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Comparing rxvt-unicode/src/background.C (file contents):
Revision 1.27 by ayin, Sun Jan 27 22:48:33 2008 UTC vs.
Revision 1.108 by sf-exg, Mon Nov 1 14:58:44 2010 UTC

1/*----------------------------------------------------------------------* 1/*----------------------------------------------------------------------*
2 * File: background.C - former xpm.C 2 * File: background.C - former xpm.C
3 *----------------------------------------------------------------------* 3 *----------------------------------------------------------------------*
4 * 4 *
5 * All portions of code are copyright by their respective author/s. 5 * All portions of code are copyright by their respective author/s.
6 * Copyright (c) 2005-2006 Marc Lehmann <pcg@goof.com> 6 * Copyright (c) 2005-2008 Marc Lehmann <pcg@goof.com>
7 * Copyright (c) 2007 Sasha Vasko <sasha@aftercode.net> 7 * Copyright (c) 2007 Sasha Vasko <sasha@aftercode.net>
8 * Copyright (c) 2010 Emanuele Giaquinta <e.giaquinta@glauco.it>
8 * 9 *
9 * This program is free software; you can redistribute it and/or modify 10 * This program is free software; you can redistribute it and/or modify
10 * it under the terms of the GNU General Public License as published by 11 * it under the terms of the GNU General Public License as published by
11 * the Free Software Foundation; either version 2 of the License, or 12 * the Free Software Foundation; either version 2 of the License, or
12 * (at your option) any later version. 13 * (at your option) any later version.
19 * You should have received a copy of the GNU General Public License 20 * You should have received a copy of the GNU General Public License
20 * along with this program; if not, write to the Free Software 21 * along with this program; if not, write to the Free Software
21 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. 22 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
22 *---------------------------------------------------------------------*/ 23 *---------------------------------------------------------------------*/
23 24
25#include <cmath>
24#include "../config.h" /* NECESSARY */ 26#include "../config.h" /* NECESSARY */
25#include "rxvt.h" /* NECESSARY */ 27#include "rxvt.h" /* NECESSARY */
26 28
27#define DO_TIMING_TEST 0 29#define DO_TIMING_TEST 0
28 30
29#if DO_TIMING_TEST 31#if DO_TIMING_TEST
30# include <sys/time.h> 32# include <sys/time.h>
31#define TIMING_TEST_START(id) \ 33#define TIMING_TEST_START(id) \
32 struct timeval timing_test_##id##_stv;\ 34 struct timeval timing_test_##id##_stv; \
33 gettimeofday (&timing_test_##id##_stv, NULL); 35 gettimeofday (&timing_test_##id##_stv, NULL);
34 36
35#define TIMING_TEST_PRINT_RESULT(id) \ 37#define TIMING_TEST_PRINT_RESULT(id) \
36 do{ struct timeval tv;gettimeofday (&tv, NULL); tv.tv_sec -= (timing_test_##id##_stv).tv_sec;\ 38 do { \
39 struct timeval tv; \
40 gettimeofday (&tv, NULL); \
41 tv.tv_sec -= (timing_test_##id##_stv).tv_sec; \
37 fprintf (stderr, "%s: %s: %d: elapsed %ld usec\n", #id, __FILE__, __LINE__,\ 42 fprintf (stderr, "%s: %s: %d: elapsed %ld usec\n", #id, __FILE__, __LINE__, \
38 tv.tv_sec * 1000000 + tv.tv_usec - (timing_test_##id##_stv).tv_usec);}while (0) 43 tv.tv_sec * 1000000 + tv.tv_usec - (timing_test_##id##_stv).tv_usec); \
44 } while (0)
39 45
40#else 46#else
41#define TIMING_TEST_START(id) do{}while (0) 47#define TIMING_TEST_START(id) do {} while (0)
42#define TIMING_TEST_PRINT_RESULT(id) do{}while (0) 48#define TIMING_TEST_PRINT_RESULT(id) do {} while (0)
43#endif 49#endif
44 50
45/* 51/*
46 * Pixmap geometry string interpretation : 52 * Pixmap geometry string interpretation :
47 * Each geometry string contains zero or one scale/position 53 * Each geometry string contains zero or one scale/position
48 * adjustment and may optionally be followed by a colon and one or more 54 * adjustment and may optionally be followed by a colon and one or more
49 * colon-delimited pixmap operations. 55 * colon-delimited pixmap operations.
50 * The following table shows the valid geometry strings and their 56 * The following table shows the valid geometry strings and their
51 * affects on the background image : 57 * effects on the background image :
52 * 58 *
53 * WxH+X+Y Set scaling to W% by H%, and position to X% by Y%. 59 * WxH+X+Y Set scaling to W% by H%, and position to X% by Y%.
54 * W and H are percentages of the terminal window size. 60 * W and H are percentages of the terminal window size.
55 * X and Y are also percentages; e.g., +50+50 centers 61 * X and Y are also percentages; e.g., +50+50 centers
56 * the image in the window. 62 * the image in the window.
57 * WxH+X Assumes Y == X 63 * WxH+X Assumes Y == X
58 * WxH Assumes Y == X == 50 (centers the image) 64 * WxH Assumes Y == X == 50 (centers the image)
59 * W+X+Y Assumes H == W 65 * W+X+Y Assumes H == W
60 * W+X Assumes H == W and Y == X 66 * W+X Assumes H == W and Y == X
61 * W Assumes H == W and Y == X == 50 67 * W Assumes H == W and Y == X == 50
62 * 68 *
63 * Adjusting position only : 69 * Adjusting position only :
64 * =+X+Y Set position to X% by Y% (absolute). 70 * =+X+Y Set position to X% by Y% (absolute).
65 * =+X Set position to X% by X%. 71 * =+X Set position to X% by X%.
66 * +X+Y Adjust position horizontally X% and vertically Y% 72 * +X+Y Adjust position horizontally X% and vertically Y%
67 * from current position (relative). 73 * from current position (relative).
68 * +X Adjust position horizontally X% and vertically X% 74 * +X Adjust position horizontally X% and vertically X%
69 * from current position. 75 * from current position.
70 * 76 *
71 * Adjusting scale only : 77 * Adjusting scale only :
72 * Wx0 Multiply horizontal scaling factor by W% 78 * Wx0 Multiply horizontal scaling factor by W%
73 * 0xH Multiply vertical scaling factor by H% 79 * 0xH Multiply vertical scaling factor by H%
74 * 0x0 No scaling (show image at normal size). 80 * 0x0 No scaling (show image at normal size).
75 * 81 *
76 * Pixmap Operations : (should be prepended by a colon) 82 * Pixmap Operations : (should be prepended by a colon)
77 * tile Tile image. Scaling/position modifiers above will affect 83 * tile Tile image. Scaling/position modifiers above will affect
78 * the tile size and origin. 84 * the tile size and origin.
79 * propscale When scaling, scale proportionally. That is, maintain the 85 * propscale When scaling, scale proportionally. That is, maintain the
80 * proper aspect ratio for the image. Any portion of the 86 * proper aspect ratio for the image. Any portion of the
81 * background not covered by the image is filled with the 87 * background not covered by the image is filled with the
82 * current background color. 88 * current background color.
83 * hscale Scale horizontally, tile vertically ? 89 * hscale Scale horizontally, tile vertically ?
84 * vscale Tile horizontally, scale vertically ? 90 * vscale Tile horizontally, scale vertically ?
92 // this is basically redundant as bgPixmap_t is only used in 98 // this is basically redundant as bgPixmap_t is only used in
93 // zero_initialised-derived structs 99 // zero_initialised-derived structs
94#ifdef HAVE_AFTERIMAGE 100#ifdef HAVE_AFTERIMAGE
95 original_asim = NULL; 101 original_asim = NULL;
96#endif 102#endif
103#ifdef HAVE_PIXBUF
104 pixbuf = NULL;
105#endif
97#ifdef BG_IMAGE_FROM_FILE 106#ifdef BG_IMAGE_FROM_FILE
107 have_image = false;
98 h_scale = v_scale = 0; 108 h_scale = v_scale = 0;
99 h_align = v_align = 0; 109 h_align = v_align = 0;
110#endif
111#ifdef ENABLE_TRANSPARENCY
112 shade = 100;
100#endif 113#endif
101 flags = 0; 114 flags = 0;
102 pixmap = None; 115 pixmap = None;
103 valid_since = invalid_since = 0; 116 valid_since = invalid_since = 0;
104 target = 0; 117 target = 0;
110#ifdef HAVE_AFTERIMAGE 123#ifdef HAVE_AFTERIMAGE
111 if (original_asim) 124 if (original_asim)
112 safe_asimage_destroy (original_asim); 125 safe_asimage_destroy (original_asim);
113#endif 126#endif
114 127
128#ifdef HAVE_PIXBUF
129 if (pixbuf)
130 g_object_unref (pixbuf);
131#endif
132
115 if (pixmap && target) 133 if (pixmap && target)
116 XFreePixmap (target->dpy, pixmap); 134 XFreePixmap (target->dpy, pixmap);
117} 135}
118 136
119bool 137bool
123 if (flags & isTransparent) 141 if (flags & isTransparent)
124 return true; 142 return true;
125# endif 143# endif
126 144
127# ifdef BG_IMAGE_FROM_FILE 145# ifdef BG_IMAGE_FROM_FILE
128# ifdef HAVE_AFTERIMAGE 146 if (have_image)
129 if (original_asim)
130# endif
131 { 147 {
132 if (h_scale != 0 || v_scale != 0 148 if (flags & sizeSensitive)
133 || h_align != 0 || v_align != 0)
134 return true; 149 return true;
135 } 150 }
136# endif 151# endif
137 152
138 return false; 153 return false;
139} 154}
140 155
141bool 156bool
142bgPixmap_t::window_position_sensitive () 157bgPixmap_t::window_position_sensitive ()
143{ 158{
144# ifdef ENABLE_TRANSPARENCY 159# ifdef ENABLE_TRANSPARENCY
145 if (flags & isTransparent) 160 if (flags & isTransparent)
146 return true; 161 return true;
147# endif 162# endif
148 163
149# ifdef BG_IMAGE_FROM_FILE 164# ifdef BG_IMAGE_FROM_FILE
150# ifdef HAVE_AFTERIMAGE 165 if (have_image)
151 if (original_asim)
152# endif
153 { 166 {
154 if (h_align == rootAlign || v_align == rootAlign) 167 if (flags & rootAlign)
155 return true; 168 return true;
156 } 169 }
157# endif 170# endif
158 171
159 return false; 172 return false;
163{ 176{
164# ifdef HAVE_AFTERIMAGE 177# ifdef HAVE_AFTERIMAGE
165 if (original_asim) 178 if (original_asim)
166 return true; 179 return true;
167# endif 180# endif
168# ifdef ENABLE_TRANSPARENCY
169 if (flags & isTransparent)
170 {
171# ifdef HAVE_AFTERIMAGE // can't blur without libAI anyways
172 if ((flags & blurNeeded) && !(flags & blurServerSide))
173 return true;
174# endif
175 if ((flags & tintNeeded) && !(flags & tintServerSide))
176 return true;
177 }
178# endif
179 return false; 181 return false;
180} 182}
181 183
182# ifdef BG_IMAGE_FROM_FILE 184# ifdef BG_IMAGE_FROM_FILE
183static inline bool 185static inline bool
199static inline bool 201static inline bool
200check_set_align_value (int geom_flags, int flag, int &align, int new_value) 202check_set_align_value (int geom_flags, int flag, int &align, int new_value)
201{ 203{
202 if (geom_flags & flag) 204 if (geom_flags & flag)
203 { 205 {
204 if (new_value != bgPixmap_t::rootAlign)
205 {
206 if (new_value < -100) 206 if (new_value < -100)
207 new_value = -100; 207 new_value = -100;
208 else if (new_value > 200) 208 else if (new_value > 200)
209 new_value = 200; 209 new_value = 200;
210 }
211 if (new_value != align) 210 if (new_value != align)
212 { 211 {
213 align = new_value; 212 align = new_value;
214 return true; 213 return true;
215 } 214 }
219 218
220static inline int 219static inline int
221make_align_position (int align, int window_size, int image_size) 220make_align_position (int align, int window_size, int image_size)
222{ 221{
223 int diff = window_size - image_size; 222 int diff = window_size - image_size;
224 int smaller = MIN (image_size,window_size); 223 int smaller = min (image_size, window_size);
225 224
226 if (align >= 0 && align <= 50) 225 if (align >= 0 && align <= 100)
227 return diff * align / 100; 226 return diff * align / 100;
228 else if (align > 50 && align <= 100)
229 return window_size - image_size - diff * (100 - align) / 100;
230 else if (align > 100 && align <= 200 ) 227 else if (align > 100 && align <= 200)
231 return ((align - 100) * smaller / 100) + window_size - smaller; 228 return ((align - 100) * smaller / 100) + window_size - smaller;
232 else if (align > -100 && align < 0) 229 else if (align >= -100 && align < 0)
233 return ((align + 100) * smaller / 100) - image_size; 230 return ((align + 100) * smaller / 100) - image_size;
234 return 0; 231 return 0;
235} 232}
236 233
237static inline int 234static inline int
238make_clip_rectangle (int pos, int size, int target_size, int &dst_pos, int &dst_size) 235make_clip_rectangle (int pos, int size, int target_size, int &dst_pos, int &dst_size)
239{ 236{
240 int src_pos = 0; 237 int src_pos = 0;
241 dst_pos = 0; 238 dst_pos = pos;
242 dst_size = size; 239 dst_size = size;
243 if (pos < 0 && size > target_size) 240 if (pos < 0)
244 { 241 {
245 src_pos = -pos; 242 src_pos = -pos;
243 dst_pos = 0;
246 dst_size += pos; 244 dst_size += pos;
247 } 245 }
248 else if (pos > 0)
249 dst_pos = pos;
250 246
251 if (dst_pos + dst_size > target_size) 247 if (dst_pos + dst_size > target_size)
252 dst_size = target_size - dst_pos; 248 dst_size = target_size - dst_pos;
253 return src_pos; 249 return src_pos;
254} 250}
259 int geom_flags = 0, changed = 0; 255 int geom_flags = 0, changed = 0;
260 int x = 0, y = 0; 256 int x = 0, y = 0;
261 unsigned int w = 0, h = 0; 257 unsigned int w = 0, h = 0;
262 unsigned int n; 258 unsigned int n;
263 unsigned long new_flags = (flags & (~geometryFlags)); 259 unsigned long new_flags = (flags & (~geometryFlags));
264 char *p; 260 const char *p;
265# define MAXLEN_GEOM 256 /* could be longer than regular geometry string */ 261# define MAXLEN_GEOM 256 /* could be longer than regular geometry string */
266 262
267 if (geom == NULL) 263 if (geom == NULL)
268 return false; 264 return false;
269 265
379 w = h = noScale; 375 w = h = noScale;
380 geom_flags |= WidthValue|HeightValue; 376 geom_flags |= WidthValue|HeightValue;
381 } 377 }
382 else if (CHECK_GEOM_OPS ("propscale")) 378 else if (CHECK_GEOM_OPS ("propscale"))
383 { 379 {
384 if (w == 0 && h == 0)
385 {
386 w = windowScale;
387 geom_flags |= WidthValue;
388 }
389 new_flags |= propScale; 380 new_flags |= propScale;
390 } 381 }
391 else if (CHECK_GEOM_OPS ("hscale")) 382 else if (CHECK_GEOM_OPS ("hscale"))
392 { 383 {
393 if (w == 0) w = windowScale; 384 if (w == 0) w = windowScale;
415 x = y = centerAlign; 406 x = y = centerAlign;
416 geom_flags |= WidthValue|HeightValue|XValue|YValue; 407 geom_flags |= WidthValue|HeightValue|XValue|YValue;
417 } 408 }
418 else if (CHECK_GEOM_OPS ("root")) 409 else if (CHECK_GEOM_OPS ("root"))
419 { 410 {
411 new_flags |= rootAlign;
420 w = h = noScale; 412 w = h = noScale;
421 x = y = rootAlign;
422 geom_flags |= WidthValue|HeightValue|XValue|YValue; 413 geom_flags |= WidthValue|HeightValue;
423 } 414 }
424# undef CHECK_GEOM_OPS 415# undef CHECK_GEOM_OPS
425 416
426 while (*ops != ':' && *ops != '\0') ++ops; 417 while (*ops != ':' && *ops != '\0') ++ops;
427 } /* done parsing ops */ 418 } /* done parsing ops */
437 { 428 {
438 flags = new_flags; 429 flags = new_flags;
439 changed++; 430 changed++;
440 } 431 }
441 432
442//fprintf (stderr, "flags = %lX, scale = %ux%u, align=%+d%+d\n",
443// flags, h_scale, v_scale, h_align, v_align);
444 return (changed > 0); 433 return (changed > 0);
434}
435
436void
437bgPixmap_t::get_image_geometry (int image_width, int image_height, int &w, int &h, int &x, int &y)
438{
439 int target_width = target->szHint.width;
440 int target_height = target->szHint.height;
441
442 if (flags & propScale)
443 {
444 float scale = (float)target_width / image_width;
445 min_it (scale, (float)target_height / image_height);
446 w = image_width * scale + 0.5;
447 h = image_height * scale + 0.5;
448 }
449 else
450 {
451 w = h_scale * target_width / 100;
452 h = v_scale * target_height / 100;
453 }
454
455 if (!w) w = image_width;
456 if (!h) h = image_height;
457
458 if (flags & rootAlign)
459 {
460 target->get_window_origin (x, y);
461 x = -x;
462 y = -y;
463 }
464 else
465 {
466 x = make_align_position (h_align, target_width, w);
467 y = make_align_position (v_align, target_height, h);
468 }
469
470 flags &= ~sizeSensitive;
471 if ((flags & propScale) || h_scale || v_scale
472 || (!(flags & rootAlign) && (h_align || v_align))
473 || w > target_width || h > target_height)
474 flags |= sizeSensitive;
445} 475}
446 476
447# ifdef HAVE_AFTERIMAGE 477# ifdef HAVE_AFTERIMAGE
448bool 478bool
449bgPixmap_t::render_asim (ASImage *background, ARGB32 background_tint) 479bgPixmap_t::render_image (unsigned long background_flags)
450{ 480{
451 if (target == NULL) 481 if (target == NULL)
452 return false; 482 return false;
453 483
484 target->init_asv ();
485
486 ASImage *background = NULL;
487 ARGB32 background_tint = TINT_LEAVE_SAME;
488
489# ifdef ENABLE_TRANSPARENCY
490 if (background_flags)
491 background = pixmap2ximage (target->asv, pixmap, 0, 0, pmap_width, pmap_height, AllPlanes, 100);
492
493 if (!(background_flags & transpPmapTinted) && (flags & tintNeeded))
494 {
495 ShadingInfo as_shade;
496 as_shade.shading = shade;
497
498 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC);
499 if (flags & tintSet)
500 tint.get (c);
501 as_shade.tintColor.red = c.r;
502 as_shade.tintColor.green = c.g;
503 as_shade.tintColor.blue = c.b;
504
505 background_tint = shading2tint32 (&as_shade);
506 }
507
508 if (!(background_flags & transpPmapBlurred) && (flags & blurNeeded) && background != NULL)
509 {
510 ASImage *tmp = blur_asimage_gauss (target->asv, background, h_blurRadius, v_blurRadius, 0xFFFFFFFF,
511 (original_asim == NULL || tint == TINT_LEAVE_SAME) ? ASA_XImage : ASA_ASImage,
512 100, ASIMAGE_QUALITY_DEFAULT);
513 if (tmp)
514 {
515 destroy_asimage (&background);
516 background = tmp;
517 }
518 }
519# endif
520
521 ASImage *result = 0;
522
454 int target_width = (int)target->szHint.width; 523 int target_width = target->szHint.width;
455 int target_height = (int)target->szHint.height; 524 int target_height = target->szHint.height;
456 int new_pmap_width = target_width, new_pmap_height = target_height; 525 int new_pmap_width = target_width;
457 ASImage *result = NULL; 526 int new_pmap_height = target_height;
458 527
459 int x = 0; 528 int x = 0;
460 int y = 0; 529 int y = 0;
461 int w = h_scale * target_width / 100; 530 int w = 0;
462 int h = v_scale * target_height / 100; 531 int h = 0;
463
464 TIMING_TEST_START (asim);
465 532
466 if (original_asim) 533 if (original_asim)
467 { 534 get_image_geometry (original_asim->width, original_asim->height, w, h, x, y);
468 if (h_align == rootAlign || v_align == rootAlign)
469 {
470 target->get_window_origin(x, y);
471 x = -x;
472 y = -y;
473 }
474
475 if (h_align != rootAlign)
476 x = make_align_position (h_align, target_width, w > 0 ? w : (int)original_asim->width);
477
478 if (v_align != rootAlign)
479 y = make_align_position (v_align, target_height, h > 0 ? h : (int)original_asim->height);
480 }
481 535
482 if (!original_asim 536 if (!original_asim
537 || (!(flags & rootAlign)
483 || x >= target_width 538 && (x >= target_width
484 || y >= target_height 539 || y >= target_height
485 || (w > 0 && x + w <= 0) 540 || (x + w <= 0)
486 || (h > 0 && y + h <= 0)) 541 || (y + h <= 0))))
487 { 542 {
488 if (background) 543 if (background)
489 { 544 {
490 new_pmap_width = background->width; 545 new_pmap_width = background->width;
491 new_pmap_height = background->height; 546 new_pmap_height = background->height;
492 result = background; 547 result = background;
493 548
494 if (background_tint != TINT_LEAVE_SAME) 549 if (background_tint != TINT_LEAVE_SAME)
495 { 550 {
496 ASImage* tmp = tile_asimage (target->asv, background, 0, 0, 551 ASImage *tmp = tile_asimage (target->asv, background, 0, 0,
497 target_width, target_height, background_tint, 552 target_width, target_height, background_tint,
498 ASA_XImage, 100, ASIMAGE_QUALITY_DEFAULT); 553 ASA_XImage, 100, ASIMAGE_QUALITY_DEFAULT);
499 if (tmp) 554 if (tmp)
500 result = tmp; 555 result = tmp;
501 } 556 }
505 } 560 }
506 else 561 else
507 { 562 {
508 result = original_asim; 563 result = original_asim;
509 564
510 if ((w > 0 && w != original_asim->width) 565 if ((w != original_asim->width)
511 || (h > 0 && h != original_asim->height)) 566 || (h != original_asim->height))
512 { 567 {
513 result = scale_asimage (target->asv, original_asim, 568 result = scale_asimage (target->asv, original_asim,
514 w > 0 ? w : original_asim->width, 569 w, h,
515 h > 0 ? h : original_asim->height,
516 background ? ASA_ASImage : ASA_XImage, 570 background ? ASA_ASImage : ASA_XImage,
517 100, ASIMAGE_QUALITY_DEFAULT); 571 100, ASIMAGE_QUALITY_DEFAULT);
518 } 572 }
519 573
520 if (background == NULL) 574 if (background == NULL)
521 { 575 {
522 /* if tiling - pixmap has to be sized exactly as the image,
523 but there is no need to make it bigger than the window! */
524 if (h_scale == 0)
525 new_pmap_width = min (result->width, target_width);
526 if (v_scale == 0)
527 new_pmap_height = min (result->height, target_height);
528 /* we also need to tile our image in one or both directions */
529 if (h_scale == 0 || v_scale == 0) 576 if (h_scale == 0 || v_scale == 0)
530 { 577 {
578 /* if tiling - pixmap has to be sized exactly as the image,
579 but there is no need to make it bigger than the window! */
580 new_pmap_width = min (result->width, target_width);
581 new_pmap_height = min (result->height, target_height);
582
583 /* we also need to tile our image in both directions */
531 ASImage *tmp = tile_asimage (target->asv, result, 584 ASImage *tmp = tile_asimage (target->asv, result,
532 (h_scale > 0) ? 0 : (int)result->width - x, 585 (int)result->width - x,
533 (v_scale > 0) ? 0 : (int)result->height - y, 586 (int)result->height - y,
534 new_pmap_width, 587 new_pmap_width,
535 new_pmap_height, 588 new_pmap_height,
536 TINT_LEAVE_SAME, ASA_XImage, 589 TINT_LEAVE_SAME, ASA_XImage,
537 100, ASIMAGE_QUALITY_DEFAULT); 590 100, ASIMAGE_QUALITY_DEFAULT);
538 if (tmp) 591 if (tmp)
539 { 592 {
546 } 599 }
547 else 600 else
548 { 601 {
549 /* if blending background and image - pixmap has to be sized same as target window */ 602 /* if blending background and image - pixmap has to be sized same as target window */
550 ASImageLayer *layers = create_image_layers (2); 603 ASImageLayer *layers = create_image_layers (2);
551 ASImage *merged_im = NULL;
552 604
553 layers[0].im = background; 605 layers[0].im = background;
554 layers[0].clip_width = target_width; 606 layers[0].clip_width = target_width;
555 layers[0].clip_height = target_height; 607 layers[0].clip_height = target_height;
556 layers[0].tint = background_tint; 608 layers[0].tint = background_tint;
557 layers[1].im = result; 609 layers[1].im = result;
558 610
559 if (w <= 0) 611 if (h_scale == 0 || v_scale == 0)
560 { 612 {
561 /* tile horizontally */ 613 /* tile horizontally */
562 while (x > 0) x -= (int)result->width; 614 while (x > 0) x -= (int)result->width;
563 layers[1].dst_x = x; 615 layers[1].dst_x = x;
564 layers[1].clip_width = result->width+target_width; 616 layers[1].clip_width = result->width+target_width;
568 /* clip horizontally */ 620 /* clip horizontally */
569 layers[1].dst_x = x; 621 layers[1].dst_x = x;
570 layers[1].clip_width = result->width; 622 layers[1].clip_width = result->width;
571 } 623 }
572 624
573 if (h <= 0) 625 if (h_scale == 0 || v_scale == 0)
574 { 626 {
575 while (y > 0) y -= (int)result->height; 627 while (y > 0) y -= (int)result->height;
576 layers[1].dst_y = y; 628 layers[1].dst_y = y;
577 layers[1].clip_height = result->height + target_height; 629 layers[1].clip_height = result->height + target_height;
578 } 630 }
601 } 653 }
602 654
603 free (layers); 655 free (layers);
604 } 656 }
605 } 657 }
606 TIMING_TEST_PRINT_RESULT (asim);
607 658
608 if (pixmap) 659 bool ret = false;
609 {
610 if (result == NULL
611 || pmap_width != new_pmap_width
612 || pmap_height != new_pmap_height
613 || pmap_depth != target->depth)
614 {
615 XFreePixmap (target->dpy, pixmap);
616 pixmap = None;
617 }
618 }
619 660
620 if (result) 661 if (result)
621 { 662 {
622 XGCValues gcv; 663 XGCValues gcv;
623 GC gc; 664 GC gc;
665
666 if (pixmap)
667 {
668 if (pmap_width != new_pmap_width
669 || pmap_height != new_pmap_height
670 || pmap_depth != target->depth)
671 {
672 XFreePixmap (target->dpy, pixmap);
673 pixmap = None;
674 }
675 }
624 676
625 /* create Pixmap */ 677 /* create Pixmap */
626 if (pixmap == None) 678 if (pixmap == None)
627 { 679 {
628 pixmap = XCreatePixmap (target->dpy, target->vt, new_pmap_width, new_pmap_height, target->depth); 680 pixmap = XCreatePixmap (target->dpy, target->vt, new_pmap_width, new_pmap_height, target->depth);
629 pmap_width = new_pmap_width; 681 pmap_width = new_pmap_width;
630 pmap_height = new_pmap_height; 682 pmap_height = new_pmap_height;
631 pmap_depth = target->depth; 683 pmap_depth = target->depth;
632 } 684 }
633 /* fill with background color ( if result's not completely overlapping it)*/ 685 /* fill with background color (if result's not completely overlapping it) */
634 gcv.foreground = target->pix_colors[Color_bg]; 686 gcv.foreground = target->pix_colors[Color_bg];
635 gc = XCreateGC (target->dpy, target->vt, GCForeground, &gcv); 687 gc = XCreateGC (target->dpy, target->vt, GCForeground, &gcv);
636 688
637 int src_x = 0, src_y = 0, dst_x = 0, dst_y = 0; 689 int src_x = 0, src_y = 0, dst_x = 0, dst_y = 0;
638 int dst_width = result->width, dst_height = result->height; 690 int dst_width = result->width, dst_height = result->height;
639 if (background == NULL) 691 if (background == NULL)
640 { 692 {
693 if (!(h_scale == 0 || v_scale == 0))
694 {
641 if (h_scale > 0) src_x = make_clip_rectangle (x, result->width , new_pmap_width , dst_x, dst_width ); 695 src_x = make_clip_rectangle (x, result->width , new_pmap_width , dst_x, dst_width );
642 if (v_scale > 0) src_y = make_clip_rectangle (y, result->height, new_pmap_height, dst_y, dst_height); 696 src_y = make_clip_rectangle (y, result->height, new_pmap_height, dst_y, dst_height);
697 }
643 698
644 if (dst_x > 0 || dst_y > 0 699 if (dst_x > 0 || dst_y > 0
645 || dst_x + dst_width < new_pmap_width 700 || dst_x + dst_width < new_pmap_width
646 || dst_y + dst_height < new_pmap_height) 701 || dst_y + dst_height < new_pmap_height)
647 XFillRectangle (target->dpy, pixmap, gc, 0, 0, new_pmap_width, new_pmap_height); 702 XFillRectangle (target->dpy, pixmap, gc, 0, 0, new_pmap_width, new_pmap_height);
653 708
654 if (result != background && result != original_asim) 709 if (result != background && result != original_asim)
655 destroy_asimage (&result); 710 destroy_asimage (&result);
656 711
657 XFreeGC (target->dpy, gc); 712 XFreeGC (target->dpy, gc);
658 TIMING_TEST_PRINT_RESULT (asim);
659 }
660 713
714 ret = true;
715 }
716
717 if (background)
718 destroy_asimage (&background);
719
661 return true; 720 return ret;
662} 721}
663# endif /* HAVE_AFTERIMAGE */ 722# endif /* HAVE_AFTERIMAGE */
723
724# ifdef HAVE_PIXBUF
725bool
726bgPixmap_t::render_image (unsigned long background_flags)
727{
728 if (target == NULL)
729 return false;
730
731 if (!pixbuf)
732 return false;
733
734 if (background_flags
735 && !(flags & HAS_RENDER))
736 return false;
737
738 GdkPixbuf *result;
739
740 int image_width = gdk_pixbuf_get_width (pixbuf);
741 int image_height = gdk_pixbuf_get_height (pixbuf);
742
743 int target_width = target->szHint.width;
744 int target_height = target->szHint.height;
745 int new_pmap_width = target_width;
746 int new_pmap_height = target_height;
747
748 int x = 0;
749 int y = 0;
750 int w = 0;
751 int h = 0;
752
753 get_image_geometry (image_width, image_height, w, h, x, y);
754
755 if (!(flags & rootAlign)
756 && (x >= target_width
757 || y >= target_height
758 || (x + w <= 0)
759 || (y + h <= 0)))
760 return false;
761
762 result = pixbuf;
763
764 if ((w != image_width)
765 || (h != image_height))
766 {
767 result = gdk_pixbuf_scale_simple (pixbuf,
768 w, h,
769 GDK_INTERP_BILINEAR);
770 }
771
772 bool ret = false;
773
774 if (result)
775 {
776 XGCValues gcv;
777 GC gc;
778 Pixmap root_pmap;
779
780 image_width = gdk_pixbuf_get_width (result);
781 image_height = gdk_pixbuf_get_height (result);
782
783 if (background_flags)
784 {
785 root_pmap = pixmap;
786 pixmap = None;
787 }
788 else
789 {
790 if (h_scale == 0 || v_scale == 0)
791 {
792 new_pmap_width = min (image_width, target_width);
793 new_pmap_height = min (image_height, target_height);
794 }
795 }
796
797 if (pixmap)
798 {
799 if (pmap_width != new_pmap_width
800 || pmap_height != new_pmap_height
801 || pmap_depth != target->depth)
802 {
803 XFreePixmap (target->dpy, pixmap);
804 pixmap = None;
805 }
806 }
807
808 if (pixmap == None)
809 {
810 pixmap = XCreatePixmap (target->dpy, target->vt, new_pmap_width, new_pmap_height, target->depth);
811 pmap_width = new_pmap_width;
812 pmap_height = new_pmap_height;
813 pmap_depth = target->depth;
814 }
815
816 gcv.foreground = target->pix_colors[Color_bg];
817 gc = XCreateGC (target->dpy, target->vt, GCForeground, &gcv);
818
819 if (h_scale == 0 || v_scale == 0)
820 {
821 Pixmap tile = XCreatePixmap (target->dpy, target->vt, image_width, image_height, target->depth);
822 gdk_pixbuf_xlib_render_to_drawable (result, tile, gc,
823 0, 0,
824 0, 0,
825 image_width, image_height,
826 XLIB_RGB_DITHER_NONE,
827 0, 0);
828
829 gcv.tile = tile;
830 gcv.fill_style = FillTiled;
831 gcv.ts_x_origin = x;
832 gcv.ts_y_origin = y;
833 XChangeGC (target->dpy, gc, GCFillStyle | GCTile | GCTileStipXOrigin | GCTileStipYOrigin, &gcv);
834
835 XFillRectangle (target->dpy, pixmap, gc, 0, 0, new_pmap_width, new_pmap_height);
836 XFreePixmap (target->dpy, tile);
837 }
838 else
839 {
840 int src_x, src_y, dst_x, dst_y;
841 int dst_width, dst_height;
842
843 src_x = make_clip_rectangle (x, image_width , new_pmap_width , dst_x, dst_width );
844 src_y = make_clip_rectangle (y, image_height, new_pmap_height, dst_y, dst_height);
845
846 if (dst_x > 0 || dst_y > 0
847 || dst_x + dst_width < new_pmap_width
848 || dst_y + dst_height < new_pmap_height)
849 XFillRectangle (target->dpy, pixmap, gc, 0, 0, new_pmap_width, new_pmap_height);
850
851 if (dst_x < new_pmap_width && dst_y < new_pmap_height)
852 gdk_pixbuf_xlib_render_to_drawable (result, pixmap, gc,
853 src_x, src_y,
854 dst_x, dst_y,
855 dst_width, dst_height,
856 XLIB_RGB_DITHER_NONE,
857 0, 0);
858 }
859
860#if XRENDER
861 if (background_flags)
862 {
863 Display *dpy = target->dpy;
864 XRenderPictureAttributes pa;
865
866 XRenderPictFormat *src_format = XRenderFindVisualFormat (dpy, target->visual);
867 Picture src = XRenderCreatePicture (dpy, root_pmap, src_format, 0, &pa);
868
869 XRenderPictFormat *dst_format = XRenderFindVisualFormat (dpy, target->visual);
870 Picture dst = XRenderCreatePicture (dpy, pixmap, dst_format, 0, &pa);
871
872 pa.repeat = True;
873 Pixmap mask_pmap = XCreatePixmap (dpy, target->vt, 1, 1, 8);
874 XRenderPictFormat *mask_format = XRenderFindStandardFormat (dpy, PictStandardA8);
875 Picture mask = XRenderCreatePicture (dpy, mask_pmap, mask_format, CPRepeat, &pa);
876 XFreePixmap (dpy, mask_pmap);
877
878 if (src && dst && mask)
879 {
880 XRenderColor mask_c;
881
882 mask_c.alpha = 0x8000;
883 mask_c.red = 0;
884 mask_c.green = 0;
885 mask_c.blue = 0;
886 XRenderFillRectangle (dpy, PictOpSrc, mask, &mask_c, 0, 0, 1, 1);
887 XRenderComposite (dpy, PictOpOver, src, mask, dst, 0, 0, 0, 0, 0, 0, target_width, target_height);
888 }
889
890 XRenderFreePicture (dpy, src);
891 XRenderFreePicture (dpy, dst);
892 XRenderFreePicture (dpy, mask);
893
894 XFreePixmap (dpy, root_pmap);
895 }
896#endif
897
898 if (result != pixbuf)
899 g_object_unref (result);
900
901 XFreeGC (target->dpy, gc);
902
903 ret = true;
904 }
905
906 return ret;
907}
908# endif /* HAVE_PIXBUF */
664 909
665bool 910bool
666bgPixmap_t::set_file (const char *file) 911bgPixmap_t::set_file (const char *file)
667{ 912{
668 char *f; 913 if (!file || !*file)
914 return false;
669 915
670 assert (file); 916 if (const char *p = strchr (file, ';'))
671 917 {
672 if (*file) 918 size_t len = p - file;
919 char *f = rxvt_temp_buf<char> (len + 1);
920 memcpy (f, file, len);
921 f[len] = '\0';
922 file = f;
673 { 923 }
924
674# ifdef HAVE_AFTERIMAGE 925# ifdef HAVE_AFTERIMAGE
675 if (target->asimman == NULL) 926 if (!target->asimman)
676 target->asimman = create_generic_imageman (target->rs[Rs_path]); 927 target->asimman = create_generic_imageman (target->rs[Rs_path]);
677
678 if ((f = strchr (file, ';')) == NULL)
679 original_asim = get_asimage (target->asimman, file, 0xFFFFFFFF, 100); 928 ASImage *image = get_asimage (target->asimman, file, 0xFFFFFFFF, 100);
680 else 929 if (image)
681 { 930 {
682 size_t len = f - file; 931 if (original_asim)
683 f = (char *)malloc (len + 1); 932 safe_asimage_destroy (original_asim);
684 memcpy (f, file, len); 933 original_asim = image;
685 f[len] = '\0'; 934 have_image = true;
686 original_asim = get_asimage (target->asimman, f, 0xFFFFFFFF, 100); 935 return true;
687 free (f); 936 }
688 }
689
690 return original_asim;
691# endif 937# endif
938
939# ifdef HAVE_PIXBUF
940 GdkPixbuf *image = gdk_pixbuf_new_from_file (file, NULL);
941 if (image)
692 } 942 {
943 if (pixbuf)
944 g_object_unref (pixbuf);
945 pixbuf = image;
946 have_image = true;
947 return true;
948 }
949# endif
693 950
694 return false; 951 return false;
695} 952}
696 953
697# endif /* BG_IMAGE_FROM_FILE */ 954# endif /* BG_IMAGE_FROM_FILE */
715 int changed = 0; 972 int changed = 0;
716 unsigned int hr, vr; 973 unsigned int hr, vr;
717 int junk; 974 int junk;
718 int geom_flags = XParseGeometry (geom, &junk, &junk, &hr, &vr); 975 int geom_flags = XParseGeometry (geom, &junk, &junk, &hr, &vr);
719 976
720 if (!(geom_flags&WidthValue)) 977 if (!(geom_flags & WidthValue))
721 hr = 1; 978 hr = 1;
722 if (!(geom_flags&HeightValue)) 979 if (!(geom_flags & HeightValue))
723 vr = hr; 980 vr = hr;
981
982 min_it (hr, 128);
983 min_it (vr, 128);
724 984
725 if (h_blurRadius != hr) 985 if (h_blurRadius != hr)
726 { 986 {
727 ++changed; 987 ++changed;
728 h_blurRadius = hr; 988 h_blurRadius = hr;
737 if (v_blurRadius == 0 && h_blurRadius == 0) 997 if (v_blurRadius == 0 && h_blurRadius == 0)
738 flags &= ~blurNeeded; 998 flags &= ~blurNeeded;
739 else 999 else
740 flags |= blurNeeded; 1000 flags |= blurNeeded;
741 1001
742 return (changed>0); 1002 return (changed > 0);
743} 1003}
744 1004
745static inline unsigned long 1005static inline unsigned long
746compute_tint_shade_flags (rxvt_color *tint, int shade) 1006compute_tint_shade_flags (rxvt_color *tint, int shade)
747{ 1007{
748 unsigned long flags = 0; 1008 unsigned long flags = 0;
749 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC); 1009 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC);
750 bool has_shade = (shade > 0 && shade < 100) || (shade > 100 && shade < 200); 1010 bool has_shade = shade != 100;
751 1011
752 if (tint) 1012 if (tint)
753 { 1013 {
754 tint->get (c); 1014 tint->get (c);
755# define IS_COMPONENT_WHOLESOME(cmp) ((cmp) <= 0x000700 || (cmp) >= 0x00f700) 1015# define IS_COMPONENT_WHOLESOME(cmp) ((cmp) <= 0x000700 || (cmp) >= 0x00f700)
764 flags |= bgPixmap_t::tintNeeded; 1024 flags |= bgPixmap_t::tintNeeded;
765 else if (tint) 1025 else if (tint)
766 { 1026 {
767 if ((c.r > 0x000700 || c.g > 0x000700 || c.b > 0x000700) 1027 if ((c.r > 0x000700 || c.g > 0x000700 || c.b > 0x000700)
768 && (c.r < 0x00f700 || c.g < 0x00f700 || c.b < 0x00f700)) 1028 && (c.r < 0x00f700 || c.g < 0x00f700 || c.b < 0x00f700))
769 { 1029 {
770 flags |= bgPixmap_t::tintNeeded; 1030 flags |= bgPixmap_t::tintNeeded;
771 }
772 }
773
774 if (flags & bgPixmap_t::tintNeeded)
775 {
776 if (flags & bgPixmap_t::tintWholesome)
777 flags |= bgPixmap_t::tintServerSide;
778 else
779 {
780#if XFT
781 flags |= bgPixmap_t::tintServerSide;
782#endif
783 } 1031 }
784 } 1032 }
785 1033
786 return flags; 1034 return flags;
787} 1035}
788 1036
789bool 1037bool
790bgPixmap_t::set_tint (rxvt_color &new_tint) 1038bgPixmap_t::set_tint (rxvt_color &new_tint)
791{ 1039{
792 if (tint != new_tint) 1040 if (!(flags & tintSet) || tint != new_tint)
793 { 1041 {
794 unsigned long new_flags = compute_tint_shade_flags (&new_tint, shade); 1042 unsigned long new_flags = compute_tint_shade_flags (&new_tint, shade);
795 tint = new_tint; 1043 tint = new_tint;
796 flags = (flags & ~tintFlags) | new_flags | tintSet; 1044 flags = (flags & ~tintFlags) | new_flags | tintSet;
797 return true; 1045 return true;
805{ 1053{
806 unsigned long new_flags = compute_tint_shade_flags (NULL, shade); 1054 unsigned long new_flags = compute_tint_shade_flags (NULL, shade);
807 1055
808 if (new_flags != (flags & tintFlags)) 1056 if (new_flags != (flags & tintFlags))
809 { 1057 {
810 flags = (flags&~tintFlags)|new_flags; 1058 flags = (flags & ~tintFlags) | new_flags;
811 return true; 1059 return true;
812 } 1060 }
813 1061
814 return false; 1062 return false;
815} 1063}
816 1064
817bool 1065bool
818bgPixmap_t::set_shade (const char *shade_str) 1066bgPixmap_t::set_shade (const char *shade_str)
819{ 1067{
820 int new_shade = (shade_str) ? atoi (shade_str) : 0; 1068 int new_shade = (shade_str) ? atoi (shade_str) : 100;
821 1069
822 if (new_shade < 0 && new_shade > -100) 1070 clamp_it (new_shade, -100, 200);
1071 if (new_shade < 0)
823 new_shade = 200 - (100 + new_shade); 1072 new_shade = 200 - (100 + new_shade);
824 else if (new_shade == 100)
825 new_shade = 0;
826 1073
827 if (new_shade != shade) 1074 if (new_shade != shade)
828 { 1075 {
829 unsigned long new_flags = compute_tint_shade_flags ((flags & tintSet) ? &tint : NULL, new_shade); 1076 unsigned long new_flags = compute_tint_shade_flags ((flags & tintSet) ? &tint : NULL, new_shade);
830 shade = new_shade; 1077 shade = new_shade;
833 } 1080 }
834 1081
835 return false; 1082 return false;
836} 1083}
837 1084
1085#if XRENDER
1086static void
1087get_gaussian_kernel (int radius, int width, double *kernel, XFixed *params)
1088{
1089 double sigma = radius / 2.0;
1090 double scale = sqrt (2.0 * M_PI) * sigma;
1091 double sum = 0.0;
1092
1093 for (int i = 0; i < width; i++)
1094 {
1095 double x = i - width / 2;
1096 kernel[i] = exp (-(x * x) / (2.0 * sigma * sigma)) / scale;
1097 sum += kernel[i];
1098 }
1099
1100 params[0] = XDoubleToFixed (width);
1101 params[1] = XDoubleToFixed (1);
1102
1103 for (int i = 0; i < width; i++)
1104 params[i+2] = XDoubleToFixed (kernel[i] / sum);
1105}
1106#endif
1107
1108bool
1109bgPixmap_t::blur_pixmap (Pixmap pixmap, Visual *visual, int width, int height)
1110{
1111 bool ret = false;
1112#if XRENDER
1113 int size = max (h_blurRadius, v_blurRadius) * 2 + 1;
1114 double *kernel = (double *)malloc (size * sizeof (double));
1115 XFixed *params = (XFixed *)malloc ((size + 2) * sizeof (XFixed));
1116
1117 Display *dpy = target->dpy;
1118 XRenderPictureAttributes pa;
1119 XRenderPictFormat *format = XRenderFindVisualFormat (dpy, visual);
1120
1121 Picture src = XRenderCreatePicture (dpy, pixmap, format, 0, &pa);
1122 Picture dst = XRenderCreatePicture (dpy, pixmap, format, 0, &pa);
1123
1124 if (kernel && params && src && dst)
1125 {
1126 if (h_blurRadius)
1127 {
1128 size = h_blurRadius * 2 + 1;
1129 get_gaussian_kernel (h_blurRadius, size, kernel, params);
1130
1131 XRenderSetPictureFilter (dpy, src, FilterConvolution, params, size+2);
1132 XRenderComposite (dpy,
1133 PictOpSrc,
1134 src,
1135 None,
1136 dst,
1137 0, 0,
1138 0, 0,
1139 0, 0,
1140 width, height);
1141 }
1142
1143 if (v_blurRadius)
1144 {
1145 size = v_blurRadius * 2 + 1;
1146 get_gaussian_kernel (v_blurRadius, size, kernel, params);
1147 swap (params[0], params[1]);
1148
1149 XRenderSetPictureFilter (dpy, src, FilterConvolution, params, size+2);
1150 XRenderComposite (dpy,
1151 PictOpSrc,
1152 src,
1153 None,
1154 dst,
1155 0, 0,
1156 0, 0,
1157 0, 0,
1158 width, height);
1159 }
1160
1161 ret = true;
1162 }
1163
1164 free (kernel);
1165 free (params);
1166 XRenderFreePicture (dpy, src);
1167 XRenderFreePicture (dpy, dst);
1168#endif
1169 return ret;
1170}
1171
1172bool
1173bgPixmap_t::tint_pixmap (Pixmap pixmap, Visual *visual, int width, int height)
1174{
1175 Display *dpy = target->dpy;
1176 bool ret = false;
1177
1178 if (flags & tintWholesome)
1179 {
1180 XGCValues gcv;
1181 GC gc;
1182
1183 /* In this case we can tint image server-side getting significant
1184 * performance improvements, as we eliminate XImage transfer
1185 */
1186 gcv.foreground = Pixel (tint);
1187 gcv.function = GXand;
1188 gcv.fill_style = FillSolid;
1189 gc = XCreateGC (dpy, pixmap, GCFillStyle | GCForeground | GCFunction, &gcv);
1190 if (gc)
1191 {
1192 XFillRectangle (dpy, pixmap, gc, 0, 0, width, height);
1193 ret = true;
1194 XFreeGC (dpy, gc);
1195 }
1196 }
1197 else
1198 {
1199# if XRENDER
1200 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC);
1201
1202 if (flags & tintSet)
1203 tint.get (c);
1204
1205 if (shade <= 100)
1206 {
1207 c.r = (c.r * shade) / 100;
1208 c.g = (c.g * shade) / 100;
1209 c.b = (c.b * shade) / 100;
1210 }
1211 else
1212 {
1213 c.r = ((0xffff - c.r) * (200 - shade)) / 100;
1214 c.g = ((0xffff - c.g) * (200 - shade)) / 100;
1215 c.b = ((0xffff - c.b) * (200 - shade)) / 100;
1216 }
1217
1218 XRenderPictFormat *solid_format = XRenderFindStandardFormat (dpy, PictStandardARGB32);
1219 XRenderPictFormat *format = XRenderFindVisualFormat (dpy, visual);
1220 XRenderPictureAttributes pa;
1221
1222 Picture back_pic = XRenderCreatePicture (dpy, pixmap, format, 0, &pa);
1223
1224 pa.repeat = True;
1225
1226 Pixmap overlay_pmap = XCreatePixmap (dpy, pixmap, 1, 1, 32);
1227 Picture overlay_pic = XRenderCreatePicture (dpy, overlay_pmap, solid_format, CPRepeat, &pa);
1228 XFreePixmap (dpy, overlay_pmap);
1229
1230 pa.component_alpha = True;
1231 Pixmap mask_pmap = XCreatePixmap (dpy, pixmap, 1, 1, 32);
1232 Picture mask_pic = XRenderCreatePicture (dpy, mask_pmap, solid_format, CPRepeat|CPComponentAlpha, &pa);
1233 XFreePixmap (dpy, mask_pmap);
1234
1235 if (mask_pic && overlay_pic && back_pic)
1236 {
1237 XRenderColor mask_c;
1238
1239 memset (&mask_c, (shade > 100) ? 0xFF : 0x0, sizeof (mask_c));
1240 mask_c.alpha = 0xffff;
1241 XRenderFillRectangle (dpy, PictOpSrc, overlay_pic, &mask_c, 0, 0, 1, 1);
1242
1243 mask_c.alpha = 0;
1244 mask_c.red = 0xffff - c.r;
1245 mask_c.green = 0xffff - c.g;
1246 mask_c.blue = 0xffff - c.b;
1247 XRenderFillRectangle (dpy, PictOpSrc, mask_pic, &mask_c, 0, 0, 1, 1);
1248 XRenderComposite (dpy, PictOpOver, overlay_pic, mask_pic, back_pic, 0, 0, 0, 0, 0, 0, width, height);
1249 ret = true;
1250 }
1251
1252 XRenderFreePicture (dpy, mask_pic);
1253 XRenderFreePicture (dpy, overlay_pic);
1254 XRenderFreePicture (dpy, back_pic);
1255# endif
1256 }
1257
1258 return ret;
1259}
1260
838/* make_transparency_pixmap() 1261/* make_transparency_pixmap()
839 * Builds a pixmap sized the same as terminal window, with depth same as the root window 1262 * Builds a pixmap of the same size as the terminal window that contains
840 * that pixmap contains tiled portion of the root pixmap that is supposed to be covered by 1263 * the tiled portion of the root pixmap that is supposed to be covered by
841 * our window. 1264 * our window.
842 */ 1265 */
843unsigned long 1266unsigned long
844bgPixmap_t::make_transparency_pixmap () 1267bgPixmap_t::make_transparency_pixmap ()
845{ 1268{
846 unsigned long result = 0; 1269 unsigned long result = 0;
847 1270
848 if (target == NULL) 1271 if (target == NULL)
849 return 0; 1272 return 0;
850 1273
851 /* root dimentions may change from call to call - but Display structure should 1274 /* root dimensions may change from call to call - but Display structure should
852 * be always up-to-date, so let's use it : 1275 * be always up-to-date, so let's use it :
853 */ 1276 */
854 Window root = target->display->root;
855 int screen = target->display->screen; 1277 int screen = target->display->screen;
856 Display *dpy = target->dpy; 1278 Display *dpy = target->dpy;
1279 int root_depth = DefaultDepth (dpy, screen);
857 int root_width = DisplayWidth (dpy, screen); 1280 int root_width = DisplayWidth (dpy, screen);
858 int root_height = DisplayHeight (dpy, screen); 1281 int root_height = DisplayHeight (dpy, screen);
859 unsigned int root_pmap_width, root_pmap_height; 1282 unsigned int root_pmap_width, root_pmap_height;
860 int window_width = target->szHint.width; 1283 int window_width = target->szHint.width;
861 int window_height = target->szHint.height; 1284 int window_height = target->szHint.height;
862 int sx, sy; 1285 int sx, sy;
863 XGCValues gcv; 1286 XGCValues gcv;
1287 GC gc;
864 1288
865 TIMING_TEST_START (tp);
866 target->get_window_origin (sx, sy); 1289 target->get_window_origin (sx, sy);
867 1290
868 /* check if we are outside of the visible part of the virtual screen : */ 1291 /* check if we are outside of the visible part of the virtual screen : */
869 if (sx + window_width <= 0 || sy + window_height <= 0 1292 if (sx + window_width <= 0 || sy + window_height <= 0
870 || sx >= root_width || sy >= root_height) 1293 || sx >= root_width || sy >= root_height)
871 return 0; 1294 return 0;
872 1295
1296 // validate root pixmap and get its size
873 if (root_pixmap != None) 1297 if (root_pixmap != None)
874 { 1298 {
875 /* we want to validate the pixmap and get it's size at the same time : */ 1299 Window wdummy;
876 int junk; 1300 int idummy;
877 unsigned int ujunk; 1301 unsigned int udummy;
878 /* root pixmap may be bad - allow a error */ 1302
879 target->allowedxerror = -1; 1303 target->allowedxerror = -1;
880 1304
881 if (!XGetGeometry (dpy, root_pixmap, &root, &junk, &junk, &root_pmap_width, &root_pmap_height, &ujunk, &ujunk)) 1305 if (!XGetGeometry (dpy, root_pixmap, &wdummy, &idummy, &idummy, &root_pmap_width, &root_pmap_height, &udummy, &udummy))
882 root_pixmap = None; 1306 root_pixmap = None;
883 1307
884 target->allowedxerror = 0; 1308 target->allowedxerror = 0;
885 } 1309 }
886 1310
1311 Pixmap recoded_root_pmap = root_pixmap;
1312
1313 if (root_pixmap != None && root_depth != target->depth)
1314 {
1315#if XRENDER
1316 if (flags & HAS_RENDER)
1317 {
1318 XRenderPictureAttributes pa;
1319
1320 XRenderPictFormat *src_format = XRenderFindVisualFormat (dpy, DefaultVisual (dpy, screen));
1321 Picture src = XRenderCreatePicture (dpy, root_pixmap, src_format, 0, &pa);
1322
1323 recoded_root_pmap = XCreatePixmap (dpy, target->vt, root_pmap_width, root_pmap_height, target->depth);
1324 XRenderPictFormat *dst_format = XRenderFindVisualFormat (dpy, target->visual);
1325 Picture dst = XRenderCreatePicture (dpy, recoded_root_pmap, dst_format, 0, &pa);
1326
1327 if (src && dst)
1328 XRenderComposite (dpy, PictOpSrc, src, None, dst, 0, 0, 0, 0, 0, 0, root_pmap_width, root_pmap_height);
1329 else
1330 {
1331 XFreePixmap (dpy, recoded_root_pmap);
1332 root_pixmap = None;
1333 }
1334
1335 XRenderFreePicture (dpy, src);
1336 XRenderFreePicture (dpy, dst);
1337 }
1338 else
1339#endif
1340 root_pixmap = None;
1341 }
1342
1343 if (root_pixmap == None)
1344 return 0;
1345
887 Pixmap tiled_root_pmap = XCreatePixmap (dpy, root, window_width, window_height, root_depth); 1346 Pixmap tiled_root_pmap = XCreatePixmap (dpy, target->vt, window_width, window_height, target->depth);
888 GC gc = NULL;
889 1347
890 if (tiled_root_pmap == None) /* something really bad happened - abort */ 1348 if (tiled_root_pmap == None) /* something really bad happened - abort */
891 return 0; 1349 return 0;
892 1350
893 if (root_pixmap == None)
894 {
895 /* use tricks to obtain the root background image :*/
896 /* we want to create Overrideredirect window overlapping out window
897 with background type of Parent Relative and then grab it */
898 XSetWindowAttributes attr;
899 Window src;
900 bool success = false;
901
902 attr.background_pixmap = ParentRelative;
903 attr.backing_store = Always;
904 attr.event_mask = ExposureMask;
905 attr.override_redirect = True;
906 src = XCreateWindow (dpy, root, sx, sy, window_width, window_height, 0,
907 CopyFromParent, CopyFromParent, CopyFromParent,
908 CWBackPixmap|CWBackingStore|CWOverrideRedirect|CWEventMask,
909 &attr);
910
911 if (src != None)
912 {
913 XEvent event;
914 int ev_count = 0;
915 XGrabServer (dpy);
916 XMapRaised (dpy, src);
917 XSync (dpy, False);
918
919 /* XSync should get window where it's properly exposed,
920 * but to be on the safe side - let's check for the actual event to arrive : */
921 while (XCheckWindowEvent (dpy, src, ExposureMask, &event))
922 ++ev_count;
923
924 if (ev_count > 0);
925 {
926 /* hooray! - we can grab the image! */
927 gc = XCreateGC (dpy, root, 0, NULL);
928 if (gc)
929 {
930 XCopyArea (dpy, src, tiled_root_pmap, gc, 0, 0, window_width, window_height, 0, 0);
931 success = true;
932 }
933 }
934
935 XDestroyWindow (dpy, src);
936 XUngrabServer (dpy);
937 //fprintf (stderr, "%s:%d: ev_count = %d\n", __FUNCTION__, __LINE__, ev_count);
938 }
939
940 if (!success)
941 {
942 XFreePixmap (dpy, tiled_root_pmap);
943 tiled_root_pmap = None;
944 }
945 else
946 result |= transpPmapTiled;
947 }
948 else
949 {
950 /* strightforward pixmap copy */ 1351 /* straightforward pixmap copy */
951 gcv.tile = root_pixmap; 1352 gcv.tile = recoded_root_pmap;
952 gcv.fill_style = FillTiled; 1353 gcv.fill_style = FillTiled;
953 1354
954 while (sx < 0) sx += (int)root_width; 1355 while (sx < 0) sx += (int)root_width;
955 while (sy < 0) sy += (int)root_height; 1356 while (sy < 0) sy += (int)root_height;
956 1357
957 gcv.ts_x_origin = -sx; 1358 gcv.ts_x_origin = -sx;
958 gcv.ts_y_origin = -sy; 1359 gcv.ts_y_origin = -sy;
959 gc = XCreateGC (dpy, root, GCFillStyle | GCTile | GCTileStipXOrigin | GCTileStipYOrigin, &gcv); 1360 gc = XCreateGC (dpy, target->vt, GCFillStyle | GCTile | GCTileStipXOrigin | GCTileStipYOrigin, &gcv);
960 1361
961 if (gc) 1362 if (gc)
962 { 1363 {
963 XFillRectangle (dpy, tiled_root_pmap, gc, 0, 0, window_width, window_height); 1364 XFillRectangle (dpy, tiled_root_pmap, gc, 0, 0, window_width, window_height);
964 result |= transpPmapTiled; 1365 result |= transpPmapTiled;
965 } 1366 XFreeGC (dpy, gc);
966 } 1367 }
967 TIMING_TEST_PRINT_RESULT (tp);
968 1368
969 if (tiled_root_pmap != None) 1369 if (tiled_root_pmap != None)
970 { 1370 {
971 if (!need_client_side_rendering ()) 1371 if (!need_client_side_rendering ())
972 { 1372 {
1373 if ((flags & blurNeeded)
1374 && (flags & HAS_RENDER_CONV))
1375 {
1376 if (blur_pixmap (tiled_root_pmap, target->visual, window_width, window_height))
1377 result |= transpPmapBlurred;
1378 }
973 if ((flags & tintNeeded)) 1379 if ((flags & tintNeeded)
974 {
975 if (flags & tintWholesome) 1380 && (flags & (tintWholesome | HAS_RENDER)))
976 { 1381 {
977 /* In this case we can tint image server-side getting significant 1382 if (tint_pixmap (tiled_root_pmap, target->visual, window_width, window_height))
978 * performance improvements, as we eliminate XImage transfer
979 */
980 gcv.foreground = Pixel (tint);
981 gcv.function = GXand;
982 gcv.fill_style = FillSolid;
983 if (gc)
984 XChangeGC (dpy, gc, GCFillStyle | GCForeground | GCFunction, &gcv);
985 else
986 gc = XCreateGC (dpy, root, GCFillStyle | GCForeground | GCFunction, &gcv);
987 if (gc)
988 {
989 XFillRectangle (dpy, tiled_root_pmap, gc, 0, 0, window_width, window_height);
990 result |= transpPmapTinted; 1383 result |= transpPmapTinted;
991 }
992 }
993 else
994 {
995# if XFT
996 Picture back_pic = 0;
997 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC);
998
999 if (flags & tintSet)
1000 tint.get (c);
1001
1002 if (shade > 0 && shade < 100)
1003 {
1004 c.r = (c.r * shade) / 100;
1005 c.g = (c.g * shade) / 100;
1006 c.b = (c.b * shade) / 100;
1007 }
1008 else if (shade > 100 && shade < 200)
1009 {
1010 c.r = (c.r * (200 - shade)) / 100;
1011 c.g = (c.g * (200 - shade)) / 100;
1012 c.b = (c.b * (200 - shade)) / 100;
1013 }
1014
1015 XRenderPictFormat pf;
1016 pf.type = PictTypeDirect;
1017 pf.depth = 32;
1018 pf.direct.redMask = 0xff;
1019 pf.direct.greenMask = 0xff;
1020 pf.direct.blueMask = 0xff;
1021 pf.direct.alphaMask = 0xff;
1022
1023 XRenderPictFormat *solid_format = XRenderFindFormat (dpy,
1024 (PictFormatType|
1025 PictFormatDepth|
1026 PictFormatRedMask|
1027 PictFormatGreenMask|
1028 PictFormatBlueMask|
1029 PictFormatAlphaMask),
1030 &pf,
1031 0);
1032 XRenderPictFormat *root_format = XRenderFindVisualFormat (dpy, DefaultVisualOfScreen (ScreenOfDisplay (dpy, target->display->screen)));
1033 XRenderPictureAttributes pa ;
1034
1035 back_pic = XRenderCreatePicture (dpy, tiled_root_pmap, root_format, 0, &pa);
1036
1037 pa.repeat = True;
1038
1039 Pixmap overlay_pmap = XCreatePixmap (dpy, root, 1, 1, 32);
1040 Picture overlay_pic = XRenderCreatePicture (dpy, overlay_pmap, solid_format, CPRepeat, &pa);
1041 XFreePixmap (dpy, overlay_pmap);
1042
1043 pa.component_alpha = True;
1044 Pixmap mask_pmap = XCreatePixmap (dpy, root, 1, 1, 32);
1045 Picture mask_pic = XRenderCreatePicture (dpy, mask_pmap, solid_format, CPRepeat|CPComponentAlpha, &pa);
1046 XFreePixmap (dpy, mask_pmap);
1047
1048 if (mask_pic && overlay_pic && back_pic)
1049 {
1050 XRenderColor mask_c;
1051
1052 memset (&mask_c, (shade > 100) ? 0xFF : 0x0, sizeof (mask_c));
1053 mask_c.alpha = 0xffff;
1054 XRenderFillRectangle (dpy, PictOpSrc, overlay_pic, &mask_c, 0, 0, 1, 1);
1055
1056 mask_c.alpha = 0;
1057 mask_c.red = 0xffff - c.r;
1058 mask_c.green = 0xffff - c.g;
1059 mask_c.blue = 0xffff - c.b;
1060 XRenderFillRectangle (dpy, PictOpSrc, mask_pic, &mask_c, 0, 0, 1, 1);
1061 XRenderComposite (dpy, PictOpOver, overlay_pic, mask_pic, back_pic, 0, 0, 0, 0, 0, 0, window_width, window_height);
1062 result |= transpPmapTinted;
1063 }
1064
1065 XRenderFreePicture (dpy, mask_pic);
1066 XRenderFreePicture (dpy, overlay_pic);
1067 XRenderFreePicture (dpy, back_pic);
1068# if DO_TIMING_TEST
1069 XSync (dpy, False);
1070# endif
1071# endif
1072 }
1073 } 1384 }
1074 } /* server side rendering completed */ 1385 } /* server side rendering completed */
1075 1386
1076 if (pixmap) 1387 if (pixmap)
1077 XFreePixmap (dpy, pixmap); 1388 XFreePixmap (dpy, pixmap);
1078 1389
1079 pixmap = tiled_root_pmap; 1390 pixmap = tiled_root_pmap;
1080 pmap_width = window_width; 1391 pmap_width = window_width;
1081 pmap_height = window_height; 1392 pmap_height = window_height;
1082 pmap_depth = root_depth; 1393 pmap_depth = target->depth;
1083 } 1394 }
1084 1395
1085 if (gc) 1396 if (recoded_root_pmap != root_pixmap)
1086 XFreeGC (dpy, gc); 1397 XFreePixmap (dpy, recoded_root_pmap);
1087
1088 TIMING_TEST_PRINT_RESULT (tp);
1089 1398
1090 return result; 1399 return result;
1091} 1400}
1092 1401
1093bool 1402void
1094bgPixmap_t::set_root_pixmap () 1403bgPixmap_t::set_root_pixmap ()
1095{ 1404{
1096 Pixmap new_root_pixmap = target->get_pixmap_property (XA_XROOTPMAP_ID); 1405 Pixmap new_root_pixmap = target->get_pixmap_property (XA_XROOTPMAP_ID);
1097 if (new_root_pixmap == None) 1406 if (new_root_pixmap == None)
1098 new_root_pixmap = target->get_pixmap_property (XA_ESETROOT_PMAP_ID); 1407 new_root_pixmap = target->get_pixmap_property (XA_ESETROOT_PMAP_ID);
1099 1408
1100 if (new_root_pixmap != root_pixmap)
1101 {
1102 root_pixmap = new_root_pixmap; 1409 root_pixmap = new_root_pixmap;
1103 return true;
1104 }
1105
1106 return false;
1107} 1410}
1108# endif /* ENABLE_TRANSPARENCY */ 1411# endif /* ENABLE_TRANSPARENCY */
1109 1412
1110# ifndef HAVE_AFTERIMAGE 1413# ifndef HAVE_AFTERIMAGE
1111static void ShadeXImage(rxvt_term *term, XImage* srcImage, int shade, int rm, int gm, int bm); 1414static void ShadeXImage(Visual *visual, XImage *srcImage, int shade, int rm, int gm, int bm);
1112# endif 1415# endif
1113 1416
1114bool 1417bool
1115bgPixmap_t::render () 1418bgPixmap_t::render ()
1116{ 1419{
1117 unsigned long background_flags = 0; 1420 unsigned long background_flags = 0;
1118 1421
1119 if (target == NULL) 1422 if (target == NULL)
1120 return false; 1423 return false;
1121 1424
1122 TIMING_TEST_START (tp);
1123
1124 invalidate(); 1425 invalidate ();
1125# ifdef ENABLE_TRANSPARENCY 1426# ifdef ENABLE_TRANSPARENCY
1126 if (flags & isTransparent) 1427 if (flags & isTransparent)
1127 { 1428 {
1128 /* we need to re-generate transparency pixmap in that case ! */ 1429 /* we need to re-generate transparency pixmap in that case ! */
1129 background_flags = make_transparency_pixmap (); 1430 background_flags = make_transparency_pixmap ();
1130 if (background_flags == 0) 1431 if (background_flags == 0)
1131 return false; 1432 return false;
1132 else if ((background_flags & transpTransformations) == (flags & transpTransformations) 1433 else if ((background_flags & transpTransformations) == (flags & transpTransformations))
1133 && pmap_depth == target->depth)
1134 flags = flags & ~isInvalid; 1434 flags = flags & ~isInvalid;
1135 } 1435 }
1136# endif 1436# endif
1137 1437
1438# ifdef BG_IMAGE_FROM_FILE
1439 if (have_image
1440 || (background_flags & transpTransformations) != (flags & transpTransformations))
1441 {
1442 if (render_image (background_flags))
1443 flags = flags & ~isInvalid;
1444 }
1445# endif
1446
1138 XImage *result = NULL; 1447 XImage *result = NULL;
1139# ifdef HAVE_AFTERIMAGE 1448
1140 if (original_asim 1449 if (background_flags && (flags & isInvalid))
1141 || (background_flags & transpTransformations) != (flags & transpTransformations)) 1450 {
1451 result = XGetImage (target->dpy, pixmap, 0, 0, pmap_width, pmap_height, AllPlanes, ZPixmap);
1142 { 1452 }
1143 ASImage *background = NULL;
1144 ARGB32 as_tint = TINT_LEAVE_SAME;
1145 if (background_flags)
1146 background = pixmap2ximage (target->asv, pixmap, 0, 0, pmap_width, pmap_height, AllPlanes, 100);
1147 1453
1148# ifdef ENABLE_TRANSPARENCY 1454 if (result)
1455 {
1456# if !defined(HAVE_AFTERIMAGE) && !XRENDER
1457 /* our own client-side tinting */
1149 if (!(background_flags & transpPmapTinted) && (flags & tintNeeded)) 1458 if (!(background_flags & transpPmapTinted) && (flags & tintNeeded))
1150 { 1459 {
1151 ShadingInfo as_shade;
1152 as_shade.shading = (shade == 0) ? 100 : shade;
1153
1154 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC); 1460 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC);
1155 if (flags & tintSet) 1461 if (flags & tintSet)
1156 tint.get (c); 1462 tint.get (c);
1157 as_shade.tintColor.red = c.r; 1463 ShadeXImage (DefaultVisual (target->dpy, target->display->screen), result, shade, c.r, c.g, c.b);
1158 as_shade.tintColor.green = c.g;
1159 as_shade.tintColor.blue = c.b;
1160
1161 as_tint = shading2tint32 (&as_shade);
1162 }
1163 if (!(background_flags & transpPmapBlured) && (flags & blurNeeded) && background != NULL)
1164 {
1165 ASImage* tmp = blur_asimage_gauss (target->asv, background, h_blurRadius, v_blurRadius, 0xFFFFFFFF,
1166 (original_asim == NULL || tint == TINT_LEAVE_SAME)?ASA_XImage:ASA_ASImage,
1167 100, ASIMAGE_QUALITY_DEFAULT);
1168 if (tmp)
1169 {
1170 destroy_asimage (&background);
1171 background = tmp;
1172 }
1173 } 1464 }
1174# endif 1465# endif
1175 1466
1176 if (render_asim (background, as_tint))
1177 flags = flags & ~isInvalid;
1178 if (background)
1179 destroy_asimage (&background);
1180 }
1181 else if (background_flags && pmap_depth != target->depth)
1182 {
1183 result = XGetImage (target->dpy, pixmap, 0, 0, pmap_width, pmap_height, AllPlanes, ZPixmap);
1184 }
1185
1186# elif !XFT /* our own client-side tinting */
1187
1188 /* ATTENTION: We ASSUME that XFT will let us do all the tinting neccessary server-side.
1189 This may need to be changed in need_client_side_rendering() logic is altered !!! */
1190
1191 if (background_flags && (flags & isInvalid))
1192 {
1193 result = XGetImage (target->dpy, pixmap, 0, 0, pmap_width, pmap_height, AllPlanes, ZPixmap);
1194 if (result != NULL && !(background_flags & transpPmapTinted) && (flags & tintNeeded))
1195 {
1196 rgba c (rgba::MAX_CC,rgba::MAX_CC,rgba::MAX_CC);
1197 if (flags & tintSet)
1198 tint.get (c);
1199 ShadeXImage (target, result, shade, c.r, c.g, c.b);
1200 }
1201 }
1202# endif /* HAVE_AFTERIMAGE */
1203
1204 if (result)
1205 {
1206 GC gc = XCreateGC (target->dpy, target->vt, 0UL, NULL); 1467 GC gc = XCreateGC (target->dpy, target->vt, 0UL, NULL);
1207 1468
1208 if (gc) 1469 if (gc)
1209 { 1470 {
1210 if (/*pmap_depth != target->depth &&*/ pixmap != None)
1211 {
1212 XFreePixmap (target->dpy, pixmap);
1213 pixmap = None;
1214 }
1215
1216 if (pixmap == None)
1217 {
1218 pixmap = XCreatePixmap (target->dpy, target->vt, result->width, result->height, target->depth);
1219 pmap_width = result->width;
1220 pmap_height = result->height;
1221 pmap_depth = target->depth;
1222 }
1223
1224 if (pmap_depth != result->depth)
1225 {
1226 /* Bad Match error will ensue ! stupid X !!!! */
1227 if (result->depth == 24 && pmap_depth == 32)
1228 result->depth = 32;
1229 else if (result->depth == 32 && pmap_depth == 24)
1230 result->depth = 24;
1231 else
1232 {
1233 /* TODO: implement image recoding */
1234 }
1235 }
1236
1237 if (pmap_depth == result->depth)
1238 XPutImage (target->dpy, pixmap, gc, result, 0, 0, 0, 0, result->width, result->height); 1471 XPutImage (target->dpy, pixmap, gc, result, 0, 0, 0, 0, result->width, result->height);
1239 1472
1240 XFreeGC (target->dpy, gc); 1473 XFreeGC (target->dpy, gc);
1241 flags = flags & ~isInvalid; 1474 flags = flags & ~isInvalid;
1242 } 1475 }
1243 1476
1244 XDestroyImage (result); 1477 XDestroyImage (result);
1245 } 1478 }
1246 1479
1247 if (flags & isInvalid) 1480 if (flags & isInvalid)
1248 { 1481 {
1249 if (pixmap != None) 1482 if (pixmap != None)
1253 } 1486 }
1254 } 1487 }
1255 1488
1256 apply (); 1489 apply ();
1257 1490
1258 XSync (target->dpy, False);
1259 valid_since = ev::now (); 1491 valid_since = ev::now ();
1260 1492
1261 TIMING_TEST_PRINT_RESULT (tp);
1262
1263 return true; 1493 return true;
1264} 1494}
1265 1495
1266bool 1496void
1267bgPixmap_t::set_target (rxvt_term *new_target) 1497bgPixmap_t::set_target (rxvt_term *new_target)
1268{ 1498{
1269 if (new_target)
1270 if (target != new_target)
1271 {
1272 target = new_target; 1499 target = new_target;
1273# ifdef ENABLE_TRANSPARENCY 1500
1274 root_depth = DefaultDepthOfScreen (ScreenOfDisplay (target->dpy, target->display->screen)); 1501 flags &= ~(HAS_RENDER | HAS_RENDER_CONV);
1502#if XRENDER
1503 int major, minor;
1504 if (XRenderQueryVersion (target->dpy, &major, &minor))
1505 flags |= HAS_RENDER;
1506 XFilters *filters = XRenderQueryFilters (target->dpy, target->vt);
1507 if (filters)
1508 {
1509 for (int i = 0; i < filters->nfilter; i++)
1510 if (!strcmp (filters->filter[i], FilterConvolution))
1511 flags |= HAS_RENDER_CONV;
1512
1513 XFree (filters);
1514 }
1275# endif 1515#endif
1276 return true;
1277 }
1278 return false;
1279} 1516}
1280 1517
1281void 1518void
1282bgPixmap_t::apply () 1519bgPixmap_t::apply ()
1283{ 1520{
1284 if (target) 1521 if (target == NULL)
1285 { 1522 return;
1286 flags &= ~isVtOrigin; 1523
1287 if (pixmap != None) 1524 if (pixmap != None)
1288 { 1525 {
1289 /* set target's background to pixmap */ 1526 /* set target's background to pixmap */
1290# ifdef ENABLE_TRANSPARENCY 1527# ifdef ENABLE_TRANSPARENCY
1291 if (flags & isTransparent) 1528 if (flags & isTransparent)
1292 { 1529 {
1293 XSetWindowBackgroundPixmap (target->dpy, target->parent[0], pixmap); 1530 XSetWindowBackgroundPixmap (target->dpy, target->parent[0], pixmap);
1294 XSetWindowBackgroundPixmap (target->dpy, target->vt, ParentRelative); 1531 XSetWindowBackgroundPixmap (target->dpy, target->vt, ParentRelative);
1532
1295 if (target->scrollBar.win) 1533 if (target->scrollBar.win)
1296 XSetWindowBackgroundPixmap (target->dpy, target->scrollBar.win, ParentRelative); 1534 XSetWindowBackgroundPixmap (target->dpy, target->scrollBar.win, ParentRelative);
1297 } 1535 }
1298 else 1536 else
1299# endif 1537# endif
1300 { 1538 {
1301 flags |= isVtOrigin;
1302 /* force old pixmap dereference in case it was transparent before :*/ 1539 /* force old pixmap dereference in case it was transparent before :*/
1303 XSetWindowBackground (target->dpy, target->parent[0], target->pix_colors[Color_border]);
1304 XSetWindowBackgroundPixmap (target->dpy, target->vt, pixmap);
1305 /* do we also need to set scrollbar's background here ? */
1306 if (target->scrollBar.win)
1307 XSetWindowBackground (target->dpy, target->scrollBar.win, target->pix_colors[Color_border]);
1308 }
1309 }
1310 else
1311 {
1312 /* set target background to a pixel */
1313 XSetWindowBackground (target->dpy, target->parent[0], target->pix_colors[Color_border]); 1540 XSetWindowBackground (target->dpy, target->parent[0], target->pix_colors[Color_border]);
1314 XSetWindowBackground (target->dpy, target->vt, target->pix_colors[Color_bg]); 1541 XSetWindowBackgroundPixmap (target->dpy, target->vt, pixmap);
1315 /* do we also need to set scrollbar's background here ? */ 1542 /* do we also need to set scrollbar's background here ? */
1543
1316 if (target->scrollBar.win) 1544 if (target->scrollBar.win)
1317 XSetWindowBackground (target->dpy, target->scrollBar.win, target->pix_colors[Color_border]); 1545 XSetWindowBackground (target->dpy, target->scrollBar.win, target->pix_colors[Color_border]);
1318 } 1546 }
1319 /* don't want Expose on the parent or vt. It is better to use 1547 }
1320 scr_touch or we get a great deal of flicker otherwise: */ 1548 else
1321 XClearWindow (target->dpy, target->parent[0]); 1549 {
1322 1550 /* set target background to a pixel */
1551 XSetWindowBackground (target->dpy, target->parent[0], target->pix_colors[Color_border]);
1552 XSetWindowBackground (target->dpy, target->vt, target->pix_colors[Color_bg]);
1553 /* do we also need to set scrollbar's background here ? */
1323 if (target->scrollBar.win) 1554 if (target->scrollBar.win)
1324 { 1555 XSetWindowBackground (target->dpy, target->scrollBar.win, target->pix_colors[Color_border]);
1325 target->scrollBar.setIdle (); 1556 }
1557
1558 /* don't want Expose on the parent or vt. It is better to use
1559 scr_touch or we get a great deal of flicker otherwise: */
1560 XClearWindow (target->dpy, target->parent[0]);
1561
1562 if (target->scrollBar.state && target->scrollBar.win)
1563 {
1564 target->scrollBar.state = STATE_IDLE;
1326 target->scrollbar_show (0); 1565 target->scrollBar.show (0);
1327 } 1566 }
1328 1567
1329 target->want_refresh = 1; 1568 target->want_refresh = 1;
1330 flags |= hasChanged; 1569 flags |= hasChanged;
1331 }
1332} 1570}
1333 1571
1334#endif /* HAVE_BG_PIXMAP */ 1572#endif /* HAVE_BG_PIXMAP */
1335 1573
1336#if defined(ENABLE_TRANSPARENCY) && !defined(HAVE_AFTERIMAGE) && !XFT 1574#if defined(ENABLE_TRANSPARENCY) && !defined(HAVE_AFTERIMAGE) && !XRENDER
1337/* taken from aterm-0.4.2 */ 1575/* taken from aterm-0.4.2 */
1338 1576
1339typedef uint32_t RUINT32T;
1340
1341static void 1577static void
1342ShadeXImage(rxvt_term *term, XImage* srcImage, int shade, int rm, int gm, int bm) 1578ShadeXImage(Visual *visual, XImage *srcImage, int shade, int rm, int gm, int bm)
1343{ 1579{
1344 int sh_r, sh_g, sh_b; 1580 int sh_r, sh_g, sh_b;
1345 RUINT32T mask_r, mask_g, mask_b; 1581 uint32_t mask_r, mask_g, mask_b;
1346 RUINT32T *lookup, *lookup_r, *lookup_g, *lookup_b; 1582 uint32_t *lookup, *lookup_r, *lookup_g, *lookup_b;
1347 unsigned int lower_lim_r, lower_lim_g, lower_lim_b; 1583 unsigned int lower_lim_r, lower_lim_g, lower_lim_b;
1348 unsigned int upper_lim_r, upper_lim_g, upper_lim_b; 1584 unsigned int upper_lim_r, upper_lim_g, upper_lim_b;
1349 int i; 1585 int i;
1586 int host_byte_order = byteorder.big_endian () ? MSBFirst : LSBFirst;
1350 1587
1351 Visual *visual = term->visual;
1352
1353 if (visual->c_class != TrueColor || srcImage->format != ZPixmap) return ; 1588 if (visual->c_class != TrueColor || srcImage->format != ZPixmap) return;
1354
1355 if (shade == 0)
1356 shade = 100;
1357 1589
1358 /* for convenience */ 1590 /* for convenience */
1359 mask_r = visual->red_mask; 1591 mask_r = visual->red_mask;
1360 mask_g = visual->green_mask; 1592 mask_g = visual->green_mask;
1361 mask_b = visual->blue_mask; 1593 mask_b = visual->blue_mask;
1362 1594
1363 /* boring lookup table pre-initialization */ 1595 /* boring lookup table pre-initialization */
1364 switch (srcImage->bits_per_pixel) { 1596 switch (srcImage->depth)
1597 {
1365 case 15: 1598 case 15:
1366 if ((mask_r != 0x7c00) || 1599 if ((mask_r != 0x7c00) ||
1367 (mask_g != 0x03e0) || 1600 (mask_g != 0x03e0) ||
1368 (mask_b != 0x001f)) 1601 (mask_b != 0x001f))
1369 return; 1602 return;
1370 lookup = (RUINT32T *) malloc (sizeof (RUINT32T)*(32+32+32)); 1603 lookup = (uint32_t *) malloc (sizeof (uint32_t)*(32+32+32));
1371 lookup_r = lookup; 1604 lookup_r = lookup;
1372 lookup_g = lookup+32; 1605 lookup_g = lookup+32;
1373 lookup_b = lookup+32+32; 1606 lookup_b = lookup+32+32;
1374 sh_r = 10; 1607 sh_r = 10;
1375 sh_g = 5; 1608 sh_g = 5;
1376 sh_b = 0; 1609 sh_b = 0;
1377 break; 1610 break;
1378 case 16: 1611 case 16:
1379 if ((mask_r != 0xf800) || 1612 if ((mask_r != 0xf800) ||
1380 (mask_g != 0x07e0) || 1613 (mask_g != 0x07e0) ||
1381 (mask_b != 0x001f)) 1614 (mask_b != 0x001f))
1382 return; 1615 return;
1383 lookup = (RUINT32T *) malloc (sizeof (RUINT32T)*(32+64+32)); 1616 lookup = (uint32_t *) malloc (sizeof (uint32_t)*(32+64+32));
1384 lookup_r = lookup; 1617 lookup_r = lookup;
1385 lookup_g = lookup+32; 1618 lookup_g = lookup+32;
1386 lookup_b = lookup+32+64; 1619 lookup_b = lookup+32+64;
1387 sh_r = 11; 1620 sh_r = 11;
1388 sh_g = 5; 1621 sh_g = 5;
1389 sh_b = 0; 1622 sh_b = 0;
1390 break; 1623 break;
1391 case 24: 1624 case 24:
1392 if ((mask_r != 0xff0000) || 1625 if ((mask_r != 0xff0000) ||
1393 (mask_g != 0x00ff00) || 1626 (mask_g != 0x00ff00) ||
1394 (mask_b != 0x0000ff)) 1627 (mask_b != 0x0000ff))
1395 return; 1628 return;
1396 lookup = (RUINT32T *) malloc (sizeof (RUINT32T)*(256+256+256)); 1629 lookup = (uint32_t *) malloc (sizeof (uint32_t)*(256+256+256));
1397 lookup_r = lookup; 1630 lookup_r = lookup;
1398 lookup_g = lookup+256; 1631 lookup_g = lookup+256;
1399 lookup_b = lookup+256+256; 1632 lookup_b = lookup+256+256;
1400 sh_r = 16; 1633 sh_r = 16;
1401 sh_g = 8; 1634 sh_g = 8;
1402 sh_b = 0; 1635 sh_b = 0;
1403 break; 1636 break;
1404 case 32: 1637 case 32:
1405 if ((mask_r != 0xff0000) || 1638 if ((mask_r != 0xff0000) ||
1406 (mask_g != 0x00ff00) || 1639 (mask_g != 0x00ff00) ||
1407 (mask_b != 0x0000ff)) 1640 (mask_b != 0x0000ff))
1408 return; 1641 return;
1409 lookup = (RUINT32T *) malloc (sizeof (RUINT32T)*(256+256+256)); 1642 lookup = (uint32_t *) malloc (sizeof (uint32_t)*(256+256+256));
1410 lookup_r = lookup; 1643 lookup_r = lookup;
1411 lookup_g = lookup+256; 1644 lookup_g = lookup+256;
1412 lookup_b = lookup+256+256; 1645 lookup_b = lookup+256+256;
1413 sh_r = 16; 1646 sh_r = 16;
1414 sh_g = 8; 1647 sh_g = 8;
1415 sh_b = 0; 1648 sh_b = 0;
1416 break; 1649 break;
1417 default: 1650 default:
1418 return; /* we do not support this color depth */ 1651 return; /* we do not support this color depth */
1419 } 1652 }
1420 1653
1421 /* prepare limits for color transformation (each channel is handled separately) */ 1654 /* prepare limits for color transformation (each channel is handled separately) */
1422 if (shade < 0) { 1655 if (shade > 100)
1656 {
1423 shade = -shade; 1657 shade = 200 - shade;
1424 if (shade < 0) shade = 0;
1425 if (shade > 100) shade = 100;
1426 1658
1427 lower_lim_r = 65535-rm; 1659 lower_lim_r = 65535-rm;
1428 lower_lim_g = 65535-gm; 1660 lower_lim_g = 65535-gm;
1429 lower_lim_b = 65535-bm; 1661 lower_lim_b = 65535-bm;
1430 1662
1431 lower_lim_r = 65535-(unsigned int)(((RUINT32T)lower_lim_r)*((RUINT32T)shade)/100); 1663 lower_lim_r = 65535-(unsigned int)(((uint32_t)lower_lim_r)*((uint32_t)shade)/100);
1432 lower_lim_g = 65535-(unsigned int)(((RUINT32T)lower_lim_g)*((RUINT32T)shade)/100); 1664 lower_lim_g = 65535-(unsigned int)(((uint32_t)lower_lim_g)*((uint32_t)shade)/100);
1433 lower_lim_b = 65535-(unsigned int)(((RUINT32T)lower_lim_b)*((RUINT32T)shade)/100); 1665 lower_lim_b = 65535-(unsigned int)(((uint32_t)lower_lim_b)*((uint32_t)shade)/100);
1434 1666
1435 upper_lim_r = upper_lim_g = upper_lim_b = 65535; 1667 upper_lim_r = upper_lim_g = upper_lim_b = 65535;
1668 }
1436 } else { 1669 else
1437 if (shade < 0) shade = 0; 1670 {
1438 if (shade > 100) shade = 100;
1439 1671
1440 lower_lim_r = lower_lim_g = lower_lim_b = 0; 1672 lower_lim_r = lower_lim_g = lower_lim_b = 0;
1441 1673
1442 upper_lim_r = (unsigned int)((((RUINT32T)rm)*((RUINT32T)shade))/100); 1674 upper_lim_r = (unsigned int)((((uint32_t)rm)*((uint32_t)shade))/100);
1443 upper_lim_g = (unsigned int)((((RUINT32T)gm)*((RUINT32T)shade))/100); 1675 upper_lim_g = (unsigned int)((((uint32_t)gm)*((uint32_t)shade))/100);
1444 upper_lim_b = (unsigned int)((((RUINT32T)bm)*((RUINT32T)shade))/100); 1676 upper_lim_b = (unsigned int)((((uint32_t)bm)*((uint32_t)shade))/100);
1445 } 1677 }
1446
1447 /* switch red and blue bytes if necessary, we need it for some weird XServers like XFree86 3.3.3.1 */
1448 if ((srcImage->bits_per_pixel == 24) && (mask_r >= 0xFF0000 ))
1449 {
1450 unsigned int tmp;
1451
1452 tmp = lower_lim_r;
1453 lower_lim_r = lower_lim_b;
1454 lower_lim_b = tmp;
1455
1456 tmp = upper_lim_r;
1457 upper_lim_r = upper_lim_b;
1458 upper_lim_b = tmp;
1459 }
1460 1678
1461 /* fill our lookup tables */ 1679 /* fill our lookup tables */
1462 for (i = 0; i <= mask_r>>sh_r; i++) 1680 for (i = 0; i <= mask_r>>sh_r; i++)
1463 { 1681 {
1464 RUINT32T tmp; 1682 uint32_t tmp;
1465 tmp = ((RUINT32T)i)*((RUINT32T)(upper_lim_r-lower_lim_r)); 1683 tmp = ((uint32_t)i)*((uint32_t)(upper_lim_r-lower_lim_r));
1466 tmp += ((RUINT32T)(mask_r>>sh_r))*((RUINT32T)lower_lim_r); 1684 tmp += ((uint32_t)(mask_r>>sh_r))*((uint32_t)lower_lim_r);
1467 lookup_r[i] = (tmp/65535)<<sh_r; 1685 lookup_r[i] = (tmp/65535)<<sh_r;
1468 } 1686 }
1469 for (i = 0; i <= mask_g>>sh_g; i++) 1687 for (i = 0; i <= mask_g>>sh_g; i++)
1470 { 1688 {
1471 RUINT32T tmp; 1689 uint32_t tmp;
1472 tmp = ((RUINT32T)i)*((RUINT32T)(upper_lim_g-lower_lim_g)); 1690 tmp = ((uint32_t)i)*((uint32_t)(upper_lim_g-lower_lim_g));
1473 tmp += ((RUINT32T)(mask_g>>sh_g))*((RUINT32T)lower_lim_g); 1691 tmp += ((uint32_t)(mask_g>>sh_g))*((uint32_t)lower_lim_g);
1474 lookup_g[i] = (tmp/65535)<<sh_g; 1692 lookup_g[i] = (tmp/65535)<<sh_g;
1475 } 1693 }
1476 for (i = 0; i <= mask_b>>sh_b; i++) 1694 for (i = 0; i <= mask_b>>sh_b; i++)
1477 { 1695 {
1478 RUINT32T tmp; 1696 uint32_t tmp;
1479 tmp = ((RUINT32T)i)*((RUINT32T)(upper_lim_b-lower_lim_b)); 1697 tmp = ((uint32_t)i)*((uint32_t)(upper_lim_b-lower_lim_b));
1480 tmp += ((RUINT32T)(mask_b>>sh_b))*((RUINT32T)lower_lim_b); 1698 tmp += ((uint32_t)(mask_b>>sh_b))*((uint32_t)lower_lim_b);
1481 lookup_b[i] = (tmp/65535)<<sh_b; 1699 lookup_b[i] = (tmp/65535)<<sh_b;
1482 } 1700 }
1483 1701
1484 /* apply table to input image (replacing colors by newly calculated ones) */ 1702 /* apply table to input image (replacing colors by newly calculated ones) */
1485 switch (srcImage->bits_per_pixel) 1703 if (srcImage->bits_per_pixel == 32
1704 && (srcImage->depth == 24 || srcImage->depth == 32)
1705 && srcImage->byte_order == host_byte_order)
1486 { 1706 {
1487 case 15:
1488 {
1489 unsigned short *p1, *pf, *p, *pl; 1707 uint32_t *p1, *pf, *p, *pl;
1490 p1 = (unsigned short *) srcImage->data; 1708 p1 = (uint32_t *) srcImage->data;
1491 pf = (unsigned short *) (srcImage->data + srcImage->height * srcImage->bytes_per_line); 1709 pf = (uint32_t *) (srcImage->data + srcImage->height * srcImage->bytes_per_line);
1710
1492 while (p1 < pf) 1711 while (p1 < pf)
1493 { 1712 {
1494 p = p1; 1713 p = p1;
1495 pl = p1 + srcImage->width; 1714 pl = p1 + srcImage->width;
1496 for (; p < pl; p++) 1715 for (; p < pl; p++)
1497 { 1716 {
1498 *p = lookup_r[(*p & 0x7c00)>>10] |
1499 lookup_g[(*p & 0x03e0)>> 5] |
1500 lookup_b[(*p & 0x001f)];
1501 }
1502 p1 = (unsigned short *) ((char *) p1 + srcImage->bytes_per_line);
1503 }
1504 break;
1505 }
1506 case 16:
1507 {
1508 unsigned short *p1, *pf, *p, *pl;
1509 p1 = (unsigned short *) srcImage->data;
1510 pf = (unsigned short *) (srcImage->data + srcImage->height * srcImage->bytes_per_line);
1511 while (p1 < pf)
1512 {
1513 p = p1;
1514 pl = p1 + srcImage->width;
1515 for (; p < pl; p++)
1516 {
1517 *p = lookup_r[(*p & 0xf800)>>11] |
1518 lookup_g[(*p & 0x07e0)>> 5] |
1519 lookup_b[(*p & 0x001f)];
1520 }
1521 p1 = (unsigned short *) ((char *) p1 + srcImage->bytes_per_line);
1522 }
1523 break;
1524 }
1525 case 24:
1526 {
1527 unsigned char *p1, *pf, *p, *pl;
1528 p1 = (unsigned char *) srcImage->data;
1529 pf = (unsigned char *) (srcImage->data + srcImage->height * srcImage->bytes_per_line);
1530 while (p1 < pf)
1531 {
1532 p = p1;
1533 pl = p1 + srcImage->width * 3;
1534 for (; p < pl; p += 3)
1535 {
1536 p[0] = lookup_r[(p[0] & 0xff0000)>>16];
1537 p[1] = lookup_r[(p[1] & 0x00ff00)>> 8];
1538 p[2] = lookup_r[(p[2] & 0x0000ff)];
1539 }
1540 p1 = (unsigned char *) ((char *) p1 + srcImage->bytes_per_line);
1541 }
1542 break;
1543 }
1544 case 32:
1545 {
1546 RUINT32T *p1, *pf, *p, *pl;
1547 p1 = (RUINT32T *) srcImage->data;
1548 pf = (RUINT32T *) (srcImage->data + srcImage->height * srcImage->bytes_per_line);
1549
1550 while (p1 < pf)
1551 {
1552 p = p1;
1553 pl = p1 + srcImage->width;
1554 for (; p < pl; p++)
1555 {
1556 *p = lookup_r[(*p & 0xff0000)>>16] | 1717 *p = lookup_r[(*p & 0xff0000) >> 16] |
1557 lookup_g[(*p & 0x00ff00)>> 8] | 1718 lookup_g[(*p & 0x00ff00) >> 8] |
1558 lookup_b[(*p & 0x0000ff)] | 1719 lookup_b[(*p & 0x0000ff)] |
1559 (*p & ~0xffffff); 1720 (*p & 0xff000000);
1721 }
1722 p1 = (uint32_t *) ((char *) p1 + srcImage->bytes_per_line);
1723 }
1724 }
1725 else
1726 {
1727 for (int y = 0; y < srcImage->height; y++)
1728 for (int x = 0; x < srcImage->width; x++)
1729 {
1730 unsigned long pixel = XGetPixel (srcImage, x, y);
1731 pixel = lookup_r[(pixel & mask_r) >> sh_r] |
1732 lookup_g[(pixel & mask_g) >> sh_g] |
1733 lookup_b[(pixel & mask_b) >> sh_b];
1734 XPutPixel (srcImage, x, y, pixel);
1560 } 1735 }
1561 p1 = (RUINT32T *) ((char *) p1 + srcImage->bytes_per_line);
1562 } 1736 }
1563 break;
1564 }
1565 }
1566 1737
1567 free (lookup); 1738 free (lookup);
1568} 1739}
1569#endif /* defined(ENABLE_TRANSPARENCY) && !defined(HAVE_AFTERIMAGE) */ 1740#endif /* defined(ENABLE_TRANSPARENCY) && !defined(HAVE_AFTERIMAGE) */

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