isa-l/igzip/igzip_perf.c
Tomasz Kantecki 5a00eaec33 igzip: several fixes for issues reported by static code analysis
Signed-off-by: Tomasz Kantecki <tomasz.kantecki@intel.com>
2023-12-19 20:36:39 +00:00

954 lines
25 KiB
C

/**********************************************************************
Copyright(c) 2011-2018 Intel Corporation All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions
are met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in
the documentation and/or other materials provided with the
distribution.
* Neither the name of Intel Corporation nor the names of its
contributors may be used to endorse or promote products derived
from this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
**********************************************************************/
#define _FILE_OFFSET_BITS 64
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include <getopt.h>
#include "huff_codes.h"
#include "igzip_lib.h"
#include "test.h"
#include <zlib.h>
#define BUF_SIZE 1024
#define OPTARGS "hl:f:z:i:d:stub:y:w:o:D:"
#define COMPRESSION_QUEUE_LIMIT 32
#define UNSET -1
#define xstr(a) str(a)
#define str(a) #a
/* Limit output buffer size to 2 Gigabytes. Since stream->avail_out is a
* uint32_t and there is no logic for handling an overflowed output buffer in
* the perf test, this define must be less then 4 Gigabytes */
#define MAX_COMPRESS_BUF_SIZE (1U << 31)
int level_size_buf[10] = {
#ifdef ISAL_DEF_LVL0_DEFAULT
ISAL_DEF_LVL0_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL1_DEFAULT
ISAL_DEF_LVL1_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL2_DEFAULT
ISAL_DEF_LVL2_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL3_DEFAULT
ISAL_DEF_LVL3_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL4_DEFAULT
ISAL_DEF_LVL4_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL5_DEFAULT
ISAL_DEF_LVL5_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL6_DEFAULT
ISAL_DEF_LVL6_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL7_DEFAULT
ISAL_DEF_LVL7_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL8_DEFAULT
ISAL_DEF_LVL8_DEFAULT,
#else
0,
#endif
#ifdef ISAL_DEF_LVL9_DEFAULT
ISAL_DEF_LVL9_DEFAULT,
#else
0,
#endif
};
enum {
ISAL_STATELESS,
ISAL_STATEFUL,
ISAL_WITH_DICTIONARY,
ZLIB
};
struct compress_strategy {
int32_t mode;
int32_t level;
};
struct inflate_modes {
int32_t stateless;
int32_t stateful;
int32_t zlib;
};
struct perf_info {
char *file_name;
size_t file_size;
size_t deflate_size;
uint32_t inblock_size;
uint32_t flush_type;
int32_t hist_bits;
int32_t deflate_time;
int32_t inflate_time;
struct compress_strategy strategy;
uint32_t inflate_mode;
struct perf start;
};
void init_perf_info(struct perf_info *info)
{
memset(info, 0, sizeof(*info));
info->deflate_time = BENCHMARK_TIME;
info->inflate_time = BENCHMARK_TIME;
}
int usage(void)
{
fprintf(stderr,
"Usage: igzip_perf [options] <infile>\n"
" -h help, print this message\n"
" The options -l, -f, -z may be used up to "
xstr(COMPRESSION_QUEUE_LIMIT) " times\n"
" -l <level> isa-l stateless deflate level to test ("
xstr(ISAL_DEF_MIN_LEVEL) "-" xstr(ISAL_DEF_MAX_LEVEL) ")\n"
" -f <level> isa-l stateful deflate level to test ("
xstr(ISAL_DEF_MIN_LEVEL) "-" xstr(ISAL_DEF_MAX_LEVEL) ")\n"
" -z <level> zlib deflate level to test\n"
" -d <time> approx time in seconds for deflate (at least 0)\n"
" -i <time> approx time in seconds for inflate (at least 0)\n"
" -s performance test isa-l stateful inflate\n"
" -t performance test isa-l stateless inflate\n"
" -u performance test zlib inflate\n"
" -D <file> use dictionary file\n"
" -o <file> output file to store compressed data (last one if multiple)\n"
" -b <size> input buffer size, applies to stateful options (-f,-z,-s)\n"
" -y <type> flush type: 0 (default: no flush), 1 (sync flush), 2 (full flush)\n"
" -w <size> log base 2 size of history window, between 9 and 15\n");
exit(0);
}
void print_perf_info_line(struct perf_info *info)
{
printf("igzip_perf-> compress level: %d flush_type: %d block_size: %d\n",
info->strategy.level, info->flush_type, info->inblock_size);
}
void print_file_line(struct perf_info *info)
{
printf(" file info-> name: %s file_size: %lu compress_size: %lu ratio: %2.02f%%\n",
info->file_name, info->file_size, info->deflate_size,
100.0 * info->deflate_size / info->file_size);
}
void print_deflate_perf_line(struct perf_info *info)
{
if (info->strategy.mode == ISAL_STATELESS)
printf(" isal_stateless_deflate-> ");
else if (info->strategy.mode == ISAL_STATEFUL)
printf(" isal_stateful_deflate-> ");
else if (info->strategy.mode == ISAL_WITH_DICTIONARY)
printf(" isal_dictionary_deflate-> ");
else if (info->strategy.mode == ZLIB)
printf(" zlib_deflate-> ");
perf_print(info->start, info->file_size);
}
void print_inflate_perf_line(struct perf_info *info)
{
if (info->inflate_mode == ISAL_STATELESS)
printf(" isal_stateless_inflate-> ");
else if (info->inflate_mode == ISAL_STATEFUL)
printf(" isal_stateful_inflate-> ");
else if (info->inflate_mode == ISAL_WITH_DICTIONARY)
printf(" isal_dictionary_inflate-> ");
else if (info->inflate_mode == ZLIB)
printf(" zlib_inflate-> ");
perf_print(info->start, info->file_size);
}
int isal_deflate_round(struct isal_zstream *stream, uint8_t * outbuf, uint32_t outbuf_size,
uint8_t * inbuf, uint32_t inbuf_size,
uint32_t level, uint8_t * level_buf, uint32_t level_buf_size,
int flush_type, int hist_bits)
{
int check;
/* Setup stream for stateless compression */
isal_deflate_init(stream);
stream->end_of_stream = 1; /* Do the entire file at once */
stream->flush = flush_type;
stream->next_in = inbuf;
stream->avail_in = inbuf_size;
stream->next_out = outbuf;
stream->avail_out = outbuf_size;
stream->level = level;
stream->level_buf = level_buf;
stream->level_buf_size = level_buf_size;
stream->hist_bits = hist_bits;
/* Compress stream */
check = isal_deflate_stateless(stream);
/* Verify compression success */
if (check || stream->avail_in)
return 1;
return 0;
}
int isal_deflate_dict_round(struct isal_zstream *stream, uint8_t * outbuf,
uint32_t outbuf_size, uint8_t * inbuf,
uint32_t inbuf_size, uint32_t level,
uint8_t * level_buf, uint32_t level_buf_size, int flush_type,
int hist_bits, struct isal_dict *dict_str)
{
int check;
/* Setup stream for compression with dictionary */
isal_deflate_init(stream);
stream->level = level;
stream->level_buf = level_buf;
stream->level_buf_size = level_buf_size;
if (COMP_OK != isal_deflate_reset_dict(stream, dict_str))
return 1;
stream->end_of_stream = 1;
stream->flush = flush_type;
stream->next_in = inbuf;
stream->avail_in = inbuf_size;
stream->next_out = outbuf;
stream->avail_out = outbuf_size;
stream->hist_bits = hist_bits;
check = isal_deflate(stream);
/* Verify Compression Success */
if (COMP_OK != check || stream->avail_in > 0)
return 1;
return 0;
}
int isal_inflate_round(struct inflate_state *state, uint8_t * inbuf, uint32_t inbuf_size,
uint8_t * outbuf, uint32_t outbuf_size, int hist_bits)
{
int check = 0;
/* Setup for stateless inflate */
state->next_in = inbuf;
state->avail_in = inbuf_size;
state->next_out = outbuf;
state->avail_out = outbuf_size;
state->crc_flag = ISAL_DEFLATE;
state->hist_bits = hist_bits;
/* Inflate data */
check = isal_inflate_stateless(state);
/* Verify inflate was successful */
if (check)
return 1;
return 0;
}
int isal_deflate_stateful_round(struct isal_zstream *stream, uint8_t * outbuf,
uint32_t outbuf_size, uint8_t * inbuf,
uint32_t inbuf_size, uint32_t in_block_size, uint32_t level,
uint8_t * level_buf, uint32_t level_buf_size, int flush_type,
int hist_bits)
{
uint64_t inbuf_remaining;
int check = COMP_OK;
/* Setup stream for stateful compression */
inbuf_remaining = inbuf_size;
isal_deflate_init(stream);
stream->flush = flush_type;
stream->next_in = inbuf;
stream->next_out = outbuf;
stream->avail_out = outbuf_size;
stream->level = level;
stream->level_buf = level_buf;
stream->level_buf_size = level_buf_size;
stream->hist_bits = hist_bits;
/* Keep compressing so long as more data is available and no error has
* been hit */
while (COMP_OK == check && inbuf_remaining > in_block_size) {
/* Setup next in buffer, assumes out buffer is sufficiently
* large */
stream->avail_in = in_block_size;
inbuf_remaining -= in_block_size;
/* Compress stream */
check = isal_deflate(stream);
}
/* Finish compressing all remaining input */
if (COMP_OK == check) {
stream->avail_in = inbuf_remaining;
stream->end_of_stream = 1;
check = isal_deflate(stream);
}
/* Verify Compression Success */
if (COMP_OK != check || stream->avail_in > 0)
return 1;
return 0;
}
int isal_inflate_stateful_round(struct inflate_state *state, uint8_t * inbuf,
uint32_t inbuf_size, uint32_t in_block_size, uint8_t * outbuf,
uint32_t outbuf_size, int hist_bits,
uint8_t * dict_buf, int dict_file_size)
{
int check = ISAL_DECOMP_OK;
uint64_t inbuf_remaining;
isal_inflate_init(state);
state->next_in = inbuf;
state->next_out = outbuf;
state->avail_out = outbuf_size;
state->hist_bits = hist_bits;
if (dict_file_size != 0)
isal_inflate_set_dict(state, dict_buf, dict_file_size);
inbuf_remaining = inbuf_size;
while (ISAL_DECOMP_OK == check && inbuf_remaining >= in_block_size) {
state->avail_in = in_block_size;
inbuf_remaining -= in_block_size;
check = isal_inflate(state);
}
if (ISAL_DECOMP_OK == check && inbuf_remaining > 0) {
state->avail_in = inbuf_remaining;
check = isal_inflate(state);
}
if (ISAL_DECOMP_OK != check || state->avail_in > 0)
return 1;
return 0;
}
int zlib_deflate_round(z_stream * gstream, uint8_t * outbuf, uInt outbuf_size,
uint8_t * inbuf, uLong inbuf_size,
uLong in_block_size, int level, int flush_type)
{
uLong inbuf_remaining;
int check = Z_OK;
inbuf_remaining = inbuf_size;
/* Setup stream for stateful compression */
if (0 != deflateReset(gstream))
return 1;
gstream->next_in = inbuf;
gstream->next_out = outbuf;
gstream->avail_out = outbuf_size;
/* Keep compressing so long as more data is available and no error has
* been hit */
while (Z_OK == check && inbuf_remaining > in_block_size) {
gstream->avail_in = in_block_size;
inbuf_remaining -= in_block_size;
check = deflate(gstream, flush_type);
}
/* Finish compressing all remaining input */
if (Z_OK == check) {
gstream->avail_in = inbuf_remaining;
check = deflate(gstream, Z_FINISH);
}
/* Verify Compression Success */
if (Z_STREAM_END != check)
return 1;
return 0;
}
int zlib_inflate_round(z_stream * gstream, uint8_t * inbuf,
uLong inbuf_size, uint8_t * outbuf, uInt outbuf_size)
{
int check = 0;
if (0 != inflateReset(gstream))
return 1;
gstream->next_in = inbuf;
gstream->avail_in = inbuf_size;
gstream->next_out = outbuf;
gstream->avail_out = outbuf_size;
check = inflate(gstream, Z_FINISH);
if (check != Z_STREAM_END)
return 1;
return 0;
}
int isal_deflate_perf(uint8_t * outbuf, uint64_t * outbuf_size, uint8_t * inbuf,
uint64_t inbuf_size, int level, int flush_type, int hist_bits, int time,
struct perf *start)
{
struct isal_zstream stream;
uint8_t *level_buf = NULL;
int check;
if (level_size_buf[level] > 0) {
level_buf = malloc(level_size_buf[level]);
if (level_buf == NULL)
return 1;
}
BENCHMARK(start, time, check =
isal_deflate_round(&stream, outbuf, *outbuf_size, inbuf,
inbuf_size, level, level_buf,
level_size_buf[level], flush_type, hist_bits));
*outbuf_size = stream.total_out;
return check;
}
int isal_deflate_dict_perf(uint8_t * outbuf, uint64_t * outbuf_size, uint8_t * inbuf,
uint64_t inbuf_size, int level, int flush_type, int hist_bits,
int time, struct perf *start, uint8_t * dict_buf,
int dict_file_size)
{
struct isal_zstream stream;
struct isal_dict dict_str;
uint8_t *level_buf = NULL;
int check;
if (level_size_buf[level] > 0) {
level_buf = malloc(level_size_buf[level]);
if (level_buf == NULL)
return 1;
}
stream.level = level;
if (isal_deflate_process_dict(&stream, &dict_str, dict_buf, dict_file_size) != COMP_OK) {
if (level_buf != NULL)
free(level_buf);
return 1;
}
BENCHMARK(start, time, check =
isal_deflate_dict_round(&stream, outbuf, *outbuf_size, inbuf,
inbuf_size, level, level_buf,
level_size_buf[level], flush_type, hist_bits,
&dict_str));
if (level_buf != NULL)
free(level_buf);
*outbuf_size = stream.total_out;
return check;
}
int isal_deflate_stateful_perf(uint8_t * outbuf, uint64_t * outbuf_size, uint8_t * inbuf,
uint64_t inbuf_size, int level, int flush_type,
uint64_t in_block_size, int hist_bits, int time,
struct perf *start)
{
struct isal_zstream stream;
uint8_t *level_buf = NULL;
int check;
if (in_block_size == 0)
in_block_size = inbuf_size;
if (level_size_buf[level] > 0) {
level_buf = malloc(level_size_buf[level]);
if (level_buf == NULL)
return 1;
}
BENCHMARK(start, time, check =
isal_deflate_stateful_round(&stream, outbuf, *outbuf_size, inbuf, inbuf_size,
in_block_size, level, level_buf,
level_size_buf[level], flush_type, hist_bits));
*outbuf_size = stream.total_out;
return check;
}
int zlib_deflate_perf(uint8_t * outbuf, uint64_t * outbuf_size, uint8_t * inbuf,
uint64_t inbuf_size, int level, int flush_type,
uint64_t in_block_size, int hist_bits, int time, struct perf *start)
{
int check;
z_stream gstream;
int flush_translator[] = { Z_NO_FLUSH, Z_SYNC_FLUSH, Z_FULL_FLUSH };
if (in_block_size == 0)
in_block_size = inbuf_size;
flush_type = flush_translator[flush_type];
/* Initialize the gstream buffer */
gstream.next_in = inbuf;
gstream.avail_in = inbuf_size;
gstream.zalloc = Z_NULL;
gstream.zfree = Z_NULL;
gstream.opaque = Z_NULL;
if (hist_bits == 0)
hist_bits = -15;
else
hist_bits = -hist_bits;
if (0 != deflateInit2(&gstream, level, Z_DEFLATED, hist_bits, 9, Z_DEFAULT_STRATEGY))
return 1;
BENCHMARK(start, time, check =
zlib_deflate_round(&gstream, outbuf, *outbuf_size, inbuf, inbuf_size,
in_block_size, level, flush_type));
*outbuf_size = gstream.total_out;
deflateEnd(&gstream);
return check;
}
int isal_inflate_perf(uint8_t * inbuf, uint64_t inbuf_size, uint8_t * outbuf,
uint64_t outbuf_size, uint8_t * filebuf, uint64_t file_size,
int hist_bits, int time, struct perf *start)
{
struct inflate_state state;
int check;
/* Check that data decompresses */
check = isal_inflate_round(&state, inbuf, inbuf_size, outbuf, outbuf_size, hist_bits);
if (check || state.total_out != file_size || memcmp(outbuf, filebuf, file_size))
return 1;
BENCHMARK(start, time, isal_inflate_round(&state, inbuf, inbuf_size,
outbuf, outbuf_size, hist_bits));
return check;
}
int isal_inflate_stateful_perf(uint8_t * inbuf, uint64_t inbuf_size, uint8_t * outbuf,
uint64_t outbuf_size, uint8_t * filebuf, uint64_t file_size,
uint64_t in_block_size, int hist_bits, int time,
struct perf *start, uint8_t * dict_buf, int dict_file_size)
{
struct inflate_state state;
int check;
if (in_block_size == 0)
in_block_size = inbuf_size;
check = isal_inflate_stateful_round(&state, inbuf, inbuf_size, in_block_size, outbuf,
outbuf_size, hist_bits, dict_buf, dict_file_size);
if (check || state.total_out != file_size || memcmp(outbuf, filebuf, file_size))
return 1;
BENCHMARK(start, time,
isal_inflate_stateful_round(&state, inbuf, inbuf_size, in_block_size, outbuf,
outbuf_size, hist_bits, dict_buf,
dict_file_size));
return 0;
}
int zlib_inflate_perf(uint8_t * inbuf, uint64_t inbuf_size, uint8_t * outbuf,
uint64_t outbuf_size, uint8_t * filebuf, uint64_t file_size,
int hist_bits, int time, struct perf *start)
{
int check;
z_stream gstream;
gstream.next_in = inbuf;
gstream.avail_in = inbuf_size;
gstream.zalloc = Z_NULL;
gstream.zfree = Z_NULL;
gstream.opaque = Z_NULL;
if (hist_bits == 0)
hist_bits = -15;
else
hist_bits = -hist_bits;
if (0 != inflateInit2(&gstream, hist_bits))
return 1;
check = zlib_inflate_round(&gstream, inbuf, inbuf_size, outbuf, outbuf_size);
if (check || gstream.total_out != file_size || memcmp(outbuf, filebuf, file_size))
return 1;
BENCHMARK(start, time,
zlib_inflate_round(&gstream, inbuf, inbuf_size, outbuf, outbuf_size));
inflateEnd(&gstream);
return 0;
}
int main(int argc, char *argv[])
{
FILE *in = NULL;
FILE *dict_fn = NULL;
unsigned char *compressbuf, *decompbuf, *filebuf;
char *outfile = NULL;
int i, c, ret = 0;
int dict_file_size = 0;
uint8_t *dict_buf = NULL;
uint64_t decompbuf_size, compressbuf_size;
uint64_t block_count;
struct compress_strategy compression_queue[COMPRESSION_QUEUE_LIMIT];
int compression_queue_size = 0;
struct compress_strategy compress_strat;
struct inflate_modes inflate_strat = { 0 };
struct perf_info info;
init_perf_info(&info);
while ((c = getopt(argc, argv, OPTARGS)) != -1) {
switch (c) {
case 'l':
if (compression_queue_size >= COMPRESSION_QUEUE_LIMIT) {
printf("Too many levels specified");
exit(0);
}
compress_strat.mode = ISAL_STATELESS;
compress_strat.level = atoi(optarg);
if (compress_strat.level > ISAL_DEF_MAX_LEVEL) {
printf("Unsupported isa-l compression level\n");
exit(0);
}
compression_queue[compression_queue_size] = compress_strat;
compression_queue_size++;
break;
case 'f':
if (compression_queue_size >= COMPRESSION_QUEUE_LIMIT) {
printf("Too many levels specified");
exit(0);
}
compress_strat.mode = ISAL_STATEFUL;
compress_strat.level = atoi(optarg);
if (compress_strat.level > ISAL_DEF_MAX_LEVEL) {
printf("Unsupported isa-l compression level\n");
exit(0);
}
compression_queue[compression_queue_size] = compress_strat;
compression_queue_size++;
break;
case 'z':
if (compression_queue_size >= COMPRESSION_QUEUE_LIMIT) {
printf("Too many levels specified");
exit(0);
}
compress_strat.mode = ZLIB;
compress_strat.level = atoi(optarg);
if (compress_strat.level > Z_BEST_COMPRESSION) {
printf("Unsupported zlib compression level\n");
exit(0);
}
compression_queue[compression_queue_size] = compress_strat;
compression_queue_size++;
break;
case 'i':
info.inflate_time = atoi(optarg);
if (info.inflate_time < 0)
usage();
break;
case 'd':
info.deflate_time = atoi(optarg);
if (info.deflate_time < 0)
usage();
break;
case 'D':
dict_fn = fopen(optarg, "rb");
if (!dict_fn) {
printf("Can't open dictionary for reading\n");
exit(0);
}
dict_file_size = get_filesize(dict_fn);
dict_buf = malloc(dict_file_size);
if (dict_buf == NULL || dict_file_size == 0) {
printf("Can't allocate mem for dictionary buffer\n");
exit(0);
}
if (dict_file_size != fread(dict_buf, 1, dict_file_size, dict_fn)) {
printf("Couldn't read all of dictionary file\n");
exit(0);
}
fclose(dict_fn);
break;
case 's':
inflate_strat.stateful = 1;
break;
case 't':
inflate_strat.stateless = 1;
break;
case 'u':
inflate_strat.zlib = 1;
break;
case 'b':
inflate_strat.stateful = 1;
info.inblock_size = atoi(optarg);
break;
case 'y':
info.flush_type = atoi(optarg);
if (info.flush_type != NO_FLUSH && info.flush_type != SYNC_FLUSH
&& info.flush_type != FULL_FLUSH) {
printf("Unsupported flush type\n");
exit(0);
}
break;
case 'w':
info.hist_bits = atoi(optarg);
if (info.hist_bits > 15 || info.hist_bits < 9)
usage();
break;
case 'o':
outfile = optarg;
break;
case 'h':
default:
usage();
break;
}
}
if (optind >= argc)
usage();
if (!inflate_strat.stateless && !inflate_strat.stateful && !inflate_strat.zlib) {
if (info.inblock_size == 0)
inflate_strat.stateless = 1;
else
inflate_strat.stateful = 1;
}
/* Allocate space for entire input file and output
* (assuming some possible expansion on output size)
*/
info.file_name = argv[optind];
in = fopen(info.file_name, "rb");
if (NULL == in) {
printf("Error: Can not find file %s\n", info.file_name);
exit(0);
}
info.file_size = get_filesize(in);
if (info.file_size == 0) {
printf("Error: input file has 0 size\n");
exit(0);
}
decompbuf_size = info.file_size;
if (compression_queue_size == 0) {
if (info.inblock_size == 0)
compression_queue[0].mode = ISAL_STATELESS;
else
compression_queue[0].mode = ISAL_STATEFUL;
compression_queue[0].level = 1;
compression_queue_size = 1;
}
filebuf = malloc(info.file_size);
if (filebuf == NULL) {
fprintf(stderr, "Can't allocate temp buffer memory\n");
exit(0);
}
block_count = 1;
if (info.flush_type > 0)
block_count = (info.file_size + info.inblock_size - 1) / info.inblock_size;
/* Way overestimate likely compressed size to handle bad type 0 and
* small block_size case */
compressbuf_size = block_count * ISAL_DEF_MAX_HDR_SIZE + 2 * info.file_size;
if (compressbuf_size >= MAX_COMPRESS_BUF_SIZE)
compressbuf_size = MAX_COMPRESS_BUF_SIZE;
compressbuf = malloc(compressbuf_size);
if (compressbuf == NULL) {
fprintf(stderr, "Can't allocate input buffer memory\n");
exit(0);
}
decompbuf = malloc(decompbuf_size);
if (decompbuf == NULL) {
fprintf(stderr, "Can't allocate output buffer memory\n");
exit(0);
}
if (info.file_size != fread(filebuf, 1, info.file_size, in)) {
fprintf(stderr, "Could not read in all input\n");
exit(0);
}
fclose(in);
for (i = 0; i < compression_queue_size; i++) {
if (i > 0)
printf("\n\n");
info.strategy = compression_queue[i];
print_perf_info_line(&info);
info.deflate_size = compressbuf_size;
if (dict_file_size != 0) {
info.strategy.mode = ISAL_WITH_DICTIONARY;
ret = isal_deflate_dict_perf(compressbuf, &info.deflate_size,
filebuf, info.file_size,
compression_queue[i].level,
info.flush_type, info.hist_bits,
info.deflate_time, &info.start,
dict_buf, dict_file_size);
} else if (info.strategy.mode == ISAL_STATELESS)
ret = isal_deflate_perf(compressbuf, &info.deflate_size, filebuf,
info.file_size,
compression_queue[i].level,
info.flush_type, info.hist_bits,
info.deflate_time, &info.start);
else if (info.strategy.mode == ISAL_STATEFUL)
ret = isal_deflate_stateful_perf(compressbuf, &info.deflate_size,
filebuf, info.file_size,
compression_queue[i].level,
info.flush_type, info.inblock_size,
info.hist_bits, info.deflate_time,
&info.start);
else if (info.strategy.mode == ZLIB)
ret = zlib_deflate_perf(compressbuf, &info.deflate_size, filebuf,
info.file_size, compression_queue[i].level,
info.flush_type, info.inblock_size,
info.hist_bits, info.deflate_time,
&info.start);
if (ret) {
printf(" Error in compression\n");
continue;
}
print_file_line(&info);
printf("\n");
print_deflate_perf_line(&info);
printf("\n");
if (outfile != NULL && i + 1 == compression_queue_size) {
FILE *out = fopen(outfile, "wb");
if (out == NULL) {
fprintf(stderr, "Could not write to the output file \"%s\"\n",
outfile);
exit(0);
}
fwrite(compressbuf, 1, info.deflate_size, out);
fclose(out);
}
if (info.inflate_time == 0)
continue;
if (inflate_strat.stateless) {
if (dict_file_size != 0)
continue;
info.inflate_mode = ISAL_STATELESS;
ret = isal_inflate_perf(compressbuf, info.deflate_size, decompbuf,
decompbuf_size, filebuf, info.file_size,
info.hist_bits, info.inflate_time,
&info.start);
if (ret)
printf(" Error in isal stateless inflate\n");
else
print_inflate_perf_line(&info);
}
if (inflate_strat.stateful) {
info.inflate_mode =
(dict_file_size == 0) ? ISAL_STATEFUL : ISAL_WITH_DICTIONARY;
ret = isal_inflate_stateful_perf(compressbuf, info.deflate_size,
decompbuf, decompbuf_size, filebuf,
info.file_size, info.inblock_size,
info.hist_bits, info.inflate_time,
&info.start, dict_buf,
dict_file_size);
if (ret)
printf(" Error in isal stateful inflate\n");
else
print_inflate_perf_line(&info);
}
if (inflate_strat.zlib) {
info.inflate_mode = ZLIB;
ret = zlib_inflate_perf(compressbuf, info.deflate_size, decompbuf,
decompbuf_size, filebuf, info.file_size,
info.hist_bits, info.inflate_time,
&info.start);
if (ret)
printf(" Error in zlib inflate\n");
else
print_inflate_perf_line(&info);
}
}
free(compressbuf);
free(decompbuf);
free(filebuf);
if (dict_buf != NULL)
free(dict_buf);
return 0;
}