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arm_adi_v5: Do not ignore register polling timeout
[openocd.git] / src / target / arm_adi_v5.c
1 /***************************************************************************
2 * Copyright (C) 2006 by Magnus Lundin *
3 * lundin@mlu.mine.nu *
4 * *
5 * Copyright (C) 2008 by Spencer Oliver *
6 * spen@spen-soft.co.uk *
7 * *
8 * Copyright (C) 2009-2010 by Oyvind Harboe *
9 * oyvind.harboe@zylin.com *
10 * *
11 * Copyright (C) 2009-2010 by David Brownell *
12 * *
13 * Copyright (C) 2013 by Andreas Fritiofson *
14 * andreas.fritiofson@gmail.com *
15 * *
16 * This program is free software; you can redistribute it and/or modify *
17 * it under the terms of the GNU General Public License as published by *
18 * the Free Software Foundation; either version 2 of the License, or *
19 * (at your option) any later version. *
20 * *
21 * This program is distributed in the hope that it will be useful, *
22 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
23 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
24 * GNU General Public License for more details. *
25 * *
26 * You should have received a copy of the GNU General Public License *
27 * along with this program; if not, write to the *
28 * Free Software Foundation, Inc., *
29 * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. *
30 ***************************************************************************/
31
32 /**
33 * @file
34 * This file implements support for the ARM Debug Interface version 5 (ADIv5)
35 * debugging architecture. Compared with previous versions, this includes
36 * a low pin-count Serial Wire Debug (SWD) alternative to JTAG for message
37 * transport, and focusses on memory mapped resources as defined by the
38 * CoreSight architecture.
39 *
40 * A key concept in ADIv5 is the Debug Access Port, or DAP. A DAP has two
41 * basic components: a Debug Port (DP) transporting messages to and from a
42 * debugger, and an Access Port (AP) accessing resources. Three types of DP
43 * are defined. One uses only JTAG for communication, and is called JTAG-DP.
44 * One uses only SWD for communication, and is called SW-DP. The third can
45 * use either SWD or JTAG, and is called SWJ-DP. The most common type of AP
46 * is used to access memory mapped resources and is called a MEM-AP. Also a
47 * JTAG-AP is also defined, bridging to JTAG resources; those are uncommon.
48 *
49 * This programming interface allows DAP pipelined operations through a
50 * transaction queue. This primarily affects AP operations (such as using
51 * a MEM-AP to access memory or registers). If the current transaction has
52 * not finished by the time the next one must begin, and the ORUNDETECT bit
53 * is set in the DP_CTRL_STAT register, the SSTICKYORUN status is set and
54 * further AP operations will fail. There are two basic methods to avoid
55 * such overrun errors. One involves polling for status instead of using
56 * transaction piplining. The other involves adding delays to ensure the
57 * AP has enough time to complete one operation before starting the next
58 * one. (For JTAG these delays are controlled by memaccess_tck.)
59 */
60
61 /*
62 * Relevant specifications from ARM include:
63 *
64 * ARM(tm) Debug Interface v5 Architecture Specification ARM IHI 0031A
65 * CoreSight(tm) v1.0 Architecture Specification ARM IHI 0029B
66 *
67 * CoreSight(tm) DAP-Lite TRM, ARM DDI 0316D
68 * Cortex-M3(tm) TRM, ARM DDI 0337G
69 */
70
71 #ifdef HAVE_CONFIG_H
72 #include "config.h"
73 #endif
74
75 #include "jtag/interface.h"
76 #include "arm.h"
77 #include "arm_adi_v5.h"
78 #include <helper/time_support.h>
79
80 /* ARM ADI Specification requires at least 10 bits used for TAR autoincrement */
81
82 /*
83 uint32_t tar_block_size(uint32_t address)
84 Return the largest block starting at address that does not cross a tar block size alignment boundary
85 */
86 static uint32_t max_tar_block_size(uint32_t tar_autoincr_block, uint32_t address)
87 {
88 return tar_autoincr_block - ((tar_autoincr_block - 1) & address);
89 }
90
91 /***************************************************************************
92 * *
93 * DP and MEM-AP register access through APACC and DPACC *
94 * *
95 ***************************************************************************/
96
97 /**
98 * Select one of the APs connected to the specified DAP. The
99 * selection is implicitly used with future AP transactions.
100 * This is a NOP if the specified AP is already selected.
101 *
102 * @param dap The DAP
103 * @param apsel Number of the AP to (implicitly) use with further
104 * transactions. This normally identifies a MEM-AP.
105 */
106 void dap_ap_select(struct adiv5_dap *dap, uint8_t ap)
107 {
108 uint32_t new_ap = (ap << 24) & 0xFF000000;
109
110 if (new_ap != dap->ap_current) {
111 dap->ap_current = new_ap;
112 /* Switching AP invalidates cached values.
113 * Values MUST BE UPDATED BEFORE AP ACCESS.
114 */
115 dap->ap_bank_value = -1;
116 dap->ap_csw_value = -1;
117 dap->ap_tar_value = -1;
118 }
119 }
120
121 static int dap_setup_accessport_csw(struct adiv5_dap *dap, uint32_t csw)
122 {
123 csw = csw | CSW_DBGSWENABLE | CSW_MASTER_DEBUG | CSW_HPROT |
124 dap->apcsw[dap->ap_current >> 24];
125
126 if (csw != dap->ap_csw_value) {
127 /* LOG_DEBUG("DAP: Set CSW %x",csw); */
128 int retval = dap_queue_ap_write(dap, AP_REG_CSW, csw);
129 if (retval != ERROR_OK)
130 return retval;
131 dap->ap_csw_value = csw;
132 }
133 return ERROR_OK;
134 }
135
136 static int dap_setup_accessport_tar(struct adiv5_dap *dap, uint32_t tar)
137 {
138 if (tar != dap->ap_tar_value || dap->ap_csw_value & CSW_ADDRINC_MASK) {
139 /* LOG_DEBUG("DAP: Set TAR %x",tar); */
140 int retval = dap_queue_ap_write(dap, AP_REG_TAR, tar);
141 if (retval != ERROR_OK)
142 return retval;
143 dap->ap_tar_value = tar;
144 }
145 return ERROR_OK;
146 }
147
148 /**
149 * Queue transactions setting up transfer parameters for the
150 * currently selected MEM-AP.
151 *
152 * Subsequent transfers using registers like AP_REG_DRW or AP_REG_BD2
153 * initiate data reads or writes using memory or peripheral addresses.
154 * If the CSW is configured for it, the TAR may be automatically
155 * incremented after each transfer.
156 *
157 * @todo Rename to reflect it being specifically a MEM-AP function.
158 *
159 * @param dap The DAP connected to the MEM-AP.
160 * @param csw MEM-AP Control/Status Word (CSW) register to assign. If this
161 * matches the cached value, the register is not changed.
162 * @param tar MEM-AP Transfer Address Register (TAR) to assign. If this
163 * matches the cached address, the register is not changed.
164 *
165 * @return ERROR_OK if the transaction was properly queued, else a fault code.
166 */
167 int dap_setup_accessport(struct adiv5_dap *dap, uint32_t csw, uint32_t tar)
168 {
169 int retval;
170 retval = dap_setup_accessport_csw(dap, csw);
171 if (retval != ERROR_OK)
172 return retval;
173 retval = dap_setup_accessport_tar(dap, tar);
174 if (retval != ERROR_OK)
175 return retval;
176 return ERROR_OK;
177 }
178
179 /**
180 * Asynchronous (queued) read of a word from memory or a system register.
181 *
182 * @param dap The DAP connected to the MEM-AP performing the read.
183 * @param address Address of the 32-bit word to read; it must be
184 * readable by the currently selected MEM-AP.
185 * @param value points to where the word will be stored when the
186 * transaction queue is flushed (assuming no errors).
187 *
188 * @return ERROR_OK for success. Otherwise a fault code.
189 */
190 int mem_ap_read_u32(struct adiv5_dap *dap, uint32_t address,
191 uint32_t *value)
192 {
193 int retval;
194
195 /* Use banked addressing (REG_BDx) to avoid some link traffic
196 * (updating TAR) when reading several consecutive addresses.
197 */
198 retval = dap_setup_accessport(dap, CSW_32BIT | CSW_ADDRINC_OFF,
199 address & 0xFFFFFFF0);
200 if (retval != ERROR_OK)
201 return retval;
202
203 return dap_queue_ap_read(dap, AP_REG_BD0 | (address & 0xC), value);
204 }
205
206 /**
207 * Synchronous read of a word from memory or a system register.
208 * As a side effect, this flushes any queued transactions.
209 *
210 * @param dap The DAP connected to the MEM-AP performing the read.
211 * @param address Address of the 32-bit word to read; it must be
212 * readable by the currently selected MEM-AP.
213 * @param value points to where the result will be stored.
214 *
215 * @return ERROR_OK for success; *value holds the result.
216 * Otherwise a fault code.
217 */
218 int mem_ap_read_atomic_u32(struct adiv5_dap *dap, uint32_t address,
219 uint32_t *value)
220 {
221 int retval;
222
223 retval = mem_ap_read_u32(dap, address, value);
224 if (retval != ERROR_OK)
225 return retval;
226
227 return dap_run(dap);
228 }
229
230 /**
231 * Asynchronous (queued) write of a word to memory or a system register.
232 *
233 * @param dap The DAP connected to the MEM-AP.
234 * @param address Address to be written; it must be writable by
235 * the currently selected MEM-AP.
236 * @param value Word that will be written to the address when transaction
237 * queue is flushed (assuming no errors).
238 *
239 * @return ERROR_OK for success. Otherwise a fault code.
240 */
241 int mem_ap_write_u32(struct adiv5_dap *dap, uint32_t address,
242 uint32_t value)
243 {
244 int retval;
245
246 /* Use banked addressing (REG_BDx) to avoid some link traffic
247 * (updating TAR) when writing several consecutive addresses.
248 */
249 retval = dap_setup_accessport(dap, CSW_32BIT | CSW_ADDRINC_OFF,
250 address & 0xFFFFFFF0);
251 if (retval != ERROR_OK)
252 return retval;
253
254 return dap_queue_ap_write(dap, AP_REG_BD0 | (address & 0xC),
255 value);
256 }
257
258 /**
259 * Synchronous write of a word to memory or a system register.
260 * As a side effect, this flushes any queued transactions.
261 *
262 * @param dap The DAP connected to the MEM-AP.
263 * @param address Address to be written; it must be writable by
264 * the currently selected MEM-AP.
265 * @param value Word that will be written.
266 *
267 * @return ERROR_OK for success; the data was written. Otherwise a fault code.
268 */
269 int mem_ap_write_atomic_u32(struct adiv5_dap *dap, uint32_t address,
270 uint32_t value)
271 {
272 int retval = mem_ap_write_u32(dap, address, value);
273
274 if (retval != ERROR_OK)
275 return retval;
276
277 return dap_run(dap);
278 }
279
280 /**
281 * Synchronous write of a block of memory, using a specific access size.
282 *
283 * @param dap The DAP connected to the MEM-AP.
284 * @param buffer The data buffer to write. No particular alignment is assumed.
285 * @param size Which access size to use, in bytes. 1, 2 or 4.
286 * @param count The number of writes to do (in size units, not bytes).
287 * @param address Address to be written; it must be writable by the currently selected MEM-AP.
288 * @param addrinc Whether the target address should be increased for each write or not. This
289 * should normally be true, except when writing to e.g. a FIFO.
290 * @return ERROR_OK on success, otherwise an error code.
291 */
292 int mem_ap_write(struct adiv5_dap *dap, const uint8_t *buffer, uint32_t size, uint32_t count,
293 uint32_t address, bool addrinc)
294 {
295 size_t nbytes = size * count;
296 const uint32_t csw_addrincr = addrinc ? CSW_ADDRINC_SINGLE : CSW_ADDRINC_OFF;
297 uint32_t csw_size;
298 uint32_t addr_xor;
299 int retval;
300
301 /* TI BE-32 Quirks mode:
302 * Writes on big-endian TMS570 behave very strangely. Observed behavior:
303 * size write address bytes written in order
304 * 4 TAR ^ 0 (val >> 24), (val >> 16), (val >> 8), (val)
305 * 2 TAR ^ 2 (val >> 8), (val)
306 * 1 TAR ^ 3 (val)
307 * For example, if you attempt to write a single byte to address 0, the processor
308 * will actually write a byte to address 3.
309 *
310 * To make writes of size < 4 work as expected, we xor a value with the address before
311 * setting the TAP, and we set the TAP after every transfer rather then relying on
312 * address increment. */
313
314 if (size == 4) {
315 csw_size = CSW_32BIT;
316 addr_xor = 0;
317 } else if (size == 2) {
318 csw_size = CSW_16BIT;
319 addr_xor = dap->ti_be_32_quirks ? 2 : 0;
320 } else if (size == 1) {
321 csw_size = CSW_8BIT;
322 addr_xor = dap->ti_be_32_quirks ? 3 : 0;
323 } else {
324 return ERROR_TARGET_UNALIGNED_ACCESS;
325 }
326
327 if (dap->unaligned_access_bad && (address % size != 0))
328 return ERROR_TARGET_UNALIGNED_ACCESS;
329
330 retval = dap_setup_accessport_tar(dap, address ^ addr_xor);
331 if (retval != ERROR_OK)
332 return retval;
333
334 while (nbytes > 0) {
335 uint32_t this_size = size;
336
337 /* Select packed transfer if possible */
338 if (addrinc && dap->packed_transfers && nbytes >= 4
339 && max_tar_block_size(dap->tar_autoincr_block, address) >= 4) {
340 this_size = 4;
341 retval = dap_setup_accessport_csw(dap, csw_size | CSW_ADDRINC_PACKED);
342 } else {
343 retval = dap_setup_accessport_csw(dap, csw_size | csw_addrincr);
344 }
345
346 if (retval != ERROR_OK)
347 break;
348
349 /* How many source bytes each transfer will consume, and their location in the DRW,
350 * depends on the type of transfer and alignment. See ARM document IHI0031C. */
351 uint32_t outvalue = 0;
352 if (dap->ti_be_32_quirks) {
353 switch (this_size) {
354 case 4:
355 outvalue |= (uint32_t)*buffer++ << 8 * (3 ^ (address++ & 3) ^ addr_xor);
356 outvalue |= (uint32_t)*buffer++ << 8 * (3 ^ (address++ & 3) ^ addr_xor);
357 outvalue |= (uint32_t)*buffer++ << 8 * (3 ^ (address++ & 3) ^ addr_xor);
358 outvalue |= (uint32_t)*buffer++ << 8 * (3 ^ (address++ & 3) ^ addr_xor);
359 break;
360 case 2:
361 outvalue |= (uint32_t)*buffer++ << 8 * (1 ^ (address++ & 3) ^ addr_xor);
362 outvalue |= (uint32_t)*buffer++ << 8 * (1 ^ (address++ & 3) ^ addr_xor);
363 break;
364 case 1:
365 outvalue |= (uint32_t)*buffer++ << 8 * (0 ^ (address++ & 3) ^ addr_xor);
366 break;
367 }
368 } else {
369 switch (this_size) {
370 case 4:
371 outvalue |= (uint32_t)*buffer++ << 8 * (address++ & 3);
372 outvalue |= (uint32_t)*buffer++ << 8 * (address++ & 3);
373 case 2:
374 outvalue |= (uint32_t)*buffer++ << 8 * (address++ & 3);
375 case 1:
376 outvalue |= (uint32_t)*buffer++ << 8 * (address++ & 3);
377 }
378 }
379
380 nbytes -= this_size;
381
382 retval = dap_queue_ap_write(dap, AP_REG_DRW, outvalue);
383 if (retval != ERROR_OK)
384 break;
385
386 /* Rewrite TAR if it wrapped or we're xoring addresses */
387 if (addrinc && (addr_xor || (address % dap->tar_autoincr_block < size && nbytes > 0))) {
388 retval = dap_setup_accessport_tar(dap, address ^ addr_xor);
389 if (retval != ERROR_OK)
390 break;
391 }
392 }
393
394 /* REVISIT: Might want to have a queued version of this function that does not run. */
395 if (retval == ERROR_OK)
396 retval = dap_run(dap);
397
398 if (retval != ERROR_OK) {
399 uint32_t tar;
400 if (dap_queue_ap_read(dap, AP_REG_TAR, &tar) == ERROR_OK
401 && dap_run(dap) == ERROR_OK)
402 LOG_ERROR("Failed to write memory at 0x%08"PRIx32, tar);
403 else
404 LOG_ERROR("Failed to write memory and, additionally, failed to find out where");
405 }
406
407 return retval;
408 }
409
410 /**
411 * Synchronous read of a block of memory, using a specific access size.
412 *
413 * @param dap The DAP connected to the MEM-AP.
414 * @param buffer The data buffer to receive the data. No particular alignment is assumed.
415 * @param size Which access size to use, in bytes. 1, 2 or 4.
416 * @param count The number of reads to do (in size units, not bytes).
417 * @param address Address to be read; it must be readable by the currently selected MEM-AP.
418 * @param addrinc Whether the target address should be increased after each read or not. This
419 * should normally be true, except when reading from e.g. a FIFO.
420 * @return ERROR_OK on success, otherwise an error code.
421 */
422 int mem_ap_read(struct adiv5_dap *dap, uint8_t *buffer, uint32_t size, uint32_t count,
423 uint32_t adr, bool addrinc)
424 {
425 size_t nbytes = size * count;
426 const uint32_t csw_addrincr = addrinc ? CSW_ADDRINC_SINGLE : CSW_ADDRINC_OFF;
427 uint32_t csw_size;
428 uint32_t address = adr;
429 int retval;
430
431 /* TI BE-32 Quirks mode:
432 * Reads on big-endian TMS570 behave strangely differently than writes.
433 * They read from the physical address requested, but with DRW byte-reversed.
434 * For example, a byte read from address 0 will place the result in the high bytes of DRW.
435 * Also, packed 8-bit and 16-bit transfers seem to sometimes return garbage in some bytes,
436 * so avoid them. */
437
438 if (size == 4)
439 csw_size = CSW_32BIT;
440 else if (size == 2)
441 csw_size = CSW_16BIT;
442 else if (size == 1)
443 csw_size = CSW_8BIT;
444 else
445 return ERROR_TARGET_UNALIGNED_ACCESS;
446
447 if (dap->unaligned_access_bad && (adr % size != 0))
448 return ERROR_TARGET_UNALIGNED_ACCESS;
449
450 /* Allocate buffer to hold the sequence of DRW reads that will be made. This is a significant
451 * over-allocation if packed transfers are going to be used, but determining the real need at
452 * this point would be messy. */
453 uint32_t *read_buf = malloc(count * sizeof(uint32_t));
454 uint32_t *read_ptr = read_buf;
455 if (read_buf == NULL) {
456 LOG_ERROR("Failed to allocate read buffer");
457 return ERROR_FAIL;
458 }
459
460 retval = dap_setup_accessport_tar(dap, address);
461 if (retval != ERROR_OK) {
462 free(read_buf);
463 return retval;
464 }
465
466 /* Queue up all reads. Each read will store the entire DRW word in the read buffer. How many
467 * useful bytes it contains, and their location in the word, depends on the type of transfer
468 * and alignment. */
469 while (nbytes > 0) {
470 uint32_t this_size = size;
471
472 /* Select packed transfer if possible */
473 if (addrinc && dap->packed_transfers && nbytes >= 4
474 && max_tar_block_size(dap->tar_autoincr_block, address) >= 4) {
475 this_size = 4;
476 retval = dap_setup_accessport_csw(dap, csw_size | CSW_ADDRINC_PACKED);
477 } else {
478 retval = dap_setup_accessport_csw(dap, csw_size | csw_addrincr);
479 }
480 if (retval != ERROR_OK)
481 break;
482
483 retval = dap_queue_ap_read(dap, AP_REG_DRW, read_ptr++);
484 if (retval != ERROR_OK)
485 break;
486
487 nbytes -= this_size;
488 address += this_size;
489
490 /* Rewrite TAR if it wrapped */
491 if (addrinc && address % dap->tar_autoincr_block < size && nbytes > 0) {
492 retval = dap_setup_accessport_tar(dap, address);
493 if (retval != ERROR_OK)
494 break;
495 }
496 }
497
498 if (retval == ERROR_OK)
499 retval = dap_run(dap);
500
501 /* Restore state */
502 address = adr;
503 nbytes = size * count;
504 read_ptr = read_buf;
505
506 /* If something failed, read TAR to find out how much data was successfully read, so we can
507 * at least give the caller what we have. */
508 if (retval != ERROR_OK) {
509 uint32_t tar;
510 if (dap_queue_ap_read(dap, AP_REG_TAR, &tar) == ERROR_OK
511 && dap_run(dap) == ERROR_OK) {
512 LOG_ERROR("Failed to read memory at 0x%08"PRIx32, tar);
513 if (nbytes > tar - address)
514 nbytes = tar - address;
515 } else {
516 LOG_ERROR("Failed to read memory and, additionally, failed to find out where");
517 nbytes = 0;
518 }
519 }
520
521 /* Replay loop to populate caller's buffer from the correct word and byte lane */
522 while (nbytes > 0) {
523 uint32_t this_size = size;
524
525 if (addrinc && dap->packed_transfers && nbytes >= 4
526 && max_tar_block_size(dap->tar_autoincr_block, address) >= 4) {
527 this_size = 4;
528 }
529
530 if (dap->ti_be_32_quirks) {
531 switch (this_size) {
532 case 4:
533 *buffer++ = *read_ptr >> 8 * (3 - (address++ & 3));
534 *buffer++ = *read_ptr >> 8 * (3 - (address++ & 3));
535 case 2:
536 *buffer++ = *read_ptr >> 8 * (3 - (address++ & 3));
537 case 1:
538 *buffer++ = *read_ptr >> 8 * (3 - (address++ & 3));
539 }
540 } else {
541 switch (this_size) {
542 case 4:
543 *buffer++ = *read_ptr >> 8 * (address++ & 3);
544 *buffer++ = *read_ptr >> 8 * (address++ & 3);
545 case 2:
546 *buffer++ = *read_ptr >> 8 * (address++ & 3);
547 case 1:
548 *buffer++ = *read_ptr >> 8 * (address++ & 3);
549 }
550 }
551
552 read_ptr++;
553 nbytes -= this_size;
554 }
555
556 free(read_buf);
557 return retval;
558 }
559
560 /*--------------------------------------------------------------------*/
561 /* Wrapping function with selection of AP */
562 /*--------------------------------------------------------------------*/
563 int mem_ap_sel_read_u32(struct adiv5_dap *swjdp, uint8_t ap,
564 uint32_t address, uint32_t *value)
565 {
566 dap_ap_select(swjdp, ap);
567 return mem_ap_read_u32(swjdp, address, value);
568 }
569
570 int mem_ap_sel_write_u32(struct adiv5_dap *swjdp, uint8_t ap,
571 uint32_t address, uint32_t value)
572 {
573 dap_ap_select(swjdp, ap);
574 return mem_ap_write_u32(swjdp, address, value);
575 }
576
577 int mem_ap_sel_read_atomic_u32(struct adiv5_dap *swjdp, uint8_t ap,
578 uint32_t address, uint32_t *value)
579 {
580 dap_ap_select(swjdp, ap);
581 return mem_ap_read_atomic_u32(swjdp, address, value);
582 }
583
584 int mem_ap_sel_write_atomic_u32(struct adiv5_dap *swjdp, uint8_t ap,
585 uint32_t address, uint32_t value)
586 {
587 dap_ap_select(swjdp, ap);
588 return mem_ap_write_atomic_u32(swjdp, address, value);
589 }
590
591 int mem_ap_sel_read_buf(struct adiv5_dap *swjdp, uint8_t ap,
592 uint8_t *buffer, uint32_t size, uint32_t count, uint32_t address)
593 {
594 dap_ap_select(swjdp, ap);
595 return mem_ap_read(swjdp, buffer, size, count, address, true);
596 }
597
598 int mem_ap_sel_write_buf(struct adiv5_dap *swjdp, uint8_t ap,
599 const uint8_t *buffer, uint32_t size, uint32_t count, uint32_t address)
600 {
601 dap_ap_select(swjdp, ap);
602 return mem_ap_write(swjdp, buffer, size, count, address, true);
603 }
604
605 int mem_ap_sel_read_buf_noincr(struct adiv5_dap *swjdp, uint8_t ap,
606 uint8_t *buffer, uint32_t size, uint32_t count, uint32_t address)
607 {
608 dap_ap_select(swjdp, ap);
609 return mem_ap_read(swjdp, buffer, size, count, address, false);
610 }
611
612 int mem_ap_sel_write_buf_noincr(struct adiv5_dap *swjdp, uint8_t ap,
613 const uint8_t *buffer, uint32_t size, uint32_t count, uint32_t address)
614 {
615 dap_ap_select(swjdp, ap);
616 return mem_ap_write(swjdp, buffer, size, count, address, false);
617 }
618
619 /*--------------------------------------------------------------------------*/
620
621
622 #define DAP_POWER_DOMAIN_TIMEOUT (10)
623
624 /* FIXME don't import ... just initialize as
625 * part of DAP transport setup
626 */
627 extern const struct dap_ops jtag_dp_ops;
628
629 /*--------------------------------------------------------------------------*/
630
631 /**
632 * Initialize a DAP. This sets up the power domains, prepares the DP
633 * for further use, and arranges to use AP #0 for all AP operations
634 * until dap_ap-select() changes that policy.
635 *
636 * @param dap The DAP being initialized.
637 *
638 * @todo Rename this. We also need an initialization scheme which account
639 * for SWD transports not just JTAG; that will need to address differences
640 * in layering. (JTAG is useful without any debug target; but not SWD.)
641 * And this may not even use an AHB-AP ... e.g. DAP-Lite uses an APB-AP.
642 */
643 int ahbap_debugport_init(struct adiv5_dap *dap)
644 {
645 int retval;
646
647 LOG_DEBUG(" ");
648
649 /* JTAG-DP or SWJ-DP, in JTAG mode
650 * ... for SWD mode this is patched as part
651 * of link switchover
652 */
653 if (!dap->ops)
654 dap->ops = &jtag_dp_ops;
655
656 /* Default MEM-AP setup.
657 *
658 * REVISIT AP #0 may be an inappropriate default for this.
659 * Should we probe, or take a hint from the caller?
660 * Presumably we can ignore the possibility of multiple APs.
661 */
662 dap->ap_current = !0;
663 dap_ap_select(dap, 0);
664
665 /* DP initialization */
666
667 retval = dap_queue_dp_read(dap, DP_CTRL_STAT, NULL);
668 if (retval != ERROR_OK)
669 return retval;
670
671 retval = dap_queue_dp_write(dap, DP_CTRL_STAT, SSTICKYERR);
672 if (retval != ERROR_OK)
673 return retval;
674
675 retval = dap_queue_dp_read(dap, DP_CTRL_STAT, NULL);
676 if (retval != ERROR_OK)
677 return retval;
678
679 dap->dp_ctrl_stat = CDBGPWRUPREQ | CSYSPWRUPREQ;
680 retval = dap_queue_dp_write(dap, DP_CTRL_STAT, dap->dp_ctrl_stat);
681 if (retval != ERROR_OK)
682 return retval;
683
684 /* Check that we have debug power domains activated */
685 LOG_DEBUG("DAP: wait CDBGPWRUPACK");
686 retval = dap_dp_poll_register(dap, DP_CTRL_STAT,
687 CDBGPWRUPACK, CDBGPWRUPACK,
688 DAP_POWER_DOMAIN_TIMEOUT);
689 if (retval != ERROR_OK)
690 return retval;
691
692 LOG_DEBUG("DAP: wait CSYSPWRUPACK");
693 retval = dap_dp_poll_register(dap, DP_CTRL_STAT,
694 CSYSPWRUPACK, CSYSPWRUPACK,
695 DAP_POWER_DOMAIN_TIMEOUT);
696 if (retval != ERROR_OK)
697 return retval;
698
699 retval = dap_queue_dp_read(dap, DP_CTRL_STAT, NULL);
700 if (retval != ERROR_OK)
701 return retval;
702 /* With debug power on we can activate OVERRUN checking */
703 dap->dp_ctrl_stat = CDBGPWRUPREQ | CSYSPWRUPREQ | CORUNDETECT;
704 retval = dap_queue_dp_write(dap, DP_CTRL_STAT, dap->dp_ctrl_stat);
705 if (retval != ERROR_OK)
706 return retval;
707 retval = dap_queue_dp_read(dap, DP_CTRL_STAT, NULL);
708 if (retval != ERROR_OK)
709 return retval;
710
711 /* check that we support packed transfers */
712 uint32_t csw, cfg;
713
714 retval = dap_setup_accessport(dap, CSW_8BIT | CSW_ADDRINC_PACKED, 0);
715 if (retval != ERROR_OK)
716 return retval;
717
718 retval = dap_queue_ap_read(dap, AP_REG_CSW, &csw);
719 if (retval != ERROR_OK)
720 return retval;
721
722 retval = dap_queue_ap_read(dap, AP_REG_CFG, &cfg);
723 if (retval != ERROR_OK)
724 return retval;
725
726 retval = dap_run(dap);
727 if (retval != ERROR_OK)
728 return retval;
729
730 if (csw & CSW_ADDRINC_PACKED)
731 dap->packed_transfers = true;
732 else
733 dap->packed_transfers = false;
734
735 /* Packed transfers on TI BE-32 processors do not work correctly in
736 * many cases. */
737 if (dap->ti_be_32_quirks)
738 dap->packed_transfers = false;
739
740 LOG_DEBUG("MEM_AP Packed Transfers: %s",
741 dap->packed_transfers ? "enabled" : "disabled");
742
743 /* The ARM ADI spec leaves implementation-defined whether unaligned
744 * memory accesses work, only work partially, or cause a sticky error.
745 * On TI BE-32 processors, reads seem to return garbage in some bytes
746 * and unaligned writes seem to cause a sticky error.
747 * TODO: it would be nice to have a way to detect whether unaligned
748 * operations are supported on other processors. */
749 dap->unaligned_access_bad = dap->ti_be_32_quirks;
750
751 LOG_DEBUG("MEM_AP CFG: large data %d, long address %d, big-endian %d",
752 !!(cfg & 0x04), !!(cfg & 0x02), !!(cfg & 0x01));
753
754 return ERROR_OK;
755 }
756
757 /* CID interpretation -- see ARM IHI 0029B section 3
758 * and ARM IHI 0031A table 13-3.
759 */
760 static const char *class_description[16] = {
761 "Reserved", "ROM table", "Reserved", "Reserved",
762 "Reserved", "Reserved", "Reserved", "Reserved",
763 "Reserved", "CoreSight component", "Reserved", "Peripheral Test Block",
764 "Reserved", "OptimoDE DESS",
765 "Generic IP component", "PrimeCell or System component"
766 };
767
768 static bool is_dap_cid_ok(uint32_t cid3, uint32_t cid2, uint32_t cid1, uint32_t cid0)
769 {
770 return cid3 == 0xb1 && cid2 == 0x05
771 && ((cid1 & 0x0f) == 0) && cid0 == 0x0d;
772 }
773
774 /*
775 * This function checks the ID for each access port to find the requested Access Port type
776 */
777 int dap_find_ap(struct adiv5_dap *dap, enum ap_type type_to_find, uint8_t *ap_num_out)
778 {
779 int ap;
780
781 /* Maximum AP number is 255 since the SELECT register is 8 bits */
782 for (ap = 0; ap <= 255; ap++) {
783
784 /* read the IDR register of the Access Port */
785 uint32_t id_val = 0;
786 dap_ap_select(dap, ap);
787
788 int retval = dap_queue_ap_read(dap, AP_REG_IDR, &id_val);
789 if (retval != ERROR_OK)
790 return retval;
791
792 retval = dap_run(dap);
793
794 /* IDR bits:
795 * 31-28 : Revision
796 * 27-24 : JEDEC bank (0x4 for ARM)
797 * 23-17 : JEDEC code (0x3B for ARM)
798 * 16 : Mem-AP
799 * 15-8 : Reserved
800 * 7-0 : AP Identity (1=AHB-AP 2=APB-AP 0x10=JTAG-AP)
801 */
802
803 /* Reading register for a non-existant AP should not cause an error,
804 * but just to be sure, try to continue searching if an error does happen.
805 */
806 if ((retval == ERROR_OK) && /* Register read success */
807 ((id_val & 0x0FFF0000) == 0x04770000) && /* Jedec codes match */
808 ((id_val & 0xFF) == type_to_find)) { /* type matches*/
809
810 LOG_DEBUG("Found %s at AP index: %d (IDR=0x%08" PRIX32 ")",
811 (type_to_find == AP_TYPE_AHB_AP) ? "AHB-AP" :
812 (type_to_find == AP_TYPE_APB_AP) ? "APB-AP" :
813 (type_to_find == AP_TYPE_JTAG_AP) ? "JTAG-AP" : "Unknown",
814 ap, id_val);
815
816 *ap_num_out = ap;
817 return ERROR_OK;
818 }
819 }
820
821 LOG_DEBUG("No %s found",
822 (type_to_find == AP_TYPE_AHB_AP) ? "AHB-AP" :
823 (type_to_find == AP_TYPE_APB_AP) ? "APB-AP" :
824 (type_to_find == AP_TYPE_JTAG_AP) ? "JTAG-AP" : "Unknown");
825 return ERROR_FAIL;
826 }
827
828 int dap_get_debugbase(struct adiv5_dap *dap, int ap,
829 uint32_t *out_dbgbase, uint32_t *out_apid)
830 {
831 uint32_t ap_old;
832 int retval;
833 uint32_t dbgbase, apid;
834
835 /* AP address is in bits 31:24 of DP_SELECT */
836 if (ap >= 256)
837 return ERROR_COMMAND_SYNTAX_ERROR;
838
839 ap_old = dap->ap_current;
840 dap_ap_select(dap, ap);
841
842 retval = dap_queue_ap_read(dap, AP_REG_BASE, &dbgbase);
843 if (retval != ERROR_OK)
844 return retval;
845 retval = dap_queue_ap_read(dap, AP_REG_IDR, &apid);
846 if (retval != ERROR_OK)
847 return retval;
848 retval = dap_run(dap);
849 if (retval != ERROR_OK)
850 return retval;
851
852 /* Excavate the device ID code */
853 struct jtag_tap *tap = dap->jtag_info->tap;
854 while (tap != NULL) {
855 if (tap->hasidcode)
856 break;
857 tap = tap->next_tap;
858 }
859 if (tap == NULL || !tap->hasidcode)
860 return ERROR_OK;
861
862 dap_ap_select(dap, ap_old);
863
864 /* The asignment happens only here to prevent modification of these
865 * values before they are certain. */
866 *out_dbgbase = dbgbase;
867 *out_apid = apid;
868
869 return ERROR_OK;
870 }
871
872 int dap_lookup_cs_component(struct adiv5_dap *dap, int ap,
873 uint32_t dbgbase, uint8_t type, uint32_t *addr)
874 {
875 uint32_t ap_old;
876 uint32_t romentry, entry_offset = 0, component_base, devtype;
877 int retval = ERROR_FAIL;
878
879 if (ap >= 256)
880 return ERROR_COMMAND_SYNTAX_ERROR;
881
882 ap_old = dap->ap_current;
883 dap_ap_select(dap, ap);
884
885 do {
886 retval = mem_ap_read_atomic_u32(dap, (dbgbase&0xFFFFF000) |
887 entry_offset, &romentry);
888 if (retval != ERROR_OK)
889 return retval;
890
891 component_base = (dbgbase & 0xFFFFF000)
892 + (romentry & 0xFFFFF000);
893
894 if (romentry & 0x1) {
895 retval = mem_ap_read_atomic_u32(dap,
896 (component_base & 0xfffff000) | 0xfcc,
897 &devtype);
898 if (retval != ERROR_OK)
899 return retval;
900 if ((devtype & 0xff) == type) {
901 *addr = component_base;
902 retval = ERROR_OK;
903 break;
904 }
905 }
906 entry_offset += 4;
907 } while (romentry > 0);
908
909 dap_ap_select(dap, ap_old);
910
911 return retval;
912 }
913
914 static int dap_rom_display(struct command_context *cmd_ctx,
915 struct adiv5_dap *dap, int ap, uint32_t dbgbase, int depth)
916 {
917 int retval;
918 uint32_t cid0, cid1, cid2, cid3, memtype, romentry;
919 uint16_t entry_offset;
920 char tabs[7] = "";
921
922 if (depth > 16) {
923 command_print(cmd_ctx, "\tTables too deep");
924 return ERROR_FAIL;
925 }
926
927 if (depth)
928 snprintf(tabs, sizeof(tabs), "[L%02d] ", depth);
929
930 /* bit 16 of apid indicates a memory access port */
931 if (dbgbase & 0x02)
932 command_print(cmd_ctx, "\t%sValid ROM table present", tabs);
933 else
934 command_print(cmd_ctx, "\t%sROM table in legacy format", tabs);
935
936 /* Now we read ROM table ID registers, ref. ARM IHI 0029B sec */
937 retval = mem_ap_read_u32(dap, (dbgbase&0xFFFFF000) | 0xFF0, &cid0);
938 if (retval != ERROR_OK)
939 return retval;
940 retval = mem_ap_read_u32(dap, (dbgbase&0xFFFFF000) | 0xFF4, &cid1);
941 if (retval != ERROR_OK)
942 return retval;
943 retval = mem_ap_read_u32(dap, (dbgbase&0xFFFFF000) | 0xFF8, &cid2);
944 if (retval != ERROR_OK)
945 return retval;
946 retval = mem_ap_read_u32(dap, (dbgbase&0xFFFFF000) | 0xFFC, &cid3);
947 if (retval != ERROR_OK)
948 return retval;
949 retval = mem_ap_read_u32(dap, (dbgbase&0xFFFFF000) | 0xFCC, &memtype);
950 if (retval != ERROR_OK)
951 return retval;
952 retval = dap_run(dap);
953 if (retval != ERROR_OK)
954 return retval;
955
956 if (!is_dap_cid_ok(cid3, cid2, cid1, cid0))
957 command_print(cmd_ctx, "\t%sCID3 0x%02x"
958 ", CID2 0x%02x"
959 ", CID1 0x%02x"
960 ", CID0 0x%02x",
961 tabs,
962 (unsigned)cid3, (unsigned)cid2,
963 (unsigned)cid1, (unsigned)cid0);
964 if (memtype & 0x01)
965 command_print(cmd_ctx, "\t%sMEMTYPE system memory present on bus", tabs);
966 else
967 command_print(cmd_ctx, "\t%sMEMTYPE system memory not present: dedicated debug bus", tabs);
968
969 /* Now we read ROM table entries from dbgbase&0xFFFFF000) | 0x000 until we get 0x00000000 */
970 for (entry_offset = 0; ; entry_offset += 4) {
971 retval = mem_ap_read_atomic_u32(dap, (dbgbase&0xFFFFF000) | entry_offset, &romentry);
972 if (retval != ERROR_OK)
973 return retval;
974 command_print(cmd_ctx, "\t%sROMTABLE[0x%x] = 0x%" PRIx32 "",
975 tabs, entry_offset, romentry);
976 if (romentry & 0x01) {
977 uint32_t c_cid0, c_cid1, c_cid2, c_cid3;
978 uint32_t c_pid0, c_pid1, c_pid2, c_pid3, c_pid4;
979 uint32_t component_base;
980 unsigned part_num;
981 char *type, *full;
982
983 component_base = (dbgbase & 0xFFFFF000) + (romentry & 0xFFFFF000);
984
985 /* IDs are in last 4K section */
986 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFE0, &c_pid0);
987 if (retval != ERROR_OK) {
988 command_print(cmd_ctx, "\t%s\tCan't read component with base address 0x%" PRIx32
989 ", the corresponding core might be turned off", tabs, component_base);
990 continue;
991 }
992 c_pid0 &= 0xff;
993 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFE4, &c_pid1);
994 if (retval != ERROR_OK)
995 return retval;
996 c_pid1 &= 0xff;
997 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFE8, &c_pid2);
998 if (retval != ERROR_OK)
999 return retval;
1000 c_pid2 &= 0xff;
1001 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFEC, &c_pid3);
1002 if (retval != ERROR_OK)
1003 return retval;
1004 c_pid3 &= 0xff;
1005 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFD0, &c_pid4);
1006 if (retval != ERROR_OK)
1007 return retval;
1008 c_pid4 &= 0xff;
1009
1010 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFF0, &c_cid0);
1011 if (retval != ERROR_OK)
1012 return retval;
1013 c_cid0 &= 0xff;
1014 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFF4, &c_cid1);
1015 if (retval != ERROR_OK)
1016 return retval;
1017 c_cid1 &= 0xff;
1018 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFF8, &c_cid2);
1019 if (retval != ERROR_OK)
1020 return retval;
1021 c_cid2 &= 0xff;
1022 retval = mem_ap_read_atomic_u32(dap, component_base + 0xFFC, &c_cid3);
1023 if (retval != ERROR_OK)
1024 return retval;
1025 c_cid3 &= 0xff;
1026
1027 command_print(cmd_ctx, "\t\tComponent base address 0x%" PRIx32 ", "
1028 "start address 0x%" PRIx32, component_base,
1029 /* component may take multiple 4K pages */
1030 (uint32_t)(component_base - 0x1000*(c_pid4 >> 4)));
1031 command_print(cmd_ctx, "\t\tComponent class is 0x%" PRIx8 ", %s",
1032 (uint8_t)((c_cid1 >> 4) & 0xf),
1033 /* See ARM IHI 0029B Table 3-3 */
1034 class_description[(c_cid1 >> 4) & 0xf]);
1035
1036 /* CoreSight component? */
1037 if (((c_cid1 >> 4) & 0x0f) == 9) {
1038 uint32_t devtype;
1039 unsigned minor;
1040 char *major = "Reserved", *subtype = "Reserved";
1041
1042 retval = mem_ap_read_atomic_u32(dap,
1043 (component_base & 0xfffff000) | 0xfcc,
1044 &devtype);
1045 if (retval != ERROR_OK)
1046 return retval;
1047 minor = (devtype >> 4) & 0x0f;
1048 switch (devtype & 0x0f) {
1049 case 0:
1050 major = "Miscellaneous";
1051 switch (minor) {
1052 case 0:
1053 subtype = "other";
1054 break;
1055 case 4:
1056 subtype = "Validation component";
1057 break;
1058 }
1059 break;
1060 case 1:
1061 major = "Trace Sink";
1062 switch (minor) {
1063 case 0:
1064 subtype = "other";
1065 break;
1066 case 1:
1067 subtype = "Port";
1068 break;
1069 case 2:
1070 subtype = "Buffer";
1071 break;
1072 }
1073 break;
1074 case 2:
1075 major = "Trace Link";
1076 switch (minor) {
1077 case 0:
1078 subtype = "other";
1079 break;
1080 case 1:
1081 subtype = "Funnel, router";
1082 break;
1083 case 2:
1084 subtype = "Filter";
1085 break;
1086 case 3:
1087 subtype = "FIFO, buffer";
1088 break;
1089 }
1090 break;
1091 case 3:
1092 major = "Trace Source";
1093 switch (minor) {
1094 case 0:
1095 subtype = "other";
1096 break;
1097 case 1:
1098 subtype = "Processor";
1099 break;
1100 case 2:
1101 subtype = "DSP";
1102 break;
1103 case 3:
1104 subtype = "Engine/Coprocessor";
1105 break;
1106 case 4:
1107 subtype = "Bus";
1108 break;
1109 }
1110 break;
1111 case 4:
1112 major = "Debug Control";
1113 switch (minor) {
1114 case 0:
1115 subtype = "other";
1116 break;
1117 case 1:
1118 subtype = "Trigger Matrix";
1119 break;
1120 case 2:
1121 subtype = "Debug Auth";
1122 break;
1123 }
1124 break;
1125 case 5:
1126 major = "Debug Logic";
1127 switch (minor) {
1128 case 0:
1129 subtype = "other";
1130 break;
1131 case 1:
1132 subtype = "Processor";
1133 break;
1134 case 2:
1135 subtype = "DSP";
1136 break;
1137 case 3:
1138 subtype = "Engine/Coprocessor";
1139 break;
1140 }
1141 break;
1142 }
1143 command_print(cmd_ctx, "\t\tType is 0x%02" PRIx8 ", %s, %s",
1144 (uint8_t)(devtype & 0xff),
1145 major, subtype);
1146 /* REVISIT also show 0xfc8 DevId */
1147 }
1148
1149 if (!is_dap_cid_ok(cid3, cid2, cid1, cid0))
1150 command_print(cmd_ctx,
1151 "\t\tCID3 0%02x"
1152 ", CID2 0%02x"
1153 ", CID1 0%02x"
1154 ", CID0 0%02x",
1155 (int)c_cid3,
1156 (int)c_cid2,
1157 (int)c_cid1,
1158 (int)c_cid0);
1159 command_print(cmd_ctx,
1160 "\t\tPeripheral ID[4..0] = hex "
1161 "%02x %02x %02x %02x %02x",
1162 (int)c_pid4, (int)c_pid3, (int)c_pid2,
1163 (int)c_pid1, (int)c_pid0);
1164
1165 /* Part number interpretations are from Cortex
1166 * core specs, the CoreSight components TRM
1167 * (ARM DDI 0314H), CoreSight System Design
1168 * Guide (ARM DGI 0012D) and ETM specs; also
1169 * from chip observation (e.g. TI SDTI).
1170 */
1171 part_num = (c_pid0 & 0xff);
1172 part_num |= (c_pid1 & 0x0f) << 8;
1173 switch (part_num) {
1174 case 0x000:
1175 type = "Cortex-M3 NVIC";
1176 full = "(Interrupt Controller)";
1177 break;
1178 case 0x001:
1179 type = "Cortex-M3 ITM";
1180 full = "(Instrumentation Trace Module)";
1181 break;
1182 case 0x002:
1183 type = "Cortex-M3 DWT";
1184 full = "(Data Watchpoint and Trace)";
1185 break;
1186 case 0x003:
1187 type = "Cortex-M3 FBP";
1188 full = "(Flash Patch and Breakpoint)";
1189 break;
1190 case 0x00c:
1191 type = "Cortex-M4 SCS";
1192 full = "(System Control Space)";
1193 break;
1194 case 0x00d:
1195 type = "CoreSight ETM11";
1196 full = "(Embedded Trace)";
1197 break;
1198 /* case 0x113: what? */
1199 case 0x120: /* from OMAP3 memmap */
1200 type = "TI SDTI";
1201 full = "(System Debug Trace Interface)";
1202 break;
1203 case 0x343: /* from OMAP3 memmap */
1204 type = "TI DAPCTL";
1205 full = "";
1206 break;
1207 case 0x906:
1208 type = "Coresight CTI";
1209 full = "(Cross Trigger)";
1210 break;
1211 case 0x907:
1212 type = "Coresight ETB";
1213 full = "(Trace Buffer)";
1214 break;
1215 case 0x908:
1216 type = "Coresight CSTF";
1217 full = "(Trace Funnel)";
1218 break;
1219 case 0x910:
1220 type = "CoreSight ETM9";
1221 full = "(Embedded Trace)";
1222 break;
1223 case 0x912:
1224 type = "Coresight TPIU";
1225 full = "(Trace Port Interface Unit)";
1226 break;
1227 case 0x913:
1228 type = "Coresight ITM";
1229 full = "(Instrumentation Trace Macrocell)";
1230 break;
1231 case 0x921:
1232 type = "Cortex-A8 ETM";
1233 full = "(Embedded Trace)";
1234 break;
1235 case 0x922:
1236 type = "Cortex-A8 CTI";
1237 full = "(Cross Trigger)";
1238 break;
1239 case 0x923:
1240 type = "Cortex-M3 TPIU";
1241 full = "(Trace Port Interface Unit)";
1242 break;
1243 case 0x924:
1244 type = "Cortex-M3 ETM";
1245 full = "(Embedded Trace)";
1246 break;
1247 case 0x925:
1248 type = "Cortex-M4 ETM";
1249 full = "(Embedded Trace)";
1250 break;
1251 case 0x930:
1252 type = "Cortex-R4 ETM";
1253 full = "(Embedded Trace)";
1254 break;
1255 case 0x950:
1256 type = "CoreSight Component";
1257 full = "(unidentified Cortex-A9 component)";
1258 break;
1259 case 0x9a0:
1260 type = "CoreSight PMU";
1261 full = "(Performance Monitoring Unit)";
1262 break;
1263 case 0x9a1:
1264 type = "Cortex-M4 TPUI";
1265 full = "(Trace Port Interface Unit)";
1266 break;
1267 case 0xc08:
1268 type = "Cortex-A8 Debug";
1269 full = "(Debug Unit)";
1270 break;
1271 case 0xc09:
1272 type = "Cortex-A9 Debug";
1273 full = "(Debug Unit)";
1274 break;
1275 default:
1276 type = "-*- unrecognized -*-";
1277 full = "";
1278 break;
1279 }
1280 command_print(cmd_ctx, "\t\tPart is %s %s",
1281 type, full);
1282
1283 /* ROM Table? */
1284 if (((c_cid1 >> 4) & 0x0f) == 1) {
1285 retval = dap_rom_display(cmd_ctx, dap, ap, component_base, depth + 1);
1286 if (retval != ERROR_OK)
1287 return retval;
1288 }
1289 } else {
1290 if (romentry)
1291 command_print(cmd_ctx, "\t\tComponent not present");
1292 else
1293 break;
1294 }
1295 }
1296 command_print(cmd_ctx, "\t%s\tEnd of ROM table", tabs);
1297 return ERROR_OK;
1298 }
1299
1300 static int dap_info_command(struct command_context *cmd_ctx,
1301 struct adiv5_dap *dap, int ap)
1302 {
1303 int retval;
1304 uint32_t dbgbase = 0, apid = 0; /* Silence gcc by initializing */
1305 int romtable_present = 0;
1306 uint8_t mem_ap;
1307 uint32_t ap_old;
1308
1309 retval = dap_get_debugbase(dap, ap, &dbgbase, &apid);
1310 if (retval != ERROR_OK)
1311 return retval;
1312
1313 ap_old = dap->ap_current;
1314 dap_ap_select(dap, ap);
1315
1316 /* Now we read ROM table ID registers, ref. ARM IHI 0029B sec */
1317 mem_ap = ((apid&0x10000) && ((apid&0x0F) != 0));
1318 command_print(cmd_ctx, "AP ID register 0x%8.8" PRIx32, apid);
1319 if (apid) {
1320 switch (apid&0x0F) {
1321 case 0:
1322 command_print(cmd_ctx, "\tType is JTAG-AP");
1323 break;
1324 case 1:
1325 command_print(cmd_ctx, "\tType is MEM-AP AHB");
1326 break;
1327 case 2:
1328 command_print(cmd_ctx, "\tType is MEM-AP APB");
1329 break;
1330 default:
1331 command_print(cmd_ctx, "\tUnknown AP type");
1332 break;
1333 }
1334
1335 /* NOTE: a MEM-AP may have a single CoreSight component that's
1336 * not a ROM table ... or have no such components at all.
1337 */
1338 if (mem_ap)
1339 command_print(cmd_ctx, "AP BASE 0x%8.8" PRIx32, dbgbase);
1340 } else
1341 command_print(cmd_ctx, "No AP found at this ap 0x%x", ap);
1342
1343 romtable_present = ((mem_ap) && (dbgbase != 0xFFFFFFFF));
1344 if (romtable_present) {
1345 dap_rom_display(cmd_ctx, dap, ap, dbgbase, 0);
1346 } else
1347 command_print(cmd_ctx, "\tNo ROM table present");
1348 dap_ap_select(dap, ap_old);
1349
1350 return ERROR_OK;
1351 }
1352
1353 COMMAND_HANDLER(handle_dap_info_command)
1354 {
1355 struct target *target = get_current_target(CMD_CTX);
1356 struct arm *arm = target_to_arm(target);
1357 struct adiv5_dap *dap = arm->dap;
1358 uint32_t apsel;
1359
1360 switch (CMD_ARGC) {
1361 case 0:
1362 apsel = dap->apsel;
1363 break;
1364 case 1:
1365 COMMAND_PARSE_NUMBER(u32, CMD_ARGV[0], apsel);
1366 break;
1367 default:
1368 return ERROR_COMMAND_SYNTAX_ERROR;
1369 }
1370
1371 return dap_info_command(CMD_CTX, dap, apsel);
1372 }
1373
1374 COMMAND_HANDLER(dap_baseaddr_command)
1375 {
1376 struct target *target = get_current_target(CMD_CTX);
1377 struct arm *arm = target_to_arm(target);
1378 struct adiv5_dap *dap = arm->dap;
1379
1380 uint32_t apsel, baseaddr;
1381 int retval;
1382
1383 switch (CMD_ARGC) {
1384 case 0:
1385 apsel = dap->apsel;
1386 break;
1387 case 1:
1388 COMMAND_PARSE_NUMBER(u32, CMD_ARGV[0], apsel);
1389 /* AP address is in bits 31:24 of DP_SELECT */
1390 if (apsel >= 256)
1391 return ERROR_COMMAND_SYNTAX_ERROR;
1392 break;
1393 default:
1394 return ERROR_COMMAND_SYNTAX_ERROR;
1395 }
1396
1397 dap_ap_select(dap, apsel);
1398
1399 /* NOTE: assumes we're talking to a MEM-AP, which
1400 * has a base address. There are other kinds of AP,
1401 * though they're not common for now. This should
1402 * use the ID register to verify it's a MEM-AP.
1403 */
1404 retval = dap_queue_ap_read(dap, AP_REG_BASE, &baseaddr);
1405 if (retval != ERROR_OK)
1406 return retval;
1407 retval = dap_run(dap);
1408 if (retval != ERROR_OK)
1409 return retval;
1410
1411 command_print(CMD_CTX, "0x%8.8" PRIx32, baseaddr);
1412
1413 return retval;
1414 }
1415
1416 COMMAND_HANDLER(dap_memaccess_command)
1417 {
1418 struct target *target = get_current_target(CMD_CTX);
1419 struct arm *arm = target_to_arm(target);
1420 struct adiv5_dap *dap = arm->dap;
1421
1422 uint32_t memaccess_tck;
1423
1424 switch (CMD_ARGC) {
1425 case 0:
1426 memaccess_tck = dap->memaccess_tck;
1427 break;
1428 case 1:
1429 COMMAND_PARSE_NUMBER(u32, CMD_ARGV[0], memaccess_tck);
1430 break;
1431 default:
1432 return ERROR_COMMAND_SYNTAX_ERROR;
1433 }
1434 dap->memaccess_tck = memaccess_tck;
1435
1436 command_print(CMD_CTX, "memory bus access delay set to %" PRIi32 " tck",
1437 dap->memaccess_tck);
1438
1439 return ERROR_OK;
1440 }
1441
1442 COMMAND_HANDLER(dap_apsel_command)
1443 {
1444 struct target *target = get_current_target(CMD_CTX);
1445 struct arm *arm = target_to_arm(target);
1446 struct adiv5_dap *dap = arm->dap;
1447
1448 uint32_t apsel, apid;
1449 int retval;
1450
1451 switch (CMD_ARGC) {
1452 case 0:
1453 apsel = 0;
1454 break;
1455 case 1:
1456 COMMAND_PARSE_NUMBER(u32, CMD_ARGV[0], apsel);
1457 /* AP address is in bits 31:24 of DP_SELECT */
1458 if (apsel >= 256)
1459 return ERROR_COMMAND_SYNTAX_ERROR;
1460 break;
1461 default:
1462 return ERROR_COMMAND_SYNTAX_ERROR;
1463 }
1464
1465 dap->apsel = apsel;
1466 dap_ap_select(dap, apsel);
1467
1468 retval = dap_queue_ap_read(dap, AP_REG_IDR, &apid);
1469 if (retval != ERROR_OK)
1470 return retval;
1471 retval = dap_run(dap);
1472 if (retval != ERROR_OK)
1473 return retval;
1474
1475 command_print(CMD_CTX, "ap %" PRIi32 " selected, identification register 0x%8.8" PRIx32,
1476 apsel, apid);
1477
1478 return retval;
1479 }
1480
1481 COMMAND_HANDLER(dap_apcsw_command)
1482 {
1483 struct target *target = get_current_target(CMD_CTX);
1484 struct arm *arm = target_to_arm(target);
1485 struct adiv5_dap *dap = arm->dap;
1486
1487 uint32_t apcsw = dap->apcsw[dap->apsel], sprot = 0;
1488
1489 switch (CMD_ARGC) {
1490 case 0:
1491 command_print(CMD_CTX, "apsel %" PRIi32 " selected, csw 0x%8.8" PRIx32,
1492 (dap->apsel), apcsw);
1493 break;
1494 case 1:
1495 COMMAND_PARSE_NUMBER(u32, CMD_ARGV[0], sprot);
1496 /* AP address is in bits 31:24 of DP_SELECT */
1497 if (sprot > 1)
1498 return ERROR_COMMAND_SYNTAX_ERROR;
1499 if (sprot)
1500 apcsw |= CSW_SPROT;
1501 else
1502 apcsw &= ~CSW_SPROT;
1503 break;
1504 default:
1505 return ERROR_COMMAND_SYNTAX_ERROR;
1506 }
1507 dap->apcsw[dap->apsel] = apcsw;
1508
1509 return 0;
1510 }
1511
1512
1513
1514 COMMAND_HANDLER(dap_apid_command)
1515 {
1516 struct target *target = get_current_target(CMD_CTX);
1517 struct arm *arm = target_to_arm(target);
1518 struct adiv5_dap *dap = arm->dap;
1519
1520 uint32_t apsel, apid;
1521 int retval;
1522
1523 switch (CMD_ARGC) {
1524 case 0:
1525 apsel = dap->apsel;
1526 break;
1527 case 1:
1528 COMMAND_PARSE_NUMBER(u32, CMD_ARGV[0], apsel);
1529 /* AP address is in bits 31:24 of DP_SELECT */
1530 if (apsel >= 256)
1531 return ERROR_COMMAND_SYNTAX_ERROR;
1532 break;
1533 default:
1534 return ERROR_COMMAND_SYNTAX_ERROR;
1535 }
1536
1537 dap_ap_select(dap, apsel);
1538
1539 retval = dap_queue_ap_read(dap, AP_REG_IDR, &apid);
1540 if (retval != ERROR_OK)
1541 return retval;
1542 retval = dap_run(dap);
1543 if (retval != ERROR_OK)
1544 return retval;
1545
1546 command_print(CMD_CTX, "0x%8.8" PRIx32, apid);
1547
1548 return retval;
1549 }
1550
1551 COMMAND_HANDLER(dap_ti_be_32_quirks_command)
1552 {
1553 struct target *target = get_current_target(CMD_CTX);
1554 struct arm *arm = target_to_arm(target);
1555 struct adiv5_dap *dap = arm->dap;
1556
1557 uint32_t enable = dap->ti_be_32_quirks;
1558
1559 switch (CMD_ARGC) {
1560 case 0:
1561 break;
1562 case 1:
1563 COMMAND_PARSE_NUMBER(u32, CMD_ARGV[0], enable);
1564 if (enable > 1)
1565 return ERROR_COMMAND_SYNTAX_ERROR;
1566 break;
1567 default:
1568 return ERROR_COMMAND_SYNTAX_ERROR;
1569 }
1570 dap->ti_be_32_quirks = enable;
1571 command_print(CMD_CTX, "TI BE-32 quirks mode %s",
1572 enable ? "enabled" : "disabled");
1573
1574 return 0;
1575 }
1576
1577 static const struct command_registration dap_commands[] = {
1578 {
1579 .name = "info",
1580 .handler = handle_dap_info_command,
1581 .mode = COMMAND_EXEC,
1582 .help = "display ROM table for MEM-AP "
1583 "(default currently selected AP)",
1584 .usage = "[ap_num]",
1585 },
1586 {
1587 .name = "apsel",
1588 .handler = dap_apsel_command,
1589 .mode = COMMAND_EXEC,
1590 .help = "Set the currently selected AP (default 0) "
1591 "and display the result",
1592 .usage = "[ap_num]",
1593 },
1594 {
1595 .name = "apcsw",
1596 .handler = dap_apcsw_command,
1597 .mode = COMMAND_EXEC,
1598 .help = "Set csw access bit ",
1599 .usage = "[sprot]",
1600 },
1601
1602 {
1603 .name = "apid",
1604 .handler = dap_apid_command,
1605 .mode = COMMAND_EXEC,
1606 .help = "return ID register from AP "
1607 "(default currently selected AP)",
1608 .usage = "[ap_num]",
1609 },
1610 {
1611 .name = "baseaddr",
1612 .handler = dap_baseaddr_command,
1613 .mode = COMMAND_EXEC,
1614 .help = "return debug base address from MEM-AP "
1615 "(default currently selected AP)",
1616 .usage = "[ap_num]",
1617 },
1618 {
1619 .name = "memaccess",
1620 .handler = dap_memaccess_command,
1621 .mode = COMMAND_EXEC,
1622 .help = "set/get number of extra tck for MEM-AP memory "
1623 "bus access [0-255]",
1624 .usage = "[cycles]",
1625 },
1626 {
1627 .name = "ti_be_32_quirks",
1628 .handler = dap_ti_be_32_quirks_command,
1629 .mode = COMMAND_CONFIG,
1630 .help = "set/get quirks mode for TI TMS450/TMS570 processors",
1631 .usage = "[enable]",
1632 },
1633 COMMAND_REGISTRATION_DONE
1634 };
1635
1636 const struct command_registration dap_command_handlers[] = {
1637 {
1638 .name = "dap",
1639 .mode = COMMAND_EXEC,
1640 .help = "DAP command group",
1641 .usage = "",
1642 .chain = dap_commands,
1643 },
1644 COMMAND_REGISTRATION_DONE
1645 };
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