sys/kern/subr_devsw.c

1.30.12.1       tls /*	$NetBSD: subr_devsw.c,v 1.30.12.1 2014/08/10 06:55:58 tls Exp $	*/
     1.11        ad
      1.2   gehenna /*-
     1.20        ad  * Copyright (c) 2001, 2002, 2007, 2008 The NetBSD Foundation, Inc.
      1.2   gehenna  * All rights reserved.
      1.2   gehenna  *
      1.2   gehenna  * This code is derived from software contributed to The NetBSD Foundation
     1.11        ad  * by MAEKAWA Masahide <gehenna (at) NetBSD.org>, and by Andrew Doran.
      1.2   gehenna  *
      1.2   gehenna  * Redistribution and use in source and binary forms, with or without
      1.2   gehenna  * modification, are permitted provided that the following conditions
      1.2   gehenna  * are met:
      1.2   gehenna  * 1. Redistributions of source code must retain the above copyright
      1.2   gehenna  *    notice, this list of conditions and the following disclaimer.
      1.2   gehenna  * 2. Redistributions in binary form must reproduce the above copyright
      1.2   gehenna  *    notice, this list of conditions and the following disclaimer in the
      1.2   gehenna  *    documentation and/or other materials provided with the distribution.
      1.2   gehenna  *
      1.2   gehenna  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
      1.2   gehenna  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
      1.2   gehenna  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
      1.2   gehenna  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
      1.2   gehenna  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
      1.2   gehenna  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
      1.2   gehenna  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
      1.2   gehenna  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
      1.2   gehenna  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
      1.2   gehenna  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
      1.2   gehenna  * POSSIBILITY OF SUCH DAMAGE.
      1.2   gehenna  */
     1.11        ad
     1.11        ad /*
     1.11        ad  * Overview
     1.11        ad  *
     1.11        ad  *	subr_devsw.c: registers device drivers by name and by major
     1.11        ad  *	number, and provides wrapper methods for performing I/O and
     1.11        ad  *	other tasks on device drivers, keying on the device number
     1.11        ad  *	(dev_t).
     1.11        ad  *
     1.11        ad  *	When the system is built, the config(8) command generates
     1.11        ad  *	static tables of device drivers built into the kernel image
     1.11        ad  *	along with their associated methods.  These are recorded in
     1.11        ad  *	the cdevsw0 and bdevsw0 tables.  Drivers can also be added to
     1.11        ad  *	and removed from the system dynamically.
     1.11        ad  *
     1.11        ad  * Allocation
     1.11        ad  *
     1.11        ad  *	When the system initially boots only the statically allocated
     1.11        ad  *	indexes (bdevsw0, cdevsw0) are used.  If these overflow due to
     1.11        ad  *	allocation, we allocate a fixed block of memory to hold the new,
     1.11        ad  *	expanded index.  This "fork" of the table is only ever performed
     1.11        ad  *	once in order to guarantee that other threads may safely access
     1.11        ad  *	the device tables:
     1.11        ad  *
     1.11        ad  *	o Once a thread has a "reference" to the table via an earlier
     1.11        ad  *	  open() call, we know that the entry in the table must exist
     1.11        ad  *	  and so it is safe to access it.
     1.11        ad  *
     1.11        ad  *	o Regardless of whether other threads see the old or new
     1.11        ad  *	  pointers, they will point to a correct device switch
     1.11        ad  *	  structure for the operation being performed.
     1.11        ad  *
     1.11        ad  *	XXX Currently, the wrapper methods such as cdev_read() verify
     1.11        ad  *	that a device driver does in fact exist before calling the
     1.11        ad  *	associated driver method.  This should be changed so that
     1.11        ad  *	once the device is has been referenced by a vnode (opened),
     1.11        ad  *	calling	the other methods should be valid until that reference
     1.11        ad  *	is dropped.
     1.11        ad  */
      1.7     lukem
      1.7     lukem #include <sys/cdefs.h>
1.30.12.1       tls __KERNEL_RCSID(0, "$NetBSD: subr_devsw.c,v 1.30.12.1 2014/08/10 06:55:58 tls Exp $");
      1.2   gehenna
      1.2   gehenna #include <sys/param.h>
      1.2   gehenna #include <sys/conf.h>
     1.11        ad #include <sys/kmem.h>
      1.2   gehenna #include <sys/systm.h>
     1.11        ad #include <sys/poll.h>
     1.11        ad #include <sys/tty.h>
     1.15      matt #include <sys/cpu.h>
     1.11        ad #include <sys/buf.h>
     1.29       mrg #include <sys/reboot.h>
      1.2   gehenna
      1.2   gehenna #ifdef DEVSW_DEBUG
      1.2   gehenna #define	DPRINTF(x)	printf x
      1.2   gehenna #else /* DEVSW_DEBUG */
      1.2   gehenna #define	DPRINTF(x)
      1.2   gehenna #endif /* DEVSW_DEBUG */
      1.2   gehenna
     1.11        ad #define	MAXDEVSW	512	/* the maximum of major device number */
      1.2   gehenna #define	BDEVSW_SIZE	(sizeof(struct bdevsw *))
      1.2   gehenna #define	CDEVSW_SIZE	(sizeof(struct cdevsw *))
      1.2   gehenna #define	DEVSWCONV_SIZE	(sizeof(struct devsw_conv))
      1.2   gehenna
      1.2   gehenna extern const struct bdevsw **bdevsw, *bdevsw0[];
      1.2   gehenna extern const struct cdevsw **cdevsw, *cdevsw0[];
      1.2   gehenna extern struct devsw_conv *devsw_conv, devsw_conv0[];
      1.2   gehenna extern const int sys_bdevsws, sys_cdevsws;
      1.2   gehenna extern int max_bdevsws, max_cdevsws, max_devsw_convs;
      1.2   gehenna
     1.24  drochner static int bdevsw_attach(const struct bdevsw *, devmajor_t *);
     1.24  drochner static int cdevsw_attach(const struct cdevsw *, devmajor_t *);
     1.11        ad static void devsw_detach_locked(const struct bdevsw *, const struct cdevsw *);
     1.11        ad
     1.23     pooka kmutex_t device_lock;
     1.23     pooka
1.30.12.1       tls void (*biodone_vfs)(buf_t *) = (void *)nullop;
1.30.12.1       tls
     1.11        ad void
     1.11        ad devsw_init(void)
     1.11        ad {
     1.11        ad
     1.11        ad 	KASSERT(sys_bdevsws < MAXDEVSW - 1);
     1.11        ad 	KASSERT(sys_cdevsws < MAXDEVSW - 1);
     1.23     pooka 	mutex_init(&device_lock, MUTEX_DEFAULT, IPL_NONE);
     1.11        ad }
      1.2   gehenna
      1.2   gehenna int
     1.24  drochner devsw_attach(const char *devname,
     1.24  drochner 	     const struct bdevsw *bdev, devmajor_t *bmajor,
     1.24  drochner 	     const struct cdevsw *cdev, devmajor_t *cmajor)
      1.2   gehenna {
      1.2   gehenna 	struct devsw_conv *conv;
      1.2   gehenna 	char *name;
      1.2   gehenna 	int error, i;
     1.25     enami 	size_t len;
      1.2   gehenna
      1.2   gehenna 	if (devname == NULL || cdev == NULL)
      1.2   gehenna 		return (EINVAL);
      1.2   gehenna
     1.23     pooka 	mutex_enter(&device_lock);
     1.11        ad
      1.2   gehenna 	for (i = 0 ; i < max_devsw_convs ; i++) {
      1.2   gehenna 		conv = &devsw_conv[i];
      1.2   gehenna 		if (conv->d_name == NULL || strcmp(devname, conv->d_name) != 0)
      1.2   gehenna 			continue;
      1.2   gehenna
      1.2   gehenna 		if (*bmajor < 0)
      1.2   gehenna 			*bmajor = conv->d_bmajor;
      1.2   gehenna 		if (*cmajor < 0)
      1.2   gehenna 			*cmajor = conv->d_cmajor;
      1.2   gehenna
     1.11        ad 		if (*bmajor != conv->d_bmajor || *cmajor != conv->d_cmajor) {
     1.11        ad 			error = EINVAL;
     1.11        ad 			goto fail;
     1.11        ad 		}
     1.11        ad 		if ((*bmajor >= 0 && bdev == NULL) || *cmajor < 0) {
     1.11        ad 			error = EINVAL;
     1.11        ad 			goto fail;
     1.11        ad 		}
      1.2   gehenna
      1.2   gehenna 		if ((*bmajor >= 0 && bdevsw[*bmajor] != NULL) ||
     1.11        ad 		    cdevsw[*cmajor] != NULL) {
     1.11        ad 			error = EEXIST;
     1.11        ad 			goto fail;
     1.11        ad 		}
      1.2   gehenna
      1.2   gehenna 		if (bdev != NULL)
      1.2   gehenna 			bdevsw[*bmajor] = bdev;
      1.2   gehenna 		cdevsw[*cmajor] = cdev;
      1.2   gehenna
     1.23     pooka 		mutex_exit(&device_lock);
      1.2   gehenna 		return (0);
      1.2   gehenna 	}
      1.2   gehenna
     1.14     pooka 	error = bdevsw_attach(bdev, bmajor);
     1.11        ad 	if (error != 0)
     1.11        ad 		goto fail;
     1.14     pooka 	error = cdevsw_attach(cdev, cmajor);
      1.2   gehenna 	if (error != 0) {
     1.11        ad 		devsw_detach_locked(bdev, NULL);
     1.11        ad 		goto fail;
      1.2   gehenna 	}
      1.2   gehenna
      1.2   gehenna 	for (i = 0 ; i < max_devsw_convs ; i++) {
      1.2   gehenna 		if (devsw_conv[i].d_name == NULL)
      1.2   gehenna 			break;
      1.2   gehenna 	}
      1.2   gehenna 	if (i == max_devsw_convs) {
      1.2   gehenna 		struct devsw_conv *newptr;
      1.2   gehenna 		int old, new;
      1.2   gehenna
      1.2   gehenna 		old = max_devsw_convs;
      1.2   gehenna 		new = old + 1;
      1.2   gehenna
     1.11        ad 		newptr = kmem_zalloc(new * DEVSWCONV_SIZE, KM_NOSLEEP);
      1.2   gehenna 		if (newptr == NULL) {
     1.11        ad 			devsw_detach_locked(bdev, cdev);
     1.11        ad 			error = ENOMEM;
     1.11        ad 			goto fail;
      1.2   gehenna 		}
      1.2   gehenna 		newptr[old].d_name = NULL;
      1.2   gehenna 		newptr[old].d_bmajor = -1;
      1.2   gehenna 		newptr[old].d_cmajor = -1;
      1.2   gehenna 		memcpy(newptr, devsw_conv, old * DEVSWCONV_SIZE);
      1.2   gehenna 		if (devsw_conv != devsw_conv0)
     1.11        ad 			kmem_free(devsw_conv, old * DEVSWCONV_SIZE);
      1.2   gehenna 		devsw_conv = newptr;
      1.2   gehenna 		max_devsw_convs = new;
      1.2   gehenna 	}
      1.2   gehenna
     1.25     enami 	len = strlen(devname) + 1;
     1.25     enami 	name = kmem_alloc(len, KM_NOSLEEP);
      1.2   gehenna 	if (name == NULL) {
     1.11        ad 		devsw_detach_locked(bdev, cdev);
     1.25     enami 		error = ENOMEM;
     1.11        ad 		goto fail;
      1.2   gehenna 	}
     1.25     enami 	strlcpy(name, devname, len);
      1.2   gehenna
      1.2   gehenna 	devsw_conv[i].d_name = name;
      1.2   gehenna 	devsw_conv[i].d_bmajor = *bmajor;
      1.2   gehenna 	devsw_conv[i].d_cmajor = *cmajor;
      1.2   gehenna
     1.23     pooka 	mutex_exit(&device_lock);
      1.2   gehenna 	return (0);
     1.11        ad  fail:
     1.23     pooka 	mutex_exit(&device_lock);
     1.11        ad 	return (error);
      1.2   gehenna }
      1.2   gehenna
      1.2   gehenna static int
     1.24  drochner bdevsw_attach(const struct bdevsw *devsw, devmajor_t *devmajor)
      1.2   gehenna {
     1.11        ad 	const struct bdevsw **newptr;
     1.24  drochner 	devmajor_t bmajor;
     1.24  drochner 	int i;
      1.2   gehenna
     1.23     pooka 	KASSERT(mutex_owned(&device_lock));
     1.11        ad
      1.2   gehenna 	if (devsw == NULL)
      1.2   gehenna 		return (0);
      1.2   gehenna
      1.2   gehenna 	if (*devmajor < 0) {
      1.2   gehenna 		for (bmajor = sys_bdevsws ; bmajor < max_bdevsws ; bmajor++) {
      1.2   gehenna 			if (bdevsw[bmajor] != NULL)
      1.2   gehenna 				continue;
      1.2   gehenna 			for (i = 0 ; i < max_devsw_convs ; i++) {
      1.2   gehenna 				if (devsw_conv[i].d_bmajor == bmajor)
      1.2   gehenna 					break;
      1.2   gehenna 			}
      1.2   gehenna 			if (i != max_devsw_convs)
      1.2   gehenna 				continue;
      1.2   gehenna 			break;
      1.2   gehenna 		}
      1.3   gehenna 		*devmajor = bmajor;
      1.2   gehenna 	}
     1.11        ad
      1.2   gehenna 	if (*devmajor >= MAXDEVSW) {
     1.11        ad 		printf("bdevsw_attach: block majors exhausted");
      1.2   gehenna 		return (ENOMEM);
      1.2   gehenna 	}
      1.2   gehenna
      1.2   gehenna 	if (*devmajor >= max_bdevsws) {
     1.11        ad 		KASSERT(bdevsw == bdevsw0);
     1.11        ad 		newptr = kmem_zalloc(MAXDEVSW * BDEVSW_SIZE, KM_NOSLEEP);
      1.2   gehenna 		if (newptr == NULL)
      1.2   gehenna 			return (ENOMEM);
     1.11        ad 		memcpy(newptr, bdevsw, max_bdevsws * BDEVSW_SIZE);
      1.2   gehenna 		bdevsw = newptr;
     1.11        ad 		max_bdevsws = MAXDEVSW;
      1.2   gehenna 	}
      1.2   gehenna
      1.2   gehenna 	if (bdevsw[*devmajor] != NULL)
      1.2   gehenna 		return (EEXIST);
      1.2   gehenna
      1.2   gehenna 	bdevsw[*devmajor] = devsw;
      1.2   gehenna
      1.2   gehenna 	return (0);
      1.2   gehenna }
      1.2   gehenna
      1.2   gehenna static int
     1.24  drochner cdevsw_attach(const struct cdevsw *devsw, devmajor_t *devmajor)
      1.2   gehenna {
     1.11        ad 	const struct cdevsw **newptr;
     1.24  drochner 	devmajor_t cmajor;
     1.24  drochner 	int i;
      1.2   gehenna
     1.23     pooka 	KASSERT(mutex_owned(&device_lock));
     1.11        ad
      1.2   gehenna 	if (*devmajor < 0) {
      1.2   gehenna 		for (cmajor = sys_cdevsws ; cmajor < max_cdevsws ; cmajor++) {
      1.2   gehenna 			if (cdevsw[cmajor] != NULL)
      1.2   gehenna 				continue;
      1.2   gehenna 			for (i = 0 ; i < max_devsw_convs ; i++) {
      1.2   gehenna 				if (devsw_conv[i].d_cmajor == cmajor)
      1.2   gehenna 					break;
      1.2   gehenna 			}
      1.2   gehenna 			if (i != max_devsw_convs)
      1.2   gehenna 				continue;
      1.2   gehenna 			break;
      1.2   gehenna 		}
      1.3   gehenna 		*devmajor = cmajor;
      1.2   gehenna 	}
     1.11        ad
      1.2   gehenna 	if (*devmajor >= MAXDEVSW) {
     1.11        ad 		printf("cdevsw_attach: character majors exhausted");
      1.2   gehenna 		return (ENOMEM);
      1.2   gehenna 	}
      1.2   gehenna
      1.2   gehenna 	if (*devmajor >= max_cdevsws) {
     1.11        ad 		KASSERT(cdevsw == cdevsw0);
     1.11        ad 		newptr = kmem_zalloc(MAXDEVSW * CDEVSW_SIZE, KM_NOSLEEP);
      1.2   gehenna 		if (newptr == NULL)
      1.2   gehenna 			return (ENOMEM);
     1.11        ad 		memcpy(newptr, cdevsw, max_cdevsws * CDEVSW_SIZE);
      1.2   gehenna 		cdevsw = newptr;
     1.11        ad 		max_cdevsws = MAXDEVSW;
      1.2   gehenna 	}
      1.2   gehenna
      1.2   gehenna 	if (cdevsw[*devmajor] != NULL)
      1.2   gehenna 		return (EEXIST);
      1.2   gehenna
      1.2   gehenna 	cdevsw[*devmajor] = devsw;
      1.2   gehenna
      1.2   gehenna 	return (0);
      1.2   gehenna }
      1.2   gehenna
     1.11        ad static void
     1.11        ad devsw_detach_locked(const struct bdevsw *bdev, const struct cdevsw *cdev)
      1.2   gehenna {
      1.2   gehenna 	int i;
      1.2   gehenna
     1.23     pooka 	KASSERT(mutex_owned(&device_lock));
     1.11        ad
      1.2   gehenna 	if (bdev != NULL) {
      1.2   gehenna 		for (i = 0 ; i < max_bdevsws ; i++) {
      1.2   gehenna 			if (bdevsw[i] != bdev)
      1.2   gehenna 				continue;
      1.2   gehenna 			bdevsw[i] = NULL;
      1.2   gehenna 			break;
      1.2   gehenna 		}
      1.2   gehenna 	}
      1.2   gehenna 	if (cdev != NULL) {
      1.2   gehenna 		for (i = 0 ; i < max_cdevsws ; i++) {
      1.2   gehenna 			if (cdevsw[i] != cdev)
      1.2   gehenna 				continue;
      1.2   gehenna 			cdevsw[i] = NULL;
      1.2   gehenna 			break;
      1.2   gehenna 		}
      1.2   gehenna 	}
      1.2   gehenna }
      1.2   gehenna
     1.19        ad int
     1.11        ad devsw_detach(const struct bdevsw *bdev, const struct cdevsw *cdev)
     1.11        ad {
     1.11        ad
     1.23     pooka 	mutex_enter(&device_lock);
     1.11        ad 	devsw_detach_locked(bdev, cdev);
     1.23     pooka 	mutex_exit(&device_lock);
     1.19        ad 	return 0;
     1.11        ad }
     1.11        ad
     1.11        ad /*
     1.11        ad  * Look up a block device by number.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is attached.
     1.11        ad  */
      1.2   gehenna const struct bdevsw *
      1.2   gehenna bdevsw_lookup(dev_t dev)
      1.2   gehenna {
     1.24  drochner 	devmajor_t bmajor;
      1.2   gehenna
      1.2   gehenna 	if (dev == NODEV)
      1.2   gehenna 		return (NULL);
      1.2   gehenna 	bmajor = major(dev);
      1.2   gehenna 	if (bmajor < 0 || bmajor >= max_bdevsws)
      1.2   gehenna 		return (NULL);
      1.2   gehenna
      1.2   gehenna 	return (bdevsw[bmajor]);
      1.2   gehenna }
      1.2   gehenna
     1.11        ad /*
     1.11        ad  * Look up a character device by number.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is attached.
     1.11        ad  */
      1.2   gehenna const struct cdevsw *
      1.2   gehenna cdevsw_lookup(dev_t dev)
      1.2   gehenna {
     1.24  drochner 	devmajor_t cmajor;
      1.2   gehenna
      1.2   gehenna 	if (dev == NODEV)
      1.2   gehenna 		return (NULL);
      1.2   gehenna 	cmajor = major(dev);
      1.2   gehenna 	if (cmajor < 0 || cmajor >= max_cdevsws)
      1.2   gehenna 		return (NULL);
      1.2   gehenna
      1.2   gehenna 	return (cdevsw[cmajor]);
      1.2   gehenna }
      1.2   gehenna
     1.11        ad /*
     1.11        ad  * Look up a block device by reference to its operations set.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is not detached, and therefore
     1.11        ad  *    that the returned major is still valid when dereferenced.
     1.11        ad  */
     1.24  drochner devmajor_t
      1.2   gehenna bdevsw_lookup_major(const struct bdevsw *bdev)
      1.2   gehenna {
     1.24  drochner 	devmajor_t bmajor;
      1.2   gehenna
      1.2   gehenna 	for (bmajor = 0 ; bmajor < max_bdevsws ; bmajor++) {
      1.2   gehenna 		if (bdevsw[bmajor] == bdev)
      1.2   gehenna 			return (bmajor);
      1.2   gehenna 	}
      1.2   gehenna
     1.24  drochner 	return (NODEVMAJOR);
      1.2   gehenna }
      1.2   gehenna
     1.11        ad /*
     1.11        ad  * Look up a character device by reference to its operations set.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is not detached, and therefore
     1.11        ad  *    that the returned major is still valid when dereferenced.
     1.11        ad  */
     1.24  drochner devmajor_t
      1.2   gehenna cdevsw_lookup_major(const struct cdevsw *cdev)
      1.2   gehenna {
     1.24  drochner 	devmajor_t cmajor;
      1.2   gehenna
      1.2   gehenna 	for (cmajor = 0 ; cmajor < max_cdevsws ; cmajor++) {
      1.2   gehenna 		if (cdevsw[cmajor] == cdev)
      1.2   gehenna 			return (cmajor);
      1.2   gehenna 	}
      1.2   gehenna
     1.24  drochner 	return (NODEVMAJOR);
      1.2   gehenna }
      1.2   gehenna
      1.2   gehenna /*
      1.2   gehenna  * Convert from block major number to name.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is not detached, and therefore
     1.11        ad  *    that the name pointer is still valid when dereferenced.
      1.2   gehenna  */
      1.2   gehenna const char *
     1.24  drochner devsw_blk2name(devmajor_t bmajor)
      1.2   gehenna {
     1.11        ad 	const char *name;
     1.24  drochner 	devmajor_t cmajor;
     1.24  drochner 	int i;
      1.2   gehenna
     1.11        ad 	name = NULL;
     1.11        ad 	cmajor = -1;
     1.11        ad
     1.23     pooka 	mutex_enter(&device_lock);
     1.11        ad 	if (bmajor < 0 || bmajor >= max_bdevsws || bdevsw[bmajor] == NULL) {
     1.23     pooka 		mutex_exit(&device_lock);
      1.2   gehenna 		return (NULL);
      1.2   gehenna 	}
     1.11        ad 	for (i = 0 ; i < max_devsw_convs; i++) {
     1.11        ad 		if (devsw_conv[i].d_bmajor == bmajor) {
     1.11        ad 			cmajor = devsw_conv[i].d_cmajor;
     1.11        ad 			break;
     1.11        ad 		}
     1.11        ad 	}
     1.11        ad 	if (cmajor >= 0 && cmajor < max_cdevsws && cdevsw[cmajor] != NULL)
     1.11        ad 		name = devsw_conv[i].d_name;
     1.23     pooka 	mutex_exit(&device_lock);
      1.2   gehenna
     1.11        ad 	return (name);
      1.2   gehenna }
      1.2   gehenna
      1.2   gehenna /*
     1.26      haad  * Convert char major number to device driver name.
     1.26      haad  */
     1.27      yamt const char *
     1.26      haad cdevsw_getname(devmajor_t major)
     1.26      haad {
     1.26      haad 	const char *name;
     1.26      haad 	int i;
     1.26      haad
     1.26      haad 	name = NULL;
     1.26      haad
     1.26      haad 	if (major < 0)
     1.26      haad 		return (NULL);
     1.26      haad
     1.26      haad 	mutex_enter(&device_lock);
     1.26      haad 	for (i = 0 ; i < max_devsw_convs; i++) {
     1.26      haad 		if (devsw_conv[i].d_cmajor == major) {
     1.26      haad 			name = devsw_conv[i].d_name;
     1.26      haad 			break;
     1.26      haad 		}
     1.26      haad 	}
     1.26      haad 	mutex_exit(&device_lock);
     1.26      haad 	return (name);
     1.26      haad }
     1.26      haad
     1.26      haad /*
     1.26      haad  * Convert block major number to device driver name.
     1.26      haad  */
     1.27      yamt const char *
     1.26      haad bdevsw_getname(devmajor_t major)
     1.26      haad {
     1.26      haad 	const char *name;
     1.26      haad 	int i;
     1.26      haad
     1.26      haad 	name = NULL;
     1.26      haad
     1.26      haad 	if (major < 0)
     1.26      haad 		return (NULL);
     1.26      haad
     1.26      haad 	mutex_enter(&device_lock);
     1.26      haad 	for (i = 0 ; i < max_devsw_convs; i++) {
     1.26      haad 		if (devsw_conv[i].d_bmajor == major) {
     1.26      haad 			name = devsw_conv[i].d_name;
     1.26      haad 			break;
     1.26      haad 		}
     1.26      haad 	}
     1.26      haad 	mutex_exit(&device_lock);
     1.26      haad 	return (name);
     1.26      haad }
     1.26      haad
     1.26      haad /*
      1.2   gehenna  * Convert from device name to block major number.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is not detached, and therefore
     1.11        ad  *    that the major number is still valid when dereferenced.
      1.2   gehenna  */
     1.24  drochner devmajor_t
      1.2   gehenna devsw_name2blk(const char *name, char *devname, size_t devnamelen)
      1.2   gehenna {
      1.2   gehenna 	struct devsw_conv *conv;
     1.24  drochner 	devmajor_t bmajor;
     1.24  drochner 	int i;
      1.2   gehenna
      1.2   gehenna 	if (name == NULL)
     1.24  drochner 		return (NODEVMAJOR);
      1.2   gehenna
     1.23     pooka 	mutex_enter(&device_lock);
      1.2   gehenna 	for (i = 0 ; i < max_devsw_convs ; i++) {
      1.5       mrg 		size_t len;
      1.5       mrg
      1.2   gehenna 		conv = &devsw_conv[i];
      1.2   gehenna 		if (conv->d_name == NULL)
      1.2   gehenna 			continue;
      1.5       mrg 		len = strlen(conv->d_name);
      1.5       mrg 		if (strncmp(conv->d_name, name, len) != 0)
      1.5       mrg 			continue;
      1.5       mrg 		if (*(name +len) && !isdigit(*(name + len)))
      1.2   gehenna 			continue;
      1.2   gehenna 		bmajor = conv->d_bmajor;
      1.2   gehenna 		if (bmajor < 0 || bmajor >= max_bdevsws ||
      1.2   gehenna 		    bdevsw[bmajor] == NULL)
      1.5       mrg 			break;
      1.2   gehenna 		if (devname != NULL) {
      1.2   gehenna #ifdef DEVSW_DEBUG
      1.2   gehenna 			if (strlen(conv->d_name) >= devnamelen)
      1.2   gehenna 				printf("devsw_name2blk: too short buffer");
      1.2   gehenna #endif /* DEVSW_DEBUG */
      1.4   tsutsui 			strncpy(devname, conv->d_name, devnamelen);
      1.2   gehenna 			devname[devnamelen - 1] = '\0';
      1.2   gehenna 		}
     1.23     pooka 		mutex_exit(&device_lock);
      1.2   gehenna 		return (bmajor);
      1.2   gehenna 	}
      1.2   gehenna
     1.23     pooka 	mutex_exit(&device_lock);
     1.24  drochner 	return (NODEVMAJOR);
      1.2   gehenna }
      1.2   gehenna
      1.2   gehenna /*
     1.16    plunky  * Convert from device name to char major number.
     1.16    plunky  *
     1.16    plunky  * => Caller must ensure that the device is not detached, and therefore
     1.16    plunky  *    that the major number is still valid when dereferenced.
     1.16    plunky  */
     1.24  drochner devmajor_t
     1.16    plunky devsw_name2chr(const char *name, char *devname, size_t devnamelen)
     1.16    plunky {
     1.16    plunky 	struct devsw_conv *conv;
     1.24  drochner 	devmajor_t cmajor;
     1.24  drochner 	int i;
     1.16    plunky
     1.16    plunky 	if (name == NULL)
     1.24  drochner 		return (NODEVMAJOR);
     1.16    plunky
     1.23     pooka 	mutex_enter(&device_lock);
     1.16    plunky 	for (i = 0 ; i < max_devsw_convs ; i++) {
     1.16    plunky 		size_t len;
     1.16    plunky
     1.16    plunky 		conv = &devsw_conv[i];
     1.16    plunky 		if (conv->d_name == NULL)
     1.16    plunky 			continue;
     1.16    plunky 		len = strlen(conv->d_name);
     1.16    plunky 		if (strncmp(conv->d_name, name, len) != 0)
     1.16    plunky 			continue;
     1.16    plunky 		if (*(name +len) && !isdigit(*(name + len)))
     1.16    plunky 			continue;
     1.16    plunky 		cmajor = conv->d_cmajor;
     1.16    plunky 		if (cmajor < 0 || cmajor >= max_cdevsws ||
     1.16    plunky 		    cdevsw[cmajor] == NULL)
     1.16    plunky 			break;
     1.16    plunky 		if (devname != NULL) {
     1.16    plunky #ifdef DEVSW_DEBUG
     1.16    plunky 			if (strlen(conv->d_name) >= devnamelen)
     1.16    plunky 				printf("devsw_name2chr: too short buffer");
     1.16    plunky #endif /* DEVSW_DEBUG */
     1.16    plunky 			strncpy(devname, conv->d_name, devnamelen);
     1.16    plunky 			devname[devnamelen - 1] = '\0';
     1.16    plunky 		}
     1.23     pooka 		mutex_exit(&device_lock);
     1.16    plunky 		return (cmajor);
     1.16    plunky 	}
     1.16    plunky
     1.23     pooka 	mutex_exit(&device_lock);
     1.24  drochner 	return (NODEVMAJOR);
     1.16    plunky }
     1.16    plunky
     1.16    plunky /*
      1.2   gehenna  * Convert from character dev_t to block dev_t.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is not detached, and therefore
     1.11        ad  *    that the major number is still valid when dereferenced.
      1.2   gehenna  */
      1.2   gehenna dev_t
      1.2   gehenna devsw_chr2blk(dev_t cdev)
      1.2   gehenna {
     1.24  drochner 	devmajor_t bmajor, cmajor;
     1.24  drochner 	int i;
     1.11        ad 	dev_t rv;
      1.2   gehenna
      1.2   gehenna 	cmajor = major(cdev);
     1.24  drochner 	bmajor = NODEVMAJOR;
     1.11        ad 	rv = NODEV;
      1.2   gehenna
     1.23     pooka 	mutex_enter(&device_lock);
     1.11        ad 	if (cmajor < 0 || cmajor >= max_cdevsws || cdevsw[cmajor] == NULL) {
     1.23     pooka 		mutex_exit(&device_lock);
     1.11        ad 		return (NODEV);
     1.11        ad 	}
      1.2   gehenna 	for (i = 0 ; i < max_devsw_convs ; i++) {
     1.11        ad 		if (devsw_conv[i].d_cmajor == cmajor) {
     1.11        ad 			bmajor = devsw_conv[i].d_bmajor;
     1.11        ad 			break;
     1.11        ad 		}
      1.2   gehenna 	}
     1.11        ad 	if (bmajor >= 0 && bmajor < max_bdevsws && bdevsw[bmajor] != NULL)
     1.11        ad 		rv = makedev(bmajor, minor(cdev));
     1.23     pooka 	mutex_exit(&device_lock);
      1.2   gehenna
     1.11        ad 	return (rv);
      1.2   gehenna }
      1.2   gehenna
      1.2   gehenna /*
      1.2   gehenna  * Convert from block dev_t to character dev_t.
     1.11        ad  *
     1.11        ad  * => Caller must ensure that the device is not detached, and therefore
     1.11        ad  *    that the major number is still valid when dereferenced.
      1.2   gehenna  */
      1.2   gehenna dev_t
      1.2   gehenna devsw_blk2chr(dev_t bdev)
      1.2   gehenna {
     1.24  drochner 	devmajor_t bmajor, cmajor;
     1.24  drochner 	int i;
     1.11        ad 	dev_t rv;
      1.2   gehenna
     1.11        ad 	bmajor = major(bdev);
     1.24  drochner 	cmajor = NODEVMAJOR;
     1.11        ad 	rv = NODEV;
     1.11        ad
     1.23     pooka 	mutex_enter(&device_lock);
     1.11        ad 	if (bmajor < 0 || bmajor >= max_bdevsws || bdevsw[bmajor] == NULL) {
     1.23     pooka 		mutex_exit(&device_lock);
      1.2   gehenna 		return (NODEV);
     1.11        ad 	}
     1.11        ad 	for (i = 0 ; i < max_devsw_convs ; i++) {
     1.11        ad 		if (devsw_conv[i].d_bmajor == bmajor) {
     1.11        ad 			cmajor = devsw_conv[i].d_cmajor;
     1.11        ad 			break;
     1.11        ad 		}
     1.11        ad 	}
     1.11        ad 	if (cmajor >= 0 && cmajor < max_cdevsws && cdevsw[cmajor] != NULL)
     1.11        ad 		rv = makedev(cmajor, minor(bdev));
     1.23     pooka 	mutex_exit(&device_lock);
      1.2   gehenna
     1.11        ad 	return (rv);
     1.11        ad }
     1.11        ad
     1.11        ad /*
     1.11        ad  * Device access methods.
     1.11        ad  */
     1.11        ad
     1.11        ad #define	DEV_LOCK(d)						\
     1.17        ad 	if ((mpflag = (d->d_flag & D_MPSAFE)) == 0) {		\
     1.17        ad 		KERNEL_LOCK(1, NULL);				\
     1.11        ad 	}
      1.2   gehenna
     1.11        ad #define	DEV_UNLOCK(d)						\
     1.17        ad 	if (mpflag == 0) {					\
     1.17        ad 		KERNEL_UNLOCK_ONE(NULL);			\
      1.2   gehenna 	}
      1.2   gehenna
     1.11        ad int
     1.11        ad bdev_open(dev_t dev, int flag, int devtype, lwp_t *l)
     1.11        ad {
     1.11        ad 	const struct bdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	/*
     1.11        ad 	 * For open we need to lock, in order to synchronize
     1.11        ad 	 * with attach/detach.
     1.11        ad 	 */
     1.23     pooka 	mutex_enter(&device_lock);
     1.11        ad 	d = bdevsw_lookup(dev);
     1.23     pooka 	mutex_exit(&device_lock);
     1.11        ad 	if (d == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_open)(dev, flag, devtype, l);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad bdev_close(dev_t dev, int flag, int devtype, lwp_t *l)
     1.11        ad {
     1.11        ad 	const struct bdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = bdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_close)(dev, flag, devtype, l);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad void
     1.11        ad bdev_strategy(struct buf *bp)
     1.11        ad {
     1.11        ad 	const struct bdevsw *d;
     1.17        ad 	int mpflag;
     1.11        ad
     1.28  jmcneill 	if ((d = bdevsw_lookup(bp->b_dev)) == NULL) {
     1.28  jmcneill 		bp->b_error = ENXIO;
     1.28  jmcneill 		bp->b_resid = bp->b_bcount;
1.30.12.1       tls 		biodone_vfs(bp); /* biodone() iff vfs present */
     1.28  jmcneill 		return;
     1.28  jmcneill 	}
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	(*d->d_strategy)(bp);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad bdev_ioctl(dev_t dev, u_long cmd, void *data, int flag, lwp_t *l)
     1.11        ad {
     1.11        ad 	const struct bdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = bdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_ioctl)(dev, cmd, data, flag, l);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad bdev_dump(dev_t dev, daddr_t addr, void *data, size_t sz)
     1.11        ad {
     1.11        ad 	const struct bdevsw *d;
     1.11        ad 	int rv;
     1.11        ad
     1.11        ad 	/*
     1.11        ad 	 * Dump can be called without the device open.  Since it can
     1.11        ad 	 * currently only be called with the system paused (and in a
     1.11        ad 	 * potentially unstable state), we don't perform any locking.
     1.11        ad 	 */
     1.11        ad 	if ((d = bdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	/* DEV_LOCK(d); */
     1.11        ad 	rv = (*d->d_dump)(dev, addr, data, sz);
     1.11        ad 	/* DEV_UNLOCK(d); */
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad bdev_type(dev_t dev)
     1.11        ad {
     1.11        ad 	const struct bdevsw *d;
     1.11        ad
     1.11        ad 	if ((d = bdevsw_lookup(dev)) == NULL)
     1.11        ad 		return D_OTHER;
     1.11        ad 	return d->d_flag & D_TYPEMASK;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.29       mrg bdev_size(dev_t dev)
     1.29       mrg {
     1.29       mrg 	const struct bdevsw *d;
     1.29       mrg 	int rv, mpflag = 0;
     1.29       mrg
     1.29       mrg 	if ((d = bdevsw_lookup(dev)) == NULL ||
     1.29       mrg 	    d->d_psize == NULL)
     1.29       mrg 		return -1;
     1.29       mrg
     1.29       mrg 	/*
     1.29       mrg 	 * Don't to try lock the device if we're dumping.
     1.30       mrg 	 * XXX: is there a better way to test this?
     1.29       mrg 	 */
     1.29       mrg 	if ((boothowto & RB_DUMP) == 0)
     1.29       mrg 		DEV_LOCK(d);
     1.29       mrg 	rv = (*d->d_psize)(dev);
     1.29       mrg 	if ((boothowto & RB_DUMP) == 0)
     1.29       mrg 		DEV_UNLOCK(d);
     1.29       mrg
     1.29       mrg 	return rv;
     1.29       mrg }
     1.29       mrg
     1.29       mrg int
1.30.12.1       tls bdev_discard(dev_t dev, off_t pos, off_t len)
1.30.12.1       tls {
1.30.12.1       tls 	const struct bdevsw *d;
1.30.12.1       tls 	int rv, mpflag;
1.30.12.1       tls
1.30.12.1       tls 	if ((d = bdevsw_lookup(dev)) == NULL)
1.30.12.1       tls 		return ENXIO;
1.30.12.1       tls
1.30.12.1       tls 	DEV_LOCK(d);
1.30.12.1       tls 	rv = (*d->d_discard)(dev, pos, len);
1.30.12.1       tls 	DEV_UNLOCK(d);
1.30.12.1       tls
1.30.12.1       tls 	return rv;
1.30.12.1       tls }
1.30.12.1       tls
1.30.12.1       tls int
     1.11        ad cdev_open(dev_t dev, int flag, int devtype, lwp_t *l)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	/*
     1.11        ad 	 * For open we need to lock, in order to synchronize
     1.11        ad 	 * with attach/detach.
     1.11        ad 	 */
     1.23     pooka 	mutex_enter(&device_lock);
     1.11        ad 	d = cdevsw_lookup(dev);
     1.23     pooka 	mutex_exit(&device_lock);
     1.11        ad 	if (d == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_open)(dev, flag, devtype, l);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad cdev_close(dev_t dev, int flag, int devtype, lwp_t *l)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_close)(dev, flag, devtype, l);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad cdev_read(dev_t dev, struct uio *uio, int flag)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_read)(dev, uio, flag);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad cdev_write(dev_t dev, struct uio *uio, int flag)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_write)(dev, uio, flag);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad cdev_ioctl(dev_t dev, u_long cmd, void *data, int flag, lwp_t *l)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_ioctl)(dev, cmd, data, flag, l);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad void
     1.11        ad cdev_stop(struct tty *tp, int flag)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(tp->t_dev)) == NULL)
     1.11        ad 		return;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	(*d->d_stop)(tp, flag);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad }
     1.11        ad
     1.11        ad struct tty *
     1.11        ad cdev_tty(dev_t dev)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return NULL;
     1.11        ad
     1.12        ad 	/* XXX Check if necessary. */
     1.12        ad 	if (d->d_tty == NULL)
     1.12        ad 		return NULL;
     1.12        ad
     1.21        ad 	return (*d->d_tty)(dev);
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad cdev_poll(dev_t dev, int flag, lwp_t *l)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return POLLERR;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_poll)(dev, flag, l);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad paddr_t
     1.11        ad cdev_mmap(dev_t dev, off_t off, int flag)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.11        ad 	paddr_t rv;
     1.17        ad 	int mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return (paddr_t)-1LL;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_mmap)(dev, off, flag);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
     1.11        ad cdev_kqfilter(dev_t dev, struct knote *kn)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.17        ad 	int rv, mpflag;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return ENXIO;
     1.11        ad
     1.11        ad 	DEV_LOCK(d);
     1.11        ad 	rv = (*d->d_kqfilter)(dev, kn);
     1.11        ad 	DEV_UNLOCK(d);
     1.11        ad
     1.11        ad 	return rv;
     1.11        ad }
     1.11        ad
     1.11        ad int
1.30.12.1       tls cdev_discard(dev_t dev, off_t pos, off_t len)
1.30.12.1       tls {
1.30.12.1       tls 	const struct cdevsw *d;
1.30.12.1       tls 	int rv, mpflag;
1.30.12.1       tls
1.30.12.1       tls 	if ((d = cdevsw_lookup(dev)) == NULL)
1.30.12.1       tls 		return ENXIO;
1.30.12.1       tls
1.30.12.1       tls 	DEV_LOCK(d);
1.30.12.1       tls 	rv = (*d->d_discard)(dev, pos, len);
1.30.12.1       tls 	DEV_UNLOCK(d);
1.30.12.1       tls
1.30.12.1       tls 	return rv;
1.30.12.1       tls }
1.30.12.1       tls
1.30.12.1       tls int
     1.11        ad cdev_type(dev_t dev)
     1.11        ad {
     1.11        ad 	const struct cdevsw *d;
     1.11        ad
     1.11        ad 	if ((d = cdevsw_lookup(dev)) == NULL)
     1.11        ad 		return D_OTHER;
     1.11        ad 	return d->d_flag & D_TYPEMASK;
      1.2   gehenna }