/* Predict.c, motion compensation routines */
/* Copyright (C) 1996, MPEG Software Simulation Group. All Rights Reserved. */
/*
* Disclaimer of Warranty
*
* These software programs are available to the user without any license fee or
* royalty on an "as is" basis. The MPEG Software Simulation Group disclaims
* any and all warranties, whether express, implied, or statuary, including any
* implied warranties or merchantability or of fitness for a particular
* purpose. In no event shall the copyright-holder be liable for any
* incidental, punitive, or consequential damages of any kind whatsoever
* arising from the use of these programs.
*
* This disclaimer of warranty extends to the user of these programs and user's
* customers, employees, agents, transferees, successors, and assigns.
*
* The MPEG Software Simulation Group does not represent or warrant that the
* programs furnished hereunder are free of infringement of any third-party
* patents.
*
* Commercial implementations of MPEG-1 and MPEG-2 video, including shareware,
* are subject to royalty fees to patent holders. Many of these patents are
* general enough such that they are unavoidable regardless of implementation
* design.
*
*/
#include <stdio.h>
#include "config.h"
#include "global.h"
/* private prototypes */
static void form_prediction _ANSI_ARGS_
((unsigned char *src
[], int sfield
,
unsigned char *dst
[], int dfield
,
int lx
, int lx2
, int w
, int h
, int x
, int y
, int dx
, int dy
,
int average_flag
));
static void form_component_prediction _ANSI_ARGS_
((unsigned char *src
, unsigned char *dst
,
int lx
, int lx2
, int w
, int h
, int x
, int y
, int dx
, int dy
, int average_flag
));
void form_predictions
(bx
,by
,macroblock_type
,motion_type
,PMV
,motion_vertical_field_select
,dmvector
,stwtype
)
int bx
, by
;
int macroblock_type
;
int motion_type
;
int PMV
[2][2][2], motion_vertical_field_select
[2][2], dmvector
[2];
int stwtype
;
{
int currentfield
;
unsigned char **predframe
;
int DMV
[2][2];
int stwtop
, stwbot
;
stwtop
= stwtype
%3; /* 0:temporal, 1:(spat+temp)/2, 2:spatial */
stwbot
= stwtype
/3;
if ((macroblock_type
& MACROBLOCK_MOTION_FORWARD
)
|| (picture_coding_type
==P_TYPE
))
{
if (picture_structure
==FRAME_PICTURE
)
{
if ((motion_type
==MC_FRAME
)
|| !(macroblock_type
& MACROBLOCK_MOTION_FORWARD
))
{
/* frame-based prediction (broken into top and bottom halves
for spatial scalability prediction purposes) */
if (stwtop
<2)
form_prediction
(forward_reference_frame
,0,current_frame
,0,
Coded_Picture_Width
,Coded_Picture_Width
<<1,16,8,bx
,by
,
PMV
[0][0][0],PMV
[0][0][1],stwtop
);
if (stwbot
<2)
form_prediction
(forward_reference_frame
,1,current_frame
,1,
Coded_Picture_Width
,Coded_Picture_Width
<<1,16,8,bx
,by
,
PMV
[0][0][0],PMV
[0][0][1],stwbot
);
}
else if (motion_type
==MC_FIELD
) /* field-based prediction */
{
/* top field prediction */
if (stwtop
<2)
form_prediction
(forward_reference_frame
,motion_vertical_field_select
[0][0],
current_frame
,0,Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,
bx
,by
>>1,PMV
[0][0][0],PMV
[0][0][1]>>1,stwtop
);
/* bottom field prediction */
if (stwbot
<2)
form_prediction
(forward_reference_frame
,motion_vertical_field_select
[1][0],
current_frame
,1,Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,
bx
,by
>>1,PMV
[1][0][0],PMV
[1][0][1]>>1,stwbot
);
}
else if (motion_type
==MC_DMV
) /* dual prime prediction */
{
/* calculate derived motion vectors */
Dual_Prime_Arithmetic
(DMV
,dmvector
,PMV
[0][0][0],PMV
[0][0][1]>>1);
if (stwtop
<2)
{
/* predict top field from top field */
form_prediction
(forward_reference_frame
,0,current_frame
,0,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,bx
,by
>>1,
PMV
[0][0][0],PMV
[0][0][1]>>1,0);
/* predict and add to top field from bottom field */
form_prediction
(forward_reference_frame
,1,current_frame
,0,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,bx
,by
>>1,
DMV
[0][0],DMV
[0][1],1);
}
if (stwbot
<2)
{
/* predict bottom field from bottom field */
form_prediction
(forward_reference_frame
,1,current_frame
,1,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,bx
,by
>>1,
PMV
[0][0][0],PMV
[0][0][1]>>1,0);
/* predict and add to bottom field from top field */
form_prediction
(forward_reference_frame
,0,current_frame
,1,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,bx
,by
>>1,
DMV
[1][0],DMV
[1][1],1);
}
}
else
/* invalid motion_type */
printf("invalid motion_type\n");
}
else /* TOP_FIELD or BOTTOM_FIELD */
{
/* field picture */
currentfield
= (picture_structure
==BOTTOM_FIELD
);
/* determine which frame to use for prediction */
if ((picture_coding_type
==P_TYPE
) && Second_Field
&& (currentfield
!=motion_vertical_field_select
[0][0]))
predframe
= backward_reference_frame
; /* same frame */
else
predframe
= forward_reference_frame
; /* previous frame */
if ((motion_type
==MC_FIELD
)
|| !(macroblock_type
& MACROBLOCK_MOTION_FORWARD
))
{
/* field-based prediction */
if (stwtop
<2)
form_prediction
(predframe
,motion_vertical_field_select
[0][0],current_frame
,0,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,16,bx
,by
,
PMV
[0][0][0],PMV
[0][0][1],stwtop
);
}
else if (motion_type
==MC_16X8
)
{
if (stwtop
<2)
{
form_prediction
(predframe
,motion_vertical_field_select
[0][0],current_frame
,0,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,bx
,by
,
PMV
[0][0][0],PMV
[0][0][1],stwtop
);
/* determine which frame to use for lower half prediction */
if ((picture_coding_type
==P_TYPE
) && Second_Field
&& (currentfield
!=motion_vertical_field_select
[1][0]))
predframe
= backward_reference_frame
; /* same frame */
else
predframe
= forward_reference_frame
; /* previous frame */
form_prediction
(predframe
,motion_vertical_field_select
[1][0],current_frame
,0,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,bx
,by
+8,
PMV
[1][0][0],PMV
[1][0][1],stwtop
);
}
}
else if (motion_type
==MC_DMV
) /* dual prime prediction */
{
if (Second_Field
)
predframe
= backward_reference_frame
; /* same frame */
else
predframe
= forward_reference_frame
; /* previous frame */
/* calculate derived motion vectors */
Dual_Prime_Arithmetic
(DMV
,dmvector
,PMV
[0][0][0],PMV
[0][0][1]);
/* predict from field of same parity */
form_prediction
(forward_reference_frame
,currentfield
,current_frame
,0,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,16,bx
,by
,
PMV
[0][0][0],PMV
[0][0][1],0);
/* predict from field of opposite parity */
form_prediction
(predframe
,!currentfield
,current_frame
,0,
Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,16,bx
,by
,
DMV
[0][0],DMV
[0][1],1);
}
else
/* invalid motion_type */
printf("invalid motion_type\n");
}
stwtop
= stwbot
= 1;
}
if (macroblock_type
& MACROBLOCK_MOTION_BACKWARD
)
{
if (picture_structure
==FRAME_PICTURE
)
{
if (motion_type
==MC_FRAME
)
{
/* frame-based prediction */
if (stwtop
<2)
form_prediction
(backward_reference_frame
,0,current_frame
,0,
Coded_Picture_Width
,Coded_Picture_Width
<<1,16,8,bx
,by
,
PMV
[0][1][0],PMV
[0][1][1],stwtop
);
if (stwbot
<2)
form_prediction
(backward_reference_frame
,1,current_frame
,1,
Coded_Picture_Width
,Coded_Picture_Width
<<1,16,8,bx
,by
,
PMV
[0][1][0],PMV
[0][1][1],stwbot
);
}
else /* field-based prediction */
{
/* top field prediction */
if (stwtop
<2)
form_prediction
(backward_reference_frame
,motion_vertical_field_select
[0][1],
current_frame
,0,Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,
bx
,by
>>1,PMV
[0][1][0],PMV
[0][1][1]>>1,stwtop
);
/* bottom field prediction */
if (stwbot
<2)
form_prediction
(backward_reference_frame
,motion_vertical_field_select
[1][1],
current_frame
,1,Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,
bx
,by
>>1,PMV
[1][1][0],PMV
[1][1][1]>>1,stwbot
);
}
}
else /* TOP_FIELD or BOTTOM_FIELD */
{
/* field picture */
if (motion_type
==MC_FIELD
)
{
/* field-based prediction */
form_prediction
(backward_reference_frame
,motion_vertical_field_select
[0][1],
current_frame
,0,Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,16,
bx
,by
,PMV
[0][1][0],PMV
[0][1][1],stwtop
);
}
else if (motion_type
==MC_16X8
)
{
form_prediction
(backward_reference_frame
,motion_vertical_field_select
[0][1],
current_frame
,0,Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,
bx
,by
,PMV
[0][1][0],PMV
[0][1][1],stwtop
);
form_prediction
(backward_reference_frame
,motion_vertical_field_select
[1][1],
current_frame
,0,Coded_Picture_Width
<<1,Coded_Picture_Width
<<1,16,8,
bx
,by
+8,PMV
[1][1][0],PMV
[1][1][1],stwtop
);
}
else
/* invalid motion_type */
printf("invalid motion_type\n");
}
}
}
static void form_prediction
(src
,sfield
,dst
,dfield
,lx
,lx2
,w
,h
,x
,y
,dx
,dy
,average_flag
)
unsigned char *src
[]; /* prediction source buffer */
int sfield
; /* prediction source field number (0 or 1) */
unsigned char *dst
[]; /* prediction destination buffer */
int dfield
; /* prediction destination field number (0 or 1)*/
int lx
,lx2
; /* line strides */
int w
,h
; /* prediction block/sub-block width, height */
int x
,y
; /* pixel co-ordinates of top-left sample in current MB */
int dx
,dy
; /* horizontal, vertical prediction address */
int average_flag
; /* add prediction error to prediction ? */
{
/* Y */
form_component_prediction
(src
[0]+(sfield
?lx2
>>1:0),dst
[0]+(dfield
?lx2
>>1:0),
lx
,lx2
,w
,h
,x
,y
,dx
,dy
,average_flag
);
if (chroma_format
!=CHROMA444
)
{
lx
>>=1; lx2
>>=1; w
>>=1; x
>>=1; dx
/=2;
}
if (chroma_format
==CHROMA420
)
{
h
>>=1; y
>>=1; dy
/=2;
}
/* Cb */
form_component_prediction
(src
[1]+(sfield
?lx2
>>1:0),dst
[1]+(dfield
?lx2
>>1:0),
lx
,lx2
,w
,h
,x
,y
,dx
,dy
,average_flag
);
/* Cr */
form_component_prediction
(src
[2]+(sfield
?lx2
>>1:0),dst
[2]+(dfield
?lx2
>>1:0),
lx
,lx2
,w
,h
,x
,y
,dx
,dy
,average_flag
);
}
/* ISO/IEC 13818-2 section 7.6.4: Forming predictions */
/* NOTE: the arithmetic below produces numerically equivalent results
* to 7.6.4, yet is more elegant. It differs in the following ways:
*
* 1. the vectors (dx, dy) are based on cartesian frame
* coordiantes along a half-pel grid (always positive numbers)
* In contrast, vector[r][s][t] are differential (with positive and
* negative values). As a result, deriving the integer vectors
* (int_vec[t]) from dx, dy is accomplished by a simple right shift.
*
* 2. Half pel flags (xh, yh) are equivalent to the LSB (Least
* Significant Bit) of the half-pel coordinates (dx,dy).
*
*
* NOTE: the work of combining predictions (ISO/IEC 13818-2 section 7.6.7)
* is distributed among several other stages. This is accomplished by
* folding line offsets into the source and destination (src,dst)
* addresses (note the call arguments to form_prediction() in Predict()),
* line stride variables lx and lx2, the block dimension variables (w,h),
* average_flag, and by the very order in which Predict() is called.
* This implementation design (implicitly different than the spec)
* was chosen for its elegance.
*/
static void form_component_prediction
(src
,dst
,lx
,lx2
,w
,h
,x
,y
,dx
,dy
,average_flag
)
unsigned char *src
;
unsigned char *dst
;
int lx
; /* raster line increment */
int lx2
;
int w
,h
;
int x
,y
;
int dx
,dy
;
int average_flag
; /* flag that signals bi-directional or Dual-Prime
averaging (7.6.7.1 and 7.6.7.4). if average_flag==1,
a previously formed prediction has been stored in
pel_pred[] */
{
int xint
; /* horizontal integer sample vector: analogous to int_vec[0] */
int yint
; /* vertical integer sample vectors: analogous to int_vec[1] */
int xh
; /* horizontal half sample flag: analogous to half_flag[0] */
int yh
; /* vertical half sample flag: analogous to half_flag[1] */
int i
, j
, v
;
unsigned char *s
; /* source pointer: analogous to pel_ref[][] */
unsigned char *d
; /* destination pointer: analogous to pel_pred[][] */
/* half pel scaling for integer vectors */
xint
= dx
>>1;
yint
= dy
>>1;
/* derive half pel flags */
xh
= dx
& 1;
yh
= dy
& 1;
/* compute the linear address of pel_ref[][] and pel_pred[][]
based on cartesian/raster cordinates provided */
s
= src
+ lx
*(y
+yint
) + x
+ xint
;
d
= dst
+ lx
*y
+ x
;
if (!xh
&& !yh
) /* no horizontal nor vertical half-pel */
{
if (average_flag
)
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
v
= d
[i
]+s
[i
];
d
[i
] = (v
+(v
>=0?1:0))>>1;
}
s
+= lx2
;
d
+= lx2
;
}
}
else
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
d
[i
] = s
[i
];
}
s
+= lx2
;
d
+= lx2
;
}
}
}
else if (!xh
&& yh
) /* no horizontal but vertical half-pel */
{
if (average_flag
)
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
v
= d
[i
] + ((unsigned int)(s
[i
]+s
[i
+lx
]+1)>>1);
d
[i
]=(v
+(v
>=0?1:0))>>1;
}
s
+= lx2
;
d
+= lx2
;
}
}
else
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
d
[i
] = (unsigned int)(s
[i
]+s
[i
+lx
]+1)>>1;
}
s
+= lx2
;
d
+= lx2
;
}
}
}
else if (xh
&& !yh
) /* horizontal but no vertical half-pel */
{
if (average_flag
)
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
v
= d
[i
] + ((unsigned int)(s
[i
]+s
[i
+1]+1)>>1);
d
[i
] = (v
+(v
>=0?1:0))>>1;
}
s
+= lx2
;
d
+= lx2
;
}
}
else
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
d
[i
] = (unsigned int)(s
[i
]+s
[i
+1]+1)>>1;
}
s
+= lx2
;
d
+= lx2
;
}
}
}
else /* if (xh && yh) horizontal and vertical half-pel */
{
if (average_flag
)
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
v
= d
[i
] + ((unsigned int)(s
[i
]+s
[i
+1]+s
[i
+lx
]+s
[i
+lx
+1]+2)>>2);
d
[i
] = (v
+(v
>=0?1:0))>>1;
}
s
+= lx2
;
d
+= lx2
;
}
}
else
{
for (j
=0; j
<h
; j
++)
{
for (i
=0; i
<w
; i
++)
{
d
[i
] = (unsigned int)(s
[i
]+s
[i
+1]+s
[i
+lx
]+s
[i
+lx
+1]+2)>>2;
}
s
+= lx2
;
d
+= lx2
;
}
}
}
}