1 /***************************************************************************
2 * Copyright (C) 2005 by Dominic Rath *
3 * Dominic.Rath@gmx.de *
5 * Copyright (C) 2007-2010 Øyvind Harboe *
6 * oyvind.harboe@zylin.com *
8 * Copyright (C) 2008, Duane Ellis *
9 * openocd@duaneeellis.com *
11 * Copyright (C) 2008 by Spencer Oliver *
12 * spen@spen-soft.co.uk *
14 * Copyright (C) 2008 by Rick Altherr *
15 * kc8apf@kc8apf.net> *
17 * Copyright (C) 2011 by Broadcom Corporation *
18 * Evan Hunter - ehunter@broadcom.com *
20 * Copyright (C) ST-Ericsson SA 2011 *
21 * michel.jaouen@stericsson.com : smp minimum support *
23 * Copyright (C) 2011 Andreas Fritiofson *
24 * andreas.fritiofson@gmail.com *
26 * This program is free software; you can redistribute it and/or modify *
27 * it under the terms of the GNU General Public License as published by *
28 * the Free Software Foundation; either version 2 of the License, or *
29 * (at your option) any later version. *
31 * This program is distributed in the hope that it will be useful, *
32 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
33 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
34 * GNU General Public License for more details. *
36 * You should have received a copy of the GNU General Public License *
37 * along with this program. If not, see <http://www.gnu.org/licenses/>. *
38 ***************************************************************************/
44 #include <helper/time_support.h>
45 #include <jtag/jtag.h>
46 #include <flash/nor/core.h>
49 #include "target_type.h"
50 #include "target_request.h"
51 #include "breakpoints.h"
55 #include "rtos/rtos.h"
56 #include "transport/transport.h"
59 /* default halt wait timeout (ms) */
60 #define DEFAULT_HALT_TIMEOUT 5000
62 static int target_read_buffer_default(struct target
*target
, target_addr_t address
,
63 uint32_t count
, uint8_t *buffer
);
64 static int target_write_buffer_default(struct target
*target
, target_addr_t address
,
65 uint32_t count
, const uint8_t *buffer
);
66 static int target_array2mem(Jim_Interp
*interp
, struct target
*target
,
67 int argc
, Jim_Obj
* const *argv
);
68 static int target_mem2array(Jim_Interp
*interp
, struct target
*target
,
69 int argc
, Jim_Obj
* const *argv
);
70 static int target_register_user_commands(struct command_context
*cmd_ctx
);
71 static int target_get_gdb_fileio_info_default(struct target
*target
,
72 struct gdb_fileio_info
*fileio_info
);
73 static int target_gdb_fileio_end_default(struct target
*target
, int retcode
,
74 int fileio_errno
, bool ctrl_c
);
75 static int target_profiling_default(struct target
*target
, uint32_t *samples
,
76 uint32_t max_num_samples
, uint32_t *num_samples
, uint32_t seconds
);
79 extern struct target_type arm7tdmi_target
;
80 extern struct target_type arm720t_target
;
81 extern struct target_type arm9tdmi_target
;
82 extern struct target_type arm920t_target
;
83 extern struct target_type arm966e_target
;
84 extern struct target_type arm946e_target
;
85 extern struct target_type arm926ejs_target
;
86 extern struct target_type fa526_target
;
87 extern struct target_type feroceon_target
;
88 extern struct target_type dragonite_target
;
89 extern struct target_type xscale_target
;
90 extern struct target_type cortexm_target
;
91 extern struct target_type cortexa_target
;
92 extern struct target_type aarch64_target
;
93 extern struct target_type cortexr4_target
;
94 extern struct target_type arm11_target
;
95 extern struct target_type ls1_sap_target
;
96 extern struct target_type mips_m4k_target
;
97 extern struct target_type avr_target
;
98 extern struct target_type dsp563xx_target
;
99 extern struct target_type dsp5680xx_target
;
100 extern struct target_type testee_target
;
101 extern struct target_type avr32_ap7k_target
;
102 extern struct target_type hla_target
;
103 extern struct target_type nds32_v2_target
;
104 extern struct target_type nds32_v3_target
;
105 extern struct target_type nds32_v3m_target
;
106 extern struct target_type or1k_target
;
107 extern struct target_type quark_x10xx_target
;
108 extern struct target_type quark_d20xx_target
;
109 extern struct target_type stm8_target
;
111 static struct target_type
*target_types
[] = {
148 struct target
*all_targets
;
149 static struct target_event_callback
*target_event_callbacks
;
150 static struct target_timer_callback
*target_timer_callbacks
;
151 LIST_HEAD(target_reset_callback_list
);
152 LIST_HEAD(target_trace_callback_list
);
153 static const int polling_interval
= 100;
155 static const Jim_Nvp nvp_assert
[] = {
156 { .name
= "assert", NVP_ASSERT
},
157 { .name
= "deassert", NVP_DEASSERT
},
158 { .name
= "T", NVP_ASSERT
},
159 { .name
= "F", NVP_DEASSERT
},
160 { .name
= "t", NVP_ASSERT
},
161 { .name
= "f", NVP_DEASSERT
},
162 { .name
= NULL
, .value
= -1 }
165 static const Jim_Nvp nvp_error_target
[] = {
166 { .value
= ERROR_TARGET_INVALID
, .name
= "err-invalid" },
167 { .value
= ERROR_TARGET_INIT_FAILED
, .name
= "err-init-failed" },
168 { .value
= ERROR_TARGET_TIMEOUT
, .name
= "err-timeout" },
169 { .value
= ERROR_TARGET_NOT_HALTED
, .name
= "err-not-halted" },
170 { .value
= ERROR_TARGET_FAILURE
, .name
= "err-failure" },
171 { .value
= ERROR_TARGET_UNALIGNED_ACCESS
, .name
= "err-unaligned-access" },
172 { .value
= ERROR_TARGET_DATA_ABORT
, .name
= "err-data-abort" },
173 { .value
= ERROR_TARGET_RESOURCE_NOT_AVAILABLE
, .name
= "err-resource-not-available" },
174 { .value
= ERROR_TARGET_TRANSLATION_FAULT
, .name
= "err-translation-fault" },
175 { .value
= ERROR_TARGET_NOT_RUNNING
, .name
= "err-not-running" },
176 { .value
= ERROR_TARGET_NOT_EXAMINED
, .name
= "err-not-examined" },
177 { .value
= -1, .name
= NULL
}
180 static const char *target_strerror_safe(int err
)
184 n
= Jim_Nvp_value2name_simple(nvp_error_target
, err
);
191 static const Jim_Nvp nvp_target_event
[] = {
193 { .value
= TARGET_EVENT_GDB_HALT
, .name
= "gdb-halt" },
194 { .value
= TARGET_EVENT_HALTED
, .name
= "halted" },
195 { .value
= TARGET_EVENT_RESUMED
, .name
= "resumed" },
196 { .value
= TARGET_EVENT_RESUME_START
, .name
= "resume-start" },
197 { .value
= TARGET_EVENT_RESUME_END
, .name
= "resume-end" },
199 { .name
= "gdb-start", .value
= TARGET_EVENT_GDB_START
},
200 { .name
= "gdb-end", .value
= TARGET_EVENT_GDB_END
},
202 { .value
= TARGET_EVENT_RESET_START
, .name
= "reset-start" },
203 { .value
= TARGET_EVENT_RESET_ASSERT_PRE
, .name
= "reset-assert-pre" },
204 { .value
= TARGET_EVENT_RESET_ASSERT
, .name
= "reset-assert" },
205 { .value
= TARGET_EVENT_RESET_ASSERT_POST
, .name
= "reset-assert-post" },
206 { .value
= TARGET_EVENT_RESET_DEASSERT_PRE
, .name
= "reset-deassert-pre" },
207 { .value
= TARGET_EVENT_RESET_DEASSERT_POST
, .name
= "reset-deassert-post" },
208 { .value
= TARGET_EVENT_RESET_INIT
, .name
= "reset-init" },
209 { .value
= TARGET_EVENT_RESET_END
, .name
= "reset-end" },
211 { .value
= TARGET_EVENT_EXAMINE_START
, .name
= "examine-start" },
212 { .value
= TARGET_EVENT_EXAMINE_END
, .name
= "examine-end" },
214 { .value
= TARGET_EVENT_DEBUG_HALTED
, .name
= "debug-halted" },
215 { .value
= TARGET_EVENT_DEBUG_RESUMED
, .name
= "debug-resumed" },
217 { .value
= TARGET_EVENT_GDB_ATTACH
, .name
= "gdb-attach" },
218 { .value
= TARGET_EVENT_GDB_DETACH
, .name
= "gdb-detach" },
220 { .value
= TARGET_EVENT_GDB_FLASH_WRITE_START
, .name
= "gdb-flash-write-start" },
221 { .value
= TARGET_EVENT_GDB_FLASH_WRITE_END
, .name
= "gdb-flash-write-end" },
223 { .value
= TARGET_EVENT_GDB_FLASH_ERASE_START
, .name
= "gdb-flash-erase-start" },
224 { .value
= TARGET_EVENT_GDB_FLASH_ERASE_END
, .name
= "gdb-flash-erase-end" },
226 { .value
= TARGET_EVENT_TRACE_CONFIG
, .name
= "trace-config" },
228 { .name
= NULL
, .value
= -1 }
231 static const Jim_Nvp nvp_target_state
[] = {
232 { .name
= "unknown", .value
= TARGET_UNKNOWN
},
233 { .name
= "running", .value
= TARGET_RUNNING
},
234 { .name
= "halted", .value
= TARGET_HALTED
},
235 { .name
= "reset", .value
= TARGET_RESET
},
236 { .name
= "debug-running", .value
= TARGET_DEBUG_RUNNING
},
237 { .name
= NULL
, .value
= -1 },
240 static const Jim_Nvp nvp_target_debug_reason
[] = {
241 { .name
= "debug-request" , .value
= DBG_REASON_DBGRQ
},
242 { .name
= "breakpoint" , .value
= DBG_REASON_BREAKPOINT
},
243 { .name
= "watchpoint" , .value
= DBG_REASON_WATCHPOINT
},
244 { .name
= "watchpoint-and-breakpoint", .value
= DBG_REASON_WPTANDBKPT
},
245 { .name
= "single-step" , .value
= DBG_REASON_SINGLESTEP
},
246 { .name
= "target-not-halted" , .value
= DBG_REASON_NOTHALTED
},
247 { .name
= "program-exit" , .value
= DBG_REASON_EXIT
},
248 { .name
= "undefined" , .value
= DBG_REASON_UNDEFINED
},
249 { .name
= NULL
, .value
= -1 },
252 static const Jim_Nvp nvp_target_endian
[] = {
253 { .name
= "big", .value
= TARGET_BIG_ENDIAN
},
254 { .name
= "little", .value
= TARGET_LITTLE_ENDIAN
},
255 { .name
= "be", .value
= TARGET_BIG_ENDIAN
},
256 { .name
= "le", .value
= TARGET_LITTLE_ENDIAN
},
257 { .name
= NULL
, .value
= -1 },
260 static const Jim_Nvp nvp_reset_modes
[] = {
261 { .name
= "unknown", .value
= RESET_UNKNOWN
},
262 { .name
= "run" , .value
= RESET_RUN
},
263 { .name
= "halt" , .value
= RESET_HALT
},
264 { .name
= "init" , .value
= RESET_INIT
},
265 { .name
= NULL
, .value
= -1 },
268 const char *debug_reason_name(struct target
*t
)
272 cp
= Jim_Nvp_value2name_simple(nvp_target_debug_reason
,
273 t
->debug_reason
)->name
;
275 LOG_ERROR("Invalid debug reason: %d", (int)(t
->debug_reason
));
276 cp
= "(*BUG*unknown*BUG*)";
281 const char *target_state_name(struct target
*t
)
284 cp
= Jim_Nvp_value2name_simple(nvp_target_state
, t
->state
)->name
;
286 LOG_ERROR("Invalid target state: %d", (int)(t
->state
));
287 cp
= "(*BUG*unknown*BUG*)";
290 if (!target_was_examined(t
) && t
->defer_examine
)
291 cp
= "examine deferred";
296 const char *target_event_name(enum target_event event
)
299 cp
= Jim_Nvp_value2name_simple(nvp_target_event
, event
)->name
;
301 LOG_ERROR("Invalid target event: %d", (int)(event
));
302 cp
= "(*BUG*unknown*BUG*)";
307 const char *target_reset_mode_name(enum target_reset_mode reset_mode
)
310 cp
= Jim_Nvp_value2name_simple(nvp_reset_modes
, reset_mode
)->name
;
312 LOG_ERROR("Invalid target reset mode: %d", (int)(reset_mode
));
313 cp
= "(*BUG*unknown*BUG*)";
318 /* determine the number of the new target */
319 static int new_target_number(void)
324 /* number is 0 based */
328 if (x
< t
->target_number
)
329 x
= t
->target_number
;
335 /* read a uint64_t from a buffer in target memory endianness */
336 uint64_t target_buffer_get_u64(struct target
*target
, const uint8_t *buffer
)
338 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
339 return le_to_h_u64(buffer
);
341 return be_to_h_u64(buffer
);
344 /* read a uint32_t from a buffer in target memory endianness */
345 uint32_t target_buffer_get_u32(struct target
*target
, const uint8_t *buffer
)
347 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
348 return le_to_h_u32(buffer
);
350 return be_to_h_u32(buffer
);
353 /* read a uint24_t from a buffer in target memory endianness */
354 uint32_t target_buffer_get_u24(struct target
*target
, const uint8_t *buffer
)
356 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
357 return le_to_h_u24(buffer
);
359 return be_to_h_u24(buffer
);
362 /* read a uint16_t from a buffer in target memory endianness */
363 uint16_t target_buffer_get_u16(struct target
*target
, const uint8_t *buffer
)
365 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
366 return le_to_h_u16(buffer
);
368 return be_to_h_u16(buffer
);
371 /* read a uint8_t from a buffer in target memory endianness */
372 static uint8_t target_buffer_get_u8(struct target
*target
, const uint8_t *buffer
)
374 return *buffer
& 0x0ff;
377 /* write a uint64_t to a buffer in target memory endianness */
378 void target_buffer_set_u64(struct target
*target
, uint8_t *buffer
, uint64_t value
)
380 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
381 h_u64_to_le(buffer
, value
);
383 h_u64_to_be(buffer
, value
);
386 /* write a uint32_t to a buffer in target memory endianness */
387 void target_buffer_set_u32(struct target
*target
, uint8_t *buffer
, uint32_t value
)
389 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
390 h_u32_to_le(buffer
, value
);
392 h_u32_to_be(buffer
, value
);
395 /* write a uint24_t to a buffer in target memory endianness */
396 void target_buffer_set_u24(struct target
*target
, uint8_t *buffer
, uint32_t value
)
398 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
399 h_u24_to_le(buffer
, value
);
401 h_u24_to_be(buffer
, value
);
404 /* write a uint16_t to a buffer in target memory endianness */
405 void target_buffer_set_u16(struct target
*target
, uint8_t *buffer
, uint16_t value
)
407 if (target
->endianness
== TARGET_LITTLE_ENDIAN
)
408 h_u16_to_le(buffer
, value
);
410 h_u16_to_be(buffer
, value
);
413 /* write a uint8_t to a buffer in target memory endianness */
414 static void target_buffer_set_u8(struct target
*target
, uint8_t *buffer
, uint8_t value
)
419 /* write a uint64_t array to a buffer in target memory endianness */
420 void target_buffer_get_u64_array(struct target
*target
, const uint8_t *buffer
, uint32_t count
, uint64_t *dstbuf
)
423 for (i
= 0; i
< count
; i
++)
424 dstbuf
[i
] = target_buffer_get_u64(target
, &buffer
[i
* 8]);
427 /* write a uint32_t array to a buffer in target memory endianness */
428 void target_buffer_get_u32_array(struct target
*target
, const uint8_t *buffer
, uint32_t count
, uint32_t *dstbuf
)
431 for (i
= 0; i
< count
; i
++)
432 dstbuf
[i
] = target_buffer_get_u32(target
, &buffer
[i
* 4]);
435 /* write a uint16_t array to a buffer in target memory endianness */
436 void target_buffer_get_u16_array(struct target
*target
, const uint8_t *buffer
, uint32_t count
, uint16_t *dstbuf
)
439 for (i
= 0; i
< count
; i
++)
440 dstbuf
[i
] = target_buffer_get_u16(target
, &buffer
[i
* 2]);
443 /* write a uint64_t array to a buffer in target memory endianness */
444 void target_buffer_set_u64_array(struct target
*target
, uint8_t *buffer
, uint32_t count
, const uint64_t *srcbuf
)
447 for (i
= 0; i
< count
; i
++)
448 target_buffer_set_u64(target
, &buffer
[i
* 8], srcbuf
[i
]);
451 /* write a uint32_t array to a buffer in target memory endianness */
452 void target_buffer_set_u32_array(struct target
*target
, uint8_t *buffer
, uint32_t count
, const uint32_t *srcbuf
)
455 for (i
= 0; i
< count
; i
++)
456 target_buffer_set_u32(target
, &buffer
[i
* 4], srcbuf
[i
]);
459 /* write a uint16_t array to a buffer in target memory endianness */
460 void target_buffer_set_u16_array(struct target
*target
, uint8_t *buffer
, uint32_t count
, const uint16_t *srcbuf
)
463 for (i
= 0; i
< count
; i
++)
464 target_buffer_set_u16(target
, &buffer
[i
* 2], srcbuf
[i
]);
467 /* return a pointer to a configured target; id is name or number */
468 struct target
*get_target(const char *id
)
470 struct target
*target
;
472 /* try as tcltarget name */
473 for (target
= all_targets
; target
; target
= target
->next
) {
474 if (target_name(target
) == NULL
)
476 if (strcmp(id
, target_name(target
)) == 0)
480 /* It's OK to remove this fallback sometime after August 2010 or so */
482 /* no match, try as number */
484 if (parse_uint(id
, &num
) != ERROR_OK
)
487 for (target
= all_targets
; target
; target
= target
->next
) {
488 if (target
->target_number
== (int)num
) {
489 LOG_WARNING("use '%s' as target identifier, not '%u'",
490 target_name(target
), num
);
498 /* returns a pointer to the n-th configured target */
499 struct target
*get_target_by_num(int num
)
501 struct target
*target
= all_targets
;
504 if (target
->target_number
== num
)
506 target
= target
->next
;
512 struct target
*get_current_target(struct command_context
*cmd_ctx
)
514 struct target
*target
= cmd_ctx
->current_target_override
515 ? cmd_ctx
->current_target_override
516 : cmd_ctx
->current_target
;
518 if (target
== NULL
) {
519 LOG_ERROR("BUG: current_target out of bounds");
526 int target_poll(struct target
*target
)
530 /* We can't poll until after examine */
531 if (!target_was_examined(target
)) {
532 /* Fail silently lest we pollute the log */
536 retval
= target
->type
->poll(target
);
537 if (retval
!= ERROR_OK
)
540 if (target
->halt_issued
) {
541 if (target
->state
== TARGET_HALTED
)
542 target
->halt_issued
= false;
544 int64_t t
= timeval_ms() - target
->halt_issued_time
;
545 if (t
> DEFAULT_HALT_TIMEOUT
) {
546 target
->halt_issued
= false;
547 LOG_INFO("Halt timed out, wake up GDB.");
548 target_call_event_callbacks(target
, TARGET_EVENT_GDB_HALT
);
556 int target_halt(struct target
*target
)
559 /* We can't poll until after examine */
560 if (!target_was_examined(target
)) {
561 LOG_ERROR("Target not examined yet");
565 retval
= target
->type
->halt(target
);
566 if (retval
!= ERROR_OK
)
569 target
->halt_issued
= true;
570 target
->halt_issued_time
= timeval_ms();
576 * Make the target (re)start executing using its saved execution
577 * context (possibly with some modifications).
579 * @param target Which target should start executing.
580 * @param current True to use the target's saved program counter instead
581 * of the address parameter
582 * @param address Optionally used as the program counter.
583 * @param handle_breakpoints True iff breakpoints at the resumption PC
584 * should be skipped. (For example, maybe execution was stopped by
585 * such a breakpoint, in which case it would be counterprodutive to
587 * @param debug_execution False if all working areas allocated by OpenOCD
588 * should be released and/or restored to their original contents.
589 * (This would for example be true to run some downloaded "helper"
590 * algorithm code, which resides in one such working buffer and uses
591 * another for data storage.)
593 * @todo Resolve the ambiguity about what the "debug_execution" flag
594 * signifies. For example, Target implementations don't agree on how
595 * it relates to invalidation of the register cache, or to whether
596 * breakpoints and watchpoints should be enabled. (It would seem wrong
597 * to enable breakpoints when running downloaded "helper" algorithms
598 * (debug_execution true), since the breakpoints would be set to match
599 * target firmware being debugged, not the helper algorithm.... and
600 * enabling them could cause such helpers to malfunction (for example,
601 * by overwriting data with a breakpoint instruction. On the other
602 * hand the infrastructure for running such helpers might use this
603 * procedure but rely on hardware breakpoint to detect termination.)
605 int target_resume(struct target
*target
, int current
, target_addr_t address
,
606 int handle_breakpoints
, int debug_execution
)
610 /* We can't poll until after examine */
611 if (!target_was_examined(target
)) {
612 LOG_ERROR("Target not examined yet");
616 target_call_event_callbacks(target
, TARGET_EVENT_RESUME_START
);
618 /* note that resume *must* be asynchronous. The CPU can halt before
619 * we poll. The CPU can even halt at the current PC as a result of
620 * a software breakpoint being inserted by (a bug?) the application.
622 retval
= target
->type
->resume(target
, current
, address
, handle_breakpoints
, debug_execution
);
623 if (retval
!= ERROR_OK
)
626 target_call_event_callbacks(target
, TARGET_EVENT_RESUME_END
);
631 static int target_process_reset(struct command_context
*cmd_ctx
, enum target_reset_mode reset_mode
)
636 n
= Jim_Nvp_value2name_simple(nvp_reset_modes
, reset_mode
);
637 if (n
->name
== NULL
) {
638 LOG_ERROR("invalid reset mode");
642 struct target
*target
;
643 for (target
= all_targets
; target
; target
= target
->next
)
644 target_call_reset_callbacks(target
, reset_mode
);
646 /* disable polling during reset to make reset event scripts
647 * more predictable, i.e. dr/irscan & pathmove in events will
648 * not have JTAG operations injected into the middle of a sequence.
650 bool save_poll
= jtag_poll_get_enabled();
652 jtag_poll_set_enabled(false);
654 sprintf(buf
, "ocd_process_reset %s", n
->name
);
655 retval
= Jim_Eval(cmd_ctx
->interp
, buf
);
657 jtag_poll_set_enabled(save_poll
);
659 if (retval
!= JIM_OK
) {
660 Jim_MakeErrorMessage(cmd_ctx
->interp
);
661 command_print(NULL
, "%s\n", Jim_GetString(Jim_GetResult(cmd_ctx
->interp
), NULL
));
665 /* We want any events to be processed before the prompt */
666 retval
= target_call_timer_callbacks_now();
668 for (target
= all_targets
; target
; target
= target
->next
) {
669 target
->type
->check_reset(target
);
670 target
->running_alg
= false;
676 static int identity_virt2phys(struct target
*target
,
677 target_addr_t
virtual, target_addr_t
*physical
)
683 static int no_mmu(struct target
*target
, int *enabled
)
689 static int default_examine(struct target
*target
)
691 target_set_examined(target
);
695 /* no check by default */
696 static int default_check_reset(struct target
*target
)
701 int target_examine_one(struct target
*target
)
703 target_call_event_callbacks(target
, TARGET_EVENT_EXAMINE_START
);
705 int retval
= target
->type
->examine(target
);
706 if (retval
!= ERROR_OK
)
709 target_call_event_callbacks(target
, TARGET_EVENT_EXAMINE_END
);
714 static int jtag_enable_callback(enum jtag_event event
, void *priv
)
716 struct target
*target
= priv
;
718 if (event
!= JTAG_TAP_EVENT_ENABLE
|| !target
->tap
->enabled
)
721 jtag_unregister_event_callback(jtag_enable_callback
, target
);
723 return target_examine_one(target
);
726 /* Targets that correctly implement init + examine, i.e.
727 * no communication with target during init:
731 int target_examine(void)
733 int retval
= ERROR_OK
;
734 struct target
*target
;
736 for (target
= all_targets
; target
; target
= target
->next
) {
737 /* defer examination, but don't skip it */
738 if (!target
->tap
->enabled
) {
739 jtag_register_event_callback(jtag_enable_callback
,
744 if (target
->defer_examine
)
747 retval
= target_examine_one(target
);
748 if (retval
!= ERROR_OK
)
754 const char *target_type_name(struct target
*target
)
756 return target
->type
->name
;
759 static int target_soft_reset_halt(struct target
*target
)
761 if (!target_was_examined(target
)) {
762 LOG_ERROR("Target not examined yet");
765 if (!target
->type
->soft_reset_halt
) {
766 LOG_ERROR("Target %s does not support soft_reset_halt",
767 target_name(target
));
770 return target
->type
->soft_reset_halt(target
);
774 * Downloads a target-specific native code algorithm to the target,
775 * and executes it. * Note that some targets may need to set up, enable,
776 * and tear down a breakpoint (hard or * soft) to detect algorithm
777 * termination, while others may support lower overhead schemes where
778 * soft breakpoints embedded in the algorithm automatically terminate the
781 * @param target used to run the algorithm
782 * @param arch_info target-specific description of the algorithm.
784 int target_run_algorithm(struct target
*target
,
785 int num_mem_params
, struct mem_param
*mem_params
,
786 int num_reg_params
, struct reg_param
*reg_param
,
787 uint32_t entry_point
, uint32_t exit_point
,
788 int timeout_ms
, void *arch_info
)
790 int retval
= ERROR_FAIL
;
792 if (!target_was_examined(target
)) {
793 LOG_ERROR("Target not examined yet");
796 if (!target
->type
->run_algorithm
) {
797 LOG_ERROR("Target type '%s' does not support %s",
798 target_type_name(target
), __func__
);
802 target
->running_alg
= true;
803 retval
= target
->type
->run_algorithm(target
,
804 num_mem_params
, mem_params
,
805 num_reg_params
, reg_param
,
806 entry_point
, exit_point
, timeout_ms
, arch_info
);
807 target
->running_alg
= false;
814 * Executes a target-specific native code algorithm and leaves it running.
816 * @param target used to run the algorithm
817 * @param arch_info target-specific description of the algorithm.
819 int target_start_algorithm(struct target
*target
,
820 int num_mem_params
, struct mem_param
*mem_params
,
821 int num_reg_params
, struct reg_param
*reg_params
,
822 uint32_t entry_point
, uint32_t exit_point
,
825 int retval
= ERROR_FAIL
;
827 if (!target_was_examined(target
)) {
828 LOG_ERROR("Target not examined yet");
831 if (!target
->type
->start_algorithm
) {
832 LOG_ERROR("Target type '%s' does not support %s",
833 target_type_name(target
), __func__
);
836 if (target
->running_alg
) {
837 LOG_ERROR("Target is already running an algorithm");
841 target
->running_alg
= true;
842 retval
= target
->type
->start_algorithm(target
,
843 num_mem_params
, mem_params
,
844 num_reg_params
, reg_params
,
845 entry_point
, exit_point
, arch_info
);
852 * Waits for an algorithm started with target_start_algorithm() to complete.
854 * @param target used to run the algorithm
855 * @param arch_info target-specific description of the algorithm.
857 int target_wait_algorithm(struct target
*target
,
858 int num_mem_params
, struct mem_param
*mem_params
,
859 int num_reg_params
, struct reg_param
*reg_params
,
860 uint32_t exit_point
, int timeout_ms
,
863 int retval
= ERROR_FAIL
;
865 if (!target
->type
->wait_algorithm
) {
866 LOG_ERROR("Target type '%s' does not support %s",
867 target_type_name(target
), __func__
);
870 if (!target
->running_alg
) {
871 LOG_ERROR("Target is not running an algorithm");
875 retval
= target
->type
->wait_algorithm(target
,
876 num_mem_params
, mem_params
,
877 num_reg_params
, reg_params
,
878 exit_point
, timeout_ms
, arch_info
);
879 if (retval
!= ERROR_TARGET_TIMEOUT
)
880 target
->running_alg
= false;
887 * Streams data to a circular buffer on target intended for consumption by code
888 * running asynchronously on target.
890 * This is intended for applications where target-specific native code runs
891 * on the target, receives data from the circular buffer, does something with
892 * it (most likely writing it to a flash memory), and advances the circular
895 * This assumes that the helper algorithm has already been loaded to the target,
896 * but has not been started yet. Given memory and register parameters are passed
899 * The buffer is defined by (buffer_start, buffer_size) arguments and has the
902 * [buffer_start + 0, buffer_start + 4):
903 * Write Pointer address (aka head). Written and updated by this
904 * routine when new data is written to the circular buffer.
905 * [buffer_start + 4, buffer_start + 8):
906 * Read Pointer address (aka tail). Updated by code running on the
907 * target after it consumes data.
908 * [buffer_start + 8, buffer_start + buffer_size):
909 * Circular buffer contents.
911 * See contrib/loaders/flash/stm32f1x.S for an example.
913 * @param target used to run the algorithm
914 * @param buffer address on the host where data to be sent is located
915 * @param count number of blocks to send
916 * @param block_size size in bytes of each block
917 * @param num_mem_params count of memory-based params to pass to algorithm
918 * @param mem_params memory-based params to pass to algorithm
919 * @param num_reg_params count of register-based params to pass to algorithm
920 * @param reg_params memory-based params to pass to algorithm
921 * @param buffer_start address on the target of the circular buffer structure
922 * @param buffer_size size of the circular buffer structure
923 * @param entry_point address on the target to execute to start the algorithm
924 * @param exit_point address at which to set a breakpoint to catch the
925 * end of the algorithm; can be 0 if target triggers a breakpoint itself
928 int target_run_flash_async_algorithm(struct target
*target
,
929 const uint8_t *buffer
, uint32_t count
, int block_size
,
930 int num_mem_params
, struct mem_param
*mem_params
,
931 int num_reg_params
, struct reg_param
*reg_params
,
932 uint32_t buffer_start
, uint32_t buffer_size
,
933 uint32_t entry_point
, uint32_t exit_point
, void *arch_info
)
938 const uint8_t *buffer_orig
= buffer
;
940 /* Set up working area. First word is write pointer, second word is read pointer,
941 * rest is fifo data area. */
942 uint32_t wp_addr
= buffer_start
;
943 uint32_t rp_addr
= buffer_start
+ 4;
944 uint32_t fifo_start_addr
= buffer_start
+ 8;
945 uint32_t fifo_end_addr
= buffer_start
+ buffer_size
;
947 uint32_t wp
= fifo_start_addr
;
948 uint32_t rp
= fifo_start_addr
;
950 /* validate block_size is 2^n */
951 assert(!block_size
|| !(block_size
& (block_size
- 1)));
953 retval
= target_write_u32(target
, wp_addr
, wp
);
954 if (retval
!= ERROR_OK
)
956 retval
= target_write_u32(target
, rp_addr
, rp
);
957 if (retval
!= ERROR_OK
)
960 /* Start up algorithm on target and let it idle while writing the first chunk */
961 retval
= target_start_algorithm(target
, num_mem_params
, mem_params
,
962 num_reg_params
, reg_params
,
967 if (retval
!= ERROR_OK
) {
968 LOG_ERROR("error starting target flash write algorithm");
974 retval
= target_read_u32(target
, rp_addr
, &rp
);
975 if (retval
!= ERROR_OK
) {
976 LOG_ERROR("failed to get read pointer");
980 LOG_DEBUG("offs 0x%zx count 0x%" PRIx32
" wp 0x%" PRIx32
" rp 0x%" PRIx32
,
981 (size_t) (buffer
- buffer_orig
), count
, wp
, rp
);
984 LOG_ERROR("flash write algorithm aborted by target");
985 retval
= ERROR_FLASH_OPERATION_FAILED
;
989 if (((rp
- fifo_start_addr
) & (block_size
- 1)) || rp
< fifo_start_addr
|| rp
>= fifo_end_addr
) {
990 LOG_ERROR("corrupted fifo read pointer 0x%" PRIx32
, rp
);
994 /* Count the number of bytes available in the fifo without
995 * crossing the wrap around. Make sure to not fill it completely,
996 * because that would make wp == rp and that's the empty condition. */
997 uint32_t thisrun_bytes
;
999 thisrun_bytes
= rp
- wp
- block_size
;
1000 else if (rp
> fifo_start_addr
)
1001 thisrun_bytes
= fifo_end_addr
- wp
;
1003 thisrun_bytes
= fifo_end_addr
- wp
- block_size
;
1005 if (thisrun_bytes
== 0) {
1006 /* Throttle polling a bit if transfer is (much) faster than flash
1007 * programming. The exact delay shouldn't matter as long as it's
1008 * less than buffer size / flash speed. This is very unlikely to
1009 * run when using high latency connections such as USB. */
1012 /* to stop an infinite loop on some targets check and increment a timeout
1013 * this issue was observed on a stellaris using the new ICDI interface */
1014 if (timeout
++ >= 500) {
1015 LOG_ERROR("timeout waiting for algorithm, a target reset is recommended");
1016 return ERROR_FLASH_OPERATION_FAILED
;
1021 /* reset our timeout */
1024 /* Limit to the amount of data we actually want to write */
1025 if (thisrun_bytes
> count
* block_size
)
1026 thisrun_bytes
= count
* block_size
;
1028 /* Write data to fifo */
1029 retval
= target_write_buffer(target
, wp
, thisrun_bytes
, buffer
);
1030 if (retval
!= ERROR_OK
)
1033 /* Update counters and wrap write pointer */
1034 buffer
+= thisrun_bytes
;
1035 count
-= thisrun_bytes
/ block_size
;
1036 wp
+= thisrun_bytes
;
1037 if (wp
>= fifo_end_addr
)
1038 wp
= fifo_start_addr
;
1040 /* Store updated write pointer to target */
1041 retval
= target_write_u32(target
, wp_addr
, wp
);
1042 if (retval
!= ERROR_OK
)
1046 if (retval
!= ERROR_OK
) {
1047 /* abort flash write algorithm on target */
1048 target_write_u32(target
, wp_addr
, 0);
1051 int retval2
= target_wait_algorithm(target
, num_mem_params
, mem_params
,
1052 num_reg_params
, reg_params
,
1057 if (retval2
!= ERROR_OK
) {
1058 LOG_ERROR("error waiting for target flash write algorithm");
1062 if (retval
== ERROR_OK
) {
1063 /* check if algorithm set rp = 0 after fifo writer loop finished */
1064 retval
= target_read_u32(target
, rp_addr
, &rp
);
1065 if (retval
== ERROR_OK
&& rp
== 0) {
1066 LOG_ERROR("flash write algorithm aborted by target");
1067 retval
= ERROR_FLASH_OPERATION_FAILED
;
1074 int target_read_memory(struct target
*target
,
1075 target_addr_t address
, uint32_t size
, uint32_t count
, uint8_t *buffer
)
1077 if (!target_was_examined(target
)) {
1078 LOG_ERROR("Target not examined yet");
1081 if (!target
->type
->read_memory
) {
1082 LOG_ERROR("Target %s doesn't support read_memory", target_name(target
));
1085 return target
->type
->read_memory(target
, address
, size
, count
, buffer
);
1088 int target_read_phys_memory(struct target
*target
,
1089 target_addr_t address
, uint32_t size
, uint32_t count
, uint8_t *buffer
)
1091 if (!target_was_examined(target
)) {
1092 LOG_ERROR("Target not examined yet");
1095 if (!target
->type
->read_phys_memory
) {
1096 LOG_ERROR("Target %s doesn't support read_phys_memory", target_name(target
));
1099 return target
->type
->read_phys_memory(target
, address
, size
, count
, buffer
);
1102 int target_write_memory(struct target
*target
,
1103 target_addr_t address
, uint32_t size
, uint32_t count
, const uint8_t *buffer
)
1105 if (!target_was_examined(target
)) {
1106 LOG_ERROR("Target not examined yet");
1109 if (!target
->type
->write_memory
) {
1110 LOG_ERROR("Target %s doesn't support write_memory", target_name(target
));
1113 return target
->type
->write_memory(target
, address
, size
, count
, buffer
);
1116 int target_write_phys_memory(struct target
*target
,
1117 target_addr_t address
, uint32_t size
, uint32_t count
, const uint8_t *buffer
)
1119 if (!target_was_examined(target
)) {
1120 LOG_ERROR("Target not examined yet");
1123 if (!target
->type
->write_phys_memory
) {
1124 LOG_ERROR("Target %s doesn't support write_phys_memory", target_name(target
));
1127 return target
->type
->write_phys_memory(target
, address
, size
, count
, buffer
);
1130 int target_add_breakpoint(struct target
*target
,
1131 struct breakpoint
*breakpoint
)
1133 if ((target
->state
!= TARGET_HALTED
) && (breakpoint
->type
!= BKPT_HARD
)) {
1134 LOG_WARNING("target %s is not halted (add breakpoint)", target_name(target
));
1135 return ERROR_TARGET_NOT_HALTED
;
1137 return target
->type
->add_breakpoint(target
, breakpoint
);
1140 int target_add_context_breakpoint(struct target
*target
,
1141 struct breakpoint
*breakpoint
)
1143 if (target
->state
!= TARGET_HALTED
) {
1144 LOG_WARNING("target %s is not halted (add context breakpoint)", target_name(target
));
1145 return ERROR_TARGET_NOT_HALTED
;
1147 return target
->type
->add_context_breakpoint(target
, breakpoint
);
1150 int target_add_hybrid_breakpoint(struct target
*target
,
1151 struct breakpoint
*breakpoint
)
1153 if (target
->state
!= TARGET_HALTED
) {
1154 LOG_WARNING("target %s is not halted (add hybrid breakpoint)", target_name(target
));
1155 return ERROR_TARGET_NOT_HALTED
;
1157 return target
->type
->add_hybrid_breakpoint(target
, breakpoint
);
1160 int target_remove_breakpoint(struct target
*target
,
1161 struct breakpoint
*breakpoint
)
1163 return target
->type
->remove_breakpoint(target
, breakpoint
);
1166 int target_add_watchpoint(struct target
*target
,
1167 struct watchpoint
*watchpoint
)
1169 if (target
->state
!= TARGET_HALTED
) {
1170 LOG_WARNING("target %s is not halted (add watchpoint)", target_name(target
));
1171 return ERROR_TARGET_NOT_HALTED
;
1173 return target
->type
->add_watchpoint(target
, watchpoint
);
1175 int target_remove_watchpoint(struct target
*target
,
1176 struct watchpoint
*watchpoint
)
1178 return target
->type
->remove_watchpoint(target
, watchpoint
);
1180 int target_hit_watchpoint(struct target
*target
,
1181 struct watchpoint
**hit_watchpoint
)
1183 if (target
->state
!= TARGET_HALTED
) {
1184 LOG_WARNING("target %s is not halted (hit watchpoint)", target
->cmd_name
);
1185 return ERROR_TARGET_NOT_HALTED
;
1188 if (target
->type
->hit_watchpoint
== NULL
) {
1189 /* For backward compatible, if hit_watchpoint is not implemented,
1190 * return ERROR_FAIL such that gdb_server will not take the nonsense
1195 return target
->type
->hit_watchpoint(target
, hit_watchpoint
);
1198 int target_get_gdb_reg_list(struct target
*target
,
1199 struct reg
**reg_list
[], int *reg_list_size
,
1200 enum target_register_class reg_class
)
1202 return target
->type
->get_gdb_reg_list(target
, reg_list
, reg_list_size
, reg_class
);
1204 int target_step(struct target
*target
,
1205 int current
, target_addr_t address
, int handle_breakpoints
)
1207 return target
->type
->step(target
, current
, address
, handle_breakpoints
);
1210 int target_get_gdb_fileio_info(struct target
*target
, struct gdb_fileio_info
*fileio_info
)
1212 if (target
->state
!= TARGET_HALTED
) {
1213 LOG_WARNING("target %s is not halted (gdb fileio)", target
->cmd_name
);
1214 return ERROR_TARGET_NOT_HALTED
;
1216 return target
->type
->get_gdb_fileio_info(target
, fileio_info
);
1219 int target_gdb_fileio_end(struct target
*target
, int retcode
, int fileio_errno
, bool ctrl_c
)
1221 if (target
->state
!= TARGET_HALTED
) {
1222 LOG_WARNING("target %s is not halted (gdb fileio end)", target
->cmd_name
);
1223 return ERROR_TARGET_NOT_HALTED
;
1225 return target
->type
->gdb_fileio_end(target
, retcode
, fileio_errno
, ctrl_c
);
1228 int target_profiling(struct target
*target
, uint32_t *samples
,
1229 uint32_t max_num_samples
, uint32_t *num_samples
, uint32_t seconds
)
1231 if (target
->state
!= TARGET_HALTED
) {
1232 LOG_WARNING("target %s is not halted (profiling)", target
->cmd_name
);
1233 return ERROR_TARGET_NOT_HALTED
;
1235 return target
->type
->profiling(target
, samples
, max_num_samples
,
1236 num_samples
, seconds
);
1240 * Reset the @c examined flag for the given target.
1241 * Pure paranoia -- targets are zeroed on allocation.
1243 static void target_reset_examined(struct target
*target
)
1245 target
->examined
= false;
1248 static int handle_target(void *priv
);
1250 static int target_init_one(struct command_context
*cmd_ctx
,
1251 struct target
*target
)
1253 target_reset_examined(target
);
1255 struct target_type
*type
= target
->type
;
1256 if (type
->examine
== NULL
)
1257 type
->examine
= default_examine
;
1259 if (type
->check_reset
== NULL
)
1260 type
->check_reset
= default_check_reset
;
1262 assert(type
->init_target
!= NULL
);
1264 int retval
= type
->init_target(cmd_ctx
, target
);
1265 if (ERROR_OK
!= retval
) {
1266 LOG_ERROR("target '%s' init failed", target_name(target
));
1270 /* Sanity-check MMU support ... stub in what we must, to help
1271 * implement it in stages, but warn if we need to do so.
1274 if (type
->virt2phys
== NULL
) {
1275 LOG_ERROR("type '%s' is missing virt2phys", type
->name
);
1276 type
->virt2phys
= identity_virt2phys
;
1279 /* Make sure no-MMU targets all behave the same: make no
1280 * distinction between physical and virtual addresses, and
1281 * ensure that virt2phys() is always an identity mapping.
1283 if (type
->write_phys_memory
|| type
->read_phys_memory
|| type
->virt2phys
)
1284 LOG_WARNING("type '%s' has bad MMU hooks", type
->name
);
1287 type
->write_phys_memory
= type
->write_memory
;
1288 type
->read_phys_memory
= type
->read_memory
;
1289 type
->virt2phys
= identity_virt2phys
;
1292 if (target
->type
->read_buffer
== NULL
)
1293 target
->type
->read_buffer
= target_read_buffer_default
;
1295 if (target
->type
->write_buffer
== NULL
)
1296 target
->type
->write_buffer
= target_write_buffer_default
;
1298 if (target
->type
->get_gdb_fileio_info
== NULL
)
1299 target
->type
->get_gdb_fileio_info
= target_get_gdb_fileio_info_default
;
1301 if (target
->type
->gdb_fileio_end
== NULL
)
1302 target
->type
->gdb_fileio_end
= target_gdb_fileio_end_default
;
1304 if (target
->type
->profiling
== NULL
)
1305 target
->type
->profiling
= target_profiling_default
;
1310 static int target_init(struct command_context
*cmd_ctx
)
1312 struct target
*target
;
1315 for (target
= all_targets
; target
; target
= target
->next
) {
1316 retval
= target_init_one(cmd_ctx
, target
);
1317 if (ERROR_OK
!= retval
)
1324 retval
= target_register_user_commands(cmd_ctx
);
1325 if (ERROR_OK
!= retval
)
1328 retval
= target_register_timer_callback(&handle_target
,
1329 polling_interval
, 1, cmd_ctx
->interp
);
1330 if (ERROR_OK
!= retval
)
1336 COMMAND_HANDLER(handle_target_init_command
)
1341 return ERROR_COMMAND_SYNTAX_ERROR
;
1343 static bool target_initialized
;
1344 if (target_initialized
) {
1345 LOG_INFO("'target init' has already been called");
1348 target_initialized
= true;
1350 retval
= command_run_line(CMD_CTX
, "init_targets");
1351 if (ERROR_OK
!= retval
)
1354 retval
= command_run_line(CMD_CTX
, "init_target_events");
1355 if (ERROR_OK
!= retval
)
1358 retval
= command_run_line(CMD_CTX
, "init_board");
1359 if (ERROR_OK
!= retval
)
1362 LOG_DEBUG("Initializing targets...");
1363 return target_init(CMD_CTX
);
1366 int target_register_event_callback(int (*callback
)(struct target
*target
,
1367 enum target_event event
, void *priv
), void *priv
)
1369 struct target_event_callback
**callbacks_p
= &target_event_callbacks
;
1371 if (callback
== NULL
)
1372 return ERROR_COMMAND_SYNTAX_ERROR
;
1375 while ((*callbacks_p
)->next
)
1376 callbacks_p
= &((*callbacks_p
)->next
);
1377 callbacks_p
= &((*callbacks_p
)->next
);
1380 (*callbacks_p
) = malloc(sizeof(struct target_event_callback
));
1381 (*callbacks_p
)->callback
= callback
;
1382 (*callbacks_p
)->priv
= priv
;
1383 (*callbacks_p
)->next
= NULL
;
1388 int target_register_reset_callback(int (*callback
)(struct target
*target
,
1389 enum target_reset_mode reset_mode
, void *priv
), void *priv
)
1391 struct target_reset_callback
*entry
;
1393 if (callback
== NULL
)
1394 return ERROR_COMMAND_SYNTAX_ERROR
;
1396 entry
= malloc(sizeof(struct target_reset_callback
));
1397 if (entry
== NULL
) {
1398 LOG_ERROR("error allocating buffer for reset callback entry");
1399 return ERROR_COMMAND_SYNTAX_ERROR
;
1402 entry
->callback
= callback
;
1404 list_add(&entry
->list
, &target_reset_callback_list
);
1410 int target_register_trace_callback(int (*callback
)(struct target
*target
,
1411 size_t len
, uint8_t *data
, void *priv
), void *priv
)
1413 struct target_trace_callback
*entry
;
1415 if (callback
== NULL
)
1416 return ERROR_COMMAND_SYNTAX_ERROR
;
1418 entry
= malloc(sizeof(struct target_trace_callback
));
1419 if (entry
== NULL
) {
1420 LOG_ERROR("error allocating buffer for trace callback entry");
1421 return ERROR_COMMAND_SYNTAX_ERROR
;
1424 entry
->callback
= callback
;
1426 list_add(&entry
->list
, &target_trace_callback_list
);
1432 int target_register_timer_callback(int (*callback
)(void *priv
), int time_ms
, int periodic
, void *priv
)
1434 struct target_timer_callback
**callbacks_p
= &target_timer_callbacks
;
1436 if (callback
== NULL
)
1437 return ERROR_COMMAND_SYNTAX_ERROR
;
1440 while ((*callbacks_p
)->next
)
1441 callbacks_p
= &((*callbacks_p
)->next
);
1442 callbacks_p
= &((*callbacks_p
)->next
);
1445 (*callbacks_p
) = malloc(sizeof(struct target_timer_callback
));
1446 (*callbacks_p
)->callback
= callback
;
1447 (*callbacks_p
)->periodic
= periodic
;
1448 (*callbacks_p
)->time_ms
= time_ms
;
1449 (*callbacks_p
)->removed
= false;
1451 gettimeofday(&(*callbacks_p
)->when
, NULL
);
1452 timeval_add_time(&(*callbacks_p
)->when
, 0, time_ms
* 1000);
1454 (*callbacks_p
)->priv
= priv
;
1455 (*callbacks_p
)->next
= NULL
;
1460 int target_unregister_event_callback(int (*callback
)(struct target
*target
,
1461 enum target_event event
, void *priv
), void *priv
)
1463 struct target_event_callback
**p
= &target_event_callbacks
;
1464 struct target_event_callback
*c
= target_event_callbacks
;
1466 if (callback
== NULL
)
1467 return ERROR_COMMAND_SYNTAX_ERROR
;
1470 struct target_event_callback
*next
= c
->next
;
1471 if ((c
->callback
== callback
) && (c
->priv
== priv
)) {
1483 int target_unregister_reset_callback(int (*callback
)(struct target
*target
,
1484 enum target_reset_mode reset_mode
, void *priv
), void *priv
)
1486 struct target_reset_callback
*entry
;
1488 if (callback
== NULL
)
1489 return ERROR_COMMAND_SYNTAX_ERROR
;
1491 list_for_each_entry(entry
, &target_reset_callback_list
, list
) {
1492 if (entry
->callback
== callback
&& entry
->priv
== priv
) {
1493 list_del(&entry
->list
);
1502 int target_unregister_trace_callback(int (*callback
)(struct target
*target
,
1503 size_t len
, uint8_t *data
, void *priv
), void *priv
)
1505 struct target_trace_callback
*entry
;
1507 if (callback
== NULL
)
1508 return ERROR_COMMAND_SYNTAX_ERROR
;
1510 list_for_each_entry(entry
, &target_trace_callback_list
, list
) {
1511 if (entry
->callback
== callback
&& entry
->priv
== priv
) {
1512 list_del(&entry
->list
);
1521 int target_unregister_timer_callback(int (*callback
)(void *priv
), void *priv
)
1523 if (callback
== NULL
)
1524 return ERROR_COMMAND_SYNTAX_ERROR
;
1526 for (struct target_timer_callback
*c
= target_timer_callbacks
;
1528 if ((c
->callback
== callback
) && (c
->priv
== priv
)) {
1537 int target_call_event_callbacks(struct target
*target
, enum target_event event
)
1539 struct target_event_callback
*callback
= target_event_callbacks
;
1540 struct target_event_callback
*next_callback
;
1542 if (event
== TARGET_EVENT_HALTED
) {
1543 /* execute early halted first */
1544 target_call_event_callbacks(target
, TARGET_EVENT_GDB_HALT
);
1547 LOG_DEBUG("target event %i (%s)", event
,
1548 Jim_Nvp_value2name_simple(nvp_target_event
, event
)->name
);
1550 target_handle_event(target
, event
);
1553 next_callback
= callback
->next
;
1554 callback
->callback(target
, event
, callback
->priv
);
1555 callback
= next_callback
;
1561 int target_call_reset_callbacks(struct target
*target
, enum target_reset_mode reset_mode
)
1563 struct target_reset_callback
*callback
;
1565 LOG_DEBUG("target reset %i (%s)", reset_mode
,
1566 Jim_Nvp_value2name_simple(nvp_reset_modes
, reset_mode
)->name
);
1568 list_for_each_entry(callback
, &target_reset_callback_list
, list
)
1569 callback
->callback(target
, reset_mode
, callback
->priv
);
1574 int target_call_trace_callbacks(struct target
*target
, size_t len
, uint8_t *data
)
1576 struct target_trace_callback
*callback
;
1578 list_for_each_entry(callback
, &target_trace_callback_list
, list
)
1579 callback
->callback(target
, len
, data
, callback
->priv
);
1584 static int target_timer_callback_periodic_restart(
1585 struct target_timer_callback
*cb
, struct timeval
*now
)
1588 timeval_add_time(&cb
->when
, 0, cb
->time_ms
* 1000L);
1592 static int target_call_timer_callback(struct target_timer_callback
*cb
,
1593 struct timeval
*now
)
1595 cb
->callback(cb
->priv
);
1598 return target_timer_callback_periodic_restart(cb
, now
);
1600 return target_unregister_timer_callback(cb
->callback
, cb
->priv
);
1603 static int target_call_timer_callbacks_check_time(int checktime
)
1605 static bool callback_processing
;
1607 /* Do not allow nesting */
1608 if (callback_processing
)
1611 callback_processing
= true;
1616 gettimeofday(&now
, NULL
);
1618 /* Store an address of the place containing a pointer to the
1619 * next item; initially, that's a standalone "root of the
1620 * list" variable. */
1621 struct target_timer_callback
**callback
= &target_timer_callbacks
;
1623 if ((*callback
)->removed
) {
1624 struct target_timer_callback
*p
= *callback
;
1625 *callback
= (*callback
)->next
;
1630 bool call_it
= (*callback
)->callback
&&
1631 ((!checktime
&& (*callback
)->periodic
) ||
1632 timeval_compare(&now
, &(*callback
)->when
) >= 0);
1635 target_call_timer_callback(*callback
, &now
);
1637 callback
= &(*callback
)->next
;
1640 callback_processing
= false;
1644 int target_call_timer_callbacks(void)
1646 return target_call_timer_callbacks_check_time(1);
1649 /* invoke periodic callbacks immediately */
1650 int target_call_timer_callbacks_now(void)
1652 return target_call_timer_callbacks_check_time(0);
1655 /* Prints the working area layout for debug purposes */
1656 static void print_wa_layout(struct target
*target
)
1658 struct working_area
*c
= target
->working_areas
;
1661 LOG_DEBUG("%c%c " TARGET_ADDR_FMT
"-" TARGET_ADDR_FMT
" (%" PRIu32
" bytes)",
1662 c
->backup
? 'b' : ' ', c
->free
? ' ' : '*',
1663 c
->address
, c
->address
+ c
->size
- 1, c
->size
);
1668 /* Reduce area to size bytes, create a new free area from the remaining bytes, if any. */
1669 static void target_split_working_area(struct working_area
*area
, uint32_t size
)
1671 assert(area
->free
); /* Shouldn't split an allocated area */
1672 assert(size
<= area
->size
); /* Caller should guarantee this */
1674 /* Split only if not already the right size */
1675 if (size
< area
->size
) {
1676 struct working_area
*new_wa
= malloc(sizeof(*new_wa
));
1681 new_wa
->next
= area
->next
;
1682 new_wa
->size
= area
->size
- size
;
1683 new_wa
->address
= area
->address
+ size
;
1684 new_wa
->backup
= NULL
;
1685 new_wa
->user
= NULL
;
1686 new_wa
->free
= true;
1688 area
->next
= new_wa
;
1691 /* If backup memory was allocated to this area, it has the wrong size
1692 * now so free it and it will be reallocated if/when needed */
1695 area
->backup
= NULL
;
1700 /* Merge all adjacent free areas into one */
1701 static void target_merge_working_areas(struct target
*target
)
1703 struct working_area
*c
= target
->working_areas
;
1705 while (c
&& c
->next
) {
1706 assert(c
->next
->address
== c
->address
+ c
->size
); /* This is an invariant */
1708 /* Find two adjacent free areas */
1709 if (c
->free
&& c
->next
->free
) {
1710 /* Merge the last into the first */
1711 c
->size
+= c
->next
->size
;
1713 /* Remove the last */
1714 struct working_area
*to_be_freed
= c
->next
;
1715 c
->next
= c
->next
->next
;
1716 if (to_be_freed
->backup
)
1717 free(to_be_freed
->backup
);
1720 /* If backup memory was allocated to the remaining area, it's has
1721 * the wrong size now */
1732 int target_alloc_working_area_try(struct target
*target
, uint32_t size
, struct working_area
**area
)
1734 /* Reevaluate working area address based on MMU state*/
1735 if (target
->working_areas
== NULL
) {
1739 retval
= target
->type
->mmu(target
, &enabled
);
1740 if (retval
!= ERROR_OK
)
1744 if (target
->working_area_phys_spec
) {
1745 LOG_DEBUG("MMU disabled, using physical "
1746 "address for working memory " TARGET_ADDR_FMT
,
1747 target
->working_area_phys
);
1748 target
->working_area
= target
->working_area_phys
;
1750 LOG_ERROR("No working memory available. "
1751 "Specify -work-area-phys to target.");
1752 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1755 if (target
->working_area_virt_spec
) {
1756 LOG_DEBUG("MMU enabled, using virtual "
1757 "address for working memory " TARGET_ADDR_FMT
,
1758 target
->working_area_virt
);
1759 target
->working_area
= target
->working_area_virt
;
1761 LOG_ERROR("No working memory available. "
1762 "Specify -work-area-virt to target.");
1763 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1767 /* Set up initial working area on first call */
1768 struct working_area
*new_wa
= malloc(sizeof(*new_wa
));
1770 new_wa
->next
= NULL
;
1771 new_wa
->size
= target
->working_area_size
& ~3UL; /* 4-byte align */
1772 new_wa
->address
= target
->working_area
;
1773 new_wa
->backup
= NULL
;
1774 new_wa
->user
= NULL
;
1775 new_wa
->free
= true;
1778 target
->working_areas
= new_wa
;
1781 /* only allocate multiples of 4 byte */
1783 size
= (size
+ 3) & (~3UL);
1785 struct working_area
*c
= target
->working_areas
;
1787 /* Find the first large enough working area */
1789 if (c
->free
&& c
->size
>= size
)
1795 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1797 /* Split the working area into the requested size */
1798 target_split_working_area(c
, size
);
1800 LOG_DEBUG("allocated new working area of %" PRIu32
" bytes at address " TARGET_ADDR_FMT
,
1803 if (target
->backup_working_area
) {
1804 if (c
->backup
== NULL
) {
1805 c
->backup
= malloc(c
->size
);
1806 if (c
->backup
== NULL
)
1810 int retval
= target_read_memory(target
, c
->address
, 4, c
->size
/ 4, c
->backup
);
1811 if (retval
!= ERROR_OK
)
1815 /* mark as used, and return the new (reused) area */
1822 print_wa_layout(target
);
1827 int target_alloc_working_area(struct target
*target
, uint32_t size
, struct working_area
**area
)
1831 retval
= target_alloc_working_area_try(target
, size
, area
);
1832 if (retval
== ERROR_TARGET_RESOURCE_NOT_AVAILABLE
)
1833 LOG_WARNING("not enough working area available(requested %"PRIu32
")", size
);
1838 static int target_restore_working_area(struct target
*target
, struct working_area
*area
)
1840 int retval
= ERROR_OK
;
1842 if (target
->backup_working_area
&& area
->backup
!= NULL
) {
1843 retval
= target_write_memory(target
, area
->address
, 4, area
->size
/ 4, area
->backup
);
1844 if (retval
!= ERROR_OK
)
1845 LOG_ERROR("failed to restore %" PRIu32
" bytes of working area at address " TARGET_ADDR_FMT
,
1846 area
->size
, area
->address
);
1852 /* Restore the area's backup memory, if any, and return the area to the allocation pool */
1853 static int target_free_working_area_restore(struct target
*target
, struct working_area
*area
, int restore
)
1855 int retval
= ERROR_OK
;
1861 retval
= target_restore_working_area(target
, area
);
1862 /* REVISIT: Perhaps the area should be freed even if restoring fails. */
1863 if (retval
!= ERROR_OK
)
1869 LOG_DEBUG("freed %" PRIu32
" bytes of working area at address " TARGET_ADDR_FMT
,
1870 area
->size
, area
->address
);
1872 /* mark user pointer invalid */
1873 /* TODO: Is this really safe? It points to some previous caller's memory.
1874 * How could we know that the area pointer is still in that place and not
1875 * some other vital data? What's the purpose of this, anyway? */
1879 target_merge_working_areas(target
);
1881 print_wa_layout(target
);
1886 int target_free_working_area(struct target
*target
, struct working_area
*area
)
1888 return target_free_working_area_restore(target
, area
, 1);
1891 static void target_destroy(struct target
*target
)
1893 if (target
->type
->deinit_target
)
1894 target
->type
->deinit_target(target
);
1896 jtag_unregister_event_callback(jtag_enable_callback
, target
);
1898 struct target_event_action
*teap
= target
->event_action
;
1900 struct target_event_action
*next
= teap
->next
;
1901 Jim_DecrRefCount(teap
->interp
, teap
->body
);
1906 target_free_all_working_areas(target
);
1907 /* Now we have none or only one working area marked as free */
1908 if (target
->working_areas
) {
1909 free(target
->working_areas
->backup
);
1910 free(target
->working_areas
);
1913 /* release the targets SMP list */
1915 struct target_list
*head
= target
->head
;
1916 while (head
!= NULL
) {
1917 struct target_list
*pos
= head
->next
;
1918 head
->target
->smp
= 0;
1926 free(target
->trace_info
);
1927 free(target
->fileio_info
);
1928 free(target
->cmd_name
);
1932 void target_quit(void)
1934 struct target_event_callback
*pe
= target_event_callbacks
;
1936 struct target_event_callback
*t
= pe
->next
;
1940 target_event_callbacks
= NULL
;
1942 struct target_timer_callback
*pt
= target_timer_callbacks
;
1944 struct target_timer_callback
*t
= pt
->next
;
1948 target_timer_callbacks
= NULL
;
1950 for (struct target
*target
= all_targets
; target
;) {
1954 target_destroy(target
);
1961 /* free resources and restore memory, if restoring memory fails,
1962 * free up resources anyway
1964 static void target_free_all_working_areas_restore(struct target
*target
, int restore
)
1966 struct working_area
*c
= target
->working_areas
;
1968 LOG_DEBUG("freeing all working areas");
1970 /* Loop through all areas, restoring the allocated ones and marking them as free */
1974 target_restore_working_area(target
, c
);
1976 *c
->user
= NULL
; /* Same as above */
1982 /* Run a merge pass to combine all areas into one */
1983 target_merge_working_areas(target
);
1985 print_wa_layout(target
);
1988 void target_free_all_working_areas(struct target
*target
)
1990 target_free_all_working_areas_restore(target
, 1);
1993 /* Find the largest number of bytes that can be allocated */
1994 uint32_t target_get_working_area_avail(struct target
*target
)
1996 struct working_area
*c
= target
->working_areas
;
1997 uint32_t max_size
= 0;
2000 return target
->working_area_size
;
2003 if (c
->free
&& max_size
< c
->size
)
2012 int target_arch_state(struct target
*target
)
2015 if (target
== NULL
) {
2016 LOG_WARNING("No target has been configured");
2020 if (target
->state
!= TARGET_HALTED
)
2023 retval
= target
->type
->arch_state(target
);
2027 static int target_get_gdb_fileio_info_default(struct target
*target
,
2028 struct gdb_fileio_info
*fileio_info
)
2030 /* If target does not support semi-hosting function, target
2031 has no need to provide .get_gdb_fileio_info callback.
2032 It just return ERROR_FAIL and gdb_server will return "Txx"
2033 as target halted every time. */
2037 static int target_gdb_fileio_end_default(struct target
*target
,
2038 int retcode
, int fileio_errno
, bool ctrl_c
)
2043 static int target_profiling_default(struct target
*target
, uint32_t *samples
,
2044 uint32_t max_num_samples
, uint32_t *num_samples
, uint32_t seconds
)
2046 struct timeval timeout
, now
;
2048 gettimeofday(&timeout
, NULL
);
2049 timeval_add_time(&timeout
, seconds
, 0);
2051 LOG_INFO("Starting profiling. Halting and resuming the"
2052 " target as often as we can...");
2054 uint32_t sample_count
= 0;
2055 /* hopefully it is safe to cache! We want to stop/restart as quickly as possible. */
2056 struct reg
*reg
= register_get_by_name(target
->reg_cache
, "pc", 1);
2058 int retval
= ERROR_OK
;
2060 target_poll(target
);
2061 if (target
->state
== TARGET_HALTED
) {
2062 uint32_t t
= buf_get_u32(reg
->value
, 0, 32);
2063 samples
[sample_count
++] = t
;
2064 /* current pc, addr = 0, do not handle breakpoints, not debugging */
2065 retval
= target_resume(target
, 1, 0, 0, 0);
2066 target_poll(target
);
2067 alive_sleep(10); /* sleep 10ms, i.e. <100 samples/second. */
2068 } else if (target
->state
== TARGET_RUNNING
) {
2069 /* We want to quickly sample the PC. */
2070 retval
= target_halt(target
);
2072 LOG_INFO("Target not halted or running");
2077 if (retval
!= ERROR_OK
)
2080 gettimeofday(&now
, NULL
);
2081 if ((sample_count
>= max_num_samples
) || timeval_compare(&now
, &timeout
) >= 0) {
2082 LOG_INFO("Profiling completed. %" PRIu32
" samples.", sample_count
);
2087 *num_samples
= sample_count
;
2091 /* Single aligned words are guaranteed to use 16 or 32 bit access
2092 * mode respectively, otherwise data is handled as quickly as
2095 int target_write_buffer(struct target
*target
, target_addr_t address
, uint32_t size
, const uint8_t *buffer
)
2097 LOG_DEBUG("writing buffer of %" PRIi32
" byte at " TARGET_ADDR_FMT
,
2100 if (!target_was_examined(target
)) {
2101 LOG_ERROR("Target not examined yet");
2108 if ((address
+ size
- 1) < address
) {
2109 /* GDB can request this when e.g. PC is 0xfffffffc */
2110 LOG_ERROR("address + size wrapped (" TARGET_ADDR_FMT
", 0x%08" PRIx32
")",
2116 return target
->type
->write_buffer(target
, address
, size
, buffer
);
2119 static int target_write_buffer_default(struct target
*target
,
2120 target_addr_t address
, uint32_t count
, const uint8_t *buffer
)
2124 /* Align up to maximum 4 bytes. The loop condition makes sure the next pass
2125 * will have something to do with the size we leave to it. */
2126 for (size
= 1; size
< 4 && count
>= size
* 2 + (address
& size
); size
*= 2) {
2127 if (address
& size
) {
2128 int retval
= target_write_memory(target
, address
, size
, 1, buffer
);
2129 if (retval
!= ERROR_OK
)
2137 /* Write the data with as large access size as possible. */
2138 for (; size
> 0; size
/= 2) {
2139 uint32_t aligned
= count
- count
% size
;
2141 int retval
= target_write_memory(target
, address
, size
, aligned
/ size
, buffer
);
2142 if (retval
!= ERROR_OK
)
2153 /* Single aligned words are guaranteed to use 16 or 32 bit access
2154 * mode respectively, otherwise data is handled as quickly as
2157 int target_read_buffer(struct target
*target
, target_addr_t address
, uint32_t size
, uint8_t *buffer
)
2159 LOG_DEBUG("reading buffer of %" PRIi32
" byte at " TARGET_ADDR_FMT
,
2162 if (!target_was_examined(target
)) {
2163 LOG_ERROR("Target not examined yet");
2170 if ((address
+ size
- 1) < address
) {
2171 /* GDB can request this when e.g. PC is 0xfffffffc */
2172 LOG_ERROR("address + size wrapped (" TARGET_ADDR_FMT
", 0x%08" PRIx32
")",
2178 return target
->type
->read_buffer(target
, address
, size
, buffer
);
2181 static int target_read_buffer_default(struct target
*target
, target_addr_t address
, uint32_t count
, uint8_t *buffer
)
2185 /* Align up to maximum 4 bytes. The loop condition makes sure the next pass
2186 * will have something to do with the size we leave to it. */
2187 for (size
= 1; size
< 4 && count
>= size
* 2 + (address
& size
); size
*= 2) {
2188 if (address
& size
) {
2189 int retval
= target_read_memory(target
, address
, size
, 1, buffer
);
2190 if (retval
!= ERROR_OK
)
2198 /* Read the data with as large access size as possible. */
2199 for (; size
> 0; size
/= 2) {
2200 uint32_t aligned
= count
- count
% size
;
2202 int retval
= target_read_memory(target
, address
, size
, aligned
/ size
, buffer
);
2203 if (retval
!= ERROR_OK
)
2214 int target_checksum_memory(struct target
*target
, target_addr_t address
, uint32_t size
, uint32_t* crc
)
2219 uint32_t checksum
= 0;
2220 if (!target_was_examined(target
)) {
2221 LOG_ERROR("Target not examined yet");
2225 retval
= target
->type
->checksum_memory(target
, address
, size
, &checksum
);
2226 if (retval
!= ERROR_OK
) {
2227 buffer
= malloc(size
);
2228 if (buffer
== NULL
) {
2229 LOG_ERROR("error allocating buffer for section (%" PRId32
" bytes)", size
);
2230 return ERROR_COMMAND_SYNTAX_ERROR
;
2232 retval
= target_read_buffer(target
, address
, size
, buffer
);
2233 if (retval
!= ERROR_OK
) {
2238 /* convert to target endianness */
2239 for (i
= 0; i
< (size
/sizeof(uint32_t)); i
++) {
2240 uint32_t target_data
;
2241 target_data
= target_buffer_get_u32(target
, &buffer
[i
*sizeof(uint32_t)]);
2242 target_buffer_set_u32(target
, &buffer
[i
*sizeof(uint32_t)], target_data
);
2245 retval
= image_calculate_checksum(buffer
, size
, &checksum
);
2254 int target_blank_check_memory(struct target
*target
, target_addr_t address
, uint32_t size
, uint32_t* blank
,
2255 uint8_t erased_value
)
2258 if (!target_was_examined(target
)) {
2259 LOG_ERROR("Target not examined yet");
2263 if (target
->type
->blank_check_memory
== 0)
2264 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
2266 retval
= target
->type
->blank_check_memory(target
, address
, size
, blank
, erased_value
);
2271 int target_read_u64(struct target
*target
, target_addr_t address
, uint64_t *value
)
2273 uint8_t value_buf
[8];
2274 if (!target_was_examined(target
)) {
2275 LOG_ERROR("Target not examined yet");
2279 int retval
= target_read_memory(target
, address
, 8, 1, value_buf
);
2281 if (retval
== ERROR_OK
) {
2282 *value
= target_buffer_get_u64(target
, value_buf
);
2283 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%16.16" PRIx64
"",
2288 LOG_DEBUG("address: " TARGET_ADDR_FMT
" failed",
2295 int target_read_u32(struct target
*target
, target_addr_t address
, uint32_t *value
)
2297 uint8_t value_buf
[4];
2298 if (!target_was_examined(target
)) {
2299 LOG_ERROR("Target not examined yet");
2303 int retval
= target_read_memory(target
, address
, 4, 1, value_buf
);
2305 if (retval
== ERROR_OK
) {
2306 *value
= target_buffer_get_u32(target
, value_buf
);
2307 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%8.8" PRIx32
"",
2312 LOG_DEBUG("address: " TARGET_ADDR_FMT
" failed",
2319 int target_read_u16(struct target
*target
, target_addr_t address
, uint16_t *value
)
2321 uint8_t value_buf
[2];
2322 if (!target_was_examined(target
)) {
2323 LOG_ERROR("Target not examined yet");
2327 int retval
= target_read_memory(target
, address
, 2, 1, value_buf
);
2329 if (retval
== ERROR_OK
) {
2330 *value
= target_buffer_get_u16(target
, value_buf
);
2331 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%4.4" PRIx16
,
2336 LOG_DEBUG("address: " TARGET_ADDR_FMT
" failed",
2343 int target_read_u8(struct target
*target
, target_addr_t address
, uint8_t *value
)
2345 if (!target_was_examined(target
)) {
2346 LOG_ERROR("Target not examined yet");
2350 int retval
= target_read_memory(target
, address
, 1, 1, value
);
2352 if (retval
== ERROR_OK
) {
2353 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%2.2" PRIx8
,
2358 LOG_DEBUG("address: " TARGET_ADDR_FMT
" failed",
2365 int target_write_u64(struct target
*target
, target_addr_t address
, uint64_t value
)
2368 uint8_t value_buf
[8];
2369 if (!target_was_examined(target
)) {
2370 LOG_ERROR("Target not examined yet");
2374 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%16.16" PRIx64
"",
2378 target_buffer_set_u64(target
, value_buf
, value
);
2379 retval
= target_write_memory(target
, address
, 8, 1, value_buf
);
2380 if (retval
!= ERROR_OK
)
2381 LOG_DEBUG("failed: %i", retval
);
2386 int target_write_u32(struct target
*target
, target_addr_t address
, uint32_t value
)
2389 uint8_t value_buf
[4];
2390 if (!target_was_examined(target
)) {
2391 LOG_ERROR("Target not examined yet");
2395 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%8.8" PRIx32
"",
2399 target_buffer_set_u32(target
, value_buf
, value
);
2400 retval
= target_write_memory(target
, address
, 4, 1, value_buf
);
2401 if (retval
!= ERROR_OK
)
2402 LOG_DEBUG("failed: %i", retval
);
2407 int target_write_u16(struct target
*target
, target_addr_t address
, uint16_t value
)
2410 uint8_t value_buf
[2];
2411 if (!target_was_examined(target
)) {
2412 LOG_ERROR("Target not examined yet");
2416 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%8.8" PRIx16
,
2420 target_buffer_set_u16(target
, value_buf
, value
);
2421 retval
= target_write_memory(target
, address
, 2, 1, value_buf
);
2422 if (retval
!= ERROR_OK
)
2423 LOG_DEBUG("failed: %i", retval
);
2428 int target_write_u8(struct target
*target
, target_addr_t address
, uint8_t value
)
2431 if (!target_was_examined(target
)) {
2432 LOG_ERROR("Target not examined yet");
2436 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%2.2" PRIx8
,
2439 retval
= target_write_memory(target
, address
, 1, 1, &value
);
2440 if (retval
!= ERROR_OK
)
2441 LOG_DEBUG("failed: %i", retval
);
2446 int target_write_phys_u64(struct target
*target
, target_addr_t address
, uint64_t value
)
2449 uint8_t value_buf
[8];
2450 if (!target_was_examined(target
)) {
2451 LOG_ERROR("Target not examined yet");
2455 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%16.16" PRIx64
"",
2459 target_buffer_set_u64(target
, value_buf
, value
);
2460 retval
= target_write_phys_memory(target
, address
, 8, 1, value_buf
);
2461 if (retval
!= ERROR_OK
)
2462 LOG_DEBUG("failed: %i", retval
);
2467 int target_write_phys_u32(struct target
*target
, target_addr_t address
, uint32_t value
)
2470 uint8_t value_buf
[4];
2471 if (!target_was_examined(target
)) {
2472 LOG_ERROR("Target not examined yet");
2476 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%8.8" PRIx32
"",
2480 target_buffer_set_u32(target
, value_buf
, value
);
2481 retval
= target_write_phys_memory(target
, address
, 4, 1, value_buf
);
2482 if (retval
!= ERROR_OK
)
2483 LOG_DEBUG("failed: %i", retval
);
2488 int target_write_phys_u16(struct target
*target
, target_addr_t address
, uint16_t value
)
2491 uint8_t value_buf
[2];
2492 if (!target_was_examined(target
)) {
2493 LOG_ERROR("Target not examined yet");
2497 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%8.8" PRIx16
,
2501 target_buffer_set_u16(target
, value_buf
, value
);
2502 retval
= target_write_phys_memory(target
, address
, 2, 1, value_buf
);
2503 if (retval
!= ERROR_OK
)
2504 LOG_DEBUG("failed: %i", retval
);
2509 int target_write_phys_u8(struct target
*target
, target_addr_t address
, uint8_t value
)
2512 if (!target_was_examined(target
)) {
2513 LOG_ERROR("Target not examined yet");
2517 LOG_DEBUG("address: " TARGET_ADDR_FMT
", value: 0x%2.2" PRIx8
,
2520 retval
= target_write_phys_memory(target
, address
, 1, 1, &value
);
2521 if (retval
!= ERROR_OK
)
2522 LOG_DEBUG("failed: %i", retval
);
2527 static int find_target(struct command_context
*cmd_ctx
, const char *name
)
2529 struct target
*target
= get_target(name
);
2530 if (target
== NULL
) {
2531 LOG_ERROR("Target: %s is unknown, try one of:\n", name
);
2534 if (!target
->tap
->enabled
) {
2535 LOG_USER("Target: TAP %s is disabled, "
2536 "can't be the current target\n",
2537 target
->tap
->dotted_name
);
2541 cmd_ctx
->current_target
= target
;
2542 if (cmd_ctx
->current_target_override
)
2543 cmd_ctx
->current_target_override
= target
;
2549 COMMAND_HANDLER(handle_targets_command
)
2551 int retval
= ERROR_OK
;
2552 if (CMD_ARGC
== 1) {
2553 retval
= find_target(CMD_CTX
, CMD_ARGV
[0]);
2554 if (retval
== ERROR_OK
) {
2560 struct target
*target
= all_targets
;
2561 command_print(CMD_CTX
, " TargetName Type Endian TapName State ");
2562 command_print(CMD_CTX
, "-- ------------------ ---------- ------ ------------------ ------------");
2567 if (target
->tap
->enabled
)
2568 state
= target_state_name(target
);
2570 state
= "tap-disabled";
2572 if (CMD_CTX
->current_target
== target
)
2575 /* keep columns lined up to match the headers above */
2576 command_print(CMD_CTX
,
2577 "%2d%c %-18s %-10s %-6s %-18s %s",
2578 target
->target_number
,
2580 target_name(target
),
2581 target_type_name(target
),
2582 Jim_Nvp_value2name_simple(nvp_target_endian
,
2583 target
->endianness
)->name
,
2584 target
->tap
->dotted_name
,
2586 target
= target
->next
;
2592 /* every 300ms we check for reset & powerdropout and issue a "reset halt" if so. */
2594 static int powerDropout
;
2595 static int srstAsserted
;
2597 static int runPowerRestore
;
2598 static int runPowerDropout
;
2599 static int runSrstAsserted
;
2600 static int runSrstDeasserted
;
2602 static int sense_handler(void)
2604 static int prevSrstAsserted
;
2605 static int prevPowerdropout
;
2607 int retval
= jtag_power_dropout(&powerDropout
);
2608 if (retval
!= ERROR_OK
)
2612 powerRestored
= prevPowerdropout
&& !powerDropout
;
2614 runPowerRestore
= 1;
2616 int64_t current
= timeval_ms();
2617 static int64_t lastPower
;
2618 bool waitMore
= lastPower
+ 2000 > current
;
2619 if (powerDropout
&& !waitMore
) {
2620 runPowerDropout
= 1;
2621 lastPower
= current
;
2624 retval
= jtag_srst_asserted(&srstAsserted
);
2625 if (retval
!= ERROR_OK
)
2629 srstDeasserted
= prevSrstAsserted
&& !srstAsserted
;
2631 static int64_t lastSrst
;
2632 waitMore
= lastSrst
+ 2000 > current
;
2633 if (srstDeasserted
&& !waitMore
) {
2634 runSrstDeasserted
= 1;
2638 if (!prevSrstAsserted
&& srstAsserted
)
2639 runSrstAsserted
= 1;
2641 prevSrstAsserted
= srstAsserted
;
2642 prevPowerdropout
= powerDropout
;
2644 if (srstDeasserted
|| powerRestored
) {
2645 /* Other than logging the event we can't do anything here.
2646 * Issuing a reset is a particularly bad idea as we might
2647 * be inside a reset already.
2654 /* process target state changes */
2655 static int handle_target(void *priv
)
2657 Jim_Interp
*interp
= (Jim_Interp
*)priv
;
2658 int retval
= ERROR_OK
;
2660 if (!is_jtag_poll_safe()) {
2661 /* polling is disabled currently */
2665 /* we do not want to recurse here... */
2666 static int recursive
;
2670 /* danger! running these procedures can trigger srst assertions and power dropouts.
2671 * We need to avoid an infinite loop/recursion here and we do that by
2672 * clearing the flags after running these events.
2674 int did_something
= 0;
2675 if (runSrstAsserted
) {
2676 LOG_INFO("srst asserted detected, running srst_asserted proc.");
2677 Jim_Eval(interp
, "srst_asserted");
2680 if (runSrstDeasserted
) {
2681 Jim_Eval(interp
, "srst_deasserted");
2684 if (runPowerDropout
) {
2685 LOG_INFO("Power dropout detected, running power_dropout proc.");
2686 Jim_Eval(interp
, "power_dropout");
2689 if (runPowerRestore
) {
2690 Jim_Eval(interp
, "power_restore");
2694 if (did_something
) {
2695 /* clear detect flags */
2699 /* clear action flags */
2701 runSrstAsserted
= 0;
2702 runSrstDeasserted
= 0;
2703 runPowerRestore
= 0;
2704 runPowerDropout
= 0;
2709 /* Poll targets for state changes unless that's globally disabled.
2710 * Skip targets that are currently disabled.
2712 for (struct target
*target
= all_targets
;
2713 is_jtag_poll_safe() && target
;
2714 target
= target
->next
) {
2716 if (!target_was_examined(target
))
2719 if (!target
->tap
->enabled
)
2722 if (target
->backoff
.times
> target
->backoff
.count
) {
2723 /* do not poll this time as we failed previously */
2724 target
->backoff
.count
++;
2727 target
->backoff
.count
= 0;
2729 /* only poll target if we've got power and srst isn't asserted */
2730 if (!powerDropout
&& !srstAsserted
) {
2731 /* polling may fail silently until the target has been examined */
2732 retval
= target_poll(target
);
2733 if (retval
!= ERROR_OK
) {
2734 /* 100ms polling interval. Increase interval between polling up to 5000ms */
2735 if (target
->backoff
.times
* polling_interval
< 5000) {
2736 target
->backoff
.times
*= 2;
2737 target
->backoff
.times
++;
2740 /* Tell GDB to halt the debugger. This allows the user to
2741 * run monitor commands to handle the situation.
2743 target_call_event_callbacks(target
, TARGET_EVENT_GDB_HALT
);
2745 if (target
->backoff
.times
> 0) {
2746 LOG_USER("Polling target %s failed, trying to reexamine", target_name(target
));
2747 target_reset_examined(target
);
2748 retval
= target_examine_one(target
);
2749 /* Target examination could have failed due to unstable connection,
2750 * but we set the examined flag anyway to repoll it later */
2751 if (retval
!= ERROR_OK
) {
2752 target
->examined
= true;
2753 LOG_USER("Examination failed, GDB will be halted. Polling again in %dms",
2754 target
->backoff
.times
* polling_interval
);
2759 /* Since we succeeded, we reset backoff count */
2760 target
->backoff
.times
= 0;
2767 COMMAND_HANDLER(handle_reg_command
)
2769 struct target
*target
;
2770 struct reg
*reg
= NULL
;
2776 target
= get_current_target(CMD_CTX
);
2778 /* list all available registers for the current target */
2779 if (CMD_ARGC
== 0) {
2780 struct reg_cache
*cache
= target
->reg_cache
;
2786 command_print(CMD_CTX
, "===== %s", cache
->name
);
2788 for (i
= 0, reg
= cache
->reg_list
;
2789 i
< cache
->num_regs
;
2790 i
++, reg
++, count
++) {
2791 /* only print cached values if they are valid */
2793 value
= buf_to_str(reg
->value
,
2795 command_print(CMD_CTX
,
2796 "(%i) %s (/%" PRIu32
"): 0x%s%s",
2804 command_print(CMD_CTX
, "(%i) %s (/%" PRIu32
")",
2809 cache
= cache
->next
;
2815 /* access a single register by its ordinal number */
2816 if ((CMD_ARGV
[0][0] >= '0') && (CMD_ARGV
[0][0] <= '9')) {
2818 COMMAND_PARSE_NUMBER(uint
, CMD_ARGV
[0], num
);
2820 struct reg_cache
*cache
= target
->reg_cache
;
2824 for (i
= 0; i
< cache
->num_regs
; i
++) {
2825 if (count
++ == num
) {
2826 reg
= &cache
->reg_list
[i
];
2832 cache
= cache
->next
;
2836 command_print(CMD_CTX
, "%i is out of bounds, the current target "
2837 "has only %i registers (0 - %i)", num
, count
, count
- 1);
2841 /* access a single register by its name */
2842 reg
= register_get_by_name(target
->reg_cache
, CMD_ARGV
[0], 1);
2845 command_print(CMD_CTX
, "register %s not found in current target", CMD_ARGV
[0]);
2850 assert(reg
!= NULL
); /* give clang a hint that we *know* reg is != NULL here */
2852 /* display a register */
2853 if ((CMD_ARGC
== 1) || ((CMD_ARGC
== 2) && !((CMD_ARGV
[1][0] >= '0')
2854 && (CMD_ARGV
[1][0] <= '9')))) {
2855 if ((CMD_ARGC
== 2) && (strcmp(CMD_ARGV
[1], "force") == 0))
2858 if (reg
->valid
== 0)
2859 reg
->type
->get(reg
);
2860 value
= buf_to_str(reg
->value
, reg
->size
, 16);
2861 command_print(CMD_CTX
, "%s (/%i): 0x%s", reg
->name
, (int)(reg
->size
), value
);
2866 /* set register value */
2867 if (CMD_ARGC
== 2) {
2868 uint8_t *buf
= malloc(DIV_ROUND_UP(reg
->size
, 8));
2871 str_to_buf(CMD_ARGV
[1], strlen(CMD_ARGV
[1]), buf
, reg
->size
, 0);
2873 reg
->type
->set(reg
, buf
);
2875 value
= buf_to_str(reg
->value
, reg
->size
, 16);
2876 command_print(CMD_CTX
, "%s (/%i): 0x%s", reg
->name
, (int)(reg
->size
), value
);
2884 return ERROR_COMMAND_SYNTAX_ERROR
;
2887 COMMAND_HANDLER(handle_poll_command
)
2889 int retval
= ERROR_OK
;
2890 struct target
*target
= get_current_target(CMD_CTX
);
2892 if (CMD_ARGC
== 0) {
2893 command_print(CMD_CTX
, "background polling: %s",
2894 jtag_poll_get_enabled() ? "on" : "off");
2895 command_print(CMD_CTX
, "TAP: %s (%s)",
2896 target
->tap
->dotted_name
,
2897 target
->tap
->enabled
? "enabled" : "disabled");
2898 if (!target
->tap
->enabled
)
2900 retval
= target_poll(target
);
2901 if (retval
!= ERROR_OK
)
2903 retval
= target_arch_state(target
);
2904 if (retval
!= ERROR_OK
)
2906 } else if (CMD_ARGC
== 1) {
2908 COMMAND_PARSE_ON_OFF(CMD_ARGV
[0], enable
);
2909 jtag_poll_set_enabled(enable
);
2911 return ERROR_COMMAND_SYNTAX_ERROR
;
2916 COMMAND_HANDLER(handle_wait_halt_command
)
2919 return ERROR_COMMAND_SYNTAX_ERROR
;
2921 unsigned ms
= DEFAULT_HALT_TIMEOUT
;
2922 if (1 == CMD_ARGC
) {
2923 int retval
= parse_uint(CMD_ARGV
[0], &ms
);
2924 if (ERROR_OK
!= retval
)
2925 return ERROR_COMMAND_SYNTAX_ERROR
;
2928 struct target
*target
= get_current_target(CMD_CTX
);
2929 return target_wait_state(target
, TARGET_HALTED
, ms
);
2932 /* wait for target state to change. The trick here is to have a low
2933 * latency for short waits and not to suck up all the CPU time
2936 * After 500ms, keep_alive() is invoked
2938 int target_wait_state(struct target
*target
, enum target_state state
, int ms
)
2941 int64_t then
= 0, cur
;
2945 retval
= target_poll(target
);
2946 if (retval
!= ERROR_OK
)
2948 if (target
->state
== state
)
2953 then
= timeval_ms();
2954 LOG_DEBUG("waiting for target %s...",
2955 Jim_Nvp_value2name_simple(nvp_target_state
, state
)->name
);
2961 if ((cur
-then
) > ms
) {
2962 LOG_ERROR("timed out while waiting for target %s",
2963 Jim_Nvp_value2name_simple(nvp_target_state
, state
)->name
);
2971 COMMAND_HANDLER(handle_halt_command
)
2975 struct target
*target
= get_current_target(CMD_CTX
);
2977 target
->verbose_halt_msg
= true;
2979 int retval
= target_halt(target
);
2980 if (ERROR_OK
!= retval
)
2983 if (CMD_ARGC
== 1) {
2984 unsigned wait_local
;
2985 retval
= parse_uint(CMD_ARGV
[0], &wait_local
);
2986 if (ERROR_OK
!= retval
)
2987 return ERROR_COMMAND_SYNTAX_ERROR
;
2992 return CALL_COMMAND_HANDLER(handle_wait_halt_command
);
2995 COMMAND_HANDLER(handle_soft_reset_halt_command
)
2997 struct target
*target
= get_current_target(CMD_CTX
);
2999 LOG_USER("requesting target halt and executing a soft reset");
3001 target_soft_reset_halt(target
);
3006 COMMAND_HANDLER(handle_reset_command
)
3009 return ERROR_COMMAND_SYNTAX_ERROR
;
3011 enum target_reset_mode reset_mode
= RESET_RUN
;
3012 if (CMD_ARGC
== 1) {
3014 n
= Jim_Nvp_name2value_simple(nvp_reset_modes
, CMD_ARGV
[0]);
3015 if ((n
->name
== NULL
) || (n
->value
== RESET_UNKNOWN
))
3016 return ERROR_COMMAND_SYNTAX_ERROR
;
3017 reset_mode
= n
->value
;
3020 /* reset *all* targets */
3021 return target_process_reset(CMD_CTX
, reset_mode
);
3025 COMMAND_HANDLER(handle_resume_command
)
3029 return ERROR_COMMAND_SYNTAX_ERROR
;
3031 struct target
*target
= get_current_target(CMD_CTX
);
3033 /* with no CMD_ARGV, resume from current pc, addr = 0,
3034 * with one arguments, addr = CMD_ARGV[0],
3035 * handle breakpoints, not debugging */
3036 target_addr_t addr
= 0;
3037 if (CMD_ARGC
== 1) {
3038 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], addr
);
3042 return target_resume(target
, current
, addr
, 1, 0);
3045 COMMAND_HANDLER(handle_step_command
)
3048 return ERROR_COMMAND_SYNTAX_ERROR
;
3052 /* with no CMD_ARGV, step from current pc, addr = 0,
3053 * with one argument addr = CMD_ARGV[0],
3054 * handle breakpoints, debugging */
3055 target_addr_t addr
= 0;
3057 if (CMD_ARGC
== 1) {
3058 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], addr
);
3062 struct target
*target
= get_current_target(CMD_CTX
);
3064 return target
->type
->step(target
, current_pc
, addr
, 1);
3067 static void handle_md_output(struct command_context
*cmd_ctx
,
3068 struct target
*target
, target_addr_t address
, unsigned size
,
3069 unsigned count
, const uint8_t *buffer
)
3071 const unsigned line_bytecnt
= 32;
3072 unsigned line_modulo
= line_bytecnt
/ size
;
3074 char output
[line_bytecnt
* 4 + 1];
3075 unsigned output_len
= 0;
3077 const char *value_fmt
;
3080 value_fmt
= "%16.16"PRIx64
" ";
3083 value_fmt
= "%8.8"PRIx64
" ";
3086 value_fmt
= "%4.4"PRIx64
" ";
3089 value_fmt
= "%2.2"PRIx64
" ";
3092 /* "can't happen", caller checked */
3093 LOG_ERROR("invalid memory read size: %u", size
);
3097 for (unsigned i
= 0; i
< count
; i
++) {
3098 if (i
% line_modulo
== 0) {
3099 output_len
+= snprintf(output
+ output_len
,
3100 sizeof(output
) - output_len
,
3101 TARGET_ADDR_FMT
": ",
3102 (address
+ (i
* size
)));
3106 const uint8_t *value_ptr
= buffer
+ i
* size
;
3109 value
= target_buffer_get_u64(target
, value_ptr
);
3112 value
= target_buffer_get_u32(target
, value_ptr
);
3115 value
= target_buffer_get_u16(target
, value_ptr
);
3120 output_len
+= snprintf(output
+ output_len
,
3121 sizeof(output
) - output_len
,
3124 if ((i
% line_modulo
== line_modulo
- 1) || (i
== count
- 1)) {
3125 command_print(cmd_ctx
, "%s", output
);
3131 COMMAND_HANDLER(handle_md_command
)
3134 return ERROR_COMMAND_SYNTAX_ERROR
;
3137 switch (CMD_NAME
[2]) {
3151 return ERROR_COMMAND_SYNTAX_ERROR
;
3154 bool physical
= strcmp(CMD_ARGV
[0], "phys") == 0;
3155 int (*fn
)(struct target
*target
,
3156 target_addr_t address
, uint32_t size_value
, uint32_t count
, uint8_t *buffer
);
3160 fn
= target_read_phys_memory
;
3162 fn
= target_read_memory
;
3163 if ((CMD_ARGC
< 1) || (CMD_ARGC
> 2))
3164 return ERROR_COMMAND_SYNTAX_ERROR
;
3166 target_addr_t address
;
3167 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], address
);
3171 COMMAND_PARSE_NUMBER(uint
, CMD_ARGV
[1], count
);
3173 uint8_t *buffer
= calloc(count
, size
);
3174 if (buffer
== NULL
) {
3175 LOG_ERROR("Failed to allocate md read buffer");
3179 struct target
*target
= get_current_target(CMD_CTX
);
3180 int retval
= fn(target
, address
, size
, count
, buffer
);
3181 if (ERROR_OK
== retval
)
3182 handle_md_output(CMD_CTX
, target
, address
, size
, count
, buffer
);
3189 typedef int (*target_write_fn
)(struct target
*target
,
3190 target_addr_t address
, uint32_t size
, uint32_t count
, const uint8_t *buffer
);
3192 static int target_fill_mem(struct target
*target
,
3193 target_addr_t address
,
3201 /* We have to write in reasonably large chunks to be able
3202 * to fill large memory areas with any sane speed */
3203 const unsigned chunk_size
= 16384;
3204 uint8_t *target_buf
= malloc(chunk_size
* data_size
);
3205 if (target_buf
== NULL
) {
3206 LOG_ERROR("Out of memory");
3210 for (unsigned i
= 0; i
< chunk_size
; i
++) {
3211 switch (data_size
) {
3213 target_buffer_set_u64(target
, target_buf
+ i
* data_size
, b
);
3216 target_buffer_set_u32(target
, target_buf
+ i
* data_size
, b
);
3219 target_buffer_set_u16(target
, target_buf
+ i
* data_size
, b
);
3222 target_buffer_set_u8(target
, target_buf
+ i
* data_size
, b
);
3229 int retval
= ERROR_OK
;
3231 for (unsigned x
= 0; x
< c
; x
+= chunk_size
) {
3234 if (current
> chunk_size
)
3235 current
= chunk_size
;
3236 retval
= fn(target
, address
+ x
* data_size
, data_size
, current
, target_buf
);
3237 if (retval
!= ERROR_OK
)
3239 /* avoid GDB timeouts */
3248 COMMAND_HANDLER(handle_mw_command
)
3251 return ERROR_COMMAND_SYNTAX_ERROR
;
3252 bool physical
= strcmp(CMD_ARGV
[0], "phys") == 0;
3257 fn
= target_write_phys_memory
;
3259 fn
= target_write_memory
;
3260 if ((CMD_ARGC
< 2) || (CMD_ARGC
> 3))
3261 return ERROR_COMMAND_SYNTAX_ERROR
;
3263 target_addr_t address
;
3264 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], address
);
3266 target_addr_t value
;
3267 COMMAND_PARSE_ADDRESS(CMD_ARGV
[1], value
);
3271 COMMAND_PARSE_NUMBER(uint
, CMD_ARGV
[2], count
);
3273 struct target
*target
= get_current_target(CMD_CTX
);
3275 switch (CMD_NAME
[2]) {
3289 return ERROR_COMMAND_SYNTAX_ERROR
;
3292 return target_fill_mem(target
, address
, fn
, wordsize
, value
, count
);
3295 static COMMAND_HELPER(parse_load_image_command_CMD_ARGV
, struct image
*image
,
3296 target_addr_t
*min_address
, target_addr_t
*max_address
)
3298 if (CMD_ARGC
< 1 || CMD_ARGC
> 5)
3299 return ERROR_COMMAND_SYNTAX_ERROR
;
3301 /* a base address isn't always necessary,
3302 * default to 0x0 (i.e. don't relocate) */
3303 if (CMD_ARGC
>= 2) {
3305 COMMAND_PARSE_ADDRESS(CMD_ARGV
[1], addr
);
3306 image
->base_address
= addr
;
3307 image
->base_address_set
= 1;
3309 image
->base_address_set
= 0;
3311 image
->start_address_set
= 0;
3314 COMMAND_PARSE_ADDRESS(CMD_ARGV
[3], *min_address
);
3315 if (CMD_ARGC
== 5) {
3316 COMMAND_PARSE_ADDRESS(CMD_ARGV
[4], *max_address
);
3317 /* use size (given) to find max (required) */
3318 *max_address
+= *min_address
;
3321 if (*min_address
> *max_address
)
3322 return ERROR_COMMAND_SYNTAX_ERROR
;
3327 COMMAND_HANDLER(handle_load_image_command
)
3331 uint32_t image_size
;
3332 target_addr_t min_address
= 0;
3333 target_addr_t max_address
= -1;
3337 int retval
= CALL_COMMAND_HANDLER(parse_load_image_command_CMD_ARGV
,
3338 &image
, &min_address
, &max_address
);
3339 if (ERROR_OK
!= retval
)
3342 struct target
*target
= get_current_target(CMD_CTX
);
3344 struct duration bench
;
3345 duration_start(&bench
);
3347 if (image_open(&image
, CMD_ARGV
[0], (CMD_ARGC
>= 3) ? CMD_ARGV
[2] : NULL
) != ERROR_OK
)
3352 for (i
= 0; i
< image
.num_sections
; i
++) {
3353 buffer
= malloc(image
.sections
[i
].size
);
3354 if (buffer
== NULL
) {
3355 command_print(CMD_CTX
,
3356 "error allocating buffer for section (%d bytes)",
3357 (int)(image
.sections
[i
].size
));
3358 retval
= ERROR_FAIL
;
3362 retval
= image_read_section(&image
, i
, 0x0, image
.sections
[i
].size
, buffer
, &buf_cnt
);
3363 if (retval
!= ERROR_OK
) {
3368 uint32_t offset
= 0;
3369 uint32_t length
= buf_cnt
;
3371 /* DANGER!!! beware of unsigned comparision here!!! */
3373 if ((image
.sections
[i
].base_address
+ buf_cnt
>= min_address
) &&
3374 (image
.sections
[i
].base_address
< max_address
)) {
3376 if (image
.sections
[i
].base_address
< min_address
) {
3377 /* clip addresses below */
3378 offset
+= min_address
-image
.sections
[i
].base_address
;
3382 if (image
.sections
[i
].base_address
+ buf_cnt
> max_address
)
3383 length
-= (image
.sections
[i
].base_address
+ buf_cnt
)-max_address
;
3385 retval
= target_write_buffer(target
,
3386 image
.sections
[i
].base_address
+ offset
, length
, buffer
+ offset
);
3387 if (retval
!= ERROR_OK
) {
3391 image_size
+= length
;
3392 command_print(CMD_CTX
, "%u bytes written at address " TARGET_ADDR_FMT
"",
3393 (unsigned int)length
,
3394 image
.sections
[i
].base_address
+ offset
);
3400 if ((ERROR_OK
== retval
) && (duration_measure(&bench
) == ERROR_OK
)) {
3401 command_print(CMD_CTX
, "downloaded %" PRIu32
" bytes "
3402 "in %fs (%0.3f KiB/s)", image_size
,
3403 duration_elapsed(&bench
), duration_kbps(&bench
, image_size
));
3406 image_close(&image
);
3412 COMMAND_HANDLER(handle_dump_image_command
)
3414 struct fileio
*fileio
;
3416 int retval
, retvaltemp
;
3417 target_addr_t address
, size
;
3418 struct duration bench
;
3419 struct target
*target
= get_current_target(CMD_CTX
);
3422 return ERROR_COMMAND_SYNTAX_ERROR
;
3424 COMMAND_PARSE_ADDRESS(CMD_ARGV
[1], address
);
3425 COMMAND_PARSE_ADDRESS(CMD_ARGV
[2], size
);
3427 uint32_t buf_size
= (size
> 4096) ? 4096 : size
;
3428 buffer
= malloc(buf_size
);
3432 retval
= fileio_open(&fileio
, CMD_ARGV
[0], FILEIO_WRITE
, FILEIO_BINARY
);
3433 if (retval
!= ERROR_OK
) {
3438 duration_start(&bench
);
3441 size_t size_written
;
3442 uint32_t this_run_size
= (size
> buf_size
) ? buf_size
: size
;
3443 retval
= target_read_buffer(target
, address
, this_run_size
, buffer
);
3444 if (retval
!= ERROR_OK
)
3447 retval
= fileio_write(fileio
, this_run_size
, buffer
, &size_written
);
3448 if (retval
!= ERROR_OK
)
3451 size
-= this_run_size
;
3452 address
+= this_run_size
;
3457 if ((ERROR_OK
== retval
) && (duration_measure(&bench
) == ERROR_OK
)) {
3459 retval
= fileio_size(fileio
, &filesize
);
3460 if (retval
!= ERROR_OK
)
3462 command_print(CMD_CTX
,
3463 "dumped %zu bytes in %fs (%0.3f KiB/s)", filesize
,
3464 duration_elapsed(&bench
), duration_kbps(&bench
, filesize
));
3467 retvaltemp
= fileio_close(fileio
);
3468 if (retvaltemp
!= ERROR_OK
)
3477 IMAGE_CHECKSUM_ONLY
= 2
3480 static COMMAND_HELPER(handle_verify_image_command_internal
, enum verify_mode verify
)
3484 uint32_t image_size
;
3487 uint32_t checksum
= 0;
3488 uint32_t mem_checksum
= 0;
3492 struct target
*target
= get_current_target(CMD_CTX
);
3495 return ERROR_COMMAND_SYNTAX_ERROR
;
3498 LOG_ERROR("no target selected");
3502 struct duration bench
;
3503 duration_start(&bench
);
3505 if (CMD_ARGC
>= 2) {
3507 COMMAND_PARSE_ADDRESS(CMD_ARGV
[1], addr
);
3508 image
.base_address
= addr
;
3509 image
.base_address_set
= 1;
3511 image
.base_address_set
= 0;
3512 image
.base_address
= 0x0;
3515 image
.start_address_set
= 0;
3517 retval
= image_open(&image
, CMD_ARGV
[0], (CMD_ARGC
== 3) ? CMD_ARGV
[2] : NULL
);
3518 if (retval
!= ERROR_OK
)
3524 for (i
= 0; i
< image
.num_sections
; i
++) {
3525 buffer
= malloc(image
.sections
[i
].size
);
3526 if (buffer
== NULL
) {
3527 command_print(CMD_CTX
,
3528 "error allocating buffer for section (%d bytes)",
3529 (int)(image
.sections
[i
].size
));
3532 retval
= image_read_section(&image
, i
, 0x0, image
.sections
[i
].size
, buffer
, &buf_cnt
);
3533 if (retval
!= ERROR_OK
) {
3538 if (verify
>= IMAGE_VERIFY
) {
3539 /* calculate checksum of image */
3540 retval
= image_calculate_checksum(buffer
, buf_cnt
, &checksum
);
3541 if (retval
!= ERROR_OK
) {
3546 retval
= target_checksum_memory(target
, image
.sections
[i
].base_address
, buf_cnt
, &mem_checksum
);
3547 if (retval
!= ERROR_OK
) {
3551 if ((checksum
!= mem_checksum
) && (verify
== IMAGE_CHECKSUM_ONLY
)) {
3552 LOG_ERROR("checksum mismatch");
3554 retval
= ERROR_FAIL
;
3557 if (checksum
!= mem_checksum
) {
3558 /* failed crc checksum, fall back to a binary compare */
3562 LOG_ERROR("checksum mismatch - attempting binary compare");
3564 data
= malloc(buf_cnt
);
3566 /* Can we use 32bit word accesses? */
3568 int count
= buf_cnt
;
3569 if ((count
% 4) == 0) {
3573 retval
= target_read_memory(target
, image
.sections
[i
].base_address
, size
, count
, data
);
3574 if (retval
== ERROR_OK
) {
3576 for (t
= 0; t
< buf_cnt
; t
++) {
3577 if (data
[t
] != buffer
[t
]) {
3578 command_print(CMD_CTX
,
3579 "diff %d address 0x%08x. Was 0x%02x instead of 0x%02x",
3581 (unsigned)(t
+ image
.sections
[i
].base_address
),
3584 if (diffs
++ >= 127) {
3585 command_print(CMD_CTX
, "More than 128 errors, the rest are not printed.");
3597 command_print(CMD_CTX
, "address " TARGET_ADDR_FMT
" length 0x%08zx",
3598 image
.sections
[i
].base_address
,
3603 image_size
+= buf_cnt
;
3606 command_print(CMD_CTX
, "No more differences found.");
3609 retval
= ERROR_FAIL
;
3610 if ((ERROR_OK
== retval
) && (duration_measure(&bench
) == ERROR_OK
)) {
3611 command_print(CMD_CTX
, "verified %" PRIu32
" bytes "
3612 "in %fs (%0.3f KiB/s)", image_size
,
3613 duration_elapsed(&bench
), duration_kbps(&bench
, image_size
));
3616 image_close(&image
);
3621 COMMAND_HANDLER(handle_verify_image_checksum_command
)
3623 return CALL_COMMAND_HANDLER(handle_verify_image_command_internal
, IMAGE_CHECKSUM_ONLY
);
3626 COMMAND_HANDLER(handle_verify_image_command
)
3628 return CALL_COMMAND_HANDLER(handle_verify_image_command_internal
, IMAGE_VERIFY
);
3631 COMMAND_HANDLER(handle_test_image_command
)
3633 return CALL_COMMAND_HANDLER(handle_verify_image_command_internal
, IMAGE_TEST
);
3636 static int handle_bp_command_list(struct command_context
*cmd_ctx
)
3638 struct target
*target
= get_current_target(cmd_ctx
);
3639 struct breakpoint
*breakpoint
= target
->breakpoints
;
3640 while (breakpoint
) {
3641 if (breakpoint
->type
== BKPT_SOFT
) {
3642 char *buf
= buf_to_str(breakpoint
->orig_instr
,
3643 breakpoint
->length
, 16);
3644 command_print(cmd_ctx
, "IVA breakpoint: " TARGET_ADDR_FMT
", 0x%x, %i, 0x%s",
3645 breakpoint
->address
,
3647 breakpoint
->set
, buf
);
3650 if ((breakpoint
->address
== 0) && (breakpoint
->asid
!= 0))
3651 command_print(cmd_ctx
, "Context breakpoint: 0x%8.8" PRIx32
", 0x%x, %i",
3653 breakpoint
->length
, breakpoint
->set
);
3654 else if ((breakpoint
->address
!= 0) && (breakpoint
->asid
!= 0)) {
3655 command_print(cmd_ctx
, "Hybrid breakpoint(IVA): " TARGET_ADDR_FMT
", 0x%x, %i",
3656 breakpoint
->address
,
3657 breakpoint
->length
, breakpoint
->set
);
3658 command_print(cmd_ctx
, "\t|--->linked with ContextID: 0x%8.8" PRIx32
,
3661 command_print(cmd_ctx
, "Breakpoint(IVA): " TARGET_ADDR_FMT
", 0x%x, %i",
3662 breakpoint
->address
,
3663 breakpoint
->length
, breakpoint
->set
);
3666 breakpoint
= breakpoint
->next
;
3671 static int handle_bp_command_set(struct command_context
*cmd_ctx
,
3672 target_addr_t addr
, uint32_t asid
, uint32_t length
, int hw
)
3674 struct target
*target
= get_current_target(cmd_ctx
);
3678 retval
= breakpoint_add(target
, addr
, length
, hw
);
3679 if (ERROR_OK
== retval
)
3680 command_print(cmd_ctx
, "breakpoint set at " TARGET_ADDR_FMT
"", addr
);
3682 LOG_ERROR("Failure setting breakpoint, the same address(IVA) is already used");
3685 } else if (addr
== 0) {
3686 if (target
->type
->add_context_breakpoint
== NULL
) {
3687 LOG_WARNING("Context breakpoint not available");
3690 retval
= context_breakpoint_add(target
, asid
, length
, hw
);
3691 if (ERROR_OK
== retval
)
3692 command_print(cmd_ctx
, "Context breakpoint set at 0x%8.8" PRIx32
"", asid
);
3694 LOG_ERROR("Failure setting breakpoint, the same address(CONTEXTID) is already used");
3698 if (target
->type
->add_hybrid_breakpoint
== NULL
) {
3699 LOG_WARNING("Hybrid breakpoint not available");
3702 retval
= hybrid_breakpoint_add(target
, addr
, asid
, length
, hw
);
3703 if (ERROR_OK
== retval
)
3704 command_print(cmd_ctx
, "Hybrid breakpoint set at 0x%8.8" PRIx32
"", asid
);
3706 LOG_ERROR("Failure setting breakpoint, the same address is already used");
3713 COMMAND_HANDLER(handle_bp_command
)
3722 return handle_bp_command_list(CMD_CTX
);
3726 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], addr
);
3727 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], length
);
3728 return handle_bp_command_set(CMD_CTX
, addr
, asid
, length
, hw
);
3731 if (strcmp(CMD_ARGV
[2], "hw") == 0) {
3733 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], addr
);
3734 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], length
);
3736 return handle_bp_command_set(CMD_CTX
, addr
, asid
, length
, hw
);
3737 } else if (strcmp(CMD_ARGV
[2], "hw_ctx") == 0) {
3739 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[0], asid
);
3740 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], length
);
3742 return handle_bp_command_set(CMD_CTX
, addr
, asid
, length
, hw
);
3747 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], addr
);
3748 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], asid
);
3749 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[2], length
);
3750 return handle_bp_command_set(CMD_CTX
, addr
, asid
, length
, hw
);
3753 return ERROR_COMMAND_SYNTAX_ERROR
;
3757 COMMAND_HANDLER(handle_rbp_command
)
3760 return ERROR_COMMAND_SYNTAX_ERROR
;
3763 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], addr
);
3765 struct target
*target
= get_current_target(CMD_CTX
);
3766 breakpoint_remove(target
, addr
);
3771 COMMAND_HANDLER(handle_wp_command
)
3773 struct target
*target
= get_current_target(CMD_CTX
);
3775 if (CMD_ARGC
== 0) {
3776 struct watchpoint
*watchpoint
= target
->watchpoints
;
3778 while (watchpoint
) {
3779 command_print(CMD_CTX
, "address: " TARGET_ADDR_FMT
3780 ", len: 0x%8.8" PRIx32
3781 ", r/w/a: %i, value: 0x%8.8" PRIx32
3782 ", mask: 0x%8.8" PRIx32
,
3783 watchpoint
->address
,
3785 (int)watchpoint
->rw
,
3788 watchpoint
= watchpoint
->next
;
3793 enum watchpoint_rw type
= WPT_ACCESS
;
3795 uint32_t length
= 0;
3796 uint32_t data_value
= 0x0;
3797 uint32_t data_mask
= 0xffffffff;
3801 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[4], data_mask
);
3804 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[3], data_value
);
3807 switch (CMD_ARGV
[2][0]) {
3818 LOG_ERROR("invalid watchpoint mode ('%c')", CMD_ARGV
[2][0]);
3819 return ERROR_COMMAND_SYNTAX_ERROR
;
3823 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], length
);
3824 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[0], addr
);
3828 return ERROR_COMMAND_SYNTAX_ERROR
;
3831 int retval
= watchpoint_add(target
, addr
, length
, type
,
3832 data_value
, data_mask
);
3833 if (ERROR_OK
!= retval
)
3834 LOG_ERROR("Failure setting watchpoints");
3839 COMMAND_HANDLER(handle_rwp_command
)
3842 return ERROR_COMMAND_SYNTAX_ERROR
;
3845 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[0], addr
);
3847 struct target
*target
= get_current_target(CMD_CTX
);
3848 watchpoint_remove(target
, addr
);
3854 * Translate a virtual address to a physical address.
3856 * The low-level target implementation must have logged a detailed error
3857 * which is forwarded to telnet/GDB session.
3859 COMMAND_HANDLER(handle_virt2phys_command
)
3862 return ERROR_COMMAND_SYNTAX_ERROR
;
3865 COMMAND_PARSE_ADDRESS(CMD_ARGV
[0], va
);
3868 struct target
*target
= get_current_target(CMD_CTX
);
3869 int retval
= target
->type
->virt2phys(target
, va
, &pa
);
3870 if (retval
== ERROR_OK
)
3871 command_print(CMD_CTX
, "Physical address " TARGET_ADDR_FMT
"", pa
);
3876 static void writeData(FILE *f
, const void *data
, size_t len
)
3878 size_t written
= fwrite(data
, 1, len
, f
);
3880 LOG_ERROR("failed to write %zu bytes: %s", len
, strerror(errno
));
3883 static void writeLong(FILE *f
, int l
, struct target
*target
)
3887 target_buffer_set_u32(target
, val
, l
);
3888 writeData(f
, val
, 4);
3891 static void writeString(FILE *f
, char *s
)
3893 writeData(f
, s
, strlen(s
));
3896 typedef unsigned char UNIT
[2]; /* unit of profiling */
3898 /* Dump a gmon.out histogram file. */
3899 static void write_gmon(uint32_t *samples
, uint32_t sampleNum
, const char *filename
, bool with_range
,
3900 uint32_t start_address
, uint32_t end_address
, struct target
*target
, uint32_t duration_ms
)
3903 FILE *f
= fopen(filename
, "w");
3906 writeString(f
, "gmon");
3907 writeLong(f
, 0x00000001, target
); /* Version */
3908 writeLong(f
, 0, target
); /* padding */
3909 writeLong(f
, 0, target
); /* padding */
3910 writeLong(f
, 0, target
); /* padding */
3912 uint8_t zero
= 0; /* GMON_TAG_TIME_HIST */
3913 writeData(f
, &zero
, 1);
3915 /* figure out bucket size */
3919 min
= start_address
;
3924 for (i
= 0; i
< sampleNum
; i
++) {
3925 if (min
> samples
[i
])
3927 if (max
< samples
[i
])
3931 /* max should be (largest sample + 1)
3932 * Refer to binutils/gprof/hist.c (find_histogram_for_pc) */
3936 int addressSpace
= max
- min
;
3937 assert(addressSpace
>= 2);
3939 /* FIXME: What is the reasonable number of buckets?
3940 * The profiling result will be more accurate if there are enough buckets. */
3941 static const uint32_t maxBuckets
= 128 * 1024; /* maximum buckets. */
3942 uint32_t numBuckets
= addressSpace
/ sizeof(UNIT
);
3943 if (numBuckets
> maxBuckets
)
3944 numBuckets
= maxBuckets
;
3945 int *buckets
= malloc(sizeof(int) * numBuckets
);
3946 if (buckets
== NULL
) {
3950 memset(buckets
, 0, sizeof(int) * numBuckets
);
3951 for (i
= 0; i
< sampleNum
; i
++) {
3952 uint32_t address
= samples
[i
];
3954 if ((address
< min
) || (max
<= address
))
3957 long long a
= address
- min
;
3958 long long b
= numBuckets
;
3959 long long c
= addressSpace
;
3960 int index_t
= (a
* b
) / c
; /* danger!!!! int32 overflows */
3964 /* append binary memory gmon.out &profile_hist_hdr ((char*)&profile_hist_hdr + sizeof(struct gmon_hist_hdr)) */
3965 writeLong(f
, min
, target
); /* low_pc */
3966 writeLong(f
, max
, target
); /* high_pc */
3967 writeLong(f
, numBuckets
, target
); /* # of buckets */
3968 float sample_rate
= sampleNum
/ (duration_ms
/ 1000.0);
3969 writeLong(f
, sample_rate
, target
);
3970 writeString(f
, "seconds");
3971 for (i
= 0; i
< (15-strlen("seconds")); i
++)
3972 writeData(f
, &zero
, 1);
3973 writeString(f
, "s");
3975 /*append binary memory gmon.out profile_hist_data (profile_hist_data + profile_hist_hdr.hist_size) */
3977 char *data
= malloc(2 * numBuckets
);
3979 for (i
= 0; i
< numBuckets
; i
++) {
3984 data
[i
* 2] = val
&0xff;
3985 data
[i
* 2 + 1] = (val
>> 8) & 0xff;
3988 writeData(f
, data
, numBuckets
* 2);
3996 /* profiling samples the CPU PC as quickly as OpenOCD is able,
3997 * which will be used as a random sampling of PC */
3998 COMMAND_HANDLER(handle_profile_command
)
4000 struct target
*target
= get_current_target(CMD_CTX
);
4002 if ((CMD_ARGC
!= 2) && (CMD_ARGC
!= 4))
4003 return ERROR_COMMAND_SYNTAX_ERROR
;
4005 const uint32_t MAX_PROFILE_SAMPLE_NUM
= 10000;
4007 uint32_t num_of_samples
;
4008 int retval
= ERROR_OK
;
4010 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[0], offset
);
4012 uint32_t *samples
= malloc(sizeof(uint32_t) * MAX_PROFILE_SAMPLE_NUM
);
4013 if (samples
== NULL
) {
4014 LOG_ERROR("No memory to store samples.");
4018 uint64_t timestart_ms
= timeval_ms();
4020 * Some cores let us sample the PC without the
4021 * annoying halt/resume step; for example, ARMv7 PCSR.
4022 * Provide a way to use that more efficient mechanism.
4024 retval
= target_profiling(target
, samples
, MAX_PROFILE_SAMPLE_NUM
,
4025 &num_of_samples
, offset
);
4026 if (retval
!= ERROR_OK
) {
4030 uint32_t duration_ms
= timeval_ms() - timestart_ms
;
4032 assert(num_of_samples
<= MAX_PROFILE_SAMPLE_NUM
);
4034 retval
= target_poll(target
);
4035 if (retval
!= ERROR_OK
) {
4039 if (target
->state
== TARGET_RUNNING
) {
4040 retval
= target_halt(target
);
4041 if (retval
!= ERROR_OK
) {
4047 retval
= target_poll(target
);
4048 if (retval
!= ERROR_OK
) {
4053 uint32_t start_address
= 0;
4054 uint32_t end_address
= 0;
4055 bool with_range
= false;
4056 if (CMD_ARGC
== 4) {
4058 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[2], start_address
);
4059 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[3], end_address
);
4062 write_gmon(samples
, num_of_samples
, CMD_ARGV
[1],
4063 with_range
, start_address
, end_address
, target
, duration_ms
);
4064 command_print(CMD_CTX
, "Wrote %s", CMD_ARGV
[1]);
4070 static int new_int_array_element(Jim_Interp
*interp
, const char *varname
, int idx
, uint32_t val
)
4073 Jim_Obj
*nameObjPtr
, *valObjPtr
;
4076 namebuf
= alloc_printf("%s(%d)", varname
, idx
);
4080 nameObjPtr
= Jim_NewStringObj(interp
, namebuf
, -1);
4081 valObjPtr
= Jim_NewIntObj(interp
, val
);
4082 if (!nameObjPtr
|| !valObjPtr
) {
4087 Jim_IncrRefCount(nameObjPtr
);
4088 Jim_IncrRefCount(valObjPtr
);
4089 result
= Jim_SetVariable(interp
, nameObjPtr
, valObjPtr
);
4090 Jim_DecrRefCount(interp
, nameObjPtr
);
4091 Jim_DecrRefCount(interp
, valObjPtr
);
4093 /* printf("%s(%d) <= 0%08x\n", varname, idx, val); */
4097 static int jim_mem2array(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
4099 struct command_context
*context
;
4100 struct target
*target
;
4102 context
= current_command_context(interp
);
4103 assert(context
!= NULL
);
4105 target
= get_current_target(context
);
4106 if (target
== NULL
) {
4107 LOG_ERROR("mem2array: no current target");
4111 return target_mem2array(interp
, target
, argc
- 1, argv
+ 1);
4114 static int target_mem2array(Jim_Interp
*interp
, struct target
*target
, int argc
, Jim_Obj
*const *argv
)
4122 const char *varname
;
4128 /* argv[1] = name of array to receive the data
4129 * argv[2] = desired width
4130 * argv[3] = memory address
4131 * argv[4] = count of times to read
4133 if (argc
< 4 || argc
> 5) {
4134 Jim_WrongNumArgs(interp
, 1, argv
, "varname width addr nelems [phys]");
4137 varname
= Jim_GetString(argv
[0], &len
);
4138 /* given "foo" get space for worse case "foo(%d)" .. add 20 */
4140 e
= Jim_GetLong(interp
, argv
[1], &l
);
4145 e
= Jim_GetLong(interp
, argv
[2], &l
);
4149 e
= Jim_GetLong(interp
, argv
[3], &l
);
4155 phys
= Jim_GetString(argv
[4], &n
);
4156 if (!strncmp(phys
, "phys", n
))
4172 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4173 Jim_AppendStrings(interp
, Jim_GetResult(interp
), "Invalid width param, must be 8/16/32", NULL
);
4177 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4178 Jim_AppendStrings(interp
, Jim_GetResult(interp
), "mem2array: zero width read?", NULL
);
4181 if ((addr
+ (len
* width
)) < addr
) {
4182 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4183 Jim_AppendStrings(interp
, Jim_GetResult(interp
), "mem2array: addr + len - wraps to zero?", NULL
);
4186 /* absurd transfer size? */
4188 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4189 Jim_AppendStrings(interp
, Jim_GetResult(interp
), "mem2array: absurd > 64K item request", NULL
);
4194 ((width
== 2) && ((addr
& 1) == 0)) ||
4195 ((width
== 4) && ((addr
& 3) == 0))) {
4199 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4200 sprintf(buf
, "mem2array address: 0x%08" PRIx32
" is not aligned for %" PRId32
" byte reads",
4203 Jim_AppendStrings(interp
, Jim_GetResult(interp
), buf
, NULL
);
4212 size_t buffersize
= 4096;
4213 uint8_t *buffer
= malloc(buffersize
);
4220 /* Slurp... in buffer size chunks */
4222 count
= len
; /* in objects.. */
4223 if (count
> (buffersize
/ width
))
4224 count
= (buffersize
/ width
);
4227 retval
= target_read_phys_memory(target
, addr
, width
, count
, buffer
);
4229 retval
= target_read_memory(target
, addr
, width
, count
, buffer
);
4230 if (retval
!= ERROR_OK
) {
4232 LOG_ERROR("mem2array: Read @ 0x%08" PRIx32
", w=%" PRId32
", cnt=%" PRId32
", failed",
4236 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4237 Jim_AppendStrings(interp
, Jim_GetResult(interp
), "mem2array: cannot read memory", NULL
);
4241 v
= 0; /* shut up gcc */
4242 for (i
= 0; i
< count
; i
++, n
++) {
4245 v
= target_buffer_get_u32(target
, &buffer
[i
*width
]);
4248 v
= target_buffer_get_u16(target
, &buffer
[i
*width
]);
4251 v
= buffer
[i
] & 0x0ff;
4254 new_int_array_element(interp
, varname
, n
, v
);
4257 addr
+= count
* width
;
4263 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4268 static int get_int_array_element(Jim_Interp
*interp
, const char *varname
, int idx
, uint32_t *val
)
4271 Jim_Obj
*nameObjPtr
, *valObjPtr
;
4275 namebuf
= alloc_printf("%s(%d)", varname
, idx
);
4279 nameObjPtr
= Jim_NewStringObj(interp
, namebuf
, -1);
4285 Jim_IncrRefCount(nameObjPtr
);
4286 valObjPtr
= Jim_GetVariable(interp
, nameObjPtr
, JIM_ERRMSG
);
4287 Jim_DecrRefCount(interp
, nameObjPtr
);
4289 if (valObjPtr
== NULL
)
4292 result
= Jim_GetLong(interp
, valObjPtr
, &l
);
4293 /* printf("%s(%d) => 0%08x\n", varname, idx, val); */
4298 static int jim_array2mem(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
4300 struct command_context
*context
;
4301 struct target
*target
;
4303 context
= current_command_context(interp
);
4304 assert(context
!= NULL
);
4306 target
= get_current_target(context
);
4307 if (target
== NULL
) {
4308 LOG_ERROR("array2mem: no current target");
4312 return target_array2mem(interp
, target
, argc
-1, argv
+ 1);
4315 static int target_array2mem(Jim_Interp
*interp
, struct target
*target
,
4316 int argc
, Jim_Obj
*const *argv
)
4324 const char *varname
;
4330 /* argv[1] = name of array to get the data
4331 * argv[2] = desired width
4332 * argv[3] = memory address
4333 * argv[4] = count to write
4335 if (argc
< 4 || argc
> 5) {
4336 Jim_WrongNumArgs(interp
, 0, argv
, "varname width addr nelems [phys]");
4339 varname
= Jim_GetString(argv
[0], &len
);
4340 /* given "foo" get space for worse case "foo(%d)" .. add 20 */
4342 e
= Jim_GetLong(interp
, argv
[1], &l
);
4347 e
= Jim_GetLong(interp
, argv
[2], &l
);
4351 e
= Jim_GetLong(interp
, argv
[3], &l
);
4357 phys
= Jim_GetString(argv
[4], &n
);
4358 if (!strncmp(phys
, "phys", n
))
4374 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4375 Jim_AppendStrings(interp
, Jim_GetResult(interp
),
4376 "Invalid width param, must be 8/16/32", NULL
);
4380 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4381 Jim_AppendStrings(interp
, Jim_GetResult(interp
),
4382 "array2mem: zero width read?", NULL
);
4385 if ((addr
+ (len
* width
)) < addr
) {
4386 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4387 Jim_AppendStrings(interp
, Jim_GetResult(interp
),
4388 "array2mem: addr + len - wraps to zero?", NULL
);
4391 /* absurd transfer size? */
4393 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4394 Jim_AppendStrings(interp
, Jim_GetResult(interp
),
4395 "array2mem: absurd > 64K item request", NULL
);
4400 ((width
== 2) && ((addr
& 1) == 0)) ||
4401 ((width
== 4) && ((addr
& 3) == 0))) {
4405 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4406 sprintf(buf
, "array2mem address: 0x%08" PRIx32
" is not aligned for %" PRId32
" byte reads",
4409 Jim_AppendStrings(interp
, Jim_GetResult(interp
), buf
, NULL
);
4420 size_t buffersize
= 4096;
4421 uint8_t *buffer
= malloc(buffersize
);
4426 /* Slurp... in buffer size chunks */
4428 count
= len
; /* in objects.. */
4429 if (count
> (buffersize
/ width
))
4430 count
= (buffersize
/ width
);
4432 v
= 0; /* shut up gcc */
4433 for (i
= 0; i
< count
; i
++, n
++) {
4434 get_int_array_element(interp
, varname
, n
, &v
);
4437 target_buffer_set_u32(target
, &buffer
[i
* width
], v
);
4440 target_buffer_set_u16(target
, &buffer
[i
* width
], v
);
4443 buffer
[i
] = v
& 0x0ff;
4450 retval
= target_write_phys_memory(target
, addr
, width
, count
, buffer
);
4452 retval
= target_write_memory(target
, addr
, width
, count
, buffer
);
4453 if (retval
!= ERROR_OK
) {
4455 LOG_ERROR("array2mem: Write @ 0x%08" PRIx32
", w=%" PRId32
", cnt=%" PRId32
", failed",
4459 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4460 Jim_AppendStrings(interp
, Jim_GetResult(interp
), "array2mem: cannot read memory", NULL
);
4464 addr
+= count
* width
;
4469 Jim_SetResult(interp
, Jim_NewEmptyStringObj(interp
));
4474 /* FIX? should we propagate errors here rather than printing them
4477 void target_handle_event(struct target
*target
, enum target_event e
)
4479 struct target_event_action
*teap
;
4481 for (teap
= target
->event_action
; teap
!= NULL
; teap
= teap
->next
) {
4482 if (teap
->event
== e
) {
4483 LOG_DEBUG("target(%d): %s (%s) event: %d (%s) action: %s",
4484 target
->target_number
,
4485 target_name(target
),
4486 target_type_name(target
),
4488 Jim_Nvp_value2name_simple(nvp_target_event
, e
)->name
,
4489 Jim_GetString(teap
->body
, NULL
));
4491 /* Override current target by the target an event
4492 * is issued from (lot of scripts need it).
4493 * Return back to previous override as soon
4494 * as the handler processing is done */
4495 struct command_context
*cmd_ctx
= current_command_context(teap
->interp
);
4496 struct target
*saved_target_override
= cmd_ctx
->current_target_override
;
4497 cmd_ctx
->current_target_override
= target
;
4499 if (Jim_EvalObj(teap
->interp
, teap
->body
) != JIM_OK
) {
4500 Jim_MakeErrorMessage(teap
->interp
);
4501 command_print(NULL
, "%s\n", Jim_GetString(Jim_GetResult(teap
->interp
), NULL
));
4504 cmd_ctx
->current_target_override
= saved_target_override
;
4510 * Returns true only if the target has a handler for the specified event.
4512 bool target_has_event_action(struct target
*target
, enum target_event event
)
4514 struct target_event_action
*teap
;
4516 for (teap
= target
->event_action
; teap
!= NULL
; teap
= teap
->next
) {
4517 if (teap
->event
== event
)
4523 enum target_cfg_param
{
4526 TCFG_WORK_AREA_VIRT
,
4527 TCFG_WORK_AREA_PHYS
,
4528 TCFG_WORK_AREA_SIZE
,
4529 TCFG_WORK_AREA_BACKUP
,
4532 TCFG_CHAIN_POSITION
,
4538 static Jim_Nvp nvp_config_opts
[] = {
4539 { .name
= "-type", .value
= TCFG_TYPE
},
4540 { .name
= "-event", .value
= TCFG_EVENT
},
4541 { .name
= "-work-area-virt", .value
= TCFG_WORK_AREA_VIRT
},
4542 { .name
= "-work-area-phys", .value
= TCFG_WORK_AREA_PHYS
},
4543 { .name
= "-work-area-size", .value
= TCFG_WORK_AREA_SIZE
},
4544 { .name
= "-work-area-backup", .value
= TCFG_WORK_AREA_BACKUP
},
4545 { .name
= "-endian" , .value
= TCFG_ENDIAN
},
4546 { .name
= "-coreid", .value
= TCFG_COREID
},
4547 { .name
= "-chain-position", .value
= TCFG_CHAIN_POSITION
},
4548 { .name
= "-dbgbase", .value
= TCFG_DBGBASE
},
4549 { .name
= "-rtos", .value
= TCFG_RTOS
},
4550 { .name
= "-defer-examine", .value
= TCFG_DEFER_EXAMINE
},
4551 { .name
= NULL
, .value
= -1 }
4554 static int target_configure(Jim_GetOptInfo
*goi
, struct target
*target
)
4561 /* parse config or cget options ... */
4562 while (goi
->argc
> 0) {
4563 Jim_SetEmptyResult(goi
->interp
);
4564 /* Jim_GetOpt_Debug(goi); */
4566 if (target
->type
->target_jim_configure
) {
4567 /* target defines a configure function */
4568 /* target gets first dibs on parameters */
4569 e
= (*(target
->type
->target_jim_configure
))(target
, goi
);
4578 /* otherwise we 'continue' below */
4580 e
= Jim_GetOpt_Nvp(goi
, nvp_config_opts
, &n
);
4582 Jim_GetOpt_NvpUnknown(goi
, nvp_config_opts
, 0);
4588 if (goi
->isconfigure
) {
4589 Jim_SetResultFormatted(goi
->interp
,
4590 "not settable: %s", n
->name
);
4594 if (goi
->argc
!= 0) {
4595 Jim_WrongNumArgs(goi
->interp
,
4596 goi
->argc
, goi
->argv
,
4601 Jim_SetResultString(goi
->interp
,
4602 target_type_name(target
), -1);
4606 if (goi
->argc
== 0) {
4607 Jim_WrongNumArgs(goi
->interp
, goi
->argc
, goi
->argv
, "-event ?event-name? ...");
4611 e
= Jim_GetOpt_Nvp(goi
, nvp_target_event
, &n
);
4613 Jim_GetOpt_NvpUnknown(goi
, nvp_target_event
, 1);
4617 if (goi
->isconfigure
) {
4618 if (goi
->argc
!= 1) {
4619 Jim_WrongNumArgs(goi
->interp
, goi
->argc
, goi
->argv
, "-event ?event-name? ?EVENT-BODY?");
4623 if (goi
->argc
!= 0) {
4624 Jim_WrongNumArgs(goi
->interp
, goi
->argc
, goi
->argv
, "-event ?event-name?");
4630 struct target_event_action
*teap
;
4632 teap
= target
->event_action
;
4633 /* replace existing? */
4635 if (teap
->event
== (enum target_event
)n
->value
)
4640 if (goi
->isconfigure
) {
4641 bool replace
= true;
4644 teap
= calloc(1, sizeof(*teap
));
4647 teap
->event
= n
->value
;
4648 teap
->interp
= goi
->interp
;
4649 Jim_GetOpt_Obj(goi
, &o
);
4651 Jim_DecrRefCount(teap
->interp
, teap
->body
);
4652 teap
->body
= Jim_DuplicateObj(goi
->interp
, o
);
4655 * Tcl/TK - "tk events" have a nice feature.
4656 * See the "BIND" command.
4657 * We should support that here.
4658 * You can specify %X and %Y in the event code.
4659 * The idea is: %T - target name.
4660 * The idea is: %N - target number
4661 * The idea is: %E - event name.
4663 Jim_IncrRefCount(teap
->body
);
4666 /* add to head of event list */
4667 teap
->next
= target
->event_action
;
4668 target
->event_action
= teap
;
4670 Jim_SetEmptyResult(goi
->interp
);
4674 Jim_SetEmptyResult(goi
->interp
);
4676 Jim_SetResult(goi
->interp
, Jim_DuplicateObj(goi
->interp
, teap
->body
));
4682 case TCFG_WORK_AREA_VIRT
:
4683 if (goi
->isconfigure
) {
4684 target_free_all_working_areas(target
);
4685 e
= Jim_GetOpt_Wide(goi
, &w
);
4688 target
->working_area_virt
= w
;
4689 target
->working_area_virt_spec
= true;
4694 Jim_SetResult(goi
->interp
, Jim_NewIntObj(goi
->interp
, target
->working_area_virt
));
4698 case TCFG_WORK_AREA_PHYS
:
4699 if (goi
->isconfigure
) {
4700 target_free_all_working_areas(target
);
4701 e
= Jim_GetOpt_Wide(goi
, &w
);
4704 target
->working_area_phys
= w
;
4705 target
->working_area_phys_spec
= true;
4710 Jim_SetResult(goi
->interp
, Jim_NewIntObj(goi
->interp
, target
->working_area_phys
));
4714 case TCFG_WORK_AREA_SIZE
:
4715 if (goi
->isconfigure
) {
4716 target_free_all_working_areas(target
);
4717 e
= Jim_GetOpt_Wide(goi
, &w
);
4720 target
->working_area_size
= w
;
4725 Jim_SetResult(goi
->interp
, Jim_NewIntObj(goi
->interp
, target
->working_area_size
));
4729 case TCFG_WORK_AREA_BACKUP
:
4730 if (goi
->isconfigure
) {
4731 target_free_all_working_areas(target
);
4732 e
= Jim_GetOpt_Wide(goi
, &w
);
4735 /* make this exactly 1 or 0 */
4736 target
->backup_working_area
= (!!w
);
4741 Jim_SetResult(goi
->interp
, Jim_NewIntObj(goi
->interp
, target
->backup_working_area
));
4742 /* loop for more e*/
4747 if (goi
->isconfigure
) {
4748 e
= Jim_GetOpt_Nvp(goi
, nvp_target_endian
, &n
);
4750 Jim_GetOpt_NvpUnknown(goi
, nvp_target_endian
, 1);
4753 target
->endianness
= n
->value
;
4758 n
= Jim_Nvp_value2name_simple(nvp_target_endian
, target
->endianness
);
4759 if (n
->name
== NULL
) {
4760 target
->endianness
= TARGET_LITTLE_ENDIAN
;
4761 n
= Jim_Nvp_value2name_simple(nvp_target_endian
, target
->endianness
);
4763 Jim_SetResultString(goi
->interp
, n
->name
, -1);
4768 if (goi
->isconfigure
) {
4769 e
= Jim_GetOpt_Wide(goi
, &w
);
4772 target
->coreid
= (int32_t)w
;
4777 Jim_SetResult(goi
->interp
, Jim_NewIntObj(goi
->interp
, target
->working_area_size
));
4781 case TCFG_CHAIN_POSITION
:
4782 if (goi
->isconfigure
) {
4784 struct jtag_tap
*tap
;
4786 if (target
->has_dap
) {
4787 Jim_SetResultString(goi
->interp
,
4788 "target requires -dap parameter instead of -chain-position!", -1);
4792 target_free_all_working_areas(target
);
4793 e
= Jim_GetOpt_Obj(goi
, &o_t
);
4796 tap
= jtag_tap_by_jim_obj(goi
->interp
, o_t
);
4800 target
->tap_configured
= true;
4805 Jim_SetResultString(goi
->interp
, target
->tap
->dotted_name
, -1);
4806 /* loop for more e*/
4809 if (goi
->isconfigure
) {
4810 e
= Jim_GetOpt_Wide(goi
, &w
);
4813 target
->dbgbase
= (uint32_t)w
;
4814 target
->dbgbase_set
= true;
4819 Jim_SetResult(goi
->interp
, Jim_NewIntObj(goi
->interp
, target
->dbgbase
));
4825 int result
= rtos_create(goi
, target
);
4826 if (result
!= JIM_OK
)
4832 case TCFG_DEFER_EXAMINE
:
4834 target
->defer_examine
= true;
4839 } /* while (goi->argc) */
4842 /* done - we return */
4846 static int jim_target_configure(Jim_Interp
*interp
, int argc
, Jim_Obj
* const *argv
)
4850 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
4851 goi
.isconfigure
= !strcmp(Jim_GetString(argv
[0], NULL
), "configure");
4853 Jim_WrongNumArgs(goi
.interp
, goi
.argc
, goi
.argv
,
4854 "missing: -option ...");
4857 struct target
*target
= Jim_CmdPrivData(goi
.interp
);
4858 return target_configure(&goi
, target
);
4861 static int jim_target_mw(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
4863 const char *cmd_name
= Jim_GetString(argv
[0], NULL
);
4866 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
4868 if (goi
.argc
< 2 || goi
.argc
> 4) {
4869 Jim_SetResultFormatted(goi
.interp
,
4870 "usage: %s [phys] <address> <data> [<count>]", cmd_name
);
4875 fn
= target_write_memory
;
4878 if (strcmp(Jim_GetString(argv
[1], NULL
), "phys") == 0) {
4880 struct Jim_Obj
*obj
;
4881 e
= Jim_GetOpt_Obj(&goi
, &obj
);
4885 fn
= target_write_phys_memory
;
4889 e
= Jim_GetOpt_Wide(&goi
, &a
);
4894 e
= Jim_GetOpt_Wide(&goi
, &b
);
4899 if (goi
.argc
== 1) {
4900 e
= Jim_GetOpt_Wide(&goi
, &c
);
4905 /* all args must be consumed */
4909 struct target
*target
= Jim_CmdPrivData(goi
.interp
);
4911 if (strcasecmp(cmd_name
, "mww") == 0)
4913 else if (strcasecmp(cmd_name
, "mwh") == 0)
4915 else if (strcasecmp(cmd_name
, "mwb") == 0)
4918 LOG_ERROR("command '%s' unknown: ", cmd_name
);
4922 return (target_fill_mem(target
, a
, fn
, data_size
, b
, c
) == ERROR_OK
) ? JIM_OK
: JIM_ERR
;
4926 * @brief Reads an array of words/halfwords/bytes from target memory starting at specified address.
4928 * Usage: mdw [phys] <address> [<count>] - for 32 bit reads
4929 * mdh [phys] <address> [<count>] - for 16 bit reads
4930 * mdb [phys] <address> [<count>] - for 8 bit reads
4932 * Count defaults to 1.
4934 * Calls target_read_memory or target_read_phys_memory depending on
4935 * the presence of the "phys" argument
4936 * Reads the target memory in blocks of max. 32 bytes, and returns an array of ints formatted
4937 * to int representation in base16.
4938 * Also outputs read data in a human readable form using command_print
4940 * @param phys if present target_read_phys_memory will be used instead of target_read_memory
4941 * @param address address where to start the read. May be specified in decimal or hex using the standard "0x" prefix
4942 * @param count optional count parameter to read an array of values. If not specified, defaults to 1.
4943 * @returns: JIM_ERR on error or JIM_OK on success and sets the result string to an array of ascii formatted numbers
4944 * on success, with [<count>] number of elements.
4946 * In case of little endian target:
4947 * Example1: "mdw 0x00000000" returns "10123456"
4948 * Exmaple2: "mdh 0x00000000 1" returns "3456"
4949 * Example3: "mdb 0x00000000" returns "56"
4950 * Example4: "mdh 0x00000000 2" returns "3456 1012"
4951 * Example5: "mdb 0x00000000 3" returns "56 34 12"
4953 static int jim_target_md(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
4955 const char *cmd_name
= Jim_GetString(argv
[0], NULL
);
4958 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
4960 if ((goi
.argc
< 1) || (goi
.argc
> 3)) {
4961 Jim_SetResultFormatted(goi
.interp
,
4962 "usage: %s [phys] <address> [<count>]", cmd_name
);
4966 int (*fn
)(struct target
*target
,
4967 target_addr_t address
, uint32_t size
, uint32_t count
, uint8_t *buffer
);
4968 fn
= target_read_memory
;
4971 if (strcmp(Jim_GetString(argv
[1], NULL
), "phys") == 0) {
4973 struct Jim_Obj
*obj
;
4974 e
= Jim_GetOpt_Obj(&goi
, &obj
);
4978 fn
= target_read_phys_memory
;
4981 /* Read address parameter */
4983 e
= Jim_GetOpt_Wide(&goi
, &addr
);
4987 /* If next parameter exists, read it out as the count parameter, if not, set it to 1 (default) */
4989 if (goi
.argc
== 1) {
4990 e
= Jim_GetOpt_Wide(&goi
, &count
);
4996 /* all args must be consumed */
5000 jim_wide dwidth
= 1; /* shut up gcc */
5001 if (strcasecmp(cmd_name
, "mdw") == 0)
5003 else if (strcasecmp(cmd_name
, "mdh") == 0)
5005 else if (strcasecmp(cmd_name
, "mdb") == 0)
5008 LOG_ERROR("command '%s' unknown: ", cmd_name
);
5012 /* convert count to "bytes" */
5013 int bytes
= count
* dwidth
;
5015 struct target
*target
= Jim_CmdPrivData(goi
.interp
);
5016 uint8_t target_buf
[32];
5019 y
= (bytes
< 16) ? bytes
: 16; /* y = min(bytes, 16); */
5021 /* Try to read out next block */
5022 e
= fn(target
, addr
, dwidth
, y
/ dwidth
, target_buf
);
5024 if (e
!= ERROR_OK
) {
5025 Jim_SetResultFormatted(interp
, "error reading target @ 0x%08lx", (long)addr
);
5029 command_print_sameline(NULL
, "0x%08x ", (int)(addr
));
5032 for (x
= 0; x
< 16 && x
< y
; x
+= 4) {
5033 z
= target_buffer_get_u32(target
, &(target_buf
[x
]));
5034 command_print_sameline(NULL
, "%08x ", (int)(z
));
5036 for (; (x
< 16) ; x
+= 4)
5037 command_print_sameline(NULL
, " ");
5040 for (x
= 0; x
< 16 && x
< y
; x
+= 2) {
5041 z
= target_buffer_get_u16(target
, &(target_buf
[x
]));
5042 command_print_sameline(NULL
, "%04x ", (int)(z
));
5044 for (; (x
< 16) ; x
+= 2)
5045 command_print_sameline(NULL
, " ");
5049 for (x
= 0 ; (x
< 16) && (x
< y
) ; x
+= 1) {
5050 z
= target_buffer_get_u8(target
, &(target_buf
[x
]));
5051 command_print_sameline(NULL
, "%02x ", (int)(z
));
5053 for (; (x
< 16) ; x
+= 1)
5054 command_print_sameline(NULL
, " ");
5057 /* ascii-ify the bytes */
5058 for (x
= 0 ; x
< y
; x
++) {
5059 if ((target_buf
[x
] >= 0x20) &&
5060 (target_buf
[x
] <= 0x7e)) {
5064 target_buf
[x
] = '.';
5069 target_buf
[x
] = ' ';
5074 /* print - with a newline */
5075 command_print_sameline(NULL
, "%s\n", target_buf
);
5083 static int jim_target_mem2array(Jim_Interp
*interp
,
5084 int argc
, Jim_Obj
*const *argv
)
5086 struct target
*target
= Jim_CmdPrivData(interp
);
5087 return target_mem2array(interp
, target
, argc
- 1, argv
+ 1);
5090 static int jim_target_array2mem(Jim_Interp
*interp
,
5091 int argc
, Jim_Obj
*const *argv
)
5093 struct target
*target
= Jim_CmdPrivData(interp
);
5094 return target_array2mem(interp
, target
, argc
- 1, argv
+ 1);
5097 static int jim_target_tap_disabled(Jim_Interp
*interp
)
5099 Jim_SetResultFormatted(interp
, "[TAP is disabled]");
5103 static int jim_target_examine(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5105 bool allow_defer
= false;
5108 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
5110 const char *cmd_name
= Jim_GetString(argv
[0], NULL
);
5111 Jim_SetResultFormatted(goi
.interp
,
5112 "usage: %s ['allow-defer']", cmd_name
);
5116 strcmp(Jim_GetString(argv
[1], NULL
), "allow-defer") == 0) {
5118 struct Jim_Obj
*obj
;
5119 int e
= Jim_GetOpt_Obj(&goi
, &obj
);
5125 struct target
*target
= Jim_CmdPrivData(interp
);
5126 if (!target
->tap
->enabled
)
5127 return jim_target_tap_disabled(interp
);
5129 if (allow_defer
&& target
->defer_examine
) {
5130 LOG_INFO("Deferring arp_examine of %s", target_name(target
));
5131 LOG_INFO("Use arp_examine command to examine it manually!");
5135 int e
= target
->type
->examine(target
);
5141 static int jim_target_was_examined(Jim_Interp
*interp
, int argc
, Jim_Obj
* const *argv
)
5143 struct target
*target
= Jim_CmdPrivData(interp
);
5145 Jim_SetResultBool(interp
, target_was_examined(target
));
5149 static int jim_target_examine_deferred(Jim_Interp
*interp
, int argc
, Jim_Obj
* const *argv
)
5151 struct target
*target
= Jim_CmdPrivData(interp
);
5153 Jim_SetResultBool(interp
, target
->defer_examine
);
5157 static int jim_target_halt_gdb(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5160 Jim_WrongNumArgs(interp
, 1, argv
, "[no parameters]");
5163 struct target
*target
= Jim_CmdPrivData(interp
);
5165 if (target_call_event_callbacks(target
, TARGET_EVENT_GDB_HALT
) != ERROR_OK
)
5171 static int jim_target_poll(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5174 Jim_WrongNumArgs(interp
, 1, argv
, "[no parameters]");
5177 struct target
*target
= Jim_CmdPrivData(interp
);
5178 if (!target
->tap
->enabled
)
5179 return jim_target_tap_disabled(interp
);
5182 if (!(target_was_examined(target
)))
5183 e
= ERROR_TARGET_NOT_EXAMINED
;
5185 e
= target
->type
->poll(target
);
5191 static int jim_target_reset(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5194 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
5196 if (goi
.argc
!= 2) {
5197 Jim_WrongNumArgs(interp
, 0, argv
,
5198 "([tT]|[fF]|assert|deassert) BOOL");
5203 int e
= Jim_GetOpt_Nvp(&goi
, nvp_assert
, &n
);
5205 Jim_GetOpt_NvpUnknown(&goi
, nvp_assert
, 1);
5208 /* the halt or not param */
5210 e
= Jim_GetOpt_Wide(&goi
, &a
);
5214 struct target
*target
= Jim_CmdPrivData(goi
.interp
);
5215 if (!target
->tap
->enabled
)
5216 return jim_target_tap_disabled(interp
);
5218 if (!target
->type
->assert_reset
|| !target
->type
->deassert_reset
) {
5219 Jim_SetResultFormatted(interp
,
5220 "No target-specific reset for %s",
5221 target_name(target
));
5225 if (target
->defer_examine
)
5226 target_reset_examined(target
);
5228 /* determine if we should halt or not. */
5229 target
->reset_halt
= !!a
;
5230 /* When this happens - all workareas are invalid. */
5231 target_free_all_working_areas_restore(target
, 0);
5234 if (n
->value
== NVP_ASSERT
)
5235 e
= target
->type
->assert_reset(target
);
5237 e
= target
->type
->deassert_reset(target
);
5238 return (e
== ERROR_OK
) ? JIM_OK
: JIM_ERR
;
5241 static int jim_target_halt(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5244 Jim_WrongNumArgs(interp
, 1, argv
, "[no parameters]");
5247 struct target
*target
= Jim_CmdPrivData(interp
);
5248 if (!target
->tap
->enabled
)
5249 return jim_target_tap_disabled(interp
);
5250 int e
= target
->type
->halt(target
);
5251 return (e
== ERROR_OK
) ? JIM_OK
: JIM_ERR
;
5254 static int jim_target_wait_state(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5257 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
5259 /* params: <name> statename timeoutmsecs */
5260 if (goi
.argc
!= 2) {
5261 const char *cmd_name
= Jim_GetString(argv
[0], NULL
);
5262 Jim_SetResultFormatted(goi
.interp
,
5263 "%s <state_name> <timeout_in_msec>", cmd_name
);
5268 int e
= Jim_GetOpt_Nvp(&goi
, nvp_target_state
, &n
);
5270 Jim_GetOpt_NvpUnknown(&goi
, nvp_target_state
, 1);
5274 e
= Jim_GetOpt_Wide(&goi
, &a
);
5277 struct target
*target
= Jim_CmdPrivData(interp
);
5278 if (!target
->tap
->enabled
)
5279 return jim_target_tap_disabled(interp
);
5281 e
= target_wait_state(target
, n
->value
, a
);
5282 if (e
!= ERROR_OK
) {
5283 Jim_Obj
*eObj
= Jim_NewIntObj(interp
, e
);
5284 Jim_SetResultFormatted(goi
.interp
,
5285 "target: %s wait %s fails (%#s) %s",
5286 target_name(target
), n
->name
,
5287 eObj
, target_strerror_safe(e
));
5288 Jim_FreeNewObj(interp
, eObj
);
5293 /* List for human, Events defined for this target.
5294 * scripts/programs should use 'name cget -event NAME'
5296 static int jim_target_event_list(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5298 struct command_context
*cmd_ctx
= current_command_context(interp
);
5299 assert(cmd_ctx
!= NULL
);
5301 struct target
*target
= Jim_CmdPrivData(interp
);
5302 struct target_event_action
*teap
= target
->event_action
;
5303 command_print(cmd_ctx
, "Event actions for target (%d) %s\n",
5304 target
->target_number
,
5305 target_name(target
));
5306 command_print(cmd_ctx
, "%-25s | Body", "Event");
5307 command_print(cmd_ctx
, "------------------------- | "
5308 "----------------------------------------");
5310 Jim_Nvp
*opt
= Jim_Nvp_value2name_simple(nvp_target_event
, teap
->event
);
5311 command_print(cmd_ctx
, "%-25s | %s",
5312 opt
->name
, Jim_GetString(teap
->body
, NULL
));
5315 command_print(cmd_ctx
, "***END***");
5318 static int jim_target_current_state(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5321 Jim_WrongNumArgs(interp
, 1, argv
, "[no parameters]");
5324 struct target
*target
= Jim_CmdPrivData(interp
);
5325 Jim_SetResultString(interp
, target_state_name(target
), -1);
5328 static int jim_target_invoke_event(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5331 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
5332 if (goi
.argc
!= 1) {
5333 const char *cmd_name
= Jim_GetString(argv
[0], NULL
);
5334 Jim_SetResultFormatted(goi
.interp
, "%s <eventname>", cmd_name
);
5338 int e
= Jim_GetOpt_Nvp(&goi
, nvp_target_event
, &n
);
5340 Jim_GetOpt_NvpUnknown(&goi
, nvp_target_event
, 1);
5343 struct target
*target
= Jim_CmdPrivData(interp
);
5344 target_handle_event(target
, n
->value
);
5348 static const struct command_registration target_instance_command_handlers
[] = {
5350 .name
= "configure",
5351 .mode
= COMMAND_CONFIG
,
5352 .jim_handler
= jim_target_configure
,
5353 .help
= "configure a new target for use",
5354 .usage
= "[target_attribute ...]",
5358 .mode
= COMMAND_ANY
,
5359 .jim_handler
= jim_target_configure
,
5360 .help
= "returns the specified target attribute",
5361 .usage
= "target_attribute",
5365 .mode
= COMMAND_EXEC
,
5366 .jim_handler
= jim_target_mw
,
5367 .help
= "Write 32-bit word(s) to target memory",
5368 .usage
= "address data [count]",
5372 .mode
= COMMAND_EXEC
,
5373 .jim_handler
= jim_target_mw
,
5374 .help
= "Write 16-bit half-word(s) to target memory",
5375 .usage
= "address data [count]",
5379 .mode
= COMMAND_EXEC
,
5380 .jim_handler
= jim_target_mw
,
5381 .help
= "Write byte(s) to target memory",
5382 .usage
= "address data [count]",
5386 .mode
= COMMAND_EXEC
,
5387 .jim_handler
= jim_target_md
,
5388 .help
= "Display target memory as 32-bit words",
5389 .usage
= "address [count]",
5393 .mode
= COMMAND_EXEC
,
5394 .jim_handler
= jim_target_md
,
5395 .help
= "Display target memory as 16-bit half-words",
5396 .usage
= "address [count]",
5400 .mode
= COMMAND_EXEC
,
5401 .jim_handler
= jim_target_md
,
5402 .help
= "Display target memory as 8-bit bytes",
5403 .usage
= "address [count]",
5406 .name
= "array2mem",
5407 .mode
= COMMAND_EXEC
,
5408 .jim_handler
= jim_target_array2mem
,
5409 .help
= "Writes Tcl array of 8/16/32 bit numbers "
5411 .usage
= "arrayname bitwidth address count",
5414 .name
= "mem2array",
5415 .mode
= COMMAND_EXEC
,
5416 .jim_handler
= jim_target_mem2array
,
5417 .help
= "Loads Tcl array of 8/16/32 bit numbers "
5418 "from target memory",
5419 .usage
= "arrayname bitwidth address count",
5422 .name
= "eventlist",
5423 .mode
= COMMAND_EXEC
,
5424 .jim_handler
= jim_target_event_list
,
5425 .help
= "displays a table of events defined for this target",
5429 .mode
= COMMAND_EXEC
,
5430 .jim_handler
= jim_target_current_state
,
5431 .help
= "displays the current state of this target",
5434 .name
= "arp_examine",
5435 .mode
= COMMAND_EXEC
,
5436 .jim_handler
= jim_target_examine
,
5437 .help
= "used internally for reset processing",
5438 .usage
= "arp_examine ['allow-defer']",
5441 .name
= "was_examined",
5442 .mode
= COMMAND_EXEC
,
5443 .jim_handler
= jim_target_was_examined
,
5444 .help
= "used internally for reset processing",
5445 .usage
= "was_examined",
5448 .name
= "examine_deferred",
5449 .mode
= COMMAND_EXEC
,
5450 .jim_handler
= jim_target_examine_deferred
,
5451 .help
= "used internally for reset processing",
5452 .usage
= "examine_deferred",
5455 .name
= "arp_halt_gdb",
5456 .mode
= COMMAND_EXEC
,
5457 .jim_handler
= jim_target_halt_gdb
,
5458 .help
= "used internally for reset processing to halt GDB",
5462 .mode
= COMMAND_EXEC
,
5463 .jim_handler
= jim_target_poll
,
5464 .help
= "used internally for reset processing",
5467 .name
= "arp_reset",
5468 .mode
= COMMAND_EXEC
,
5469 .jim_handler
= jim_target_reset
,
5470 .help
= "used internally for reset processing",
5474 .mode
= COMMAND_EXEC
,
5475 .jim_handler
= jim_target_halt
,
5476 .help
= "used internally for reset processing",
5479 .name
= "arp_waitstate",
5480 .mode
= COMMAND_EXEC
,
5481 .jim_handler
= jim_target_wait_state
,
5482 .help
= "used internally for reset processing",
5485 .name
= "invoke-event",
5486 .mode
= COMMAND_EXEC
,
5487 .jim_handler
= jim_target_invoke_event
,
5488 .help
= "invoke handler for specified event",
5489 .usage
= "event_name",
5491 COMMAND_REGISTRATION_DONE
5494 static int target_create(Jim_GetOptInfo
*goi
)
5501 struct target
*target
;
5502 struct command_context
*cmd_ctx
;
5504 cmd_ctx
= current_command_context(goi
->interp
);
5505 assert(cmd_ctx
!= NULL
);
5507 if (goi
->argc
< 3) {
5508 Jim_WrongNumArgs(goi
->interp
, 1, goi
->argv
, "?name? ?type? ..options...");
5513 Jim_GetOpt_Obj(goi
, &new_cmd
);
5514 /* does this command exist? */
5515 cmd
= Jim_GetCommand(goi
->interp
, new_cmd
, JIM_ERRMSG
);
5517 cp
= Jim_GetString(new_cmd
, NULL
);
5518 Jim_SetResultFormatted(goi
->interp
, "Command/target: %s Exists", cp
);
5523 e
= Jim_GetOpt_String(goi
, &cp
, NULL
);
5526 struct transport
*tr
= get_current_transport();
5527 if (tr
->override_target
) {
5528 e
= tr
->override_target(&cp
);
5529 if (e
!= ERROR_OK
) {
5530 LOG_ERROR("The selected transport doesn't support this target");
5533 LOG_INFO("The selected transport took over low-level target control. The results might differ compared to plain JTAG/SWD");
5535 /* now does target type exist */
5536 for (x
= 0 ; target_types
[x
] ; x
++) {
5537 if (0 == strcmp(cp
, target_types
[x
]->name
)) {
5542 /* check for deprecated name */
5543 if (target_types
[x
]->deprecated_name
) {
5544 if (0 == strcmp(cp
, target_types
[x
]->deprecated_name
)) {
5546 LOG_WARNING("target name is deprecated use: \'%s\'", target_types
[x
]->name
);
5551 if (target_types
[x
] == NULL
) {
5552 Jim_SetResultFormatted(goi
->interp
, "Unknown target type %s, try one of ", cp
);
5553 for (x
= 0 ; target_types
[x
] ; x
++) {
5554 if (target_types
[x
+ 1]) {
5555 Jim_AppendStrings(goi
->interp
,
5556 Jim_GetResult(goi
->interp
),
5557 target_types
[x
]->name
,
5560 Jim_AppendStrings(goi
->interp
,
5561 Jim_GetResult(goi
->interp
),
5563 target_types
[x
]->name
, NULL
);
5570 target
= calloc(1, sizeof(struct target
));
5571 /* set target number */
5572 target
->target_number
= new_target_number();
5573 cmd_ctx
->current_target
= target
;
5575 /* allocate memory for each unique target type */
5576 target
->type
= calloc(1, sizeof(struct target_type
));
5578 memcpy(target
->type
, target_types
[x
], sizeof(struct target_type
));
5580 /* will be set by "-endian" */
5581 target
->endianness
= TARGET_ENDIAN_UNKNOWN
;
5583 /* default to first core, override with -coreid */
5586 target
->working_area
= 0x0;
5587 target
->working_area_size
= 0x0;
5588 target
->working_areas
= NULL
;
5589 target
->backup_working_area
= 0;
5591 target
->state
= TARGET_UNKNOWN
;
5592 target
->debug_reason
= DBG_REASON_UNDEFINED
;
5593 target
->reg_cache
= NULL
;
5594 target
->breakpoints
= NULL
;
5595 target
->watchpoints
= NULL
;
5596 target
->next
= NULL
;
5597 target
->arch_info
= NULL
;
5599 target
->verbose_halt_msg
= true;
5601 target
->halt_issued
= false;
5603 /* initialize trace information */
5604 target
->trace_info
= calloc(1, sizeof(struct trace
));
5606 target
->dbgmsg
= NULL
;
5607 target
->dbg_msg_enabled
= 0;
5609 target
->endianness
= TARGET_ENDIAN_UNKNOWN
;
5611 target
->rtos
= NULL
;
5612 target
->rtos_auto_detect
= false;
5614 /* Do the rest as "configure" options */
5615 goi
->isconfigure
= 1;
5616 e
= target_configure(goi
, target
);
5619 if (target
->has_dap
) {
5620 if (!target
->dap_configured
) {
5621 Jim_SetResultString(goi
->interp
, "-dap ?name? required when creating target", -1);
5625 if (!target
->tap_configured
) {
5626 Jim_SetResultString(goi
->interp
, "-chain-position ?name? required when creating target", -1);
5630 /* tap must be set after target was configured */
5631 if (target
->tap
== NULL
)
5641 if (target
->endianness
== TARGET_ENDIAN_UNKNOWN
) {
5642 /* default endian to little if not specified */
5643 target
->endianness
= TARGET_LITTLE_ENDIAN
;
5646 cp
= Jim_GetString(new_cmd
, NULL
);
5647 target
->cmd_name
= strdup(cp
);
5649 if (target
->type
->target_create
) {
5650 e
= (*(target
->type
->target_create
))(target
, goi
->interp
);
5651 if (e
!= ERROR_OK
) {
5652 LOG_DEBUG("target_create failed");
5654 free(target
->cmd_name
);
5660 /* create the target specific commands */
5661 if (target
->type
->commands
) {
5662 e
= register_commands(cmd_ctx
, NULL
, target
->type
->commands
);
5664 LOG_ERROR("unable to register '%s' commands", cp
);
5667 /* append to end of list */
5669 struct target
**tpp
;
5670 tpp
= &(all_targets
);
5672 tpp
= &((*tpp
)->next
);
5676 /* now - create the new target name command */
5677 const struct command_registration target_subcommands
[] = {
5679 .chain
= target_instance_command_handlers
,
5682 .chain
= target
->type
->commands
,
5684 COMMAND_REGISTRATION_DONE
5686 const struct command_registration target_commands
[] = {
5689 .mode
= COMMAND_ANY
,
5690 .help
= "target command group",
5692 .chain
= target_subcommands
,
5694 COMMAND_REGISTRATION_DONE
5696 e
= register_commands(cmd_ctx
, NULL
, target_commands
);
5700 struct command
*c
= command_find_in_context(cmd_ctx
, cp
);
5702 command_set_handler_data(c
, target
);
5704 return (ERROR_OK
== e
) ? JIM_OK
: JIM_ERR
;
5707 static int jim_target_current(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5710 Jim_WrongNumArgs(interp
, 1, argv
, "Too many parameters");
5713 struct command_context
*cmd_ctx
= current_command_context(interp
);
5714 assert(cmd_ctx
!= NULL
);
5716 Jim_SetResultString(interp
, target_name(get_current_target(cmd_ctx
)), -1);
5720 static int jim_target_types(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5723 Jim_WrongNumArgs(interp
, 1, argv
, "Too many parameters");
5726 Jim_SetResult(interp
, Jim_NewListObj(interp
, NULL
, 0));
5727 for (unsigned x
= 0; NULL
!= target_types
[x
]; x
++) {
5728 Jim_ListAppendElement(interp
, Jim_GetResult(interp
),
5729 Jim_NewStringObj(interp
, target_types
[x
]->name
, -1));
5734 static int jim_target_names(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5737 Jim_WrongNumArgs(interp
, 1, argv
, "Too many parameters");
5740 Jim_SetResult(interp
, Jim_NewListObj(interp
, NULL
, 0));
5741 struct target
*target
= all_targets
;
5743 Jim_ListAppendElement(interp
, Jim_GetResult(interp
),
5744 Jim_NewStringObj(interp
, target_name(target
), -1));
5745 target
= target
->next
;
5750 static int jim_target_smp(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5753 const char *targetname
;
5755 struct target
*target
= (struct target
*) NULL
;
5756 struct target_list
*head
, *curr
, *new;
5757 curr
= (struct target_list
*) NULL
;
5758 head
= (struct target_list
*) NULL
;
5761 LOG_DEBUG("%d", argc
);
5762 /* argv[1] = target to associate in smp
5763 * argv[2] = target to assoicate in smp
5767 for (i
= 1; i
< argc
; i
++) {
5769 targetname
= Jim_GetString(argv
[i
], &len
);
5770 target
= get_target(targetname
);
5771 LOG_DEBUG("%s ", targetname
);
5773 new = malloc(sizeof(struct target_list
));
5774 new->target
= target
;
5775 new->next
= (struct target_list
*)NULL
;
5776 if (head
== (struct target_list
*)NULL
) {
5785 /* now parse the list of cpu and put the target in smp mode*/
5788 while (curr
!= (struct target_list
*)NULL
) {
5789 target
= curr
->target
;
5791 target
->head
= head
;
5795 if (target
&& target
->rtos
)
5796 retval
= rtos_smp_init(head
->target
);
5802 static int jim_target_create(Jim_Interp
*interp
, int argc
, Jim_Obj
*const *argv
)
5805 Jim_GetOpt_Setup(&goi
, interp
, argc
- 1, argv
+ 1);
5807 Jim_WrongNumArgs(goi
.interp
, goi
.argc
, goi
.argv
,
5808 "<name> <target_type> [<target_options> ...]");
5811 return target_create(&goi
);
5814 static const struct command_registration target_subcommand_handlers
[] = {
5817 .mode
= COMMAND_CONFIG
,
5818 .handler
= handle_target_init_command
,
5819 .help
= "initialize targets",
5823 /* REVISIT this should be COMMAND_CONFIG ... */
5824 .mode
= COMMAND_ANY
,
5825 .jim_handler
= jim_target_create
,
5826 .usage
= "name type '-chain-position' name [options ...]",
5827 .help
= "Creates and selects a new target",
5831 .mode
= COMMAND_ANY
,
5832 .jim_handler
= jim_target_current
,
5833 .help
= "Returns the currently selected target",
5837 .mode
= COMMAND_ANY
,
5838 .jim_handler
= jim_target_types
,
5839 .help
= "Returns the available target types as "
5840 "a list of strings",
5844 .mode
= COMMAND_ANY
,
5845 .jim_handler
= jim_target_names
,
5846 .help
= "Returns the names of all targets as a list of strings",
5850 .mode
= COMMAND_ANY
,
5851 .jim_handler
= jim_target_smp
,
5852 .usage
= "targetname1 targetname2 ...",
5853 .help
= "gather several target in a smp list"
5856 COMMAND_REGISTRATION_DONE
5860 target_addr_t address
;
5866 static int fastload_num
;
5867 static struct FastLoad
*fastload
;
5869 static void free_fastload(void)
5871 if (fastload
!= NULL
) {
5873 for (i
= 0; i
< fastload_num
; i
++) {
5874 if (fastload
[i
].data
)
5875 free(fastload
[i
].data
);
5882 COMMAND_HANDLER(handle_fast_load_image_command
)
5886 uint32_t image_size
;
5887 target_addr_t min_address
= 0;
5888 target_addr_t max_address
= -1;
5893 int retval
= CALL_COMMAND_HANDLER(parse_load_image_command_CMD_ARGV
,
5894 &image
, &min_address
, &max_address
);
5895 if (ERROR_OK
!= retval
)
5898 struct duration bench
;
5899 duration_start(&bench
);
5901 retval
= image_open(&image
, CMD_ARGV
[0], (CMD_ARGC
>= 3) ? CMD_ARGV
[2] : NULL
);
5902 if (retval
!= ERROR_OK
)
5907 fastload_num
= image
.num_sections
;
5908 fastload
= malloc(sizeof(struct FastLoad
)*image
.num_sections
);
5909 if (fastload
== NULL
) {
5910 command_print(CMD_CTX
, "out of memory");
5911 image_close(&image
);
5914 memset(fastload
, 0, sizeof(struct FastLoad
)*image
.num_sections
);
5915 for (i
= 0; i
< image
.num_sections
; i
++) {
5916 buffer
= malloc(image
.sections
[i
].size
);
5917 if (buffer
== NULL
) {
5918 command_print(CMD_CTX
, "error allocating buffer for section (%d bytes)",
5919 (int)(image
.sections
[i
].size
));
5920 retval
= ERROR_FAIL
;
5924 retval
= image_read_section(&image
, i
, 0x0, image
.sections
[i
].size
, buffer
, &buf_cnt
);
5925 if (retval
!= ERROR_OK
) {
5930 uint32_t offset
= 0;
5931 uint32_t length
= buf_cnt
;
5933 /* DANGER!!! beware of unsigned comparision here!!! */
5935 if ((image
.sections
[i
].base_address
+ buf_cnt
>= min_address
) &&
5936 (image
.sections
[i
].base_address
< max_address
)) {
5937 if (image
.sections
[i
].base_address
< min_address
) {
5938 /* clip addresses below */
5939 offset
+= min_address
-image
.sections
[i
].base_address
;
5943 if (image
.sections
[i
].base_address
+ buf_cnt
> max_address
)
5944 length
-= (image
.sections
[i
].base_address
+ buf_cnt
)-max_address
;
5946 fastload
[i
].address
= image
.sections
[i
].base_address
+ offset
;
5947 fastload
[i
].data
= malloc(length
);
5948 if (fastload
[i
].data
== NULL
) {
5950 command_print(CMD_CTX
, "error allocating buffer for section (%" PRIu32
" bytes)",
5952 retval
= ERROR_FAIL
;
5955 memcpy(fastload
[i
].data
, buffer
+ offset
, length
);
5956 fastload
[i
].length
= length
;
5958 image_size
+= length
;
5959 command_print(CMD_CTX
, "%u bytes written at address 0x%8.8x",
5960 (unsigned int)length
,
5961 ((unsigned int)(image
.sections
[i
].base_address
+ offset
)));
5967 if ((ERROR_OK
== retval
) && (duration_measure(&bench
) == ERROR_OK
)) {
5968 command_print(CMD_CTX
, "Loaded %" PRIu32
" bytes "
5969 "in %fs (%0.3f KiB/s)", image_size
,
5970 duration_elapsed(&bench
), duration_kbps(&bench
, image_size
));
5972 command_print(CMD_CTX
,
5973 "WARNING: image has not been loaded to target!"
5974 "You can issue a 'fast_load' to finish loading.");
5977 image_close(&image
);
5979 if (retval
!= ERROR_OK
)
5985 COMMAND_HANDLER(handle_fast_load_command
)
5988 return ERROR_COMMAND_SYNTAX_ERROR
;
5989 if (fastload
== NULL
) {
5990 LOG_ERROR("No image in memory");
5994 int64_t ms
= timeval_ms();
5996 int retval
= ERROR_OK
;
5997 for (i
= 0; i
< fastload_num
; i
++) {
5998 struct target
*target
= get_current_target(CMD_CTX
);
5999 command_print(CMD_CTX
, "Write to 0x%08x, length 0x%08x",
6000 (unsigned int)(fastload
[i
].address
),
6001 (unsigned int)(fastload
[i
].length
));
6002 retval
= target_write_buffer(target
, fastload
[i
].address
, fastload
[i
].length
, fastload
[i
].data
);
6003 if (retval
!= ERROR_OK
)
6005 size
+= fastload
[i
].length
;
6007 if (retval
== ERROR_OK
) {
6008 int64_t after
= timeval_ms();
6009 command_print(CMD_CTX
, "Loaded image %f kBytes/s", (float)(size
/1024.0)/((float)(after
-ms
)/1000.0));
6014 static const struct command_registration target_command_handlers
[] = {
6017 .handler
= handle_targets_command
,
6018 .mode
= COMMAND_ANY
,
6019 .help
= "change current default target (one parameter) "
6020 "or prints table of all targets (no parameters)",
6021 .usage
= "[target]",
6025 .mode
= COMMAND_CONFIG
,
6026 .help
= "configure target",
6028 .chain
= target_subcommand_handlers
,
6030 COMMAND_REGISTRATION_DONE
6033 int target_register_commands(struct command_context
*cmd_ctx
)
6035 return register_commands(cmd_ctx
, NULL
, target_command_handlers
);
6038 static bool target_reset_nag
= true;
6040 bool get_target_reset_nag(void)
6042 return target_reset_nag
;
6045 COMMAND_HANDLER(handle_target_reset_nag
)
6047 return CALL_COMMAND_HANDLER(handle_command_parse_bool
,
6048 &target_reset_nag
, "Nag after each reset about options to improve "
6052 COMMAND_HANDLER(handle_ps_command
)
6054 struct target
*target
= get_current_target(CMD_CTX
);
6056 if (target
->state
!= TARGET_HALTED
) {
6057 LOG_INFO("target not halted !!");
6061 if ((target
->rtos
) && (target
->rtos
->type
)
6062 && (target
->rtos
->type
->ps_command
)) {
6063 display
= target
->rtos
->type
->ps_command(target
);
6064 command_print(CMD_CTX
, "%s", display
);
6069 return ERROR_TARGET_FAILURE
;
6073 static void binprint(struct command_context
*cmd_ctx
, const char *text
, const uint8_t *buf
, int size
)
6076 command_print_sameline(cmd_ctx
, "%s", text
);
6077 for (int i
= 0; i
< size
; i
++)
6078 command_print_sameline(cmd_ctx
, " %02x", buf
[i
]);
6079 command_print(cmd_ctx
, " ");
6082 COMMAND_HANDLER(handle_test_mem_access_command
)
6084 struct target
*target
= get_current_target(CMD_CTX
);
6086 int retval
= ERROR_OK
;
6088 if (target
->state
!= TARGET_HALTED
) {
6089 LOG_INFO("target not halted !!");
6094 return ERROR_COMMAND_SYNTAX_ERROR
;
6096 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[0], test_size
);
6099 size_t num_bytes
= test_size
+ 4;
6101 struct working_area
*wa
= NULL
;
6102 retval
= target_alloc_working_area(target
, num_bytes
, &wa
);
6103 if (retval
!= ERROR_OK
) {
6104 LOG_ERROR("Not enough working area");
6108 uint8_t *test_pattern
= malloc(num_bytes
);
6110 for (size_t i
= 0; i
< num_bytes
; i
++)
6111 test_pattern
[i
] = rand();
6113 retval
= target_write_memory(target
, wa
->address
, 1, num_bytes
, test_pattern
);
6114 if (retval
!= ERROR_OK
) {
6115 LOG_ERROR("Test pattern write failed");
6119 for (int host_offset
= 0; host_offset
<= 1; host_offset
++) {
6120 for (int size
= 1; size
<= 4; size
*= 2) {
6121 for (int offset
= 0; offset
< 4; offset
++) {
6122 uint32_t count
= test_size
/ size
;
6123 size_t host_bufsiz
= (count
+ 2) * size
+ host_offset
;
6124 uint8_t *read_ref
= malloc(host_bufsiz
);
6125 uint8_t *read_buf
= malloc(host_bufsiz
);
6127 for (size_t i
= 0; i
< host_bufsiz
; i
++) {
6128 read_ref
[i
] = rand();
6129 read_buf
[i
] = read_ref
[i
];
6131 command_print_sameline(CMD_CTX
,
6132 "Test read %" PRIu32
" x %d @ %d to %saligned buffer: ", count
,
6133 size
, offset
, host_offset
? "un" : "");
6135 struct duration bench
;
6136 duration_start(&bench
);
6138 retval
= target_read_memory(target
, wa
->address
+ offset
, size
, count
,
6139 read_buf
+ size
+ host_offset
);
6141 duration_measure(&bench
);
6143 if (retval
== ERROR_TARGET_UNALIGNED_ACCESS
) {
6144 command_print(CMD_CTX
, "Unsupported alignment");
6146 } else if (retval
!= ERROR_OK
) {
6147 command_print(CMD_CTX
, "Memory read failed");
6151 /* replay on host */
6152 memcpy(read_ref
+ size
+ host_offset
, test_pattern
+ offset
, count
* size
);
6155 int result
= memcmp(read_ref
, read_buf
, host_bufsiz
);
6157 command_print(CMD_CTX
, "Pass in %fs (%0.3f KiB/s)",
6158 duration_elapsed(&bench
),
6159 duration_kbps(&bench
, count
* size
));
6161 command_print(CMD_CTX
, "Compare failed");
6162 binprint(CMD_CTX
, "ref:", read_ref
, host_bufsiz
);
6163 binprint(CMD_CTX
, "buf:", read_buf
, host_bufsiz
);
6176 target_free_working_area(target
, wa
);
6179 num_bytes
= test_size
+ 4 + 4 + 4;
6181 retval
= target_alloc_working_area(target
, num_bytes
, &wa
);
6182 if (retval
!= ERROR_OK
) {
6183 LOG_ERROR("Not enough working area");
6187 test_pattern
= malloc(num_bytes
);
6189 for (size_t i
= 0; i
< num_bytes
; i
++)
6190 test_pattern
[i
] = rand();
6192 for (int host_offset
= 0; host_offset
<= 1; host_offset
++) {
6193 for (int size
= 1; size
<= 4; size
*= 2) {
6194 for (int offset
= 0; offset
< 4; offset
++) {
6195 uint32_t count
= test_size
/ size
;
6196 size_t host_bufsiz
= count
* size
+ host_offset
;
6197 uint8_t *read_ref
= malloc(num_bytes
);
6198 uint8_t *read_buf
= malloc(num_bytes
);
6199 uint8_t *write_buf
= malloc(host_bufsiz
);
6201 for (size_t i
= 0; i
< host_bufsiz
; i
++)
6202 write_buf
[i
] = rand();
6203 command_print_sameline(CMD_CTX
,
6204 "Test write %" PRIu32
" x %d @ %d from %saligned buffer: ", count
,
6205 size
, offset
, host_offset
? "un" : "");
6207 retval
= target_write_memory(target
, wa
->address
, 1, num_bytes
, test_pattern
);
6208 if (retval
!= ERROR_OK
) {
6209 command_print(CMD_CTX
, "Test pattern write failed");
6213 /* replay on host */
6214 memcpy(read_ref
, test_pattern
, num_bytes
);
6215 memcpy(read_ref
+ size
+ offset
, write_buf
+ host_offset
, count
* size
);
6217 struct duration bench
;
6218 duration_start(&bench
);
6220 retval
= target_write_memory(target
, wa
->address
+ size
+ offset
, size
, count
,
6221 write_buf
+ host_offset
);
6223 duration_measure(&bench
);
6225 if (retval
== ERROR_TARGET_UNALIGNED_ACCESS
) {
6226 command_print(CMD_CTX
, "Unsupported alignment");
6228 } else if (retval
!= ERROR_OK
) {
6229 command_print(CMD_CTX
, "Memory write failed");
6234 retval
= target_read_memory(target
, wa
->address
, 1, num_bytes
, read_buf
);
6235 if (retval
!= ERROR_OK
) {
6236 command_print(CMD_CTX
, "Test pattern write failed");
6241 int result
= memcmp(read_ref
, read_buf
, num_bytes
);
6243 command_print(CMD_CTX
, "Pass in %fs (%0.3f KiB/s)",
6244 duration_elapsed(&bench
),
6245 duration_kbps(&bench
, count
* size
));
6247 command_print(CMD_CTX
, "Compare failed");
6248 binprint(CMD_CTX
, "ref:", read_ref
, num_bytes
);
6249 binprint(CMD_CTX
, "buf:", read_buf
, num_bytes
);
6261 target_free_working_area(target
, wa
);
6265 static const struct command_registration target_exec_command_handlers
[] = {
6267 .name
= "fast_load_image",
6268 .handler
= handle_fast_load_image_command
,
6269 .mode
= COMMAND_ANY
,
6270 .help
= "Load image into server memory for later use by "
6271 "fast_load; primarily for profiling",
6272 .usage
= "filename address ['bin'|'ihex'|'elf'|'s19'] "
6273 "[min_address [max_length]]",
6276 .name
= "fast_load",
6277 .handler
= handle_fast_load_command
,
6278 .mode
= COMMAND_EXEC
,
6279 .help
= "loads active fast load image to current target "
6280 "- mainly for profiling purposes",
6285 .handler
= handle_profile_command
,
6286 .mode
= COMMAND_EXEC
,
6287 .usage
= "seconds filename [start end]",
6288 .help
= "profiling samples the CPU PC",
6290 /** @todo don't register virt2phys() unless target supports it */
6292 .name
= "virt2phys",
6293 .handler
= handle_virt2phys_command
,
6294 .mode
= COMMAND_ANY
,
6295 .help
= "translate a virtual address into a physical address",
6296 .usage
= "virtual_address",
6300 .handler
= handle_reg_command
,
6301 .mode
= COMMAND_EXEC
,
6302 .help
= "display (reread from target with \"force\") or set a register; "
6303 "with no arguments, displays all registers and their values",
6304 .usage
= "[(register_number|register_name) [(value|'force')]]",
6308 .handler
= handle_poll_command
,
6309 .mode
= COMMAND_EXEC
,
6310 .help
= "poll target state; or reconfigure background polling",
6311 .usage
= "['on'|'off']",
6314 .name
= "wait_halt",
6315 .handler
= handle_wait_halt_command
,
6316 .mode
= COMMAND_EXEC
,
6317 .help
= "wait up to the specified number of milliseconds "
6318 "(default 5000) for a previously requested halt",
6319 .usage
= "[milliseconds]",
6323 .handler
= handle_halt_command
,
6324 .mode
= COMMAND_EXEC
,
6325 .help
= "request target to halt, then wait up to the specified"
6326 "number of milliseconds (default 5000) for it to complete",
6327 .usage
= "[milliseconds]",
6331 .handler
= handle_resume_command
,
6332 .mode
= COMMAND_EXEC
,
6333 .help
= "resume target execution from current PC or address",
6334 .usage
= "[address]",
6338 .handler
= handle_reset_command
,
6339 .mode
= COMMAND_EXEC
,
6340 .usage
= "[run|halt|init]",
6341 .help
= "Reset all targets into the specified mode."
6342 "Default reset mode is run, if not given.",
6345 .name
= "soft_reset_halt",
6346 .handler
= handle_soft_reset_halt_command
,
6347 .mode
= COMMAND_EXEC
,
6349 .help
= "halt the target and do a soft reset",
6353 .handler
= handle_step_command
,
6354 .mode
= COMMAND_EXEC
,
6355 .help
= "step one instruction from current PC or address",
6356 .usage
= "[address]",
6360 .handler
= handle_md_command
,
6361 .mode
= COMMAND_EXEC
,
6362 .help
= "display memory words",
6363 .usage
= "['phys'] address [count]",
6367 .handler
= handle_md_command
,
6368 .mode
= COMMAND_EXEC
,
6369 .help
= "display memory words",
6370 .usage
= "['phys'] address [count]",
6374 .handler
= handle_md_command
,
6375 .mode
= COMMAND_EXEC
,
6376 .help
= "display memory half-words",
6377 .usage
= "['phys'] address [count]",
6381 .handler
= handle_md_command
,
6382 .mode
= COMMAND_EXEC
,
6383 .help
= "display memory bytes",
6384 .usage
= "['phys'] address [count]",
6388 .handler
= handle_mw_command
,
6389 .mode
= COMMAND_EXEC
,
6390 .help
= "write memory word",
6391 .usage
= "['phys'] address value [count]",
6395 .handler
= handle_mw_command
,
6396 .mode
= COMMAND_EXEC
,
6397 .help
= "write memory word",
6398 .usage
= "['phys'] address value [count]",
6402 .handler
= handle_mw_command
,
6403 .mode
= COMMAND_EXEC
,
6404 .help
= "write memory half-word",
6405 .usage
= "['phys'] address value [count]",
6409 .handler
= handle_mw_command
,
6410 .mode
= COMMAND_EXEC
,
6411 .help
= "write memory byte",
6412 .usage
= "['phys'] address value [count]",
6416 .handler
= handle_bp_command
,
6417 .mode
= COMMAND_EXEC
,
6418 .help
= "list or set hardware or software breakpoint",
6419 .usage
= "<address> [<asid>]<length> ['hw'|'hw_ctx']",
6423 .handler
= handle_rbp_command
,
6424 .mode
= COMMAND_EXEC
,
6425 .help
= "remove breakpoint",
6430 .handler
= handle_wp_command
,
6431 .mode
= COMMAND_EXEC
,
6432 .help
= "list (no params) or create watchpoints",
6433 .usage
= "[address length [('r'|'w'|'a') value [mask]]]",
6437 .handler
= handle_rwp_command
,
6438 .mode
= COMMAND_EXEC
,
6439 .help
= "remove watchpoint",
6443 .name
= "load_image",
6444 .handler
= handle_load_image_command
,
6445 .mode
= COMMAND_EXEC
,
6446 .usage
= "filename address ['bin'|'ihex'|'elf'|'s19'] "
6447 "[min_address] [max_length]",
6450 .name
= "dump_image",
6451 .handler
= handle_dump_image_command
,
6452 .mode
= COMMAND_EXEC
,
6453 .usage
= "filename address size",
6456 .name
= "verify_image_checksum",
6457 .handler
= handle_verify_image_checksum_command
,
6458 .mode
= COMMAND_EXEC
,
6459 .usage
= "filename [offset [type]]",
6462 .name
= "verify_image",
6463 .handler
= handle_verify_image_command
,
6464 .mode
= COMMAND_EXEC
,
6465 .usage
= "filename [offset [type]]",
6468 .name
= "test_image",
6469 .handler
= handle_test_image_command
,
6470 .mode
= COMMAND_EXEC
,
6471 .usage
= "filename [offset [type]]",
6474 .name
= "mem2array",
6475 .mode
= COMMAND_EXEC
,
6476 .jim_handler
= jim_mem2array
,
6477 .help
= "read 8/16/32 bit memory and return as a TCL array "
6478 "for script processing",
6479 .usage
= "arrayname bitwidth address count",
6482 .name
= "array2mem",
6483 .mode
= COMMAND_EXEC
,
6484 .jim_handler
= jim_array2mem
,
6485 .help
= "convert a TCL array to memory locations "
6486 "and write the 8/16/32 bit values",
6487 .usage
= "arrayname bitwidth address count",
6490 .name
= "reset_nag",
6491 .handler
= handle_target_reset_nag
,
6492 .mode
= COMMAND_ANY
,
6493 .help
= "Nag after each reset about options that could have been "
6494 "enabled to improve performance. ",
6495 .usage
= "['enable'|'disable']",
6499 .handler
= handle_ps_command
,
6500 .mode
= COMMAND_EXEC
,
6501 .help
= "list all tasks ",
6505 .name
= "test_mem_access",
6506 .handler
= handle_test_mem_access_command
,
6507 .mode
= COMMAND_EXEC
,
6508 .help
= "Test the target's memory access functions",
6512 COMMAND_REGISTRATION_DONE
6514 static int target_register_user_commands(struct command_context
*cmd_ctx
)
6516 int retval
= ERROR_OK
;
6517 retval
= target_request_register_commands(cmd_ctx
);
6518 if (retval
!= ERROR_OK
)
6521 retval
= trace_register_commands(cmd_ctx
);
6522 if (retval
!= ERROR_OK
)
6526 return register_commands(cmd_ctx
, NULL
, target_exec_command_handlers
);