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2713 lines
96 KiB
C
2713 lines
96 KiB
C
/********************************************************************
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* *
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* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. *
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* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS *
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* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE *
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* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. *
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* *
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* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2009 *
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* by the Xiph.Org Foundation http://www.xiph.org/ *
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* *
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********************************************************************
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function: mode selection code
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last mod: $Id$
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********************************************************************/
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#include <limits.h>
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#include <string.h>
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#include "encint.h"
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#include "modedec.h"
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#if defined(OC_COLLECT_METRICS)
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# include "collect.c"
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#endif
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typedef struct oc_rd_metric oc_rd_metric;
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typedef struct oc_mode_choice oc_mode_choice;
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/*There are 8 possible schemes used to encode macro block modes.
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Schemes 0-6 use a maximally-skewed Huffman code to code each of the modes.
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The same set of Huffman codes is used for each of these 7 schemes, but the
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mode assigned to each codeword varies.
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Scheme 0 writes a custom mapping from codeword to MB mode to the bitstream,
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while schemes 1-6 have a fixed mapping.
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Scheme 7 just encodes each mode directly in 3 bits.*/
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/*The mode orderings for the various mode coding schemes.
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Scheme 0 uses a custom alphabet, which is not stored in this table.
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This is the inverse of the equivalent table OC_MODE_ALPHABETS in the
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decoder.*/
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static const unsigned char OC_MODE_RANKS[7][OC_NMODES]={
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/*Last MV dominates.*/
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/*L P M N I G GM 4*/
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{3,4,2,0,1,5,6,7},
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/*L P N M I G GM 4*/
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{2,4,3,0,1,5,6,7},
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/*L M P N I G GM 4*/
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{3,4,1,0,2,5,6,7},
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/*L M N P I G GM 4*/
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{2,4,1,0,3,5,6,7},
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/*No MV dominates.*/
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/*N L P M I G GM 4*/
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{0,4,3,1,2,5,6,7},
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/*N G L P M I GM 4*/
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{0,5,4,2,3,1,6,7},
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/*Default ordering.*/
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/*N I M L P G GM 4*/
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{0,1,2,3,4,5,6,7}
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};
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/*Initialize the mode scheme chooser.
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This need only be called once per encoder.*/
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void oc_mode_scheme_chooser_init(oc_mode_scheme_chooser *_chooser){
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int si;
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_chooser->mode_ranks[0]=_chooser->scheme0_ranks;
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for(si=1;si<8;si++)_chooser->mode_ranks[si]=OC_MODE_RANKS[si-1];
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}
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/*Reset the mode scheme chooser.
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This needs to be called once for each frame, including the first.*/
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static void oc_mode_scheme_chooser_reset(oc_mode_scheme_chooser *_chooser){
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int si;
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memset(_chooser->mode_counts,0,OC_NMODES*sizeof(*_chooser->mode_counts));
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/*Scheme 0 starts with 24 bits to store the mode list in.*/
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_chooser->scheme_bits[0]=24;
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memset(_chooser->scheme_bits+1,0,7*sizeof(*_chooser->scheme_bits));
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for(si=0;si<8;si++){
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/*Scheme 7 should always start first, and scheme 0 should always start
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last.*/
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_chooser->scheme_list[si]=7-si;
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_chooser->scheme0_list[si]=_chooser->scheme0_ranks[si]=si;
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}
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}
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/*Return the cost of coding _mb_mode in the specified scheme.*/
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static int oc_mode_scheme_chooser_scheme_mb_cost(
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const oc_mode_scheme_chooser *_chooser,int _scheme,int _mb_mode){
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int codebook;
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int ri;
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codebook=_scheme+1>>3;
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/*For any scheme except 0, we can just use the bit cost of the mode's rank
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in that scheme.*/
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ri=_chooser->mode_ranks[_scheme][_mb_mode];
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if(_scheme==0){
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int mc;
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/*For scheme 0, incrementing the mode count could potentially change the
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mode's rank.
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Find the index where the mode would be moved to in the optimal list,
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and use its bit cost instead of the one for the mode's current
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position in the list.*/
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/*We don't actually reorder the list; this is for computing opportunity
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cost, not an update.*/
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mc=_chooser->mode_counts[_mb_mode];
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while(ri>0&&mc>=_chooser->mode_counts[_chooser->scheme0_list[ri-1]])ri--;
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}
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return OC_MODE_BITS[codebook][ri];
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}
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/*This is the real purpose of this data structure: not actually selecting a
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mode scheme, but estimating the cost of coding a given mode given all the
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modes selected so far.
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This is done via opportunity cost: the cost is defined as the number of bits
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required to encode all the modes selected so far including the current one
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using the best possible scheme, minus the number of bits required to encode
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all the modes selected so far not including the current one using the best
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possible scheme.
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The computational expense of doing this probably makes it overkill.
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Just be happy we take a greedy approach instead of trying to solve the
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global mode-selection problem (which is NP-hard).
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_mb_mode: The mode to determine the cost of.
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Return: The number of bits required to code this mode.*/
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static int oc_mode_scheme_chooser_cost(oc_mode_scheme_chooser *_chooser,
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int _mb_mode){
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int scheme0;
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int scheme1;
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int best_bits;
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int mode_bits;
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int si;
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int scheme0_bits;
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int scheme1_bits;
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scheme0=_chooser->scheme_list[0];
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scheme1=_chooser->scheme_list[1];
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scheme0_bits=_chooser->scheme_bits[scheme0];
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scheme1_bits=_chooser->scheme_bits[scheme1];
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mode_bits=oc_mode_scheme_chooser_scheme_mb_cost(_chooser,scheme0,_mb_mode);
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/*Typical case: If the difference between the best scheme and the next best
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is greater than 6 bits, then adding just one mode cannot change which
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scheme we use.*/
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if(scheme1_bits-scheme0_bits>6)return mode_bits;
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/*Otherwise, check to see if adding this mode selects a different scheme as
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the best.*/
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si=1;
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best_bits=scheme0_bits+mode_bits;
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do{
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int cur_bits;
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cur_bits=scheme1_bits+
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oc_mode_scheme_chooser_scheme_mb_cost(_chooser,scheme1,_mb_mode);
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if(cur_bits<best_bits)best_bits=cur_bits;
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if(++si>=8)break;
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scheme1=_chooser->scheme_list[si];
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scheme1_bits=_chooser->scheme_bits[scheme1];
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}
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while(scheme1_bits-scheme0_bits<=6);
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return best_bits-scheme0_bits;
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}
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/*Incrementally update the mode counts and per-scheme bit counts and re-order
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the scheme lists once a mode has been selected.
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_mb_mode: The mode that was chosen.*/
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static void oc_mode_scheme_chooser_update(oc_mode_scheme_chooser *_chooser,
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int _mb_mode){
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int ri;
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int si;
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_chooser->mode_counts[_mb_mode]++;
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/*Re-order the scheme0 mode list if necessary.*/
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for(ri=_chooser->scheme0_ranks[_mb_mode];ri>0;ri--){
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int pmode;
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pmode=_chooser->scheme0_list[ri-1];
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if(_chooser->mode_counts[pmode]>=_chooser->mode_counts[_mb_mode])break;
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/*Reorder the mode ranking.*/
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_chooser->scheme0_ranks[pmode]++;
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_chooser->scheme0_list[ri]=pmode;
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}
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_chooser->scheme0_ranks[_mb_mode]=ri;
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_chooser->scheme0_list[ri]=_mb_mode;
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/*Now add the bit cost for the mode to each scheme.*/
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for(si=0;si<8;si++){
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_chooser->scheme_bits[si]+=
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OC_MODE_BITS[si+1>>3][_chooser->mode_ranks[si][_mb_mode]];
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}
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/*Finally, re-order the list of schemes.*/
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for(si=1;si<8;si++){
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int sj;
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int scheme0;
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int bits0;
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sj=si;
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scheme0=_chooser->scheme_list[si];
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bits0=_chooser->scheme_bits[scheme0];
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do{
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int scheme1;
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scheme1=_chooser->scheme_list[sj-1];
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if(bits0>=_chooser->scheme_bits[scheme1])break;
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_chooser->scheme_list[sj]=scheme1;
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}
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while(--sj>0);
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_chooser->scheme_list[sj]=scheme0;
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}
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}
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/*The number of bits required to encode a super block run.
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_run_count: The desired run count; must be positive and less than 4130.*/
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static int oc_sb_run_bits(int _run_count){
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int i;
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for(i=0;_run_count>=OC_SB_RUN_VAL_MIN[i+1];i++);
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return OC_SB_RUN_CODE_NBITS[i];
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}
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/*The number of bits required to encode a block run.
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_run_count: The desired run count; must be positive and less than 30.*/
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static int oc_block_run_bits(int _run_count){
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return OC_BLOCK_RUN_CODE_NBITS[_run_count-1];
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}
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static void oc_fr_state_init(oc_fr_state *_fr){
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_fr->bits=0;
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_fr->sb_partial_count=0;
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_fr->sb_full_count=0;
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_fr->b_coded_count_prev=0;
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_fr->b_coded_count=0;
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_fr->b_count=0;
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_fr->sb_prefer_partial=0;
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_fr->sb_bits=0;
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_fr->sb_partial=-1;
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_fr->sb_full=-1;
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_fr->b_coded_prev=-1;
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_fr->b_coded=-1;
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}
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static int oc_fr_state_sb_cost(const oc_fr_state *_fr,
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int _sb_partial,int _sb_full){
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int bits;
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int sb_partial_count;
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int sb_full_count;
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bits=0;
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sb_partial_count=_fr->sb_partial_count;
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/*Extend the sb_partial run, or start a new one.*/
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if(_fr->sb_partial==_sb_partial){
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if(sb_partial_count>=4129){
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bits++;
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sb_partial_count=0;
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}
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else bits-=oc_sb_run_bits(sb_partial_count);
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}
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else sb_partial_count=0;
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bits+=oc_sb_run_bits(++sb_partial_count);
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if(!_sb_partial){
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/*Extend the sb_full run, or start a new one.*/
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sb_full_count=_fr->sb_full_count;
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if(_fr->sb_full==_sb_full){
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if(sb_full_count>=4129){
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bits++;
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sb_full_count=0;
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}
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else bits-=oc_sb_run_bits(sb_full_count);
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}
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else sb_full_count=0;
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bits+=oc_sb_run_bits(++sb_full_count);
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}
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return bits;
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}
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static void oc_fr_state_advance_sb(oc_fr_state *_fr,
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int _sb_partial,int _sb_full){
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int sb_partial_count;
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int sb_full_count;
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sb_partial_count=_fr->sb_partial_count;
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if(_fr->sb_partial!=_sb_partial||sb_partial_count>=4129)sb_partial_count=0;
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sb_partial_count++;
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if(!_sb_partial){
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sb_full_count=_fr->sb_full_count;
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if(_fr->sb_full!=_sb_full||sb_full_count>=4129)sb_full_count=0;
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sb_full_count++;
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_fr->sb_full_count=sb_full_count;
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_fr->sb_full=_sb_full;
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/*Roll back the partial block state.*/
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_fr->b_coded=_fr->b_coded_prev;
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_fr->b_coded_count=_fr->b_coded_count_prev;
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}
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else{
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/*Commit back the partial block state.*/
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_fr->b_coded_prev=_fr->b_coded;
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_fr->b_coded_count_prev=_fr->b_coded_count;
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}
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_fr->sb_partial_count=sb_partial_count;
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_fr->sb_partial=_sb_partial;
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_fr->b_count=0;
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_fr->sb_prefer_partial=0;
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_fr->sb_bits=0;
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}
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/*Commit the state of the current super block and advance to the next.*/
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static void oc_fr_state_flush_sb(oc_fr_state *_fr){
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int sb_partial;
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int sb_full;
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int b_coded_count;
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int b_count;
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b_count=_fr->b_count;
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b_coded_count=_fr->b_coded_count;
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sb_full=_fr->b_coded;
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sb_partial=b_coded_count<b_count;
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if(!sb_partial){
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/*If the super block is fully coded/uncoded...*/
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if(_fr->sb_prefer_partial){
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/*So far coding this super block as partial was cheaper anyway.*/
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if(b_coded_count>15||_fr->b_coded_prev<0){
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int sb_bits;
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/*If the block run is too long, this will limit how far it can be
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extended into the next partial super block.
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If we need to extend it farther, we don't want to have to roll all
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the way back here (since there could be many full SBs between now
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and then), so we disallow this.
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Similarly, if this is the start of a stripe, we don't know how the
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length of the outstanding block run from the previous stripe.*/
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sb_bits=oc_fr_state_sb_cost(_fr,sb_partial,sb_full);
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_fr->bits+=sb_bits-_fr->sb_bits;
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_fr->sb_bits=sb_bits;
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}
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else sb_partial=1;
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}
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}
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oc_fr_state_advance_sb(_fr,sb_partial,sb_full);
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}
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static void oc_fr_state_advance_block(oc_fr_state *_fr,int _b_coded){
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ptrdiff_t bits;
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int sb_bits;
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int b_coded_count;
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int b_count;
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int sb_prefer_partial;
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sb_bits=_fr->sb_bits;
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bits=_fr->bits-sb_bits;
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b_count=_fr->b_count;
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b_coded_count=_fr->b_coded_count;
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sb_prefer_partial=_fr->sb_prefer_partial;
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if(b_coded_count>=b_count){
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int sb_partial_bits;
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/*This super block is currently fully coded/uncoded.*/
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if(b_count<=0){
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/*This is the first block in this SB.*/
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b_count=1;
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/*Check to see whether it's cheaper to code it partially or fully.*/
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if(_fr->b_coded==_b_coded){
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sb_partial_bits=-oc_block_run_bits(b_coded_count);
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sb_partial_bits+=oc_block_run_bits(++b_coded_count);
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}
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else{
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b_coded_count=1;
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sb_partial_bits=2;
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}
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sb_partial_bits+=oc_fr_state_sb_cost(_fr,1,_b_coded);
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sb_bits=oc_fr_state_sb_cost(_fr,0,_b_coded);
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sb_prefer_partial=sb_partial_bits<sb_bits;
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sb_bits^=(sb_partial_bits^sb_bits)&-sb_prefer_partial;
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}
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else if(_fr->b_coded==_b_coded){
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b_coded_count++;
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if(++b_count<16){
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if(sb_prefer_partial){
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/*Check to see if it's cheaper to code it fully.*/
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sb_partial_bits=sb_bits;
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sb_partial_bits+=oc_block_run_bits(b_coded_count);
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if(b_coded_count>0){
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sb_partial_bits-=oc_block_run_bits(b_coded_count-1);
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}
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sb_bits=oc_fr_state_sb_cost(_fr,0,_b_coded);
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sb_prefer_partial=sb_partial_bits<sb_bits;
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sb_bits^=(sb_partial_bits^sb_bits)&-sb_prefer_partial;
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}
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/*There's no need to check the converse (whether it's cheaper to code
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this SB partially if we were coding it fully), since the cost to
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code a SB partially can only increase as we add more blocks, whereas
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the cost to code it fully stays constant.*/
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}
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else{
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/*If we get to the end and this SB is still full, then force it to be
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coded full.
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Otherwise we might not be able to extend the block run far enough
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into the next partial SB.*/
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if(sb_prefer_partial){
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sb_prefer_partial=0;
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sb_bits=oc_fr_state_sb_cost(_fr,0,_b_coded);
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}
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}
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}
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else{
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/*This SB was full, but now must be made partial.*/
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if(!sb_prefer_partial){
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sb_bits=oc_block_run_bits(b_coded_count);
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if(b_coded_count>b_count){
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sb_bits-=oc_block_run_bits(b_coded_count-b_count);
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}
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sb_bits+=oc_fr_state_sb_cost(_fr,1,_b_coded);
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}
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b_count++;
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b_coded_count=1;
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sb_prefer_partial=1;
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sb_bits+=2;
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}
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}
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else{
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b_count++;
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if(_fr->b_coded==_b_coded)sb_bits-=oc_block_run_bits(b_coded_count);
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else b_coded_count=0;
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sb_bits+=oc_block_run_bits(++b_coded_count);
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}
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_fr->bits=bits+sb_bits;
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_fr->b_coded_count=b_coded_count;
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_fr->b_coded=_b_coded;
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_fr->b_count=b_count;
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_fr->sb_prefer_partial=sb_prefer_partial;
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_fr->sb_bits=sb_bits;
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}
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static void oc_fr_skip_block(oc_fr_state *_fr){
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oc_fr_state_advance_block(_fr,0);
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}
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static void oc_fr_code_block(oc_fr_state *_fr){
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oc_fr_state_advance_block(_fr,1);
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}
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static int oc_fr_cost1(const oc_fr_state *_fr){
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oc_fr_state tmp;
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ptrdiff_t bits;
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*&tmp=*_fr;
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oc_fr_skip_block(&tmp);
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bits=tmp.bits;
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*&tmp=*_fr;
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oc_fr_code_block(&tmp);
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return (int)(tmp.bits-bits);
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}
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static int oc_fr_cost4(const oc_fr_state *_pre,const oc_fr_state *_post){
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oc_fr_state tmp;
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*&tmp=*_pre;
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oc_fr_skip_block(&tmp);
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oc_fr_skip_block(&tmp);
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oc_fr_skip_block(&tmp);
|
|
oc_fr_skip_block(&tmp);
|
|
return (int)(_post->bits-tmp.bits);
|
|
}
|
|
|
|
|
|
|
|
static void oc_qii_state_init(oc_qii_state *_qs){
|
|
_qs->bits=0;
|
|
_qs->qi01_count=0;
|
|
_qs->qi01=-1;
|
|
_qs->qi12_count=0;
|
|
_qs->qi12=-1;
|
|
}
|
|
|
|
|
|
static void oc_qii_state_advance(oc_qii_state *_qd,
|
|
const oc_qii_state *_qs,int _qii){
|
|
ptrdiff_t bits;
|
|
int qi01;
|
|
int qi01_count;
|
|
int qi12;
|
|
int qi12_count;
|
|
bits=_qs->bits;
|
|
qi01=_qii+1>>1;
|
|
qi01_count=_qs->qi01_count;
|
|
if(qi01==_qs->qi01){
|
|
if(qi01_count>=4129){
|
|
bits++;
|
|
qi01_count=0;
|
|
}
|
|
else bits-=oc_sb_run_bits(qi01_count);
|
|
}
|
|
else qi01_count=0;
|
|
qi01_count++;
|
|
bits+=oc_sb_run_bits(qi01_count);
|
|
qi12_count=_qs->qi12_count;
|
|
if(_qii){
|
|
qi12=_qii>>1;
|
|
if(qi12==_qs->qi12){
|
|
if(qi12_count>=4129){
|
|
bits++;
|
|
qi12_count=0;
|
|
}
|
|
else bits-=oc_sb_run_bits(qi12_count);
|
|
}
|
|
else qi12_count=0;
|
|
qi12_count++;
|
|
bits+=oc_sb_run_bits(qi12_count);
|
|
}
|
|
else qi12=_qs->qi12;
|
|
_qd->bits=bits;
|
|
_qd->qi01=qi01;
|
|
_qd->qi01_count=qi01_count;
|
|
_qd->qi12=qi12;
|
|
_qd->qi12_count=qi12_count;
|
|
}
|
|
|
|
|
|
|
|
static void oc_enc_pipeline_init(oc_enc_ctx *_enc,oc_enc_pipeline_state *_pipe){
|
|
ptrdiff_t *coded_fragis;
|
|
unsigned mcu_nvsbs;
|
|
ptrdiff_t mcu_nfrags;
|
|
int flimit;
|
|
int hdec;
|
|
int vdec;
|
|
int pli;
|
|
int nqis;
|
|
int qii;
|
|
int qi0;
|
|
int qti;
|
|
/*Initialize the per-plane coded block flag trackers.
|
|
These are used for bit-estimation purposes only; the real flag bits span
|
|
all three planes, so we can't compute them in parallel.*/
|
|
for(pli=0;pli<3;pli++)oc_fr_state_init(_pipe->fr+pli);
|
|
for(pli=0;pli<3;pli++)oc_qii_state_init(_pipe->qs+pli);
|
|
/*Set up the per-plane skip SSD storage pointers.*/
|
|
mcu_nvsbs=_enc->mcu_nvsbs;
|
|
mcu_nfrags=mcu_nvsbs*_enc->state.fplanes[0].nhsbs*16;
|
|
hdec=!(_enc->state.info.pixel_fmt&1);
|
|
vdec=!(_enc->state.info.pixel_fmt&2);
|
|
_pipe->skip_ssd[0]=_enc->mcu_skip_ssd;
|
|
_pipe->skip_ssd[1]=_pipe->skip_ssd[0]+mcu_nfrags;
|
|
_pipe->skip_ssd[2]=_pipe->skip_ssd[1]+(mcu_nfrags>>hdec+vdec);
|
|
/*Set up per-plane pointers to the coded and uncoded fragments lists.
|
|
Unlike the decoder, each planes' coded and uncoded fragment list is kept
|
|
separate during the analysis stage; we only make the coded list for all
|
|
three planes contiguous right before the final packet is output
|
|
(destroying the uncoded lists, which are no longer needed).*/
|
|
coded_fragis=_enc->state.coded_fragis;
|
|
for(pli=0;pli<3;pli++){
|
|
_pipe->coded_fragis[pli]=coded_fragis;
|
|
coded_fragis+=_enc->state.fplanes[pli].nfrags;
|
|
_pipe->uncoded_fragis[pli]=coded_fragis;
|
|
}
|
|
memset(_pipe->ncoded_fragis,0,sizeof(_pipe->ncoded_fragis));
|
|
memset(_pipe->nuncoded_fragis,0,sizeof(_pipe->nuncoded_fragis));
|
|
/*Set up condensed quantizer tables.*/
|
|
qi0=_enc->state.qis[0];
|
|
nqis=_enc->state.nqis;
|
|
for(pli=0;pli<3;pli++){
|
|
for(qii=0;qii<nqis;qii++){
|
|
int qi;
|
|
qi=_enc->state.qis[qii];
|
|
for(qti=0;qti<2;qti++){
|
|
/*Set the DC coefficient in the dequantization table.*/
|
|
_enc->state.dequant_tables[qi][pli][qti][0]=
|
|
_enc->dequant_dc[qi0][pli][qti];
|
|
_enc->dequant[pli][qii][qti]=_enc->state.dequant_tables[qi][pli][qti];
|
|
/*Copy over the quantization table.*/
|
|
memcpy(_enc->enquant[pli][qii][qti],_enc->enquant_tables[qi][pli][qti],
|
|
_enc->opt_data.enquant_table_size);
|
|
}
|
|
}
|
|
}
|
|
/*Fix up the DC coefficients in the quantization tables.*/
|
|
oc_enc_enquant_table_fixup(_enc,_enc->enquant,nqis);
|
|
/*Initialize the tokenization state.*/
|
|
for(pli=0;pli<3;pli++){
|
|
_pipe->ndct_tokens1[pli]=0;
|
|
_pipe->eob_run1[pli]=0;
|
|
}
|
|
/*Initialize the bounding value array for the loop filter.*/
|
|
flimit=_enc->state.loop_filter_limits[_enc->state.qis[0]];
|
|
_pipe->loop_filter=flimit!=0;
|
|
if(flimit!=0)oc_loop_filter_init(&_enc->state,_pipe->bounding_values,flimit);
|
|
/*Clear the temporary DCT scratch space.*/
|
|
memset(_pipe->dct_data,0,sizeof(_pipe->dct_data));
|
|
}
|
|
|
|
/*Sets the current MCU stripe to super block row _sby.
|
|
Return: A non-zero value if this was the last MCU.*/
|
|
static int oc_enc_pipeline_set_stripe(oc_enc_ctx *_enc,
|
|
oc_enc_pipeline_state *_pipe,int _sby){
|
|
const oc_fragment_plane *fplane;
|
|
unsigned mcu_nvsbs;
|
|
int sby_end;
|
|
int notdone;
|
|
int vdec;
|
|
int pli;
|
|
mcu_nvsbs=_enc->mcu_nvsbs;
|
|
sby_end=_enc->state.fplanes[0].nvsbs;
|
|
notdone=_sby+mcu_nvsbs<sby_end;
|
|
if(notdone)sby_end=_sby+mcu_nvsbs;
|
|
vdec=0;
|
|
for(pli=0;pli<3;pli++){
|
|
fplane=_enc->state.fplanes+pli;
|
|
_pipe->sbi0[pli]=fplane->sboffset+(_sby>>vdec)*fplane->nhsbs;
|
|
_pipe->fragy0[pli]=_sby<<2-vdec;
|
|
_pipe->froffset[pli]=fplane->froffset
|
|
+_pipe->fragy0[pli]*(ptrdiff_t)fplane->nhfrags;
|
|
if(notdone){
|
|
_pipe->sbi_end[pli]=fplane->sboffset+(sby_end>>vdec)*fplane->nhsbs;
|
|
_pipe->fragy_end[pli]=sby_end<<2-vdec;
|
|
}
|
|
else{
|
|
_pipe->sbi_end[pli]=fplane->sboffset+fplane->nsbs;
|
|
_pipe->fragy_end[pli]=fplane->nvfrags;
|
|
}
|
|
vdec=!(_enc->state.info.pixel_fmt&2);
|
|
}
|
|
return notdone;
|
|
}
|
|
|
|
static void oc_enc_pipeline_finish_mcu_plane(oc_enc_ctx *_enc,
|
|
oc_enc_pipeline_state *_pipe,int _pli,int _sdelay,int _edelay){
|
|
/*Copy over all the uncoded fragments from this plane and advance the uncoded
|
|
fragment list.*/
|
|
if(_pipe->nuncoded_fragis[_pli]>0){
|
|
_pipe->uncoded_fragis[_pli]-=_pipe->nuncoded_fragis[_pli];
|
|
oc_frag_copy_list(&_enc->state,
|
|
_enc->state.ref_frame_data[OC_FRAME_SELF],
|
|
_enc->state.ref_frame_data[OC_FRAME_PREV],
|
|
_enc->state.ref_ystride[_pli],_pipe->uncoded_fragis[_pli],
|
|
_pipe->nuncoded_fragis[_pli],_enc->state.frag_buf_offs);
|
|
_pipe->nuncoded_fragis[_pli]=0;
|
|
}
|
|
/*Perform DC prediction.*/
|
|
oc_enc_pred_dc_frag_rows(_enc,_pli,
|
|
_pipe->fragy0[_pli],_pipe->fragy_end[_pli]);
|
|
/*Finish DC tokenization.*/
|
|
oc_enc_tokenize_dc_frag_list(_enc,_pli,
|
|
_pipe->coded_fragis[_pli],_pipe->ncoded_fragis[_pli],
|
|
_pipe->ndct_tokens1[_pli],_pipe->eob_run1[_pli]);
|
|
_pipe->ndct_tokens1[_pli]=_enc->ndct_tokens[_pli][1];
|
|
_pipe->eob_run1[_pli]=_enc->eob_run[_pli][1];
|
|
/*And advance the coded fragment list.*/
|
|
_enc->state.ncoded_fragis[_pli]+=_pipe->ncoded_fragis[_pli];
|
|
_pipe->coded_fragis[_pli]+=_pipe->ncoded_fragis[_pli];
|
|
_pipe->ncoded_fragis[_pli]=0;
|
|
/*Apply the loop filter if necessary.*/
|
|
if(_pipe->loop_filter){
|
|
oc_state_loop_filter_frag_rows(&_enc->state,
|
|
_pipe->bounding_values,OC_FRAME_SELF,_pli,
|
|
_pipe->fragy0[_pli]-_sdelay,_pipe->fragy_end[_pli]-_edelay);
|
|
}
|
|
else _sdelay=_edelay=0;
|
|
/*To fill borders, we have an additional two pixel delay, since a fragment
|
|
in the next row could filter its top edge, using two pixels from a
|
|
fragment in this row.
|
|
But there's no reason to delay a full fragment between the two.*/
|
|
oc_state_borders_fill_rows(&_enc->state,
|
|
_enc->state.ref_frame_idx[OC_FRAME_SELF],_pli,
|
|
(_pipe->fragy0[_pli]-_sdelay<<3)-(_sdelay<<1),
|
|
(_pipe->fragy_end[_pli]-_edelay<<3)-(_edelay<<1));
|
|
}
|
|
|
|
|
|
|
|
/*Cost information about the coded blocks in a MB.*/
|
|
struct oc_rd_metric{
|
|
int uncoded_ac_ssd;
|
|
int coded_ac_ssd;
|
|
int ac_bits;
|
|
int dc_flag;
|
|
};
|
|
|
|
|
|
|
|
static int oc_enc_block_transform_quantize(oc_enc_ctx *_enc,
|
|
oc_enc_pipeline_state *_pipe,int _pli,ptrdiff_t _fragi,
|
|
unsigned _rd_scale,unsigned _rd_iscale,oc_rd_metric *_mo,
|
|
oc_fr_state *_fr,oc_token_checkpoint **_stack){
|
|
ogg_int16_t *data;
|
|
ogg_int16_t *dct;
|
|
ogg_int16_t *idct;
|
|
oc_qii_state qs;
|
|
const ogg_uint16_t *dequant;
|
|
ogg_uint16_t dequant_dc;
|
|
ptrdiff_t frag_offs;
|
|
int ystride;
|
|
const unsigned char *src;
|
|
const unsigned char *ref;
|
|
unsigned char *dst;
|
|
int nonzero;
|
|
unsigned uncoded_ssd;
|
|
unsigned coded_ssd;
|
|
oc_token_checkpoint *checkpoint;
|
|
oc_fragment *frags;
|
|
int mb_mode;
|
|
int refi;
|
|
int mv_offs[2];
|
|
int nmv_offs;
|
|
int ac_bits;
|
|
int borderi;
|
|
int nqis;
|
|
int qti;
|
|
int qii;
|
|
int dc;
|
|
nqis=_enc->state.nqis;
|
|
frags=_enc->state.frags;
|
|
frag_offs=_enc->state.frag_buf_offs[_fragi];
|
|
ystride=_enc->state.ref_ystride[_pli];
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO]+frag_offs;
|
|
borderi=frags[_fragi].borderi;
|
|
qii=frags[_fragi].qii;
|
|
data=_enc->pipe.dct_data;
|
|
dct=data+64;
|
|
idct=data+128;
|
|
if(qii&~3){
|
|
#if !defined(OC_COLLECT_METRICS)
|
|
if(_enc->sp_level>=OC_SP_LEVEL_EARLY_SKIP){
|
|
/*Enable early skip detection.*/
|
|
frags[_fragi].coded=0;
|
|
frags[_fragi].refi=OC_FRAME_NONE;
|
|
oc_fr_skip_block(_fr);
|
|
return 0;
|
|
}
|
|
#endif
|
|
/*Try and code this block anyway.*/
|
|
qii&=3;
|
|
}
|
|
refi=frags[_fragi].refi;
|
|
mb_mode=frags[_fragi].mb_mode;
|
|
ref=_enc->state.ref_frame_data[refi]+frag_offs;
|
|
dst=_enc->state.ref_frame_data[OC_FRAME_SELF]+frag_offs;
|
|
/*Motion compensation:*/
|
|
switch(mb_mode){
|
|
case OC_MODE_INTRA:{
|
|
nmv_offs=0;
|
|
oc_enc_frag_sub_128(_enc,data,src,ystride);
|
|
}break;
|
|
case OC_MODE_GOLDEN_NOMV:
|
|
case OC_MODE_INTER_NOMV:{
|
|
nmv_offs=1;
|
|
mv_offs[0]=0;
|
|
oc_enc_frag_sub(_enc,data,src,ref,ystride);
|
|
}break;
|
|
default:{
|
|
const oc_mv *frag_mvs;
|
|
frag_mvs=_enc->state.frag_mvs;
|
|
nmv_offs=oc_state_get_mv_offsets(&_enc->state,mv_offs,
|
|
_pli,frag_mvs[_fragi]);
|
|
if(nmv_offs>1){
|
|
oc_enc_frag_copy2(_enc,dst,
|
|
ref+mv_offs[0],ref+mv_offs[1],ystride);
|
|
oc_enc_frag_sub(_enc,data,src,dst,ystride);
|
|
}
|
|
else oc_enc_frag_sub(_enc,data,src,ref+mv_offs[0],ystride);
|
|
}break;
|
|
}
|
|
#if defined(OC_COLLECT_METRICS)
|
|
{
|
|
unsigned sad;
|
|
unsigned satd;
|
|
switch(nmv_offs){
|
|
case 0:{
|
|
sad=oc_enc_frag_intra_sad(_enc,src,ystride);
|
|
satd=oc_enc_frag_intra_satd(_enc,&dc,src,ystride);
|
|
}break;
|
|
case 1:{
|
|
sad=oc_enc_frag_sad_thresh(_enc,src,ref+mv_offs[0],ystride,UINT_MAX);
|
|
satd=oc_enc_frag_satd(_enc,&dc,src,ref+mv_offs[0],ystride);
|
|
satd+=abs(dc);
|
|
}break;
|
|
default:{
|
|
sad=oc_enc_frag_sad_thresh(_enc,src,dst,ystride,UINT_MAX);
|
|
satd=oc_enc_frag_satd(_enc,&dc,src,dst,ystride);
|
|
satd+=abs(dc);
|
|
}break;
|
|
}
|
|
_enc->frag_sad[_fragi]=sad;
|
|
_enc->frag_satd[_fragi]=satd;
|
|
}
|
|
#endif
|
|
/*Transform:*/
|
|
oc_enc_fdct8x8(_enc,dct,data);
|
|
/*Quantize:*/
|
|
qti=mb_mode!=OC_MODE_INTRA;
|
|
dequant=_enc->dequant[_pli][qii][qti];
|
|
nonzero=oc_enc_quantize(_enc,data,dct,dequant,_enc->enquant[_pli][qii][qti]);
|
|
dc=data[0];
|
|
/*Tokenize.*/
|
|
checkpoint=*_stack;
|
|
if(_enc->sp_level<OC_SP_LEVEL_FAST_ANALYSIS){
|
|
ac_bits=oc_enc_tokenize_ac(_enc,_pli,_fragi,idct,data,dequant,dct,
|
|
nonzero+1,_stack,OC_RD_ISCALE(_enc->lambda,_rd_iscale),qti?0:3);
|
|
}
|
|
else{
|
|
ac_bits=oc_enc_tokenize_ac_fast(_enc,_pli,_fragi,idct,data,dequant,dct,
|
|
nonzero+1,_stack,OC_RD_ISCALE(_enc->lambda,_rd_iscale),qti?0:3);
|
|
}
|
|
/*Reconstruct.
|
|
TODO: nonzero may need to be adjusted after tokenization.*/
|
|
dequant_dc=dequant[0];
|
|
if(nonzero==0){
|
|
ogg_int16_t p;
|
|
int ci;
|
|
int qi01;
|
|
int qi12;
|
|
/*We round this dequant product (and not any of the others) because there's
|
|
no iDCT rounding.*/
|
|
p=(ogg_int16_t)(dc*(ogg_int32_t)dequant_dc+15>>5);
|
|
/*LOOP VECTORIZES.*/
|
|
for(ci=0;ci<64;ci++)data[ci]=p;
|
|
/*We didn't code any AC coefficients, so don't change the quantizer.*/
|
|
qi01=_pipe->qs[_pli].qi01;
|
|
qi12=_pipe->qs[_pli].qi12;
|
|
if(qi01>0)qii=1+qi12;
|
|
else if(qi01>=0)qii=0;
|
|
}
|
|
else{
|
|
idct[0]=dc*dequant_dc;
|
|
/*Note: This clears idct[] back to zero for the next block.*/
|
|
oc_idct8x8(&_enc->state,data,idct,nonzero+1);
|
|
}
|
|
frags[_fragi].qii=qii;
|
|
if(nqis>1){
|
|
oc_qii_state_advance(&qs,_pipe->qs+_pli,qii);
|
|
ac_bits+=qs.bits-_pipe->qs[_pli].bits;
|
|
}
|
|
if(!qti)oc_enc_frag_recon_intra(_enc,dst,ystride,data);
|
|
else{
|
|
oc_enc_frag_recon_inter(_enc,dst,
|
|
nmv_offs==1?ref+mv_offs[0]:dst,ystride,data);
|
|
}
|
|
/*If _fr is NULL, then this is an INTRA frame, and we can't skip blocks.*/
|
|
#if !defined(OC_COLLECT_METRICS)
|
|
if(_fr!=NULL)
|
|
#endif
|
|
{
|
|
/*In retrospect, should we have skipped this block?*/
|
|
if(borderi<0){
|
|
coded_ssd=oc_enc_frag_ssd(_enc,src,dst,ystride);
|
|
}
|
|
else{
|
|
coded_ssd=oc_enc_frag_border_ssd(_enc,src,dst,ystride,
|
|
_enc->state.borders[borderi].mask);
|
|
}
|
|
/*Scale to match DCT domain.*/
|
|
coded_ssd<<=4;
|
|
#if defined(OC_COLLECT_METRICS)
|
|
_enc->frag_ssd[_fragi]=coded_ssd;
|
|
}
|
|
if(_fr!=NULL){
|
|
#endif
|
|
coded_ssd=OC_RD_SCALE(coded_ssd,_rd_scale);
|
|
uncoded_ssd=_pipe->skip_ssd[_pli][_fragi-_pipe->froffset[_pli]];
|
|
if(uncoded_ssd<UINT_MAX&&
|
|
/*Don't allow luma blocks to be skipped in 4MV mode when VP3 compatibility
|
|
is enabled.*/
|
|
(!_enc->vp3_compatible||mb_mode!=OC_MODE_INTER_MV_FOUR||_pli)){
|
|
int overhead_bits;
|
|
overhead_bits=oc_fr_cost1(_fr);
|
|
/*Although the fragment coding overhead determination is accurate, it is
|
|
greedy, using very coarse-grained local information.
|
|
Allowing it to mildly discourage coding turns out to be beneficial, but
|
|
it's not clear that allowing it to encourage coding through negative
|
|
coding overhead deltas is useful.
|
|
For that reason, we disallow negative coding overheads.*/
|
|
if(overhead_bits<0)overhead_bits=0;
|
|
if(uncoded_ssd<=coded_ssd+(overhead_bits+ac_bits)*_enc->lambda){
|
|
/*Hm, not worth it; roll back.*/
|
|
oc_enc_tokenlog_rollback(_enc,checkpoint,(*_stack)-checkpoint);
|
|
*_stack=checkpoint;
|
|
frags[_fragi].coded=0;
|
|
frags[_fragi].refi=OC_FRAME_NONE;
|
|
oc_fr_skip_block(_fr);
|
|
return 0;
|
|
}
|
|
}
|
|
else _mo->dc_flag=1;
|
|
_mo->uncoded_ac_ssd+=uncoded_ssd;
|
|
_mo->coded_ac_ssd+=coded_ssd;
|
|
_mo->ac_bits+=ac_bits;
|
|
oc_fr_code_block(_fr);
|
|
}
|
|
/*GCC 4.4.4 generates a warning here because it can't tell that
|
|
the init code in the nqis check above will run anytime this
|
|
line runs.*/
|
|
if(nqis>1)*(_pipe->qs+_pli)=*&qs;
|
|
frags[_fragi].dc=dc;
|
|
frags[_fragi].coded=1;
|
|
return 1;
|
|
}
|
|
|
|
static int oc_enc_mb_transform_quantize_inter_luma(oc_enc_ctx *_enc,
|
|
oc_enc_pipeline_state *_pipe,unsigned _mbi,int _mode_overhead,
|
|
const unsigned _rd_scale[4],const unsigned _rd_iscale[4]){
|
|
/*Worst case token stack usage for 4 fragments.*/
|
|
oc_token_checkpoint stack[64*4];
|
|
oc_token_checkpoint *stackptr;
|
|
const oc_sb_map *sb_maps;
|
|
signed char *mb_modes;
|
|
oc_fragment *frags;
|
|
ptrdiff_t *coded_fragis;
|
|
ptrdiff_t ncoded_fragis;
|
|
ptrdiff_t *uncoded_fragis;
|
|
ptrdiff_t nuncoded_fragis;
|
|
oc_rd_metric mo;
|
|
oc_fr_state fr_checkpoint;
|
|
oc_qii_state qs_checkpoint;
|
|
int mb_mode;
|
|
int refi;
|
|
int ncoded;
|
|
ptrdiff_t fragi;
|
|
int bi;
|
|
*&fr_checkpoint=*(_pipe->fr+0);
|
|
*&qs_checkpoint=*(_pipe->qs+0);
|
|
sb_maps=(const oc_sb_map *)_enc->state.sb_maps;
|
|
mb_modes=_enc->state.mb_modes;
|
|
frags=_enc->state.frags;
|
|
coded_fragis=_pipe->coded_fragis[0];
|
|
ncoded_fragis=_pipe->ncoded_fragis[0];
|
|
uncoded_fragis=_pipe->uncoded_fragis[0];
|
|
nuncoded_fragis=_pipe->nuncoded_fragis[0];
|
|
mb_mode=mb_modes[_mbi];
|
|
refi=OC_FRAME_FOR_MODE(mb_mode);
|
|
ncoded=0;
|
|
stackptr=stack;
|
|
memset(&mo,0,sizeof(mo));
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_maps[_mbi>>2][_mbi&3][bi];
|
|
frags[fragi].refi=refi;
|
|
frags[fragi].mb_mode=mb_mode;
|
|
if(oc_enc_block_transform_quantize(_enc,_pipe,0,fragi,
|
|
_rd_scale[bi],_rd_iscale[bi],&mo,_pipe->fr+0,&stackptr)){
|
|
coded_fragis[ncoded_fragis++]=fragi;
|
|
ncoded++;
|
|
}
|
|
else *(uncoded_fragis-++nuncoded_fragis)=fragi;
|
|
}
|
|
if(ncoded>0&&!mo.dc_flag){
|
|
int cost;
|
|
/*Some individual blocks were worth coding.
|
|
See if that's still true when accounting for mode and MV overhead.*/
|
|
cost=mo.coded_ac_ssd+_enc->lambda*(mo.ac_bits
|
|
+oc_fr_cost4(&fr_checkpoint,_pipe->fr+0)+_mode_overhead);
|
|
if(mo.uncoded_ac_ssd<=cost){
|
|
/*Taking macroblock overhead into account, it is not worth coding this
|
|
MB.*/
|
|
oc_enc_tokenlog_rollback(_enc,stack,stackptr-stack);
|
|
*(_pipe->fr+0)=*&fr_checkpoint;
|
|
*(_pipe->qs+0)=*&qs_checkpoint;
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_maps[_mbi>>2][_mbi&3][bi];
|
|
if(frags[fragi].coded){
|
|
*(uncoded_fragis-++nuncoded_fragis)=fragi;
|
|
frags[fragi].coded=0;
|
|
frags[fragi].refi=OC_FRAME_NONE;
|
|
}
|
|
oc_fr_skip_block(_pipe->fr+0);
|
|
}
|
|
ncoded_fragis-=ncoded;
|
|
ncoded=0;
|
|
}
|
|
}
|
|
/*If no luma blocks coded, the mode is forced.*/
|
|
if(ncoded==0)mb_modes[_mbi]=OC_MODE_INTER_NOMV;
|
|
/*Assume that a 1MV with a single coded block is always cheaper than a 4MV
|
|
with a single coded block.
|
|
This may not be strictly true: a 4MV computes chroma MVs using (0,0) for
|
|
skipped blocks, while a 1MV does not.*/
|
|
else if(ncoded==1&&mb_mode==OC_MODE_INTER_MV_FOUR){
|
|
mb_modes[_mbi]=OC_MODE_INTER_MV;
|
|
}
|
|
_pipe->ncoded_fragis[0]=ncoded_fragis;
|
|
_pipe->nuncoded_fragis[0]=nuncoded_fragis;
|
|
return ncoded;
|
|
}
|
|
|
|
static void oc_enc_sb_transform_quantize_inter_chroma(oc_enc_ctx *_enc,
|
|
oc_enc_pipeline_state *_pipe,int _pli,int _sbi_start,int _sbi_end){
|
|
const ogg_uint16_t *mcu_rd_scale;
|
|
const ogg_uint16_t *mcu_rd_iscale;
|
|
const oc_sb_map *sb_maps;
|
|
oc_sb_flags *sb_flags;
|
|
oc_fr_state *fr;
|
|
ptrdiff_t *coded_fragis;
|
|
ptrdiff_t ncoded_fragis;
|
|
ptrdiff_t *uncoded_fragis;
|
|
ptrdiff_t nuncoded_fragis;
|
|
ptrdiff_t froffset;
|
|
int sbi;
|
|
fr=_pipe->fr+_pli;
|
|
mcu_rd_scale=(const ogg_uint16_t *)_enc->mcu_rd_scale;
|
|
mcu_rd_iscale=(const ogg_uint16_t *)_enc->mcu_rd_iscale;
|
|
sb_maps=(const oc_sb_map *)_enc->state.sb_maps;
|
|
sb_flags=_enc->state.sb_flags;
|
|
coded_fragis=_pipe->coded_fragis[_pli];
|
|
ncoded_fragis=_pipe->ncoded_fragis[_pli];
|
|
uncoded_fragis=_pipe->uncoded_fragis[_pli];
|
|
nuncoded_fragis=_pipe->nuncoded_fragis[_pli];
|
|
froffset=_pipe->froffset[_pli];
|
|
for(sbi=_sbi_start;sbi<_sbi_end;sbi++){
|
|
/*Worst case token stack usage for 1 fragment.*/
|
|
oc_token_checkpoint stack[64];
|
|
oc_rd_metric mo;
|
|
int quadi;
|
|
int bi;
|
|
memset(&mo,0,sizeof(mo));
|
|
for(quadi=0;quadi<4;quadi++)for(bi=0;bi<4;bi++){
|
|
ptrdiff_t fragi;
|
|
fragi=sb_maps[sbi][quadi][bi];
|
|
if(fragi>=0){
|
|
oc_token_checkpoint *stackptr;
|
|
unsigned rd_scale;
|
|
unsigned rd_iscale;
|
|
rd_scale=mcu_rd_scale[fragi-froffset];
|
|
rd_iscale=mcu_rd_iscale[fragi-froffset];
|
|
stackptr=stack;
|
|
if(oc_enc_block_transform_quantize(_enc,_pipe,_pli,fragi,
|
|
rd_scale,rd_iscale,&mo,fr,&stackptr)){
|
|
coded_fragis[ncoded_fragis++]=fragi;
|
|
}
|
|
else *(uncoded_fragis-++nuncoded_fragis)=fragi;
|
|
}
|
|
}
|
|
oc_fr_state_flush_sb(fr);
|
|
sb_flags[sbi].coded_fully=fr->sb_full;
|
|
sb_flags[sbi].coded_partially=fr->sb_partial;
|
|
}
|
|
_pipe->ncoded_fragis[_pli]=ncoded_fragis;
|
|
_pipe->nuncoded_fragis[_pli]=nuncoded_fragis;
|
|
}
|
|
|
|
/*Mode decision is done by exhaustively examining all potential choices.
|
|
Obviously, doing the motion compensation, fDCT, tokenization, and then
|
|
counting the bits each token uses is computationally expensive.
|
|
Theora's EOB runs can also split the cost of these tokens across multiple
|
|
fragments, and naturally we don't know what the optimal choice of Huffman
|
|
codes will be until we know all the tokens we're going to encode in all the
|
|
fragments.
|
|
So we use a simple approach to estimating the bit cost and distortion of each
|
|
mode based upon the SATD value of the residual before coding.
|
|
The mathematics behind the technique are outlined by Kim \cite{Kim03}, but
|
|
the process (modified somewhat from that of the paper) is very simple.
|
|
We build a non-linear regression of the mappings from
|
|
(pre-transform+quantization) SATD to (post-transform+quantization) bits and
|
|
SSD for each qi.
|
|
A separate set of mappings is kept for each quantization type and color
|
|
plane.
|
|
The mappings are constructed by partitioning the SATD values into a small
|
|
number of bins (currently 24) and using a linear regression in each bin
|
|
(as opposed to the 0th-order regression used by Kim).
|
|
The bit counts and SSD measurements are obtained by examining actual encoded
|
|
frames, with appropriate lambda values and optimal Huffman codes selected.
|
|
EOB bits are assigned to the fragment that started the EOB run (as opposed to
|
|
dividing them among all the blocks in the run; the latter approach seems
|
|
more theoretically correct, but Monty's testing showed a small improvement
|
|
with the former, though that may have been merely statistical noise).
|
|
|
|
@ARTICLE{Kim03,
|
|
author="Hyun Mun Kim",
|
|
title="Adaptive Rate Control Using Nonlinear Regression",
|
|
journal="IEEE Transactions on Circuits and Systems for Video Technology",
|
|
volume=13,
|
|
number=5,
|
|
pages="432--439",
|
|
month=May,
|
|
year=2003
|
|
}*/
|
|
|
|
/*Computes (_ssd+_lambda*_rate)/(1<<OC_BIT_SCALE) with rounding, avoiding
|
|
overflow for large lambda values.*/
|
|
#define OC_MODE_RD_COST(_ssd,_rate,_lambda) \
|
|
((_ssd)>>OC_BIT_SCALE)+((_rate)>>OC_BIT_SCALE)*(_lambda) \
|
|
+(((_ssd)&(1<<OC_BIT_SCALE)-1)+((_rate)&(1<<OC_BIT_SCALE)-1)*(_lambda) \
|
|
+((1<<OC_BIT_SCALE)>>1)>>OC_BIT_SCALE)
|
|
|
|
static void oc_enc_mode_rd_init(oc_enc_ctx *_enc){
|
|
#if !defined(OC_COLLECT_METRICS)
|
|
const
|
|
#endif
|
|
oc_mode_rd (*oc_mode_rd_table)[3][2][OC_COMP_BINS]=
|
|
_enc->sp_level<OC_SP_LEVEL_NOSATD?OC_MODE_RD_SATD:OC_MODE_RD_SAD;
|
|
int qii;
|
|
#if defined(OC_COLLECT_METRICS)
|
|
oc_enc_mode_metrics_load(_enc);
|
|
#endif
|
|
for(qii=0;qii<_enc->state.nqis;qii++){
|
|
int qi;
|
|
int pli;
|
|
qi=_enc->state.qis[qii];
|
|
for(pli=0;pli<3;pli++){
|
|
int qti;
|
|
for(qti=0;qti<2;qti++){
|
|
int log_plq;
|
|
int modeline;
|
|
int bin;
|
|
int dx;
|
|
int dq;
|
|
log_plq=_enc->log_plq[qi][pli][qti];
|
|
/*Find the pair of rows in the mode table that bracket this quantizer.
|
|
If it falls outside the range the table covers, then we just use a
|
|
pair on the edge for linear extrapolation.*/
|
|
for(modeline=0;modeline<OC_LOGQ_BINS-1&&
|
|
OC_MODE_LOGQ[modeline+1][pli][qti]>log_plq;modeline++);
|
|
/*Interpolate a row for this quantizer.*/
|
|
dx=OC_MODE_LOGQ[modeline][pli][qti]-log_plq;
|
|
dq=OC_MODE_LOGQ[modeline][pli][qti]-OC_MODE_LOGQ[modeline+1][pli][qti];
|
|
if(dq==0)dq=1;
|
|
for(bin=0;bin<OC_COMP_BINS;bin++){
|
|
int y0;
|
|
int z0;
|
|
int dy;
|
|
int dz;
|
|
y0=oc_mode_rd_table[modeline][pli][qti][bin].rate;
|
|
z0=oc_mode_rd_table[modeline][pli][qti][bin].rmse;
|
|
dy=oc_mode_rd_table[modeline+1][pli][qti][bin].rate-y0;
|
|
dz=oc_mode_rd_table[modeline+1][pli][qti][bin].rmse-z0;
|
|
_enc->mode_rd[qii][pli][qti][bin].rate=
|
|
(ogg_int16_t)OC_CLAMPI(-32768,y0+(dy*dx+(dq>>1))/dq,32767);
|
|
_enc->mode_rd[qii][pli][qti][bin].rmse=
|
|
(ogg_int16_t)OC_CLAMPI(-32768,z0+(dz*dx+(dq>>1))/dq,32767);
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
|
|
/*Estimate the R-D cost of the DCT coefficients given the SATD of a block after
|
|
prediction.*/
|
|
static unsigned oc_dct_cost2(oc_enc_ctx *_enc,unsigned *_ssd,
|
|
int _qii,int _pli,int _qti,int _satd){
|
|
unsigned rmse;
|
|
int shift;
|
|
int bin;
|
|
int dx;
|
|
int y0;
|
|
int z0;
|
|
int dy;
|
|
int dz;
|
|
/*SATD metrics for chroma planes vary much less than luma, so we scale them
|
|
by 4 to distribute them into the mode decision bins more evenly.*/
|
|
_satd<<=_pli+1&2;
|
|
shift=_enc->sp_level<OC_SP_LEVEL_NOSATD?OC_SATD_SHIFT:OC_SAD_SHIFT;
|
|
bin=OC_MINI(_satd>>shift,OC_COMP_BINS-2);
|
|
dx=_satd-(bin<<shift);
|
|
y0=_enc->mode_rd[_qii][_pli][_qti][bin].rate;
|
|
z0=_enc->mode_rd[_qii][_pli][_qti][bin].rmse;
|
|
dy=_enc->mode_rd[_qii][_pli][_qti][bin+1].rate-y0;
|
|
dz=_enc->mode_rd[_qii][_pli][_qti][bin+1].rmse-z0;
|
|
rmse=OC_MAXI(z0+(dz*dx>>shift),0);
|
|
*_ssd=rmse*rmse>>2*OC_RMSE_SCALE-OC_BIT_SCALE;
|
|
return OC_MAXI(y0+(dy*dx>>shift),0);
|
|
}
|
|
|
|
/*activity_avg must be positive, or flat regions could get a zero weight, which
|
|
confounds analysis.
|
|
We set the minimum to this value so that it also avoids the need for divide
|
|
by zero checks in oc_mb_masking().*/
|
|
# define OC_ACTIVITY_AVG_MIN (1<<OC_RD_SCALE_BITS)
|
|
|
|
static unsigned oc_mb_activity(oc_enc_ctx *_enc,unsigned _mbi,
|
|
unsigned _activity[4]){
|
|
const unsigned char *src;
|
|
const ptrdiff_t *frag_buf_offs;
|
|
const ptrdiff_t *sb_map;
|
|
unsigned luma;
|
|
int ystride;
|
|
ptrdiff_t frag_offs;
|
|
ptrdiff_t fragi;
|
|
int bi;
|
|
frag_buf_offs=_enc->state.frag_buf_offs;
|
|
sb_map=_enc->state.sb_maps[_mbi>>2][_mbi&3];
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO];
|
|
ystride=_enc->state.ref_ystride[0];
|
|
luma=0;
|
|
for(bi=0;bi<4;bi++){
|
|
const unsigned char *s;
|
|
unsigned x;
|
|
unsigned x2;
|
|
unsigned act;
|
|
int i;
|
|
int j;
|
|
fragi=sb_map[bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
/*TODO: This could be replaced with SATD^2, since we already have to
|
|
compute SATD.*/
|
|
x=x2=0;
|
|
s=src+frag_offs;
|
|
for(i=0;i<8;i++){
|
|
for(j=0;j<8;j++){
|
|
unsigned c;
|
|
c=s[j];
|
|
x+=c;
|
|
x2+=c*c;
|
|
}
|
|
s+=ystride;
|
|
}
|
|
luma+=x;
|
|
act=(x2<<6)-x*x;
|
|
if(act<8<<12){
|
|
/*The region is flat.*/
|
|
act=OC_MINI(act,5<<12);
|
|
}
|
|
else{
|
|
unsigned e1;
|
|
unsigned e2;
|
|
unsigned e3;
|
|
unsigned e4;
|
|
/*Test for an edge.
|
|
TODO: There are probably much simpler ways to do this (e.g., it could
|
|
probably be combined with the SATD calculation).
|
|
Alternatively, we could split the block around the mean and compute the
|
|
reduction in variance in each half.
|
|
For a Gaussian source the reduction should be
|
|
(1-2/pi) ~= 0.36338022763241865692446494650994.
|
|
Significantly more reduction is a good indication of a bi-level image.
|
|
This has the advantage of identifying, in addition to straight edges,
|
|
small text regions, which would otherwise be classified as "texture".*/
|
|
e1=e2=e3=e4=0;
|
|
s=src+frag_offs-1;
|
|
for(i=0;i<8;i++){
|
|
for(j=0;j<8;j++){
|
|
e1+=abs((s[j+2]-s[j]<<1)+(s-ystride)[j+2]-(s-ystride)[j]
|
|
+(s+ystride)[j+2]-(s+ystride)[j]);
|
|
e2+=abs(((s+ystride)[j+1]-(s-ystride)[j+1]<<1)
|
|
+(s+ystride)[j]-(s-ystride)[j]+(s+ystride)[j+2]-(s-ystride)[j+2]);
|
|
e3+=abs(((s+ystride)[j+2]-(s-ystride)[j]<<1)
|
|
+(s+ystride)[j+1]-s[j]+s[j+2]-(s-ystride)[j+1]);
|
|
e4+=abs(((s+ystride)[j]-(s-ystride)[j+2]<<1)
|
|
+(s+ystride)[j+1]-s[j+2]+s[j]-(s-ystride)[j+1]);
|
|
}
|
|
s+=ystride;
|
|
}
|
|
/*If the largest component of the edge energy is at least 40% of the
|
|
total, then classify the block as an edge block.*/
|
|
if(5*OC_MAXI(OC_MAXI(e1,e2),OC_MAXI(e3,e4))>2*(e1+e2+e3+e4)){
|
|
/*act=act_th*(act/act_th)**0.7
|
|
=exp(log(act_th)+0.7*(log(act)-log(act_th))).
|
|
Here act_th=5.0 and 0x394A=oc_blog32_q10(5<<12).*/
|
|
act=oc_bexp32_q10(0x394A+(7*(oc_blog32_q10(act)-0x394A+5)/10));
|
|
}
|
|
}
|
|
_activity[bi]=act;
|
|
}
|
|
return luma;
|
|
}
|
|
|
|
static void oc_mb_activity_fast(oc_enc_ctx *_enc,unsigned _mbi,
|
|
unsigned _activity[4],const unsigned _intra_satd[12]){
|
|
int bi;
|
|
for(bi=0;bi<4;bi++){
|
|
unsigned act;
|
|
act=(11*_intra_satd[bi]>>8)*_intra_satd[bi];
|
|
if(act<8<<12){
|
|
/*The region is flat.*/
|
|
act=OC_MINI(act,5<<12);
|
|
}
|
|
_activity[bi]=act;
|
|
}
|
|
}
|
|
|
|
/*Compute the masking scales for the blocks in a macro block.
|
|
All masking is computed from the luma blocks.
|
|
We derive scaling factors for the chroma blocks from these, and use the same
|
|
ones for all chroma blocks, regardless of the subsampling.
|
|
It's possible for luma to be perfectly flat and yet have high chroma energy,
|
|
but this is unlikely in non-artificial images, and not a case that has been
|
|
addressed by any research to my knowledge.
|
|
The output of the masking process is two scale factors, which are fed into
|
|
the various R-D optimizations.
|
|
The first, rd_scale, is applied to D in the equation
|
|
D*rd_scale+lambda*R.
|
|
This is the form that must be used to properly combine scores from multiple
|
|
blocks, and can be interpreted as scaling distortions by their visibility.
|
|
The inverse, rd_iscale, is applied to lambda in the equation
|
|
D+rd_iscale*lambda*R.
|
|
This is equivalent to the first form within a single block, but much faster
|
|
to use when evaluating many possible distortions (e.g., during actual
|
|
quantization, where separate distortions are evaluated for every
|
|
coefficient).
|
|
The two macros OC_RD_SCALE(rd_scale,d) and OC_RD_ISCALE(rd_iscale,lambda) are
|
|
used to perform the multiplications with the proper re-scaling for the range
|
|
of the scaling factors.
|
|
Many researchers apply masking values directly to the quantizers used, and
|
|
not to the R-D cost.
|
|
Since we generally use MSE for D, rd_scale must use the square of their
|
|
values to generate an equivalent effect.*/
|
|
static unsigned oc_mb_masking(unsigned _rd_scale[5],unsigned _rd_iscale[5],
|
|
const ogg_uint16_t _chroma_rd_scale[2],const unsigned _activity[4],
|
|
unsigned _activity_avg,unsigned _luma,unsigned _luma_avg){
|
|
unsigned activity_sum;
|
|
unsigned la;
|
|
unsigned lb;
|
|
unsigned d;
|
|
int bi;
|
|
int bi_min;
|
|
int bi_min2;
|
|
/*The ratio lb/la is meant to approximate
|
|
((((_luma-16)/219)*(255/128))**0.649**0.4**2), which is the
|
|
effective luminance masking from~\cite{LKW06} (including the self-masking
|
|
deflator).
|
|
The following actually turns out to be a pretty good approximation for
|
|
_luma>75 or so.
|
|
For smaller values luminance does not really follow Weber's Law anyway, and
|
|
this approximation gives a much less aggressive bitrate boost in this
|
|
region.
|
|
Though some researchers claim that contrast sensitivity actually decreases
|
|
for very low luminance values, in my experience excessive brightness on
|
|
LCDs or buggy color conversions (e.g., treating Y' as full-range instead
|
|
of the CCIR 601 range) make artifacts in such regions extremely visible.
|
|
We substitute _luma_avg for 128 to allow the strength of the masking to
|
|
vary with the actual average image luminance, within certain limits (the
|
|
caller has clamped _luma_avg to the range [90,160], inclusive).
|
|
@ARTICLE{LKW06,
|
|
author="Zhen Liu and Lina J. Karam and Andrew B. Watson",
|
|
title="{JPEG2000} Encoding With Perceptual Distortion Control",
|
|
journal="{IEEE} Transactions on Image Processing",
|
|
volume=15,
|
|
number=7,
|
|
pages="1763--1778",
|
|
month=Jul,
|
|
year=2006
|
|
}*/
|
|
#if 0
|
|
la=_luma+4*_luma_avg;
|
|
lb=4*_luma+_luma_avg;
|
|
#else
|
|
/*Disable luminance masking.*/
|
|
la=lb=1;
|
|
#endif
|
|
activity_sum=0;
|
|
for(bi=0;bi<4;bi++){
|
|
unsigned a;
|
|
unsigned b;
|
|
activity_sum+=_activity[bi];
|
|
/*Apply activity masking.*/
|
|
a=_activity[bi]+4*_activity_avg;
|
|
b=4*_activity[bi]+_activity_avg;
|
|
d=OC_RD_SCALE(b,1);
|
|
/*And luminance masking.*/
|
|
d=(a+(d>>1))/d;
|
|
_rd_scale[bi]=(d*la+(lb>>1))/lb;
|
|
/*And now the inverse.*/
|
|
d=OC_MAXI(OC_RD_ISCALE(a,1),1);
|
|
d=(b+(d>>1))/d;
|
|
_rd_iscale[bi]=(d*lb+(la>>1))/la;
|
|
}
|
|
/*Now compute scaling factors for chroma blocks.
|
|
We start by finding the two smallest iscales from the luma blocks.*/
|
|
bi_min=_rd_iscale[1]<_rd_iscale[0];
|
|
bi_min2=1-bi_min;
|
|
for(bi=2;bi<4;bi++){
|
|
if(_rd_iscale[bi]<_rd_iscale[bi_min]){
|
|
bi_min2=bi_min;
|
|
bi_min=bi;
|
|
}
|
|
else if(_rd_iscale[bi]<_rd_iscale[bi_min2])bi_min2=bi;
|
|
}
|
|
/*If the minimum iscale is less than 1.0, use the second smallest instead,
|
|
and force the value to at least 1.0 (inflating chroma is a waste).*/
|
|
if(_rd_iscale[bi_min]<(1<<OC_RD_ISCALE_BITS))bi_min=bi_min2;
|
|
d=OC_MINI(_rd_scale[bi_min],1<<OC_RD_SCALE_BITS);
|
|
_rd_scale[4]=OC_RD_SCALE(d,_chroma_rd_scale[0]);
|
|
d=OC_MAXI(_rd_iscale[bi_min],1<<OC_RD_ISCALE_BITS);
|
|
_rd_iscale[4]=OC_RD_ISCALE(d,_chroma_rd_scale[1]);
|
|
return activity_sum;
|
|
}
|
|
|
|
static int oc_mb_intra_satd(oc_enc_ctx *_enc,unsigned _mbi,
|
|
unsigned _frag_satd[12]){
|
|
const unsigned char *src;
|
|
const ptrdiff_t *frag_buf_offs;
|
|
const ptrdiff_t *sb_map;
|
|
const oc_mb_map_plane *mb_map;
|
|
const unsigned char *map_idxs;
|
|
int map_nidxs;
|
|
int mapii;
|
|
int mapi;
|
|
int ystride;
|
|
int pli;
|
|
int bi;
|
|
ptrdiff_t fragi;
|
|
ptrdiff_t frag_offs;
|
|
unsigned luma;
|
|
int dc;
|
|
frag_buf_offs=_enc->state.frag_buf_offs;
|
|
sb_map=_enc->state.sb_maps[_mbi>>2][_mbi&3];
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO];
|
|
ystride=_enc->state.ref_ystride[0];
|
|
luma=0;
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_map[bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
_frag_satd[bi]=oc_enc_frag_intra_satd(_enc,&dc,src+frag_offs,ystride);
|
|
luma+=dc;
|
|
}
|
|
mb_map=(const oc_mb_map_plane *)_enc->state.mb_maps[_mbi];
|
|
map_idxs=OC_MB_MAP_IDXS[_enc->state.info.pixel_fmt];
|
|
map_nidxs=OC_MB_MAP_NIDXS[_enc->state.info.pixel_fmt];
|
|
/*Note: This assumes ref_ystride[1]==ref_ystride[2].*/
|
|
ystride=_enc->state.ref_ystride[1];
|
|
for(mapii=4;mapii<map_nidxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
pli=mapi>>2;
|
|
bi=mapi&3;
|
|
fragi=mb_map[pli][bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
_frag_satd[mapii]=oc_enc_frag_intra_satd(_enc,&dc,src+frag_offs,ystride);
|
|
}
|
|
return luma;
|
|
}
|
|
|
|
/*Select luma block-level quantizers for a MB in an INTRA frame.*/
|
|
static unsigned oc_analyze_intra_mb_luma(oc_enc_ctx *_enc,
|
|
const oc_qii_state *_qs,unsigned _mbi,const unsigned _rd_scale[4]){
|
|
const unsigned char *src;
|
|
const ptrdiff_t *frag_buf_offs;
|
|
const oc_sb_map *sb_maps;
|
|
oc_fragment *frags;
|
|
ptrdiff_t frag_offs;
|
|
ptrdiff_t fragi;
|
|
oc_qii_state qs[4][3];
|
|
unsigned cost[4][3];
|
|
unsigned ssd[4][3];
|
|
unsigned rate[4][3];
|
|
int prev[3][3];
|
|
unsigned satd;
|
|
int dc;
|
|
unsigned best_cost;
|
|
unsigned best_ssd;
|
|
unsigned best_rate;
|
|
int best_qii;
|
|
int qii;
|
|
int lambda;
|
|
int ystride;
|
|
int nqis;
|
|
int bi;
|
|
frag_buf_offs=_enc->state.frag_buf_offs;
|
|
sb_maps=(const oc_sb_map *)_enc->state.sb_maps;
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO];
|
|
ystride=_enc->state.ref_ystride[0];
|
|
fragi=sb_maps[_mbi>>2][_mbi&3][0];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(_enc->sp_level<OC_SP_LEVEL_NOSATD){
|
|
satd=oc_enc_frag_intra_satd(_enc,&dc,src+frag_offs,ystride);
|
|
}
|
|
else{
|
|
satd=oc_enc_frag_intra_sad(_enc,src+frag_offs,ystride);
|
|
}
|
|
nqis=_enc->state.nqis;
|
|
lambda=_enc->lambda;
|
|
for(qii=0;qii<nqis;qii++){
|
|
oc_qii_state_advance(qs[0]+qii,_qs,qii);
|
|
rate[0][qii]=oc_dct_cost2(_enc,ssd[0]+qii,qii,0,0,satd)
|
|
+(qs[0][qii].bits-_qs->bits<<OC_BIT_SCALE);
|
|
ssd[0][qii]=OC_RD_SCALE(ssd[0][qii],_rd_scale[0]);
|
|
cost[0][qii]=OC_MODE_RD_COST(ssd[0][qii],rate[0][qii],lambda);
|
|
}
|
|
for(bi=1;bi<4;bi++){
|
|
fragi=sb_maps[_mbi>>2][_mbi&3][bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(_enc->sp_level<OC_SP_LEVEL_NOSATD){
|
|
satd=oc_enc_frag_intra_satd(_enc,&dc,src+frag_offs,ystride);
|
|
}
|
|
else{
|
|
satd=oc_enc_frag_intra_sad(_enc,src+frag_offs,ystride);
|
|
}
|
|
for(qii=0;qii<nqis;qii++){
|
|
oc_qii_state qt[3];
|
|
unsigned cur_ssd;
|
|
unsigned cur_rate;
|
|
int best_qij;
|
|
int qij;
|
|
oc_qii_state_advance(qt+0,qs[bi-1]+0,qii);
|
|
cur_rate=oc_dct_cost2(_enc,&cur_ssd,qii,0,0,satd);
|
|
cur_ssd=OC_RD_SCALE(cur_ssd,_rd_scale[bi]);
|
|
best_ssd=ssd[bi-1][0]+cur_ssd;
|
|
best_rate=rate[bi-1][0]+cur_rate
|
|
+(qt[0].bits-qs[bi-1][0].bits<<OC_BIT_SCALE);
|
|
best_cost=OC_MODE_RD_COST(best_ssd,best_rate,lambda);
|
|
best_qij=0;
|
|
for(qij=1;qij<nqis;qij++){
|
|
unsigned chain_ssd;
|
|
unsigned chain_rate;
|
|
unsigned chain_cost;
|
|
oc_qii_state_advance(qt+qij,qs[bi-1]+qij,qii);
|
|
chain_ssd=ssd[bi-1][qij]+cur_ssd;
|
|
chain_rate=rate[bi-1][qij]+cur_rate
|
|
+(qt[qij].bits-qs[bi-1][qij].bits<<OC_BIT_SCALE);
|
|
chain_cost=OC_MODE_RD_COST(chain_ssd,chain_rate,lambda);
|
|
if(chain_cost<best_cost){
|
|
best_cost=chain_cost;
|
|
best_ssd=chain_ssd;
|
|
best_rate=chain_rate;
|
|
best_qij=qij;
|
|
}
|
|
}
|
|
*(qs[bi]+qii)=*(qt+best_qij);
|
|
cost[bi][qii]=best_cost;
|
|
ssd[bi][qii]=best_ssd;
|
|
rate[bi][qii]=best_rate;
|
|
prev[bi-1][qii]=best_qij;
|
|
}
|
|
}
|
|
best_qii=0;
|
|
best_cost=cost[3][0];
|
|
for(qii=1;qii<nqis;qii++){
|
|
if(cost[3][qii]<best_cost){
|
|
best_cost=cost[3][qii];
|
|
best_qii=qii;
|
|
}
|
|
}
|
|
frags=_enc->state.frags;
|
|
for(bi=3;;){
|
|
fragi=sb_maps[_mbi>>2][_mbi&3][bi];
|
|
frags[fragi].qii=best_qii;
|
|
if(bi--<=0)break;
|
|
best_qii=prev[bi][best_qii];
|
|
}
|
|
return best_cost;
|
|
}
|
|
|
|
/*Select a block-level quantizer for a single chroma block in an INTRA frame.*/
|
|
static unsigned oc_analyze_intra_chroma_block(oc_enc_ctx *_enc,
|
|
const oc_qii_state *_qs,int _pli,ptrdiff_t _fragi,unsigned _rd_scale){
|
|
const unsigned char *src;
|
|
oc_fragment *frags;
|
|
ptrdiff_t frag_offs;
|
|
oc_qii_state qt[3];
|
|
unsigned cost[3];
|
|
unsigned satd;
|
|
int dc;
|
|
unsigned best_cost;
|
|
int best_qii;
|
|
int qii;
|
|
int lambda;
|
|
int ystride;
|
|
int nqis;
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO];
|
|
ystride=_enc->state.ref_ystride[_pli];
|
|
frag_offs=_enc->state.frag_buf_offs[_fragi];
|
|
if(_enc->sp_level<OC_SP_LEVEL_NOSATD){
|
|
satd=oc_enc_frag_intra_satd(_enc,&dc,src+frag_offs,ystride);
|
|
}
|
|
else{
|
|
satd=oc_enc_frag_intra_sad(_enc,src+frag_offs,ystride);
|
|
}
|
|
/*Most chroma blocks have no AC coefficients to speak of anyway, so it's not
|
|
worth spending the bits to change the AC quantizer.
|
|
TODO: This may be worth revisiting when we separate out DC and AC
|
|
predictions from SATD.*/
|
|
#if 0
|
|
nqis=_enc->state.nqis;
|
|
#else
|
|
nqis=1;
|
|
#endif
|
|
lambda=_enc->lambda;
|
|
best_qii=0;
|
|
for(qii=0;qii<nqis;qii++){
|
|
unsigned cur_rate;
|
|
unsigned cur_ssd;
|
|
oc_qii_state_advance(qt+qii,_qs,qii);
|
|
cur_rate=oc_dct_cost2(_enc,&cur_ssd,qii,_pli,0,satd)
|
|
+(qt[qii].bits-_qs->bits<<OC_BIT_SCALE);
|
|
cur_ssd=OC_RD_SCALE(cur_ssd,_rd_scale);
|
|
cost[qii]=OC_MODE_RD_COST(cur_ssd,cur_rate,lambda);
|
|
}
|
|
best_cost=cost[0];
|
|
for(qii=1;qii<nqis;qii++){
|
|
if(cost[qii]<best_cost){
|
|
best_cost=cost[qii];
|
|
best_qii=qii;
|
|
}
|
|
}
|
|
frags=_enc->state.frags;
|
|
frags[_fragi].qii=best_qii;
|
|
return best_cost;
|
|
}
|
|
|
|
static void oc_enc_mb_transform_quantize_intra_luma(oc_enc_ctx *_enc,
|
|
oc_enc_pipeline_state *_pipe,unsigned _mbi,
|
|
const unsigned _rd_scale[4],const unsigned _rd_iscale[4]){
|
|
/*Worst case token stack usage for 4 fragments.*/
|
|
oc_token_checkpoint stack[64*4];
|
|
oc_token_checkpoint *stackptr;
|
|
const oc_sb_map *sb_maps;
|
|
oc_fragment *frags;
|
|
ptrdiff_t *coded_fragis;
|
|
ptrdiff_t ncoded_fragis;
|
|
ptrdiff_t fragi;
|
|
int bi;
|
|
sb_maps=(const oc_sb_map *)_enc->state.sb_maps;
|
|
frags=_enc->state.frags;
|
|
coded_fragis=_pipe->coded_fragis[0];
|
|
ncoded_fragis=_pipe->ncoded_fragis[0];
|
|
stackptr=stack;
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_maps[_mbi>>2][_mbi&3][bi];
|
|
frags[fragi].refi=OC_FRAME_SELF;
|
|
frags[fragi].mb_mode=OC_MODE_INTRA;
|
|
oc_enc_block_transform_quantize(_enc,_pipe,0,fragi,
|
|
_rd_scale[bi],_rd_iscale[bi],NULL,NULL,&stackptr);
|
|
coded_fragis[ncoded_fragis++]=fragi;
|
|
}
|
|
_pipe->ncoded_fragis[0]=ncoded_fragis;
|
|
}
|
|
|
|
static void oc_enc_sb_transform_quantize_intra_chroma(oc_enc_ctx *_enc,
|
|
oc_enc_pipeline_state *_pipe,int _pli,int _sbi_start,int _sbi_end){
|
|
const ogg_uint16_t *mcu_rd_scale;
|
|
const ogg_uint16_t *mcu_rd_iscale;
|
|
const oc_sb_map *sb_maps;
|
|
ptrdiff_t *coded_fragis;
|
|
ptrdiff_t ncoded_fragis;
|
|
ptrdiff_t froffset;
|
|
int sbi;
|
|
mcu_rd_scale=(const ogg_uint16_t *)_enc->mcu_rd_scale;
|
|
mcu_rd_iscale=(const ogg_uint16_t *)_enc->mcu_rd_iscale;
|
|
sb_maps=(const oc_sb_map *)_enc->state.sb_maps;
|
|
coded_fragis=_pipe->coded_fragis[_pli];
|
|
ncoded_fragis=_pipe->ncoded_fragis[_pli];
|
|
froffset=_pipe->froffset[_pli];
|
|
for(sbi=_sbi_start;sbi<_sbi_end;sbi++){
|
|
/*Worst case token stack usage for 1 fragment.*/
|
|
oc_token_checkpoint stack[64];
|
|
int quadi;
|
|
int bi;
|
|
for(quadi=0;quadi<4;quadi++)for(bi=0;bi<4;bi++){
|
|
ptrdiff_t fragi;
|
|
fragi=sb_maps[sbi][quadi][bi];
|
|
if(fragi>=0){
|
|
oc_token_checkpoint *stackptr;
|
|
unsigned rd_scale;
|
|
unsigned rd_iscale;
|
|
rd_scale=mcu_rd_scale[fragi-froffset];
|
|
rd_iscale=mcu_rd_iscale[fragi-froffset];
|
|
oc_analyze_intra_chroma_block(_enc,_pipe->qs+_pli,_pli,fragi,rd_scale);
|
|
stackptr=stack;
|
|
oc_enc_block_transform_quantize(_enc,_pipe,_pli,fragi,
|
|
rd_scale,rd_iscale,NULL,NULL,&stackptr);
|
|
coded_fragis[ncoded_fragis++]=fragi;
|
|
}
|
|
}
|
|
}
|
|
_pipe->ncoded_fragis[_pli]=ncoded_fragis;
|
|
}
|
|
|
|
/*Analysis stage for an INTRA frame.*/
|
|
void oc_enc_analyze_intra(oc_enc_ctx *_enc,int _recode){
|
|
ogg_int64_t activity_sum;
|
|
ogg_int64_t luma_sum;
|
|
unsigned activity_avg;
|
|
unsigned luma_avg;
|
|
const ogg_uint16_t *chroma_rd_scale;
|
|
ogg_uint16_t *mcu_rd_scale;
|
|
ogg_uint16_t *mcu_rd_iscale;
|
|
const unsigned char *map_idxs;
|
|
int nmap_idxs;
|
|
oc_sb_flags *sb_flags;
|
|
signed char *mb_modes;
|
|
const oc_mb_map *mb_maps;
|
|
const oc_sb_map *sb_maps;
|
|
oc_fragment *frags;
|
|
unsigned stripe_sby;
|
|
unsigned mcu_nvsbs;
|
|
int notstart;
|
|
int notdone;
|
|
int refi;
|
|
int pli;
|
|
_enc->state.frame_type=OC_INTRA_FRAME;
|
|
oc_enc_tokenize_start(_enc);
|
|
oc_enc_pipeline_init(_enc,&_enc->pipe);
|
|
oc_enc_mode_rd_init(_enc);
|
|
activity_sum=luma_sum=0;
|
|
activity_avg=_enc->activity_avg;
|
|
luma_avg=OC_CLAMPI(90<<8,_enc->luma_avg,160<<8);
|
|
chroma_rd_scale=_enc->chroma_rd_scale[OC_INTRA_FRAME][_enc->state.qis[0]];
|
|
mcu_rd_scale=_enc->mcu_rd_scale;
|
|
mcu_rd_iscale=_enc->mcu_rd_iscale;
|
|
/*Choose MVs and MB modes and quantize and code luma.
|
|
Must be done in Hilbert order.*/
|
|
map_idxs=OC_MB_MAP_IDXS[_enc->state.info.pixel_fmt];
|
|
nmap_idxs=OC_MB_MAP_NIDXS[_enc->state.info.pixel_fmt];
|
|
_enc->state.ncoded_fragis[0]=0;
|
|
_enc->state.ncoded_fragis[1]=0;
|
|
_enc->state.ncoded_fragis[2]=0;
|
|
sb_flags=_enc->state.sb_flags;
|
|
mb_modes=_enc->state.mb_modes;
|
|
mb_maps=(const oc_mb_map *)_enc->state.mb_maps;
|
|
sb_maps=(const oc_sb_map *)_enc->state.sb_maps;
|
|
frags=_enc->state.frags;
|
|
notstart=0;
|
|
notdone=1;
|
|
mcu_nvsbs=_enc->mcu_nvsbs;
|
|
for(stripe_sby=0;notdone;stripe_sby+=mcu_nvsbs){
|
|
ptrdiff_t cfroffset;
|
|
unsigned sbi;
|
|
unsigned sbi_end;
|
|
notdone=oc_enc_pipeline_set_stripe(_enc,&_enc->pipe,stripe_sby);
|
|
sbi_end=_enc->pipe.sbi_end[0];
|
|
cfroffset=_enc->pipe.froffset[1];
|
|
for(sbi=_enc->pipe.sbi0[0];sbi<sbi_end;sbi++){
|
|
int quadi;
|
|
/*Mode addressing is through Y plane, always 4 MB per SB.*/
|
|
for(quadi=0;quadi<4;quadi++)if(sb_flags[sbi].quad_valid&1<<quadi){
|
|
unsigned activity[4];
|
|
unsigned rd_scale[5];
|
|
unsigned rd_iscale[5];
|
|
unsigned luma;
|
|
unsigned mbi;
|
|
int mapii;
|
|
int mapi;
|
|
int bi;
|
|
ptrdiff_t fragi;
|
|
mbi=sbi<<2|quadi;
|
|
/*Activity masking.*/
|
|
if(_enc->sp_level<OC_SP_LEVEL_FAST_ANALYSIS){
|
|
luma=oc_mb_activity(_enc,mbi,activity);
|
|
}
|
|
else{
|
|
unsigned intra_satd[12];
|
|
luma=oc_mb_intra_satd(_enc,mbi,intra_satd);
|
|
oc_mb_activity_fast(_enc,mbi,activity,intra_satd);
|
|
for(bi=0;bi<4;bi++)frags[sb_maps[mbi>>2][mbi&3][bi]].qii=0;
|
|
}
|
|
activity_sum+=oc_mb_masking(rd_scale,rd_iscale,
|
|
chroma_rd_scale,activity,activity_avg,luma,luma_avg);
|
|
luma_sum+=luma;
|
|
/*Motion estimation:
|
|
We do a basic 1MV search for all macroblocks, coded or not,
|
|
keyframe or not, unless we aren't using motion estimation at all.*/
|
|
if(!_recode&&_enc->state.curframe_num>0&&
|
|
_enc->sp_level<OC_SP_LEVEL_NOMC&&_enc->keyframe_frequency_force>1){
|
|
oc_mcenc_search(_enc,mbi);
|
|
}
|
|
if(_enc->sp_level<OC_SP_LEVEL_FAST_ANALYSIS){
|
|
oc_analyze_intra_mb_luma(_enc,_enc->pipe.qs+0,mbi,rd_scale);
|
|
}
|
|
mb_modes[mbi]=OC_MODE_INTRA;
|
|
oc_enc_mb_transform_quantize_intra_luma(_enc,&_enc->pipe,
|
|
mbi,rd_scale,rd_iscale);
|
|
/*Propagate final MB mode and MVs to the chroma blocks.*/
|
|
for(mapii=4;mapii<nmap_idxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
pli=mapi>>2;
|
|
bi=mapi&3;
|
|
fragi=mb_maps[mbi][pli][bi];
|
|
frags[fragi].refi=OC_FRAME_SELF;
|
|
frags[fragi].mb_mode=OC_MODE_INTRA;
|
|
}
|
|
/*Save masking scale factors for chroma blocks.*/
|
|
for(mapii=4;mapii<(nmap_idxs-4>>1)+4;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
bi=mapi&3;
|
|
fragi=mb_maps[mbi][1][bi];
|
|
mcu_rd_scale[fragi-cfroffset]=(ogg_uint16_t)rd_scale[4];
|
|
mcu_rd_iscale[fragi-cfroffset]=(ogg_uint16_t)rd_iscale[4];
|
|
}
|
|
}
|
|
}
|
|
oc_enc_pipeline_finish_mcu_plane(_enc,&_enc->pipe,0,notstart,notdone);
|
|
/*Code chroma planes.*/
|
|
for(pli=1;pli<3;pli++){
|
|
oc_enc_sb_transform_quantize_intra_chroma(_enc,&_enc->pipe,
|
|
pli,_enc->pipe.sbi0[pli],_enc->pipe.sbi_end[pli]);
|
|
oc_enc_pipeline_finish_mcu_plane(_enc,&_enc->pipe,pli,notstart,notdone);
|
|
}
|
|
notstart=1;
|
|
}
|
|
/*Compute the average block activity and MB luma score for the frame.*/
|
|
_enc->activity_avg=OC_MAXI(OC_ACTIVITY_AVG_MIN,
|
|
(unsigned)((activity_sum+(_enc->state.fplanes[0].nfrags>>1))/
|
|
_enc->state.fplanes[0].nfrags));
|
|
_enc->luma_avg=(unsigned)((luma_sum+(_enc->state.nmbs>>1))/_enc->state.nmbs);
|
|
/*Finish filling in the reference frame borders.*/
|
|
refi=_enc->state.ref_frame_idx[OC_FRAME_SELF];
|
|
for(pli=0;pli<3;pli++)oc_state_borders_fill_caps(&_enc->state,refi,pli);
|
|
_enc->state.ntotal_coded_fragis=_enc->state.nfrags;
|
|
}
|
|
|
|
|
|
|
|
/*Cost information about a MB mode.*/
|
|
struct oc_mode_choice{
|
|
unsigned cost;
|
|
unsigned ssd;
|
|
unsigned rate;
|
|
unsigned overhead;
|
|
unsigned char qii[12];
|
|
};
|
|
|
|
|
|
|
|
static void oc_mode_set_cost(oc_mode_choice *_modec,int _lambda){
|
|
_modec->cost=OC_MODE_RD_COST(_modec->ssd,
|
|
_modec->rate+_modec->overhead,_lambda);
|
|
}
|
|
|
|
/*A set of skip SSD's to use to disable early skipping.*/
|
|
static const unsigned OC_NOSKIP[12]={
|
|
UINT_MAX,UINT_MAX,UINT_MAX,UINT_MAX,
|
|
UINT_MAX,UINT_MAX,UINT_MAX,UINT_MAX,
|
|
UINT_MAX,UINT_MAX,UINT_MAX,UINT_MAX
|
|
};
|
|
|
|
/*The estimated number of bits used by a coded chroma block to specify the AC
|
|
quantizer.
|
|
TODO: Currently this is just 0.5*log2(3) (estimating about 50% compression);
|
|
measurements suggest this is in the right ballpark, but it varies somewhat
|
|
with lambda.*/
|
|
#define OC_CHROMA_QII_RATE ((0xCAE00D1DU>>31-OC_BIT_SCALE)+1>>1)
|
|
|
|
static void oc_analyze_mb_mode_luma(oc_enc_ctx *_enc,
|
|
oc_mode_choice *_modec,const oc_fr_state *_fr,const oc_qii_state *_qs,
|
|
const unsigned _frag_satd[12],const unsigned _skip_ssd[12],
|
|
const unsigned _rd_scale[4],int _qti){
|
|
oc_fr_state fr;
|
|
oc_qii_state qs;
|
|
unsigned ssd;
|
|
unsigned rate;
|
|
unsigned satd;
|
|
unsigned best_ssd;
|
|
unsigned best_rate;
|
|
int best_fri;
|
|
int best_qii;
|
|
int lambda;
|
|
int nqis;
|
|
int nskipped;
|
|
int bi;
|
|
lambda=_enc->lambda;
|
|
nqis=_enc->state.nqis;
|
|
/*We could do a trellis optimization here, but we don't make final skip
|
|
decisions until after transform+quantization, so the result wouldn't be
|
|
optimal anyway.
|
|
Instead we just use a greedy approach; for most SATD values, the
|
|
differences between the qiis are large enough to drown out the cost to
|
|
code the flags, anyway.*/
|
|
*&fr=*_fr;
|
|
*&qs=*_qs;
|
|
ssd=rate=nskipped=0;
|
|
for(bi=0;bi<4;bi++){
|
|
oc_fr_state ft[2];
|
|
oc_qii_state qt[3];
|
|
unsigned best_cost;
|
|
unsigned cur_cost;
|
|
unsigned cur_ssd;
|
|
unsigned cur_rate;
|
|
unsigned cur_overhead;
|
|
int qii;
|
|
satd=_frag_satd[bi];
|
|
*(ft+0)=*&fr;
|
|
oc_fr_code_block(ft+0);
|
|
cur_overhead=ft[0].bits-fr.bits;
|
|
best_rate=oc_dct_cost2(_enc,&best_ssd,0,0,_qti,satd)
|
|
+(cur_overhead<<OC_BIT_SCALE);
|
|
if(nqis>1){
|
|
oc_qii_state_advance(qt+0,&qs,0);
|
|
best_rate+=qt[0].bits-qs.bits<<OC_BIT_SCALE;
|
|
}
|
|
best_ssd=OC_RD_SCALE(best_ssd,_rd_scale[bi]);
|
|
best_cost=OC_MODE_RD_COST(ssd+best_ssd,rate+best_rate,lambda);
|
|
best_fri=0;
|
|
best_qii=0;
|
|
for(qii=1;qii<nqis;qii++){
|
|
oc_qii_state_advance(qt+qii,&qs,qii);
|
|
cur_rate=oc_dct_cost2(_enc,&cur_ssd,qii,0,_qti,satd)
|
|
+(cur_overhead+qt[qii].bits-qs.bits<<OC_BIT_SCALE);
|
|
cur_ssd=OC_RD_SCALE(cur_ssd,_rd_scale[bi]);
|
|
cur_cost=OC_MODE_RD_COST(ssd+cur_ssd,rate+cur_rate,lambda);
|
|
if(cur_cost<best_cost){
|
|
best_cost=cur_cost;
|
|
best_ssd=cur_ssd;
|
|
best_rate=cur_rate;
|
|
best_qii=qii;
|
|
}
|
|
}
|
|
if(_skip_ssd[bi]<(UINT_MAX>>OC_BIT_SCALE+2)&&nskipped<3){
|
|
*(ft+1)=*&fr;
|
|
oc_fr_skip_block(ft+1);
|
|
cur_overhead=ft[1].bits-fr.bits<<OC_BIT_SCALE;
|
|
cur_ssd=_skip_ssd[bi]<<OC_BIT_SCALE;
|
|
cur_cost=OC_MODE_RD_COST(ssd+cur_ssd,rate+cur_overhead,lambda);
|
|
if(cur_cost<=best_cost){
|
|
best_ssd=cur_ssd;
|
|
best_rate=cur_overhead;
|
|
best_fri=1;
|
|
best_qii+=4;
|
|
}
|
|
}
|
|
rate+=best_rate;
|
|
ssd+=best_ssd;
|
|
*&fr=*(ft+best_fri);
|
|
if(best_fri==0)*&qs=*(qt+best_qii);
|
|
else nskipped++;
|
|
_modec->qii[bi]=best_qii;
|
|
}
|
|
_modec->ssd=ssd;
|
|
_modec->rate=rate;
|
|
}
|
|
|
|
static void oc_analyze_mb_mode_chroma(oc_enc_ctx *_enc,
|
|
oc_mode_choice *_modec,const oc_fr_state *_fr,const oc_qii_state *_qs,
|
|
const unsigned _frag_satd[12],const unsigned _skip_ssd[12],
|
|
unsigned _rd_scale,int _qti){
|
|
unsigned ssd;
|
|
unsigned rate;
|
|
unsigned satd;
|
|
unsigned best_ssd;
|
|
unsigned best_rate;
|
|
int best_qii;
|
|
unsigned cur_cost;
|
|
unsigned cur_ssd;
|
|
unsigned cur_rate;
|
|
int lambda;
|
|
int nblocks;
|
|
int nqis;
|
|
int pli;
|
|
int bi;
|
|
int qii;
|
|
lambda=_enc->lambda;
|
|
/*Most chroma blocks have no AC coefficients to speak of anyway, so it's not
|
|
worth spending the bits to change the AC quantizer.
|
|
TODO: This may be worth revisiting when we separate out DC and AC
|
|
predictions from SATD.*/
|
|
#if 0
|
|
nqis=_enc->state.nqis;
|
|
#else
|
|
nqis=1;
|
|
#endif
|
|
ssd=_modec->ssd;
|
|
rate=_modec->rate;
|
|
/*Because (except in 4:4:4 mode) we aren't considering chroma blocks in coded
|
|
order, we assume a constant overhead for coded block and qii flags.*/
|
|
nblocks=OC_MB_MAP_NIDXS[_enc->state.info.pixel_fmt];
|
|
nblocks=(nblocks-4>>1)+4;
|
|
bi=4;
|
|
for(pli=1;pli<3;pli++){
|
|
for(;bi<nblocks;bi++){
|
|
unsigned best_cost;
|
|
satd=_frag_satd[bi];
|
|
best_rate=oc_dct_cost2(_enc,&best_ssd,0,pli,_qti,satd)
|
|
+OC_CHROMA_QII_RATE;
|
|
best_ssd=OC_RD_SCALE(best_ssd,_rd_scale);
|
|
best_cost=OC_MODE_RD_COST(ssd+best_ssd,rate+best_rate,lambda);
|
|
best_qii=0;
|
|
for(qii=1;qii<nqis;qii++){
|
|
cur_rate=oc_dct_cost2(_enc,&cur_ssd,qii,pli,_qti,satd)
|
|
+OC_CHROMA_QII_RATE;
|
|
cur_ssd=OC_RD_SCALE(cur_ssd,_rd_scale);
|
|
cur_cost=OC_MODE_RD_COST(ssd+cur_ssd,rate+cur_rate,lambda);
|
|
if(cur_cost<best_cost){
|
|
best_cost=cur_cost;
|
|
best_ssd=cur_ssd;
|
|
best_rate=cur_rate;
|
|
best_qii=qii;
|
|
}
|
|
}
|
|
if(_skip_ssd[bi]<(UINT_MAX>>OC_BIT_SCALE+2)){
|
|
cur_ssd=_skip_ssd[bi]<<OC_BIT_SCALE;
|
|
cur_cost=OC_MODE_RD_COST(ssd+cur_ssd,rate,lambda);
|
|
if(cur_cost<=best_cost){
|
|
best_ssd=cur_ssd;
|
|
best_rate=0;
|
|
best_qii+=4;
|
|
}
|
|
}
|
|
rate+=best_rate;
|
|
ssd+=best_ssd;
|
|
_modec->qii[bi]=best_qii;
|
|
}
|
|
nblocks=(nblocks-4<<1)+4;
|
|
}
|
|
_modec->ssd=ssd;
|
|
_modec->rate=rate;
|
|
}
|
|
|
|
static void oc_skip_cost(oc_enc_ctx *_enc,oc_enc_pipeline_state *_pipe,
|
|
unsigned _mbi,const unsigned _rd_scale[4],unsigned _ssd[12]){
|
|
const unsigned char *src;
|
|
const unsigned char *ref;
|
|
int ystride;
|
|
const oc_fragment *frags;
|
|
const ptrdiff_t *frag_buf_offs;
|
|
const ptrdiff_t *sb_map;
|
|
const oc_mb_map_plane *mb_map;
|
|
const unsigned char *map_idxs;
|
|
oc_mv *mvs;
|
|
int map_nidxs;
|
|
unsigned uncoded_ssd;
|
|
int mapii;
|
|
int mapi;
|
|
int pli;
|
|
int bi;
|
|
ptrdiff_t fragi;
|
|
ptrdiff_t frag_offs;
|
|
int borderi;
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO];
|
|
ref=_enc->state.ref_frame_data[OC_FRAME_PREV];
|
|
ystride=_enc->state.ref_ystride[0];
|
|
frags=_enc->state.frags;
|
|
frag_buf_offs=_enc->state.frag_buf_offs;
|
|
sb_map=_enc->state.sb_maps[_mbi>>2][_mbi&3];
|
|
mvs=_enc->mb_info[_mbi].block_mv;
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_map[bi];
|
|
borderi=frags[fragi].borderi;
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(borderi<0){
|
|
uncoded_ssd=oc_enc_frag_ssd(_enc,src+frag_offs,ref+frag_offs,ystride);
|
|
}
|
|
else{
|
|
uncoded_ssd=oc_enc_frag_border_ssd(_enc,
|
|
src+frag_offs,ref+frag_offs,ystride,_enc->state.borders[borderi].mask);
|
|
}
|
|
/*Scale to match DCT domain and RD.*/
|
|
uncoded_ssd=OC_RD_SKIP_SCALE(uncoded_ssd,_rd_scale[bi]);
|
|
/*Motion is a special case; if there is more than a full-pixel motion
|
|
against the prior frame, penalize skipping.
|
|
TODO: The factor of two here is a kludge, but it tested out better than a
|
|
hard limit.*/
|
|
if(mvs[bi]!=0)uncoded_ssd*=2;
|
|
_pipe->skip_ssd[0][fragi-_pipe->froffset[0]]=_ssd[bi]=uncoded_ssd;
|
|
}
|
|
mb_map=(const oc_mb_map_plane *)_enc->state.mb_maps[_mbi];
|
|
map_nidxs=OC_MB_MAP_NIDXS[_enc->state.info.pixel_fmt];
|
|
map_idxs=OC_MB_MAP_IDXS[_enc->state.info.pixel_fmt];
|
|
map_nidxs=(map_nidxs-4>>1)+4;
|
|
mapii=4;
|
|
mvs=_enc->mb_info[_mbi].unref_mv;
|
|
for(pli=1;pli<3;pli++){
|
|
ystride=_enc->state.ref_ystride[pli];
|
|
for(;mapii<map_nidxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
bi=mapi&3;
|
|
fragi=mb_map[pli][bi];
|
|
borderi=frags[fragi].borderi;
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(borderi<0){
|
|
uncoded_ssd=oc_enc_frag_ssd(_enc,src+frag_offs,ref+frag_offs,ystride);
|
|
}
|
|
else{
|
|
uncoded_ssd=oc_enc_frag_border_ssd(_enc,
|
|
src+frag_offs,ref+frag_offs,ystride,_enc->state.borders[borderi].mask);
|
|
}
|
|
/*Scale to match DCT domain and RD.*/
|
|
uncoded_ssd=OC_RD_SKIP_SCALE(uncoded_ssd,_rd_scale[4]);
|
|
/*Motion is a special case; if there is more than a full-pixel motion
|
|
against the prior frame, penalize skipping.
|
|
TODO: The factor of two here is a kludge, but it tested out better than
|
|
a hard limit*/
|
|
if(mvs[OC_FRAME_PREV]!=0)uncoded_ssd*=2;
|
|
_pipe->skip_ssd[pli][fragi-_pipe->froffset[pli]]=_ssd[mapii]=uncoded_ssd;
|
|
}
|
|
map_nidxs=(map_nidxs-4<<1)+4;
|
|
}
|
|
}
|
|
|
|
|
|
static void oc_cost_intra(oc_enc_ctx *_enc,oc_mode_choice *_modec,
|
|
unsigned _mbi,const oc_fr_state *_fr,const oc_qii_state *_qs,
|
|
const unsigned _frag_satd[12],const unsigned _skip_ssd[12],
|
|
const unsigned _rd_scale[5]){
|
|
oc_analyze_mb_mode_luma(_enc,_modec,_fr,_qs,_frag_satd,_skip_ssd,_rd_scale,0);
|
|
oc_analyze_mb_mode_chroma(_enc,_modec,_fr,_qs,
|
|
_frag_satd,_skip_ssd,_rd_scale[4],0);
|
|
_modec->overhead=
|
|
oc_mode_scheme_chooser_cost(&_enc->chooser,OC_MODE_INTRA)<<OC_BIT_SCALE;
|
|
oc_mode_set_cost(_modec,_enc->lambda);
|
|
}
|
|
|
|
static void oc_cost_inter(oc_enc_ctx *_enc,oc_mode_choice *_modec,
|
|
unsigned _mbi,int _mb_mode,oc_mv _mv,
|
|
const oc_fr_state *_fr,const oc_qii_state *_qs,
|
|
const unsigned _skip_ssd[12],const unsigned _rd_scale[5]){
|
|
unsigned frag_satd[12];
|
|
const unsigned char *src;
|
|
const unsigned char *ref;
|
|
int ystride;
|
|
const ptrdiff_t *frag_buf_offs;
|
|
const ptrdiff_t *sb_map;
|
|
const oc_mb_map_plane *mb_map;
|
|
const unsigned char *map_idxs;
|
|
int map_nidxs;
|
|
int mapii;
|
|
int mapi;
|
|
int mv_offs[2];
|
|
int pli;
|
|
int bi;
|
|
ptrdiff_t fragi;
|
|
ptrdiff_t frag_offs;
|
|
int dc;
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO];
|
|
ref=_enc->state.ref_frame_data[OC_FRAME_FOR_MODE(_mb_mode)];
|
|
ystride=_enc->state.ref_ystride[0];
|
|
frag_buf_offs=_enc->state.frag_buf_offs;
|
|
sb_map=_enc->state.sb_maps[_mbi>>2][_mbi&3];
|
|
_modec->rate=_modec->ssd=0;
|
|
if(oc_state_get_mv_offsets(&_enc->state,mv_offs,0,_mv)>1){
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_map[bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(_enc->sp_level<OC_SP_LEVEL_NOSATD){
|
|
frag_satd[bi]=oc_enc_frag_satd2(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ref+frag_offs+mv_offs[1],ystride);
|
|
frag_satd[bi]+=abs(dc);
|
|
}
|
|
else{
|
|
frag_satd[bi]=oc_enc_frag_sad2_thresh(_enc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ref+frag_offs+mv_offs[1],ystride,UINT_MAX);
|
|
}
|
|
}
|
|
}
|
|
else{
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_map[bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(_enc->sp_level<OC_SP_LEVEL_NOSATD){
|
|
frag_satd[bi]=oc_enc_frag_satd(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ystride);
|
|
frag_satd[bi]+=abs(dc);
|
|
}
|
|
else{
|
|
frag_satd[bi]=oc_enc_frag_sad(_enc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ystride);
|
|
}
|
|
}
|
|
}
|
|
mb_map=(const oc_mb_map_plane *)_enc->state.mb_maps[_mbi];
|
|
map_idxs=OC_MB_MAP_IDXS[_enc->state.info.pixel_fmt];
|
|
map_nidxs=OC_MB_MAP_NIDXS[_enc->state.info.pixel_fmt];
|
|
/*Note: This assumes ref_ystride[1]==ref_ystride[2].*/
|
|
ystride=_enc->state.ref_ystride[1];
|
|
if(oc_state_get_mv_offsets(&_enc->state,mv_offs,1,_mv)>1){
|
|
for(mapii=4;mapii<map_nidxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
pli=mapi>>2;
|
|
bi=mapi&3;
|
|
fragi=mb_map[pli][bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(_enc->sp_level<OC_SP_LEVEL_NOSATD){
|
|
frag_satd[mapii]=oc_enc_frag_satd2(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ref+frag_offs+mv_offs[1],ystride);
|
|
frag_satd[mapii]+=abs(dc);
|
|
}
|
|
else{
|
|
frag_satd[mapii]=oc_enc_frag_sad2_thresh(_enc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ref+frag_offs+mv_offs[1],ystride,UINT_MAX);
|
|
}
|
|
}
|
|
}
|
|
else{
|
|
for(mapii=4;mapii<map_nidxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
pli=mapi>>2;
|
|
bi=mapi&3;
|
|
fragi=mb_map[pli][bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(_enc->sp_level<OC_SP_LEVEL_NOSATD){
|
|
frag_satd[mapii]=oc_enc_frag_satd(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ystride);
|
|
frag_satd[mapii]+=abs(dc);
|
|
}
|
|
else{
|
|
frag_satd[mapii]=oc_enc_frag_sad(_enc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ystride);
|
|
}
|
|
}
|
|
}
|
|
oc_analyze_mb_mode_luma(_enc,_modec,_fr,_qs,frag_satd,_skip_ssd,_rd_scale,1);
|
|
oc_analyze_mb_mode_chroma(_enc,_modec,_fr,_qs,
|
|
frag_satd,_skip_ssd,_rd_scale[4],1);
|
|
_modec->overhead=
|
|
oc_mode_scheme_chooser_cost(&_enc->chooser,_mb_mode)<<OC_BIT_SCALE;
|
|
oc_mode_set_cost(_modec,_enc->lambda);
|
|
}
|
|
|
|
static void oc_cost_inter_nomv(oc_enc_ctx *_enc,oc_mode_choice *_modec,
|
|
unsigned _mbi,int _mb_mode,const oc_fr_state *_fr,const oc_qii_state *_qs,
|
|
const unsigned _skip_ssd[12],const unsigned _rd_scale[4]){
|
|
oc_cost_inter(_enc,_modec,_mbi,_mb_mode,0,_fr,_qs,_skip_ssd,_rd_scale);
|
|
}
|
|
|
|
static int oc_cost_inter1mv(oc_enc_ctx *_enc,oc_mode_choice *_modec,
|
|
unsigned _mbi,int _mb_mode,oc_mv _mv,
|
|
const oc_fr_state *_fr,const oc_qii_state *_qs,const unsigned _skip_ssd[12],
|
|
const unsigned _rd_scale[4]){
|
|
int bits0;
|
|
oc_cost_inter(_enc,_modec,_mbi,_mb_mode,_mv,_fr,_qs,_skip_ssd,_rd_scale);
|
|
bits0=OC_MV_BITS[0][OC_MV_X(_mv)+31]+OC_MV_BITS[0][OC_MV_Y(_mv)+31];
|
|
_modec->overhead+=OC_MINI(_enc->mv_bits[0]+bits0,_enc->mv_bits[1]+12)
|
|
-OC_MINI(_enc->mv_bits[0],_enc->mv_bits[1])<<OC_BIT_SCALE;
|
|
oc_mode_set_cost(_modec,_enc->lambda);
|
|
return bits0;
|
|
}
|
|
|
|
/*A mapping from oc_mb_map (raster) ordering to oc_sb_map (Hilbert) ordering.*/
|
|
static const unsigned char OC_MB_PHASE[4][4]={
|
|
{0,1,3,2},{0,3,1,2},{0,3,1,2},{2,3,1,0}
|
|
};
|
|
|
|
static void oc_cost_inter4mv(oc_enc_ctx *_enc,oc_mode_choice *_modec,
|
|
unsigned _mbi,oc_mv _mv[4],const oc_fr_state *_fr,const oc_qii_state *_qs,
|
|
const unsigned _skip_ssd[12],const unsigned _rd_scale[5]){
|
|
unsigned frag_satd[12];
|
|
oc_mv lbmvs[4];
|
|
oc_mv cbmvs[4];
|
|
const unsigned char *src;
|
|
const unsigned char *ref;
|
|
int ystride;
|
|
const ptrdiff_t *frag_buf_offs;
|
|
oc_mv *frag_mvs;
|
|
const oc_mb_map_plane *mb_map;
|
|
const unsigned char *map_idxs;
|
|
int map_nidxs;
|
|
int nqis;
|
|
int mapii;
|
|
int mapi;
|
|
int mv_offs[2];
|
|
int pli;
|
|
int bi;
|
|
ptrdiff_t fragi;
|
|
ptrdiff_t frag_offs;
|
|
int bits0;
|
|
int bits1;
|
|
unsigned satd;
|
|
int dc;
|
|
src=_enc->state.ref_frame_data[OC_FRAME_IO];
|
|
ref=_enc->state.ref_frame_data[OC_FRAME_PREV];
|
|
ystride=_enc->state.ref_ystride[0];
|
|
frag_buf_offs=_enc->state.frag_buf_offs;
|
|
frag_mvs=_enc->state.frag_mvs;
|
|
mb_map=(const oc_mb_map_plane *)_enc->state.mb_maps[_mbi];
|
|
_modec->rate=_modec->ssd=0;
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=mb_map[0][bi];
|
|
/*Save the block MVs as the current ones while we're here; we'll replace
|
|
them if we don't ultimately choose 4MV mode.*/
|
|
frag_mvs[fragi]=_mv[bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
if(oc_state_get_mv_offsets(&_enc->state,mv_offs,0,_mv[bi])>1){
|
|
satd=oc_enc_frag_satd2(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ref+frag_offs+mv_offs[1],ystride);
|
|
}
|
|
else{
|
|
satd=oc_enc_frag_satd(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ystride);
|
|
}
|
|
frag_satd[OC_MB_PHASE[_mbi&3][bi]]=satd+abs(dc);
|
|
}
|
|
oc_analyze_mb_mode_luma(_enc,_modec,_fr,_qs,frag_satd,
|
|
_enc->vp3_compatible?OC_NOSKIP:_skip_ssd,_rd_scale,1);
|
|
/*Figure out which blocks are being skipped and give them (0,0) MVs.*/
|
|
bits0=0;
|
|
bits1=0;
|
|
nqis=_enc->state.nqis;
|
|
for(bi=0;bi<4;bi++){
|
|
if(_modec->qii[OC_MB_PHASE[_mbi&3][bi]]>=nqis)lbmvs[bi]=0;
|
|
else{
|
|
lbmvs[bi]=_mv[bi];
|
|
bits0+=OC_MV_BITS[0][OC_MV_X(_mv[bi])+31]
|
|
+OC_MV_BITS[0][OC_MV_Y(_mv[bi])+31];
|
|
bits1+=12;
|
|
}
|
|
}
|
|
(*OC_SET_CHROMA_MVS_TABLE[_enc->state.info.pixel_fmt])(cbmvs,lbmvs);
|
|
map_idxs=OC_MB_MAP_IDXS[_enc->state.info.pixel_fmt];
|
|
map_nidxs=OC_MB_MAP_NIDXS[_enc->state.info.pixel_fmt];
|
|
/*Note: This assumes ref_ystride[1]==ref_ystride[2].*/
|
|
ystride=_enc->state.ref_ystride[1];
|
|
for(mapii=4;mapii<map_nidxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
pli=mapi>>2;
|
|
bi=mapi&3;
|
|
fragi=mb_map[pli][bi];
|
|
frag_offs=frag_buf_offs[fragi];
|
|
/*TODO: We could save half these calls by re-using the results for the Cb
|
|
and Cr planes; is it worth it?*/
|
|
if(oc_state_get_mv_offsets(&_enc->state,mv_offs,pli,cbmvs[bi])>1){
|
|
satd=oc_enc_frag_satd2(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ref+frag_offs+mv_offs[1],ystride);
|
|
}
|
|
else{
|
|
satd=oc_enc_frag_satd(_enc,&dc,src+frag_offs,
|
|
ref+frag_offs+mv_offs[0],ystride);
|
|
}
|
|
frag_satd[mapii]=satd+abs(dc);
|
|
}
|
|
oc_analyze_mb_mode_chroma(_enc,_modec,_fr,_qs,
|
|
frag_satd,_skip_ssd,_rd_scale[4],1);
|
|
_modec->overhead=
|
|
oc_mode_scheme_chooser_cost(&_enc->chooser,OC_MODE_INTER_MV_FOUR)
|
|
+OC_MINI(_enc->mv_bits[0]+bits0,_enc->mv_bits[1]+bits1)
|
|
-OC_MINI(_enc->mv_bits[0],_enc->mv_bits[1])<<OC_BIT_SCALE;
|
|
oc_mode_set_cost(_modec,_enc->lambda);
|
|
}
|
|
|
|
int oc_enc_analyze_inter(oc_enc_ctx *_enc,int _allow_keyframe,int _recode){
|
|
oc_set_chroma_mvs_func set_chroma_mvs;
|
|
oc_qii_state intra_luma_qs;
|
|
oc_mv last_mv;
|
|
oc_mv prior_mv;
|
|
ogg_int64_t interbits;
|
|
ogg_int64_t intrabits;
|
|
ogg_int64_t activity_sum;
|
|
ogg_int64_t luma_sum;
|
|
unsigned activity_avg;
|
|
unsigned luma_avg;
|
|
const ogg_uint16_t *chroma_rd_scale;
|
|
ogg_uint16_t *mcu_rd_scale;
|
|
ogg_uint16_t *mcu_rd_iscale;
|
|
const unsigned char *map_idxs;
|
|
int nmap_idxs;
|
|
unsigned *coded_mbis;
|
|
unsigned *uncoded_mbis;
|
|
size_t ncoded_mbis;
|
|
size_t nuncoded_mbis;
|
|
oc_sb_flags *sb_flags;
|
|
signed char *mb_modes;
|
|
const oc_sb_map *sb_maps;
|
|
const oc_mb_map *mb_maps;
|
|
oc_mb_enc_info *embs;
|
|
oc_fragment *frags;
|
|
oc_mv *frag_mvs;
|
|
unsigned stripe_sby;
|
|
unsigned mcu_nvsbs;
|
|
int notstart;
|
|
int notdone;
|
|
unsigned sbi;
|
|
unsigned sbi_end;
|
|
int refi;
|
|
int pli;
|
|
int sp_level;
|
|
sp_level=_enc->sp_level;
|
|
set_chroma_mvs=OC_SET_CHROMA_MVS_TABLE[_enc->state.info.pixel_fmt];
|
|
_enc->state.frame_type=OC_INTER_FRAME;
|
|
oc_mode_scheme_chooser_reset(&_enc->chooser);
|
|
oc_enc_tokenize_start(_enc);
|
|
oc_enc_pipeline_init(_enc,&_enc->pipe);
|
|
oc_enc_mode_rd_init(_enc);
|
|
if(_allow_keyframe)oc_qii_state_init(&intra_luma_qs);
|
|
_enc->mv_bits[0]=_enc->mv_bits[1]=0;
|
|
interbits=intrabits=0;
|
|
activity_sum=luma_sum=0;
|
|
activity_avg=_enc->activity_avg;
|
|
luma_avg=OC_CLAMPI(90<<8,_enc->luma_avg,160<<8);
|
|
chroma_rd_scale=_enc->chroma_rd_scale[OC_INTER_FRAME][_enc->state.qis[0]];
|
|
mcu_rd_scale=_enc->mcu_rd_scale;
|
|
mcu_rd_iscale=_enc->mcu_rd_iscale;
|
|
last_mv=prior_mv=0;
|
|
/*Choose MVs and MB modes and quantize and code luma.
|
|
Must be done in Hilbert order.*/
|
|
map_idxs=OC_MB_MAP_IDXS[_enc->state.info.pixel_fmt];
|
|
nmap_idxs=OC_MB_MAP_NIDXS[_enc->state.info.pixel_fmt];
|
|
coded_mbis=_enc->coded_mbis;
|
|
uncoded_mbis=coded_mbis+_enc->state.nmbs;
|
|
ncoded_mbis=0;
|
|
nuncoded_mbis=0;
|
|
_enc->state.ncoded_fragis[0]=0;
|
|
_enc->state.ncoded_fragis[1]=0;
|
|
_enc->state.ncoded_fragis[2]=0;
|
|
sb_flags=_enc->state.sb_flags;
|
|
mb_modes=_enc->state.mb_modes;
|
|
sb_maps=(const oc_sb_map *)_enc->state.sb_maps;
|
|
mb_maps=(const oc_mb_map *)_enc->state.mb_maps;
|
|
embs=_enc->mb_info;
|
|
frags=_enc->state.frags;
|
|
frag_mvs=_enc->state.frag_mvs;
|
|
notstart=0;
|
|
notdone=1;
|
|
mcu_nvsbs=_enc->mcu_nvsbs;
|
|
for(stripe_sby=0;notdone;stripe_sby+=mcu_nvsbs){
|
|
ptrdiff_t cfroffset;
|
|
notdone=oc_enc_pipeline_set_stripe(_enc,&_enc->pipe,stripe_sby);
|
|
sbi_end=_enc->pipe.sbi_end[0];
|
|
cfroffset=_enc->pipe.froffset[1];
|
|
for(sbi=_enc->pipe.sbi0[0];sbi<sbi_end;sbi++){
|
|
int quadi;
|
|
/*Mode addressing is through Y plane, always 4 MB per SB.*/
|
|
for(quadi=0;quadi<4;quadi++)if(sb_flags[sbi].quad_valid&1<<quadi){
|
|
oc_mode_choice modes[8];
|
|
unsigned activity[4];
|
|
unsigned rd_scale[5];
|
|
unsigned rd_iscale[5];
|
|
unsigned skip_ssd[12];
|
|
unsigned intra_satd[12];
|
|
unsigned luma;
|
|
int mb_mv_bits_0;
|
|
int mb_gmv_bits_0;
|
|
int inter_mv_pref;
|
|
int mb_mode;
|
|
int refi;
|
|
int mv;
|
|
unsigned mbi;
|
|
int mapii;
|
|
int mapi;
|
|
int bi;
|
|
ptrdiff_t fragi;
|
|
mbi=sbi<<2|quadi;
|
|
luma=oc_mb_intra_satd(_enc,mbi,intra_satd);
|
|
/*Activity masking.*/
|
|
if(sp_level<OC_SP_LEVEL_FAST_ANALYSIS){
|
|
oc_mb_activity(_enc,mbi,activity);
|
|
}
|
|
else oc_mb_activity_fast(_enc,mbi,activity,intra_satd);
|
|
luma_sum+=luma;
|
|
activity_sum+=oc_mb_masking(rd_scale,rd_iscale,
|
|
chroma_rd_scale,activity,activity_avg,luma,luma_avg);
|
|
/*Motion estimation:
|
|
We always do a basic 1MV search for all macroblocks, coded or not,
|
|
keyframe or not.*/
|
|
if(!_recode&&sp_level<OC_SP_LEVEL_NOMC)oc_mcenc_search(_enc,mbi);
|
|
mv=0;
|
|
/*Find the block choice with the lowest estimated coding cost.
|
|
If a Cb or Cr block is coded but no Y' block from a macro block then
|
|
the mode MUST be OC_MODE_INTER_NOMV.
|
|
This is the default state to which the mode data structure is
|
|
initialised in encoder and decoder at the start of each frame.*/
|
|
/*Block coding cost is estimated from correlated SATD metrics.*/
|
|
/*At this point, all blocks that are in frame are still marked coded.*/
|
|
if(!_recode){
|
|
embs[mbi].unref_mv[OC_FRAME_GOLD]=
|
|
embs[mbi].analysis_mv[0][OC_FRAME_GOLD];
|
|
embs[mbi].unref_mv[OC_FRAME_PREV]=
|
|
embs[mbi].analysis_mv[0][OC_FRAME_PREV];
|
|
embs[mbi].refined=0;
|
|
}
|
|
/*Estimate the cost of coding this MB in a keyframe.*/
|
|
if(_allow_keyframe){
|
|
oc_cost_intra(_enc,modes+OC_MODE_INTRA,mbi,
|
|
_enc->pipe.fr+0,&intra_luma_qs,intra_satd,OC_NOSKIP,rd_scale);
|
|
intrabits+=modes[OC_MODE_INTRA].rate;
|
|
for(bi=0;bi<4;bi++){
|
|
oc_qii_state_advance(&intra_luma_qs,&intra_luma_qs,
|
|
modes[OC_MODE_INTRA].qii[bi]);
|
|
}
|
|
}
|
|
/*Estimate the cost in a delta frame for various modes.*/
|
|
oc_skip_cost(_enc,&_enc->pipe,mbi,rd_scale,skip_ssd);
|
|
if(sp_level<OC_SP_LEVEL_NOMC){
|
|
oc_cost_inter_nomv(_enc,modes+OC_MODE_INTER_NOMV,mbi,
|
|
OC_MODE_INTER_NOMV,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
oc_cost_intra(_enc,modes+OC_MODE_INTRA,mbi,
|
|
_enc->pipe.fr+0,_enc->pipe.qs+0,intra_satd,skip_ssd,rd_scale);
|
|
mb_mv_bits_0=oc_cost_inter1mv(_enc,modes+OC_MODE_INTER_MV,mbi,
|
|
OC_MODE_INTER_MV,embs[mbi].unref_mv[OC_FRAME_PREV],
|
|
_enc->pipe.fr+0,_enc->pipe.qs+0,skip_ssd,rd_scale);
|
|
oc_cost_inter(_enc,modes+OC_MODE_INTER_MV_LAST,mbi,
|
|
OC_MODE_INTER_MV_LAST,last_mv,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
oc_cost_inter(_enc,modes+OC_MODE_INTER_MV_LAST2,mbi,
|
|
OC_MODE_INTER_MV_LAST2,prior_mv,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
oc_cost_inter_nomv(_enc,modes+OC_MODE_GOLDEN_NOMV,mbi,
|
|
OC_MODE_GOLDEN_NOMV,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
mb_gmv_bits_0=oc_cost_inter1mv(_enc,modes+OC_MODE_GOLDEN_MV,mbi,
|
|
OC_MODE_GOLDEN_MV,embs[mbi].unref_mv[OC_FRAME_GOLD],
|
|
_enc->pipe.fr+0,_enc->pipe.qs+0,skip_ssd,rd_scale);
|
|
/*The explicit MV modes (2,6,7) have not yet gone through halfpel
|
|
refinement.
|
|
We choose the explicit MV mode that's already furthest ahead on
|
|
R-D cost and refine only that one.
|
|
We have to be careful to remember which ones we've refined so that
|
|
we don't refine it again if we re-encode this frame.*/
|
|
inter_mv_pref=_enc->lambda*3;
|
|
if(sp_level<OC_SP_LEVEL_FAST_ANALYSIS){
|
|
oc_cost_inter4mv(_enc,modes+OC_MODE_INTER_MV_FOUR,mbi,
|
|
embs[mbi].block_mv,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
}
|
|
else{
|
|
modes[OC_MODE_INTER_MV_FOUR].cost=UINT_MAX;
|
|
}
|
|
if(modes[OC_MODE_INTER_MV_FOUR].cost<modes[OC_MODE_INTER_MV].cost&&
|
|
modes[OC_MODE_INTER_MV_FOUR].cost<modes[OC_MODE_GOLDEN_MV].cost){
|
|
if(!(embs[mbi].refined&0x80)){
|
|
oc_mcenc_refine4mv(_enc,mbi);
|
|
embs[mbi].refined|=0x80;
|
|
}
|
|
oc_cost_inter4mv(_enc,modes+OC_MODE_INTER_MV_FOUR,mbi,
|
|
embs[mbi].ref_mv,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
}
|
|
else if(modes[OC_MODE_GOLDEN_MV].cost+inter_mv_pref<
|
|
modes[OC_MODE_INTER_MV].cost){
|
|
if(!(embs[mbi].refined&0x40)){
|
|
oc_mcenc_refine1mv(_enc,mbi,OC_FRAME_GOLD);
|
|
embs[mbi].refined|=0x40;
|
|
}
|
|
mb_gmv_bits_0=oc_cost_inter1mv(_enc,modes+OC_MODE_GOLDEN_MV,mbi,
|
|
OC_MODE_GOLDEN_MV,embs[mbi].analysis_mv[0][OC_FRAME_GOLD],
|
|
_enc->pipe.fr+0,_enc->pipe.qs+0,skip_ssd,rd_scale);
|
|
}
|
|
if(!(embs[mbi].refined&0x04)){
|
|
oc_mcenc_refine1mv(_enc,mbi,OC_FRAME_PREV);
|
|
embs[mbi].refined|=0x04;
|
|
}
|
|
mb_mv_bits_0=oc_cost_inter1mv(_enc,modes+OC_MODE_INTER_MV,mbi,
|
|
OC_MODE_INTER_MV,embs[mbi].analysis_mv[0][OC_FRAME_PREV],
|
|
_enc->pipe.fr+0,_enc->pipe.qs+0,skip_ssd,rd_scale);
|
|
/*Finally, pick the mode with the cheapest estimated R-D cost.*/
|
|
mb_mode=OC_MODE_INTER_NOMV;
|
|
if(modes[OC_MODE_INTRA].cost<modes[OC_MODE_INTER_NOMV].cost){
|
|
mb_mode=OC_MODE_INTRA;
|
|
}
|
|
if(modes[OC_MODE_INTER_MV_LAST].cost<modes[mb_mode].cost){
|
|
mb_mode=OC_MODE_INTER_MV_LAST;
|
|
}
|
|
if(modes[OC_MODE_INTER_MV_LAST2].cost<modes[mb_mode].cost){
|
|
mb_mode=OC_MODE_INTER_MV_LAST2;
|
|
}
|
|
if(modes[OC_MODE_GOLDEN_NOMV].cost<modes[mb_mode].cost){
|
|
mb_mode=OC_MODE_GOLDEN_NOMV;
|
|
}
|
|
if(modes[OC_MODE_GOLDEN_MV].cost<modes[mb_mode].cost){
|
|
mb_mode=OC_MODE_GOLDEN_MV;
|
|
}
|
|
if(modes[OC_MODE_INTER_MV_FOUR].cost<modes[mb_mode].cost){
|
|
mb_mode=OC_MODE_INTER_MV_FOUR;
|
|
}
|
|
/*We prefer OC_MODE_INTER_MV, but not over LAST and LAST2.*/
|
|
if(mb_mode==OC_MODE_INTER_MV_LAST||mb_mode==OC_MODE_INTER_MV_LAST2){
|
|
inter_mv_pref=0;
|
|
}
|
|
if(modes[OC_MODE_INTER_MV].cost<modes[mb_mode].cost+inter_mv_pref){
|
|
mb_mode=OC_MODE_INTER_MV;
|
|
}
|
|
}
|
|
else{
|
|
oc_cost_inter_nomv(_enc,modes+OC_MODE_INTER_NOMV,mbi,
|
|
OC_MODE_INTER_NOMV,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
oc_cost_intra(_enc,modes+OC_MODE_INTRA,mbi,
|
|
_enc->pipe.fr+0,_enc->pipe.qs+0,intra_satd,skip_ssd,rd_scale);
|
|
oc_cost_inter_nomv(_enc,modes+OC_MODE_GOLDEN_NOMV,mbi,
|
|
OC_MODE_GOLDEN_NOMV,_enc->pipe.fr+0,_enc->pipe.qs+0,
|
|
skip_ssd,rd_scale);
|
|
mb_mode=OC_MODE_INTER_NOMV;
|
|
if(modes[OC_MODE_INTRA].cost<modes[OC_MODE_INTER_NOMV].cost){
|
|
mb_mode=OC_MODE_INTRA;
|
|
}
|
|
if(modes[OC_MODE_GOLDEN_NOMV].cost<modes[mb_mode].cost){
|
|
mb_mode=OC_MODE_GOLDEN_NOMV;
|
|
}
|
|
mb_mv_bits_0=mb_gmv_bits_0=0;
|
|
}
|
|
mb_modes[mbi]=mb_mode;
|
|
/*Propagate the MVs to the luma blocks.*/
|
|
if(mb_mode!=OC_MODE_INTER_MV_FOUR){
|
|
switch(mb_mode){
|
|
case OC_MODE_INTER_MV:{
|
|
mv=embs[mbi].analysis_mv[0][OC_FRAME_PREV];
|
|
}break;
|
|
case OC_MODE_INTER_MV_LAST:mv=last_mv;break;
|
|
case OC_MODE_INTER_MV_LAST2:mv=prior_mv;break;
|
|
case OC_MODE_GOLDEN_MV:{
|
|
mv=embs[mbi].analysis_mv[0][OC_FRAME_GOLD];
|
|
}break;
|
|
}
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=mb_maps[mbi][0][bi];
|
|
frag_mvs[fragi]=mv;
|
|
}
|
|
}
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=sb_maps[mbi>>2][mbi&3][bi];
|
|
frags[fragi].qii=modes[mb_mode].qii[bi];
|
|
}
|
|
if(oc_enc_mb_transform_quantize_inter_luma(_enc,&_enc->pipe,mbi,
|
|
modes[mb_mode].overhead>>OC_BIT_SCALE,rd_scale,rd_iscale)>0){
|
|
int orig_mb_mode;
|
|
orig_mb_mode=mb_mode;
|
|
mb_mode=mb_modes[mbi];
|
|
refi=OC_FRAME_FOR_MODE(mb_mode);
|
|
switch(mb_mode){
|
|
case OC_MODE_INTER_MV:{
|
|
prior_mv=last_mv;
|
|
/*If we're backing out from 4MV, find the MV we're actually
|
|
using.*/
|
|
if(orig_mb_mode==OC_MODE_INTER_MV_FOUR){
|
|
for(bi=0;;bi++){
|
|
fragi=mb_maps[mbi][0][bi];
|
|
if(frags[fragi].coded){
|
|
mv=last_mv=frag_mvs[fragi];
|
|
break;
|
|
}
|
|
}
|
|
mb_mv_bits_0=OC_MV_BITS[0][OC_MV_X(mv)+31]
|
|
+OC_MV_BITS[0][OC_MV_Y(mv)+31];
|
|
}
|
|
/*Otherwise we used the original analysis MV.*/
|
|
else last_mv=embs[mbi].analysis_mv[0][OC_FRAME_PREV];
|
|
_enc->mv_bits[0]+=mb_mv_bits_0;
|
|
_enc->mv_bits[1]+=12;
|
|
}break;
|
|
case OC_MODE_INTER_MV_LAST2:{
|
|
oc_mv tmp_mv;
|
|
tmp_mv=prior_mv;
|
|
prior_mv=last_mv;
|
|
last_mv=tmp_mv;
|
|
}break;
|
|
case OC_MODE_GOLDEN_MV:{
|
|
_enc->mv_bits[0]+=mb_gmv_bits_0;
|
|
_enc->mv_bits[1]+=12;
|
|
}break;
|
|
case OC_MODE_INTER_MV_FOUR:{
|
|
oc_mv lbmvs[4];
|
|
oc_mv cbmvs[4];
|
|
prior_mv=last_mv;
|
|
for(bi=0;bi<4;bi++){
|
|
fragi=mb_maps[mbi][0][bi];
|
|
if(frags[fragi].coded){
|
|
lbmvs[bi]=last_mv=frag_mvs[fragi];
|
|
_enc->mv_bits[0]+=OC_MV_BITS[0][OC_MV_X(last_mv)+31]
|
|
+OC_MV_BITS[0][OC_MV_Y(last_mv)+31];
|
|
_enc->mv_bits[1]+=12;
|
|
}
|
|
/*Replace the block MVs for not-coded blocks with (0,0).*/
|
|
else lbmvs[bi]=0;
|
|
}
|
|
(*set_chroma_mvs)(cbmvs,lbmvs);
|
|
for(mapii=4;mapii<nmap_idxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
pli=mapi>>2;
|
|
bi=mapi&3;
|
|
fragi=mb_maps[mbi][pli][bi];
|
|
frags[fragi].qii=modes[OC_MODE_INTER_MV_FOUR].qii[mapii];
|
|
frags[fragi].refi=refi;
|
|
frags[fragi].mb_mode=mb_mode;
|
|
frag_mvs[fragi]=cbmvs[bi];
|
|
}
|
|
}break;
|
|
}
|
|
coded_mbis[ncoded_mbis++]=mbi;
|
|
oc_mode_scheme_chooser_update(&_enc->chooser,mb_mode);
|
|
interbits+=modes[mb_mode].rate+modes[mb_mode].overhead;
|
|
}
|
|
else{
|
|
*(uncoded_mbis-++nuncoded_mbis)=mbi;
|
|
mb_mode=OC_MODE_INTER_NOMV;
|
|
refi=OC_FRAME_PREV;
|
|
mv=0;
|
|
}
|
|
/*Propagate final MB mode and MVs to the chroma blocks.
|
|
This has already been done for 4MV mode, since it requires individual
|
|
block motion vectors.*/
|
|
if(mb_mode!=OC_MODE_INTER_MV_FOUR){
|
|
for(mapii=4;mapii<nmap_idxs;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
pli=mapi>>2;
|
|
bi=mapi&3;
|
|
fragi=mb_maps[mbi][pli][bi];
|
|
/*If we switched from 4MV mode to INTER_MV mode, then the qii
|
|
values won't have been chosen with the right MV, but it's
|
|
probaby not worth re-estimating them.*/
|
|
frags[fragi].qii=modes[mb_mode].qii[mapii];
|
|
frags[fragi].refi=refi;
|
|
frags[fragi].mb_mode=mb_mode;
|
|
frag_mvs[fragi]=mv;
|
|
}
|
|
}
|
|
/*Save masking scale factors for chroma blocks.*/
|
|
for(mapii=4;mapii<(nmap_idxs-4>>1)+4;mapii++){
|
|
mapi=map_idxs[mapii];
|
|
bi=mapi&3;
|
|
fragi=mb_maps[mbi][1][bi];
|
|
mcu_rd_scale[fragi-cfroffset]=(ogg_uint16_t)rd_scale[4];
|
|
mcu_rd_iscale[fragi-cfroffset]=(ogg_uint16_t)rd_iscale[4];
|
|
}
|
|
}
|
|
oc_fr_state_flush_sb(_enc->pipe.fr+0);
|
|
sb_flags[sbi].coded_fully=_enc->pipe.fr[0].sb_full;
|
|
sb_flags[sbi].coded_partially=_enc->pipe.fr[0].sb_partial;
|
|
}
|
|
oc_enc_pipeline_finish_mcu_plane(_enc,&_enc->pipe,0,notstart,notdone);
|
|
/*Code chroma planes.*/
|
|
for(pli=1;pli<3;pli++){
|
|
oc_enc_sb_transform_quantize_inter_chroma(_enc,&_enc->pipe,
|
|
pli,_enc->pipe.sbi0[pli],_enc->pipe.sbi_end[pli]);
|
|
oc_enc_pipeline_finish_mcu_plane(_enc,&_enc->pipe,pli,notstart,notdone);
|
|
}
|
|
notstart=1;
|
|
}
|
|
/*Update the average block activity and MB luma score for the frame.
|
|
We could use a Bessel follower here, but fast reaction is probably almost
|
|
always best.*/
|
|
_enc->activity_avg=OC_MAXI(OC_ACTIVITY_AVG_MIN,
|
|
(unsigned)((activity_sum+(_enc->state.fplanes[0].nfrags>>1))/
|
|
_enc->state.fplanes[0].nfrags));
|
|
_enc->luma_avg=(unsigned)((luma_sum+(_enc->state.nmbs>>1))/_enc->state.nmbs);
|
|
/*Finish filling in the reference frame borders.*/
|
|
refi=_enc->state.ref_frame_idx[OC_FRAME_SELF];
|
|
for(pli=0;pli<3;pli++)oc_state_borders_fill_caps(&_enc->state,refi,pli);
|
|
/*Finish adding flagging overhead costs to inter bit counts to determine if
|
|
we should have coded a key frame instead.*/
|
|
if(_allow_keyframe){
|
|
/*Technically the chroma plane counts are over-estimations, because they
|
|
don't account for continuing runs from the luma planes, but the
|
|
inaccuracy is small.
|
|
We don't need to add the luma plane coding flag costs, because they are
|
|
already included in the MB rate estimates.*/
|
|
for(pli=1;pli<3;pli++)interbits+=_enc->pipe.fr[pli].bits<<OC_BIT_SCALE;
|
|
if(interbits>intrabits)return 1;
|
|
}
|
|
_enc->ncoded_mbis=ncoded_mbis;
|
|
/*Compact the coded fragment list.*/
|
|
{
|
|
ptrdiff_t ncoded_fragis;
|
|
ncoded_fragis=_enc->state.ncoded_fragis[0];
|
|
for(pli=1;pli<3;pli++){
|
|
memmove(_enc->state.coded_fragis+ncoded_fragis,
|
|
_enc->state.coded_fragis+_enc->state.fplanes[pli].froffset,
|
|
_enc->state.ncoded_fragis[pli]*sizeof(*_enc->state.coded_fragis));
|
|
ncoded_fragis+=_enc->state.ncoded_fragis[pli];
|
|
}
|
|
_enc->state.ntotal_coded_fragis=ncoded_fragis;
|
|
}
|
|
return 0;
|
|
}
|