| blob | c645455c3fd1552ed9f7932bd28dabb7f963280d |
1 /*****************************************************************************/
3 /*
4 * istallion.c -- stallion intelligent multiport serial driver.
5 *
6 * Copyright (C) 1996-1999 Stallion Technologies
7 * Copyright (C) 1994-1996 Greg Ungerer.
8 *
9 * This code is loosely based on the Linux serial driver, written by
10 * Linus Torvalds, Theodore T'so and others.
11 *
12 * This program is free software; you can redistribute it and/or modify
13 * it under the terms of the GNU General Public License as published by
14 * the Free Software Foundation; either version 2 of the License, or
15 * (at your option) any later version.
16 *
17 */
19 /*****************************************************************************/
21 #include <linux/module.h>
22 #include <linux/slab.h>
23 #include <linux/interrupt.h>
24 #include <linux/tty.h>
25 #include <linux/tty_flip.h>
26 #include <linux/serial.h>
27 #include <linux/cdk.h>
28 #include <linux/comstats.h>
29 #include <linux/istallion.h>
30 #include <linux/ioport.h>
31 #include <linux/delay.h>
32 #include <linux/init.h>
33 #include <linux/device.h>
34 #include <linux/wait.h>
35 #include <linux/eisa.h>
36 #include <linux/ctype.h>
38 #include <asm/io.h>
39 #include <asm/uaccess.h>
41 #include <linux/pci.h>
43 /*****************************************************************************/
45 /*
46 * Define different board types. Not all of the following board types
47 * are supported by this driver. But I will use the standard "assigned"
48 * board numbers. Currently supported boards are abbreviated as:
49 * ECP = EasyConnection 8/64, ONB = ONboard, BBY = Brumby and
50 * STAL = Stallion.
51 */
52 #define BRD_UNKNOWN 0
53 #define BRD_STALLION 1
54 #define BRD_BRUMBY4 2
55 #define BRD_ONBOARD2 3
56 #define BRD_ONBOARD 4
57 #define BRD_ONBOARDE 7
58 #define BRD_ECP 23
59 #define BRD_ECPE 24
60 #define BRD_ECPMC 25
61 #define BRD_ECPPCI 29
63 #define BRD_BRUMBY BRD_BRUMBY4
65 /*
66 * Define a configuration structure to hold the board configuration.
67 * Need to set this up in the code (for now) with the boards that are
68 * to be configured into the system. This is what needs to be modified
69 * when adding/removing/modifying boards. Each line entry in the
70 * stli_brdconf[] array is a board. Each line contains io/irq/memory
71 * ranges for that board (as well as what type of board it is).
72 * Some examples:
73 * { BRD_ECP, 0x2a0, 0, 0xcc000, 0, 0 },
74 * This line will configure an EasyConnection 8/64 at io address 2a0,
75 * and shared memory address of cc000. Multiple EasyConnection 8/64
76 * boards can share the same shared memory address space. No interrupt
77 * is required for this board type.
78 * Another example:
79 * { BRD_ECPE, 0x5000, 0, 0x80000000, 0, 0 },
80 * This line will configure an EasyConnection 8/64 EISA in slot 5 and
81 * shared memory address of 0x80000000 (2 GByte). Multiple
82 * EasyConnection 8/64 EISA boards can share the same shared memory
83 * address space. No interrupt is required for this board type.
84 * Another example:
85 * { BRD_ONBOARD, 0x240, 0, 0xd0000, 0, 0 },
86 * This line will configure an ONboard (ISA type) at io address 240,
87 * and shared memory address of d0000. Multiple ONboards can share
88 * the same shared memory address space. No interrupt required.
89 * Another example:
90 * { BRD_BRUMBY4, 0x360, 0, 0xc8000, 0, 0 },
91 * This line will configure a Brumby board (any number of ports!) at
92 * io address 360 and shared memory address of c8000. All Brumby boards
93 * configured into a system must have their own separate io and memory
94 * addresses. No interrupt is required.
95 * Another example:
96 * { BRD_STALLION, 0x330, 0, 0xd0000, 0, 0 },
97 * This line will configure an original Stallion board at io address 330
98 * and shared memory address d0000 (this would only be valid for a "V4.0"
99 * or Rev.O Stallion board). All Stallion boards configured into the
100 * system must have their own separate io and memory addresses. No
101 * interrupt is required.
102 */
111 };
115 /* stli_lock must NOT be taken holding brd_lock */
119 /*
120 * There is some experimental EISA board detection code in this driver.
121 * By default it is disabled, but for those that want to try it out,
122 * then set the define below to be 1.
123 */
124 #define STLI_EISAPROBE 0
126 /*****************************************************************************/
128 /*
129 * Define some important driver characteristics. Device major numbers
130 * allocated as per Linux Device Registry.
131 */
132 #ifndef STL_SIOMEMMAJOR
133 #define STL_SIOMEMMAJOR 28
134 #endif
135 #ifndef STL_SERIALMAJOR
136 #define STL_SERIALMAJOR 24
137 #endif
138 #ifndef STL_CALLOUTMAJOR
139 #define STL_CALLOUTMAJOR 25
140 #endif
142 /*****************************************************************************/
144 /*
145 * Define our local driver identity first. Set up stuff to deal with
146 * all the local structures required by a serial tty driver.
147 */
156 #define STLI_TXBUFSIZE 4096
158 /*
159 * Use a fast local buffer for cooked characters. Typically a whole
160 * bunch of cooked characters come in for a port, 1 at a time. So we
161 * save those up into a local buffer, then write out the whole lot
162 * with a large memcpy. Just use 1 buffer for all ports, since its
163 * use it is only need for short periods of time by each port.
164 */
170 /*
171 * Define a local default termios struct. All ports will be created
172 * with this termios initially. Basically all it defines is a raw port
173 * at 9600 baud, 8 data bits, no parity, 1 stop bit.
174 */
180 };
182 /*
183 * Define global stats structures. Not used often, and can be
184 * re-used for each stats call.
185 */
190 /*****************************************************************************/
197 /*
198 * Per board state flags. Used with the state field of the board struct.
199 * Not really much here... All we need to do is keep track of whether
200 * the board has been detected, and whether it is actually running a slave
201 * or not.
202 */
203 #define BST_FOUND 0x1
204 #define BST_STARTED 0x2
205 #define BST_PROBED 0x4
207 /*
208 * Define the set of port state flags. These are marked for internal
209 * state purposes only, usually to do with the state of communications
210 * with the slave. Most of them need to be updated atomically, so always
211 * use the bit setting operations (unless protected by cli/sti).
212 */
213 #define ST_INITIALIZING 1
214 #define ST_OPENING 2
215 #define ST_CLOSING 3
216 #define ST_CMDING 4
217 #define ST_TXBUSY 5
218 #define ST_RXING 6
219 #define ST_DOFLUSHRX 7
220 #define ST_DOFLUSHTX 8
221 #define ST_DOSIGS 9
222 #define ST_RXSTOP 10
223 #define ST_GETSIGS 11
225 /*
226 * Define an array of board names as printable strings. Handy for
227 * referencing boards when printing trace and stuff.
228 */
238 NULL,
242 NULL,
243 NULL,
244 NULL,
245 NULL,
246 NULL,
247 NULL,
248 NULL,
249 NULL,
260 };
262 /*****************************************************************************/
264 /*
265 * Define some string labels for arguments passed from the module
266 * load line. These allow for easy board definitions, and easy
267 * modification of the io, memory and irq resoucres.
268 */
280 };
282 /*
283 * Define a set of common board names, and types. This is used to
284 * parse any module arguments.
285 */
341 };
343 /*
344 * Define the module agruments.
345 */
360 #if STLI_EISAPROBE != 0
361 /*
362 * Set up a default memory address table for EISA board probing.
363 * The default addresses are all bellow 1Mbyte, which has to be the
364 * case anyway. They should be safe, since we only read values from
365 * them, and interrupts are disabled while we do it. If the higher
366 * memory support is compiled in then we also try probing around
367 * the 1Gb, 2Gb and 3Gb areas as well...
368 */
375 };
378 #endif
380 /*
381 * Define the Stallion PCI vendor and device IDs.
382 */
383 #ifndef PCI_DEVICE_ID_ECRA
384 #define PCI_DEVICE_ID_ECRA 0x0004
385 #endif
390 };
395 /*****************************************************************************/
397 /*
398 * Hardware configuration info for ECP boards. These defines apply
399 * to the directly accessible io ports of the ECP. There is a set of
400 * defines for each ECP board type, ISA, EISA, MCA and PCI.
401 */
402 #define ECP_IOSIZE 4
404 #define ECP_MEMSIZE (128 * 1024)
405 #define ECP_PCIMEMSIZE (256 * 1024)
407 #define ECP_ATPAGESIZE (4 * 1024)
408 #define ECP_MCPAGESIZE (4 * 1024)
409 #define ECP_EIPAGESIZE (64 * 1024)
410 #define ECP_PCIPAGESIZE (64 * 1024)
412 #define STL_EISAID 0x8c4e
414 /*
415 * Important defines for the ISA class of ECP board.
416 */
417 #define ECP_ATIREG 0
418 #define ECP_ATCONFR 1
419 #define ECP_ATMEMAR 2
420 #define ECP_ATMEMPR 3
421 #define ECP_ATSTOP 0x1
422 #define ECP_ATINTENAB 0x10
423 #define ECP_ATENABLE 0x20
424 #define ECP_ATDISABLE 0x00
425 #define ECP_ATADDRMASK 0x3f000
426 #define ECP_ATADDRSHFT 12
428 /*
429 * Important defines for the EISA class of ECP board.
430 */
431 #define ECP_EIIREG 0
432 #define ECP_EIMEMARL 1
433 #define ECP_EICONFR 2
434 #define ECP_EIMEMARH 3
435 #define ECP_EIENABLE 0x1
436 #define ECP_EIDISABLE 0x0
437 #define ECP_EISTOP 0x4
438 #define ECP_EIEDGE 0x00
439 #define ECP_EILEVEL 0x80
440 #define ECP_EIADDRMASKL 0x00ff0000
441 #define ECP_EIADDRSHFTL 16
442 #define ECP_EIADDRMASKH 0xff000000
443 #define ECP_EIADDRSHFTH 24
444 #define ECP_EIBRDENAB 0xc84
446 #define ECP_EISAID 0x4
448 /*
449 * Important defines for the Micro-channel class of ECP board.
450 * (It has a lot in common with the ISA boards.)
451 */
452 #define ECP_MCIREG 0
453 #define ECP_MCCONFR 1
454 #define ECP_MCSTOP 0x20
455 #define ECP_MCENABLE 0x80
456 #define ECP_MCDISABLE 0x00
458 /*
459 * Important defines for the PCI class of ECP board.
460 * (It has a lot in common with the other ECP boards.)
461 */
462 #define ECP_PCIIREG 0
463 #define ECP_PCICONFR 1
464 #define ECP_PCISTOP 0x01
466 /*
467 * Hardware configuration info for ONboard and Brumby boards. These
468 * defines apply to the directly accessible io ports of these boards.
469 */
470 #define ONB_IOSIZE 16
471 #define ONB_MEMSIZE (64 * 1024)
472 #define ONB_ATPAGESIZE (64 * 1024)
473 #define ONB_MCPAGESIZE (64 * 1024)
474 #define ONB_EIMEMSIZE (128 * 1024)
475 #define ONB_EIPAGESIZE (64 * 1024)
477 /*
478 * Important defines for the ISA class of ONboard board.
479 */
480 #define ONB_ATIREG 0
481 #define ONB_ATMEMAR 1
482 #define ONB_ATCONFR 2
483 #define ONB_ATSTOP 0x4
484 #define ONB_ATENABLE 0x01
485 #define ONB_ATDISABLE 0x00
486 #define ONB_ATADDRMASK 0xff0000
487 #define ONB_ATADDRSHFT 16
489 #define ONB_MEMENABLO 0
490 #define ONB_MEMENABHI 0x02
492 /*
493 * Important defines for the EISA class of ONboard board.
494 */
495 #define ONB_EIIREG 0
496 #define ONB_EIMEMARL 1
497 #define ONB_EICONFR 2
498 #define ONB_EIMEMARH 3
499 #define ONB_EIENABLE 0x1
500 #define ONB_EIDISABLE 0x0
501 #define ONB_EISTOP 0x4
502 #define ONB_EIEDGE 0x00
503 #define ONB_EILEVEL 0x80
504 #define ONB_EIADDRMASKL 0x00ff0000
505 #define ONB_EIADDRSHFTL 16
506 #define ONB_EIADDRMASKH 0xff000000
507 #define ONB_EIADDRSHFTH 24
508 #define ONB_EIBRDENAB 0xc84
510 #define ONB_EISAID 0x1
512 /*
513 * Important defines for the Brumby boards. They are pretty simple,
514 * there is not much that is programmably configurable.
515 */
516 #define BBY_IOSIZE 16
517 #define BBY_MEMSIZE (64 * 1024)
518 #define BBY_PAGESIZE (16 * 1024)
520 #define BBY_ATIREG 0
521 #define BBY_ATCONFR 1
522 #define BBY_ATSTOP 0x4
524 /*
525 * Important defines for the Stallion boards. They are pretty simple,
526 * there is not much that is programmably configurable.
527 */
528 #define STAL_IOSIZE 16
529 #define STAL_MEMSIZE (64 * 1024)
530 #define STAL_PAGESIZE (64 * 1024)
532 /*
533 * Define the set of status register values for EasyConnection panels.
534 * The signature will return with the status value for each panel. From
535 * this we can determine what is attached to the board - before we have
536 * actually down loaded any code to it.
537 */
538 #define ECH_PNLSTATUS 2
539 #define ECH_PNL16PORT 0x20
540 #define ECH_PNLIDMASK 0x07
541 #define ECH_PNLXPID 0x40
542 #define ECH_PNLINTRPEND 0x80
544 /*
545 * Define some macros to do things to the board. Even those these boards
546 * are somewhat related there is often significantly different ways of
547 * doing some operation on it (like enable, paging, reset, etc). So each
548 * board class has a set of functions which do the commonly required
549 * operations. The macros below basically just call these functions,
550 * generally checking for a NULL function - which means that the board
551 * needs nothing done to it to achieve this operation!
552 */
553 #define EBRDINIT(brdp) \
554 if (brdp->init != NULL) \
555 (* brdp->init)(brdp)
557 #define EBRDENABLE(brdp) \
558 if (brdp->enable != NULL) \
559 (* brdp->enable)(brdp);
561 #define EBRDDISABLE(brdp) \
562 if (brdp->disable != NULL) \
563 (* brdp->disable)(brdp);
565 #define EBRDINTR(brdp) \
566 if (brdp->intr != NULL) \
567 (* brdp->intr)(brdp);
569 #define EBRDRESET(brdp) \
570 if (brdp->reset != NULL) \
571 (* brdp->reset)(brdp);
573 #define EBRDGETMEMPTR(brdp,offset) \
574 (* brdp->getmemptr)(brdp, offset, __LINE__)
576 /*
577 * Define the maximal baud rate, and the default baud base for ports.
578 */
579 #define STL_MAXBAUD 460800
580 #define STL_BAUDBASE 115200
581 #define STL_CLOSEDELAY (5 * HZ / 10)
583 /*****************************************************************************/
585 /*
586 * Define macros to extract a brd or port number from a minor number.
587 */
588 #define MINOR2BRD(min) (((min) & 0xc0) >> 6)
589 #define MINOR2PORT(min) ((min) & 0x3f)
591 /*****************************************************************************/
593 /*
594 * Prototype all functions in this driver!
595 */
605 static int stli_ioctl(struct tty_struct *tty, struct file *file, unsigned int cmd, unsigned long arg);
621 static ssize_t stli_memwrite(struct file *fp, const char __user *buf, size_t count, loff_t *offp);
622 static int stli_memioctl(struct inode *ip, struct file *fp, unsigned int cmd, unsigned long arg);
627 static int stli_rawopen(struct stlibrd *brdp, struct stliport *portp, unsigned long arg, int wait);
628 static int stli_rawclose(struct stlibrd *brdp, struct stliport *portp, unsigned long arg, int wait);
631 static int stli_cmdwait(struct stlibrd *brdp, struct stliport *portp, unsigned long cmd, void *arg, int size, int copyback);
632 static void stli_sendcmd(struct stlibrd *brdp, struct stliport *portp, unsigned long cmd, void *arg, int size, int copyback);
633 static void __stli_sendcmd(struct stlibrd *brdp, struct stliport *portp, unsigned long cmd, void *arg, int size, int copyback);
665 static void __iomem *stli_ecppcigetmemptr(struct stlibrd *brdp, unsigned long offset, int line);
685 static struct stliport *stli_getport(unsigned int brdnr, unsigned int panelnr, unsigned int portnr);
689 #if STLI_EISAPROBE != 0
691 #endif
694 /*****************************************************************************/
696 /*
697 * Define the driver info for a user level shared memory device. This
698 * device will work sort of like the /dev/kmem device - except that it
699 * will give access to the shared memory on the Stallion intelligent
700 * board. This is also a very useful debugging tool.
701 */
707 };
709 /*****************************************************************************/
711 /*
712 * Define a timer_list entry for our poll routine. The slave board
713 * is polled every so often to see if anything needs doing. This is
714 * much cheaper on host cpu than using interrupts. It turns out to
715 * not increase character latency by much either...
716 */
721 /*
722 * Define the calculation for the timeout routine.
723 */
724 #define STLI_TIMEOUT (jiffies + 1)
726 /*****************************************************************************/
731 {
741 }
742 }
743 }
745 /*****************************************************************************/
747 /*
748 * Parse the supplied argument string, into the board conf struct.
749 */
752 {
765 }
769 }
777 }
779 /*****************************************************************************/
782 {
808 /*
809 * Check if this port is in the middle of closing. If so then wait
810 * until it is closed then return error status based on flag settings.
811 * The sleep here does not need interrupt protection since the wakeup
812 * for it is done with the same context.
813 */
819 }
821 /*
822 * On the first open of the device setup the port hardware, and
823 * initialize the per port data structure. Since initializing the port
824 * requires several commands to the board we will need to wait for any
825 * other open that is already initializing the port.
826 */
841 }
846 }
848 /*
849 * Check if this port is in the middle of closing. If so then wait
850 * until it is closed then return error status, based on flag settings.
851 * The sleep here does not need interrupt protection since the wakeup
852 * for it is done with the same context.
853 */
859 }
861 /*
862 * Based on type of open being done check if it can overlap with any
863 * previous opens still in effect. If we are a normal serial device
864 * then also we might have to wait for carrier.
865 */
869 }
872 }
874 /*****************************************************************************/
877 {
890 }
896 }
900 /*
901 * May want to wait for data to drain before closing. The BUSY flag
902 * keeps track of whether we are still transmitting or not. It is
903 * updated by messages from the slave - indicating when all chars
904 * really have drained.
905 */
921 else
924 }
940 }
944 }
946 /*****************************************************************************/
948 /*
949 * Carry out first open operations on a port. This involves a number of
950 * commands to be sent to the slave. We need to open the port, set the
951 * notification events, set the initial port settings, get and set the
952 * initial signal values. We sleep and wait in between each one. But
953 * this still all happens pretty quickly.
954 */
957 {
959 asynotify_t nt;
960 asyport_t aport;
993 }
995 /*****************************************************************************/
997 /*
998 * Send an open message to the slave. This will sleep waiting for the
999 * acknowledgement, so must have user context. We need to co-ordinate
1000 * with close events here, since we don't want open and close events
1001 * to overlap.
1002 */
1004 static int stli_rawopen(struct stlibrd *brdp, struct stliport *portp, unsigned long arg, int wait)
1005 {
1012 /*
1013 * Send a message to the slave to open this port.
1014 */
1016 /*
1017 * Slave is already closing this port. This can happen if a hangup
1018 * occurs on this port. So we must wait until it is complete. The
1019 * order of opens and closes may not be preserved across shared
1020 * memory, so we must wait until it is complete.
1021 */
1026 }
1028 /*
1029 * Everything is ready now, so write the open message into shared
1030 * memory. Once the message is in set the service bits to say that
1031 * this port wants service.
1032 */
1047 }
1049 /*
1050 * Slave is in action, so now we must wait for the open acknowledgment
1051 * to come back.
1052 */
1065 }
1067 /*****************************************************************************/
1069 /*
1070 * Send a close message to the slave. Normally this will sleep waiting
1071 * for the acknowledgement, but if wait parameter is 0 it will not. If
1072 * wait is true then must have user context (to sleep).
1073 */
1075 static int stli_rawclose(struct stlibrd *brdp, struct stliport *portp, unsigned long arg, int wait)
1076 {
1083 /*
1084 * Slave is already closing this port. This can happen if a hangup
1085 * occurs on this port.
1086 */
1092 }
1093 }
1095 /*
1096 * Write the close command into shared memory.
1097 */
1115 /*
1116 * Slave is in action, so now we must wait for the open acknowledgment
1117 * to come back.
1118 */
1128 }
1130 /*****************************************************************************/
1132 /*
1133 * Send a command to the slave and wait for the response. This must
1134 * have user context (it sleeps). This routine is generic in that it
1135 * can send any type of command. Its purpose is to wait for that command
1136 * to complete (as opposed to initiating the command then returning).
1137 */
1139 static int stli_cmdwait(struct stlibrd *brdp, struct stliport *portp, unsigned long cmd, void *arg, int size, int copyback)
1140 {
1156 }
1158 /*****************************************************************************/
1160 /*
1161 * Send the termios settings for this port to the slave. This sleeps
1162 * waiting for the command to complete - so must have user context.
1163 */
1166 {
1168 asyport_t aport;
1182 }
1184 /*****************************************************************************/
1186 /*
1187 * Possibly need to wait for carrier (DCD signal) to come high. Say
1188 * maybe because if we are clocal then we don't need to wait...
1189 */
1192 {
1200 doclocal++;
1217 else
1220 }
1224 }
1228 }
1230 }
1239 }
1241 /*****************************************************************************/
1243 /*
1244 * Write routine. Take the data and put it in the shared memory ring
1245 * queue. If port is not already sending chars then need to mark the
1246 * service bits for this port.
1247 */
1250 {
1273 /*
1274 * All data is now local, shove as much as possible into shared memory.
1275 */
1290 }
1306 }
1307 }
1314 }
1324 }
1326 /*****************************************************************************/
1328 /*
1329 * Output a single character. We put it into a temporary local buffer
1330 * (for speed) then write out that buffer when the flushchars routine
1331 * is called. There is a safety catch here so that if some other port
1332 * writes chars before the current buffer has been, then we write them
1333 * first them do the new ports.
1334 */
1337 {
1342 }
1345 }
1347 /*****************************************************************************/
1349 /*
1350 * Transfer characters from the local TX cooking buffer to the board.
1351 * We sort of ignore the tty that gets passed in here. We rely on the
1352 * info stored with the TX cook buffer to tell us which port to flush
1353 * the data on. In any case we clean out the TX cook buffer, for re-use
1354 * by someone else.
1355 */
1358 {
1409 }
1426 }
1427 }
1435 }
1444 }
1446 /*****************************************************************************/
1449 {
1460 }
1461 }
1480 len--;
1487 }
1489 }
1491 /*****************************************************************************/
1493 /*
1494 * Return the number of characters in the transmit buffer. Normally we
1495 * will return the number of chars in the shared memory ring queue.
1496 * We need to kludge around the case where the shared memory buffer is
1497 * empty but not all characters have drained yet, for this case just
1498 * return that there is 1 character in the buffer!
1499 */
1502 {
1534 }
1536 /*****************************************************************************/
1538 /*
1539 * Generate the serial struct info.
1540 */
1543 {
1565 }
1567 /*****************************************************************************/
1569 /*
1570 * Set port according to the serial struct info.
1571 * At this point we do not do any auto-configure stuff, so we will
1572 * just quietly ignore any requests to change irq, etc.
1573 */
1576 {
1588 }
1600 }
1602 /*****************************************************************************/
1605 {
1625 }
1629 {
1657 }
1659 static int stli_ioctl(struct tty_struct *tty, struct file *file, unsigned int cmd, unsigned long arg)
1660 {
1680 }
1724 }
1727 }
1729 /*****************************************************************************/
1731 /*
1732 * This routine assumes that we have user context and can sleep.
1733 * Looks like it is true for the current ttys implementation..!!
1734 */
1737 {
1741 asyport_t aport;
1765 }
1767 /*****************************************************************************/
1769 /*
1770 * Attempt to flow control who ever is sending us data. We won't really
1771 * do any flow control action here. We can't directly, and even if we
1772 * wanted to we would have to send a command to the slave. The slave
1773 * knows how to flow control, and will do so when its buffers reach its
1774 * internal high water marks. So what we will do is set a local state
1775 * bit that will stop us sending any RX data up from the poll routine
1776 * (which is the place where RX data from the slave is handled).
1777 */
1780 {
1785 }
1787 /*****************************************************************************/
1789 /*
1790 * Unflow control the device sending us data... That means that all
1791 * we have to do is clear the RXSTOP state bit. The next poll call
1792 * will then be able to pass the RX data back up.
1793 */
1796 {
1801 }
1803 /*****************************************************************************/
1805 /*
1806 * Stop the transmitter.
1807 */
1810 {
1811 }
1813 /*****************************************************************************/
1815 /*
1816 * Start the transmitter again.
1817 */
1820 {
1821 }
1823 /*****************************************************************************/
1825 /*
1826 * Hangup this port. This is pretty much like closing the port, only
1827 * a little more brutal. No waiting for data to drain. Shutdown the
1828 * port and maybe drop signals. This is rather tricky really. We want
1829 * to close the port as well.
1830 */
1833 {
1862 }
1863 }
1874 }
1876 /*****************************************************************************/
1878 /*
1879 * Flush characters from the lower buffer. We may not have user context
1880 * so we cannot sleep waiting for it to complete. Also we need to check
1881 * if there is chars for this port in the TX cook buffer, and flush them
1882 * as well.
1883 */
1886 {
1905 }
1913 }
1915 }
1918 }
1920 /*****************************************************************************/
1923 {
1939 }
1941 /*****************************************************************************/
1944 {
1964 }
1965 }
1967 /*****************************************************************************/
1970 {
1973 asyctrl_t actrl;
1992 }
1994 }
1996 /*****************************************************************************/
1998 #define MAXLINE 80
2000 /*
2001 * Format info for a specified port. The line is deliberately limited
2002 * to 80 characters. (If it is too long it will be truncated, if too
2003 * short then padded with spaces).
2004 */
2007 {
2019 }
2020 }
2050 }
2059 }
2061 /*****************************************************************************/
2063 /*
2064 * Port info, read from the /proc file system.
2065 */
2068 {
2081 stli_drvversion);
2085 }
2088 /*
2089 * We scan through for each board, panel and port. The offset is
2090 * calculated on the fly, and irrelevant ports are skipped.
2091 */
2103 }
2107 totalport++) {
2116 }
2117 }
2121 stli_readdone:
2124 }
2126 /*****************************************************************************/
2128 /*
2129 * Generic send command routine. This will send a message to the slave,
2130 * of the specified type with the specified argument. Must be very
2131 * careful of data that will be copied out from shared memory -
2132 * containing command results. The command completion is all done from
2133 * a poll routine that does not have user context. Therefore you cannot
2134 * copy back directly into user space, or to the kernel stack of a
2135 * process. This routine does not sleep, so can be called from anywhere.
2136 *
2137 * The caller must hold the brd_lock (see also stli_sendcmd the usual
2138 * entry point)
2139 */
2141 static void __stli_sendcmd(struct stlibrd *brdp, struct stliport *portp, unsigned long cmd, void *arg, int size, int copyback)
2142 {
2151 }
2160 }
2161 }
2170 }
2172 static void stli_sendcmd(struct stlibrd *brdp, struct stliport *portp, unsigned long cmd, void *arg, int size, int copyback)
2173 {
2179 }
2181 /*****************************************************************************/
2183 /*
2184 * Read data from shared memory. This assumes that the shared memory
2185 * is enabled and that interrupts are off. Basically we just empty out
2186 * the shared memory buffer into the tty buffer. Must be careful to
2187 * handle the case where we fill up the tty buffer, but still have
2188 * more chars to unload.
2189 */
2192 {
2217 }
2234 }
2235 }
2243 }
2245 /*****************************************************************************/
2247 /*
2248 * Set up and carry out any delayed commands. There is only a small set
2249 * of slave commands that can be done "off-level". So it is not too
2250 * difficult to deal with them here.
2251 */
2254 {
2265 else
2285 }
2286 }
2288 /*****************************************************************************/
2290 /*
2291 * Host command service checking. This handles commands or messages
2292 * coming from the slave to the host. Must have board shared memory
2293 * enabled and interrupts off when called. Notice that by servicing the
2294 * read data last we don't need to change the shared memory pointer
2295 * during processing (which is a slow IO operation).
2296 * Return value indicates if this port is still awaiting actions from
2297 * the slave (like open, command, or even TX data being sent). If 0
2298 * then port is still busy, otherwise no longer busy.
2299 */
2302 {
2306 asynotify_t nt;
2313 /*
2314 * Check if we are waiting for an open completion message.
2315 */
2320 rc--;
2325 }
2326 }
2328 /*
2329 * Check if we are waiting for a close completion message.
2330 */
2335 rc--;
2340 }
2341 }
2343 /*
2344 * Check if we are waiting for a command completion message. We may
2345 * need to copy out the command results associated with this command.
2346 */
2351 rc--;
2356 }
2362 }
2363 }
2365 /*
2366 * Check for any notification messages ready. This includes lots of
2367 * different types of events - RX chars ready, RX break received,
2368 * TX data low or empty in the slave, modem signals changed state.
2369 */
2389 }
2390 }
2391 }
2399 }
2400 }
2408 }
2410 }
2411 }
2414 donerx++;
2416 }
2417 }
2419 /*
2420 * It might seem odd that we are checking for more RX chars here.
2421 * But, we need to handle the case where the tty buffer was previously
2422 * filled, but we had more characters to pass up. The slave will not
2423 * send any more RX notify messages until the RX buffer has been emptied.
2424 * But it will leave the service bits on (since the buffer is not empty).
2425 * So from here we can try to process more RX chars.
2426 */
2430 }
2437 }
2439 /*****************************************************************************/
2441 /*
2442 * Service all ports on a particular board. Assumes that the boards
2443 * shared memory is enabled, and that the page pointer is pointed
2444 * at the cdk header structure.
2445 */
2448 {
2459 /*
2460 * Check if slave wants any service. Basically we try to do as
2461 * little work as possible here. There are 2 levels of service
2462 * bits. So if there is nothing to do we bail early. We check
2463 * 8 service bits at a time in the inner loop, so we can bypass
2464 * the lot if none of them want service.
2465 */
2467 bitsize);
2480 slavebitchange++;
2482 }
2483 }
2484 }
2485 }
2487 /*
2488 * If any of the ports are no longer busy then update them in the
2489 * slave request bits. We need to do this after, since a host port
2490 * service may initiate more slave requests.
2491 */
2498 }
2499 }
2500 }
2502 /*****************************************************************************/
2504 /*
2505 * Driver poll routine. This routine polls the boards in use and passes
2506 * messages back up to host when necessary. This is actually very
2507 * CPU efficient, since we will always have the kernel poll clock, it
2508 * adds only a few cycles when idle (since board service can be
2509 * determined very easily), but when loaded generates no interrupts
2510 * (with their expensive associated context change).
2511 */
2514 {
2521 /*
2522 * Check each board and do any servicing required.
2523 */
2538 }
2539 }
2541 /*****************************************************************************/
2543 /*
2544 * Translate the termios settings into the port setting structure of
2545 * the slave.
2546 */
2549 {
2552 /*
2553 * Start of by setting the baud, char size, parity and stop bit info.
2554 */
2567 }
2585 }
2589 else
2595 else
2599 }
2601 /*
2602 * Set up any flow control options enabled.
2603 */
2608 }
2617 /*
2618 * Set up the RX char marking mask with those RX error types we must
2619 * catch. We can get the slave to help us out a little here, it will
2620 * ignore parity errors and breaks for us, and mark parity errors in
2621 * the data stream.
2622 */
2634 /*
2635 * Set up clocal processing as required.
2636 */
2639 else
2642 /*
2643 * Transfer any persistent flags into the asyport structure.
2644 */
2649 }
2651 /*****************************************************************************/
2653 /*
2654 * Construct a slave signals structure for setting the DTR and RTS
2655 * signals as specified.
2656 */
2659 {
2664 }
2668 }
2669 }
2671 /*****************************************************************************/
2673 /*
2674 * Convert the signals returned from the slave into a local TIOCM type
2675 * signals value. We keep them locally in TIOCM format.
2676 */
2679 {
2688 }
2690 /*****************************************************************************/
2692 /*
2693 * All panels and ports actually attached have been worked out. All
2694 * we need to do here is set up the appropriate per port data structures.
2695 */
2698 {
2707 }
2719 panelport++;
2722 panelnr++;
2723 }
2725 }
2728 }
2730 /*****************************************************************************/
2732 /*
2733 * All the following routines are board specific hardware operations.
2734 */
2737 {
2747 }
2749 /*****************************************************************************/
2752 {
2754 }
2756 /*****************************************************************************/
2759 {
2761 }
2763 /*****************************************************************************/
2766 {
2779 }
2782 }
2784 /*****************************************************************************/
2787 {
2792 }
2794 /*****************************************************************************/
2797 {
2799 }
2801 /*****************************************************************************/
2803 /*
2804 * The following set of functions act on ECP EISA boards.
2805 */
2808 {
2821 }
2823 /*****************************************************************************/
2826 {
2828 }
2830 /*****************************************************************************/
2833 {
2835 }
2837 /*****************************************************************************/
2840 {
2854 else
2856 }
2859 }
2861 /*****************************************************************************/
2864 {
2869 }
2871 /*****************************************************************************/
2873 /*
2874 * The following set of functions act on ECP MCA boards.
2875 */
2878 {
2880 }
2882 /*****************************************************************************/
2885 {
2887 }
2889 /*****************************************************************************/
2892 {
2905 }
2908 }
2910 /*****************************************************************************/
2913 {
2918 }
2920 /*****************************************************************************/
2922 /*
2923 * The following set of functions act on ECP PCI boards.
2924 */
2927 {
2932 }
2934 /*****************************************************************************/
2936 static void __iomem *stli_ecppcigetmemptr(struct stlibrd *brdp, unsigned long offset, int line)
2937 {
2950 }
2953 }
2955 /*****************************************************************************/
2958 {
2963 }
2965 /*****************************************************************************/
2967 /*
2968 * The following routines act on ONboards.
2969 */
2972 {
2984 }
2986 /*****************************************************************************/
2989 {
2991 }
2993 /*****************************************************************************/
2996 {
2998 }
3000 /*****************************************************************************/
3003 {
3013 }
3015 }
3017 /*****************************************************************************/
3020 {
3025 }
3027 /*****************************************************************************/
3029 /*
3030 * The following routines act on ONboard EISA.
3031 */
3034 {
3049 }
3051 /*****************************************************************************/
3054 {
3056 }
3058 /*****************************************************************************/
3061 {
3063 }
3065 /*****************************************************************************/
3068 {
3082 else
3084 }
3087 }
3089 /*****************************************************************************/
3092 {
3097 }
3099 /*****************************************************************************/
3101 /*
3102 * The following routines act on Brumby boards.
3103 */
3106 {
3113 }
3115 /*****************************************************************************/
3118 {
3128 }
3130 /*****************************************************************************/
3133 {
3138 }
3140 /*****************************************************************************/
3142 /*
3143 * The following routines act on original old Stallion boards.
3144 */
3147 {
3150 }
3152 /*****************************************************************************/
3155 {
3158 }
3160 /*****************************************************************************/
3163 {
3170 }
3172 /*****************************************************************************/
3174 /*
3175 * Try to find an ECP board and initialize it. This handles only ECP
3176 * board types.
3177 */
3180 {
3181 cdkecpsig_t sig;
3190 }
3197 }
3199 /*
3200 * Based on the specific board type setup the common vars to access
3201 * and enable shared memory. Set all board specific information now
3202 * as well.
3203 */
3260 }
3262 /*
3263 * The per-board operations structure is all set up, so now let's go
3264 * and get the board operational. Firstly initialize board configuration
3265 * registers. Set the memory mapping info so we can get at the boards
3266 * shared memory.
3267 */
3274 }
3276 /*
3277 * Now that all specific code is set up, enable the shared memory and
3278 * look for the a signature area that will tell us exactly what board
3279 * this is, and what it is connected to it.
3280 */
3289 }
3291 /*
3292 * Scan through the signature looking at the panels connected to the
3293 * board. Calculate the total number of ports as we go.
3294 */
3303 nxtid++;
3306 nxtid++;
3308 }
3313 err_unmap:
3316 err_reg:
3318 err:
3320 }
3322 /*****************************************************************************/
3324 /*
3325 * Try to find an ONboard, Brumby or Stallion board and initialize it.
3326 * This handles only these board types.
3327 */
3330 {
3331 cdkonbsig_t sig;
3336 /*
3337 * Do a basic sanity check on the IO and memory addresses.
3338 */
3342 }
3349 }
3351 /*
3352 * Based on the specific board type setup the common vars to access
3353 * and enable shared memory. Set all board specific information now
3354 * as well.
3355 */
3370 else
3417 }
3419 /*
3420 * The per-board operations structure is all set up, so now let's go
3421 * and get the board operational. Firstly initialize board configuration
3422 * registers. Set the memory mapping info so we can get at the boards
3423 * shared memory.
3424 */
3431 }
3433 /*
3434 * Now that all specific code is set up, enable the shared memory and
3435 * look for the a signature area that will tell us exactly what board
3436 * this is, and how many ports.
3437 */
3449 }
3451 /*
3452 * Scan through the signature alive mask and calculate how many ports
3453 * there are on this board.
3454 */
3462 }
3464 }
3470 err_unmap:
3473 err_reg:
3475 err:
3477 }
3479 /*****************************************************************************/
3481 /*
3482 * Start up a running board. This routine is only called after the
3483 * code has been down loaded to the board and is operational. It will
3484 * read in the memory map, and get the show on the road...
3485 */
3488 {
3496 u32 memoff;
3503 #if 0
3509 #endif
3515 }
3525 }
3530 }
3531 memp++;
3533 /*
3534 * Cycle through memory allocation of each port. We are guaranteed to
3535 * have all ports inside the first page of slave window, so no need to
3536 * change pages while reading memory map.
3537 */
3549 }
3553 /*
3554 * For each port setup a local copy of the RX and TX buffer offsets
3555 * and sizes. We do this separate from the above, because we need to
3556 * move the shared memory page...
3557 */
3570 }
3571 }
3573 stli_donestartup:
3581 stli_timeron++;
3583 }
3586 }
3588 /*****************************************************************************/
3590 /*
3591 * Probe and initialize the specified board.
3592 */
3595 {
3616 }
3627 }
3629 #if STLI_EISAPROBE != 0
3630 /*****************************************************************************/
3632 /*
3633 * Probe around trying to find where the EISA boards shared memory
3634 * might be. This is a bit if hack, but it is the best we can do.
3635 */
3638 {
3643 /*
3644 * First up we reset the board, to get it into a known state. There
3645 * is only 2 board types here we need to worry about. Don;t use the
3646 * standard board init routine here, it programs up the shared
3647 * memory address, and we don't know it yet...
3648 */
3667 }
3672 /*
3673 * Board shared memory is enabled, so now we have a poke around and
3674 * see if we can find it.
3675 */
3697 }
3702 }
3704 /*
3705 * Regardless of whether we found the shared memory or not we must
3706 * disable the region. After that return success or failure.
3707 */
3710 else
3720 }
3722 }
3723 #endif
3726 {
3734 }
3735 }
3737 }
3739 #if STLI_EISAPROBE != 0
3740 /*****************************************************************************/
3742 /*
3743 * Probe around and try to find any EISA boards in system. The biggest
3744 * problem here is finding out what memory address is associated with
3745 * an EISA board after it is found. The registers of the ECPE and
3746 * ONboardE are not readable - so we can't read them from there. We
3747 * don't have access to the EISA CMOS (or EISA BIOS) so we don't
3748 * actually have any way to find out the real value. The best we can
3749 * do is go probing around in the usual places hoping we can find it.
3750 */
3753 {
3758 /*
3759 * Firstly check if this is an EISA system. If this is not an EISA system then
3760 * don't bother going any further!
3761 */
3765 /*
3766 * Looks like an EISA system, so go searching for EISA boards.
3767 */
3775 /*
3776 * We have found a board. Need to check if this board was
3777 * statically configured already (just in case!).
3778 */
3785 }
3789 /*
3790 * We have found a Stallion board and it is not configured already.
3791 * Allocate a board structure and initialize it.
3792 */
3804 else
3813 }
3816 found++;
3821 }
3824 }
3825 #else
3827 #endif
3829 /*****************************************************************************/
3831 /*
3832 * Find the next available board number that is free.
3833 */
3835 /*****************************************************************************/
3837 /*
3838 * We have a Stallion board. Allocate a board structure and
3839 * initialize it. Read its IO and MEMORY resources from PCI
3840 * configuration space.
3841 */
3845 {
3857 }
3866 }
3871 /*
3872 * We have all resources from the board, so lets setup the actual
3873 * board structure now.
3874 */
3893 err_null:
3895 err_fr:
3897 err:
3899 }
3902 {
3913 }
3920 };
3921 /*****************************************************************************/
3923 /*
3924 * Allocate a new board structure. Fill out the basic info in it.
3925 */
3928 {
3936 }
3939 }
3941 /*****************************************************************************/
3943 /*
3944 * Scan through all the boards in the configuration and see what we
3945 * can find.
3946 */
3949 {
3956 stli_nrbrds++) {
3969 }
3971 found++;
3976 }
3982 /*
3983 * All found boards are initialized. Now for a little optimization, if
3984 * no boards are sharing the "shared memory" regions then we can just
3985 * leave them all enabled. This is in fact the usual case.
3986 */
4000 stli_shared++;
4002 }
4003 }
4004 }
4005 }
4016 }
4017 }
4018 }
4025 }
4028 err:
4030 }
4032 /*****************************************************************************/
4034 /*
4035 * Code to handle an "staliomem" read operation. This device is the
4036 * contents of the board shared memory. It is used for down loading
4037 * the slave image (and debugging :-)
4038 */
4041 {
4063 /*
4064 * Copy the data a page at a time
4065 */
4083 }
4087 }
4088 out:
4092 }
4094 /*****************************************************************************/
4096 /*
4097 * Code to handle an "staliomem" write operation. This device is the
4098 * contents of the board shared memory. It is used for down loading
4099 * the slave image (and debugging :-)
4100 *
4101 * FIXME: copy under lock
4102 */
4104 static ssize_t stli_memwrite(struct file *fp, const char __user *buf, size_t count, loff_t *offp)
4105 {
4130 /*
4131 * Copy the data a page at a time
4132 */
4145 }
4155 }
4156 out:
4160 }
4162 /*****************************************************************************/
4164 /*
4165 * Return the board stats structure to user app.
4166 */
4169 {
4194 }
4199 }
4201 /*****************************************************************************/
4203 /*
4204 * Resolve the referenced port number into a port struct pointer.
4205 */
4209 {
4223 }
4225 /*****************************************************************************/
4227 /*
4228 * Return the port stats structure to user app. A NULL port struct
4229 * pointer passed in means that we need to find out from the app
4230 * what port to get stats for (used through board control device).
4231 */
4234 {
4253 }
4271 }
4272 }
4273 }
4297 }
4299 /*****************************************************************************/
4301 /*
4302 * Return the port stats structure to user app. A NULL port struct
4303 * pointer passed in means that we need to find out from the app
4304 * what port to get stats for (used through board control device).
4305 */
4308 {
4319 }
4330 }
4332 /*****************************************************************************/
4334 /*
4335 * Clear the port stats structure. We also return it zeroed out...
4336 */
4339 {
4350 }
4359 }
4369 }
4371 /*****************************************************************************/
4373 /*
4374 * Return the entire driver ports structure to a user app.
4375 */
4378 {
4391 }
4393 /*****************************************************************************/
4395 /*
4396 * Return the entire driver board structure to a user app.
4397 */
4400 {
4414 }
4416 /*****************************************************************************/
4418 /*
4419 * The "staliomem" device is also required to do some special operations on
4420 * the board. We need to be able to send an interrupt to the board,
4421 * reset it, and start/stop it.
4422 */
4424 static int stli_memioctl(struct inode *ip, struct file *fp, unsigned int cmd, unsigned long arg)
4425 {
4430 /*
4431 * First up handle the board independent ioctls.
4432 */
4439 done++;
4443 done++;
4447 done++;
4451 done++;
4455 done++;
4457 }
4462 /*
4463 * Now handle the board specific ioctls. These all depend on the
4464 * minor number of the device they were called from.
4465 */
4491 }
4496 }
4498 }
4522 };
4524 /*****************************************************************************/
4525 /*
4526 * Loadable module initialization stuff.
4527 */
4530 {
4545 }
4546 }
4549 {
4564 }
4570 }
4587 }
4593 /*
4594 * Set up a character driver for the shared memory region. We need this
4595 * to down load the slave code image. Also it is a useful debugging tool.
4596 */
4602 }
4610 err_deinit:
4613 err_ttyunr:
4615 err_ttyput:
4617 err_free:
4619 err:
4621 }
4623 /*****************************************************************************/
4626 {
4630 stli_drvversion);
4635 }
4650 }