1 /***************************************************************************
2 * Copyright (C) 2005 by Dominic Rath *
3 * Dominic.Rath@gmx.de *
5 * This program is free software; you can redistribute it and/or modify *
6 * it under the terms of the GNU General Public License as published by *
7 * the Free Software Foundation; either version 2 of the License, or *
8 * (at your option) any later version. *
10 * This program is distributed in the hope that it will be useful, *
11 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
13 * GNU General Public License for more details. *
15 * You should have received a copy of the GNU General Public License *
16 * along with this program; if not, write to the *
17 * Free Software Foundation, Inc., *
18 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
19 ***************************************************************************/
25 #include <helper/time_support.h>
26 #include "target_type.h"
28 #include "arm_opcodes.h"
32 * For information about the ARM920T, see ARM DDI 0151C especially
33 * Chapter 9 about debug support, which shows how to manipulate each
34 * of the different scan chains:
36 * 0 ... ARM920 signals, e.g. to rest of SOC (unused here)
37 * 1 ... debugging; watchpoint and breakpoint status, etc; also
38 * MMU and cache access in conjunction with scan chain 15
40 * 3 ... external boundary scan (SoC-specific, unused here)
41 * 4 ... access to cache tag RAM
43 * 15 ... access coprocessor 15, "physical" or "interpreted" modes
44 * "interpreted" works with a few actual MRC/MCR instructions
45 * "physical" provides register-like behaviors. Section 9.6.7
46 * covers these details.
48 * The ARM922T is similar, but with smaller caches (8K each, vs 16K).
52 #define _DEBUG_INSTRUCTION_EXECUTION_
55 /* Table 9-8 shows scan chain 15 format during physical access mode, using a
56 * dedicated 6-bit address space (encoded in bits 33:38). Writes use one
57 * JTAG scan, while reads use two.
59 * Table 9-9 lists the thirteen registers which support physical access.
60 * ARM920T_CP15_PHYS_ADDR() constructs the 6-bit reg_addr parameter passed
61 * to arm920t_read_cp15_physical() and arm920t_write_cp15_physical().
67 #define ARM920T_CP15_PHYS_ADDR(x, y, z) ((x << 5) | (y << 1) << (z))
69 /* Registers supporting physical Read access (from table 9-9) */
70 #define CP15PHYS_CACHETYPE ARM920T_CP15_PHYS_ADDR(0, 0x0, 1)
71 #define CP15PHYS_ICACHE_IDX ARM920T_CP15_PHYS_ADDR(1, 0xd, 1)
72 #define CP15PHYS_DCACHE_IDX ARM920T_CP15_PHYS_ADDR(1, 0xe, 1)
73 /* NOTE: several more registers support only physical read access */
75 /* Registers supporting physical Read/Write access (from table 9-9) */
76 #define CP15PHYS_CTRL ARM920T_CP15_PHYS_ADDR(0, 0x1, 0)
77 #define CP15PHYS_PID ARM920T_CP15_PHYS_ADDR(0, 0xd, 0)
78 #define CP15PHYS_TESTSTATE ARM920T_CP15_PHYS_ADDR(0, 0xf, 0)
79 #define CP15PHYS_ICACHE ARM920T_CP15_PHYS_ADDR(1, 0x1, 1)
80 #define CP15PHYS_DCACHE ARM920T_CP15_PHYS_ADDR(1, 0x2, 1)
82 static int arm920t_read_cp15_physical(struct target
*target
,
83 int reg_addr
, uint32_t *value
)
85 struct arm920t_common
*arm920t
= target_to_arm920(target
);
86 struct arm_jtag
*jtag_info
;
87 struct scan_field fields
[4];
88 uint8_t access_type_buf
= 1;
89 uint8_t reg_addr_buf
= reg_addr
& 0x3f;
92 jtag_info
= &arm920t
->arm7_9_common
.jtag_info
;
94 arm_jtag_scann(jtag_info
, 0xf, TAP_IDLE
);
95 arm_jtag_set_instr(jtag_info
, jtag_info
->intest_instr
, NULL
, TAP_IDLE
);
97 fields
[0].num_bits
= 1;
98 fields
[0].out_value
= &access_type_buf
;
99 fields
[0].in_value
= NULL
;
101 fields
[1].num_bits
= 32;
102 fields
[1].out_value
= NULL
;
103 fields
[1].in_value
= NULL
;
105 fields
[2].num_bits
= 6;
106 fields
[2].out_value
= ®_addr_buf
;
107 fields
[2].in_value
= NULL
;
109 fields
[3].num_bits
= 1;
110 fields
[3].out_value
= &nr_w_buf
;
111 fields
[3].in_value
= NULL
;
113 jtag_add_dr_scan(jtag_info
->tap
, 4, fields
, TAP_IDLE
);
115 fields
[1].in_value
= (uint8_t *)value
;
117 jtag_add_dr_scan(jtag_info
->tap
, 4, fields
, TAP_IDLE
);
119 jtag_add_callback(arm_le_to_h_u32
, (jtag_callback_data_t
)value
);
121 #ifdef _DEBUG_INSTRUCTION_EXECUTION_
122 jtag_execute_queue();
123 LOG_DEBUG("addr: 0x%x value: %8.8x", reg_addr
, *value
);
129 static int arm920t_write_cp15_physical(struct target
*target
,
130 int reg_addr
, uint32_t value
)
132 struct arm920t_common
*arm920t
= target_to_arm920(target
);
133 struct arm_jtag
*jtag_info
;
134 struct scan_field fields
[4];
135 uint8_t access_type_buf
= 1;
136 uint8_t reg_addr_buf
= reg_addr
& 0x3f;
137 uint8_t nr_w_buf
= 1;
138 uint8_t value_buf
[4];
140 jtag_info
= &arm920t
->arm7_9_common
.jtag_info
;
142 buf_set_u32(value_buf
, 0, 32, value
);
144 arm_jtag_scann(jtag_info
, 0xf, TAP_IDLE
);
145 arm_jtag_set_instr(jtag_info
, jtag_info
->intest_instr
, NULL
, TAP_IDLE
);
147 fields
[0].num_bits
= 1;
148 fields
[0].out_value
= &access_type_buf
;
149 fields
[0].in_value
= NULL
;
151 fields
[1].num_bits
= 32;
152 fields
[1].out_value
= value_buf
;
153 fields
[1].in_value
= NULL
;
155 fields
[2].num_bits
= 6;
156 fields
[2].out_value
= ®_addr_buf
;
157 fields
[2].in_value
= NULL
;
159 fields
[3].num_bits
= 1;
160 fields
[3].out_value
= &nr_w_buf
;
161 fields
[3].in_value
= NULL
;
163 jtag_add_dr_scan(jtag_info
->tap
, 4, fields
, TAP_IDLE
);
165 #ifdef _DEBUG_INSTRUCTION_EXECUTION_
166 LOG_DEBUG("addr: 0x%x value: %8.8x", reg_addr
, value
);
172 /* See table 9-10 for scan chain 15 format during interpreted access mode.
173 * If the TESTSTATE register is set for interpreted access, certain CP15
174 * MRC and MCR instructions may be executed through scan chain 15.
176 * Tables 9-11, 9-12, and 9-13 show which MRC and MCR instructions can be
177 * executed using scan chain 15 interpreted mode.
179 static int arm920t_execute_cp15(struct target
*target
, uint32_t cp15_opcode
,
183 struct arm920t_common
*arm920t
= target_to_arm920(target
);
184 struct arm_jtag
*jtag_info
;
185 struct scan_field fields
[4];
186 uint8_t access_type_buf
= 0; /* interpreted access */
187 uint8_t reg_addr_buf
= 0x0;
188 uint8_t nr_w_buf
= 0;
189 uint8_t cp15_opcode_buf
[4];
191 jtag_info
= &arm920t
->arm7_9_common
.jtag_info
;
193 arm_jtag_scann(jtag_info
, 0xf, TAP_IDLE
);
194 arm_jtag_set_instr(jtag_info
, jtag_info
->intest_instr
, NULL
, TAP_IDLE
);
196 buf_set_u32(cp15_opcode_buf
, 0, 32, cp15_opcode
);
198 fields
[0].num_bits
= 1;
199 fields
[0].out_value
= &access_type_buf
;
200 fields
[0].in_value
= NULL
;
202 fields
[1].num_bits
= 32;
203 fields
[1].out_value
= cp15_opcode_buf
;
204 fields
[1].in_value
= NULL
;
206 fields
[2].num_bits
= 6;
207 fields
[2].out_value
= ®_addr_buf
;
208 fields
[2].in_value
= NULL
;
210 fields
[3].num_bits
= 1;
211 fields
[3].out_value
= &nr_w_buf
;
212 fields
[3].in_value
= NULL
;
214 jtag_add_dr_scan(jtag_info
->tap
, 4, fields
, TAP_IDLE
);
216 arm9tdmi_clock_out(jtag_info
, arm_opcode
, 0, NULL
, 0);
217 arm9tdmi_clock_out(jtag_info
, ARMV4_5_NOP
, 0, NULL
, 1);
218 retval
= arm7_9_execute_sys_speed(target
);
219 if (retval
!= ERROR_OK
)
222 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
224 LOG_ERROR("failed executing JTAG queue");
231 static int arm920t_read_cp15_interpreted(struct target
*target
,
232 uint32_t cp15_opcode
, uint32_t address
, uint32_t *value
)
234 struct arm
*armv4_5
= target_to_arm(target
);
237 uint32_t cp15c15
= 0x0;
238 struct reg
*r
= armv4_5
->core_cache
->reg_list
;
240 /* load address into R1 */
242 arm9tdmi_write_core_regs(target
, 0x2, regs
);
244 /* read-modify-write CP15 test state register
245 * to enable interpreted access mode */
246 arm920t_read_cp15_physical(target
, CP15PHYS_TESTSTATE
, &cp15c15
);
247 jtag_execute_queue();
248 cp15c15
|= 1; /* set interpret mode */
249 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
251 /* execute CP15 instruction and ARM load (reading from coprocessor) */
252 arm920t_execute_cp15(target
, cp15_opcode
, ARMV4_5_LDR(0, 1));
254 /* disable interpreted access mode */
255 cp15c15
&= ~1U; /* clear interpret mode */
256 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
258 /* retrieve value from R0 */
260 arm9tdmi_read_core_regs(target
, 0x1, regs_p
);
261 jtag_execute_queue();
263 #ifdef _DEBUG_INSTRUCTION_EXECUTION_
264 LOG_DEBUG("cp15_opcode: %8.8x, address: %8.8x, value: %8.8x",
265 cp15_opcode
, address
, *value
);
268 if (!is_arm_mode(armv4_5
->core_mode
))
278 int arm920t_write_cp15_interpreted(struct target
*target
,
279 uint32_t cp15_opcode
, uint32_t value
, uint32_t address
)
281 uint32_t cp15c15
= 0x0;
282 struct arm
*armv4_5
= target_to_arm(target
);
284 struct reg
*r
= armv4_5
->core_cache
->reg_list
;
286 /* load value, address into R0, R1 */
289 arm9tdmi_write_core_regs(target
, 0x3, regs
);
291 /* read-modify-write CP15 test state register
292 * to enable interpreted access mode */
293 arm920t_read_cp15_physical(target
, CP15PHYS_TESTSTATE
, &cp15c15
);
294 jtag_execute_queue();
295 cp15c15
|= 1; /* set interpret mode */
296 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
298 /* execute CP15 instruction and ARM store (writing to coprocessor) */
299 arm920t_execute_cp15(target
, cp15_opcode
, ARMV4_5_STR(0, 1));
301 /* disable interpreted access mode */
302 cp15c15
&= ~1U; /* set interpret mode */
303 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
305 #ifdef _DEBUG_INSTRUCTION_EXECUTION_
306 LOG_DEBUG("cp15_opcode: %8.8x, value: %8.8x, address: %8.8x",
307 cp15_opcode
, value
, address
);
310 if (!is_arm_mode(armv4_5
->core_mode
))
320 uint32_t arm920t_get_ttb(struct target
*target
)
325 if ((retval
= arm920t_read_cp15_interpreted(target
,
326 /* FIXME use opcode macro */
327 0xeebf0f51, 0x0, &ttb
)) != ERROR_OK
)
334 void arm920t_disable_mmu_caches(struct target
*target
, int mmu
,
335 int d_u_cache
, int i_cache
)
337 uint32_t cp15_control
;
339 /* read cp15 control register */
340 arm920t_read_cp15_physical(target
, CP15PHYS_CTRL
, &cp15_control
);
341 jtag_execute_queue();
344 cp15_control
&= ~0x1U
;
347 cp15_control
&= ~0x4U
;
350 cp15_control
&= ~0x1000U
;
352 arm920t_write_cp15_physical(target
, CP15PHYS_CTRL
, cp15_control
);
356 void arm920t_enable_mmu_caches(struct target
*target
, int mmu
,
357 int d_u_cache
, int i_cache
)
359 uint32_t cp15_control
;
361 /* read cp15 control register */
362 arm920t_read_cp15_physical(target
, CP15PHYS_CTRL
, &cp15_control
);
363 jtag_execute_queue();
366 cp15_control
|= 0x1U
;
369 cp15_control
|= 0x4U
;
372 cp15_control
|= 0x1000U
;
374 arm920t_write_cp15_physical(target
, CP15PHYS_CTRL
, cp15_control
);
378 void arm920t_post_debug_entry(struct target
*target
)
381 struct arm920t_common
*arm920t
= target_to_arm920(target
);
383 /* examine cp15 control reg */
384 arm920t_read_cp15_physical(target
,
385 CP15PHYS_CTRL
, &arm920t
->cp15_control_reg
);
386 jtag_execute_queue();
387 LOG_DEBUG("cp15_control_reg: %8.8" PRIx32
, arm920t
->cp15_control_reg
);
389 if (arm920t
->armv4_5_mmu
.armv4_5_cache
.ctype
== -1)
391 uint32_t cache_type_reg
;
392 /* identify caches */
393 arm920t_read_cp15_physical(target
,
394 CP15PHYS_CACHETYPE
, &cache_type_reg
);
395 jtag_execute_queue();
396 armv4_5_identify_cache(cache_type_reg
,
397 &arm920t
->armv4_5_mmu
.armv4_5_cache
);
400 arm920t
->armv4_5_mmu
.mmu_enabled
=
401 (arm920t
->cp15_control_reg
& 0x1U
) ? 1 : 0;
402 arm920t
->armv4_5_mmu
.armv4_5_cache
.d_u_cache_enabled
=
403 (arm920t
->cp15_control_reg
& 0x4U
) ? 1 : 0;
404 arm920t
->armv4_5_mmu
.armv4_5_cache
.i_cache_enabled
=
405 (arm920t
->cp15_control_reg
& 0x1000U
) ? 1 : 0;
407 /* save i/d fault status and address register */
408 /* FIXME use opcode macros */
409 arm920t_read_cp15_interpreted(target
, 0xee150f10, 0x0, &arm920t
->d_fsr
);
410 arm920t_read_cp15_interpreted(target
, 0xee150f30, 0x0, &arm920t
->i_fsr
);
411 arm920t_read_cp15_interpreted(target
, 0xee160f10, 0x0, &arm920t
->d_far
);
412 arm920t_read_cp15_interpreted(target
, 0xee160f30, 0x0, &arm920t
->i_far
);
414 LOG_DEBUG("D FSR: 0x%8.8" PRIx32
", D FAR: 0x%8.8" PRIx32
415 ", I FSR: 0x%8.8" PRIx32
", I FAR: 0x%8.8" PRIx32
,
416 arm920t
->d_fsr
, arm920t
->d_far
, arm920t
->i_fsr
, arm920t
->i_far
);
418 if (arm920t
->preserve_cache
)
420 /* read-modify-write CP15 test state register
421 * to disable I/D-cache linefills */
422 arm920t_read_cp15_physical(target
,
423 CP15PHYS_TESTSTATE
, &cp15c15
);
424 jtag_execute_queue();
426 arm920t_write_cp15_physical(target
,
427 CP15PHYS_TESTSTATE
, cp15c15
);
432 void arm920t_pre_restore_context(struct target
*target
)
435 struct arm920t_common
*arm920t
= target_to_arm920(target
);
437 /* restore i/d fault status and address register */
438 arm920t_write_cp15_interpreted(target
, 0xee050f10, arm920t
->d_fsr
, 0x0);
439 arm920t_write_cp15_interpreted(target
, 0xee050f30, arm920t
->i_fsr
, 0x0);
440 arm920t_write_cp15_interpreted(target
, 0xee060f10, arm920t
->d_far
, 0x0);
441 arm920t_write_cp15_interpreted(target
, 0xee060f30, arm920t
->i_far
, 0x0);
443 /* read-modify-write CP15 test state register
444 * to reenable I/D-cache linefills */
445 if (arm920t
->preserve_cache
)
447 arm920t_read_cp15_physical(target
,
448 CP15PHYS_TESTSTATE
, &cp15c15
);
449 jtag_execute_queue();
451 arm920t_write_cp15_physical(target
,
452 CP15PHYS_TESTSTATE
, cp15c15
);
456 static const char arm920_not
[] = "target is not an ARM920";
458 static int arm920t_verify_pointer(struct command_context
*cmd_ctx
,
459 struct arm920t_common
*arm920t
)
461 if (arm920t
->common_magic
!= ARM920T_COMMON_MAGIC
) {
462 command_print(cmd_ctx
, arm920_not
);
463 return ERROR_TARGET_INVALID
;
469 /** Logs summary of ARM920 state for a halted target. */
470 int arm920t_arch_state(struct target
*target
)
472 static const char *state
[] =
474 "disabled", "enabled"
477 struct arm920t_common
*arm920t
= target_to_arm920(target
);
480 if (arm920t
->common_magic
!= ARM920T_COMMON_MAGIC
)
482 LOG_ERROR("BUG: %s", arm920_not
);
483 return ERROR_TARGET_INVALID
;
486 armv4_5
= &arm920t
->arm7_9_common
.armv4_5_common
;
488 arm_arch_state(target
);
489 LOG_USER("MMU: %s, D-Cache: %s, I-Cache: %s",
490 state
[arm920t
->armv4_5_mmu
.mmu_enabled
],
491 state
[arm920t
->armv4_5_mmu
.armv4_5_cache
.d_u_cache_enabled
],
492 state
[arm920t
->armv4_5_mmu
.armv4_5_cache
.i_cache_enabled
]);
497 static int arm920_mmu(struct target
*target
, int *enabled
)
499 if (target
->state
!= TARGET_HALTED
) {
500 LOG_ERROR("%s: target not halted", __func__
);
501 return ERROR_TARGET_INVALID
;
504 *enabled
= target_to_arm920(target
)->armv4_5_mmu
.mmu_enabled
;
508 static int arm920_virt2phys(struct target
*target
,
509 uint32_t virt
, uint32_t *phys
)
512 struct arm920t_common
*arm920t
= target_to_arm920(target
);
515 int retval
= armv4_5_mmu_translate_va(target
,
516 &arm920t
->armv4_5_mmu
, virt
, &cb
, &ret
);
517 if (retval
!= ERROR_OK
)
523 /** Reads a buffer, in the specified word size, with current MMU settings. */
524 int arm920t_read_memory(struct target
*target
, uint32_t address
,
525 uint32_t size
, uint32_t count
, uint8_t *buffer
)
529 retval
= arm7_9_read_memory(target
, address
, size
, count
, buffer
);
535 static int arm920t_read_phys_memory(struct target
*target
,
536 uint32_t address
, uint32_t size
,
537 uint32_t count
, uint8_t *buffer
)
539 struct arm920t_common
*arm920t
= target_to_arm920(target
);
541 return armv4_5_mmu_read_physical(target
, &arm920t
->armv4_5_mmu
,
542 address
, size
, count
, buffer
);
545 static int arm920t_write_phys_memory(struct target
*target
,
546 uint32_t address
, uint32_t size
,
547 uint32_t count
, uint8_t *buffer
)
549 struct arm920t_common
*arm920t
= target_to_arm920(target
);
551 return armv4_5_mmu_write_physical(target
, &arm920t
->armv4_5_mmu
,
552 address
, size
, count
, buffer
);
556 /** Writes a buffer, in the specified word size, with current MMU settings. */
557 int arm920t_write_memory(struct target
*target
, uint32_t address
,
558 uint32_t size
, uint32_t count
, uint8_t *buffer
)
561 const uint32_t cache_mask
= ~0x1f; /* cache line size : 32 byte */
562 struct arm920t_common
*arm920t
= target_to_arm920(target
);
564 /* FIX!!!! this should be cleaned up and made much more general. The
565 * plan is to write up and test on arm920t specifically and
566 * then generalize and clean up afterwards.
568 * Also it should be moved to the callbacks that handle breakpoints
569 * specifically and not the generic memory write fn's. See XScale code.
571 if (arm920t
->armv4_5_mmu
.mmu_enabled
&& (count
== 1) &&
572 ((size
==2) || (size
==4)))
574 /* special case the handling of single word writes to
575 * bypass MMU, to allow implementation of breakpoints
576 * in memory marked read only
583 * We need physical address and cb
585 retval
= armv4_5_mmu_translate_va(target
, &arm920t
->armv4_5_mmu
,
587 if (retval
!= ERROR_OK
)
590 if (arm920t
->armv4_5_mmu
.armv4_5_cache
.d_u_cache_enabled
)
594 LOG_DEBUG("D-Cache buffered, "
595 "drain write buffer");
598 * Drain write buffer - MCR p15,0,Rd,c7,c10,4
601 retval
= arm920t_write_cp15_interpreted(target
,
602 ARMV4_5_MCR(15, 0, 0, 7, 10, 4),
604 if (retval
!= ERROR_OK
)
611 * Write back memory ? -> clean cache
613 * There is no way to clean cache lines using
614 * cp15 scan chain, so copy the full cache
615 * line from cache to physical memory.
619 LOG_DEBUG("D-Cache in 'write back' mode, "
622 retval
= target_read_memory(target
,
623 address
& cache_mask
, 1,
624 sizeof(data
), &data
[0]);
625 if (retval
!= ERROR_OK
)
628 retval
= armv4_5_mmu_write_physical(target
,
629 &arm920t
->armv4_5_mmu
,
631 sizeof(data
), &data
[0]);
632 if (retval
!= ERROR_OK
)
640 * Cached ? -> Invalidate data cache using MVA
642 * MCR p15,0,Rd,c7,c6,1
644 LOG_DEBUG("D-Cache enabled, "
645 "invalidate cache line");
647 retval
= arm920t_write_cp15_interpreted(target
,
648 ARMV4_5_MCR(15, 0, 0, 7, 6, 1), 0x0,
649 address
& cache_mask
);
650 if (retval
!= ERROR_OK
)
655 /* write directly to physical memory,
656 * bypassing any read only MMU bits, etc.
658 retval
= armv4_5_mmu_write_physical(target
,
659 &arm920t
->armv4_5_mmu
, pa
, size
,
661 if (retval
!= ERROR_OK
)
665 if ((retval
= arm7_9_write_memory(target
, address
,
666 size
, count
, buffer
)) != ERROR_OK
)
670 /* If ICache is enabled, we have to invalidate affected ICache lines
671 * the DCache is forced to write-through,
672 * so we don't have to clean it here
674 if (arm920t
->armv4_5_mmu
.armv4_5_cache
.i_cache_enabled
)
678 /* invalidate ICache single entry with MVA
679 * mcr 15, 0, r0, cr7, cr5, {1}
681 LOG_DEBUG("I-Cache enabled, "
682 "invalidating affected I-Cache line");
683 retval
= arm920t_write_cp15_interpreted(target
,
684 ARMV4_5_MCR(15, 0, 0, 7, 5, 1),
685 0x0, address
& cache_mask
);
686 if (retval
!= ERROR_OK
)
692 * mcr 15, 0, r0, cr7, cr5, {0}
694 retval
= arm920t_write_cp15_interpreted(target
,
695 ARMV4_5_MCR(15, 0, 0, 7, 5, 0),
697 if (retval
!= ERROR_OK
)
706 int arm920t_soft_reset_halt(struct target
*target
)
708 int retval
= ERROR_OK
;
709 struct arm920t_common
*arm920t
= target_to_arm920(target
);
710 struct arm7_9_common
*arm7_9
= target_to_arm7_9(target
);
711 struct arm
*armv4_5
= &arm7_9
->armv4_5_common
;
712 struct reg
*dbg_stat
= &arm7_9
->eice_cache
->reg_list
[EICE_DBG_STAT
];
714 if ((retval
= target_halt(target
)) != ERROR_OK
)
719 long long then
= timeval_ms();
721 while (!(timeout
= ((timeval_ms()-then
) > 1000)))
723 if (buf_get_u32(dbg_stat
->value
, EICE_DBG_STATUS_DBGACK
, 1)
726 embeddedice_read_reg(dbg_stat
);
727 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
735 if (debug_level
>= 3)
737 /* do not eat all CPU, time out after 1 se*/
746 LOG_ERROR("Failed to halt CPU after 1 sec");
747 return ERROR_TARGET_TIMEOUT
;
750 target
->state
= TARGET_HALTED
;
752 /* SVC, ARM state, IRQ and FIQ disabled */
755 cpsr
= buf_get_u32(armv4_5
->cpsr
->value
, 0, 32);
758 arm_set_cpsr(armv4_5
, cpsr
);
759 armv4_5
->cpsr
->dirty
= 1;
761 /* start fetching from 0x0 */
762 buf_set_u32(armv4_5
->pc
->value
, 0, 32, 0x0);
763 armv4_5
->pc
->dirty
= 1;
764 armv4_5
->pc
->valid
= 1;
766 arm920t_disable_mmu_caches(target
, 1, 1, 1);
767 arm920t
->armv4_5_mmu
.mmu_enabled
= 0;
768 arm920t
->armv4_5_mmu
.armv4_5_cache
.d_u_cache_enabled
= 0;
769 arm920t
->armv4_5_mmu
.armv4_5_cache
.i_cache_enabled
= 0;
771 return target_call_event_callbacks(target
, TARGET_EVENT_HALTED
);
774 /* FIXME remove forward decls */
775 static int arm920t_mrc(struct target
*target
, int cpnum
,
776 uint32_t op1
, uint32_t op2
,
777 uint32_t CRn
, uint32_t CRm
,
779 static int arm920t_mcr(struct target
*target
, int cpnum
,
780 uint32_t op1
, uint32_t op2
,
781 uint32_t CRn
, uint32_t CRm
,
784 static int arm920t_init_arch_info(struct target
*target
,
785 struct arm920t_common
*arm920t
, struct jtag_tap
*tap
)
787 struct arm7_9_common
*arm7_9
= &arm920t
->arm7_9_common
;
789 arm7_9
->armv4_5_common
.mrc
= arm920t_mrc
;
790 arm7_9
->armv4_5_common
.mcr
= arm920t_mcr
;
792 /* initialize arm7/arm9 specific info (including armv4_5) */
793 arm9tdmi_init_arch_info(target
, arm7_9
, tap
);
795 arm920t
->common_magic
= ARM920T_COMMON_MAGIC
;
797 arm7_9
->post_debug_entry
= arm920t_post_debug_entry
;
798 arm7_9
->pre_restore_context
= arm920t_pre_restore_context
;
800 arm920t
->armv4_5_mmu
.armv4_5_cache
.ctype
= -1;
801 arm920t
->armv4_5_mmu
.get_ttb
= arm920t_get_ttb
;
802 arm920t
->armv4_5_mmu
.read_memory
= arm7_9_read_memory
;
803 arm920t
->armv4_5_mmu
.write_memory
= arm7_9_write_memory
;
804 arm920t
->armv4_5_mmu
.disable_mmu_caches
= arm920t_disable_mmu_caches
;
805 arm920t
->armv4_5_mmu
.enable_mmu_caches
= arm920t_enable_mmu_caches
;
806 arm920t
->armv4_5_mmu
.has_tiny_pages
= 1;
807 arm920t
->armv4_5_mmu
.mmu_enabled
= 0;
809 /* disabling linefills leads to lockups, so keep them enabled for now
810 * this doesn't affect correctness, but might affect timing issues, if
811 * important data is evicted from the cache during the debug session
813 arm920t
->preserve_cache
= 0;
815 /* override hw single-step capability from ARM9TDMI */
816 arm7_9
->has_single_step
= 1;
821 static int arm920t_target_create(struct target
*target
, Jim_Interp
*interp
)
823 struct arm920t_common
*arm920t
;
825 arm920t
= calloc(1,sizeof(struct arm920t_common
));
826 return arm920t_init_arch_info(target
, arm920t
, target
->tap
);
829 COMMAND_HANDLER(arm920t_handle_read_cache_command
)
831 int retval
= ERROR_OK
;
832 struct target
*target
= get_current_target(CMD_CTX
);
833 struct arm920t_common
*arm920t
= target_to_arm920(target
);
834 struct arm7_9_common
*arm7_9
= target_to_arm7_9(target
);
835 struct arm
*armv4_5
= &arm7_9
->armv4_5_common
;
837 uint32_t cp15_ctrl
, cp15_ctrl_saved
;
839 uint32_t *regs_p
[16];
840 uint32_t C15_C_D_Ind
, C15_C_I_Ind
;
843 struct arm920t_cache_line d_cache
[8][64], i_cache
[8][64];
847 retval
= arm920t_verify_pointer(CMD_CTX
, arm920t
);
848 if (retval
!= ERROR_OK
)
853 command_print(CMD_CTX
, "usage: arm920t read_cache <filename>");
857 if ((output
= fopen(CMD_ARGV
[0], "w")) == NULL
)
859 LOG_DEBUG("error opening cache content file");
863 for (i
= 0; i
< 16; i
++)
864 regs_p
[i
] = ®s
[i
];
866 /* disable MMU and Caches */
867 arm920t_read_cp15_physical(target
, CP15PHYS_CTRL
, &cp15_ctrl
);
868 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
872 cp15_ctrl_saved
= cp15_ctrl
;
873 cp15_ctrl
&= ~(ARMV4_5_MMU_ENABLED
874 | ARMV4_5_D_U_CACHE_ENABLED
| ARMV4_5_I_CACHE_ENABLED
);
875 arm920t_write_cp15_physical(target
, CP15PHYS_CTRL
, cp15_ctrl
);
877 /* read CP15 test state register */
878 arm920t_read_cp15_physical(target
, CP15PHYS_TESTSTATE
, &cp15c15
);
879 jtag_execute_queue();
881 /* read DCache content */
882 fprintf(output
, "DCache:\n");
884 /* go through segments 0 to nsets (8 on ARM920T, 4 on ARM922T) */
886 segment
< arm920t
->armv4_5_mmu
.armv4_5_cache
.d_u_size
.nsets
;
889 fprintf(output
, "\nsegment: %i\n----------", segment
);
891 /* Ra: r0 = SBZ(31:8):segment(7:5):SBZ(4:0) */
892 regs
[0] = 0x0 | (segment
<< 5);
893 arm9tdmi_write_core_regs(target
, 0x1, regs
);
895 /* set interpret mode */
897 arm920t_write_cp15_physical(target
,
898 CP15PHYS_TESTSTATE
, cp15c15
);
900 /* D CAM Read, loads current victim into C15.C.D.Ind */
901 arm920t_execute_cp15(target
,
902 ARMV4_5_MCR(15,2,0,15,6,2), ARMV4_5_LDR(1, 0));
904 /* read current victim */
905 arm920t_read_cp15_physical(target
,
906 CP15PHYS_DCACHE_IDX
, &C15_C_D_Ind
);
908 /* clear interpret mode */
910 arm920t_write_cp15_physical(target
,
911 CP15PHYS_TESTSTATE
, cp15c15
);
913 for (index
= 0; index
< 64; index
++)
916 * r0 = index(31:26):SBZ(25:8):segment(7:5):SBZ(4:0)
918 regs
[0] = 0x0 | (segment
<< 5) | (index
<< 26);
919 arm9tdmi_write_core_regs(target
, 0x1, regs
);
921 /* set interpret mode */
923 arm920t_write_cp15_physical(target
,
924 CP15PHYS_TESTSTATE
, cp15c15
);
926 /* Write DCache victim */
927 arm920t_execute_cp15(target
,
928 ARMV4_5_MCR(15,0,0,9,1,0), ARMV4_5_LDR(1, 0));
931 arm920t_execute_cp15(target
,
932 ARMV4_5_MCR(15,2,0,15,10,2),
933 ARMV4_5_LDMIA(0, 0x1fe, 0, 0));
936 arm920t_execute_cp15(target
,
937 ARMV4_5_MCR(15,2,0,15,6,2),
940 /* clear interpret mode */
942 arm920t_write_cp15_physical(target
,
943 CP15PHYS_TESTSTATE
, cp15c15
);
945 /* read D RAM and CAM content */
946 arm9tdmi_read_core_regs(target
, 0x3fe, regs_p
);
947 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
952 d_cache
[segment
][index
].cam
= regs
[9];
955 regs
[9] &= 0xfffffffe;
956 fprintf(output
, "\nsegment: %i, index: %i, CAM: 0x%8.8"
957 PRIx32
", content (%s):\n",
958 segment
, index
, regs
[9],
959 (regs
[9] & 0x10) ? "valid" : "invalid");
961 for (i
= 1; i
< 9; i
++)
963 d_cache
[segment
][index
].data
[i
] = regs
[i
];
964 fprintf(output
, "%i: 0x%8.8" PRIx32
"\n",
970 /* Ra: r0 = index(31:26):SBZ(25:8):segment(7:5):SBZ(4:0) */
971 regs
[0] = 0x0 | (segment
<< 5) | (C15_C_D_Ind
<< 26);
972 arm9tdmi_write_core_regs(target
, 0x1, regs
);
974 /* set interpret mode */
976 arm920t_write_cp15_physical(target
,
977 CP15PHYS_TESTSTATE
, cp15c15
);
979 /* Write DCache victim */
980 arm920t_execute_cp15(target
,
981 ARMV4_5_MCR(15,0,0,9,1,0), ARMV4_5_LDR(1, 0));
983 /* clear interpret mode */
985 arm920t_write_cp15_physical(target
,
986 CP15PHYS_TESTSTATE
, cp15c15
);
989 /* read ICache content */
990 fprintf(output
, "ICache:\n");
992 /* go through segments 0 to nsets (8 on ARM920T, 4 on ARM922T) */
994 segment
< arm920t
->armv4_5_mmu
.armv4_5_cache
.d_u_size
.nsets
;
997 fprintf(output
, "segment: %i\n----------", segment
);
999 /* Ra: r0 = SBZ(31:8):segment(7:5):SBZ(4:0) */
1000 regs
[0] = 0x0 | (segment
<< 5);
1001 arm9tdmi_write_core_regs(target
, 0x1, regs
);
1003 /* set interpret mode */
1005 arm920t_write_cp15_physical(target
,
1006 CP15PHYS_TESTSTATE
, cp15c15
);
1008 /* I CAM Read, loads current victim into C15.C.I.Ind */
1009 arm920t_execute_cp15(target
,
1010 ARMV4_5_MCR(15,2,0,15,5,2), ARMV4_5_LDR(1, 0));
1012 /* read current victim */
1013 arm920t_read_cp15_physical(target
, CP15PHYS_ICACHE_IDX
,
1016 /* clear interpret mode */
1018 arm920t_write_cp15_physical(target
,
1019 CP15PHYS_TESTSTATE
, cp15c15
);
1021 for (index
= 0; index
< 64; index
++)
1024 * r0 = index(31:26):SBZ(25:8):segment(7:5):SBZ(4:0)
1026 regs
[0] = 0x0 | (segment
<< 5) | (index
<< 26);
1027 arm9tdmi_write_core_regs(target
, 0x1, regs
);
1029 /* set interpret mode */
1031 arm920t_write_cp15_physical(target
,
1032 CP15PHYS_TESTSTATE
, cp15c15
);
1034 /* Write ICache victim */
1035 arm920t_execute_cp15(target
,
1036 ARMV4_5_MCR(15,0,0,9,1,1), ARMV4_5_LDR(1, 0));
1039 arm920t_execute_cp15(target
,
1040 ARMV4_5_MCR(15,2,0,15,9,2),
1041 ARMV4_5_LDMIA(0, 0x1fe, 0, 0));
1044 arm920t_execute_cp15(target
,
1045 ARMV4_5_MCR(15,2,0,15,5,2),
1048 /* clear interpret mode */
1050 arm920t_write_cp15_physical(target
,
1051 CP15PHYS_TESTSTATE
, cp15c15
);
1053 /* read I RAM and CAM content */
1054 arm9tdmi_read_core_regs(target
, 0x3fe, regs_p
);
1055 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1060 i_cache
[segment
][index
].cam
= regs
[9];
1063 regs
[9] &= 0xfffffffe;
1064 fprintf(output
, "\nsegment: %i, index: %i, "
1065 "CAM: 0x%8.8" PRIx32
", content (%s):\n",
1066 segment
, index
, regs
[9],
1067 (regs
[9] & 0x10) ? "valid" : "invalid");
1069 for (i
= 1; i
< 9; i
++)
1071 i_cache
[segment
][index
].data
[i
] = regs
[i
];
1072 fprintf(output
, "%i: 0x%8.8" PRIx32
"\n",
1077 /* Ra: r0 = index(31:26):SBZ(25:8):segment(7:5):SBZ(4:0) */
1078 regs
[0] = 0x0 | (segment
<< 5) | (C15_C_D_Ind
<< 26);
1079 arm9tdmi_write_core_regs(target
, 0x1, regs
);
1081 /* set interpret mode */
1083 arm920t_write_cp15_physical(target
,
1084 CP15PHYS_TESTSTATE
, cp15c15
);
1086 /* Write ICache victim */
1087 arm920t_execute_cp15(target
,
1088 ARMV4_5_MCR(15,0,0,9,1,1), ARMV4_5_LDR(1, 0));
1090 /* clear interpret mode */
1092 arm920t_write_cp15_physical(target
,
1093 CP15PHYS_TESTSTATE
, cp15c15
);
1096 /* restore CP15 MMU and Cache settings */
1097 arm920t_write_cp15_physical(target
, CP15PHYS_CTRL
, cp15_ctrl_saved
);
1099 command_print(CMD_CTX
, "cache content successfully output to %s",
1104 if (!is_arm_mode(armv4_5
->core_mode
))
1107 /* force writeback of the valid data */
1108 r
= armv4_5
->core_cache
->reg_list
;
1109 r
[0].dirty
= r
[0].valid
;
1110 r
[1].dirty
= r
[1].valid
;
1111 r
[2].dirty
= r
[2].valid
;
1112 r
[3].dirty
= r
[3].valid
;
1113 r
[4].dirty
= r
[4].valid
;
1114 r
[5].dirty
= r
[5].valid
;
1115 r
[6].dirty
= r
[6].valid
;
1116 r
[7].dirty
= r
[7].valid
;
1118 r
= arm_reg_current(armv4_5
, 8);
1119 r
->dirty
= r
->valid
;
1121 r
= arm_reg_current(armv4_5
, 9);
1122 r
->dirty
= r
->valid
;
1127 COMMAND_HANDLER(arm920t_handle_read_mmu_command
)
1129 int retval
= ERROR_OK
;
1130 struct target
*target
= get_current_target(CMD_CTX
);
1131 struct arm920t_common
*arm920t
= target_to_arm920(target
);
1132 struct arm7_9_common
*arm7_9
= target_to_arm7_9(target
);
1133 struct arm
*armv4_5
= &arm7_9
->armv4_5_common
;
1135 uint32_t cp15_ctrl
, cp15_ctrl_saved
;
1137 uint32_t *regs_p
[16];
1140 uint32_t Dlockdown
, Ilockdown
;
1141 struct arm920t_tlb_entry d_tlb
[64], i_tlb
[64];
1145 retval
= arm920t_verify_pointer(CMD_CTX
, arm920t
);
1146 if (retval
!= ERROR_OK
)
1151 command_print(CMD_CTX
, "usage: arm920t read_mmu <filename>");
1155 if ((output
= fopen(CMD_ARGV
[0], "w")) == NULL
)
1157 LOG_DEBUG("error opening mmu content file");
1161 for (i
= 0; i
< 16; i
++)
1162 regs_p
[i
] = ®s
[i
];
1164 /* disable MMU and Caches */
1165 arm920t_read_cp15_physical(target
, CP15PHYS_CTRL
, &cp15_ctrl
);
1166 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1170 cp15_ctrl_saved
= cp15_ctrl
;
1171 cp15_ctrl
&= ~(ARMV4_5_MMU_ENABLED
1172 | ARMV4_5_D_U_CACHE_ENABLED
| ARMV4_5_I_CACHE_ENABLED
);
1173 arm920t_write_cp15_physical(target
, CP15PHYS_CTRL
, cp15_ctrl
);
1175 /* read CP15 test state register */
1176 arm920t_read_cp15_physical(target
, CP15PHYS_TESTSTATE
, &cp15c15
);
1177 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1182 /* prepare reading D TLB content
1185 /* set interpret mode */
1187 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
1189 /* Read D TLB lockdown */
1190 arm920t_execute_cp15(target
,
1191 ARMV4_5_MRC(15,0,0,10,0,0), ARMV4_5_LDR(1, 0));
1193 /* clear interpret mode */
1195 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
1197 /* read D TLB lockdown stored to r1 */
1198 arm9tdmi_read_core_regs(target
, 0x2, regs_p
);
1199 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1203 Dlockdown
= regs
[1];
1205 for (victim
= 0; victim
< 64; victim
+= 8)
1207 /* new lockdown value: base[31:26]:victim[25:20]:SBZ[19:1]:p[0]
1208 * base remains unchanged, victim goes through entries 0 to 63
1210 regs
[1] = (Dlockdown
& 0xfc000000) | (victim
<< 20);
1211 arm9tdmi_write_core_regs(target
, 0x2, regs
);
1213 /* set interpret mode */
1215 arm920t_write_cp15_physical(target
,
1216 CP15PHYS_TESTSTATE
, cp15c15
);
1218 /* Write D TLB lockdown */
1219 arm920t_execute_cp15(target
,
1220 ARMV4_5_MCR(15,0,0,10,0,0),
1223 /* Read D TLB CAM */
1224 arm920t_execute_cp15(target
,
1225 ARMV4_5_MCR(15,4,0,15,6,4),
1226 ARMV4_5_LDMIA(0, 0x3fc, 0, 0));
1228 /* clear interpret mode */
1230 arm920t_write_cp15_physical(target
,
1231 CP15PHYS_TESTSTATE
, cp15c15
);
1233 /* read D TLB CAM content stored to r2-r9 */
1234 arm9tdmi_read_core_regs(target
, 0x3fc, regs_p
);
1235 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1240 for (i
= 0; i
< 8; i
++)
1241 d_tlb
[victim
+ i
].cam
= regs
[i
+ 2];
1244 for (victim
= 0; victim
< 64; victim
++)
1246 /* new lockdown value: base[31:26]:victim[25:20]:SBZ[19:1]:p[0]
1247 * base remains unchanged, victim goes through entries 0 to 63
1249 regs
[1] = (Dlockdown
& 0xfc000000) | (victim
<< 20);
1250 arm9tdmi_write_core_regs(target
, 0x2, regs
);
1252 /* set interpret mode */
1254 arm920t_write_cp15_physical(target
,
1255 CP15PHYS_TESTSTATE
, cp15c15
);
1257 /* Write D TLB lockdown */
1258 arm920t_execute_cp15(target
,
1259 ARMV4_5_MCR(15,0,0,10,0,0), ARMV4_5_STR(1, 0));
1261 /* Read D TLB RAM1 */
1262 arm920t_execute_cp15(target
,
1263 ARMV4_5_MCR(15,4,0,15,10,4), ARMV4_5_LDR(2,0));
1265 /* Read D TLB RAM2 */
1266 arm920t_execute_cp15(target
,
1267 ARMV4_5_MCR(15,4,0,15,2,5), ARMV4_5_LDR(3,0));
1269 /* clear interpret mode */
1271 arm920t_write_cp15_physical(target
,
1272 CP15PHYS_TESTSTATE
, cp15c15
);
1274 /* read D TLB RAM content stored to r2 and r3 */
1275 arm9tdmi_read_core_regs(target
, 0xc, regs_p
);
1276 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1281 d_tlb
[victim
].ram1
= regs
[2];
1282 d_tlb
[victim
].ram2
= regs
[3];
1285 /* restore D TLB lockdown */
1286 regs
[1] = Dlockdown
;
1287 arm9tdmi_write_core_regs(target
, 0x2, regs
);
1289 /* Write D TLB lockdown */
1290 arm920t_execute_cp15(target
,
1291 ARMV4_5_MCR(15,0,0,10,0,0), ARMV4_5_STR(1, 0));
1293 /* prepare reading I TLB content
1296 /* set interpret mode */
1298 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
1300 /* Read I TLB lockdown */
1301 arm920t_execute_cp15(target
,
1302 ARMV4_5_MRC(15,0,0,10,0,1), ARMV4_5_LDR(1, 0));
1304 /* clear interpret mode */
1306 arm920t_write_cp15_physical(target
, CP15PHYS_TESTSTATE
, cp15c15
);
1308 /* read I TLB lockdown stored to r1 */
1309 arm9tdmi_read_core_regs(target
, 0x2, regs_p
);
1310 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1314 Ilockdown
= regs
[1];
1316 for (victim
= 0; victim
< 64; victim
+= 8)
1318 /* new lockdown value: base[31:26]:victim[25:20]:SBZ[19:1]:p[0]
1319 * base remains unchanged, victim goes through entries 0 to 63
1321 regs
[1] = (Ilockdown
& 0xfc000000) | (victim
<< 20);
1322 arm9tdmi_write_core_regs(target
, 0x2, regs
);
1324 /* set interpret mode */
1326 arm920t_write_cp15_physical(target
,
1327 CP15PHYS_TESTSTATE
, cp15c15
);
1329 /* Write I TLB lockdown */
1330 arm920t_execute_cp15(target
,
1331 ARMV4_5_MCR(15,0,0,10,0,1),
1334 /* Read I TLB CAM */
1335 arm920t_execute_cp15(target
,
1336 ARMV4_5_MCR(15,4,0,15,5,4),
1337 ARMV4_5_LDMIA(0, 0x3fc, 0, 0));
1339 /* clear interpret mode */
1341 arm920t_write_cp15_physical(target
,
1342 CP15PHYS_TESTSTATE
, cp15c15
);
1344 /* read I TLB CAM content stored to r2-r9 */
1345 arm9tdmi_read_core_regs(target
, 0x3fc, regs_p
);
1346 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1351 for (i
= 0; i
< 8; i
++)
1352 i_tlb
[i
+ victim
].cam
= regs
[i
+ 2];
1355 for (victim
= 0; victim
< 64; victim
++)
1357 /* new lockdown value: base[31:26]:victim[25:20]:SBZ[19:1]:p[0]
1358 * base remains unchanged, victim goes through entries 0 to 63
1360 regs
[1] = (Dlockdown
& 0xfc000000) | (victim
<< 20);
1361 arm9tdmi_write_core_regs(target
, 0x2, regs
);
1363 /* set interpret mode */
1365 arm920t_write_cp15_physical(target
,
1366 CP15PHYS_TESTSTATE
, cp15c15
);
1368 /* Write I TLB lockdown */
1369 arm920t_execute_cp15(target
,
1370 ARMV4_5_MCR(15,0,0,10,0,1), ARMV4_5_STR(1, 0));
1372 /* Read I TLB RAM1 */
1373 arm920t_execute_cp15(target
,
1374 ARMV4_5_MCR(15,4,0,15,9,4), ARMV4_5_LDR(2,0));
1376 /* Read I TLB RAM2 */
1377 arm920t_execute_cp15(target
,
1378 ARMV4_5_MCR(15,4,0,15,1,5), ARMV4_5_LDR(3,0));
1380 /* clear interpret mode */
1382 arm920t_write_cp15_physical(target
,
1383 CP15PHYS_TESTSTATE
, cp15c15
);
1385 /* read I TLB RAM content stored to r2 and r3 */
1386 arm9tdmi_read_core_regs(target
, 0xc, regs_p
);
1387 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1392 i_tlb
[victim
].ram1
= regs
[2];
1393 i_tlb
[victim
].ram2
= regs
[3];
1396 /* restore I TLB lockdown */
1397 regs
[1] = Ilockdown
;
1398 arm9tdmi_write_core_regs(target
, 0x2, regs
);
1400 /* Write I TLB lockdown */
1401 arm920t_execute_cp15(target
,
1402 ARMV4_5_MCR(15,0,0,10,0,1), ARMV4_5_STR(1, 0));
1404 /* restore CP15 MMU and Cache settings */
1405 arm920t_write_cp15_physical(target
, CP15PHYS_CTRL
, cp15_ctrl_saved
);
1407 /* output data to file */
1408 fprintf(output
, "D TLB content:\n");
1409 for (i
= 0; i
< 64; i
++)
1411 fprintf(output
, "%i: 0x%8.8" PRIx32
" 0x%8.8" PRIx32
1412 " 0x%8.8" PRIx32
" %s\n",
1413 i
, d_tlb
[i
].cam
, d_tlb
[i
].ram1
, d_tlb
[i
].ram2
,
1414 (d_tlb
[i
].cam
& 0x20) ? "(valid)" : "(invalid)");
1417 fprintf(output
, "\n\nI TLB content:\n");
1418 for (i
= 0; i
< 64; i
++)
1420 fprintf(output
, "%i: 0x%8.8" PRIx32
" 0x%8.8" PRIx32
1421 " 0x%8.8" PRIx32
" %s\n",
1422 i
, i_tlb
[i
].cam
, i_tlb
[i
].ram1
, i_tlb
[i
].ram2
,
1423 (i_tlb
[i
].cam
& 0x20) ? "(valid)" : "(invalid)");
1426 command_print(CMD_CTX
, "mmu content successfully output to %s",
1431 if (!is_arm_mode(armv4_5
->core_mode
))
1434 /* force writeback of the valid data */
1435 r
= armv4_5
->core_cache
->reg_list
;
1436 r
[0].dirty
= r
[0].valid
;
1437 r
[1].dirty
= r
[1].valid
;
1438 r
[2].dirty
= r
[2].valid
;
1439 r
[3].dirty
= r
[3].valid
;
1440 r
[4].dirty
= r
[4].valid
;
1441 r
[5].dirty
= r
[5].valid
;
1442 r
[6].dirty
= r
[6].valid
;
1443 r
[7].dirty
= r
[7].valid
;
1445 r
= arm_reg_current(armv4_5
, 8);
1446 r
->dirty
= r
->valid
;
1448 r
= arm_reg_current(armv4_5
, 9);
1449 r
->dirty
= r
->valid
;
1454 COMMAND_HANDLER(arm920t_handle_cp15_command
)
1457 struct target
*target
= get_current_target(CMD_CTX
);
1458 struct arm920t_common
*arm920t
= target_to_arm920(target
);
1460 retval
= arm920t_verify_pointer(CMD_CTX
, arm920t
);
1461 if (retval
!= ERROR_OK
)
1464 if (target
->state
!= TARGET_HALTED
)
1466 command_print(CMD_CTX
, "target must be stopped for "
1467 "\"%s\" command", CMD_NAME
);
1471 /* one argument, read a register.
1472 * two arguments, write it.
1477 COMMAND_PARSE_NUMBER(int, CMD_ARGV
[0], address
);
1482 if ((retval
= arm920t_read_cp15_physical(target
,
1483 address
, &value
)) != ERROR_OK
)
1485 command_print(CMD_CTX
,
1486 "couldn't access reg %i", address
);
1489 if ((retval
= jtag_execute_queue()) != ERROR_OK
)
1494 command_print(CMD_CTX
, "%i: %8.8" PRIx32
,
1497 else if (CMD_ARGC
== 2)
1500 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], value
);
1501 retval
= arm920t_write_cp15_physical(target
,
1503 if (retval
!= ERROR_OK
)
1505 command_print(CMD_CTX
,
1506 "couldn't access reg %i", address
);
1507 /* REVISIT why lie? "return retval"? */
1510 command_print(CMD_CTX
, "%i: %8.8" PRIx32
,
1518 COMMAND_HANDLER(arm920t_handle_cp15i_command
)
1521 struct target
*target
= get_current_target(CMD_CTX
);
1522 struct arm920t_common
*arm920t
= target_to_arm920(target
);
1524 retval
= arm920t_verify_pointer(CMD_CTX
, arm920t
);
1525 if (retval
!= ERROR_OK
)
1529 if (target
->state
!= TARGET_HALTED
)
1531 command_print(CMD_CTX
, "target must be stopped for "
1532 "\"%s\" command", CMD_NAME
);
1536 /* one argument, read a register.
1537 * two arguments, write it.
1542 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[0], opcode
);
1547 retval
= arm920t_read_cp15_interpreted(target
,
1548 opcode
, 0x0, &value
);
1549 if (retval
!= ERROR_OK
)
1551 command_print(CMD_CTX
,
1552 "couldn't execute %8.8" PRIx32
,
1554 /* REVISIT why lie? "return retval"? */
1558 command_print(CMD_CTX
, "%8.8" PRIx32
": %8.8" PRIx32
,
1561 else if (CMD_ARGC
== 2)
1564 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], value
);
1565 retval
= arm920t_write_cp15_interpreted(target
,
1567 if (retval
!= ERROR_OK
)
1569 command_print(CMD_CTX
,
1570 "couldn't execute %8.8" PRIx32
,
1572 /* REVISIT why lie? "return retval"? */
1575 command_print(CMD_CTX
, "%8.8" PRIx32
": %8.8" PRIx32
,
1578 else if (CMD_ARGC
== 3)
1581 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[1], value
);
1583 COMMAND_PARSE_NUMBER(u32
, CMD_ARGV
[2], address
);
1584 retval
= arm920t_write_cp15_interpreted(target
,
1585 opcode
, value
, address
);
1586 if (retval
!= ERROR_OK
)
1588 command_print(CMD_CTX
,
1589 "couldn't execute %8.8" PRIx32
, opcode
);
1590 /* REVISIT why lie? "return retval"? */
1593 command_print(CMD_CTX
, "%8.8" PRIx32
": %8.8" PRIx32
1594 " %8.8" PRIx32
, opcode
, value
, address
);
1599 command_print(CMD_CTX
,
1600 "usage: arm920t cp15i <opcode> [value] [address]");
1606 COMMAND_HANDLER(arm920t_handle_cache_info_command
)
1609 struct target
*target
= get_current_target(CMD_CTX
);
1610 struct arm920t_common
*arm920t
= target_to_arm920(target
);
1612 retval
= arm920t_verify_pointer(CMD_CTX
, arm920t
);
1613 if (retval
!= ERROR_OK
)
1616 return armv4_5_handle_cache_info_command(CMD_CTX
,
1617 &arm920t
->armv4_5_mmu
.armv4_5_cache
);
1621 static int arm920t_mrc(struct target
*target
, int cpnum
,
1622 uint32_t op1
, uint32_t op2
,
1623 uint32_t CRn
, uint32_t CRm
,
1628 LOG_ERROR("Only cp15 is supported");
1633 return arm920t_read_cp15_interpreted(target
,
1634 ARMV4_5_MRC(cpnum
, op1
, 0, CRn
, CRm
, op2
),
1638 static int arm920t_mcr(struct target
*target
, int cpnum
,
1639 uint32_t op1
, uint32_t op2
,
1640 uint32_t CRn
, uint32_t CRm
,
1645 LOG_ERROR("Only cp15 is supported");
1649 /* write "from" r0 */
1650 return arm920t_write_cp15_interpreted(target
,
1651 ARMV4_5_MCR(cpnum
, op1
, 0, CRn
, CRm
, op2
),
1655 static const struct command_registration arm920t_exec_command_handlers
[] = {
1658 .handler
= arm920t_handle_cp15_command
,
1659 .mode
= COMMAND_EXEC
,
1660 .help
= "display/modify cp15 register",
1661 .usage
= "regnum [value]",
1665 .handler
= arm920t_handle_cp15i_command
,
1666 .mode
= COMMAND_EXEC
,
1667 /* prefer using less error-prone "arm mcr" or "arm mrc" */
1668 .help
= "display/modify cp15 register using ARM opcode"
1670 .usage
= "instruction [value [address]]",
1673 .name
= "cache_info",
1674 .handler
= arm920t_handle_cache_info_command
,
1675 .mode
= COMMAND_EXEC
,
1676 .help
= "display information about target caches",
1679 .name
= "read_cache",
1680 .handler
= arm920t_handle_read_cache_command
,
1681 .mode
= COMMAND_EXEC
,
1682 .help
= "dump I/D cache content to file",
1683 .usage
= "filename",
1687 .handler
= arm920t_handle_read_mmu_command
,
1688 .mode
= COMMAND_EXEC
,
1689 .help
= "dump I/D mmu content to file",
1690 .usage
= "filename",
1692 COMMAND_REGISTRATION_DONE
1694 const struct command_registration arm920t_command_handlers
[] = {
1696 .chain
= arm9tdmi_command_handlers
,
1700 .mode
= COMMAND_ANY
,
1701 .help
= "arm920t command group",
1702 .chain
= arm920t_exec_command_handlers
,
1704 COMMAND_REGISTRATION_DONE
1707 /** Holds methods for ARM920 targets. */
1708 struct target_type arm920t_target
=
1712 .poll
= arm7_9_poll
,
1713 .arch_state
= arm920t_arch_state
,
1715 .target_request_data
= arm7_9_target_request_data
,
1717 .halt
= arm7_9_halt
,
1718 .resume
= arm7_9_resume
,
1719 .step
= arm7_9_step
,
1721 .assert_reset
= arm7_9_assert_reset
,
1722 .deassert_reset
= arm7_9_deassert_reset
,
1723 .soft_reset_halt
= arm920t_soft_reset_halt
,
1725 .get_gdb_reg_list
= arm_get_gdb_reg_list
,
1727 .read_memory
= arm920t_read_memory
,
1728 .write_memory
= arm920t_write_memory
,
1729 .read_phys_memory
= arm920t_read_phys_memory
,
1730 .write_phys_memory
= arm920t_write_phys_memory
,
1732 .virt2phys
= arm920_virt2phys
,
1734 .bulk_write_memory
= arm7_9_bulk_write_memory
,
1736 .checksum_memory
= arm_checksum_memory
,
1737 .blank_check_memory
= arm_blank_check_memory
,
1739 .run_algorithm
= armv4_5_run_algorithm
,
1741 .add_breakpoint
= arm7_9_add_breakpoint
,
1742 .remove_breakpoint
= arm7_9_remove_breakpoint
,
1743 .add_watchpoint
= arm7_9_add_watchpoint
,
1744 .remove_watchpoint
= arm7_9_remove_watchpoint
,
1746 .commands
= arm920t_command_handlers
,
1747 .target_create
= arm920t_target_create
,
1748 .init_target
= arm9tdmi_init_target
,
1749 .examine
= arm7_9_examine
,
1750 .check_reset
= arm7_9_check_reset
,