1 /***************************************************************************
2 * Copyright (C) 2008 by Spencer Oliver *
3 * spen@spen-soft.co.uk *
5 * Copyright (C) 2008 by David T.L. Wong *
7 * Copyright (C) 2009 by David N. Claffey <dnclaffey@gmail.com> *
9 * Copyright (C) 2011 by Drasko DRASKOVIC *
10 * drasko.draskovic@gmail.com *
12 * This program is free software; you can redistribute it and/or modify *
13 * it under the terms of the GNU General Public License as published by *
14 * the Free Software Foundation; either version 2 of the License, or *
15 * (at your option) any later version. *
17 * This program is distributed in the hope that it will be useful, *
18 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
19 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
20 * GNU General Public License for more details. *
22 * You should have received a copy of the GNU General Public License *
23 * along with this program; if not, write to the *
24 * Free Software Foundation, Inc., *
25 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
26 ***************************************************************************/
29 * This version has optimized assembly routines for 32 bit operations:
32 * - write array of words
34 * One thing to be aware of is that the MIPS32 cpu will execute the
35 * instruction after a branch instruction (one delay slot).
42 * The LW $1, ($2 +100) instruction is also executed. If this is
43 * not wanted a NOP can be inserted:
50 * or the code can be changed to:
56 * The original code contained NOPs. I have removed these and moved
59 * I also moved the PRACC_STACK to 0xFF204000. This allows
60 * the use of 16 bits offsets to get pointers to the input
61 * and output area relative to the stack. Note that the stack
62 * isn't really a stack (the stack pointer is not 'moving')
63 * but a FIFO simulated in software.
65 * These changes result in a 35% speed increase when programming an
68 * More improvement could be gained if the registers do no need
69 * to be preserved but in that case the routines should be aware
70 * OpenOCD is used as a flash programmer or as a debug tool.
79 #include <helper/time_support.h>
82 #include "mips32_pracc.h"
84 struct mips32_pracc_context
{
85 uint32_t *local_iparam
;
87 uint32_t *local_oparam
;
93 struct mips_ejtag
*ejtag_info
;
96 static int mips32_pracc_sync_cache(struct mips_ejtag
*ejtag_info
,
97 uint32_t start_addr
, uint32_t end_addr
);
98 static int mips32_pracc_clean_invalidate_cache(struct mips_ejtag
*ejtag_info
,
99 uint32_t start_addr
, uint32_t end_addr
);
101 static int wait_for_pracc_rw(struct mips_ejtag
*ejtag_info
, uint32_t *ctrl
)
104 long long then
= timeval_ms();
108 /* wait for the PrAcc to become "1" */
109 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_CONTROL
);
112 ejtag_ctrl
= ejtag_info
->ejtag_ctrl
;
113 retval
= mips_ejtag_drscan_32(ejtag_info
, &ejtag_ctrl
);
114 if (retval
!= ERROR_OK
)
117 if (ejtag_ctrl
& EJTAG_CTRL_PRACC
)
120 timeout
= timeval_ms() - then
;
121 if (timeout
> 1000) {
122 LOG_DEBUG("DEBUGMODULE: No memory access in progress!");
123 return ERROR_JTAG_DEVICE_ERROR
;
131 static int mips32_pracc_exec_read(struct mips32_pracc_context
*ctx
, uint32_t address
)
133 struct mips_ejtag
*ejtag_info
= ctx
->ejtag_info
;
135 uint32_t ejtag_ctrl
, data
;
137 if ((address
>= MIPS32_PRACC_PARAM_IN
)
138 && (address
< MIPS32_PRACC_PARAM_IN
+ ctx
->num_iparam
* 4)) {
139 offset
= (address
- MIPS32_PRACC_PARAM_IN
) / 4;
140 data
= ctx
->local_iparam
[offset
];
141 } else if ((address
>= MIPS32_PRACC_PARAM_OUT
)
142 && (address
< MIPS32_PRACC_PARAM_OUT
+ ctx
->num_oparam
* 4)) {
143 offset
= (address
- MIPS32_PRACC_PARAM_OUT
) / 4;
144 data
= ctx
->local_oparam
[offset
];
145 } else if ((address
>= MIPS32_PRACC_TEXT
)
146 && (address
< MIPS32_PRACC_TEXT
+ ctx
->code_len
* 4)) {
147 offset
= (address
- MIPS32_PRACC_TEXT
) / 4;
148 data
= ctx
->code
[offset
];
149 } else if (address
== MIPS32_PRACC_STACK
) {
150 if (ctx
->stack_offset
<= 0) {
151 LOG_ERROR("Error: Pracc stack out of bounds");
152 return ERROR_JTAG_DEVICE_ERROR
;
154 /* save to our debug stack */
155 data
= ctx
->stack
[--ctx
->stack_offset
];
157 /* TODO: send JMP 0xFF200000 instruction. Hopefully processor jump back
158 * to start of debug vector */
160 LOG_ERROR("Error reading unexpected address 0x%8.8" PRIx32
"", address
);
161 return ERROR_JTAG_DEVICE_ERROR
;
164 /* Send the data out */
165 mips_ejtag_set_instr(ctx
->ejtag_info
, EJTAG_INST_DATA
);
166 mips_ejtag_drscan_32_out(ctx
->ejtag_info
, data
);
168 /* Clear the access pending bit (let the processor eat!) */
169 ejtag_ctrl
= ejtag_info
->ejtag_ctrl
& ~EJTAG_CTRL_PRACC
;
170 mips_ejtag_set_instr(ctx
->ejtag_info
, EJTAG_INST_CONTROL
);
171 mips_ejtag_drscan_32_out(ctx
->ejtag_info
, ejtag_ctrl
);
173 return jtag_execute_queue();
176 static int mips32_pracc_exec_write(struct mips32_pracc_context
*ctx
, uint32_t address
)
178 uint32_t ejtag_ctrl
, data
;
180 struct mips_ejtag
*ejtag_info
= ctx
->ejtag_info
;
183 mips_ejtag_set_instr(ctx
->ejtag_info
, EJTAG_INST_DATA
);
184 retval
= mips_ejtag_drscan_32(ctx
->ejtag_info
, &data
);
185 if (retval
!= ERROR_OK
)
188 /* Clear access pending bit */
189 ejtag_ctrl
= ejtag_info
->ejtag_ctrl
& ~EJTAG_CTRL_PRACC
;
190 mips_ejtag_set_instr(ctx
->ejtag_info
, EJTAG_INST_CONTROL
);
191 mips_ejtag_drscan_32_out(ctx
->ejtag_info
, ejtag_ctrl
);
193 retval
= jtag_execute_queue();
194 if (retval
!= ERROR_OK
)
197 if ((address
>= MIPS32_PRACC_PARAM_OUT
)
198 && (address
< MIPS32_PRACC_PARAM_OUT
+ ctx
->num_oparam
* 4)) {
199 offset
= (address
- MIPS32_PRACC_PARAM_OUT
) / 4;
200 ctx
->local_oparam
[offset
] = data
;
201 } else if (address
== MIPS32_PRACC_STACK
) {
202 if (ctx
->stack_offset
>= 32) {
203 LOG_ERROR("Error: Pracc stack out of bounds");
204 return ERROR_JTAG_DEVICE_ERROR
;
206 /* save data onto our stack */
207 ctx
->stack
[ctx
->stack_offset
++] = data
;
209 LOG_ERROR("Error writing unexpected address 0x%8.8" PRIx32
"", address
);
210 return ERROR_JTAG_DEVICE_ERROR
;
216 int mips32_pracc_exec(struct mips_ejtag
*ejtag_info
, int code_len
, const uint32_t *code
,
217 int num_param_in
, uint32_t *param_in
, int num_param_out
, uint32_t *param_out
, int cycle
)
221 struct mips32_pracc_context ctx
;
225 ctx
.local_iparam
= param_in
;
226 ctx
.local_oparam
= param_out
;
227 ctx
.num_iparam
= num_param_in
;
228 ctx
.num_oparam
= num_param_out
;
230 ctx
.code_len
= code_len
;
231 ctx
.ejtag_info
= ejtag_info
;
232 ctx
.stack_offset
= 0;
235 retval
= wait_for_pracc_rw(ejtag_info
, &ejtag_ctrl
);
236 if (retval
!= ERROR_OK
)
240 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_ADDRESS
);
241 retval
= mips_ejtag_drscan_32(ejtag_info
, &address
);
242 if (retval
!= ERROR_OK
)
245 /* Check for read or write */
246 if (ejtag_ctrl
& EJTAG_CTRL_PRNW
) {
247 retval
= mips32_pracc_exec_write(&ctx
, address
);
248 if (retval
!= ERROR_OK
)
251 /* Check to see if its reading at the debug vector. The first pass through
252 * the module is always read at the vector, so the first one we allow. When
253 * the second read from the vector occurs we are done and just exit. */
254 if ((address
== MIPS32_PRACC_TEXT
) && (pass
++))
257 retval
= mips32_pracc_exec_read(&ctx
, address
);
258 if (retval
!= ERROR_OK
)
266 /* stack sanity check */
267 if (ctx
.stack_offset
!= 0)
268 LOG_DEBUG("Pracc Stack not zero");
273 static int mips32_pracc_read_u32(struct mips_ejtag
*ejtag_info
, uint32_t addr
, uint32_t *buf
)
277 MIPS32_MTC0(15, 31, 0), /* move $15 to COP0 DeSave */
278 MIPS32_LUI(15, PRACC_UPPER_BASE_ADDR
), /* $15 = MIPS32_PRACC_BASE_ADDR */
279 MIPS32_SW(8, PRACC_STACK_OFFSET
, 15), /* sw $8,PRACC_STACK_OFFSET($15) */
281 MIPS32_LUI(8, UPPER16((addr
+ 0x8000))), /* load $8 with modified upper address */
282 MIPS32_LW(8, LOWER16(addr
), 8), /* lw $8, LOWER16(addr)($8) */
283 MIPS32_SW(8, PRACC_OUT_OFFSET
, 15), /* sw $8,PRACC_OUT_OFFSET($15) */
285 MIPS32_LW(8, PRACC_STACK_OFFSET
, 15), /* lw $8,PRACC_STACK_OFFSET($15) */
286 MIPS32_B(NEG16(8)), /* b start */
287 MIPS32_MFC0(15, 31, 0), /* move COP0 DeSave to $15 */
290 return mips32_pracc_exec(ejtag_info
, ARRAY_SIZE(code
), code
, 0, NULL
, 1, buf
, 1);
293 int mips32_pracc_read_mem(struct mips_ejtag
*ejtag_info
, uint32_t addr
, int size
, int count
, void *buf
)
295 if (count
== 1 && size
== 4)
296 return mips32_pracc_read_u32(ejtag_info
, addr
, (uint32_t *)buf
);
298 int retval
= ERROR_FAIL
;
300 uint32_t *code
= NULL
;
301 uint32_t *data
= NULL
;
303 code
= malloc((256 * 2 + 10) * sizeof(uint32_t));
305 LOG_ERROR("Out of memory");
310 data
= malloc(256 * sizeof(uint32_t));
312 LOG_ERROR("Out of memory");
317 uint32_t *buf32
= buf
;
318 uint16_t *buf16
= buf
;
322 uint32_t upper_base_addr
, last_upper_base_addr
;
323 int this_round_count
;
327 this_round_count
= (count
> 256) ? 256 : count
;
328 last_upper_base_addr
= UPPER16((addr
+ 0x8000));
329 uint32_t *code_p
= code
;
331 *code_p
++ = MIPS32_MTC0(15, 31, 0); /* save $15 in DeSave */
332 *code_p
++ = MIPS32_LUI(15, PRACC_UPPER_BASE_ADDR
); /* $15 = MIPS32_PRACC_BASE_ADDR */
333 *code_p
++ = MIPS32_SW(8, PRACC_STACK_OFFSET
, 15); /* save $8 and $9 to pracc stack */
334 *code_p
++ = MIPS32_SW(9, PRACC_STACK_OFFSET
, 15);
335 *code_p
++ = MIPS32_LUI(9, last_upper_base_addr
); /* load the upper memory address in $9*/
338 for (i
= 0; i
!= this_round_count
; i
++) { /* Main code loop */
339 upper_base_addr
= UPPER16((addr
+ 0x8000));
340 if (last_upper_base_addr
!= upper_base_addr
) {
341 *code_p
++ = MIPS32_LUI(9, upper_base_addr
); /* if needed, change upper address in $9*/
343 last_upper_base_addr
= upper_base_addr
;
347 *code_p
++ = MIPS32_LW(8, LOWER16(addr
), 9); /* load from memory to $8 */
349 *code_p
++ = MIPS32_LHU(8, LOWER16(addr
), 9);
351 *code_p
++ = MIPS32_LBU(8, LOWER16(addr
), 9);
353 *code_p
++ = MIPS32_SW(8, PRACC_OUT_OFFSET
+ i
* 4, 15); /* store $8 at param out */
359 *code_p
++ = MIPS32_LW(9, PRACC_STACK_OFFSET
, 15); /* restore $8 and $9 from pracc stack */
360 *code_p
++ = MIPS32_LW(8, PRACC_STACK_OFFSET
, 15);
363 *code_p
++ = MIPS32_B(NEG16(code_len
- 1)); /* jump to start */
364 *code_p
= MIPS32_MFC0(15, 31, 0); /* restore $15 from DeSave */
367 retval
= mips32_pracc_exec(ejtag_info
, code_len
, code
, 0, NULL
, this_round_count
, buf32
, 1);
368 if (retval
!= ERROR_OK
)
370 buf32
+= this_round_count
;
372 retval
= mips32_pracc_exec(ejtag_info
, code_len
, code
, 0, NULL
, this_round_count
, data
, 1);
373 if (retval
!= ERROR_OK
)
375 uint32_t *data_p
= data
;
376 for (i
= 0; i
!= this_round_count
; i
++) {
378 *buf16
++ = *data_p
++;
383 count
-= this_round_count
;
394 int mips32_cp0_read(struct mips_ejtag
*ejtag_info
, uint32_t *val
, uint32_t cp0_reg
, uint32_t cp0_sel
)
397 * Do not make this code static, but regenerate it every time,
398 * as 3th element has to be changed to add parameters
402 MIPS32_MTC0(15, 31, 0), /* move $15 to COP0 DeSave */
403 MIPS32_LUI(15, PRACC_UPPER_BASE_ADDR
), /* $15 = MIPS32_PRACC_BASE_ADDR */
404 MIPS32_SW(8, PRACC_STACK_OFFSET
, 15), /* sw $8,PRACC_STACK_OFFSET($15) */
406 /* 3 */ MIPS32_MFC0(8, 0, 0), /* move COP0 [cp0_reg select] to $8 */
407 MIPS32_SW(8, PRACC_OUT_OFFSET
, 15), /* sw $8,PRACC_OUT_OFFSET($15) */
409 MIPS32_LW(8, PRACC_STACK_OFFSET
, 15), /* lw $8,PRACC_STACK_OFFSET($15) */
410 MIPS32_B(NEG16(7)), /* b start */
411 MIPS32_MFC0(15, 31, 0), /* move COP0 DeSave to $15 */
415 * Note that our input parametes cp0_reg and cp0_sel
416 * are numbers (not gprs) which make part of mfc0 instruction opcode.
418 * These are not fix, but can be different for each mips32_cp0_read() function call,
419 * and that is why we must insert them directly into opcode,
420 * i.e. we can not pass it on EJTAG microprogram stack (via param_in),
421 * and put them into the gprs later from MIPS32_PRACC_STACK
422 * because mfc0 do not use gpr as a parameter for the cp0_reg and select part,
423 * but plain (immediate) number.
425 * MIPS32_MTC0 is implemented via MIPS32_R_INST macro.
426 * In order to insert our parameters, we must change rd and funct fields.
428 code
[3] |= (cp0_reg
<< 11) | cp0_sel
; /* change rd and funct of MIPS32_R_INST macro */
430 return mips32_pracc_exec(ejtag_info
, ARRAY_SIZE(code
), code
, 0, NULL
, 1, val
, 1);
433 int mips32_cp0_write(struct mips_ejtag
*ejtag_info
, uint32_t val
, uint32_t cp0_reg
, uint32_t cp0_sel
)
437 MIPS32_MTC0(15, 31, 0), /* move $15 to COP0 DeSave */
438 MIPS32_LUI(15, UPPER16(val
)), /* Load val to $15 */
439 MIPS32_ORI(15, 15, LOWER16(val
)),
441 /* 3 */ MIPS32_MTC0(15, 0, 0), /* move $15 to COP0 [cp0_reg select] */
443 MIPS32_B(NEG16(5)), /* b start */
444 MIPS32_MFC0(15, 31, 0), /* move COP0 DeSave to $15 */
448 * Note that MIPS32_MTC0 macro is implemented via MIPS32_R_INST macro.
449 * In order to insert our parameters, we must change rd and funct fields.
451 code
[3] |= (cp0_reg
<< 11) | cp0_sel
; /* change rd and funct fields of MIPS32_R_INST macro */
453 return mips32_pracc_exec(ejtag_info
, ARRAY_SIZE(code
), code
, 0, NULL
, 0, NULL
, 1);
457 * \b mips32_pracc_sync_cache
459 * Synchronize Caches to Make Instruction Writes Effective
460 * (ref. doc. MIPS32 Architecture For Programmers Volume II: The MIPS32 Instruction Set,
461 * Document Number: MD00086, Revision 2.00, June 9, 2003)
463 * When the instruction stream is written, the SYNCI instruction should be used
464 * in conjunction with other instructions to make the newly-written instructions effective.
467 * A program that loads another program into memory is actually writing the D- side cache.
468 * The instructions it has loaded can't be executed until they reach the I-cache.
470 * After the instructions have been written, the loader should arrange
471 * to write back any containing D-cache line and invalidate any locations
472 * already in the I-cache.
474 * You can do that with cache instructions, but those instructions are only available in kernel mode,
475 * and a loader writing instructions for the use of its own process need not be privileged software.
477 * In the latest MIPS32/64 CPUs, MIPS provides the synci instruction,
478 * which does the whole job for a cache-line-sized chunk of the memory you just loaded:
479 * That is, it arranges a D-cache write-back and an I-cache invalidate.
481 * To employ synci at user level, you need to know the size of a cache line,
482 * and that can be obtained with a rdhwr SYNCI_Step
483 * from one of the standard “hardware registers”.
485 static int mips32_pracc_sync_cache(struct mips_ejtag
*ejtag_info
,
486 uint32_t start_addr
, uint32_t end_addr
)
488 static const uint32_t code
[] = {
490 MIPS32_MTC0(15, 31, 0), /* move $15 to COP0 DeSave */
491 MIPS32_LUI(15, UPPER16(MIPS32_PRACC_STACK
)), /* $15 = MIPS32_PRACC_STACK */
492 MIPS32_ORI(15, 15, LOWER16(MIPS32_PRACC_STACK
)),
493 MIPS32_SW(8, 0, 15), /* sw $8,($15) */
494 MIPS32_SW(9, 0, 15), /* sw $9,($15) */
495 MIPS32_SW(10, 0, 15), /* sw $10,($15) */
496 MIPS32_SW(11, 0, 15), /* sw $11,($15) */
498 MIPS32_LUI(8, UPPER16(MIPS32_PRACC_PARAM_IN
)), /* $8 = MIPS32_PRACC_PARAM_IN */
499 MIPS32_ORI(8, 8, LOWER16(MIPS32_PRACC_PARAM_IN
)),
500 MIPS32_LW(9, 0, 8), /* Load write start_addr to $9 */
501 MIPS32_LW(10, 4, 8), /* Load write end_addr to $10 */
503 MIPS32_RDHWR(11, MIPS32_SYNCI_STEP
), /* $11 = MIPS32_SYNCI_STEP */
504 MIPS32_BEQ(11, 0, 6), /* beq $11, $0, end */
507 MIPS32_SYNCI(0, 9), /* synci 0($9) */
508 MIPS32_SLTU(8, 10, 9), /* sltu $8, $10, $9 # $8 = $10 < $9 ? 1 : 0 */
509 MIPS32_BNE(8, 0, NEG16(3)), /* bne $8, $0, synci_loop */
510 MIPS32_ADDU(9, 9, 11), /* $9 += MIPS32_SYNCI_STEP */
513 MIPS32_LW(11, 0, 15), /* lw $11,($15) */
514 MIPS32_LW(10, 0, 15), /* lw $10,($15) */
515 MIPS32_LW(9, 0, 15), /* lw $9,($15) */
516 MIPS32_LW(8, 0, 15), /* lw $8,($15) */
517 MIPS32_B(NEG16(24)), /* b start */
518 MIPS32_MFC0(15, 31, 0), /* move COP0 DeSave to $15 */
521 /* TODO remove array */
522 uint32_t *param_in
= malloc(2 * sizeof(uint32_t));
524 param_in
[0] = start_addr
;
525 param_in
[1] = end_addr
;
527 retval
= mips32_pracc_exec(ejtag_info
, ARRAY_SIZE(code
), code
, 2, param_in
, 0, NULL
, 1);
535 * \b mips32_pracc_clean_invalidate_cache
537 * Writeback D$ and Invalidate I$
538 * so that the instructions written can be visible to CPU
540 static int mips32_pracc_clean_invalidate_cache(struct mips_ejtag
*ejtag_info
,
541 uint32_t start_addr
, uint32_t end_addr
)
543 static const uint32_t code
[] = {
545 MIPS32_MTC0(15, 31, 0), /* move $15 to COP0 DeSave */
546 MIPS32_LUI(15, UPPER16(MIPS32_PRACC_STACK
)), /* $15 = MIPS32_PRACC_STACK */
547 MIPS32_ORI(15, 15, LOWER16(MIPS32_PRACC_STACK
)),
548 MIPS32_SW(8, 0, 15), /* sw $8,($15) */
549 MIPS32_SW(9, 0, 15), /* sw $9,($15) */
550 MIPS32_SW(10, 0, 15), /* sw $10,($15) */
551 MIPS32_SW(11, 0, 15), /* sw $11,($15) */
553 MIPS32_LUI(8, UPPER16(MIPS32_PRACC_PARAM_IN
)), /* $8 = MIPS32_PRACC_PARAM_IN */
554 MIPS32_ORI(8, 8, LOWER16(MIPS32_PRACC_PARAM_IN
)),
555 MIPS32_LW(9, 0, 8), /* Load write start_addr to $9 */
556 MIPS32_LW(10, 4, 8), /* Load write end_addr to $10 */
557 MIPS32_LW(11, 8, 8), /* Load write clsiz to $11 */
560 MIPS32_SLTU(8, 10, 9), /* sltu $8, $10, $9 : $8 <- $10 < $9 ? */
561 MIPS32_BGTZ(8, 6), /* bgtz $8, end */
564 MIPS32_CACHE(MIPS32_CACHE_D_HIT_WRITEBACK
, 0, 9), /* cache Hit_Writeback_D, 0($9) */
565 MIPS32_CACHE(MIPS32_CACHE_I_HIT_INVALIDATE
, 0, 9), /* cache Hit_Invalidate_I, 0($9) */
567 MIPS32_ADDU(9, 9, 11), /* $9 += $11 */
569 MIPS32_B(NEG16(7)), /* b cache_loop */
572 MIPS32_LW(11, 0, 15), /* lw $11,($15) */
573 MIPS32_LW(10, 0, 15), /* lw $10,($15) */
574 MIPS32_LW(9, 0, 15), /* lw $9,($15) */
575 MIPS32_LW(8, 0, 15), /* lw $8,($15) */
576 MIPS32_B(NEG16(25)), /* b start */
577 MIPS32_MFC0(15, 31, 0), /* move COP0 DeSave to $15 */
581 * Find cache line size in bytes
586 mips32_cp0_read(ejtag_info
, &conf
, 16, 1);
587 dl
= (conf
& MIPS32_CONFIG1_DL_MASK
) >> MIPS32_CONFIG1_DL_SHIFT
;
589 /* dl encoding : dl=1 => 4 bytes, dl=2 => 8 bytes, etc... */
592 /* TODO remove array */
593 uint32_t *param_in
= malloc(3 * sizeof(uint32_t));
595 param_in
[0] = start_addr
;
596 param_in
[1] = end_addr
;
599 retval
= mips32_pracc_exec(ejtag_info
, ARRAY_SIZE(code
), code
, 3, param_in
, 0, NULL
, 1);
606 static int mips32_pracc_write_mem_generic(struct mips_ejtag
*ejtag_info
, uint32_t addr
, int size
, int count
, void *buf
)
609 code
= malloc((128 * 3 + 9) * sizeof(uint32_t)); /* alloc memory for the worst case */
611 LOG_ERROR("Out of memory");
615 uint32_t *buf32
= buf
;
616 uint16_t *buf16
= buf
;
620 int retval
= ERROR_FAIL
;
622 uint32_t upper_base_addr
, last_upper_base_addr
;
623 int this_round_count
;
627 this_round_count
= (count
> 128) ? 128 : count
;
628 last_upper_base_addr
= UPPER16((addr
+ 0x8000));
631 *code_p
++ = MIPS32_MTC0(15, 31, 0); /* save $15 in DeSave */
632 *code_p
++ = MIPS32_LUI(15, PRACC_UPPER_BASE_ADDR
); /* $15 = MIPS32_PRACC_BASE_ADDR */
633 *code_p
++ = MIPS32_SW(8, PRACC_STACK_OFFSET
, 15); /* save $8 to pracc stack */
634 *code_p
++ = MIPS32_LUI(15, last_upper_base_addr
); /* reuse $15 as memory base address */
637 for (i
= 0; i
!= this_round_count
; i
++) {
638 upper_base_addr
= UPPER16((addr
+ 0x8000));
639 if (last_upper_base_addr
!= upper_base_addr
) {
640 *code_p
++ = MIPS32_LUI(15, upper_base_addr
); /* if needed, change upper address in $15*/
642 last_upper_base_addr
= upper_base_addr
;
645 if (size
== 4) { /* for word write check if one half word is 0 and load it accordingly */
646 if (LOWER16(*buf32
) == 0) {
647 *code_p
++ = MIPS32_LUI(8, UPPER16(*buf32
)); /* load only upper value */
649 } else if (UPPER16(*buf32
) == 0) {
650 *code_p
++ = MIPS32_ORI(8, 0, LOWER16(*buf32
)); /* load only lower value */
653 *code_p
++ = MIPS32_LUI(8, UPPER16(*buf32
)); /* load upper and lower */
654 *code_p
++ = MIPS32_ORI(8, 8, LOWER16(*buf32
));
657 *code_p
++ = MIPS32_SW(8, LOWER16(addr
), 15); /* store word to memory */
661 } else if (size
== 2) {
662 *code_p
++ = MIPS32_ORI(8, 0, *buf16
); /* load lower value */
663 *code_p
++ = MIPS32_SH(8, LOWER16(addr
), 15); /* store half word to memory */
668 *code_p
++ = MIPS32_ORI(8, 0, *buf8
); /* load lower value */
669 *code_p
++ = MIPS32_SB(8, LOWER16(addr
), 15); /* store byte to memory */
677 *code_p
++ = MIPS32_LUI(15, PRACC_UPPER_BASE_ADDR
); /* $15 = MIPS32_PRACC_BASE_ADDR */
678 *code_p
++ = MIPS32_LW(8, PRACC_STACK_OFFSET
, 15); /* restore $8 from pracc stack */
681 *code_p
++ = MIPS32_B(NEG16(code_len
- 1)); /* jump to start */
682 *code_p
= MIPS32_MFC0(15, 31, 0); /* restore $15 from DeSave */
684 retval
= mips32_pracc_exec(ejtag_info
, code_len
, code
, 0, NULL
, 0, NULL
, 1);
685 if (retval
!= ERROR_OK
)
688 count
-= this_round_count
;
696 int mips32_pracc_write_mem(struct mips_ejtag
*ejtag_info
, uint32_t addr
, int size
, int count
, void *buf
)
698 int retval
= mips32_pracc_write_mem_generic(ejtag_info
, addr
, size
, count
, buf
);
699 if (retval
!= ERROR_OK
)
703 * If we are in the cachable regoion and cache is activated,
704 * we must clean D$ + invalidate I$ after we did the write,
705 * so that changes do not continue to live only in D$, but to be
706 * replicated in I$ also (maybe we wrote the istructions)
711 if ((KSEGX(addr
) == KSEG1
) || ((addr
>= 0xff200000) && (addr
<= 0xff3fffff)))
712 return retval
; /*Nothing to do*/
714 mips32_cp0_read(ejtag_info
, &conf
, 16, 0);
716 switch (KSEGX(addr
)) {
718 cached
= (conf
& MIPS32_CONFIG0_KU_MASK
) >> MIPS32_CONFIG0_KU_SHIFT
;
721 cached
= (conf
& MIPS32_CONFIG0_K0_MASK
) >> MIPS32_CONFIG0_K0_SHIFT
;
725 cached
= (conf
& MIPS32_CONFIG0_K23_MASK
) >> MIPS32_CONFIG0_K23_SHIFT
;
733 * Check cachablitiy bits coherency algorithm -
734 * is the region cacheable or uncached.
735 * If cacheable we have to synchronize the cache
738 uint32_t start_addr
, end_addr
;
742 end_addr
= addr
+ count
* size
;
744 /** select cache synchronisation mechanism based on Architecture Release */
745 rel
= (conf
& MIPS32_CONFIG0_AR_MASK
) >> MIPS32_CONFIG0_AR_SHIFT
;
747 case MIPS32_ARCH_REL1
:
748 /* MIPS32/64 Release 1 - we must use cache instruction */
749 mips32_pracc_clean_invalidate_cache(ejtag_info
, start_addr
, end_addr
);
751 case MIPS32_ARCH_REL2
:
752 /* MIPS32/64 Release 2 - we can use synci instruction */
753 mips32_pracc_sync_cache(ejtag_info
, start_addr
, end_addr
);
764 int mips32_pracc_write_regs(struct mips_ejtag
*ejtag_info
, uint32_t *regs
)
766 static const uint32_t cp0_write_code
[] = {
767 MIPS32_MTC0(1, 12, 0), /* move $1 to status */
768 MIPS32_MTLO(1), /* move $1 to lo */
769 MIPS32_MTHI(1), /* move $1 to hi */
770 MIPS32_MTC0(1, 8, 0), /* move $1 to badvaddr */
771 MIPS32_MTC0(1, 13, 0), /* move $1 to cause*/
772 MIPS32_MTC0(1, 24, 0), /* move $1 to depc (pc) */
776 code
= malloc((37 * 2 + 6 + 1) * sizeof(uint32_t)); /* alloc memory for the worst case */
778 LOG_ERROR("Out of memory");
782 uint32_t *code_p
= code
;
784 /* load registers 2 to 31 with lui an ori instructions, check if same instructions can be saved */
785 for (int i
= 2; i
< 32; i
++) {
786 if (LOWER16((regs
[i
])) == 0) {
787 *code_p
++ = MIPS32_LUI(i
, UPPER16((regs
[i
]))); /* if lower half word is 0, lui instruction only */
789 } else if (UPPER16((regs
[i
])) == 0) {
790 *code_p
++ = MIPS32_ORI(i
, 0, LOWER16((regs
[i
]))); /* if upper half word is 0, ori with $0 only*/
793 *code_p
++ = MIPS32_LUI(i
, UPPER16((regs
[i
]))); /* default, load with lui and ori instructions */
794 *code_p
++ = MIPS32_ORI(i
, i
, LOWER16((regs
[i
])));
799 for (int i
= 0; i
!= 6; i
++) {
800 *code_p
++ = MIPS32_LUI(1, UPPER16((regs
[i
+ 32]))); /* load CPO value in $1, with lui and ori */
801 *code_p
++ = MIPS32_ORI(1, 1, LOWER16((regs
[i
+ 32])));
802 *code_p
++ = cp0_write_code
[i
]; /* write value from $1 to CPO register */
806 *code_p
++ = MIPS32_LUI(1, UPPER16((regs
[1]))); /* load upper half word in $1 */
808 *code_p
++ = MIPS32_B(NEG16(code_len
- 1)), /* b start */
809 *code_p
= MIPS32_ORI(1, 1, LOWER16((regs
[1]))); /* load lower half word in $1 */
811 int retval
= mips32_pracc_exec(ejtag_info
, code_len
, code
, 0, NULL
, 0, NULL
, 1);
816 int mips32_pracc_read_regs(struct mips_ejtag
*ejtag_info
, uint32_t *regs
)
818 static int cp0_read_code
[] = {
819 MIPS32_MFC0(2, 12, 0), /* move status to $2 */
820 MIPS32_MFLO(2), /* move lo to $2 */
821 MIPS32_MFHI(2), /* move hi to $2 */
822 MIPS32_MFC0(2, 8, 0), /* move badvaddr to $2 */
823 MIPS32_MFC0(2, 13, 0), /* move cause to $2 */
824 MIPS32_MFC0(2, 24, 0), /* move depc (pc) to $2 */
828 code
= malloc(49 * sizeof(uint32_t));
830 LOG_ERROR("Out of memory");
834 uint32_t *code_p
= code
;
836 *code_p
++ = MIPS32_MTC0(1, 31, 0), /* move $1 to COP0 DeSave */
837 *code_p
++ = MIPS32_LUI(1, PRACC_UPPER_BASE_ADDR
); /* $1 = MIP32_PRACC_BASE_ADDR */
839 for (int i
= 2; i
!= 32; i
++)
840 *code_p
++ = MIPS32_SW(i
, PRACC_OUT_OFFSET
+ (i
* 4), 1); /* store GPR's 2 to 31 */
842 for (int i
= 0; i
!= 6; i
++) {
843 *code_p
++ = cp0_read_code
[i
]; /* load COP0 needed registers to $2 */
844 *code_p
++ = MIPS32_SW(2, PRACC_OUT_OFFSET
+ (i
+ 32) * 4, 1); /* store COP0 registers from $2 to param out */
847 *code_p
++ = MIPS32_MFC0(2, 31, 0), /* move DeSave to $2, reg1 value */
848 *code_p
++ = MIPS32_SW(2, PRACC_OUT_OFFSET
+ 4, 1); /* store reg1 value from $2 to param out */
850 *code_p
++ = MIPS32_LW(2, PRACC_OUT_OFFSET
+ 8, 1); /* restore $2 from param out (singularity) */
851 *code_p
++ = MIPS32_B(NEG16(48)); /* b start */
852 *code_p
= MIPS32_MFC0(1, 31, 0); /* move COP0 DeSave to $1 */
854 int retval
= mips32_pracc_exec(ejtag_info
, 49, code
, 0, NULL
, MIPS32NUMCOREREGS
, regs
, 1);
860 /* fastdata upload/download requires an initialized working area
861 * to load the download code; it should not be called otherwise
862 * fetch order from the fastdata area
867 int mips32_pracc_fastdata_xfer(struct mips_ejtag
*ejtag_info
, struct working_area
*source
,
868 int write_t
, uint32_t addr
, int count
, uint32_t *buf
)
870 uint32_t handler_code
[] = {
871 /* caution when editing, table is modified below */
872 /* r15 points to the start of this code */
873 MIPS32_SW(8, MIPS32_FASTDATA_HANDLER_SIZE
- 4, 15),
874 MIPS32_SW(9, MIPS32_FASTDATA_HANDLER_SIZE
- 8, 15),
875 MIPS32_SW(10, MIPS32_FASTDATA_HANDLER_SIZE
- 12, 15),
876 MIPS32_SW(11, MIPS32_FASTDATA_HANDLER_SIZE
- 16, 15),
877 /* start of fastdata area in t0 */
878 MIPS32_LUI(8, UPPER16(MIPS32_PRACC_FASTDATA_AREA
)),
879 MIPS32_ORI(8, 8, LOWER16(MIPS32_PRACC_FASTDATA_AREA
)),
880 MIPS32_LW(9, 0, 8), /* start addr in t1 */
881 MIPS32_LW(10, 0, 8), /* end addr to t2 */
883 /* 8 */ MIPS32_LW(11, 0, 0), /* lw t3,[t8 | r9] */
884 /* 9 */ MIPS32_SW(11, 0, 0), /* sw t3,[r9 | r8] */
885 MIPS32_BNE(10, 9, NEG16(3)), /* bne $t2,t1,loop */
886 MIPS32_ADDI(9, 9, 4), /* addi t1,t1,4 */
888 MIPS32_LW(8, MIPS32_FASTDATA_HANDLER_SIZE
- 4, 15),
889 MIPS32_LW(9, MIPS32_FASTDATA_HANDLER_SIZE
- 8, 15),
890 MIPS32_LW(10, MIPS32_FASTDATA_HANDLER_SIZE
- 12, 15),
891 MIPS32_LW(11, MIPS32_FASTDATA_HANDLER_SIZE
- 16, 15),
893 MIPS32_LUI(15, UPPER16(MIPS32_PRACC_TEXT
)),
894 MIPS32_ORI(15, 15, LOWER16(MIPS32_PRACC_TEXT
)),
895 MIPS32_JR(15), /* jr start */
896 MIPS32_MFC0(15, 31, 0), /* move COP0 DeSave to $15 */
899 uint32_t jmp_code
[] = {
900 MIPS32_MTC0(15, 31, 0), /* move $15 to COP0 DeSave */
901 /* 1 */ MIPS32_LUI(15, 0), /* addr of working area added below */
902 /* 2 */ MIPS32_ORI(15, 15, 0), /* addr of working area added below */
903 MIPS32_JR(15), /* jump to ram program */
908 uint32_t val
, ejtag_ctrl
, address
;
910 if (source
->size
< MIPS32_FASTDATA_HANDLER_SIZE
)
911 return ERROR_TARGET_RESOURCE_NOT_AVAILABLE
;
914 handler_code
[8] = MIPS32_LW(11, 0, 8); /* load data from probe at fastdata area */
915 handler_code
[9] = MIPS32_SW(11, 0, 9); /* store data to RAM @ r9 */
917 handler_code
[8] = MIPS32_LW(11, 0, 9); /* load data from RAM @ r9 */
918 handler_code
[9] = MIPS32_SW(11, 0, 8); /* store data to probe at fastdata area */
921 /* write program into RAM */
922 if (write_t
!= ejtag_info
->fast_access_save
) {
923 mips32_pracc_write_mem_generic(ejtag_info
, source
->address
, 4, ARRAY_SIZE(handler_code
), handler_code
);
924 /* save previous operation to speed to any consecutive read/writes */
925 ejtag_info
->fast_access_save
= write_t
;
928 LOG_DEBUG("%s using 0x%.8" PRIx32
" for write handler", __func__
, source
->address
);
930 jmp_code
[1] |= UPPER16(source
->address
);
931 jmp_code
[2] |= LOWER16(source
->address
);
933 for (i
= 0; i
< (int) ARRAY_SIZE(jmp_code
); i
++) {
934 retval
= wait_for_pracc_rw(ejtag_info
, &ejtag_ctrl
);
935 if (retval
!= ERROR_OK
)
938 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_DATA
);
939 mips_ejtag_drscan_32_out(ejtag_info
, jmp_code
[i
]);
941 /* Clear the access pending bit (let the processor eat!) */
942 ejtag_ctrl
= ejtag_info
->ejtag_ctrl
& ~EJTAG_CTRL_PRACC
;
943 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_CONTROL
);
944 mips_ejtag_drscan_32_out(ejtag_info
, ejtag_ctrl
);
947 /* wait PrAcc pending bit for FASTDATA write */
948 retval
= wait_for_pracc_rw(ejtag_info
, &ejtag_ctrl
);
949 if (retval
!= ERROR_OK
)
952 /* next fetch to dmseg should be in FASTDATA_AREA, check */
954 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_ADDRESS
);
955 retval
= mips_ejtag_drscan_32(ejtag_info
, &address
);
956 if (retval
!= ERROR_OK
)
959 if (address
!= MIPS32_PRACC_FASTDATA_AREA
)
962 /* Send the load start address */
964 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_FASTDATA
);
965 mips_ejtag_fastdata_scan(ejtag_info
, 1, &val
);
967 retval
= wait_for_pracc_rw(ejtag_info
, &ejtag_ctrl
);
968 if (retval
!= ERROR_OK
)
971 /* Send the load end address */
972 val
= addr
+ (count
- 1) * 4;
973 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_FASTDATA
);
974 mips_ejtag_fastdata_scan(ejtag_info
, 1, &val
);
976 for (i
= 0; i
< count
; i
++) {
977 retval
= mips_ejtag_fastdata_scan(ejtag_info
, write_t
, buf
++);
978 if (retval
!= ERROR_OK
)
982 retval
= jtag_execute_queue();
983 if (retval
!= ERROR_OK
) {
984 LOG_ERROR("fastdata load failed");
988 retval
= wait_for_pracc_rw(ejtag_info
, &ejtag_ctrl
);
989 if (retval
!= ERROR_OK
)
993 mips_ejtag_set_instr(ejtag_info
, EJTAG_INST_ADDRESS
);
994 retval
= mips_ejtag_drscan_32(ejtag_info
, &address
);
995 if (retval
!= ERROR_OK
)
998 if (address
!= MIPS32_PRACC_TEXT
)
999 LOG_ERROR("mini program did not return to start");
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