25 |
* along with this program; if not, write to the Free Software |
* along with this program; if not, write to the Free Software |
26 |
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA |
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA |
27 |
* |
* |
28 |
* $Id: plugin_2pass2.c,v 1.1.2.20 2003-06-09 13:55:07 edgomez Exp $ |
* $Id: plugin_2pass2.c,v 1.1.2.31 2003-12-17 15:16:16 edgomez Exp $ |
29 |
* |
* |
30 |
*****************************************************************************/ |
*****************************************************************************/ |
31 |
|
|
32 |
|
#define BQUANT_PRESCALE |
33 |
|
#undef COMPENSATE_FORMULA |
34 |
|
|
35 |
#include <stdio.h> |
#include <stdio.h> |
36 |
#include <math.h> |
#include <math.h> |
37 |
#include <limits.h> |
#include <limits.h> |
40 |
#include "../image/image.h" |
#include "../image/image.h" |
41 |
|
|
42 |
/***************************************************************************** |
/***************************************************************************** |
43 |
* Some constants |
* Some default settings |
44 |
****************************************************************************/ |
****************************************************************************/ |
45 |
|
|
46 |
#define DEFAULT_KEYFRAME_BOOST 0 |
#define DEFAULT_KEYFRAME_BOOST 0 |
47 |
#define DEFAULT_PAYBACK_METHOD XVID_PAYBACK_PROP |
#define DEFAULT_OVERFLOW_CONTROL_STRENGTH 10 |
|
#define DEFAULT_BITRATE_PAYBACK_DELAY 250 |
|
48 |
#define DEFAULT_CURVE_COMPRESSION_HIGH 0 |
#define DEFAULT_CURVE_COMPRESSION_HIGH 0 |
49 |
#define DEFAULT_CURVE_COMPRESSION_LOW 0 |
#define DEFAULT_CURVE_COMPRESSION_LOW 0 |
50 |
#define DEFAULT_MAX_OVERFLOW_IMPROVEMENT 60 |
#define DEFAULT_MAX_OVERFLOW_IMPROVEMENT 10 |
51 |
#define DEFAULT_MAX_OVERFLOW_DEGRADATION 60 |
#define DEFAULT_MAX_OVERFLOW_DEGRADATION 10 |
52 |
|
|
53 |
/* Keyframe settings */ |
/* Keyframe settings */ |
|
#define DEFAULT_KFTRESHOLD 10 |
|
54 |
#define DEFAULT_KFREDUCTION 20 |
#define DEFAULT_KFREDUCTION 20 |
55 |
#define DEFAULT_MIN_KEY_INTERVAL 1 |
#define DEFAULT_KFTHRESHOLD 1 |
56 |
|
|
57 |
|
/***************************************************************************** |
58 |
|
* Some default constants (can be tuned) |
59 |
|
****************************************************************************/ |
60 |
|
|
61 |
|
/* Specify the invariant part of the headers bits (header+MV) |
62 |
|
* as hlength/cst */ |
63 |
|
#define INVARIANT_HEADER_PART_IVOP 1 /* factor 1.0f */ |
64 |
|
#define INVARIANT_HEADER_PART_PVOP 2 /* factor 0.5f */ |
65 |
|
#define INVARIANT_HEADER_PART_BVOP 8 /* factor 0.125f */ |
66 |
|
|
67 |
/***************************************************************************** |
/***************************************************************************** |
68 |
* Structures |
* Structures |
74 |
int quant; /* first pass quant */ |
int quant; /* first pass quant */ |
75 |
int blks[3]; /* k,m,y blks */ |
int blks[3]; /* k,m,y blks */ |
76 |
int length; /* first pass length */ |
int length; /* first pass length */ |
77 |
|
int invariant; /* what we assume as being invariant between the two passes, it's a sub part of header + MV bits */ |
78 |
int scaled_length; /* scaled length */ |
int scaled_length; /* scaled length */ |
79 |
int desired_length; /* desired length; calcuated during encoding */ |
int desired_length; /* desired length; calculated during encoding */ |
80 |
|
int error; |
81 |
|
|
82 |
int zone_mode; /* XVID_ZONE_xxx */ |
int zone_mode; /* XVID_ZONE_xxx */ |
83 |
double weight; |
double weight; |
84 |
} stat_t; |
} twopass_stat_t; |
85 |
|
|
86 |
/* Context struct */ |
/* Context struct */ |
87 |
typedef struct |
typedef struct |
88 |
{ |
{ |
89 |
xvid_plugin_2pass2_t param; |
xvid_plugin_2pass2_t param; |
90 |
|
|
91 |
/* constant statistical data */ |
/*---------------------------------- |
92 |
int num_frames; |
* constant statistical data |
93 |
int num_keyframes; |
*--------------------------------*/ |
|
uint64_t target; /* target filesize */ |
|
94 |
|
|
95 |
int count[3]; /* count of each frame types */ |
/* Number of frames of the sequence */ |
96 |
uint64_t tot_length[3]; /* total length of each frame types */ |
int num_frames; |
|
double avg_length[3]; /* avg */ |
|
|
int min_length[3]; /* min frame length of each frame types */ |
|
|
uint64_t tot_scaled_length[3]; /* total scaled length of each frame type */ |
|
|
int max_length; /* max frame size */ |
|
97 |
|
|
98 |
/* zone statistical data */ |
/* Number of Intra frames of the sequence */ |
99 |
double avg_weight; /* average weight */ |
int num_keyframes; |
|
int64_t tot_quant; /* total length used by XVID_ZONE_QUANT zones */ |
|
100 |
|
|
101 |
|
/* Target filesize to reach */ |
102 |
|
uint64_t target; |
103 |
|
|
104 |
double curve_comp_scale; |
/* Count of each frame types */ |
105 |
double movie_curve; |
int count[3]; |
106 |
|
|
107 |
/* dynamic */ |
/* Total length of each frame types (1st pass) */ |
108 |
|
uint64_t tot_length[3]; |
109 |
|
uint64_t tot_invariant[3]; |
110 |
|
|
111 |
|
/* Average length of each frame types (used first for 1st pass data and |
112 |
|
* then for scaled averages */ |
113 |
|
double avg_length[3]; |
114 |
|
|
115 |
|
/* Minimum frame length allowed for each frame type */ |
116 |
|
int min_length[3]; |
117 |
|
|
118 |
|
/* Total bytes per frame type once the curve has been scaled |
119 |
|
* NB: advanced parameters do not change this value. This field |
120 |
|
* represents the total scaled w/o any advanced settings */ |
121 |
|
uint64_t tot_scaled_length[3]; |
122 |
|
|
123 |
|
/* Maximum observed frame size observed during the first pass, the RC |
124 |
|
* will try tp force all frame sizes in the second pass to be under that |
125 |
|
* limit */ |
126 |
|
int max_length; |
127 |
|
|
128 |
|
/*---------------------------------- |
129 |
|
* Zones statistical data |
130 |
|
* |
131 |
|
* ToDo: Fix zones, current |
132 |
|
* implementation is buggy |
133 |
|
*--------------------------------*/ |
134 |
|
|
135 |
|
/* Average weight of the zones */ |
136 |
|
double avg_weight; |
137 |
|
|
138 |
|
/* Total length used by XVID_ZONE_QUANT zones */ |
139 |
|
uint64_t tot_quant; |
140 |
|
uint64_t tot_quant_invariant; |
141 |
|
|
142 |
|
/*---------------------------------- |
143 |
|
* Advanced settings helper ratios |
144 |
|
*--------------------------------*/ |
145 |
|
|
146 |
|
/* This the ratio that has to be applied to all p/b frames in order |
147 |
|
* to reserve/retrieve bits for/from keyframe boosting and consecutive |
148 |
|
* keyframe penalty */ |
149 |
|
double pb_iboost_tax_ratio; |
150 |
|
|
151 |
|
/* This the ratio to apply to all b/p frames in order to respect the |
152 |
|
* assymetric curve compression while respecting a target filesize |
153 |
|
* NB: The assymetric delta gain has to be computed before this ratio |
154 |
|
* is applied, and then the delta is added to the scaled size */ |
155 |
|
double assymetric_tax_ratio; |
156 |
|
|
157 |
|
/*---------------------------------- |
158 |
|
* Data from the stats file kept |
159 |
|
* into RAM for easy access |
160 |
|
*--------------------------------*/ |
161 |
|
|
162 |
|
/* Array of keyframe locations |
163 |
|
* eg: rc->keyframe_locations[100] returns the frame number of the 100th |
164 |
|
* keyframe */ |
165 |
int * keyframe_locations; |
int * keyframe_locations; |
|
stat_t * stats; |
|
166 |
|
|
167 |
|
/* Index of the last keyframe used in the keyframe_location */ |
168 |
|
int KF_idx; |
169 |
|
|
170 |
|
/* Array of all 1st pass data file -- see the twopass_stat_t structure |
171 |
|
* definition for more details */ |
172 |
|
twopass_stat_t * stats; |
173 |
|
|
174 |
|
/*---------------------------------- |
175 |
|
* Histerysis helpers |
176 |
|
*--------------------------------*/ |
177 |
|
|
178 |
|
/* This field holds the int2float conversion errors of each quant per |
179 |
|
* frame type, this allow the RC to keep track of rouding error and thus |
180 |
|
* increase or decrease the chosen quant according to this residue */ |
181 |
double quant_error[3][32]; |
double quant_error[3][32]; |
182 |
int quant_count[32]; |
|
183 |
|
/* This fields stores the count of each quant usage per frame type |
184 |
|
* No real role but for debugging */ |
185 |
|
int quant_count[3][32]; |
186 |
|
|
187 |
|
/* Last valid quantizer used per frame type, it allows quantizer |
188 |
|
* increament/decreament limitation in order to avoid big image quality |
189 |
|
* "jumps" */ |
190 |
int last_quant[3]; |
int last_quant[3]; |
191 |
|
|
192 |
double curve_comp_error; |
/*---------------------------------- |
193 |
int overflow; |
* Overflow control |
194 |
int KFoverflow; |
*--------------------------------*/ |
195 |
int KFoverflow_partial; |
|
196 |
int KF_idx; |
/* Current overflow that has to be distributed to p/b frames */ |
197 |
|
double overflow; |
198 |
|
|
199 |
|
/* Total overflow for keyframes -- not distributed directly */ |
200 |
|
double KFoverflow; |
201 |
|
|
202 |
|
/* Amount of keyframe overflow to introduce to the global p/b frame |
203 |
|
* overflow counter at each encoded frame */ |
204 |
|
double KFoverflow_partial; |
205 |
|
|
206 |
|
/* Unknown ??? |
207 |
|
* ToDo: description */ |
208 |
double fq_error; |
double fq_error; |
209 |
|
|
210 |
|
/*---------------------------------- |
211 |
|
* Debug |
212 |
|
*--------------------------------*/ |
213 |
|
double desired_total; |
214 |
|
double real_total; |
215 |
} rc_2pass2_t; |
} rc_2pass2_t; |
216 |
|
|
217 |
|
|
233 |
{ |
{ |
234 |
switch(opt) { |
switch(opt) { |
235 |
case XVID_PLG_INFO : |
case XVID_PLG_INFO : |
236 |
|
case XVID_PLG_FRAME : |
237 |
return 0; |
return 0; |
238 |
|
|
239 |
case XVID_PLG_CREATE : |
case XVID_PLG_CREATE : |
257 |
****************************************************************************/ |
****************************************************************************/ |
258 |
|
|
259 |
/* First a few local helping function prototypes */ |
/* First a few local helping function prototypes */ |
260 |
static int det_stats_length(rc_2pass2_t * rc, char * filename); |
static int statsfile_count_frames(rc_2pass2_t * rc, char * filename); |
261 |
static int load_stats(rc_2pass2_t *rc, char * filename); |
static int statsfile_load(rc_2pass2_t *rc, char * filename); |
262 |
static void zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create); |
static void zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create); |
263 |
static void internal_scale(rc_2pass2_t *rc); |
static void first_pass_stats_prepare_data(rc_2pass2_t * rc); |
264 |
static void pre_process0(rc_2pass2_t * rc); |
static void first_pass_scale_curve_internal(rc_2pass2_t *rc); |
265 |
static void pre_process1(rc_2pass2_t * rc); |
static void scaled_curve_apply_advanced_parameters(rc_2pass2_t * rc); |
266 |
|
#if 0 |
267 |
|
static void stats_print(rc_2pass2_t * rc); |
268 |
|
#endif |
269 |
|
|
270 |
/*---------------------------------------------------------------------------- |
/*---------------------------------------------------------------------------- |
271 |
*--------------------------------------------------------------------------*/ |
*--------------------------------------------------------------------------*/ |
283 |
|
|
284 |
rc->param = *param; |
rc->param = *param; |
285 |
|
|
286 |
/* |
/* Initialize all defaults */ |
|
* Initialize all defaults |
|
|
*/ |
|
287 |
#define _INIT(a, b) if((a) <= 0) (a) = (b) |
#define _INIT(a, b) if((a) <= 0) (a) = (b) |
288 |
/* Let's set our defaults if needed */ |
/* Let's set our defaults if needed */ |
289 |
_INIT(rc->param.keyframe_boost, DEFAULT_KEYFRAME_BOOST); |
_INIT(rc->param.keyframe_boost, DEFAULT_KEYFRAME_BOOST); |
290 |
_INIT(rc->param.payback_method, DEFAULT_PAYBACK_METHOD); |
_INIT(rc->param.overflow_control_strength, DEFAULT_OVERFLOW_CONTROL_STRENGTH); |
|
_INIT(rc->param.bitrate_payback_delay, DEFAULT_BITRATE_PAYBACK_DELAY); |
|
291 |
_INIT(rc->param.curve_compression_high, DEFAULT_CURVE_COMPRESSION_HIGH); |
_INIT(rc->param.curve_compression_high, DEFAULT_CURVE_COMPRESSION_HIGH); |
292 |
_INIT(rc->param.curve_compression_low, DEFAULT_CURVE_COMPRESSION_LOW); |
_INIT(rc->param.curve_compression_low, DEFAULT_CURVE_COMPRESSION_LOW); |
293 |
_INIT(rc->param.max_overflow_improvement, DEFAULT_MAX_OVERFLOW_IMPROVEMENT); |
_INIT(rc->param.max_overflow_improvement, DEFAULT_MAX_OVERFLOW_IMPROVEMENT); |
294 |
_INIT(rc->param.max_overflow_degradation, DEFAULT_MAX_OVERFLOW_DEGRADATION); |
_INIT(rc->param.max_overflow_degradation, DEFAULT_MAX_OVERFLOW_DEGRADATION); |
295 |
|
|
296 |
/* Keyframe settings */ |
/* Keyframe settings */ |
|
_INIT(rc->param.kftreshold, DEFAULT_KFTRESHOLD); |
|
297 |
_INIT(rc->param.kfreduction, DEFAULT_KFREDUCTION); |
_INIT(rc->param.kfreduction, DEFAULT_KFREDUCTION); |
298 |
_INIT(rc->param.min_key_interval, DEFAULT_MIN_KEY_INTERVAL); |
_INIT(rc->param.kfthreshold, DEFAULT_KFTHRESHOLD); |
299 |
#undef _INIT |
#undef _INIT |
300 |
|
|
301 |
/* Initialize some stuff to zero */ |
/* Initialize some stuff to zero */ |
|
for(i=0; i<32; i++) rc->quant_count[i] = 0; |
|
|
|
|
302 |
for(i=0; i<3; i++) { |
for(i=0; i<3; i++) { |
303 |
int j; |
int j; |
304 |
for (j=0; j<32; j++) |
for (j=0; j<32; j++) { |
305 |
rc->quant_error[i][j] = 0; |
rc->quant_error[i][j] = 0; |
306 |
|
rc->quant_count[i][j] = 0; |
307 |
|
} |
308 |
} |
} |
309 |
|
|
310 |
for (i=0; i<3; i++) |
for (i=0; i<3; i++) rc->last_quant[i] = 0; |
|
rc->last_quant[i] = 0; |
|
311 |
|
|
312 |
rc->fq_error = 0; |
rc->fq_error = 0; |
313 |
|
|
314 |
/* Count frames in the stats file */ |
/* Count frames (and intra frames) in the stats file, store the result into |
315 |
if (!det_stats_length(rc, param->filename)) { |
* the rc structure */ |
316 |
DPRINTF(XVID_DEBUG_RC,"ERROR: fopen %s failed\n", param->filename); |
if (statsfile_count_frames(rc, param->filename) == -1) { |
317 |
|
DPRINTF(XVID_DEBUG_RC,"[xvid rc] -- ERROR: fopen %s failed\n", param->filename); |
318 |
free(rc); |
free(rc); |
319 |
return XVID_ERR_FAIL; |
return(XVID_ERR_FAIL); |
320 |
} |
} |
321 |
|
|
322 |
/* Allocate the stats' memory */ |
/* Allocate the stats' memory */ |
323 |
if ((rc->stats = malloc(rc->num_frames * sizeof(stat_t))) == NULL) { |
if ((rc->stats = malloc(rc->num_frames * sizeof(twopass_stat_t))) == NULL) { |
324 |
free(rc); |
free(rc); |
325 |
return XVID_ERR_MEMORY; |
return(XVID_ERR_MEMORY); |
326 |
} |
} |
327 |
|
|
328 |
/* |
/* Allocate keyframes location's memory |
329 |
* Allocate keyframes location's memory |
* PS: see comment in pre_process0 for the +1 location requirement */ |
|
* PS: see comment in pre_process0 for the +1 location requirement |
|
|
*/ |
|
330 |
rc->keyframe_locations = malloc((rc->num_keyframes + 1) * sizeof(int)); |
rc->keyframe_locations = malloc((rc->num_keyframes + 1) * sizeof(int)); |
331 |
if (rc->keyframe_locations == NULL) { |
if (rc->keyframe_locations == NULL) { |
332 |
free(rc->stats); |
free(rc->stats); |
333 |
free(rc); |
free(rc); |
334 |
return XVID_ERR_MEMORY; |
return(XVID_ERR_MEMORY); |
335 |
} |
} |
336 |
|
|
337 |
if (!load_stats(rc, param->filename)) { |
/* Load the first pass stats */ |
338 |
DPRINTF(XVID_DEBUG_RC,"ERROR: fopen %s failed\n", param->filename); |
if (statsfile_load(rc, param->filename) == -1) { |
339 |
|
DPRINTF(XVID_DEBUG_RC,"[xvid rc] -- ERROR: fopen %s failed\n", param->filename); |
340 |
free(rc->keyframe_locations); |
free(rc->keyframe_locations); |
341 |
free(rc->stats); |
free(rc->stats); |
342 |
free(rc); |
free(rc); |
344 |
} |
} |
345 |
|
|
346 |
/* Compute the target filesize */ |
/* Compute the target filesize */ |
347 |
if (rc->num_frames < create->fbase/create->fincr) { |
if (rc->param.bitrate<0) { |
348 |
|
/* if negative, bitrate equals the target (in kbytes) */ |
349 |
|
rc->target = ((uint64_t)(-rc->param.bitrate)) * 1024; |
350 |
|
} else if (rc->num_frames < create->fbase/create->fincr) { |
351 |
/* Source sequence is less than 1s long, we do as if it was 1s long */ |
/* Source sequence is less than 1s long, we do as if it was 1s long */ |
352 |
rc->target = rc->param.bitrate / 8; |
rc->target = rc->param.bitrate / 8; |
353 |
} else { |
} else { |
358 |
((uint64_t)create->fbase * 8); |
((uint64_t)create->fbase * 8); |
359 |
} |
} |
360 |
|
|
361 |
DPRINTF(XVID_DEBUG_RC, "Frame rate: %d/%d (%ffps)\n", |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Frame rate: %d/%d (%ffps)\n", |
362 |
create->fbase, create->fincr, |
create->fbase, create->fincr, |
363 |
(double)create->fbase/(double)create->fincr); |
(double)create->fbase/(double)create->fincr); |
364 |
DPRINTF(XVID_DEBUG_RC, "Number of frames: %d\n", rc->num_frames); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Number of frames: %d\n", rc->num_frames); |
365 |
DPRINTF(XVID_DEBUG_RC, "Target bitrate: %ld\n", rc->param.bitrate); |
if(rc->param.bitrate>=0) |
366 |
DPRINTF(XVID_DEBUG_RC, "Target filesize: %lld\n", rc->target); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Target bitrate: %ld\n", rc->param.bitrate); |
367 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Target filesize: %lld\n", rc->target); |
368 |
|
|
369 |
/* Compensate the average frame overhead caused by the container */ |
/* Compensate the average frame overhead caused by the container */ |
370 |
rc->target -= rc->num_frames*rc->param.container_frame_overhead; |
rc->target -= rc->num_frames*rc->param.container_frame_overhead; |
371 |
DPRINTF(XVID_DEBUG_RC, "Container Frame overhead: %d\n", rc->param.container_frame_overhead); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Container Frame overhead: %d\n", rc->param.container_frame_overhead); |
372 |
DPRINTF(XVID_DEBUG_RC, "Target filesize (after container compensation): %lld\n", rc->target); |
if(rc->param.container_frame_overhead) |
373 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- New target filesize after container compensation: %lld\n", rc->target); |
374 |
|
|
375 |
/* |
/* Gathers some information about first pass stats: |
|
* First data pre processing: |
|
376 |
* - finds the minimum frame length for each frame type during 1st pass. |
* - finds the minimum frame length for each frame type during 1st pass. |
377 |
* rc->min_size[] |
* rc->min_size[] |
378 |
* - determines the maximum frame length observed (no frame type distinction). |
* - determines the maximum frame length observed (no frame type distinction). |
380 |
* - count how many times each frame type has been used. |
* - count how many times each frame type has been used. |
381 |
* rc->count[] |
* rc->count[] |
382 |
* - total bytes used per frame type |
* - total bytes used per frame type |
383 |
* rc->total[] |
* rc->tot_length[] |
384 |
|
* - total bytes considered invariant between the 2 passes |
385 |
* - store keyframe location |
* - store keyframe location |
386 |
* rc->keyframe_locations[] |
* rc->keyframe_locations[] |
387 |
*/ |
*/ |
388 |
pre_process0(rc); |
first_pass_stats_prepare_data(rc); |
389 |
|
|
390 |
/* |
/* When bitrate is not given it means it has been scaled by an external |
391 |
* When bitrate is not given it means it has been scaled by an external |
* application */ |
|
* application |
|
|
*/ |
|
392 |
if (rc->param.bitrate) { |
if (rc->param.bitrate) { |
393 |
/* Apply zone settings */ |
/* Apply zone settings |
394 |
|
* - set rc->tot_quant which represents the total num of bytes spent in |
395 |
|
* fixed quant zones |
396 |
|
* - set rc->tot_quant_invariant which represents the total num of bytes spent |
397 |
|
* in fixed quant zones for headers */ |
398 |
zone_process(rc, create); |
zone_process(rc, create); |
399 |
/* Perform curve scaling */ |
/* Perform internal curve scaling */ |
400 |
internal_scale(rc); |
first_pass_scale_curve_internal(rc); |
401 |
} else { |
} else { |
402 |
/* External scaling -- zones are ignored */ |
/* External scaling -- zones are ignored */ |
403 |
for (i=0;i<rc->num_frames;i++) { |
for (i=0;i<rc->num_frames;i++) { |
408 |
rc->tot_quant = 0; |
rc->tot_quant = 0; |
409 |
} |
} |
410 |
|
|
411 |
pre_process1(rc); |
/* Apply advanced curve options, and compute some parameters in order to |
412 |
|
* shape the curve in the BEFORE/AFTER pair of functions */ |
413 |
|
scaled_curve_apply_advanced_parameters(rc); |
414 |
|
|
415 |
*handle = rc; |
*handle = rc; |
416 |
return(0); |
return(0); |
422 |
static int |
static int |
423 |
rc_2pass2_destroy(rc_2pass2_t * rc, xvid_plg_destroy_t * destroy) |
rc_2pass2_destroy(rc_2pass2_t * rc, xvid_plg_destroy_t * destroy) |
424 |
{ |
{ |
425 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- target_total:%lld desired_total:%.2f (%.2f%%) actual_total:%.2f (%.2f%%)\n", |
426 |
|
rc->target, |
427 |
|
rc->desired_total, |
428 |
|
100*rc->desired_total/(double)rc->target, |
429 |
|
rc->real_total, |
430 |
|
100*rc->real_total/(double)rc->target); |
431 |
|
|
432 |
free(rc->keyframe_locations); |
free(rc->keyframe_locations); |
433 |
free(rc->stats); |
free(rc->stats); |
434 |
free(rc); |
free(rc); |
441 |
static int |
static int |
442 |
rc_2pass2_before(rc_2pass2_t * rc, xvid_plg_data_t * data) |
rc_2pass2_before(rc_2pass2_t * rc, xvid_plg_data_t * data) |
443 |
{ |
{ |
444 |
stat_t * s = &rc->stats[data->frame_num]; |
twopass_stat_t * s = &rc->stats[data->frame_num]; |
|
int overflow; |
|
|
int desired; |
|
445 |
double dbytes; |
double dbytes; |
|
double curve_temp; |
|
446 |
double scaled_quant; |
double scaled_quant; |
447 |
|
double overflow; |
448 |
int capped_to_max_framesize = 0; |
int capped_to_max_framesize = 0; |
449 |
|
|
450 |
/* |
/* This function is quite long but easy to understand. In order to simplify |
451 |
* This function is quite long but easy to understand. In order to simplify |
* the code path (a bit), we treat 3 cases that can return immediatly. */ |
|
* the code path (a bit), we treat 3 cases that can return immediatly. |
|
|
*/ |
|
452 |
|
|
453 |
/* First case: Another plugin has already set a quantizer */ |
/* First case: Another plugin has already set a quantizer */ |
454 |
if (data->quant > 0) |
if (data->quant > 0) |
455 |
return(0); |
return(0); |
456 |
|
|
457 |
/* Second case: We are in a Quant zone */ |
/* Second case: insufficent stats data */ |
458 |
|
if (data->frame_num >= rc->num_frames) { |
459 |
|
DPRINTF(XVID_DEBUG_RC,"[xvid rc] -- stats file too short (now processing frame %d)", |
460 |
|
data->frame_num); |
461 |
|
return(0); |
462 |
|
} |
463 |
|
|
464 |
|
/* Third case: We are in a Quant zone */ |
465 |
if (s->zone_mode == XVID_ZONE_QUANT) { |
if (s->zone_mode == XVID_ZONE_QUANT) { |
466 |
rc->fq_error += s->weight; |
rc->fq_error += s->weight; |
467 |
data->quant = (int)rc->fq_error; |
data->quant = (int)rc->fq_error; |
472 |
return(0); |
return(0); |
473 |
} |
} |
474 |
|
|
|
/* Third case: insufficent stats data */ |
|
|
if (data->frame_num >= rc->num_frames) |
|
|
return 0; |
|
|
|
|
|
/* XXX: why by 8 */ |
|
|
overflow = rc->overflow / 8; |
|
|
|
|
|
/* |
|
|
* The rc->overflow field represents the overflow in current scene (between two |
|
|
* IFrames) so we must not forget to reset it if we are entering a new scene |
|
|
*/ |
|
|
if (s->type == XVID_TYPE_IVOP) |
|
|
overflow = 0; |
|
475 |
|
|
476 |
desired = s->scaled_length; |
/*************************************************************************/ |
477 |
|
/*************************************************************************/ |
478 |
dbytes = desired; |
/*************************************************************************/ |
|
if (s->type == XVID_TYPE_IVOP) |
|
|
dbytes += desired * rc->param.keyframe_boost / 100; |
|
|
dbytes /= rc->movie_curve; |
|
|
|
|
|
/* |
|
|
* Apply user's choosen Payback method. Payback helps bitrate to follow the |
|
|
* scaled curve "paying back" past errors in curve previsions. |
|
|
*/ |
|
|
if (rc->param.payback_method == XVID_PAYBACK_BIAS) { |
|
|
desired = (int)(rc->curve_comp_error / rc->param.bitrate_payback_delay); |
|
|
} else { |
|
|
desired = (int)(rc->curve_comp_error * dbytes / |
|
|
rc->avg_length[s->type-1] / rc->param.bitrate_payback_delay); |
|
|
|
|
|
if (labs(desired) > fabs(rc->curve_comp_error)) |
|
|
desired = (int)rc->curve_comp_error; |
|
|
} |
|
479 |
|
|
480 |
rc->curve_comp_error -= desired; |
/*------------------------------------------------------------------------- |
481 |
|
* Frame bit allocation first part |
482 |
/* XXX: warning */ |
* |
483 |
curve_temp = 0; |
* First steps apply user settings, just like it is done in the theoritical |
484 |
|
* scaled_curve_apply_advanced_parameters |
485 |
|
*-----------------------------------------------------------------------*/ |
486 |
|
|
487 |
if ((rc->param.curve_compression_high + rc->param.curve_compression_low) && s->type != XVID_TYPE_IVOP) { |
/* Set desired to what we are wanting to obtain for this frame */ |
488 |
|
dbytes = (double)s->scaled_length; |
489 |
|
|
490 |
curve_temp = rc->curve_comp_scale; |
/* IFrame user settings*/ |
491 |
if (dbytes > rc->avg_length[s->type-1]) { |
if (s->type == XVID_TYPE_IVOP) { |
492 |
curve_temp *= ((double)dbytes + (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_high / 100.0); |
/* Keyframe boosting -- All keyframes benefit from it */ |
493 |
} else { |
dbytes += dbytes*rc->param.keyframe_boost / 100; |
|
curve_temp *= ((double)dbytes + (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_low / 100.0); |
|
|
} |
|
494 |
|
|
495 |
desired += (int)curve_temp; |
#if 0 /* ToDo: decide how to apply kfthresholding */ |
496 |
rc->curve_comp_error += curve_temp - (int)curve_temp; |
#endif |
497 |
} else { |
} else { |
|
desired += (int)dbytes; |
|
|
rc->curve_comp_error += dbytes - (int)dbytes; |
|
|
} |
|
498 |
|
|
499 |
|
/* P/S/B frames must reserve some bits for iframe boosting */ |
500 |
|
dbytes *= rc->pb_iboost_tax_ratio; |
501 |
|
|
502 |
/* |
/* Apply assymetric curve compression */ |
503 |
* We can't do bigger frames than first pass, this would be stupid as first |
if (rc->param.curve_compression_high || rc->param.curve_compression_low) { |
504 |
* pass is quant=2 and that reaching quant=1 is not worth it. We would lose |
double assymetric_delta; |
505 |
* many bytes and we would not not gain much quality. |
|
506 |
*/ |
/* Compute the assymetric delta, this is computed before applying |
507 |
if (desired > s->length) { |
* the tax, as done in the pre_process function */ |
508 |
rc->curve_comp_error += desired - s->length; |
if (dbytes > rc->avg_length[s->type-1]) |
509 |
desired = s->length; |
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_high / 100.0; |
510 |
} else { |
else |
511 |
if (desired < rc->min_length[s->type-1]) { |
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_low / 100.0; |
512 |
if (s->type == XVID_TYPE_IVOP){ |
|
513 |
rc->curve_comp_error -= rc->min_length[XVID_TYPE_IVOP-1] - desired; |
/* Now we must apply the assymetric tax, else our curve compression |
514 |
} |
* would not give a theoritical target size equal to what it is |
515 |
desired = rc->min_length[s->type-1]; |
* expected */ |
516 |
|
dbytes *= rc->assymetric_tax_ratio; |
517 |
|
|
518 |
|
/* Now we can add the assymetric delta */ |
519 |
|
dbytes += assymetric_delta; |
520 |
} |
} |
521 |
} |
} |
522 |
|
|
523 |
s->desired_length = desired; |
/* That is what we would like to have -- Don't put that chunk after |
524 |
|
* overflow control, otherwise, overflow is counted twice and you obtain |
525 |
|
* half sized bitrate sequences */ |
526 |
|
s->desired_length = (int)dbytes; |
527 |
|
rc->desired_total += dbytes; |
528 |
|
|
529 |
/* |
/*------------------------------------------------------------------------ |
530 |
* if this keyframe is too close to the next, reduce it's byte allotment |
* Frame bit allocation: overflow control part. |
531 |
* XXX: why do we do this after setting the desired length ? |
* |
532 |
*/ |
* Unlike the theoritical scaled_curve_apply_advanced_parameters, here |
533 |
|
* it's real encoding and we need to make sure we don't go so far from |
534 |
if (s->type == XVID_TYPE_IVOP) { |
* what is our ideal scaled curve. |
535 |
int KFdistance = rc->keyframe_locations[rc->KF_idx] - rc->keyframe_locations[rc->KF_idx - 1]; |
*-----------------------------------------------------------------------*/ |
|
|
|
|
if (KFdistance < rc->param.kftreshold) { |
|
536 |
|
|
537 |
KFdistance -= rc->param.min_key_interval; |
/* Compute the overflow we should compensate */ |
538 |
|
if (s->type != XVID_TYPE_IVOP) { |
539 |
|
double frametype_factor; |
540 |
|
double framesize_factor; |
541 |
|
|
542 |
if (KFdistance >= 0) { |
/* Take only the desired part of overflow */ |
543 |
int KF_min_size; |
overflow = rc->overflow; |
544 |
|
|
545 |
KF_min_size = desired * (100 - rc->param.kfreduction) / 100; |
/* Factor that will take care to decrease the overflow applied |
546 |
if (KF_min_size < 1) |
* according to the importance of this frame type in term of |
547 |
KF_min_size = 1; |
* overall size */ |
548 |
|
frametype_factor = rc->count[XVID_TYPE_IVOP-1]*rc->avg_length[XVID_TYPE_IVOP-1]; |
549 |
|
frametype_factor += rc->count[XVID_TYPE_PVOP-1]*rc->avg_length[XVID_TYPE_PVOP-1]; |
550 |
|
frametype_factor += rc->count[XVID_TYPE_BVOP-1]*rc->avg_length[XVID_TYPE_BVOP-1]; |
551 |
|
frametype_factor /= rc->count[s->type-1]*rc->avg_length[s->type-1]; |
552 |
|
frametype_factor = 1/frametype_factor; |
553 |
|
|
554 |
|
/* Factor that will take care not to compensate too much for this frame |
555 |
|
* size */ |
556 |
|
framesize_factor = dbytes; |
557 |
|
framesize_factor /= rc->avg_length[s->type-1]; |
558 |
|
|
559 |
desired = KF_min_size + (desired - KF_min_size) * KFdistance / |
/* Treat only the overflow part concerned by this frame type and size */ |
560 |
(rc->param.kftreshold - rc->param.min_key_interval); |
overflow *= frametype_factor; |
561 |
|
#if 0 |
562 |
|
/* Leave this one alone, as it impacts badly on quality */ |
563 |
|
overflow *= framesize_factor; |
564 |
|
#endif |
565 |
|
|
566 |
if (desired < 1) |
/* Apply the overflow strength imposed by the user */ |
567 |
desired = 1; |
overflow *= (rc->param.overflow_control_strength/100.0f); |
568 |
} |
} else { |
569 |
} |
/* no overflow applied in IFrames because: |
570 |
|
* - their role is important as they're references for P/BFrames. |
571 |
|
* - there aren't much in typical sequences, so if an IFrame overflows too |
572 |
|
* much, this overflow may impact the next IFrame too much and generate |
573 |
|
* a sequence of poor quality frames */ |
574 |
|
overflow = 0; |
575 |
} |
} |
576 |
|
|
577 |
/* |
/* Make sure we are not trying to compensate more overflow than we even have */ |
578 |
* The "sens commun" would force us to use rc->avg_length[s->type-1] but |
if (fabs(overflow) > fabs(rc->overflow)) |
|
* even VFW code uses the pframe average length. Note that this length is |
|
|
* used with desired which represents bframes _and_ pframes length. |
|
|
* |
|
|
* XXX: why are we using the avg pframe length for all frame types ? |
|
|
*/ |
|
|
overflow = (int)((double)overflow * desired / rc->avg_length[XVID_TYPE_PVOP-1]); |
|
|
|
|
|
/* Reign in overflow with huge frames */ |
|
|
if (labs(overflow) > labs(rc->overflow)) |
|
579 |
overflow = rc->overflow; |
overflow = rc->overflow; |
580 |
|
|
581 |
/* Make sure overflow doesn't run away */ |
/* Make sure the overflow doesn't make the frame size to get out of the range |
582 |
if (overflow > desired * rc->param.max_overflow_improvement / 100) { |
* [-max_degradation..+max_improvment] */ |
583 |
desired += (overflow <= desired) ? desired * rc->param.max_overflow_improvement / 100 : |
if (overflow > dbytes*rc->param.max_overflow_improvement / 100) { |
584 |
overflow * rc->param.max_overflow_improvement / 100; |
if(overflow <= dbytes) |
585 |
} else if (overflow < desired * rc->param.max_overflow_degradation / -100){ |
dbytes += dbytes * rc->param.max_overflow_improvement / 100; |
586 |
desired += desired * rc->param.max_overflow_degradation / -100; |
else |
587 |
|
dbytes += overflow * rc->param.max_overflow_improvement / 100; |
588 |
|
} else if (overflow < - dbytes * rc->param.max_overflow_degradation / 100) { |
589 |
|
dbytes -= dbytes * rc->param.max_overflow_degradation / 100; |
590 |
} else { |
} else { |
591 |
desired += overflow; |
dbytes += overflow; |
592 |
} |
} |
593 |
|
|
594 |
/* Make sure we are not higher than desired frame size */ |
/*------------------------------------------------------------------------- |
595 |
if (desired > rc->max_length) { |
* Frame bit allocation last part: |
596 |
|
* |
597 |
|
* Cap frame length so we don't reach neither bigger frame sizes than first |
598 |
|
* pass nor smaller than the allowed minimum. |
599 |
|
*-----------------------------------------------------------------------*/ |
600 |
|
|
601 |
|
if (dbytes > s->length) { |
602 |
|
dbytes = s->length; |
603 |
|
} else if (dbytes < rc->min_length[s->type-1]) { |
604 |
|
dbytes = rc->min_length[s->type-1]; |
605 |
|
} else if (dbytes > rc->max_length) { |
606 |
|
/* ToDo: this condition is always wrong as max_length == maximum frame |
607 |
|
* length of first pass, so the first condition already caps the frame |
608 |
|
* size... */ |
609 |
capped_to_max_framesize = 1; |
capped_to_max_framesize = 1; |
610 |
desired = rc->max_length; |
dbytes = rc->max_length; |
611 |
DPRINTF(XVID_DEBUG_RC,"[%i] Capped to maximum frame size\n", |
DPRINTF(XVID_DEBUG_RC,"[xvid rc] -- frame:%d Capped to maximum frame size\n", |
612 |
data->frame_num); |
data->frame_num); |
613 |
} |
} |
614 |
|
|
615 |
/* Make sure to not scale below the minimum framesize */ |
/*------------------------------------------------------------------------ |
616 |
if (desired < rc->min_length[s->type-1]) { |
* Desired frame length <-> quantizer mapping |
617 |
desired = rc->min_length[s->type-1]; |
*-----------------------------------------------------------------------*/ |
618 |
DPRINTF(XVID_DEBUG_RC,"[%i] Capped to minimum frame size\n", |
|
619 |
data->frame_num); |
#ifdef BQUANT_PRESCALE |
620 |
|
/* For bframes we prescale the quantizer to avoid too high quant scaling */ |
621 |
|
if(s->type == XVID_TYPE_BVOP) { |
622 |
|
|
623 |
|
twopass_stat_t *b_ref = s; |
624 |
|
|
625 |
|
/* Find the reference frame */ |
626 |
|
while(b_ref != &rc->stats[0] && b_ref->type == XVID_TYPE_BVOP) |
627 |
|
b_ref--; |
628 |
|
|
629 |
|
/* Compute the original quant */ |
630 |
|
s->quant = 2*(100*s->quant - data->bquant_offset); |
631 |
|
s->quant += data->bquant_ratio - 1; /* to avoid rounding issues */ |
632 |
|
s->quant = s->quant/data->bquant_ratio - b_ref->quant; |
633 |
} |
} |
634 |
|
#endif |
635 |
|
|
636 |
/* |
/* Don't laugh at this very 'simple' quant<->size relationship, it |
637 |
* Don't laugh at this very 'simple' quant<->filesize relationship, it |
* proves to be acurate enough for our algorithm */ |
638 |
* proves to be acurate enough for our algorithm |
scaled_quant = (double)s->quant*(double)s->length/(double)dbytes; |
639 |
*/ |
|
640 |
scaled_quant = (double)s->quant*(double)s->length/(double)desired; |
#ifdef COMPENSATE_FORMULA |
641 |
|
/* We know xvidcore will apply the bframe formula again, so we compensate |
642 |
|
* it right now to make sure we would not apply it twice */ |
643 |
|
if(s->type == XVID_TYPE_BVOP) { |
644 |
|
|
645 |
|
twopass_stat_t *b_ref = s; |
646 |
|
|
647 |
|
/* Find the reference frame */ |
648 |
|
while(b_ref != &rc->stats[0] && b_ref->type == XVID_TYPE_BVOP) |
649 |
|
b_ref--; |
650 |
|
|
651 |
|
/* Compute the quant it would be if the core did not apply the bframe |
652 |
|
* formula */ |
653 |
|
scaled_quant = 100*scaled_quant - data->bquant_offset; |
654 |
|
scaled_quant += data->bquant_ratio - 1; /* to avoid rouding issues */ |
655 |
|
scaled_quant /= data->bquant_ratio; |
656 |
|
} |
657 |
|
#endif |
658 |
|
|
659 |
/* |
/* Quantizer has been scaled using floating point operations/results, we |
660 |
* Quantizer has been scaled using floating point operations/results, we |
* must cast it to integer */ |
|
* must cast it to integer |
|
|
*/ |
|
661 |
data->quant = (int)scaled_quant; |
data->quant = (int)scaled_quant; |
662 |
|
|
663 |
/* Let's clip the computed quantizer, if needed */ |
/* Let's clip the computed quantizer, if needed */ |
665 |
data->quant = 1; |
data->quant = 1; |
666 |
} else if (data->quant > 31) { |
} else if (data->quant > 31) { |
667 |
data->quant = 31; |
data->quant = 31; |
668 |
} else if (s->type != XVID_TYPE_IVOP) { |
} else { |
669 |
|
|
670 |
/* |
/* The frame quantizer has not been clipped, this appears to be a good |
|
* The frame quantizer has not been clipped, this appears to be a good |
|
671 |
* computed quantizer, do not loose quantizer decimal part that we |
* computed quantizer, do not loose quantizer decimal part that we |
672 |
* accumulate for later reuse when its sum represents a complete unit. |
* accumulate for later reuse when its sum represents a complete |
673 |
*/ |
* unit. */ |
674 |
rc->quant_error[s->type-1][data->quant] += scaled_quant - (double)data->quant; |
rc->quant_error[s->type-1][data->quant] += scaled_quant - (double)data->quant; |
675 |
|
|
676 |
if (rc->quant_error[s->type-1][data->quant] >= 1.0) { |
if (rc->quant_error[s->type-1][data->quant] >= 1.0) { |
680 |
rc->quant_error[s->type-1][data->quant] += 1.0; |
rc->quant_error[s->type-1][data->quant] += 1.0; |
681 |
data->quant--; |
data->quant--; |
682 |
} |
} |
|
|
|
683 |
} |
} |
684 |
|
|
685 |
/* |
/* Now we have a computed quant that is in the right quante range, with a |
|
* Now we have a computed quant that is in the right quante range, with a |
|
686 |
* possible +1 correction due to cumulated error. We can now safely clip |
* possible +1 correction due to cumulated error. We can now safely clip |
687 |
* the quantizer again with user's quant ranges. "Safely" means the Rate |
* the quantizer again with user's quant ranges. "Safely" means the Rate |
688 |
* Control could learn more about this quantizer, this knowledge is useful |
* Control could learn more about this quantizer, this knowledge is useful |
689 |
* for future frames even if it this quantizer won't be really used atm, |
* for future frames even if it this quantizer won't be really used atm, |
690 |
* that's why we don't perform this clipping earlier. |
* that's why we don't perform this clipping earlier. */ |
|
*/ |
|
691 |
if (data->quant < data->min_quant[s->type-1]) { |
if (data->quant < data->min_quant[s->type-1]) { |
692 |
data->quant = data->min_quant[s->type-1]; |
data->quant = data->min_quant[s->type-1]; |
693 |
} else if (data->quant > data->max_quant[s->type-1]) { |
} else if (data->quant > data->max_quant[s->type-1]) { |
694 |
data->quant = data->max_quant[s->type-1]; |
data->quant = data->max_quant[s->type-1]; |
695 |
} |
} |
696 |
|
|
697 |
/* |
/* To avoid big quality jumps from frame to frame, we apply a "security" |
|
* To avoid big quality jumps from frame to frame, we apply a "security" |
|
698 |
* rule that makes |last_quant - new_quant| <= 2. This rule only applies |
* rule that makes |last_quant - new_quant| <= 2. This rule only applies |
699 |
* to predicted frames (P and B) |
* to predicted frames (P and B) */ |
|
*/ |
|
700 |
if (s->type != XVID_TYPE_IVOP && rc->last_quant[s->type-1] && capped_to_max_framesize == 0) { |
if (s->type != XVID_TYPE_IVOP && rc->last_quant[s->type-1] && capped_to_max_framesize == 0) { |
701 |
|
|
702 |
if (data->quant > rc->last_quant[s->type-1] + 2) { |
if (data->quant > rc->last_quant[s->type-1] + 2) { |
703 |
data->quant = rc->last_quant[s->type-1] + 2; |
data->quant = rc->last_quant[s->type-1] + 2; |
704 |
DPRINTF(XVID_DEBUG_RC, |
DPRINTF(XVID_DEBUG_RC, |
705 |
"[%i] p/b-frame quantizer prevented from rising too steeply\n", |
"[xvid rc] -- frame %d p/b-frame quantizer prevented from rising too steeply\n", |
706 |
data->frame_num); |
data->frame_num); |
707 |
} |
} |
708 |
if (data->quant < rc->last_quant[s->type-1] - 2) { |
if (data->quant < rc->last_quant[s->type-1] - 2) { |
709 |
data->quant = rc->last_quant[s->type-1] - 2; |
data->quant = rc->last_quant[s->type-1] - 2; |
710 |
DPRINTF(XVID_DEBUG_RC, |
DPRINTF(XVID_DEBUG_RC, |
711 |
"[%i] p/b-frame quantizer prevented from falling too steeply\n", |
"[xvid rc] -- frame:%d p/b-frame quantizer prevented from falling too steeply\n", |
712 |
data->frame_num); |
data->frame_num); |
713 |
} |
} |
714 |
} |
} |
715 |
|
|
716 |
/* |
/* We don't want to pollute the RC histerisis when our computed quant has |
717 |
* We don't want to pollute the RC history results when our computed quant |
* been computed from a capped frame size */ |
|
* has been computed from a capped frame size |
|
|
*/ |
|
718 |
if (capped_to_max_framesize == 0) |
if (capped_to_max_framesize == 0) |
719 |
rc->last_quant[s->type-1] = data->quant; |
rc->last_quant[s->type-1] = data->quant; |
720 |
|
|
721 |
/* Force frame type */ |
/* Don't forget to force 1st pass frame type ;-) */ |
722 |
data->type = s->type; |
data->type = s->type; |
723 |
|
|
724 |
return 0; |
return 0; |
731 |
rc_2pass2_after(rc_2pass2_t * rc, xvid_plg_data_t * data) |
rc_2pass2_after(rc_2pass2_t * rc, xvid_plg_data_t * data) |
732 |
{ |
{ |
733 |
const char frame_type[4] = { 'i', 'p', 'b', 's'}; |
const char frame_type[4] = { 'i', 'p', 'b', 's'}; |
734 |
stat_t * s = &rc->stats[data->frame_num]; |
twopass_stat_t * s = &rc->stats[data->frame_num]; |
735 |
|
|
736 |
/* Insufficent stats data */ |
/* Insufficent stats data */ |
737 |
if (data->frame_num >= rc->num_frames) |
if (data->frame_num >= rc->num_frames) |
738 |
return 0; |
return 0; |
739 |
|
|
740 |
rc->quant_count[data->quant]++; |
/* Update the quantizer counter */ |
741 |
|
rc->quant_count[s->type-1][data->quant]++; |
742 |
|
|
743 |
|
/* Update the frame type overflow */ |
744 |
if (data->type == XVID_TYPE_IVOP) { |
if (data->type == XVID_TYPE_IVOP) { |
745 |
int kfdiff = (rc->keyframe_locations[rc->KF_idx] - rc->keyframe_locations[rc->KF_idx - 1]); |
int kfdiff = 0; |
746 |
|
|
747 |
|
if(rc->KF_idx != rc->num_frames -1) { |
748 |
|
kfdiff = rc->keyframe_locations[rc->KF_idx+1]; |
749 |
|
kfdiff -= rc->keyframe_locations[rc->KF_idx]; |
750 |
|
} |
751 |
|
|
752 |
|
/* Flush Keyframe overflow accumulator */ |
753 |
rc->overflow += rc->KFoverflow; |
rc->overflow += rc->KFoverflow; |
754 |
|
|
755 |
|
/* Store the frame overflow to the keyframe accumulator */ |
756 |
rc->KFoverflow = s->desired_length - data->length; |
rc->KFoverflow = s->desired_length - data->length; |
757 |
|
|
758 |
if (kfdiff > 1) { /* non-consecutive keyframes */ |
if (kfdiff > 1) { |
759 |
|
/* Non-consecutive keyframes case: |
760 |
|
* We can then divide this total keyframe overflow into equal parts |
761 |
|
* that we will distribute into regular overflow at each frame |
762 |
|
* between the sequence bounded by two IFrames */ |
763 |
rc->KFoverflow_partial = rc->KFoverflow / (kfdiff - 1); |
rc->KFoverflow_partial = rc->KFoverflow / (kfdiff - 1); |
764 |
}else{ /* consecutive keyframes */ |
} else { |
765 |
|
/* Consecutive keyframes case: |
766 |
|
* Flush immediatly the keyframe overflow and reset keyframe |
767 |
|
* overflow */ |
768 |
rc->overflow += rc->KFoverflow; |
rc->overflow += rc->KFoverflow; |
769 |
rc->KFoverflow = 0; |
rc->KFoverflow = 0; |
770 |
rc->KFoverflow_partial = 0; |
rc->KFoverflow_partial = 0; |
771 |
} |
} |
772 |
rc->KF_idx++; |
rc->KF_idx++; |
773 |
} else { |
} else { |
774 |
/* distribute part of the keyframe overflow */ |
/* Accumulate the frame overflow */ |
775 |
rc->overflow += s->desired_length - data->length + rc->KFoverflow_partial; |
rc->overflow += s->desired_length - data->length; |
776 |
|
|
777 |
|
/* Distribute part of the keyframe overflow */ |
778 |
|
rc->overflow += rc->KFoverflow_partial; |
779 |
|
|
780 |
|
/* Don't forget to substract that same amount from the total keyframe |
781 |
|
* overflow */ |
782 |
rc->KFoverflow -= rc->KFoverflow_partial; |
rc->KFoverflow -= rc->KFoverflow_partial; |
783 |
} |
} |
784 |
|
|
785 |
DPRINTF(XVID_DEBUG_RC, "[%i] type:%c quant:%i stats1:%i scaled:%i actual:%i desired:%d overflow:%i\n", |
rc->overflow += (s->error = s->desired_length - data->length); |
786 |
|
rc->real_total += data->length; |
787 |
|
|
788 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- frame:%d type:%c quant:%d stats:%d scaled:%d desired:%d actual:%d error:%d overflow:%.2f\n", |
789 |
data->frame_num, |
data->frame_num, |
790 |
frame_type[data->type-1], |
frame_type[data->type-1], |
791 |
data->quant, |
data->quant, |
792 |
s->length, |
s->length, |
793 |
s->scaled_length, |
s->scaled_length, |
|
data->length, |
|
794 |
s->desired_length, |
s->desired_length, |
795 |
|
s->desired_length - s->error, |
796 |
|
-s->error, |
797 |
rc->overflow); |
rc->overflow); |
798 |
|
|
799 |
return(0); |
return(0); |
803 |
* Helper functions definition |
* Helper functions definition |
804 |
****************************************************************************/ |
****************************************************************************/ |
805 |
|
|
806 |
|
/* Default buffer size for reading lines */ |
807 |
#define BUF_SZ 1024 |
#define BUF_SZ 1024 |
|
#define MAX_COLS 5 |
|
808 |
|
|
809 |
/* open stats file, and count num frames */ |
/* Helper functions for reading/parsing the stats file */ |
810 |
|
static char *skipspaces(char *string); |
811 |
|
static int iscomment(char *string); |
812 |
|
static char *readline(FILE *f); |
813 |
|
|
814 |
|
/* This function counts the number of frame entries in the stats file |
815 |
|
* It also counts the number of I Frames */ |
816 |
static int |
static int |
817 |
det_stats_length(rc_2pass2_t * rc, char * filename) |
statsfile_count_frames(rc_2pass2_t * rc, char * filename) |
818 |
{ |
{ |
819 |
FILE * f; |
FILE * f; |
820 |
int n, ignore; |
char *line; |
821 |
char type; |
int lines; |
822 |
|
|
823 |
rc->num_frames = 0; |
rc->num_frames = 0; |
824 |
rc->num_keyframes = 0; |
rc->num_keyframes = 0; |
825 |
|
|
826 |
if ((f = fopen(filename, "rt")) == NULL) |
if ((f = fopen(filename, "rb")) == NULL) |
827 |
return 0; |
return(-1); |
828 |
|
|
829 |
while((n = fscanf(f, "%c %d %d %d %d %d %d\n", |
lines = 0; |
830 |
&type, &ignore, &ignore, &ignore, &ignore, &ignore, &ignore)) != EOF) { |
while ((line = readline(f)) != NULL) { |
831 |
if (type == 'i') { |
|
832 |
rc->num_frames++; |
char *ptr; |
833 |
|
char type; |
834 |
|
int fields; |
835 |
|
|
836 |
|
lines++; |
837 |
|
|
838 |
|
/* We skip spaces */ |
839 |
|
ptr = skipspaces(line); |
840 |
|
|
841 |
|
/* Skip coment lines or empty lines */ |
842 |
|
if(iscomment(ptr) || *ptr == '\0') { |
843 |
|
free(line); |
844 |
|
continue; |
845 |
|
} |
846 |
|
|
847 |
|
/* Read the stat line from buffer */ |
848 |
|
fields = sscanf(ptr, "%c", &type); |
849 |
|
|
850 |
|
/* Valid stats files have at least 7 fields */ |
851 |
|
if (fields == 1) { |
852 |
|
switch(type) { |
853 |
|
case 'i': |
854 |
|
case 'I': |
855 |
rc->num_keyframes++; |
rc->num_keyframes++; |
856 |
}else if (type == 'p' || type == 'b' || type == 's') { |
case 'p': |
857 |
|
case 'P': |
858 |
|
case 'b': |
859 |
|
case 'B': |
860 |
|
case 's': |
861 |
|
case 'S': |
862 |
rc->num_frames++; |
rc->num_frames++; |
863 |
|
break; |
864 |
|
default: |
865 |
|
DPRINTF(XVID_DEBUG_RC, |
866 |
|
"[xvid rc] -- WARNING: L%d unknown frame type used (%c).\n", |
867 |
|
lines, type); |
868 |
} |
} |
869 |
|
} else { |
870 |
|
DPRINTF(XVID_DEBUG_RC, |
871 |
|
"[xvid rc] -- WARNING: L%d misses some stat fields (%d).\n", |
872 |
|
lines, 7-fields); |
873 |
|
} |
874 |
|
|
875 |
|
/* Free the line buffer */ |
876 |
|
free(line); |
877 |
} |
} |
878 |
|
|
879 |
|
/* We are done with the file */ |
880 |
fclose(f); |
fclose(f); |
881 |
|
|
882 |
return 1; |
return(0); |
883 |
} |
} |
884 |
|
|
885 |
/* open stats file(s) and read into rc->stats array */ |
/* open stats file(s) and read into rc->stats array */ |
|
|
|
886 |
static int |
static int |
887 |
load_stats(rc_2pass2_t *rc, char * filename) |
statsfile_load(rc_2pass2_t *rc, char * filename) |
888 |
{ |
{ |
889 |
FILE * f; |
FILE * f; |
890 |
int i, not_scaled; |
int processed_entries; |
891 |
|
|
892 |
|
/* Opens the file */ |
893 |
|
if ((f = fopen(filename, "rb"))==NULL) |
894 |
|
return(-1); |
895 |
|
|
896 |
if ((f = fopen(filename, "rt"))==NULL) |
processed_entries = 0; |
897 |
return 0; |
while(processed_entries < rc->num_frames) { |
|
|
|
|
i = 0; |
|
|
not_scaled = 0; |
|
|
while(i < rc->num_frames) { |
|
|
stat_t * s = &rc->stats[i]; |
|
|
int n; |
|
898 |
char type; |
char type; |
899 |
|
int fields; |
900 |
|
twopass_stat_t * s = &rc->stats[processed_entries]; |
901 |
|
char *line, *ptr; |
902 |
|
|
903 |
|
/* Read the line from the file */ |
904 |
|
if((line = readline(f)) == NULL) |
905 |
|
break; |
906 |
|
|
907 |
|
/* We skip spaces */ |
908 |
|
ptr = skipspaces(line); |
909 |
|
|
910 |
|
/* Skip comment lines or empty lines */ |
911 |
|
if(iscomment(ptr) || *ptr == '\0') { |
912 |
|
free(line); |
913 |
|
continue; |
914 |
|
} |
915 |
|
|
916 |
|
/* Reset this field that is optional */ |
917 |
s->scaled_length = 0; |
s->scaled_length = 0; |
|
n = fscanf(f, "%c %d %d %d %d %d %d\n", &type, &s->quant, &s->blks[0], &s->blks[1], &s->blks[2], &s->length, &s->scaled_length); |
|
|
if (n == EOF) break; |
|
|
if (n < 7) { |
|
|
not_scaled = 1; |
|
|
} |
|
918 |
|
|
919 |
if (type == 'i') { |
/* Convert the fields */ |
920 |
|
fields = sscanf(ptr, |
921 |
|
"%c %d %d %d %d %d %d %d\n", |
922 |
|
&type, |
923 |
|
&s->quant, |
924 |
|
&s->blks[0], &s->blks[1], &s->blks[2], |
925 |
|
&s->length, &s->invariant /* not really yet */, |
926 |
|
&s->scaled_length); |
927 |
|
|
928 |
|
/* Free line buffer, we don't need it anymore */ |
929 |
|
free(line); |
930 |
|
|
931 |
|
/* Fail silently, this has probably been warned in |
932 |
|
* statsfile_count_frames */ |
933 |
|
if(fields != 7 && fields != 8) |
934 |
|
continue; |
935 |
|
|
936 |
|
/* Convert frame type and compute the invariant length part */ |
937 |
|
switch(type) { |
938 |
|
case 'i': |
939 |
|
case 'I': |
940 |
s->type = XVID_TYPE_IVOP; |
s->type = XVID_TYPE_IVOP; |
941 |
}else if (type == 'p' || type == 's') { |
s->invariant /= INVARIANT_HEADER_PART_IVOP; |
942 |
|
break; |
943 |
|
case 'p': |
944 |
|
case 'P': |
945 |
|
case 's': |
946 |
|
case 'S': |
947 |
s->type = XVID_TYPE_PVOP; |
s->type = XVID_TYPE_PVOP; |
948 |
}else if (type == 'b') { |
s->invariant /= INVARIANT_HEADER_PART_PVOP; |
949 |
|
break; |
950 |
|
case 'b': |
951 |
|
case 'B': |
952 |
s->type = XVID_TYPE_BVOP; |
s->type = XVID_TYPE_BVOP; |
953 |
}else{ /* unknown type */ |
s->invariant /= INVARIANT_HEADER_PART_BVOP; |
954 |
DPRINTF(XVID_DEBUG_RC, "WARNING: unknown stats frame type, assuming pvop\n"); |
break; |
955 |
s->type = XVID_TYPE_PVOP; |
default: |
956 |
|
/* Same as before, fail silently */ |
957 |
|
continue; |
958 |
} |
} |
959 |
|
|
960 |
i++; |
/* Ok it seems it's been processed correctly */ |
961 |
|
processed_entries++; |
962 |
} |
} |
963 |
|
|
964 |
rc->num_frames = i; |
/* Close the file */ |
|
|
|
965 |
fclose(f); |
fclose(f); |
966 |
|
|
967 |
return 1; |
return(0); |
|
} |
|
|
|
|
|
#if 0 |
|
|
static void print_stats(rc_2pass2_t * rc) |
|
|
{ |
|
|
int i; |
|
|
DPRINTF(XVID_DEBUG_RC, "type quant length scaled_length\n"); |
|
|
for (i = 0; i < rc->num_frames; i++) { |
|
|
stat_t * s = &rc->stats[i]; |
|
|
DPRINTF(XVID_DEBUG_RC, "%d %d %d %d\n", s->type, s->quant, s->length, s->scaled_length); |
|
|
} |
|
968 |
} |
} |
|
#endif |
|
969 |
|
|
970 |
/* pre-process the statistics data |
/* pre-process the statistics data |
971 |
- for each type, count, tot_length, min_length, max_length |
* - for each type, count, tot_length, min_length, max_length |
972 |
- set keyframes_locations |
* - set keyframes_locations */ |
|
*/ |
|
|
|
|
973 |
static void |
static void |
974 |
pre_process0(rc_2pass2_t * rc) |
first_pass_stats_prepare_data(rc_2pass2_t * rc) |
975 |
{ |
{ |
976 |
int i,j; |
int i,j; |
977 |
|
|
978 |
/* |
/* *rc fields initialization |
|
* *rc fields initialization |
|
979 |
* NB: INT_MAX and INT_MIN are used in order to be immediately replaced |
* NB: INT_MAX and INT_MIN are used in order to be immediately replaced |
980 |
* with real values of the 1pass |
* with real values of the 1pass */ |
|
*/ |
|
981 |
for (i=0; i<3; i++) { |
for (i=0; i<3; i++) { |
982 |
rc->count[i]=0; |
rc->count[i]=0; |
983 |
rc->tot_length[i] = 0; |
rc->tot_length[i] = 0; |
984 |
|
rc->tot_invariant[i] = 0; |
985 |
rc->min_length[i] = INT_MAX; |
rc->min_length[i] = INT_MAX; |
986 |
} |
} |
987 |
|
|
988 |
rc->max_length = INT_MIN; |
rc->max_length = INT_MIN; |
989 |
|
|
990 |
/* |
/* Loop through all frames and find/compute all the stuff this function |
991 |
* Loop through all frames and find/compute all the stuff this function |
* is supposed to do */ |
|
* is supposed to do |
|
|
*/ |
|
992 |
for (i=j=0; i<rc->num_frames; i++) { |
for (i=j=0; i<rc->num_frames; i++) { |
993 |
stat_t * s = &rc->stats[i]; |
twopass_stat_t * s = &rc->stats[i]; |
994 |
|
|
995 |
rc->count[s->type-1]++; |
rc->count[s->type-1]++; |
996 |
rc->tot_length[s->type-1] += s->length; |
rc->tot_length[s->type-1] += s->length; |
997 |
|
rc->tot_invariant[s->type-1] += s->invariant; |
998 |
|
|
999 |
if (s->length < rc->min_length[s->type-1]) { |
if (s->length < rc->min_length[s->type-1]) { |
1000 |
rc->min_length[s->type-1] = s->length; |
rc->min_length[s->type-1] = s->length; |
1010 |
} |
} |
1011 |
} |
} |
1012 |
|
|
1013 |
/* |
/* NB: |
|
* Nota Bene: |
|
1014 |
* The "per sequence" overflow system considers a natural sequence to be |
* The "per sequence" overflow system considers a natural sequence to be |
1015 |
* formed by all frames between two iframes, so if we want to make sure |
* formed by all frames between two iframes, so if we want to make sure |
1016 |
* the system does not go nuts during last sequence, we force the last |
* the system does not go nuts during last sequence, we force the last |
1017 |
* frame to appear in the keyframe locations array. |
* frame to appear in the keyframe locations array. */ |
|
*/ |
|
1018 |
rc->keyframe_locations[j] = i; |
rc->keyframe_locations[j] = i; |
1019 |
|
|
1020 |
DPRINTF(XVID_DEBUG_RC, "Min 1st pass IFrame length: %d\n", rc->min_length[0]); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Min 1st pass IFrame length: %d\n", rc->min_length[0]); |
1021 |
DPRINTF(XVID_DEBUG_RC, "Min 1st pass PFrame length: %d\n", rc->min_length[1]); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Min 1st pass PFrame length: %d\n", rc->min_length[1]); |
1022 |
DPRINTF(XVID_DEBUG_RC, "Min 1st pass BFrame length: %d\n", rc->min_length[2]); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Min 1st pass BFrame length: %d\n", rc->min_length[2]); |
1023 |
} |
} |
1024 |
|
|
1025 |
/* calculate zone weight "center" */ |
/* calculate zone weight "center" */ |
|
|
|
1026 |
static void |
static void |
1027 |
zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create) |
zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create) |
1028 |
{ |
{ |
1031 |
|
|
1032 |
rc->avg_weight = 0.0; |
rc->avg_weight = 0.0; |
1033 |
rc->tot_quant = 0; |
rc->tot_quant = 0; |
1034 |
|
rc->tot_quant_invariant = 0; |
1035 |
|
|
1036 |
if (create->num_zones == 0) { |
if (create->num_zones == 0) { |
1037 |
for (j = 0; j < rc->num_frames; j++) { |
for (j = 0; j < rc->num_frames; j++) { |
1069 |
rc->stats[j].zone_mode = XVID_ZONE_QUANT; |
rc->stats[j].zone_mode = XVID_ZONE_QUANT; |
1070 |
rc->stats[j].weight = (double)create->zones[i].increment / (double)create->zones[i].base; |
rc->stats[j].weight = (double)create->zones[i].increment / (double)create->zones[i].base; |
1071 |
rc->tot_quant += rc->stats[j].length; |
rc->tot_quant += rc->stats[j].length; |
1072 |
|
rc->tot_quant_invariant += rc->stats[j].invariant; |
1073 |
} |
} |
1074 |
} |
} |
1075 |
} |
} |
1076 |
rc->avg_weight = n>0 ? rc->avg_weight/n : 1.0; |
rc->avg_weight = n>0 ? rc->avg_weight/n : 1.0; |
1077 |
|
|
1078 |
DPRINTF(XVID_DEBUG_RC, "center_weight: %f (for %i frames); fixed_bytes: %i\n", rc->avg_weight, n, rc->tot_quant); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- center_weight:%f (for %d frames) fixed_bytes:%d\n", rc->avg_weight, n, rc->tot_quant); |
1079 |
} |
} |
1080 |
|
|
1081 |
|
|
1082 |
/* scale the curve */ |
/* scale the curve */ |
|
|
|
1083 |
static void |
static void |
1084 |
internal_scale(rc_2pass2_t *rc) |
first_pass_scale_curve_internal(rc_2pass2_t *rc) |
1085 |
{ |
{ |
1086 |
int64_t target = rc->target - rc->tot_quant; |
int64_t target; |
1087 |
int64_t pass1_length = rc->tot_length[0] + rc->tot_length[1] + rc->tot_length[2] - rc->tot_quant; |
int64_t pass1_length; |
1088 |
|
int64_t total_invariant; |
1089 |
double scaler; |
double scaler; |
1090 |
int i, num_MBs; |
int i, num_MBs; |
1091 |
|
|
1092 |
|
/* We only scale texture data ! */ |
1093 |
|
total_invariant = rc->tot_invariant[XVID_TYPE_IVOP-1]; |
1094 |
|
total_invariant += rc->tot_invariant[XVID_TYPE_PVOP-1]; |
1095 |
|
total_invariant += rc->tot_invariant[XVID_TYPE_BVOP-1]; |
1096 |
|
/* don't forget to substract header bytes used in quant zones, otherwise we |
1097 |
|
* counting them twice */ |
1098 |
|
total_invariant -= rc->tot_quant_invariant; |
1099 |
|
|
1100 |
|
/* We remove the bytes used by the fixed quantizer zones during first pass |
1101 |
|
* with the same quants, so we know very precisely how much that |
1102 |
|
* represents */ |
1103 |
|
target = rc->target; |
1104 |
|
target -= rc->tot_quant; |
1105 |
|
|
1106 |
|
/* Do the same for the first pass data */ |
1107 |
|
pass1_length = rc->tot_length[XVID_TYPE_IVOP-1]; |
1108 |
|
pass1_length += rc->tot_length[XVID_TYPE_PVOP-1]; |
1109 |
|
pass1_length += rc->tot_length[XVID_TYPE_BVOP-1]; |
1110 |
|
pass1_length -= rc->tot_quant; |
1111 |
|
|
1112 |
/* Let's compute a linear scaler in order to perform curve scaling */ |
/* Let's compute a linear scaler in order to perform curve scaling */ |
1113 |
scaler = (double)target / (double)pass1_length; |
scaler = (double)(target - total_invariant) / (double)(pass1_length - total_invariant); |
1114 |
|
|
1115 |
if (target <= 0 || pass1_length <= 0 || target >= pass1_length) { |
if ((target - total_invariant) <= 0 || |
1116 |
DPRINTF(XVID_DEBUG_RC, "WARNING: Undersize detected\n"); |
(pass1_length - total_invariant) <= 0 || |
1117 |
|
target >= pass1_length) { |
1118 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- WARNING: Undersize detected before correction\n"); |
1119 |
scaler = 1.0; |
scaler = 1.0; |
1120 |
} |
} |
1121 |
|
|
1122 |
DPRINTF(XVID_DEBUG_RC, |
/* Compute min frame lengths (for each frame type) according to the number |
1123 |
"Before correction: target=%i, tot_length=%i, scaler=%f\n", |
* of MBs. We sum all block type counters of frame 0, this gives us the |
1124 |
(int)target, (int)pass1_length, scaler); |
* number of MBs. |
|
|
|
|
/* |
|
|
* Compute min frame lengths (for each frame type) according to the number |
|
|
* of MBs. We sum all blocks count from frame 0 (should be an IFrame, so |
|
|
* blocks[0] should be enough) to know how many MBs there are. |
|
1125 |
* |
* |
1126 |
* We compare these hardcoded values with observed values in first pass |
* We compare these hardcoded values with observed values in first pass |
1127 |
* (determined in pre_process0).Then we keep the real minimum. |
* (determined in pre_process0).Then we keep the real minimum. */ |
|
*/ |
|
|
num_MBs = rc->stats[0].blks[0] + rc->stats[0].blks[1] + rc->stats[0].blks[2]; |
|
|
|
|
|
if(rc->min_length[0] > ((num_MBs*22) + 240) / 8) |
|
|
rc->min_length[0] = ((num_MBs*22) + 240) / 8; |
|
|
|
|
|
if(rc->min_length[1] > ((num_MBs) + 88) / 8) |
|
|
rc->min_length[1] = ((num_MBs) + 88) / 8; |
|
1128 |
|
|
1129 |
if(rc->min_length[2] > 8) |
/* Number of MBs */ |
1130 |
rc->min_length[2] = 8; |
num_MBs = rc->stats[0].blks[0]; |
1131 |
|
num_MBs += rc->stats[0].blks[1]; |
1132 |
|
num_MBs += rc->stats[0].blks[2]; |
1133 |
|
|
1134 |
|
/* Minimum for I frames */ |
1135 |
|
if(rc->min_length[XVID_TYPE_IVOP-1] > ((num_MBs*22) + 240) / 8) |
1136 |
|
rc->min_length[XVID_TYPE_IVOP-1] = ((num_MBs*22) + 240) / 8; |
1137 |
|
|
1138 |
|
/* Minimum for P/S frames */ |
1139 |
|
if(rc->min_length[XVID_TYPE_PVOP-1] > ((num_MBs) + 88) / 8) |
1140 |
|
rc->min_length[XVID_TYPE_PVOP-1] = ((num_MBs) + 88) / 8; |
1141 |
|
|
1142 |
|
/* Minimum for B frames */ |
1143 |
|
if(rc->min_length[XVID_TYPE_BVOP-1] > 8) |
1144 |
|
rc->min_length[XVID_TYPE_BVOP-1] = 8; |
1145 |
|
|
1146 |
/* |
/* Perform an initial scale pass. |
1147 |
* Perform an initial scale pass. |
* |
1148 |
* If a frame size is scaled underneath our hardcoded minimums, then we |
* If a frame size is scaled underneath our hardcoded minimums, then we |
1149 |
* force the frame size to the minimum, and deduct the original & scaled |
* force the frame size to the minimum, and deduct the original & scaled |
1150 |
* frame length from the original and target total lengths |
* frame length from the original and target total lengths */ |
|
*/ |
|
1151 |
for (i=0; i<rc->num_frames; i++) { |
for (i=0; i<rc->num_frames; i++) { |
1152 |
stat_t * s = &rc->stats[i]; |
twopass_stat_t * s = &rc->stats[i]; |
1153 |
int len; |
int len; |
1154 |
|
|
1155 |
|
/* No need to scale frame length for which a specific quantizer is |
1156 |
|
* specified thanks to zones */ |
1157 |
if (s->zone_mode == XVID_ZONE_QUANT) { |
if (s->zone_mode == XVID_ZONE_QUANT) { |
1158 |
s->scaled_length = s->length; |
s->scaled_length = s->length; |
1159 |
continue; |
continue; |
1160 |
} |
} |
1161 |
|
|
1162 |
/* Compute the scaled length */ |
/* Compute the scaled length -- only non invariant data length is scaled */ |
1163 |
len = (int)((double)s->length * scaler * s->weight / rc->avg_weight); |
len = s->invariant + (int)((double)(s->length-s->invariant) * scaler * s->weight / rc->avg_weight); |
1164 |
|
|
1165 |
/* Compare with the computed minimum */ |
/* Compare with the computed minimum */ |
1166 |
if (len < rc->min_length[s->type-1]) { |
if (len < rc->min_length[s->type-1]) { |
1167 |
/* force frame size to our computed minimum */ |
/* This is a 'forced size' frame, set its frame size to the |
1168 |
|
* computed minimum */ |
1169 |
s->scaled_length = rc->min_length[s->type-1]; |
s->scaled_length = rc->min_length[s->type-1]; |
1170 |
|
|
1171 |
|
/* Remove both scaled and original size from their respective |
1172 |
|
* total counters, as we prepare a second pass for 'regular' |
1173 |
|
* frames */ |
1174 |
target -= s->scaled_length; |
target -= s->scaled_length; |
1175 |
pass1_length -= s->length; |
pass1_length -= s->length; |
1176 |
} else { |
} else { |
1179 |
} |
} |
1180 |
} |
} |
1181 |
|
|
1182 |
/* Correct the scaler for all non forced frames */ |
/* The first pass on data substracted all 'forced size' frames from the |
1183 |
scaler = (double)target / (double)pass1_length; |
* total counters. Now, it's possible to scale the 'regular' frames. */ |
1184 |
|
|
1185 |
|
/* Scaling factor for 'regular' frames */ |
1186 |
|
scaler = (double)(target - total_invariant) / (double)(pass1_length - total_invariant); |
1187 |
|
|
1188 |
/* Detect undersizing */ |
/* Detect undersizing */ |
1189 |
if (target <= 0 || pass1_length <= 0 || target >= pass1_length) { |
if (target <= 0 || pass1_length <= 0 || target >= pass1_length) { |
1190 |
DPRINTF(XVID_DEBUG_RC, "WARNING: Undersize detected\n"); |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- WARNING: Undersize detected after correction\n"); |
1191 |
scaler = 1.0; |
scaler = 1.0; |
1192 |
} |
} |
1193 |
|
|
|
DPRINTF(XVID_DEBUG_RC, |
|
|
"After correction: target=%i, tot_length=%i, scaler=%f\n", |
|
|
(int)target, (int)pass1_length, scaler); |
|
|
|
|
1194 |
/* Do another pass with the new scaler */ |
/* Do another pass with the new scaler */ |
1195 |
for (i=0; i<rc->num_frames; i++) { |
for (i=0; i<rc->num_frames; i++) { |
1196 |
stat_t * s = &rc->stats[i]; |
twopass_stat_t * s = &rc->stats[i]; |
1197 |
|
|
1198 |
/* Ignore frame with forced frame sizes */ |
/* Ignore frame with forced frame sizes */ |
1199 |
if (s->scaled_length == 0) |
if (s->scaled_length == 0) |
1200 |
s->scaled_length = (int)((double)s->length * scaler * s->weight / rc->avg_weight); |
s->scaled_length = s->invariant + (int)((double)(s->length-s->invariant) * scaler * s->weight / rc->avg_weight); |
1201 |
} |
} |
1202 |
|
|
1203 |
|
/* Job done */ |
1204 |
|
return; |
1205 |
} |
} |
1206 |
|
|
1207 |
|
/* Apply all user settings to the scaled curve |
1208 |
|
* This implies: |
1209 |
|
* keyframe boosting |
1210 |
|
* high/low compression */ |
1211 |
static void |
static void |
1212 |
pre_process1(rc_2pass2_t * rc) |
scaled_curve_apply_advanced_parameters(rc_2pass2_t * rc) |
1213 |
{ |
{ |
1214 |
int i; |
int i; |
1215 |
double total1, total2; |
int64_t ivop_boost_total; |
|
uint64_t ivop_boost_total; |
|
1216 |
|
|
1217 |
ivop_boost_total = 0; |
/* Reset the rate controller (per frame type) total byte counters */ |
1218 |
rc->curve_comp_error = 0; |
for (i=0; i<3; i++) rc->tot_scaled_length[i] = 0; |
1219 |
|
|
1220 |
for (i=0; i<3; i++) { |
/* Compute total bytes for each frame type */ |
1221 |
rc->tot_scaled_length[i] = 0; |
for (i=0; i<rc->num_frames;i++) { |
1222 |
|
twopass_stat_t *s = &rc->stats[i]; |
1223 |
|
rc->tot_scaled_length[s->type-1] += s->scaled_length; |
1224 |
} |
} |
1225 |
|
|
1226 |
|
/* First we compute the total amount of bits needed, as being described by |
1227 |
|
* the scaled distribution. During this pass over the complete stats data, |
1228 |
|
* we see how much bits two user settings will get/give from/to p&b frames: |
1229 |
|
* - keyframe boosting |
1230 |
|
* - keyframe distance penalty */ |
1231 |
|
rc->KF_idx = 0; |
1232 |
|
ivop_boost_total = 0; |
1233 |
for (i=0; i<rc->num_frames; i++) { |
for (i=0; i<rc->num_frames; i++) { |
1234 |
stat_t * s = &rc->stats[i]; |
twopass_stat_t * s = &rc->stats[i]; |
|
|
|
|
rc->tot_scaled_length[s->type-1] += s->scaled_length; |
|
1235 |
|
|
1236 |
|
/* Some more work is needed for I frames */ |
1237 |
if (s->type == XVID_TYPE_IVOP) { |
if (s->type == XVID_TYPE_IVOP) { |
1238 |
ivop_boost_total += s->scaled_length * rc->param.keyframe_boost / 100; |
int ivop_boost; |
1239 |
|
|
1240 |
|
/* Accumulate bytes needed for keyframe boosting */ |
1241 |
|
ivop_boost = s->scaled_length*rc->param.keyframe_boost/100; |
1242 |
|
|
1243 |
|
#if 0 /* ToDo: decide how to apply kfthresholding */ |
1244 |
|
#endif |
1245 |
|
/* If the frame size drops under the minimum length, then cap ivop_boost */ |
1246 |
|
if (ivop_boost + s->scaled_length < rc->min_length[XVID_TYPE_IVOP-1]) |
1247 |
|
ivop_boost = rc->min_length[XVID_TYPE_IVOP-1] - s->scaled_length; |
1248 |
|
|
1249 |
|
/* Accumulate the ivop boost */ |
1250 |
|
ivop_boost_total += ivop_boost; |
1251 |
|
|
1252 |
|
/* Don't forget to update the keyframe index */ |
1253 |
|
rc->KF_idx++; |
1254 |
} |
} |
1255 |
} |
} |
1256 |
|
|
1257 |
rc->movie_curve = ((double)(rc->tot_scaled_length[XVID_TYPE_PVOP-1] + rc->tot_scaled_length[XVID_TYPE_BVOP-1] + ivop_boost_total) / |
/* Initialize the IBoost tax ratio for P/S/B frames |
1258 |
(rc->tot_scaled_length[XVID_TYPE_PVOP-1] + rc->tot_scaled_length[XVID_TYPE_BVOP-1])); |
* |
1259 |
|
* This ratio has to be applied to p/b/s frames in order to reserve |
1260 |
|
* additional bits for keyframes (keyframe boosting) or if too much |
1261 |
|
* keyframe distance is applied, bits retrieved from the keyframes. |
1262 |
|
* |
1263 |
|
* ie pb_length *= rc->pb_iboost_tax_ratio; |
1264 |
|
* |
1265 |
|
* gives the ideal length of a p/b frame */ |
1266 |
|
|
1267 |
|
/* Compute the total length of p/b/s frames (temporary storage into |
1268 |
|
* movie_curve) */ |
1269 |
|
rc->pb_iboost_tax_ratio = (double)rc->tot_scaled_length[XVID_TYPE_PVOP-1]; |
1270 |
|
rc->pb_iboost_tax_ratio += (double)rc->tot_scaled_length[XVID_TYPE_BVOP-1]; |
1271 |
|
|
1272 |
|
/* Compute the ratio described above |
1273 |
|
* taxed_total = sum(0, n, tax*scaled_length) |
1274 |
|
* <=> taxed_total = tax.sum(0, n, scaled_length) |
1275 |
|
* <=> tax = taxed_total / original_total */ |
1276 |
|
rc->pb_iboost_tax_ratio = |
1277 |
|
(rc->pb_iboost_tax_ratio - ivop_boost_total) / |
1278 |
|
rc->pb_iboost_tax_ratio; |
1279 |
|
|
1280 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- IFrame boost tax ratio:%.2f\n", |
1281 |
|
rc->pb_iboost_tax_ratio); |
1282 |
|
|
1283 |
|
/* Compute the average size of frames per frame type */ |
1284 |
for(i=0; i<3; i++) { |
for(i=0; i<3; i++) { |
1285 |
if (rc->count[i] == 0 || rc->movie_curve == 0) { |
/* Special case for missing type or weird case */ |
1286 |
|
if (rc->count[i] == 0 || rc->pb_iboost_tax_ratio == 0) { |
1287 |
rc->avg_length[i] = 1; |
rc->avg_length[i] = 1; |
1288 |
}else{ |
}else{ |
1289 |
rc->avg_length[i] = rc->tot_scaled_length[i] / rc->count[i] / rc->movie_curve; |
rc->avg_length[i] = rc->tot_scaled_length[i]; |
1290 |
} |
|
1291 |
|
if (i == (XVID_TYPE_IVOP-1)) { |
1292 |
|
/* I Frames total has to be added the boost total */ |
1293 |
|
rc->avg_length[i] += ivop_boost_total; |
1294 |
|
} else { |
1295 |
|
/* P/B frames has to taxed */ |
1296 |
|
rc->avg_length[i] *= rc->pb_iboost_tax_ratio; |
1297 |
} |
} |
1298 |
|
|
1299 |
/* --- */ |
/* Finally compute the average frame size */ |
1300 |
|
rc->avg_length[i] /= (double)rc->count[i]; |
1301 |
|
} |
1302 |
|
} |
1303 |
|
|
1304 |
total1=total2=0; |
/* Assymetric curve compression */ |
1305 |
|
if (rc->param.curve_compression_high || rc->param.curve_compression_low) { |
1306 |
|
double symetric_total; |
1307 |
|
double assymetric_delta_total; |
1308 |
|
|
1309 |
|
/* Like I frame boosting, assymetric curve compression modifies the total |
1310 |
|
* amount of needed bits, we must compute the ratio so we can prescale |
1311 |
|
lengths */ |
1312 |
|
symetric_total = 0; |
1313 |
|
assymetric_delta_total = 0; |
1314 |
for (i=0; i<rc->num_frames; i++) { |
for (i=0; i<rc->num_frames; i++) { |
1315 |
stat_t * s = &rc->stats[i]; |
double assymetric_delta; |
1316 |
|
double dbytes; |
1317 |
|
twopass_stat_t * s = &rc->stats[i]; |
1318 |
|
|
1319 |
if (s->type != XVID_TYPE_IVOP) { |
/* I Frames are not concerned by assymetric scaling */ |
1320 |
double dbytes,dbytes2; |
if (s->type == XVID_TYPE_IVOP) |
1321 |
|
continue; |
1322 |
|
|
1323 |
|
/* During the real run, we would have to apply the iboost tax */ |
1324 |
|
dbytes = s->scaled_length * rc->pb_iboost_tax_ratio; |
1325 |
|
|
1326 |
dbytes = s->scaled_length / rc->movie_curve; |
/* Update the symmetric curve compression total */ |
1327 |
dbytes2 = 0; /* XXX: warning */ |
symetric_total += dbytes; |
|
total1 += dbytes; |
|
1328 |
|
|
1329 |
if (dbytes > rc->avg_length[s->type-1]) { |
/* Apply assymetric curve compression */ |
1330 |
dbytes2=((double)dbytes + (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_high / 100.0); |
if (dbytes > rc->avg_length[s->type-1]) |
1331 |
|
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * (double)rc->param.curve_compression_high / 100.0f; |
1332 |
|
else |
1333 |
|
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * (double)rc->param.curve_compression_low / 100.0f; |
1334 |
|
|
1335 |
|
/* Cap to the minimum frame size if needed */ |
1336 |
|
if (dbytes + assymetric_delta < rc->min_length[s->type-1]) |
1337 |
|
assymetric_delta = rc->min_length[s->type-1] - dbytes; |
1338 |
|
|
1339 |
|
/* Accumulate after assymetric curve compression */ |
1340 |
|
assymetric_delta_total += assymetric_delta; |
1341 |
|
} |
1342 |
|
|
1343 |
|
/* Compute the tax that all p/b frames have to pay in order to respect the |
1344 |
|
* bit distribution changes that the assymetric compression curve imposes |
1345 |
|
* We want assymetric_total = sum(0, n-1, tax.scaled_length) |
1346 |
|
* ie assymetric_total = ratio.sum(0, n-1, scaled_length) |
1347 |
|
* ratio = assymetric_total / symmetric_total */ |
1348 |
|
rc->assymetric_tax_ratio = ((double)symetric_total - (double)assymetric_delta_total) / (double)symetric_total; |
1349 |
} else { |
} else { |
1350 |
dbytes2 = ((double)dbytes + (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_low / 100.0); |
rc->assymetric_tax_ratio = 1.0f; |
1351 |
} |
} |
1352 |
|
|
1353 |
if (dbytes2 < rc->min_length[s->type-1]) |
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Assymetric tax ratio:%.2f\n", rc->assymetric_tax_ratio); |
|
dbytes2 = rc->min_length[s->type-1]; |
|
1354 |
|
|
1355 |
total2 += dbytes2; |
/* Last bits that need to be reset */ |
1356 |
|
rc->overflow = 0; |
1357 |
|
rc->KFoverflow = 0; |
1358 |
|
rc->KFoverflow_partial = 0; |
1359 |
|
rc->KF_idx = 0; |
1360 |
|
rc->desired_total = 0; |
1361 |
|
rc->real_total = 0; |
1362 |
|
|
1363 |
|
/* Job done */ |
1364 |
|
return; |
1365 |
} |
} |
1366 |
|
|
1367 |
|
/***************************************************************************** |
1368 |
|
* Still more low level stuff (nothing to do with stats treatment) |
1369 |
|
****************************************************************************/ |
1370 |
|
|
1371 |
|
/* This function returns an allocated string containing a complete line read |
1372 |
|
* from the file starting at the current position */ |
1373 |
|
static char * |
1374 |
|
readline(FILE *f) |
1375 |
|
{ |
1376 |
|
char *buffer = NULL; |
1377 |
|
int buffer_size = 0; |
1378 |
|
int pos = 0; |
1379 |
|
|
1380 |
|
do { |
1381 |
|
int c; |
1382 |
|
|
1383 |
|
/* Read a character from the stream */ |
1384 |
|
c = fgetc(f); |
1385 |
|
|
1386 |
|
/* Is that EOF or new line ? */ |
1387 |
|
if(c == EOF || c == '\n') |
1388 |
|
break; |
1389 |
|
|
1390 |
|
/* Do we have to update buffer ? */ |
1391 |
|
if(pos >= buffer_size - 1) { |
1392 |
|
buffer_size += BUF_SZ; |
1393 |
|
buffer = (char*)realloc(buffer, buffer_size); |
1394 |
|
if (buffer == NULL) |
1395 |
|
return(NULL); |
1396 |
} |
} |
1397 |
|
|
1398 |
rc->curve_comp_scale = total1 / total2; |
buffer[pos] = c; |
1399 |
|
pos++; |
1400 |
|
} while(1); |
1401 |
|
|
1402 |
DPRINTF(XVID_DEBUG_RC, "middle frame size for asymmetric curve compression: pframe%d bframe:%d\n", |
/* Read \n or EOF */ |
1403 |
(int)(rc->avg_length[XVID_TYPE_PVOP-1] * rc->curve_comp_scale), |
if (buffer == NULL) { |
1404 |
(int)(rc->avg_length[XVID_TYPE_BVOP-1] * rc->curve_comp_scale)); |
/* EOF, so we reached the end of the file, return NULL */ |
1405 |
|
if(feof(f)) |
1406 |
|
return(NULL); |
1407 |
|
|
1408 |
rc->overflow = 0; |
/* Just an empty line with just a newline, allocate a 1 byte buffer to |
1409 |
rc->KFoverflow = 0; |
* store a zero length string */ |
1410 |
rc->KFoverflow_partial = 0; |
buffer = (char*)malloc(1); |
1411 |
rc->KF_idx = 1; |
if(buffer == NULL) |
1412 |
|
return(NULL); |
1413 |
|
} |
1414 |
|
|
1415 |
|
/* Zero terminated string */ |
1416 |
|
buffer[pos] = '\0'; |
1417 |
|
|
1418 |
|
return(buffer); |
1419 |
|
} |
1420 |
|
|
1421 |
|
/* This function returns a pointer to the first non space char in the given |
1422 |
|
* string */ |
1423 |
|
static char * |
1424 |
|
skipspaces(char *string) |
1425 |
|
{ |
1426 |
|
const char spaces[] = |
1427 |
|
{ |
1428 |
|
' ','\t','\0' |
1429 |
|
}; |
1430 |
|
const char *spacechar = spaces; |
1431 |
|
|
1432 |
|
if (string == NULL) return(NULL); |
1433 |
|
|
1434 |
|
while (*string != '\0') { |
1435 |
|
/* Test against space chars */ |
1436 |
|
while (*spacechar != '\0') { |
1437 |
|
if (*string == *spacechar) { |
1438 |
|
string++; |
1439 |
|
spacechar = spaces; |
1440 |
|
break; |
1441 |
|
} |
1442 |
|
spacechar++; |
1443 |
|
} |
1444 |
|
|
1445 |
|
/* No space char */ |
1446 |
|
if (*spacechar == '\0') return(string); |
1447 |
|
} |
1448 |
|
|
1449 |
|
return(string); |
1450 |
|
} |
1451 |
|
|
1452 |
|
/* This function returns a boolean that tells if the string is only a |
1453 |
|
* comment */ |
1454 |
|
static int |
1455 |
|
iscomment(char *string) |
1456 |
|
{ |
1457 |
|
const char comments[] = |
1458 |
|
{ |
1459 |
|
'#',';', '%', '\0' |
1460 |
|
}; |
1461 |
|
const char *cmtchar = comments; |
1462 |
|
int iscomment = 0; |
1463 |
|
|
1464 |
|
if (string == NULL) return(1); |
1465 |
|
|
1466 |
|
string = skipspaces(string); |
1467 |
|
|
1468 |
|
while(*cmtchar != '\0') { |
1469 |
|
if(*string == *cmtchar) { |
1470 |
|
iscomment = 1; |
1471 |
|
break; |
1472 |
} |
} |
1473 |
|
cmtchar++; |
1474 |
|
} |
1475 |
|
|
1476 |
|
return(iscomment); |
1477 |
|
} |
1478 |
|
|
1479 |
|
#if 0 |
1480 |
|
static void |
1481 |
|
stats_print(rc_2pass2_t * rc) |
1482 |
|
{ |
1483 |
|
int i; |
1484 |
|
const char frame_type[4] = { 'i', 'p', 'b', 's'}; |
1485 |
|
|
1486 |
|
for (i=0; i<rc->num_frames; i++) { |
1487 |
|
twopass_stat_t *s = &rc->stats[i]; |
1488 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- frame:%d type:%c quant:%d stats:%d scaled:%d desired:%d actual:%d overflow(%c):%.2f\n", |
1489 |
|
i, frame_type[s->type-1], -1, s->length, s->scaled_length, |
1490 |
|
s->desired_length, -1, frame_type[s->type-1], -1.0f); |
1491 |
|
} |
1492 |
|
} |
1493 |
|
#endif |