1 /***************************************************************************
2 * Copyright (C) 2009 by Øyvind Harboe *
3 * Øyvind Harboe <oyvind.harboe@zylin.com> *
5 * Copyright (C) 2009 by SoftPLC Corporation. http://softplc.com *
6 * Dick Hollenbeck <dick@softplc.com> *
8 * Copyright (C) 2004, 2006 by Dominic Rath *
9 * Dominic.Rath@gmx.de *
11 * Copyright (C) 2008 by Spencer Oliver *
12 * spen@spen-soft.co.uk *
14 * This program is free software; you can redistribute it and/or modify *
15 * it under the terms of the GNU General Public License as published by *
16 * the Free Software Foundation; either version 2 of the License, or *
17 * (at your option) any later version. *
19 * This program is distributed in the hope that it will be useful, *
20 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
21 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
22 * GNU General Public License for more details. *
24 * You should have received a copy of the GNU General Public License *
25 * along with this program; if not, write to the *
26 * Free Software Foundation, Inc., *
27 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
28 ***************************************************************************/
32 * JTAG adapters based on the FT2232 full and high speed USB parts are
33 * popular low cost JTAG debug solutions. Many FT2232 based JTAG adapters
34 * are discrete, but development boards may integrate them as alternatives
35 * to more capable (and expensive) third party JTAG pods.
37 * JTAG uses only one of the two communications channels ("MPSSE engines")
38 * on these devices. Adapters based on FT4232 parts have four ports/channels
39 * (A/B/C/D), instead of just two (A/B).
41 * Especially on development boards integrating one of these chips (as
42 * opposed to discrete pods/dongles), the additional channels can be used
43 * for a variety of purposes, but OpenOCD only uses one channel at a time.
45 * - As a USB-to-serial adapter for the target's console UART ...
46 * which may be able to support ROM boot loaders that load initial
47 * firmware images to flash (or SRAM).
49 * - On systems which support ARM's SWD in addition to JTAG, or instead
50 * of it, that second port can be used for reading SWV/SWO trace data.
52 * - Additional JTAG links, e.g. to a CPLD or * FPGA.
54 * FT2232 based JTAG adapters are "dumb" not "smart", because most JTAG
55 * request/response interactions involve round trips over the USB link.
56 * A "smart" JTAG adapter has intelligence close to the scan chain, so it
57 * can for example poll quickly for a status change (usually taking on the
58 * order of microseconds not milliseconds) before beginning a queued
59 * transaction which require the previous one to have completed.
61 * There are dozens of adapters of this type, differing in details which
62 * this driver needs to understand. Those "layout" details are required
63 * as part of FT2232 driver configuration.
65 * This code uses information contained in the MPSSE specification which was
67 * http://www.ftdichip.com/Documents/AppNotes/AN2232C-01_MPSSE_Cmnd.pdf
68 * Hereafter this is called the "MPSSE Spec".
70 * The datasheet for the ftdichip.com's FT2232D part is here:
71 * http://www.ftdichip.com/Documents/DataSheets/DS_FT2232D.pdf
73 * Also note the issue with code 0x4b (clock data to TMS) noted in
74 * http://developer.intra2net.com/mailarchive/html/libftdi/2009/msg00292.html
75 * which can affect longer JTAG state paths.
82 /* project specific includes */
83 #include <jtag/interface.h>
84 #include <jtag/transport.h>
85 #include <helper/time_support.h>
93 #if (BUILD_FT2232_FTD2XX == 1 && BUILD_FT2232_LIBFTDI == 1)
94 #error "BUILD_FT2232_FTD2XX && BUILD_FT2232_LIBFTDI are mutually exclusive"
95 #elif (BUILD_FT2232_FTD2XX != 1 && BUILD_FT2232_LIBFTDI != 1)
96 #error "BUILD_FT2232_FTD2XX || BUILD_FT2232_LIBFTDI must be chosen"
99 /* FT2232 access library includes */
100 #if BUILD_FT2232_FTD2XX == 1
112 #elif BUILD_FT2232_LIBFTDI == 1
116 /* max TCK for the high speed devices 30000 kHz */
117 #define FTDI_2232H_4232H_MAX_TCK 30000
118 /* max TCK for the full speed devices 6000 kHz */
119 #define FTDI_2232C_MAX_TCK 6000
120 /* this speed value tells that RTCK is requested */
121 #define RTCK_SPEED -1
124 * On my Athlon XP 1900+ EHCI host with FT2232H JTAG dongle I get read timeout
125 * errors with a retry count of 100. Increasing it solves the problem for me.
128 * FIXME There's likely an issue with the usb_read_timeout from libftdi.
129 * Fix that (libusb? kernel? libftdi? here?) and restore the retry count
132 #define LIBFTDI_READ_RETRY_COUNT 2000
134 #ifndef BUILD_FT2232_HIGHSPEED
135 #if BUILD_FT2232_FTD2XX == 1
136 enum { FT_DEVICE_2232H
= 6, FT_DEVICE_4232H
};
137 #elif BUILD_FT2232_LIBFTDI == 1
138 enum { TYPE_2232H
= 4, TYPE_4232H
= 5 };
143 * Send out \a num_cycles on the TCK line while the TAP(s) are in a
144 * stable state. Calling code must ensure that current state is stable,
145 * that verification is not done in here.
147 * @param num_cycles The number of clocks cycles to send.
148 * @param cmd The command to send.
150 * @returns ERROR_OK on success, or ERROR_JTAG_QUEUE_FAILED on failure.
152 static int ft2232_stableclocks(int num_cycles
, struct jtag_command
* cmd
);
154 static char * ft2232_device_desc_A
= NULL
;
155 static char* ft2232_device_desc
= NULL
;
156 static char* ft2232_serial
= NULL
;
157 static uint8_t ft2232_latency
= 2;
158 static unsigned ft2232_max_tck
= FTDI_2232C_MAX_TCK
;
160 #define MAX_USB_IDS 8
161 /* vid = pid = 0 marks the end of the list */
162 static uint16_t ft2232_vid
[MAX_USB_IDS
+ 1] = { 0x0403, 0 };
163 static uint16_t ft2232_pid
[MAX_USB_IDS
+ 1] = { 0x6010, 0 };
165 struct ft2232_layout
{
168 void (*reset
)(int trst
, int srst
);
173 /* init procedures for supported layouts */
174 static int usbjtag_init(void);
175 static int jtagkey_init(void);
176 static int lm3s811_jtag_init(void);
177 static int icdi_jtag_init(void);
178 static int olimex_jtag_init(void);
179 static int flyswatter_init(void);
180 static int turtle_init(void);
181 static int comstick_init(void);
182 static int stm32stick_init(void);
183 static int axm0432_jtag_init(void);
184 static int sheevaplug_init(void);
185 static int icebear_jtag_init(void);
186 static int cortino_jtag_init(void);
187 static int signalyzer_init(void);
188 static int signalyzer_h_init(void);
189 static int ktlink_init(void);
190 static int redbee_init(void);
191 static int lisa_l_init(void);
192 static int flossjtag_init(void);
194 /* reset procedures for supported layouts */
195 static void ftx23_reset(int trst
, int srst
);
196 static void jtagkey_reset(int trst
, int srst
);
197 static void olimex_jtag_reset(int trst
, int srst
);
198 static void flyswatter_reset(int trst
, int srst
);
199 static void turtle_reset(int trst
, int srst
);
200 static void comstick_reset(int trst
, int srst
);
201 static void stm32stick_reset(int trst
, int srst
);
202 static void axm0432_jtag_reset(int trst
, int srst
);
203 static void sheevaplug_reset(int trst
, int srst
);
204 static void icebear_jtag_reset(int trst
, int srst
);
205 static void signalyzer_h_reset(int trst
, int srst
);
206 static void ktlink_reset(int trst
, int srst
);
207 static void redbee_reset(int trst
, int srst
);
209 /* blink procedures for layouts that support a blinking led */
210 static void olimex_jtag_blink(void);
211 static void flyswatter_jtag_blink(void);
212 static void turtle_jtag_blink(void);
213 static void signalyzer_h_blink(void);
214 static void ktlink_blink(void);
215 static void lisa_l_blink(void);
216 static void flossjtag_blink(void);
218 /* common transport support options */
220 //static const char *jtag_and_swd[] = { "jtag", "swd", NULL };
222 static const struct ft2232_layout ft2232_layouts
[] =
225 .init
= usbjtag_init
,
226 .reset
= ftx23_reset
,
229 .init
= jtagkey_init
,
230 .reset
= jtagkey_reset
,
232 { .name
= "jtagkey_prototype_v1",
233 .init
= jtagkey_init
,
234 .reset
= jtagkey_reset
,
236 { .name
= "oocdlink",
237 .init
= jtagkey_init
,
238 .reset
= jtagkey_reset
,
240 { .name
= "signalyzer",
241 .init
= signalyzer_init
,
242 .reset
= ftx23_reset
,
244 { .name
= "evb_lm3s811",
245 .init
= lm3s811_jtag_init
,
246 .reset
= ftx23_reset
,
248 { .name
= "luminary_icdi",
249 .init
= icdi_jtag_init
,
250 .reset
= ftx23_reset
,
252 { .name
= "olimex-jtag",
253 .init
= olimex_jtag_init
,
254 .reset
= olimex_jtag_reset
,
255 .blink
= olimex_jtag_blink
257 { .name
= "flyswatter",
258 .init
= flyswatter_init
,
259 .reset
= flyswatter_reset
,
260 .blink
= flyswatter_jtag_blink
262 { .name
= "turtelizer2",
264 .reset
= turtle_reset
,
265 .blink
= turtle_jtag_blink
267 { .name
= "comstick",
268 .init
= comstick_init
,
269 .reset
= comstick_reset
,
271 { .name
= "stm32stick",
272 .init
= stm32stick_init
,
273 .reset
= stm32stick_reset
,
275 { .name
= "axm0432_jtag",
276 .init
= axm0432_jtag_init
,
277 .reset
= axm0432_jtag_reset
,
279 { .name
= "sheevaplug",
280 .init
= sheevaplug_init
,
281 .reset
= sheevaplug_reset
,
284 .init
= icebear_jtag_init
,
285 .reset
= icebear_jtag_reset
,
288 .init
= cortino_jtag_init
,
289 .reset
= comstick_reset
,
291 { .name
= "signalyzer-h",
292 .init
= signalyzer_h_init
,
293 .reset
= signalyzer_h_reset
,
294 .blink
= signalyzer_h_blink
298 .reset
= ktlink_reset
,
299 .blink
= ktlink_blink
301 { .name
= "redbee-econotag",
303 .reset
= redbee_reset
,
305 { .name
= "redbee-usb",
307 .reset
= redbee_reset
,
308 .channel
= INTERFACE_B
,
312 .reset
= ftx23_reset
,
313 .blink
= lisa_l_blink
,
314 .channel
= INTERFACE_B
,
316 { .name
= "flossjtag",
317 .init
= flossjtag_init
,
318 .reset
= ftx23_reset
,
319 .blink
= flossjtag_blink
,
321 { .name
= NULL
, /* END OF TABLE */ },
324 /* bitmask used to drive nTRST; usually a GPIOLx signal */
325 static uint8_t nTRST
;
326 static uint8_t nTRSTnOE
;
327 /* bitmask used to drive nSRST; usually a GPIOLx signal */
328 static uint8_t nSRST
;
329 static uint8_t nSRSTnOE
;
331 /** the layout being used with this debug session */
332 static const struct ft2232_layout
*layout
;
334 /** default bitmask values driven on DBUS: TCK/TDI/TDO/TMS and GPIOL(0..4) */
335 static uint8_t low_output
= 0x0;
337 /* note that direction bit == 1 means that signal is an output */
339 /** default direction bitmask for DBUS: TCK/TDI/TDO/TMS and GPIOL(0..4) */
340 static uint8_t low_direction
= 0x0;
341 /** default value bitmask for CBUS GPIOH(0..4) */
342 static uint8_t high_output
= 0x0;
343 /** default direction bitmask for CBUS GPIOH(0..4) */
344 static uint8_t high_direction
= 0x0;
346 #if BUILD_FT2232_FTD2XX == 1
347 static FT_HANDLE ftdih
= NULL
;
348 static FT_DEVICE ftdi_device
= 0;
349 #elif BUILD_FT2232_LIBFTDI == 1
350 static struct ftdi_context ftdic
;
351 static enum ftdi_chip_type ftdi_device
;
354 static struct jtag_command
* first_unsent
; /* next command that has to be sent */
355 static int require_send
;
357 /* http://urjtag.wiki.sourceforge.net/Cable + FT2232 says:
359 "There is a significant difference between libftdi and libftd2xx. The latter
360 one allows to schedule up to 64*64 bytes of result data while libftdi fails
361 with more than 4*64. As a consequence, the FT2232 driver is forced to
362 perform around 16x more USB transactions for long command streams with TDO
363 capture when running with libftdi."
366 #define FT2232_BUFFER_SIZE 131072
367 a comment would have been nice.
370 #define FT2232_BUFFER_SIZE 131072
372 static uint8_t* ft2232_buffer
= NULL
;
373 static int ft2232_buffer_size
= 0;
374 static int ft2232_read_pointer
= 0;
375 static int ft2232_expect_read
= 0;
378 * Function buffer_write
379 * writes a byte into the byte buffer, "ft2232_buffer", which must be sent later.
380 * @param val is the byte to send.
382 static inline void buffer_write(uint8_t val
)
384 assert(ft2232_buffer
);
385 assert((unsigned) ft2232_buffer_size
< (unsigned) FT2232_BUFFER_SIZE
);
386 ft2232_buffer
[ft2232_buffer_size
++] = val
;
390 * Function buffer_read
391 * returns a byte from the byte buffer.
393 static inline uint8_t buffer_read(void)
395 assert(ft2232_buffer
);
396 assert(ft2232_read_pointer
< ft2232_buffer_size
);
397 return ft2232_buffer
[ft2232_read_pointer
++];
401 * Clocks out \a bit_count bits on the TMS line, starting with the least
402 * significant bit of tms_bits and progressing to more significant bits.
403 * Rigorous state transition logging is done here via tap_set_state().
405 * @param mpsse_cmd One of the MPSSE TMS oriented commands such as
406 * 0x4b or 0x6b. See the MPSSE spec referenced above for their
407 * functionality. The MPSSE command "Clock Data to TMS/CS Pin (no Read)"
408 * is often used for this, 0x4b.
410 * @param tms_bits Holds the sequence of bits to send.
411 * @param tms_count Tells how many bits in the sequence.
412 * @param tdi_bit A single bit to pass on to TDI before the first TCK
413 * cycle and held static for the duration of TMS clocking.
415 * See the MPSSE spec referenced above.
417 static void clock_tms(uint8_t mpsse_cmd
, int tms_bits
, int tms_count
, bool tdi_bit
)
421 int tms_ndx
; /* bit index into tms_byte */
423 assert(tms_count
> 0);
425 DEBUG_JTAG_IO("mpsse cmd=%02x, tms_bits = 0x%08x, bit_count=%d",
426 mpsse_cmd
, tms_bits
, tms_count
);
428 for (tms_byte
= tms_ndx
= i
= 0; i
< tms_count
; ++i
, tms_bits
>>=1)
430 bool bit
= tms_bits
& 1;
433 tms_byte
|= (1 << tms_ndx
);
435 /* always do state transitions in public view */
436 tap_set_state(tap_state_transition(tap_get_state(), bit
));
438 /* we wrote a bit to tms_byte just above, increment bit index. if bit was zero
443 if (tms_ndx
== 7 || i
== tms_count
-1)
445 buffer_write(mpsse_cmd
);
446 buffer_write(tms_ndx
- 1);
448 /* Bit 7 of the byte is passed on to TDI/DO before the first TCK/SK of
449 TMS/CS and is held static for the duration of TMS/CS clocking.
451 buffer_write(tms_byte
| (tdi_bit
<< 7));
457 * Function get_tms_buffer_requirements
458 * returns what clock_tms() will consume if called with
461 static inline int get_tms_buffer_requirements(int bit_count
)
463 return ((bit_count
+ 6)/7) * 3;
467 * Function move_to_state
468 * moves the TAP controller from the current state to a
469 * \a goal_state through a path given by tap_get_tms_path(). State transition
470 * logging is performed by delegation to clock_tms().
472 * @param goal_state is the destination state for the move.
474 static void move_to_state(tap_state_t goal_state
)
476 tap_state_t start_state
= tap_get_state();
478 /* goal_state is 1/2 of a tuple/pair of states which allow convenient
479 lookup of the required TMS pattern to move to this state from the
483 /* do the 2 lookups */
484 int tms_bits
= tap_get_tms_path(start_state
, goal_state
);
485 int tms_count
= tap_get_tms_path_len(start_state
, goal_state
);
487 DEBUG_JTAG_IO("start=%s goal=%s", tap_state_name(start_state
), tap_state_name(goal_state
));
489 clock_tms(0x4b, tms_bits
, tms_count
, 0);
492 static int ft2232_write(uint8_t* buf
, int size
, uint32_t* bytes_written
)
494 #if BUILD_FT2232_FTD2XX == 1
496 DWORD dw_bytes_written
;
497 if ((status
= FT_Write(ftdih
, buf
, size
, &dw_bytes_written
)) != FT_OK
)
499 *bytes_written
= dw_bytes_written
;
500 LOG_ERROR("FT_Write returned: %lu", status
);
501 return ERROR_JTAG_DEVICE_ERROR
;
505 *bytes_written
= dw_bytes_written
;
507 #elif BUILD_FT2232_LIBFTDI == 1
509 if ((retval
= ftdi_write_data(&ftdic
, buf
, size
)) < 0)
512 LOG_ERROR("ftdi_write_data: %s", ftdi_get_error_string(&ftdic
));
513 return ERROR_JTAG_DEVICE_ERROR
;
517 *bytes_written
= retval
;
521 if (*bytes_written
!= (uint32_t)size
)
523 return ERROR_JTAG_DEVICE_ERROR
;
529 static int ft2232_read(uint8_t* buf
, uint32_t size
, uint32_t* bytes_read
)
531 #if BUILD_FT2232_FTD2XX == 1
537 while ((*bytes_read
< size
) && timeout
--)
539 if ((status
= FT_Read(ftdih
, buf
+ *bytes_read
, size
-
540 *bytes_read
, &dw_bytes_read
)) != FT_OK
)
543 LOG_ERROR("FT_Read returned: %lu", status
);
544 return ERROR_JTAG_DEVICE_ERROR
;
546 *bytes_read
+= dw_bytes_read
;
549 #elif BUILD_FT2232_LIBFTDI == 1
551 int timeout
= LIBFTDI_READ_RETRY_COUNT
;
554 while ((*bytes_read
< size
) && timeout
--)
556 if ((retval
= ftdi_read_data(&ftdic
, buf
+ *bytes_read
, size
- *bytes_read
)) < 0)
559 LOG_ERROR("ftdi_read_data: %s", ftdi_get_error_string(&ftdic
));
560 return ERROR_JTAG_DEVICE_ERROR
;
562 *bytes_read
+= retval
;
567 if (*bytes_read
< size
)
569 LOG_ERROR("couldn't read enough bytes from "
570 "FT2232 device (%i < %i)",
571 (unsigned)*bytes_read
,
573 return ERROR_JTAG_DEVICE_ERROR
;
579 static bool ft2232_device_is_highspeed(void)
581 #if BUILD_FT2232_FTD2XX == 1
582 return (ftdi_device
== FT_DEVICE_2232H
) || (ftdi_device
== FT_DEVICE_4232H
);
583 #elif BUILD_FT2232_LIBFTDI == 1
584 return (ftdi_device
== TYPE_2232H
|| ftdi_device
== TYPE_4232H
);
589 * Commands that only apply to the FT2232H and FT4232H devices.
590 * See chapter 6 in http://www.ftdichip.com/Documents/AppNotes/
591 * AN_108_Command_Processor_for_MPSSE_and_MCU_Host_Bus_Emulation_Modes.pdf
594 static int ft2232h_ft4232h_adaptive_clocking(bool enable
)
596 uint8_t buf
= enable
? 0x96 : 0x97;
597 LOG_DEBUG("%2.2x", buf
);
599 uint32_t bytes_written
;
602 if ((retval
= ft2232_write(&buf
, sizeof(buf
), &bytes_written
)) != ERROR_OK
)
604 LOG_ERROR("couldn't write command to %s adaptive clocking"
605 , enable
? "enable" : "disable");
613 * Enable/disable the clk divide by 5 of the 60MHz master clock.
614 * This result in a JTAG clock speed range of 91.553Hz-6MHz
615 * respective 457.763Hz-30MHz.
617 static int ft2232h_ft4232h_clk_divide_by_5(bool enable
)
619 uint32_t bytes_written
;
620 uint8_t buf
= enable
? 0x8b : 0x8a;
622 if (ft2232_write(&buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
624 LOG_ERROR("couldn't write command to %s clk divide by 5"
625 , enable
? "enable" : "disable");
626 return ERROR_JTAG_INIT_FAILED
;
628 ft2232_max_tck
= enable
? FTDI_2232C_MAX_TCK
: FTDI_2232H_4232H_MAX_TCK
;
629 LOG_INFO("max TCK change to: %u kHz", ft2232_max_tck
);
634 static int ft2232_speed(int speed
)
638 uint32_t bytes_written
;
641 bool enable_adaptive_clocking
= (RTCK_SPEED
== speed
);
642 if (ft2232_device_is_highspeed())
643 retval
= ft2232h_ft4232h_adaptive_clocking(enable_adaptive_clocking
);
644 else if (enable_adaptive_clocking
)
646 LOG_ERROR("ft2232 device %lu does not support RTCK"
647 , (long unsigned int)ftdi_device
);
651 if ((enable_adaptive_clocking
) || (ERROR_OK
!= retval
))
654 buf
[0] = 0x86; /* command "set divisor" */
655 buf
[1] = speed
& 0xff; /* valueL (0 = 6MHz, 1 = 3MHz, 2 = 2.0MHz, ...*/
656 buf
[2] = (speed
>> 8) & 0xff; /* valueH */
658 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
659 if ((retval
= ft2232_write(buf
, sizeof(buf
), &bytes_written
)) != ERROR_OK
)
661 LOG_ERROR("couldn't set FT2232 TCK speed");
668 static int ft2232_speed_div(int speed
, int* khz
)
670 /* Take a look in the FT2232 manual,
671 * AN2232C-01 Command Processor for
672 * MPSSE and MCU Host Bus. Chapter 3.8 */
674 *khz
= (RTCK_SPEED
== speed
) ? 0 : ft2232_max_tck
/ (1 + speed
);
679 static int ft2232_khz(int khz
, int* jtag_speed
)
683 if (ft2232_device_is_highspeed())
685 *jtag_speed
= RTCK_SPEED
;
690 LOG_DEBUG("RCLK not supported");
695 /* Take a look in the FT2232 manual,
696 * AN2232C-01 Command Processor for
697 * MPSSE and MCU Host Bus. Chapter 3.8
699 * We will calc here with a multiplier
700 * of 10 for better rounding later. */
702 /* Calc speed, (ft2232_max_tck / khz) - 1 */
703 /* Use 65000 for better rounding */
704 *jtag_speed
= ((ft2232_max_tck
*10) / khz
) - 10;
706 /* Add 0.9 for rounding */
709 /* Calc real speed */
710 *jtag_speed
= *jtag_speed
/ 10;
712 /* Check if speed is greater than 0 */
718 /* Check max value */
719 if (*jtag_speed
> 0xFFFF)
721 *jtag_speed
= 0xFFFF;
727 static void ft2232_end_state(tap_state_t state
)
729 if (tap_is_state_stable(state
))
730 tap_set_end_state(state
);
733 LOG_ERROR("BUG: %s is not a stable end state", tap_state_name(state
));
738 static void ft2232_read_scan(enum scan_type type
, uint8_t* buffer
, int scan_size
)
740 int num_bytes
= (scan_size
+ 7) / 8;
741 int bits_left
= scan_size
;
744 while (num_bytes
-- > 1)
746 buffer
[cur_byte
++] = buffer_read();
750 buffer
[cur_byte
] = 0x0;
752 /* There is one more partial byte left from the clock data in/out instructions */
755 buffer
[cur_byte
] = buffer_read() >> 1;
757 /* This shift depends on the length of the clock data to tms instruction, insterted at end of the scan, now fixed to a two step transition in ft2232_add_scan */
758 buffer
[cur_byte
] = (buffer
[cur_byte
] | (((buffer_read()) << 1) & 0x80)) >> (8 - bits_left
);
761 static void ft2232_debug_dump_buffer(void)
767 for (i
= 0; i
< ft2232_buffer_size
; i
++)
769 line_p
+= snprintf(line_p
, sizeof(line
) - (line_p
- line
), "%2.2x ", ft2232_buffer
[i
]);
772 LOG_DEBUG("%s", line
);
778 LOG_DEBUG("%s", line
);
781 static int ft2232_send_and_recv(struct jtag_command
* first
, struct jtag_command
* last
)
783 struct jtag_command
* cmd
;
788 uint32_t bytes_written
= 0;
789 uint32_t bytes_read
= 0;
791 #ifdef _DEBUG_USB_IO_
792 struct timeval start
, inter
, inter2
, end
;
793 struct timeval d_inter
, d_inter2
, d_end
;
796 #ifdef _DEBUG_USB_COMMS_
797 LOG_DEBUG("write buffer (size %i):", ft2232_buffer_size
);
798 ft2232_debug_dump_buffer();
801 #ifdef _DEBUG_USB_IO_
802 gettimeofday(&start
, NULL
);
805 if ((retval
= ft2232_write(ft2232_buffer
, ft2232_buffer_size
, &bytes_written
)) != ERROR_OK
)
807 LOG_ERROR("couldn't write MPSSE commands to FT2232");
811 #ifdef _DEBUG_USB_IO_
812 gettimeofday(&inter
, NULL
);
815 if (ft2232_expect_read
)
817 /* FIXME this "timeout" is never changed ... */
818 int timeout
= LIBFTDI_READ_RETRY_COUNT
;
819 ft2232_buffer_size
= 0;
821 #ifdef _DEBUG_USB_IO_
822 gettimeofday(&inter2
, NULL
);
825 if ((retval
= ft2232_read(ft2232_buffer
, ft2232_expect_read
, &bytes_read
)) != ERROR_OK
)
827 LOG_ERROR("couldn't read from FT2232");
831 #ifdef _DEBUG_USB_IO_
832 gettimeofday(&end
, NULL
);
834 timeval_subtract(&d_inter
, &inter
, &start
);
835 timeval_subtract(&d_inter2
, &inter2
, &start
);
836 timeval_subtract(&d_end
, &end
, &start
);
838 LOG_INFO("inter: %u.%06u, inter2: %u.%06u end: %u.%06u",
839 (unsigned)d_inter
.tv_sec
, (unsigned)d_inter
.tv_usec
,
840 (unsigned)d_inter2
.tv_sec
, (unsigned)d_inter2
.tv_usec
,
841 (unsigned)d_end
.tv_sec
, (unsigned)d_end
.tv_usec
);
844 ft2232_buffer_size
= bytes_read
;
846 if (ft2232_expect_read
!= ft2232_buffer_size
)
848 LOG_ERROR("ft2232_expect_read (%i) != "
849 "ft2232_buffer_size (%i) "
853 LIBFTDI_READ_RETRY_COUNT
- timeout
);
854 ft2232_debug_dump_buffer();
859 #ifdef _DEBUG_USB_COMMS_
860 LOG_DEBUG("read buffer (%i retries): %i bytes",
861 LIBFTDI_READ_RETRY_COUNT
- timeout
,
863 ft2232_debug_dump_buffer();
867 ft2232_expect_read
= 0;
868 ft2232_read_pointer
= 0;
870 /* return ERROR_OK, unless a jtag_read_buffer returns a failed check
871 * that wasn't handled by a caller-provided error handler
881 type
= jtag_scan_type(cmd
->cmd
.scan
);
882 if (type
!= SCAN_OUT
)
884 scan_size
= jtag_scan_size(cmd
->cmd
.scan
);
885 buffer
= calloc(DIV_ROUND_UP(scan_size
, 8), 1);
886 ft2232_read_scan(type
, buffer
, scan_size
);
887 if (jtag_read_buffer(buffer
, cmd
->cmd
.scan
) != ERROR_OK
)
888 retval
= ERROR_JTAG_QUEUE_FAILED
;
900 ft2232_buffer_size
= 0;
906 * Function ft2232_add_pathmove
907 * moves the TAP controller from the current state to a new state through the
908 * given path, where path is an array of tap_state_t's.
910 * @param path is an array of tap_stat_t which gives the states to traverse through
911 * ending with the last state at path[num_states-1]
912 * @param num_states is the count of state steps to move through
914 static void ft2232_add_pathmove(tap_state_t
* path
, int num_states
)
918 assert((unsigned) num_states
<= 32u); /* tms_bits only holds 32 bits */
922 /* this loop verifies that the path is legal and logs each state in the path */
925 unsigned char tms_byte
= 0; /* zero this on each MPSSE batch */
927 int num_states_batch
= num_states
> 7 ? 7 : num_states
;
929 /* command "Clock Data to TMS/CS Pin (no Read)" */
932 /* number of states remaining */
933 buffer_write(num_states_batch
- 1);
935 while (num_states_batch
--) {
936 /* either TMS=0 or TMS=1 must work ... */
937 if (tap_state_transition(tap_get_state(), false)
938 == path
[state_count
])
939 buf_set_u32(&tms_byte
, bit_count
++, 1, 0x0);
940 else if (tap_state_transition(tap_get_state(), true)
941 == path
[state_count
])
942 buf_set_u32(&tms_byte
, bit_count
++, 1, 0x1);
944 /* ... or else the caller goofed BADLY */
946 LOG_ERROR("BUG: %s -> %s isn't a valid "
947 "TAP state transition",
948 tap_state_name(tap_get_state()),
949 tap_state_name(path
[state_count
]));
953 tap_set_state(path
[state_count
]);
958 buffer_write(tms_byte
);
960 tap_set_end_state(tap_get_state());
963 static void ft2232_add_scan(bool ir_scan
, enum scan_type type
, uint8_t* buffer
, int scan_size
)
965 int num_bytes
= (scan_size
+ 7) / 8;
966 int bits_left
= scan_size
;
972 if (tap_get_state() != TAP_DRSHIFT
)
974 move_to_state(TAP_DRSHIFT
);
979 if (tap_get_state() != TAP_IRSHIFT
)
981 move_to_state(TAP_IRSHIFT
);
985 /* add command for complete bytes */
986 while (num_bytes
> 1)
991 /* Clock Data Bytes In and Out LSB First */
993 /* LOG_DEBUG("added TDI bytes (io %i)", num_bytes); */
995 else if (type
== SCAN_OUT
)
997 /* Clock Data Bytes Out on -ve Clock Edge LSB First (no Read) */
999 /* LOG_DEBUG("added TDI bytes (o)"); */
1001 else if (type
== SCAN_IN
)
1003 /* Clock Data Bytes In on +ve Clock Edge LSB First (no Write) */
1005 /* LOG_DEBUG("added TDI bytes (i %i)", num_bytes); */
1008 thisrun_bytes
= (num_bytes
> 65537) ? 65536 : (num_bytes
- 1);
1009 num_bytes
-= thisrun_bytes
;
1011 buffer_write((uint8_t) (thisrun_bytes
- 1));
1012 buffer_write((uint8_t) ((thisrun_bytes
- 1) >> 8));
1014 if (type
!= SCAN_IN
)
1016 /* add complete bytes */
1017 while (thisrun_bytes
-- > 0)
1019 buffer_write(buffer
[cur_byte
++]);
1023 else /* (type == SCAN_IN) */
1025 bits_left
-= 8 * (thisrun_bytes
);
1029 /* the most signifcant bit is scanned during TAP movement */
1030 if (type
!= SCAN_IN
)
1031 last_bit
= (buffer
[cur_byte
] >> (bits_left
- 1)) & 0x1;
1035 /* process remaining bits but the last one */
1038 if (type
== SCAN_IO
)
1040 /* Clock Data Bits In and Out LSB First */
1042 /* LOG_DEBUG("added TDI bits (io) %i", bits_left - 1); */
1044 else if (type
== SCAN_OUT
)
1046 /* Clock Data Bits Out on -ve Clock Edge LSB First (no Read) */
1048 /* LOG_DEBUG("added TDI bits (o)"); */
1050 else if (type
== SCAN_IN
)
1052 /* Clock Data Bits In on +ve Clock Edge LSB First (no Write) */
1054 /* LOG_DEBUG("added TDI bits (i %i)", bits_left - 1); */
1057 buffer_write(bits_left
- 2);
1058 if (type
!= SCAN_IN
)
1059 buffer_write(buffer
[cur_byte
]);
1062 if ((ir_scan
&& (tap_get_end_state() == TAP_IRSHIFT
))
1063 || (!ir_scan
&& (tap_get_end_state() == TAP_DRSHIFT
)))
1065 if (type
== SCAN_IO
)
1067 /* Clock Data Bits In and Out LSB First */
1069 /* LOG_DEBUG("added TDI bits (io) %i", bits_left - 1); */
1071 else if (type
== SCAN_OUT
)
1073 /* Clock Data Bits Out on -ve Clock Edge LSB First (no Read) */
1075 /* LOG_DEBUG("added TDI bits (o)"); */
1077 else if (type
== SCAN_IN
)
1079 /* Clock Data Bits In on +ve Clock Edge LSB First (no Write) */
1081 /* LOG_DEBUG("added TDI bits (i %i)", bits_left - 1); */
1084 buffer_write(last_bit
);
1092 /* move from Shift-IR/DR to end state */
1093 if (type
!= SCAN_OUT
)
1095 /* We always go to the PAUSE state in two step at the end of an IN or IO scan */
1096 /* This must be coordinated with the bit shifts in ft2232_read_scan */
1099 /* Clock Data to TMS/CS Pin with Read */
1104 tms_bits
= tap_get_tms_path(tap_get_state(), tap_get_end_state());
1105 tms_count
= tap_get_tms_path_len(tap_get_state(), tap_get_end_state());
1106 /* Clock Data to TMS/CS Pin (no Read) */
1110 DEBUG_JTAG_IO("finish %s", (type
== SCAN_OUT
) ? "without read" : "via PAUSE");
1111 clock_tms(mpsse_cmd
, tms_bits
, tms_count
, last_bit
);
1114 if (tap_get_state() != tap_get_end_state())
1116 move_to_state(tap_get_end_state());
1120 static int ft2232_large_scan(struct scan_command
* cmd
, enum scan_type type
, uint8_t* buffer
, int scan_size
)
1122 int num_bytes
= (scan_size
+ 7) / 8;
1123 int bits_left
= scan_size
;
1126 uint8_t* receive_buffer
= malloc(DIV_ROUND_UP(scan_size
, 8));
1127 uint8_t* receive_pointer
= receive_buffer
;
1128 uint32_t bytes_written
;
1129 uint32_t bytes_read
;
1131 int thisrun_read
= 0;
1135 LOG_ERROR("BUG: large IR scans are not supported");
1139 if (tap_get_state() != TAP_DRSHIFT
)
1141 move_to_state(TAP_DRSHIFT
);
1144 if ((retval
= ft2232_write(ft2232_buffer
, ft2232_buffer_size
, &bytes_written
)) != ERROR_OK
)
1146 LOG_ERROR("couldn't write MPSSE commands to FT2232");
1149 LOG_DEBUG("ft2232_buffer_size: %i, bytes_written: %i",
1150 ft2232_buffer_size
, (int)bytes_written
);
1151 ft2232_buffer_size
= 0;
1153 /* add command for complete bytes */
1154 while (num_bytes
> 1)
1158 if (type
== SCAN_IO
)
1160 /* Clock Data Bytes In and Out LSB First */
1162 /* LOG_DEBUG("added TDI bytes (io %i)", num_bytes); */
1164 else if (type
== SCAN_OUT
)
1166 /* Clock Data Bytes Out on -ve Clock Edge LSB First (no Read) */
1168 /* LOG_DEBUG("added TDI bytes (o)"); */
1170 else if (type
== SCAN_IN
)
1172 /* Clock Data Bytes In on +ve Clock Edge LSB First (no Write) */
1174 /* LOG_DEBUG("added TDI bytes (i %i)", num_bytes); */
1177 thisrun_bytes
= (num_bytes
> 65537) ? 65536 : (num_bytes
- 1);
1178 thisrun_read
= thisrun_bytes
;
1179 num_bytes
-= thisrun_bytes
;
1180 buffer_write((uint8_t) (thisrun_bytes
- 1));
1181 buffer_write((uint8_t) ((thisrun_bytes
- 1) >> 8));
1183 if (type
!= SCAN_IN
)
1185 /* add complete bytes */
1186 while (thisrun_bytes
-- > 0)
1188 buffer_write(buffer
[cur_byte
]);
1193 else /* (type == SCAN_IN) */
1195 bits_left
-= 8 * (thisrun_bytes
);
1198 if ((retval
= ft2232_write(ft2232_buffer
, ft2232_buffer_size
, &bytes_written
)) != ERROR_OK
)
1200 LOG_ERROR("couldn't write MPSSE commands to FT2232");
1203 LOG_DEBUG("ft2232_buffer_size: %i, bytes_written: %i",
1205 (int)bytes_written
);
1206 ft2232_buffer_size
= 0;
1208 if (type
!= SCAN_OUT
)
1210 if ((retval
= ft2232_read(receive_pointer
, thisrun_read
, &bytes_read
)) != ERROR_OK
)
1212 LOG_ERROR("couldn't read from FT2232");
1215 LOG_DEBUG("thisrun_read: %i, bytes_read: %i",
1218 receive_pointer
+= bytes_read
;
1224 /* the most signifcant bit is scanned during TAP movement */
1225 if (type
!= SCAN_IN
)
1226 last_bit
= (buffer
[cur_byte
] >> (bits_left
- 1)) & 0x1;
1230 /* process remaining bits but the last one */
1233 if (type
== SCAN_IO
)
1235 /* Clock Data Bits In and Out LSB First */
1237 /* LOG_DEBUG("added TDI bits (io) %i", bits_left - 1); */
1239 else if (type
== SCAN_OUT
)
1241 /* Clock Data Bits Out on -ve Clock Edge LSB First (no Read) */
1243 /* LOG_DEBUG("added TDI bits (o)"); */
1245 else if (type
== SCAN_IN
)
1247 /* Clock Data Bits In on +ve Clock Edge LSB First (no Write) */
1249 /* LOG_DEBUG("added TDI bits (i %i)", bits_left - 1); */
1251 buffer_write(bits_left
- 2);
1252 if (type
!= SCAN_IN
)
1253 buffer_write(buffer
[cur_byte
]);
1255 if (type
!= SCAN_OUT
)
1259 if (tap_get_end_state() == TAP_DRSHIFT
)
1261 if (type
== SCAN_IO
)
1263 /* Clock Data Bits In and Out LSB First */
1265 /* LOG_DEBUG("added TDI bits (io) %i", bits_left - 1); */
1267 else if (type
== SCAN_OUT
)
1269 /* Clock Data Bits Out on -ve Clock Edge LSB First (no Read) */
1271 /* LOG_DEBUG("added TDI bits (o)"); */
1273 else if (type
== SCAN_IN
)
1275 /* Clock Data Bits In on +ve Clock Edge LSB First (no Write) */
1277 /* LOG_DEBUG("added TDI bits (i %i)", bits_left - 1); */
1280 buffer_write(last_bit
);
1284 int tms_bits
= tap_get_tms_path(tap_get_state(), tap_get_end_state());
1285 int tms_count
= tap_get_tms_path_len(tap_get_state(), tap_get_end_state());
1288 /* move from Shift-IR/DR to end state */
1289 if (type
!= SCAN_OUT
)
1291 /* Clock Data to TMS/CS Pin with Read */
1293 /* LOG_DEBUG("added TMS scan (read)"); */
1297 /* Clock Data to TMS/CS Pin (no Read) */
1299 /* LOG_DEBUG("added TMS scan (no read)"); */
1302 DEBUG_JTAG_IO("finish, %s", (type
== SCAN_OUT
) ? "no read" : "read");
1303 clock_tms(mpsse_cmd
, tms_bits
, tms_count
, last_bit
);
1306 if (type
!= SCAN_OUT
)
1309 if ((retval
= ft2232_write(ft2232_buffer
, ft2232_buffer_size
, &bytes_written
)) != ERROR_OK
)
1311 LOG_ERROR("couldn't write MPSSE commands to FT2232");
1314 LOG_DEBUG("ft2232_buffer_size: %i, bytes_written: %i",
1316 (int)bytes_written
);
1317 ft2232_buffer_size
= 0;
1319 if (type
!= SCAN_OUT
)
1321 if ((retval
= ft2232_read(receive_pointer
, thisrun_read
, &bytes_read
)) != ERROR_OK
)
1323 LOG_ERROR("couldn't read from FT2232");
1326 LOG_DEBUG("thisrun_read: %i, bytes_read: %i",
1329 receive_pointer
+= bytes_read
;
1335 static int ft2232_predict_scan_out(int scan_size
, enum scan_type type
)
1337 int predicted_size
= 3;
1338 int num_bytes
= (scan_size
- 1) / 8;
1340 if (tap_get_state() != TAP_DRSHIFT
)
1341 predicted_size
+= get_tms_buffer_requirements(tap_get_tms_path_len(tap_get_state(), TAP_DRSHIFT
));
1343 if (type
== SCAN_IN
) /* only from device to host */
1345 /* complete bytes */
1346 predicted_size
+= DIV_ROUND_UP(num_bytes
, 65536) * 3;
1348 /* remaining bits - 1 (up to 7) */
1349 predicted_size
+= ((scan_size
- 1) % 8) ? 2 : 0;
1351 else /* host to device, or bidirectional */
1353 /* complete bytes */
1354 predicted_size
+= num_bytes
+ DIV_ROUND_UP(num_bytes
, 65536) * 3;
1356 /* remaining bits -1 (up to 7) */
1357 predicted_size
+= ((scan_size
- 1) % 8) ? 3 : 0;
1360 return predicted_size
;
1363 static int ft2232_predict_scan_in(int scan_size
, enum scan_type type
)
1365 int predicted_size
= 0;
1367 if (type
!= SCAN_OUT
)
1369 /* complete bytes */
1370 predicted_size
+= (DIV_ROUND_UP(scan_size
, 8) > 1) ? (DIV_ROUND_UP(scan_size
, 8) - 1) : 0;
1372 /* remaining bits - 1 */
1373 predicted_size
+= ((scan_size
- 1) % 8) ? 1 : 0;
1375 /* last bit (from TMS scan) */
1376 predicted_size
+= 1;
1379 /* LOG_DEBUG("scan_size: %i, predicted_size: %i", scan_size, predicted_size); */
1381 return predicted_size
;
1384 /* semi-generic FT2232/FT4232 reset code */
1385 static void ftx23_reset(int trst
, int srst
)
1387 enum reset_types jtag_reset_config
= jtag_get_reset_config();
1390 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
1391 low_direction
|= nTRSTnOE
; /* switch to output pin (output is low) */
1393 low_output
&= ~nTRST
; /* switch output low */
1397 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
1398 low_direction
&= ~nTRSTnOE
; /* switch to input pin (high-Z + internal and external pullup) */
1400 low_output
|= nTRST
; /* switch output high */
1405 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
1406 low_output
&= ~nSRST
; /* switch output low */
1408 low_direction
|= nSRSTnOE
; /* switch to output pin (output is low) */
1412 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
1413 low_output
|= nSRST
; /* switch output high */
1415 low_direction
&= ~nSRSTnOE
; /* switch to input pin (high-Z) */
1418 /* command "set data bits low byte" */
1420 buffer_write(low_output
);
1421 buffer_write(low_direction
);
1424 static void jtagkey_reset(int trst
, int srst
)
1426 enum reset_types jtag_reset_config
= jtag_get_reset_config();
1429 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
1430 high_output
&= ~nTRSTnOE
;
1432 high_output
&= ~nTRST
;
1436 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
1437 high_output
|= nTRSTnOE
;
1439 high_output
|= nTRST
;
1444 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
1445 high_output
&= ~nSRST
;
1447 high_output
&= ~nSRSTnOE
;
1451 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
1452 high_output
|= nSRST
;
1454 high_output
|= nSRSTnOE
;
1457 /* command "set data bits high byte" */
1459 buffer_write(high_output
);
1460 buffer_write(high_direction
);
1461 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, high_direction: 0x%2.2x", trst
, srst
, high_output
,
1465 static void olimex_jtag_reset(int trst
, int srst
)
1467 enum reset_types jtag_reset_config
= jtag_get_reset_config();
1470 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
1471 high_output
&= ~nTRSTnOE
;
1473 high_output
&= ~nTRST
;
1477 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
1478 high_output
|= nTRSTnOE
;
1480 high_output
|= nTRST
;
1485 high_output
|= nSRST
;
1489 high_output
&= ~nSRST
;
1492 /* command "set data bits high byte" */
1494 buffer_write(high_output
);
1495 buffer_write(high_direction
);
1496 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, high_direction: 0x%2.2x", trst
, srst
, high_output
,
1500 static void axm0432_jtag_reset(int trst
, int srst
)
1504 tap_set_state(TAP_RESET
);
1505 high_output
&= ~nTRST
;
1509 high_output
|= nTRST
;
1514 high_output
&= ~nSRST
;
1518 high_output
|= nSRST
;
1521 /* command "set data bits low byte" */
1523 buffer_write(high_output
);
1524 buffer_write(high_direction
);
1525 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, high_direction: 0x%2.2x", trst
, srst
, high_output
,
1529 static void flyswatter_reset(int trst
, int srst
)
1533 low_output
&= ~nTRST
;
1537 low_output
|= nTRST
;
1542 low_output
|= nSRST
;
1546 low_output
&= ~nSRST
;
1549 /* command "set data bits low byte" */
1551 buffer_write(low_output
);
1552 buffer_write(low_direction
);
1553 LOG_DEBUG("trst: %i, srst: %i, low_output: 0x%2.2x, low_direction: 0x%2.2x", trst
, srst
, low_output
, low_direction
);
1556 static void turtle_reset(int trst
, int srst
)
1562 low_output
|= nSRST
;
1566 low_output
&= ~nSRST
;
1569 /* command "set data bits low byte" */
1571 buffer_write(low_output
);
1572 buffer_write(low_direction
);
1573 LOG_DEBUG("srst: %i, low_output: 0x%2.2x, low_direction: 0x%2.2x", srst
, low_output
, low_direction
);
1576 static void comstick_reset(int trst
, int srst
)
1580 high_output
&= ~nTRST
;
1584 high_output
|= nTRST
;
1589 high_output
&= ~nSRST
;
1593 high_output
|= nSRST
;
1596 /* command "set data bits high byte" */
1598 buffer_write(high_output
);
1599 buffer_write(high_direction
);
1600 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, high_direction: 0x%2.2x", trst
, srst
, high_output
,
1604 static void stm32stick_reset(int trst
, int srst
)
1608 high_output
&= ~nTRST
;
1612 high_output
|= nTRST
;
1617 low_output
&= ~nSRST
;
1621 low_output
|= nSRST
;
1624 /* command "set data bits low byte" */
1626 buffer_write(low_output
);
1627 buffer_write(low_direction
);
1629 /* command "set data bits high byte" */
1631 buffer_write(high_output
);
1632 buffer_write(high_direction
);
1633 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, high_direction: 0x%2.2x", trst
, srst
, high_output
,
1637 static void sheevaplug_reset(int trst
, int srst
)
1640 high_output
&= ~nTRST
;
1642 high_output
|= nTRST
;
1645 high_output
&= ~nSRSTnOE
;
1647 high_output
|= nSRSTnOE
;
1649 /* command "set data bits high byte" */
1651 buffer_write(high_output
);
1652 buffer_write(high_direction
);
1653 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, high_direction: 0x%2.2x", trst
, srst
, high_output
, high_direction
);
1656 static void redbee_reset(int trst
, int srst
)
1660 tap_set_state(TAP_RESET
);
1661 high_output
&= ~nTRST
;
1665 high_output
|= nTRST
;
1670 high_output
&= ~nSRST
;
1674 high_output
|= nSRST
;
1677 /* command "set data bits low byte" */
1679 buffer_write(high_output
);
1680 buffer_write(high_direction
);
1681 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, "
1682 "high_direction: 0x%2.2x", trst
, srst
, high_output
,
1686 static int ft2232_execute_runtest(struct jtag_command
*cmd
)
1690 int predicted_size
= 0;
1693 DEBUG_JTAG_IO("runtest %i cycles, end in %s",
1694 cmd
->cmd
.runtest
->num_cycles
,
1695 tap_state_name(cmd
->cmd
.runtest
->end_state
));
1697 /* only send the maximum buffer size that FT2232C can handle */
1699 if (tap_get_state() != TAP_IDLE
)
1700 predicted_size
+= 3;
1701 predicted_size
+= 3 * DIV_ROUND_UP(cmd
->cmd
.runtest
->num_cycles
, 7);
1702 if (cmd
->cmd
.runtest
->end_state
!= TAP_IDLE
)
1703 predicted_size
+= 3;
1704 if (tap_get_end_state() != TAP_IDLE
)
1705 predicted_size
+= 3;
1706 if (ft2232_buffer_size
+ predicted_size
+ 1 > FT2232_BUFFER_SIZE
)
1708 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1709 retval
= ERROR_JTAG_QUEUE_FAILED
;
1713 if (tap_get_state() != TAP_IDLE
)
1715 move_to_state(TAP_IDLE
);
1718 i
= cmd
->cmd
.runtest
->num_cycles
;
1721 /* there are no state transitions in this code, so omit state tracking */
1723 /* command "Clock Data to TMS/CS Pin (no Read)" */
1727 buffer_write((i
> 7) ? 6 : (i
- 1));
1732 i
-= (i
> 7) ? 7 : i
;
1733 /* LOG_DEBUG("added TMS scan (no read)"); */
1736 ft2232_end_state(cmd
->cmd
.runtest
->end_state
);
1738 if (tap_get_state() != tap_get_end_state())
1740 move_to_state(tap_get_end_state());
1744 DEBUG_JTAG_IO("runtest: %i, end in %s",
1745 cmd
->cmd
.runtest
->num_cycles
,
1746 tap_state_name(tap_get_end_state()));
1750 static int ft2232_execute_statemove(struct jtag_command
*cmd
)
1752 int predicted_size
= 0;
1753 int retval
= ERROR_OK
;
1755 DEBUG_JTAG_IO("statemove end in %s",
1756 tap_state_name(cmd
->cmd
.statemove
->end_state
));
1758 /* only send the maximum buffer size that FT2232C can handle */
1760 if (ft2232_buffer_size
+ predicted_size
+ 1 > FT2232_BUFFER_SIZE
)
1762 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1763 retval
= ERROR_JTAG_QUEUE_FAILED
;
1767 ft2232_end_state(cmd
->cmd
.statemove
->end_state
);
1769 /* For TAP_RESET, ignore the current recorded state. It's often
1770 * wrong at server startup, and this transation is critical whenever
1773 if (tap_get_end_state() == TAP_RESET
) {
1774 clock_tms(0x4b, 0xff, 5, 0);
1777 /* shortest-path move to desired end state */
1778 } else if (tap_get_state() != tap_get_end_state())
1780 move_to_state(tap_get_end_state());
1788 * Clock a bunch of TMS (or SWDIO) transitions, to change the JTAG
1789 * (or SWD) state machine.
1791 static int ft2232_execute_tms(struct jtag_command
*cmd
)
1793 int retval
= ERROR_OK
;
1794 unsigned num_bits
= cmd
->cmd
.tms
->num_bits
;
1795 const uint8_t *bits
= cmd
->cmd
.tms
->bits
;
1798 DEBUG_JTAG_IO("TMS: %d bits", num_bits
);
1800 /* only send the maximum buffer size that FT2232C can handle */
1801 count
= 3 * DIV_ROUND_UP(num_bits
, 4);
1802 if (ft2232_buffer_size
+ 3*count
+ 1 > FT2232_BUFFER_SIZE
) {
1803 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1804 retval
= ERROR_JTAG_QUEUE_FAILED
;
1810 /* Shift out in batches of at most 6 bits; there's a report of an
1811 * FT2232 bug in this area, where shifting exactly 7 bits can make
1812 * problems with TMS signaling for the last clock cycle:
1814 * http://developer.intra2net.com/mailarchive/html/
1815 * libftdi/2009/msg00292.html
1817 * Command 0x4b is: "Clock Data to TMS/CS Pin (no Read)"
1819 * Note that pathmoves in JTAG are not often seven bits, so that
1820 * isn't a particularly likely situation outside of "special"
1821 * signaling such as switching between JTAG and SWD modes.
1824 if (num_bits
<= 6) {
1826 buffer_write(num_bits
- 1);
1827 buffer_write(*bits
& 0x3f);
1831 /* Yes, this is lazy ... we COULD shift out more data
1832 * bits per operation, but doing it in nybbles is easy
1836 buffer_write(*bits
& 0xf);
1839 count
= (num_bits
> 4) ? 4 : num_bits
;
1842 buffer_write(count
- 1);
1843 buffer_write((*bits
>> 4) & 0xf);
1853 static int ft2232_execute_pathmove(struct jtag_command
*cmd
)
1855 int predicted_size
= 0;
1856 int retval
= ERROR_OK
;
1858 tap_state_t
* path
= cmd
->cmd
.pathmove
->path
;
1859 int num_states
= cmd
->cmd
.pathmove
->num_states
;
1861 DEBUG_JTAG_IO("pathmove: %i states, current: %s end: %s", num_states
,
1862 tap_state_name(tap_get_state()),
1863 tap_state_name(path
[num_states
-1]));
1865 /* only send the maximum buffer size that FT2232C can handle */
1866 predicted_size
= 3 * DIV_ROUND_UP(num_states
, 7);
1867 if (ft2232_buffer_size
+ predicted_size
+ 1 > FT2232_BUFFER_SIZE
)
1869 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1870 retval
= ERROR_JTAG_QUEUE_FAILED
;
1876 ft2232_add_pathmove(path
, num_states
);
1882 static int ft2232_execute_scan(struct jtag_command
*cmd
)
1885 int scan_size
; /* size of IR or DR scan */
1886 int predicted_size
= 0;
1887 int retval
= ERROR_OK
;
1889 enum scan_type type
= jtag_scan_type(cmd
->cmd
.scan
);
1891 DEBUG_JTAG_IO("%s type:%d", cmd
->cmd
.scan
->ir_scan
? "IRSCAN" : "DRSCAN", type
);
1893 scan_size
= jtag_build_buffer(cmd
->cmd
.scan
, &buffer
);
1895 predicted_size
= ft2232_predict_scan_out(scan_size
, type
);
1896 if ((predicted_size
+ 1) > FT2232_BUFFER_SIZE
)
1898 LOG_DEBUG("oversized ft2232 scan (predicted_size > FT2232_BUFFER_SIZE)");
1899 /* unsent commands before this */
1900 if (first_unsent
!= cmd
)
1901 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1902 retval
= ERROR_JTAG_QUEUE_FAILED
;
1904 /* current command */
1905 ft2232_end_state(cmd
->cmd
.scan
->end_state
);
1906 ft2232_large_scan(cmd
->cmd
.scan
, type
, buffer
, scan_size
);
1908 first_unsent
= cmd
->next
;
1913 else if (ft2232_buffer_size
+ predicted_size
+ 1 > FT2232_BUFFER_SIZE
)
1915 LOG_DEBUG("ft2232 buffer size reached, sending queued commands (first_unsent: %p, cmd: %p)",
1918 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1919 retval
= ERROR_JTAG_QUEUE_FAILED
;
1923 ft2232_expect_read
+= ft2232_predict_scan_in(scan_size
, type
);
1924 /* LOG_DEBUG("new read size: %i", ft2232_expect_read); */
1925 ft2232_end_state(cmd
->cmd
.scan
->end_state
);
1926 ft2232_add_scan(cmd
->cmd
.scan
->ir_scan
, type
, buffer
, scan_size
);
1930 DEBUG_JTAG_IO("%s scan, %i bits, end in %s",
1931 (cmd
->cmd
.scan
->ir_scan
) ? "IR" : "DR", scan_size
,
1932 tap_state_name(tap_get_end_state()));
1937 static int ft2232_execute_reset(struct jtag_command
*cmd
)
1940 int predicted_size
= 0;
1943 DEBUG_JTAG_IO("reset trst: %i srst %i",
1944 cmd
->cmd
.reset
->trst
, cmd
->cmd
.reset
->srst
);
1946 /* only send the maximum buffer size that FT2232C can handle */
1948 if (ft2232_buffer_size
+ predicted_size
+ 1 > FT2232_BUFFER_SIZE
)
1950 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1951 retval
= ERROR_JTAG_QUEUE_FAILED
;
1956 if ((cmd
->cmd
.reset
->trst
== 1) || (cmd
->cmd
.reset
->srst
&& (jtag_get_reset_config() & RESET_SRST_PULLS_TRST
)))
1958 tap_set_state(TAP_RESET
);
1961 layout
->reset(cmd
->cmd
.reset
->trst
, cmd
->cmd
.reset
->srst
);
1964 DEBUG_JTAG_IO("trst: %i, srst: %i",
1965 cmd
->cmd
.reset
->trst
, cmd
->cmd
.reset
->srst
);
1969 static int ft2232_execute_sleep(struct jtag_command
*cmd
)
1974 DEBUG_JTAG_IO("sleep %" PRIi32
, cmd
->cmd
.sleep
->us
);
1976 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
1977 retval
= ERROR_JTAG_QUEUE_FAILED
;
1978 first_unsent
= cmd
->next
;
1979 jtag_sleep(cmd
->cmd
.sleep
->us
);
1980 DEBUG_JTAG_IO("sleep %" PRIi32
" usec while in %s",
1982 tap_state_name(tap_get_state()));
1986 static int ft2232_execute_stableclocks(struct jtag_command
*cmd
)
1991 /* this is only allowed while in a stable state. A check for a stable
1992 * state was done in jtag_add_clocks()
1994 if (ft2232_stableclocks(cmd
->cmd
.stableclocks
->num_cycles
, cmd
) != ERROR_OK
)
1995 retval
= ERROR_JTAG_QUEUE_FAILED
;
1996 DEBUG_JTAG_IO("clocks %i while in %s",
1997 cmd
->cmd
.stableclocks
->num_cycles
,
1998 tap_state_name(tap_get_state()));
2002 static int ft2232_execute_command(struct jtag_command
*cmd
)
2008 case JTAG_RESET
: retval
= ft2232_execute_reset(cmd
); break;
2009 case JTAG_RUNTEST
: retval
= ft2232_execute_runtest(cmd
); break;
2010 case JTAG_TLR_RESET
: retval
= ft2232_execute_statemove(cmd
); break;
2011 case JTAG_PATHMOVE
: retval
= ft2232_execute_pathmove(cmd
); break;
2012 case JTAG_SCAN
: retval
= ft2232_execute_scan(cmd
); break;
2013 case JTAG_SLEEP
: retval
= ft2232_execute_sleep(cmd
); break;
2014 case JTAG_STABLECLOCKS
: retval
= ft2232_execute_stableclocks(cmd
); break;
2016 retval
= ft2232_execute_tms(cmd
);
2019 LOG_ERROR("BUG: unknown JTAG command type encountered");
2020 retval
= ERROR_JTAG_QUEUE_FAILED
;
2026 static int ft2232_execute_queue(void)
2028 struct jtag_command
* cmd
= jtag_command_queue
; /* currently processed command */
2031 first_unsent
= cmd
; /* next command that has to be sent */
2034 /* return ERROR_OK, unless ft2232_send_and_recv reports a failed check
2035 * that wasn't handled by a caller-provided error handler
2039 ft2232_buffer_size
= 0;
2040 ft2232_expect_read
= 0;
2042 /* blink, if the current layout has that feature */
2048 if (ft2232_execute_command(cmd
) != ERROR_OK
)
2049 retval
= ERROR_JTAG_QUEUE_FAILED
;
2050 /* Start reading input before FT2232 TX buffer fills up */
2052 if (ft2232_expect_read
> 256)
2054 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
2055 retval
= ERROR_JTAG_QUEUE_FAILED
;
2060 if (require_send
> 0)
2061 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
2062 retval
= ERROR_JTAG_QUEUE_FAILED
;
2067 #if BUILD_FT2232_FTD2XX == 1
2068 static int ft2232_init_ftd2xx(uint16_t vid
, uint16_t pid
, int more
, int* try_more
)
2072 char SerialNumber
[16];
2073 char Description
[64];
2074 DWORD openex_flags
= 0;
2075 char* openex_string
= NULL
;
2076 uint8_t latency_timer
;
2078 if (layout
== NULL
) {
2079 LOG_WARNING("No ft2232 layout specified'");
2080 return ERROR_JTAG_INIT_FAILED
;
2083 LOG_DEBUG("'ft2232' interface using FTD2XX with '%s' layout (%4.4x:%4.4x)", layout
->name
, vid
, pid
);
2086 /* Add non-standard Vid/Pid to the linux driver */
2087 if ((status
= FT_SetVIDPID(vid
, pid
)) != FT_OK
)
2089 LOG_WARNING("couldn't add %4.4x:%4.4x", vid
, pid
);
2093 if (ft2232_device_desc
&& ft2232_serial
)
2095 LOG_WARNING("can't open by device description and serial number, giving precedence to serial");
2096 ft2232_device_desc
= NULL
;
2099 if (ft2232_device_desc
)
2101 openex_string
= ft2232_device_desc
;
2102 openex_flags
= FT_OPEN_BY_DESCRIPTION
;
2104 else if (ft2232_serial
)
2106 openex_string
= ft2232_serial
;
2107 openex_flags
= FT_OPEN_BY_SERIAL_NUMBER
;
2111 LOG_ERROR("neither device description nor serial number specified");
2112 LOG_ERROR("please add \"ft2232_device_desc <string>\" or \"ft2232_serial <string>\" to your .cfg file");
2114 return ERROR_JTAG_INIT_FAILED
;
2117 status
= FT_OpenEx(openex_string
, openex_flags
, &ftdih
);
2118 if (status
!= FT_OK
) {
2119 /* under Win32, the FTD2XX driver appends an "A" to the end
2120 * of the description, if we tried by the desc, then
2121 * try by the alternate "A" description. */
2122 if (openex_string
== ft2232_device_desc
) {
2123 /* Try the alternate method. */
2124 openex_string
= ft2232_device_desc_A
;
2125 status
= FT_OpenEx(openex_string
, openex_flags
, &ftdih
);
2126 if (status
== FT_OK
) {
2127 /* yea, the "alternate" method worked! */
2129 /* drat, give the user a meaningfull message.
2130 * telling the use we tried *BOTH* methods. */
2131 LOG_WARNING("Unable to open FTDI Device tried: '%s' and '%s'\n",
2133 ft2232_device_desc_A
);
2138 if (status
!= FT_OK
)
2144 LOG_WARNING("unable to open ftdi device (trying more): %lu", status
);
2146 return ERROR_JTAG_INIT_FAILED
;
2148 LOG_ERROR("unable to open ftdi device: %lu", status
);
2149 status
= FT_ListDevices(&num_devices
, NULL
, FT_LIST_NUMBER_ONLY
);
2150 if (status
== FT_OK
)
2152 char** desc_array
= malloc(sizeof(char*) * (num_devices
+ 1));
2155 for (i
= 0; i
< num_devices
; i
++)
2156 desc_array
[i
] = malloc(64);
2158 desc_array
[num_devices
] = NULL
;
2160 status
= FT_ListDevices(desc_array
, &num_devices
, FT_LIST_ALL
| openex_flags
);
2162 if (status
== FT_OK
)
2164 LOG_ERROR("ListDevices: %lu\n", num_devices
);
2165 for (i
= 0; i
< num_devices
; i
++)
2166 LOG_ERROR("%" PRIu32
": \"%s\"", i
, desc_array
[i
]);
2169 for (i
= 0; i
< num_devices
; i
++)
2170 free(desc_array
[i
]);
2176 LOG_ERROR("ListDevices: NONE\n");
2178 return ERROR_JTAG_INIT_FAILED
;
2181 if ((status
= FT_SetLatencyTimer(ftdih
, ft2232_latency
)) != FT_OK
)
2183 LOG_ERROR("unable to set latency timer: %lu", status
);
2184 return ERROR_JTAG_INIT_FAILED
;
2187 if ((status
= FT_GetLatencyTimer(ftdih
, &latency_timer
)) != FT_OK
)
2189 LOG_ERROR("unable to get latency timer: %lu", status
);
2190 return ERROR_JTAG_INIT_FAILED
;
2194 LOG_DEBUG("current latency timer: %i", latency_timer
);
2197 if ((status
= FT_SetTimeouts(ftdih
, 5000, 5000)) != FT_OK
)
2199 LOG_ERROR("unable to set timeouts: %lu", status
);
2200 return ERROR_JTAG_INIT_FAILED
;
2203 if ((status
= FT_SetBitMode(ftdih
, 0x0b, 2)) != FT_OK
)
2205 LOG_ERROR("unable to enable bit i/o mode: %lu", status
);
2206 return ERROR_JTAG_INIT_FAILED
;
2209 if ((status
= FT_GetDeviceInfo(ftdih
, &ftdi_device
, &deviceID
, SerialNumber
, Description
, NULL
)) != FT_OK
)
2211 LOG_ERROR("unable to get FT_GetDeviceInfo: %lu", status
);
2212 return ERROR_JTAG_INIT_FAILED
;
2216 static const char* type_str
[] =
2217 {"BM", "AM", "100AX", "UNKNOWN", "2232C", "232R", "2232H", "4232H"};
2218 unsigned no_of_known_types
= ARRAY_SIZE(type_str
) - 1;
2219 unsigned type_index
= ((unsigned)ftdi_device
<= no_of_known_types
)
2220 ? ftdi_device
: FT_DEVICE_UNKNOWN
;
2221 LOG_INFO("device: %lu \"%s\"", ftdi_device
, type_str
[type_index
]);
2222 LOG_INFO("deviceID: %lu", deviceID
);
2223 LOG_INFO("SerialNumber: %s", SerialNumber
);
2224 LOG_INFO("Description: %s", Description
);
2230 static int ft2232_purge_ftd2xx(void)
2234 if ((status
= FT_Purge(ftdih
, FT_PURGE_RX
| FT_PURGE_TX
)) != FT_OK
)
2236 LOG_ERROR("error purging ftd2xx device: %lu", status
);
2237 return ERROR_JTAG_INIT_FAILED
;
2243 #endif /* BUILD_FT2232_FTD2XX == 1 */
2245 #if BUILD_FT2232_LIBFTDI == 1
2246 static int ft2232_init_libftdi(uint16_t vid
, uint16_t pid
, int more
, int* try_more
, int channel
)
2248 uint8_t latency_timer
;
2250 if (layout
== NULL
) {
2251 LOG_WARNING("No ft2232 layout specified'");
2252 return ERROR_JTAG_INIT_FAILED
;
2255 LOG_DEBUG("'ft2232' interface using libftdi with '%s' layout (%4.4x:%4.4x)",
2256 layout
->name
, vid
, pid
);
2258 if (ftdi_init(&ftdic
) < 0)
2259 return ERROR_JTAG_INIT_FAILED
;
2261 /* default to INTERFACE_A */
2262 if(channel
== INTERFACE_ANY
) { channel
= INTERFACE_A
; }
2264 if (ftdi_set_interface(&ftdic
, channel
) < 0)
2266 LOG_ERROR("unable to select FT2232 channel A: %s", ftdic
.error_str
);
2267 return ERROR_JTAG_INIT_FAILED
;
2270 /* context, vendor id, product id */
2271 if (ftdi_usb_open_desc(&ftdic
, vid
, pid
, ft2232_device_desc
,
2275 LOG_WARNING("unable to open ftdi device (trying more): %s",
2278 LOG_ERROR("unable to open ftdi device: %s", ftdic
.error_str
);
2280 return ERROR_JTAG_INIT_FAILED
;
2283 /* There is already a reset in ftdi_usb_open_desc, this should be redundant */
2284 if (ftdi_usb_reset(&ftdic
) < 0)
2286 LOG_ERROR("unable to reset ftdi device");
2287 return ERROR_JTAG_INIT_FAILED
;
2290 if (ftdi_set_latency_timer(&ftdic
, ft2232_latency
) < 0)
2292 LOG_ERROR("unable to set latency timer");
2293 return ERROR_JTAG_INIT_FAILED
;
2296 if (ftdi_get_latency_timer(&ftdic
, &latency_timer
) < 0)
2298 LOG_ERROR("unable to get latency timer");
2299 return ERROR_JTAG_INIT_FAILED
;
2303 LOG_DEBUG("current latency timer: %i", latency_timer
);
2306 ftdi_set_bitmode(&ftdic
, 0x0b, 2); /* ctx, JTAG I/O mask */
2308 ftdi_device
= ftdic
.type
;
2309 static const char* type_str
[] =
2310 {"AM", "BM", "2232C", "R", "2232H", "4232H", "Unknown"};
2311 unsigned no_of_known_types
= ARRAY_SIZE(type_str
) - 1;
2312 unsigned type_index
= ((unsigned)ftdi_device
< no_of_known_types
)
2313 ? ftdi_device
: no_of_known_types
;
2314 LOG_DEBUG("FTDI chip type: %i \"%s\"", (int)ftdi_device
, type_str
[type_index
]);
2318 static int ft2232_purge_libftdi(void)
2320 if (ftdi_usb_purge_buffers(&ftdic
) < 0)
2322 LOG_ERROR("ftdi_purge_buffers: %s", ftdic
.error_str
);
2323 return ERROR_JTAG_INIT_FAILED
;
2329 #endif /* BUILD_FT2232_LIBFTDI == 1 */
2331 static int ft2232_init(void)
2335 uint32_t bytes_written
;
2337 if (tap_get_tms_path_len(TAP_IRPAUSE
,TAP_IRPAUSE
) == 7)
2339 LOG_DEBUG("ft2232 interface using 7 step jtag state transitions");
2343 LOG_DEBUG("ft2232 interface using shortest path jtag state transitions");
2346 if (layout
== NULL
) {
2347 LOG_WARNING("No ft2232 layout specified'");
2348 return ERROR_JTAG_INIT_FAILED
;
2351 for (int i
= 0; 1; i
++)
2354 * "more indicates that there are more IDs to try, so we should
2355 * not print an error for an ID mismatch (but for anything
2358 * try_more indicates that the error code returned indicates an
2359 * ID mismatch (and nothing else) and that we should proceeed
2360 * with the next ID pair.
2362 int more
= ft2232_vid
[i
+ 1] || ft2232_pid
[i
+ 1];
2365 #if BUILD_FT2232_FTD2XX == 1
2366 retval
= ft2232_init_ftd2xx(ft2232_vid
[i
], ft2232_pid
[i
],
2368 #elif BUILD_FT2232_LIBFTDI == 1
2369 retval
= ft2232_init_libftdi(ft2232_vid
[i
], ft2232_pid
[i
],
2370 more
, &try_more
, layout
->channel
);
2374 if (!more
|| !try_more
)
2378 ft2232_buffer_size
= 0;
2379 ft2232_buffer
= malloc(FT2232_BUFFER_SIZE
);
2381 if (layout
->init() != ERROR_OK
)
2382 return ERROR_JTAG_INIT_FAILED
;
2384 if (ft2232_device_is_highspeed())
2386 #ifndef BUILD_FT2232_HIGHSPEED
2387 #if BUILD_FT2232_FTD2XX == 1
2388 LOG_WARNING("High Speed device found - You need a newer FTD2XX driver (version 2.04.16 or later)");
2389 #elif BUILD_FT2232_LIBFTDI == 1
2390 LOG_WARNING("High Speed device found - You need a newer libftdi version (0.16 or later)");
2393 /* make sure the legacy mode is disabled */
2394 if (ft2232h_ft4232h_clk_divide_by_5(false) != ERROR_OK
)
2395 return ERROR_JTAG_INIT_FAILED
;
2399 int retval
= jtag_get_speed(&jtag_speed_var
);
2400 if (retval
!= ERROR_OK
)
2402 ft2232_speed(jtag_speed_var
);
2404 buf
[0] = 0x85; /* Disconnect TDI/DO to TDO/DI for Loopback */
2405 if ((retval
= ft2232_write(buf
, 1, &bytes_written
)) != ERROR_OK
)
2407 LOG_ERROR("couldn't write to FT2232 to disable loopback");
2408 return ERROR_JTAG_INIT_FAILED
;
2411 #if BUILD_FT2232_FTD2XX == 1
2412 return ft2232_purge_ftd2xx();
2413 #elif BUILD_FT2232_LIBFTDI == 1
2414 return ft2232_purge_libftdi();
2420 /** Updates defaults for DBUS signals: the four JTAG signals
2421 * (TCK, TDI, TDO, TMS) and * the four GPIOL signals.
2423 static inline void ftx232_dbus_init(void)
2426 low_direction
= 0x0b;
2429 /** Initializes DBUS signals: the four JTAG signals (TCK, TDI, TDO, TMS),
2430 * the four GPIOL signals. Initialization covers value and direction,
2431 * as customized for each layout.
2433 static int ftx232_dbus_write(void)
2436 uint32_t bytes_written
;
2438 enum reset_types jtag_reset_config
= jtag_get_reset_config();
2439 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
2441 low_direction
&= ~nTRSTnOE
; /* nTRST input */
2442 low_output
&= ~nTRST
; /* nTRST = 0 */
2446 low_direction
|= nTRSTnOE
; /* nTRST output */
2447 low_output
|= nTRST
; /* nTRST = 1 */
2450 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
2452 low_direction
|= nSRSTnOE
; /* nSRST output */
2453 low_output
|= nSRST
; /* nSRST = 1 */
2457 low_direction
&= ~nSRSTnOE
; /* nSRST input */
2458 low_output
&= ~nSRST
; /* nSRST = 0 */
2461 /* initialize low byte for jtag */
2462 buf
[0] = 0x80; /* command "set data bits low byte" */
2463 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, xRST high) */
2464 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in */
2465 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2467 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2469 LOG_ERROR("couldn't initialize FT2232 DBUS");
2470 return ERROR_JTAG_INIT_FAILED
;
2476 static int usbjtag_init(void)
2479 * NOTE: This is now _specific_ to the "usbjtag" layout.
2480 * Don't try cram any more layouts into this.
2489 return ftx232_dbus_write();
2492 static int lm3s811_jtag_init(void)
2496 /* There are multiple revisions of LM3S811 eval boards:
2497 * - Rev B (and older?) boards have no SWO trace support.
2498 * - Rev C boards add ADBUS_6 DBG_ENn and BDBUS_4 SWO_EN;
2499 * they should use the "luminary_icdi" layout instead.
2506 low_direction
= 0x8b;
2508 return ftx232_dbus_write();
2511 static int icdi_jtag_init(void)
2515 /* Most Luminary eval boards support SWO trace output,
2516 * and should use this "luminary_icdi" layout.
2518 * ADBUS 0..3 are used for JTAG as usual. GPIOs are used
2519 * to switch between JTAG and SWD, or switch the ft2232 UART
2520 * on the second MPSSE channel/interface (BDBUS)
2521 * between (i) the stellaris UART (on Luminary boards)
2522 * or (ii) SWO trace data (generic).
2524 * We come up in JTAG mode and may switch to SWD later (with
2525 * SWO/trace option if SWD is active).
2532 #define ICDI_JTAG_EN (1 << 7) /* ADBUS 7 (a.k.a. DBGMOD) */
2533 #define ICDI_DBG_ENn (1 << 6) /* ADBUS 6 */
2534 #define ICDI_SRST (1 << 5) /* ADBUS 5 */
2537 /* GPIOs on second channel/interface (UART) ... */
2538 #define ICDI_SWO_EN (1 << 4) /* BDBUS 4 */
2539 #define ICDI_TX_SWO (1 << 1) /* BDBUS 1 */
2540 #define ICDI_VCP_RX (1 << 0) /* BDBUS 0 (to stellaris UART) */
2545 nSRSTnOE
= ICDI_SRST
;
2547 low_direction
|= ICDI_JTAG_EN
| ICDI_DBG_ENn
;
2548 low_output
|= ICDI_JTAG_EN
;
2549 low_output
&= ~ICDI_DBG_ENn
;
2551 return ftx232_dbus_write();
2554 static int signalyzer_init(void)
2562 return ftx232_dbus_write();
2565 static int axm0432_jtag_init(void)
2568 uint32_t bytes_written
;
2571 low_direction
= 0x2b;
2573 /* initialize low byte for jtag */
2574 buf
[0] = 0x80; /* command "set data bits low byte" */
2575 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2576 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
2577 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2579 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2581 LOG_ERROR("couldn't initialize FT2232 with 'JTAGkey' layout");
2582 return ERROR_JTAG_INIT_FAILED
;
2585 if (strcmp(layout
->name
, "axm0432_jtag") == 0)
2588 nTRSTnOE
= 0x0; /* No output enable for TRST*/
2590 nSRSTnOE
= 0x0; /* No output enable for SRST*/
2594 LOG_ERROR("BUG: axm0432_jtag_init called for non axm0432 layout");
2599 high_direction
= 0x0c;
2601 enum reset_types jtag_reset_config
= jtag_get_reset_config();
2602 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
2604 LOG_ERROR("can't set nTRSTOE to push-pull on the Dicarlo jtag");
2608 high_output
|= nTRST
;
2611 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
2613 LOG_ERROR("can't set nSRST to push-pull on the Dicarlo jtag");
2617 high_output
|= nSRST
;
2620 /* initialize high port */
2621 buf
[0] = 0x82; /* command "set data bits high byte" */
2622 buf
[1] = high_output
; /* value */
2623 buf
[2] = high_direction
; /* all outputs (xRST and xRSTnOE) */
2624 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2626 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2628 LOG_ERROR("couldn't initialize FT2232 with 'Dicarlo' layout");
2629 return ERROR_JTAG_INIT_FAILED
;
2635 static int redbee_init(void)
2638 uint32_t bytes_written
;
2641 low_direction
= 0x2b;
2643 /* initialize low byte for jtag */
2644 /* command "set data bits low byte" */
2646 /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2647 buf
[2] = low_direction
;
2648 /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
2649 buf
[1] = low_output
;
2650 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2652 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2654 LOG_ERROR("couldn't initialize FT2232 with 'redbee' layout");
2655 return ERROR_JTAG_INIT_FAILED
;
2659 nTRSTnOE
= 0x0; /* No output enable for TRST*/
2661 nSRSTnOE
= 0x0; /* No output enable for SRST*/
2664 high_direction
= 0x0c;
2666 enum reset_types jtag_reset_config
= jtag_get_reset_config();
2667 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
2669 LOG_ERROR("can't set nTRSTOE to push-pull on redbee");
2673 high_output
|= nTRST
;
2676 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
2678 LOG_ERROR("can't set nSRST to push-pull on redbee");
2682 high_output
|= nSRST
;
2685 /* initialize high port */
2686 buf
[0] = 0x82; /* command "set data bits high byte" */
2687 buf
[1] = high_output
; /* value */
2688 buf
[2] = high_direction
; /* all outputs (xRST and xRSTnOE) */
2689 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2691 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2693 LOG_ERROR("couldn't initialize FT2232 with 'redbee' layout");
2694 return ERROR_JTAG_INIT_FAILED
;
2700 static int jtagkey_init(void)
2703 uint32_t bytes_written
;
2706 low_direction
= 0x1b;
2708 /* initialize low byte for jtag */
2709 buf
[0] = 0x80; /* command "set data bits low byte" */
2710 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2711 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
2712 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2714 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2716 LOG_ERROR("couldn't initialize FT2232 with 'JTAGkey' layout");
2717 return ERROR_JTAG_INIT_FAILED
;
2720 if (strcmp(layout
->name
, "jtagkey") == 0)
2727 else if ((strcmp(layout
->name
, "jtagkey_prototype_v1") == 0)
2728 || (strcmp(layout
->name
, "oocdlink") == 0))
2737 LOG_ERROR("BUG: jtagkey_init called for non jtagkey layout");
2742 high_direction
= 0x0f;
2744 enum reset_types jtag_reset_config
= jtag_get_reset_config();
2745 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
2747 high_output
|= nTRSTnOE
;
2748 high_output
&= ~nTRST
;
2752 high_output
&= ~nTRSTnOE
;
2753 high_output
|= nTRST
;
2756 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
2758 high_output
&= ~nSRSTnOE
;
2759 high_output
|= nSRST
;
2763 high_output
|= nSRSTnOE
;
2764 high_output
&= ~nSRST
;
2767 /* initialize high port */
2768 buf
[0] = 0x82; /* command "set data bits high byte" */
2769 buf
[1] = high_output
; /* value */
2770 buf
[2] = high_direction
; /* all outputs (xRST and xRSTnOE) */
2771 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2773 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2775 LOG_ERROR("couldn't initialize FT2232 with 'JTAGkey' layout");
2776 return ERROR_JTAG_INIT_FAILED
;
2782 static int olimex_jtag_init(void)
2785 uint32_t bytes_written
;
2788 low_direction
= 0x1b;
2790 /* initialize low byte for jtag */
2791 buf
[0] = 0x80; /* command "set data bits low byte" */
2792 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2793 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
2794 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2796 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2798 LOG_ERROR("couldn't initialize FT2232 with 'Olimex' layout");
2799 return ERROR_JTAG_INIT_FAILED
;
2805 nSRSTnOE
= 0x00; /* no output enable for nSRST */
2808 high_direction
= 0x0f;
2810 enum reset_types jtag_reset_config
= jtag_get_reset_config();
2811 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
2813 high_output
|= nTRSTnOE
;
2814 high_output
&= ~nTRST
;
2818 high_output
&= ~nTRSTnOE
;
2819 high_output
|= nTRST
;
2822 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
2824 LOG_ERROR("can't set nSRST to push-pull on the Olimex ARM-USB-OCD");
2828 high_output
&= ~nSRST
;
2831 /* turn red LED on */
2832 high_output
|= 0x08;
2834 /* initialize high port */
2835 buf
[0] = 0x82; /* command "set data bits high byte" */
2836 buf
[1] = high_output
; /* value */
2837 buf
[2] = high_direction
; /* all outputs (xRST and xRSTnOE) */
2838 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2840 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2842 LOG_ERROR("couldn't initialize FT2232 with 'Olimex' layout");
2843 return ERROR_JTAG_INIT_FAILED
;
2849 static int flyswatter_init(void)
2852 uint32_t bytes_written
;
2855 low_direction
= 0xfb;
2857 /* initialize low byte for jtag */
2858 buf
[0] = 0x80; /* command "set data bits low byte" */
2859 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2860 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE[12]=out, n[ST]srst = out */
2861 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2863 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2865 LOG_ERROR("couldn't initialize FT2232 with 'flyswatter' layout");
2866 return ERROR_JTAG_INIT_FAILED
;
2870 nTRSTnOE
= 0x0; /* not output enable for nTRST */
2872 nSRSTnOE
= 0x00; /* no output enable for nSRST */
2875 high_direction
= 0x0c;
2877 /* turn red LED3 on, LED2 off */
2878 high_output
|= 0x08;
2880 /* initialize high port */
2881 buf
[0] = 0x82; /* command "set data bits high byte" */
2882 buf
[1] = high_output
; /* value */
2883 buf
[2] = high_direction
; /* all outputs (xRST and xRSTnOE) */
2884 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2886 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2888 LOG_ERROR("couldn't initialize FT2232 with 'flyswatter' layout");
2889 return ERROR_JTAG_INIT_FAILED
;
2895 static int turtle_init(void)
2898 uint32_t bytes_written
;
2901 low_direction
= 0x5b;
2903 /* initialize low byte for jtag */
2904 buf
[0] = 0x80; /* command "set data bits low byte" */
2905 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2906 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
2907 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2909 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2911 LOG_ERROR("couldn't initialize FT2232 with 'turtelizer2' layout");
2912 return ERROR_JTAG_INIT_FAILED
;
2918 high_direction
= 0x0C;
2920 /* initialize high port */
2921 buf
[0] = 0x82; /* command "set data bits high byte" */
2922 buf
[1] = high_output
;
2923 buf
[2] = high_direction
;
2924 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2926 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2928 LOG_ERROR("couldn't initialize FT2232 with 'turtelizer2' layout");
2929 return ERROR_JTAG_INIT_FAILED
;
2935 static int comstick_init(void)
2938 uint32_t bytes_written
;
2941 low_direction
= 0x0b;
2943 /* initialize low byte for jtag */
2944 buf
[0] = 0x80; /* command "set data bits low byte" */
2945 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2946 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
2947 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2949 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2951 LOG_ERROR("couldn't initialize FT2232 with 'comstick' layout");
2952 return ERROR_JTAG_INIT_FAILED
;
2956 nTRSTnOE
= 0x00; /* no output enable for nTRST */
2958 nSRSTnOE
= 0x00; /* no output enable for nSRST */
2961 high_direction
= 0x03;
2963 /* initialize high port */
2964 buf
[0] = 0x82; /* command "set data bits high byte" */
2965 buf
[1] = high_output
;
2966 buf
[2] = high_direction
;
2967 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2969 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2971 LOG_ERROR("couldn't initialize FT2232 with 'comstick' layout");
2972 return ERROR_JTAG_INIT_FAILED
;
2978 static int stm32stick_init(void)
2981 uint32_t bytes_written
;
2984 low_direction
= 0x8b;
2986 /* initialize low byte for jtag */
2987 buf
[0] = 0x80; /* command "set data bits low byte" */
2988 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
2989 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
2990 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
2992 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
2994 LOG_ERROR("couldn't initialize FT2232 with 'stm32stick' layout");
2995 return ERROR_JTAG_INIT_FAILED
;
2999 nTRSTnOE
= 0x00; /* no output enable for nTRST */
3001 nSRSTnOE
= 0x00; /* no output enable for nSRST */
3004 high_direction
= 0x03;
3006 /* initialize high port */
3007 buf
[0] = 0x82; /* command "set data bits high byte" */
3008 buf
[1] = high_output
;
3009 buf
[2] = high_direction
;
3010 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3012 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
3014 LOG_ERROR("couldn't initialize FT2232 with 'stm32stick' layout");
3015 return ERROR_JTAG_INIT_FAILED
;
3021 static int sheevaplug_init(void)
3024 uint32_t bytes_written
;
3027 low_direction
= 0x1b;
3029 /* initialize low byte for jtag */
3030 buf
[0] = 0x80; /* command "set data bits low byte" */
3031 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
3032 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in */
3033 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3035 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
3037 LOG_ERROR("couldn't initialize FT2232 with 'sheevaplug' layout");
3038 return ERROR_JTAG_INIT_FAILED
;
3047 high_direction
= 0x0f;
3049 /* nTRST is always push-pull */
3050 high_output
&= ~nTRSTnOE
;
3051 high_output
|= nTRST
;
3053 /* nSRST is always open-drain */
3054 high_output
|= nSRSTnOE
;
3055 high_output
&= ~nSRST
;
3057 /* initialize high port */
3058 buf
[0] = 0x82; /* command "set data bits high byte" */
3059 buf
[1] = high_output
; /* value */
3060 buf
[2] = high_direction
; /* all outputs - xRST */
3061 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3063 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
3065 LOG_ERROR("couldn't initialize FT2232 with 'sheevaplug' layout");
3066 return ERROR_JTAG_INIT_FAILED
;
3072 static int cortino_jtag_init(void)
3075 uint32_t bytes_written
;
3078 low_direction
= 0x1b;
3080 /* initialize low byte for jtag */
3081 buf
[0] = 0x80; /* command "set data bits low byte" */
3082 buf
[1] = low_output
; /* value (TMS = 1,TCK = 0, TDI = 0, nOE = 0) */
3083 buf
[2] = low_direction
; /* dir (output = 1), TCK/TDI/TMS = out, TDO = in, nOE = out */
3084 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3086 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
3088 LOG_ERROR("couldn't initialize FT2232 with 'cortino' layout");
3089 return ERROR_JTAG_INIT_FAILED
;
3093 nTRSTnOE
= 0x00; /* no output enable for nTRST */
3095 nSRSTnOE
= 0x00; /* no output enable for nSRST */
3098 high_direction
= 0x03;
3100 /* initialize high port */
3101 buf
[0] = 0x82; /* command "set data bits high byte" */
3102 buf
[1] = high_output
;
3103 buf
[2] = high_direction
;
3104 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3106 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
3108 LOG_ERROR("couldn't initialize FT2232 with 'stm32stick' layout");
3109 return ERROR_JTAG_INIT_FAILED
;
3115 static int lisa_l_init(void)
3118 uint32_t bytes_written
;
3128 high_direction
= 0x18;
3130 /* initialize high port */
3131 buf
[0] = 0x82; /* command "set data bits high byte" */
3132 buf
[1] = high_output
;
3133 buf
[2] = high_direction
;
3134 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3136 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
3138 LOG_ERROR("couldn't initialize FT2232 with 'lisa_l' layout");
3139 return ERROR_JTAG_INIT_FAILED
;
3142 return ftx232_dbus_write();
3145 static int flossjtag_init(void)
3148 uint32_t bytes_written
;
3158 high_direction
= 0x18;
3160 /* initialize high port */
3161 buf
[0] = 0x82; /* command "set data bits high byte" */
3162 buf
[1] = high_output
;
3163 buf
[2] = high_direction
;
3164 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3166 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
3168 LOG_ERROR("couldn't initialize FT2232 with 'Floss-JTAG' layout");
3169 return ERROR_JTAG_INIT_FAILED
;
3172 return ftx232_dbus_write();
3175 static void olimex_jtag_blink(void)
3177 /* Olimex ARM-USB-OCD has a LED connected to ACBUS3
3178 * ACBUS3 is bit 3 of the GPIOH port
3180 if (high_output
& 0x08)
3182 /* set port pin high */
3183 high_output
&= 0x07;
3187 /* set port pin low */
3188 high_output
|= 0x08;
3192 buffer_write(high_output
);
3193 buffer_write(high_direction
);
3196 static void flyswatter_jtag_blink(void)
3199 * Flyswatter has two LEDs connected to ACBUS2 and ACBUS3
3201 high_output
^= 0x0c;
3204 buffer_write(high_output
);
3205 buffer_write(high_direction
);
3208 static void turtle_jtag_blink(void)
3211 * Turtelizer2 has two LEDs connected to ACBUS2 and ACBUS3
3213 if (high_output
& 0x08)
3223 buffer_write(high_output
);
3224 buffer_write(high_direction
);
3227 static void lisa_l_blink(void)
3230 * Lisa/L has two LEDs connected to BCBUS3 and BCBUS4
3232 if (high_output
& 0x10)
3242 buffer_write(high_output
);
3243 buffer_write(high_direction
);
3246 static void flossjtag_blink(void)
3249 * Floss-JTAG has two LEDs connected to ACBUS3 and ACBUS4
3251 if (high_output
& 0x10)
3261 buffer_write(high_output
);
3262 buffer_write(high_direction
);
3265 static int ft2232_quit(void)
3267 #if BUILD_FT2232_FTD2XX == 1
3270 status
= FT_Close(ftdih
);
3271 #elif BUILD_FT2232_LIBFTDI == 1
3272 ftdi_usb_close(&ftdic
);
3274 ftdi_deinit(&ftdic
);
3277 free(ft2232_buffer
);
3278 ft2232_buffer
= NULL
;
3283 COMMAND_HANDLER(ft2232_handle_device_desc_command
)
3289 ft2232_device_desc
= strdup(CMD_ARGV
[0]);
3290 cp
= strchr(ft2232_device_desc
, 0);
3291 /* under Win32, the FTD2XX driver appends an "A" to the end
3292 * of the description, this examines the given desc
3293 * and creates the 'missing' _A or non_A variable. */
3294 if ((cp
[-1] == 'A') && (cp
[-2]==' ')) {
3295 /* it was, so make this the "A" version. */
3296 ft2232_device_desc_A
= ft2232_device_desc
;
3297 /* and *CREATE* the non-A version. */
3298 strcpy(buf
, ft2232_device_desc
);
3299 cp
= strchr(buf
, 0);
3301 ft2232_device_desc
= strdup(buf
);
3303 /* <space > A not defined
3305 sprintf(buf
, "%s A", ft2232_device_desc
);
3306 ft2232_device_desc_A
= strdup(buf
);
3311 LOG_ERROR("expected exactly one argument to ft2232_device_desc <description>");
3317 COMMAND_HANDLER(ft2232_handle_serial_command
)
3321 ft2232_serial
= strdup(CMD_ARGV
[0]);
3325 LOG_ERROR("expected exactly one argument to ft2232_serial <serial-number>");
3331 COMMAND_HANDLER(ft2232_handle_layout_command
)
3333 if (CMD_ARGC
!= 1) {
3334 LOG_ERROR("Need exactly one argument to ft2232_layout");
3339 LOG_ERROR("already specified ft2232_layout %s",
3341 return (strcmp(layout
->name
, CMD_ARGV
[0]) != 0)
3346 for (const struct ft2232_layout
*l
= ft2232_layouts
; l
->name
; l
++) {
3347 if (strcmp(l
->name
, CMD_ARGV
[0]) == 0) {
3353 LOG_ERROR("No FT2232 layout '%s' found", CMD_ARGV
[0]);
3357 COMMAND_HANDLER(ft2232_handle_vid_pid_command
)
3359 if (CMD_ARGC
> MAX_USB_IDS
* 2)
3361 LOG_WARNING("ignoring extra IDs in ft2232_vid_pid "
3362 "(maximum is %d pairs)", MAX_USB_IDS
);
3363 CMD_ARGC
= MAX_USB_IDS
* 2;
3365 if (CMD_ARGC
< 2 || (CMD_ARGC
& 1))
3367 LOG_WARNING("incomplete ft2232_vid_pid configuration directive");
3369 return ERROR_COMMAND_SYNTAX_ERROR
;
3370 /* remove the incomplete trailing id */
3375 for (i
= 0; i
< CMD_ARGC
; i
+= 2)
3377 COMMAND_PARSE_NUMBER(u16
, CMD_ARGV
[i
], ft2232_vid
[i
>> 1]);
3378 COMMAND_PARSE_NUMBER(u16
, CMD_ARGV
[i
+ 1], ft2232_pid
[i
>> 1]);
3382 * Explicitly terminate, in case there are multiples instances of
3385 ft2232_vid
[i
>> 1] = ft2232_pid
[i
>> 1] = 0;
3390 COMMAND_HANDLER(ft2232_handle_latency_command
)
3394 ft2232_latency
= atoi(CMD_ARGV
[0]);
3398 LOG_ERROR("expected exactly one argument to ft2232_latency <ms>");
3404 static int ft2232_stableclocks(int num_cycles
, struct jtag_command
* cmd
)
3408 /* 7 bits of either ones or zeros. */
3409 uint8_t tms
= (tap_get_state() == TAP_RESET
? 0x7F : 0x00);
3411 while (num_cycles
> 0)
3413 /* the command 0x4b, "Clock Data to TMS/CS Pin (no Read)" handles
3414 * at most 7 bits per invocation. Here we invoke it potentially
3417 int bitcount_per_command
= (num_cycles
> 7) ? 7 : num_cycles
;
3419 if (ft2232_buffer_size
+ 3 >= FT2232_BUFFER_SIZE
)
3421 if (ft2232_send_and_recv(first_unsent
, cmd
) != ERROR_OK
)
3422 retval
= ERROR_JTAG_QUEUE_FAILED
;
3427 /* there are no state transitions in this code, so omit state tracking */
3429 /* command "Clock Data to TMS/CS Pin (no Read)" */
3433 buffer_write(bitcount_per_command
- 1);
3435 /* TMS data bits are either all zeros or ones to stay in the current stable state */
3440 num_cycles
-= bitcount_per_command
;
3446 /* ---------------------------------------------------------------------
3447 * Support for IceBear JTAG adapter from Section5:
3448 * http://section5.ch/icebear
3450 * Author: Sten, debian@sansys-electronic.com
3453 /* Icebear pin layout
3455 * ADBUS5 (nEMU) nSRST | 2 1| GND (10k->VCC)
3456 * GND GND | 4 3| n.c.
3457 * ADBUS3 TMS | 6 5| ADBUS6 VCC
3458 * ADBUS0 TCK | 8 7| ADBUS7 (GND)
3459 * ADBUS4 nTRST |10 9| ACBUS0 (GND)
3460 * ADBUS1 TDI |12 11| ACBUS1 (GND)
3461 * ADBUS2 TDO |14 13| GND GND
3463 * ADBUS0 O L TCK ACBUS0 GND
3464 * ADBUS1 O L TDI ACBUS1 GND
3465 * ADBUS2 I TDO ACBUS2 n.c.
3466 * ADBUS3 O H TMS ACBUS3 n.c.
3472 static int icebear_jtag_init(void) {
3474 uint32_t bytes_written
;
3476 low_direction
= 0x0b; /* output: TCK TDI TMS; input: TDO */
3477 low_output
= 0x08; /* high: TMS; low: TCK TDI */
3481 enum reset_types jtag_reset_config
= jtag_get_reset_config();
3482 if ((jtag_reset_config
& RESET_TRST_OPEN_DRAIN
) != 0) {
3483 low_direction
&= ~nTRST
; /* nTRST high impedance */
3486 low_direction
|= nTRST
;
3487 low_output
|= nTRST
;
3490 low_direction
|= nSRST
;
3491 low_output
|= nSRST
;
3493 /* initialize low byte for jtag */
3494 buf
[0] = 0x80; /* command "set data bits low byte" */
3495 buf
[1] = low_output
;
3496 buf
[2] = low_direction
;
3497 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3499 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
) {
3500 LOG_ERROR("couldn't initialize FT2232 with 'IceBear' layout (low)");
3501 return ERROR_JTAG_INIT_FAILED
;
3505 high_direction
= 0x00;
3508 /* initialize high port */
3509 buf
[0] = 0x82; /* command "set data bits high byte" */
3510 buf
[1] = high_output
; /* value */
3511 buf
[2] = high_direction
; /* all outputs (xRST and xRSTnOE) */
3512 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
3514 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
) {
3515 LOG_ERROR("couldn't initialize FT2232 with 'IceBear' layout (high)");
3516 return ERROR_JTAG_INIT_FAILED
;
3522 static void icebear_jtag_reset(int trst
, int srst
) {
3525 low_direction
|= nTRST
;
3526 low_output
&= ~nTRST
;
3528 else if (trst
== 0) {
3529 enum reset_types jtag_reset_config
= jtag_get_reset_config();
3530 if ((jtag_reset_config
& RESET_TRST_OPEN_DRAIN
) != 0)
3531 low_direction
&= ~nTRST
;
3533 low_output
|= nTRST
;
3537 low_output
&= ~nSRST
;
3539 else if (srst
== 0) {
3540 low_output
|= nSRST
;
3543 /* command "set data bits low byte" */
3545 buffer_write(low_output
);
3546 buffer_write(low_direction
);
3548 LOG_DEBUG("trst: %i, srst: %i, low_output: 0x%2.2x, low_direction: 0x%2.2x", trst
, srst
, low_output
, low_direction
);
3551 /* ---------------------------------------------------------------------
3552 * Support for Signalyzer H2 and Signalyzer H4
3553 * JTAG adapter from Xverve Technologies Inc.
3554 * http://www.signalyzer.com or http://www.xverve.com
3556 * Author: Oleg Seiljus, oleg@signalyzer.com
3558 static unsigned char signalyzer_h_side
;
3559 static unsigned int signalyzer_h_adapter_type
;
3561 static int signalyzer_h_ctrl_write(int address
, unsigned short value
);
3563 #if BUILD_FT2232_FTD2XX == 1
3564 static int signalyzer_h_ctrl_read(int address
, unsigned short *value
);
3567 #define SIGNALYZER_COMMAND_ADDR 128
3568 #define SIGNALYZER_DATA_BUFFER_ADDR 129
3570 #define SIGNALYZER_COMMAND_VERSION 0x41
3571 #define SIGNALYZER_COMMAND_RESET 0x42
3572 #define SIGNALYZER_COMMAND_POWERCONTROL_GET 0x50
3573 #define SIGNALYZER_COMMAND_POWERCONTROL_SET 0x51
3574 #define SIGNALYZER_COMMAND_PWM_SET 0x52
3575 #define SIGNALYZER_COMMAND_LED_SET 0x53
3576 #define SIGNALYZER_COMMAND_ADC 0x54
3577 #define SIGNALYZER_COMMAND_GPIO_STATE 0x55
3578 #define SIGNALYZER_COMMAND_GPIO_MODE 0x56
3579 #define SIGNALYZER_COMMAND_GPIO_PORT 0x57
3580 #define SIGNALYZER_COMMAND_I2C 0x58
3582 #define SIGNALYZER_CHAN_A 1
3583 #define SIGNALYZER_CHAN_B 2
3584 /* LEDS use channel C */
3585 #define SIGNALYZER_CHAN_C 4
3587 #define SIGNALYZER_LED_GREEN 1
3588 #define SIGNALYZER_LED_RED 2
3590 #define SIGNALYZER_MODULE_TYPE_EM_LT16_A 0x0301
3591 #define SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG 0x0302
3592 #define SIGNALYZER_MODULE_TYPE_EM_JTAG 0x0303
3593 #define SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG_P 0x0304
3594 #define SIGNALYZER_MODULE_TYPE_EM_JTAG_P 0x0305
3597 static int signalyzer_h_ctrl_write(int address
, unsigned short value
)
3599 #if BUILD_FT2232_FTD2XX == 1
3600 return FT_WriteEE(ftdih
, address
, value
);
3601 #elif BUILD_FT2232_LIBFTDI == 1
3606 #if BUILD_FT2232_FTD2XX == 1
3607 static int signalyzer_h_ctrl_read(int address
, unsigned short *value
)
3609 return FT_ReadEE(ftdih
, address
, value
);
3613 static int signalyzer_h_led_set(unsigned char channel
, unsigned char led
,
3614 int on_time_ms
, int off_time_ms
, unsigned char cycles
)
3616 unsigned char on_time
;
3617 unsigned char off_time
;
3619 if (on_time_ms
< 0xFFFF)
3620 on_time
= (unsigned char)(on_time_ms
/ 62);
3624 off_time
= (unsigned char)(off_time_ms
/ 62);
3626 #if BUILD_FT2232_FTD2XX == 1
3629 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_DATA_BUFFER_ADDR
,
3630 ((uint32_t)(channel
<< 8) | led
))) != FT_OK
)
3632 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3633 return ERROR_JTAG_DEVICE_ERROR
;
3636 if ((status
= signalyzer_h_ctrl_write(
3637 (SIGNALYZER_DATA_BUFFER_ADDR
+ 1),
3638 ((uint32_t)(on_time
<< 8) | off_time
))) != FT_OK
)
3640 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3641 return ERROR_JTAG_DEVICE_ERROR
;
3644 if ((status
= signalyzer_h_ctrl_write(
3645 (SIGNALYZER_DATA_BUFFER_ADDR
+ 2),
3646 ((uint32_t)cycles
))) != FT_OK
)
3648 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3649 return ERROR_JTAG_DEVICE_ERROR
;
3652 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_COMMAND_ADDR
,
3653 SIGNALYZER_COMMAND_LED_SET
)) != FT_OK
)
3655 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3656 return ERROR_JTAG_DEVICE_ERROR
;
3660 #elif BUILD_FT2232_LIBFTDI == 1
3663 if ((retval
= signalyzer_h_ctrl_write(SIGNALYZER_DATA_BUFFER_ADDR
,
3664 ((uint32_t)(channel
<< 8) | led
))) < 0)
3666 LOG_ERROR("signalyzer_h_ctrl_write returned: %s",
3667 ftdi_get_error_string(&ftdic
));
3668 return ERROR_JTAG_DEVICE_ERROR
;
3671 if ((retval
= signalyzer_h_ctrl_write(
3672 (SIGNALYZER_DATA_BUFFER_ADDR
+ 1),
3673 ((uint32_t)(on_time
<< 8) | off_time
))) < 0)
3675 LOG_ERROR("signalyzer_h_ctrl_write returned: %s",
3676 ftdi_get_error_string(&ftdic
));
3677 return ERROR_JTAG_DEVICE_ERROR
;
3680 if ((retval
= signalyzer_h_ctrl_write(
3681 (SIGNALYZER_DATA_BUFFER_ADDR
+ 2),
3682 (uint32_t)cycles
)) < 0)
3684 LOG_ERROR("signalyzer_h_ctrl_write returned: %s",
3685 ftdi_get_error_string(&ftdic
));
3686 return ERROR_JTAG_DEVICE_ERROR
;
3689 if ((retval
= signalyzer_h_ctrl_write(SIGNALYZER_COMMAND_ADDR
,
3690 SIGNALYZER_COMMAND_LED_SET
)) < 0)
3692 LOG_ERROR("signalyzer_h_ctrl_write returned: %s",
3693 ftdi_get_error_string(&ftdic
));
3694 return ERROR_JTAG_DEVICE_ERROR
;
3701 static int signalyzer_h_init(void)
3703 #if BUILD_FT2232_FTD2XX == 1
3710 uint16_t read_buf
[12] = { 0 };
3712 uint32_t bytes_written
;
3714 /* turn on center green led */
3715 signalyzer_h_led_set(SIGNALYZER_CHAN_C
, SIGNALYZER_LED_GREEN
,
3716 0xFFFF, 0x00, 0x00);
3718 /* determine what channel config wants to open
3719 * TODO: change me... current implementation is made to work
3720 * with openocd description parsing.
3722 end_of_desc
= strrchr(ft2232_device_desc
, 0x00);
3726 signalyzer_h_side
= *(end_of_desc
- 1);
3727 if (signalyzer_h_side
== 'B')
3728 signalyzer_h_side
= SIGNALYZER_CHAN_B
;
3730 signalyzer_h_side
= SIGNALYZER_CHAN_A
;
3734 LOG_ERROR("No Channel was specified");
3738 signalyzer_h_led_set(signalyzer_h_side
, SIGNALYZER_LED_GREEN
,
3741 #if BUILD_FT2232_FTD2XX == 1
3742 /* read signalyzer versionining information */
3743 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_COMMAND_ADDR
,
3744 SIGNALYZER_COMMAND_VERSION
)) != FT_OK
)
3746 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3747 return ERROR_JTAG_DEVICE_ERROR
;
3750 for (i
= 0; i
< 10; i
++)
3752 if ((status
= signalyzer_h_ctrl_read(
3753 (SIGNALYZER_DATA_BUFFER_ADDR
+ i
),
3754 &read_buf
[i
])) != FT_OK
)
3756 LOG_ERROR("signalyzer_h_ctrl_read returned: %lu",
3758 return ERROR_JTAG_DEVICE_ERROR
;
3762 LOG_INFO("Signalyzer: ID info: { %.4x %.4x %.4x %.4x %.4x %.4x %.4x }",
3763 read_buf
[0], read_buf
[1], read_buf
[2], read_buf
[3],
3764 read_buf
[4], read_buf
[5], read_buf
[6]);
3766 /* set gpio register */
3767 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_DATA_BUFFER_ADDR
,
3768 (uint32_t)(signalyzer_h_side
<< 8))) != FT_OK
)
3770 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3771 return ERROR_JTAG_DEVICE_ERROR
;
3774 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_DATA_BUFFER_ADDR
+ 1,
3777 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3778 return ERROR_JTAG_DEVICE_ERROR
;
3781 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_COMMAND_ADDR
,
3782 SIGNALYZER_COMMAND_GPIO_STATE
)) != FT_OK
)
3784 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3785 return ERROR_JTAG_DEVICE_ERROR
;
3788 /* read adapter type information */
3789 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_DATA_BUFFER_ADDR
,
3790 ((uint32_t)(signalyzer_h_side
<< 8) | 0x01))) != FT_OK
)
3792 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3793 return ERROR_JTAG_DEVICE_ERROR
;
3796 if ((status
= signalyzer_h_ctrl_write(
3797 (SIGNALYZER_DATA_BUFFER_ADDR
+ 1), 0xA000)) != FT_OK
)
3799 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3800 return ERROR_JTAG_DEVICE_ERROR
;
3803 if ((status
= signalyzer_h_ctrl_write(
3804 (SIGNALYZER_DATA_BUFFER_ADDR
+ 2), 0x0008)) != FT_OK
)
3806 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3807 return ERROR_JTAG_DEVICE_ERROR
;
3810 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_COMMAND_ADDR
,
3811 SIGNALYZER_COMMAND_I2C
)) != FT_OK
)
3813 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu", status
);
3814 return ERROR_JTAG_DEVICE_ERROR
;
3819 if ((status
= signalyzer_h_ctrl_read(SIGNALYZER_COMMAND_ADDR
,
3820 &read_buf
[0])) != FT_OK
)
3822 LOG_ERROR("signalyzer_h_ctrl_read returned: %lu", status
);
3823 return ERROR_JTAG_DEVICE_ERROR
;
3826 if (read_buf
[0] != 0x0498)
3827 signalyzer_h_adapter_type
= 0x0000;
3830 for (i
= 0; i
< 4; i
++)
3832 if ((status
= signalyzer_h_ctrl_read(
3833 (SIGNALYZER_DATA_BUFFER_ADDR
+ i
),
3834 &read_buf
[i
])) != FT_OK
)
3836 LOG_ERROR("signalyzer_h_ctrl_read returned: %lu",
3838 return ERROR_JTAG_DEVICE_ERROR
;
3842 signalyzer_h_adapter_type
= read_buf
[0];
3845 #elif BUILD_FT2232_LIBFTDI == 1
3846 /* currently libftdi does not allow reading individual eeprom
3847 * locations, therefore adapter type cannot be detected.
3848 * override with most common type
3850 signalyzer_h_adapter_type
= SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG
;
3853 enum reset_types jtag_reset_config
= jtag_get_reset_config();
3855 /* ADAPTOR: EM_LT16_A */
3856 if (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_LT16_A
)
3858 LOG_INFO("Signalyzer: EM-LT (16-channel level translator) "
3859 "detected. (HW: %2x).", (read_buf
[1] >> 8));
3867 low_direction
= 0x1b;
3870 high_direction
= 0x0;
3872 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
3874 low_direction
&= ~nTRSTnOE
; /* nTRST input */
3875 low_output
&= ~nTRST
; /* nTRST = 0 */
3879 low_direction
|= nTRSTnOE
; /* nTRST output */
3880 low_output
|= nTRST
; /* nTRST = 1 */
3883 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
3885 low_direction
|= nSRSTnOE
; /* nSRST output */
3886 low_output
|= nSRST
; /* nSRST = 1 */
3890 low_direction
&= ~nSRSTnOE
; /* nSRST input */
3891 low_output
&= ~nSRST
; /* nSRST = 0 */
3894 #if BUILD_FT2232_FTD2XX == 1
3895 /* enable power to the module */
3896 if ((status
= signalyzer_h_ctrl_write(
3897 SIGNALYZER_DATA_BUFFER_ADDR
,
3898 ((uint32_t)(signalyzer_h_side
<< 8) | 0x01)))
3901 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3903 return ERROR_JTAG_DEVICE_ERROR
;
3906 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_COMMAND_ADDR
,
3907 SIGNALYZER_COMMAND_POWERCONTROL_SET
)) != FT_OK
)
3909 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3911 return ERROR_JTAG_DEVICE_ERROR
;
3914 /* set gpio mode register */
3915 if ((status
= signalyzer_h_ctrl_write(
3916 SIGNALYZER_DATA_BUFFER_ADDR
,
3917 (uint32_t)(signalyzer_h_side
<< 8))) != FT_OK
)
3919 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3921 return ERROR_JTAG_DEVICE_ERROR
;
3924 if ((status
= signalyzer_h_ctrl_write(
3925 SIGNALYZER_DATA_BUFFER_ADDR
+ 1, 0x0000))
3928 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3930 return ERROR_JTAG_DEVICE_ERROR
;
3933 if ((status
= signalyzer_h_ctrl_write(SIGNALYZER_COMMAND_ADDR
,
3934 SIGNALYZER_COMMAND_GPIO_MODE
)) != FT_OK
)
3936 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3938 return ERROR_JTAG_DEVICE_ERROR
;
3941 /* set gpio register */
3942 if ((status
= signalyzer_h_ctrl_write(
3943 SIGNALYZER_DATA_BUFFER_ADDR
,
3944 (uint32_t)(signalyzer_h_side
<< 8))) != FT_OK
)
3946 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3948 return ERROR_JTAG_DEVICE_ERROR
;
3951 if ((status
= signalyzer_h_ctrl_write(
3952 SIGNALYZER_DATA_BUFFER_ADDR
+ 1, 0x4040))
3955 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3957 return ERROR_JTAG_DEVICE_ERROR
;
3960 if ((status
= signalyzer_h_ctrl_write(
3961 SIGNALYZER_COMMAND_ADDR
,
3962 SIGNALYZER_COMMAND_GPIO_STATE
)) != FT_OK
)
3964 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
3966 return ERROR_JTAG_DEVICE_ERROR
;
3971 /* ADAPTOR: EM_ARM_JTAG, EM_ARM_JTAG_P, EM_JTAG, EM_JTAG_P */
3972 else if ((signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG
) ||
3973 (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG_P
) ||
3974 (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_JTAG
) ||
3975 (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_JTAG_P
))
3977 if (signalyzer_h_adapter_type
3978 == SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG
)
3979 LOG_INFO("Signalyzer: EM-ARM-JTAG (ARM JTAG) "
3980 "detected. (HW: %2x).", (read_buf
[1] >> 8));
3981 else if (signalyzer_h_adapter_type
3982 == SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG_P
)
3983 LOG_INFO("Signalyzer: EM-ARM-JTAG_P "
3984 "(ARM JTAG with PSU) detected. (HW: %2x).",
3985 (read_buf
[1] >> 8));
3986 else if (signalyzer_h_adapter_type
3987 == SIGNALYZER_MODULE_TYPE_EM_JTAG
)
3988 LOG_INFO("Signalyzer: EM-JTAG (Generic JTAG) "
3989 "detected. (HW: %2x).", (read_buf
[1] >> 8));
3990 else if (signalyzer_h_adapter_type
3991 == SIGNALYZER_MODULE_TYPE_EM_JTAG_P
)
3992 LOG_INFO("Signalyzer: EM-JTAG-P "
3993 "(Generic JTAG with PSU) detected. (HW: %2x).",
3994 (read_buf
[1] >> 8));
4002 low_direction
= 0x1b;
4005 high_direction
= 0x1f;
4007 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4009 high_output
|= nTRSTnOE
;
4010 high_output
&= ~nTRST
;
4014 high_output
&= ~nTRSTnOE
;
4015 high_output
|= nTRST
;
4018 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4020 high_output
&= ~nSRSTnOE
;
4021 high_output
|= nSRST
;
4025 high_output
|= nSRSTnOE
;
4026 high_output
&= ~nSRST
;
4029 #if BUILD_FT2232_FTD2XX == 1
4030 /* enable power to the module */
4031 if ((status
= signalyzer_h_ctrl_write(
4032 SIGNALYZER_DATA_BUFFER_ADDR
,
4033 ((uint32_t)(signalyzer_h_side
<< 8) | 0x01)))
4036 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4038 return ERROR_JTAG_DEVICE_ERROR
;
4041 if ((status
= signalyzer_h_ctrl_write(
4042 SIGNALYZER_COMMAND_ADDR
,
4043 SIGNALYZER_COMMAND_POWERCONTROL_SET
)) != FT_OK
)
4045 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4047 return ERROR_JTAG_DEVICE_ERROR
;
4050 /* set gpio mode register (IO_16 and IO_17 set as analog
4051 * inputs, other is gpio)
4053 if ((status
= signalyzer_h_ctrl_write(
4054 SIGNALYZER_DATA_BUFFER_ADDR
,
4055 (uint32_t)(signalyzer_h_side
<< 8))) != FT_OK
)
4057 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4059 return ERROR_JTAG_DEVICE_ERROR
;
4062 if ((status
= signalyzer_h_ctrl_write(
4063 SIGNALYZER_DATA_BUFFER_ADDR
+ 1, 0x0060))
4066 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4068 return ERROR_JTAG_DEVICE_ERROR
;
4071 if ((status
= signalyzer_h_ctrl_write(
4072 SIGNALYZER_COMMAND_ADDR
,
4073 SIGNALYZER_COMMAND_GPIO_MODE
)) != FT_OK
)
4075 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4077 return ERROR_JTAG_DEVICE_ERROR
;
4080 /* set gpio register (all inputs, for -P modules,
4081 * PSU will be turned off)
4083 if ((status
= signalyzer_h_ctrl_write(
4084 SIGNALYZER_DATA_BUFFER_ADDR
,
4085 (uint32_t)(signalyzer_h_side
<< 8))) != FT_OK
)
4087 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4089 return ERROR_JTAG_DEVICE_ERROR
;
4092 if ((status
= signalyzer_h_ctrl_write(
4093 SIGNALYZER_DATA_BUFFER_ADDR
+ 1, 0x0000))
4096 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4098 return ERROR_JTAG_DEVICE_ERROR
;
4101 if ((status
= signalyzer_h_ctrl_write(
4102 SIGNALYZER_COMMAND_ADDR
,
4103 SIGNALYZER_COMMAND_GPIO_STATE
)) != FT_OK
)
4105 LOG_ERROR("signalyzer_h_ctrl_write returned: %lu",
4107 return ERROR_JTAG_DEVICE_ERROR
;
4112 else if (signalyzer_h_adapter_type
== 0x0000)
4114 LOG_INFO("Signalyzer: No external modules were detected.");
4122 low_direction
= 0x1b;
4125 high_direction
= 0x0;
4127 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4129 low_direction
&= ~nTRSTnOE
; /* nTRST input */
4130 low_output
&= ~nTRST
; /* nTRST = 0 */
4134 low_direction
|= nTRSTnOE
; /* nTRST output */
4135 low_output
|= nTRST
; /* nTRST = 1 */
4138 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4140 low_direction
|= nSRSTnOE
; /* nSRST output */
4141 low_output
|= nSRST
; /* nSRST = 1 */
4145 low_direction
&= ~nSRSTnOE
; /* nSRST input */
4146 low_output
&= ~nSRST
; /* nSRST = 0 */
4151 LOG_ERROR("Unknown module type is detected: %.4x",
4152 signalyzer_h_adapter_type
);
4153 return ERROR_JTAG_DEVICE_ERROR
;
4156 /* initialize low byte of controller for jtag operation */
4158 buf
[1] = low_output
;
4159 buf
[2] = low_direction
;
4161 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
4163 LOG_ERROR("couldn't initialize Signalyzer-H layout");
4164 return ERROR_JTAG_INIT_FAILED
;
4167 #if BUILD_FT2232_FTD2XX == 1
4168 if (ftdi_device
== FT_DEVICE_2232H
)
4170 /* initialize high byte of controller for jtag operation */
4172 buf
[1] = high_output
;
4173 buf
[2] = high_direction
;
4175 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
4177 LOG_ERROR("couldn't initialize Signalyzer-H layout");
4178 return ERROR_JTAG_INIT_FAILED
;
4181 #elif BUILD_FT2232_LIBFTDI == 1
4182 if (ftdi_device
== TYPE_2232H
)
4184 /* initialize high byte of controller for jtag operation */
4186 buf
[1] = high_output
;
4187 buf
[2] = high_direction
;
4189 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
4191 LOG_ERROR("couldn't initialize Signalyzer-H layout");
4192 return ERROR_JTAG_INIT_FAILED
;
4199 static void signalyzer_h_reset(int trst
, int srst
)
4201 enum reset_types jtag_reset_config
= jtag_get_reset_config();
4203 /* ADAPTOR: EM_LT16_A */
4204 if (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_LT16_A
)
4208 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4209 /* switch to output pin (output is low) */
4210 low_direction
|= nTRSTnOE
;
4212 /* switch output low */
4213 low_output
&= ~nTRST
;
4217 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4218 /* switch to input pin (high-Z + internal
4219 * and external pullup) */
4220 low_direction
&= ~nTRSTnOE
;
4222 /* switch output high */
4223 low_output
|= nTRST
;
4228 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4229 /* switch output low */
4230 low_output
&= ~nSRST
;
4232 /* switch to output pin (output is low) */
4233 low_direction
|= nSRSTnOE
;
4237 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4238 /* switch output high */
4239 low_output
|= nSRST
;
4241 /* switch to input pin (high-Z) */
4242 low_direction
&= ~nSRSTnOE
;
4245 /* command "set data bits low byte" */
4247 buffer_write(low_output
);
4248 buffer_write(low_direction
);
4249 LOG_DEBUG("trst: %i, srst: %i, low_output: 0x%2.2x, "
4250 "low_direction: 0x%2.2x",
4251 trst
, srst
, low_output
, low_direction
);
4253 /* ADAPTOR: EM_ARM_JTAG, EM_ARM_JTAG_P, EM_JTAG, EM_JTAG_P */
4254 else if ((signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG
) ||
4255 (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_ARM_JTAG_P
) ||
4256 (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_JTAG
) ||
4257 (signalyzer_h_adapter_type
== SIGNALYZER_MODULE_TYPE_EM_JTAG_P
))
4261 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4262 high_output
&= ~nTRSTnOE
;
4264 high_output
&= ~nTRST
;
4268 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4269 high_output
|= nTRSTnOE
;
4271 high_output
|= nTRST
;
4276 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4277 high_output
&= ~nSRST
;
4279 high_output
&= ~nSRSTnOE
;
4283 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4284 high_output
|= nSRST
;
4286 high_output
|= nSRSTnOE
;
4289 /* command "set data bits high byte" */
4291 buffer_write(high_output
);
4292 buffer_write(high_direction
);
4293 LOG_INFO("trst: %i, srst: %i, high_output: 0x%2.2x, "
4294 "high_direction: 0x%2.2x",
4295 trst
, srst
, high_output
, high_direction
);
4297 else if (signalyzer_h_adapter_type
== 0x0000)
4301 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4302 /* switch to output pin (output is low) */
4303 low_direction
|= nTRSTnOE
;
4305 /* switch output low */
4306 low_output
&= ~nTRST
;
4310 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4311 /* switch to input pin (high-Z + internal
4312 * and external pullup) */
4313 low_direction
&= ~nTRSTnOE
;
4315 /* switch output high */
4316 low_output
|= nTRST
;
4321 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4322 /* switch output low */
4323 low_output
&= ~nSRST
;
4325 /* switch to output pin (output is low) */
4326 low_direction
|= nSRSTnOE
;
4330 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4331 /* switch output high */
4332 low_output
|= nSRST
;
4334 /* switch to input pin (high-Z) */
4335 low_direction
&= ~nSRSTnOE
;
4338 /* command "set data bits low byte" */
4340 buffer_write(low_output
);
4341 buffer_write(low_direction
);
4342 LOG_DEBUG("trst: %i, srst: %i, low_output: 0x%2.2x, "
4343 "low_direction: 0x%2.2x",
4344 trst
, srst
, low_output
, low_direction
);
4348 static void signalyzer_h_blink(void)
4350 signalyzer_h_led_set(signalyzer_h_side
, SIGNALYZER_LED_RED
, 100, 0, 1);
4353 /********************************************************************
4354 * Support for KT-LINK
4355 * JTAG adapter from KRISTECH
4356 * http://www.kristech.eu
4357 *******************************************************************/
4358 static int ktlink_init(void)
4361 uint32_t bytes_written
;
4362 uint8_t swd_en
= 0x20; //0x20 SWD disable, 0x00 SWD enable (ADBUS5)
4364 low_output
= 0x08 | swd_en
; // value; TMS=1,TCK=0,TDI=0,SWD=swd_en
4365 low_direction
= 0x3B; // out=1; TCK/TDI/TMS=out,TDO=in,SWD=out,RTCK=in,SRSTIN=in
4367 // initialize low port
4368 buf
[0] = 0x80; // command "set data bits low byte"
4369 buf
[1] = low_output
;
4370 buf
[2] = low_direction
;
4371 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
4373 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
4375 LOG_ERROR("couldn't initialize FT2232 with 'ktlink' layout");
4376 return ERROR_JTAG_INIT_FAILED
;
4384 high_output
= 0x80; // turn LED on
4385 high_direction
= 0xFF; // all outputs
4387 enum reset_types jtag_reset_config
= jtag_get_reset_config();
4389 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
) {
4390 high_output
|= nTRSTnOE
;
4391 high_output
&= ~nTRST
;
4393 high_output
&= ~nTRSTnOE
;
4394 high_output
|= nTRST
;
4397 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
) {
4398 high_output
&= ~nSRSTnOE
;
4399 high_output
|= nSRST
;
4401 high_output
|= nSRSTnOE
;
4402 high_output
&= ~nSRST
;
4405 // initialize high port
4406 buf
[0] = 0x82; // command "set data bits high byte"
4407 buf
[1] = high_output
; // value
4408 buf
[2] = high_direction
;
4409 LOG_DEBUG("%2.2x %2.2x %2.2x", buf
[0], buf
[1], buf
[2]);
4411 if (ft2232_write(buf
, sizeof(buf
), &bytes_written
) != ERROR_OK
)
4413 LOG_ERROR("couldn't initialize FT2232 with 'ktlink' layout");
4414 return ERROR_JTAG_INIT_FAILED
;
4420 static void ktlink_reset(int trst
, int srst
)
4422 enum reset_types jtag_reset_config
= jtag_get_reset_config();
4425 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4426 high_output
&= ~nTRSTnOE
;
4428 high_output
&= ~nTRST
;
4429 } else if (trst
== 0) {
4430 if (jtag_reset_config
& RESET_TRST_OPEN_DRAIN
)
4431 high_output
|= nTRSTnOE
;
4433 high_output
|= nTRST
;
4437 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4438 high_output
&= ~nSRST
;
4440 high_output
&= ~nSRSTnOE
;
4441 } else if (srst
== 0) {
4442 if (jtag_reset_config
& RESET_SRST_PUSH_PULL
)
4443 high_output
|= nSRST
;
4445 high_output
|= nSRSTnOE
;
4448 buffer_write(0x82); // command "set data bits high byte"
4449 buffer_write(high_output
);
4450 buffer_write(high_direction
);
4451 LOG_DEBUG("trst: %i, srst: %i, high_output: 0x%2.2x, high_direction: 0x%2.2x", trst
, srst
, high_output
,high_direction
);
4454 static void ktlink_blink(void)
4456 /* LED connected to ACBUS7 */
4457 if (high_output
& 0x80)
4458 high_output
&= 0x7F;
4460 high_output
|= 0x80;
4462 buffer_write(0x82); // command "set data bits high byte"
4463 buffer_write(high_output
);
4464 buffer_write(high_direction
);
4467 static const struct command_registration ft2232_command_handlers
[] = {
4469 .name
= "ft2232_device_desc",
4470 .handler
= &ft2232_handle_device_desc_command
,
4471 .mode
= COMMAND_CONFIG
,
4472 .help
= "set the USB device description of the FTDI FT2232 device",
4473 .usage
= "description_string",
4476 .name
= "ft2232_serial",
4477 .handler
= &ft2232_handle_serial_command
,
4478 .mode
= COMMAND_CONFIG
,
4479 .help
= "set the serial number of the FTDI FT2232 device",
4480 .usage
= "serial_string",
4483 .name
= "ft2232_layout",
4484 .handler
= &ft2232_handle_layout_command
,
4485 .mode
= COMMAND_CONFIG
,
4486 .help
= "set the layout of the FT2232 GPIO signals used "
4487 "to control output-enables and reset signals",
4488 .usage
= "layout_name",
4491 .name
= "ft2232_vid_pid",
4492 .handler
= &ft2232_handle_vid_pid_command
,
4493 .mode
= COMMAND_CONFIG
,
4494 .help
= "the vendor ID and product ID of the FTDI FT2232 device",
4495 .usage
= "(vid pid)* ",
4498 .name
= "ft2232_latency",
4499 .handler
= &ft2232_handle_latency_command
,
4500 .mode
= COMMAND_CONFIG
,
4501 .help
= "set the FT2232 latency timer to a new value",
4504 COMMAND_REGISTRATION_DONE
4507 struct jtag_interface ft2232_interface
= {
4509 .supported
= DEBUG_CAP_TMS_SEQ
,
4510 .commands
= ft2232_command_handlers
,
4511 .transports
= jtag_only
,
4513 .init
= ft2232_init
,
4514 .quit
= ft2232_quit
,
4515 .speed
= ft2232_speed
,
4516 .speed_div
= ft2232_speed_div
,
4518 .execute_queue
= ft2232_execute_queue
,