--- plugin_2pass2.c 2003/03/25 10:58:33 1.1 +++ plugin_2pass2.c 2003/05/29 10:36:41 1.1.2.14 @@ -0,0 +1,1007 @@ +/****************************************************************************** + * + * XviD Bit Rate Controller Library + * - VBR 2 pass bitrate controller implementation - + * + * Copyright (C) 2002 Foxer + * 2002 Dirk Knop + * 2002-2003 Edouard Gomez + * 2003 Pete Ross + * + * This curve treatment algorithm is the one originally implemented by Foxer + * and tuned by Dirk Knop for the XviD vfw frontend. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; either version 2 of the License, or + * (at your option) any later version. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA + * + * $Id: plugin_2pass2.c,v 1.1.2.14 2003/05/29 10:36:41 edgomez Exp $ + * + *****************************************************************************/ + +#include +#include +#include + +#include "../xvid.h" +#include "../image/image.h" + +/***************************************************************************** + * Some constants + ****************************************************************************/ + +#define DEFAULT_KEYFRAME_BOOST 0 +#define DEFAULT_PAYBACK_METHOD XVID_PAYBACK_PROP +#define DEFAULT_BITRATE_PAYBACK_DELAY 250 +#define DEFAULT_CURVE_COMPRESSION_HIGH 0 +#define DEFAULT_CURVE_COMPRESSION_LOW 0 +#define DEFAULT_MAX_OVERFLOW_IMPROVEMENT 60 +#define DEFAULT_MAX_OVERFLOW_DEGRADATION 60 + +/* Alt curve settings */ +#define DEFAULT_USE_ALT_CURVE 0 +#define DEFAULT_ALT_CURVE_HIGH_DIST 500 +#define DEFAULT_ALT_CURVE_LOW_DIST 90 +#define DEFAULT_ALT_CURVE_USE_AUTO 1 +#define DEFAULT_ALT_CURVE_AUTO_STR 30 +#define DEFAULT_ALT_CURVE_TYPE XVID_CURVE_LINEAR +#define DEFAULT_ALT_CURVE_MIN_REL_QUAL 50 +#define DEFAULT_ALT_CURVE_USE_AUTO_BONUS_BIAS 1 +#define DEFAULT_ALT_CURVE_BONUS_BIAS 50 + +/* Keyframe settings */ +#define DEFAULT_KFTRESHOLD 10 +#define DEFAULT_KFREDUCTION 20 +#define DEFAULT_MIN_KEY_INTERVAL 1 + +/***************************************************************************** + * Structures + ****************************************************************************/ + +/* Statistics */ +typedef struct { + int type; /* first pass type */ + int quant; /* first pass quant */ + int blks[3]; /* k,m,y blks */ + int length; /* first pass length */ + int scaled_length; /* scaled length */ + int desired_length; /* desired length; calcuated during encoding */ + + int zone_mode; /* XVID_ZONE_xxx */ + double weight; +} stat_t; + +/* Context struct */ +typedef struct +{ + xvid_plugin_2pass2_t param; + + /* constant statistical data */ + int num_frames; + int num_keyframes; + uint64_t target; /* target filesize */ + + int count[3]; /* count of each frame types */ + uint64_t tot_length[3]; /* total length of each frame types */ + 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 */ + + /* zone statistical data */ + double avg_weight; /* average weight */ + int64_t tot_quant; /* total length used by XVID_ZONE_QUANT zones */ + + + double curve_comp_scale; + double movie_curve; + + /* dynamic */ + + int * keyframe_locations; + stat_t * stats; + + double pquant_error[32]; + double bquant_error[32]; + int quant_count[32]; + int last_quant[3]; + + double curve_comp_error; + int overflow; + int KFoverflow; + int KFoverflow_partial; + int KF_idx; + + double fq_error; +} rc_2pass2_t; + + +/***************************************************************************** + * Sub plugin functions prototypes + ****************************************************************************/ + +static int rc_2pass2_create(xvid_plg_create_t * create, rc_2pass2_t ** handle); +static int rc_2pass2_before(rc_2pass2_t * rc, xvid_plg_data_t * data); +static int rc_2pass2_after(rc_2pass2_t * rc, xvid_plg_data_t * data); +static int rc_2pass2_destroy(rc_2pass2_t * rc, xvid_plg_destroy_t * destroy); + +/***************************************************************************** + * Plugin definition + ****************************************************************************/ + +int +xvid_plugin_2pass2(void * handle, int opt, void * param1, void * param2) +{ + switch(opt) { + case XVID_PLG_INFO : + return 0; + + case XVID_PLG_CREATE : + return rc_2pass2_create((xvid_plg_create_t*)param1, param2); + + case XVID_PLG_DESTROY : + return rc_2pass2_destroy((rc_2pass2_t*)handle, (xvid_plg_destroy_t*)param1); + + case XVID_PLG_BEFORE : + return rc_2pass2_before((rc_2pass2_t*)handle, (xvid_plg_data_t*)param1); + + case XVID_PLG_AFTER : + return rc_2pass2_after((rc_2pass2_t*)handle, (xvid_plg_data_t*)param1); + } + + return XVID_ERR_FAIL; +} + +/***************************************************************************** + * Sub plugin functions definitions + ****************************************************************************/ + +/* First a few local helping function prototypes */ +static int det_stats_length(rc_2pass2_t * rc, char * filename); +static int load_stats(rc_2pass2_t *rc, char * filename); +static void zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create); +static void internal_scale(rc_2pass2_t *rc); +static void pre_process0(rc_2pass2_t * rc); +static void pre_process1(rc_2pass2_t * rc); + +/*---------------------------------------------------------------------------- + *--------------------------------------------------------------------------*/ + +static int +rc_2pass2_create(xvid_plg_create_t * create, rc_2pass2_t **handle) +{ + xvid_plugin_2pass2_t * param = (xvid_plugin_2pass2_t *)create->param; + rc_2pass2_t * rc; + int i; + + rc = malloc(sizeof(rc_2pass2_t)); + if (rc == NULL) + return XVID_ERR_MEMORY; + + rc->param = *param; + +#define _INIT(a, b) if((a) <= 0) (a) = (b) + /* Let's set our defaults if needed */ + _INIT(rc->param.keyframe_boost, DEFAULT_KEYFRAME_BOOST); + _INIT(rc->param.payback_method, DEFAULT_PAYBACK_METHOD); + _INIT(rc->param.bitrate_payback_delay, DEFAULT_BITRATE_PAYBACK_DELAY); + _INIT(rc->param.curve_compression_high, DEFAULT_CURVE_COMPRESSION_HIGH); + _INIT(rc->param.curve_compression_low, DEFAULT_CURVE_COMPRESSION_LOW); + _INIT(rc->param.max_overflow_improvement, DEFAULT_MAX_OVERFLOW_IMPROVEMENT); + _INIT(rc->param.max_overflow_degradation, DEFAULT_MAX_OVERFLOW_DEGRADATION); + + /* Keyframe settings */ + _INIT(rc->param.kftreshold, DEFAULT_KFTRESHOLD); + _INIT(rc->param.kfreduction, DEFAULT_KFREDUCTION); + _INIT(rc->param.min_key_interval, DEFAULT_MIN_KEY_INTERVAL); +#undef _INIT + + /* Count frames in the stats file */ + if (!det_stats_length(rc, param->filename)) { + DPRINTF(XVID_DEBUG_RC,"fopen %s failed\n", param->filename); + free(rc); + return XVID_ERR_FAIL; + } + + /* Allocate the stats' memory */ + if ((rc->stats = malloc(rc->num_frames * sizeof(stat_t))) == NULL) { + free(rc); + return XVID_ERR_MEMORY; + } + + /* + * Allocate keyframes location's memory + * PS: see comment in pre_process0 for the +1 location requirement + */ + if ((rc->keyframe_locations = malloc((rc->num_keyframes + 1) * sizeof(int))) == NULL) { + free(rc->stats); + free(rc); + return XVID_ERR_MEMORY; + } + + if (!load_stats(rc, param->filename)) { + DPRINTF(XVID_DEBUG_RC,"fopen %s failed\n", param->filename); + free(rc->keyframe_locations); + free(rc->stats); + free(rc); + return XVID_ERR_FAIL; + } + + /* pre-process our stats */ + + if (rc->num_frames < create->fbase/create->fincr) { + rc->target = rc->param.bitrate / 8; /* one second */ + } else { + rc->target = + ((uint64_t)rc->param.bitrate * (uint64_t)rc->num_frames * (uint64_t)create->fincr) / \ + ((uint64_t)create->fbase * 8); + } + + DPRINTF(XVID_DEBUG_RC, "Number of frames: %d\n", rc->num_frames); + DPRINTF(XVID_DEBUG_RC, "Frame rate: %d/%d\n", create->fbase, create->fincr); + DPRINTF(XVID_DEBUG_RC, "Target bitrate: %ld\n", rc->param.bitrate); + DPRINTF(XVID_DEBUG_RC, "Target filesize: %lld\n", rc->target); + + /* Compensate the mean frame overhead caused by the container */ + rc->target -= rc->num_frames*rc->param.container_frame_overhead; + DPRINTF(XVID_DEBUG_RC, "Container Frame overhead: %d\n", rc->param.container_frame_overhead); + DPRINTF(XVID_DEBUG_RC, "Target filesize (after container compensation): %lld\n", rc->target); + + pre_process0(rc); + + if (rc->param.bitrate) { + zone_process(rc, create); + internal_scale(rc); + }else{ + /* external scaler: ignore zone */ + for (i=0;inum_frames;i++) { + rc->stats[i].zone_mode = XVID_ZONE_WEIGHT; + rc->stats[i].weight = 1.0; + } + rc->avg_weight = 1.0; + rc->tot_quant = 0; + } + pre_process1(rc); + + for (i=0; i<32;i++) { + rc->pquant_error[i] = 0; + rc->bquant_error[i] = 0; + rc->quant_count[i] = 0; + } + + rc->fq_error = 0; + + *handle = rc; + return(0); +} + +/*---------------------------------------------------------------------------- + *--------------------------------------------------------------------------*/ + +static int +rc_2pass2_destroy(rc_2pass2_t * rc, xvid_plg_destroy_t * destroy) +{ + free(rc->keyframe_locations); + free(rc->stats); + free(rc); + return(0); +} + +/*---------------------------------------------------------------------------- + *--------------------------------------------------------------------------*/ + +static int +rc_2pass2_before(rc_2pass2_t * rc, xvid_plg_data_t * data) +{ + stat_t * s = &rc->stats[data->frame_num]; + int overflow; + int desired; + double dbytes; + double curve_temp; + int capped_to_max_framesize = 0; + + /* + * 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. + */ + + /* First case: Another plugin has already set a quantizer */ + if (data->quant > 0) + return(0); + + /* Second case: We are in a Quant zone */ + if (s->zone_mode == XVID_ZONE_QUANT) { + + rc->fq_error += s->weight; + data->quant = (int)rc->fq_error; + rc->fq_error -= data->quant; + + s->desired_length = s->length; + + return(0); + + } + + /* Third case: insufficent stats data */ + if (data->frame_num >= rc->num_frames) + return 0; + + /* + * The last case is the one every normal minded developer should fear to + * maintain in a project :-) + */ + + /* 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; + + desired = s->scaled_length; + + dbytes = desired; + if (s->type == XVID_TYPE_IVOP) + dbytes += desired * rc->param.keyframe_boost / 100; + dbytes /= rc->movie_curve; + + /* + * We are now entering in the hard part of the algo, it was first designed + * to work with i/pframes only streams, so the way it computes things is + * adapted to pframes only. However we can use it if we just take care to + * scale the bframes sizes to pframes sizes using the ratio avg_p/avg_p and + * then before really using values depending on frame sizes, scaling the + * value again with the inverse ratio + */ + if (s->type == XVID_TYPE_BVOP) + dbytes *= rc->avg_length[XVID_TYPE_PVOP-1] / rc->avg_length[XVID_TYPE_BVOP-1]; + + /* + * 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[XVID_TYPE_PVOP-1] / rc->param.bitrate_payback_delay); + + if (labs(desired) > fabs(rc->curve_comp_error)) { + desired = (int)rc->curve_comp_error; + } + } + + rc->curve_comp_error -= desired; + + /* + * Alt curve treatment is not that hard to understand though the formulas + * seem to be huge. Alt treatment is basically a way to soft/harden the + * curve flux applying sine/linear/cosine ratios + */ + + /* XXX: warning */ + curve_temp = 0; + + if ((rc->param.curve_compression_high + rc->param.curve_compression_low) && s->type != XVID_TYPE_IVOP) { + + curve_temp = rc->curve_comp_scale; + if (dbytes > rc->avg_length[XVID_TYPE_PVOP-1]) { + curve_temp *= ((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_high / 100.0); + } else { + curve_temp *= ((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_low / 100.0); + } + + /* + * End of code path for curve_temp, as told earlier, we are now + * obliged to scale the value to a bframe one using the inverse + * ratio applied earlier + */ + if (s->type == XVID_TYPE_BVOP) + curve_temp *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; + + desired += (int)curve_temp; + rc->curve_comp_error += curve_temp - (int)curve_temp; + } else { + /* + * End of code path for dbytes, as told earlier, we are now + * obliged to scale the value to a bframe one using the inverse + * ratio applied earlier + */ + if (s->type == XVID_TYPE_BVOP) + dbytes *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; + + desired += (int)dbytes; + rc->curve_comp_error += dbytes - (int)dbytes; + } + + + /* + * We can't do bigger frames than first pass, this would be stupid as first + * pass is quant=2 and that reaching quant=1 is not worth it. We would lose + * many bytes and we would not not gain much quality. + */ + if (desired > s->length) { + rc->curve_comp_error += desired - s->length; + desired = s->length; + } else { + if (desired < rc->min_length[s->type-1]) { + if (s->type == XVID_TYPE_IVOP){ + rc->curve_comp_error -= rc->min_length[XVID_TYPE_IVOP-1] - desired; + } + desired = rc->min_length[s->type-1]; + } + } + + s->desired_length = desired; + + + /* if this keyframe is too close to the next, reduce it's byte allotment + XXX: why do we do this after setting the desired length */ + + if (s->type == XVID_TYPE_IVOP) { + int KFdistance = rc->keyframe_locations[rc->KF_idx] - rc->keyframe_locations[rc->KF_idx - 1]; + + if (KFdistance < rc->param.kftreshold) { + + KFdistance -= rc->param.min_key_interval; + + if (KFdistance >= 0) { + int KF_min_size; + + KF_min_size = desired * (100 - rc->param.kfreduction) / 100; + if (KF_min_size < 1) + KF_min_size = 1; + + desired = KF_min_size + (desired - KF_min_size) * KFdistance / + (rc->param.kftreshold - rc->param.min_key_interval); + + if (desired < 1) + desired = 1; + } + } + } + + overflow = (int)((double)overflow * desired / rc->avg_length[XVID_TYPE_PVOP-1]); + + /* Reign in overflow with huge frames */ + if (labs(overflow) > labs(rc->overflow)) + overflow = rc->overflow; + + /* Make sure overflow doesn't run away */ + if (overflow > desired * rc->param.max_overflow_improvement / 100) { + desired += (overflow <= desired) ? desired * rc->param.max_overflow_improvement / 100 : + overflow * rc->param.max_overflow_improvement / 100; + } else if (overflow < desired * rc->param.max_overflow_degradation / -100){ + desired += desired * rc->param.max_overflow_degradation / -100; + } else { + desired += overflow; + } + + /* Make sure we are not higher than desired frame size */ + if (desired > rc->max_length) { + capped_to_max_framesize = 1; + desired = rc->max_length; + DPRINTF(XVID_DEBUG_RC,"[%i] Capped to maximum frame size\n", + data->frame_num); + } + + /* Make sure to not scale below the minimum framesize */ + if (desired < rc->min_length[s->type-1]) { + desired = rc->min_length[s->type-1]; + DPRINTF(XVID_DEBUG_RC,"[%i] Capped to minimum frame size\n", + data->frame_num); + } + + /* + * Don't laugh at this very 'simple' quant<->filesize relationship, it + * proves to be acurate enough for our algorithm + */ + data->quant = s->quant*s->length/desired; + + /* Let's clip the computed quantizer, if needed */ + if (data->quant < 1) { + data->quant = 1; + } else if (data->quant > 31) { + data->quant = 31; + } else if (s->type != XVID_TYPE_IVOP) { + + /* + * The frame quantizer has not been clipped, this appear to be a good + * computed quantizer, however past frames give us some info about how + * this quantizer performs against the algo prevision. Let's use this + * prevision to increase the quantizer when we observe a too big + * accumulated error + */ + if (s->type == XVID_TYPE_BVOP) { + rc->bquant_error[data->quant] += ((double)(s->quant * s->length) / desired) - data->quant; + + if (rc->bquant_error[data->quant] >= 1.0) { + rc->bquant_error[data->quant] -= 1.0; + data->quant++; + } + } else { + rc->pquant_error[data->quant] += ((double)(s->quant * s->length) / desired) - data->quant; + + if (rc->pquant_error[data->quant] >= 1.0) { + rc->pquant_error[data->quant] -= 1.0; + data->quant++; + } + } + } + + /* + * Now we have a computed quant that is in the right quante range, with a + * possible +1 correction due to cumulated error. We can now safely clip + * the quantizer again with user's quant ranges. "Safely" means the Rate + * Control could learn more about this quantizer, this knowledge is useful + * for future frames even if it this quantizer won't be really used atm, + * that's why we don't perform this clipping earlier. + */ + if (data->quant < data->min_quant[s->type-1]) { + data->quant = data->min_quant[s->type-1]; + } else if (data->quant > data->max_quant[s->type-1]) { + data->quant = data->max_quant[s->type-1]; + } + + /* + * To avoid big quality jumps from frame to frame, we apply a "security" + * rule that makes |last_quant - new_quant| <= 2. This rule only applies + * to predicted frames (P and B) + */ + if (s->type != XVID_TYPE_IVOP && rc->last_quant[s->type-1] && capped_to_max_framesize == 0) { + + if (data->quant > rc->last_quant[s->type-1] + 2) { + data->quant = rc->last_quant[s->type-1] + 2; + DPRINTF(XVID_DEBUG_RC, + "[%i] p/b-frame quantizer prevented from rising too steeply\n", + data->frame_num); + } + if (data->quant < rc->last_quant[s->type-1] - 2) { + data->quant = rc->last_quant[s->type-1] - 2; + DPRINTF(XVID_DEBUG_RC, + "[%i] p/b-frame quantizer prevented from falling too steeply\n", + data->frame_num); + } + } + + /* + * We don't want to pollute the RC history results when our computed quant + * has been computed from a capped frame size + */ + if (capped_to_max_framesize == 0) + rc->last_quant[s->type-1] = data->quant; + + return 0; +} + +/*---------------------------------------------------------------------------- + *--------------------------------------------------------------------------*/ + +static int +rc_2pass2_after(rc_2pass2_t * rc, xvid_plg_data_t * data) +{ + const char frame_type[4] = { 'i', 'p', 'b', 's'}; + stat_t * s = &rc->stats[data->frame_num]; + + /* Insufficent stats data */ + if (data->frame_num >= rc->num_frames) + return 0; + + rc->quant_count[data->quant]++; + + if (data->type == XVID_TYPE_IVOP) { + int kfdiff = (rc->keyframe_locations[rc->KF_idx] - rc->keyframe_locations[rc->KF_idx - 1]); + + rc->overflow += rc->KFoverflow; + rc->KFoverflow = s->desired_length - data->length; + + if (kfdiff > 1) { // non-consecutive keyframes + rc->KFoverflow_partial = rc->KFoverflow / (kfdiff - 1); + }else{ // consecutive keyframes + rc->overflow += rc->KFoverflow; + rc->KFoverflow = 0; + rc->KFoverflow_partial = 0; + } + rc->KF_idx++; + } else { + // distribute part of the keyframe overflow + rc->overflow += s->desired_length - data->length + rc->KFoverflow_partial; + rc->KFoverflow -= rc->KFoverflow_partial; + } + + DPRINTF(XVID_DEBUG_RC, "[%i] type:%c quant:%i stats1:%i scaled:%i actual:%i overflow:%i\n", + data->frame_num, + frame_type[data->type-1], + data->quant, + s->length, + s->scaled_length, + data->length, + rc->overflow); + + return(0); +} + +/***************************************************************************** + * Helper functions definition + ****************************************************************************/ + +#define BUF_SZ 1024 +#define MAX_COLS 5 + +/* open stats file, and count num frames */ +static int +det_stats_length(rc_2pass2_t * rc, char * filename) +{ + FILE * f; + int n, ignore; + char type; + + rc->num_frames = 0; + rc->num_keyframes = 0; + + if ((f = fopen(filename, "rt")) == NULL) + return 0; + + while((n = fscanf(f, "%c %d %d %d %d %d %d\n", + &type, &ignore, &ignore, &ignore, &ignore, &ignore, &ignore)) != EOF) { + if (type == 'i') { + rc->num_frames++; + rc->num_keyframes++; + }else if (type == 'p' || type == 'b' || type == 's') { + rc->num_frames++; + } + } + + fclose(f); + + return 1; +} + +/* open stats file(s) and read into rc->stats array */ + +static int +load_stats(rc_2pass2_t *rc, char * filename) +{ + FILE * f; + int i, not_scaled; + + + if ((f = fopen(filename, "rt"))==NULL) + return 0; + + i = 0; + not_scaled = 0; + while(i < rc->num_frames) { + stat_t * s = &rc->stats[i]; + int n; + char type; + + 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; + } + + if (type == 'i') { + s->type = XVID_TYPE_IVOP; + }else if (type == 'p' || type == 's') { + s->type = XVID_TYPE_PVOP; + }else if (type == 'b') { + s->type = XVID_TYPE_BVOP; + }else{ /* unknown type */ + DPRINTF(XVID_DEBUG_RC, "unknown stats frame type; assuming pvop\n"); + s->type = XVID_TYPE_PVOP; + } + + i++; + } + + rc->num_frames = i; + + fclose(f); + + return 1; +} + +#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); + } +} +#endif + +/* pre-process the statistics data + - for each type, count, tot_length, min_length, max_length + - set keyframes_locations +*/ + +static void +pre_process0(rc_2pass2_t * rc) +{ + int i,j; + + for (i=0; i<3; i++) { + rc->count[i]=0; + rc->tot_length[i] = 0; + rc->last_quant[i] = 0; + rc->min_length[i] = INT_MAX; + } + + rc->max_length = INT_MIN; + + for (i=j=0; inum_frames; i++) { + stat_t * s = &rc->stats[i]; + + rc->count[s->type-1]++; + rc->tot_length[s->type-1] += s->length; + + if (s->length < rc->min_length[s->type-1]) { + rc->min_length[s->type-1] = s->length; + } + + if (s->length > rc->max_length) { + rc->max_length = s->length; + } + + if (s->type == XVID_TYPE_IVOP) { + rc->keyframe_locations[j] = i; + j++; + } + } + + /* + * Nota Bene: + * The "per sequence" overflow system considers a natural sequence to be + * formed by all frames between two iframes, so if we want to make sure + * the system does not go nuts during last sequence, we force the last + * frame to appear in the keyframe locations array. + */ + rc->keyframe_locations[j] = i; + + DPRINTF(XVID_DEBUG_RC, "Min 1st pass IFrame length: %d\n", rc->min_length[0]); + DPRINTF(XVID_DEBUG_RC, "Min 1st pass PFrame length: %d\n", rc->min_length[1]); + DPRINTF(XVID_DEBUG_RC, "Min 1st pass BFrame length: %d\n", rc->min_length[2]); +} + +/* calculate zone weight "center" */ + +static void +zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create) +{ + int i,j; + int n = 0; + + rc->avg_weight = 0.0; + rc->tot_quant = 0; + + + if (create->num_zones == 0) { + for (j = 0; j < rc->num_frames; j++) { + rc->stats[j].zone_mode = XVID_ZONE_WEIGHT; + rc->stats[j].weight = 1.0; + } + rc->avg_weight += rc->num_frames * 1.0; + n += rc->num_frames; + } + + + for(i=0; i < create->num_zones; i++) { + + int next = (i+1num_zones) ? create->zones[i+1].frame : rc->num_frames; + + if (i==0 && create->zones[i].frame > 0) { + for (j = 0; j < create->zones[i].frame && j < rc->num_frames; j++) { + rc->stats[j].zone_mode = XVID_ZONE_WEIGHT; + rc->stats[j].weight = 1.0; + } + rc->avg_weight += create->zones[i].frame * 1.0; + n += create->zones[i].frame; + } + + if (create->zones[i].mode == XVID_ZONE_WEIGHT) { + for (j = create->zones[i].frame; j < next && j < rc->num_frames; j++ ) { + rc->stats[j].zone_mode = XVID_ZONE_WEIGHT; + rc->stats[j].weight = (double)create->zones[i].increment / (double)create->zones[i].base; + } + next -= create->zones[i].frame; + rc->avg_weight += (double)(next * create->zones[i].increment) / (double)create->zones[i].base; + n += next; + }else{ // XVID_ZONE_QUANT + for (j = create->zones[i].frame; j < next && j < rc->num_frames; j++ ) { + rc->stats[j].zone_mode = XVID_ZONE_QUANT; + rc->stats[j].weight = (double)create->zones[i].increment / (double)create->zones[i].base; + rc->tot_quant += rc->stats[j].length; + } + } + } + rc->avg_weight = n>0 ? rc->avg_weight/n : 1.0; + + DPRINTF(XVID_DEBUG_RC, "center_weight: %f (for %i frames); fixed_bytes: %i\n", rc->avg_weight, n, rc->tot_quant); +} + + +/* scale the curve */ + +static void +internal_scale(rc_2pass2_t *rc) +{ + int64_t target = rc->target - rc->tot_quant; + int64_t pass1_length = rc->tot_length[0] + rc->tot_length[1] + rc->tot_length[2] - rc->tot_quant; + double scaler; + int i, num_MBs; + int min_size[3]; + + /* Let's compute a linear scaler in order to perform curve scaling */ + scaler = (double)target / (double)pass1_length; + + if (target <= 0 || pass1_length <= 0 || target >= pass1_length) { + DPRINTF(XVID_DEBUG_RC, "WARNING: Undersize detected\n"); + scaler = 1.0; + } + + DPRINTF(XVID_DEBUG_RC, + "Before correction: target=%i, tot_length=%i, scaler=%f\n", + (int)target, (int)pass1_length, scaler); + + /* + * 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. + */ + num_MBs = rc->stats[0].blks[0] + rc->stats[0].blks[1] + rc->stats[0].blks[2]; + min_size[0] = ((num_MBs*22) + 240) / 8; + min_size[1] = ((num_MBs) + 88) / 8; + min_size[2] = 8; + + /* + * Perform an initial scale pass. + * If a frame size is scaled underneath our hardcoded minimums, then we + * force the frame size to the minimum, and deduct the original & scaled + * frame length from the original and target total lengths + */ + for (i=0; inum_frames; i++) { + stat_t * s = &rc->stats[i]; + int len; + + if (s->zone_mode == XVID_ZONE_QUANT) { + s->scaled_length = s->length; + continue; + } + + /* Compute teh scaled length */ + len = (int)((double)s->length * scaler * s->weight / rc->avg_weight); + + /* Compare with the computed minimum */ + if (len < min_size[s->type-1]) { + /* force frame size to our computed minimum */ + s->scaled_length = min_size[s->type-1]; + target -= s->scaled_length; + pass1_length -= s->length; + } else { + /* Do nothing for now, we'll scale this later */ + s->scaled_length = 0; + } + } + + /* Correct the scaler for all non forced frames */ + scaler = (double)target / (double)pass1_length; + + /* Detect undersizing */ + if (target <= 0 || pass1_length <= 0 || target >= pass1_length) { + DPRINTF(XVID_DEBUG_RC, "WARNING: Undersize detected\n"); + scaler = 1.0; + } + + DPRINTF(XVID_DEBUG_RC, + "After correction: target=%i, tot_length=%i, scaler=%f\n", + (int)target, (int)pass1_length, scaler); + + /* Do another pass with the new scaler */ + for (i=0; inum_frames; i++) { + stat_t * s = &rc->stats[i]; + + /* Ignore frame with forced frame sizes */ + if (s->scaled_length == 0) + s->scaled_length = (int)((double)s->length * scaler * s->weight / rc->avg_weight); + } + +} + +static void +pre_process1(rc_2pass2_t * rc) +{ + int i; + double total1, total2; + uint64_t ivop_boost_total; + + ivop_boost_total = 0; + rc->curve_comp_error = 0; + + for (i=0; i<3; i++) { + rc->tot_scaled_length[i] = 0; + } + + for (i=0; inum_frames; i++) { + stat_t * s = &rc->stats[i]; + + rc->tot_scaled_length[s->type-1] += s->scaled_length; + + if (s->type == XVID_TYPE_IVOP) { + ivop_boost_total += s->scaled_length * rc->param.keyframe_boost / 100; + } + } + + rc->movie_curve = ((double)(rc->tot_scaled_length[XVID_TYPE_PVOP-1] + rc->tot_scaled_length[XVID_TYPE_BVOP-1] + ivop_boost_total) / + (rc->tot_scaled_length[XVID_TYPE_PVOP-1] + rc->tot_scaled_length[XVID_TYPE_BVOP-1])); + + for(i=0; i<3; i++) { + if (rc->count[i] == 0 || rc->movie_curve == 0) { + rc->avg_length[i] = 1; + }else{ + rc->avg_length[i] = rc->tot_scaled_length[i] / rc->count[i] / rc->movie_curve; + } + } + + /* --- */ + + total1=total2=0; + + for (i=0; inum_frames; i++) { + stat_t * s = &rc->stats[i]; + + if (s->type != XVID_TYPE_IVOP) { + double dbytes,dbytes2; + + dbytes = s->scaled_length / rc->movie_curve; + dbytes2 = 0; /* XXX: warning */ + total1 += dbytes; + if (s->type == XVID_TYPE_BVOP) + dbytes *= rc->avg_length[XVID_TYPE_PVOP-1] / rc->avg_length[XVID_TYPE_BVOP-1]; + + if (dbytes > rc->avg_length[XVID_TYPE_PVOP-1]) { + dbytes2=((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_high / 100.0); + } else { + dbytes2 = ((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_low / 100.0); + } + + if (s->type == XVID_TYPE_BVOP) { + dbytes2 *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; + if (dbytes2 < rc->min_length[XVID_TYPE_BVOP-1]) + dbytes2 = rc->min_length[XVID_TYPE_BVOP-1]; + }else{ + if (dbytes2 < rc->min_length[XVID_TYPE_PVOP-1]) + dbytes2 = rc->min_length[XVID_TYPE_PVOP-1]; + } + total2 += dbytes2; + } + } + + rc->curve_comp_scale = total1 / total2; + + DPRINTF(XVID_DEBUG_RC, "middle frame size for asymmetric curve compression: %i\n", + (int)(rc->avg_length[XVID_TYPE_PVOP-1] * rc->curve_comp_scale)); + + rc->overflow = 0; + rc->KFoverflow = 0; + rc->KFoverflow_partial = 0; + rc->KF_idx = 1; +}