freebsd-skq/sys/i386/isa/wd.c
Julian Elischer 7146c13e43 the second set of changes in a move towards getting devices to be
totally dynamic.

this is only the devices in i386/isa
I'll do more tomorrow.
they're completely masked by #ifdef JREMOD at this stage...
the eventual aim is that every driver will do a SYSINIT
at startup BEFORE the probes, which will effectively
link it into the devsw tables etc.

If I'd thought about it more I'd have put that in in this set (damn)
The ioconf lines generated by config will also end up in the
device's own scope as well, so ioconf.c will eventually be gutted
the SYSINIT call to the driver will include a phase where the
driver links it's ioconf line into a chain of such. when this phase is done
then the user can modify them with the boot: -c
config menu if he wants, just like now..
config will put the config lines out in the .h file
(e.g. in aha.h will be the addresses for the aha driver to look.)
as I said this is a very small first step..
the aim of THIS set of edits is to not have to edit conf.c at all when
adding a new device.. the tabe will be a simple skeleton..

when this is done, it will allow other changes to be made,
all teh time still having a fully working kernel tree,
but the logical outcome is the complete REMOVAL of the devsw tables.

By the end of this, linked in drivers will be exactly the same as
run-time loaded drivers, except they JUST HAPPEN to already be linked
and present at startup..
the SYSINIT calls will be the equivalent of the "init" call
made to a newly loaded driver in every respect.

For this edit,
each of the files has the following code inserted into it:

obviously, tailored to suit..
----------------------somewhere at the top:
#ifdef JREMOD
#include <sys/conf.h>
#define CDEV_MAJOR 13
#define BDEV_MAJOR 4
static void 	sd_devsw_install();
#endif /*JREMOD */
---------------------somewhere that's run during bootup: EVENTUALLY a SYSINIT
#ifdef JREMOD
        sd_devsw_install();
#endif /*JREMOD*/
-----------------------at the bottom:
#ifdef JREMOD
struct bdevsw sd_bdevsw =
	{ sdopen,	sdclose,	sdstrategy,	sdioctl,	/*4*/
	  sddump,	sdsize,		0 };

struct cdevsw sd_cdevsw =
	{ sdopen,	sdclose,	rawread,	rawwrite,	/*13*/
	  sdioctl,	nostop,		nullreset,	nodevtotty,/* sd */
	  seltrue,	nommap,		sdstrategy };

static sd_devsw_installed = 0;

static void 	sd_devsw_install()
{
	dev_t descript;
	if( ! sd_devsw_installed ) {
		descript = makedev(CDEV_MAJOR,0);
		cdevsw_add(&descript,&sd_cdevsw,NULL);
#if defined(BDEV_MAJOR)
		descript = makedev(BDEV_MAJOR,0);
		bdevsw_add(&descript,&sd_bdevsw,NULL);
#endif /*BDEV_MAJOR*/
		sd_devsw_installed = 1;
	}
}
#endif /* JREMOD */
1995-11-28 09:42:06 +00:00

2156 lines
57 KiB
C

/*-
* Copyright (c) 1990 The Regents of the University of California.
* All rights reserved.
*
* This code is derived from software contributed to Berkeley by
* William Jolitz.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the University of
* California, Berkeley and its contributors.
* 4. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* from: @(#)wd.c 7.2 (Berkeley) 5/9/91
* $Id: wd.c,v 1.92 1995/11/23 07:24:41 dyson Exp $
*/
/* TODO:
* o Bump error count after timeout.
* o Satisfy ATA timing in all cases.
* o Finish merging berry/sos timeout code (bump error count...).
* o Merge/fix TIH/NetBSD bad144 code.
* o Don't use polling except for initialization. Need to
* reorganize the state machine. Then "extra" interrupts
* shouldn't happen (except maybe one for initialization).
* o Fix disklabel, boot and driver inconsistencies with
* bad144 in standard versions.
* o Support extended DOS partitions.
* o Support swapping to DOS partitions.
* o Handle bad sectors, clustering, disklabelling, DOS
* partitions and swapping driver-independently. Use
* i386/dkbad.c for bad sectors. Swapping will need new
* driver entries for polled reinit and polled write).
*/
#include "wd.h"
#ifdef NWDC
#undef NWDC
#endif
#include "wdc.h"
#if NWDC > 0
#include <sys/param.h>
#include <sys/dkbad.h>
#include <sys/systm.h>
#include <sys/kernel.h>
#include <sys/conf.h>
#include <sys/file.h>
#include <sys/stat.h>
#include <sys/ioctl.h>
#include <sys/disklabel.h>
#include <sys/diskslice.h>
#include <sys/buf.h>
#include <sys/proc.h>
#include <sys/uio.h>
#include <sys/malloc.h>
#include <sys/devconf.h>
#include <machine/bootinfo.h>
#include <machine/clock.h>
#include <machine/cons.h>
#include <machine/md_var.h>
#include <i386/isa/isa.h>
#include <i386/isa/isa_device.h>
#include <i386/isa/wdreg.h>
#include <sys/syslog.h>
#include <sys/dkstat.h>
#include <vm/vm.h>
#ifdef ATAPI
#include <i386/isa/atapi.h>
#endif
extern void wdstart(int ctrlr);
#define TIMEOUT 10000
#define RETRIES 5 /* number of retries before giving up */
#define RECOVERYTIME 500000 /* usec for controller to recover after err */
#define MAXTRANSFER 255 /* max size of transfer in sectors */
/* correct max is 256 but some controllers */
/* can't handle that in all cases */
#define WDOPT_32BIT 0x8000
#define WDOPT_SLEEPHACK 0x4000
#define WDOPT_MULTIMASK 0x00ff
#ifdef JREMOD
#define CDEV_MAJOR 3
#define BDEV_MAJOR 0
static void wd_devsw_install();
#endif /*JREMOD */
static int wd_goaway(struct kern_devconf *, int);
static int wdc_goaway(struct kern_devconf *, int);
static int wd_externalize(struct kern_devconf *, struct sysctl_req *);
/*
* Templates for the kern_devconf structures used when we attach.
*/
static struct kern_devconf kdc_wd[NWD] = { {
0, 0, 0, /* filled in by kern_devconf.c */
"wd", 0, { MDDT_DISK, 0 },
wd_externalize, 0, wd_goaway, DISK_EXTERNALLEN,
0, /* parent */
0, /* parentdata */
DC_UNKNOWN, /* state */
"ST506/ESDI/IDE disk", /* description */
DC_CLS_DISK /* class */
} };
static struct kern_devconf kdc_wdc[NWDC] = { {
0, 0, 0, /* filled in by kern_devconf.c */
"wdc", 0, { MDDT_ISA, 0 },
isa_generic_externalize, 0, wdc_goaway, ISA_EXTERNALLEN,
&kdc_isa0, /* parent */
0, /* parentdata */
DC_UNCONFIGURED, /* state */
"ST506/ESDI/IDE disk controller",
DC_CLS_MISC /* just an ordinary device */
} };
static inline void
wd_registerdev(int ctlr, int unit)
{
if(unit != 0) {
kdc_wd[unit] = kdc_wd[0];
kdc_wd[unit].kdc_state = DC_IDLE;
}
kdc_wd[unit].kdc_unit = unit;
kdc_wd[unit].kdc_parent = &kdc_wdc[ctlr];
kdc_wdc[ctlr].kdc_state = DC_BUSY;
dev_attach(&kdc_wd[unit]);
}
static inline void
wdc_registerdev(struct isa_device *dvp)
{
int unit = dvp->id_unit;
if(unit != 0) {
kdc_wdc[unit] = kdc_wdc[0];
kdc_wdc[unit].kdc_state = DC_IDLE;
}
kdc_wdc[unit].kdc_unit = unit;
kdc_wdc[unit].kdc_parentdata = dvp;
dev_attach(&kdc_wdc[unit]);
}
static int
wdc_goaway(struct kern_devconf *kdc, int force)
{
if(force) {
dev_detach(kdc);
return 0;
} else {
return EBUSY; /* XXX fix */
}
}
static int
wd_goaway(struct kern_devconf *kdc, int force)
{
dev_detach(kdc);
return 0;
}
/*
* This biotab field doubles as a field for the physical unit number on
* the controller.
*/
#define id_physid id_scsiid
/*
* Drive states. Used to initialize drive.
*/
#define CLOSED 0 /* disk is closed. */
#define WANTOPEN 1 /* open requested, not started */
#define RECAL 2 /* doing restore */
#define OPEN 3 /* done with open */
/*
* Disk geometry. A small part of struct disklabel.
* XXX disklabel.5 contains an old clone of disklabel.h.
*/
struct diskgeom {
u_long d_secsize; /* # of bytes per sector */
u_long d_nsectors; /* # of data sectors per track */
u_long d_ntracks; /* # of tracks per cylinder */
u_long d_ncylinders; /* # of data cylinders per unit */
u_long d_secpercyl; /* # of data sectors per cylinder */
u_long d_secperunit; /* # of data sectors per unit */
u_long d_precompcyl; /* XXX always 0 */
};
/*
* The structure of a disk drive.
*/
struct disk {
long dk_bc; /* byte count left */
short dk_skip; /* blocks already transferred */
char dk_ctrlr; /* physical controller number */
char dk_unit; /* physical unit number */
char dk_lunit; /* logical unit number */
char dk_state; /* control state */
u_char dk_status; /* copy of status reg. */
u_char dk_error; /* copy of error reg. */
u_char dk_timeout; /* countdown to next timeout */
short dk_port; /* i/o port base */
u_long cfg_flags; /* configured characteristics */
short dk_flags; /* drive characteristics found */
#define DKFL_SINGLE 0x00004 /* sector at a time mode */
#define DKFL_ERROR 0x00008 /* processing a disk error */
#define DKFL_LABELLING 0x00080 /* readdisklabel() in progress */
#define DKFL_32BIT 0x00100 /* use 32-bit i/o mode */
#define DKFL_MULTI 0x00200 /* use multi-i/o mode */
#define DKFL_BADSCAN 0x00400 /* report all errors */
struct wdparams dk_params; /* ESDI/IDE drive/controller parameters */
int dk_dkunit; /* disk stats unit number */
int dk_multi; /* multi transfers */
int dk_currentiosize; /* current io size */
struct diskgeom dk_dd; /* device configuration data */
struct diskslices *dk_slices; /* virtual drives */
};
#define WD_COUNT_RETRIES
static int wdtest = 0;
static struct disk *wddrives[NWD]; /* table of units */
static struct buf_queue_head drive_queue[NWD]; /* head of queue per drive */
static struct {
int b_errcnt;
int b_active;
} wdutab[NWD];
/*
static struct buf wdtab[NWDC];
*/
static struct {
struct buf_queue_head controller_queue;
int b_errcnt;
int b_active;
} wdtab[NWDC];
#ifdef notyet
static struct buf rwdbuf[NWD]; /* buffers for raw IO */
#endif
static int wdprobe(struct isa_device *dvp);
static int wdattach(struct isa_device *dvp);
static void wdustart(struct disk *du);
static int wdcontrol(struct buf *bp);
static int wdcommand(struct disk *du, u_int cylinder, u_int head,
u_int sector, u_int count, u_int command);
static int wdsetctlr(struct disk *du);
static int wdwsetctlr(struct disk *du);
static int wdgetctlr(struct disk *du);
static void wderror(struct buf *bp, struct disk *du, char *mesg);
static void wdflushirq(struct disk *du, int old_ipl);
static int wdreset(struct disk *du);
static void wdsleep(int ctrlr, char *wmesg);
static void wdstrategy1(struct buf *bp);
static timeout_t wdtimeout;
static int wdunwedge(struct disk *du);
static int wdwait(struct disk *du, u_char bits_wanted, int timeout);
/*
* Provide hw.devconf information.
*/
static int
wd_externalize(struct kern_devconf *kdc, struct sysctl_req *req)
{
return disk_externalize(wddrives[kdc->kdc_unit]->dk_unit, req);
}
struct isa_driver wdcdriver = {
wdprobe, wdattach, "wdc",
};
/*
* Probe for controller.
*/
static int
wdprobe(struct isa_device *dvp)
{
int unit = dvp->id_unit;
struct disk *du;
if (unit >= NWDC)
return (0);
du = malloc(sizeof *du, M_TEMP, M_NOWAIT);
if (du == NULL)
return (0);
bzero(du, sizeof *du);
du->dk_ctrlr = dvp->id_unit;
du->dk_port = dvp->id_iobase;
wdc_registerdev(dvp);
#ifdef JREMOD
wd_devsw_install();
#endif /*JREMOD*/
/* check if we have registers that work */
outb(du->dk_port + wd_sdh, WDSD_IBM); /* set unit 0 */
outb(du->dk_port + wd_cyl_lo, 0xa5); /* wd_cyl_lo is read/write */
if (inb(du->dk_port + wd_cyl_lo) == 0xff) { /* XXX too weak */
#ifdef ATAPI
/* There is no master, try the ATAPI slave. */
outb(du->dk_port + wd_sdh, WDSD_IBM | 0x10);
outb(du->dk_port + wd_cyl_lo, 0xa5);
if (inb(du->dk_port + wd_cyl_lo) == 0xff)
#endif
goto nodevice;
}
if (wdreset(du) == 0)
goto reset_ok;
#ifdef ATAPI
/* test for ATAPI signature */
outb(du->dk_port + wd_sdh, WDSD_IBM); /* master */
if (inb(du->dk_port + wd_cyl_lo) == 0x14 &&
inb(du->dk_port + wd_cyl_hi) == 0xeb)
goto reset_ok;
du->dk_unit = 1;
outb(du->dk_port + wd_sdh, WDSD_IBM | 0x10); /* slave */
if (inb(du->dk_port + wd_cyl_lo) == 0x14 &&
inb(du->dk_port + wd_cyl_hi) == 0xeb)
goto reset_ok;
#endif
DELAY(RECOVERYTIME);
if (wdreset(du) != 0)
goto nodevice;
reset_ok:
/* execute a controller only command */
if (wdcommand(du, 0, 0, 0, 0, WDCC_DIAGNOSE) != 0
|| wdwait(du, 0, TIMEOUT) < 0)
goto nodevice;
/*
* drive(s) did not time out during diagnostic :
* Get error status and check that both drives are OK.
* Table 9-2 of ATA specs suggests that we must check for
* a value of 0x01
*
* Strangely, some controllers will return a status of
* 0x81 (drive 0 OK, drive 1 failure), and then when
* the DRV bit is set, return status of 0x01 (OK) for
* drive 2. (This seems to contradict the ATA spec.)
*/
du->dk_error = inb(du->dk_port + wd_error);
/* printf("Error : %x\n", du->dk_error); */
if(du->dk_error != 0x01) {
if(du->dk_error & 0x80) { /* drive 1 failure */
/* first set the DRV bit */
u_int sdh;
sdh = inb(du->dk_port+ wd_sdh);
sdh = sdh | 0x10;
outb(du->dk_port+ wd_sdh, sdh);
/* Wait, to make sure drv 1 has completed diags */
if ( wdwait(du, 0, TIMEOUT) < 0)
goto nodevice;
/* Get status for drive 1 */
du->dk_error = inb(du->dk_port + wd_error);
/* printf("Error (drv 1) : %x\n", du->dk_error); */
if(du->dk_error != 0x01)
goto nodevice;
} else /* drive 0 fail */
goto nodevice;
}
free(du, M_TEMP);
return (IO_WDCSIZE);
nodevice:
free(du, M_TEMP);
return (0);
}
/*
* Attach each drive if possible.
*/
static int
wdattach(struct isa_device *dvp)
{
int unit, lunit;
struct isa_device *wdup;
struct disk *du;
if (dvp->id_unit >= NWDC)
return (0);
kdc_wdc[dvp->id_unit].kdc_state = DC_UNKNOWN; /* XXX */
TAILQ_INIT( &wdtab[dvp->id_unit].controller_queue);
for (wdup = isa_biotab_wdc; wdup->id_driver != 0; wdup++) {
if (wdup->id_iobase != dvp->id_iobase)
continue;
lunit = wdup->id_unit;
if (lunit >= NWD)
continue;
unit = wdup->id_physid;
du = malloc(sizeof *du, M_TEMP, M_NOWAIT);
if (du == NULL)
continue;
if (wddrives[lunit] != NULL)
panic("drive attached twice");
wddrives[lunit] = du;
TAILQ_INIT( &drive_queue[lunit]);
bzero(du, sizeof *du);
du->dk_ctrlr = dvp->id_unit;
du->dk_unit = unit;
du->dk_lunit = lunit;
du->dk_port = dvp->id_iobase;
/*
* Use the individual device flags or the controller
* flags.
*/
du->cfg_flags = wdup->id_flags |
((dvp->id_flags) >> (16 * unit));
if (wdgetctlr(du) == 0) {
char buf[sizeof du->dk_params.wdp_model + 1];
/*
* Print out description of drive.
* wdp_model may not be null terminated, and printf
* doesn't support "%.*s" :-(, so copy wdp_model
* and add a null before printing.
*/
bcopy(du->dk_params.wdp_model, buf, sizeof buf - 1);
buf[sizeof buf - 1] = '\0';
printf("wdc%d: unit %d (wd%d): <%s>",
dvp->id_unit, unit, lunit, buf);
if (du->dk_flags & DKFL_32BIT)
printf(", 32-bit");
if (du->dk_multi > 1)
printf(", multi-block-%d", du->dk_multi);
if (du->cfg_flags & WDOPT_SLEEPHACK)
printf(", sleep-hack");
printf("\n");
if (du->dk_params.wdp_heads == 0)
printf("wd%d: size unknown, using %s values\n",
lunit, du->dk_dd.d_secperunit > 17
? "BIOS" : "fake");
printf(
"wd%d: %luMB (%lu sectors), %lu cyls, %lu heads, %lu S/T, %lu B/S\n",
lunit,
du->dk_dd.d_secperunit
* du->dk_dd.d_secsize / (1024 * 1024),
du->dk_dd.d_secperunit,
du->dk_dd.d_ncylinders,
du->dk_dd.d_ntracks,
du->dk_dd.d_nsectors,
du->dk_dd.d_secsize);
/*
* Start timeout routine for this drive.
* XXX timeout should be per controller.
*/
wdtimeout(du);
wd_registerdev(dvp->id_unit, lunit);
if (dk_ndrive < DK_NDRIVE) {
sprintf(dk_names[dk_ndrive], "wd%d", lunit);
/*
* XXX we don't know the transfer rate of the
* drive. Guess the maximum ISA rate of
* 4MB/sec. `wpms' is words per _second_
* according to iostat.
*/
dk_wpms[dk_ndrive] = 4 * 1024 * 1024 / 2;
du->dk_dkunit = dk_ndrive++;
} else {
du->dk_dkunit = -1;
}
} else {
free(du, M_TEMP);
wddrives[lunit] = NULL;
}
}
#ifdef ATAPI
/*
* Probe all free IDE units, searching for ATAPI drives.
*/
for (unit=0; unit<2; ++unit) {
for (lunit=0; lunit<NWD && wddrives[lunit]; ++lunit)
if (wddrives[lunit]->dk_ctrlr == dvp->id_unit &&
wddrives[lunit]->dk_unit == unit)
goto next;
atapi_attach (dvp->id_unit, unit, dvp->id_iobase,
&kdc_wdc[dvp->id_unit]);
next: }
#endif
/*
* Discard any interrupts generated by wdgetctlr(). wdflushirq()
* doesn't work now because the ambient ipl is too high.
*/
wdtab[dvp->id_unit].b_active = 2;
return (1);
}
/* Read/write routine for a buffer. Finds the proper unit, range checks
* arguments, and schedules the transfer. Does not wait for the transfer
* to complete. Multi-page transfers are supported. All I/O requests must
* be a multiple of a sector in length.
*/
void
wdstrategy(register struct buf *bp)
{
register struct buf *dp;
struct disk *du;
int lunit = dkunit(bp->b_dev);
int s;
/* valid unit, controller, and request? */
if (lunit >= NWD || bp->b_blkno < 0 || (du = wddrives[lunit]) == NULL
|| bp->b_bcount % DEV_BSIZE != 0) {
bp->b_error = EINVAL;
bp->b_flags |= B_ERROR;
goto done;
}
/*
* Do bounds checking, adjust transfer, set b_cylin and b_pbklno.
*/
if (dscheck(bp, du->dk_slices) <= 0)
goto done;
/*
* Check for *any* block on this transfer being on the bad block list
* if it is, then flag the block as a transfer that requires
* bad block handling. Also, used as a hint for low level disksort
* clustering code to keep from coalescing a bad transfer into
* a normal transfer. Single block transfers for a large number of
* blocks associated with a cluster I/O are undesirable.
*
* XXX the old disksort() doesn't look at B_BAD. Coalescing _is_
* desirable. We should split the results at bad blocks just
* like we should split them at MAXTRANSFER boundaries.
*/
if (dsgetbad(bp->b_dev, du->dk_slices) != NULL) {
long *badsect = dsgetbad(bp->b_dev, du->dk_slices)->bi_bad;
int i;
int nsecs = howmany(bp->b_bcount, DEV_BSIZE);
/* XXX pblkno is too physical. */
daddr_t nspblkno = bp->b_pblkno
- du->dk_slices->dss_slices[dkslice(bp->b_dev)].ds_offset;
int blkend = nspblkno + nsecs;
for (i = 0; badsect[i] != -1 && badsect[i] < blkend; i++) {
if (badsect[i] >= nspblkno) {
bp->b_flags |= B_BAD;
break;
}
}
}
/* queue transfer on drive, activate drive and controller if idle */
s = splbio();
tqdisksort(&drive_queue[lunit], bp);
if (wdutab[lunit].b_active == 0)
wdustart(du); /* start drive */
/* Pick up changes made by readdisklabel(). */
if (du->dk_flags & DKFL_LABELLING && du->dk_state > RECAL) {
wdsleep(du->dk_ctrlr, "wdlab");
du->dk_state = WANTOPEN;
}
if (wdtab[du->dk_ctrlr].b_active == 0)
wdstart(du->dk_ctrlr); /* start controller */
if (du->dk_dkunit >= 0) {
/*
* XXX perhaps we should only count successful transfers.
*/
dk_xfer[du->dk_dkunit]++;
/*
* XXX we can't count seeks correctly but we can do better
* than this. E.g., assume that the geometry is correct
* and count 1 seek if the starting cylinder of this i/o
* differs from the starting cylinder of the previous i/o,
* or count 1 seek if the starting bn of this i/o doesn't
* immediately follow the ending bn of the previos i/o.
*/
dk_seek[du->dk_dkunit]++;
}
splx(s);
return;
done:
s = splbio();
/* toss transfer, we're done early */
biodone(bp);
splx(s);
}
static void
wdstrategy1(struct buf *bp)
{
/*
* XXX - do something to make wdstrategy() but not this block while
* we're doing dsinit() and dsioctl().
*/
wdstrategy(bp);
}
/*
* Routine to queue a command to the controller. The unit's
* request is linked into the active list for the controller.
* If the controller is idle, the transfer is started.
*/
static void
wdustart(register struct disk *du)
{
register struct buf *bp;
int ctrlr = du->dk_ctrlr;
/* unit already active? */
if (wdutab[du->dk_lunit].b_active)
return;
bp = drive_queue[du->dk_lunit].tqh_first;
if (bp == NULL) { /* yes, an assign */
return;
}
TAILQ_REMOVE( &drive_queue[du->dk_lunit], bp, b_act);
/* link onto controller queue */
TAILQ_INSERT_TAIL( &wdtab[ctrlr].controller_queue, bp, b_act);
/* mark the drive unit as busy */
wdutab[du->dk_lunit].b_active = 1;
}
/*
* Controller startup routine. This does the calculation, and starts
* a single-sector read or write operation. Called to start a transfer,
* or from the interrupt routine to continue a multi-sector transfer.
* RESTRICTIONS:
* 1. The transfer length must be an exact multiple of the sector size.
*/
void
wdstart(int ctrlr)
{
register struct disk *du;
register struct buf *bp;
struct diskgeom *lp; /* XXX sic */
struct buf *dp;
long blknum;
long secpertrk, secpercyl;
int lunit;
int count;
#ifdef ATAPI
if (wdtab[ctrlr].b_active == 2)
wdtab[ctrlr].b_active = 0;
if (wdtab[ctrlr].b_active)
return;
#endif
loop:
/* is there a drive for the controller to do a transfer with? */
bp = wdtab[ctrlr].controller_queue.tqh_first;
if (bp == NULL) {
#ifdef ATAPI
if (atapi_start && atapi_start (ctrlr))
/* mark controller active in ATAPI mode */
wdtab[ctrlr].b_active = 3;
#endif
return;
}
/* obtain controller and drive information */
lunit = dkunit(bp->b_dev);
du = wddrives[lunit];
/* if not really a transfer, do control operations specially */
if (du->dk_state < OPEN) {
if (du->dk_state != WANTOPEN)
printf("wd%d: wdstart: weird dk_state %d\n",
du->dk_lunit, du->dk_state);
if (wdcontrol(bp) != 0)
printf("wd%d: wdstart: wdcontrol returned nonzero, state = %d\n",
du->dk_lunit, du->dk_state);
return;
}
/* calculate transfer details */
blknum = bp->b_pblkno + du->dk_skip;
#ifdef WDDEBUG
if (du->dk_skip == 0)
printf("wd%d: wdstart: %s %d@%d; map ", lunit,
(bp->b_flags & B_READ) ? "read" : "write",
bp->b_bcount, blknum);
else
printf(" %d)%x", du->dk_skip, inb(du->dk_port + wd_altsts));
#endif
lp = &du->dk_dd;
secpertrk = lp->d_nsectors;
secpercyl = lp->d_secpercyl;
if (du->dk_skip == 0) {
du->dk_bc = bp->b_bcount;
if (bp->b_flags & B_BAD
/*
* XXX handle large transfers inefficiently instead
* of crashing on them.
*/
|| howmany(du->dk_bc, DEV_BSIZE) > MAXTRANSFER)
du->dk_flags |= DKFL_SINGLE;
}
if (du->dk_flags & DKFL_SINGLE
&& dsgetbad(bp->b_dev, du->dk_slices) != NULL) {
/* XXX */
u_long ds_offset =
du->dk_slices->dss_slices[dkslice(bp->b_dev)].ds_offset;
blknum = transbad144(dsgetbad(bp->b_dev, du->dk_slices),
blknum - ds_offset) + ds_offset;
}
wdtab[ctrlr].b_active = 1; /* mark controller active */
/* if starting a multisector transfer, or doing single transfers */
if (du->dk_skip == 0 || (du->dk_flags & DKFL_SINGLE)) {
u_int command;
u_int count;
long cylin, head, sector;
cylin = blknum / secpercyl;
head = (blknum % secpercyl) / secpertrk;
sector = blknum % secpertrk;
if (wdtab[ctrlr].b_errcnt && (bp->b_flags & B_READ) == 0)
du->dk_bc += DEV_BSIZE;
count = howmany( du->dk_bc, DEV_BSIZE);
du->dk_flags &= ~DKFL_MULTI;
#ifdef B_FORMAT
if (bp->b_flags & B_FORMAT) {
command = WDCC_FORMAT;
count = lp->d_nsectors;
sector = lp->d_gap3 - 1; /* + 1 later */
} else
#endif
{
if (du->dk_flags & DKFL_SINGLE) {
command = (bp->b_flags & B_READ)
? WDCC_READ : WDCC_WRITE;
count = 1;
du->dk_currentiosize = 1;
} else {
if( (count > 1) && (du->dk_multi > 1)) {
du->dk_flags |= DKFL_MULTI;
if( bp->b_flags & B_READ) {
command = WDCC_READ_MULTI;
} else {
command = WDCC_WRITE_MULTI;
}
du->dk_currentiosize = du->dk_multi;
if( du->dk_currentiosize > count)
du->dk_currentiosize = count;
} else {
if( bp->b_flags & B_READ) {
command = WDCC_READ;
} else {
command = WDCC_WRITE;
}
du->dk_currentiosize = 1;
}
}
}
/*
* XXX this loop may never terminate. The code to handle
* counting down of retries and eventually failing the i/o
* is in wdintr() and we can't get there from here.
*/
if (wdtest != 0) {
if (--wdtest == 0) {
wdtest = 100;
printf("dummy wdunwedge\n");
wdunwedge(du);
}
}
if(du->dk_dkunit >= 0) {
dk_busy |= 1 << du->dk_dkunit;
}
while (wdcommand(du, cylin, head, sector, count, command)
!= 0) {
wderror(bp, du,
"wdstart: timeout waiting to give command");
wdunwedge(du);
}
#ifdef WDDEBUG
printf("cylin %ld head %ld sector %ld addr %x sts %x\n",
cylin, head, sector,
(int)bp->b_un.b_addr + du->dk_skip * DEV_BSIZE,
inb(du->dk_port + wd_altsts));
#endif
}
/*
* Schedule wdtimeout() to wake up after a few seconds. Retrying
* unmarked bad blocks can take 3 seconds! Then it is not good that
* we retry 5 times.
*
* XXX wdtimeout() doesn't increment the error count so we may loop
* forever. More seriously, the loop isn't forever but causes a
* crash.
*
* TODO fix b_resid bug elsewhere (fd.c....). Fix short but positive
* counts being discarded after there is an error (in physio I
* think). Discarding them would be OK if the (special) file offset
* was not advanced.
*/
du->dk_timeout = 1 + 3;
/* If this is a read operation, just go away until it's done. */
if (bp->b_flags & B_READ)
return;
/* Ready to send data? */
if (wdwait(du, WDCS_READY | WDCS_SEEKCMPLT | WDCS_DRQ, TIMEOUT) < 0) {
wderror(bp, du, "wdstart: timeout waiting for DRQ");
/*
* XXX what do we do now? If we've just issued the command,
* then we can treat this failure the same as a command
* failure. But if we are continuing a multi-sector write,
* the command was issued ages ago, so we can't simply
* restart it.
*
* XXX we waste a lot of time unnecessarily translating block
* numbers to cylin/head/sector for continued i/o's.
*/
}
count = 1;
if( du->dk_flags & DKFL_MULTI) {
count = howmany(du->dk_bc, DEV_BSIZE);
if( count > du->dk_multi)
count = du->dk_multi;
if( du->dk_currentiosize > count)
du->dk_currentiosize = count;
}
if (du->dk_flags & DKFL_32BIT)
outsl(du->dk_port + wd_data,
(void *)((int)bp->b_un.b_addr + du->dk_skip * DEV_BSIZE),
(count * DEV_BSIZE) / sizeof(long));
else
outsw(du->dk_port + wd_data,
(void *)((int)bp->b_un.b_addr + du->dk_skip * DEV_BSIZE),
(count * DEV_BSIZE) / sizeof(short));
du->dk_bc -= DEV_BSIZE * count;
if (du->dk_dkunit >= 0) {
/*
* `wd's are blocks of 32 16-bit `word's according to
* iostat. dk_wds[] is the one disk i/o statistic that
* we can record correctly.
* XXX perhaps we shouldn't record words for failed
* transfers.
*/
dk_wds[du->dk_dkunit] += (count * DEV_BSIZE) >> 6;
}
}
/* Interrupt routine for the controller. Acknowledge the interrupt, check for
* errors on the current operation, mark it done if necessary, and start
* the next request. Also check for a partially done transfer, and
* continue with the next chunk if so.
*/
void
wdintr(int unit)
{
register struct disk *du;
register struct buf *bp, *dp;
if (wdtab[unit].b_active == 2)
return; /* intr in wdflushirq() */
if (!wdtab[unit].b_active) {
#ifdef WDDEBUG
/*
* These happen mostly because the power-mgt part of the
* bios shuts us down, and we just manage to see the
* interrupt from the "SLEEP" command.
*/
printf("wdc%d: extra interrupt\n", unit);
#endif
return;
}
#ifdef ATAPI
if (wdtab[unit].b_active == 3) {
/* process an ATAPI interrupt */
if (atapi_intr && atapi_intr (unit))
/* ATAPI op continues */
return;
/* controller is free, start new op */
wdtab[unit].b_active = 0;
wdstart (unit);
return;
}
#endif
bp = wdtab[unit].controller_queue.tqh_first;
du = wddrives[dkunit(bp->b_dev)];
du->dk_timeout = 0;
if (wdwait(du, 0, TIMEOUT) < 0) {
wderror(bp, du, "wdintr: timeout waiting for status");
du->dk_status |= WDCS_ERR; /* XXX */
}
/* is it not a transfer, but a control operation? */
if (du->dk_state < OPEN) {
wdtab[unit].b_active = 0;
switch (wdcontrol(bp)) {
case 0:
return;
case 1:
wdstart(unit);
return;
case 2:
goto done;
}
}
/* have we an error? */
if (du->dk_status & (WDCS_ERR | WDCS_ECCCOR)) {
oops:
/*
* XXX bogus inb() here, register 0 is assumed and intr status
* is reset.
*/
if( (du->dk_status & DKFL_MULTI) && (inb(du->dk_port) & WDERR_ABORT)) {
wderror(bp, du, "reverting to non-multi sector mode");
du->dk_multi = 1;
}
#ifdef WDDEBUG
wderror(bp, du, "wdintr");
#endif
if ((du->dk_flags & DKFL_SINGLE) == 0) {
du->dk_flags |= DKFL_ERROR;
goto outt;
}
#ifdef B_FORMAT
if (bp->b_flags & B_FORMAT) {
bp->b_error = EIO;
bp->b_flags |= B_ERROR;
goto done;
}
#endif
if (du->dk_flags & DKFL_BADSCAN) {
bp->b_error = EIO;
bp->b_flags |= B_ERROR;
} else if (du->dk_status & WDCS_ERR) {
if (++wdtab[unit].b_errcnt < RETRIES) {
wdtab[unit].b_active = 0;
} else {
wderror(bp, du, "hard error");
bp->b_error = EIO;
bp->b_flags |= B_ERROR; /* flag the error */
}
} else
wderror(bp, du, "soft ecc");
}
/*
* If this was a successful read operation, fetch the data.
*/
if (((bp->b_flags & (B_READ | B_ERROR)) == B_READ)
&& wdtab[unit].b_active) {
int chk, dummy, multisize;
multisize = chk = du->dk_currentiosize * DEV_BSIZE;
if( du->dk_bc < chk) {
chk = du->dk_bc;
if( ((chk + DEV_BSIZE - 1) / DEV_BSIZE) < du->dk_currentiosize) {
du->dk_currentiosize = (chk + DEV_BSIZE - 1) / DEV_BSIZE;
multisize = du->dk_currentiosize * DEV_BSIZE;
}
}
/* ready to receive data? */
if ((du->dk_status & (WDCS_READY | WDCS_SEEKCMPLT | WDCS_DRQ))
!= (WDCS_READY | WDCS_SEEKCMPLT | WDCS_DRQ))
wderror(bp, du, "wdintr: read intr arrived early");
if (wdwait(du, WDCS_READY | WDCS_SEEKCMPLT | WDCS_DRQ, TIMEOUT) != 0) {
wderror(bp, du, "wdintr: read error detected late");
goto oops;
}
/* suck in data */
if( du->dk_flags & DKFL_32BIT)
insl(du->dk_port + wd_data,
(void *)((int)bp->b_un.b_addr + du->dk_skip * DEV_BSIZE),
chk / sizeof(long));
else
insw(du->dk_port + wd_data,
(void *)((int)bp->b_un.b_addr + du->dk_skip * DEV_BSIZE),
chk / sizeof(short));
du->dk_bc -= chk;
/* XXX for obsolete fractional sector reads. */
while (chk < multisize) {
insw(du->dk_port + wd_data, &dummy, 1);
chk += sizeof(short);
}
if (du->dk_dkunit >= 0)
dk_wds[du->dk_dkunit] += chk >> 6;
}
outt:
if (wdtab[unit].b_active) {
if ((bp->b_flags & B_ERROR) == 0) {
du->dk_skip += du->dk_currentiosize;/* add to successful sectors */
if (wdtab[unit].b_errcnt)
wderror(bp, du, "soft error");
wdtab[unit].b_errcnt = 0;
/* see if more to transfer */
if (du->dk_bc > 0 && (du->dk_flags & DKFL_ERROR) == 0) {
if( (du->dk_flags & DKFL_SINGLE) ||
((bp->b_flags & B_READ) == 0)) {
wdtab[unit].b_active = 0;
wdstart(unit);
} else {
du->dk_timeout = 1 + 3;
}
return; /* next chunk is started */
} else if ((du->dk_flags & (DKFL_SINGLE | DKFL_ERROR))
== DKFL_ERROR) {
du->dk_skip = 0;
du->dk_flags &= ~DKFL_ERROR;
du->dk_flags |= DKFL_SINGLE;
wdtab[unit].b_active = 0;
wdstart(unit);
return; /* redo xfer sector by sector */
}
}
done: ;
/* done with this transfer, with or without error */
du->dk_flags &= ~DKFL_SINGLE;
TAILQ_REMOVE(&wdtab[unit].controller_queue, bp, b_act);
wdtab[unit].b_errcnt = 0;
bp->b_resid = bp->b_bcount - du->dk_skip * DEV_BSIZE;
wdutab[du->dk_lunit].b_active = 0;
wdutab[du->dk_lunit].b_errcnt = 0;
du->dk_skip = 0;
biodone(bp);
}
if(du->dk_dkunit >= 0) {
dk_busy &= ~(1 << du->dk_dkunit);
}
/* controller idle */
wdtab[unit].b_active = 0;
/* anything more on drive queue? */
wdustart(du);
/* anything more for controller to do? */
#ifndef ATAPI
/* This is not valid in ATAPI mode. */
if (wdtab[unit].controller_queue.tqh_first)
#endif
wdstart(unit);
}
/*
* Initialize a drive.
*/
int
wdopen(dev_t dev, int flags, int fmt, struct proc *p)
{
register unsigned int lunit;
register struct disk *du;
int error;
int part = dkpart(dev), mask = 1 << part;
struct partition *pp;
char *msg;
lunit = dkunit(dev);
if (lunit >= NWD || dktype(dev) != 0)
return (ENXIO);
du = wddrives[lunit];
if (du == NULL)
return (ENXIO);
/* Finish flushing IRQs left over from wdattach(). */
if (wdtab[du->dk_ctrlr].b_active == 2)
wdtab[du->dk_ctrlr].b_active = 0;
du->dk_flags &= ~DKFL_BADSCAN;
while (du->dk_flags & DKFL_LABELLING)
tsleep((caddr_t)&du->dk_flags, PZERO - 1, "wdopen", 1);
#if 1
kdc_wd[lunit].kdc_state = DC_BUSY;
wdsleep(du->dk_ctrlr, "wdopn1");
du->dk_flags |= DKFL_LABELLING;
du->dk_state = WANTOPEN;
/* drive_queue[lunit].b_actf = NULL; */
{
struct disklabel label;
bzero(&label, sizeof label);
label.d_secsize = du->dk_dd.d_secsize;
label.d_nsectors = du->dk_dd.d_nsectors;
label.d_ntracks = du->dk_dd.d_ntracks;
label.d_ncylinders = du->dk_dd.d_ncylinders;
label.d_secpercyl = du->dk_dd.d_secpercyl;
label.d_secperunit = du->dk_dd.d_secperunit;
error = dsopen("wd", dev, fmt, &du->dk_slices, &label, wdstrategy1,
(ds_setgeom_t *)NULL);
}
du->dk_flags &= ~DKFL_LABELLING;
wdsleep(du->dk_ctrlr, "wdopn2");
return (error);
#else
if ((du->dk_flags & DKFL_BSDLABEL) == 0) {
/*
* wdtab[ctrlr].b_active != 0 implies
* drive_queue[lunit].b_actf == NULL (?)
* so the following guards most things (until the next i/o).
* It doesn't guard against a new i/o starting and being
* affected by the label being changed. Sigh.
*/
wdsleep(du->dk_ctrlr, "wdopn1");
du->dk_flags |= DKFL_LABELLING;
du->dk_state = WANTOPEN;
/* drive_queue[lunit].b_actf = NULL; */
error = dsinit(dkmodpart(dev, RAW_PART), wdstrategy,
&du->dk_dd, &du->dk_slices);
if (error != 0) {
du->dk_flags &= ~DKFL_LABELLING;
return (error);
}
/* XXX check value returned by wdwsetctlr(). */
wdwsetctlr(du);
if (dkslice(dev) == WHOLE_DISK_SLICE) {
dsopen(dev, fmt, du->dk_slices);
return (0);
}
/*
* Read label using RAW_PART partition.
*
* If the drive has an MBR, then the current geometry (from
* wdgetctlr()) is used to read it; then the BIOS/DOS
* geometry is inferred and used to read the label off the
* 'c' partition. Otherwise the label is read using the
* current geometry. The label gives the final geometry.
* If bad sector handling is enabled, then this geometry
* is used to read the bad sector table. The geometry
* changes occur inside readdisklabel() and are propagated
* to the driver by resetting the state machine.
*
* XXX can now handle changes directly since dsinit() doesn't
* do too much.
*/
msg = correct_readdisklabel(dkmodpart(dev, RAW_PART), wdstrategy,
&du->dk_dd);
/* XXX check value returned by wdwsetctlr(). */
wdwsetctlr(du);
if (msg == NULL && du->dk_dd.d_flags & D_BADSECT)
msg = readbad144(dkmodpart(dev, RAW_PART), wdstrategy,
&du->dk_dd, &du->dk_bad);
du->dk_flags &= ~DKFL_LABELLING;
if (msg != NULL) {
log(LOG_WARNING, "wd%d: cannot find label (%s)\n",
lunit, msg);
if (part != RAW_PART)
return (EINVAL); /* XXX needs translation */
/*
* Soon return. This is how slices without labels
* are allowed. They only work on the raw partition.
*/
} else {
unsigned long newsize, offset, size;
#if 0
/*
* Force RAW_PART partition to be the whole disk.
*/
offset = du->dk_dd.d_partitions[RAW_PART].p_offset;
if (offset != 0) {
printf(
"wd%d: changing offset of '%c' partition from %lu to 0\n",
du->dk_lunit, 'a' + RAW_PART, offset);
du->dk_dd.d_partitions[RAW_PART].p_offset = 0;
}
size = du->dk_dd.d_partitions[RAW_PART].p_size;
newsize = du->dk_dd.d_secperunit; /* XXX */
if (size != newsize) {
printf(
"wd%d: changing size of '%c' partition from %lu to %lu\n",
du->dk_lunit, 'a' + RAW_PART, size,
newsize);
du->dk_dd.d_partitions[RAW_PART].p_size
= newsize;
}
#endif
}
/* Pick up changes made by readdisklabel(). */
wdsleep(du->dk_ctrlr, "wdopn2");
du->dk_state = WANTOPEN;
}
/*
* Warn if a partion is opened that overlaps another partition which
* is open unless one is the "raw" partition (whole disk).
*/
if ((du->dk_openpart & mask) == 0 && part != RAW_PART) {
int start, end;
pp = &du->dk_dd.d_partitions[part];
start = pp->p_offset;
end = pp->p_offset + pp->p_size;
for (pp = du->dk_dd.d_partitions;
pp < &du->dk_dd.d_partitions[du->dk_dd.d_npartitions];
pp++) {
if (pp->p_offset + pp->p_size <= start ||
pp->p_offset >= end)
continue;
if (pp - du->dk_dd.d_partitions == RAW_PART)
continue;
if (du->dk_openpart
& (1 << (pp - du->dk_dd.d_partitions)))
log(LOG_WARNING,
"wd%d%c: overlaps open partition (%c)\n",
lunit, part + 'a',
pp - du->dk_dd.d_partitions + 'a');
}
}
if (part >= du->dk_dd.d_npartitions && part != RAW_PART)
return (ENXIO);
dsopen(dev, fmt, du->dk_slices);
return (0);
#endif
}
/*
* Implement operations other than read/write.
* Called from wdstart or wdintr during opens and formats.
* Uses finite-state-machine to track progress of operation in progress.
* Returns 0 if operation still in progress, 1 if completed, 2 if error.
*/
static int
wdcontrol(register struct buf *bp)
{
register struct disk *du;
int ctrlr;
du = wddrives[dkunit(bp->b_dev)];
ctrlr = du->dk_ctrlr;
switch (du->dk_state) {
case WANTOPEN:
tryagainrecal:
wdtab[ctrlr].b_active = 1;
if (wdcommand(du, 0, 0, 0, 0, WDCC_RESTORE | WD_STEP) != 0) {
wderror(bp, du, "wdcontrol: wdcommand failed");
goto maybe_retry;
}
du->dk_state = RECAL;
return (0);
case RECAL:
if (du->dk_status & WDCS_ERR || wdsetctlr(du) != 0) {
wderror(bp, du, "wdcontrol: recal failed");
maybe_retry:
if (du->dk_status & WDCS_ERR)
wdunwedge(du);
du->dk_state = WANTOPEN;
if (++wdtab[ctrlr].b_errcnt < RETRIES)
goto tryagainrecal;
bp->b_error = ENXIO; /* XXX needs translation */
bp->b_flags |= B_ERROR;
return (2);
}
wdtab[ctrlr].b_errcnt = 0;
du->dk_state = OPEN;
/*
* The rest of the initialization can be done by normal
* means.
*/
return (1);
}
panic("wdcontrol");
return (2);
}
/*
* Wait uninterruptibly until controller is not busy, then send it a command.
* The wait usually terminates immediately because we waited for the previous
* command to terminate.
*/
static int
wdcommand(struct disk *du, u_int cylinder, u_int head, u_int sector,
u_int count, u_int command)
{
u_int wdc;
wdc = du->dk_port;
if (du->cfg_flags & WDOPT_SLEEPHACK)
if(inb(wdc + wd_status) == WDCS_BUSY)
wdunwedge(du);
if (wdwait(du, 0, TIMEOUT) < 0)
return (1);
if( command == WDCC_FEATURES) {
outb(wdc + wd_features, count);
} else {
outb(wdc + wd_precomp, du->dk_dd.d_precompcyl / 4);
outb(wdc + wd_cyl_lo, cylinder);
outb(wdc + wd_cyl_hi, cylinder >> 8);
outb(wdc + wd_sdh, WDSD_IBM | (du->dk_unit << 4) | head);
outb(wdc + wd_sector, sector + 1);
outb(wdc + wd_seccnt, count);
}
if (wdwait(du, command == WDCC_DIAGNOSE || command == WDCC_IDC
? 0 : WDCS_READY, TIMEOUT) < 0)
return (1);
outb(wdc + wd_command, command);
return (0);
}
/*
* issue IDC to drive to tell it just what geometry it is to be.
*/
static int
wdsetctlr(struct disk *du)
{
int error = 0;
#ifdef WDDEBUG
printf("wd(%d,%d): wdsetctlr: C %lu H %lu S %lu\n",
du->dk_ctrlr, du->dk_unit,
du->dk_dd.d_ncylinders, du->dk_dd.d_ntracks,
du->dk_dd.d_nsectors);
#endif
if (du->dk_dd.d_ntracks == 0 || du->dk_dd.d_ntracks > 16) {
struct wdparams *wp;
printf("wd%d: can't handle %lu heads from partition table ",
du->dk_lunit, du->dk_dd.d_ntracks);
/* obtain parameters */
wp = &du->dk_params;
if (wp->wdp_heads > 0 && wp->wdp_heads <= 16) {
printf("(controller value %u restored)\n",
wp->wdp_heads);
du->dk_dd.d_ntracks = wp->wdp_heads;
}
else {
printf("(truncating to 16)\n");
du->dk_dd.d_ntracks = 16;
}
}
if (du->dk_dd.d_nsectors == 0 || du->dk_dd.d_nsectors > 255) {
printf("wd%d: cannot handle %lu sectors (max 255)\n",
du->dk_lunit, du->dk_dd.d_nsectors);
error = 1;
}
if (error) {
wdtab[du->dk_ctrlr].b_errcnt += RETRIES;
return (1);
}
if (wdcommand(du, du->dk_dd.d_ncylinders, du->dk_dd.d_ntracks - 1, 0,
du->dk_dd.d_nsectors, WDCC_IDC) != 0
|| wdwait(du, WDCS_READY, TIMEOUT) < 0) {
wderror((struct buf *)NULL, du, "wdsetctlr failed");
return (1);
}
return (0);
}
/*
* Wait until driver is inactive, then set up controller.
*/
static int
wdwsetctlr(struct disk *du)
{
int stat;
int x;
wdsleep(du->dk_ctrlr, "wdwset");
x = splbio();
stat = wdsetctlr(du);
wdflushirq(du, x);
splx(x);
return (stat);
}
/*
* issue READP to drive to ask it what it is.
*/
static int
wdgetctlr(struct disk *du)
{
int i;
char tb[DEV_BSIZE], tb2[DEV_BSIZE];
struct wdparams *wp = NULL;
u_long flags = du->cfg_flags;
again:
if (wdcommand(du, 0, 0, 0, 0, WDCC_READP) != 0
|| wdwait(du, WDCS_READY | WDCS_SEEKCMPLT | WDCS_DRQ, TIMEOUT) != 0) {
/*
* if we failed on the second try, assume non-32bit
*/
if( du->dk_flags & DKFL_32BIT)
goto failed;
/* XXX need to check error status after final transfer. */
/*
* Old drives don't support WDCC_READP. Try a seek to 0.
* Some IDE controllers return trash if there is no drive
* attached, so first test that the drive can be selected.
* This also avoids long waits for nonexistent drives.
*/
if (wdwait(du, 0, TIMEOUT) < 0)
return (1);
outb(du->dk_port + wd_sdh, WDSD_IBM | (du->dk_unit << 4));
DELAY(5000); /* usually unnecessary; drive select is fast */
if ((inb(du->dk_port + wd_status) & (WDCS_BUSY | WDCS_READY))
!= WDCS_READY
|| wdcommand(du, 0, 0, 0, 0, WDCC_RESTORE | WD_STEP) != 0
|| wdwait(du, WDCS_READY | WDCS_SEEKCMPLT, TIMEOUT) != 0)
return (1);
if (du->dk_unit == bootinfo.bi_n_bios_used) {
du->dk_dd.d_secsize = DEV_BSIZE;
du->dk_dd.d_nsectors =
bootinfo.bi_bios_geom[du->dk_unit] & 0xff;
du->dk_dd.d_ntracks =
((bootinfo.bi_bios_geom[du->dk_unit] >> 8) & 0xff)
+ 1;
/* XXX Why 2 ? */
du->dk_dd.d_ncylinders =
(bootinfo.bi_bios_geom[du->dk_unit] >> 16) + 2;
du->dk_dd.d_secpercyl =
du->dk_dd.d_ntracks * du->dk_dd.d_nsectors;
du->dk_dd.d_secperunit =
du->dk_dd.d_secpercyl * du->dk_dd.d_ncylinders;
#if 0
du->dk_dd.d_partitions[WDRAW].p_size =
du->dk_dd.d_secperunit;
du->dk_dd.d_type = DTYPE_ST506;
du->dk_dd.d_subtype |= DSTYPE_GEOMETRY;
strncpy(du->dk_dd.d_typename, "Bios geometry",
sizeof du->dk_dd.d_typename);
strncpy(du->dk_params.wdp_model, "ST506",
sizeof du->dk_params.wdp_model);
#endif
bootinfo.bi_n_bios_used ++;
return 0;
}
/*
* Fake minimal drive geometry for reading the MBR.
* readdisklabel() may enlarge it to read the label and the
* bad sector table.
*/
du->dk_dd.d_secsize = DEV_BSIZE;
du->dk_dd.d_nsectors = 17;
du->dk_dd.d_ntracks = 1;
du->dk_dd.d_ncylinders = 1;
du->dk_dd.d_secpercyl = 17;
du->dk_dd.d_secperunit = 17;
#if 0
/*
* Fake maximal drive size for writing the label.
*/
du->dk_dd.d_partitions[RAW_PART].p_size = 64 * 16 * 1024;
/*
* Fake some more of the label for printing by disklabel(1)
* in case there is no real label.
*/
du->dk_dd.d_type = DTYPE_ST506;
du->dk_dd.d_subtype |= DSTYPE_GEOMETRY;
strncpy(du->dk_dd.d_typename, "Fake geometry",
sizeof du->dk_dd.d_typename);
#endif
/* Fake the model name for printing by wdattach(). */
strncpy(du->dk_params.wdp_model, "unknown",
sizeof du->dk_params.wdp_model);
return (0);
}
/* obtain parameters */
wp = &du->dk_params;
if (du->dk_flags & DKFL_32BIT)
insl(du->dk_port + wd_data, tb, sizeof(tb) / sizeof(long));
else
insw(du->dk_port + wd_data, tb, sizeof(tb) / sizeof(short));
/* try 32-bit data path (VLB IDE controller) */
if (flags & WDOPT_32BIT) {
if (! (du->dk_flags & DKFL_32BIT)) {
bcopy(tb, tb2, sizeof(struct wdparams));
du->dk_flags |= DKFL_32BIT;
goto again;
}
/* check that we really have 32-bit controller */
if (bcmp (tb, tb2, sizeof(struct wdparams)) != 0) {
failed:
/* test failed, use 16-bit i/o mode */
bcopy(tb2, tb, sizeof(struct wdparams));
du->dk_flags &= ~DKFL_32BIT;
}
}
bcopy(tb, wp, sizeof(struct wdparams));
/* shuffle string byte order */
for (i = 0; i < sizeof(wp->wdp_model); i += 2) {
u_short *p;
p = (u_short *) (wp->wdp_model + i);
*p = ntohs(*p);
}
/*
* Clean up the wdp_model by converting nulls to spaces, and
* then removing the trailing spaces.
*/
for (i=0; i < sizeof(wp->wdp_model); i++) {
if (wp->wdp_model[i] == '\0') {
wp->wdp_model[i] = ' ';
}
}
for (i=sizeof(wp->wdp_model)-1; i>=0 && wp->wdp_model[i]==' '; i--) {
wp->wdp_model[i] = '\0';
}
#ifdef WDDEBUG
printf(
"\nwd(%d,%d): wdgetctlr: gc %x cyl %d trk %d sec %d type %d sz %d model %s\n",
du->dk_ctrlr, du->dk_unit, wp->wdp_config,
wp->wdp_fixedcyl + wp->wdp_removcyl, wp->wdp_heads,
wp->wdp_sectors, wp->wdp_cntype, wp->wdp_cnsbsz,
wp->wdp_model);
#endif
/* update disklabel given drive information */
du->dk_dd.d_secsize = DEV_BSIZE;
du->dk_dd.d_ncylinders = wp->wdp_fixedcyl + wp->wdp_removcyl /*+- 1*/ ;
du->dk_dd.d_ntracks = wp->wdp_heads;
du->dk_dd.d_nsectors = wp->wdp_sectors;
du->dk_dd.d_secpercyl = du->dk_dd.d_ntracks * du->dk_dd.d_nsectors;
du->dk_dd.d_secperunit = du->dk_dd.d_secpercyl * du->dk_dd.d_ncylinders;
#if 0
du->dk_dd.d_partitions[RAW_PART].p_size = du->dk_dd.d_secperunit;
/* dubious ... */
bcopy("ESDI/IDE", du->dk_dd.d_typename, 9);
bcopy(wp->wdp_model + 20, du->dk_dd.d_packname, 14 - 1);
/* better ... */
du->dk_dd.d_type = DTYPE_ESDI;
du->dk_dd.d_subtype |= DSTYPE_GEOMETRY;
#endif
/*
* find out the drives maximum multi-block transfer capability
*/
du->dk_multi = wp->wdp_nsecperint & 0xff;
/*
* The config option flags low 8 bits define the maximum multi-block
* transfer size. If the user wants the maximum that the drive
* is capable of, just set the low bits of the config option to
* 0x00ff.
*/
if ((flags & WDOPT_MULTIMASK) != 0 && (du->dk_multi > 1)) {
if (du->dk_multi > (flags & WDOPT_MULTIMASK))
du->dk_multi = flags & WDOPT_MULTIMASK;
if (wdcommand(du, 0, 0, 0, du->dk_multi, WDCC_SET_MULTI)) {
du->dk_multi = 1;
}
} else {
du->dk_multi = 1;
}
#ifdef NOTYET
/* set read caching and write caching */
wdcommand(du, 0, 0, 0, WDFEA_RCACHE, WDCC_FEATURES);
wdcommand(du, 0, 0, 0, WDFEA_WCACHE, WDCC_FEATURES);
#endif
return (0);
}
int
wdclose(dev_t dev, int flags, int fmt, struct proc *p)
{
dsclose(dev, fmt, wddrives[dkunit(dev)]->dk_slices);
kdc_wd[wddrives[dkunit(dev)]->dk_lunit].kdc_state = DC_IDLE;
return (0);
}
int
wdioctl(dev_t dev, int cmd, caddr_t addr, int flags, struct proc *p)
{
int lunit = dkunit(dev);
register struct disk *du;
int error;
#ifdef notyet
struct uio auio;
struct iovec aiov;
struct format_op *fop;
#endif
du = wddrives[lunit];
wdsleep(du->dk_ctrlr, "wdioct");
error = dsioctl("wd", dev, cmd, addr, flags, &du->dk_slices,
wdstrategy1, (ds_setgeom_t *)NULL);
if (error != -1)
return (error);
switch (cmd) {
case DIOCSBADSCAN:
if (*(int *)addr)
du->dk_flags |= DKFL_BADSCAN;
else
du->dk_flags &= ~DKFL_BADSCAN;
return (0);
#ifdef notyet
case DIOCWFORMAT:
if (!(flag & FWRITE))
return (EBADF);
fop = (struct format_op *)addr;
aiov.iov_base = fop->df_buf;
aiov.iov_len = fop->df_count;
auio.uio_iov = &aiov;
auio.uio_iovcnt = 1;
auio.uio_resid = fop->df_count;
auio.uio_segflg = 0;
auio.uio_offset = fop->df_startblk * du->dk_dd.d_secsize;
#error /* XXX the 386BSD interface is different */
error = physio(wdformat, &rwdbuf[lunit], 0, dev, B_WRITE,
minphys, &auio);
fop->df_count -= auio.uio_resid;
fop->df_reg[0] = du->dk_status;
fop->df_reg[1] = du->dk_error;
return (error);
#endif
default:
return (ENOTTY);
}
}
#ifdef B_FORMAT
int
wdformat(struct buf *bp)
{
bp->b_flags |= B_FORMAT;
wdstrategy(bp);
/*
* phk put this here, better that return(wdstrategy(bp));
* XXX
*/
return -1;
}
#endif
int
wdsize(dev_t dev)
{
struct disk *du;
int lunit;
lunit = dkunit(dev);
if (lunit >= NWD || dktype(dev) != 0)
return (-1);
du = wddrives[lunit];
if (du == NULL)
return (-1);
return (dssize(dev, &du->dk_slices, wdopen, wdclose));
}
/*
* Dump core after a system crash.
*/
int
wddump(dev_t dev)
{
register struct disk *du;
struct disklabel *lp;
long num; /* number of sectors to write */
int lunit, part;
long blkoff, blknum;
long blkchk, blkcnt, blknext;
long cylin, head, sector;
long secpertrk, secpercyl, nblocks;
u_long ds_offset;
char *addr;
static int wddoingadump = 0;
/* Toss any characters present prior to dump. */
while (cncheckc())
;
/* Check for acceptable device. */
/* XXX should reset to maybe allow du->dk_state < OPEN. */
lunit = dkunit(dev); /* eventually support floppies? */
part = dkpart(dev);
if (lunit >= NWD || (du = wddrives[lunit]) == NULL
|| du->dk_state < OPEN
|| (lp = dsgetlabel(dev, du->dk_slices)) == NULL)
return (ENXIO);
/* Size of memory to dump, in disk sectors. */
num = (u_long)Maxmem * NBPG / du->dk_dd.d_secsize;
secpertrk = du->dk_dd.d_nsectors;
secpercyl = du->dk_dd.d_secpercyl;
nblocks = lp->d_partitions[part].p_size;
blkoff = lp->d_partitions[part].p_offset;
/* XXX */
ds_offset = du->dk_slices->dss_slices[dkslice(dev)].ds_offset;
blkoff += ds_offset;
#if 0
pg("part %x, nblocks %d, dumplo %d num %d\n",
part, nblocks, dumplo, num);
#endif
/* Check transfer bounds against partition size. */
if (dumplo < 0 || dumplo + num > nblocks)
return (EINVAL);
/* Check if we are being called recursively. */
if (wddoingadump)
return (EFAULT);
#if 0
/* Mark controller active for if we panic during the dump. */
wdtab[du->dk_ctrlr].b_active = 1;
#endif
wddoingadump = 1;
/* Recalibrate the drive. */
DELAY(5); /* ATA spec XXX NOT */
if (wdcommand(du, 0, 0, 0, 0, WDCC_RESTORE | WD_STEP) != 0
|| wdwait(du, WDCS_READY | WDCS_SEEKCMPLT, TIMEOUT) != 0
|| wdsetctlr(du) != 0) {
wderror((struct buf *)NULL, du, "wddump: recalibrate failed");
return (EIO);
}
du->dk_flags |= DKFL_SINGLE;
addr = (char *) 0;
blknum = dumplo + blkoff;
while (num > 0) {
blkcnt = num;
if (blkcnt > MAXTRANSFER)
blkcnt = MAXTRANSFER;
/* Keep transfer within current cylinder. */
if ((blknum + blkcnt - 1) / secpercyl != blknum / secpercyl)
blkcnt = secpercyl - (blknum % secpercyl);
blknext = blknum + blkcnt;
/*
* See if one of the sectors is in the bad sector list
* (if we have one). If the first sector is bad, then
* reduce the transfer to this one bad sector; if another
* sector is bad, then reduce reduce the transfer to
* avoid any bad sectors.
*/
if (du->dk_flags & DKFL_SINGLE
&& dsgetbad(dev, du->dk_slices) != NULL) {
for (blkchk = blknum; blkchk < blknum + blkcnt; blkchk++) {
daddr_t blknew;
blknew = transbad144(dsgetbad(dev, du->dk_slices),
blkchk - ds_offset) + ds_offset;
if (blknew != blkchk) {
/* Found bad block. */
blkcnt = blkchk - blknum;
if (blkcnt > 0) {
blknext = blknum + blkcnt;
goto out;
}
blkcnt = 1;
blknext = blknum + blkcnt;
#if 1 || defined(WDDEBUG)
printf("bad block %lu -> %lu\n",
blknum, blknew);
#endif
break;
}
}
}
out:
/* Compute disk address. */
cylin = blknum / secpercyl;
head = (blknum % secpercyl) / secpertrk;
sector = blknum % secpertrk;
#if 0
/* Let's just talk about this first... */
pg("cylin l%d head %ld sector %ld addr 0x%x count %ld",
cylin, head, sector, addr, blkcnt);
#endif
/* Do the write. */
if (wdcommand(du, cylin, head, sector, blkcnt, WDCC_WRITE)
!= 0) {
wderror((struct buf *)NULL, du,
"wddump: timeout waiting to to give command");
return (EIO);
}
while (blkcnt != 0) {
pmap_enter(kernel_pmap, (vm_offset_t)CADDR1, trunc_page(addr),
VM_PROT_READ, TRUE);
/* Ready to send data? */
DELAY(5); /* ATA spec */
if (wdwait(du, WDCS_READY | WDCS_SEEKCMPLT | WDCS_DRQ, TIMEOUT)
< 0) {
wderror((struct buf *)NULL, du,
"wddump: timeout waiting for DRQ");
return (EIO);
}
if (du->dk_flags & DKFL_32BIT)
outsl(du->dk_port + wd_data,
CADDR1 + ((int)addr & (NBPG - 1)),
DEV_BSIZE / sizeof(long));
else
outsw(du->dk_port + wd_data,
CADDR1 + ((int)addr & (NBPG - 1)),
DEV_BSIZE / sizeof(short));
addr += DEV_BSIZE;
if ((unsigned)addr % (1024 * 1024) == 0)
printf("%ld ", num / (1024 * 1024 / DEV_BSIZE));
num--;
blkcnt--;
}
/* Wait for completion. */
DELAY(5); /* ATA spec XXX NOT */
if (wdwait(du, WDCS_READY | WDCS_SEEKCMPLT, TIMEOUT) < 0) {
wderror((struct buf *)NULL, du,
"wddump: timeout waiting for status");
return (EIO);
}
/* Check final status. */
if (du->dk_status
& (WDCS_READY | WDCS_SEEKCMPLT | WDCS_DRQ | WDCS_ERR)
!= (WDCS_READY | WDCS_SEEKCMPLT)) {
wderror((struct buf *)NULL, du,
"wddump: extra DRQ, or error");
return (EIO);
}
/* Update block count. */
blknum = blknext;
/* Operator aborting dump? */
if (cncheckc())
return (EINTR);
}
return (0);
}
static void
wderror(struct buf *bp, struct disk *du, char *mesg)
{
if (bp == NULL)
printf("wd%d: %s:\n", du->dk_lunit, mesg);
else
diskerr(bp, "wd", mesg, LOG_PRINTF, du->dk_skip,
dsgetlabel(bp->b_dev, du->dk_slices));
printf("wd%d: status %b error %b\n", du->dk_lunit,
du->dk_status, WDCS_BITS, du->dk_error, WDERR_BITS);
}
/*
* Discard any interrupts that were latched by the interrupt system while
* we were doing polled i/o.
*/
static void
wdflushirq(struct disk *du, int old_ipl)
{
wdtab[du->dk_ctrlr].b_active = 2;
splx(old_ipl);
(void)splbio();
wdtab[du->dk_ctrlr].b_active = 0;
}
/*
* Reset the controller.
*/
static int
wdreset(struct disk *du)
{
int wdc, err = 0;
wdc = du->dk_port;
(void)wdwait(du, 0, TIMEOUT);
outb(wdc + wd_ctlr, WDCTL_IDS | WDCTL_RST);
DELAY(10 * 1000);
outb(wdc + wd_ctlr, WDCTL_IDS);
#ifdef ATAPI
if (wdwait(du, WDCS_READY | WDCS_SEEKCMPLT, TIMEOUT) != 0)
err = 1; /* no IDE drive found */
du->dk_error = inb(wdc + wd_error);
if (du->dk_error != 0x01)
err = 1; /* the drive is incompatible */
#else
if (wdwait(du, WDCS_READY | WDCS_SEEKCMPLT, TIMEOUT) != 0
|| (du->dk_error = inb(wdc + wd_error)) != 0x01)
return (1);
#endif
outb(wdc + wd_ctlr, WDCTL_4BIT);
return (err);
}
/*
* Sleep until driver is inactive.
* This is used only for avoiding rare race conditions, so it is unimportant
* that the sleep may be far too short or too long.
*/
static void
wdsleep(int ctrlr, char *wmesg)
{
int s = splbio();
while (wdtab[ctrlr].b_active)
tsleep((caddr_t)&wdtab[ctrlr].b_active, PZERO - 1, wmesg, 1);
splx(s);
}
static void
wdtimeout(void *cdu)
{
struct disk *du;
int x;
static int timeouts;
du = (struct disk *)cdu;
x = splbio();
if (du->dk_timeout != 0 && --du->dk_timeout == 0) {
if(timeouts++ == 5)
wderror((struct buf *)NULL, du,
"Last time I say: interrupt timeout. Probably a portable PC.");
else if(timeouts++ < 5)
wderror((struct buf *)NULL, du, "interrupt timeout");
wdunwedge(du);
wdflushirq(du, x);
du->dk_skip = 0;
du->dk_flags |= DKFL_SINGLE;
wdstart(du->dk_ctrlr);
}
timeout(wdtimeout, cdu, hz);
splx(x);
}
/*
* Reset the controller after it has become wedged. This is different from
* wdreset() so that wdreset() can be used in the probe and so that this
* can restore the geometry .
*/
static int
wdunwedge(struct disk *du)
{
struct disk *du1;
int lunit;
/* Schedule other drives for recalibration. */
for (lunit = 0; lunit < NWD; lunit++)
if ((du1 = wddrives[lunit]) != NULL && du1 != du
&& du1->dk_ctrlr == du->dk_ctrlr
&& du1->dk_state > WANTOPEN)
du1->dk_state = WANTOPEN;
DELAY(RECOVERYTIME);
if (wdreset(du) == 0) {
/*
* XXX - recalibrate current drive now because some callers
* aren't prepared to have its state change.
*/
if (wdcommand(du, 0, 0, 0, 0, WDCC_RESTORE | WD_STEP) == 0
&& wdwait(du, WDCS_READY | WDCS_SEEKCMPLT, TIMEOUT) == 0
&& wdsetctlr(du) == 0)
return (0);
}
wderror((struct buf *)NULL, du, "wdunwedge failed");
return (1);
}
/*
* Wait uninterruptibly until controller is not busy and either certain
* status bits are set or an error has occurred.
* The wait is usually short unless it is for the controller to process
* an entire critical command.
* Return 1 for (possibly stale) controller errors, -1 for timeout errors,
* or 0 for no errors.
* Return controller status in du->dk_status and, if there was a controller
* error, return the error code in du->dk_error.
*/
#ifdef WD_COUNT_RETRIES
static int min_retries[NWDC];
#endif
static int
wdwait(struct disk *du, u_char bits_wanted, int timeout)
{
int wdc;
u_char status;
#define POLLING 1000
wdc = du->dk_port;
timeout += POLLING;
/*
* This delay is really too long, but does not impact the performance
* as much when using the multi-sector option. Shorter delays have
* caused I/O errors on some drives and system configs. This should
* probably be fixed if we develop a better short term delay mechanism.
*/
DELAY(1);
do {
#ifdef WD_COUNT_RETRIES
if (min_retries[du->dk_ctrlr] > timeout
|| min_retries[du->dk_ctrlr] == 0)
min_retries[du->dk_ctrlr] = timeout;
#endif
du->dk_status = status = inb(wdc + wd_status);
#ifdef ATAPI
/*
* Atapi drives have a very interesting feature, when attached
* as a slave on the IDE bus, and there is no master.
* They release the bus after getting the command.
* We should reselect the drive here to get the status.
*/
if (status == 0xff) {
outb(wdc + wd_sdh, WDSD_IBM | du->dk_unit << 4);
du->dk_status = status = inb(wdc + wd_status);
}
#endif
if (!(status & WDCS_BUSY)) {
if (status & WDCS_ERR) {
du->dk_error = inb(wdc + wd_error);
/*
* We once returned here. This is wrong
* because the error bit is apparently only
* valid after the controller has interrupted
* (e.g., the error bit is stale when we wait
* for DRQ for writes). So we can't depend
* on the error bit at all when polling for
* command completion.
*/
}
if ((status & bits_wanted) == bits_wanted)
return (status & WDCS_ERR);
}
if (timeout < TIMEOUT)
/*
* Switch to a polling rate of about 1 KHz so that
* the timeout is almost machine-independent. The
* controller is taking a long time to respond, so
* an extra msec won't matter.
*/
DELAY(1000);
else
DELAY(1);
} while (--timeout != 0);
return (-1);
}
#ifdef JREMOD
struct bdevsw wd_bdevsw =
{ wdopen, wdclose, wdstrategy, wdioctl, /*0*/
wddump, wdsize, 0 };
struct cdevsw wd_cdevsw =
{ wdopen, wdclose, rawread, rawwrite, /*3*/
wdioctl, nostop, nullreset, nodevtotty,/* wd */
seltrue, nommap, wdstrategy };
static wd_devsw_installed = 0;
static void wd_devsw_install()
{
dev_t descript;
if( ! wd_devsw_installed ) {
descript = makedev(CDEV_MAJOR,0);
cdevsw_add(&descript,&wd_cdevsw,NULL);
#if defined(BDEV_MAJOR)
descript = makedev(BDEV_MAJOR,0);
bdevsw_add(&descript,&wd_bdevsw,NULL);
#endif /*BDEV_MAJOR*/
wd_devsw_installed = 1;
}
}
#endif /* JREMOD */
#endif /* NWDC > 0 */