| blob | 02fafecd47738a23dc9bf40de76e59b374653e4b |
1 /*
2 * Driver for Quatech Inc USB2.0 to serial adaptors. Largely unrelated to the
3 * serqt_usb driver, based on a re-write of the vendor supplied serqt_usb2 code,
4 * which is unrelated to the serqt_usb2 in the staging kernel
5 */
7 #include <linux/errno.h>
8 #include <linux/init.h>
9 #include <linux/slab.h>
10 #include <linux/tty.h>
11 #include <linux/tty_driver.h>
12 #include <linux/tty_flip.h>
13 #include <linux/module.h>
14 #include <linux/serial.h>
15 #include <linux/usb.h>
16 #include <linux/usb/serial.h>
17 #include <linux/uaccess.h>
21 /* Version Information */
26 /* vendor and device IDs */
36 /* magic numbers go here, when we find out which ones are needed */
42 #define QT2_TX_HEADER_LENGTH 5
43 /* length of the header sent to the box with each write URB */
45 /* directions for USB transfers */
46 #define USBD_TRANSFER_DIRECTION_IN 0xc0
47 #define USBD_TRANSFER_DIRECTION_OUT 0x40
49 /* special Quatech command IDs. These are pushed down the
50 USB control pipe to get the box on the end to do things */
51 #define QT_SET_GET_DEVICE 0xc2
52 #define QT_OPEN_CLOSE_CHANNEL 0xca
53 /*#define QT_GET_SET_PREBUF_TRIG_LVL 0xcc
54 #define QT_SET_ATF 0xcd*/
55 #define QT2_GET_SET_REGISTER 0xc0
56 #define QT2_GET_SET_UART 0xc1
57 #define QT2_HW_FLOW_CONTROL_MASK 0xc5
58 #define QT2_SW_FLOW_CONTROL_MASK 0xc6
59 #define QT2_SW_FLOW_CONTROL_DISABLE 0xc7
60 #define QT2_BREAK_CONTROL 0xc8
61 #define QT2_STOP_RECEIVE 0xe0
62 #define QT2_FLUSH_DEVICE 0xc4
63 #define QT2_GET_SET_QMCR 0xe1
65 /* sorts of flush we can do on */
66 #define QT2_FLUSH_RX 0x00
67 #define QT2_FLUSH_TX 0x01
69 /* port setting constants, used to set up serial port speeds, flow
70 * control and so on */
71 #define QT2_SERIAL_MCR_DTR 0x01
72 #define QT2_SERIAL_MCR_RTS 0x02
73 #define QT2_SERIAL_MCR_LOOP 0x10
75 #define QT2_SERIAL_MSR_CTS 0x10
76 #define QT2_SERIAL_MSR_CD 0x80
77 #define QT2_SERIAL_MSR_RI 0x40
78 #define QT2_SERIAL_MSR_DSR 0x20
79 #define QT2_SERIAL_MSR_MASK 0xf0
81 #define QT2_SERIAL_8_DATA 0x03
82 #define QT2_SERIAL_7_DATA 0x02
83 #define QT2_SERIAL_6_DATA 0x01
84 #define QT2_SERIAL_5_DATA 0x00
86 #define QT2_SERIAL_ODD_PARITY 0x08
87 #define QT2_SERIAL_EVEN_PARITY 0x18
88 #define QT2_SERIAL_TWO_STOPB 0x04
89 #define QT2_SERIAL_ONE_STOPB 0x00
91 #define QT2_MAX_BAUD_RATE 921600
92 #define QT2_MAX_BAUD_REMAINDER 4608
94 #define QT2_SERIAL_LSR_OE 0x02
95 #define QT2_SERIAL_LSR_PE 0x04
96 #define QT2_SERIAL_LSR_FE 0x08
97 #define QT2_SERIAL_LSR_BI 0x10
99 /* value of Line Status Register when UART has completed
100 * emptying data out on the line */
101 #define QT2_LSR_TEMT 0x40
103 /* register numbers on each UART, for use with qt2_box_[get|set]_register*/
104 #define QT2_XMT_HOLD_REGISTER 0x00
105 #define QT2_XVR_BUFFER_REGISTER 0x00
106 #define QT2_FIFO_CONTROL_REGISTER 0x02
107 #define QT2_LINE_CONTROL_REGISTER 0x03
108 #define QT2_MODEM_CONTROL_REGISTER 0x04
109 #define QT2_LINE_STATUS_REGISTER 0x05
110 #define QT2_MODEM_STATUS_REGISTER 0x06
112 /* handy macros for doing escape sequence parsing on data reads */
113 #define THISCHAR ((unsigned char *)(urb->transfer_buffer))[i]
114 #define NEXTCHAR ((unsigned char *)(urb->transfer_buffer))[i + 1]
115 #define THIRDCHAR ((unsigned char *)(urb->transfer_buffer))[i + 2]
116 #define FOURTHCHAR ((unsigned char *)(urb->transfer_buffer))[i + 3]
117 #define FIFTHCHAR ((unsigned char *)(urb->transfer_buffer))[i + 4]
128 };
132 /* custom structures we need go here */
139 };
141 /**
142 * quatech2_port: Structure in which to keep all the messy stuff that this
143 * driver needs alongside the usb_serial_port structure
144 * @read_urb_busy: Flag indicating that port->read_urb is in use
145 * @close_pending: flag indicating that this port is in the process of
146 * being closed (and so no new reads / writes should be started).
147 * @shadowLSR: Last received state of the line status register, holds the
148 * value of the line status flags from the port
149 * @shadowMSR: Last received state of the modem status register, holds
150 * the value of the modem status received from the port
151 * @rcv_flush: Flag indicating that a receive flush has occurred on
152 * the hardware.
153 * @xmit_flush: Flag indicating that a transmit flush has been processed by
154 * the hardware.
155 * @tx_pending_bytes: Number of bytes waiting to be sent. This total
156 * includes the size (excluding header) of URBs that have been submitted but
157 * have not yet been sent to to the device, and bytes that have been sent out
158 * of the port but not yet reported sent by the "xmit_empty" messages (which
159 * indicate the number of bytes sent each time they are received, despite the
160 * misleading name).
161 * - Starts at zero when port is initialised.
162 * - is incremented by the size of the data to be written (no headers)
163 * each time a write urb is dispatched.
164 * - is decremented each time a "transmit empty" message is received
165 * by the driver in the data stream.
166 * @lock: Mutex to lock access to this structure when we need to ensure that
167 * races don't occur to access bits of it.
168 * @open_count: The number of uses of the port currently having
169 * it open, i.e. the reference count.
170 */
175 __u8 shadowLSR;
176 __u8 shadowMSR;
185 wait_queue_head_t wait;
190 spinlock_t lock;
191 };
193 /**
194 * Structure to hold device-wide internal status information
195 * @param ReadBulkStopped The last bulk read attempt ended in tears
196 * @param open_ports The number of serial ports currently in use on the box
197 * @param current_port Pointer to the serial port structure of the port which
198 * the read stream is currently directed to. Escape sequences in the read
199 * stream will change this around as data arrives from different ports on the
200 * box
201 * @buffer_size: The max size buffer each URB can take, used to set the size of
202 * the buffers allocated for writing to each port on the device (we need to
203 * store this because it is known only to the endpoint, but used each time a
204 * port is opened and a new buffer is allocated.
205 */
211 };
213 /* structure which holds line and modem status flags */
215 __u8 line_status;
216 __u8 modem_status;
217 };
219 /* Function prototypes */
222 __u8 QMCR_Value);
238 Uart_Number);
271 /* implementation functions, roughly in order of use, are here */
273 {
301 }
303 }
306 {
311 /* stuff for storing endpoint addresses now */
316 /* check how many endpoints there are on the device, for
317 * sanity's sake */
324 }
327 /* Set up per-device private data, storing extra data alongside
328 * struct usb_serial */
332 __func__);
334 }
338 /* Now setup per port private data, which replaces all the things
339 * that quatech added to standard kernel structures in their driver */
347 }
348 /* initialise stuff in the structure */
353 }
355 /* gain access to port[0]'s structure because we want to store
356 * device-level stuff in it */
361 /* print endpoint addresses so we can check them later
362 * by hand */
367 /* we found a bulk in endpoint */
370 }
374 /* we found a bulk out endpoint */
378 /* max size of URB needs recording for the device */
379 }
382 /* switch on power to the hardware */
386 }
387 /* set all ports to RS232 mode */
391 i);
393 }
394 }
398 startup_error:
404 }
411 }
414 {
429 }
430 }
431 /* This function is called once per serial port on the device, when
432 * that port is opened by a userspace application.
433 * The tty_struct and the usb_serial_port belong to this port,
434 * i.e. there are multiple ones for a multi-port device.
435 * However the usb_serial_port structure has a back-pointer
436 * to the parent usb_serial structure which belongs to the device,
437 * so we can access either the device-wide information or
438 * any other port's information (because there are also forward
439 * pointers) via that pointer.
440 * This is most helpful if the device shares resources (e.g. end
441 * points) between different ports
442 */
444 {
465 }
467 /* get the device private data */
471 }
476 }
483 }
485 /* FIXME: are these needed? Does it even do anything useful? */
486 /* get the modem and line status values from the UART */
493 }
501 /* port_extra->fifo_empty_flag = true;*/
505 /* Set Baud rate to default and turn off flow control here */
507 default_LCR);
512 }
516 /*
517 * At this point we will need some end points to make further progress.
518 * Handlily, the correct endpoint addresses have been filled out into
519 * the usb_serial_port structure for us by the driver core, so we
520 * already have access to them.
521 * As there is only one bulk in and one bulk out end-point, these are in
522 * port[0]'s structure, and the rest are uninitialised. Handily,
523 * when we do a write to a port, we will use the same endpoint
524 * regardless of the port, with a 5-byte header added on to
525 * tell the box which port it should eventually come out of, so we only
526 * need the one set of endpoints. We will have one URB per port for
527 * writing, so that multiple ports can be writing at once.
528 * Finally we need a bulk in URB to use for background reads from the
529 * device, which will deal with uplink data from the box to host.
530 */
535 /* set up write_urb for bulk out transfers on this port. The USB
536 * serial framework will have allocated a blank URB, buffer etc for
537 * port0 when it put the endpoints there, but not for any of the other
538 * ports on the device because there are no more endpoints. Thus we
539 * have to allocate our own URBs for ports 1-7
540 */
547 }
548 /* buffer same size as port0 */
551 GFP_KERNEL);
555 }
556 }
566 qt2_write_bulk_callback,
567 port);
571 /* this is first port to be opened, so need the read URB
572 * initialised for bulk in transfers (this is shared amongst
573 * all the ports on the device) */
582 /* submit URB, i.e. start reading from device (async) */
592 }
594 /* When the first port is opened, initialise the value of
595 * current_port in dev_extra to this port, so it is set
596 * to something. Once the box sends data it will send the
597 * relevant escape sequences to get it to the right port anyway
598 */
600 }
602 /* initialize our wait queues */
604 /* increment the count of openings of this port by one */
607 /* remember to store dev_extra, port_extra and port0_extra back again at
608 * end !*/
616 }
618 /* called when a port is closed by userspace. It won't be called, however,
619 * until calls to chars_in_buffer() reveal that the port has completed
620 * sending buffered data, and there is nothing else to do. Thus we don't have
621 * to rely on forcing data through in this function. */
622 /* Setting close_pending should keep new data from being written out,
623 * once all the data in the enpoint buffers is moved out we won't get
624 * any more. */
625 /* BoxStopReceive would keep any more data from coming from a given
626 * port, but isn't called by the vendor driver, although their comments
627 * mention it. Should it be used here to stop the inbound data
628 * flow?
629 */
631 {
632 /* time out value for flush loops */
643 /* get the device private data */
646 /* we can now (and only now) stop reading data */
649 /* although the USB side is now empty, the UART itself may
650 * still be pushing characters out over the line, so we have to
651 * wait testing the actual line status until the lines change
652 * indicating that the data is done transferring. */
653 /* FIXME: slow this polling down so it doesn't run the USB bus flat out
654 * if it actually has to spend any time in this loop (which it normally
655 * doesn't because the buffer is nearly empty) */
663 }
667 }
675 /* to avoid leaking URBs, we should now free the write_urb for this
676 * port and set the pointer to null so that next time the port is opened
677 * a new URB is allocated. This avoids leaking URBs when the device is
678 * removed */
684 /* decrement the count of openings of this port by one */
686 /* one less overall open as well */
690 }
692 /**
693 * qt2_write - write bytes from the tty layer out to the USB device.
694 * @buf: The data to be written, size at least count.
695 * @count: The number of bytes requested for transmission.
696 * @return The number of bytes actually accepted for transmission to the device.
697 */
700 {
703 port on the device */
717 }
719 /* check if the write urb is already in use, i.e. data already being
720 * sent to this port */
722 /* Fifo hasn't been emptied since last write to this port */
725 /* schedule_work(&port->work); commented in vendor driver */
728 /* buffer is full (==). > should not occur, but would indicate
729 * that an overflow had occurred */
731 /* schedule_work(&port->work); commented in vendor driver */
733 }
735 /* We must fill the first 5 bytes of anything we sent with a transmit
736 * header which directes the data to the correct port. The maximum
737 * size we can send out in one URB is port->bulk_out_size, which caps
738 * the number of bytes of real data we can send in each write. As the
739 * semantics of write allow us to write less than we were give, we cap
740 * the maximum we will ever write to the device as 5 bytes less than
741 * one URB's worth, by reducing the value of the count argument
742 * appropriately*/
747 }
748 /* we must also ensure that the FIFO at the other end can cope with the
749 * URB we send it, otherwise it will have problems. As above, we can
750 * restrict the write size by just shrinking count.*/
755 }
756 /* now build the header for transmission */
762 /* copy header into URB */
764 QT2_TX_HEADER_LENGTH);
765 /* and actual data to write */
770 /* set up our urb */
776 /* send the data out the bulk port */
779 /* error couldn't submit urb */
789 }
791 }
793 /* This is used by the next layer up to know how much space is available
794 * in the buffer on the device. It is used on a device closure to avoid
795 * calling close() until the buffer is reported to be empty.
796 * The returned value must never go down by more than the number of bytes
797 * written for correct behaviour further up the driver stack, i.e. if I call
798 * it, then write 6 bytes, then call again I should get 6 less, or possibly
799 * only 5 less if one was written in the meantime, etc. I should never get 7
800 * less (or any bigger number) because I only wrote 6 bytes.
801 */
803 {
805 /* parent usb_serial_port pointer */
813 }
814 /* Q: how many bytes would a write() call actually succeed in writing
815 * if it happened now?
816 * A: one QT2_FIFO_DEPTH, less the number of bytes waiting to be sent
817 * out of the port, unless this is more than the size of the
818 * write_urb output buffer less the header, which is the maximum
819 * size write we can do.
821 * Most of the implementation of this is done when writes to the device
822 * are started or terminate. When we send a write to the device, we
823 * reduce the free space count by the size of the dispatched write.
824 * When a "transmit empty" message comes back up the USB read stream,
825 * we decrement the count by the number of bytes reported sent, thus
826 * keeping track of the difference between sent and received bytes.
827 */
830 /* space in FIFO */
833 /* if more than the URB can hold, then cap to that limit */
837 }
840 {
842 /* parent usb_serial_port pointer */
849 }
851 /* called when userspace does an ioctl() on the device. Note that
852 * TIOCMGET and TIOCMSET are filtered off to their own methods before they get
853 * here, so we don't have to handle them.
854 */
857 {
863 * Register used to implement waiting for a line status change to
864 * occur */
867 /* Declare a wait queue named "wait" */
914 }
927 /* see if a signal woke us up */
935 }
950 }
952 /* FIXME: This while loop needs a way to break out if the device
953 * is disconnected while a process is waiting for the MSR to
954 * change, because once it's disconnected, it isn't going to
955 * change state ... */
957 /* any other ioctls we don't know about come here */
961 }
962 }
964 /* Called when the user wishes to change the port settings using the termios
965 * userspace interface */
968 {
973 __u16 UartNumber;
998 }
1000 /* Parity stuff */
1004 else
1006 }
1007 /* Because LCR_change_to is initialised to zero, we don't have to worry
1008 * about the case where PARENB is not set or clearing bits, because by
1009 * default all of them are cleared, turning parity off.
1010 * as we don't support mark/space parity, we should clear the
1011 * mark/space parity bit in c_cflag, so the caller can tell we have
1012 * ignored the request */
1017 else
1020 /* Thats the LCR stuff, next we need to work out the divisor as the
1021 * LCR and the divisor are set together */
1024 /* pick a default, any default... */
1026 }
1031 /* Round to nearest divisor */
1033 divisor++;
1038 LCR_change_to);
1043 /* now encode the baud rate we actually set, which may be
1044 * different to the request */
1047 }
1049 /* Now determine flow control */
1053 /* Enable RTS/CTS flow control */
1058 }
1060 /* Disable RTS/CTS flow control */
1067 }
1068 }
1069 /* if we are implementing XON/XOFF, set the start and stop character
1070 * in the device */
1075 start_char);
1079 /* disable SW flow control */
1083 }
1084 }
1087 {
1109 }
1112 /*DTR set */
1114 /*RTS set */
1116 /* CTS set */
1118 /*Carrier detect set */
1120 /* Ring indicator set */
1122 /* DSR set */
1126 }
1127 }
1131 {
1149 /* Turn off RTS, DTR and loopback, then only turn on what was asked
1150 * for */
1152 QT2_SERIAL_MCR_LOOP);
1164 else
1166 }
1168 /** qt2_break - Turn BREAK on and off on the UARTs
1169 */
1171 {
1175 __u16 break_value;
1182 }
1186 else
1189 break_value);
1195 }
1200 exit:
1204 }
1205 /**
1206 * qt2_throttle: - stop reading new data from the port
1207 */
1209 {
1220 }
1226 }
1227 /* Send command to box to stop receiving stuff. This will stop this
1228 * particular UART from filling the endpoint - in the multiport case the
1229 * FPGA UART will handle any flow control implemented, but for the single
1230 * port it's handed differently and we just quit submitting urbs
1231 */
1236 exit:
1240 }
1242 /**
1243 * qt2_unthrottle: - start receiving data through the port again after being
1244 * throttled
1245 */
1247 {
1258 }
1268 }
1274 /* Send command to box to start receiving stuff */
1283 qt2_read_bulk_callback,
1284 serial);
1285 }
1286 }
1287 exit:
1291 }
1293 /* internal, private helper functions for the driver */
1295 /* Power up the FPGA in the box to get it working */
1297 {
1299 __u8 Direcion;
1307 }
1309 /*
1310 * qt2_boxsetQMCR Issue a QT2_GET_SET_QMCR vendor-spcific request on the
1311 * default control pipe. If successful return the number of bytes written,
1312 * otherwise return a negative error number of the problem.
1313 */
1315 __u8 QMCR_Value)
1316 {
1318 __u16 PortSettings;
1329 }
1333 {
1337 }
1341 }
1343 }
1347 {
1351 }
1356 }
1359 }
1363 {
1365 }
1369 {
1371 }
1375 {
1377 }
1380 {
1382 }
1386 {
1388 __u16 length;
1389 __u8 Direcion;
1397 }
1399 {
1401 __u8 direcion;
1408 }
1410 /* qt2_conf_uart Issue a SET_UART vendor-spcific request on the default
1411 * control pipe. If successful sets baud rate divisor and LCR value
1412 */
1415 {
1425 }
1427 /** @brief Callback for asynchronous submission of read URBs on bulk in
1428 * endpoints
1429 *
1430 * Registered in qt2_open_port(), used to deal with incomming data
1431 * from the box.
1432 */
1434 {
1435 /* Get the device pointer (struct usb_serial) back out of the URB */
1437 /* get the extra struct for the device */
1439 /* Get first port structure from the device */
1441 /* Get the currently active port structure from serial struct */
1443 /* get the extra struct for port 0 */
1445 /* and for the currently active port */
1447 /* When we finally get to doing some tty stuff, we will need this */
1453 * parsing an escape sequence, rather than
1454 * ordinary data */
1459 /* read didn't go well */
1464 }
1466 /* inline port_sofrint() here */
1469 __func__);
1471 }
1476 }
1478 /* This single callback function has to do for all the ports on
1479 * the device. Data being read up the USB can contain certain
1480 * escape sequences which are used to communicate out-of-band
1481 * information from the serial port in-band over the USB.
1482 * These escapes include sending modem and flow control line
1483 * status, and switching the port. The concept of a "Current Port"
1484 * is used, which is where data is going until a port change
1485 * escape seqence is received. This Current Port is kept between
1486 * callbacks so that when this function enters we know which the
1487 * currently active port is and can get to work right away without
1488 * the box having to send repeat escape sequences (anyway, how
1489 * would it know to do so?).
1490 */
1493 /* We are closing , stop reading */
1496 /* If this is the only port left open - stop the
1497 * bulk read */
1501 }
1502 }
1504 /*
1505 * RxHolding is asserted by throttle, if we assert it, we're not
1506 * receiving any more characters and let the box handle the flow
1507 * control
1508 */
1511 /* single port device, input is already stopped, so we don't
1512 * need any more input data */
1515 }
1516 /* finally, we are in a situation where we might consider the data
1517 * that is contained within the URB, and what to do about it.
1518 * This is likely to involved communicating up to the TTY layer, so
1519 * we will need to get hold of the tty for the port we are currently
1520 * dealing with */
1522 /* active is a usb_serial_port. It has a member port which is a
1523 * tty_port. From this we get a tty_struct pointer which is what we
1524 * actually wanted, and keep it on tty_st */
1529 }
1533 /* skip all this if no data to process */
1535 /* Look ahead code here -works on several bytes at onc*/
1538 /* we are in an escape sequence, type
1539 * determined by the 3rd char */
1543 /* Line status change 4th byte must
1544 * follow */
1549 }
1551 FOURTHCHAR);
1556 /* Modem status status change 4th byte
1557 * must follow */
1562 }
1564 FOURTHCHAR);
1569 /* xmit hold empty 4th byte
1570 * must follow */
1575 }
1582 /* Port number change 4th byte
1583 * must follow */
1588 }
1589 /* Port change. If port open push
1590 * current data up to tty layer */
1595 FOURTHCHAR);
1597 FOURTHCHAR);
1600 /* having changed port, the pointers for
1601 * the currently active port are all out
1602 * of date and need updating */
1604 active_extra =
1610 /* Recv flush 3rd byte must
1611 * follow */
1616 }
1622 /* xmit flush 3rd byte must follow */
1627 }
1645 /* if we did an escape char, we don't need
1646 * to mess around pushing data through the
1647 * tty layer, and can go round again */
1655 }
1660 /* at this point we have complete dealing with the data for this
1661 * callback. All we have to do now is to start the async read process
1662 * back off again. */
1675 /* if some inbound data was processed, then
1676 * we need to push that through the tty layer
1677 */
1680 }
1681 }
1683 /* cribbed from serqt_usb2 driver, but not sure which work needs
1684 * scheduling - port0 or currently active port? */
1685 /* schedule_work(&port->work); */
1688 }
1690 /** @brief Callback for asynchronous submission of write URBs on bulk in
1691 * endpoints
1692 *
1693 * Registered in qt2_write(), used to deal with outgoing data
1694 * to the box.
1695 */
1697 {
1704 }
1709 }
1710 /* FIXME What is supposed to be going on here?
1711 * does this actually do anything useful, and should it?
1712 */
1713 /*port_softint((void *) serial); commented in vendor driver */
1717 }
1721 {
1722 /* obtain the private structure for the port */
1726 }
1729 {
1730 /* obtain the private structure for the port */
1734 /* this wakes up the otherwise indefinitely waiting code for
1735 * the TIOCMIWAIT ioctl, so that it can notice that
1736 * port_extra->shadowMSR has changed and the ioctl needs to return.
1737 */
1738 }
1742 {
1744 /* obtain the private structure for the port */
1749 /* byte_count indicates how many bytes the device has written out. This
1750 * message appears to occur regularly, and is used in the vendor driver
1751 * to keep track of the fill state of the port transmit buffer */
1753 /* reduce the stored data queue length by the known number of bytes
1754 * sent */
1758 /*port_extra->xmit_fifo_room_bytes = FIFO_DEPTH; ???*/
1759 }
1763 {
1764 /* obtain the parent usb serial device structure */
1766 /* obtain the private structure for the device */
1769 /* what should I do with this? commented out in upstream
1770 * driver */
1771 /*schedule_work(&port->work);*/
1772 }
1775 {
1776 /* obtain the private structure for the port */
1779 }
1781 {
1782 /* obtain the private structure for the port */
1785 }
1789 {
1790 /* get the tty_struct for this port */
1792 /* get the URB with the data in to push */
1798 /* should this be commented out here? */
1799 /*tty_flip_buffer_push(tty);*/
1800 }
1801 }
1803 /** @brief Retrieve the value of a register from the device
1804 *
1805 * Issues a GET_REGISTER vendor-spcific request over the USB control
1806 * pipe to obtain a value back from a specific register on a specific
1807 * UART
1808 * @param serial Serial device handle to access the device through
1809 * @param uart_number Which UART the value is wanted from
1810 * @param register_num Which register to read the value from
1811 * @param pValue Pointer to somewhere to put the retrieved value
1812 */
1816 {
1822 }
1824 /** qt2_box_set_register
1825 * Issue a SET_REGISTER vendor-specific request on the default control pipe
1826 */
1830 {
1842 }
1844 /** qt2_boxsetuart - Issue a SET_UART vendor-spcific request on the default
1845 * control pipe. If successful sets baud rate divisor and LCR value.
1846 */
1849 {
1857 }
1859 /** qt2_boxsethw_flowctl - Turn hardware (RTS/CTS) flow control on and off for
1860 * a hardware UART.
1861 */
1864 {
1871 /* flow control, box will clear RTS line to prevent remote
1872 * device from transmitting more chars */
1874 /* no flow control to remote device */
1876 }
1881 /* flow control on, box will inhibit tx data if CTS line is
1882 * asserted */
1884 /* Box will not inhibit tx data due to CTS line */
1886 }
1891 }
1893 /** qt2_boxsetsw_flowctl - Turn software (XON/XOFF) flow control on for
1894 * a hardware UART, and set the XON and XOFF characters.
1895 */
1898 {
1899 __u16 nSWflowout;
1906 }
1908 /** qt2_boxunsetsw_flowctl - Turn software (XON/XOFF) flow control off for
1909 * a hardware UART.
1910 */
1912 {
1916 }
1918 /**
1919 * qt2_boxstoprx - Start and stop reception of data by the FPGA UART in
1920 * response to requests from the tty layer
1921 * @serial: pointer to the usb_serial structure for the parent device
1922 * @uart_number: which UART on the device we are addressing
1923 * @stop: Whether to start or stop data reception. Set to 1 to stop data being
1924 * received, and to 0 to start it being received.
1925 */
1928 {
1931 }
1934 /*
1935 * last things in file: stuff to register this driver into the generic
1936 * USB serial framework.
1937 */
1943 },
1965 };
1968 {
1973 /* register with usb-serial */
1982 /* register with usb */
1988 /* if we're here, usb_register() failed */
1990 failed_usb_serial_register:
1992 }
1995 {
1998 }