| 31 |
#include <assert.h> |
#include <assert.h> |
| 32 |
#include <stdio.h> |
#include <stdio.h> |
| 33 |
#include <stdlib.h> |
#include <stdlib.h> |
| 34 |
|
#include <string.h> // memcpy |
| 35 |
|
|
| 36 |
#include "../encoder.h" |
#include "../encoder.h" |
| 37 |
#include "../utils/mbfunctions.h" |
#include "../utils/mbfunctions.h" |
| 53 |
(*CheckCandidate)((const int)(X),(const int)(Y), (D), &iDirection, data ); } |
(*CheckCandidate)((const int)(X),(const int)(Y), (D), &iDirection, data ); } |
| 54 |
|
|
| 55 |
static __inline int |
static __inline int |
| 56 |
d_mv_bits(int x, int y, const uint32_t iFcode, const int qpel, const int rrv) |
d_mv_bits(int x, int y, const VECTOR pred, const uint32_t iFcode, const int qpel, const int rrv) |
| 57 |
{ |
{ |
| 58 |
int xb, yb; |
int xb, yb; |
| 59 |
if (qpel) { x *= 2; y *= 2;} |
if (qpel) { x *= 2; y *= 2;} |
| 60 |
else if (rrv) { x = RRV_MV_SCALEDOWN(x); y = RRV_MV_SCALEDOWN(y); } |
else if (rrv) { x = RRV_MV_SCALEDOWN(x); y = RRV_MV_SCALEDOWN(y); } |
| 61 |
|
x -= pred.x; |
| 62 |
|
y -= pred.y; |
| 63 |
|
|
| 64 |
if (x == 0) xb = 1; |
if (x) { |
|
else { |
|
| 65 |
if (x < 0) x = -x; |
if (x < 0) x = -x; |
| 66 |
x += (1 << (iFcode - 1)) - 1; |
x += (1 << (iFcode - 1)) - 1; |
| 67 |
x >>= (iFcode - 1); |
x >>= (iFcode - 1); |
| 68 |
if (x > 32) x = 32; |
if (x > 32) x = 32; |
| 69 |
xb = mvtab[x] + iFcode; |
xb = mvtab[x] + iFcode; |
| 70 |
} |
} else xb = 1; |
| 71 |
|
|
| 72 |
if (y == 0) yb = 1; |
if (y) { |
|
else { |
|
| 73 |
if (y < 0) y = -y; |
if (y < 0) y = -y; |
| 74 |
y += (1 << (iFcode - 1)) - 1; |
y += (1 << (iFcode - 1)) - 1; |
| 75 |
y >>= (iFcode - 1); |
y >>= (iFcode - 1); |
| 76 |
if (y > 32) y = 32; |
if (y > 32) y = 32; |
| 77 |
yb = mvtab[y] + iFcode; |
yb = mvtab[y] + iFcode; |
| 78 |
} |
} else yb = 1; |
| 79 |
return xb + yb; |
return xb + yb; |
| 80 |
} |
} |
| 81 |
|
|
| 83 |
ChromaSAD(int dx, int dy, const SearchData * const data) |
ChromaSAD(int dx, int dy, const SearchData * const data) |
| 84 |
{ |
{ |
| 85 |
int sad; |
int sad; |
| 86 |
dx = (dx >> 1) + roundtab_79[dx & 0x3]; |
const uint32_t stride = data->iEdgedWidth/2; |
|
dy = (dy >> 1) + roundtab_79[dy & 0x3]; |
|
| 87 |
|
|
| 88 |
if (dx == data->temp[5] && dy == data->temp[6]) return data->temp[7]; //it has been checked recently |
if (dx == data->temp[5] && dy == data->temp[6]) return data->temp[7]; //it has been checked recently |
| 89 |
|
data->temp[5] = dx; data->temp[6] = dy; // backup |
| 90 |
|
|
| 91 |
switch (((dx & 1) << 1) | (dy & 1)) { |
switch (((dx & 1) << 1) | (dy & 1)) { |
| 92 |
case 0: |
case 0: |
| 93 |
sad = sad8(data->CurU, data->RefCU + (dy/2) * (data->iEdgedWidth/2) + dx/2, data->iEdgedWidth/2); |
dx = dx / 2; dy = dy / 2; |
| 94 |
sad += sad8(data->CurV, data->RefCV + (dy/2) * (data->iEdgedWidth/2) + dx/2, data->iEdgedWidth/2); |
sad = sad8(data->CurU, data->RefCU + dy * stride + dx, stride); |
| 95 |
|
sad += sad8(data->CurV, data->RefCV + dy * stride + dx, stride); |
| 96 |
break; |
break; |
| 97 |
case 1: |
case 1: |
| 98 |
dx = dx / 2; dy = (dy - 1) / 2; |
dx = dx / 2; dy = (dy - 1) / 2; |
| 99 |
sad = sad8bi(data->CurU, data->RefCU + dy * (data->iEdgedWidth/2) + dx, data->RefCU + (dy+1) * (data->iEdgedWidth/2) + dx, data->iEdgedWidth/2); |
sad = sad8bi(data->CurU, data->RefCU + dy * stride + dx, data->RefCU + (dy+1) * stride + dx, stride); |
| 100 |
sad += sad8bi(data->CurV, data->RefCV + dy * (data->iEdgedWidth/2) + dx, data->RefCV + (dy+1) * (data->iEdgedWidth/2) + dx, data->iEdgedWidth/2); |
sad += sad8bi(data->CurV, data->RefCV + dy * stride + dx, data->RefCV + (dy+1) * stride + dx, stride); |
| 101 |
break; |
break; |
| 102 |
case 2: |
case 2: |
| 103 |
dx = (dx - 1) / 2; dy = dy / 2; |
dx = (dx - 1) / 2; dy = dy / 2; |
| 104 |
sad = sad8bi(data->CurU, data->RefCU + dy * (data->iEdgedWidth/2) + dx, data->RefCU + dy * (data->iEdgedWidth/2) + dx+1, data->iEdgedWidth/2); |
sad = sad8bi(data->CurU, data->RefCU + dy * stride + dx, data->RefCU + dy * stride + dx+1, stride); |
| 105 |
sad += sad8bi(data->CurV, data->RefCV + dy * (data->iEdgedWidth/2) + dx, data->RefCV + dy * (data->iEdgedWidth/2) + dx+1, data->iEdgedWidth/2); |
sad += sad8bi(data->CurV, data->RefCV + dy * stride + dx, data->RefCV + dy * stride + dx+1, stride); |
| 106 |
break; |
break; |
| 107 |
default: |
default: |
| 108 |
dx = (dx - 1) / 2; dy = (dy - 1) / 2; |
dx = (dx - 1) / 2; dy = (dy - 1) / 2; |
| 109 |
interpolate8x8_halfpel_hv(data->RefQ, |
interpolate8x8_halfpel_hv(data->RefQ, data->RefCU + dy * stride + dx, stride, data->rounding); |
| 110 |
data->RefCU + dy * (data->iEdgedWidth/2) + dx, data->iEdgedWidth/2, |
sad = sad8(data->CurU, data->RefQ, stride); |
| 111 |
data->rounding); |
|
| 112 |
sad = sad8(data->CurU, data->RefQ, data->iEdgedWidth/2); |
interpolate8x8_halfpel_hv(data->RefQ, data->RefCV + dy * stride + dx, stride, data->rounding); |
| 113 |
interpolate8x8_halfpel_hv(data->RefQ, |
sad += sad8(data->CurV, data->RefQ, stride); |
|
data->RefCV + dy * (data->iEdgedWidth/2) + dx, data->iEdgedWidth/2, |
|
|
data->rounding); |
|
|
sad += sad8(data->CurV, data->RefQ, data->iEdgedWidth/2); |
|
| 114 |
break; |
break; |
| 115 |
} |
} |
| 116 |
data->temp[5] = dx; data->temp[6] = dy; data->temp[7] = sad; //backup |
data->temp[7] = sad; //backup, part 2 |
| 117 |
return sad; |
return sad; |
| 118 |
} |
} |
| 119 |
|
|
| 120 |
static __inline const uint8_t * |
static __inline const uint8_t * |
| 121 |
GetReference(const int x, const int y, const int dir, const SearchData * const data) |
GetReferenceB(const int x, const int y, const int dir, const SearchData * const data) |
| 122 |
{ |
{ |
| 123 |
// dir : 0 = forward, 1 = backward |
// dir : 0 = forward, 1 = backward |
| 124 |
switch ( (dir << 2) | ((x&1)<<1) | (y&1) ) { |
switch ( (dir << 2) | ((x&1)<<1) | (y&1) ) { |
| 133 |
} |
} |
| 134 |
} |
} |
| 135 |
|
|
| 136 |
|
// this is a simpler copy of GetReferenceB, but as it's __inline anyway, we can keep the two separate |
| 137 |
|
static __inline const uint8_t * |
| 138 |
|
GetReference(const int x, const int y, const SearchData * const data) |
| 139 |
|
{ |
| 140 |
|
switch ( ((x&1)<<1) | (y&1) ) { |
| 141 |
|
case 0 : return data->Ref + x/2 + (y/2)*(data->iEdgedWidth); |
| 142 |
|
case 1 : return data->RefV + x/2 + ((y-1)/2)*(data->iEdgedWidth); |
| 143 |
|
case 2 : return data->RefH + (x-1)/2 + (y/2)*(data->iEdgedWidth); |
| 144 |
|
default : return data->RefHV + (x-1)/2 + ((y-1)/2)*(data->iEdgedWidth); |
| 145 |
|
} |
| 146 |
|
} |
| 147 |
|
|
| 148 |
static uint8_t * |
static uint8_t * |
| 149 |
Interpolate8x8qpel(const int x, const int y, const int block, const int dir, const SearchData * const data) |
Interpolate8x8qpel(const int x, const int y, const int block, const int dir, const SearchData * const data) |
| 150 |
{ |
{ |
| 156 |
const int halfpel_y = y/2; |
const int halfpel_y = y/2; |
| 157 |
const uint8_t *ref1, *ref2, *ref3, *ref4; |
const uint8_t *ref1, *ref2, *ref3, *ref4; |
| 158 |
|
|
| 159 |
ref1 = GetReference(halfpel_x, halfpel_y, dir, data); // this reference is used in all cases |
ref1 = GetReferenceB(halfpel_x, halfpel_y, dir, data); |
| 160 |
ref1 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
ref1 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
| 161 |
switch( ((x&1)<<1) + (y&1) ) { |
switch( ((x&1)<<1) + (y&1) ) { |
| 162 |
case 0: // pure halfpel position |
case 0: // pure halfpel position |
| 163 |
Reference = (uint8_t *) GetReference(halfpel_x, halfpel_y, dir, data); |
return (uint8_t *) ref1; |
|
Reference += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
|
| 164 |
break; |
break; |
| 165 |
|
|
| 166 |
case 1: // x halfpel, y qpel - top or bottom during qpel refinement |
case 1: // x halfpel, y qpel - top or bottom during qpel refinement |
| 167 |
ref2 = GetReference(halfpel_x, y - halfpel_y, dir, data); |
ref2 = GetReferenceB(halfpel_x, y - halfpel_y, dir, data); |
| 168 |
ref2 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
ref2 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
| 169 |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
| 170 |
break; |
break; |
| 171 |
|
|
| 172 |
case 2: // x qpel, y halfpel - left or right during qpel refinement |
case 2: // x qpel, y halfpel - left or right during qpel refinement |
| 173 |
ref2 = GetReference(x - halfpel_x, halfpel_y, dir, data); |
ref2 = GetReferenceB(x - halfpel_x, halfpel_y, dir, data); |
| 174 |
ref2 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
ref2 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
| 175 |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
| 176 |
break; |
break; |
| 177 |
|
|
| 178 |
default: // x and y in qpel resolution - the "corners" (top left/right and |
default: // x and y in qpel resolution - the "corners" (top left/right and |
| 179 |
// bottom left/right) during qpel refinement |
// bottom left/right) during qpel refinement |
| 180 |
ref2 = GetReference(halfpel_x, y - halfpel_y, dir, data); |
ref2 = GetReferenceB(halfpel_x, y - halfpel_y, dir, data); |
| 181 |
ref3 = GetReference(x - halfpel_x, halfpel_y, dir, data); |
ref3 = GetReferenceB(x - halfpel_x, halfpel_y, dir, data); |
| 182 |
ref4 = GetReference(x - halfpel_x, y - halfpel_y, dir, data); |
ref4 = GetReferenceB(x - halfpel_x, y - halfpel_y, dir, data); |
| 183 |
ref2 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
ref2 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
| 184 |
ref3 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
ref3 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
| 185 |
ref4 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
ref4 += 8 * (block&1) + 8 * (block>>1) * iEdgedWidth; |
| 200 |
const int halfpel_y = y/2; |
const int halfpel_y = y/2; |
| 201 |
const uint8_t *ref1, *ref2, *ref3, *ref4; |
const uint8_t *ref1, *ref2, *ref3, *ref4; |
| 202 |
|
|
| 203 |
ref1 = GetReference(halfpel_x, halfpel_y, dir, data); // this reference is used in all cases |
ref1 = GetReferenceB(halfpel_x, halfpel_y, dir, data); |
| 204 |
switch( ((x&1)<<1) + (y&1) ) { |
switch( ((x&1)<<1) + (y&1) ) { |
| 205 |
case 0: // pure halfpel position |
case 0: // pure halfpel position |
| 206 |
return (uint8_t *) GetReference(halfpel_x, halfpel_y, dir, data); |
return (uint8_t *) ref1; |
| 207 |
case 1: // x halfpel, y qpel - top or bottom during qpel refinement |
case 1: // x halfpel, y qpel - top or bottom during qpel refinement |
| 208 |
ref2 = GetReference(halfpel_x, y - halfpel_y, dir, data); |
ref2 = GetReferenceB(halfpel_x, y - halfpel_y, dir, data); |
| 209 |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
| 210 |
interpolate8x8_avg2(Reference+8, ref1+8, ref2+8, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference+8, ref1+8, ref2+8, iEdgedWidth, rounding, 8); |
| 211 |
interpolate8x8_avg2(Reference+8*iEdgedWidth, ref1+8*iEdgedWidth, ref2+8*iEdgedWidth, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference+8*iEdgedWidth, ref1+8*iEdgedWidth, ref2+8*iEdgedWidth, iEdgedWidth, rounding, 8); |
| 213 |
break; |
break; |
| 214 |
|
|
| 215 |
case 2: // x qpel, y halfpel - left or right during qpel refinement |
case 2: // x qpel, y halfpel - left or right during qpel refinement |
| 216 |
ref2 = GetReference(x - halfpel_x, halfpel_y, dir, data); |
ref2 = GetReferenceB(x - halfpel_x, halfpel_y, dir, data); |
| 217 |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference, ref1, ref2, iEdgedWidth, rounding, 8); |
| 218 |
interpolate8x8_avg2(Reference+8, ref1+8, ref2+8, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference+8, ref1+8, ref2+8, iEdgedWidth, rounding, 8); |
| 219 |
interpolate8x8_avg2(Reference+8*iEdgedWidth, ref1+8*iEdgedWidth, ref2+8*iEdgedWidth, iEdgedWidth, rounding, 8); |
interpolate8x8_avg2(Reference+8*iEdgedWidth, ref1+8*iEdgedWidth, ref2+8*iEdgedWidth, iEdgedWidth, rounding, 8); |
| 222 |
|
|
| 223 |
default: // x and y in qpel resolution - the "corners" (top left/right and |
default: // x and y in qpel resolution - the "corners" (top left/right and |
| 224 |
// bottom left/right) during qpel refinement |
// bottom left/right) during qpel refinement |
| 225 |
ref2 = GetReference(halfpel_x, y - halfpel_y, dir, data); |
ref2 = GetReferenceB(halfpel_x, y - halfpel_y, dir, data); |
| 226 |
ref3 = GetReference(x - halfpel_x, halfpel_y, dir, data); |
ref3 = GetReferenceB(x - halfpel_x, halfpel_y, dir, data); |
| 227 |
ref4 = GetReference(x - halfpel_x, y - halfpel_y, dir, data); |
ref4 = GetReferenceB(x - halfpel_x, y - halfpel_y, dir, data); |
| 228 |
interpolate8x8_avg4(Reference, ref1, ref2, ref3, ref4, iEdgedWidth, rounding); |
interpolate8x8_avg4(Reference, ref1, ref2, ref3, ref4, iEdgedWidth, rounding); |
| 229 |
interpolate8x8_avg4(Reference+8, ref1+8, ref2+8, ref3+8, ref4+8, iEdgedWidth, rounding); |
interpolate8x8_avg4(Reference+8, ref1+8, ref2+8, ref3+8, ref4+8, iEdgedWidth, rounding); |
| 230 |
interpolate8x8_avg4(Reference+8*iEdgedWidth, ref1+8*iEdgedWidth, ref2+8*iEdgedWidth, ref3+8*iEdgedWidth, ref4+8*iEdgedWidth, iEdgedWidth, rounding); |
interpolate8x8_avg4(Reference+8*iEdgedWidth, ref1+8*iEdgedWidth, ref2+8*iEdgedWidth, ref3+8*iEdgedWidth, ref4+8*iEdgedWidth, iEdgedWidth, rounding); |
| 251 |
xc = x/2; yc = y/2; //for chroma sad |
xc = x/2; yc = y/2; //for chroma sad |
| 252 |
current = data->currentQMV; |
current = data->currentQMV; |
| 253 |
} else { |
} else { |
| 254 |
Reference = GetReference(x, y, 0, data); |
Reference = GetReference(x, y, data); |
| 255 |
current = data->currentMV; |
current = data->currentMV; |
| 256 |
xc = x; yc = y; |
xc = x; yc = y; |
| 257 |
} |
} |
| 258 |
t = d_mv_bits(x - data->predMV.x, y - data->predMV.y, data->iFcode, data->qpel && !data->qpel_precision, 0); |
t = d_mv_bits(x, y, data->predMV, data->iFcode, data->qpel && !data->qpel_precision, 0); |
| 259 |
|
|
| 260 |
data->temp[0] = sad16v(data->Cur, Reference, data->iEdgedWidth, data->temp + 1); |
data->temp[0] = sad16v(data->Cur, Reference, data->iEdgedWidth, data->temp + 1); |
| 261 |
|
|
| 262 |
data->temp[0] += (data->lambda16 * t * data->temp[0])/1000; |
data->temp[0] += (data->lambda16 * t * data->temp[0])/1000; |
| 263 |
data->temp[1] += (data->lambda8 * t * (data->temp[1] + NEIGH_8X8_BIAS))/100; |
data->temp[1] += (data->lambda8 * t * (data->temp[1] + NEIGH_8X8_BIAS))/100; |
| 264 |
|
|
| 265 |
if (data->chroma) data->temp[0] += ChromaSAD(xc, yc, data); |
if (data->chroma) data->temp[0] += ChromaSAD((xc >> 1) + roundtab_79[xc & 0x3], |
| 266 |
|
(yc >> 1) + roundtab_79[yc & 0x3], data); |
| 267 |
|
|
| 268 |
if (data->temp[0] < data->iMinSAD[0]) { |
if (data->temp[0] < data->iMinSAD[0]) { |
| 269 |
data->iMinSAD[0] = data->temp[0]; |
data->iMinSAD[0] = data->temp[0]; |
| 291 |
( x > data->max_dx) || ( x < data->min_dx) |
( x > data->max_dx) || ( x < data->min_dx) |
| 292 |
|| ( y > data->max_dy) || (y < data->min_dy)) return; |
|| ( y > data->max_dy) || (y < data->min_dy)) return; |
| 293 |
|
|
| 294 |
Reference = GetReference(x, y, 0, data); |
Reference = GetReference(x, y, data); |
| 295 |
t = d_mv_bits(x - data->predMV.x, y - data->predMV.y, data->iFcode, 0, 1); |
t = d_mv_bits(x, y, data->predMV, data->iFcode, 0, 1); |
| 296 |
|
|
| 297 |
data->temp[0] = sad32v_c(data->Cur, Reference, data->iEdgedWidth, data->temp + 1); |
data->temp[0] = sad32v_c(data->Cur, Reference, data->iEdgedWidth, data->temp + 1); |
| 298 |
|
|
| 332 |
Reference = Interpolate16x16qpel(x, y, 0, data); |
Reference = Interpolate16x16qpel(x, y, 0, data); |
| 333 |
current = data->currentQMV; |
current = data->currentQMV; |
| 334 |
} else { |
} else { |
| 335 |
Reference = GetReference(x, y, 0, data); |
Reference = GetReference(x, y, data); |
| 336 |
current = data->currentMV; |
current = data->currentMV; |
| 337 |
} |
} |
| 338 |
t = d_mv_bits(x - data->predMV.x, y - data->predMV.y, data->iFcode, |
t = d_mv_bits(x, y, data->predMV, data->iFcode, |
| 339 |
data->qpel && !data->qpel_precision && !data->rrv, data->rrv); |
data->qpel && !data->qpel_precision, data->rrv); |
| 340 |
|
|
| 341 |
sad = sad16(data->Cur, Reference, data->iEdgedWidth, 256*4096); |
sad = sad16(data->Cur, Reference, data->iEdgedWidth, 256*4096); |
| 342 |
sad += (data->lambda16 * t * sad)/1000; |
sad += (data->lambda16 * t * sad)/1000; |
| 348 |
} |
} |
| 349 |
|
|
| 350 |
static void |
static void |
| 351 |
CheckCandidate16no4vI(const int x, const int y, const int Direction, int * const dir, const SearchData * const data) |
CheckCandidate32I(const int x, const int y, const int Direction, int * const dir, const SearchData * const data) |
| 352 |
{ |
{ |
| 353 |
// maximum speed - for P/B/I decision |
// maximum speed - for P/B/I decision |
|
int32_t sad; |
|
| 354 |
|
|
| 355 |
if (( x > data->max_dx) || ( x < data->min_dx) |
if (( x > data->max_dx) || ( x < data->min_dx) |
| 356 |
|| ( y > data->max_dy) || (y < data->min_dy)) return; |
|| ( y > data->max_dy) || (y < data->min_dy)) return; |
| 357 |
|
|
| 358 |
sad = sad16(data->Cur, data->Ref + x/2 + (y/2)*(data->iEdgedWidth), |
data->temp[0] = sad32v_c(data->Cur, data->Ref + x/2 + (y/2)*(data->iEdgedWidth), |
| 359 |
data->iEdgedWidth, 256*4096); |
data->iEdgedWidth, data->temp+1); |
| 360 |
|
if (data->temp[0] < *(data->iMinSAD)) { |
| 361 |
if (sad < *(data->iMinSAD)) { |
*(data->iMinSAD) = data->temp[0]; |
|
*(data->iMinSAD) = sad; |
|
| 362 |
data->currentMV[0].x = x; data->currentMV[0].y = y; |
data->currentMV[0].x = x; data->currentMV[0].y = y; |
| 363 |
*dir = Direction; } |
*dir = Direction; } |
| 364 |
} |
if (data->temp[1] < data->iMinSAD[1]) { |
| 365 |
|
data->iMinSAD[1] = data->temp[1]; data->currentMV[1].x = x; data->currentMV[1].y = y; } |
| 366 |
|
if (data->temp[2] < data->iMinSAD[2]) { |
| 367 |
|
data->iMinSAD[2] = data->temp[2]; data->currentMV[2].x = x; data->currentMV[2].y = y; } |
| 368 |
|
if (data->temp[3] < data->iMinSAD[3]) { |
| 369 |
|
data->iMinSAD[3] = data->temp[3]; data->currentMV[3].x = x; data->currentMV[3].y = y; } |
| 370 |
|
if (data->temp[4] < data->iMinSAD[4]) { |
| 371 |
|
data->iMinSAD[4] = data->temp[4]; data->currentMV[4].x = x; data->currentMV[4].y = y; } |
| 372 |
|
|
| 373 |
|
} |
| 374 |
|
|
| 375 |
static void |
static void |
| 376 |
CheckCandidateInt(const int xf, const int yf, const int Direction, int * const dir, const SearchData * const data) |
CheckCandidateInt(const int xf, const int yf, const int Direction, int * const dir, const SearchData * const data) |
| 389 |
current = data->currentQMV; |
current = data->currentQMV; |
| 390 |
ReferenceB = Interpolate16x16qpel(xb, yb, 1, data); |
ReferenceB = Interpolate16x16qpel(xb, yb, 1, data); |
| 391 |
} else { |
} else { |
| 392 |
ReferenceF = GetReference(xf, yf, 0, data); |
ReferenceF = GetReference(xf, yf, data); |
| 393 |
xb = data->currentMV[1].x; yb = data->currentMV[1].y; |
xb = data->currentMV[1].x; yb = data->currentMV[1].y; |
| 394 |
ReferenceB = GetReference(xb, yb, 1, data); |
ReferenceB = GetReferenceB(xb, yb, 1, data); |
| 395 |
current = data->currentMV; |
current = data->currentMV; |
| 396 |
} |
} |
| 397 |
|
|
| 398 |
t = d_mv_bits(xf - data->predMV.x, yf - data->predMV.y, data->iFcode, data->qpel && !data->qpel_precision, 0) |
t = d_mv_bits(xf, yf, data->predMV, data->iFcode, data->qpel && !data->qpel_precision, 0) |
| 399 |
+ d_mv_bits(xb - data->bpredMV.x, yb - data->bpredMV.y, data->iFcode, data->qpel && !data->qpel_precision, 0); |
+ d_mv_bits(xb, yb, data->bpredMV, data->iFcode, data->qpel && !data->qpel_precision, 0); |
| 400 |
|
|
| 401 |
sad = sad16bi(data->Cur, ReferenceF, ReferenceB, data->iEdgedWidth); |
sad = sad16bi(data->Cur, ReferenceF, ReferenceB, data->iEdgedWidth); |
| 402 |
sad += (data->lambda16 * t * sad)/1000; |
sad += (data->lambda16 * t * sad)/1000; |
| 415 |
const uint8_t *ReferenceF; |
const uint8_t *ReferenceF; |
| 416 |
const uint8_t *ReferenceB; |
const uint8_t *ReferenceB; |
| 417 |
VECTOR mvs, b_mvs; |
VECTOR mvs, b_mvs; |
| 418 |
|
const VECTOR zeroMV={0,0}; |
| 419 |
|
|
| 420 |
if (( x > 31) || ( x < -32) || ( y > 31) || (y < -32)) return; |
if (( x > 31) || ( x < -32) || ( y > 31) || (y < -32)) return; |
| 421 |
|
|
| 448 |
if (sad > *(data->iMinSAD)) return; |
if (sad > *(data->iMinSAD)) return; |
| 449 |
} |
} |
| 450 |
|
|
| 451 |
sad += (data->lambda16 * d_mv_bits(x, y, 1, 0, 0) * sad)/1000; |
sad += (data->lambda16 * d_mv_bits(x, y, zeroMV, 1, 0, 0) * sad)/1000; |
| 452 |
|
|
| 453 |
if (sad < *(data->iMinSAD)) { |
if (sad < *(data->iMinSAD)) { |
| 454 |
*(data->iMinSAD) = sad; |
*(data->iMinSAD) = sad; |
| 463 |
const uint8_t *ReferenceF; |
const uint8_t *ReferenceF; |
| 464 |
const uint8_t *ReferenceB; |
const uint8_t *ReferenceB; |
| 465 |
VECTOR mvs, b_mvs; |
VECTOR mvs, b_mvs; |
| 466 |
|
const VECTOR zeroMV = {0,0}; |
| 467 |
|
|
| 468 |
if (( x > 31) || ( x < -32) || ( y > 31) || (y < -32)) return; |
if (( x > 31) || ( x < -32) || ( y > 31) || (y < -32)) return; |
| 469 |
|
|
| 490 |
ReferenceB = Interpolate16x16qpel(b_mvs.x, b_mvs.y, 1, data); |
ReferenceB = Interpolate16x16qpel(b_mvs.x, b_mvs.y, 1, data); |
| 491 |
|
|
| 492 |
sad = sad16bi(data->Cur, ReferenceF, ReferenceB, data->iEdgedWidth); |
sad = sad16bi(data->Cur, ReferenceF, ReferenceB, data->iEdgedWidth); |
| 493 |
sad += (data->lambda16 * d_mv_bits(x, y, 1, 0, 0) * sad)/1000; |
sad += (data->lambda16 * d_mv_bits(x, y, zeroMV, 1, 0, 0) * sad)/1000; |
| 494 |
|
|
| 495 |
if (sad < *(data->iMinSAD)) { |
if (sad < *(data->iMinSAD)) { |
| 496 |
*(data->iMinSAD) = sad; |
*(data->iMinSAD) = sad; |
| 508 |
|| ( y > data->max_dy) || (y < data->min_dy)) return; |
|| ( y > data->max_dy) || (y < data->min_dy)) return; |
| 509 |
|
|
| 510 |
if (data->qpel) Reference = Interpolate16x16qpel(x, y, 0, data); |
if (data->qpel) Reference = Interpolate16x16qpel(x, y, 0, data); |
| 511 |
else Reference = GetReference(x, y, 0, data); |
else Reference = GetReference(x, y, data); |
| 512 |
|
|
| 513 |
sad = sad8(data->Cur, Reference, data->iEdgedWidth); |
sad = sad8(data->Cur, Reference, data->iEdgedWidth); |
| 514 |
t = d_mv_bits(x - data->predMV.x, y - data->predMV.y, data->iFcode, data->qpel && !data->qpel_precision, 0); |
t = d_mv_bits(x, y, data->predMV, data->iFcode, data->qpel && !data->qpel_precision, 0); |
| 515 |
|
|
| 516 |
sad += (data->lambda8 * t * (sad+NEIGH_8X8_BIAS))/100; |
sad += (data->lambda8 * t * (sad+NEIGH_8X8_BIAS))/100; |
| 517 |
|
|
| 681 |
backupMV = *(data->currentQMV); |
backupMV = *(data->currentQMV); |
| 682 |
else backupMV = *(data->currentMV); |
else backupMV = *(data->currentMV); |
| 683 |
|
|
| 684 |
CHECK_CANDIDATE(backupMV.x - 1, backupMV.y - 1, 0); |
CHECK_CANDIDATE(backupMV.x, backupMV.y - 1, 0); |
| 685 |
CHECK_CANDIDATE(backupMV.x + 1, backupMV.y - 1, 0); |
CHECK_CANDIDATE(backupMV.x + 1, backupMV.y - 1, 0); |
|
CHECK_CANDIDATE(backupMV.x - 1, backupMV.y + 1, 0); |
|
|
CHECK_CANDIDATE(backupMV.x + 1, backupMV.y + 1, 0); |
|
|
|
|
|
CHECK_CANDIDATE(backupMV.x - 1, backupMV.y, 0); |
|
| 686 |
CHECK_CANDIDATE(backupMV.x + 1, backupMV.y, 0); |
CHECK_CANDIDATE(backupMV.x + 1, backupMV.y, 0); |
| 687 |
|
CHECK_CANDIDATE(backupMV.x + 1, backupMV.y + 1, 0); |
| 688 |
CHECK_CANDIDATE(backupMV.x, backupMV.y + 1, 0); |
CHECK_CANDIDATE(backupMV.x, backupMV.y + 1, 0); |
| 689 |
CHECK_CANDIDATE(backupMV.x, backupMV.y - 1, 0); |
CHECK_CANDIDATE(backupMV.x - 1, backupMV.y + 1, 0); |
| 690 |
|
CHECK_CANDIDATE(backupMV.x - 1, backupMV.y, 0); |
| 691 |
|
CHECK_CANDIDATE(backupMV.x - 1, backupMV.y - 1, 0); |
| 692 |
} |
} |
| 693 |
|
|
| 694 |
static __inline int |
static __inline int |
| 753 |
uint32_t x, y; |
uint32_t x, y; |
| 754 |
uint32_t iIntra = 0; |
uint32_t iIntra = 0; |
| 755 |
int32_t InterBias, quant = current->quant, sad00; |
int32_t InterBias, quant = current->quant, sad00; |
|
uint8_t *qimage; |
|
| 756 |
|
|
| 757 |
// some pre-initialized thingies for SearchP |
// some pre-initialized thingies for SearchP |
| 758 |
int32_t temp[8]; |
int32_t temp[8]; |
| 778 |
Data.qpel = Data.chroma = 0; |
Data.qpel = Data.chroma = 0; |
| 779 |
} |
} |
| 780 |
|
|
| 781 |
if((qimage = (uint8_t *) malloc(32 * pParam->edged_width)) == NULL) |
Data.RefQ = pRefV->u; // a good place, also used in MC (for similar purpose) |
|
return 1; // allocate some mem for qpel interpolated blocks |
|
|
// somehow this is dirty since I think we shouldn't use malloc outside |
|
|
// encoder_create() - so please fix me! |
|
|
Data.RefQ = qimage; |
|
| 782 |
if (sadInit) (*sadInit) (); |
if (sadInit) (*sadInit) (); |
| 783 |
|
|
| 784 |
for (y = 0; y < mb_height; y++) { |
for (y = 0; y < mb_height; y++) { |
| 870 |
pParam->edged_width); |
pParam->edged_width); |
| 871 |
|
|
| 872 |
if (deviation < (pMB->sad16 - InterBias)) { |
if (deviation < (pMB->sad16 - InterBias)) { |
| 873 |
if (++iIntra >= iLimit) { free(qimage); return 1; } |
if (++iIntra >= iLimit) return 1; |
| 874 |
pMB->mode = MODE_INTRA; |
pMB->mode = MODE_INTRA; |
| 875 |
pMB->mvs[0] = pMB->mvs[1] = pMB->mvs[2] = |
pMB->mvs[0] = pMB->mvs[1] = pMB->mvs[2] = |
| 876 |
pMB->mvs[3] = zeroMV; |
pMB->mvs[3] = zeroMV; |
| 882 |
} |
} |
| 883 |
} |
} |
| 884 |
} |
} |
|
free(qimage); |
|
| 885 |
|
|
| 886 |
if (current->coding_type == S_VOP) /* first GMC step only for S(GMC)-VOPs */ |
if (current->coding_type == S_VOP) /* first GMC step only for S(GMC)-VOPs */ |
| 887 |
current->GMC_MV = GlobalMotionEst( pMBs, pParam, current->fcode ); |
current->GMC_MV = GlobalMotionEst( pMBs, pParam, current->fcode ); |
| 932 |
else pmv[4].x = pmv[4].y = 0; |
else pmv[4].x = pmv[4].y = 0; |
| 933 |
|
|
| 934 |
// [1] median prediction |
// [1] median prediction |
| 935 |
if (rrv) { //median is in halfzero-precision |
pmv[1].x = EVEN(pmv[0].x); pmv[1].y = EVEN(pmv[0].y); |
|
pmv[1].x = RRV_MV_SCALEUP(pmv[0].x); |
|
|
pmv[1].y = RRV_MV_SCALEUP(pmv[0].y); |
|
|
} else { pmv[1].x = EVEN(pmv[0].x); pmv[1].y = EVEN(pmv[0].y); } |
|
| 936 |
|
|
| 937 |
pmv[0].x = pmv[0].y = 0; // [0] is zero; not used in the loop (checked before) but needed here for make_mask |
pmv[0].x = pmv[0].y = 0; // [0] is zero; not used in the loop (checked before) but needed here for make_mask |
| 938 |
|
|
| 947 |
if (rrv) { |
if (rrv) { |
| 948 |
int i; |
int i; |
| 949 |
for (i = 0; i < 7; i++) { |
for (i = 0; i < 7; i++) { |
| 950 |
pmv[i].x = RRV_MV_SCALEDOWN(pmv[i].x); |
pmv[i].x = RRV_MV_SCALEUP(pmv[i].x); // halfzero->halfpel |
| 951 |
pmv[i].x = RRV_MV_SCALEUP(pmv[i].x); // a trick |
pmv[i].y = RRV_MV_SCALEUP(pmv[i].y); |
| 952 |
} |
} |
| 953 |
} |
} |
| 954 |
} |
} |
| 1004 |
if (pParam->m_quarterpel) Data->predMV = get_qpmv2(pMBs, pParam->mb_width, 0, x, y, 0); |
if (pParam->m_quarterpel) Data->predMV = get_qpmv2(pMBs, pParam->mb_width, 0, x, y, 0); |
| 1005 |
else Data->predMV = pmv[0]; |
else Data->predMV = pmv[0]; |
| 1006 |
|
|
| 1007 |
i = d_mv_bits(Data->predMV.x, Data->predMV.y, Data->iFcode, 0, 0); |
i = d_mv_bits(0, 0, Data->predMV, Data->iFcode, 0, 0); |
| 1008 |
Data->iMinSAD[0] = pMB->sad16 + (Data->lambda16 * i * pMB->sad16)/1000; |
Data->iMinSAD[0] = pMB->sad16 + (Data->lambda16 * i * pMB->sad16)/1000; |
| 1009 |
Data->iMinSAD[1] = pMB->sad8[0] + (Data->lambda8 * i * (pMB->sad8[0]+NEIGH_8X8_BIAS))/100; |
Data->iMinSAD[1] = pMB->sad8[0] + (Data->lambda8 * i * (pMB->sad8[0]+NEIGH_8X8_BIAS))/100; |
| 1010 |
Data->iMinSAD[2] = pMB->sad8[1]; |
Data->iMinSAD[2] = pMB->sad8[1]; |
| 1090 |
Data->currentQMV[i].y = 2 * Data->currentMV[i].y; |
Data->currentQMV[i].y = 2 * Data->currentMV[i].y; |
| 1091 |
} |
} |
| 1092 |
|
|
| 1093 |
if((!Data->rrv) && (pParam->m_quarterpel) && (MotionFlags & PMV_QUARTERPELREFINE16)) { |
if((Data->qpel) && (MotionFlags & PMV_QUARTERPELREFINE16)) { |
| 1094 |
|
|
| 1095 |
Data->qpel_precision = 1; |
Data->qpel_precision = 1; |
| 1096 |
get_range(&Data->min_dx, &Data->max_dx, &Data->min_dy, &Data->max_dy, x, y, 16, |
get_range(&Data->min_dx, &Data->max_dx, &Data->min_dy, &Data->max_dy, x, y, 16, |
| 1114 |
Search8(Data, 2*x + 1, 2*y + 1, MotionFlags, pParam, pMB, pMBs, 3, &Data8); |
Search8(Data, 2*x + 1, 2*y + 1, MotionFlags, pParam, pMB, pMBs, 3, &Data8); |
| 1115 |
|
|
| 1116 |
if (Data->chroma) { |
if (Data->chroma) { |
| 1117 |
int sumx, sumy, dx, dy; |
int sumx, sumy; |
| 1118 |
|
|
| 1119 |
if(pParam->m_quarterpel) { |
if(pParam->m_quarterpel) { |
| 1120 |
sumx= pMB->qmvs[0].x/2 + pMB->qmvs[1].x/2 + pMB->qmvs[2].x/2 + pMB->qmvs[3].x/2; |
sumx= pMB->qmvs[0].x/2 + pMB->qmvs[1].x/2 + pMB->qmvs[2].x/2 + pMB->qmvs[3].x/2; |
| 1123 |
sumx = pMB->mvs[0].x + pMB->mvs[1].x + pMB->mvs[2].x + pMB->mvs[3].x; |
sumx = pMB->mvs[0].x + pMB->mvs[1].x + pMB->mvs[2].x + pMB->mvs[3].x; |
| 1124 |
sumy = pMB->mvs[0].y + pMB->mvs[1].y + pMB->mvs[2].y + pMB->mvs[3].y; |
sumy = pMB->mvs[0].y + pMB->mvs[1].y + pMB->mvs[2].y + pMB->mvs[3].y; |
| 1125 |
} |
} |
|
dx = (sumx >> 3) + roundtab_76[sumx & 0xf]; |
|
|
dy = (sumy >> 3) + roundtab_76[sumy & 0xf]; |
|
| 1126 |
|
|
| 1127 |
Data->iMinSAD[1] += ChromaSAD(dx, dy, Data); |
Data->iMinSAD[1] += ChromaSAD( (sumx >> 3) + roundtab_76[sumx & 0xf], |
| 1128 |
|
(sumy >> 3) + roundtab_76[sumy & 0xf], Data); |
| 1129 |
} |
} |
| 1130 |
} |
} |
| 1131 |
|
|
| 1133 |
Data->currentMV[0].x = RRV_MV_SCALEDOWN(Data->currentMV[0].x); |
Data->currentMV[0].x = RRV_MV_SCALEDOWN(Data->currentMV[0].x); |
| 1134 |
Data->currentMV[0].y = RRV_MV_SCALEDOWN(Data->currentMV[0].y); |
Data->currentMV[0].y = RRV_MV_SCALEDOWN(Data->currentMV[0].y); |
| 1135 |
} |
} |
| 1136 |
|
|
| 1137 |
if (!(inter4v) || |
if (!(inter4v) || |
| 1138 |
(Data->iMinSAD[0] < Data->iMinSAD[1] + Data->iMinSAD[2] + |
(Data->iMinSAD[0] < Data->iMinSAD[1] + Data->iMinSAD[2] + |
| 1139 |
Data->iMinSAD[3] + Data->iMinSAD[4] + IMV16X16 * (int32_t)iQuant )) { |
Data->iMinSAD[3] + Data->iMinSAD[4] + IMV16X16 * (int32_t)iQuant )) { |
| 1179 |
|
|
| 1180 |
if(pParam->m_quarterpel) { |
if(pParam->m_quarterpel) { |
| 1181 |
Data->predMV = get_qpmv2(pMBs, pParam->mb_width, 0, x/2, y/2, block); |
Data->predMV = get_qpmv2(pMBs, pParam->mb_width, 0, x/2, y/2, block); |
| 1182 |
if (block != 0) i = d_mv_bits( Data->currentQMV->x - Data->predMV.x, |
if (block != 0) i = d_mv_bits( Data->currentQMV->x, Data->currentQMV->y, |
| 1183 |
Data->currentQMV->y - Data->predMV.y, Data->iFcode, 0, 0); |
Data->predMV, Data->iFcode, 0, 0); |
| 1184 |
|
|
| 1185 |
} else { |
} else { |
| 1186 |
Data->predMV = get_pmv2(pMBs, pParam->mb_width, 0, x/2, y/2, block); |
Data->predMV = get_pmv2(pMBs, pParam->mb_width, 0, x/2, y/2, block); |
| 1187 |
if (block != 0) { |
if (block != 0) { |
| 1188 |
if (block != 0) i = d_mv_bits( Data->currentMV->x - Data->predMV.x, |
if (block != 0) i = d_mv_bits( Data->currentMV->x, Data->currentMV->y, |
| 1189 |
Data->currentMV->y - Data->predMV.y, Data->iFcode, 0, Data->rrv); |
Data->predMV, Data->iFcode, 0, Data->rrv); |
| 1190 |
} |
} |
| 1191 |
} |
} |
| 1192 |
|
|
| 1236 |
} |
} |
| 1237 |
} |
} |
| 1238 |
|
|
| 1239 |
if(!Data->rrv && Data->qpel) { |
if(Data->qpel) { |
| 1240 |
if((!(Data->currentQMV->x & 1)) && (!(Data->currentQMV->y & 1)) && |
if((!(Data->currentQMV->x & 1)) && (!(Data->currentQMV->y & 1)) && |
| 1241 |
(MotionFlags & PMV_QUARTERPELREFINE8)) { |
(MotionFlags & PMV_QUARTERPELREFINE8)) { |
| 1242 |
Data->qpel_precision = 1; |
Data->qpel_precision = 1; |
| 1307 |
|
|
| 1308 |
if ((x != 0)&&(y != 0)) { |
if ((x != 0)&&(y != 0)) { |
| 1309 |
pmv[6] = ChoosePred(pMB-1-iWcount, mode_curr); |
pmv[6] = ChoosePred(pMB-1-iWcount, mode_curr); |
| 1310 |
pmv[6].x = EVEN(pmv[5].x); pmv[5].y = EVEN(pmv[5].y); |
pmv[6].x = EVEN(pmv[6].x); pmv[6].y = EVEN(pmv[6].y); |
| 1311 |
} else pmv[6].x = pmv[6].y = 0; |
} else pmv[6].x = pmv[6].y = 0; |
| 1312 |
|
|
| 1313 |
// more? |
// more? |
| 1334 |
|
|
| 1335 |
const int32_t iEdgedWidth = pParam->edged_width; |
const int32_t iEdgedWidth = pParam->edged_width; |
| 1336 |
|
|
| 1337 |
int i, iDirection, mask; |
int i, iDirection = 255, mask; |
| 1338 |
VECTOR pmv[7]; |
VECTOR pmv[7]; |
| 1339 |
MainSearchFunc *MainSearchPtr; |
MainSearchFunc *MainSearchPtr; |
| 1340 |
*Data->iMinSAD = MV_MAX_ERROR; |
*Data->iMinSAD = MV_MAX_ERROR; |
| 1359 |
CheckCandidate = CheckCandidate16no4v; |
CheckCandidate = CheckCandidate16no4v; |
| 1360 |
|
|
| 1361 |
// main loop. checking all predictions |
// main loop. checking all predictions |
| 1362 |
for (i = 0; i < 8; i++) { |
for (i = 0; i < 7; i++) { |
| 1363 |
if (!(mask = make_mask(pmv, i)) ) continue; |
if (!(mask = make_mask(pmv, i)) ) continue; |
| 1364 |
CheckCandidate16no4v(pmv[i].x, pmv[i].y, mask, &iDirection, Data); |
CheckCandidate16no4v(pmv[i].x, pmv[i].y, mask, &iDirection, Data); |
| 1365 |
} |
} |
| 1370 |
MainSearchPtr = AdvDiamondSearch; |
MainSearchPtr = AdvDiamondSearch; |
| 1371 |
else MainSearchPtr = DiamondSearch; |
else MainSearchPtr = DiamondSearch; |
| 1372 |
|
|
| 1373 |
(*MainSearchPtr)(Data->currentMV->x, Data->currentMV->y, Data, 255); |
(*MainSearchPtr)(Data->currentMV->x, Data->currentMV->y, Data, iDirection); |
| 1374 |
|
|
| 1375 |
SubpelRefine(Data); |
SubpelRefine(Data); |
| 1376 |
|
|
| 1377 |
if (Data->qpel) { |
if (Data->qpel && *Data->iMinSAD < *best_sad + 300) { |
| 1378 |
Data->currentQMV->x = 2*Data->currentMV->x; |
Data->currentQMV->x = 2*Data->currentMV->x; |
| 1379 |
Data->currentQMV->y = 2*Data->currentMV->y; |
Data->currentQMV->y = 2*Data->currentMV->y; |
| 1380 |
Data->qpel_precision = 1; |
Data->qpel_precision = 1; |
| 1384 |
} |
} |
| 1385 |
|
|
| 1386 |
// three bits are needed to code backward mode. four for forward |
// three bits are needed to code backward mode. four for forward |
| 1387 |
// we treat the bits just like they were vector's |
|
| 1388 |
if (mode_current == MODE_FORWARD) *Data->iMinSAD += 4 * Data->lambda16; |
if (mode_current == MODE_FORWARD) *Data->iMinSAD += 4 * Data->lambda16; |
| 1389 |
else *Data->iMinSAD += 3 * Data->lambda16; |
else *Data->iMinSAD += 3 * Data->lambda16; |
| 1390 |
|
|
| 1402 |
pMB->pmvs[0].x = Data->currentMV->x - predMV->x; |
pMB->pmvs[0].x = Data->currentMV->x - predMV->x; |
| 1403 |
pMB->pmvs[0].y = Data->currentMV->y - predMV->y; |
pMB->pmvs[0].y = Data->currentMV->y - predMV->y; |
| 1404 |
} |
} |
| 1405 |
if (mode_current == MODE_FORWARD) |
if (mode_current == MODE_FORWARD) pMB->mvs[0] = *Data->currentMV; |
| 1406 |
pMB->mvs[0] = *(Data->currentMV+2) = *Data->currentMV; |
else pMB->b_mvs[0] = *Data->currentMV; |
|
else |
|
|
pMB->b_mvs[0] = *(Data->currentMV+1) = *Data->currentMV; //we store currmv for interpolate search |
|
|
|
|
| 1407 |
} |
} |
| 1408 |
|
if (mode_current == MODE_FORWARD) *(Data->currentMV+2) = *Data->currentMV; |
| 1409 |
|
else *(Data->currentMV+1) = *Data->currentMV; //we store currmv for interpolate search |
| 1410 |
|
|
| 1411 |
} |
} |
| 1412 |
|
|
| 1415 |
const IMAGE * const f_Ref, |
const IMAGE * const f_Ref, |
| 1416 |
const IMAGE * const b_Ref, |
const IMAGE * const b_Ref, |
| 1417 |
MACROBLOCK * const pMB, |
MACROBLOCK * const pMB, |
|
const uint32_t quant, |
|
| 1418 |
const uint32_t x, const uint32_t y, |
const uint32_t x, const uint32_t y, |
| 1419 |
const SearchData * const Data) |
const SearchData * const Data) |
| 1420 |
{ |
{ |
| 1421 |
int dx, dy, b_dx, b_dy; |
int dx = 0, dy = 0, b_dx = 0, b_dy = 0; |
| 1422 |
uint32_t sum; |
uint32_t sum; |
| 1423 |
|
const int div = 1 + Data->qpel; |
| 1424 |
|
int k; |
| 1425 |
|
const uint32_t quant = pMB->quant; |
| 1426 |
//this is not full chroma compensation, only it's fullpel approximation. should work though |
//this is not full chroma compensation, only it's fullpel approximation. should work though |
|
if (Data->qpel) { |
|
|
dy = Data->directmvF[0].y/2 + Data->directmvF[1].y/2 + |
|
|
Data->directmvF[2].y/2 + Data->directmvF[3].y/2; |
|
|
|
|
|
dx = Data->directmvF[0].x/2 + Data->directmvF[1].x/2 + |
|
|
Data->directmvF[2].x/2 + Data->directmvF[3].x/2; |
|
|
|
|
|
b_dy = Data->directmvB[0].y/2 + Data->directmvB[1].y/2 + |
|
|
Data->directmvB[2].y/2 + Data->directmvB[3].y/2; |
|
|
|
|
|
b_dx = Data->directmvB[0].x/2 + Data->directmvB[1].x/2 + |
|
|
Data->directmvB[2].x/2 + Data->directmvB[3].x/2; |
|
|
|
|
|
} else { |
|
|
dy = Data->directmvF[0].y + Data->directmvF[1].y + |
|
|
Data->directmvF[2].y + Data->directmvF[3].y; |
|
|
|
|
|
dx = Data->directmvF[0].x + Data->directmvF[1].x + |
|
|
Data->directmvF[2].x + Data->directmvF[3].x; |
|
| 1427 |
|
|
| 1428 |
b_dy = Data->directmvB[0].y + Data->directmvB[1].y + |
for (k = 0; k < 4; k++) { |
| 1429 |
Data->directmvB[2].y + Data->directmvB[3].y; |
dy += Data->directmvF[k].y / div; |
| 1430 |
|
dx += Data->directmvF[0].x / div; |
| 1431 |
b_dx = Data->directmvB[0].x + Data->directmvB[1].x + |
b_dy += Data->directmvB[0].y / div; |
| 1432 |
Data->directmvB[2].x + Data->directmvB[3].x; |
b_dx += Data->directmvB[0].x / div; |
| 1433 |
} |
} |
| 1434 |
|
|
|
|
|
| 1435 |
dy = (dy >> 3) + roundtab_76[dy & 0xf]; |
dy = (dy >> 3) + roundtab_76[dy & 0xf]; |
| 1436 |
dx = (dx >> 3) + roundtab_76[dx & 0xf]; |
dx = (dx >> 3) + roundtab_76[dx & 0xf]; |
| 1437 |
b_dy = (b_dy >> 3) + roundtab_76[b_dy & 0xf]; |
b_dy = (b_dy >> 3) + roundtab_76[b_dy & 0xf]; |
| 1441 |
f_Ref->u + (y*8 + dy/2) * (Data->iEdgedWidth/2) + x*8 + dx/2, |
f_Ref->u + (y*8 + dy/2) * (Data->iEdgedWidth/2) + x*8 + dx/2, |
| 1442 |
b_Ref->u + (y*8 + b_dy/2) * (Data->iEdgedWidth/2) + x*8 + b_dx/2, |
b_Ref->u + (y*8 + b_dy/2) * (Data->iEdgedWidth/2) + x*8 + b_dx/2, |
| 1443 |
Data->iEdgedWidth/2); |
Data->iEdgedWidth/2); |
| 1444 |
|
|
| 1445 |
|
if (sum >= 2 * MAX_CHROMA_SAD_FOR_SKIP * quant) return; //no skip |
| 1446 |
|
|
| 1447 |
sum += sad8bi(pCur->v + 8*x + 8*y*(Data->iEdgedWidth/2), |
sum += sad8bi(pCur->v + 8*x + 8*y*(Data->iEdgedWidth/2), |
| 1448 |
f_Ref->v + (y*8 + dy/2) * (Data->iEdgedWidth/2) + x*8 + dx/2, |
f_Ref->v + (y*8 + dy/2) * (Data->iEdgedWidth/2) + x*8 + dx/2, |
| 1449 |
b_Ref->v + (y*8 + b_dy/2) * (Data->iEdgedWidth/2) + x*8 + b_dx/2, |
b_Ref->v + (y*8 + b_dy/2) * (Data->iEdgedWidth/2) + x*8 + b_dx/2, |
| 1526 |
} |
} |
| 1527 |
} |
} |
| 1528 |
|
|
|
|
|
| 1529 |
if (b_mb->mode == MODE_INTER4V) CheckCandidate = CheckCandidateDirect; |
if (b_mb->mode == MODE_INTER4V) CheckCandidate = CheckCandidateDirect; |
| 1530 |
else CheckCandidate = CheckCandidateDirectno4v; |
else CheckCandidate = CheckCandidateDirectno4v; |
| 1531 |
|
|
| 1533 |
|
|
| 1534 |
// initial (fast) skip decision |
// initial (fast) skip decision |
| 1535 |
if (*Data->iMinSAD < pMB->quant * INITIAL_SKIP_THRESH*2) { |
if (*Data->iMinSAD < pMB->quant * INITIAL_SKIP_THRESH*2) { |
| 1536 |
SkipDecisionB(pCur, f_Ref, b_Ref, pMB, x, y, Data->chroma, Data); //possible skip - checking chroma |
SkipDecisionB(pCur, f_Ref, b_Ref, pMB, x, y, Data); //possible skip - checking chroma |
| 1537 |
if (pMB->mode == MODE_DIRECT_NONE_MV) return *Data->iMinSAD; // skip. |
if (pMB->mode == MODE_DIRECT_NONE_MV) return *Data->iMinSAD; // skip. |
| 1538 |
} |
} |
| 1539 |
|
|
| 1552 |
|
|
| 1553 |
*best_sad = *Data->iMinSAD; |
*best_sad = *Data->iMinSAD; |
| 1554 |
|
|
| 1555 |
if (b_mb->mode == MODE_INTER4V) |
if (b_mb->mode == MODE_INTER4V || Data->qpel) pMB->mode = MODE_DIRECT; |
|
pMB->mode = MODE_DIRECT; |
|
| 1556 |
else pMB->mode = MODE_DIRECT_NO4V; //for faster compensation |
else pMB->mode = MODE_DIRECT_NO4V; //for faster compensation |
| 1557 |
|
|
| 1558 |
pMB->pmvs[3] = *Data->currentMV; |
pMB->pmvs[3] = *Data->currentMV; |
| 1669 |
} while (!(iDirection)); |
} while (!(iDirection)); |
| 1670 |
|
|
| 1671 |
if (fData->qpel) { |
if (fData->qpel) { |
| 1672 |
|
if (*fData->iMinSAD > *best_sad + 500) return; |
| 1673 |
CheckCandidate = CheckCandidateInt; |
CheckCandidate = CheckCandidateInt; |
| 1674 |
fData->qpel_precision = bData.qpel_precision = 1; |
fData->qpel_precision = bData.qpel_precision = 1; |
| 1675 |
get_range(&fData->min_dx, &fData->max_dx, &fData->min_dy, &fData->max_dy, x, y, 16, pParam->width, pParam->height, fcode, 1, 0); |
get_range(&fData->min_dx, &fData->max_dx, &fData->min_dy, &fData->max_dy, x, y, 16, pParam->width, pParam->height, fcode, 1, 0); |
| 1679 |
fData->currentQMV[1].x = 2 * fData->currentMV[1].x; |
fData->currentQMV[1].x = 2 * fData->currentMV[1].x; |
| 1680 |
fData->currentQMV[1].y = 2 * fData->currentMV[1].y; |
fData->currentQMV[1].y = 2 * fData->currentMV[1].y; |
| 1681 |
SubpelRefine(fData); |
SubpelRefine(fData); |
| 1682 |
|
if (*fData->iMinSAD > *best_sad + 300) return; |
| 1683 |
fData->currentQMV[2] = fData->currentQMV[0]; |
fData->currentQMV[2] = fData->currentQMV[0]; |
| 1684 |
SubpelRefine(&bData); |
SubpelRefine(&bData); |
| 1685 |
} |
} |
| 1686 |
|
|
| 1687 |
*fData->iMinSAD += (2+2) * fData->lambda16; // two bits are needed to code interpolate mode. |
*fData->iMinSAD += (2+3) * fData->lambda16; // two bits are needed to code interpolate mode. |
| 1688 |
|
|
| 1689 |
if (*fData->iMinSAD < *best_sad) { |
if (*fData->iMinSAD < *best_sad) { |
| 1690 |
*best_sad = *fData->iMinSAD; |
*best_sad = *fData->iMinSAD; |
| 1736 |
|
|
| 1737 |
const int32_t TRB = time_pp - time_bp; |
const int32_t TRB = time_pp - time_bp; |
| 1738 |
const int32_t TRD = time_pp; |
const int32_t TRD = time_pp; |
|
uint8_t * qimage; |
|
| 1739 |
|
|
| 1740 |
// some pre-inintialized data for the rest of the search |
// some pre-inintialized data for the rest of the search |
| 1741 |
|
|
| 1752 |
Data.qpel = pParam->m_quarterpel; |
Data.qpel = pParam->m_quarterpel; |
| 1753 |
Data.rounding = 0; |
Data.rounding = 0; |
| 1754 |
|
|
| 1755 |
if((qimage = (uint8_t *) malloc(32 * pParam->edged_width)) == NULL) |
Data.RefQ = f_refV->u; // a good place, also used in MC (for similar purpose) |
|
return; // allocate some mem for qpel interpolated blocks |
|
|
// somehow this is dirty since I think we shouldn't use malloc outside |
|
|
// encoder_create() - so please fix me! |
|
|
Data.RefQ = qimage; |
|
|
|
|
| 1756 |
// note: i==horizontal, j==vertical |
// note: i==horizontal, j==vertical |
| 1757 |
for (j = 0; j < pParam->mb_height; j++) { |
for (j = 0; j < pParam->mb_height; j++) { |
| 1758 |
|
|
| 1804 |
MODE_BACKWARD, &Data); |
MODE_BACKWARD, &Data); |
| 1805 |
|
|
| 1806 |
// interpolate search comes last, because it uses data from forward and backward as prediction |
// interpolate search comes last, because it uses data from forward and backward as prediction |
|
|
|
| 1807 |
SearchInterpolate(f_ref->y, f_refH->y, f_refV->y, f_refHV->y, |
SearchInterpolate(f_ref->y, f_refH->y, f_refV->y, f_refHV->y, |
| 1808 |
b_ref->y, b_refH->y, b_refV->y, b_refHV->y, |
b_ref->y, b_refH->y, b_refV->y, b_refHV->y, |
| 1809 |
&frame->image, |
&frame->image, |
| 1818 |
// final skip decision |
// final skip decision |
| 1819 |
if ( (skip_sad < frame->quant * MAX_SAD00_FOR_SKIP*2) |
if ( (skip_sad < frame->quant * MAX_SAD00_FOR_SKIP*2) |
| 1820 |
&& ((100*best_sad)/(skip_sad+1) > FINAL_SKIP_THRESH) ) |
&& ((100*best_sad)/(skip_sad+1) > FINAL_SKIP_THRESH) ) |
| 1821 |
SkipDecisionB(&frame->image, f_ref, b_ref, pMB,frame->quant, i, j, &Data); |
SkipDecisionB(&frame->image, f_ref, b_ref, pMB, i, j, &Data); |
| 1822 |
|
|
| 1823 |
switch (pMB->mode) { |
switch (pMB->mode) { |
| 1824 |
case MODE_FORWARD: |
case MODE_FORWARD: |
| 1849 |
} |
} |
| 1850 |
} |
} |
| 1851 |
} |
} |
|
free(qimage); |
|
| 1852 |
} |
} |
| 1853 |
|
|
| 1854 |
static __inline int |
static __inline void |
| 1855 |
MEanalyzeMB ( const uint8_t * const pRef, |
MEanalyzeMB ( const uint8_t * const pRef, |
| 1856 |
const uint8_t * const pCur, |
const uint8_t * const pCur, |
| 1857 |
const int x, |
const int x, |
| 1858 |
const int y, |
const int y, |
| 1859 |
const MBParam * const pParam, |
const MBParam * const pParam, |
| 1860 |
const MACROBLOCK * const pMBs, |
MACROBLOCK * const pMBs, |
|
MACROBLOCK * const pMB, |
|
| 1861 |
SearchData * const Data) |
SearchData * const Data) |
| 1862 |
{ |
{ |
| 1863 |
|
|
| 1864 |
int i = 255, mask; |
int i, mask; |
| 1865 |
VECTOR pmv[3]; |
VECTOR pmv[3]; |
| 1866 |
*(Data->iMinSAD) = MV_MAX_ERROR; |
MACROBLOCK * pMB = &pMBs[x + y * pParam->mb_width]; |
| 1867 |
|
|
| 1868 |
|
for (i = 0; i < 5; i++) Data->iMinSAD[i] = MV_MAX_ERROR; |
| 1869 |
|
|
| 1870 |
//median is only used as prediction. it doesn't have to be real |
//median is only used as prediction. it doesn't have to be real |
| 1871 |
if (x == 1 && y == 1) Data->predMV.x = Data->predMV.y = 0; |
if (x == 1 && y == 1) Data->predMV.x = Data->predMV.y = 0; |
| 1872 |
else |
else |
| 1873 |
if (x == 1) //left macroblock does not have any vector now |
if (x == 1) //left macroblock does not have any vector now |
| 1874 |
Data->predMV = (pMB - pParam->mb_width)->mvs[0]; // top instead of median |
Data->predMV = (pMB - pParam->mb_width)->mvs[0]; // top instead of median |
| 1875 |
else if (y == 1) // top macroblock don't have it's vector |
else if (y == 1) // top macroblock doesn't have it's vector |
| 1876 |
Data->predMV = (pMB - 1)->mvs[0]; // left instead of median |
Data->predMV = (pMB - 1)->mvs[0]; // left instead of median |
| 1877 |
else Data->predMV = get_pmv2(pMBs, pParam->mb_width, 0, x, y, 0); //else median |
else Data->predMV = get_pmv2(pMBs, pParam->mb_width, 0, x, y, 0); //else median |
| 1878 |
|
|
| 1879 |
get_range(&Data->min_dx, &Data->max_dx, &Data->min_dy, &Data->max_dy, x, y, 16, |
get_range(&Data->min_dx, &Data->max_dx, &Data->min_dy, &Data->max_dy, x, y, 16, |
| 1880 |
pParam->width, pParam->height, Data->iFcode - pParam->m_quarterpel, 0, 0); |
pParam->width, pParam->height, Data->iFcode - pParam->m_quarterpel, 0, Data->rrv); |
| 1881 |
|
|
| 1882 |
Data->Cur = pCur + (x + y * pParam->edged_width) * 16; |
Data->Cur = pCur + (x + y * pParam->edged_width) * 16; |
| 1883 |
Data->Ref = pRef + (x + y * pParam->edged_width) * 16; |
Data->Ref = pRef + (x + y * pParam->edged_width) * 16; |
| 1888 |
pmv[2].y = EVEN(Data->predMV.y); |
pmv[2].y = EVEN(Data->predMV.y); |
| 1889 |
pmv[0].x = pmv[0].y = 0; |
pmv[0].x = pmv[0].y = 0; |
| 1890 |
|
|
| 1891 |
CheckCandidate16no4vI(0, 0, 255, &i, Data); |
CheckCandidate32I(0, 0, 255, &i, Data); |
| 1892 |
|
|
| 1893 |
//early skip for 0,0 |
if (*Data->iMinSAD > 4 * MAX_SAD00_FOR_SKIP * 4) { |
|
if (*Data->iMinSAD < MAX_SAD00_FOR_SKIP * 4) { |
|
|
pMB->mvs[0] = pMB->mvs[1] = pMB->mvs[2] = pMB->mvs[3] = Data->currentMV[0]; |
|
|
pMB->mode = MODE_NOT_CODED; |
|
|
return 0; |
|
|
} |
|
| 1894 |
|
|
| 1895 |
if (!(mask = make_mask(pmv, 1))) |
if (!(mask = make_mask(pmv, 1))) |
| 1896 |
CheckCandidate16no4vI(pmv[1].x, pmv[1].y, mask, &i, Data); |
CheckCandidate32I(pmv[1].x, pmv[1].y, mask, &i, Data); |
| 1897 |
if (!(mask = make_mask(pmv, 2))) |
if (!(mask = make_mask(pmv, 2))) |
| 1898 |
CheckCandidate16no4vI(pmv[2].x, pmv[2].y, mask, &i, Data); |
CheckCandidate32I(pmv[2].x, pmv[2].y, mask, &i, Data); |
| 1899 |
|
|
| 1900 |
if (*Data->iMinSAD > MAX_SAD00_FOR_SKIP * 6) // diamond only if needed |
if (*Data->iMinSAD > 4 * MAX_SAD00_FOR_SKIP * 4) // diamond only if needed |
| 1901 |
DiamondSearch(Data->currentMV->x, Data->currentMV->y, Data, i); |
DiamondSearch(Data->currentMV->x, Data->currentMV->y, Data, i); |
| 1902 |
|
|
| 1903 |
pMB->mvs[0] = pMB->mvs[1] = pMB->mvs[2] = pMB->mvs[3] = Data->currentMV[0]; |
for (i = 0; i < 4; i++) { |
| 1904 |
pMB->mode = MODE_INTER; |
MACROBLOCK * MB = &pMBs[x + (i&1) + (y+(i>>1) * pParam->mb_width)]; |
| 1905 |
return *(Data->iMinSAD); |
MB->mvs[0] = MB->mvs[1] = MB->mvs[2] = MB->mvs[3] = Data->currentMV[i]; |
| 1906 |
|
MB->mode = MODE_INTER; |
| 1907 |
|
MB->sad16 = Data->iMinSAD[i+1]; |
| 1908 |
|
} |
| 1909 |
|
} |
| 1910 |
} |
} |
| 1911 |
|
|
| 1912 |
#define INTRA_THRESH 1350 |
#define INTRA_BIAS 2500 |
| 1913 |
#define INTER_THRESH 1200 |
#define INTRA_THRESH 1500 |
| 1914 |
|
#define INTER_THRESH 1400 |
| 1915 |
|
|
| 1916 |
|
|
| 1917 |
int |
int |
| 1927 |
MACROBLOCK * const pMBs = Current->mbs; |
MACROBLOCK * const pMBs = Current->mbs; |
| 1928 |
const IMAGE * const pCurrent = &Current->image; |
const IMAGE * const pCurrent = &Current->image; |
| 1929 |
int IntraThresh = INTRA_THRESH, InterThresh = INTER_THRESH; |
int IntraThresh = INTRA_THRESH, InterThresh = INTER_THRESH; |
| 1930 |
|
const VECTOR zeroMV = {0,0}; |
| 1931 |
|
|
| 1932 |
VECTOR currentMV; |
int32_t iMinSAD[5], temp[5]; |
| 1933 |
int32_t iMinSAD; |
VECTOR currentMV[5]; |
| 1934 |
SearchData Data; |
SearchData Data; |
| 1935 |
Data.iEdgedWidth = pParam->edged_width; |
Data.iEdgedWidth = pParam->edged_width; |
| 1936 |
Data.currentMV = ¤tMV; |
Data.currentMV = currentMV; |
| 1937 |
Data.iMinSAD = &iMinSAD; |
Data.iMinSAD = iMinSAD; |
| 1938 |
Data.iFcode = Current->fcode; |
Data.iFcode = Current->fcode; |
| 1939 |
CheckCandidate = CheckCandidate16no4vI; |
Data.rrv = Current->global_flags & XVID_REDUCED; |
| 1940 |
|
Data.temp = temp; |
| 1941 |
|
CheckCandidate = CheckCandidate32I; |
| 1942 |
|
|
| 1943 |
if (intraCount < 10) // we're right after an I frame |
if (intraCount < 10) // we're right after an I frame |
| 1944 |
IntraThresh += 4 * (intraCount - 10) * (intraCount - 10); |
IntraThresh += 4 * (intraCount - 10) * (intraCount - 10); |
| 1946 |
if ( 5*(maxIntra - intraCount) < maxIntra) // we're close to maximum. 2 sec when max is 10 sec |
if ( 5*(maxIntra - intraCount) < maxIntra) // we're close to maximum. 2 sec when max is 10 sec |
| 1947 |
IntraThresh -= (IntraThresh * (maxIntra - 5*(maxIntra - intraCount)))/maxIntra; |
IntraThresh -= (IntraThresh * (maxIntra - 5*(maxIntra - intraCount)))/maxIntra; |
| 1948 |
|
|
|
|
|
| 1949 |
InterThresh += 400 * (1 - bCount); |
InterThresh += 400 * (1 - bCount); |
| 1950 |
if (InterThresh < 200) InterThresh = 200; |
if (InterThresh < 300) InterThresh = 300; |
| 1951 |
|
|
| 1952 |
if (sadInit) (*sadInit) (); |
if (sadInit) (*sadInit) (); |
| 1953 |
|
|
| 1954 |
for (y = 1; y < pParam->mb_height-1; y++) { |
for (y = 1; y < pParam->mb_height-1; y+=2) { |
| 1955 |
for (x = 1; x < pParam->mb_width-1; x++) { |
for (x = 1; x < pParam->mb_width-1; x+=2) { |
| 1956 |
int sad, dev; |
int i; |
| 1957 |
MACROBLOCK *pMB = &pMBs[x + y * pParam->mb_width]; |
|
| 1958 |
|
if (bCount == 0) pMBs[x + y * pParam->mb_width].mvs[0] = zeroMV; |
| 1959 |
|
|
| 1960 |
sad = MEanalyzeMB(pRef->y, pCurrent->y, x, y, |
MEanalyzeMB(pRef->y, pCurrent->y, x, y, pParam, pMBs, &Data); |
|
pParam, pMBs, pMB, &Data); |
|
| 1961 |
|
|
| 1962 |
if (sad > IntraThresh) { |
for (i = 0; i < 4; i++) { |
| 1963 |
dev = dev16(pCurrent->y + (x + y * pParam->edged_width) * 16, |
int dev; |
| 1964 |
|
MACROBLOCK *pMB = &pMBs[x+(i&1) + y+(i>>1) * pParam->mb_width]; |
| 1965 |
|
if (pMB->sad16 > IntraThresh) { |
| 1966 |
|
dev = dev16(pCurrent->y + (x + (i&1) + (y + (i>>1))* pParam->edged_width) * 16, |
| 1967 |
pParam->edged_width); |
pParam->edged_width); |
| 1968 |
if (dev + IntraThresh < sad) { |
if (dev + IntraThresh < pMB->sad16) { |
| 1969 |
pMB->mode = MODE_INTRA; |
pMB->mode = MODE_INTRA; |
| 1970 |
if (++intra > (pParam->mb_height-2)*(pParam->mb_width-2)/2) return I_VOP; |
if (++intra > (pParam->mb_height-2)*(pParam->mb_width-2)/2) return I_VOP; |
| 1971 |
} |
} |
| 1972 |
} |
} |
| 1973 |
sSAD += sad; |
sSAD += pMB->sad16; |
| 1974 |
|
} |
| 1975 |
} |
} |
| 1976 |
} |
} |
| 1977 |
sSAD /= (pParam->mb_height-2)*(pParam->mb_width-2); |
sSAD /= (pParam->mb_height-2)*(pParam->mb_width-2); |
| 1978 |
|
if (sSAD > IntraThresh + INTRA_BIAS ) return I_VOP; |
| 1979 |
if (sSAD > InterThresh ) return P_VOP; |
if (sSAD > InterThresh ) return P_VOP; |
| 1980 |
emms(); |
emms(); |
| 1981 |
return B_VOP; |
return B_VOP; |
| 2007 |
} |
} |
| 2008 |
|
|
| 2009 |
|
|
| 2010 |
static __inline VECTOR |
static VECTOR |
| 2011 |
GlobalMotionEst(const MACROBLOCK * const pMBs, const MBParam * const pParam, const uint32_t iFcode) |
GlobalMotionEst(const MACROBLOCK * const pMBs, const MBParam * const pParam, const uint32_t iFcode) |
| 2012 |
{ |
{ |
| 2013 |
|
|
| 2046 |
max_x = gmc.x + step; |
max_x = gmc.x + step; |
| 2047 |
min_y = gmc.y - step; |
min_y = gmc.y - step; |
| 2048 |
max_y = gmc.y + step; |
max_y = gmc.y + step; |
|
|
|
| 2049 |
} |
} |
| 2050 |
|
|
| 2051 |
if (bestcount < (pParam->mb_height-2)*(pParam->mb_width-2)/10) |
if (bestcount < (pParam->mb_height-2)*(pParam->mb_width-2)/10) |
| 2052 |
gmc.x = gmc.y = 0; //no camara pan, no GMC |
gmc.x = gmc.y = 0; //no camara pan, no GMC |
| 2053 |
|
|
| 2054 |
// step2: let's refine camera panning using gradiend-descent approach. |
// step2: let's refine camera panning using gradiend-descent approach |
| 2055 |
// TODO: more warping points may be evaluated here (like in interpolate mode search - two vectors in one diamond) |
// TODO: more warping points may be evaluated here (like in interpolate mode search - two vectors in one diamond) |
| 2056 |
bestcount = 0; |
bestcount = 0; |
| 2057 |
CheckGMC(gmc.x, gmc.y, 255, &iDirection, pMBs, &bestcount, &gmc, pParam); |
CheckGMC(gmc.x, gmc.y, 255, &iDirection, pMBs, &bestcount, &gmc, pParam); |
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