1 /*****************************************************************************
2 * decoder_synchro.c : frame dropping routines
3 *****************************************************************************
4 * Copyright (C) 1999-2005 the VideoLAN team
7 * Authors: Christophe Massiot <massiot@via.ecp.fr>
8 * Samuel Hocevar <sam@via.ecp.fr>
9 * Jean-Marc Dressler <polux@via.ecp.fr>
11 * This program is free software; you can redistribute it and/or modify
12 * it under the terms of the GNU General Public License as published by
13 * the Free Software Foundation; either version 2 of the License, or
14 * (at your option) any later version.
16 * This program is distributed in the hope that it will be useful,
17 * but WITHOUT ANY WARRANTY; without even the implied warranty of
18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 * GNU General Public License for more details.
21 * You should have received a copy of the GNU General Public License
22 * along with this program; if not, write to the Free Software
23 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston MA 02110-1301, USA.
24 *****************************************************************************/
27 * DISCUSSION : How to Write an efficient Frame-Dropping Algorithm
30 * This implementation is based on mathematical and statistical
31 * developments. Older implementations used an enslavement, considering
32 * that if we're late when reading an I picture, we will decode one frame
33 * less. It had a tendancy to derive, and wasn't responsive enough, which
34 * would have caused trouble with the stream control stuff.
36 * 1. Structure of a picture stream
37 * =============================
38 * Between 2 I's, we have for instance :
39 * I B P B P B P B P B P B I
40 * t0 t1 t2 t3 t4 t5 t6 t7 t8 t9 t10 t11 t12
41 * Please bear in mind that B's and IP's will be inverted when displaying
42 * (decoding order != presentation order). Thus, t1 < t0.
46 * t[0..12] : Presentation timestamps of pictures 0..12.
47 * t : Current timestamp, at the moment of the decoding.
48 * T : Picture period, T = 1/frame_rate.
49 * tau[I,P,B] : Mean time to decode an [I,P,B] picture.
50 * tauYUV : Mean time to render a picture (given by the video_output).
51 * tau´[I,P,B] = 2 * tau[I,P,B] + tauYUV
52 * : Mean time + typical difference (estimated to tau/2, that
53 * needs to be confirmed) + render time.
54 * DELTA : A given error margin.
56 * 3. General considerations
57 * ======================
58 * We define three types of machines :
59 * 14T > tauI : machines capable of decoding all I pictures
60 * 2T > tauP : machines capable of decoding all P pictures
61 * T > tauB : machines capable of decoding all B pictures
63 * 4. Decoding of an I picture
64 * ========================
65 * On fast machines, we decode all I's.
67 * We can decode an I picture if we simply have enough time to decode it
69 * t0 - t > tau´I + DELTA
71 * 5. Decoding of a P picture
72 * =======================
73 * On fast machines, we decode all P's.
75 * First criterion : have time to decode it.
76 * t2 - t > tau´P + DELTA
78 * Second criterion : it shouldn't prevent us from displaying the forthcoming
79 * I picture, which is more important.
80 * t12 - t > tau´P + tau´I + DELTA
82 * 6. Decoding of a B picture
83 * =======================
84 * On fast machines, we decode all B's. Otherwise :
85 * t1 - t > tau´B + DELTA
86 * Since the next displayed I or P is already decoded, we don't have to
89 * I hope you will have a pleasant flight and do not forget your life
91 * --Meuuh (2000-12-29)
94 /*****************************************************************************
96 *****************************************************************************/
101 #include <vlc_common.h>
102 #include <vlc_input.h>
103 #include <vlc_codec.h>
104 #include <vlc_codec_synchro.h>
110 #define MAX_PIC_AVERAGE 8
112 struct decoder_synchro_t
123 /* date of the beginning of the decoding of the current picture */
124 mtime_t decoding_start
;
126 /* stream properties */
127 unsigned int i_n_p
, i_n_b
;
129 /* decoding values */
130 mtime_t p_tau
[4]; /* average decoding durations */
131 unsigned int pi_meaningful
[4]; /* number of durations read */
133 /* render_time filled by SynchroChoose() */
137 int i_nb_ref
; /* Number of reference pictures */
138 int i_dec_nb_ref
; /* Number of reference pictures we'll *
139 * have if we decode the current pic */
140 int i_trash_nb_ref
; /* Number of reference pictures we'll *
141 * have if we trash the current pic */
142 unsigned int i_eta_p
, i_eta_b
;
143 mtime_t backward_pts
, current_pts
;
144 int i_current_period
; /* period to add to the next picture */
145 int i_backward_period
; /* period to add after the next
147 * (backward_period * period / 2) */
150 unsigned int i_trashed_pic
, i_not_chosen_pic
, i_pic
;
154 #define DELTA (int)(0.075*CLOCK_FREQ)
155 #define MAX_VALID_TAU (int)(0.3*CLOCK_FREQ)
157 #define DEFAULT_NB_P 5
158 #define DEFAULT_NB_B 1
160 /*****************************************************************************
161 * decoder_SynchroInit : You know what ?
162 *****************************************************************************/
163 decoder_synchro_t
* decoder_SynchroInit( decoder_t
*p_dec
, int i_frame_rate
)
165 decoder_synchro_t
* p_synchro
= malloc( sizeof(*p_synchro
) );
166 if ( p_synchro
== NULL
)
168 memset( p_synchro
, 0, sizeof(*p_synchro
) );
170 p_synchro
->p_dec
= p_dec
;
171 p_synchro
->b_no_skip
= !config_GetInt( p_dec
, "skip-frames" );
172 p_synchro
->b_quiet
= config_GetInt( p_dec
, "quiet-synchro" );
174 /* We use a fake stream pattern, which is often right. */
175 p_synchro
->i_n_p
= p_synchro
->i_eta_p
= DEFAULT_NB_P
;
176 p_synchro
->i_n_b
= p_synchro
->i_eta_b
= DEFAULT_NB_B
;
177 memset( p_synchro
->p_tau
, 0, 4 * sizeof(mtime_t
) );
178 memset( p_synchro
->pi_meaningful
, 0, 4 * sizeof(unsigned int) );
179 p_synchro
->i_nb_ref
= 0;
180 p_synchro
->i_trash_nb_ref
= p_synchro
->i_dec_nb_ref
= 0;
181 p_synchro
->current_pts
= mdate() + DEFAULT_PTS_DELAY
;
182 p_synchro
->backward_pts
= 0;
183 p_synchro
->i_current_period
= p_synchro
->i_backward_period
= 0;
184 p_synchro
->i_trashed_pic
= p_synchro
->i_not_chosen_pic
=
185 p_synchro
->i_pic
= 0;
187 p_synchro
->i_frame_rate
= i_frame_rate
;
192 /*****************************************************************************
193 * decoder_SynchroRelease : You know what ?
194 *****************************************************************************/
195 void decoder_SynchroRelease( decoder_synchro_t
* p_synchro
)
200 /*****************************************************************************
201 * decoder_SynchroReset : Reset the reference picture counter
202 *****************************************************************************/
203 void decoder_SynchroReset( decoder_synchro_t
* p_synchro
)
205 p_synchro
->i_nb_ref
= 0;
206 p_synchro
->i_trash_nb_ref
= p_synchro
->i_dec_nb_ref
= 0;
209 /*****************************************************************************
210 * decoder_SynchroChoose : Decide whether we will decode a picture or not
211 *****************************************************************************/
212 bool decoder_SynchroChoose( decoder_synchro_t
* p_synchro
, int i_coding_type
,
213 int i_render_time
, bool b_low_delay
)
215 #define TAU_PRIME( coding_type ) (p_synchro->p_tau[(coding_type)] \
216 + (p_synchro->p_tau[(coding_type)] >> 1) \
217 + p_synchro->i_render_time)
218 #define S (*p_synchro)
223 if ( p_synchro
->b_no_skip
)
227 period
= 1000000 * 1001 / p_synchro
->i_frame_rate
228 * p_synchro
->i_current_rate
/ INPUT_RATE_DEFAULT
;
230 p_synchro
->i_render_time
= i_render_time
;
232 switch( i_coding_type
)
239 else if( S
.backward_pts
)
241 pts
= S
.backward_pts
;
245 /* displaying order : B B P B B I
247 * | +- current picture
250 pts
= S
.current_pts
+ period
* (S
.i_n_b
+ 2);
253 if( (1 + S
.i_n_p
* (S
.i_n_b
+ 1)) * period
>
254 S
.p_tau
[I_CODING_TYPE
] )
260 b_decode
= (pts
- now
) > (TAU_PRIME(I_CODING_TYPE
) + DELTA
);
262 if( !b_decode
&& !p_synchro
->b_quiet
)
264 msg_Warn( p_synchro
->p_dec
,
265 "synchro trashing I (%"PRId64
")", pts
- now
);
274 else if( S
.backward_pts
)
276 pts
= S
.backward_pts
;
280 pts
= S
.current_pts
+ period
* (S
.i_n_b
+ 1);
283 if( p_synchro
->i_nb_ref
< 1 )
287 else if( (1 + S
.i_n_p
* (S
.i_n_b
+ 1)) * period
>
288 S
.p_tau
[I_CODING_TYPE
] )
290 if( (S
.i_n_b
+ 1) * period
> S
.p_tau
[P_CODING_TYPE
] )
292 /* Security in case we're _really_ late */
293 b_decode
= (pts
- now
> 0);
297 b_decode
= (pts
- now
) > (TAU_PRIME(P_CODING_TYPE
) + DELTA
);
299 b_decode
&= (pts
- now
301 * ( (S
.i_n_p
- S
.i_eta_p
) * (1 + S
.i_n_b
) - 1 ))
302 > (TAU_PRIME(P_CODING_TYPE
)
303 + TAU_PRIME(I_CODING_TYPE
) + DELTA
);
315 if( p_synchro
->i_nb_ref
< 2 )
319 else if( (S
.i_n_b
+ 1) * period
> S
.p_tau
[P_CODING_TYPE
] )
321 b_decode
= (pts
- now
) > (TAU_PRIME(B_CODING_TYPE
) + DELTA
);
331 S
.i_not_chosen_pic
++;
338 /*****************************************************************************
339 * decoder_SynchroTrash : Update counters when we trash a picture
340 *****************************************************************************/
341 void decoder_SynchroTrash( decoder_synchro_t
* p_synchro
)
343 p_synchro
->i_trashed_pic
++;
344 p_synchro
->i_nb_ref
= p_synchro
->i_trash_nb_ref
;
347 /*****************************************************************************
348 * decoder_SynchroDecode : Update timers when we decide to decode a picture
349 *****************************************************************************/
350 void decoder_SynchroDecode( decoder_synchro_t
* p_synchro
)
352 p_synchro
->decoding_start
= mdate();
353 p_synchro
->i_nb_ref
= p_synchro
->i_dec_nb_ref
;
356 /*****************************************************************************
357 * decoder_SynchroEnd : Called when the image is totally decoded
358 *****************************************************************************/
359 void decoder_SynchroEnd( decoder_synchro_t
* p_synchro
, int i_coding_type
,
366 tau
= mdate() - p_synchro
->decoding_start
;
368 /* If duration too high, something happened (pause ?), so don't
369 * take it into account. */
370 if( tau
< 3 * p_synchro
->p_tau
[i_coding_type
]
371 || ( !p_synchro
->pi_meaningful
[i_coding_type
]
372 && tau
< MAX_VALID_TAU
) )
374 /* Mean with average tau, to ensure stability. */
375 p_synchro
->p_tau
[i_coding_type
] =
376 (p_synchro
->pi_meaningful
[i_coding_type
]
377 * p_synchro
->p_tau
[i_coding_type
] + tau
)
378 / (p_synchro
->pi_meaningful
[i_coding_type
] + 1);
379 if( p_synchro
->pi_meaningful
[i_coding_type
] < MAX_PIC_AVERAGE
)
381 p_synchro
->pi_meaningful
[i_coding_type
]++;
387 /*****************************************************************************
388 * decoder_SynchroDate : When an image has been decoded, ask for its date
389 *****************************************************************************/
390 mtime_t
decoder_SynchroDate( decoder_synchro_t
* p_synchro
)
392 /* No need to lock, since PTS are only used by the video parser. */
393 return p_synchro
->current_pts
;
396 /*****************************************************************************
397 * decoder_SynchroNewPicture: Update stream structure and PTS
398 *****************************************************************************/
399 void decoder_SynchroNewPicture( decoder_synchro_t
* p_synchro
, int i_coding_type
,
400 int i_repeat_field
, mtime_t next_pts
,
401 mtime_t next_dts
, int i_current_rate
,
404 mtime_t period
= 1000000 * 1001 / p_synchro
->i_frame_rate
405 * i_current_rate
/ INPUT_RATE_DEFAULT
;
407 mtime_t now
= mdate();
409 p_synchro
->i_current_rate
= i_current_rate
;
411 switch( i_coding_type
)
414 if( p_synchro
->i_eta_p
415 && p_synchro
->i_eta_p
!= p_synchro
->i_n_p
)
418 if( !p_synchro
->b_quiet
)
419 msg_Dbg( p_synchro
->p_dec
,
420 "stream periodicity changed from P[%d] to P[%d]",
421 p_synchro
->i_n_p
, p_synchro
->i_eta_p
);
423 p_synchro
->i_n_p
= p_synchro
->i_eta_p
;
425 p_synchro
->i_eta_p
= p_synchro
->i_eta_b
= 0;
426 p_synchro
->i_trash_nb_ref
= 0;
427 if( p_synchro
->i_nb_ref
< 2 )
428 p_synchro
->i_dec_nb_ref
= p_synchro
->i_nb_ref
+ 1;
430 p_synchro
->i_dec_nb_ref
= p_synchro
->i_nb_ref
;
433 if( !p_synchro
->b_quiet
)
434 msg_Dbg( p_synchro
->p_dec
, "I(%"PRId64
") P(%"PRId64
")[%d] B(%"PRId64
")"
435 "[%d] YUV(%"PRId64
") : trashed %d:%d/%d",
436 p_synchro
->p_tau
[I_CODING_TYPE
],
437 p_synchro
->p_tau
[P_CODING_TYPE
],
439 p_synchro
->p_tau
[B_CODING_TYPE
],
441 p_synchro
->i_render_time
,
442 p_synchro
->i_not_chosen_pic
,
443 p_synchro
->i_trashed_pic
-
444 p_synchro
->i_not_chosen_pic
,
446 p_synchro
->i_trashed_pic
= p_synchro
->i_not_chosen_pic
447 = p_synchro
->i_pic
= 0;
449 if( p_synchro
->i_pic
>= 100 )
451 if( !p_synchro
->b_quiet
&& p_synchro
->i_trashed_pic
!= 0 )
452 msg_Dbg( p_synchro
->p_dec
, "decoded %d/%d pictures",
454 - p_synchro
->i_trashed_pic
,
456 p_synchro
->i_trashed_pic
= p_synchro
->i_not_chosen_pic
457 = p_synchro
->i_pic
= 0;
463 p_synchro
->i_eta_p
++;
464 if( p_synchro
->i_eta_b
465 && p_synchro
->i_eta_b
!= p_synchro
->i_n_b
)
468 if( !p_synchro
->b_quiet
)
469 msg_Dbg( p_synchro
->p_dec
,
470 "stream periodicity changed from B[%d] to B[%d]",
471 p_synchro
->i_n_b
, p_synchro
->i_eta_b
);
473 p_synchro
->i_n_b
= p_synchro
->i_eta_b
;
475 p_synchro
->i_eta_b
= 0;
476 p_synchro
->i_dec_nb_ref
= 2;
477 p_synchro
->i_trash_nb_ref
= 0;
481 p_synchro
->i_eta_b
++;
482 p_synchro
->i_dec_nb_ref
= p_synchro
->i_trash_nb_ref
483 = p_synchro
->i_nb_ref
;
487 p_synchro
->current_pts
+= p_synchro
->i_current_period
490 #define PTS_THRESHOLD (period >> 2)
491 if( i_coding_type
== B_CODING_TYPE
|| b_low_delay
)
493 /* A video frame can be displayed 1, 2 or 3 times, according to
494 * repeat_first_field, top_field_first, progressive_sequence and
495 * progressive_frame. */
496 p_synchro
->i_current_period
= i_repeat_field
;
500 if( (next_pts
- p_synchro
->current_pts
502 || p_synchro
->current_pts
- next_pts
503 > PTS_THRESHOLD
) && !p_synchro
->b_quiet
)
505 msg_Warn( p_synchro
->p_dec
, "decoder synchro warning: pts != "
506 "current_date (%"PRId64
")",
507 p_synchro
->current_pts
510 p_synchro
->current_pts
= next_pts
;
515 p_synchro
->i_current_period
= p_synchro
->i_backward_period
;
516 p_synchro
->i_backward_period
= i_repeat_field
;
518 if( p_synchro
->backward_pts
)
521 (next_dts
- p_synchro
->backward_pts
523 || p_synchro
->backward_pts
- next_dts
524 > PTS_THRESHOLD
) && !p_synchro
->b_quiet
)
526 msg_Warn( p_synchro
->p_dec
, "backward_pts != dts (%"PRId64
")",
528 - p_synchro
->backward_pts
);
530 if( (p_synchro
->backward_pts
- p_synchro
->current_pts
532 || p_synchro
->current_pts
- p_synchro
->backward_pts
533 > PTS_THRESHOLD
) && !p_synchro
->b_quiet
)
535 msg_Warn( p_synchro
->p_dec
,
536 "backward_pts != current_pts (%"PRId64
")",
537 p_synchro
->current_pts
538 - p_synchro
->backward_pts
);
540 p_synchro
->current_pts
= p_synchro
->backward_pts
;
541 p_synchro
->backward_pts
= 0;
545 if( (next_dts
- p_synchro
->current_pts
547 || p_synchro
->current_pts
- next_dts
548 > PTS_THRESHOLD
) && !p_synchro
->b_quiet
)
550 msg_Warn( p_synchro
->p_dec
, "dts != current_pts (%"PRId64
")",
551 p_synchro
->current_pts
554 /* By definition of a DTS. */
555 p_synchro
->current_pts
= next_dts
;
561 /* Store the PTS for the next time we have to date an I picture. */
562 p_synchro
->backward_pts
= next_pts
;
569 /* Removed for incompatibility with slow motion */
570 if( p_synchro
->current_pts
+ DEFAULT_PTS_DELAY
< now
)
572 /* We cannot be _that_ late, something must have happened, reinit
574 if( !p_synchro
->b_quiet
)
575 msg_Warn( p_synchro
->p_dec
, "PTS << now (%"PRId64
"), resetting",
576 now
- p_synchro
->current_pts
- DEFAULT_PTS_DELAY
);
577 p_synchro
->current_pts
= now
+ DEFAULT_PTS_DELAY
;
579 if( p_synchro
->backward_pts
580 && p_synchro
->backward_pts
+ DEFAULT_PTS_DELAY
< now
)
583 p_synchro
->backward_pts
= 0;