2 * Copyright (C) 2009 by David Brownell
4 * This program is free software; you can redistribute it and/or modify
5 * it under the terms of the GNU General Public License as published by
6 * the Free Software Foundation; either version 2 of the License, or
7 * (at your option) any later version.
9 * This program is distributed in the hope that it will be useful
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
22 #include "armv8_dpm.h"
23 #include <jtag/jtag.h>
25 #include "breakpoints.h"
26 #include "target_type.h"
27 #include "armv8_opcodes.h"
29 #include "helper/time_support.h"
32 #define T32_FMTITR(instr) (((instr & 0x0000FFFF) << 16) | ((instr & 0xFFFF0000) >> 16))
36 * Implements various ARM DPM operations using architectural debug registers.
37 * These routines layer over core-specific communication methods to cope with
38 * implementation differences between cores like ARM1136 and Cortex-A8.
40 * The "Debug Programmers' Model" (DPM) for ARMv6 and ARMv7 is defined by
41 * Part C (Debug Architecture) of the ARM Architecture Reference Manual,
42 * ARMv7-A and ARMv7-R edition (ARM DDI 0406B). In OpenOCD, DPM operations
43 * are abstracted through internal programming interfaces to share code and
44 * to minimize needless differences in debug behavior between cores.
48 * Get core state from EDSCR, without necessity to retrieve CPSR
50 enum arm_state
armv8_dpm_get_core_state(struct arm_dpm
*dpm
)
52 int el
= (dpm
->dscr
>> 8) & 0x3;
53 int rw
= (dpm
->dscr
>> 10) & 0xF;
57 /* In Debug state, each bit gives the current Execution state of each EL */
59 return ARM_STATE_AARCH64
;
64 /*----------------------------------------------------------------------*/
66 static int dpmv8_write_dcc(struct armv8_common
*armv8
, uint32_t data
)
68 return mem_ap_write_u32(armv8
->debug_ap
,
69 armv8
->debug_base
+ CPUV8_DBG_DTRRX
, data
);
72 static int dpmv8_write_dcc_64(struct armv8_common
*armv8
, uint64_t data
)
75 ret
= mem_ap_write_u32(armv8
->debug_ap
,
76 armv8
->debug_base
+ CPUV8_DBG_DTRRX
, data
);
78 ret
= mem_ap_write_u32(armv8
->debug_ap
,
79 armv8
->debug_base
+ CPUV8_DBG_DTRTX
, data
>> 32);
83 static int dpmv8_read_dcc(struct armv8_common
*armv8
, uint32_t *data
,
86 uint32_t dscr
= DSCR_ITE
;
92 /* Wait for DTRRXfull */
93 long long then
= timeval_ms();
94 while ((dscr
& DSCR_DTR_TX_FULL
) == 0) {
95 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
96 armv8
->debug_base
+ CPUV8_DBG_DSCR
,
98 if (retval
!= ERROR_OK
)
100 if (timeval_ms() > then
+ 1000) {
101 LOG_ERROR("Timeout waiting for read dcc");
106 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
107 armv8
->debug_base
+ CPUV8_DBG_DTRTX
,
109 if (retval
!= ERROR_OK
)
118 static int dpmv8_read_dcc_64(struct armv8_common
*armv8
, uint64_t *data
,
121 uint32_t dscr
= DSCR_ITE
;
128 /* Wait for DTRRXfull */
129 long long then
= timeval_ms();
130 while ((dscr
& DSCR_DTR_TX_FULL
) == 0) {
131 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
132 armv8
->debug_base
+ CPUV8_DBG_DSCR
,
134 if (retval
!= ERROR_OK
)
136 if (timeval_ms() > then
+ 1000) {
137 LOG_ERROR("Timeout waiting for DTR_TX_FULL, dscr = 0x%08" PRIx32
, dscr
);
142 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
143 armv8
->debug_base
+ CPUV8_DBG_DTRTX
,
145 if (retval
!= ERROR_OK
)
148 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
149 armv8
->debug_base
+ CPUV8_DBG_DTRRX
,
151 if (retval
!= ERROR_OK
)
154 *data
= *(uint32_t *)data
| (uint64_t)higher
<< 32;
162 static int dpmv8_dpm_prepare(struct arm_dpm
*dpm
)
164 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
168 /* set up invariant: ITE is set after ever DPM operation */
169 long long then
= timeval_ms();
171 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
172 armv8
->debug_base
+ CPUV8_DBG_DSCR
,
174 if (retval
!= ERROR_OK
)
176 if ((dscr
& DSCR_ITE
) != 0)
178 if (timeval_ms() > then
+ 1000) {
179 LOG_ERROR("Timeout waiting for dpm prepare");
184 /* update the stored copy of dscr */
187 /* this "should never happen" ... */
188 if (dscr
& DSCR_DTR_RX_FULL
) {
189 LOG_ERROR("DSCR_DTR_RX_FULL, dscr 0x%08" PRIx32
, dscr
);
191 retval
= mem_ap_read_u32(armv8
->debug_ap
,
192 armv8
->debug_base
+ CPUV8_DBG_DTRRX
, &dscr
);
193 if (retval
!= ERROR_OK
)
200 static int dpmv8_dpm_finish(struct arm_dpm
*dpm
)
202 /* REVISIT what could be done here? */
206 static int dpmv8_exec_opcode(struct arm_dpm
*dpm
,
207 uint32_t opcode
, uint32_t *p_dscr
)
209 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
210 uint32_t dscr
= dpm
->dscr
;
216 /* Wait for InstrCompl bit to be set */
217 long long then
= timeval_ms();
218 while ((dscr
& DSCR_ITE
) == 0) {
219 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
220 armv8
->debug_base
+ CPUV8_DBG_DSCR
, &dscr
);
221 if (retval
!= ERROR_OK
) {
222 LOG_ERROR("Could not read DSCR register, opcode = 0x%08" PRIx32
, opcode
);
225 if (timeval_ms() > then
+ 1000) {
226 LOG_ERROR("Timeout waiting for aarch64_exec_opcode");
231 if (armv8_dpm_get_core_state(dpm
) != ARM_STATE_AARCH64
)
232 opcode
= T32_FMTITR(opcode
);
234 retval
= mem_ap_write_u32(armv8
->debug_ap
,
235 armv8
->debug_base
+ CPUV8_DBG_ITR
, opcode
);
236 if (retval
!= ERROR_OK
)
241 retval
= mem_ap_read_atomic_u32(armv8
->debug_ap
,
242 armv8
->debug_base
+ CPUV8_DBG_DSCR
, &dscr
);
243 if (retval
!= ERROR_OK
) {
244 LOG_ERROR("Could not read DSCR register");
247 if (timeval_ms() > then
+ 1000) {
248 LOG_ERROR("Timeout waiting for aarch64_exec_opcode");
251 } while ((dscr
& DSCR_ITE
) == 0); /* Wait for InstrCompl bit to be set */
253 /* update dscr and el after each command execution */
255 if (dpm
->last_el
!= ((dscr
>> 8) & 3))
256 LOG_DEBUG("EL %i -> %i", dpm
->last_el
, (dscr
>> 8) & 3);
257 dpm
->last_el
= (dscr
>> 8) & 3;
259 if (dscr
& DSCR_ERR
) {
260 LOG_ERROR("Opcode 0x%08"PRIx32
", DSCR.ERR=1, DSCR.EL=%i", opcode
, dpm
->last_el
);
261 armv8_dpm_handle_exception(dpm
, true);
271 static int dpmv8_instr_execute(struct arm_dpm
*dpm
, uint32_t opcode
)
273 return dpmv8_exec_opcode(dpm
, opcode
, NULL
);
276 static int dpmv8_instr_write_data_dcc(struct arm_dpm
*dpm
,
277 uint32_t opcode
, uint32_t data
)
279 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
282 retval
= dpmv8_write_dcc(armv8
, data
);
283 if (retval
!= ERROR_OK
)
286 return dpmv8_exec_opcode(dpm
, opcode
, 0);
289 static int dpmv8_instr_write_data_dcc_64(struct arm_dpm
*dpm
,
290 uint32_t opcode
, uint64_t data
)
292 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
295 retval
= dpmv8_write_dcc_64(armv8
, data
);
296 if (retval
!= ERROR_OK
)
299 return dpmv8_exec_opcode(dpm
, opcode
, 0);
302 static int dpmv8_instr_write_data_r0(struct arm_dpm
*dpm
,
303 uint32_t opcode
, uint32_t data
)
305 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
306 uint32_t dscr
= DSCR_ITE
;
309 retval
= dpmv8_write_dcc(armv8
, data
);
310 if (retval
!= ERROR_OK
)
313 retval
= dpmv8_exec_opcode(dpm
, armv8_opcode(armv8
, READ_REG_DTRRX
), &dscr
);
314 if (retval
!= ERROR_OK
)
317 /* then the opcode, taking data from R0 */
318 return dpmv8_exec_opcode(dpm
, opcode
, &dscr
);
321 static int dpmv8_instr_write_data_r0_64(struct arm_dpm
*dpm
,
322 uint32_t opcode
, uint64_t data
)
324 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
327 if (dpm
->arm
->core_state
!= ARM_STATE_AARCH64
)
328 return dpmv8_instr_write_data_r0(dpm
, opcode
, data
);
330 /* transfer data from DCC to R0 */
331 retval
= dpmv8_write_dcc_64(armv8
, data
);
332 if (retval
== ERROR_OK
)
333 retval
= dpmv8_exec_opcode(dpm
, ARMV8_MRS(SYSTEM_DBG_DBGDTR_EL0
, 0), &dpm
->dscr
);
335 /* then the opcode, taking data from R0 */
336 if (retval
== ERROR_OK
)
337 retval
= dpmv8_exec_opcode(dpm
, opcode
, &dpm
->dscr
);
342 static int dpmv8_instr_cpsr_sync(struct arm_dpm
*dpm
)
345 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
347 /* "Prefetch flush" after modifying execution status in CPSR */
348 retval
= dpmv8_exec_opcode(dpm
, armv8_opcode(armv8
, ARMV8_OPC_DSB_SY
), &dpm
->dscr
);
349 if (retval
== ERROR_OK
)
350 dpmv8_exec_opcode(dpm
, armv8_opcode(armv8
, ARMV8_OPC_ISB_SY
), &dpm
->dscr
);
354 static int dpmv8_instr_read_data_dcc(struct arm_dpm
*dpm
,
355 uint32_t opcode
, uint32_t *data
)
357 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
360 /* the opcode, writing data to DCC */
361 retval
= dpmv8_exec_opcode(dpm
, opcode
, &dpm
->dscr
);
362 if (retval
!= ERROR_OK
)
365 return dpmv8_read_dcc(armv8
, data
, &dpm
->dscr
);
368 static int dpmv8_instr_read_data_dcc_64(struct arm_dpm
*dpm
,
369 uint32_t opcode
, uint64_t *data
)
371 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
374 /* the opcode, writing data to DCC */
375 retval
= dpmv8_exec_opcode(dpm
, opcode
, &dpm
->dscr
);
376 if (retval
!= ERROR_OK
)
379 return dpmv8_read_dcc_64(armv8
, data
, &dpm
->dscr
);
382 static int dpmv8_instr_read_data_r0(struct arm_dpm
*dpm
,
383 uint32_t opcode
, uint32_t *data
)
385 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
388 /* the opcode, writing data to R0 */
389 retval
= dpmv8_exec_opcode(dpm
, opcode
, &dpm
->dscr
);
390 if (retval
!= ERROR_OK
)
393 /* write R0 to DCC */
394 retval
= dpmv8_exec_opcode(dpm
, armv8_opcode(armv8
, WRITE_REG_DTRTX
), &dpm
->dscr
);
395 if (retval
!= ERROR_OK
)
398 return dpmv8_read_dcc(armv8
, data
, &dpm
->dscr
);
401 static int dpmv8_instr_read_data_r0_64(struct arm_dpm
*dpm
,
402 uint32_t opcode
, uint64_t *data
)
404 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
407 if (dpm
->arm
->core_state
!= ARM_STATE_AARCH64
) {
409 retval
= dpmv8_instr_read_data_r0(dpm
, opcode
, &tmp
);
410 if (retval
== ERROR_OK
)
415 /* the opcode, writing data to R0 */
416 retval
= dpmv8_exec_opcode(dpm
, opcode
, &dpm
->dscr
);
417 if (retval
!= ERROR_OK
)
420 /* write R0 to DCC */
421 retval
= dpmv8_exec_opcode(dpm
, ARMV8_MSR_GP(SYSTEM_DBG_DBGDTR_EL0
, 0), &dpm
->dscr
);
422 if (retval
!= ERROR_OK
)
425 return dpmv8_read_dcc_64(armv8
, data
, &dpm
->dscr
);
429 static int dpmv8_bpwp_enable(struct arm_dpm
*dpm
, unsigned index_t
,
430 target_addr_t addr
, uint32_t control
)
432 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
433 uint32_t vr
= armv8
->debug_base
;
434 uint32_t cr
= armv8
->debug_base
;
438 case 0 ... 15: /* breakpoints */
439 vr
+= CPUV8_DBG_BVR_BASE
;
440 cr
+= CPUV8_DBG_BCR_BASE
;
442 case 16 ... 31: /* watchpoints */
443 vr
+= CPUV8_DBG_WVR_BASE
;
444 cr
+= CPUV8_DBG_WCR_BASE
;
453 LOG_DEBUG("A8: bpwp enable, vr %08x cr %08x",
454 (unsigned) vr
, (unsigned) cr
);
456 retval
= mem_ap_write_atomic_u32(armv8
->debug_ap
, vr
, addr
);
457 if (retval
!= ERROR_OK
)
459 return mem_ap_write_atomic_u32(armv8
->debug_ap
, cr
, control
);
463 static int dpmv8_bpwp_disable(struct arm_dpm
*dpm
, unsigned index_t
)
465 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
470 cr
= armv8
->debug_base
+ CPUV8_DBG_BCR_BASE
;
473 cr
= armv8
->debug_base
+ CPUV8_DBG_WCR_BASE
;
481 LOG_DEBUG("A: bpwp disable, cr %08x", (unsigned) cr
);
483 /* clear control register */
484 return mem_ap_write_atomic_u32(armv8
->debug_ap
, cr
, 0);
488 * Coprocessor support
491 /* Read coprocessor */
492 static int dpmv8_mrc(struct target
*target
, int cpnum
,
493 uint32_t op1
, uint32_t op2
, uint32_t CRn
, uint32_t CRm
,
496 struct arm
*arm
= target_to_arm(target
);
497 struct arm_dpm
*dpm
= arm
->dpm
;
500 retval
= dpm
->prepare(dpm
);
501 if (retval
!= ERROR_OK
)
504 LOG_DEBUG("MRC p%d, %d, r0, c%d, c%d, %d", cpnum
,
505 (int) op1
, (int) CRn
,
506 (int) CRm
, (int) op2
);
508 /* read coprocessor register into R0; return via DCC */
509 retval
= dpm
->instr_read_data_r0(dpm
,
510 ARMV4_5_MRC(cpnum
, op1
, 0, CRn
, CRm
, op2
),
513 /* (void) */ dpm
->finish(dpm
);
517 static int dpmv8_mcr(struct target
*target
, int cpnum
,
518 uint32_t op1
, uint32_t op2
, uint32_t CRn
, uint32_t CRm
,
521 struct arm
*arm
= target_to_arm(target
);
522 struct arm_dpm
*dpm
= arm
->dpm
;
525 retval
= dpm
->prepare(dpm
);
526 if (retval
!= ERROR_OK
)
529 LOG_DEBUG("MCR p%d, %d, r0, c%d, c%d, %d", cpnum
,
530 (int) op1
, (int) CRn
,
531 (int) CRm
, (int) op2
);
533 /* read DCC into r0; then write coprocessor register from R0 */
534 retval
= dpm
->instr_write_data_r0(dpm
,
535 ARMV4_5_MCR(cpnum
, op1
, 0, CRn
, CRm
, op2
),
538 /* (void) */ dpm
->finish(dpm
);
542 /*----------------------------------------------------------------------*/
545 * Register access utilities
548 int armv8_dpm_modeswitch(struct arm_dpm
*dpm
, enum arm_mode mode
)
550 struct armv8_common
*armv8
= (struct armv8_common
*)dpm
->arm
->arch_info
;
551 int retval
= ERROR_OK
;
552 unsigned int target_el
;
553 enum arm_state core_state
;
556 /* restore previous mode */
557 if (mode
== ARM_MODE_ANY
) {
558 cpsr
= buf_get_u32(dpm
->arm
->cpsr
->value
, 0, 32);
560 LOG_DEBUG("restoring mode, cpsr = 0x%08"PRIx32
, cpsr
);
563 LOG_DEBUG("setting mode 0x%"PRIx32
, mode
);
567 switch (cpsr
& 0x1f) {
580 * TODO: handle ARM_MODE_HYP
590 target_el
= (cpsr
>> 2) & 3;
593 if (target_el
> SYSTEM_CUREL_EL3
) {
594 LOG_ERROR("%s: Invalid target exception level %i", __func__
, target_el
);
598 LOG_DEBUG("target_el = %i, last_el = %i", target_el
, dpm
->last_el
);
599 if (target_el
> dpm
->last_el
) {
600 retval
= dpm
->instr_execute(dpm
,
601 armv8_opcode(armv8
, ARMV8_OPC_DCPS
) | target_el
);
603 /* DCPS clobbers registers just like an exception taken */
604 armv8_dpm_handle_exception(dpm
, false);
606 core_state
= armv8_dpm_get_core_state(dpm
);
607 if (core_state
!= ARM_STATE_AARCH64
) {
608 /* cannot do DRPS/ERET when already in EL0 */
609 if (dpm
->last_el
!= 0) {
610 /* load SPSR with the desired mode and execute DRPS */
611 LOG_DEBUG("SPSR = 0x%08"PRIx32
, cpsr
);
612 retval
= dpm
->instr_write_data_r0(dpm
,
613 ARMV8_MSR_GP_xPSR_T1(1, 0, 15), cpsr
);
614 if (retval
== ERROR_OK
)
615 retval
= dpm
->instr_execute(dpm
, armv8_opcode(armv8
, ARMV8_OPC_DRPS
));
619 * need to execute multiple DRPS instructions until target_el
622 while (retval
== ERROR_OK
&& dpm
->last_el
!= target_el
) {
623 unsigned int cur_el
= dpm
->last_el
;
624 retval
= dpm
->instr_execute(dpm
, armv8_opcode(armv8
, ARMV8_OPC_DRPS
));
625 if (cur_el
== dpm
->last_el
) {
626 LOG_INFO("Cannot reach EL %i, SPSR corrupted?", target_el
);
632 /* On executing DRPS, DSPSR and DLR become UNKNOWN, mark them as dirty */
633 dpm
->arm
->cpsr
->dirty
= true;
634 dpm
->arm
->pc
->dirty
= true;
637 * re-evaluate the core state, we might be in Aarch32 state now
638 * we rely on dpm->dscr being up-to-date
640 core_state
= armv8_dpm_get_core_state(dpm
);
641 armv8_select_opcodes(armv8
, core_state
== ARM_STATE_AARCH64
);
642 armv8_select_reg_access(armv8
, core_state
== ARM_STATE_AARCH64
);
649 * Common register read, relies on armv8_select_reg_access() having been called.
651 static int dpmv8_read_reg(struct arm_dpm
*dpm
, struct reg
*r
, unsigned regnum
)
653 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
654 int retval
= ERROR_FAIL
;
658 retval
= armv8
->read_reg_u64(armv8
, regnum
, &value_64
);
660 if (retval
== ERROR_OK
) {
663 buf_set_u64(r
->value
, 0, r
->size
, value_64
);
665 LOG_DEBUG("READ: %s, %16.8llx", r
->name
, (unsigned long long) value_64
);
667 LOG_DEBUG("READ: %s, %8.8x", r
->name
, (unsigned int) value_64
);
669 } else if (r
->size
<= 128) {
670 uint64_t lvalue
= 0, hvalue
= 0;
671 retval
= armv8
->read_reg_u128(armv8
, regnum
, &lvalue
, &hvalue
);
673 if (retval
== ERROR_OK
) {
677 buf_set_u64(r
->value
, 0, 64, lvalue
);
678 buf_set_u64(r
->value
+ 8, 0, r
->size
- 64, hvalue
);
680 LOG_DEBUG("READ: %s, lvalue=%16.8llx", r
->name
, (unsigned long long) lvalue
);
681 LOG_DEBUG("READ: %s, hvalue=%16.8llx", r
->name
, (unsigned long long) hvalue
);
685 if (retval
!= ERROR_OK
)
686 LOG_ERROR("Failed to read %s register", r
->name
);
692 * Common register write, relies on armv8_select_reg_access() having been called.
694 static int dpmv8_write_reg(struct arm_dpm
*dpm
, struct reg
*r
, unsigned regnum
)
696 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
697 int retval
= ERROR_FAIL
;
702 value_64
= buf_get_u64(r
->value
, 0, r
->size
);
703 retval
= armv8
->write_reg_u64(armv8
, regnum
, value_64
);
705 if (retval
== ERROR_OK
) {
708 LOG_DEBUG("WRITE: %s, %16.8llx", r
->name
, (unsigned long long)value_64
);
710 LOG_DEBUG("WRITE: %s, %8.8x", r
->name
, (unsigned int)value_64
);
712 } else if (r
->size
<= 128) {
713 uint64_t lvalue
, hvalue
;
715 lvalue
= buf_get_u64(r
->value
, 0, 64);
716 hvalue
= buf_get_u64(r
->value
+ 8, 0, r
->size
- 64);
717 retval
= armv8
->write_reg_u128(armv8
, regnum
, lvalue
, hvalue
);
719 if (retval
== ERROR_OK
) {
722 LOG_DEBUG("WRITE: %s, lvalue=%16.8llx", r
->name
, (unsigned long long) lvalue
);
723 LOG_DEBUG("WRITE: %s, hvalue=%16.8llx", r
->name
, (unsigned long long) hvalue
);
727 if (retval
!= ERROR_OK
)
728 LOG_ERROR("Failed to write %s register", r
->name
);
734 * Read basic registers of the the current context: R0 to R15, and CPSR;
735 * sets the core mode (such as USR or IRQ) and state (such as ARM or Thumb).
736 * In normal operation this is called on entry to halting debug state,
737 * possibly after some other operations supporting restore of debug state
738 * or making sure the CPU is fully idle (drain write buffer, etc).
740 int armv8_dpm_read_current_registers(struct arm_dpm
*dpm
)
742 struct arm
*arm
= dpm
->arm
;
743 struct armv8_common
*armv8
= (struct armv8_common
*)arm
->arch_info
;
744 struct reg_cache
*cache
;
749 retval
= dpm
->prepare(dpm
);
750 if (retval
!= ERROR_OK
)
753 cache
= arm
->core_cache
;
755 /* read R0 first (it's used for scratch), then CPSR */
756 r
= cache
->reg_list
+ ARMV8_R0
;
758 retval
= dpmv8_read_reg(dpm
, r
, ARMV8_R0
);
759 if (retval
!= ERROR_OK
)
764 /* read R1, too, it will be clobbered during memory access */
765 r
= cache
->reg_list
+ ARMV8_R1
;
767 retval
= dpmv8_read_reg(dpm
, r
, ARMV8_R1
);
768 if (retval
!= ERROR_OK
)
772 /* read cpsr to r0 and get it back */
773 retval
= dpm
->instr_read_data_r0(dpm
,
774 armv8_opcode(armv8
, READ_REG_DSPSR
), &cpsr
);
775 if (retval
!= ERROR_OK
)
778 /* update core mode and state */
779 armv8_set_cpsr(arm
, cpsr
);
781 for (unsigned int i
= ARMV8_PC
; i
< cache
->num_regs
; i
++) {
782 struct arm_reg
*arm_reg
;
784 r
= armv8_reg_current(arm
, i
);
788 /* Skip reading FP-SIMD registers */
789 if (r
->number
>= ARMV8_V0
&& r
->number
<= ARMV8_FPCR
)
793 * Only read registers that are available from the
794 * current EL (or core mode).
796 arm_reg
= r
->arch_info
;
797 if (arm_reg
->mode
!= ARM_MODE_ANY
&&
798 dpm
->last_el
!= armv8_curel_from_core_mode(arm_reg
->mode
))
801 /* Special case: ARM_MODE_SYS has no SPSR at EL1 */
802 if (r
->number
== ARMV8_SPSR_EL1
&& arm
->core_mode
== ARM_MODE_SYS
)
805 retval
= dpmv8_read_reg(dpm
, r
, i
);
806 if (retval
!= ERROR_OK
)
816 /* Avoid needless I/O ... leave breakpoints and watchpoints alone
817 * unless they're removed, or need updating because of single-stepping
818 * or running debugger code.
820 static int dpmv8_maybe_update_bpwp(struct arm_dpm
*dpm
, bool bpwp
,
821 struct dpm_bpwp
*xp
, int *set_p
)
823 int retval
= ERROR_OK
;
830 /* removed or startup; we must disable it */
835 /* disabled, but we must set it */
836 xp
->dirty
= disable
= false;
841 /* set, but we must temporarily disable it */
842 xp
->dirty
= disable
= true;
847 retval
= dpm
->bpwp_disable(dpm
, xp
->number
);
849 retval
= dpm
->bpwp_enable(dpm
, xp
->number
,
850 xp
->address
, xp
->control
);
852 if (retval
!= ERROR_OK
)
853 LOG_ERROR("%s: can't %s HW %spoint %d",
854 disable
? "disable" : "enable",
855 target_name(dpm
->arm
->target
),
856 (xp
->number
< 16) ? "break" : "watch",
862 static int dpmv8_add_breakpoint(struct target
*target
, struct breakpoint
*bp
);
865 * Writes all modified core registers for all processor modes. In normal
866 * operation this is called on exit from halting debug state.
868 * @param dpm: represents the processor
869 * @param bpwp: true ensures breakpoints and watchpoints are set,
870 * false ensures they are cleared
872 int armv8_dpm_write_dirty_registers(struct arm_dpm
*dpm
, bool bpwp
)
874 struct arm
*arm
= dpm
->arm
;
875 struct reg_cache
*cache
= arm
->core_cache
;
878 retval
= dpm
->prepare(dpm
);
879 if (retval
!= ERROR_OK
)
882 /* If we're managing hardware breakpoints for this core, enable
883 * or disable them as requested.
885 * REVISIT We don't yet manage them for ANY cores. Eventually
886 * we should be able to assume we handle them; but until then,
887 * cope with the hand-crafted breakpoint code.
889 if (arm
->target
->type
->add_breakpoint
== dpmv8_add_breakpoint
) {
890 for (unsigned i
= 0; i
< dpm
->nbp
; i
++) {
891 struct dpm_bp
*dbp
= dpm
->dbp
+ i
;
892 struct breakpoint
*bp
= dbp
->bp
;
894 retval
= dpmv8_maybe_update_bpwp(dpm
, bpwp
, &dbp
->bpwp
,
895 bp
? &bp
->set
: NULL
);
896 if (retval
!= ERROR_OK
)
901 /* enable/disable watchpoints */
902 for (unsigned i
= 0; i
< dpm
->nwp
; i
++) {
903 struct dpm_wp
*dwp
= dpm
->dwp
+ i
;
904 struct watchpoint
*wp
= dwp
->wp
;
906 retval
= dpmv8_maybe_update_bpwp(dpm
, bpwp
, &dwp
->bpwp
,
907 wp
? &wp
->set
: NULL
);
908 if (retval
!= ERROR_OK
)
912 /* NOTE: writes to breakpoint and watchpoint registers might
913 * be queued, and need (efficient/batched) flushing later.
916 /* Restore original core mode and state */
917 retval
= armv8_dpm_modeswitch(dpm
, ARM_MODE_ANY
);
918 if (retval
!= ERROR_OK
)
921 /* check everything except our scratch register R0 */
922 for (unsigned i
= 1; i
< cache
->num_regs
; i
++) {
925 /* skip PC and CPSR */
926 if (i
== ARMV8_PC
|| i
== ARMV8_xPSR
)
929 if (!cache
->reg_list
[i
].valid
)
932 if (!cache
->reg_list
[i
].dirty
)
935 /* skip all registers not on the current EL */
936 r
= cache
->reg_list
[i
].arch_info
;
937 if (r
->mode
!= ARM_MODE_ANY
&&
938 dpm
->last_el
!= armv8_curel_from_core_mode(r
->mode
))
941 retval
= dpmv8_write_reg(dpm
, &cache
->reg_list
[i
], i
);
942 if (retval
!= ERROR_OK
)
946 /* flush CPSR and PC */
947 if (retval
== ERROR_OK
)
948 retval
= dpmv8_write_reg(dpm
, &cache
->reg_list
[ARMV8_xPSR
], ARMV8_xPSR
);
949 if (retval
== ERROR_OK
)
950 retval
= dpmv8_write_reg(dpm
, &cache
->reg_list
[ARMV8_PC
], ARMV8_PC
);
951 /* flush R0 -- it's *very* dirty by now */
952 if (retval
== ERROR_OK
)
953 retval
= dpmv8_write_reg(dpm
, &cache
->reg_list
[0], 0);
954 if (retval
== ERROR_OK
)
955 dpm
->instr_cpsr_sync(dpm
);
962 * Standard ARM register accessors ... there are three methods
963 * in "struct arm", to support individual read/write and bulk read
967 static int armv8_dpm_read_core_reg(struct target
*target
, struct reg
*r
,
968 int regnum
, enum arm_mode mode
)
970 struct arm
*arm
= target_to_arm(target
);
971 struct arm_dpm
*dpm
= target_to_arm(target
)->dpm
;
973 int max
= arm
->core_cache
->num_regs
;
975 if (regnum
< 0 || regnum
>= max
)
976 return ERROR_COMMAND_SYNTAX_ERROR
;
979 * REVISIT what happens if we try to read SPSR in a core mode
980 * which has no such register?
982 retval
= dpm
->prepare(dpm
);
983 if (retval
!= ERROR_OK
)
986 retval
= dpmv8_read_reg(dpm
, r
, regnum
);
987 if (retval
!= ERROR_OK
)
991 /* (void) */ dpm
->finish(dpm
);
995 static int armv8_dpm_write_core_reg(struct target
*target
, struct reg
*r
,
996 int regnum
, enum arm_mode mode
, uint8_t *value
)
998 struct arm
*arm
= target_to_arm(target
);
999 struct arm_dpm
*dpm
= target_to_arm(target
)->dpm
;
1001 int max
= arm
->core_cache
->num_regs
;
1003 if (regnum
< 0 || regnum
> max
)
1004 return ERROR_COMMAND_SYNTAX_ERROR
;
1006 /* REVISIT what happens if we try to write SPSR in a core mode
1007 * which has no such register?
1010 retval
= dpm
->prepare(dpm
);
1011 if (retval
!= ERROR_OK
)
1014 retval
= dpmv8_write_reg(dpm
, r
, regnum
);
1016 /* always clean up, regardless of error */
1022 static int armv8_dpm_full_context(struct target
*target
)
1024 struct arm
*arm
= target_to_arm(target
);
1025 struct arm_dpm
*dpm
= arm
->dpm
;
1026 struct reg_cache
*cache
= arm
->core_cache
;
1030 retval
= dpm
->prepare(dpm
);
1031 if (retval
!= ERROR_OK
)
1035 enum arm_mode mode
= ARM_MODE_ANY
;
1039 /* We "know" arm_dpm_read_current_registers() was called so
1040 * the unmapped registers (R0..R7, PC, AND CPSR) and some
1041 * view of R8..R14 are current. We also "know" oddities of
1042 * register mapping: special cases for R8..R12 and SPSR.
1044 * Pick some mode with unread registers and read them all.
1045 * Repeat until done.
1047 for (unsigned i
= 0; i
< cache
->num_regs
; i
++) {
1050 if (cache
->reg_list
[i
].valid
)
1052 r
= cache
->reg_list
[i
].arch_info
;
1054 /* may need to pick a mode and set CPSR */
1059 /* For regular (ARM_MODE_ANY) R8..R12
1060 * in case we've entered debug state
1061 * in FIQ mode we need to patch mode.
1063 if (mode
!= ARM_MODE_ANY
)
1064 retval
= armv8_dpm_modeswitch(dpm
, mode
);
1066 retval
= armv8_dpm_modeswitch(dpm
, ARM_MODE_USR
);
1068 if (retval
!= ERROR_OK
)
1071 if (r
->mode
!= mode
)
1074 /* CPSR was read, so "R16" must mean SPSR */
1075 retval
= dpmv8_read_reg(dpm
,
1076 &cache
->reg_list
[i
],
1077 (r
->num
== 16) ? 17 : r
->num
);
1078 if (retval
!= ERROR_OK
)
1084 retval
= armv8_dpm_modeswitch(dpm
, ARM_MODE_ANY
);
1085 /* (void) */ dpm
->finish(dpm
);
1091 /*----------------------------------------------------------------------*/
1094 * Breakpoint and Watchpoint support.
1096 * Hardware {break,watch}points are usually left active, to minimize
1097 * debug entry/exit costs. When they are set or cleared, it's done in
1098 * batches. Also, DPM-conformant hardware can update debug registers
1099 * regardless of whether the CPU is running or halted ... though that
1100 * fact isn't currently leveraged.
1103 static int dpmv8_bpwp_setup(struct arm_dpm
*dpm
, struct dpm_bpwp
*xp
,
1104 uint32_t addr
, uint32_t length
)
1108 control
= (1 << 0) /* enable */
1109 | (3 << 1); /* both user and privileged access */
1111 /* Match 1, 2, or all 4 byte addresses in this word.
1113 * FIXME: v7 hardware allows lengths up to 2 GB for BP and WP.
1114 * Support larger length, when addr is suitably aligned. In
1115 * particular, allow watchpoints on 8 byte "double" values.
1117 * REVISIT allow watchpoints on unaligned 2-bit values; and on
1118 * v7 hardware, unaligned 4-byte ones too.
1122 control
|= (1 << (addr
& 3)) << 5;
1125 /* require 2-byte alignment */
1127 control
|= (3 << (addr
& 2)) << 5;
1132 /* require 4-byte alignment */
1134 control
|= 0xf << 5;
1139 LOG_ERROR("unsupported {break,watch}point length/alignment");
1140 return ERROR_COMMAND_SYNTAX_ERROR
;
1143 /* other shared control bits:
1144 * bits 15:14 == 0 ... both secure and nonsecure states (v6.1+ only)
1145 * bit 20 == 0 ... not linked to a context ID
1146 * bit 28:24 == 0 ... not ignoring N LSBs (v7 only)
1149 xp
->address
= addr
& ~3;
1150 xp
->control
= control
;
1153 LOG_DEBUG("BPWP: addr %8.8" PRIx32
", control %" PRIx32
", number %d",
1154 xp
->address
, control
, xp
->number
);
1156 /* hardware is updated in write_dirty_registers() */
1160 static int dpmv8_add_breakpoint(struct target
*target
, struct breakpoint
*bp
)
1162 struct arm
*arm
= target_to_arm(target
);
1163 struct arm_dpm
*dpm
= arm
->dpm
;
1164 int retval
= ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1167 return ERROR_COMMAND_SYNTAX_ERROR
;
1168 if (!dpm
->bpwp_enable
)
1171 /* FIXME we need a generic solution for software breakpoints. */
1172 if (bp
->type
== BKPT_SOFT
)
1173 LOG_DEBUG("using HW bkpt, not SW...");
1175 for (unsigned i
= 0; i
< dpm
->nbp
; i
++) {
1176 if (!dpm
->dbp
[i
].bp
) {
1177 retval
= dpmv8_bpwp_setup(dpm
, &dpm
->dbp
[i
].bpwp
,
1178 bp
->address
, bp
->length
);
1179 if (retval
== ERROR_OK
)
1180 dpm
->dbp
[i
].bp
= bp
;
1188 static int dpmv8_remove_breakpoint(struct target
*target
, struct breakpoint
*bp
)
1190 struct arm
*arm
= target_to_arm(target
);
1191 struct arm_dpm
*dpm
= arm
->dpm
;
1192 int retval
= ERROR_COMMAND_SYNTAX_ERROR
;
1194 for (unsigned i
= 0; i
< dpm
->nbp
; i
++) {
1195 if (dpm
->dbp
[i
].bp
== bp
) {
1196 dpm
->dbp
[i
].bp
= NULL
;
1197 dpm
->dbp
[i
].bpwp
.dirty
= true;
1199 /* hardware is updated in write_dirty_registers() */
1208 static int dpmv8_watchpoint_setup(struct arm_dpm
*dpm
, unsigned index_t
,
1209 struct watchpoint
*wp
)
1212 struct dpm_wp
*dwp
= dpm
->dwp
+ index_t
;
1215 /* this hardware doesn't support data value matching or masking */
1216 if (wp
->value
|| wp
->mask
!= ~(uint32_t)0) {
1217 LOG_DEBUG("watchpoint values and masking not supported");
1218 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1221 retval
= dpmv8_bpwp_setup(dpm
, &dwp
->bpwp
, wp
->address
, wp
->length
);
1222 if (retval
!= ERROR_OK
)
1225 control
= dwp
->bpwp
.control
;
1237 dwp
->bpwp
.control
= control
;
1239 dpm
->dwp
[index_t
].wp
= wp
;
1244 static int dpmv8_add_watchpoint(struct target
*target
, struct watchpoint
*wp
)
1246 struct arm
*arm
= target_to_arm(target
);
1247 struct arm_dpm
*dpm
= arm
->dpm
;
1248 int retval
= ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
1250 if (dpm
->bpwp_enable
) {
1251 for (unsigned i
= 0; i
< dpm
->nwp
; i
++) {
1252 if (!dpm
->dwp
[i
].wp
) {
1253 retval
= dpmv8_watchpoint_setup(dpm
, i
, wp
);
1262 static int dpmv8_remove_watchpoint(struct target
*target
, struct watchpoint
*wp
)
1264 struct arm
*arm
= target_to_arm(target
);
1265 struct arm_dpm
*dpm
= arm
->dpm
;
1266 int retval
= ERROR_COMMAND_SYNTAX_ERROR
;
1268 for (unsigned i
= 0; i
< dpm
->nwp
; i
++) {
1269 if (dpm
->dwp
[i
].wp
== wp
) {
1270 dpm
->dwp
[i
].wp
= NULL
;
1271 dpm
->dwp
[i
].bpwp
.dirty
= true;
1273 /* hardware is updated in write_dirty_registers() */
1282 void armv8_dpm_report_wfar(struct arm_dpm
*dpm
, uint64_t addr
)
1284 switch (dpm
->arm
->core_state
) {
1286 case ARM_STATE_AARCH64
:
1289 case ARM_STATE_THUMB
:
1290 case ARM_STATE_THUMB_EE
:
1293 case ARM_STATE_JAZELLE
:
1297 LOG_DEBUG("Unknown core_state");
1304 * Handle exceptions taken in debug state. This happens mostly for memory
1305 * accesses that violated a MMU policy. Taking an exception while in debug
1306 * state clobbers certain state registers on the target exception level.
1307 * Just mark those registers dirty so that they get restored on resume.
1308 * This works both for Aarch32 and Aarch64 states.
1310 * This function must not perform any actions that trigger another exception
1311 * or a recursion will happen.
1313 void armv8_dpm_handle_exception(struct arm_dpm
*dpm
, bool do_restore
)
1315 struct armv8_common
*armv8
= dpm
->arm
->arch_info
;
1316 struct reg_cache
*cache
= dpm
->arm
->core_cache
;
1317 enum arm_state core_state
;
1322 static const int clobbered_regs_by_el
[3][5] = {
1323 { ARMV8_PC
, ARMV8_xPSR
, ARMV8_ELR_EL1
, ARMV8_ESR_EL1
, ARMV8_SPSR_EL1
},
1324 { ARMV8_PC
, ARMV8_xPSR
, ARMV8_ELR_EL2
, ARMV8_ESR_EL2
, ARMV8_SPSR_EL2
},
1325 { ARMV8_PC
, ARMV8_xPSR
, ARMV8_ELR_EL3
, ARMV8_ESR_EL3
, ARMV8_SPSR_EL3
},
1328 el
= (dpm
->dscr
>> 8) & 3;
1330 /* safety check, must not happen since EL0 cannot be a target for an exception */
1331 if (el
< SYSTEM_CUREL_EL1
|| el
> SYSTEM_CUREL_EL3
) {
1332 LOG_ERROR("%s: EL %i is invalid, DSCR corrupted?", __func__
, el
);
1336 /* Clear sticky error */
1337 mem_ap_write_u32(armv8
->debug_ap
,
1338 armv8
->debug_base
+ CPUV8_DBG_DRCR
, DRCR_CSE
);
1340 armv8
->read_reg_u64(armv8
, ARMV8_xPSR
, &dlr
);
1342 armv8
->read_reg_u64(armv8
, ARMV8_PC
, &dlr
);
1344 LOG_DEBUG("Exception taken to EL %i, DLR=0x%016"PRIx64
" DSPSR=0x%08"PRIx32
,
1347 /* mark all clobbered registers as dirty */
1348 for (int i
= 0; i
< 5; i
++)
1349 cache
->reg_list
[clobbered_regs_by_el
[el
-1][i
]].dirty
= true;
1352 * re-evaluate the core state, we might be in Aarch64 state now
1353 * we rely on dpm->dscr being up-to-date
1355 core_state
= armv8_dpm_get_core_state(dpm
);
1356 armv8_select_opcodes(armv8
, core_state
== ARM_STATE_AARCH64
);
1357 armv8_select_reg_access(armv8
, core_state
== ARM_STATE_AARCH64
);
1360 armv8_dpm_modeswitch(dpm
, ARM_MODE_ANY
);
1363 /*----------------------------------------------------------------------*/
1366 * Other debug and support utilities
1369 void armv8_dpm_report_dscr(struct arm_dpm
*dpm
, uint32_t dscr
)
1371 struct target
*target
= dpm
->arm
->target
;
1374 dpm
->last_el
= (dscr
>> 8) & 3;
1376 /* Examine debug reason */
1377 switch (DSCR_ENTRY(dscr
)) {
1378 /* FALL THROUGH -- assume a v6 core in abort mode */
1379 case DSCRV8_ENTRY_EXT_DEBUG
: /* EDBGRQ */
1380 target
->debug_reason
= DBG_REASON_DBGRQ
;
1382 case DSCRV8_ENTRY_HALT_STEP_EXECLU
: /* HALT step */
1383 case DSCRV8_ENTRY_HALT_STEP_NORMAL
: /* Halt step*/
1384 case DSCRV8_ENTRY_HALT_STEP
:
1385 target
->debug_reason
= DBG_REASON_SINGLESTEP
;
1387 case DSCRV8_ENTRY_HLT
: /* HLT instruction (software breakpoint) */
1388 case DSCRV8_ENTRY_BKPT
: /* SW BKPT (?) */
1389 case DSCRV8_ENTRY_RESET_CATCH
: /* Reset catch */
1390 case DSCRV8_ENTRY_OS_UNLOCK
: /*OS unlock catch*/
1391 case DSCRV8_ENTRY_SW_ACCESS_DBG
: /*SW access dbg register*/
1392 target
->debug_reason
= DBG_REASON_BREAKPOINT
;
1394 case DSCRV8_ENTRY_WATCHPOINT
: /* asynch watchpoint */
1395 target
->debug_reason
= DBG_REASON_WATCHPOINT
;
1397 case DSCRV8_ENTRY_EXCEPTION_CATCH
: /*exception catch*/
1398 target
->debug_reason
= DBG_REASON_EXC_CATCH
;
1401 target
->debug_reason
= DBG_REASON_UNDEFINED
;
1407 /*----------------------------------------------------------------------*/
1410 * Setup and management support.
1414 * Hooks up this DPM to its associated target; call only once.
1415 * Initially this only covers the register cache.
1417 * Oh, and watchpoints. Yeah.
1419 int armv8_dpm_setup(struct arm_dpm
*dpm
)
1421 struct arm
*arm
= dpm
->arm
;
1422 struct target
*target
= arm
->target
;
1423 struct reg_cache
*cache
;
1426 /* register access setup */
1427 arm
->full_context
= armv8_dpm_full_context
;
1428 arm
->read_core_reg
= armv8_dpm_read_core_reg
;
1429 arm
->write_core_reg
= armv8_dpm_write_core_reg
;
1431 if (arm
->core_cache
== NULL
) {
1432 cache
= armv8_build_reg_cache(target
);
1437 /* coprocessor access setup */
1438 arm
->mrc
= dpmv8_mrc
;
1439 arm
->mcr
= dpmv8_mcr
;
1441 dpm
->prepare
= dpmv8_dpm_prepare
;
1442 dpm
->finish
= dpmv8_dpm_finish
;
1444 dpm
->instr_execute
= dpmv8_instr_execute
;
1445 dpm
->instr_write_data_dcc
= dpmv8_instr_write_data_dcc
;
1446 dpm
->instr_write_data_dcc_64
= dpmv8_instr_write_data_dcc_64
;
1447 dpm
->instr_write_data_r0
= dpmv8_instr_write_data_r0
;
1448 dpm
->instr_write_data_r0_64
= dpmv8_instr_write_data_r0_64
;
1449 dpm
->instr_cpsr_sync
= dpmv8_instr_cpsr_sync
;
1451 dpm
->instr_read_data_dcc
= dpmv8_instr_read_data_dcc
;
1452 dpm
->instr_read_data_dcc_64
= dpmv8_instr_read_data_dcc_64
;
1453 dpm
->instr_read_data_r0
= dpmv8_instr_read_data_r0
;
1454 dpm
->instr_read_data_r0_64
= dpmv8_instr_read_data_r0_64
;
1456 dpm
->arm_reg_current
= armv8_reg_current
;
1458 /* dpm->bpwp_enable = dpmv8_bpwp_enable; */
1459 dpm
->bpwp_disable
= dpmv8_bpwp_disable
;
1461 /* breakpoint setup -- optional until it works everywhere */
1462 if (!target
->type
->add_breakpoint
) {
1463 target
->type
->add_breakpoint
= dpmv8_add_breakpoint
;
1464 target
->type
->remove_breakpoint
= dpmv8_remove_breakpoint
;
1467 /* watchpoint setup */
1468 target
->type
->add_watchpoint
= dpmv8_add_watchpoint
;
1469 target
->type
->remove_watchpoint
= dpmv8_remove_watchpoint
;
1471 /* FIXME add vector catch support */
1473 dpm
->nbp
= 1 + ((dpm
->didr
>> 12) & 0xf);
1474 dpm
->dbp
= calloc(dpm
->nbp
, sizeof(*dpm
->dbp
));
1476 dpm
->nwp
= 1 + ((dpm
->didr
>> 20) & 0xf);
1477 dpm
->dwp
= calloc(dpm
->nwp
, sizeof(*dpm
->dwp
));
1479 if (!dpm
->dbp
|| !dpm
->dwp
) {
1485 LOG_INFO("%s: hardware has %d breakpoints, %d watchpoints",
1486 target_name(target
), dpm
->nbp
, dpm
->nwp
);
1488 /* REVISIT ... and some of those breakpoints could match
1489 * execution context IDs...
1496 * Reinitializes DPM state at the beginning of a new debug session
1497 * or after a reset which may have affected the debug module.
1499 int armv8_dpm_initialize(struct arm_dpm
*dpm
)
1501 /* Disable all breakpoints and watchpoints at startup. */
1502 if (dpm
->bpwp_disable
) {
1505 for (i
= 0; i
< dpm
->nbp
; i
++) {
1506 dpm
->dbp
[i
].bpwp
.number
= i
;
1507 (void) dpm
->bpwp_disable(dpm
, i
);
1509 for (i
= 0; i
< dpm
->nwp
; i
++) {
1510 dpm
->dwp
[i
].bpwp
.number
= 16 + i
;
1511 (void) dpm
->bpwp_disable(dpm
, 16 + i
);
1514 LOG_WARNING("%s: can't disable breakpoints and watchpoints",
1515 target_name(dpm
->arm
->target
));
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