| blob | 9630e7d3314e59d19dd9e94be9f917cab7307f16 |
1 /*
2 * rtc-ds1305.c -- driver for DS1305 and DS1306 SPI RTC chips
3 *
4 * Copyright (C) 2008 David Brownell
5 *
6 * This program is free software; you can redistribute it and/or modify
7 * it under the terms of the GNU General Public License version 2 as
8 * published by the Free Software Foundation.
9 *
10 */
11 #include <linux/kernel.h>
12 #include <linux/init.h>
13 #include <linux/bcd.h>
14 #include <linux/rtc.h>
15 #include <linux/workqueue.h>
17 #include <linux/spi/spi.h>
18 #include <linux/spi/ds1305.h>
21 /*
22 * Registers ... mask DS1305_WRITE into register address to write,
23 * otherwise you're reading it. All non-bitmask values are BCD.
24 */
25 #define DS1305_WRITE 0x80
28 /* RTC date/time ... the main special cases are that we:
29 * - Need fancy "hours" encoding in 12hour mode
30 * - Don't rely on the "day-of-week" field (or tm_wday)
31 * - Are a 21st-century clock (2000 <= year < 2100)
32 */
36 #define DS1305_MIN 0x01
37 #define DS1305_HOUR 0x02
40 #define DS1305_WDAY 0x03
41 #define DS1305_MDAY 0x04
42 #define DS1305_MON 0x05
43 #define DS1305_YEAR 0x06
46 /* The two alarms have only sec/min/hour/wday fields (ALM_LEN).
47 * DS1305_ALM_DISABLE disables a match field (some combos are bad).
48 *
49 * NOTE that since we don't use WDAY, we limit ourselves to alarms
50 * only one day into the future (vs potentially up to a week).
51 *
52 * NOTE ALSO that while we could generate once-a-second IRQs (UIE), we
53 * don't currently support them. We'd either need to do it only when
54 * no alarm is pending (not the standard model), or to use the second
55 * alarm (implying that this is a DS1305 not DS1306, *and* that either
56 * it's wired up a second IRQ we know, or that INTCN is set)
57 */
59 #define DS1305_ALM_DISABLE 0x80
62 #define DS1305_ALM1(r) (0x0b + (r))
65 /* three control registers */
75 #define DS1305_STATUS 0x10
76 /* status has just AEIx bits, mirrored as IRQFx */
77 #define DS1305_TRICKLE 0x11
78 /* trickle bits are defined in <linux/spi/ds1305.h> */
80 /* a bunch of NVRAM */
93 #define FLAG_EXITING 0
97 };
100 /*----------------------------------------------------------------------*/
102 /*
103 * Utilities ... tolerate 12-hour AM/PM notation in case of non-Linux
104 * software (like a bootloader) which may require it.
105 */
108 {
116 }
119 }
121 }
124 {
126 hour++;
131 }
133 }
135 /*----------------------------------------------------------------------*/
137 /*
138 * Interface to RTC framework
139 */
141 #ifdef CONFIG_RTC_INTF_DEV
143 /*
144 * Context: caller holds rtc->ops_lock (to protect ds1305->ctrl)
145 */
147 {
169 }
175 }
177 done:
179 }
181 #else
182 #define ds1305_ioctl NULL
183 #endif
185 /*
186 * Get/set of date and time is pretty normal.
187 */
190 {
196 /* Use write-then-read to get all the date/time registers
197 * since dma from stack is nonportable
198 */
208 /* Decode the registers */
223 /* Time may not be set */
225 }
228 {
239 /* Write registers starting at the first time/date address. */
254 /* use write-then-read since dma from stack is nonportable */
257 }
259 /*
260 * Get/set of alarm is a bit funky:
261 *
262 * - First there's the inherent raciness of getting the (partitioned)
263 * status of an alarm that could trigger while we're reading parts
264 * of that status.
265 *
266 * - Second there's its limited range (we could increase it a bit by
267 * relying on WDAY), which means it will easily roll over.
268 *
269 * - Third there's the choice of two alarms and alarm signals.
270 * Here we use ALM0 and expect that nINT0 (open drain) is used;
271 * that's the only real option for DS1306 runtime alarms, and is
272 * natural on DS1305.
273 *
274 * - Fourth, there's also ALM1, and a second interrupt signal:
275 * + On DS1305 ALM1 uses nINT1 (when INTCN=1) else nINT0;
276 * + On DS1306 ALM1 only uses INT1 (an active high pulse)
277 * and it won't work when VCC1 is active.
278 *
279 * So to be most general, we should probably set both alarms to the
280 * same value, letting ALM1 be the wakeup event source on DS1306
281 * and handling several wiring options on DS1305.
282 *
283 * - Fifth, we support the polled mode (as well as possible; why not?)
284 * even when no interrupt line is wired to an IRQ.
285 */
287 /*
288 * Context: caller holds rtc->ops_lock (to protect ds1305->ctrl)
289 */
291 {
294 u8 addr;
298 /* Refresh control register cache BEFORE reading ALM0 registers,
299 * since reading alarm registers acks any pending IRQ. That
300 * makes returning "pending" status a bit of a lie, but that bit
301 * of EFI status is at best fragile anyway (given IRQ handlers).
302 */
312 /* get and check ALM0 registers */
328 /* Stuff these values into alm->time and let RTC framework code
329 * fill in the rest ... and also handle rollover to tomorrow when
330 * that's needed.
331 */
338 /* next three fields are unused by Linux */
344 }
346 /*
347 * Context: caller holds rtc->ops_lock (to protect ds1305->ctrl)
348 */
350 {
358 /* convert desired alarm to time_t */
363 /* Read current time as time_t */
371 /* make sure alarm fires within the next 24 hours */
377 /* disable alarm if needed */
386 }
388 /* write alarm */
403 /* enable alarm if requested */
410 }
413 }
415 #ifdef CONFIG_PROC_FS
418 {
423 /* ctrl[2] is treated as read-only; no locking needed */
434 }
448 }
449 }
451 done:
455 }
457 #else
458 #define ds1305_proc NULL
459 #endif
468 };
471 {
478 /* lock to protect ds1305->ctrl */
481 /* Disable the IRQ, and clear its status ... for now, we "know"
482 * that if more than one alarm is active, they're in sync.
483 * Note that reading ALM data registers also clears IRQ status.
484 */
503 }
505 /*
506 * This "real" IRQ handler hands off to a workqueue mostly to allow
507 * mutex locking for ds1305->ctrl ... unlike I2C, we could issue async
508 * I/O requests in IRQ context (to clear the IRQ status).
509 */
511 {
517 }
519 /*----------------------------------------------------------------------*/
521 /*
522 * Interface for NVRAM
523 */
527 {
535 x++;
541 }
543 static ssize_t
546 {
548 u8 addr;
571 }
573 static ssize_t
576 {
578 u8 addr;
601 }
609 };
611 /*----------------------------------------------------------------------*/
613 /*
614 * Interface to SPI stack
615 */
618 {
625 /* Sanity check board setup data. This may be hooked up
626 * in 3wire mode, but we don't care. Note that unless
627 * there's an inverter in place, this needs SPI_CS_HIGH!
628 */
634 /* set up driver data */
641 /* read and cache control registers */
649 }
655 /* Sanity check register values ... partially compensating for the
656 * fact that SPI has no device handshake. A pullup on MISO would
657 * make these tests fail; but not all systems will have one. If
658 * some register is neither 0x00 nor 0xff, a chip is likely there.
659 */
664 }
668 /* enable writes if needed ... if we were paranoid it would
669 * make sense to enable them only when absolutely necessary.
670 */
683 }
685 /* on DS1305, maybe start oscillator; like most low power
686 * oscillators, it may take a second to stabilize
687 */
692 }
694 /* ack any pending IRQs */
698 }
700 /* this may need one-time (re)init */
702 /* maybe enable trickle charge */
707 }
709 /* on DS1306, configure 1 Hz signal */
715 }
720 }
721 }
722 }
723 }
737 }
742 }
744 /* see if non-Linux software set up AM/PM mode */
751 }
757 /* register RTC ... from here on, ds1305->ctrl needs locking */
764 }
766 /* Maybe set up alarm IRQ; be ready to handle it triggering right
767 * away. NOTE that we don't share this. The signal is active low,
768 * and we can't ack it before a SPI message delay. We temporarily
769 * disable the IRQ until it's acked, which lets us work with more
770 * IRQ trigger modes (not all IRQ controllers can do falling edge).
771 */
780 }
783 }
785 /* export NVRAM */
790 }
794 fail2:
796 fail1:
798 fail0:
801 }
804 {
809 /* carefully shut down irq and workqueue, if present */
814 }
820 }
827 /* REVISIT add suspend/resume */
828 };
831 {
833 }
837 {
839 }