dev/vme/xy.c

1.2  pk /*	$NetBSD: xy.c,v 1.2 1997/12/01 23:25:38 pk Exp $	*/
1.1  pk
1.1  pk /*
1.1  pk  *
1.1  pk  * Copyright (c) 1995 Charles D. Cranor
1.1  pk  * All rights reserved.
1.1  pk  *
1.1  pk  * Redistribution and use in source and binary forms, with or without
1.1  pk  * modification, are permitted provided that the following conditions
1.1  pk  * are met:
1.1  pk  * 1. Redistributions of source code must retain the above copyright
1.1  pk  *    notice, this list of conditions and the following disclaimer.
1.1  pk  * 2. Redistributions in binary form must reproduce the above copyright
1.1  pk  *    notice, this list of conditions and the following disclaimer in the
1.1  pk  *    documentation and/or other materials provided with the distribution.
1.1  pk  * 3. All advertising materials mentioning features or use of this software
1.1  pk  *    must display the following acknowledgement:
1.1  pk  *      This product includes software developed by Charles D. Cranor.
1.1  pk  * 4. The name of the author may not be used to endorse or promote products
1.1  pk  *    derived from this software without specific prior written permission.
1.1  pk  *
1.1  pk  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.1  pk  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.1  pk  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.1  pk  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.1  pk  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.1  pk  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.1  pk  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.1  pk  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.1  pk  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.1  pk  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  *
1.1  pk  * x y . c   x y l o g i c s   4 5 0 / 4 5 1   s m d   d r i v e r
1.1  pk  *
1.1  pk  * author: Chuck Cranor <chuck (at) ccrc.wustl.edu>
1.2  pk  * id: $NetBSD: xy.c,v 1.2 1997/12/01 23:25:38 pk Exp $
1.1  pk  * started: 14-Sep-95
1.1  pk  * references: [1] Xylogics Model 753 User's Manual
1.1  pk  *                 part number: 166-753-001, Revision B, May 21, 1988.
1.1  pk  *                 "Your Partner For Performance"
1.1  pk  *             [2] other NetBSD disk device drivers
1.1  pk  *	       [3] Xylogics Model 450 User's Manual
1.1  pk  *		   part number: 166-017-001, Revision B, 1983.
1.1  pk  *	       [4] Addendum to Xylogics Model 450 Disk Controller User's
1.1  pk  *			Manual, Jan. 1985.
1.1  pk  *	       [5] The 451 Controller, Rev. B3, September 2, 1986.
1.1  pk  *	       [6] David Jones <dej (at) achilles.net>'s unfinished 450/451 driver
1.1  pk  *
1.1  pk  */
1.1  pk
1.1  pk #undef XYC_DEBUG		/* full debug */
1.1  pk #undef XYC_DIAG			/* extra sanity checks */
1.1  pk #if defined(DIAGNOSTIC) && !defined(XYC_DIAG)
1.1  pk #define XYC_DIAG		/* link in with master DIAG option */
1.1  pk #endif
1.1  pk
1.1  pk #include <sys/param.h>
1.1  pk #include <sys/proc.h>
1.1  pk #include <sys/systm.h>
1.1  pk #include <sys/kernel.h>
1.1  pk #include <sys/file.h>
1.1  pk #include <sys/stat.h>
1.1  pk #include <sys/ioctl.h>
1.1  pk #include <sys/buf.h>
1.1  pk #include <sys/uio.h>
1.1  pk #include <sys/malloc.h>
1.1  pk #include <sys/device.h>
1.1  pk #include <sys/disklabel.h>
1.1  pk #include <sys/disk.h>
1.1  pk #include <sys/syslog.h>
1.1  pk #include <sys/dkbad.h>
1.1  pk #include <sys/conf.h>
1.1  pk
1.1  pk #include <vm/vm.h>
1.1  pk #include <vm/vm_kern.h>
1.1  pk
1.1  pk #include <machine/bus.h>
1.1  pk #include <machine/autoconf.h>
1.1  pk #include <machine/sun_disklabel.h>
1.1  pk #include <machine/conf.h>
1.1  pk
1.1  pk #include <dev/vme/vmevar.h>
1.1  pk #include <dev/vme/xyreg.h>
1.1  pk #include <dev/vme/xyvar.h>
1.1  pk #include <dev/vme/xio.h>
1.1  pk
1.1  pk #include "locators.h"
1.1  pk
1.1  pk /*
1.1  pk  * macros
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * XYC_GO: start iopb ADDR (DVMA addr in a u_long) on XYC
1.1  pk  */
1.1  pk #define XYC_GO(XYC, ADDR) { \
1.1  pk 	(XYC)->xyc_addr_lo = ((ADDR) & 0xff); \
1.1  pk 	(ADDR) = ((ADDR) >> 8); \
1.1  pk 	(XYC)->xyc_addr_hi = ((ADDR) & 0xff); \
1.1  pk 	(ADDR) = ((ADDR) >> 8); \
1.1  pk 	(XYC)->xyc_reloc_lo = ((ADDR) & 0xff); \
1.1  pk 	(ADDR) = ((ADDR) >> 8); \
1.1  pk 	(XYC)->xyc_reloc_hi = (ADDR); \
1.1  pk 	(XYC)->xyc_csr = XYC_GBSY; /* go! */ \
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * XYC_DONE: don't need IORQ, get error code and free (done after xyc_cmd)
1.1  pk  */
1.1  pk
1.1  pk #define XYC_DONE(SC,ER) { \
1.1  pk 	if ((ER) == XY_ERR_AOK) { \
1.1  pk 		(ER) = (SC)->ciorq->errno; \
1.1  pk 		(SC)->ciorq->mode = XY_SUB_FREE; \
1.1  pk 		wakeup((SC)->ciorq); \
1.1  pk 	} \
1.1  pk 	}
1.1  pk
1.1  pk /*
1.1  pk  * XYC_ADVANCE: advance iorq's pointers by a number of sectors
1.1  pk  */
1.1  pk
1.1  pk #define XYC_ADVANCE(IORQ, N) { \
1.1  pk 	if (N) { \
1.1  pk 		(IORQ)->sectcnt -= (N); \
1.1  pk 		(IORQ)->blockno += (N); \
1.1  pk 		(IORQ)->dbuf += ((N)*XYFM_BPS); \
1.1  pk 	} \
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * note - addresses you can sleep on:
1.1  pk  *   [1] & of xy_softc's "state" (waiting for a chance to attach a drive)
1.1  pk  *   [2] & an iorq (waiting for an XY_SUB_WAIT iorq to finish)
1.1  pk  */
1.1  pk
1.1  pk
1.1  pk /*
1.1  pk  * function prototypes
1.1  pk  * "xyc_*" functions are internal, all others are external interfaces
1.1  pk  */
1.1  pk
1.1  pk extern int pil_to_vme[];	/* from obio.c */
1.1  pk
1.1  pk /* internals */
1.1  pk struct xy_iopb *xyc_chain __P((struct xyc_softc *, struct xy_iorq *));
1.1  pk int	xyc_cmd __P((struct xyc_softc *, int, int, int, int, int, char *, int));
1.1  pk char   *xyc_e2str __P((int));
1.1  pk int	xyc_entoact __P((int));
1.1  pk int	xyc_error __P((struct xyc_softc *, struct xy_iorq *,
1.1  pk 		   struct xy_iopb *, int));
1.1  pk int	xyc_ioctlcmd __P((struct xy_softc *, dev_t dev, struct xd_iocmd *));
1.1  pk void	xyc_perror __P((struct xy_iorq *, struct xy_iopb *, int));
1.1  pk int	xyc_piodriver __P((struct xyc_softc *, struct xy_iorq *));
1.1  pk int	xyc_remove_iorq __P((struct xyc_softc *));
1.1  pk int	xyc_reset __P((struct xyc_softc *, int, struct xy_iorq *, int,
1.1  pk 			struct xy_softc *));
1.1  pk inline void xyc_rqinit __P((struct xy_iorq *, struct xyc_softc *,
1.1  pk 			    struct xy_softc *, int, u_long, int,
1.1  pk 			    caddr_t, struct buf *));
1.1  pk void	xyc_rqtopb __P((struct xy_iorq *, struct xy_iopb *, int, int));
1.1  pk void	xyc_start __P((struct xyc_softc *, struct xy_iorq *));
1.1  pk int	xyc_startbuf __P((struct xyc_softc *, struct xy_softc *, struct buf *));
1.1  pk int	xyc_submit_iorq __P((struct xyc_softc *, struct xy_iorq *, int));
1.1  pk void	xyc_tick __P((void *));
1.1  pk int	xyc_unbusy __P((struct xyc *, int));
1.1  pk void	xyc_xyreset __P((struct xyc_softc *, struct xy_softc *));
1.1  pk
1.1  pk /* machine interrupt hook */
1.1  pk int	xycintr __P((void *));
1.1  pk
1.1  pk /* autoconf */
1.1  pk int	xycmatch __P((struct device *, struct cfdata *, void *));
1.1  pk void	xycattach __P((struct device *, struct device *, void *));
1.1  pk int	xymatch __P((struct device *, struct cfdata *, void *));
1.1  pk void	xyattach __P((struct device *, struct device *, void *));
1.1  pk
1.1  pk static	void xydummystrat __P((struct buf *));
1.1  pk int	xygetdisklabel __P((struct xy_softc *, void *));
1.1  pk
1.1  pk /*
1.1  pk  * cfdrivers: device driver interface to autoconfig
1.1  pk  */
1.1  pk
1.1  pk struct cfattach xyc_ca = {
1.1  pk 	sizeof(struct xyc_softc), xycmatch, xycattach
1.1  pk };
1.1  pk
1.1  pk struct cfdriver xyc_cd = {
1.1  pk 	NULL, "xyc", DV_DULL
1.1  pk };
1.1  pk
1.1  pk struct cfattach xy_ca = {
1.1  pk 	sizeof(struct xy_softc), xymatch, xyattach
1.1  pk };
1.1  pk
1.1  pk struct cfdriver xy_cd = {
1.1  pk 	NULL, "xy", DV_DISK
1.1  pk };
1.1  pk
1.1  pk struct xyc_attach_args {	/* this is the "aux" args to xyattach */
1.1  pk 	int	driveno;	/* unit number */
1.1  pk 	int	fullmode;	/* submit mode */
1.1  pk 	int	booting;	/* are we booting or not? */
1.1  pk };
1.1  pk
1.1  pk /*
1.1  pk  * dkdriver
1.1  pk  */
1.1  pk
1.1  pk struct dkdriver xydkdriver = { xystrategy };
1.1  pk
1.1  pk /*
1.1  pk  * start: disk label fix code (XXX)
1.1  pk  */
1.1  pk
1.1  pk static void *xy_labeldata;
1.1  pk
1.1  pk static void
1.1  pk xydummystrat(bp)
1.1  pk 	struct buf *bp;
1.1  pk {
1.1  pk 	if (bp->b_bcount != XYFM_BPS)
1.1  pk 		panic("xydummystrat");
1.1  pk 	bcopy(xy_labeldata, bp->b_un.b_addr, XYFM_BPS);
1.1  pk 	bp->b_flags |= B_DONE;
1.1  pk 	bp->b_flags &= ~B_BUSY;
1.1  pk }
1.1  pk
1.1  pk int
1.1  pk xygetdisklabel(xy, b)
1.1  pk 	struct xy_softc *xy;
1.1  pk 	void *b;
1.1  pk {
1.1  pk 	char *err;
1.1  pk 	struct sun_disklabel *sdl;
1.1  pk
1.1  pk 	/* We already have the label data in `b'; setup for dummy strategy */
1.1  pk 	xy_labeldata = b;
1.1  pk
1.1  pk 	/* Required parameter for readdisklabel() */
1.1  pk 	xy->sc_dk.dk_label->d_secsize = XYFM_BPS;
1.1  pk
1.1  pk 	err = readdisklabel(MAKEDISKDEV(0, xy->sc_dev.dv_unit, RAW_PART),
1.1  pk 					xydummystrat,
1.1  pk 				xy->sc_dk.dk_label, xy->sc_dk.dk_cpulabel);
1.1  pk 	if (err) {
1.1  pk 		printf("%s: %s\n", xy->sc_dev.dv_xname, err);
1.1  pk 		return(XY_ERR_FAIL);
1.1  pk 	}
1.1  pk
1.1  pk 	/* Ok, we have the label; fill in `pcyl' if there's SunOS magic */
1.1  pk 	sdl = (struct sun_disklabel *)xy->sc_dk.dk_cpulabel->cd_block;
1.1  pk 	if (sdl->sl_magic == SUN_DKMAGIC)
1.1  pk 		xy->pcyl = sdl->sl_pcylinders;
1.1  pk 	else {
1.1  pk 		printf("%s: WARNING: no `pcyl' in disk label.\n",
1.1  pk 			xy->sc_dev.dv_xname);
1.1  pk 		xy->pcyl = xy->sc_dk.dk_label->d_ncylinders +
1.1  pk 			xy->sc_dk.dk_label->d_acylinders;
1.1  pk 		printf("%s: WARNING: guessing pcyl=%d (ncyl+acyl)\n",
1.1  pk 		xy->sc_dev.dv_xname, xy->pcyl);
1.1  pk 	}
1.1  pk
1.1  pk 	xy->ncyl = xy->sc_dk.dk_label->d_ncylinders;
1.1  pk 	xy->acyl = xy->sc_dk.dk_label->d_acylinders;
1.1  pk 	xy->nhead = xy->sc_dk.dk_label->d_ntracks;
1.1  pk 	xy->nsect = xy->sc_dk.dk_label->d_nsectors;
1.1  pk 	xy->sectpercyl = xy->nhead * xy->nsect;
1.1  pk 	xy->sc_dk.dk_label->d_secsize = XYFM_BPS; /* not handled by
1.1  pk                                           	  * sun->bsd */
1.1  pk 	return(XY_ERR_AOK);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * end: disk label fix code (XXX)
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * a u t o c o n f i g   f u n c t i o n s
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * xycmatch: determine if xyc is present or not.   we do a
1.1  pk  * soft reset to detect the xyc.
1.1  pk  */
1.1  pk
1.1  pk int xycmatch(parent, cf, aux)
1.1  pk 	struct device *parent;
1.1  pk 	struct cfdata *cf;
1.1  pk 	void *aux;
1.1  pk {
1.1  pk 	struct vme_attach_args	*va = aux;
1.1  pk 	vme_chipset_tag_t	ct = va->vma_chipset_tag;
1.1  pk 	bus_space_tag_t		bt = va->vma_bustag;
1.1  pk 	struct xyc		*xyc;
1.1  pk 	vme_mod_t		mod;
1.1  pk
1.1  pk 	mod = VMEMOD_A16 | VMEMOD_S | VMEMOD_D;
1.1  pk
1.1  pk 	xyc = (struct xyc *) va->vma_reg[0];
1.1  pk 	if (vme_bus_probe(ct, bt, (vme_addr_t)&xyc->xyc_rsetup, 1, mod)) {
1.1  pk 		if (xyc_unbusy(xyc, XYC_RESETUSEC) == XY_ERR_FAIL)
1.1  pk 			return(0);
1.1  pk 		return (1);
1.1  pk 	}
1.1  pk 	return (0);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xycattach: attach controller
1.1  pk  */
1.1  pk void
1.1  pk xycattach(parent, self, aux)
1.1  pk 	struct device *parent, *self;
1.1  pk 	void   *aux;
1.1  pk
1.1  pk {
1.1  pk 	struct vme_attach_args	*va = aux;
1.1  pk 	vme_chipset_tag_t	ct = va->vma_chipset_tag;
1.1  pk 	bus_space_tag_t		bt = va->vma_bustag;
1.1  pk 	bus_space_handle_t	bh;
1.1  pk 	vme_intr_handle_t	ih;
1.1  pk 	vme_mod_t		mod;
1.1  pk 	struct xyc_softc	*xyc = (void *) self;
1.1  pk 	struct xyc_attach_args	xa;
1.2  pk 	int			lcv, res, pbsz, error;
1.2  pk 	bus_dma_segment_t	seg;
1.2  pk 	int			rseg;
1.1  pk
1.1  pk 	/* get addressing and intr level stuff from autoconfig and load it
1.1  pk 	 * into our xyc_softc. */
1.1  pk
1.1  pk 	mod = VMEMOD_A16 | VMEMOD_S | VMEMOD_D;
1.1  pk
1.1  pk 	if (vme_bus_map(ct, va->vma_reg[0], sizeof(struct xyc),
1.1  pk 			mod, bt, &bh) != 0)
1.1  pk 		panic("xyc: vme_map");
1.1  pk
1.1  pk 	xyc->xyc = (struct xyc *) bh;
1.1  pk 	xyc->ipl = va->vma_pri;
1.1  pk 	xyc->vector = va->vma_vec;
1.1  pk 	printf(" pri %d", va->vma_pri);
1.1  pk 	xyc->no_ols = 0; /* XXX should be from config */
1.1  pk
1.1  pk 	for (lcv = 0; lcv < XYC_MAXDEV; lcv++)
1.1  pk 		xyc->sc_drives[lcv] = (struct xy_softc *) 0;
1.1  pk
1.1  pk 	/*
1.1  pk 	 * allocate and zero buffers
1.1  pk 	 * check boundaries of the KVA's ... all IOPBs must reside in
1.1  pk  	 * the same 64K region.
1.1  pk 	 */
1.1  pk
1.1  pk 	pbsz = XYC_MAXIOPB * sizeof(struct xy_iopb);
1.2  pk
1.2  pk 	error = bus_dmamem_alloc(
1.2  pk 			xyc->dmatag,
1.2  pk 			pbsz,		/* size */
1.2  pk 			64*1024,	/* boundary */
1.2  pk 			0,		/* alignment */
1.2  pk 			&seg,
1.2  pk 			1,		/* # of segments */
1.2  pk 			&rseg,		/* actual # of segments */
1.2  pk 			BUS_DMA_NOWAIT);
1.2  pk 	if (error) {
1.2  pk 		printf("%s: DMA buffer map error %d\n",
1.2  pk 			xyc->sc_dev.dv_xname, error);
1.2  pk 		return;
1.2  pk 	}
1.2  pk 	xyc->dvmaiopb = (struct xy_iopb *)seg.ds_addr;
1.2  pk
1.2  pk 	error = bus_dmamem_map(
1.2  pk 			xyc->dmatag,
1.2  pk 			&seg,
1.2  pk 			rseg,
1.2  pk 			XYC_MAXIOPB * sizeof(struct xy_iopb),
1.2  pk 			(caddr_t *)&xyc->iopbase,
1.2  pk 			BUS_DMA_NOWAIT|BUS_DMAMEM_NOSYNC);
1.2  pk 	if (error) {
1.2  pk 		bus_dmamem_free(xyc->dmatag, &seg, rseg);
1.2  pk 		printf("%s: DMA buffer map error %d\n",
1.2  pk 			xyc->sc_dev.dv_xname, error);
1.2  pk 		return;
1.1  pk 	}
1.2  pk 	bzero(xyc->iopbase, pbsz);
1.2  pk
1.1  pk 	xyc->reqs = (struct xy_iorq *)
1.1  pk 	    malloc(XYC_MAXIOPB * sizeof(struct xy_iorq), M_DEVBUF, M_NOWAIT);
1.1  pk 	if (xyc->reqs == NULL)
1.1  pk 		panic("xyc malloc");
1.1  pk 	bzero(xyc->reqs, XYC_MAXIOPB * sizeof(struct xy_iorq));
1.1  pk
1.1  pk 	/*
1.1  pk 	 * init iorq to iopb pointers, and non-zero fields in the
1.1  pk 	 * iopb which never change.
1.1  pk 	 */
1.1  pk
1.1  pk 	for (lcv = 0; lcv < XYC_MAXIOPB; lcv++) {
1.1  pk 		xyc->xy_chain[lcv] = NULL;
1.1  pk 		xyc->reqs[lcv].iopb = &xyc->iopbase[lcv];
1.1  pk 		xyc->iopbase[lcv].asr = 1;	/* always the same */
1.1  pk 		xyc->iopbase[lcv].eef = 1;	/* always the same */
1.1  pk 		xyc->iopbase[lcv].ecm = XY_ECM;	/* always the same */
1.1  pk 		xyc->iopbase[lcv].aud = 1;	/* always the same */
1.1  pk 		xyc->iopbase[lcv].relo = 1;	/* always the same */
1.1  pk 		xyc->iopbase[lcv].thro = XY_THRO;/* always the same */
1.2  pk
1.2  pk 		error = bus_dmamap_create(
1.2  pk 				xyc->dmatag,
1.2  pk 				MAXPHYS,	/* size */
1.2  pk 				1,		/* nsegments */
1.2  pk 				MAXPHYS,	/* maxsegsz */
1.2  pk 				0,		/* boundary */
1.2  pk 				BUS_DMA_NOWAIT,
1.2  pk 				&xyc->reqs[lcv].dmamap);
1.2  pk 		if (error) {
1.2  pk 			printf("%s: DMA buffer map create error %d\n",
1.2  pk 				xyc->sc_dev.dv_xname, error);
1.2  pk 			return;
1.2  pk 		}
1.1  pk 	}
1.1  pk 	xyc->ciorq = &xyc->reqs[XYC_CTLIOPB];    /* short hand name */
1.1  pk 	xyc->ciopb = &xyc->iopbase[XYC_CTLIOPB]; /* short hand name */
1.1  pk 	xyc->xy_hand = 0;
1.1  pk
1.1  pk 	/* read controller parameters and insure we have a 450/451 */
1.1  pk
1.2  pk 	error = xyc_cmd(xyc, XYCMD_ST, 0, 0, 0, 0, 0, XY_SUB_POLL);
1.1  pk 	res = xyc->ciopb->ctyp;
1.2  pk 	XYC_DONE(xyc, error);
1.1  pk 	if (res != XYCT_450) {
1.2  pk 		if (error)
1.2  pk 			printf(": %s: ", xyc_e2str(error));
1.1  pk 		printf(": doesn't identify as a 450/451\n");
1.1  pk 		return;
1.1  pk 	}
1.1  pk 	printf(": Xylogics 450/451");
1.1  pk 	if (xyc->no_ols)
1.1  pk 		printf(" [OLS disabled]"); /* 450 doesn't overlap seek right */
1.1  pk 	printf("\n");
1.2  pk 	if (error) {
1.1  pk 		printf("%s: error: %s\n", xyc->sc_dev.dv_xname,
1.2  pk 				xyc_e2str(error));
1.1  pk 		return;
1.1  pk 	}
1.1  pk 	if ((xyc->xyc->xyc_csr & XYC_ADRM) == 0) {
1.1  pk 		printf("%s: 24 bit addressing turned off\n",
1.1  pk 			xyc->sc_dev.dv_xname);
1.1  pk 		printf("please set hardware jumpers JM1-JM2=in, JM3-JM4=out\n");
1.1  pk 		printf("to enable 24 bit mode and this driver\n");
1.1  pk 		return;
1.1  pk 	}
1.1  pk
1.1  pk 	/* link in interrupt with higher level software */
1.1  pk 	vme_intr_map(ct, va->vma_vec, va->vma_pri, &ih);
1.1  pk 	vme_intr_establish(ct, ih, xycintr, xyc);
1.1  pk 	evcnt_attach(&xyc->sc_dev, "intr", &xyc->sc_intrcnt);
1.1  pk
1.1  pk
1.1  pk 	/* now we must look for disks using autoconfig */
1.1  pk 	xa.fullmode = XY_SUB_POLL;
1.1  pk 	xa.booting = 1;
1.1  pk
1.1  pk #if 0	/* XXX - deal with this disksubr */
1.1  pk 	if (ca->ca_ra.ra_bp && ca->ca_ra.ra_bp->val[0] == -1 &&
1.1  pk 	    ca->ca_ra.ra_bp->val[1] == xyc->sc_dev.dv_unit) {
1.1  pk 		bootpath_store(1, ca->ca_ra.ra_bp + 1); /* advance bootpath */
1.1  pk 	}
1.1  pk #endif
1.1  pk
1.1  pk 	for (xa.driveno = 0; xa.driveno < XYC_MAXDEV; xa.driveno++)
1.1  pk 		(void) config_found(self, (void *) &xa, NULL);
1.1  pk
1.1  pk #if 0
1.1  pk 	bootpath_store(1, NULL);
1.1  pk #endif
1.1  pk
1.1  pk 	/* start the watchdog clock */
1.1  pk 	timeout(xyc_tick, xyc, XYC_TICKCNT);
1.1  pk
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xymatch: probe for disk.
1.1  pk  *
1.1  pk  * note: we almost always say disk is present.   this allows us to
1.1  pk  * spin up and configure a disk after the system is booted (we can
1.1  pk  * call xyattach!).
1.1  pk  */
1.1  pk int
1.1  pk xymatch(parent, cf, aux)
1.1  pk 	struct device *parent;
1.1  pk 	struct cfdata *cf;
1.1  pk 	void *aux;
1.1  pk {
1.1  pk 	struct xyc_attach_args *xa = aux;
1.1  pk
1.1  pk 	/* looking for autoconf wildcard or exact match */
1.1  pk
1.1  pk 	if (cf->cf_loc[XYCCF_DRIVE] != XYCCF_DRIVE_DEFAULT &&
1.1  pk 	    cf->cf_loc[XYCCF_DRIVE] != xa->driveno)
1.1  pk 		return 0;
1.1  pk
1.1  pk 	return 1;
1.1  pk
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyattach: attach a disk.   this can be called from autoconf and also
1.1  pk  * from xyopen/xystrategy.
1.1  pk  */
1.1  pk void
1.1  pk xyattach(parent, self, aux)
1.1  pk 	struct device *parent, *self;
1.1  pk 	void   *aux;
1.1  pk
1.1  pk {
1.1  pk 	struct xy_softc *xy = (void *) self, *oxy;
1.1  pk 	struct xyc_softc *xyc = (void *) parent;
1.1  pk 	struct xyc_attach_args *xa = aux;
1.2  pk 	int     spt, mb, blk, lcv, fmode, s = 0, newstate;
1.1  pk 	struct dkbad *dkb;
1.1  pk 	struct bootpath *bp;
1.2  pk 	int			rseg, error;
1.2  pk 	bus_dma_segment_t	seg;
1.2  pk 	caddr_t			dmaddr;
1.2  pk 	caddr_t			buf;
1.1  pk
1.1  pk 	/*
1.1  pk 	 * Always re-initialize the disk structure.  We want statistics
1.1  pk 	 * to start with a clean slate.
1.1  pk 	 */
1.1  pk 	bzero(&xy->sc_dk, sizeof(xy->sc_dk));
1.1  pk 	xy->sc_dk.dk_driver = &xydkdriver;
1.1  pk 	xy->sc_dk.dk_name = xy->sc_dev.dv_xname;
1.1  pk
1.1  pk 	/* if booting, init the xy_softc */
1.1  pk
1.1  pk 	if (xa->booting) {
1.1  pk 		xy->state = XY_DRIVE_UNKNOWN;	/* to start */
1.1  pk 		xy->flags = 0;
1.1  pk 		xy->parent = xyc;
1.1  pk
1.1  pk 		/* init queue of waiting bufs */
1.1  pk
1.1  pk 		xy->xyq.b_active = 0;
1.1  pk 		xy->xyq.b_actf = 0;
1.1  pk 		xy->xyq.b_actb = &xy->xyq.b_actf; /* XXX b_actb: not used? */
1.1  pk
1.1  pk 		xy->xyrq = &xyc->reqs[xa->driveno];
1.1  pk
1.1  pk 	}
1.1  pk 	xy->xy_drive = xa->driveno;
1.1  pk 	fmode = xa->fullmode;
1.1  pk 	xyc->sc_drives[xa->driveno] = xy;
1.1  pk
1.1  pk 	/* if not booting, make sure we are the only process in the attach for
1.1  pk 	 * this drive.   if locked out, sleep on it. */
1.1  pk
1.1  pk 	if (!xa->booting) {
1.1  pk 		s = splbio();
1.1  pk 		while (xy->state == XY_DRIVE_ATTACHING) {
1.1  pk 			if (tsleep(&xy->state, PRIBIO, "xyattach", 0)) {
1.1  pk 				splx(s);
1.1  pk 				return;
1.1  pk 			}
1.1  pk 		}
1.1  pk 		printf("%s at %s",
1.1  pk 			xy->sc_dev.dv_xname, xy->parent->sc_dev.dv_xname);
1.1  pk 	}
1.2  pk
1.1  pk 	/* we now have control */
1.1  pk 	xy->state = XY_DRIVE_ATTACHING;
1.1  pk 	newstate = XY_DRIVE_UNKNOWN;
1.1  pk
1.2  pk 	buf = NULL;
1.2  pk 	error = bus_dmamem_alloc(xyc->dmatag, XYFM_BPS, NBPG, 0,
1.2  pk 				 &seg, 1, &rseg, BUS_DMA_NOWAIT);
1.2  pk 	if (error) {
1.2  pk 		printf("%s: DMA buffer alloc error %d\n",
1.2  pk 			xy->sc_dev.dv_xname, error);
1.2  pk 		goto done;
1.2  pk 	}
1.2  pk 	dmaddr = (caddr_t)seg.ds_addr;
1.2  pk
1.2  pk 	error = bus_dmamem_map(xyc->dmatag, &seg, rseg, XYFM_BPS,
1.2  pk 				&buf,
1.2  pk 				BUS_DMA_NOWAIT|BUS_DMAMEM_NOSYNC);
1.2  pk 	if (error) {
1.2  pk 		printf("%s: DMA buffer alloc error %d\n",
1.2  pk 			xy->sc_dev.dv_xname, error);
1.2  pk 		bus_dmamem_free(xyc->dmatag, &seg, rseg);
1.2  pk 		goto done;
1.2  pk 	}
1.2  pk
1.2  pk
1.1  pk 	/* first try and reset the drive */
1.1  pk
1.2  pk 	error = xyc_cmd(xyc, XYCMD_RST, 0, xy->xy_drive, 0, 0, 0, fmode);
1.2  pk 	XYC_DONE(xyc, error);
1.2  pk 	if (error == XY_ERR_DNRY) {
1.1  pk 		printf(" drive %d: off-line\n", xa->driveno);
1.1  pk 		goto done;
1.1  pk 	}
1.2  pk 	if (error) {
1.2  pk 		printf(": ERROR 0x%02x (%s)\n", error, xyc_e2str(error));
1.1  pk 		goto done;
1.1  pk 	}
1.1  pk 	printf(" drive %d: ready", xa->driveno);
1.1  pk
1.1  pk 	/*
1.1  pk 	 * now set drive parameters (to semi-bogus values) so we can read the
1.1  pk 	 * disk label.
1.1  pk 	 */
1.1  pk 	xy->pcyl = xy->ncyl = 1;
1.1  pk 	xy->acyl = 0;
1.1  pk 	xy->nhead = 1;
1.1  pk 	xy->nsect = 1;
1.1  pk 	xy->sectpercyl = 1;
1.1  pk 	for (lcv = 0; lcv < 126; lcv++)	/* init empty bad144 table */
1.1  pk 		xy->dkb.bt_bad[lcv].bt_cyl =
1.1  pk 			xy->dkb.bt_bad[lcv].bt_trksec = 0xffff;
1.1  pk
1.1  pk 	/* read disk label */
1.1  pk 	for (xy->drive_type = 0 ; xy->drive_type <= XYC_MAXDT ;
1.1  pk 						xy->drive_type++) {
1.2  pk 		error = xyc_cmd(xyc, XYCMD_RD, 0, xy->xy_drive, 0, 1,
1.2  pk 						dmaddr, fmode);
1.2  pk 		XYC_DONE(xyc, error);
1.2  pk 		if (error == XY_ERR_AOK) break;
1.1  pk 	}
1.1  pk
1.2  pk 	if (error != XY_ERR_AOK) {
1.1  pk 		printf("\n%s: reading disk label failed: %s\n",
1.2  pk 			xy->sc_dev.dv_xname, xyc_e2str(error));
1.1  pk 		goto done;
1.1  pk 	}
1.1  pk 	printf(" (drive type %d)\n", xy->drive_type);
1.1  pk
1.1  pk 	newstate = XY_DRIVE_NOLABEL;
1.1  pk
1.1  pk 	xy->hw_spt = spt = 0; /* XXX needed ? */
1.1  pk 	/* Attach the disk: must be before getdisklabel to malloc label */
1.1  pk 	disk_attach(&xy->sc_dk);
1.1  pk
1.2  pk 	if (xygetdisklabel(xy, buf) != XY_ERR_AOK)
1.1  pk 		goto done;
1.1  pk
1.1  pk 	/* inform the user of what is up */
1.1  pk 	printf("%s: <%s>, pcyl %d\n", xy->sc_dev.dv_xname,
1.2  pk 		buf, xy->pcyl);
1.1  pk 	mb = xy->ncyl * (xy->nhead * xy->nsect) / (1048576 / XYFM_BPS);
1.1  pk 	printf("%s: %dMB, %d cyl, %d head, %d sec, %d bytes/sec\n",
1.1  pk 		xy->sc_dev.dv_xname, mb, xy->ncyl, xy->nhead, xy->nsect,
1.1  pk 		XYFM_BPS);
1.1  pk
1.1  pk 	/*
1.1  pk 	 * 450/451 stupidity: the drive type is encoded into the format
1.1  pk 	 * of the disk.   the drive type in the IOPB must match the drive
1.1  pk 	 * type in the format, or you will not be able to do I/O to the
1.1  pk 	 * disk (you get header not found errors).  if you have two drives
1.1  pk 	 * of different sizes that have the same drive type in their
1.1  pk 	 * formatting then you are out of luck.
1.1  pk 	 *
1.1  pk 	 * this problem was corrected in the 753/7053.
1.1  pk 	 */
1.1  pk
1.1  pk 	for (lcv = 0 ; lcv < XYC_MAXDEV ; lcv++) {
1.1  pk 		oxy = xyc->sc_drives[lcv];
1.1  pk 		if (oxy == NULL || oxy == xy) continue;
1.1  pk 		if (oxy->drive_type != xy->drive_type) continue;
1.1  pk 		if (xy->nsect != oxy->nsect || xy->pcyl != oxy->pcyl ||
1.1  pk 			xy->nhead != oxy->nhead) {
1.1  pk 			printf("%s: %s and %s must be the same size!\n",
1.1  pk 				xyc->sc_dev.dv_xname, xy->sc_dev.dv_xname,
1.1  pk 				oxy->sc_dev.dv_xname);
1.1  pk 			panic("xy drive size mismatch");
1.1  pk 		}
1.1  pk 	}
1.1  pk
1.1  pk
1.1  pk 	/* now set the real drive parameters! */
1.1  pk
1.1  pk 	blk = (xy->nsect - 1) +
1.1  pk 		((xy->nhead - 1) * xy->nsect) +
1.1  pk 		((xy->pcyl - 1) * xy->nsect * xy->nhead);
1.2  pk 	error = xyc_cmd(xyc, XYCMD_SDS, 0, xy->xy_drive, blk, 0, 0, fmode);
1.2  pk 	XYC_DONE(xyc, error);
1.2  pk 	if (error) {
1.1  pk 		printf("%s: write drive size failed: %s\n",
1.2  pk 			xy->sc_dev.dv_xname, xyc_e2str(error));
1.1  pk 		goto done;
1.1  pk 	}
1.1  pk 	newstate = XY_DRIVE_ONLINE;
1.1  pk
1.1  pk 	/*
1.1  pk 	 * read bad144 table. this table resides on the first sector of the
1.1  pk 	 * last track of the disk (i.e. second cyl of "acyl" area).
1.1  pk 	 */
1.1  pk
1.1  pk 	blk = (xy->ncyl + xy->acyl - 1) * (xy->nhead * xy->nsect) +
1.1  pk 								/* last cyl */
1.1  pk 	    (xy->nhead - 1) * xy->nsect;	/* last head */
1.2  pk 	error = xyc_cmd(xyc, XYCMD_RD, 0, xy->xy_drive, blk, 1,
1.2  pk 						dmaddr, fmode);
1.2  pk 	XYC_DONE(xyc, error);
1.2  pk 	if (error) {
1.1  pk 		printf("%s: reading bad144 failed: %s\n",
1.2  pk 			xy->sc_dev.dv_xname, xyc_e2str(error));
1.1  pk 		goto done;
1.1  pk 	}
1.1  pk
1.1  pk 	/* check dkbad for sanity */
1.2  pk 	dkb = (struct dkbad *) buf;
1.1  pk 	for (lcv = 0; lcv < 126; lcv++) {
1.1  pk 		if ((dkb->bt_bad[lcv].bt_cyl == 0xffff ||
1.1  pk 				dkb->bt_bad[lcv].bt_cyl == 0) &&
1.1  pk 		     dkb->bt_bad[lcv].bt_trksec == 0xffff)
1.1  pk 			continue;	/* blank */
1.1  pk 		if (dkb->bt_bad[lcv].bt_cyl >= xy->ncyl)
1.1  pk 			break;
1.1  pk 		if ((dkb->bt_bad[lcv].bt_trksec >> 8) >= xy->nhead)
1.1  pk 			break;
1.1  pk 		if ((dkb->bt_bad[lcv].bt_trksec & 0xff) >= xy->nsect)
1.1  pk 			break;
1.1  pk 	}
1.1  pk 	if (lcv != 126) {
1.1  pk 		printf("%s: warning: invalid bad144 sector!\n",
1.1  pk 			xy->sc_dev.dv_xname);
1.1  pk 	} else {
1.2  pk 		bcopy(buf, &xy->dkb, XYFM_BPS);
1.1  pk 	}
1.1  pk
1.1  pk 	if (xa->booting) {
1.1  pk 		/* restore bootpath! (do this via attach_args again?)*/
1.1  pk 		bp = bootpath_store(0, NULL);
1.1  pk 		if (bp && strcmp("xy", bp->name) == 0 &&
1.1  pk 					xy->xy_drive == bp->val[0])
1.1  pk 			bp->dev = &xy->sc_dev;
1.1  pk 	}
1.1  pk
1.1  pk 	dk_establish(&xy->sc_dk, &xy->sc_dev);		/* XXX */
1.1  pk
1.1  pk done:
1.2  pk 	if (buf != NULL) {
1.2  pk 		bus_dmamem_unmap(xyc->dmatag, buf, XYFM_BPS);
1.2  pk 		bus_dmamem_free(xyc->dmatag, &seg, rseg);
1.2  pk 	}
1.2  pk
1.1  pk 	xy->state = newstate;
1.1  pk 	if (!xa->booting) {
1.1  pk 		wakeup(&xy->state);
1.1  pk 		splx(s);
1.1  pk 	}
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * end of autoconfig functions
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * { b , c } d e v s w   f u n c t i o n s
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * xyclose: close device
1.1  pk  */
1.1  pk int
1.1  pk xyclose(dev, flag, fmt, p)
1.1  pk 	dev_t   dev;
1.1  pk 	int     flag, fmt;
1.1  pk 	struct proc *p;
1.1  pk
1.1  pk {
1.1  pk 	struct xy_softc *xy = xy_cd.cd_devs[DISKUNIT(dev)];
1.1  pk 	int     part = DISKPART(dev);
1.1  pk
1.1  pk 	/* clear mask bits */
1.1  pk
1.1  pk 	switch (fmt) {
1.1  pk 	case S_IFCHR:
1.1  pk 		xy->sc_dk.dk_copenmask &= ~(1 << part);
1.1  pk 		break;
1.1  pk 	case S_IFBLK:
1.1  pk 		xy->sc_dk.dk_bopenmask &= ~(1 << part);
1.1  pk 		break;
1.1  pk 	}
1.1  pk 	xy->sc_dk.dk_openmask = xy->sc_dk.dk_copenmask | xy->sc_dk.dk_bopenmask;
1.1  pk
1.1  pk 	return 0;
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xydump: crash dump system
1.1  pk  */
1.1  pk int
1.1  pk xydump(dev, blkno, va, size)
1.1  pk 	dev_t dev;
1.1  pk 	daddr_t blkno;
1.1  pk 	caddr_t va;
1.1  pk 	size_t size;
1.1  pk {
1.1  pk 	int     unit, part;
1.1  pk 	struct xy_softc *xy;
1.1  pk
1.1  pk 	unit = DISKUNIT(dev);
1.1  pk 	if (unit >= xy_cd.cd_ndevs)
1.1  pk 		return ENXIO;
1.1  pk 	part = DISKPART(dev);
1.1  pk
1.1  pk 	xy = xy_cd.cd_devs[unit];
1.1  pk
1.1  pk 	printf("%s%c: crash dump not supported (yet)\n", xy->sc_dev.dv_xname,
1.1  pk 	    'a' + part);
1.1  pk
1.1  pk 	return ENXIO;
1.1  pk
1.1  pk 	/* outline: globals: "dumplo" == sector number of partition to start
1.1  pk 	 * dump at (convert to physical sector with partition table)
1.1  pk 	 * "dumpsize" == size of dump in clicks "physmem" == size of physical
1.1  pk 	 * memory (clicks, ctob() to get bytes) (normal case: dumpsize ==
1.1  pk 	 * physmem)
1.1  pk 	 *
1.1  pk 	 * dump a copy of physical memory to the dump device starting at sector
1.1  pk 	 * "dumplo" in the swap partition (make sure > 0).   map in pages as
1.1  pk 	 * we go.   use polled I/O.
1.1  pk 	 *
1.1  pk 	 * XXX how to handle NON_CONTIG? */
1.1  pk
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyioctl: ioctls on XY drives.   based on ioctl's of other netbsd disks.
1.1  pk  */
1.1  pk int
1.1  pk xyioctl(dev, command, addr, flag, p)
1.1  pk 	dev_t   dev;
1.1  pk 	u_long  command;
1.1  pk 	caddr_t addr;
1.1  pk 	int     flag;
1.1  pk 	struct proc *p;
1.1  pk
1.1  pk {
1.1  pk 	struct xy_softc *xy;
1.1  pk 	struct xd_iocmd *xio;
1.1  pk 	int     error, s, unit;
1.1  pk
1.1  pk 	unit = DISKUNIT(dev);
1.1  pk
1.1  pk 	if (unit >= xy_cd.cd_ndevs || (xy = xy_cd.cd_devs[unit]) == NULL)
1.1  pk 		return (ENXIO);
1.1  pk
1.1  pk 	/* switch on ioctl type */
1.1  pk
1.1  pk 	switch (command) {
1.1  pk 	case DIOCSBAD:		/* set bad144 info */
1.1  pk 		if ((flag & FWRITE) == 0)
1.1  pk 			return EBADF;
1.1  pk 		s = splbio();
1.1  pk 		bcopy(addr, &xy->dkb, sizeof(xy->dkb));
1.1  pk 		splx(s);
1.1  pk 		return 0;
1.1  pk
1.1  pk 	case DIOCGDINFO:	/* get disk label */
1.1  pk 		bcopy(xy->sc_dk.dk_label, addr, sizeof(struct disklabel));
1.1  pk 		return 0;
1.1  pk
1.1  pk 	case DIOCGPART:	/* get partition info */
1.1  pk 		((struct partinfo *) addr)->disklab = xy->sc_dk.dk_label;
1.1  pk 		((struct partinfo *) addr)->part =
1.1  pk 		    &xy->sc_dk.dk_label->d_partitions[DISKPART(dev)];
1.1  pk 		return 0;
1.1  pk
1.1  pk 	case DIOCSDINFO:	/* set disk label */
1.1  pk 		if ((flag & FWRITE) == 0)
1.1  pk 			return EBADF;
1.1  pk 		error = setdisklabel(xy->sc_dk.dk_label,
1.1  pk 		    (struct disklabel *) addr, /* xy->sc_dk.dk_openmask : */ 0,
1.1  pk 		    xy->sc_dk.dk_cpulabel);
1.1  pk 		if (error == 0) {
1.1  pk 			if (xy->state == XY_DRIVE_NOLABEL)
1.1  pk 				xy->state = XY_DRIVE_ONLINE;
1.1  pk 		}
1.1  pk 		return error;
1.1  pk
1.1  pk 	case DIOCWLABEL:	/* change write status of disk label */
1.1  pk 		if ((flag & FWRITE) == 0)
1.1  pk 			return EBADF;
1.1  pk 		if (*(int *) addr)
1.1  pk 			xy->flags |= XY_WLABEL;
1.1  pk 		else
1.1  pk 			xy->flags &= ~XY_WLABEL;
1.1  pk 		return 0;
1.1  pk
1.1  pk 	case DIOCWDINFO:	/* write disk label */
1.1  pk 		if ((flag & FWRITE) == 0)
1.1  pk 			return EBADF;
1.1  pk 		error = setdisklabel(xy->sc_dk.dk_label,
1.1  pk 		    (struct disklabel *) addr, /* xy->sc_dk.dk_openmask : */ 0,
1.1  pk 		    xy->sc_dk.dk_cpulabel);
1.1  pk 		if (error == 0) {
1.1  pk 			if (xy->state == XY_DRIVE_NOLABEL)
1.1  pk 				xy->state = XY_DRIVE_ONLINE;
1.1  pk
1.1  pk 			/* Simulate opening partition 0 so write succeeds. */
1.1  pk 			xy->sc_dk.dk_openmask |= (1 << 0);
1.1  pk 			error = writedisklabel(MAKEDISKDEV(major(dev), DISKUNIT(dev), RAW_PART),
1.1  pk 			    xystrategy, xy->sc_dk.dk_label,
1.1  pk 			    xy->sc_dk.dk_cpulabel);
1.1  pk 			xy->sc_dk.dk_openmask =
1.1  pk 			    xy->sc_dk.dk_copenmask | xy->sc_dk.dk_bopenmask;
1.1  pk 		}
1.1  pk 		return error;
1.1  pk
1.1  pk 	case DIOSXDCMD:
1.1  pk 		xio = (struct xd_iocmd *) addr;
1.1  pk 		if ((error = suser(p->p_ucred, &p->p_acflag)) != 0)
1.1  pk 			return (error);
1.1  pk 		return (xyc_ioctlcmd(xy, dev, xio));
1.1  pk
1.1  pk 	default:
1.1  pk 		return ENOTTY;
1.1  pk 	}
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyopen: open drive
1.1  pk  */
1.1  pk
1.1  pk int
1.1  pk xyopen(dev, flag, fmt, p)
1.1  pk 	dev_t   dev;
1.1  pk 	int     flag, fmt;
1.1  pk 	struct proc *p;
1.1  pk {
1.1  pk 	int     unit, part;
1.1  pk 	struct xy_softc *xy;
1.1  pk 	struct xyc_attach_args xa;
1.1  pk
1.1  pk 	/* first, could it be a valid target? */
1.1  pk
1.1  pk 	unit = DISKUNIT(dev);
1.1  pk 	if (unit >= xy_cd.cd_ndevs || (xy = xy_cd.cd_devs[unit]) == NULL)
1.1  pk 		return (ENXIO);
1.1  pk 	part = DISKPART(dev);
1.1  pk
1.1  pk 	/* do we need to attach the drive? */
1.1  pk
1.1  pk 	if (xy->state == XY_DRIVE_UNKNOWN) {
1.1  pk 		xa.driveno = xy->xy_drive;
1.1  pk 		xa.fullmode = XY_SUB_WAIT;
1.1  pk 		xa.booting = 0;
1.1  pk 		xyattach((struct device *) xy->parent,
1.1  pk 						(struct device *) xy, &xa);
1.1  pk 		if (xy->state == XY_DRIVE_UNKNOWN) {
1.1  pk 			return (EIO);
1.1  pk 		}
1.1  pk 	}
1.1  pk 	/* check for partition */
1.1  pk
1.1  pk 	if (part != RAW_PART &&
1.1  pk 	    (part >= xy->sc_dk.dk_label->d_npartitions ||
1.1  pk 		xy->sc_dk.dk_label->d_partitions[part].p_fstype == FS_UNUSED)) {
1.1  pk 		return (ENXIO);
1.1  pk 	}
1.1  pk 	/* set open masks */
1.1  pk
1.1  pk 	switch (fmt) {
1.1  pk 	case S_IFCHR:
1.1  pk 		xy->sc_dk.dk_copenmask |= (1 << part);
1.1  pk 		break;
1.1  pk 	case S_IFBLK:
1.1  pk 		xy->sc_dk.dk_bopenmask |= (1 << part);
1.1  pk 		break;
1.1  pk 	}
1.1  pk 	xy->sc_dk.dk_openmask = xy->sc_dk.dk_copenmask | xy->sc_dk.dk_bopenmask;
1.1  pk
1.1  pk 	return 0;
1.1  pk }
1.1  pk
1.1  pk int
1.1  pk xyread(dev, uio, flags)
1.1  pk 	dev_t   dev;
1.1  pk 	struct uio *uio;
1.1  pk 	int flags;
1.1  pk {
1.1  pk
1.1  pk 	return (physio(xystrategy, NULL, dev, B_READ, minphys, uio));
1.1  pk }
1.1  pk
1.1  pk int
1.1  pk xywrite(dev, uio, flags)
1.1  pk 	dev_t   dev;
1.1  pk 	struct uio *uio;
1.1  pk 	int flags;
1.1  pk {
1.1  pk
1.1  pk 	return (physio(xystrategy, NULL, dev, B_WRITE, minphys, uio));
1.1  pk }
1.1  pk
1.1  pk
1.1  pk /*
1.1  pk  * xysize: return size of a partition for a dump
1.1  pk  */
1.1  pk
1.1  pk int
1.1  pk xysize(dev)
1.1  pk 	dev_t   dev;
1.1  pk
1.1  pk {
1.1  pk 	struct xy_softc *xysc;
1.1  pk 	int     unit, part, size, omask;
1.1  pk
1.1  pk 	/* valid unit? */
1.1  pk 	unit = DISKUNIT(dev);
1.1  pk 	if (unit >= xy_cd.cd_ndevs || (xysc = xy_cd.cd_devs[unit]) == NULL)
1.1  pk 		return (-1);
1.1  pk
1.1  pk 	part = DISKPART(dev);
1.1  pk 	omask = xysc->sc_dk.dk_openmask & (1 << part);
1.1  pk
1.1  pk 	if (omask == 0 && xyopen(dev, 0, S_IFBLK, NULL) != 0)
1.1  pk 		return (-1);
1.1  pk
1.1  pk 	/* do it */
1.1  pk 	if (xysc->sc_dk.dk_label->d_partitions[part].p_fstype != FS_SWAP)
1.1  pk 		size = -1;	/* only give valid size for swap partitions */
1.1  pk 	else
1.1  pk 		size = xysc->sc_dk.dk_label->d_partitions[part].p_size *
1.1  pk 		    (xysc->sc_dk.dk_label->d_secsize / DEV_BSIZE);
1.1  pk 	if (omask == 0 && xyclose(dev, 0, S_IFBLK, NULL) != 0)
1.1  pk 		return (-1);
1.1  pk 	return (size);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xystrategy: buffering system interface to xy.
1.1  pk  */
1.1  pk
1.1  pk void
1.1  pk xystrategy(bp)
1.1  pk 	struct buf *bp;
1.1  pk
1.1  pk {
1.1  pk 	struct xy_softc *xy;
1.1  pk 	int     s, unit;
1.1  pk 	struct xyc_attach_args xa;
1.1  pk
1.1  pk 	unit = DISKUNIT(bp->b_dev);
1.1  pk
1.1  pk 	/* check for live device */
1.1  pk
1.1  pk 	if (unit >= xy_cd.cd_ndevs || (xy = xy_cd.cd_devs[unit]) == 0 ||
1.1  pk 	    bp->b_blkno < 0 ||
1.1  pk 	    (bp->b_bcount % xy->sc_dk.dk_label->d_secsize) != 0) {
1.1  pk 		bp->b_error = EINVAL;
1.1  pk 		goto bad;
1.1  pk 	}
1.1  pk 	/* do we need to attach the drive? */
1.1  pk
1.1  pk 	if (xy->state == XY_DRIVE_UNKNOWN) {
1.1  pk 		xa.driveno = xy->xy_drive;
1.1  pk 		xa.fullmode = XY_SUB_WAIT;
1.1  pk 		xa.booting = 0;
1.1  pk 		xyattach((struct device *)xy->parent, (struct device *)xy, &xa);
1.1  pk 		if (xy->state == XY_DRIVE_UNKNOWN) {
1.1  pk 			bp->b_error = EIO;
1.1  pk 			goto bad;
1.1  pk 		}
1.1  pk 	}
1.1  pk 	if (xy->state != XY_DRIVE_ONLINE && DISKPART(bp->b_dev) != RAW_PART) {
1.1  pk 		/* no I/O to unlabeled disks, unless raw partition */
1.1  pk 		bp->b_error = EIO;
1.1  pk 		goto bad;
1.1  pk 	}
1.1  pk 	/* short circuit zero length request */
1.1  pk
1.1  pk 	if (bp->b_bcount == 0)
1.1  pk 		goto done;
1.1  pk
1.1  pk 	/* check bounds with label (disksubr.c).  Determine the size of the
1.1  pk 	 * transfer, and make sure it is within the boundaries of the
1.1  pk 	 * partition. Adjust transfer if needed, and signal errors or early
1.1  pk 	 * completion. */
1.1  pk
1.1  pk 	if (bounds_check_with_label(bp, xy->sc_dk.dk_label,
1.1  pk 		(xy->flags & XY_WLABEL) != 0) <= 0)
1.1  pk 		goto done;
1.1  pk
1.1  pk 	/*
1.1  pk 	 * now we know we have a valid buf structure that we need to do I/O
1.1  pk 	 * on.
1.1  pk 	 */
1.1  pk 	s = splbio();		/* protect the queues */
1.1  pk
1.1  pk 	disksort(&xy->xyq, bp);
1.1  pk
1.1  pk 	/* start 'em up */
1.1  pk
1.1  pk 	xyc_start(xy->parent, NULL);
1.1  pk
1.1  pk 	/* done! */
1.1  pk
1.1  pk 	splx(s);
1.1  pk 	return;
1.1  pk
1.1  pk bad:				/* tells upper layers we have an error */
1.1  pk 	bp->b_flags |= B_ERROR;
1.1  pk done:				/* tells upper layers we are done with this
1.1  pk 				 * buf */
1.1  pk 	bp->b_resid = bp->b_bcount;
1.1  pk 	biodone(bp);
1.1  pk }
1.1  pk /*
1.1  pk  * end of {b,c}devsw functions
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * i n t e r r u p t   f u n c t i o n
1.1  pk  *
1.1  pk  * xycintr: hardware interrupt.
1.1  pk  */
1.1  pk int
1.1  pk xycintr(v)
1.1  pk 	void   *v;
1.1  pk
1.1  pk {
1.1  pk 	struct xyc_softc *xycsc = v;
1.1  pk
1.1  pk 	/* kick the event counter */
1.1  pk
1.1  pk 	xycsc->sc_intrcnt.ev_count++;
1.1  pk
1.1  pk 	/* remove as many done IOPBs as possible */
1.1  pk
1.1  pk 	xyc_remove_iorq(xycsc);
1.1  pk
1.1  pk 	/* start any iorq's already waiting */
1.1  pk
1.1  pk 	xyc_start(xycsc, NULL);
1.1  pk
1.1  pk 	return (1);
1.1  pk }
1.1  pk /*
1.1  pk  * end of interrupt function
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * i n t e r n a l   f u n c t i o n s
1.1  pk  */
1.1  pk
1.1  pk /*
1.1  pk  * xyc_rqinit: fill out the fields of an I/O request
1.1  pk  */
1.1  pk
1.1  pk inline void
1.1  pk xyc_rqinit(rq, xyc, xy, md, blk, cnt, db, bp)
1.1  pk 	struct xy_iorq *rq;
1.1  pk 	struct xyc_softc *xyc;
1.1  pk 	struct xy_softc *xy;
1.1  pk 	int     md;
1.1  pk 	u_long  blk;
1.1  pk 	int     cnt;
1.1  pk 	caddr_t db;
1.1  pk 	struct buf *bp;
1.1  pk {
1.1  pk 	rq->xyc = xyc;
1.1  pk 	rq->xy = xy;
1.1  pk 	rq->ttl = XYC_MAXTTL + 10;
1.1  pk 	rq->mode = md;
1.1  pk 	rq->tries = rq->errno = rq->lasterror = 0;
1.1  pk 	rq->blockno = blk;
1.1  pk 	rq->sectcnt = cnt;
1.2  pk 	rq->dbuf = db;
1.1  pk 	rq->buf = bp;
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_rqtopb: load up an IOPB based on an iorq
1.1  pk  */
1.1  pk
1.1  pk void
1.1  pk xyc_rqtopb(iorq, iopb, cmd, subfun)
1.1  pk 	struct xy_iorq *iorq;
1.1  pk 	struct xy_iopb *iopb;
1.1  pk 	int     cmd, subfun;
1.1  pk
1.1  pk {
1.1  pk 	u_long  block, dp;
1.1  pk
1.1  pk 	/* normal IOPB case, standard stuff */
1.1  pk
1.1  pk 	/* chain bit handled later */
1.1  pk 	iopb->ien = (XY_STATE(iorq->mode) == XY_SUB_POLL) ? 0 : 1;
1.1  pk 	iopb->com = cmd;
1.1  pk 	iopb->errno = 0;
1.1  pk 	iopb->errs = 0;
1.1  pk 	iopb->done = 0;
1.1  pk 	if (iorq->xy) {
1.1  pk 		iopb->unit = iorq->xy->xy_drive;
1.1  pk 		iopb->dt = iorq->xy->drive_type;
1.1  pk 	} else {
1.1  pk 		iopb->unit = 0;
1.1  pk 		iopb->dt = 0;
1.1  pk 	}
1.1  pk 	block = iorq->blockno;
1.1  pk 	if (iorq->xy == NULL || block == 0) {
1.1  pk 		iopb->sect = iopb->head = iopb->cyl = 0;
1.1  pk 	} else {
1.1  pk 		iopb->sect = block % iorq->xy->nsect;
1.1  pk 		block = block / iorq->xy->nsect;
1.1  pk 		iopb->head = block % iorq->xy->nhead;
1.1  pk 		block = block / iorq->xy->nhead;
1.1  pk 		iopb->cyl = block;
1.1  pk 	}
1.1  pk 	iopb->scnt = iorq->sectcnt;
1.2  pk 	dp = (u_long) iorq->dbuf;
1.1  pk 	if (iorq->dbuf == NULL) {
1.1  pk 		iopb->dataa = 0;
1.1  pk 		iopb->datar = 0;
1.1  pk 	} else {
1.1  pk 		iopb->dataa = (dp & 0xffff);
1.1  pk 		iopb->datar = ((dp & 0xff0000) >> 16);
1.1  pk 	}
1.1  pk 	iopb->subfn = subfun;
1.1  pk }
1.1  pk
1.1  pk
1.1  pk /*
1.1  pk  * xyc_unbusy: wait for the xyc to go unbusy, or timeout.
1.1  pk  */
1.1  pk
1.1  pk int
1.1  pk xyc_unbusy(xyc, del)
1.1  pk
1.1  pk struct xyc *xyc;
1.1  pk int del;
1.1  pk
1.1  pk {
1.1  pk 	while (del-- > 0) {
1.1  pk 		if ((xyc->xyc_csr & XYC_GBSY) == 0)
1.1  pk 			break;
1.1  pk 		DELAY(1);
1.1  pk 	}
1.1  pk 	return(del == 0 ? XY_ERR_FAIL : XY_ERR_AOK);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_cmd: front end for POLL'd and WAIT'd commands.  Returns 0 or error.
1.1  pk  * note that NORM requests are handled seperately.
1.1  pk  */
1.1  pk int
1.1  pk xyc_cmd(xycsc, cmd, subfn, unit, block, scnt, dptr, fullmode)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	int     cmd, subfn, unit, block, scnt;
1.1  pk 	char   *dptr;
1.1  pk 	int     fullmode;
1.1  pk
1.1  pk {
1.1  pk 	int     submode = XY_STATE(fullmode);
1.1  pk 	struct xy_iorq *iorq = xycsc->ciorq;
1.1  pk 	struct xy_iopb *iopb = xycsc->ciopb;
1.1  pk
1.1  pk 	/*
1.1  pk 	 * is someone else using the control iopq wait for it if we can
1.1  pk 	 */
1.1  pk start:
1.1  pk 	if (submode == XY_SUB_WAIT && XY_STATE(iorq->mode) != XY_SUB_FREE) {
1.1  pk 		if (tsleep(iorq, PRIBIO, "xyc_cmd", 0))
1.1  pk                                 return(XY_ERR_FAIL);
1.1  pk 		goto start;
1.1  pk 	}
1.1  pk
1.1  pk 	if (XY_STATE(iorq->mode) != XY_SUB_FREE) {
1.1  pk 		DELAY(1000000);		/* XY_SUB_POLL: steal the iorq */
1.1  pk 		iorq->mode = XY_SUB_FREE;
1.1  pk 		printf("%s: stole control iopb\n", xycsc->sc_dev.dv_xname);
1.1  pk 	}
1.1  pk
1.1  pk 	/* init iorq/iopb */
1.1  pk
1.1  pk 	xyc_rqinit(iorq, xycsc,
1.1  pk 	    (unit == XYC_NOUNIT) ? NULL : xycsc->sc_drives[unit],
1.1  pk 	    fullmode, block, scnt, dptr, NULL);
1.1  pk
1.1  pk 	/* load IOPB from iorq */
1.1  pk
1.1  pk 	xyc_rqtopb(iorq, iopb, cmd, subfn);
1.1  pk
1.1  pk 	/* submit it for processing */
1.1  pk
1.1  pk 	xyc_submit_iorq(xycsc, iorq, fullmode);	/* error code will be in iorq */
1.1  pk
1.1  pk 	return(XY_ERR_AOK);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_startbuf
1.1  pk  * start a buffer for running
1.1  pk  */
1.1  pk
1.1  pk int
1.1  pk xyc_startbuf(xycsc, xysc, bp)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	struct xy_softc *xysc;
1.1  pk 	struct buf *bp;
1.1  pk
1.1  pk {
1.2  pk 	int     partno, error;
1.1  pk 	struct xy_iorq *iorq;
1.1  pk 	struct xy_iopb *iopb;
1.1  pk 	u_long  block;
1.1  pk
1.1  pk 	iorq = xysc->xyrq;
1.1  pk 	iopb = iorq->iopb;
1.1  pk
1.1  pk 	/* get buf */
1.1  pk
1.1  pk 	if (bp == NULL)
1.1  pk 		panic("xyc_startbuf null buf");
1.1  pk
1.1  pk 	partno = DISKPART(bp->b_dev);
1.1  pk #ifdef XYC_DEBUG
1.1  pk 	printf("xyc_startbuf: %s%c: %s block %d\n", xysc->sc_dev.dv_xname,
1.1  pk 	    'a' + partno, (bp->b_flags & B_READ) ? "read" : "write", bp->b_blkno);
1.1  pk 	printf("xyc_startbuf: b_bcount %d, b_data 0x%x\n",
1.1  pk 	    bp->b_bcount, bp->b_data);
1.1  pk #endif
1.1  pk
1.1  pk 	/*
1.1  pk 	 * load request.  we have to calculate the correct block number based
1.1  pk 	 * on partition info.
1.1  pk 	 *
1.1  pk 	 * note that iorq points to the buffer as mapped into DVMA space,
1.1  pk 	 * where as the bp->b_data points to its non-DVMA mapping.
1.1  pk 	 */
1.1  pk
1.1  pk 	block = bp->b_blkno + ((partno == RAW_PART) ? 0 :
1.1  pk 	    xysc->sc_dk.dk_label->d_partitions[partno].p_offset);
1.1  pk
1.2  pk 	error = bus_dmamap_load(xycsc->dmatag, iorq->dmamap,
1.2  pk 			bp->b_data, bp->b_bcount, 0, BUS_DMA_NOWAIT);
1.2  pk 	if (error) {
1.2  pk 		printf("%s: warning: cannot load DMA map\n",
1.1  pk 			xycsc->sc_dev.dv_xname);
1.1  pk 		return (XY_ERR_FAIL);	/* XXX: need some sort of
1.1  pk 					 * call-back scheme here? */
1.1  pk 	}
1.1  pk
1.2  pk 	bus_dmamap_sync(xycsc->dmatag, iorq->dmamap,
1.2  pk 			(bp->b_flags & B_READ)
1.2  pk 				? BUS_DMASYNC_PREREAD
1.2  pk 				: BUS_DMASYNC_PREWRITE);
1.2  pk
1.1  pk 	/* init iorq and load iopb from it */
1.1  pk 	xyc_rqinit(iorq, xycsc, xysc, XY_SUB_NORM | XY_MODE_VERBO, block,
1.2  pk 		   bp->b_bcount / XYFM_BPS,
1.2  pk 		   (caddr_t)iorq->dmamap->dm_segs[0].ds_addr,
1.2  pk 		   bp);
1.1  pk
1.1  pk 	xyc_rqtopb(iorq, iopb, (bp->b_flags & B_READ) ? XYCMD_RD : XYCMD_WR, 0);
1.1  pk
1.1  pk 	/* Instrumentation. */
1.1  pk 	disk_busy(&xysc->sc_dk);
1.1  pk
1.1  pk 	return (XY_ERR_AOK);
1.1  pk }
1.1  pk
1.1  pk
1.1  pk /*
1.1  pk  * xyc_submit_iorq: submit an iorq for processing.  returns XY_ERR_AOK
1.1  pk  * if ok.  if it fail returns an error code.  type is XY_SUB_*.
1.1  pk  *
1.1  pk  * note: caller frees iorq in all cases except NORM
1.1  pk  *
1.1  pk  * return value:
1.1  pk  *   NORM: XY_AOK (req pending), XY_FAIL (couldn't submit request)
1.1  pk  *   WAIT: XY_AOK (success), <error-code> (failed)
1.1  pk  *   POLL: <same as WAIT>
1.1  pk  *   NOQ : <same as NORM>
1.1  pk  *
1.1  pk  * there are three sources for i/o requests:
1.1  pk  * [1] xystrategy: normal block I/O, using "struct buf" system.
1.1  pk  * [2] autoconfig/crash dump: these are polled I/O requests, no interrupts.
1.1  pk  * [3] open/ioctl: these are I/O requests done in the context of a process,
1.1  pk  *                 and the process should block until they are done.
1.1  pk  *
1.1  pk  * software state is stored in the iorq structure.  each iorq has an
1.1  pk  * iopb structure.  the hardware understands the iopb structure.
1.1  pk  * every command must go through an iopb.  a 450 handles one iopb at a
1.1  pk  * time, where as a 451 can take them in chains.  [the 450 claims it
1.1  pk  * can handle chains, but is appears to be buggy...]   iopb are allocated
1.1  pk  * in DVMA space at boot up time.  each disk gets one iopb, and the
1.1  pk  * controller gets one (for POLL and WAIT commands).  what happens if
1.1  pk  * the iopb is busy?  for i/o type [1], the buffers are queued at the
1.1  pk  * "buff" layer and * picked up later by the interrupt routine.  for case
1.1  pk  * [2] we can only be blocked if there is a WAIT type I/O request being
1.1  pk  * run.   since this can only happen when we are crashing, we wait a sec
1.1  pk  * and then steal the IOPB.  for case [3] the process can sleep
1.1  pk  * on the iorq free list until some iopbs are avaliable.
1.1  pk  */
1.1  pk
1.1  pk
1.1  pk int
1.1  pk xyc_submit_iorq(xycsc, iorq, type)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	struct xy_iorq *iorq;
1.1  pk 	int     type;
1.1  pk
1.1  pk {
1.1  pk 	struct xy_iopb *iopb;
1.1  pk 	u_long  iopbaddr;
1.1  pk
1.1  pk #ifdef XYC_DEBUG
1.1  pk 	printf("xyc_submit_iorq(%s, addr=0x%x, type=%d)\n",
1.1  pk 		xycsc->sc_dev.dv_xname, iorq, type);
1.1  pk #endif
1.1  pk
1.1  pk 	/* first check and see if controller is busy */
1.1  pk 	if ((xycsc->xyc->xyc_csr & XYC_GBSY) != 0) {
1.1  pk #ifdef XYC_DEBUG
1.1  pk 		printf("xyc_submit_iorq: XYC not ready (BUSY)\n");
1.1  pk #endif
1.1  pk 		if (type == XY_SUB_NOQ)
1.1  pk 			return (XY_ERR_FAIL);	/* failed */
1.1  pk 		switch (type) {
1.1  pk 		case XY_SUB_NORM:
1.1  pk 			return XY_ERR_AOK;	/* success */
1.1  pk 		case XY_SUB_WAIT:
1.1  pk 			while (iorq->iopb->done == 0) {
1.1  pk 				sleep(iorq, PRIBIO);
1.1  pk 			}
1.1  pk 			return (iorq->errno);
1.1  pk 		case XY_SUB_POLL:		/* steal controller */
1.1  pk 			iopbaddr = xycsc->xyc->xyc_rsetup; /* RESET */
1.1  pk 			if (xyc_unbusy(xycsc->xyc,XYC_RESETUSEC) == XY_ERR_FAIL)
1.1  pk 				panic("xyc_submit_iorq: stuck xyc");
1.1  pk 			printf("%s: stole controller\n",
1.1  pk 				xycsc->sc_dev.dv_xname);
1.1  pk 			break;
1.1  pk 		default:
1.1  pk 			panic("xyc_submit_iorq adding");
1.1  pk 		}
1.1  pk 	}
1.1  pk
1.1  pk 	iopb = xyc_chain(xycsc, iorq);	 /* build chain */
1.1  pk 	if (iopb == NULL) { /* nothing doing? */
1.1  pk 		if (type == XY_SUB_NORM || type == XY_SUB_NOQ)
1.1  pk 			return(XY_ERR_AOK);
1.1  pk 		panic("xyc_submit_iorq: xyc_chain failed!\n");
1.1  pk 	}
1.1  pk 	iopbaddr = (u_long) iopb - DVMA_BASE;
1.1  pk
1.1  pk 	XYC_GO(xycsc->xyc, iopbaddr);
1.1  pk
1.1  pk 	/* command now running, wrap it up */
1.1  pk 	switch (type) {
1.1  pk 	case XY_SUB_NORM:
1.1  pk 	case XY_SUB_NOQ:
1.1  pk 		return (XY_ERR_AOK);	/* success */
1.1  pk 	case XY_SUB_WAIT:
1.1  pk 		while (iorq->iopb->done == 0) {
1.1  pk 			sleep(iorq, PRIBIO);
1.1  pk 		}
1.1  pk 		return (iorq->errno);
1.1  pk 	case XY_SUB_POLL:
1.1  pk 		return (xyc_piodriver(xycsc, iorq));
1.1  pk 	default:
1.1  pk 		panic("xyc_submit_iorq wrap up");
1.1  pk 	}
1.1  pk 	panic("xyc_submit_iorq");
1.1  pk 	return 0;	/* not reached */
1.1  pk }
1.1  pk
1.1  pk
1.1  pk /*
1.1  pk  * xyc_chain: build a chain.  return dvma address of first element in
1.1  pk  * the chain.   iorq != NULL: means we only want that item on the chain.
1.1  pk  */
1.1  pk
1.1  pk struct xy_iopb *
1.1  pk xyc_chain(xycsc, iorq)
1.1  pk
1.1  pk struct xyc_softc *xycsc;
1.1  pk struct xy_iorq *iorq;
1.1  pk
1.1  pk {
1.1  pk   int togo, chain, hand;
1.1  pk   struct xy_iopb *iopb, *prev_iopb;
1.1  pk   bzero(xycsc->xy_chain, sizeof(xycsc->xy_chain));
1.1  pk
1.1  pk   /*
1.1  pk    * promote control IOPB to the top
1.1  pk    */
1.1  pk   if (iorq == NULL) {
1.1  pk     if ((XY_STATE(xycsc->reqs[XYC_CTLIOPB].mode) == XY_SUB_POLL ||
1.1  pk         XY_STATE(xycsc->reqs[XYC_CTLIOPB].mode) == XY_SUB_WAIT) &&
1.1  pk 		xycsc->iopbase[XYC_CTLIOPB].done == 0)
1.1  pk     iorq = &xycsc->reqs[XYC_CTLIOPB];
1.1  pk   }
1.1  pk   /*
1.1  pk    * special case: if iorq != NULL then we have a POLL or WAIT request.
1.1  pk    * we let these take priority and do them first.
1.1  pk    */
1.1  pk   if (iorq) {
1.1  pk     xycsc->xy_chain[0] = iorq;
1.1  pk     iorq->iopb->chen = 0;
1.1  pk     return(iorq->iopb);
1.1  pk   }
1.1  pk
1.1  pk   /*
1.1  pk    * NORM case: do round robin and maybe chain (if allowed and possible)
1.1  pk    */
1.1  pk
1.1  pk   chain = 0;
1.1  pk   hand = xycsc->xy_hand;
1.1  pk   xycsc->xy_hand = (xycsc->xy_hand + 1) % XYC_MAXIOPB;
1.1  pk
1.1  pk   for (togo = XYC_MAXIOPB ; togo > 0 ; togo--, hand = (hand + 1) % XYC_MAXIOPB){
1.1  pk
1.1  pk     if (XY_STATE(xycsc->reqs[hand].mode) != XY_SUB_NORM ||
1.1  pk 		xycsc->iopbase[hand].done)
1.1  pk       continue;   /* not ready-for-i/o */
1.1  pk
1.1  pk     xycsc->xy_chain[chain] = &xycsc->reqs[hand];
1.1  pk     iopb = xycsc->xy_chain[chain]->iopb;
1.1  pk     iopb->chen = 0;
1.1  pk     if (chain != 0) {   /* adding a link to a chain? */
1.1  pk       prev_iopb = xycsc->xy_chain[chain-1]->iopb;
1.1  pk       prev_iopb->chen = 1;
1.1  pk       prev_iopb->nxtiopb = ((u_long) iopb - DVMA_BASE) & 0xffff;
1.1  pk     } else {            /* head of chain */
1.1  pk       iorq = xycsc->xy_chain[chain];
1.1  pk     }
1.1  pk     chain++;
1.1  pk     if (xycsc->no_ols) break;   /* quit if chaining dis-allowed */
1.1  pk   }
1.1  pk   return(iorq ? iorq->iopb : NULL);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_piodriver
1.1  pk  *
1.1  pk  * programmed i/o driver.   this function takes over the computer
1.1  pk  * and drains off the polled i/o request.   it returns the status of the iorq
1.1  pk  * the caller is interesting in.
1.1  pk  */
1.1  pk int
1.1  pk xyc_piodriver(xycsc, iorq)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	struct xy_iorq  *iorq;
1.1  pk
1.1  pk {
1.1  pk 	int     nreset = 0;
1.1  pk 	int     retval = 0;
1.1  pk 	u_long  res;
1.1  pk #ifdef XYC_DEBUG
1.1  pk 	printf("xyc_piodriver(%s, 0x%x)\n", xycsc->sc_dev.dv_xname, iorq);
1.1  pk #endif
1.1  pk
1.1  pk 	while (iorq->iopb->done == 0) {
1.1  pk
1.1  pk 		res = xyc_unbusy(xycsc->xyc, XYC_MAXTIME);
1.1  pk
1.1  pk 		/* we expect some progress soon */
1.1  pk 		if (res == XY_ERR_FAIL && nreset >= 2) {
1.1  pk 			xyc_reset(xycsc, 0, XY_RSET_ALL, XY_ERR_FAIL, 0);
1.1  pk #ifdef XYC_DEBUG
1.1  pk 			printf("xyc_piodriver: timeout\n");
1.1  pk #endif
1.1  pk 			return (XY_ERR_FAIL);
1.1  pk 		}
1.1  pk 		if (res == XY_ERR_FAIL) {
1.1  pk 			if (xyc_reset(xycsc, 0,
1.1  pk 				      (nreset++ == 0) ? XY_RSET_NONE : iorq,
1.1  pk 				      XY_ERR_FAIL,
1.1  pk 				      0) == XY_ERR_FAIL)
1.1  pk 				return (XY_ERR_FAIL);	/* flushes all but POLL
1.1  pk 							 * requests, resets */
1.1  pk 			continue;
1.1  pk 		}
1.1  pk
1.1  pk 		xyc_remove_iorq(xycsc);	 /* may resubmit request */
1.1  pk
1.1  pk 		if (iorq->iopb->done == 0)
1.1  pk 			xyc_start(xycsc, iorq);
1.1  pk 	}
1.1  pk
1.1  pk 	/* get return value */
1.1  pk
1.1  pk 	retval = iorq->errno;
1.1  pk
1.1  pk #ifdef XYC_DEBUG
1.1  pk 	printf("xyc_piodriver: done, retval = 0x%x (%s)\n",
1.1  pk 	    iorq->errno, xyc_e2str(iorq->errno));
1.1  pk #endif
1.1  pk
1.1  pk 	/* start up any bufs that have queued */
1.1  pk
1.1  pk 	xyc_start(xycsc, NULL);
1.1  pk
1.1  pk 	return (retval);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_xyreset: reset one drive.   NOTE: assumes xyc was just reset.
1.1  pk  * we steal iopb[XYC_CTLIOPB] for this, but we put it back when we are done.
1.1  pk  */
1.1  pk void
1.1  pk xyc_xyreset(xycsc, xysc)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	struct xy_softc *xysc;
1.1  pk
1.1  pk {
1.1  pk 	struct xy_iopb tmpiopb;
1.1  pk 	u_long  addr;
1.1  pk 	int     del;
1.1  pk 	bcopy(xycsc->ciopb, &tmpiopb, sizeof(tmpiopb));
1.1  pk 	xycsc->ciopb->chen = xycsc->ciopb->done = xycsc->ciopb->errs = 0;
1.1  pk 	xycsc->ciopb->ien = 0;
1.1  pk 	xycsc->ciopb->com = XYCMD_RST;
1.1  pk 	xycsc->ciopb->unit = xysc->xy_drive;
1.1  pk 	addr = (u_long) xycsc->ciopb - DVMA_BASE;
1.1  pk
1.1  pk 	XYC_GO(xycsc->xyc, addr);
1.1  pk
1.1  pk 	del = XYC_RESETUSEC;
1.1  pk 	while (del > 0) {
1.1  pk 		if ((xycsc->xyc->xyc_csr & XYC_GBSY) == 0) break;
1.1  pk 		DELAY(1);
1.1  pk 		del--;
1.1  pk 	}
1.1  pk
1.1  pk 	if (del <= 0 || xycsc->ciopb->errs) {
1.1  pk 		printf("%s: off-line: %s\n", xycsc->sc_dev.dv_xname,
1.1  pk 		    xyc_e2str(xycsc->ciopb->errno));
1.1  pk 		del = xycsc->xyc->xyc_rsetup;
1.1  pk 		if (xyc_unbusy(xycsc->xyc, XYC_RESETUSEC) == XY_ERR_FAIL)
1.1  pk 			panic("xyc_reset");
1.1  pk 	} else {
1.1  pk 		xycsc->xyc->xyc_csr = XYC_IPND;	/* clear IPND */
1.1  pk 	}
1.1  pk 	bcopy(&tmpiopb, xycsc->ciopb, sizeof(tmpiopb));
1.1  pk }
1.1  pk
1.1  pk
1.1  pk /*
1.1  pk  * xyc_reset: reset everything: requests are marked as errors except
1.1  pk  * a polled request (which is resubmitted)
1.1  pk  */
1.1  pk int
1.1  pk xyc_reset(xycsc, quiet, blastmode, error, xysc)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	int     quiet, error;
1.1  pk 	struct xy_iorq *blastmode;
1.1  pk 	struct xy_softc *xysc;
1.1  pk
1.1  pk {
1.1  pk 	int     del = 0, lcv, retval = XY_ERR_AOK;
1.1  pk
1.1  pk 	/* soft reset hardware */
1.1  pk
1.1  pk 	if (!quiet)
1.1  pk 		printf("%s: soft reset\n", xycsc->sc_dev.dv_xname);
1.1  pk 	del = xycsc->xyc->xyc_rsetup;
1.1  pk 	del = xyc_unbusy(xycsc->xyc, XYC_RESETUSEC);
1.1  pk 	if (del == XY_ERR_FAIL) {
1.1  pk 		blastmode = XY_RSET_ALL;	/* dead, flush all requests */
1.1  pk 		retval = XY_ERR_FAIL;
1.1  pk 	}
1.1  pk 	if (xysc)
1.1  pk 		xyc_xyreset(xycsc, xysc);
1.1  pk
1.1  pk 	/* fix queues based on "blast-mode" */
1.1  pk
1.1  pk 	for (lcv = 0; lcv < XYC_MAXIOPB; lcv++) {
1.1  pk 		register struct xy_iorq *iorq = &xycsc->reqs[lcv];
1.1  pk
1.1  pk 		if (XY_STATE(iorq->mode) != XY_SUB_POLL &&
1.1  pk 		    XY_STATE(iorq->mode) != XY_SUB_WAIT &&
1.1  pk 		    XY_STATE(iorq->mode) != XY_SUB_NORM)
1.1  pk 			/* is it active? */
1.1  pk 			continue;
1.1  pk
1.1  pk 		if (blastmode == XY_RSET_ALL ||
1.1  pk 				blastmode != iorq) {
1.1  pk 			/* failed */
1.1  pk 			iorq->errno = error;
1.1  pk 			xycsc->iopbase[lcv].done = xycsc->iopbase[lcv].errs = 1;
1.1  pk 			switch (XY_STATE(iorq->mode)) {
1.1  pk 			case XY_SUB_NORM:
1.1  pk 			    iorq->buf->b_error = EIO;
1.1  pk 			    iorq->buf->b_flags |= B_ERROR;
1.1  pk 			    iorq->buf->b_resid = iorq->sectcnt * XYFM_BPS;
1.2  pk
1.2  pk 			    bus_dmamap_sync(xycsc->dmatag, iorq->dmamap,
1.2  pk 					(iorq->buf->b_flags & B_READ)
1.2  pk 						? BUS_DMASYNC_POSTREAD
1.2  pk 						: BUS_DMASYNC_POSTWRITE);
1.2  pk
1.2  pk 			    bus_dmamap_unload(xycsc->dmatag, iorq->dmamap);
1.2  pk
1.1  pk 			    iorq->xy->xyq.b_actf = iorq->buf->b_actf;
1.1  pk 			    disk_unbusy(&xycsc->reqs[lcv].xy->sc_dk,
1.1  pk 				(xycsc->reqs[lcv].buf->b_bcount -
1.1  pk 				xycsc->reqs[lcv].buf->b_resid));
1.1  pk 			    biodone(iorq->buf);
1.1  pk 			    iorq->mode = XY_SUB_FREE;
1.1  pk 			    break;
1.1  pk 			case XY_SUB_WAIT:
1.1  pk 			    wakeup(iorq);
1.1  pk 			case XY_SUB_POLL:
1.1  pk 			    iorq->mode =
1.1  pk 				XY_NEWSTATE(iorq->mode, XY_SUB_DONE);
1.1  pk 			    break;
1.1  pk 			}
1.1  pk
1.1  pk 		} else {
1.1  pk
1.1  pk 			/* resubmit, no need to do anything here */
1.1  pk 		}
1.1  pk 	}
1.1  pk
1.1  pk 	/*
1.1  pk 	 * now, if stuff is waiting, start it.
1.1  pk 	 * since we just reset it should go
1.1  pk 	 */
1.1  pk 	xyc_start(xycsc, NULL);
1.1  pk
1.1  pk 	return (retval);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_start: start waiting buffers
1.1  pk  */
1.1  pk
1.1  pk void
1.1  pk xyc_start(xycsc, iorq)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	struct xy_iorq *iorq;
1.1  pk
1.1  pk {
1.1  pk 	int lcv;
1.1  pk 	struct xy_softc *xy;
1.1  pk
1.1  pk 	if (iorq == NULL) {
1.1  pk 		for (lcv = 0; lcv < XYC_MAXDEV ; lcv++) {
1.1  pk 			if ((xy = xycsc->sc_drives[lcv]) == NULL) continue;
1.1  pk 			if (xy->xyq.b_actf == NULL) continue;
1.1  pk 			if (xy->xyrq->mode != XY_SUB_FREE) continue;
1.1  pk 			xyc_startbuf(xycsc, xy, xy->xyq.b_actf);
1.1  pk 		}
1.1  pk 	}
1.1  pk 	xyc_submit_iorq(xycsc, iorq, XY_SUB_NOQ);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_remove_iorq: remove "done" IOPB's.
1.1  pk  */
1.1  pk
1.1  pk int
1.1  pk xyc_remove_iorq(xycsc)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk
1.1  pk {
1.1  pk 	int     errno, rq, comm, errs;
1.1  pk 	struct xyc *xyc = xycsc->xyc;
1.1  pk 	u_long  addr;
1.1  pk 	struct xy_iopb *iopb;
1.1  pk 	struct xy_iorq *iorq;
1.1  pk 	struct buf *bp;
1.1  pk
1.1  pk 	if (xyc->xyc_csr & XYC_DERR) {
1.1  pk 		/*
1.1  pk 		 * DOUBLE ERROR: should never happen under normal use. This
1.1  pk 		 * error is so bad, you can't even tell which IOPB is bad, so
1.1  pk 		 * we dump them all.
1.1  pk 		 */
1.1  pk 		errno = XY_ERR_DERR;
1.1  pk 		printf("%s: DOUBLE ERROR!\n", xycsc->sc_dev.dv_xname);
1.1  pk 		if (xyc_reset(xycsc, 0, XY_RSET_ALL, errno, 0) != XY_ERR_AOK) {
1.1  pk 			printf("%s: soft reset failed!\n",
1.1  pk 				xycsc->sc_dev.dv_xname);
1.1  pk 			panic("xyc_remove_iorq: controller DEAD");
1.1  pk 		}
1.1  pk 		return (XY_ERR_AOK);
1.1  pk 	}
1.1  pk
1.1  pk 	/*
1.1  pk 	 * get iopb that is done, loop down the chain
1.1  pk 	 */
1.1  pk
1.1  pk 	if (xyc->xyc_csr & XYC_ERR) {
1.1  pk 		xyc->xyc_csr = XYC_ERR; /* clear error condition */
1.1  pk 	}
1.1  pk 	if (xyc->xyc_csr & XYC_IPND) {
1.1  pk 		xyc->xyc_csr = XYC_IPND; /* clear interrupt */
1.1  pk 	}
1.1  pk
1.1  pk 	for (rq = 0; rq < XYC_MAXIOPB; rq++) {
1.1  pk 		iorq = xycsc->xy_chain[rq];
1.1  pk 		if (iorq == NULL) break; /* done ! */
1.1  pk 		if (iorq->mode == 0 || XY_STATE(iorq->mode) == XY_SUB_DONE)
1.1  pk 			continue;	/* free, or done */
1.1  pk 		iopb = iorq->iopb;
1.1  pk 		if (iopb->done == 0)
1.1  pk 			continue;	/* not done yet */
1.1  pk
1.1  pk 		comm = iopb->com;
1.1  pk 		errs = iopb->errs;
1.1  pk
1.1  pk 		if (errs)
1.1  pk 			iorq->errno = iopb->errno;
1.1  pk 		else
1.1  pk 			iorq->errno = 0;
1.1  pk
1.1  pk 		/* handle non-fatal errors */
1.1  pk
1.1  pk 		if (errs &&
1.1  pk 		    xyc_error(xycsc, iorq, iopb, comm) == XY_ERR_AOK)
1.1  pk 			continue;	/* AOK: we resubmitted it */
1.1  pk
1.1  pk
1.1  pk 		/* this iorq is now done (hasn't been restarted or anything) */
1.1  pk
1.1  pk 		if ((iorq->mode & XY_MODE_VERBO) && iorq->lasterror)
1.1  pk 			xyc_perror(iorq, iopb, 0);
1.1  pk
1.1  pk 		/* now, if read/write check to make sure we got all the data
1.1  pk 		 * we needed. (this may not be the case if we got an error in
1.1  pk 		 * the middle of a multisector request).   */
1.1  pk
1.1  pk 		if ((iorq->mode & XY_MODE_B144) != 0 && errs == 0 &&
1.1  pk 		    (comm == XYCMD_RD || comm == XYCMD_WR)) {
1.1  pk 			/* we just successfully processed a bad144 sector
1.1  pk 			 * note: if we are in bad 144 mode, the pointers have
1.1  pk 			 * been advanced already (see above) and are pointing
1.1  pk 			 * at the bad144 sector.   to exit bad144 mode, we
1.1  pk 			 * must advance the pointers 1 sector and issue a new
1.1  pk 			 * request if there are still sectors left to process
1.1  pk 			 *
1.1  pk 			 */
1.1  pk 			XYC_ADVANCE(iorq, 1);	/* advance 1 sector */
1.1  pk
1.1  pk 			/* exit b144 mode */
1.1  pk 			iorq->mode = iorq->mode & (~XY_MODE_B144);
1.1  pk
1.1  pk 			if (iorq->sectcnt) {	/* more to go! */
1.1  pk 				iorq->lasterror = iorq->errno = iopb->errno = 0;
1.1  pk 				iopb->errs = iopb->done = 0;
1.1  pk 				iorq->tries = 0;
1.1  pk 				iopb->scnt = iorq->sectcnt;
1.1  pk 				iopb->cyl = iorq->blockno /
1.1  pk 						iorq->xy->sectpercyl;
1.1  pk 				iopb->head =
1.1  pk 					(iorq->blockno / iorq->xy->nhead) %
1.1  pk 						iorq->xy->nhead;
1.1  pk 				iopb->sect = iorq->blockno % XYFM_BPS;
1.2  pk 				addr = (u_long) iorq->dbuf;
1.1  pk 				iopb->dataa = (addr & 0xffff);
1.1  pk 				iopb->datar = ((addr & 0xff0000) >> 16);
1.1  pk 				/* will resubit at end */
1.1  pk 				continue;
1.1  pk 			}
1.1  pk 		}
1.1  pk 		/* final cleanup, totally done with this request */
1.1  pk
1.1  pk 		switch (XY_STATE(iorq->mode)) {
1.1  pk 		case XY_SUB_NORM:
1.1  pk 			bp = iorq->buf;
1.1  pk 			if (errs) {
1.1  pk 				bp->b_error = EIO;
1.1  pk 				bp->b_flags |= B_ERROR;
1.1  pk 				bp->b_resid = iorq->sectcnt * XYFM_BPS;
1.1  pk 			} else {
1.1  pk 				bp->b_resid = 0;	/* done */
1.1  pk 			}
1.2  pk 			bus_dmamap_sync(xycsc->dmatag, iorq->dmamap,
1.2  pk 					(iorq->buf->b_flags & B_READ)
1.2  pk 						? BUS_DMASYNC_POSTREAD
1.2  pk 						: BUS_DMASYNC_POSTWRITE);
1.2  pk
1.2  pk 			bus_dmamap_unload(xycsc->dmatag, iorq->dmamap);
1.2  pk
1.1  pk 			iorq->xy->xyq.b_actf = bp->b_actf;
1.1  pk 			disk_unbusy(&iorq->xy->sc_dk,
1.1  pk 			    (bp->b_bcount - bp->b_resid));
1.1  pk 			iorq->mode = XY_SUB_FREE;
1.1  pk 			biodone(bp);
1.1  pk 			break;
1.1  pk 		case XY_SUB_WAIT:
1.1  pk 			iorq->mode = XY_NEWSTATE(iorq->mode, XY_SUB_DONE);
1.1  pk 			wakeup(iorq);
1.1  pk 			break;
1.1  pk 		case XY_SUB_POLL:
1.1  pk 			iorq->mode = XY_NEWSTATE(iorq->mode, XY_SUB_DONE);
1.1  pk 			break;
1.1  pk 		}
1.1  pk 	}
1.1  pk
1.1  pk 	return (XY_ERR_AOK);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_perror: print error.
1.1  pk  * - if still_trying is true: we got an error, retried and got a
1.1  pk  *   different error.  in that case lasterror is the old error,
1.1  pk  *   and errno is the new one.
1.1  pk  * - if still_trying is not true, then if we ever had an error it
1.1  pk  *   is in lasterror. also, if iorq->errno == 0, then we recovered
1.1  pk  *   from that error (otherwise iorq->errno == iorq->lasterror).
1.1  pk  */
1.1  pk void
1.1  pk xyc_perror(iorq, iopb, still_trying)
1.1  pk 	struct xy_iorq *iorq;
1.1  pk 	struct xy_iopb *iopb;
1.1  pk 	int     still_trying;
1.1  pk
1.1  pk {
1.1  pk
1.1  pk 	int     error = iorq->lasterror;
1.1  pk
1.1  pk 	printf("%s", (iorq->xy) ? iorq->xy->sc_dev.dv_xname
1.1  pk 	    : iorq->xyc->sc_dev.dv_xname);
1.1  pk 	if (iorq->buf)
1.1  pk 		printf("%c: ", 'a' + DISKPART(iorq->buf->b_dev));
1.1  pk 	if (iopb->com == XYCMD_RD || iopb->com == XYCMD_WR)
1.1  pk 		printf("%s %d/%d/%d: ",
1.1  pk 			(iopb->com == XYCMD_RD) ? "read" : "write",
1.1  pk 			iopb->cyl, iopb->head, iopb->sect);
1.1  pk 	printf("%s", xyc_e2str(error));
1.1  pk
1.1  pk 	if (still_trying)
1.1  pk 		printf(" [still trying, new error=%s]", xyc_e2str(iorq->errno));
1.1  pk 	else
1.1  pk 		if (iorq->errno == 0)
1.1  pk 			printf(" [recovered in %d tries]", iorq->tries);
1.1  pk
1.1  pk 	printf("\n");
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_error: non-fatal error encountered... recover.
1.1  pk  * return AOK if resubmitted, return FAIL if this iopb is done
1.1  pk  */
1.1  pk int
1.1  pk xyc_error(xycsc, iorq, iopb, comm)
1.1  pk 	struct xyc_softc *xycsc;
1.1  pk 	struct xy_iorq *iorq;
1.1  pk 	struct xy_iopb *iopb;
1.1  pk 	int     comm;
1.1  pk
1.1  pk {
1.1  pk 	int     errno = iorq->errno;
1.1  pk 	int     erract = xyc_entoact(errno);
1.1  pk 	int     oldmode, advance, i;
1.1  pk
1.1  pk 	if (erract == XY_ERA_RSET) {	/* some errors require a reset */
1.1  pk 		oldmode = iorq->mode;
1.1  pk 		iorq->mode = XY_SUB_DONE | (~XY_SUB_MASK & oldmode);
1.1  pk 		/* make xyc_start ignore us */
1.1  pk 		xyc_reset(xycsc, 1, XY_RSET_NONE, errno, iorq->xy);
1.1  pk 		iorq->mode = oldmode;
1.1  pk 	}
1.1  pk 	/* check for read/write to a sector in bad144 table if bad: redirect
1.1  pk 	 * request to bad144 area */
1.1  pk
1.1  pk 	if ((comm == XYCMD_RD || comm == XYCMD_WR) &&
1.1  pk 	    (iorq->mode & XY_MODE_B144) == 0) {
1.1  pk 		advance = iorq->sectcnt - iopb->scnt;
1.1  pk 		XYC_ADVANCE(iorq, advance);
1.1  pk 		if ((i = isbad(&iorq->xy->dkb, iorq->blockno / iorq->xy->sectpercyl,
1.1  pk 			    (iorq->blockno / iorq->xy->nsect) % iorq->xy->nhead,
1.1  pk 			    iorq->blockno % iorq->xy->nsect)) != -1) {
1.1  pk 			iorq->mode |= XY_MODE_B144;	/* enter bad144 mode &
1.1  pk 							 * redirect */
1.1  pk 			iopb->errno = iopb->done = iopb->errs = 0;
1.1  pk 			iopb->scnt = 1;
1.1  pk 			iopb->cyl = (iorq->xy->ncyl + iorq->xy->acyl) - 2;
1.1  pk 			/* second to last acyl */
1.1  pk 			i = iorq->xy->sectpercyl - 1 - i;	/* follow bad144
1.1  pk 								 * standard */
1.1  pk 			iopb->head = i / iorq->xy->nhead;
1.1  pk 			iopb->sect = i % iorq->xy->nhead;
1.1  pk 			/* will resubmit when we come out of remove_iorq */
1.1  pk 			return (XY_ERR_AOK);	/* recovered! */
1.1  pk 		}
1.1  pk 	}
1.1  pk
1.1  pk 	/*
1.1  pk 	 * it isn't a bad144 sector, must be real error! see if we can retry
1.1  pk 	 * it?
1.1  pk 	 */
1.1  pk 	if ((iorq->mode & XY_MODE_VERBO) && iorq->lasterror)
1.1  pk 		xyc_perror(iorq, iopb, 1);	/* inform of error state
1.1  pk 						 * change */
1.1  pk 	iorq->lasterror = errno;
1.1  pk
1.1  pk 	if ((erract == XY_ERA_RSET || erract == XY_ERA_HARD)
1.1  pk 	    && iorq->tries < XYC_MAXTRIES) {	/* retry? */
1.1  pk 		iorq->tries++;
1.1  pk 		iorq->errno = iopb->errno = iopb->done = iopb->errs = 0;
1.1  pk 		/* will resubmit at end of remove_iorq */
1.1  pk 		return (XY_ERR_AOK);	/* recovered! */
1.1  pk 	}
1.1  pk
1.1  pk 	/* failed to recover from this error */
1.1  pk 	return (XY_ERR_FAIL);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_tick: make sure xy is still alive and ticking (err, kicking).
1.1  pk  */
1.1  pk void
1.1  pk xyc_tick(arg)
1.1  pk 	void   *arg;
1.1  pk
1.1  pk {
1.1  pk 	struct xyc_softc *xycsc = arg;
1.1  pk 	int     lcv, s, reset = 0;
1.1  pk
1.1  pk 	/* reduce ttl for each request if one goes to zero, reset xyc */
1.1  pk 	s = splbio();
1.1  pk 	for (lcv = 0; lcv < XYC_MAXIOPB; lcv++) {
1.1  pk 		if (xycsc->reqs[lcv].mode == 0 ||
1.1  pk 		    XY_STATE(xycsc->reqs[lcv].mode) == XY_SUB_DONE)
1.1  pk 			continue;
1.1  pk 		xycsc->reqs[lcv].ttl--;
1.1  pk 		if (xycsc->reqs[lcv].ttl == 0)
1.1  pk 			reset = 1;
1.1  pk 	}
1.1  pk 	if (reset) {
1.1  pk 		printf("%s: watchdog timeout\n", xycsc->sc_dev.dv_xname);
1.1  pk 		xyc_reset(xycsc, 0, XY_RSET_NONE, XY_ERR_FAIL, NULL);
1.1  pk 	}
1.1  pk 	splx(s);
1.1  pk
1.1  pk 	/* until next time */
1.1  pk
1.1  pk 	timeout(xyc_tick, xycsc, XYC_TICKCNT);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_ioctlcmd: this function provides a user level interface to the
1.1  pk  * controller via ioctl.   this allows "format" programs to be written
1.1  pk  * in user code, and is also useful for some debugging.   we return
1.1  pk  * an error code.   called at user priority.
1.1  pk  *
1.1  pk  * XXX missing a few commands (see the 7053 driver for ideas)
1.1  pk  */
1.1  pk int
1.1  pk xyc_ioctlcmd(xy, dev, xio)
1.1  pk 	struct xy_softc *xy;
1.1  pk 	dev_t   dev;
1.1  pk 	struct xd_iocmd *xio;
1.1  pk
1.1  pk {
1.2  pk 	int     s, rqno, dummy = 0;
1.1  pk 	caddr_t dvmabuf = NULL, buf = NULL;
1.1  pk 	struct xyc_softc *xycsc;
1.2  pk 	int			rseg, error;
1.2  pk 	bus_dma_segment_t	seg;
1.1  pk
1.1  pk 	/* check sanity of requested command */
1.1  pk
1.1  pk 	switch (xio->cmd) {
1.1  pk
1.1  pk 	case XYCMD_NOP:	/* no op: everything should be zero */
1.1  pk 		if (xio->subfn || xio->dptr || xio->dlen ||
1.1  pk 		    xio->block || xio->sectcnt)
1.1  pk 			return (EINVAL);
1.1  pk 		break;
1.1  pk
1.1  pk 	case XYCMD_RD:		/* read / write sectors (up to XD_IOCMD_MAXS) */
1.1  pk 	case XYCMD_WR:
1.1  pk 		if (xio->subfn || xio->sectcnt > XD_IOCMD_MAXS ||
1.1  pk 		    xio->sectcnt * XYFM_BPS != xio->dlen || xio->dptr == NULL)
1.1  pk 			return (EINVAL);
1.1  pk 		break;
1.1  pk
1.1  pk 	case XYCMD_SK:		/* seek: doesn't seem useful to export this */
1.1  pk 		return (EINVAL);
1.1  pk
1.1  pk 		break;
1.1  pk
1.1  pk 	default:
1.1  pk 		return (EINVAL);/* ??? */
1.1  pk 	}
1.1  pk
1.2  pk 	xycsc = xy->parent;
1.2  pk
1.1  pk 	/* create DVMA buffer for request if needed */
1.2  pk 	if (xio->dlen) {
1.2  pk 		error = bus_dmamem_alloc(xycsc->dmatag, xio->dlen, NBPG, 0,
1.2  pk 					 &seg, 1, &rseg, BUS_DMA_WAITOK);
1.2  pk 		if (error) {
1.2  pk 			return (error);
1.2  pk 		}
1.2  pk 		dvmabuf = (caddr_t)seg.ds_addr;
1.1  pk
1.2  pk 		error = bus_dmamem_map(xycsc->dmatag, &seg, rseg, xio->dlen,
1.2  pk 					&buf,
1.2  pk 					BUS_DMA_WAITOK|BUS_DMAMEM_NOSYNC);
1.2  pk 		if (error) {
1.2  pk 			bus_dmamem_free(xycsc->dmatag, &seg, rseg);
1.2  pk 			return (error);
1.2  pk 		}
1.1  pk 		if (xio->cmd == XYCMD_WR) {
1.2  pk 			if ((error = copyin(xio->dptr, buf, xio->dlen)) != 0) {
1.2  pk 				bus_dmamem_unmap(xycsc->dmatag, buf, xio->dlen);
1.2  pk 				bus_dmamem_free(xycsc->dmatag, &seg, rseg);
1.2  pk 				return (error);
1.1  pk 			}
1.1  pk 		}
1.1  pk 	}
1.1  pk 	/* do it! */
1.1  pk
1.2  pk 	error = 0;
1.1  pk 	s = splbio();
1.1  pk 	rqno = xyc_cmd(xycsc, xio->cmd, xio->subfn, xy->xy_drive, xio->block,
1.1  pk 	    xio->sectcnt, dvmabuf, XY_SUB_WAIT);
1.1  pk 	if (rqno == XY_ERR_FAIL) {
1.2  pk 		error = EIO;
1.1  pk 		goto done;
1.1  pk 	}
1.1  pk 	xio->errno = xycsc->ciorq->errno;
1.1  pk 	xio->tries = xycsc->ciorq->tries;
1.1  pk 	XYC_DONE(xycsc, dummy);
1.1  pk
1.1  pk 	if (xio->cmd == XYCMD_RD)
1.2  pk 		error = copyout(buf, xio->dptr, xio->dlen);
1.1  pk
1.1  pk done:
1.1  pk 	splx(s);
1.2  pk 	if (dvmabuf) {
1.2  pk 		bus_dmamem_unmap(xycsc->dmatag, buf, xio->dlen);
1.2  pk 		bus_dmamem_free(xycsc->dmatag, &seg, rseg);
1.2  pk 	}
1.2  pk 	return (error);
1.1  pk }
1.1  pk
1.1  pk /*
1.1  pk  * xyc_e2str: convert error code number into an error string
1.1  pk  */
1.1  pk char *
1.1  pk xyc_e2str(no)
1.1  pk 	int     no;
1.1  pk {
1.1  pk 	switch (no) {
1.1  pk 	case XY_ERR_FAIL:
1.1  pk 		return ("Software fatal error");
1.1  pk 	case XY_ERR_DERR:
1.1  pk 		return ("DOUBLE ERROR");
1.1  pk 	case XY_ERR_AOK:
1.1  pk 		return ("Successful completion");
1.1  pk 	case XY_ERR_IPEN:
1.1  pk 		return("Interrupt pending");
1.1  pk 	case XY_ERR_BCFL:
1.1  pk 		return("Busy conflict");
1.1  pk 	case XY_ERR_TIMO:
1.1  pk 		return("Operation timeout");
1.1  pk 	case XY_ERR_NHDR:
1.1  pk 		return("Header not found");
1.1  pk 	case XY_ERR_HARD:
1.1  pk 		return("Hard ECC error");
1.1  pk 	case XY_ERR_ICYL:
1.1  pk 		return("Illegal cylinder address");
1.1  pk 	case XY_ERR_ISEC:
1.1  pk 		return("Illegal sector address");
1.1  pk 	case XY_ERR_SMAL:
1.1  pk 		return("Last sector too small");
1.1  pk 	case XY_ERR_SACK:
1.1  pk 		return("Slave ACK error (non-existent memory)");
1.1  pk 	case XY_ERR_CHER:
1.1  pk 		return("Cylinder and head/header error");
1.1  pk 	case XY_ERR_SRTR:
1.1  pk 		return("Auto-seek retry successful");
1.1  pk 	case XY_ERR_WPRO:
1.1  pk 		return("Write-protect error");
1.1  pk 	case XY_ERR_UIMP:
1.1  pk 		return("Unimplemented command");
1.1  pk 	case XY_ERR_DNRY:
1.1  pk 		return("Drive not ready");
1.1  pk 	case XY_ERR_SZER:
1.1  pk 		return("Sector count zero");
1.1  pk 	case XY_ERR_DFLT:
1.1  pk 		return("Drive faulted");
1.1  pk 	case XY_ERR_ISSZ:
1.1  pk 		return("Illegal sector size");
1.1  pk 	case XY_ERR_SLTA:
1.1  pk 		return("Self test A");
1.1  pk 	case XY_ERR_SLTB:
1.1  pk 		return("Self test B");
1.1  pk 	case XY_ERR_SLTC:
1.1  pk 		return("Self test C");
1.1  pk 	case XY_ERR_SOFT:
1.1  pk 		return("Soft ECC error");
1.1  pk 	case XY_ERR_SFOK:
1.1  pk 		return("Soft ECC error recovered");
1.1  pk 	case XY_ERR_IHED:
1.1  pk 		return("Illegal head");
1.1  pk 	case XY_ERR_DSEQ:
1.1  pk 		return("Disk sequencer error");
1.1  pk 	case XY_ERR_SEEK:
1.1  pk 		return("Seek error");
1.1  pk 	default:
1.1  pk 		return ("Unknown error");
1.1  pk 	}
1.1  pk }
1.1  pk
1.1  pk int
1.1  pk xyc_entoact(errno)
1.1  pk
1.1  pk int errno;
1.1  pk
1.1  pk {
1.1  pk   switch (errno) {
1.1  pk     case XY_ERR_FAIL:	case XY_ERR_DERR:	case XY_ERR_IPEN:
1.1  pk     case XY_ERR_BCFL:	case XY_ERR_ICYL:	case XY_ERR_ISEC:
1.1  pk     case XY_ERR_UIMP:	case XY_ERR_SZER:	case XY_ERR_ISSZ:
1.1  pk     case XY_ERR_SLTA:	case XY_ERR_SLTB:	case XY_ERR_SLTC:
1.1  pk     case XY_ERR_IHED:	case XY_ERR_SACK:	case XY_ERR_SMAL:
1.1  pk
1.1  pk 	return(XY_ERA_PROG); /* program error ! */
1.1  pk
1.1  pk     case XY_ERR_TIMO:	case XY_ERR_NHDR:	case XY_ERR_HARD:
1.1  pk     case XY_ERR_DNRY:	case XY_ERR_CHER:	case XY_ERR_SEEK:
1.1  pk     case XY_ERR_SOFT:
1.1  pk
1.1  pk 	return(XY_ERA_HARD); /* hard error, retry */
1.1  pk
1.1  pk     case XY_ERR_DFLT:	case XY_ERR_DSEQ:
1.1  pk
1.1  pk 	return(XY_ERA_RSET); /* hard error reset */
1.1  pk
1.1  pk     case XY_ERR_SRTR:	case XY_ERR_SFOK:	case XY_ERR_AOK:
1.1  pk
1.1  pk 	return(XY_ERA_SOFT); /* an FYI error */
1.1  pk
1.1  pk     case XY_ERR_WPRO:
1.1  pk
1.1  pk 	return(XY_ERA_WPRO); /* write protect */
1.1  pk   }
1.1  pk
1.1  pk   return(XY_ERA_PROG); /* ??? */
1.1  pk }