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[melted] / src / modules / gtk2 / pixops.c
1 /* GdkPixbuf library - Scaling and compositing functions
2 *
3 * Original:
4 * Copyright (C) 2000 Red Hat, Inc
5 * Author: Owen Taylor <otaylor@redhat.com>
6 *
7 * Modification for MLT:
8 * Copyright (C) 2003-2004 Ushodaya Enterprises Limited
9 * Author: Dan Dennedy <dan@dennedy.org>
10 *
11 * This library is free software; you can redistribute it and/or
12 * modify it under the terms of the GNU Lesser General Public
13 * License as published by the Free Software Foundation; either
14 * version 2 of the License, or (at your option) any later version.
15 *
16 * This library is distributed in the hope that it will be useful,
17 * but WITHOUT ANY WARRANTY; without even the implied warranty of
18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
19 * Lesser General Public License for more details.
20 *
21 * You should have received a copy of the GNU Lesser General Public
22 * License along with this library; if not, write to the
23 * Free Software Foundation, Inc., 59 Temple Place - Suite 330,
24 * Boston, MA 02111-1307, USA.
25 */
26
27 #include <math.h>
28 #include <glib.h>
29 #include <stdio.h>
30
31 #include "pixops.h"
32
33 #define SUBSAMPLE_BITS 4
34 #define SUBSAMPLE (1 << SUBSAMPLE_BITS)
35 #define SUBSAMPLE_MASK ((1 << SUBSAMPLE_BITS)-1)
36 #define SCALE_SHIFT 16
37
38 typedef struct _PixopsFilter PixopsFilter;
39 typedef struct _PixopsFilterDimension PixopsFilterDimension;
40
41 struct _PixopsFilterDimension
42 {
43 int n;
44 double offset;
45 double *weights;
46 };
47
48 struct _PixopsFilter
49 {
50 PixopsFilterDimension x;
51 PixopsFilterDimension y;
52 double overall_alpha;
53 };
54
55 typedef guchar *( *PixopsLineFunc ) ( int *weights, int n_x, int n_y,
56 guchar *dest, int dest_x, guchar *dest_end,
57 guchar **src,
58 int x_init, int x_step, int src_width );
59
60 typedef void ( *PixopsPixelFunc ) ( guchar *dest, guint y1, guint cr, guint y2, guint cb );
61
62
63 /* mmx function declarations */
64 #ifdef USE_MMX
65 guchar *pixops_scale_line_22_yuv_mmx ( guint32 weights[ 16 ][ 8 ], guchar *p, guchar *q1, guchar *q2, int x_step, guchar *p_stop, int x_init, int destx );
66 int pixops_have_mmx ( void );
67 #endif
68
69 static inline int
70 get_check_shift ( int check_size )
71 {
72 int check_shift = 0;
73 g_return_val_if_fail ( check_size >= 0, 4 );
74
75 while ( !( check_size & 1 ) )
76 {
77 check_shift++;
78 check_size >>= 1;
79 }
80
81 return check_shift;
82 }
83
84 static inline void
85 pixops_scale_nearest ( guchar *dest_buf,
86 int render_x0,
87 int render_y0,
88 int render_x1,
89 int render_y1,
90 int dest_rowstride,
91 const guchar *src_buf,
92 int src_width,
93 int src_height,
94 int src_rowstride,
95 double scale_x,
96 double scale_y )
97 {
98 register int i, j;
99 register int x_step = ( 1 << SCALE_SHIFT ) / scale_x;
100 register int y_step = ( 1 << SCALE_SHIFT ) / scale_y;
101 register int x, x_scaled;
102
103 for ( i = 0; i < ( render_y1 - render_y0 ); i++ )
104 {
105 const guchar *src = src_buf + ( ( ( i + render_y0 ) * y_step + ( y_step >> 1 ) ) >> SCALE_SHIFT ) * src_rowstride;
106 guchar *dest = dest_buf + i * dest_rowstride;
107 x = render_x0 * x_step + ( x_step >> 1 );
108
109 for ( j = 0; j < ( render_x1 - render_x0 ); j++ )
110 {
111 x_scaled = x >> SCALE_SHIFT;
112 *dest++ = src[ x_scaled << 1 ];
113 *dest++ = src[ ( ( x_scaled >> 1 ) << 2 ) + ( ( j & 1 ) << 1 ) + 1 ];
114 x += x_step;
115 }
116 }
117 }
118
119
120 static inline guchar *
121 scale_line ( int *weights, int n_x, int n_y,
122 guchar *dest, int dest_x, guchar *dest_end,
123 guchar **src,
124 int x_init, int x_step, int src_width )
125 {
126 register int x = x_init;
127 register int i, j, x_scaled, y_index, uv_index;
128
129 while ( dest < dest_end )
130 {
131 unsigned int y = 0, uv = 0;
132 int *pixel_weights = weights + ( ( x >> ( SCALE_SHIFT - SUBSAMPLE_BITS ) ) & SUBSAMPLE_MASK ) * n_x * n_y;
133
134 x_scaled = x >> SCALE_SHIFT;
135 y_index = x_scaled << 1;
136 uv_index = ( ( x_scaled >> 1 ) << 2 ) + ( ( dest_x & 1 ) << 1 ) + 1;
137
138 for ( i = 0; i < n_y; i++ )
139 {
140 int *line_weights = pixel_weights + n_x * i;
141 guchar *q = src[ i ];
142
143 for ( j = 0; j < n_x; j ++ )
144 {
145 unsigned int ta = line_weights[ j ];
146
147 y += ta * q[ y_index ];
148 uv += ta * q[ uv_index ];
149 }
150 }
151
152 *dest++ = ( y + 0xffff ) >> SCALE_SHIFT;
153 *dest++ = ( uv + 0xffff ) >> SCALE_SHIFT;
154
155 x += x_step;
156 dest_x++;
157 }
158
159 return dest;
160 }
161
162 #ifdef USE_MMX
163 static inline guchar *
164 scale_line_22_yuv_mmx_stub ( int *weights, int n_x, int n_y,
165 guchar *dest, int dest_x, guchar *dest_end,
166 guchar **src,
167 int x_init, int x_step, int src_width )
168 {
169 guint32 mmx_weights[ 16 ][ 8 ];
170 int j;
171
172 for ( j = 0; j < 16; j++ )
173 {
174 mmx_weights[ j ][ 0 ] = 0x00010001 * ( weights[ 4 * j ] >> 8 );
175 mmx_weights[ j ][ 1 ] = 0x00010001 * ( weights[ 4 * j ] >> 8 );
176 mmx_weights[ j ][ 2 ] = 0x00010001 * ( weights[ 4 * j + 1 ] >> 8 );
177 mmx_weights[ j ][ 3 ] = 0x00010001 * ( weights[ 4 * j + 1 ] >> 8 );
178 mmx_weights[ j ][ 4 ] = 0x00010001 * ( weights[ 4 * j + 2 ] >> 8 );
179 mmx_weights[ j ][ 5 ] = 0x00010001 * ( weights[ 4 * j + 2 ] >> 8 );
180 mmx_weights[ j ][ 6 ] = 0x00010001 * ( weights[ 4 * j + 3 ] >> 8 );
181 mmx_weights[ j ][ 7 ] = 0x00010001 * ( weights[ 4 * j + 3 ] >> 8 );
182 }
183
184 return pixops_scale_line_22_yuv_mmx ( mmx_weights, dest, src[ 0 ], src[ 1 ], x_step, dest_end, x_init, dest_x );
185 }
186 #endif /* USE_MMX */
187
188 static inline guchar *
189 scale_line_22_yuv ( int *weights, int n_x, int n_y,
190 guchar *dest, int dest_x, guchar *dest_end,
191 guchar **src,
192 int x_init, int x_step, int src_width )
193 {
194 register int x = x_init;
195 register guchar *src0 = src[ 0 ];
196 register guchar *src1 = src[ 1 ];
197 register unsigned int p;
198 register guchar *q0, *q1;
199 register int w1, w2, w3, w4;
200 register int x_scaled, x_aligned, uv_index;
201
202 while ( dest < dest_end )
203 {
204 int *pixel_weights = weights + ( ( x >> ( SCALE_SHIFT - SUBSAMPLE_BITS ) ) & SUBSAMPLE_MASK ) * 4;
205
206 x_scaled = x >> SCALE_SHIFT;
207
208 w1 = pixel_weights[ 0 ];
209 w2 = pixel_weights[ 1 ];
210 w3 = pixel_weights[ 2 ];
211 w4 = pixel_weights[ 3 ];
212
213 /* process Y */
214 q0 = src0 + ( x_scaled << 1 );
215 q1 = src1 + ( x_scaled << 1 );
216 p = w1 * q0[ 0 ];
217 p += w2 * q0[ 2 ];
218 p += w3 * q1[ 0 ];
219 p += w4 * q1[ 2 ];
220 *dest++ = ( p + 0x8000 ) >> SCALE_SHIFT;
221
222 /* process U/V */
223 x_aligned = ( ( x_scaled >> 1 ) << 2 );
224 uv_index = ( ( dest_x & 1 ) << 1 ) + 1;
225
226 q0 = src0 + x_aligned;
227 q1 = src1 + x_aligned;
228 p = w1 * q0[ uv_index ];
229 p += w3 * q1[ uv_index ];
230 p += w2 * q0[ uv_index ];
231 p += w4 * q1[ uv_index ];
232
233 x += x_step;
234 dest_x ++;
235
236 *dest++ = ( p + 0x8000 ) >> SCALE_SHIFT;
237 }
238
239 return dest;
240 }
241
242
243 static inline void
244 process_pixel ( int *weights, int n_x, int n_y,
245 guchar *dest, int dest_x, int dest_channels,
246 guchar **src, int src_channels,
247 int x_start, int src_width )
248 {
249 register unsigned int y = 0, uv = 0;
250 register int i, j;
251 int uv_index = ( ( dest_x & 1 ) << 1 ) + 1;
252
253 for ( i = 0; i < n_y; i++ )
254 {
255 int *line_weights = weights + n_x * i;
256
257 for ( j = 0; j < n_x; j++ )
258 {
259 unsigned int ta = 0xff * line_weights[ j ];
260
261 if ( x_start + j < 0 )
262 {
263 y += ta * src[ i ][ 0 ];
264 uv += ta * src[ i ][ uv_index ];
265 }
266 else if ( x_start + j < src_width )
267 {
268 y += ta * src[ i ][ ( x_start + j ) << 1 ];
269 uv += ta * src[ i ][ ( ( ( x_start + j ) >> 1 ) << 2) + uv_index ];
270 }
271 else
272 {
273 y += ta * src[ i ][ ( src_width - 1 ) << 1 ];
274 uv += ta * src[ i ][ ( ( ( src_width - 1 ) >> 1 ) << 2) + uv_index ];
275 }
276 }
277 }
278
279 *dest++ = ( y + 0xffffff ) >> 24;
280 *dest++ = ( uv + 0xffffff ) >> 24;
281 }
282
283
284 static inline void
285 correct_total ( int *weights,
286 int n_x,
287 int n_y,
288 int total,
289 double overall_alpha )
290 {
291 int correction = ( int ) ( 0.5 + 65536 * overall_alpha ) - total;
292 int remaining, c, d, i;
293
294 if ( correction != 0 )
295 {
296 remaining = correction;
297 for ( d = 1, c = correction; c != 0 && remaining != 0; d++, c = correction / d )
298 for ( i = n_x * n_y - 1; i >= 0 && c != 0 && remaining != 0; i-- )
299 if ( *( weights + i ) + c >= 0 )
300 {
301 *( weights + i ) += c;
302 remaining -= c;
303 if ( ( 0 < remaining && remaining < c ) ||
304 ( 0 > remaining && remaining > c ) )
305 c = remaining;
306 }
307 }
308 }
309
310
311 static inline int *
312 make_filter_table ( PixopsFilter *filter )
313 {
314 int i_offset, j_offset;
315 int n_x = filter->x.n;
316 int n_y = filter->y.n;
317 int *weights = g_new ( int, SUBSAMPLE * SUBSAMPLE * n_x * n_y );
318
319 for ( i_offset = 0; i_offset < SUBSAMPLE; i_offset++ )
320 for ( j_offset = 0; j_offset < SUBSAMPLE; j_offset++ )
321 {
322 double weight;
323 int *pixel_weights = weights + ( ( i_offset * SUBSAMPLE ) + j_offset ) * n_x * n_y;
324 int total = 0;
325 int i, j;
326
327 for ( i = 0; i < n_y; i++ )
328 for ( j = 0; j < n_x; j++ )
329 {
330 weight = filter->x.weights[ ( j_offset * n_x ) + j ] *
331 filter->y.weights[ ( i_offset * n_y ) + i ] *
332 filter->overall_alpha * 65536 + 0.5;
333
334 total += ( int ) weight;
335
336 *( pixel_weights + n_x * i + j ) = weight;
337 }
338
339 correct_total ( pixel_weights, n_x, n_y, total, filter->overall_alpha );
340 }
341
342 return weights;
343 }
344
345
346 static inline void
347 pixops_process ( guchar *dest_buf,
348 int render_x0,
349 int render_y0,
350 int render_x1,
351 int render_y1,
352 int dest_rowstride,
353 int dest_channels,
354 gboolean dest_has_alpha,
355 const guchar *src_buf,
356 int src_width,
357 int src_height,
358 int src_rowstride,
359 int src_channels,
360 gboolean src_has_alpha,
361 double scale_x,
362 double scale_y,
363 int check_x,
364 int check_y,
365 int check_size,
366 guint32 color1,
367 guint32 color2,
368 PixopsFilter *filter,
369 PixopsLineFunc line_func )
370 {
371 int i, j;
372 int x, y; /* X and Y position in source (fixed_point) */
373
374 guchar **line_bufs = g_new ( guchar *, filter->y.n );
375 int *filter_weights = make_filter_table ( filter );
376
377 int x_step = ( 1 << SCALE_SHIFT ) / scale_x; /* X step in source (fixed point) */
378 int y_step = ( 1 << SCALE_SHIFT ) / scale_y; /* Y step in source (fixed point) */
379
380 int check_shift = check_size ? get_check_shift ( check_size ) : 0;
381
382 int scaled_x_offset = floor ( filter->x.offset * ( 1 << SCALE_SHIFT ) );
383
384 /* Compute the index where we run off the end of the source buffer. The furthest
385 * source pixel we access at index i is:
386 *
387 * ((render_x0 + i) * x_step + scaled_x_offset) >> SCALE_SHIFT + filter->x.n - 1
388 *
389 * So, run_end_index is the smallest i for which this pixel is src_width, i.e, for which:
390 *
391 * (i + render_x0) * x_step >= ((src_width - filter->x.n + 1) << SCALE_SHIFT) - scaled_x_offset
392 *
393 */
394 #define MYDIV(a,b) ((a) > 0 ? (a) / (b) : ((a) - (b) + 1) / (b)) /* Division so that -1/5 = -1 */
395
396 int run_end_x = ( ( ( src_width - filter->x.n + 1 ) << SCALE_SHIFT ) - scaled_x_offset );
397 int run_end_index = MYDIV ( run_end_x + x_step - 1, x_step ) - render_x0;
398 run_end_index = MIN ( run_end_index, render_x1 - render_x0 );
399
400 y = render_y0 * y_step + floor ( filter->y.offset * ( 1 << SCALE_SHIFT ) );
401 for ( i = 0; i < ( render_y1 - render_y0 ); i++ )
402 {
403 int dest_x;
404 int y_start = y >> SCALE_SHIFT;
405 int x_start;
406 int *run_weights = filter_weights +
407 ( ( y >> ( SCALE_SHIFT - SUBSAMPLE_BITS ) ) & SUBSAMPLE_MASK ) *
408 filter->x.n * filter->y.n * SUBSAMPLE;
409 guchar *new_outbuf;
410 guint32 tcolor1, tcolor2;
411
412 guchar *outbuf = dest_buf + dest_rowstride * i;
413 guchar *outbuf_end = outbuf + dest_channels * ( render_x1 - render_x0 );
414
415 if ( ( ( i + check_y ) >> check_shift ) & 1 )
416 {
417 tcolor1 = color2;
418 tcolor2 = color1;
419 }
420 else
421 {
422 tcolor1 = color1;
423 tcolor2 = color2;
424 }
425
426 for ( j = 0; j < filter->y.n; j++ )
427 {
428 if ( y_start < 0 )
429 line_bufs[ j ] = ( guchar * ) src_buf;
430 else if ( y_start < src_height )
431 line_bufs[ j ] = ( guchar * ) src_buf + src_rowstride * y_start;
432 else
433 line_bufs[ j ] = ( guchar * ) src_buf + src_rowstride * ( src_height - 1 );
434
435 y_start++;
436 }
437
438 dest_x = check_x;
439 x = render_x0 * x_step + scaled_x_offset;
440 x_start = x >> SCALE_SHIFT;
441
442 while ( x_start < 0 && outbuf < outbuf_end )
443 {
444 process_pixel ( run_weights + ( ( x >> ( SCALE_SHIFT - SUBSAMPLE_BITS ) ) & SUBSAMPLE_MASK ) * ( filter->x.n * filter->y.n ),
445 filter->x.n, filter->y.n,
446 outbuf, dest_x, dest_channels,
447 line_bufs, src_channels,
448 x >> SCALE_SHIFT, src_width );
449
450 x += x_step;
451 x_start = x >> SCALE_SHIFT;
452 dest_x++;
453 outbuf += dest_channels;
454 }
455
456 new_outbuf = ( *line_func ) ( run_weights, filter->x.n, filter->y.n,
457 outbuf, dest_x,
458 dest_buf + dest_rowstride * i + run_end_index * dest_channels,
459 line_bufs,
460 x, x_step, src_width );
461
462 dest_x += ( new_outbuf - outbuf ) / dest_channels;
463
464 x = ( dest_x - check_x + render_x0 ) * x_step + scaled_x_offset;
465 outbuf = new_outbuf;
466
467 while ( outbuf < outbuf_end )
468 {
469 process_pixel ( run_weights + ( ( x >> ( SCALE_SHIFT - SUBSAMPLE_BITS ) ) & SUBSAMPLE_MASK ) * ( filter->x.n * filter->y.n ),
470 filter->x.n, filter->y.n,
471 outbuf, dest_x, dest_channels,
472 line_bufs, src_channels,
473 x >> SCALE_SHIFT, src_width );
474
475 x += x_step;
476 dest_x++;
477 outbuf += dest_channels;
478 }
479
480 y += y_step;
481 }
482
483 g_free ( line_bufs );
484 g_free ( filter_weights );
485 }
486
487
488 /* Compute weights for reconstruction by replication followed by
489 * sampling with a box filter
490 */
491 static inline void
492 tile_make_weights ( PixopsFilterDimension *dim,
493 double scale )
494 {
495 int n = ceil ( 1 / scale + 1 );
496 double *pixel_weights = g_new ( double, SUBSAMPLE * n );
497 int offset;
498 int i;
499
500 dim->n = n;
501 dim->offset = 0;
502 dim->weights = pixel_weights;
503
504 for ( offset = 0; offset < SUBSAMPLE; offset++ )
505 {
506 double x = ( double ) offset / SUBSAMPLE;
507 double a = x + 1 / scale;
508
509 for ( i = 0; i < n; i++ )
510 {
511 if ( i < x )
512 {
513 if ( i + 1 > x )
514 * ( pixel_weights++ ) = ( MIN ( i + 1, a ) - x ) * scale;
515 else
516 *( pixel_weights++ ) = 0;
517 }
518 else
519 {
520 if ( a > i )
521 * ( pixel_weights++ ) = ( MIN ( i + 1, a ) - i ) * scale;
522 else
523 *( pixel_weights++ ) = 0;
524 }
525 }
526 }
527 }
528
529 /* Compute weights for a filter that, for minification
530 * is the same as 'tiles', and for magnification, is bilinear
531 * reconstruction followed by a sampling with a delta function.
532 */
533 static inline void
534 bilinear_magnify_make_weights ( PixopsFilterDimension *dim,
535 double scale )
536 {
537 double * pixel_weights;
538 int n;
539 int offset;
540 int i;
541
542 if ( scale > 1.0 ) /* Linear */
543 {
544 n = 2;
545 dim->offset = 0.5 * ( 1 / scale - 1 );
546 }
547 else /* Tile */
548 {
549 n = ceil ( 1.0 + 1.0 / scale );
550 dim->offset = 0.0;
551 }
552
553 dim->n = n;
554 dim->weights = g_new ( double, SUBSAMPLE * n );
555
556 pixel_weights = dim->weights;
557
558 for ( offset = 0; offset < SUBSAMPLE; offset++ )
559 {
560 double x = ( double ) offset / SUBSAMPLE;
561
562 if ( scale > 1.0 ) /* Linear */
563 {
564 for ( i = 0; i < n; i++ )
565 *( pixel_weights++ ) = ( ( ( i == 0 ) ? ( 1 - x ) : x ) / scale ) * scale;
566 }
567 else /* Tile */
568 {
569 double a = x + 1 / scale;
570
571 /* x
572 * ---------|--.-|----|--.-|------- SRC
573 * ------------|---------|--------- DEST
574 */
575 for ( i = 0; i < n; i++ )
576 {
577 if ( i < x )
578 {
579 if ( i + 1 > x )
580 * ( pixel_weights++ ) = ( MIN ( i + 1, a ) - x ) * scale;
581 else
582 *( pixel_weights++ ) = 0;
583 }
584 else
585 {
586 if ( a > i )
587 * ( pixel_weights++ ) = ( MIN ( i + 1, a ) - i ) * scale;
588 else
589 *( pixel_weights++ ) = 0;
590 }
591 }
592 }
593 }
594 }
595
596 /* Computes the integral from b0 to b1 of
597 *
598 * f(x) = x; 0 <= x < 1
599 * f(x) = 0; otherwise
600 *
601 * We combine two of these to compute the convolution of
602 * a box filter with a triangular spike.
603 */
604 static inline double
605 linear_box_half ( double b0, double b1 )
606 {
607 double a0, a1;
608 double x0, x1;
609
610 a0 = 0.;
611 a1 = 1.;
612
613 if ( a0 < b0 )
614 {
615 if ( a1 > b0 )
616 {
617 x0 = b0;
618 x1 = MIN ( a1, b1 );
619 }
620 else
621 return 0;
622 }
623 else
624 {
625 if ( b1 > a0 )
626 {
627 x0 = a0;
628 x1 = MIN ( a1, b1 );
629 }
630 else
631 return 0;
632 }
633
634 return 0.5 * ( x1 * x1 - x0 * x0 );
635 }
636
637 /* Compute weights for reconstructing with bilinear
638 * interpolation, then sampling with a box filter
639 */
640 static inline void
641 bilinear_box_make_weights ( PixopsFilterDimension *dim,
642 double scale )
643 {
644 int n = ceil ( 1 / scale + 2.0 );
645 double *pixel_weights = g_new ( double, SUBSAMPLE * n );
646 double w;
647 int offset, i;
648
649 dim->offset = -1.0;
650 dim->n = n;
651 dim->weights = pixel_weights;
652
653 for ( offset = 0 ; offset < SUBSAMPLE; offset++ )
654 {
655 double x = ( double ) offset / SUBSAMPLE;
656 double a = x + 1 / scale;
657
658 for ( i = 0; i < n; i++ )
659 {
660 w = linear_box_half ( 0.5 + i - a, 0.5 + i - x );
661 w += linear_box_half ( 1.5 + x - i, 1.5 + a - i );
662
663 *( pixel_weights++ ) = w * scale;
664 }
665 }
666 }
667
668
669 static inline void
670 make_weights ( PixopsFilter *filter,
671 PixopsInterpType interp_type,
672 double scale_x,
673 double scale_y )
674 {
675 switch ( interp_type )
676 {
677 case PIXOPS_INTERP_NEAREST:
678 g_assert_not_reached ();
679 break;
680
681 case PIXOPS_INTERP_TILES:
682 tile_make_weights ( &filter->x, scale_x );
683 tile_make_weights ( &filter->y, scale_y );
684 break;
685
686 case PIXOPS_INTERP_BILINEAR:
687 bilinear_magnify_make_weights ( &filter->x, scale_x );
688 bilinear_magnify_make_weights ( &filter->y, scale_y );
689 break;
690
691 case PIXOPS_INTERP_HYPER:
692 bilinear_box_make_weights ( &filter->x, scale_x );
693 bilinear_box_make_weights ( &filter->y, scale_y );
694 break;
695 }
696 }
697
698
699 void
700 yuv422_scale ( guchar *dest_buf,
701 int render_x0,
702 int render_y0,
703 int render_x1,
704 int render_y1,
705 int dest_rowstride,
706 int dest_channels,
707 gboolean dest_has_alpha,
708 const guchar *src_buf,
709 int src_width,
710 int src_height,
711 int src_rowstride,
712 int src_channels,
713 gboolean src_has_alpha,
714 double scale_x,
715 double scale_y,
716 PixopsInterpType interp_type )
717 {
718 PixopsFilter filter = { { 0, 0, 0}, { 0, 0, 0 }, 0 };
719 PixopsLineFunc line_func;
720
721 #ifdef USE_MMX
722 gboolean found_mmx = pixops_have_mmx();
723 #endif
724
725 //g_return_if_fail ( !( dest_channels == 3 && dest_has_alpha ) );
726 //g_return_if_fail ( !( src_channels == 3 && src_has_alpha ) );
727 //g_return_if_fail ( !( src_has_alpha && !dest_has_alpha ) );
728
729 if ( scale_x == 0 || scale_y == 0 )
730 return ;
731
732 if ( interp_type == PIXOPS_INTERP_NEAREST )
733 {
734 pixops_scale_nearest ( dest_buf, render_x0, render_y0, render_x1, render_y1,
735 dest_rowstride,
736 src_buf, src_width, src_height, src_rowstride,
737 scale_x, scale_y );
738 return;
739 }
740
741 filter.overall_alpha = 1.0;
742 make_weights ( &filter, interp_type, scale_x, scale_y );
743
744 if ( filter.x.n == 2 && filter.y.n == 2 )
745 {
746 #ifdef USE_MMX
747 if ( found_mmx )
748 {
749 //fprintf( stderr, "rescale: using mmx\n" );
750 line_func = scale_line_22_yuv_mmx_stub;
751 }
752 else
753 #endif
754
755 line_func = scale_line_22_yuv;
756 }
757 else
758 line_func = scale_line;
759
760 pixops_process ( dest_buf, render_x0, render_y0, render_x1, render_y1,
761 dest_rowstride, dest_channels, dest_has_alpha,
762 src_buf, src_width, src_height, src_rowstride, src_channels,
763 src_has_alpha, scale_x, scale_y, 0, 0, 0, 0, 0,
764 &filter, line_func );
765
766 g_free ( filter.x.weights );
767 g_free ( filter.y.weights );
768 }
769
my melted branch