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|
#pragma once
#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
#endif
//===- BitstreamWriter.h - Low-level bitstream writer interface -*- C++ -*-===//
//
// 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 header defines the BitstreamWriter class. This class can be used to
// write an arbitrary bitstream, regardless of its contents.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_BITSTREAM_BITSTREAMWRITER_H
#define LLVM_BITSTREAM_BITSTREAMWRITER_H
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/SmallVector.h"
#include "llvm/ADT/StringRef.h"
#include "llvm/Bitstream/BitCodes.h"
#include "llvm/Support/Endian.h"
#include "llvm/Support/MathExtras.h"
#include "llvm/Support/raw_ostream.h"
#include <algorithm>
#include <optional>
#include <vector>
namespace llvm {
class BitstreamWriter {
/// Out - The buffer that keeps unflushed bytes.
SmallVectorImpl<char> &Out;
/// FS - The file stream that Out flushes to. If FS is nullptr, it does not
/// support read or seek, Out cannot be flushed until all data are written.
raw_fd_stream *FS;
/// FlushThreshold - If FS is valid, this is the threshold (unit B) to flush
/// FS.
const uint64_t FlushThreshold;
/// CurBit - Always between 0 and 31 inclusive, specifies the next bit to use.
unsigned CurBit;
/// CurValue - The current value. Only bits < CurBit are valid.
uint32_t CurValue;
/// CurCodeSize - This is the declared size of code values used for the
/// current block, in bits.
unsigned CurCodeSize;
/// BlockInfoCurBID - When emitting a BLOCKINFO_BLOCK, this is the currently
/// selected BLOCK ID.
unsigned BlockInfoCurBID;
/// CurAbbrevs - Abbrevs installed at in this block.
std::vector<std::shared_ptr<BitCodeAbbrev>> CurAbbrevs;
struct Block {
unsigned PrevCodeSize;
size_t StartSizeWord;
std::vector<std::shared_ptr<BitCodeAbbrev>> PrevAbbrevs;
Block(unsigned PCS, size_t SSW) : PrevCodeSize(PCS), StartSizeWord(SSW) {}
};
/// BlockScope - This tracks the current blocks that we have entered.
std::vector<Block> BlockScope;
/// 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<std::shared_ptr<BitCodeAbbrev>> Abbrevs;
};
std::vector<BlockInfo> BlockInfoRecords;
void WriteWord(unsigned Value) {
Value = support::endian::byte_swap<uint32_t, support::little>(Value);
Out.append(reinterpret_cast<const char *>(&Value),
reinterpret_cast<const char *>(&Value + 1));
}
uint64_t GetNumOfFlushedBytes() const { return FS ? FS->tell() : 0; }
size_t GetBufferOffset() const { return Out.size() + GetNumOfFlushedBytes(); }
size_t GetWordIndex() const {
size_t Offset = GetBufferOffset();
assert((Offset & 3) == 0 && "Not 32-bit aligned");
return Offset / 4;
}
/// If the related file stream supports reading, seeking and writing, flush
/// the buffer if its size is above a threshold.
void FlushToFile() {
if (!FS)
return;
if (Out.size() < FlushThreshold)
return;
FS->write((char *)&Out.front(), Out.size());
Out.clear();
}
public:
/// Create a BitstreamWriter that writes to Buffer \p O.
///
/// \p FS is the file stream that \p O flushes to incrementally. If \p FS is
/// null, \p O does not flush incrementially, but writes to disk at the end.
///
/// \p FlushThreshold is the threshold (unit M) to flush \p O if \p FS is
/// valid. Flushing only occurs at (sub)block boundaries.
BitstreamWriter(SmallVectorImpl<char> &O, raw_fd_stream *FS = nullptr,
uint32_t FlushThreshold = 512)
: Out(O), FS(FS), FlushThreshold(FlushThreshold << 20), CurBit(0),
CurValue(0), CurCodeSize(2) {}
~BitstreamWriter() {
assert(CurBit == 0 && "Unflushed data remaining");
assert(BlockScope.empty() && CurAbbrevs.empty() && "Block imbalance");
}
/// Retrieve the current position in the stream, in bits.
uint64_t GetCurrentBitNo() const { return GetBufferOffset() * 8 + CurBit; }
/// Retrieve the number of bits currently used to encode an abbrev ID.
unsigned GetAbbrevIDWidth() const { return CurCodeSize; }
//===--------------------------------------------------------------------===//
// Basic Primitives for emitting bits to the stream.
//===--------------------------------------------------------------------===//
/// Backpatch a 32-bit word in the output at the given bit offset
/// with the specified value.
void BackpatchWord(uint64_t BitNo, unsigned NewWord) {
using namespace llvm::support;
uint64_t ByteNo = BitNo / 8;
uint64_t StartBit = BitNo & 7;
uint64_t NumOfFlushedBytes = GetNumOfFlushedBytes();
if (ByteNo >= NumOfFlushedBytes) {
assert((!endian::readAtBitAlignment<uint32_t, little, unaligned>(
&Out[ByteNo - NumOfFlushedBytes], StartBit)) &&
"Expected to be patching over 0-value placeholders");
endian::writeAtBitAlignment<uint32_t, little, unaligned>(
&Out[ByteNo - NumOfFlushedBytes], NewWord, StartBit);
return;
}
// If the byte offset to backpatch is flushed, use seek to backfill data.
// First, save the file position to restore later.
uint64_t CurPos = FS->tell();
// Copy data to update into Bytes from the file FS and the buffer Out.
char Bytes[9]; // Use one more byte to silence a warning from Visual C++.
size_t BytesNum = StartBit ? 8 : 4;
size_t BytesFromDisk = std::min(static_cast<uint64_t>(BytesNum), NumOfFlushedBytes - ByteNo);
size_t BytesFromBuffer = BytesNum - BytesFromDisk;
// When unaligned, copy existing data into Bytes from the file FS and the
// buffer Out so that it can be updated before writing. For debug builds
// read bytes unconditionally in order to check that the existing value is 0
// as expected.
#ifdef NDEBUG
if (StartBit)
#endif
{
FS->seek(ByteNo);
ssize_t BytesRead = FS->read(Bytes, BytesFromDisk);
(void)BytesRead; // silence warning
assert(BytesRead >= 0 && static_cast<size_t>(BytesRead) == BytesFromDisk);
for (size_t i = 0; i < BytesFromBuffer; ++i)
Bytes[BytesFromDisk + i] = Out[i];
assert((!endian::readAtBitAlignment<uint32_t, little, unaligned>(
Bytes, StartBit)) &&
"Expected to be patching over 0-value placeholders");
}
// Update Bytes in terms of bit offset and value.
endian::writeAtBitAlignment<uint32_t, little, unaligned>(Bytes, NewWord,
StartBit);
// Copy updated data back to the file FS and the buffer Out.
FS->seek(ByteNo);
FS->write(Bytes, BytesFromDisk);
for (size_t i = 0; i < BytesFromBuffer; ++i)
Out[i] = Bytes[BytesFromDisk + i];
// Restore the file position.
FS->seek(CurPos);
}
void BackpatchWord64(uint64_t BitNo, uint64_t Val) {
BackpatchWord(BitNo, (uint32_t)Val);
BackpatchWord(BitNo + 32, (uint32_t)(Val >> 32));
}
void Emit(uint32_t Val, unsigned NumBits) {
assert(NumBits && NumBits <= 32 && "Invalid value size!");
assert((Val & ~(~0U >> (32-NumBits))) == 0 && "High bits set!");
CurValue |= Val << CurBit;
if (CurBit + NumBits < 32) {
CurBit += NumBits;
return;
}
// Add the current word.
WriteWord(CurValue);
if (CurBit)
CurValue = Val >> (32-CurBit);
else
CurValue = 0;
CurBit = (CurBit+NumBits) & 31;
}
void FlushToWord() {
if (CurBit) {
WriteWord(CurValue);
CurBit = 0;
CurValue = 0;
}
}
void EmitVBR(uint32_t Val, unsigned NumBits) {
assert(NumBits <= 32 && "Too many bits to emit!");
uint32_t Threshold = 1U << (NumBits-1);
// Emit the bits with VBR encoding, NumBits-1 bits at a time.
while (Val >= Threshold) {
Emit((Val & ((1 << (NumBits-1))-1)) | (1 << (NumBits-1)), NumBits);
Val >>= NumBits-1;
}
Emit(Val, NumBits);
}
void EmitVBR64(uint64_t Val, unsigned NumBits) {
assert(NumBits <= 32 && "Too many bits to emit!");
if ((uint32_t)Val == Val)
return EmitVBR((uint32_t)Val, NumBits);
uint32_t Threshold = 1U << (NumBits-1);
// Emit the bits with VBR encoding, NumBits-1 bits at a time.
while (Val >= Threshold) {
Emit(((uint32_t)Val & ((1 << (NumBits - 1)) - 1)) | (1 << (NumBits - 1)),
NumBits);
Val >>= NumBits-1;
}
Emit((uint32_t)Val, NumBits);
}
/// EmitCode - Emit the specified code.
void EmitCode(unsigned Val) {
Emit(Val, CurCodeSize);
}
//===--------------------------------------------------------------------===//
// Block Manipulation
//===--------------------------------------------------------------------===//
/// getBlockInfo - If there is block info for the specified ID, return it,
/// otherwise return null.
BlockInfo *getBlockInfo(unsigned BlockID) {
// Common case, the most recent entry matches BlockID.
if (!BlockInfoRecords.empty() && BlockInfoRecords.back().BlockID == BlockID)
return &BlockInfoRecords.back();
for (BlockInfo &BI : BlockInfoRecords)
if (BI.BlockID == BlockID)
return &BI;
return nullptr;
}
void EnterSubblock(unsigned BlockID, unsigned CodeLen) {
// Block header:
// [ENTER_SUBBLOCK, blockid, newcodelen, <align4bytes>, blocklen]
EmitCode(bitc::ENTER_SUBBLOCK);
EmitVBR(BlockID, bitc::BlockIDWidth);
EmitVBR(CodeLen, bitc::CodeLenWidth);
FlushToWord();
size_t BlockSizeWordIndex = GetWordIndex();
unsigned OldCodeSize = CurCodeSize;
// Emit a placeholder, which will be replaced when the block is popped.
Emit(0, bitc::BlockSizeWidth);
CurCodeSize = CodeLen;
// Push the outer block's abbrev set onto the stack, start out with an
// empty abbrev set.
BlockScope.emplace_back(OldCodeSize, BlockSizeWordIndex);
BlockScope.back().PrevAbbrevs.swap(CurAbbrevs);
// If there is a blockinfo for this BlockID, add all the predefined abbrevs
// to the abbrev list.
if (BlockInfo *Info = getBlockInfo(BlockID))
append_range(CurAbbrevs, Info->Abbrevs);
}
void ExitBlock() {
assert(!BlockScope.empty() && "Block scope imbalance!");
const Block &B = BlockScope.back();
// Block tail:
// [END_BLOCK, <align4bytes>]
EmitCode(bitc::END_BLOCK);
FlushToWord();
// Compute the size of the block, in words, not counting the size field.
size_t SizeInWords = GetWordIndex() - B.StartSizeWord - 1;
uint64_t BitNo = uint64_t(B.StartSizeWord) * 32;
// Update the block size field in the header of this sub-block.
BackpatchWord(BitNo, SizeInWords);
// Restore the inner block's code size and abbrev table.
CurCodeSize = B.PrevCodeSize;
CurAbbrevs = std::move(B.PrevAbbrevs);
BlockScope.pop_back();
FlushToFile();
}
//===--------------------------------------------------------------------===//
// Record Emission
//===--------------------------------------------------------------------===//
private:
/// EmitAbbreviatedLiteral - Emit a literal value according to its abbrev
/// record. This is a no-op, since the abbrev specifies the literal to use.
template<typename uintty>
void EmitAbbreviatedLiteral(const BitCodeAbbrevOp &Op, uintty V) {
assert(Op.isLiteral() && "Not a literal");
// If the abbrev specifies the literal value to use, don't emit
// anything.
assert(V == Op.getLiteralValue() &&
"Invalid abbrev for record!");
}
/// EmitAbbreviatedField - Emit a single scalar field value with the specified
/// encoding.
template<typename uintty>
void EmitAbbreviatedField(const BitCodeAbbrevOp &Op, uintty V) {
assert(!Op.isLiteral() && "Literals should use EmitAbbreviatedLiteral!");
// Encode the value as we are commanded.
switch (Op.getEncoding()) {
default: llvm_unreachable("Unknown encoding!");
case BitCodeAbbrevOp::Fixed:
if (Op.getEncodingData())
Emit((unsigned)V, (unsigned)Op.getEncodingData());
break;
case BitCodeAbbrevOp::VBR:
if (Op.getEncodingData())
EmitVBR64(V, (unsigned)Op.getEncodingData());
break;
case BitCodeAbbrevOp::Char6:
Emit(BitCodeAbbrevOp::EncodeChar6((char)V), 6);
break;
}
}
/// EmitRecordWithAbbrevImpl - This is the core implementation of the record
/// emission code. If BlobData is non-null, then it specifies an array of
/// data that should be emitted as part of the Blob or Array operand that is
/// known to exist at the end of the record. If Code is specified, then
/// it is the record code to emit before the Vals, which must not contain
/// the code.
template <typename uintty>
void EmitRecordWithAbbrevImpl(unsigned Abbrev, ArrayRef<uintty> Vals,
StringRef Blob, std::optional<unsigned> Code) {
const char *BlobData = Blob.data();
unsigned BlobLen = (unsigned) Blob.size();
unsigned AbbrevNo = Abbrev-bitc::FIRST_APPLICATION_ABBREV;
assert(AbbrevNo < CurAbbrevs.size() && "Invalid abbrev #!");
const BitCodeAbbrev *Abbv = CurAbbrevs[AbbrevNo].get();
EmitCode(Abbrev);
unsigned i = 0, e = static_cast<unsigned>(Abbv->getNumOperandInfos());
if (Code) {
assert(e && "Expected non-empty abbreviation");
const BitCodeAbbrevOp &Op = Abbv->getOperandInfo(i++);
if (Op.isLiteral())
EmitAbbreviatedLiteral(Op, *Code);
else {
assert(Op.getEncoding() != BitCodeAbbrevOp::Array &&
Op.getEncoding() != BitCodeAbbrevOp::Blob &&
"Expected literal or scalar");
EmitAbbreviatedField(Op, *Code);
}
}
unsigned RecordIdx = 0;
for (; i != e; ++i) {
const BitCodeAbbrevOp &Op = Abbv->getOperandInfo(i);
if (Op.isLiteral()) {
assert(RecordIdx < Vals.size() && "Invalid abbrev/record");
EmitAbbreviatedLiteral(Op, Vals[RecordIdx]);
++RecordIdx;
} else if (Op.getEncoding() == BitCodeAbbrevOp::Array) {
// Array case.
assert(i + 2 == e && "array op not second to last?");
const BitCodeAbbrevOp &EltEnc = Abbv->getOperandInfo(++i);
// If this record has blob data, emit it, otherwise we must have record
// entries to encode this way.
if (BlobData) {
assert(RecordIdx == Vals.size() &&
"Blob data and record entries specified for array!");
// Emit a vbr6 to indicate the number of elements present.
EmitVBR(static_cast<uint32_t>(BlobLen), 6);
// Emit each field.
for (unsigned i = 0; i != BlobLen; ++i)
EmitAbbreviatedField(EltEnc, (unsigned char)BlobData[i]);
// Know that blob data is consumed for assertion below.
BlobData = nullptr;
} else {
// Emit a vbr6 to indicate the number of elements present.
EmitVBR(static_cast<uint32_t>(Vals.size()-RecordIdx), 6);
// Emit each field.
for (unsigned e = Vals.size(); RecordIdx != e; ++RecordIdx)
EmitAbbreviatedField(EltEnc, Vals[RecordIdx]);
}
} else if (Op.getEncoding() == BitCodeAbbrevOp::Blob) {
// If this record has blob data, emit it, otherwise we must have record
// entries to encode this way.
if (BlobData) {
assert(RecordIdx == Vals.size() &&
"Blob data and record entries specified for blob operand!");
assert(Blob.data() == BlobData && "BlobData got moved");
assert(Blob.size() == BlobLen && "BlobLen got changed");
emitBlob(Blob);
BlobData = nullptr;
} else {
emitBlob(Vals.slice(RecordIdx));
}
} else { // Single scalar field.
assert(RecordIdx < Vals.size() && "Invalid abbrev/record");
EmitAbbreviatedField(Op, Vals[RecordIdx]);
++RecordIdx;
}
}
assert(RecordIdx == Vals.size() && "Not all record operands emitted!");
assert(BlobData == nullptr &&
"Blob data specified for record that doesn't use it!");
}
public:
/// Emit a blob, including flushing before and tail-padding.
template <class UIntTy>
void emitBlob(ArrayRef<UIntTy> Bytes, bool ShouldEmitSize = true) {
// Emit a vbr6 to indicate the number of elements present.
if (ShouldEmitSize)
EmitVBR(static_cast<uint32_t>(Bytes.size()), 6);
// Flush to a 32-bit alignment boundary.
FlushToWord();
// Emit literal bytes.
assert(llvm::all_of(Bytes, [](UIntTy B) { return isUInt<8>(B); }));
Out.append(Bytes.begin(), Bytes.end());
// Align end to 32-bits.
while (GetBufferOffset() & 3)
Out.push_back(0);
}
void emitBlob(StringRef Bytes, bool ShouldEmitSize = true) {
emitBlob(ArrayRef((const uint8_t *)Bytes.data(), Bytes.size()),
ShouldEmitSize);
}
/// EmitRecord - Emit the specified record to the stream, using an abbrev if
/// we have one to compress the output.
template <typename Container>
void EmitRecord(unsigned Code, const Container &Vals, unsigned Abbrev = 0) {
if (!Abbrev) {
// If we don't have an abbrev to use, emit this in its fully unabbreviated
// form.
auto Count = static_cast<uint32_t>(std::size(Vals));
EmitCode(bitc::UNABBREV_RECORD);
EmitVBR(Code, 6);
EmitVBR(Count, 6);
for (unsigned i = 0, e = Count; i != e; ++i)
EmitVBR64(Vals[i], 6);
return;
}
EmitRecordWithAbbrevImpl(Abbrev, ArrayRef(Vals), StringRef(), Code);
}
/// EmitRecordWithAbbrev - Emit a record with the specified abbreviation.
/// Unlike EmitRecord, the code for the record should be included in Vals as
/// the first entry.
template <typename Container>
void EmitRecordWithAbbrev(unsigned Abbrev, const Container &Vals) {
EmitRecordWithAbbrevImpl(Abbrev, ArrayRef(Vals), StringRef(), std::nullopt);
}
/// EmitRecordWithBlob - Emit the specified record to the stream, using an
/// abbrev that includes a blob at the end. The blob data to emit is
/// specified by the pointer and length specified at the end. In contrast to
/// EmitRecord, this routine expects that the first entry in Vals is the code
/// of the record.
template <typename Container>
void EmitRecordWithBlob(unsigned Abbrev, const Container &Vals,
StringRef Blob) {
EmitRecordWithAbbrevImpl(Abbrev, ArrayRef(Vals), Blob, std::nullopt);
}
template <typename Container>
void EmitRecordWithBlob(unsigned Abbrev, const Container &Vals,
const char *BlobData, unsigned BlobLen) {
return EmitRecordWithAbbrevImpl(Abbrev, ArrayRef(Vals),
StringRef(BlobData, BlobLen), std::nullopt);
}
/// EmitRecordWithArray - Just like EmitRecordWithBlob, works with records
/// that end with an array.
template <typename Container>
void EmitRecordWithArray(unsigned Abbrev, const Container &Vals,
StringRef Array) {
EmitRecordWithAbbrevImpl(Abbrev, ArrayRef(Vals), Array, std::nullopt);
}
template <typename Container>
void EmitRecordWithArray(unsigned Abbrev, const Container &Vals,
const char *ArrayData, unsigned ArrayLen) {
return EmitRecordWithAbbrevImpl(
Abbrev, ArrayRef(Vals), StringRef(ArrayData, ArrayLen), std::nullopt);
}
//===--------------------------------------------------------------------===//
// Abbrev Emission
//===--------------------------------------------------------------------===//
private:
// Emit the abbreviation as a DEFINE_ABBREV record.
void EncodeAbbrev(const BitCodeAbbrev &Abbv) {
EmitCode(bitc::DEFINE_ABBREV);
EmitVBR(Abbv.getNumOperandInfos(), 5);
for (unsigned i = 0, e = static_cast<unsigned>(Abbv.getNumOperandInfos());
i != e; ++i) {
const BitCodeAbbrevOp &Op = Abbv.getOperandInfo(i);
Emit(Op.isLiteral(), 1);
if (Op.isLiteral()) {
EmitVBR64(Op.getLiteralValue(), 8);
} else {
Emit(Op.getEncoding(), 3);
if (Op.hasEncodingData())
EmitVBR64(Op.getEncodingData(), 5);
}
}
}
public:
/// Emits the abbreviation \p Abbv to the stream.
unsigned EmitAbbrev(std::shared_ptr<BitCodeAbbrev> Abbv) {
EncodeAbbrev(*Abbv);
CurAbbrevs.push_back(std::move(Abbv));
return static_cast<unsigned>(CurAbbrevs.size())-1 +
bitc::FIRST_APPLICATION_ABBREV;
}
//===--------------------------------------------------------------------===//
// BlockInfo Block Emission
//===--------------------------------------------------------------------===//
/// EnterBlockInfoBlock - Start emitting the BLOCKINFO_BLOCK.
void EnterBlockInfoBlock() {
EnterSubblock(bitc::BLOCKINFO_BLOCK_ID, 2);
BlockInfoCurBID = ~0U;
BlockInfoRecords.clear();
}
private:
/// SwitchToBlockID - If we aren't already talking about the specified block
/// ID, emit a BLOCKINFO_CODE_SETBID record.
void SwitchToBlockID(unsigned BlockID) {
if (BlockInfoCurBID == BlockID) return;
SmallVector<unsigned, 2> V;
V.push_back(BlockID);
EmitRecord(bitc::BLOCKINFO_CODE_SETBID, V);
BlockInfoCurBID = BlockID;
}
BlockInfo &getOrCreateBlockInfo(unsigned BlockID) {
if (BlockInfo *BI = getBlockInfo(BlockID))
return *BI;
// Otherwise, add a new record.
BlockInfoRecords.emplace_back();
BlockInfoRecords.back().BlockID = BlockID;
return BlockInfoRecords.back();
}
public:
/// EmitBlockInfoAbbrev - Emit a DEFINE_ABBREV record for the specified
/// BlockID.
unsigned EmitBlockInfoAbbrev(unsigned BlockID, std::shared_ptr<BitCodeAbbrev> Abbv) {
SwitchToBlockID(BlockID);
EncodeAbbrev(*Abbv);
// Add the abbrev to the specified block record.
BlockInfo &Info = getOrCreateBlockInfo(BlockID);
Info.Abbrevs.push_back(std::move(Abbv));
return Info.Abbrevs.size()-1+bitc::FIRST_APPLICATION_ABBREV;
}
};
} // End llvm namespace
#endif
#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif
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