| blob | 7c62a7048302c78fca45a19c5e2a67feb3109415 |
1 /*
2 * USB Keyspan PDA / Xircom / Entregra Converter driver
3 *
4 * Copyright (C) 1999 - 2001 Greg Kroah-Hartman <greg@kroah.com>
5 * Copyright (C) 1999, 2000 Brian Warner <warner@lothar.com>
6 * Copyright (C) 2000 Al Borchers <borchers@steinerpoint.com>
7 *
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License as published by
10 * the Free Software Foundation; either version 2 of the License, or
11 * (at your option) any later version.
12 *
13 * See Documentation/usb/usb-serial.txt for more information on using this
14 * driver
15 */
18 #include <linux/kernel.h>
19 #include <linux/errno.h>
20 #include <linux/init.h>
21 #include <linux/slab.h>
22 #include <linux/tty.h>
23 #include <linux/tty_driver.h>
24 #include <linux/tty_flip.h>
25 #include <linux/module.h>
26 #include <linux/spinlock.h>
27 #include <linux/workqueue.h>
28 #include <linux/firmware.h>
29 #include <linux/ihex.h>
30 #include <linux/uaccess.h>
31 #include <linux/usb.h>
32 #include <linux/usb/serial.h>
36 /* make a simple define to handle if we are compiling keyspan_pda or xircom support */
37 #if defined(CONFIG_USB_SERIAL_KEYSPAN_PDA) || defined(CONFIG_USB_SERIAL_KEYSPAN_PDA_MODULE)
38 #define KEYSPAN
39 #else
40 #undef KEYSPAN
41 #endif
42 #if defined(CONFIG_USB_SERIAL_XIRCOM) || defined(CONFIG_USB_SERIAL_XIRCOM_MODULE)
43 #define XIRCOM
44 #else
45 #undef XIRCOM
46 #endif
48 /*
49 * Version Information
50 */
62 };
65 #define KEYSPAN_VENDOR_ID 0x06cd
66 #define KEYSPAN_PDA_FAKE_ID 0x0103
69 /* For Xircom PGSDB9 and older Entregra version of the same device */
70 #define XIRCOM_VENDOR_ID 0x085a
71 #define XIRCOM_FAKE_ID 0x8027
72 #define ENTREGRA_VENDOR_ID 0x1645
73 #define ENTREGRA_FAKE_ID 0x8093
76 #ifdef KEYSPAN
78 #endif
79 #ifdef XIRCOM
82 #endif
85 };
95 };
100 };
102 #ifdef KEYSPAN
106 };
107 #endif
109 #ifdef XIRCOM
113 { }
114 };
115 #endif
118 {
126 }
129 {
136 /* ask the device to tell us when the tx buffer becomes
137 sufficiently empty */
141 USB_TYPE_VENDOR | USB_RECIP_INTERFACE
145 NULL,
151 }
155 {
166 /* success */
171 /* this urb is terminated, clean up */
179 }
181 /* see if the message is data or a status interrupt */
185 /* rest of message is rx data */
190 }
194 /* status interrupt */
201 /* queue up a wakeup at scheduler time */
206 }
210 }
212 exit:
218 }
222 {
223 /* stop receiving characters. We just turn off the URB request, and
224 let chars pile up in the device. If we're doing hardware
225 flowcontrol, the device will signal the other end when its buffer
226 fills up. If we're doing XON/XOFF, this would be a good time to
227 send an XOFF, although it might make sense to foist that off
228 upon the device too. */
232 }
236 {
238 /* just restart the receive interrupt URB */
242 }
246 {
284 }
286 /* rather than figure out how to sleep while waiting for this
287 to complete, I just use the "legacy" API. */
290 USB_TYPE_VENDOR
291 | USB_RECIP_INTERFACE
301 }
305 {
313 else
322 /* there is something funky about this.. the TCSBRK that 'cu' performs
323 ought to translate into a break_ctl(-1),break_ctl(0) pair HZ/4
324 seconds apart, but it feels like the break sent isn't as long as it
325 is on /dev/ttyS0 */
326 }
331 {
333 speed_t speed;
335 /* cflag specifies lots of stuff: number of stop bits, parity, number
336 of data bits, baud. What can the device actually handle?:
337 CSTOPB (1 stop bit or 2)
338 PARENB (parity)
339 CSIZE (5bit .. 8bit)
340 There is minimal hw support for parity (a PSW bit seems to hold the
341 parity of whatever is in the accumulator). The UART either deals
342 with 10 bits (start, 8 data, stop) or 11 bits (start, 8 data,
343 1 special, stop). So, with firmware changes, we could do:
344 8N1: 10 bit
345 8N2: 11 bit, extra bit always (mark?)
346 8[EOMS]1: 11 bit, extra bit is parity
347 7[EOMS]1: 10 bit, b0/b7 is parity
348 7[EOMS]2: 11 bit, b0/b7 is parity, extra bit always (mark?)
350 HW flow control is dictated by the tty->termios->c_cflags & CRTSCTS
351 bit.
353 For now, just do baud. */
360 /* It hasn't changed so.. */
362 }
363 /* Only speed can change so copy the old h/w parameters
364 then encode the new speed */
367 }
370 /* modem control pins: DTR and RTS are outputs and can be controlled.
371 DCD, RI, DSR, CTS are inputs and can be read. All outputs can also be
372 read. The byte passed is: DTR(b7) DCD RI DSR CTS RTS(b2) unused unused */
376 {
393 }
398 {
405 }
408 {
418 value =
426 }
430 {
451 }
455 {
462 /* guess how much room is left in the device's ring buffer, and if we
463 want to send more than that, check first, updating our notion of
464 what is left. If our write will result in no room left, ask the
465 device to give us an interrupt when the room available rises above
466 a threshold, and hold off all writers (eventually, those using
467 select() or poll() too) until we receive that unthrottle interrupt.
468 Block if we can't write anything at all, otherwise write as much as
469 we can. */
474 }
476 /* we might block because of:
477 the TX urb is in-flight (wait until it completes)
478 the device is full (wait until it says there is room)
479 */
484 }
488 /* At this point the URB is in our control, nobody else can submit it
489 again (the only sudden transition was the one from EINPROGRESS to
490 finished). Also, the tx process is not throttled. So we are
491 ready to write. */
495 /* Check if we might overrun the Tx buffer. If so, ask the
496 device how much room it really has. This is done only on
497 scheduler time, since usb_control_msg() sleeps. */
505 }
510 USB_TYPE_VENDOR | USB_RECIP_INTERFACE
514 room,
520 }
525 }
530 }
531 }
533 /* we're about to completely fill the Tx buffer, so
534 we'll be throttled afterwards. */
537 }
540 /* now transfer data */
542 /* send the data out the bulk port */
551 }
553 /* There wasn't any room left, so we are throttled until
554 the buffer empties a bit */
556 }
561 }
564 exit:
568 }
572 {
579 /* queue up a wakeup at scheduler time */
581 }
585 {
589 /* used by n_tty.c for processing of tabs and such. Giving it our
590 conservative guess is probably good enough, but needs testing by
591 running a console through the device. */
593 }
597 {
605 /* when throttled, return at least WAKEUP_CHARS to tell select() (via
606 n_tty.c:normal_poll() ) that we're not writeable. */
613 }
617 {
623 else
625 }
626 }
631 {
637 /* find out how much room is in the Tx ring */
644 USB_TYPE_VENDOR | USB_RECIP_INTERFACE
648 room,
654 }
659 }
664 /*Start reading from the device*/
669 }
670 error:
673 }
675 {
679 /* shutdown our bulk reads and writes */
682 }
683 }
686 /* download the firmware to a "fake" device (pre-renumeration) */
688 {
694 /* download the firmware here ... */
698 #ifdef KEYSPAN
701 #endif
702 #ifdef XIRCOM
706 #endif
709 __func__);
711 }
714 fw_name);
716 }
729 }
731 }
733 /* bring device out of reset. Renumeration will occur in a moment
734 and the new device will bind to the real driver */
737 /* we want this device to fail to have a driver assigned to it. */
739 }
741 #ifdef KEYSPAN
743 #endif
744 #ifdef XIRCOM
746 #endif
749 {
753 /* allocate the private data structures for all ports. Well, for all
754 one ports. */
766 }
769 {
773 }
775 #ifdef KEYSPAN
780 },
786 };
787 #endif
789 #ifdef XIRCOM
794 },
800 };
801 #endif
807 },
828 };
832 {
837 #ifdef KEYSPAN
841 #endif
842 #ifdef XIRCOM
846 #endif
853 failed_usb_register:
854 #ifdef XIRCOM
856 failed_xircom_register:
858 #ifdef KEYSPAN
860 #endif
861 #ifdef KEYSPAN
862 failed_pda_fake_register:
863 #endif
865 failed_pda_register:
867 }
871 {
874 #ifdef KEYSPAN
876 #endif
877 #ifdef XIRCOM
879 #endif
880 }