| blob | f112c5bc082a57b1c5402f1d2a21907f80b36637 |
1 /*
2 * at24.c - handle most I2C EEPROMs
3 *
4 * Copyright (C) 2005-2007 David Brownell
5 * Copyright (C) 2008 Wolfram Sang, Pengutronix
6 *
7 * This program is free software; you can redistribute it and/or modify
8 * it under the terms of the GNU General Public License as published by
9 * the Free Software Foundation; either version 2 of the License, or
10 * (at your option) any later version.
11 */
12 #include <linux/kernel.h>
13 #include <linux/init.h>
14 #include <linux/module.h>
15 #include <linux/slab.h>
16 #include <linux/delay.h>
17 #include <linux/mutex.h>
18 #include <linux/sysfs.h>
19 #include <linux/mod_devicetable.h>
20 #include <linux/log2.h>
21 #include <linux/bitops.h>
22 #include <linux/jiffies.h>
23 #include <linux/of.h>
24 #include <linux/acpi.h>
25 #include <linux/i2c.h>
26 #include <linux/platform_data/at24.h>
28 /*
29 * I2C EEPROMs from most vendors are inexpensive and mostly interchangeable.
30 * Differences between different vendor product lines (like Atmel AT24C or
31 * MicroChip 24LC, etc) won't much matter for typical read/write access.
32 * There are also I2C RAM chips, likewise interchangeable. One example
33 * would be the PCF8570, which acts like a 24c02 EEPROM (256 bytes).
34 *
35 * However, misconfiguration can lose data. "Set 16-bit memory address"
36 * to a part with 8-bit addressing will overwrite data. Writing with too
37 * big a page size also loses data. And it's not safe to assume that the
38 * conventional addresses 0x50..0x57 only hold eeproms; a PCF8563 RTC
39 * uses 0x51, for just one example.
40 *
41 * Accordingly, explicit board-specific configuration data should be used
42 * in almost all cases. (One partial exception is an SMBus used to access
43 * "SPD" data for DRAM sticks. Those only use 24c02 EEPROMs.)
44 *
45 * So this driver uses "new style" I2C driver binding, expecting to be
46 * told what devices exist. That may be in arch/X/mach-Y/board-Z.c or
47 * similar kernel-resident tables; or, configuration data coming from
48 * a bootloader.
49 *
50 * Other than binding model, current differences from "eeprom" driver are
51 * that this one handles write access and isn't restricted to 24c02 devices.
52 * It also handles larger devices (32 kbit and up) with two-byte addresses,
53 * which won't work on pure SMBus systems.
54 */
62 /*
63 * Lock protects against activities from other Linux tasks,
64 * but not from changes by other I2C masters.
65 */
73 /*
74 * Some chips tie up multiple I2C addresses; dummy devices reserve
75 * them for us, and we'll use them with SMBus calls.
76 */
78 };
80 /*
81 * This parameter is to help this driver avoid blocking other drivers out
82 * of I2C for potentially troublesome amounts of time. With a 100 kHz I2C
83 * clock, one 256 byte read takes about 1/43 second which is excessive;
84 * but the 1/170 second it takes at 400 kHz may be quite reasonable; and
85 * at 1 MHz (Fm+) a 1/430 second delay could easily be invisible.
86 *
87 * This value is forced to be a power of two so that writes align on pages.
88 */
93 /*
94 * Specs often allow 5 msec for a page write, sometimes 20 msec;
95 * it's important to recover from write timeouts.
96 */
101 #define AT24_SIZE_BYTELEN 5
102 #define AT24_SIZE_FLAGS 8
104 #define AT24_BITMASK(x) (BIT(x) - 1)
106 /* create non-zero magic value for given eeprom parameters */
107 #define AT24_DEVICE_MAGIC(_len, _flags) \
108 ((1 << AT24_SIZE_FLAGS | (_flags)) \
109 << AT24_SIZE_BYTELEN | ilog2(_len))
112 /* needs 8 addresses as A0-A2 are ignored */
114 /* old variants can't be handled with this generic entry! */
117 /* spd is a 24c02 in memory DIMMs */
121 /* 24rf08 quirk is handled at i2c-core */
132 };
137 { }
138 };
141 /*-------------------------------------------------------------------------*/
143 /*
144 * This routine supports chips which consume multiple I2C addresses. It
145 * computes the addressing information to be used for a given r/w request.
146 * Assumes that sanity checks for offset happened at sysfs-layer.
147 */
150 {
159 }
162 }
166 {
175 /*
176 * REVISIT some multi-address chips don't rollover page reads to
177 * the next slave address, so we may need to truncate the count.
178 * Those chips might need another quirk flag.
179 *
180 * If the real hardware used four adjacent 24c02 chips and that
181 * were misconfigured as one 24c08, that would be a similar effect:
182 * one "eeprom" file not four, but larger reads would fail when
183 * they crossed certain pages.
184 */
186 /*
187 * Slave address and byte offset derive from the offset. Always
188 * set the byte address; on a multi-master board, another master
189 * may have changed the chip's "current" address pointer.
190 */
197 /* Smaller eeproms can work given some SMBus extension calls */
201 /*
202 * When we have a better choice than SMBus calls, use a
203 * combined I2C message. Write address; then read up to
204 * io_limit data bytes. Note that read page rollover helps us
205 * here (unlike writes). msgbuf is u8 and will cast to our
206 * needs.
207 */
221 }
223 /*
224 * Reads fail if the previous write didn't complete yet. We may
225 * loop a few times until this one succeeds, waiting at least
226 * long enough for one entire page write to work.
227 */
238 }
245 /* REVISIT: at HZ=100, this is sloooow */
250 }
254 {
263 /*
264 * Read data from chip, protecting against concurrent updates
265 * from this host, but not from other I2C masters.
266 */
270 ssize_t status;
277 }
282 }
287 }
292 {
297 }
300 /*
301 * Note that if the hardware write-protect pin is pulled high, the whole
302 * chip is normally write protected. But there are plenty of product
303 * variants here, including OTP fuses and partial chip protect.
304 *
305 * We only use page mode writes; the alternative is sloooow. This routine
306 * writes at most one page.
307 */
310 {
320 /* Get corresponding I2C address and adjust offset */
323 /* write_max is at most a page */
327 /* Never roll over backwards, to the start of this page */
332 /* If we'll use I2C calls for I/O, set up the message */
339 /* msg.buf is u8 and casts will mask the values */
347 }
349 /*
350 * Writes fail if the previous one didn't complete yet. We may
351 * loop a few times until this one succeeds, waiting at least
352 * long enough for one entire page write to work.
353 */
367 }
375 }
382 /* REVISIT: at HZ=100, this is sloooow */
387 }
391 {
397 /*
398 * Write data to chip, protecting against concurrent updates
399 * from this host, but not from other I2C masters.
400 */
404 ssize_t status;
411 }
416 }
421 }
426 {
431 }
433 /*-------------------------------------------------------------------------*/
435 /*
436 * This lets other kernel code access the eeprom data. For example, it
437 * might hold a board's Ethernet address, or board-specific calibration
438 * data generated on the manufacturing floor.
439 */
443 {
447 }
451 {
455 }
457 /*-------------------------------------------------------------------------*/
459 #ifdef CONFIG_OF
462 {
472 }
473 }
474 #else
477 { }
481 {
502 }
509 /*
510 * This is slow, but we can't know all eeproms, so we better
511 * play safe. Specifying custom eeprom-types via platform_data
512 * is recommended anyhow.
513 */
516 /* update chipdata if OF is present */
521 }
529 }
534 /* Use I2C operations unless we're stuck with SMBus extensions. */
540 I2C_FUNC_SMBUS_READ_I2C_BLOCK)) {
543 I2C_FUNC_SMBUS_READ_WORD_DATA)) {
546 I2C_FUNC_SMBUS_READ_BYTE_DATA)) {
550 }
551 }
553 /* Use I2C operations unless we're stuck with SMBus extensions. */
556 I2C_FUNC_SMBUS_WRITE_I2C_BLOCK)) {
559 I2C_FUNC_SMBUS_WRITE_BYTE_DATA)) {
562 }
563 }
567 else
582 /*
583 * Export the EEPROM bytes through sysfs, since that's convenient.
584 * By default, only root should see the data (maybe passwords etc)
585 */
611 /* buffer (data + address at the beginning) */
619 }
620 }
624 /* use dummy devices for multiple-address chips */
633 }
634 }
650 }
652 /* export data to kernel code */
658 err_clients:
664 }
667 {
678 }
680 /*-------------------------------------------------------------------------*/
686 },
690 };
693 {
697 }
701 }
705 {
707 }