| 1 |
/****************************************************************************** |
/****************************************************************************** |
| 2 |
* |
* |
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* XviD Bit Rate Controller Library |
* XviD Bit Rate Controller Library |
| 4 |
* - VBR 2 pass bitrate controler implementation - |
* - VBR 2 pass bitrate controller implementation - |
| 5 |
* |
* |
| 6 |
* Copyright (C) 2002 Edouard Gomez <ed.gomez@wanadoo.fr> |
* Copyright (C) 2002 Foxer <email?> |
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* 2002 Dirk Knop <dknop@gwdg.de> |
| 8 |
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* 2002-2003 Edouard Gomez <ed.gomez@free.fr> |
| 9 |
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* 2003 Pete Ross <pross@xvid.org> |
| 10 |
* |
* |
| 11 |
* The curve treatment algorithm is the one implemented by Foxer <email?> and |
* This curve treatment algorithm is the one originally implemented by Foxer |
| 12 |
* Dirk Knop <dknop@gwdg.de> for the XviD vfw dynamic library. |
* and tuned by Dirk Knop for the XviD vfw frontend. |
| 13 |
* |
* |
| 14 |
* This program is free software; you can redistribute it and/or modify |
* This program is free software; you can redistribute it and/or modify |
| 15 |
* it under the terms of the GNU General Public License as published by |
* it under the terms of the GNU General Public License as published by |
| 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 1.1.2.3 2003-05-12 12:33:16 suxen_drol Exp $ |
* $Id: plugin_2pass2.c,v 1.1.2.38 2004-05-09 14:00:35 chl Exp $ |
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* |
* |
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*****************************************************************************/ |
*****************************************************************************/ |
| 31 |
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#define BQUANT_PRESCALE |
| 33 |
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#undef COMPENSATE_FORMULA |
| 34 |
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| 35 |
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/* forces second pass not to be bigger than first */ |
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#undef PASS_SMALLER |
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/* automtically alters overflow controls (strength and improvement/degradation) |
| 39 |
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to fight most common problems without user's knowladge */ |
| 40 |
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#define SMART_OVERFLOW_SETTING |
| 41 |
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| 42 |
#include <stdio.h> |
#include <stdio.h> |
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#include <math.h> |
#include <math.h> |
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#include <limits.h> |
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#define RAD2DEG 57.295779513082320876798154814105 |
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#define DEG2RAD 0.017453292519943295769236907684886 |
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#include "../xvid.h" |
#include "../xvid.h" |
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#include "../image/image.h" |
#include "../image/image.h" |
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/***************************************************************************** |
| 50 |
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* Some default settings |
| 51 |
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****************************************************************************/ |
| 52 |
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#define DEFAULT_KEYFRAME_BOOST 0 |
| 54 |
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#define DEFAULT_OVERFLOW_CONTROL_STRENGTH 10 |
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#define DEFAULT_CURVE_COMPRESSION_HIGH 0 |
| 56 |
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#define DEFAULT_CURVE_COMPRESSION_LOW 0 |
| 57 |
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#define DEFAULT_MAX_OVERFLOW_IMPROVEMENT 10 |
| 58 |
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#define DEFAULT_MAX_OVERFLOW_DEGRADATION 10 |
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/* Keyframe settings */ |
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#define DEFAULT_KFREDUCTION 20 |
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#define DEFAULT_KFTHRESHOLD 1 |
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/***************************************************************************** |
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* Some default constants (can be tuned) |
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****************************************************************************/ |
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/* Specify the invariant part of the headers bits (header+MV) |
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* as hlength/cst */ |
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#define INVARIANT_HEADER_PART_IVOP 1 /* factor 1.0f */ |
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#define INVARIANT_HEADER_PART_PVOP 2 /* factor 0.5f */ |
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#define INVARIANT_HEADER_PART_BVOP 8 /* factor 0.125f */ |
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/***************************************************************************** |
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* Structures |
| 76 |
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****************************************************************************/ |
| 77 |
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/* Statistics */ |
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typedef struct { |
typedef struct { |
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int type; /* first pass type */ |
int type; /* first pass type */ |
| 81 |
int quant; /* first pass quant */ |
int quant; /* first pass quant */ |
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int blks[3]; /* k,m,y blks */ |
int blks[3]; /* k,m,y blks */ |
| 83 |
int length; /* first pass length */ |
int length; /* first pass length */ |
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int invariant; /* what we assume as being invariant between the two passes, it's a sub part of header + MV bits */ |
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int scaled_length; /* scaled length */ |
int scaled_length; /* scaled length */ |
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int desired_length; |
int desired_length; /* desired length; calculated during encoding */ |
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} stat_t; |
int error; |
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int zone_mode; /* XVID_ZONE_xxx */ |
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double weight; |
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} twopass_stat_t; |
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/* Context struct */ |
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/* context struct */ |
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typedef struct |
typedef struct |
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{ |
{ |
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xvid_plugin_2pass2_t param; |
xvid_plugin_2pass2_t param; |
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/* constant statistical data */ |
/*---------------------------------- |
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* constant statistical data |
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*--------------------------------*/ |
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/* Number of frames of the sequence */ |
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int num_frames; |
int num_frames; |
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/* Number of Intra frames of the sequence */ |
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int num_keyframes; |
int num_keyframes; |
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uint64_t target; /* target bitrate */ |
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int count[3]; /* count of each frame types */ |
/* Target filesize to reach */ |
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uint64_t tot_length[3]; /* total length of each frame types */ |
uint64_t target; |
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double avg_length[3]; /* avg */ |
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int min_length[3]; /* min frame length of each frame types */ |
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uint64_t tot_scaled_length[3]; /* total scaled length of each frame type */ |
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int max_length; /* max frame size */ |
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double curve_comp_scale; |
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double movie_curve; |
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double alt_curve_low; |
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double alt_curve_high; |
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double alt_curve_low_diff; |
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double alt_curve_high_diff; |
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double alt_curve_curve_bias_bonus; |
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double alt_curve_mid_qual; |
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double alt_curve_qual_dev; |
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| 111 |
/* dynamic */ |
/* Count of each frame types */ |
| 112 |
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int count[3]; |
| 113 |
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/* Total length of each frame types (1st pass) */ |
| 115 |
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uint64_t tot_length[3]; |
| 116 |
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uint64_t tot_invariant[3]; |
| 117 |
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| 118 |
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/* Average length of each frame types (used first for 1st pass data and |
| 119 |
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* then for scaled averages */ |
| 120 |
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double avg_length[3]; |
| 121 |
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| 122 |
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/* Minimum frame length allowed for each frame type */ |
| 123 |
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int min_length[3]; |
| 124 |
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| 125 |
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/* Total bytes per frame type once the curve has been scaled |
| 126 |
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* NB: advanced parameters do not change this value. This field |
| 127 |
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* represents the total scaled w/o any advanced settings */ |
| 128 |
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uint64_t tot_scaled_length[3]; |
| 129 |
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| 130 |
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/* Maximum observed frame size observed during the first pass, the RC |
| 131 |
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* will try tp force all frame sizes in the second pass to be under that |
| 132 |
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* limit */ |
| 133 |
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int max_length; |
| 134 |
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| 135 |
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/*---------------------------------- |
| 136 |
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* Zones statistical data |
| 137 |
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*--------------------------------*/ |
| 138 |
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| 139 |
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/* Total length used by XVID_ZONE_QUANT zones */ |
| 140 |
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uint64_t tot_quant; |
| 141 |
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uint64_t tot_quant_invariant; |
| 142 |
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| 143 |
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/* Holds the total amount of frame bytes, zone weighted (only scalable |
| 144 |
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* part of frame bytes) */ |
| 145 |
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uint64_t tot_weighted; |
| 146 |
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| 147 |
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/*---------------------------------- |
| 148 |
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* Advanced settings helper ratios |
| 149 |
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*--------------------------------*/ |
| 150 |
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| 151 |
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/* This the ratio that has to be applied to all p/b frames in order |
| 152 |
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* to reserve/retrieve bits for/from keyframe boosting and consecutive |
| 153 |
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* keyframe penalty */ |
| 154 |
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double pb_iboost_tax_ratio; |
| 155 |
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| 156 |
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/* This the ratio to apply to all b/p frames in order to respect the |
| 157 |
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* assymetric curve compression while respecting a target filesize |
| 158 |
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* NB: The assymetric delta gain has to be computed before this ratio |
| 159 |
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* is applied, and then the delta is added to the scaled size */ |
| 160 |
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double assymetric_tax_ratio; |
| 161 |
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| 162 |
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/*---------------------------------- |
| 163 |
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* Data from the stats file kept |
| 164 |
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* into RAM for easy access |
| 165 |
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*--------------------------------*/ |
| 166 |
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/* Array of keyframe locations |
| 168 |
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* eg: rc->keyframe_locations[100] returns the frame number of the 100th |
| 169 |
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* keyframe */ |
| 170 |
int * keyframe_locations; |
int * keyframe_locations; |
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stat_t * stats; |
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double pquant_error[32]; |
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double bquant_error[32]; |
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int quant_count[32]; |
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int last_quant[3]; |
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| 171 |
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| 172 |
double curve_comp_error; |
/* Index of the last keyframe used in the keyframe_location */ |
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int overflow; |
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int KFoverflow; |
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int KFoverflow_partial; |
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| 173 |
int KF_idx; |
int KF_idx; |
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} rc_2pass2_t; |
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| 175 |
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/* Array of all 1st pass data file -- see the twopass_stat_t structure |
| 176 |
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* definition for more details */ |
| 177 |
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twopass_stat_t * stats; |
| 178 |
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| 179 |
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/*---------------------------------- |
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* Hysteresis helpers |
| 181 |
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*--------------------------------*/ |
| 182 |
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| 183 |
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/* This field holds the int2float conversion errors of each quant per |
| 184 |
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* frame type, this allow the RC to keep track of rouding error and thus |
| 185 |
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* increase or decrease the chosen quant according to this residue */ |
| 186 |
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double quant_error[3][32]; |
| 187 |
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| 188 |
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/* This fields stores the count of each quant usage per frame type |
| 189 |
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* No real role but for debugging */ |
| 190 |
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int quant_count[3][32]; |
| 191 |
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| 192 |
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/* Last valid quantizer used per frame type, it allows quantizer |
| 193 |
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* increament/decreament limitation in order to avoid big image quality |
| 194 |
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* "jumps" */ |
| 195 |
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int last_quant[3]; |
| 196 |
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#define BUF_SZ 1024 |
/*---------------------------------- |
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#define MAX_COLS 5 |
* Overflow control |
| 199 |
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*--------------------------------*/ |
| 200 |
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/* Current overflow that has to be distributed to p/b frames */ |
| 202 |
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double overflow; |
| 203 |
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| 204 |
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/* Total overflow for keyframes -- not distributed directly */ |
| 205 |
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double KFoverflow; |
| 206 |
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/* Amount of keyframe overflow to introduce to the global p/b frame |
| 208 |
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* overflow counter at each encoded frame */ |
| 209 |
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double KFoverflow_partial; |
| 210 |
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/* Unknown ??? |
| 212 |
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* ToDo: description */ |
| 213 |
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double fq_error; |
| 214 |
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int min_quant; /* internal minimal quant, prevents wrong quants from being used */ |
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/*---------------------------------- |
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* Debug |
| 219 |
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*--------------------------------*/ |
| 220 |
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double desired_total; |
| 221 |
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double real_total; |
| 222 |
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} rc_2pass2_t; |
| 223 |
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| 224 |
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/* open stats file, and count num frames */ |
/***************************************************************************** |
| 226 |
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* Sub plugin functions prototypes |
| 227 |
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****************************************************************************/ |
| 228 |
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| 229 |
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static int rc_2pass2_create(xvid_plg_create_t * create, rc_2pass2_t ** handle); |
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static int rc_2pass2_before(rc_2pass2_t * rc, xvid_plg_data_t * data); |
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static int rc_2pass2_after(rc_2pass2_t * rc, xvid_plg_data_t * data); |
| 232 |
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static int rc_2pass2_destroy(rc_2pass2_t * rc, xvid_plg_destroy_t * destroy); |
| 233 |
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| 234 |
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/***************************************************************************** |
| 235 |
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* Plugin definition |
| 236 |
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****************************************************************************/ |
| 237 |
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| 238 |
static int det_stats_length(rc_2pass2_t * rc, char * filename) |
int |
| 239 |
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xvid_plugin_2pass2(void * handle, int opt, void * param1, void * param2) |
| 240 |
{ |
{ |
| 241 |
FILE * f; |
switch(opt) { |
| 242 |
int n, ignore; |
case XVID_PLG_INFO : |
| 243 |
char type; |
case XVID_PLG_FRAME : |
| 244 |
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return 0; |
| 245 |
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| 246 |
rc->num_frames = 0; |
case XVID_PLG_CREATE : |
| 247 |
rc->num_keyframes = 0; |
return rc_2pass2_create((xvid_plg_create_t*)param1, param2); |
| 248 |
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| 249 |
if ((f = fopen(filename, "rt")) == NULL) |
case XVID_PLG_DESTROY : |
| 250 |
return 0; |
return rc_2pass2_destroy((rc_2pass2_t*)handle, (xvid_plg_destroy_t*)param1); |
| 251 |
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| 252 |
while((n = fscanf(f, "%c %d %d %d %d %d %d\n", |
case XVID_PLG_BEFORE : |
| 253 |
&type, &ignore, &ignore, &ignore, &ignore, &ignore, &ignore)) != EOF) { |
return rc_2pass2_before((rc_2pass2_t*)handle, (xvid_plg_data_t*)param1); |
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if (type == 'i') { |
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rc->num_frames++; |
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rc->num_keyframes++; |
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}else if (type == 'p' || type == 'b' || type == 's') { |
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rc->num_frames++; |
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} |
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} |
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| 254 |
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| 255 |
fclose(f); |
case XVID_PLG_AFTER : |
| 256 |
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return rc_2pass2_after((rc_2pass2_t*)handle, (xvid_plg_data_t*)param1); |
| 257 |
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} |
| 258 |
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| 259 |
return 1; |
return XVID_ERR_FAIL; |
| 260 |
} |
} |
| 261 |
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| 262 |
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/***************************************************************************** |
| 263 |
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* Sub plugin functions definitions |
| 264 |
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****************************************************************************/ |
| 265 |
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| 266 |
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/* First a few local helping function prototypes */ |
| 267 |
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static int statsfile_count_frames(rc_2pass2_t * rc, char * filename); |
| 268 |
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static int statsfile_load(rc_2pass2_t *rc, char * filename); |
| 269 |
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static void zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create); |
| 270 |
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static void first_pass_stats_prepare_data(rc_2pass2_t * rc); |
| 271 |
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static void first_pass_scale_curve_internal(rc_2pass2_t *rc); |
| 272 |
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static void scaled_curve_apply_advanced_parameters(rc_2pass2_t * rc); |
| 273 |
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#ifdef VBV |
| 274 |
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static int check_curve_for_vbv_compliancy(rc_2pass2_t * rc, const float fps); |
| 275 |
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static int scale_curve_for_vbv_compliancy(rc_2pass2_t * rc, const float fps); |
| 276 |
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#endif |
| 277 |
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| 278 |
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#if 0 |
| 279 |
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static void stats_print(rc_2pass2_t * rc); |
| 280 |
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#endif |
| 281 |
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| 282 |
/* scale the curve */ |
/*---------------------------------------------------------------------------- |
| 283 |
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*--------------------------------------------------------------------------*/ |
| 284 |
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| 285 |
static void internal_scale(rc_2pass2_t *rc) |
static int |
| 286 |
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rc_2pass2_create(xvid_plg_create_t * create, rc_2pass2_t **handle) |
| 287 |
{ |
{ |
| 288 |
int64_t target = rc->target; |
xvid_plugin_2pass2_t * param = (xvid_plugin_2pass2_t *)create->param; |
| 289 |
int64_t tot_length = rc->tot_length[0] + rc->tot_length[1] + rc->tot_length[2]; |
rc_2pass2_t * rc; |
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int min_size[3]; |
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double scaler; |
|
| 290 |
int i; |
int i; |
| 291 |
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| 292 |
if (target <= 0 || target >= tot_length) { |
rc = malloc(sizeof(rc_2pass2_t)); |
| 293 |
printf("undersize warning\n"); |
if (rc == NULL) |
| 294 |
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return XVID_ERR_MEMORY; |
| 295 |
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| 296 |
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rc->param = *param; |
| 297 |
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| 298 |
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/* Initialize all defaults */ |
| 299 |
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#define _INIT(a, b) if((a) <= 0) (a) = (b) |
| 300 |
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/* Let's set our defaults if needed */ |
| 301 |
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_INIT(rc->param.keyframe_boost, DEFAULT_KEYFRAME_BOOST); |
| 302 |
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_INIT(rc->param.overflow_control_strength, DEFAULT_OVERFLOW_CONTROL_STRENGTH); |
| 303 |
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_INIT(rc->param.curve_compression_high, DEFAULT_CURVE_COMPRESSION_HIGH); |
| 304 |
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_INIT(rc->param.curve_compression_low, DEFAULT_CURVE_COMPRESSION_LOW); |
| 305 |
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_INIT(rc->param.max_overflow_improvement, DEFAULT_MAX_OVERFLOW_IMPROVEMENT); |
| 306 |
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_INIT(rc->param.max_overflow_degradation, DEFAULT_MAX_OVERFLOW_DEGRADATION); |
| 307 |
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| 308 |
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/* Keyframe settings */ |
| 309 |
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_INIT(rc->param.kfreduction, DEFAULT_KFREDUCTION); |
| 310 |
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_INIT(rc->param.kfthreshold, DEFAULT_KFTHRESHOLD); |
| 311 |
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#undef _INIT |
| 312 |
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| 313 |
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/* Initialize some stuff to zero */ |
| 314 |
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for(i=0; i<3; i++) { |
| 315 |
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int j; |
| 316 |
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for (j=0; j<32; j++) { |
| 317 |
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rc->quant_error[i][j] = 0; |
| 318 |
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rc->quant_count[i][j] = 0; |
| 319 |
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} |
| 320 |
} |
} |
| 321 |
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| 322 |
/* perform an initial scale pass. |
for (i=0; i<3; i++) rc->last_quant[i] = 0; |
|
if a frame size is scaled underneath our hardcoded minimums, then we force the |
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frame size to the minimum, and deduct the original & scaled frmae length from the |
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original and target total lengths */ |
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| 323 |
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| 324 |
min_size[0] = ((rc->stats[0].blks[0]*22) + 240) / 8; |
rc->fq_error = 0; |
| 325 |
min_size[1] = (rc->stats[0].blks[0] + 88) / 8; |
rc->min_quant = 1; |
|
min_size[2] = 8; |
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| 326 |
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| 327 |
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/* Count frames (and intra frames) in the stats file, store the result into |
| 328 |
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* the rc structure */ |
| 329 |
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if (statsfile_count_frames(rc, param->filename) == -1) { |
| 330 |
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DPRINTF(XVID_DEBUG_RC,"[xvid rc] -- ERROR: fopen %s failed\n", param->filename); |
| 331 |
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free(rc); |
| 332 |
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return(XVID_ERR_FAIL); |
| 333 |
|
} |
| 334 |
|
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| 335 |
scaler = (double)target / (double)tot_length; |
/* Allocate the stats' memory */ |
| 336 |
//printf("target=%i, tot_length=%i, scaler=%f\n", (int)target, (int)tot_length, scaler); |
if ((rc->stats = malloc(rc->num_frames * sizeof(twopass_stat_t))) == NULL) { |
| 337 |
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free(rc); |
| 338 |
|
return(XVID_ERR_MEMORY); |
| 339 |
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} |
| 340 |
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| 341 |
for (i=0; i<rc->num_frames; i++) { |
/* Allocate keyframes location's memory |
| 342 |
stat_t * s = &rc->stats[i]; |
* PS: see comment in pre_process0 for the +1 location requirement */ |
| 343 |
int len; |
rc->keyframe_locations = malloc((rc->num_keyframes + 1) * sizeof(int)); |
| 344 |
|
if (rc->keyframe_locations == NULL) { |
| 345 |
|
free(rc->stats); |
| 346 |
|
free(rc); |
| 347 |
|
return(XVID_ERR_MEMORY); |
| 348 |
|
} |
| 349 |
|
|
| 350 |
len = (int)((double)s->length * scaler); |
/* Load the first pass stats */ |
| 351 |
if (len < min_size[s->type]) { /* force frame size */ |
if (statsfile_load(rc, param->filename) == -1) { |
| 352 |
s->scaled_length = min_size[s->type]; |
DPRINTF(XVID_DEBUG_RC,"[xvid rc] -- ERROR: fopen %s failed\n", param->filename); |
| 353 |
target -= s->scaled_length; |
free(rc->keyframe_locations); |
| 354 |
tot_length -= s->length; |
free(rc->stats); |
| 355 |
|
free(rc); |
| 356 |
|
return XVID_ERR_FAIL; |
| 357 |
|
} |
| 358 |
|
|
| 359 |
|
/* Compute the target filesize */ |
| 360 |
|
if (rc->param.bitrate<0) { |
| 361 |
|
/* if negative, bitrate equals the target (in kbytes) */ |
| 362 |
|
rc->target = ((uint64_t)(-rc->param.bitrate)) * 1024; |
| 363 |
|
} else if (rc->num_frames < create->fbase/create->fincr) { |
| 364 |
|
/* Source sequence is less than 1s long, we do as if it was 1s long */ |
| 365 |
|
rc->target = rc->param.bitrate / 8; |
| 366 |
|
} else { |
| 367 |
|
/* Target filesize = bitrate/8 * numframes / framerate */ |
| 368 |
|
rc->target = |
| 369 |
|
((uint64_t)rc->param.bitrate * (uint64_t)rc->num_frames * \ |
| 370 |
|
(uint64_t)create->fincr) / \ |
| 371 |
|
((uint64_t)create->fbase * 8); |
| 372 |
|
} |
| 373 |
|
|
| 374 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Frame rate: %d/%d (%ffps)\n", |
| 375 |
|
create->fbase, create->fincr, |
| 376 |
|
(double)create->fbase/(double)create->fincr); |
| 377 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Number of frames: %d\n", rc->num_frames); |
| 378 |
|
if(rc->param.bitrate>=0) |
| 379 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Target bitrate: %ld\n", rc->param.bitrate); |
| 380 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Target filesize: %lld\n", rc->target); |
| 381 |
|
|
| 382 |
|
/* Compensate the average frame overhead caused by the container */ |
| 383 |
|
rc->target -= rc->num_frames*rc->param.container_frame_overhead; |
| 384 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Container Frame overhead: %d\n", rc->param.container_frame_overhead); |
| 385 |
|
if(rc->param.container_frame_overhead) |
| 386 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- New target filesize after container compensation: %lld\n", rc->target); |
| 387 |
|
|
| 388 |
|
/* When bitrate is not given it means it has been scaled by an external |
| 389 |
|
* application */ |
| 390 |
|
if (rc->param.bitrate) { |
| 391 |
|
/* Apply zone settings |
| 392 |
|
* - set rc->tot_quant which represents the total num of bytes spent in |
| 393 |
|
* fixed quant zones |
| 394 |
|
* - set rc->tot_weighted which represents the total amount of bytes |
| 395 |
|
* spent in normal or weighted zones in first pass (normal zones can |
| 396 |
|
* be considered weight=1) |
| 397 |
|
* - set rc->tot_quant_invariant which represents the total num of bytes |
| 398 |
|
* spent in fixed quant zones for headers */ |
| 399 |
|
zone_process(rc, create); |
| 400 |
}else{ |
}else{ |
| 401 |
s->scaled_length = 0; |
/* External scaling -- zones are ignored */ |
| 402 |
|
for (i=0;i<rc->num_frames;i++) { |
| 403 |
|
rc->stats[i].zone_mode = XVID_ZONE_WEIGHT; |
| 404 |
|
rc->stats[i].weight = 1.0; |
| 405 |
} |
} |
| 406 |
|
rc->tot_quant = 0; |
| 407 |
} |
} |
| 408 |
|
|
| 409 |
if (target <= 0 || target >= tot_length) { |
/* Gathers some information about first pass stats: |
| 410 |
printf("undersize warning\n"); |
* - finds the minimum frame length for each frame type during 1st pass. |
| 411 |
return; |
* rc->min_size[] |
| 412 |
|
* - determines the maximum frame length observed (no frame type distinction). |
| 413 |
|
* rc->max_size |
| 414 |
|
* - count how many times each frame type has been used. |
| 415 |
|
* rc->count[] |
| 416 |
|
* - total bytes used per frame type |
| 417 |
|
* rc->tot_length[] |
| 418 |
|
* - total bytes considered invariant between the 2 passes |
| 419 |
|
* - store keyframe location |
| 420 |
|
* rc->keyframe_locations[] |
| 421 |
|
*/ |
| 422 |
|
first_pass_stats_prepare_data(rc); |
| 423 |
|
|
| 424 |
|
/* If we have a user bitrate, it means it's an internal curve scaling */ |
| 425 |
|
if (rc->param.bitrate) { |
| 426 |
|
/* Perform internal curve scaling */ |
| 427 |
|
first_pass_scale_curve_internal(rc); |
| 428 |
} |
} |
| 429 |
|
|
| 430 |
scaler = (double)target / (double)tot_length; |
/* Apply advanced curve options, and compute some parameters in order to |
| 431 |
//printf("target=%i, tot_length=%i, scaler=%f\n", (int)target, (int)tot_length, scaler); |
* shape the curve in the BEFORE/AFTER pair of functions */ |
| 432 |
|
scaled_curve_apply_advanced_parameters(rc); |
| 433 |
|
|
|
for (i=0; i<rc->num_frames; i++) { |
|
|
stat_t * s = &rc->stats[i]; |
|
| 434 |
|
|
| 435 |
if (s->scaled_length==0) { /* ignore frame with forced frame sizes */ |
#ifdef VBV |
| 436 |
s->scaled_length = (int)((double)s->length * scaler); |
/* Check curve for VBV compliancy and rescale if necessary */ |
| 437 |
|
|
| 438 |
|
|
| 439 |
|
#ifdef VBV_FORCE |
| 440 |
|
if (rc->param.vbvsize==0) |
| 441 |
|
{ |
| 442 |
|
rc->param.vbvsize = 3145728; |
| 443 |
|
rc->param.vbvinitial = 2359296; |
| 444 |
|
rc->param.vbv_maxrate = 4000000; |
| 445 |
|
rc->param.vbv_peakrate = 10000000; |
| 446 |
} |
} |
| 447 |
|
#endif |
| 448 |
|
|
| 449 |
|
if (rc->param.vbvsize>0) /* vbvsize==0 switches VBV check off */ |
| 450 |
|
{ |
| 451 |
|
const double fps = (double)create->fbase/(double)create->fincr; |
| 452 |
|
int status = check_curve_for_vbv_compliancy(rc, fps); |
| 453 |
|
#ifdef VBV_DEBUG |
| 454 |
|
if (status) |
| 455 |
|
fprintf(stderr,"underflow detected\n Scaling Curve for compliancy... "); |
| 456 |
|
#endif |
| 457 |
|
|
| 458 |
|
status = scale_curve_for_vbv_compliancy(rc, fps); |
| 459 |
|
|
| 460 |
|
#ifdef VBV_DEBUG |
| 461 |
|
if (status==0) |
| 462 |
|
fprintf(stderr,"done.\n"); |
| 463 |
|
else |
| 464 |
|
fprintf(stderr,"impossible.\n"); |
| 465 |
|
#endif |
| 466 |
} |
} |
| 467 |
|
#endif |
| 468 |
|
|
| 469 |
|
*handle = rc; |
| 470 |
|
return(0); |
| 471 |
} |
} |
| 472 |
|
|
| 473 |
|
/*---------------------------------------------------------------------------- |
| 474 |
|
*--------------------------------------------------------------------------*/ |
| 475 |
|
|
| 476 |
|
static int |
| 477 |
|
rc_2pass2_destroy(rc_2pass2_t * rc, xvid_plg_destroy_t * destroy) |
| 478 |
|
{ |
| 479 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- target_total:%lld desired_total:%.2f (%.2f%%) actual_total:%.2f (%.2f%%)\n", |
| 480 |
|
rc->target, |
| 481 |
|
rc->desired_total, |
| 482 |
|
100*rc->desired_total/(double)rc->target, |
| 483 |
|
rc->real_total, |
| 484 |
|
100*rc->real_total/(double)rc->target); |
| 485 |
|
|
| 486 |
|
free(rc->keyframe_locations); |
| 487 |
|
free(rc->stats); |
| 488 |
|
free(rc); |
| 489 |
|
return(0); |
| 490 |
|
} |
| 491 |
|
|
| 492 |
|
/*---------------------------------------------------------------------------- |
| 493 |
|
*--------------------------------------------------------------------------*/ |
| 494 |
|
|
| 495 |
/* static void internal_scale(rc_2pass2_t *rc) |
static int |
| 496 |
|
rc_2pass2_before(rc_2pass2_t * rc, xvid_plg_data_t * data) |
| 497 |
{ |
{ |
| 498 |
const double avg_pvop = rc->avg_length[XVID_TYPE_PVOP-1]; |
twopass_stat_t * s = &rc->stats[data->frame_num]; |
| 499 |
const double avg_bvop = rc->avg_length[XVID_TYPE_BVOP-1]; |
double dbytes; |
| 500 |
const uint64_t tot_pvop = rc->tot_length[XVID_TYPE_PVOP-1]; |
double scaled_quant; |
| 501 |
const uint64_t tot_bvop = rc->tot_length[XVID_TYPE_BVOP-1]; |
double overflow; |
| 502 |
uint64_t i_total = 0; |
int capped_to_max_framesize = 0; |
|
double total1,total2; |
|
|
int i; |
|
| 503 |
|
|
| 504 |
for (i=0; i<rc->num_frames; i++) { |
/* This function is quite long but easy to understand. In order to simplify |
| 505 |
stat_t * s = &rc->stats[i]; |
* the code path (a bit), we treat 3 cases that can return immediatly. */ |
| 506 |
|
|
| 507 |
if (s->type == XVID_TYPE_IVOP) { |
/* First case: Another plugin has already set a quantizer */ |
| 508 |
i_total += s->length + s->length * rc->param.keyframe_boost / 100; |
if (data->quant > 0) |
| 509 |
|
return(0); |
| 510 |
|
|
| 511 |
|
/* Second case: insufficent stats data |
| 512 |
|
* We can't guess much what we should do, let core decide all alone */ |
| 513 |
|
if (data->frame_num >= rc->num_frames) { |
| 514 |
|
DPRINTF(XVID_DEBUG_RC,"[xvid rc] -- stats file too short (now processing frame %d)", |
| 515 |
|
data->frame_num); |
| 516 |
|
return(0); |
| 517 |
} |
} |
| 518 |
|
|
| 519 |
|
/* Third case: We are in a Quant zone |
| 520 |
|
* Quant zones must just ensure we use the same settings as first pass |
| 521 |
|
* So set the quantizer and the type */ |
| 522 |
|
if (s->zone_mode == XVID_ZONE_QUANT) { |
| 523 |
|
/* Quant stuff */ |
| 524 |
|
rc->fq_error += s->weight; |
| 525 |
|
data->quant = (int)rc->fq_error; |
| 526 |
|
rc->fq_error -= data->quant; |
| 527 |
|
|
| 528 |
|
/* The type stuff */ |
| 529 |
|
data->type = s->type; |
| 530 |
|
|
| 531 |
|
/* The only required data for AFTER step is this one for the overflow |
| 532 |
|
* control */ |
| 533 |
|
s->desired_length = s->length; |
| 534 |
|
|
| 535 |
|
return(0); |
| 536 |
} |
} |
| 537 |
|
|
|
// compensate for avi frame overhead |
|
|
rc->target_size -= rc->num_frames * 24; |
|
| 538 |
|
|
| 539 |
// perform prepass to compensate for over/undersizing |
/*************************************************************************/ |
| 540 |
|
/*************************************************************************/ |
| 541 |
|
/*************************************************************************/ |
| 542 |
|
|
| 543 |
|
/*------------------------------------------------------------------------- |
| 544 |
|
* Frame bit allocation first part |
| 545 |
|
* |
| 546 |
|
* First steps apply user settings, just like it is done in the theoritical |
| 547 |
|
* scaled_curve_apply_advanced_parameters |
| 548 |
|
*-----------------------------------------------------------------------*/ |
| 549 |
|
|
| 550 |
|
/* Set desired to what we are wanting to obtain for this frame */ |
| 551 |
|
dbytes = (double)s->scaled_length; |
| 552 |
|
|
| 553 |
if (rc->param.use_alt_curve) { |
/* IFrame user settings*/ |
| 554 |
|
if (s->type == XVID_TYPE_IVOP) { |
| 555 |
|
/* Keyframe boosting -- All keyframes benefit from it */ |
| 556 |
|
dbytes += dbytes*rc->param.keyframe_boost / 100; |
| 557 |
|
|
| 558 |
rc->alt_curve_low = avg_pvop - avg_pvop * (double)rc->param.alt_curve_low_dist / 100.0; |
#if 0 /* ToDo: decide how to apply kfthresholding */ |
| 559 |
rc->alt_curve_low_diff = avg_pvop - rc->alt_curve_low; |
#endif |
|
rc->alt_curve_high = avg_pvop + avg_pvop * (double)rc->param.alt_curve_high_dist / 100.0; |
|
|
rc->alt_curve_high_diff = rc->alt_curve_high - avg_pvop; |
|
|
if (rc->alt_curve_use_auto) { |
|
|
if (rc->movie_curve > 1.0) { |
|
|
rc->param.alt_curve_min_rel_qual = (int)(100.0 - (100.0 - 100.0 / rc->movie_curve) * (double)rc->param.alt_curve_auto_str / 100.0); |
|
|
if (rc->param.alt_curve_min_rel_qual < 20) |
|
|
rc->param.alt_curve_min_rel_qual = 20; |
|
| 560 |
}else{ |
}else{ |
| 561 |
rc->param.alt_curve_min_rel_qual = 100; |
|
| 562 |
|
/* P/S/B frames must reserve some bits for iframe boosting */ |
| 563 |
|
dbytes *= rc->pb_iboost_tax_ratio; |
| 564 |
|
|
| 565 |
|
/* Apply assymetric curve compression */ |
| 566 |
|
if (rc->param.curve_compression_high || rc->param.curve_compression_low) { |
| 567 |
|
double assymetric_delta; |
| 568 |
|
|
| 569 |
|
/* Compute the assymetric delta, this is computed before applying |
| 570 |
|
* the tax, as done in the pre_process function */ |
| 571 |
|
if (dbytes > rc->avg_length[s->type-1]) |
| 572 |
|
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_high / 100.0; |
| 573 |
|
else |
| 574 |
|
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * rc->param.curve_compression_low / 100.0; |
| 575 |
|
|
| 576 |
|
/* Now we must apply the assymetric tax, else our curve compression |
| 577 |
|
* would not give a theoritical target size equal to what it is |
| 578 |
|
* expected */ |
| 579 |
|
dbytes *= rc->assymetric_tax_ratio; |
| 580 |
|
|
| 581 |
|
/* Now we can add the assymetric delta */ |
| 582 |
|
dbytes += assymetric_delta; |
| 583 |
} |
} |
| 584 |
} |
} |
|
rc->alt_curve_mid_qual = (1.0 + (double)rc->param.alt_curve_min_rel_qual / 100.0) / 2.0; |
|
|
rc->alt_curve_qual_dev = 1.0 - rc->alt_curve_mid_qual; |
|
| 585 |
|
|
| 586 |
if (rc->param.alt_curve_low_dist > 100) { |
/* That is what we would like to have -- Don't put that chunk after |
| 587 |
switch(rc->param.alt_curve_type) { |
* overflow control, otherwise, overflow is counted twice and you obtain |
| 588 |
case XVID_CURVE_SINE : // Sine Curve (high aggressiveness) |
* half sized bitrate sequences */ |
| 589 |
rc->alt_curve_qual_dev *= 2.0 / (1.0 + sin(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff))); |
s->desired_length = (int)dbytes; |
| 590 |
rc->alt_curve_mid_qual = 1.0 - rc->alt_curve_qual_dev * sin(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff)); |
rc->desired_total += dbytes; |
| 591 |
break; |
|
| 592 |
case XVID_CURVE_LINEAR : // Linear (medium aggressiveness) |
/*------------------------------------------------------------------------ |
| 593 |
rc->alt_curve_qual_dev *= 2.0 / (1.0 + avg_pvop / rc->alt_curve_low_diff); |
* Frame bit allocation: overflow control part. |
| 594 |
rc->alt_curve_mid_qual = 1.0 - rc->alt_curve_qual_dev * avg_pvop / rc->alt_curve_low_diff; |
* |
| 595 |
break; |
* Unlike the theoritical scaled_curve_apply_advanced_parameters, here |
| 596 |
case XVID_CURVE_COSINE : // Cosine Curve (low aggressiveness) |
* it's real encoding and we need to make sure we don't go so far from |
| 597 |
rc->alt_curve_qual_dev *= 2.0 / (1.0 + (1.0 - cos(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff)))); |
* what is our ideal scaled curve. |
| 598 |
rc->alt_curve_mid_qual = 1.0 - rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff))); |
*-----------------------------------------------------------------------*/ |
| 599 |
|
|
| 600 |
|
/* Compute the overflow we should compensate */ |
| 601 |
|
if (s->type != XVID_TYPE_IVOP || rc->overflow > 0) { |
| 602 |
|
double frametype_factor; |
| 603 |
|
double framesize_factor; |
| 604 |
|
|
| 605 |
|
/* Take only the desired part of overflow */ |
| 606 |
|
overflow = rc->overflow; |
| 607 |
|
|
| 608 |
|
/* Factor that will take care to decrease the overflow applied |
| 609 |
|
* according to the importance of this frame type in term of |
| 610 |
|
* overall size */ |
| 611 |
|
frametype_factor = rc->count[XVID_TYPE_IVOP-1]*rc->avg_length[XVID_TYPE_IVOP-1]; |
| 612 |
|
frametype_factor += rc->count[XVID_TYPE_PVOP-1]*rc->avg_length[XVID_TYPE_PVOP-1]; |
| 613 |
|
frametype_factor += rc->count[XVID_TYPE_BVOP-1]*rc->avg_length[XVID_TYPE_BVOP-1]; |
| 614 |
|
frametype_factor /= rc->count[s->type-1]*rc->avg_length[s->type-1]; |
| 615 |
|
frametype_factor = 1/frametype_factor; |
| 616 |
|
|
| 617 |
|
/* Factor that will take care not to compensate too much for this frame |
| 618 |
|
* size */ |
| 619 |
|
framesize_factor = dbytes; |
| 620 |
|
framesize_factor /= rc->avg_length[s->type-1]; |
| 621 |
|
|
| 622 |
|
/* Treat only the overflow part concerned by this frame type and size */ |
| 623 |
|
overflow *= frametype_factor; |
| 624 |
|
#if 0 |
| 625 |
|
/* Leave this one alone, as it impacts badly on quality */ |
| 626 |
|
overflow *= framesize_factor; |
| 627 |
|
#endif |
| 628 |
|
|
| 629 |
|
/* Apply the overflow strength imposed by the user */ |
| 630 |
|
overflow *= (rc->param.overflow_control_strength/100.0f); |
| 631 |
|
} else { |
| 632 |
|
/* no negative overflow applied in IFrames because: |
| 633 |
|
* - their role is important as they're references for P/BFrames. |
| 634 |
|
* - there aren't much in typical sequences, so if an IFrame overflows too |
| 635 |
|
* much, this overflow may impact the next IFrame too much and generate |
| 636 |
|
* a sequence of poor quality frames */ |
| 637 |
|
overflow = 0; |
| 638 |
} |
} |
| 639 |
|
|
| 640 |
|
/* Make sure we are not trying to compensate more overflow than we even have */ |
| 641 |
|
if (fabs(overflow) > fabs(rc->overflow)) |
| 642 |
|
overflow = rc->overflow; |
| 643 |
|
|
| 644 |
|
/* Make sure the overflow doesn't make the frame size to get out of the range |
| 645 |
|
* [-max_degradation..+max_improvment] */ |
| 646 |
|
if (overflow > dbytes*rc->param.max_overflow_improvement / 100) { |
| 647 |
|
if(overflow <= dbytes) |
| 648 |
|
dbytes += dbytes * rc->param.max_overflow_improvement / 100; |
| 649 |
|
else |
| 650 |
|
dbytes += overflow * rc->param.max_overflow_improvement / 100; |
| 651 |
|
} else if (overflow < - dbytes * rc->param.max_overflow_degradation / 100) { |
| 652 |
|
dbytes -= dbytes * rc->param.max_overflow_degradation / 100; |
| 653 |
|
} else { |
| 654 |
|
dbytes += overflow; |
| 655 |
} |
} |
| 656 |
|
|
| 657 |
|
/*------------------------------------------------------------------------- |
| 658 |
|
* Frame bit allocation last part: |
| 659 |
|
* |
| 660 |
|
* Cap frame length so we don't reach neither bigger frame sizes than first |
| 661 |
|
* pass nor smaller than the allowed minimum. |
| 662 |
|
*-----------------------------------------------------------------------*/ |
| 663 |
|
|
| 664 |
|
#ifdef PASS_SMALLER |
| 665 |
|
if (dbytes > s->length) { |
| 666 |
|
dbytes = s->length; |
| 667 |
} |
} |
| 668 |
|
#endif |
| 669 |
|
|
| 670 |
total1 = 0; |
/* Prevent stupid desired sizes under logical values */ |
| 671 |
total2 = 0; |
if (dbytes < rc->min_length[s->type-1]) { |
| 672 |
|
dbytes = rc->min_length[s->type-1]; |
| 673 |
|
} |
| 674 |
|
|
| 675 |
for (i=0; i<rc->num_frames; i++) { |
/*------------------------------------------------------------------------ |
| 676 |
stat_t * s = &rc->stats[i]; |
* Desired frame length <-> quantizer mapping |
| 677 |
|
*-----------------------------------------------------------------------*/ |
| 678 |
|
|
| 679 |
if (s->type != XVID_TYPE_IVOP) { |
#ifdef BQUANT_PRESCALE |
| 680 |
|
/* For bframes we prescale the quantizer to avoid too high quant scaling */ |
| 681 |
|
if(s->type == XVID_TYPE_BVOP) { |
| 682 |
|
|
| 683 |
double dbytes = s->length / rc->movie_curve; |
twopass_stat_t *b_ref = s; |
|
double dbytes2; |
|
|
total1 += dbytes; |
|
| 684 |
|
|
| 685 |
if (s->type == XVID_TYPE_BVOP) |
/* Find the reference frame */ |
| 686 |
dbytes *= avg_pvop / avg_bvop; |
while(b_ref != &rc->stats[0] && b_ref->type == XVID_TYPE_BVOP) |
| 687 |
|
b_ref--; |
| 688 |
|
|
| 689 |
|
/* Compute the original quant */ |
| 690 |
|
s->quant = 2*(100*s->quant - data->bquant_offset); |
| 691 |
|
s->quant += data->bquant_ratio - 1; /* to avoid rounding issues */ |
| 692 |
|
s->quant = s->quant/data->bquant_ratio - b_ref->quant; |
| 693 |
|
} |
| 694 |
|
#endif |
| 695 |
|
|
| 696 |
|
/* Don't laugh at this very 'simple' quant<->size relationship, it |
| 697 |
|
* proves to be acurate enough for our algorithm */ |
| 698 |
|
scaled_quant = (double)s->quant*(double)s->length/(double)dbytes; |
| 699 |
|
|
| 700 |
|
#ifdef COMPENSATE_FORMULA |
| 701 |
|
/* We know xvidcore will apply the bframe formula again, so we compensate |
| 702 |
|
* it right now to make sure we would not apply it twice */ |
| 703 |
|
if(s->type == XVID_TYPE_BVOP) { |
| 704 |
|
|
| 705 |
if (rc->param.use_alt_curve) { |
twopass_stat_t *b_ref = s; |
| 706 |
if (dbytes > avg_pvop) { |
|
| 707 |
if (dbytes >= rc->alt_curve_high) { |
/* Find the reference frame */ |
| 708 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev); |
while(b_ref != &rc->stats[0] && b_ref->type == XVID_TYPE_BVOP) |
| 709 |
}else{ |
b_ref--; |
| 710 |
switch(rc->param.alt_curve_type){ |
|
| 711 |
case XVID_CURVE_SINE : |
/* Compute the quant it would be if the core did not apply the bframe |
| 712 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - avg_pvop) * 90.0 / rc->alt_curve_high_diff))); |
* formula */ |
| 713 |
break; |
scaled_quant = 100*scaled_quant - data->bquant_offset; |
| 714 |
case XVID_CURVE_LINEAR : |
scaled_quant += data->bquant_ratio - 1; /* to avoid rouding issues */ |
| 715 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - avg_pvop) / rc->alt_curve_high_diff); |
scaled_quant /= data->bquant_ratio; |
|
break; |
|
|
case XVID_CURVE_COSINE : |
|
|
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - avg_pvop) * 90.0 / rc->alt_curve_high_diff)))); |
|
|
} |
|
| 716 |
} |
} |
| 717 |
|
#endif |
| 718 |
|
|
| 719 |
|
/* Quantizer has been scaled using floating point operations/results, we |
| 720 |
|
* must cast it to integer */ |
| 721 |
|
data->quant = (int)scaled_quant; |
| 722 |
|
|
| 723 |
|
/* Let's clip the computed quantizer, if needed */ |
| 724 |
|
if (data->quant < 1) { |
| 725 |
|
data->quant = 1; |
| 726 |
|
} else if (data->quant > 31) { |
| 727 |
|
data->quant = 31; |
| 728 |
}else{ |
}else{ |
| 729 |
if (dbytes <= rc->alt_curve_low){ |
|
| 730 |
dbytes2 = dbytes; |
/* The frame quantizer has not been clipped, this appears to be a good |
| 731 |
}else{ |
* computed quantizer, do not loose quantizer decimal part that we |
| 732 |
switch(rc->param.alt_curve_type){ |
* accumulate for later reuse when its sum represents a complete |
| 733 |
case XVID_CURVE_SINE : |
* unit. */ |
| 734 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - avg_pvop) * 90.0 / rc->alt_curve_low_diff))); |
rc->quant_error[s->type-1][data->quant] += scaled_quant - (double)data->quant; |
| 735 |
break; |
|
| 736 |
case XVID_CURVE_LINEAR : |
if (rc->quant_error[s->type-1][data->quant] >= 1.0) { |
| 737 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - avg_pvop) / rc->alt_curve_low_diff); |
rc->quant_error[s->type-1][data->quant] -= 1.0; |
| 738 |
break; |
data->quant++; |
| 739 |
case XVID_CURVE_COSINE : |
} else if (rc->quant_error[s->type-1][data->quant] <= -1.0) { |
| 740 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual + rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - avg_pvop) * 90.0 / rc->alt_curve_low_diff)))); |
rc->quant_error[s->type-1][data->quant] += 1.0; |
| 741 |
|
data->quant--; |
| 742 |
} |
} |
| 743 |
} |
} |
| 744 |
|
|
| 745 |
|
/* Now we have a computed quant that is in the right quante range, with a |
| 746 |
|
* possible +1 correction due to cumulated error. We can now safely clip |
| 747 |
|
* the quantizer again with user's quant ranges. "Safely" means the Rate |
| 748 |
|
* Control could learn more about this quantizer, this knowledge is useful |
| 749 |
|
* for future frames even if it this quantizer won't be really used atm, |
| 750 |
|
* that's why we don't perform this clipping earlier. */ |
| 751 |
|
if (data->quant < data->min_quant[s->type-1]) { |
| 752 |
|
data->quant = data->min_quant[s->type-1]; |
| 753 |
|
} else if (data->quant > data->max_quant[s->type-1]) { |
| 754 |
|
data->quant = data->max_quant[s->type-1]; |
| 755 |
} |
} |
| 756 |
}else{ |
|
| 757 |
if (dbytes > avg_pvop) { |
if (data->quant < rc->min_quant) data->quant = rc->min_quant; |
| 758 |
dbytes2 = ((double)dbytes + (avg_pvop - dbytes) * |
|
| 759 |
rc->param.curve_compression_high / 100.0); |
/* To avoid big quality jumps from frame to frame, we apply a "security" |
| 760 |
}else{ |
* rule that makes |last_quant - new_quant| <= 2. This rule only applies |
| 761 |
dbytes2 = ((double)dbytes + (avg_pvop - dbytes) * |
* to predicted frames (P and B) */ |
| 762 |
rc->param.curve_compression_low / 100.0); |
if (s->type != XVID_TYPE_IVOP && rc->last_quant[s->type-1] && capped_to_max_framesize == 0) { |
| 763 |
|
|
| 764 |
|
if (data->quant > rc->last_quant[s->type-1] + 2) { |
| 765 |
|
data->quant = rc->last_quant[s->type-1] + 2; |
| 766 |
|
DPRINTF(XVID_DEBUG_RC, |
| 767 |
|
"[xvid rc] -- frame %d p/b-frame quantizer prevented from rising too steeply\n", |
| 768 |
|
data->frame_num); |
| 769 |
} |
} |
| 770 |
|
if (data->quant < rc->last_quant[s->type-1] - 2) { |
| 771 |
|
data->quant = rc->last_quant[s->type-1] - 2; |
| 772 |
|
DPRINTF(XVID_DEBUG_RC, |
| 773 |
|
"[xvid rc] -- frame:%d p/b-frame quantizer prevented from falling too steeply\n", |
| 774 |
|
data->frame_num); |
| 775 |
} |
} |
|
|
|
|
if (s->type == XVID_TYPE_BVOP) { |
|
|
dbytes2 *= avg_bvop / avg_pvop; |
|
| 776 |
} |
} |
| 777 |
|
|
| 778 |
if (dbytes2 < rc->min_length[s->type-1]) { |
/* We don't want to pollute the RC histerisis when our computed quant has |
| 779 |
dbytes = rc->min_length[s->type-1]; |
* been computed from a capped frame size */ |
| 780 |
|
if (capped_to_max_framesize == 0) |
| 781 |
|
rc->last_quant[s->type-1] = data->quant; |
| 782 |
|
|
| 783 |
|
/* Don't forget to force 1st pass frame type ;-) */ |
| 784 |
|
data->type = s->type; |
| 785 |
|
|
| 786 |
|
return 0; |
| 787 |
} |
} |
| 788 |
|
|
| 789 |
total2 += dbytes2; |
/*---------------------------------------------------------------------------- |
| 790 |
|
*--------------------------------------------------------------------------*/ |
| 791 |
|
|
| 792 |
|
static int |
| 793 |
|
rc_2pass2_after(rc_2pass2_t * rc, xvid_plg_data_t * data) |
| 794 |
|
{ |
| 795 |
|
const char frame_type[4] = { 'i', 'p', 'b', 's'}; |
| 796 |
|
twopass_stat_t * s = &rc->stats[data->frame_num]; |
| 797 |
|
|
| 798 |
|
/* Insufficent stats data */ |
| 799 |
|
if (data->frame_num >= rc->num_frames) |
| 800 |
|
return 0; |
| 801 |
|
|
| 802 |
|
/* Update the quantizer counter */ |
| 803 |
|
rc->quant_count[s->type-1][data->quant]++; |
| 804 |
|
|
| 805 |
|
/* Update the frame type overflow */ |
| 806 |
|
if (data->type == XVID_TYPE_IVOP) { |
| 807 |
|
int kfdiff = 0; |
| 808 |
|
|
| 809 |
|
if(rc->KF_idx != rc->num_frames -1) { |
| 810 |
|
kfdiff = rc->keyframe_locations[rc->KF_idx+1]; |
| 811 |
|
kfdiff -= rc->keyframe_locations[rc->KF_idx]; |
| 812 |
} |
} |
| 813 |
|
|
| 814 |
|
/* Flush Keyframe overflow accumulator */ |
| 815 |
|
rc->overflow += rc->KFoverflow; |
| 816 |
|
|
| 817 |
|
/* Store the frame overflow to the keyframe accumulator */ |
| 818 |
|
rc->KFoverflow = s->desired_length - data->length; |
| 819 |
|
|
| 820 |
|
if (kfdiff > 1) { |
| 821 |
|
/* Non-consecutive keyframes case: |
| 822 |
|
* We can then divide this total keyframe overflow into equal parts |
| 823 |
|
* that we will distribute into regular overflow at each frame |
| 824 |
|
* between the sequence bounded by two IFrames */ |
| 825 |
|
rc->KFoverflow_partial = rc->KFoverflow / (kfdiff - 1); |
| 826 |
|
} else { |
| 827 |
|
/* Consecutive keyframes case: |
| 828 |
|
* Flush immediatly the keyframe overflow and reset keyframe |
| 829 |
|
* overflow */ |
| 830 |
|
rc->overflow += rc->KFoverflow; |
| 831 |
|
rc->KFoverflow = 0; |
| 832 |
|
rc->KFoverflow_partial = 0; |
| 833 |
} |
} |
| 834 |
|
rc->KF_idx++; |
| 835 |
|
} else { |
| 836 |
|
/* Accumulate the frame overflow */ |
| 837 |
|
rc->overflow += s->desired_length - data->length; |
| 838 |
|
|
| 839 |
rc->curve_comp_scale = total1 / total2; |
/* Distribute part of the keyframe overflow */ |
| 840 |
|
rc->overflow += rc->KFoverflow_partial; |
| 841 |
|
|
| 842 |
if (!rc->param.use_alt_curve) { |
/* Don't forget to substract that same amount from the total keyframe |
| 843 |
printf("middle frame size for asymmetric curve compression: %i", |
* overflow */ |
| 844 |
(int)(avg_pvop * rc->curve_comp_scale)); |
rc->KFoverflow -= rc->KFoverflow_partial; |
| 845 |
} |
} |
|
}*/ |
|
| 846 |
|
|
| 847 |
|
rc->overflow += (s->error = s->desired_length - data->length); |
| 848 |
|
rc->real_total += data->length; |
| 849 |
|
|
| 850 |
|
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", |
| 851 |
|
data->frame_num, |
| 852 |
|
frame_type[data->type-1], |
| 853 |
|
data->quant, |
| 854 |
|
s->length, |
| 855 |
|
s->scaled_length, |
| 856 |
|
s->desired_length, |
| 857 |
|
s->desired_length - s->error, |
| 858 |
|
-s->error, |
| 859 |
|
rc->overflow); |
| 860 |
|
|
| 861 |
|
return(0); |
| 862 |
|
} |
| 863 |
|
|
| 864 |
/* open stats file(s) and read into rc->stats array */ |
/***************************************************************************** |
| 865 |
|
* Helper functions definition |
| 866 |
|
****************************************************************************/ |
| 867 |
|
|
| 868 |
static int load_stats(rc_2pass2_t *rc, char * filename) |
/* Default buffer size for reading lines */ |
| 869 |
|
#define BUF_SZ 1024 |
| 870 |
|
|
| 871 |
|
/* Helper functions for reading/parsing the stats file */ |
| 872 |
|
static char *skipspaces(char *string); |
| 873 |
|
static int iscomment(char *string); |
| 874 |
|
static char *readline(FILE *f); |
| 875 |
|
|
| 876 |
|
/* This function counts the number of frame entries in the stats file |
| 877 |
|
* It also counts the number of I Frames */ |
| 878 |
|
static int |
| 879 |
|
statsfile_count_frames(rc_2pass2_t * rc, char * filename) |
| 880 |
{ |
{ |
| 881 |
FILE * f; |
FILE * f; |
| 882 |
int i, not_scaled; |
char *line; |
| 883 |
|
int lines; |
| 884 |
|
|
| 885 |
|
rc->num_frames = 0; |
| 886 |
|
rc->num_keyframes = 0; |
| 887 |
|
|
| 888 |
|
if ((f = fopen(filename, "rb")) == NULL) |
| 889 |
|
return(-1); |
| 890 |
|
|
| 891 |
if ((f = fopen(filename, "rt"))==NULL) |
lines = 0; |
| 892 |
return 0; |
while ((line = readline(f)) != NULL) { |
| 893 |
|
|
| 894 |
i = 0; |
char *ptr; |
|
not_scaled = 0; |
|
|
while(i < rc->num_frames) { |
|
|
stat_t * s = &rc->stats[i]; |
|
|
int n; |
|
| 895 |
char type; |
char type; |
| 896 |
|
int fields; |
| 897 |
|
|
| 898 |
s->scaled_length = 0; |
lines++; |
|
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; |
|
|
} |
|
| 899 |
|
|
| 900 |
if (type == 'i') { |
/* We skip spaces */ |
| 901 |
s->type = XVID_TYPE_IVOP; |
ptr = skipspaces(line); |
| 902 |
}else if (type == 'p' || type == 's') { |
|
| 903 |
s->type = XVID_TYPE_PVOP; |
/* Skip coment lines or empty lines */ |
| 904 |
}else if (type == 'b') { |
if(iscomment(ptr) || *ptr == '\0') { |
| 905 |
s->type = XVID_TYPE_BVOP; |
free(line); |
|
}else{ /* unknown type */ |
|
|
printf("unk\n"); |
|
| 906 |
continue; |
continue; |
| 907 |
} |
} |
| 908 |
|
|
| 909 |
i++; |
/* Read the stat line from buffer */ |
| 910 |
|
fields = sscanf(ptr, "%c", &type); |
| 911 |
|
|
| 912 |
|
/* Valid stats files have at least 7 fields */ |
| 913 |
|
if (fields == 1) { |
| 914 |
|
switch(type) { |
| 915 |
|
case 'i': |
| 916 |
|
case 'I': |
| 917 |
|
rc->num_keyframes++; |
| 918 |
|
case 'p': |
| 919 |
|
case 'P': |
| 920 |
|
case 'b': |
| 921 |
|
case 'B': |
| 922 |
|
case 's': |
| 923 |
|
case 'S': |
| 924 |
|
rc->num_frames++; |
| 925 |
|
break; |
| 926 |
|
default: |
| 927 |
|
DPRINTF(XVID_DEBUG_RC, |
| 928 |
|
"[xvid rc] -- WARNING: L%d unknown frame type used (%c).\n", |
| 929 |
|
lines, type); |
| 930 |
|
} |
| 931 |
|
} else { |
| 932 |
|
DPRINTF(XVID_DEBUG_RC, |
| 933 |
|
"[xvid rc] -- WARNING: L%d misses some stat fields (%d).\n", |
| 934 |
|
lines, 7-fields); |
| 935 |
|
} |
| 936 |
|
|
| 937 |
|
/* Free the line buffer */ |
| 938 |
|
free(line); |
| 939 |
} |
} |
|
rc->num_frames = i; |
|
| 940 |
|
|
| 941 |
|
/* We are done with the file */ |
| 942 |
fclose(f); |
fclose(f); |
| 943 |
|
|
| 944 |
return 1; |
return(0); |
| 945 |
} |
} |
| 946 |
|
|
| 947 |
|
/* open stats file(s) and read into rc->stats array */ |
| 948 |
|
static int |
| 949 |
|
statsfile_load(rc_2pass2_t *rc, char * filename) |
| 950 |
|
{ |
| 951 |
|
FILE * f; |
| 952 |
|
int processed_entries; |
| 953 |
|
|
| 954 |
|
/* Opens the file */ |
| 955 |
|
if ((f = fopen(filename, "rb"))==NULL) |
| 956 |
|
return(-1); |
| 957 |
|
|
| 958 |
|
processed_entries = 0; |
| 959 |
|
while(processed_entries < rc->num_frames) { |
| 960 |
|
char type; |
| 961 |
|
int fields; |
| 962 |
|
twopass_stat_t * s = &rc->stats[processed_entries]; |
| 963 |
|
char *line, *ptr; |
| 964 |
|
|
| 965 |
|
/* Read the line from the file */ |
| 966 |
|
if((line = readline(f)) == NULL) |
| 967 |
|
break; |
| 968 |
|
|
| 969 |
|
/* We skip spaces */ |
| 970 |
|
ptr = skipspaces(line); |
| 971 |
|
|
| 972 |
static void print_stats(rc_2pass2_t * rc) |
/* Skip comment lines or empty lines */ |
| 973 |
{ |
if(iscomment(ptr) || *ptr == '\0') { |
| 974 |
int i; |
free(line); |
| 975 |
for (i = 0; i < rc->num_frames; i++) { |
continue; |
| 976 |
stat_t * s = &rc->stats[i]; |
} |
|
printf("%i %i %i %i\n", s->type, s->quant, s->length, s->scaled_length); |
|
| 977 |
|
|
| 978 |
|
/* Reset this field that is optional */ |
| 979 |
|
s->scaled_length = 0; |
| 980 |
|
|
| 981 |
|
/* Convert the fields */ |
| 982 |
|
fields = sscanf(ptr, |
| 983 |
|
"%c %d %d %d %d %d %d %d\n", |
| 984 |
|
&type, |
| 985 |
|
&s->quant, |
| 986 |
|
&s->blks[0], &s->blks[1], &s->blks[2], |
| 987 |
|
&s->length, &s->invariant /* not really yet */, |
| 988 |
|
&s->scaled_length); |
| 989 |
|
|
| 990 |
|
/* Free line buffer, we don't need it anymore */ |
| 991 |
|
free(line); |
| 992 |
|
|
| 993 |
|
/* Fail silently, this has probably been warned in |
| 994 |
|
* statsfile_count_frames */ |
| 995 |
|
if(fields != 7 && fields != 8) |
| 996 |
|
continue; |
| 997 |
|
|
| 998 |
|
/* Convert frame type and compute the invariant length part */ |
| 999 |
|
switch(type) { |
| 1000 |
|
case 'i': |
| 1001 |
|
case 'I': |
| 1002 |
|
s->type = XVID_TYPE_IVOP; |
| 1003 |
|
s->invariant /= INVARIANT_HEADER_PART_IVOP; |
| 1004 |
|
break; |
| 1005 |
|
case 'p': |
| 1006 |
|
case 'P': |
| 1007 |
|
case 's': |
| 1008 |
|
case 'S': |
| 1009 |
|
s->type = XVID_TYPE_PVOP; |
| 1010 |
|
s->invariant /= INVARIANT_HEADER_PART_PVOP; |
| 1011 |
|
break; |
| 1012 |
|
case 'b': |
| 1013 |
|
case 'B': |
| 1014 |
|
s->type = XVID_TYPE_BVOP; |
| 1015 |
|
s->invariant /= INVARIANT_HEADER_PART_BVOP; |
| 1016 |
|
break; |
| 1017 |
|
default: |
| 1018 |
|
/* Same as before, fail silently */ |
| 1019 |
|
continue; |
| 1020 |
} |
} |
| 1021 |
|
|
| 1022 |
|
/* Ok it seems it's been processed correctly */ |
| 1023 |
|
processed_entries++; |
| 1024 |
} |
} |
| 1025 |
|
|
| 1026 |
|
/* Close the file */ |
| 1027 |
|
fclose(f); |
| 1028 |
|
|
| 1029 |
/* pre-process the statistics data |
return(0); |
| 1030 |
this is a clone of vfw/src/2pass.c:codec_2pass_init minus file reading, alt_curve, internal scale |
} |
|
*/ |
|
| 1031 |
|
|
| 1032 |
void pre_process0(rc_2pass2_t * rc) |
/* pre-process the statistics data |
| 1033 |
|
* - for each type, count, tot_length, min_length, max_length |
| 1034 |
|
* - set keyframes_locations, tot_prescaled */ |
| 1035 |
|
static void |
| 1036 |
|
first_pass_stats_prepare_data(rc_2pass2_t * rc) |
| 1037 |
{ |
{ |
| 1038 |
int i,j; |
int i,j; |
| 1039 |
|
|
| 1040 |
|
/* *rc fields initialization |
| 1041 |
|
* NB: INT_MAX and INT_MIN are used in order to be immediately replaced |
| 1042 |
|
* with real values of the 1pass */ |
| 1043 |
for (i=0; i<3; i++) { |
for (i=0; i<3; i++) { |
| 1044 |
rc->count[i]=0; |
rc->count[i]=0; |
| 1045 |
rc->tot_length[i] = 0; |
rc->tot_length[i] = 0; |
| 1046 |
rc->last_quant[i] = 0; |
rc->tot_invariant[i] = 0; |
| 1047 |
|
rc->min_length[i] = INT_MAX; |
| 1048 |
} |
} |
| 1049 |
|
|
| 1050 |
for (i=0; i<32;i++) { |
rc->max_length = INT_MIN; |
| 1051 |
rc->pquant_error[i] = 0; |
rc->tot_weighted = 0; |
|
rc->bquant_error[i] = 0; |
|
|
rc->quant_count[i] = 0; |
|
|
} |
|
| 1052 |
|
|
| 1053 |
|
/* Loop through all frames and find/compute all the stuff this function |
| 1054 |
|
* is supposed to do */ |
| 1055 |
for (i=j=0; i<rc->num_frames; i++) { |
for (i=j=0; i<rc->num_frames; i++) { |
| 1056 |
stat_t * s = &rc->stats[i]; |
twopass_stat_t * s = &rc->stats[i]; |
| 1057 |
|
|
| 1058 |
rc->count[s->type-1]++; |
rc->count[s->type-1]++; |
| 1059 |
rc->tot_length[s->type-1] += s->length; |
rc->tot_length[s->type-1] += s->length; |
| 1060 |
|
rc->tot_invariant[s->type-1] += s->invariant; |
| 1061 |
|
if (s->zone_mode != XVID_ZONE_QUANT) |
| 1062 |
|
rc->tot_weighted += (int)(s->weight*(s->length - s->invariant)); |
| 1063 |
|
|
| 1064 |
if (i == 0 || s->length < rc->min_length[s->type-1]) { |
if (s->length < rc->min_length[s->type-1]) { |
| 1065 |
rc->min_length[s->type-1] = s->length; |
rc->min_length[s->type-1] = s->length; |
| 1066 |
} |
} |
| 1067 |
|
|
| 1068 |
if (i == 0 || s->length > rc->max_length) { |
if (s->length > rc->max_length) { |
| 1069 |
rc->max_length = s->length; |
rc->max_length = s->length; |
| 1070 |
} |
} |
| 1071 |
|
|
| 1074 |
j++; |
j++; |
| 1075 |
} |
} |
| 1076 |
} |
} |
| 1077 |
|
|
| 1078 |
|
/* NB: |
| 1079 |
|
* The "per sequence" overflow system considers a natural sequence to be |
| 1080 |
|
* formed by all frames between two iframes, so if we want to make sure |
| 1081 |
|
* the system does not go nuts during last sequence, we force the last |
| 1082 |
|
* frame to appear in the keyframe locations array. */ |
| 1083 |
rc->keyframe_locations[j] = i; |
rc->keyframe_locations[j] = i; |
| 1084 |
|
|
| 1085 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Min 1st pass IFrame length: %d\n", rc->min_length[0]); |
| 1086 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Min 1st pass PFrame length: %d\n", rc->min_length[1]); |
| 1087 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Min 1st pass BFrame length: %d\n", rc->min_length[2]); |
| 1088 |
} |
} |
| 1089 |
|
|
| 1090 |
|
/* calculate zone weight "center" */ |
| 1091 |
|
static void |
| 1092 |
|
zone_process(rc_2pass2_t *rc, const xvid_plg_create_t * create) |
| 1093 |
|
{ |
| 1094 |
|
int i,j; |
| 1095 |
|
int n = 0; |
| 1096 |
|
|
| 1097 |
|
rc->tot_quant = 0; |
| 1098 |
|
rc->tot_quant_invariant = 0; |
| 1099 |
|
|
| 1100 |
void pre_process1(rc_2pass2_t * rc) |
if (create->num_zones == 0) { |
| 1101 |
{ |
for (j = 0; j < rc->num_frames; j++) { |
| 1102 |
int i; |
rc->stats[j].zone_mode = XVID_ZONE_WEIGHT; |
| 1103 |
double total1, total2; |
rc->stats[j].weight = 1.0; |
| 1104 |
uint64_t ivop_boost_total; |
} |
| 1105 |
|
n += rc->num_frames; |
|
ivop_boost_total = 0; |
|
|
rc->curve_comp_error = 0; |
|
|
|
|
|
for (i=0; i<3; i++) { |
|
|
rc->tot_scaled_length[i] = 0; |
|
| 1106 |
} |
} |
| 1107 |
|
|
|
for (i=0; i<rc->num_frames; i++) { |
|
|
stat_t * s = &rc->stats[i]; |
|
| 1108 |
|
|
| 1109 |
rc->tot_scaled_length[s->type-1] += s->scaled_length; |
for(i=0; i < create->num_zones; i++) { |
| 1110 |
|
|
| 1111 |
if (s->type == XVID_TYPE_IVOP) { |
int next = (i+1<create->num_zones) ? create->zones[i+1].frame : rc->num_frames; |
|
ivop_boost_total += s->scaled_length * rc->param.keyframe_boost / 100; |
|
|
} |
|
|
} |
|
| 1112 |
|
|
| 1113 |
rc->movie_curve = ((double)(rc->tot_scaled_length[XVID_TYPE_PVOP-1] + rc->tot_scaled_length[XVID_TYPE_BVOP-1] + ivop_boost_total) / |
/* Zero weight make no sense */ |
| 1114 |
(rc->tot_scaled_length[XVID_TYPE_PVOP-1] + rc->tot_scaled_length[XVID_TYPE_BVOP-1])); |
if (create->zones[i].increment == 0) create->zones[i].increment = 1; |
| 1115 |
|
/* And obviously an undetermined infinite makes even less sense */ |
| 1116 |
|
if (create->zones[i].base == 0) create->zones[i].base = 1; |
| 1117 |
|
|
| 1118 |
for(i=0; i<3; i++) { |
if (i==0 && create->zones[i].frame > 0) { |
| 1119 |
if (rc->count[i] == 0 || rc->movie_curve == 0) { |
for (j = 0; j < create->zones[i].frame && j < rc->num_frames; j++) { |
| 1120 |
rc->avg_length[i] = 1; |
rc->stats[j].zone_mode = XVID_ZONE_WEIGHT; |
| 1121 |
}else{ |
rc->stats[j].weight = 1.0; |
|
rc->avg_length[i] = rc->tot_scaled_length[i] / rc->count[i] / rc->movie_curve; |
|
| 1122 |
} |
} |
| 1123 |
|
n += create->zones[i].frame; |
| 1124 |
} |
} |
| 1125 |
|
|
| 1126 |
/* alt curve stuff here */ |
if (create->zones[i].mode == XVID_ZONE_WEIGHT) { |
| 1127 |
|
for (j = create->zones[i].frame; j < next && j < rc->num_frames; j++ ) { |
| 1128 |
if (rc->param.use_alt_curve) { |
rc->stats[j].zone_mode = XVID_ZONE_WEIGHT; |
| 1129 |
const double avg_pvop = rc->avg_length[XVID_TYPE_PVOP-1]; |
rc->stats[j].weight = (double)create->zones[i].increment / (double)create->zones[i].base; |
|
const uint64_t tot_pvop = rc->tot_length[XVID_TYPE_PVOP-1]; |
|
|
const uint64_t tot_bvop = rc->tot_length[XVID_TYPE_BVOP-1]; |
|
|
const uint64_t tot_scaled_pvop = rc->tot_scaled_length[XVID_TYPE_PVOP-1]; |
|
|
const uint64_t tot_scaled_bvop = rc->tot_scaled_length[XVID_TYPE_BVOP-1]; |
|
|
|
|
|
rc->alt_curve_low = avg_pvop - avg_pvop * (double)rc->param.alt_curve_low_dist / 100.0; |
|
|
rc->alt_curve_low_diff = avg_pvop - rc->alt_curve_low; |
|
|
rc->alt_curve_high = avg_pvop + avg_pvop * (double)rc->param.alt_curve_high_dist / 100.0; |
|
|
rc->alt_curve_high_diff = rc->alt_curve_high - avg_pvop; |
|
|
|
|
|
if (rc->param.alt_curve_use_auto) { |
|
|
if (tot_bvop + tot_pvop > tot_scaled_bvop + tot_scaled_pvop) { |
|
|
rc->param.alt_curve_min_rel_qual = (int)(100.0 - (100.0 - 100.0 / |
|
|
((double)(tot_pvop + tot_bvop) / (double)(tot_scaled_pvop + tot_scaled_bvop))) * (double)rc->param.alt_curve_auto_str / 100.0); |
|
|
|
|
|
if (rc->param.alt_curve_min_rel_qual < 20) |
|
|
rc->param.alt_curve_min_rel_qual = 20; |
|
|
}else{ |
|
|
rc->param.alt_curve_min_rel_qual = 100; |
|
| 1130 |
} |
} |
| 1131 |
|
next -= create->zones[i].frame; |
| 1132 |
|
n += next; |
| 1133 |
|
} else{ /* XVID_ZONE_QUANT */ |
| 1134 |
|
for (j = create->zones[i].frame; j < next && j < rc->num_frames; j++ ) { |
| 1135 |
|
rc->stats[j].zone_mode = XVID_ZONE_QUANT; |
| 1136 |
|
rc->stats[j].weight = (double)create->zones[i].increment / (double)create->zones[i].base; |
| 1137 |
|
rc->tot_quant += rc->stats[j].length; |
| 1138 |
|
rc->tot_quant_invariant += rc->stats[j].invariant; |
| 1139 |
} |
} |
|
rc->alt_curve_mid_qual = (1.0 + (double)rc->param.alt_curve_min_rel_qual / 100.0) / 2.0; |
|
|
rc->alt_curve_qual_dev = 1.0 - rc->alt_curve_mid_qual; |
|
|
|
|
|
if (rc->param.alt_curve_low_dist > 100) { |
|
|
switch(rc->param.alt_curve_type) { |
|
|
case XVID_CURVE_SINE: // Sine Curve (high aggressiveness) |
|
|
rc->alt_curve_qual_dev *= 2.0 / (1.0 + sin(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff))); |
|
|
rc->alt_curve_mid_qual = 1.0 - rc->alt_curve_qual_dev * sin(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff)); |
|
|
break; |
|
|
case XVID_CURVE_LINEAR: // Linear (medium aggressiveness) |
|
|
rc->alt_curve_qual_dev *= 2.0 / (1.0 + avg_pvop / rc->alt_curve_low_diff); |
|
|
rc->alt_curve_mid_qual = 1.0 - rc->alt_curve_qual_dev * avg_pvop / rc->alt_curve_low_diff; |
|
|
break; |
|
|
case XVID_CURVE_COSINE: // Cosine Curve (low aggressiveness) |
|
|
rc->alt_curve_qual_dev *= 2.0 / (1.0 + (1.0 - cos(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff)))); |
|
|
rc->alt_curve_mid_qual = 1.0 - rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * (avg_pvop * 90.0 / rc->alt_curve_low_diff))); |
|
| 1140 |
} |
} |
| 1141 |
} |
} |
| 1142 |
} |
} |
|
/* --- */ |
|
| 1143 |
|
|
| 1144 |
|
|
| 1145 |
total1=total2=0; |
/* scale the curve */ |
| 1146 |
for (i=0; i<rc->num_frames; i++) { |
static void |
| 1147 |
stat_t * s = &rc->stats[i]; |
first_pass_scale_curve_internal(rc_2pass2_t *rc) |
| 1148 |
|
{ |
| 1149 |
if (s->type != XVID_TYPE_IVOP) { |
int64_t target; |
| 1150 |
double dbytes,dbytes2; |
int64_t total_invariant; |
| 1151 |
|
double scaler; |
| 1152 |
|
int i, num_MBs; |
| 1153 |
|
|
| 1154 |
dbytes = s->scaled_length / rc->movie_curve; |
/* We only scale texture data ! */ |
| 1155 |
dbytes2 = 0; /* XXX: warning */ |
total_invariant = rc->tot_invariant[XVID_TYPE_IVOP-1]; |
| 1156 |
total1 += dbytes; |
total_invariant += rc->tot_invariant[XVID_TYPE_PVOP-1]; |
| 1157 |
if (s->type == XVID_TYPE_BVOP) |
total_invariant += rc->tot_invariant[XVID_TYPE_BVOP-1]; |
| 1158 |
dbytes *= rc->avg_length[XVID_TYPE_PVOP-1] / rc->avg_length[XVID_TYPE_BVOP-1]; |
/* don't forget to substract header bytes used in quant zones, otherwise we |
| 1159 |
|
* counting them twice */ |
| 1160 |
|
total_invariant -= rc->tot_quant_invariant; |
| 1161 |
|
|
| 1162 |
|
/* We remove the bytes used by the fixed quantizer zones during first pass |
| 1163 |
|
* with the same quants, so we know very precisely how much that |
| 1164 |
|
* represents */ |
| 1165 |
|
target = rc->target; |
| 1166 |
|
target -= rc->tot_quant; |
| 1167 |
|
|
| 1168 |
|
/* Let's compute a linear scaler in order to perform curve scaling */ |
| 1169 |
|
scaler = (double)(target - total_invariant) / (double)(rc->tot_weighted); |
| 1170 |
|
|
| 1171 |
|
#ifdef SMART_OVERFLOW_SETTING |
| 1172 |
|
if (scaler > 0.9) { |
| 1173 |
|
rc->param.max_overflow_degradation *= 5; |
| 1174 |
|
rc->param.max_overflow_improvement *= 5; |
| 1175 |
|
rc->param.overflow_control_strength *= 3; |
| 1176 |
|
} else if (scaler > 0.6) { |
| 1177 |
|
rc->param.max_overflow_degradation *= 2; |
| 1178 |
|
rc->param.max_overflow_improvement *= 2; |
| 1179 |
|
rc->param.overflow_control_strength *= 2; |
| 1180 |
|
} else { |
| 1181 |
|
rc->min_quant = 2; |
| 1182 |
|
} |
| 1183 |
|
#endif |
| 1184 |
|
|
| 1185 |
|
/* Compute min frame lengths (for each frame type) according to the number |
| 1186 |
|
* of MBs. We sum all block type counters of frame 0, this gives us the |
| 1187 |
|
* number of MBs. |
| 1188 |
|
* |
| 1189 |
|
* We compare these hardcoded values with observed values in first pass |
| 1190 |
|
* (determined in pre_process0).Then we keep the real minimum. */ |
| 1191 |
|
|
| 1192 |
if (rc->param.use_alt_curve) { |
/* Number of MBs */ |
| 1193 |
if (dbytes > rc->avg_length[XVID_TYPE_PVOP-1]) { |
num_MBs = rc->stats[0].blks[0]; |
| 1194 |
|
num_MBs += rc->stats[0].blks[1]; |
| 1195 |
|
num_MBs += rc->stats[0].blks[2]; |
| 1196 |
|
|
| 1197 |
|
/* Minimum for I frames */ |
| 1198 |
|
if(rc->min_length[XVID_TYPE_IVOP-1] > ((num_MBs*22) + 240) / 8) |
| 1199 |
|
rc->min_length[XVID_TYPE_IVOP-1] = ((num_MBs*22) + 240) / 8; |
| 1200 |
|
|
| 1201 |
|
/* Minimum for P/S frames */ |
| 1202 |
|
if(rc->min_length[XVID_TYPE_PVOP-1] > ((num_MBs) + 88) / 8) |
| 1203 |
|
rc->min_length[XVID_TYPE_PVOP-1] = ((num_MBs) + 88) / 8; |
| 1204 |
|
|
| 1205 |
|
/* Minimum for B frames */ |
| 1206 |
|
if(rc->min_length[XVID_TYPE_BVOP-1] > 8) |
| 1207 |
|
rc->min_length[XVID_TYPE_BVOP-1] = 8; |
| 1208 |
|
|
| 1209 |
if (dbytes >= rc->alt_curve_high) { |
/* Perform an initial scale pass. |
| 1210 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev); |
* |
| 1211 |
}else{ |
* If a frame size is scaled underneath our hardcoded minimums, then we |
| 1212 |
switch(rc->param.alt_curve_type) { |
* force the frame size to the minimum, and deduct the original & scaled |
| 1213 |
case XVID_CURVE_SINE : |
* frame length from the original and target total lengths */ |
| 1214 |
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_high_diff))); |
for (i=0; i<rc->num_frames; i++) { |
| 1215 |
break; |
twopass_stat_t * s = &rc->stats[i]; |
| 1216 |
case XVID_CURVE_LINEAR : |
int len; |
|
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) / rc->alt_curve_high_diff); |
|
|
break; |
|
|
case XVID_CURVE_COSINE : |
|
|
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_high_diff)))); |
|
|
} |
|
|
} |
|
|
}else{ |
|
|
if (dbytes <= rc->alt_curve_low) { |
|
|
dbytes2 = dbytes; |
|
|
}else{ |
|
|
switch(rc->param.alt_curve_type) { |
|
|
case XVID_CURVE_SINE : |
|
|
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_low_diff))); |
|
|
break; |
|
|
case XVID_CURVE_LINEAR : |
|
|
dbytes2 = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) / rc->alt_curve_low_diff); |
|
|
break; |
|
|
case XVID_CURVE_COSINE : |
|
|
dbytes2 = dbytes * (rc->alt_curve_mid_qual + rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_low_diff)))); |
|
|
} |
|
|
} |
|
| 1217 |
|
|
| 1218 |
|
/* No need to scale frame length for which a specific quantizer is |
| 1219 |
|
* specified thanks to zones */ |
| 1220 |
|
if (s->zone_mode == XVID_ZONE_QUANT) { |
| 1221 |
|
s->scaled_length = s->length; |
| 1222 |
|
continue; |
| 1223 |
} |
} |
| 1224 |
|
|
| 1225 |
|
/* Compute the scaled length -- only non invariant data length is scaled */ |
| 1226 |
|
len = s->invariant + (int)((double)(s->length-s->invariant) * scaler * s->weight); |
| 1227 |
|
|
| 1228 |
|
/* Compare with the computed minimum */ |
| 1229 |
|
if (len < rc->min_length[s->type-1]) { |
| 1230 |
|
/* This is a 'forced size' frame, set its frame size to the |
| 1231 |
|
* computed minimum */ |
| 1232 |
|
s->scaled_length = rc->min_length[s->type-1]; |
| 1233 |
|
|
| 1234 |
|
/* Remove both scaled and original size from their respective |
| 1235 |
|
* total counters, as we prepare a second pass for 'regular' |
| 1236 |
|
* frames */ |
| 1237 |
|
target -= s->scaled_length; |
| 1238 |
}else{ |
}else{ |
| 1239 |
if (dbytes > rc->avg_length[XVID_TYPE_PVOP-1]) { |
/* Do nothing for now, we'll scale this later */ |
| 1240 |
dbytes2=((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_high / 100.0); |
s->scaled_length = 0; |
|
}else{ |
|
|
dbytes2 = ((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_low / 100.0); |
|
| 1241 |
} |
} |
| 1242 |
} |
} |
| 1243 |
|
|
| 1244 |
if (s->type == XVID_TYPE_BVOP) { |
/* The first pass on data substracted all 'forced size' frames from the |
| 1245 |
dbytes2 *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; |
* total counters. Now, it's possible to scale the 'regular' frames. */ |
|
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; |
|
|
} |
|
|
} |
|
| 1246 |
|
|
| 1247 |
rc->curve_comp_scale = total1 / total2; |
/* Scaling factor for 'regular' frames */ |
| 1248 |
|
scaler = (double)(target - total_invariant) / (double)(rc->tot_weighted); |
| 1249 |
|
|
| 1250 |
if (!rc->param.use_alt_curve) { |
/* Do another pass with the new scaler */ |
| 1251 |
printf("middle frame size for asymmetric curve compression: %i\n", |
for (i=0; i<rc->num_frames; i++) { |
| 1252 |
(int)(rc->avg_length[XVID_TYPE_PVOP-1] * rc->curve_comp_scale)); |
twopass_stat_t * s = &rc->stats[i]; |
| 1253 |
|
|
| 1254 |
|
/* Ignore frame with forced frame sizes */ |
| 1255 |
|
if (s->scaled_length == 0) |
| 1256 |
|
s->scaled_length = s->invariant + (int)((double)(s->length-s->invariant) * scaler * s->weight); |
| 1257 |
} |
} |
| 1258 |
|
|
| 1259 |
if (rc->param.use_alt_curve) { |
/* Job done */ |
| 1260 |
int bonus_bias = rc->param.alt_curve_bonus_bias; |
return; |
| 1261 |
int oldquant = 1; |
} |
| 1262 |
|
|
| 1263 |
if (rc->param.alt_curve_use_auto_bonus_bias) |
/* Apply all user settings to the scaled curve |
| 1264 |
bonus_bias = rc->param.alt_curve_min_rel_qual; |
* This implies: |
| 1265 |
|
* keyframe boosting |
| 1266 |
|
* high/low compression */ |
| 1267 |
|
static void |
| 1268 |
|
scaled_curve_apply_advanced_parameters(rc_2pass2_t * rc) |
| 1269 |
|
{ |
| 1270 |
|
int i; |
| 1271 |
|
int64_t ivop_boost_total; |
| 1272 |
|
|
| 1273 |
rc->alt_curve_curve_bias_bonus = (total1 - total2) * (double)bonus_bias / 100.0 / (double)(rc->num_frames /* - credits_frames */ - rc->num_keyframes); |
/* Reset the rate controller (per frame type) total byte counters */ |
| 1274 |
rc->curve_comp_scale = ((total1 - total2) * (1.0 - (double)bonus_bias / 100.0) + total2) / total2; |
for (i=0; i<3; i++) rc->tot_scaled_length[i] = 0; |
| 1275 |
|
|
| 1276 |
|
/* Compute total bytes for each frame type */ |
| 1277 |
|
for (i=0; i<rc->num_frames;i++) { |
| 1278 |
|
twopass_stat_t *s = &rc->stats[i]; |
| 1279 |
|
rc->tot_scaled_length[s->type-1] += s->scaled_length; |
| 1280 |
|
} |
| 1281 |
|
|
| 1282 |
/* special info for alt curve: bias bonus and quantizer thresholds */ |
/* First we compute the total amount of bits needed, as being described by |
| 1283 |
|
* the scaled distribution. During this pass over the complete stats data, |
| 1284 |
|
* we see how much bits two user settings will get/give from/to p&b frames: |
| 1285 |
|
* - keyframe boosting |
| 1286 |
|
* - keyframe distance penalty */ |
| 1287 |
|
rc->KF_idx = 0; |
| 1288 |
|
ivop_boost_total = 0; |
| 1289 |
|
for (i=0; i<rc->num_frames; i++) { |
| 1290 |
|
twopass_stat_t * s = &rc->stats[i]; |
| 1291 |
|
|
| 1292 |
printf("avg scaled framesize:%i", (int)rc->avg_length[XVID_TYPE_PVOP-1]); |
/* Some more work is needed for I frames */ |
| 1293 |
printf("bias bonus:%i bytes", (int)rc->alt_curve_curve_bias_bonus); |
if (s->type == XVID_TYPE_IVOP) { |
| 1294 |
|
int ivop_boost; |
| 1295 |
|
|
| 1296 |
for (i=1; i <= (int)(rc->alt_curve_high*2)+1; i++) { |
/* Accumulate bytes needed for keyframe boosting */ |
| 1297 |
double curve_temp, dbytes; |
ivop_boost = s->scaled_length*rc->param.keyframe_boost/100; |
|
int newquant; |
|
| 1298 |
|
|
| 1299 |
dbytes = i; |
#if 0 /* ToDo: decide how to apply kfthresholding */ |
| 1300 |
if (dbytes > rc->avg_length[XVID_TYPE_PVOP-1]) { |
#endif |
| 1301 |
if (dbytes >= rc->alt_curve_high) { |
/* If the frame size drops under the minimum length, then cap ivop_boost */ |
| 1302 |
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev); |
if (ivop_boost + s->scaled_length < rc->min_length[XVID_TYPE_IVOP-1]) |
| 1303 |
}else{ |
ivop_boost = rc->min_length[XVID_TYPE_IVOP-1] - s->scaled_length; |
|
switch(rc->param.alt_curve_type) |
|
|
{ |
|
|
case XVID_CURVE_SINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_high_diff))); |
|
|
break; |
|
|
case XVID_CURVE_LINEAR : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) / rc->alt_curve_high_diff); |
|
|
break; |
|
|
case XVID_CURVE_COSINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_high_diff)))); |
|
|
} |
|
|
} |
|
|
}else{ |
|
|
if (dbytes <= rc->alt_curve_low) { |
|
|
curve_temp = dbytes; |
|
|
}else{ |
|
|
switch(rc->param.alt_curve_type) |
|
|
{ |
|
|
case XVID_CURVE_SINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_low_diff))); |
|
|
break; |
|
|
case XVID_CURVE_LINEAR : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) / rc->alt_curve_low_diff); |
|
|
break; |
|
|
case XVID_CURVE_COSINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual + rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_low_diff)))); |
|
|
} |
|
|
} |
|
|
} |
|
| 1304 |
|
|
| 1305 |
if (rc->movie_curve > 1.0) |
/* Accumulate the ivop boost */ |
| 1306 |
dbytes *= rc->movie_curve; |
ivop_boost_total += ivop_boost; |
| 1307 |
|
|
| 1308 |
newquant = (int)(dbytes * 2.0 / (curve_temp * rc->curve_comp_scale + rc->alt_curve_curve_bias_bonus)); |
/* Don't forget to update the keyframe index */ |
| 1309 |
if (newquant > 1) { |
rc->KF_idx++; |
|
if (newquant != oldquant) { |
|
|
int percent = (int)((i - rc->avg_length[XVID_TYPE_PVOP-1]) * 100.0 / rc->avg_length[XVID_TYPE_PVOP-1]); |
|
|
oldquant = newquant; |
|
|
printf("quant:%i threshold at %i : %i percent", newquant, i, percent); |
|
|
} |
|
| 1310 |
} |
} |
| 1311 |
} |
} |
| 1312 |
|
|
| 1313 |
} |
/* Initialize the IBoost tax ratio for P/S/B frames |
| 1314 |
|
* |
| 1315 |
|
* This ratio has to be applied to p/b/s frames in order to reserve |
| 1316 |
|
* additional bits for keyframes (keyframe boosting) or if too much |
| 1317 |
|
* keyframe distance is applied, bits retrieved from the keyframes. |
| 1318 |
|
* |
| 1319 |
|
* ie pb_length *= rc->pb_iboost_tax_ratio; |
| 1320 |
|
* |
| 1321 |
|
* gives the ideal length of a p/b frame */ |
| 1322 |
|
|
| 1323 |
rc->overflow = 0; |
/* Compute the total length of p/b/s frames (temporary storage into |
| 1324 |
rc->KFoverflow = 0; |
* movie_curve) */ |
| 1325 |
rc->KFoverflow_partial = 0; |
rc->pb_iboost_tax_ratio = (double)rc->tot_scaled_length[XVID_TYPE_PVOP-1]; |
| 1326 |
rc->KF_idx = 1; |
rc->pb_iboost_tax_ratio += (double)rc->tot_scaled_length[XVID_TYPE_BVOP-1]; |
| 1327 |
} |
|
| 1328 |
|
/* Compute the ratio described above |
| 1329 |
|
* taxed_total = sum(0, n, tax*scaled_length) |
| 1330 |
|
* <=> taxed_total = tax.sum(0, n, scaled_length) |
| 1331 |
|
* <=> tax = taxed_total / original_total */ |
| 1332 |
|
rc->pb_iboost_tax_ratio = |
| 1333 |
|
(rc->pb_iboost_tax_ratio - ivop_boost_total) / |
| 1334 |
|
rc->pb_iboost_tax_ratio; |
| 1335 |
|
|
| 1336 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- IFrame boost tax ratio:%.2f\n", |
| 1337 |
|
rc->pb_iboost_tax_ratio); |
| 1338 |
|
|
| 1339 |
|
/* Compute the average size of frames per frame type */ |
| 1340 |
|
for(i=0; i<3; i++) { |
| 1341 |
|
/* Special case for missing type or weird case */ |
| 1342 |
|
if (rc->count[i] == 0 || rc->pb_iboost_tax_ratio == 0) { |
| 1343 |
|
rc->avg_length[i] = 1; |
| 1344 |
|
} else { |
| 1345 |
|
rc->avg_length[i] = rc->tot_scaled_length[i]; |
| 1346 |
|
|
| 1347 |
|
if (i == (XVID_TYPE_IVOP-1)) { |
| 1348 |
|
/* I Frames total has to be added the boost total */ |
| 1349 |
|
rc->avg_length[i] += ivop_boost_total; |
| 1350 |
|
} else { |
| 1351 |
|
/* P/B frames has to taxed */ |
| 1352 |
|
rc->avg_length[i] *= rc->pb_iboost_tax_ratio; |
| 1353 |
|
} |
| 1354 |
|
|
| 1355 |
static int rc_2pass2_create(xvid_plg_create_t * create, rc_2pass2_t ** handle) |
/* Finally compute the average frame size */ |
| 1356 |
{ |
rc->avg_length[i] /= (double)rc->count[i]; |
| 1357 |
xvid_plugin_2pass2_t * param = (xvid_plugin_2pass2_t *)create->param; |
} |
| 1358 |
rc_2pass2_t * rc; |
} |
| 1359 |
|
|
| 1360 |
rc = malloc(sizeof(rc_2pass2_t)); |
/* Assymetric curve compression */ |
| 1361 |
if (rc == NULL) |
if (rc->param.curve_compression_high || rc->param.curve_compression_low) { |
| 1362 |
return XVID_ERR_MEMORY; |
double symetric_total; |
| 1363 |
|
double assymetric_delta_total; |
| 1364 |
|
|
| 1365 |
rc->param = *param; |
/* Like I frame boosting, assymetric curve compression modifies the total |
| 1366 |
|
* amount of needed bits, we must compute the ratio so we can prescale |
| 1367 |
|
lengths */ |
| 1368 |
|
symetric_total = 0; |
| 1369 |
|
assymetric_delta_total = 0; |
| 1370 |
|
for (i=0; i<rc->num_frames; i++) { |
| 1371 |
|
double assymetric_delta; |
| 1372 |
|
double dbytes; |
| 1373 |
|
twopass_stat_t * s = &rc->stats[i]; |
| 1374 |
|
|
| 1375 |
if (rc->param.keyframe_boost <= 0) rc->param.keyframe_boost = 0; |
/* I Frames are not concerned by assymetric scaling */ |
| 1376 |
if (rc->param.payback_method <= 0) rc->param.payback_method = XVID_PAYBACK_PROP; |
if (s->type == XVID_TYPE_IVOP) |
| 1377 |
if (rc->param.bitrate_payback_delay <= 0) rc->param.bitrate_payback_delay = 250; |
continue; |
|
if (rc->param.curve_compression_high <= 0) rc->param.curve_compression_high = 0; |
|
|
if (rc->param.curve_compression_low <= 0) rc->param.curve_compression_low = 0; |
|
|
if (rc->param.max_overflow_improvement <= 0) rc->param.max_overflow_improvement = 60; |
|
|
if (rc->param.max_overflow_degradation <= 0) rc->param.max_overflow_degradation = 60; |
|
|
|
|
|
if (rc->param.use_alt_curve <= 0) rc->param.use_alt_curve = 0; |
|
|
if (rc->param.alt_curve_high_dist <= 0) rc->param.alt_curve_high_dist = 500; |
|
|
if (rc->param.alt_curve_low_dist <= 0) rc->param.alt_curve_low_dist = 90; |
|
|
if (rc->param.alt_curve_use_auto <= 0) rc->param.alt_curve_use_auto = 1; |
|
|
if (rc->param.alt_curve_auto_str <= 0) rc->param.alt_curve_auto_str = 30; |
|
|
if (rc->param.alt_curve_type <= 0) rc->param.alt_curve_type = XVID_CURVE_LINEAR; |
|
|
if (rc->param.alt_curve_min_rel_qual <= 0) rc->param.alt_curve_min_rel_qual = 50; |
|
|
if (rc->param.alt_curve_use_auto_bonus_bias <= 0) rc->param.alt_curve_use_auto_bonus_bias = 1; |
|
|
if (rc->param.alt_curve_bonus_bias <= 0) rc->param.alt_curve_bonus_bias = 50; |
|
|
|
|
|
if (rc->param.kftreshold <= 0) rc->param.kftreshold = 10; |
|
|
if (rc->param.kfreduction <= 0) rc->param.kfreduction = 20; |
|
|
if (rc->param.min_key_interval <= 0) rc->param.min_key_interval = 300; |
|
| 1378 |
|
|
| 1379 |
if (!det_stats_length(rc, param->filename)){ |
/* During the real run, we would have to apply the iboost tax */ |
| 1380 |
DPRINTF(DPRINTF_RC,"fopen %s failed\n", param->filename); |
dbytes = s->scaled_length * rc->pb_iboost_tax_ratio; |
|
free(rc); |
|
|
return XVID_ERR_FAIL; |
|
|
} |
|
| 1381 |
|
|
| 1382 |
if ((rc->stats = malloc(rc->num_frames * sizeof(stat_t))) == NULL) { |
/* Update the symmetric curve compression total */ |
| 1383 |
free(rc); |
symetric_total += dbytes; |
|
return XVID_ERR_MEMORY; |
|
|
} |
|
| 1384 |
|
|
| 1385 |
/* XXX: do we need an addition location */ |
/* Apply assymetric curve compression */ |
| 1386 |
if ((rc->keyframe_locations = malloc((rc->num_keyframes + 1) * sizeof(int))) == NULL) { |
if (dbytes > rc->avg_length[s->type-1]) |
| 1387 |
free(rc->stats); |
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * (double)rc->param.curve_compression_high / 100.0f; |
| 1388 |
free(rc); |
else |
| 1389 |
return XVID_ERR_MEMORY; |
assymetric_delta = (rc->avg_length[s->type-1] - dbytes) * (double)rc->param.curve_compression_low / 100.0f; |
|
} |
|
| 1390 |
|
|
| 1391 |
if (!load_stats(rc, param->filename)) { |
/* Cap to the minimum frame size if needed */ |
| 1392 |
DPRINTF(DPRINTF_RC,"fopen %s failed\n", param->filename); |
if (dbytes + assymetric_delta < rc->min_length[s->type-1]) |
| 1393 |
free(rc->keyframe_locations); |
assymetric_delta = rc->min_length[s->type-1] - dbytes; |
|
free(rc->stats); |
|
|
free(rc); |
|
|
return XVID_ERR_FAIL; |
|
|
} |
|
| 1394 |
|
|
| 1395 |
/* pre-process our stats */ |
/* Accumulate after assymetric curve compression */ |
| 1396 |
|
assymetric_delta_total += assymetric_delta; |
| 1397 |
|
} |
| 1398 |
|
|
| 1399 |
{ |
/* Compute the tax that all p/b frames have to pay in order to respect the |
| 1400 |
if (rc->num_frames < create->fbase/create->fincr) { |
* bit distribution changes that the assymetric compression curve imposes |
| 1401 |
rc->target = rc->param.bitrate / 8; /* one second */ |
* We want assymetric_total = sum(0, n-1, tax.scaled_length) |
| 1402 |
|
* ie assymetric_total = ratio.sum(0, n-1, scaled_length) |
| 1403 |
|
* ratio = assymetric_total / symmetric_total */ |
| 1404 |
|
rc->assymetric_tax_ratio = ((double)symetric_total - (double)assymetric_delta_total) / (double)symetric_total; |
| 1405 |
}else{ |
}else{ |
| 1406 |
rc->target = (rc->param.bitrate * rc->num_frames * create->fincr) / (create->fbase * 8); |
rc->assymetric_tax_ratio = 1.0f; |
| 1407 |
} |
} |
| 1408 |
|
|
| 1409 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- Assymetric tax ratio:%.2f\n", rc->assymetric_tax_ratio); |
| 1410 |
|
|
| 1411 |
rc->target -= rc->num_frames*24; /* avi file header */ |
/* Last bits that need to be reset */ |
| 1412 |
|
rc->overflow = 0; |
| 1413 |
|
rc->KFoverflow = 0; |
| 1414 |
|
rc->KFoverflow_partial = 0; |
| 1415 |
|
rc->KF_idx = 0; |
| 1416 |
|
rc->desired_total = 0; |
| 1417 |
|
rc->real_total = 0; |
| 1418 |
|
|
| 1419 |
|
/* Job done */ |
| 1420 |
|
return; |
| 1421 |
} |
} |
| 1422 |
|
|
| 1423 |
|
|
| 1424 |
pre_process0(rc); |
#ifdef VBV |
|
if (rc->param.bitrate) { |
|
|
internal_scale(rc); |
|
|
} |
|
|
pre_process1(rc);pre_process1(rc);pre_process1(rc); |
|
| 1425 |
|
|
| 1426 |
*handle = rc; |
/***************************************************************************** |
| 1427 |
return(0); |
* VBV compliancy check and scale |
| 1428 |
} |
* MPEG-4 standard specifies certain restrictions for bitrate/framesize in VBR |
| 1429 |
|
* to enable playback on devices with limited readspeed and memory (and which |
| 1430 |
|
* aren't...) |
| 1431 |
|
* |
| 1432 |
|
* DivX profiles have 2 criteria: VBV as in MPEG standard |
| 1433 |
|
* a limit on peak bitrate for any 3 seconds |
| 1434 |
|
* |
| 1435 |
|
* But if VBV is fulfilled, peakrate is automatically fulfilled in any profile |
| 1436 |
|
* define so far, so we check for it (for completeness) but correct only VBV |
| 1437 |
|
* |
| 1438 |
|
*****************************************************************************/ |
| 1439 |
|
|
| 1440 |
|
#define VBV_COMPLIANT 0 |
| 1441 |
|
#define VBV_UNDERFLOW 1 /* video buffer runs empty */ |
| 1442 |
|
#define VBV_OVERFLOW 2 /* doesn't exist for VBR encoding */ |
| 1443 |
|
#define VBV_PEAKRATE 4 /* peak bitrate (within 3s) violated */ |
| 1444 |
|
|
| 1445 |
static int rc_2pass2_destroy(rc_2pass2_t * rc, xvid_plg_destroy_t * destroy) |
static int check_curve_for_vbv_compliancy(rc_2pass2_t * rc, const float fps) |
| 1446 |
{ |
{ |
| 1447 |
free(rc->keyframe_locations); |
/* We do all calculations in float, for higher accuracy, and bytes for convenience |
|
free(rc->stats); |
|
|
free(rc); |
|
|
return(0); |
|
|
} |
|
| 1448 |
|
|
| 1449 |
|
typical values from DivX Home Theater profile: |
| 1450 |
|
vbvsize= 384*1024 (384kB), vbvinitial= 288*1024 (75% fill) |
| 1451 |
|
maxrate= 4000000 (4MBps), peakrate= 10000000 (10MBps) |
| 1452 |
|
|
| 1453 |
|
PAL: offset3s = 75 (3 seconds of 25fps) |
| 1454 |
|
NTSC: offset3s = 90 (3 seconds of 29.97fps) or 72 (3 seconds of 23.976fps) |
| 1455 |
|
*/ |
| 1456 |
|
|
| 1457 |
static int rc_2pass2_before(rc_2pass2_t * rc, xvid_plg_data_t * data) |
const float vbvsize = (float)rc->param.vbvsize/8.f; |
| 1458 |
{ |
float vbvfill = (float)rc->param.vbvinitial/8.f; |
|
stat_t * s = &rc->stats[data->frame_num]; |
|
|
int overflow; |
|
|
int desired; |
|
|
double dbytes; |
|
|
double curve_temp; |
|
|
int capped_to_max_framesize = 0; |
|
| 1459 |
|
|
| 1460 |
if (data->frame_num >= rc->num_frames) { |
const float maxrate = (float)rc->param.vbv_maxrate; |
| 1461 |
/* insufficent stats data */ |
const float peakrate = (float)rc->param.vbv_peakrate; |
| 1462 |
return 0; |
const float r0 = (int)(maxrate/fps+0.5)/8.f; |
|
} |
|
| 1463 |
|
|
| 1464 |
overflow = rc->overflow / 8; /* XXX: why by 8 */ |
int bytes3s = 0; |
| 1465 |
|
int offset3s = (int)(3.f*fps+0.5); |
| 1466 |
|
|
| 1467 |
if (s->type == XVID_TYPE_IVOP) { /* XXX: why */ |
int i; |
| 1468 |
overflow = 0; |
for (i=0; i<rc->num_frames; i++) { |
| 1469 |
} |
/* DivX 3s peak bitrate check */ |
| 1470 |
|
|
| 1471 |
desired = s->scaled_length; |
bytes3s += rc->stats[i].scaled_length; |
| 1472 |
|
if (i>=offset3s) |
| 1473 |
|
bytes3s -= rc->stats[i-offset3s].scaled_length; |
| 1474 |
|
|
| 1475 |
dbytes = desired; |
if (8.f*bytes3s > 3*peakrate) |
| 1476 |
if (s->type == XVID_TYPE_IVOP) { |
return VBV_PEAKRATE; |
|
dbytes += desired * rc->param.keyframe_boost / 100; |
|
|
} |
|
|
dbytes /= rc->movie_curve; |
|
| 1477 |
|
|
| 1478 |
if (s->type == XVID_TYPE_BVOP) { |
/* update vbv fill level */ |
|
dbytes *= rc->avg_length[XVID_TYPE_PVOP-1] / rc->avg_length[XVID_TYPE_BVOP-1]; |
|
|
} |
|
| 1479 |
|
|
| 1480 |
if (rc->param.payback_method == XVID_PAYBACK_BIAS) { |
vbvfill += r0 - rc->stats[i].scaled_length; |
|
desired =(int)(rc->curve_comp_error / rc->param.bitrate_payback_delay); |
|
|
}else{ |
|
|
//printf("desired=%i, dbytes=%i\n", desired,dbytes); |
|
|
desired = (int)(rc->curve_comp_error * dbytes / |
|
|
rc->avg_length[XVID_TYPE_PVOP-1] / rc->param.bitrate_payback_delay); |
|
|
//printf("desired=%i\n", desired); |
|
| 1481 |
|
|
| 1482 |
if (labs(desired) > fabs(rc->curve_comp_error)) { |
/* this check is _NOT_ an "overflow"! only reading from disk stops then */ |
| 1483 |
desired = (int)rc->curve_comp_error; |
if (vbvfill > vbvsize) |
| 1484 |
} |
vbvfill = vbvsize; |
| 1485 |
|
|
| 1486 |
|
/* but THIS would be an underflow. report it! */ |
| 1487 |
|
if (vbvfill < 0) |
| 1488 |
|
return VBV_UNDERFLOW; |
| 1489 |
} |
} |
| 1490 |
|
|
| 1491 |
rc->curve_comp_error -= desired; |
return VBV_COMPLIANT; |
| 1492 |
|
} |
| 1493 |
|
/* idea: min(vbvfill) could be stored to print "minimum buffer fill" */ |
| 1494 |
|
|
|
/* alt curve */ |
|
| 1495 |
|
|
|
curve_temp = 0; /* XXX: warning */ |
|
| 1496 |
|
|
| 1497 |
if (rc->param.use_alt_curve) { |
static int scale_curve_for_vbv_compliancy(rc_2pass2_t * rc, const float fps) |
| 1498 |
if (s->type != XVID_TYPE_IVOP) { |
{ |
| 1499 |
if (dbytes > rc->avg_length[XVID_TYPE_PVOP-1]) { |
/* correct any VBV violations. Peak bitrate violations disappears |
| 1500 |
if (dbytes >= rc->alt_curve_high) { |
by this automatically |
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev); |
|
|
}else{ |
|
|
switch(rc->param.alt_curve_type) { |
|
|
case XVID_CURVE_SINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_high_diff))); |
|
|
break; |
|
|
case XVID_CURVE_LINEAR : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) / rc->alt_curve_high_diff); |
|
|
break; |
|
|
case XVID_CURVE_COSINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_high_diff)))); |
|
|
} |
|
|
} |
|
|
}else{ |
|
|
if (dbytes <= rc->alt_curve_low){ |
|
|
curve_temp = dbytes; |
|
|
}else{ |
|
|
switch(rc->param.alt_curve_type) { |
|
|
case XVID_CURVE_SINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * sin(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_low_diff))); |
|
|
break; |
|
|
case XVID_CURVE_LINEAR : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual - rc->alt_curve_qual_dev * (dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) / rc->alt_curve_low_diff); |
|
|
break; |
|
|
case XVID_CURVE_COSINE : |
|
|
curve_temp = dbytes * (rc->alt_curve_mid_qual + rc->alt_curve_qual_dev * (1.0 - cos(DEG2RAD * ((dbytes - rc->avg_length[XVID_TYPE_PVOP-1]) * 90.0 / rc->alt_curve_low_diff)))); |
|
|
} |
|
|
} |
|
|
} |
|
|
if (s->type == XVID_TYPE_BVOP) |
|
|
curve_temp *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; |
|
| 1501 |
|
|
| 1502 |
curve_temp = curve_temp * rc->curve_comp_scale + rc->alt_curve_curve_bias_bonus; |
This implementation follows |
| 1503 |
|
|
| 1504 |
desired += ((int)curve_temp); |
Westerink, Rajagopalan, Gonzales "Two-pass MPEG-2 variable-bitrate encoding" |
| 1505 |
rc->curve_comp_error += curve_temp - (int)curve_temp; |
IBM J. RES. DEVELOP. VOL 43, No. 4, July 1999, p.471--488 |
|
}else{ |
|
|
if (s->type == XVID_TYPE_BVOP) |
|
|
dbytes *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; |
|
| 1506 |
|
|
| 1507 |
desired += ((int)dbytes); |
Thanks, guys! This paper rocks!!! |
| 1508 |
rc->curve_comp_error += dbytes - (int)dbytes; |
*/ |
|
} |
|
| 1509 |
|
|
| 1510 |
}else if ((rc->param.curve_compression_high + rc->param.curve_compression_low) && s->type != XVID_TYPE_IVOP) { |
/* |
| 1511 |
|
For each scene of len N, we have to check up to N^2 possible buffer fills. |
| 1512 |
|
This works well with MPEG-2 where N==12 or so, but for MPEG-4 it's a |
| 1513 |
|
little slow... |
| 1514 |
|
*/ |
| 1515 |
|
const float vbvsize = (float)rc->param.vbvsize/8.f; |
| 1516 |
|
const float vbvinitial = (float)rc->param.vbvinitial/8.f; |
| 1517 |
|
|
| 1518 |
curve_temp = rc->curve_comp_scale; |
const float maxrate = 0.9*rc->param.vbv_maxrate; |
| 1519 |
if (dbytes > rc->avg_length[XVID_TYPE_PVOP-1]) { |
const float vbvlow = 0.10f*vbvsize; |
| 1520 |
curve_temp *= ((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_high / 100.0); |
const float r0 = (int)(maxrate/fps+0.5)/8.f; |
| 1521 |
} else { |
|
| 1522 |
curve_temp *= ((double)dbytes + (rc->avg_length[XVID_TYPE_PVOP-1] - dbytes) * rc->param.curve_compression_low / 100.0); |
int i,k,l,n,violation = 0; |
| 1523 |
|
float *scenefactor; |
| 1524 |
|
int *scenestart; |
| 1525 |
|
int *scenelength; |
| 1526 |
|
|
| 1527 |
|
/* first step: determine how many "scenes" there are and store their boundaries |
| 1528 |
|
we could get all this from existing keyframe_positions, somehow, but there we |
| 1529 |
|
don't have a min_scenelength, and it's no big deal to get it again. */ |
| 1530 |
|
|
| 1531 |
|
const int min_scenelength = 50; |
| 1532 |
|
int num_scenes = 0; |
| 1533 |
|
int last_scene = -999; |
| 1534 |
|
for (i=0; i<rc->num_frames; i++) { |
| 1535 |
|
if ( (rc->stats[i].type == XVID_TYPE_IVOP) && (i-last_scene>min_scenelength) ) |
| 1536 |
|
{ |
| 1537 |
|
last_scene = i; |
| 1538 |
|
num_scenes++; |
| 1539 |
} |
} |
|
|
|
|
if (s->type == XVID_TYPE_BVOP){ |
|
|
curve_temp *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; |
|
| 1540 |
} |
} |
| 1541 |
|
|
| 1542 |
desired += (int)curve_temp; |
scenefactor = (float*)malloc( num_scenes*sizeof(float) ); |
| 1543 |
rc->curve_comp_error += curve_temp - (int)curve_temp; |
scenestart = (int*)malloc( num_scenes*sizeof(int) ); |
| 1544 |
}else{ |
scenelength = (int*)malloc( num_scenes*sizeof(int) ); |
|
if (s->type == XVID_TYPE_BVOP){ |
|
|
dbytes *= rc->avg_length[XVID_TYPE_BVOP-1] / rc->avg_length[XVID_TYPE_PVOP-1]; |
|
|
} |
|
| 1545 |
|
|
| 1546 |
desired += (int)dbytes; |
if ((!scenefactor) || (!scenestart) || (!scenelength) ) |
| 1547 |
rc->curve_comp_error += dbytes - (int)dbytes; |
{ |
| 1548 |
|
free(scenefactor); |
| 1549 |
|
free(scenestart); |
| 1550 |
|
free(scenelength); |
| 1551 |
|
/* remember: free(0) is valid and does exactly nothing. */ |
| 1552 |
|
return -1; |
| 1553 |
} |
} |
| 1554 |
|
|
| 1555 |
if (desired > s->length){ |
/* count again and safe the length/position */ |
| 1556 |
rc->curve_comp_error += desired - s->length; |
|
| 1557 |
desired = s->length; |
num_scenes = 0; |
| 1558 |
}else{ |
last_scene = -999; |
| 1559 |
if (desired < rc->min_length[s->type-1]) { |
for (i=0; i<rc->num_frames; i++) { |
| 1560 |
if (s->type == XVID_TYPE_IVOP){ |
if ( (rc->stats[i].type == XVID_TYPE_IVOP) && (i-last_scene>min_scenelength) ) |
| 1561 |
rc->curve_comp_error -= rc->min_length[XVID_TYPE_IVOP-1] - desired; |
{ |
| 1562 |
} |
if (num_scenes>0) |
| 1563 |
desired = rc->min_length[s->type-1]; |
scenelength[num_scenes-1]=i-last_scene; |
| 1564 |
|
scenestart[num_scenes]=i; |
| 1565 |
|
num_scenes++; |
| 1566 |
|
last_scene = i; |
| 1567 |
} |
} |
| 1568 |
} |
} |
| 1569 |
|
scenelength[num_scenes-1]=i-last_scene; |
| 1570 |
|
|
| 1571 |
s->desired_length = desired; |
/* second step: check for each scene, how much we can scale its frames up or down |
| 1572 |
|
such that the VBV restriction is just fulfilled |
| 1573 |
|
*/ |
|
/* 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 */ |
|
| 1574 |
|
|
|
if (s->type == XVID_TYPE_IVOP) { |
|
|
int KFdistance = rc->keyframe_locations[rc->KF_idx] - rc->keyframe_locations[rc->KF_idx - 1]; |
|
| 1575 |
|
|
| 1576 |
if (KFdistance < rc->param.kftreshold) { |
#define R(k,n) (((n)+1-(k))*r0) /* how much enters the buffer between frame k and n */ |
| 1577 |
|
for (l=0; l<num_scenes;l++) |
| 1578 |
|
{ |
| 1579 |
|
const int start = scenestart[l]; |
| 1580 |
|
const int length = scenelength[l]; |
| 1581 |
|
twopass_stat_t * frames = &rc->stats[start]; |
| 1582 |
|
|
| 1583 |
KFdistance = KFdistance - rc->param.min_key_interval; |
float S0n,Skn; |
| 1584 |
|
float f,minf = 99999.f; |
| 1585 |
|
|
| 1586 |
if (KFdistance >= 0) { |
S0n=0.; |
| 1587 |
int KF_min_size; |
for (n=0;n<=length-1;n++) |
| 1588 |
|
{ |
| 1589 |
|
S0n += frames[n].scaled_length; |
| 1590 |
|
|
| 1591 |
KF_min_size = desired * (100 - rc->param.kfreduction) / 100; |
k=0; |
| 1592 |
if (KF_min_size < 1) |
Skn = S0n; |
| 1593 |
KF_min_size = 1; |
f = (R(k,n-1) + (vbvinitial - vbvlow)) / Skn; |
| 1594 |
|
if (f < minf) |
| 1595 |
|
minf = f; |
| 1596 |
|
|
| 1597 |
desired = KF_min_size + (desired - KF_min_size) * KFdistance / |
for (k=1;k<=n;k++) |
| 1598 |
(rc->param.kftreshold - rc->param.min_key_interval); |
{ |
| 1599 |
|
Skn -= frames[k].scaled_length; |
| 1600 |
|
|
| 1601 |
if (desired < 1) |
f = (R(k,n-1) + (vbvsize - vbvlow)) / Skn; |
| 1602 |
desired = 1; |
if (f < minf) |
| 1603 |
} |
minf = f; |
| 1604 |
} |
} |
| 1605 |
} |
} |
| 1606 |
|
|
| 1607 |
overflow = (int)((double)overflow * desired / rc->avg_length[XVID_TYPE_PVOP-1]); |
/* special case: at the end, fill buffer up to vbvinitial again |
| 1608 |
|
TODO: Allow other values for buffer fill between scenes |
| 1609 |
|
e.g. if n=N is smallest f-value, then check for better value */ |
| 1610 |
|
|
| 1611 |
// Foxer: reign in overflow with huge frames |
n=length; |
| 1612 |
if (labs(overflow) > labs(rc->overflow)) { |
k=0; |
| 1613 |
overflow = rc->overflow; |
Skn = S0n; |
| 1614 |
} |
f = R(k,n-1)/Skn; |
| 1615 |
|
if (f < minf) |
| 1616 |
|
minf = f; |
| 1617 |
|
|
| 1618 |
// Foxer: make sure overflow doesn't run away |
for (k=1;k<=n-1;k++) |
| 1619 |
|
{ |
| 1620 |
|
Skn -= frames[k].scaled_length; |
| 1621 |
|
|
| 1622 |
if (overflow > desired * rc->param.max_overflow_improvement / 100) { |
f = (R(k,n-1) + (vbvinitial - vbvlow)) / Skn; |
| 1623 |
desired += (overflow <= desired) ? desired * rc->param.max_overflow_improvement / 100 : |
if (f < minf) |
| 1624 |
overflow * rc->param.max_overflow_improvement / 100; |
minf = f; |
|
}else if (overflow < desired * rc->param.max_overflow_degradation / -100){ |
|
|
desired += desired * rc->param.max_overflow_degradation / -100; |
|
|
}else{ |
|
|
desired += overflow; |
|
| 1625 |
} |
} |
| 1626 |
|
|
| 1627 |
if (desired > rc->max_length) { |
#ifdef VBV_DEBUG |
| 1628 |
capped_to_max_framesize = 1; |
printf("Scene %d (Frames %d-%d): VBVfactor %f\n", l, start, start+length-1 , minf); |
| 1629 |
desired = rc->max_length; |
#endif |
|
} |
|
| 1630 |
|
|
| 1631 |
// make sure to not scale below the minimum framesize |
scenefactor[l] = minf; |
|
if (desired < rc->min_length[s->type-1]) { |
|
|
desired = rc->min_length[s->type-1]; |
|
| 1632 |
} |
} |
| 1633 |
|
#undef R |
| 1634 |
|
|
| 1635 |
|
/* last step: now we know of any scene how much it can be scaled up or down without |
| 1636 |
|
violating VBV. Next, distribute bits from the evil scenes to the good ones */ |
| 1637 |
|
|
| 1638 |
// very 'simple' quant<->filesize relationship |
do |
| 1639 |
data->quant= (s->quant * s->length) / desired; |
{ |
| 1640 |
|
float S_red = 0.f; /* how much to redistribute */ |
| 1641 |
|
float S_elig = 0.f; /* sum of bit for those scenes you can still swallow something*/ |
| 1642 |
|
int l; |
| 1643 |
|
|
| 1644 |
if (data->quant < 1) { |
for (l=0;l<num_scenes;l++) /* check how much is wrong */ |
|
data->quant = 1; |
|
|
} else if (data->quant > 31) { |
|
|
data->quant = 31; |
|
|
} |
|
|
else if (s->type != XVID_TYPE_IVOP) |
|
| 1645 |
{ |
{ |
| 1646 |
// Foxer: aid desired quantizer precision by accumulating decision error |
const int start = scenestart[l]; |
| 1647 |
if (s->type== XVID_TYPE_BVOP) { |
const int length = scenelength[l]; |
| 1648 |
rc->bquant_error[data->quant] += ((double)(s->quant * s->length) / desired) - data->quant; |
twopass_stat_t * frames = &rc->stats[start]; |
| 1649 |
|
|
| 1650 |
if (rc->bquant_error[data->quant] >= 1.0) { |
if (scenefactor[l] == 1.) /* exactly 1 means "don't touch this anymore!" */ |
| 1651 |
rc->bquant_error[data->quant] -= 1.0; |
continue; |
|
data->quant++; |
|
|
} |
|
|
}else{ |
|
|
rc->pquant_error[data->quant] += ((double)(s->quant * s->length) / desired) - data->quant; |
|
| 1652 |
|
|
| 1653 |
if (rc->pquant_error[data->quant] >= 1.0) { |
if (scenefactor[l] > 1.) /* within limits */ |
| 1654 |
rc->pquant_error[data->quant] -= 1.0; |
{ |
| 1655 |
++data->quant; |
for (n= 0; n < length; n++) |
| 1656 |
|
S_elig += frames[n].scaled_length; |
| 1657 |
} |
} |
| 1658 |
|
else /* underflowing segment */ |
| 1659 |
|
{ |
| 1660 |
|
for (n= 0; n < length; n++) |
| 1661 |
|
{ |
| 1662 |
|
float newbytes = (float)frames[n].scaled_length * scenefactor[l]; |
| 1663 |
|
S_red += (float)frames[n].scaled_length - (float)newbytes; |
| 1664 |
|
frames[n].scaled_length =(int)newbytes; |
| 1665 |
|
} |
| 1666 |
|
scenefactor[l] = 1.f; |
| 1667 |
} |
} |
| 1668 |
} |
} |
| 1669 |
|
|
| 1670 |
/* cap to min/max quant */ |
if (S_red < 1.f) /* no more underflows */ |
| 1671 |
|
break; |
| 1672 |
|
|
| 1673 |
if (data->quant < data->min_quant[s->type-1]) { |
if (S_elig < 1.f) |
| 1674 |
data->quant = data->min_quant[s->type-1]; |
{ |
| 1675 |
}else if (data->quant > data->max_quant[s->type-1]) { |
#ifdef VBV_DEBUG |
| 1676 |
data->quant = data->max_quant[s->type-1]; |
fprintf(stderr,"Everything underflowing. \n"); |
| 1677 |
} |
#endif |
| 1678 |
|
free(scenefactor); |
| 1679 |
|
free(scenestart); |
| 1680 |
|
free(scenelength); |
| 1681 |
|
return -2; |
| 1682 |
|
} |
| 1683 |
|
|
| 1684 |
|
const float f_red = (1.f + S_red/S_elig); |
| 1685 |
|
|
| 1686 |
|
#ifdef VBV_DEBUG |
| 1687 |
|
printf("Moving %.0f kB to avoid buffer underflow, correction factor: %.5f\n",S_red/1024.f,f_red); |
| 1688 |
|
#endif |
| 1689 |
|
|
| 1690 |
/* subsequent p/b frame quants can only be +- 2 */ |
violation=0; |
| 1691 |
if (s->type != XVID_TYPE_IVOP && rc->last_quant[s->type-1] && capped_to_max_framesize == 0) { |
for (l=0; l<num_scenes; l++) /* scale remaining scenes up to meet total size */ |
| 1692 |
|
{ |
| 1693 |
|
const int start = scenestart[l]; |
| 1694 |
|
const int length = scenelength[l]; |
| 1695 |
|
twopass_stat_t * frames = &rc->stats[start]; |
| 1696 |
|
|
| 1697 |
if (data->quant > rc->last_quant[s->type-1] + 2) { |
if (scenefactor[l] == 1.) |
| 1698 |
data->quant = rc->last_quant[s->type-1] + 2; |
continue; |
| 1699 |
DPRINTF(DPRINTF_RC, "p/b-frame quantizer prevented from rising too steeply"); |
|
| 1700 |
} |
/* there shouldn't be any segments with factor<1 left, so all the rest is >1 */ |
| 1701 |
if (data->quant < rc->last_quant[s->type-1] - 2) { |
|
| 1702 |
data->quant = rc->last_quant[s->type-1] - 2; |
for (n= 0; n < length; n++) |
| 1703 |
DPRINTF(DPRINTF_RC, "p/b-frame quantizer prevented from falling too steeply"); |
{ |
| 1704 |
} |
frames[n].scaled_length = (int)(frames[n].scaled_length * f_red + 0.5); |
| 1705 |
} |
} |
| 1706 |
|
|
| 1707 |
if (capped_to_max_framesize == 0) { |
scenefactor[l] /= f_red; |
| 1708 |
rc->last_quant[s->type-1] = data->quant; |
if (scenefactor[l] < 1.f) |
| 1709 |
|
violation=1; |
| 1710 |
} |
} |
| 1711 |
|
|
| 1712 |
|
} while (violation); |
| 1713 |
|
|
| 1714 |
|
free(scenefactor); |
| 1715 |
|
free(scenestart); |
| 1716 |
|
free(scenelength); |
| 1717 |
return 0; |
return 0; |
| 1718 |
} |
} |
| 1719 |
|
|
| 1720 |
|
|
| 1721 |
|
#endif |
| 1722 |
|
|
|
static int rc_2pass2_after(rc_2pass2_t * rc, xvid_plg_data_t * data) |
|
|
{ |
|
|
stat_t * s = &rc->stats[data->frame_num]; |
|
| 1723 |
|
|
| 1724 |
if (data->frame_num >= rc->num_frames) { |
/***************************************************************************** |
| 1725 |
/* insufficent stats data */ |
* Still more low level stuff (nothing to do with stats treatment) |
| 1726 |
return 0; |
****************************************************************************/ |
|
} |
|
| 1727 |
|
|
| 1728 |
rc->quant_count[data->quant]++; |
/* This function returns an allocated string containing a complete line read |
| 1729 |
|
* from the file starting at the current position */ |
| 1730 |
|
static char * |
| 1731 |
|
readline(FILE *f) |
| 1732 |
|
{ |
| 1733 |
|
char *buffer = NULL; |
| 1734 |
|
int buffer_size = 0; |
| 1735 |
|
int pos = 0; |
| 1736 |
|
|
| 1737 |
if (data->type == XVID_TYPE_IVOP) { |
do { |
| 1738 |
int kfdiff = (rc->keyframe_locations[rc->KF_idx] - rc->keyframe_locations[rc->KF_idx - 1]); |
int c; |
| 1739 |
|
|
| 1740 |
rc->overflow += rc->KFoverflow; |
/* Read a character from the stream */ |
| 1741 |
rc->KFoverflow = s->desired_length - data->length; |
c = fgetc(f); |
| 1742 |
|
|
| 1743 |
if (kfdiff > 1) { // non-consecutive keyframes |
/* Is that EOF or new line ? */ |
| 1744 |
rc->KFoverflow_partial = rc->KFoverflow / (kfdiff - 1); |
if(c == EOF || c == '\n') |
| 1745 |
}else{ // consecutive keyframes |
break; |
| 1746 |
rc->overflow += rc->KFoverflow; |
|
| 1747 |
rc->KFoverflow = 0; |
/* Do we have to update buffer ? */ |
| 1748 |
rc->KFoverflow_partial = 0; |
if(pos >= buffer_size - 1) { |
| 1749 |
} |
buffer_size += BUF_SZ; |
| 1750 |
rc->KF_idx++; |
buffer = (char*)realloc(buffer, buffer_size); |
| 1751 |
}else{ |
if (buffer == NULL) |
| 1752 |
// distribute part of the keyframe overflow |
return(NULL); |
|
rc->overflow += s->desired_length - data->length + rc->KFoverflow_partial; |
|
|
rc->KFoverflow -= rc->KFoverflow_partial; |
|
| 1753 |
} |
} |
| 1754 |
|
|
| 1755 |
printf("[%i] quant:%i stats1:%i scaled:%i actual:%i overflow:%i\n", |
buffer[pos] = c; |
| 1756 |
data->frame_num, |
pos++; |
| 1757 |
data->quant, |
} while(1); |
|
s->length, |
|
|
s->scaled_length, |
|
|
data->length, |
|
|
rc->overflow); |
|
| 1758 |
|
|
| 1759 |
return(0); |
/* Read \n or EOF */ |
| 1760 |
|
if (buffer == NULL) { |
| 1761 |
|
/* EOF, so we reached the end of the file, return NULL */ |
| 1762 |
|
if(feof(f)) |
| 1763 |
|
return(NULL); |
| 1764 |
|
|
| 1765 |
|
/* Just an empty line with just a newline, allocate a 1 byte buffer to |
| 1766 |
|
* store a zero length string */ |
| 1767 |
|
buffer = (char*)malloc(1); |
| 1768 |
|
if(buffer == NULL) |
| 1769 |
|
return(NULL); |
| 1770 |
} |
} |
| 1771 |
|
|
| 1772 |
|
/* Zero terminated string */ |
| 1773 |
|
buffer[pos] = '\0'; |
| 1774 |
|
|
| 1775 |
|
return(buffer); |
| 1776 |
|
} |
| 1777 |
|
|
| 1778 |
int xvid_plugin_2pass2(void * handle, int opt, void * param1, void * param2) |
/* This function returns a pointer to the first non space char in the given |
| 1779 |
|
* string */ |
| 1780 |
|
static char * |
| 1781 |
|
skipspaces(char *string) |
| 1782 |
{ |
{ |
| 1783 |
switch(opt) |
const char spaces[] = |
| 1784 |
{ |
{ |
| 1785 |
case XVID_PLG_INFO : |
' ','\t','\0' |
| 1786 |
return 0; |
}; |
| 1787 |
|
const char *spacechar = spaces; |
| 1788 |
|
|
| 1789 |
|
if (string == NULL) return(NULL); |
| 1790 |
|
|
| 1791 |
|
while (*string != '\0') { |
| 1792 |
|
/* Test against space chars */ |
| 1793 |
|
while (*spacechar != '\0') { |
| 1794 |
|
if (*string == *spacechar) { |
| 1795 |
|
string++; |
| 1796 |
|
spacechar = spaces; |
| 1797 |
|
break; |
| 1798 |
|
} |
| 1799 |
|
spacechar++; |
| 1800 |
|
} |
| 1801 |
|
|
| 1802 |
case XVID_PLG_CREATE : |
/* No space char */ |
| 1803 |
return rc_2pass2_create((xvid_plg_create_t*)param1, param2); |
if (*spacechar == '\0') return(string); |
| 1804 |
|
} |
| 1805 |
|
|
| 1806 |
case XVID_PLG_DESTROY : |
return(string); |
| 1807 |
return rc_2pass2_destroy((rc_2pass2_t*)handle, (xvid_plg_destroy_t*)param1); |
} |
| 1808 |
|
|
| 1809 |
case XVID_PLG_BEFORE : |
/* This function returns a boolean that tells if the string is only a |
| 1810 |
return rc_2pass2_before((rc_2pass2_t*)handle, (xvid_plg_data_t*)param1); |
* comment */ |
| 1811 |
|
static int |
| 1812 |
|
iscomment(char *string) |
| 1813 |
|
{ |
| 1814 |
|
const char comments[] = |
| 1815 |
|
{ |
| 1816 |
|
'#',';', '%', '\0' |
| 1817 |
|
}; |
| 1818 |
|
const char *cmtchar = comments; |
| 1819 |
|
int iscomment = 0; |
| 1820 |
|
|
| 1821 |
|
if (string == NULL) return(1); |
| 1822 |
|
|
| 1823 |
|
string = skipspaces(string); |
| 1824 |
|
|
| 1825 |
|
while(*cmtchar != '\0') { |
| 1826 |
|
if(*string == *cmtchar) { |
| 1827 |
|
iscomment = 1; |
| 1828 |
|
break; |
| 1829 |
|
} |
| 1830 |
|
cmtchar++; |
| 1831 |
|
} |
| 1832 |
|
|
| 1833 |
case XVID_PLG_AFTER : |
return(iscomment); |
|
return rc_2pass2_after((rc_2pass2_t*)handle, (xvid_plg_data_t*)param1); |
|
| 1834 |
} |
} |
| 1835 |
|
|
| 1836 |
return XVID_ERR_FAIL; |
#if 0 |
| 1837 |
|
static void |
| 1838 |
|
stats_print(rc_2pass2_t * rc) |
| 1839 |
|
{ |
| 1840 |
|
int i; |
| 1841 |
|
const char frame_type[4] = { 'i', 'p', 'b', 's'}; |
| 1842 |
|
|
| 1843 |
|
for (i=0; i<rc->num_frames; i++) { |
| 1844 |
|
twopass_stat_t *s = &rc->stats[i]; |
| 1845 |
|
DPRINTF(XVID_DEBUG_RC, "[xvid rc] -- frame:%d type:%c quant:%d stats:%d scaled:%d desired:%d actual:%d overflow(%c):%.2f\n", |
| 1846 |
|
i, frame_type[s->type-1], -1, s->length, s->scaled_length, |
| 1847 |
|
s->desired_length, -1, frame_type[s->type-1], -1.0f); |
| 1848 |
|
} |
| 1849 |
} |
} |
| 1850 |
|
#endif |
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