| blob | 509e91e4c8c43a9646f3dd3e7eab81d5ca787f95 |
1 /***************************************************************************
2 * Copyright (C) 2005 by Dominic Rath *
3 * Dominic.Rath@gmx.de *
4 * *
5 * Copyright (C) 2007-2009 Øyvind Harboe *
6 * oyvind.harboe@zylin.com *
7 * *
8 * Copyright (C) 2008 by Spencer Oliver *
9 * spen@spen-soft.co.uk *
10 * *
11 * Copyright (C) 2008 by Hongtao Zheng *
12 * hontor@126.com *
13 * *
14 * Copyright (C) 2009 by David Brownell *
15 * *
16 * This program is free software; you can redistribute it and/or modify *
17 * it under the terms of the GNU General Public License as published by *
18 * the Free Software Foundation; either version 2 of the License, or *
19 * (at your option) any later version. *
20 * *
21 * This program is distributed in the hope that it will be useful, *
22 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
23 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
24 * GNU General Public License for more details. *
25 * *
26 * You should have received a copy of the GNU General Public License *
27 * along with this program; if not, write to the *
28 * Free Software Foundation, Inc., *
29 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
30 ***************************************************************************/
31 #ifdef HAVE_CONFIG_H
33 #endif
39 #include <helper/time_support.h>
47 /**
48 * @file
49 * Hold common code supporting the ARM7 and ARM9 core generations.
50 *
51 * While the ARM core implementations evolved substantially during these
52 * two generations, they look quite similar from the JTAG perspective.
53 * Both have similar debug facilities, based on the same two scan chains
54 * providing access to the core and to an EmbeddedICE module. Both can
55 * support similar ETM and ETB modules, for tracing. And both expose
56 * what could be viewed as "ARM Classic", with multiple processor modes,
57 * shadowed registers, and support for the Thumb instruction set.
58 *
59 * Processor differences include things like presence or absence of MMU
60 * and cache, pipeline sizes, use of a modified Harvard Architecure
61 * (with separate instruction and data busses from the CPU), support
62 * for cpu clock gating during idle, and more.
63 */
67 /**
68 * Clear watchpoints for an ARM7/9 target.
69 *
70 * @param arm7_9 Pointer to the common struct for an ARM7/9 target
71 * @return JTAG error status after executing queue
72 */
74 {
85 }
87 /**
88 * Assign a watchpoint to one of the two available hardware comparators in an
89 * ARM7 or ARM9 target.
90 *
91 * @param arm7_9 Pointer to the common struct for an ARM7/9 target
92 * @param breakpoint Pointer to the breakpoint to be used as a watchpoint
93 */
95 {
97 {
101 }
103 {
107 }
108 else
109 {
111 }
116 }
118 /**
119 * Setup an ARM7/9 target's embedded ICE registers for software breakpoints.
120 *
121 * @param arm7_9 Pointer to common struct for ARM7/9 targets
122 * @return Error codes if there is a problem finding a watchpoint or the result
123 * of executing the JTAG queue
124 */
126 {
128 {
130 }
132 {
135 }
138 /* pick a breakpoint unit */
140 {
144 {
147 }
148 else
149 {
152 }
155 {
159 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff);
161 }
163 {
167 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff);
169 }
170 else
171 {
174 }
179 }
181 /**
182 * Setup the common pieces for an ARM7/9 target after reset or on startup.
183 *
184 * @param target Pointer to an ARM7/9 target to setup
185 * @return Result of clearing the watchpoints on the target
186 */
188 {
192 }
194 /**
195 * Set either a hardware or software breakpoint on an ARM7/9 target. The
196 * breakpoint is set up even if it is already set. Some actions, e.g. reset,
197 * might have erased the values in Embedded ICE.
198 *
199 * @param target Pointer to the target device to set the breakpoints on
200 * @param breakpoint Pointer to the breakpoint to be set
201 * @return For hardware breakpoints, this is the result of executing the JTAG
202 * queue. For software breakpoints, this will be the status of the
203 * required memory reads and writes
204 */
206 {
216 {
219 }
222 {
223 /* either an ARM (4 byte) or Thumb (2 byte) breakpoint */
226 /* reassign a hw breakpoint */
228 {
230 }
233 {
237 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff);
239 }
241 {
245 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff);
247 }
248 else
249 {
252 }
255 }
257 {
258 /* did we already set this breakpoint? */
263 {
265 /* keep the original instruction in target endianness */
266 if ((retval = target_read_memory(target, breakpoint->address, 4, 1, breakpoint->orig_instr)) != ERROR_OK)
267 {
269 }
270 /* write the breakpoint instruction in target endianness (arm7_9->arm_bkpt is host endian) */
272 {
274 }
277 {
279 }
281 {
282 LOG_ERROR("Unable to set 32 bit software breakpoint at address %08" PRIx32 " - check that memory is read/writable", breakpoint->address);
284 }
285 }
286 else
287 {
289 /* keep the original instruction in target endianness */
290 if ((retval = target_read_memory(target, breakpoint->address, 2, 1, breakpoint->orig_instr)) != ERROR_OK)
291 {
293 }
294 /* write the breakpoint instruction in target endianness (arm7_9->thumb_bkpt is host endian) */
296 {
298 }
301 {
303 }
305 {
306 LOG_ERROR("Unable to set thumb software breakpoint at address %08" PRIx32 " - check that memory is read/writable", breakpoint->address);
308 }
309 }
317 }
320 }
322 /**
323 * Unsets an existing breakpoint on an ARM7/9 target. If it is a hardware
324 * breakpoint, the watchpoint used will be freed and the Embedded ICE registers
325 * will be updated. Otherwise, the software breakpoint will be restored to its
326 * original instruction if it hasn't already been modified.
327 *
328 * @param target Pointer to ARM7/9 target to unset the breakpoint from
329 * @param breakpoint Pointer to breakpoint to be unset
330 * @return For hardware breakpoints, this is the result of executing the JTAG
331 * queue. For software breakpoints, this will be the status of the
332 * required memory reads and writes
333 */
335 {
344 {
347 }
350 {
355 {
359 }
361 {
365 }
368 }
369 else
370 {
371 /* restore original instruction (kept in target endianness) */
373 {
375 /* check that user program as not modified breakpoint instruction */
376 if ((retval = target_read_memory(target, breakpoint->address, 4, 1, (uint8_t*)¤t_instr)) != ERROR_OK)
377 {
379 }
381 if ((retval = target_write_memory(target, breakpoint->address, 4, 1, breakpoint->orig_instr)) != ERROR_OK)
382 {
384 }
385 }
386 else
387 {
389 /* check that user program as not modified breakpoint instruction */
390 if ((retval = target_read_memory(target, breakpoint->address, 2, 1, (uint8_t*)¤t_instr)) != ERROR_OK)
391 {
393 }
395 if ((retval = target_write_memory(target, breakpoint->address, 2, 1, breakpoint->orig_instr)) != ERROR_OK)
396 {
398 }
399 }
402 {
403 /* We have removed the last sw breakpoint, clear the hw breakpoint we used to implement it */
405 {
407 }
409 {
411 }
412 }
415 }
418 }
420 /**
421 * Add a breakpoint to an ARM7/9 target. This makes sure that there are no
422 * dangling breakpoints and that the desired breakpoint can be added.
423 *
424 * @param target Pointer to the target ARM7/9 device to add a breakpoint to
425 * @param breakpoint Pointer to the breakpoint to be added
426 * @return An error status if there is a problem adding the breakpoint or the
427 * result of setting the breakpoint
428 */
430 {
434 {
435 /* make sure we don't have any dangling breakpoints. This is vital upon
436 * GDB connect/disconnect
437 */
439 }
442 {
445 }
448 {
451 }
454 {
456 }
461 }
463 /**
464 * Removes a breakpoint from an ARM7/9 target. This will make sure there are no
465 * dangling breakpoints and updates available watchpoints if it is a hardware
466 * breakpoint.
467 *
468 * @param target Pointer to the target to have a breakpoint removed
469 * @param breakpoint Pointer to the breakpoint to be removed
470 * @return Error status if there was a problem unsetting the breakpoint or the
471 * watchpoints could not be cleared
472 */
474 {
479 {
481 }
488 {
489 /* make sure we don't have any dangling breakpoints */
491 {
493 }
494 }
497 }
499 /**
500 * Sets a watchpoint for an ARM7/9 target in one of the watchpoint units. It is
501 * considered a bug to call this function when there are no available watchpoint
502 * units.
503 *
504 * @param target Pointer to an ARM7/9 target to set a watchpoint on
505 * @param watchpoint Pointer to the watchpoint to be set
506 * @return Error status if watchpoint set fails or the result of executing the
507 * JTAG queue
508 */
510 {
519 {
522 }
526 else
530 {
536 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], 0xff & ~EICE_W_CTRL_nOPC & ~rw_mask);
537 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE | EICE_W_CTRL_nOPC | (watchpoint->rw & 1));
540 {
542 }
545 }
547 {
553 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], 0xff & ~EICE_W_CTRL_nOPC & ~rw_mask);
554 embeddedice_set_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], EICE_W_CTRL_ENABLE | EICE_W_CTRL_nOPC | (watchpoint->rw & 1));
557 {
559 }
562 }
563 else
564 {
567 }
570 }
572 /**
573 * Unset an existing watchpoint and clear the used watchpoint unit.
574 *
575 * @param target Pointer to the target to have the watchpoint removed
576 * @param watchpoint Pointer to the watchpoint to be removed
577 * @return Error status while trying to unset the watchpoint or the result of
578 * executing the JTAG queue
579 */
581 {
586 {
589 }
592 {
595 }
598 {
601 {
603 }
605 }
607 {
610 {
612 }
614 }
618 }
620 /**
621 * Add a watchpoint to an ARM7/9 target. If there are no watchpoint units
622 * available, an error response is returned.
623 *
624 * @param target Pointer to the ARM7/9 target to add a watchpoint to
625 * @param watchpoint Pointer to the watchpoint to be added
626 * @return Error status while trying to add the watchpoint
627 */
629 {
633 {
635 }
638 {
640 }
645 }
647 /**
648 * Remove a watchpoint from an ARM7/9 target. The watchpoint will be unset and
649 * the used watchpoint unit will be reopened.
650 *
651 * @param target Pointer to the target to remove a watchpoint from
652 * @param watchpoint Pointer to the watchpoint to be removed
653 * @return Result of trying to unset the watchpoint
654 */
656 {
661 {
663 {
665 }
666 }
671 }
673 /**
674 * Restarts the target by sending a RESTART instruction and moving the JTAG
675 * state to IDLE. This includes a timeout waiting for DBGACK and SYSCOMP to be
676 * asserted by the processor.
677 *
678 * @param target Pointer to target to issue commands to
679 * @return Error status if there is a timeout or a problem while executing the
680 * JTAG queue
681 */
683 {
689 /* set RESTART instruction */
694 }
700 {
701 /* read debug status register */
709 {
712 {
714 }
715 }
717 {
718 LOG_ERROR("timeout waiting for SYSCOMP & DBGACK, last DBG_STATUS: %" PRIx32 "", buf_get_u32(dbg_stat->value, 0, dbg_stat->size));
720 }
723 }
725 /**
726 * Restarts the target by sending a RESTART instruction and moving the JTAG
727 * state to IDLE. This validates that DBGACK and SYSCOMP are set without
728 * waiting until they are.
729 *
730 * @param target Pointer to the target to issue commands to
731 * @return Always ERROR_OK
732 */
734 {
742 /* set RESTART instruction */
747 }
751 {
752 /* check for DBGACK and SYSCOMP set (others don't care) */
754 /* NB! These are constants that must be available until after next jtag_execute() and
755 * we evaluate the values upon first execution in lieu of setting up these constants
756 * during early setup.
757 * */
761 }
763 /* read debug status register */
767 }
769 /**
770 * Get some data from the ARM7/9 target.
771 *
772 * @param target Pointer to the ARM7/9 target to read data from
773 * @param size The number of 32bit words to be read
774 * @param buffer Pointer to the buffer that will hold the data
775 * @return The result of receiving data from the Embedded ICE unit
776 */
778 {
789 /* return the 32-bit ints in the 8-bit array */
791 {
793 }
798 }
800 /**
801 * Handles requests to an ARM7/9 target. If debug messaging is enabled, the
802 * target is running and the DCC control register has the W bit high, this will
803 * execute the request on the target.
804 *
805 * @param priv Void pointer expected to be a struct target pointer
806 * @return ERROR_OK unless there are issues with the JTAG queue or when reading
807 * from the Embedded ICE unit
808 */
810 {
823 {
824 /* read DCC control register */
827 {
829 }
831 /* check W bit */
833 {
837 {
839 }
841 {
843 }
844 }
845 }
848 }
850 /**
851 * Polls an ARM7/9 target for its current status. If DBGACK is set, the target
852 * is manipulated to the right halted state based on its current state. This is
853 * what happens:
854 *
855 * <table>
856 * <tr><th > State</th><th > Action</th></tr>
857 * <tr><td > TARGET_RUNNING | TARGET_RESET</td><td > Enters debug mode. If TARGET_RESET, pc may be checked</td></tr>
858 * <tr><td > TARGET_UNKNOWN</td><td > Warning is logged</td></tr>
859 * <tr><td > TARGET_DEBUG_RUNNING</td><td > Enters debug mode</td></tr>
860 * <tr><td > TARGET_HALTED</td><td > Nothing</td></tr>
861 * </table>
862 *
863 * If the target does not end up in the halted state, a warning is produced. If
864 * DBGACK is cleared, then the target is expected to either be running or
865 * running in debug.
866 *
867 * @param target Pointer to the ARM7/9 target to poll
868 * @return ERROR_OK or an error status if a command fails
869 */
871 {
876 /* read debug status register */
879 {
881 }
884 {
885 /* LOG_DEBUG("DBGACK set, dbg_state->value: 0x%x", buf_get_u32(dbg_stat->value, 0, 32));*/
887 {
888 /* Starting OpenOCD with target in debug-halt */
891 }
893 {
903 {
905 }
906 }
908 {
914 {
916 }
917 }
919 {
921 }
922 }
923 else
924 {
927 }
930 }
932 /**
933 * Asserts the reset (SRST) on an ARM7/9 target. Some -S targets (ARM966E-S in
934 * the STR912 isn't affected, ARM926EJ-S in the LPC3180 and AT91SAM9260 is
935 * affected) completely stop the JTAG clock while the core is held in reset
936 * (SRST). It isn't possible to program the halt condition once reset is
937 * asserted, hence a hook that allows the target to set up its reset-halt
938 * condition is setup prior to asserting reset.
939 *
940 * @param target Pointer to an ARM7/9 target to assert reset on
941 * @return ERROR_FAIL if the JTAG device does not have SRST, otherwise ERROR_OK
942 */
944 {
957 }
959 /* At this point trst has been asserted/deasserted once. We would
960 * like to program EmbeddedICE while SRST is asserted, instead of
961 * depending on SRST to leave that module alone. However, many CPUs
962 * gate the JTAG clock while SRST is asserted; or JTAG may need
963 * clock stability guarantees (adaptive clocking might help).
964 *
965 * So we assume JTAG access during SRST is off the menu unless it's
966 * been specifically enabled.
967 */
973 {
976 }
979 {
980 /*
981 * For targets that don't support communication while SRST is
982 * asserted, we need to set up the reset vector catch first.
983 *
984 * When we use TRST+SRST and that's equivalent to a power-up
985 * reset, these settings may well be reset anyway; so setting
986 * them here won't matter.
987 */
989 {
990 /* program vector catch register to catch reset */
994 /* extra runtest added as issues were found with
995 * certain ARM9 cores (maybe more) - AT91SAM9260
996 * and STR9
997 */
999 }
1000 else
1001 {
1002 /* program watchpoint unit to match on reset vector
1003 * address
1004 */
1014 EICE_W_CTRL_ENABLE);
1018 }
1019 }
1024 /* If we use SRST ... we'd like to issue just SRST, but the
1025 * board or chip may be set up so we have to assert TRST as
1026 * well. On some chips that combination is equivalent to a
1027 * power-up reset, and generally clobbers EICE state.
1028 */
1034 }
1039 /* REVISIT why isn't standard debug entry logic sufficient?? */
1043 {
1044 /* debug entry was prepared above */
1046 }
1049 }
1051 /**
1052 * Deassert the reset (SRST) signal on an ARM7/9 target. If SRST pulls TRST
1053 * and the target is being reset into a halt, a warning will be triggered
1054 * because it is not possible to reset into a halted mode in this case. The
1055 * target is halted using the target's functions.
1056 *
1057 * @param target Pointer to the target to have the reset deasserted
1058 * @return ERROR_OK or an error from polling or halting the target
1059 */
1061 {
1066 /* deassert reset lines */
1071 {
1073 /* set up embedded ice registers again */
1078 {
1080 }
1083 {
1085 }
1087 }
1089 }
1091 /**
1092 * Clears the halt condition for an ARM7/9 target. If it isn't coming out of
1093 * reset and if DBGRQ is used, it is progammed to be deasserted. If the reset
1094 * vector catch was used, it is restored. Otherwise, the control value is
1095 * restored and the watchpoint unit is restored if it was in use.
1096 *
1097 * @param target Pointer to the ARM7/9 target to have halt cleared
1098 * @return Always ERROR_OK
1099 */
1101 {
1105 /* we used DBGRQ only if we didn't come out of reset */
1107 {
1108 /* program EmbeddedICE Debug Control Register to deassert DBGRQ
1109 */
1112 }
1113 else
1114 {
1116 {
1117 /* if we came out of reset, and vector catch is supported, we used
1118 * vector catch to enter debug state
1119 * restore the register in that case
1120 */
1122 }
1123 else
1124 {
1125 /* restore registers if watchpoint unit 0 was in use
1126 */
1128 {
1130 {
1132 }
1136 }
1137 /* control value always has to be restored, as it was either disabled,
1138 * or enabled with possibly different bits
1139 */
1141 }
1142 }
1145 }
1147 /**
1148 * Issue a software reset and halt to an ARM7/9 target. The target is halted
1149 * and then there is a wait until the processor shows the halt. This wait can
1150 * timeout and results in an error being returned. The software reset involves
1151 * clearing the halt, updating the debug control register, changing to ARM mode,
1152 * reset of the program counter, and reset of all of the registers.
1153 *
1154 * @param target Pointer to the ARM7/9 target to be reset and halted by software
1155 * @return Error status if any of the commands fail, otherwise ERROR_OK
1156 */
1158 {
1166 /* FIX!!! replace some of this code with tcl commands
1167 *
1168 * halt # the halt command is synchronous
1169 * armv4_5 core_state arm
1170 *
1171 */
1179 {
1186 {
1189 {
1191 }
1192 }
1194 {
1197 }
1200 /* program EmbeddedICE Debug Control Register to assert DBGACK and INTDIS
1201 * ensure that DBGRQ is cleared
1202 */
1209 {
1211 }
1213 /* if the target is in Thumb state, change to ARM state */
1215 {
1218 /* Entered debug from Thumb mode */
1221 }
1223 /* REVISIT likewise for bit 5 -- switch Jazelle-to-ARM */
1225 /* all register content is now invalid */
1228 /* SVC, ARM state, IRQ and FIQ disabled */
1237 /* start fetching from 0x0 */
1242 /* reset registers */
1244 {
1250 }
1253 {
1255 }
1258 }
1260 /**
1261 * Halt an ARM7/9 target. This is accomplished by either asserting the DBGRQ
1262 * line or by programming a watchpoint to trigger on any address. It is
1263 * considered a bug to call this function while the target is in the
1264 * TARGET_RESET state.
1265 *
1266 * @param target Pointer to the ARM7/9 target to be halted
1267 * @return Always ERROR_OK
1268 */
1270 {
1272 {
1273 LOG_ERROR("BUG: arm7/9 does not support halt during reset. This is handled in arm7_9_assert_reset()");
1275 }
1284 {
1287 }
1290 {
1292 }
1295 {
1296 /* program EmbeddedICE Debug Control Register to assert DBGRQ
1297 */
1303 }
1304 }
1305 else
1306 {
1307 /* program watchpoint unit to match on any address
1308 */
1311 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE);
1312 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff);
1313 }
1318 }
1320 /**
1321 * Handle an ARM7/9 target's entry into debug mode. The halt is cleared on the
1322 * ARM. The JTAG queue is then executed and the reason for debug entry is
1323 * examined. Once done, the target is verified to be halted and the processor
1324 * is forced into ARM mode. The core registers are saved for the current core
1325 * mode and the program counter (register 15) is updated as needed. The core
1326 * registers and CPSR and SPSR are saved for restoration later.
1327 *
1328 * @param target Pointer to target that is entering debug mode
1329 * @return Error code if anything fails, otherwise ERROR_OK
1330 */
1332 {
1344 #ifdef _DEBUG_ARM7_9_
1346 #endif
1348 /* program EmbeddedICE Debug Control Register to assert DBGACK and INTDIS
1349 * ensure that DBGRQ is cleared
1350 */
1357 {
1359 }
1362 {
1364 }
1371 {
1374 }
1376 /* if the target is in Thumb state, change to ARM state */
1378 {
1380 /* Entered debug from Thumb mode */
1387 /* \todo Get some vaguely correct handling of Jazelle, if
1388 * anyone ever uses it and full info becomes available.
1389 * See ARM9EJS TRM B.7.1 for how to switch J->ARM; and
1390 * B.7.3 for the reverse. That'd be the bare minimum...
1391 */
1398 /* Entered debug from ARM mode */
1400 }
1404 /* save core registers (r0 - r15 of current core mode) */
1412 /* Sync our CPSR copy with J or T bits EICE reported, but
1413 * which we then erased by putting the core into ARM mode.
1414 */
1418 {
1422 }
1428 {
1433 {
1434 /* adjust value stored by STM */
1436 }
1440 else
1444 {
1450 /* r0 and r15 (pc) have to be restored later */
1453 }
1457 /* exceptions other than USR & SYS have a saved program status register */
1462 {
1464 }
1468 }
1477 }
1479 /**
1480 * Validate the full context for an ARM7/9 target in all processor modes. If
1481 * there are any invalid registers for the target, they will all be read. This
1482 * includes the PSR.
1483 *
1484 * @param target Pointer to the ARM7/9 target to capture the full context from
1485 * @return Error if the target is not halted, has an invalid core mode, or if
1486 * the JTAG queue fails to execute
1487 */
1489 {
1498 {
1501 }
1506 /* iterate through processor modes (User, FIQ, IRQ, SVC, ABT, UND)
1507 * SYS shares registers with User, so we don't touch SYS
1508 */
1510 {
1516 /* check if there are invalid registers in the current mode
1517 */
1519 {
1522 }
1525 {
1528 /* change processor mode (and mask T bit) */
1536 {
1538 {
1539 reg_p[j] = (uint32_t*)ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), j).value;
1543 }
1544 }
1546 /* if only the PSR is invalid, mask is all zeroes */
1550 /* check if the PSR has to be read */
1552 {
1553 arm7_9->read_xpsr(target, (uint32_t*)ARMV4_5_CORE_REG_MODE(armv4_5->core_cache, armv4_5_number_to_mode(i), 16).value, 1);
1556 }
1557 }
1558 }
1560 /* restore processor mode (mask T bit) */
1566 {
1568 }
1570 }
1572 /**
1573 * Restore the processor context on an ARM7/9 target. The full processor
1574 * context is analyzed to see if any of the registers are dirty on this end, but
1575 * have a valid new value. If this is the case, the processor is changed to the
1576 * appropriate mode and the new register values are written out to the
1577 * processor. If there happens to be a dirty register with an invalid value, an
1578 * error will be logged.
1579 *
1580 * @param target Pointer to the ARM7/9 target to have its context restored
1581 * @return Error status if the target is not halted or the core mode in the
1582 * armv4_5 struct is invalid.
1583 */
1585 {
1598 {
1601 }
1609 /* iterate through processor modes (User, FIQ, IRQ, SVC, ABT, UND)
1610 * SYS shares registers with User, so we don't touch SYS
1611 */
1613 {
1618 /* check if there are dirty registers in the current mode
1619 */
1621 {
1625 {
1627 {
1634 {
1637 }
1638 }
1639 else
1640 {
1642 }
1643 }
1644 }
1647 {
1653 {
1656 /* change processor mode (mask T bit) */
1663 }
1666 {
1672 {
1675 num_regs++;
1682 }
1683 }
1686 {
1688 }
1693 {
1694 LOG_DEBUG("writing SPSR of mode %i with value 0x%8.8" PRIx32 "", i, buf_get_u32(reg->value, 0, 32));
1696 }
1697 }
1698 }
1701 {
1702 /* restore processor mode (mask T bit) */
1710 }
1712 {
1713 /* CPSR has been changed, full restore necessary (mask T bit) */
1721 }
1723 /* restore PC */
1724 LOG_DEBUG("writing PC with value 0x%8.8" PRIx32 "", buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32));
1732 }
1734 /**
1735 * Restart the core of an ARM7/9 target. A RESTART command is sent to the
1736 * instruction register and the JTAG state is set to TAP_IDLE causing a core
1737 * restart.
1738 *
1739 * @param target Pointer to the ARM7/9 target to be restarted
1740 * @return Result of executing the JTAG queue
1741 */
1743 {
1747 /* set RESTART instruction */
1752 }
1757 }
1759 /**
1760 * Enable the watchpoints on an ARM7/9 target. The target's watchpoints are
1761 * iterated through and are set on the target if they aren't already set.
1762 *
1763 * @param target Pointer to the ARM7/9 target to enable watchpoints on
1764 */
1766 {
1770 {
1774 }
1775 }
1777 /**
1778 * Enable the breakpoints on an ARM7/9 target. The target's breakpoints are
1779 * iterated through and are set on the target.
1780 *
1781 * @param target Pointer to the ARM7/9 target to enable breakpoints on
1782 */
1784 {
1787 /* set any pending breakpoints */
1789 {
1792 }
1793 }
1795 int arm7_9_resume(struct target *target, int current, uint32_t address, int handle_breakpoints, int debug_execution)
1796 {
1806 {
1809 }
1812 {
1814 }
1816 /* current = 1: continue on current pc, otherwise continue at <address> */
1823 /* the front-end may request us not to handle breakpoints */
1825 {
1826 if ((breakpoint = breakpoint_find(target, buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32))))
1827 {
1828 LOG_DEBUG("unset breakpoint at 0x%8.8" PRIx32 " (id: %d)", breakpoint->address, breakpoint->unique_id );
1830 {
1832 }
1834 /* calculate PC of next instruction */
1837 {
1840 LOG_ERROR("Couldn't calculate PC of next instruction, current opcode was 0x%8.8" PRIx32 "", current_opcode);
1842 }
1850 {
1852 }
1857 {
1859 }
1860 else
1861 {
1864 }
1874 {
1876 {
1878 }
1881 }
1884 LOG_DEBUG("new PC after step: 0x%8.8" PRIx32 "", buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32));
1888 {
1890 }
1891 }
1892 }
1894 /* enable any pending breakpoints and watchpoints */
1899 {
1901 }
1904 {
1906 }
1908 {
1910 }
1911 else
1912 {
1915 }
1917 /* deassert DBGACK and INTDIS */
1919 /* INTDIS only when we really resume, not during debug execution */
1925 {
1927 }
1932 {
1933 /* registers are now invalid */
1937 {
1939 }
1940 }
1941 else
1942 {
1945 {
1947 }
1948 }
1953 }
1956 {
1963 {
1964 /* setup an inverse breakpoint on the current PC
1965 * - comparator 1 matches the current address
1966 * - rangeout from comparator 1 is connected to comparator 0 rangein
1967 * - comparator 0 matches any address, as long as rangein is low */
1970 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_VALUE], EICE_W_CTRL_ENABLE);
1971 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W0_CONTROL_MASK], ~(EICE_W_CTRL_RANGE | EICE_W_CTRL_nOPC) & 0xff);
1976 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff);
1977 }
1978 else
1979 {
1987 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_VALUE], EICE_W_CTRL_ENABLE);
1988 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_W1_CONTROL_MASK], ~EICE_W_CTRL_nOPC & 0xff);
1989 }
1990 }
1993 {
2005 }
2008 {
2015 {
2018 }
2020 /* current = 1: continue on current pc, otherwise continue at <address> */
2027 /* the front-end may request us not to handle breakpoints */
2029 if ((breakpoint = breakpoint_find(target, buf_get_u32(armv4_5->core_cache->reg_list[15].value, 0, 32))))
2031 {
2033 }
2037 /* calculate PC of next instruction */
2040 {
2043 LOG_ERROR("Couldn't calculate PC of next instruction, current opcode was 0x%8.8" PRIx32 "", current_opcode);
2045 }
2048 {
2050 }
2055 {
2057 }
2059 {
2061 }
2062 else
2063 {
2066 }
2069 {
2071 }
2076 /* registers are now invalid */
2080 {
2085 {
2087 }
2089 }
2093 {
2095 }
2098 }
2102 {
2118 {
2121 /* change processor mode (mask T bit) */
2126 }
2129 {
2130 /* read a normal core register */
2134 }
2135 else
2136 {
2137 /* read a program status register
2138 * if the register mode is MODE_ANY, we read the cpsr, otherwise a spsr
2139 */
2141 }
2144 {
2146 }
2155 /* restore processor mode (mask T bit) */
2159 }
2162 }
2166 {
2182 /* change processor mode (mask T bit) */
2187 }
2190 {
2191 /* write a normal core register */
2195 }
2196 else
2197 {
2198 /* write a program status register
2199 * if the register mode is MODE_ANY, we write the cpsr, otherwise a spsr
2200 */
2203 /* if we're writing the CPSR, mask the T bit */
2208 }
2216 /* restore processor mode (mask T bit) */
2220 }
2223 }
2225 int arm7_9_read_memory(struct target *target, uint32_t address, uint32_t size, uint32_t count, uint8_t *buffer)
2226 {
2237 LOG_DEBUG("address: 0x%8.8" PRIx32 ", size: 0x%8.8" PRIx32 ", count: 0x%8.8" PRIx32 "", address, size, count);
2240 {
2243 }
2245 /* sanitize arguments */
2252 /* load the base register with the address of the first word */
2259 {
2262 {
2272 /* fast memory reads are only safe when the target is running
2273 * from a sufficiently high clock (32 kHz is usually too slow)
2274 */
2277 else
2284 /* advance buffer, count number of accesses */
2289 {
2291 }
2292 }
2296 {
2302 {
2306 /* fast memory reads are only safe when the target is running
2307 * from a sufficiently high clock (32 kHz is usually too slow)
2308 */
2311 else
2314 {
2316 }
2318 }
2322 /* advance buffer, count number of accesses */
2327 {
2329 }
2330 }
2334 {
2340 {
2344 /* fast memory reads are only safe when the target is running
2345 * from a sufficiently high clock (32 kHz is usually too slow)
2346 */
2349 else
2352 {
2354 }
2355 }
2359 /* advance buffer, count number of accesses */
2364 {
2366 }
2367 }
2369 }
2378 }
2382 {
2385 }
2388 {
2389 LOG_WARNING("memory read caused data abort (address: 0x%8.8" PRIx32 ", size: 0x%" PRIx32 ", count: 0x%" PRIx32 ")", address, size, count);
2396 }
2399 }
2401 int arm7_9_write_memory(struct target *target, uint32_t address, uint32_t size, uint32_t count, uint8_t *buffer)
2402 {
2415 #ifdef _DEBUG_ARM7_9_
2417 #endif
2420 {
2423 }
2425 /* sanitize arguments */
2432 /* load the base register with the address of the first word */
2436 /* Clear DBGACK, to make sure memory fetches work as expected */
2441 {
2444 {
2450 {
2455 }
2461 /* fast memory writes are only safe when the target is running
2462 * from a sufficiently high clock (32 kHz is usually too slow)
2463 */
2466 else
2469 {
2471 }
2474 }
2478 {
2484 {
2489 }
2494 {
2497 /* fast memory writes are only safe when the target is running
2498 * from a sufficiently high clock (32 kHz is usually too slow)
2499 */
2502 else
2505 {
2507 }
2508 }
2511 }
2515 {
2521 {
2525 }
2530 {
2532 /* fast memory writes are only safe when the target is running
2533 * from a sufficiently high clock (32 kHz is usually too slow)
2534 */
2537 else
2540 {
2542 }
2544 }
2547 }
2549 }
2551 /* Re-Set DBGACK */
2562 }
2566 {
2569 }
2572 {
2573 LOG_WARNING("memory write caused data abort (address: 0x%8.8" PRIx32 ", size: 0x%" PRIx32 ", count: 0x%" PRIx32 ")", address, size, count);
2580 }
2583 }
2588 static int arm7_9_dcc_completion(struct target *target, uint32_t exit_point, int timeout_ms, void *arch_info)
2589 {
2600 {
2601 /* Handle first & last using standard embeddedice_write_reg and the middle ones w/the
2602 * core function repeated. */
2603 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_COMMS_DATA], fast_target_buffer_get_u32(buffer, little));
2614 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_COMMS_DATA], fast_target_buffer_get_u32(buffer, little));
2616 {
2619 {
2620 embeddedice_write_reg(&arm7_9->eice_cache->reg_list[EICE_COMMS_DATA], fast_target_buffer_get_u32(buffer, little));
2622 }
2623 }
2626 {
2628 }
2630 }
2633 {
2634 /* r0 == input, points to memory buffer
2635 * r1 == scratch
2636 */
2638 /* spin until DCC control (c0) reports data arrived */
2643 /* read word from DCC (c1), write to memory */
2647 /* repeat */
2649 };
2651 int arm7_9_bulk_write_memory(struct target *target, uint32_t address, uint32_t count, uint8_t *buffer)
2652 {
2660 /* regrab previously allocated working_area, or allocate a new one */
2662 {
2665 /* make sure we have a working area */
2667 {
2670 }
2672 /* copy target instructions to target endianness */
2674 {
2676 }
2678 /* write DCC code to working area */
2679 if ((retval = target_write_memory(target, arm7_9->dcc_working_area->address, 4, 6, dcc_code_buf)) != ERROR_OK)
2680 {
2682 }
2683 }
2704 {
2707 {
2708 LOG_ERROR("DCC write failed, expected end address 0x%08" PRIx32 " got 0x%0" PRIx32 "", (address + count*4), endaddress);
2710 }
2711 }
2716 }
2718 /**
2719 * Perform per-target setup that requires JTAG access.
2720 */
2722 {
2743 }
2751 }
2755 {
2759 {
2760 LOG_WARNING("NOTE! DCC downloads have not been enabled, defaulting to slow memory writes. Type 'help dcc'.");
2761 }
2764 {
2766 }
2769 {
2770 LOG_WARNING("NOTE! Severe performance degradation without fast memory access enabled. Type 'help fast'.");
2771 }
2774 }
2777 {
2782 {
2785 }
2790 command_print(CMD_CTX, "use of EmbeddedICE dbgrq instead of breakpoint for target halt %s", (arm7_9->use_dbgrq) ? "enabled" : "disabled");
2793 }
2796 {
2801 {
2804 }
2809 command_print(CMD_CTX, "fast memory access is %s", (arm7_9->fast_memory_access) ? "enabled" : "disabled");
2812 }
2815 {
2820 {
2823 }
2828 command_print(CMD_CTX, "dcc downloads are %s", (arm7_9->dcc_downloads) ? "enabled" : "disabled");
2831 }
2834 {
2839 {
2842 }
2845 {
2851 {
2854 }
2865 /* TODO: allow optional high vectors and/or BKPT_HARD */
2868 else
2870 }
2872 /* FIXME never let that "catch" be dropped! */
2875 }
2882 }
2885 {
2894 /* caller must have allocated via calloc(), so everything's zeroed */
2912 }
2915 {
2922 },
2923 {
2930 },
2931 {
2937 },
2938 {
2944 },
2945 COMMAND_REGISTRATION_DONE
2946 };
2948 {
2950 },
2951 {
2953 },
2954 {
2959 },
2960 COMMAND_REGISTRATION_DONE
2961 };