1 /***************************************************************************
2 * Copyright (C) 2015 by David Ung *
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. *
14 * You should have received a copy of the GNU General Public License *
15 * along with this program; if not, write to the *
16 * Free Software Foundation, Inc., *
17 ***************************************************************************/
23 #include <helper/replacements.h>
26 #include "arm_disassembler.h"
29 #include <helper/binarybuffer.h>
30 #include <helper/command.h>
36 #include "armv8_opcodes.h"
37 #include "arm_opcodes.h"
39 #include "target_type.h"
41 static const char * const armv8_state_strings[] = {
42 "ARM", "Thumb", "Jazelle", "ThumbEE", "ARM64",
48 /* For user and system modes, these list indices for all registers.
49 * otherwise they're just indices for the shadow registers and SPSR.
51 unsigned short n_indices;
52 const uint8_t *indices;
53 } armv8_mode_data[] = {
54 /* These special modes are currently only supported
55 * by ARMv6M and ARMv7M profiles */
86 /** Map PSR mode bits to the name of an ARM processor operating mode. */
87 const char *armv8_mode_name(unsigned psr_mode)
89 for (unsigned i = 0; i < ARRAY_SIZE(armv8_mode_data); i++) {
90 if (armv8_mode_data[i].psr == psr_mode)
91 return armv8_mode_data[i].name;
93 LOG_ERROR("unrecognized psr mode: %#02x", psr_mode);
94 return "UNRECOGNIZED";
97 int armv8_mode_to_number(enum arm_mode mode)
101 /* map MODE_ANY to user mode */
134 LOG_ERROR("invalid mode value encountered %d", mode);
140 static int armv8_read_core_reg(struct target *target, struct reg *r,
141 int num, enum arm_mode mode)
145 struct arm_reg *armv8_core_reg;
146 struct armv8_common *armv8 = target_to_armv8(target);
148 assert(num < (int)armv8->arm.core_cache->num_regs);
150 armv8_core_reg = armv8->arm.core_cache->reg_list[num].arch_info;
151 retval = armv8->load_core_reg_u64(target,
152 armv8_core_reg->num, ®_value);
154 buf_set_u64(armv8->arm.core_cache->reg_list[num].value, 0, 64, reg_value);
155 armv8->arm.core_cache->reg_list[num].valid = 1;
156 armv8->arm.core_cache->reg_list[num].dirty = 0;
162 static int armv8_write_core_reg(struct target *target, struct reg *r,
163 int num, enum arm_mode mode, target_addr_t value)
166 struct arm_reg *armv8_core_reg;
167 struct armv8_common *armv8 = target_to_armv8(target);
169 assert(num < (int)armv8->arm.core_cache->num_regs);
171 armv8_core_reg = armv8->arm.core_cache->reg_list[num].arch_info;
172 retval = armv8->store_core_reg_u64(target,
175 if (retval != ERROR_OK) {
176 LOG_ERROR("JTAG failure");
177 armv8->arm.core_cache->reg_list[num].dirty = armv8->arm.core_cache->reg_list[num].valid;
178 return ERROR_JTAG_DEVICE_ERROR;
181 LOG_DEBUG("write core reg %i value 0x%" PRIx64 "", num, value);
182 armv8->arm.core_cache->reg_list[num].valid = 1;
183 armv8->arm.core_cache->reg_list[num].dirty = 0;
189 * Configures host-side ARM records to reflect the specified CPSR.
190 * Later, code can use arm_reg_current() to map register numbers
191 * according to how they are exposed by this mode.
193 void armv8_set_cpsr(struct arm *arm, uint32_t cpsr)
195 uint32_t mode = cpsr & 0x1F;
197 /* NOTE: this may be called very early, before the register
198 * cache is set up. We can't defend against many errors, in
199 * particular against CPSRs that aren't valid *here* ...
202 buf_set_u32(arm->cpsr->value, 0, 32, cpsr);
203 arm->cpsr->valid = 1;
204 arm->cpsr->dirty = 0;
207 /* Older ARMs won't have the J bit */
208 enum arm_state state = 0xFF;
210 if (((cpsr & 0x10) >> 4) == 0) {
211 state = ARM_STATE_AARCH64;
213 if (cpsr & (1 << 5)) { /* T */
214 if (cpsr & (1 << 24)) { /* J */
215 LOG_WARNING("ThumbEE -- incomplete support");
216 state = ARM_STATE_THUMB_EE;
218 state = ARM_STATE_THUMB;
220 if (cpsr & (1 << 24)) { /* J */
221 LOG_ERROR("Jazelle state handling is BROKEN!");
222 state = ARM_STATE_JAZELLE;
224 state = ARM_STATE_ARM;
227 arm->core_state = state;
228 if (arm->core_state == ARM_STATE_AARCH64) {
230 case SYSTEM_AAR64_MODE_EL0t:
231 arm->core_mode = ARMV8_64_EL0T;
233 case SYSTEM_AAR64_MODE_EL1t:
234 arm->core_mode = ARMV8_64_EL0T;
236 case SYSTEM_AAR64_MODE_EL1h:
237 arm->core_mode = ARMV8_64_EL1H;
239 case SYSTEM_AAR64_MODE_EL2t:
240 arm->core_mode = ARMV8_64_EL2T;
242 case SYSTEM_AAR64_MODE_EL2h:
243 arm->core_mode = ARMV8_64_EL2H;
245 case SYSTEM_AAR64_MODE_EL3t:
246 arm->core_mode = ARMV8_64_EL3T;
248 case SYSTEM_AAR64_MODE_EL3h:
249 arm->core_mode = ARMV8_64_EL3H;
252 LOG_DEBUG("unknow mode 0x%x", (unsigned) (mode));
256 arm->core_mode = mode;
259 LOG_DEBUG("set CPSR %#8.8x: %s mode, %s state", (unsigned) cpsr,
260 armv8_mode_name(arm->core_mode),
261 armv8_state_strings[arm->core_state]);
264 static void armv8_show_fault_registers(struct target *target)
269 static uint8_t armv8_pa_size(uint32_t ps)
292 LOG_INFO("Unknow physicall address size");
298 static int armv8_read_ttbcr(struct target *target)
300 struct armv8_common *armv8 = target_to_armv8(target);
301 struct arm_dpm *dpm = armv8->arm.dpm;
302 struct arm *arm = &armv8->arm;
306 int retval = dpm->prepare(dpm);
307 if (retval != ERROR_OK)
310 /* claaer ttrr1_used and ttbr0_mask */
311 memset(&armv8->armv8_mmu.ttbr1_used, 0, sizeof(armv8->armv8_mmu.ttbr1_used));
312 memset(&armv8->armv8_mmu.ttbr0_mask, 0, sizeof(armv8->armv8_mmu.ttbr0_mask));
314 switch (arm->core_mode) {
317 retval = dpm->instr_read_data_r0(dpm,
318 ARMV8_MRS(SYSTEM_TCR_EL3, 0),
320 retval += dpm->instr_read_data_r0_64(dpm,
321 ARMV8_MRS(SYSTEM_TTBR0_EL3, 0),
323 if (retval != ERROR_OK)
325 armv8->va_size = 64 - (ttbcr & 0x3F);
326 armv8->pa_size = armv8_pa_size((ttbcr >> 16) & 7);
327 armv8->page_size = (ttbcr >> 14) & 3;
331 retval = dpm->instr_read_data_r0(dpm,
332 ARMV8_MRS(SYSTEM_TCR_EL2, 0),
334 retval += dpm->instr_read_data_r0_64(dpm,
335 ARMV8_MRS(SYSTEM_TTBR0_EL2, 0),
337 if (retval != ERROR_OK)
339 armv8->va_size = 64 - (ttbcr & 0x3F);
340 armv8->pa_size = armv8_pa_size((ttbcr >> 16) & 7);
341 armv8->page_size = (ttbcr >> 14) & 3;
346 retval = dpm->instr_read_data_r0_64(dpm,
347 ARMV8_MRS(SYSTEM_TCR_EL1, 0),
349 armv8->va_size = 64 - (ttbcr_64 & 0x3F);
350 armv8->pa_size = armv8_pa_size((ttbcr_64 >> 32) & 7);
351 armv8->page_size = (ttbcr_64 >> 14) & 3;
352 armv8->armv8_mmu.ttbr1_used = (((ttbcr_64 >> 16) & 0x3F) != 0) ? 1 : 0;
353 armv8->armv8_mmu.ttbr0_mask = 0x0000FFFFFFFFFFFF;
354 retval += dpm->instr_read_data_r0_64(dpm,
355 ARMV8_MRS(SYSTEM_TTBR0_EL1 | (armv8->armv8_mmu.ttbr1_used), 0),
357 if (retval != ERROR_OK)
361 LOG_ERROR("unknow core state");
365 if (retval != ERROR_OK)
369 LOG_INFO("ttb1 %s ,ttb0_mask %llx",
370 armv8->armv8_mmu.ttbr1_used ? "used" : "not used",
371 armv8->armv8_mmu.ttbr0_mask);
373 if (armv8->armv8_mmu.ttbr1_used == 1) {
374 LOG_INFO("TTBR0 access above %" PRIx64,
375 (uint64_t)(armv8->armv8_mmu.ttbr0_mask));
376 armv8->armv8_mmu.os_border = armv8->armv8_mmu.ttbr0_mask;
378 /* fix me , default is hard coded LINUX border */
379 armv8->armv8_mmu.os_border = 0xc0000000;
387 /* method adapted to cortex A : reused arm v4 v5 method*/
388 int armv8_mmu_translate_va(struct target *target, uint32_t va, uint32_t *val)
390 uint32_t first_lvl_descriptor = 0x0;
391 uint32_t second_lvl_descriptor = 0x0;
393 struct armv8_common *armv8 = target_to_armv8(target);
394 struct arm_dpm *dpm = armv8->arm.dpm;
395 uint32_t ttb = 0; /* default ttb0 */
396 if (armv8->armv8_mmu.ttbr1_used == -1)
397 armv8_read_ttbcr(target);
398 if ((armv8->armv8_mmu.ttbr1_used) &&
399 (va > (0xffffffff & armv8->armv8_mmu.ttbr0_mask))) {
403 retval = dpm->prepare(dpm);
404 if (retval != ERROR_OK)
407 /* MRC p15,0,<Rt>,c2,c0,ttb */
408 retval = dpm->instr_read_data_r0(dpm,
409 ARMV4_5_MRC(15, 0, 0, 2, 0, ttb),
411 if (retval != ERROR_OK)
413 retval = armv8->armv8_mmu.read_physical_memory(target,
414 (ttb & 0xffffc000) | ((va & 0xfff00000) >> 18),
415 4, 1, (uint8_t *)&first_lvl_descriptor);
416 if (retval != ERROR_OK)
418 first_lvl_descriptor = target_buffer_get_u32(target, (uint8_t *)
419 &first_lvl_descriptor);
420 /* reuse armv4_5 piece of code, specific armv8 changes may come later */
421 LOG_DEBUG("1st lvl desc: %8.8" PRIx32 "", first_lvl_descriptor);
423 if ((first_lvl_descriptor & 0x3) == 0) {
424 LOG_ERROR("Address translation failure");
425 return ERROR_TARGET_TRANSLATION_FAULT;
429 if ((first_lvl_descriptor & 0x3) == 2) {
430 /* section descriptor */
431 *val = (first_lvl_descriptor & 0xfff00000) | (va & 0x000fffff);
435 if ((first_lvl_descriptor & 0x3) == 1) {
436 /* coarse page table */
437 retval = armv8->armv8_mmu.read_physical_memory(target,
438 (first_lvl_descriptor & 0xfffffc00) | ((va & 0x000ff000) >> 10),
439 4, 1, (uint8_t *)&second_lvl_descriptor);
440 if (retval != ERROR_OK)
442 } else if ((first_lvl_descriptor & 0x3) == 3) {
443 /* fine page table */
444 retval = armv8->armv8_mmu.read_physical_memory(target,
445 (first_lvl_descriptor & 0xfffff000) | ((va & 0x000ffc00) >> 8),
446 4, 1, (uint8_t *)&second_lvl_descriptor);
447 if (retval != ERROR_OK)
451 second_lvl_descriptor = target_buffer_get_u32(target, (uint8_t *)
452 &second_lvl_descriptor);
454 LOG_DEBUG("2nd lvl desc: %8.8" PRIx32 "", second_lvl_descriptor);
456 if ((second_lvl_descriptor & 0x3) == 0) {
457 LOG_ERROR("Address translation failure");
458 return ERROR_TARGET_TRANSLATION_FAULT;
461 if ((second_lvl_descriptor & 0x3) == 1) {
462 /* large page descriptor */
463 *val = (second_lvl_descriptor & 0xffff0000) | (va & 0x0000ffff);
467 if ((second_lvl_descriptor & 0x3) == 2) {
468 /* small page descriptor */
469 *val = (second_lvl_descriptor & 0xfffff000) | (va & 0x00000fff);
473 if ((second_lvl_descriptor & 0x3) == 3) {
474 *val = (second_lvl_descriptor & 0xfffffc00) | (va & 0x000003ff);
478 /* should not happen */
479 LOG_ERROR("Address translation failure");
480 return ERROR_TARGET_TRANSLATION_FAULT;
486 /* V8 method VA TO PA */
487 int armv8_mmu_translate_va_pa(struct target *target, target_addr_t va,
488 target_addr_t *val, int meminfo)
493 static int armv8_handle_inner_cache_info_command(struct command_context *cmd_ctx,
494 struct armv8_cache_common *armv8_cache)
496 if (armv8_cache->ctype == -1) {
497 command_print(cmd_ctx, "cache not yet identified");
501 command_print(cmd_ctx,
502 "D-Cache: linelen %" PRIi32 ", associativity %" PRIi32 ", nsets %" PRIi32 ", cachesize %" PRId32 " KBytes",
503 armv8_cache->d_u_size.linelen,
504 armv8_cache->d_u_size.associativity,
505 armv8_cache->d_u_size.nsets,
506 armv8_cache->d_u_size.cachesize);
508 command_print(cmd_ctx,
509 "I-Cache: linelen %" PRIi32 ", associativity %" PRIi32 ", nsets %" PRIi32 ", cachesize %" PRId32 " KBytes",
510 armv8_cache->i_size.linelen,
511 armv8_cache->i_size.associativity,
512 armv8_cache->i_size.nsets,
513 armv8_cache->i_size.cachesize);
518 static int _armv8_flush_all_data(struct target *target)
520 struct armv8_common *armv8 = target_to_armv8(target);
521 struct arm_dpm *dpm = armv8->arm.dpm;
522 struct armv8_cachesize *d_u_size =
523 &(armv8->armv8_mmu.armv8_cache.d_u_size);
524 int32_t c_way, c_index = d_u_size->index;
526 /* check that cache data is on at target halt */
527 if (!armv8->armv8_mmu.armv8_cache.d_u_cache_enabled) {
528 LOG_INFO("flushed not performed :cache not on at target halt");
531 retval = dpm->prepare(dpm);
532 if (retval != ERROR_OK)
535 c_way = d_u_size->way;
537 uint32_t value = (c_index << d_u_size->index_shift)
538 | (c_way << d_u_size->way_shift);
540 /* LOG_INFO ("%d %d %x",c_way,c_index,value); */
541 retval = dpm->instr_write_data_r0(dpm,
542 ARMV4_5_MCR(15, 0, 0, 7, 14, 2),
544 if (retval != ERROR_OK)
547 } while (c_way >= 0);
549 } while (c_index >= 0);
552 LOG_ERROR("flushed failed");
557 static int armv8_flush_all_data(struct target *target)
559 int retval = ERROR_FAIL;
560 /* check that armv8_cache is correctly identify */
561 struct armv8_common *armv8 = target_to_armv8(target);
562 if (armv8->armv8_mmu.armv8_cache.ctype == -1) {
563 LOG_ERROR("trying to flush un-identified cache");
568 /* look if all the other target have been flushed in order to flush level
570 struct target_list *head;
573 while (head != (struct target_list *)NULL) {
575 if (curr->state == TARGET_HALTED) {
576 LOG_INFO("Wait flushing data l1 on core %" PRId32, curr->coreid);
577 retval = _armv8_flush_all_data(curr);
582 retval = _armv8_flush_all_data(target);
586 int armv8_handle_cache_info_command(struct command_context *cmd_ctx,
587 struct armv8_cache_common *armv8_cache)
589 if (armv8_cache->ctype == -1) {
590 command_print(cmd_ctx, "cache not yet identified");
594 if (armv8_cache->display_cache_info)
595 armv8_cache->display_cache_info(cmd_ctx, armv8_cache);
599 /* retrieve core id cluster id */
600 static int armv8_read_mpidr(struct target *target)
602 int retval = ERROR_FAIL;
603 struct armv8_common *armv8 = target_to_armv8(target);
604 struct arm_dpm *dpm = armv8->arm.dpm;
606 retval = dpm->prepare(dpm);
607 if (retval != ERROR_OK)
609 /* MRC p15,0,<Rd>,c0,c0,5; read Multiprocessor ID register*/
611 retval = dpm->instr_read_data_r0(dpm,
612 ARMV8_MRS(SYSTEM_MPIDR, 0),
614 if (retval != ERROR_OK)
617 armv8->multi_processor_system = (mpidr >> 30) & 1;
618 armv8->cluster_id = (mpidr >> 8) & 0xf;
619 armv8->cpu_id = mpidr & 0x3;
620 LOG_INFO("%s cluster %x core %x %s", target_name(target),
623 armv8->multi_processor_system == 0 ? "multi core" : "mono core");
626 LOG_ERROR("mpdir not in multiprocessor format");
635 int armv8_identify_cache(struct target *target)
637 /* read cache descriptor */
638 int retval = ERROR_FAIL;
639 struct armv8_common *armv8 = target_to_armv8(target);
640 struct arm_dpm *dpm = armv8->arm.dpm;
641 uint32_t cache_selected, clidr;
642 uint32_t cache_i_reg, cache_d_reg;
643 struct armv8_cache_common *cache = &(armv8->armv8_mmu.armv8_cache);
644 armv8_read_ttbcr(target);
645 retval = dpm->prepare(dpm);
647 if (retval != ERROR_OK)
650 * mrc p15, 1, r0, c0, c0, 1 @ read clidr */
651 retval = dpm->instr_read_data_r0(dpm,
652 ARMV8_MRS(SYSTEM_CLIDR, 0),
654 if (retval != ERROR_OK)
656 clidr = (clidr & 0x7000000) >> 23;
657 LOG_INFO("number of cache level %" PRIx32, (uint32_t)(clidr / 2));
658 if ((clidr / 2) > 1) {
659 /* FIXME not supported present in cortex A8 and later */
660 /* in cortex A7, A15 */
661 LOG_ERROR("cache l2 present :not supported");
663 /* retrieve selected cache*/
664 retval = dpm->instr_read_data_r0(dpm,
665 ARMV8_MRS(SYSTEM_CSSELR, 0),
667 if (retval != ERROR_OK)
671 /* select instruction cache
672 * [0] : 1 instruction cache selection , 0 data cache selection */
673 retval = dpm->instr_write_data_r0(dpm,
674 ARMV8_MRS(SYSTEM_CSSELR, 0),
676 if (retval != ERROR_OK)
680 * MRC P15,1,<RT>,C0, C0,0 ;on cortex A9 read CCSIDR
681 * [2:0] line size 001 eight word per line
682 * [27:13] NumSet 0x7f 16KB, 0xff 32Kbytes, 0x1ff 64Kbytes */
683 retval = dpm->instr_read_data_r0(dpm,
684 ARMV8_MRS(SYSTEM_CCSIDR, 0),
686 if (retval != ERROR_OK)
689 /* select data cache*/
690 retval = dpm->instr_write_data_r0(dpm,
691 ARMV8_MRS(SYSTEM_CSSELR, 0),
693 if (retval != ERROR_OK)
696 retval = dpm->instr_read_data_r0(dpm,
697 ARMV8_MRS(SYSTEM_CCSIDR, 0),
699 if (retval != ERROR_OK)
702 /* restore selected cache */
703 dpm->instr_write_data_r0(dpm,
704 ARMV8_MRS(SYSTEM_CSSELR, 0),
707 if (retval != ERROR_OK)
712 cache->d_u_size.linelen = 16 << (cache_d_reg & 0x7);
713 cache->d_u_size.cachesize = (((cache_d_reg >> 13) & 0x7fff)+1)/8;
714 cache->d_u_size.nsets = (cache_d_reg >> 13) & 0x7fff;
715 cache->d_u_size.associativity = ((cache_d_reg >> 3) & 0x3ff) + 1;
716 /* compute info for set way operation on cache */
717 cache->d_u_size.index_shift = (cache_d_reg & 0x7) + 4;
718 cache->d_u_size.index = (cache_d_reg >> 13) & 0x7fff;
719 cache->d_u_size.way = ((cache_d_reg >> 3) & 0x3ff);
720 cache->d_u_size.way_shift = cache->d_u_size.way + 1;
723 while (((cache->d_u_size.way_shift >> i) & 1) != 1)
725 cache->d_u_size.way_shift = 32-i;
728 LOG_INFO("data cache index %d << %d, way %d << %d",
729 cache->d_u_size.index, cache->d_u_size.index_shift,
731 cache->d_u_size.way_shift);
733 LOG_INFO("data cache %d bytes %d KBytes asso %d ways",
734 cache->d_u_size.linelen,
735 cache->d_u_size.cachesize,
736 cache->d_u_size.associativity);
738 cache->i_size.linelen = 16 << (cache_i_reg & 0x7);
739 cache->i_size.associativity = ((cache_i_reg >> 3) & 0x3ff) + 1;
740 cache->i_size.nsets = (cache_i_reg >> 13) & 0x7fff;
741 cache->i_size.cachesize = (((cache_i_reg >> 13) & 0x7fff)+1)/8;
742 /* compute info for set way operation on cache */
743 cache->i_size.index_shift = (cache_i_reg & 0x7) + 4;
744 cache->i_size.index = (cache_i_reg >> 13) & 0x7fff;
745 cache->i_size.way = ((cache_i_reg >> 3) & 0x3ff);
746 cache->i_size.way_shift = cache->i_size.way + 1;
749 while (((cache->i_size.way_shift >> i) & 1) != 1)
751 cache->i_size.way_shift = 32-i;
754 LOG_INFO("instruction cache index %d << %d, way %d << %d",
755 cache->i_size.index, cache->i_size.index_shift,
756 cache->i_size.way, cache->i_size.way_shift);
758 LOG_INFO("instruction cache %d bytes %d KBytes asso %d ways",
759 cache->i_size.linelen,
760 cache->i_size.cachesize,
761 cache->i_size.associativity);
763 /* if no l2 cache initialize l1 data cache flush function function */
764 if (armv8->armv8_mmu.armv8_cache.flush_all_data_cache == NULL) {
765 armv8->armv8_mmu.armv8_cache.display_cache_info =
766 armv8_handle_inner_cache_info_command;
767 armv8->armv8_mmu.armv8_cache.flush_all_data_cache =
768 armv8_flush_all_data;
770 armv8->armv8_mmu.armv8_cache.ctype = 0;
774 armv8_read_mpidr(target);
779 int armv8_init_arch_info(struct target *target, struct armv8_common *armv8)
781 struct arm *arm = &armv8->arm;
782 arm->arch_info = armv8;
783 target->arch_info = &armv8->arm;
784 /* target is useful in all function arm v4 5 compatible */
785 armv8->arm.target = target;
786 armv8->arm.common_magic = ARM_COMMON_MAGIC;
787 armv8->common_magic = ARMV8_COMMON_MAGIC;
789 arm->read_core_reg = armv8_read_core_reg;
791 arm->write_core_reg = armv8_write_core_reg;
794 armv8->armv8_mmu.armv8_cache.l2_cache = NULL;
795 armv8->armv8_mmu.armv8_cache.ctype = -1;
796 armv8->armv8_mmu.armv8_cache.flush_all_data_cache = NULL;
797 armv8->armv8_mmu.armv8_cache.display_cache_info = NULL;
801 int armv8_arch_state(struct target *target)
803 static const char * const state[] = {
804 "disabled", "enabled"
807 struct armv8_common *armv8 = target_to_armv8(target);
808 struct arm *arm = &armv8->arm;
810 if (armv8->common_magic != ARMV8_COMMON_MAGIC) {
811 LOG_ERROR("BUG: called for a non-Armv8 target");
812 return ERROR_COMMAND_SYNTAX_ERROR;
815 arm_arch_state(target);
817 if (armv8->is_armv7r) {
818 LOG_USER("D-Cache: %s, I-Cache: %s",
819 state[armv8->armv8_mmu.armv8_cache.d_u_cache_enabled],
820 state[armv8->armv8_mmu.armv8_cache.i_cache_enabled]);
822 LOG_USER("MMU: %s, D-Cache: %s, I-Cache: %s",
823 state[armv8->armv8_mmu.mmu_enabled],
824 state[armv8->armv8_mmu.armv8_cache.d_u_cache_enabled],
825 state[armv8->armv8_mmu.armv8_cache.i_cache_enabled]);
828 if (arm->core_mode == ARM_MODE_ABT)
829 armv8_show_fault_registers(target);
830 if (target->debug_reason == DBG_REASON_WATCHPOINT)
831 LOG_USER("Watchpoint triggered at PC %#08x",
832 (unsigned) armv8->dpm.wp_pc);
837 static const struct {
845 { ARMV8_R0, "x0", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
846 { ARMV8_R1, "x1", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
847 { ARMV8_R2, "x2", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
848 { ARMV8_R3, "x3", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
849 { ARMV8_R4, "x4", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
850 { ARMV8_R5, "x5", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
851 { ARMV8_R6, "x6", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
852 { ARMV8_R7, "x7", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
853 { ARMV8_R8, "x8", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
854 { ARMV8_R9, "x9", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
855 { ARMV8_R10, "x10", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
856 { ARMV8_R11, "x11", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
857 { ARMV8_R12, "x12", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
858 { ARMV8_R13, "x13", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
859 { ARMV8_R14, "x14", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
860 { ARMV8_R15, "x15", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
861 { ARMV8_R16, "x16", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
862 { ARMV8_R17, "x17", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
863 { ARMV8_R18, "x18", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
864 { ARMV8_R19, "x19", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
865 { ARMV8_R20, "x20", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
866 { ARMV8_R21, "x21", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
867 { ARMV8_R22, "x22", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
868 { ARMV8_R23, "x23", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
869 { ARMV8_R24, "x24", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
870 { ARMV8_R25, "x25", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
871 { ARMV8_R26, "x26", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
872 { ARMV8_R27, "x27", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
873 { ARMV8_R28, "x28", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
874 { ARMV8_R29, "x29", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
875 { ARMV8_R30, "x30", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
877 { ARMV8_R31, "sp", 64, REG_TYPE_DATA_PTR, "general", "org.gnu.gdb.aarch64.core" },
878 { ARMV8_PC, "pc", 64, REG_TYPE_CODE_PTR, "general", "org.gnu.gdb.aarch64.core" },
880 { ARMV8_xPSR, "CPSR", 64, REG_TYPE_INT, "general", "org.gnu.gdb.aarch64.core" },
883 #define ARMV8_NUM_REGS ARRAY_SIZE(armv8_regs)
886 static int armv8_get_core_reg(struct reg *reg)
889 struct arm_reg *armv8_reg = reg->arch_info;
890 struct target *target = armv8_reg->target;
891 struct arm *arm = target_to_arm(target);
893 if (target->state != TARGET_HALTED)
894 return ERROR_TARGET_NOT_HALTED;
896 retval = arm->read_core_reg(target, reg, armv8_reg->num, arm->core_mode);
901 static int armv8_set_core_reg(struct reg *reg, uint8_t *buf)
903 struct arm_reg *armv8_reg = reg->arch_info;
904 struct target *target = armv8_reg->target;
905 uint64_t value = buf_get_u64(buf, 0, 64);
907 if (target->state != TARGET_HALTED)
908 return ERROR_TARGET_NOT_HALTED;
910 buf_set_u64(reg->value, 0, 64, value);
917 static const struct reg_arch_type armv8_reg_type = {
918 .get = armv8_get_core_reg,
919 .set = armv8_set_core_reg,
922 /** Builds cache of architecturally defined registers. */
923 struct reg_cache *armv8_build_reg_cache(struct target *target)
925 struct armv8_common *armv8 = target_to_armv8(target);
926 struct arm *arm = &armv8->arm;
927 int num_regs = ARMV8_NUM_REGS;
928 struct reg_cache **cache_p = register_get_last_cache_p(&target->reg_cache);
929 struct reg_cache *cache = malloc(sizeof(struct reg_cache));
930 struct reg *reg_list = calloc(num_regs, sizeof(struct reg));
931 struct arm_reg *arch_info = calloc(num_regs, sizeof(struct arm_reg));
932 struct reg_feature *feature;
935 /* Build the process context cache */
936 cache->name = "arm v8 registers";
938 cache->reg_list = reg_list;
939 cache->num_regs = num_regs;
942 for (i = 0; i < num_regs; i++) {
943 arch_info[i].num = armv8_regs[i].id;
944 arch_info[i].target = target;
945 arch_info[i].arm = arm;
947 reg_list[i].name = armv8_regs[i].name;
948 reg_list[i].size = armv8_regs[i].bits;
949 reg_list[i].value = calloc(1, 4);
950 reg_list[i].dirty = 0;
951 reg_list[i].valid = 0;
952 reg_list[i].type = &armv8_reg_type;
953 reg_list[i].arch_info = &arch_info[i];
955 reg_list[i].group = armv8_regs[i].group;
956 reg_list[i].number = i;
957 reg_list[i].exist = true;
958 reg_list[i].caller_save = true; /* gdb defaults to true */
960 feature = calloc(1, sizeof(struct reg_feature));
962 feature->name = armv8_regs[i].feature;
963 reg_list[i].feature = feature;
965 LOG_ERROR("unable to allocate feature list");
967 reg_list[i].reg_data_type = calloc(1, sizeof(struct reg_data_type));
968 if (reg_list[i].reg_data_type)
969 reg_list[i].reg_data_type->type = armv8_regs[i].type;
971 LOG_ERROR("unable to allocate reg type list");
974 arm->cpsr = reg_list + ARMV8_xPSR;
975 arm->pc = reg_list + ARMV8_PC;
976 arm->core_cache = cache;
981 struct reg *armv8_reg_current(struct arm *arm, unsigned regnum)
988 r = arm->core_cache->reg_list + regnum;
992 const struct command_registration armv8_command_handlers[] = {
994 .chain = dap_command_handlers,
996 COMMAND_REGISTRATION_DONE
1000 int armv8_get_gdb_reg_list(struct target *target,
1001 struct reg **reg_list[], int *reg_list_size,
1002 enum target_register_class reg_class)
1004 struct arm *arm = target_to_arm(target);
1007 switch (reg_class) {
1008 case REG_CLASS_GENERAL:
1010 *reg_list_size = 34;
1011 *reg_list = malloc(sizeof(struct reg *) * (*reg_list_size));
1013 for (i = 0; i < *reg_list_size; i++)
1014 (*reg_list)[i] = armv8_reg_current(arm, i);
1020 LOG_ERROR("not a valid register class type in query.");