llvm-6502/include/llvm/Bitcode/BitstreamReader.h
Benjamin Kramer 49a6a8d8f2 Remove the Copied parameter from MemoryObject::readBytes.
There was exactly one caller using this API right, the others were relying on
specific behavior of the default implementation. Since it's too hard to use it
right just remove it and standardize on the default behavior.

Defines away PR16132.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@182636 91177308-0d34-0410-b5e6-96231b3b80d8
2013-05-24 10:54:58 +00:00

558 lines
17 KiB
C++

//===- BitstreamReader.h - Low-level bitstream reader interface -*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This header defines the BitstreamReader class. This class can be used to
// read an arbitrary bitstream, regardless of its contents.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_BITCODE_BITSTREAMREADER_H
#define LLVM_BITCODE_BITSTREAMREADER_H
#include "llvm/ADT/OwningPtr.h"
#include "llvm/Bitcode/BitCodes.h"
#include "llvm/Support/Endian.h"
#include "llvm/Support/StreamableMemoryObject.h"
#include <climits>
#include <string>
#include <vector>
namespace llvm {
class Deserializer;
/// BitstreamReader - This class is used to read from an LLVM bitcode stream,
/// maintaining information that is global to decoding the entire file. While
/// a file is being read, multiple cursors can be independently advanced or
/// skipped around within the file. These are represented by the
/// BitstreamCursor class.
class BitstreamReader {
public:
/// BlockInfo - This contains information emitted to BLOCKINFO_BLOCK blocks.
/// These describe abbreviations that all blocks of the specified ID inherit.
struct BlockInfo {
unsigned BlockID;
std::vector<BitCodeAbbrev*> Abbrevs;
std::string Name;
std::vector<std::pair<unsigned, std::string> > RecordNames;
};
private:
OwningPtr<StreamableMemoryObject> BitcodeBytes;
std::vector<BlockInfo> BlockInfoRecords;
/// IgnoreBlockInfoNames - This is set to true if we don't care about the
/// block/record name information in the BlockInfo block. Only llvm-bcanalyzer
/// uses this.
bool IgnoreBlockInfoNames;
BitstreamReader(const BitstreamReader&) LLVM_DELETED_FUNCTION;
void operator=(const BitstreamReader&) LLVM_DELETED_FUNCTION;
public:
BitstreamReader() : IgnoreBlockInfoNames(true) {
}
BitstreamReader(const unsigned char *Start, const unsigned char *End) {
IgnoreBlockInfoNames = true;
init(Start, End);
}
BitstreamReader(StreamableMemoryObject *bytes) {
BitcodeBytes.reset(bytes);
}
void init(const unsigned char *Start, const unsigned char *End) {
assert(((End-Start) & 3) == 0 &&"Bitcode stream not a multiple of 4 bytes");
BitcodeBytes.reset(getNonStreamedMemoryObject(Start, End));
}
StreamableMemoryObject &getBitcodeBytes() { return *BitcodeBytes; }
~BitstreamReader() {
// Free the BlockInfoRecords.
while (!BlockInfoRecords.empty()) {
BlockInfo &Info = BlockInfoRecords.back();
// Free blockinfo abbrev info.
for (unsigned i = 0, e = static_cast<unsigned>(Info.Abbrevs.size());
i != e; ++i)
Info.Abbrevs[i]->dropRef();
BlockInfoRecords.pop_back();
}
}
/// CollectBlockInfoNames - This is called by clients that want block/record
/// name information.
void CollectBlockInfoNames() { IgnoreBlockInfoNames = false; }
bool isIgnoringBlockInfoNames() { return IgnoreBlockInfoNames; }
//===--------------------------------------------------------------------===//
// Block Manipulation
//===--------------------------------------------------------------------===//
/// hasBlockInfoRecords - Return true if we've already read and processed the
/// block info block for this Bitstream. We only process it for the first
/// cursor that walks over it.
bool hasBlockInfoRecords() const { return !BlockInfoRecords.empty(); }
/// getBlockInfo - If there is block info for the specified ID, return it,
/// otherwise return null.
const BlockInfo *getBlockInfo(unsigned BlockID) const {
// Common case, the most recent entry matches BlockID.
if (!BlockInfoRecords.empty() && BlockInfoRecords.back().BlockID == BlockID)
return &BlockInfoRecords.back();
for (unsigned i = 0, e = static_cast<unsigned>(BlockInfoRecords.size());
i != e; ++i)
if (BlockInfoRecords[i].BlockID == BlockID)
return &BlockInfoRecords[i];
return 0;
}
BlockInfo &getOrCreateBlockInfo(unsigned BlockID) {
if (const BlockInfo *BI = getBlockInfo(BlockID))
return *const_cast<BlockInfo*>(BI);
// Otherwise, add a new record.
BlockInfoRecords.push_back(BlockInfo());
BlockInfoRecords.back().BlockID = BlockID;
return BlockInfoRecords.back();
}
};
/// BitstreamEntry - When advancing through a bitstream cursor, each advance can
/// discover a few different kinds of entries:
/// Error - Malformed bitcode was found.
/// EndBlock - We've reached the end of the current block, (or the end of the
/// file, which is treated like a series of EndBlock records.
/// SubBlock - This is the start of a new subblock of a specific ID.
/// Record - This is a record with a specific AbbrevID.
///
struct BitstreamEntry {
enum {
Error,
EndBlock,
SubBlock,
Record
} Kind;
unsigned ID;
static BitstreamEntry getError() {
BitstreamEntry E; E.Kind = Error; return E;
}
static BitstreamEntry getEndBlock() {
BitstreamEntry E; E.Kind = EndBlock; return E;
}
static BitstreamEntry getSubBlock(unsigned ID) {
BitstreamEntry E; E.Kind = SubBlock; E.ID = ID; return E;
}
static BitstreamEntry getRecord(unsigned AbbrevID) {
BitstreamEntry E; E.Kind = Record; E.ID = AbbrevID; return E;
}
};
/// BitstreamCursor - This represents a position within a bitcode file. There
/// may be multiple independent cursors reading within one bitstream, each
/// maintaining their own local state.
///
/// Unlike iterators, BitstreamCursors are heavy-weight objects that should not
/// be passed by value.
class BitstreamCursor {
friend class Deserializer;
BitstreamReader *BitStream;
size_t NextChar;
/// CurWord/word_t - This is the current data we have pulled from the stream
/// but have not returned to the client. This is specifically and
/// intentionally defined to follow the word size of the host machine for
/// efficiency. We use word_t in places that are aware of this to make it
/// perfectly explicit what is going on.
typedef uint32_t word_t;
word_t CurWord;
/// BitsInCurWord - This is the number of bits in CurWord that are valid. This
/// is always from [0...31/63] inclusive (depending on word size).
unsigned BitsInCurWord;
// CurCodeSize - This is the declared size of code values used for the current
// block, in bits.
unsigned CurCodeSize;
/// CurAbbrevs - Abbrevs installed at in this block.
std::vector<BitCodeAbbrev*> CurAbbrevs;
struct Block {
unsigned PrevCodeSize;
std::vector<BitCodeAbbrev*> PrevAbbrevs;
explicit Block(unsigned PCS) : PrevCodeSize(PCS) {}
};
/// BlockScope - This tracks the codesize of parent blocks.
SmallVector<Block, 8> BlockScope;
public:
BitstreamCursor() : BitStream(0), NextChar(0) {
}
BitstreamCursor(const BitstreamCursor &RHS) : BitStream(0), NextChar(0) {
operator=(RHS);
}
explicit BitstreamCursor(BitstreamReader &R) : BitStream(&R) {
NextChar = 0;
CurWord = 0;
BitsInCurWord = 0;
CurCodeSize = 2;
}
void init(BitstreamReader &R) {
freeState();
BitStream = &R;
NextChar = 0;
CurWord = 0;
BitsInCurWord = 0;
CurCodeSize = 2;
}
~BitstreamCursor() {
freeState();
}
void operator=(const BitstreamCursor &RHS);
void freeState();
bool isEndPos(size_t pos) {
return BitStream->getBitcodeBytes().isObjectEnd(static_cast<uint64_t>(pos));
}
bool canSkipToPos(size_t pos) const {
// pos can be skipped to if it is a valid address or one byte past the end.
return pos == 0 || BitStream->getBitcodeBytes().isValidAddress(
static_cast<uint64_t>(pos - 1));
}
uint32_t getWord(size_t pos) {
uint8_t buf[4] = { 0xFF, 0xFF, 0xFF, 0xFF };
BitStream->getBitcodeBytes().readBytes(pos, sizeof(buf), buf);
return *reinterpret_cast<support::ulittle32_t *>(buf);
}
bool AtEndOfStream() {
return BitsInCurWord == 0 && isEndPos(NextChar);
}
/// getAbbrevIDWidth - Return the number of bits used to encode an abbrev #.
unsigned getAbbrevIDWidth() const { return CurCodeSize; }
/// GetCurrentBitNo - Return the bit # of the bit we are reading.
uint64_t GetCurrentBitNo() const {
return NextChar*CHAR_BIT - BitsInCurWord;
}
BitstreamReader *getBitStreamReader() {
return BitStream;
}
const BitstreamReader *getBitStreamReader() const {
return BitStream;
}
/// Flags that modify the behavior of advance().
enum {
/// AF_DontPopBlockAtEnd - If this flag is used, the advance() method does
/// not automatically pop the block scope when the end of a block is
/// reached.
AF_DontPopBlockAtEnd = 1,
/// AF_DontAutoprocessAbbrevs - If this flag is used, abbrev entries are
/// returned just like normal records.
AF_DontAutoprocessAbbrevs = 2
};
/// advance - Advance the current bitstream, returning the next entry in the
/// stream.
BitstreamEntry advance(unsigned Flags = 0) {
while (1) {
unsigned Code = ReadCode();
if (Code == bitc::END_BLOCK) {
// Pop the end of the block unless Flags tells us not to.
if (!(Flags & AF_DontPopBlockAtEnd) && ReadBlockEnd())
return BitstreamEntry::getError();
return BitstreamEntry::getEndBlock();
}
if (Code == bitc::ENTER_SUBBLOCK)
return BitstreamEntry::getSubBlock(ReadSubBlockID());
if (Code == bitc::DEFINE_ABBREV &&
!(Flags & AF_DontAutoprocessAbbrevs)) {
// We read and accumulate abbrev's, the client can't do anything with
// them anyway.
ReadAbbrevRecord();
continue;
}
return BitstreamEntry::getRecord(Code);
}
}
/// advanceSkippingSubblocks - This is a convenience function for clients that
/// don't expect any subblocks. This just skips over them automatically.
BitstreamEntry advanceSkippingSubblocks(unsigned Flags = 0) {
while (1) {
// If we found a normal entry, return it.
BitstreamEntry Entry = advance(Flags);
if (Entry.Kind != BitstreamEntry::SubBlock)
return Entry;
// If we found a sub-block, just skip over it and check the next entry.
if (SkipBlock())
return BitstreamEntry::getError();
}
}
/// JumpToBit - Reset the stream to the specified bit number.
void JumpToBit(uint64_t BitNo) {
uintptr_t ByteNo = uintptr_t(BitNo/8) & ~(sizeof(word_t)-1);
unsigned WordBitNo = unsigned(BitNo & (sizeof(word_t)*8-1));
assert(canSkipToPos(ByteNo) && "Invalid location");
// Move the cursor to the right word.
NextChar = ByteNo;
BitsInCurWord = 0;
CurWord = 0;
// Skip over any bits that are already consumed.
if (WordBitNo) {
if (sizeof(word_t) > 4)
Read64(WordBitNo);
else
Read(WordBitNo);
}
}
uint32_t Read(unsigned NumBits) {
assert(NumBits && NumBits <= 32 &&
"Cannot return zero or more than 32 bits!");
// If the field is fully contained by CurWord, return it quickly.
if (BitsInCurWord >= NumBits) {
uint32_t R = uint32_t(CurWord) & (~0U >> (32-NumBits));
CurWord >>= NumBits;
BitsInCurWord -= NumBits;
return R;
}
// If we run out of data, stop at the end of the stream.
if (isEndPos(NextChar)) {
CurWord = 0;
BitsInCurWord = 0;
return 0;
}
uint32_t R = uint32_t(CurWord);
// Read the next word from the stream.
uint8_t Array[sizeof(word_t)] = {0};
BitStream->getBitcodeBytes().readBytes(NextChar, sizeof(Array), Array);
// Handle big-endian byte-swapping if necessary.
support::detail::packed_endian_specific_integral
<word_t, support::little, support::unaligned> EndianValue;
memcpy(&EndianValue, Array, sizeof(Array));
CurWord = EndianValue;
NextChar += sizeof(word_t);
// Extract NumBits-BitsInCurWord from what we just read.
unsigned BitsLeft = NumBits-BitsInCurWord;
// Be careful here, BitsLeft is in the range [1..32]/[1..64] inclusive.
R |= uint32_t((CurWord & (word_t(~0ULL) >> (sizeof(word_t)*8-BitsLeft)))
<< BitsInCurWord);
// BitsLeft bits have just been used up from CurWord. BitsLeft is in the
// range [1..32]/[1..64] so be careful how we shift.
if (BitsLeft != sizeof(word_t)*8)
CurWord >>= BitsLeft;
else
CurWord = 0;
BitsInCurWord = sizeof(word_t)*8-BitsLeft;
return R;
}
uint64_t Read64(unsigned NumBits) {
if (NumBits <= 32) return Read(NumBits);
uint64_t V = Read(32);
return V | (uint64_t)Read(NumBits-32) << 32;
}
uint32_t ReadVBR(unsigned NumBits) {
uint32_t Piece = Read(NumBits);
if ((Piece & (1U << (NumBits-1))) == 0)
return Piece;
uint32_t Result = 0;
unsigned NextBit = 0;
while (1) {
Result |= (Piece & ((1U << (NumBits-1))-1)) << NextBit;
if ((Piece & (1U << (NumBits-1))) == 0)
return Result;
NextBit += NumBits-1;
Piece = Read(NumBits);
}
}
// ReadVBR64 - Read a VBR that may have a value up to 64-bits in size. The
// chunk size of the VBR must still be <= 32 bits though.
uint64_t ReadVBR64(unsigned NumBits) {
uint32_t Piece = Read(NumBits);
if ((Piece & (1U << (NumBits-1))) == 0)
return uint64_t(Piece);
uint64_t Result = 0;
unsigned NextBit = 0;
while (1) {
Result |= uint64_t(Piece & ((1U << (NumBits-1))-1)) << NextBit;
if ((Piece & (1U << (NumBits-1))) == 0)
return Result;
NextBit += NumBits-1;
Piece = Read(NumBits);
}
}
private:
void SkipToFourByteBoundary() {
// If word_t is 64-bits and if we've read less than 32 bits, just dump
// the bits we have up to the next 32-bit boundary.
if (sizeof(word_t) > 4 &&
BitsInCurWord >= 32) {
CurWord >>= BitsInCurWord-32;
BitsInCurWord = 32;
return;
}
BitsInCurWord = 0;
CurWord = 0;
}
public:
unsigned ReadCode() {
return Read(CurCodeSize);
}
// Block header:
// [ENTER_SUBBLOCK, blockid, newcodelen, <align4bytes>, blocklen]
/// ReadSubBlockID - Having read the ENTER_SUBBLOCK code, read the BlockID for
/// the block.
unsigned ReadSubBlockID() {
return ReadVBR(bitc::BlockIDWidth);
}
/// SkipBlock - Having read the ENTER_SUBBLOCK abbrevid and a BlockID, skip
/// over the body of this block. If the block record is malformed, return
/// true.
bool SkipBlock() {
// Read and ignore the codelen value. Since we are skipping this block, we
// don't care what code widths are used inside of it.
ReadVBR(bitc::CodeLenWidth);
SkipToFourByteBoundary();
unsigned NumFourBytes = Read(bitc::BlockSizeWidth);
// Check that the block wasn't partially defined, and that the offset isn't
// bogus.
size_t SkipTo = GetCurrentBitNo() + NumFourBytes*4*8;
if (AtEndOfStream() || !canSkipToPos(SkipTo/8))
return true;
JumpToBit(SkipTo);
return false;
}
/// EnterSubBlock - Having read the ENTER_SUBBLOCK abbrevid, enter
/// the block, and return true if the block has an error.
bool EnterSubBlock(unsigned BlockID, unsigned *NumWordsP = 0);
bool ReadBlockEnd() {
if (BlockScope.empty()) return true;
// Block tail:
// [END_BLOCK, <align4bytes>]
SkipToFourByteBoundary();
popBlockScope();
return false;
}
private:
void popBlockScope() {
CurCodeSize = BlockScope.back().PrevCodeSize;
// Delete abbrevs from popped scope.
for (unsigned i = 0, e = static_cast<unsigned>(CurAbbrevs.size());
i != e; ++i)
CurAbbrevs[i]->dropRef();
BlockScope.back().PrevAbbrevs.swap(CurAbbrevs);
BlockScope.pop_back();
}
//===--------------------------------------------------------------------===//
// Record Processing
//===--------------------------------------------------------------------===//
private:
void readAbbreviatedLiteral(const BitCodeAbbrevOp &Op,
SmallVectorImpl<uint64_t> &Vals);
void readAbbreviatedField(const BitCodeAbbrevOp &Op,
SmallVectorImpl<uint64_t> &Vals);
void skipAbbreviatedField(const BitCodeAbbrevOp &Op);
public:
/// getAbbrev - Return the abbreviation for the specified AbbrevId.
const BitCodeAbbrev *getAbbrev(unsigned AbbrevID) {
unsigned AbbrevNo = AbbrevID-bitc::FIRST_APPLICATION_ABBREV;
assert(AbbrevNo < CurAbbrevs.size() && "Invalid abbrev #!");
return CurAbbrevs[AbbrevNo];
}
/// skipRecord - Read the current record and discard it.
void skipRecord(unsigned AbbrevID);
unsigned readRecord(unsigned AbbrevID, SmallVectorImpl<uint64_t> &Vals,
StringRef *Blob = 0);
//===--------------------------------------------------------------------===//
// Abbrev Processing
//===--------------------------------------------------------------------===//
void ReadAbbrevRecord();
bool ReadBlockInfoBlock();
};
} // End llvm namespace
#endif