cfcc8a20e8
Same rationale as the previous commits.
1227 lines
44 KiB
C
1227 lines
44 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 and contributors http://www.xiph.org/ *
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* *
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********************************************************************
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function:
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last mod: $Id: state.c 16503 2009-08-22 18:14:02Z giles $
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********************************************************************/
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#include <stdlib.h>
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#include <string.h>
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#include "internal.h"
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#if defined(OC_X86_ASM)
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#if defined(_MSC_VER)
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# include "x86_vc/x86int.h"
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#else
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# include "x86/x86int.h"
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#endif
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#endif
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#if defined(OC_DUMP_IMAGES)
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# include <stdio.h>
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# include "png.h"
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#endif
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/*Returns the fragment index of the top-left block in a macro block.
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This can be used to test whether or not the whole macro block is valid.
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_sb_map: The super block map.
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_quadi: The quadrant number.
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Return: The index of the fragment of the upper left block in the macro
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block, or -1 if the block lies outside the coded frame.*/
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static ptrdiff_t oc_sb_quad_top_left_frag(oc_sb_map_quad _sb_map[4],int _quadi){
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/*It so happens that under the Hilbert curve ordering described below, the
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upper-left block in each macro block is at index 0, except in macro block
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3, where it is at index 2.*/
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return _sb_map[_quadi][_quadi&_quadi<<1];
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}
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/*Fills in the mapping from block positions to fragment numbers for a single
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color plane.
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This function also fills in the "valid" flag of each quadrant in the super
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block flags.
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_sb_maps: The array of super block maps for the color plane.
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_sb_flags: The array of super block flags for the color plane.
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_frag0: The index of the first fragment in the plane.
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_hfrags: The number of horizontal fragments in a coded frame.
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_vfrags: The number of vertical fragments in a coded frame.*/
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static void oc_sb_create_plane_mapping(oc_sb_map _sb_maps[],
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oc_sb_flags _sb_flags[],ptrdiff_t _frag0,int _hfrags,int _vfrags){
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/*Contains the (macro_block,block) indices for a 4x4 grid of
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fragments.
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The pattern is a 4x4 Hilbert space-filling curve.
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A Hilbert curve has the nice property that as the curve grows larger, its
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fractal dimension approaches 2.
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The intuition is that nearby blocks in the curve are also close spatially,
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with the previous element always an immediate neighbor, so that runs of
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blocks should be well correlated.*/
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static const int SB_MAP[4][4][2]={
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{{0,0},{0,1},{3,2},{3,3}},
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{{0,3},{0,2},{3,1},{3,0}},
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{{1,0},{1,3},{2,0},{2,3}},
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{{1,1},{1,2},{2,1},{2,2}}
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};
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ptrdiff_t yfrag;
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unsigned sbi;
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int y;
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sbi=0;
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yfrag=_frag0;
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for(y=0;;y+=4){
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int imax;
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int x;
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/*Figure out how many columns of blocks in this super block lie within the
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image.*/
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imax=_vfrags-y;
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if(imax>4)imax=4;
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else if(imax<=0)break;
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for(x=0;;x+=4,sbi++){
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ptrdiff_t xfrag;
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int jmax;
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int quadi;
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int i;
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/*Figure out how many rows of blocks in this super block lie within the
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image.*/
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jmax=_hfrags-x;
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if(jmax>4)jmax=4;
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else if(jmax<=0)break;
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/*By default, set all fragment indices to -1.*/
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memset(_sb_maps[sbi][0],0xFF,sizeof(_sb_maps[sbi]));
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/*Fill in the fragment map for this super block.*/
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xfrag=yfrag+x;
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for(i=0;i<imax;i++){
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int j;
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for(j=0;j<jmax;j++){
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_sb_maps[sbi][SB_MAP[i][j][0]][SB_MAP[i][j][1]]=xfrag+j;
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}
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xfrag+=_hfrags;
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}
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/*Mark which quadrants of this super block lie within the image.*/
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for(quadi=0;quadi<4;quadi++){
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_sb_flags[sbi].quad_valid|=
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(oc_sb_quad_top_left_frag(_sb_maps[sbi],quadi)>=0)<<quadi;
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}
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}
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yfrag+=_hfrags<<2;
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}
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}
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/*Fills in the Y plane fragment map for a macro block given the fragment
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coordinates of its upper-left hand corner.
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_mb_map: The macro block map to fill.
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_fplane: The description of the Y plane.
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_xfrag0: The X location of the upper-left hand fragment in the luma plane.
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_yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/
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static void oc_mb_fill_ymapping(oc_mb_map_plane _mb_map[3],
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const oc_fragment_plane *_fplane,int _xfrag0,int _yfrag0){
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int i;
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int j;
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for(i=0;i<2;i++)for(j=0;j<2;j++){
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_mb_map[0][i<<1|j]=(_yfrag0+i)*(ptrdiff_t)_fplane->nhfrags+_xfrag0+j;
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}
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}
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/*Fills in the chroma plane fragment maps for a macro block.
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This version is for use with chroma decimated in the X and Y directions
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(4:2:0).
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_mb_map: The macro block map to fill.
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_fplanes: The descriptions of the fragment planes.
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_xfrag0: The X location of the upper-left hand fragment in the luma plane.
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_yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/
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static void oc_mb_fill_cmapping00(oc_mb_map_plane _mb_map[3],
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const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0){
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ptrdiff_t fragi;
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_xfrag0>>=1;
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_yfrag0>>=1;
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fragi=_yfrag0*(ptrdiff_t)_fplanes[1].nhfrags+_xfrag0;
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_mb_map[1][0]=fragi+_fplanes[1].froffset;
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_mb_map[2][0]=fragi+_fplanes[2].froffset;
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}
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/*Fills in the chroma plane fragment maps for a macro block.
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This version is for use with chroma decimated in the Y direction.
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_mb_map: The macro block map to fill.
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_fplanes: The descriptions of the fragment planes.
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_xfrag0: The X location of the upper-left hand fragment in the luma plane.
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_yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/
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static void oc_mb_fill_cmapping01(oc_mb_map_plane _mb_map[3],
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const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0){
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ptrdiff_t fragi;
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int j;
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_yfrag0>>=1;
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fragi=_yfrag0*(ptrdiff_t)_fplanes[1].nhfrags+_xfrag0;
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for(j=0;j<2;j++){
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_mb_map[1][j]=fragi+_fplanes[1].froffset;
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_mb_map[2][j]=fragi+_fplanes[2].froffset;
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fragi++;
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}
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}
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/*Fills in the chroma plane fragment maps for a macro block.
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This version is for use with chroma decimated in the X direction (4:2:2).
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_mb_map: The macro block map to fill.
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_fplanes: The descriptions of the fragment planes.
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_xfrag0: The X location of the upper-left hand fragment in the luma plane.
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_yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/
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static void oc_mb_fill_cmapping10(oc_mb_map_plane _mb_map[3],
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const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0){
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ptrdiff_t fragi;
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int i;
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_xfrag0>>=1;
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fragi=_yfrag0*(ptrdiff_t)_fplanes[1].nhfrags+_xfrag0;
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for(i=0;i<2;i++){
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_mb_map[1][i<<1]=fragi+_fplanes[1].froffset;
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_mb_map[2][i<<1]=fragi+_fplanes[2].froffset;
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fragi+=_fplanes[1].nhfrags;
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}
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}
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/*Fills in the chroma plane fragment maps for a macro block.
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This version is for use with no chroma decimation (4:4:4).
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This uses the already filled-in luma plane values.
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_mb_map: The macro block map to fill.
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_fplanes: The descriptions of the fragment planes.*/
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static void oc_mb_fill_cmapping11(oc_mb_map_plane _mb_map[3],
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const oc_fragment_plane _fplanes[3]){
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int k;
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for(k=0;k<4;k++){
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_mb_map[1][k]=_mb_map[0][k]+_fplanes[1].froffset;
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_mb_map[2][k]=_mb_map[0][k]+_fplanes[2].froffset;
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}
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}
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/*The function type used to fill in the chroma plane fragment maps for a
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macro block.
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_mb_map: The macro block map to fill.
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_fplanes: The descriptions of the fragment planes.
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_xfrag0: The X location of the upper-left hand fragment in the luma plane.
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_yfrag0: The Y location of the upper-left hand fragment in the luma plane.*/
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typedef void (*oc_mb_fill_cmapping_func)(oc_mb_map_plane _mb_map[3],
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const oc_fragment_plane _fplanes[3],int _xfrag0,int _yfrag0);
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/*A table of functions used to fill in the chroma plane fragment maps for a
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macro block for each type of chrominance decimation.*/
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static const oc_mb_fill_cmapping_func OC_MB_FILL_CMAPPING_TABLE[4]={
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oc_mb_fill_cmapping00,
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oc_mb_fill_cmapping01,
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oc_mb_fill_cmapping10,
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(oc_mb_fill_cmapping_func)oc_mb_fill_cmapping11
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};
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/*Fills in the mapping from macro blocks to their corresponding fragment
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numbers in each plane.
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_mb_maps: The list of macro block maps.
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_mb_modes: The list of macro block modes; macro blocks completely outside
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the coded region are marked invalid.
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_fplanes: The descriptions of the fragment planes.
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_pixel_fmt: The chroma decimation type.*/
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static void oc_mb_create_mapping(oc_mb_map _mb_maps[],
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signed char _mb_modes[],const oc_fragment_plane _fplanes[3],int _pixel_fmt){
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oc_mb_fill_cmapping_func mb_fill_cmapping;
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unsigned sbi;
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int y;
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mb_fill_cmapping=OC_MB_FILL_CMAPPING_TABLE[_pixel_fmt];
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/*Loop through the luma plane super blocks.*/
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for(sbi=y=0;y<_fplanes[0].nvfrags;y+=4){
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int x;
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for(x=0;x<_fplanes[0].nhfrags;x+=4,sbi++){
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int ymb;
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/*Loop through the macro blocks in each super block in display order.*/
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for(ymb=0;ymb<2;ymb++){
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int xmb;
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for(xmb=0;xmb<2;xmb++){
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unsigned mbi;
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int mbx;
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int mby;
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mbi=sbi<<2|OC_MB_MAP[ymb][xmb];
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mbx=x|xmb<<1;
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mby=y|ymb<<1;
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/*Initialize fragment indices to -1.*/
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memset(_mb_maps[mbi],0xFF,sizeof(_mb_maps[mbi]));
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/*Make sure this macro block is within the encoded region.*/
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if(mbx>=_fplanes[0].nhfrags||mby>=_fplanes[0].nvfrags){
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_mb_modes[mbi]=OC_MODE_INVALID;
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continue;
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}
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/*Fill in the fragment indices for the luma plane.*/
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oc_mb_fill_ymapping(_mb_maps[mbi],_fplanes,mbx,mby);
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/*Fill in the fragment indices for the chroma planes.*/
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(*mb_fill_cmapping)(_mb_maps[mbi],_fplanes,mbx,mby);
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}
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}
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}
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}
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}
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/*Marks the fragments which fall all or partially outside the displayable
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region of the frame.
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_state: The Theora state containing the fragments to be marked.*/
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static void oc_state_border_init(oc_theora_state *_state){
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oc_fragment *frag;
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oc_fragment *yfrag_end;
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oc_fragment *xfrag_end;
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oc_fragment_plane *fplane;
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int crop_x0;
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int crop_y0;
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int crop_xf;
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int crop_yf;
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int pli;
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int y;
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int x;
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/*The method we use here is slow, but the code is dead simple and handles
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all the special cases easily.
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We only ever need to do it once.*/
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/*Loop through the fragments, marking those completely outside the
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displayable region and constructing a border mask for those that straddle
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the border.*/
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_state->nborders=0;
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yfrag_end=frag=_state->frags;
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for(pli=0;pli<3;pli++){
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fplane=_state->fplanes+pli;
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/*Set up the cropping rectangle for this plane.*/
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crop_x0=_state->info.pic_x;
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crop_xf=_state->info.pic_x+_state->info.pic_width;
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crop_y0=_state->info.pic_y;
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crop_yf=_state->info.pic_y+_state->info.pic_height;
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if(pli>0){
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if(!(_state->info.pixel_fmt&1)){
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crop_x0=crop_x0>>1;
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crop_xf=crop_xf+1>>1;
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}
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if(!(_state->info.pixel_fmt&2)){
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crop_y0=crop_y0>>1;
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crop_yf=crop_yf+1>>1;
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}
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}
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y=0;
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for(yfrag_end+=fplane->nfrags;frag<yfrag_end;y+=8){
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x=0;
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for(xfrag_end=frag+fplane->nhfrags;frag<xfrag_end;frag++,x+=8){
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/*First check to see if this fragment is completely outside the
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displayable region.*/
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/*Note the special checks for an empty cropping rectangle.
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This guarantees that if we count a fragment as straddling the
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border below, at least one pixel in the fragment will be inside
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the displayable region.*/
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if(x+8<=crop_x0||crop_xf<=x||y+8<=crop_y0||crop_yf<=y||
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crop_x0>=crop_xf||crop_y0>=crop_yf){
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frag->invalid=1;
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}
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/*Otherwise, check to see if it straddles the border.*/
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else if(x<crop_x0&&crop_x0<x+8||x<crop_xf&&crop_xf<x+8||
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y<crop_y0&&crop_y0<y+8||y<crop_yf&&crop_yf<y+8){
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ogg_int64_t mask;
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int npixels;
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int i;
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mask=npixels=0;
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for(i=0;i<8;i++){
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int j;
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for(j=0;j<8;j++){
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if(x+j>=crop_x0&&x+j<crop_xf&&y+i>=crop_y0&&y+i<crop_yf){
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mask|=(ogg_int64_t)1<<(i<<3|j);
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npixels++;
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}
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}
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}
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/*Search the fragment array for border info with the same pattern.
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In general, there will be at most 8 different patterns (per
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plane).*/
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for(i=0;;i++){
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if(i>=_state->nborders){
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_state->nborders++;
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_state->borders[i].mask=mask;
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_state->borders[i].npixels=npixels;
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}
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else if(_state->borders[i].mask!=mask)continue;
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frag->borderi=i;
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break;
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}
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}
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else frag->borderi=-1;
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}
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}
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}
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}
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static int oc_state_frarray_init(oc_theora_state *_state){
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int yhfrags;
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int yvfrags;
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int chfrags;
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int cvfrags;
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ptrdiff_t yfrags;
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ptrdiff_t cfrags;
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ptrdiff_t nfrags;
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unsigned yhsbs;
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unsigned yvsbs;
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unsigned chsbs;
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unsigned cvsbs;
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unsigned ysbs;
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unsigned csbs;
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unsigned nsbs;
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size_t nmbs;
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int hdec;
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int vdec;
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int pli;
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/*Figure out the number of fragments in each plane.*/
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/*These parameters have already been validated to be multiples of 16.*/
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yhfrags=_state->info.frame_width>>3;
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yvfrags=_state->info.frame_height>>3;
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hdec=!(_state->info.pixel_fmt&1);
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vdec=!(_state->info.pixel_fmt&2);
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chfrags=yhfrags+hdec>>hdec;
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cvfrags=yvfrags+vdec>>vdec;
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yfrags=yhfrags*(ptrdiff_t)yvfrags;
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cfrags=chfrags*(ptrdiff_t)cvfrags;
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nfrags=yfrags+2*cfrags;
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/*Figure out the number of super blocks in each plane.*/
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yhsbs=yhfrags+3>>2;
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yvsbs=yvfrags+3>>2;
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chsbs=chfrags+3>>2;
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cvsbs=cvfrags+3>>2;
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ysbs=yhsbs*yvsbs;
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csbs=chsbs*cvsbs;
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nsbs=ysbs+2*csbs;
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nmbs=(size_t)ysbs<<2;
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/*Check for overflow.
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We support the ridiculous upper limits of the specification (1048560 by
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1048560, or 3 TB frames) if the target architecture has 64-bit pointers,
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but for those with 32-bit pointers (or smaller!) we have to check.
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If the caller wants to prevent denial-of-service by imposing a more
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reasonable upper limit on the size of attempted allocations, they must do
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so themselves; we have no platform independent way to determine how much
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system memory there is nor an application-independent way to decide what a
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"reasonable" allocation is.*/
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if(yfrags/yhfrags!=yvfrags||2*cfrags<cfrags||nfrags<yfrags||
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ysbs/yhsbs!=yvsbs||2*csbs<csbs||nsbs<ysbs||nmbs>>2!=ysbs){
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return TH_EIMPL;
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}
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/*Initialize the fragment array.*/
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_state->fplanes[0].nhfrags=yhfrags;
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_state->fplanes[0].nvfrags=yvfrags;
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_state->fplanes[0].froffset=0;
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_state->fplanes[0].nfrags=yfrags;
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_state->fplanes[0].nhsbs=yhsbs;
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_state->fplanes[0].nvsbs=yvsbs;
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_state->fplanes[0].sboffset=0;
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_state->fplanes[0].nsbs=ysbs;
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_state->fplanes[1].nhfrags=_state->fplanes[2].nhfrags=chfrags;
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_state->fplanes[1].nvfrags=_state->fplanes[2].nvfrags=cvfrags;
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_state->fplanes[1].froffset=yfrags;
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_state->fplanes[2].froffset=yfrags+cfrags;
|
|
_state->fplanes[1].nfrags=_state->fplanes[2].nfrags=cfrags;
|
|
_state->fplanes[1].nhsbs=_state->fplanes[2].nhsbs=chsbs;
|
|
_state->fplanes[1].nvsbs=_state->fplanes[2].nvsbs=cvsbs;
|
|
_state->fplanes[1].sboffset=ysbs;
|
|
_state->fplanes[2].sboffset=ysbs+csbs;
|
|
_state->fplanes[1].nsbs=_state->fplanes[2].nsbs=csbs;
|
|
_state->nfrags=nfrags;
|
|
_state->frags=_ogg_calloc(nfrags,sizeof(*_state->frags));
|
|
_state->frag_mvs=_ogg_malloc(nfrags*sizeof(*_state->frag_mvs));
|
|
_state->nsbs=nsbs;
|
|
_state->sb_maps=_ogg_malloc(nsbs*sizeof(*_state->sb_maps));
|
|
_state->sb_flags=_ogg_calloc(nsbs,sizeof(*_state->sb_flags));
|
|
_state->nhmbs=yhsbs<<1;
|
|
_state->nvmbs=yvsbs<<1;
|
|
_state->nmbs=nmbs;
|
|
_state->mb_maps=_ogg_calloc(nmbs,sizeof(*_state->mb_maps));
|
|
_state->mb_modes=_ogg_calloc(nmbs,sizeof(*_state->mb_modes));
|
|
_state->coded_fragis=_ogg_malloc(nfrags*sizeof(*_state->coded_fragis));
|
|
if(_state->frags==NULL||_state->frag_mvs==NULL||_state->sb_maps==NULL||
|
|
_state->sb_flags==NULL||_state->mb_maps==NULL||_state->mb_modes==NULL||
|
|
_state->coded_fragis==NULL){
|
|
return TH_EFAULT;
|
|
}
|
|
/*Create the mapping from super blocks to fragments.*/
|
|
for(pli=0;pli<3;pli++){
|
|
oc_fragment_plane *fplane;
|
|
fplane=_state->fplanes+pli;
|
|
oc_sb_create_plane_mapping(_state->sb_maps+fplane->sboffset,
|
|
_state->sb_flags+fplane->sboffset,fplane->froffset,
|
|
fplane->nhfrags,fplane->nvfrags);
|
|
}
|
|
/*Create the mapping from macro blocks to fragments.*/
|
|
oc_mb_create_mapping(_state->mb_maps,_state->mb_modes,
|
|
_state->fplanes,_state->info.pixel_fmt);
|
|
/*Initialize the invalid and borderi fields of each fragment.*/
|
|
oc_state_border_init(_state);
|
|
return 0;
|
|
}
|
|
|
|
static void oc_state_frarray_clear(oc_theora_state *_state){
|
|
_ogg_free(_state->coded_fragis);
|
|
_ogg_free(_state->mb_modes);
|
|
_ogg_free(_state->mb_maps);
|
|
_ogg_free(_state->sb_flags);
|
|
_ogg_free(_state->sb_maps);
|
|
_ogg_free(_state->frag_mvs);
|
|
_ogg_free(_state->frags);
|
|
}
|
|
|
|
|
|
/*Initializes the buffers used for reconstructed frames.
|
|
These buffers are padded with 16 extra pixels on each side, to allow
|
|
unrestricted motion vectors without special casing the boundary.
|
|
If chroma is decimated in either direction, the padding is reduced by a
|
|
factor of 2 on the appropriate sides.
|
|
_nrefs: The number of reference buffers to init; must be 3 or 4.*/
|
|
static int oc_state_ref_bufs_init(oc_theora_state *_state,int _nrefs){
|
|
th_info *info;
|
|
unsigned char *ref_frame_data;
|
|
size_t ref_frame_data_sz;
|
|
size_t ref_frame_sz;
|
|
size_t yplane_sz;
|
|
size_t cplane_sz;
|
|
int yhstride;
|
|
int yheight;
|
|
int chstride;
|
|
int cheight;
|
|
ptrdiff_t yoffset;
|
|
ptrdiff_t coffset;
|
|
ptrdiff_t *frag_buf_offs;
|
|
ptrdiff_t fragi;
|
|
int hdec;
|
|
int vdec;
|
|
int rfi;
|
|
int pli;
|
|
if(_nrefs<3||_nrefs>4)return TH_EINVAL;
|
|
info=&_state->info;
|
|
/*Compute the image buffer parameters for each plane.*/
|
|
hdec=!(info->pixel_fmt&1);
|
|
vdec=!(info->pixel_fmt&2);
|
|
yhstride=info->frame_width+2*OC_UMV_PADDING;
|
|
yheight=info->frame_height+2*OC_UMV_PADDING;
|
|
chstride=yhstride>>hdec;
|
|
cheight=yheight>>vdec;
|
|
yplane_sz=yhstride*(size_t)yheight;
|
|
cplane_sz=chstride*(size_t)cheight;
|
|
yoffset=OC_UMV_PADDING+OC_UMV_PADDING*(ptrdiff_t)yhstride;
|
|
coffset=(OC_UMV_PADDING>>hdec)+(OC_UMV_PADDING>>vdec)*(ptrdiff_t)chstride;
|
|
ref_frame_sz=yplane_sz+2*cplane_sz;
|
|
ref_frame_data_sz=_nrefs*ref_frame_sz;
|
|
/*Check for overflow.
|
|
The same caveats apply as for oc_state_frarray_init().*/
|
|
if(yplane_sz/yhstride!=yheight||2*cplane_sz<cplane_sz||
|
|
ref_frame_sz<yplane_sz||ref_frame_data_sz/_nrefs!=ref_frame_sz){
|
|
return TH_EIMPL;
|
|
}
|
|
ref_frame_data=_ogg_malloc(ref_frame_data_sz);
|
|
frag_buf_offs=_state->frag_buf_offs=
|
|
_ogg_malloc(_state->nfrags*sizeof(*frag_buf_offs));
|
|
if(ref_frame_data==NULL||frag_buf_offs==NULL){
|
|
_ogg_free(frag_buf_offs);
|
|
_ogg_free(ref_frame_data);
|
|
return TH_EFAULT;
|
|
}
|
|
/*Set up the width, height and stride for the image buffers.*/
|
|
_state->ref_frame_bufs[0][0].width=info->frame_width;
|
|
_state->ref_frame_bufs[0][0].height=info->frame_height;
|
|
_state->ref_frame_bufs[0][0].stride=yhstride;
|
|
_state->ref_frame_bufs[0][1].width=_state->ref_frame_bufs[0][2].width=
|
|
info->frame_width>>hdec;
|
|
_state->ref_frame_bufs[0][1].height=_state->ref_frame_bufs[0][2].height=
|
|
info->frame_height>>vdec;
|
|
_state->ref_frame_bufs[0][1].stride=_state->ref_frame_bufs[0][2].stride=
|
|
chstride;
|
|
for(rfi=1;rfi<_nrefs;rfi++){
|
|
memcpy(_state->ref_frame_bufs[rfi],_state->ref_frame_bufs[0],
|
|
sizeof(_state->ref_frame_bufs[0]));
|
|
}
|
|
/*Set up the data pointers for the image buffers.*/
|
|
for(rfi=0;rfi<_nrefs;rfi++){
|
|
_state->ref_frame_data[rfi]=ref_frame_data;
|
|
_state->ref_frame_bufs[rfi][0].data=ref_frame_data+yoffset;
|
|
ref_frame_data+=yplane_sz;
|
|
_state->ref_frame_bufs[rfi][1].data=ref_frame_data+coffset;
|
|
ref_frame_data+=cplane_sz;
|
|
_state->ref_frame_bufs[rfi][2].data=ref_frame_data+coffset;
|
|
ref_frame_data+=cplane_sz;
|
|
/*Flip the buffer upside down.
|
|
This allows us to decode Theora's bottom-up frames in their natural
|
|
order, yet return a top-down buffer with a positive stride to the user.*/
|
|
oc_ycbcr_buffer_flip(_state->ref_frame_bufs[rfi],
|
|
_state->ref_frame_bufs[rfi]);
|
|
}
|
|
_state->ref_ystride[0]=-yhstride;
|
|
_state->ref_ystride[1]=_state->ref_ystride[2]=-chstride;
|
|
/*Initialize the fragment buffer offsets.*/
|
|
ref_frame_data=_state->ref_frame_data[0];
|
|
fragi=0;
|
|
for(pli=0;pli<3;pli++){
|
|
th_img_plane *iplane;
|
|
oc_fragment_plane *fplane;
|
|
unsigned char *vpix;
|
|
ptrdiff_t stride;
|
|
ptrdiff_t vfragi_end;
|
|
int nhfrags;
|
|
iplane=_state->ref_frame_bufs[0]+pli;
|
|
fplane=_state->fplanes+pli;
|
|
vpix=iplane->data;
|
|
vfragi_end=fplane->froffset+fplane->nfrags;
|
|
nhfrags=fplane->nhfrags;
|
|
stride=iplane->stride;
|
|
while(fragi<vfragi_end){
|
|
ptrdiff_t hfragi_end;
|
|
unsigned char *hpix;
|
|
hpix=vpix;
|
|
for(hfragi_end=fragi+nhfrags;fragi<hfragi_end;fragi++){
|
|
frag_buf_offs[fragi]=hpix-ref_frame_data;
|
|
hpix+=8;
|
|
}
|
|
vpix+=stride<<3;
|
|
}
|
|
}
|
|
/*Initialize the reference frame indices.*/
|
|
_state->ref_frame_idx[OC_FRAME_GOLD]=
|
|
_state->ref_frame_idx[OC_FRAME_PREV]=
|
|
_state->ref_frame_idx[OC_FRAME_SELF]=-1;
|
|
_state->ref_frame_idx[OC_FRAME_IO]=_nrefs>3?3:-1;
|
|
return 0;
|
|
}
|
|
|
|
static void oc_state_ref_bufs_clear(oc_theora_state *_state){
|
|
_ogg_free(_state->frag_buf_offs);
|
|
_ogg_free(_state->ref_frame_data[0]);
|
|
}
|
|
|
|
|
|
void oc_state_vtable_init_c(oc_theora_state *_state){
|
|
_state->opt_vtable.frag_copy=oc_frag_copy_c;
|
|
_state->opt_vtable.frag_recon_intra=oc_frag_recon_intra_c;
|
|
_state->opt_vtable.frag_recon_inter=oc_frag_recon_inter_c;
|
|
_state->opt_vtable.frag_recon_inter2=oc_frag_recon_inter2_c;
|
|
_state->opt_vtable.idct8x8=oc_idct8x8_c;
|
|
_state->opt_vtable.state_frag_recon=oc_state_frag_recon_c;
|
|
_state->opt_vtable.state_frag_copy_list=oc_state_frag_copy_list_c;
|
|
_state->opt_vtable.state_loop_filter_frag_rows=
|
|
oc_state_loop_filter_frag_rows_c;
|
|
_state->opt_vtable.restore_fpu=oc_restore_fpu_c;
|
|
_state->opt_data.dct_fzig_zag=OC_FZIG_ZAG;
|
|
}
|
|
|
|
/*Initialize the accelerated function pointers.*/
|
|
void oc_state_vtable_init(oc_theora_state *_state){
|
|
#if defined(OC_X86_ASM)
|
|
oc_state_vtable_init_x86(_state);
|
|
#else
|
|
oc_state_vtable_init_c(_state);
|
|
#endif
|
|
}
|
|
|
|
|
|
int oc_state_init(oc_theora_state *_state,const th_info *_info,int _nrefs){
|
|
int ret;
|
|
/*First validate the parameters.*/
|
|
if(_info==NULL)return TH_EFAULT;
|
|
/*The width and height of the encoded frame must be multiples of 16.
|
|
They must also, when divided by 16, fit into a 16-bit unsigned integer.
|
|
The displayable frame offset coordinates must fit into an 8-bit unsigned
|
|
integer.
|
|
Note that the offset Y in the API is specified on the opposite side from
|
|
how it is specified in the bitstream, because the Y axis is flipped in
|
|
the bitstream.
|
|
The displayable frame must fit inside the encoded frame.
|
|
The color space must be one known by the encoder.*/
|
|
if((_info->frame_width&0xF)||(_info->frame_height&0xF)||
|
|
_info->frame_width<=0||_info->frame_width>=0x100000||
|
|
_info->frame_height<=0||_info->frame_height>=0x100000||
|
|
_info->pic_x+_info->pic_width>_info->frame_width||
|
|
_info->pic_y+_info->pic_height>_info->frame_height||
|
|
_info->pic_x>255||_info->frame_height-_info->pic_height-_info->pic_y>255||
|
|
/*Note: the following <0 comparisons may generate spurious warnings on
|
|
platforms where enums are unsigned.
|
|
We could cast them to unsigned and just use the following >= comparison,
|
|
but there are a number of compilers which will mis-optimize this.
|
|
It's better to live with the spurious warnings.*/
|
|
_info->colorspace<0||_info->colorspace>=TH_CS_NSPACES||
|
|
_info->pixel_fmt<0||_info->pixel_fmt>=TH_PF_NFORMATS){
|
|
return TH_EINVAL;
|
|
}
|
|
memset(_state,0,sizeof(*_state));
|
|
memcpy(&_state->info,_info,sizeof(*_info));
|
|
/*Invert the sense of pic_y to match Theora's right-handed coordinate
|
|
system.*/
|
|
_state->info.pic_y=_info->frame_height-_info->pic_height-_info->pic_y;
|
|
_state->frame_type=OC_UNKWN_FRAME;
|
|
oc_state_vtable_init(_state);
|
|
ret=oc_state_frarray_init(_state);
|
|
if(ret>=0)ret=oc_state_ref_bufs_init(_state,_nrefs);
|
|
if(ret<0){
|
|
oc_state_frarray_clear(_state);
|
|
return ret;
|
|
}
|
|
/*If the keyframe_granule_shift is out of range, use the maximum allowable
|
|
value.*/
|
|
if(_info->keyframe_granule_shift<0||_info->keyframe_granule_shift>31){
|
|
_state->info.keyframe_granule_shift=31;
|
|
}
|
|
_state->keyframe_num=0;
|
|
_state->curframe_num=-1;
|
|
/*3.2.0 streams mark the frame index instead of the frame count.
|
|
This was changed with stream version 3.2.1 to conform to other Ogg
|
|
codecs.
|
|
We add an extra bias when computing granule positions for new streams.*/
|
|
_state->granpos_bias=TH_VERSION_CHECK(_info,3,2,1);
|
|
return 0;
|
|
}
|
|
|
|
void oc_state_clear(oc_theora_state *_state){
|
|
oc_state_ref_bufs_clear(_state);
|
|
oc_state_frarray_clear(_state);
|
|
}
|
|
|
|
|
|
/*Duplicates the pixels on the border of the image plane out into the
|
|
surrounding padding for use by unrestricted motion vectors.
|
|
This function only adds the left and right borders, and only for the fragment
|
|
rows specified.
|
|
_refi: The index of the reference buffer to pad.
|
|
_pli: The color plane.
|
|
_y0: The Y coordinate of the first row to pad.
|
|
_yend: The Y coordinate of the row to stop padding at.*/
|
|
void oc_state_borders_fill_rows(oc_theora_state *_state,int _refi,int _pli,
|
|
int _y0,int _yend){
|
|
th_img_plane *iplane;
|
|
unsigned char *apix;
|
|
unsigned char *bpix;
|
|
unsigned char *epix;
|
|
int stride;
|
|
int hpadding;
|
|
hpadding=OC_UMV_PADDING>>(_pli!=0&&!(_state->info.pixel_fmt&1));
|
|
iplane=_state->ref_frame_bufs[_refi]+_pli;
|
|
stride=iplane->stride;
|
|
apix=iplane->data+_y0*(ptrdiff_t)stride;
|
|
bpix=apix+iplane->width-1;
|
|
epix=iplane->data+_yend*(ptrdiff_t)stride;
|
|
/*Note the use of != instead of <, which allows the stride to be negative.*/
|
|
while(apix!=epix){
|
|
memset(apix-hpadding,apix[0],hpadding);
|
|
memset(bpix+1,bpix[0],hpadding);
|
|
apix+=stride;
|
|
bpix+=stride;
|
|
}
|
|
}
|
|
|
|
/*Duplicates the pixels on the border of the image plane out into the
|
|
surrounding padding for use by unrestricted motion vectors.
|
|
This function only adds the top and bottom borders, and must be called after
|
|
the left and right borders are added.
|
|
_refi: The index of the reference buffer to pad.
|
|
_pli: The color plane.*/
|
|
void oc_state_borders_fill_caps(oc_theora_state *_state,int _refi,int _pli){
|
|
th_img_plane *iplane;
|
|
unsigned char *apix;
|
|
unsigned char *bpix;
|
|
unsigned char *epix;
|
|
int stride;
|
|
int hpadding;
|
|
int vpadding;
|
|
int fullw;
|
|
hpadding=OC_UMV_PADDING>>(_pli!=0&&!(_state->info.pixel_fmt&1));
|
|
vpadding=OC_UMV_PADDING>>(_pli!=0&&!(_state->info.pixel_fmt&2));
|
|
iplane=_state->ref_frame_bufs[_refi]+_pli;
|
|
stride=iplane->stride;
|
|
fullw=iplane->width+(hpadding<<1);
|
|
apix=iplane->data-hpadding;
|
|
bpix=iplane->data+(iplane->height-1)*(ptrdiff_t)stride-hpadding;
|
|
epix=apix-stride*(ptrdiff_t)vpadding;
|
|
while(apix!=epix){
|
|
memcpy(apix-stride,apix,fullw);
|
|
memcpy(bpix+stride,bpix,fullw);
|
|
apix-=stride;
|
|
bpix+=stride;
|
|
}
|
|
}
|
|
|
|
/*Duplicates the pixels on the border of the given reference image out into
|
|
the surrounding padding for use by unrestricted motion vectors.
|
|
_state: The context containing the reference buffers.
|
|
_refi: The index of the reference buffer to pad.*/
|
|
void oc_state_borders_fill(oc_theora_state *_state,int _refi){
|
|
int pli;
|
|
for(pli=0;pli<3;pli++){
|
|
oc_state_borders_fill_rows(_state,_refi,pli,0,
|
|
_state->ref_frame_bufs[_refi][pli].height);
|
|
oc_state_borders_fill_caps(_state,_refi,pli);
|
|
}
|
|
}
|
|
|
|
/*Determines the offsets in an image buffer to use for motion compensation.
|
|
_state: The Theora state the offsets are to be computed with.
|
|
_offsets: Returns the offset for the buffer(s).
|
|
_offsets[0] is always set.
|
|
_offsets[1] is set if the motion vector has non-zero fractional
|
|
components.
|
|
_pli: The color plane index.
|
|
_dx: The X component of the motion vector.
|
|
_dy: The Y component of the motion vector.
|
|
Return: The number of offsets returned: 1 or 2.*/
|
|
int oc_state_get_mv_offsets(const oc_theora_state *_state,int _offsets[2],
|
|
int _pli,int _dx,int _dy){
|
|
/*Here is a brief description of how Theora handles motion vectors:
|
|
Motion vector components are specified to half-pixel accuracy in
|
|
undecimated directions of each plane, and quarter-pixel accuracy in
|
|
decimated directions.
|
|
Integer parts are extracted by dividing (not shifting) by the
|
|
appropriate amount, with truncation towards zero.
|
|
These integer values are used to calculate the first offset.
|
|
|
|
If either of the fractional parts are non-zero, then a second offset is
|
|
computed.
|
|
No third or fourth offsets are computed, even if both components have
|
|
non-zero fractional parts.
|
|
The second offset is computed by dividing (not shifting) by the
|
|
appropriate amount, always truncating _away_ from zero.*/
|
|
#if 0
|
|
/*This version of the code doesn't use any tables, but is slower.*/
|
|
int ystride;
|
|
int xprec;
|
|
int yprec;
|
|
int xfrac;
|
|
int yfrac;
|
|
int offs;
|
|
ystride=_state->ref_ystride[_pli];
|
|
/*These two variables decide whether we are in half- or quarter-pixel
|
|
precision in each component.*/
|
|
xprec=1+(_pli!=0&&!(_state->info.pixel_fmt&1));
|
|
yprec=1+(_pli!=0&&!(_state->info.pixel_fmt&2));
|
|
/*These two variables are either 0 if all the fractional bits are zero or -1
|
|
if any of them are non-zero.*/
|
|
xfrac=OC_SIGNMASK(-(_dx&(xprec|1)));
|
|
yfrac=OC_SIGNMASK(-(_dy&(yprec|1)));
|
|
offs=(_dx>>xprec)+(_dy>>yprec)*ystride;
|
|
if(xfrac||yfrac){
|
|
int xmask;
|
|
int ymask;
|
|
xmask=OC_SIGNMASK(_dx);
|
|
ymask=OC_SIGNMASK(_dy);
|
|
yfrac&=ystride;
|
|
_offsets[0]=offs-(xfrac&xmask)+(yfrac&ymask);
|
|
_offsets[1]=offs-(xfrac&~xmask)+(yfrac&~ymask);
|
|
return 2;
|
|
}
|
|
else{
|
|
_offsets[0]=offs;
|
|
return 1;
|
|
}
|
|
#else
|
|
/*Using tables simplifies the code, and there's enough arithmetic to hide the
|
|
latencies of the memory references.*/
|
|
static const signed char OC_MVMAP[2][64]={
|
|
{
|
|
-15,-15,-14,-14,-13,-13,-12,-12,-11,-11,-10,-10, -9, -9, -8,
|
|
-8, -7, -7, -6, -6, -5, -5, -4, -4, -3, -3, -2, -2, -1, -1, 0,
|
|
0, 0, 1, 1, 2, 2, 3, 3, 4, 4, 5, 5, 6, 6, 7, 7,
|
|
8, 8, 9, 9, 10, 10, 11, 11, 12, 12, 13, 13, 14, 14, 15, 15
|
|
},
|
|
{
|
|
-7, -7, -7, -7, -6, -6, -6, -6, -5, -5, -5, -5, -4, -4, -4,
|
|
-4, -3, -3, -3, -3, -2, -2, -2, -2, -1, -1, -1, -1, 0, 0, 0,
|
|
0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 3, 3, 3, 3,
|
|
4, 4, 4, 4, 5, 5, 5, 5, 6, 6, 6, 6, 7, 7, 7, 7
|
|
}
|
|
};
|
|
static const signed char OC_MVMAP2[2][64]={
|
|
{
|
|
-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1,
|
|
0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1, 0,-1,
|
|
0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1,
|
|
0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1
|
|
},
|
|
{
|
|
-1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1,
|
|
0,-1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1, 0,-1,-1,-1,
|
|
0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1,
|
|
0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1
|
|
}
|
|
};
|
|
int ystride;
|
|
int qpx;
|
|
int qpy;
|
|
int mx;
|
|
int my;
|
|
int mx2;
|
|
int my2;
|
|
int offs;
|
|
ystride=_state->ref_ystride[_pli];
|
|
qpy=_pli!=0&&!(_state->info.pixel_fmt&2);
|
|
my=OC_MVMAP[qpy][_dy+31];
|
|
my2=OC_MVMAP2[qpy][_dy+31];
|
|
qpx=_pli!=0&&!(_state->info.pixel_fmt&1);
|
|
mx=OC_MVMAP[qpx][_dx+31];
|
|
mx2=OC_MVMAP2[qpx][_dx+31];
|
|
offs=my*ystride+mx;
|
|
if(mx2||my2){
|
|
_offsets[1]=offs+my2*ystride+mx2;
|
|
_offsets[0]=offs;
|
|
return 2;
|
|
}
|
|
_offsets[0]=offs;
|
|
return 1;
|
|
#endif
|
|
}
|
|
|
|
void oc_state_frag_recon(const oc_theora_state *_state,ptrdiff_t _fragi,
|
|
int _pli,ogg_int16_t _dct_coeffs[64],int _last_zzi,ogg_uint16_t _dc_quant){
|
|
_state->opt_vtable.state_frag_recon(_state,_fragi,_pli,_dct_coeffs,
|
|
_last_zzi,_dc_quant);
|
|
}
|
|
|
|
void oc_state_frag_recon_c(const oc_theora_state *_state,ptrdiff_t _fragi,
|
|
int _pli,ogg_int16_t _dct_coeffs[64],int _last_zzi,ogg_uint16_t _dc_quant){
|
|
unsigned char *dst;
|
|
ptrdiff_t frag_buf_off;
|
|
int ystride;
|
|
int mb_mode;
|
|
/*Apply the inverse transform.*/
|
|
/*Special case only having a DC component.*/
|
|
if(_last_zzi<2){
|
|
ogg_int16_t p;
|
|
int ci;
|
|
/*We round this dequant product (and not any of the others) because there's
|
|
no iDCT rounding.*/
|
|
p=(ogg_int16_t)(_dct_coeffs[0]*(ogg_int32_t)_dc_quant+15>>5);
|
|
/*LOOP VECTORIZES.*/
|
|
for(ci=0;ci<64;ci++)_dct_coeffs[ci]=p;
|
|
}
|
|
else{
|
|
/*First, dequantize the DC coefficient.*/
|
|
_dct_coeffs[0]=(ogg_int16_t)(_dct_coeffs[0]*(int)_dc_quant);
|
|
oc_idct8x8(_state,_dct_coeffs,_last_zzi);
|
|
}
|
|
/*Fill in the target buffer.*/
|
|
frag_buf_off=_state->frag_buf_offs[_fragi];
|
|
mb_mode=_state->frags[_fragi].mb_mode;
|
|
ystride=_state->ref_ystride[_pli];
|
|
dst=_state->ref_frame_data[_state->ref_frame_idx[OC_FRAME_SELF]]+frag_buf_off;
|
|
if(mb_mode==OC_MODE_INTRA)oc_frag_recon_intra(_state,dst,ystride,_dct_coeffs);
|
|
else{
|
|
const unsigned char *ref;
|
|
int mvoffsets[2];
|
|
ref=
|
|
_state->ref_frame_data[_state->ref_frame_idx[OC_FRAME_FOR_MODE(mb_mode)]]
|
|
+frag_buf_off;
|
|
if(oc_state_get_mv_offsets(_state,mvoffsets,_pli,
|
|
_state->frag_mvs[_fragi][0],_state->frag_mvs[_fragi][1])>1){
|
|
oc_frag_recon_inter2(_state,
|
|
dst,ref+mvoffsets[0],ref+mvoffsets[1],ystride,_dct_coeffs);
|
|
}
|
|
else oc_frag_recon_inter(_state,dst,ref+mvoffsets[0],ystride,_dct_coeffs);
|
|
}
|
|
}
|
|
|
|
/*Copies the fragments specified by the lists of fragment indices from one
|
|
frame to another.
|
|
_fragis: A pointer to a list of fragment indices.
|
|
_nfragis: The number of fragment indices to copy.
|
|
_dst_frame: The reference frame to copy to.
|
|
_src_frame: The reference frame to copy from.
|
|
_pli: The color plane the fragments lie in.*/
|
|
void oc_state_frag_copy_list(const oc_theora_state *_state,
|
|
const ptrdiff_t *_fragis,ptrdiff_t _nfragis,
|
|
int _dst_frame,int _src_frame,int _pli){
|
|
_state->opt_vtable.state_frag_copy_list(_state,_fragis,_nfragis,_dst_frame,
|
|
_src_frame,_pli);
|
|
}
|
|
|
|
void oc_state_frag_copy_list_c(const oc_theora_state *_state,
|
|
const ptrdiff_t *_fragis,ptrdiff_t _nfragis,
|
|
int _dst_frame,int _src_frame,int _pli){
|
|
const ptrdiff_t *frag_buf_offs;
|
|
const unsigned char *src_frame_data;
|
|
unsigned char *dst_frame_data;
|
|
ptrdiff_t fragii;
|
|
int ystride;
|
|
dst_frame_data=_state->ref_frame_data[_state->ref_frame_idx[_dst_frame]];
|
|
src_frame_data=_state->ref_frame_data[_state->ref_frame_idx[_src_frame]];
|
|
ystride=_state->ref_ystride[_pli];
|
|
frag_buf_offs=_state->frag_buf_offs;
|
|
for(fragii=0;fragii<_nfragis;fragii++){
|
|
ptrdiff_t frag_buf_off;
|
|
frag_buf_off=frag_buf_offs[_fragis[fragii]];
|
|
oc_frag_copy(_state,dst_frame_data+frag_buf_off,
|
|
src_frame_data+frag_buf_off,ystride);
|
|
}
|
|
}
|
|
|
|
static void loop_filter_h(unsigned char *_pix,int _ystride,int *_bv){
|
|
int y;
|
|
_pix-=2;
|
|
for(y=0;y<8;y++){
|
|
int f;
|
|
f=_pix[0]-_pix[3]+3*(_pix[2]-_pix[1]);
|
|
/*The _bv array is used to compute the function
|
|
f=OC_CLAMPI(OC_MINI(-_2flimit-f,0),f,OC_MAXI(_2flimit-f,0));
|
|
where _2flimit=_state->loop_filter_limits[_state->qis[0]]<<1;*/
|
|
f=*(_bv+(f+4>>3));
|
|
_pix[1]=OC_CLAMP255(_pix[1]+f);
|
|
_pix[2]=OC_CLAMP255(_pix[2]-f);
|
|
_pix+=_ystride;
|
|
}
|
|
}
|
|
|
|
static void loop_filter_v(unsigned char *_pix,int _ystride,int *_bv){
|
|
int x;
|
|
_pix-=_ystride*2;
|
|
for(x=0;x<8;x++){
|
|
int f;
|
|
f=_pix[x]-_pix[_ystride*3+x]+3*(_pix[_ystride*2+x]-_pix[_ystride+x]);
|
|
/*The _bv array is used to compute the function
|
|
f=OC_CLAMPI(OC_MINI(-_2flimit-f,0),f,OC_MAXI(_2flimit-f,0));
|
|
where _2flimit=_state->loop_filter_limits[_state->qis[0]]<<1;*/
|
|
f=*(_bv+(f+4>>3));
|
|
_pix[_ystride+x]=OC_CLAMP255(_pix[_ystride+x]+f);
|
|
_pix[_ystride*2+x]=OC_CLAMP255(_pix[_ystride*2+x]-f);
|
|
}
|
|
}
|
|
|
|
/*Initialize the bounding values array used by the loop filter.
|
|
_bv: Storage for the array.
|
|
Return: 0 on success, or a non-zero value if no filtering need be applied.*/
|
|
int oc_state_loop_filter_init(oc_theora_state *_state,int _bv[256]){
|
|
int flimit;
|
|
int i;
|
|
flimit=_state->loop_filter_limits[_state->qis[0]];
|
|
if(flimit==0)return 1;
|
|
memset(_bv,0,sizeof(_bv[0])*256);
|
|
for(i=0;i<flimit;i++){
|
|
if(127-i-flimit>=0)_bv[127-i-flimit]=i-flimit;
|
|
_bv[127-i]=-i;
|
|
_bv[127+i]=i;
|
|
if(127+i+flimit<256)_bv[127+i+flimit]=flimit-i;
|
|
}
|
|
return 0;
|
|
}
|
|
|
|
/*Apply the loop filter to a given set of fragment rows in the given plane.
|
|
The filter may be run on the bottom edge, affecting pixels in the next row of
|
|
fragments, so this row also needs to be available.
|
|
_bv: The bounding values array.
|
|
_refi: The index of the frame buffer to filter.
|
|
_pli: The color plane to filter.
|
|
_fragy0: The Y coordinate of the first fragment row to filter.
|
|
_fragy_end: The Y coordinate of the fragment row to stop filtering at.*/
|
|
void oc_state_loop_filter_frag_rows(const oc_theora_state *_state,int _bv[256],
|
|
int _refi,int _pli,int _fragy0,int _fragy_end){
|
|
_state->opt_vtable.state_loop_filter_frag_rows(_state,_bv,_refi,_pli,
|
|
_fragy0,_fragy_end);
|
|
}
|
|
|
|
void oc_state_loop_filter_frag_rows_c(const oc_theora_state *_state,int *_bv,
|
|
int _refi,int _pli,int _fragy0,int _fragy_end){
|
|
const oc_fragment_plane *fplane;
|
|
const oc_fragment *frags;
|
|
const ptrdiff_t *frag_buf_offs;
|
|
unsigned char *ref_frame_data;
|
|
ptrdiff_t fragi_top;
|
|
ptrdiff_t fragi_bot;
|
|
ptrdiff_t fragi0;
|
|
ptrdiff_t fragi0_end;
|
|
int ystride;
|
|
int nhfrags;
|
|
_bv+=127;
|
|
fplane=_state->fplanes+_pli;
|
|
nhfrags=fplane->nhfrags;
|
|
fragi_top=fplane->froffset;
|
|
fragi_bot=fragi_top+fplane->nfrags;
|
|
fragi0=fragi_top+_fragy0*(ptrdiff_t)nhfrags;
|
|
fragi0_end=fragi0+(_fragy_end-_fragy0)*(ptrdiff_t)nhfrags;
|
|
ystride=_state->ref_ystride[_pli];
|
|
frags=_state->frags;
|
|
frag_buf_offs=_state->frag_buf_offs;
|
|
ref_frame_data=_state->ref_frame_data[_refi];
|
|
/*The following loops are constructed somewhat non-intuitively on purpose.
|
|
The main idea is: if a block boundary has at least one coded fragment on
|
|
it, the filter is applied to it.
|
|
However, the order that the filters are applied in matters, and VP3 chose
|
|
the somewhat strange ordering used below.*/
|
|
while(fragi0<fragi0_end){
|
|
ptrdiff_t fragi;
|
|
ptrdiff_t fragi_end;
|
|
fragi=fragi0;
|
|
fragi_end=fragi+nhfrags;
|
|
while(fragi<fragi_end){
|
|
if(frags[fragi].coded){
|
|
unsigned char *ref;
|
|
ref=ref_frame_data+frag_buf_offs[fragi];
|
|
if(fragi>fragi0)loop_filter_h(ref,ystride,_bv);
|
|
if(fragi0>fragi_top)loop_filter_v(ref,ystride,_bv);
|
|
if(fragi+1<fragi_end&&!frags[fragi+1].coded){
|
|
loop_filter_h(ref+8,ystride,_bv);
|
|
}
|
|
if(fragi+nhfrags<fragi_bot&&!frags[fragi+nhfrags].coded){
|
|
loop_filter_v(ref+(ystride<<3),ystride,_bv);
|
|
}
|
|
}
|
|
fragi++;
|
|
}
|
|
fragi0+=nhfrags;
|
|
}
|
|
}
|
|
|
|
#if defined(OC_DUMP_IMAGES)
|
|
int oc_state_dump_frame(const oc_theora_state *_state,int _frame,
|
|
const char *_suf){
|
|
/*Dump a PNG of the reconstructed image.*/
|
|
png_structp png;
|
|
png_infop info;
|
|
png_bytep *image;
|
|
FILE *fp;
|
|
char fname[16];
|
|
unsigned char *y_row;
|
|
unsigned char *u_row;
|
|
unsigned char *v_row;
|
|
unsigned char *y;
|
|
unsigned char *u;
|
|
unsigned char *v;
|
|
ogg_int64_t iframe;
|
|
ogg_int64_t pframe;
|
|
int y_stride;
|
|
int u_stride;
|
|
int v_stride;
|
|
int framei;
|
|
int width;
|
|
int height;
|
|
int imgi;
|
|
int imgj;
|
|
width=_state->info.frame_width;
|
|
height=_state->info.frame_height;
|
|
iframe=_state->granpos>>_state->info.keyframe_granule_shift;
|
|
pframe=_state->granpos-(iframe<<_state->info.keyframe_granule_shift);
|
|
sprintf(fname,"%08i%s.png",(int)(iframe+pframe),_suf);
|
|
fp=fopen(fname,"wb");
|
|
if(fp==NULL)return TH_EFAULT;
|
|
image=(png_bytep *)oc_malloc_2d(height,6*width,sizeof(**image));
|
|
if(image==NULL){
|
|
fclose(fp);
|
|
return TH_EFAULT;
|
|
}
|
|
png=png_create_write_struct(PNG_LIBPNG_VER_STRING,NULL,NULL,NULL);
|
|
if(png==NULL){
|
|
oc_free_2d(image);
|
|
fclose(fp);
|
|
return TH_EFAULT;
|
|
}
|
|
info=png_create_info_struct(png);
|
|
if(info==NULL){
|
|
png_destroy_write_struct(&png,NULL);
|
|
oc_free_2d(image);
|
|
fclose(fp);
|
|
return TH_EFAULT;
|
|
}
|
|
if(setjmp(png_jmpbuf(png))){
|
|
png_destroy_write_struct(&png,&info);
|
|
oc_free_2d(image);
|
|
fclose(fp);
|
|
return TH_EFAULT;
|
|
}
|
|
framei=_state->ref_frame_idx[_frame];
|
|
y_row=_state->ref_frame_bufs[framei][0].data;
|
|
u_row=_state->ref_frame_bufs[framei][1].data;
|
|
v_row=_state->ref_frame_bufs[framei][2].data;
|
|
y_stride=_state->ref_frame_bufs[framei][0].stride;
|
|
u_stride=_state->ref_frame_bufs[framei][1].stride;
|
|
v_stride=_state->ref_frame_bufs[framei][2].stride;
|
|
/*Chroma up-sampling is just done with a box filter.
|
|
This is very likely what will actually be used in practice on a real
|
|
display, and also removes one more layer to search in for the source of
|
|
artifacts.
|
|
As an added bonus, it's dead simple.*/
|
|
for(imgi=height;imgi-->0;){
|
|
int dc;
|
|
y=y_row;
|
|
u=u_row;
|
|
v=v_row;
|
|
for(imgj=0;imgj<6*width;){
|
|
float yval;
|
|
float uval;
|
|
float vval;
|
|
unsigned rval;
|
|
unsigned gval;
|
|
unsigned bval;
|
|
/*This is intentionally slow and very accurate.*/
|
|
yval=(*y-16)*(1.0F/219);
|
|
uval=(*u-128)*(2*(1-0.114F)/224);
|
|
vval=(*v-128)*(2*(1-0.299F)/224);
|
|
rval=OC_CLAMPI(0,(int)(65535*(yval+vval)+0.5F),65535);
|
|
gval=OC_CLAMPI(0,(int)(65535*(
|
|
yval-uval*(0.114F/0.587F)-vval*(0.299F/0.587F))+0.5F),65535);
|
|
bval=OC_CLAMPI(0,(int)(65535*(yval+uval)+0.5F),65535);
|
|
image[imgi][imgj++]=(unsigned char)(rval>>8);
|
|
image[imgi][imgj++]=(unsigned char)(rval&0xFF);
|
|
image[imgi][imgj++]=(unsigned char)(gval>>8);
|
|
image[imgi][imgj++]=(unsigned char)(gval&0xFF);
|
|
image[imgi][imgj++]=(unsigned char)(bval>>8);
|
|
image[imgi][imgj++]=(unsigned char)(bval&0xFF);
|
|
dc=(y-y_row&1)|(_state->info.pixel_fmt&1);
|
|
y++;
|
|
u+=dc;
|
|
v+=dc;
|
|
}
|
|
dc=-((height-1-imgi&1)|_state->info.pixel_fmt>>1);
|
|
y_row+=y_stride;
|
|
u_row+=dc&u_stride;
|
|
v_row+=dc&v_stride;
|
|
}
|
|
png_init_io(png,fp);
|
|
png_set_compression_level(png,Z_BEST_COMPRESSION);
|
|
png_set_IHDR(png,info,width,height,16,PNG_COLOR_TYPE_RGB,
|
|
PNG_INTERLACE_NONE,PNG_COMPRESSION_TYPE_DEFAULT,PNG_FILTER_TYPE_DEFAULT);
|
|
switch(_state->info.colorspace){
|
|
case TH_CS_ITU_REC_470M:{
|
|
png_set_gAMA(png,info,2.2);
|
|
png_set_cHRM_fixed(png,info,31006,31616,
|
|
67000,32000,21000,71000,14000,8000);
|
|
}break;
|
|
case TH_CS_ITU_REC_470BG:{
|
|
png_set_gAMA(png,info,2.67);
|
|
png_set_cHRM_fixed(png,info,31271,32902,
|
|
64000,33000,29000,60000,15000,6000);
|
|
}break;
|
|
default:break;
|
|
}
|
|
png_set_pHYs(png,info,_state->info.aspect_numerator,
|
|
_state->info.aspect_denominator,0);
|
|
png_set_rows(png,info,image);
|
|
png_write_png(png,info,PNG_TRANSFORM_IDENTITY,NULL);
|
|
png_write_end(png,info);
|
|
png_destroy_write_struct(&png,&info);
|
|
oc_free_2d(image);
|
|
fclose(fp);
|
|
return 0;
|
|
}
|
|
#endif
|
|
|
|
|
|
|
|
ogg_int64_t th_granule_frame(void *_encdec,ogg_int64_t _granpos){
|
|
oc_theora_state *state;
|
|
state=(oc_theora_state *)_encdec;
|
|
if(_granpos>=0){
|
|
ogg_int64_t iframe;
|
|
ogg_int64_t pframe;
|
|
iframe=_granpos>>state->info.keyframe_granule_shift;
|
|
pframe=_granpos-(iframe<<state->info.keyframe_granule_shift);
|
|
/*3.2.0 streams store the frame index in the granule position.
|
|
3.2.1 and later store the frame count.
|
|
We return the index, so adjust the value if we have a 3.2.1 or later
|
|
stream.*/
|
|
return iframe+pframe-TH_VERSION_CHECK(&state->info,3,2,1);
|
|
}
|
|
return -1;
|
|
}
|
|
|
|
double th_granule_time(void *_encdec,ogg_int64_t _granpos){
|
|
oc_theora_state *state;
|
|
state=(oc_theora_state *)_encdec;
|
|
if(_granpos>=0){
|
|
return (th_granule_frame(_encdec, _granpos)+1)*(
|
|
(double)state->info.fps_denominator/state->info.fps_numerator);
|
|
}
|
|
return -1;
|
|
}
|