ARM: switch target_to_armv4_5() to target_to_arm()
[openocd/jflash.git] / src / svf / svf.c
blobe6d842b7a5edb2175837f3c5454b95a65b172d73
1 /*
2 * Copyright (C) 2009 by Simon Qian
3 * SimonQian@SimonQian.com
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 along
16 * with this program; if not, write to the Free Software Foundation, Inc.,
17 * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
21 /* The specification for SVF is available here:
22 * http://www.asset-intertech.com/support/svf.pdf
23 * Below, this document is refered to as the "SVF spec".
25 * The specification for XSVF is available here:
26 * http://www.xilinx.com/support/documentation/application_notes/xapp503.pdf
27 * Below, this document is refered to as the "XSVF spec".
30 #ifdef HAVE_CONFIG_H
31 #include "config.h"
32 #endif
34 #include <jtag/jtag.h>
35 #include "svf.h"
36 #include <helper/time_support.h>
39 // SVF command
40 typedef enum
42 ENDDR,
43 ENDIR,
44 FREQUENCY,
45 HDR,
46 HIR,
47 PIO,
48 PIOMAP,
49 RUNTEST,
50 SDR,
51 SIR,
52 STATE,
53 TDR,
54 TIR,
55 TRST,
56 }svf_command_t;
58 static const char *svf_command_name[14] =
60 "ENDDR",
61 "ENDIR",
62 "FREQUENCY",
63 "HDR",
64 "HIR",
65 "PIO",
66 "PIOMAP",
67 "RUNTEST",
68 "SDR",
69 "SIR",
70 "STATE",
71 "TDR",
72 "TIR",
73 "TRST"
76 typedef enum
78 TRST_ON,
79 TRST_OFF,
80 TRST_Z,
81 TRST_ABSENT
82 }trst_mode_t;
84 static const char *svf_trst_mode_name[4] =
86 "ON",
87 "OFF",
88 "Z",
89 "ABSENT"
92 struct svf_statemove
94 tap_state_t from;
95 tap_state_t to;
96 uint32_t num_of_moves;
97 tap_state_t paths[8];
101 * These paths are from the SVF specification for the STATE command, to be
102 * used when the STATE command only includes the final state. The first
103 * element of the path is the "from" (current) state, and the last one is
104 * the "to" (target) state.
106 * All specified paths are the shortest ones in the JTAG spec, and are thus
107 * not (!!) exact matches for the paths used elsewhere in OpenOCD. Note
108 * that PAUSE-to-PAUSE transitions all go through UPDATE and then CAPTURE,
109 * which has specific effects on the various registers; they are not NOPs.
111 * Paths to RESET are disabled here. As elsewhere in OpenOCD, and in XSVF
112 * and many SVF implementations, we don't want to risk missing that state.
113 * To get to RESET, always we ignore the current state.
115 static const struct svf_statemove svf_statemoves[] =
117 // from to num_of_moves, paths[8]
118 // {TAP_RESET, TAP_RESET, 1, {TAP_RESET}},
119 {TAP_RESET, TAP_IDLE, 2, {TAP_RESET, TAP_IDLE}},
120 {TAP_RESET, TAP_DRPAUSE, 6, {TAP_RESET, TAP_IDLE, TAP_DRSELECT, TAP_DRCAPTURE, TAP_DREXIT1, TAP_DRPAUSE}},
121 {TAP_RESET, TAP_IRPAUSE, 7, {TAP_RESET, TAP_IDLE, TAP_DRSELECT, TAP_IRSELECT, TAP_IRCAPTURE, TAP_IREXIT1, TAP_IRPAUSE}},
123 // {TAP_IDLE, TAP_RESET, 4, {TAP_IDLE, TAP_DRSELECT, TAP_IRSELECT, TAP_RESET}},
124 {TAP_IDLE, TAP_IDLE, 1, {TAP_IDLE}},
125 {TAP_IDLE, TAP_DRPAUSE, 5, {TAP_IDLE, TAP_DRSELECT, TAP_DRCAPTURE, TAP_DREXIT1, TAP_DRPAUSE}},
126 {TAP_IDLE, TAP_IRPAUSE, 6, {TAP_IDLE, TAP_DRSELECT, TAP_IRSELECT, TAP_IRCAPTURE, TAP_IREXIT1, TAP_IRPAUSE}},
128 // {TAP_DRPAUSE, TAP_RESET, 6, {TAP_DRPAUSE, TAP_DREXIT2, TAP_DRUPDATE, TAP_DRSELECT, TAP_IRSELECT, TAP_RESET}},
129 {TAP_DRPAUSE, TAP_IDLE, 4, {TAP_DRPAUSE, TAP_DREXIT2, TAP_DRUPDATE, TAP_IDLE}},
130 {TAP_DRPAUSE, TAP_DRPAUSE, 7, {TAP_DRPAUSE, TAP_DREXIT2, TAP_DRUPDATE, TAP_DRSELECT, TAP_DRCAPTURE, TAP_DREXIT1, TAP_DRPAUSE}},
131 {TAP_DRPAUSE, TAP_IRPAUSE, 8, {TAP_DRPAUSE, TAP_DREXIT2, TAP_DRUPDATE, TAP_DRSELECT, TAP_IRSELECT, TAP_IRCAPTURE, TAP_IREXIT1, TAP_IRPAUSE}},
133 // {TAP_IRPAUSE, TAP_RESET, 6, {TAP_IRPAUSE, TAP_IREXIT2, TAP_IRUPDATE, TAP_DRSELECT, TAP_IRSELECT, TAP_RESET}},
134 {TAP_IRPAUSE, TAP_IDLE, 4, {TAP_IRPAUSE, TAP_IREXIT2, TAP_IRUPDATE, TAP_IDLE}},
135 {TAP_IRPAUSE, TAP_DRPAUSE, 7, {TAP_IRPAUSE, TAP_IREXIT2, TAP_IRUPDATE, TAP_DRSELECT, TAP_DRCAPTURE, TAP_DREXIT1, TAP_DRPAUSE}},
136 {TAP_IRPAUSE, TAP_IRPAUSE, 8, {TAP_IRPAUSE, TAP_IREXIT2, TAP_IRUPDATE, TAP_DRSELECT, TAP_IRSELECT, TAP_IRCAPTURE, TAP_IREXIT1, TAP_IRPAUSE}}
140 #define XXR_TDI (1 << 0)
141 #define XXR_TDO (1 << 1)
142 #define XXR_MASK (1 << 2)
143 #define XXR_SMASK (1 << 3)
144 struct svf_xxr_para
146 int len;
147 int data_mask;
148 uint8_t *tdi;
149 uint8_t *tdo;
150 uint8_t *mask;
151 uint8_t *smask;
154 struct svf_para
156 float frequency;
157 tap_state_t ir_end_state;
158 tap_state_t dr_end_state;
159 tap_state_t runtest_run_state;
160 tap_state_t runtest_end_state;
161 trst_mode_t trst_mode;
163 struct svf_xxr_para hir_para;
164 struct svf_xxr_para hdr_para;
165 struct svf_xxr_para tir_para;
166 struct svf_xxr_para tdr_para;
167 struct svf_xxr_para sir_para;
168 struct svf_xxr_para sdr_para;
171 static struct svf_para svf_para;
172 static const struct svf_para svf_para_init =
174 // frequency, ir_end_state, dr_end_state, runtest_run_state, runtest_end_state, trst_mode
175 0, TAP_IDLE, TAP_IDLE, TAP_IDLE, TAP_IDLE, TRST_Z,
176 // hir_para
177 // {len, data_mask, tdi, tdo, mask, smask},
178 {0, 0, NULL, NULL, NULL, NULL},
179 // hdr_para
180 // {len, data_mask, tdi, tdo, mask, smask},
181 {0, 0, NULL, NULL, NULL, NULL},
182 // tir_para
183 // {len, data_mask, tdi, tdo, mask, smask},
184 {0, 0, NULL, NULL, NULL, NULL},
185 // tdr_para
186 // {len, data_mask, tdi, tdo, mask, smask},
187 {0, 0, NULL, NULL, NULL, NULL},
188 // sir_para
189 // {len, data_mask, tdi, tdo, mask, smask},
190 {0, 0, NULL, NULL, NULL, NULL},
191 // sdr_para
192 // {len, data_mask, tdi, tdo, mask, smask},
193 {0, 0, NULL, NULL, NULL, NULL},
196 struct svf_check_tdo_para
198 int line_num; // used to record line number of the check operation
199 // so more information could be printed
200 int enabled; // check is enabled or not
201 int buffer_offset; // buffer_offset to buffers
202 int bit_len; // bit length to check
205 #define SVF_CHECK_TDO_PARA_SIZE 1024
206 static struct svf_check_tdo_para *svf_check_tdo_para = NULL;
207 static int svf_check_tdo_para_index = 0;
209 static int svf_read_command_from_file(int fd);
210 static int svf_check_tdo(void);
211 static int svf_add_check_para(uint8_t enabled, int buffer_offset, int bit_len);
212 static int svf_run_command(struct command_context *cmd_ctx, char *cmd_str);
214 static int svf_fd = 0;
215 static char *svf_command_buffer = NULL;
216 static int svf_command_buffer_size = 0;
217 static int svf_line_number = 1;
219 static struct jtag_tap *tap = NULL;
221 #define SVF_MAX_BUFFER_SIZE_TO_COMMIT (4 * 1024)
222 static uint8_t *svf_tdi_buffer = NULL, *svf_tdo_buffer = NULL, *svf_mask_buffer = NULL;
223 static int svf_buffer_index = 0, svf_buffer_size = 0;
224 static int svf_quiet = 0;
227 static void svf_free_xxd_para(struct svf_xxr_para *para)
229 if (NULL != para)
231 if (para->tdi != NULL)
233 free(para->tdi);
234 para->tdi = NULL;
236 if (para->tdo != NULL)
238 free(para->tdo);
239 para->tdo = NULL;
241 if (para->mask != NULL)
243 free(para->mask);
244 para->mask = NULL;
246 if (para->smask != NULL)
248 free(para->smask);
249 para->smask = NULL;
254 static unsigned svf_get_mask_u32(int bitlen)
256 uint32_t bitmask;
258 if (bitlen < 0)
260 bitmask = 0;
262 else if (bitlen >= 32)
264 bitmask = 0xFFFFFFFF;
266 else
268 bitmask = (1 << bitlen) - 1;
271 return bitmask;
274 int svf_add_statemove(tap_state_t state_to)
276 tap_state_t state_from = cmd_queue_cur_state;
277 uint8_t index;
279 /* when resetting, be paranoid and ignore current state */
280 if (state_to == TAP_RESET) {
281 jtag_add_tlr();
282 return ERROR_OK;
285 for (index = 0; index < ARRAY_SIZE(svf_statemoves); index++)
287 if ((svf_statemoves[index].from == state_from)
288 && (svf_statemoves[index].to == state_to))
290 /* recorded path includes current state ... avoid extra TCKs! */
291 if (svf_statemoves[index].num_of_moves > 1)
292 jtag_add_pathmove(svf_statemoves[index].num_of_moves - 1,
293 svf_statemoves[index].paths + 1);
294 else
295 jtag_add_pathmove(svf_statemoves[index].num_of_moves,
296 svf_statemoves[index].paths);
297 return ERROR_OK;
300 LOG_ERROR("SVF: can not move to %s", tap_state_name(state_to));
301 return ERROR_FAIL;
304 COMMAND_HANDLER(handle_svf_command)
306 #define SVF_NUM_OF_OPTIONS 1
307 int command_num = 0;
308 int ret = ERROR_OK;
309 long long time_ago;
311 if ((CMD_ARGC < 1) || (CMD_ARGC > (1 + SVF_NUM_OF_OPTIONS)))
313 command_print(CMD_CTX, "usage: svf <file> [quiet]");
314 return ERROR_FAIL;
317 // parse variant
318 svf_quiet = 0;
319 for (unsigned i = 1; i < CMD_ARGC; i++)
321 if (!strcmp(CMD_ARGV[i], "quiet"))
323 svf_quiet = 1;
325 else
327 LOG_ERROR("unknown variant for svf: %s", CMD_ARGV[i]);
329 // no need to free anything now
330 return ERROR_FAIL;
334 if ((svf_fd = open(CMD_ARGV[0], O_RDONLY)) < 0)
336 command_print(CMD_CTX, "file \"%s\" not found", CMD_ARGV[0]);
338 // no need to free anything now
339 return ERROR_FAIL;
342 LOG_USER("svf processing file: \"%s\"", CMD_ARGV[0]);
344 // get time
345 time_ago = timeval_ms();
347 // init
348 svf_line_number = 1;
349 svf_command_buffer_size = 0;
351 svf_check_tdo_para_index = 0;
352 svf_check_tdo_para = malloc(sizeof(struct svf_check_tdo_para) * SVF_CHECK_TDO_PARA_SIZE);
353 if (NULL == svf_check_tdo_para)
355 LOG_ERROR("not enough memory");
356 ret = ERROR_FAIL;
357 goto free_all;
360 svf_buffer_index = 0;
361 // double the buffer size
362 // in case current command cannot be commited, and next command is a bit scan command
363 // here is 32K bits for this big scan command, it should be enough
364 // buffer will be reallocated if buffer size is not enough
365 svf_tdi_buffer = (uint8_t *)malloc(2 * SVF_MAX_BUFFER_SIZE_TO_COMMIT);
366 if (NULL == svf_tdi_buffer)
368 LOG_ERROR("not enough memory");
369 ret = ERROR_FAIL;
370 goto free_all;
372 svf_tdo_buffer = (uint8_t *)malloc(2 * SVF_MAX_BUFFER_SIZE_TO_COMMIT);
373 if (NULL == svf_tdo_buffer)
375 LOG_ERROR("not enough memory");
376 ret = ERROR_FAIL;
377 goto free_all;
379 svf_mask_buffer = (uint8_t *)malloc(2 * SVF_MAX_BUFFER_SIZE_TO_COMMIT);
380 if (NULL == svf_mask_buffer)
382 LOG_ERROR("not enough memory");
383 ret = ERROR_FAIL;
384 goto free_all;
386 svf_buffer_size = 2 * SVF_MAX_BUFFER_SIZE_TO_COMMIT;
388 memcpy(&svf_para, &svf_para_init, sizeof(svf_para));
390 // TAP_RESET
391 jtag_add_tlr();
393 while (ERROR_OK == svf_read_command_from_file(svf_fd))
395 if (ERROR_OK != svf_run_command(CMD_CTX, svf_command_buffer))
397 LOG_ERROR("fail to run command at line %d", svf_line_number);
398 ret = ERROR_FAIL;
399 break;
401 command_num++;
403 if (ERROR_OK != jtag_execute_queue())
405 ret = ERROR_FAIL;
407 else if (ERROR_OK != svf_check_tdo())
409 ret = ERROR_FAIL;
412 // print time
413 command_print(CMD_CTX, "%lld ms used", timeval_ms() - time_ago);
415 free_all:
417 close(svf_fd);
418 svf_fd = 0;
420 // free buffers
421 if (svf_command_buffer)
423 free(svf_command_buffer);
424 svf_command_buffer = NULL;
425 svf_command_buffer_size = 0;
427 if (svf_check_tdo_para)
429 free(svf_check_tdo_para);
430 svf_check_tdo_para = NULL;
431 svf_check_tdo_para_index = 0;
433 if (svf_tdi_buffer)
435 free(svf_tdi_buffer);
436 svf_tdi_buffer = NULL;
438 if (svf_tdo_buffer)
440 free(svf_tdo_buffer);
441 svf_tdo_buffer = NULL;
443 if (svf_mask_buffer)
445 free(svf_mask_buffer);
446 svf_mask_buffer = NULL;
448 svf_buffer_index = 0;
449 svf_buffer_size = 0;
451 svf_free_xxd_para(&svf_para.hdr_para);
452 svf_free_xxd_para(&svf_para.hir_para);
453 svf_free_xxd_para(&svf_para.tdr_para);
454 svf_free_xxd_para(&svf_para.tir_para);
455 svf_free_xxd_para(&svf_para.sdr_para);
456 svf_free_xxd_para(&svf_para.sir_para);
458 if (ERROR_OK == ret)
460 command_print(CMD_CTX, "svf file programmed successfully for %d commands", command_num);
462 else
464 command_print(CMD_CTX, "svf file programmed failed");
467 return ret;
470 #define SVFP_CMD_INC_CNT 1024
471 static int svf_read_command_from_file(int fd)
473 char ch, *tmp_buffer = NULL;
474 int cmd_pos = 0, cmd_ok = 0, slash = 0, comment = 0;
476 while (!cmd_ok && (read(fd, &ch, 1) > 0))
478 switch (ch)
480 case '!':
481 slash = 0;
482 comment = 1;
483 break;
484 case '/':
485 if (++slash == 2)
487 comment = 1;
489 break;
490 case ';':
491 slash = 0;
492 if (!comment)
494 cmd_ok = 1;
496 break;
497 case '\n':
498 svf_line_number++;
499 case '\r':
500 slash = 0;
501 comment = 0;
502 break;
503 default:
504 if (!comment)
506 if (cmd_pos >= svf_command_buffer_size - 1)
508 tmp_buffer = (char*)malloc(svf_command_buffer_size + SVFP_CMD_INC_CNT); // 1 more byte for '\0'
509 if (NULL == tmp_buffer)
511 LOG_ERROR("not enough memory");
512 return ERROR_FAIL;
514 if (svf_command_buffer_size > 0)
516 memcpy(tmp_buffer, svf_command_buffer, svf_command_buffer_size);
518 if (svf_command_buffer != NULL)
520 free(svf_command_buffer);
522 svf_command_buffer = tmp_buffer;
523 svf_command_buffer_size += SVFP_CMD_INC_CNT;
524 tmp_buffer = NULL;
526 svf_command_buffer[cmd_pos++] = (char)toupper(ch);
528 break;
532 if (cmd_ok)
534 svf_command_buffer[cmd_pos] = '\0';
535 return ERROR_OK;
537 else
539 return ERROR_FAIL;
543 static int svf_parse_cmd_string(char *str, int len, char **argus, int *num_of_argu)
545 int pos = 0, num = 0, space_found = 1;
547 while (pos < len)
549 switch (str[pos])
551 case '\n':
552 case '\r':
553 case '!':
554 case '/':
555 LOG_ERROR("fail to parse svf command");
556 return ERROR_FAIL;
557 break;
558 case ' ':
559 space_found = 1;
560 str[pos] = '\0';
561 break;
562 default:
563 if (space_found)
565 argus[num++] = &str[pos];
566 space_found = 0;
568 break;
570 pos++;
573 *num_of_argu = num;
575 return ERROR_OK;
578 bool svf_tap_state_is_stable(tap_state_t state)
580 return (TAP_RESET == state) || (TAP_IDLE == state)
581 || (TAP_DRPAUSE == state) || (TAP_IRPAUSE == state);
584 static int svf_find_string_in_array(char *str, char **strs, int num_of_element)
586 int i;
588 for (i = 0; i < num_of_element; i++)
590 if (!strcmp(str, strs[i]))
592 return i;
595 return 0xFF;
598 static int svf_adjust_array_length(uint8_t **arr, int orig_bit_len, int new_bit_len)
600 int new_byte_len = (new_bit_len + 7) >> 3;
602 if ((NULL == *arr) || (((orig_bit_len + 7) >> 3) < ((new_bit_len + 7) >> 3)))
604 if (*arr != NULL)
606 free(*arr);
607 *arr = NULL;
609 *arr = (uint8_t*)malloc(new_byte_len);
610 if (NULL == *arr)
612 LOG_ERROR("not enough memory");
613 return ERROR_FAIL;
615 memset(*arr, 0, new_byte_len);
617 return ERROR_OK;
620 static int svf_copy_hexstring_to_binary(char *str, uint8_t **bin, int orig_bit_len, int bit_len)
622 int i, str_len = strlen(str), str_hbyte_len = (bit_len + 3) >> 2;
623 uint8_t ch = 0;
625 if (ERROR_OK != svf_adjust_array_length(bin, orig_bit_len, bit_len))
627 LOG_ERROR("fail to adjust length of array");
628 return ERROR_FAIL;
631 for (i = 0; i < str_hbyte_len; i++)
633 ch = 0;
634 while (str_len > 0)
636 ch = str[--str_len];
638 if (!isblank(ch))
640 if ((ch >= '0') && (ch <= '9'))
642 ch = ch - '0';
643 break;
645 else if ((ch >= 'A') && (ch <= 'F'))
647 ch = ch - 'A' + 10;
648 break;
650 else
652 LOG_ERROR("invalid hex string");
653 return ERROR_FAIL;
657 ch = 0;
660 // write bin
661 if (i % 2)
663 // MSB
664 (*bin)[i / 2] |= ch << 4;
666 else
668 // LSB
669 (*bin)[i / 2] = 0;
670 (*bin)[i / 2] |= ch;
674 // consume optional leading '0' characters
675 while (str_len > 0 && str[str_len - 1] == '0')
676 str_len--;
678 // check valid
679 if (str_len > 0 || (ch & ~((2 << ((bit_len - 1) % 4)) - 1)) != 0)
681 LOG_ERROR("value execeeds length");
682 return ERROR_FAIL;
685 return ERROR_OK;
688 static int svf_check_tdo(void)
690 int i, len, index;
692 for (i = 0; i < svf_check_tdo_para_index; i++)
694 index = svf_check_tdo_para[i].buffer_offset;
695 len = svf_check_tdo_para[i].bit_len;
696 if ((svf_check_tdo_para[i].enabled)
697 && buf_cmp_mask(&svf_tdi_buffer[index], &svf_tdo_buffer[index], &svf_mask_buffer[index], len))
699 unsigned bitmask;
700 unsigned received, expected, tapmask;
701 bitmask = svf_get_mask_u32(svf_check_tdo_para[i].bit_len);
703 memcpy(&received, svf_tdi_buffer + index, sizeof(unsigned));
704 memcpy(&expected, svf_tdo_buffer + index, sizeof(unsigned));
705 memcpy(&tapmask, svf_mask_buffer + index, sizeof(unsigned));
706 LOG_ERROR("tdo check error at line %d",
707 svf_check_tdo_para[i].line_num);
708 LOG_ERROR("read = 0x%X, want = 0x%X, mask = 0x%X",
709 received & bitmask,
710 expected & bitmask,
711 tapmask & bitmask);
712 return ERROR_FAIL;
715 svf_check_tdo_para_index = 0;
717 return ERROR_OK;
720 static int svf_add_check_para(uint8_t enabled, int buffer_offset, int bit_len)
722 if (svf_check_tdo_para_index >= SVF_CHECK_TDO_PARA_SIZE)
724 LOG_ERROR("toooooo many operation undone");
725 return ERROR_FAIL;
728 svf_check_tdo_para[svf_check_tdo_para_index].line_num = svf_line_number;
729 svf_check_tdo_para[svf_check_tdo_para_index].bit_len = bit_len;
730 svf_check_tdo_para[svf_check_tdo_para_index].enabled = enabled;
731 svf_check_tdo_para[svf_check_tdo_para_index].buffer_offset = buffer_offset;
732 svf_check_tdo_para_index++;
734 return ERROR_OK;
737 static int svf_execute_tap(void)
739 if (ERROR_OK != jtag_execute_queue())
741 return ERROR_FAIL;
743 else if (ERROR_OK != svf_check_tdo())
745 return ERROR_FAIL;
748 svf_buffer_index = 0;
750 return ERROR_OK;
753 static int svf_run_command(struct command_context *cmd_ctx, char *cmd_str)
755 char *argus[256], command;
756 int num_of_argu = 0, i;
758 // tmp variable
759 int i_tmp;
761 // for RUNTEST
762 int run_count;
763 float min_time, max_time;
764 // for XXR
765 struct svf_xxr_para *xxr_para_tmp;
766 uint8_t **pbuffer_tmp;
767 struct scan_field field;
768 // for STATE
769 tap_state_t *path = NULL, state;
771 if (!svf_quiet)
773 LOG_USER("%s", svf_command_buffer);
776 if (ERROR_OK != svf_parse_cmd_string(cmd_str, strlen(cmd_str), argus, &num_of_argu))
778 return ERROR_FAIL;
781 /* NOTE: we're a bit loose here, because we ignore case in
782 * TAP state names (instead of insisting on uppercase).
785 command = svf_find_string_in_array(argus[0],
786 (char **)svf_command_name, ARRAY_SIZE(svf_command_name));
787 switch (command)
789 case ENDDR:
790 case ENDIR:
791 if (num_of_argu != 2)
793 LOG_ERROR("invalid parameter of %s", argus[0]);
794 return ERROR_FAIL;
797 i_tmp = tap_state_by_name(argus[1]);
799 if (svf_tap_state_is_stable(i_tmp))
801 if (command == ENDIR)
803 svf_para.ir_end_state = i_tmp;
804 LOG_DEBUG("\tIR end_state = %s",
805 tap_state_name(i_tmp));
807 else
809 svf_para.dr_end_state = i_tmp;
810 LOG_DEBUG("\tDR end_state = %s",
811 tap_state_name(i_tmp));
814 else
816 LOG_ERROR("%s: %s is not a stable state",
817 argus[0], argus[1]);
818 return ERROR_FAIL;
820 break;
821 case FREQUENCY:
822 if ((num_of_argu != 1) && (num_of_argu != 3))
824 LOG_ERROR("invalid parameter of %s", argus[0]);
825 return ERROR_FAIL;
827 if (1 == num_of_argu)
829 // TODO: set jtag speed to full speed
830 svf_para.frequency = 0;
832 else
834 if (strcmp(argus[2], "HZ"))
836 LOG_ERROR("HZ not found in FREQUENCY command");
837 return ERROR_FAIL;
839 if (ERROR_OK != svf_execute_tap())
841 return ERROR_FAIL;
843 svf_para.frequency = atof(argus[1]);
844 // TODO: set jtag speed to
845 if (svf_para.frequency > 0)
847 command_run_linef(cmd_ctx, "jtag_khz %d", (int)svf_para.frequency / 1000);
848 LOG_DEBUG("\tfrequency = %f", svf_para.frequency);
851 break;
852 case HDR:
853 xxr_para_tmp = &svf_para.hdr_para;
854 goto XXR_common;
855 case HIR:
856 xxr_para_tmp = &svf_para.hir_para;
857 goto XXR_common;
858 case TDR:
859 xxr_para_tmp = &svf_para.tdr_para;
860 goto XXR_common;
861 case TIR:
862 xxr_para_tmp = &svf_para.tir_para;
863 goto XXR_common;
864 case SDR:
865 xxr_para_tmp = &svf_para.sdr_para;
866 goto XXR_common;
867 case SIR:
868 xxr_para_tmp = &svf_para.sir_para;
869 goto XXR_common;
870 XXR_common:
871 // XXR length [TDI (tdi)] [TDO (tdo)][MASK (mask)] [SMASK (smask)]
872 if ((num_of_argu > 10) || (num_of_argu % 2))
874 LOG_ERROR("invalid parameter of %s", argus[0]);
875 return ERROR_FAIL;
877 i_tmp = xxr_para_tmp->len;
878 xxr_para_tmp->len = atoi(argus[1]);
879 LOG_DEBUG("\tlength = %d", xxr_para_tmp->len);
880 xxr_para_tmp->data_mask = 0;
881 for (i = 2; i < num_of_argu; i += 2)
883 if ((strlen(argus[i + 1]) < 3) || (argus[i + 1][0] != '(') || (argus[i + 1][strlen(argus[i + 1]) - 1] != ')'))
885 LOG_ERROR("data section error");
886 return ERROR_FAIL;
888 argus[i + 1][strlen(argus[i + 1]) - 1] = '\0';
889 // TDI, TDO, MASK, SMASK
890 if (!strcmp(argus[i], "TDI"))
892 // TDI
893 pbuffer_tmp = &xxr_para_tmp->tdi;
894 xxr_para_tmp->data_mask |= XXR_TDI;
896 else if (!strcmp(argus[i], "TDO"))
898 // TDO
899 pbuffer_tmp = &xxr_para_tmp->tdo;
900 xxr_para_tmp->data_mask |= XXR_TDO;
902 else if (!strcmp(argus[i], "MASK"))
904 // MASK
905 pbuffer_tmp = &xxr_para_tmp->mask;
906 xxr_para_tmp->data_mask |= XXR_MASK;
908 else if (!strcmp(argus[i], "SMASK"))
910 // SMASK
911 pbuffer_tmp = &xxr_para_tmp->smask;
912 xxr_para_tmp->data_mask |= XXR_SMASK;
914 else
916 LOG_ERROR("unknow parameter: %s", argus[i]);
917 return ERROR_FAIL;
919 if (ERROR_OK != svf_copy_hexstring_to_binary(&argus[i + 1][1], pbuffer_tmp, i_tmp, xxr_para_tmp->len))
921 LOG_ERROR("fail to parse hex value");
922 return ERROR_FAIL;
924 LOG_DEBUG("\t%s = 0x%X", argus[i], (**(int**)pbuffer_tmp) & svf_get_mask_u32(xxr_para_tmp->len));
926 // If a command changes the length of the last scan of the same type and the MASK parameter is absent,
927 // the mask pattern used is all cares
928 if (!(xxr_para_tmp->data_mask & XXR_MASK) && (i_tmp != xxr_para_tmp->len))
930 // MASK not defined and length changed
931 if (ERROR_OK != svf_adjust_array_length(&xxr_para_tmp->mask, i_tmp, xxr_para_tmp->len))
933 LOG_ERROR("fail to adjust length of array");
934 return ERROR_FAIL;
936 buf_set_ones(xxr_para_tmp->mask, xxr_para_tmp->len);
938 // If TDO is absent, no comparison is needed, set the mask to 0
939 if (!(xxr_para_tmp->data_mask & XXR_TDO))
941 if (NULL == xxr_para_tmp->tdo)
943 if (ERROR_OK != svf_adjust_array_length(&xxr_para_tmp->tdo, i_tmp, xxr_para_tmp->len))
945 LOG_ERROR("fail to adjust length of array");
946 return ERROR_FAIL;
949 if (NULL == xxr_para_tmp->mask)
951 if (ERROR_OK != svf_adjust_array_length(&xxr_para_tmp->mask, i_tmp, xxr_para_tmp->len))
953 LOG_ERROR("fail to adjust length of array");
954 return ERROR_FAIL;
957 memset(xxr_para_tmp->mask, 0, (xxr_para_tmp->len + 7) >> 3);
959 // do scan if necessary
960 if (SDR == command)
962 // check buffer size first, reallocate if necessary
963 i = svf_para.hdr_para.len + svf_para.sdr_para.len + svf_para.tdr_para.len;
964 if ((svf_buffer_size - svf_buffer_index) < ((i + 7) >> 3))
966 #if 1
967 // simply print error message
968 LOG_ERROR("buffer is not enough, report to author");
969 return ERROR_FAIL;
970 #else
971 uint8_t *buffer_tmp;
973 // reallocate buffer
974 buffer_tmp = (uint8_t *)malloc(svf_buffer_index + ((i + 7) >> 3));
975 if (NULL == buffer_tmp)
977 LOG_ERROR("not enough memory");
978 return ERROR_FAIL;
980 memcpy(buffer_tmp, svf_tdi_buffer, svf_buffer_index);
981 // svf_tdi_buffer isn't NULL here
982 free(svf_tdi_buffer);
983 svf_tdi_buffer = buffer_tmp;
985 buffer_tmp = (uint8_t *)malloc(svf_buffer_index + ((i + 7) >> 3));
986 if (NULL == buffer_tmp)
988 LOG_ERROR("not enough memory");
989 return ERROR_FAIL;
991 memcpy(buffer_tmp, svf_tdo_buffer, svf_buffer_index);
992 // svf_tdo_buffer isn't NULL here
993 free(svf_tdo_buffer);
994 svf_tdo_buffer = buffer_tmp;
996 buffer_tmp = (uint8_t *)malloc(svf_buffer_index + ((i + 7) >> 3));
997 if (NULL == buffer_tmp)
999 LOG_ERROR("not enough memory");
1000 return ERROR_FAIL;
1002 memcpy(buffer_tmp, svf_mask_buffer, svf_buffer_index);
1003 // svf_mask_buffer isn't NULL here
1004 free(svf_mask_buffer);
1005 svf_mask_buffer = buffer_tmp;
1007 buffer_tmp = NULL;
1008 svf_buffer_size = svf_buffer_index + ((i + 7) >> 3);
1009 #endif
1012 // assemble dr data
1013 i = 0;
1014 buf_set_buf(svf_para.hdr_para.tdi, 0, &svf_tdi_buffer[svf_buffer_index], i, svf_para.hdr_para.len);
1015 i += svf_para.hdr_para.len;
1016 buf_set_buf(svf_para.sdr_para.tdi, 0, &svf_tdi_buffer[svf_buffer_index], i, svf_para.sdr_para.len);
1017 i += svf_para.sdr_para.len;
1018 buf_set_buf(svf_para.tdr_para.tdi, 0, &svf_tdi_buffer[svf_buffer_index], i, svf_para.tdr_para.len);
1019 i += svf_para.tdr_para.len;
1021 // add check data
1022 if (svf_para.sdr_para.data_mask & XXR_TDO)
1024 // assemble dr mask data
1025 i = 0;
1026 buf_set_buf(svf_para.hdr_para.mask, 0, &svf_mask_buffer[svf_buffer_index], i, svf_para.hdr_para.len);
1027 i += svf_para.hdr_para.len;
1028 buf_set_buf(svf_para.sdr_para.mask, 0, &svf_mask_buffer[svf_buffer_index], i, svf_para.sdr_para.len);
1029 i += svf_para.sdr_para.len;
1030 buf_set_buf(svf_para.tdr_para.mask, 0, &svf_mask_buffer[svf_buffer_index], i, svf_para.tdr_para.len);
1031 i += svf_para.tdr_para.len;
1032 // assemble dr check data
1033 i = 0;
1034 buf_set_buf(svf_para.hdr_para.tdo, 0, &svf_tdo_buffer[svf_buffer_index], i, svf_para.hdr_para.len);
1035 i += svf_para.hdr_para.len;
1036 buf_set_buf(svf_para.sdr_para.tdo, 0, &svf_tdo_buffer[svf_buffer_index], i, svf_para.sdr_para.len);
1037 i += svf_para.sdr_para.len;
1038 buf_set_buf(svf_para.tdr_para.tdo, 0, &svf_tdo_buffer[svf_buffer_index], i, svf_para.tdr_para.len);
1039 i += svf_para.tdr_para.len;
1041 svf_add_check_para(1, svf_buffer_index, i);
1043 else
1045 svf_add_check_para(0, svf_buffer_index, i);
1047 field.tap = tap;
1048 field.num_bits = i;
1049 field.out_value = &svf_tdi_buffer[svf_buffer_index];
1050 field.in_value = &svf_tdi_buffer[svf_buffer_index];
1051 /* NOTE: doesn't use SVF-specified state paths */
1052 jtag_add_plain_dr_scan(1, &field, svf_para.dr_end_state);
1054 svf_buffer_index += (i + 7) >> 3;
1056 else if (SIR == command)
1058 // check buffer size first, reallocate if necessary
1059 i = svf_para.hir_para.len + svf_para.sir_para.len + svf_para.tir_para.len;
1060 if ((svf_buffer_size - svf_buffer_index) < ((i + 7) >> 3))
1062 #if 1
1063 // simply print error message
1064 LOG_ERROR("buffer is not enough, report to author");
1065 return ERROR_FAIL;
1066 #else
1067 uint8_t *buffer_tmp;
1069 // reallocate buffer
1070 buffer_tmp = (uint8_t *)malloc(svf_buffer_index + ((i + 7) >> 3));
1071 if (NULL == buffer_tmp)
1073 LOG_ERROR("not enough memory");
1074 return ERROR_FAIL;
1076 memcpy(buffer_tmp, svf_tdi_buffer, svf_buffer_index);
1077 // svf_tdi_buffer isn't NULL here
1078 free(svf_tdi_buffer);
1079 svf_tdi_buffer = buffer_tmp;
1081 buffer_tmp = (uint8_t *)malloc(svf_buffer_index + ((i + 7) >> 3));
1082 if (NULL == buffer_tmp)
1084 LOG_ERROR("not enough memory");
1085 return ERROR_FAIL;
1087 memcpy(buffer_tmp, svf_tdo_buffer, svf_buffer_index);
1088 // svf_tdo_buffer isn't NULL here
1089 free(svf_tdo_buffer);
1090 svf_tdo_buffer = buffer_tmp;
1092 buffer_tmp = (uint8_t *)malloc(svf_buffer_index + ((i + 7) >> 3));
1093 if (NULL == buffer_tmp)
1095 LOG_ERROR("not enough memory");
1096 return ERROR_FAIL;
1098 memcpy(buffer_tmp, svf_mask_buffer, svf_buffer_index);
1099 // svf_mask_buffer isn't NULL here
1100 free(svf_mask_buffer);
1101 svf_mask_buffer = buffer_tmp;
1103 buffer_tmp = NULL;
1104 svf_buffer_size = svf_buffer_index + ((i + 7) >> 3);
1105 #endif
1108 // assemble ir data
1109 i = 0;
1110 buf_set_buf(svf_para.hir_para.tdi, 0, &svf_tdi_buffer[svf_buffer_index], i, svf_para.hir_para.len);
1111 i += svf_para.hir_para.len;
1112 buf_set_buf(svf_para.sir_para.tdi, 0, &svf_tdi_buffer[svf_buffer_index], i, svf_para.sir_para.len);
1113 i += svf_para.sir_para.len;
1114 buf_set_buf(svf_para.tir_para.tdi, 0, &svf_tdi_buffer[svf_buffer_index], i, svf_para.tir_para.len);
1115 i += svf_para.tir_para.len;
1117 // add check data
1118 if (svf_para.sir_para.data_mask & XXR_TDO)
1120 // assemble dr mask data
1121 i = 0;
1122 buf_set_buf(svf_para.hir_para.mask, 0, &svf_mask_buffer[svf_buffer_index], i, svf_para.hir_para.len);
1123 i += svf_para.hir_para.len;
1124 buf_set_buf(svf_para.sir_para.mask, 0, &svf_mask_buffer[svf_buffer_index], i, svf_para.sir_para.len);
1125 i += svf_para.sir_para.len;
1126 buf_set_buf(svf_para.tir_para.mask, 0, &svf_mask_buffer[svf_buffer_index], i, svf_para.tir_para.len);
1127 i += svf_para.tir_para.len;
1128 // assemble dr check data
1129 i = 0;
1130 buf_set_buf(svf_para.hir_para.tdo, 0, &svf_tdo_buffer[svf_buffer_index], i, svf_para.hir_para.len);
1131 i += svf_para.hir_para.len;
1132 buf_set_buf(svf_para.sir_para.tdo, 0, &svf_tdo_buffer[svf_buffer_index], i, svf_para.sir_para.len);
1133 i += svf_para.sir_para.len;
1134 buf_set_buf(svf_para.tir_para.tdo, 0, &svf_tdo_buffer[svf_buffer_index], i, svf_para.tir_para.len);
1135 i += svf_para.tir_para.len;
1137 svf_add_check_para(1, svf_buffer_index, i);
1139 else
1141 svf_add_check_para(0, svf_buffer_index, i);
1143 field.tap = tap;
1144 field.num_bits = i;
1145 field.out_value = &svf_tdi_buffer[svf_buffer_index];
1146 field.in_value = &svf_tdi_buffer[svf_buffer_index];
1147 /* NOTE: doesn't use SVF-specified state paths */
1148 jtag_add_plain_ir_scan(1, &field, svf_para.ir_end_state);
1150 svf_buffer_index += (i + 7) >> 3;
1152 break;
1153 case PIO:
1154 case PIOMAP:
1155 LOG_ERROR("PIO and PIOMAP are not supported");
1156 return ERROR_FAIL;
1157 break;
1158 case RUNTEST:
1159 // RUNTEST [run_state] run_count run_clk [min_time SEC [MAXIMUM max_time SEC]] [ENDSTATE end_state]
1160 // RUNTEST [run_state] min_time SEC [MAXIMUM max_time SEC] [ENDSTATE end_state]
1161 if ((num_of_argu < 3) && (num_of_argu > 11))
1163 LOG_ERROR("invalid parameter of %s", argus[0]);
1164 return ERROR_FAIL;
1166 // init
1167 run_count = 0;
1168 min_time = 0;
1169 max_time = 0;
1170 i = 1;
1172 // run_state
1173 i_tmp = tap_state_by_name(argus[i]);
1174 if (i_tmp != TAP_INVALID)
1176 if (svf_tap_state_is_stable(i_tmp))
1178 svf_para.runtest_run_state = i_tmp;
1180 /* When a run_state is specified, the new
1181 * run_state becomes the default end_state.
1183 svf_para.runtest_end_state = i_tmp;
1184 LOG_DEBUG("\trun_state = %s",
1185 tap_state_name(i_tmp));
1186 i++;
1188 else
1190 LOG_ERROR("%s: %s is not a stable state",
1191 argus[0], tap_state_name(i_tmp));
1192 return ERROR_FAIL;
1196 // run_count run_clk
1197 if (((i + 2) <= num_of_argu) && strcmp(argus[i + 1], "SEC"))
1199 if (!strcmp(argus[i + 1], "TCK"))
1201 // clock source is TCK
1202 run_count = atoi(argus[i]);
1203 LOG_DEBUG("\trun_count@TCK = %d", run_count);
1205 else
1207 LOG_ERROR("%s not supported for clock", argus[i + 1]);
1208 return ERROR_FAIL;
1210 i += 2;
1212 // min_time SEC
1213 if (((i + 2) <= num_of_argu) && !strcmp(argus[i + 1], "SEC"))
1215 min_time = atof(argus[i]);
1216 LOG_DEBUG("\tmin_time = %fs", min_time);
1217 i += 2;
1219 // MAXIMUM max_time SEC
1220 if (((i + 3) <= num_of_argu) && !strcmp(argus[i], "MAXIMUM") && !strcmp(argus[i + 2], "SEC"))
1222 max_time = atof(argus[i + 1]);
1223 LOG_DEBUG("\tmax_time = %fs", max_time);
1224 i += 3;
1226 // ENDSTATE end_state
1227 if (((i + 2) <= num_of_argu) && !strcmp(argus[i], "ENDSTATE"))
1229 i_tmp = tap_state_by_name(argus[i + 1]);
1231 if (svf_tap_state_is_stable(i_tmp))
1233 svf_para.runtest_end_state = i_tmp;
1234 LOG_DEBUG("\tend_state = %s",
1235 tap_state_name(i_tmp));
1237 else
1239 LOG_ERROR("%s: %s is not a stable state",
1240 argus[0], tap_state_name(i_tmp));
1241 return ERROR_FAIL;
1243 i += 2;
1245 // calculate run_count
1246 if ((0 == run_count) && (min_time > 0))
1248 run_count = min_time * svf_para.frequency;
1250 // all parameter should be parsed
1251 if (i == num_of_argu)
1253 if (run_count > 0)
1255 // run_state and end_state is checked to be stable state
1256 // TODO: do runtest
1257 #if 1
1258 /* FIXME handle statemove failures */
1259 int retval;
1261 // enter into run_state if necessary
1262 if (cmd_queue_cur_state != svf_para.runtest_run_state)
1264 retval = svf_add_statemove(svf_para.runtest_run_state);
1267 // call jtag_add_clocks
1268 jtag_add_clocks(run_count);
1270 // move to end_state if necessary
1271 if (svf_para.runtest_end_state != svf_para.runtest_run_state)
1273 retval = svf_add_statemove(svf_para.runtest_end_state);
1275 #else
1276 if (svf_para.runtest_run_state != TAP_IDLE)
1278 LOG_ERROR("cannot runtest in %s state",
1279 tap_state_name(svf_para.runtest_run_state));
1280 return ERROR_FAIL;
1283 jtag_add_runtest(run_count, svf_para.runtest_end_state);
1284 #endif
1287 else
1289 LOG_ERROR("fail to parse parameter of RUNTEST, %d out of %d is parsed", i, num_of_argu);
1290 return ERROR_FAIL;
1292 break;
1293 case STATE:
1294 // STATE [pathstate1 [pathstate2 ...[pathstaten]]] stable_state
1295 if (num_of_argu < 2)
1297 LOG_ERROR("invalid parameter of %s", argus[0]);
1298 return ERROR_FAIL;
1300 if (num_of_argu > 2)
1302 // STATE pathstate1 ... stable_state
1303 path = (tap_state_t *)malloc((num_of_argu - 1) * sizeof(tap_state_t));
1304 if (NULL == path)
1306 LOG_ERROR("not enough memory");
1307 return ERROR_FAIL;
1309 num_of_argu--; // num of path
1310 i_tmp = 1; /* path is from parameter 1 */
1311 for (i = 0; i < num_of_argu; i++, i_tmp++)
1313 path[i] = tap_state_by_name(argus[i_tmp]);
1314 if (path[i] == TAP_INVALID)
1316 LOG_ERROR("%s: %s is not a valid state",
1317 argus[0], argus[i_tmp]);
1318 free(path);
1319 return ERROR_FAIL;
1321 /* OpenOCD refuses paths containing TAP_RESET */
1322 if (TAP_RESET == path[i])
1324 /* FIXME last state MUST be stable! */
1325 if (i > 0)
1327 jtag_add_pathmove(i, path);
1329 jtag_add_tlr();
1330 num_of_argu -= i + 1;
1331 i = -1;
1334 if (num_of_argu > 0)
1336 // execute last path if necessary
1337 if (svf_tap_state_is_stable(path[num_of_argu - 1]))
1339 // last state MUST be stable state
1340 jtag_add_pathmove(num_of_argu, path);
1341 LOG_DEBUG("\tmove to %s by path_move",
1342 tap_state_name(path[num_of_argu - 1]));
1344 else
1346 LOG_ERROR("%s: %s is not a stable state",
1347 argus[0],
1348 tap_state_name(path[num_of_argu - 1]));
1349 free(path);
1350 return ERROR_FAIL;
1353 // no need to keep this memory, in jtag_add_pathmove, path will be duplicated
1354 if (NULL != path)
1356 free(path);
1357 path = NULL;
1360 else
1362 // STATE stable_state
1363 state = tap_state_by_name(argus[1]);
1364 if (svf_tap_state_is_stable(state))
1366 LOG_DEBUG("\tmove to %s by svf_add_statemove",
1367 tap_state_name(state));
1368 /* FIXME handle statemove failures */
1369 svf_add_statemove(state);
1371 else
1373 LOG_ERROR("%s: %s is not a stable state",
1374 argus[0], tap_state_name(state));
1375 return ERROR_FAIL;
1378 break;
1379 case TRST:
1380 // TRST trst_mode
1381 if (num_of_argu != 2)
1383 LOG_ERROR("invalid parameter of %s", argus[0]);
1384 return ERROR_FAIL;
1386 if (svf_para.trst_mode != TRST_ABSENT)
1388 if (ERROR_OK != svf_execute_tap())
1390 return ERROR_FAIL;
1392 i_tmp = svf_find_string_in_array(argus[1],
1393 (char **)svf_trst_mode_name,
1394 ARRAY_SIZE(svf_trst_mode_name));
1395 switch (i_tmp)
1397 case TRST_ON:
1398 jtag_add_reset(1, 0);
1399 break;
1400 case TRST_Z:
1401 case TRST_OFF:
1402 jtag_add_reset(0, 0);
1403 break;
1404 case TRST_ABSENT:
1405 break;
1406 default:
1407 LOG_ERROR("unknown TRST mode: %s", argus[1]);
1408 return ERROR_FAIL;
1410 svf_para.trst_mode = i_tmp;
1411 LOG_DEBUG("\ttrst_mode = %s", svf_trst_mode_name[svf_para.trst_mode]);
1413 else
1415 LOG_ERROR("can not accpet TRST command if trst_mode is ABSENT");
1416 return ERROR_FAIL;
1418 break;
1419 default:
1420 LOG_ERROR("invalid svf command: %s", argus[0]);
1421 return ERROR_FAIL;
1422 break;
1425 if (debug_level >= LOG_LVL_DEBUG)
1427 // for convenient debugging, execute tap if possible
1428 if ((svf_buffer_index > 0) && \
1429 (((command != STATE) && (command != RUNTEST)) || \
1430 ((command == STATE) && (num_of_argu == 2))))
1432 if (ERROR_OK != svf_execute_tap())
1434 return ERROR_FAIL;
1437 // output debug info
1438 if ((SIR == command) || (SDR == command))
1440 int read_value;
1441 memcpy(&read_value, svf_tdi_buffer, sizeof(int));
1442 // in debug mode, data is from index 0
1443 int read_mask = svf_get_mask_u32(svf_check_tdo_para[0].bit_len);
1444 LOG_DEBUG("\tTDO read = 0x%X", read_value & read_mask);
1448 else
1450 // for fast executing, execute tap if necessary
1451 // half of the buffer is for the next command
1452 if (((svf_buffer_index >= SVF_MAX_BUFFER_SIZE_TO_COMMIT) || (svf_check_tdo_para_index >= SVF_CHECK_TDO_PARA_SIZE / 2)) && \
1453 (((command != STATE) && (command != RUNTEST)) || \
1454 ((command == STATE) && (num_of_argu == 2))))
1456 return svf_execute_tap();
1460 return ERROR_OK;
1463 static const struct command_registration svf_command_handlers[] = {
1465 .name = "svf",
1466 .handler = &handle_svf_command,
1467 .mode = COMMAND_EXEC,
1468 .help = "Runs a SVF file.",
1469 .usage = "<file>",
1471 COMMAND_REGISTRATION_DONE
1474 int svf_register_commands(struct command_context *cmd_ctx)
1476 return register_commands(cmd_ctx, NULL, svf_command_handlers);