llvm-6502/lib/Support/Compressor.cpp
Reid Spencer fe07581d78 Make sure that decompression checks for the case that bzip2 returns
BZ_OK (meaning more data is expected) but there is no more input data. In
this case, the input file is probably truncated. Generate an exception that
indicates this case when its detected.


git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@21926 91177308-0d34-0410-b5e6-96231b3b80d8
2005-05-13 07:05:37 +00:00

490 lines
16 KiB
C++

//===- lib/Support/Compressor.cpp -------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file was developed by Reid Spencer and is distributed under the
// University of Illinois Open Source License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the llvm::Compressor class, an abstraction for memory
// block compression.
//
//===----------------------------------------------------------------------===//
#include "llvm/Config/config.h"
#include "llvm/Support/Compressor.h"
#include "llvm/ADT/StringExtras.h"
#include <cassert>
#include <string>
#include <ostream>
#include "bzip2/bzlib.h"
using namespace llvm;
enum CompressionTypes {
COMP_TYPE_NONE = '0',
COMP_TYPE_BZIP2 = '2',
};
static int getdata(char*& buffer, size_t &size,
llvm::Compressor::OutputDataCallback* cb, void* context) {
buffer = 0;
size = 0;
int result = (*cb)(buffer, size, context);
assert(buffer != 0 && "Invalid result from Compressor callback");
assert(size != 0 && "Invalid result from Compressor callback");
return result;
}
static int getdata_uns(char*& buffer, unsigned &size,
llvm::Compressor::OutputDataCallback* cb, void* context)
{
size_t SizeOut;
int Res = getdata(buffer, SizeOut, cb, context);
size = SizeOut;
return Res;
}
//===----------------------------------------------------------------------===//
//=== NULLCOMP - a compression like set of routines that just copies data
//=== without doing any compression. This is provided so that if the
//=== configured environment doesn't have a compression library the
//=== program can still work, albeit using more data/memory.
//===----------------------------------------------------------------------===//
struct NULLCOMP_stream {
// User provided fields
char* next_in;
size_t avail_in;
char* next_out;
size_t avail_out;
// Information fields
size_t output_count; // Total count of output bytes
};
static void NULLCOMP_init(NULLCOMP_stream* s) {
s->output_count = 0;
}
static bool NULLCOMP_compress(NULLCOMP_stream* s) {
assert(s && "Invalid NULLCOMP_stream");
assert(s->next_in != 0);
assert(s->next_out != 0);
assert(s->avail_in >= 1);
assert(s->avail_out >= 1);
if (s->avail_out >= s->avail_in) {
::memcpy(s->next_out, s->next_in, s->avail_in);
s->output_count += s->avail_in;
s->avail_out -= s->avail_in;
s->next_in += s->avail_in;
s->avail_in = 0;
return true;
} else {
::memcpy(s->next_out, s->next_in, s->avail_out);
s->output_count += s->avail_out;
s->avail_in -= s->avail_out;
s->next_in += s->avail_out;
s->avail_out = 0;
return false;
}
}
static bool NULLCOMP_decompress(NULLCOMP_stream* s) {
assert(s && "Invalid NULLCOMP_stream");
assert(s->next_in != 0);
assert(s->next_out != 0);
assert(s->avail_in >= 1);
assert(s->avail_out >= 1);
if (s->avail_out >= s->avail_in) {
::memcpy(s->next_out, s->next_in, s->avail_in);
s->output_count += s->avail_in;
s->avail_out -= s->avail_in;
s->next_in += s->avail_in;
s->avail_in = 0;
return true;
} else {
::memcpy(s->next_out, s->next_in, s->avail_out);
s->output_count += s->avail_out;
s->avail_in -= s->avail_out;
s->next_in += s->avail_out;
s->avail_out = 0;
return false;
}
}
static void NULLCOMP_end(NULLCOMP_stream* strm) {
}
namespace {
/// This structure is only used when a bytecode file is compressed.
/// As bytecode is being decompressed, the memory buffer might need
/// to be reallocated. The buffer allocation is handled in a callback
/// and this structure is needed to retain information across calls
/// to the callback.
/// @brief An internal buffer object used for handling decompression
struct BufferContext {
char* buff;
size_t size;
BufferContext(size_t compressedSize) {
// Null to indicate malloc of a new block
buff = 0;
// Compute the initial length of the uncompression buffer. Note that this
// is twice the length of the compressed buffer and will be doubled again
// in the callback for an initial allocation of 4x compressedSize. This
// calculation is based on the typical compression ratio of bzip2 on LLVM
// bytecode files which typically ranges in the 50%-75% range. Since we
// typically get at least 50%, doubling is insufficient. By using a 4x
// multiplier on the first allocation, we minimize the impact of having to
// copy the buffer on reallocation.
size = compressedSize*2;
}
/// trimTo - Reduce the size of the buffer down to the specified amount. This
/// is useful after have read in the bytecode file to discard extra unused
/// memory.
///
void trimTo(size_t NewSize) {
buff = (char*)::realloc(buff, NewSize);
size = NewSize;
}
/// This function handles allocation of the buffer used for decompression of
/// compressed bytecode files. It is called by Compressor::decompress which is
/// called by BytecodeReader::ParseBytecode.
static size_t callback(char*&buff, size_t &sz, void* ctxt){
// Case the context variable to our BufferContext
BufferContext* bc = reinterpret_cast<BufferContext*>(ctxt);
// Compute the new, doubled, size of the block
size_t new_size = bc->size * 2;
// Extend or allocate the block (realloc(0,n) == malloc(n))
char* new_buff = (char*) ::realloc(bc->buff, new_size);
// Figure out what to return to the Compressor. If this is the first call,
// then bc->buff will be null. In this case we want to return the entire
// buffer because there was no previous allocation. Otherwise, when the
// buffer is reallocated, we save the new base pointer in the
// BufferContext.buff field but return the address of only the extension,
// mid-way through the buffer (since its size was doubled). Furthermore,
// the sz result must be 1/2 the total size of the buffer.
if (bc->buff == 0 ) {
buff = bc->buff = new_buff;
sz = new_size;
} else {
bc->buff = new_buff;
buff = new_buff + bc->size;
sz = bc->size;
}
// Retain the size of the allocated block
bc->size = new_size;
// Make sure we fail (return 1) if we didn't get any memory.
return (bc->buff == 0 ? 1 : 0);
}
};
} // end anonymous namespace
namespace {
// This structure retains the context when compressing the bytecode file. The
// WriteCompressedData function below uses it to keep track of the previously
// filled chunk of memory (which it writes) and how many bytes have been
// written.
struct WriterContext {
// Initialize the context
WriterContext(std::ostream*OS, size_t CS)
: chunk(0), sz(0), written(0), compSize(CS), Out(OS) {}
// Make sure we clean up memory
~WriterContext() {
if (chunk)
delete [] chunk;
}
// Write the chunk
void write(size_t size = 0) {
size_t write_size = (size == 0 ? sz : size);
Out->write(chunk,write_size);
written += write_size;
delete [] chunk;
chunk = 0;
sz = 0;
}
// This function is a callback used by the Compressor::compress function to
// allocate memory for the compression buffer. This function fulfills that
// responsibility but also writes the previous (now filled) buffer out to the
// stream.
static size_t callback(char*& buffer, size_t &size, void* context) {
// Cast the context to the structure it must point to.
WriterContext* ctxt = reinterpret_cast<WriterContext*>(context);
// If there's a previously allocated chunk, it must now be filled with
// compressed data, so we write it out and deallocate it.
if (ctxt->chunk != 0 && ctxt->sz > 0 ) {
ctxt->write();
}
// Compute the size of the next chunk to allocate. We attempt to allocate
// enough memory to handle the compression in a single memory allocation. In
// general, the worst we do on compression of bytecode is about 50% so we
// conservatively estimate compSize / 2 as the size needed for the
// compression buffer. compSize is the size of the compressed data, provided
// by WriteBytecodeToFile.
size = ctxt->sz = ctxt->compSize / 2;
// Allocate the chunks
buffer = ctxt->chunk = new char [size];
// We must return 1 if the allocation failed so that the Compressor knows
// not to use the buffer pointer.
return (ctxt->chunk == 0 ? 1 : 0);
}
char* chunk; // pointer to the chunk of memory filled by compression
size_t sz; // size of chunk
size_t written; // aggregate total of bytes written in all chunks
size_t compSize; // size of the uncompressed buffer
std::ostream* Out; // The stream we write the data to.
};
} // end anonymous namespace
// Compress in one of three ways
size_t Compressor::compress(const char* in, size_t size,
OutputDataCallback* cb, void* context) {
assert(in && "Can't compress null buffer");
assert(size && "Can't compress empty buffer");
assert(cb && "Can't compress without a callback function");
size_t result = 0;
// For small files, we just don't bother compressing. bzip2 isn't very good
// with tiny files and can actually make the file larger, so we just avoid
// it altogether.
if (size > 64*1024) {
// Set up the bz_stream
bz_stream bzdata;
bzdata.bzalloc = 0;
bzdata.bzfree = 0;
bzdata.opaque = 0;
bzdata.next_in = (char*)in;
bzdata.avail_in = size;
bzdata.next_out = 0;
bzdata.avail_out = 0;
switch ( BZ2_bzCompressInit(&bzdata, 5, 0, 100) ) {
case BZ_CONFIG_ERROR: throw std::string("bzip2 library mis-compiled");
case BZ_PARAM_ERROR: throw std::string("Compressor internal error");
case BZ_MEM_ERROR: throw std::string("Out of memory");
case BZ_OK:
default:
break;
}
// Get a block of memory
if (0 != getdata_uns(bzdata.next_out, bzdata.avail_out,cb,context)) {
BZ2_bzCompressEnd(&bzdata);
throw std::string("Can't allocate output buffer");
}
// Put compression code in first byte
(*bzdata.next_out++) = COMP_TYPE_BZIP2;
bzdata.avail_out--;
// Compress it
int bzerr = BZ_FINISH_OK;
while (BZ_FINISH_OK == (bzerr = BZ2_bzCompress(&bzdata, BZ_FINISH))) {
if (0 != getdata_uns(bzdata.next_out, bzdata.avail_out,cb,context)) {
BZ2_bzCompressEnd(&bzdata);
throw std::string("Can't allocate output buffer");
}
}
switch (bzerr) {
case BZ_SEQUENCE_ERROR:
case BZ_PARAM_ERROR: throw std::string("Param/Sequence error");
case BZ_FINISH_OK:
case BZ_STREAM_END: break;
default: throw std::string("Oops: ") + utostr(unsigned(bzerr));
}
// Finish
result = bzdata.total_out_lo32 + 1;
if (sizeof(size_t) == sizeof(uint64_t))
result |= static_cast<uint64_t>(bzdata.total_out_hi32) << 32;
BZ2_bzCompressEnd(&bzdata);
} else {
// Do null compression, for small files
NULLCOMP_stream sdata;
sdata.next_in = (char*)in;
sdata.avail_in = size;
NULLCOMP_init(&sdata);
if (0 != getdata(sdata.next_out, sdata.avail_out,cb,context)) {
throw std::string("Can't allocate output buffer");
}
*(sdata.next_out++) = COMP_TYPE_NONE;
sdata.avail_out--;
while (!NULLCOMP_compress(&sdata)) {
if (0 != getdata(sdata.next_out, sdata.avail_out,cb,context)) {
throw std::string("Can't allocate output buffer");
}
}
result = sdata.output_count + 1;
NULLCOMP_end(&sdata);
}
return result;
}
size_t Compressor::compressToNewBuffer(const char* in, size_t size, char*&out) {
BufferContext bc(size);
size_t result = compress(in,size,BufferContext::callback,(void*)&bc);
bc.trimTo(result);
out = bc.buff;
return result;
}
size_t
Compressor::compressToStream(const char*in, size_t size, std::ostream& out) {
// Set up the context and writer
WriterContext ctxt(&out, size / 2);
// Compress everything after the magic number (which we'll alter).
size_t zipSize = Compressor::compress(in,size,
WriterContext::callback, (void*)&ctxt);
if (ctxt.chunk) {
ctxt.write(zipSize - ctxt.written);
}
return zipSize;
}
// Decompress in one of three ways
size_t Compressor::decompress(const char *in, size_t size,
OutputDataCallback* cb, void* context) {
assert(in && "Can't decompress null buffer");
assert(size > 1 && "Can't decompress empty buffer");
assert(cb && "Can't decompress without a callback function");
size_t result = 0;
switch (*in++) {
case COMP_TYPE_BZIP2: {
// Set up the bz_stream
bz_stream bzdata;
bzdata.bzalloc = 0;
bzdata.bzfree = 0;
bzdata.opaque = 0;
bzdata.next_in = (char*)in;
bzdata.avail_in = size - 1;
bzdata.next_out = 0;
bzdata.avail_out = 0;
switch ( BZ2_bzDecompressInit(&bzdata, 0, 0) ) {
case BZ_CONFIG_ERROR: throw std::string("bzip2 library mis-compiled");
case BZ_PARAM_ERROR: throw std::string("Compressor internal error");
case BZ_MEM_ERROR: throw std::string("Out of memory");
case BZ_OK:
default:
break;
}
// Get a block of memory
if (0 != getdata_uns(bzdata.next_out, bzdata.avail_out,cb,context)) {
BZ2_bzDecompressEnd(&bzdata);
throw std::string("Can't allocate output buffer");
}
// Decompress it
int bzerr = BZ_OK;
while ( BZ_OK == (bzerr = BZ2_bzDecompress(&bzdata)) &&
bzdata.avail_in != 0 ) {
if (0 != getdata_uns(bzdata.next_out, bzdata.avail_out,cb,context)) {
BZ2_bzDecompressEnd(&bzdata);
throw std::string("Can't allocate output buffer");
}
}
switch (bzerr) {
case BZ_PARAM_ERROR: throw std::string("Compressor internal error");
case BZ_MEM_ERROR: throw std::string("Out of memory");
case BZ_DATA_ERROR: throw std::string("Data integrity error");
case BZ_DATA_ERROR_MAGIC:throw std::string("Data is not BZIP2");
case BZ_OK: throw std::string("Insufficient input for bzip2");
case BZ_STREAM_END: break;
default: throw("Ooops");
}
// Finish
result = bzdata.total_out_lo32;
if (sizeof(size_t) == sizeof(uint64_t))
result |= (static_cast<uint64_t>(bzdata.total_out_hi32) << 32);
BZ2_bzDecompressEnd(&bzdata);
break;
}
case COMP_TYPE_NONE: {
NULLCOMP_stream sdata;
sdata.next_in = (char*)in;
sdata.avail_in = size - 1;
NULLCOMP_init(&sdata);
if (0 != getdata(sdata.next_out, sdata.avail_out,cb,context)) {
throw std::string("Can't allocate output buffer");
}
while (!NULLCOMP_decompress(&sdata)) {
if (0 != getdata(sdata.next_out, sdata.avail_out,cb,context)) {
throw std::string("Can't allocate output buffer");
}
}
result = sdata.output_count;
NULLCOMP_end(&sdata);
break;
}
default:
throw std::string("Unknown type of compressed data");
}
return result;
}
size_t
Compressor::decompressToNewBuffer(const char* in, size_t size, char*&out) {
BufferContext bc(size);
size_t result = decompress(in,size,BufferContext::callback,(void*)&bc);
out = bc.buff;
return result;
}
size_t
Compressor::decompressToStream(const char*in, size_t size, std::ostream& out){
// Set up the context and writer
WriterContext ctxt(&out,size / 2);
// Decompress everything after the magic number (which we'll alter)
size_t zipSize = Compressor::decompress(in,size,
WriterContext::callback, (void*)&ctxt);
if (ctxt.chunk) {
ctxt.write(zipSize - ctxt.written);
}
return zipSize;
}
// vim: sw=2 ai