[XFRM]: skb_cow_data() does not set proper owner for new skbs.
[linux-2.6/verdex.git] / drivers / cdrom / cm206.c
blobda80b14335a524d532ef9086d19a7e4ac26e81c3
1 /* cm206.c. A linux-driver for the cm206 cdrom player with cm260 adapter card.
2 Copyright (c) 1995--1997 David A. van Leeuwen.
3 $Id: cm206.c,v 1.5 1997/12/26 11:02:51 david Exp $
5 This program is free software; you can redistribute it and/or modify
6 it under the terms of the GNU General Public License as published by
7 the Free Software Foundation; either version 2 of the License, or
8 (at your option) any later version.
10 This program is distributed in the hope that it will be useful,
11 but WITHOUT ANY WARRANTY; without even the implied warranty of
12 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
13 GNU General Public License for more details.
15 You should have received a copy of the GNU General Public License
16 along with this program; if not, write to the Free Software
17 Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
19 History:
20 Started 25 jan 1994. Waiting for documentation...
21 22 feb 1995: 0.1a first reasonably safe polling driver.
22 Two major bugs, one in read_sector and one in
23 do_cm206_request, happened to cancel!
24 25 feb 1995: 0.2a first reasonable interrupt driven version of above.
25 uart writes are still done in polling mode.
26 25 feb 1995: 0.21a writes also in interrupt mode, still some
27 small bugs to be found... Larger buffer.
28 2 mrt 1995: 0.22 Bug found (cd-> nowhere, interrupt was called in
29 initialization), read_ahead of 16. Timeouts implemented.
30 unclear if they do something...
31 7 mrt 1995: 0.23 Start of background read-ahead.
32 18 mrt 1995: 0.24 Working background read-ahead. (still problems)
33 26 mrt 1995: 0.25 Multi-session ioctl added (kernel v1.2).
34 Statistics implemented, though separate stats206.h.
35 Accessible trough ioctl 0x1000 (just a number).
36 Hard to choose between v1.2 development and 1.1.75.
37 Bottom-half doesn't work with 1.2...
38 0.25a: fixed... typo. Still problems...
39 1 apr 1995: 0.26 Module support added. Most bugs found. Use kernel 1.2.n.
40 5 apr 1995: 0.27 Auto-probe for the adapter card base address.
41 Auto-probe for the adaptor card irq line.
42 7 apr 1995: 0.28 Added lilo setup support for base address and irq.
43 Use major number 32 (not in this source), officially
44 assigned to this driver.
45 9 apr 1995: 0.29 Added very limited audio support. Toc_header, stop, pause,
46 resume, eject. Play_track ignores track info, because we can't
47 read a table-of-contents entry. Toc_entry is implemented
48 as a `placebo' function: always returns start of disc.
49 3 may 1995: 0.30 Audio support completed. The get_toc_entry function
50 is implemented as a binary search.
51 15 may 1995: 0.31 More work on audio stuff. Workman is not easy to
52 satisfy; changed binary search into linear search.
53 Auto-probe for base address somewhat relaxed.
54 1 jun 1995: 0.32 Removed probe_irq_on/off for module version.
55 10 jun 1995: 0.33 Workman still behaves funny, but you should be
56 able to eject and substitute another disc.
58 An adaptation of 0.33 is included in linux-1.3.7 by Eberhard Moenkeberg
60 18 jul 1995: 0.34 Patch by Heiko Eissfeldt included, mainly considering
61 verify_area's in the ioctls. Some bugs introduced by
62 EM considering the base port and irq fixed.
64 18 dec 1995: 0.35 Add some code for error checking... no luck...
66 We jump to reach our goal: version 1.0 in the next stable linux kernel.
68 19 mar 1996: 0.95 Different implementation of CDROM_GET_UPC, on
69 request of Thomas Quinot.
70 25 mar 1996: 0.96 Interpretation of opening with O_WRONLY or O_RDWR:
71 open only for ioctl operation, e.g., for operation of
72 tray etc.
73 4 apr 1996: 0.97 First implementation of layer between VFS and cdrom
74 driver, a generic interface. Much of the functionality
75 of cm206_open() and cm206_ioctl() is transferred to a
76 new file cdrom.c and its header ucdrom.h.
78 Upgrade to Linux kernel 1.3.78.
80 11 apr 1996 0.98 Upgrade to Linux kernel 1.3.85
81 More code moved to cdrom.c
83 0.99 Some more small changes to decrease number
84 of oopses at module load;
86 27 jul 1996 0.100 Many hours of debugging, kernel change from 1.2.13
87 to 2.0.7 seems to have introduced some weird behavior
88 in (interruptible_)sleep_on(&cd->data): the process
89 seems to be woken without any explicit wake_up in my own
90 code. Patch to try 100x in case such untriggered wake_up's
91 occur.
93 28 jul 1996 0.101 Rewriting of the code that receives the command echo,
94 using a fifo to store echoed bytes.
96 Branch from 0.99:
98 0.99.1.0 Update to kernel release 2.0.10 dev_t -> kdev_t
99 (emoenke) various typos found by others. extra
100 module-load oops protection.
102 0.99.1.1 Initialization constant cdrom_dops.speed
103 changed from float (2.0) to int (2); Cli()-sti() pair
104 around cm260_reset() in module initialization code.
106 0.99.1.2 Changes literally as proposed by Scott Snyder
107 <snyder@d0sgif.fnal.gov> for the 2.1 kernel line, which
108 have to do mainly with the poor minor support i had. The
109 major new concept is to change a cdrom driver's
110 operations struct from the capabilities struct. This
111 reflects the fact that there is one major for a driver,
112 whilst there can be many minors whith completely
113 different capabilities.
115 0.99.1.3 More changes for operations/info separation.
117 0.99.1.4 Added speed selection (someone had to do this
118 first).
120 23 jan 1997 0.99.1.5 MODULE_PARMS call added.
122 23 jan 1997 0.100.1.2--0.100.1.5 following similar lines as
123 0.99.1.1--0.99.1.5. I get too many complaints about the
124 drive making read errors. What't wrong with the 2.0+
125 kernel line? Why get i (and othe cm206 owners) weird
126 results? Why were things good in the good old 1.1--1.2
127 era? Why don't i throw away the drive?
129 2 feb 1997 0.102 Added `volatile' to values in cm206_struct. Seems to
130 reduce many of the problems. Rewrote polling routines
131 to use fixed delays between polls.
132 0.103 Changed printk behavior.
133 0.104 Added a 0.100 -> 0.100.1.1 change
135 11 feb 1997 0.105 Allow auto_probe during module load, disable
136 with module option "auto_probe=0". Moved some debugging
137 statements to lower priority. Implemented select_speed()
138 function.
140 13 feb 1997 1.0 Final version for 2.0 kernel line.
142 All following changes will be for the 2.1 kernel line.
144 15 feb 1997 1.1 Keep up with kernel 2.1.26, merge in changes from
145 cdrom.c 0.100.1.1--1.0. Add some more MODULE_PARMS.
147 14 sep 1997 1.2 Upgrade to Linux 2.1.55. Added blksize_size[], patch
148 sent by James Bottomley <James.Bottomley@columbiasc.ncr.com>.
150 21 dec 1997 1.4 Upgrade to Linux 2.1.72.
152 24 jan 1998 Removed the cm206_disc_status() function, as it was now dead
153 code. The Uniform CDROM driver now provides this functionality.
155 9 Nov. 1999 Make kernel-parameter implementation work with 2.3.x
156 Removed init_module & cleanup_module in favor of
157 module_init & module_exit.
158 Torben Mathiasen <tmm@image.dk>
160 * Parts of the code are based upon lmscd.c written by Kai Petzke,
161 * sbpcd.c written by Eberhard Moenkeberg, and mcd.c by Martin
162 * Harriss, but any off-the-shelf dynamic programming algorithm won't
163 * be able to find them.
165 * The cm206 drive interface and the cm260 adapter card seem to be
166 * sufficiently different from their cm205/cm250 counterparts
167 * in order to write a complete new driver.
169 * I call all routines connected to the Linux kernel something
170 * with `cm206' in it, as this stuff is too series-dependent.
172 * Currently, my limited knowledge is based on:
173 * - The Linux Kernel Hacker's guide, v. 0.5, by Michael K. Johnson
174 * - Linux Kernel Programmierung, by Michael Beck and others
175 * - Philips/LMS cm206 and cm226 product specification
176 * - Philips/LMS cm260 product specification
178 * David van Leeuwen, david@tm.tno.nl. */
179 #define REVISION "$Revision: 1.5 $"
181 #include <linux/module.h>
183 #include <linux/errno.h> /* These include what we really need */
184 #include <linux/delay.h>
185 #include <linux/string.h>
186 #include <linux/sched.h>
187 #include <linux/interrupt.h>
188 #include <linux/timer.h>
189 #include <linux/cdrom.h>
190 #include <linux/devfs_fs_kernel.h>
191 #include <linux/ioport.h>
192 #include <linux/mm.h>
193 #include <linux/slab.h>
194 #include <linux/init.h>
196 /* #include <linux/ucdrom.h> */
198 #include <asm/io.h>
200 #define MAJOR_NR CM206_CDROM_MAJOR
202 #include <linux/blkdev.h>
204 #undef DEBUG
205 #define STATISTICS /* record times and frequencies of events */
206 #define AUTO_PROBE_MODULE
207 #define USE_INSW
209 #include "cm206.h"
211 /* This variable defines whether or not to probe for adapter base port
212 address and interrupt request. It can be overridden by the boot
213 parameter `auto'.
215 static int auto_probe = 1; /* Yes, why not? */
217 static int cm206_base = CM206_BASE;
218 static int cm206_irq = CM206_IRQ;
219 #ifdef MODULE
220 static int cm206[2] = { 0, 0 }; /* for compatible `insmod' parameter passing */
221 #endif
223 MODULE_PARM(cm206_base, "i"); /* base */
224 MODULE_PARM(cm206_irq, "i"); /* irq */
225 MODULE_PARM(cm206, "1-2i"); /* base,irq or irq,base */
226 MODULE_PARM(auto_probe, "i"); /* auto probe base and irq */
227 MODULE_LICENSE("GPL");
229 #define POLLOOP 100 /* milliseconds */
230 #define READ_AHEAD 1 /* defines private buffer, waste! */
231 #define BACK_AHEAD 1 /* defines adapter-read ahead */
232 #define DATA_TIMEOUT (3*HZ) /* measured in jiffies (10 ms) */
233 #define UART_TIMEOUT (5*HZ/100)
234 #define DSB_TIMEOUT (7*HZ) /* time for the slowest command to finish */
235 #define UR_SIZE 4 /* uart receive buffer fifo size */
237 #define LINUX_BLOCK_SIZE 512 /* WHERE is this defined? */
238 #define RAW_SECTOR_SIZE 2352 /* ok, is also defined in cdrom.h */
239 #define ISO_SECTOR_SIZE 2048
240 #define BLOCKS_ISO (ISO_SECTOR_SIZE/LINUX_BLOCK_SIZE) /* 4 */
241 #define CD_SYNC_HEAD 16 /* CD_SYNC + CD_HEAD */
243 #ifdef STATISTICS /* keep track of errors in counters */
244 #define stats(i) { ++cd->stats[st_ ## i]; \
245 cd->last_stat[st_ ## i] = cd->stat_counter++; \
247 #else
248 #define stats(i) (void) 0;
249 #endif
251 #define Debug(a) {printk (KERN_DEBUG); printk a;}
252 #ifdef DEBUG
253 #define debug(a) Debug(a)
254 #else
255 #define debug(a) (void) 0;
256 #endif
258 typedef unsigned char uch; /* 8-bits */
259 typedef unsigned short ush; /* 16-bits */
261 struct toc_struct { /* private copy of Table of Contents */
262 uch track, fsm[3], q0;
265 struct cm206_struct {
266 volatile ush intr_ds; /* data status read on last interrupt */
267 volatile ush intr_ls; /* uart line status read on last interrupt */
268 volatile uch ur[UR_SIZE]; /* uart receive buffer fifo */
269 volatile uch ur_w, ur_r; /* write/read buffer index */
270 volatile uch dsb, cc; /* drive status byte and condition (error) code */
271 int command; /* command to be written to the uart */
272 int openfiles;
273 ush sector[READ_AHEAD * RAW_SECTOR_SIZE / 2]; /* buffered cd-sector */
274 int sector_first, sector_last; /* range of these sectors */
275 wait_queue_head_t uart; /* wait queues for interrupt */
276 wait_queue_head_t data;
277 struct timer_list timer; /* time-out */
278 char timed_out;
279 signed char max_sectors; /* number of sectors that fit in adapter mem */
280 char wait_back; /* we're waiting for a background-read */
281 char background; /* is a read going on in the background? */
282 int adapter_first; /* if so, that's the starting sector */
283 int adapter_last;
284 char fifo_overflowed;
285 uch disc_status[7]; /* result of get_disc_status command */
286 #ifdef STATISTICS
287 int stats[NR_STATS];
288 int last_stat[NR_STATS]; /* `time' at which stat was stat */
289 int stat_counter;
290 #endif
291 struct toc_struct toc[101]; /* The whole table of contents + lead-out */
292 uch q[10]; /* Last read q-channel info */
293 uch audio_status[5]; /* last read position on pause */
294 uch media_changed; /* record if media changed */
297 #define DISC_STATUS cd->disc_status[0]
298 #define FIRST_TRACK cd->disc_status[1]
299 #define LAST_TRACK cd->disc_status[2]
300 #define PAUSED cd->audio_status[0] /* misuse this memory byte! */
301 #define PLAY_TO cd->toc[0] /* toc[0] records end-time in play */
303 static struct cm206_struct *cd; /* the main memory structure */
304 static struct request_queue *cm206_queue;
305 static DEFINE_SPINLOCK(cm206_lock);
307 /* First, we define some polling functions. These are actually
308 only being used in the initialization. */
310 void send_command_polled(int command)
312 int loop = POLLOOP;
313 while (!(inw(r_line_status) & ls_transmitter_buffer_empty)
314 && loop > 0) {
315 mdelay(1); /* one millisec delay */
316 --loop;
318 outw(command, r_uart_transmit);
321 uch receive_echo_polled(void)
323 int loop = POLLOOP;
324 while (!(inw(r_line_status) & ls_receive_buffer_full) && loop > 0) {
325 mdelay(1);
326 --loop;
328 return ((uch) inw(r_uart_receive));
331 uch send_receive_polled(int command)
333 send_command_polled(command);
334 return receive_echo_polled();
337 inline void clear_ur(void)
339 if (cd->ur_r != cd->ur_w) {
340 debug(("Deleting bytes from fifo:"));
341 for (; cd->ur_r != cd->ur_w;
342 cd->ur_r++, cd->ur_r %= UR_SIZE)
343 debug((" 0x%x", cd->ur[cd->ur_r]));
344 debug(("\n"));
348 static struct tasklet_struct cm206_tasklet;
350 /* The interrupt handler. When the cm260 generates an interrupt, very
351 much care has to be taken in reading out the registers in the right
352 order; in case of a receive_buffer_full interrupt, first the
353 uart_receive must be read, and then the line status again to
354 de-assert the interrupt line. It took me a couple of hours to find
355 this out:-(
357 The function reset_cm206 appears to cause an interrupt, because
358 pulling up the INIT line clears both the uart-write-buffer /and/
359 the uart-write-buffer-empty mask. We call this a `lost interrupt,'
360 as there seems so reason for this to happen.
363 static irqreturn_t cm206_interrupt(int sig, void *dev_id, struct pt_regs *regs)
365 volatile ush fool;
366 cd->intr_ds = inw(r_data_status); /* resets data_ready, data_error,
367 crc_error, sync_error, toc_ready
368 interrupts */
369 cd->intr_ls = inw(r_line_status); /* resets overrun bit */
370 debug(("Intr, 0x%x 0x%x, %d\n", cd->intr_ds, cd->intr_ls,
371 cd->background));
372 if (cd->intr_ls & ls_attention)
373 stats(attention);
374 /* receive buffer full? */
375 if (cd->intr_ls & ls_receive_buffer_full) {
376 cd->ur[cd->ur_w] = inb(r_uart_receive); /* get order right! */
377 cd->intr_ls = inw(r_line_status); /* resets rbf interrupt */
378 debug(("receiving #%d: 0x%x\n", cd->ur_w,
379 cd->ur[cd->ur_w]));
380 cd->ur_w++;
381 cd->ur_w %= UR_SIZE;
382 if (cd->ur_w == cd->ur_r)
383 debug(("cd->ur overflow!\n"));
384 if (waitqueue_active(&cd->uart) && cd->background < 2) {
385 del_timer(&cd->timer);
386 wake_up_interruptible(&cd->uart);
389 /* data ready in fifo? */
390 else if (cd->intr_ds & ds_data_ready) {
391 if (cd->background)
392 ++cd->adapter_last;
393 if (waitqueue_active(&cd->data)
394 && (cd->wait_back || !cd->background)) {
395 del_timer(&cd->timer);
396 wake_up_interruptible(&cd->data);
398 stats(data_ready);
400 /* ready to issue a write command? */
401 else if (cd->command && cd->intr_ls & ls_transmitter_buffer_empty) {
402 outw(dc_normal | (inw(r_data_status) & 0x7f),
403 r_data_control);
404 outw(cd->command, r_uart_transmit);
405 cd->command = 0;
406 if (!cd->background)
407 wake_up_interruptible(&cd->uart);
409 /* now treat errors (at least, identify them for debugging) */
410 else if (cd->intr_ds & ds_fifo_overflow) {
411 debug(("Fifo overflow at sectors 0x%x\n",
412 cd->sector_first));
413 fool = inw(r_fifo_output_buffer); /* de-assert the interrupt */
414 cd->fifo_overflowed = 1; /* signal one word less should be read */
415 stats(fifo_overflow);
416 } else if (cd->intr_ds & ds_data_error) {
417 debug(("Data error at sector 0x%x\n", cd->sector_first));
418 stats(data_error);
419 } else if (cd->intr_ds & ds_crc_error) {
420 debug(("CRC error at sector 0x%x\n", cd->sector_first));
421 stats(crc_error);
422 } else if (cd->intr_ds & ds_sync_error) {
423 debug(("Sync at sector 0x%x\n", cd->sector_first));
424 stats(sync_error);
425 } else if (cd->intr_ds & ds_toc_ready) {
426 /* do something appropriate */
428 /* couldn't see why this interrupt, maybe due to init */
429 else {
430 outw(dc_normal | READ_AHEAD, r_data_control);
431 stats(lost_intr);
433 if (cd->background
434 && (cd->adapter_last - cd->adapter_first == cd->max_sectors
435 || cd->fifo_overflowed))
436 tasklet_schedule(&cm206_tasklet); /* issue a stop read command */
437 stats(interrupt);
438 return IRQ_HANDLED;
441 /* we have put the address of the wait queue in who */
442 void cm206_timeout(unsigned long who)
444 cd->timed_out = 1;
445 debug(("Timing out\n"));
446 wake_up_interruptible((wait_queue_head_t *) who);
449 /* This function returns 1 if a timeout occurred, 0 if an interrupt
450 happened */
451 int sleep_or_timeout(wait_queue_head_t * wait, int timeout)
453 cd->timed_out = 0;
454 init_timer(&cd->timer);
455 cd->timer.data = (unsigned long) wait;
456 cd->timer.expires = jiffies + timeout;
457 add_timer(&cd->timer);
458 debug(("going to sleep\n"));
459 interruptible_sleep_on(wait);
460 del_timer(&cd->timer);
461 if (cd->timed_out) {
462 cd->timed_out = 0;
463 return 1;
464 } else
465 return 0;
468 void cm206_delay(int nr_jiffies)
470 DECLARE_WAIT_QUEUE_HEAD(wait);
471 sleep_or_timeout(&wait, nr_jiffies);
474 void send_command(int command)
476 debug(("Sending 0x%x\n", command));
477 if (!(inw(r_line_status) & ls_transmitter_buffer_empty)) {
478 cd->command = command;
479 cli(); /* don't interrupt before sleep */
480 outw(dc_mask_sync_error | dc_no_stop_on_error |
481 (inw(r_data_status) & 0x7f), r_data_control);
482 /* interrupt routine sends command */
483 if (sleep_or_timeout(&cd->uart, UART_TIMEOUT)) {
484 debug(("Time out on write-buffer\n"));
485 stats(write_timeout);
486 outw(command, r_uart_transmit);
488 debug(("Write commmand delayed\n"));
489 } else
490 outw(command, r_uart_transmit);
493 uch receive_byte(int timeout)
495 uch ret;
496 cli();
497 debug(("cli\n"));
498 ret = cd->ur[cd->ur_r];
499 if (cd->ur_r != cd->ur_w) {
500 sti();
501 debug(("returning #%d: 0x%x\n", cd->ur_r,
502 cd->ur[cd->ur_r]));
503 cd->ur_r++;
504 cd->ur_r %= UR_SIZE;
505 return ret;
506 } else if (sleep_or_timeout(&cd->uart, timeout)) { /* does sti() */
507 debug(("Time out on receive-buffer\n"));
508 #ifdef STATISTICS
509 if (timeout == UART_TIMEOUT)
510 stats(receive_timeout) /* no `;'! */
511 else
512 stats(dsb_timeout);
513 #endif
514 return 0xda;
516 ret = cd->ur[cd->ur_r];
517 debug(("slept; returning #%d: 0x%x\n", cd->ur_r,
518 cd->ur[cd->ur_r]));
519 cd->ur_r++;
520 cd->ur_r %= UR_SIZE;
521 return ret;
524 inline uch receive_echo(void)
526 return receive_byte(UART_TIMEOUT);
529 inline uch send_receive(int command)
531 send_command(command);
532 return receive_echo();
535 inline uch wait_dsb(void)
537 return receive_byte(DSB_TIMEOUT);
540 int type_0_command(int command, int expect_dsb)
542 int e;
543 clear_ur();
544 if (command != (e = send_receive(command))) {
545 debug(("command 0x%x echoed as 0x%x\n", command, e));
546 stats(echo);
547 return -1;
549 if (expect_dsb) {
550 cd->dsb = wait_dsb(); /* wait for command to finish */
552 return 0;
555 int type_1_command(int command, int bytes, uch * status)
556 { /* returns info */
557 int i;
558 if (type_0_command(command, 0))
559 return -1;
560 for (i = 0; i < bytes; i++)
561 status[i] = send_receive(c_gimme);
562 return 0;
565 /* This function resets the adapter card. We'd better not do this too
566 * often, because it tends to generate `lost interrupts.' */
567 void reset_cm260(void)
569 outw(dc_normal | dc_initialize | READ_AHEAD, r_data_control);
570 udelay(10); /* 3.3 mu sec minimum */
571 outw(dc_normal | READ_AHEAD, r_data_control);
574 /* fsm: frame-sec-min from linear address; one of many */
575 void fsm(int lba, uch * fsm)
577 fsm[0] = lba % 75;
578 lba /= 75;
579 lba += 2;
580 fsm[1] = lba % 60;
581 fsm[2] = lba / 60;
584 inline int fsm2lba(uch * fsm)
586 return fsm[0] + 75 * (fsm[1] - 2 + 60 * fsm[2]);
589 inline int f_s_m2lba(uch f, uch s, uch m)
591 return f + 75 * (s - 2 + 60 * m);
594 int start_read(int start)
596 uch read_sector[4] = { c_read_data, };
597 int i, e;
599 fsm(start, &read_sector[1]);
600 clear_ur();
601 for (i = 0; i < 4; i++)
602 if (read_sector[i] != (e = send_receive(read_sector[i]))) {
603 debug(("read_sector: %x echoes %x\n",
604 read_sector[i], e));
605 stats(echo);
606 if (e == 0xff) { /* this seems to happen often */
607 e = receive_echo();
608 debug(("Second try %x\n", e));
609 if (e != read_sector[i])
610 return -1;
613 return 0;
616 int stop_read(void)
618 int e;
619 type_0_command(c_stop, 0);
620 if ((e = receive_echo()) != 0xff) {
621 debug(("c_stop didn't send 0xff, but 0x%x\n", e));
622 stats(stop_0xff);
623 return -1;
625 return 0;
628 /* This function starts to read sectors in adapter memory, the
629 interrupt routine should stop the read. In fact, the bottom_half
630 routine takes care of this. Set a flag `background' in the cd
631 struct to indicate the process. */
633 int read_background(int start, int reading)
635 if (cd->background)
636 return -1; /* can't do twice */
637 outw(dc_normal | BACK_AHEAD, r_data_control);
638 if (!reading && start_read(start))
639 return -2;
640 cd->adapter_first = cd->adapter_last = start;
641 cd->background = 1; /* flag a read is going on */
642 return 0;
645 #ifdef USE_INSW
646 #define transport_data insw
647 #else
648 /* this routine implements insw(,,). There was a time i had the
649 impression that there would be any difference in error-behaviour. */
650 void transport_data(int port, ush * dest, int count)
652 int i;
653 ush *d;
654 for (i = 0, d = dest; i < count; i++, d++)
655 *d = inw(port);
657 #endif
660 #define MAX_TRIES 100
661 int read_sector(int start)
663 int tries = 0;
664 if (cd->background) {
665 cd->background = 0;
666 cd->adapter_last = -1; /* invalidate adapter memory */
667 stop_read();
669 cd->fifo_overflowed = 0;
670 reset_cm260(); /* empty fifo etc. */
671 if (start_read(start))
672 return -1;
673 do {
674 if (sleep_or_timeout(&cd->data, DATA_TIMEOUT)) {
675 debug(("Read timed out sector 0x%x\n", start));
676 stats(read_timeout);
677 stop_read();
678 return -3;
680 tries++;
681 } while (cd->intr_ds & ds_fifo_empty && tries < MAX_TRIES);
682 if (tries > 1)
683 debug(("Took me some tries\n"))
684 else
685 if (tries == MAX_TRIES)
686 debug(("MAX_TRIES tries for read sector\n"));
687 transport_data(r_fifo_output_buffer, cd->sector,
688 READ_AHEAD * RAW_SECTOR_SIZE / 2);
689 if (read_background(start + READ_AHEAD, 1))
690 stats(read_background);
691 cd->sector_first = start;
692 cd->sector_last = start + READ_AHEAD;
693 stats(read_restarted);
694 return 0;
697 /* The function of bottom-half is to send a stop command to the drive
698 This isn't easy because the routine is not `owned' by any process;
699 we can't go to sleep! The variable cd->background gives the status:
700 0 no read pending
701 1 a read is pending
702 2 c_stop waits for write_buffer_empty
703 3 c_stop waits for receive_buffer_full: echo
704 4 c_stop waits for receive_buffer_full: 0xff
707 static void cm206_tasklet_func(unsigned long ignore)
709 debug(("bh: %d\n", cd->background));
710 switch (cd->background) {
711 case 1:
712 stats(bh);
713 if (!(cd->intr_ls & ls_transmitter_buffer_empty)) {
714 cd->command = c_stop;
715 outw(dc_mask_sync_error | dc_no_stop_on_error |
716 (inw(r_data_status) & 0x7f), r_data_control);
717 cd->background = 2;
718 break; /* we'd better not time-out here! */
719 } else
720 outw(c_stop, r_uart_transmit);
721 /* fall into case 2: */
722 case 2:
723 /* the write has been satisfied by interrupt routine */
724 cd->background = 3;
725 break;
726 case 3:
727 if (cd->ur_r != cd->ur_w) {
728 if (cd->ur[cd->ur_r] != c_stop) {
729 debug(("cm206_bh: c_stop echoed 0x%x\n",
730 cd->ur[cd->ur_r]));
731 stats(echo);
733 cd->ur_r++;
734 cd->ur_r %= UR_SIZE;
736 cd->background++;
737 break;
738 case 4:
739 if (cd->ur_r != cd->ur_w) {
740 if (cd->ur[cd->ur_r] != 0xff) {
741 debug(("cm206_bh: c_stop reacted with 0x%x\n", cd->ur[cd->ur_r]));
742 stats(stop_0xff);
744 cd->ur_r++;
745 cd->ur_r %= UR_SIZE;
747 cd->background = 0;
751 static DECLARE_TASKLET(cm206_tasklet, cm206_tasklet_func, 0);
753 /* This command clears the dsb_possible_media_change flag, so we must
754 * retain it.
756 void get_drive_status(void)
758 uch status[2];
759 type_1_command(c_drive_status, 2, status); /* this might be done faster */
760 cd->dsb = status[0];
761 cd->cc = status[1];
762 cd->media_changed |=
763 !!(cd->dsb & (dsb_possible_media_change |
764 dsb_drive_not_ready | dsb_tray_not_closed));
767 void get_disc_status(void)
769 if (type_1_command(c_disc_status, 7, cd->disc_status)) {
770 debug(("get_disc_status: error\n"));
774 /* The new open. The real opening strategy is defined in cdrom.c. */
776 static int cm206_open(struct cdrom_device_info *cdi, int purpose)
778 if (!cd->openfiles) { /* reset only first time */
779 cd->background = 0;
780 reset_cm260();
781 cd->adapter_last = -1; /* invalidate adapter memory */
782 cd->sector_last = -1;
784 ++cd->openfiles;
785 stats(open);
786 return 0;
789 static void cm206_release(struct cdrom_device_info *cdi)
791 if (cd->openfiles == 1) {
792 if (cd->background) {
793 cd->background = 0;
794 stop_read();
796 cd->sector_last = -1; /* Make our internal buffer invalid */
797 FIRST_TRACK = 0; /* No valid disc status */
799 --cd->openfiles;
802 /* Empty buffer empties $sectors$ sectors of the adapter card buffer,
803 * and then reads a sector in kernel memory. */
804 void empty_buffer(int sectors)
806 while (sectors >= 0) {
807 transport_data(r_fifo_output_buffer,
808 cd->sector + cd->fifo_overflowed,
809 RAW_SECTOR_SIZE / 2 - cd->fifo_overflowed);
810 --sectors;
811 ++cd->adapter_first; /* update the current adapter sector */
812 cd->fifo_overflowed = 0; /* reset overflow bit */
813 stats(sector_transferred);
815 cd->sector_first = cd->adapter_first - 1;
816 cd->sector_last = cd->adapter_first; /* update the buffer sector */
819 /* try_adapter. This function determines if the requested sector is
820 in adapter memory, or will appear there soon. Returns 0 upon
821 success */
822 int try_adapter(int sector)
824 if (cd->adapter_first <= sector && sector < cd->adapter_last) {
825 /* sector is in adapter memory */
826 empty_buffer(sector - cd->adapter_first);
827 return 0;
828 } else if (cd->background == 1 && cd->adapter_first <= sector
829 && sector < cd->adapter_first + cd->max_sectors) {
830 /* a read is going on, we can wait for it */
831 cd->wait_back = 1;
832 while (sector >= cd->adapter_last) {
833 if (sleep_or_timeout(&cd->data, DATA_TIMEOUT)) {
834 debug(("Timed out during background wait: %d %d %d %d\n", sector, cd->adapter_last, cd->adapter_first, cd->background));
835 stats(back_read_timeout);
836 cd->wait_back = 0;
837 return -1;
840 cd->wait_back = 0;
841 empty_buffer(sector - cd->adapter_first);
842 return 0;
843 } else
844 return -2;
847 /* This is not a very smart implementation. We could optimize for
848 consecutive block numbers. I'm not convinced this would really
849 bring down the processor load. */
850 static void do_cm206_request(request_queue_t * q)
852 long int i, cd_sec_no;
853 int quarter, error;
854 uch *source, *dest;
855 struct request *req;
857 while (1) { /* repeat until all requests have been satisfied */
858 req = elv_next_request(q);
859 if (!req)
860 return;
862 if (req->cmd != READ) {
863 debug(("Non-read command %d on cdrom\n", req->cmd));
864 end_request(req, 0);
865 continue;
867 spin_unlock_irq(q->queue_lock);
868 error = 0;
869 for (i = 0; i < req->nr_sectors; i++) {
870 int e1, e2;
871 cd_sec_no = (req->sector + i) / BLOCKS_ISO; /* 4 times 512 bytes */
872 quarter = (req->sector + i) % BLOCKS_ISO;
873 dest = req->buffer + i * LINUX_BLOCK_SIZE;
874 /* is already in buffer memory? */
875 if (cd->sector_first <= cd_sec_no
876 && cd_sec_no < cd->sector_last) {
877 source =
878 ((uch *) cd->sector) + 16 +
879 quarter * LINUX_BLOCK_SIZE +
880 (cd_sec_no -
881 cd->sector_first) * RAW_SECTOR_SIZE;
882 memcpy(dest, source, LINUX_BLOCK_SIZE);
883 } else if (!(e1 = try_adapter(cd_sec_no)) ||
884 !(e2 = read_sector(cd_sec_no))) {
885 source =
886 ((uch *) cd->sector) + 16 +
887 quarter * LINUX_BLOCK_SIZE;
888 memcpy(dest, source, LINUX_BLOCK_SIZE);
889 } else {
890 error = 1;
891 debug(("cm206_request: %d %d\n", e1, e2));
894 spin_lock_irq(q->queue_lock);
895 end_request(req, !error);
899 /* Audio support. I've tried very hard, but the cm206 drive doesn't
900 seem to have a get_toc (table-of-contents) function, while i'm
901 pretty sure it must read the toc upon disc insertion. Therefore
902 this function has been implemented through a binary search
903 strategy. All track starts that happen to be found are stored in
904 cd->toc[], for future use.
906 I've spent a whole day on a bug that only shows under Workman---
907 I don't get it. Tried everything, nothing works. If workman asks
908 for track# 0xaa, it'll get the wrong time back. Any other program
909 receives the correct value. I'm stymied.
912 /* seek seeks to address lba. It does wait to arrive there. */
913 void seek(int lba)
915 int i;
916 uch seek_command[4] = { c_seek, };
918 fsm(lba, &seek_command[1]);
919 for (i = 0; i < 4; i++)
920 type_0_command(seek_command[i], 0);
921 cd->dsb = wait_dsb();
924 uch bcdbin(unsigned char bcd)
925 { /* stolen from mcd.c! */
926 return (bcd >> 4) * 10 + (bcd & 0xf);
929 inline uch normalize_track(uch track)
931 if (track < 1)
932 return 1;
933 if (track > LAST_TRACK)
934 return LAST_TRACK + 1;
935 return track;
938 /* This function does a binary search for track start. It records all
939 * tracks seen in the process. Input $track$ must be between 1 and
940 * #-of-tracks+1. Note that the start of the disc must be in toc[1].fsm.
942 int get_toc_lba(uch track)
944 int max = 74 * 60 * 75 - 150, min = fsm2lba(cd->toc[1].fsm);
945 int i, lba, l, old_lba = 0;
946 uch *q = cd->q;
947 uch ct; /* current track */
948 int binary = 0;
949 const int skip = 3 * 60 * 75; /* 3 minutes */
951 for (i = track; i > 0; i--)
952 if (cd->toc[i].track) {
953 min = fsm2lba(cd->toc[i].fsm);
954 break;
956 lba = min + skip;
957 do {
958 seek(lba);
959 type_1_command(c_read_current_q, 10, q);
960 ct = normalize_track(q[1]);
961 if (!cd->toc[ct].track) {
962 l = q[9] - bcdbin(q[5]) + 75 * (q[8] -
963 bcdbin(q[4]) - 2 +
964 60 * (q[7] -
965 bcdbin(q
966 [3])));
967 cd->toc[ct].track = q[1]; /* lead out still 0xaa */
968 fsm(l, cd->toc[ct].fsm);
969 cd->toc[ct].q0 = q[0]; /* contains adr and ctrl info */
970 if (ct == track)
971 return l;
973 old_lba = lba;
974 if (binary) {
975 if (ct < track)
976 min = lba;
977 else
978 max = lba;
979 lba = (min + max) / 2;
980 } else {
981 if (ct < track)
982 lba += skip;
983 else {
984 binary = 1;
985 max = lba;
986 min = lba - skip;
987 lba = (min + max) / 2;
990 } while (lba != old_lba);
991 return lba;
994 void update_toc_entry(uch track)
996 track = normalize_track(track);
997 if (!cd->toc[track].track)
998 get_toc_lba(track);
1001 /* return 0 upon success */
1002 int read_toc_header(struct cdrom_tochdr *hp)
1004 if (!FIRST_TRACK)
1005 get_disc_status();
1006 if (hp) {
1007 int i;
1008 hp->cdth_trk0 = FIRST_TRACK;
1009 hp->cdth_trk1 = LAST_TRACK;
1010 /* fill in first track position */
1011 for (i = 0; i < 3; i++)
1012 cd->toc[1].fsm[i] = cd->disc_status[3 + i];
1013 update_toc_entry(LAST_TRACK + 1); /* find most entries */
1014 return 0;
1016 return -1;
1019 void play_from_to_msf(struct cdrom_msf *msfp)
1021 uch play_command[] = { c_play,
1022 msfp->cdmsf_frame0, msfp->cdmsf_sec0, msfp->cdmsf_min0,
1023 msfp->cdmsf_frame1, msfp->cdmsf_sec1, msfp->cdmsf_min1, 2,
1026 int i;
1027 for (i = 0; i < 9; i++)
1028 type_0_command(play_command[i], 0);
1029 for (i = 0; i < 3; i++)
1030 PLAY_TO.fsm[i] = play_command[i + 4];
1031 PLAY_TO.track = 0; /* say no track end */
1032 cd->dsb = wait_dsb();
1035 void play_from_to_track(int from, int to)
1037 uch play_command[8] = { c_play, };
1038 int i;
1040 if (from == 0) { /* continue paused play */
1041 for (i = 0; i < 3; i++) {
1042 play_command[i + 1] = cd->audio_status[i + 2];
1043 play_command[i + 4] = PLAY_TO.fsm[i];
1045 } else {
1046 update_toc_entry(from);
1047 update_toc_entry(to + 1);
1048 for (i = 0; i < 3; i++) {
1049 play_command[i + 1] = cd->toc[from].fsm[i];
1050 PLAY_TO.fsm[i] = play_command[i + 4] =
1051 cd->toc[to + 1].fsm[i];
1053 PLAY_TO.track = to;
1055 for (i = 0; i < 7; i++)
1056 type_0_command(play_command[i], 0);
1057 for (i = 0; i < 2; i++)
1058 type_0_command(0x2, 0); /* volume */
1059 cd->dsb = wait_dsb();
1062 int get_current_q(struct cdrom_subchnl *qp)
1064 int i;
1065 uch *q = cd->q;
1066 if (type_1_command(c_read_current_q, 10, q))
1067 return 0;
1068 /* q[0] = bcdbin(q[0]); Don't think so! */
1069 for (i = 2; i < 6; i++)
1070 q[i] = bcdbin(q[i]);
1071 qp->cdsc_adr = q[0] & 0xf;
1072 qp->cdsc_ctrl = q[0] >> 4; /* from mcd.c */
1073 qp->cdsc_trk = q[1];
1074 qp->cdsc_ind = q[2];
1075 if (qp->cdsc_format == CDROM_MSF) {
1076 qp->cdsc_reladdr.msf.minute = q[3];
1077 qp->cdsc_reladdr.msf.second = q[4];
1078 qp->cdsc_reladdr.msf.frame = q[5];
1079 qp->cdsc_absaddr.msf.minute = q[7];
1080 qp->cdsc_absaddr.msf.second = q[8];
1081 qp->cdsc_absaddr.msf.frame = q[9];
1082 } else {
1083 qp->cdsc_reladdr.lba = f_s_m2lba(q[5], q[4], q[3]);
1084 qp->cdsc_absaddr.lba = f_s_m2lba(q[9], q[8], q[7]);
1086 get_drive_status();
1087 if (cd->dsb & dsb_play_in_progress)
1088 qp->cdsc_audiostatus = CDROM_AUDIO_PLAY;
1089 else if (PAUSED)
1090 qp->cdsc_audiostatus = CDROM_AUDIO_PAUSED;
1091 else
1092 qp->cdsc_audiostatus = CDROM_AUDIO_NO_STATUS;
1093 return 0;
1096 void invalidate_toc(void)
1098 memset(cd->toc, 0, sizeof(cd->toc));
1099 memset(cd->disc_status, 0, sizeof(cd->disc_status));
1102 /* cdrom.c guarantees that cdte_format == CDROM_MSF */
1103 void get_toc_entry(struct cdrom_tocentry *ep)
1105 uch track = normalize_track(ep->cdte_track);
1106 update_toc_entry(track);
1107 ep->cdte_addr.msf.frame = cd->toc[track].fsm[0];
1108 ep->cdte_addr.msf.second = cd->toc[track].fsm[1];
1109 ep->cdte_addr.msf.minute = cd->toc[track].fsm[2];
1110 ep->cdte_adr = cd->toc[track].q0 & 0xf;
1111 ep->cdte_ctrl = cd->toc[track].q0 >> 4;
1112 ep->cdte_datamode = 0;
1115 /* Audio ioctl. Ioctl commands connected to audio are in such an
1116 * idiosyncratic i/o format, that we leave these untouched. Return 0
1117 * upon success. Memory checking has been done by cdrom_ioctl(), the
1118 * calling function, as well as LBA/MSF sanitization.
1120 int cm206_audio_ioctl(struct cdrom_device_info *cdi, unsigned int cmd,
1121 void *arg)
1123 switch (cmd) {
1124 case CDROMREADTOCHDR:
1125 return read_toc_header((struct cdrom_tochdr *) arg);
1126 case CDROMREADTOCENTRY:
1127 get_toc_entry((struct cdrom_tocentry *) arg);
1128 return 0;
1129 case CDROMPLAYMSF:
1130 play_from_to_msf((struct cdrom_msf *) arg);
1131 return 0;
1132 case CDROMPLAYTRKIND: /* admittedly, not particularly beautiful */
1133 play_from_to_track(((struct cdrom_ti *) arg)->cdti_trk0,
1134 ((struct cdrom_ti *) arg)->cdti_trk1);
1135 return 0;
1136 case CDROMSTOP:
1137 PAUSED = 0;
1138 if (cd->dsb & dsb_play_in_progress)
1139 return type_0_command(c_stop, 1);
1140 else
1141 return 0;
1142 case CDROMPAUSE:
1143 get_drive_status();
1144 if (cd->dsb & dsb_play_in_progress) {
1145 type_0_command(c_stop, 1);
1146 type_1_command(c_audio_status, 5,
1147 cd->audio_status);
1148 PAUSED = 1; /* say we're paused */
1150 return 0;
1151 case CDROMRESUME:
1152 if (PAUSED)
1153 play_from_to_track(0, 0);
1154 PAUSED = 0;
1155 return 0;
1156 case CDROMSTART:
1157 case CDROMVOLCTRL:
1158 return 0;
1159 case CDROMSUBCHNL:
1160 return get_current_q((struct cdrom_subchnl *) arg);
1161 default:
1162 return -EINVAL;
1166 /* Ioctl. These ioctls are specific to the cm206 driver. I have made
1167 some driver statistics accessible through ioctl calls.
1170 static int cm206_ioctl(struct cdrom_device_info *cdi, unsigned int cmd,
1171 unsigned long arg)
1173 switch (cmd) {
1174 #ifdef STATISTICS
1175 case CM206CTL_GET_STAT:
1176 if (arg >= NR_STATS)
1177 return -EINVAL;
1178 else
1179 return cd->stats[arg];
1180 case CM206CTL_GET_LAST_STAT:
1181 if (arg >= NR_STATS)
1182 return -EINVAL;
1183 else
1184 return cd->last_stat[arg];
1185 #endif
1186 default:
1187 debug(("Unknown ioctl call 0x%x\n", cmd));
1188 return -EINVAL;
1192 int cm206_media_changed(struct cdrom_device_info *cdi, int disc_nr)
1194 if (cd != NULL) {
1195 int r;
1196 get_drive_status(); /* ensure cd->media_changed OK */
1197 r = cd->media_changed;
1198 cd->media_changed = 0; /* clear bit */
1199 return r;
1200 } else
1201 return -EIO;
1204 /* The new generic cdrom support. Routines should be concise, most of
1205 the logic should be in cdrom.c */
1207 /* returns number of times device is in use */
1208 int cm206_open_files(struct cdrom_device_info *cdi)
1210 if (cd)
1211 return cd->openfiles;
1212 return -1;
1215 /* controls tray movement */
1216 int cm206_tray_move(struct cdrom_device_info *cdi, int position)
1218 if (position) { /* 1: eject */
1219 type_0_command(c_open_tray, 1);
1220 invalidate_toc();
1221 } else
1222 type_0_command(c_close_tray, 1); /* 0: close */
1223 return 0;
1226 /* gives current state of the drive */
1227 int cm206_drive_status(struct cdrom_device_info *cdi, int slot_nr)
1229 get_drive_status();
1230 if (cd->dsb & dsb_tray_not_closed)
1231 return CDS_TRAY_OPEN;
1232 if (!(cd->dsb & dsb_disc_present))
1233 return CDS_NO_DISC;
1234 if (cd->dsb & dsb_drive_not_ready)
1235 return CDS_DRIVE_NOT_READY;
1236 return CDS_DISC_OK;
1239 /* locks or unlocks door lock==1: lock; return 0 upon success */
1240 int cm206_lock_door(struct cdrom_device_info *cdi, int lock)
1242 uch command = (lock) ? c_lock_tray : c_unlock_tray;
1243 type_0_command(command, 1); /* wait and get dsb */
1244 /* the logic calculates the success, 0 means successful */
1245 return lock ^ ((cd->dsb & dsb_tray_locked) != 0);
1248 /* Although a session start should be in LBA format, we return it in
1249 MSF format because it is slightly easier, and the new generic ioctl
1250 will take care of the necessary conversion. */
1251 int cm206_get_last_session(struct cdrom_device_info *cdi,
1252 struct cdrom_multisession *mssp)
1254 if (!FIRST_TRACK)
1255 get_disc_status();
1256 if (mssp != NULL) {
1257 if (DISC_STATUS & cds_multi_session) { /* multi-session */
1258 mssp->addr.msf.frame = cd->disc_status[3];
1259 mssp->addr.msf.second = cd->disc_status[4];
1260 mssp->addr.msf.minute = cd->disc_status[5];
1261 mssp->addr_format = CDROM_MSF;
1262 mssp->xa_flag = 1;
1263 } else {
1264 mssp->xa_flag = 0;
1266 return 1;
1268 return 0;
1271 int cm206_get_upc(struct cdrom_device_info *cdi, struct cdrom_mcn *mcn)
1273 uch upc[10];
1274 char *ret = mcn->medium_catalog_number;
1275 int i;
1277 if (type_1_command(c_read_upc, 10, upc))
1278 return -EIO;
1279 for (i = 0; i < 13; i++) {
1280 int w = i / 2 + 1, r = i % 2;
1281 if (r)
1282 ret[i] = 0x30 | (upc[w] & 0x0f);
1283 else
1284 ret[i] = 0x30 | ((upc[w] >> 4) & 0x0f);
1286 ret[13] = '\0';
1287 return 0;
1290 int cm206_reset(struct cdrom_device_info *cdi)
1292 stop_read();
1293 reset_cm260();
1294 outw(dc_normal | dc_break | READ_AHEAD, r_data_control);
1295 mdelay(1); /* 750 musec minimum */
1296 outw(dc_normal | READ_AHEAD, r_data_control);
1297 cd->sector_last = -1; /* flag no data buffered */
1298 cd->adapter_last = -1;
1299 invalidate_toc();
1300 return 0;
1303 int cm206_select_speed(struct cdrom_device_info *cdi, int speed)
1305 int r;
1306 switch (speed) {
1307 case 0:
1308 r = type_0_command(c_auto_mode, 1);
1309 break;
1310 case 1:
1311 r = type_0_command(c_force_1x, 1);
1312 break;
1313 case 2:
1314 r = type_0_command(c_force_2x, 1);
1315 break;
1316 default:
1317 return -1;
1319 if (r < 0)
1320 return r;
1321 else
1322 return 1;
1325 static struct cdrom_device_ops cm206_dops = {
1326 .open = cm206_open,
1327 .release = cm206_release,
1328 .drive_status = cm206_drive_status,
1329 .media_changed = cm206_media_changed,
1330 .tray_move = cm206_tray_move,
1331 .lock_door = cm206_lock_door,
1332 .select_speed = cm206_select_speed,
1333 .get_last_session = cm206_get_last_session,
1334 .get_mcn = cm206_get_upc,
1335 .reset = cm206_reset,
1336 .audio_ioctl = cm206_audio_ioctl,
1337 .dev_ioctl = cm206_ioctl,
1338 .capability = CDC_CLOSE_TRAY | CDC_OPEN_TRAY | CDC_LOCK |
1339 CDC_MULTI_SESSION | CDC_MEDIA_CHANGED |
1340 CDC_MCN | CDC_PLAY_AUDIO | CDC_SELECT_SPEED |
1341 CDC_IOCTLS | CDC_DRIVE_STATUS,
1342 .n_minors = 1,
1346 static struct cdrom_device_info cm206_info = {
1347 .ops = &cm206_dops,
1348 .speed = 2,
1349 .capacity = 1,
1350 .name = "cm206",
1353 static int cm206_block_open(struct inode *inode, struct file *file)
1355 return cdrom_open(&cm206_info, inode, file);
1358 static int cm206_block_release(struct inode *inode, struct file *file)
1360 return cdrom_release(&cm206_info, file);
1363 static int cm206_block_ioctl(struct inode *inode, struct file *file,
1364 unsigned cmd, unsigned long arg)
1366 return cdrom_ioctl(file, &cm206_info, inode, cmd, arg);
1369 static int cm206_block_media_changed(struct gendisk *disk)
1371 return cdrom_media_changed(&cm206_info);
1374 static struct block_device_operations cm206_bdops =
1376 .owner = THIS_MODULE,
1377 .open = cm206_block_open,
1378 .release = cm206_block_release,
1379 .ioctl = cm206_block_ioctl,
1380 .media_changed = cm206_block_media_changed,
1383 static struct gendisk *cm206_gendisk;
1385 /* This function probes for the adapter card. It returns the base
1386 address if it has found the adapter card. One can specify a base
1387 port to probe specifically, or 0 which means span all possible
1388 bases.
1390 Linus says it is too dangerous to use writes for probing, so we
1391 stick with pure reads for a while. Hope that 8 possible ranges,
1392 request_region, 15 bits of one port and 6 of another make things
1393 likely enough to accept the region on the first hit...
1395 int __init probe_base_port(int base)
1397 int b = 0x300, e = 0x370; /* this is the range of start addresses */
1398 volatile int fool, i;
1400 if (base)
1401 b = e = base;
1402 for (base = b; base <= e; base += 0x10) {
1403 if (!request_region(base, 0x10,"cm206"))
1404 continue;
1405 for (i = 0; i < 3; i++)
1406 fool = inw(base + 2); /* empty possibly uart_receive_buffer */
1407 if ((inw(base + 6) & 0xffef) != 0x0001 || /* line_status */
1408 (inw(base) & 0xad00) != 0) { /* data status */
1409 release_region(base,0x10);
1410 continue;
1412 return (base);
1414 return 0;
1417 #if !defined(MODULE) || defined(AUTO_PROBE_MODULE)
1418 /* Probe for irq# nr. If nr==0, probe for all possible irq's. */
1419 int __init probe_irq(int nr)
1421 int irqs, irq;
1422 outw(dc_normal | READ_AHEAD, r_data_control); /* disable irq-generation */
1423 sti();
1424 irqs = probe_irq_on();
1425 reset_cm260(); /* causes interrupt */
1426 udelay(100); /* wait for it */
1427 irq = probe_irq_off(irqs);
1428 outw(dc_normal | READ_AHEAD, r_data_control); /* services interrupt */
1429 if (nr && irq != nr && irq > 0)
1430 return 0; /* wrong interrupt happened */
1431 else
1432 return irq;
1434 #endif
1436 int __init cm206_init(void)
1438 uch e = 0;
1439 long int size = sizeof(struct cm206_struct);
1440 struct gendisk *disk;
1442 printk(KERN_INFO "cm206 cdrom driver " REVISION);
1443 cm206_base = probe_base_port(auto_probe ? 0 : cm206_base);
1444 if (!cm206_base) {
1445 printk(" can't find adapter!\n");
1446 return -EIO;
1448 printk(" adapter at 0x%x", cm206_base);
1449 cd = (struct cm206_struct *) kmalloc(size, GFP_KERNEL);
1450 if (!cd)
1451 goto out_base;
1452 /* Now we have found the adaptor card, try to reset it. As we have
1453 * found out earlier, this process generates an interrupt as well,
1454 * so we might just exploit that fact for irq probing! */
1455 #if !defined(MODULE) || defined(AUTO_PROBE_MODULE)
1456 cm206_irq = probe_irq(auto_probe ? 0 : cm206_irq);
1457 if (cm206_irq <= 0) {
1458 printk("can't find IRQ!\n");
1459 goto out_probe;
1460 } else
1461 printk(" IRQ %d found\n", cm206_irq);
1462 #else
1463 cli();
1464 reset_cm260();
1465 /* Now, the problem here is that reset_cm260 can generate an
1466 interrupt. It seems that this can cause a kernel oops some time
1467 later. So we wait a while and `service' this interrupt. */
1468 mdelay(1);
1469 outw(dc_normal | READ_AHEAD, r_data_control);
1470 sti();
1471 printk(" using IRQ %d\n", cm206_irq);
1472 #endif
1473 if (send_receive_polled(c_drive_configuration) !=
1474 c_drive_configuration) {
1475 printk(KERN_INFO " drive not there\n");
1476 goto out_probe;
1478 e = send_receive_polled(c_gimme);
1479 printk(KERN_INFO "Firmware revision %d", e & dcf_revision_code);
1480 if (e & dcf_transfer_rate)
1481 printk(" double");
1482 else
1483 printk(" single");
1484 printk(" speed drive");
1485 if (e & dcf_motorized_tray)
1486 printk(", motorized tray");
1487 if (request_irq(cm206_irq, cm206_interrupt, 0, "cm206", NULL)) {
1488 printk("\nUnable to reserve IRQ---aborted\n");
1489 goto out_probe;
1491 printk(".\n");
1493 if (register_blkdev(MAJOR_NR, "cm206"))
1494 goto out_blkdev;
1496 disk = alloc_disk(1);
1497 if (!disk)
1498 goto out_disk;
1499 disk->major = MAJOR_NR;
1500 disk->first_minor = 0;
1501 sprintf(disk->disk_name, "cm206cd");
1502 disk->fops = &cm206_bdops;
1503 disk->flags = GENHD_FL_CD;
1504 cm206_gendisk = disk;
1505 if (register_cdrom(&cm206_info) != 0) {
1506 printk(KERN_INFO "Cannot register for cdrom %d!\n", MAJOR_NR);
1507 goto out_cdrom;
1509 cm206_queue = blk_init_queue(do_cm206_request, &cm206_lock);
1510 if (!cm206_queue)
1511 goto out_queue;
1513 blk_queue_hardsect_size(cm206_queue, 2048);
1514 disk->queue = cm206_queue;
1515 add_disk(disk);
1517 memset(cd, 0, sizeof(*cd)); /* give'm some reasonable value */
1518 cd->sector_last = -1; /* flag no data buffered */
1519 cd->adapter_last = -1;
1520 init_timer(&cd->timer);
1521 cd->timer.function = cm206_timeout;
1522 cd->max_sectors = (inw(r_data_status) & ds_ram_size) ? 24 : 97;
1523 printk(KERN_INFO "%d kB adapter memory available, "
1524 " %ld bytes kernel memory used.\n", cd->max_sectors * 2,
1525 size);
1526 return 0;
1528 out_queue:
1529 unregister_cdrom(&cm206_info);
1530 out_cdrom:
1531 put_disk(disk);
1532 out_disk:
1533 unregister_blkdev(MAJOR_NR, "cm206");
1534 out_blkdev:
1535 free_irq(cm206_irq, NULL);
1536 out_probe:
1537 kfree(cd);
1538 out_base:
1539 release_region(cm206_base, 16);
1540 return -EIO;
1543 #ifdef MODULE
1546 static void __init parse_options(void)
1548 int i;
1549 for (i = 0; i < 2; i++) {
1550 if (0x300 <= cm206[i] && i <= 0x370
1551 && cm206[i] % 0x10 == 0) {
1552 cm206_base = cm206[i];
1553 auto_probe = 0;
1554 } else if (3 <= cm206[i] && cm206[i] <= 15) {
1555 cm206_irq = cm206[i];
1556 auto_probe = 0;
1561 int __cm206_init(void)
1563 parse_options();
1564 #if !defined(AUTO_PROBE_MODULE)
1565 auto_probe = 0;
1566 #endif
1567 return cm206_init();
1570 void __exit cm206_exit(void)
1572 del_gendisk(cm206_gendisk);
1573 put_disk(cm206_gendisk);
1574 if (unregister_cdrom(&cm206_info)) {
1575 printk("Can't unregister cdrom cm206\n");
1576 return;
1578 if (unregister_blkdev(MAJOR_NR, "cm206")) {
1579 printk("Can't unregister major cm206\n");
1580 return;
1582 blk_cleanup_queue(cm206_queue);
1583 free_irq(cm206_irq, NULL);
1584 kfree(cd);
1585 release_region(cm206_base, 16);
1586 printk(KERN_INFO "cm206 removed\n");
1589 module_init(__cm206_init);
1590 module_exit(cm206_exit);
1592 #else /* !MODULE */
1594 /* This setup function accepts either `auto' or numbers in the range
1595 * 3--11 (for irq) or 0x300--0x370 (for base port) or both. */
1597 static int __init cm206_setup(char *s)
1599 int i, p[4];
1601 (void) get_options(s, ARRAY_SIZE(p), p);
1603 if (!strcmp(s, "auto"))
1604 auto_probe = 1;
1605 for (i = 1; i <= p[0]; i++) {
1606 if (0x300 <= p[i] && i <= 0x370 && p[i] % 0x10 == 0) {
1607 cm206_base = p[i];
1608 auto_probe = 0;
1609 } else if (3 <= p[i] && p[i] <= 15) {
1610 cm206_irq = p[i];
1611 auto_probe = 0;
1614 return 1;
1617 __setup("cm206=", cm206_setup);
1619 #endif /* !MODULE */
1620 MODULE_ALIAS_BLOCKDEV_MAJOR(CM206_CDROM_MAJOR);
1623 * Local variables:
1624 * compile-command: "gcc -D__KERNEL__ -I/usr/src/linux/include -Wall -Wstrict-prototypes -O2 -fomit-frame-pointer -pipe -fno-strength-reduce -m486 -DMODULE -DMODVERSIONS -include /usr/src/linux/include/linux/modversions.h -c -o cm206.o cm206.c"
1625 * End: