gecko-dev/media/libtheora/lib/internal.h
2008-08-14 11:21:24 +01:00

509 lines
19 KiB
C

/********************************************************************
* *
* THIS FILE IS PART OF THE OggTheora SOFTWARE CODEC SOURCE CODE. *
* USE, DISTRIBUTION AND REPRODUCTION OF THIS LIBRARY SOURCE IS *
* GOVERNED BY A BSD-STYLE SOURCE LICENSE INCLUDED WITH THIS SOURCE *
* IN 'COPYING'. PLEASE READ THESE TERMS BEFORE DISTRIBUTING. *
* *
* THE Theora SOURCE CODE IS COPYRIGHT (C) 2002-2007 *
* by the Xiph.Org Foundation http://www.xiph.org/ *
* *
********************************************************************
function:
last mod: $Id: internal.h 14714 2008-04-12 01:04:43Z giles $
********************************************************************/
#if !defined(_internal_H)
# define _internal_H (1)
# include <stdlib.h>
# if defined(HAVE_CONFIG_H)
# include <config.h>
# endif
# include "theora/codec.h"
# include "theora/theora.h"
# include "dec/ocintrin.h"
# include "dec/huffman.h"
# include "dec/quant.h"
/* debug macros */
#if defined(_MSC_VER) && _MSC_VER < 1400
static const dframe = 0;
static void TH_DEBUG(const char *fmt, ...) {}
#elif defined(_TH_DEBUG_)
#include <stdio.h>
extern long dframe;
extern FILE *debugout;
#define TH_DEBUG(...) fprintf(debugout, __VA_ARGS__)
#else
#define TH_DEBUG(...)
#endif
/*Thank you Microsoft, I know the order of operations.*/
# if defined(_MSC_VER)
# pragma warning(disable:4554) /* order of operations */
# pragma warning(disable:4799) /* disable missing EMMS warnings */
# endif
/*This library's version.*/
# define OC_VENDOR_STRING "Xiph.Org libTheora I 20071025 3 2 1"
/*Theora bitstream version.*/
# define TH_VERSION_MAJOR (3)
# define TH_VERSION_MINOR (2)
# define TH_VERSION_SUB (1)
# define TH_VERSION_CHECK(_info,_maj,_min,_sub) \
((_info)->version_major>(_maj)||(_info)->version_major==(_maj)&& \
((_info)->version_minor>(_min)||(_info)->version_minor==(_min)&& \
(_info)->version_subminor>=(_sub)))
/*A keyframe.*/
#define OC_INTRA_FRAME (0)
/*A predicted frame.*/
#define OC_INTER_FRAME (1)
/*A frame of unknown type (frame type decision has not yet been made).*/
#define OC_UNKWN_FRAME (-1)
/*The amount of padding to add to the reconstructed frame buffers on all
sides.
This is used to allow unrestricted motion vectors without special casing.
This must be a multiple of 2.*/
#define OC_UMV_PADDING (16)
/*Frame classification indices.*/
/*The previous golden frame.*/
#define OC_FRAME_GOLD (0)
/*The previous frame.*/
#define OC_FRAME_PREV (1)
/*The current frame.*/
#define OC_FRAME_SELF (2)
/*The input or output buffer.*/
#define OC_FRAME_IO (3)
/*Macroblock modes.*/
/*Macro block is invalid: It is never coded.*/
#define OC_MODE_INVALID (-1)
/*Encoded difference from the same macro block in the previous frame.*/
#define OC_MODE_INTER_NOMV (0)
/*Encoded with no motion compensated prediction.*/
#define OC_MODE_INTRA (1)
/*Encoded difference from the previous frame offset by the given motion
vector.*/
#define OC_MODE_INTER_MV (2)
/*Encoded difference from the previous frame offset by the last coded motion
vector.*/
#define OC_MODE_INTER_MV_LAST (3)
/*Encoded difference from the previous frame offset by the second to last
coded motion vector.*/
#define OC_MODE_INTER_MV_LAST2 (4)
/*Encoded difference from the same macro block in the previous golden
frame.*/
#define OC_MODE_GOLDEN_NOMV (5)
/*Encoded difference from the previous golden frame offset by the given motion
vector.*/
#define OC_MODE_GOLDEN_MV (6)
/*Encoded difference from the previous frame offset by the individual motion
vectors given for each block.*/
#define OC_MODE_INTER_MV_FOUR (7)
/*The number of (coded) modes.*/
#define OC_NMODES (8)
/*Macro block is not coded.*/
#define OC_MODE_NOT_CODED (8)
/*Predictor bit flags.*/
/*Left.*/
#define OC_PL (1)
/*Upper-left.*/
#define OC_PUL (2)
/*Up.*/
#define OC_PU (4)
/*Upper-right.*/
#define OC_PUR (8)
/*Constants for the packet state machine common between encoder and decoder.*/
/*Next packet to emit/read: Codec info header.*/
#define OC_PACKET_INFO_HDR (-3)
/*Next packet to emit/read: Comment header.*/
#define OC_PACKET_COMMENT_HDR (-2)
/*Next packet to emit/read: Codec setup header.*/
#define OC_PACKET_SETUP_HDR (-1)
/*No more packets to emit/read.*/
#define OC_PACKET_DONE (INT_MAX)
typedef struct oc_theora_state oc_theora_state;
/*A map from a super block to fragment numbers.*/
typedef int oc_sb_map[4][4];
/*A map from a macro block to fragment numbers.*/
typedef int oc_mb_map[3][4];
/*A motion vector.*/
typedef signed char oc_mv[2];
/*Super block information.
Super blocks are 32x32 segments of pixels in a single color plane indexed
in image order.
Internally, super blocks are broken up into four quadrants, each of which
contains a 2x2 pattern of blocks, each of which is an 8x8 block of pixels.
Quadrants, and the blocks within them, are indexed in a special order called
a "Hilbert curve" within the super block.
In order to differentiate between the Hilbert-curve indexing strategy and
the regular image order indexing strategy, blocks indexed in image order
are called "fragments".
Fragments are indexed in image order, left to right, then bottom to top,
from Y plane to Cb plane to Cr plane.*/
typedef struct{
unsigned coded_fully:1;
unsigned coded_partially:1;
unsigned quad_valid:4;
oc_sb_map map;
}oc_sb;
/*Macro block information.
The co-located fragments in all image planes corresponding to the location of
a single luma plane super block quadrant forms a macro block.
Thus there is only a single set of macro blocks for all planes, which
contains between 6 and 12 fragments, depending on the pixel format.
Therefore macro block information is kept in a separate array from super
blocks, to avoid unused space in the other planes.*/
typedef struct{
/*The current macro block mode.
A negative number indicates the macro block lies entirely outside the
coded frame.*/
int mode;
/*The X location of the macro block's upper-left hand pixel.*/
int x;
/*The Y location of the macro block's upper-right hand pixel.*/
int y;
/*The fragments that belong to this macro block in each color plane.
Fragments are stored in image order (left to right then top to bottom).
When chroma components are decimated, the extra fragments have an index of
-1.*/
oc_mb_map map;
}oc_mb;
/*Information about a fragment which intersects the border of the displayable
region.
This marks which pixels belong to the displayable region, and is used to
ensure that pixels outside of this region are never referenced.
This allows applications to pass in buffers that are really the size of the
displayable region without causing a seg fault.*/
typedef struct{
/*A bit mask marking which pixels are in the displayable region.
Pixel (x,y) corresponds to bit (y<<3|x).*/
ogg_int64_t mask;
/*The number of pixels in the displayable region.
This is always positive, and always less than 64.*/
int npixels;
}oc_border_info;
/*Fragment information.*/
typedef struct{
/*A flag indicating whether or not this fragment is coded.*/
unsigned coded:1;
/*A flag indicating that all of this fragment lies outside the displayable
region of the frame.
Note the contrast with an invalid macro block, which is outside the coded
frame, not just the displayable one.*/
unsigned invalid:1;
/*The quality index used for this fragment's AC coefficients.*/
unsigned qi:6;
/*The mode of the macroblock this fragment belongs to.*/
int mbmode:8;
/*The prediction-corrected DC component.*/
int dc:16;
/*A pointer to the portion of an image covered by this fragment in several
images.
The first three are reconstructed frame buffers, while the last is the
input image buffer.
The appropriate stride value is determined by the color plane the fragment
belongs in.*/
unsigned char *buffer[4];
/*Information for fragments which lie partially outside the displayable
region.
For fragments completely inside or outside this region, this is NULL.*/
oc_border_info *border;
/*The motion vector used for this fragment.*/
oc_mv mv;
#ifdef _TH_DEBUG_
int quant[64];
int freq[64];
int time[64];
int recon[64];
int loop[64];
#endif
}oc_fragment;
/*A description of each fragment plane.*/
typedef struct{
/*The number of fragments in the horizontal direction.*/
int nhfrags;
/*The number of fragments in the vertical direction.*/
int nvfrags;
/*The offset of the first fragment in the plane.*/
int froffset;
/*The total number of fragments in the plane.*/
int nfrags;
/*The number of super blocks in the horizontal direction.*/
int nhsbs;
/*The number of super blocks in the vertical direction.*/
int nvsbs;
/*The offset of the first super block in the plane.*/
int sboffset;
/*The total number of super blocks in the plane.*/
int nsbs;
}oc_fragment_plane;
/*The shared (encoder and decoder) functions that have accelerated variants.*/
typedef struct{
void (*frag_recon_intra)(unsigned char *_dst,int _dst_ystride,
const ogg_int16_t *_residue);
void (*frag_recon_inter)(unsigned char *_dst,int _dst_ystride,
const unsigned char *_src,int _src_ystride,const ogg_int16_t *_residue);
void (*frag_recon_inter2)(unsigned char *_dst,int _dst_ystride,
const unsigned char *_src1,int _src1_ystride,const unsigned char *_src2,
int _src2_ystride,const ogg_int16_t *_residue);
void (*state_frag_copy)(const oc_theora_state *_state,
const int *_fragis,int _nfragis,int _dst_frame,int _src_frame,int _pli);
void (*state_frag_recon)(oc_theora_state *_state,oc_fragment *_frag,
int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,int _ncoefs,
ogg_uint16_t _dc_iquant,const ogg_uint16_t _ac_iquant[64]);
void (*restore_fpu)(void);
void (*state_loop_filter_frag_rows)(oc_theora_state *_state,int *_bv,
int _refi,int _pli,int _fragy0,int _fragy_end);
}oc_base_opt_vtable;
/*Common state information between the encoder and decoder.*/
struct oc_theora_state{
/*The stream information.*/
th_info info;
/*Table for shared accelerated functions.*/
oc_base_opt_vtable opt_vtable;
/*CPU flags to detect the presence of extended instruction sets.*/
ogg_uint32_t cpu_flags;
/*The fragment plane descriptions.*/
oc_fragment_plane fplanes[3];
/*The total number of fragments in a single frame.*/
int nfrags;
/*The list of fragments, indexed in image order.*/
oc_fragment *frags;
/*The total number of super blocks in a single frame.*/
int nsbs;
/*The list of super blocks, indexed in image order.*/
oc_sb *sbs;
/*The number of macro blocks in the X direction.*/
int nhmbs;
/*The number of macro blocks in the Y direction.*/
int nvmbs;
/*The total number of macro blocks.*/
int nmbs;
/*The list of macro blocks, indexed in super block order.
That is, the macro block corresponding to the macro block mbi in (luma
plane) super block sbi is (sbi<<2|mbi).*/
oc_mb *mbs;
/*The list of coded fragments, in coded order.*/
int *coded_fragis;
/*The number of coded fragments in each plane.*/
int ncoded_fragis[3];
/*The list of uncoded fragments.
This just past the end of the list, which is in reverse order, and
uses the same block of allocated storage as the coded_fragis list.*/
int *uncoded_fragis;
/*The number of uncoded fragments in each plane.*/
int nuncoded_fragis[3];
/*The list of coded macro blocks in the Y plane, in coded order.*/
int *coded_mbis;
/*The number of coded macro blocks in the Y plane.*/
int ncoded_mbis;
/*A copy of the image data used to fill the input pointers in each fragment.
If the data pointers or strides change, these input pointers must be
re-populated.*/
th_ycbcr_buffer input;
/*The number of unique border patterns.*/
int nborders;
/*The storage for the border info for all border fragments.
This data is pointed to from the appropriate fragments.*/
oc_border_info borders[16];
/*The index of the buffers being used for each OC_FRAME_* reference frame.*/
int ref_frame_idx[3];
/*The actual buffers used for the previously decoded frames.*/
th_ycbcr_buffer ref_frame_bufs[3];
/*The storage for the reference frame buffers.*/
unsigned char *ref_frame_data;
/*The frame number of the last keyframe.*/
ogg_int64_t keyframe_num;
/*The frame number of the current frame.*/
ogg_int64_t curframe_num;
/*The granpos of the current frame.*/
ogg_int64_t granpos;
/*The type of the current frame.*/
int frame_type;
/*The quality indices of the current frame.*/
int qis[3];
/*The number of quality indices used in the current frame.*/
int nqis;
/*The dequantization tables.*/
oc_quant_table *dequant_tables[2][3];
oc_quant_tables dequant_table_data[2][3];
/*Loop filter strength parameters.*/
unsigned char loop_filter_limits[64];
};
/*The function type used to fill in the chroma plane motion vectors for a
macro block when 4 different motion vectors are specified in the luma
plane.
_cbmvs: The chroma block-level motion vectors to fill in.
_lmbmv: The luma macro-block level motion vector to fill in for use in
prediction.
_lbmvs: The luma block-level motion vectors.*/
typedef void (*oc_set_chroma_mvs_func)(oc_mv _cbmvs[4],const oc_mv _lbmvs[4]);
/*A map from the index in the zig zag scan to the coefficient number in a
block.
The extra 64 entries send out of bounds indexes to index 64.
This is used to safely ignore invalid zero runs when decoding
coefficients.*/
extern const int OC_FZIG_ZAG[128];
/*A map from the coefficient number in a block to its index in the zig zag
scan.*/
extern const int OC_IZIG_ZAG[64];
/*The predictor frame to use for each macro block mode.*/
extern const int OC_FRAME_FOR_MODE[OC_NMODES];
/*A map from physical macro block ordering to bitstream macro block
ordering within a super block.*/
extern const int OC_MB_MAP[2][2];
/*A list of the indices in the oc_mb.map array that can be valid for each of
the various chroma decimation types.*/
extern const int OC_MB_MAP_IDXS[TH_PF_NFORMATS][12];
/*The number of indices in the oc_mb.map array that can be valid for each of
the various chroma decimation types.*/
extern const int OC_MB_MAP_NIDXS[TH_PF_NFORMATS];
/*A table of functions used to fill in the Cb,Cr plane motion vectors for a
macro block when 4 different motion vectors are specified in the luma
plane.*/
extern const oc_set_chroma_mvs_func OC_SET_CHROMA_MVS_TABLE[TH_PF_NFORMATS];
int oc_ilog(unsigned _v);
void **oc_malloc_2d(size_t _height,size_t _width,size_t _sz);
void **oc_calloc_2d(size_t _height,size_t _width,size_t _sz);
void oc_free_2d(void *_ptr);
void oc_ycbcr_buffer_flip(th_ycbcr_buffer _dst,
const th_ycbcr_buffer _src);
int oc_dct_token_skip(int _token,int _extra_bits);
int oc_frag_pred_dc(const oc_fragment *_frag,
const oc_fragment_plane *_fplane,int _x,int _y,int _pred_last[3]);
int oc_state_init(oc_theora_state *_state,const th_info *_info);
void oc_state_clear(oc_theora_state *_state);
void oc_state_vtable_init_c(oc_theora_state *_state);
void oc_state_borders_fill_rows(oc_theora_state *_state,int _refi,int _pli,
int _y0,int _yend);
void oc_state_borders_fill_caps(oc_theora_state *_state,int _refi,int _pli);
void oc_state_borders_fill(oc_theora_state *_state,int _refi);
void oc_state_fill_buffer_ptrs(oc_theora_state *_state,int _buf_idx,
th_ycbcr_buffer _img);
int oc_state_mbi_for_pos(oc_theora_state *_state,int _mbx,int _mby);
int oc_state_get_mv_offsets(oc_theora_state *_state,int *_offsets,
int _dx,int _dy,int _ystride,int _pli);
int oc_state_loop_filter_init(oc_theora_state *_state,int *_bv);
void oc_state_loop_filter(oc_theora_state *_state,int _frame);
#if defined(OC_DUMP_IMAGES)
int oc_state_dump_frame(const oc_theora_state *_state,int _frame,
const char *_suf);
#endif
/*Shared accelerated functions.*/
void oc_frag_recon_intra(const oc_theora_state *_state,
unsigned char *_dst,int _dst_ystride,const ogg_int16_t *_residue);
void oc_frag_recon_inter(const oc_theora_state *_state,
unsigned char *_dst,int _dst_ystride,
const unsigned char *_src,int _src_ystride,const ogg_int16_t *_residue);
void oc_frag_recon_inter2(const oc_theora_state *_state,
unsigned char *_dst,int _dst_ystride,
const unsigned char *_src1,int _src1_ystride,const unsigned char *_src2,
int _src2_ystride,const ogg_int16_t *_residue);
void oc_state_frag_copy(const oc_theora_state *_state,const int *_fragis,
int _nfragis,int _dst_frame,int _src_frame,int _pli);
void oc_state_frag_recon(oc_theora_state *_state,oc_fragment *_frag,
int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,int _ncoefs,
ogg_uint16_t _dc_iquant,const ogg_uint16_t _ac_iquant[64]);
void oc_state_loop_filter_frag_rows(oc_theora_state *_state,int *_bv,
int _refi,int _pli,int _fragy0,int _fragy_end);
void oc_restore_fpu(const oc_theora_state *_state);
/*Default pure-C implementations.*/
void oc_frag_recon_intra_c(unsigned char *_dst,int _dst_ystride,
const ogg_int16_t *_residue);
void oc_frag_recon_inter_c(unsigned char *_dst,int _dst_ystride,
const unsigned char *_src,int _src_ystride,const ogg_int16_t *_residue);
void oc_frag_recon_inter2_c(unsigned char *_dst,int _dst_ystride,
const unsigned char *_src1,int _src1_ystride,const unsigned char *_src2,
int _src2_ystride,const ogg_int16_t *_residue);
void oc_state_frag_copy_c(const oc_theora_state *_state,const int *_fragis,
int _nfragis,int _dst_frame,int _src_frame,int _pli);
void oc_state_frag_recon_c(oc_theora_state *_state,oc_fragment *_frag,
int _pli,ogg_int16_t _dct_coeffs[128],int _last_zzi,int _ncoefs,
ogg_uint16_t _dc_iquant,const ogg_uint16_t _ac_iquant[64]);
void oc_state_loop_filter_frag_rows_c(oc_theora_state *_state,int *_bv,
int _refi,int _pli,int _fragy0,int _fragy_end);
void oc_restore_fpu_c(void);
/*We need a way to call a few encoder functions without introducing a link-time
dependency into the decoder, while still allowing the old alpha API which
does not distinguish between encoder and decoder objects to be used.
We do this by placing a function table at the start of the encoder object
which can dispatch into the encoder library.
We do a similar thing for the decoder in case we ever decide to split off a
common base library.*/
typedef void (*oc_state_clear_func)(theora_state *_th);
typedef int (*oc_state_control_func)(theora_state *th,int req,
void *buf,size_t buf_sz);
typedef ogg_int64_t (*oc_state_granule_frame_func)(theora_state *_th,
ogg_int64_t _granulepos);
typedef double (*oc_state_granule_time_func)(theora_state *_th,
ogg_int64_t _granulepos);
typedef struct oc_state_dispatch_vtbl oc_state_dispatch_vtbl;
struct oc_state_dispatch_vtbl{
oc_state_clear_func clear;
oc_state_control_func control;
oc_state_granule_frame_func granule_frame;
oc_state_granule_time_func granule_time;
};
#endif