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/*
* sbpcd.c CD-ROM device driver for the whole family of traditional,
* non-ATAPI IDE-style Matsushita/Panasonic CR-5xx drives.
* Works with SoundBlaster compatible cards and with "no-sound"
* interface cards like Lasermate, Panasonic CI-101P, Teac, ...
* Also for the Longshine LCS-7260 drive.
* Also for the IBM "External ISA CD-Rom" drive.
* Also for the CreativeLabs CD200 drive.
* Also for the TEAC CD-55A drive.
* Also for the ECS-AT "Vertos 100" drive.
* Not for Sanyo drives (but for the H94A, sjcd is there...).
* Not for any other Funai drives than the CD200 types (sometimes
* labelled E2550UA or MK4015 or 2800F).
*/
#define VERSION "v4.63 Andrew J. Kroll <ag784@freenet.buffalo.edu> Wed Jul 26 04:24:10 EDT 2000"
/* Copyright (C) 1993, 1994, 1995 Eberhard Moenkeberg <emoenke@gwdg.de>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2, or (at your option)
* any later version.
*
* You should have received a copy of the GNU General Public License
* (for example /usr/src/linux/COPYING); if not, write to the Free
* Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*
* If you change this software, you should mail a .diff file with some
* description lines to emoenke@gwdg.de. I want to know about it.
*
* If you are the editor of a Linux CD, you should enable sbpcd.c within
* your boot floppy kernel and send me one of your CDs for free.
*
* If you would like to port the driver to an other operating system (f.e.
* FreeBSD or NetBSD) or use it as an information source, you shall not be
* restricted by the GPL under the following conditions:
* a) the source code of your work is freely available
* b) my part of the work gets mentioned at all places where your
* authorship gets mentioned
* c) I receive a copy of your code together with a full installation
* package of your operating system for free.
*
*
* VERSION HISTORY
*
* 0.1 initial release, April/May 93, after mcd.c (Martin Harriss)
*
* 0.2 thek "repeat:"-loop in do_sbpcd_request did not check for
* end-of-request_queue (resulting in kernel panic).
* Flow control seems stable, but throughput is not better.
*
* 0.3 interrupt locking totally eliminated (maybe "inb" and "outb"
* are still locking) - 0.2 made keyboard-type-ahead losses.
* check_sbpcd_media_change added (to use by isofs/inode.c)
* - but it detects almost nothing.
*
* 0.4 use MAJOR 25 definitely.
* Almost total re-design to support double-speed drives and
* "naked" (no sound) interface cards ("LaserMate" interface type).
* Flow control should be exact now.
* Don't occupy the SbPro IRQ line (not needed either); will
* live together with Hannu Savolainen's sndkit now.
* Speeded up data transfer to 150 kB/sec, with help from Kai
* Makisara, the "provider" of the "mt" tape utility.
* Give "SpinUp" command if necessary.
* First steps to support up to 4 drives (but currently only one).
* Implemented audio capabilities - workman should work, xcdplayer
* gives some problems.
* This version is still consuming too much CPU time, and
* sleeping still has to be worked on.
* During "long" implied seeks, it seems possible that a
* ReadStatus command gets ignored. That gives the message
* "ResponseStatus timed out" (happens about 6 times here during
* a "ls -alR" of the YGGDRASIL LGX-Beta CD). Such a case is
* handled without data error, but it should get done better.
*
* 0.5 Free CPU during waits (again with help from Kai Makisara).
* Made it work together with the LILO/kernel setup standard.
* Included auto-probing code, as suggested by YGGDRASIL.
* Formal redesign to add DDI debugging.
* There are still flaws in IOCTL (workman with double speed drive).
*
* 1.0 Added support for all drive IDs (0...3, no longer only 0)
* and up to 4 drives on one controller.
* Added "#define MANY_SESSION" for "old" multi session CDs.
*
* 1.1 Do SpinUp for new drives, too.
* Revised for clean compile under "old" kernels (0.99pl9).
*
* 1.2 Found the "workman with double-speed drive" bug: use the driver's
* audio_state, not what the drive is reporting with ReadSubQ.
*
* 1.3 Minor cleanups.
* Refinements regarding Workman.
*
* 1.4 Read XA disks (PhotoCDs) with "old" drives, too (but only the first
* session - no chance to fully access a "multi-session" CD).
* This currently still is too slow (50 kB/sec) - but possibly
* the old drives won't do it faster.
* Implemented "door (un)lock" for new drives (still does not work
* as wanted - no lock possible after an unlock).
* Added some debugging printout for the UPC/EAN code - but my drives
* return only zeroes. Is there no UPC/EAN code written?
*
* 1.5 Laborate with UPC/EAN code (not better yet).
* Adapt to kernel 1.1.8 change (have to explicitly include
* <linux/string.h> now).
*
* 1.6 Trying to read audio frames as data. Impossible with the current
* drive firmware levels, as it seems. Awaiting any hint. ;-)
* Changed "door unlock": repeat it until success.
* Changed CDROMSTOP routine (stop somewhat "softer" so that Workman
* won't get confused).
* Added a third interface type: Sequoia S-1000, as used with the SPEA
* Media FX sound card. This interface (usable for Sony and Mitsumi
* drives, too) needs a special configuration setup and behaves like a
* LaserMate type after that. Still experimental - I do not have such
* an interface.
* Use the "variable BLOCK_SIZE" feature (2048). But it does only work
* if you give the mount option "block=2048".
* The media_check routine is currently disabled; now that it gets
* called as it should I fear it must get synchronized for not to
* disturb the normal driver's activity.
*
* 2.0 Version number bumped - two reasons:
* - reading audio tracks as data works now with CR-562 and CR-563. We
* currently do it by an IOCTL (yet has to get standardized), one frame
* at a time; that is pretty slow. But it works.
* - we are maintaining now up to 4 interfaces (each up to 4 drives):
* did it the easy way - a different MAJOR (25, 26, ...) and a different
* copy of the driver (sbpcd.c, sbpcd2.c, sbpcd3.c, sbpcd4.c - only
* distinguished by the value of SBPCD_ISSUE and the driver's name),
* and a common sbpcd.h file.
* Bettered the "ReadCapacity error" problem with old CR-52x drives (the
* drives sometimes need a manual "eject/insert" before work): just
* reset the drive and do again. Needs lots of resets here and sometimes
* that does not cure, so this can't be the solution.
*
* 2.1 Found bug with multisession CDs (accessing frame 16).
* "read audio" works now with address type CDROM_MSF, too.
* Bigger audio frame buffer: allows reading max. 4 frames at time; this
* gives a significant speedup, but reading more than one frame at once
* gives missing chunks at each single frame boundary.
*
* 2.2 Kernel interface cleanups: timers, init, setup, media check.
*
* 2.3 Let "door lock" and "eject" live together.
* Implemented "close tray" (done automatically during open).
*
* 2.4 Use different names for device registering.
*
* 2.5 Added "#if EJECT" code (default: enabled) to automatically eject
* the tray during last call to "sbpcd_release".
* Added "#if JUKEBOX" code (default: disabled) to automatically eject
* the tray during call to "sbpcd_open" if no disk is in.
* Turn on the CD volume of "compatible" sound cards, too; just define
* SOUND_BASE (in sbpcd.h) accordingly (default: disabled).
*
* 2.6 Nothing new.
*
* 2.7 Added CDROMEJECT_SW ioctl to set the "EJECT" behavior on the fly:
* 0 disables, 1 enables auto-ejecting. Useful to keep the tray in
* during shutdown.
*
* 2.8 Added first support (still BETA, I need feedback or a drive) for
* the Longshine LCS-7260 drives. They appear as double-speed drives
* using the "old" command scheme, extended by tray control and door
* lock functions.
* Found (and fixed preliminary) a flaw with some multisession CDs: we
* have to re-direct not only the accesses to frame 16 (the isofs
* routines drive it up to max. 100), but also those to the continuation
* (repetition) frames (as far as they exist - currently set fix as
* 16..20).
* Changed default of the "JUKEBOX" define. If you use this default,
* your tray will eject if you try to mount without a disk in. Next
* mount command will insert the tray - so, just fill in a disk. ;-)
*
* 2.9 Fulfilled the Longshine LCS-7260 support; with great help and
* experiments by Serge Robyns.
* First attempts to support the TEAC CD-55A drives; but still not
* usable yet.
* Implemented the CDROMMULTISESSION ioctl; this is an attempt to handle
* multi session CDs more "transparent" (redirection handling has to be
* done within the isofs routines, and only for the special purpose of
* obtaining the "right" volume descriptor; accesses to the raw device
* should not get redirected).
*
* 3.0 Just a "normal" increment, with some provisions to do it better. ;-)
* Introduced "#define READ_AUDIO" to specify the maximum number of
* audio frames to grab with one request. This defines a buffer size
* within kernel space; a value of 0 will reserve no such space and
* disable the CDROMREADAUDIO ioctl. A value of 75 enables the reading
* of a whole second with one command, but will use a buffer of more
* than 172 kB.
* Started CD200 support. Drive detection should work, but nothing
* more.
*
* 3.1 Working to support the CD200 and the Teac CD-55A drives.
* AT-BUS style device numbering no longer used: use SCSI style now.
* So, the first "found" device has MINOR 0, regardless of the
* jumpered drive ID. This implies modifications to the /dev/sbpcd*
* entries for some people, but will help the DAU (german TLA, english:
* "newbie", maybe ;-) to install his "first" system from a CD.
*
* 3.2 Still testing with CD200 and CD-55A drives.
*
* 3.3 Working with CD200 support.
*
* 3.4 Auto-probing stops if an address of 0 is seen (to be entered with
* the kernel command line).
* Made the driver "loadable". If used as a module, "audio copy" is
* disabled, and the internal read ahead data buffer has a reduced size
* of 4 kB; so, throughput may be reduced a little bit with slow CPUs.
*
* 3.5 Provisions to handle weird photoCDs which have an interrupted
* "formatting" immediately after the last frames of some files: simply
* never "read ahead" with MultiSession CDs. By this, CPU usage may be
* increased with those CDs, and there may be a loss in speed.
* Re-structured the messaging system.
* The "loadable" version no longer has a limited READ_AUDIO buffer
* size.
* Removed "MANY_SESSION" handling for "old" multi session CDs.
* Added "private" IOCTLs CDROMRESET and CDROMVOLREAD.
* Started again to support the TEAC CD-55A drives, now that I found
* the money for "my own" drive. ;-)
* The TEAC CD-55A support is fairly working now.
* I have measured that the drive "delivers" at 600 kB/sec (even with
* bigger requests than the drive's 64 kB buffer can satisfy), but
* the "real" rate does not exceed 520 kB/sec at the moment.
* Caused by the various changes to build in TEAC support, the timed
* loops are de-optimized at the moment (less throughput with CR-52x
* drives, and the TEAC will give speed only with SBP_BUFFER_FRAMES 64).
*
* 3.6 Fixed TEAC data read problems with SbPro interfaces.
* Initial size of the READ_AUDIO buffer is 0. Can get set to any size
* during runtime.
*
* 3.7 Introduced MAX_DRIVES for some poor interface cards (seen with TEAC
* drives) which allow only one drive (ID 0); this avoids repetitive
* detection under IDs 1..3.
* Elongated cmd_out_T response waiting; necessary for photo CDs with
* a lot of sessions.
* Bettered the sbpcd_open() behavior with TEAC drives.
*
* 3.8 Elongated max_latency for CR-56x drives.
*
* 3.9 Finally fixed the long-known SoundScape/SPEA/Sequoia S-1000 interface
* configuration bug.
* Now Corey, Heiko, Ken, Leo, Vadim/Eric & Werner are invited to copy
* the config_spea() routine into their drivers. ;-)
*
* 4.0 No "big step" - normal version increment.
* Adapted the benefits from 1.3.33.
* Fiddled with CDROMREADAUDIO flaws.
* Avoid ReadCapacity command with CD200 drives (the MKE 1.01 version
* seems not to support it).
* Fulfilled "read audio" for CD200 drives, with help of Pete Heist
* (heistp@rpi.edu).
*
* 4.1 Use loglevel KERN_INFO with printk().
* Added support for "Vertos 100" drive ("ECS-AT") - it is very similar
* to the Longshine LCS-7260. Give feedback if you can - I never saw
* such a drive, and I have no specs.
*
* 4.2 Support for Teac 16-bit interface cards. Can't get auto-detected,
* so you have to jumper your card to 0x2C0. Still not 100% - come
* in contact if you can give qualified feedback.
* Use loglevel KERN_NOTICE with printk(). If you get annoyed by a
* flood of unwanted messages and the accompanied delay, try to read
* my documentation. Especially the Linux CDROM drivers have to do an
* important job for the newcomers, so the "distributed" version has
* to fit some special needs. Since generations, the flood of messages
* is user-configurable (even at runtime), but to get aware of this, one
* needs a special mental quality: the ability to read.
*
* 4.3 CD200F does not like to receive a command while the drive is
* reading the ToC; still trying to solve it.
* Removed some redundant verify_area calls (yes, Heiko Eissfeldt
* is visiting all the Linux CDROM drivers ;-).
*
* 4.4 Adapted one idea from tiensivu@pilot.msu.edu's "stripping-down"
* experiments: "KLOGD_PAUSE".
* Inhibited "play audio" attempts with data CDs. Provisions for a
* "data-safe" handling of "mixed" (data plus audio) Cds.
*
* 4.5 Meanwhile Gonzalo Tornaria <tornaria@cmat.edu.uy> (GTL) built a
* special end_request routine: we seem to have to take care for not
* to have two processes working at the request list. My understanding
* was and is that ll_rw_blk should not call do_sbpcd_request as long
* as there is still one call active (the first call will care for all
* outstanding I/Os, and if a second call happens, that is a bug in
* ll_rw_blk.c).
* "Check media change" without touching any drive.
*
* 4.6 Use a semaphore to synchronize multi-activity; elaborated by Rob
* Riggs <rriggs@tesser.com>. At the moment, we simply block "read"
* against "ioctl" and vice versa. This could be refined further, but
* I guess with almost no performance increase.
* Experiments to speed up the CD-55A; again with help of Rob Riggs
* (to be true, he gave both, idea & code. ;-)
*
* 4.61 Ported to Uniform CD-ROM driver by
* Heiko Eissfeldt <heiko@colossus.escape.de> with additional
* changes by Erik Andersen <andersee@debian.org>
*
* 4.62 Fix a bug where playing audio left the drive in an unusable state.
* Heiko Eissfeldt <heiko@colossus.escape.de>
*
* November 1999 -- Make kernel-parameter implementation work with 2.3.x
* Removed init_module & cleanup_module in favor of
* module_init & module_exit.
* Torben Mathiasen <tmm@image.dk>
*
* 4.63 Bug fixes for audio annoyances, new legacy CDROM maintainer.
* Annoying things fixed:
* TOC reread on automated disk changes
* TOC reread on manual cd changes
* Play IOCTL tries to play CD before it's actually ready... sometimes.
* CD_AUDIO_COMPLETED state so workman (and other playes) can repeat play.
* Andrew J. Kroll <ag784@freenet.buffalo.edu> Wed Jul 26 04:24:10 EDT 2000
*
* 4.64 Fix module parameters - were being completely ignored.
* Can also specify max_drives=N as a setup int to get rid of
* "ghost" drives on crap hardware (aren't they all?) Paul Gortmaker
*
* TODO
* implement "read all subchannel data" (96 bytes per frame)
* remove alot of the virtual status bits and deal with hardware status
* move the change of cd for audio to a better place
* add debug levels to insmod parameters (trivial)
*
* special thanks to Kai Makisara (kai.makisara@vtt.fi) for his fine
* elaborated speed-up experiments (and the fabulous results!), for
* the "push" towards load-free wait loops, and for the extensive mail
* thread which brought additional hints and bug fixes.
*
*/
/*
* Trying to merge requests breaks this driver horribly (as in it goes
* boom and apparently has done so since 2.3.41). As it is a legacy
* driver for a horribly slow double speed CD on a hideous interface
* designed for polled operation, I won't loose any sleep in simply
* disallowing merging. Paul G. 02/2001
*/
#define DONT_MERGE_REQUESTS
#ifndef SBPCD_ISSUE
#define SBPCD_ISSUE 1
#endif /* SBPCD_ISSUE */
#include <linux/module.h>
#include <linux/version.h>
#include <linux/errno.h>
#include <linux/sched.h>
#include <linux/mm.h>
#include <linux/timer.h>
#include <linux/fs.h>
#include <linux/kernel.h>
#include <linux/cdrom.h>
#include <linux/ioport.h>
#include <linux/devfs_fs_kernel.h>
#include <linux/major.h>
#include <linux/string.h>
#include <linux/vmalloc.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <asm/system.h>
#include <asm/io.h>
#include <asm/uaccess.h>
#include <stdarg.h>
#include <linux/config.h>
#include "sbpcd.h"
#if !(SBPCD_ISSUE-1)
#define MAJOR_NR MATSUSHITA_CDROM_MAJOR
#endif
#if !(SBPCD_ISSUE-2)
#define MAJOR_NR MATSUSHITA_CDROM2_MAJOR /* second driver issue */
#endif
#if !(SBPCD_ISSUE-3)
#define MAJOR_NR MATSUSHITA_CDROM3_MAJOR /* third driver issue */
#endif
#if !(SBPCD_ISSUE-4)
#define MAJOR_NR MATSUSHITA_CDROM4_MAJOR /* fourth driver issue */
#endif
#include <linux/blk.h>
/*==========================================================================*/
/*
* provisions for more than 1 driver issues
* currently up to 4 drivers, expandable
*/
#if !(SBPCD_ISSUE-1)
#define DO_SBPCD_REQUEST(a) do_sbpcd_request(a)
#define SBPCD_INIT(a) sbpcd_init(a)
#endif
#if !(SBPCD_ISSUE-2)
#define DO_SBPCD_REQUEST(a) do_sbpcd2_request(a)
#define SBPCD_INIT(a) sbpcd2_init(a)
#endif
#if !(SBPCD_ISSUE-3)
#define DO_SBPCD_REQUEST(a) do_sbpcd3_request(a)
#define SBPCD_INIT(a) sbpcd3_init(a)
#endif
#if !(SBPCD_ISSUE-4)
#define DO_SBPCD_REQUEST(a) do_sbpcd4_request(a)
#define SBPCD_INIT(a) sbpcd4_init(a)
#endif
/*==========================================================================*/
#if SBPCD_DIS_IRQ
#define SBPCD_CLI cli()
#define SBPCD_STI sti()
#else
#define SBPCD_CLI
#define SBPCD_STI
#endif /* SBPCD_DIS_IRQ */
/*==========================================================================*/
/*
* auto-probing address list
* inspired by Adam J. Richter from Yggdrasil
*
* still not good enough - can cause a hang.
* example: a NE 2000 ethernet card at 300 will cause a hang probing 310.
* if that happens, reboot and use the LILO (kernel) command line.
* The possibly conflicting ethernet card addresses get NOT probed
* by default - to minimize the hang possibilities.
*
* The SB Pro addresses get "mirrored" at 0x6xx and some more locations - to
* avoid a type error, the 0x2xx-addresses must get checked before 0x6xx.
*
* send mail to emoenke@gwdg.de if your interface card is not FULLY
* represented here.
*/
#if !(SBPCD_ISSUE-1)
static int sbpcd[] =
{
CDROM_PORT, SBPRO, /* probe with user's setup first */
#if DISTRIBUTION
0x230, 1, /* Soundblaster Pro and 16 (default) */
#if 0
0x300, 0, /* CI-101P (default), WDH-7001C (default),
Galaxy (default), Reveal (one default) */
0x250, 1, /* OmniCD default, Soundblaster Pro and 16 */
0x2C0, 3, /* Teac 16-bit cards */
0x260, 1, /* OmniCD */
0x320, 0, /* Lasermate, CI-101P, WDH-7001C, Galaxy, Reveal (other default),
Longshine LCS-6853 (default) */
0x338, 0, /* Reveal Sound Wave 32 card model #SC600 */
0x340, 0, /* Mozart sound card (default), Lasermate, CI-101P */
0x360, 0, /* Lasermate, CI-101P */
0x270, 1, /* Soundblaster 16 */
0x670, 0, /* "sound card #9" */
0x690, 0, /* "sound card #9" */
0x338, 2, /* SPEA Media FX, Ensonic SoundScape (default) */
0x328, 2, /* SPEA Media FX */
0x348, 2, /* SPEA Media FX */
0x634, 0, /* some newer sound cards */
0x638, 0, /* some newer sound cards */
0x230, 1, /* some newer sound cards */
/* due to incomplete address decoding of the SbPro card, these must be last */
0x630, 0, /* "sound card #9" (default) */
0x650, 0, /* "sound card #9" */
#ifdef MODULE
/*
* some "hazardous" locations (no harm with the loadable version)
* (will stop the bus if a NE2000 ethernet card resides at offset -0x10)
*/
0x330, 0, /* Lasermate, CI-101P, WDH-7001C */
0x350, 0, /* Lasermate, CI-101P */
0x358, 2, /* SPEA Media FX */
0x370, 0, /* Lasermate, CI-101P */
0x290, 1, /* Soundblaster 16 */
0x310, 0, /* Lasermate, CI-101P, WDH-7001C */
#endif /* MODULE */
#endif
#endif /* DISTRIBUTION */
};
#else
static int sbpcd[] = {CDROM_PORT, SBPRO}; /* probe with user's setup only */
#endif
MODULE_PARM(sbpcd, "2i");
MODULE_PARM(max_drives, "i");
#define NUM_PROBE (sizeof(sbpcd) / sizeof(int))
/*==========================================================================*/
/*
* the external references:
*/
#if !(SBPCD_ISSUE-1)
#ifdef CONFIG_SBPCD2
extern int sbpcd2_init(void);
#endif
#ifdef CONFIG_SBPCD3
extern int sbpcd3_init(void);
#endif
#ifdef CONFIG_SBPCD4
extern int sbpcd4_init(void);
#endif
#endif
/*==========================================================================*/
#define INLINE inline
/*==========================================================================*/
/*
* the forward references:
*/
static void sbp_sleep(u_int);
static void mark_timeout_delay(u_long);
static void mark_timeout_data(u_long);
#if 0
static void mark_timeout_audio(u_long);
#endif
static void sbp_read_cmd(struct request *req);
static int sbp_data(struct request *req);
static int cmd_out(void);
static int DiskInfo(void);
static int sbpcd_chk_disk_change(kdev_t);
/*==========================================================================*/
/*
* pattern for printk selection:
*
* (1<<DBG_INF) necessary information
* (1<<DBG_BSZ) BLOCK_SIZE trace
* (1<<DBG_REA) "read" status trace
* (1<<DBG_CHK) "media check" trace
* (1<<DBG_TIM) datarate timer test
* (1<<DBG_INI) initialization trace
* (1<<DBG_TOC) tell TocEntry values
* (1<<DBG_IOC) ioctl trace
* (1<<DBG_STA) "ResponseStatus" trace
* (1<<DBG_ERR) "cc_ReadError" trace
* (1<<DBG_CMD) "cmd_out" trace
* (1<<DBG_WRN) give explanation before auto-probing
* (1<<DBG_MUL) multi session code test
* (1<<DBG_IDX) "drive_id != 0" test code
* (1<<DBG_IOX) some special information
* (1<<DBG_DID) drive ID test
* (1<<DBG_RES) drive reset info
* (1<<DBG_SPI) SpinUp test info
* (1<<DBG_IOS) ioctl trace: "subchannel"
* (1<<DBG_IO2) ioctl trace: general
* (1<<DBG_UPC) show UPC info
* (1<<DBG_XA1) XA mode debugging
* (1<<DBG_LCK) door (un)lock info
* (1<<DBG_SQ1) dump SubQ frame
* (1<<DBG_AUD) "read audio" debugging
* (1<<DBG_SEQ) Sequoia interface configuration trace
* (1<<DBG_LCS) Longshine LCS-7260 debugging trace
* (1<<DBG_CD2) MKE/Funai CD200 debugging trace
* (1<<DBG_TEA) TEAC CD-55A debugging trace
* (1<<DBG_ECS) ECS-AT (Vertos-100) debugging trace
* (1<<DBG_000) unnecessary information
*/
#if DISTRIBUTION
static int sbpcd_debug = (1<<DBG_INF);
#else
static int sbpcd_debug = 0 & ((1<<DBG_INF) |
(1<<DBG_TOC) |
(1<<DBG_MUL) |
(1<<DBG_UPC));
#endif /* DISTRIBUTION */
static int sbpcd_ioaddr = CDROM_PORT; /* default I/O base address */
static int sbpro_type = SBPRO;
static unsigned char f_16bit;
static unsigned char do_16bit;
static int CDo_command, CDo_reset;
static int CDo_sel_i_d, CDo_enable;
static int CDi_info, CDi_status, CDi_data;
static struct cdrom_msf msf;
static struct cdrom_ti ti;
static struct cdrom_tochdr tochdr;
static struct cdrom_tocentry tocentry;
static struct cdrom_subchnl SC;
static struct cdrom_volctrl volctrl;
static struct cdrom_read_audio read_audio;
static unsigned char msgnum;
static char msgbuf[80];
static int max_drives = MAX_DRIVES;
#ifndef MODULE
static unsigned char setup_done;
static const char *str_sb_l = "soundblaster";
static const char *str_sp_l = "spea";
static const char *str_ss_l = "soundscape";
static const char *str_t16_l = "teac16bit";
static const char *str_ss = "SoundScape";
#endif
static const char *str_sb = "SoundBlaster";
static const char *str_lm = "LaserMate";
static const char *str_sp = "SPEA";
static const char *str_t16 = "Teac16bit";
static const char *type;
#if !(SBPCD_ISSUE-1)
static const char *major_name="sbpcd";
#endif
#if !(SBPCD_ISSUE-2)
static const char *major_name="sbpcd2";
#endif
#if !(SBPCD_ISSUE-3)
static const char *major_name="sbpcd3";
#endif
#if !(SBPCD_ISSUE-4)
static const char *major_name="sbpcd4";
#endif
/*==========================================================================*/
#if FUTURE
static DECLARE_WAIT_QUEUE_HEAD(sbp_waitq);
#endif /* FUTURE */
static int teac=SBP_TEAC_SPEED;
static int buffers=SBP_BUFFER_FRAMES;
static u_char family0[]="MATSHITA"; /* MKE CR-521, CR-522, CR-523 */
static u_char family1[]="CR-56"; /* MKE CR-562, CR-563 */
static u_char family2[]="CD200"; /* MKE CD200, Funai CD200F */
static u_char familyL[]="LCS-7260"; /* Longshine LCS-7260 */
static u_char familyT[]="CD-55"; /* TEAC CD-55A */
static u_char familyV[]="ECS-AT"; /* ECS Vertos 100 */
static u_int recursion; /* internal testing only */
static u_int fatal_err; /* internal testing only */
static u_int response_count;
static u_int flags_cmd_out;
static u_char cmd_type;
static u_char drvcmd[10];
static u_char infobuf[20];
static u_char xa_head_buf[CD_XA_HEAD];
static u_char xa_tail_buf[CD_XA_TAIL];
#if OLD_BUSY
static volatile u_char busy_data;
static volatile u_char busy_audio; /* true semaphores would be safer */
#endif /* OLD_BUSY */
static DECLARE_MUTEX(ioctl_read_sem);
static u_long timeout;
static volatile u_char timed_out_delay;
static volatile u_char timed_out_data;
#if 0
static volatile u_char timed_out_audio;
#endif
static u_int datarate= 1000000;
static u_int maxtim16=16000000;
static u_int maxtim04= 4000000;
static u_int maxtim02= 2000000;
static u_int maxtim_8= 30000;
#if LONG_TIMING
static u_int maxtim_data= 9000;
#else
static u_int maxtim_data= 3000;
#endif /* LONG_TIMING */
#if DISTRIBUTION
static int n_retries=6;
#else
static int n_retries=6;
#endif
/*==========================================================================*/
static int ndrives;
static u_char drv_pattern[NR_SBPCD]={speed_auto,speed_auto,speed_auto,speed_auto};
static int sbpcd_blocksizes[NR_SBPCD];
/*==========================================================================*/
/*
* drive space begins here (needed separate for each unit)
*/
static int d; /* DriveStruct index: drive number */
static struct {
char drv_id; /* "jumpered" drive ID or -1 */
char drv_sel; /* drive select lines bits */
char drive_model[9];
u_char firmware_version[4];
char f_eject; /* auto-eject flag: 0 or 1 */
u_char *sbp_buf; /* Pointer to internal data buffer,
space allocated during sbpcd_init() */
u_int sbp_bufsiz; /* size of sbp_buf (# of frames) */
int sbp_first_frame; /* First frame in buffer */
int sbp_last_frame; /* Last frame in buffer */
int sbp_read_frames; /* Number of frames being read to buffer */
int sbp_current; /* Frame being currently read */
u_char mode; /* read_mode: READ_M1, READ_M2, READ_SC, READ_AU */
u_char *aud_buf; /* Pointer to audio data buffer,
space allocated during sbpcd_init() */
u_int sbp_audsiz; /* size of aud_buf (# of raw frames) */
u_int drv_type;
u_char drv_options;
int status_bits;
u_char diskstate_flags;
u_char sense_byte;
u_char CD_changed;
char open_count;
u_char error_byte;
u_char f_multisession;
u_int lba_multi;
int first_session;
int last_session;
int track_of_last_session;
u_char audio_state;
u_int pos_audio_start;
u_int pos_audio_end;
char vol_chan0;
u_char vol_ctrl0;
char vol_chan1;
u_char vol_ctrl1;
#if 000 /* no supported drive has it */
char vol_chan2;
u_char vol_ctrl2;
char vol_chan3;
u_char vol_ctrl3;
#endif /*000 */
u_char volume_control; /* TEAC on/off bits */
u_char SubQ_ctl_adr;
u_char SubQ_trk;
u_char SubQ_pnt_idx;
u_int SubQ_run_tot;
u_int SubQ_run_trk;
u_char SubQ_whatisthis;
u_char UPC_ctl_adr;
u_char UPC_buf[7];
int frame_size;
int CDsize_frm;
u_char xa_byte; /* 0x20: XA capabilities */
u_char n_first_track; /* binary */
u_char n_last_track; /* binary (not bcd), 0x01...0x63 */
u_int size_msf; /* time of whole CD, position of LeadOut track */
u_int size_blk;
u_char TocEnt_nixbyte; /* em */
u_char TocEnt_ctl_adr;
u_char TocEnt_number;
u_char TocEnt_format; /* em */
u_int TocEnt_address;
#if SAFE_MIXED
char has_data;
#endif /* SAFE_MIXED */
u_char ored_ctl_adr; /* to detect if CDROM contains data tracks */
struct {
u_char nixbyte; /* em */
u_char ctl_adr; /* 0x4x: data, 0x0x: audio */
u_char number;
u_char format; /* em */ /* 0x00: lba, 0x01: msf */
u_int address;
} TocBuffer[MAX_TRACKS+1]; /* last entry faked */
int in_SpinUp; /* CR-52x test flag */
int n_bytes; /* TEAC awaited response count */
u_char error_state, b3, b4; /* TEAC command error state */
u_char f_drv_error; /* TEAC command error flag */
u_char speed_byte;
int frmsiz;
u_char f_XA; /* 1: XA */
u_char type_byte; /* 0, 1, 3 */
u_char mode_xb_6;
u_char mode_yb_7;
u_char mode_xb_8;
u_char delay;
struct cdrom_device_info *sbpcd_infop;
} D_S[NR_SBPCD];
/*
* drive space ends here (needed separate for each unit)
*/
/*==========================================================================*/
#if 0
unsigned long cli_sti; /* for saving the processor flags */
#endif
/*==========================================================================*/
static struct timer_list delay_timer = { function: mark_timeout_delay};
static struct timer_list data_timer = { function: mark_timeout_data};
#if 0
static struct timer_list audio_timer = { function: mark_timeout_audio};
#endif
/*==========================================================================*/
/*
* DDI interface
*/
static void msg(int level, const char *fmt, ...)
{
#if DISTRIBUTION
#define MSG_LEVEL KERN_NOTICE
#else
#define MSG_LEVEL KERN_INFO
#endif /* DISTRIBUTION */
char buf[256];
va_list args;
if (!(sbpcd_debug&(1<<level))) return;
msgnum++;
if (msgnum>99) msgnum=0;
sprintf(buf, MSG_LEVEL "%s-%d [%02d]: ", major_name, d, msgnum);
va_start(args, fmt);
vsprintf(&buf[18], fmt, args);
va_end(args);
printk(buf);
#if KLOGD_PAUSE
sbp_sleep(KLOGD_PAUSE); /* else messages get lost */
#endif /* KLOGD_PAUSE */
return;
}
/*==========================================================================*/
/*
* DDI interface: runtime trace bit pattern maintenance
*/
static int sbpcd_dbg_ioctl(unsigned long arg, int level)
{
switch(arg)
{
case 0: /* OFF */
sbpcd_debug = DBG_INF;
break;
default:
if (arg>=128) sbpcd_debug &= ~(1<<(arg-128));
else sbpcd_debug |= (1<<arg);
}
return (arg);
}
/*==========================================================================*/
static void mark_timeout_delay(u_long i)
{
timed_out_delay=1;
#if 0
msg(DBG_TIM,"delay timer expired.\n");
#endif
}
/*==========================================================================*/
static void mark_timeout_data(u_long i)
{
timed_out_data=1;
#if 0
msg(DBG_TIM,"data timer expired.\n");
#endif
}
/*==========================================================================*/
#if 0
static void mark_timeout_audio(u_long i)
{
timed_out_audio=1;
#if 0
msg(DBG_TIM,"audio timer expired.\n");
#endif
}
#endif
/*==========================================================================*/
/*
* Wait a little while (used for polling the drive).
*/
static void sbp_sleep(u_int time)
{
sti();
current->state = TASK_INTERRUPTIBLE;
schedule_timeout(time);
sti();
}
/*==========================================================================*/
#define RETURN_UP(rc) {up(&ioctl_read_sem); return(rc);}
/*==========================================================================*/
/*
* convert logical_block_address to m-s-f_number (3 bytes only)
*/
static INLINE void lba2msf(int lba, u_char *msf)
{
lba += CD_MSF_OFFSET;
msf[0] = lba / (CD_SECS*CD_FRAMES);
lba %= CD_SECS*CD_FRAMES;
msf[1] = lba / CD_FRAMES;
msf[2] = lba % CD_FRAMES;
}
/*==========================================================================*/
/*==========================================================================*/
/*
* convert msf-bin to msf-bcd
*/
static INLINE void bin2bcdx(u_char *p) /* must work only up to 75 or 99 */
{
*p=((*p/10)<<4)|(*p%10);
}
/*==========================================================================*/
static INLINE u_int blk2msf(u_int blk)
{
MSF msf;
u_int mm;
msf.c[3] = 0;
msf.c[2] = (blk + CD_MSF_OFFSET) / (CD_SECS * CD_FRAMES);
mm = (blk + CD_MSF_OFFSET) % (CD_SECS * CD_FRAMES);
msf.c[1] = mm / CD_FRAMES;
msf.c[0] = mm % CD_FRAMES;
return (msf.n);
}
/*==========================================================================*/
static INLINE u_int make16(u_char rh, u_char rl)
{
return ((rh<<8)|rl);
}
/*==========================================================================*/
static INLINE u_int make32(u_int rh, u_int rl)
{
return ((rh<<16)|rl);
}
/*==========================================================================*/
static INLINE u_char swap_nibbles(u_char i)
{
return ((i<<4)|(i>>4));
}
/*==========================================================================*/
static INLINE u_char byt2bcd(u_char i)
{
return (((i/10)<<4)+i%10);
}
/*==========================================================================*/
static INLINE u_char bcd2bin(u_char bcd)
{
return ((bcd>>4)*10+(bcd&0x0F));
}
/*==========================================================================*/
static INLINE int msf2blk(int msfx)
{
MSF msf;
int i;
msf.n=msfx;
i=(msf.c[2] * CD_SECS + msf.c[1]) * CD_FRAMES + msf.c[0] - CD_MSF_OFFSET;
if (i<0) return (0);
return (i);
}
/*==========================================================================*/
/*
* convert m-s-f_number (3 bytes only) to logical_block_address
*/
static INLINE int msf2lba(u_char *msf)
{
int i;
i=(msf[0] * CD_SECS + msf[1]) * CD_FRAMES + msf[2] - CD_MSF_OFFSET;
if (i<0) return (0);
return (i);
}
/*==========================================================================*/
/* evaluate cc_ReadError code */
static int sta2err(int sta)
{
if (famT_drive)
{
if (sta==0x00) return (0);
if (sta==0x01) return (-604); /* CRC error */
if (sta==0x02) return (-602); /* drive not ready */
if (sta==0x03) return (-607); /* unknown media */
if (sta==0x04) return (-612); /* general failure */
if (sta==0x05) return (0);
if (sta==0x06) return (-ERR_DISKCHANGE); /* disk change */
if (sta==0x0b) return (-612); /* general failure */
if (sta==0xff) return (-612); /* general failure */
return (0);
}
else
{
if (sta<=2) return (sta);
if (sta==0x05) return (-604); /* CRC error */
if (sta==0x06) return (-606); /* seek error */
if (sta==0x0d) return (-606); /* seek error */
if (sta==0x0e) return (-603); /* unknown command */
if (sta==0x14) return (-603); /* unknown command */
if (sta==0x0c) return (-611); /* read fault */
if (sta==0x0f) return (-611); /* read fault */
if (sta==0x10) return (-611); /* read fault */
if (sta>=0x16) return (-612); /* general failure */
if (sta==0x11) return (-ERR_DISKCHANGE); /* disk change (LCS: removed) */
if (famL_drive)
if (sta==0x12) return (-ERR_DISKCHANGE); /* disk change (inserted) */
return (-602); /* drive not ready */
}
}
/*==========================================================================*/
static INLINE void clr_cmdbuf(void)
{
int i;
for (i=0;i<10;i++) drvcmd[i]=0;
cmd_type=0;
}
/*==========================================================================*/
static void flush_status(void)
{
int i;
sbp_sleep(15*HZ/10);
for (i=maxtim_data;i!=0;i--) inb(CDi_status);
}
/*====================================================================*/
/*
* CDi status loop for Teac CD-55A (Rob Riggs)
*
* This is needed because for some strange reason
* the CD-55A can take a real long time to give a
* status response. This seems to happen after we
* issue a READ command where a long seek is involved.
*
* I tried to ensure that we get max throughput with
* minimal busy waiting. We busy wait at first, then
* "switch gears" and start sleeping. We sleep for
* longer periods of time the longer we wait.
*
*/
static int CDi_stat_loop_T(void)
{
int i, gear=1;
u_long timeout_1, timeout_2, timeout_3, timeout_4;
timeout_1 = jiffies + HZ / 50; /* sbp_sleep(0) for a short period */
timeout_2 = jiffies + HZ / 5; /* nap for no more than 200ms */
timeout_3 = jiffies + 5 * HZ; /* sleep for up to 5s */
timeout_4 = jiffies + 45 * HZ; /* long sleep for up to 45s. */
do
{
i = inb(CDi_status);
if (!(i&s_not_data_ready)) return (i);
if (!(i&s_not_result_ready)) return (i);
switch(gear)
{
case 4:
sbp_sleep(HZ);
if (time_after(jiffies, timeout_4)) gear++;
msg(DBG_TEA, "CDi_stat_loop_T: long sleep active.\n");
break;
case 3:
sbp_sleep(HZ/10);
if (time_after(jiffies, timeout_3)) gear++;
break;
case 2:
sbp_sleep(HZ/100);
if (time_after(jiffies, timeout_2)) gear++;
break;
case 1:
sbp_sleep(0);
if (time_after(jiffies, timeout_1)) gear++;
}
} while (gear < 5);
return -1;
}
/*==========================================================================*/
static int CDi_stat_loop(void)
{
int i,j;
for(timeout = jiffies + 10*HZ, i=maxtim_data; time_before(jiffies, timeout); )
{
for ( ;i!=0;i--)
{
j=inb(CDi_status);
if (!(j&s_not_data_ready)) return (j);
if (!(j&s_not_result_ready)) return (j);
if (fam0L_drive) if (j&s_attention) return (j);
}
sbp_sleep(1);
i = 1;
}
msg(DBG_LCS,"CDi_stat_loop failed in line %d\n", __LINE__);
return (-1);
}
/*==========================================================================*/
#if 00000
/*==========================================================================*/
static int tst_DataReady(void)
{
int i;
i=inb(CDi_status);
if (i&s_not_data_ready) return (0);
return (1);
}
/*==========================================================================*/
static int tst_ResultReady(void)
{
int i;
i=inb(CDi_status);
if (i&s_not_result_ready) return (0);
return (1);
}
/*==========================================================================*/
static int tst_Attention(void)
{
int i;
i=inb(CDi_status);
if (i&s_attention) return (1);
return (0);
}
/*==========================================================================*/
#endif
/*==========================================================================*/
static int ResponseInfo(void)
{
int i,j,st=0;
u_long timeout;
for (i=0,timeout=jiffies+HZ;i<response_count;i++)
{
for (j=maxtim_data; ; )
{
for ( ;j!=0;j-- )
{
st=inb(CDi_status);
if (!(st&s_not_result_ready)) break;
}
if ((j!=0)||time_after_eq(jiffies, timeout)) break;
sbp_sleep(1);
j = 1;
}
if (time_after_eq(jiffies, timeout)) break;
infobuf[i]=inb(CDi_info);
}
#if 000
while (!(inb(CDi_status)&s_not_result_ready))
{
infobuf[i++]=inb(CDi_info);
}
j=i-response_count;
if (j>0) msg(DBG_INF,"ResponseInfo: got %d trailing bytes.\n",j);
#endif /* 000 */
for (j=0;j<i;j++)
sprintf(&msgbuf[j*3]," %02X",infobuf[j]);
msgbuf[j*3]=0;
msg(DBG_CMD,"ResponseInfo:%s (%d,%d)\n",msgbuf,response_count,i);
j=response_count-i;
if (j>0) return (-j);
else return (i);
}
/*==========================================================================*/
static void EvaluateStatus(int st)
{
D_S[d].status_bits=0;
if (fam1_drive) D_S[d].status_bits=st|p_success;
else if (fam0_drive)
{
if (st&p_caddin_old) D_S[d].status_bits |= p_door_closed|p_caddy_in;
if (st&p_spinning) D_S[d].status_bits |= p_spinning;
if (st&p_check) D_S[d].status_bits |= p_check;
if (st&p_success_old) D_S[d].status_bits |= p_success;
if (st&p_busy_old) D_S[d].status_bits |= p_busy_new;
if (st&p_disk_ok) D_S[d].status_bits |= p_disk_ok;
}
else if (famLV_drive)
{
D_S[d].status_bits |= p_success;
if (st&p_caddin_old) D_S[d].status_bits |= p_disk_ok|p_caddy_in;
if (st&p_spinning) D_S[d].status_bits |= p_spinning;
if (st&p_check) D_S[d].status_bits |= p_check;
if (st&p_busy_old) D_S[d].status_bits |= p_busy_new;
if (st&p_lcs_door_closed) D_S[d].status_bits |= p_door_closed;
if (st&p_lcs_door_locked) D_S[d].status_bits |= p_door_locked;
}
else if (fam2_drive)
{
D_S[d].status_bits |= p_success;
if (st&p2_check) D_S[d].status_bits |= p1_check;
if (st&p2_door_closed) D_S[d].status_bits |= p1_door_closed;
if (st&p2_disk_in) D_S[d].status_bits |= p1_disk_in;
if (st&p2_busy1) D_S[d].status_bits |= p1_busy;
if (st&p2_busy2) D_S[d].status_bits |= p1_busy;
if (st&p2_spinning) D_S[d].status_bits |= p1_spinning;
if (st&p2_door_locked) D_S[d].status_bits |= p1_door_locked;
if (st&p2_disk_ok) D_S[d].status_bits |= p1_disk_ok;
}
else if (famT_drive)
{
return; /* still needs to get coded */
D_S[d].status_bits |= p_success;
if (st&p2_check) D_S[d].status_bits |= p1_check;
if (st&p2_door_closed) D_S[d].status_bits |= p1_door_closed;
if (st&p2_disk_in) D_S[d].status_bits |= p1_disk_in;
if (st&p2_busy1) D_S[d].status_bits |= p1_busy;
if (st&p2_busy2) D_S[d].status_bits |= p1_busy;
if (st&p2_spinning) D_S[d].status_bits |= p1_spinning;
if (st&p2_door_locked) D_S[d].status_bits |= p1_door_locked;
if (st&p2_disk_ok) D_S[d].status_bits |= p1_disk_ok;
}
return;
}
/*==========================================================================*/
static int get_state_T(void)
{
int i;
static int cmd_out_T(void);
clr_cmdbuf();
D_S[d].n_bytes=1;
drvcmd[0]=CMDT_STATUS;
i=cmd_out_T();
if (i>=0) i=infobuf[0];
else
{
msg(DBG_TEA,"get_state_T error %d\n", i);
return (i);
}
if (i>=0)
/* 2: closed, disk in */
D_S[d].status_bits=p1_door_closed|p1_disk_in|p1_spinning|p1_disk_ok;
else if (D_S[d].error_state==6)
{
/* 3: closed, disk in, changed ("06 xx xx") */
D_S[d].status_bits=p1_door_closed|p1_disk_in;
D_S[d].CD_changed=0xFF;
D_S[d].diskstate_flags &= ~toc_bit;
}
else if ((D_S[d].error_state!=2)||(D_S[d].b3!=0x3A)||(D_S[d].b4==0x00))
{
/* 1: closed, no disk ("xx yy zz"or "02 3A 00") */
D_S[d].status_bits=p1_door_closed;
D_S[d].open_count=0;
}
else if (D_S[d].b4==0x01)
{
/* 0: open ("02 3A 01") */
D_S[d].status_bits=0;
D_S[d].open_count=0;
}
else
{
/* 1: closed, no disk ("02 3A xx") */
D_S[d].status_bits=p1_door_closed;
D_S[d].open_count=0;
}
return (D_S[d].status_bits);
}
/*==========================================================================*/
static int ResponseStatus(void)
{
int i,j;
u_long timeout;
msg(DBG_STA,"doing ResponseStatus...\n");
if (famT_drive) return (get_state_T());
if (flags_cmd_out & f_respo3) timeout = jiffies;
else if (flags_cmd_out & f_respo2) timeout = jiffies + 16*HZ;
else timeout = jiffies + 4*HZ;
j=maxtim_8;
do
{
for ( ;j!=0;j--)
{
i=inb(CDi_status);
if (!(i&s_not_result_ready)) break;
}
if ((j!=0)||time_after(jiffies, timeout)) break;
sbp_sleep(1);
j = 1;
}
while (1);
if (j==0)
{
if ((flags_cmd_out & f_respo3) == 0)
msg(DBG_STA,"ResponseStatus: timeout.\n");
D_S[d].status_bits=0;
return (-401);
}
i=inb(CDi_info);
msg(DBG_STA,"ResponseStatus: response %02X.\n", i);
EvaluateStatus(i);
msg(DBG_STA,"status_bits=%02X, i=%02X\n",D_S[d].status_bits,i);
return (D_S[d].status_bits);
}
/*==========================================================================*/
static void cc_ReadStatus(void)
{
int i;
msg(DBG_STA,"giving cc_ReadStatus command\n");
if (famT_drive) return;
SBPCD_CLI;
if (fam0LV_drive) OUT(CDo_command,CMD0_STATUS);
else if (fam1_drive) OUT(CDo_command,CMD1_STATUS);
else if (fam2_drive) OUT(CDo_command,CMD2_STATUS);
if (!fam0LV_drive) for (i=0;i<6;i++) OUT(CDo_command,0);
SBPCD_STI;
}
/*==========================================================================*/
static int cc_ReadError(void)
{
int i;
clr_cmdbuf();
msg(DBG_ERR,"giving cc_ReadError command.\n");
if (fam1_drive)
{
drvcmd[0]=CMD1_READ_ERR;
response_count=8;
flags_cmd_out=f_putcmd|f_ResponseStatus;
}
else if (fam0LV_drive)
{
drvcmd[0]=CMD0_READ_ERR;
response_count=6;
if (famLV_drive)
flags_cmd_out=f_putcmd;
else
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_READ_ERR;
response_count=6;
flags_cmd_out=f_putcmd;
}
else if (famT_drive)
{
response_count=5;
drvcmd[0]=CMDT_READ_ERR;
}
i=cmd_out();
D_S[d].error_byte=0;
msg(DBG_ERR,"cc_ReadError: cmd_out(CMDx_READ_ERR) returns %d (%02X)\n",i,i);
if (i<0) return (i);
if (fam0V_drive) i=1;
else i=2;
D_S[d].error_byte=infobuf[i];
msg(DBG_ERR,"cc_ReadError: infobuf[%d] is %d (%02X)\n",i,D_S[d].error_byte,D_S[d].error_byte);
i=sta2err(infobuf[i]);
if (i==-ERR_DISKCHANGE)
{
D_S[d].CD_changed=0xFF;
D_S[d].diskstate_flags &= ~toc_bit;
}
return (i);
}
/*==========================================================================*/
static int cmd_out_T(void)
{
#undef CMDT_TRIES
#define CMDT_TRIES 1000
#define TEST_FALSE_FF 1
static int cc_DriveReset(void);
int i, j, l=0, m, ntries;
long flags;
D_S[d].error_state=0;
D_S[d].b3=0;
D_S[d].b4=0;
D_S[d].f_drv_error=0;
for (i=0;i<10;i++) sprintf(&msgbuf[i*3]," %02X",drvcmd[i]);
msgbuf[i*3]=0;
msg(DBG_CMD,"cmd_out_T:%s\n",msgbuf);
OUT(CDo_sel_i_d,0);
OUT(CDo_enable,D_S[d].drv_sel);
i=inb(CDi_status);
do_16bit=0;
if ((f_16bit)&&(!(i&0x80)))
{
do_16bit=1;
msg(DBG_TEA,"cmd_out_T: do_16bit set.\n");
}
if (!(i&s_not_result_ready))
do
{
j=inb(CDi_info);
i=inb(CDi_status);
sbp_sleep(0);
msg(DBG_TEA,"cmd_out_T: spurious !s_not_result_ready. (%02X)\n", j);
}
while (!(i&s_not_result_ready));
save_flags(flags); cli();
for (i=0;i<10;i++) OUT(CDo_command,drvcmd[i]);
restore_flags(flags);
for (ntries=CMDT_TRIES;ntries>0;ntries--)
{
if (drvcmd[0]==CMDT_READ_VER) sbp_sleep(HZ); /* fixme */
#if 01
OUT(CDo_sel_i_d,1);
#endif /* 01 */
if (teac==2)
{
if ((i=CDi_stat_loop_T()) == -1) break;
}
else
{
#if 0
OUT(CDo_sel_i_d,1);
#endif /* 0 */
i=inb(CDi_status);
}
if (!(i&s_not_data_ready)) /* f.e. CMDT_DISKINFO */
{
OUT(CDo_sel_i_d,1);
if (drvcmd[0]==CMDT_READ) return (0); /* handled elsewhere */
if (drvcmd[0]==CMDT_DISKINFO)
{
l=0;
do
{
if (do_16bit)
{
i=inw(CDi_data);
infobuf[l++]=i&0x0ff;
infobuf[l++]=i>>8;
#if TEST_FALSE_FF
if ((l==2)&&(infobuf[0]==0x0ff))
{
infobuf[0]=infobuf[1];
l=1;
msg(DBG_TEA,"cmd_out_T: do_16bit: false first byte!\n");
}
#endif /* TEST_FALSE_FF */
}
else infobuf[l++]=inb(CDi_data);
i=inb(CDi_status);
}
while (!(i&s_not_data_ready));
for (j=0;j<l;j++) sprintf(&msgbuf[j*3]," %02X",infobuf[j]);
msgbuf[j*3]=0;
msg(DBG_CMD,"cmd_out_T data response:%s\n", msgbuf);
}
else
{
msg(DBG_TEA,"cmd_out_T: data response with cmd_%02X!\n",
drvcmd[0]);
j=0;
do
{
if (do_16bit) i=inw(CDi_data);
else i=inb(CDi_data);
j++;
i=inb(CDi_status);
}
while (!(i&s_not_data_ready));
msg(DBG_TEA,"cmd_out_T: data response: discarded %d bytes/words.\n", j);
fatal_err++;
}
}
i=inb(CDi_status);
if (!(i&s_not_result_ready))
{
OUT(CDo_sel_i_d,0);
if (drvcmd[0]==CMDT_DISKINFO) m=l;
else m=0;
do
{
infobuf[m++]=inb(CDi_info);
i=inb(CDi_status);
}
while (!(i&s_not_result_ready));
for (j=0;j<m;j++) sprintf(&msgbuf[j*3]," %02X",infobuf[j]);
msgbuf[j*3]=0;
msg(DBG_CMD,"cmd_out_T info response:%s\n", msgbuf);
if (drvcmd[0]==CMDT_DISKINFO)
{
infobuf[0]=infobuf[l];
if (infobuf[0]!=0x02) return (l); /* data length */
}
else if (infobuf[0]!=0x02) return (m); /* info length */
do
{
++recursion;
if (recursion>1) msg(DBG_TEA,"cmd_out_T READ_ERR recursion (%02X): %d !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n", drvcmd[0], recursion);
clr_cmdbuf();
drvcmd[0]=CMDT_READ_ERR;
j=cmd_out_T(); /* !!! recursive here !!! */
--recursion;
sbp_sleep(1);
}
while (j<0);
D_S[d].error_state=infobuf[2];
D_S[d].b3=infobuf[3];
D_S[d].b4=infobuf[4];
if (D_S[d].f_drv_error)
{
D_S[d].f_drv_error=0;
cc_DriveReset();
D_S[d].error_state=2;
}
return (-D_S[d].error_state-400);
}
if (drvcmd[0]==CMDT_READ) return (0); /* handled elsewhere */
if ((teac==0)||(ntries<(CMDT_TRIES-5))) sbp_sleep(HZ/10);
else sbp_sleep(HZ/100);
if (ntries>(CMDT_TRIES-50)) continue;
msg(DBG_TEA,"cmd_out_T: next CMDT_TRIES (%02X): %d.\n", drvcmd[0], ntries-1);
}
D_S[d].f_drv_error=1;
cc_DriveReset();
D_S[d].error_state=2;
return (-99);
}
/*==========================================================================*/
static int cmd_out(void)
{
int i=0;
if (famT_drive) return(cmd_out_T());
if (flags_cmd_out&f_putcmd)
{
unsigned long flags;
for (i=0;i<7;i++)
sprintf(&msgbuf[i*3], " %02X", drvcmd[i]);
msgbuf[i*3]=0;
msg(DBG_CMD,"cmd_out:%s\n", msgbuf);
save_flags(flags); cli();
for (i=0;i<7;i++) OUT(CDo_command,drvcmd[i]);
restore_flags(flags);
}
if (response_count!=0)
{
if (cmd_type!=0)
{
if (sbpro_type==1) OUT(CDo_sel_i_d,1);
msg(DBG_INF,"misleaded to try ResponseData.\n");
if (sbpro_type==1) OUT(CDo_sel_i_d,0);
return (-22);
}
else i=ResponseInfo();
if (i<0) return (i);
}
if (D_S[d].in_SpinUp) msg(DBG_SPI,"in_SpinUp: to CDi_stat_loop.\n");
if (flags_cmd_out&f_lopsta)
{
i=CDi_stat_loop();
if ((i<0)||!(i&s_attention)) return (-8);
}
if (!(flags_cmd_out&f_getsta)) goto LOC_229;
LOC_228:
if (D_S[d].in_SpinUp) msg(DBG_SPI,"in_SpinUp: to cc_ReadStatus.\n");
cc_ReadStatus();
LOC_229:
if (flags_cmd_out&f_ResponseStatus)
{
if (D_S[d].in_SpinUp) msg(DBG_SPI,"in_SpinUp: to ResponseStatus.\n");
i=ResponseStatus();
/* builds status_bits, returns orig. status or p_busy_new */
if (i<0) return (i);
if (flags_cmd_out&(f_bit1|f_wait_if_busy))
{
if (!st_check)
{
if ((flags_cmd_out&f_bit1)&&(i&p_success)) goto LOC_232;
if ((!(flags_cmd_out&f_wait_if_busy))||(!st_busy)) goto LOC_228;
}
}
}
LOC_232:
if (!(flags_cmd_out&f_obey_p_check)) return (0);
if (!st_check) return (0);
if (D_S[d].in_SpinUp) msg(DBG_SPI,"in_SpinUp: to cc_ReadError.\n");
i=cc_ReadError();
if (D_S[d].in_SpinUp) msg(DBG_SPI,"in_SpinUp: to cmd_out OK.\n");
msg(DBG_000,"cmd_out: cc_ReadError=%d\n", i);
return (i);
}
/*==========================================================================*/
static int cc_Seek(u_int pos, char f_blk_msf)
{
int i;
clr_cmdbuf();
if (f_blk_msf>1) return (-3);
if (fam0V_drive)
{
drvcmd[0]=CMD0_SEEK;
if (f_blk_msf==1) pos=msf2blk(pos);
drvcmd[2]=(pos>>16)&0x00FF;
drvcmd[3]=(pos>>8)&0x00FF;
drvcmd[4]=pos&0x00FF;
if (fam0_drive)
flags_cmd_out = f_putcmd | f_respo2 | f_lopsta | f_getsta |
f_ResponseStatus | f_obey_p_check | f_bit1;
else
flags_cmd_out = f_putcmd;
}
else if (fam1L_drive)
{
drvcmd[0]=CMD1_SEEK; /* same as CMD1_ and CMDL_ */
if (f_blk_msf==0) pos=blk2msf(pos);
drvcmd[1]=(pos>>16)&0x00FF;
drvcmd[2]=(pos>>8)&0x00FF;
drvcmd[3]=pos&0x00FF;
if (famL_drive)
flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
else
flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_SEEK;
if (f_blk_msf==0) pos=blk2msf(pos);
drvcmd[2]=(pos>>24)&0x00FF;
drvcmd[3]=(pos>>16)&0x00FF;
drvcmd[4]=(pos>>8)&0x00FF;
drvcmd[5]=pos&0x00FF;
flags_cmd_out=f_putcmd|f_ResponseStatus;
}
else if (famT_drive)
{
drvcmd[0]=CMDT_SEEK;
if (f_blk_msf==1) pos=msf2blk(pos);
drvcmd[2]=(pos>>24)&0x00FF;
drvcmd[3]=(pos>>16)&0x00FF;
drvcmd[4]=(pos>>8)&0x00FF;
drvcmd[5]=pos&0x00FF;
D_S[d].n_bytes=1;
}
response_count=0;
i=cmd_out();
return (i);
}
/*==========================================================================*/
static int cc_SpinUp(void)
{
int i;
msg(DBG_SPI,"SpinUp.\n");
D_S[d].in_SpinUp = 1;
clr_cmdbuf();
if (fam0LV_drive)
{
drvcmd[0]=CMD0_SPINUP;
if (fam0L_drive)
flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|
f_ResponseStatus|f_obey_p_check|f_bit1;
else
flags_cmd_out=f_putcmd;
}
else if (fam1_drive)
{
drvcmd[0]=CMD1_SPINUP;
flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_TRAY_CTL;
drvcmd[4]=0x01; /* "spinup" */
flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
}
else if (famT_drive)
{
drvcmd[0]=CMDT_TRAY_CTL;
drvcmd[4]=0x03; /* "insert", it hopefully spins the drive up */
}
response_count=0;
i=cmd_out();
D_S[d].in_SpinUp = 0;
return (i);
}
/*==========================================================================*/
static int cc_SpinDown(void)
{
int i;
if (fam0_drive) return (0);
clr_cmdbuf();
response_count=0;
if (fam1_drive)
{
drvcmd[0]=CMD1_SPINDOWN;
flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_TRAY_CTL;
drvcmd[4]=0x02; /* "eject" */
flags_cmd_out=f_putcmd|f_ResponseStatus;
}
else if (famL_drive)
{
drvcmd[0]=CMDL_SPINDOWN;
drvcmd[1]=1;
flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
}
else if (famV_drive)
{
drvcmd[0]=CMDV_SPINDOWN;
flags_cmd_out=f_putcmd;
}
else if (famT_drive)
{
drvcmd[0]=CMDT_TRAY_CTL;
drvcmd[4]=0x02; /* "eject" */
}
i=cmd_out();
return (i);
}
/*==========================================================================*/
static int cc_get_mode_T(void)
{
int i;
clr_cmdbuf();
response_count=10;
drvcmd[0]=CMDT_GETMODE;
drvcmd[4]=response_count;
i=cmd_out_T();
return (i);
}
/*==========================================================================*/
static int cc_set_mode_T(void)
{
int i;
clr_cmdbuf();
response_count=1;
drvcmd[0]=CMDT_SETMODE;
drvcmd[1]=D_S[d].speed_byte;
drvcmd[2]=D_S[d].frmsiz>>8;
drvcmd[3]=D_S[d].frmsiz&0x0FF;
drvcmd[4]=D_S[d].f_XA; /* 1: XA */
drvcmd[5]=D_S[d].type_byte; /* 0, 1, 3 */
drvcmd[6]=D_S[d].mode_xb_6;
drvcmd[7]=D_S[d].mode_yb_7|D_S[d].volume_control;
drvcmd[8]=D_S[d].mode_xb_8;
drvcmd[9]=D_S[d].delay;
i=cmd_out_T();
return (i);
}
/*==========================================================================*/
static int cc_prep_mode_T(void)
{
int i, j;
i=cc_get_mode_T();
if (i<0) return (i);
for (i=0;i<10;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_TEA,"CMDT_GETMODE:%s\n", msgbuf);
D_S[d].speed_byte=0x02; /* 0x02: auto quad, 0x82: quad, 0x81: double, 0x80: single */
D_S[d].frmsiz=make16(infobuf[2],infobuf[3]);
D_S[d].f_XA=infobuf[4];
if (D_S[d].f_XA==0) D_S[d].type_byte=0;
else D_S[d].type_byte=1;
D_S[d].mode_xb_6=infobuf[6];
D_S[d].mode_yb_7=1;
D_S[d].mode_xb_8=infobuf[8];
D_S[d].delay=0; /* 0, 1, 2, 3 */
j=cc_set_mode_T();
i=cc_get_mode_T();
for (i=0;i<10;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_TEA,"CMDT_GETMODE:%s\n", msgbuf);
return (j);
}
/*==========================================================================*/
static int cc_SetSpeed(u_char speed, u_char x1, u_char x2)
{
int i;
if (fam0LV_drive) return (0);
clr_cmdbuf();
response_count=0;
if (fam1_drive)
{
drvcmd[0]=CMD1_SETMODE;
drvcmd[1]=0x03;
drvcmd[2]=speed;
drvcmd[3]=x1;
drvcmd[4]=x2;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_SETSPEED;
if (speed&speed_auto)
{
drvcmd[2]=0xFF;
drvcmd[3]=0xFF;
}
else
{
drvcmd[2]=0;
drvcmd[3]=150;
}
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (famT_drive)
{
return (0);
}
i=cmd_out();
return (i);
}
/*==========================================================================*/
static int cc_SetVolume(void)
{
int i;
u_char channel0,channel1,volume0,volume1;
u_char control0,value0,control1,value1;
D_S[d].diskstate_flags &= ~volume_bit;
clr_cmdbuf();
channel0=D_S[d].vol_chan0;
volume0=D_S[d].vol_ctrl0;
channel1=control1=D_S[d].vol_chan1;
volume1=value1=D_S[d].vol_ctrl1;
control0=value0=0;
if (famV_drive) return (0);
if (((D_S[d].drv_options&audio_mono)!=0)&&(D_S[d].drv_type>=drv_211))
{
if ((volume0!=0)&&(volume1==0))
{
volume1=volume0;
channel1=channel0;
}
else if ((volume0==0)&&(volume1!=0))
{
volume0=volume1;
channel0=channel1;
}
}
if (channel0>1)
{
channel0=0;
volume0=0;
}
if (channel1>1)
{
channel1=1;
volume1=0;
}
if (fam1_drive)
{
control0=channel0+1;
control1=channel1+1;
value0=(volume0>volume1)?volume0:volume1;
value1=value0;
if (volume0==0) control0=0;
if (volume1==0) control1=0;
drvcmd[0]=CMD1_SETMODE;
drvcmd[1]=0x05;
drvcmd[3]=control0;
drvcmd[4]=value0;
drvcmd[5]=control1;
drvcmd[6]=value1;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
control0=channel0+1;
control1=channel1+1;
value0=(volume0>volume1)?volume0:volume1;
value1=value0;
if (volume0==0) control0=0;
if (volume1==0) control1=0;
drvcmd[0]=CMD2_SETMODE;
drvcmd[1]=0x0E;
drvcmd[3]=control0;
drvcmd[4]=value0;
drvcmd[5]=control1;
drvcmd[6]=value1;
flags_cmd_out=f_putcmd|f_ResponseStatus;
}
else if (famL_drive)
{
if ((volume0==0)||(channel0!=0)) control0 |= 0x80;
if ((volume1==0)||(channel1!=1)) control0 |= 0x40;
if (volume0|volume1) value0=0x80;
drvcmd[0]=CMDL_SETMODE;
drvcmd[1]=0x03;
drvcmd[4]=control0;
drvcmd[5]=value0;
flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
}
else if (fam0_drive) /* different firmware levels */
{
if (D_S[d].drv_type>=drv_300)
{
control0=volume0&0xFC;
value0=volume1&0xFC;
if ((volume0!=0)&&(volume0<4)) control0 |= 0x04;
if ((volume1!=0)&&(volume1<4)) value0 |= 0x04;
if (channel0!=0) control0 |= 0x01;
if (channel1==1) value0 |= 0x01;
}
else
{
value0=(volume0>volume1)?volume0:volume1;
if (D_S[d].drv_type<drv_211)
{
if (channel0!=0)
{
i=channel1;
channel1=channel0;
channel0=i;
i=volume1;
volume1=volume0;
volume0=i;
}
if (channel0==channel1)
{
if (channel0==0)
{
channel1=1;
volume1=0;
volume0=value0;
}
else
{
channel0=0;
volume0=0;
volume1=value0;
}
}
}
if ((volume0!=0)&&(volume1!=0))
{
if (volume0==0xFF) volume1=0xFF;
else if (volume1==0xFF) volume0=0xFF;
}
else if (D_S[d].drv_type<drv_201) volume0=volume1=value0;
if (D_S[d].drv_type>=drv_201)
{
if (volume0==0) control0 |= 0x80;
if (volume1==0) control0 |= 0x40;
}
if (D_S[d].drv_type>=drv_211)
{
if (channel0!=0) control0 |= 0x20;
if (channel1!=1) control0 |= 0x10;
}
}
drvcmd[0]=CMD0_SETMODE;
drvcmd[1]=0x83;
drvcmd[4]=control0;
drvcmd[5]=value0;
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
}
else if (famT_drive)
{
D_S[d].volume_control=0;
if (!volume0) D_S[d].volume_control|=0x10;
if (!volume1) D_S[d].volume_control|=0x20;
i=cc_prep_mode_T();
if (i<0) return (i);
}
if (!famT_drive)
{
response_count=0;
i=cmd_out();
if (i<0) return (i);
}
D_S[d].diskstate_flags |= volume_bit;
return (0);
}
/*==========================================================================*/
static int GetStatus(void)
{
int i;
if (famT_drive) return (0);
flags_cmd_out=f_getsta|f_ResponseStatus|f_obey_p_check;
response_count=0;
cmd_type=0;
i=cmd_out();
return (i);
}
/*==========================================================================*/
static int cc_DriveReset(void)
{
int i;
msg(DBG_RES,"cc_DriveReset called.\n");
clr_cmdbuf();
response_count=0;
if (fam0LV_drive) OUT(CDo_reset,0x00);
else if (fam1_drive)
{
drvcmd[0]=CMD1_RESET;
flags_cmd_out=f_putcmd;
i=cmd_out();
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_RESET;
flags_cmd_out=f_putcmd;
i=cmd_out();
OUT(CDo_reset,0x00);
}
else if (famT_drive)
{
OUT(CDo_sel_i_d,0);
OUT(CDo_enable,D_S[d].drv_sel);
OUT(CDo_command,CMDT_RESET);
for (i=1;i<10;i++) OUT(CDo_command,0);
}
if (fam0LV_drive) sbp_sleep(5*HZ); /* wait 5 seconds */
else sbp_sleep(1*HZ); /* wait a second */
#if 1
if (famT_drive)
{
msg(DBG_TEA, "================CMDT_RESET given=================.\n");
sbp_sleep(3*HZ);
}
#endif /* 1 */
flush_status();
i=GetStatus();
if (i<0) return i;
if (!famT_drive)
if (D_S[d].error_byte!=aud_12) return -501;
return (0);
}
/*==========================================================================*/
static int SetSpeed(void)
{
int i, speed;
if (!(D_S[d].drv_options&(speed_auto|speed_300|speed_150))) return (0);
speed=speed_auto;
if (!(D_S[d].drv_options&speed_auto))
{
speed |= speed_300;
if (!(D_S[d].drv_options&speed_300)) speed=0;
}
i=cc_SetSpeed(speed,0,0);
return (i);
}
static void switch_drive(int i);
static int sbpcd_select_speed(struct cdrom_device_info *cdi, int speed)
{
int i = MINOR(cdi->dev);
if (i != d)
switch_drive(i);
return cc_SetSpeed(speed == 2 ? speed_300 : speed_150, 0, 0);
}
/*==========================================================================*/
static int DriveReset(void)
{
int i;
i=cc_DriveReset();
if (i<0) return (-22);
do
{
i=GetStatus();
if ((i<0)&&(i!=-ERR_DISKCHANGE)) {
return (-2); /* from sta2err */
}
if (!st_caddy_in) break;
sbp_sleep(1);
}
while (!st_diskok);
#if 000
D_S[d].CD_changed=1;
#endif
if ((st_door_closed) && (st_caddy_in))
{
i=DiskInfo();
if (i<0) return (-23);
}
return (0);
}
static int sbpcd_reset(struct cdrom_device_info *cdi)
{
int i = MINOR(cdi->dev);
if (i != d)
switch_drive(i);
return DriveReset();
}
/*==========================================================================*/
static int cc_PlayAudio(int pos_audio_start,int pos_audio_end)
{
int i, j, n;
if (D_S[d].audio_state==audio_playing) return (-EINVAL);
clr_cmdbuf();
response_count=0;
if (famLV_drive)
{
drvcmd[0]=CMDL_PLAY;
i=msf2blk(pos_audio_start);
n=msf2blk(pos_audio_end)+1-i;
drvcmd[1]=(i>>16)&0x00FF;
drvcmd[2]=(i>>8)&0x00FF;
drvcmd[3]=i&0x00FF;
drvcmd[4]=(n>>16)&0x00FF;
drvcmd[5]=(n>>8)&0x00FF;
drvcmd[6]=n&0x00FF;
if (famL_drive)
flags_cmd_out = f_putcmd | f_respo2 | f_lopsta | f_getsta |
f_ResponseStatus | f_obey_p_check | f_wait_if_busy;
else
flags_cmd_out = f_putcmd;
}
else
{
j=1;
if (fam1_drive)
{
drvcmd[0]=CMD1_PLAY_MSF;
flags_cmd_out = f_putcmd | f_respo2 | f_ResponseStatus |
f_obey_p_check | f_wait_if_busy;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_PLAY_MSF;
flags_cmd_out = f_putcmd | f_ResponseStatus | f_obey_p_check;
}
else if (famT_drive)
{
drvcmd[0]=CMDT_PLAY_MSF;
j=3;
response_count=1;
}
else if (fam0_drive)
{
drvcmd[0]=CMD0_PLAY_MSF;
flags_cmd_out = f_putcmd | f_respo2 | f_lopsta | f_getsta |
f_ResponseStatus | f_obey_p_check | f_wait_if_busy;
}
drvcmd[j]=(pos_audio_start>>16)&0x00FF;
drvcmd[j+1]=(pos_audio_start>>8)&0x00FF;
drvcmd[j+2]=pos_audio_start&0x00FF;
drvcmd[j+3]=(pos_audio_end>>16)&0x00FF;
drvcmd[j+4]=(pos_audio_end>>8)&0x00FF;
drvcmd[j+5]=pos_audio_end&0x00FF;
}
i=cmd_out();
return (i);
}
/*==========================================================================*/
static int cc_Pause_Resume(int pau_res)
{
int i;
clr_cmdbuf();
response_count=0;
if (fam1_drive)
{
drvcmd[0]=CMD1_PAU_RES;
if (pau_res!=1) drvcmd[1]=0x80;
flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_PAU_RES;
if (pau_res!=1) drvcmd[2]=0x01;
flags_cmd_out=f_putcmd|f_ResponseStatus;
}
else if (fam0LV_drive)
{
drvcmd[0]=CMD0_PAU_RES;
if (pau_res!=1) drvcmd[1]=0x80;
if (famL_drive)
flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|
f_obey_p_check|f_bit1;
else if (famV_drive)
flags_cmd_out=f_putcmd;
else
flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|
f_obey_p_check;
}
else if (famT_drive)
{
if (pau_res==3) return (cc_PlayAudio(D_S[d].pos_audio_start,D_S[d].pos_audio_end));
else if (pau_res==1) drvcmd[0]=CMDT_PAUSE;
else return (-56);
}
i=cmd_out();
return (i);
}
/*==========================================================================*/
static int cc_LockDoor(char lock)
{
int i;
if (fam0_drive) return (0);
msg(DBG_LCK,"cc_LockDoor: %d (drive %d)\n", lock, d);
msg(DBG_LCS,"p_door_locked bit %d before\n", st_door_locked);
clr_cmdbuf();
response_count=0;
if (fam1_drive)
{
drvcmd[0]=CMD1_LOCK_CTL;
if (lock==1) drvcmd[1]=0x01;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_LOCK_CTL;
if (lock==1) drvcmd[4]=0x01;
flags_cmd_out=f_putcmd|f_ResponseStatus;
}
else if (famLV_drive)
{
drvcmd[0]=CMDL_LOCK_CTL;
if (lock==1) drvcmd[1]=0x01;
if (famL_drive)
flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
else
flags_cmd_out=f_putcmd;
}
else if (famT_drive)
{
drvcmd[0]=CMDT_LOCK_CTL;
if (lock==1) drvcmd[4]=0x01;
}
i=cmd_out();
msg(DBG_LCS,"p_door_locked bit %d after\n", st_door_locked);
return (i);
}
/*==========================================================================*/
/*==========================================================================*/
static int UnLockDoor(void)
{
int i,j;
j=20;
do
{
i=cc_LockDoor(0);
--j;
sbp_sleep(1);
}
while ((i<0)&&(j));
if (i<0)
{
cc_DriveReset();
return -84;
}
return (0);
}
/*==========================================================================*/
static int LockDoor(void)
{
int i,j;
j=20;
do
{
i=cc_LockDoor(1);
--j;
sbp_sleep(1);
}
while ((i<0)&&(j));
if (j==0)
{
cc_DriveReset();
j=20;
do
{
i=cc_LockDoor(1);
--j;
sbp_sleep(1);
}
while ((i<0)&&(j));
}
return (i);
}
static int sbpcd_lock_door(struct cdrom_device_info *cdi, int lock)
{
return lock ? LockDoor() : UnLockDoor();
}
/*==========================================================================*/
static int cc_CloseTray(void)
{
int i;
if (fam0_drive) return (0);
msg(DBG_LCK,"cc_CloseTray (drive %d)\n", d);
msg(DBG_LCS,"p_door_closed bit %d before\n", st_door_closed);
clr_cmdbuf();
response_count=0;
if (fam1_drive)
{
drvcmd[0]=CMD1_TRAY_CTL;
flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_TRAY_CTL;
drvcmd[1]=0x01;
drvcmd[4]=0x03; /* "insert" */
flags_cmd_out=f_putcmd|f_ResponseStatus;
}
else if (famLV_drive)
{
drvcmd[0]=CMDL_TRAY_CTL;
if (famLV_drive)
flags_cmd_out=f_putcmd|f_respo2|f_lopsta|f_getsta|
f_ResponseStatus|f_obey_p_check|f_bit1;
else
flags_cmd_out=f_putcmd;
}
else if (famT_drive)
{
drvcmd[0]=CMDT_TRAY_CTL;
drvcmd[4]=0x03; /* "insert" */
}
i=cmd_out();
msg(DBG_LCS,"p_door_closed bit %d after\n", st_door_closed);
i=cc_ReadError();
flags_cmd_out |= f_respo2;
cc_ReadStatus(); /* command: give 1-byte status */
i=ResponseStatus();
if (famT_drive&&(i<0))
{
cc_DriveReset();
i=ResponseStatus();
#if 0
sbp_sleep(HZ);
#endif /* 0 */
i=ResponseStatus();
}
if (i<0)
{
msg(DBG_INF,"sbpcd cc_CloseTray: ResponseStatus timed out (%d).\n",i);
}
if (!(famT_drive))
{
if (!st_spinning)
{
cc_SpinUp();
if (st_check) i=cc_ReadError();
flags_cmd_out |= f_respo2;
cc_ReadStatus();
i=ResponseStatus();
} else {
}
}
i=DiskInfo();
return (i);
}
static int sbpcd_tray_move(struct cdrom_device_info *cdi, int position)
{
int i;
int retval=0;
i = MINOR(cdi->dev);
switch_drive(i);
/* DUH! --AJK */
if(D_S[d].CD_changed != 0xFF) {
D_S[d].CD_changed=0xFF;
D_S[d].diskstate_flags &= ~cd_size_bit;
}
if (position == 1) {
cc_SpinDown();
} else {
retval=cc_CloseTray();
}
return retval;
}
/*==========================================================================*/
static int cc_ReadSubQ(void)
{
int i,j;
D_S[d].diskstate_flags &= ~subq_bit;
for (j=255;j>0;j--)
{
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_READSUBQ;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
response_count=11;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_READSUBQ;
drvcmd[1]=0x02;
drvcmd[3]=0x01;
flags_cmd_out=f_putcmd;
response_count=10;
}
else if (fam0LV_drive)
{
drvcmd[0]=CMD0_READSUBQ;
drvcmd[1]=0x02;
if (famLV_drive)
flags_cmd_out=f_putcmd;
else
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
response_count=13;
}
else if (famT_drive)
{
response_count=12;
drvcmd[0]=CMDT_READSUBQ;
drvcmd[1]=0x02;
drvcmd[2]=0x40;
drvcmd[3]=0x01;
drvcmd[8]=response_count;
}
i=cmd_out();
if (i<0) return (i);
for (i=0;i<response_count;i++)
{
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_SQ1,"cc_ReadSubQ:%s\n", msgbuf);
}
if (famT_drive) break;
if (infobuf[0]!=0) break;
if ((!st_spinning) || (j==1))
{
D_S[d].SubQ_ctl_adr=D_S[d].SubQ_trk=D_S[d].SubQ_pnt_idx=D_S[d].SubQ_whatisthis=0;
D_S[d].SubQ_run_tot=D_S[d].SubQ_run_trk=0;
return (0);
}
}
if (famT_drive) D_S[d].SubQ_ctl_adr=infobuf[1];
else D_S[d].SubQ_ctl_adr=swap_nibbles(infobuf[1]);
D_S[d].SubQ_trk=byt2bcd(infobuf[2]);
D_S[d].SubQ_pnt_idx=byt2bcd(infobuf[3]);
if (fam0LV_drive) i=5;
else if (fam12_drive) i=4;
else if (famT_drive) i=8;
D_S[d].SubQ_run_tot=make32(make16(0,infobuf[i]),make16(infobuf[i+1],infobuf[i+2])); /* msf-bin */
i=7;
if (fam0LV_drive) i=9;
else if (fam12_drive) i=7;
else if (famT_drive) i=4;
D_S[d].SubQ_run_trk=make32(make16(0,infobuf[i]),make16(infobuf[i+1],infobuf[i+2])); /* msf-bin */
D_S[d].SubQ_whatisthis=infobuf[i+3];
D_S[d].diskstate_flags |= subq_bit;
return (0);
}
/*==========================================================================*/
static int cc_ModeSense(void)
{
int i;
if (fam2_drive) return (0);
if (famV_drive) return (0);
D_S[d].diskstate_flags &= ~frame_size_bit;
clr_cmdbuf();
if (fam1_drive)
{
response_count=5;
drvcmd[0]=CMD1_GETMODE;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam0L_drive)
{
response_count=2;
drvcmd[0]=CMD0_GETMODE;
if (famL_drive) flags_cmd_out=f_putcmd;
else flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
}
else if (famT_drive)
{
response_count=10;
drvcmd[0]=CMDT_GETMODE;
drvcmd[4]=response_count;
}
i=cmd_out();
if (i<0) return (i);
i=0;
D_S[d].sense_byte=0;
if (fam1_drive) D_S[d].sense_byte=infobuf[i++];
else if (famT_drive)
{
if (infobuf[4]==0x01) D_S[d].xa_byte=0x20;
else D_S[d].xa_byte=0;
i=2;
}
D_S[d].frame_size=make16(infobuf[i],infobuf[i+1]);
for (i=0;i<response_count;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_XA1,"cc_ModeSense:%s\n", msgbuf);
D_S[d].diskstate_flags |= frame_size_bit;
return (0);
}
/*==========================================================================*/
/*==========================================================================*/
static int cc_ModeSelect(int framesize)
{
int i;
if (fam2_drive) return (0);
if (famV_drive) return (0);
D_S[d].diskstate_flags &= ~frame_size_bit;
clr_cmdbuf();
D_S[d].frame_size=framesize;
if (framesize==CD_FRAMESIZE_RAW) D_S[d].sense_byte=0x82;
else D_S[d].sense_byte=0x00;
msg(DBG_XA1,"cc_ModeSelect: %02X %04X\n",
D_S[d].sense_byte, D_S[d].frame_size);
if (fam1_drive)
{
drvcmd[0]=CMD1_SETMODE;
drvcmd[1]=0x00;
drvcmd[2]=D_S[d].sense_byte;
drvcmd[3]=(D_S[d].frame_size>>8)&0xFF;
drvcmd[4]=D_S[d].frame_size&0xFF;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam0L_drive)
{
drvcmd[0]=CMD0_SETMODE;
drvcmd[1]=0x00;
drvcmd[2]=(D_S[d].frame_size>>8)&0xFF;
drvcmd[3]=D_S[d].frame_size&0xFF;
drvcmd[4]=0x00;
if(famL_drive)
flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check;
else
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
}
else if (famT_drive)
{
return (-1);
}
response_count=0;
i=cmd_out();
if (i<0) return (i);
D_S[d].diskstate_flags |= frame_size_bit;
return (0);
}
/*==========================================================================*/
static int cc_GetVolume(void)
{
int i;
u_char switches;
u_char chan0=0;
u_char vol0=0;
u_char chan1=1;
u_char vol1=0;
if (famV_drive) return (0);
D_S[d].diskstate_flags &= ~volume_bit;
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_GETMODE;
drvcmd[1]=0x05;
response_count=5;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_GETMODE;
drvcmd[1]=0x0E;
response_count=5;
flags_cmd_out=f_putcmd;
}
else if (fam0L_drive)
{
drvcmd[0]=CMD0_GETMODE;
drvcmd[1]=0x03;
response_count=2;
if(famL_drive)
flags_cmd_out=f_putcmd;
else
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
}
else if (famT_drive)
{
i=cc_get_mode_T();
if (i<0) return (i);
}
if (!famT_drive)
{
i=cmd_out();
if (i<0) return (i);
}
if (fam1_drive)
{
chan0=infobuf[1]&0x0F;
vol0=infobuf[2];
chan1=infobuf[3]&0x0F;
vol1=infobuf[4];
if (chan0==0)
{
chan0=1;
vol0=0;
}
if (chan1==0)
{
chan1=2;
vol1=0;
}
chan0 >>= 1;
chan1 >>= 1;
}
else if (fam2_drive)
{
chan0=infobuf[1];
vol0=infobuf[2];
chan1=infobuf[3];
vol1=infobuf[4];
}
else if (famL_drive)
{
chan0=0;
chan1=1;
vol0=vol1=infobuf[1];
switches=infobuf[0];
if ((switches&0x80)!=0) chan0=1;
if ((switches&0x40)!=0) chan1=0;
}
else if (fam0_drive) /* different firmware levels */
{
chan0=0;
chan1=1;
vol0=vol1=infobuf[1];
if (D_S[d].drv_type>=drv_201)
{
if (D_S[d].drv_type<drv_300)
{
switches=infobuf[0];
if ((switches&0x80)!=0) vol0=0;
if ((switches&0x40)!=0) vol1=0;
if (D_S[d].drv_type>=drv_211)
{
if ((switches&0x20)!=0) chan0=1;
if ((switches&0x10)!=0) chan1=0;
}
}
else
{
vol0=infobuf[0];
if ((vol0&0x01)!=0) chan0=1;
if ((vol1&0x01)==0) chan1=0;
vol0 &= 0xFC;
vol1 &= 0xFC;
if (vol0!=0) vol0 += 3;
if (vol1!=0) vol1 += 3;
}
}
}
else if (famT_drive)
{
D_S[d].volume_control=infobuf[7];
chan0=0;
chan1=1;
if (D_S[d].volume_control&0x10) vol0=0;
else vol0=0xff;
if (D_S[d].volume_control&0x20) vol1=0;
else vol1=0xff;
}
D_S[d].vol_chan0=chan0;
D_S[d].vol_ctrl0=vol0;
D_S[d].vol_chan1=chan1;
D_S[d].vol_ctrl1=vol1;
#if 000
D_S[d].vol_chan2=2;
D_S[d].vol_ctrl2=0xFF;
D_S[d].vol_chan3=3;
D_S[d].vol_ctrl3=0xFF;
#endif /* 000 */
D_S[d].diskstate_flags |= volume_bit;
return (0);
}
/*==========================================================================*/
static int cc_ReadCapacity(void)
{
int i, j;
if (fam2_drive) return (0); /* some firmware lacks this command */
if (famLV_drive) return (0); /* some firmware lacks this command */
if (famT_drive) return (0); /* done with cc_ReadTocDescr() */
D_S[d].diskstate_flags &= ~cd_size_bit;
for (j=3;j>0;j--)
{
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_CAPACITY;
response_count=5;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
#if 00
else if (fam2_drive)
{
drvcmd[0]=CMD2_CAPACITY;
response_count=8;
flags_cmd_out=f_putcmd;
}
#endif
else if (fam0_drive)
{
drvcmd[0]=CMD0_CAPACITY;
response_count=5;
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
}
i=cmd_out();
if (i>=0) break;
msg(DBG_000,"cc_ReadCapacity: cmd_out: err %d\n", i);
cc_ReadError();
}
if (j==0) return (i);
if (fam1_drive) D_S[d].CDsize_frm=msf2blk(make32(make16(0,infobuf[0]),make16(infobuf[1],infobuf[2])))+CD_MSF_OFFSET;
else if (fam0_drive) D_S[d].CDsize_frm=make32(make16(0,infobuf[0]),make16(infobuf[1],infobuf[2]));
#if 00
else if (fam2_drive) D_S[d].CDsize_frm=make32(make16(infobuf[0],infobuf[1]),make16(infobuf[2],infobuf[3]));
#endif
D_S[d].diskstate_flags |= cd_size_bit;
msg(DBG_000,"cc_ReadCapacity: %d frames.\n", D_S[d].CDsize_frm);
return (0);
}
/*==========================================================================*/
static int cc_ReadTocDescr(void)
{
int i;
D_S[d].diskstate_flags &= ~toc_bit;
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_DISKINFO;
response_count=6;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam0LV_drive)
{
drvcmd[0]=CMD0_DISKINFO;
response_count=6;
if(famLV_drive)
flags_cmd_out=f_putcmd;
else
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
/* possibly longer timeout periods necessary */
D_S[d].f_multisession=0;
drvcmd[0]=CMD2_DISKINFO;
drvcmd[1]=0x02;
drvcmd[2]=0xAB;
drvcmd[3]=0xFF; /* session */
response_count=8;
flags_cmd_out=f_putcmd;
}
else if (famT_drive)
{
D_S[d].f_multisession=0;
response_count=12;
drvcmd[0]=CMDT_DISKINFO;
drvcmd[1]=0x02;
drvcmd[6]=CDROM_LEADOUT;
drvcmd[8]=response_count;
drvcmd[9]=0x00;
}
i=cmd_out();
if (i<0) return (i);
if ((famT_drive)&&(i<response_count)) return (-100-i);
if ((fam1_drive)||(fam2_drive)||(fam0LV_drive))
D_S[d].xa_byte=infobuf[0];
if (fam2_drive)
{
D_S[d].first_session=infobuf[1];
D_S[d].last_session=infobuf[2];
D_S[d].n_first_track=infobuf[3];
D_S[d].n_last_track=infobuf[4];
if (D_S[d].first_session!=D_S[d].last_session)
{
D_S[d].f_multisession=1;
D_S[d].lba_multi=msf2blk(make32(make16(0,infobuf[5]),make16(infobuf[6],infobuf[7])));
}
#if 0
if (D_S[d].first_session!=D_S[d].last_session)
{
if (D_S[d].last_session<=20)
zwanzig=D_S[d].last_session+1;
else zwanzig=20;
for (count=D_S[d].first_session;count<zwanzig;count++)
{
drvcmd[0]=CMD2_DISKINFO;
drvcmd[1]=0x02;
drvcmd[2]=0xAB;
drvcmd[3]=count;
response_count=8;
flags_cmd_out=f_putcmd;
i=cmd_out();
if (i<0) return (i);
D_S[d].msf_multi_n[count]=make32(make16(0,infobuf[5]),make16(infobuf[6],infobuf[7]));
}
D_S[d].diskstate_flags |= multisession_bit;
}
#endif
drvcmd[0]=CMD2_DISKINFO;
drvcmd[1]=0x02;
drvcmd[2]=0xAA;
drvcmd[3]=0xFF;
response_count=5;
flags_cmd_out=f_putcmd;
i=cmd_out();
if (i<0) return (i);
D_S[d].size_msf=make32(make16(0,infobuf[2]),make16(infobuf[3],infobuf[4]));
D_S[d].size_blk=msf2blk(D_S[d].size_msf);
D_S[d].CDsize_frm=D_S[d].size_blk+1;
}
else if (famT_drive)
{
D_S[d].size_msf=make32(make16(infobuf[8],infobuf[9]),make16(infobuf[10],infobuf[11]));
D_S[d].size_blk=msf2blk(D_S[d].size_msf);
D_S[d].CDsize_frm=D_S[d].size_blk+1;
D_S[d].n_first_track=infobuf[2];
D_S[d].n_last_track=infobuf[3];
}
else
{
D_S[d].n_first_track=infobuf[1];
D_S[d].n_last_track=infobuf[2];
D_S[d].size_msf=make32(make16(0,infobuf[3]),make16(infobuf[4],infobuf[5]));
D_S[d].size_blk=msf2blk(D_S[d].size_msf);
if (famLV_drive) D_S[d].CDsize_frm=D_S[d].size_blk+1;
}
D_S[d].diskstate_flags |= toc_bit;
msg(DBG_TOC,"TocDesc: xa %02X firstt %02X lastt %02X size %08X firstses %02X lastsess %02X\n",
D_S[d].xa_byte,
D_S[d].n_first_track,
D_S[d].n_last_track,
D_S[d].size_msf,
D_S[d].first_session,
D_S[d].last_session);
return (0);
}
/*==========================================================================*/
static int cc_ReadTocEntry(int num)
{
int i;
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_READTOC;
drvcmd[2]=num;
response_count=8;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam2_drive)
{
/* possibly longer timeout periods necessary */
drvcmd[0]=CMD2_DISKINFO;
drvcmd[1]=0x02;
drvcmd[2]=num;
response_count=5;
flags_cmd_out=f_putcmd;
}
else if (fam0LV_drive)
{
drvcmd[0]=CMD0_READTOC;
drvcmd[1]=0x02;
drvcmd[2]=num;
response_count=8;
if (famLV_drive)
flags_cmd_out=f_putcmd;
else
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
}
else if (famT_drive)
{
response_count=12;
drvcmd[0]=CMDT_DISKINFO;
drvcmd[1]=0x02;
drvcmd[6]=num;
drvcmd[8]=response_count;
drvcmd[9]=0x00;
}
i=cmd_out();
if (i<0) return (i);
if ((famT_drive)&&(i<response_count)) return (-100-i);
if ((fam1_drive)||(fam0LV_drive))
{
D_S[d].TocEnt_nixbyte=infobuf[0];
i=1;
}
else if (fam2_drive) i=0;
else if (famT_drive) i=5;
D_S[d].TocEnt_ctl_adr=swap_nibbles(infobuf[i++]);
if ((fam1_drive)||(fam0L_drive))
{
D_S[d].TocEnt_number=infobuf[i++];
D_S[d].TocEnt_format=infobuf[i];
}
else
{
D_S[d].TocEnt_number=num;
D_S[d].TocEnt_format=0;
}
if (fam1_drive) i=4;
else if (fam0LV_drive) i=5;
else if (fam2_drive) i=2;
else if (famT_drive) i=9;
D_S[d].TocEnt_address=make32(make16(0,infobuf[i]),
make16(infobuf[i+1],infobuf[i+2]));
for (i=0;i<response_count;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_ECS,"TocEntry:%s\n", msgbuf);
msg(DBG_TOC,"TocEntry: %02X %02X %02X %02X %08X\n",
D_S[d].TocEnt_nixbyte, D_S[d].TocEnt_ctl_adr,
D_S[d].TocEnt_number, D_S[d].TocEnt_format,
D_S[d].TocEnt_address);
return (0);
}
/*==========================================================================*/
static int cc_ReadPacket(void)
{
int i;
clr_cmdbuf();
drvcmd[0]=CMD0_PACKET;
drvcmd[1]=response_count;
if(famL_drive) flags_cmd_out=f_putcmd;
else if (fam01_drive)
flags_cmd_out=f_putcmd|f_getsta|f_ResponseStatus|f_obey_p_check;
else if (fam2_drive) return (-1); /* not implemented yet */
else if (famT_drive)
{
return (-1);
}
i=cmd_out();
return (i);
}
/*==========================================================================*/
static int convert_UPC(u_char *p)
{
int i;
p++;
if (fam0L_drive) p[13]=0;
for (i=0;i<7;i++)
{
if (fam1_drive) D_S[d].UPC_buf[i]=swap_nibbles(*p++);
else if (fam0L_drive)
{
D_S[d].UPC_buf[i]=((*p++)<<4)&0xFF;
D_S[d].UPC_buf[i] |= *p++;
}
else if (famT_drive)
{
return (-1);
}
else /* CD200 */
{
return (-1);
}
}
D_S[d].UPC_buf[6] &= 0xF0;
return (0);
}
/*==========================================================================*/
static int cc_ReadUPC(void)
{
int i;
#if TEST_UPC
int block, checksum;
#endif /* TEST_UPC */
if (fam2_drive) return (0); /* not implemented yet */
if (famT_drive) return (0); /* not implemented yet */
if (famV_drive) return (0); /* not implemented yet */
#if 1
if (fam0_drive) return (0); /* but it should work */
#endif
D_S[d].diskstate_flags &= ~upc_bit;
#if TEST_UPC
for (block=CD_MSF_OFFSET+1;block<CD_MSF_OFFSET+200;block++)
{
#endif /* TEST_UPC */
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_READ_UPC;
#if TEST_UPC
drvcmd[1]=(block>>16)&0xFF;
drvcmd[2]=(block>>8)&0xFF;
drvcmd[3]=block&0xFF;
#endif /* TEST_UPC */
response_count=8;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam0L_drive)
{
drvcmd[0]=CMD0_READ_UPC;
#if TEST_UPC
drvcmd[2]=(block>>16)&0xFF;
drvcmd[3]=(block>>8)&0xFF;
drvcmd[4]=block&0xFF;
#endif /* TEST_UPC */
response_count=0;
flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
}
else if (fam2_drive)
{
return (-1);
}
else if (famT_drive)
{
return (-1);
}
i=cmd_out();
if (i<0)
{
msg(DBG_000,"cc_ReadUPC cmd_out: err %d\n", i);
return (i);
}
if (fam0L_drive)
{
response_count=16;
if (famL_drive) flags_cmd_out=f_putcmd;
i=cc_ReadPacket();
if (i<0)
{
msg(DBG_000,"cc_ReadUPC ReadPacket: err %d\n", i);
return (i);
}
}
#if TEST_UPC
checksum=0;
#endif /* TEST_UPC */
for (i=0;i<(fam1_drive?8:16);i++)
{
#if TEST_UPC
checksum |= infobuf[i];
#endif /* TEST_UPC */
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
}
msgbuf[i*3]=0;
msg(DBG_UPC,"UPC info:%s\n", msgbuf);
#if TEST_UPC
if ((checksum&0x7F)!=0) break;
}
#endif /* TEST_UPC */
D_S[d].UPC_ctl_adr=0;
if (fam1_drive) i=0;
else i=2;
if ((infobuf[i]&0x80)!=0)
{
convert_UPC(&infobuf[i]);
D_S[d].UPC_ctl_adr = (D_S[d].TocEnt_ctl_adr & 0xF0) | 0x02;
}
for (i=0;i<7;i++)
sprintf(&msgbuf[i*3], " %02X", D_S[d].UPC_buf[i]);
sprintf(&msgbuf[i*3], " (%02X)", D_S[d].UPC_ctl_adr);
msgbuf[i*3+5]=0;
msg(DBG_UPC,"UPC code:%s\n", msgbuf);
D_S[d].diskstate_flags |= upc_bit;
return (0);
}
static int sbpcd_get_mcn(struct cdrom_device_info *cdi, struct cdrom_mcn *mcn)
{
int i;
unsigned char *mcnp = mcn->medium_catalog_number;
unsigned char *resp;
D_S[d].diskstate_flags &= ~upc_bit;
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_READ_UPC;
response_count=8;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
}
else if (fam0L_drive)
{
drvcmd[0]=CMD0_READ_UPC;
response_count=0;
flags_cmd_out=f_putcmd|f_lopsta|f_getsta|f_ResponseStatus|f_obey_p_check|f_bit1;
}
else if (fam2_drive)
{
return (-1);
}
else if (famT_drive)
{
return (-1);
}
i=cmd_out();
if (i<0)
{
msg(DBG_000,"cc_ReadUPC cmd_out: err %d\n", i);
return (i);
}
if (fam0L_drive)
{
response_count=16;
if (famL_drive) flags_cmd_out=f_putcmd;
i=cc_ReadPacket();
if (i<0)
{
msg(DBG_000,"cc_ReadUPC ReadPacket: err %d\n", i);
return (i);
}
}
D_S[d].UPC_ctl_adr=0;
if (fam1_drive) i=0;
else i=2;
resp = infobuf + i;
if (*resp++ == 0x80) {
/* packed bcd to single ASCII digits */
*mcnp++ = (*resp >> 4) + '0';
*mcnp++ = (*resp++ & 0x0f) + '0';
*mcnp++ = (*resp >> 4) + '0';
*mcnp++ = (*resp++ & 0x0f) + '0';
*mcnp++ = (*resp >> 4) + '0';
*mcnp++ = (*resp++ & 0x0f) + '0';
*mcnp++ = (*resp >> 4) + '0';
*mcnp++ = (*resp++ & 0x0f) + '0';
*mcnp++ = (*resp >> 4) + '0';
*mcnp++ = (*resp++ & 0x0f) + '0';
*mcnp++ = (*resp >> 4) + '0';
*mcnp++ = (*resp++ & 0x0f) + '0';
*mcnp++ = (*resp >> 4) + '0';
}
*mcnp = '\0';
D_S[d].diskstate_flags |= upc_bit;
return (0);
}
/*==========================================================================*/
static int cc_CheckMultiSession(void)
{
int i;
if (fam2_drive) return (0);
D_S[d].f_multisession=0;
D_S[d].lba_multi=0;
if (fam0_drive) return (0);
clr_cmdbuf();
if (fam1_drive)
{
drvcmd[0]=CMD1_MULTISESS;
response_count=6;
flags_cmd_out=f_putcmd|f_ResponseStatus|f_obey_p_check;
i=cmd_out();
if (i<0) return (i);
if ((infobuf[0]&0x80)!=0)
{
D_S[d].f_multisession=1;
D_S[d].lba_multi=msf2blk(make32(make16(0,infobuf[1]),
make16(infobuf[2],infobuf[3])));
}
}
else if (famLV_drive)
{
drvcmd[0]=CMDL_MULTISESS;
drvcmd[1]=3;
drvcmd[2]=1;
response_count=8;
flags_cmd_out=f_putcmd;
i=cmd_out();
if (i<0) return (i);
D_S[d].lba_multi=msf2blk(make32(make16(0,infobuf[5]),
make16(infobuf[6],infobuf[7])));
}
else if (famT_drive)
{
response_count=12;
drvcmd[0]=CMDT_DISKINFO;
drvcmd[1]=0x02;
drvcmd[6]=0;
drvcmd[8]=response_count;
drvcmd[9]=0x40;
i=cmd_out();
if (i<0) return (i);
if (i<response_count) return (-100-i);
D_S[d].first_session=infobuf[2];
D_S[d].last_session=infobuf[3];
D_S[d].track_of_last_session=infobuf[6];
if (D_S[d].first_session!=D_S[d].last_session)
{
D_S[d].f_multisession=1;
D_S[d].lba_multi=msf2blk(make32(make16(0,infobuf[9]),make16(infobuf[10],infobuf[11])));
}
}
for (i=0;i<response_count;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_MUL,"MultiSession Info:%s (%d)\n", msgbuf, D_S[d].lba_multi);
if (D_S[d].lba_multi>200)
{
D_S[d].f_multisession=1;
msg(DBG_MUL,"MultiSession base: %06X\n", D_S[d].lba_multi);
}
return (0);
}
/*==========================================================================*/
#if FUTURE
static int cc_SubChanInfo(int frame, int count, u_char *buffer)
/* "frame" is a RED BOOK (msf-bin) address */
{
int i;
if (fam0LV_drive) return (-ENOSYS); /* drive firmware lacks it */
if (famT_drive)
{
return (-1);
}
#if 0
if (D_S[d].audio_state!=audio_playing) return (-ENODATA);
#endif
clr_cmdbuf();
drvcmd[0]=CMD1_SUBCHANINF;
drvcmd[1]=(frame>>16)&0xFF;
drvcmd[2]=(frame>>8)&0xFF;
drvcmd[3]=frame&0xFF;
drvcmd[5]=(count>>8)&0xFF;
drvcmd[6]=count&0xFF;
flags_cmd_out=f_putcmd|f_respo2|f_ResponseStatus|f_obey_p_check;
cmd_type=READ_SC;
D_S[d].frame_size=CD_FRAMESIZE_SUB;
i=cmd_out(); /* which buffer to use? */
return (i);
}
#endif /* FUTURE */
/*==========================================================================*/
static void __init check_datarate(void)
{
int i=0;
msg(DBG_IOX,"check_datarate entered.\n");
datarate=0;
#if TEST_STI
for (i=0;i<=1000;i++) printk(".");
#endif
/* set a timer to make (timed_out_delay!=0) after 1.1 seconds */
#if 1
del_timer(&delay_timer);
#endif
delay_timer.expires=jiffies+11*HZ/10;
timed_out_delay=0;
add_timer(&delay_timer);
#if 0
msg(DBG_TIM,"delay timer started (11*HZ/10).\n");
#endif
do
{
i=inb(CDi_status);
datarate++;
#if 1
if (datarate>0x6FFFFFFF) break;
#endif
}
while (!timed_out_delay);
del_timer(&delay_timer);
#if 0
msg(DBG_TIM,"datarate: %04X\n", datarate);
#endif
if (datarate<65536) datarate=65536;
maxtim16=datarate*16;
maxtim04=datarate*4;
maxtim02=datarate*2;
maxtim_8=datarate/32;
#if LONG_TIMING
maxtim_data=datarate/100;
#else
maxtim_data=datarate/300;
#endif /* LONG_TIMING */
#if 0
msg(DBG_TIM,"maxtim_8 %d, maxtim_data %d.\n", maxtim_8, maxtim_data);
#endif
}
/*==========================================================================*/
#if 0
static int c2_ReadError(int fam)
{
int i;
clr_cmdbuf();
response_count=9;
clr_respo_buf(9);
if (fam==1)
{
drvcmd[0]=CMD0_READ_ERR; /* same as CMD1_ and CMDL_ */
i=do_cmd(f_putcmd|f_lopsta|f_getsta|f_ResponseStatus);
}
else if (fam==2)
{
drvcmd[0]=CMD2_READ_ERR;
i=do_cmd(f_putcmd);
}
else return (-1);
return (i);
}
#endif
/*==========================================================================*/
static void __init ask_mail(void)
{
int i;
msg(DBG_INF, "please mail the following lines to emoenke@gwdg.de\n");
msg(DBG_INF, "(don't mail if you are not using the actual kernel):\n");
msg(DBG_INF, "%s\n", VERSION);
msg(DBG_INF, "address %03X, type %s, drive %s (ID %d)\n",
CDo_command, type, D_S[d].drive_model, D_S[d].drv_id);
for (i=0;i<12;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_INF,"infobuf =%s\n", msgbuf);
for (i=0;i<12;i++)
sprintf(&msgbuf[i*3], " %c ", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_INF,"infobuf =%s\n", msgbuf);
}
/*==========================================================================*/
static int __init check_version(void)
{
int i, j, l;
int teac_possible=0;
msg(DBG_INI,"check_version: id=%d, d=%d.\n", D_S[d].drv_id, d);
D_S[d].drv_type=0;
/* check for CR-52x, CR-56x, LCS-7260 and ECS-AT */
/* clear any pending error state */
clr_cmdbuf();
drvcmd[0]=CMD0_READ_ERR; /* same as CMD1_ and CMDL_ */
response_count=9;
flags_cmd_out=f_putcmd;
i=cmd_out();
if (i<0) msg(DBG_INI,"CMD0_READ_ERR returns %d (ok anyway).\n",i);
/* read drive version */
clr_cmdbuf();
for (i=0;i<12;i++) infobuf[i]=0;
drvcmd[0]=CMD0_READ_VER; /* same as CMD1_ and CMDL_ */
response_count=12; /* fam1: only 11 */
flags_cmd_out=f_putcmd;
i=cmd_out();
if (i<-1) msg(DBG_INI,"CMD0_READ_VER returns %d\n",i);
if (i==-11) teac_possible++;
j=0;
for (i=0;i<12;i++) j+=infobuf[i];
if (j)
{
for (i=0;i<12;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_ECS,"infobuf =%s\n", msgbuf);
for (i=0;i<12;i++)
sprintf(&msgbuf[i*3], " %c ", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_ECS,"infobuf =%s\n", msgbuf);
}
for (i=0;i<4;i++) if (infobuf[i]!=family1[i]) break;
if (i==4)
{
D_S[d].drive_model[0]='C';
D_S[d].drive_model[1]='R';
D_S[d].drive_model[2]='-';
D_S[d].drive_model[3]='5';
D_S[d].drive_model[4]=infobuf[i++];
D_S[d].drive_model[5]=infobuf[i++];
D_S[d].drive_model[6]=0;
D_S[d].drv_type=drv_fam1;
}
if (!D_S[d].drv_type)
{
for (i=0;i<8;i++) if (infobuf[i]!=family0[i]) break;
if (i==8)
{
D_S[d].drive_model[0]='C';
D_S[d].drive_model[1]='R';
D_S[d].drive_model[2]='-';
D_S[d].drive_model[3]='5';
D_S[d].drive_model[4]='2';
D_S[d].drive_model[5]='x';
D_S[d].drive_model[6]=0;
D_S[d].drv_type=drv_fam0;
}
}
if (!D_S[d].drv_type)
{
for (i=0;i<8;i++) if (infobuf[i]!=familyL[i]) break;
if (i==8)
{
for (j=0;j<8;j++)
D_S[d].drive_model[j]=infobuf[j];
D_S[d].drive_model[8]=0;
D_S[d].drv_type=drv_famL;
}
}
if (!D_S[d].drv_type)
{
for (i=0;i<6;i++) if (infobuf[i]!=familyV[i]) break;
if (i==6)
{
for (j=0;j<6;j++)
D_S[d].drive_model[j]=infobuf[j];
D_S[d].drive_model[6]=0;
D_S[d].drv_type=drv_famV;
i+=2; /* 2 blanks before version */
}
}
if (!D_S[d].drv_type)
{
/* check for CD200 */
clr_cmdbuf();
drvcmd[0]=CMD2_READ_ERR;
response_count=9;
flags_cmd_out=f_putcmd;
i=cmd_out();
if (i<0) msg(DBG_INI,"CMD2_READERR returns %d (ok anyway).\n",i);
if (i<0) msg(DBG_000,"CMD2_READERR returns %d (ok anyway).\n",i);
/* read drive version */
clr_cmdbuf();
for (i=0;i<12;i++) infobuf[i]=0;
if (sbpro_type==1) OUT(CDo_sel_i_d,0);
#if 0
OUT(CDo_reset,0);
sbp_sleep(6*HZ);
OUT(CDo_enable,D_S[d].drv_sel);
#endif
drvcmd[0]=CMD2_READ_VER;
response_count=12;
flags_cmd_out=f_putcmd;
i=cmd_out();
if (i<0) msg(DBG_INI,"CMD2_READ_VER returns %d\n",i);
if (i==-7) teac_possible++;
j=0;
for (i=0;i<12;i++) j+=infobuf[i];
if (j)
{
for (i=0;i<12;i++)
sprintf(&msgbuf[i*3], " %02X", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_IDX,"infobuf =%s\n", msgbuf);
for (i=0;i<12;i++)
sprintf(&msgbuf[i*3], " %c ", infobuf[i]);
msgbuf[i*3]=0;
msg(DBG_IDX,"infobuf =%s\n", msgbuf);
}
if (i>=0)
{
for (i=0;i<5;i++) if (infobuf[i]!=family2[i]) break;
if (i==5)
{
D_S[d].drive_model[0]='C';
D_S[d].drive_model[1]='D';
D_S[d].drive_model[2]='2';
D_S[d].drive_model[3]='0';
D_S[d].drive_model[4]='0';
D_S[d].drive_model[5]=infobuf[i++];
D_S[d].drive_model[6]=infobuf[i++];
D_S[d].drive_model[7]=0;
D_S[d].drv_type=drv_fam2;
}
}
}
if (!D_S[d].drv_type)
{
/* check for TEAC CD-55A */
msg(DBG_TEA,"teac_possible: %d\n",teac_possible);
for (j=1;j<=((D_S[d].drv_id==0)?3:1);j++)
{
for (l=1;l<=((D_S[d].drv_id==0)?10:1);l++)
{
msg(DBG_TEA,"TEAC reset #%d-%d.\n", j, l);
if (sbpro_type==1) OUT(CDo_reset,0);
else
{
OUT(CDo_enable,D_S[d].drv_sel);
OUT(CDo_sel_i_d,0);
OUT(CDo_command,CMDT_RESET);
for (i=0;i<9;i++) OUT(CDo_command,0);
}
sbp_sleep(5*HZ/10);
OUT(CDo_enable,D_S[d].drv_sel);
OUT(CDo_sel_i_d,0);
i=inb(CDi_status);
msg(DBG_TEA,"TEAC CDi_status: %02X.\n",i);
#if 0
if (i&s_not_result_ready) continue; /* drive not present or ready */
#endif
i=inb(CDi_info);
msg(DBG_TEA,"TEAC CDi_info: %02X.\n",i);
if (i==0x55) break; /* drive found */
}
if (i==0x55) break; /* drive found */
}
if (i==0x55) /* drive found */
{
msg(DBG_TEA,"TEAC drive found.\n");
clr_cmdbuf();
flags_cmd_out=f_putcmd;
response_count=12;
drvcmd[0]=CMDT_READ_VER;
drvcmd[4]=response_count;
for (i=0;i<12;i++) infobuf[i]=0;
i=cmd_out_T();
if (i!=0) msg(DBG_TEA,"cmd_out_T(CMDT_READ_VER) returns %d.\n",i);
for (i=1;i<6;i++) if (infobuf[i]!=familyT[i-1]) break;
if (i==6)
{
D_S[d].drive_model[0]='C';
D_S[d].drive_model[1]='D';
D_S[d].drive_model[2]='-';
D_S[d].drive_model[3]='5';
D_S[d].drive_model[4]='5';
D_S[d].drive_model[5]=0;
D_S[d].drv_type=drv_famT;
}
}
}
if (!D_S[d].drv_type)
{
msg(DBG_TEA,"no drive found at address %03X under ID %d.\n",CDo_command,D_S[d].drv_id);
return (-522);
}
for (j=0;j<4;j++) D_S[d].firmware_version[j]=infobuf[i+j];
if (famL_drive)
{
u_char lcs_firm_e1[]="A E1";
u_char lcs_firm_f4[]="A4F4";
for (j=0;j<4;j++)
if (D_S[d].firmware_version[j]!=lcs_firm_e1[j]) break;
if (j==4) D_S[d].drv_type=drv_e1;
for (j=0;j<4;j++)
if (D_S[d].firmware_version[j]!=lcs_firm_f4[j]) break;
if (j==4) D_S[d].drv_type=drv_f4;
if (D_S[d].drv_type==drv_famL) ask_mail();
}
else if (famT_drive)
{
j=infobuf[4]; /* one-byte version??? - here: 0x15 */
if (j=='5')
{
D_S[d].firmware_version[0]=infobuf[7];
D_S[d].firmware_version[1]=infobuf[8];
D_S[d].firmware_version[2]=infobuf[10];
D_S[d].firmware_version[3]=infobuf[11];
}
else
{
if (j!=0x15) ask_mail();
D_S[d].firmware_version[0]='0';
D_S[d].firmware_version[1]='.';
D_S[d].firmware_version[2]='0'+(j>>4);
D_S[d].firmware_version[3]='0'+(j&0x0f);
}
}
else /* CR-52x, CR-56x, CD200, ECS-AT */
{
j = (D_S[d].firmware_version[0] & 0x0F) * 100 +
(D_S[d].firmware_version[2] & 0x0F) *10 +
(D_S[d].firmware_version[3] & 0x0F);
if (fam0_drive)
{
if (j<200) D_S[d].drv_type=drv_199;
else if (j<201) D_S[d].drv_type=drv_200;
else if (j<210) D_S[d].drv_type=drv_201;
else if (j<211) D_S[d].drv_type=drv_210;
else if (j<300) D_S[d].drv_type=drv_211;
else if (j>=300) D_S[d].drv_type=drv_300;
}
else if (fam1_drive)
{
if (j<100) D_S[d].drv_type=drv_099;
else
{
D_S[d].drv_type=drv_100;
if ((j!=500)&&(j!=102)) ask_mail();
}
}
else if (fam2_drive)
{
if (D_S[d].drive_model[5]=='F')
{
if ((j!=1)&&(j!=35)&&(j!=200)&&(j!=210))
ask_mail(); /* unknown version at time */
}
else
{
msg(DBG_INF,"this CD200 drive is not fully supported yet - only audio will work.\n");
if ((j!=101)&&(j!=35))
ask_mail(); /* unknown version at time */
}
}
else if (famV_drive)
{
if ((j==100)||(j==150)) D_S[d].drv_type=drv_at;
ask_mail(); /* hopefully we get some feedback by this */
}
}
msg(DBG_LCS,"drive type %02X\n",D_S[d].drv_type);
msg(DBG_INI,"check_version done.\n");
return (0);
}
/*==========================================================================*/
static void switch_drive(int i)
{
d=i;
OUT(CDo_enable,D_S[d].drv_sel);
msg(DBG_DID,"drive %d (ID=%d) activated.\n", i, D_S[d].drv_id);
return;
}
/*==========================================================================*/
#ifdef PATH_CHECK
/*
* probe for the presence of an interface card
*/
static int __init check_card(int port)
{
#undef N_RESPO
#define N_RESPO 20
int i, j, k;
u_char response[N_RESPO];
u_char save_port0;
u_char save_port3;
msg(DBG_INI,"check_card entered.\n");
save_port0=inb(port+0);
save_port3=inb(port+3);
for (j=0;j<NR_SBPCD;j++)
{
OUT(port+3,j) ; /* enable drive #j */
OUT(port+0,CMD0_PATH_CHECK);
for (i=10;i>0;i--) OUT(port+0,0);
for (k=0;k<N_RESPO;k++) response[k]=0;
for (k=0;k<N_RESPO;k++)
{
for (i=10000;i>0;i--)
{
if (inb(port+1)&s_not_result_ready) continue;
response[k]=inb(port+0);
break;
}
}
for (i=0;i<N_RESPO;i++)
sprintf(&msgbuf[i*3], " %02X", response[i]);
msgbuf[i*3]=0;
msg(DBG_TEA,"path check 00 (%d): %s\n", j, msgbuf);
OUT(port+0,CMD0_PATH_CHECK);
for (i=10;i>0;i--) OUT(port+0,0);
for (k=0;k<N_RESPO;k++) response[k]=0xFF;
for (k=0;k<N_RESPO;k++)
{
for (i=10000;i>0;i--)
{
if (inb(port+1)&s_not_result_ready) continue;
response[k]=inb(port+0);
break;
}
}
for (i=0;i<N_RESPO;i++)
sprintf(&msgbuf[i*3], " %02X", response[i]);
msgbuf[i*3]=0;
msg(DBG_TEA,"path check 00 (%d): %s\n", j, msgbuf);
if (response[0]==0xAA)
if (response[1]==0x55)
return (0);
}
for (j=0;j<NR_SBPCD;j++)
{
OUT(port+3,j) ; /* enable drive #j */
OUT(port+0,CMD2_READ_VER);
for (i=10;i>0;i--) OUT(port+0,0);
for (k=0;k<N_RESPO;k++) response[k]=0;
for (k=0;k<N_RESPO;k++)
{
for (i=1000000;i>0;i--)
{
if (inb(port+1)&s_not_result_ready) continue;
response[k]=inb(port+0);
break;
}
}
for (i=0;i<N_RESPO;i++)
sprintf(&msgbuf[i*3], " %02X", response[i]);
msgbuf[i*3]=0;
msg(DBG_TEA,"path check 12 (%d): %s\n", j, msgbuf);
OUT(port+0,CMD2_READ_VER);
for (i=10;i>0;i--) OUT(port+0,0);
for (k=0;k<N_RESPO;k++) response[k]=0xFF;
for (k=0;k<N_RESPO;k++)
{
for (i=1000000;i>0;i--)
{
if (inb(port+1)&s_not_result_ready) continue;
response[k]=inb(port+0);
break;
}
}
for (i=0;i<N_RESPO;i++)
sprintf(&msgbuf[i*3], " %02X", response[i]);
msgbuf[i*3]=0;
msg(DBG_TEA,"path check 12 (%d): %s\n", j, msgbuf);
if (response[0]==0xAA)
if (response[1]==0x55)
return (0);
}
OUT(port+0,save_port0);
OUT(port+3,save_port3);
return (0); /* in any case - no real "function" at time */
}
#endif /* PATH_CHECK */
/*==========================================================================*/
/*==========================================================================*/
/*
* probe for the presence of drives on the selected controller
*/
static int __init check_drives(void)
{
int i, j;
msg(DBG_INI,"check_drives entered.\n");
ndrives=0;
for (j=0;j<max_drives;j++)
{
D_S[ndrives].drv_id=j;
if (sbpro_type==1) D_S[ndrives].drv_sel=(j&0x01)<<1|(j&0x02)>>1;
else D_S[ndrives].drv_sel=j;
switch_drive(ndrives);
msg(DBG_INI,"check_drives: drive %d (ID=%d) activated.\n",ndrives,j);
msg(DBG_000,"check_drives: drive %d (ID=%d) activated.\n",ndrives,j);
i=check_version();
if (i<0) msg(DBG_INI,"check_version returns %d.\n",i);
else
{
D_S[d].drv_options=drv_pattern[j];
if (fam0L_drive) D_S[d].drv_options&=~(speed_auto|speed_300|speed_150);
msg(DBG_INF, "Drive %d (ID=%d): %.9s (%.4s) at 0x%03X (type %d)\n",
d,
D_S[d].drv_id,
D_S[d].drive_model,
D_S[d].firmware_version,
CDo_command,
sbpro_type);
ndrives++;
}
}
for (j=ndrives;j<NR_SBPCD;j++) D_S[j].drv_id=-1;
if (ndrives==0) return (-1);
return (0);
}
/*==========================================================================*/
#if FUTURE
/*
* obtain if requested service disturbs current audio state
*/
static int obey_audio_state(u_char audio_state, u_char func,u_char subfunc)
{
switch (audio_state) /* audio status from controller */
{
case aud_11: /* "audio play in progress" */
case audx11:
switch (func) /* DOS command code */
{
case cmd_07: /* input flush */
case cmd_0d: /* open device */
case cmd_0e: /* close device */
case cmd_0c: /* ioctl output */
return (1);
case cmd_03: /* ioctl input */
switch (subfunc)
/* DOS ioctl input subfunction */
{
case cxi_00:
case cxi_06:
case cxi_09:
return (1);
default:
return (ERROR15);
}
return (1);
default:
return (ERROR15);
}
return (1);
case aud_12: /* "audio play paused" */
case audx12:
return (1);
default:
return (2);
}
}
/*==========================================================================*/
/* allowed is only
* ioctl_o, flush_input, open_device, close_device,
* tell_address, tell_volume, tell_capabiliti,
* tell_framesize, tell_CD_changed, tell_audio_posi
*/
static int check_allowed1(u_char func1, u_char func2)
{
#if 000
if (func1==ioctl_o) return (0);
if (func1==read_long) return (-1);
if (func1==read_long_prefetch) return (-1);
if (func1==seek) return (-1);
if (func1==audio_play) return (-1);
if (func1==audio_pause) return (-1);
if (func1==audio_resume) return (-1);
if (func1!=ioctl_i) return (0);
if (func2==tell_SubQ_run_tot) return (-1);
if (func2==tell_cdsize) return (-1);
if (func2==tell_TocDescrip) return (-1);
if (func2==tell_TocEntry) return (-1);
if (func2==tell_subQ_info) return (-1);
if (fam1_drive) if (func2==tell_SubChanInfo) return (-1);
if (func2==tell_UPC) return (-1);
#else
return (0);
#endif
}
/*==========================================================================*/
static int check_allowed2(u_char func1, u_char func2)
{
#if 000
if (func1==read_long) return (-1);
if (func1==read_long_prefetch) return (-1);
if (func1==seek) return (-1);
if (func1==audio_play) return (-1);
if (func1!=ioctl_o) return (0);
if (fam1_drive)
{
if (func2==EjectDisk) return (-1);
if (func2==CloseTray) return (-1);
}
#else
return (0);
#endif
}
/*==========================================================================*/
static int check_allowed3(u_char func1, u_char func2)
{
#if 000
if (func1==ioctl_i)
{
if (func2==tell_address) return (0);
if (func2==tell_capabiliti) return (0);
if (func2==tell_CD_changed) return (0);
if (fam0L_drive) if (func2==tell_SubChanInfo) return (0);
return (-1);
}
if (func1==ioctl_o)
{
if (func2==DriveReset) return (0);
if (fam0L_drive)
{
if (func2==EjectDisk) return (0);
if (func2==LockDoor) return (0);
if (func2==CloseTray) return (0);
}
return (-1);
}
if (func1==flush_input) return (-1);
if (func1==read_long) return (-1);
if (func1==read_long_prefetch) return (-1);
if (func1==seek) return (-1);
if (func1==audio_play) return (-1);
if (func1==audio_pause) return (-1);
if (func1==audio_resume) return (-1);
#else
return (0);
#endif
}
/*==========================================================================*/
static int seek_pos_audio_end(void)
{
int i;
i=msf2blk(D_S[d].pos_audio_end)-1;
if (i<0) return (-1);
i=cc_Seek(i,0);
return (i);
}
#endif /* FUTURE */
/*==========================================================================*/
static int ReadToC(void)
{
int i, j;
D_S[d].diskstate_flags &= ~toc_bit;
D_S[d].ored_ctl_adr=0;
/* special handling of CD-I HE */
if ((D_S[d].n_first_track == 2 && D_S[d].n_last_track == 2) ||
D_S[d].xa_byte == 0x10)
{
D_S[d].TocBuffer[1].nixbyte=0;
D_S[d].TocBuffer[1].ctl_adr=0x40;
D_S[d].TocBuffer[1].number=1;
D_S[d].TocBuffer[1].format=0;
D_S[d].TocBuffer[1].address=blk2msf(0);
D_S[d].ored_ctl_adr |= 0x40;
D_S[d].n_first_track = 1;
D_S[d].n_last_track = 1;
D_S[d].xa_byte = 0x10;
j = 2;
} else
for (j=D_S[d].n_first_track;j<=D_S[d].n_last_track;j++)
{
i=cc_ReadTocEntry(j);
if (i<0)
{
msg(DBG_INF,"cc_ReadTocEntry(%d) returns %d.\n",j,i);
return (i);
}
D_S[d].TocBuffer[j].nixbyte=D_S[d].TocEnt_nixbyte;
D_S[d].TocBuffer[j].ctl_adr=D_S[d].TocEnt_ctl_adr;
D_S[d].TocBuffer[j].number=D_S[d].TocEnt_number;
D_S[d].TocBuffer[j].format=D_S[d].TocEnt_format;
D_S[d].TocBuffer[j].address=D_S[d].TocEnt_address;
D_S[d].ored_ctl_adr |= D_S[d].TocEnt_ctl_adr;
}
/* fake entry for LeadOut Track */
D_S[d].TocBuffer[j].nixbyte=0;
D_S[d].TocBuffer[j].ctl_adr=0;
D_S[d].TocBuffer[j].number=CDROM_LEADOUT;
D_S[d].TocBuffer[j].format=0;
D_S[d].TocBuffer[j].address=D_S[d].size_msf;
D_S[d].diskstate_flags |= toc_bit;
return (0);
}
/*==========================================================================*/
static int DiskInfo(void)
{
int i, j;
D_S[d].mode=READ_M1;
#undef LOOP_COUNT
#define LOOP_COUNT 10 /* needed for some "old" drives */
msg(DBG_000,"DiskInfo entered.\n");
for (j=1;j<LOOP_COUNT;j++)
{
#if 0
i=SetSpeed();
if (i<0)
{
msg(DBG_INF,"DiskInfo: SetSpeed returns %d\n", i);
continue;
}
i=cc_ModeSense();
if (i<0)
{
msg(DBG_INF,"DiskInfo: cc_ModeSense returns %d\n", i);
continue;
}
#endif
i=cc_ReadCapacity();
if (i>=0) break;
msg(DBG_INF,"DiskInfo: ReadCapacity #%d returns %d\n", j, i);
#if 0
i=cc_DriveReset();
#endif
if (!fam0_drive && j == 2) break;
}
if (j==LOOP_COUNT) return (-33); /* give up */
i=cc_ReadTocDescr();
if (i<0)
{
msg(DBG_INF,"DiskInfo: ReadTocDescr returns %d\n", i);
return (i);
}
i=ReadToC();
if (i<0)
{
msg(DBG_INF,"DiskInfo: ReadToC returns %d\n", i);
return (i);
}
i=cc_CheckMultiSession();
if (i<0)
{
msg(DBG_INF,"DiskInfo: cc_CheckMultiSession returns %d\n", i);
return (i);
}
if (D_S[d].f_multisession) D_S[d].sbp_bufsiz=1; /* possibly a weird PhotoCD */
else D_S[d].sbp_bufsiz=buffers;
i=cc_ReadTocEntry(D_S[d].n_first_track);
if (i<0)
{
msg(DBG_INF,"DiskInfo: cc_ReadTocEntry(1) returns %d\n", i);
return (i);
}
i=cc_ReadUPC();
if (i<0) msg(DBG_INF,"DiskInfo: cc_ReadUPC returns %d\n", i);
if ((fam0L_drive) && (D_S[d].xa_byte==0x20 || D_S[d].xa_byte == 0x10))
{
/* XA disk with old drive */
cc_ModeSelect(CD_FRAMESIZE_RAW1);
cc_ModeSense();
}
if (famT_drive) cc_prep_mode_T();
msg(DBG_000,"DiskInfo done.\n");
return (0);
}
static int sbpcd_drive_status(struct cdrom_device_info *cdi, int slot_nr)
{
int st;
if (CDSL_CURRENT != slot_nr) {
/* we have no changer support */
return -EINVAL;
}
cc_ReadStatus();
st=ResponseStatus();
if (st<0)
{
msg(DBG_INF,"sbpcd_drive_status: timeout.\n");
return (0);
}
msg(DBG_000,"Drive Status: door_locked =%d.\n", st_door_locked);
msg(DBG_000,"Drive Status: door_closed =%d.\n", st_door_closed);
msg(DBG_000,"Drive Status: caddy_in =%d.\n", st_caddy_in);
msg(DBG_000,"Drive Status: disk_ok =%d.\n", st_diskok);
msg(DBG_000,"Drive Status: spinning =%d.\n", st_spinning);
msg(DBG_000,"Drive Status: busy =%d.\n", st_busy);
#if 0
if (!(D_S[MINOR(cdi->dev)].status_bits & p_door_closed)) return CDS_TRAY_OPEN;
if (D_S[MINOR(cdi->dev)].status_bits & p_disk_ok) return CDS_DISC_OK;
if (D_S[MINOR(cdi->dev)].status_bits & p_disk_in) return CDS_DRIVE_NOT_READY;
return CDS_NO_DISC;
#else
if (D_S[MINOR(cdi->dev)].status_bits & p_spinning) return CDS_DISC_OK;
/* return CDS_TRAY_OPEN; */
return CDS_NO_DISC;
#endif
}
/*==========================================================================*/
#if FUTURE
/*
* called always if driver gets entered
* returns 0 or ERROR2 or ERROR15
*/
static int prepare(u_char func, u_char subfunc)
{
int i;
if (fam0L_drive)
{
i=inb(CDi_status);
if (i&s_attention) GetStatus();
}
else if (fam1_drive) GetStatus();
else if (fam2_drive) GetStatus();
else if (famT_drive) GetStatus();
if (D_S[d].CD_changed==0xFF)
{
D_S[d].diskstate_flags=0;
D_S[d].audio_state=0;
if (!st_diskok)
{
i=check_allowed1(func,subfunc);
if (i<0) return (-2);
}
else
{
i=check_allowed3(func,subfunc);
if (i<0)
{
D_S[d].CD_changed=1;
return (-15);
}
}
}
else
{
if (!st_diskok)
{
D_S[d].diskstate_flags=0;
D_S[d].audio_state=0;
i=check_allowed1(func,subfunc);
if (i<0) return (-2);
}
else
{
if (st_busy)
{
if (D_S[d].audio_state!=audio_pausing)
{
i=check_allowed2(func,subfunc);
if (i<0) return (-2);
}
}
else
{
if (D_S[d].audio_state==audio_playing) seek_pos_audio_end();
D_S[d].audio_state=0;
}
if (!frame_size_valid)
{
i=DiskInfo();
if (i<0)
{
D_S[d].diskstate_flags=0;
D_S[d].audio_state=0;
i=check_allowed1(func,subfunc);
if (i<0) return (-2);
}
}
}
}
return (0);
}
#endif /* FUTURE */
/*==========================================================================*/
/*==========================================================================*/
/*
* Check the results of the "get status" command.
*/
static int sbp_status(void)
{
int st;
st=ResponseStatus();
if (st<0)
{
msg(DBG_INF,"sbp_status: timeout.\n");
return (0);
}
if (!st_spinning) msg(DBG_SPI,"motor got off - ignoring.\n");
if (st_check)
{
msg(DBG_INF,"st_check detected - retrying.\n");
return (0);
}
if (!st_door_closed)
{
msg(DBG_INF,"door is open - retrying.\n");
return (0);
}
if (!st_caddy_in)
{
msg(DBG_INF,"disk removed - retrying.\n");
return (0);
}
if (!st_diskok)
{
msg(DBG_INF,"!st_diskok detected - retrying.\n");
return (0);
}
if (st_busy)
{
msg(DBG_INF,"st_busy detected - retrying.\n");
return (0);
}
return (1);
}
/*==========================================================================*/
static int sbpcd_get_last_session(struct cdrom_device_info *cdi, struct cdrom_multisession *ms_infp)
{
ms_infp->addr_format = CDROM_LBA;
ms_infp->addr.lba = D_S[MINOR(cdi->dev)].lba_multi;
if (D_S[MINOR(cdi->dev)].f_multisession)
ms_infp->xa_flag=1; /* valid redirection address */
else
ms_infp->xa_flag=0; /* invalid redirection address */
return 0;
}
/*==========================================================================*/
/*==========================================================================*/
/*
* ioctl support
*/
static int sbpcd_dev_ioctl(struct cdrom_device_info *cdi, u_int cmd,
u_long arg)
{
int i;
msg(DBG_IO2,"ioctl(%d, 0x%08lX, 0x%08lX)\n",
MINOR(cdi->dev), cmd, arg);
i=MINOR(cdi->dev);
if ((i<0) || (i>=NR_SBPCD) || (D_S[i].drv_id==-1))
{
msg(DBG_INF, "ioctl: bad device: %04X\n", cdi->dev);
return (-ENXIO); /* no such drive */
}
down(&ioctl_read_sem);
if (d!=i) switch_drive(i);
msg(DBG_IO2,"ioctl: device %d, request %04X\n",i,cmd);
switch (cmd) /* Sun-compatible */
{
case DDIOCSDBG: /* DDI Debug */
if (!capable(CAP_SYS_ADMIN)) RETURN_UP(-EPERM);
i=sbpcd_dbg_ioctl(arg,1);
RETURN_UP(i);
case CDROMRESET: /* hard reset the drive */
msg(DBG_IOC,"ioctl: CDROMRESET entered.\n");
i=DriveReset();
D_S[d].audio_state=0;
RETURN_UP(i);
case CDROMREADMODE1:
msg(DBG_IOC,"ioctl: CDROMREADMODE1 requested.\n");
#if SAFE_MIXED
if (D_S[d].has_data>1) RETURN_UP(-EBUSY);
#endif /* SAFE_MIXED */
cc_ModeSelect(CD_FRAMESIZE);
cc_ModeSense();
D_S[d].mode=READ_M1;
RETURN_UP(0);
case CDROMREADMODE2: /* not usable at the moment */
msg(DBG_IOC,"ioctl: CDROMREADMODE2 requested.\n");
#if SAFE_MIXED
if (D_S[d].has_data>1) RETURN_UP(-EBUSY);
#endif /* SAFE_MIXED */
cc_ModeSelect(CD_FRAMESIZE_RAW1);
cc_ModeSense();
D_S[d].mode=READ_M2;
RETURN_UP(0);
case CDROMAUDIOBUFSIZ: /* configure the audio buffer size */
msg(DBG_IOC,"ioctl: CDROMAUDIOBUFSIZ entered.\n");
if (D_S[d].sbp_audsiz>0) vfree(D_S[d].aud_buf);
D_S[d].aud_buf=NULL;
D_S[d].sbp_audsiz=arg;
if (D_S[d].sbp_audsiz>16)
{
D_S[d].sbp_audsiz = 0;
RETURN_UP(D_S[d].sbp_audsiz);
}
if (D_S[d].sbp_audsiz>0)
{
D_S[d].aud_buf=(u_char *) vmalloc(D_S[d].sbp_audsiz*CD_FRAMESIZE_RAW);
if (D_S[d].aud_buf==NULL)
{
msg(DBG_INF,"audio buffer (%d frames) not available.\n",D_S[d].sbp_audsiz);
D_S[d].sbp_audsiz=0;
}
else msg(DBG_INF,"audio buffer size: %d frames.\n",D_S[d].sbp_audsiz);
}
RETURN_UP(D_S[d].sbp_audsiz);
case CDROMREADAUDIO:
{ /* start of CDROMREADAUDIO */
int i=0, j=0, frame, block=0;
u_int try=0;
u_long timeout;
u_char *p;
u_int data_tries = 0;
u_int data_waits = 0;
u_int data_retrying = 0;
int status_tries;
int error_flag;
msg(DBG_IOC,"ioctl: CDROMREADAUDIO entered.\n");
if (fam0_drive) RETURN_UP(-EINVAL);
if (famL_drive) RETURN_UP(-EINVAL);
if (famV_drive) RETURN_UP(-EINVAL);
if (famT_drive) RETURN_UP(-EINVAL);
#if SAFE_MIXED
if (D_S[d].has_data>1) RETURN_UP(-EBUSY);
#endif /* SAFE_MIXED */
if (D_S[d].aud_buf==NULL) RETURN_UP(-EINVAL);
i=verify_area(VERIFY_READ, (void *) arg, sizeof(struct cdrom_read_audio));
if (i) RETURN_UP(i);
copy_from_user(&read_audio, (void *) arg, sizeof(struct cdrom_read_audio));
if (read_audio.nframes < 0 || read_audio.nframes>D_S[d].sbp_audsiz) RETURN_UP(-EINVAL);
i=verify_area(VERIFY_WRITE, read_audio.buf,
read_audio.nframes*CD_FRAMESIZE_RAW);
if (i) RETURN_UP(i);
if (read_audio.addr_format==CDROM_MSF) /* MSF-bin specification of where to start */
block=msf2lba(&read_audio.addr.msf.minute);
else if (read_audio.addr_format==CDROM_LBA) /* lba specification of where to start */
block=read_audio.addr.lba;
else RETURN_UP(-EINVAL);
#if 000
i=cc_SetSpeed(speed_150,0,0);
if (i) msg(DBG_AUD,"read_audio: SetSpeed error %d\n", i);
#endif
msg(DBG_AUD,"read_audio: lba: %d, msf: %06X\n",
block, blk2msf(block));
msg(DBG_AUD,"read_audio: before cc_ReadStatus.\n");
#if OLD_BUSY
while (busy_data) sbp_sleep(HZ/10); /* wait a bit */
busy_audio=1;
#endif /* OLD_BUSY */
error_flag=0;
for (data_tries=5; data_tries>0; data_tries--)
{
msg(DBG_AUD,"data_tries=%d ...\n", data_tries);
D_S[d].mode=READ_AU;
cc_ModeSelect(CD_FRAMESIZE_RAW);
cc_ModeSense();
for (status_tries=3; status_tries > 0; status_tries--)
{
flags_cmd_out |= f_respo3;
cc_ReadStatus();
if (sbp_status() != 0) break;
if (st_check) cc_ReadError();
sbp_sleep(1); /* wait a bit, try again */
}
if (status_tries == 0)
{
msg(DBG_AUD,"read_audio: sbp_status: failed after 3 tries in line %d.\n", __LINE__);
continue;
}
msg(DBG_AUD,"read_audio: sbp_status: ok.\n");
flags_cmd_out = f_putcmd | f_respo2 | f_ResponseStatus | f_obey_p_check;
if (fam0L_drive)
{
flags_cmd_out |= f_lopsta | f_getsta | f_bit1;
cmd_type=READ_M2;
drvcmd[0]=CMD0_READ_XA; /* "read XA frames", old drives */
drvcmd[1]=(block>>16)&0x000000ff;
drvcmd[2]=(block>>8)&0x000000ff;
drvcmd[3]=block&0x000000ff;
drvcmd[4]=0;
drvcmd[5]=read_audio.nframes; /* # of frames */
drvcmd[6]=0;
}
else if (fam1_drive)
{
drvcmd[0]=CMD1_READ; /* "read frames", new drives */
lba2msf(block,&drvcmd[1]); /* msf-bin format required */
drvcmd[4]=0;
drvcmd[5]=0;
drvcmd[6]=read_audio.nframes; /* # of frames */
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_READ_XA2;
lba2msf(block,&drvcmd[1]); /* msf-bin format required */
drvcmd[4]=0;
drvcmd[5]=read_audio.nframes; /* # of frames */
drvcmd[6]=0x11; /* raw mode */
}
else if (famT_drive) /* CD-55A: not tested yet */
{
}
msg(DBG_AUD,"read_audio: before giving \"read\" command.\n");
flags_cmd_out=f_putcmd;
response_count=0;
i=cmd_out();
if (i<0) msg(DBG_INF,"error giving READ AUDIO command: %0d\n", i);
sbp_sleep(0);
msg(DBG_AUD,"read_audio: after giving \"read\" command.\n");
for (frame=1;frame<2 && !error_flag; frame++)
{
try=maxtim_data;
for (timeout=jiffies+9*HZ; ; )
{
for ( ; try!=0;try--)
{
j=inb(CDi_status);
if (!(j&s_not_data_ready)) break;
if (!(j&s_not_result_ready)) break;
if (fam0L_drive) if (j&s_attention) break;
}
if (try != 0 || time_after_eq(jiffies, timeout)) break;
if (data_retrying == 0) data_waits++;
data_retrying = 1;
sbp_sleep(1);
try = 1;
}
if (try==0)
{
msg(DBG_INF,"read_audio: sbp_data: CDi_status timeout.\n");
error_flag++;
break;
}
msg(DBG_AUD,"read_audio: sbp_data: CDi_status ok.\n");
if (j&s_not_data_ready)
{
msg(DBG_INF, "read_audio: sbp_data: DATA_READY timeout.\n");
error_flag++;
break;
}
msg(DBG_AUD,"read_audio: before reading data.\n");
error_flag=0;
p = D_S[d].aud_buf;
if (sbpro_type==1) OUT(CDo_sel_i_d,1);
if (do_16bit)
{
u_short *p2 = (u_short *) p;
for (; (u_char *) p2 < D_S[d].aud_buf + read_audio.nframes*CD_FRAMESIZE_RAW;)
{
if ((inb_p(CDi_status)&s_not_data_ready)) continue;
/* get one sample */
*p2++ = inw_p(CDi_data);
*p2++ = inw_p(CDi_data);
}
} else {
for (; p < D_S[d].aud_buf + read_audio.nframes*CD_FRAMESIZE_RAW;)
{
if ((inb_p(CDi_status)&s_not_data_ready)) continue;
/* get one sample */
*p++ = inb_p(CDi_data);
*p++ = inb_p(CDi_data);
*p++ = inb_p(CDi_data);
*p++ = inb_p(CDi_data);
}
}
if (sbpro_type==1) OUT(CDo_sel_i_d,0);
data_retrying = 0;
}
msg(DBG_AUD,"read_audio: after reading data.\n");
if (error_flag) /* must have been spurious D_RDY or (ATTN&&!D_RDY) */
{
msg(DBG_AUD,"read_audio: read aborted by drive\n");
#if 0000
i=cc_DriveReset(); /* ugly fix to prevent a hang */
#else
i=cc_ReadError();
#endif
continue;
}
if (fam0L_drive)
{
i=maxtim_data;
for (timeout=jiffies+9*HZ; time_before(jiffies, timeout); timeout--)
{
for ( ;i!=0;i--)
{
j=inb(CDi_status);
if (!(j&s_not_data_ready)) break;
if (!(j&s_not_result_ready)) break;
if (j&s_attention) break;
}
if (i != 0 || time_after_eq(jiffies, timeout)) break;
sbp_sleep(0);
i = 1;
}
if (i==0) msg(DBG_AUD,"read_audio: STATUS TIMEOUT AFTER READ");
if (!(j&s_attention))
{
msg(DBG_AUD,"read_audio: sbp_data: timeout waiting DRV_ATTN - retrying\n");
i=cc_DriveReset(); /* ugly fix to prevent a hang */
continue;
}
}
do
{
if (fam0L_drive) cc_ReadStatus();
i=ResponseStatus(); /* builds status_bits, returns orig. status (old) or faked p_success (new) */
if (i<0) { msg(DBG_AUD,
"read_audio: cc_ReadStatus error after read: %02X\n",
D_S[d].status_bits);
continue; /* FIXME */
}
}
while ((fam0L_drive)&&(!st_check)&&(!(i&p_success)));
if (st_check)
{
i=cc_ReadError();
msg(DBG_AUD,"read_audio: cc_ReadError was necessary after read: %02X\n",i);
continue;
}
copy_to_user((u_char *) read_audio.buf,
(u_char *) D_S[d].aud_buf,
read_audio.nframes*CD_FRAMESIZE_RAW);
msg(DBG_AUD,"read_audio: copy_to_user done.\n");
break;
}
cc_ModeSelect(CD_FRAMESIZE);
cc_ModeSense();
D_S[d].mode=READ_M1;
#if OLD_BUSY
busy_audio=0;
#endif /* OLD_BUSY */
if (data_tries == 0)
{
msg(DBG_AUD,"read_audio: failed after 5 tries in line %d.\n", __LINE__);
RETURN_UP(-EIO);
}
msg(DBG_AUD,"read_audio: successful return.\n");
RETURN_UP(0);
} /* end of CDROMREADAUDIO */
case BLKRASET:
if(!capable(CAP_SYS_ADMIN)) RETURN_UP(-EACCES);
if(!(cdi->dev)) RETURN_UP(-EINVAL);
if(arg > 0xff) RETURN_UP(-EINVAL);
read_ahead[MAJOR(cdi->dev)] = arg;
RETURN_UP(0);
default:
msg(DBG_IOC,"ioctl: unknown function request %04X\n", cmd);
RETURN_UP(-EINVAL);
} /* end switch(cmd) */
}
static int sbpcd_audio_ioctl(struct cdrom_device_info *cdi, u_int cmd,
void * arg)
{
int i, st, j;
msg(DBG_IO2,"ioctl(%d, 0x%08lX, 0x%08p)\n",
MINOR(cdi->dev), cmd, arg);
i=MINOR(cdi->dev);
if ((i<0) || (i>=NR_SBPCD) || (D_S[i].drv_id==-1))
{
msg(DBG_INF, "ioctl: bad device: %04X\n", cdi->dev);
return (-ENXIO); /* no such drive */
}
down(&ioctl_read_sem);
if (d!=i) switch_drive(i);
msg(DBG_IO2,"ioctl: device %d, request %04X\n",i,cmd);
switch (cmd) /* Sun-compatible */
{
case CDROMPAUSE: /* Pause the drive */
msg(DBG_IOC,"ioctl: CDROMPAUSE entered.\n");
/* pause the drive unit when it is currently in PLAY mode, */
/* or reset the starting and ending locations when in PAUSED mode. */
/* If applicable, at the next stopping point it reaches */
/* the drive will discontinue playing. */
switch (D_S[d].audio_state)
{
case audio_playing:
if (famL_drive) i=cc_ReadSubQ();
else i=cc_Pause_Resume(1);
if (i<0) RETURN_UP(-EIO);
if (famL_drive) i=cc_Pause_Resume(1);
else i=cc_ReadSubQ();
if (i<0) RETURN_UP(-EIO);
D_S[d].pos_audio_start=D_S[d].SubQ_run_tot;
D_S[d].audio_state=audio_pausing;
RETURN_UP(0);
case audio_pausing:
i=cc_Seek(D_S[d].pos_audio_start,1);
if (i<0) RETURN_UP(-EIO);
RETURN_UP(0);
default:
RETURN_UP(-EINVAL);
}
case CDROMRESUME: /* resume paused audio play */
msg(DBG_IOC,"ioctl: CDROMRESUME entered.\n");
/* resume playing audio tracks when a previous PLAY AUDIO call has */
/* been paused with a PAUSE command. */
/* It will resume playing from the location saved in SubQ_run_tot. */
if (D_S[d].audio_state!=audio_pausing) RETURN_UP(-EINVAL);
if (famL_drive)
i=cc_PlayAudio(D_S[d].pos_audio_start,
D_S[d].pos_audio_end);
else i=cc_Pause_Resume(3);
if (i<0) RETURN_UP(-EIO);
D_S[d].audio_state=audio_playing;
RETURN_UP(0);
case CDROMPLAYMSF:
msg(DBG_IOC,"ioctl: CDROMPLAYMSF entered.\n");
#if SAFE_MIXED
if (D_S[d].has_data>1) RETURN_UP(-EBUSY);
#endif /* SAFE_MIXED */
if (D_S[d].audio_state==audio_playing)
{
i=cc_Pause_Resume(1);
if (i<0) RETURN_UP(-EIO);
i=cc_ReadSubQ();
if (i<0) RETURN_UP(-EIO);
D_S[d].pos_audio_start=D_S[d].SubQ_run_tot;
i=cc_Seek(D_S[d].pos_audio_start,1);
}
memcpy(&msf, (void *) arg, sizeof(struct cdrom_msf));
/* values come as msf-bin */
D_S[d].pos_audio_start = (msf.cdmsf_min0<<16) |
(msf.cdmsf_sec0<<8) |
msf.cdmsf_frame0;
D_S[d].pos_audio_end = (msf.cdmsf_min1<<16) |
(msf.cdmsf_sec1<<8) |
msf.cdmsf_frame1;
msg(DBG_IOX,"ioctl: CDROMPLAYMSF %08X %08X\n",
D_S[d].pos_audio_start,D_S[d].pos_audio_end);
i=cc_PlayAudio(D_S[d].pos_audio_start,D_S[d].pos_audio_end);
if (i<0)
{
msg(DBG_INF,"ioctl: cc_PlayAudio returns %d\n",i);
DriveReset();
D_S[d].audio_state=0;
RETURN_UP(-EIO);
}
D_S[d].audio_state=audio_playing;
RETURN_UP(0);
case CDROMPLAYTRKIND: /* Play a track. This currently ignores index. */
msg(DBG_IOC,"ioctl: CDROMPLAYTRKIND entered.\n");
#if SAFE_MIXED
if (D_S[d].has_data>1) RETURN_UP(-EBUSY);
#endif /* SAFE_MIXED */
if (D_S[d].audio_state==audio_playing)
{
msg(DBG_IOX,"CDROMPLAYTRKIND: already audio_playing.\n");
#if 1
RETURN_UP(0); /* just let us play on */
#else
RETURN_UP(-EINVAL); /* play on, but say "error" */
#endif
}
memcpy(&ti,(void *) arg,sizeof(struct cdrom_ti));
msg(DBG_IOX,"ioctl: trk0: %d, ind0: %d, trk1:%d, ind1:%d\n",
ti.cdti_trk0,ti.cdti_ind0,ti.cdti_trk1,ti.cdti_ind1);
if (ti.cdti_trk0<D_S[d].n_first_track) RETURN_UP(-EINVAL);
if (ti.cdti_trk0>D_S[d].n_last_track) RETURN_UP(-EINVAL);
if (ti.cdti_trk1<ti.cdti_trk0) ti.cdti_trk1=ti.cdti_trk0;
if (ti.cdti_trk1>D_S[d].n_last_track) ti.cdti_trk1=D_S[d].n_last_track;
D_S[d].pos_audio_start=D_S[d].TocBuffer[ti.cdti_trk0].address;
D_S[d].pos_audio_end=D_S[d].TocBuffer[ti.cdti_trk1+1].address;
i=cc_PlayAudio(D_S[d].pos_audio_start,D_S[d].pos_audio_end);
if (i<0)
{
msg(DBG_INF,"ioctl: cc_PlayAudio returns %d\n",i);
DriveReset();
D_S[d].audio_state=0;
RETURN_UP(-EIO);
}
D_S[d].audio_state=audio_playing;
RETURN_UP(0);
case CDROMREADTOCHDR: /* Read the table of contents header */
msg(DBG_IOC,"ioctl: CDROMREADTOCHDR entered.\n");
tochdr.cdth_trk0=D_S[d].n_first_track;
tochdr.cdth_trk1=D_S[d].n_last_track;
memcpy((void *) arg, &tochdr, sizeof(struct cdrom_tochdr));
RETURN_UP(0);
case CDROMREADTOCENTRY: /* Read an entry in the table of contents */
msg(DBG_IOC,"ioctl: CDROMREADTOCENTRY entered.\n");
memcpy(&tocentry, (void *) arg, sizeof(struct cdrom_tocentry));
i=tocentry.cdte_track;
if (i==CDROM_LEADOUT) i=D_S[d].n_last_track+1;
else if (i<D_S[d].n_first_track||i>D_S[d].n_last_track)
RETURN_UP(-EINVAL);
tocentry.cdte_adr=D_S[d].TocBuffer[i].ctl_adr&0x0F;
tocentry.cdte_ctrl=(D_S[d].TocBuffer[i].ctl_adr>>4)&0x0F;
tocentry.cdte_datamode=D_S[d].TocBuffer[i].format;
if (tocentry.cdte_format==CDROM_MSF) /* MSF-bin required */
{
tocentry.cdte_addr.msf.minute=(D_S[d].TocBuffer[i].address>>16)&0x00FF;
tocentry.cdte_addr.msf.second=(D_S[d].TocBuffer[i].address>>8)&0x00FF;
tocentry.cdte_addr.msf.frame=D_S[d].TocBuffer[i].address&0x00FF;
}
else if (tocentry.cdte_format==CDROM_LBA) /* blk required */
tocentry.cdte_addr.lba=msf2blk(D_S[d].TocBuffer[i].address);
else RETURN_UP(-EINVAL);
memcpy((void *) arg, &tocentry, sizeof(struct cdrom_tocentry));
RETURN_UP(0);
case CDROMSTOP: /* Spin down the drive */
msg(DBG_IOC,"ioctl: CDROMSTOP entered.\n");
#if SAFE_MIXED
if (D_S[d].has_data>1) RETURN_UP(-EBUSY);
#endif /* SAFE_MIXED */
i=cc_Pause_Resume(1);
D_S[d].audio_state=0;
#if 0
cc_DriveReset();
#endif
RETURN_UP(i);
case CDROMSTART: /* Spin up the drive */
msg(DBG_IOC,"ioctl: CDROMSTART entered.\n");
cc_SpinUp();
D_S[d].audio_state=0;
RETURN_UP(0);
case CDROMVOLCTRL: /* Volume control */
msg(DBG_IOC,"ioctl: CDROMVOLCTRL entered.\n");
memcpy(&volctrl,(char *) arg,sizeof(volctrl));
D_S[d].vol_chan0=0;
D_S[d].vol_ctrl0=volctrl.channel0;
D_S[d].vol_chan1=1;
D_S[d].vol_ctrl1=volctrl.channel1;
i=cc_SetVolume();
RETURN_UP(0);
case CDROMVOLREAD: /* read Volume settings from drive */
msg(DBG_IOC,"ioctl: CDROMVOLREAD entered.\n");
st=cc_GetVolume();
if (st<0) RETURN_UP(st);
volctrl.channel0=D_S[d].vol_ctrl0;
volctrl.channel1=D_S[d].vol_ctrl1;
volctrl.channel2=0;
volctrl.channel2=0;
memcpy((void *)arg,&volctrl,sizeof(volctrl));
RETURN_UP(0);
case CDROMSUBCHNL: /* Get subchannel info */
msg(DBG_IOS,"ioctl: CDROMSUBCHNL entered.\n");
/* Bogus, I can do better than this! --AJK
if ((st_spinning)||(!subq_valid)) {
i=cc_ReadSubQ();
if (i<0) RETURN_UP(-EIO);
}
*/
i=cc_ReadSubQ();
if (i<0) {
j=cc_ReadError(); /* clear out error status from drive */
D_S[d].audio_state=CDROM_AUDIO_NO_STATUS;
/* get and set the disk state here,
probably not the right place, but who cares!
It makes it work properly! --AJK */
if (D_S[d].CD_changed==0xFF) {
msg(DBG_000,"Disk changed detect\n");
D_S[d].diskstate_flags &= ~cd_size_bit;
}
RETURN_UP(-EIO);
}
if (D_S[d].CD_changed==0xFF) {
/* reread the TOC because the disk has changed! --AJK */
msg(DBG_000,"Disk changed STILL detected, rereading TOC!\n");
i=DiskInfo();
if(i==0) {
D_S[d].CD_changed=0x00; /* cd has changed, procede, */
RETURN_UP(-EIO); /* and get TOC, etc on next try! --AJK */
} else {
RETURN_UP(-EIO); /* we weren't ready yet! --AJK */
}
}
memcpy(&SC, (void *) arg, sizeof(struct cdrom_subchnl));
/*
This virtual crap is very bogus!
It doesn't detect when the cd is done playing audio!
Lets do this right with proper hardware register reading!
*/
cc_ReadStatus();
i=ResponseStatus();
msg(DBG_000,"Drive Status: door_locked =%d.\n", st_door_locked);
msg(DBG_000,"Drive Status: door_closed =%d.\n", st_door_closed);
msg(DBG_000,"Drive Status: caddy_in =%d.\n", st_caddy_in);
msg(DBG_000,"Drive Status: disk_ok =%d.\n", st_diskok);
msg(DBG_000,"Drive Status: spinning =%d.\n", st_spinning);
msg(DBG_000,"Drive Status: busy =%d.\n", st_busy);
/* st_busy indicates if it's _ACTUALLY_ playing audio */
switch (D_S[d].audio_state)
{
case audio_playing:
if(st_busy==0) {
/* CD has stopped playing audio --AJK */
D_S[d].audio_state=audio_completed;
SC.cdsc_audiostatus=CDROM_AUDIO_COMPLETED;
} else {
SC.cdsc_audiostatus=CDROM_AUDIO_PLAY;
}
break;
case audio_pausing:
SC.cdsc_audiostatus=CDROM_AUDIO_PAUSED;
break;
case audio_completed:
SC.cdsc_audiostatus=CDROM_AUDIO_COMPLETED;
break;
default:
SC.cdsc_audiostatus=CDROM_AUDIO_NO_STATUS;
break;
}
SC.cdsc_adr=D_S[d].SubQ_ctl_adr;
SC.cdsc_ctrl=D_S[d].SubQ_ctl_adr>>4;
SC.cdsc_trk=bcd2bin(D_S[d].SubQ_trk);
SC.cdsc_ind=bcd2bin(D_S[d].SubQ_pnt_idx);
if (SC.cdsc_format==CDROM_LBA)
{
SC.cdsc_absaddr.lba=msf2blk(D_S[d].SubQ_run_tot);
SC.cdsc_reladdr.lba=msf2blk(D_S[d].SubQ_run_trk);
}
else /* not only if (SC.cdsc_format==CDROM_MSF) */
{
SC.cdsc_absaddr.msf.minute=(D_S[d].SubQ_run_tot>>16)&0x00FF;
SC.cdsc_absaddr.msf.second=(D_S[d].SubQ_run_tot>>8)&0x00FF;
SC.cdsc_absaddr.msf.frame=D_S[d].SubQ_run_tot&0x00FF;
SC.cdsc_reladdr.msf.minute=(D_S[d].SubQ_run_trk>>16)&0x00FF;
SC.cdsc_reladdr.msf.second=(D_S[d].SubQ_run_trk>>8)&0x00FF;
SC.cdsc_reladdr.msf.frame=D_S[d].SubQ_run_trk&0x00FF;
}
memcpy((void *) arg, &SC, sizeof(struct cdrom_subchnl));
msg(DBG_IOS,"CDROMSUBCHNL: %1X %02X %08X %08X %02X %02X %06X %06X\n",
SC.cdsc_format,SC.cdsc_audiostatus,
SC.cdsc_adr,SC.cdsc_ctrl,
SC.cdsc_trk,SC.cdsc_ind,
SC.cdsc_absaddr,SC.cdsc_reladdr);
RETURN_UP(0);
default:
msg(DBG_IOC,"ioctl: unknown function request %04X\n", cmd);
RETURN_UP(-EINVAL);
} /* end switch(cmd) */
}
/*==========================================================================*/
/*
* Take care of the different block sizes between cdrom and Linux.
*/
static void sbp_transfer(struct request *req)
{
long offs;
while ( (req->nr_sectors > 0) &&
(req->sector/4 >= D_S[d].sbp_first_frame) &&
(req->sector/4 <= D_S[d].sbp_last_frame) )
{
offs = (req->sector - D_S[d].sbp_first_frame * 4) * 512;
memcpy(req->buffer, D_S[d].sbp_buf + offs, 512);
req->nr_sectors--;
req->sector++;
req->buffer += 512;
}
}
/*==========================================================================*/
/*
* special end_request for sbpcd to solve CURRENT==NULL bug. (GTL)
* GTL = Gonzalo Tornaria <tornaria@cmat.edu.uy>
*
* This is a kludge so we don't need to modify end_request.
* We put the req we take out after INIT_REQUEST in the requests list,
* so that end_request will discard it.
*
* The bug could be present in other block devices, perhaps we
* should modify INIT_REQUEST and end_request instead, and
* change every block device..
*
* Could be a race here?? Could e.g. a timer interrupt schedule() us?
* If so, we should copy end_request here, and do it right.. (or
* modify end_request and the block devices).
*
* In any case, the race here would be much small than it was, and
* I couldn't reproduce..
*
* The race could be: suppose CURRENT==NULL. We put our req in the list,
* and we are scheduled. Other process takes over, and gets into
* do_sbpcd_request. It sees CURRENT!=NULL (it is == to our req), so
* proceeds. It ends, so CURRENT is now NULL.. Now we awake somewhere in
* end_request, but now CURRENT==NULL... oops!
*
*/
#undef DEBUG_GTL
static inline void sbpcd_end_request(struct request *req, int uptodate) {
list_add(&req->queue, &req->q->queue_head);
end_request(uptodate);
}
/*==========================================================================*/
/*
* I/O request routine, called from Linux kernel.
*/
static void DO_SBPCD_REQUEST(request_queue_t * q)
{
u_int block;
u_int nsect;
int i, status_tries, data_tries;
struct request *req;
#ifdef DEBUG_GTL
static int xx_nr=0;
int xnr;
#endif
request_loop:
#ifdef DEBUG_GTL
xnr=++xx_nr;
if(QUEUE_EMPTY)
{
printk( "do_sbpcd_request[%di](NULL), Pid:%d, Time:%li\n",
xnr, current->pid, jiffies);
printk( "do_sbpcd_request[%do](NULL) end 0 (null), Time:%li\n",
xnr, jiffies);
CLEAR_INTR;
return;
}
printk(" do_sbpcd_request[%di](%p:%ld+%ld), Pid:%d, Time:%li\n",
xnr, CURRENT, CURRENT->sector, CURRENT->nr_sectors, current->pid, jiffies);
#endif
INIT_REQUEST;
req=CURRENT; /* take out our request so no other */
blkdev_dequeue_request(req); /* task can fuck it up GTL */
if (req->rq_status == RQ_INACTIVE)
sbpcd_end_request(req, 0);
if (req -> sector == -1)
sbpcd_end_request(req, 0);
spin_unlock_irq(&io_request_lock);
down(&ioctl_read_sem);
if (req->cmd != READ)
{
msg(DBG_INF, "bad cmd %d\n", req->cmd);
goto err_done;
}
i = MINOR(req->rq_dev);
if ( (i<0) || (i>=NR_SBPCD) || (D_S[i].drv_id==-1))
{
msg(DBG_INF, "do_request: bad device: %s\n",
kdevname(req->rq_dev));
goto err_done;
}
#if OLD_BUSY
while (busy_audio) sbp_sleep(HZ); /* wait a bit */
busy_data=1;
#endif /* OLD_BUSY */
if (D_S[i].audio_state==audio_playing) goto err_done;
if (d!=i) switch_drive(i);
block = req->sector; /* always numbered as 512-byte-pieces */
nsect = req->nr_sectors; /* always counted as 512-byte-pieces */
msg(DBG_BSZ,"read sector %d (%d sectors)\n", block, nsect);
#if 0
msg(DBG_MUL,"read LBA %d\n", block/4);
#endif
sbp_transfer(req);
/* if we satisfied the request from the buffer, we're done. */
if (req->nr_sectors == 0)
{
#ifdef DEBUG_GTL
printk(" do_sbpcd_request[%do](%p:%ld+%ld) end 2, Time:%li\n",
xnr, req, req->sector, req->nr_sectors, jiffies);
#endif
up(&ioctl_read_sem);
spin_lock_irq(&io_request_lock);
sbpcd_end_request(req, 1);
goto request_loop;
}
#if FUTURE
i=prepare(0,0); /* at moment not really a hassle check, but ... */
if (i!=0)
msg(DBG_INF,"\"prepare\" tells error %d -- ignored\n", i);
#endif /* FUTURE */
if (!st_spinning) cc_SpinUp();
for (data_tries=n_retries; data_tries > 0; data_tries--)
{
for (status_tries=3; status_tries > 0; status_tries--)
{
flags_cmd_out |= f_respo3;
cc_ReadStatus();
if (sbp_status() != 0) break;
if (st_check) cc_ReadError();
sbp_sleep(1); /* wait a bit, try again */
}
if (status_tries == 0)
{
msg(DBG_INF,"sbp_status: failed after 3 tries in line %d\n", __LINE__);
break;
}
sbp_read_cmd(req);
sbp_sleep(0);
if (sbp_data(req) != 0)
{
#if SAFE_MIXED
D_S[d].has_data=2; /* is really a data disk */
#endif /* SAFE_MIXED */
#ifdef DEBUG_GTL
printk(" do_sbpcd_request[%do](%p:%ld+%ld) end 3, Time:%li\n",
xnr, req, req->sector, req->nr_sectors, jiffies);
#endif
up(&ioctl_read_sem);
spin_lock_irq(&io_request_lock);
sbpcd_end_request(req, 1);
goto request_loop;
}
}
err_done:
#if OLD_BUSY
busy_data=0;
#endif /* OLD_BUSY */
#ifdef DEBUG_GTL
printk(" do_sbpcd_request[%do](%p:%ld+%ld) end 4 (error), Time:%li\n",
xnr, req, req->sector, req->nr_sectors, jiffies);
#endif
up(&ioctl_read_sem);
sbp_sleep(0); /* wait a bit, try again */
spin_lock_irq(&io_request_lock);
sbpcd_end_request(req, 0);
goto request_loop;
}
/*==========================================================================*/
/*
* build and send the READ command.
*/
static void sbp_read_cmd(struct request *req)
{
#undef OLD
int i;
int block;
D_S[d].sbp_first_frame=D_S[d].sbp_last_frame=-1; /* purge buffer */
D_S[d].sbp_current = 0;
block=req->sector/4;
if (block+D_S[d].sbp_bufsiz <= D_S[d].CDsize_frm)
D_S[d].sbp_read_frames = D_S[d].sbp_bufsiz;
else
{
D_S[d].sbp_read_frames=D_S[d].CDsize_frm-block;
/* avoid reading past end of data */
if (D_S[d].sbp_read_frames < 1)
{
msg(DBG_INF,"requested frame %d, CD size %d ???\n",
block, D_S[d].CDsize_frm);
D_S[d].sbp_read_frames=1;
}
}
flags_cmd_out = f_putcmd | f_respo2 | f_ResponseStatus | f_obey_p_check;
clr_cmdbuf();
if (famV_drive)
{
drvcmd[0]=CMDV_READ;
lba2msf(block,&drvcmd[1]); /* msf-bcd format required */
bin2bcdx(&drvcmd[1]);
bin2bcdx(&drvcmd[2]);
bin2bcdx(&drvcmd[3]);
drvcmd[4]=D_S[d].sbp_read_frames>>8;
drvcmd[5]=D_S[d].sbp_read_frames&0xff;
drvcmd[6]=0x02; /* flag "msf-bcd" */
}
else if (fam0L_drive)
{
flags_cmd_out |= f_lopsta | f_getsta | f_bit1;
if (D_S[d].xa_byte==0x20)
{
cmd_type=READ_M2;
drvcmd[0]=CMD0_READ_XA; /* "read XA frames", old drives */
drvcmd[1]=(block>>16)&0x0ff;
drvcmd[2]=(block>>8)&0x0ff;
drvcmd[3]=block&0x0ff;
drvcmd[4]=(D_S[d].sbp_read_frames>>8)&0x0ff;
drvcmd[5]=D_S[d].sbp_read_frames&0x0ff;
}
else
{
drvcmd[0]=CMD0_READ; /* "read frames", old drives */
if (D_S[d].drv_type>=drv_201)
{
lba2msf(block,&drvcmd[1]); /* msf-bcd format required */
bin2bcdx(&drvcmd[1]);
bin2bcdx(&drvcmd[2]);
bin2bcdx(&drvcmd[3]);
}
else
{
drvcmd[1]=(block>>16)&0x0ff;
drvcmd[2]=(block>>8)&0x0ff;
drvcmd[3]=block&0x0ff;
}
drvcmd[4]=(D_S[d].sbp_read_frames>>8)&0x0ff;
drvcmd[5]=D_S[d].sbp_read_frames&0x0ff;
drvcmd[6]=(D_S[d].drv_type<drv_201)?0:2; /* flag "lba or msf-bcd format" */
}
}
else if (fam1_drive)
{
drvcmd[0]=CMD1_READ;
lba2msf(block,&drvcmd[1]); /* msf-bin format required */
drvcmd[5]=(D_S[d].sbp_read_frames>>8)&0x0ff;
drvcmd[6]=D_S[d].sbp_read_frames&0x0ff;
}
else if (fam2_drive)
{
drvcmd[0]=CMD2_READ;
lba2msf(block,&drvcmd[1]); /* msf-bin format required */
drvcmd[4]=(D_S[d].sbp_read_frames>>8)&0x0ff;
drvcmd[5]=D_S[d].sbp_read_frames&0x0ff;
drvcmd[6]=0x02;
}
else if (famT_drive)
{
drvcmd[0]=CMDT_READ;
drvcmd[2]=(block>>24)&0x0ff;
drvcmd[3]=(block>>16)&0x0ff;
drvcmd[4]=(block>>8)&0x0ff;
drvcmd[5]=block&0x0ff;
drvcmd[7]=(D_S[d].sbp_read_frames>>8)&0x0ff;
drvcmd[8]=D_S[d].sbp_read_frames&0x0ff;
}
flags_cmd_out=f_putcmd;
response_count=0;
i=cmd_out();
if (i<0) msg(DBG_INF,"error giving READ command: %0d\n", i);
return;
}
/*==========================================================================*/
/*
* Check the completion of the read-data command. On success, read
* the D_S[d].sbp_bufsiz * 2048 bytes of data from the disk into buffer.
*/
static int sbp_data(struct request *req)
{
int i=0, j=0, l, frame;
u_int try=0;
u_long timeout;
u_char *p;
u_int data_tries = 0;
u_int data_waits = 0;
u_int data_retrying = 0;
int error_flag;
int xa_count;
int max_latency;
int success;
int wait;
int duration;
error_flag=0;
success=0;
#if LONG_TIMING
max_latency=9*HZ;
#else
if (D_S[d].f_multisession) max_latency=15*HZ;
else max_latency=5*HZ;
#endif
duration=jiffies;
for (frame=0;frame<D_S[d].sbp_read_frames&&!error_flag; frame++)
{
SBPCD_CLI;
del_timer(&data_timer);
data_timer.expires=jiffies+max_latency;
timed_out_data=0;
add_timer(&data_timer);
while (!timed_out_data)
{
if (D_S[d].f_multisession) try=maxtim_data*4;
else try=maxtim_data;
msg(DBG_000,"sbp_data: CDi_status loop: try=%d.\n",try);
for ( ; try!=0;try--)
{
j=inb(CDi_status);
if (!(j&s_not_data_ready)) break;;
if (!(j&s_not_result_ready)) break;
if (fam0LV_drive) if (j&s_attention) break;
}
if (!(j&s_not_data_ready)) goto data_ready;
if (try==0)
{
if (data_retrying == 0) data_waits++;
data_retrying = 1;
msg(DBG_000,"sbp_data: CDi_status loop: sleeping.\n");
sbp_sleep(1);
try = 1;
}
}
msg(DBG_INF,"sbp_data: CDi_status loop expired.\n");
data_ready:
del_timer(&data_timer);
if (timed_out_data)
{
msg(DBG_INF,"sbp_data: CDi_status timeout (timed_out_data) (%02X).\n", j);
error_flag++;
}
if (try==0)
{
msg(DBG_INF,"sbp_data: CDi_status timeout (try=0) (%02X).\n", j);
error_flag++;
}
if (!(j&s_not_result_ready))
{
msg(DBG_INF, "sbp_data: RESULT_READY where DATA_READY awaited (%02X).\n", j);
response_count=20;
j=ResponseInfo();
j=inb(CDi_status);
}
if (j&s_not_data_ready)
{
if ((D_S[d].ored_ctl_adr&0x40)==0)
msg(DBG_INF, "CD contains no data tracks.\n");
else msg(DBG_INF, "sbp_data: DATA_READY timeout (%02X).\n", j);
error_flag++;
}
SBPCD_STI;
if (error_flag) break;
msg(DBG_000, "sbp_data: beginning to read.\n");
p = D_S[d].sbp_buf + frame * CD_FRAMESIZE;
if (sbpro_type==1) OUT(CDo_sel_i_d,1);
if (cmd_type==READ_M2) {
if (do_16bit) insw(CDi_data, xa_head_buf, CD_XA_HEAD>>1);
else insb(CDi_data, xa_head_buf, CD_XA_HEAD);
}
if (do_16bit) insw(CDi_data, p, CD_FRAMESIZE>>1);
else insb(CDi_data, p, CD_FRAMESIZE);
if (cmd_type==READ_M2) {
if (do_16bit) insw(CDi_data, xa_tail_buf, CD_XA_TAIL>>1);
else insb(CDi_data, xa_tail_buf, CD_XA_TAIL);
}
D_S[d].sbp_current++;
if (sbpro_type==1) OUT(CDo_sel_i_d,0);
if (cmd_type==READ_M2)
{
for (xa_count=0;xa_count<CD_XA_HEAD;xa_count++)
sprintf(&msgbuf[xa_count*3], " %02X", xa_head_buf[xa_count]);
msgbuf[xa_count*3]=0;
msg(DBG_XA1,"xa head:%s\n", msgbuf);
}
data_retrying = 0;
data_tries++;
if (data_tries >= 1000)
{
msg(DBG_INF,"sbp_data() statistics: %d waits in %d frames.\n", data_waits, data_tries);
data_waits = data_tries = 0;
}
}
duration=jiffies-duration;
msg(DBG_TEA,"time to read %d frames: %d jiffies .\n",frame,duration);
if (famT_drive)
{
wait=8;
do
{
if (teac==2)
{
if ((i=CDi_stat_loop_T()) == -1) break;
}
else
{
sbp_sleep(1);
OUT(CDo_sel_i_d,0);
i=inb(CDi_status);
}
if (!(i&s_not_data_ready))
{
OUT(CDo_sel_i_d,1);
j=0;
do
{
if (do_16bit) i=inw(CDi_data);
else i=inb(CDi_data);
j++;
i=inb(CDi_status);
}
while (!(i&s_not_data_ready));
msg(DBG_TEA, "==========too much data (%d bytes/words)==============.\n", j);
}
if (!(i&s_not_result_ready))
{
OUT(CDo_sel_i_d,0);
l=0;
do
{
infobuf[l++]=inb(CDi_info);
i=inb(CDi_status);
}
while (!(i&s_not_result_ready));
if (infobuf[0]==0x00) success=1;
#if 1
for (j=0;j<l;j++) sprintf(&msgbuf[j*3], " %02X", infobuf[j]);
msgbuf[j*3]=0;
msg(DBG_TEA,"sbp_data info response:%s\n", msgbuf);
#endif
if (infobuf[0]==0x02)
{
error_flag++;
do
{
++recursion;
if (recursion>1) msg(DBG_TEA,"cmd_out_T READ_ERR recursion (sbp_data): %d !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!\n",recursion);
else msg(DBG_TEA,"sbp_data: CMDT_READ_ERR necessary.\n");
clr_cmdbuf();
drvcmd[0]=CMDT_READ_ERR;
j=cmd_out_T(); /* !!! recursive here !!! */
--recursion;
sbp_sleep(1);
}
while (j<0);
D_S[d].error_state=infobuf[2];
D_S[d].b3=infobuf[3];
D_S[d].b4=infobuf[4];
}
break;
}
else
{
#if 0
msg(DBG_TEA, "============= waiting for result=================.\n");
sbp_sleep(1);
#endif
}
}
while (wait--);
}
if (error_flag) /* must have been spurious D_RDY or (ATTN&&!D_RDY) */
{
msg(DBG_TEA, "================error flag: %d=================.\n", error_flag);
msg(DBG_INF,"sbp_data: read aborted by drive.\n");
#if 1
i=cc_DriveReset(); /* ugly fix to prevent a hang */
#else
i=cc_ReadError();
#endif
return (0);
}
if (fam0LV_drive)
{
SBPCD_CLI;
i=maxtim_data;
for (timeout=jiffies+HZ; time_before(jiffies, timeout); timeout--)
{
for ( ;i!=0;i--)
{
j=inb(CDi_status);
if (!(j&s_not_data_ready)) break;
if (!(j&s_not_result_ready)) break;
if (j&s_attention) break;
}
if (i != 0 || time_after_eq(jiffies, timeout)) break;
sbp_sleep(0);
i = 1;
}
if (i==0) msg(DBG_INF,"status timeout after READ.\n");
if (!(j&s_attention))
{
msg(DBG_INF,"sbp_data: timeout waiting DRV_ATTN - retrying.\n");
i=cc_DriveReset(); /* ugly fix to prevent a hang */
SBPCD_STI;
return (0);
}
SBPCD_STI;
}
#if 0
if (!success)
#endif
do
{
if (fam0LV_drive) cc_ReadStatus();
#if 1
if (famT_drive) msg(DBG_TEA, "================before ResponseStatus=================.\n", i);
#endif
i=ResponseStatus(); /* builds status_bits, returns orig. status (old) or faked p_success (new) */
#if 1
if (famT_drive) msg(DBG_TEA, "================ResponseStatus: %d=================.\n", i);
#endif
if (i<0)
{
msg(DBG_INF,"bad cc_ReadStatus after read: %02X\n", D_S[d].status_bits);
return (0);
}
}
while ((fam0LV_drive)&&(!st_check)&&(!(i&p_success)));
if (st_check)
{
i=cc_ReadError();
msg(DBG_INF,"cc_ReadError was necessary after read: %d\n",i);
return (0);
}
if (fatal_err)
{
fatal_err=0;
D_S[d].sbp_first_frame=D_S[d].sbp_last_frame=-1; /* purge buffer */
D_S[d].sbp_current = 0;
msg(DBG_INF,"sbp_data: fatal_err - retrying.\n");
return (0);
}
D_S[d].sbp_first_frame = req -> sector / 4;
D_S[d].sbp_last_frame = D_S[d].sbp_first_frame + D_S[d].sbp_read_frames - 1;
sbp_transfer(req);
return (1);
}
/*==========================================================================*/
static struct block_device_operations sbpcd_bdops =
{
owner: THIS_MODULE,
open: cdrom_open,
release: cdrom_release,
ioctl: cdrom_ioctl,
check_media_change: cdrom_media_changed,
};
/*==========================================================================*/
/*
* Open the device special file. Check that a disk is in. Read TOC.
*/
static int sbpcd_open(struct cdrom_device_info *cdi, int purpose)
{
int i;
i = MINOR(cdi->dev);
down(&ioctl_read_sem);
switch_drive(i);
/*
* try to keep an "open" counter here and lock the door if 0->1.
*/
msg(DBG_LCK,"open_count: %d -> %d\n",
D_S[d].open_count,D_S[d].open_count+1);
if (++D_S[d].open_count<=1)
{
i=LockDoor();
D_S[d].open_count=1;
if (famT_drive) msg(DBG_TEA,"sbpcd_open: before i=DiskInfo();.\n");
i=DiskInfo();
if (famT_drive) msg(DBG_TEA,"sbpcd_open: after i=DiskInfo();.\n");
if ((D_S[d].ored_ctl_adr&0x40)==0)
{
msg(DBG_INF,"CD contains no data tracks.\n");
#if SAFE_MIXED
D_S[d].has_data=0;
#endif /* SAFE_MIXED */
}
#if SAFE_MIXED
else if (D_S[d].has_data<1) D_S[d].has_data=1;
#endif /* SAFE_MIXED */
}
if (!st_spinning) cc_SpinUp();
RETURN_UP(0);
}
/*==========================================================================*/
/*
* On close, we flush all sbp blocks from the buffer cache.
*/
static void sbpcd_release(struct cdrom_device_info * cdi)
{
int i;
i = MINOR(cdi->dev);
if ((i<0) || (i>=NR_SBPCD) || (D_S[i].drv_id==-1))
{
msg(DBG_INF, "release: bad device: %04X\n", cdi->dev);
return ;
}
down(&ioctl_read_sem);
switch_drive(i);
/*
* try to keep an "open" counter here and unlock the door if 1->0.
*/
msg(DBG_LCK,"open_count: %d -> %d\n",
D_S[d].open_count,D_S[d].open_count-1);
if (D_S[d].open_count>-2) /* CDROMEJECT may have been done */
{
if (--D_S[d].open_count<=0)
{
D_S[d].sbp_first_frame=D_S[d].sbp_last_frame=-1;
invalidate_buffers(cdi->dev);
if (D_S[d].audio_state!=audio_playing)
if (D_S[d].f_eject) cc_SpinDown();
D_S[d].diskstate_flags &= ~cd_size_bit;
D_S[d].open_count=0;
#if SAFE_MIXED
D_S[d].has_data=0;
#endif /* SAFE_MIXED */
}
}
up(&ioctl_read_sem);
return ;
}
/*==========================================================================*/
/*
*
*/
static int sbpcd_media_changed( struct cdrom_device_info *cdi, int disc_nr);
static struct cdrom_device_ops sbpcd_dops = {
open: sbpcd_open,
release: sbpcd_release,
drive_status: sbpcd_drive_status,
media_changed: sbpcd_media_changed,
tray_move: sbpcd_tray_move,
lock_door: sbpcd_lock_door,
select_speed: sbpcd_select_speed,
get_last_session: sbpcd_get_last_session,
get_mcn: sbpcd_get_mcn,
reset: sbpcd_reset,
audio_ioctl: sbpcd_audio_ioctl,
dev_ioctl: sbpcd_dev_ioctl,
capability: CDC_CLOSE_TRAY | CDC_OPEN_TRAY | CDC_LOCK |
CDC_MULTI_SESSION | CDC_MEDIA_CHANGED |
CDC_MCN | CDC_PLAY_AUDIO | CDC_IOCTLS,
n_minors: 1,
};
static struct cdrom_device_info sbpcd_info = {
ops: &sbpcd_dops,
speed: 2,
capacity: 1,
name: "sbpcd",
};
/*==========================================================================*/
/*
* accept "kernel command line" parameters
* (suggested by Peter MacDonald with SLS 1.03)
*
* This is only implemented for the first controller. Should be enough to
* allow installing with a "strange" distribution kernel.
*
* use: tell LILO:
* sbpcd=0x230,SoundBlaster
* or
* sbpcd=0x300,LaserMate
* or
* sbpcd=0x338,SoundScape
* or
* sbpcd=0x2C0,Teac16bit
*
* (upper/lower case sensitive here - but all-lowercase is ok!!!).
*
* the address value has to be the CDROM PORT ADDRESS -
* not the soundcard base address.
* For the SPEA/SoundScape setup, DO NOT specify the "configuration port"
* address, but the address which is really used for the CDROM (usually 8
* bytes above).
*
*/
#if (SBPCD_ISSUE-1)
static int sbpcd_setup(char *s)
#else
int sbpcd_setup(char *s)
#endif
{
#ifndef MODULE
int p[4];
(void)get_options(s, ARRAY_SIZE(p), p);
setup_done++;
msg(DBG_INI,"sbpcd_setup called with %04X,%s\n",p[1], s);
sbpro_type=0; /* default: "LaserMate" */
if (p[0]>1) sbpro_type=p[2];
else if (!strcmp(s,str_sb)) sbpro_type=1;
else if (!strcmp(s,str_sb_l)) sbpro_type=1;
else if (!strcmp(s,str_sp)) sbpro_type=2;
else if (!strcmp(s,str_sp_l)) sbpro_type=2;
else if (!strcmp(s,str_ss)) sbpro_type=2;
else if (!strcmp(s,str_ss_l)) sbpro_type=2;
else if (!strcmp(s,str_t16)) sbpro_type=3;
else if (!strcmp(s,str_t16_l)) sbpro_type=3;
if (p[0]>0) sbpcd_ioaddr=p[1];
if (p[0]>2) max_drives=p[3];
#else
sbpcd_ioaddr = sbpcd[0];
sbpro_type = sbpcd[1];
#endif
CDo_command=sbpcd_ioaddr;
CDi_info=sbpcd_ioaddr;
CDi_status=sbpcd_ioaddr+1;
CDo_sel_i_d=sbpcd_ioaddr+1;
CDo_reset=sbpcd_ioaddr+2;
CDo_enable=sbpcd_ioaddr+3;
f_16bit=0;
if ((sbpro_type==1)||(sbpro_type==3))
{
CDi_data=sbpcd_ioaddr;
if (sbpro_type==3)
{
f_16bit=1;
sbpro_type=1;
}
}
else CDi_data=sbpcd_ioaddr+2;
return 1;
}
__setup("sbpcd=", sbpcd_setup);
/*==========================================================================*/
/*
* Sequoia S-1000 CD-ROM Interface Configuration
* as used within SPEA Media FX, Ensonic SoundScape and some Reveal cards
* The soundcard has to get jumpered for the interface type "Panasonic"
* (not Sony or Mitsumi) and to get soft-configured for
* -> configuration port address
* -> CDROM port offset (num_ports): has to be 8 here. Possibly this
* offset value determines the interface type (none, Panasonic,
* Mitsumi, Sony).
* The interface uses a configuration port (0x320, 0x330, 0x340, 0x350)
* some bytes below the real CDROM address.
*
* For the Panasonic style (LaserMate) interface and the configuration
* port 0x330, we have to use an offset of 8; so, the real CDROM port
* address is 0x338.
*/
static int __init config_spea(void)
{
/*
* base address offset between configuration port and CDROM port,
* this probably defines the interface type
* 2 (type=??): 0x00
* 8 (type=LaserMate):0x10
* 16 (type=??):0x20
* 32 (type=??):0x30
*/
int n_ports=0x10;
int irq_number=0; /* off:0x00, 2/9:0x01, 7:0x03, 12:0x05, 15:0x07 */
int dma_channel=0; /* off: 0x00, 0:0x08, 1:0x18, 3:0x38, 5:0x58, 6:0x68 */
int dack_polarity=0; /* L:0x00, H:0x80 */
int drq_polarity=0x40; /* L:0x00, H:0x40 */
int i;
#define SPEA_REG_1 sbpcd_ioaddr-0x08+4
#define SPEA_REG_2 sbpcd_ioaddr-0x08+5
OUT(SPEA_REG_1,0xFF);
i=inb(SPEA_REG_1);
if (i!=0x0F)
{
msg(DBG_SEQ,"no SPEA interface at %04X present.\n", sbpcd_ioaddr);
return (-1); /* no interface found */
}
OUT(SPEA_REG_1,0x04);
OUT(SPEA_REG_2,0xC0);
OUT(SPEA_REG_1,0x05);
OUT(SPEA_REG_2,0x10|drq_polarity|dack_polarity);
#if 1
#define SPEA_PATTERN 0x80
#else
#define SPEA_PATTERN 0x00
#endif
OUT(SPEA_REG_1,0x06);
OUT(SPEA_REG_2,dma_channel|irq_number|SPEA_PATTERN);
OUT(SPEA_REG_2,dma_channel|irq_number|SPEA_PATTERN);
OUT(SPEA_REG_1,0x09);
i=(inb(SPEA_REG_2)&0xCF)|n_ports;
OUT(SPEA_REG_2,i);
sbpro_type = 0; /* acts like a LaserMate interface now */
msg(DBG_SEQ,"found SoundScape interface at %04X.\n", sbpcd_ioaddr);
return (0);
}
#ifdef DONT_MERGE_REQUESTS
static int dont_merge_requests_fn(request_queue_t *q, struct request *req,
struct request *next, int max_segments)
{
return 0;
}
static int dont_bh_merge_fn(request_queue_t *q, struct request *req,
struct buffer_head *bh, int max_segments)
{
return 0;
}
#endif
/*==========================================================================*/
/*
* Test for presence of drive and initialize it.
* Called once at boot or load time.
*/
static devfs_handle_t devfs_handle;
#ifdef MODULE
int __init __SBPCD_INIT(void)
#else
int __init SBPCD_INIT(void)
#endif /* MODULE */
{
char nbuff[16];
int i=0, j=0;
int addr[2]={1, CDROM_PORT};
int port_index;
sti();
msg(DBG_INF,"sbpcd.c %s\n", VERSION);
#ifndef MODULE
#if DISTRIBUTION
if (!setup_done)
{
msg(DBG_INF,"Looking for Matsushita/Panasonic, CreativeLabs, Longshine, TEAC CD-ROM drives\n");
msg(DBG_INF,"= = = = = = = = = = W A R N I N G = = = = = = = = = =\n");
msg(DBG_INF,"Auto-Probing can cause a hang (f.e. touching an NE2000 card).\n");
msg(DBG_INF,"If that happens, you have to reboot and use the\n");
msg(DBG_INF,"LILO (kernel) command line feature like:\n");
msg(DBG_INF," LILO boot: ... sbpcd=0x230,SoundBlaster\n");
msg(DBG_INF,"or like:\n");
msg(DBG_INF," LILO boot: ... sbpcd=0x300,LaserMate\n");
msg(DBG_INF,"or like:\n");
msg(DBG_INF," LILO boot: ... sbpcd=0x338,SoundScape\n");
msg(DBG_INF,"with your REAL address.\n");
msg(DBG_INF,"= = = = = = = = = = END of WARNING = = = = = == = = =\n");
}
#endif /* DISTRIBUTION */
sbpcd[0]=sbpcd_ioaddr; /* possibly changed by kernel command line */
sbpcd[1]=sbpro_type; /* possibly changed by kernel command line */
#endif /* MODULE */
for (port_index=0;port_index<NUM_PROBE;port_index+=2)
{
addr[1]=sbpcd[port_index];
if (addr[1]==0) break;
if (check_region(addr[1],4))
{
msg(DBG_INF,"check_region: %03X is not free.\n",addr[1]);
continue;
}
if (sbpcd[port_index+1]==2) type=str_sp;
else if (sbpcd[port_index+1]==1) type=str_sb;
else if (sbpcd[port_index+1]==3) type=str_t16;
else type=str_lm;
sbpcd_setup((char *)type);
#if DISTRIBUTION
msg(DBG_INF,"Scanning 0x%X (%s)...\n", CDo_command, type);
#endif /* DISTRIBUTION */
if (sbpcd[port_index+1]==2)
{
i=config_spea();
if (i<0) continue;
}
#ifdef PATH_CHECK
if (check_card(addr[1])) continue;
#endif /* PATH_CHECK */
i=check_drives();
msg(DBG_INI,"check_drives done.\n");
if (i>=0) break; /* drive found */
} /* end of cycling through the set of possible I/O port addresses */
if (ndrives==0)
{
msg(DBG_INF, "No drive found.\n");
#ifdef MODULE
return -EIO;
#else
goto init_done;
#endif /* MODULE */
}
if (port_index>0)
{
msg(DBG_INF, "You should read linux/Documentation/cdrom/sbpcd\n");
msg(DBG_INF, "and then configure sbpcd.h for your hardware.\n");
}
check_datarate();
msg(DBG_INI,"check_datarate done.\n");
for (j=0;j<NR_SBPCD;j++)
{
if (D_S[j].drv_id==-1) continue;
switch_drive(j);
#if 1
if (!famL_drive) cc_DriveReset();
#endif
if (!st_spinning) cc_SpinUp();
D_S[j].sbp_first_frame = -1; /* First frame in buffer */
D_S[j].sbp_last_frame = -1; /* Last frame in buffer */
D_S[j].sbp_read_frames = 0; /* Number of frames being read to buffer */
D_S[j].sbp_current = 0; /* Frame being currently read */
D_S[j].CD_changed=1;
D_S[j].frame_size=CD_FRAMESIZE;
D_S[j].f_eject=0;
#if EJECT
if (!fam0_drive) D_S[j].f_eject=1;
#endif /* EJECT */
cc_ReadStatus();
i=ResponseStatus(); /* returns orig. status or p_busy_new */
if (famT_drive) i=ResponseStatus(); /* returns orig. status or p_busy_new */
if (i<0)
{
if (i!=-402)
msg(DBG_INF,"init: ResponseStatus returns %d.\n",i);
}
else
{
if (st_check)
{
i=cc_ReadError();
msg(DBG_INI,"init: cc_ReadError returns %d\n",i);
}
}
msg(DBG_INI,"init: first GetStatus: %d\n",i);
msg(DBG_LCS,"init: first GetStatus: error_byte=%d\n",
D_S[j].error_byte);
if (D_S[j].error_byte==aud_12)
{
timeout=jiffies+2*HZ;
do
{
i=GetStatus();
msg(DBG_INI,"init: second GetStatus: %02X\n",i);
msg(DBG_LCS,
"init: second GetStatus: error_byte=%d\n",
D_S[j].error_byte);
if (i<0) break;
if (!st_caddy_in) break;
}
while ((!st_diskok)||time_after(jiffies, timeout));
}
i=SetSpeed();
if (i>=0) D_S[j].CD_changed=1;
}
/*
* Turn on the CD audio channels.
* The addresses are obtained from SOUND_BASE (see sbpcd.h).
*/
#if SOUND_BASE
OUT(MIXER_addr,MIXER_CD_Volume); /* select SB Pro mixer register */
OUT(MIXER_data,0xCC); /* one nibble per channel, max. value: 0xFF */
#endif /* SOUND_BASE */
if (devfs_register_blkdev(MAJOR_NR, major_name, &sbpcd_bdops) != 0)
{
msg(DBG_INF, "Can't get MAJOR %d for Matsushita CDROM\n", MAJOR_NR);
#ifdef MODULE
return -EIO;
#else
goto init_done;
#endif /* MODULE */
}
blk_init_queue(BLK_DEFAULT_QUEUE(MAJOR_NR), DEVICE_REQUEST);
#ifdef DONT_MERGE_REQUESTS
(BLK_DEFAULT_QUEUE(MAJOR_NR))->back_merge_fn = dont_bh_merge_fn;
(BLK_DEFAULT_QUEUE(MAJOR_NR))->front_merge_fn = dont_bh_merge_fn;
(BLK_DEFAULT_QUEUE(MAJOR_NR))->merge_requests_fn = dont_merge_requests_fn;
#endif
blk_queue_headactive(BLK_DEFAULT_QUEUE(MAJOR_NR), 0);
read_ahead[MAJOR_NR] = buffers * (CD_FRAMESIZE / 512);
request_region(CDo_command,4,major_name);
devfs_handle = devfs_mk_dir (NULL, "sbp", NULL);
for (j=0;j<NR_SBPCD;j++)
{
struct cdrom_device_info * sbpcd_infop;
if (D_S[j].drv_id==-1) continue;
switch_drive(j);
#if SAFE_MIXED
D_S[j].has_data=0;
#endif /* SAFE_MIXED */
/*
* allocate memory for the frame buffers
*/
D_S[j].aud_buf=NULL;
D_S[j].sbp_audsiz=0;
D_S[j].sbp_bufsiz=buffers;
if (D_S[j].drv_type&drv_fam1)
if (READ_AUDIO>0) D_S[j].sbp_audsiz=READ_AUDIO;
D_S[j].sbp_buf=(u_char *) vmalloc(D_S[j].sbp_bufsiz*CD_FRAMESIZE);
if (D_S[j].sbp_buf==NULL)
{
msg(DBG_INF,"data buffer (%d frames) not available.\n",D_S[j].sbp_bufsiz);
if ((devfs_unregister_blkdev(MAJOR_NR, major_name) == -EINVAL))
{
printk("Can't unregister %s\n", major_name);
}
release_region(CDo_command,4);
blk_cleanup_queue(BLK_DEFAULT_QUEUE(MAJOR_NR));
return -EIO;
}
#ifdef MODULE
msg(DBG_INF,"data buffer size: %d frames.\n",buffers);
#endif /* MODULE */
if (D_S[j].sbp_audsiz>0)
{
D_S[j].aud_buf=(u_char *) vmalloc(D_S[j].sbp_audsiz*CD_FRAMESIZE_RAW);
if (D_S[j].aud_buf==NULL) msg(DBG_INF,"audio buffer (%d frames) not available.\n",D_S[j].sbp_audsiz);
else msg(DBG_INF,"audio buffer size: %d frames.\n",D_S[j].sbp_audsiz);
}
sbpcd_infop = vmalloc(sizeof (struct cdrom_device_info));
if (sbpcd_infop == NULL)
{
release_region(CDo_command,4);
blk_cleanup_queue(BLK_DEFAULT_QUEUE(MAJOR_NR));
return -ENOMEM;
}
D_S[j].sbpcd_infop = sbpcd_infop;
memcpy (sbpcd_infop, &sbpcd_info, sizeof(struct cdrom_device_info));
sbpcd_infop->dev = MKDEV(MAJOR_NR, j);
strncpy(sbpcd_infop->name,major_name, sizeof(sbpcd_infop->name));
sprintf (nbuff, "c%dt%d/cd", SBPCD_ISSUE - 1, D_S[j].drv_id);
sbpcd_infop->de =
devfs_register (devfs_handle, nbuff, DEVFS_FL_DEFAULT,
MAJOR_NR, j, S_IFBLK | S_IRUGO | S_IWUGO,
&sbpcd_bdops, NULL);
if (register_cdrom(sbpcd_infop))
{
printk(" sbpcd: Unable to register with Uniform CD-ROm driver\n");
}
/*
* set the block size
*/
sbpcd_blocksizes[j]=CD_FRAMESIZE;
}
blksize_size[MAJOR_NR]=sbpcd_blocksizes;
#ifndef MODULE
init_done:
#if !(SBPCD_ISSUE-1)
#ifdef CONFIG_SBPCD2
sbpcd2_init();
#endif /* CONFIG_SBPCD2 */
#ifdef CONFIG_SBPCD3
sbpcd3_init();
#endif /* CONFIG_SBPCD3 */
#ifdef CONFIG_SBPCD4
sbpcd4_init();
#endif /* CONFIG_SBPCD4 */
#endif /* !(SBPCD_ISSUE-1) */
#endif /* MODULE */
return 0;
}
/*==========================================================================*/
#ifdef MODULE
void sbpcd_exit(void)
{
int j;
if ((devfs_unregister_blkdev(MAJOR_NR, major_name) == -EINVAL))
{
msg(DBG_INF, "What's that: can't unregister %s.\n", major_name);
return;
}
release_region(CDo_command,4);
blk_cleanup_queue(BLK_DEFAULT_QUEUE(MAJOR_NR));
devfs_unregister (devfs_handle);
for (j=0;j<NR_SBPCD;j++)
{
if (D_S[j].drv_id==-1) continue;
vfree(D_S[j].sbp_buf);
if (D_S[j].sbp_audsiz>0) vfree(D_S[j].aud_buf);
if ((unregister_cdrom(D_S[j].sbpcd_infop) == -EINVAL))
{
msg(DBG_INF, "What's that: can't unregister info %s.\n", major_name);
return;
}
vfree(D_S[j].sbpcd_infop);
}
msg(DBG_INF, "%s module released.\n", major_name);
}
#ifdef MODULE
module_init(__SBPCD_INIT) /*HACK!*/;
#endif
module_exit(sbpcd_exit);
#endif /* MODULE */
/*==========================================================================*/
/*
* Check if the media has changed in the CD-ROM drive.
* used externally (isofs/inode.c, fs/buffer.c)
*/
static int sbpcd_chk_disk_change(kdev_t full_dev)
{
int i;
msg(DBG_CHK,"media_check (%d) called\n", MINOR(full_dev));
i=MINOR(full_dev);
if (D_S[i].CD_changed==0xFF)
{
D_S[i].CD_changed=0;
msg(DBG_CHK,"medium changed (drive %d)\n", i);
/* BUG! Should invalidate buffers! --AJK */
invalidate_buffers(full_dev);
D_S[d].diskstate_flags &= ~toc_bit;
D_S[d].diskstate_flags &= ~cd_size_bit;
#if SAFE_MIXED
D_S[d].has_data=0;
#endif /* SAFE_MIXED */
return (1);
}
else
return (0);
}
static int sbpcd_media_changed( struct cdrom_device_info *cdi, int disc_nr)
{
return sbpcd_chk_disk_change(cdi->dev);
}
MODULE_LICENSE("GPL");
/*==========================================================================*/
/*
* Overrides for Emacs so that we follow Linus's tabbing style.
* Emacs will notice this stuff at the end of the file and automatically
* adjust the settings for this buffer only. This must remain at the end
* of the file.
* ---------------------------------------------------------------------------
* Local variables:
* c-indent-level: 8
* c-brace-imaginary-offset: 0
* c-brace-offset: -8
* c-argdecl-indent: 8
* c-label-offset: -8
* c-continued-statement-offset: 8
* c-continued-brace-offset: 0
* End:
*/
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