Linux-2.6.12-rc2

[linux-2.6/linux-acpi-2.6/ibm-acpi-2.6.git] / drivers / scsi / fdomain.c

/* fdomain.c -- Future Domain TMC-16x0 SCSI driver
 * Created: Sun May  3 18:53:19 1992 by faith@cs.unc.edu
 * Revised: Mon Dec 28 21:59:02 1998 by faith@acm.org
 * Author: Rickard E. Faith, faith@cs.unc.edu
 * Copyright 1992-1996, 1998 Rickard E. Faith (faith@acm.org)
 * Shared IRQ supported added 7/7/2001  Alan Cox <alan@redhat.com>

 * 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.

 * This program is distributed in the hope that it will be useful, but
 * WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * General Public License for more details.

 * You should have received a copy of the GNU General Public License along
 * with this program; if not, write to the Free Software Foundation, Inc.,
 * 675 Mass Ave, Cambridge, MA 02139, USA.

 **************************************************************************

 SUMMARY:

 Future Domain BIOS versions supported for autodetect:
    2.0, 3.0, 3.2, 3.4 (1.0), 3.5 (2.0), 3.6, 3.61
 Chips are supported:
    TMC-1800, TMC-18C50, TMC-18C30, TMC-36C70
 Boards supported:
    Future Domain TMC-1650, TMC-1660, TMC-1670, TMC-1680, TMC-1610M/MER/MEX
    Future Domain TMC-3260 (PCI)
    Quantum ISA-200S, ISA-250MG
    Adaptec AHA-2920A (PCI) [BUT *NOT* AHA-2920C -- use aic7xxx instead]
    IBM ?
 LILO/INSMOD command-line options:
    fdomain=<PORT_BASE>,<IRQ>[,<ADAPTER_ID>]


    
 NOTE:

 The Adaptec AHA-2920C has an Adaptec AIC-7850 chip on it.
 Use the aic7xxx driver for this board.
       
 The Adaptec AHA-2920A has a Future Domain chip on it, so this is the right
 driver for that card.  Unfortunately, the boxes will probably just say
 "2920", so you'll have to look on the card for a Future Domain logo, or a
 letter after the 2920.

 
 
 THANKS:

 Thanks to Adaptec for providing PCI boards for testing.  This finally
 enabled me to test the PCI detection and correct it for PCI boards that do
 not have a BIOS at a standard ISA location.  For PCI boards, LILO/INSMOD
 command-line options should no longer be needed.  --RF 18Nov98


 
 DESCRIPTION:
 
 This is the Linux low-level SCSI driver for Future Domain TMC-1660/1680
 TMC-1650/1670, and TMC-3260 SCSI host adapters.  The 1650 and 1670 have a
 25-pin external connector, whereas the 1660 and 1680 have a SCSI-2 50-pin
 high-density external connector.  The 1670 and 1680 have floppy disk
 controllers built in.  The TMC-3260 is a PCI bus card.

 Future Domain's older boards are based on the TMC-1800 chip, and this
 driver was originally written for a TMC-1680 board with the TMC-1800 chip.
 More recently, boards are being produced with the TMC-18C50 and TMC-18C30
 chips.  The latest and greatest board may not work with this driver.  If
 you have to patch this driver so that it will recognize your board's BIOS
 signature, then the driver may fail to function after the board is
 detected.

 Please note that the drive ordering that Future Domain implemented in BIOS
 versions 3.4 and 3.5 is the opposite of the order (currently) used by the
 rest of the SCSI industry.  If you have BIOS version 3.4 or 3.5, and have
 more than one drive, then the drive ordering will be the reverse of that
 which you see under DOS.  For example, under DOS SCSI ID 0 will be D: and
 SCSI ID 1 will be C: (the boot device).  Under Linux, SCSI ID 0 will be
 /dev/sda and SCSI ID 1 will be /dev/sdb.  The Linux ordering is consistent
 with that provided by all the other SCSI drivers for Linux.  If you want
 this changed, you will probably have to patch the higher level SCSI code.
 If you do so, please send me patches that are protected by #ifdefs.

 If you have a TMC-8xx or TMC-9xx board, then this is not the driver for
 your board.  Please refer to the Seagate driver for more information and
 possible support.

 
 
 HISTORY:

 Linux       Driver      Driver
 Version     Version     Date         Support/Notes

             0.0          3 May 1992  V2.0 BIOS; 1800 chip
 0.97        1.9         28 Jul 1992
 0.98.6      3.1         27 Nov 1992
 0.99        3.2          9 Dec 1992

 0.99.3      3.3         10 Jan 1993  V3.0 BIOS
 0.99.5      3.5         18 Feb 1993
 0.99.10     3.6         15 May 1993  V3.2 BIOS; 18C50 chip
 0.99.11     3.17         3 Jul 1993  (now under RCS)
 0.99.12     3.18        13 Aug 1993
 0.99.14     5.6         31 Oct 1993  (reselection code removed)

 0.99.15     5.9         23 Jan 1994  V3.4 BIOS (preliminary)
 1.0.8/1.1.1 5.15         1 Apr 1994  V3.4 BIOS; 18C30 chip (preliminary)
 1.0.9/1.1.3 5.16         7 Apr 1994  V3.4 BIOS; 18C30 chip
 1.1.38      5.18        30 Jul 1994  36C70 chip (PCI version of 18C30)
 1.1.62      5.20         2 Nov 1994  V3.5 BIOS
 1.1.73      5.22         7 Dec 1994  Quantum ISA-200S board; V2.0 BIOS

 1.1.82      5.26        14 Jan 1995  V3.5 BIOS; TMC-1610M/MER/MEX board
 1.2.10      5.28         5 Jun 1995  Quantum ISA-250MG board; V2.0, V2.01 BIOS
 1.3.4       5.31        23 Jun 1995  PCI BIOS-32 detection (preliminary)
 1.3.7       5.33         4 Jul 1995  PCI BIOS-32 detection
 1.3.28      5.36        17 Sep 1995  V3.61 BIOS; LILO command-line support
 1.3.34      5.39        12 Oct 1995  V3.60 BIOS; /proc
 1.3.72      5.39         8 Feb 1996  Adaptec AHA-2920 board
 1.3.85      5.41         4 Apr 1996
 2.0.12      5.44         8 Aug 1996  Use ID 7 for all PCI cards
 2.1.1       5.45         2 Oct 1996  Update ROM accesses for 2.1.x
 2.1.97      5.46        23 Apr 1998  Rewritten PCI detection routines [mj]
 2.1.11x     5.47         9 Aug 1998  Touched for 8 SCSI disk majors support
             5.48        18 Nov 1998  BIOS no longer needed for PCI detection
 2.2.0       5.50        28 Dec 1998  Support insmod parameters
 

 REFERENCES USED:

 "TMC-1800 SCSI Chip Specification (FDC-1800T)", Future Domain Corporation,
 1990.

 "Technical Reference Manual: 18C50 SCSI Host Adapter Chip", Future Domain
 Corporation, January 1992.

 "LXT SCSI Products: Specifications and OEM Technical Manual (Revision
 B/September 1991)", Maxtor Corporation, 1991.

 "7213S product Manual (Revision P3)", Maxtor Corporation, 1992.

 "Draft Proposed American National Standard: Small Computer System
 Interface - 2 (SCSI-2)", Global Engineering Documents. (X3T9.2/86-109,
 revision 10h, October 17, 1991)

 Private communications, Drew Eckhardt (drew@cs.colorado.edu) and Eric
 Youngdale (ericy@cais.com), 1992.

 Private communication, Tuong Le (Future Domain Engineering department),
 1994. (Disk geometry computations for Future Domain BIOS version 3.4, and
 TMC-18C30 detection.)

 Hogan, Thom. The Programmer's PC Sourcebook. Microsoft Press, 1988. Page
 60 (2.39: Disk Partition Table Layout).

 "18C30 Technical Reference Manual", Future Domain Corporation, 1993, page
 6-1.


 
 NOTES ON REFERENCES:

 The Maxtor manuals were free.  Maxtor telephone technical support is
 great!

 The Future Domain manuals were $25 and $35.  They document the chip, not
 the TMC-16x0 boards, so some information I had to guess at.  In 1992,
 Future Domain sold DOS BIOS source for $250 and the UN*X driver source was
 $750, but these required a non-disclosure agreement, so even if I could
 have afforded them, they would *not* have been useful for writing this
 publically distributable driver.  Future Domain technical support has
 provided some information on the phone and have sent a few useful FAXs.
 They have been much more helpful since they started to recognize that the
 word "Linux" refers to an operating system :-).

 

 ALPHA TESTERS:

 There are many other alpha testers that come and go as the driver
 develops.  The people listed here were most helpful in times of greatest
 need (mostly early on -- I've probably left out a few worthy people in
 more recent times):

 Todd Carrico (todd@wutc.wustl.edu), Dan Poirier (poirier@cs.unc.edu ), Ken
 Corey (kenc@sol.acs.unt.edu), C. de Bruin (bruin@bruin@sterbbs.nl), Sakari
 Aaltonen (sakaria@vipunen.hit.fi), John Rice (rice@xanth.cs.odu.edu), Brad
 Yearwood (brad@optilink.com), and Ray Toy (toy@soho.crd.ge.com).

 Special thanks to Tien-Wan Yang (twyang@cs.uh.edu), who graciously lent me
 his 18C50-based card for debugging.  He is the sole reason that this
 driver works with the 18C50 chip.

 Thanks to Dave Newman (dnewman@crl.com) for providing initial patches for
 the version 3.4 BIOS.

 Thanks to James T. McKinley (mckinley@msupa.pa.msu.edu) for providing
 patches that support the TMC-3260, a PCI bus card with the 36C70 chip.
 The 36C70 chip appears to be "completely compatible" with the 18C30 chip.

 Thanks to Eric Kasten (tigger@petroglyph.cl.msu.edu) for providing the
 patch for the version 3.5 BIOS.

 Thanks for Stephen Henson (shenson@nyx10.cs.du.edu) for providing the
 patch for the Quantum ISA-200S SCSI adapter.
 
 Thanks to Adam Bowen for the signature to the 1610M/MER/MEX scsi cards, to
 Martin Andrews (andrewm@ccfadm.eeg.ccf.org) for the signature to some
 random TMC-1680 repackaged by IBM; and to Mintak Ng (mintak@panix.com) for
 the version 3.61 BIOS signature.

 Thanks for Mark Singer (elf@netcom.com) and Richard Simpson
 (rsimpson@ewrcsdra.demon.co.uk) for more Quantum signatures and detective
 work on the Quantum RAM layout.

 Special thanks to James T. McKinley (mckinley@msupa.pa.msu.edu) for
 providing patches for proper PCI BIOS32-mediated detection of the TMC-3260
 card (a PCI bus card with the 36C70 chip).  Please send James PCI-related
 bug reports.

 Thanks to Tom Cavin (tec@usa1.com) for preliminary command-line option
 patches.

 New PCI detection code written by Martin Mares <mj@atrey.karlin.mff.cuni.cz>

 Insmod parameter code based on patches from Daniel Graham
 <graham@balance.uoregon.edu>. 
 
 All of the alpha testers deserve much thanks.



 NOTES ON USER DEFINABLE OPTIONS:

 DEBUG: This turns on the printing of various debug information.

 ENABLE_PARITY: This turns on SCSI parity checking.  With the current
 driver, all attached devices must support SCSI parity.  If none of your
 devices support parity, then you can probably get the driver to work by
 turning this option off.  I have no way of testing this, however, and it
 would appear that no one ever uses this option.

 FIFO_COUNT: The host adapter has an 8K cache (host adapters based on the
 18C30 chip have a 2k cache).  When this many 512 byte blocks are filled by
 the SCSI device, an interrupt will be raised.  Therefore, this could be as
 low as 0, or as high as 16.  Note, however, that values which are too high
 or too low seem to prevent any interrupts from occurring, and thereby lock
 up the machine.  I have found that 2 is a good number, but throughput may
 be increased by changing this value to values which are close to 2.
 Please let me know if you try any different values.

 RESELECTION: This is no longer an option, since I gave up trying to
 implement it in version 4.x of this driver.  It did not improve
 performance at all and made the driver unstable (because I never found one
 of the two race conditions which were introduced by the multiple
 outstanding command code).  The instability seems a very high price to pay
 just so that you don't have to wait for the tape to rewind.  If you want
 this feature implemented, send me patches.  I'll be happy to send a copy
 of my (broken) driver to anyone who would like to see a copy.

 **************************************************************************/

#include <linux/config.h>
#include <linux/module.h>
#include <linux/init.h>
#include <linux/interrupt.h>
#include <linux/blkdev.h>
#include <linux/spinlock.h>
#include <linux/errno.h>
#include <linux/string.h>
#include <linux/ioport.h>
#include <linux/proc_fs.h>
#include <linux/pci.h>
#include <linux/stat.h>
#include <linux/delay.h>
#include <scsi/scsicam.h>

#include <asm/io.h>
#include <asm/system.h>

#include <scsi/scsi.h>
#include <scsi/scsi_cmnd.h>
#include <scsi/scsi_device.h>
#include <scsi/scsi_host.h>
#include <scsi/scsi_ioctl.h>
#include "fdomain.h"

MODULE_AUTHOR("Rickard E. Faith");
MODULE_DESCRIPTION("Future domain SCSI driver");
MODULE_LICENSE("GPL");

  
#define VERSION          "$Revision: 5.51 $"

/* START OF USER DEFINABLE OPTIONS */

#define DEBUG            0      /* Enable debugging output */
#define ENABLE_PARITY    1      /* Enable SCSI Parity */
#define FIFO_COUNT       2      /* Number of 512 byte blocks before INTR */

/* END OF USER DEFINABLE OPTIONS */

#if DEBUG
#define EVERY_ACCESS     0      /* Write a line on every scsi access */
#define ERRORS_ONLY      1      /* Only write a line if there is an error */
#define DEBUG_DETECT     0      /* Debug fdomain_16x0_detect() */
#define DEBUG_MESSAGES   1      /* Debug MESSAGE IN phase */
#define DEBUG_ABORT      1      /* Debug abort() routine */
#define DEBUG_RESET      1      /* Debug reset() routine */
#define DEBUG_RACE       1      /* Debug interrupt-driven race condition */
#else
#define EVERY_ACCESS     0      /* LEAVE THESE ALONE--CHANGE THE ONES ABOVE */
#define ERRORS_ONLY      0
#define DEBUG_DETECT     0
#define DEBUG_MESSAGES   0
#define DEBUG_ABORT      0
#define DEBUG_RESET      0
#define DEBUG_RACE       0
#endif

/* Errors are reported on the line, so we don't need to report them again */
#if EVERY_ACCESS
#undef ERRORS_ONLY
#define ERRORS_ONLY      0
#endif

#if ENABLE_PARITY
#define PARITY_MASK      0x08
#else
#define PARITY_MASK      0x00
#endif

enum chip_type {
   unknown          = 0x00,
   tmc1800          = 0x01,
   tmc18c50         = 0x02,
   tmc18c30         = 0x03,
};

enum {
   in_arbitration   = 0x02,
   in_selection     = 0x04,
   in_other         = 0x08,
   disconnect       = 0x10,
   aborted          = 0x20,
   sent_ident       = 0x40,
};

enum in_port_type {
   Read_SCSI_Data   =  0,
   SCSI_Status      =  1,
   TMC_Status       =  2,
   FIFO_Status      =  3,       /* tmc18c50/tmc18c30 only */
   Interrupt_Cond   =  4,       /* tmc18c50/tmc18c30 only */
   LSB_ID_Code      =  5,
   MSB_ID_Code      =  6,
   Read_Loopback    =  7,
   SCSI_Data_NoACK  =  8,
   Interrupt_Status =  9,
   Configuration1   = 10,
   Configuration2   = 11,       /* tmc18c50/tmc18c30 only */
   Read_FIFO        = 12,
   FIFO_Data_Count  = 14
};

enum out_port_type {
   Write_SCSI_Data  =  0,
   SCSI_Cntl        =  1,
   Interrupt_Cntl   =  2,
   SCSI_Mode_Cntl   =  3,
   TMC_Cntl         =  4,
   Memory_Cntl      =  5,       /* tmc18c50/tmc18c30 only */
   Write_Loopback   =  7,
   IO_Control       = 11,       /* tmc18c30 only */
   Write_FIFO       = 12
};

/* .bss will zero all the static variables below */
static int               port_base;
static unsigned long     bios_base;
static void __iomem *    bios_mem;
static int               bios_major;
static int               bios_minor;
static int               PCI_bus;
static int               Quantum;       /* Quantum board variant */
static int               interrupt_level;
static volatile int      in_command;
static struct scsi_cmnd  *current_SC;
static enum chip_type    chip              = unknown;
static int               adapter_mask;
static int               this_id;
static int               setup_called;

#if DEBUG_RACE
static volatile int      in_interrupt_flag;
#endif

static int               FIFO_Size = 0x2000; /* 8k FIFO for
                                                pre-tmc18c30 chips */

static irqreturn_t       do_fdomain_16x0_intr( int irq, void *dev_id,
                                            struct pt_regs * regs );
/* Allow insmod parameters to be like LILO parameters.  For example:
   insmod fdomain fdomain=0x140,11 */
static char * fdomain = NULL;
module_param(fdomain, charp, 0);

static unsigned long addresses[] = {
   0xc8000,
   0xca000,
   0xce000,
   0xde000,
   0xcc000,             /* Extra addresses for PCI boards */
   0xd0000,
   0xe0000,
};
#define ADDRESS_COUNT (sizeof( addresses ) / sizeof( unsigned ))
                       
static unsigned short ports[] = { 0x140, 0x150, 0x160, 0x170 };
#define PORT_COUNT (sizeof( ports ) / sizeof( unsigned short ))

static unsigned short ints[] = { 3, 5, 10, 11, 12, 14, 15, 0 };

/*

  READ THIS BEFORE YOU ADD A SIGNATURE!

  READING THIS SHORT NOTE CAN SAVE YOU LOTS OF TIME!

  READ EVERY WORD, ESPECIALLY THE WORD *NOT*

  This driver works *ONLY* for Future Domain cards using the TMC-1800,
  TMC-18C50, or TMC-18C30 chip.  This includes models TMC-1650, 1660, 1670,
  and 1680.  These are all 16-bit cards.

  The following BIOS signature signatures are for boards which do *NOT*
  work with this driver (these TMC-8xx and TMC-9xx boards may work with the
  Seagate driver):

  FUTURE DOMAIN CORP. (C) 1986-1988 V4.0I 03/16/88
  FUTURE DOMAIN CORP. (C) 1986-1989 V5.0C2/14/89
  FUTURE DOMAIN CORP. (C) 1986-1989 V6.0A7/28/89
  FUTURE DOMAIN CORP. (C) 1986-1990 V6.0105/31/90
  FUTURE DOMAIN CORP. (C) 1986-1990 V6.0209/18/90
  FUTURE DOMAIN CORP. (C) 1986-1990 V7.009/18/90
  FUTURE DOMAIN CORP. (C) 1992 V8.00.004/02/92

  (The cards which do *NOT* work are all 8-bit cards -- although some of
  them have a 16-bit form-factor, the upper 8-bits are used only for IRQs
  and are *NOT* used for data.  You can tell the difference by following
  the tracings on the circuit board -- if only the IRQ lines are involved,
  you have a "8-bit" card, and should *NOT* use this driver.)

*/

static struct signature {
   const char *signature;
   int  sig_offset;
   int  sig_length;
   int  major_bios_version;
   int  minor_bios_version;
   int  flag; /* 1 == PCI_bus, 2 == ISA_200S, 3 == ISA_250MG, 4 == ISA_200S */
} signatures[] = {
   /*          1         2         3         4         5         6 */
   /* 123456789012345678901234567890123456789012345678901234567890 */
   { "FUTURE DOMAIN CORP. (C) 1986-1990 1800-V2.07/28/89",  5, 50,  2,  0, 0 },
   { "FUTURE DOMAIN CORP. (C) 1986-1990 1800-V1.07/28/89",  5, 50,  2,  0, 0 },
   { "FUTURE DOMAIN CORP. (C) 1986-1990 1800-V2.07/28/89", 72, 50,  2,  0, 2 },
   { "FUTURE DOMAIN CORP. (C) 1986-1990 1800-V2.0",        73, 43,  2,  0, 3 },
   { "FUTURE DOMAIN CORP. (C) 1991 1800-V2.0.",            72, 39,  2,  0, 4 },
   { "FUTURE DOMAIN CORP. (C) 1992 V3.00.004/02/92",        5, 44,  3,  0, 0 },
   { "FUTURE DOMAIN TMC-18XX (C) 1993 V3.203/12/93",        5, 44,  3,  2, 0 },
   { "IBM F1 P2 BIOS v1.0104/29/93",                        5, 28,  3, -1, 0 },
   { "Future Domain Corp. V1.0008/18/93",                   5, 33,  3,  4, 0 },
   { "Future Domain Corp. V1.0008/18/93",                  26, 33,  3,  4, 1 },
   { "Adaptec AHA-2920 PCI-SCSI Card",                     42, 31,  3, -1, 1 },
   { "IBM F1 P264/32",                                      5, 14,  3, -1, 1 },
                                /* This next signature may not be a 3.5 bios */
   { "Future Domain Corp. V2.0108/18/93",                   5, 33,  3,  5, 0 },
   { "FUTURE DOMAIN CORP.  V3.5008/18/93",                  5, 34,  3,  5, 0 },
   { "FUTURE DOMAIN 18c30/18c50/1800 (C) 1994 V3.5",        5, 44,  3,  5, 0 },
   { "FUTURE DOMAIN CORP.  V3.6008/18/93",                  5, 34,  3,  6, 0 },
   { "FUTURE DOMAIN CORP.  V3.6108/18/93",                  5, 34,  3,  6, 0 },
   { "FUTURE DOMAIN TMC-18XX",                              5, 22, -1, -1, 0 },

   /* READ NOTICE ABOVE *BEFORE* YOU WASTE YOUR TIME ADDING A SIGNATURE
    Also, fix the disk geometry code for your signature and send your
    changes for faith@cs.unc.edu.  Above all, do *NOT* change any old
    signatures!

    Note that the last line will match a "generic" 18XX bios.  Because
    Future Domain has changed the host SCSI ID and/or the location of the
    geometry information in the on-board RAM area for each of the first
    three BIOS's, it is still important to enter a fully qualified
    signature in the table for any new BIOS's (after the host SCSI ID and
    geometry location are verified). */
};

#define SIGNATURE_COUNT (sizeof( signatures ) / sizeof( struct signature ))

static void print_banner( struct Scsi_Host *shpnt )
{
   if (!shpnt) return;          /* This won't ever happen */

   if (bios_major < 0 && bios_minor < 0) {
      printk(KERN_INFO "scsi%d: <fdomain> No BIOS; using scsi id %d\n",
              shpnt->host_no, shpnt->this_id);
   } else {
      printk(KERN_INFO "scsi%d: <fdomain> BIOS version ", shpnt->host_no);

      if (bios_major >= 0) printk("%d.", bios_major);
      else                 printk("?.");

      if (bios_minor >= 0) printk("%d", bios_minor);
      else                 printk("?.");
   
      printk( " at 0x%lx using scsi id %d\n",
              bios_base, shpnt->this_id );
   }

                                /* If this driver works for later FD PCI
                                   boards, we will have to modify banner
                                   for additional PCI cards, but for now if
                                   it's PCI it's a TMC-3260 - JTM */
   printk(KERN_INFO "scsi%d: <fdomain> %s chip at 0x%x irq ",
           shpnt->host_no,
           chip == tmc1800 ? "TMC-1800" : (chip == tmc18c50 ? "TMC-18C50" : (chip == tmc18c30 ? (PCI_bus ? "TMC-36C70 (PCI bus)" : "TMC-18C30") : "Unknown")),
           port_base);

   if (interrupt_level)
        printk("%d", interrupt_level);
   else
        printk("<none>");

   printk( "\n" );
}

int fdomain_setup(char *str)
{
        int ints[4];

        (void)get_options(str, ARRAY_SIZE(ints), ints);

        if (setup_called++ || ints[0] < 2 || ints[0] > 3) {
                printk(KERN_INFO "scsi: <fdomain> Usage: fdomain=<PORT_BASE>,<IRQ>[,<ADAPTER_ID>]\n");
                printk(KERN_ERR "scsi: <fdomain> Bad LILO/INSMOD parameters?\n");
                return 0;
        }

        port_base       = ints[0] >= 1 ? ints[1] : 0;
        interrupt_level = ints[0] >= 2 ? ints[2] : 0;
        this_id         = ints[0] >= 3 ? ints[3] : 0;
   
        bios_major = bios_minor = -1; /* Use geometry for BIOS version >= 3.4 */
        ++setup_called;
        return 1;
}

__setup("fdomain=", fdomain_setup);


static void do_pause(unsigned amount)   /* Pause for amount*10 milliseconds */
{
        mdelay(10*amount);
}

inline static void fdomain_make_bus_idle( void )
{
   outb(0, port_base + SCSI_Cntl);
   outb(0, port_base + SCSI_Mode_Cntl);
   if (chip == tmc18c50 || chip == tmc18c30)
         outb(0x21 | PARITY_MASK, port_base + TMC_Cntl); /* Clear forced intr. */
   else
         outb(0x01 | PARITY_MASK, port_base + TMC_Cntl);
}

static int fdomain_is_valid_port( int port )
{
#if DEBUG_DETECT 
   printk( " (%x%x),",
           inb( port + MSB_ID_Code ), inb( port + LSB_ID_Code ) );
#endif

   /* The MCA ID is a unique id for each MCA compatible board.  We
      are using ISA boards, but Future Domain provides the MCA ID
      anyway.  We can use this ID to ensure that this is a Future
      Domain TMC-1660/TMC-1680.
    */

   if (inb( port + LSB_ID_Code ) != 0xe9) { /* test for 0x6127 id */
      if (inb( port + LSB_ID_Code ) != 0x27) return 0;
      if (inb( port + MSB_ID_Code ) != 0x61) return 0;
      chip = tmc1800;
   } else {                                 /* test for 0xe960 id */
      if (inb( port + MSB_ID_Code ) != 0x60) return 0;
      chip = tmc18c50;

                                /* Try to toggle 32-bit mode.  This only
                                   works on an 18c30 chip.  (User reports
                                   say this works, so we should switch to
                                   it in the near future.) */

      outb( 0x80, port + IO_Control );
      if ((inb( port + Configuration2 ) & 0x80) == 0x80) {
         outb( 0x00, port + IO_Control );
         if ((inb( port + Configuration2 ) & 0x80) == 0x00) {
            chip = tmc18c30;
            FIFO_Size = 0x800;  /* 2k FIFO */
         }
      }
                                /* If that failed, we are an 18c50. */
   }

   return 1;
}

static int fdomain_test_loopback( void )
{
   int i;
   int result;

   for (i = 0; i < 255; i++) {
      outb( i, port_base + Write_Loopback );
      result = inb( port_base + Read_Loopback );
      if (i != result)
            return 1;
   }
   return 0;
}

/* fdomain_get_irq assumes that we have a valid MCA ID for a
   TMC-1660/TMC-1680 Future Domain board.  Now, check to be sure the
   bios_base matches these ports.  If someone was unlucky enough to have
   purchased more than one Future Domain board, then they will have to
   modify this code, as we only detect one board here.  [The one with the
   lowest bios_base.]

   Note that this routine is only used for systems without a PCI BIOS32
   (e.g., ISA bus).  For PCI bus systems, this routine will likely fail
   unless one of the IRQs listed in the ints array is used by the board.
   Sometimes it is possible to use the computer's BIOS setup screen to
   configure a PCI system so that one of these IRQs will be used by the
   Future Domain card. */

static int fdomain_get_irq( int base )
{
   int options = inb(base + Configuration1);

#if DEBUG_DETECT
   printk("scsi: <fdomain> Options = %x\n", options);
#endif
 
   /* Check for board with lowest bios_base --
      this isn't valid for the 18c30 or for
      boards on the PCI bus, so just assume we
      have the right board. */

   if (chip != tmc18c30 && !PCI_bus && addresses[(options & 0xc0) >> 6 ] != bios_base)
        return 0;
   return ints[(options & 0x0e) >> 1];
}

static int fdomain_isa_detect( int *irq, int *iobase )
{
#ifndef PCMCIA
   int i, j;
   int base = 0xdeadbeef;
   int flag = 0;

#if DEBUG_DETECT
   printk( "scsi: <fdomain> fdomain_isa_detect:" );
#endif

   for (i = 0; i < ADDRESS_COUNT; i++) {
      void __iomem *p = ioremap(addresses[i], 0x2000);
      if (!p)
        continue;
#if DEBUG_DETECT
      printk( " %lx(%lx),", addresses[i], bios_base );
#endif
      for (j = 0; j < SIGNATURE_COUNT; j++) {
         if (check_signature(p + signatures[j].sig_offset,
                             signatures[j].signature,
                             signatures[j].sig_length )) {
            bios_major = signatures[j].major_bios_version;
            bios_minor = signatures[j].minor_bios_version;
            PCI_bus    = (signatures[j].flag == 1);
            Quantum    = (signatures[j].flag > 1) ? signatures[j].flag : 0;
            bios_base  = addresses[i];
            bios_mem   = p;
            goto found;
         }
      }
      iounmap(p);
   }
 
found:
   if (bios_major == 2) {
      /* The TMC-1660/TMC-1680 has a RAM area just after the BIOS ROM.
         Assuming the ROM is enabled (otherwise we wouldn't have been
         able to read the ROM signature :-), then the ROM sets up the
         RAM area with some magic numbers, such as a list of port
         base addresses and a list of the disk "geometry" reported to
         DOS (this geometry has nothing to do with physical geometry).
       */

      switch (Quantum) {
      case 2:                   /* ISA_200S */
      case 3:                   /* ISA_250MG */
         base = readb(bios_mem + 0x1fa2) + (readb(bios_mem + 0x1fa3) << 8);
         break;
      case 4:                   /* ISA_200S (another one) */
         base = readb(bios_mem + 0x1fa3) + (readb(bios_mem + 0x1fa4) << 8);
         break;
      default:
         base = readb(bios_mem + 0x1fcc) + (readb(bios_mem + 0x1fcd) << 8);
         break;
      }
   
#if DEBUG_DETECT
      printk( " %x,", base );
#endif

      for (i = 0; i < PORT_COUNT; i++) {
        if (base == ports[i]) {
                if (!request_region(base, 0x10, "fdomain"))
                        break;
                if (!fdomain_is_valid_port(base)) {
                        release_region(base, 0x10);
                        break;
                }
                *irq    = fdomain_get_irq( base );
                *iobase = base;
                return 1;
        }
      }

      /* This is a bad sign.  It usually means that someone patched the
         BIOS signature list (the signatures variable) to contain a BIOS
         signature for a board *OTHER THAN* the TMC-1660/TMC-1680. */
      
#if DEBUG_DETECT
      printk( " RAM FAILED, " );
#endif
   }

   /* Anyway, the alternative to finding the address in the RAM is to just
      search through every possible port address for one that is attached
      to the Future Domain card.  Don't panic, though, about reading all
      these random port addresses -- there are rumors that the Future
      Domain BIOS does something very similar.

      Do not, however, check ports which the kernel knows are being used by
      another driver. */

   for (i = 0; i < PORT_COUNT; i++) {
      base = ports[i];
      if (!request_region(base, 0x10, "fdomain")) {
#if DEBUG_DETECT
         printk( " (%x inuse),", base );
#endif
         continue;
      }
#if DEBUG_DETECT
      printk( " %x,", base );
#endif
      flag = fdomain_is_valid_port(base);
      if (flag)
        break;
      release_region(base, 0x10);
   }

#if DEBUG_DETECT
   if (flag) printk( " SUCCESS\n" );
   else      printk( " FAILURE\n" );
#endif

   if (!flag) return 0;         /* iobase not found */

   *irq    = fdomain_get_irq( base );
   *iobase = base;

   return 1;                    /* success */
#else
   return 0;
#endif
}

/* PCI detection function: int fdomain_pci_bios_detect(int* irq, int*
   iobase) This function gets the Interrupt Level and I/O base address from
   the PCI configuration registers. */

#ifdef CONFIG_PCI
static int fdomain_pci_bios_detect( int *irq, int *iobase, struct pci_dev **ret_pdev )
{
   unsigned int     pci_irq;                /* PCI interrupt line */
   unsigned long    pci_base;               /* PCI I/O base address */
   struct pci_dev   *pdev = NULL;

#if DEBUG_DETECT
   /* Tell how to print a list of the known PCI devices from bios32 and
      list vendor and device IDs being used if in debug mode.  */
      
   printk( "scsi: <fdomain> INFO: use lspci -v to see list of PCI devices\n" );
   printk( "scsi: <fdomain> TMC-3260 detect:"
           " Using Vendor ID: 0x%x and Device ID: 0x%x\n",
           PCI_VENDOR_ID_FD, 
           PCI_DEVICE_ID_FD_36C70 );
#endif 

   if ((pdev = pci_find_device(PCI_VENDOR_ID_FD, PCI_DEVICE_ID_FD_36C70, pdev)) == NULL)
                return 0;
   if (pci_enable_device(pdev)) return 0;
       
#if DEBUG_DETECT
   printk( "scsi: <fdomain> TMC-3260 detect:"
           " PCI bus %u, device %u, function %u\n",
           pdev->bus->number,
           PCI_SLOT(pdev->devfn),
           PCI_FUNC(pdev->devfn));
#endif

   /* We now have the appropriate device function for the FD board so we
      just read the PCI config info from the registers.  */

   pci_base = pci_resource_start(pdev, 0);
   pci_irq = pdev->irq;

   if (!request_region( pci_base, 0x10, "fdomain" ))
        return 0;

   /* Now we have the I/O base address and interrupt from the PCI
      configuration registers. */

   *irq    = pci_irq;
   *iobase = pci_base;
   *ret_pdev = pdev;

#if DEBUG_DETECT
   printk( "scsi: <fdomain> TMC-3260 detect:"
           " IRQ = %d, I/O base = 0x%x [0x%lx]\n", *irq, *iobase, pci_base );
#endif

   if (!fdomain_is_valid_port(pci_base)) {
      printk(KERN_ERR "scsi: <fdomain> PCI card detected, but driver not loaded (invalid port)\n" );
      release_region(pci_base, 0x10);
      return 0;
   }

                                /* Fill in a few global variables.  Ugh. */
   bios_major = bios_minor = -1;
   PCI_bus    = 1;
   Quantum    = 0;
   bios_base  = 0;
   
   return 1;
}
#endif

struct Scsi_Host *__fdomain_16x0_detect(struct scsi_host_template *tpnt )
{
   int              retcode;
   struct Scsi_Host *shpnt;
   struct pci_dev *pdev = NULL;

   if (setup_called) {
#if DEBUG_DETECT
      printk( "scsi: <fdomain> No BIOS, using port_base = 0x%x, irq = %d\n",
              port_base, interrupt_level );
#endif
      if (!request_region(port_base, 0x10, "fdomain")) {
         printk( "scsi: <fdomain> port 0x%x is busy\n", port_base );
         printk( "scsi: <fdomain> Bad LILO/INSMOD parameters?\n" );
         return NULL;
      }
      if (!fdomain_is_valid_port( port_base )) {
         printk( "scsi: <fdomain> Cannot locate chip at port base 0x%x\n",
                 port_base );
         printk( "scsi: <fdomain> Bad LILO/INSMOD parameters?\n" );
         release_region(port_base, 0x10);
         return NULL;
      }
   } else {
      int flag = 0;

#ifdef CONFIG_PCI
                                /* Try PCI detection first */
      flag = fdomain_pci_bios_detect( &interrupt_level, &port_base, &pdev );
#endif
      if (!flag) {
                                /* Then try ISA bus detection */
         flag = fdomain_isa_detect( &interrupt_level, &port_base );

         if (!flag) {
            printk( "scsi: <fdomain> Detection failed (no card)\n" );
            return NULL;
         }
      }
   }

   fdomain_16x0_bus_reset(NULL);

   if (fdomain_test_loopback()) {
      printk(KERN_ERR  "scsi: <fdomain> Detection failed (loopback test failed at port base 0x%x)\n", port_base);
      if (setup_called) {
         printk(KERN_ERR "scsi: <fdomain> Bad LILO/INSMOD parameters?\n");
      }
      release_region(port_base, 0x10);
      return NULL;
   }

   if (this_id) {
      tpnt->this_id = (this_id & 0x07);
      adapter_mask  = (1 << tpnt->this_id);
   } else {
      if (PCI_bus || (bios_major == 3 && bios_minor >= 2) || bios_major < 0) {
         tpnt->this_id = 7;
         adapter_mask  = 0x80;
      } else {
         tpnt->this_id = 6;
         adapter_mask  = 0x40;
      }
   }

/* Print out a banner here in case we can't
   get resources.  */

   shpnt = scsi_register( tpnt, 0 );
   if(shpnt == NULL) {
        release_region(port_base, 0x10);
        return NULL;
   }
   shpnt->irq = interrupt_level;
   shpnt->io_port = port_base;
   scsi_set_device(shpnt, &pdev->dev);
   shpnt->n_io_port = 0x10;
   print_banner( shpnt );

   /* Log IRQ with kernel */   
   if (!interrupt_level) {
      printk(KERN_ERR "scsi: <fdomain> Card Detected, but driver not loaded (no IRQ)\n" );
      release_region(port_base, 0x10);
      return NULL;
   } else {
      /* Register the IRQ with the kernel */

      retcode = request_irq( interrupt_level,
                             do_fdomain_16x0_intr, pdev?SA_SHIRQ:0, "fdomain", shpnt);

      if (retcode < 0) {
         if (retcode == -EINVAL) {
            printk(KERN_ERR "scsi: <fdomain> IRQ %d is bad!\n", interrupt_level );
            printk(KERN_ERR "                This shouldn't happen!\n" );
            printk(KERN_ERR "                Send mail to faith@acm.org\n" );
         } else if (retcode == -EBUSY) {
            printk(KERN_ERR "scsi: <fdomain> IRQ %d is already in use!\n", interrupt_level );
            printk(KERN_ERR "                Please use another IRQ!\n" );
         } else {
            printk(KERN_ERR "scsi: <fdomain> Error getting IRQ %d\n", interrupt_level );
            printk(KERN_ERR "                This shouldn't happen!\n" );
            printk(KERN_ERR "                Send mail to faith@acm.org\n" );
         }
         printk(KERN_ERR "scsi: <fdomain> Detected, but driver not loaded (IRQ)\n" );
         release_region(port_base, 0x10);
         return NULL;
      }
   }
   return shpnt;
}

static int fdomain_16x0_detect(struct scsi_host_template *tpnt)
{
        if (fdomain)
                fdomain_setup(fdomain);
        return (__fdomain_16x0_detect(tpnt) != NULL);
}

static const char *fdomain_16x0_info( struct Scsi_Host *ignore )
{
   static char buffer[128];
   char        *pt;
   
   strcpy( buffer, "Future Domain 16-bit SCSI Driver Version" );
   if (strchr( VERSION, ':')) { /* Assume VERSION is an RCS Revision string */
      strcat( buffer, strchr( VERSION, ':' ) + 1 );
      pt = strrchr( buffer, '$') - 1;
      if (!pt)                  /* Stripped RCS Revision string? */
            pt = buffer + strlen( buffer ) - 1;
      if (*pt != ' ')
            ++pt;
      *pt = '\0';
   } else {                     /* Assume VERSION is a number */
      strcat( buffer, " " VERSION );
   }
      
   return buffer;
}

#if 0
static int fdomain_arbitrate( void )
{
   int           status = 0;
   unsigned long timeout;

#if EVERY_ACCESS
   printk( "fdomain_arbitrate()\n" );
#endif
   
   outb(0x00, port_base + SCSI_Cntl);              /* Disable data drivers */
   outb(adapter_mask, port_base + SCSI_Data_NoACK); /* Set our id bit */
   outb(0x04 | PARITY_MASK, port_base + TMC_Cntl); /* Start arbitration */

   timeout = 500;
   do {
      status = inb(port_base + TMC_Status);        /* Read adapter status */
      if (status & 0x02)                      /* Arbitration complete */
            return 0;
      mdelay(1);                        /* Wait one millisecond */
   } while (--timeout);

   /* Make bus idle */
   fdomain_make_bus_idle();

#if EVERY_ACCESS
   printk( "Arbitration failed, status = %x\n", status );
#endif
#if ERRORS_ONLY
   printk( "scsi: <fdomain> Arbitration failed, status = %x\n", status );
#endif
   return 1;
}
#endif

static int fdomain_select( int target )
{
   int           status;
   unsigned long timeout;
#if ERRORS_ONLY
   static int    flag = 0;
#endif

   outb(0x82, port_base + SCSI_Cntl); /* Bus Enable + Select */
   outb(adapter_mask | (1 << target), port_base + SCSI_Data_NoACK);

   /* Stop arbitration and enable parity */
   outb(PARITY_MASK, port_base + TMC_Cntl); 

   timeout = 350;                       /* 350 msec */

   do {
      status = inb(port_base + SCSI_Status); /* Read adapter status */
      if (status & 1) {                 /* Busy asserted */
         /* Enable SCSI Bus (on error, should make bus idle with 0) */
         outb(0x80, port_base + SCSI_Cntl);
         return 0;
      }
      mdelay(1);                        /* wait one msec */
   } while (--timeout);
   /* Make bus idle */
   fdomain_make_bus_idle();
#if EVERY_ACCESS
   if (!target) printk( "Selection failed\n" );
#endif
#if ERRORS_ONLY
   if (!target) {
      if (!flag) /* Skip first failure for all chips. */
            ++flag;
      else
            printk( "scsi: <fdomain> Selection failed\n" );
   }
#endif
   return 1;
}

static void my_done(int error)
{
   if (in_command) {
      in_command = 0;
      outb(0x00, port_base + Interrupt_Cntl);
      fdomain_make_bus_idle();
      current_SC->result = error;
      if (current_SC->scsi_done)
            current_SC->scsi_done( current_SC );
      else panic( "scsi: <fdomain> current_SC->scsi_done() == NULL" );
   } else {
      panic( "scsi: <fdomain> my_done() called outside of command\n" );
   }
#if DEBUG_RACE
   in_interrupt_flag = 0;
#endif
}

static irqreturn_t do_fdomain_16x0_intr(int irq, void *dev_id,
                                        struct pt_regs * regs )
{
   unsigned long flags;
   int      status;
   int      done = 0;
   unsigned data_count;

                                /* The fdomain_16x0_intr is only called via
                                   the interrupt handler.  The goal of the
                                   sti() here is to allow other
                                   interruptions while this routine is
                                   running. */

   /* Check for other IRQ sources */
   if ((inb(port_base + TMC_Status) & 0x01) == 0)
        return IRQ_NONE;

   /* It is our IRQ */          
   outb(0x00, port_base + Interrupt_Cntl);

   /* We usually have one spurious interrupt after each command.  Ignore it. */
   if (!in_command || !current_SC) {    /* Spurious interrupt */
#if EVERY_ACCESS
      printk( "Spurious interrupt, in_command = %d, current_SC = %x\n",
              in_command, current_SC );
#endif
      return IRQ_NONE;
   }

   /* Abort calls my_done, so we do nothing here. */
   if (current_SC->SCp.phase & aborted) {
#if DEBUG_ABORT
      printk( "scsi: <fdomain> Interrupt after abort, ignoring\n" );
#endif
      /*
      return IRQ_HANDLED; */
   }

#if DEBUG_RACE
   ++in_interrupt_flag;
#endif

   if (current_SC->SCp.phase & in_arbitration) {
      status = inb(port_base + TMC_Status);        /* Read adapter status */
      if (!(status & 0x02)) {
#if EVERY_ACCESS
         printk( " AFAIL " );
#endif
         spin_lock_irqsave(current_SC->device->host->host_lock, flags);
         my_done( DID_BUS_BUSY << 16 );
         spin_unlock_irqrestore(current_SC->device->host->host_lock, flags);
         return IRQ_HANDLED;
      }
      current_SC->SCp.phase = in_selection;
      
      outb(0x40 | FIFO_COUNT, port_base + Interrupt_Cntl);

      outb(0x82, port_base + SCSI_Cntl); /* Bus Enable + Select */
      outb(adapter_mask | (1 << current_SC->device->id), port_base + SCSI_Data_NoACK);
      
      /* Stop arbitration and enable parity */
      outb(0x10 | PARITY_MASK, port_base + TMC_Cntl);
#if DEBUG_RACE
      in_interrupt_flag = 0;
#endif
      return IRQ_HANDLED;
   } else if (current_SC->SCp.phase & in_selection) {
      status = inb(port_base + SCSI_Status);
      if (!(status & 0x01)) {
         /* Try again, for slow devices */
         if (fdomain_select( current_SC->device->id )) {
#if EVERY_ACCESS
            printk( " SFAIL " );
#endif
            spin_lock_irqsave(current_SC->device->host->host_lock, flags);
            my_done( DID_NO_CONNECT << 16 );
            spin_unlock_irqrestore(current_SC->device->host->host_lock, flags);
            return IRQ_HANDLED;
         } else {
#if EVERY_ACCESS
            printk( " AltSel " );
#endif
            /* Stop arbitration and enable parity */
            outb(0x10 | PARITY_MASK, port_base + TMC_Cntl);
         }
      }
      current_SC->SCp.phase = in_other;
      outb(0x90 | FIFO_COUNT, port_base + Interrupt_Cntl);
      outb(0x80, port_base + SCSI_Cntl);
#if DEBUG_RACE
      in_interrupt_flag = 0;
#endif
      return IRQ_HANDLED;
   }
   
   /* current_SC->SCp.phase == in_other: this is the body of the routine */
   
   status = inb(port_base + SCSI_Status);
   
   if (status & 0x10) { /* REQ */
      
      switch (status & 0x0e) {
       
      case 0x08:                /* COMMAND OUT */
         outb(current_SC->cmnd[current_SC->SCp.sent_command++],
              port_base + Write_SCSI_Data);
#if EVERY_ACCESS
         printk( "CMD = %x,",
                 current_SC->cmnd[ current_SC->SCp.sent_command - 1] );
#endif
         break;
      case 0x00:                /* DATA OUT -- tmc18c50/tmc18c30 only */
         if (chip != tmc1800 && !current_SC->SCp.have_data_in) {
            current_SC->SCp.have_data_in = -1;
            outb(0xd0 | PARITY_MASK, port_base + TMC_Cntl);
         }
         break;
      case 0x04:                /* DATA IN -- tmc18c50/tmc18c30 only */
         if (chip != tmc1800 && !current_SC->SCp.have_data_in) {
            current_SC->SCp.have_data_in = 1;
            outb(0x90 | PARITY_MASK, port_base + TMC_Cntl);
         }
         break;
      case 0x0c:                /* STATUS IN */
         current_SC->SCp.Status = inb(port_base + Read_SCSI_Data);
#if EVERY_ACCESS
         printk( "Status = %x, ", current_SC->SCp.Status );
#endif
#if ERRORS_ONLY
         if (current_SC->SCp.Status
             && current_SC->SCp.Status != 2
             && current_SC->SCp.Status != 8) {
            printk( "scsi: <fdomain> target = %d, command = %x, status = %x\n",
                    current_SC->device->id,
                    current_SC->cmnd[0],
                    current_SC->SCp.Status );
         }
#endif
               break;
      case 0x0a:                /* MESSAGE OUT */
         outb(MESSAGE_REJECT, port_base + Write_SCSI_Data); /* Reject */
         break;
      case 0x0e:                /* MESSAGE IN */
         current_SC->SCp.Message = inb(port_base + Read_SCSI_Data);
#if EVERY_ACCESS
         printk( "Message = %x, ", current_SC->SCp.Message );
#endif
         if (!current_SC->SCp.Message) ++done;
#if DEBUG_MESSAGES || EVERY_ACCESS
         if (current_SC->SCp.Message) {
            printk( "scsi: <fdomain> message = %x\n",
                    current_SC->SCp.Message );
         }
#endif
         break;
      }
   }

   if (chip == tmc1800 && !current_SC->SCp.have_data_in
       && (current_SC->SCp.sent_command >= current_SC->cmd_len)) {
      
      if(current_SC->sc_data_direction == DMA_TO_DEVICE)
      {
         current_SC->SCp.have_data_in = -1;
         outb(0xd0 | PARITY_MASK, port_base + TMC_Cntl);
      }
      else
      {
         current_SC->SCp.have_data_in = 1;
         outb(0x90 | PARITY_MASK, port_base + TMC_Cntl);
      }
   }

   if (current_SC->SCp.have_data_in == -1) { /* DATA OUT */
      while ((data_count = FIFO_Size - inw(port_base + FIFO_Data_Count)) > 512) {
#if EVERY_ACCESS
         printk( "DC=%d, ", data_count ) ;
#endif
         if (data_count > current_SC->SCp.this_residual)
               data_count = current_SC->SCp.this_residual;
         if (data_count > 0) {
#if EVERY_ACCESS
            printk( "%d OUT, ", data_count );
#endif
            if (data_count == 1) {
               outb(*current_SC->SCp.ptr++, port_base + Write_FIFO);
               --current_SC->SCp.this_residual;
            } else {
               data_count >>= 1;
               outsw(port_base + Write_FIFO, current_SC->SCp.ptr, data_count);
               current_SC->SCp.ptr += 2 * data_count;
               current_SC->SCp.this_residual -= 2 * data_count;
            }
         }
         if (!current_SC->SCp.this_residual) {
            if (current_SC->SCp.buffers_residual) {
               --current_SC->SCp.buffers_residual;
               ++current_SC->SCp.buffer;
               current_SC->SCp.ptr = page_address(current_SC->SCp.buffer->page) + current_SC->SCp.buffer->offset;
               current_SC->SCp.this_residual = current_SC->SCp.buffer->length;
            } else
                  break;
         }
      }
   }
   
   if (current_SC->SCp.have_data_in == 1) { /* DATA IN */
      while ((data_count = inw(port_base + FIFO_Data_Count)) > 0) {
#if EVERY_ACCESS
         printk( "DC=%d, ", data_count );
#endif
         if (data_count > current_SC->SCp.this_residual)
               data_count = current_SC->SCp.this_residual;
         if (data_count) {
#if EVERY_ACCESS
            printk( "%d IN, ", data_count );
#endif
            if (data_count == 1) {
               *current_SC->SCp.ptr++ = inb(port_base + Read_FIFO);
               --current_SC->SCp.this_residual;
            } else {
               data_count >>= 1; /* Number of words */
               insw(port_base + Read_FIFO, current_SC->SCp.ptr, data_count);
               current_SC->SCp.ptr += 2 * data_count;
               current_SC->SCp.this_residual -= 2 * data_count;
            }
         }
         if (!current_SC->SCp.this_residual
             && current_SC->SCp.buffers_residual) {
            --current_SC->SCp.buffers_residual;
            ++current_SC->SCp.buffer;
            current_SC->SCp.ptr = page_address(current_SC->SCp.buffer->page) + current_SC->SCp.buffer->offset;
            current_SC->SCp.this_residual = current_SC->SCp.buffer->length;
         }
      }
   }
   
   if (done) {
#if EVERY_ACCESS
      printk( " ** IN DONE %d ** ", current_SC->SCp.have_data_in );
#endif

#if ERRORS_ONLY
      if (current_SC->cmnd[0] == REQUEST_SENSE && !current_SC->SCp.Status) {
         if ((unsigned char)(*((char *)current_SC->request_buffer+2)) & 0x0f) {
            unsigned char key;
            unsigned char code;
            unsigned char qualifier;

            key = (unsigned char)(*((char *)current_SC->request_buffer + 2))
                  & 0x0f;
            code = (unsigned char)(*((char *)current_SC->request_buffer + 12));
            qualifier = (unsigned char)(*((char *)current_SC->request_buffer
                                          + 13));

            if (key != UNIT_ATTENTION
                && !(key == NOT_READY
                     && code == 0x04
                     && (!qualifier || qualifier == 0x02 || qualifier == 0x01))
                && !(key == ILLEGAL_REQUEST && (code == 0x25
                                                || code == 0x24
                                                || !code)))
                  
                  printk( "scsi: <fdomain> REQUEST SENSE"
                          " Key = %x, Code = %x, Qualifier = %x\n",
                          key, code, qualifier );
         }
      }
#endif
#if EVERY_ACCESS
      printk( "BEFORE MY_DONE. . ." );
#endif
      spin_lock_irqsave(current_SC->device->host->host_lock, flags);
      my_done( (current_SC->SCp.Status & 0xff)
               | ((current_SC->SCp.Message & 0xff) << 8) | (DID_OK << 16) );
      spin_unlock_irqrestore(current_SC->device->host->host_lock, flags);
#if EVERY_ACCESS
      printk( "RETURNING.\n" );
#endif
      
   } else {
      if (current_SC->SCp.phase & disconnect) {
         outb(0xd0 | FIFO_COUNT, port_base + Interrupt_Cntl);
         outb(0x00, port_base + SCSI_Cntl);
      } else {
         outb(0x90 | FIFO_COUNT, port_base + Interrupt_Cntl);
      }
   }
#if DEBUG_RACE
   in_interrupt_flag = 0;
#endif
   return IRQ_HANDLED;
}

static int fdomain_16x0_queue(struct scsi_cmnd *SCpnt,
                void (*done)(struct scsi_cmnd *))
{
   if (in_command) {
      panic( "scsi: <fdomain> fdomain_16x0_queue() NOT REENTRANT!\n" );
   }
#if EVERY_ACCESS
   printk( "queue: target = %d cmnd = 0x%02x pieces = %d size = %u\n",
           SCpnt->target,
           *(unsigned char *)SCpnt->cmnd,
           SCpnt->use_sg,
           SCpnt->request_bufflen );
#endif

   fdomain_make_bus_idle();

   current_SC            = SCpnt; /* Save this for the done function */
   current_SC->scsi_done = done;

   /* Initialize static data */

   if (current_SC->use_sg) {
      current_SC->SCp.buffer =
            (struct scatterlist *)current_SC->request_buffer;
      current_SC->SCp.ptr              = page_address(current_SC->SCp.buffer->page) + current_SC->SCp.buffer->offset;
      current_SC->SCp.this_residual    = current_SC->SCp.buffer->length;
      current_SC->SCp.buffers_residual = current_SC->use_sg - 1;
   } else {
      current_SC->SCp.ptr              = (char *)current_SC->request_buffer;
      current_SC->SCp.this_residual    = current_SC->request_bufflen;
      current_SC->SCp.buffer           = NULL;
      current_SC->SCp.buffers_residual = 0;
   }
         
   
   current_SC->SCp.Status              = 0;
   current_SC->SCp.Message             = 0;
   current_SC->SCp.have_data_in        = 0;
   current_SC->SCp.sent_command        = 0;
   current_SC->SCp.phase               = in_arbitration;

   /* Start arbitration */
   outb(0x00, port_base + Interrupt_Cntl);
   outb(0x00, port_base + SCSI_Cntl);              /* Disable data drivers */
   outb(adapter_mask, port_base + SCSI_Data_NoACK); /* Set our id bit */
   ++in_command;
   outb(0x20, port_base + Interrupt_Cntl);
   outb(0x14 | PARITY_MASK, port_base + TMC_Cntl); /* Start arbitration */

   return 0;
}

#if DEBUG_ABORT
static void print_info(struct scsi_cmnd *SCpnt)
{
   unsigned int imr;
   unsigned int irr;
   unsigned int isr;

   if (!SCpnt || !SCpnt->device || !SCpnt->device->host) {
      printk(KERN_WARNING "scsi: <fdomain> Cannot provide detailed information\n");
      return;
   }
   
   printk(KERN_INFO "%s\n", fdomain_16x0_info( SCpnt->device->host ) );
   print_banner(SCpnt->device->host);
   switch (SCpnt->SCp.phase) {
   case in_arbitration: printk("arbitration"); break;
   case in_selection:   printk("selection");   break;
   case in_other:       printk("other");       break;
   default:             printk("unknown");     break;
   }

   printk( " (%d), target = %d cmnd = 0x%02x pieces = %d size = %u\n",
           SCpnt->SCp.phase,
           SCpnt->device->id,
           *(unsigned char *)SCpnt->cmnd,
           SCpnt->use_sg,
           SCpnt->request_bufflen );
   printk( "sent_command = %d, have_data_in = %d, timeout = %d\n",
           SCpnt->SCp.sent_command,
           SCpnt->SCp.have_data_in,
           SCpnt->timeout );
#if DEBUG_RACE
   printk( "in_interrupt_flag = %d\n", in_interrupt_flag );
#endif

   imr = (inb( 0x0a1 ) << 8) + inb( 0x21 );
   outb( 0x0a, 0xa0 );
   irr = inb( 0xa0 ) << 8;
   outb( 0x0a, 0x20 );
   irr += inb( 0x20 );
   outb( 0x0b, 0xa0 );
   isr = inb( 0xa0 ) << 8;
   outb( 0x0b, 0x20 );
   isr += inb( 0x20 );

                                /* Print out interesting information */
   printk( "IMR = 0x%04x", imr );
   if (imr & (1 << interrupt_level))
         printk( " (masked)" );
   printk( ", IRR = 0x%04x, ISR = 0x%04x\n", irr, isr );

   printk( "SCSI Status      = 0x%02x\n", inb(port_base + SCSI_Status));
   printk( "TMC Status       = 0x%02x", inb(port_base + TMC_Status));
   if (inb((port_base + TMC_Status) & 1))
         printk( " (interrupt)" );
   printk( "\n" );
   printk("Interrupt Status = 0x%02x", inb(port_base + Interrupt_Status));
   if (inb(port_base + Interrupt_Status) & 0x08)
         printk( " (enabled)" );
   printk( "\n" );
   if (chip == tmc18c50 || chip == tmc18c30) {
      printk("FIFO Status      = 0x%02x\n", inb(port_base + FIFO_Status));
      printk( "Int. Condition   = 0x%02x\n",
              inb( port_base + Interrupt_Cond ) );
   }
   printk( "Configuration 1  = 0x%02x\n", inb( port_base + Configuration1 ) );
   if (chip == tmc18c50 || chip == tmc18c30)
         printk( "Configuration 2  = 0x%02x\n",
                 inb( port_base + Configuration2 ) );
}
#endif

static int fdomain_16x0_abort(struct scsi_cmnd *SCpnt)
{
#if EVERY_ACCESS || ERRORS_ONLY || DEBUG_ABORT
   printk( "scsi: <fdomain> abort " );
#endif

   if (!in_command) {
#if EVERY_ACCESS || ERRORS_ONLY
      printk( " (not in command)\n" );
#endif
      return FAILED;
   } else printk( "\n" );

#if DEBUG_ABORT
   print_info( SCpnt );
#endif

   fdomain_make_bus_idle();
   current_SC->SCp.phase |= aborted;
   current_SC->result = DID_ABORT << 16;
   
   /* Aborts are not done well. . . */
   my_done(DID_ABORT << 16);
   return SUCCESS;
}

int fdomain_16x0_bus_reset(struct scsi_cmnd *SCpnt)
{
   outb(1, port_base + SCSI_Cntl);
   do_pause( 2 );
   outb(0, port_base + SCSI_Cntl);
   do_pause( 115 );
   outb(0, port_base + SCSI_Mode_Cntl);
   outb(PARITY_MASK, port_base + TMC_Cntl);
   return SUCCESS;
}

static int fdomain_16x0_biosparam(struct scsi_device *sdev,
                struct block_device *bdev,
                sector_t capacity, int *info_array)
{
   int              drive;
   int              size      = capacity;
   unsigned long    offset;
   struct drive_info {
      unsigned short cylinders;
      unsigned char  heads;
      unsigned char  sectors;
   } i;
   
   /* NOTES:
      The RAM area starts at 0x1f00 from the bios_base address.

      For BIOS Version 2.0:
      
      The drive parameter table seems to start at 0x1f30.
      The first byte's purpose is not known.
      Next is the cylinder, head, and sector information.
      The last 4 bytes appear to be the drive's size in sectors.
      The other bytes in the drive parameter table are unknown.
      If anyone figures them out, please send me mail, and I will
      update these notes.

      Tape drives do not get placed in this table.

      There is another table at 0x1fea:
      If the byte is 0x01, then the SCSI ID is not in use.
      If the byte is 0x18 or 0x48, then the SCSI ID is in use,
      although tapes don't seem to be in this table.  I haven't
      seen any other numbers (in a limited sample).

      0x1f2d is a drive count (i.e., not including tapes)

      The table at 0x1fcc are I/O ports addresses for the various
      operations.  I calculate these by hand in this driver code.

      
      
      For the ISA-200S version of BIOS Version 2.0:

      The drive parameter table starts at 0x1f33.

      WARNING: Assume that the table entry is 25 bytes long.  Someone needs
      to check this for the Quantum ISA-200S card.

      
      
      For BIOS Version 3.2:

      The drive parameter table starts at 0x1f70.  Each entry is
      0x0a bytes long.  Heads are one less than we need to report.
    */

   if (MAJOR(bdev->bd_dev) != SCSI_DISK0_MAJOR) {
      printk("scsi: <fdomain> fdomain_16x0_biosparam: too many disks");
      return 0;
   }
   drive = MINOR(bdev->bd_dev) >> 4;

   if (bios_major == 2) {
      switch (Quantum) {
      case 2:                   /* ISA_200S */
                                /* The value of 25 has never been verified.
                                   It should probably be 15. */
         offset = 0x1f33 + drive * 25;
         break;
      case 3:                   /* ISA_250MG */
         offset = 0x1f36 + drive * 15;
         break;
      case 4:                   /* ISA_200S (another one) */
         offset = 0x1f34 + drive * 15;
         break;
      default:
         offset = 0x1f31 + drive * 25;
         break;
      }
      memcpy_fromio( &i, bios_mem + offset, sizeof( struct drive_info ) );
      info_array[0] = i.heads;
      info_array[1] = i.sectors;
      info_array[2] = i.cylinders;
   } else if (bios_major == 3
              && bios_minor >= 0
              && bios_minor < 4) { /* 3.0 and 3.2 BIOS */
      memcpy_fromio( &i, bios_mem + 0x1f71 + drive * 10,
                     sizeof( struct drive_info ) );
      info_array[0] = i.heads + 1;
      info_array[1] = i.sectors;
      info_array[2] = i.cylinders;
   } else {                     /* 3.4 BIOS (and up?) */
      /* This algorithm was provided by Future Domain (much thanks!). */
      unsigned char *p = scsi_bios_ptable(bdev);

      if (p && p[65] == 0xaa && p[64] == 0x55 /* Partition table valid */
          && p[4]) {                        /* Partition type */

         /* The partition table layout is as follows:

            Start: 0x1b3h
            Offset: 0 = partition status
                    1 = starting head
                    2 = starting sector and cylinder (word, encoded)
                    4 = partition type
                    5 = ending head
                    6 = ending sector and cylinder (word, encoded)
                    8 = starting absolute sector (double word)
                    c = number of sectors (double word)
            Signature: 0x1fe = 0x55aa

            So, this algorithm assumes:
            1) the first partition table is in use,
            2) the data in the first entry is correct, and
            3) partitions never divide cylinders

            Note that (1) may be FALSE for NetBSD (and other BSD flavors),
            as well as for Linux.  Note also, that Linux doesn't pay any
            attention to the fields that are used by this algorithm -- it
            only uses the absolute sector data.  Recent versions of Linux's
            fdisk(1) will fill this data in correctly, and forthcoming
            versions will check for consistency.

            Checking for a non-zero partition type is not part of the
            Future Domain algorithm, but it seemed to be a reasonable thing
            to do, especially in the Linux and BSD worlds. */

         info_array[0] = p[5] + 1;          /* heads */
         info_array[1] = p[6] & 0x3f;       /* sectors */
      } else {

         /* Note that this new method guarantees that there will always be
            less than 1024 cylinders on a platter.  This is good for drives
            up to approximately 7.85GB (where 1GB = 1024 * 1024 kB). */

         if ((unsigned int)size >= 0x7e0000U) {
            info_array[0] = 0xff; /* heads   = 255 */
            info_array[1] = 0x3f; /* sectors =  63 */
         } else if ((unsigned int)size >= 0x200000U) {
            info_array[0] = 0x80; /* heads   = 128 */
            info_array[1] = 0x3f; /* sectors =  63 */
         } else {
            info_array[0] = 0x40; /* heads   =  64 */
            info_array[1] = 0x20; /* sectors =  32 */
         }
      }
                                /* For both methods, compute the cylinders */
      info_array[2] = (unsigned int)size / (info_array[0] * info_array[1] );
      kfree(p);
   }
   
   return 0;
}

static int fdomain_16x0_release(struct Scsi_Host *shpnt)
{
        if (shpnt->irq)
                free_irq(shpnt->irq, shpnt);
        if (shpnt->io_port && shpnt->n_io_port)
                release_region(shpnt->io_port, shpnt->n_io_port);
        return 0;
}

struct scsi_host_template fdomain_driver_template = {
        .module                 = THIS_MODULE,
        .name                   = "fdomain",
        .proc_name              = "fdomain",
        .detect                 = fdomain_16x0_detect,
        .info                   = fdomain_16x0_info,
        .queuecommand           = fdomain_16x0_queue,
        .eh_abort_handler       = fdomain_16x0_abort,
        .eh_bus_reset_handler   = fdomain_16x0_bus_reset,
        .bios_param             = fdomain_16x0_biosparam,
        .release                = fdomain_16x0_release,
        .can_queue              = 1,
        .this_id                = 6,
        .sg_tablesize           = 64,
        .cmd_per_lun            = 1,
        .use_clustering         = DISABLE_CLUSTERING,
};

#ifndef PCMCIA
#define driver_template fdomain_driver_template
#include "scsi_module.c"
#endif