xref: /openbmc/qemu/hw/display/blizzard.c (revision 2df1eb27)
1 /*
2  * Epson S1D13744/S1D13745 (Blizzard/Hailstorm/Tornado) LCD/TV controller.
3  *
4  * Copyright (C) 2008 Nokia Corporation
5  * Written by Andrzej Zaborowski <andrew@openedhand.com>
6  *
7  * This program is free software; you can redistribute it and/or
8  * modify it under the terms of the GNU General Public License as
9  * published by the Free Software Foundation; either version 2 or
10  * (at your option) version 3 of the License.
11  *
12  * This program is distributed in the hope that it will be useful,
13  * but WITHOUT ANY WARRANTY; without even the implied warranty of
14  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
15  * GNU General Public License for more details.
16  *
17  * You should have received a copy of the GNU General Public License along
18  * with this program; if not, see <http://www.gnu.org/licenses/>.
19  */
20 
21 #include "qemu/osdep.h"
22 #include "qemu/bitops.h"
23 #include "ui/console.h"
24 #include "hw/display/blizzard.h"
25 #include "ui/pixel_ops.h"
26 
27 typedef void (*blizzard_fn_t)(uint8_t *, const uint8_t *, unsigned int);
28 
29 typedef struct {
30     uint8_t reg;
31     uint32_t addr;
32     int swallow;
33 
34     int pll;
35     int pll_range;
36     int pll_ctrl;
37     uint8_t pll_mode;
38     uint8_t clksel;
39     int memenable;
40     int memrefresh;
41     uint8_t timing[3];
42     int priority;
43 
44     uint8_t lcd_config;
45     int x;
46     int y;
47     int skipx;
48     int skipy;
49     uint8_t hndp;
50     uint8_t vndp;
51     uint8_t hsync;
52     uint8_t vsync;
53     uint8_t pclk;
54     uint8_t u;
55     uint8_t v;
56     uint8_t yrc[2];
57     int ix[2];
58     int iy[2];
59     int ox[2];
60     int oy[2];
61 
62     int enable;
63     int blank;
64     int bpp;
65     int invalidate;
66     int mx[2];
67     int my[2];
68     uint8_t mode;
69     uint8_t effect;
70     uint8_t iformat;
71     uint8_t source;
72     QemuConsole *con;
73     blizzard_fn_t *line_fn_tab[2];
74     void *fb;
75 
76     uint8_t hssi_config[3];
77     uint8_t tv_config;
78     uint8_t tv_timing[4];
79     uint8_t vbi;
80     uint8_t tv_x;
81     uint8_t tv_y;
82     uint8_t tv_test;
83     uint8_t tv_filter_config;
84     uint8_t tv_filter_idx;
85     uint8_t tv_filter_coeff[0x20];
86     uint8_t border_r;
87     uint8_t border_g;
88     uint8_t border_b;
89     uint8_t gamma_config;
90     uint8_t gamma_idx;
91     uint8_t gamma_lut[0x100];
92     uint8_t matrix_ena;
93     uint8_t matrix_coeff[0x12];
94     uint8_t matrix_r;
95     uint8_t matrix_g;
96     uint8_t matrix_b;
97     uint8_t pm;
98     uint8_t status;
99     uint8_t rgbgpio_dir;
100     uint8_t rgbgpio;
101     uint8_t gpio_dir;
102     uint8_t gpio;
103     uint8_t gpio_edge[2];
104     uint8_t gpio_irq;
105     uint8_t gpio_pdown;
106 
107     struct {
108         int x;
109         int y;
110         int dx;
111         int dy;
112         int len;
113         int buflen;
114         void *buf;
115         void *data;
116         uint16_t *ptr;
117         int angle;
118         int pitch;
119         blizzard_fn_t line_fn;
120     } data;
121 } BlizzardState;
122 
123 /* Bytes(!) per pixel */
124 static const int blizzard_iformat_bpp[0x10] = {
125     0,
126     2,  /* RGB 5:6:5*/
127     3,  /* RGB 6:6:6 mode 1 */
128     3,  /* RGB 8:8:8 mode 1 */
129     0, 0,
130     4,  /* RGB 6:6:6 mode 2 */
131     4,  /* RGB 8:8:8 mode 2 */
132     0,  /* YUV 4:2:2 */
133     0,  /* YUV 4:2:0 */
134     0, 0, 0, 0, 0, 0,
135 };
136 
137 static void blizzard_window(BlizzardState *s)
138 {
139     DisplaySurface *surface = qemu_console_surface(s->con);
140     uint8_t *src, *dst;
141     int bypp[2];
142     int bypl[3];
143     int y;
144     blizzard_fn_t fn = s->data.line_fn;
145 
146     if (!fn)
147         return;
148     if (s->mx[0] > s->data.x)
149         s->mx[0] = s->data.x;
150     if (s->my[0] > s->data.y)
151         s->my[0] = s->data.y;
152     if (s->mx[1] < s->data.x + s->data.dx)
153         s->mx[1] = s->data.x + s->data.dx;
154     if (s->my[1] < s->data.y + s->data.dy)
155         s->my[1] = s->data.y + s->data.dy;
156 
157     bypp[0] = s->bpp;
158     bypp[1] = surface_bytes_per_pixel(surface);
159     bypl[0] = bypp[0] * s->data.pitch;
160     bypl[1] = bypp[1] * s->x;
161     bypl[2] = bypp[0] * s->data.dx;
162 
163     src = s->data.data;
164     dst = s->fb + bypl[1] * s->data.y + bypp[1] * s->data.x;
165     for (y = s->data.dy; y > 0; y --, src += bypl[0], dst += bypl[1])
166         fn(dst, src, bypl[2]);
167 }
168 
169 static int blizzard_transfer_setup(BlizzardState *s)
170 {
171     if (s->source > 3 || !s->bpp ||
172                     s->ix[1] < s->ix[0] || s->iy[1] < s->iy[0])
173         return 0;
174 
175     s->data.angle = s->effect & 3;
176     s->data.line_fn = s->line_fn_tab[!!s->data.angle][s->iformat];
177     s->data.x = s->ix[0];
178     s->data.y = s->iy[0];
179     s->data.dx = s->ix[1] - s->ix[0] + 1;
180     s->data.dy = s->iy[1] - s->iy[0] + 1;
181     s->data.len = s->bpp * s->data.dx * s->data.dy;
182     s->data.pitch = s->data.dx;
183     if (s->data.len > s->data.buflen) {
184         s->data.buf = g_realloc(s->data.buf, s->data.len);
185         s->data.buflen = s->data.len;
186     }
187     s->data.ptr = s->data.buf;
188     s->data.data = s->data.buf;
189     s->data.len /= 2;
190     return 1;
191 }
192 
193 static void blizzard_reset(BlizzardState *s)
194 {
195     s->reg = 0;
196     s->swallow = 0;
197 
198     s->pll = 9;
199     s->pll_range = 1;
200     s->pll_ctrl = 0x14;
201     s->pll_mode = 0x32;
202     s->clksel = 0x00;
203     s->memenable = 0;
204     s->memrefresh = 0x25c;
205     s->timing[0] = 0x3f;
206     s->timing[1] = 0x13;
207     s->timing[2] = 0x21;
208     s->priority = 0;
209 
210     s->lcd_config = 0x74;
211     s->x = 8;
212     s->y = 1;
213     s->skipx = 0;
214     s->skipy = 0;
215     s->hndp = 3;
216     s->vndp = 2;
217     s->hsync = 1;
218     s->vsync = 1;
219     s->pclk = 0x80;
220 
221     s->ix[0] = 0;
222     s->ix[1] = 0;
223     s->iy[0] = 0;
224     s->iy[1] = 0;
225     s->ox[0] = 0;
226     s->ox[1] = 0;
227     s->oy[0] = 0;
228     s->oy[1] = 0;
229 
230     s->yrc[0] = 0x00;
231     s->yrc[1] = 0x30;
232     s->u = 0;
233     s->v = 0;
234 
235     s->iformat = 3;
236     s->source = 0;
237     s->bpp = blizzard_iformat_bpp[s->iformat];
238 
239     s->hssi_config[0] = 0x00;
240     s->hssi_config[1] = 0x00;
241     s->hssi_config[2] = 0x01;
242     s->tv_config = 0x00;
243     s->tv_timing[0] = 0x00;
244     s->tv_timing[1] = 0x00;
245     s->tv_timing[2] = 0x00;
246     s->tv_timing[3] = 0x00;
247     s->vbi = 0x10;
248     s->tv_x = 0x14;
249     s->tv_y = 0x03;
250     s->tv_test = 0x00;
251     s->tv_filter_config = 0x80;
252     s->tv_filter_idx = 0x00;
253     s->border_r = 0x10;
254     s->border_g = 0x80;
255     s->border_b = 0x80;
256     s->gamma_config = 0x00;
257     s->gamma_idx = 0x00;
258     s->matrix_ena = 0x00;
259     memset(&s->matrix_coeff, 0, sizeof(s->matrix_coeff));
260     s->matrix_r = 0x00;
261     s->matrix_g = 0x00;
262     s->matrix_b = 0x00;
263     s->pm = 0x02;
264     s->status = 0x00;
265     s->rgbgpio_dir = 0x00;
266     s->gpio_dir = 0x00;
267     s->gpio_edge[0] = 0x00;
268     s->gpio_edge[1] = 0x00;
269     s->gpio_irq = 0x00;
270     s->gpio_pdown = 0xff;
271 }
272 
273 static inline void blizzard_invalidate_display(void *opaque) {
274     BlizzardState *s = (BlizzardState *) opaque;
275 
276     s->invalidate = 1;
277 }
278 
279 static uint16_t blizzard_reg_read(void *opaque, uint8_t reg)
280 {
281     BlizzardState *s = (BlizzardState *) opaque;
282 
283     switch (reg) {
284     case 0x00:  /* Revision Code */
285         return 0xa5;
286 
287     case 0x02:  /* Configuration Readback */
288         return 0x83;    /* Macrovision OK, CNF[2:0] = 3 */
289 
290     case 0x04:  /* PLL M-Divider */
291         return (s->pll - 1) | (1 << 7);
292     case 0x06:  /* PLL Lock Range Control */
293         return s->pll_range;
294     case 0x08:  /* PLL Lock Synthesis Control 0 */
295         return s->pll_ctrl & 0xff;
296     case 0x0a:  /* PLL Lock Synthesis Control 1 */
297         return s->pll_ctrl >> 8;
298     case 0x0c:  /* PLL Mode Control 0 */
299         return s->pll_mode;
300 
301     case 0x0e:  /* Clock-Source Select */
302         return s->clksel;
303 
304     case 0x10:  /* Memory Controller Activate */
305     case 0x14:  /* Memory Controller Bank 0 Status Flag */
306         return s->memenable;
307 
308     case 0x18:  /* Auto-Refresh Interval Setting 0 */
309         return s->memrefresh & 0xff;
310     case 0x1a:  /* Auto-Refresh Interval Setting 1 */
311         return s->memrefresh >> 8;
312 
313     case 0x1c:  /* Power-On Sequence Timing Control */
314         return s->timing[0];
315     case 0x1e:  /* Timing Control 0 */
316         return s->timing[1];
317     case 0x20:  /* Timing Control 1 */
318         return s->timing[2];
319 
320     case 0x24:  /* Arbitration Priority Control */
321         return s->priority;
322 
323     case 0x28:  /* LCD Panel Configuration */
324         return s->lcd_config;
325 
326     case 0x2a:  /* LCD Horizontal Display Width */
327         return s->x >> 3;
328     case 0x2c:  /* LCD Horizontal Non-display Period */
329         return s->hndp;
330     case 0x2e:  /* LCD Vertical Display Height 0 */
331         return s->y & 0xff;
332     case 0x30:  /* LCD Vertical Display Height 1 */
333         return s->y >> 8;
334     case 0x32:  /* LCD Vertical Non-display Period */
335         return s->vndp;
336     case 0x34:  /* LCD HS Pulse-width */
337         return s->hsync;
338     case 0x36:  /* LCd HS Pulse Start Position */
339         return s->skipx >> 3;
340     case 0x38:  /* LCD VS Pulse-width */
341         return s->vsync;
342     case 0x3a:  /* LCD VS Pulse Start Position */
343         return s->skipy;
344 
345     case 0x3c:  /* PCLK Polarity */
346         return s->pclk;
347 
348     case 0x3e:  /* High-speed Serial Interface Tx Configuration Port 0 */
349         return s->hssi_config[0];
350     case 0x40:  /* High-speed Serial Interface Tx Configuration Port 1 */
351         return s->hssi_config[1];
352     case 0x42:  /* High-speed Serial Interface Tx Mode */
353         return s->hssi_config[2];
354     case 0x44:  /* TV Display Configuration */
355         return s->tv_config;
356     case 0x46 ... 0x4c: /* TV Vertical Blanking Interval Data bits */
357         return s->tv_timing[(reg - 0x46) >> 1];
358     case 0x4e:  /* VBI: Closed Caption / XDS Control / Status */
359         return s->vbi;
360     case 0x50:  /* TV Horizontal Start Position */
361         return s->tv_x;
362     case 0x52:  /* TV Vertical Start Position */
363         return s->tv_y;
364     case 0x54:  /* TV Test Pattern Setting */
365         return s->tv_test;
366     case 0x56:  /* TV Filter Setting */
367         return s->tv_filter_config;
368     case 0x58:  /* TV Filter Coefficient Index */
369         return s->tv_filter_idx;
370     case 0x5a:  /* TV Filter Coefficient Data */
371         if (s->tv_filter_idx < 0x20)
372             return s->tv_filter_coeff[s->tv_filter_idx ++];
373         return 0;
374 
375     case 0x60:  /* Input YUV/RGB Translate Mode 0 */
376         return s->yrc[0];
377     case 0x62:  /* Input YUV/RGB Translate Mode 1 */
378         return s->yrc[1];
379     case 0x64:  /* U Data Fix */
380         return s->u;
381     case 0x66:  /* V Data Fix */
382         return s->v;
383 
384     case 0x68:  /* Display Mode */
385         return s->mode;
386 
387     case 0x6a:  /* Special Effects */
388         return s->effect;
389 
390     case 0x6c:  /* Input Window X Start Position 0 */
391         return s->ix[0] & 0xff;
392     case 0x6e:  /* Input Window X Start Position 1 */
393         return s->ix[0] >> 3;
394     case 0x70:  /* Input Window Y Start Position 0 */
395         return s->ix[0] & 0xff;
396     case 0x72:  /* Input Window Y Start Position 1 */
397         return s->ix[0] >> 3;
398     case 0x74:  /* Input Window X End Position 0 */
399         return s->ix[1] & 0xff;
400     case 0x76:  /* Input Window X End Position 1 */
401         return s->ix[1] >> 3;
402     case 0x78:  /* Input Window Y End Position 0 */
403         return s->ix[1] & 0xff;
404     case 0x7a:  /* Input Window Y End Position 1 */
405         return s->ix[1] >> 3;
406     case 0x7c:  /* Output Window X Start Position 0 */
407         return s->ox[0] & 0xff;
408     case 0x7e:  /* Output Window X Start Position 1 */
409         return s->ox[0] >> 3;
410     case 0x80:  /* Output Window Y Start Position 0 */
411         return s->oy[0] & 0xff;
412     case 0x82:  /* Output Window Y Start Position 1 */
413         return s->oy[0] >> 3;
414     case 0x84:  /* Output Window X End Position 0 */
415         return s->ox[1] & 0xff;
416     case 0x86:  /* Output Window X End Position 1 */
417         return s->ox[1] >> 3;
418     case 0x88:  /* Output Window Y End Position 0 */
419         return s->oy[1] & 0xff;
420     case 0x8a:  /* Output Window Y End Position 1 */
421         return s->oy[1] >> 3;
422 
423     case 0x8c:  /* Input Data Format */
424         return s->iformat;
425     case 0x8e:  /* Data Source Select */
426         return s->source;
427     case 0x90:  /* Display Memory Data Port */
428         return 0;
429 
430     case 0xa8:  /* Border Color 0 */
431         return s->border_r;
432     case 0xaa:  /* Border Color 1 */
433         return s->border_g;
434     case 0xac:  /* Border Color 2 */
435         return s->border_b;
436 
437     case 0xb4:  /* Gamma Correction Enable */
438         return s->gamma_config;
439     case 0xb6:  /* Gamma Correction Table Index */
440         return s->gamma_idx;
441     case 0xb8:  /* Gamma Correction Table Data */
442         return s->gamma_lut[s->gamma_idx ++];
443 
444     case 0xba:  /* 3x3 Matrix Enable */
445         return s->matrix_ena;
446     case 0xbc ... 0xde: /* Coefficient Registers */
447         return s->matrix_coeff[(reg - 0xbc) >> 1];
448     case 0xe0:  /* 3x3 Matrix Red Offset */
449         return s->matrix_r;
450     case 0xe2:  /* 3x3 Matrix Green Offset */
451         return s->matrix_g;
452     case 0xe4:  /* 3x3 Matrix Blue Offset */
453         return s->matrix_b;
454 
455     case 0xe6:  /* Power-save */
456         return s->pm;
457     case 0xe8:  /* Non-display Period Control / Status */
458         return s->status | (1 << 5);
459     case 0xea:  /* RGB Interface Control */
460         return s->rgbgpio_dir;
461     case 0xec:  /* RGB Interface Status */
462         return s->rgbgpio;
463     case 0xee:  /* General-purpose IO Pins Configuration */
464         return s->gpio_dir;
465     case 0xf0:  /* General-purpose IO Pins Status / Control */
466         return s->gpio;
467     case 0xf2:  /* GPIO Positive Edge Interrupt Trigger */
468         return s->gpio_edge[0];
469     case 0xf4:  /* GPIO Negative Edge Interrupt Trigger */
470         return s->gpio_edge[1];
471     case 0xf6:  /* GPIO Interrupt Status */
472         return s->gpio_irq;
473     case 0xf8:  /* GPIO Pull-down Control */
474         return s->gpio_pdown;
475 
476     default:
477         fprintf(stderr, "%s: unknown register %02x\n", __func__, reg);
478         return 0;
479     }
480 }
481 
482 static void blizzard_reg_write(void *opaque, uint8_t reg, uint16_t value)
483 {
484     BlizzardState *s = (BlizzardState *) opaque;
485 
486     switch (reg) {
487     case 0x04:  /* PLL M-Divider */
488         s->pll = (value & 0x3f) + 1;
489         break;
490     case 0x06:  /* PLL Lock Range Control */
491         s->pll_range = value & 3;
492         break;
493     case 0x08:  /* PLL Lock Synthesis Control 0 */
494         s->pll_ctrl &= 0xf00;
495         s->pll_ctrl |= (value << 0) & 0x0ff;
496         break;
497     case 0x0a:  /* PLL Lock Synthesis Control 1 */
498         s->pll_ctrl &= 0x0ff;
499         s->pll_ctrl |= (value << 8) & 0xf00;
500         break;
501     case 0x0c:  /* PLL Mode Control 0 */
502         s->pll_mode = value & 0x77;
503         if ((value & 3) == 0 || (value & 3) == 3)
504             fprintf(stderr, "%s: wrong PLL Control bits (%i)\n",
505                     __func__, value & 3);
506         break;
507 
508     case 0x0e:  /* Clock-Source Select */
509         s->clksel = value & 0xff;
510         break;
511 
512     case 0x10:  /* Memory Controller Activate */
513         s->memenable = value & 1;
514         break;
515     case 0x14:  /* Memory Controller Bank 0 Status Flag */
516         break;
517 
518     case 0x18:  /* Auto-Refresh Interval Setting 0 */
519         s->memrefresh &= 0xf00;
520         s->memrefresh |= (value << 0) & 0x0ff;
521         break;
522     case 0x1a:  /* Auto-Refresh Interval Setting 1 */
523         s->memrefresh &= 0x0ff;
524         s->memrefresh |= (value << 8) & 0xf00;
525         break;
526 
527     case 0x1c:  /* Power-On Sequence Timing Control */
528         s->timing[0] = value & 0x7f;
529         break;
530     case 0x1e:  /* Timing Control 0 */
531         s->timing[1] = value & 0x17;
532         break;
533     case 0x20:  /* Timing Control 1 */
534         s->timing[2] = value & 0x35;
535         break;
536 
537     case 0x24:  /* Arbitration Priority Control */
538         s->priority = value & 1;
539         break;
540 
541     case 0x28:  /* LCD Panel Configuration */
542         s->lcd_config = value & 0xff;
543         if (value & (1 << 7))
544             fprintf(stderr, "%s: data swap not supported!\n", __func__);
545         break;
546 
547     case 0x2a:  /* LCD Horizontal Display Width */
548         s->x = value << 3;
549         break;
550     case 0x2c:  /* LCD Horizontal Non-display Period */
551         s->hndp = value & 0xff;
552         break;
553     case 0x2e:  /* LCD Vertical Display Height 0 */
554         s->y &= 0x300;
555         s->y |= (value << 0) & 0x0ff;
556         break;
557     case 0x30:  /* LCD Vertical Display Height 1 */
558         s->y &= 0x0ff;
559         s->y |= (value << 8) & 0x300;
560         break;
561     case 0x32:  /* LCD Vertical Non-display Period */
562         s->vndp = value & 0xff;
563         break;
564     case 0x34:  /* LCD HS Pulse-width */
565         s->hsync = value & 0xff;
566         break;
567     case 0x36:  /* LCD HS Pulse Start Position */
568         s->skipx = value & 0xff;
569         break;
570     case 0x38:  /* LCD VS Pulse-width */
571         s->vsync = value & 0xbf;
572         break;
573     case 0x3a:  /* LCD VS Pulse Start Position */
574         s->skipy = value & 0xff;
575         break;
576 
577     case 0x3c:  /* PCLK Polarity */
578         s->pclk = value & 0x82;
579         /* Affects calculation of s->hndp, s->hsync and s->skipx.  */
580         break;
581 
582     case 0x3e:  /* High-speed Serial Interface Tx Configuration Port 0 */
583         s->hssi_config[0] = value;
584         break;
585     case 0x40:  /* High-speed Serial Interface Tx Configuration Port 1 */
586         s->hssi_config[1] = value;
587         if (((value >> 4) & 3) == 3)
588             fprintf(stderr, "%s: Illegal active-data-links value\n",
589                             __func__);
590         break;
591     case 0x42:  /* High-speed Serial Interface Tx Mode */
592         s->hssi_config[2] = value & 0xbd;
593         break;
594 
595     case 0x44:  /* TV Display Configuration */
596         s->tv_config = value & 0xfe;
597         break;
598     case 0x46 ... 0x4c: /* TV Vertical Blanking Interval Data bits 0 */
599         s->tv_timing[(reg - 0x46) >> 1] = value;
600         break;
601     case 0x4e:  /* VBI: Closed Caption / XDS Control / Status */
602         s->vbi = value;
603         break;
604     case 0x50:  /* TV Horizontal Start Position */
605         s->tv_x = value;
606         break;
607     case 0x52:  /* TV Vertical Start Position */
608         s->tv_y = value & 0x7f;
609         break;
610     case 0x54:  /* TV Test Pattern Setting */
611         s->tv_test = value;
612         break;
613     case 0x56:  /* TV Filter Setting */
614         s->tv_filter_config = value & 0xbf;
615         break;
616     case 0x58:  /* TV Filter Coefficient Index */
617         s->tv_filter_idx = value & 0x1f;
618         break;
619     case 0x5a:  /* TV Filter Coefficient Data */
620         if (s->tv_filter_idx < 0x20)
621             s->tv_filter_coeff[s->tv_filter_idx ++] = value;
622         break;
623 
624     case 0x60:  /* Input YUV/RGB Translate Mode 0 */
625         s->yrc[0] = value & 0xb0;
626         break;
627     case 0x62:  /* Input YUV/RGB Translate Mode 1 */
628         s->yrc[1] = value & 0x30;
629         break;
630     case 0x64:  /* U Data Fix */
631         s->u = value & 0xff;
632         break;
633     case 0x66:  /* V Data Fix */
634         s->v = value & 0xff;
635         break;
636 
637     case 0x68:  /* Display Mode */
638         if ((s->mode ^ value) & 3)
639             s->invalidate = 1;
640         s->mode = value & 0xb7;
641         s->enable = value & 1;
642         s->blank = (value >> 1) & 1;
643         if (value & (1 << 4))
644             fprintf(stderr, "%s: Macrovision enable attempt!\n", __func__);
645         break;
646 
647     case 0x6a:  /* Special Effects */
648         s->effect = value & 0xfb;
649         break;
650 
651     case 0x6c:  /* Input Window X Start Position 0 */
652         s->ix[0] &= 0x300;
653         s->ix[0] |= (value << 0) & 0x0ff;
654         break;
655     case 0x6e:  /* Input Window X Start Position 1 */
656         s->ix[0] &= 0x0ff;
657         s->ix[0] |= (value << 8) & 0x300;
658         break;
659     case 0x70:  /* Input Window Y Start Position 0 */
660         s->iy[0] &= 0x300;
661         s->iy[0] |= (value << 0) & 0x0ff;
662         break;
663     case 0x72:  /* Input Window Y Start Position 1 */
664         s->iy[0] &= 0x0ff;
665         s->iy[0] |= (value << 8) & 0x300;
666         break;
667     case 0x74:  /* Input Window X End Position 0 */
668         s->ix[1] &= 0x300;
669         s->ix[1] |= (value << 0) & 0x0ff;
670         break;
671     case 0x76:  /* Input Window X End Position 1 */
672         s->ix[1] &= 0x0ff;
673         s->ix[1] |= (value << 8) & 0x300;
674         break;
675     case 0x78:  /* Input Window Y End Position 0 */
676         s->iy[1] &= 0x300;
677         s->iy[1] |= (value << 0) & 0x0ff;
678         break;
679     case 0x7a:  /* Input Window Y End Position 1 */
680         s->iy[1] &= 0x0ff;
681         s->iy[1] |= (value << 8) & 0x300;
682         break;
683     case 0x7c:  /* Output Window X Start Position 0 */
684         s->ox[0] &= 0x300;
685         s->ox[0] |= (value << 0) & 0x0ff;
686         break;
687     case 0x7e:  /* Output Window X Start Position 1 */
688         s->ox[0] &= 0x0ff;
689         s->ox[0] |= (value << 8) & 0x300;
690         break;
691     case 0x80:  /* Output Window Y Start Position 0 */
692         s->oy[0] &= 0x300;
693         s->oy[0] |= (value << 0) & 0x0ff;
694         break;
695     case 0x82:  /* Output Window Y Start Position 1 */
696         s->oy[0] &= 0x0ff;
697         s->oy[0] |= (value << 8) & 0x300;
698         break;
699     case 0x84:  /* Output Window X End Position 0 */
700         s->ox[1] &= 0x300;
701         s->ox[1] |= (value << 0) & 0x0ff;
702         break;
703     case 0x86:  /* Output Window X End Position 1 */
704         s->ox[1] &= 0x0ff;
705         s->ox[1] |= (value << 8) & 0x300;
706         break;
707     case 0x88:  /* Output Window Y End Position 0 */
708         s->oy[1] &= 0x300;
709         s->oy[1] |= (value << 0) & 0x0ff;
710         break;
711     case 0x8a:  /* Output Window Y End Position 1 */
712         s->oy[1] &= 0x0ff;
713         s->oy[1] |= (value << 8) & 0x300;
714         break;
715 
716     case 0x8c:  /* Input Data Format */
717         s->iformat = value & 0xf;
718         s->bpp = blizzard_iformat_bpp[s->iformat];
719         if (!s->bpp)
720             fprintf(stderr, "%s: Illegal or unsupported input format %x\n",
721                             __func__, s->iformat);
722         break;
723     case 0x8e:  /* Data Source Select */
724         s->source = value & 7;
725         /* Currently all windows will be "destructive overlays".  */
726         if ((!(s->effect & (1 << 3)) && (s->ix[0] != s->ox[0] ||
727                                         s->iy[0] != s->oy[0] ||
728                                         s->ix[1] != s->ox[1] ||
729                                         s->iy[1] != s->oy[1])) ||
730                         !((s->ix[1] - s->ix[0]) & (s->iy[1] - s->iy[0]) &
731                           (s->ox[1] - s->ox[0]) & (s->oy[1] - s->oy[0]) & 1))
732             fprintf(stderr, "%s: Illegal input/output window positions\n",
733                             __func__);
734 
735         blizzard_transfer_setup(s);
736         break;
737 
738     case 0x90:  /* Display Memory Data Port */
739         if (!s->data.len && !blizzard_transfer_setup(s))
740             break;
741 
742         *s->data.ptr ++ = value;
743         if (-- s->data.len == 0)
744             blizzard_window(s);
745         break;
746 
747     case 0xa8:  /* Border Color 0 */
748         s->border_r = value;
749         break;
750     case 0xaa:  /* Border Color 1 */
751         s->border_g = value;
752         break;
753     case 0xac:  /* Border Color 2 */
754         s->border_b = value;
755         break;
756 
757     case 0xb4:  /* Gamma Correction Enable */
758         s->gamma_config = value & 0x87;
759         break;
760     case 0xb6:  /* Gamma Correction Table Index */
761         s->gamma_idx = value;
762         break;
763     case 0xb8:  /* Gamma Correction Table Data */
764         s->gamma_lut[s->gamma_idx ++] = value;
765         break;
766 
767     case 0xba:  /* 3x3 Matrix Enable */
768         s->matrix_ena = value & 1;
769         break;
770     case 0xbc ... 0xde: /* Coefficient Registers */
771         s->matrix_coeff[(reg - 0xbc) >> 1] = value & ((reg & 2) ? 0x80 : 0xff);
772         break;
773     case 0xe0:  /* 3x3 Matrix Red Offset */
774         s->matrix_r = value;
775         break;
776     case 0xe2:  /* 3x3 Matrix Green Offset */
777         s->matrix_g = value;
778         break;
779     case 0xe4:  /* 3x3 Matrix Blue Offset */
780         s->matrix_b = value;
781         break;
782 
783     case 0xe6:  /* Power-save */
784         s->pm = value & 0x83;
785         if (value & s->mode & 1)
786             fprintf(stderr, "%s: The display must be disabled before entering "
787                             "Standby Mode\n", __func__);
788         break;
789     case 0xe8:  /* Non-display Period Control / Status */
790         s->status = value & 0x1b;
791         break;
792     case 0xea:  /* RGB Interface Control */
793         s->rgbgpio_dir = value & 0x8f;
794         break;
795     case 0xec:  /* RGB Interface Status */
796         s->rgbgpio = value & 0xcf;
797         break;
798     case 0xee:  /* General-purpose IO Pins Configuration */
799         s->gpio_dir = value;
800         break;
801     case 0xf0:  /* General-purpose IO Pins Status / Control */
802         s->gpio = value;
803         break;
804     case 0xf2:  /* GPIO Positive Edge Interrupt Trigger */
805         s->gpio_edge[0] = value;
806         break;
807     case 0xf4:  /* GPIO Negative Edge Interrupt Trigger */
808         s->gpio_edge[1] = value;
809         break;
810     case 0xf6:  /* GPIO Interrupt Status */
811         s->gpio_irq &= value;
812         break;
813     case 0xf8:  /* GPIO Pull-down Control */
814         s->gpio_pdown = value;
815         break;
816 
817     default:
818         fprintf(stderr, "%s: unknown register %02x\n", __func__, reg);
819         break;
820     }
821 }
822 
823 uint16_t s1d13745_read(void *opaque, int dc)
824 {
825     BlizzardState *s = (BlizzardState *) opaque;
826     uint16_t value = blizzard_reg_read(s, s->reg);
827 
828     if (s->swallow -- > 0)
829         return 0;
830     if (dc)
831         s->reg ++;
832 
833     return value;
834 }
835 
836 void s1d13745_write(void *opaque, int dc, uint16_t value)
837 {
838     BlizzardState *s = (BlizzardState *) opaque;
839 
840     if (s->swallow -- > 0)
841         return;
842     if (dc) {
843         blizzard_reg_write(s, s->reg, value);
844 
845         if (s->reg != 0x90 && s->reg != 0x5a && s->reg != 0xb8)
846             s->reg += 2;
847     } else
848         s->reg = value & 0xff;
849 }
850 
851 void s1d13745_write_block(void *opaque, int dc,
852                 void *buf, size_t len, int pitch)
853 {
854     BlizzardState *s = (BlizzardState *) opaque;
855 
856     while (len > 0) {
857         if (s->reg == 0x90 && dc &&
858                         (s->data.len || blizzard_transfer_setup(s)) &&
859                         len >= (s->data.len << 1)) {
860             len -= s->data.len << 1;
861             s->data.len = 0;
862             s->data.data = buf;
863             if (pitch)
864                 s->data.pitch = pitch;
865             blizzard_window(s);
866             s->data.data = s->data.buf;
867             continue;
868         }
869 
870         s1d13745_write(opaque, dc, *(uint16_t *) buf);
871         len -= 2;
872         buf += 2;
873     }
874 }
875 
876 static void blizzard_update_display(void *opaque)
877 {
878     BlizzardState *s = (BlizzardState *) opaque;
879     DisplaySurface *surface = qemu_console_surface(s->con);
880     int y, bypp, bypl, bwidth;
881     uint8_t *src, *dst;
882 
883     if (!s->enable)
884         return;
885 
886     if (s->x != surface_width(surface) || s->y != surface_height(surface)) {
887         s->invalidate = 1;
888         qemu_console_resize(s->con, s->x, s->y);
889         surface = qemu_console_surface(s->con);
890     }
891 
892     if (s->invalidate) {
893         s->invalidate = 0;
894 
895         if (s->blank) {
896             bypp = surface_bytes_per_pixel(surface);
897             memset(surface_data(surface), 0, bypp * s->x * s->y);
898             return;
899         }
900 
901         s->mx[0] = 0;
902         s->mx[1] = s->x;
903         s->my[0] = 0;
904         s->my[1] = s->y;
905     }
906 
907     if (s->mx[1] <= s->mx[0])
908         return;
909 
910     bypp = surface_bytes_per_pixel(surface);
911     bypl = bypp * s->x;
912     bwidth = bypp * (s->mx[1] - s->mx[0]);
913     y = s->my[0];
914     src = s->fb + bypl * y + bypp * s->mx[0];
915     dst = surface_data(surface) + bypl * y + bypp * s->mx[0];
916     for (; y < s->my[1]; y ++, src += bypl, dst += bypl)
917         memcpy(dst, src, bwidth);
918 
919     dpy_gfx_update(s->con, s->mx[0], s->my[0],
920                    s->mx[1] - s->mx[0], y - s->my[0]);
921 
922     s->mx[0] = s->x;
923     s->mx[1] = 0;
924     s->my[0] = s->y;
925     s->my[1] = 0;
926 }
927 
928 static void blizzard_draw_line16_32(uint32_t *dest,
929                                     const uint16_t *src, unsigned int width)
930 {
931     uint16_t data;
932     unsigned int r, g, b;
933     const uint16_t *end = (const void *) src + width;
934     while (src < end) {
935         data = *src ++;
936         b = extract16(data, 0, 5) << 3;
937         g = extract16(data, 5, 6) << 2;
938         r = extract16(data, 11, 5) << 3;
939         *dest++ = rgb_to_pixel32(r, g, b);
940     }
941 }
942 
943 static void blizzard_draw_line24mode1_32(uint32_t *dest,
944                                          const uint8_t *src, unsigned int width)
945 {
946     /* TODO: check if SDL 24-bit planes are not in the same format and
947      * if so, use memcpy */
948     unsigned int r[2], g[2], b[2];
949     const uint8_t *end = src + width;
950     while (src < end) {
951         g[0] = *src ++;
952         r[0] = *src ++;
953         r[1] = *src ++;
954         b[0] = *src ++;
955         *dest++ = rgb_to_pixel32(r[0], g[0], b[0]);
956         b[1] = *src ++;
957         g[1] = *src ++;
958         *dest++ = rgb_to_pixel32(r[1], g[1], b[1]);
959     }
960 }
961 
962 static void blizzard_draw_line24mode2_32(uint32_t *dest,
963                                          const uint8_t *src, unsigned int width)
964 {
965     unsigned int r, g, b;
966     const uint8_t *end = src + width;
967     while (src < end) {
968         r = *src ++;
969         src ++;
970         b = *src ++;
971         g = *src ++;
972         *dest++ = rgb_to_pixel32(r, g, b);
973     }
974 }
975 
976 /* No rotation */
977 static blizzard_fn_t blizzard_draw_fn_32[0x10] = {
978     NULL,
979     /* RGB 5:6:5*/
980     (blizzard_fn_t) blizzard_draw_line16_32,
981     /* RGB 6:6:6 mode 1 */
982     (blizzard_fn_t) blizzard_draw_line24mode1_32,
983     /* RGB 8:8:8 mode 1 */
984     (blizzard_fn_t) blizzard_draw_line24mode1_32,
985     NULL, NULL,
986     /* RGB 6:6:6 mode 2 */
987     (blizzard_fn_t) blizzard_draw_line24mode2_32,
988     /* RGB 8:8:8 mode 2 */
989     (blizzard_fn_t) blizzard_draw_line24mode2_32,
990     /* YUV 4:2:2 */
991     NULL,
992     /* YUV 4:2:0 */
993     NULL,
994     NULL, NULL, NULL, NULL, NULL, NULL,
995 };
996 
997 /* 90deg, 180deg and 270deg rotation */
998 static blizzard_fn_t blizzard_draw_fn_r_32[0x10] = {
999     /* TODO */
1000     [0 ... 0xf] = NULL,
1001 };
1002 
1003 static const GraphicHwOps blizzard_ops = {
1004     .invalidate  = blizzard_invalidate_display,
1005     .gfx_update  = blizzard_update_display,
1006 };
1007 
1008 void *s1d13745_init(qemu_irq gpio_int)
1009 {
1010     BlizzardState *s = g_malloc0(sizeof(*s));
1011     DisplaySurface *surface;
1012 
1013     s->fb = g_malloc(0x180000);
1014 
1015     s->con = graphic_console_init(NULL, 0, &blizzard_ops, s);
1016     surface = qemu_console_surface(s->con);
1017 
1018     assert(surface_bits_per_pixel(surface) == 32);
1019 
1020     s->line_fn_tab[0] = blizzard_draw_fn_32;
1021     s->line_fn_tab[1] = blizzard_draw_fn_r_32;
1022 
1023     blizzard_reset(s);
1024 
1025     return s;
1026 }
1027