dev/dkwedge/dk.c

1.144  riastrad /*	$NetBSD: dk.c,v 1.144 2023/04/21 18:31:00 riastradh Exp $	*/
  1.1   thorpej
  1.1   thorpej /*-
 1.27        ad  * Copyright (c) 2004, 2005, 2006, 2007 The NetBSD Foundation, Inc.
  1.1   thorpej  * All rights reserved.
  1.1   thorpej  *
  1.1   thorpej  * This code is derived from software contributed to The NetBSD Foundation
  1.1   thorpej  * by Jason R. Thorpe.
  1.1   thorpej  *
  1.1   thorpej  * Redistribution and use in source and binary forms, with or without
  1.1   thorpej  * modification, are permitted provided that the following conditions
  1.1   thorpej  * are met:
  1.1   thorpej  * 1. Redistributions of source code must retain the above copyright
  1.1   thorpej  *    notice, this list of conditions and the following disclaimer.
  1.1   thorpej  * 2. Redistributions in binary form must reproduce the above copyright
  1.1   thorpej  *    notice, this list of conditions and the following disclaimer in the
  1.1   thorpej  *    documentation and/or other materials provided with the distribution.
  1.1   thorpej  *
  1.1   thorpej  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
  1.1   thorpej  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
  1.1   thorpej  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  1.1   thorpej  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
  1.1   thorpej  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  1.1   thorpej  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  1.1   thorpej  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
  1.1   thorpej  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
  1.1   thorpej  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
  1.1   thorpej  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
  1.1   thorpej  * POSSIBILITY OF SUCH DAMAGE.
  1.1   thorpej  */
  1.1   thorpej
  1.1   thorpej #include <sys/cdefs.h>
1.144  riastrad __KERNEL_RCSID(0, "$NetBSD: dk.c,v 1.144 2023/04/21 18:31:00 riastradh Exp $");
  1.1   thorpej
 1.50     pooka #ifdef _KERNEL_OPT
  1.1   thorpej #include "opt_dkwedge.h"
 1.50     pooka #endif
  1.1   thorpej
  1.1   thorpej #include <sys/param.h>
1.133  riastrad #include <sys/types.h>
1.133  riastrad
  1.5      yamt #include <sys/buf.h>
  1.5      yamt #include <sys/bufq.h>
1.133  riastrad #include <sys/callout.h>
  1.1   thorpej #include <sys/conf.h>
1.133  riastrad #include <sys/device.h>
1.133  riastrad #include <sys/disk.h>
1.133  riastrad #include <sys/disklabel.h>
1.133  riastrad #include <sys/errno.h>
1.133  riastrad #include <sys/fcntl.h>
1.133  riastrad #include <sys/ioctl.h>
1.133  riastrad #include <sys/kauth.h>
  1.1   thorpej #include <sys/kernel.h>
  1.1   thorpej #include <sys/malloc.h>
1.133  riastrad #include <sys/pool.h>
1.133  riastrad #include <sys/proc.h>
1.134  riastrad #include <sys/rwlock.h>
1.133  riastrad #include <sys/stat.h>
1.133  riastrad #include <sys/systm.h>
1.133  riastrad #include <sys/vnode.h>
  1.1   thorpej
  1.1   thorpej #include <miscfs/specfs/specdev.h>
  1.1   thorpej
  1.1   thorpej MALLOC_DEFINE(M_DKWEDGE, "dkwedge", "Disk wedge structures");
  1.1   thorpej
  1.1   thorpej typedef enum {
  1.1   thorpej 	DKW_STATE_LARVAL	= 0,
  1.1   thorpej 	DKW_STATE_RUNNING	= 1,
  1.1   thorpej 	DKW_STATE_DYING		= 2,
  1.1   thorpej 	DKW_STATE_DEAD		= 666
  1.1   thorpej } dkwedge_state_t;
  1.1   thorpej
  1.1   thorpej struct dkwedge_softc {
 1.65       chs 	device_t	sc_dev;	/* pointer to our pseudo-device */
  1.2   thorpej 	struct cfdata	sc_cfdata;	/* our cfdata structure */
  1.1   thorpej 	uint8_t		sc_wname[128];	/* wedge name (Unicode, UTF-8) */
  1.1   thorpej
  1.1   thorpej 	dkwedge_state_t sc_state;	/* state this wedge is in */
  1.1   thorpej
  1.1   thorpej 	struct disk	*sc_parent;	/* parent disk */
  1.1   thorpej 	daddr_t		sc_offset;	/* LBA offset of wedge in parent */
1.135  riastrad 	krwlock_t	sc_sizelock;
  1.1   thorpej 	uint64_t	sc_size;	/* size of wedge in blocks */
  1.1   thorpej 	char		sc_ptype[32];	/* partition type */
  1.1   thorpej 	dev_t		sc_pdev;	/* cached parent's dev_t */
  1.1   thorpej 					/* link on parent's wedge list */
  1.1   thorpej 	LIST_ENTRY(dkwedge_softc) sc_plink;
  1.1   thorpej
  1.1   thorpej 	struct disk	sc_dk;		/* our own disk structure */
  1.9      yamt 	struct bufq_state *sc_bufq;	/* buffer queue */
  1.1   thorpej 	struct callout	sc_restart_ch;	/* callout to restart I/O */
  1.1   thorpej
 1.92   mlelstv 	kmutex_t	sc_iolock;
 1.92   mlelstv 	kcondvar_t	sc_dkdrn;
  1.1   thorpej 	u_int		sc_iopend;	/* I/Os pending */
1.142  riastrad 	bool		sc_iostop;	/* don't schedule restart */
1.103   mlelstv 	int		sc_mode;	/* parent open mode */
  1.1   thorpej };
  1.1   thorpej
1.136  riastrad static int	dkwedge_match(device_t, cfdata_t, void *);
1.136  riastrad static void	dkwedge_attach(device_t, device_t, void *);
1.136  riastrad static int	dkwedge_detach(device_t, int);
1.136  riastrad
  1.1   thorpej static void	dkstart(struct dkwedge_softc *);
  1.1   thorpej static void	dkiodone(struct buf *);
  1.1   thorpej static void	dkrestart(void *);
 1.52  jakllsch static void	dkminphys(struct buf *);
  1.1   thorpej
1.118  riastrad static int	dkfirstopen(struct dkwedge_softc *, int);
1.121  riastrad static void	dklastclose(struct dkwedge_softc *);
 1.47    dyoung static int	dkwedge_detach(device_t, int);
 1.74   mlelstv static void	dkwedge_delall1(struct disk *, bool);
 1.74   mlelstv static int	dkwedge_del1(struct dkwedge_info *, int);
 1.87   mlelstv static int	dk_open_parent(dev_t, int, struct vnode **);
 1.82   mlelstv static int	dk_close_parent(struct vnode *, int);
 1.46    dyoung
1.144  riastrad static int	dkunit(dev_t);
1.144  riastrad
  1.1   thorpej static dev_type_open(dkopen);
  1.1   thorpej static dev_type_close(dkclose);
1.141  riastrad static dev_type_cancel(dkcancel);
  1.1   thorpej static dev_type_read(dkread);
  1.1   thorpej static dev_type_write(dkwrite);
  1.1   thorpej static dev_type_ioctl(dkioctl);
  1.1   thorpej static dev_type_strategy(dkstrategy);
  1.1   thorpej static dev_type_dump(dkdump);
  1.1   thorpej static dev_type_size(dksize);
 1.72  dholland static dev_type_discard(dkdiscard);
  1.1   thorpej
1.136  riastrad CFDRIVER_DECL(dk, DV_DISK, NULL);
1.136  riastrad CFATTACH_DECL3_NEW(dk, 0,
1.136  riastrad     dkwedge_match, dkwedge_attach, dkwedge_detach, NULL, NULL, NULL,
1.136  riastrad     DVF_DETACH_SHUTDOWN);
1.136  riastrad
  1.1   thorpej const struct bdevsw dk_bdevsw = {
 1.68  dholland 	.d_open = dkopen,
 1.68  dholland 	.d_close = dkclose,
1.141  riastrad 	.d_cancel = dkcancel,
 1.68  dholland 	.d_strategy = dkstrategy,
 1.68  dholland 	.d_ioctl = dkioctl,
 1.68  dholland 	.d_dump = dkdump,
 1.68  dholland 	.d_psize = dksize,
 1.72  dholland 	.d_discard = dkdiscard,
1.144  riastrad 	.d_cfdriver = &dk_cd,
1.144  riastrad 	.d_devtounit = dkunit,
 1.92   mlelstv 	.d_flag = D_DISK | D_MPSAFE
  1.1   thorpej };
  1.1   thorpej
  1.1   thorpej const struct cdevsw dk_cdevsw = {
 1.68  dholland 	.d_open = dkopen,
 1.68  dholland 	.d_close = dkclose,
1.141  riastrad 	.d_cancel = dkcancel,
 1.68  dholland 	.d_read = dkread,
 1.68  dholland 	.d_write = dkwrite,
 1.68  dholland 	.d_ioctl = dkioctl,
 1.68  dholland 	.d_stop = nostop,
 1.68  dholland 	.d_tty = notty,
 1.68  dholland 	.d_poll = nopoll,
 1.68  dholland 	.d_mmap = nommap,
 1.68  dholland 	.d_kqfilter = nokqfilter,
 1.72  dholland 	.d_discard = dkdiscard,
1.144  riastrad 	.d_cfdriver = &dk_cd,
1.144  riastrad 	.d_devtounit = dkunit,
 1.92   mlelstv 	.d_flag = D_DISK | D_MPSAFE
  1.1   thorpej };
  1.1   thorpej
  1.1   thorpej static struct dkwedge_softc **dkwedges;
  1.1   thorpej static u_int ndkwedges;
 1.27        ad static krwlock_t dkwedges_lock;
  1.1   thorpej
  1.1   thorpej static LIST_HEAD(, dkwedge_discovery_method) dkwedge_discovery_methods;
 1.27        ad static krwlock_t dkwedge_discovery_methods_lock;
  1.1   thorpej
  1.1   thorpej /*
  1.2   thorpej  * dkwedge_match:
  1.2   thorpej  *
  1.2   thorpej  *	Autoconfiguration match function for pseudo-device glue.
  1.2   thorpej  */
  1.2   thorpej static int
1.129  riastrad dkwedge_match(device_t parent, cfdata_t match, void *aux)
  1.2   thorpej {
  1.2   thorpej
  1.2   thorpej 	/* Pseudo-device; always present. */
1.128  riastrad 	return 1;
  1.2   thorpej }
  1.2   thorpej
  1.2   thorpej /*
  1.2   thorpej  * dkwedge_attach:
  1.2   thorpej  *
  1.2   thorpej  *	Autoconfiguration attach function for pseudo-device glue.
  1.2   thorpej  */
  1.2   thorpej static void
1.129  riastrad dkwedge_attach(device_t parent, device_t self, void *aux)
  1.2   thorpej {
  1.2   thorpej
 1.31  jmcneill 	if (!pmf_device_register(self, NULL, NULL))
 1.31  jmcneill 		aprint_error_dev(self, "couldn't establish power handler\n");
  1.2   thorpej }
  1.2   thorpej
  1.2   thorpej /*
  1.1   thorpej  * dkwedge_wait_drain:
  1.1   thorpej  *
  1.1   thorpej  *	Wait for I/O on the wedge to drain.
  1.1   thorpej  */
  1.1   thorpej static void
  1.1   thorpej dkwedge_wait_drain(struct dkwedge_softc *sc)
  1.1   thorpej {
  1.1   thorpej
 1.92   mlelstv 	mutex_enter(&sc->sc_iolock);
1.110  riastrad 	while (sc->sc_iopend != 0)
 1.92   mlelstv 		cv_wait(&sc->sc_dkdrn, &sc->sc_iolock);
 1.92   mlelstv 	mutex_exit(&sc->sc_iolock);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_compute_pdev:
  1.1   thorpej  *
  1.1   thorpej  *	Compute the parent disk's dev_t.
  1.1   thorpej  */
  1.1   thorpej static int
 1.74   mlelstv dkwedge_compute_pdev(const char *pname, dev_t *pdevp, enum vtype type)
  1.1   thorpej {
  1.1   thorpej 	const char *name, *cp;
 1.63  drochner 	devmajor_t pmaj;
 1.63  drochner 	int punit;
  1.1   thorpej 	char devname[16];
  1.1   thorpej
  1.1   thorpej 	name = pname;
 1.74   mlelstv 	switch (type) {
 1.74   mlelstv 	case VBLK:
 1.74   mlelstv 		pmaj = devsw_name2blk(name, devname, sizeof(devname));
 1.74   mlelstv 		break;
 1.74   mlelstv 	case VCHR:
 1.74   mlelstv 		pmaj = devsw_name2chr(name, devname, sizeof(devname));
 1.74   mlelstv 		break;
 1.74   mlelstv 	default:
 1.75   mlelstv 		pmaj = NODEVMAJOR;
 1.74   mlelstv 		break;
 1.74   mlelstv 	}
 1.75   mlelstv 	if (pmaj == NODEVMAJOR)
1.132  riastrad 		return ENXIO;
  1.6     perry
  1.1   thorpej 	name += strlen(devname);
  1.1   thorpej 	for (cp = name, punit = 0; *cp >= '0' && *cp <= '9'; cp++)
  1.1   thorpej 		punit = (punit * 10) + (*cp - '0');
  1.1   thorpej 	if (cp == name) {
  1.1   thorpej 		/* Invalid parent disk name. */
1.132  riastrad 		return ENXIO;
  1.1   thorpej 	}
  1.1   thorpej
  1.1   thorpej 	*pdevp = MAKEDISKDEV(pmaj, punit, RAW_PART);
  1.1   thorpej
1.128  riastrad 	return 0;
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_array_expand:
  1.1   thorpej  *
  1.1   thorpej  *	Expand the dkwedges array.
1.127  riastrad  *
1.127  riastrad  *	Releases and reacquires dkwedges_lock as a writer.
  1.1   thorpej  */
1.127  riastrad static int
  1.1   thorpej dkwedge_array_expand(void)
  1.1   thorpej {
  1.1   thorpej
1.127  riastrad 	const unsigned incr = 16;
1.127  riastrad 	unsigned newcnt, oldcnt;
1.127  riastrad 	struct dkwedge_softc **newarray = NULL, **oldarray = NULL;
1.127  riastrad
1.127  riastrad 	KASSERT(rw_write_held(&dkwedges_lock));
1.127  riastrad
1.127  riastrad 	oldcnt = ndkwedges;
1.127  riastrad 	oldarray = dkwedges;
1.127  riastrad
1.127  riastrad 	if (oldcnt >= INT_MAX - incr)
1.127  riastrad 		return ENFILE;	/* XXX */
1.127  riastrad 	newcnt = oldcnt + incr;
1.127  riastrad
1.127  riastrad 	rw_exit(&dkwedges_lock);
  1.1   thorpej 	newarray = malloc(newcnt * sizeof(*newarray), M_DKWEDGE,
  1.1   thorpej 	    M_WAITOK|M_ZERO);
1.127  riastrad 	rw_enter(&dkwedges_lock, RW_WRITER);
1.127  riastrad
1.127  riastrad 	if (ndkwedges != oldcnt || dkwedges != oldarray) {
1.127  riastrad 		oldarray = NULL; /* already recycled */
1.127  riastrad 		goto out;
1.127  riastrad 	}
1.127  riastrad
1.127  riastrad 	if (oldarray != NULL)
  1.1   thorpej 		memcpy(newarray, dkwedges, ndkwedges * sizeof(*newarray));
  1.1   thorpej 	dkwedges = newarray;
1.127  riastrad 	newarray = NULL;	/* transferred to dkwedges */
  1.1   thorpej 	ndkwedges = newcnt;
1.127  riastrad
1.127  riastrad out:	rw_exit(&dkwedges_lock);
  1.1   thorpej 	if (oldarray != NULL)
  1.1   thorpej 		free(oldarray, M_DKWEDGE);
1.127  riastrad 	if (newarray != NULL)
1.127  riastrad 		free(newarray, M_DKWEDGE);
1.127  riastrad 	rw_enter(&dkwedges_lock, RW_WRITER);
1.127  riastrad 	return 0;
  1.1   thorpej }
  1.1   thorpej
 1.48      haad static void
1.135  riastrad dkwedge_size_init(struct dkwedge_softc *sc, uint64_t size)
1.135  riastrad {
1.135  riastrad
1.135  riastrad 	rw_init(&sc->sc_sizelock);
1.135  riastrad 	sc->sc_size = size;
1.135  riastrad }
1.135  riastrad
1.135  riastrad static void
1.135  riastrad dkwedge_size_fini(struct dkwedge_softc *sc)
1.135  riastrad {
1.135  riastrad
1.135  riastrad 	rw_destroy(&sc->sc_sizelock);
1.135  riastrad }
1.135  riastrad
1.135  riastrad static uint64_t
1.135  riastrad dkwedge_size(struct dkwedge_softc *sc)
1.135  riastrad {
1.135  riastrad 	uint64_t size;
1.135  riastrad
1.135  riastrad 	rw_enter(&sc->sc_sizelock, RW_READER);
1.135  riastrad 	size = sc->sc_size;
1.135  riastrad 	rw_exit(&sc->sc_sizelock);
1.135  riastrad
1.135  riastrad 	return size;
1.135  riastrad }
1.135  riastrad
1.135  riastrad static void
1.135  riastrad dkwedge_size_increase(struct dkwedge_softc *sc, uint64_t size)
1.135  riastrad {
1.135  riastrad
1.135  riastrad 	KASSERT(mutex_owned(&sc->sc_dk.dk_openlock));
1.135  riastrad
1.135  riastrad 	rw_enter(&sc->sc_sizelock, RW_WRITER);
1.135  riastrad 	KASSERTMSG(size >= sc->sc_size,
1.135  riastrad 	    "decreasing dkwedge size from %"PRIu64" to %"PRIu64,
1.135  riastrad 	    sc->sc_size, size);
1.135  riastrad 	sc->sc_size = size;
1.135  riastrad 	rw_exit(&sc->sc_sizelock);
1.135  riastrad }
1.135  riastrad
1.135  riastrad static void
 1.77   mlelstv dk_set_geometry(struct dkwedge_softc *sc, struct disk *pdk)
 1.48      haad {
 1.77   mlelstv 	struct disk *dk = &sc->sc_dk;
 1.77   mlelstv 	struct disk_geom *dg = &dk->dk_geom;
 1.48      haad
1.140  riastrad 	KASSERT(mutex_owned(&pdk->dk_openlock));
1.140  riastrad
 1.66  christos 	memset(dg, 0, sizeof(*dg));
 1.48      haad
1.135  riastrad 	dg->dg_secperunit = dkwedge_size(sc);
 1.77   mlelstv 	dg->dg_secsize = DEV_BSIZE << pdk->dk_blkshift;
 1.76   mlelstv
 1.76   mlelstv 	/* fake numbers, 1 cylinder is 1 MB with default sector size */
 1.66  christos 	dg->dg_nsectors = 32;
 1.66  christos 	dg->dg_ntracks = 64;
1.129  riastrad 	dg->dg_ncylinders =
1.129  riastrad 	    dg->dg_secperunit / (dg->dg_nsectors * dg->dg_ntracks);
 1.48      haad
 1.77   mlelstv 	disk_set_info(sc->sc_dev, dk, NULL);
 1.48      haad }
 1.48      haad
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_add:		[exported function]
  1.1   thorpej  *
  1.1   thorpej  *	Add a disk wedge based on the provided information.
  1.1   thorpej  *
  1.1   thorpej  *	The incoming dkw_devname[] is ignored, instead being
  1.1   thorpej  *	filled in and returned to the caller.
  1.1   thorpej  */
  1.1   thorpej int
  1.1   thorpej dkwedge_add(struct dkwedge_info *dkw)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc, *lsc;
  1.1   thorpej 	struct disk *pdk;
  1.1   thorpej 	u_int unit;
  1.1   thorpej 	int error;
  1.1   thorpej 	dev_t pdev;
  1.1   thorpej
  1.1   thorpej 	dkw->dkw_parent[sizeof(dkw->dkw_parent) - 1] = '\0';
  1.1   thorpej 	pdk = disk_find(dkw->dkw_parent);
  1.1   thorpej 	if (pdk == NULL)
1.132  riastrad 		return ENXIO;
  1.1   thorpej
 1.74   mlelstv 	error = dkwedge_compute_pdev(pdk->dk_name, &pdev, VBLK);
  1.1   thorpej 	if (error)
1.128  riastrad 		return error;
  1.1   thorpej
  1.1   thorpej 	if (dkw->dkw_offset < 0)
1.128  riastrad 		return EINVAL;
  1.1   thorpej
1.101  jmcneill 	/*
1.101  jmcneill 	 * Check for an existing wedge at the same disk offset. Allow
1.101  jmcneill 	 * updating a wedge if the only change is the size, and the new
1.101  jmcneill 	 * size is larger than the old.
1.101  jmcneill 	 */
1.101  jmcneill 	sc = NULL;
1.101  jmcneill 	mutex_enter(&pdk->dk_openlock);
1.101  jmcneill 	LIST_FOREACH(lsc, &pdk->dk_wedges, sc_plink) {
1.101  jmcneill 		if (lsc->sc_offset != dkw->dkw_offset)
1.101  jmcneill 			continue;
1.101  jmcneill 		if (strcmp(lsc->sc_wname, dkw->dkw_wname) != 0)
1.101  jmcneill 			break;
1.101  jmcneill 		if (strcmp(lsc->sc_ptype, dkw->dkw_ptype) != 0)
1.101  jmcneill 			break;
1.135  riastrad 		if (dkwedge_size(lsc) > dkw->dkw_size)
1.101  jmcneill 			break;
1.101  jmcneill
1.101  jmcneill 		sc = lsc;
1.135  riastrad 		dkwedge_size_increase(sc, dkw->dkw_size);
1.101  jmcneill 		dk_set_geometry(sc, pdk);
1.101  jmcneill
1.101  jmcneill 		break;
1.101  jmcneill 	}
1.101  jmcneill 	mutex_exit(&pdk->dk_openlock);
1.101  jmcneill
1.101  jmcneill 	if (sc != NULL)
1.101  jmcneill 		goto announce;
1.101  jmcneill
  1.1   thorpej 	sc = malloc(sizeof(*sc), M_DKWEDGE, M_WAITOK|M_ZERO);
  1.1   thorpej 	sc->sc_state = DKW_STATE_LARVAL;
  1.1   thorpej 	sc->sc_parent = pdk;
  1.1   thorpej 	sc->sc_pdev = pdev;
  1.1   thorpej 	sc->sc_offset = dkw->dkw_offset;
1.135  riastrad 	dkwedge_size_init(sc, dkw->dkw_size);
  1.1   thorpej
  1.1   thorpej 	memcpy(sc->sc_wname, dkw->dkw_wname, sizeof(sc->sc_wname));
  1.1   thorpej 	sc->sc_wname[sizeof(sc->sc_wname) - 1] = '\0';
  1.1   thorpej
  1.1   thorpej 	memcpy(sc->sc_ptype, dkw->dkw_ptype, sizeof(sc->sc_ptype));
  1.1   thorpej 	sc->sc_ptype[sizeof(sc->sc_ptype) - 1] = '\0';
  1.1   thorpej
  1.9      yamt 	bufq_alloc(&sc->sc_bufq, "fcfs", 0);
  1.1   thorpej
 1.26        ad 	callout_init(&sc->sc_restart_ch, 0);
  1.1   thorpej 	callout_setfunc(&sc->sc_restart_ch, dkrestart, sc);
  1.1   thorpej
 1.92   mlelstv 	mutex_init(&sc->sc_iolock, MUTEX_DEFAULT, IPL_BIO);
 1.92   mlelstv 	cv_init(&sc->sc_dkdrn, "dkdrn");
 1.92   mlelstv
  1.1   thorpej 	/*
  1.1   thorpej 	 * Wedge will be added; increment the wedge count for the parent.
1.107    andvar 	 * Only allow this to happen if RAW_PART is the only thing open.
  1.1   thorpej 	 */
 1.27        ad 	mutex_enter(&pdk->dk_openlock);
  1.1   thorpej 	if (pdk->dk_openmask & ~(1 << RAW_PART))
  1.1   thorpej 		error = EBUSY;
  1.1   thorpej 	else {
  1.1   thorpej 		/* Check for wedge overlap. */
  1.1   thorpej 		LIST_FOREACH(lsc, &pdk->dk_wedges, sc_plink) {
1.135  riastrad 			/* XXX arithmetic overflow */
1.135  riastrad 			uint64_t size = dkwedge_size(sc);
1.135  riastrad 			uint64_t lsize = dkwedge_size(lsc);
1.135  riastrad 			daddr_t lastblk = sc->sc_offset + size - 1;
1.135  riastrad 			daddr_t llastblk = lsc->sc_offset + lsize - 1;
  1.1   thorpej
  1.1   thorpej 			if (sc->sc_offset >= lsc->sc_offset &&
  1.1   thorpej 			    sc->sc_offset <= llastblk) {
 1.63  drochner 				/* Overlaps the tail of the existing wedge. */
  1.1   thorpej 				break;
  1.1   thorpej 			}
  1.1   thorpej 			if (lastblk >= lsc->sc_offset &&
  1.1   thorpej 			    lastblk <= llastblk) {
  1.1   thorpej 				/* Overlaps the head of the existing wedge. */
  1.1   thorpej 			    	break;
  1.1   thorpej 			}
  1.1   thorpej 		}
 1.74   mlelstv 		if (lsc != NULL) {
 1.74   mlelstv 			if (sc->sc_offset == lsc->sc_offset &&
1.135  riastrad 			    dkwedge_size(sc) == dkwedge_size(lsc) &&
 1.74   mlelstv 			    strcmp(sc->sc_wname, lsc->sc_wname) == 0)
 1.74   mlelstv 				error = EEXIST;
 1.74   mlelstv 			else
 1.74   mlelstv 				error = EINVAL;
 1.74   mlelstv 		} else {
  1.1   thorpej 			pdk->dk_nwedges++;
  1.1   thorpej 			LIST_INSERT_HEAD(&pdk->dk_wedges, sc, sc_plink);
  1.1   thorpej 		}
  1.1   thorpej 	}
 1.27        ad 	mutex_exit(&pdk->dk_openlock);
  1.1   thorpej 	if (error) {
 1.93   mlelstv 		cv_destroy(&sc->sc_dkdrn);
 1.93   mlelstv 		mutex_destroy(&sc->sc_iolock);
  1.9      yamt 		bufq_free(sc->sc_bufq);
1.135  riastrad 		dkwedge_size_fini(sc);
  1.1   thorpej 		free(sc, M_DKWEDGE);
1.128  riastrad 		return error;
  1.1   thorpej 	}
  1.1   thorpej
  1.2   thorpej 	/* Fill in our cfdata for the pseudo-device glue. */
  1.2   thorpej 	sc->sc_cfdata.cf_name = dk_cd.cd_name;
  1.2   thorpej 	sc->sc_cfdata.cf_atname = dk_ca.ca_name;
  1.2   thorpej 	/* sc->sc_cfdata.cf_unit set below */
  1.8   nathanw 	sc->sc_cfdata.cf_fstate = FSTATE_STAR;
  1.2   thorpej
  1.1   thorpej 	/* Insert the larval wedge into the array. */
 1.27        ad 	rw_enter(&dkwedges_lock, RW_WRITER);
  1.1   thorpej 	for (error = 0;;) {
  1.1   thorpej 		struct dkwedge_softc **scpp;
  1.1   thorpej
  1.1   thorpej 		/*
  1.1   thorpej 		 * Check for a duplicate wname while searching for
  1.1   thorpej 		 * a slot.
  1.1   thorpej 		 */
  1.1   thorpej 		for (scpp = NULL, unit = 0; unit < ndkwedges; unit++) {
  1.1   thorpej 			if (dkwedges[unit] == NULL) {
  1.1   thorpej 				if (scpp == NULL) {
  1.1   thorpej 					scpp = &dkwedges[unit];
  1.2   thorpej 					sc->sc_cfdata.cf_unit = unit;
  1.1   thorpej 				}
  1.1   thorpej 			} else {
  1.1   thorpej 				/* XXX Unicode. */
  1.1   thorpej 				if (strcmp(dkwedges[unit]->sc_wname,
1.129  riastrad 					sc->sc_wname) == 0) {
  1.1   thorpej 					error = EEXIST;
  1.1   thorpej 					break;
  1.1   thorpej 				}
  1.1   thorpej 			}
  1.1   thorpej 		}
  1.1   thorpej 		if (error)
  1.1   thorpej 			break;
  1.1   thorpej 		KASSERT(unit == ndkwedges);
1.127  riastrad 		if (scpp == NULL) {
1.127  riastrad 			error = dkwedge_array_expand();
1.127  riastrad 			if (error)
1.127  riastrad 				break;
1.127  riastrad 		} else {
  1.2   thorpej 			KASSERT(scpp == &dkwedges[sc->sc_cfdata.cf_unit]);
  1.1   thorpej 			*scpp = sc;
  1.1   thorpej 			break;
  1.1   thorpej 		}
  1.1   thorpej 	}
 1.27        ad 	rw_exit(&dkwedges_lock);
  1.1   thorpej 	if (error) {
 1.27        ad 		mutex_enter(&pdk->dk_openlock);
  1.1   thorpej 		pdk->dk_nwedges--;
  1.1   thorpej 		LIST_REMOVE(sc, sc_plink);
 1.27        ad 		mutex_exit(&pdk->dk_openlock);
  1.1   thorpej
 1.93   mlelstv 		cv_destroy(&sc->sc_dkdrn);
 1.93   mlelstv 		mutex_destroy(&sc->sc_iolock);
  1.9      yamt 		bufq_free(sc->sc_bufq);
1.135  riastrad 		dkwedge_size_fini(sc);
  1.1   thorpej 		free(sc, M_DKWEDGE);
1.128  riastrad 		return error;
  1.1   thorpej 	}
  1.1   thorpej
  1.2   thorpej 	/*
  1.2   thorpej 	 * Now that we know the unit #, attach a pseudo-device for
  1.2   thorpej 	 * this wedge instance.  This will provide us with the
 1.65       chs 	 * device_t necessary for glue to other parts of the system.
  1.2   thorpej 	 *
  1.2   thorpej 	 * This should never fail, unless we're almost totally out of
  1.2   thorpej 	 * memory.
  1.2   thorpej 	 */
  1.2   thorpej 	if ((sc->sc_dev = config_attach_pseudo(&sc->sc_cfdata)) == NULL) {
  1.2   thorpej 		aprint_error("%s%u: unable to attach pseudo-device\n",
  1.2   thorpej 		    sc->sc_cfdata.cf_name, sc->sc_cfdata.cf_unit);
  1.2   thorpej
 1.27        ad 		rw_enter(&dkwedges_lock, RW_WRITER);
1.139  riastrad 		KASSERT(dkwedges[sc->sc_cfdata.cf_unit] == sc);
  1.2   thorpej 		dkwedges[sc->sc_cfdata.cf_unit] = NULL;
 1.27        ad 		rw_exit(&dkwedges_lock);
  1.2   thorpej
 1.27        ad 		mutex_enter(&pdk->dk_openlock);
  1.2   thorpej 		pdk->dk_nwedges--;
  1.2   thorpej 		LIST_REMOVE(sc, sc_plink);
 1.27        ad 		mutex_exit(&pdk->dk_openlock);
  1.2   thorpej
 1.93   mlelstv 		cv_destroy(&sc->sc_dkdrn);
 1.93   mlelstv 		mutex_destroy(&sc->sc_iolock);
  1.9      yamt 		bufq_free(sc->sc_bufq);
1.135  riastrad 		dkwedge_size_fini(sc);
  1.2   thorpej 		free(sc, M_DKWEDGE);
1.128  riastrad 		return ENOMEM;
  1.2   thorpej 	}
  1.1   thorpej
  1.1   thorpej 	/*
  1.1   thorpej 	 * XXX Really ought to make the disk_attach() and the changing
  1.1   thorpej 	 * of state to RUNNING atomic.
  1.1   thorpej 	 */
  1.1   thorpej
 1.36    cegger 	disk_init(&sc->sc_dk, device_xname(sc->sc_dev), NULL);
1.140  riastrad 	mutex_enter(&pdk->dk_openlock);
 1.77   mlelstv 	dk_set_geometry(sc, pdk);
1.140  riastrad 	mutex_exit(&pdk->dk_openlock);
  1.1   thorpej 	disk_attach(&sc->sc_dk);
  1.1   thorpej
  1.1   thorpej 	/* Disk wedge is ready for use! */
  1.1   thorpej 	sc->sc_state = DKW_STATE_RUNNING;
  1.1   thorpej
1.101  jmcneill announce:
  1.1   thorpej 	/* Announce our arrival. */
 1.84  jmcneill 	aprint_normal(
 1.84  jmcneill 	    "%s at %s: \"%s\", %"PRIu64" blocks at %"PRId64", type: %s\n",
 1.84  jmcneill 	    device_xname(sc->sc_dev), pdk->dk_name,
 1.84  jmcneill 	    sc->sc_wname,	/* XXX Unicode */
1.135  riastrad 	    dkwedge_size(sc), sc->sc_offset,
 1.84  jmcneill 	    sc->sc_ptype[0] == '\0' ? "<unknown>" : sc->sc_ptype);
  1.1   thorpej
1.112    martin 	/* Return the devname to the caller. */
1.112    martin 	strlcpy(dkw->dkw_devname, device_xname(sc->sc_dev),
1.129  riastrad 	    sizeof(dkw->dkw_devname));
1.112    martin
1.128  riastrad 	return 0;
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
 1.47    dyoung  * dkwedge_find:
  1.1   thorpej  *
 1.47    dyoung  *	Lookup a disk wedge based on the provided information.
  1.1   thorpej  *	NOTE: We look up the wedge based on the wedge devname,
  1.1   thorpej  *	not wname.
 1.47    dyoung  *
 1.47    dyoung  *	Return NULL if the wedge is not found, otherwise return
 1.47    dyoung  *	the wedge's softc.  Assign the wedge's unit number to unitp
 1.47    dyoung  *	if unitp is not NULL.
  1.1   thorpej  */
 1.47    dyoung static struct dkwedge_softc *
 1.47    dyoung dkwedge_find(struct dkwedge_info *dkw, u_int *unitp)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = NULL;
  1.1   thorpej 	u_int unit;
  1.1   thorpej
  1.1   thorpej 	/* Find our softc. */
  1.1   thorpej 	dkw->dkw_devname[sizeof(dkw->dkw_devname) - 1] = '\0';
 1.47    dyoung 	rw_enter(&dkwedges_lock, RW_READER);
  1.1   thorpej 	for (unit = 0; unit < ndkwedges; unit++) {
  1.1   thorpej 		if ((sc = dkwedges[unit]) != NULL &&
 1.36    cegger 		    strcmp(device_xname(sc->sc_dev), dkw->dkw_devname) == 0 &&
  1.1   thorpej 		    strcmp(sc->sc_parent->dk_name, dkw->dkw_parent) == 0) {
  1.1   thorpej 			break;
  1.1   thorpej 		}
  1.1   thorpej 	}
 1.27        ad 	rw_exit(&dkwedges_lock);
1.137  riastrad 	if (sc == NULL)
 1.47    dyoung 		return NULL;
 1.47    dyoung
 1.47    dyoung 	if (unitp != NULL)
 1.47    dyoung 		*unitp = unit;
 1.47    dyoung
 1.47    dyoung 	return sc;
 1.47    dyoung }
 1.47    dyoung
 1.47    dyoung /*
 1.47    dyoung  * dkwedge_del:		[exported function]
 1.47    dyoung  *
 1.47    dyoung  *	Delete a disk wedge based on the provided information.
 1.47    dyoung  *	NOTE: We look up the wedge based on the wedge devname,
 1.47    dyoung  *	not wname.
 1.47    dyoung  */
 1.47    dyoung int
 1.47    dyoung dkwedge_del(struct dkwedge_info *dkw)
 1.47    dyoung {
1.129  riastrad
 1.74   mlelstv 	return dkwedge_del1(dkw, 0);
 1.74   mlelstv }
 1.74   mlelstv
 1.74   mlelstv int
 1.74   mlelstv dkwedge_del1(struct dkwedge_info *dkw, int flags)
 1.74   mlelstv {
 1.47    dyoung 	struct dkwedge_softc *sc = NULL;
 1.47    dyoung
 1.47    dyoung 	/* Find our softc. */
 1.47    dyoung 	if ((sc = dkwedge_find(dkw, NULL)) == NULL)
1.128  riastrad 		return ESRCH;
  1.1   thorpej
 1.74   mlelstv 	return config_detach(sc->sc_dev, flags);
 1.47    dyoung }
 1.47    dyoung
 1.47    dyoung /*
 1.47    dyoung  * dkwedge_detach:
 1.47    dyoung  *
 1.47    dyoung  *	Autoconfiguration detach function for pseudo-device glue.
 1.47    dyoung  */
 1.47    dyoung static int
 1.47    dyoung dkwedge_detach(device_t self, int flags)
 1.47    dyoung {
 1.47    dyoung 	struct dkwedge_softc *sc = NULL;
 1.47    dyoung 	u_int unit;
 1.92   mlelstv 	int bmaj, cmaj, rc;
 1.47    dyoung
 1.47    dyoung 	rw_enter(&dkwedges_lock, RW_WRITER);
 1.47    dyoung 	for (unit = 0; unit < ndkwedges; unit++) {
 1.47    dyoung 		if ((sc = dkwedges[unit]) != NULL && sc->sc_dev == self)
 1.47    dyoung 			break;
 1.47    dyoung 	}
 1.47    dyoung 	if (unit == ndkwedges)
 1.47    dyoung 		rc = ENXIO;
1.143  riastrad 	else if ((rc = disk_begindetach(&sc->sc_dk, /*lastclose*/NULL, self,
1.143  riastrad 		    flags)) == 0) {
 1.47    dyoung 		/* Mark the wedge as dying. */
 1.47    dyoung 		sc->sc_state = DKW_STATE_DYING;
 1.47    dyoung 	}
 1.47    dyoung 	rw_exit(&dkwedges_lock);
 1.47    dyoung
 1.47    dyoung 	if (rc != 0)
 1.47    dyoung 		return rc;
 1.47    dyoung
 1.47    dyoung 	pmf_device_deregister(self);
  1.1   thorpej
  1.1   thorpej 	/* Locate the wedge major numbers. */
  1.1   thorpej 	bmaj = bdevsw_lookup_major(&dk_bdevsw);
  1.1   thorpej 	cmaj = cdevsw_lookup_major(&dk_cdevsw);
  1.1   thorpej
  1.1   thorpej 	/* Kill any pending restart. */
1.142  riastrad 	mutex_enter(&sc->sc_iolock);
1.142  riastrad 	sc->sc_iostop = true;
1.142  riastrad 	mutex_exit(&sc->sc_iolock);
1.142  riastrad 	callout_halt(&sc->sc_restart_ch, NULL);
  1.1   thorpej
  1.1   thorpej 	/*
  1.1   thorpej 	 * dkstart() will kill any queued buffers now that the
  1.1   thorpej 	 * state of the wedge is not RUNNING.  Once we've done
  1.1   thorpej 	 * that, wait for any other pending I/O to complete.
  1.1   thorpej 	 */
  1.1   thorpej 	dkstart(sc);
  1.1   thorpej 	dkwedge_wait_drain(sc);
  1.1   thorpej
  1.1   thorpej 	/* Nuke the vnodes for any open instances. */
 1.14   thorpej 	vdevgone(bmaj, unit, unit, VBLK);
 1.14   thorpej 	vdevgone(cmaj, unit, unit, VCHR);
  1.1   thorpej
1.143  riastrad 	/*
1.143  riastrad 	 * At this point, all block device opens have been closed,
1.143  riastrad 	 * synchronously flushing any buffered writes; and all
1.143  riastrad 	 * character device I/O operations have completed
1.143  riastrad 	 * synchronously, and character device opens have been closed.
1.143  riastrad 	 *
1.143  riastrad 	 * So there can be no more opens or queued buffers by now.
1.143  riastrad 	 */
1.143  riastrad 	KASSERT(sc->sc_dk.dk_openmask == 0);
1.143  riastrad 	KASSERT(bufq_peek(sc->sc_bufq) == NULL);
1.143  riastrad 	bufq_drain(sc->sc_bufq);
  1.1   thorpej
  1.1   thorpej 	/* Announce our departure. */
 1.36    cegger 	aprint_normal("%s at %s (%s) deleted\n", device_xname(sc->sc_dev),
  1.1   thorpej 	    sc->sc_parent->dk_name,
  1.1   thorpej 	    sc->sc_wname);	/* XXX Unicode */
  1.1   thorpej
 1.27        ad 	mutex_enter(&sc->sc_parent->dk_openlock);
  1.1   thorpej 	sc->sc_parent->dk_nwedges--;
  1.1   thorpej 	LIST_REMOVE(sc, sc_plink);
 1.27        ad 	mutex_exit(&sc->sc_parent->dk_openlock);
  1.1   thorpej
  1.1   thorpej 	/* Delete our buffer queue. */
  1.9      yamt 	bufq_free(sc->sc_bufq);
  1.1   thorpej
  1.1   thorpej 	/* Detach from the disk list. */
  1.1   thorpej 	disk_detach(&sc->sc_dk);
 1.39    plunky 	disk_destroy(&sc->sc_dk);
  1.1   thorpej
  1.1   thorpej 	/* Poof. */
 1.27        ad 	rw_enter(&dkwedges_lock, RW_WRITER);
1.139  riastrad 	KASSERT(dkwedges[unit] == sc);
  1.1   thorpej 	dkwedges[unit] = NULL;
  1.1   thorpej 	sc->sc_state = DKW_STATE_DEAD;
 1.27        ad 	rw_exit(&dkwedges_lock);
  1.1   thorpej
 1.92   mlelstv 	mutex_destroy(&sc->sc_iolock);
 1.92   mlelstv 	cv_destroy(&sc->sc_dkdrn);
1.135  riastrad 	dkwedge_size_fini(sc);
 1.92   mlelstv
  1.1   thorpej 	free(sc, M_DKWEDGE);
  1.1   thorpej
 1.47    dyoung 	return 0;
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_delall:	[exported function]
  1.1   thorpej  *
  1.1   thorpej  *	Delete all of the wedges on the specified disk.  Used when
  1.1   thorpej  *	a disk is being detached.
  1.1   thorpej  */
  1.1   thorpej void
  1.1   thorpej dkwedge_delall(struct disk *pdk)
  1.1   thorpej {
1.129  riastrad
 1.74   mlelstv 	dkwedge_delall1(pdk, false);
 1.74   mlelstv }
 1.74   mlelstv
 1.74   mlelstv static void
 1.74   mlelstv dkwedge_delall1(struct disk *pdk, bool idleonly)
 1.74   mlelstv {
  1.1   thorpej 	struct dkwedge_info dkw;
  1.1   thorpej 	struct dkwedge_softc *sc;
 1.74   mlelstv 	int flags;
 1.74   mlelstv
 1.74   mlelstv 	flags = DETACH_QUIET;
1.129  riastrad 	if (!idleonly)
1.129  riastrad 		flags |= DETACH_FORCE;
  1.1   thorpej
  1.1   thorpej 	for (;;) {
 1.27        ad 		mutex_enter(&pdk->dk_openlock);
 1.74   mlelstv 		LIST_FOREACH(sc, &pdk->dk_wedges, sc_plink) {
 1.74   mlelstv 			if (!idleonly || sc->sc_dk.dk_openmask == 0)
 1.74   mlelstv 				break;
 1.74   mlelstv 		}
 1.74   mlelstv 		if (sc == NULL) {
 1.74   mlelstv 			KASSERT(idleonly || pdk->dk_nwedges == 0);
 1.27        ad 			mutex_exit(&pdk->dk_openlock);
  1.1   thorpej 			return;
  1.1   thorpej 		}
 1.94      maya 		strlcpy(dkw.dkw_parent, pdk->dk_name, sizeof(dkw.dkw_parent));
 1.36    cegger 		strlcpy(dkw.dkw_devname, device_xname(sc->sc_dev),
1.129  riastrad 		    sizeof(dkw.dkw_devname));
 1.27        ad 		mutex_exit(&pdk->dk_openlock);
 1.74   mlelstv 		(void) dkwedge_del1(&dkw, flags);
  1.1   thorpej 	}
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_list:	[exported function]
  1.1   thorpej  *
  1.1   thorpej  *	List all of the wedges on a particular disk.
  1.1   thorpej  */
  1.1   thorpej int
 1.10  christos dkwedge_list(struct disk *pdk, struct dkwedge_list *dkwl, struct lwp *l)
  1.1   thorpej {
  1.1   thorpej 	struct uio uio;
  1.1   thorpej 	struct iovec iov;
  1.1   thorpej 	struct dkwedge_softc *sc;
  1.1   thorpej 	struct dkwedge_info dkw;
  1.1   thorpej 	int error = 0;
  1.1   thorpej
  1.1   thorpej 	iov.iov_base = dkwl->dkwl_buf;
  1.1   thorpej 	iov.iov_len = dkwl->dkwl_bufsize;
  1.1   thorpej
  1.1   thorpej 	uio.uio_iov = &iov;
  1.1   thorpej 	uio.uio_iovcnt = 1;
  1.1   thorpej 	uio.uio_offset = 0;
  1.1   thorpej 	uio.uio_resid = dkwl->dkwl_bufsize;
  1.1   thorpej 	uio.uio_rw = UIO_READ;
 1.51     pooka 	KASSERT(l == curlwp);
 1.51     pooka 	uio.uio_vmspace = l->l_proc->p_vmspace;
  1.1   thorpej
  1.1   thorpej 	dkwl->dkwl_ncopied = 0;
  1.1   thorpej
 1.27        ad 	mutex_enter(&pdk->dk_openlock);
  1.1   thorpej 	LIST_FOREACH(sc, &pdk->dk_wedges, sc_plink) {
  1.1   thorpej 		if (uio.uio_resid < sizeof(dkw))
  1.1   thorpej 			break;
  1.1   thorpej
  1.1   thorpej 		if (sc->sc_state != DKW_STATE_RUNNING)
  1.1   thorpej 			continue;
  1.1   thorpej
 1.36    cegger 		strlcpy(dkw.dkw_devname, device_xname(sc->sc_dev),
1.129  riastrad 		    sizeof(dkw.dkw_devname));
  1.1   thorpej 		memcpy(dkw.dkw_wname, sc->sc_wname, sizeof(dkw.dkw_wname));
  1.1   thorpej 		dkw.dkw_wname[sizeof(dkw.dkw_wname) - 1] = '\0';
 1.94      maya 		strlcpy(dkw.dkw_parent, sc->sc_parent->dk_name,
 1.94      maya 		    sizeof(dkw.dkw_parent));
  1.1   thorpej 		dkw.dkw_offset = sc->sc_offset;
1.135  riastrad 		dkw.dkw_size = dkwedge_size(sc);
 1.94      maya 		strlcpy(dkw.dkw_ptype, sc->sc_ptype, sizeof(dkw.dkw_ptype));
  1.1   thorpej
  1.1   thorpej 		error = uiomove(&dkw, sizeof(dkw), &uio);
  1.1   thorpej 		if (error)
  1.1   thorpej 			break;
  1.1   thorpej 		dkwl->dkwl_ncopied++;
  1.1   thorpej 	}
  1.1   thorpej 	dkwl->dkwl_nwedges = pdk->dk_nwedges;
 1.27        ad 	mutex_exit(&pdk->dk_openlock);
  1.1   thorpej
1.128  riastrad 	return error;
  1.1   thorpej }
  1.1   thorpej
 1.25    dyoung device_t
 1.25    dyoung dkwedge_find_by_wname(const char *wname)
 1.25    dyoung {
 1.25    dyoung 	device_t dv = NULL;
 1.25    dyoung 	struct dkwedge_softc *sc;
 1.25    dyoung 	int i;
 1.25    dyoung
 1.27        ad 	rw_enter(&dkwedges_lock, RW_WRITER);
 1.25    dyoung 	for (i = 0; i < ndkwedges; i++) {
 1.25    dyoung 		if ((sc = dkwedges[i]) == NULL)
 1.25    dyoung 			continue;
 1.25    dyoung 		if (strcmp(sc->sc_wname, wname) == 0) {
 1.25    dyoung 			if (dv != NULL) {
 1.25    dyoung 				printf(
 1.25    dyoung 				    "WARNING: double match for wedge name %s "
 1.25    dyoung 				    "(%s, %s)\n", wname, device_xname(dv),
 1.25    dyoung 				    device_xname(sc->sc_dev));
 1.25    dyoung 				continue;
 1.25    dyoung 			}
 1.25    dyoung 			dv = sc->sc_dev;
 1.25    dyoung 		}
 1.25    dyoung 	}
 1.27        ad 	rw_exit(&dkwedges_lock);
 1.25    dyoung 	return dv;
 1.25    dyoung }
 1.25    dyoung
 1.89  christos device_t
 1.89  christos dkwedge_find_by_parent(const char *name, size_t *i)
 1.89  christos {
1.129  riastrad
 1.89  christos 	rw_enter(&dkwedges_lock, RW_WRITER);
 1.89  christos 	for (; *i < (size_t)ndkwedges; (*i)++) {
 1.89  christos 		struct dkwedge_softc *sc;
 1.89  christos 		if ((sc = dkwedges[*i]) == NULL)
 1.89  christos 			continue;
 1.89  christos 		if (strcmp(sc->sc_parent->dk_name, name) != 0)
 1.89  christos 			continue;
 1.89  christos 		rw_exit(&dkwedges_lock);
 1.89  christos 		return sc->sc_dev;
 1.89  christos 	}
 1.89  christos 	rw_exit(&dkwedges_lock);
 1.89  christos 	return NULL;
 1.89  christos }
 1.89  christos
 1.25    dyoung void
 1.25    dyoung dkwedge_print_wnames(void)
 1.25    dyoung {
 1.25    dyoung 	struct dkwedge_softc *sc;
 1.25    dyoung 	int i;
 1.25    dyoung
 1.27        ad 	rw_enter(&dkwedges_lock, RW_WRITER);
 1.25    dyoung 	for (i = 0; i < ndkwedges; i++) {
 1.25    dyoung 		if ((sc = dkwedges[i]) == NULL)
 1.25    dyoung 			continue;
 1.25    dyoung 		printf(" wedge:%s", sc->sc_wname);
 1.25    dyoung 	}
 1.27        ad 	rw_exit(&dkwedges_lock);
 1.25    dyoung }
 1.25    dyoung
  1.1   thorpej /*
 1.18  uebayasi  * We need a dummy object to stuff into the dkwedge discovery method link
  1.1   thorpej  * set to ensure that there is always at least one object in the set.
  1.1   thorpej  */
  1.1   thorpej static struct dkwedge_discovery_method dummy_discovery_method;
  1.1   thorpej __link_set_add_bss(dkwedge_methods, dummy_discovery_method);
  1.1   thorpej
  1.1   thorpej /*
 1.27        ad  * dkwedge_init:
  1.1   thorpej  *
 1.27        ad  *	Initialize the disk wedge subsystem.
  1.1   thorpej  */
 1.27        ad void
 1.27        ad dkwedge_init(void)
  1.1   thorpej {
  1.1   thorpej 	__link_set_decl(dkwedge_methods, struct dkwedge_discovery_method);
  1.1   thorpej 	struct dkwedge_discovery_method * const *ddmp;
  1.1   thorpej 	struct dkwedge_discovery_method *lddm, *ddm;
  1.1   thorpej
 1.27        ad 	rw_init(&dkwedges_lock);
 1.27        ad 	rw_init(&dkwedge_discovery_methods_lock);
 1.27        ad
 1.27        ad 	if (config_cfdriver_attach(&dk_cd) != 0)
 1.27        ad 		panic("dkwedge: unable to attach cfdriver");
 1.27        ad 	if (config_cfattach_attach(dk_cd.cd_name, &dk_ca) != 0)
 1.27        ad 		panic("dkwedge: unable to attach cfattach");
  1.1   thorpej
 1.27        ad 	rw_enter(&dkwedge_discovery_methods_lock, RW_WRITER);
  1.1   thorpej
  1.1   thorpej 	LIST_INIT(&dkwedge_discovery_methods);
  1.1   thorpej
  1.1   thorpej 	__link_set_foreach(ddmp, dkwedge_methods) {
  1.1   thorpej 		ddm = *ddmp;
  1.1   thorpej 		if (ddm == &dummy_discovery_method)
  1.1   thorpej 			continue;
  1.1   thorpej 		if (LIST_EMPTY(&dkwedge_discovery_methods)) {
  1.1   thorpej 			LIST_INSERT_HEAD(&dkwedge_discovery_methods,
1.129  riastrad 			    ddm, ddm_list);
  1.1   thorpej 			continue;
  1.1   thorpej 		}
  1.1   thorpej 		LIST_FOREACH(lddm, &dkwedge_discovery_methods, ddm_list) {
  1.1   thorpej 			if (ddm->ddm_priority == lddm->ddm_priority) {
  1.1   thorpej 				aprint_error("dk-method-%s: method \"%s\" "
  1.1   thorpej 				    "already exists at priority %d\n",
  1.1   thorpej 				    ddm->ddm_name, lddm->ddm_name,
  1.1   thorpej 				    lddm->ddm_priority);
  1.1   thorpej 				/* Not inserted. */
  1.1   thorpej 				break;
  1.1   thorpej 			}
  1.1   thorpej 			if (ddm->ddm_priority < lddm->ddm_priority) {
  1.1   thorpej 				/* Higher priority; insert before. */
  1.1   thorpej 				LIST_INSERT_BEFORE(lddm, ddm, ddm_list);
  1.1   thorpej 				break;
  1.1   thorpej 			}
  1.1   thorpej 			if (LIST_NEXT(lddm, ddm_list) == NULL) {
  1.1   thorpej 				/* Last one; insert after. */
  1.1   thorpej 				KASSERT(lddm->ddm_priority < ddm->ddm_priority);
  1.1   thorpej 				LIST_INSERT_AFTER(lddm, ddm, ddm_list);
  1.1   thorpej 				break;
  1.1   thorpej 			}
  1.1   thorpej 		}
  1.1   thorpej 	}
  1.1   thorpej
 1.27        ad 	rw_exit(&dkwedge_discovery_methods_lock);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej #ifdef DKWEDGE_AUTODISCOVER
  1.1   thorpej int	dkwedge_autodiscover = 1;
  1.1   thorpej #else
  1.1   thorpej int	dkwedge_autodiscover = 0;
  1.1   thorpej #endif
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_discover:	[exported function]
  1.1   thorpej  *
  1.1   thorpej  *	Discover the wedges on a newly attached disk.
 1.74   mlelstv  *	Remove all unused wedges on the disk first.
  1.1   thorpej  */
  1.1   thorpej void
  1.1   thorpej dkwedge_discover(struct disk *pdk)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_discovery_method *ddm;
  1.1   thorpej 	struct vnode *vp;
  1.1   thorpej 	int error;
  1.1   thorpej 	dev_t pdev;
  1.1   thorpej
  1.1   thorpej 	/*
  1.1   thorpej 	 * Require people playing with wedges to enable this explicitly.
  1.1   thorpej 	 */
  1.1   thorpej 	if (dkwedge_autodiscover == 0)
  1.1   thorpej 		return;
  1.1   thorpej
 1.27        ad 	rw_enter(&dkwedge_discovery_methods_lock, RW_READER);
  1.1   thorpej
 1.74   mlelstv 	/*
 1.74   mlelstv 	 * Use the character device for scanning, the block device
 1.74   mlelstv 	 * is busy if there are already wedges attached.
 1.74   mlelstv 	 */
 1.74   mlelstv 	error = dkwedge_compute_pdev(pdk->dk_name, &pdev, VCHR);
  1.1   thorpej 	if (error) {
  1.1   thorpej 		aprint_error("%s: unable to compute pdev, error = %d\n",
  1.1   thorpej 		    pdk->dk_name, error);
  1.1   thorpej 		goto out;
  1.1   thorpej 	}
  1.1   thorpej
 1.74   mlelstv 	error = cdevvp(pdev, &vp);
  1.1   thorpej 	if (error) {
  1.1   thorpej 		aprint_error("%s: unable to find vnode for pdev, error = %d\n",
  1.1   thorpej 		    pdk->dk_name, error);
  1.1   thorpej 		goto out;
  1.1   thorpej 	}
  1.1   thorpej
  1.1   thorpej 	error = vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
  1.1   thorpej 	if (error) {
  1.1   thorpej 		aprint_error("%s: unable to lock vnode for pdev, error = %d\n",
  1.1   thorpej 		    pdk->dk_name, error);
  1.1   thorpej 		vrele(vp);
  1.1   thorpej 		goto out;
  1.1   thorpej 	}
  1.1   thorpej
 1.62  jmcneill 	error = VOP_OPEN(vp, FREAD | FSILENT, NOCRED);
  1.1   thorpej 	if (error) {
1.132  riastrad 		if (error != ENXIO)
 1.67     soren 			aprint_error("%s: unable to open device, error = %d\n",
 1.67     soren 			    pdk->dk_name, error);
  1.1   thorpej 		vput(vp);
  1.1   thorpej 		goto out;
  1.1   thorpej 	}
 1.56   hannken 	VOP_UNLOCK(vp);
  1.1   thorpej
  1.1   thorpej 	/*
 1.74   mlelstv 	 * Remove unused wedges
 1.74   mlelstv 	 */
 1.74   mlelstv 	dkwedge_delall1(pdk, true);
 1.74   mlelstv
 1.74   mlelstv 	/*
  1.1   thorpej 	 * For each supported partition map type, look to see if
  1.1   thorpej 	 * this map type exists.  If so, parse it and add the
  1.1   thorpej 	 * corresponding wedges.
  1.1   thorpej 	 */
  1.1   thorpej 	LIST_FOREACH(ddm, &dkwedge_discovery_methods, ddm_list) {
  1.1   thorpej 		error = (*ddm->ddm_discover)(pdk, vp);
  1.1   thorpej 		if (error == 0) {
  1.1   thorpej 			/* Successfully created wedges; we're done. */
  1.1   thorpej 			break;
  1.1   thorpej 		}
  1.1   thorpej 	}
  1.1   thorpej
 1.35        ad 	error = vn_close(vp, FREAD, NOCRED);
  1.1   thorpej 	if (error) {
  1.1   thorpej 		aprint_error("%s: unable to close device, error = %d\n",
  1.1   thorpej 		    pdk->dk_name, error);
  1.1   thorpej 		/* We'll just assume the vnode has been cleaned up. */
  1.1   thorpej 	}
 1.75   mlelstv
1.129  riastrad out:
 1.27        ad 	rw_exit(&dkwedge_discovery_methods_lock);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_read:
  1.1   thorpej  *
 1.37       agc  *	Read some data from the specified disk, used for
  1.1   thorpej  *	partition discovery.
  1.1   thorpej  */
  1.1   thorpej int
 1.20  christos dkwedge_read(struct disk *pdk, struct vnode *vp, daddr_t blkno,
 1.19  christos     void *tbuf, size_t len)
  1.1   thorpej {
 1.74   mlelstv 	buf_t *bp;
 1.81   mlelstv 	int error;
 1.82   mlelstv 	bool isopen;
 1.82   mlelstv 	dev_t bdev;
 1.83     pooka 	struct vnode *bdvp;
 1.74   mlelstv
 1.74   mlelstv 	/*
 1.74   mlelstv 	 * The kernel cannot read from a character device vnode
 1.74   mlelstv 	 * as physio() only handles user memory.
 1.74   mlelstv 	 *
 1.82   mlelstv 	 * If the block device has already been opened by a wedge
 1.82   mlelstv 	 * use that vnode and temporarily bump the open counter.
 1.82   mlelstv 	 *
 1.82   mlelstv 	 * Otherwise try to open the block device.
 1.74   mlelstv 	 */
  1.1   thorpej
 1.82   mlelstv 	bdev = devsw_chr2blk(vp->v_rdev);
 1.82   mlelstv
 1.82   mlelstv 	mutex_enter(&pdk->dk_rawlock);
 1.82   mlelstv 	if (pdk->dk_rawopens != 0) {
 1.82   mlelstv 		KASSERT(pdk->dk_rawvp != NULL);
 1.82   mlelstv 		isopen = true;
 1.82   mlelstv 		++pdk->dk_rawopens;
 1.83     pooka 		bdvp = pdk->dk_rawvp;
 1.87   mlelstv 		error = 0;
 1.82   mlelstv 	} else {
 1.82   mlelstv 		isopen = false;
 1.87   mlelstv 		error = dk_open_parent(bdev, FREAD, &bdvp);
 1.82   mlelstv 	}
 1.82   mlelstv 	mutex_exit(&pdk->dk_rawlock);
 1.82   mlelstv
 1.87   mlelstv 	if (error)
 1.87   mlelstv 		return error;
 1.82   mlelstv
 1.83     pooka 	bp = getiobuf(bdvp, true);
 1.41        ad 	bp->b_flags = B_READ;
 1.74   mlelstv 	bp->b_cflags = BC_BUSY;
 1.82   mlelstv 	bp->b_dev = bdev;
 1.41        ad 	bp->b_data = tbuf;
 1.75   mlelstv 	bp->b_bufsize = bp->b_bcount = len;
 1.74   mlelstv 	bp->b_blkno = blkno;
 1.75   mlelstv 	bp->b_cylinder = 0;
 1.75   mlelstv 	bp->b_error = 0;
 1.74   mlelstv
 1.83     pooka 	VOP_STRATEGY(bdvp, bp);
 1.74   mlelstv 	error = biowait(bp);
 1.41        ad 	putiobuf(bp);
  1.1   thorpej
 1.82   mlelstv 	mutex_enter(&pdk->dk_rawlock);
 1.82   mlelstv 	if (isopen) {
 1.82   mlelstv 		--pdk->dk_rawopens;
 1.82   mlelstv 	} else {
 1.83     pooka 		dk_close_parent(bdvp, FREAD);
 1.82   mlelstv 	}
 1.82   mlelstv 	mutex_exit(&pdk->dk_rawlock);
 1.74   mlelstv
 1.74   mlelstv 	return error;
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwedge_lookup:
  1.1   thorpej  *
  1.1   thorpej  *	Look up a dkwedge_softc based on the provided dev_t.
  1.1   thorpej  */
  1.1   thorpej static struct dkwedge_softc *
  1.1   thorpej dkwedge_lookup(dev_t dev)
  1.1   thorpej {
1.137  riastrad 	const int unit = minor(dev);
1.137  riastrad 	struct dkwedge_softc *sc;
  1.1   thorpej
1.137  riastrad 	rw_enter(&dkwedges_lock, RW_READER);
1.137  riastrad 	if (unit < 0 || unit >= ndkwedges)
1.137  riastrad 		sc = NULL;
1.137  riastrad 	else
1.137  riastrad 		sc = dkwedges[unit];
1.137  riastrad 	rw_exit(&dkwedges_lock);
  1.1   thorpej
1.137  riastrad 	return sc;
  1.1   thorpej }
  1.1   thorpej
 1.87   mlelstv static int
 1.87   mlelstv dk_open_parent(dev_t dev, int mode, struct vnode **vpp)
 1.82   mlelstv {
 1.82   mlelstv 	struct vnode *vp;
 1.82   mlelstv 	int error;
 1.82   mlelstv
 1.82   mlelstv 	error = bdevvp(dev, &vp);
 1.82   mlelstv 	if (error)
 1.87   mlelstv 		return error;
 1.82   mlelstv
 1.82   mlelstv 	error = vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
 1.82   mlelstv 	if (error) {
 1.82   mlelstv 		vrele(vp);
 1.87   mlelstv 		return error;
 1.82   mlelstv 	}
 1.82   mlelstv 	error = VOP_OPEN(vp, mode, NOCRED);
 1.82   mlelstv 	if (error) {
 1.82   mlelstv 		vput(vp);
 1.87   mlelstv 		return error;
 1.82   mlelstv 	}
 1.82   mlelstv
 1.82   mlelstv 	/* VOP_OPEN() doesn't do this for us. */
 1.82   mlelstv 	if (mode & FWRITE) {
 1.82   mlelstv 		mutex_enter(vp->v_interlock);
 1.82   mlelstv 		vp->v_writecount++;
 1.82   mlelstv 		mutex_exit(vp->v_interlock);
 1.82   mlelstv 	}
 1.82   mlelstv
 1.82   mlelstv 	VOP_UNLOCK(vp);
 1.82   mlelstv
 1.87   mlelstv 	*vpp = vp;
 1.87   mlelstv
 1.87   mlelstv 	return 0;
 1.82   mlelstv }
 1.82   mlelstv
 1.82   mlelstv static int
 1.82   mlelstv dk_close_parent(struct vnode *vp, int mode)
 1.82   mlelstv {
 1.82   mlelstv 	int error;
 1.82   mlelstv
 1.82   mlelstv 	error = vn_close(vp, mode, NOCRED);
 1.82   mlelstv 	return error;
 1.82   mlelstv }
 1.82   mlelstv
  1.1   thorpej /*
1.144  riastrad  * dkunit:		[devsw entry point]
1.144  riastrad  *
1.144  riastrad  *	Return the autoconf device_t unit number of a wedge by its
1.144  riastrad  *	devsw dev_t number, or -1 if there is none.
1.144  riastrad  *
1.144  riastrad  *	XXX This is a temporary hack until dkwedge numbering is made to
1.144  riastrad  *	correspond 1:1 to autoconf device numbering.
1.144  riastrad  */
1.144  riastrad static int
1.144  riastrad dkunit(dev_t dev)
1.144  riastrad {
1.144  riastrad 	int mn = minor(dev);
1.144  riastrad 	struct dkwedge_softc *sc;
1.144  riastrad 	device_t dv;
1.144  riastrad 	int unit = -1;
1.144  riastrad
1.144  riastrad 	if (mn < 0)
1.144  riastrad 		return -1;
1.144  riastrad
1.144  riastrad 	rw_enter(&dkwedges_lock, RW_READER);
1.144  riastrad 	if (mn < ndkwedges &&
1.144  riastrad 	    (sc = dkwedges[minor(dev)]) != NULL &&
1.144  riastrad 	    (dv = sc->sc_dev) != NULL)
1.144  riastrad 		unit = device_unit(dv);
1.144  riastrad 	rw_exit(&dkwedges_lock);
1.144  riastrad
1.144  riastrad 	return unit;
1.144  riastrad }
1.144  riastrad
1.144  riastrad /*
  1.1   thorpej  * dkopen:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Open a wedge.
  1.1   thorpej  */
  1.1   thorpej static int
 1.20  christos dkopen(dev_t dev, int flags, int fmt, struct lwp *l)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
 1.14   thorpej 	int error = 0;
  1.1   thorpej
  1.1   thorpej 	if (sc == NULL)
1.132  riastrad 		return ENXIO;
  1.1   thorpej 	if (sc->sc_state != DKW_STATE_RUNNING)
1.128  riastrad 		return ENXIO;
  1.1   thorpej
  1.1   thorpej 	/*
  1.1   thorpej 	 * We go through a complicated little dance to only open the parent
  1.1   thorpej 	 * vnode once per wedge, no matter how many times the wedge is
  1.1   thorpej 	 * opened.  The reason?  We see one dkopen() per open call, but
  1.1   thorpej 	 * only dkclose() on the last close.
  1.1   thorpej 	 */
 1.27        ad 	mutex_enter(&sc->sc_dk.dk_openlock);
 1.27        ad 	mutex_enter(&sc->sc_parent->dk_rawlock);
  1.3   thorpej 	if (sc->sc_dk.dk_openmask == 0) {
1.118  riastrad 		error = dkfirstopen(sc, flags);
1.118  riastrad 		if (error)
1.118  riastrad 			goto popen_fail;
1.104   mlelstv 	}
1.104   mlelstv 	KASSERT(sc->sc_mode != 0);
1.104   mlelstv 	if (flags & ~sc->sc_mode & FWRITE) {
1.103   mlelstv 		error = EROFS;
1.103   mlelstv 		goto popen_fail;
  1.1   thorpej 	}
 1.17       dbj 	if (fmt == S_IFCHR)
 1.17       dbj 		sc->sc_dk.dk_copenmask |= 1;
 1.17       dbj 	else
 1.17       dbj 		sc->sc_dk.dk_bopenmask |= 1;
 1.17       dbj 	sc->sc_dk.dk_openmask =
 1.17       dbj 	    sc->sc_dk.dk_copenmask | sc->sc_dk.dk_bopenmask;
  1.1   thorpej
1.129  riastrad popen_fail:
 1.27        ad 	mutex_exit(&sc->sc_parent->dk_rawlock);
 1.27        ad 	mutex_exit(&sc->sc_dk.dk_openlock);
1.128  riastrad 	return error;
  1.1   thorpej }
  1.1   thorpej
 1.46    dyoung static int
1.118  riastrad dkfirstopen(struct dkwedge_softc *sc, int flags)
1.118  riastrad {
1.118  riastrad 	struct dkwedge_softc *nsc;
1.118  riastrad 	struct vnode *vp;
1.118  riastrad 	int mode;
1.118  riastrad 	int error;
1.118  riastrad
1.118  riastrad 	KASSERT(mutex_owned(&sc->sc_dk.dk_openlock));
1.118  riastrad 	KASSERT(mutex_owned(&sc->sc_parent->dk_rawlock));
1.118  riastrad
1.118  riastrad 	if (sc->sc_parent->dk_rawopens == 0) {
1.118  riastrad 		KASSERT(sc->sc_parent->dk_rawvp == NULL);
1.118  riastrad 		/*
1.118  riastrad 		 * Try open read-write. If this fails for EROFS
1.118  riastrad 		 * and wedge is read-only, retry to open read-only.
1.118  riastrad 		 */
1.118  riastrad 		mode = FREAD | FWRITE;
1.118  riastrad 		error = dk_open_parent(sc->sc_pdev, mode, &vp);
1.118  riastrad 		if (error == EROFS && (flags & FWRITE) == 0) {
1.118  riastrad 			mode &= ~FWRITE;
1.118  riastrad 			error = dk_open_parent(sc->sc_pdev, mode, &vp);
1.118  riastrad 		}
1.118  riastrad 		if (error)
1.118  riastrad 			return error;
1.138  riastrad 		KASSERT(vp != NULL);
1.118  riastrad 		sc->sc_parent->dk_rawvp = vp;
1.118  riastrad 	} else {
1.118  riastrad 		/*
1.118  riastrad 		 * Retrieve mode from an already opened wedge.
1.125  riastrad 		 *
1.125  riastrad 		 * At this point, dk_rawopens is bounded by the number
1.125  riastrad 		 * of dkwedge devices in the system, which is limited
1.125  riastrad 		 * by autoconf device numbering to INT_MAX.  Since
1.125  riastrad 		 * dk_rawopens is unsigned, this can't overflow.
1.118  riastrad 		 */
1.125  riastrad 		KASSERT(sc->sc_parent->dk_rawopens < UINT_MAX);
1.138  riastrad 		KASSERT(sc->sc_parent->dk_rawvp != NULL);
1.118  riastrad 		mode = 0;
1.118  riastrad 		LIST_FOREACH(nsc, &sc->sc_parent->dk_wedges, sc_plink) {
1.118  riastrad 			if (nsc == sc || nsc->sc_dk.dk_openmask == 0)
1.118  riastrad 				continue;
1.118  riastrad 			mode = nsc->sc_mode;
1.118  riastrad 			break;
1.118  riastrad 		}
1.118  riastrad 	}
1.118  riastrad 	sc->sc_mode = mode;
1.118  riastrad 	sc->sc_parent->dk_rawopens++;
1.118  riastrad
1.118  riastrad 	return 0;
1.118  riastrad }
1.118  riastrad
1.121  riastrad static void
 1.46    dyoung dklastclose(struct dkwedge_softc *sc)
 1.46    dyoung {
1.104   mlelstv
1.117  riastrad 	KASSERT(mutex_owned(&sc->sc_dk.dk_openlock));
1.117  riastrad 	KASSERT(mutex_owned(&sc->sc_parent->dk_rawlock));
1.126  riastrad 	KASSERT(sc->sc_parent->dk_rawopens > 0);
1.126  riastrad 	KASSERT(sc->sc_parent->dk_rawvp != NULL);
1.117  riastrad
1.120  riastrad 	if (--sc->sc_parent->dk_rawopens == 0) {
1.120  riastrad 		struct vnode *const vp = sc->sc_parent->dk_rawvp;
1.120  riastrad 		const int mode = sc->sc_mode;
 1.74   mlelstv
1.120  riastrad 		sc->sc_parent->dk_rawvp = NULL;
1.120  riastrad 		sc->sc_mode = 0;
 1.74   mlelstv
1.104   mlelstv 		dk_close_parent(vp, mode);
 1.74   mlelstv 	}
 1.46    dyoung }
 1.46    dyoung
 1.46    dyoung /*
  1.1   thorpej  * dkclose:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Close a wedge.
  1.1   thorpej  */
  1.1   thorpej static int
 1.20  christos dkclose(dev_t dev, int flags, int fmt, struct lwp *l)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
  1.1   thorpej
 1.59  christos 	if (sc == NULL)
1.132  riastrad 		return ENXIO;
 1.59  christos 	if (sc->sc_state != DKW_STATE_RUNNING)
1.121  riastrad 		return ENXIO;
 1.59  christos
 1.27        ad 	mutex_enter(&sc->sc_dk.dk_openlock);
1.122  riastrad 	mutex_enter(&sc->sc_parent->dk_rawlock);
  1.1   thorpej
1.123  riastrad 	KASSERT(sc->sc_dk.dk_openmask != 0);
1.123  riastrad
  1.3   thorpej 	if (fmt == S_IFCHR)
  1.3   thorpej 		sc->sc_dk.dk_copenmask &= ~1;
  1.3   thorpej 	else
  1.3   thorpej 		sc->sc_dk.dk_bopenmask &= ~1;
  1.3   thorpej 	sc->sc_dk.dk_openmask =
  1.3   thorpej 	    sc->sc_dk.dk_copenmask | sc->sc_dk.dk_bopenmask;
  1.3   thorpej
1.104   mlelstv 	if (sc->sc_dk.dk_openmask == 0) {
1.121  riastrad 		dklastclose(sc);
 1.90   mlelstv 	}
  1.1   thorpej
1.122  riastrad 	mutex_exit(&sc->sc_parent->dk_rawlock);
1.115  riastrad 	mutex_exit(&sc->sc_dk.dk_openlock);
1.115  riastrad
1.121  riastrad 	return 0;
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
1.141  riastrad  * dkcancel:		[devsw entry point]
1.141  riastrad  *
1.141  riastrad  *	Cancel any pending I/O operations waiting on a wedge.
1.141  riastrad  */
1.141  riastrad static int
1.141  riastrad dkcancel(dev_t dev, int flags, int fmt, struct lwp *l)
1.141  riastrad {
1.141  riastrad 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
1.141  riastrad
1.141  riastrad 	KASSERT(sc != NULL);
1.141  riastrad 	KASSERT(sc->sc_dev != NULL);
1.141  riastrad
1.141  riastrad 	/*
1.141  riastrad 	 * Disk I/O is expected to complete or fail within a reasonable
1.141  riastrad 	 * timeframe -- it's storage, not communication.  Further, the
1.141  riastrad 	 * character and block device interface guarantees that prior
1.141  riastrad 	 * reads and writes have completed or failed by the time close
1.141  riastrad 	 * returns -- we are not to cancel them here.  If the parent
1.141  riastrad 	 * device's hardware is gone, the parent driver can make them
1.141  riastrad 	 * fail.  Nothing for dk(4) itself to do.
1.141  riastrad 	 */
1.141  riastrad
1.141  riastrad 	return 0;
1.141  riastrad }
1.141  riastrad
1.141  riastrad /*
1.131  riastrad  * dkstrategy:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Perform I/O based on the wedge I/O strategy.
  1.1   thorpej  */
  1.1   thorpej static void
  1.1   thorpej dkstrategy(struct buf *bp)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(bp->b_dev);
 1.54   mlelstv 	uint64_t p_size, p_offset;
  1.1   thorpej
 1.59  christos 	if (sc == NULL) {
1.132  riastrad 		bp->b_error = ENXIO;
 1.59  christos 		goto done;
 1.59  christos 	}
 1.60  christos
 1.60  christos 	if (sc->sc_state != DKW_STATE_RUNNING ||
 1.60  christos 	    sc->sc_parent->dk_rawvp == NULL) {
  1.1   thorpej 		bp->b_error = ENXIO;
  1.1   thorpej 		goto done;
  1.1   thorpej 	}
  1.1   thorpej
  1.1   thorpej 	/* If it's an empty transfer, wake up the top half now. */
  1.1   thorpej 	if (bp->b_bcount == 0)
  1.1   thorpej 		goto done;
  1.1   thorpej
 1.54   mlelstv 	p_offset = sc->sc_offset << sc->sc_parent->dk_blkshift;
1.135  riastrad 	p_size = dkwedge_size(sc) << sc->sc_parent->dk_blkshift;
 1.54   mlelstv
  1.1   thorpej 	/* Make sure it's in-range. */
 1.54   mlelstv 	if (bounds_check_with_mediasize(bp, DEV_BSIZE, p_size) <= 0)
  1.1   thorpej 		goto done;
  1.1   thorpej
  1.1   thorpej 	/* Translate it to the parent's raw LBA. */
 1.54   mlelstv 	bp->b_rawblkno = bp->b_blkno + p_offset;
  1.1   thorpej
  1.1   thorpej 	/* Place it in the queue and start I/O on the unit. */
 1.92   mlelstv 	mutex_enter(&sc->sc_iolock);
  1.1   thorpej 	sc->sc_iopend++;
 1.96   mlelstv 	disk_wait(&sc->sc_dk);
 1.43      yamt 	bufq_put(sc->sc_bufq, bp);
 1.92   mlelstv 	mutex_exit(&sc->sc_iolock);
 1.92   mlelstv
  1.1   thorpej 	dkstart(sc);
  1.1   thorpej 	return;
  1.1   thorpej
1.129  riastrad done:
  1.1   thorpej 	bp->b_resid = bp->b_bcount;
  1.1   thorpej 	biodone(bp);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkstart:
  1.1   thorpej  *
  1.1   thorpej  *	Start I/O that has been enqueued on the wedge.
  1.1   thorpej  */
  1.1   thorpej static void
  1.1   thorpej dkstart(struct dkwedge_softc *sc)
  1.1   thorpej {
 1.32        ad 	struct vnode *vp;
  1.1   thorpej 	struct buf *bp, *nbp;
  1.1   thorpej
 1.92   mlelstv 	mutex_enter(&sc->sc_iolock);
 1.92   mlelstv
  1.1   thorpej 	/* Do as much work as has been enqueued. */
 1.43      yamt 	while ((bp = bufq_peek(sc->sc_bufq)) != NULL) {
1.142  riastrad 		if (sc->sc_iostop) {
 1.43      yamt 			(void) bufq_get(sc->sc_bufq);
1.110  riastrad 			if (--sc->sc_iopend == 0)
 1.92   mlelstv 				cv_broadcast(&sc->sc_dkdrn);
 1.92   mlelstv 			mutex_exit(&sc->sc_iolock);
  1.1   thorpej 			bp->b_error = ENXIO;
  1.1   thorpej 			bp->b_resid = bp->b_bcount;
  1.1   thorpej 			biodone(bp);
 1.92   mlelstv 			mutex_enter(&sc->sc_iolock);
 1.92   mlelstv 			continue;
  1.1   thorpej 		}
  1.1   thorpej
 1.92   mlelstv 		/* fetch an I/O buf with sc_iolock dropped */
 1.92   mlelstv 		mutex_exit(&sc->sc_iolock);
 1.32        ad 		nbp = getiobuf(sc->sc_parent->dk_rawvp, false);
 1.92   mlelstv 		mutex_enter(&sc->sc_iolock);
  1.1   thorpej 		if (nbp == NULL) {
  1.1   thorpej 			/*
  1.1   thorpej 			 * No resources to run this request; leave the
  1.1   thorpej 			 * buffer queued up, and schedule a timer to
  1.1   thorpej 			 * restart the queue in 1/2 a second.
  1.1   thorpej 			 */
1.142  riastrad 			if (!sc->sc_iostop)
1.142  riastrad 				callout_schedule(&sc->sc_restart_ch, hz/2);
 1.92   mlelstv 			break;
 1.92   mlelstv 		}
 1.92   mlelstv
 1.92   mlelstv 		/*
 1.92   mlelstv 		 * fetch buf, this can fail if another thread
 1.92   mlelstv 		 * has already processed the queue, it can also
 1.92   mlelstv 		 * return a completely different buf.
 1.92   mlelstv 		 */
 1.92   mlelstv 		bp = bufq_get(sc->sc_bufq);
 1.92   mlelstv 		if (bp == NULL) {
 1.92   mlelstv 			mutex_exit(&sc->sc_iolock);
 1.92   mlelstv 			putiobuf(nbp);
 1.92   mlelstv 			mutex_enter(&sc->sc_iolock);
 1.92   mlelstv 			continue;
  1.1   thorpej 		}
  1.1   thorpej
 1.92   mlelstv 		/* Instrumentation. */
 1.92   mlelstv 		disk_busy(&sc->sc_dk);
 1.92   mlelstv
 1.92   mlelstv 		/* release lock for VOP_STRATEGY */
 1.92   mlelstv 		mutex_exit(&sc->sc_iolock);
  1.1   thorpej
  1.1   thorpej 		nbp->b_data = bp->b_data;
 1.32        ad 		nbp->b_flags = bp->b_flags;
 1.32        ad 		nbp->b_oflags = bp->b_oflags;
 1.32        ad 		nbp->b_cflags = bp->b_cflags;
  1.1   thorpej 		nbp->b_iodone = dkiodone;
  1.1   thorpej 		nbp->b_proc = bp->b_proc;
  1.1   thorpej 		nbp->b_blkno = bp->b_rawblkno;
  1.1   thorpej 		nbp->b_dev = sc->sc_parent->dk_rawvp->v_rdev;
  1.1   thorpej 		nbp->b_bcount = bp->b_bcount;
  1.1   thorpej 		nbp->b_private = bp;
  1.1   thorpej 		BIO_COPYPRIO(nbp, bp);
  1.1   thorpej
 1.32        ad 		vp = nbp->b_vp;
 1.32        ad 		if ((nbp->b_flags & B_READ) == 0) {
 1.61     rmind 			mutex_enter(vp->v_interlock);
 1.32        ad 			vp->v_numoutput++;
 1.61     rmind 			mutex_exit(vp->v_interlock);
 1.32        ad 		}
 1.32        ad 		VOP_STRATEGY(vp, nbp);
 1.92   mlelstv
 1.92   mlelstv 		mutex_enter(&sc->sc_iolock);
  1.1   thorpej 	}
 1.92   mlelstv
 1.92   mlelstv 	mutex_exit(&sc->sc_iolock);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkiodone:
  1.1   thorpej  *
  1.1   thorpej  *	I/O to a wedge has completed; alert the top half.
  1.1   thorpej  */
  1.1   thorpej static void
  1.1   thorpej dkiodone(struct buf *bp)
  1.1   thorpej {
  1.1   thorpej 	struct buf *obp = bp->b_private;
  1.1   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(obp->b_dev);
  1.1   thorpej
 1.28        ad 	if (bp->b_error != 0)
  1.1   thorpej 		obp->b_error = bp->b_error;
  1.1   thorpej 	obp->b_resid = bp->b_resid;
 1.11      yamt 	putiobuf(bp);
  1.1   thorpej
 1.92   mlelstv 	mutex_enter(&sc->sc_iolock);
1.110  riastrad 	if (--sc->sc_iopend == 0)
 1.92   mlelstv 		cv_broadcast(&sc->sc_dkdrn);
  1.1   thorpej
  1.1   thorpej 	disk_unbusy(&sc->sc_dk, obp->b_bcount - obp->b_resid,
  1.1   thorpej 	    obp->b_flags & B_READ);
 1.92   mlelstv 	mutex_exit(&sc->sc_iolock);
  1.1   thorpej
  1.1   thorpej 	biodone(obp);
  1.1   thorpej
  1.1   thorpej 	/* Kick the queue in case there is more work we can do. */
  1.1   thorpej 	dkstart(sc);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkrestart:
  1.1   thorpej  *
  1.1   thorpej  *	Restart the work queue after it was stalled due to
  1.1   thorpej  *	a resource shortage.  Invoked via a callout.
  1.1   thorpej  */
  1.1   thorpej static void
  1.1   thorpej dkrestart(void *v)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = v;
  1.1   thorpej
  1.1   thorpej 	dkstart(sc);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
 1.52  jakllsch  * dkminphys:
 1.52  jakllsch  *
 1.52  jakllsch  *	Call parent's minphys function.
 1.52  jakllsch  */
 1.52  jakllsch static void
 1.52  jakllsch dkminphys(struct buf *bp)
 1.52  jakllsch {
 1.52  jakllsch 	struct dkwedge_softc *sc = dkwedge_lookup(bp->b_dev);
 1.52  jakllsch 	dev_t dev;
 1.52  jakllsch
 1.52  jakllsch 	dev = bp->b_dev;
 1.52  jakllsch 	bp->b_dev = sc->sc_pdev;
1.102   mlelstv 	if (sc->sc_parent->dk_driver && sc->sc_parent->dk_driver->d_minphys)
1.102   mlelstv 		(*sc->sc_parent->dk_driver->d_minphys)(bp);
1.102   mlelstv 	else
1.102   mlelstv 		minphys(bp);
 1.52  jakllsch 	bp->b_dev = dev;
 1.52  jakllsch }
 1.52  jakllsch
 1.52  jakllsch /*
  1.1   thorpej  * dkread:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Read from a wedge.
  1.1   thorpej  */
  1.1   thorpej static int
 1.20  christos dkread(dev_t dev, struct uio *uio, int flags)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
  1.1   thorpej
 1.59  christos 	if (sc == NULL)
1.132  riastrad 		return ENXIO;
  1.1   thorpej 	if (sc->sc_state != DKW_STATE_RUNNING)
1.128  riastrad 		return ENXIO;
  1.6     perry
1.128  riastrad 	return physio(dkstrategy, NULL, dev, B_READ, dkminphys, uio);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkwrite:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Write to a wedge.
  1.1   thorpej  */
  1.1   thorpej static int
 1.20  christos dkwrite(dev_t dev, struct uio *uio, int flags)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
  1.1   thorpej
 1.59  christos 	if (sc == NULL)
1.132  riastrad 		return ENXIO;
  1.1   thorpej 	if (sc->sc_state != DKW_STATE_RUNNING)
1.128  riastrad 		return ENXIO;
  1.6     perry
1.128  riastrad 	return physio(dkstrategy, NULL, dev, B_WRITE, dkminphys, uio);
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkioctl:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Perform an ioctl request on a wedge.
  1.1   thorpej  */
  1.1   thorpej static int
 1.22  christos dkioctl(dev_t dev, u_long cmd, void *data, int flag, struct lwp *l)
  1.1   thorpej {
  1.1   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
  1.1   thorpej 	int error = 0;
  1.1   thorpej
 1.59  christos 	if (sc == NULL)
1.132  riastrad 		return ENXIO;
  1.1   thorpej 	if (sc->sc_state != DKW_STATE_RUNNING)
1.128  riastrad 		return ENXIO;
 1.60  christos 	if (sc->sc_parent->dk_rawvp == NULL)
1.128  riastrad 		return ENXIO;
  1.1   thorpej
 1.78  christos 	/*
 1.79  christos 	 * We pass NODEV instead of our device to indicate we don't
 1.78  christos 	 * want to handle disklabel ioctls
 1.78  christos 	 */
 1.79  christos 	error = disk_ioctl(&sc->sc_dk, NODEV, cmd, data, flag, l);
 1.48      haad 	if (error != EPASSTHROUGH)
1.128  riastrad 		return error;
 1.48      haad
 1.48      haad 	error = 0;
1.109    simonb
  1.1   thorpej 	switch (cmd) {
 1.95  jdolecek 	case DIOCGSTRATEGY:
 1.95  jdolecek 	case DIOCGCACHE:
  1.4   thorpej 	case DIOCCACHESYNC:
 1.95  jdolecek 		error = VOP_IOCTL(sc->sc_parent->dk_rawvp, cmd, data, flag,
1.129  riastrad 		    l != NULL ? l->l_cred : NOCRED);
  1.4   thorpej 		break;
1.129  riastrad 	case DIOCGWEDGEINFO: {
1.130  riastrad 		struct dkwedge_info *dkw = data;
  1.1   thorpej
 1.36    cegger 		strlcpy(dkw->dkw_devname, device_xname(sc->sc_dev),
1.129  riastrad 		    sizeof(dkw->dkw_devname));
  1.1   thorpej 	    	memcpy(dkw->dkw_wname, sc->sc_wname, sizeof(dkw->dkw_wname));
  1.1   thorpej 		dkw->dkw_wname[sizeof(dkw->dkw_wname) - 1] = '\0';
 1.94      maya 		strlcpy(dkw->dkw_parent, sc->sc_parent->dk_name,
 1.94      maya 		    sizeof(dkw->dkw_parent));
  1.1   thorpej 		dkw->dkw_offset = sc->sc_offset;
1.135  riastrad 		dkw->dkw_size = dkwedge_size(sc);
 1.94      maya 		strlcpy(dkw->dkw_ptype, sc->sc_ptype, sizeof(dkw->dkw_ptype));
  1.1   thorpej
  1.1   thorpej 		break;
1.129  riastrad 	}
1.129  riastrad 	case DIOCGSECTORALIGN: {
1.100  riastrad 		struct disk_sectoralign *dsa = data;
1.100  riastrad 		uint32_t r;
1.100  riastrad
1.100  riastrad 		error = VOP_IOCTL(sc->sc_parent->dk_rawvp, cmd, dsa, flag,
1.100  riastrad 		    l != NULL ? l->l_cred : NOCRED);
1.100  riastrad 		if (error)
1.100  riastrad 			break;
  1.1   thorpej
1.100  riastrad 		r = sc->sc_offset % dsa->dsa_alignment;
1.100  riastrad 		if (r < dsa->dsa_firstaligned)
1.100  riastrad 			dsa->dsa_firstaligned = dsa->dsa_firstaligned - r;
1.100  riastrad 		else
1.100  riastrad 			dsa->dsa_firstaligned = (dsa->dsa_firstaligned +
1.100  riastrad 			    dsa->dsa_alignment) - r;
1.100  riastrad 		break;
1.129  riastrad 	}
  1.1   thorpej 	default:
  1.1   thorpej 		error = ENOTTY;
  1.1   thorpej 	}
  1.1   thorpej
1.128  riastrad 	return error;
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
 1.72  dholland  * dkdiscard:		[devsw entry point]
 1.72  dholland  *
 1.72  dholland  *	Perform a discard-range request on a wedge.
 1.72  dholland  */
 1.72  dholland static int
 1.72  dholland dkdiscard(dev_t dev, off_t pos, off_t len)
 1.72  dholland {
 1.72  dholland 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
1.135  riastrad 	uint64_t size = dkwedge_size(sc);
 1.73  riastrad 	unsigned shift;
 1.73  riastrad 	off_t offset, maxlen;
1.111   hannken 	int error;
 1.72  dholland
 1.72  dholland 	if (sc == NULL)
1.132  riastrad 		return ENXIO;
 1.72  dholland 	if (sc->sc_state != DKW_STATE_RUNNING)
1.128  riastrad 		return ENXIO;
 1.72  dholland 	if (sc->sc_parent->dk_rawvp == NULL)
1.128  riastrad 		return ENXIO;
 1.72  dholland
1.135  riastrad 	/* XXX check bounds on size/offset up front */
 1.73  riastrad 	shift = (sc->sc_parent->dk_blkshift + DEV_BSHIFT);
1.135  riastrad 	KASSERT(__type_fit(off_t, size));
 1.73  riastrad 	KASSERT(__type_fit(off_t, sc->sc_offset));
 1.73  riastrad 	KASSERT(0 <= sc->sc_offset);
1.135  riastrad 	KASSERT(size <= (__type_max(off_t) >> shift));
1.135  riastrad 	KASSERT(sc->sc_offset <= ((__type_max(off_t) >> shift) - size));
 1.73  riastrad 	offset = ((off_t)sc->sc_offset << shift);
1.135  riastrad 	maxlen = ((off_t)size << shift);
 1.73  riastrad
 1.73  riastrad 	if (len > maxlen)
1.128  riastrad 		return EINVAL;
 1.73  riastrad 	if (pos > (maxlen - len))
1.128  riastrad 		return EINVAL;
 1.73  riastrad
 1.73  riastrad 	pos += offset;
1.111   hannken
1.111   hannken 	vn_lock(sc->sc_parent->dk_rawvp, LK_EXCLUSIVE | LK_RETRY);
1.111   hannken 	error = VOP_FDISCARD(sc->sc_parent->dk_rawvp, pos, len);
1.111   hannken 	VOP_UNLOCK(sc->sc_parent->dk_rawvp);
1.111   hannken
1.111   hannken 	return error;
 1.72  dholland }
 1.72  dholland
 1.72  dholland /*
  1.1   thorpej  * dksize:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Query the size of a wedge for the purpose of performing a dump
  1.1   thorpej  *	or for swapping to.
  1.1   thorpej  */
  1.1   thorpej static int
  1.1   thorpej dksize(dev_t dev)
  1.1   thorpej {
 1.13   thorpej 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
1.106   mlelstv 	uint64_t p_size;
 1.13   thorpej 	int rv = -1;
 1.13   thorpej
 1.13   thorpej 	if (sc == NULL)
1.128  riastrad 		return -1;
 1.13   thorpej 	if (sc->sc_state != DKW_STATE_RUNNING)
1.128  riastrad 		return -1;
 1.13   thorpej
 1.27        ad 	mutex_enter(&sc->sc_dk.dk_openlock);
 1.27        ad 	mutex_enter(&sc->sc_parent->dk_rawlock);
  1.1   thorpej
 1.13   thorpej 	/* Our content type is static, no need to open the device. */
 1.13   thorpej
1.135  riastrad 	p_size = dkwedge_size(sc) << sc->sc_parent->dk_blkshift;
 1.13   thorpej 	if (strcmp(sc->sc_ptype, DKW_PTYPE_SWAP) == 0) {
 1.13   thorpej 		/* Saturate if we are larger than INT_MAX. */
1.106   mlelstv 		if (p_size > INT_MAX)
 1.13   thorpej 			rv = INT_MAX;
 1.13   thorpej 		else
1.129  riastrad 			rv = (int)p_size;
 1.13   thorpej 	}
 1.13   thorpej
 1.27        ad 	mutex_exit(&sc->sc_parent->dk_rawlock);
 1.27        ad 	mutex_exit(&sc->sc_dk.dk_openlock);
 1.13   thorpej
1.128  riastrad 	return rv;
  1.1   thorpej }
  1.1   thorpej
  1.1   thorpej /*
  1.1   thorpej  * dkdump:		[devsw entry point]
  1.1   thorpej  *
  1.1   thorpej  *	Perform a crash dump to a wedge.
  1.1   thorpej  */
  1.1   thorpej static int
 1.23    dyoung dkdump(dev_t dev, daddr_t blkno, void *va, size_t size)
  1.1   thorpej {
 1.23    dyoung 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
 1.23    dyoung 	const struct bdevsw *bdev;
1.106   mlelstv 	uint64_t p_size, p_offset;
 1.23    dyoung 	int rv = 0;
 1.23    dyoung
 1.23    dyoung 	if (sc == NULL)
1.132  riastrad 		return ENXIO;
 1.23    dyoung 	if (sc->sc_state != DKW_STATE_RUNNING)
1.128  riastrad 		return ENXIO;
 1.23    dyoung
 1.27        ad 	mutex_enter(&sc->sc_dk.dk_openlock);
 1.27        ad 	mutex_enter(&sc->sc_parent->dk_rawlock);
 1.23    dyoung
 1.23    dyoung 	/* Our content type is static, no need to open the device. */
 1.23    dyoung
 1.88   mlelstv 	if (strcmp(sc->sc_ptype, DKW_PTYPE_SWAP) != 0 &&
 1.99  riastrad 	    strcmp(sc->sc_ptype, DKW_PTYPE_RAID) != 0 &&
 1.99  riastrad 	    strcmp(sc->sc_ptype, DKW_PTYPE_CGD) != 0) {
 1.23    dyoung 		rv = ENXIO;
 1.23    dyoung 		goto out;
 1.23    dyoung 	}
 1.23    dyoung 	if (size % DEV_BSIZE != 0) {
 1.23    dyoung 		rv = EINVAL;
 1.23    dyoung 		goto out;
 1.23    dyoung 	}
1.106   mlelstv
1.106   mlelstv 	p_offset = sc->sc_offset << sc->sc_parent->dk_blkshift;
1.135  riastrad 	p_size = dkwedge_size(sc) << sc->sc_parent->dk_blkshift;
1.106   mlelstv
1.129  riastrad 	if (blkno < 0 || blkno + size/DEV_BSIZE > p_size) {
 1.23    dyoung 		printf("%s: blkno (%" PRIu64 ") + size / DEV_BSIZE (%zu) > "
1.106   mlelstv 		    "p_size (%" PRIu64 ")\n", __func__, blkno,
1.129  riastrad 		    size/DEV_BSIZE, p_size);
 1.23    dyoung 		rv = EINVAL;
 1.23    dyoung 		goto out;
 1.23    dyoung 	}
 1.23    dyoung
 1.23    dyoung 	bdev = bdevsw_lookup(sc->sc_pdev);
1.106   mlelstv 	rv = (*bdev->d_dump)(sc->sc_pdev, blkno + p_offset, va, size);
 1.23    dyoung
 1.23    dyoung out:
 1.27        ad 	mutex_exit(&sc->sc_parent->dk_rawlock);
 1.27        ad 	mutex_exit(&sc->sc_dk.dk_openlock);
  1.1   thorpej
 1.23    dyoung 	return rv;
  1.1   thorpej }
 1.49     pooka
 1.49     pooka /*
 1.49     pooka  * config glue
 1.49     pooka  */
 1.49     pooka
 1.64   mlelstv /*
 1.64   mlelstv  * dkwedge_find_partition
 1.64   mlelstv  *
 1.64   mlelstv  *	Find wedge corresponding to the specified parent name
 1.64   mlelstv  *	and offset/length.
 1.64   mlelstv  */
 1.64   mlelstv device_t
 1.64   mlelstv dkwedge_find_partition(device_t parent, daddr_t startblk, uint64_t nblks)
 1.49     pooka {
 1.64   mlelstv 	struct dkwedge_softc *sc;
 1.64   mlelstv 	int i;
 1.64   mlelstv 	device_t wedge = NULL;
 1.49     pooka
 1.64   mlelstv 	rw_enter(&dkwedges_lock, RW_READER);
 1.64   mlelstv 	for (i = 0; i < ndkwedges; i++) {
 1.64   mlelstv 		if ((sc = dkwedges[i]) == NULL)
 1.64   mlelstv 			continue;
 1.64   mlelstv 		if (strcmp(sc->sc_parent->dk_name, device_xname(parent)) == 0 &&
 1.64   mlelstv 		    sc->sc_offset == startblk &&
1.135  riastrad 		    dkwedge_size(sc) == nblks) {
 1.64   mlelstv 			if (wedge) {
 1.64   mlelstv 				printf("WARNING: double match for boot wedge "
 1.64   mlelstv 				    "(%s, %s)\n",
 1.64   mlelstv 				    device_xname(wedge),
 1.64   mlelstv 				    device_xname(sc->sc_dev));
 1.64   mlelstv 				continue;
 1.64   mlelstv 			}
 1.64   mlelstv 			wedge = sc->sc_dev;
 1.64   mlelstv 		}
 1.49     pooka 	}
 1.64   mlelstv 	rw_exit(&dkwedges_lock);
 1.49     pooka
 1.64   mlelstv 	return wedge;
 1.64   mlelstv }
 1.49     pooka
 1.69  christos const char *
 1.69  christos dkwedge_get_parent_name(dev_t dev)
 1.69  christos {
 1.69  christos 	/* XXX: perhaps do this in lookup? */
 1.69  christos 	int bmaj = bdevsw_lookup_major(&dk_bdevsw);
 1.69  christos 	int cmaj = cdevsw_lookup_major(&dk_cdevsw);
1.129  riastrad
 1.69  christos 	if (major(dev) != bmaj && major(dev) != cmaj)
 1.69  christos 		return NULL;
 1.69  christos 	struct dkwedge_softc *sc = dkwedge_lookup(dev);
 1.69  christos 	if (sc == NULL)
 1.69  christos 		return NULL;
 1.69  christos 	return sc->sc_parent->dk_name;
 1.69  christos }