1 /*
2 * Status and system control registers for ARM RealView/Versatile boards.
3 *
4 * Copyright (c) 2006-2007 CodeSourcery.
5 * Written by Paul Brook
6 *
7 * This code is licensed under the GPL.
8 */
9
10 #include "qemu/osdep.h"
11 #include "hw/irq.h"
12 #include "hw/qdev-properties.h"
13 #include "qemu/timer.h"
14 #include "sysemu/runstate.h"
15 #include "qemu/bitops.h"
16 #include "hw/sysbus.h"
17 #include "migration/vmstate.h"
18 #include "hw/arm/primecell.h"
19 #include "qemu/log.h"
20 #include "qemu/module.h"
21 #include "qom/object.h"
22
23 #define LOCK_VALUE 0xa05f
24
25 #define TYPE_ARM_SYSCTL "realview_sysctl"
26 OBJECT_DECLARE_SIMPLE_TYPE(arm_sysctl_state, ARM_SYSCTL)
27
28 struct arm_sysctl_state {
29 SysBusDevice parent_obj;
30
31 MemoryRegion iomem;
32 qemu_irq pl110_mux_ctrl;
33
34 uint32_t sys_id;
35 uint32_t leds;
36 uint16_t lockval;
37 uint32_t cfgdata1;
38 uint32_t cfgdata2;
39 uint32_t flags;
40 uint32_t nvflags;
41 uint32_t resetlevel;
42 uint32_t proc_id;
43 uint32_t sys_mci;
44 uint32_t sys_cfgdata;
45 uint32_t sys_cfgctrl;
46 uint32_t sys_cfgstat;
47 uint32_t sys_clcd;
48 uint32_t mb_clock[6];
49 uint32_t *db_clock;
50 uint32_t db_num_vsensors;
51 uint32_t *db_voltage;
52 uint32_t db_num_clocks;
53 uint32_t *db_clock_reset;
54 };
55
56 static const VMStateDescription vmstate_arm_sysctl = {
57 .name = "realview_sysctl",
58 .version_id = 4,
59 .minimum_version_id = 1,
60 .fields = (const VMStateField[]) {
61 VMSTATE_UINT32(leds, arm_sysctl_state),
62 VMSTATE_UINT16(lockval, arm_sysctl_state),
63 VMSTATE_UINT32(cfgdata1, arm_sysctl_state),
64 VMSTATE_UINT32(cfgdata2, arm_sysctl_state),
65 VMSTATE_UINT32(flags, arm_sysctl_state),
66 VMSTATE_UINT32(nvflags, arm_sysctl_state),
67 VMSTATE_UINT32(resetlevel, arm_sysctl_state),
68 VMSTATE_UINT32_V(sys_mci, arm_sysctl_state, 2),
69 VMSTATE_UINT32_V(sys_cfgdata, arm_sysctl_state, 2),
70 VMSTATE_UINT32_V(sys_cfgctrl, arm_sysctl_state, 2),
71 VMSTATE_UINT32_V(sys_cfgstat, arm_sysctl_state, 2),
72 VMSTATE_UINT32_V(sys_clcd, arm_sysctl_state, 3),
73 VMSTATE_UINT32_ARRAY_V(mb_clock, arm_sysctl_state, 6, 4),
74 VMSTATE_VARRAY_UINT32(db_clock, arm_sysctl_state, db_num_clocks,
75 4, vmstate_info_uint32, uint32_t),
76 VMSTATE_END_OF_LIST()
77 }
78 };
79
80 /* The PB926 actually uses a different format for
81 * its SYS_ID register. Fortunately the bits which are
82 * board type on later boards are distinct.
83 */
84 #define BOARD_ID_PB926 0x100
85 #define BOARD_ID_EB 0x140
86 #define BOARD_ID_PBA8 0x178
87 #define BOARD_ID_PBX 0x182
88 #define BOARD_ID_VEXPRESS 0x190
89
board_id(arm_sysctl_state * s)90 static int board_id(arm_sysctl_state *s)
91 {
92 /* Extract the board ID field from the SYS_ID register value */
93 return (s->sys_id >> 16) & 0xfff;
94 }
95
arm_sysctl_reset(DeviceState * d)96 static void arm_sysctl_reset(DeviceState *d)
97 {
98 arm_sysctl_state *s = ARM_SYSCTL(d);
99 int i;
100
101 s->leds = 0;
102 s->lockval = 0;
103 s->cfgdata1 = 0;
104 s->cfgdata2 = 0;
105 s->flags = 0;
106 s->resetlevel = 0;
107 /* Motherboard oscillators (in Hz) */
108 s->mb_clock[0] = 50000000; /* Static memory clock: 50MHz */
109 s->mb_clock[1] = 23750000; /* motherboard CLCD clock: 23.75MHz */
110 s->mb_clock[2] = 24000000; /* IO FPGA peripheral clock: 24MHz */
111 s->mb_clock[3] = 24000000; /* IO FPGA reserved clock: 24MHz */
112 s->mb_clock[4] = 24000000; /* System bus global clock: 24MHz */
113 s->mb_clock[5] = 24000000; /* IO FPGA reserved clock: 24MHz */
114 /* Daughterboard oscillators: reset from property values */
115 for (i = 0; i < s->db_num_clocks; i++) {
116 s->db_clock[i] = s->db_clock_reset[i];
117 }
118 if (board_id(s) == BOARD_ID_VEXPRESS) {
119 /* On VExpress this register will RAZ/WI */
120 s->sys_clcd = 0;
121 } else {
122 /* All others: CLCDID 0x1f, indicating VGA */
123 s->sys_clcd = 0x1f00;
124 }
125 }
126
arm_sysctl_read(void * opaque,hwaddr offset,unsigned size)127 static uint64_t arm_sysctl_read(void *opaque, hwaddr offset,
128 unsigned size)
129 {
130 arm_sysctl_state *s = (arm_sysctl_state *)opaque;
131
132 switch (offset) {
133 case 0x00: /* ID */
134 return s->sys_id;
135 case 0x04: /* SW */
136 /* General purpose hardware switches.
137 We don't have a useful way of exposing these to the user. */
138 return 0;
139 case 0x08: /* LED */
140 return s->leds;
141 case 0x20: /* LOCK */
142 return s->lockval;
143 case 0x0c: /* OSC0 */
144 case 0x10: /* OSC1 */
145 case 0x14: /* OSC2 */
146 case 0x18: /* OSC3 */
147 case 0x1c: /* OSC4 */
148 case 0x24: /* 100HZ */
149 /* ??? Implement these. */
150 return 0;
151 case 0x28: /* CFGDATA1 */
152 return s->cfgdata1;
153 case 0x2c: /* CFGDATA2 */
154 return s->cfgdata2;
155 case 0x30: /* FLAGS */
156 return s->flags;
157 case 0x38: /* NVFLAGS */
158 return s->nvflags;
159 case 0x40: /* RESETCTL */
160 if (board_id(s) == BOARD_ID_VEXPRESS) {
161 /* reserved: RAZ/WI */
162 return 0;
163 }
164 return s->resetlevel;
165 case 0x44: /* PCICTL */
166 return 1;
167 case 0x48: /* MCI */
168 return s->sys_mci;
169 case 0x4c: /* FLASH */
170 return 0;
171 case 0x50: /* CLCD */
172 return s->sys_clcd;
173 case 0x54: /* CLCDSER */
174 return 0;
175 case 0x58: /* BOOTCS */
176 return 0;
177 case 0x5c: /* 24MHz */
178 return muldiv64(qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL), 24000000,
179 NANOSECONDS_PER_SECOND);
180 case 0x60: /* MISC */
181 return 0;
182 case 0x84: /* PROCID0 */
183 return s->proc_id;
184 case 0x88: /* PROCID1 */
185 return 0xff000000;
186 case 0x64: /* DMAPSR0 */
187 case 0x68: /* DMAPSR1 */
188 case 0x6c: /* DMAPSR2 */
189 case 0x70: /* IOSEL */
190 case 0x74: /* PLDCTL */
191 case 0x80: /* BUSID */
192 case 0x8c: /* OSCRESET0 */
193 case 0x90: /* OSCRESET1 */
194 case 0x94: /* OSCRESET2 */
195 case 0x98: /* OSCRESET3 */
196 case 0x9c: /* OSCRESET4 */
197 case 0xc0: /* SYS_TEST_OSC0 */
198 case 0xc4: /* SYS_TEST_OSC1 */
199 case 0xc8: /* SYS_TEST_OSC2 */
200 case 0xcc: /* SYS_TEST_OSC3 */
201 case 0xd0: /* SYS_TEST_OSC4 */
202 return 0;
203 case 0xa0: /* SYS_CFGDATA */
204 if (board_id(s) != BOARD_ID_VEXPRESS) {
205 goto bad_reg;
206 }
207 return s->sys_cfgdata;
208 case 0xa4: /* SYS_CFGCTRL */
209 if (board_id(s) != BOARD_ID_VEXPRESS) {
210 goto bad_reg;
211 }
212 return s->sys_cfgctrl;
213 case 0xa8: /* SYS_CFGSTAT */
214 if (board_id(s) != BOARD_ID_VEXPRESS) {
215 goto bad_reg;
216 }
217 return s->sys_cfgstat;
218 default:
219 bad_reg:
220 qemu_log_mask(LOG_GUEST_ERROR,
221 "arm_sysctl_read: Bad register offset 0x%x\n",
222 (int)offset);
223 return 0;
224 }
225 }
226
227 /* SYS_CFGCTRL functions */
228 #define SYS_CFG_OSC 1
229 #define SYS_CFG_VOLT 2
230 #define SYS_CFG_AMP 3
231 #define SYS_CFG_TEMP 4
232 #define SYS_CFG_RESET 5
233 #define SYS_CFG_SCC 6
234 #define SYS_CFG_MUXFPGA 7
235 #define SYS_CFG_SHUTDOWN 8
236 #define SYS_CFG_REBOOT 9
237 #define SYS_CFG_DVIMODE 11
238 #define SYS_CFG_POWER 12
239 #define SYS_CFG_ENERGY 13
240
241 /* SYS_CFGCTRL site field values */
242 #define SYS_CFG_SITE_MB 0
243 #define SYS_CFG_SITE_DB1 1
244 #define SYS_CFG_SITE_DB2 2
245
246 /**
247 * vexpress_cfgctrl_read:
248 * @s: arm_sysctl_state pointer
249 * @dcc, @function, @site, @position, @device: split out values from
250 * SYS_CFGCTRL register
251 * @val: pointer to where to put the read data on success
252 *
253 * Handle a VExpress SYS_CFGCTRL register read. On success, return true and
254 * write the read value to *val. On failure, return false (and val may
255 * or may not be written to).
256 */
vexpress_cfgctrl_read(arm_sysctl_state * s,unsigned int dcc,unsigned int function,unsigned int site,unsigned int position,unsigned int device,uint32_t * val)257 static bool vexpress_cfgctrl_read(arm_sysctl_state *s, unsigned int dcc,
258 unsigned int function, unsigned int site,
259 unsigned int position, unsigned int device,
260 uint32_t *val)
261 {
262 /* We don't support anything other than DCC 0, board stack position 0
263 * or sites other than motherboard/daughterboard:
264 */
265 if (dcc != 0 || position != 0 ||
266 (site != SYS_CFG_SITE_MB && site != SYS_CFG_SITE_DB1)) {
267 goto cfgctrl_unimp;
268 }
269
270 switch (function) {
271 case SYS_CFG_VOLT:
272 if (site == SYS_CFG_SITE_DB1 && device < s->db_num_vsensors) {
273 *val = s->db_voltage[device];
274 return true;
275 }
276 if (site == SYS_CFG_SITE_MB && device == 0) {
277 /* There is only one motherboard voltage sensor:
278 * VIO : 3.3V : bus voltage between mother and daughterboard
279 */
280 *val = 3300000;
281 return true;
282 }
283 break;
284 case SYS_CFG_OSC:
285 if (site == SYS_CFG_SITE_MB && device < ARRAY_SIZE(s->mb_clock)) {
286 /* motherboard clock */
287 *val = s->mb_clock[device];
288 return true;
289 }
290 if (site == SYS_CFG_SITE_DB1 && device < s->db_num_clocks) {
291 /* daughterboard clock */
292 *val = s->db_clock[device];
293 return true;
294 }
295 break;
296 default:
297 break;
298 }
299
300 cfgctrl_unimp:
301 qemu_log_mask(LOG_UNIMP,
302 "arm_sysctl: Unimplemented SYS_CFGCTRL read of function "
303 "0x%x DCC 0x%x site 0x%x position 0x%x device 0x%x\n",
304 function, dcc, site, position, device);
305 return false;
306 }
307
308 /**
309 * vexpress_cfgctrl_write:
310 * @s: arm_sysctl_state pointer
311 * @dcc, @function, @site, @position, @device: split out values from
312 * SYS_CFGCTRL register
313 * @val: data to write
314 *
315 * Handle a VExpress SYS_CFGCTRL register write. On success, return true.
316 * On failure, return false.
317 */
vexpress_cfgctrl_write(arm_sysctl_state * s,unsigned int dcc,unsigned int function,unsigned int site,unsigned int position,unsigned int device,uint32_t val)318 static bool vexpress_cfgctrl_write(arm_sysctl_state *s, unsigned int dcc,
319 unsigned int function, unsigned int site,
320 unsigned int position, unsigned int device,
321 uint32_t val)
322 {
323 /* We don't support anything other than DCC 0, board stack position 0
324 * or sites other than motherboard/daughterboard:
325 */
326 if (dcc != 0 || position != 0 ||
327 (site != SYS_CFG_SITE_MB && site != SYS_CFG_SITE_DB1)) {
328 goto cfgctrl_unimp;
329 }
330
331 switch (function) {
332 case SYS_CFG_OSC:
333 if (site == SYS_CFG_SITE_MB && device < ARRAY_SIZE(s->mb_clock)) {
334 /* motherboard clock */
335 s->mb_clock[device] = val;
336 return true;
337 }
338 if (site == SYS_CFG_SITE_DB1 && device < s->db_num_clocks) {
339 /* daughterboard clock */
340 s->db_clock[device] = val;
341 return true;
342 }
343 break;
344 case SYS_CFG_MUXFPGA:
345 if (site == SYS_CFG_SITE_MB && device == 0) {
346 /* Select whether video output comes from motherboard
347 * or daughterboard: log and ignore as QEMU doesn't
348 * support this.
349 */
350 qemu_log_mask(LOG_UNIMP, "arm_sysctl: selection of video output "
351 "not supported, ignoring\n");
352 return true;
353 }
354 break;
355 case SYS_CFG_SHUTDOWN:
356 if (site == SYS_CFG_SITE_MB && device == 0) {
357 qemu_system_shutdown_request(SHUTDOWN_CAUSE_GUEST_SHUTDOWN);
358 return true;
359 }
360 break;
361 case SYS_CFG_REBOOT:
362 if (site == SYS_CFG_SITE_MB && device == 0) {
363 qemu_system_reset_request(SHUTDOWN_CAUSE_GUEST_RESET);
364 return true;
365 }
366 break;
367 case SYS_CFG_DVIMODE:
368 if (site == SYS_CFG_SITE_MB && device == 0) {
369 /* Selecting DVI mode is meaningless for QEMU: we will
370 * always display the output correctly according to the
371 * pixel height/width programmed into the CLCD controller.
372 */
373 return true;
374 }
375 default:
376 break;
377 }
378
379 cfgctrl_unimp:
380 qemu_log_mask(LOG_UNIMP,
381 "arm_sysctl: Unimplemented SYS_CFGCTRL write of function "
382 "0x%x DCC 0x%x site 0x%x position 0x%x device 0x%x\n",
383 function, dcc, site, position, device);
384 return false;
385 }
386
arm_sysctl_write(void * opaque,hwaddr offset,uint64_t val,unsigned size)387 static void arm_sysctl_write(void *opaque, hwaddr offset,
388 uint64_t val, unsigned size)
389 {
390 arm_sysctl_state *s = (arm_sysctl_state *)opaque;
391
392 switch (offset) {
393 case 0x08: /* LED */
394 s->leds = val;
395 break;
396 case 0x0c: /* OSC0 */
397 case 0x10: /* OSC1 */
398 case 0x14: /* OSC2 */
399 case 0x18: /* OSC3 */
400 case 0x1c: /* OSC4 */
401 /* ??? */
402 break;
403 case 0x20: /* LOCK */
404 if (val == LOCK_VALUE)
405 s->lockval = val;
406 else
407 s->lockval = val & 0x7fff;
408 break;
409 case 0x28: /* CFGDATA1 */
410 /* ??? Need to implement this. */
411 s->cfgdata1 = val;
412 break;
413 case 0x2c: /* CFGDATA2 */
414 /* ??? Need to implement this. */
415 s->cfgdata2 = val;
416 break;
417 case 0x30: /* FLAGSSET */
418 s->flags |= val;
419 break;
420 case 0x34: /* FLAGSCLR */
421 s->flags &= ~val;
422 break;
423 case 0x38: /* NVFLAGSSET */
424 s->nvflags |= val;
425 break;
426 case 0x3c: /* NVFLAGSCLR */
427 s->nvflags &= ~val;
428 break;
429 case 0x40: /* RESETCTL */
430 switch (board_id(s)) {
431 case BOARD_ID_PB926:
432 if (s->lockval == LOCK_VALUE) {
433 s->resetlevel = val;
434 if (val & 0x100) {
435 qemu_system_reset_request(SHUTDOWN_CAUSE_GUEST_RESET);
436 }
437 }
438 break;
439 case BOARD_ID_PBX:
440 case BOARD_ID_PBA8:
441 if (s->lockval == LOCK_VALUE) {
442 s->resetlevel = val;
443 if (val & 0x04) {
444 qemu_system_reset_request(SHUTDOWN_CAUSE_GUEST_RESET);
445 }
446 }
447 break;
448 case BOARD_ID_VEXPRESS:
449 case BOARD_ID_EB:
450 default:
451 /* reserved: RAZ/WI */
452 break;
453 }
454 break;
455 case 0x44: /* PCICTL */
456 /* nothing to do. */
457 break;
458 case 0x4c: /* FLASH */
459 break;
460 case 0x50: /* CLCD */
461 switch (board_id(s)) {
462 case BOARD_ID_PB926:
463 /* On 926 bits 13:8 are R/O, bits 1:0 control
464 * the mux that defines how to interpret the PL110
465 * graphics format, and other bits are r/w but we
466 * don't implement them to do anything.
467 */
468 s->sys_clcd &= 0x3f00;
469 s->sys_clcd |= val & ~0x3f00;
470 qemu_set_irq(s->pl110_mux_ctrl, val & 3);
471 break;
472 case BOARD_ID_EB:
473 /* The EB is the same except that there is no mux since
474 * the EB has a PL111.
475 */
476 s->sys_clcd &= 0x3f00;
477 s->sys_clcd |= val & ~0x3f00;
478 break;
479 case BOARD_ID_PBA8:
480 case BOARD_ID_PBX:
481 /* On PBA8 and PBX bit 7 is r/w and all other bits
482 * are either r/o or RAZ/WI.
483 */
484 s->sys_clcd &= (1 << 7);
485 s->sys_clcd |= val & ~(1 << 7);
486 break;
487 case BOARD_ID_VEXPRESS:
488 default:
489 /* On VExpress this register is unimplemented and will RAZ/WI */
490 break;
491 }
492 break;
493 case 0x54: /* CLCDSER */
494 case 0x64: /* DMAPSR0 */
495 case 0x68: /* DMAPSR1 */
496 case 0x6c: /* DMAPSR2 */
497 case 0x70: /* IOSEL */
498 case 0x74: /* PLDCTL */
499 case 0x80: /* BUSID */
500 case 0x84: /* PROCID0 */
501 case 0x88: /* PROCID1 */
502 case 0x8c: /* OSCRESET0 */
503 case 0x90: /* OSCRESET1 */
504 case 0x94: /* OSCRESET2 */
505 case 0x98: /* OSCRESET3 */
506 case 0x9c: /* OSCRESET4 */
507 break;
508 case 0xa0: /* SYS_CFGDATA */
509 if (board_id(s) != BOARD_ID_VEXPRESS) {
510 goto bad_reg;
511 }
512 s->sys_cfgdata = val;
513 return;
514 case 0xa4: /* SYS_CFGCTRL */
515 if (board_id(s) != BOARD_ID_VEXPRESS) {
516 goto bad_reg;
517 }
518 /* Undefined bits [19:18] are RAZ/WI, and writing to
519 * the start bit just triggers the action; it always reads
520 * as zero.
521 */
522 s->sys_cfgctrl = val & ~((3 << 18) | (1 << 31));
523 if (val & (1 << 31)) {
524 /* Start bit set -- actually do something */
525 unsigned int dcc = extract32(s->sys_cfgctrl, 26, 4);
526 unsigned int function = extract32(s->sys_cfgctrl, 20, 6);
527 unsigned int site = extract32(s->sys_cfgctrl, 16, 2);
528 unsigned int position = extract32(s->sys_cfgctrl, 12, 4);
529 unsigned int device = extract32(s->sys_cfgctrl, 0, 12);
530 s->sys_cfgstat = 1; /* complete */
531 if (s->sys_cfgctrl & (1 << 30)) {
532 if (!vexpress_cfgctrl_write(s, dcc, function, site, position,
533 device, s->sys_cfgdata)) {
534 s->sys_cfgstat |= 2; /* error */
535 }
536 } else {
537 uint32_t data;
538 if (!vexpress_cfgctrl_read(s, dcc, function, site, position,
539 device, &data)) {
540 s->sys_cfgstat |= 2; /* error */
541 } else {
542 s->sys_cfgdata = data;
543 }
544 }
545 }
546 s->sys_cfgctrl &= ~(1 << 31);
547 return;
548 case 0xa8: /* SYS_CFGSTAT */
549 if (board_id(s) != BOARD_ID_VEXPRESS) {
550 goto bad_reg;
551 }
552 s->sys_cfgstat = val & 3;
553 return;
554 default:
555 bad_reg:
556 qemu_log_mask(LOG_GUEST_ERROR,
557 "arm_sysctl_write: Bad register offset 0x%x\n",
558 (int)offset);
559 return;
560 }
561 }
562
563 static const MemoryRegionOps arm_sysctl_ops = {
564 .read = arm_sysctl_read,
565 .write = arm_sysctl_write,
566 .endianness = DEVICE_NATIVE_ENDIAN,
567 };
568
arm_sysctl_gpio_set(void * opaque,int line,int level)569 static void arm_sysctl_gpio_set(void *opaque, int line, int level)
570 {
571 arm_sysctl_state *s = (arm_sysctl_state *)opaque;
572 switch (line) {
573 case ARM_SYSCTL_GPIO_MMC_WPROT:
574 {
575 /* For PB926 and EB write-protect is bit 2 of SYS_MCI;
576 * for all later boards it is bit 1.
577 */
578 int bit = 2;
579 if ((board_id(s) == BOARD_ID_PB926) || (board_id(s) == BOARD_ID_EB)) {
580 bit = 4;
581 }
582 s->sys_mci &= ~bit;
583 if (level) {
584 s->sys_mci |= bit;
585 }
586 break;
587 }
588 case ARM_SYSCTL_GPIO_MMC_CARDIN:
589 s->sys_mci &= ~1;
590 if (level) {
591 s->sys_mci |= 1;
592 }
593 break;
594 }
595 }
596
arm_sysctl_init(Object * obj)597 static void arm_sysctl_init(Object *obj)
598 {
599 DeviceState *dev = DEVICE(obj);
600 SysBusDevice *sd = SYS_BUS_DEVICE(obj);
601 arm_sysctl_state *s = ARM_SYSCTL(obj);
602
603 memory_region_init_io(&s->iomem, OBJECT(dev), &arm_sysctl_ops, s,
604 "arm-sysctl", 0x1000);
605 sysbus_init_mmio(sd, &s->iomem);
606 qdev_init_gpio_in(dev, arm_sysctl_gpio_set, 2);
607 qdev_init_gpio_out(dev, &s->pl110_mux_ctrl, 1);
608 }
609
arm_sysctl_realize(DeviceState * d,Error ** errp)610 static void arm_sysctl_realize(DeviceState *d, Error **errp)
611 {
612 arm_sysctl_state *s = ARM_SYSCTL(d);
613
614 s->db_clock = g_new0(uint32_t, s->db_num_clocks);
615 }
616
arm_sysctl_finalize(Object * obj)617 static void arm_sysctl_finalize(Object *obj)
618 {
619 arm_sysctl_state *s = ARM_SYSCTL(obj);
620
621 g_free(s->db_voltage);
622 g_free(s->db_clock);
623 g_free(s->db_clock_reset);
624 }
625
626 static Property arm_sysctl_properties[] = {
627 DEFINE_PROP_UINT32("sys_id", arm_sysctl_state, sys_id, 0),
628 DEFINE_PROP_UINT32("proc_id", arm_sysctl_state, proc_id, 0),
629 /* Daughterboard power supply voltages (as reported via SYS_CFG) */
630 DEFINE_PROP_ARRAY("db-voltage", arm_sysctl_state, db_num_vsensors,
631 db_voltage, qdev_prop_uint32, uint32_t),
632 /* Daughterboard clock reset values (as reported via SYS_CFG) */
633 DEFINE_PROP_ARRAY("db-clock", arm_sysctl_state, db_num_clocks,
634 db_clock_reset, qdev_prop_uint32, uint32_t),
635 DEFINE_PROP_END_OF_LIST(),
636 };
637
arm_sysctl_class_init(ObjectClass * klass,void * data)638 static void arm_sysctl_class_init(ObjectClass *klass, void *data)
639 {
640 DeviceClass *dc = DEVICE_CLASS(klass);
641
642 dc->realize = arm_sysctl_realize;
643 dc->reset = arm_sysctl_reset;
644 dc->vmsd = &vmstate_arm_sysctl;
645 device_class_set_props(dc, arm_sysctl_properties);
646 }
647
648 static const TypeInfo arm_sysctl_info = {
649 .name = TYPE_ARM_SYSCTL,
650 .parent = TYPE_SYS_BUS_DEVICE,
651 .instance_size = sizeof(arm_sysctl_state),
652 .instance_init = arm_sysctl_init,
653 .instance_finalize = arm_sysctl_finalize,
654 .class_init = arm_sysctl_class_init,
655 };
656
arm_sysctl_register_types(void)657 static void arm_sysctl_register_types(void)
658 {
659 type_register_static(&arm_sysctl_info);
660 }
661
662 type_init(arm_sysctl_register_types)
663