| blob | ee61003971b464e9a37a8ffa9ec7e443f17e1ce1 |
1 /***************************************************************************
2 * Copyright (C) 2007-2010 by Øyvind Harboe *
3 * *
4 * This program is free software; you can redistribute it and/or modify *
5 * it under the terms of the GNU General Public License as published by *
6 * the Free Software Foundation; either version 2 of the License, or *
7 * (at your option) any later version. *
8 * *
9 * This program is distributed in the hope that it will be useful, *
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
12 * GNU General Public License for more details. *
13 * *
14 * You should have received a copy of the GNU General Public License *
15 * along with this program; if not, write to the *
16 * Free Software Foundation, Inc., *
17 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
18 ***************************************************************************/
20 /* This file supports the zy1000 debugger: http://www.zylin.com/zy1000.html
21 *
22 * The zy1000 is a standalone debugger that has a web interface and
23 * requires no drivers on the developer host as all communication
24 * is via TCP/IP. The zy1000 gets it performance(~400-700kBytes/s
25 * DCC downloads @ 16MHz target) as it has an FPGA to hardware
26 * accelerate the JTAG commands, while offering *very* low latency
27 * between OpenOCD and the FPGA registers.
28 *
29 * The disadvantage of the zy1000 is that it has a feeble CPU compared to
30 * a PC(ca. 50-500 DMIPS depending on how one counts it), whereas a PC
31 * is on the order of 10000 DMIPS(i.e. at a factor of 20-200).
32 *
33 * The zy1000 revc hardware is using an Altera Nios CPU, whereas the
34 * revb is using ARM7 + Xilinx.
35 *
36 * See Zylin web pages or contact Zylin for more information.
37 *
38 * The reason this code is in OpenOCD rather than OpenOCD linked with the
39 * ZY1000 code is that OpenOCD is the long road towards getting
40 * libopenocd into place. libopenocd will support both low performance,
41 * low latency systems(embedded) and high performance high latency
42 * systems(PCs).
43 */
44 #ifdef HAVE_CONFIG_H
46 #endif
48 #include <pthread.h>
50 #include <target/embeddedice.h>
51 #include <jtag/minidriver.h>
52 #include <jtag/interface.h>
53 #include <time.h>
54 #include <helper/time_support.h>
56 #include <netinet/tcp.h>
58 #if BUILD_ECOSBOARD
62 #include <cyg/hal/hal_diag.h>
64 #ifdef CYGPKG_HAL_NIOS2
65 #include <cyg/hal/io.h>
66 #include <cyg/firmwareutil/firmwareutil.h>
67 #define ZYLIN_KHZ 60000
68 #else
69 #define ZYLIN_KHZ 64000
70 #endif
72 #define ZYLIN_VERSION GIT_ZY1000_VERSION
73 #define ZYLIN_DATE __DATE__
74 #define ZYLIN_TIME __TIME__
75 #define ZYLIN_OPENOCD GIT_OPENOCD_VERSION
78 #else
79 /* Assume we're connecting to a revc w/60MHz clock. */
80 #define ZYLIN_KHZ 60000
81 #endif
84 /* The software needs to check if it's in RCLK mode or not */
88 {
90 {
92 }
93 else
94 {
96 /* Round speed up to nearest divisor.
97 *
98 * E.g. 16000kHz
99 * (64000 + 15999) / 16000 = 4
100 * (4 + 1) / 2 = 2
101 * 2 * 2 = 4
102 *
103 * 64000 / 4 = 16000
104 *
105 * E.g. 15999
106 * (64000 + 15998) / 15999 = 5
107 * (5 + 1) / 2 = 3
108 * 3 * 2 = 6
109 *
110 * 64000 / 6 = 10666
111 *
112 */
117 {
118 /* maximum dividend */
120 }
122 }
124 }
127 {
129 {
131 }
132 else
133 {
135 }
138 }
141 {
143 // sample and clear power dropout
149 }
153 {
155 // sample and clear SRST sensing
161 }
164 {
167 }
170 {
173 }
175 /* Wait for SRST to assert or deassert */
177 {
184 {
187 {
189 {
191 }
193 }
196 {
199 }
206 {
209 }
210 }
211 }
215 {
218 /* flush the JTAG FIFO. Not flushing the queue before messing with
219 * reset has such interesting bugs as causing hard to reproduce
220 * RCLK bugs as RCLK will stop responding when TRST is asserted
221 */
225 {
227 }
228 else
229 {
230 /* Danger!!! if clk != 0 when in
231 * idle in TAP_IDLE, reset halt on str912 will fail.
232 */
236 }
239 {
241 }
242 else
243 {
244 /* assert reset */
246 }
249 {
250 /* we're now in the RESET state until trst is deasserted */
253 {
254 /* We'll get RCLK failure when we assert TRST, so clear any false positives here */
256 }
258 /* wait for srst to float back up */
261 {
263 }
264 }
267 {
268 /* flush JTAG master FIFO before setting speed */
274 {
275 /*0 means RCLK*/
279 }
280 else
281 {
283 {
284 LOG_USER("valid ZY1000 jtag_speed=[8190,2]. With divisor is %dkHz / even values between 8190-2, i.e. min %dHz, max %dMHz",
287 }
295 }
297 }
303 {
306 {
309 {
311 }
312 }
315 {
317 {
322 // fall through
323 }
329 }
332 }
334 #if !BUILD_ZY1000_MASTER
337 {
344 }
345 #endif
347 #if BUILD_ECOSBOARD
348 /* Give TELNET a way to find out what version this is */
350 {
356 {
359 {
365 {
367 }
369 {
371 }
373 {
375 }
377 {
379 }
381 {
382 #ifdef CYGPKG_HAL_NIOS2
384 #else
386 #endif
387 }
388 #ifdef CYGPKG_HAL_NIOS2
390 {
392 /* return a list of 32 bit integers to describe the expected
393 * and actual FPGA
394 */
402 {
407 }
408 }
409 #endif
411 else
412 {
414 }
415 }
420 }
421 #endif
423 #ifdef CYGPKG_HAL_NIOS2
426 struct info_forward
427 {
430 };
433 {
437 }
440 {
448 report_info,
449 };
451 // File written to /ram/firmware.phi before arriving at this fn
453 {
461 }
462 #endif
464 static int
468 {
470 {
473 }
480 }
485 {
488 }
493 {
498 /* We must make sure to write data read back to memory location before we return
499 * from this fn
500 */
503 /* and handle any callbacks... */
507 {
508 /* Only check for errors when using RCLK to speed up
509 * jtag over TCP/IP
510 */
512 /* clear JTAG error register */
516 {
518 /* the error is informative only as we don't want to break the firmware if there
519 * is a false positive.
520 */
521 // return ERROR_FAIL;
522 }
523 }
525 }
532 // here we shuffle N bits out/in
533 static __inline void scanBits(const uint8_t *out_value, uint8_t *in_value, int num_bits, bool pause_now, tap_state_t shiftState, tap_state_t end_state)
534 {
537 {
540 {
542 /* we have more to shift out */
544 {
545 /* this was the last to shift out this time */
547 }
549 // we have (num_bits + 7)/8 bytes of bits to toggle out.
550 // bits are pushed out LSB to MSB
554 {
556 {
558 }
559 }
560 /* mask away unused bits for easier debugging */
562 {
565 {
566 /* Shifting by >= 32 is not defined by the C standard
567 * and will in fact shift by &0x1f bits on nios */
568 }
573 {
575 }
576 }
577 }
579 static __inline void scanFields(int num_fields, const struct scan_field *fields, tap_state_t shiftState, tap_state_t end_state)
580 {
582 {
587 shiftState,
588 end_state);
589 }
590 }
592 int interface_jtag_add_ir_scan(struct jtag_tap *active, const struct scan_field *fields, tap_state_t state)
593 {
599 {
602 {
604 }
607 /* search the list */
609 {
611 /* update device information */
616 {
617 /* if a device isn't listed, set it to BYPASS */
622 }
623 }
626 }
632 int interface_jtag_add_plain_ir_scan(int num_bits, const uint8_t *out_bits, uint8_t *in_bits, tap_state_t state)
633 {
636 }
638 int interface_jtag_add_dr_scan(struct jtag_tap *active, int num_fields, const struct scan_field *fields, tap_state_t state)
639 {
643 {
646 {
648 }
650 /* Find a range of fields to write to this tap */
652 {
657 {
658 /* Shift out a 0 for disabled tap's */
661 }
662 }
664 }
666 int interface_jtag_add_plain_dr_scan(int num_bits, const uint8_t *out_bits, uint8_t *in_bits, tap_state_t state)
667 {
670 }
673 {
676 }
680 {
683 }
686 {
687 /* num_cycles can be 0 */
690 /* execute num_cycles, 32 at the time. */
693 {
697 {
699 }
701 }
703 #if !TEST_MANUAL()
704 /* finish in end_state */
706 #else
708 /* test manual drive code on any target */
714 {
718 }
721 #endif
724 }
727 {
729 }
732 {
734 }
737 {
738 /*wait for the fifo to be empty*/
742 {
746 {
748 }
749 else
750 {
752 }
756 }
760 {
763 {
764 /* this would be normal if we are switching to SWD mode */
765 }
767 }
770 {
783 {
785 {
787 }
789 {
791 }
792 else
793 {
794 LOG_ERROR("BUG: %s -> %s isn't a valid TAP transition", tap_state_name(cur_state), tap_state_name(path[state_count]));
796 }
801 state_count++;
802 num_states--;
803 }
806 }
809 {
810 /* bypass bits before and after */
817 {
820 {
823 {
825 {
826 post_bits++;
828 {
829 pre_bits++;
830 }
831 }
832 }
835 }
837 /*
838 static const int embeddedice_num_bits[] = {32, 6};
839 uint32_t values[2];
841 values[0] = value;
842 values[1] = (1 << 5) | reg_addr;
844 jtag_add_dr_out(tap,
845 2,
846 embeddedice_num_bits,
847 values,
848 TAP_IDLE);
849 */
851 void embeddedice_write_dcc(struct jtag_tap *tap, int reg_addr, uint8_t *buffer, int little, int count)
852 {
853 #if 0
856 {
859 }
860 #else
866 {
869 {
872 }
874 {
877 {
878 /* Fewer pokes means we get to use the FIFO more efficiently */
881 /* Danger! here we need to exit into the TAP_IDLE state to make
882 * DCC pick up this value.
883 */
886 }
887 }
888 #endif
889 }
893 int arm11_run_instr_data_to_core_noack_inner(struct jtag_tap * tap, uint32_t opcode, uint32_t * data, size_t count)
894 {
895 /* bypass bits before and after */
902 {
903 int arm11_run_instr_data_to_core_noack_inner_default(struct jtag_tap *, uint32_t, uint32_t *, size_t);
906 {
910 /* FIX!!!!!! the target_write_memory() API started this nasty problem
911 * with unaligned uint32_t * pointers... */
915 {
916 #if 1
917 /* Danger! This code doesn't update cmd_queue_cur_state, so
918 * invoking jtag_add_pathmove() before jtag_add_dr_out() after
919 * this loop would fail!
920 */
930 /* minimum 2 bits */
933 /* copy & paste from arm11_dbgtap.c */
934 //TAP_DREXIT2, TAP_DRUPDATE, TAP_IDLE, TAP_IDLE, TAP_IDLE, TAP_DRSELECT, TAP_DRCAPTURE, TAP_DRSHIFT
935 /* KLUDGE! we have to flush the fifo or the Nios CPU locks up.
936 * This is probably a bug in the Avalon bus(cross clocking bridge?)
937 * or in the jtag registers module.
938 */
948 /* we don't have to wait for the queue to empty here */
951 #else
953 {
954 TAP_DREXIT2, TAP_DRUPDATE, TAP_IDLE, TAP_IDLE, TAP_IDLE, TAP_DRSELECT, TAP_DRCAPTURE, TAP_DRSHIFT
955 };
964 bits,
965 values,
966 TAP_IDLE);
969 arm11_MOVE_DRPAUSE_IDLE_DRPAUSE_with_delay);
970 #endif
971 }
978 /* This will happen on the last iteration updating cmd_queue_cur_state
979 * so we don't have to track it during the common code path
980 */
983 bits,
984 values,
985 TAP_IDLE);
988 }
989 }
993 {
1000 },
1001 #if BUILD_ZY1000_MASTER
1002 #if BUILD_ECOSBOARD
1003 {
1009 },
1010 #endif
1011 #else
1012 {
1018 },
1019 #endif
1020 {
1025 },
1026 #ifdef CYGPKG_HAL_NIOS2
1027 {
1032 /* .usage = "some_string", */
1033 },
1034 #endif
1035 COMMAND_REGISTRATION_DONE
1036 };
1039 #if !BUILD_ZY1000_MASTER
1043 /* Write large packets if we can */
1051 {
1055 }
1058 {
1061 {
1065 {
1067 {
1069 }
1070 }
1071 }
1073 }
1076 {
1080 {
1083 {
1084 /* If we have some data that we can send, send them before
1085 * we wait for more data
1086 */
1088 {
1090 {
1092 }
1093 }
1095 /* read more */
1099 {
1101 }
1104 }
1108 }
1111 }
1113 enum ZY1000_CMD
1114 {
1119 };
1124 /* We initialize this late since we need to know the server address
1125 * first.
1126 */
1128 {
1134 /* Create a reliable, stream socket using TCP */
1136 {
1139 }
1141 /* Construct the server address structure */
1147 /* Establish the connection to the echo server */
1149 {
1152 }
1161 }
1164 /* send a poke */
1166 {
1170 {
1173 }
1174 }
1176 /* By sending the wait to the server, we avoid a readback
1177 * of status. Radically improves performance for this operation
1178 * with long ping times.
1179 */
1181 {
1184 {
1187 }
1188 }
1191 {
1199 {
1202 }
1204 }
1207 {
1211 {
1214 }
1216 }
1218 /* queue a readback */
1219 #define readqueue_size 16384
1220 static struct
1221 {
1228 /* flush the readqueue, this means reading any data that
1229 * we're expecting and store them into the final position
1230 */
1232 {
1234 {
1235 /* simply debugging by allowing easy breakpoints when there
1236 * is something to do. */
1238 }
1242 {
1245 {
1248 }
1253 // we're shifting in data to MSB, shift data to be aligned for returning the value
1257 {
1259 }
1260 }
1262 }
1264 /* By queuing the callback's we avoid flushing the
1265 read queue until jtag_execute_queue(). This can
1266 reduce latency dramatically for cases where
1267 callbacks are used extensively.
1268 */
1269 #define callbackqueue_size 128
1270 static struct callbackentry
1271 {
1272 jtag_callback_t callback;
1273 jtag_callback_data_t data0;
1274 jtag_callback_data_t data1;
1275 jtag_callback_data_t data2;
1276 jtag_callback_data_t data3;
1281 void zy1000_jtag_add_callback4(jtag_callback_t callback, jtag_callback_data_t data0, jtag_callback_data_t data1, jtag_callback_data_t data2, jtag_callback_data_t data3)
1282 {
1284 {
1286 }
1293 callbackqueue_pos++;
1294 }
1296 static int zy1000_jtag_convert_to_callback4(jtag_callback_data_t data0, jtag_callback_data_t data1, jtag_callback_data_t data2, jtag_callback_data_t data3)
1297 {
1300 }
1303 {
1304 zy1000_jtag_add_callback4(zy1000_jtag_convert_to_callback4, data0, (jtag_callback_data_t)callback, 0, 0);
1305 }
1308 {
1309 /* we have to flush the read queue so we have access to
1310 the data the callbacks will use
1311 */
1315 {
1318 }
1320 }
1323 {
1327 {
1330 }
1333 {
1335 }
1339 readqueue_pos++;
1340 }
1342 #else
1345 {
1351 // data in, LSB to MSB
1352 // we're shifting in data to MSB, shift data to be aligned for returning the value
1356 {
1358 }
1359 }
1361 #endif
1363 #if BUILD_ZY1000_MASTER
1365 #if BUILD_ECOSBOARD
1369 #endif
1371 #ifdef WATCHDOG_BASE
1372 /* If we connect to port 8888 we must send a char every 10s or the board resets itself */
1374 {
1379 {
1382 }
1396 {
1399 }
1402 {
1405 }
1409 {
1412 /* Start watchdog, must be reset every 10 seconds. */
1416 {
1419 }
1431 {
1433 {
1434 /* Reset timer */
1436 /* Echo so we can telnet in and see that resetting works */
1439 {
1440 /* Stop tickling the watchdog, the CPU will reset in < 10 seconds
1441 * now.
1442 */
1444 }
1446 }
1448 /* Never reached */
1449 }
1450 }
1451 #endif
1453 #endif
1455 #if BUILD_ZY1000_MASTER
1457 {
1460 }
1461 #endif
1463 #if BUILD_ZY1000_MASTER && !BUILD_ECOSBOARD
1465 #include <sys/mman.h>
1466 #endif
1469 {
1470 #if BUILD_ECOSBOARD
1472 #elif BUILD_ZY1000_MASTER
1475 {
1478 }
1479 #ifndef REGISTERS_BASE
1480 #define REGISTERS_BASE 0x9002000
1481 #define REGISTERS_SPAN 128
1482 #endif
1484 zy1000_jtag_master = mmap(0, REGISTERS_SPAN, PROT_READ | PROT_WRITE, MAP_SHARED, fd, REGISTERS_BASE);
1487 {
1491 }
1492 #endif
1501 /* deassert resets. Important to avoid infinite loop waiting for SRST to deassert */
1509 #if BUILD_ZY1000_MASTER
1510 #if BUILD_ECOSBOARD
1511 #ifdef WATCHDOG_BASE
1516 #endif
1517 #endif
1518 #endif
1521 }
1526 {
1538 };