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/*
* Cinepak encoder ( c ) 2011 Tomas H <EFBFBD> rdin
* http : //titan.codemill.se/~tomhar/cinepakenc.patch
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*
* Fixes and improvements , vintage decoders compatibility
* ( c ) 2013 , 2014 Rl , Aetey Global Technologies AB
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Permission is hereby granted , free of charge , to any person obtaining a
copy of this software and associated documentation files ( the " Software " ) ,
to deal in the Software without restriction , including without limitation
the rights to use , copy , modify , merge , publish , distribute , sublicense ,
and / or sell copies of the Software , and to permit persons to whom the
Software is furnished to do so , subject to the following conditions :
The above copyright notice and this permission notice shall be included
in all copies or substantial portions of the Software .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL
THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR
OTHER LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE ,
ARISING FROM , OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
OTHER DEALINGS IN THE SOFTWARE .
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* TODO :
* - optimize : color space conversion , . . .
* - implement options to set the min / max number of strips ?
* MAYBE :
* - " optimally " split the frame into several non - regular areas
* using a separate codebook pair for each area and approximating
* the area by several rectangular strips ( generally not full width ones )
* ( use quadtree splitting ? a simple fixed - granularity grid ? )
*
*
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* version 2014 - 01 - 23 Rl
* - added option handling for flexibility
*
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* version 2014 - 01 - 21 Rl
* - believe it or not , now we get even smaller files , with better quality
* ( which means I missed an optimization earlier : )
*
* version 2014 - 01 - 20 Rl
* - made the encoder compatible with vintage decoders
* and added some yet unused code for possible future
* incremental codebook updates
* - fixed a small memory leak
*
* version 2013 - 04 - 28 Rl
* - bugfixed codebook optimization logic
*
* version 2013 - 02 - 14 Rl
* " Valentine's Day " version :
* - made strip division more robust
* - minimized bruteforcing the number of strips ,
* ( costs some R / D but speeds up compession a lot ) , the heuristic
* assumption is that score as a function of the number of strips has
* one wide minimum which moves slowly , of course not fully true
* - simplified codebook generation ,
* the old code was meant for other optimizations than we actually do
* - optimized the codebook generation / error estimation for MODE_MC
*
* version 2013 - 02 - 12 Rl
* - separated codebook training sets , avoided the transfer of wasted bytes ,
* which yields both better quality and smaller files
* - now using the correct colorspace ( TODO : move conversion to libswscale )
*
* version 2013 - 02 - 08 Rl
* - fixes / optimization in multistrip encoding and codebook size choice ,
* quality / bitrate is now better than that of the binary proprietary encoder
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*/
# include "libavutil/intreadwrite.h"
# include "avcodec.h"
# include "libavutil/lfg.h"
# include "elbg.h"
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# include "internal.h"
# include "libavutil/avassert.h"
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# include "libavutil/opt.h"
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# define CVID_HEADER_SIZE 10
# define STRIP_HEADER_SIZE 12
# define CHUNK_HEADER_SIZE 4
# define MB_SIZE 4 //4x4 MBs
# define MB_AREA (MB_SIZE*MB_SIZE)
# define VECTOR_MAX 6 //six or four entries per vector depending on format
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# define CODEBOOK_MAX 256 //size of a codebook
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# define MAX_STRIPS 32 //Note: having fewer choices regarding the number of strips speeds up encoding (obviously)
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# define MIN_STRIPS 1 //Note: having more strips speeds up encoding the frame (this is less obvious)
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// MAX_STRIPS limits the maximum quality you can reach
// when you want hight quality on high resolutions,
// MIN_STRIPS limits the minimum efficiently encodable bit rate
// on low resolutions
// the numbers are only used for brute force optimization for the first frame,
// for the following frames they are adaptively readjusted
// NOTE the decoder in ffmpeg has its own arbitrary limitation on the number
// of strips, currently 32
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typedef enum {
MODE_V1_ONLY = 0 ,
MODE_V1_V4 ,
MODE_MC ,
MODE_COUNT ,
} CinepakMode ;
typedef enum {
ENC_V1 ,
ENC_V4 ,
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ENC_SKIP ,
ENC_UNCERTAIN
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} mb_encoding ;
typedef struct {
int v1_vector ; //index into v1 codebook
int v1_error ; //error when using V1 encoding
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int v4_vector [ 4 ] ; //indices into v4 codebooks
int v4_error ; //error when using V4 encoding
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int skip_error ; //error when block is skipped (aka copied from last frame)
mb_encoding best_encoding ; //last result from calculate_mode_score()
} mb_info ;
typedef struct {
int v1_codebook [ CODEBOOK_MAX * VECTOR_MAX ] ;
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int v4_codebook [ CODEBOOK_MAX * VECTOR_MAX ] ;
int v1_size ;
int v4_size ;
CinepakMode mode ;
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} strip_info ;
typedef struct {
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const AVClass * class ;
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AVCodecContext * avctx ;
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unsigned char * pict_bufs [ 4 ] , * strip_buf , * frame_buf ;
AVFrame * last_frame ;
AVFrame * best_frame ;
AVFrame * scratch_frame ;
AVFrame * input_frame ;
enum AVPixelFormat pix_fmt ;
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int w , h ;
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int frame_buf_size ;
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int curframe , keyint ;
AVLFG randctx ;
uint64_t lambda ;
int * codebook_input ;
int * codebook_closest ;
mb_info * mb ; //MB RD state
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int min_strips ; //the current limit
int max_strips ; //the current limit
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# ifdef CINEPAKENC_DEBUG
mb_info * best_mb ; //TODO: remove. only used for printing stats
int num_v1_mode , num_v4_mode , num_mc_mode ;
int num_v1_encs , num_v4_encs , num_skips ;
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# endif
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// options
int max_extra_cb_iterations ;
int skip_empty_cb ;
int min_min_strips ;
int max_max_strips ;
int strip_number_delta_range ;
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} CinepakEncContext ;
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# define OFFSET(x) offsetof(CinepakEncContext, x)
# define VE AV_OPT_FLAG_VIDEO_PARAM | AV_OPT_FLAG_ENCODING_PARAM
static const AVOption options [ ] = {
{ " max_extra_cb_iterations " , " Max extra codebook recalculation passes, more is better and slower " , OFFSET ( max_extra_cb_iterations ) , AV_OPT_TYPE_INT , { . i64 = 2 } , 0 , INT_MAX , VE } ,
{ " skip_empty_cb " , " Avoid wasting bytes, ignore vintage MacOS decoder " , OFFSET ( skip_empty_cb ) , AV_OPT_TYPE_INT , { . i64 = 0 } , 0 , 1 , VE } ,
{ " max_strips " , " Limit strips/frame, vintage compatible is 1..3, otherwise the more the better " , OFFSET ( max_max_strips ) , AV_OPT_TYPE_INT , { . i64 = 3 } , MIN_STRIPS , MAX_STRIPS , VE } ,
{ " min_strips " , " Enforce min strips/frame, more is worse and faster, must be <= max_strips " , OFFSET ( min_min_strips ) , AV_OPT_TYPE_INT , { . i64 = MIN_STRIPS } , MIN_STRIPS , MAX_STRIPS , VE } ,
{ " strip_number_adaptivity " , " How fast the strip number adapts, more is slightly better, much slower " , OFFSET ( strip_number_delta_range ) , AV_OPT_TYPE_INT , { . i64 = 0 } , 0 , MAX_STRIPS - MIN_STRIPS , VE } ,
{ NULL } ,
} ;
static const AVClass cinepak_class = {
. class_name = " cinepak " ,
. item_name = av_default_item_name ,
. option = options ,
. version = LIBAVUTIL_VERSION_INT ,
} ;
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static av_cold int cinepak_encode_init ( AVCodecContext * avctx )
{
CinepakEncContext * s = avctx - > priv_data ;
int x , mb_count , strip_buf_size , frame_buf_size ;
if ( avctx - > width & 3 | | avctx - > height & 3 ) {
av_log ( avctx , AV_LOG_ERROR , " width and height must be multiples of four (got %ix%i) \n " ,
avctx - > width , avctx - > height ) ;
return AVERROR ( EINVAL ) ;
}
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if ( s - > min_min_strips > s - > max_max_strips ) {
av_log ( avctx , AV_LOG_ERROR , " minimal number of strips can not exceed maximal (got %i and %i) \n " ,
s - > min_min_strips , s - > max_max_strips ) ;
return AVERROR ( EINVAL ) ;
}
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if ( ! ( s - > last_frame = av_frame_alloc ( ) ) )
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return AVERROR ( ENOMEM ) ;
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if ( ! ( s - > best_frame = av_frame_alloc ( ) ) )
goto enomem ;
if ( ! ( s - > scratch_frame = av_frame_alloc ( ) ) )
goto enomem ;
if ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 )
if ( ! ( s - > input_frame = av_frame_alloc ( ) ) )
goto enomem ;
if ( ! ( s - > codebook_input = av_malloc ( sizeof ( int ) * ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 ? 6 : 4 ) * ( avctx - > width * avctx - > height ) > > 2 ) ) )
goto enomem ;
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if ( ! ( s - > codebook_closest = av_malloc ( sizeof ( int ) * ( avctx - > width * avctx - > height ) > > 2 ) ) )
goto enomem ;
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for ( x = 0 ; x < ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 ? 4 : 3 ) ; x + + )
if ( ! ( s - > pict_bufs [ x ] = av_malloc ( ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 ? 6 : 4 ) * ( avctx - > width * avctx - > height ) > > 2 ) ) )
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goto enomem ;
mb_count = avctx - > width * avctx - > height / MB_AREA ;
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//the largest possible chunk is 0x31 with all MBs encoded in V4 mode
//and full codebooks being replaced in INTER mode,
// which is 34 bits per MB
//and 2*256 extra flag bits per strip
strip_buf_size = STRIP_HEADER_SIZE + 3 * CHUNK_HEADER_SIZE + 2 * VECTOR_MAX * CODEBOOK_MAX + 4 * ( mb_count + ( mb_count + 15 ) / 16 ) + ( 2 * CODEBOOK_MAX ) / 8 ;
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frame_buf_size = CVID_HEADER_SIZE + s - > max_max_strips * strip_buf_size ;
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if ( ! ( s - > strip_buf = av_malloc ( strip_buf_size ) ) )
goto enomem ;
if ( ! ( s - > frame_buf = av_malloc ( frame_buf_size ) ) )
goto enomem ;
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if ( ! ( s - > mb = av_malloc_array ( mb_count , sizeof ( mb_info ) ) ) )
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goto enomem ;
# ifdef CINEPAKENC_DEBUG
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if ( ! ( s - > best_mb = av_malloc_array ( mb_count , sizeof ( mb_info ) ) ) )
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goto enomem ;
# endif
av_lfg_init ( & s - > randctx , 1 ) ;
s - > avctx = avctx ;
s - > w = avctx - > width ;
s - > h = avctx - > height ;
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s - > frame_buf_size = frame_buf_size ;
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s - > curframe = 0 ;
s - > keyint = avctx - > keyint_min ;
s - > pix_fmt = avctx - > pix_fmt ;
//set up AVFrames
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s - > last_frame - > data [ 0 ] = s - > pict_bufs [ 0 ] ;
s - > last_frame - > linesize [ 0 ] = s - > w ;
s - > best_frame - > data [ 0 ] = s - > pict_bufs [ 1 ] ;
s - > best_frame - > linesize [ 0 ] = s - > w ;
s - > scratch_frame - > data [ 0 ] = s - > pict_bufs [ 2 ] ;
s - > scratch_frame - > linesize [ 0 ] = s - > w ;
if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 ) {
s - > last_frame - > data [ 1 ] = s - > last_frame - > data [ 0 ] + s - > w * s - > h ;
s - > last_frame - > data [ 2 ] = s - > last_frame - > data [ 1 ] + ( ( s - > w * s - > h ) > > 2 ) ;
s - > last_frame - > linesize [ 1 ] = s - > last_frame - > linesize [ 2 ] = s - > w > > 1 ;
s - > best_frame - > data [ 1 ] = s - > best_frame - > data [ 0 ] + s - > w * s - > h ;
s - > best_frame - > data [ 2 ] = s - > best_frame - > data [ 1 ] + ( ( s - > w * s - > h ) > > 2 ) ;
s - > best_frame - > linesize [ 1 ] = s - > best_frame - > linesize [ 2 ] = s - > w > > 1 ;
s - > scratch_frame - > data [ 1 ] = s - > scratch_frame - > data [ 0 ] + s - > w * s - > h ;
s - > scratch_frame - > data [ 2 ] = s - > scratch_frame - > data [ 1 ] + ( ( s - > w * s - > h ) > > 2 ) ;
s - > scratch_frame - > linesize [ 1 ] = s - > scratch_frame - > linesize [ 2 ] = s - > w > > 1 ;
s - > input_frame - > data [ 0 ] = s - > pict_bufs [ 3 ] ;
s - > input_frame - > linesize [ 0 ] = s - > w ;
s - > input_frame - > data [ 1 ] = s - > input_frame - > data [ 0 ] + s - > w * s - > h ;
s - > input_frame - > data [ 2 ] = s - > input_frame - > data [ 1 ] + ( ( s - > w * s - > h ) > > 2 ) ;
s - > input_frame - > linesize [ 1 ] = s - > input_frame - > linesize [ 2 ] = s - > w > > 1 ;
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}
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s - > min_strips = s - > min_min_strips ;
s - > max_strips = s - > max_max_strips ;
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# ifdef CINEPAKENC_DEBUG
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s - > num_v1_mode = s - > num_v4_mode = s - > num_mc_mode = s - > num_v1_encs = s - > num_v4_encs = s - > num_skips = 0 ;
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# endif
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return 0 ;
enomem :
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av_frame_free ( & s - > last_frame ) ;
av_frame_free ( & s - > best_frame ) ;
av_frame_free ( & s - > scratch_frame ) ;
if ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 )
av_frame_free ( & s - > input_frame ) ;
av_freep ( & s - > codebook_input ) ;
av_freep ( & s - > codebook_closest ) ;
av_freep ( & s - > strip_buf ) ;
av_freep ( & s - > frame_buf ) ;
av_freep ( & s - > mb ) ;
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# ifdef CINEPAKENC_DEBUG
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av_freep ( & s - > best_mb ) ;
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# endif
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for ( x = 0 ; x < ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 ? 4 : 3 ) ; x + + )
av_freep ( & s - > pict_bufs [ x ] ) ;
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return AVERROR ( ENOMEM ) ;
}
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static int64_t calculate_mode_score ( CinepakEncContext * s , int h , strip_info * info , int report , int * training_set_v1_shrunk , int * training_set_v4_shrunk
# ifdef CINEPAK_REPORT_SERR
, int64_t * serr
# endif
)
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{
//score = FF_LAMBDA_SCALE * error + lambda * bits
int x ;
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int entry_size = s - > pix_fmt = = AV_PIX_FMT_RGB24 ? 6 : 4 ;
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int mb_count = s - > w * h / MB_AREA ;
mb_info * mb ;
int64_t score1 , score2 , score3 ;
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int64_t ret = s - > lambda * ( ( info - > v1_size ? CHUNK_HEADER_SIZE + info - > v1_size * entry_size : 0 ) +
( info - > v4_size ? CHUNK_HEADER_SIZE + info - > v4_size * entry_size : 0 ) +
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CHUNK_HEADER_SIZE ) < < 3 ;
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//av_log(s->avctx, AV_LOG_INFO, "sizes %3i %3i -> %9lli score mb_count %i", info->v1_size, info->v4_size, (long long int)ret, mb_count);
# ifdef CINEPAK_REPORT_SERR
* serr = 0 ;
# endif
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switch ( info - > mode ) {
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case MODE_V1_ONLY :
//one byte per MB
ret + = s - > lambda * 8 * mb_count ;
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// while calculating we assume all blocks are ENC_V1
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for ( x = 0 ; x < mb_count ; x + + ) {
mb = & s - > mb [ x ] ;
ret + = FF_LAMBDA_SCALE * mb - > v1_error ;
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# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > v1_error ;
# endif
// this function is never called for report in MODE_V1_ONLY
// if(!report)
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mb - > best_encoding = ENC_V1 ;
}
break ;
case MODE_V1_V4 :
//9 or 33 bits per MB
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if ( report ) {
// no moves between the corresponding training sets are allowed
* training_set_v1_shrunk = * training_set_v4_shrunk = 0 ;
for ( x = 0 ; x < mb_count ; x + + ) {
int mberr ;
mb = & s - > mb [ x ] ;
if ( mb - > best_encoding = = ENC_V1 )
score1 = s - > lambda * 9 + FF_LAMBDA_SCALE * ( mberr = mb - > v1_error ) ;
else
score1 = s - > lambda * 33 + FF_LAMBDA_SCALE * ( mberr = mb - > v4_error ) ;
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ret + = score1 ;
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# ifdef CINEPAK_REPORT_SERR
* serr + = mberr ;
# endif
}
} else { // find best mode per block
for ( x = 0 ; x < mb_count ; x + + ) {
mb = & s - > mb [ x ] ;
score1 = s - > lambda * 9 + FF_LAMBDA_SCALE * mb - > v1_error ;
score2 = s - > lambda * 33 + FF_LAMBDA_SCALE * mb - > v4_error ;
if ( score1 < = score2 ) {
ret + = score1 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > v1_error ;
# endif
mb - > best_encoding = ENC_V1 ;
} else {
ret + = score2 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > v4_error ;
# endif
mb - > best_encoding = ENC_V4 ;
}
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}
}
break ;
case MODE_MC :
//1, 10 or 34 bits per MB
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if ( report ) {
int v1_shrunk = 0 , v4_shrunk = 0 ;
for ( x = 0 ; x < mb_count ; x + + ) {
mb = & s - > mb [ x ] ;
// it is OK to move blocks to ENC_SKIP here
// but not to any codebook encoding!
score1 = s - > lambda * 1 + FF_LAMBDA_SCALE * mb - > skip_error ;
if ( mb - > best_encoding = = ENC_SKIP ) {
ret + = score1 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > skip_error ;
# endif
} else if ( mb - > best_encoding = = ENC_V1 ) {
if ( ( score2 = s - > lambda * 10 + FF_LAMBDA_SCALE * mb - > v1_error ) > = score1 ) {
mb - > best_encoding = ENC_SKIP ;
+ + v1_shrunk ;
ret + = score1 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > skip_error ;
# endif
} else {
ret + = score2 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > v1_error ;
# endif
}
} else {
if ( ( score3 = s - > lambda * 34 + FF_LAMBDA_SCALE * mb - > v4_error ) > = score1 ) {
mb - > best_encoding = ENC_SKIP ;
+ + v4_shrunk ;
ret + = score1 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > skip_error ;
# endif
} else {
ret + = score3 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > v4_error ;
# endif
}
}
}
* training_set_v1_shrunk = v1_shrunk ;
* training_set_v4_shrunk = v4_shrunk ;
} else { // find best mode per block
for ( x = 0 ; x < mb_count ; x + + ) {
mb = & s - > mb [ x ] ;
score1 = s - > lambda * 1 + FF_LAMBDA_SCALE * mb - > skip_error ;
score2 = s - > lambda * 10 + FF_LAMBDA_SCALE * mb - > v1_error ;
score3 = s - > lambda * 34 + FF_LAMBDA_SCALE * mb - > v4_error ;
if ( score1 < = score2 & & score1 < = score3 ) {
ret + = score1 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > skip_error ;
# endif
mb - > best_encoding = ENC_SKIP ;
} else if ( score2 < = score3 ) {
ret + = score2 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > v1_error ;
# endif
mb - > best_encoding = ENC_V1 ;
} else {
ret + = score3 ;
# ifdef CINEPAK_REPORT_SERR
* serr + = mb - > v4_error ;
# endif
mb - > best_encoding = ENC_V4 ;
}
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}
}
break ;
}
return ret ;
}
static int write_chunk_header ( unsigned char * buf , int chunk_type , int chunk_size )
{
buf [ 0 ] = chunk_type ;
AV_WB24 ( & buf [ 1 ] , chunk_size + CHUNK_HEADER_SIZE ) ;
return CHUNK_HEADER_SIZE ;
}
static int encode_codebook ( CinepakEncContext * s , int * codebook , int size , int chunk_type_yuv , int chunk_type_gray , unsigned char * buf )
{
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int x , y , ret , entry_size = s - > pix_fmt = = AV_PIX_FMT_RGB24 ? 6 : 4 ;
int incremental_codebook_replacement_mode = 0 ; // hardcoded here,
// the compiler should notice that this is a constant -- rl
ret = write_chunk_header ( buf ,
s - > pix_fmt = = AV_PIX_FMT_RGB24 ?
chunk_type_yuv + ( incremental_codebook_replacement_mode ? 1 : 0 ) :
chunk_type_gray + ( incremental_codebook_replacement_mode ? 1 : 0 ) ,
entry_size * size
+ ( incremental_codebook_replacement_mode ? ( size + 31 ) / 32 * 4 : 0 ) ) ;
// we do codebook encoding according to the "intra" mode
// but we keep the "dead" code for reference in case we will want
// to use incremental codebook updates (which actually would give us
// "kind of" motion compensation, especially in 1 strip/frame case) -- rl
// (of course, the code will be not useful as-is)
if ( incremental_codebook_replacement_mode ) {
int flags = 0 ;
int flagsind ;
for ( x = 0 ; x < size ; x + + ) {
if ( flags = = 0 ) {
flagsind = ret ;
ret + = 4 ;
flags = 0x80000000 ;
} else
flags = ( ( flags > > 1 ) | 0x80000000 ) ;
for ( y = 0 ; y < entry_size ; y + + )
buf [ ret + + ] = codebook [ y + x * entry_size ] ^ ( y > = 4 ? 0x80 : 0 ) ;
if ( ( flags & 0xffffffff ) = = 0xffffffff ) {
AV_WB32 ( & buf [ flagsind ] , flags ) ;
flags = 0 ;
}
}
if ( flags )
AV_WB32 ( & buf [ flagsind ] , flags ) ;
} else
for ( x = 0 ; x < size ; x + + )
for ( y = 0 ; y < entry_size ; y + + )
buf [ ret + + ] = codebook [ y + x * entry_size ] ^ ( y > = 4 ? 0x80 : 0 ) ;
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return ret ;
}
//sets out to the sub picture starting at (x,y) in in
static void get_sub_picture ( CinepakEncContext * s , int x , int y , AVPicture * in , AVPicture * out )
{
out - > data [ 0 ] = in - > data [ 0 ] + x + y * in - > linesize [ 0 ] ;
out - > linesize [ 0 ] = in - > linesize [ 0 ] ;
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if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 ) {
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out - > data [ 1 ] = in - > data [ 1 ] + ( x > > 1 ) + ( y > > 1 ) * in - > linesize [ 1 ] ;
out - > linesize [ 1 ] = in - > linesize [ 1 ] ;
out - > data [ 2 ] = in - > data [ 2 ] + ( x > > 1 ) + ( y > > 1 ) * in - > linesize [ 2 ] ;
out - > linesize [ 2 ] = in - > linesize [ 2 ] ;
}
}
//decodes the V1 vector in mb into the 4x4 MB pointed to by sub_pict
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static void decode_v1_vector ( CinepakEncContext * s , AVPicture * sub_pict , int v1_vector , strip_info * info )
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{
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int entry_size = s - > pix_fmt = = AV_PIX_FMT_RGB24 ? 6 : 4 ;
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sub_pict - > data [ 0 ] [ 0 ] =
sub_pict - > data [ 0 ] [ 1 ] =
sub_pict - > data [ 0 ] [ sub_pict - > linesize [ 0 ] ] =
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sub_pict - > data [ 0 ] [ 1 + sub_pict - > linesize [ 0 ] ] = info - > v1_codebook [ v1_vector * entry_size ] ;
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sub_pict - > data [ 0 ] [ 2 ] =
sub_pict - > data [ 0 ] [ 3 ] =
sub_pict - > data [ 0 ] [ 2 + sub_pict - > linesize [ 0 ] ] =
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sub_pict - > data [ 0 ] [ 3 + sub_pict - > linesize [ 0 ] ] = info - > v1_codebook [ v1_vector * entry_size + 1 ] ;
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sub_pict - > data [ 0 ] [ 2 * sub_pict - > linesize [ 0 ] ] =
sub_pict - > data [ 0 ] [ 1 + 2 * sub_pict - > linesize [ 0 ] ] =
sub_pict - > data [ 0 ] [ 3 * sub_pict - > linesize [ 0 ] ] =
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sub_pict - > data [ 0 ] [ 1 + 3 * sub_pict - > linesize [ 0 ] ] = info - > v1_codebook [ v1_vector * entry_size + 2 ] ;
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sub_pict - > data [ 0 ] [ 2 + 2 * sub_pict - > linesize [ 0 ] ] =
sub_pict - > data [ 0 ] [ 3 + 2 * sub_pict - > linesize [ 0 ] ] =
sub_pict - > data [ 0 ] [ 2 + 3 * sub_pict - > linesize [ 0 ] ] =
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sub_pict - > data [ 0 ] [ 3 + 3 * sub_pict - > linesize [ 0 ] ] = info - > v1_codebook [ v1_vector * entry_size + 3 ] ;
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if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 ) {
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sub_pict - > data [ 1 ] [ 0 ] =
sub_pict - > data [ 1 ] [ 1 ] =
sub_pict - > data [ 1 ] [ sub_pict - > linesize [ 1 ] ] =
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sub_pict - > data [ 1 ] [ 1 + sub_pict - > linesize [ 1 ] ] = info - > v1_codebook [ v1_vector * entry_size + 4 ] ;
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sub_pict - > data [ 2 ] [ 0 ] =
sub_pict - > data [ 2 ] [ 1 ] =
sub_pict - > data [ 2 ] [ sub_pict - > linesize [ 2 ] ] =
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sub_pict - > data [ 2 ] [ 1 + sub_pict - > linesize [ 2 ] ] = info - > v1_codebook [ v1_vector * entry_size + 5 ] ;
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}
}
//decodes the V4 vectors in mb into the 4x4 MB pointed to by sub_pict
static void decode_v4_vector ( CinepakEncContext * s , AVPicture * sub_pict , int * v4_vector , strip_info * info )
{
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int i , x , y , entry_size = s - > pix_fmt = = AV_PIX_FMT_RGB24 ? 6 : 4 ;
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for ( i = y = 0 ; y < 4 ; y + = 2 ) {
for ( x = 0 ; x < 4 ; x + = 2 , i + + ) {
sub_pict - > data [ 0 ] [ x + y * sub_pict - > linesize [ 0 ] ] = info - > v4_codebook [ v4_vector [ i ] * entry_size ] ;
sub_pict - > data [ 0 ] [ x + 1 + y * sub_pict - > linesize [ 0 ] ] = info - > v4_codebook [ v4_vector [ i ] * entry_size + 1 ] ;
sub_pict - > data [ 0 ] [ x + ( y + 1 ) * sub_pict - > linesize [ 0 ] ] = info - > v4_codebook [ v4_vector [ i ] * entry_size + 2 ] ;
sub_pict - > data [ 0 ] [ x + 1 + ( y + 1 ) * sub_pict - > linesize [ 0 ] ] = info - > v4_codebook [ v4_vector [ i ] * entry_size + 3 ] ;
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if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 ) {
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sub_pict - > data [ 1 ] [ ( x > > 1 ) + ( y > > 1 ) * sub_pict - > linesize [ 1 ] ] = info - > v4_codebook [ v4_vector [ i ] * entry_size + 4 ] ;
sub_pict - > data [ 2 ] [ ( x > > 1 ) + ( y > > 1 ) * sub_pict - > linesize [ 2 ] ] = info - > v4_codebook [ v4_vector [ i ] * entry_size + 5 ] ;
}
}
}
}
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static void copy_mb ( CinepakEncContext * s , AVPicture * a , AVPicture * b )
{
int y , p ;
for ( y = 0 ; y < MB_SIZE ; y + + ) {
memcpy ( a - > data [ 0 ] + y * a - > linesize [ 0 ] , b - > data [ 0 ] + y * b - > linesize [ 0 ] ,
MB_SIZE ) ;
}
if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 ) {
for ( p = 1 ; p < = 2 ; p + + ) {
for ( y = 0 ; y < MB_SIZE / 2 ; y + + ) {
memcpy ( a - > data [ p ] + y * a - > linesize [ p ] ,
b - > data [ p ] + y * b - > linesize [ p ] ,
MB_SIZE / 2 ) ;
}
}
}
}
static int encode_mode ( CinepakEncContext * s , int h , AVPicture * scratch_pict , AVPicture * last_pict , strip_info * info , unsigned char * buf )
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{
int x , y , z , flags , bits , temp_size , header_ofs , ret = 0 , mb_count = s - > w * h / MB_AREA ;
int needs_extra_bit , should_write_temp ;
unsigned char temp [ 64 ] ; //32/2 = 16 V4 blocks at 4 B each -> 64 B
mb_info * mb ;
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AVPicture sub_scratch = { { 0 } } , sub_last = { { 0 } } ;
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//encode codebooks
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////// MacOS vintage decoder compatibility dictates the presence of
////// the codebook chunk even when the codebook is empty - pretty dumb...
////// and also the certain order of the codebook chunks -- rl
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if ( info - > v4_size | | ! s - > skip_empty_cb )
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ret + = encode_codebook ( s , info - > v4_codebook , info - > v4_size , 0x20 , 0x24 , buf + ret ) ;
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if ( info - > v1_size | | ! s - > skip_empty_cb )
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ret + = encode_codebook ( s , info - > v1_codebook , info - > v1_size , 0x22 , 0x26 , buf + ret ) ;
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//update scratch picture
for ( z = y = 0 ; y < h ; y + = MB_SIZE ) {
for ( x = 0 ; x < s - > w ; x + = MB_SIZE , z + + ) {
mb = & s - > mb [ z ] ;
get_sub_picture ( s , x , y , scratch_pict , & sub_scratch ) ;
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if ( info - > mode = = MODE_MC & & mb - > best_encoding = = ENC_SKIP ) {
get_sub_picture ( s , x , y , last_pict , & sub_last ) ;
copy_mb ( s , & sub_scratch , & sub_last ) ;
} else if ( info - > mode = = MODE_V1_ONLY | | mb - > best_encoding = = ENC_V1 )
decode_v1_vector ( s , & sub_scratch , mb - > v1_vector , info ) ;
else
decode_v4_vector ( s , & sub_scratch , mb - > v4_vector , info ) ;
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}
}
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switch ( info - > mode ) {
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case MODE_V1_ONLY :
//av_log(s->avctx, AV_LOG_INFO, "mb_count = %i\n", mb_count);
ret + = write_chunk_header ( buf + ret , 0x32 , mb_count ) ;
for ( x = 0 ; x < mb_count ; x + + )
buf [ ret + + ] = s - > mb [ x ] . v1_vector ;
break ;
case MODE_V1_V4 :
//remember header position
header_ofs = ret ;
ret + = CHUNK_HEADER_SIZE ;
for ( x = 0 ; x < mb_count ; x + = 32 ) {
flags = 0 ;
for ( y = x ; y < FFMIN ( x + 32 , mb_count ) ; y + + )
if ( s - > mb [ y ] . best_encoding = = ENC_V4 )
flags | = 1 < < ( 31 - y + x ) ;
AV_WB32 ( & buf [ ret ] , flags ) ;
ret + = 4 ;
for ( y = x ; y < FFMIN ( x + 32 , mb_count ) ; y + + ) {
mb = & s - > mb [ y ] ;
if ( mb - > best_encoding = = ENC_V1 )
buf [ ret + + ] = mb - > v1_vector ;
else
for ( z = 0 ; z < 4 ; z + + )
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buf [ ret + + ] = mb - > v4_vector [ z ] ;
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}
}
write_chunk_header ( buf + header_ofs , 0x30 , ret - header_ofs - CHUNK_HEADER_SIZE ) ;
break ;
case MODE_MC :
//remember header position
header_ofs = ret ;
ret + = CHUNK_HEADER_SIZE ;
flags = bits = temp_size = 0 ;
for ( x = 0 ; x < mb_count ; x + + ) {
mb = & s - > mb [ x ] ;
flags | = ( mb - > best_encoding ! = ENC_SKIP ) < < ( 31 - bits + + ) ;
needs_extra_bit = 0 ;
should_write_temp = 0 ;
if ( mb - > best_encoding ! = ENC_SKIP ) {
if ( bits < 32 )
flags | = ( mb - > best_encoding = = ENC_V4 ) < < ( 31 - bits + + ) ;
else
needs_extra_bit = 1 ;
}
if ( bits = = 32 ) {
AV_WB32 ( & buf [ ret ] , flags ) ;
ret + = 4 ;
flags = bits = 0 ;
if ( mb - > best_encoding = = ENC_SKIP | | needs_extra_bit ) {
memcpy ( & buf [ ret ] , temp , temp_size ) ;
ret + = temp_size ;
temp_size = 0 ;
} else
should_write_temp = 1 ;
}
if ( needs_extra_bit ) {
flags = ( mb - > best_encoding = = ENC_V4 ) < < 31 ;
bits = 1 ;
}
if ( mb - > best_encoding = = ENC_V1 )
temp [ temp_size + + ] = mb - > v1_vector ;
else if ( mb - > best_encoding = = ENC_V4 )
for ( z = 0 ; z < 4 ; z + + )
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temp [ temp_size + + ] = mb - > v4_vector [ z ] ;
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if ( should_write_temp ) {
memcpy ( & buf [ ret ] , temp , temp_size ) ;
ret + = temp_size ;
temp_size = 0 ;
}
}
if ( bits > 0 ) {
AV_WB32 ( & buf [ ret ] , flags ) ;
ret + = 4 ;
memcpy ( & buf [ ret ] , temp , temp_size ) ;
ret + = temp_size ;
}
write_chunk_header ( buf + header_ofs , 0x31 , ret - header_ofs - CHUNK_HEADER_SIZE ) ;
break ;
}
return ret ;
}
//computes distortion of 4x4 MB in b compared to a
static int compute_mb_distortion ( CinepakEncContext * s , AVPicture * a , AVPicture * b )
{
int x , y , p , d , ret = 0 ;
for ( y = 0 ; y < MB_SIZE ; y + + ) {
for ( x = 0 ; x < MB_SIZE ; x + + ) {
d = a - > data [ 0 ] [ x + y * a - > linesize [ 0 ] ] - b - > data [ 0 ] [ x + y * b - > linesize [ 0 ] ] ;
ret + = d * d ;
}
}
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if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 ) {
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for ( p = 1 ; p < = 2 ; p + + ) {
for ( y = 0 ; y < MB_SIZE / 2 ; y + + ) {
for ( x = 0 ; x < MB_SIZE / 2 ; x + + ) {
d = a - > data [ p ] [ x + y * a - > linesize [ p ] ] - b - > data [ p ] [ x + y * b - > linesize [ p ] ] ;
ret + = d * d ;
}
}
}
}
return ret ;
}
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// return the possibly adjusted size of the codebook
# define CERTAIN(x) ((x)!=ENC_UNCERTAIN)
static int quantize ( CinepakEncContext * s , int h , AVPicture * pict ,
int v1mode , strip_info * info ,
mb_encoding encoding )
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{
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int x , y , i , j , k , x2 , y2 , x3 , y3 , plane , shift , mbn ;
int entry_size = s - > pix_fmt = = AV_PIX_FMT_RGB24 ? 6 : 4 ;
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int * codebook = v1mode ? info - > v1_codebook : info - > v4_codebook ;
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int size = v1mode ? info - > v1_size : info - > v4_size ;
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int64_t total_error = 0 ;
uint8_t vq_pict_buf [ ( MB_AREA * 3 ) / 2 ] ;
AVPicture sub_pict , vq_pict ;
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for ( mbn = i = y = 0 ; y < h ; y + = MB_SIZE ) {
for ( x = 0 ; x < s - > w ; x + = MB_SIZE , + + mbn ) {
int * base ;
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if ( CERTAIN ( encoding ) ) {
// use for the training only the blocks known to be to be encoded [sic:-]
if ( s - > mb [ mbn ] . best_encoding ! = encoding ) continue ;
}
base = s - > codebook_input + i * entry_size ;
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if ( v1mode ) {
//subsample
for ( j = y2 = 0 ; y2 < entry_size ; y2 + = 2 ) {
for ( x2 = 0 ; x2 < 4 ; x2 + = 2 , j + + ) {
plane = y2 < 4 ? 0 : 1 + ( x2 > > 1 ) ;
shift = y2 < 4 ? 0 : 1 ;
x3 = shift ? 0 : x2 ;
y3 = shift ? 0 : y2 ;
base [ j ] = ( pict - > data [ plane ] [ ( ( x + x3 ) > > shift ) + ( ( y + y3 ) > > shift ) * pict - > linesize [ plane ] ] +
pict - > data [ plane ] [ ( ( x + x3 ) > > shift ) + 1 + ( ( y + y3 ) > > shift ) * pict - > linesize [ plane ] ] +
pict - > data [ plane ] [ ( ( x + x3 ) > > shift ) + ( ( ( y + y3 ) > > shift ) + 1 ) * pict - > linesize [ plane ] ] +
pict - > data [ plane ] [ ( ( x + x3 ) > > shift ) + 1 + ( ( ( y + y3 ) > > shift ) + 1 ) * pict - > linesize [ plane ] ] ) > > 2 ;
}
}
} else {
//copy
for ( j = y2 = 0 ; y2 < MB_SIZE ; y2 + = 2 ) {
for ( x2 = 0 ; x2 < MB_SIZE ; x2 + = 2 ) {
for ( k = 0 ; k < entry_size ; k + + , j + + ) {
plane = k > = 4 ? k - 3 : 0 ;
if ( k > = 4 ) {
x3 = ( x + x2 ) > > 1 ;
y3 = ( y + y2 ) > > 1 ;
} else {
x3 = x + x2 + ( k & 1 ) ;
y3 = y + y2 + ( k > > 1 ) ;
}
base [ j ] = pict - > data [ plane ] [ x3 + y3 * pict - > linesize [ plane ] ] ;
}
}
}
}
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i + = v1mode ? 1 : 4 ;
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}
}
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// if(i < mbn*(v1mode ? 1 : 4)) {
// av_log(s->avctx, AV_LOG_INFO, "reducing training set for %s from %i to %i (encoding %i)\n", v1mode?"v1":"v4", mbn*(v1mode ? 1 : 4), i, encoding);
// }
if ( i = = 0 ) // empty training set, nothing to do
return 0 ;
if ( i < size ) {
//av_log(s->avctx, (CERTAIN(encoding) ? AV_LOG_ERROR : AV_LOG_INFO), "WOULD WASTE: %s cbsize %i bigger than training set size %i (encoding %i)\n", v1mode?"v1":"v4", size, i, encoding);
size = i ;
}
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avpriv_init_elbg ( s - > codebook_input , entry_size , i , codebook , size , 1 , s - > codebook_closest , & s - > randctx ) ;
avpriv_do_elbg ( s - > codebook_input , entry_size , i , codebook , size , 1 , s - > codebook_closest , & s - > randctx ) ;
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//setup vq_pict, which contains a single MB
vq_pict . data [ 0 ] = vq_pict_buf ;
vq_pict . linesize [ 0 ] = MB_SIZE ;
vq_pict . data [ 1 ] = & vq_pict_buf [ MB_AREA ] ;
vq_pict . data [ 2 ] = vq_pict . data [ 1 ] + ( MB_AREA > > 2 ) ;
vq_pict . linesize [ 1 ] = vq_pict . linesize [ 2 ] = MB_SIZE > > 1 ;
//copy indices
for ( i = j = y = 0 ; y < h ; y + = MB_SIZE ) {
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for ( x = 0 ; x < s - > w ; x + = MB_SIZE , j + + ) {
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mb_info * mb = & s - > mb [ j ] ;
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// skip uninteresting blocks if we know their preferred encoding
if ( CERTAIN ( encoding ) & & mb - > best_encoding ! = encoding )
continue ;
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//point sub_pict to current MB
get_sub_picture ( s , x , y , pict , & sub_pict ) ;
if ( v1mode ) {
mb - > v1_vector = s - > codebook_closest [ i ] ;
//fill in vq_pict with V1 data
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decode_v1_vector ( s , & vq_pict , mb - > v1_vector , info ) ;
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mb - > v1_error = compute_mb_distortion ( s , & sub_pict , & vq_pict ) ;
total_error + = mb - > v1_error ;
} else {
for ( k = 0 ; k < 4 ; k + + )
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mb - > v4_vector [ k ] = s - > codebook_closest [ i + k ] ;
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//fill in vq_pict with V4 data
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decode_v4_vector ( s , & vq_pict , mb - > v4_vector , info ) ;
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mb - > v4_error = compute_mb_distortion ( s , & sub_pict , & vq_pict ) ;
total_error + = mb - > v4_error ;
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}
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i + = v1mode ? 1 : 4 ;
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}
}
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// check that we did it right in the beginning of the function
av_assert0 ( i > = size ) ; // training set is no smaller than the codebook
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//av_log(s->avctx, AV_LOG_INFO, "isv1 %i size= %i i= %i error %lli\n", v1mode, size, i, (long long int)total_error);
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return size ;
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}
static void calculate_skip_errors ( CinepakEncContext * s , int h , AVPicture * last_pict , AVPicture * pict , strip_info * info )
{
int x , y , i ;
AVPicture sub_last , sub_pict ;
for ( i = y = 0 ; y < h ; y + = MB_SIZE ) {
for ( x = 0 ; x < s - > w ; x + = MB_SIZE , i + + ) {
get_sub_picture ( s , x , y , last_pict , & sub_last ) ;
get_sub_picture ( s , x , y , pict , & sub_pict ) ;
s - > mb [ i ] . skip_error = compute_mb_distortion ( s , & sub_last , & sub_pict ) ;
}
}
}
static void write_strip_header ( CinepakEncContext * s , int y , int h , int keyframe , unsigned char * buf , int strip_size )
{
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// actually we are exclusively using intra strip coding (how much can we win
// otherwise? how to choose which part of a codebook to update?),
// keyframes are different only because we disallow ENC_SKIP on them -- rl
// (besides, the logic here used to be inverted: )
// buf[0] = keyframe ? 0x11: 0x10;
buf [ 0 ] = keyframe ? 0x10 : 0x11 ;
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AV_WB24 ( & buf [ 1 ] , strip_size + STRIP_HEADER_SIZE ) ;
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// AV_WB16(&buf[4], y); /* using absolute y values works -- rl */
AV_WB16 ( & buf [ 4 ] , 0 ) ; /* using relative values works as well -- rl */
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AV_WB16 ( & buf [ 6 ] , 0 ) ;
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// AV_WB16(&buf[8], y+h); /* using absolute y values works -- rl */
AV_WB16 ( & buf [ 8 ] , h ) ; /* using relative values works as well -- rl */
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AV_WB16 ( & buf [ 10 ] , s - > w ) ;
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//av_log(s->avctx, AV_LOG_INFO, "write_strip_header() %x keyframe=%d\n", buf[0], keyframe);
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}
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static int rd_strip ( CinepakEncContext * s , int y , int h , int keyframe , AVPicture * last_pict , AVPicture * pict , AVPicture * scratch_pict , unsigned char * buf , int64_t * best_score
# ifdef CINEPAK_REPORT_SERR
, int64_t * best_serr
# endif
)
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{
int64_t score = 0 ;
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# ifdef CINEPAK_REPORT_SERR
int64_t serr ;
# endif
int best_size = 0 ;
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strip_info info ;
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// for codebook optimization:
int v1enough , v1_size , v4enough , v4_size ;
int new_v1_size , new_v4_size ;
int v1shrunk , v4shrunk ;
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if ( ! keyframe )
calculate_skip_errors ( s , h , last_pict , pict , & info ) ;
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//try some powers of 4 for the size of the codebooks
//constraint the v4 codebook to be no bigger than v1 one,
//(and no less than v1_size/4)
//thus making v1 preferable and possibly losing small details? should be ok
# define SMALLEST_CODEBOOK 1
for ( v1enough = 0 , v1_size = SMALLEST_CODEBOOK ; v1_size < = CODEBOOK_MAX & & ! v1enough ; v1_size < < = 2 ) {
for ( v4enough = 0 , v4_size = 0 ; v4_size < = v1_size & & ! v4enough ; v4_size = v4_size ? v4_size < < 2 : v1_size > = SMALLEST_CODEBOOK < < 2 ? v1_size > > 2 : SMALLEST_CODEBOOK ) {
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//try all modes
for ( CinepakMode mode = 0 ; mode < MODE_COUNT ; mode + + ) {
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//don't allow MODE_MC in intra frames
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if ( keyframe & & mode = = MODE_MC )
continue ;
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if ( mode = = MODE_V1_ONLY ) {
info . v1_size = v1_size ;
// the size may shrink even before optimizations if the input is short:
info . v1_size = quantize ( s , h , pict , 1 , & info , ENC_UNCERTAIN ) ;
if ( info . v1_size < v1_size )
// too few eligible blocks, no sense in trying bigger sizes
v1enough = 1 ;
info . v4_size = 0 ;
} else { // mode != MODE_V1_ONLY
// if v4 codebook is empty then only allow V1-only mode
if ( ! v4_size )
continue ;
if ( mode = = MODE_V1_V4 ) {
info . v4_size = v4_size ;
info . v4_size = quantize ( s , h , pict , 0 , & info , ENC_UNCERTAIN ) ;
if ( info . v4_size < v4_size )
// too few eligible blocks, no sense in trying bigger sizes
v4enough = 1 ;
}
}
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info . mode = mode ;
// choose the best encoding per block, based on current experience
score = calculate_mode_score ( s , h , & info , 0 ,
& v1shrunk , & v4shrunk
# ifdef CINEPAK_REPORT_SERR
, & serr
# endif
) ;
if ( mode ! = MODE_V1_ONLY ) {
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int extra_iterations_limit = s - > max_extra_cb_iterations ;
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// recompute the codebooks, omitting the extra blocks
// we assume we _may_ come here with more blocks to encode than before
info . v1_size = v1_size ;
new_v1_size = quantize ( s , h , pict , 1 , & info , ENC_V1 ) ;
if ( new_v1_size < info . v1_size ) {
//av_log(s->avctx, AV_LOG_INFO, "mode %i, %3i, %3i: cut v1 codebook to %i entries\n", mode, v1_size, v4_size, new_v1_size);
info . v1_size = new_v1_size ;
}
// we assume we _may_ come here with more blocks to encode than before
info . v4_size = v4_size ;
new_v4_size = quantize ( s , h , pict , 0 , & info , ENC_V4 ) ;
if ( new_v4_size < info . v4_size ) {
//av_log(s->avctx, AV_LOG_INFO, "mode %i, %3i, %3i: cut v4 codebook to %i entries at first iteration\n", mode, v1_size, v4_size, new_v4_size);
info . v4_size = new_v4_size ;
}
// calculate the resulting score
// (do not move blocks to codebook encodings now, as some blocks may have
// got bigger errors despite a smaller training set - but we do not
// ever grow the training sets back)
for ( ; ; ) {
score = calculate_mode_score ( s , h , & info , 1 ,
& v1shrunk , & v4shrunk
# ifdef CINEPAK_REPORT_SERR
, & serr
# endif
) ;
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// do we have a reason to reiterate? if so, have we reached the limit?
if ( ( ! v1shrunk & & ! v4shrunk ) | | ! extra_iterations_limit - - ) break ;
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// recompute the codebooks, omitting the extra blocks
if ( v1shrunk ) {
info . v1_size = v1_size ;
new_v1_size = quantize ( s , h , pict , 1 , & info , ENC_V1 ) ;
if ( new_v1_size < info . v1_size ) {
//av_log(s->avctx, AV_LOG_INFO, "mode %i, %3i, %3i: cut v1 codebook to %i entries\n", mode, v1_size, v4_size, new_v1_size);
info . v1_size = new_v1_size ;
}
}
if ( v4shrunk ) {
info . v4_size = v4_size ;
new_v4_size = quantize ( s , h , pict , 0 , & info , ENC_V4 ) ;
if ( new_v4_size < info . v4_size ) {
//av_log(s->avctx, AV_LOG_INFO, "mode %i, %3i, %3i: cut v4 codebook to %i entries\n", mode, v1_size, v4_size, new_v4_size);
info . v4_size = new_v4_size ;
}
}
}
}
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//av_log(s->avctx, AV_LOG_INFO, "%3i %3i score = %lli\n", v1_size, v4_size, (long long int)score);
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if ( best_size = = 0 | | score < * best_score ) {
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* best_score = score ;
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# ifdef CINEPAK_REPORT_SERR
* best_serr = serr ;
# endif
best_size = encode_mode ( s , h , scratch_pict , last_pict , & info , s - > strip_buf + STRIP_HEADER_SIZE ) ;
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//av_log(s->avctx, AV_LOG_INFO, "mode %i, %3i, %3i: %18lli %i B", mode, info.v1_size, info.v4_size, (long long int)score, best_size);
//av_log(s->avctx, AV_LOG_INFO, "\n");
# ifdef CINEPAK_REPORT_SERR
av_log ( s - > avctx , AV_LOG_INFO , " mode %i, %3i, %3i: %18lli %i B \n " , mode , v1_size , v4_size , ( long long int ) serr , best_size ) ;
# endif
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# ifdef CINEPAKENC_DEBUG
//save MB encoding choices
memcpy ( s - > best_mb , s - > mb , mb_count * sizeof ( mb_info ) ) ;
# endif
//memcpy(strip_temp + STRIP_HEADER_SIZE, strip_temp, best_size);
write_strip_header ( s , y , h , keyframe , s - > strip_buf , best_size ) ;
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}
}
}
}
# ifdef CINEPAKENC_DEBUG
//gather stats. this will only work properly of MAX_STRIPS == 1
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if ( best_info . mode = = MODE_V1_ONLY ) {
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s - > num_v1_mode + + ;
s - > num_v1_encs + = s - > w * h / MB_AREA ;
} else {
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if ( best_info . mode = = MODE_V1_V4 )
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s - > num_v4_mode + + ;
else
s - > num_mc_mode + + ;
int x ;
for ( x = 0 ; x < s - > w * h / MB_AREA ; x + + )
if ( s - > best_mb [ x ] . best_encoding = = ENC_V1 )
s - > num_v1_encs + + ;
else if ( s - > best_mb [ x ] . best_encoding = = ENC_V4 )
s - > num_v4_encs + + ;
else
s - > num_skips + + ;
}
# endif
best_size + = STRIP_HEADER_SIZE ;
memcpy ( buf , s - > strip_buf , best_size ) ;
return best_size ;
}
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static int write_cvid_header ( CinepakEncContext * s , unsigned char * buf , int num_strips , int data_size , int isakeyframe )
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{
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buf [ 0 ] = isakeyframe ? 0 : 1 ;
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AV_WB24 ( & buf [ 1 ] , data_size + CVID_HEADER_SIZE ) ;
AV_WB16 ( & buf [ 4 ] , s - > w ) ;
AV_WB16 ( & buf [ 6 ] , s - > h ) ;
AV_WB16 ( & buf [ 8 ] , num_strips ) ;
return CVID_HEADER_SIZE ;
}
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static int rd_frame ( CinepakEncContext * s , const AVFrame * frame , int isakeyframe , unsigned char * buf , int buf_size )
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{
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int num_strips , strip , i , y , nexty , size , temp_size ;
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AVPicture last_pict , pict , scratch_pict ;
int64_t best_score = 0 , score , score_temp ;
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# ifdef CINEPAK_REPORT_SERR
int64_t best_serr = 0 , serr , serr_temp ;
# endif
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int best_nstrips = - 1 , best_size = - 1 ; // mark as uninitialzed
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if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 ) {
int x ;
// build a copy of the given frame in the correct colorspace
for ( y = 0 ; y < s - > h ; y + = 2 ) {
for ( x = 0 ; x < s - > w ; x + = 2 ) {
uint8_t * ir [ 2 ] ; int32_t r , g , b , rr , gg , bb ;
ir [ 0 ] = ( ( AVPicture * ) frame ) - > data [ 0 ] + x * 3 + y * ( ( AVPicture * ) frame ) - > linesize [ 0 ] ;
ir [ 1 ] = ir [ 0 ] + ( ( AVPicture * ) frame ) - > linesize [ 0 ] ;
get_sub_picture ( s , x , y , ( AVPicture * ) s - > input_frame , & scratch_pict ) ;
r = g = b = 0 ;
for ( i = 0 ; i < 4 ; + + i ) {
int i1 , i2 ;
i1 = ( i & 1 ) ; i2 = ( i > = 2 ) ;
rr = ir [ i2 ] [ i1 * 3 + 0 ] ;
gg = ir [ i2 ] [ i1 * 3 + 1 ] ;
bb = ir [ i2 ] [ i1 * 3 + 2 ] ;
r + = rr ; g + = gg ; b + = bb ;
// using fixed point arithmetic for portable repeatability, scaling by 2^23
// "Y"
// rr = 0.2857*rr + 0.5714*gg + 0.1429*bb;
rr = ( 2396625 * rr + 4793251 * gg + 1198732 * bb ) > > 23 ;
if ( rr < 0 ) rr = 0 ;
else if ( rr > 255 ) rr = 255 ;
scratch_pict . data [ 0 ] [ i1 + i2 * scratch_pict . linesize [ 0 ] ] = rr ;
}
// let us scale down as late as possible
// r /= 4; g /= 4; b /= 4;
// "U"
// rr = -0.1429*r - 0.2857*g + 0.4286*b;
rr = ( - 299683 * r - 599156 * g + 898839 * b ) > > 23 ;
if ( rr < - 128 ) rr = - 128 ;
else if ( rr > 127 ) rr = 127 ;
scratch_pict . data [ 1 ] [ 0 ] = rr + 128 ; // quantize needs unsigned
// "V"
// rr = 0.3571*r - 0.2857*g - 0.0714*b;
rr = ( 748893 * r - 599156 * g - 149737 * b ) > > 23 ;
if ( rr < - 128 ) rr = - 128 ;
else if ( rr > 127 ) rr = 127 ;
scratch_pict . data [ 2 ] [ 0 ] = rr + 128 ; // quantize needs unsigned
}
}
}
//would be nice but quite certainly incompatible with vintage players:
// support encoding zero strips (meaning skip the whole frame)
for ( num_strips = s - > min_strips ; num_strips < = s - > max_strips & & num_strips < = s - > h / MB_SIZE ; num_strips + + ) {
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score = 0 ;
size = 0 ;
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# ifdef CINEPAK_REPORT_SERR
serr = 0 ;
# endif
for ( y = 0 , strip = 1 ; y < s - > h ; strip + + , y = nexty ) {
int strip_height ;
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nexty = strip * s - > h / num_strips ; // <= s->h
//make nexty the next multiple of 4 if not already there
if ( nexty & 3 )
nexty + = 4 - ( nexty & 3 ) ;
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strip_height = nexty - y ;
if ( strip_height < = 0 ) { // can this ever happen?
av_log ( s - > avctx , AV_LOG_INFO , " skipping zero height strip %i of %i \n " , strip , num_strips ) ;
continue ;
}
if ( s - > pix_fmt = = AV_PIX_FMT_RGB24 )
get_sub_picture ( s , 0 , y , ( AVPicture * ) s - > input_frame , & pict ) ;
else
get_sub_picture ( s , 0 , y , ( AVPicture * ) frame , & pict ) ;
get_sub_picture ( s , 0 , y , ( AVPicture * ) s - > last_frame , & last_pict ) ;
get_sub_picture ( s , 0 , y , ( AVPicture * ) s - > scratch_frame , & scratch_pict ) ;
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if ( ( temp_size = rd_strip ( s , y , strip_height , isakeyframe , & last_pict , & pict , & scratch_pict , s - > frame_buf + size + CVID_HEADER_SIZE , & score_temp
# ifdef CINEPAK_REPORT_SERR
, & serr_temp
# endif
) ) < 0 )
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return temp_size ;
score + = score_temp ;
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# ifdef CINEPAK_REPORT_SERR
serr + = serr_temp ;
# endif
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size + = temp_size ;
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//av_log(s->avctx, AV_LOG_INFO, "strip %d, isakeyframe=%d", strip, isakeyframe);
//av_log(s->avctx, AV_LOG_INFO, "\n");
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}
if ( best_score = = 0 | | score < best_score ) {
best_score = score ;
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# ifdef CINEPAK_REPORT_SERR
best_serr = serr ;
# endif
best_size = size + write_cvid_header ( s , s - > frame_buf , num_strips , size , isakeyframe ) ;
//av_log(s->avctx, AV_LOG_INFO, "best number of strips so far: %2i, %12lli, %i B\n", num_strips, (long long int)score, best_size);
# ifdef CINEPAK_REPORT_SERR
av_log ( s - > avctx , AV_LOG_INFO , " best number of strips so far: %2i, %12lli, %i B \n " , num_strips , ( long long int ) serr , best_size ) ;
# endif
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FFSWAP ( AVFrame * , s - > best_frame , s - > scratch_frame ) ;
memcpy ( buf , s - > frame_buf , best_size ) ;
best_nstrips = num_strips ;
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}
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// avoid trying too many strip numbers without a real reason
// (this makes the processing of the very first frame faster)
if ( num_strips - best_nstrips > 4 )
break ;
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}
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av_assert0 ( best_nstrips > = 0 & & best_size > = 0 ) ;
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// let the number of strips slowly adapt to the changes in the contents,
// compared to full bruteforcing every time this will occasionally lead
// to some r/d performance loss but makes encoding up to several times faster
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if ( ! s - > strip_number_delta_range ) {
if ( best_nstrips = = s - > max_strips ) { // let us try to step up
s - > max_strips = best_nstrips + 1 ;
if ( s - > max_strips > = s - > max_max_strips )
s - > max_strips = s - > max_max_strips ;
} else { // try to step down
s - > max_strips = best_nstrips ;
}
s - > min_strips = s - > max_strips - 1 ;
if ( s - > min_strips < s - > min_min_strips )
s - > min_strips = s - > min_min_strips ;
} else {
s - > max_strips = best_nstrips + s - > strip_number_delta_range ;
if ( s - > max_strips > = s - > max_max_strips )
s - > max_strips = s - > max_max_strips ;
s - > min_strips = best_nstrips - s - > strip_number_delta_range ;
if ( s - > min_strips < s - > min_min_strips )
s - > min_strips = s - > min_min_strips ;
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}
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return best_size ;
}
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static int cinepak_encode_frame ( AVCodecContext * avctx , AVPacket * pkt ,
const AVFrame * frame , int * got_packet )
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{
CinepakEncContext * s = avctx - > priv_data ;
int ret ;
s - > lambda = frame - > quality ? frame - > quality - 1 : 2 * FF_LAMBDA_SCALE ;
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if ( ( ret = ff_alloc_packet2 ( avctx , pkt , s - > frame_buf_size ) ) < 0 )
return ret ;
ret = rd_frame ( s , frame , ( s - > curframe = = 0 ) , pkt - > data , s - > frame_buf_size ) ;
pkt - > size = ret ;
if ( s - > curframe = = 0 )
pkt - > flags | = AV_PKT_FLAG_KEY ;
* got_packet = 1 ;
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FFSWAP ( AVFrame * , s - > last_frame , s - > best_frame ) ;
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if ( + + s - > curframe > = s - > keyint )
s - > curframe = 0 ;
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return 0 ;
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}
static av_cold int cinepak_encode_end ( AVCodecContext * avctx )
{
CinepakEncContext * s = avctx - > priv_data ;
int x ;
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av_frame_free ( & s - > last_frame ) ;
av_frame_free ( & s - > best_frame ) ;
av_frame_free ( & s - > scratch_frame ) ;
if ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 )
av_frame_free ( & s - > input_frame ) ;
av_freep ( & s - > codebook_input ) ;
av_freep ( & s - > codebook_closest ) ;
av_freep ( & s - > strip_buf ) ;
av_freep ( & s - > frame_buf ) ;
av_freep ( & s - > mb ) ;
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# ifdef CINEPAKENC_DEBUG
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av_freep ( & s - > best_mb ) ;
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# endif
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for ( x = 0 ; x < ( avctx - > pix_fmt = = AV_PIX_FMT_RGB24 ? 4 : 3 ) ; x + + )
av_freep ( & s - > pict_bufs [ x ] ) ;
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# ifdef CINEPAKENC_DEBUG
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av_log ( avctx , AV_LOG_INFO , " strip coding stats: %i V1 mode, %i V4 mode, %i MC mode (%i V1 encs, %i V4 encs, %i skips) \n " ,
s - > num_v1_mode , s - > num_v4_mode , s - > num_mc_mode , s - > num_v1_encs , s - > num_v4_encs , s - > num_skips ) ;
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# endif
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return 0 ;
}
AVCodec ff_cinepak_encoder = {
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. name = " cinepak " ,
. type = AVMEDIA_TYPE_VIDEO ,
. id = AV_CODEC_ID_CINEPAK ,
. priv_data_size = sizeof ( CinepakEncContext ) ,
. init = cinepak_encode_init ,
. encode2 = cinepak_encode_frame ,
. close = cinepak_encode_end ,
. pix_fmts = ( const enum AVPixelFormat [ ] ) { AV_PIX_FMT_RGB24 , AV_PIX_FMT_GRAY8 , AV_PIX_FMT_NONE } ,
. long_name = NULL_IF_CONFIG_SMALL ( " Cinepak / CVID " ) ,
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. priv_class = & cinepak_class ,
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} ;