Coverage Report

Created: 2026-06-30 11:14

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/work/workdir/UnpackedTarball/cairo/src/cairo-rectangular-scan-converter.c
Line
Count
Source
1
/* cairo - a vector graphics library with display and print output
2
 *
3
 * Copyright © 2009 Intel Corporation
4
 *
5
 * This library is free software; you can redistribute it and/or
6
 * modify it either under the terms of the GNU Lesser General Public
7
 * License version 2.1 as published by the Free Software Foundation
8
 * (the "LGPL") or, at your option, under the terms of the Mozilla
9
 * Public License Version 1.1 (the "MPL"). If you do not alter this
10
 * notice, a recipient may use your version of this file under either
11
 * the MPL or the LGPL.
12
 *
13
 * You should have received a copy of the LGPL along with this library
14
 * in the file COPYING-LGPL-2.1; if not, write to the Free Software
15
 * Foundation, Inc., 51 Franklin Street, Suite 500, Boston, MA 02110-1335, USA
16
 * You should have received a copy of the MPL along with this library
17
 * in the file COPYING-MPL-1.1
18
 *
19
 * The contents of this file are subject to the Mozilla Public License
20
 * Version 1.1 (the "License"); you may not use this file except in
21
 * compliance with the License. You may obtain a copy of the License at
22
 * http://www.mozilla.org/MPL/
23
 *
24
 * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY
25
 * OF ANY KIND, either express or implied. See the LGPL or the MPL for
26
 * the specific language governing rights and limitations.
27
 *
28
 * The Original Code is the cairo graphics library.
29
 *
30
 * Contributor(s):
31
 *  Chris Wilson <chris@chris-wilson.co.uk>
32
 */
33
34
#include "cairoint.h"
35
36
#include "cairo-combsort-inline.h"
37
#include "cairo-error-private.h"
38
#include "cairo-freelist-private.h"
39
#include "cairo-list-private.h"
40
#include "cairo-spans-private.h"
41
42
#include <setjmp.h>
43
44
typedef struct _rectangle {
45
    struct _rectangle *next, *prev;
46
    cairo_fixed_t left, right;
47
    cairo_fixed_t top, bottom;
48
    int32_t top_y, bottom_y;
49
    int dir;
50
} rectangle_t;
51
52
2.64k
#define UNROLL3(x) x x x
53
54
/* the parent is always given by index/2 */
55
254
#define PQ_PARENT_INDEX(i) ((i) >> 1)
56
1.69k
#define PQ_FIRST_ENTRY 1
57
58
/* left and right children are index * 2 and (index * 2) +1 respectively */
59
336
#define PQ_LEFT_CHILD_INDEX(i) ((i) << 1)
60
61
typedef struct _pqueue {
62
    int size, max_size;
63
64
    rectangle_t **elements;
65
    rectangle_t *elements_embedded[1024];
66
} pqueue_t;
67
68
typedef struct {
69
    rectangle_t **start;
70
    pqueue_t stop;
71
    rectangle_t head, tail;
72
    rectangle_t *insert_cursor;
73
    int32_t current_y;
74
    int32_t xmin, xmax;
75
76
    struct coverage {
77
  struct cell {
78
      struct cell *prev, *next;
79
      int x, covered, uncovered;
80
  } head, tail, *cursor;
81
  unsigned int count;
82
  cairo_freepool_t pool;
83
    } coverage;
84
85
    cairo_half_open_span_t spans_stack[CAIRO_STACK_ARRAY_LENGTH (cairo_half_open_span_t)];
86
    cairo_half_open_span_t *spans;
87
    unsigned int num_spans;
88
    unsigned int size_spans;
89
90
    jmp_buf jmpbuf;
91
} sweep_line_t;
92
93
static inline int
94
rectangle_compare_start (const rectangle_t *a,
95
       const rectangle_t *b)
96
504
{
97
504
    int cmp;
98
99
504
    cmp = a->top_y - b->top_y;
100
504
    if (cmp)
101
422
  return cmp;
102
103
82
    return a->left - b->left;
104
504
}
105
106
static inline int
107
rectangle_compare_stop (const rectangle_t *a,
108
      const rectangle_t *b)
109
418
{
110
418
    return a->bottom_y - b->bottom_y;
111
418
}
112
113
static inline void
114
pqueue_init (pqueue_t *pq)
115
86
{
116
86
    pq->max_size = ARRAY_LENGTH (pq->elements_embedded);
117
86
    pq->size = 0;
118
119
86
    pq->elements = pq->elements_embedded;
120
86
    pq->elements[PQ_FIRST_ENTRY] = NULL;
121
86
}
122
123
static inline void
124
pqueue_fini (pqueue_t *pq)
125
86
{
126
86
    if (pq->elements != pq->elements_embedded)
127
0
  free (pq->elements);
128
86
}
129
130
static cairo_bool_t
131
pqueue_grow (pqueue_t *pq)
132
0
{
133
0
    rectangle_t **new_elements;
134
0
    pq->max_size *= 2;
135
136
0
    if (pq->elements == pq->elements_embedded) {
137
0
  new_elements = _cairo_malloc_ab (pq->max_size,
138
0
           sizeof (rectangle_t *));
139
0
  if (unlikely (new_elements == NULL))
140
0
      return FALSE;
141
142
0
  memcpy (new_elements, pq->elements_embedded,
143
0
    sizeof (pq->elements_embedded));
144
0
    } else {
145
0
  new_elements = _cairo_realloc_ab (pq->elements,
146
0
            pq->max_size,
147
0
            sizeof (rectangle_t *));
148
0
  if (unlikely (new_elements == NULL))
149
0
      return FALSE;
150
0
    }
151
152
0
    pq->elements = new_elements;
153
0
    return TRUE;
154
0
}
155
156
static inline void
157
pqueue_push (sweep_line_t *sweep, rectangle_t *rectangle)
158
340
{
159
340
    rectangle_t **elements;
160
340
    int i, parent;
161
162
340
    if (unlikely (sweep->stop.size + 1 == sweep->stop.max_size)) {
163
0
  if (unlikely (! pqueue_grow (&sweep->stop)))
164
0
      longjmp (sweep->jmpbuf,
165
0
         _cairo_error (CAIRO_STATUS_NO_MEMORY));
166
0
    }
167
168
340
    elements = sweep->stop.elements;
169
340
    for (i = ++sweep->stop.size;
170
340
   i != PQ_FIRST_ENTRY &&
171
254
   rectangle_compare_stop (rectangle,
172
254
         elements[parent = PQ_PARENT_INDEX (i)]) < 0;
173
340
   i = parent)
174
0
    {
175
0
  elements[i] = elements[parent];
176
0
    }
177
178
340
    elements[i] = rectangle;
179
340
}
180
181
static inline void
182
pqueue_pop (pqueue_t *pq)
183
336
{
184
336
    rectangle_t **elements = pq->elements;
185
336
    rectangle_t *tail;
186
336
    int child, i;
187
188
336
    tail = elements[pq->size--];
189
336
    if (pq->size == 0) {
190
82
  elements[PQ_FIRST_ENTRY] = NULL;
191
82
  return;
192
82
    }
193
194
254
    for (i = PQ_FIRST_ENTRY;
195
336
   (child = PQ_LEFT_CHILD_INDEX (i)) <= pq->size;
196
254
   i = child)
197
164
    {
198
164
  if (child != pq->size &&
199
0
      rectangle_compare_stop (elements[child+1],
200
0
            elements[child]) < 0)
201
0
  {
202
0
      child++;
203
0
  }
204
205
164
  if (rectangle_compare_stop (elements[child], tail) >= 0)
206
82
      break;
207
208
82
  elements[i] = elements[child];
209
82
    }
210
254
    elements[i] = tail;
211
254
}
212
213
static inline rectangle_t *
214
peek_stop (sweep_line_t *sweep)
215
594
{
216
594
    return sweep->stop.elements[PQ_FIRST_ENTRY];
217
594
}
218
219
CAIRO_COMBSORT_DECLARE (rectangle_sort, rectangle_t *, rectangle_compare_start)
220
221
static void
222
sweep_line_init (sweep_line_t *sweep)
223
86
{
224
86
    sweep->head.left = INT_MIN;
225
86
    sweep->head.next = &sweep->tail;
226
86
    sweep->tail.left = INT_MAX;
227
86
    sweep->tail.prev = &sweep->head;
228
86
    sweep->insert_cursor = &sweep->tail;
229
230
86
    _cairo_freepool_init (&sweep->coverage.pool, sizeof (struct cell));
231
232
86
    sweep->spans = sweep->spans_stack;
233
86
    sweep->size_spans = ARRAY_LENGTH (sweep->spans_stack);
234
235
86
    sweep->coverage.head.prev = NULL;
236
86
    sweep->coverage.head.x = INT_MIN;
237
86
    sweep->coverage.tail.next = NULL;
238
86
    sweep->coverage.tail.x = INT_MAX;
239
240
86
    pqueue_init (&sweep->stop);
241
86
}
242
243
static void
244
sweep_line_fini (sweep_line_t *sweep)
245
86
{
246
86
    _cairo_freepool_fini (&sweep->coverage.pool);
247
86
    pqueue_fini (&sweep->stop);
248
249
86
    if (sweep->spans != sweep->spans_stack)
250
0
  free (sweep->spans);
251
86
}
252
253
static inline void
254
add_cell (sweep_line_t *sweep, int x, int covered, int uncovered)
255
1.38k
{
256
1.38k
    struct cell *cell;
257
258
1.38k
    cell = sweep->coverage.cursor;
259
1.38k
    if (cell->x > x) {
260
606
  do {
261
606
      UNROLL3({
262
242
    if (cell->prev->x < x)
263
242
        break;
264
242
    cell = cell->prev;
265
242
      })
266
242
  } while (TRUE);
267
778
    } else {
268
778
  if (cell->x == x)
269
78
      goto found;
270
271
700
  do {
272
700
      UNROLL3({
273
82
    cell = cell->next;
274
82
    if (cell->x >= x)
275
82
        break;
276
82
      })
277
82
  } while (TRUE);
278
700
    }
279
280
1.30k
    if (x != cell->x) {
281
900
  struct cell *c;
282
283
900
  sweep->coverage.count++;
284
285
900
  c = _cairo_freepool_alloc (&sweep->coverage.pool);
286
900
  if (unlikely (c == NULL)) {
287
0
      longjmp (sweep->jmpbuf,
288
0
         _cairo_error (CAIRO_STATUS_NO_MEMORY));
289
0
  }
290
291
900
  cell->prev->next = c;
292
900
  c->prev = cell->prev;
293
900
  c->next = cell;
294
900
  cell->prev = c;
295
296
900
  c->x = x;
297
900
  c->covered = 0;
298
900
  c->uncovered = 0;
299
300
900
  cell = c;
301
900
    }
302
303
1.38k
found:
304
1.38k
    cell->covered += covered;
305
1.38k
    cell->uncovered += uncovered;
306
1.38k
    sweep->coverage.cursor = cell;
307
1.38k
}
308
309
static inline void
310
_active_edges_to_spans (sweep_line_t  *sweep)
311
352
{
312
352
    int32_t y = sweep->current_y;
313
352
    rectangle_t *rectangle;
314
352
    int coverage, prev_coverage;
315
352
    int prev_x;
316
352
    struct cell *cell;
317
318
352
    sweep->num_spans = 0;
319
352
    if (sweep->head.next == &sweep->tail)
320
0
  return;
321
322
352
    sweep->coverage.head.next = &sweep->coverage.tail;
323
352
    sweep->coverage.tail.prev = &sweep->coverage.head;
324
352
    sweep->coverage.cursor = &sweep->coverage.tail;
325
352
    sweep->coverage.count = 0;
326
327
    /* XXX cell coverage only changes when a rectangle appears or
328
     * disappears. Try only modifying coverage at such times.
329
     */
330
352
    for (rectangle = sweep->head.next;
331
1.04k
   rectangle != &sweep->tail;
332
692
   rectangle = rectangle->next)
333
692
    {
334
692
  int height;
335
692
  int frac, i;
336
337
692
  if (y == rectangle->bottom_y) {
338
336
      height = rectangle->bottom & CAIRO_FIXED_FRAC_MASK;
339
336
      if (height == 0)
340
0
    continue;
341
336
  } else
342
356
      height = CAIRO_FIXED_ONE;
343
692
  if (y == rectangle->top_y)
344
340
      height -= rectangle->top & CAIRO_FIXED_FRAC_MASK;
345
692
  height *= rectangle->dir;
346
347
692
  i = _cairo_fixed_integer_part (rectangle->left),
348
692
  frac = _cairo_fixed_fractional_part (rectangle->left);
349
692
  add_cell (sweep, i,
350
692
      (CAIRO_FIXED_ONE-frac) * height,
351
692
      frac * height);
352
353
692
  i = _cairo_fixed_integer_part (rectangle->right),
354
692
  frac = _cairo_fixed_fractional_part (rectangle->right);
355
692
  add_cell (sweep, i,
356
692
      -(CAIRO_FIXED_ONE-frac) * height,
357
692
      -frac * height);
358
692
    }
359
360
352
    if (2*sweep->coverage.count >= sweep->size_spans) {
361
0
  unsigned size;
362
363
0
  size = sweep->size_spans;
364
0
  while (size <= 2*sweep->coverage.count)
365
0
      size <<= 1;
366
367
0
  if (sweep->spans != sweep->spans_stack)
368
0
      free (sweep->spans);
369
370
0
  sweep->spans = _cairo_malloc_ab (size, sizeof (cairo_half_open_span_t));
371
0
  if (unlikely (sweep->spans == NULL))
372
0
      longjmp (sweep->jmpbuf, _cairo_error (CAIRO_STATUS_NO_MEMORY));
373
374
0
  sweep->size_spans = size;
375
0
    }
376
377
352
    prev_coverage = coverage = 0;
378
352
    prev_x = INT_MIN;
379
1.25k
    for (cell = sweep->coverage.head.next; cell != &sweep->coverage.tail; cell = cell->next) {
380
900
  if (cell->x != prev_x && coverage != prev_coverage) {
381
188
      int n = sweep->num_spans++;
382
188
      int c = coverage >> (CAIRO_FIXED_FRAC_BITS * 2 - 8);
383
188
      sweep->spans[n].x = prev_x;
384
188
      sweep->spans[n].inverse = 0;
385
188
      sweep->spans[n].coverage = c - (c >> 8);
386
188
      prev_coverage = coverage;
387
188
  }
388
389
900
  coverage += cell->covered;
390
900
  if (coverage != prev_coverage) {
391
900
      int n = sweep->num_spans++;
392
900
      int c = coverage >> (CAIRO_FIXED_FRAC_BITS * 2 - 8);
393
900
      sweep->spans[n].x = cell->x;
394
900
      sweep->spans[n].inverse = 0;
395
900
      sweep->spans[n].coverage = c - (c >> 8);
396
900
      prev_coverage = coverage;
397
900
  }
398
900
  coverage += cell->uncovered;
399
900
  prev_x = cell->x + 1;
400
900
    }
401
352
    _cairo_freepool_reset (&sweep->coverage.pool);
402
403
352
    if (sweep->num_spans) {
404
352
  if (prev_x <= sweep->xmax) {
405
336
      int n = sweep->num_spans++;
406
336
      int c = coverage >> (CAIRO_FIXED_FRAC_BITS * 2 - 8);
407
336
      sweep->spans[n].x = prev_x;
408
336
      sweep->spans[n].inverse = 0;
409
336
      sweep->spans[n].coverage = c - (c >> 8);
410
336
  }
411
412
352
  if (coverage && prev_x < sweep->xmax) {
413
0
      int n = sweep->num_spans++;
414
0
      sweep->spans[n].x = sweep->xmax;
415
0
      sweep->spans[n].inverse = 1;
416
0
      sweep->spans[n].coverage = 0;
417
0
  }
418
352
    }
419
352
}
420
421
static inline void
422
sweep_line_delete (sweep_line_t *sweep,
423
           rectangle_t  *rectangle)
424
336
{
425
336
    if (sweep->insert_cursor == rectangle)
426
82
  sweep->insert_cursor = rectangle->next;
427
428
336
    rectangle->prev->next = rectangle->next;
429
336
    rectangle->next->prev = rectangle->prev;
430
431
336
    pqueue_pop (&sweep->stop);
432
336
}
433
434
static inline void
435
sweep_line_insert (sweep_line_t *sweep,
436
       rectangle_t  *rectangle)
437
340
{
438
340
    rectangle_t *pos;
439
440
340
    pos = sweep->insert_cursor;
441
340
    if (pos->left != rectangle->left) {
442
258
  if (pos->left > rectangle->left) {
443
172
      do {
444
172
    UNROLL3({
445
82
        if (pos->prev->left < rectangle->left)
446
82
      break;
447
82
        pos = pos->prev;
448
82
    })
449
82
      } while (TRUE);
450
172
  } else {
451
86
      do {
452
86
    UNROLL3({
453
82
        pos = pos->next;
454
82
        if (pos->left >= rectangle->left)
455
82
      break;
456
82
    });
457
0
      } while (TRUE);
458
86
  }
459
258
    }
460
461
340
    pos->prev->next = rectangle;
462
340
    rectangle->prev = pos->prev;
463
340
    rectangle->next = pos;
464
340
    pos->prev = rectangle;
465
340
    sweep->insert_cursor = rectangle;
466
467
340
    pqueue_push (sweep, rectangle);
468
340
}
469
470
static void
471
render_rows (sweep_line_t *sweep_line,
472
       cairo_span_renderer_t *renderer,
473
       int height)
474
352
{
475
352
    cairo_status_t status;
476
477
352
    _active_edges_to_spans (sweep_line);
478
479
352
    status = renderer->render_rows (renderer,
480
352
            sweep_line->current_y, height,
481
352
            sweep_line->spans,
482
352
            sweep_line->num_spans);
483
352
    if (unlikely (status))
484
0
  longjmp (sweep_line->jmpbuf, status);
485
352
}
486
487
static cairo_status_t
488
generate (cairo_rectangular_scan_converter_t *self,
489
    cairo_span_renderer_t *renderer,
490
    rectangle_t **rectangles)
491
86
{
492
86
    sweep_line_t sweep_line;
493
86
    rectangle_t *start, *stop;
494
86
    cairo_status_t status;
495
496
86
    sweep_line_init (&sweep_line);
497
86
    sweep_line.xmin = _cairo_fixed_integer_part (self->extents.p1.x);
498
86
    sweep_line.xmax = _cairo_fixed_integer_part (self->extents.p2.x);
499
86
    sweep_line.start = rectangles;
500
86
    if ((status = setjmp (sweep_line.jmpbuf)))
501
0
  goto out;
502
503
86
    sweep_line.current_y = _cairo_fixed_integer_part (self->extents.p1.y);
504
86
    start = *sweep_line.start++;
505
258
    do {
506
258
  if (start->top_y != sweep_line.current_y) {
507
8
      render_rows (&sweep_line, renderer,
508
8
       start->top_y - sweep_line.current_y);
509
8
      sweep_line.current_y = start->top_y;
510
8
  }
511
512
340
  do {
513
340
      sweep_line_insert (&sweep_line, start);
514
340
      start = *sweep_line.start++;
515
340
      if (start == NULL)
516
86
    goto end;
517
254
      if (start->top_y != sweep_line.current_y)
518
172
    break;
519
254
  } while (TRUE);
520
521
172
  render_rows (&sweep_line, renderer, 1);
522
523
172
  stop = peek_stop (&sweep_line);
524
258
  while (stop->bottom_y == sweep_line.current_y) {
525
86
      sweep_line_delete (&sweep_line, stop);
526
86
      stop = peek_stop (&sweep_line);
527
86
      if (stop == NULL)
528
0
    break;
529
86
  }
530
531
172
  sweep_line.current_y++;
532
533
172
  while (stop != NULL && stop->bottom_y < start->top_y) {
534
0
      if (stop->bottom_y != sweep_line.current_y) {
535
0
    render_rows (&sweep_line, renderer,
536
0
           stop->bottom_y - sweep_line.current_y);
537
0
    sweep_line.current_y = stop->bottom_y;
538
0
      }
539
540
0
      render_rows (&sweep_line, renderer, 1);
541
542
0
      do {
543
0
    sweep_line_delete (&sweep_line, stop);
544
0
    stop = peek_stop (&sweep_line);
545
0
      } while (stop != NULL && stop->bottom_y == sweep_line.current_y);
546
547
0
      sweep_line.current_y++;
548
0
  }
549
172
    } while (TRUE);
550
551
86
  end:
552
86
    render_rows (&sweep_line, renderer, 1);
553
554
86
    stop = peek_stop (&sweep_line);
555
254
    while (stop->bottom_y == sweep_line.current_y) {
556
168
  sweep_line_delete (&sweep_line, stop);
557
168
  stop = peek_stop (&sweep_line);
558
168
  if (stop == NULL)
559
0
      goto out;
560
168
    }
561
562
86
    while (++sweep_line.current_y < _cairo_fixed_integer_part (self->extents.p2.y)) {
563
82
  if (stop->bottom_y != sweep_line.current_y) {
564
4
      render_rows (&sweep_line, renderer,
565
4
       stop->bottom_y - sweep_line.current_y);
566
4
      sweep_line.current_y = stop->bottom_y;
567
4
  }
568
569
82
  render_rows (&sweep_line, renderer, 1);
570
571
82
  do {
572
82
      sweep_line_delete (&sweep_line, stop);
573
82
      stop = peek_stop (&sweep_line);
574
82
      if (stop == NULL)
575
82
    goto out;
576
82
  } while (stop->bottom_y == sweep_line.current_y);
577
578
82
    }
579
580
86
  out:
581
86
    sweep_line_fini (&sweep_line);
582
583
86
    return status;
584
86
}
585
static void generate_row(cairo_span_renderer_t *renderer,
586
       const rectangle_t *r,
587
       int y, int h,
588
       uint16_t coverage)
589
984
{
590
984
    cairo_half_open_span_t spans[4];
591
984
    unsigned int num_spans = 0;
592
984
    int x1 = _cairo_fixed_integer_part (r->left);
593
984
    int x2 = _cairo_fixed_integer_part (r->right);
594
984
    if (x2 > x1) {
595
984
  if (! _cairo_fixed_is_integer (r->left)) {
596
984
      spans[num_spans].x = x1;
597
984
      spans[num_spans].coverage =
598
984
    coverage * (256 - _cairo_fixed_fractional_part (r->left)) >> 8;
599
984
      num_spans++;
600
984
      x1++;
601
984
  }
602
603
984
  if (x2 > x1) {
604
900
      spans[num_spans].x = x1;
605
900
      spans[num_spans].coverage = coverage - (coverage >> 8);
606
900
      num_spans++;
607
900
  }
608
609
984
  if (! _cairo_fixed_is_integer (r->right)) {
610
136
      spans[num_spans].x = x2++;
611
136
      spans[num_spans].coverage =
612
136
    coverage * _cairo_fixed_fractional_part (r->right) >> 8;
613
136
      num_spans++;
614
136
  }
615
984
    } else {
616
0
  spans[num_spans].x = x2++;
617
0
  spans[num_spans].coverage = coverage * (r->right - r->left) >> 8;
618
0
  num_spans++;
619
0
    }
620
621
984
    spans[num_spans].x = x2;
622
984
    spans[num_spans].coverage = 0;
623
984
    num_spans++;
624
625
984
    renderer->render_rows (renderer, y, h, spans, num_spans);
626
984
}
627
628
static cairo_status_t
629
generate_box (cairo_rectangular_scan_converter_t *self,
630
        cairo_span_renderer_t *renderer)
631
366
{
632
366
    const rectangle_t *r = self->chunks.base;
633
366
    int y1 = _cairo_fixed_integer_part (r->top);
634
366
    int y2 = _cairo_fixed_integer_part (r->bottom);
635
366
    if (y2 > y1) {
636
366
  if (! _cairo_fixed_is_integer (r->top)) {
637
366
      generate_row(renderer, r, y1, 1,
638
366
       256 - _cairo_fixed_fractional_part (r->top));
639
366
      y1++;
640
366
  }
641
642
366
  if (y2 > y1)
643
358
      generate_row(renderer, r, y1, y2-y1, 256);
644
645
366
  if (! _cairo_fixed_is_integer (r->bottom))
646
260
      generate_row(renderer, r, y2, 1,
647
260
       _cairo_fixed_fractional_part (r->bottom));
648
366
    } else
649
0
  generate_row(renderer, r, y1, 1, r->bottom - r->top);
650
651
366
    return CAIRO_STATUS_SUCCESS;
652
366
}
653
654
static cairo_status_t
655
_cairo_rectangular_scan_converter_generate (void      *converter,
656
              cairo_span_renderer_t *renderer)
657
452
{
658
452
    cairo_rectangular_scan_converter_t *self = converter;
659
452
    rectangle_t *rectangles_stack[CAIRO_STACK_ARRAY_LENGTH (rectangle_t *)];
660
452
    rectangle_t **rectangles;
661
452
    struct _cairo_rectangular_scan_converter_chunk *chunk;
662
452
    cairo_status_t status;
663
452
    int i, j;
664
665
452
    if (unlikely (self->num_rectangles == 0)) {
666
0
  return renderer->render_rows (renderer,
667
0
              _cairo_fixed_integer_part (self->extents.p1.y),
668
0
              _cairo_fixed_integer_part (self->extents.p2.y - self->extents.p1.y),
669
0
              NULL, 0);
670
0
    }
671
672
452
    if (self->num_rectangles == 1)
673
366
  return generate_box (self, renderer);
674
675
86
    rectangles = rectangles_stack;
676
86
    if (unlikely (self->num_rectangles >= ARRAY_LENGTH (rectangles_stack))) {
677
0
  rectangles = _cairo_malloc_ab (self->num_rectangles + 1,
678
0
               sizeof (rectangle_t *));
679
0
  if (unlikely (rectangles == NULL))
680
0
      return _cairo_error (CAIRO_STATUS_NO_MEMORY);
681
0
    }
682
683
86
    j = 0;
684
172
    for (chunk = &self->chunks; chunk != NULL; chunk = chunk->next) {
685
86
  rectangle_t *rectangle;
686
687
86
  rectangle = chunk->base;
688
426
  for (i = 0; i < chunk->count; i++)
689
340
      rectangles[j++] = &rectangle[i];
690
86
    }
691
86
    rectangle_sort (rectangles, j);
692
86
    rectangles[j] = NULL;
693
694
86
    status = generate (self, renderer, rectangles);
695
696
86
    if (rectangles != rectangles_stack)
697
0
  free (rectangles);
698
699
86
    return status;
700
86
}
701
702
static rectangle_t *
703
_allocate_rectangle (cairo_rectangular_scan_converter_t *self)
704
706
{
705
706
    rectangle_t *rectangle;
706
706
    struct _cairo_rectangular_scan_converter_chunk *chunk;
707
708
706
    chunk = self->tail;
709
706
    if (chunk->count == chunk->size) {
710
0
  int size;
711
712
0
  size = chunk->size * 2;
713
0
  chunk->next = _cairo_malloc_ab_plus_c (size,
714
0
                 sizeof (rectangle_t),
715
0
                 sizeof (struct _cairo_rectangular_scan_converter_chunk));
716
717
0
  if (unlikely (chunk->next == NULL))
718
0
      return NULL;
719
720
0
  chunk = chunk->next;
721
0
  chunk->next = NULL;
722
0
  chunk->count = 0;
723
0
  chunk->size = size;
724
0
  chunk->base = chunk + 1;
725
0
  self->tail = chunk;
726
0
    }
727
728
706
    rectangle = chunk->base;
729
706
    return rectangle + chunk->count++;
730
706
}
731
732
cairo_status_t
733
_cairo_rectangular_scan_converter_add_box (cairo_rectangular_scan_converter_t *self,
734
             const cairo_box_t *box,
735
             int dir)
736
706
{
737
706
    rectangle_t *rectangle;
738
739
706
    rectangle = _allocate_rectangle (self);
740
706
    if (unlikely (rectangle == NULL))
741
0
  return _cairo_error (CAIRO_STATUS_NO_MEMORY);
742
743
706
    rectangle->dir = dir;
744
706
    rectangle->left  = MAX (box->p1.x, self->extents.p1.x);
745
706
    rectangle->right = MIN (box->p2.x, self->extents.p2.x);
746
706
    if (unlikely (rectangle->right <= rectangle->left)) {
747
0
  self->tail->count--;
748
0
  return CAIRO_STATUS_SUCCESS;
749
0
    }
750
751
706
    rectangle->top = MAX (box->p1.y, self->extents.p1.y);
752
706
    rectangle->top_y  = _cairo_fixed_integer_floor (rectangle->top);
753
706
    rectangle->bottom = MIN (box->p2.y, self->extents.p2.y);
754
706
    rectangle->bottom_y = _cairo_fixed_integer_floor (rectangle->bottom);
755
706
    if (likely (rectangle->bottom > rectangle->top))
756
706
  self->num_rectangles++;
757
0
    else
758
0
  self->tail->count--;
759
760
706
    return CAIRO_STATUS_SUCCESS;
761
706
}
762
763
static void
764
_cairo_rectangular_scan_converter_destroy (void *converter)
765
452
{
766
452
    cairo_rectangular_scan_converter_t *self = converter;
767
452
    struct _cairo_rectangular_scan_converter_chunk *chunk, *next;
768
769
452
    for (chunk = self->chunks.next; chunk != NULL; chunk = next) {
770
0
  next = chunk->next;
771
0
  free (chunk);
772
0
    }
773
452
}
774
775
void
776
_cairo_rectangular_scan_converter_init (cairo_rectangular_scan_converter_t *self,
777
          const cairo_rectangle_int_t *extents)
778
452
{
779
452
    self->base.destroy = _cairo_rectangular_scan_converter_destroy;
780
452
    self->base.generate = _cairo_rectangular_scan_converter_generate;
781
782
452
    _cairo_box_from_rectangle (&self->extents, extents);
783
784
452
    self->chunks.base = self->buf;
785
452
    self->chunks.next = NULL;
786
452
    self->chunks.count = 0;
787
452
    self->chunks.size = sizeof (self->buf) / sizeof (rectangle_t);
788
452
    self->tail = &self->chunks;
789
790
452
    self->num_rectangles = 0;
791
452
}