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FFmpeg/libavcodec/put_bits.h

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/*
* copyright (c) 2004 Michael Niedermayer <michaelni@gmx.at>
*
* This file is part of FFmpeg.
*
* FFmpeg is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* FFmpeg is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with FFmpeg; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
*/
/**
* @file
* bitstream writer API
*/
#ifndef AVCODEC_PUT_BITS_H
#define AVCODEC_PUT_BITS_H
#include <stdint.h>
#include <stddef.h>
avcodec/put_bits: Make bit buffers 64-bit Change BitBuf into uint64_t on 64-bit x86. This means we need to flush the buffer less often, which is a significant speed win. All other platforms, including all 32-bit ones, are unchanged. Output bitstream is the same. All API constraints are kept in place, e.g., you still cannot put_bits() more than 31 bits at a time. This is so that codecs cannot accidentally become 64-bit-only or similar. Benchmarking on transcoding to various formats shows consistently positive results: dnxhd 25.60 fps -> 26.26 fps ( +2.6%) dvvideo 24.88 fps -> 25.17 fps ( +1.2%) ffv1 14.32 fps -> 14.58 fps ( +1.8%) huffyuv 58.75 fps -> 63.27 fps ( +7.7%) jpegls 6.22 fps -> 6.34 fps ( +1.8%) magicyuv 57.10 fps -> 63.29 fps (+10.8%) mjpeg 48.65 fps -> 49.01 fps ( +0.7%) mpeg1video 76.41 fps -> 77.01 fps ( +0.8%) mpeg2video 75.99 fps -> 77.43 fps ( +1.9%) mpeg4 80.66 fps -> 81.37 fps ( +0.9%) prores 12.35 fps -> 12.88 fps ( +4.3%) prores_ks 16.20 fps -> 16.80 fps ( +3.7%) rv20 62.80 fps -> 62.99 fps ( +0.3%) utvideo 68.41 fps -> 76.32 fps (+11.6%) Note that this includes video decoding and all other encoding work, such as DCTs. If you isolate the actual bit-writing routines, it is likely to be much more. Benchmark details: Transcoding the first 30 seconds of Big Buck Bunny in 1080p, Haswell 2.1 GHz, GCC 8.3, generally quantizer locked to 5.0. (Exceptions: DNxHD needs fixed bitrate, and JPEG-LS is so slow that I only took the first 10 seconds, not 30.) All runs were done ten times and single-threaded, top and bottom two results discarded to get rid of outliers, arithmetic mean between the remaining six. Signed-off-by: Michael Niedermayer <michael@niedermayer.cc>
2020-07-18 16:53:03 +02:00
#include "config.h"
#include "libavutil/intreadwrite.h"
#include "libavutil/avassert.h"
#include "libavutil/common.h"
avcodec/put_bits: Make bit buffers 64-bit Change BitBuf into uint64_t on 64-bit x86. This means we need to flush the buffer less often, which is a significant speed win. All other platforms, including all 32-bit ones, are unchanged. Output bitstream is the same. All API constraints are kept in place, e.g., you still cannot put_bits() more than 31 bits at a time. This is so that codecs cannot accidentally become 64-bit-only or similar. Benchmarking on transcoding to various formats shows consistently positive results: dnxhd 25.60 fps -> 26.26 fps ( +2.6%) dvvideo 24.88 fps -> 25.17 fps ( +1.2%) ffv1 14.32 fps -> 14.58 fps ( +1.8%) huffyuv 58.75 fps -> 63.27 fps ( +7.7%) jpegls 6.22 fps -> 6.34 fps ( +1.8%) magicyuv 57.10 fps -> 63.29 fps (+10.8%) mjpeg 48.65 fps -> 49.01 fps ( +0.7%) mpeg1video 76.41 fps -> 77.01 fps ( +0.8%) mpeg2video 75.99 fps -> 77.43 fps ( +1.9%) mpeg4 80.66 fps -> 81.37 fps ( +0.9%) prores 12.35 fps -> 12.88 fps ( +4.3%) prores_ks 16.20 fps -> 16.80 fps ( +3.7%) rv20 62.80 fps -> 62.99 fps ( +0.3%) utvideo 68.41 fps -> 76.32 fps (+11.6%) Note that this includes video decoding and all other encoding work, such as DCTs. If you isolate the actual bit-writing routines, it is likely to be much more. Benchmark details: Transcoding the first 30 seconds of Big Buck Bunny in 1080p, Haswell 2.1 GHz, GCC 8.3, generally quantizer locked to 5.0. (Exceptions: DNxHD needs fixed bitrate, and JPEG-LS is so slow that I only took the first 10 seconds, not 30.) All runs were done ten times and single-threaded, top and bottom two results discarded to get rid of outliers, arithmetic mean between the remaining six. Signed-off-by: Michael Niedermayer <michael@niedermayer.cc>
2020-07-18 16:53:03 +02:00
#if ARCH_X86_64
// TODO: Benchmark and optionally enable on other 64-bit architectures.
typedef uint64_t BitBuf;
#define AV_WBBUF AV_WB64
#define AV_WLBUF AV_WL64
#else
typedef uint32_t BitBuf;
#define AV_WBBUF AV_WB32
#define AV_WLBUF AV_WL32
avcodec/put_bits: Make bit buffers 64-bit Change BitBuf into uint64_t on 64-bit x86. This means we need to flush the buffer less often, which is a significant speed win. All other platforms, including all 32-bit ones, are unchanged. Output bitstream is the same. All API constraints are kept in place, e.g., you still cannot put_bits() more than 31 bits at a time. This is so that codecs cannot accidentally become 64-bit-only or similar. Benchmarking on transcoding to various formats shows consistently positive results: dnxhd 25.60 fps -> 26.26 fps ( +2.6%) dvvideo 24.88 fps -> 25.17 fps ( +1.2%) ffv1 14.32 fps -> 14.58 fps ( +1.8%) huffyuv 58.75 fps -> 63.27 fps ( +7.7%) jpegls 6.22 fps -> 6.34 fps ( +1.8%) magicyuv 57.10 fps -> 63.29 fps (+10.8%) mjpeg 48.65 fps -> 49.01 fps ( +0.7%) mpeg1video 76.41 fps -> 77.01 fps ( +0.8%) mpeg2video 75.99 fps -> 77.43 fps ( +1.9%) mpeg4 80.66 fps -> 81.37 fps ( +0.9%) prores 12.35 fps -> 12.88 fps ( +4.3%) prores_ks 16.20 fps -> 16.80 fps ( +3.7%) rv20 62.80 fps -> 62.99 fps ( +0.3%) utvideo 68.41 fps -> 76.32 fps (+11.6%) Note that this includes video decoding and all other encoding work, such as DCTs. If you isolate the actual bit-writing routines, it is likely to be much more. Benchmark details: Transcoding the first 30 seconds of Big Buck Bunny in 1080p, Haswell 2.1 GHz, GCC 8.3, generally quantizer locked to 5.0. (Exceptions: DNxHD needs fixed bitrate, and JPEG-LS is so slow that I only took the first 10 seconds, not 30.) All runs were done ten times and single-threaded, top and bottom two results discarded to get rid of outliers, arithmetic mean between the remaining six. Signed-off-by: Michael Niedermayer <michael@niedermayer.cc>
2020-07-18 16:53:03 +02:00
#endif
static const int BUF_BITS = 8 * sizeof(BitBuf);
typedef struct PutBitContext {
BitBuf bit_buf;
int bit_left;
uint8_t *buf, *buf_ptr, *buf_end;
} PutBitContext;
/**
* Initialize the PutBitContext s.
*
* @param buffer the buffer where to put bits
* @param buffer_size the size in bytes of buffer
*/
static inline void init_put_bits(PutBitContext *s, uint8_t *buffer,
int buffer_size)
{
if (buffer_size < 0) {
buffer_size = 0;
buffer = NULL;
}
s->buf = buffer;
s->buf_end = s->buf + buffer_size;
s->buf_ptr = s->buf;
s->bit_left = BUF_BITS;
s->bit_buf = 0;
}
/**
* @return the total number of bits written to the bitstream.
*/
static inline int put_bits_count(PutBitContext *s)
{
return (s->buf_ptr - s->buf) * 8 + BUF_BITS - s->bit_left;
}
/**
* @return the number of bytes output so far; may only be called
* when the PutBitContext is freshly initialized or flushed.
*/
static inline int put_bytes_output(const PutBitContext *s)
{
av_assert2(s->bit_left == BUF_BITS);
return s->buf_ptr - s->buf;
}
/**
* @param round_up When set, the number of bits written so far will be
* rounded up to the next byte.
* @return the number of bytes output so far.
*/
static inline int put_bytes_count(const PutBitContext *s, int round_up)
{
return s->buf_ptr - s->buf + ((BUF_BITS - s->bit_left + (round_up ? 7 : 0)) >> 3);
}
/**
* Rebase the bit writer onto a reallocated buffer.
*
* @param buffer the buffer where to put bits
* @param buffer_size the size in bytes of buffer,
* must be large enough to hold everything written so far
*/
static inline void rebase_put_bits(PutBitContext *s, uint8_t *buffer,
int buffer_size)
{
av_assert0(8*buffer_size >= put_bits_count(s));
s->buf_end = buffer + buffer_size;
s->buf_ptr = buffer + (s->buf_ptr - s->buf);
s->buf = buffer;
}
2013-06-28 04:40:35 +03:00
/**
* @return the number of bits available in the bitstream.
*/
static inline int put_bits_left(PutBitContext* s)
{
return (s->buf_end - s->buf_ptr) * 8 - BUF_BITS + s->bit_left;
2013-06-28 04:40:35 +03:00
}
/**
* @param round_up When set, the number of bits written will be
* rounded up to the next byte.
* @return the number of bytes left.
*/
static inline int put_bytes_left(const PutBitContext *s, int round_up)
{
return s->buf_end - s->buf_ptr - ((BUF_BITS - s->bit_left + (round_up ? 7 : 0)) >> 3);
}
/**
* Pad the end of the output stream with zeros.
*/
static inline void flush_put_bits(PutBitContext *s)
{
#ifndef BITSTREAM_WRITER_LE
if (s->bit_left < BUF_BITS)
s->bit_buf <<= s->bit_left;
#endif
while (s->bit_left < BUF_BITS) {
av_assert0(s->buf_ptr < s->buf_end);
#ifdef BITSTREAM_WRITER_LE
*s->buf_ptr++ = s->bit_buf;
s->bit_buf >>= 8;
#else
*s->buf_ptr++ = s->bit_buf >> (BUF_BITS - 8);
s->bit_buf <<= 8;
#endif
s->bit_left += 8;
}
s->bit_left = BUF_BITS;
s->bit_buf = 0;
}
static inline void flush_put_bits_le(PutBitContext *s)
{
while (s->bit_left < BUF_BITS) {
av_assert0(s->buf_ptr < s->buf_end);
*s->buf_ptr++ = s->bit_buf;
s->bit_buf >>= 8;
s->bit_left += 8;
}
s->bit_left = BUF_BITS;
s->bit_buf = 0;
}
#ifdef BITSTREAM_WRITER_LE
#define ff_put_string ff_put_string_unsupported_here
#define ff_copy_bits ff_copy_bits_unsupported_here
#else
/**
* Put the string string in the bitstream.
*
* @param terminate_string 0-terminates the written string if value is 1
*/
void ff_put_string(PutBitContext *pb, const char *string,
int terminate_string);
/**
* Copy the content of src to the bitstream.
*
* @param length the number of bits of src to copy
*/
void ff_copy_bits(PutBitContext *pb, const uint8_t *src, int length);
#endif
avcodec/put_bits: Make bit buffers 64-bit Change BitBuf into uint64_t on 64-bit x86. This means we need to flush the buffer less often, which is a significant speed win. All other platforms, including all 32-bit ones, are unchanged. Output bitstream is the same. All API constraints are kept in place, e.g., you still cannot put_bits() more than 31 bits at a time. This is so that codecs cannot accidentally become 64-bit-only or similar. Benchmarking on transcoding to various formats shows consistently positive results: dnxhd 25.60 fps -> 26.26 fps ( +2.6%) dvvideo 24.88 fps -> 25.17 fps ( +1.2%) ffv1 14.32 fps -> 14.58 fps ( +1.8%) huffyuv 58.75 fps -> 63.27 fps ( +7.7%) jpegls 6.22 fps -> 6.34 fps ( +1.8%) magicyuv 57.10 fps -> 63.29 fps (+10.8%) mjpeg 48.65 fps -> 49.01 fps ( +0.7%) mpeg1video 76.41 fps -> 77.01 fps ( +0.8%) mpeg2video 75.99 fps -> 77.43 fps ( +1.9%) mpeg4 80.66 fps -> 81.37 fps ( +0.9%) prores 12.35 fps -> 12.88 fps ( +4.3%) prores_ks 16.20 fps -> 16.80 fps ( +3.7%) rv20 62.80 fps -> 62.99 fps ( +0.3%) utvideo 68.41 fps -> 76.32 fps (+11.6%) Note that this includes video decoding and all other encoding work, such as DCTs. If you isolate the actual bit-writing routines, it is likely to be much more. Benchmark details: Transcoding the first 30 seconds of Big Buck Bunny in 1080p, Haswell 2.1 GHz, GCC 8.3, generally quantizer locked to 5.0. (Exceptions: DNxHD needs fixed bitrate, and JPEG-LS is so slow that I only took the first 10 seconds, not 30.) All runs were done ten times and single-threaded, top and bottom two results discarded to get rid of outliers, arithmetic mean between the remaining six. Signed-off-by: Michael Niedermayer <michael@niedermayer.cc>
2020-07-18 16:53:03 +02:00
static inline void put_bits_no_assert(PutBitContext *s, int n, BitBuf value)
{
BitBuf bit_buf;
int bit_left;
bit_buf = s->bit_buf;
bit_left = s->bit_left;
/* XXX: optimize */
#ifdef BITSTREAM_WRITER_LE
bit_buf |= value << (BUF_BITS - bit_left);
if (n >= bit_left) {
if (s->buf_end - s->buf_ptr >= sizeof(BitBuf)) {
AV_WLBUF(s->buf_ptr, bit_buf);
s->buf_ptr += sizeof(BitBuf);
} else {
av_log(NULL, AV_LOG_ERROR, "Internal error, put_bits buffer too small\n");
av_assert2(0);
}
bit_buf = value >> bit_left;
bit_left += BUF_BITS;
}
bit_left -= n;
#else
if (n < bit_left) {
bit_buf = (bit_buf << n) | value;
bit_left -= n;
} else {
bit_buf <<= bit_left;
bit_buf |= value >> (n - bit_left);
if (s->buf_end - s->buf_ptr >= sizeof(BitBuf)) {
AV_WBBUF(s->buf_ptr, bit_buf);
s->buf_ptr += sizeof(BitBuf);
} else {
av_log(NULL, AV_LOG_ERROR, "Internal error, put_bits buffer too small\n");
av_assert2(0);
}
bit_left += BUF_BITS - n;
bit_buf = value;
}
#endif
s->bit_buf = bit_buf;
s->bit_left = bit_left;
}
avcodec/put_bits: Make bit buffers 64-bit Change BitBuf into uint64_t on 64-bit x86. This means we need to flush the buffer less often, which is a significant speed win. All other platforms, including all 32-bit ones, are unchanged. Output bitstream is the same. All API constraints are kept in place, e.g., you still cannot put_bits() more than 31 bits at a time. This is so that codecs cannot accidentally become 64-bit-only or similar. Benchmarking on transcoding to various formats shows consistently positive results: dnxhd 25.60 fps -> 26.26 fps ( +2.6%) dvvideo 24.88 fps -> 25.17 fps ( +1.2%) ffv1 14.32 fps -> 14.58 fps ( +1.8%) huffyuv 58.75 fps -> 63.27 fps ( +7.7%) jpegls 6.22 fps -> 6.34 fps ( +1.8%) magicyuv 57.10 fps -> 63.29 fps (+10.8%) mjpeg 48.65 fps -> 49.01 fps ( +0.7%) mpeg1video 76.41 fps -> 77.01 fps ( +0.8%) mpeg2video 75.99 fps -> 77.43 fps ( +1.9%) mpeg4 80.66 fps -> 81.37 fps ( +0.9%) prores 12.35 fps -> 12.88 fps ( +4.3%) prores_ks 16.20 fps -> 16.80 fps ( +3.7%) rv20 62.80 fps -> 62.99 fps ( +0.3%) utvideo 68.41 fps -> 76.32 fps (+11.6%) Note that this includes video decoding and all other encoding work, such as DCTs. If you isolate the actual bit-writing routines, it is likely to be much more. Benchmark details: Transcoding the first 30 seconds of Big Buck Bunny in 1080p, Haswell 2.1 GHz, GCC 8.3, generally quantizer locked to 5.0. (Exceptions: DNxHD needs fixed bitrate, and JPEG-LS is so slow that I only took the first 10 seconds, not 30.) All runs were done ten times and single-threaded, top and bottom two results discarded to get rid of outliers, arithmetic mean between the remaining six. Signed-off-by: Michael Niedermayer <michael@niedermayer.cc>
2020-07-18 16:53:03 +02:00
/**
* Write up to 31 bits into a bitstream.
* Use put_bits32 to write 32 bits.
*/
static inline void put_bits(PutBitContext *s, int n, BitBuf value)
{
av_assert2(n <= 31 && value < (1UL << n));
put_bits_no_assert(s, n, value);
}
static inline void put_bits_le(PutBitContext *s, int n, BitBuf value)
{
BitBuf bit_buf;
int bit_left;
av_assert2(n <= 31 && value < (1UL << n));
bit_buf = s->bit_buf;
bit_left = s->bit_left;
bit_buf |= value << (BUF_BITS - bit_left);
if (n >= bit_left) {
if (s->buf_end - s->buf_ptr >= sizeof(BitBuf)) {
AV_WLBUF(s->buf_ptr, bit_buf);
s->buf_ptr += sizeof(BitBuf);
} else {
av_log(NULL, AV_LOG_ERROR, "Internal error, put_bits buffer too small\n");
av_assert2(0);
}
bit_buf = value >> bit_left;
bit_left += BUF_BITS;
}
bit_left -= n;
s->bit_buf = bit_buf;
s->bit_left = bit_left;
}
static inline void put_sbits(PutBitContext *pb, int n, int32_t value)
{
av_assert2(n >= 0 && n <= 31);
put_bits(pb, n, av_mod_uintp2(value, n));
}
/**
* Write exactly 32 bits into a bitstream.
*/
static void av_unused put_bits32(PutBitContext *s, uint32_t value)
{
BitBuf bit_buf;
int bit_left;
avcodec/put_bits: Make bit buffers 64-bit Change BitBuf into uint64_t on 64-bit x86. This means we need to flush the buffer less often, which is a significant speed win. All other platforms, including all 32-bit ones, are unchanged. Output bitstream is the same. All API constraints are kept in place, e.g., you still cannot put_bits() more than 31 bits at a time. This is so that codecs cannot accidentally become 64-bit-only or similar. Benchmarking on transcoding to various formats shows consistently positive results: dnxhd 25.60 fps -> 26.26 fps ( +2.6%) dvvideo 24.88 fps -> 25.17 fps ( +1.2%) ffv1 14.32 fps -> 14.58 fps ( +1.8%) huffyuv 58.75 fps -> 63.27 fps ( +7.7%) jpegls 6.22 fps -> 6.34 fps ( +1.8%) magicyuv 57.10 fps -> 63.29 fps (+10.8%) mjpeg 48.65 fps -> 49.01 fps ( +0.7%) mpeg1video 76.41 fps -> 77.01 fps ( +0.8%) mpeg2video 75.99 fps -> 77.43 fps ( +1.9%) mpeg4 80.66 fps -> 81.37 fps ( +0.9%) prores 12.35 fps -> 12.88 fps ( +4.3%) prores_ks 16.20 fps -> 16.80 fps ( +3.7%) rv20 62.80 fps -> 62.99 fps ( +0.3%) utvideo 68.41 fps -> 76.32 fps (+11.6%) Note that this includes video decoding and all other encoding work, such as DCTs. If you isolate the actual bit-writing routines, it is likely to be much more. Benchmark details: Transcoding the first 30 seconds of Big Buck Bunny in 1080p, Haswell 2.1 GHz, GCC 8.3, generally quantizer locked to 5.0. (Exceptions: DNxHD needs fixed bitrate, and JPEG-LS is so slow that I only took the first 10 seconds, not 30.) All runs were done ten times and single-threaded, top and bottom two results discarded to get rid of outliers, arithmetic mean between the remaining six. Signed-off-by: Michael Niedermayer <michael@niedermayer.cc>
2020-07-18 16:53:03 +02:00
if (BUF_BITS > 32) {
put_bits_no_assert(s, 32, value);
return;
}
bit_buf = s->bit_buf;
bit_left = s->bit_left;
#ifdef BITSTREAM_WRITER_LE
bit_buf |= (BitBuf)value << (BUF_BITS - bit_left);
if (s->buf_end - s->buf_ptr >= sizeof(BitBuf)) {
AV_WLBUF(s->buf_ptr, bit_buf);
s->buf_ptr += sizeof(BitBuf);
} else {
av_log(NULL, AV_LOG_ERROR, "Internal error, put_bits buffer too small\n");
av_assert2(0);
}
bit_buf = (uint64_t)value >> bit_left;
#else
bit_buf = (uint64_t)bit_buf << bit_left;
bit_buf |= (BitBuf)value >> (BUF_BITS - bit_left);
if (s->buf_end - s->buf_ptr >= sizeof(BitBuf)) {
AV_WBBUF(s->buf_ptr, bit_buf);
s->buf_ptr += sizeof(BitBuf);
} else {
av_log(NULL, AV_LOG_ERROR, "Internal error, put_bits buffer too small\n");
av_assert2(0);
}
bit_buf = value;
#endif
s->bit_buf = bit_buf;
s->bit_left = bit_left;
}
/**
* Write up to 64 bits into a bitstream.
*/
static inline void put_bits64(PutBitContext *s, int n, uint64_t value)
{
av_assert2((n == 64) || (n < 64 && value < (UINT64_C(1) << n)));
if (n < 32)
put_bits(s, n, value);
else if (n == 32)
put_bits32(s, value);
else if (n < 64) {
uint32_t lo = value & 0xffffffff;
uint32_t hi = value >> 32;
#ifdef BITSTREAM_WRITER_LE
put_bits32(s, lo);
put_bits(s, n - 32, hi);
#else
put_bits(s, n - 32, hi);
put_bits32(s, lo);
#endif
} else {
uint32_t lo = value & 0xffffffff;
uint32_t hi = value >> 32;
#ifdef BITSTREAM_WRITER_LE
put_bits32(s, lo);
put_bits32(s, hi);
#else
put_bits32(s, hi);
put_bits32(s, lo);
#endif
}
}
/**
* Return the pointer to the byte where the bitstream writer will put
* the next bit.
*/
static inline uint8_t *put_bits_ptr(PutBitContext *s)
{
return s->buf_ptr;
}
/**
* Skip the given number of bytes.
* PutBitContext must be flushed & aligned to a byte boundary before calling this.
*/
static inline void skip_put_bytes(PutBitContext *s, int n)
{
av_assert2((put_bits_count(s) & 7) == 0);
av_assert2(s->bit_left == BUF_BITS);
av_assert0(n <= s->buf_end - s->buf_ptr);
s->buf_ptr += n;
}
/**
* Skip the given number of bits.
* Must only be used if the actual values in the bitstream do not matter.
avcodec/put_bits: Make skip_put_bits() less dangerous Before c63c303a1f2b58677d480505ec93a90f77dd25b5 (the commit which introduced a typedef for the type of the buffer of a PutBitContext) skip_put_bits() was as follows: static inline void skip_put_bits(PutBitContext *s, int n) { s->bit_left -= n; s->buf_ptr -= 4 * (s->bit_left >> 5); s->bit_left &= 31; } If s->bit_left was negative after the first subtraction, then the next line will divide this by 32 with rounding towards -inf and multiply by four; the result will be negative, of course. The aforementioned commit changed this to: static inline void skip_put_bits(PutBitContext *s, int n) { s->bit_left -= n; s->buf_ptr -= sizeof(BitBuf) * ((unsigned)s->bit_left / BUF_BITS); s->bit_left &= (BUF_BITS - 1); } Casting s->bit_left to unsigned meant that the rounding is still towards -inf; yet the right side is now always positive (it transformed the arithmetic shift into a logical shift), so that s->buf_ptr will always be decremented (by about UINT_MAX / 8 unless n is huge) which leads to segfaults on further usage and is already undefined pointer arithmetic before that. This can be reproduced with the mpeg4 encoder with the AV_CODEC_FLAG2_NO_OUTPUT flag set. Furthermore, the earlier version as well as the new version share another bug: s->bit_left will be in the range of 0..(BUF_BITS - 1) afterwards, although the assumption throughout the other PutBitContext functions is that it is in the range of 1..BUF_BITS. This might lead to a shift by BUF_BITS in little-endian mode. This has been fixed, too. The new version is furthermore able to skip zero bits, too. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2020-07-31 08:32:55 +02:00
* If n is < 0 the behavior is undefined.
*/
static inline void skip_put_bits(PutBitContext *s, int n)
{
avcodec/put_bits: Make skip_put_bits() less dangerous Before c63c303a1f2b58677d480505ec93a90f77dd25b5 (the commit which introduced a typedef for the type of the buffer of a PutBitContext) skip_put_bits() was as follows: static inline void skip_put_bits(PutBitContext *s, int n) { s->bit_left -= n; s->buf_ptr -= 4 * (s->bit_left >> 5); s->bit_left &= 31; } If s->bit_left was negative after the first subtraction, then the next line will divide this by 32 with rounding towards -inf and multiply by four; the result will be negative, of course. The aforementioned commit changed this to: static inline void skip_put_bits(PutBitContext *s, int n) { s->bit_left -= n; s->buf_ptr -= sizeof(BitBuf) * ((unsigned)s->bit_left / BUF_BITS); s->bit_left &= (BUF_BITS - 1); } Casting s->bit_left to unsigned meant that the rounding is still towards -inf; yet the right side is now always positive (it transformed the arithmetic shift into a logical shift), so that s->buf_ptr will always be decremented (by about UINT_MAX / 8 unless n is huge) which leads to segfaults on further usage and is already undefined pointer arithmetic before that. This can be reproduced with the mpeg4 encoder with the AV_CODEC_FLAG2_NO_OUTPUT flag set. Furthermore, the earlier version as well as the new version share another bug: s->bit_left will be in the range of 0..(BUF_BITS - 1) afterwards, although the assumption throughout the other PutBitContext functions is that it is in the range of 1..BUF_BITS. This might lead to a shift by BUF_BITS in little-endian mode. This has been fixed, too. The new version is furthermore able to skip zero bits, too. Signed-off-by: Andreas Rheinhardt <andreas.rheinhardt@gmail.com>
2020-07-31 08:32:55 +02:00
unsigned bits = BUF_BITS - s->bit_left + n;
s->buf_ptr += sizeof(BitBuf) * (bits / BUF_BITS);
s->bit_left = BUF_BITS - (bits & (BUF_BITS - 1));
}
/**
* Change the end of the buffer.
*
* @param size the new size in bytes of the buffer where to put bits
*/
static inline void set_put_bits_buffer_size(PutBitContext *s, int size)
{
av_assert0(size <= INT_MAX/8 - BUF_BITS);
s->buf_end = s->buf + size;
}
/**
* Pad the bitstream with zeros up to the next byte boundary.
*/
static inline void align_put_bits(PutBitContext *s)
{
put_bits(s, s->bit_left & 7, 0);
}
#undef AV_WBBUF
#undef AV_WLBUF
#endif /* AVCODEC_PUT_BITS_H */