| blob | 8d8049bdfaf613a83336fd22ed326ddfe9717716 |
1 /*
2 * Copyright 2008-2009 Freescale Semiconductor, Inc. All Rights Reserved.
3 * Copyright 2010 Orex Computed Radiography
4 */
6 /*
7 * The code contained herein is licensed under the GNU General Public
8 * License. You may obtain a copy of the GNU General Public License
9 * Version 2 or later at the following locations:
10 *
11 * http://www.opensource.org/licenses/gpl-license.html
12 * http://www.gnu.org/copyleft/gpl.html
13 */
15 /* based on rtc-mc13892.c */
17 /*
18 * This driver uses the 47-bit 32 kHz counter in the Freescale DryIce block
19 * to implement a Linux RTC. Times and alarms are truncated to seconds.
20 * Since the RTC framework performs API locking via rtc->ops_lock the
21 * only simultaneous accesses we need to deal with is updating DryIce
22 * registers while servicing an alarm.
23 *
24 * Note that reading the DSR (DryIce Status Register) automatically clears
25 * the WCF (Write Complete Flag). All DryIce writes are synchronized to the
26 * LP (Low Power) domain and set the WCF upon completion. Writes to the
27 * DIER (DryIce Interrupt Enable Register) are the only exception. These
28 * occur at normal bus speeds and do not set WCF. Periodic interrupts are
29 * not supported by the hardware.
30 */
32 #include <linux/io.h>
33 #include <linux/clk.h>
34 #include <linux/delay.h>
35 #include <linux/module.h>
36 #include <linux/platform_device.h>
37 #include <linux/rtc.h>
38 #include <linux/sched.h>
39 #include <linux/spinlock.h>
40 #include <linux/workqueue.h>
41 #include <linux/of.h>
43 /* DryIce Register Definitions */
106 /**
107 * struct imxdi_dev - private imxdi rtc data
108 * @pdev: pionter to platform dev
109 * @rtc: pointer to rtc struct
110 * @ioaddr: IO registers pointer
111 * @irq: dryice normal interrupt
112 * @clk: input reference clock
113 * @dsr: copy of the DSR register
114 * @irq_lock: interrupt enable register (DIER) lock
115 * @write_wait: registers write complete queue
116 * @write_mutex: serialize registers write
117 * @work: schedule alarm work
118 */
125 u32 dsr;
126 spinlock_t irq_lock;
127 wait_queue_head_t write_wait;
130 };
132 /* Some background:
133 *
134 * The DryIce unit is a complex security/tamper monitor device. To be able do
135 * its job in a useful manner it runs a bigger statemachine to bring it into
136 * security/tamper failure state and once again to bring it out of this state.
137 *
138 * This unit can be in one of three states:
139 *
140 * - "NON-VALID STATE"
141 * always after the battery power was removed
142 * - "FAILURE STATE"
143 * if one of the enabled security events has happened
144 * - "VALID STATE"
145 * if the unit works as expected
146 *
147 * Everything stops when the unit enters the failure state including the RTC
148 * counter (to be able to detect the time the security event happened).
149 *
150 * The following events (when enabled) let the DryIce unit enter the failure
151 * state:
152 *
153 * - wire-mesh-tamper detect
154 * - external tamper B detect
155 * - external tamper A detect
156 * - temperature tamper detect
157 * - clock tamper detect
158 * - voltage tamper detect
159 * - RTC counter overflow
160 * - monotonic counter overflow
161 * - external boot
162 *
163 * If we find the DryIce unit in "FAILURE STATE" and the TDCHL cleared, we
164 * can only detect this state. In this case the unit is completely locked and
165 * must force a second "SYSTEM POR" to bring the DryIce into the
166 * "NON-VALID STATE" + "FAILURE STATE" where a recovery is possible.
167 * If the TDCHL is set in the "FAILURE STATE" we are out of luck. In this case
168 * a battery power cycle is required.
169 *
170 * In the "NON-VALID STATE" + "FAILURE STATE" we can clear the "FAILURE STATE"
171 * and recover the DryIce unit. By clearing the "NON-VALID STATE" as the last
172 * task, we bring back this unit into life.
173 */
175 /*
176 * Do a write into the unit without interrupt support.
177 * We do not need to check the WEF here, because the only reason this kind of
178 * write error can happen is if we write to the unit twice within the 122 us
179 * interval. This cannot happen, since we are using this function only while
180 * setting up the unit.
181 */
184 {
185 /* do the register write */
188 /*
189 * now it takes four 32,768 kHz clock cycles to take
190 * the change into effect = 122 us
191 */
193 }
196 {
197 u32 dtcr;
202 /* the following flags force a transition into the "FAILURE STATE" */
244 }
248 {
249 dev_emerg(&imxdi->pdev->dev, "Please cycle the %s power supply in order to get the DryIce/RTC unit working again\n",
250 power_supply);
251 }
254 {
255 u32 dcr;
259 /* report the cause */
265 /* we are out of luck */
268 }
269 /*
270 * with the next SYSTEM POR we will transit from the "FAILURE STATE"
271 * into the "NON-VALID STATE" + "FAILURE STATE"
272 */
276 }
279 {
280 /* initialize alarm */
284 /* clear alarm flag */
289 }
292 {
295 /*
296 * lets disable all sources which can force the DryIce unit into
297 * the "FAILURE STATE" for now
298 */
300 /* and lets protect them at runtime from any change */
307 sec);
308 /*
309 * the timer cannot be set/modified if
310 * - the TCHL or TCSL bit is set in DCR
311 */
315 /* we are out of luck */
318 }
322 }
323 }
324 /*
325 * - the timer counter stops/is stopped if
326 * - its overflow flag is set (TCO in DSR)
327 * -> clear overflow bit to make it count again
328 * - NVF is set in DSR
329 * -> clear non-valid bit to make it count again
330 * - its TCE (DCR) is cleared
331 * -> set TCE to make it count
332 * - it was never set before
333 * -> write a time into it (required again if the NVF was set)
334 */
335 /* state handled */
337 /* clear overflow flag */
339 /* enable the counter */
341 /* set and trigger it to make it count */
344 /* now prepare for the valid state */
346 }
349 {
350 u32 dcr;
352 /*
353 * now we must first remove the tamper sources in order to get the
354 * device out of the "FAILURE STATE"
355 * To disable any of the following sources we need to modify the DTCR
356 */
361 /*
362 * the tamper register is locked. We cannot disable the
363 * tamper detection. The TDCHL can only be reset by a
364 * DRYICE POR, but we cannot force a DRYICE POR in
365 * softwere because we are still in "FAILURE STATE".
366 * We need a DRYICE POR via battery power cycling....
367 */
368 /*
369 * out of luck!
370 * we cannot disable them without a DRYICE POR
371 */
374 }
376 /* a soft lock can be removed by a SYSTEM POR */
379 }
380 }
382 /* disable all sources */
385 /* clear the status bits now */
398 /*
399 * now we are trying to clear the "Security-violation flag" to
400 * get the DryIce out of this state
401 */
404 /* success? */
409 /* last resort */
412 }
414 /*
415 * now we have left the "FAILURE STATE" and ending up in the
416 * "NON-VALID STATE" time to recover everything
417 */
419 }
422 {
424 u32 dsr;
445 }
448 }
450 /*
451 * enable a dryice interrupt
452 */
454 {
461 }
463 /*
464 * disable a dryice interrupt
465 */
467 {
474 }
476 /*
477 * This function attempts to clear the dryice write-error flag.
478 *
479 * A dryice write error is similar to a bus fault and should not occur in
480 * normal operation. Clearing the flag requires another write, so the root
481 * cause of the problem may need to be fixed before the flag can be cleared.
482 */
484 {
489 /* clear the write error flag */
492 /* wait for it to take effect */
497 }
500 }
502 /*
503 * Write a dryice register and wait until it completes.
504 *
505 * This function uses interrupts to determine when the
506 * write has completed.
507 */
509 {
513 /* serialize register writes */
516 /* enable the write-complete interrupt */
521 /* do the register write */
524 /* wait for the write to finish */
532 "Write-wait timeout "
534 }
536 /* check for write error */
540 }
542 out:
546 }
548 /*
549 * read the seconds portion of the current time from the dryice time counter
550 */
552 {
560 }
562 /*
563 * set the seconds portion of dryice time counter and clear the
564 * fractional part.
565 */
567 {
577 /* we are even more out of luck */
580 }
582 /* we are out of luck for now */
585 }
586 }
588 /* zero the fractional part first */
598 }
602 {
607 else
611 }
613 /*
614 * read the seconds portion of the alarm register.
615 * the fractional part of the alarm register is always zero.
616 */
618 {
620 u32 dcamr;
625 /* alarm is enabled if the interrupt is enabled */
628 /* don't allow the DSR read to mess up DSR_WCF */
631 /* alarm is pending if the alarm flag is set */
637 }
639 /*
640 * set the seconds portion of dryice alarm register
641 */
643 {
653 /* don't allow setting alarm in the past */
658 /* write the new alarm time */
665 else
669 }
677 };
679 /*
680 * dryice "normal" interrupt handler
681 */
683 {
691 /* handle the security violation event */
694 /*
695 * Disable the interrupt when this kind of event has
696 * happened.
697 * There cannot be more than one event of this type,
698 * because it needs a complex state change
699 * including a main power cycle to get again out of
700 * this state.
701 */
703 /* report the violation */
706 }
707 }
709 /* handle write complete and write error cases */
711 /*If the write wait queue is empty then there is no pending
712 operations. It means the interrupt is for DryIce -Security.
713 IRQ must be returned as none.*/
717 /* DSR_WCF clears itself on DSR read */
719 /* mask the interrupt */
722 /* save the dsr value for the wait queue */
727 }
728 }
730 /* handle the alarm case */
732 /* DSR_WCF clears itself on DSR read */
734 /* mask the interrupt */
737 /* finish alarm in user context */
740 }
741 }
743 }
745 /*
746 * post the alarm event from user context so it can sleep
747 * on the write completion.
748 */
750 {
754 /* dismiss the interrupt (ignore error) */
757 /* pass the alarm event to the rtc framework. */
759 }
761 /*
762 * probe for dryice rtc device
763 */
765 {
800 /*
801 * Initialize dryice hardware
802 */
804 /* mask all interrupts */
816 }
824 }
828 err:
832 }
835 {
840 /* mask all interrupts */
846 }
848 #ifdef CONFIG_OF
852 };
855 #endif
861 },
863 };