lib/Bitcode/Reader/Deserialize.cpp - llvm - Git at Google

 //==- Deserialize.cpp - Generic Object Serialization to Bitcode --*- C++ -*-==//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines the internal methods used for object serialization.
 //
 //===----------------------------------------------------------------------===//

 #include "llvm/Bitcode/Deserialize.h"

 #ifdef DEBUG_BACKPATCH
 #include "llvm/Support/Streams.h"
 #endif

 using namespace llvm;

 Deserializer::Deserializer(BitstreamReader& stream)
   : Stream(stream), RecIdx(0), FreeList(NULL), AbbrevNo(0), RecordCode(0) {

   StreamStart = Stream.GetCurrentBitNo();
 }

 Deserializer::~Deserializer() {
   assert (RecIdx >= Record.size() &&
           "Still scanning bitcode record when deserialization completed.");

 #ifdef DEBUG_BACKPATCH
   for (MapTy::iterator I=BPatchMap.begin(), E=BPatchMap.end(); I!=E; ++I)
     assert (I->first.hasFinalPtr() &&
             "Some pointers were not backpatched.");
 #endif
 }


 bool Deserializer::inRecord() {
   if (Record.size() > 0) {
     if (RecIdx >= Record.size()) {
       RecIdx = 0;
       Record.clear();
       AbbrevNo = 0;
       return false;
     }
     else
       return true;
   }

   return false;
 }

 bool Deserializer::AdvanceStream() {
   assert (!inRecord() &&
           "Cannot advance stream.  Still processing a record.");

   if (AbbrevNo == bitc::ENTER_SUBBLOCK ||
       AbbrevNo >= bitc::UNABBREV_RECORD)
     return true;

   while (!Stream.AtEndOfStream()) {

     uint64_t Pos = Stream.GetCurrentBitNo();
     AbbrevNo = Stream.ReadCode();

     switch (AbbrevNo) {
       case bitc::ENTER_SUBBLOCK: {
         unsigned id = Stream.ReadSubBlockID();

         // Determine the extent of the block.  This is useful for jumping around
         // the stream.  This is hack: we read the header of the block, save
         // the length, and then revert the bitstream to a location just before
         // the block is entered.
         uint64_t BPos = Stream.GetCurrentBitNo();
         Stream.ReadVBR(bitc::CodeLenWidth); // Skip the code size.
         Stream.SkipToWord();
         unsigned NumWords = Stream.Read(bitc::BlockSizeWidth);
         Stream.JumpToBit(BPos);

         BlockStack.push_back(Location(Pos,id,NumWords));
         break;
       }

       case bitc::END_BLOCK: {
         bool x = Stream.ReadBlockEnd();
         assert(!x && "Error at block end."); x=x;
         BlockStack.pop_back();
         continue;
       }

       case bitc::DEFINE_ABBREV:
         Stream.ReadAbbrevRecord();
         continue;

       default:
         break;
     }

     return true;
   }

   return false;
 }

 void Deserializer::ReadRecord() {

   while (AdvanceStream() && AbbrevNo == bitc::ENTER_SUBBLOCK) {
     assert (!BlockStack.empty());
     Stream.EnterSubBlock(BlockStack.back().BlockID);
     AbbrevNo = 0;
   }

   if (Stream.AtEndOfStream())
     return;

   assert (Record.empty());
   assert (AbbrevNo >= bitc::UNABBREV_RECORD);
   RecordCode = Stream.ReadRecord(AbbrevNo,Record);
   assert (Record.size() > 0);
 }

 void Deserializer::SkipBlock() {
   assert (!inRecord());

   if (AtEnd())
     return;

   AdvanceStream();

   assert (AbbrevNo == bitc::ENTER_SUBBLOCK);
   BlockStack.pop_back();
   Stream.SkipBlock();

   AbbrevNo = 0;
   AdvanceStream();
 }

 bool Deserializer::SkipToBlock(unsigned BlockID) {
   assert (!inRecord());

   AdvanceStream();
   assert (AbbrevNo == bitc::ENTER_SUBBLOCK);

   unsigned BlockLevel = BlockStack.size();

   while (!AtEnd() &&
          BlockLevel == BlockStack.size() &&
          getCurrentBlockID() != BlockID)
     SkipBlock();

   return !(AtEnd() || BlockLevel != BlockStack.size());
 }

 Deserializer::Location Deserializer::getCurrentBlockLocation() {
   if (!inRecord())
     AdvanceStream();

   return BlockStack.back();
 }

 bool Deserializer::JumpTo(const Location& Loc) {

   assert (!inRecord());

   AdvanceStream();

   assert (!BlockStack.empty() || AtEnd());

   uint64_t LastBPos = StreamStart;

   while (!BlockStack.empty()) {

     LastBPos = BlockStack.back().BitNo;

     // Determine of the current block contains the location of the block
     // we are looking for.
     if (BlockStack.back().contains(Loc)) {
       // We found the enclosing block.  We must first POP it off to
       // destroy any accumulated context within the block scope.  We then
       // jump to the position of the block and enter it.
       Stream.JumpToBit(LastBPos);

       if (BlockStack.size() == Stream.BlockScope.size())
         Stream.PopBlockScope();

       BlockStack.pop_back();

       AbbrevNo = 0;
       AdvanceStream();
       assert (AbbrevNo == bitc::ENTER_SUBBLOCK);

       Stream.EnterSubBlock(BlockStack.back().BlockID);
       break;
     }

     // This block does not contain the block we are looking for.  Pop it.
     if (BlockStack.size() == Stream.BlockScope.size())
       Stream.PopBlockScope();

     BlockStack.pop_back();

   }

   // Check if we have popped our way to the outermost scope.  If so,
   // we need to adjust our position.
   if (BlockStack.empty()) {
     assert (Stream.BlockScope.empty());

     Stream.JumpToBit(Loc.BitNo < LastBPos ? StreamStart : LastBPos);
     AbbrevNo = 0;
     AdvanceStream();
   }

   assert (AbbrevNo == bitc::ENTER_SUBBLOCK);
   assert (!BlockStack.empty());

   while (!AtEnd() && BlockStack.back() != Loc) {
     if (BlockStack.back().contains(Loc)) {
       Stream.EnterSubBlock(BlockStack.back().BlockID);
       AbbrevNo = 0;
       AdvanceStream();
       continue;
     }
     else
       SkipBlock();
   }

   if (AtEnd())
     return false;

   assert (BlockStack.back() == Loc);

   return true;
 }

 void Deserializer::Rewind() {
   while (!Stream.BlockScope.empty())
     Stream.PopBlockScope();

   while (!BlockStack.empty())
     BlockStack.pop_back();

   Stream.JumpToBit(StreamStart);
   AbbrevNo = 0;
 }


 unsigned Deserializer::getCurrentBlockID() {
   if (!inRecord())
     AdvanceStream();

   return BlockStack.back().BlockID;
 }

 unsigned Deserializer::getRecordCode() {
   if (!inRecord()) {
     AdvanceStream();
     assert (AbbrevNo >= bitc::UNABBREV_RECORD);
     ReadRecord();
   }

   return RecordCode;
 }

 bool Deserializer::FinishedBlock(Location BlockLoc) {
   if (!inRecord())
     AdvanceStream();

   for (llvm::SmallVector<Location,8>::reverse_iterator
         I=BlockStack.rbegin(), E=BlockStack.rend(); I!=E; ++I)
       if (*I == BlockLoc)
         return false;

   return true;
 }

 unsigned Deserializer::getAbbrevNo() {
   if (!inRecord())
     AdvanceStream();

   return AbbrevNo;
 }

 bool Deserializer::AtEnd() {
   if (inRecord())
     return false;

   if (!AdvanceStream())
     return true;

   return false;
 }

 uint64_t Deserializer::ReadInt() {
   // FIXME: Any error recovery/handling with incomplete or bad files?
   if (!inRecord())
     ReadRecord();

   return Record[RecIdx++];
 }

 int64_t Deserializer::ReadSInt() {
   uint64_t x = ReadInt();
   int64_t magnitude = x >> 1;
   return x & 0x1 ? -magnitude : magnitude;
 }

 char* Deserializer::ReadCStr(char* cstr, unsigned MaxLen, bool isNullTerm) {
   if (cstr == NULL)
     MaxLen = 0; // Zero this just in case someone does something funny.

   unsigned len = ReadInt();

   assert (MaxLen == 0 || (len + (isNullTerm ? 1 : 0)) <= MaxLen);

   if (!cstr)
     cstr = new char[len + (isNullTerm ? 1 : 0)];

   assert (cstr != NULL);

   for (unsigned i = 0; i < len; ++i)
     cstr[i] = (char) ReadInt();

   if (isNullTerm)
     cstr[len] = '\0';

   return cstr;
 }

 void Deserializer::ReadCStr(std::vector<char>& buff, bool isNullTerm,
                             unsigned Idx) {

   unsigned len = ReadInt();

   // If Idx is beyond the current before size, reduce Idx to refer to the
   // element after the last element.
   if (Idx > buff.size())
     Idx = buff.size();

   buff.reserve(len+Idx);
   buff.resize(Idx);

   for (unsigned i = 0; i < len; ++i)
     buff.push_back((char) ReadInt());

   if (isNullTerm)
     buff.push_back('\0');
 }

 void Deserializer::RegisterPtr(const SerializedPtrID& PtrId,
                                const void* Ptr) {

   MapTy::value_type& E = BPatchMap.FindAndConstruct(BPKey(PtrId));

   assert (!HasFinalPtr(E) && "Pointer already registered.");

 #ifdef DEBUG_BACKPATCH
   llvm::cerr << "RegisterPtr: " << PtrId << " => " << Ptr << "\n";
 #endif

   SetPtr(E,Ptr);
 }

 void Deserializer::ReadUIntPtr(uintptr_t& PtrRef,
                                const SerializedPtrID& PtrId,
                                bool AllowBackpatch) {
   if (PtrId == 0) {
     PtrRef = 0;
     return;
   }

   MapTy::value_type& E = BPatchMap.FindAndConstruct(BPKey(PtrId));

   if (HasFinalPtr(E)) {
     PtrRef = GetFinalPtr(E);

 #ifdef DEBUG_BACKPATCH
     llvm::cerr << "ReadUintPtr: " << PtrId
                << " <-- " <<  (void*) GetFinalPtr(E) << '\n';
 #endif
   }
   else {
     assert (AllowBackpatch &&
             "Client forbids backpatching for this pointer.");

 #ifdef DEBUG_BACKPATCH
     llvm::cerr << "ReadUintPtr: " << PtrId << " (NO PTR YET)\n";
 #endif

     // Register backpatch.  Check the freelist for a BPNode.
     BPNode* N;

     if (FreeList) {
       N = FreeList;
       FreeList = FreeList->Next;
     }
     else // No available BPNode.  Allocate one.
       N = (BPNode*) Allocator.Allocate<BPNode>();

     new (N) BPNode(GetBPNode(E),PtrRef);
     SetBPNode(E,N);
   }
 }

 uintptr_t Deserializer::ReadInternalRefPtr() {
   SerializedPtrID PtrId = ReadPtrID();

   assert (PtrId != 0 && "References cannot refer the NULL address.");

   MapTy::value_type& E = BPatchMap.FindAndConstruct(BPKey(PtrId));

   assert (HasFinalPtr(E) &&
           "Cannot backpatch references.  Object must be already deserialized.");

   return GetFinalPtr(E);
 }

 void Deserializer::BPEntry::SetPtr(BPNode*& FreeList, void* P) {
   BPNode* Last = NULL;

   for (BPNode* N = Head; N != NULL; N=N->Next) {
     Last = N;
     N->PtrRef |= reinterpret_cast<uintptr_t>(P);
   }

   if (Last) {
     Last->Next = FreeList;
     FreeList = Head;
   }

   Ptr = const_cast<void*>(P);
 }


 #define INT_READ(TYPE)\
 void SerializeTrait<TYPE>::Read(Deserializer& D, TYPE& X) {\
   X = (TYPE) D.ReadInt(); }

 INT_READ(bool)
 INT_READ(unsigned char)
 INT_READ(unsigned short)
 INT_READ(unsigned int)
 INT_READ(unsigned long)

 #define SINT_READ(TYPE)\
 void SerializeTrait<TYPE>::Read(Deserializer& D, TYPE& X) {\
   X = (TYPE) D.ReadSInt(); }

 INT_READ(signed char)
 INT_READ(signed short)
 INT_READ(signed int)
 INT_READ(signed long)
	//==- Deserialize.cpp - Generic Object Serialization to Bitcode --- C++ --==//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines the internal methods used for object serialization.
	//
	//===----------------------------------------------------------------------===//

	#include "llvm/Bitcode/Deserialize.h"

	#ifdef DEBUG_BACKPATCH
	#include "llvm/Support/Streams.h"
	#endif

	using namespace llvm;

	Deserializer::Deserializer(BitstreamReader& stream)
	: Stream(stream), RecIdx(0), FreeList(NULL), AbbrevNo(0), RecordCode(0) {

	StreamStart = Stream.GetCurrentBitNo();
	}

	Deserializer::~Deserializer() {
	assert (RecIdx >= Record.size() &&
	"Still scanning bitcode record when deserialization completed.");

	#ifdef DEBUG_BACKPATCH
	for (MapTy::iterator I=BPatchMap.begin(), E=BPatchMap.end(); I!=E; ++I)
	assert (I->first.hasFinalPtr() &&
	"Some pointers were not backpatched.");
	#endif
	}


	bool Deserializer::inRecord() {
	if (Record.size() > 0) {
	if (RecIdx >= Record.size()) {
	RecIdx = 0;
	Record.clear();
	AbbrevNo = 0;
	return false;
	}
	else
	return true;
	}

	return false;
	}

	bool Deserializer::AdvanceStream() {
	assert (!inRecord() &&
	"Cannot advance stream. Still processing a record.");

	if (AbbrevNo == bitc::ENTER_SUBBLOCK \|\|
	AbbrevNo >= bitc::UNABBREV_RECORD)
	return true;

	while (!Stream.AtEndOfStream()) {

	uint64_t Pos = Stream.GetCurrentBitNo();
	AbbrevNo = Stream.ReadCode();

	switch (AbbrevNo) {
	case bitc::ENTER_SUBBLOCK: {
	unsigned id = Stream.ReadSubBlockID();

	// Determine the extent of the block. This is useful for jumping around
	// the stream. This is hack: we read the header of the block, save
	// the length, and then revert the bitstream to a location just before
	// the block is entered.
	uint64_t BPos = Stream.GetCurrentBitNo();
	Stream.ReadVBR(bitc::CodeLenWidth); // Skip the code size.
	Stream.SkipToWord();
	unsigned NumWords = Stream.Read(bitc::BlockSizeWidth);
	Stream.JumpToBit(BPos);

	BlockStack.push_back(Location(Pos,id,NumWords));
	break;
	}

	case bitc::END_BLOCK: {
	bool x = Stream.ReadBlockEnd();
	assert(!x && "Error at block end."); x=x;
	BlockStack.pop_back();
	continue;
	}

	case bitc::DEFINE_ABBREV:
	Stream.ReadAbbrevRecord();
	continue;

	default:
	break;
	}

	return true;
	}

	return false;
	}

	void Deserializer::ReadRecord() {

	while (AdvanceStream() && AbbrevNo == bitc::ENTER_SUBBLOCK) {
	assert (!BlockStack.empty());
	Stream.EnterSubBlock(BlockStack.back().BlockID);
	AbbrevNo = 0;
	}

	if (Stream.AtEndOfStream())
	return;

	assert (Record.empty());
	assert (AbbrevNo >= bitc::UNABBREV_RECORD);
	RecordCode = Stream.ReadRecord(AbbrevNo,Record);
	assert (Record.size() > 0);
	}

	void Deserializer::SkipBlock() {
	assert (!inRecord());

	if (AtEnd())
	return;

	AdvanceStream();

	assert (AbbrevNo == bitc::ENTER_SUBBLOCK);
	BlockStack.pop_back();
	Stream.SkipBlock();

	AbbrevNo = 0;
	AdvanceStream();
	}

	bool Deserializer::SkipToBlock(unsigned BlockID) {
	assert (!inRecord());

	AdvanceStream();
	assert (AbbrevNo == bitc::ENTER_SUBBLOCK);

	unsigned BlockLevel = BlockStack.size();

	while (!AtEnd() &&
	BlockLevel == BlockStack.size() &&
	getCurrentBlockID() != BlockID)
	SkipBlock();

	return !(AtEnd() \|\| BlockLevel != BlockStack.size());
	}

	Deserializer::Location Deserializer::getCurrentBlockLocation() {
	if (!inRecord())
	AdvanceStream();

	return BlockStack.back();
	}

	bool Deserializer::JumpTo(const Location& Loc) {

	assert (!inRecord());

	AdvanceStream();

	assert (!BlockStack.empty() \|\| AtEnd());

	uint64_t LastBPos = StreamStart;

	while (!BlockStack.empty()) {

	LastBPos = BlockStack.back().BitNo;

	// Determine of the current block contains the location of the block
	// we are looking for.
	if (BlockStack.back().contains(Loc)) {
	// We found the enclosing block. We must first POP it off to
	// destroy any accumulated context within the block scope. We then
	// jump to the position of the block and enter it.
	Stream.JumpToBit(LastBPos);

	if (BlockStack.size() == Stream.BlockScope.size())
	Stream.PopBlockScope();

	BlockStack.pop_back();

	AbbrevNo = 0;
	AdvanceStream();
	assert (AbbrevNo == bitc::ENTER_SUBBLOCK);

	Stream.EnterSubBlock(BlockStack.back().BlockID);
	break;
	}

	// This block does not contain the block we are looking for. Pop it.
	if (BlockStack.size() == Stream.BlockScope.size())
	Stream.PopBlockScope();

	BlockStack.pop_back();

	}

	// Check if we have popped our way to the outermost scope. If so,
	// we need to adjust our position.
	if (BlockStack.empty()) {
	assert (Stream.BlockScope.empty());

	Stream.JumpToBit(Loc.BitNo < LastBPos ? StreamStart : LastBPos);
	AbbrevNo = 0;
	AdvanceStream();
	}

	assert (AbbrevNo == bitc::ENTER_SUBBLOCK);
	assert (!BlockStack.empty());

	while (!AtEnd() && BlockStack.back() != Loc) {
	if (BlockStack.back().contains(Loc)) {
	Stream.EnterSubBlock(BlockStack.back().BlockID);
	AbbrevNo = 0;
	AdvanceStream();
	continue;
	}
	else
	SkipBlock();
	}

	if (AtEnd())
	return false;

	assert (BlockStack.back() == Loc);

	return true;
	}

	void Deserializer::Rewind() {
	while (!Stream.BlockScope.empty())
	Stream.PopBlockScope();

	while (!BlockStack.empty())
	BlockStack.pop_back();

	Stream.JumpToBit(StreamStart);
	AbbrevNo = 0;
	}


	unsigned Deserializer::getCurrentBlockID() {
	if (!inRecord())
	AdvanceStream();

	return BlockStack.back().BlockID;
	}

	unsigned Deserializer::getRecordCode() {
	if (!inRecord()) {
	AdvanceStream();
	assert (AbbrevNo >= bitc::UNABBREV_RECORD);
	ReadRecord();
	}

	return RecordCode;
	}

	bool Deserializer::FinishedBlock(Location BlockLoc) {
	if (!inRecord())
	AdvanceStream();

	for (llvm::SmallVector<Location,8>::reverse_iterator
	I=BlockStack.rbegin(), E=BlockStack.rend(); I!=E; ++I)
	if (*I == BlockLoc)
	return false;

	return true;
	}

	unsigned Deserializer::getAbbrevNo() {
	if (!inRecord())
	AdvanceStream();

	return AbbrevNo;
	}

	bool Deserializer::AtEnd() {
	if (inRecord())
	return false;

	if (!AdvanceStream())
	return true;

	return false;
	}

	uint64_t Deserializer::ReadInt() {
	// FIXME: Any error recovery/handling with incomplete or bad files?
	if (!inRecord())
	ReadRecord();

	return Record[RecIdx++];
	}

	int64_t Deserializer::ReadSInt() {
	uint64_t x = ReadInt();
	int64_t magnitude = x >> 1;
	return x & 0x1 ? -magnitude : magnitude;
	}

	char* Deserializer::ReadCStr(char* cstr, unsigned MaxLen, bool isNullTerm) {
	if (cstr == NULL)
	MaxLen = 0; // Zero this just in case someone does something funny.

	unsigned len = ReadInt();

	assert (MaxLen == 0 \|\| (len + (isNullTerm ? 1 : 0)) <= MaxLen);

	if (!cstr)
	cstr = new char[len + (isNullTerm ? 1 : 0)];

	assert (cstr != NULL);

	for (unsigned i = 0; i < len; ++i)
	cstr[i] = (char) ReadInt();

	if (isNullTerm)
	cstr[len] = '\0';

	return cstr;
	}

	void Deserializer::ReadCStr(std::vector<char>& buff, bool isNullTerm,
	unsigned Idx) {

	unsigned len = ReadInt();

	// If Idx is beyond the current before size, reduce Idx to refer to the
	// element after the last element.
	if (Idx > buff.size())
	Idx = buff.size();

	buff.reserve(len+Idx);
	buff.resize(Idx);

	for (unsigned i = 0; i < len; ++i)
	buff.push_back((char) ReadInt());

	if (isNullTerm)
	buff.push_back('\0');
	}

	void Deserializer::RegisterPtr(const SerializedPtrID& PtrId,
	const void* Ptr) {

	MapTy::value_type& E = BPatchMap.FindAndConstruct(BPKey(PtrId));

	assert (!HasFinalPtr(E) && "Pointer already registered.");

	#ifdef DEBUG_BACKPATCH
	llvm::cerr << "RegisterPtr: " << PtrId << " => " << Ptr << "\n";
	#endif

	SetPtr(E,Ptr);
	}

	void Deserializer::ReadUIntPtr(uintptr_t& PtrRef,
	const SerializedPtrID& PtrId,
	bool AllowBackpatch) {
	if (PtrId == 0) {
	PtrRef = 0;
	return;
	}

	MapTy::value_type& E = BPatchMap.FindAndConstruct(BPKey(PtrId));

	if (HasFinalPtr(E)) {
	PtrRef = GetFinalPtr(E);

	#ifdef DEBUG_BACKPATCH
	llvm::cerr << "ReadUintPtr: " << PtrId
	<< " <-- " << (void*) GetFinalPtr(E) << '\n';
	#endif
	}
	else {
	assert (AllowBackpatch &&
	"Client forbids backpatching for this pointer.");

	#ifdef DEBUG_BACKPATCH
	llvm::cerr << "ReadUintPtr: " << PtrId << " (NO PTR YET)\n";
	#endif

	// Register backpatch. Check the freelist for a BPNode.
	BPNode* N;

	if (FreeList) {
	N = FreeList;
	FreeList = FreeList->Next;
	}
	else // No available BPNode. Allocate one.
	N = (BPNode*) Allocator.Allocate<BPNode>();

	new (N) BPNode(GetBPNode(E),PtrRef);
	SetBPNode(E,N);
	}
	}

	uintptr_t Deserializer::ReadInternalRefPtr() {
	SerializedPtrID PtrId = ReadPtrID();

	assert (PtrId != 0 && "References cannot refer the NULL address.");

	MapTy::value_type& E = BPatchMap.FindAndConstruct(BPKey(PtrId));

	assert (HasFinalPtr(E) &&
	"Cannot backpatch references. Object must be already deserialized.");

	return GetFinalPtr(E);
	}

	void Deserializer::BPEntry::SetPtr(BPNode& FreeList, void P) {
	BPNode* Last = NULL;

	for (BPNode* N = Head; N != NULL; N=N->Next) {
	Last = N;
	N->PtrRef \|= reinterpret_cast<uintptr_t>(P);
	}

	if (Last) {
	Last->Next = FreeList;
	FreeList = Head;
	}

	Ptr = const_cast<void*>(P);
	}


	#define INT_READ(TYPE)\
	void SerializeTrait<TYPE>::Read(Deserializer& D, TYPE& X) {\
	X = (TYPE) D.ReadInt(); }

	INT_READ(bool)
	INT_READ(unsigned char)
	INT_READ(unsigned short)
	INT_READ(unsigned int)
	INT_READ(unsigned long)

	#define SINT_READ(TYPE)\
	void SerializeTrait<TYPE>::Read(Deserializer& D, TYPE& X) {\
	X = (TYPE) D.ReadSInt(); }

	INT_READ(signed char)
	INT_READ(signed short)
	INT_READ(signed int)
	INT_READ(signed long)