lib/DebugInfo/CodeView/ContinuationRecordBuilder.cpp - llvm - Git at Google

 #include "llvm/DebugInfo/CodeView/ContinuationRecordBuilder.h"

 using namespace llvm;
 using namespace llvm::codeview;

 namespace {
 struct ContinuationRecord {
   ulittle16_t Kind{uint16_t(TypeLeafKind::LF_INDEX)};
   ulittle16_t Size{0};
   ulittle32_t IndexRef{0xB0C0B0C0};
 };

 struct SegmentInjection {
   SegmentInjection(TypeLeafKind Kind) { Prefix.RecordKind = Kind; }

   ContinuationRecord Cont;
   RecordPrefix Prefix;
 };
 } // namespace

 static void addPadding(BinaryStreamWriter &Writer) {
   uint32_t Align = Writer.getOffset() % 4;
   if (Align == 0)
     return;

   int PaddingBytes = 4 - Align;
   while (PaddingBytes > 0) {
     uint8_t Pad = static_cast<uint8_t>(LF_PAD0 + PaddingBytes);
     cantFail(Writer.writeInteger(Pad));
     --PaddingBytes;
   }
 }

 static SegmentInjection InjectFieldList(TypeLeafKind::LF_FIELDLIST);
 static SegmentInjection InjectMethodOverloadList(TypeLeafKind::LF_METHODLIST);

 static constexpr uint32_t ContinuationLength = sizeof(ContinuationRecord);
 static constexpr uint32_t MaxSegmentLength =
     MaxRecordLength - ContinuationLength;

 static inline TypeLeafKind getTypeLeafKind(ContinuationRecordKind CK) {
   return (CK == ContinuationRecordKind::FieldList) ? LF_FIELDLIST
                                                    : LF_METHODLIST;
 }

 ContinuationRecordBuilder::ContinuationRecordBuilder()
     : SegmentWriter(Buffer), Mapping(SegmentWriter) {}

 ContinuationRecordBuilder::~ContinuationRecordBuilder() {}

 void ContinuationRecordBuilder::begin(ContinuationRecordKind RecordKind) {
   assert(!Kind.hasValue());
   Kind = RecordKind;
   Buffer.clear();
   SegmentWriter.setOffset(0);
   SegmentOffsets.clear();
   SegmentOffsets.push_back(0);
   assert(SegmentWriter.getOffset() == 0);
   assert(SegmentWriter.getLength() == 0);

   const SegmentInjection *FLI =
       (RecordKind == ContinuationRecordKind::FieldList)
           ? &InjectFieldList
           : &InjectMethodOverloadList;
   const uint8_t *FLIB = reinterpret_cast<const uint8_t *>(FLI);
   InjectedSegmentBytes =
       ArrayRef<uint8_t>(FLIB, FLIB + sizeof(SegmentInjection));

   CVType Type;
   Type.Type = getTypeLeafKind(RecordKind);
   cantFail(Mapping.visitTypeBegin(Type));

   // Seed the first trecord with an appropriate record prefix.
   RecordPrefix Prefix;
   Prefix.RecordLen = 0;
   Prefix.RecordKind = Type.Type;
   cantFail(SegmentWriter.writeObject(Prefix));
 }

 template <typename RecordType>
 void ContinuationRecordBuilder::writeMemberType(RecordType &Record) {
   assert(Kind.hasValue());

   uint32_t OriginalOffset = SegmentWriter.getOffset();
   CVMemberRecord CVMR;
   CVMR.Kind = static_cast<TypeLeafKind>(Record.getKind());

   // Member Records aren't length-prefixed, they only have a 2-byte TypeLeafKind
   // at the beginning.
   cantFail(SegmentWriter.writeEnum(CVMR.Kind));

   // Let the Mapping handle the rest.
   cantFail(Mapping.visitMemberBegin(CVMR));
   cantFail(Mapping.visitKnownMember(CVMR, Record));
   cantFail(Mapping.visitMemberEnd(CVMR));

   // Make sure it's padded to 4 bytes.
   addPadding(SegmentWriter);
   assert(getCurrentSegmentLength() % 4 == 0);

   // The maximum length of a single segment is 64KB minus the size to insert a
   // continuation.  So if we are over that, inject a continuation between the
   // previous member and the member that was just written, then end the previous
   // segment after the continuation and begin a new one with the just-written
   // member.
   if (getCurrentSegmentLength() > MaxSegmentLength) {
     // We need to inject some bytes before the member we just wrote but after
     // the previous member.  Save off the length of the member we just wrote so
     // that we can do some sanity checking on it.
     uint32_t MemberLength = SegmentWriter.getOffset() - OriginalOffset;
     (void) MemberLength;
     insertSegmentEnd(OriginalOffset);
     // Since this member now becomes a new top-level record, it should have
     // gotten a RecordPrefix injected, and that RecordPrefix + the member we
     // just wrote should now constitute the entirety of the current "new"
     // segment.
     assert(getCurrentSegmentLength() == MemberLength + sizeof(RecordPrefix));
   }

   assert(getCurrentSegmentLength() % 4 == 0);
   assert(getCurrentSegmentLength() <= MaxSegmentLength);
 }

 uint32_t ContinuationRecordBuilder::getCurrentSegmentLength() const {
   return SegmentWriter.getOffset() - SegmentOffsets.back();
 }

 void ContinuationRecordBuilder::insertSegmentEnd(uint32_t Offset) {
   uint32_t SegmentBegin = SegmentOffsets.back();
   (void)SegmentBegin;
   assert(Offset > SegmentBegin);
   assert(Offset - SegmentBegin <= MaxSegmentLength);

   // We need to make space for the continuation record.  For now we can't fill
   // out the length or the TypeIndex of the back-reference, but we need the
   // space to at least be there.
   Buffer.insert(Offset, InjectedSegmentBytes);

   uint32_t NewSegmentBegin = Offset + ContinuationLength;
   uint32_t SegmentLength = NewSegmentBegin - SegmentOffsets.back();
   (void) SegmentLength;

   assert(SegmentLength % 4 == 0);
   assert(SegmentLength <= MaxRecordLength);
   SegmentOffsets.push_back(NewSegmentBegin);

   // Seek to the end so that we can keep writing against the new segment.
   SegmentWriter.setOffset(SegmentWriter.getLength());
   assert(SegmentWriter.bytesRemaining() == 0);
 }

 CVType ContinuationRecordBuilder::createSegmentRecord(
     uint32_t OffBegin, uint32_t OffEnd, Optional<TypeIndex> RefersTo) {
   assert(OffEnd - OffBegin <= USHRT_MAX);

   MutableArrayRef<uint8_t> Data = Buffer.data();
   Data = Data.slice(OffBegin, OffEnd - OffBegin);

   CVType Type;
   Type.Type = getTypeLeafKind(*Kind);
   Type.RecordData = Data;

   // Write the length to the RecordPrefix, making sure it does not include
   // sizeof(RecordPrefix.Length)
   RecordPrefix *Prefix = reinterpret_cast<RecordPrefix *>(Data.data());
   assert(Prefix->RecordKind == Type.Type);
   Prefix->RecordLen = Data.size() - sizeof(RecordPrefix::RecordLen);

   if (RefersTo.hasValue()) {
     auto Continuation = Data.take_back(ContinuationLength);
     ContinuationRecord *CR =
         reinterpret_cast<ContinuationRecord *>(Continuation.data());
     assert(CR->Kind == TypeLeafKind::LF_INDEX);
     assert(CR->IndexRef == 0xB0C0B0C0);
     CR->IndexRef = RefersTo->getIndex();
   }

   return Type;
 }

 std::vector<CVType> ContinuationRecordBuilder::end(TypeIndex Index) {
   CVType Type;
   Type.Type = getTypeLeafKind(*Kind);
   cantFail(Mapping.visitTypeEnd(Type));

   // We're now done, and we have a series of segments each beginning at an
   // offset specified in the SegmentOffsets array.  We now need to iterate
   // over each segment and post-process them in the following two ways:
   // 1) Each top-level record has a RecordPrefix whose type is either
   //    LF_FIELDLIST or LF_METHODLIST, but the Length field is still 0.
   //    Those should all be set to the correct length now.
   // 2) Each continuation record has an IndexRef field which we set to the
   //    magic value 0xB0C0B0C0.  Now that the caller has told us the TypeIndex
   //    they want this sequence to start from, we can go through and update
   //    each one.
   //
   // Logically, the sequence of records we've built up looks like this:
   //
   // SegmentOffsets[0]:   <Length>                    (Initially: uninitialized)
   // SegmentOffsets[0]+2: LF_FIELDLIST
   // SegmentOffsets[0]+4: Member[0]
   // SegmentOffsets[0]+?: ...
   // SegmentOffsets[0]+?: Member[4]
   // SegmentOffsets[1]-8: LF_INDEX
   // SegmentOffsets[1]-6: 0
   // SegmentOffsets[1]-4: <Type Index of Next Record> (Initially: 0xB0C0B0C0)
   //
   // SegmentOffsets[1]:   <Length>                    (Initially: uninitialized)
   // SegmentOffsets[1]+2: LF_FIELDLIST
   // SegmentOffsets[1]+4: Member[0]
   // SegmentOffsets[1]+?: ...
   // SegmentOffsets[1]+?: Member[s]
   // SegmentOffsets[2]-8: LF_INDEX
   // SegmentOffsets[2]-6: 0
   // SegmentOffsets[2]-4: <Type Index of Next Record> (Initially: 0xB0C0B0C0)
   //
   // ...
   //
   // SegmentOffsets[N]:   <Length>                    (Initially: uninitialized)
   // SegmentOffsets[N]+2: LF_FIELDLIST
   // SegmentOffsets[N]+4: Member[0]
   // SegmentOffsets[N]+?: ...
   // SegmentOffsets[N]+?: Member[t]
   //
   // And this is the way we have laid them out in the serialization buffer.  But
   // we cannot actually commit them to the underlying stream this way, due to
   // the topological sorting requirement of a type stream (specifically,
   // TypeIndex references can only point backwards, not forwards).  So the
   // sequence that we return to the caller contains the records in reverse
   // order, which is the proper order for committing the serialized records.

   std::vector<CVType> Types;
   Types.reserve(SegmentOffsets.size());

   auto SO = makeArrayRef(SegmentOffsets);

   uint32_t End = SegmentWriter.getOffset();

   Optional<TypeIndex> RefersTo;
   for (uint32_t Offset : reverse(SO)) {
     Types.push_back(createSegmentRecord(Offset, End, RefersTo));

     End = Offset;
     RefersTo = Index++;
   }

   Kind.reset();
   return Types;
 }

 // Explicitly instantiate the member function for each known type so that we can
 // implement this in the cpp file.
 #define TYPE_RECORD(EnumName, EnumVal, Name)
 #define TYPE_RECORD_ALIAS(EnumName, EnumVal, Name, AliasName)
 #define MEMBER_RECORD(EnumName, EnumVal, Name)                                 \
   template void llvm::codeview::ContinuationRecordBuilder::writeMemberType(    \
       Name##Record &Record);
 #define MEMBER_RECORD_ALIAS(EnumName, EnumVal, Name, AliasName)
 #include "llvm/DebugInfo/CodeView/CodeViewTypes.def"
	#include "llvm/DebugInfo/CodeView/ContinuationRecordBuilder.h"

	using namespace llvm;
	using namespace llvm::codeview;

	namespace {
	struct ContinuationRecord {
	ulittle16_t Kind{uint16_t(TypeLeafKind::LF_INDEX)};
	ulittle16_t Size{0};
	ulittle32_t IndexRef{0xB0C0B0C0};
	};

	struct SegmentInjection {
	SegmentInjection(TypeLeafKind Kind) { Prefix.RecordKind = Kind; }

	ContinuationRecord Cont;
	RecordPrefix Prefix;
	};
	} // namespace

	static void addPadding(BinaryStreamWriter &Writer) {
	uint32_t Align = Writer.getOffset() % 4;
	if (Align == 0)
	return;

	int PaddingBytes = 4 - Align;
	while (PaddingBytes > 0) {
	uint8_t Pad = static_cast<uint8_t>(LF_PAD0 + PaddingBytes);
	cantFail(Writer.writeInteger(Pad));
	--PaddingBytes;
	}
	}

	static SegmentInjection InjectFieldList(TypeLeafKind::LF_FIELDLIST);
	static SegmentInjection InjectMethodOverloadList(TypeLeafKind::LF_METHODLIST);

	static constexpr uint32_t ContinuationLength = sizeof(ContinuationRecord);
	static constexpr uint32_t MaxSegmentLength =
	MaxRecordLength - ContinuationLength;

	static inline TypeLeafKind getTypeLeafKind(ContinuationRecordKind CK) {
	return (CK == ContinuationRecordKind::FieldList) ? LF_FIELDLIST
	: LF_METHODLIST;
	}

	ContinuationRecordBuilder::ContinuationRecordBuilder()
	: SegmentWriter(Buffer), Mapping(SegmentWriter) {}

	ContinuationRecordBuilder::~ContinuationRecordBuilder() {}

	void ContinuationRecordBuilder::begin(ContinuationRecordKind RecordKind) {
	assert(!Kind.hasValue());
	Kind = RecordKind;
	Buffer.clear();
	SegmentWriter.setOffset(0);
	SegmentOffsets.clear();
	SegmentOffsets.push_back(0);
	assert(SegmentWriter.getOffset() == 0);
	assert(SegmentWriter.getLength() == 0);

	const SegmentInjection *FLI =
	(RecordKind == ContinuationRecordKind::FieldList)
	? &InjectFieldList
	: &InjectMethodOverloadList;
	const uint8_t FLIB = reinterpret_cast<const uint8_t >(FLI);
	InjectedSegmentBytes =
	ArrayRef<uint8_t>(FLIB, FLIB + sizeof(SegmentInjection));

	CVType Type;
	Type.Type = getTypeLeafKind(RecordKind);
	cantFail(Mapping.visitTypeBegin(Type));

	// Seed the first trecord with an appropriate record prefix.
	RecordPrefix Prefix;
	Prefix.RecordLen = 0;
	Prefix.RecordKind = Type.Type;
	cantFail(SegmentWriter.writeObject(Prefix));
	}

	template <typename RecordType>
	void ContinuationRecordBuilder::writeMemberType(RecordType &Record) {
	assert(Kind.hasValue());

	uint32_t OriginalOffset = SegmentWriter.getOffset();
	CVMemberRecord CVMR;
	CVMR.Kind = static_cast<TypeLeafKind>(Record.getKind());

	// Member Records aren't length-prefixed, they only have a 2-byte TypeLeafKind
	// at the beginning.
	cantFail(SegmentWriter.writeEnum(CVMR.Kind));

	// Let the Mapping handle the rest.
	cantFail(Mapping.visitMemberBegin(CVMR));
	cantFail(Mapping.visitKnownMember(CVMR, Record));
	cantFail(Mapping.visitMemberEnd(CVMR));

	// Make sure it's padded to 4 bytes.
	addPadding(SegmentWriter);
	assert(getCurrentSegmentLength() % 4 == 0);

	// The maximum length of a single segment is 64KB minus the size to insert a
	// continuation. So if we are over that, inject a continuation between the
	// previous member and the member that was just written, then end the previous
	// segment after the continuation and begin a new one with the just-written
	// member.
	if (getCurrentSegmentLength() > MaxSegmentLength) {
	// We need to inject some bytes before the member we just wrote but after
	// the previous member. Save off the length of the member we just wrote so
	// that we can do some sanity checking on it.
	uint32_t MemberLength = SegmentWriter.getOffset() - OriginalOffset;
	(void) MemberLength;
	insertSegmentEnd(OriginalOffset);
	// Since this member now becomes a new top-level record, it should have
	// gotten a RecordPrefix injected, and that RecordPrefix + the member we
	// just wrote should now constitute the entirety of the current "new"
	// segment.
	assert(getCurrentSegmentLength() == MemberLength + sizeof(RecordPrefix));
	}

	assert(getCurrentSegmentLength() % 4 == 0);
	assert(getCurrentSegmentLength() <= MaxSegmentLength);
	}

	uint32_t ContinuationRecordBuilder::getCurrentSegmentLength() const {
	return SegmentWriter.getOffset() - SegmentOffsets.back();
	}

	void ContinuationRecordBuilder::insertSegmentEnd(uint32_t Offset) {
	uint32_t SegmentBegin = SegmentOffsets.back();
	(void)SegmentBegin;
	assert(Offset > SegmentBegin);
	assert(Offset - SegmentBegin <= MaxSegmentLength);

	// We need to make space for the continuation record. For now we can't fill
	// out the length or the TypeIndex of the back-reference, but we need the
	// space to at least be there.
	Buffer.insert(Offset, InjectedSegmentBytes);

	uint32_t NewSegmentBegin = Offset + ContinuationLength;
	uint32_t SegmentLength = NewSegmentBegin - SegmentOffsets.back();
	(void) SegmentLength;

	assert(SegmentLength % 4 == 0);
	assert(SegmentLength <= MaxRecordLength);
	SegmentOffsets.push_back(NewSegmentBegin);

	// Seek to the end so that we can keep writing against the new segment.
	SegmentWriter.setOffset(SegmentWriter.getLength());
	assert(SegmentWriter.bytesRemaining() == 0);
	}

	CVType ContinuationRecordBuilder::createSegmentRecord(
	uint32_t OffBegin, uint32_t OffEnd, Optional<TypeIndex> RefersTo) {
	assert(OffEnd - OffBegin <= USHRT_MAX);

	MutableArrayRef<uint8_t> Data = Buffer.data();
	Data = Data.slice(OffBegin, OffEnd - OffBegin);

	CVType Type;
	Type.Type = getTypeLeafKind(*Kind);
	Type.RecordData = Data;

	// Write the length to the RecordPrefix, making sure it does not include
	// sizeof(RecordPrefix.Length)
	RecordPrefix Prefix = reinterpret_cast<RecordPrefix >(Data.data());
	assert(Prefix->RecordKind == Type.Type);
	Prefix->RecordLen = Data.size() - sizeof(RecordPrefix::RecordLen);

	if (RefersTo.hasValue()) {
	auto Continuation = Data.take_back(ContinuationLength);
	ContinuationRecord *CR =
	reinterpret_cast<ContinuationRecord *>(Continuation.data());
	assert(CR->Kind == TypeLeafKind::LF_INDEX);
	assert(CR->IndexRef == 0xB0C0B0C0);
	CR->IndexRef = RefersTo->getIndex();
	}

	return Type;
	}

	std::vector<CVType> ContinuationRecordBuilder::end(TypeIndex Index) {
	CVType Type;
	Type.Type = getTypeLeafKind(*Kind);
	cantFail(Mapping.visitTypeEnd(Type));

	// We're now done, and we have a series of segments each beginning at an
	// offset specified in the SegmentOffsets array. We now need to iterate
	// over each segment and post-process them in the following two ways:
	// 1) Each top-level record has a RecordPrefix whose type is either
	// LF_FIELDLIST or LF_METHODLIST, but the Length field is still 0.
	// Those should all be set to the correct length now.
	// 2) Each continuation record has an IndexRef field which we set to the
	// magic value 0xB0C0B0C0. Now that the caller has told us the TypeIndex
	// they want this sequence to start from, we can go through and update
	// each one.
	//
	// Logically, the sequence of records we've built up looks like this:
	//
	// SegmentOffsets[0]: <Length> (Initially: uninitialized)
	// SegmentOffsets[0]+2: LF_FIELDLIST
	// SegmentOffsets[0]+4: Member[0]
	// SegmentOffsets[0]+?: ...
	// SegmentOffsets[0]+?: Member[4]
	// SegmentOffsets[1]-8: LF_INDEX
	// SegmentOffsets[1]-6: 0
	// SegmentOffsets[1]-4: <Type Index of Next Record> (Initially: 0xB0C0B0C0)
	//
	// SegmentOffsets[1]: <Length> (Initially: uninitialized)
	// SegmentOffsets[1]+2: LF_FIELDLIST
	// SegmentOffsets[1]+4: Member[0]
	// SegmentOffsets[1]+?: ...
	// SegmentOffsets[1]+?: Member[s]
	// SegmentOffsets[2]-8: LF_INDEX
	// SegmentOffsets[2]-6: 0
	// SegmentOffsets[2]-4: <Type Index of Next Record> (Initially: 0xB0C0B0C0)
	//
	// ...
	//
	// SegmentOffsets[N]: <Length> (Initially: uninitialized)
	// SegmentOffsets[N]+2: LF_FIELDLIST
	// SegmentOffsets[N]+4: Member[0]
	// SegmentOffsets[N]+?: ...
	// SegmentOffsets[N]+?: Member[t]
	//
	// And this is the way we have laid them out in the serialization buffer. But
	// we cannot actually commit them to the underlying stream this way, due to
	// the topological sorting requirement of a type stream (specifically,
	// TypeIndex references can only point backwards, not forwards). So the
	// sequence that we return to the caller contains the records in reverse
	// order, which is the proper order for committing the serialized records.

	std::vector<CVType> Types;
	Types.reserve(SegmentOffsets.size());

	auto SO = makeArrayRef(SegmentOffsets);

	uint32_t End = SegmentWriter.getOffset();

	Optional<TypeIndex> RefersTo;
	for (uint32_t Offset : reverse(SO)) {
	Types.push_back(createSegmentRecord(Offset, End, RefersTo));

	End = Offset;
	RefersTo = Index++;
	}

	Kind.reset();
	return Types;
	}

	// Explicitly instantiate the member function for each known type so that we can
	// implement this in the cpp file.
	#define TYPE_RECORD(EnumName, EnumVal, Name)
	#define TYPE_RECORD_ALIAS(EnumName, EnumVal, Name, AliasName)
	#define MEMBER_RECORD(EnumName, EnumVal, Name) \
	template void llvm::codeview::ContinuationRecordBuilder::writeMemberType( \
	Name##Record &Record);
	#define MEMBER_RECORD_ALIAS(EnumName, EnumVal, Name, AliasName)
	#include "llvm/DebugInfo/CodeView/CodeViewTypes.def"