NetBSD/sys/arch/sun3/dev/xd.c
1996-10-13 03:47:25 +00:00

2395 lines
61 KiB
C

/* $NetBSD: xd.c,v 1.10 1996/10/13 03:47:39 christos Exp $ */
/*
*
* Copyright (c) 1995 Charles D. Cranor
* All rights reserved.
*
* 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 Charles D. Cranor.
* 4. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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.
*/
/*
*
* x d . c x y l o g i c s 7 5 3 / 7 0 5 3 v m e / s m d d r i v e r
*
* author: Chuck Cranor <chuck@ccrc.wustl.edu>
* id: $NetBSD: xd.c,v 1.10 1996/10/13 03:47:39 christos Exp $
* started: 27-Feb-95
* references: [1] Xylogics Model 753 User's Manual
* part number: 166-753-001, Revision B, May 21, 1988.
* "Your Partner For Performance"
* [2] other NetBSD disk device drivers
*
* Special thanks go to Scott E. Campbell of Xylogics, Inc. for taking
* the time to answer some of my questions about the 753/7053.
*
* note: the 753 and the 7053 are programmed the same way, but are
* different sizes. the 753 is a 6U VME card, while the 7053 is a 9U
* VME card (found in many VME based suns).
*/
#undef XDC_DEBUG /* full debug */
#define XDC_DIAG /* extra sanity checks */
#if defined(DIAGNOSTIC) && !defined(XDC_DIAG)
#define XDC_DIAG /* link in with master DIAG option */
#endif
#include <sys/param.h>
#include <sys/proc.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/buf.h>
#include <sys/uio.h>
#include <sys/malloc.h>
#include <sys/device.h>
#include <sys/disklabel.h>
#include <sys/disk.h>
#include <sys/syslog.h>
#include <sys/dkbad.h>
#include <vm/vm.h>
#include <vm/vm_kern.h>
#include <machine/autoconf.h>
#include <machine/sun_disklabel.h>
#include <machine/dvma.h>
#include <sun3/dev/xdreg.h>
#include <sun3/dev/xdvar.h>
#include <sun3/dev/xio.h>
/*
* macros
*/
/*
* XDC_TWAIT: add iorq "N" to tail of SC's wait queue
*/
#define XDC_TWAIT(SC, N) { \
(SC)->waitq[(SC)->waitend] = (N); \
(SC)->waitend = ((SC)->waitend + 1) % XDC_MAXIOPB; \
(SC)->nwait++; \
}
/*
* XDC_HWAIT: add iorq "N" to head of SC's wait queue
*/
#define XDC_HWAIT(SC, N) { \
(SC)->waithead = ((SC)->waithead == 0) ? \
(XDC_MAXIOPB - 1) : ((SC)->waithead - 1); \
(SC)->waitq[(SC)->waithead] = (N); \
(SC)->nwait++; \
}
/*
* XDC_GET_WAITER: gets the first request waiting on the waitq
* and removes it (so it can be submitted)
*/
#define XDC_GET_WAITER(XDCSC, RQ) { \
(RQ) = (XDCSC)->waitq[(XDCSC)->waithead]; \
(XDCSC)->waithead = ((XDCSC)->waithead + 1) % XDC_MAXIOPB; \
xdcsc->nwait--; \
}
/*
* XDC_FREE: add iorq "N" to SC's free list
*/
#define XDC_FREE(SC, N) { \
(SC)->freereq[(SC)->nfree++] = (N); \
(SC)->reqs[N].mode = 0; \
if ((SC)->nfree == 1) wakeup(&(SC)->nfree); \
}
/*
* XDC_RQALLOC: allocate an iorq off the free list (assume nfree > 0).
*/
#define XDC_RQALLOC(XDCSC) (XDCSC)->freereq[--((XDCSC)->nfree)]
/*
* XDC_GO: start iopb ADDR (DVMA addr in a u_long) on XDC
*/
#define XDC_GO(XDC, ADDR) { \
(XDC)->xdc_iopbaddr0 = ((ADDR) & 0xff); \
(ADDR) = ((ADDR) >> 8); \
(XDC)->xdc_iopbaddr1 = ((ADDR) & 0xff); \
(ADDR) = ((ADDR) >> 8); \
(XDC)->xdc_iopbaddr2 = ((ADDR) & 0xff); \
(ADDR) = ((ADDR) >> 8); \
(XDC)->xdc_iopbaddr3 = (ADDR); \
(XDC)->xdc_iopbamod = XDC_ADDRMOD; \
(XDC)->xdc_csr = XDC_ADDIOPB; /* go! */ \
}
/*
* XDC_WAIT: wait for XDC's csr "BITS" to come on in "TIME".
* LCV is a counter. If it goes to zero then we timed out.
*/
#define XDC_WAIT(XDC, LCV, TIME, BITS) { \
(LCV) = (TIME); \
while ((LCV) > 0) { \
if ((XDC)->xdc_csr & (BITS)) break; \
(LCV) = (LCV) - 1; \
DELAY(1); \
} \
}
/*
* XDC_DONE: don't need IORQ, get error code and free (done after xdc_cmd)
*/
#define XDC_DONE(SC,RQ,ER) { \
if ((RQ) == XD_ERR_FAIL) { \
(ER) = (RQ); \
} else { \
if ((SC)->ndone-- == XDC_SUBWAITLIM) \
wakeup(&(SC)->ndone); \
(ER) = (SC)->reqs[RQ].errno; \
XDC_FREE((SC), (RQ)); \
} \
}
/*
* XDC_ADVANCE: advance iorq's pointers by a number of sectors
*/
#define XDC_ADVANCE(IORQ, N) { \
if (N) { \
(IORQ)->sectcnt -= (N); \
(IORQ)->blockno += (N); \
(IORQ)->dbuf += ((N)*XDFM_BPS); \
} \
}
/*
* note - addresses you can sleep on:
* [1] & of xd_softc's "state" (waiting for a chance to attach a drive)
* [2] & of xdc_softc's "nfree" (waiting for a free iorq/iopb)
* [3] & of xdc_softc's "ndone" (waiting for number of done iorq/iopb's
* to drop below XDC_SUBWAITLIM)
* [4] & an iorq (waiting for an XD_SUB_WAIT iorq to finish)
*/
/*
* function prototypes
* "xdc_*" functions are internal, all others are external interfaces
*/
/* internals */
int xdc_cmd __P((struct xdc_softc *, int, int, int, int, int, char *, int));
char *xdc_e2str __P((int));
int xdc_error __P((struct xdc_softc *, struct xd_iorq *,
struct xd_iopb *, int, int));
int xdc_ioctlcmd __P((struct xd_softc *, dev_t dev, struct xd_iocmd *));
void xdc_perror __P((struct xd_iorq *, struct xd_iopb *, int));
int xdc_piodriver __P((struct xdc_softc *, int, int));
int xdc_remove_iorq __P((struct xdc_softc *));
int xdc_reset __P((struct xdc_softc *, int, int, int, struct xd_softc *));
inline void xdc_rqinit __P((struct xd_iorq *, struct xdc_softc *,
struct xd_softc *, int, u_long, int,
caddr_t, struct buf *));
void xdc_rqtopb __P((struct xd_iorq *, struct xd_iopb *, int, int));
int xdc_start __P((struct xdc_softc *, int));
int xdc_startbuf __P((struct xdc_softc *, struct xd_softc *, struct buf *));
int xdc_submit_iorq __P((struct xdc_softc *, int, int));
void xdc_tick __P((void *));
int xdc_xdreset __P((struct xdc_softc *, struct xd_softc *));
/* machine interrupt hook */
int xdcintr __P((void *));
/* {b,c}devsw */
int xdclose __P((dev_t, int, int));
int xddump __P((dev_t));
int xdioctl __P((dev_t, u_long, caddr_t, int, struct proc *));
int xdopen __P((dev_t, int, int));
int xdread __P((dev_t, struct uio *));
int xdwrite __P((dev_t, struct uio *));
int xdsize __P((dev_t));
void xdstrategy __P((struct buf *));
/* autoconf */
int xdcmatch __P((struct device *, void *, void *));
void xdcattach __P((struct device *, struct device *, void *));
int xdmatch __P((struct device *, void *, void *));
void xdattach __P((struct device *, struct device *, void *));
static void xddummystrat __P((struct buf *));
int xdgetdisklabel __P((struct xd_softc *, void *));
/*
* cfdrivers: device driver interface to autoconfig
*/
struct cfattach xdc_ca = {
sizeof(struct xdc_softc), xdcmatch, xdcattach
};
struct cfdriver xdc_cd = {
NULL, "xdc", DV_DULL
};
struct cfattach xd_ca = {
sizeof(struct xd_softc), xdmatch, xdattach
};
struct cfdriver xd_cd = {
NULL, "xd", DV_DISK
};
struct xdc_attach_args { /* this is the "aux" args to xdattach */
int driveno; /* unit number */
char *dvmabuf; /* scratch buffer for reading disk label */
int fullmode; /* submit mode */
int booting; /* are we booting or not? */
};
/*
* dkdriver
*/
struct dkdriver xddkdriver = {xdstrategy};
/*
* start: disk label fix code (XXX)
*/
static void *xd_labeldata;
static void
xddummystrat(bp)
struct buf *bp;
{
if (bp->b_bcount != XDFM_BPS)
panic("xddummystrat");
bcopy(xd_labeldata, bp->b_un.b_addr, XDFM_BPS);
bp->b_flags |= B_DONE;
bp->b_flags &= ~B_BUSY;
}
int
xdgetdisklabel(xd, b)
struct xd_softc *xd;
void *b;
{
char *err;
struct sun_disklabel *sdl;
/* We already have the label data in `b'; setup for dummy strategy */
xd_labeldata = b;
/* Required parameter for readdisklabel() */
xd->sc_dk.dk_label->d_secsize = XDFM_BPS;
err = readdisklabel(MAKEDISKDEV(0, xd->sc_dev.dv_unit, RAW_PART),
xddummystrat,
xd->sc_dk.dk_label, xd->sc_dk.dk_cpulabel);
if (err) {
printf("%s: %s\n", xd->sc_dev.dv_xname, err);
return(XD_ERR_FAIL);
}
/* Ok, we have the label; fill in `pcyl' if there's SunOS magic */
sdl = (struct sun_disklabel *)xd->sc_dk.dk_cpulabel->cd_block;
if (sdl->sl_magic == SUN_DKMAGIC)
xd->pcyl = sdl->sl_pcyl;
else {
printf("%s: WARNING: no `pcyl' in disk label.\n",
xd->sc_dev.dv_xname);
xd->pcyl = xd->sc_dk.dk_label->d_ncylinders +
xd->sc_dk.dk_label->d_acylinders;
printf("%s: WARNING: guessing pcyl=%d (ncyl+acyl)\n",
xd->sc_dev.dv_xname, xd->pcyl);
}
xd->ncyl = xd->sc_dk.dk_label->d_ncylinders;
xd->acyl = xd->sc_dk.dk_label->d_acylinders;
xd->nhead = xd->sc_dk.dk_label->d_ntracks;
xd->nsect = xd->sc_dk.dk_label->d_nsectors;
xd->sectpercyl = xd->nhead * xd->nsect;
xd->sc_dk.dk_label->d_secsize = XDFM_BPS; /* not handled by
* sun->bsd */
return(XD_ERR_AOK);
}
/*
* end: disk label fix code (XXX)
*/
/*
* a u t o c o n f i g f u n c t i o n s
*/
/*
* xdcmatch: determine if xdc is present or not. we do a
* soft reset to detect the xdc.
*/
int xdcmatch(parent, match, aux)
struct device *parent;
void *match, *aux;
{
struct cfdata *cf = match;
struct confargs *ca = aux;
int x;
if (ca->ca_bustype != BUS_VME32)
return (0);
/* Default interrupt priority always splbio==2 */
if (ca->ca_intpri == -1)
ca->ca_intpri = 2;
x = bus_peek(ca->ca_bustype, ca->ca_paddr + 11, 1);
if (x == -1)
return (0);
return (1);
}
/*
* xdcattach: attach controller
*/
void
xdcattach(parent, self, aux)
struct device *parent, *self;
void *aux;
{
struct xdc_softc *xdc = (void *) self;
struct confargs *ca = aux;
struct xdc_attach_args xa;
int lcv, rqno, err, pri;
struct xd_iopb_ctrl *ctl;
/* get addressing and intr level stuff from autoconfig and load it
* into our xdc_softc. */
xdc->xdc = (struct xdc *)
bus_mapin(ca->ca_bustype, ca->ca_paddr, sizeof(struct xdc));
xdc->ipl = ca->ca_intpri;
xdc->vector = ca->ca_intvec;
for (lcv = 0; lcv < XDC_MAXDEV; lcv++)
xdc->sc_drives[lcv] = (struct xd_softc *) 0;
/* allocate and zero buffers
*
* note: we simplify the code by allocating the max number of iopbs and
* iorq's up front. thus, we avoid linked lists and the costs
* associated with them in exchange for wasting a little memory. */
xdc->iopbase = (struct xd_iopb *)
dvma_malloc(XDC_MAXIOPB * sizeof(struct xd_iopb)); /* KVA */
bzero(xdc->iopbase, XDC_MAXIOPB * sizeof(struct xd_iopb));
xdc->dvmaiopb = (struct xd_iopb *)
dvma_kvtopa((long) xdc->iopbase, BUS_VME32);
xdc->reqs = (struct xd_iorq *)
malloc(XDC_MAXIOPB * sizeof(struct xd_iorq), M_DEVBUF, M_NOWAIT);
if (xdc->reqs == NULL)
panic("xdc malloc");
bzero(xdc->reqs, XDC_MAXIOPB * sizeof(struct xd_iorq));
/* init free list, iorq to iopb pointers, and non-zero fields in the
* iopb which never change. */
for (lcv = 0; lcv < XDC_MAXIOPB; lcv++) {
xdc->reqs[lcv].iopb = &xdc->iopbase[lcv];
xdc->freereq[lcv] = lcv;
xdc->iopbase[lcv].fixd = 1; /* always the same */
xdc->iopbase[lcv].naddrmod = XDC_ADDRMOD; /* always the same */
xdc->iopbase[lcv].intr_vec = xdc->vector; /* always the same */
}
xdc->nfree = XDC_MAXIOPB;
xdc->nrun = 0;
xdc->waithead = xdc->waitend = xdc->nwait = 0;
xdc->ndone = 0;
/* init queue of waiting bufs */
xdc->sc_wq.b_active = 0;
xdc->sc_wq.b_actf = 0;
xdc->sc_wq.b_actb = &xdc->sc_wq.b_actf;
/*
* section 7 of the manual tells us how to init the controller:
* - read controller parameters (6/0)
* - write controller parameters (5/0)
*/
/* read controller parameters and insure we have a 753/7053 */
rqno = xdc_cmd(xdc, XDCMD_RDP, XDFUN_CTL, 0, 0, 0, 0, XD_SUB_POLL);
if (rqno == XD_ERR_FAIL) {
printf(": couldn't read controller params\n");
return; /* shouldn't ever happen */
}
ctl = (struct xd_iopb_ctrl *) & xdc->iopbase[rqno];
if (ctl->ctype != XDCT_753) {
if (xdc->reqs[rqno].errno)
printf(": %s: ", xdc_e2str(xdc->reqs[rqno].errno));
printf(": doesn't identify as a 753/7053\n");
XDC_DONE(xdc, rqno, err);
return;
}
printf(": Xylogics 753/7053, PROM=%x.%02x.%02x\n",
ctl->eprom_partno, ctl->eprom_lvl, ctl->eprom_rev);
XDC_DONE(xdc, rqno, err);
/* now write controller parameters (xdc_cmd sets all params for us) */
rqno = xdc_cmd(xdc, XDCMD_WRP, XDFUN_CTL, 0, 0, 0, 0, XD_SUB_POLL);
XDC_DONE(xdc, rqno, err);
if (err) {
printf("%s: controller config error: %s\n",
xdc->sc_dev.dv_xname, xdc_e2str(err));
return;
}
/* link in interrupt with higher level software */
isr_add_vectored(xdcintr, (void *)xdc,
ca->ca_intpri, ca->ca_intvec);
evcnt_attach(&xdc->sc_dev, "intr", &xdc->sc_intrcnt);
/* now we must look for disks using autoconfig */
xa.dvmabuf = (char *) dvma_malloc(XDFM_BPS);
xa.fullmode = XD_SUB_POLL;
xa.booting = 1;
for (xa.driveno = 0; xa.driveno < XDC_MAXDEV; xa.driveno++)
(void) config_found(self, (void *) &xa, NULL);
dvma_free(xa.dvmabuf, XDFM_BPS);
/* start the watchdog clock */
timeout(xdc_tick, xdc, XDC_TICKCNT);
}
/*
* xdmatch: probe for disk.
*
* note: we almost always say disk is present. this allows us to
* spin up and configure a disk after the system is booted (we can
* call xdattach!).
*/
int
xdmatch(parent, match, aux)
struct device *parent;
void *match, *aux;
{
struct xdc_softc *xdc = (void *) parent;
struct cfdata *cf = match;
struct xdc_attach_args *xa = aux;
/* looking for autoconf wildcard or exact match */
if (cf->cf_loc[0] != -1 && cf->cf_loc[0] != xa->driveno)
return 0;
return 1;
}
/*
* xdattach: attach a disk. this can be called from autoconf and also
* from xdopen/xdstrategy.
*/
void
xdattach(parent, self, aux)
struct device *parent, *self;
void *aux;
{
struct xd_softc *xd = (void *) self;
struct xdc_softc *xdc = (void *) parent;
struct xdc_attach_args *xa = aux;
int rqno, err, spt, mb, blk, lcv, fmode, s, newstate;
struct xd_iopb_drive *driopb;
struct dkbad *dkb;
struct bootpath *bp;
/*
* Always re-initialize the disk structure. We want statistics
* to start with a clean slate.
*/
bzero(&xd->sc_dk, sizeof(xd->sc_dk));
xd->sc_dk.dk_driver = &xddkdriver;
xd->sc_dk.dk_name = xd->sc_dev.dv_xname;
/* if booting, init the xd_softc */
if (xa->booting) {
xd->state = XD_DRIVE_UNKNOWN; /* to start */
xd->flags = 0;
xd->parent = xdc;
}
xd->xd_drive = xa->driveno;
fmode = xa->fullmode;
xdc->sc_drives[xa->driveno] = xd;
/* if not booting, make sure we are the only process in the attach for
* this drive. if locked out, sleep on it. */
if (!xa->booting) {
s = splbio();
while (xd->state == XD_DRIVE_ATTACHING) {
if (tsleep(&xd->state, PRIBIO, "xdattach", 0)) {
splx(s);
return;
}
}
printf("%s at %s",
xd->sc_dev.dv_xname,
xd->parent->sc_dev.dv_xname);
}
/* we now have control */
xd->state = XD_DRIVE_ATTACHING;
newstate = XD_DRIVE_UNKNOWN;
/* first try and reset the drive */
rqno = xdc_cmd(xdc, XDCMD_RST, 0, xd->xd_drive, 0, 0, 0, fmode);
XDC_DONE(xdc, rqno, err);
if (err == XD_ERR_NRDY) {
printf(" drive %d: off-line\n", xa->driveno);
goto done;
}
if (err) {
printf(": ERROR 0x%02x (%s)\n", err, xdc_e2str(err));
goto done;
}
printf(" drive %d: ready\n", xa->driveno);
/* now set format parameters */
rqno = xdc_cmd(xdc, XDCMD_WRP, XDFUN_FMT, xd->xd_drive, 0, 0, 0, fmode);
XDC_DONE(xdc, rqno, err);
if (err) {
printf("%s: write format parameters failed: %s\n",
xd->sc_dev.dv_xname, xdc_e2str(err));
goto done;
}
/* get drive parameters */
rqno = xdc_cmd(xdc, XDCMD_RDP, XDFUN_DRV, xd->xd_drive, 0, 0, 0, fmode);
if (rqno != XD_ERR_FAIL) {
driopb = (struct xd_iopb_drive *) & xdc->iopbase[rqno];
spt = driopb->sectpertrk;
}
XDC_DONE(xdc, rqno, err);
if (err) {
printf("%s: read drive parameters failed: %s\n",
xd->sc_dev.dv_xname, xdc_e2str(err));
goto done;
}
/*
* now set drive parameters (to semi-bogus values) so we can read the
* disk label.
*/
xd->pcyl = xd->ncyl = 1;
xd->acyl = 0;
xd->nhead = 1;
xd->nsect = 1;
xd->sectpercyl = 1;
for (lcv = 0; lcv < 126; lcv++) /* init empty bad144 table */
xd->dkb.bt_bad[lcv].bt_cyl = xd->dkb.bt_bad[lcv].bt_trksec = 0xffff;
rqno = xdc_cmd(xdc, XDCMD_WRP, XDFUN_DRV, xd->xd_drive, 0, 0, 0, fmode);
XDC_DONE(xdc, rqno, err);
if (err) {
printf("%s: write drive parameters failed: %s\n",
xd->sc_dev.dv_xname, xdc_e2str(err));
goto done;
}
/* read disk label */
rqno = xdc_cmd(xdc, XDCMD_RD, 0, xd->xd_drive, 0, 1,
xa->dvmabuf, fmode);
XDC_DONE(xdc, rqno, err);
if (err) {
printf("%s: reading disk label failed: %s\n",
xd->sc_dev.dv_xname, xdc_e2str(err));
goto done;
}
newstate = XD_DRIVE_NOLABEL;
xd->hw_spt = spt;
/* Attach the disk: must be before getdisklabel to malloc label */
disk_attach(&xd->sc_dk);
if (xdgetdisklabel(xd, xa->dvmabuf) != XD_ERR_AOK)
goto done;
/* inform the user of what is up */
printf("%s: <%s>, pcyl %d, hw_spt %d\n",
xd->sc_dev.dv_xname,
xa->dvmabuf, xd->pcyl, spt);
mb = xd->ncyl * (xd->nhead * xd->nsect) / (1048576 / XDFM_BPS);
printf("%s: %dMB, %d cyl, %d head, %d sec, %d bytes/sec\n",
xd->sc_dev.dv_xname, mb,
xd->ncyl, xd->nhead, xd->nsect, XDFM_BPS);
/* now set the real drive parameters! */
rqno = xdc_cmd(xdc, XDCMD_WRP, XDFUN_DRV, xd->xd_drive, 0, 0, 0, fmode);
XDC_DONE(xdc, rqno, err);
if (err) {
printf("%s: write real drive parameters failed: %s\n",
xd->sc_dev.dv_xname, xdc_e2str(err));
goto done;
}
newstate = XD_DRIVE_ONLINE;
/*
* read bad144 table. this table resides on the first sector of the
* last track of the disk (i.e. second cyl of "acyl" area).
*/
blk = (xd->ncyl + xd->acyl - 1) * (xd->nhead * xd->nsect) + /* last cyl */
(xd->nhead - 1) * xd->nsect; /* last head */
rqno = xdc_cmd(xdc, XDCMD_RD, 0, xd->xd_drive, blk, 1, xa->dvmabuf, fmode);
XDC_DONE(xdc, rqno, err);
if (err) {
printf("%s: reading bad144 failed: %s\n",
xd->sc_dev.dv_xname, xdc_e2str(err));
goto done;
}
/* check dkbad for sanity */
dkb = (struct dkbad *) xa->dvmabuf;
for (lcv = 0; lcv < 126; lcv++) {
if ((dkb->bt_bad[lcv].bt_cyl == 0xffff ||
dkb->bt_bad[lcv].bt_cyl == 0) &&
dkb->bt_bad[lcv].bt_trksec == 0xffff)
continue; /* blank */
if (dkb->bt_bad[lcv].bt_cyl >= xd->ncyl)
break;
if ((dkb->bt_bad[lcv].bt_trksec >> 8) >= xd->nhead)
break;
if ((dkb->bt_bad[lcv].bt_trksec & 0xff) >= xd->nsect)
break;
}
if (lcv != 126) {
printf("%s: warning: invalid bad144 sector!\n",
xd->sc_dev.dv_xname);
} else {
bcopy(xa->dvmabuf, &xd->dkb, XDFM_BPS);
}
/* XXX - Where is this and what does it do? -gwr */
dk_establish(&xd->sc_dk, &xd->sc_dev);
done:
xd->state = newstate;
if (!xa->booting) {
wakeup(&xd->state);
splx(s);
}
}
/*
* end of autoconfig functions
*/
/*
* { b , c } d e v s w f u n c t i o n s
*/
/*
* xdclose: close device
*/
int
xdclose(dev, flag, fmt)
dev_t dev;
int flag, fmt;
{
struct xd_softc *xd = xd_cd.cd_devs[DISKUNIT(dev)];
int part = DISKPART(dev);
/* clear mask bits */
switch (fmt) {
case S_IFCHR:
xd->sc_dk.dk_copenmask &= ~(1 << part);
break;
case S_IFBLK:
xd->sc_dk.dk_bopenmask &= ~(1 << part);
break;
}
xd->sc_dk.dk_openmask = xd->sc_dk.dk_copenmask | xd->sc_dk.dk_bopenmask;
return 0;
}
/*
* xddump: crash dump system
*/
int
xddump(dev)
dev_t dev;
{
int unit, part;
struct xd_softc *xd;
unit = DISKUNIT(dev);
if (unit >= xd_cd.cd_ndevs)
return ENXIO;
part = DISKPART(dev);
xd = xd_cd.cd_devs[unit];
printf("%s%c: crash dump not supported (yet)\n",
xd->sc_dev.dv_xname, 'a' + part);
return ENXIO;
/* outline: globals: "dumplo" == sector number of partition to start
* dump at (convert to physical sector with partition table)
* "dumpsize" == size of dump in clicks "physmem" == size of physical
* memory (clicks, ctob() to get bytes) (normal case: dumpsize ==
* physmem)
*
* dump a copy of physical memory to the dump device starting at sector
* "dumplo" in the swap partition (make sure > 0). map in pages as
* we go. use polled I/O.
*
* XXX how to handle NON_CONTIG? */
}
/*
* xdioctl: ioctls on XD drives. based on ioctl's of other netbsd disks.
*/
int
xdioctl(dev, command, addr, flag, p)
dev_t dev;
u_long command;
caddr_t addr;
int flag;
struct proc *p;
{
struct xd_softc *xd;
struct xd_iocmd *xio;
int error, s, unit;
unit = DISKUNIT(dev);
if (unit >= xd_cd.cd_ndevs || (xd = xd_cd.cd_devs[unit]) == NULL)
return (ENXIO);
/* switch on ioctl type */
switch (command) {
case DIOCSBAD: /* set bad144 info */
if ((flag & FWRITE) == 0)
return EBADF;
s = splbio();
bcopy(addr, &xd->dkb, sizeof(xd->dkb));
splx(s);
return 0;
case DIOCGDINFO: /* get disk label */
bcopy(xd->sc_dk.dk_label, addr, sizeof(struct disklabel));
return 0;
case DIOCGPART: /* get partition info */
((struct partinfo *) addr)->disklab = xd->sc_dk.dk_label;
((struct partinfo *) addr)->part =
&xd->sc_dk.dk_label->d_partitions[DISKPART(dev)];
return 0;
case DIOCSDINFO: /* set disk label */
if ((flag & FWRITE) == 0)
return EBADF;
error = setdisklabel(xd->sc_dk.dk_label,
(struct disklabel *) addr, /* xd->sc_dk.dk_openmask : */ 0,
xd->sc_dk.dk_cpulabel);
if (error == 0) {
if (xd->state == XD_DRIVE_NOLABEL)
xd->state = XD_DRIVE_ONLINE;
}
return error;
case DIOCWLABEL: /* change write status of disk label */
if ((flag & FWRITE) == 0)
return EBADF;
if (*(int *) addr)
xd->flags |= XD_WLABEL;
else
xd->flags &= ~XD_WLABEL;
return 0;
case DIOCWDINFO: /* write disk label */
if ((flag & FWRITE) == 0)
return EBADF;
error = setdisklabel(xd->sc_dk.dk_label,
(struct disklabel *) addr, /* xd->sc_dk.dk_openmask : */ 0,
xd->sc_dk.dk_cpulabel);
if (error == 0) {
if (xd->state == XD_DRIVE_NOLABEL)
xd->state = XD_DRIVE_ONLINE;
/* Simulate opening partition 0 so write succeeds. */
xd->sc_dk.dk_openmask |= (1 << 0);
error = writedisklabel(MAKEDISKDEV(major(dev), DISKUNIT(dev), RAW_PART),
xdstrategy, xd->sc_dk.dk_label,
xd->sc_dk.dk_cpulabel);
xd->sc_dk.dk_openmask =
xd->sc_dk.dk_copenmask | xd->sc_dk.dk_bopenmask;
}
return error;
case DIOSXDCMD:
xio = (struct xd_iocmd *) addr;
if ((error = suser(p->p_ucred, &p->p_acflag)) != 0)
return (error);
return (xdc_ioctlcmd(xd, dev, xio));
default:
return ENOTTY;
}
}
/*
* xdopen: open drive
*/
int
xdopen(dev, flag, fmt)
dev_t dev;
int flag, fmt;
{
int unit, part;
struct xd_softc *xd;
struct xdc_attach_args xa;
/* first, could it be a valid target? */
unit = DISKUNIT(dev);
if (unit >= xd_cd.cd_ndevs || (xd = xd_cd.cd_devs[unit]) == NULL)
return (ENXIO);
part = DISKPART(dev);
/* do we need to attach the drive? */
if (xd->state == XD_DRIVE_UNKNOWN) {
xa.driveno = xd->xd_drive;
xa.dvmabuf = (char *) dvma_malloc(XDFM_BPS);
xa.fullmode = XD_SUB_WAIT;
xa.booting = 0;
xdattach((struct device *) xd->parent, (struct device *) xd, &xa);
dvma_free(xa.dvmabuf, XDFM_BPS);
if (xd->state == XD_DRIVE_UNKNOWN) {
return (EIO);
}
}
/* check for partition */
if (part != RAW_PART &&
(part >= xd->sc_dk.dk_label->d_npartitions ||
xd->sc_dk.dk_label->d_partitions[part].p_fstype == FS_UNUSED)) {
return (ENXIO);
}
/* set open masks */
switch (fmt) {
case S_IFCHR:
xd->sc_dk.dk_copenmask |= (1 << part);
break;
case S_IFBLK:
xd->sc_dk.dk_bopenmask |= (1 << part);
break;
}
xd->sc_dk.dk_openmask = xd->sc_dk.dk_copenmask | xd->sc_dk.dk_bopenmask;
return 0;
}
int
xdread(dev, uio)
dev_t dev;
struct uio *uio;
{
return (physio(xdstrategy, NULL, dev, B_READ, minphys, uio));
}
int
xdwrite(dev, uio)
dev_t dev;
struct uio *uio;
{
return (physio(xdstrategy, NULL, dev, B_WRITE, minphys, uio));
}
/*
* xdsize: return size of a partition for a dump
*/
int
xdsize(dev)
dev_t dev;
{
struct xd_softc *xdsc;
int unit, part, size;
/* valid unit? try an open */
if (xdopen(dev, 0, S_IFBLK) != 0)
return (-1);
/* do it */
xdsc = xd_cd.cd_devs[DISKUNIT(dev)];
part = DISKPART(dev);
if (xdsc->sc_dk.dk_label->d_partitions[part].p_fstype != FS_SWAP)
size = -1; /* only give valid size for swap partitions */
else
size = xdsc->sc_dk.dk_label->d_partitions[part].p_size;
if (xdclose(dev, 0, S_IFBLK) != 0)
return -1;
return size;
}
/*
* xdstrategy: buffering system interface to xd.
*/
void
xdstrategy(bp)
struct buf *bp;
{
struct xd_softc *xd;
struct xdc_softc *parent;
struct buf *wq;
int s, unit;
struct xdc_attach_args xa;
unit = DISKUNIT(bp->b_dev);
/* check for live device */
if (unit >= xd_cd.cd_ndevs || (xd = xd_cd.cd_devs[unit]) == 0 ||
bp->b_blkno < 0 ||
(bp->b_bcount % xd->sc_dk.dk_label->d_secsize) != 0) {
bp->b_error = EINVAL;
goto bad;
}
/* do we need to attach the drive? */
if (xd->state == XD_DRIVE_UNKNOWN) {
xa.driveno = xd->xd_drive;
xa.dvmabuf = (char *) dvma_malloc(XDFM_BPS);
xa.fullmode = XD_SUB_WAIT;
xa.booting = 0;
xdattach((struct device *)xd->parent, (struct device *)xd, &xa);
dvma_free(xa.dvmabuf, XDFM_BPS);
if (xd->state == XD_DRIVE_UNKNOWN) {
bp->b_error = EIO;
goto bad;
}
}
if (xd->state != XD_DRIVE_ONLINE && DISKPART(bp->b_dev) != RAW_PART) {
/* no I/O to unlabeled disks, unless raw partition */
bp->b_error = EIO;
goto bad;
}
/* short circuit zero length request */
if (bp->b_bcount == 0)
goto done;
/* check bounds with label (disksubr.c). Determine the size of the
* transfer, and make sure it is within the boundaries of the
* partition. Adjust transfer if needed, and signal errors or early
* completion. */
if (bounds_check_with_label(bp, xd->sc_dk.dk_label,
(xd->flags & XD_WLABEL) != 0) <= 0)
goto done;
/*
* now we know we have a valid buf structure that we need to do I/O
* on.
*
* note that we don't disksort because the controller has a sorting
* algorithm built into the hardware.
*/
s = splbio(); /* protect the queues */
/* first, give jobs in front of us a chance */
parent = xd->parent;
while (parent->nfree > 0 && parent->sc_wq.b_actf)
if (xdc_startbuf(parent, NULL, NULL) != XD_ERR_AOK)
break;
/* if there are no free iorq's, then we just queue and return. the
* buffs will get picked up later by xdcintr(). */
if (parent->nfree == 0) {
wq = &xd->parent->sc_wq;
bp->b_actf = 0;
bp->b_actb = wq->b_actb;
*wq->b_actb = bp;
wq->b_actb = &bp->b_actf;
splx(s);
return;
}
/* now we have free iopb's and we are at splbio... start 'em up */
if (xdc_startbuf(parent, xd, bp) != XD_ERR_AOK) {
return;
}
/* done! */
splx(s);
return;
bad: /* tells upper layers we have an error */
bp->b_flags |= B_ERROR;
done: /* tells upper layers we are done with this
* buf */
bp->b_resid = bp->b_bcount;
biodone(bp);
}
/*
* end of {b,c}devsw functions
*/
/*
* i n t e r r u p t f u n c t i o n
*
* xdcintr: hardware interrupt.
*/
int
xdcintr(v)
void *v;
{
struct xdc_softc *xdcsc = v;
struct xd_softc *xd;
struct buf *bp;
/* kick the event counter */
xdcsc->sc_intrcnt.ev_count++;
/* remove as many done IOPBs as possible */
xdc_remove_iorq(xdcsc);
/* start any iorq's already waiting */
xdc_start(xdcsc, XDC_MAXIOPB);
/* fill up any remaining iorq's with queue'd buffers */
while (xdcsc->nfree > 0 && xdcsc->sc_wq.b_actf)
if (xdc_startbuf(xdcsc, NULL, NULL) != XD_ERR_AOK)
break;
return (1);
}
/*
* end of interrupt function
*/
/*
* i n t e r n a l f u n c t i o n s
*/
/*
* xdc_rqinit: fill out the fields of an I/O request
*/
inline void
xdc_rqinit(rq, xdc, xd, md, blk, cnt, db, bp)
struct xd_iorq *rq;
struct xdc_softc *xdc;
struct xd_softc *xd;
int md;
u_long blk;
int cnt;
caddr_t db;
struct buf *bp;
{
rq->xdc = xdc;
rq->xd = xd;
rq->ttl = XDC_MAXTTL + 10;
rq->mode = md;
rq->tries = rq->errno = rq->lasterror = 0;
rq->blockno = blk;
rq->sectcnt = cnt;
rq->dbuf = rq->dbufbase = db;
rq->buf = bp;
}
/*
* xdc_rqtopb: load up an IOPB based on an iorq
*/
void
xdc_rqtopb(iorq, iopb, cmd, subfun)
struct xd_iorq *iorq;
struct xd_iopb *iopb;
int cmd, subfun;
{
u_long block, dp;
/* standard stuff */
iopb->errs = iopb->done = 0;
iopb->comm = cmd;
iopb->errno = iopb->status = 0;
iopb->subfun = subfun;
if (iorq->xd)
iopb->unit = iorq->xd->xd_drive;
else
iopb->unit = 0;
/* check for alternate IOPB format */
if (cmd == XDCMD_WRP) {
switch (subfun) {
case XDFUN_CTL:{
struct xd_iopb_ctrl *ctrl =
(struct xd_iopb_ctrl *) iopb;
iopb->lll = 0;
iopb->intl = (XD_STATE(iorq->mode) == XD_SUB_POLL)
? 0
: iorq->xdc->ipl;
ctrl->param_a = XDPA_TMOD | XDPA_DACF;
ctrl->param_b = XDPB_ROR | XDPB_TDT_3_2USEC;
ctrl->param_c = XDPC_OVS | XDPC_COP | XDPC_ASR |
XDPC_RBC | XDPC_ECC2;
ctrl->throttle = XDC_THROTTLE;
#ifdef sparc
if (cputyp == CPU_SUN4 && cpumod == SUN4_300)
ctrl->delay = XDC_DELAY_4_300;
else
ctrl->delay = XDC_DELAY_SPARC;
#endif
#ifdef sun3
ctrl->delay = XDC_DELAY_SUN3;
#endif
break;
}
case XDFUN_DRV:{
struct xd_iopb_drive *drv =
(struct xd_iopb_drive *)iopb;
/* we assume that the disk label has the right
* info */
if (XD_STATE(iorq->mode) == XD_SUB_POLL)
drv->dparam_ipl = (XDC_DPARAM << 3);
else
drv->dparam_ipl = (XDC_DPARAM << 3) |
iorq->xdc->ipl;
drv->maxsect = iorq->xd->nsect - 1;
drv->maxsector = drv->maxsect;
/* note: maxsector != maxsect only if you are
* doing cyl sparing */
drv->headoff = 0;
drv->maxcyl = iorq->xd->pcyl - 1;
drv->maxhead = iorq->xd->nhead - 1;
break;
}
case XDFUN_FMT:{
struct xd_iopb_format *form =
(struct xd_iopb_format *) iopb;
if (XD_STATE(iorq->mode) == XD_SUB_POLL)
form->interleave_ipl = (XDC_INTERLEAVE << 3);
else
form->interleave_ipl = (XDC_INTERLEAVE << 3) |
iorq->xdc->ipl;
form->field1 = XDFM_FIELD1;
form->field2 = XDFM_FIELD2;
form->field3 = XDFM_FIELD3;
form->field4 = XDFM_FIELD4;
form->bytespersec = XDFM_BPS;
form->field6 = XDFM_FIELD6;
form->field7 = XDFM_FIELD7;
break;
}
}
} else {
/* normal IOPB case (harmless to RDP command) */
iopb->lll = 0;
iopb->intl = (XD_STATE(iorq->mode) == XD_SUB_POLL)
? 0
: iorq->xdc->ipl;
iopb->sectcnt = iorq->sectcnt;
block = iorq->blockno;
if (iorq->xd == NULL || block == 0) {
iopb->sectno = iopb->headno = iopb->cylno = 0;
} else {
iopb->sectno = block % iorq->xd->nsect;
block = block / iorq->xd->nsect;
iopb->headno = block % iorq->xd->nhead;
block = block / iorq->xd->nhead;
iopb->cylno = block;
}
iopb->daddr = dp = (iorq->dbuf == NULL) ? 0 :
dvma_kvtopa((long)iorq->dbuf, BUS_VME32);
iopb->addrmod = XDC_ADDRMOD;
}
}
/*
* xdc_cmd: front end for POLL'd and WAIT'd commands. Returns rqno.
* If you've already got an IORQ, you can call submit directly (currently
* there is no need to do this). NORM requests are handled seperately.
*/
int
xdc_cmd(xdcsc, cmd, subfn, unit, block, scnt, dptr, fullmode)
struct xdc_softc *xdcsc;
int cmd, subfn, unit, block, scnt;
char *dptr;
int fullmode;
{
int rqno, submode = XD_STATE(fullmode), retry;
u_long dp;
struct xd_iorq *iorq;
struct xd_iopb *iopb;
/* get iorq/iopb */
switch (submode) {
case XD_SUB_POLL:
while (xdcsc->nfree == 0) {
if (xdc_piodriver(xdcsc, 0, 1) != XD_ERR_AOK)
return (XD_ERR_FAIL);
}
break;
case XD_SUB_WAIT:
retry = 1;
while (retry) {
while (xdcsc->nfree == 0) {
if (tsleep(&xdcsc->nfree, PRIBIO, "xdnfree", 0))
return (XD_ERR_FAIL);
}
while (xdcsc->ndone > XDC_SUBWAITLIM) {
if (tsleep(&xdcsc->ndone, PRIBIO, "xdsubwait", 0))
return (XD_ERR_FAIL);
}
if (xdcsc->nfree)
retry = 0; /* got it */
}
break;
default:
return (XD_ERR_FAIL); /* illegal */
}
if (xdcsc->nfree == 0)
panic("xdcmd nfree");
rqno = XDC_RQALLOC(xdcsc);
iorq = &xdcsc->reqs[rqno];
iopb = iorq->iopb;
/* init iorq/iopb */
xdc_rqinit(iorq, xdcsc,
(unit == XDC_NOUNIT) ? NULL : xdcsc->sc_drives[unit],
fullmode, block, scnt, dptr, NULL);
/* load IOPB from iorq */
xdc_rqtopb(iorq, iopb, cmd, subfn);
/* submit it for processing */
xdc_submit_iorq(xdcsc, rqno, fullmode); /* error code will be in iorq */
return (rqno);
}
/*
* xdc_startbuf
* start a buffer running, assumes nfree > 0
*/
int
xdc_startbuf(xdcsc, xdsc, bp)
struct xdc_softc *xdcsc;
struct xd_softc *xdsc;
struct buf *bp;
{
int rqno, partno;
struct xd_iorq *iorq;
struct xd_iopb *iopb;
struct buf *wq;
u_long block, dp;
caddr_t dbuf;
if (!xdcsc->nfree)
panic("xdc_startbuf free");
rqno = XDC_RQALLOC(xdcsc);
iorq = &xdcsc->reqs[rqno];
iopb = iorq->iopb;
/* get buf */
if (bp == NULL) {
bp = xdcsc->sc_wq.b_actf;
if (!bp)
panic("xdc_startbuf bp");
wq = bp->b_actf;
if (wq)
wq->b_actb = bp->b_actb;
else
xdcsc->sc_wq.b_actb = bp->b_actb;
*bp->b_actb = wq;
xdsc = xdcsc->sc_drives[DISKUNIT(bp->b_dev)];
}
partno = DISKPART(bp->b_dev);
#ifdef XDC_DEBUG
printf("xdc_startbuf: %s%c: %s block %d\n", xdsc->sc_dev.dv_xname,
'a' + partno, (bp->b_flags & B_READ) ? "read" : "write", bp->b_blkno);
printf("xdc_startbuf: b_bcount %d, b_data 0x%x\n",
bp->b_bcount, bp->b_data);
#endif
/*
* load request. we have to calculate the correct block number based
* on partition info.
*
* also, note that there are two kinds of buf structures, those with
* B_PHYS set and those without B_PHYS. if B_PHYS is set, then it is
* a raw I/O (to a cdevsw) and we are doing I/O directly to the users'
* buffer which has already been mapped into DVMA space. (Not on sun3)
* However, if B_PHYS is not set, then the buffer is a normal system
* buffer which does *not* live in DVMA space. In that case we call
* dvma_mapin to map it into DVMA space so we can do the DMA to it.
*
* in cases where we do a dvma_mapin, note that iorq points to the buffer
* as mapped into DVMA space, where as the bp->b_data points to its
* non-DVMA mapping.
*
* XXX - On the sun3, B_PHYS does NOT mean the buffer is mapped
* into dvma space, only that it was remapped into the kernel.
* We ALWAYS have to remap the kernel buf into DVMA space.
* (It is done inexpensively, using whole segments!)
*/
block = bp->b_blkno + ((partno == RAW_PART) ? 0 :
xdsc->sc_dk.dk_label->d_partitions[partno].p_offset);
dbuf = dvma_mapin(bp->b_data, bp->b_bcount);
if (dbuf == NULL) { /* out of DVMA space */
printf("%s: warning: out of DVMA space\n", xdcsc->sc_dev.dv_xname);
XDC_FREE(xdcsc, rqno);
wq = &xdcsc->sc_wq; /* put at end of queue */
bp->b_actf = 0;
bp->b_actb = wq->b_actb;
*wq->b_actb = bp;
wq->b_actb = &bp->b_actf;
return (XD_ERR_FAIL); /* XXX: need some sort of
* call-back scheme here? */
}
/* init iorq and load iopb from it */
xdc_rqinit(iorq, xdcsc, xdsc, XD_SUB_NORM | XD_MODE_VERBO, block,
bp->b_bcount / XDFM_BPS, dbuf, bp);
xdc_rqtopb(iorq, iopb, (bp->b_flags & B_READ) ? XDCMD_RD : XDCMD_WR, 0);
/* Instrumentation. */
disk_busy(&xdsc->sc_dk);
/* now submit [note that xdc_submit_iorq can never fail on NORM reqs] */
xdc_submit_iorq(xdcsc, rqno, XD_SUB_NORM);
return (XD_ERR_AOK);
}
/*
* xdc_submit_iorq: submit an iorq for processing. returns XD_ERR_AOK
* if ok. if it fail returns an error code. type is XD_SUB_*.
*
* note: caller frees iorq in all cases except NORM
*
* return value:
* NORM: XD_AOK (req pending), XD_FAIL (couldn't submit request)
* WAIT: XD_AOK (success), <error-code> (failed)
* POLL: <same as WAIT>
* NOQ : <same as NORM>
*
* there are three sources for i/o requests:
* [1] xdstrategy: normal block I/O, using "struct buf" system.
* [2] autoconfig/crash dump: these are polled I/O requests, no interrupts.
* [3] open/ioctl: these are I/O requests done in the context of a process,
* and the process should block until they are done.
*
* software state is stored in the iorq structure. each iorq has an
* iopb structure. the hardware understands the iopb structure.
* every command must go through an iopb. a 7053 can only handle
* XDC_MAXIOPB (31) active iopbs at one time. iopbs are allocated in
* DVMA space at boot up time. what happens if we run out of iopb's?
* for i/o type [1], the buffers are queued at the "buff" layer and
* picked up later by the interrupt routine. for case [2] the
* programmed i/o driver is called with a special flag that says
* return when one iopb is free. for case [3] the process can sleep
* on the iorq free list until some iopbs are avaliable.
*/
int
xdc_submit_iorq(xdcsc, iorqno, type)
struct xdc_softc *xdcsc;
int iorqno;
int type;
{
u_long iopbaddr;
struct xd_iorq *iorq = &xdcsc->reqs[iorqno];
#ifdef XDC_DEBUG
printf("xdc_submit_iorq(%s, no=%d, type=%d)\n", xdcsc->sc_dev.dv_xname,
iorqno, type);
#endif
/* first check and see if controller is busy */
if (xdcsc->xdc->xdc_csr & XDC_ADDING) {
#ifdef XDC_DEBUG
printf("xdc_submit_iorq: XDC not ready (ADDING)\n");
#endif
if (type == XD_SUB_NOQ)
return (XD_ERR_FAIL); /* failed */
XDC_TWAIT(xdcsc, iorqno); /* put at end of waitq */
switch (type) {
case XD_SUB_NORM:
return XD_ERR_AOK; /* success */
case XD_SUB_WAIT:
while (iorq->iopb->done == 0) {
sleep(iorq, PRIBIO);
}
return (iorq->errno);
case XD_SUB_POLL:
return (xdc_piodriver(xdcsc, iorqno, 0));
default:
panic("xdc_submit_iorq adding");
}
}
#ifdef XDC_DEBUG
{
u_char *rio = (u_char *) iorq->iopb;
int sz = sizeof(struct xd_iopb), lcv;
printf("%s: aio #%d [",
xdcsc->sc_dev.dv_xname, iorq - xdcsc->reqs);
for (lcv = 0; lcv < sz; lcv++)
printf(" %02x", rio[lcv]);
printf("]\n");
}
#endif /* XDC_DEBUG */
/* controller not busy, start command */
iopbaddr = dvma_kvtopa((long) iorq->iopb, BUS_VME32);
XDC_GO(xdcsc->xdc, iopbaddr); /* go! */
xdcsc->nrun++;
/* command now running, wrap it up */
switch (type) {
case XD_SUB_NORM:
case XD_SUB_NOQ:
return (XD_ERR_AOK); /* success */
case XD_SUB_WAIT:
while (iorq->iopb->done == 0) {
sleep(iorq, PRIBIO);
}
return (iorq->errno);
case XD_SUB_POLL:
return (xdc_piodriver(xdcsc, iorqno, 0));
default:
panic("xdc_submit_iorq wrap up");
}
panic("xdc_submit_iorq");
return 0; /* not reached */
}
/*
* xdc_piodriver
*
* programmed i/o driver. this function takes over the computer
* and drains off all i/o requests. it returns the status of the iorq
* the caller is interesting in. if freeone is true, then it returns
* when there is a free iorq.
*/
int
xdc_piodriver(xdcsc, iorqno, freeone)
struct xdc_softc *xdcsc;
char iorqno;
int freeone;
{
int nreset = 0;
int retval = 0;
u_long count;
struct xdc *xdc = xdcsc->xdc;
#ifdef XDC_DEBUG
printf("xdc_piodriver(%s, %d, freeone=%d)\n", xdcsc->sc_dev.dv_xname,
iorqno, freeone);
#endif
while (xdcsc->nwait || xdcsc->nrun) {
#ifdef XDC_DEBUG
printf("xdc_piodriver: wait=%d, run=%d\n",
xdcsc->nwait, xdcsc->nrun);
#endif
XDC_WAIT(xdc, count, XDC_MAXTIME, (XDC_REMIOPB | XDC_F_ERROR));
#ifdef XDC_DEBUG
printf("xdc_piodriver: done wait with count = %d\n", count);
#endif
/* we expect some progress soon */
if (count == 0 && nreset >= 2) {
xdc_reset(xdcsc, 0, XD_RSET_ALL, XD_ERR_FAIL, 0);
#ifdef XDC_DEBUG
printf("xdc_piodriver: timeout\n");
#endif
return (XD_ERR_FAIL);
}
if (count == 0) {
if (xdc_reset(xdcsc, 0,
(nreset++ == 0) ? XD_RSET_NONE : iorqno,
XD_ERR_FAIL,
0) == XD_ERR_FAIL)
return (XD_ERR_FAIL); /* flushes all but POLL
* requests, resets */
continue;
}
xdc_remove_iorq(xdcsc); /* could resubmit request */
if (freeone) {
if (xdcsc->nrun < XDC_MAXIOPB) {
#ifdef XDC_DEBUG
printf("xdc_piodriver: done: one free\n");
#endif
return (XD_ERR_AOK);
}
continue; /* don't xdc_start */
}
xdc_start(xdcsc, XDC_MAXIOPB);
}
/* get return value */
retval = xdcsc->reqs[iorqno].errno;
#ifdef XDC_DEBUG
printf("xdc_piodriver: done, retval = 0x%x (%s)\n",
xdcsc->reqs[iorqno].errno, xdc_e2str(xdcsc->reqs[iorqno].errno));
#endif
/* now that we've drained everything, start up any bufs that have
* queued */
while (xdcsc->nfree > 0 && xdcsc->sc_wq.b_actf)
if (xdc_startbuf(xdcsc, NULL, NULL) != XD_ERR_AOK)
break;
return (retval);
}
/*
* xdc_reset: reset one drive. NOTE: assumes xdc was just reset.
* we steal iopb[0] for this, but we put it back when we are done.
*/
int
xdc_xdreset(xdcsc, xdsc)
struct xdc_softc *xdcsc;
struct xd_softc *xdsc;
{
struct xd_iopb tmpiopb;
u_long addr;
int del;
bcopy(xdcsc->iopbase, &tmpiopb, sizeof(tmpiopb));
bzero(xdcsc->iopbase, sizeof(tmpiopb));
xdcsc->iopbase->comm = XDCMD_RST;
xdcsc->iopbase->unit = xdsc->xd_drive;
addr = (u_long) xdcsc->dvmaiopb;
XDC_GO(xdcsc->xdc, addr); /* go! */
XDC_WAIT(xdcsc->xdc, del, XDC_RESETUSEC, XDC_REMIOPB);
if (del <= 0 || xdcsc->iopbase->errs) {
printf("%s: off-line: %s\n", xdcsc->sc_dev.dv_xname,
xdc_e2str(xdcsc->iopbase->errno));
xdcsc->xdc->xdc_csr = XDC_RESET;
XDC_WAIT(xdcsc->xdc, del, XDC_RESETUSEC, XDC_RESET);
if (del <= 0)
panic("xdc_reset");
} else {
xdcsc->xdc->xdc_csr = XDC_CLRRIO; /* clear RIO */
}
bcopy(&tmpiopb, xdcsc->iopbase, sizeof(tmpiopb));
}
/*
* xdc_reset: reset everything: requests are marked as errors except
* a polled request (which is resubmitted)
*/
int
xdc_reset(xdcsc, quiet, blastmode, error, xdsc)
struct xdc_softc *xdcsc;
int quiet, blastmode, error;
struct xd_softc *xdsc;
{
int del = 0, lcv, poll = -1, retval = XD_ERR_AOK;
int oldfree = xdcsc->nfree;
struct xd_iorq *iorq;
/* soft reset hardware */
if (!quiet)
printf("%s: soft reset\n", xdcsc->sc_dev.dv_xname);
xdcsc->xdc->xdc_csr = XDC_RESET;
XDC_WAIT(xdcsc->xdc, del, XDC_RESETUSEC, XDC_RESET);
if (del <= 0) {
blastmode = XD_RSET_ALL; /* dead, flush all requests */
retval = XD_ERR_FAIL;
}
if (xdsc)
xdc_xdreset(xdcsc, xdsc);
/* fix queues based on "blast-mode" */
for (lcv = 0; lcv < XDC_MAXIOPB; lcv++) {
iorq = &xdcsc->reqs[lcv];
if (XD_STATE(iorq->mode) != XD_SUB_POLL &&
XD_STATE(iorq->mode) != XD_SUB_WAIT &&
XD_STATE(iorq->mode) != XD_SUB_NORM)
/* is it active? */
continue;
xdcsc->nrun--; /* it isn't running any more */
if (blastmode == XD_RSET_ALL || blastmode != lcv) {
/* failed */
iorq->errno = error;
xdcsc->iopbase[lcv].done = xdcsc->iopbase[lcv].errs = 1;
switch (XD_STATE(iorq->mode)) {
case XD_SUB_NORM:
iorq->buf->b_error = EIO;
iorq->buf->b_flags |= B_ERROR;
iorq->buf->b_resid =
iorq->sectcnt * XDFM_BPS;
/* Sun3: map/unmap regardless of B_PHYS */
dvma_mapout(iorq->dbufbase,
iorq->buf->b_bcount);
disk_unbusy(&iorq->xd->sc_dk,
(iorq->buf->b_bcount - iorq->buf->b_resid));
biodone(iorq->buf);
XDC_FREE(xdcsc, lcv); /* add to free list */
break;
case XD_SUB_WAIT:
wakeup(iorq);
case XD_SUB_POLL:
xdcsc->ndone++;
iorq->mode = XD_NEWSTATE(iorq->mode, XD_SUB_DONE);
break;
}
} else {
/* resubmit, put at front of wait queue */
XDC_HWAIT(xdcsc, lcv);
}
}
/*
* now, if stuff is waiting, start it.
* since we just reset it should go
*/
xdc_start(xdcsc, XDC_MAXIOPB);
/* ok, we did it */
if (oldfree == 0 && xdcsc->nfree)
wakeup(&xdcsc->nfree);
#ifdef XDC_DIAG
del = xdcsc->nwait + xdcsc->nrun + xdcsc->nfree + xdcsc->ndone;
if (del != XDC_MAXIOPB)
printf("%s: diag: xdc_reset miscount (%d should be %d)!\n",
xdcsc->sc_dev.dv_xname, del, XDC_MAXIOPB);
else
if (xdcsc->ndone > XDC_MAXIOPB - XDC_SUBWAITLIM)
printf("%s: diag: lots of done jobs (%d)\n",
xdcsc->sc_dev.dv_xname, xdcsc->ndone);
#endif
printf("RESET DONE\n");
return (retval);
}
/*
* xdc_start: start all waiting buffers
*/
int
xdc_start(xdcsc, maxio)
struct xdc_softc *xdcsc;
int maxio;
{
int rqno;
while (maxio && xdcsc->nwait &&
(xdcsc->xdc->xdc_csr & XDC_ADDING) == 0) {
XDC_GET_WAITER(xdcsc, rqno); /* note: rqno is an "out"
* param */
if (xdc_submit_iorq(xdcsc, rqno, XD_SUB_NOQ) != XD_ERR_AOK)
panic("xdc_start"); /* should never happen */
maxio--;
}
}
/*
* xdc_remove_iorq: remove "done" IOPB's.
*/
int
xdc_remove_iorq(xdcsc)
struct xdc_softc *xdcsc;
{
int errno, rqno, comm, errs;
struct xdc *xdc = xdcsc->xdc;
u_long addr;
struct xd_iopb *iopb;
struct xd_iorq *iorq;
struct buf *bp;
if (xdc->xdc_csr & XDC_F_ERROR) {
/*
* FATAL ERROR: should never happen under normal use. This
* error is so bad, you can't even tell which IOPB is bad, so
* we dump them all.
*/
errno = xdc->xdc_f_err;
printf("%s: fatal error 0x%02x: %s\n", xdcsc->sc_dev.dv_xname,
errno, xdc_e2str(errno));
if (xdc_reset(xdcsc, 0, XD_RSET_ALL, errno, 0) != XD_ERR_AOK) {
printf("%s: soft reset failed!\n",
xdcsc->sc_dev.dv_xname);
panic("xdc_remove_iorq: controller DEAD");
}
return (XD_ERR_AOK);
}
/*
* get iopb that is done
*
* hmm... I used to read the address of the done IOPB off the VME
* registers and calculate the rqno directly from that. that worked
* until I started putting a load on the controller. when loaded, i
* would get interrupts but neither the REMIOPB or F_ERROR bits would
* be set, even after DELAY'ing a while! later on the timeout
* routine would detect IOPBs that were marked "running" but their
* "done" bit was set. rather than dealing directly with this
* problem, it is just easier to look at all running IOPB's for the
* done bit.
*/
if (xdc->xdc_csr & XDC_REMIOPB) {
xdc->xdc_csr = XDC_CLRRIO;
}
for (rqno = 0; rqno < XDC_MAXIOPB; rqno++) {
iorq = &xdcsc->reqs[rqno];
if (iorq->mode == 0 || XD_STATE(iorq->mode) == XD_SUB_DONE)
continue; /* free, or done */
iopb = &xdcsc->iopbase[rqno];
if (iopb->done == 0)
continue; /* not done yet */
#ifdef XDC_DEBUG
{
u_char *rio = (u_char *) iopb;
int sz = sizeof(struct xd_iopb), lcv;
printf("%s: rio #%d [", xdcsc->sc_dev.dv_xname, rqno);
for (lcv = 0; lcv < sz; lcv++)
printf(" %02x", rio[lcv]);
printf("]\n");
}
#endif /* XDC_DEBUG */
xdcsc->nrun--;
comm = iopb->comm;
errs = iopb->errs;
if (errs)
iorq->errno = iopb->errno;
else
iorq->errno = 0;
/* handle non-fatal errors */
if (errs &&
xdc_error(xdcsc, iorq, iopb, rqno, comm) == XD_ERR_AOK)
continue; /* AOK: we resubmitted it */
/* this iorq is now done (hasn't been restarted or anything) */
if ((iorq->mode & XD_MODE_VERBO) && iorq->lasterror)
xdc_perror(iorq, iopb, 0);
/* now, if read/write check to make sure we got all the data
* we needed. (this may not be the case if we got an error in
* the middle of a multisector request). */
if ((iorq->mode & XD_MODE_B144) != 0 && errs == 0 &&
(comm == XDCMD_RD || comm == XDCMD_WR)) {
/* we just successfully processed a bad144 sector
* note: if we are in bad 144 mode, the pointers have
* been advanced already (see above) and are pointing
* at the bad144 sector. to exit bad144 mode, we
* must advance the pointers 1 sector and issue a new
* request if there are still sectors left to process
*
*/
XDC_ADVANCE(iorq, 1); /* advance 1 sector */
/* exit b144 mode */
iorq->mode = iorq->mode & (~XD_MODE_B144);
if (iorq->sectcnt) { /* more to go! */
iorq->lasterror = iorq->errno = iopb->errno = 0;
iopb->errs = iopb->done = 0;
iorq->tries = 0;
iopb->sectcnt = iorq->sectcnt;
iopb->cylno = iorq->blockno /
iorq->xd->sectpercyl;
iopb->headno =
(iorq->blockno / iorq->xd->nhead) %
iorq->xd->nhead;
iopb->sectno = iorq->blockno % XDFM_BPS;
iopb->daddr =
dvma_kvtopa((long)iorq->dbuf, BUS_VME32);
XDC_HWAIT(xdcsc, rqno);
xdc_start(xdcsc, 1); /* resubmit */
continue;
}
}
/* final cleanup, totally done with this request */
switch (XD_STATE(iorq->mode)) {
case XD_SUB_NORM:
bp = iorq->buf;
if (errs) {
bp->b_error = EIO;
bp->b_flags |= B_ERROR;
bp->b_resid = iorq->sectcnt * XDFM_BPS;
} else {
bp->b_resid = 0; /* done */
}
/* Sun3: map/unmap regardless of B_PHYS */
dvma_mapout(iorq->dbufbase,
iorq->buf->b_bcount);
disk_unbusy(&iorq->xd->sc_dk,
(bp->b_bcount - bp->b_resid));
XDC_FREE(xdcsc, rqno);
biodone(bp);
break;
case XD_SUB_WAIT:
iorq->mode = XD_NEWSTATE(iorq->mode, XD_SUB_DONE);
xdcsc->ndone++;
wakeup(iorq);
break;
case XD_SUB_POLL:
iorq->mode = XD_NEWSTATE(iorq->mode, XD_SUB_DONE);
xdcsc->ndone++;
break;
}
}
return (XD_ERR_AOK);
}
/*
* xdc_perror: print error.
* - if still_trying is true: we got an error, retried and got a
* different error. in that case lasterror is the old error,
* and errno is the new one.
* - if still_trying is not true, then if we ever had an error it
* is in lasterror. also, if iorq->errno == 0, then we recovered
* from that error (otherwise iorq->errno == iorq->lasterror).
*/
void
xdc_perror(iorq, iopb, still_trying)
struct xd_iorq *iorq;
struct xd_iopb *iopb;
int still_trying;
{
int error = iorq->lasterror;
printf("%s", (iorq->xd) ?
iorq->xd->sc_dev.dv_xname :
iorq->xdc->sc_dev.dv_xname);
if (iorq->buf)
printf("%c: ", 'a' + DISKPART(iorq->buf->b_dev));
if (iopb->comm == XDCMD_RD || iopb->comm == XDCMD_WR)
printf("%s %d/%d/%d: ",
(iopb->comm == XDCMD_RD) ? "read" : "write",
iopb->cylno, iopb->headno, iopb->sectno);
printf("%s", xdc_e2str(error));
if (still_trying)
printf(" [still trying, new error=%s]", xdc_e2str(iorq->errno));
else
if (iorq->errno == 0)
printf(" [recovered in %d tries]", iorq->tries);
printf("\n");
}
/*
* xdc_error: non-fatal error encountered... recover.
* return AOK if resubmitted, return FAIL if this iopb is done
*/
int
xdc_error(xdcsc, iorq, iopb, rqno, comm)
struct xdc_softc *xdcsc;
struct xd_iorq *iorq;
struct xd_iopb *iopb;
int rqno, comm;
{
int errno = iorq->errno;
int erract = errno & XD_ERA_MASK;
int oldmode, advance, i;
if (erract == XD_ERA_RSET) { /* some errors require a reset */
oldmode = iorq->mode;
iorq->mode = XD_SUB_DONE | (~XD_SUB_MASK & oldmode);
xdcsc->ndone++;
/* make xdc_start ignore us */
xdc_reset(xdcsc, 1, XD_RSET_NONE, errno, iorq->xd);
iorq->mode = oldmode;
xdcsc->ndone--;
}
/* check for read/write to a sector in bad144 table if bad: redirect
* request to bad144 area */
if ((comm == XDCMD_RD || comm == XDCMD_WR) &&
(iorq->mode & XD_MODE_B144) == 0) {
advance = iorq->sectcnt - iopb->sectcnt;
XDC_ADVANCE(iorq, advance);
if ((i = isbad(&iorq->xd->dkb, iorq->blockno / iorq->xd->sectpercyl,
(iorq->blockno / iorq->xd->nsect) % iorq->xd->nhead,
iorq->blockno % iorq->xd->nsect)) != -1) {
iorq->mode |= XD_MODE_B144; /* enter bad144 mode &
* redirect */
iopb->errno = iopb->done = iopb->errs = 0;
iopb->sectcnt = 1;
iopb->cylno = (iorq->xd->ncyl + iorq->xd->acyl) - 2;
/* second to last acyl */
i = iorq->xd->sectpercyl - 1 - i; /* follow bad144
* standard */
iopb->headno = i / iorq->xd->nhead;
iopb->sectno = i % iorq->xd->nhead;
XDC_HWAIT(xdcsc, rqno);
xdc_start(xdcsc, 1); /* resubmit */
return (XD_ERR_AOK); /* recovered! */
}
}
/*
* it isn't a bad144 sector, must be real error! see if we can retry
* it?
*/
if ((iorq->mode & XD_MODE_VERBO) && iorq->lasterror)
xdc_perror(iorq, iopb, 1); /* inform of error state
* change */
iorq->lasterror = errno;
if ((erract == XD_ERA_RSET || erract == XD_ERA_HARD)
&& iorq->tries < XDC_MAXTRIES) { /* retry? */
iorq->tries++;
iorq->errno = iopb->errno = iopb->done = iopb->errs = 0;
XDC_HWAIT(xdcsc, rqno);
xdc_start(xdcsc, 1); /* restart */
return (XD_ERR_AOK); /* recovered! */
}
/* failed to recover from this error */
return (XD_ERR_FAIL);
}
/*
* xdc_tick: make sure xd is still alive and ticking (err, kicking).
*/
void
xdc_tick(arg)
void *arg;
{
struct xdc_softc *xdcsc = arg;
int lcv, s, reset = 0;
#ifdef XDC_DIAG
int wait, run, free, done, whd;
u_char fqc[XDC_MAXIOPB], wqc[XDC_MAXIOPB], mark[XDC_MAXIOPB];
s = splbio();
wait = xdcsc->nwait;
run = xdcsc->nrun;
free = xdcsc->nfree;
done = xdcsc->ndone;
bcopy(xdcsc->waitq, wqc, sizeof(wqc));
bcopy(xdcsc->freereq, fqc, sizeof(fqc));
splx(s);
if (wait + run + free + done != XDC_MAXIOPB) {
printf("%s: diag: IOPB miscount (got w/f/r/d %d/%d/%d/%d, wanted %d)\n",
xdcsc->sc_dev.dv_xname, wait, free, run, done, XDC_MAXIOPB);
bzero(mark, sizeof(mark));
printf("FREE: ");
for (lcv = free; lcv > 0; lcv--) {
printf("%d ", fqc[lcv - 1]);
mark[fqc[lcv - 1]] = 1;
}
printf("\nWAIT: ");
lcv = wait;
while (lcv > 0) {
printf("%d ", wqc[whd]);
mark[wqc[whd]] = 1;
whd = (whd + 1) % XDC_MAXIOPB;
lcv--;
}
printf("\n");
for (lcv = 0; lcv < XDC_MAXIOPB; lcv++) {
if (mark[lcv] == 0)
printf("MARK: running %d: mode %d done %d errs %d errno 0x%x ttl %d buf %x\n",
lcv, xdcsc->reqs[lcv].mode,
xdcsc->iopbase[lcv].done,
xdcsc->iopbase[lcv].errs,
xdcsc->iopbase[lcv].errno,
xdcsc->reqs[lcv].ttl, xdcsc->reqs[lcv].buf);
}
} else
if (done > XDC_MAXIOPB - XDC_SUBWAITLIM)
printf("%s: diag: lots of done jobs (%d)\n",
xdcsc->sc_dev.dv_xname, done);
#endif
#ifdef XDC_DEBUG
printf("%s: tick: csr 0x%x, w/f/r/d %d/%d/%d/%d\n",
xdcsc->sc_dev.dv_xname,
xdcsc->xdc->xdc_csr, xdcsc->nwait, xdcsc->nfree, xdcsc->nrun,
xdcsc->ndone);
for (lcv = 0; lcv < XDC_MAXIOPB; lcv++) {
if (xdcsc->reqs[lcv].mode)
printf("running %d: mode %d done %d errs %d errno 0x%x\n",
lcv,
xdcsc->reqs[lcv].mode, xdcsc->iopbase[lcv].done,
xdcsc->iopbase[lcv].errs, xdcsc->iopbase[lcv].errno);
}
#endif
/* reduce ttl for each request if one goes to zero, reset xdc */
s = splbio();
for (lcv = 0; lcv < XDC_MAXIOPB; lcv++) {
if (xdcsc->reqs[lcv].mode == 0 ||
XD_STATE(xdcsc->reqs[lcv].mode) == XD_SUB_DONE)
continue;
xdcsc->reqs[lcv].ttl--;
if (xdcsc->reqs[lcv].ttl == 0)
reset = 1;
}
if (reset) {
printf("%s: watchdog timeout\n", xdcsc->sc_dev.dv_xname);
xdc_reset(xdcsc, 0, XD_RSET_NONE, XD_ERR_FAIL, NULL);
}
splx(s);
/* until next time */
timeout(xdc_tick, xdcsc, XDC_TICKCNT);
}
/*
* xdc_ioctlcmd: this function provides a user level interface to the
* controller via ioctl. this allows "format" programs to be written
* in user code, and is also useful for some debugging. we return
* an error code. called at user priority.
*/
int
xdc_ioctlcmd(xd, dev, xio)
struct xd_softc *xd;
dev_t dev;
struct xd_iocmd *xio;
{
int s, err, rqno, dummy;
caddr_t dvmabuf = NULL;
struct xdc_softc *xdcsc;
/* check sanity of requested command */
switch (xio->cmd) {
case XDCMD_NOP: /* no op: everything should be zero */
if (xio->subfn || xio->dptr || xio->dlen ||
xio->block || xio->sectcnt)
return (EINVAL);
break;
case XDCMD_RD: /* read / write sectors (up to XD_IOCMD_MAXS) */
case XDCMD_WR:
if (xio->subfn || xio->sectcnt > XD_IOCMD_MAXS ||
xio->sectcnt * XDFM_BPS != xio->dlen || xio->dptr == NULL)
return (EINVAL);
break;
case XDCMD_SK: /* seek: doesn't seem useful to export this */
return (EINVAL);
case XDCMD_WRP: /* write parameters */
return (EINVAL);/* not useful, except maybe drive
* parameters... but drive parameters should
* go via disklabel changes */
case XDCMD_RDP: /* read parameters */
if (xio->subfn != XDFUN_DRV ||
xio->dlen || xio->block || xio->dptr)
return (EINVAL); /* allow read drive params to
* get hw_spt */
xio->sectcnt = xd->hw_spt; /* we already know the answer */
return (0);
break;
case XDCMD_XRD: /* extended read/write */
case XDCMD_XWR:
switch (xio->subfn) {
case XDFUN_THD:/* track headers */
if (xio->sectcnt != xd->hw_spt ||
(xio->block % xd->nsect) != 0 ||
xio->dlen != XD_IOCMD_HSZ * xd->hw_spt ||
xio->dptr == NULL)
return (EINVAL);
xio->sectcnt = 0;
break;
case XDFUN_FMT:/* NOTE: also XDFUN_VFY */
if (xio->cmd == XDCMD_XRD)
return (EINVAL); /* no XDFUN_VFY */
if (xio->sectcnt || xio->dlen ||
(xio->block % xd->nsect) != 0 || xio->dptr)
return (EINVAL);
break;
case XDFUN_HDR:/* header, header verify, data, data ECC */
return (EINVAL); /* not yet */
case XDFUN_DM: /* defect map */
case XDFUN_DMX:/* defect map (alternate location) */
if (xio->sectcnt || xio->dlen != XD_IOCMD_DMSZ ||
(xio->block % xd->nsect) != 0 || xio->dptr == NULL)
return (EINVAL);
break;
default:
return (EINVAL);
}
break;
case XDCMD_TST: /* diagnostics */
return (EINVAL);
default:
return (EINVAL);/* ??? */
}
/* create DVMA buffer for request if needed */
if (xio->dlen) {
dvmabuf = dvma_malloc(xio->dlen);
if (xio->cmd == XDCMD_WR || xio->cmd == XDCMD_XWR) {
if (err = copyin(xio->dptr, dvmabuf, xio->dlen)) {
dvma_free(dvmabuf, xio->dlen);
return (err);
}
}
}
/* do it! */
err = 0;
xdcsc = xd->parent;
s = splbio();
rqno = xdc_cmd(xdcsc, xio->cmd, xio->subfn, xd->xd_drive, xio->block,
xio->sectcnt, dvmabuf, XD_SUB_WAIT);
if (rqno == XD_ERR_FAIL) {
err = EIO;
goto done;
}
xio->errno = xdcsc->reqs[rqno].errno;
xio->tries = xdcsc->reqs[rqno].tries;
XDC_DONE(xdcsc, rqno, dummy);
if (xio->cmd == XDCMD_RD || xio->cmd == XDCMD_XRD)
err = copyout(dvmabuf, xio->dptr, xio->dlen);
done:
splx(s);
if (dvmabuf)
dvma_free(dvmabuf, xio->dlen);
return (err);
}
/*
* xdc_e2str: convert error code number into an error string
*/
char *
xdc_e2str(no)
int no;
{
switch (no) {
case XD_ERR_FAIL:
return ("Software fatal error");
case XD_ERR_AOK:
return ("Successful completion");
case XD_ERR_ICYL:
return ("Illegal cylinder address");
case XD_ERR_IHD:
return ("Illegal head address");
case XD_ERR_ISEC:
return ("Illgal sector address");
case XD_ERR_CZER:
return ("Count zero");
case XD_ERR_UIMP:
return ("Unimplemented command");
case XD_ERR_IF1:
return ("Illegal field length 1");
case XD_ERR_IF2:
return ("Illegal field length 2");
case XD_ERR_IF3:
return ("Illegal field length 3");
case XD_ERR_IF4:
return ("Illegal field length 4");
case XD_ERR_IF5:
return ("Illegal field length 5");
case XD_ERR_IF6:
return ("Illegal field length 6");
case XD_ERR_IF7:
return ("Illegal field length 7");
case XD_ERR_ISG:
return ("Illegal scatter/gather length");
case XD_ERR_ISPT:
return ("Not enough sectors per track");
case XD_ERR_ALGN:
return ("Next IOPB address alignment error");
case XD_ERR_SGAL:
return ("Scatter/gather address alignment error");
case XD_ERR_SGEC:
return ("Scatter/gather with auto-ECC");
case XD_ERR_SECC:
return ("Soft ECC corrected");
case XD_ERR_SIGN:
return ("ECC ignored");
case XD_ERR_ASEK:
return ("Auto-seek retry recovered");
case XD_ERR_RTRY:
return ("Soft retry recovered");
case XD_ERR_HECC:
return ("Hard data ECC");
case XD_ERR_NHDR:
return ("Header not found");
case XD_ERR_NRDY:
return ("Drive not ready");
case XD_ERR_TOUT:
return ("Operation timeout");
case XD_ERR_VTIM:
return ("VMEDMA timeout");
case XD_ERR_DSEQ:
return ("Disk sequencer error");
case XD_ERR_HDEC:
return ("Header ECC error");
case XD_ERR_RVFY:
return ("Read verify");
case XD_ERR_VFER:
return ("Fatail VMEDMA error");
case XD_ERR_VBUS:
return ("VMEbus error");
case XD_ERR_DFLT:
return ("Drive faulted");
case XD_ERR_HECY:
return ("Header error/cyliner");
case XD_ERR_HEHD:
return ("Header error/head");
case XD_ERR_NOCY:
return ("Drive not on-cylinder");
case XD_ERR_SEEK:
return ("Seek error");
case XD_ERR_ILSS:
return ("Illegal sector size");
case XD_ERR_SEC:
return ("Soft ECC");
case XD_ERR_WPER:
return ("Write-protect error");
case XD_ERR_IRAM:
return ("IRAM self test failure");
case XD_ERR_MT3:
return ("Maintenance test 3 failure (DSKCEL RAM)");
case XD_ERR_MT4:
return ("Maintenance test 4 failure (header shift reg)");
case XD_ERR_MT5:
return ("Maintenance test 5 failure (VMEDMA regs)");
case XD_ERR_MT6:
return ("Maintenance test 6 failure (REGCEL chip)");
case XD_ERR_MT7:
return ("Maintenance test 7 failure (buffer parity)");
case XD_ERR_MT8:
return ("Maintenance test 8 failure (disk FIFO)");
case XD_ERR_IOCK:
return ("IOPB checksum miscompare");
case XD_ERR_IODM:
return ("IOPB DMA fatal");
case XD_ERR_IOAL:
return ("IOPB address alignment error");
case XD_ERR_FIRM:
return ("Firmware error");
case XD_ERR_MMOD:
return ("Illegal maintenance mode test number");
case XD_ERR_ACFL:
return ("ACFAIL asserted");
default:
return ("Unknown error");
}
}