| blob | 08f41328cc71199fd1220343ce64e62f02ffe0e0 |
1 // SPDX-License-Identifier: GPL-2.0-only
2 /*
3 * i.MX6 OCOTP fusebox driver
4 *
5 * Copyright (c) 2015 Pengutronix, Philipp Zabel <p.zabel@pengutronix.de>
6 *
7 * Copyright 2019 NXP
8 *
9 * Based on the barebox ocotp driver,
10 * Copyright (c) 2010 Baruch Siach <baruch@tkos.co.il>,
11 * Orex Computed Radiography
12 *
13 * Write support based on the fsl_otp driver,
14 * Copyright (C) 2010-2013 Freescale Semiconductor, Inc
15 */
17 #include <linux/clk.h>
18 #include <linux/device.h>
19 #include <linux/io.h>
20 #include <linux/module.h>
21 #include <linux/nvmem-provider.h>
22 #include <linux/of.h>
23 #include <linux/of_device.h>
24 #include <linux/platform_device.h>
25 #include <linux/slab.h>
26 #include <linux/delay.h>
29 * OTP Bank0 Word0
30 */
32 * of two consecutive OTP words.
33 */
35 #define IMX_OCOTP_ADDR_CTRL 0x0000
36 #define IMX_OCOTP_ADDR_CTRL_SET 0x0004
37 #define IMX_OCOTP_ADDR_CTRL_CLR 0x0008
38 #define IMX_OCOTP_ADDR_TIMING 0x0010
39 #define IMX_OCOTP_ADDR_DATA0 0x0020
40 #define IMX_OCOTP_ADDR_DATA1 0x0030
41 #define IMX_OCOTP_ADDR_DATA2 0x0040
42 #define IMX_OCOTP_ADDR_DATA3 0x0050
44 #define IMX_OCOTP_BM_CTRL_ADDR 0x000000FF
45 #define IMX_OCOTP_BM_CTRL_BUSY 0x00000100
46 #define IMX_OCOTP_BM_CTRL_ERROR 0x00000200
47 #define IMX_OCOTP_BM_CTRL_REL_SHADOWS 0x00000400
49 #define IMX_OCOTP_BM_CTRL_ADDR_8MP 0x000001FF
50 #define IMX_OCOTP_BM_CTRL_BUSY_8MP 0x00000200
51 #define IMX_OCOTP_BM_CTRL_ERROR_8MP 0x00000400
52 #define IMX_OCOTP_BM_CTRL_REL_SHADOWS_8MP 0x00000800
54 #define IMX_OCOTP_BM_CTRL_DEFAULT \
55 { \
56 .bm_addr = IMX_OCOTP_BM_CTRL_ADDR, \
57 .bm_busy = IMX_OCOTP_BM_CTRL_BUSY, \
58 .bm_error = IMX_OCOTP_BM_CTRL_ERROR, \
59 .bm_rel_shadows = IMX_OCOTP_BM_CTRL_REL_SHADOWS,\
60 }
62 #define IMX_OCOTP_BM_CTRL_8MP \
63 { \
64 .bm_addr = IMX_OCOTP_BM_CTRL_ADDR_8MP, \
65 .bm_busy = IMX_OCOTP_BM_CTRL_BUSY_8MP, \
66 .bm_error = IMX_OCOTP_BM_CTRL_ERROR_8MP, \
67 .bm_rel_shadows = IMX_OCOTP_BM_CTRL_REL_SHADOWS_8MP,\
68 }
72 #define TIMING_RELAX_NS 17
75 #define IMX_OCOTP_WR_UNLOCK 0x3E770000
76 #define IMX_OCOTP_READ_LOCKED_VAL 0xBADABADA
86 };
89 u32 bm_addr;
90 u32 bm_busy;
91 u32 bm_error;
92 u32 bm_rel_shadows;
93 };
100 };
103 {
119 }
122 /* HW_OCOTP_CTRL[ERROR] will be set under the following
123 * conditions:
124 * - A write is performed to a shadow register during a shadow
125 * reload (essentially, while HW_OCOTP_CTRL[RELOAD_SHADOWS] is
126 * set. In addition, the contents of the shadow register shall
127 * not be updated.
128 * - A write is performed to a shadow register which has been
129 * locked.
130 * - A read is performed to from a shadow register which has
131 * been read locked.
132 * - A program is performed to a fuse word which has been locked
133 * - A read is performed to from a fuse word which has been read
134 * locked.
135 */
139 }
142 }
145 {
156 }
160 {
188 }
194 }
200 /* 47.3.1.2
201 * For "read locked" registers 0xBADABADA will be returned and
202 * HW_OCOTP_CTRL[ERROR] will be set. It must be cleared by
203 * software before any new write, read or reload access can be
204 * issued
205 */
210 }
215 read_end:
222 }
225 {
228 u32 timing;
230 /* 47.3.1.3.1
231 * Program HW_OCOTP_TIMING[STROBE_PROG] and HW_OCOTP_TIMING[RELAX]
232 * fields with timing values to match the current frequency of the
233 * ipg_clk. OTP writes will work at maximum bus frequencies as long
234 * as the HW_OCOTP_TIMING parameters are set correctly.
235 *
236 * Note: there are minimum timings required to ensure an OTP fuse burns
237 * correctly that are independent of the ipg_clk. Those values are not
238 * formally documented anywhere however, working from the minimum
239 * timings given in u-boot we can say:
240 *
241 * - Minimum STROBE_PROG time is 10 microseconds. Intuitively 10
242 * microseconds feels about right as representative of a minimum time
243 * to physically burn out a fuse.
244 *
245 * - Minimum STROBE_READ i.e. the time to wait post OTP fuse burn before
246 * performing another read is 37 nanoseconds
247 *
248 * - Minimum RELAX timing is 17 nanoseconds. This final RELAX minimum
249 * timing is not entirely clear the documentation says "This
250 * count value specifies the time to add to all default timing
251 * parameters other than the Tpgm and Trd. It is given in number
252 * of ipg_clk periods." where Tpgm and Trd refer to STROBE_PROG
253 * and STROBE_READ respectively. What the other timing parameters
254 * are though, is not specified. Experience shows a zero RELAX
255 * value will mess up a re-load of the shadow registers post OTP
256 * burn.
257 */
274 }
277 {
280 u32 timing;
282 /* i.MX 7Solo Applications Processor Reference Manual, Rev. 0.1
283 * 6.4.3.3
284 */
295 }
299 {
304 u32 ctrl;
305 u8 waddr;
308 /* allow only writing one complete OTP word at a time */
320 }
322 /* Setup the write timing values */
325 /* 47.3.1.3.2
326 * Check that HW_OCOTP_CTRL[BUSY] and HW_OCOTP_CTRL[ERROR] are clear.
327 * Overlapped accesses are not supported by the controller. Any pending
328 * write or reload must be completed before a write access can be
329 * requested.
330 */
335 }
337 /* 47.3.1.3.3
338 * Write the requested address to HW_OCOTP_CTRL[ADDR] and program the
339 * unlock code into HW_OCOTP_CTRL[WR_UNLOCK]. This must be programmed
340 * for each write access. The lock code is documented in the register
341 * description. Both the unlock code and address can be written in the
342 * same operation.
343 */
345 /*
346 * In banked/i.MX7 mode the OTP register bank goes into waddr
347 * see i.MX 7Solo Applications Processor Reference Manual, Rev.
348 * 0.1 section 6.4.3.1
349 */
354 /*
355 * Non-banked i.MX6 mode.
356 * OTP write/read address specifies one of 128 word address
357 * locations
358 */
360 }
369 /* 47.3.1.3.4
370 * Write the data to the HW_OCOTP_DATA register. This will automatically
371 * set HW_OCOTP_CTRL[BUSY] and clear HW_OCOTP_CTRL[WR_UNLOCK]. To
372 * protect programming same OTP bit twice, before program OCOTP will
373 * automatically read fuse value in OTP and use read value to mask
374 * program data. The controller will use masked program data to program
375 * a 32-bit word in the OTP per the address in HW_OCOTP_CTRL[ADDR]. Bit
376 * fields with 1's will result in that OTP bit being programmed. Bit
377 * fields with 0's will be ignored. At the same time that the write is
378 * accepted, the controller makes an internal copy of
379 * HW_OCOTP_CTRL[ADDR] which cannot be updated until the next write
380 * sequence is initiated. This copy guarantees that erroneous writes to
381 * HW_OCOTP_CTRL[ADDR] will not affect an active write operation. It
382 * should also be noted that during the programming HW_OCOTP_DATA will
383 * shift right (with zero fill). This shifting is required to program
384 * the OTP serially. During the write operation, HW_OCOTP_DATA cannot be
385 * modified.
386 * Note: on i.MX7 there are four data fields to write for banked write
387 * with the fuse blowing operation only taking place after data0
388 * has been written. This is why data0 must always be the last
389 * register written.
390 */
392 /* Banked/i.MX7 mode */
418 }
420 /* Non-banked i.MX6 mode */
422 }
424 /* 47.4.1.4.5
425 * Once complete, the controller will clear BUSY. A write request to a
426 * protected or locked region will result in no OTP access and no
427 * setting of HW_OCOTP_CTRL[BUSY]. In addition HW_OCOTP_CTRL[ERROR] will
428 * be set. It must be cleared by software before any new write access
429 * can be issued.
430 */
438 }
440 }
442 /* 47.3.1.4
443 * Write Postamble: Due to internal electrical characteristics of the
444 * OTP during writes, all OTP operations following a write must be
445 * separated by 2 us after the clearing of HW_OCOTP_CTRL_BUSY following
446 * the write.
447 */
450 /* reload all shadow registers */
458 write_end:
462 }
471 };
478 };
485 };
492 };
499 };
506 };
513 };
520 };
526 };
533 };
540 };
547 };
554 };
569 { },
570 };
574 {
606 }
613 },
614 };