1 /***************************************************************************
2 * Copyright (C) 2009 Zachary T Welch *
3 * zw@superlucidity.net *
5 * Copyright (C) 2007,2008,2009 Øyvind Harboe *
6 * oyvind.harboe@zylin.com *
8 * Copyright (C) 2009 SoftPLC Corporation *
12 * Copyright (C) 2005 by Dominic Rath *
13 * Dominic.Rath@gmx.de *
15 * This program is free software; you can redistribute it and/or modify *
16 * it under the terms of the GNU General Public License as published by *
17 * the Free Software Foundation; either version 2 of the License, or *
18 * (at your option) any later version. *
20 * This program is distributed in the hope that it will be useful, *
21 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
22 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
23 * GNU General Public License for more details. *
25 * You should have received a copy of the GNU General Public License *
26 * along with this program. If not, see <http://www.gnu.org/licenses/>. *
27 ***************************************************************************/
35 #include "interface.h"
36 #include <transport/transport.h>
37 #include <helper/jep106.h>
43 /* SVF and XSVF are higher level JTAG command sets (for boundary scan) */
45 #include "xsvf/xsvf.h"
47 /** The number of JTAG queue flushes (for profiling and debugging purposes). */
48 static int jtag_flush_queue_count
;
50 /* Sleep this # of ms after flushing the queue */
51 static int jtag_flush_queue_sleep
;
53 static void jtag_add_scan_check(struct jtag_tap
*active
,
54 void (*jtag_add_scan
)(struct jtag_tap
*active
,
56 const struct scan_field
*in_fields
,
58 int in_num_fields
, struct scan_field
*in_fields
, tap_state_t state
);
61 * The jtag_error variable is set when an error occurs while executing
62 * the queue. Application code may set this using jtag_set_error(),
63 * when an error occurs during processing that should be reported during
64 * jtag_execute_queue().
66 * The value is set and cleared, but never read by normal application code.
68 * This value is returned (and cleared) by jtag_execute_queue().
70 static int jtag_error
= ERROR_OK
;
72 static const char *jtag_event_strings
[] = {
73 [JTAG_TRST_ASSERTED
] = "TAP reset",
74 [JTAG_TAP_EVENT_SETUP
] = "TAP setup",
75 [JTAG_TAP_EVENT_ENABLE
] = "TAP enabled",
76 [JTAG_TAP_EVENT_DISABLE
] = "TAP disabled",
80 * JTAG adapters must initialize with TRST and SRST de-asserted
81 * (they're negative logic, so that means *high*). But some
82 * hardware doesn't necessarily work that way ... so set things
83 * up so that jtag_init() always forces that state.
85 static int jtag_trst
= -1;
86 static int jtag_srst
= -1;
89 * List all TAPs that have been created.
91 static struct jtag_tap
*__jtag_all_taps
;
93 static enum reset_types jtag_reset_config
= RESET_NONE
;
94 tap_state_t cmd_queue_cur_state
= TAP_RESET
;
96 static bool jtag_verify_capture_ir
= true;
97 static int jtag_verify
= 1;
99 /* how long the OpenOCD should wait before attempting JTAG communication after reset lines
100 *deasserted (in ms) */
101 static int adapter_nsrst_delay
; /* default to no nSRST delay */
102 static int jtag_ntrst_delay
;/* default to no nTRST delay */
103 static int adapter_nsrst_assert_width
; /* width of assertion */
104 static int jtag_ntrst_assert_width
; /* width of assertion */
107 * Contains a single callback along with a pointer that will be passed
108 * when an event occurs.
110 struct jtag_event_callback
{
111 /** a event callback */
112 jtag_event_handler_t callback
;
113 /** the private data to pass to the callback */
115 /** the next callback */
116 struct jtag_event_callback
*next
;
119 /* callbacks to inform high-level handlers about JTAG state changes */
120 static struct jtag_event_callback
*jtag_event_callbacks
;
123 static int speed_khz
;
124 /* speed to fallback to when RCLK is requested but not supported */
125 static int rclk_fallback_speed_khz
;
126 static enum {CLOCK_MODE_UNSELECTED
, CLOCK_MODE_KHZ
, CLOCK_MODE_RCLK
} clock_mode
;
127 static int jtag_speed
;
129 /* FIXME: change name to this variable, it is not anymore JTAG only */
130 static struct adapter_driver
*jtag
;
132 extern struct adapter_driver
*adapter_driver
;
134 void jtag_set_flush_queue_sleep(int ms
)
136 jtag_flush_queue_sleep
= ms
;
139 void jtag_set_error(int error
)
141 if ((error
== ERROR_OK
) || (jtag_error
!= ERROR_OK
))
146 int jtag_error_clear(void)
148 int temp
= jtag_error
;
149 jtag_error
= ERROR_OK
;
155 static bool jtag_poll
= 1;
157 bool is_jtag_poll_safe(void)
159 /* Polling can be disabled explicitly with set_enabled(false).
160 * It is also implicitly disabled while TRST is active and
161 * while SRST is gating the JTAG clock.
163 if (!transport_is_jtag())
166 if (!jtag_poll
|| jtag_trst
!= 0)
168 return jtag_srst
== 0 || (jtag_reset_config
& RESET_SRST_NO_GATING
);
171 bool jtag_poll_get_enabled(void)
176 void jtag_poll_set_enabled(bool value
)
183 struct jtag_tap
*jtag_all_taps(void)
185 return __jtag_all_taps
;
188 unsigned jtag_tap_count(void)
190 struct jtag_tap
*t
= jtag_all_taps();
199 unsigned jtag_tap_count_enabled(void)
201 struct jtag_tap
*t
= jtag_all_taps();
211 /** Append a new TAP to the chain of all taps. */
212 void jtag_tap_add(struct jtag_tap
*t
)
214 unsigned jtag_num_taps
= 0;
216 struct jtag_tap
**tap
= &__jtag_all_taps
;
217 while (*tap
!= NULL
) {
219 tap
= &(*tap
)->next_tap
;
222 t
->abs_chain_position
= jtag_num_taps
;
225 /* returns a pointer to the n-th device in the scan chain */
226 struct jtag_tap
*jtag_tap_by_position(unsigned n
)
228 struct jtag_tap
*t
= jtag_all_taps();
236 struct jtag_tap
*jtag_tap_by_string(const char *s
)
238 /* try by name first */
239 struct jtag_tap
*t
= jtag_all_taps();
242 if (0 == strcmp(t
->dotted_name
, s
))
247 /* no tap found by name, so try to parse the name as a number */
249 if (parse_uint(s
, &n
) != ERROR_OK
)
252 /* FIXME remove this numeric fallback code late June 2010, along
253 * with all info in the User's Guide that TAPs have numeric IDs.
254 * Also update "scan_chain" output to not display the numbers.
256 t
= jtag_tap_by_position(n
);
258 LOG_WARNING("Specify TAP '%s' by name, not number %u",
264 struct jtag_tap
*jtag_tap_next_enabled(struct jtag_tap
*p
)
266 p
= p
? p
->next_tap
: jtag_all_taps();
275 const char *jtag_tap_name(const struct jtag_tap
*tap
)
277 return (tap
== NULL
) ? "(unknown)" : tap
->dotted_name
;
281 int jtag_register_event_callback(jtag_event_handler_t callback
, void *priv
)
283 struct jtag_event_callback
**callbacks_p
= &jtag_event_callbacks
;
285 if (callback
== NULL
)
286 return ERROR_COMMAND_SYNTAX_ERROR
;
289 while ((*callbacks_p
)->next
)
290 callbacks_p
= &((*callbacks_p
)->next
);
291 callbacks_p
= &((*callbacks_p
)->next
);
294 (*callbacks_p
) = malloc(sizeof(struct jtag_event_callback
));
295 (*callbacks_p
)->callback
= callback
;
296 (*callbacks_p
)->priv
= priv
;
297 (*callbacks_p
)->next
= NULL
;
302 int jtag_unregister_event_callback(jtag_event_handler_t callback
, void *priv
)
304 struct jtag_event_callback
**p
= &jtag_event_callbacks
, *temp
;
306 if (callback
== NULL
)
307 return ERROR_COMMAND_SYNTAX_ERROR
;
310 if (((*p
)->priv
!= priv
) || ((*p
)->callback
!= callback
)) {
323 int jtag_call_event_callbacks(enum jtag_event event
)
325 struct jtag_event_callback
*callback
= jtag_event_callbacks
;
327 LOG_DEBUG("jtag event: %s", jtag_event_strings
[event
]);
330 struct jtag_event_callback
*next
;
332 /* callback may remove itself */
333 next
= callback
->next
;
334 callback
->callback(event
, callback
->priv
);
341 static void jtag_checks(void)
343 assert(jtag_trst
== 0);
346 static void jtag_prelude(tap_state_t state
)
350 assert(state
!= TAP_INVALID
);
352 cmd_queue_cur_state
= state
;
355 void jtag_add_ir_scan_noverify(struct jtag_tap
*active
, const struct scan_field
*in_fields
,
360 int retval
= interface_jtag_add_ir_scan(active
, in_fields
, state
);
361 jtag_set_error(retval
);
364 static void jtag_add_ir_scan_noverify_callback(struct jtag_tap
*active
,
366 const struct scan_field
*in_fields
,
369 jtag_add_ir_scan_noverify(active
, in_fields
, state
);
372 /* If fields->in_value is filled out, then the captured IR value will be checked */
373 void jtag_add_ir_scan(struct jtag_tap
*active
, struct scan_field
*in_fields
, tap_state_t state
)
375 assert(state
!= TAP_RESET
);
377 if (jtag_verify
&& jtag_verify_capture_ir
) {
378 /* 8 x 32 bit id's is enough for all invocations */
380 /* if we are to run a verification of the ir scan, we need to get the input back.
381 * We may have to allocate space if the caller didn't ask for the input back.
383 in_fields
->check_value
= active
->expected
;
384 in_fields
->check_mask
= active
->expected_mask
;
385 jtag_add_scan_check(active
, jtag_add_ir_scan_noverify_callback
, 1, in_fields
,
388 jtag_add_ir_scan_noverify(active
, in_fields
, state
);
391 void jtag_add_plain_ir_scan(int num_bits
, const uint8_t *out_bits
, uint8_t *in_bits
,
394 assert(out_bits
!= NULL
);
395 assert(state
!= TAP_RESET
);
399 int retval
= interface_jtag_add_plain_ir_scan(
400 num_bits
, out_bits
, in_bits
, state
);
401 jtag_set_error(retval
);
404 static int jtag_check_value_inner(uint8_t *captured
, uint8_t *in_check_value
,
405 uint8_t *in_check_mask
, int num_bits
);
407 static int jtag_check_value_mask_callback(jtag_callback_data_t data0
,
408 jtag_callback_data_t data1
,
409 jtag_callback_data_t data2
,
410 jtag_callback_data_t data3
)
412 return jtag_check_value_inner((uint8_t *)data0
,
418 static void jtag_add_scan_check(struct jtag_tap
*active
, void (*jtag_add_scan
)(
419 struct jtag_tap
*active
,
421 const struct scan_field
*in_fields
,
423 int in_num_fields
, struct scan_field
*in_fields
, tap_state_t state
)
425 jtag_add_scan(active
, in_num_fields
, in_fields
, state
);
427 for (int i
= 0; i
< in_num_fields
; i
++) {
428 if ((in_fields
[i
].check_value
!= NULL
) && (in_fields
[i
].in_value
!= NULL
)) {
429 /* this is synchronous for a minidriver */
430 jtag_add_callback4(jtag_check_value_mask_callback
,
431 (jtag_callback_data_t
)in_fields
[i
].in_value
,
432 (jtag_callback_data_t
)in_fields
[i
].check_value
,
433 (jtag_callback_data_t
)in_fields
[i
].check_mask
,
434 (jtag_callback_data_t
)in_fields
[i
].num_bits
);
439 void jtag_add_dr_scan_check(struct jtag_tap
*active
,
441 struct scan_field
*in_fields
,
445 jtag_add_scan_check(active
, jtag_add_dr_scan
, in_num_fields
, in_fields
, state
);
447 jtag_add_dr_scan(active
, in_num_fields
, in_fields
, state
);
451 void jtag_add_dr_scan(struct jtag_tap
*active
,
453 const struct scan_field
*in_fields
,
456 assert(state
!= TAP_RESET
);
461 retval
= interface_jtag_add_dr_scan(active
, in_num_fields
, in_fields
, state
);
462 jtag_set_error(retval
);
465 void jtag_add_plain_dr_scan(int num_bits
, const uint8_t *out_bits
, uint8_t *in_bits
,
468 assert(out_bits
!= NULL
);
469 assert(state
!= TAP_RESET
);
474 retval
= interface_jtag_add_plain_dr_scan(num_bits
, out_bits
, in_bits
, state
);
475 jtag_set_error(retval
);
478 void jtag_add_tlr(void)
480 jtag_prelude(TAP_RESET
);
481 jtag_set_error(interface_jtag_add_tlr());
483 /* NOTE: order here matches TRST path in jtag_add_reset() */
484 jtag_call_event_callbacks(JTAG_TRST_ASSERTED
);
485 jtag_notify_event(JTAG_TRST_ASSERTED
);
489 * If supported by the underlying adapter, this clocks a raw bit sequence
490 * onto TMS for switching betwen JTAG and SWD modes.
492 * DO NOT use this to bypass the integrity checks and logging provided
493 * by the jtag_add_pathmove() and jtag_add_statemove() calls.
495 * @param nbits How many bits to clock out.
496 * @param seq The bit sequence. The LSB is bit 0 of seq[0].
497 * @param state The JTAG tap state to record on completion. Use
498 * TAP_INVALID to represent being in in SWD mode.
500 * @todo Update naming conventions to stop assuming everything is JTAG.
502 int jtag_add_tms_seq(unsigned nbits
, const uint8_t *seq
, enum tap_state state
)
506 if (!(jtag
->jtag_ops
->supported
& DEBUG_CAP_TMS_SEQ
))
507 return ERROR_JTAG_NOT_IMPLEMENTED
;
510 cmd_queue_cur_state
= state
;
512 retval
= interface_add_tms_seq(nbits
, seq
, state
);
513 jtag_set_error(retval
);
517 void jtag_add_pathmove(int num_states
, const tap_state_t
*path
)
519 tap_state_t cur_state
= cmd_queue_cur_state
;
521 /* the last state has to be a stable state */
522 if (!tap_is_state_stable(path
[num_states
- 1])) {
523 LOG_ERROR("BUG: TAP path doesn't finish in a stable state");
524 jtag_set_error(ERROR_JTAG_NOT_STABLE_STATE
);
528 for (int i
= 0; i
< num_states
; i
++) {
529 if (path
[i
] == TAP_RESET
) {
530 LOG_ERROR("BUG: TAP_RESET is not a valid state for pathmove sequences");
531 jtag_set_error(ERROR_JTAG_STATE_INVALID
);
535 if (tap_state_transition(cur_state
, true) != path
[i
] &&
536 tap_state_transition(cur_state
, false) != path
[i
]) {
537 LOG_ERROR("BUG: %s -> %s isn't a valid TAP transition",
538 tap_state_name(cur_state
), tap_state_name(path
[i
]));
539 jtag_set_error(ERROR_JTAG_TRANSITION_INVALID
);
547 jtag_set_error(interface_jtag_add_pathmove(num_states
, path
));
548 cmd_queue_cur_state
= path
[num_states
- 1];
551 int jtag_add_statemove(tap_state_t goal_state
)
553 tap_state_t cur_state
= cmd_queue_cur_state
;
555 if (goal_state
!= cur_state
) {
556 LOG_DEBUG("cur_state=%s goal_state=%s",
557 tap_state_name(cur_state
),
558 tap_state_name(goal_state
));
561 /* If goal is RESET, be paranoid and force that that transition
562 * (e.g. five TCK cycles, TMS high). Else trust "cur_state".
564 if (goal_state
== TAP_RESET
)
566 else if (goal_state
== cur_state
)
569 else if (tap_is_state_stable(cur_state
) && tap_is_state_stable(goal_state
)) {
570 unsigned tms_bits
= tap_get_tms_path(cur_state
, goal_state
);
571 unsigned tms_count
= tap_get_tms_path_len(cur_state
, goal_state
);
572 tap_state_t moves
[8];
573 assert(tms_count
< ARRAY_SIZE(moves
));
575 for (unsigned i
= 0; i
< tms_count
; i
++, tms_bits
>>= 1) {
576 bool bit
= tms_bits
& 1;
578 cur_state
= tap_state_transition(cur_state
, bit
);
579 moves
[i
] = cur_state
;
582 jtag_add_pathmove(tms_count
, moves
);
583 } else if (tap_state_transition(cur_state
, true) == goal_state
584 || tap_state_transition(cur_state
, false) == goal_state
)
585 jtag_add_pathmove(1, &goal_state
);
592 void jtag_add_runtest(int num_cycles
, tap_state_t state
)
595 jtag_set_error(interface_jtag_add_runtest(num_cycles
, state
));
599 void jtag_add_clocks(int num_cycles
)
601 if (!tap_is_state_stable(cmd_queue_cur_state
)) {
602 LOG_ERROR("jtag_add_clocks() called with TAP in unstable state \"%s\"",
603 tap_state_name(cmd_queue_cur_state
));
604 jtag_set_error(ERROR_JTAG_NOT_STABLE_STATE
);
608 if (num_cycles
> 0) {
610 jtag_set_error(interface_jtag_add_clocks(num_cycles
));
614 static int adapter_system_reset(int req_srst
)
619 if (!(jtag_reset_config
& RESET_HAS_SRST
)) {
620 LOG_ERROR("BUG: can't assert SRST");
626 /* Maybe change SRST signal state */
627 if (jtag_srst
!= req_srst
) {
628 retval
= jtag
->reset(0, req_srst
);
629 if (retval
!= ERROR_OK
) {
630 LOG_ERROR("SRST error");
633 jtag_srst
= req_srst
;
636 LOG_DEBUG("SRST line asserted");
637 if (adapter_nsrst_assert_width
)
638 jtag_sleep(adapter_nsrst_assert_width
* 1000);
640 LOG_DEBUG("SRST line released");
641 if (adapter_nsrst_delay
)
642 jtag_sleep(adapter_nsrst_delay
* 1000);
649 static void legacy_jtag_add_reset(int req_tlr_or_trst
, int req_srst
)
651 int trst_with_tlr
= 0;
655 /* Without SRST, we must use target-specific JTAG operations
656 * on each target; callers should not be requesting SRST when
657 * that signal doesn't exist.
659 * RESET_SRST_PULLS_TRST is a board or chip level quirk, which
660 * can kick in even if the JTAG adapter can't drive TRST.
663 if (!(jtag_reset_config
& RESET_HAS_SRST
)) {
664 LOG_ERROR("BUG: can't assert SRST");
665 jtag_set_error(ERROR_FAIL
);
668 if ((jtag_reset_config
& RESET_SRST_PULLS_TRST
) != 0
669 && !req_tlr_or_trst
) {
670 LOG_ERROR("BUG: can't assert only SRST");
671 jtag_set_error(ERROR_FAIL
);
677 /* JTAG reset (entry to TAP_RESET state) can always be achieved
678 * using TCK and TMS; that may go through a TAP_{IR,DR}UPDATE
679 * state first. TRST accelerates it, and bypasses those states.
681 * RESET_TRST_PULLS_SRST is a board or chip level quirk, which
682 * can kick in even if the JTAG adapter can't drive SRST.
684 if (req_tlr_or_trst
) {
685 if (!(jtag_reset_config
& RESET_HAS_TRST
))
687 else if ((jtag_reset_config
& RESET_TRST_PULLS_SRST
) != 0
694 /* Maybe change TRST and/or SRST signal state */
695 if (jtag_srst
!= new_srst
|| jtag_trst
!= new_trst
) {
698 retval
= interface_jtag_add_reset(new_trst
, new_srst
);
699 if (retval
!= ERROR_OK
)
700 jtag_set_error(retval
);
702 retval
= jtag_execute_queue();
704 if (retval
!= ERROR_OK
) {
705 LOG_ERROR("TRST/SRST error");
710 /* SRST resets everything hooked up to that signal */
711 if (jtag_srst
!= new_srst
) {
712 jtag_srst
= new_srst
;
714 LOG_DEBUG("SRST line asserted");
715 if (adapter_nsrst_assert_width
)
716 jtag_add_sleep(adapter_nsrst_assert_width
* 1000);
718 LOG_DEBUG("SRST line released");
719 if (adapter_nsrst_delay
)
720 jtag_add_sleep(adapter_nsrst_delay
* 1000);
724 /* Maybe enter the JTAG TAP_RESET state ...
725 * - using only TMS, TCK, and the JTAG state machine
726 * - or else more directly, using TRST
728 * TAP_RESET should be invisible to non-debug parts of the system.
731 LOG_DEBUG("JTAG reset with TLR instead of TRST");
734 } else if (jtag_trst
!= new_trst
) {
735 jtag_trst
= new_trst
;
737 LOG_DEBUG("TRST line asserted");
738 tap_set_state(TAP_RESET
);
739 if (jtag_ntrst_assert_width
)
740 jtag_add_sleep(jtag_ntrst_assert_width
* 1000);
742 LOG_DEBUG("TRST line released");
743 if (jtag_ntrst_delay
)
744 jtag_add_sleep(jtag_ntrst_delay
* 1000);
746 /* We just asserted nTRST, so we're now in TAP_RESET.
747 * Inform possible listeners about this, now that
748 * JTAG instructions and data can be shifted. This
749 * sequence must match jtag_add_tlr().
751 jtag_call_event_callbacks(JTAG_TRST_ASSERTED
);
752 jtag_notify_event(JTAG_TRST_ASSERTED
);
757 /* FIXME: name is misleading; we do not plan to "add" reset into jtag queue */
758 void jtag_add_reset(int req_tlr_or_trst
, int req_srst
)
761 int trst_with_tlr
= 0;
766 legacy_jtag_add_reset(req_tlr_or_trst
, req_srst
);
770 /* Without SRST, we must use target-specific JTAG operations
771 * on each target; callers should not be requesting SRST when
772 * that signal doesn't exist.
774 * RESET_SRST_PULLS_TRST is a board or chip level quirk, which
775 * can kick in even if the JTAG adapter can't drive TRST.
778 if (!(jtag_reset_config
& RESET_HAS_SRST
)) {
779 LOG_ERROR("BUG: can't assert SRST");
780 jtag_set_error(ERROR_FAIL
);
783 if ((jtag_reset_config
& RESET_SRST_PULLS_TRST
) != 0
784 && !req_tlr_or_trst
) {
785 LOG_ERROR("BUG: can't assert only SRST");
786 jtag_set_error(ERROR_FAIL
);
792 /* JTAG reset (entry to TAP_RESET state) can always be achieved
793 * using TCK and TMS; that may go through a TAP_{IR,DR}UPDATE
794 * state first. TRST accelerates it, and bypasses those states.
796 * RESET_TRST_PULLS_SRST is a board or chip level quirk, which
797 * can kick in even if the JTAG adapter can't drive SRST.
799 if (req_tlr_or_trst
) {
800 if (!(jtag_reset_config
& RESET_HAS_TRST
))
802 else if ((jtag_reset_config
& RESET_TRST_PULLS_SRST
) != 0
809 /* Maybe change TRST and/or SRST signal state */
810 if (jtag_srst
!= new_srst
|| jtag_trst
!= new_trst
) {
811 /* guarantee jtag queue empty before changing reset status */
812 jtag_execute_queue();
814 retval
= jtag
->reset(new_trst
, new_srst
);
815 if (retval
!= ERROR_OK
) {
816 jtag_set_error(retval
);
817 LOG_ERROR("TRST/SRST error");
822 /* SRST resets everything hooked up to that signal */
823 if (jtag_srst
!= new_srst
) {
824 jtag_srst
= new_srst
;
826 LOG_DEBUG("SRST line asserted");
827 if (adapter_nsrst_assert_width
)
828 jtag_add_sleep(adapter_nsrst_assert_width
* 1000);
830 LOG_DEBUG("SRST line released");
831 if (adapter_nsrst_delay
)
832 jtag_add_sleep(adapter_nsrst_delay
* 1000);
836 /* Maybe enter the JTAG TAP_RESET state ...
837 * - using only TMS, TCK, and the JTAG state machine
838 * - or else more directly, using TRST
840 * TAP_RESET should be invisible to non-debug parts of the system.
843 LOG_DEBUG("JTAG reset with TLR instead of TRST");
846 } else if (jtag_trst
!= new_trst
) {
847 jtag_trst
= new_trst
;
849 LOG_DEBUG("TRST line asserted");
850 tap_set_state(TAP_RESET
);
851 if (jtag_ntrst_assert_width
)
852 jtag_add_sleep(jtag_ntrst_assert_width
* 1000);
854 LOG_DEBUG("TRST line released");
855 if (jtag_ntrst_delay
)
856 jtag_add_sleep(jtag_ntrst_delay
* 1000);
858 /* We just asserted nTRST, so we're now in TAP_RESET.
859 * Inform possible listeners about this, now that
860 * JTAG instructions and data can be shifted. This
861 * sequence must match jtag_add_tlr().
863 jtag_call_event_callbacks(JTAG_TRST_ASSERTED
);
864 jtag_notify_event(JTAG_TRST_ASSERTED
);
869 void jtag_add_sleep(uint32_t us
)
871 /** @todo Here, keep_alive() appears to be a layering violation!!! */
873 jtag_set_error(interface_jtag_add_sleep(us
));
876 static int jtag_check_value_inner(uint8_t *captured
, uint8_t *in_check_value
,
877 uint8_t *in_check_mask
, int num_bits
)
879 int retval
= ERROR_OK
;
883 compare_failed
= buf_cmp_mask(captured
, in_check_value
, in_check_mask
, num_bits
);
885 compare_failed
= buf_cmp(captured
, in_check_value
, num_bits
);
887 if (compare_failed
) {
888 char *captured_str
, *in_check_value_str
;
889 int bits
= (num_bits
> DEBUG_JTAG_IOZ
) ? DEBUG_JTAG_IOZ
: num_bits
;
891 /* NOTE: we've lost diagnostic context here -- 'which tap' */
893 captured_str
= buf_to_str(captured
, bits
, 16);
894 in_check_value_str
= buf_to_str(in_check_value
, bits
, 16);
896 LOG_WARNING("Bad value '%s' captured during DR or IR scan:",
898 LOG_WARNING(" check_value: 0x%s", in_check_value_str
);
901 free(in_check_value_str
);
904 char *in_check_mask_str
;
906 in_check_mask_str
= buf_to_str(in_check_mask
, bits
, 16);
907 LOG_WARNING(" check_mask: 0x%s", in_check_mask_str
);
908 free(in_check_mask_str
);
911 retval
= ERROR_JTAG_QUEUE_FAILED
;
916 void jtag_check_value_mask(struct scan_field
*field
, uint8_t *value
, uint8_t *mask
)
918 assert(field
->in_value
!= NULL
);
921 /* no checking to do */
925 jtag_execute_queue_noclear();
927 int retval
= jtag_check_value_inner(field
->in_value
, value
, mask
, field
->num_bits
);
928 jtag_set_error(retval
);
931 int default_interface_jtag_execute_queue(void)
934 LOG_ERROR("No JTAG interface configured yet. "
935 "Issue 'init' command in startup scripts "
936 "before communicating with targets.");
940 if (!transport_is_jtag()) {
942 * FIXME: This should not happen!
943 * There could be old code that queues jtag commands with non jtag interfaces so, for
944 * the moment simply highlight it by log an error and return on empty execute_queue.
945 * We should fix it quitting with assert(0) because it is an internal error.
946 * The fix can be applied immediately after next release (v0.11.0 ?)
948 LOG_ERROR("JTAG API jtag_execute_queue() called on non JTAG interface");
949 if (!jtag
->jtag_ops
|| !jtag
->jtag_ops
->execute_queue
)
953 int result
= jtag
->jtag_ops
->execute_queue();
956 /* Only build this if we use a regular driver with a command queue.
957 * Otherwise jtag_command_queue won't be found at compile/link time. Its
958 * definition is in jtag/commands.c, which is only built/linked by
959 * jtag/Makefile.am if MINIDRIVER_DUMMY || !MINIDRIVER, but those variables
960 * aren't accessible here. */
961 struct jtag_command
*cmd
= jtag_command_queue
;
962 while (debug_level
>= LOG_LVL_DEBUG
&& cmd
) {
965 LOG_DEBUG_IO("JTAG %s SCAN to %s",
966 cmd
->cmd
.scan
->ir_scan
? "IR" : "DR",
967 tap_state_name(cmd
->cmd
.scan
->end_state
));
968 for (int i
= 0; i
< cmd
->cmd
.scan
->num_fields
; i
++) {
969 struct scan_field
*field
= cmd
->cmd
.scan
->fields
+ i
;
970 if (field
->out_value
) {
971 char *str
= buf_to_str(field
->out_value
, field
->num_bits
, 16);
972 LOG_DEBUG_IO(" %db out: %s", field
->num_bits
, str
);
975 if (field
->in_value
) {
976 char *str
= buf_to_str(field
->in_value
, field
->num_bits
, 16);
977 LOG_DEBUG_IO(" %db in: %s", field
->num_bits
, str
);
983 LOG_DEBUG_IO("JTAG TLR RESET to %s",
984 tap_state_name(cmd
->cmd
.statemove
->end_state
));
987 LOG_DEBUG_IO("JTAG RUNTEST %d cycles to %s",
988 cmd
->cmd
.runtest
->num_cycles
,
989 tap_state_name(cmd
->cmd
.runtest
->end_state
));
993 const char *reset_str
[3] = {
994 "leave", "deassert", "assert"
996 LOG_DEBUG_IO("JTAG RESET %s TRST, %s SRST",
997 reset_str
[cmd
->cmd
.reset
->trst
+ 1],
998 reset_str
[cmd
->cmd
.reset
->srst
+ 1]);
1002 LOG_DEBUG_IO("JTAG PATHMOVE (TODO)");
1005 LOG_DEBUG_IO("JTAG SLEEP (TODO)");
1007 case JTAG_STABLECLOCKS
:
1008 LOG_DEBUG_IO("JTAG STABLECLOCKS (TODO)");
1011 LOG_DEBUG_IO("JTAG TMS (TODO)");
1014 LOG_ERROR("Unknown JTAG command: %d", cmd
->type
);
1024 void jtag_execute_queue_noclear(void)
1026 jtag_flush_queue_count
++;
1027 jtag_set_error(interface_jtag_execute_queue());
1029 if (jtag_flush_queue_sleep
> 0) {
1030 /* For debug purposes it can be useful to test performance
1031 * or behavior when delaying after flushing the queue,
1032 * e.g. to simulate long roundtrip times.
1034 usleep(jtag_flush_queue_sleep
* 1000);
1038 int jtag_get_flush_queue_count(void)
1040 return jtag_flush_queue_count
;
1043 int jtag_execute_queue(void)
1045 jtag_execute_queue_noclear();
1046 return jtag_error_clear();
1049 static int jtag_reset_callback(enum jtag_event event
, void *priv
)
1051 struct jtag_tap
*tap
= priv
;
1053 if (event
== JTAG_TRST_ASSERTED
) {
1054 tap
->enabled
= !tap
->disabled_after_reset
;
1056 /* current instruction is either BYPASS or IDCODE */
1057 buf_set_ones(tap
->cur_instr
, tap
->ir_length
);
1064 /* sleep at least us microseconds. When we sleep more than 1000ms we
1065 * do an alive sleep, i.e. keep GDB alive. Note that we could starve
1066 * GDB if we slept for <1000ms many times.
1068 void jtag_sleep(uint32_t us
)
1073 alive_sleep((us
+999)/1000);
1076 #define JTAG_MAX_AUTO_TAPS 20
1078 #define EXTRACT_JEP106_BANK(X) (((X) & 0xf00) >> 8)
1079 #define EXTRACT_JEP106_ID(X) (((X) & 0xfe) >> 1)
1080 #define EXTRACT_MFG(X) (((X) & 0xffe) >> 1)
1081 #define EXTRACT_PART(X) (((X) & 0xffff000) >> 12)
1082 #define EXTRACT_VER(X) (((X) & 0xf0000000) >> 28)
1084 /* A reserved manufacturer ID is used in END_OF_CHAIN_FLAG, so we
1085 * know that no valid TAP will have it as an IDCODE value.
1087 #define END_OF_CHAIN_FLAG 0xffffffff
1089 /* a larger IR length than we ever expect to autoprobe */
1090 #define JTAG_IRLEN_MAX 60
1092 static int jtag_examine_chain_execute(uint8_t *idcode_buffer
, unsigned num_idcode
)
1094 struct scan_field field
= {
1095 .num_bits
= num_idcode
* 32,
1096 .out_value
= idcode_buffer
,
1097 .in_value
= idcode_buffer
,
1100 /* initialize to the end of chain ID value */
1101 for (unsigned i
= 0; i
< num_idcode
; i
++)
1102 buf_set_u32(idcode_buffer
, i
* 32, 32, END_OF_CHAIN_FLAG
);
1104 jtag_add_plain_dr_scan(field
.num_bits
, field
.out_value
, field
.in_value
, TAP_DRPAUSE
);
1106 return jtag_execute_queue();
1109 static bool jtag_examine_chain_check(uint8_t *idcodes
, unsigned count
)
1111 uint8_t zero_check
= 0x0;
1112 uint8_t one_check
= 0xff;
1114 for (unsigned i
= 0; i
< count
* 4; i
++) {
1115 zero_check
|= idcodes
[i
];
1116 one_check
&= idcodes
[i
];
1119 /* if there wasn't a single non-zero bit or if all bits were one,
1120 * the scan is not valid. We wrote a mix of both values; either
1122 * - There's a hardware issue (almost certainly):
1123 * + all-zeroes can mean a target stuck in JTAG reset
1124 * + all-ones tends to mean no target
1125 * - The scan chain is WAY longer than we can handle, *AND* either
1126 * + there are several hundreds of TAPs in bypass, or
1127 * + at least a few dozen TAPs all have an all-ones IDCODE
1129 if (zero_check
== 0x00 || one_check
== 0xff) {
1130 LOG_ERROR("JTAG scan chain interrogation failed: all %s",
1131 (zero_check
== 0x00) ? "zeroes" : "ones");
1132 LOG_ERROR("Check JTAG interface, timings, target power, etc.");
1138 static void jtag_examine_chain_display(enum log_levels level
, const char *msg
,
1139 const char *name
, uint32_t idcode
)
1141 log_printf_lf(level
, __FILE__
, __LINE__
, __func__
,
1142 "JTAG tap: %s %16.16s: 0x%08x "
1143 "(mfg: 0x%3.3x (%s), part: 0x%4.4x, ver: 0x%1.1x)",
1145 (unsigned int)idcode
,
1146 (unsigned int)EXTRACT_MFG(idcode
),
1147 jep106_manufacturer(EXTRACT_JEP106_BANK(idcode
), EXTRACT_JEP106_ID(idcode
)),
1148 (unsigned int)EXTRACT_PART(idcode
),
1149 (unsigned int)EXTRACT_VER(idcode
));
1152 static bool jtag_idcode_is_final(uint32_t idcode
)
1155 * Some devices, such as AVR8, will output all 1's instead
1156 * of TDI input value at end of chain. Allow those values
1157 * instead of failing.
1159 return idcode
== END_OF_CHAIN_FLAG
;
1163 * This helper checks that remaining bits in the examined chain data are
1164 * all as expected, but a single JTAG device requires only 64 bits to be
1165 * read back correctly. This can help identify and diagnose problems
1166 * with the JTAG chain earlier, gives more helpful/explicit error messages.
1167 * Returns TRUE iff garbage was found.
1169 static bool jtag_examine_chain_end(uint8_t *idcodes
, unsigned count
, unsigned max
)
1171 bool triggered
= false;
1172 for (; count
< max
- 31; count
+= 32) {
1173 uint32_t idcode
= buf_get_u32(idcodes
, count
, 32);
1175 /* do not trigger the warning if the data looks good */
1176 if (jtag_idcode_is_final(idcode
))
1178 LOG_WARNING("Unexpected idcode after end of chain: %d 0x%08x",
1179 count
, (unsigned int)idcode
);
1185 static bool jtag_examine_chain_match_tap(const struct jtag_tap
*tap
)
1188 if (tap
->expected_ids_cnt
== 0 || !tap
->hasidcode
)
1191 /* optionally ignore the JTAG version field - bits 28-31 of IDCODE */
1192 uint32_t mask
= tap
->ignore_version
? ~(0xfU
<< 28) : ~0U;
1193 uint32_t idcode
= tap
->idcode
& mask
;
1195 /* Loop over the expected identification codes and test for a match */
1196 for (unsigned ii
= 0; ii
< tap
->expected_ids_cnt
; ii
++) {
1197 uint32_t expected
= tap
->expected_ids
[ii
] & mask
;
1199 if (idcode
== expected
)
1202 /* treat "-expected-id 0" as a "don't-warn" wildcard */
1203 if (0 == tap
->expected_ids
[ii
])
1207 /* If none of the expected ids matched, warn */
1208 jtag_examine_chain_display(LOG_LVL_WARNING
, "UNEXPECTED",
1209 tap
->dotted_name
, tap
->idcode
);
1210 for (unsigned ii
= 0; ii
< tap
->expected_ids_cnt
; ii
++) {
1213 snprintf(msg
, sizeof(msg
), "expected %u of %u", ii
+ 1, tap
->expected_ids_cnt
);
1214 jtag_examine_chain_display(LOG_LVL_ERROR
, msg
,
1215 tap
->dotted_name
, tap
->expected_ids
[ii
]);
1220 /* Try to examine chain layout according to IEEE 1149.1 §12
1221 * This is called a "blind interrogation" of the scan chain.
1223 static int jtag_examine_chain(void)
1226 unsigned max_taps
= jtag_tap_count();
1228 /* Autoprobe up to this many. */
1229 if (max_taps
< JTAG_MAX_AUTO_TAPS
)
1230 max_taps
= JTAG_MAX_AUTO_TAPS
;
1232 /* Add room for end-of-chain marker. */
1235 uint8_t *idcode_buffer
= malloc(max_taps
* 4);
1236 if (idcode_buffer
== NULL
)
1237 return ERROR_JTAG_INIT_FAILED
;
1239 /* DR scan to collect BYPASS or IDCODE register contents.
1240 * Then make sure the scan data has both ones and zeroes.
1242 LOG_DEBUG("DR scan interrogation for IDCODE/BYPASS");
1243 retval
= jtag_examine_chain_execute(idcode_buffer
, max_taps
);
1244 if (retval
!= ERROR_OK
)
1246 if (!jtag_examine_chain_check(idcode_buffer
, max_taps
)) {
1247 retval
= ERROR_JTAG_INIT_FAILED
;
1251 /* Point at the 1st predefined tap, if any */
1252 struct jtag_tap
*tap
= jtag_tap_next_enabled(NULL
);
1254 unsigned bit_count
= 0;
1255 unsigned autocount
= 0;
1256 for (unsigned i
= 0; i
< max_taps
; i
++) {
1257 assert(bit_count
< max_taps
* 32);
1258 uint32_t idcode
= buf_get_u32(idcode_buffer
, bit_count
, 32);
1260 /* No predefined TAP? Auto-probe. */
1262 /* Is there another TAP? */
1263 if (jtag_idcode_is_final(idcode
))
1266 /* Default everything in this TAP except IR length.
1268 * REVISIT create a jtag_alloc(chip, tap) routine, and
1269 * share it with jim_newtap_cmd().
1271 tap
= calloc(1, sizeof *tap
);
1273 retval
= ERROR_FAIL
;
1277 tap
->chip
= alloc_printf("auto%u", autocount
++);
1278 tap
->tapname
= strdup("tap");
1279 tap
->dotted_name
= alloc_printf("%s.%s", tap
->chip
, tap
->tapname
);
1281 tap
->ir_length
= 0; /* ... signifying irlen autoprobe */
1282 tap
->ir_capture_mask
= 0x03;
1283 tap
->ir_capture_value
= 0x01;
1285 tap
->enabled
= true;
1290 if ((idcode
& 1) == 0) {
1291 /* Zero for LSB indicates a device in bypass */
1292 LOG_INFO("TAP %s does not have valid IDCODE (idcode=0x%x)",
1293 tap
->dotted_name
, idcode
);
1294 tap
->hasidcode
= false;
1299 /* Friendly devices support IDCODE */
1300 tap
->hasidcode
= true;
1301 tap
->idcode
= idcode
;
1302 jtag_examine_chain_display(LOG_LVL_INFO
, "tap/device found", tap
->dotted_name
, idcode
);
1307 /* ensure the TAP ID matches what was expected */
1308 if (!jtag_examine_chain_match_tap(tap
))
1309 retval
= ERROR_JTAG_INIT_SOFT_FAIL
;
1311 tap
= jtag_tap_next_enabled(tap
);
1314 /* After those IDCODE or BYPASS register values should be
1315 * only the data we fed into the scan chain.
1317 if (jtag_examine_chain_end(idcode_buffer
, bit_count
, max_taps
* 32)) {
1318 LOG_ERROR("double-check your JTAG setup (interface, speed, ...)");
1319 retval
= ERROR_JTAG_INIT_FAILED
;
1323 /* Return success or, for backwards compatibility if only
1324 * some IDCODE values mismatched, a soft/continuable fault.
1327 free(idcode_buffer
);
1332 * Validate the date loaded by entry to the Capture-IR state, to help
1333 * find errors related to scan chain configuration (wrong IR lengths)
1336 * Entry state can be anything. On non-error exit, all TAPs are in
1337 * bypass mode. On error exits, the scan chain is reset.
1339 static int jtag_validate_ircapture(void)
1341 struct jtag_tap
*tap
;
1342 int total_ir_length
= 0;
1343 uint8_t *ir_test
= NULL
;
1344 struct scan_field field
;
1349 /* when autoprobing, accomodate huge IR lengths */
1350 for (tap
= NULL
, total_ir_length
= 0;
1351 (tap
= jtag_tap_next_enabled(tap
)) != NULL
;
1352 total_ir_length
+= tap
->ir_length
) {
1353 if (tap
->ir_length
== 0)
1354 total_ir_length
+= JTAG_IRLEN_MAX
;
1357 /* increase length to add 2 bit sentinel after scan */
1358 total_ir_length
+= 2;
1360 ir_test
= malloc(DIV_ROUND_UP(total_ir_length
, 8));
1361 if (ir_test
== NULL
)
1364 /* after this scan, all TAPs will capture BYPASS instructions */
1365 buf_set_ones(ir_test
, total_ir_length
);
1367 field
.num_bits
= total_ir_length
;
1368 field
.out_value
= ir_test
;
1369 field
.in_value
= ir_test
;
1371 jtag_add_plain_ir_scan(field
.num_bits
, field
.out_value
, field
.in_value
, TAP_IDLE
);
1373 LOG_DEBUG("IR capture validation scan");
1374 retval
= jtag_execute_queue();
1375 if (retval
!= ERROR_OK
)
1382 tap
= jtag_tap_next_enabled(tap
);
1386 /* If we're autoprobing, guess IR lengths. They must be at
1387 * least two bits. Guessing will fail if (a) any TAP does
1388 * not conform to the JTAG spec; or (b) when the upper bits
1389 * captured from some conforming TAP are nonzero. Or if
1390 * (c) an IR length is longer than JTAG_IRLEN_MAX bits,
1391 * an implementation limit, which could someday be raised.
1393 * REVISIT optimization: if there's a *single* TAP we can
1394 * lift restrictions (a) and (b) by scanning a recognizable
1395 * pattern before the all-ones BYPASS. Check for where the
1396 * pattern starts in the result, instead of an 0...01 value.
1398 * REVISIT alternative approach: escape to some tcl code
1399 * which could provide more knowledge, based on IDCODE; and
1400 * only guess when that has no success.
1402 if (tap
->ir_length
== 0) {
1404 while ((val
= buf_get_u64(ir_test
, chain_pos
, tap
->ir_length
+ 1)) == 1
1405 && tap
->ir_length
< JTAG_IRLEN_MAX
) {
1408 LOG_WARNING("AUTO %s - use \"jtag newtap " "%s %s -irlen %d "
1409 "-expected-id 0x%08" PRIx32
"\"",
1410 tap
->dotted_name
, tap
->chip
, tap
->tapname
, tap
->ir_length
, tap
->idcode
);
1413 /* Validate the two LSBs, which must be 01 per JTAG spec.
1415 * Or ... more bits could be provided by TAP declaration.
1416 * Plus, some taps (notably in i.MX series chips) violate
1417 * this part of the JTAG spec, so their capture mask/value
1418 * attributes might disable this test.
1420 val
= buf_get_u64(ir_test
, chain_pos
, tap
->ir_length
);
1421 if ((val
& tap
->ir_capture_mask
) != tap
->ir_capture_value
) {
1422 LOG_ERROR("%s: IR capture error; saw 0x%0*" PRIx64
" not 0x%0*" PRIx32
,
1424 (tap
->ir_length
+ 7) / tap
->ir_length
, val
,
1425 (tap
->ir_length
+ 7) / tap
->ir_length
, tap
->ir_capture_value
);
1427 retval
= ERROR_JTAG_INIT_FAILED
;
1430 LOG_DEBUG("%s: IR capture 0x%0*" PRIx64
, jtag_tap_name(tap
),
1431 (tap
->ir_length
+ 7) / tap
->ir_length
, val
);
1432 chain_pos
+= tap
->ir_length
;
1435 /* verify the '11' sentinel we wrote is returned at the end */
1436 val
= buf_get_u64(ir_test
, chain_pos
, 2);
1438 char *cbuf
= buf_to_str(ir_test
, total_ir_length
, 16);
1440 LOG_ERROR("IR capture error at bit %d, saw 0x%s not 0x...3",
1443 retval
= ERROR_JTAG_INIT_FAILED
;
1448 if (retval
!= ERROR_OK
) {
1450 jtag_execute_queue();
1455 void jtag_tap_init(struct jtag_tap
*tap
)
1457 unsigned ir_len_bits
;
1458 unsigned ir_len_bytes
;
1460 /* if we're autoprobing, cope with potentially huge ir_length */
1461 ir_len_bits
= tap
->ir_length
? : JTAG_IRLEN_MAX
;
1462 ir_len_bytes
= DIV_ROUND_UP(ir_len_bits
, 8);
1464 tap
->expected
= calloc(1, ir_len_bytes
);
1465 tap
->expected_mask
= calloc(1, ir_len_bytes
);
1466 tap
->cur_instr
= malloc(ir_len_bytes
);
1468 /** @todo cope better with ir_length bigger than 32 bits */
1469 if (ir_len_bits
> 32)
1472 buf_set_u32(tap
->expected
, 0, ir_len_bits
, tap
->ir_capture_value
);
1473 buf_set_u32(tap
->expected_mask
, 0, ir_len_bits
, tap
->ir_capture_mask
);
1475 /* TAP will be in bypass mode after jtag_validate_ircapture() */
1477 buf_set_ones(tap
->cur_instr
, tap
->ir_length
);
1479 /* register the reset callback for the TAP */
1480 jtag_register_event_callback(&jtag_reset_callback
, tap
);
1483 LOG_DEBUG("Created Tap: %s @ abs position %d, "
1484 "irlen %d, capture: 0x%x mask: 0x%x", tap
->dotted_name
,
1485 tap
->abs_chain_position
, tap
->ir_length
,
1486 (unsigned) tap
->ir_capture_value
,
1487 (unsigned) tap
->ir_capture_mask
);
1490 void jtag_tap_free(struct jtag_tap
*tap
)
1492 jtag_unregister_event_callback(&jtag_reset_callback
, tap
);
1494 struct jtag_tap_event_action
*jteap
= tap
->event_action
;
1496 struct jtag_tap_event_action
*next
= jteap
->next
;
1497 Jim_DecrRefCount(jteap
->interp
, jteap
->body
);
1502 free(tap
->expected
);
1503 free(tap
->expected_mask
);
1504 free(tap
->expected_ids
);
1505 free(tap
->cur_instr
);
1508 free(tap
->dotted_name
);
1513 * Do low-level setup like initializing registers, output signals,
1516 int adapter_init(struct command_context
*cmd_ctx
)
1521 if (!adapter_driver
) {
1522 /* nothing was previously specified by "interface" command */
1523 LOG_ERROR("Debug Adapter has to be specified, "
1524 "see \"interface\" command");
1525 return ERROR_JTAG_INVALID_INTERFACE
;
1529 retval
= adapter_driver
->init();
1530 if (retval
!= ERROR_OK
)
1532 jtag
= adapter_driver
;
1534 if (jtag
->speed
== NULL
) {
1535 LOG_INFO("This adapter doesn't support configurable speed");
1539 if (CLOCK_MODE_UNSELECTED
== clock_mode
) {
1540 LOG_ERROR("An adapter speed is not selected in the init script."
1541 " Insert a call to adapter_khz or jtag_rclk to proceed.");
1542 return ERROR_JTAG_INIT_FAILED
;
1545 int requested_khz
= jtag_get_speed_khz();
1546 int actual_khz
= requested_khz
;
1547 int jtag_speed_var
= 0;
1548 retval
= jtag_get_speed(&jtag_speed_var
);
1549 if (retval
!= ERROR_OK
)
1551 retval
= jtag
->speed(jtag_speed_var
);
1552 if (retval
!= ERROR_OK
)
1554 retval
= jtag_get_speed_readable(&actual_khz
);
1555 if (ERROR_OK
!= retval
)
1556 LOG_INFO("adapter-specific clock speed value %d", jtag_speed_var
);
1557 else if (actual_khz
) {
1558 /* Adaptive clocking -- JTAG-specific */
1559 if ((CLOCK_MODE_RCLK
== clock_mode
)
1560 || ((CLOCK_MODE_KHZ
== clock_mode
) && !requested_khz
)) {
1561 LOG_INFO("RCLK (adaptive clock speed) not supported - fallback to %d kHz"
1564 LOG_INFO("clock speed %d kHz", actual_khz
);
1566 LOG_INFO("RCLK (adaptive clock speed)");
1571 int jtag_init_inner(struct command_context
*cmd_ctx
)
1573 struct jtag_tap
*tap
;
1575 bool issue_setup
= true;
1577 LOG_DEBUG("Init JTAG chain");
1579 tap
= jtag_tap_next_enabled(NULL
);
1581 /* Once JTAG itself is properly set up, and the scan chain
1582 * isn't absurdly large, IDCODE autoprobe should work fine.
1584 * But ... IRLEN autoprobe can fail even on systems which
1585 * are fully conformant to JTAG. Also, JTAG setup can be
1586 * quite finicky on some systems.
1588 * REVISIT: if TAP autoprobe works OK, then in many cases
1589 * we could escape to tcl code and set up targets based on
1590 * the TAP's IDCODE values.
1592 LOG_WARNING("There are no enabled taps. "
1593 "AUTO PROBING MIGHT NOT WORK!!");
1595 /* REVISIT default clock will often be too fast ... */
1599 retval
= jtag_execute_queue();
1600 if (retval
!= ERROR_OK
)
1603 /* Examine DR values first. This discovers problems which will
1604 * prevent communication ... hardware issues like TDO stuck, or
1605 * configuring the wrong number of (enabled) TAPs.
1607 retval
= jtag_examine_chain();
1610 /* complete success */
1613 /* For backward compatibility reasons, try coping with
1614 * configuration errors involving only ID mismatches.
1615 * We might be able to talk to the devices.
1617 * Also the device might be powered down during startup.
1619 * After OpenOCD starts, we can try to power on the device
1622 LOG_ERROR("Trying to use configured scan chain anyway...");
1623 issue_setup
= false;
1627 /* Now look at IR values. Problems here will prevent real
1628 * communication. They mostly mean that the IR length is
1629 * wrong ... or that the IR capture value is wrong. (The
1630 * latter is uncommon, but easily worked around: provide
1631 * ircapture/irmask values during TAP setup.)
1633 retval
= jtag_validate_ircapture();
1634 if (retval
!= ERROR_OK
) {
1635 /* The target might be powered down. The user
1636 * can power it up and reset it after firing
1639 issue_setup
= false;
1643 jtag_notify_event(JTAG_TAP_EVENT_SETUP
);
1645 LOG_WARNING("Bypassing JTAG setup events due to errors");
1651 int adapter_quit(void)
1653 if (jtag
&& jtag
->quit
) {
1654 /* close the JTAG interface */
1655 int result
= jtag
->quit();
1656 if (ERROR_OK
!= result
)
1657 LOG_ERROR("failed: %d", result
);
1660 struct jtag_tap
*t
= jtag_all_taps();
1662 struct jtag_tap
*n
= t
->next_tap
;
1670 int swd_init_reset(struct command_context
*cmd_ctx
)
1672 int retval
, retval1
;
1674 retval
= adapter_init(cmd_ctx
);
1675 if (retval
!= ERROR_OK
)
1678 LOG_DEBUG("Initializing with hard SRST reset");
1680 if (jtag_reset_config
& RESET_HAS_SRST
)
1681 retval
= adapter_system_reset(1);
1682 retval1
= adapter_system_reset(0);
1684 return (retval
== ERROR_OK
) ? retval1
: retval
;
1687 int jtag_init_reset(struct command_context
*cmd_ctx
)
1689 int retval
= adapter_init(cmd_ctx
);
1690 if (retval
!= ERROR_OK
)
1693 LOG_DEBUG("Initializing with hard TRST+SRST reset");
1696 * This procedure is used by default when OpenOCD triggers a reset.
1697 * It's now done through an overridable Tcl "init_reset" wrapper.
1699 * This started out as a more powerful "get JTAG working" reset than
1700 * jtag_init_inner(), applying TRST because some chips won't activate
1701 * JTAG without a TRST cycle (presumed to be async, though some of
1702 * those chips synchronize JTAG activation using TCK).
1704 * But some chips only activate JTAG as part of an SRST cycle; SRST
1705 * got mixed in. So it became a hard reset routine, which got used
1706 * in more places, and which coped with JTAG reset being forced as
1707 * part of SRST (srst_pulls_trst).
1709 * And even more corner cases started to surface: TRST and/or SRST
1710 * assertion timings matter; some chips need other JTAG operations;
1711 * TRST/SRST sequences can need to be different from these, etc.
1713 * Systems should override that wrapper to support system-specific
1714 * requirements that this not-fully-generic code doesn't handle.
1716 * REVISIT once Tcl code can read the reset_config modes, this won't
1717 * need to be a C routine at all...
1719 if (jtag_reset_config
& RESET_HAS_SRST
) {
1720 jtag_add_reset(1, 1);
1721 if ((jtag_reset_config
& RESET_SRST_PULLS_TRST
) == 0)
1722 jtag_add_reset(0, 1);
1724 jtag_add_reset(1, 0); /* TAP_RESET, using TMS+TCK or TRST */
1727 /* some targets enable us to connect with srst asserted */
1728 if (jtag_reset_config
& RESET_CNCT_UNDER_SRST
) {
1729 if (jtag_reset_config
& RESET_SRST_NO_GATING
)
1730 jtag_add_reset(0, 1);
1732 LOG_WARNING("\'srst_nogate\' reset_config option is required");
1733 jtag_add_reset(0, 0);
1736 jtag_add_reset(0, 0);
1737 retval
= jtag_execute_queue();
1738 if (retval
!= ERROR_OK
)
1741 /* Check that we can communication on the JTAG chain + eventually we want to
1742 * be able to perform enumeration only after OpenOCD has started
1743 * telnet and GDB server
1745 * That would allow users to more easily perform any magic they need to before
1748 return jtag_init_inner(cmd_ctx
);
1751 int jtag_init(struct command_context
*cmd_ctx
)
1753 int retval
= adapter_init(cmd_ctx
);
1754 if (retval
!= ERROR_OK
)
1757 /* guard against oddball hardware: force resets to be inactive */
1758 jtag_add_reset(0, 0);
1760 /* some targets enable us to connect with srst asserted */
1761 if (jtag_reset_config
& RESET_CNCT_UNDER_SRST
) {
1762 if (jtag_reset_config
& RESET_SRST_NO_GATING
)
1763 jtag_add_reset(0, 1);
1765 LOG_WARNING("\'srst_nogate\' reset_config option is required");
1767 retval
= jtag_execute_queue();
1768 if (retval
!= ERROR_OK
)
1771 if (Jim_Eval_Named(cmd_ctx
->interp
, "jtag_init", __FILE__
, __LINE__
) != JIM_OK
)
1777 unsigned jtag_get_speed_khz(void)
1782 static int adapter_khz_to_speed(unsigned khz
, int *speed
)
1784 LOG_DEBUG("convert khz to interface specific speed value");
1788 LOG_DEBUG("have interface set up");
1790 LOG_ERROR("Translation from khz to jtag_speed not implemented");
1794 int retval
= jtag
->khz(jtag_get_speed_khz(), &speed_div1
);
1795 if (ERROR_OK
!= retval
)
1797 *speed
= speed_div1
;
1801 static int jtag_rclk_to_speed(unsigned fallback_speed_khz
, int *speed
)
1803 int retval
= adapter_khz_to_speed(0, speed
);
1804 if ((ERROR_OK
!= retval
) && fallback_speed_khz
) {
1805 LOG_DEBUG("trying fallback speed...");
1806 retval
= adapter_khz_to_speed(fallback_speed_khz
, speed
);
1811 static int jtag_set_speed(int speed
)
1814 /* this command can be called during CONFIG,
1815 * in which case jtag isn't initialized */
1816 return jtag
? jtag
->speed(speed
) : ERROR_OK
;
1819 int jtag_config_khz(unsigned khz
)
1821 LOG_DEBUG("handle jtag khz");
1822 clock_mode
= CLOCK_MODE_KHZ
;
1824 int retval
= adapter_khz_to_speed(khz
, &speed
);
1825 return (ERROR_OK
!= retval
) ? retval
: jtag_set_speed(speed
);
1828 int jtag_config_rclk(unsigned fallback_speed_khz
)
1830 LOG_DEBUG("handle jtag rclk");
1831 clock_mode
= CLOCK_MODE_RCLK
;
1832 rclk_fallback_speed_khz
= fallback_speed_khz
;
1834 int retval
= jtag_rclk_to_speed(fallback_speed_khz
, &speed
);
1835 return (ERROR_OK
!= retval
) ? retval
: jtag_set_speed(speed
);
1838 int jtag_get_speed(int *speed
)
1840 switch (clock_mode
) {
1841 case CLOCK_MODE_KHZ
:
1842 adapter_khz_to_speed(jtag_get_speed_khz(), speed
);
1844 case CLOCK_MODE_RCLK
:
1845 jtag_rclk_to_speed(rclk_fallback_speed_khz
, speed
);
1848 LOG_ERROR("BUG: unknown jtag clock mode");
1854 int jtag_get_speed_readable(int *khz
)
1856 int jtag_speed_var
= 0;
1857 int retval
= jtag_get_speed(&jtag_speed_var
);
1858 if (retval
!= ERROR_OK
)
1862 if (!jtag
->speed_div
) {
1863 LOG_ERROR("Translation from jtag_speed to khz not implemented");
1866 return jtag
->speed_div(jtag_speed_var
, khz
);
1869 void jtag_set_verify(bool enable
)
1871 jtag_verify
= enable
;
1874 bool jtag_will_verify()
1879 void jtag_set_verify_capture_ir(bool enable
)
1881 jtag_verify_capture_ir
= enable
;
1884 bool jtag_will_verify_capture_ir()
1886 return jtag_verify_capture_ir
;
1889 int jtag_power_dropout(int *dropout
)
1892 /* TODO: as the jtag interface is not valid all
1893 * we can do at the moment is exit OpenOCD */
1894 LOG_ERROR("No Valid JTAG Interface Configured.");
1897 if (jtag
->power_dropout
)
1898 return jtag
->power_dropout(dropout
);
1900 *dropout
= 0; /* by default we can't detect power dropout */
1904 int jtag_srst_asserted(int *srst_asserted
)
1906 if (jtag
->srst_asserted
)
1907 return jtag
->srst_asserted(srst_asserted
);
1909 *srst_asserted
= 0; /* by default we can't detect srst asserted */
1913 enum reset_types
jtag_get_reset_config(void)
1915 return jtag_reset_config
;
1917 void jtag_set_reset_config(enum reset_types type
)
1919 jtag_reset_config
= type
;
1922 int jtag_get_trst(void)
1924 return jtag_trst
== 1;
1926 int jtag_get_srst(void)
1928 return jtag_srst
== 1;
1931 void jtag_set_nsrst_delay(unsigned delay
)
1933 adapter_nsrst_delay
= delay
;
1935 unsigned jtag_get_nsrst_delay(void)
1937 return adapter_nsrst_delay
;
1939 void jtag_set_ntrst_delay(unsigned delay
)
1941 jtag_ntrst_delay
= delay
;
1943 unsigned jtag_get_ntrst_delay(void)
1945 return jtag_ntrst_delay
;
1949 void jtag_set_nsrst_assert_width(unsigned delay
)
1951 adapter_nsrst_assert_width
= delay
;
1953 unsigned jtag_get_nsrst_assert_width(void)
1955 return adapter_nsrst_assert_width
;
1957 void jtag_set_ntrst_assert_width(unsigned delay
)
1959 jtag_ntrst_assert_width
= delay
;
1961 unsigned jtag_get_ntrst_assert_width(void)
1963 return jtag_ntrst_assert_width
;
1966 static int jtag_select(struct command_context
*ctx
)
1970 /* NOTE: interface init must already have been done.
1971 * That works with only C code ... no Tcl glue required.
1974 retval
= jtag_register_commands(ctx
);
1976 if (retval
!= ERROR_OK
)
1979 retval
= svf_register_commands(ctx
);
1981 if (retval
!= ERROR_OK
)
1984 return xsvf_register_commands(ctx
);
1987 static struct transport jtag_transport
= {
1989 .select
= jtag_select
,
1993 static void jtag_constructor(void) __attribute__((constructor
));
1994 static void jtag_constructor(void)
1996 transport_register(&jtag_transport
);
1999 /** Returns true if the current debug session
2000 * is using JTAG as its transport.
2002 bool transport_is_jtag(void)
2004 return get_current_transport() == &jtag_transport
;
2007 int adapter_resets(int trst
, int srst
)
2009 if (get_current_transport() == NULL
) {
2010 LOG_ERROR("transport is not selected");
2014 if (transport_is_jtag()) {
2015 if (srst
== SRST_ASSERT
&& !(jtag_reset_config
& RESET_HAS_SRST
)) {
2016 LOG_ERROR("adapter has no srst signal");
2020 /* adapters without trst signal will eventually use tlr sequence */
2021 jtag_add_reset(trst
, srst
);
2023 } else if (transport_is_swd() || transport_is_hla()) {
2024 if (trst
== TRST_ASSERT
) {
2025 LOG_ERROR("transport %s has no trst signal",
2026 get_current_transport()->name
);
2030 if (srst
== SRST_ASSERT
&& !(jtag_reset_config
& RESET_HAS_SRST
)) {
2031 LOG_ERROR("adapter has no srst signal");
2034 adapter_system_reset(srst
);
2038 if (trst
== TRST_DEASSERT
&& srst
== SRST_DEASSERT
)
2041 LOG_ERROR("reset is not supported on transport %s",
2042 get_current_transport()->name
);
2047 int adapter_assert_reset(void)
2049 if (transport_is_jtag()) {
2050 if (jtag_reset_config
& RESET_SRST_PULLS_TRST
)
2051 jtag_add_reset(1, 1);
2053 jtag_add_reset(0, 1);
2055 } else if (transport_is_swd() || transport_is_hla() ||
2056 transport_is_dapdirect_jtag() || transport_is_dapdirect_swd())
2057 return adapter_system_reset(1);
2058 else if (get_current_transport() != NULL
)
2059 LOG_ERROR("reset is not supported on %s",
2060 get_current_transport()->name
);
2062 LOG_ERROR("transport is not selected");
2066 int adapter_deassert_reset(void)
2068 if (transport_is_jtag()) {
2069 jtag_add_reset(0, 0);
2071 } else if (transport_is_swd() || transport_is_hla() ||
2072 transport_is_dapdirect_jtag() || transport_is_dapdirect_swd())
2073 return adapter_system_reset(0);
2074 else if (get_current_transport() != NULL
)
2075 LOG_ERROR("reset is not supported on %s",
2076 get_current_transport()->name
);
2078 LOG_ERROR("transport is not selected");
2082 int adapter_config_trace(bool enabled
, enum tpiu_pin_protocol pin_protocol
,
2083 uint32_t port_size
, unsigned int *trace_freq
,
2084 unsigned int traceclkin_freq
, uint16_t *prescaler
)
2086 if (jtag
->config_trace
) {
2087 return jtag
->config_trace(enabled
, pin_protocol
, port_size
, trace_freq
,
2088 traceclkin_freq
, prescaler
);
2089 } else if (enabled
) {
2090 LOG_ERROR("The selected interface does not support tracing");
2097 int adapter_poll_trace(uint8_t *buf
, size_t *size
)
2099 if (jtag
->poll_trace
)
2100 return jtag
->poll_trace(buf
, size
);
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