2 * OMAP2 Display Subsystem.
4 * Copyright (C) 2008 Nokia Corporation
5 * Written by Andrzej Zaborowski <andrew@openedhand.com>
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.
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.
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/>.
33 struct omap_dss_panel_s
{
54 struct omap_dss_plane_s
{
62 target_phys_addr_t addr
[3];
72 uint16_t palette
[256];
88 struct rfbi_chip_s
*chip
[2];
92 static void omap_dispc_interrupt_update(struct omap_dss_s
*s
)
94 qemu_set_irq(s
->irq
, s
->dispc
.irqst
& s
->dispc
.irqen
);
97 static void omap_rfbi_reset(struct omap_dss_s
*s
)
103 s
->rfbi
.skiplines
= 0;
105 s
->rfbi
.config
[0] = 0x00310000;
106 s
->rfbi
.config
[1] = 0x00310000;
121 void omap_dss_reset(struct omap_dss_s
*s
)
135 s
->dispc
.idlemode
= 0;
138 s
->dispc
.control
= 0;
140 s
->dispc
.capable
= 0x161;
141 s
->dispc
.timing
[0] = 0;
142 s
->dispc
.timing
[1] = 0;
143 s
->dispc
.timing
[2] = 0;
144 s
->dispc
.timing
[3] = 0;
148 s
->dispc
.trans
[0] = 0;
149 s
->dispc
.trans
[1] = 0;
151 s
->dispc
.l
[0].enable
= 0;
152 s
->dispc
.l
[0].bpp
= 0;
153 s
->dispc
.l
[0].addr
[0] = 0;
154 s
->dispc
.l
[0].addr
[1] = 0;
155 s
->dispc
.l
[0].addr
[2] = 0;
156 s
->dispc
.l
[0].posx
= 0;
157 s
->dispc
.l
[0].posy
= 0;
158 s
->dispc
.l
[0].nx
= 1;
159 s
->dispc
.l
[0].ny
= 1;
160 s
->dispc
.l
[0].attr
= 0;
161 s
->dispc
.l
[0].tresh
= 0;
162 s
->dispc
.l
[0].rowinc
= 1;
163 s
->dispc
.l
[0].colinc
= 1;
164 s
->dispc
.l
[0].wininc
= 0;
167 omap_dispc_interrupt_update(s
);
170 static uint32_t omap_diss_read(void *opaque
, target_phys_addr_t addr
)
172 struct omap_dss_s
*s
= (struct omap_dss_s
*) opaque
;
175 case 0x00: /* DSS_REVISIONNUMBER */
178 case 0x10: /* DSS_SYSCONFIG */
181 case 0x14: /* DSS_SYSSTATUS */
182 return 1; /* RESETDONE */
184 case 0x40: /* DSS_CONTROL */
187 case 0x50: /* DSS_PSA_LCD_REG_1 */
188 case 0x54: /* DSS_PSA_LCD_REG_2 */
189 case 0x58: /* DSS_PSA_VIDEO_REG */
190 /* TODO: fake some values when appropriate s->control bits are set */
193 case 0x5c: /* DSS_STATUS */
194 return 1 + (s
->control
& 1);
203 static void omap_diss_write(void *opaque
, target_phys_addr_t addr
,
206 struct omap_dss_s
*s
= (struct omap_dss_s
*) opaque
;
209 case 0x00: /* DSS_REVISIONNUMBER */
210 case 0x14: /* DSS_SYSSTATUS */
211 case 0x50: /* DSS_PSA_LCD_REG_1 */
212 case 0x54: /* DSS_PSA_LCD_REG_2 */
213 case 0x58: /* DSS_PSA_VIDEO_REG */
214 case 0x5c: /* DSS_STATUS */
218 case 0x10: /* DSS_SYSCONFIG */
219 if (value
& 2) /* SOFTRESET */
221 s
->autoidle
= value
& 1;
224 case 0x40: /* DSS_CONTROL */
225 s
->control
= value
& 0x3dd;
233 static CPUReadMemoryFunc
* const omap_diss1_readfn
[] = {
234 omap_badwidth_read32
,
235 omap_badwidth_read32
,
239 static CPUWriteMemoryFunc
* const omap_diss1_writefn
[] = {
240 omap_badwidth_write32
,
241 omap_badwidth_write32
,
245 static uint32_t omap_disc_read(void *opaque
, target_phys_addr_t addr
)
247 struct omap_dss_s
*s
= (struct omap_dss_s
*) opaque
;
250 case 0x000: /* DISPC_REVISION */
253 case 0x010: /* DISPC_SYSCONFIG */
254 return s
->dispc
.idlemode
;
256 case 0x014: /* DISPC_SYSSTATUS */
257 return 1; /* RESETDONE */
259 case 0x018: /* DISPC_IRQSTATUS */
260 return s
->dispc
.irqst
;
262 case 0x01c: /* DISPC_IRQENABLE */
263 return s
->dispc
.irqen
;
265 case 0x040: /* DISPC_CONTROL */
266 return s
->dispc
.control
;
268 case 0x044: /* DISPC_CONFIG */
269 return s
->dispc
.config
;
271 case 0x048: /* DISPC_CAPABLE */
272 return s
->dispc
.capable
;
274 case 0x04c: /* DISPC_DEFAULT_COLOR0 */
275 return s
->dispc
.bg
[0];
276 case 0x050: /* DISPC_DEFAULT_COLOR1 */
277 return s
->dispc
.bg
[1];
278 case 0x054: /* DISPC_TRANS_COLOR0 */
279 return s
->dispc
.trans
[0];
280 case 0x058: /* DISPC_TRANS_COLOR1 */
281 return s
->dispc
.trans
[1];
283 case 0x05c: /* DISPC_LINE_STATUS */
285 case 0x060: /* DISPC_LINE_NUMBER */
286 return s
->dispc
.line
;
288 case 0x064: /* DISPC_TIMING_H */
289 return s
->dispc
.timing
[0];
290 case 0x068: /* DISPC_TIMING_V */
291 return s
->dispc
.timing
[1];
292 case 0x06c: /* DISPC_POL_FREQ */
293 return s
->dispc
.timing
[2];
294 case 0x070: /* DISPC_DIVISOR */
295 return s
->dispc
.timing
[3];
297 case 0x078: /* DISPC_SIZE_DIG */
298 return ((s
->dig
.ny
- 1) << 16) | (s
->dig
.nx
- 1);
299 case 0x07c: /* DISPC_SIZE_LCD */
300 return ((s
->lcd
.ny
- 1) << 16) | (s
->lcd
.nx
- 1);
302 case 0x080: /* DISPC_GFX_BA0 */
303 return s
->dispc
.l
[0].addr
[0];
304 case 0x084: /* DISPC_GFX_BA1 */
305 return s
->dispc
.l
[0].addr
[1];
306 case 0x088: /* DISPC_GFX_POSITION */
307 return (s
->dispc
.l
[0].posy
<< 16) | s
->dispc
.l
[0].posx
;
308 case 0x08c: /* DISPC_GFX_SIZE */
309 return ((s
->dispc
.l
[0].ny
- 1) << 16) | (s
->dispc
.l
[0].nx
- 1);
310 case 0x0a0: /* DISPC_GFX_ATTRIBUTES */
311 return s
->dispc
.l
[0].attr
;
312 case 0x0a4: /* DISPC_GFX_FIFO_TRESHOLD */
313 return s
->dispc
.l
[0].tresh
;
314 case 0x0a8: /* DISPC_GFX_FIFO_SIZE_STATUS */
316 case 0x0ac: /* DISPC_GFX_ROW_INC */
317 return s
->dispc
.l
[0].rowinc
;
318 case 0x0b0: /* DISPC_GFX_PIXEL_INC */
319 return s
->dispc
.l
[0].colinc
;
320 case 0x0b4: /* DISPC_GFX_WINDOW_SKIP */
321 return s
->dispc
.l
[0].wininc
;
322 case 0x0b8: /* DISPC_GFX_TABLE_BA */
323 return s
->dispc
.l
[0].addr
[2];
325 case 0x0bc: /* DISPC_VID1_BA0 */
326 case 0x0c0: /* DISPC_VID1_BA1 */
327 case 0x0c4: /* DISPC_VID1_POSITION */
328 case 0x0c8: /* DISPC_VID1_SIZE */
329 case 0x0cc: /* DISPC_VID1_ATTRIBUTES */
330 case 0x0d0: /* DISPC_VID1_FIFO_TRESHOLD */
331 case 0x0d4: /* DISPC_VID1_FIFO_SIZE_STATUS */
332 case 0x0d8: /* DISPC_VID1_ROW_INC */
333 case 0x0dc: /* DISPC_VID1_PIXEL_INC */
334 case 0x0e0: /* DISPC_VID1_FIR */
335 case 0x0e4: /* DISPC_VID1_PICTURE_SIZE */
336 case 0x0e8: /* DISPC_VID1_ACCU0 */
337 case 0x0ec: /* DISPC_VID1_ACCU1 */
338 case 0x0f0 ... 0x140: /* DISPC_VID1_FIR_COEF, DISPC_VID1_CONV_COEF */
339 case 0x14c: /* DISPC_VID2_BA0 */
340 case 0x150: /* DISPC_VID2_BA1 */
341 case 0x154: /* DISPC_VID2_POSITION */
342 case 0x158: /* DISPC_VID2_SIZE */
343 case 0x15c: /* DISPC_VID2_ATTRIBUTES */
344 case 0x160: /* DISPC_VID2_FIFO_TRESHOLD */
345 case 0x164: /* DISPC_VID2_FIFO_SIZE_STATUS */
346 case 0x168: /* DISPC_VID2_ROW_INC */
347 case 0x16c: /* DISPC_VID2_PIXEL_INC */
348 case 0x170: /* DISPC_VID2_FIR */
349 case 0x174: /* DISPC_VID2_PICTURE_SIZE */
350 case 0x178: /* DISPC_VID2_ACCU0 */
351 case 0x17c: /* DISPC_VID2_ACCU1 */
352 case 0x180 ... 0x1d0: /* DISPC_VID2_FIR_COEF, DISPC_VID2_CONV_COEF */
353 case 0x1d4: /* DISPC_DATA_CYCLE1 */
354 case 0x1d8: /* DISPC_DATA_CYCLE2 */
355 case 0x1dc: /* DISPC_DATA_CYCLE3 */
365 static void omap_disc_write(void *opaque
, target_phys_addr_t addr
,
368 struct omap_dss_s
*s
= (struct omap_dss_s
*) opaque
;
371 case 0x010: /* DISPC_SYSCONFIG */
372 if (value
& 2) /* SOFTRESET */
374 s
->dispc
.idlemode
= value
& 0x301b;
377 case 0x018: /* DISPC_IRQSTATUS */
378 s
->dispc
.irqst
&= ~value
;
379 omap_dispc_interrupt_update(s
);
382 case 0x01c: /* DISPC_IRQENABLE */
383 s
->dispc
.irqen
= value
& 0xffff;
384 omap_dispc_interrupt_update(s
);
387 case 0x040: /* DISPC_CONTROL */
388 s
->dispc
.control
= value
& 0x07ff9fff;
389 s
->dig
.enable
= (value
>> 1) & 1;
390 s
->lcd
.enable
= (value
>> 0) & 1;
391 if (value
& (1 << 12)) /* OVERLAY_OPTIMIZATION */
392 if (~((s
->dispc
.l
[1].attr
| s
->dispc
.l
[2].attr
) & 1))
393 fprintf(stderr
, "%s: Overlay Optimization when no overlay "
394 "region effectively exists leads to "
395 "unpredictable behaviour!\n", __FUNCTION__
);
396 if (value
& (1 << 6)) { /* GODIGITAL */
397 /* XXX: Shadowed fields are:
413 * s->dispc.l[0].addr[0]
414 * s->dispc.l[0].addr[1]
415 * s->dispc.l[0].addr[2]
420 * s->dispc.l[0].tresh
421 * s->dispc.l[0].rowinc
422 * s->dispc.l[0].colinc
423 * s->dispc.l[0].wininc
424 * All they need to be loaded here from their shadow registers.
427 if (value
& (1 << 5)) { /* GOLCD */
428 /* XXX: Likewise for LCD here. */
430 s
->dispc
.invalidate
= 1;
433 case 0x044: /* DISPC_CONFIG */
434 s
->dispc
.config
= value
& 0x3fff;
436 * bits 2:1 (LOADMODE) reset to 0 after set to 1 and palette loaded
437 * bits 2:1 (LOADMODE) reset to 2 after set to 3 and palette loaded
439 s
->dispc
.invalidate
= 1;
442 case 0x048: /* DISPC_CAPABLE */
443 s
->dispc
.capable
= value
& 0x3ff;
446 case 0x04c: /* DISPC_DEFAULT_COLOR0 */
447 s
->dispc
.bg
[0] = value
& 0xffffff;
448 s
->dispc
.invalidate
= 1;
450 case 0x050: /* DISPC_DEFAULT_COLOR1 */
451 s
->dispc
.bg
[1] = value
& 0xffffff;
452 s
->dispc
.invalidate
= 1;
454 case 0x054: /* DISPC_TRANS_COLOR0 */
455 s
->dispc
.trans
[0] = value
& 0xffffff;
456 s
->dispc
.invalidate
= 1;
458 case 0x058: /* DISPC_TRANS_COLOR1 */
459 s
->dispc
.trans
[1] = value
& 0xffffff;
460 s
->dispc
.invalidate
= 1;
463 case 0x060: /* DISPC_LINE_NUMBER */
464 s
->dispc
.line
= value
& 0x7ff;
467 case 0x064: /* DISPC_TIMING_H */
468 s
->dispc
.timing
[0] = value
& 0x0ff0ff3f;
470 case 0x068: /* DISPC_TIMING_V */
471 s
->dispc
.timing
[1] = value
& 0x0ff0ff3f;
473 case 0x06c: /* DISPC_POL_FREQ */
474 s
->dispc
.timing
[2] = value
& 0x0003ffff;
476 case 0x070: /* DISPC_DIVISOR */
477 s
->dispc
.timing
[3] = value
& 0x00ff00ff;
480 case 0x078: /* DISPC_SIZE_DIG */
481 s
->dig
.nx
= ((value
>> 0) & 0x7ff) + 1; /* PPL */
482 s
->dig
.ny
= ((value
>> 16) & 0x7ff) + 1; /* LPP */
483 s
->dispc
.invalidate
= 1;
485 case 0x07c: /* DISPC_SIZE_LCD */
486 s
->lcd
.nx
= ((value
>> 0) & 0x7ff) + 1; /* PPL */
487 s
->lcd
.ny
= ((value
>> 16) & 0x7ff) + 1; /* LPP */
488 s
->dispc
.invalidate
= 1;
490 case 0x080: /* DISPC_GFX_BA0 */
491 s
->dispc
.l
[0].addr
[0] = (target_phys_addr_t
) value
;
492 s
->dispc
.invalidate
= 1;
494 case 0x084: /* DISPC_GFX_BA1 */
495 s
->dispc
.l
[0].addr
[1] = (target_phys_addr_t
) value
;
496 s
->dispc
.invalidate
= 1;
498 case 0x088: /* DISPC_GFX_POSITION */
499 s
->dispc
.l
[0].posx
= ((value
>> 0) & 0x7ff); /* GFXPOSX */
500 s
->dispc
.l
[0].posy
= ((value
>> 16) & 0x7ff); /* GFXPOSY */
501 s
->dispc
.invalidate
= 1;
503 case 0x08c: /* DISPC_GFX_SIZE */
504 s
->dispc
.l
[0].nx
= ((value
>> 0) & 0x7ff) + 1; /* GFXSIZEX */
505 s
->dispc
.l
[0].ny
= ((value
>> 16) & 0x7ff) + 1; /* GFXSIZEY */
506 s
->dispc
.invalidate
= 1;
508 case 0x0a0: /* DISPC_GFX_ATTRIBUTES */
509 s
->dispc
.l
[0].attr
= value
& 0x7ff;
510 if (value
& (3 << 9))
511 fprintf(stderr
, "%s: Big-endian pixel format not supported\n",
513 s
->dispc
.l
[0].enable
= value
& 1;
514 s
->dispc
.l
[0].bpp
= (value
>> 1) & 0xf;
515 s
->dispc
.invalidate
= 1;
517 case 0x0a4: /* DISPC_GFX_FIFO_TRESHOLD */
518 s
->dispc
.l
[0].tresh
= value
& 0x01ff01ff;
520 case 0x0ac: /* DISPC_GFX_ROW_INC */
521 s
->dispc
.l
[0].rowinc
= value
;
522 s
->dispc
.invalidate
= 1;
524 case 0x0b0: /* DISPC_GFX_PIXEL_INC */
525 s
->dispc
.l
[0].colinc
= value
;
526 s
->dispc
.invalidate
= 1;
528 case 0x0b4: /* DISPC_GFX_WINDOW_SKIP */
529 s
->dispc
.l
[0].wininc
= value
;
531 case 0x0b8: /* DISPC_GFX_TABLE_BA */
532 s
->dispc
.l
[0].addr
[2] = (target_phys_addr_t
) value
;
533 s
->dispc
.invalidate
= 1;
536 case 0x0bc: /* DISPC_VID1_BA0 */
537 case 0x0c0: /* DISPC_VID1_BA1 */
538 case 0x0c4: /* DISPC_VID1_POSITION */
539 case 0x0c8: /* DISPC_VID1_SIZE */
540 case 0x0cc: /* DISPC_VID1_ATTRIBUTES */
541 case 0x0d0: /* DISPC_VID1_FIFO_TRESHOLD */
542 case 0x0d8: /* DISPC_VID1_ROW_INC */
543 case 0x0dc: /* DISPC_VID1_PIXEL_INC */
544 case 0x0e0: /* DISPC_VID1_FIR */
545 case 0x0e4: /* DISPC_VID1_PICTURE_SIZE */
546 case 0x0e8: /* DISPC_VID1_ACCU0 */
547 case 0x0ec: /* DISPC_VID1_ACCU1 */
548 case 0x0f0 ... 0x140: /* DISPC_VID1_FIR_COEF, DISPC_VID1_CONV_COEF */
549 case 0x14c: /* DISPC_VID2_BA0 */
550 case 0x150: /* DISPC_VID2_BA1 */
551 case 0x154: /* DISPC_VID2_POSITION */
552 case 0x158: /* DISPC_VID2_SIZE */
553 case 0x15c: /* DISPC_VID2_ATTRIBUTES */
554 case 0x160: /* DISPC_VID2_FIFO_TRESHOLD */
555 case 0x168: /* DISPC_VID2_ROW_INC */
556 case 0x16c: /* DISPC_VID2_PIXEL_INC */
557 case 0x170: /* DISPC_VID2_FIR */
558 case 0x174: /* DISPC_VID2_PICTURE_SIZE */
559 case 0x178: /* DISPC_VID2_ACCU0 */
560 case 0x17c: /* DISPC_VID2_ACCU1 */
561 case 0x180 ... 0x1d0: /* DISPC_VID2_FIR_COEF, DISPC_VID2_CONV_COEF */
562 case 0x1d4: /* DISPC_DATA_CYCLE1 */
563 case 0x1d8: /* DISPC_DATA_CYCLE2 */
564 case 0x1dc: /* DISPC_DATA_CYCLE3 */
572 static CPUReadMemoryFunc
* const omap_disc1_readfn
[] = {
573 omap_badwidth_read32
,
574 omap_badwidth_read32
,
578 static CPUWriteMemoryFunc
* const omap_disc1_writefn
[] = {
579 omap_badwidth_write32
,
580 omap_badwidth_write32
,
584 static void omap_rfbi_transfer_stop(struct omap_dss_s
*s
)
589 /* TODO: in non-Bypass mode we probably need to just deassert the DRQ. */
594 static void omap_rfbi_transfer_start(struct omap_dss_s
*s
)
597 target_phys_addr_t len
;
598 target_phys_addr_t data_addr
;
600 static void *bounce_buffer
;
601 static target_phys_addr_t bounce_len
;
603 if (!s
->rfbi
.enable
|| s
->rfbi
.busy
)
606 if (s
->rfbi
.control
& (1 << 1)) { /* BYPASS */
607 /* TODO: in non-Bypass mode we probably need to just assert the
608 * DRQ and wait for DMA to write the pixels. */
609 fprintf(stderr
, "%s: Bypass mode unimplemented\n", __FUNCTION__
);
613 if (!(s
->dispc
.control
& (1 << 11))) /* RFBIMODE */
615 /* TODO: check that LCD output is enabled in DISPC. */
619 len
= s
->rfbi
.pixels
* 2;
621 data_addr
= s
->dispc
.l
[0].addr
[0];
622 data
= cpu_physical_memory_map(data_addr
, &len
, 0);
623 if (data
&& len
!= s
->rfbi
.pixels
* 2) {
624 cpu_physical_memory_unmap(data
, len
, 0, 0);
626 len
= s
->rfbi
.pixels
* 2;
629 if (len
> bounce_len
) {
630 bounce_buffer
= g_realloc(bounce_buffer
, len
);
632 data
= bounce_buffer
;
633 cpu_physical_memory_read(data_addr
, data
, len
);
639 /* TODO: negative values */
640 pitch
= s
->dispc
.l
[0].nx
+ (s
->dispc
.l
[0].rowinc
- 1) / 2;
642 if ((s
->rfbi
.control
& (1 << 2)) && s
->rfbi
.chip
[0])
643 s
->rfbi
.chip
[0]->block(s
->rfbi
.chip
[0]->opaque
, 1, data
, len
, pitch
);
644 if ((s
->rfbi
.control
& (1 << 3)) && s
->rfbi
.chip
[1])
645 s
->rfbi
.chip
[1]->block(s
->rfbi
.chip
[1]->opaque
, 1, data
, len
, pitch
);
647 if (data
!= bounce_buffer
) {
648 cpu_physical_memory_unmap(data
, len
, 0, len
);
651 omap_rfbi_transfer_stop(s
);
654 s
->dispc
.irqst
|= 1; /* FRAMEDONE */
655 omap_dispc_interrupt_update(s
);
658 static uint32_t omap_rfbi_read(void *opaque
, target_phys_addr_t addr
)
660 struct omap_dss_s
*s
= (struct omap_dss_s
*) opaque
;
663 case 0x00: /* RFBI_REVISION */
666 case 0x10: /* RFBI_SYSCONFIG */
667 return s
->rfbi
.idlemode
;
669 case 0x14: /* RFBI_SYSSTATUS */
670 return 1 | (s
->rfbi
.busy
<< 8); /* RESETDONE */
672 case 0x40: /* RFBI_CONTROL */
673 return s
->rfbi
.control
;
675 case 0x44: /* RFBI_PIXELCNT */
676 return s
->rfbi
.pixels
;
678 case 0x48: /* RFBI_LINE_NUMBER */
679 return s
->rfbi
.skiplines
;
681 case 0x58: /* RFBI_READ */
682 case 0x5c: /* RFBI_STATUS */
683 return s
->rfbi
.rxbuf
;
685 case 0x60: /* RFBI_CONFIG0 */
686 return s
->rfbi
.config
[0];
687 case 0x64: /* RFBI_ONOFF_TIME0 */
688 return s
->rfbi
.time
[0];
689 case 0x68: /* RFBI_CYCLE_TIME0 */
690 return s
->rfbi
.time
[1];
691 case 0x6c: /* RFBI_DATA_CYCLE1_0 */
692 return s
->rfbi
.data
[0];
693 case 0x70: /* RFBI_DATA_CYCLE2_0 */
694 return s
->rfbi
.data
[1];
695 case 0x74: /* RFBI_DATA_CYCLE3_0 */
696 return s
->rfbi
.data
[2];
698 case 0x78: /* RFBI_CONFIG1 */
699 return s
->rfbi
.config
[1];
700 case 0x7c: /* RFBI_ONOFF_TIME1 */
701 return s
->rfbi
.time
[2];
702 case 0x80: /* RFBI_CYCLE_TIME1 */
703 return s
->rfbi
.time
[3];
704 case 0x84: /* RFBI_DATA_CYCLE1_1 */
705 return s
->rfbi
.data
[3];
706 case 0x88: /* RFBI_DATA_CYCLE2_1 */
707 return s
->rfbi
.data
[4];
708 case 0x8c: /* RFBI_DATA_CYCLE3_1 */
709 return s
->rfbi
.data
[5];
711 case 0x90: /* RFBI_VSYNC_WIDTH */
712 return s
->rfbi
.vsync
;
713 case 0x94: /* RFBI_HSYNC_WIDTH */
714 return s
->rfbi
.hsync
;
720 static void omap_rfbi_write(void *opaque
, target_phys_addr_t addr
,
723 struct omap_dss_s
*s
= (struct omap_dss_s
*) opaque
;
726 case 0x10: /* RFBI_SYSCONFIG */
727 if (value
& 2) /* SOFTRESET */
729 s
->rfbi
.idlemode
= value
& 0x19;
732 case 0x40: /* RFBI_CONTROL */
733 s
->rfbi
.control
= value
& 0xf;
734 s
->rfbi
.enable
= value
& 1;
735 if (value
& (1 << 4) && /* ITE */
736 !(s
->rfbi
.config
[0] & s
->rfbi
.config
[1] & 0xc))
737 omap_rfbi_transfer_start(s
);
740 case 0x44: /* RFBI_PIXELCNT */
741 s
->rfbi
.pixels
= value
;
744 case 0x48: /* RFBI_LINE_NUMBER */
745 s
->rfbi
.skiplines
= value
& 0x7ff;
748 case 0x4c: /* RFBI_CMD */
749 if ((s
->rfbi
.control
& (1 << 2)) && s
->rfbi
.chip
[0])
750 s
->rfbi
.chip
[0]->write(s
->rfbi
.chip
[0]->opaque
, 0, value
& 0xffff);
751 if ((s
->rfbi
.control
& (1 << 3)) && s
->rfbi
.chip
[1])
752 s
->rfbi
.chip
[1]->write(s
->rfbi
.chip
[1]->opaque
, 0, value
& 0xffff);
754 case 0x50: /* RFBI_PARAM */
755 if ((s
->rfbi
.control
& (1 << 2)) && s
->rfbi
.chip
[0])
756 s
->rfbi
.chip
[0]->write(s
->rfbi
.chip
[0]->opaque
, 1, value
& 0xffff);
757 if ((s
->rfbi
.control
& (1 << 3)) && s
->rfbi
.chip
[1])
758 s
->rfbi
.chip
[1]->write(s
->rfbi
.chip
[1]->opaque
, 1, value
& 0xffff);
760 case 0x54: /* RFBI_DATA */
761 /* TODO: take into account the format set up in s->rfbi.config[?] and
762 * s->rfbi.data[?], but special-case the most usual scenario so that
763 * speed doesn't suffer. */
764 if ((s
->rfbi
.control
& (1 << 2)) && s
->rfbi
.chip
[0]) {
765 s
->rfbi
.chip
[0]->write(s
->rfbi
.chip
[0]->opaque
, 1, value
& 0xffff);
766 s
->rfbi
.chip
[0]->write(s
->rfbi
.chip
[0]->opaque
, 1, value
>> 16);
768 if ((s
->rfbi
.control
& (1 << 3)) && s
->rfbi
.chip
[1]) {
769 s
->rfbi
.chip
[1]->write(s
->rfbi
.chip
[1]->opaque
, 1, value
& 0xffff);
770 s
->rfbi
.chip
[1]->write(s
->rfbi
.chip
[1]->opaque
, 1, value
>> 16);
772 if (!-- s
->rfbi
.pixels
)
773 omap_rfbi_transfer_stop(s
);
775 case 0x58: /* RFBI_READ */
776 if ((s
->rfbi
.control
& (1 << 2)) && s
->rfbi
.chip
[0])
777 s
->rfbi
.rxbuf
= s
->rfbi
.chip
[0]->read(s
->rfbi
.chip
[0]->opaque
, 1);
778 else if ((s
->rfbi
.control
& (1 << 3)) && s
->rfbi
.chip
[1])
779 s
->rfbi
.rxbuf
= s
->rfbi
.chip
[0]->read(s
->rfbi
.chip
[0]->opaque
, 1);
780 if (!-- s
->rfbi
.pixels
)
781 omap_rfbi_transfer_stop(s
);
784 case 0x5c: /* RFBI_STATUS */
785 if ((s
->rfbi
.control
& (1 << 2)) && s
->rfbi
.chip
[0])
786 s
->rfbi
.rxbuf
= s
->rfbi
.chip
[0]->read(s
->rfbi
.chip
[0]->opaque
, 0);
787 else if ((s
->rfbi
.control
& (1 << 3)) && s
->rfbi
.chip
[1])
788 s
->rfbi
.rxbuf
= s
->rfbi
.chip
[0]->read(s
->rfbi
.chip
[0]->opaque
, 0);
789 if (!-- s
->rfbi
.pixels
)
790 omap_rfbi_transfer_stop(s
);
793 case 0x60: /* RFBI_CONFIG0 */
794 s
->rfbi
.config
[0] = value
& 0x003f1fff;
797 case 0x64: /* RFBI_ONOFF_TIME0 */
798 s
->rfbi
.time
[0] = value
& 0x3fffffff;
800 case 0x68: /* RFBI_CYCLE_TIME0 */
801 s
->rfbi
.time
[1] = value
& 0x0fffffff;
803 case 0x6c: /* RFBI_DATA_CYCLE1_0 */
804 s
->rfbi
.data
[0] = value
& 0x0f1f0f1f;
806 case 0x70: /* RFBI_DATA_CYCLE2_0 */
807 s
->rfbi
.data
[1] = value
& 0x0f1f0f1f;
809 case 0x74: /* RFBI_DATA_CYCLE3_0 */
810 s
->rfbi
.data
[2] = value
& 0x0f1f0f1f;
812 case 0x78: /* RFBI_CONFIG1 */
813 s
->rfbi
.config
[1] = value
& 0x003f1fff;
816 case 0x7c: /* RFBI_ONOFF_TIME1 */
817 s
->rfbi
.time
[2] = value
& 0x3fffffff;
819 case 0x80: /* RFBI_CYCLE_TIME1 */
820 s
->rfbi
.time
[3] = value
& 0x0fffffff;
822 case 0x84: /* RFBI_DATA_CYCLE1_1 */
823 s
->rfbi
.data
[3] = value
& 0x0f1f0f1f;
825 case 0x88: /* RFBI_DATA_CYCLE2_1 */
826 s
->rfbi
.data
[4] = value
& 0x0f1f0f1f;
828 case 0x8c: /* RFBI_DATA_CYCLE3_1 */
829 s
->rfbi
.data
[5] = value
& 0x0f1f0f1f;
832 case 0x90: /* RFBI_VSYNC_WIDTH */
833 s
->rfbi
.vsync
= value
& 0xffff;
835 case 0x94: /* RFBI_HSYNC_WIDTH */
836 s
->rfbi
.hsync
= value
& 0xffff;
844 static CPUReadMemoryFunc
* const omap_rfbi1_readfn
[] = {
845 omap_badwidth_read32
,
846 omap_badwidth_read32
,
850 static CPUWriteMemoryFunc
* const omap_rfbi1_writefn
[] = {
851 omap_badwidth_write32
,
852 omap_badwidth_write32
,
856 static uint32_t omap_venc_read(void *opaque
, target_phys_addr_t addr
)
859 case 0x00: /* REV_ID */
860 case 0x04: /* STATUS */
861 case 0x08: /* F_CONTROL */
862 case 0x10: /* VIDOUT_CTRL */
863 case 0x14: /* SYNC_CTRL */
864 case 0x1c: /* LLEN */
865 case 0x20: /* FLENS */
866 case 0x24: /* HFLTR_CTRL */
867 case 0x28: /* CC_CARR_WSS_CARR */
868 case 0x2c: /* C_PHASE */
869 case 0x30: /* GAIN_U */
870 case 0x34: /* GAIN_V */
871 case 0x38: /* GAIN_Y */
872 case 0x3c: /* BLACK_LEVEL */
873 case 0x40: /* BLANK_LEVEL */
874 case 0x44: /* X_COLOR */
875 case 0x48: /* M_CONTROL */
876 case 0x4c: /* BSTAMP_WSS_DATA */
877 case 0x50: /* S_CARR */
878 case 0x54: /* LINE21 */
879 case 0x58: /* LN_SEL */
880 case 0x5c: /* L21__WC_CTL */
881 case 0x60: /* HTRIGGER_VTRIGGER */
882 case 0x64: /* SAVID__EAVID */
883 case 0x68: /* FLEN__FAL */
884 case 0x6c: /* LAL__PHASE_RESET */
885 case 0x70: /* HS_INT_START_STOP_X */
886 case 0x74: /* HS_EXT_START_STOP_X */
887 case 0x78: /* VS_INT_START_X */
888 case 0x7c: /* VS_INT_STOP_X__VS_INT_START_Y */
889 case 0x80: /* VS_INT_STOP_Y__VS_INT_START_X */
890 case 0x84: /* VS_EXT_STOP_X__VS_EXT_START_Y */
891 case 0x88: /* VS_EXT_STOP_Y */
892 case 0x90: /* AVID_START_STOP_X */
893 case 0x94: /* AVID_START_STOP_Y */
894 case 0xa0: /* FID_INT_START_X__FID_INT_START_Y */
895 case 0xa4: /* FID_INT_OFFSET_Y__FID_EXT_START_X */
896 case 0xa8: /* FID_EXT_START_Y__FID_EXT_OFFSET_Y */
897 case 0xb0: /* TVDETGP_INT_START_STOP_X */
898 case 0xb4: /* TVDETGP_INT_START_STOP_Y */
899 case 0xb8: /* GEN_CTRL */
900 case 0xc4: /* DAC_TST__DAC_A */
901 case 0xc8: /* DAC_B__DAC_C */
911 static void omap_venc_write(void *opaque
, target_phys_addr_t addr
,
915 case 0x08: /* F_CONTROL */
916 case 0x10: /* VIDOUT_CTRL */
917 case 0x14: /* SYNC_CTRL */
918 case 0x1c: /* LLEN */
919 case 0x20: /* FLENS */
920 case 0x24: /* HFLTR_CTRL */
921 case 0x28: /* CC_CARR_WSS_CARR */
922 case 0x2c: /* C_PHASE */
923 case 0x30: /* GAIN_U */
924 case 0x34: /* GAIN_V */
925 case 0x38: /* GAIN_Y */
926 case 0x3c: /* BLACK_LEVEL */
927 case 0x40: /* BLANK_LEVEL */
928 case 0x44: /* X_COLOR */
929 case 0x48: /* M_CONTROL */
930 case 0x4c: /* BSTAMP_WSS_DATA */
931 case 0x50: /* S_CARR */
932 case 0x54: /* LINE21 */
933 case 0x58: /* LN_SEL */
934 case 0x5c: /* L21__WC_CTL */
935 case 0x60: /* HTRIGGER_VTRIGGER */
936 case 0x64: /* SAVID__EAVID */
937 case 0x68: /* FLEN__FAL */
938 case 0x6c: /* LAL__PHASE_RESET */
939 case 0x70: /* HS_INT_START_STOP_X */
940 case 0x74: /* HS_EXT_START_STOP_X */
941 case 0x78: /* VS_INT_START_X */
942 case 0x7c: /* VS_INT_STOP_X__VS_INT_START_Y */
943 case 0x80: /* VS_INT_STOP_Y__VS_INT_START_X */
944 case 0x84: /* VS_EXT_STOP_X__VS_EXT_START_Y */
945 case 0x88: /* VS_EXT_STOP_Y */
946 case 0x90: /* AVID_START_STOP_X */
947 case 0x94: /* AVID_START_STOP_Y */
948 case 0xa0: /* FID_INT_START_X__FID_INT_START_Y */
949 case 0xa4: /* FID_INT_OFFSET_Y__FID_EXT_START_X */
950 case 0xa8: /* FID_EXT_START_Y__FID_EXT_OFFSET_Y */
951 case 0xb0: /* TVDETGP_INT_START_STOP_X */
952 case 0xb4: /* TVDETGP_INT_START_STOP_Y */
953 case 0xb8: /* GEN_CTRL */
954 case 0xc4: /* DAC_TST__DAC_A */
955 case 0xc8: /* DAC_B__DAC_C */
963 static CPUReadMemoryFunc
* const omap_venc1_readfn
[] = {
964 omap_badwidth_read32
,
965 omap_badwidth_read32
,
969 static CPUWriteMemoryFunc
* const omap_venc1_writefn
[] = {
970 omap_badwidth_write32
,
971 omap_badwidth_write32
,
975 static uint32_t omap_im3_read(void *opaque
, target_phys_addr_t addr
)
978 case 0x0a8: /* SBIMERRLOGA */
979 case 0x0b0: /* SBIMERRLOG */
980 case 0x190: /* SBIMSTATE */
981 case 0x198: /* SBTMSTATE_L */
982 case 0x19c: /* SBTMSTATE_H */
983 case 0x1a8: /* SBIMCONFIG_L */
984 case 0x1ac: /* SBIMCONFIG_H */
985 case 0x1f8: /* SBID_L */
986 case 0x1fc: /* SBID_H */
996 static void omap_im3_write(void *opaque
, target_phys_addr_t addr
,
1000 case 0x0b0: /* SBIMERRLOG */
1001 case 0x190: /* SBIMSTATE */
1002 case 0x198: /* SBTMSTATE_L */
1003 case 0x19c: /* SBTMSTATE_H */
1004 case 0x1a8: /* SBIMCONFIG_L */
1005 case 0x1ac: /* SBIMCONFIG_H */
1013 static CPUReadMemoryFunc
* const omap_im3_readfn
[] = {
1014 omap_badwidth_read32
,
1015 omap_badwidth_read32
,
1019 static CPUWriteMemoryFunc
* const omap_im3_writefn
[] = {
1020 omap_badwidth_write32
,
1021 omap_badwidth_write32
,
1025 struct omap_dss_s
*omap_dss_init(struct omap_target_agent_s
*ta
,
1026 target_phys_addr_t l3_base
,
1027 qemu_irq irq
, qemu_irq drq
,
1028 omap_clk fck1
, omap_clk fck2
, omap_clk ck54m
,
1029 omap_clk ick1
, omap_clk ick2
)
1032 struct omap_dss_s
*s
= (struct omap_dss_s
*)
1033 g_malloc0(sizeof(struct omap_dss_s
));
1039 iomemtype
[0] = l4_register_io_memory(omap_diss1_readfn
,
1040 omap_diss1_writefn
, s
);
1041 iomemtype
[1] = l4_register_io_memory(omap_disc1_readfn
,
1042 omap_disc1_writefn
, s
);
1043 iomemtype
[2] = l4_register_io_memory(omap_rfbi1_readfn
,
1044 omap_rfbi1_writefn
, s
);
1045 iomemtype
[3] = l4_register_io_memory(omap_venc1_readfn
,
1046 omap_venc1_writefn
, s
);
1047 iomemtype
[4] = cpu_register_io_memory(omap_im3_readfn
,
1048 omap_im3_writefn
, s
, DEVICE_NATIVE_ENDIAN
);
1049 omap_l4_attach(ta
, 0, iomemtype
[0]);
1050 omap_l4_attach(ta
, 1, iomemtype
[1]);
1051 omap_l4_attach(ta
, 2, iomemtype
[2]);
1052 omap_l4_attach(ta
, 3, iomemtype
[3]);
1053 cpu_register_physical_memory(l3_base
, 0x1000, iomemtype
[4]);
1056 s
->state
= graphic_console_init(omap_update_display
,
1057 omap_invalidate_display
, omap_screen_dump
, s
);
1063 void omap_rfbi_attach(struct omap_dss_s
*s
, int cs
, struct rfbi_chip_s
*chip
)
1065 if (cs
< 0 || cs
> 1)
1066 hw_error("%s: wrong CS %i\n", __FUNCTION__
, cs
);
1067 s
->rfbi
.chip
[cs
] = chip
;