_allocator_internal.h"
	#include "sanitizer_common/sanitizer_linux.h"
	#include "sanitizer_common/sanitizer_procmaps.h"
	#include "sanitizer_common/sanitizer_stackdepot.h"
	#include "sanitizer_common/sanitizer_stackdepotbase.h"
	#include "sanitizer_common/sanitizer_stacktrace.h"
	#include "sanitizer_common/sanitizer_vector.h"

	namespace __memprof {
	using ::__sanitizer::Vector;
	using SegmentEntry = ::llvm::memprof::SegmentEntry;
	using Header = ::llvm::memprof::Header;

	namespace {
	template <class T> char WriteBytes(T Pod, char &Buffer) {
	(T )Buffer = Pod;
	return Buffer + sizeof(T);
	}

	void RecordStackId(const uptr Key, UNUSED LockedMemInfoBlock *const &MIB,
	void *Arg) {
	// No need to touch the MIB value here since we are only recording the key.
	auto StackIds = reinterpret_cast<Vector<u64> >(Arg);
	StackIds->PushBack(Key);
	}
	} // namespace

	u64 SegmentSizeBytes(MemoryMappingLayoutBase &Layout) {
	u64 NumSegmentsToRecord = 0;
	MemoryMappedSegment segment;
	for (Layout.Reset(); Layout.Next(&segment);)
	if (segment.IsReadable() && segment.IsExecutable())
	NumSegmentsToRecord++;

	return sizeof(u64) // A header which stores the number of records.
	+ sizeof(SegmentEntry) * NumSegmentsToRecord;
	}

	// The segment section uses the following format:
	// ---------- Segment Info
	// Num Entries
	// ---------- Segment Entry
	// Start
	// End
	// Offset
	// BuildID 32B
	// ----------
	// ...
	void SerializeSegmentsToBuffer(MemoryMappingLayoutBase &Layout,
	const u64 ExpectedNumBytes, char *&Buffer) {
	char *Ptr = Buffer;
	// Reserve space for the final count.
	Ptr += sizeof(u64);

	u64 NumSegmentsRecorded = 0;
	MemoryMappedSegment segment;

	for (Layout.Reset(); Layout.Next(&segment);) {
	if (segment.IsReadable() && segment.IsExecutable()) {
	SegmentEntry Entry{};
	Entry.Start = segment.start;
	Entry.End = segment.end;
	Entry.Offset = segment.offset;
	memcpy(Entry.BuildId, segment.uuid, sizeof(segment.uuid));
	memcpy(Ptr, &Entry, sizeof(SegmentEntry));
	Ptr += sizeof(SegmentEntry);
	NumSegmentsRecorded++;
	}
	}

	// Store the number of segments we recorded in the space we reserved.
	((u64 )Buffer) = NumSegmentsRecorded;
	CHECK(ExpectedNumBytes == static_cast<u64>(Ptr - Buffer) &&
	"Expected num bytes != actual bytes written");
	}

	u64 StackSizeBytes(const Vector<u64> &StackIds) {
	u64 NumBytesToWrite = sizeof(u64);

	const u64 NumIds = StackIds.Size();
	for (unsigned k = 0; k < NumIds; ++k) {
	const u64 Id = StackIds[k];
	// One entry for the id and then one more for the number of stack pcs.
	NumBytesToWrite += 2 * sizeof(u64);
	const StackTrace St = StackDepotGet(Id);

	CHECK(St.trace != nullptr && St.size > 0 && "Empty stack trace");
	for (uptr i = 0; i < St.size && St.trace[i] != 0; i++) {
	NumBytesToWrite += sizeof(u64);
	}
	}
	return NumBytesToWrite;
	}

	// The stack info section uses the following format:
	//
	// ---------- Stack Info
	// Num Entries
	// ---------- Stack Entry
	// Num Stacks
	// PC1
	// PC2
	// ...
	// ----------
	void SerializeStackToBuffer(const Vector<u64> &StackIds,
	const u64 ExpectedNumBytes, char *&Buffer) {
	const u64 NumIds = StackIds.Size();
	char *Ptr = Buffer;
	Ptr = WriteBytes(static_cast<u64>(NumIds), Ptr);

	for (unsigned k = 0; k < NumIds; ++k) {
	const u64 Id = StackIds[k];
	Ptr = WriteBytes(Id, Ptr);
	Ptr += sizeof(u64); // Bump it by u64, we will fill this in later.
	u64 Count = 0;
	const StackTrace St = StackDepotGet(Id);
	for (uptr i = 0; i < St.size && St.trace[i] != 0; i++) {
	// PCs in stack traces are actually the return addresses, that is,
	// addresses of the next instructions after the call.
	uptr pc = StackTrace::GetPreviousInstructionPc(St.trace[i]);
	Ptr = WriteBytes(static_cast<u64>(pc), Ptr);
	++Count;
	}
	// Store the count in the space we reserved earlier.
	(u64 )(Ptr - (Count + 1) * sizeof(u64)) = Count;
	}

	CHECK(ExpectedNumBytes == static_cast<u64>(Ptr - Buffer) &&
	"Expected num bytes != actual bytes written");
	}

	// The MIB section has the following format:
	// ---------- MIB Info
	// Num Entries
	// ---------- MIB Entry 0
	// Alloc Count
	// ...
	// ---------- MIB Entry 1
	// Alloc Count
	// ...
	// ----------
	void SerializeMIBInfoToBuffer(MIBMapTy &MIBMap, const Vector<u64> &StackIds,
	const u64 ExpectedNumBytes, char *&Buffer) {
	char *Ptr = Buffer;
	const u64 NumEntries = StackIds.Size();
	Ptr = WriteBytes(NumEntries, Ptr);

	for (u64 i = 0; i < NumEntries; i++) {
	const u64 Key = StackIds[i];
	MIBMapTy::Handle h(&MIBMap, Key, /remove=/true, /create=/false);
	CHECK(h.exists());
	Ptr = WriteBytes(Key, Ptr);
	Ptr = WriteBytes((*h)->mib, Ptr);
	}

	CHECK(ExpectedNumBytes == static_cast<u64>(Ptr - Buffer) &&
	"Expected num bytes != actual bytes written");
	}

	// Format
	// ---------- Header
	// Magic
	// Version
	// Total Size
	// Segment Offset
	// MIB Info Offset
	// Stack Offset
	// ---------- Segment Info
	// Num Entries
	// ---------- Segment Entry
	// Start
	// End
	// Offset
	// BuildID 32B
	// ----------
	// ...
	// ---------- MIB Info
	// Num Entries
	// ---------- MIB Entry
	// Alloc Count
	// ...
	// ---------- Stack Info
	// Num Entries
	// ---------- Stack Entry
	// Num Stacks
	// PC1
	// PC2
	// ...
	// ----------
	// ...
	u64 SerializeToRawProfile(MIBMapTy &MIBMap, MemoryMappingLayoutBase &Layout,
	char *&Buffer) {
	const u64 NumSegmentBytes = SegmentSizeBytes(Layout);

	Vector<u64> StackIds;
	MIBMap.ForEach(RecordStackId, reinterpret_cast<void *>(&StackIds));
	// The first 8b are for the total number of MIB records. Each MIB record is
	// preceded by a 8b stack id which is associated with stack frames in the next
	// section.
	const u64 NumMIBInfoBytes =
	sizeof(u64) + StackIds.Size() * (sizeof(u64) + sizeof(MemInfoBlock));

	const u64 NumStackBytes = StackSizeBytes(StackIds);

	const u64 TotalSizeBytes =
	sizeof(Header) + NumSegmentBytes + NumStackBytes + NumMIBInfoBytes;

	// Allocate the memory for the entire buffer incl. info blocks.
	Buffer = (char *)InternalAlloc(TotalSizeBytes);
	char *Ptr = Buffer;

	Header header{MEMPROF_RAW_MAGIC_64,
	MEMPROF_RAW_VERSION,
	static_cast<u64>(TotalSizeBytes),
	sizeof(Header),
	sizeof(Header) + NumSegmentBytes,
	sizeof(Header) + NumSegmentBytes + NumMIBInfoBytes};
	Ptr = WriteBytes(header, Ptr);

	SerializeSegmentsToBuffer(Layout, NumSegmentBytes, Ptr);
	Ptr += NumSegmentBytes;

	SerializeMIBInfoToBuffer(MIBMap, StackIds, NumMIBInfoBytes, Ptr);
	Ptr += NumMIBInfoBytes;

	SerializeStackToBuffer(StackIds, NumStackBytes, Ptr);

	return TotalSizeBytes;
	}

	} // namespace __memprof