1 /***************************************************************************
2 * Copyright (C) 2011 by Mathias Kuester *
5 * Copyright (C) 2011 sleep(5) ltd *
6 * tomas@sleepfive.com *
8 * Copyright (C) 2012 by Christopher D. Kilgour *
9 * techie at whiterocker.com *
11 * Copyright (C) 2013 Nemui Trinomius *
12 * nemuisan_kawausogasuki@live.jp *
14 * Copyright (C) 2015 Tomas Vanek *
17 * This program is free software; you can redistribute it and/or modify *
18 * it under the terms of the GNU General Public License as published by *
19 * the Free Software Foundation; either version 2 of the License, or *
20 * (at your option) any later version. *
22 * This program is distributed in the hope that it will be useful, *
23 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
24 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
25 * GNU General Public License for more details. *
27 * You should have received a copy of the GNU General Public License *
28 * along with this program. If not, see <http://www.gnu.org/licenses/>. *
29 ***************************************************************************/
35 #include "jtag/interface.h"
37 #include <helper/binarybuffer.h>
38 #include <helper/time_support.h>
39 #include <target/target_type.h>
40 #include <target/algorithm.h>
41 #include <target/armv7m.h>
42 #include <target/cortex_m.h>
45 * Implementation Notes
47 * The persistent memories in the Kinetis chip families K10 through
48 * K70 are all manipulated with the Flash Memory Module. Some
49 * variants call this module the FTFE, others call it the FTFL. To
50 * indicate that both are considered here, we use FTFX.
52 * Within the module, according to the chip variant, the persistent
53 * memory is divided into what Freescale terms Program Flash, FlexNVM,
54 * and FlexRAM. All chip variants have Program Flash. Some chip
55 * variants also have FlexNVM and FlexRAM, which always appear
58 * A given Kinetis chip may have 1, 2 or 4 blocks of flash. Here we map
59 * each block to a separate bank. Each block size varies by chip and
60 * may be determined by the read-only SIM_FCFG1 register. The sector
61 * size within each bank/block varies by chip, and may be 1, 2 or 4k.
62 * The sector size may be different for flash and FlexNVM.
64 * The first half of the flash (1 or 2 blocks) is always Program Flash
65 * and always starts at address 0x00000000. The "PFLSH" flag, bit 23
66 * of the read-only SIM_FCFG2 register, determines whether the second
67 * half of the flash is also Program Flash or FlexNVM+FlexRAM. When
68 * PFLSH is set, the second from the first half. When PFLSH is clear,
69 * the second half of flash is FlexNVM and always starts at address
70 * 0x10000000. FlexRAM, which is also present when PFLSH is clear,
71 * always starts at address 0x14000000.
73 * The Flash Memory Module provides a register set where flash
74 * commands are loaded to perform flash operations like erase and
75 * program. Different commands are available depending on whether
76 * Program Flash or FlexNVM/FlexRAM is being manipulated. Although
77 * the commands used are quite consistent between flash blocks, the
78 * parameters they accept differ according to the flash sector size.
83 #define FCF_ADDRESS 0x00000400
87 #define FCF_FDPROT 0xf
90 #define FLEXRAM 0x14000000
92 #define MSCM_OCMDR0 0x40001400
93 #define FMC_PFB01CR 0x4001f004
94 #define FTFx_FSTAT 0x40020000
95 #define FTFx_FCNFG 0x40020001
96 #define FTFx_FCCOB3 0x40020004
97 #define FTFx_FPROT3 0x40020010
98 #define FTFx_FDPROT 0x40020017
99 #define SIM_BASE 0x40047000
100 #define SIM_BASE_KL28 0x40074000
101 #define SIM_COPC 0x40048100
102 /* SIM_COPC does not exist on devices with changed SIM_BASE */
103 #define WDOG_BASE 0x40052000
104 #define WDOG32_KE1X 0x40052000
105 #define WDOG32_KL28 0x40076000
106 #define SMC_PMCTRL 0x4007E001
107 #define SMC_PMSTAT 0x4007E003
108 #define SMC32_PMCTRL 0x4007E00C
109 #define SMC32_PMSTAT 0x4007E014
110 #define MCM_PLACR 0xF000300C
113 #define SIM_SOPT1_OFFSET 0x0000
114 #define SIM_SDID_OFFSET 0x1024
115 #define SIM_FCFG1_OFFSET 0x104c
116 #define SIM_FCFG2_OFFSET 0x1050
118 #define WDOG_STCTRLH_OFFSET 0
119 #define WDOG32_CS_OFFSET 0
122 #define PM_STAT_RUN 0x01
123 #define PM_STAT_VLPR 0x04
124 #define PM_CTRL_RUNM_RUN 0x00
127 #define FTFx_CMD_BLOCKSTAT 0x00
128 #define FTFx_CMD_SECTSTAT 0x01
129 #define FTFx_CMD_LWORDPROG 0x06
130 #define FTFx_CMD_SECTERASE 0x09
131 #define FTFx_CMD_SECTWRITE 0x0b
132 #define FTFx_CMD_MASSERASE 0x44
133 #define FTFx_CMD_PGMPART 0x80
134 #define FTFx_CMD_SETFLEXRAM 0x81
136 /* The older Kinetis K series uses the following SDID layout :
143 * The newer Kinetis series uses the following SDID layout :
145 * Bit 27-24 : SUBFAMID
146 * Bit 23-20 : SERIESID
147 * Bit 19-16 : SRAMSIZE
149 * Bit 6-4 : Reserved (0)
152 * We assume that if bits 31-16 are 0 then it's an older
156 #define KINETIS_SOPT1_RAMSIZE_MASK 0x0000F000
157 #define KINETIS_SOPT1_RAMSIZE_K24FN1M 0x0000B000
159 #define KINETIS_SDID_K_SERIES_MASK 0x0000FFFF
161 #define KINETIS_SDID_DIEID_MASK 0x00000F80
163 #define KINETIS_SDID_DIEID_K22FN128 0x00000680 /* smaller pflash with FTFA */
164 #define KINETIS_SDID_DIEID_K22FN256 0x00000A80
165 #define KINETIS_SDID_DIEID_K22FN512 0x00000E80
166 #define KINETIS_SDID_DIEID_K24FN256 0x00000700
168 #define KINETIS_SDID_DIEID_K24FN1M 0x00000300 /* Detect Errata 7534 */
170 /* We can't rely solely on the FAMID field to determine the MCU
171 * type since some FAMID values identify multiple MCUs with
172 * different flash sector sizes (K20 and K22 for instance).
173 * Therefore we combine it with the DIEID bits which may possibly
174 * break if Freescale bumps the DIEID for a particular MCU. */
175 #define KINETIS_K_SDID_TYPE_MASK 0x00000FF0
176 #define KINETIS_K_SDID_K10_M50 0x00000000
177 #define KINETIS_K_SDID_K10_M72 0x00000080
178 #define KINETIS_K_SDID_K10_M100 0x00000100
179 #define KINETIS_K_SDID_K10_M120 0x00000180
180 #define KINETIS_K_SDID_K11 0x00000220
181 #define KINETIS_K_SDID_K12 0x00000200
182 #define KINETIS_K_SDID_K20_M50 0x00000010
183 #define KINETIS_K_SDID_K20_M72 0x00000090
184 #define KINETIS_K_SDID_K20_M100 0x00000110
185 #define KINETIS_K_SDID_K20_M120 0x00000190
186 #define KINETIS_K_SDID_K21_M50 0x00000230
187 #define KINETIS_K_SDID_K21_M120 0x00000330
188 #define KINETIS_K_SDID_K22_M50 0x00000210
189 #define KINETIS_K_SDID_K22_M120 0x00000310
190 #define KINETIS_K_SDID_K30_M72 0x000000A0
191 #define KINETIS_K_SDID_K30_M100 0x00000120
192 #define KINETIS_K_SDID_K40_M72 0x000000B0
193 #define KINETIS_K_SDID_K40_M100 0x00000130
194 #define KINETIS_K_SDID_K50_M72 0x000000E0
195 #define KINETIS_K_SDID_K51_M72 0x000000F0
196 #define KINETIS_K_SDID_K53 0x00000170
197 #define KINETIS_K_SDID_K60_M100 0x00000140
198 #define KINETIS_K_SDID_K60_M150 0x000001C0
199 #define KINETIS_K_SDID_K70_M150 0x000001D0
201 #define KINETIS_SDID_SERIESID_MASK 0x00F00000
202 #define KINETIS_SDID_SERIESID_K 0x00000000
203 #define KINETIS_SDID_SERIESID_KL 0x00100000
204 #define KINETIS_SDID_SERIESID_KE 0x00200000
205 #define KINETIS_SDID_SERIESID_KW 0x00500000
206 #define KINETIS_SDID_SERIESID_KV 0x00600000
208 #define KINETIS_SDID_SUBFAMID_SHIFT 24
209 #define KINETIS_SDID_SUBFAMID_MASK 0x0F000000
210 #define KINETIS_SDID_SUBFAMID_KX0 0x00000000
211 #define KINETIS_SDID_SUBFAMID_KX1 0x01000000
212 #define KINETIS_SDID_SUBFAMID_KX2 0x02000000
213 #define KINETIS_SDID_SUBFAMID_KX3 0x03000000
214 #define KINETIS_SDID_SUBFAMID_KX4 0x04000000
215 #define KINETIS_SDID_SUBFAMID_KX5 0x05000000
216 #define KINETIS_SDID_SUBFAMID_KX6 0x06000000
217 #define KINETIS_SDID_SUBFAMID_KX7 0x07000000
218 #define KINETIS_SDID_SUBFAMID_KX8 0x08000000
220 #define KINETIS_SDID_FAMILYID_SHIFT 28
221 #define KINETIS_SDID_FAMILYID_MASK 0xF0000000
222 #define KINETIS_SDID_FAMILYID_K0X 0x00000000
223 #define KINETIS_SDID_FAMILYID_K1X 0x10000000
224 #define KINETIS_SDID_FAMILYID_K2X 0x20000000
225 #define KINETIS_SDID_FAMILYID_K3X 0x30000000
226 #define KINETIS_SDID_FAMILYID_K4X 0x40000000
227 #define KINETIS_SDID_FAMILYID_K5X 0x50000000
228 #define KINETIS_SDID_FAMILYID_K6X 0x60000000
229 #define KINETIS_SDID_FAMILYID_K7X 0x70000000
230 #define KINETIS_SDID_FAMILYID_K8X 0x80000000
231 #define KINETIS_SDID_FAMILYID_KL8X 0x90000000
233 /* The field originally named DIEID has new name/meaning on KE1x */
234 #define KINETIS_SDID_PROJECTID_MASK KINETIS_SDID_DIEID_MASK
235 #define KINETIS_SDID_PROJECTID_KE1xF 0x00000080
236 #define KINETIS_SDID_PROJECTID_KE1xZ 0x00000100
238 struct kinetis_flash_bank
{
239 struct kinetis_chip
*k_chip
;
241 unsigned bank_number
; /* bank number in particular chip */
242 struct flash_bank
*bank
;
244 uint32_t sector_size
;
245 uint32_t protection_size
;
246 uint32_t prog_base
; /* base address for FTFx operations */
247 /* usually same as bank->base for pflash, differs for FlexNVM */
248 uint32_t protection_block
; /* number of first protection block in this bank */
258 #define KINETIS_MAX_BANKS 4u
260 struct kinetis_chip
{
261 struct target
*target
;
267 uint32_t fcfg2_maxaddr0_shifted
;
268 uint32_t fcfg2_maxaddr1_shifted
;
270 unsigned num_pflash_blocks
, num_nvm_blocks
;
271 unsigned pflash_sector_size
, nvm_sector_size
;
272 unsigned max_flash_prog_size
;
274 uint32_t pflash_base
;
275 uint32_t pflash_size
;
277 uint32_t nvm_size
; /* whole FlexNVM */
278 uint32_t dflash_size
; /* accessible rest of FlexNVM if EEPROM backup uses part of FlexNVM */
280 uint32_t progr_accel_ram
;
284 FS_PROGRAM_SECTOR
= 1,
285 FS_PROGRAM_LONGWORD
= 2,
286 FS_PROGRAM_PHRASE
= 4, /* Unsupported */
288 FS_NO_CMD_BLOCKSTAT
= 0x40,
289 FS_WIDTH_256BIT
= 0x80,
295 KINETIS_CACHE_K
, /* invalidate using FMC->PFB0CR/PFB01CR */
296 KINETIS_CACHE_L
, /* invalidate using MCM->PLACR */
297 KINETIS_CACHE_MSCM
, /* devices like KE1xF, invalidate MSCM->OCMDR0 */
316 struct kinetis_flash_bank banks
[KINETIS_MAX_BANKS
];
319 struct kinetis_type
{
324 static const struct kinetis_type kinetis_types_old
[] = {
325 { KINETIS_K_SDID_K10_M50
, "MK10D%s5" },
326 { KINETIS_K_SDID_K10_M72
, "MK10D%s7" },
327 { KINETIS_K_SDID_K10_M100
, "MK10D%s10" },
328 { KINETIS_K_SDID_K10_M120
, "MK10F%s12" },
329 { KINETIS_K_SDID_K11
, "MK11D%s5" },
330 { KINETIS_K_SDID_K12
, "MK12D%s5" },
332 { KINETIS_K_SDID_K20_M50
, "MK20D%s5" },
333 { KINETIS_K_SDID_K20_M72
, "MK20D%s7" },
334 { KINETIS_K_SDID_K20_M100
, "MK20D%s10" },
335 { KINETIS_K_SDID_K20_M120
, "MK20F%s12" },
336 { KINETIS_K_SDID_K21_M50
, "MK21D%s5" },
337 { KINETIS_K_SDID_K21_M120
, "MK21F%s12" },
338 { KINETIS_K_SDID_K22_M50
, "MK22D%s5" },
339 { KINETIS_K_SDID_K22_M120
, "MK22F%s12" },
341 { KINETIS_K_SDID_K30_M72
, "MK30D%s7" },
342 { KINETIS_K_SDID_K30_M100
, "MK30D%s10" },
344 { KINETIS_K_SDID_K40_M72
, "MK40D%s7" },
345 { KINETIS_K_SDID_K40_M100
, "MK40D%s10" },
347 { KINETIS_K_SDID_K50_M72
, "MK50D%s7" },
348 { KINETIS_K_SDID_K51_M72
, "MK51D%s7" },
349 { KINETIS_K_SDID_K53
, "MK53D%s10" },
351 { KINETIS_K_SDID_K60_M100
, "MK60D%s10" },
352 { KINETIS_K_SDID_K60_M150
, "MK60F%s15" },
354 { KINETIS_K_SDID_K70_M150
, "MK70F%s15" },
360 #define MDM_REG_STAT 0x00
361 #define MDM_REG_CTRL 0x04
362 #define MDM_REG_ID 0xfc
364 #define MDM_STAT_FMEACK (1<<0)
365 #define MDM_STAT_FREADY (1<<1)
366 #define MDM_STAT_SYSSEC (1<<2)
367 #define MDM_STAT_SYSRES (1<<3)
368 #define MDM_STAT_FMEEN (1<<5)
369 #define MDM_STAT_BACKDOOREN (1<<6)
370 #define MDM_STAT_LPEN (1<<7)
371 #define MDM_STAT_VLPEN (1<<8)
372 #define MDM_STAT_LLSMODEXIT (1<<9)
373 #define MDM_STAT_VLLSXMODEXIT (1<<10)
374 #define MDM_STAT_CORE_HALTED (1<<16)
375 #define MDM_STAT_CORE_SLEEPDEEP (1<<17)
376 #define MDM_STAT_CORESLEEPING (1<<18)
378 #define MDM_CTRL_FMEIP (1<<0)
379 #define MDM_CTRL_DBG_DIS (1<<1)
380 #define MDM_CTRL_DBG_REQ (1<<2)
381 #define MDM_CTRL_SYS_RES_REQ (1<<3)
382 #define MDM_CTRL_CORE_HOLD_RES (1<<4)
383 #define MDM_CTRL_VLLSX_DBG_REQ (1<<5)
384 #define MDM_CTRL_VLLSX_DBG_ACK (1<<6)
385 #define MDM_CTRL_VLLSX_STAT_ACK (1<<7)
387 #define MDM_ACCESS_TIMEOUT 500 /* msec */
390 static bool allow_fcf_writes
;
391 static uint8_t fcf_fopt
= 0xff;
392 static bool fcf_fopt_configured
;
393 static bool create_banks
;
396 const struct flash_driver kinetis_flash
;
397 static int kinetis_write_inner(struct flash_bank
*bank
, const uint8_t *buffer
,
398 uint32_t offset
, uint32_t count
);
399 static int kinetis_probe_chip(struct kinetis_chip
*k_chip
);
400 static int kinetis_auto_probe(struct flash_bank
*bank
);
403 static int kinetis_mdm_write_register(struct adiv5_dap
*dap
, unsigned reg
, uint32_t value
)
406 LOG_DEBUG("MDM_REG[0x%02x] <- %08" PRIX32
, reg
, value
);
408 retval
= dap_queue_ap_write(dap_ap(dap
, MDM_AP
), reg
, value
);
409 if (retval
!= ERROR_OK
) {
410 LOG_DEBUG("MDM: failed to queue a write request");
414 retval
= dap_run(dap
);
415 if (retval
!= ERROR_OK
) {
416 LOG_DEBUG("MDM: dap_run failed");
424 static int kinetis_mdm_read_register(struct adiv5_dap
*dap
, unsigned reg
, uint32_t *result
)
428 retval
= dap_queue_ap_read(dap_ap(dap
, MDM_AP
), reg
, result
);
429 if (retval
!= ERROR_OK
) {
430 LOG_DEBUG("MDM: failed to queue a read request");
434 retval
= dap_run(dap
);
435 if (retval
!= ERROR_OK
) {
436 LOG_DEBUG("MDM: dap_run failed");
440 LOG_DEBUG("MDM_REG[0x%02x]: %08" PRIX32
, reg
, *result
);
444 static int kinetis_mdm_poll_register(struct adiv5_dap
*dap
, unsigned reg
,
445 uint32_t mask
, uint32_t value
, uint32_t timeout_ms
)
449 int64_t ms_timeout
= timeval_ms() + timeout_ms
;
452 retval
= kinetis_mdm_read_register(dap
, reg
, &val
);
453 if (retval
!= ERROR_OK
|| (val
& mask
) == value
)
457 } while (timeval_ms() < ms_timeout
);
459 LOG_DEBUG("MDM: polling timed out");
464 * This command can be used to break a watchdog reset loop when
465 * connecting to an unsecured target. Unlike other commands, halt will
466 * automatically retry as it does not know how far into the boot process
467 * it is when the command is called.
469 COMMAND_HANDLER(kinetis_mdm_halt
)
471 struct target
*target
= get_current_target(CMD_CTX
);
472 struct cortex_m_common
*cortex_m
= target_to_cm(target
);
473 struct adiv5_dap
*dap
= cortex_m
->armv7m
.arm
.dap
;
477 int64_t ms_timeout
= timeval_ms() + MDM_ACCESS_TIMEOUT
;
480 LOG_ERROR("Cannot perform halt with a high-level adapter");
487 kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, MDM_CTRL_CORE_HOLD_RES
);
491 retval
= kinetis_mdm_read_register(dap
, MDM_REG_STAT
, &stat
);
492 if (retval
!= ERROR_OK
) {
493 LOG_DEBUG("MDM: failed to read MDM_REG_STAT");
497 /* Repeat setting MDM_CTRL_CORE_HOLD_RES until system is out of
498 * reset with flash ready and without security
500 if ((stat
& (MDM_STAT_FREADY
| MDM_STAT_SYSSEC
| MDM_STAT_SYSRES
))
501 == (MDM_STAT_FREADY
| MDM_STAT_SYSRES
))
504 if (timeval_ms() >= ms_timeout
) {
505 LOG_ERROR("MDM: halt timed out");
510 LOG_DEBUG("MDM: halt succeded after %d attempts.", tries
);
513 /* enable polling in case kinetis_check_flash_security_status disabled it */
514 jtag_poll_set_enabled(true);
518 target
->reset_halt
= true;
519 target
->type
->assert_reset(target
);
521 retval
= kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, 0);
522 if (retval
!= ERROR_OK
) {
523 LOG_ERROR("MDM: failed to clear MDM_REG_CTRL");
527 target
->type
->deassert_reset(target
);
532 COMMAND_HANDLER(kinetis_mdm_reset
)
534 struct target
*target
= get_current_target(CMD_CTX
);
535 struct cortex_m_common
*cortex_m
= target_to_cm(target
);
536 struct adiv5_dap
*dap
= cortex_m
->armv7m
.arm
.dap
;
540 LOG_ERROR("Cannot perform reset with a high-level adapter");
544 retval
= kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, MDM_CTRL_SYS_RES_REQ
);
545 if (retval
!= ERROR_OK
) {
546 LOG_ERROR("MDM: failed to write MDM_REG_CTRL");
550 retval
= kinetis_mdm_poll_register(dap
, MDM_REG_STAT
, MDM_STAT_SYSRES
, 0, 500);
551 if (retval
!= ERROR_OK
) {
552 LOG_ERROR("MDM: failed to assert reset");
556 retval
= kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, 0);
557 if (retval
!= ERROR_OK
) {
558 LOG_ERROR("MDM: failed to clear MDM_REG_CTRL");
566 * This function implements the procedure to mass erase the flash via
567 * SWD/JTAG on Kinetis K and L series of devices as it is described in
568 * AN4835 "Production Flash Programming Best Practices for Kinetis K-
569 * and L-series MCUs" Section 4.2.1. To prevent a watchdog reset loop,
570 * the core remains halted after this function completes as suggested
571 * by the application note.
573 COMMAND_HANDLER(kinetis_mdm_mass_erase
)
575 struct target
*target
= get_current_target(CMD_CTX
);
576 struct cortex_m_common
*cortex_m
= target_to_cm(target
);
577 struct adiv5_dap
*dap
= cortex_m
->armv7m
.arm
.dap
;
580 LOG_ERROR("Cannot perform mass erase with a high-level adapter");
587 * ... Power on the processor, or if power has already been
588 * applied, assert the RESET pin to reset the processor. For
589 * devices that do not have a RESET pin, write the System
590 * Reset Request bit in the MDM-AP control register after
591 * establishing communication...
594 /* assert SRST if configured */
595 bool has_srst
= jtag_get_reset_config() & RESET_HAS_SRST
;
597 adapter_assert_reset();
599 retval
= kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, MDM_CTRL_SYS_RES_REQ
);
600 if (retval
!= ERROR_OK
&& !has_srst
) {
601 LOG_ERROR("MDM: failed to assert reset");
602 goto deassert_reset_and_exit
;
606 * ... Read the MDM-AP status register repeatedly and wait for
607 * stable conditions suitable for mass erase:
608 * - mass erase is enabled
610 * - reset is finished
612 * Mass erase is started as soon as all conditions are met in 32
613 * subsequent status reads.
615 * In case of not stable conditions (RESET/WDOG loop in secured device)
616 * the user is asked for manual pressing of RESET button
619 int cnt_mass_erase_disabled
= 0;
621 int64_t ms_start
= timeval_ms();
622 bool man_reset_requested
= false;
626 int64_t ms_elapsed
= timeval_ms() - ms_start
;
628 if (!man_reset_requested
&& ms_elapsed
> 100) {
629 LOG_INFO("MDM: Press RESET button now if possible.");
630 man_reset_requested
= true;
633 if (ms_elapsed
> 3000) {
634 LOG_ERROR("MDM: waiting for mass erase conditions timed out.");
635 LOG_INFO("Mass erase of a secured MCU is not possible without hardware reset.");
636 LOG_INFO("Connect SRST, use 'reset_config srst_only' and retry.");
637 goto deassert_reset_and_exit
;
639 retval
= kinetis_mdm_read_register(dap
, MDM_REG_STAT
, &stat
);
640 if (retval
!= ERROR_OK
) {
645 if (!(stat
& MDM_STAT_FMEEN
)) {
647 cnt_mass_erase_disabled
++;
648 if (cnt_mass_erase_disabled
> 10) {
649 LOG_ERROR("MDM: mass erase is disabled");
650 goto deassert_reset_and_exit
;
655 if ((stat
& (MDM_STAT_FREADY
| MDM_STAT_SYSRES
)) == MDM_STAT_FREADY
)
660 } while (cnt_ready
< 32);
663 * ... Write the MDM-AP control register to set the Flash Mass
664 * Erase in Progress bit. This will start the mass erase
667 retval
= kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, MDM_CTRL_SYS_RES_REQ
| MDM_CTRL_FMEIP
);
668 if (retval
!= ERROR_OK
) {
669 LOG_ERROR("MDM: failed to start mass erase");
670 goto deassert_reset_and_exit
;
674 * ... Read the MDM-AP control register until the Flash Mass
675 * Erase in Progress bit clears...
676 * Data sheed defines erase time <3.6 sec/512kB flash block.
677 * The biggest device has 4 pflash blocks => timeout 16 sec.
679 retval
= kinetis_mdm_poll_register(dap
, MDM_REG_CTRL
, MDM_CTRL_FMEIP
, 0, 16000);
680 if (retval
!= ERROR_OK
) {
681 LOG_ERROR("MDM: mass erase timeout");
682 goto deassert_reset_and_exit
;
686 /* enable polling in case kinetis_check_flash_security_status disabled it */
687 jtag_poll_set_enabled(true);
691 target
->reset_halt
= true;
692 target
->type
->assert_reset(target
);
695 * ... Negate the RESET signal or clear the System Reset Request
696 * bit in the MDM-AP control register.
698 retval
= kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, 0);
699 if (retval
!= ERROR_OK
)
700 LOG_ERROR("MDM: failed to clear MDM_REG_CTRL");
702 target
->type
->deassert_reset(target
);
706 deassert_reset_and_exit
:
707 kinetis_mdm_write_register(dap
, MDM_REG_CTRL
, 0);
709 adapter_deassert_reset();
713 static const uint32_t kinetis_known_mdm_ids
[] = {
714 0x001C0000, /* Kinetis-K Series */
715 0x001C0020, /* Kinetis-L/M/V/E Series */
716 0x001C0030, /* Kinetis with a Cortex-M7, in time of writing KV58 */
720 * This function implements the procedure to connect to
721 * SWD/JTAG on Kinetis K and L series of devices as it is described in
722 * AN4835 "Production Flash Programming Best Practices for Kinetis K-
723 * and L-series MCUs" Section 4.1.1
725 COMMAND_HANDLER(kinetis_check_flash_security_status
)
727 struct target
*target
= get_current_target(CMD_CTX
);
728 struct cortex_m_common
*cortex_m
= target_to_cm(target
);
729 struct adiv5_dap
*dap
= cortex_m
->armv7m
.arm
.dap
;
732 LOG_WARNING("Cannot check flash security status with a high-level adapter");
737 return ERROR_OK
; /* too early to check, in JTAG mode ops may not be initialised */
743 * ... The MDM-AP ID register can be read to verify that the
744 * connection is working correctly...
746 retval
= kinetis_mdm_read_register(dap
, MDM_REG_ID
, &val
);
747 if (retval
!= ERROR_OK
) {
748 LOG_ERROR("MDM: failed to read ID register");
753 return ERROR_OK
; /* dap not yet initialised */
756 for (size_t i
= 0; i
< ARRAY_SIZE(kinetis_known_mdm_ids
); i
++) {
757 if (val
== kinetis_known_mdm_ids
[i
]) {
764 LOG_WARNING("MDM: unknown ID %08" PRIX32
, val
);
767 * ... Read the System Security bit to determine if security is enabled.
768 * If System Security = 0, then proceed. If System Security = 1, then
769 * communication with the internals of the processor, including the
770 * flash, will not be possible without issuing a mass erase command or
771 * unsecuring the part through other means (backdoor key unlock)...
773 retval
= kinetis_mdm_read_register(dap
, MDM_REG_STAT
, &val
);
774 if (retval
!= ERROR_OK
) {
775 LOG_ERROR("MDM: failed to read MDM_REG_STAT");
780 * System Security bit is also active for short time during reset.
781 * If a MCU has blank flash and runs in RESET/WDOG loop,
782 * System Security bit is active most of time!
783 * We should observe Flash Ready bit and read status several times
784 * to avoid false detection of secured MCU
786 int secured_score
= 0, flash_not_ready_score
= 0;
788 if ((val
& (MDM_STAT_SYSSEC
| MDM_STAT_FREADY
)) != MDM_STAT_FREADY
) {
792 for (i
= 0; i
< 32; i
++) {
793 stats
[i
] = MDM_STAT_FREADY
;
794 dap_queue_ap_read(dap_ap(dap
, MDM_AP
), MDM_REG_STAT
, &stats
[i
]);
796 retval
= dap_run(dap
);
797 if (retval
!= ERROR_OK
) {
798 LOG_DEBUG("MDM: dap_run failed when validating secured state");
801 for (i
= 0; i
< 32; i
++) {
802 if (stats
[i
] & MDM_STAT_SYSSEC
)
804 if (!(stats
[i
] & MDM_STAT_FREADY
))
805 flash_not_ready_score
++;
809 if (flash_not_ready_score
<= 8 && secured_score
> 24) {
810 jtag_poll_set_enabled(false);
812 LOG_WARNING("*********** ATTENTION! ATTENTION! ATTENTION! ATTENTION! **********");
813 LOG_WARNING("**** ****");
814 LOG_WARNING("**** Your Kinetis MCU is in secured state, which means that, ****");
815 LOG_WARNING("**** with exception for very basic communication, JTAG/SWD ****");
816 LOG_WARNING("**** interface will NOT work. In order to restore its ****");
817 LOG_WARNING("**** functionality please issue 'kinetis mdm mass_erase' ****");
818 LOG_WARNING("**** command, power cycle the MCU and restart OpenOCD. ****");
819 LOG_WARNING("**** ****");
820 LOG_WARNING("*********** ATTENTION! ATTENTION! ATTENTION! ATTENTION! **********");
822 } else if (flash_not_ready_score
> 24) {
823 jtag_poll_set_enabled(false);
824 LOG_WARNING("**** Your Kinetis MCU is probably locked-up in RESET/WDOG loop. ****");
825 LOG_WARNING("**** Common reason is a blank flash (at least a reset vector). ****");
826 LOG_WARNING("**** Issue 'kinetis mdm halt' command or if SRST is connected ****");
827 LOG_WARNING("**** and configured, use 'reset halt' ****");
828 LOG_WARNING("**** If MCU cannot be halted, it is likely secured and running ****");
829 LOG_WARNING("**** in RESET/WDOG loop. Issue 'kinetis mdm mass_erase' ****");
832 LOG_INFO("MDM: Chip is unsecured. Continuing.");
833 jtag_poll_set_enabled(true);
840 static struct kinetis_chip
*kinetis_get_chip(struct target
*target
)
842 struct flash_bank
*bank_iter
;
843 struct kinetis_flash_bank
*k_bank
;
845 /* iterate over all kinetis banks */
846 for (bank_iter
= flash_bank_list(); bank_iter
; bank_iter
= bank_iter
->next
) {
847 if (bank_iter
->driver
!= &kinetis_flash
848 || bank_iter
->target
!= target
)
851 k_bank
= bank_iter
->driver_priv
;
856 return k_bank
->k_chip
;
861 static int kinetis_chip_options(struct kinetis_chip
*k_chip
, int argc
, const char *argv
[])
864 for (i
= 0; i
< argc
; i
++) {
865 if (strcmp(argv
[i
], "-sim-base") == 0) {
867 k_chip
->sim_base
= strtoul(argv
[++i
], NULL
, 0);
869 LOG_ERROR("Unsupported flash bank option %s", argv
[i
]);
874 FLASH_BANK_COMMAND_HANDLER(kinetis_flash_bank_command
)
876 struct target
*target
= bank
->target
;
877 struct kinetis_chip
*k_chip
;
878 struct kinetis_flash_bank
*k_bank
;
882 return ERROR_COMMAND_SYNTAX_ERROR
;
884 LOG_INFO("add flash_bank kinetis %s", bank
->name
);
886 k_chip
= kinetis_get_chip(target
);
888 if (k_chip
== NULL
) {
889 k_chip
= calloc(sizeof(struct kinetis_chip
), 1);
890 if (k_chip
== NULL
) {
891 LOG_ERROR("No memory");
895 k_chip
->target
= target
;
897 /* only the first defined bank can define chip options */
898 retval
= kinetis_chip_options(k_chip
, CMD_ARGC
- 6, CMD_ARGV
+ 6);
899 if (retval
!= ERROR_OK
)
903 if (k_chip
->num_banks
>= KINETIS_MAX_BANKS
) {
904 LOG_ERROR("Only %u Kinetis flash banks are supported", KINETIS_MAX_BANKS
);
908 bank
->driver_priv
= k_bank
= &(k_chip
->banks
[k_chip
->num_banks
]);
909 k_bank
->k_chip
= k_chip
;
910 k_bank
->bank_number
= k_chip
->num_banks
;
918 static void kinetis_free_driver_priv(struct flash_bank
*bank
)
920 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
924 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
929 if (k_chip
->num_banks
== 0)
934 static int kinetis_create_missing_banks(struct kinetis_chip
*k_chip
)
938 struct kinetis_flash_bank
*k_bank
;
939 struct flash_bank
*bank
;
940 char base_name
[69], name
[80], num
[4];
943 num_blocks
= k_chip
->num_pflash_blocks
+ k_chip
->num_nvm_blocks
;
944 if (num_blocks
> KINETIS_MAX_BANKS
) {
945 LOG_ERROR("Only %u Kinetis flash banks are supported", KINETIS_MAX_BANKS
);
949 bank
= k_chip
->banks
[0].bank
;
950 if (bank
&& bank
->name
) {
951 strncpy(base_name
, bank
->name
, sizeof(base_name
) - 1);
952 base_name
[sizeof(base_name
) - 1] = '\0';
953 p
= strstr(base_name
, ".pflash");
956 if (k_chip
->num_pflash_blocks
> 1) {
957 /* rename first bank if numbering is needed */
958 snprintf(name
, sizeof(name
), "%s.pflash0", base_name
);
960 bank
->name
= strdup(name
);
964 strncpy(base_name
, target_name(k_chip
->target
), sizeof(base_name
) - 1);
965 base_name
[sizeof(base_name
) - 1] = '\0';
966 p
= strstr(base_name
, ".cpu");
971 for (bank_idx
= 1; bank_idx
< num_blocks
; bank_idx
++) {
972 k_bank
= &(k_chip
->banks
[bank_idx
]);
980 if (bank_idx
< k_chip
->num_pflash_blocks
) {
982 if (k_chip
->num_pflash_blocks
> 1)
983 snprintf(num
, sizeof(num
), "%u", bank_idx
);
986 if (k_chip
->num_nvm_blocks
> 1)
987 snprintf(num
, sizeof(num
), "%u",
988 bank_idx
- k_chip
->num_pflash_blocks
);
991 bank
= calloc(sizeof(struct flash_bank
), 1);
995 bank
->target
= k_chip
->target
;
996 bank
->driver
= &kinetis_flash
;
997 bank
->default_padded_value
= bank
->erased_value
= 0xff;
999 snprintf(name
, sizeof(name
), "%s.%s%s",
1000 base_name
, class, num
);
1001 bank
->name
= strdup(name
);
1003 bank
->driver_priv
= k_bank
= &(k_chip
->banks
[k_chip
->num_banks
]);
1004 k_bank
->k_chip
= k_chip
;
1005 k_bank
->bank_number
= bank_idx
;
1006 k_bank
->bank
= bank
;
1007 if (k_chip
->num_banks
<= bank_idx
)
1008 k_chip
->num_banks
= bank_idx
+ 1;
1010 flash_bank_add(bank
);
1016 static int kinetis_disable_wdog_algo(struct target
*target
, size_t code_size
, const uint8_t *code
, uint32_t wdog_base
)
1018 struct working_area
*wdog_algorithm
;
1019 struct armv7m_algorithm armv7m_info
;
1020 struct reg_param reg_params
[1];
1023 if (target
->state
!= TARGET_HALTED
) {
1024 LOG_ERROR("Target not halted");
1025 return ERROR_TARGET_NOT_HALTED
;
1028 retval
= target_alloc_working_area(target
, code_size
, &wdog_algorithm
);
1029 if (retval
!= ERROR_OK
)
1032 retval
= target_write_buffer(target
, wdog_algorithm
->address
,
1034 if (retval
== ERROR_OK
) {
1035 armv7m_info
.common_magic
= ARMV7M_COMMON_MAGIC
;
1036 armv7m_info
.core_mode
= ARM_MODE_THREAD
;
1038 init_reg_param(®_params
[0], "r0", 32, PARAM_OUT
);
1039 buf_set_u32(reg_params
[0].value
, 0, 32, wdog_base
);
1041 retval
= target_run_algorithm(target
, 0, NULL
, 1, reg_params
,
1042 wdog_algorithm
->address
,
1043 wdog_algorithm
->address
+ code_size
- 2,
1046 destroy_reg_param(®_params
[0]);
1048 if (retval
!= ERROR_OK
)
1049 LOG_ERROR("Error executing Kinetis WDOG unlock algorithm");
1052 target_free_working_area(target
, wdog_algorithm
);
1057 /* Disable the watchdog on Kinetis devices
1058 * Standard Kx WDOG peripheral checks timing and therefore requires to run algo.
1060 static int kinetis_disable_wdog_kx(struct target
*target
)
1062 const uint32_t wdog_base
= WDOG_BASE
;
1066 static const uint8_t kinetis_unlock_wdog_code
[] = {
1067 #include "../../../contrib/loaders/watchdog/armv7m_kinetis_wdog.inc"
1070 retval
= target_read_u16(target
, wdog_base
+ WDOG_STCTRLH_OFFSET
, &wdog
);
1071 if (retval
!= ERROR_OK
)
1074 if ((wdog
& 0x1) == 0) {
1075 /* watchdog already disabled */
1078 LOG_INFO("Disabling Kinetis watchdog (initial WDOG_STCTRLH = 0x%04" PRIx16
")", wdog
);
1080 retval
= kinetis_disable_wdog_algo(target
, sizeof(kinetis_unlock_wdog_code
), kinetis_unlock_wdog_code
, wdog_base
);
1081 if (retval
!= ERROR_OK
)
1084 retval
= target_read_u16(target
, wdog_base
+ WDOG_STCTRLH_OFFSET
, &wdog
);
1085 if (retval
!= ERROR_OK
)
1088 LOG_INFO("WDOG_STCTRLH = 0x%04" PRIx16
, wdog
);
1089 return (wdog
& 0x1) ? ERROR_FAIL
: ERROR_OK
;
1092 static int kinetis_disable_wdog32(struct target
*target
, uint32_t wdog_base
)
1097 static const uint8_t kinetis_unlock_wdog_code
[] = {
1098 #include "../../../contrib/loaders/watchdog/armv7m_kinetis_wdog32.inc"
1101 retval
= target_read_u32(target
, wdog_base
+ WDOG32_CS_OFFSET
, &wdog_cs
);
1102 if (retval
!= ERROR_OK
)
1105 if ((wdog_cs
& 0x80) == 0)
1106 return ERROR_OK
; /* watchdog already disabled */
1108 LOG_INFO("Disabling Kinetis watchdog (initial WDOG_CS 0x%08" PRIx32
")", wdog_cs
);
1110 retval
= kinetis_disable_wdog_algo(target
, sizeof(kinetis_unlock_wdog_code
), kinetis_unlock_wdog_code
, wdog_base
);
1111 if (retval
!= ERROR_OK
)
1114 retval
= target_read_u32(target
, wdog_base
+ WDOG32_CS_OFFSET
, &wdog_cs
);
1115 if (retval
!= ERROR_OK
)
1118 if ((wdog_cs
& 0x80) == 0)
1119 return ERROR_OK
; /* watchdog disabled successfully */
1121 LOG_ERROR("Cannot disable Kinetis watchdog (WDOG_CS 0x%08" PRIx32
"), issue 'reset init'", wdog_cs
);
1125 static int kinetis_disable_wdog(struct kinetis_chip
*k_chip
)
1127 struct target
*target
= k_chip
->target
;
1131 if (!k_chip
->probed
) {
1132 retval
= kinetis_probe_chip(k_chip
);
1133 if (retval
!= ERROR_OK
)
1137 switch (k_chip
->watchdog_type
) {
1138 case KINETIS_WDOG_K
:
1139 return kinetis_disable_wdog_kx(target
);
1141 case KINETIS_WDOG_COP
:
1142 retval
= target_read_u8(target
, SIM_COPC
, &sim_copc
);
1143 if (retval
!= ERROR_OK
)
1146 if ((sim_copc
& 0xc) == 0)
1147 return ERROR_OK
; /* watchdog already disabled */
1149 LOG_INFO("Disabling Kinetis watchdog (initial SIM_COPC 0x%02" PRIx8
")", sim_copc
);
1150 retval
= target_write_u8(target
, SIM_COPC
, sim_copc
& ~0xc);
1151 if (retval
!= ERROR_OK
)
1154 retval
= target_read_u8(target
, SIM_COPC
, &sim_copc
);
1155 if (retval
!= ERROR_OK
)
1158 if ((sim_copc
& 0xc) == 0)
1159 return ERROR_OK
; /* watchdog disabled successfully */
1161 LOG_ERROR("Cannot disable Kinetis watchdog (SIM_COPC 0x%02" PRIx8
"), issue 'reset init'", sim_copc
);
1164 case KINETIS_WDOG32_KE1X
:
1165 return kinetis_disable_wdog32(target
, WDOG32_KE1X
);
1167 case KINETIS_WDOG32_KL28
:
1168 return kinetis_disable_wdog32(target
, WDOG32_KL28
);
1175 COMMAND_HANDLER(kinetis_disable_wdog_handler
)
1178 struct target
*target
= get_current_target(CMD_CTX
);
1179 struct kinetis_chip
*k_chip
= kinetis_get_chip(target
);
1185 return ERROR_COMMAND_SYNTAX_ERROR
;
1187 result
= kinetis_disable_wdog(k_chip
);
1192 static int kinetis_ftfx_decode_error(uint8_t fstat
)
1195 LOG_ERROR("Flash operation failed, illegal command");
1196 return ERROR_FLASH_OPER_UNSUPPORTED
;
1198 } else if (fstat
& 0x10)
1199 LOG_ERROR("Flash operation failed, protection violated");
1201 else if (fstat
& 0x40)
1202 LOG_ERROR("Flash operation failed, read collision");
1204 else if (fstat
& 0x80)
1208 LOG_ERROR("Flash operation timed out");
1210 return ERROR_FLASH_OPERATION_FAILED
;
1213 static int kinetis_ftfx_clear_error(struct target
*target
)
1215 /* reset error flags */
1216 return target_write_u8(target
, FTFx_FSTAT
, 0x70);
1220 static int kinetis_ftfx_prepare(struct target
*target
)
1225 /* wait until busy */
1226 for (i
= 0; i
< 50; i
++) {
1227 result
= target_read_u8(target
, FTFx_FSTAT
, &fstat
);
1228 if (result
!= ERROR_OK
)
1235 if ((fstat
& 0x80) == 0) {
1236 LOG_ERROR("Flash controller is busy");
1237 return ERROR_FLASH_OPERATION_FAILED
;
1239 if (fstat
!= 0x80) {
1240 /* reset error flags */
1241 result
= kinetis_ftfx_clear_error(target
);
1246 /* Kinetis Program-LongWord Microcodes */
1247 static const uint8_t kinetis_flash_write_code
[] = {
1248 #include "../../../contrib/loaders/flash/kinetis/kinetis_flash.inc"
1251 /* Program LongWord Block Write */
1252 static int kinetis_write_block(struct flash_bank
*bank
, const uint8_t *buffer
,
1253 uint32_t offset
, uint32_t wcount
)
1255 struct target
*target
= bank
->target
;
1256 uint32_t buffer_size
= 2048; /* Default minimum value */
1257 struct working_area
*write_algorithm
;
1258 struct working_area
*source
;
1259 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
1260 uint32_t address
= k_bank
->prog_base
+ offset
;
1261 uint32_t end_address
;
1262 struct reg_param reg_params
[5];
1263 struct armv7m_algorithm armv7m_info
;
1267 /* Increase buffer_size if needed */
1268 if (buffer_size
< (target
->working_area_size
/2))
1269 buffer_size
= (target
->working_area_size
/2);
1271 /* allocate working area with flash programming code */
1272 if (target_alloc_working_area(target
, sizeof(kinetis_flash_write_code
),
1273 &write_algorithm
) != ERROR_OK
) {
1274 LOG_WARNING("no working area available, can't do block memory writes");
1275 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1278 retval
= target_write_buffer(target
, write_algorithm
->address
,
1279 sizeof(kinetis_flash_write_code
), kinetis_flash_write_code
);
1280 if (retval
!= ERROR_OK
)
1284 while (target_alloc_working_area(target
, buffer_size
, &source
) != ERROR_OK
) {
1286 if (buffer_size
<= 256) {
1287 /* free working area, write algorithm already allocated */
1288 target_free_working_area(target
, write_algorithm
);
1290 LOG_WARNING("No large enough working area available, can't do block memory writes");
1291 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1295 armv7m_info
.common_magic
= ARMV7M_COMMON_MAGIC
;
1296 armv7m_info
.core_mode
= ARM_MODE_THREAD
;
1298 init_reg_param(®_params
[0], "r0", 32, PARAM_IN_OUT
); /* address */
1299 init_reg_param(®_params
[1], "r1", 32, PARAM_OUT
); /* word count */
1300 init_reg_param(®_params
[2], "r2", 32, PARAM_OUT
);
1301 init_reg_param(®_params
[3], "r3", 32, PARAM_OUT
);
1302 init_reg_param(®_params
[4], "r4", 32, PARAM_OUT
);
1304 buf_set_u32(reg_params
[0].value
, 0, 32, address
);
1305 buf_set_u32(reg_params
[1].value
, 0, 32, wcount
);
1306 buf_set_u32(reg_params
[2].value
, 0, 32, source
->address
);
1307 buf_set_u32(reg_params
[3].value
, 0, 32, source
->address
+ source
->size
);
1308 buf_set_u32(reg_params
[4].value
, 0, 32, FTFx_FSTAT
);
1310 retval
= target_run_flash_async_algorithm(target
, buffer
, wcount
, 4,
1313 source
->address
, source
->size
,
1314 write_algorithm
->address
, 0,
1317 if (retval
== ERROR_FLASH_OPERATION_FAILED
) {
1318 end_address
= buf_get_u32(reg_params
[0].value
, 0, 32);
1320 LOG_ERROR("Error writing flash at %08" PRIx32
, end_address
);
1322 retval
= target_read_u8(target
, FTFx_FSTAT
, &fstat
);
1323 if (retval
== ERROR_OK
) {
1324 retval
= kinetis_ftfx_decode_error(fstat
);
1326 /* reset error flags */
1327 target_write_u8(target
, FTFx_FSTAT
, 0x70);
1329 } else if (retval
!= ERROR_OK
)
1330 LOG_ERROR("Error executing kinetis Flash programming algorithm");
1332 target_free_working_area(target
, source
);
1333 target_free_working_area(target
, write_algorithm
);
1335 destroy_reg_param(®_params
[0]);
1336 destroy_reg_param(®_params
[1]);
1337 destroy_reg_param(®_params
[2]);
1338 destroy_reg_param(®_params
[3]);
1339 destroy_reg_param(®_params
[4]);
1344 static int kinetis_protect(struct flash_bank
*bank
, int set
, int first
, int last
)
1348 if (allow_fcf_writes
) {
1349 LOG_ERROR("Protection setting is possible with 'kinetis fcf_source protection' only!");
1353 if (!bank
->prot_blocks
|| bank
->num_prot_blocks
== 0) {
1354 LOG_ERROR("No protection possible for current bank!");
1355 return ERROR_FLASH_BANK_INVALID
;
1358 for (i
= first
; i
< bank
->num_prot_blocks
&& i
<= last
; i
++)
1359 bank
->prot_blocks
[i
].is_protected
= set
;
1361 LOG_INFO("Protection bits will be written at the next FCF sector erase or write.");
1362 LOG_INFO("Do not issue 'flash info' command until protection is written,");
1363 LOG_INFO("doing so would re-read protection status from MCU.");
1368 static int kinetis_protect_check(struct flash_bank
*bank
)
1370 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
1375 if (k_bank
->flash_class
== FC_PFLASH
) {
1377 /* read protection register */
1378 result
= target_read_u32(bank
->target
, FTFx_FPROT3
, &fprot
);
1379 if (result
!= ERROR_OK
)
1382 /* Every bit protects 1/32 of the full flash (not necessarily just this bank) */
1384 } else if (k_bank
->flash_class
== FC_FLEX_NVM
) {
1387 /* read protection register */
1388 result
= target_read_u8(bank
->target
, FTFx_FDPROT
, &fdprot
);
1389 if (result
!= ERROR_OK
)
1395 LOG_ERROR("Protection checks for FlexRAM not supported");
1396 return ERROR_FLASH_BANK_INVALID
;
1399 b
= k_bank
->protection_block
;
1400 for (i
= 0; i
< bank
->num_prot_blocks
; i
++) {
1401 if ((fprot
>> b
) & 1)
1402 bank
->prot_blocks
[i
].is_protected
= 0;
1404 bank
->prot_blocks
[i
].is_protected
= 1;
1413 static int kinetis_fill_fcf(struct flash_bank
*bank
, uint8_t *fcf
)
1415 uint32_t fprot
= 0xffffffff;
1416 uint8_t fsec
= 0xfe; /* set MCU unsecure */
1417 uint8_t fdprot
= 0xff;
1420 unsigned num_blocks
;
1421 uint32_t pflash_bit
;
1423 struct flash_bank
*bank_iter
;
1424 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
1425 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
1427 memset(fcf
, 0xff, FCF_SIZE
);
1432 /* iterate over all kinetis banks */
1433 /* current bank is bank 0, it contains FCF */
1434 num_blocks
= k_chip
->num_pflash_blocks
+ k_chip
->num_nvm_blocks
;
1435 for (bank_idx
= 0; bank_idx
< num_blocks
; bank_idx
++) {
1436 k_bank
= &(k_chip
->banks
[bank_idx
]);
1437 bank_iter
= k_bank
->bank
;
1439 if (bank_iter
== NULL
) {
1440 LOG_WARNING("Missing bank %u configuration, FCF protection flags may be incomplette", bank_idx
);
1444 kinetis_auto_probe(bank_iter
);
1446 assert(bank_iter
->prot_blocks
);
1448 if (k_bank
->flash_class
== FC_PFLASH
) {
1449 for (i
= 0; i
< bank_iter
->num_prot_blocks
; i
++) {
1450 if (bank_iter
->prot_blocks
[i
].is_protected
== 1)
1451 fprot
&= ~pflash_bit
;
1456 } else if (k_bank
->flash_class
== FC_FLEX_NVM
) {
1457 for (i
= 0; i
< bank_iter
->num_prot_blocks
; i
++) {
1458 if (bank_iter
->prot_blocks
[i
].is_protected
== 1)
1459 fdprot
&= ~dflash_bit
;
1467 target_buffer_set_u32(bank
->target
, fcf
+ FCF_FPROT
, fprot
);
1468 fcf
[FCF_FSEC
] = fsec
;
1469 fcf
[FCF_FOPT
] = fcf_fopt
;
1470 fcf
[FCF_FDPROT
] = fdprot
;
1474 static int kinetis_ftfx_command(struct target
*target
, uint8_t fcmd
, uint32_t faddr
,
1475 uint8_t fccob4
, uint8_t fccob5
, uint8_t fccob6
, uint8_t fccob7
,
1476 uint8_t fccob8
, uint8_t fccob9
, uint8_t fccoba
, uint8_t fccobb
,
1477 uint8_t *ftfx_fstat
)
1479 uint8_t command
[12] = {faddr
& 0xff, (faddr
>> 8) & 0xff, (faddr
>> 16) & 0xff, fcmd
,
1480 fccob7
, fccob6
, fccob5
, fccob4
,
1481 fccobb
, fccoba
, fccob9
, fccob8
};
1484 int64_t ms_timeout
= timeval_ms() + 250;
1486 result
= target_write_memory(target
, FTFx_FCCOB3
, 4, 3, command
);
1487 if (result
!= ERROR_OK
)
1491 result
= target_write_u8(target
, FTFx_FSTAT
, 0x80);
1492 if (result
!= ERROR_OK
)
1497 result
= target_read_u8(target
, FTFx_FSTAT
, &fstat
);
1499 if (result
!= ERROR_OK
)
1505 } while (timeval_ms() < ms_timeout
);
1508 *ftfx_fstat
= fstat
;
1510 if ((fstat
& 0xf0) != 0x80) {
1511 LOG_DEBUG("ftfx command failed FSTAT: %02X FCCOB: %02X%02X%02X%02X %02X%02X%02X%02X %02X%02X%02X%02X",
1512 fstat
, command
[3], command
[2], command
[1], command
[0],
1513 command
[7], command
[6], command
[5], command
[4],
1514 command
[11], command
[10], command
[9], command
[8]);
1516 return kinetis_ftfx_decode_error(fstat
);
1523 static int kinetis_read_pmstat(struct kinetis_chip
*k_chip
, uint8_t *pmstat
)
1527 struct target
*target
= k_chip
->target
;
1529 switch (k_chip
->sysmodectrlr_type
) {
1531 result
= target_read_u8(target
, SMC_PMSTAT
, pmstat
);
1535 result
= target_read_u32(target
, SMC32_PMSTAT
, &stat32
);
1536 if (result
== ERROR_OK
)
1537 *pmstat
= stat32
& 0xff;
1543 static int kinetis_check_run_mode(struct kinetis_chip
*k_chip
)
1547 struct target
*target
;
1549 if (k_chip
== NULL
) {
1550 LOG_ERROR("Chip not probed.");
1553 target
= k_chip
->target
;
1555 if (target
->state
!= TARGET_HALTED
) {
1556 LOG_ERROR("Target not halted");
1557 return ERROR_TARGET_NOT_HALTED
;
1560 result
= kinetis_read_pmstat(k_chip
, &pmstat
);
1561 if (result
!= ERROR_OK
)
1564 if (pmstat
== PM_STAT_RUN
)
1567 if (pmstat
== PM_STAT_VLPR
) {
1568 /* It is safe to switch from VLPR to RUN mode without changing clock */
1569 LOG_INFO("Switching from VLPR to RUN mode.");
1571 switch (k_chip
->sysmodectrlr_type
) {
1573 result
= target_write_u8(target
, SMC_PMCTRL
, PM_CTRL_RUNM_RUN
);
1577 result
= target_write_u32(target
, SMC32_PMCTRL
, PM_CTRL_RUNM_RUN
);
1580 if (result
!= ERROR_OK
)
1583 for (i
= 100; i
; i
--) {
1584 result
= kinetis_read_pmstat(k_chip
, &pmstat
);
1585 if (result
!= ERROR_OK
)
1588 if (pmstat
== PM_STAT_RUN
)
1593 LOG_ERROR("Flash operation not possible in current run mode: SMC_PMSTAT: 0x%x", pmstat
);
1594 LOG_ERROR("Issue a 'reset init' command.");
1595 return ERROR_TARGET_NOT_HALTED
;
1599 static void kinetis_invalidate_flash_cache(struct kinetis_chip
*k_chip
)
1601 struct target
*target
= k_chip
->target
;
1603 switch (k_chip
->cache_type
) {
1604 case KINETIS_CACHE_K
:
1605 target_write_u8(target
, FMC_PFB01CR
+ 2, 0xf0);
1606 /* Set CINV_WAY bits - request invalidate of all cache ways */
1607 /* FMC_PFB0CR has same address and CINV_WAY bits as FMC_PFB01CR */
1610 case KINETIS_CACHE_L
:
1611 target_write_u8(target
, MCM_PLACR
+ 1, 0x04);
1612 /* set bit CFCC - Clear Flash Controller Cache */
1615 case KINETIS_CACHE_MSCM
:
1616 target_write_u32(target
, MSCM_OCMDR0
, 0x30);
1617 /* disable data prefetch and flash speculate */
1626 static int kinetis_erase(struct flash_bank
*bank
, int first
, int last
)
1629 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
1630 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
1632 result
= kinetis_check_run_mode(k_chip
);
1633 if (result
!= ERROR_OK
)
1636 /* reset error flags */
1637 result
= kinetis_ftfx_prepare(bank
->target
);
1638 if (result
!= ERROR_OK
)
1641 if ((first
> bank
->num_sectors
) || (last
> bank
->num_sectors
))
1642 return ERROR_FLASH_OPERATION_FAILED
;
1645 * FIXME: TODO: use the 'Erase Flash Block' command if the
1646 * requested erase is PFlash or NVM and encompasses the entire
1647 * block. Should be quicker.
1649 for (i
= first
; i
<= last
; i
++) {
1650 /* set command and sector address */
1651 result
= kinetis_ftfx_command(bank
->target
, FTFx_CMD_SECTERASE
, k_bank
->prog_base
+ bank
->sectors
[i
].offset
,
1652 0, 0, 0, 0, 0, 0, 0, 0, NULL
);
1654 if (result
!= ERROR_OK
) {
1655 LOG_WARNING("erase sector %d failed", i
);
1656 return ERROR_FLASH_OPERATION_FAILED
;
1659 bank
->sectors
[i
].is_erased
= 1;
1661 if (k_bank
->prog_base
== 0
1662 && bank
->sectors
[i
].offset
<= FCF_ADDRESS
1663 && bank
->sectors
[i
].offset
+ bank
->sectors
[i
].size
> FCF_ADDRESS
+ FCF_SIZE
) {
1664 if (allow_fcf_writes
) {
1665 LOG_WARNING("Flash Configuration Field erased, DO NOT reset or power off the device");
1666 LOG_WARNING("until correct FCF is programmed or MCU gets security lock.");
1668 uint8_t fcf_buffer
[FCF_SIZE
];
1670 kinetis_fill_fcf(bank
, fcf_buffer
);
1671 result
= kinetis_write_inner(bank
, fcf_buffer
, FCF_ADDRESS
, FCF_SIZE
);
1672 if (result
!= ERROR_OK
)
1673 LOG_WARNING("Flash Configuration Field write failed");
1674 bank
->sectors
[i
].is_erased
= 0;
1679 kinetis_invalidate_flash_cache(k_bank
->k_chip
);
1684 static int kinetis_make_ram_ready(struct target
*target
)
1689 /* check if ram ready */
1690 result
= target_read_u8(target
, FTFx_FCNFG
, &ftfx_fcnfg
);
1691 if (result
!= ERROR_OK
)
1694 if (ftfx_fcnfg
& (1 << 1))
1695 return ERROR_OK
; /* ram ready */
1697 /* make flex ram available */
1698 result
= kinetis_ftfx_command(target
, FTFx_CMD_SETFLEXRAM
, 0x00ff0000,
1699 0, 0, 0, 0, 0, 0, 0, 0, NULL
);
1700 if (result
!= ERROR_OK
)
1701 return ERROR_FLASH_OPERATION_FAILED
;
1704 result
= target_read_u8(target
, FTFx_FCNFG
, &ftfx_fcnfg
);
1705 if (result
!= ERROR_OK
)
1708 if (ftfx_fcnfg
& (1 << 1))
1709 return ERROR_OK
; /* ram ready */
1711 return ERROR_FLASH_OPERATION_FAILED
;
1715 static int kinetis_write_sections(struct flash_bank
*bank
, const uint8_t *buffer
,
1716 uint32_t offset
, uint32_t count
)
1718 int result
= ERROR_OK
;
1719 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
1720 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
1721 uint8_t *buffer_aligned
= NULL
;
1723 * Kinetis uses different terms for the granularity of
1724 * sector writes, e.g. "phrase" or "128 bits". We use
1725 * the generic term "chunk". The largest possible
1726 * Kinetis "chunk" is 16 bytes (128 bits).
1728 uint32_t prog_section_chunk_bytes
= k_bank
->sector_size
>> 8;
1729 uint32_t prog_size_bytes
= k_chip
->max_flash_prog_size
;
1732 uint32_t size
= prog_size_bytes
- offset
% prog_size_bytes
;
1733 uint32_t align_begin
= offset
% prog_section_chunk_bytes
;
1735 uint32_t size_aligned
;
1736 uint16_t chunk_count
;
1742 align_end
= (align_begin
+ size
) % prog_section_chunk_bytes
;
1744 align_end
= prog_section_chunk_bytes
- align_end
;
1746 size_aligned
= align_begin
+ size
+ align_end
;
1747 chunk_count
= size_aligned
/ prog_section_chunk_bytes
;
1749 if (size
!= size_aligned
) {
1750 /* aligned section: the first, the last or the only */
1751 if (!buffer_aligned
)
1752 buffer_aligned
= malloc(prog_size_bytes
);
1754 memset(buffer_aligned
, 0xff, size_aligned
);
1755 memcpy(buffer_aligned
+ align_begin
, buffer
, size
);
1757 result
= target_write_memory(bank
->target
, k_chip
->progr_accel_ram
,
1758 4, size_aligned
/ 4, buffer_aligned
);
1760 LOG_DEBUG("section @ " TARGET_ADDR_FMT
" aligned begin %" PRIu32
1762 bank
->base
+ offset
, align_begin
, align_end
);
1764 result
= target_write_memory(bank
->target
, k_chip
->progr_accel_ram
,
1765 4, size_aligned
/ 4, buffer
);
1767 LOG_DEBUG("write section @ " TARGET_ADDR_FMT
" with length %" PRIu32
1769 bank
->base
+ offset
, size
);
1771 if (result
!= ERROR_OK
) {
1772 LOG_ERROR("target_write_memory failed");
1776 /* execute section-write command */
1777 result
= kinetis_ftfx_command(bank
->target
, FTFx_CMD_SECTWRITE
,
1778 k_bank
->prog_base
+ offset
- align_begin
,
1779 chunk_count
>>8, chunk_count
, 0, 0,
1780 0, 0, 0, 0, &ftfx_fstat
);
1782 if (result
!= ERROR_OK
) {
1783 LOG_ERROR("Error writing section at " TARGET_ADDR_FMT
,
1784 bank
->base
+ offset
);
1788 if (ftfx_fstat
& 0x01) {
1789 LOG_ERROR("Flash write error at " TARGET_ADDR_FMT
,
1790 bank
->base
+ offset
);
1791 if (k_bank
->prog_base
== 0 && offset
== FCF_ADDRESS
+ FCF_SIZE
1792 && (k_chip
->flash_support
& FS_WIDTH_256BIT
)) {
1793 LOG_ERROR("Flash write immediately after the end of Flash Config Field shows error");
1794 LOG_ERROR("because the flash memory is 256 bits wide (data were written correctly).");
1795 LOG_ERROR("Either change the linker script to add a gap of 16 bytes after FCF");
1796 LOG_ERROR("or set 'kinetis fcf_source write'");
1805 free(buffer_aligned
);
1810 static int kinetis_write_inner(struct flash_bank
*bank
, const uint8_t *buffer
,
1811 uint32_t offset
, uint32_t count
)
1813 int result
, fallback
= 0;
1814 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
1815 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
1817 if (!(k_chip
->flash_support
& FS_PROGRAM_SECTOR
)) {
1818 /* fallback to longword write */
1820 LOG_INFO("This device supports Program Longword execution only.");
1822 result
= kinetis_make_ram_ready(bank
->target
);
1823 if (result
!= ERROR_OK
) {
1825 LOG_WARNING("FlexRAM not ready, fallback to slow longword write.");
1829 LOG_DEBUG("flash write @ " TARGET_ADDR_FMT
, bank
->base
+ offset
);
1831 if (fallback
== 0) {
1832 /* program section command */
1833 kinetis_write_sections(bank
, buffer
, offset
, count
);
1834 } else if (k_chip
->flash_support
& FS_PROGRAM_LONGWORD
) {
1835 /* program longword command, not supported in FTFE */
1836 uint8_t *new_buffer
= NULL
;
1838 /* check word alignment */
1840 LOG_ERROR("offset 0x%" PRIx32
" breaks the required alignment", offset
);
1841 return ERROR_FLASH_DST_BREAKS_ALIGNMENT
;
1845 uint32_t old_count
= count
;
1846 count
= (old_count
| 3) + 1;
1847 new_buffer
= malloc(count
);
1848 if (new_buffer
== NULL
) {
1849 LOG_ERROR("odd number of bytes to write and no memory "
1850 "for padding buffer");
1853 LOG_INFO("odd number of bytes to write (%" PRIu32
"), extending to %" PRIu32
" "
1854 "and padding with 0xff", old_count
, count
);
1855 memset(new_buffer
+ old_count
, 0xff, count
- old_count
);
1856 buffer
= memcpy(new_buffer
, buffer
, old_count
);
1859 uint32_t words_remaining
= count
/ 4;
1861 kinetis_disable_wdog(k_chip
);
1863 /* try using a block write */
1864 result
= kinetis_write_block(bank
, buffer
, offset
, words_remaining
);
1866 if (result
== ERROR_TARGET_RESOURCE_NOT_AVAILABLE
) {
1867 /* if block write failed (no sufficient working area),
1868 * we use normal (slow) single word accesses */
1869 LOG_WARNING("couldn't use block writes, falling back to single "
1872 while (words_remaining
) {
1875 LOG_DEBUG("write longword @ %08" PRIx32
, (uint32_t)(bank
->base
+ offset
));
1877 result
= kinetis_ftfx_command(bank
->target
, FTFx_CMD_LWORDPROG
, k_bank
->prog_base
+ offset
,
1878 buffer
[3], buffer
[2], buffer
[1], buffer
[0],
1879 0, 0, 0, 0, &ftfx_fstat
);
1881 if (result
!= ERROR_OK
) {
1882 LOG_ERROR("Error writing longword at " TARGET_ADDR_FMT
,
1883 bank
->base
+ offset
);
1887 if (ftfx_fstat
& 0x01)
1888 LOG_ERROR("Flash write error at " TARGET_ADDR_FMT
,
1889 bank
->base
+ offset
);
1898 LOG_ERROR("Flash write strategy not implemented");
1899 return ERROR_FLASH_OPERATION_FAILED
;
1902 kinetis_invalidate_flash_cache(k_chip
);
1907 static int kinetis_write(struct flash_bank
*bank
, const uint8_t *buffer
,
1908 uint32_t offset
, uint32_t count
)
1911 bool set_fcf
= false;
1912 bool fcf_in_data_valid
= false;
1914 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
1915 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
1916 uint8_t fcf_buffer
[FCF_SIZE
];
1917 uint8_t fcf_current
[FCF_SIZE
];
1918 uint8_t fcf_in_data
[FCF_SIZE
];
1920 result
= kinetis_check_run_mode(k_chip
);
1921 if (result
!= ERROR_OK
)
1924 /* reset error flags */
1925 result
= kinetis_ftfx_prepare(bank
->target
);
1926 if (result
!= ERROR_OK
)
1929 if (k_bank
->prog_base
== 0 && !allow_fcf_writes
) {
1930 if (bank
->sectors
[1].offset
<= FCF_ADDRESS
)
1931 sect
= 1; /* 1kb sector, FCF in 2nd sector */
1933 if (offset
< bank
->sectors
[sect
].offset
+ bank
->sectors
[sect
].size
1934 && offset
+ count
> bank
->sectors
[sect
].offset
)
1935 set_fcf
= true; /* write to any part of sector with FCF */
1939 kinetis_fill_fcf(bank
, fcf_buffer
);
1941 fcf_in_data_valid
= offset
<= FCF_ADDRESS
1942 && offset
+ count
>= FCF_ADDRESS
+ FCF_SIZE
;
1943 if (fcf_in_data_valid
) {
1944 memcpy(fcf_in_data
, buffer
+ FCF_ADDRESS
- offset
, FCF_SIZE
);
1945 if (memcmp(fcf_in_data
+ FCF_FPROT
, fcf_buffer
, 4)) {
1946 fcf_in_data_valid
= false;
1947 LOG_INFO("Flash protection requested in programmed file differs from current setting.");
1949 if (fcf_in_data
[FCF_FDPROT
] != fcf_buffer
[FCF_FDPROT
]) {
1950 fcf_in_data_valid
= false;
1951 LOG_INFO("Data flash protection requested in programmed file differs from current setting.");
1953 if ((fcf_in_data
[FCF_FSEC
] & 3) != 2) {
1954 fcf_in_data_valid
= false;
1955 LOG_INFO("Device security requested in programmed file!");
1956 } else if (k_chip
->flash_support
& FS_ECC
1957 && fcf_in_data
[FCF_FSEC
] != fcf_buffer
[FCF_FSEC
]) {
1958 fcf_in_data_valid
= false;
1959 LOG_INFO("Strange unsecure mode 0x%02" PRIx8
1960 "requested in programmed file!",
1961 fcf_in_data
[FCF_FSEC
]);
1963 if ((k_chip
->flash_support
& FS_ECC
|| fcf_fopt_configured
)
1964 && fcf_in_data
[FCF_FOPT
] != fcf_fopt
) {
1965 fcf_in_data_valid
= false;
1966 LOG_INFO("FOPT requested in programmed file differs from current setting.");
1968 if (!fcf_in_data_valid
)
1969 LOG_INFO("Expect verify errors at FCF (0x408-0x40f).");
1973 if (set_fcf
&& !fcf_in_data_valid
) {
1974 if (offset
< FCF_ADDRESS
) {
1975 /* write part preceding FCF */
1976 result
= kinetis_write_inner(bank
, buffer
, offset
, FCF_ADDRESS
- offset
);
1977 if (result
!= ERROR_OK
)
1981 result
= target_read_memory(bank
->target
, bank
->base
+ FCF_ADDRESS
, 4, FCF_SIZE
/ 4, fcf_current
);
1982 if (result
== ERROR_OK
&& memcmp(fcf_current
, fcf_buffer
, FCF_SIZE
) == 0)
1986 /* write FCF if differs from flash - eliminate multiple writes */
1987 result
= kinetis_write_inner(bank
, fcf_buffer
, FCF_ADDRESS
, FCF_SIZE
);
1988 if (result
!= ERROR_OK
)
1992 LOG_WARNING("Flash Configuration Field written.");
1993 LOG_WARNING("Reset or power off the device to make settings effective.");
1995 if (offset
+ count
> FCF_ADDRESS
+ FCF_SIZE
) {
1996 uint32_t delta
= FCF_ADDRESS
+ FCF_SIZE
- offset
;
1997 /* write part after FCF */
1998 result
= kinetis_write_inner(bank
, buffer
+ delta
, FCF_ADDRESS
+ FCF_SIZE
, count
- delta
);
2003 /* no FCF fiddling, normal write */
2004 return kinetis_write_inner(bank
, buffer
, offset
, count
);
2009 static int kinetis_probe_chip(struct kinetis_chip
*k_chip
)
2012 uint8_t fcfg1_nvmsize
, fcfg1_pfsize
, fcfg1_eesize
, fcfg1_depart
;
2013 uint8_t fcfg2_pflsh
;
2014 uint32_t ee_size
= 0;
2015 uint32_t pflash_size_k
, nvm_size_k
, dflash_size_k
;
2016 uint32_t pflash_size_m
;
2017 unsigned num_blocks
= 0;
2018 unsigned maxaddr_shift
= 13;
2019 struct target
*target
= k_chip
->target
;
2021 unsigned familyid
= 0, subfamid
= 0;
2022 unsigned cpu_mhz
= 120;
2024 bool use_nvm_marking
= false;
2025 char flash_marking
[12], nvm_marking
[2];
2028 k_chip
->probed
= false;
2029 k_chip
->pflash_sector_size
= 0;
2030 k_chip
->pflash_base
= 0;
2031 k_chip
->nvm_base
= 0x10000000;
2032 k_chip
->progr_accel_ram
= FLEXRAM
;
2036 if (k_chip
->sim_base
)
2037 result
= target_read_u32(target
, k_chip
->sim_base
+ SIM_SDID_OFFSET
, &k_chip
->sim_sdid
);
2039 result
= target_read_u32(target
, SIM_BASE
+ SIM_SDID_OFFSET
, &k_chip
->sim_sdid
);
2040 if (result
== ERROR_OK
)
2041 k_chip
->sim_base
= SIM_BASE
;
2043 result
= target_read_u32(target
, SIM_BASE_KL28
+ SIM_SDID_OFFSET
, &k_chip
->sim_sdid
);
2044 if (result
== ERROR_OK
)
2045 k_chip
->sim_base
= SIM_BASE_KL28
;
2048 if (result
!= ERROR_OK
)
2051 if ((k_chip
->sim_sdid
& (~KINETIS_SDID_K_SERIES_MASK
)) == 0) {
2052 /* older K-series MCU */
2053 uint32_t mcu_type
= k_chip
->sim_sdid
& KINETIS_K_SDID_TYPE_MASK
;
2054 k_chip
->cache_type
= KINETIS_CACHE_K
;
2055 k_chip
->watchdog_type
= KINETIS_WDOG_K
;
2058 case KINETIS_K_SDID_K10_M50
:
2059 case KINETIS_K_SDID_K20_M50
:
2061 k_chip
->pflash_sector_size
= 1<<10;
2062 k_chip
->nvm_sector_size
= 1<<10;
2064 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
| FS_PROGRAM_SECTOR
;
2066 case KINETIS_K_SDID_K10_M72
:
2067 case KINETIS_K_SDID_K20_M72
:
2068 case KINETIS_K_SDID_K30_M72
:
2069 case KINETIS_K_SDID_K30_M100
:
2070 case KINETIS_K_SDID_K40_M72
:
2071 case KINETIS_K_SDID_K40_M100
:
2072 case KINETIS_K_SDID_K50_M72
:
2073 /* 2kB sectors, 1kB FlexNVM sectors */
2074 k_chip
->pflash_sector_size
= 2<<10;
2075 k_chip
->nvm_sector_size
= 1<<10;
2077 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
| FS_PROGRAM_SECTOR
;
2078 k_chip
->max_flash_prog_size
= 1<<10;
2080 case KINETIS_K_SDID_K10_M100
:
2081 case KINETIS_K_SDID_K20_M100
:
2082 case KINETIS_K_SDID_K11
:
2083 case KINETIS_K_SDID_K12
:
2084 case KINETIS_K_SDID_K21_M50
:
2085 case KINETIS_K_SDID_K22_M50
:
2086 case KINETIS_K_SDID_K51_M72
:
2087 case KINETIS_K_SDID_K53
:
2088 case KINETIS_K_SDID_K60_M100
:
2090 k_chip
->pflash_sector_size
= 2<<10;
2091 k_chip
->nvm_sector_size
= 2<<10;
2093 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
| FS_PROGRAM_SECTOR
;
2095 case KINETIS_K_SDID_K21_M120
:
2096 case KINETIS_K_SDID_K22_M120
:
2097 /* 4kB sectors (MK21FN1M0, MK21FX512, MK22FN1M0, MK22FX512) */
2098 k_chip
->pflash_sector_size
= 4<<10;
2099 k_chip
->max_flash_prog_size
= 1<<10;
2100 k_chip
->nvm_sector_size
= 4<<10;
2102 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
;
2104 case KINETIS_K_SDID_K10_M120
:
2105 case KINETIS_K_SDID_K20_M120
:
2106 case KINETIS_K_SDID_K60_M150
:
2107 case KINETIS_K_SDID_K70_M150
:
2109 k_chip
->pflash_sector_size
= 4<<10;
2110 k_chip
->nvm_sector_size
= 4<<10;
2112 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
;
2115 LOG_ERROR("Unsupported K-family FAMID");
2118 for (idx
= 0; idx
< ARRAY_SIZE(kinetis_types_old
); idx
++) {
2119 if (kinetis_types_old
[idx
].sdid
== mcu_type
) {
2120 strcpy(name
, kinetis_types_old
[idx
].name
);
2121 use_nvm_marking
= true;
2127 /* Newer K-series or KL series MCU */
2128 familyid
= (k_chip
->sim_sdid
& KINETIS_SDID_FAMILYID_MASK
) >> KINETIS_SDID_FAMILYID_SHIFT
;
2129 subfamid
= (k_chip
->sim_sdid
& KINETIS_SDID_SUBFAMID_MASK
) >> KINETIS_SDID_SUBFAMID_SHIFT
;
2131 switch (k_chip
->sim_sdid
& KINETIS_SDID_SERIESID_MASK
) {
2132 case KINETIS_SDID_SERIESID_K
:
2133 use_nvm_marking
= true;
2134 k_chip
->cache_type
= KINETIS_CACHE_K
;
2135 k_chip
->watchdog_type
= KINETIS_WDOG_K
;
2137 switch (k_chip
->sim_sdid
& (KINETIS_SDID_FAMILYID_MASK
| KINETIS_SDID_SUBFAMID_MASK
)) {
2138 case KINETIS_SDID_FAMILYID_K0X
| KINETIS_SDID_SUBFAMID_KX2
:
2139 /* K02FN64, K02FN128: FTFA, 2kB sectors */
2140 k_chip
->pflash_sector_size
= 2<<10;
2142 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2146 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX2
: {
2147 /* MK24FN1M reports as K22, this should detect it (according to errata note 1N83J) */
2149 result
= target_read_u32(target
, k_chip
->sim_base
+ SIM_SOPT1_OFFSET
, &sopt1
);
2150 if (result
!= ERROR_OK
)
2153 if (((k_chip
->sim_sdid
& (KINETIS_SDID_DIEID_MASK
)) == KINETIS_SDID_DIEID_K24FN1M
) &&
2154 ((sopt1
& KINETIS_SOPT1_RAMSIZE_MASK
) == KINETIS_SOPT1_RAMSIZE_K24FN1M
)) {
2156 k_chip
->pflash_sector_size
= 4<<10;
2158 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
;
2159 k_chip
->max_flash_prog_size
= 1<<10;
2160 subfamid
= 4; /* errata 1N83J fix */
2163 if ((k_chip
->sim_sdid
& (KINETIS_SDID_DIEID_MASK
)) == KINETIS_SDID_DIEID_K22FN128
2164 || (k_chip
->sim_sdid
& (KINETIS_SDID_DIEID_MASK
)) == KINETIS_SDID_DIEID_K22FN256
2165 || (k_chip
->sim_sdid
& (KINETIS_SDID_DIEID_MASK
)) == KINETIS_SDID_DIEID_K22FN512
) {
2166 /* K22 with new-style SDID - smaller pflash with FTFA, 2kB sectors */
2167 k_chip
->pflash_sector_size
= 2<<10;
2168 /* autodetect 1 or 2 blocks */
2169 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2172 LOG_ERROR("Unsupported Kinetis K22 DIEID");
2175 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX4
:
2176 k_chip
->pflash_sector_size
= 4<<10;
2177 if ((k_chip
->sim_sdid
& (KINETIS_SDID_DIEID_MASK
)) == KINETIS_SDID_DIEID_K24FN256
) {
2178 /* K24FN256 - smaller pflash with FTFA */
2180 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2183 /* K24FN1M without errata 7534 */
2185 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
;
2186 k_chip
->max_flash_prog_size
= 1<<10;
2189 case KINETIS_SDID_FAMILYID_K6X
| KINETIS_SDID_SUBFAMID_KX1
: /* errata 7534 - should be K63 */
2190 case KINETIS_SDID_FAMILYID_K6X
| KINETIS_SDID_SUBFAMID_KX2
: /* errata 7534 - should be K64 */
2191 subfamid
+= 2; /* errata 7534 fix */
2193 case KINETIS_SDID_FAMILYID_K6X
| KINETIS_SDID_SUBFAMID_KX3
:
2195 case KINETIS_SDID_FAMILYID_K6X
| KINETIS_SDID_SUBFAMID_KX4
:
2196 /* K64FN1M0, K64FX512 */
2197 k_chip
->pflash_sector_size
= 4<<10;
2198 k_chip
->nvm_sector_size
= 4<<10;
2199 k_chip
->max_flash_prog_size
= 1<<10;
2201 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
;
2204 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX6
:
2206 case KINETIS_SDID_FAMILYID_K6X
| KINETIS_SDID_SUBFAMID_KX6
:
2207 /* K66FN2M0, K66FX1M0 */
2208 k_chip
->pflash_sector_size
= 4<<10;
2209 k_chip
->nvm_sector_size
= 4<<10;
2210 k_chip
->max_flash_prog_size
= 1<<10;
2212 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
| FS_ECC
;
2216 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX7
:
2218 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX8
:
2220 k_chip
->pflash_sector_size
= 4<<10;
2221 k_chip
->max_flash_prog_size
= 1<<10;
2223 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
| FS_ECC
;
2227 case KINETIS_SDID_FAMILYID_K8X
| KINETIS_SDID_SUBFAMID_KX0
:
2228 case KINETIS_SDID_FAMILYID_K8X
| KINETIS_SDID_SUBFAMID_KX1
:
2229 case KINETIS_SDID_FAMILYID_K8X
| KINETIS_SDID_SUBFAMID_KX2
:
2230 /* K80FN256, K81FN256, K82FN256 */
2231 k_chip
->pflash_sector_size
= 4<<10;
2233 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
| FS_NO_CMD_BLOCKSTAT
;
2237 case KINETIS_SDID_FAMILYID_KL8X
| KINETIS_SDID_SUBFAMID_KX1
:
2238 case KINETIS_SDID_FAMILYID_KL8X
| KINETIS_SDID_SUBFAMID_KX2
:
2239 /* KL81Z128, KL82Z128 */
2240 k_chip
->pflash_sector_size
= 2<<10;
2242 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
| FS_NO_CMD_BLOCKSTAT
;
2243 k_chip
->cache_type
= KINETIS_CACHE_L
;
2245 use_nvm_marking
= false;
2246 snprintf(name
, sizeof(name
), "MKL8%uZ%%s7",
2251 LOG_ERROR("Unsupported Kinetis FAMILYID SUBFAMID");
2254 if (name
[0] == '\0')
2255 snprintf(name
, sizeof(name
), "MK%u%uF%%s%u",
2256 familyid
, subfamid
, cpu_mhz
/ 10);
2259 case KINETIS_SDID_SERIESID_KL
:
2261 k_chip
->pflash_sector_size
= 1<<10;
2262 k_chip
->nvm_sector_size
= 1<<10;
2263 /* autodetect 1 or 2 blocks */
2264 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2265 k_chip
->cache_type
= KINETIS_CACHE_L
;
2266 k_chip
->watchdog_type
= KINETIS_WDOG_COP
;
2269 switch (k_chip
->sim_sdid
& (KINETIS_SDID_FAMILYID_MASK
| KINETIS_SDID_SUBFAMID_MASK
)) {
2270 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX3
:
2271 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX3
:
2275 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX8
:
2277 k_chip
->pflash_sector_size
= 2<<10;
2279 k_chip
->watchdog_type
= KINETIS_WDOG32_KL28
;
2280 k_chip
->sysmodectrlr_type
= KINETIS_SMC32
;
2284 snprintf(name
, sizeof(name
), "MKL%u%uZ%%s%u",
2285 familyid
, subfamid
, cpu_mhz
/ 10);
2288 case KINETIS_SDID_SERIESID_KW
:
2289 /* Newer KW-series (all KW series except KW2xD, KW01Z) */
2291 switch (k_chip
->sim_sdid
& (KINETIS_SDID_FAMILYID_MASK
| KINETIS_SDID_SUBFAMID_MASK
)) {
2292 case KINETIS_SDID_FAMILYID_K4X
| KINETIS_SDID_SUBFAMID_KX0
:
2294 case KINETIS_SDID_FAMILYID_K3X
| KINETIS_SDID_SUBFAMID_KX0
:
2296 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX0
:
2298 /* FTFA, 1kB sectors */
2299 k_chip
->pflash_sector_size
= 1<<10;
2300 k_chip
->nvm_sector_size
= 1<<10;
2301 /* autodetect 1 or 2 blocks */
2302 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2303 k_chip
->cache_type
= KINETIS_CACHE_L
;
2304 k_chip
->watchdog_type
= KINETIS_WDOG_COP
;
2306 case KINETIS_SDID_FAMILYID_K4X
| KINETIS_SDID_SUBFAMID_KX1
:
2308 case KINETIS_SDID_FAMILYID_K3X
| KINETIS_SDID_SUBFAMID_KX1
:
2310 case KINETIS_SDID_FAMILYID_K2X
| KINETIS_SDID_SUBFAMID_KX1
:
2312 /* FTFA, 2kB sectors */
2313 k_chip
->pflash_sector_size
= 2<<10;
2314 k_chip
->nvm_sector_size
= 2<<10;
2315 /* autodetect 1 or 2 blocks */
2316 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2317 k_chip
->cache_type
= KINETIS_CACHE_L
;
2318 k_chip
->watchdog_type
= KINETIS_WDOG_COP
;
2321 LOG_ERROR("Unsupported KW FAMILYID SUBFAMID");
2323 snprintf(name
, sizeof(name
), "MKW%u%uZ%%s%u",
2324 familyid
, subfamid
, cpu_mhz
/ 10);
2327 case KINETIS_SDID_SERIESID_KV
:
2329 k_chip
->watchdog_type
= KINETIS_WDOG_K
;
2330 switch (k_chip
->sim_sdid
& (KINETIS_SDID_FAMILYID_MASK
| KINETIS_SDID_SUBFAMID_MASK
)) {
2331 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX0
:
2332 /* KV10: FTFA, 1kB sectors */
2333 k_chip
->pflash_sector_size
= 1<<10;
2335 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2336 k_chip
->cache_type
= KINETIS_CACHE_L
;
2337 strcpy(name
, "MKV10Z%s7");
2340 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX1
:
2341 /* KV11: FTFA, 2kB sectors */
2342 k_chip
->pflash_sector_size
= 2<<10;
2344 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2345 k_chip
->cache_type
= KINETIS_CACHE_L
;
2346 strcpy(name
, "MKV11Z%s7");
2349 case KINETIS_SDID_FAMILYID_K3X
| KINETIS_SDID_SUBFAMID_KX0
:
2350 /* KV30: FTFA, 2kB sectors, 1 block */
2351 case KINETIS_SDID_FAMILYID_K3X
| KINETIS_SDID_SUBFAMID_KX1
:
2352 /* KV31: FTFA, 2kB sectors, 2 blocks */
2353 k_chip
->pflash_sector_size
= 2<<10;
2354 /* autodetect 1 or 2 blocks */
2355 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2356 k_chip
->cache_type
= KINETIS_CACHE_K
;
2359 case KINETIS_SDID_FAMILYID_K4X
| KINETIS_SDID_SUBFAMID_KX2
:
2360 case KINETIS_SDID_FAMILYID_K4X
| KINETIS_SDID_SUBFAMID_KX4
:
2361 case KINETIS_SDID_FAMILYID_K4X
| KINETIS_SDID_SUBFAMID_KX6
:
2362 /* KV4x: FTFA, 4kB sectors */
2363 k_chip
->pflash_sector_size
= 4<<10;
2365 k_chip
->flash_support
= FS_PROGRAM_LONGWORD
;
2366 k_chip
->cache_type
= KINETIS_CACHE_K
;
2370 case KINETIS_SDID_FAMILYID_K5X
| KINETIS_SDID_SUBFAMID_KX6
:
2371 case KINETIS_SDID_FAMILYID_K5X
| KINETIS_SDID_SUBFAMID_KX8
:
2372 /* KV5x: FTFE, 8kB sectors */
2373 k_chip
->pflash_sector_size
= 8<<10;
2374 k_chip
->max_flash_prog_size
= 1<<10;
2377 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
| FS_WIDTH_256BIT
| FS_ECC
;
2378 k_chip
->pflash_base
= 0x10000000;
2379 k_chip
->progr_accel_ram
= 0x18000000;
2384 LOG_ERROR("Unsupported KV FAMILYID SUBFAMID");
2387 if (name
[0] == '\0')
2388 snprintf(name
, sizeof(name
), "MKV%u%uF%%s%u",
2389 familyid
, subfamid
, cpu_mhz
/ 10);
2392 case KINETIS_SDID_SERIESID_KE
:
2394 k_chip
->watchdog_type
= KINETIS_WDOG32_KE1X
;
2395 switch (k_chip
->sim_sdid
&
2396 (KINETIS_SDID_FAMILYID_MASK
| KINETIS_SDID_SUBFAMID_MASK
| KINETIS_SDID_PROJECTID_MASK
)) {
2397 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX4
| KINETIS_SDID_PROJECTID_KE1xZ
:
2398 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX5
| KINETIS_SDID_PROJECTID_KE1xZ
:
2399 /* KE1xZ: FTFE, 2kB sectors */
2400 k_chip
->pflash_sector_size
= 2<<10;
2401 k_chip
->nvm_sector_size
= 2<<10;
2402 k_chip
->max_flash_prog_size
= 1<<9;
2404 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
;
2405 k_chip
->cache_type
= KINETIS_CACHE_L
;
2408 snprintf(name
, sizeof(name
), "MKE%u%uZ%%s%u",
2409 familyid
, subfamid
, cpu_mhz
/ 10);
2412 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX4
| KINETIS_SDID_PROJECTID_KE1xF
:
2413 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX6
| KINETIS_SDID_PROJECTID_KE1xF
:
2414 case KINETIS_SDID_FAMILYID_K1X
| KINETIS_SDID_SUBFAMID_KX8
| KINETIS_SDID_PROJECTID_KE1xF
:
2415 /* KE1xF: FTFE, 4kB sectors */
2416 k_chip
->pflash_sector_size
= 4<<10;
2417 k_chip
->nvm_sector_size
= 2<<10;
2418 k_chip
->max_flash_prog_size
= 1<<10;
2420 k_chip
->flash_support
= FS_PROGRAM_PHRASE
| FS_PROGRAM_SECTOR
;
2421 k_chip
->cache_type
= KINETIS_CACHE_MSCM
;
2424 snprintf(name
, sizeof(name
), "MKE%u%uF%%s%u",
2425 familyid
, subfamid
, cpu_mhz
/ 10);
2429 LOG_ERROR("Unsupported KE FAMILYID SUBFAMID");
2434 LOG_ERROR("Unsupported K-series");
2438 if (k_chip
->pflash_sector_size
== 0) {
2439 LOG_ERROR("MCU is unsupported, SDID 0x%08" PRIx32
, k_chip
->sim_sdid
);
2440 return ERROR_FLASH_OPER_UNSUPPORTED
;
2443 result
= target_read_u32(target
, k_chip
->sim_base
+ SIM_FCFG1_OFFSET
, &k_chip
->sim_fcfg1
);
2444 if (result
!= ERROR_OK
)
2447 result
= target_read_u32(target
, k_chip
->sim_base
+ SIM_FCFG2_OFFSET
, &k_chip
->sim_fcfg2
);
2448 if (result
!= ERROR_OK
)
2451 LOG_DEBUG("SDID: 0x%08" PRIX32
" FCFG1: 0x%08" PRIX32
" FCFG2: 0x%08" PRIX32
, k_chip
->sim_sdid
,
2452 k_chip
->sim_fcfg1
, k_chip
->sim_fcfg2
);
2454 fcfg1_nvmsize
= (uint8_t)((k_chip
->sim_fcfg1
>> 28) & 0x0f);
2455 fcfg1_pfsize
= (uint8_t)((k_chip
->sim_fcfg1
>> 24) & 0x0f);
2456 fcfg1_eesize
= (uint8_t)((k_chip
->sim_fcfg1
>> 16) & 0x0f);
2457 fcfg1_depart
= (uint8_t)((k_chip
->sim_fcfg1
>> 8) & 0x0f);
2459 fcfg2_pflsh
= (uint8_t)((k_chip
->sim_fcfg2
>> 23) & 0x01);
2460 k_chip
->fcfg2_maxaddr0_shifted
= ((k_chip
->sim_fcfg2
>> 24) & 0x7f) << maxaddr_shift
;
2461 k_chip
->fcfg2_maxaddr1_shifted
= ((k_chip
->sim_fcfg2
>> 16) & 0x7f) << maxaddr_shift
;
2463 if (num_blocks
== 0)
2464 num_blocks
= k_chip
->fcfg2_maxaddr1_shifted
? 2 : 1;
2465 else if (k_chip
->fcfg2_maxaddr1_shifted
== 0 && num_blocks
>= 2 && fcfg2_pflsh
) {
2466 /* fcfg2_maxaddr1 may be zero due to partitioning whole NVM as EEPROM backup
2467 * Do not adjust block count in this case! */
2469 LOG_WARNING("MAXADDR1 is zero, number of flash banks adjusted to 1");
2470 } else if (k_chip
->fcfg2_maxaddr1_shifted
!= 0 && num_blocks
== 1) {
2472 LOG_WARNING("MAXADDR1 is non zero, number of flash banks adjusted to 2");
2475 /* when the PFLSH bit is set, there is no FlexNVM/FlexRAM */
2477 switch (fcfg1_nvmsize
) {
2483 k_chip
->nvm_size
= 1 << (14 + (fcfg1_nvmsize
>> 1));
2486 if (k_chip
->pflash_sector_size
>= 4<<10)
2487 k_chip
->nvm_size
= 512<<10;
2490 k_chip
->nvm_size
= 256<<10;
2493 k_chip
->nvm_size
= 0;
2497 switch (fcfg1_eesize
) {
2508 ee_size
= (16 << (10 - fcfg1_eesize
));
2515 switch (fcfg1_depart
) {
2522 k_chip
->dflash_size
= k_chip
->nvm_size
- (4096 << fcfg1_depart
);
2526 k_chip
->dflash_size
= 0;
2533 k_chip
->dflash_size
= 4096 << (fcfg1_depart
& 0x7);
2536 k_chip
->dflash_size
= k_chip
->nvm_size
;
2541 switch (fcfg1_pfsize
) {
2543 k_chip
->pflash_size
= 8192;
2552 k_chip
->pflash_size
= 1 << (14 + (fcfg1_pfsize
>> 1));
2555 /* a peculiar case: Freescale states different sizes for 0xf
2556 * KL03P24M48SF0RM 32 KB .... duplicate of code 0x3
2557 * K02P64M100SFARM 128 KB ... duplicate of code 0x7
2558 * K22P121M120SF8RM 256 KB ... duplicate of code 0x9
2559 * K22P121M120SF7RM 512 KB ... duplicate of code 0xb
2560 * K22P100M120SF5RM 1024 KB ... duplicate of code 0xd
2561 * K26P169M180SF5RM 2048 KB ... the only unique value
2562 * fcfg2_maxaddr0 seems to be the only clue to pflash_size
2563 * Checking fcfg2_maxaddr0 in bank probe is pointless then
2566 k_chip
->pflash_size
= k_chip
->fcfg2_maxaddr0_shifted
* num_blocks
;
2568 k_chip
->pflash_size
= k_chip
->fcfg2_maxaddr0_shifted
* num_blocks
/ 2;
2569 if (k_chip
->pflash_size
!= 2048<<10)
2570 LOG_WARNING("SIM_FCFG1 PFSIZE = 0xf: please check if pflash is %u KB", k_chip
->pflash_size
>>10);
2574 k_chip
->pflash_size
= 0;
2578 if (k_chip
->flash_support
& FS_PROGRAM_SECTOR
&& k_chip
->max_flash_prog_size
== 0) {
2579 k_chip
->max_flash_prog_size
= k_chip
->pflash_sector_size
;
2580 /* Program section size is equal to sector size by default */
2584 k_chip
->num_pflash_blocks
= num_blocks
;
2585 k_chip
->num_nvm_blocks
= 0;
2587 k_chip
->num_pflash_blocks
= (num_blocks
+ 1) / 2;
2588 k_chip
->num_nvm_blocks
= num_blocks
- k_chip
->num_pflash_blocks
;
2591 if (use_nvm_marking
) {
2592 nvm_marking
[0] = k_chip
->num_nvm_blocks
? 'X' : 'N';
2593 nvm_marking
[1] = '\0';
2595 nvm_marking
[0] = '\0';
2597 pflash_size_k
= k_chip
->pflash_size
/ 1024;
2598 pflash_size_m
= pflash_size_k
/ 1024;
2600 snprintf(flash_marking
, sizeof(flash_marking
), "%s%" PRIu32
"M0xxx", nvm_marking
, pflash_size_m
);
2602 snprintf(flash_marking
, sizeof(flash_marking
), "%s%" PRIu32
"xxx", nvm_marking
, pflash_size_k
);
2604 snprintf(k_chip
->name
, sizeof(k_chip
->name
), name
, flash_marking
);
2605 LOG_INFO("Kinetis %s detected: %u flash blocks", k_chip
->name
, num_blocks
);
2606 LOG_INFO("%u PFlash banks: %" PRIu32
"k total", k_chip
->num_pflash_blocks
, pflash_size_k
);
2607 if (k_chip
->num_nvm_blocks
) {
2608 nvm_size_k
= k_chip
->nvm_size
/ 1024;
2609 dflash_size_k
= k_chip
->dflash_size
/ 1024;
2610 LOG_INFO("%u FlexNVM banks: %" PRIu32
"k total, %" PRIu32
"k available as data flash, %" PRIu32
"bytes FlexRAM",
2611 k_chip
->num_nvm_blocks
, nvm_size_k
, dflash_size_k
, ee_size
);
2614 k_chip
->probed
= true;
2617 kinetis_create_missing_banks(k_chip
);
2622 static int kinetis_probe(struct flash_bank
*bank
)
2625 uint8_t fcfg2_maxaddr0
, fcfg2_pflsh
, fcfg2_maxaddr1
;
2626 unsigned num_blocks
, first_nvm_bank
;
2628 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
2629 struct kinetis_chip
*k_chip
;
2632 k_chip
= k_bank
->k_chip
;
2634 k_bank
->probed
= false;
2636 if (!k_chip
->probed
) {
2637 result
= kinetis_probe_chip(k_chip
);
2638 if (result
!= ERROR_OK
)
2642 num_blocks
= k_chip
->num_pflash_blocks
+ k_chip
->num_nvm_blocks
;
2643 first_nvm_bank
= k_chip
->num_pflash_blocks
;
2645 if (k_bank
->bank_number
< k_chip
->num_pflash_blocks
) {
2646 /* pflash, banks start at address zero */
2647 k_bank
->flash_class
= FC_PFLASH
;
2648 bank
->size
= (k_chip
->pflash_size
/ k_chip
->num_pflash_blocks
);
2649 bank
->base
= k_chip
->pflash_base
+ bank
->size
* k_bank
->bank_number
;
2650 k_bank
->prog_base
= 0x00000000 + bank
->size
* k_bank
->bank_number
;
2651 k_bank
->sector_size
= k_chip
->pflash_sector_size
;
2652 /* pflash is divided into 32 protection areas for
2653 * parts with more than 32K of PFlash. For parts with
2654 * less the protection unit is set to 1024 bytes */
2655 k_bank
->protection_size
= MAX(k_chip
->pflash_size
/ 32, 1024);
2656 bank
->num_prot_blocks
= bank
->size
/ k_bank
->protection_size
;
2657 k_bank
->protection_block
= bank
->num_prot_blocks
* k_bank
->bank_number
;
2659 size_k
= bank
->size
/ 1024;
2660 LOG_DEBUG("Kinetis bank %u: %" PRIu32
"k PFlash, FTFx base 0x%08" PRIx32
", sect %u",
2661 k_bank
->bank_number
, size_k
, k_bank
->prog_base
, k_bank
->sector_size
);
2663 } else if (k_bank
->bank_number
< num_blocks
) {
2664 /* nvm, banks start at address 0x10000000 */
2665 unsigned nvm_ord
= k_bank
->bank_number
- first_nvm_bank
;
2668 k_bank
->flash_class
= FC_FLEX_NVM
;
2669 bank
->size
= k_chip
->nvm_size
/ k_chip
->num_nvm_blocks
;
2670 bank
->base
= k_chip
->nvm_base
+ bank
->size
* nvm_ord
;
2671 k_bank
->prog_base
= 0x00800000 + bank
->size
* nvm_ord
;
2672 k_bank
->sector_size
= k_chip
->nvm_sector_size
;
2673 if (k_chip
->dflash_size
== 0) {
2674 k_bank
->protection_size
= 0;
2676 for (i
= k_chip
->dflash_size
; ~i
& 1; i
>>= 1)
2679 k_bank
->protection_size
= k_chip
->dflash_size
/ 8; /* data flash size = 2^^n */
2681 k_bank
->protection_size
= k_chip
->nvm_size
/ 8; /* TODO: verify on SF1, not documented in RM */
2683 bank
->num_prot_blocks
= 8 / k_chip
->num_nvm_blocks
;
2684 k_bank
->protection_block
= bank
->num_prot_blocks
* nvm_ord
;
2686 /* EEPROM backup part of FlexNVM is not accessible, use dflash_size as a limit */
2687 if (k_chip
->dflash_size
> bank
->size
* nvm_ord
)
2688 limit
= k_chip
->dflash_size
- bank
->size
* nvm_ord
;
2692 if (bank
->size
> limit
) {
2694 LOG_DEBUG("FlexNVM bank %d limited to 0x%08" PRIx32
" due to active EEPROM backup",
2695 k_bank
->bank_number
, limit
);
2698 size_k
= bank
->size
/ 1024;
2699 LOG_DEBUG("Kinetis bank %u: %" PRIu32
"k FlexNVM, FTFx base 0x%08" PRIx32
", sect %u",
2700 k_bank
->bank_number
, size_k
, k_bank
->prog_base
, k_bank
->sector_size
);
2703 LOG_ERROR("Cannot determine parameters for bank %d, only %d banks on device",
2704 k_bank
->bank_number
, num_blocks
);
2705 return ERROR_FLASH_BANK_INVALID
;
2708 fcfg2_pflsh
= (uint8_t)((k_chip
->sim_fcfg2
>> 23) & 0x01);
2709 fcfg2_maxaddr0
= (uint8_t)((k_chip
->sim_fcfg2
>> 24) & 0x7f);
2710 fcfg2_maxaddr1
= (uint8_t)((k_chip
->sim_fcfg2
>> 16) & 0x7f);
2712 if (k_bank
->bank_number
== 0 && k_chip
->fcfg2_maxaddr0_shifted
!= bank
->size
)
2713 LOG_WARNING("MAXADDR0 0x%02" PRIx8
" check failed,"
2714 " please report to OpenOCD mailing list", fcfg2_maxaddr0
);
2717 if (k_bank
->bank_number
== 1 && k_chip
->fcfg2_maxaddr1_shifted
!= bank
->size
)
2718 LOG_WARNING("MAXADDR1 0x%02" PRIx8
" check failed,"
2719 " please report to OpenOCD mailing list", fcfg2_maxaddr1
);
2721 if (k_bank
->bank_number
== first_nvm_bank
2722 && k_chip
->fcfg2_maxaddr1_shifted
!= k_chip
->dflash_size
)
2723 LOG_WARNING("FlexNVM MAXADDR1 0x%02" PRIx8
" check failed,"
2724 " please report to OpenOCD mailing list", fcfg2_maxaddr1
);
2727 if (bank
->sectors
) {
2728 free(bank
->sectors
);
2729 bank
->sectors
= NULL
;
2731 if (bank
->prot_blocks
) {
2732 free(bank
->prot_blocks
);
2733 bank
->prot_blocks
= NULL
;
2736 if (k_bank
->sector_size
== 0) {
2737 LOG_ERROR("Unknown sector size for bank %d", bank
->bank_number
);
2738 return ERROR_FLASH_BANK_INVALID
;
2741 bank
->num_sectors
= bank
->size
/ k_bank
->sector_size
;
2743 if (bank
->num_sectors
> 0) {
2744 /* FlexNVM bank can be used for EEPROM backup therefore zero sized */
2745 bank
->sectors
= alloc_block_array(0, k_bank
->sector_size
, bank
->num_sectors
);
2749 bank
->prot_blocks
= alloc_block_array(0, k_bank
->protection_size
, bank
->num_prot_blocks
);
2750 if (!bank
->prot_blocks
)
2754 bank
->num_prot_blocks
= 0;
2757 k_bank
->probed
= true;
2762 static int kinetis_auto_probe(struct flash_bank
*bank
)
2764 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
2766 if (k_bank
&& k_bank
->probed
)
2769 return kinetis_probe(bank
);
2772 static int kinetis_info(struct flash_bank
*bank
, char *buf
, int buf_size
)
2774 const char *bank_class_names
[] = {
2775 "(ANY)", "PFlash", "FlexNVM", "FlexRAM"
2778 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
2779 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
2780 uint32_t size_k
= bank
->size
/ 1024;
2782 snprintf(buf
, buf_size
,
2783 "%s %s: %" PRIu32
"k %s bank %s at " TARGET_ADDR_FMT
,
2784 bank
->driver
->name
, k_chip
->name
,
2785 size_k
, bank_class_names
[k_bank
->flash_class
],
2786 bank
->name
, bank
->base
);
2791 static int kinetis_blank_check(struct flash_bank
*bank
)
2793 struct kinetis_flash_bank
*k_bank
= bank
->driver_priv
;
2794 struct kinetis_chip
*k_chip
= k_bank
->k_chip
;
2797 /* suprisingly blank check does not work in VLPR and HSRUN modes */
2798 result
= kinetis_check_run_mode(k_chip
);
2799 if (result
!= ERROR_OK
)
2802 /* reset error flags */
2803 result
= kinetis_ftfx_prepare(bank
->target
);
2804 if (result
!= ERROR_OK
)
2807 if (k_bank
->flash_class
== FC_PFLASH
|| k_bank
->flash_class
== FC_FLEX_NVM
) {
2808 bool block_dirty
= true;
2809 bool use_block_cmd
= !(k_chip
->flash_support
& FS_NO_CMD_BLOCKSTAT
);
2812 if (use_block_cmd
&& k_bank
->flash_class
== FC_FLEX_NVM
) {
2813 uint8_t fcfg1_depart
= (uint8_t)((k_chip
->sim_fcfg1
>> 8) & 0x0f);
2814 /* block operation cannot be used on FlexNVM when EEPROM backup partition is set */
2815 if (fcfg1_depart
!= 0xf && fcfg1_depart
!= 0)
2816 use_block_cmd
= false;
2819 if (use_block_cmd
) {
2820 /* check if whole bank is blank */
2821 result
= kinetis_ftfx_command(bank
->target
, FTFx_CMD_BLOCKSTAT
, k_bank
->prog_base
,
2822 0, 0, 0, 0, 0, 0, 0, 0, &ftfx_fstat
);
2824 if (result
!= ERROR_OK
)
2825 kinetis_ftfx_clear_error(bank
->target
);
2826 else if ((ftfx_fstat
& 0x01) == 0)
2827 block_dirty
= false;
2831 /* the whole bank is not erased, check sector-by-sector */
2833 for (i
= 0; i
< bank
->num_sectors
; i
++) {
2835 result
= kinetis_ftfx_command(bank
->target
, FTFx_CMD_SECTSTAT
,
2836 k_bank
->prog_base
+ bank
->sectors
[i
].offset
,
2837 1, 0, 0, 0, 0, 0, 0, 0, &ftfx_fstat
);
2839 if (result
== ERROR_OK
) {
2840 bank
->sectors
[i
].is_erased
= !(ftfx_fstat
& 0x01);
2842 LOG_DEBUG("Ignoring errored PFlash sector blank-check");
2843 kinetis_ftfx_clear_error(bank
->target
);
2844 bank
->sectors
[i
].is_erased
= -1;
2848 /* the whole bank is erased, update all sectors */
2850 for (i
= 0; i
< bank
->num_sectors
; i
++)
2851 bank
->sectors
[i
].is_erased
= 1;
2854 LOG_WARNING("kinetis_blank_check not supported yet for FlexRAM");
2855 return ERROR_FLASH_OPERATION_FAILED
;
2862 COMMAND_HANDLER(kinetis_nvm_partition
)
2866 unsigned num_blocks
, first_nvm_bank
;
2867 unsigned long par
, log2
= 0, ee1
= 0, ee2
= 0;
2868 enum { SHOW_INFO
, DF_SIZE
, EEBKP_SIZE
} sz_type
= SHOW_INFO
;
2870 uint8_t load_flex_ram
= 1;
2871 uint8_t ee_size_code
= 0x3f;
2872 uint8_t flex_nvm_partition_code
= 0;
2873 uint8_t ee_split
= 3;
2874 struct target
*target
= get_current_target(CMD_CTX
);
2875 struct kinetis_chip
*k_chip
;
2878 k_chip
= kinetis_get_chip(target
);
2880 if (CMD_ARGC
>= 2) {
2881 if (strcmp(CMD_ARGV
[0], "dataflash") == 0)
2883 else if (strcmp(CMD_ARGV
[0], "eebkp") == 0)
2884 sz_type
= EEBKP_SIZE
;
2886 par
= strtoul(CMD_ARGV
[1], NULL
, 10);
2887 while (par
>> (log2
+ 3))
2892 if (k_chip
== NULL
) {
2893 LOG_ERROR("Chip not probed.");
2896 result
= target_read_u32(target
, k_chip
->sim_base
+ SIM_FCFG1_OFFSET
, &sim_fcfg1
);
2897 if (result
!= ERROR_OK
)
2900 flex_nvm_partition_code
= (uint8_t)((sim_fcfg1
>> 8) & 0x0f);
2901 switch (flex_nvm_partition_code
) {
2903 command_print(CMD
, "No EEPROM backup, data flash only");
2911 command_print(CMD
, "EEPROM backup %d KB", 4 << flex_nvm_partition_code
);
2914 command_print(CMD
, "No data flash, EEPROM backup only");
2922 command_print(CMD
, "data flash %d KB", 4 << (flex_nvm_partition_code
& 7));
2925 command_print(CMD
, "No EEPROM backup, data flash only (DEPART not set)");
2928 command_print(CMD
, "Unsupported EEPROM backup size code 0x%02" PRIx8
, flex_nvm_partition_code
);
2933 flex_nvm_partition_code
= 0x8 | log2
;
2937 flex_nvm_partition_code
= log2
;
2942 ee1
= ee2
= strtoul(CMD_ARGV
[2], NULL
, 10) / 2;
2943 else if (CMD_ARGC
>= 4) {
2944 ee1
= strtoul(CMD_ARGV
[2], NULL
, 10);
2945 ee2
= strtoul(CMD_ARGV
[3], NULL
, 10);
2948 enable
= ee1
+ ee2
> 0;
2950 for (log2
= 2; ; log2
++) {
2951 if (ee1
+ ee2
== (16u << 10) >> log2
)
2953 if (ee1
+ ee2
> (16u << 10) >> log2
|| log2
>= 9) {
2954 LOG_ERROR("Unsupported EEPROM size");
2955 return ERROR_FLASH_OPERATION_FAILED
;
2961 else if (ee1
* 7 == ee2
)
2963 else if (ee1
!= ee2
) {
2964 LOG_ERROR("Unsupported EEPROM sizes ratio");
2965 return ERROR_FLASH_OPERATION_FAILED
;
2968 ee_size_code
= log2
| ee_split
<< 4;
2972 COMMAND_PARSE_ON_OFF(CMD_ARGV
[4], enable
);
2976 LOG_INFO("DEPART 0x%" PRIx8
", EEPROM size code 0x%" PRIx8
,
2977 flex_nvm_partition_code
, ee_size_code
);
2979 result
= kinetis_check_run_mode(k_chip
);
2980 if (result
!= ERROR_OK
)
2983 /* reset error flags */
2984 result
= kinetis_ftfx_prepare(target
);
2985 if (result
!= ERROR_OK
)
2988 result
= kinetis_ftfx_command(target
, FTFx_CMD_PGMPART
, load_flex_ram
,
2989 ee_size_code
, flex_nvm_partition_code
, 0, 0,
2991 if (result
!= ERROR_OK
)
2994 command_print(CMD
, "FlexNVM partition set. Please reset MCU.");
2997 first_nvm_bank
= k_chip
->num_pflash_blocks
;
2998 num_blocks
= k_chip
->num_pflash_blocks
+ k_chip
->num_nvm_blocks
;
2999 for (bank_idx
= first_nvm_bank
; bank_idx
< num_blocks
; bank_idx
++)
3000 k_chip
->banks
[bank_idx
].probed
= false; /* re-probe before next use */
3001 k_chip
->probed
= false;
3004 command_print(CMD
, "FlexNVM banks will be re-probed to set new data flash size.");
3008 COMMAND_HANDLER(kinetis_fcf_source_handler
)
3011 return ERROR_COMMAND_SYNTAX_ERROR
;
3013 if (CMD_ARGC
== 1) {
3014 if (strcmp(CMD_ARGV
[0], "write") == 0)
3015 allow_fcf_writes
= true;
3016 else if (strcmp(CMD_ARGV
[0], "protection") == 0)
3017 allow_fcf_writes
= false;
3019 return ERROR_COMMAND_SYNTAX_ERROR
;
3022 if (allow_fcf_writes
) {
3023 command_print(CMD
, "Arbitrary Flash Configuration Field writes enabled.");
3024 command_print(CMD
, "Protection info writes to FCF disabled.");
3025 LOG_WARNING("BEWARE: incorrect flash configuration may permanently lock the device.");
3027 command_print(CMD
, "Protection info writes to Flash Configuration Field enabled.");
3028 command_print(CMD
, "Arbitrary FCF writes disabled. Mode safe from unwanted locking of the device.");
3034 COMMAND_HANDLER(kinetis_fopt_handler
)
3037 return ERROR_COMMAND_SYNTAX_ERROR
;
3039 if (CMD_ARGC
== 1) {
3040 fcf_fopt
= (uint8_t)strtoul(CMD_ARGV
[0], NULL
, 0);
3041 fcf_fopt_configured
= true;
3043 command_print(CMD
, "FCF_FOPT 0x%02" PRIx8
, fcf_fopt
);
3049 COMMAND_HANDLER(kinetis_create_banks_handler
)
3052 return ERROR_COMMAND_SYNTAX_ERROR
;
3054 create_banks
= true;
3060 static const struct command_registration kinetis_security_command_handlers
[] = {
3062 .name
= "check_security",
3063 .mode
= COMMAND_EXEC
,
3064 .help
= "Check status of device security lock",
3066 .handler
= kinetis_check_flash_security_status
,
3070 .mode
= COMMAND_EXEC
,
3071 .help
= "Issue a halt via the MDM-AP",
3073 .handler
= kinetis_mdm_halt
,
3076 .name
= "mass_erase",
3077 .mode
= COMMAND_EXEC
,
3078 .help
= "Issue a complete flash erase via the MDM-AP",
3080 .handler
= kinetis_mdm_mass_erase
,
3084 .mode
= COMMAND_EXEC
,
3085 .help
= "Issue a reset via the MDM-AP",
3087 .handler
= kinetis_mdm_reset
,
3089 COMMAND_REGISTRATION_DONE
3092 static const struct command_registration kinetis_exec_command_handlers
[] = {
3095 .mode
= COMMAND_ANY
,
3096 .help
= "MDM-AP command group",
3098 .chain
= kinetis_security_command_handlers
,
3101 .name
= "disable_wdog",
3102 .mode
= COMMAND_EXEC
,
3103 .help
= "Disable the watchdog timer",
3105 .handler
= kinetis_disable_wdog_handler
,
3108 .name
= "nvm_partition",
3109 .mode
= COMMAND_EXEC
,
3110 .help
= "Show/set data flash or EEPROM backup size in kilobytes,"
3111 " set two EEPROM sizes in bytes and FlexRAM loading during reset",
3112 .usage
= "('info'|'dataflash' size|'eebkp' size) [eesize1 eesize2] ['on'|'off']",
3113 .handler
= kinetis_nvm_partition
,
3116 .name
= "fcf_source",
3117 .mode
= COMMAND_EXEC
,
3118 .help
= "Use protection as a source for Flash Configuration Field or allow writing arbitrary values to the FCF"
3119 " Mode 'protection' is safe from unwanted locking of the device.",
3120 .usage
= "['protection'|'write']",
3121 .handler
= kinetis_fcf_source_handler
,
3125 .mode
= COMMAND_EXEC
,
3126 .help
= "FCF_FOPT value source in 'kinetis fcf_source protection' mode",
3128 .handler
= kinetis_fopt_handler
,
3131 .name
= "create_banks",
3132 .mode
= COMMAND_CONFIG
,
3133 .help
= "Driver creates additional banks if device with two/four flash blocks is probed",
3134 .handler
= kinetis_create_banks_handler
,
3137 COMMAND_REGISTRATION_DONE
3140 static const struct command_registration kinetis_command_handler
[] = {
3143 .mode
= COMMAND_ANY
,
3144 .help
= "Kinetis flash controller commands",
3146 .chain
= kinetis_exec_command_handlers
,
3148 COMMAND_REGISTRATION_DONE
3153 const struct flash_driver kinetis_flash
= {
3155 .commands
= kinetis_command_handler
,
3156 .flash_bank_command
= kinetis_flash_bank_command
,
3157 .erase
= kinetis_erase
,
3158 .protect
= kinetis_protect
,
3159 .write
= kinetis_write
,
3160 .read
= default_flash_read
,
3161 .probe
= kinetis_probe
,
3162 .auto_probe
= kinetis_auto_probe
,
3163 .erase_check
= kinetis_blank_check
,
3164 .protect_check
= kinetis_protect_check
,
3165 .info
= kinetis_info
,
3166 .free_driver_priv
= kinetis_free_driver_priv
,