sys/kern/vfs_vnode.c

1.144   thorpej /*	$NetBSD: vfs_vnode.c,v 1.144 2022/07/18 04:30:30 thorpej Exp $	*/
  1.1     rmind
  1.1     rmind /*-
1.111        ad  * Copyright (c) 1997-2011, 2019, 2020 The NetBSD Foundation, Inc.
  1.1     rmind  * All rights reserved.
  1.1     rmind  *
  1.1     rmind  * This code is derived from software contributed to The NetBSD Foundation
  1.1     rmind  * by Jason R. Thorpe of the Numerical Aerospace Simulation Facility,
  1.1     rmind  * NASA Ames Research Center, by Charles M. Hannum, and by Andrew Doran.
  1.1     rmind  *
  1.1     rmind  * Redistribution and use in source and binary forms, with or without
  1.1     rmind  * modification, are permitted provided that the following conditions
  1.1     rmind  * are met:
  1.1     rmind  * 1. Redistributions of source code must retain the above copyright
  1.1     rmind  *    notice, this list of conditions and the following disclaimer.
  1.1     rmind  * 2. Redistributions in binary form must reproduce the above copyright
  1.1     rmind  *    notice, this list of conditions and the following disclaimer in the
  1.1     rmind  *    documentation and/or other materials provided with the distribution.
  1.1     rmind  *
  1.1     rmind  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
  1.1     rmind  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
  1.1     rmind  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  1.1     rmind  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
  1.1     rmind  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  1.1     rmind  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  1.1     rmind  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
  1.1     rmind  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
  1.1     rmind  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
  1.1     rmind  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
  1.1     rmind  * POSSIBILITY OF SUCH DAMAGE.
  1.1     rmind  */
  1.1     rmind
  1.1     rmind /*
  1.1     rmind  * Copyright (c) 1989, 1993
  1.1     rmind  *	The Regents of the University of California.  All rights reserved.
  1.1     rmind  * (c) UNIX System Laboratories, Inc.
  1.1     rmind  * All or some portions of this file are derived from material licensed
  1.1     rmind  * to the University of California by American Telephone and Telegraph
  1.1     rmind  * Co. or Unix System Laboratories, Inc. and are reproduced herein with
  1.1     rmind  * the permission of UNIX System Laboratories, Inc.
  1.1     rmind  *
  1.1     rmind  * Redistribution and use in source and binary forms, with or without
  1.1     rmind  * modification, are permitted provided that the following conditions
  1.1     rmind  * are met:
  1.1     rmind  * 1. Redistributions of source code must retain the above copyright
  1.1     rmind  *    notice, this list of conditions and the following disclaimer.
  1.1     rmind  * 2. Redistributions in binary form must reproduce the above copyright
  1.1     rmind  *    notice, this list of conditions and the following disclaimer in the
  1.1     rmind  *    documentation and/or other materials provided with the distribution.
  1.1     rmind  * 3. Neither the name of the University nor the names of its contributors
  1.1     rmind  *    may be used to endorse or promote products derived from this software
  1.1     rmind  *    without specific prior written permission.
  1.1     rmind  *
  1.1     rmind  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
  1.1     rmind  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  1.1     rmind  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
  1.1     rmind  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
  1.1     rmind  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
  1.1     rmind  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
  1.1     rmind  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
  1.1     rmind  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
  1.1     rmind  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
  1.1     rmind  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  1.1     rmind  * SUCH DAMAGE.
  1.1     rmind  *
  1.1     rmind  *	@(#)vfs_subr.c	8.13 (Berkeley) 4/18/94
  1.1     rmind  */
  1.1     rmind
  1.1     rmind /*
  1.8     rmind  * The vnode cache subsystem.
  1.1     rmind  *
  1.8     rmind  * Life-cycle
  1.1     rmind  *
  1.8     rmind  *	Normally, there are two points where new vnodes are created:
  1.8     rmind  *	VOP_CREATE(9) and VOP_LOOKUP(9).  The life-cycle of a vnode
  1.8     rmind  *	starts in one of the following ways:
  1.8     rmind  *
 1.45   hannken  *	- Allocation, via vcache_get(9) or vcache_new(9).
 1.66   hannken  *	- Reclamation of inactive vnode, via vcache_vget(9).
  1.8     rmind  *
 1.16     rmind  *	Recycle from a free list, via getnewvnode(9) -> getcleanvnode(9)
 1.16     rmind  *	was another, traditional way.  Currently, only the draining thread
 1.16     rmind  *	recycles the vnodes.  This behaviour might be revisited.
 1.16     rmind  *
  1.8     rmind  *	The life-cycle ends when the last reference is dropped, usually
  1.8     rmind  *	in VOP_REMOVE(9).  In such case, VOP_INACTIVE(9) is called to inform
  1.8     rmind  *	the file system that vnode is inactive.  Via this call, file system
 1.16     rmind  *	indicates whether vnode can be recycled (usually, it checks its own
 1.16     rmind  *	references, e.g. count of links, whether the file was removed).
  1.8     rmind  *
  1.8     rmind  *	Depending on indication, vnode can be put into a free list (cache),
 1.54   hannken  *	or cleaned via vcache_reclaim, which calls VOP_RECLAIM(9) to
 1.54   hannken  *	disassociate underlying file system from the vnode, and finally
 1.54   hannken  *	destroyed.
  1.8     rmind  *
 1.52   hannken  * Vnode state
 1.52   hannken  *
 1.52   hannken  *	Vnode is always in one of six states:
 1.52   hannken  *	- MARKER	This is a marker vnode to help list traversal.  It
 1.52   hannken  *			will never change its state.
 1.52   hannken  *	- LOADING	Vnode is associating underlying file system and not
 1.52   hannken  *			yet ready to use.
 1.94   hannken  *	- LOADED	Vnode has associated underlying file system and is
 1.52   hannken  *			ready to use.
 1.52   hannken  *	- BLOCKED	Vnode is active but cannot get new references.
 1.52   hannken  *	- RECLAIMING	Vnode is disassociating from the underlying file
 1.52   hannken  *			system.
 1.52   hannken  *	- RECLAIMED	Vnode has disassociated from underlying file system
 1.52   hannken  *			and is dead.
 1.52   hannken  *
 1.52   hannken  *	Valid state changes are:
 1.94   hannken  *	LOADING -> LOADED
 1.52   hannken  *			Vnode has been initialised in vcache_get() or
 1.52   hannken  *			vcache_new() and is ready to use.
1.123        ad  *	BLOCKED -> RECLAIMING
 1.52   hannken  *			Vnode starts disassociation from underlying file
 1.54   hannken  *			system in vcache_reclaim().
 1.52   hannken  *	RECLAIMING -> RECLAIMED
 1.52   hannken  *			Vnode finished disassociation from underlying file
 1.54   hannken  *			system in vcache_reclaim().
 1.94   hannken  *	LOADED -> BLOCKED
 1.52   hannken  *			Either vcache_rekey*() is changing the vnode key or
 1.52   hannken  *			vrelel() is about to call VOP_INACTIVE().
 1.94   hannken  *	BLOCKED -> LOADED
 1.52   hannken  *			The block condition is over.
 1.52   hannken  *	LOADING -> RECLAIMED
 1.52   hannken  *			Either vcache_get() or vcache_new() failed to
 1.52   hannken  *			associate the underlying file system or vcache_rekey*()
 1.52   hannken  *			drops a vnode used as placeholder.
 1.52   hannken  *
 1.52   hannken  *	Of these states LOADING, BLOCKED and RECLAIMING are intermediate
 1.52   hannken  *	and it is possible to wait for state change.
 1.52   hannken  *
 1.52   hannken  *	State is protected with v_interlock with one exception:
 1.69   hannken  *	to change from LOADING both v_interlock and vcache_lock must be held
 1.52   hannken  *	so it is possible to check "state == LOADING" without holding
 1.52   hannken  *	v_interlock.  See vcache_get() for details.
 1.52   hannken  *
  1.8     rmind  * Reference counting
  1.8     rmind  *
  1.8     rmind  *	Vnode is considered active, if reference count (vnode_t::v_usecount)
  1.8     rmind  *	is non-zero.  It is maintained using: vref(9) and vrele(9), as well
  1.8     rmind  *	as vput(9), routines.  Common points holding references are e.g.
  1.8     rmind  *	file openings, current working directory, mount points, etc.
  1.8     rmind  *
1.123        ad  *	v_usecount is adjusted with atomic operations, however to change
1.123        ad  *	from a non-zero value to zero the interlock must also be held.
  1.1     rmind  */
  1.1     rmind
  1.1     rmind #include <sys/cdefs.h>
1.144   thorpej __KERNEL_RCSID(0, "$NetBSD: vfs_vnode.c,v 1.144 2022/07/18 04:30:30 thorpej Exp $");
1.108        ad
1.109        ad #ifdef _KERNEL_OPT
1.108        ad #include "opt_pax.h"
1.109        ad #endif
  1.1     rmind
  1.1     rmind #include <sys/param.h>
  1.1     rmind #include <sys/kernel.h>
  1.1     rmind
  1.1     rmind #include <sys/atomic.h>
  1.1     rmind #include <sys/buf.h>
  1.1     rmind #include <sys/conf.h>
  1.1     rmind #include <sys/device.h>
 1.36   hannken #include <sys/hash.h>
  1.1     rmind #include <sys/kauth.h>
  1.1     rmind #include <sys/kmem.h>
  1.1     rmind #include <sys/kthread.h>
  1.1     rmind #include <sys/module.h>
  1.1     rmind #include <sys/mount.h>
  1.1     rmind #include <sys/namei.h>
1.108        ad #include <sys/pax.h>
  1.1     rmind #include <sys/syscallargs.h>
  1.1     rmind #include <sys/sysctl.h>
  1.1     rmind #include <sys/systm.h>
 1.58   hannken #include <sys/vnode_impl.h>
  1.1     rmind #include <sys/wapbl.h>
 1.24   hannken #include <sys/fstrans.h>
  1.1     rmind
  1.1     rmind #include <uvm/uvm.h>
  1.1     rmind #include <uvm/uvm_readahead.h>
1.104        ad #include <uvm/uvm_stat.h>
  1.1     rmind
 1.23   hannken /* Flags to vrelel. */
1.104        ad #define	VRELEL_ASYNC	0x0001	/* Always defer to vrele thread. */
1.104        ad
1.104        ad #define	LRU_VRELE	0
1.104        ad #define	LRU_FREE	1
1.104        ad #define	LRU_HOLD	2
1.104        ad #define	LRU_COUNT	3
  1.1     rmind
 1.16     rmind /*
 1.63   hannken  * There are three lru lists: one holds vnodes waiting for async release,
1.104        ad  * one is for vnodes which have no buffer/page references and one for those
1.104        ad  * which do (i.e.  v_holdcnt is non-zero).  We put the lists into a single,
1.104        ad  * private cache line as vnodes migrate between them while under the same
1.104        ad  * lock (vdrain_lock).
 1.63   hannken  */
1.104        ad u_int			numvnodes		__cacheline_aligned;
1.104        ad static vnodelst_t	lru_list[LRU_COUNT]	__cacheline_aligned;
 1.63   hannken static kmutex_t		vdrain_lock		__cacheline_aligned;
1.104        ad static kcondvar_t	vdrain_cv;
 1.63   hannken static int		vdrain_gen;
 1.63   hannken static kcondvar_t	vdrain_gen_cv;
 1.63   hannken static bool		vdrain_retry;
 1.63   hannken static lwp_t *		vdrain_lwp;
 1.57   hannken SLIST_HEAD(hashhead, vnode_impl);
 1.69   hannken static kmutex_t		vcache_lock		__cacheline_aligned;
1.104        ad static kcondvar_t	vcache_cv;
 1.69   hannken static u_int		vcache_hashsize;
 1.69   hannken static u_long		vcache_hashmask;
1.104        ad static struct hashhead	*vcache_hashtab;
 1.69   hannken static pool_cache_t	vcache_pool;
 1.63   hannken static void		lru_requeue(vnode_t *, vnodelst_t *);
 1.63   hannken static vnodelst_t *	lru_which(vnode_t *);
 1.63   hannken static vnode_impl_t *	vcache_alloc(void);
 1.79   hannken static void		vcache_dealloc(vnode_impl_t *);
 1.57   hannken static void		vcache_free(vnode_impl_t *);
 1.36   hannken static void		vcache_init(void);
 1.36   hannken static void		vcache_reinit(void);
 1.54   hannken static void		vcache_reclaim(vnode_t *);
1.107        ad static void		vrelel(vnode_t *, int, int);
 1.12   hannken static void		vdrain_thread(void *);
 1.11  christos static void		vnpanic(vnode_t *, const char *, ...)
 1.18  christos     __printflike(2, 3);
  1.1     rmind
  1.1     rmind /* Routines having to do with the management of the vnode table. */
 1.44   hannken extern struct mount	*dead_rootmount;
  1.1     rmind extern int		(**dead_vnodeop_p)(void *);
 1.98   hannken extern int		(**spec_vnodeop_p)(void *);
 1.31   hannken extern struct vfsops	dead_vfsops;
  1.1     rmind
1.120        ad /*
1.123        ad  * The high bit of v_usecount is a gate for vcache_tryvget().  It's set
1.123        ad  * only when the vnode state is LOADED.
1.132   hannken  * The next bit of v_usecount is a flag for vrelel().  It's set
1.132   hannken  * from vcache_vget() and vcache_tryvget() whenever the operation succeeds.
1.123        ad  */
1.132   hannken #define	VUSECOUNT_MASK	0x3fffffff
1.123        ad #define	VUSECOUNT_GATE	0x80000000
1.132   hannken #define	VUSECOUNT_VGET	0x40000000
1.123        ad
1.123        ad /*
1.120        ad  * Return the current usecount of a vnode.
1.120        ad  */
1.120        ad inline int
1.120        ad vrefcnt(struct vnode *vp)
1.120        ad {
1.120        ad
1.123        ad 	return atomic_load_relaxed(&vp->v_usecount) & VUSECOUNT_MASK;
1.120        ad }
1.120        ad
 1.51   hannken /* Vnode state operations and diagnostics. */
 1.51   hannken
 1.51   hannken #if defined(DIAGNOSTIC)
 1.51   hannken
 1.94   hannken #define VSTATE_VALID(state) \
 1.94   hannken 	((state) != VS_ACTIVE && (state) != VS_MARKER)
 1.51   hannken #define VSTATE_GET(vp) \
 1.51   hannken 	vstate_assert_get((vp), __func__, __LINE__)
 1.51   hannken #define VSTATE_CHANGE(vp, from, to) \
 1.51   hannken 	vstate_assert_change((vp), (from), (to), __func__, __LINE__)
 1.51   hannken #define VSTATE_WAIT_STABLE(vp) \
 1.51   hannken 	vstate_assert_wait_stable((vp), __func__, __LINE__)
 1.51   hannken
 1.94   hannken void
 1.99     joerg _vstate_assert(vnode_t *vp, enum vnode_state state, const char *func, int line,
 1.99     joerg     bool has_lock)
 1.51   hannken {
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
1.120        ad 	int refcnt = vrefcnt(vp);
 1.51   hannken
 1.99     joerg 	if (!has_lock) {
 1.99     joerg 		/*
 1.99     joerg 		 * Prevent predictive loads from the CPU, but check the state
 1.99     joerg 		 * without loooking first.
1.143  riastrad 		 *
1.143  riastrad 		 * XXX what does this pair with?
 1.99     joerg 		 */
 1.99     joerg 		membar_enter();
1.120        ad 		if (state == VS_ACTIVE && refcnt > 0 &&
 1.99     joerg 		    (vip->vi_state == VS_LOADED || vip->vi_state == VS_BLOCKED))
 1.99     joerg 			return;
 1.99     joerg 		if (vip->vi_state == state)
 1.99     joerg 			return;
 1.99     joerg 		mutex_enter((vp)->v_interlock);
 1.99     joerg 	}
 1.99     joerg
 1.51   hannken 	KASSERTMSG(mutex_owned(vp->v_interlock), "at %s:%d", func, line);
 1.51   hannken
1.120        ad 	if ((state == VS_ACTIVE && refcnt > 0 &&
 1.99     joerg 	    (vip->vi_state == VS_LOADED || vip->vi_state == VS_BLOCKED)) ||
 1.99     joerg 	    vip->vi_state == state) {
 1.99     joerg 		if (!has_lock)
 1.99     joerg 			mutex_exit((vp)->v_interlock);
 1.94   hannken 		return;
 1.99     joerg 	}
 1.94   hannken 	vnpanic(vp, "state is %s, usecount %d, expected %s at %s:%d",
1.120        ad 	    vstate_name(vip->vi_state), refcnt,
 1.94   hannken 	    vstate_name(state), func, line);
 1.51   hannken }
 1.51   hannken
 1.57   hannken static enum vnode_state
 1.51   hannken vstate_assert_get(vnode_t *vp, const char *func, int line)
 1.51   hannken {
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.51   hannken
 1.51   hannken 	KASSERTMSG(mutex_owned(vp->v_interlock), "at %s:%d", func, line);
 1.94   hannken 	if (! VSTATE_VALID(vip->vi_state))
 1.51   hannken 		vnpanic(vp, "state is %s at %s:%d",
 1.70   hannken 		    vstate_name(vip->vi_state), func, line);
 1.51   hannken
 1.70   hannken 	return vip->vi_state;
 1.51   hannken }
 1.51   hannken
 1.52   hannken static void
 1.51   hannken vstate_assert_wait_stable(vnode_t *vp, const char *func, int line)
 1.51   hannken {
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.51   hannken
 1.51   hannken 	KASSERTMSG(mutex_owned(vp->v_interlock), "at %s:%d", func, line);
 1.94   hannken 	if (! VSTATE_VALID(vip->vi_state))
 1.51   hannken 		vnpanic(vp, "state is %s at %s:%d",
 1.70   hannken 		    vstate_name(vip->vi_state), func, line);
 1.51   hannken
 1.94   hannken 	while (vip->vi_state != VS_LOADED && vip->vi_state != VS_RECLAIMED)
 1.51   hannken 		cv_wait(&vp->v_cv, vp->v_interlock);
 1.51   hannken
 1.94   hannken 	if (! VSTATE_VALID(vip->vi_state))
 1.51   hannken 		vnpanic(vp, "state is %s at %s:%d",
 1.70   hannken 		    vstate_name(vip->vi_state), func, line);
 1.51   hannken }
 1.51   hannken
 1.52   hannken static void
 1.57   hannken vstate_assert_change(vnode_t *vp, enum vnode_state from, enum vnode_state to,
 1.51   hannken     const char *func, int line)
 1.51   hannken {
1.123        ad 	bool gated = (atomic_load_relaxed(&vp->v_usecount) & VUSECOUNT_GATE);
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.51   hannken
 1.51   hannken 	KASSERTMSG(mutex_owned(vp->v_interlock), "at %s:%d", func, line);
 1.57   hannken 	if (from == VS_LOADING)
 1.69   hannken 		KASSERTMSG(mutex_owned(&vcache_lock), "at %s:%d", func, line);
 1.51   hannken
 1.94   hannken 	if (! VSTATE_VALID(from))
 1.51   hannken 		vnpanic(vp, "from is %s at %s:%d",
 1.51   hannken 		    vstate_name(from), func, line);
 1.94   hannken 	if (! VSTATE_VALID(to))
 1.51   hannken 		vnpanic(vp, "to is %s at %s:%d",
 1.51   hannken 		    vstate_name(to), func, line);
 1.70   hannken 	if (vip->vi_state != from)
 1.51   hannken 		vnpanic(vp, "from is %s, expected %s at %s:%d\n",
 1.70   hannken 		    vstate_name(vip->vi_state), vstate_name(from), func, line);
1.123        ad 	if ((from == VS_LOADED) != gated)
1.123        ad 		vnpanic(vp, "state is %s, gate %d does not match at %s:%d\n",
1.123        ad 		    vstate_name(vip->vi_state), gated, func, line);
1.123        ad
1.136  riastrad 	/* Open/close the gate for vcache_tryvget(). */
1.136  riastrad 	if (to == VS_LOADED) {
1.136  riastrad #ifndef __HAVE_ATOMIC_AS_MEMBAR
1.142  riastrad 		membar_release();
1.136  riastrad #endif
1.123        ad 		atomic_or_uint(&vp->v_usecount, VUSECOUNT_GATE);
1.136  riastrad 	} else {
1.123        ad 		atomic_and_uint(&vp->v_usecount, ~VUSECOUNT_GATE);
1.136  riastrad 	}
 1.51   hannken
 1.70   hannken 	vip->vi_state = to;
 1.57   hannken 	if (from == VS_LOADING)
 1.69   hannken 		cv_broadcast(&vcache_cv);
 1.94   hannken 	if (to == VS_LOADED || to == VS_RECLAIMED)
 1.51   hannken 		cv_broadcast(&vp->v_cv);
 1.51   hannken }
 1.51   hannken
 1.51   hannken #else /* defined(DIAGNOSTIC) */
 1.51   hannken
 1.51   hannken #define VSTATE_GET(vp) \
 1.57   hannken 	(VNODE_TO_VIMPL((vp))->vi_state)
 1.51   hannken #define VSTATE_CHANGE(vp, from, to) \
 1.51   hannken 	vstate_change((vp), (from), (to))
 1.51   hannken #define VSTATE_WAIT_STABLE(vp) \
 1.51   hannken 	vstate_wait_stable((vp))
 1.94   hannken void
1.100     joerg _vstate_assert(vnode_t *vp, enum vnode_state state, const char *func, int line,
1.100     joerg     bool has_lock)
 1.94   hannken {
 1.94   hannken
 1.94   hannken }
 1.51   hannken
 1.52   hannken static void
 1.51   hannken vstate_wait_stable(vnode_t *vp)
 1.51   hannken {
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.51   hannken
 1.94   hannken 	while (vip->vi_state != VS_LOADED && vip->vi_state != VS_RECLAIMED)
 1.51   hannken 		cv_wait(&vp->v_cv, vp->v_interlock);
 1.51   hannken }
 1.51   hannken
 1.52   hannken static void
 1.57   hannken vstate_change(vnode_t *vp, enum vnode_state from, enum vnode_state to)
 1.51   hannken {
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.51   hannken
1.142  riastrad 	/* Open/close the gate for vcache_tryvget(). */
1.136  riastrad 	if (to == VS_LOADED) {
1.136  riastrad #ifndef __HAVE_ATOMIC_AS_MEMBAR
1.142  riastrad 		membar_release();
1.136  riastrad #endif
1.123        ad 		atomic_or_uint(&vp->v_usecount, VUSECOUNT_GATE);
1.136  riastrad 	} else {
1.123        ad 		atomic_and_uint(&vp->v_usecount, ~VUSECOUNT_GATE);
1.136  riastrad 	}
1.123        ad
 1.70   hannken 	vip->vi_state = to;
 1.57   hannken 	if (from == VS_LOADING)
 1.69   hannken 		cv_broadcast(&vcache_cv);
 1.94   hannken 	if (to == VS_LOADED || to == VS_RECLAIMED)
 1.51   hannken 		cv_broadcast(&vp->v_cv);
 1.51   hannken }
 1.51   hannken
 1.51   hannken #endif /* defined(DIAGNOSTIC) */
 1.51   hannken
  1.1     rmind void
  1.1     rmind vfs_vnode_sysinit(void)
  1.1     rmind {
1.104        ad 	int error __diagused, i;
  1.1     rmind
 1.44   hannken 	dead_rootmount = vfs_mountalloc(&dead_vfsops, NULL);
 1.44   hannken 	KASSERT(dead_rootmount != NULL);
1.103   hannken 	dead_rootmount->mnt_iflag |= IMNT_MPSAFE;
 1.31   hannken
 1.63   hannken 	mutex_init(&vdrain_lock, MUTEX_DEFAULT, IPL_NONE);
1.104        ad 	for (i = 0; i < LRU_COUNT; i++) {
1.104        ad 		TAILQ_INIT(&lru_list[i]);
1.104        ad 	}
 1.36   hannken 	vcache_init();
 1.36   hannken
 1.12   hannken 	cv_init(&vdrain_cv, "vdrain");
 1.63   hannken 	cv_init(&vdrain_gen_cv, "vdrainwt");
 1.12   hannken 	error = kthread_create(PRI_VM, KTHREAD_MPSAFE, NULL, vdrain_thread,
 1.63   hannken 	    NULL, &vdrain_lwp, "vdrain");
 1.47  riastrad 	KASSERTMSG((error == 0), "kthread_create(vdrain) failed: %d", error);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
 1.48   hannken  * Allocate a new marker vnode.
 1.48   hannken  */
 1.48   hannken vnode_t *
 1.48   hannken vnalloc_marker(struct mount *mp)
 1.48   hannken {
 1.70   hannken 	vnode_impl_t *vip;
 1.50   hannken 	vnode_t *vp;
 1.50   hannken
 1.70   hannken 	vip = pool_cache_get(vcache_pool, PR_WAITOK);
 1.70   hannken 	memset(vip, 0, sizeof(*vip));
 1.70   hannken 	vp = VIMPL_TO_VNODE(vip);
1.111        ad 	uvm_obj_init(&vp->v_uobj, &uvm_vnodeops, true, 1);
 1.50   hannken 	vp->v_mount = mp;
 1.50   hannken 	vp->v_type = VBAD;
1.111        ad 	vp->v_interlock = mutex_obj_alloc(MUTEX_DEFAULT, IPL_NONE);
1.144   thorpej 	klist_init(&vip->vi_klist.vk_klist);
1.144   thorpej 	vp->v_klist = &vip->vi_klist;
 1.70   hannken 	vip->vi_state = VS_MARKER;
 1.48   hannken
 1.50   hannken 	return vp;
 1.48   hannken }
 1.48   hannken
 1.48   hannken /*
 1.48   hannken  * Free a marker vnode.
 1.48   hannken  */
 1.48   hannken void
 1.48   hannken vnfree_marker(vnode_t *vp)
 1.48   hannken {
 1.70   hannken 	vnode_impl_t *vip;
 1.48   hannken
 1.70   hannken 	vip = VNODE_TO_VIMPL(vp);
 1.70   hannken 	KASSERT(vip->vi_state == VS_MARKER);
1.111        ad 	mutex_obj_free(vp->v_interlock);
 1.50   hannken 	uvm_obj_destroy(&vp->v_uobj, true);
1.144   thorpej 	klist_fini(&vip->vi_klist.vk_klist);
 1.70   hannken 	pool_cache_put(vcache_pool, vip);
 1.48   hannken }
 1.48   hannken
 1.48   hannken /*
 1.48   hannken  * Test a vnode for being a marker vnode.
 1.48   hannken  */
 1.48   hannken bool
 1.48   hannken vnis_marker(vnode_t *vp)
 1.48   hannken {
 1.48   hannken
 1.57   hannken 	return (VNODE_TO_VIMPL(vp)->vi_state == VS_MARKER);
 1.48   hannken }
 1.48   hannken
 1.48   hannken /*
 1.63   hannken  * Return the lru list this node should be on.
 1.63   hannken  */
 1.63   hannken static vnodelst_t *
 1.63   hannken lru_which(vnode_t *vp)
 1.63   hannken {
 1.63   hannken
 1.63   hannken 	KASSERT(mutex_owned(vp->v_interlock));
 1.63   hannken
 1.63   hannken 	if (vp->v_holdcnt > 0)
1.104        ad 		return &lru_list[LRU_HOLD];
 1.63   hannken 	else
1.104        ad 		return &lru_list[LRU_FREE];
 1.63   hannken }
 1.63   hannken
 1.63   hannken /*
 1.63   hannken  * Put vnode to end of given list.
 1.63   hannken  * Both the current and the new list may be NULL, used on vnode alloc/free.
 1.63   hannken  * Adjust numvnodes and signal vdrain thread if there is work.
 1.63   hannken  */
 1.63   hannken static void
 1.63   hannken lru_requeue(vnode_t *vp, vnodelst_t *listhd)
 1.63   hannken {
 1.70   hannken 	vnode_impl_t *vip;
1.104        ad 	int d;
1.104        ad
1.104        ad 	/*
1.104        ad 	 * If the vnode is on the correct list, and was put there recently,
1.104        ad 	 * then leave it be, thus avoiding huge cache and lock contention.
1.104        ad 	 */
1.104        ad 	vip = VNODE_TO_VIMPL(vp);
1.104        ad 	if (listhd == vip->vi_lrulisthd &&
1.119      maxv 	    (getticks() - vip->vi_lrulisttm) < hz) {
1.104        ad 	    	return;
1.104        ad 	}
 1.63   hannken
 1.63   hannken 	mutex_enter(&vdrain_lock);
1.104        ad 	d = 0;
 1.70   hannken 	if (vip->vi_lrulisthd != NULL)
 1.70   hannken 		TAILQ_REMOVE(vip->vi_lrulisthd, vip, vi_lrulist);
 1.63   hannken 	else
1.104        ad 		d++;
 1.70   hannken 	vip->vi_lrulisthd = listhd;
1.119      maxv 	vip->vi_lrulisttm = getticks();
 1.70   hannken 	if (vip->vi_lrulisthd != NULL)
 1.70   hannken 		TAILQ_INSERT_TAIL(vip->vi_lrulisthd, vip, vi_lrulist);
 1.63   hannken 	else
1.104        ad 		d--;
1.104        ad 	if (d != 0) {
1.104        ad 		/*
1.104        ad 		 * Looks strange?  This is not a bug.  Don't store
1.104        ad 		 * numvnodes unless there is a change - avoid false
1.104        ad 		 * sharing on MP.
1.104        ad 		 */
1.104        ad 		numvnodes += d;
1.104        ad 	}
1.121   hannken 	if ((d > 0 && numvnodes > desiredvnodes) ||
1.121   hannken 	    listhd == &lru_list[LRU_VRELE])
1.121   hannken 		cv_signal(&vdrain_cv);
 1.63   hannken 	mutex_exit(&vdrain_lock);
 1.63   hannken }
 1.63   hannken
 1.63   hannken /*
 1.75   hannken  * Release deferred vrele vnodes for this mount.
 1.75   hannken  * Called with file system suspended.
 1.75   hannken  */
 1.75   hannken void
 1.75   hannken vrele_flush(struct mount *mp)
 1.75   hannken {
 1.75   hannken 	vnode_impl_t *vip, *marker;
1.104        ad 	vnode_t *vp;
1.122   hannken 	int when = 0;
 1.75   hannken
 1.75   hannken 	KASSERT(fstrans_is_owner(mp));
 1.75   hannken
 1.75   hannken 	marker = VNODE_TO_VIMPL(vnalloc_marker(NULL));
 1.75   hannken
 1.75   hannken 	mutex_enter(&vdrain_lock);
1.104        ad 	TAILQ_INSERT_HEAD(&lru_list[LRU_VRELE], marker, vi_lrulist);
 1.75   hannken
 1.75   hannken 	while ((vip = TAILQ_NEXT(marker, vi_lrulist))) {
1.104        ad 		TAILQ_REMOVE(&lru_list[LRU_VRELE], marker, vi_lrulist);
1.104        ad 		TAILQ_INSERT_AFTER(&lru_list[LRU_VRELE], vip, marker,
1.104        ad 		    vi_lrulist);
1.104        ad 		vp = VIMPL_TO_VNODE(vip);
1.104        ad 		if (vnis_marker(vp))
 1.75   hannken 			continue;
 1.75   hannken
1.104        ad 		KASSERT(vip->vi_lrulisthd == &lru_list[LRU_VRELE]);
 1.75   hannken 		TAILQ_REMOVE(vip->vi_lrulisthd, vip, vi_lrulist);
1.104        ad 		vip->vi_lrulisthd = &lru_list[LRU_HOLD];
1.119      maxv 		vip->vi_lrulisttm = getticks();
 1.75   hannken 		TAILQ_INSERT_TAIL(vip->vi_lrulisthd, vip, vi_lrulist);
 1.75   hannken 		mutex_exit(&vdrain_lock);
 1.75   hannken
1.107        ad 		vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
1.104        ad 		mutex_enter(vp->v_interlock);
1.107        ad 		vrelel(vp, 0, LK_EXCLUSIVE);
 1.75   hannken
1.122   hannken 		if (getticks() > when) {
1.122   hannken 			yield();
1.122   hannken 			when = getticks() + hz / 10;
1.122   hannken 		}
1.122   hannken
 1.75   hannken 		mutex_enter(&vdrain_lock);
 1.75   hannken 	}
 1.75   hannken
1.104        ad 	TAILQ_REMOVE(&lru_list[LRU_VRELE], marker, vi_lrulist);
 1.75   hannken 	mutex_exit(&vdrain_lock);
 1.75   hannken
 1.75   hannken 	vnfree_marker(VIMPL_TO_VNODE(marker));
 1.75   hannken }
 1.75   hannken
 1.75   hannken /*
 1.63   hannken  * Reclaim a cached vnode.  Used from vdrain_thread only.
  1.1     rmind  */
 1.63   hannken static __inline void
 1.63   hannken vdrain_remove(vnode_t *vp)
  1.1     rmind {
 1.24   hannken 	struct mount *mp;
  1.1     rmind
 1.63   hannken 	KASSERT(mutex_owned(&vdrain_lock));
 1.24   hannken
 1.63   hannken 	/* Probe usecount (unlocked). */
1.120        ad 	if (vrefcnt(vp) > 0)
 1.63   hannken 		return;
 1.63   hannken 	/* Try v_interlock -- we lock the wrong direction! */
 1.63   hannken 	if (!mutex_tryenter(vp->v_interlock))
 1.63   hannken 		return;
 1.63   hannken 	/* Probe usecount and state. */
1.120        ad 	if (vrefcnt(vp) > 0 || VSTATE_GET(vp) != VS_LOADED) {
 1.63   hannken 		mutex_exit(vp->v_interlock);
 1.63   hannken 		return;
  1.1     rmind 	}
 1.63   hannken 	mp = vp->v_mount;
 1.96   hannken 	if (fstrans_start_nowait(mp) != 0) {
 1.63   hannken 		mutex_exit(vp->v_interlock);
 1.63   hannken 		return;
  1.1     rmind 	}
 1.63   hannken 	vdrain_retry = true;
 1.63   hannken 	mutex_exit(&vdrain_lock);
  1.1     rmind
 1.66   hannken 	if (vcache_vget(vp) == 0) {
 1.78   hannken 		if (!vrecycle(vp)) {
1.107        ad 			vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
 1.78   hannken 			mutex_enter(vp->v_interlock);
1.107        ad 			vrelel(vp, 0, LK_EXCLUSIVE);
 1.78   hannken 		}
 1.60   hannken 	}
 1.24   hannken 	fstrans_done(mp);
 1.12   hannken
 1.63   hannken 	mutex_enter(&vdrain_lock);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
 1.63   hannken  * Release a cached vnode.  Used from vdrain_thread only.
 1.12   hannken  */
 1.63   hannken static __inline void
 1.63   hannken vdrain_vrele(vnode_t *vp)
 1.12   hannken {
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.63   hannken 	struct mount *mp;
 1.12   hannken
 1.63   hannken 	KASSERT(mutex_owned(&vdrain_lock));
 1.12   hannken
 1.63   hannken 	mp = vp->v_mount;
 1.96   hannken 	if (fstrans_start_nowait(mp) != 0)
 1.63   hannken 		return;
 1.63   hannken
 1.64   hannken 	/*
 1.64   hannken 	 * First remove the vnode from the vrele list.
 1.64   hannken 	 * Put it on the last lru list, the last vrele()
 1.64   hannken 	 * will put it back onto the right list before
1.120        ad 	 * its usecount reaches zero.
 1.64   hannken 	 */
1.104        ad 	KASSERT(vip->vi_lrulisthd == &lru_list[LRU_VRELE]);
 1.70   hannken 	TAILQ_REMOVE(vip->vi_lrulisthd, vip, vi_lrulist);
1.104        ad 	vip->vi_lrulisthd = &lru_list[LRU_HOLD];
1.119      maxv 	vip->vi_lrulisttm = getticks();
 1.70   hannken 	TAILQ_INSERT_TAIL(vip->vi_lrulisthd, vip, vi_lrulist);
 1.63   hannken
 1.63   hannken 	vdrain_retry = true;
 1.63   hannken 	mutex_exit(&vdrain_lock);
 1.63   hannken
1.107        ad 	vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
 1.64   hannken 	mutex_enter(vp->v_interlock);
1.107        ad 	vrelel(vp, 0, LK_EXCLUSIVE);
 1.63   hannken 	fstrans_done(mp);
 1.63   hannken
 1.63   hannken 	mutex_enter(&vdrain_lock);
 1.12   hannken }
 1.12   hannken
 1.12   hannken /*
 1.63   hannken  * Helper thread to keep the number of vnodes below desiredvnodes
 1.63   hannken  * and release vnodes from asynchronous vrele.
  1.1     rmind  */
 1.63   hannken static void
 1.63   hannken vdrain_thread(void *cookie)
  1.1     rmind {
 1.63   hannken 	int i;
 1.63   hannken 	u_int target;
 1.70   hannken 	vnode_impl_t *vip, *marker;
 1.63   hannken
 1.63   hannken 	marker = VNODE_TO_VIMPL(vnalloc_marker(NULL));
 1.63   hannken
 1.63   hannken 	mutex_enter(&vdrain_lock);
 1.63   hannken
 1.63   hannken 	for (;;) {
 1.63   hannken 		vdrain_retry = false;
 1.63   hannken 		target = desiredvnodes - desiredvnodes/10;
  1.1     rmind
1.104        ad 		for (i = 0; i < LRU_COUNT; i++) {
1.104        ad 			TAILQ_INSERT_HEAD(&lru_list[i], marker, vi_lrulist);
 1.70   hannken 			while ((vip = TAILQ_NEXT(marker, vi_lrulist))) {
1.104        ad 				TAILQ_REMOVE(&lru_list[i], marker, vi_lrulist);
1.104        ad 				TAILQ_INSERT_AFTER(&lru_list[i], vip, marker,
 1.63   hannken 				    vi_lrulist);
 1.75   hannken 				if (vnis_marker(VIMPL_TO_VNODE(vip)))
 1.75   hannken 					continue;
1.104        ad 				if (i == LRU_VRELE)
 1.70   hannken 					vdrain_vrele(VIMPL_TO_VNODE(vip));
 1.63   hannken 				else if (numvnodes < target)
 1.63   hannken 					break;
 1.63   hannken 				else
 1.70   hannken 					vdrain_remove(VIMPL_TO_VNODE(vip));
 1.63   hannken 			}
1.104        ad 			TAILQ_REMOVE(&lru_list[i], marker, vi_lrulist);
 1.63   hannken 		}
  1.1     rmind
 1.63   hannken 		if (vdrain_retry) {
1.121   hannken 			kpause("vdrainrt", false, 1, &vdrain_lock);
 1.63   hannken 		} else {
 1.63   hannken 			vdrain_gen++;
 1.63   hannken 			cv_broadcast(&vdrain_gen_cv);
 1.63   hannken 			cv_wait(&vdrain_cv, &vdrain_lock);
 1.63   hannken 		}
  1.1     rmind 	}
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
1.112        ad  * Try to drop reference on a vnode.  Abort if we are releasing the
1.112        ad  * last reference.  Note: this _must_ succeed if not the last reference.
1.112        ad  */
1.112        ad static bool
1.112        ad vtryrele(vnode_t *vp)
1.112        ad {
1.112        ad 	u_int use, next;
1.112        ad
1.136  riastrad #ifndef __HAVE_ATOMIC_AS_MEMBAR
1.142  riastrad 	membar_release();
1.136  riastrad #endif
1.112        ad 	for (use = atomic_load_relaxed(&vp->v_usecount);; use = next) {
1.123        ad 		if (__predict_false((use & VUSECOUNT_MASK) == 1)) {
1.112        ad 			return false;
1.112        ad 		}
1.123        ad 		KASSERT((use & VUSECOUNT_MASK) > 1);
1.112        ad 		next = atomic_cas_uint(&vp->v_usecount, use, use - 1);
1.112        ad 		if (__predict_true(next == use)) {
1.112        ad 			return true;
1.112        ad 		}
1.112        ad 	}
1.112        ad }
1.112        ad
1.112        ad /*
  1.4     rmind  * vput: unlock and release the reference.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind vput(vnode_t *vp)
  1.1     rmind {
1.107        ad 	int lktype;
  1.1     rmind
1.112        ad 	/*
1.120        ad 	 * Do an unlocked check of the usecount.  If it looks like we're not
1.112        ad 	 * about to drop the last reference, then unlock the vnode and try
1.112        ad 	 * to drop the reference.  If it ends up being the last reference
1.112        ad 	 * after all, vrelel() can fix it all up.  Most of the time this
1.112        ad 	 * will all go to plan.
1.112        ad 	 */
1.120        ad 	if (vrefcnt(vp) > 1) {
1.112        ad 		VOP_UNLOCK(vp);
1.112        ad 		if (vtryrele(vp)) {
1.112        ad 			return;
1.112        ad 		}
1.112        ad 		lktype = LK_NONE;
1.107        ad 	} else {
1.107        ad 		lktype = VOP_ISLOCKED(vp);
1.107        ad 		KASSERT(lktype != LK_NONE);
1.107        ad 	}
1.107        ad 	mutex_enter(vp->v_interlock);
1.107        ad 	vrelel(vp, 0, lktype);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
  1.1     rmind  * Vnode release.  If reference count drops to zero, call inactive
  1.1     rmind  * routine and either return to freelist or free to the pool.
  1.1     rmind  */
 1.23   hannken static void
1.107        ad vrelel(vnode_t *vp, int flags, int lktype)
  1.1     rmind {
1.104        ad 	const bool async = ((flags & VRELEL_ASYNC) != 0);
1.133   hannken 	bool recycle, defer, objlock_held;
1.132   hannken 	u_int use, next;
  1.1     rmind 	int error;
  1.1     rmind
1.133   hannken 	objlock_held = false;
1.133   hannken
1.132   hannken retry:
  1.9     rmind 	KASSERT(mutex_owned(vp->v_interlock));
  1.1     rmind
  1.1     rmind 	if (__predict_false(vp->v_op == dead_vnodeop_p &&
 1.57   hannken 	    VSTATE_GET(vp) != VS_RECLAIMED)) {
 1.11  christos 		vnpanic(vp, "dead but not clean");
  1.1     rmind 	}
  1.1     rmind
  1.1     rmind 	/*
1.132   hannken 	 * If not the last reference, just unlock and drop the reference count.
1.132   hannken 	 *
1.132   hannken 	 * Otherwise make sure we pass a point in time where we hold the
1.132   hannken 	 * last reference with VGET flag unset.
  1.1     rmind 	 */
1.132   hannken 	for (use = atomic_load_relaxed(&vp->v_usecount);; use = next) {
1.132   hannken 		if (__predict_false((use & VUSECOUNT_MASK) > 1)) {
1.134   hannken 			if (objlock_held) {
1.134   hannken 				objlock_held = false;
1.134   hannken 				rw_exit(vp->v_uobj.vmobjlock);
1.134   hannken 			}
1.132   hannken 			if (lktype != LK_NONE) {
1.132   hannken 				mutex_exit(vp->v_interlock);
1.132   hannken 				lktype = LK_NONE;
1.132   hannken 				VOP_UNLOCK(vp);
1.132   hannken 				mutex_enter(vp->v_interlock);
1.132   hannken 			}
1.132   hannken 			if (vtryrele(vp)) {
1.132   hannken 				mutex_exit(vp->v_interlock);
1.132   hannken 				return;
1.132   hannken 			}
1.132   hannken 			next = atomic_load_relaxed(&vp->v_usecount);
1.132   hannken 			continue;
1.132   hannken 		}
1.132   hannken 		KASSERT((use & VUSECOUNT_MASK) == 1);
1.132   hannken 		next = use & ~VUSECOUNT_VGET;
1.132   hannken 		if (next != use) {
1.132   hannken 			next = atomic_cas_uint(&vp->v_usecount, use, next);
1.132   hannken 		}
1.132   hannken 		if (__predict_true(next == use)) {
1.132   hannken 			break;
1.107        ad 		}
  1.1     rmind 	}
1.136  riastrad #ifndef __HAVE_ATOMIC_AS_MEMBAR
1.142  riastrad 	membar_acquire();
1.136  riastrad #endif
1.120        ad 	if (vrefcnt(vp) <= 0 || vp->v_writecount != 0) {
 1.11  christos 		vnpanic(vp, "%s: bad ref count", __func__);
  1.1     rmind 	}
  1.1     rmind
 1.15   hannken #ifdef DIAGNOSTIC
 1.15   hannken 	if ((vp->v_type == VBLK || vp->v_type == VCHR) &&
 1.15   hannken 	    vp->v_specnode != NULL && vp->v_specnode->sn_opencnt != 0) {
 1.15   hannken 		vprint("vrelel: missing VOP_CLOSE()", vp);
 1.15   hannken 	}
 1.15   hannken #endif
 1.15   hannken
  1.1     rmind 	/*
1.131   hannken 	 * If already clean there is no need to lock, defer or
1.131   hannken 	 * deactivate this node.
1.131   hannken 	 */
1.131   hannken 	if (VSTATE_GET(vp) == VS_RECLAIMED) {
1.134   hannken 		if (objlock_held) {
1.134   hannken 			objlock_held = false;
1.134   hannken 			rw_exit(vp->v_uobj.vmobjlock);
1.134   hannken 		}
1.131   hannken 		if (lktype != LK_NONE) {
1.131   hannken 			mutex_exit(vp->v_interlock);
1.131   hannken 			lktype = LK_NONE;
1.131   hannken 			VOP_UNLOCK(vp);
1.131   hannken 			mutex_enter(vp->v_interlock);
1.131   hannken 		}
1.131   hannken 		goto out;
1.131   hannken 	}
1.131   hannken
1.131   hannken 	/*
 1.79   hannken 	 * First try to get the vnode locked for VOP_INACTIVE().
 1.79   hannken 	 * Defer vnode release to vdrain_thread if caller requests
 1.79   hannken 	 * it explicitly, is the pagedaemon or the lock failed.
  1.1     rmind 	 */
1.107        ad 	defer = false;
 1.79   hannken 	if ((curlwp == uvm.pagedaemon_lwp) || async) {
 1.79   hannken 		defer = true;
1.107        ad 	} else if (lktype == LK_SHARED) {
1.107        ad 		/* Excellent chance of getting, if the last ref. */
1.131   hannken 		error = vn_lock(vp, LK_UPGRADE | LK_RETRY | LK_NOWAIT);
1.107        ad 		if (error != 0) {
1.107        ad 			defer = true;
1.107        ad 		} else {
1.107        ad 			lktype = LK_EXCLUSIVE;
1.107        ad 		}
1.107        ad 	} else if (lktype == LK_NONE) {
1.107        ad 		/* Excellent chance of getting, if the last ref. */
1.131   hannken 		error = vn_lock(vp, LK_EXCLUSIVE | LK_RETRY | LK_NOWAIT);
1.107        ad 		if (error != 0) {
1.107        ad 			defer = true;
1.107        ad 		} else {
1.107        ad 			lktype = LK_EXCLUSIVE;
1.107        ad 		}
 1.79   hannken 	}
 1.79   hannken 	KASSERT(mutex_owned(vp->v_interlock));
 1.79   hannken 	if (defer) {
  1.1     rmind 		/*
 1.79   hannken 		 * Defer reclaim to the kthread; it's not safe to
 1.79   hannken 		 * clean it here.  We donate it our last reference.
  1.1     rmind 		 */
1.107        ad 		if (lktype != LK_NONE) {
1.134   hannken 			mutex_exit(vp->v_interlock);
1.107        ad 			VOP_UNLOCK(vp);
1.134   hannken 			mutex_enter(vp->v_interlock);
1.107        ad 		}
1.104        ad 		lru_requeue(vp, &lru_list[LRU_VRELE]);
 1.79   hannken 		mutex_exit(vp->v_interlock);
 1.79   hannken 		return;
 1.79   hannken 	}
1.107        ad 	KASSERT(lktype == LK_EXCLUSIVE);
 1.30   hannken
1.135   hannken 	/* If the node gained another reference, retry. */
1.135   hannken 	use = atomic_load_relaxed(&vp->v_usecount);
1.137   hannken 	if ((use & VUSECOUNT_VGET) != 0) {
1.135   hannken 		goto retry;
1.135   hannken 	}
1.137   hannken 	KASSERT((use & VUSECOUNT_MASK) == 1);
1.135   hannken
1.133   hannken 	if ((vp->v_iflag & (VI_TEXT|VI_EXECMAP|VI_WRMAP)) != 0 ||
1.133   hannken 	    (vp->v_vflag & VV_MAPPED) != 0) {
1.133   hannken 		/* Take care of space accounting. */
1.133   hannken 		if (!objlock_held) {
1.133   hannken 			objlock_held = true;
1.133   hannken 			if (!rw_tryenter(vp->v_uobj.vmobjlock, RW_WRITER)) {
1.133   hannken 				mutex_exit(vp->v_interlock);
1.133   hannken 				rw_enter(vp->v_uobj.vmobjlock, RW_WRITER);
1.133   hannken 				mutex_enter(vp->v_interlock);
1.133   hannken 				goto retry;
1.133   hannken 			}
1.133   hannken 		}
1.133   hannken 		if ((vp->v_iflag & VI_EXECMAP) != 0) {
1.133   hannken 			cpu_count(CPU_COUNT_EXECPAGES, -vp->v_uobj.uo_npages);
1.133   hannken 		}
1.133   hannken 		vp->v_iflag &= ~(VI_TEXT|VI_EXECMAP|VI_WRMAP);
1.133   hannken 		vp->v_vflag &= ~VV_MAPPED;
1.133   hannken 	}
1.133   hannken 	if (objlock_held) {
1.133   hannken 		objlock_held = false;
1.133   hannken 		rw_exit(vp->v_uobj.vmobjlock);
1.133   hannken 	}
1.133   hannken
 1.79   hannken 	/*
1.131   hannken 	 * Deactivate the vnode, but preserve our reference across
1.131   hannken 	 * the call to VOP_INACTIVE().
1.131   hannken 	 *
1.131   hannken 	 * If VOP_INACTIVE() indicates that the file has been
1.131   hannken 	 * deleted, then recycle the vnode.
1.131   hannken 	 *
1.131   hannken 	 * Note that VOP_INACTIVE() will not drop the vnode lock.
 1.79   hannken 	 */
1.131   hannken 	mutex_exit(vp->v_interlock);
1.131   hannken 	recycle = false;
1.131   hannken 	VOP_INACTIVE(vp, &recycle);
1.133   hannken 	if (!recycle) {
1.133   hannken 		lktype = LK_NONE;
1.133   hannken 		VOP_UNLOCK(vp);
1.133   hannken 	}
1.131   hannken 	mutex_enter(vp->v_interlock);
1.131   hannken
1.132   hannken 	/*
1.132   hannken 	 * Block new references then check again to see if a
1.132   hannken 	 * new reference was acquired in the meantime.  If
1.132   hannken 	 * it was, restore the vnode state and try again.
1.132   hannken 	 */
1.132   hannken 	if (recycle) {
1.132   hannken 		VSTATE_CHANGE(vp, VS_LOADED, VS_BLOCKED);
1.132   hannken 		use = atomic_load_relaxed(&vp->v_usecount);
1.137   hannken 		if ((use & VUSECOUNT_VGET) != 0) {
1.132   hannken 			VSTATE_CHANGE(vp, VS_BLOCKED, VS_LOADED);
1.132   hannken 			goto retry;
1.131   hannken 		}
1.137   hannken 		KASSERT((use & VUSECOUNT_MASK) == 1);
1.132   hannken 	}
  1.1     rmind
1.131   hannken 	/*
1.133   hannken 	 * Recycle the vnode if the file is now unused (unlinked).
1.131   hannken 	 */
1.131   hannken 	if (recycle) {
1.131   hannken 		VSTATE_ASSERT(vp, VS_BLOCKED);
1.133   hannken 		KASSERT(lktype == LK_EXCLUSIVE);
1.131   hannken 		/* vcache_reclaim drops the lock. */
1.132   hannken 		lktype = LK_NONE;
1.131   hannken 		vcache_reclaim(vp);
  1.1     rmind 	}
1.131   hannken 	KASSERT(vrefcnt(vp) > 0);
1.133   hannken 	KASSERT(lktype == LK_NONE);
  1.1     rmind
1.131   hannken out:
1.132   hannken 	for (use = atomic_load_relaxed(&vp->v_usecount);; use = next) {
1.132   hannken 		if (__predict_false((use & VUSECOUNT_VGET) != 0 &&
1.132   hannken 		    (use & VUSECOUNT_MASK) == 1)) {
1.132   hannken 			/* Gained and released another reference, retry. */
1.132   hannken 			goto retry;
1.132   hannken 		}
1.132   hannken 		next = atomic_cas_uint(&vp->v_usecount, use, use - 1);
1.132   hannken 		if (__predict_true(next == use)) {
1.132   hannken 			if (__predict_false((use & VUSECOUNT_MASK) != 1)) {
1.132   hannken 				/* Gained another reference. */
1.132   hannken 				mutex_exit(vp->v_interlock);
1.132   hannken 				return;
1.132   hannken 			}
1.132   hannken 			break;
1.132   hannken 		}
  1.1     rmind 	}
1.136  riastrad #ifndef __HAVE_ATOMIC_AS_MEMBAR
1.142  riastrad 	membar_acquire();
1.136  riastrad #endif
  1.1     rmind
 1.67   hannken 	if (VSTATE_GET(vp) == VS_RECLAIMED && vp->v_holdcnt == 0) {
  1.1     rmind 		/*
  1.1     rmind 		 * It's clean so destroy it.  It isn't referenced
  1.1     rmind 		 * anywhere since it has been reclaimed.
  1.1     rmind 		 */
 1.57   hannken 		vcache_free(VNODE_TO_VIMPL(vp));
  1.1     rmind 	} else {
  1.1     rmind 		/*
  1.1     rmind 		 * Otherwise, put it back onto the freelist.  It
  1.1     rmind 		 * can't be destroyed while still associated with
  1.1     rmind 		 * a file system.
  1.1     rmind 		 */
 1.63   hannken 		lru_requeue(vp, lru_which(vp));
  1.9     rmind 		mutex_exit(vp->v_interlock);
  1.1     rmind 	}
  1.1     rmind }
  1.1     rmind
  1.1     rmind void
  1.1     rmind vrele(vnode_t *vp)
  1.1     rmind {
  1.1     rmind
1.112        ad 	if (vtryrele(vp)) {
1.112        ad 		return;
1.112        ad 	}
  1.9     rmind 	mutex_enter(vp->v_interlock);
1.107        ad 	vrelel(vp, 0, LK_NONE);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
  1.1     rmind  * Asynchronous vnode release, vnode is released in different context.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind vrele_async(vnode_t *vp)
  1.1     rmind {
  1.1     rmind
1.112        ad 	if (vtryrele(vp)) {
1.112        ad 		return;
1.112        ad 	}
  1.9     rmind 	mutex_enter(vp->v_interlock);
1.107        ad 	vrelel(vp, VRELEL_ASYNC, LK_NONE);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
  1.1     rmind  * Vnode reference, where a reference is already held by some other
  1.1     rmind  * object (for example, a file structure).
1.112        ad  *
1.123        ad  * NB: lockless code sequences may rely on this not blocking.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind vref(vnode_t *vp)
  1.1     rmind {
  1.1     rmind
1.120        ad 	KASSERT(vrefcnt(vp) > 0);
  1.1     rmind
1.112        ad 	atomic_inc_uint(&vp->v_usecount);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
  1.1     rmind  * Page or buffer structure gets a reference.
  1.1     rmind  * Called with v_interlock held.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind vholdl(vnode_t *vp)
  1.1     rmind {
  1.1     rmind
  1.9     rmind 	KASSERT(mutex_owned(vp->v_interlock));
  1.1     rmind
1.120        ad 	if (vp->v_holdcnt++ == 0 && vrefcnt(vp) == 0)
 1.63   hannken 		lru_requeue(vp, lru_which(vp));
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
1.112        ad  * Page or buffer structure gets a reference.
1.112        ad  */
1.112        ad void
1.112        ad vhold(vnode_t *vp)
1.112        ad {
1.112        ad
1.112        ad 	mutex_enter(vp->v_interlock);
1.112        ad 	vholdl(vp);
1.112        ad 	mutex_exit(vp->v_interlock);
1.112        ad }
1.112        ad
1.112        ad /*
  1.1     rmind  * Page or buffer structure frees a reference.
  1.1     rmind  * Called with v_interlock held.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind holdrelel(vnode_t *vp)
  1.1     rmind {
  1.1     rmind
  1.9     rmind 	KASSERT(mutex_owned(vp->v_interlock));
  1.1     rmind
  1.1     rmind 	if (vp->v_holdcnt <= 0) {
 1.11  christos 		vnpanic(vp, "%s: holdcnt vp %p", __func__, vp);
  1.1     rmind 	}
  1.1     rmind
  1.1     rmind 	vp->v_holdcnt--;
1.120        ad 	if (vp->v_holdcnt == 0 && vrefcnt(vp) == 0)
 1.63   hannken 		lru_requeue(vp, lru_which(vp));
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
1.112        ad  * Page or buffer structure frees a reference.
1.112        ad  */
1.112        ad void
1.112        ad holdrele(vnode_t *vp)
1.112        ad {
1.112        ad
1.112        ad 	mutex_enter(vp->v_interlock);
1.112        ad 	holdrelel(vp);
1.112        ad 	mutex_exit(vp->v_interlock);
1.112        ad }
1.112        ad
1.112        ad /*
 1.33   hannken  * Recycle an unused vnode if caller holds the last reference.
  1.1     rmind  */
 1.33   hannken bool
 1.33   hannken vrecycle(vnode_t *vp)
  1.1     rmind {
 1.60   hannken 	int error __diagused;
 1.46   hannken
 1.33   hannken 	mutex_enter(vp->v_interlock);
 1.33   hannken
1.123        ad 	/* If the vnode is already clean we're done. */
 1.60   hannken 	VSTATE_WAIT_STABLE(vp);
 1.94   hannken 	if (VSTATE_GET(vp) != VS_LOADED) {
 1.60   hannken 		VSTATE_ASSERT(vp, VS_RECLAIMED);
1.107        ad 		vrelel(vp, 0, LK_NONE);
 1.60   hannken 		return true;
 1.60   hannken 	}
 1.60   hannken
 1.60   hannken 	/* Prevent further references until the vnode is locked. */
 1.94   hannken 	VSTATE_CHANGE(vp, VS_LOADED, VS_BLOCKED);
1.123        ad
1.123        ad 	/* Make sure we hold the last reference. */
1.123        ad 	if (vrefcnt(vp) != 1) {
1.123        ad 		VSTATE_CHANGE(vp, VS_BLOCKED, VS_LOADED);
1.123        ad 		mutex_exit(vp->v_interlock);
1.123        ad 		return false;
1.123        ad 	}
1.123        ad
 1.60   hannken 	mutex_exit(vp->v_interlock);
 1.60   hannken
 1.73   hannken 	/*
 1.73   hannken 	 * On a leaf file system this lock will always succeed as we hold
 1.73   hannken 	 * the last reference and prevent further references.
 1.73   hannken 	 * On layered file systems waiting for the lock would open a can of
 1.73   hannken 	 * deadlocks as the lower vnodes may have other active references.
 1.73   hannken 	 */
 1.76   hannken 	error = vn_lock(vp, LK_EXCLUSIVE | LK_RETRY | LK_NOWAIT);
 1.60   hannken
 1.60   hannken 	mutex_enter(vp->v_interlock);
 1.73   hannken 	if (error) {
1.123        ad 		VSTATE_CHANGE(vp, VS_BLOCKED, VS_LOADED);
 1.73   hannken 		mutex_exit(vp->v_interlock);
 1.73   hannken 		return false;
 1.73   hannken 	}
 1.73   hannken
1.120        ad 	KASSERT(vrefcnt(vp) == 1);
 1.54   hannken 	vcache_reclaim(vp);
1.107        ad 	vrelel(vp, 0, LK_NONE);
 1.60   hannken
 1.33   hannken 	return true;
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
 1.92   hannken  * Helper for vrevoke() to propagate suspension from lastmp
 1.92   hannken  * to thismp.  Both args may be NULL.
 1.92   hannken  * Returns the currently suspended file system or NULL.
 1.92   hannken  */
 1.92   hannken static struct mount *
 1.92   hannken vrevoke_suspend_next(struct mount *lastmp, struct mount *thismp)
 1.92   hannken {
 1.92   hannken 	int error;
 1.92   hannken
 1.92   hannken 	if (lastmp == thismp)
 1.92   hannken 		return thismp;
 1.92   hannken
 1.92   hannken 	if (lastmp != NULL)
 1.92   hannken 		vfs_resume(lastmp);
 1.92   hannken
 1.92   hannken 	if (thismp == NULL)
 1.92   hannken 		return NULL;
 1.92   hannken
 1.92   hannken 	do {
 1.92   hannken 		error = vfs_suspend(thismp, 0);
 1.92   hannken 	} while (error == EINTR || error == ERESTART);
 1.92   hannken
 1.92   hannken 	if (error == 0)
 1.92   hannken 		return thismp;
 1.92   hannken
1.129   hannken 	KASSERT(error == EOPNOTSUPP || error == ENOENT);
 1.92   hannken 	return NULL;
 1.92   hannken }
 1.92   hannken
 1.92   hannken /*
  1.1     rmind  * Eliminate all activity associated with the requested vnode
  1.1     rmind  * and with all vnodes aliased to the requested vnode.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind vrevoke(vnode_t *vp)
  1.1     rmind {
 1.88   hannken 	struct mount *mp;
 1.19   hannken 	vnode_t *vq;
  1.1     rmind 	enum vtype type;
  1.1     rmind 	dev_t dev;
  1.1     rmind
1.120        ad 	KASSERT(vrefcnt(vp) > 0);
  1.1     rmind
 1.92   hannken 	mp = vrevoke_suspend_next(NULL, vp->v_mount);
 1.88   hannken
  1.9     rmind 	mutex_enter(vp->v_interlock);
 1.52   hannken 	VSTATE_WAIT_STABLE(vp);
 1.57   hannken 	if (VSTATE_GET(vp) == VS_RECLAIMED) {
  1.9     rmind 		mutex_exit(vp->v_interlock);
  1.1     rmind 	} else if (vp->v_type != VBLK && vp->v_type != VCHR) {
1.112        ad 		atomic_inc_uint(&vp->v_usecount);
 1.29  christos 		mutex_exit(vp->v_interlock);
 1.29  christos 		vgone(vp);
  1.1     rmind 	} else {
  1.1     rmind 		dev = vp->v_rdev;
  1.1     rmind 		type = vp->v_type;
  1.9     rmind 		mutex_exit(vp->v_interlock);
  1.1     rmind
1.140  riastrad 		while (spec_node_lookup_by_dev(type, dev, VDEAD_NOWAIT, &vq)
1.140  riastrad 		    == 0) {
 1.92   hannken 			mp = vrevoke_suspend_next(mp, vq->v_mount);
 1.88   hannken 			vgone(vq);
 1.88   hannken 		}
  1.1     rmind 	}
 1.92   hannken 	vrevoke_suspend_next(mp, NULL);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
  1.1     rmind  * Eliminate all activity associated with a vnode in preparation for
  1.1     rmind  * reuse.  Drops a reference from the vnode.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind vgone(vnode_t *vp)
  1.1     rmind {
1.107        ad 	int lktype;
  1.1     rmind
1.103   hannken 	KASSERT(vp->v_mount == dead_rootmount || fstrans_is_owner(vp->v_mount));
 1.93   hannken
 1.76   hannken 	vn_lock(vp, LK_EXCLUSIVE | LK_RETRY);
1.107        ad 	lktype = LK_EXCLUSIVE;
  1.9     rmind 	mutex_enter(vp->v_interlock);
 1.76   hannken 	VSTATE_WAIT_STABLE(vp);
1.107        ad 	if (VSTATE_GET(vp) == VS_LOADED) {
1.123        ad 		VSTATE_CHANGE(vp, VS_LOADED, VS_BLOCKED);
 1.76   hannken 		vcache_reclaim(vp);
1.107        ad 		lktype = LK_NONE;
1.107        ad 	}
 1.76   hannken 	VSTATE_ASSERT(vp, VS_RECLAIMED);
1.107        ad 	vrelel(vp, 0, lktype);
  1.1     rmind }
  1.1     rmind
 1.36   hannken static inline uint32_t
 1.36   hannken vcache_hash(const struct vcache_key *key)
 1.36   hannken {
 1.36   hannken 	uint32_t hash = HASH32_BUF_INIT;
 1.36   hannken
 1.97   hannken 	KASSERT(key->vk_key_len > 0);
 1.97   hannken
 1.36   hannken 	hash = hash32_buf(&key->vk_mount, sizeof(struct mount *), hash);
 1.36   hannken 	hash = hash32_buf(key->vk_key, key->vk_key_len, hash);
 1.36   hannken 	return hash;
 1.36   hannken }
 1.36   hannken
1.127    simonb static int
1.127    simonb vcache_stats(struct hashstat_sysctl *hs, bool fill)
1.127    simonb {
1.127    simonb 	vnode_impl_t *vip;
1.127    simonb 	uint64_t chain;
1.127    simonb
1.127    simonb 	strlcpy(hs->hash_name, "vcache", sizeof(hs->hash_name));
1.127    simonb 	strlcpy(hs->hash_desc, "vnode cache hash", sizeof(hs->hash_desc));
1.127    simonb 	if (!fill)
1.127    simonb 		return 0;
1.127    simonb
1.127    simonb 	hs->hash_size = vcache_hashmask + 1;
1.127    simonb
1.127    simonb 	for (size_t i = 0; i < hs->hash_size; i++) {
1.127    simonb 		chain = 0;
1.127    simonb 		mutex_enter(&vcache_lock);
1.127    simonb 		SLIST_FOREACH(vip, &vcache_hashtab[i], vi_hash) {
1.127    simonb 			chain++;
1.127    simonb 		}
1.127    simonb 		mutex_exit(&vcache_lock);
1.127    simonb 		if (chain > 0) {
1.127    simonb 			hs->hash_used++;
1.127    simonb 			hs->hash_items += chain;
1.127    simonb 			if (chain > hs->hash_maxchain)
1.127    simonb 				hs->hash_maxchain = chain;
1.127    simonb 		}
1.127    simonb 		preempt_point();
1.127    simonb 	}
1.127    simonb
1.127    simonb 	return 0;
1.127    simonb }
1.127    simonb
 1.36   hannken static void
 1.36   hannken vcache_init(void)
 1.36   hannken {
 1.36   hannken
1.112        ad 	vcache_pool = pool_cache_init(sizeof(vnode_impl_t), coherency_unit,
1.112        ad 	    0, 0, "vcachepl", NULL, IPL_NONE, NULL, NULL, NULL);
 1.69   hannken 	KASSERT(vcache_pool != NULL);
 1.69   hannken 	mutex_init(&vcache_lock, MUTEX_DEFAULT, IPL_NONE);
 1.69   hannken 	cv_init(&vcache_cv, "vcache");
 1.69   hannken 	vcache_hashsize = desiredvnodes;
 1.69   hannken 	vcache_hashtab = hashinit(desiredvnodes, HASH_SLIST, true,
 1.69   hannken 	    &vcache_hashmask);
1.127    simonb 	hashstat_register("vcache", vcache_stats);
 1.36   hannken }
 1.36   hannken
 1.36   hannken static void
 1.36   hannken vcache_reinit(void)
 1.36   hannken {
 1.36   hannken 	int i;
 1.36   hannken 	uint32_t hash;
 1.36   hannken 	u_long oldmask, newmask;
 1.36   hannken 	struct hashhead *oldtab, *newtab;
 1.70   hannken 	vnode_impl_t *vip;
 1.36   hannken
 1.36   hannken 	newtab = hashinit(desiredvnodes, HASH_SLIST, true, &newmask);
 1.69   hannken 	mutex_enter(&vcache_lock);
 1.69   hannken 	oldtab = vcache_hashtab;
 1.69   hannken 	oldmask = vcache_hashmask;
 1.69   hannken 	vcache_hashsize = desiredvnodes;
 1.69   hannken 	vcache_hashtab = newtab;
 1.69   hannken 	vcache_hashmask = newmask;
 1.36   hannken 	for (i = 0; i <= oldmask; i++) {
 1.70   hannken 		while ((vip = SLIST_FIRST(&oldtab[i])) != NULL) {
 1.70   hannken 			SLIST_REMOVE(&oldtab[i], vip, vnode_impl, vi_hash);
 1.70   hannken 			hash = vcache_hash(&vip->vi_key);
 1.69   hannken 			SLIST_INSERT_HEAD(&newtab[hash & vcache_hashmask],
 1.70   hannken 			    vip, vi_hash);
 1.36   hannken 		}
 1.36   hannken 	}
 1.69   hannken 	mutex_exit(&vcache_lock);
 1.36   hannken 	hashdone(oldtab, HASH_SLIST, oldmask);
 1.36   hannken }
 1.36   hannken
 1.57   hannken static inline vnode_impl_t *
 1.36   hannken vcache_hash_lookup(const struct vcache_key *key, uint32_t hash)
 1.36   hannken {
 1.36   hannken 	struct hashhead *hashp;
 1.70   hannken 	vnode_impl_t *vip;
 1.36   hannken
 1.69   hannken 	KASSERT(mutex_owned(&vcache_lock));
 1.36   hannken
 1.69   hannken 	hashp = &vcache_hashtab[hash & vcache_hashmask];
 1.70   hannken 	SLIST_FOREACH(vip, hashp, vi_hash) {
 1.70   hannken 		if (key->vk_mount != vip->vi_key.vk_mount)
 1.36   hannken 			continue;
 1.70   hannken 		if (key->vk_key_len != vip->vi_key.vk_key_len)
 1.36   hannken 			continue;
 1.70   hannken 		if (memcmp(key->vk_key, vip->vi_key.vk_key, key->vk_key_len))
 1.36   hannken 			continue;
 1.70   hannken 		return vip;
 1.36   hannken 	}
 1.36   hannken 	return NULL;
 1.36   hannken }
 1.36   hannken
 1.36   hannken /*
 1.50   hannken  * Allocate a new, uninitialized vcache node.
 1.50   hannken  */
 1.57   hannken static vnode_impl_t *
 1.50   hannken vcache_alloc(void)
 1.50   hannken {
 1.70   hannken 	vnode_impl_t *vip;
 1.50   hannken 	vnode_t *vp;
 1.50   hannken
 1.70   hannken 	vip = pool_cache_get(vcache_pool, PR_WAITOK);
1.111        ad 	vp = VIMPL_TO_VNODE(vip);
 1.70   hannken 	memset(vip, 0, sizeof(*vip));
 1.50   hannken
1.112        ad 	rw_init(&vip->vi_lock);
1.111        ad 	vp->v_interlock = mutex_obj_alloc(MUTEX_DEFAULT, IPL_NONE);
1.111        ad
1.111        ad 	uvm_obj_init(&vp->v_uobj, &uvm_vnodeops, true, 1);
1.144   thorpej 	klist_init(&vip->vi_klist.vk_klist);
1.144   thorpej 	vp->v_klist = &vip->vi_klist;
 1.50   hannken 	cv_init(&vp->v_cv, "vnode");
1.114        ad 	cache_vnode_init(vp);
 1.50   hannken
 1.50   hannken 	vp->v_usecount = 1;
 1.50   hannken 	vp->v_type = VNON;
 1.50   hannken 	vp->v_size = vp->v_writesize = VSIZENOTSET;
 1.50   hannken
 1.70   hannken 	vip->vi_state = VS_LOADING;
 1.51   hannken
1.104        ad 	lru_requeue(vp, &lru_list[LRU_FREE]);
 1.63   hannken
 1.70   hannken 	return vip;
 1.50   hannken }
 1.50   hannken
 1.50   hannken /*
 1.79   hannken  * Deallocate a vcache node in state VS_LOADING.
 1.79   hannken  *
 1.79   hannken  * vcache_lock held on entry and released on return.
 1.79   hannken  */
 1.79   hannken static void
 1.79   hannken vcache_dealloc(vnode_impl_t *vip)
 1.79   hannken {
 1.79   hannken 	vnode_t *vp;
 1.79   hannken
 1.79   hannken 	KASSERT(mutex_owned(&vcache_lock));
 1.79   hannken
 1.79   hannken 	vp = VIMPL_TO_VNODE(vip);
1.102   hannken 	vfs_ref(dead_rootmount);
1.102   hannken 	vfs_insmntque(vp, dead_rootmount);
 1.79   hannken 	mutex_enter(vp->v_interlock);
 1.79   hannken 	vp->v_op = dead_vnodeop_p;
 1.79   hannken 	VSTATE_CHANGE(vp, VS_LOADING, VS_RECLAIMED);
 1.79   hannken 	mutex_exit(&vcache_lock);
1.107        ad 	vrelel(vp, 0, LK_NONE);
 1.79   hannken }
 1.79   hannken
 1.79   hannken /*
 1.50   hannken  * Free an unused, unreferenced vcache node.
 1.67   hannken  * v_interlock locked on entry.
 1.50   hannken  */
 1.50   hannken static void
 1.70   hannken vcache_free(vnode_impl_t *vip)
 1.50   hannken {
 1.50   hannken 	vnode_t *vp;
 1.50   hannken
 1.70   hannken 	vp = VIMPL_TO_VNODE(vip);
 1.67   hannken 	KASSERT(mutex_owned(vp->v_interlock));
 1.50   hannken
1.120        ad 	KASSERT(vrefcnt(vp) == 0);
 1.67   hannken 	KASSERT(vp->v_holdcnt == 0);
 1.67   hannken 	KASSERT(vp->v_writecount == 0);
 1.67   hannken 	lru_requeue(vp, NULL);
 1.67   hannken 	mutex_exit(vp->v_interlock);
 1.67   hannken
 1.67   hannken 	vfs_insmntque(vp, NULL);
 1.67   hannken 	if (vp->v_type == VBLK || vp->v_type == VCHR)
 1.67   hannken 		spec_node_destroy(vp);
 1.50   hannken
1.111        ad 	mutex_obj_free(vp->v_interlock);
1.112        ad 	rw_destroy(&vip->vi_lock);
 1.50   hannken 	uvm_obj_destroy(&vp->v_uobj, true);
1.144   thorpej 	KASSERT(vp->v_klist == &vip->vi_klist ||
1.144   thorpej 		SLIST_EMPTY(&vip->vi_klist.vk_klist));
1.144   thorpej 	klist_fini(&vip->vi_klist.vk_klist);
 1.50   hannken 	cv_destroy(&vp->v_cv);
1.114        ad 	cache_vnode_fini(vp);
 1.70   hannken 	pool_cache_put(vcache_pool, vip);
 1.50   hannken }
 1.50   hannken
 1.50   hannken /*
 1.66   hannken  * Try to get an initial reference on this cached vnode.
1.123        ad  * Returns zero on success or EBUSY if the vnode state is not LOADED.
 1.66   hannken  *
1.123        ad  * NB: lockless code sequences may rely on this not blocking.
 1.66   hannken  */
 1.66   hannken int
 1.66   hannken vcache_tryvget(vnode_t *vp)
 1.66   hannken {
1.123        ad 	u_int use, next;
 1.66   hannken
1.123        ad 	for (use = atomic_load_relaxed(&vp->v_usecount);; use = next) {
1.123        ad 		if (__predict_false((use & VUSECOUNT_GATE) == 0)) {
1.123        ad 			return EBUSY;
1.123        ad 		}
1.132   hannken 		next = atomic_cas_uint(&vp->v_usecount,
1.132   hannken 		    use, (use + 1) | VUSECOUNT_VGET);
1.123        ad 		if (__predict_true(next == use)) {
1.136  riastrad #ifndef __HAVE_ATOMIC_AS_MEMBAR
1.142  riastrad 			membar_acquire();
1.136  riastrad #endif
1.123        ad 			return 0;
1.123        ad 		}
1.123        ad 	}
 1.66   hannken }
 1.66   hannken
 1.66   hannken /*
 1.66   hannken  * Try to get an initial reference on this cached vnode.
 1.66   hannken  * Returns zero on success and  ENOENT if the vnode has been reclaimed.
 1.66   hannken  * Will wait for the vnode state to be stable.
 1.66   hannken  *
 1.66   hannken  * v_interlock locked on entry and unlocked on exit.
 1.66   hannken  */
 1.66   hannken int
 1.66   hannken vcache_vget(vnode_t *vp)
 1.66   hannken {
1.132   hannken 	int error;
 1.66   hannken
 1.66   hannken 	KASSERT(mutex_owned(vp->v_interlock));
 1.66   hannken
 1.67   hannken 	/* Increment hold count to prevent vnode from disappearing. */
 1.67   hannken 	vp->v_holdcnt++;
 1.67   hannken 	VSTATE_WAIT_STABLE(vp);
 1.67   hannken 	vp->v_holdcnt--;
 1.66   hannken
 1.67   hannken 	/* If this was the last reference to a reclaimed vnode free it now. */
 1.67   hannken 	if (__predict_false(VSTATE_GET(vp) == VS_RECLAIMED)) {
1.120        ad 		if (vp->v_holdcnt == 0 && vrefcnt(vp) == 0)
 1.67   hannken 			vcache_free(VNODE_TO_VIMPL(vp));
 1.67   hannken 		else
 1.67   hannken 			mutex_exit(vp->v_interlock);
 1.66   hannken 		return ENOENT;
 1.66   hannken 	}
 1.94   hannken 	VSTATE_ASSERT(vp, VS_LOADED);
1.132   hannken 	error = vcache_tryvget(vp);
1.132   hannken 	KASSERT(error == 0);
 1.66   hannken 	mutex_exit(vp->v_interlock);
 1.66   hannken
 1.66   hannken 	return 0;
 1.66   hannken }
 1.66   hannken
 1.66   hannken /*
 1.36   hannken  * Get a vnode / fs node pair by key and return it referenced through vpp.
 1.36   hannken  */
 1.36   hannken int
 1.36   hannken vcache_get(struct mount *mp, const void *key, size_t key_len,
 1.36   hannken     struct vnode **vpp)
 1.36   hannken {
 1.36   hannken 	int error;
 1.36   hannken 	uint32_t hash;
 1.36   hannken 	const void *new_key;
 1.36   hannken 	struct vnode *vp;
 1.36   hannken 	struct vcache_key vcache_key;
 1.70   hannken 	vnode_impl_t *vip, *new_vip;
 1.36   hannken
 1.36   hannken 	new_key = NULL;
 1.36   hannken 	*vpp = NULL;
 1.36   hannken
 1.36   hannken 	vcache_key.vk_mount = mp;
 1.36   hannken 	vcache_key.vk_key = key;
 1.36   hannken 	vcache_key.vk_key_len = key_len;
 1.36   hannken 	hash = vcache_hash(&vcache_key);
 1.36   hannken
 1.36   hannken again:
 1.69   hannken 	mutex_enter(&vcache_lock);
 1.70   hannken 	vip = vcache_hash_lookup(&vcache_key, hash);
 1.36   hannken
 1.36   hannken 	/* If found, take a reference or retry. */
 1.70   hannken 	if (__predict_true(vip != NULL)) {
 1.52   hannken 		/*
 1.52   hannken 		 * If the vnode is loading we cannot take the v_interlock
 1.52   hannken 		 * here as it might change during load (see uvm_obj_setlock()).
 1.69   hannken 		 * As changing state from VS_LOADING requires both vcache_lock
 1.69   hannken 		 * and v_interlock it is safe to test with vcache_lock held.
 1.52   hannken 		 *
 1.57   hannken 		 * Wait for vnodes changing state from VS_LOADING and retry.
 1.52   hannken 		 */
 1.70   hannken 		if (__predict_false(vip->vi_state == VS_LOADING)) {
 1.69   hannken 			cv_wait(&vcache_cv, &vcache_lock);
 1.69   hannken 			mutex_exit(&vcache_lock);
 1.52   hannken 			goto again;
 1.52   hannken 		}
 1.70   hannken 		vp = VIMPL_TO_VNODE(vip);
 1.36   hannken 		mutex_enter(vp->v_interlock);
 1.69   hannken 		mutex_exit(&vcache_lock);
 1.66   hannken 		error = vcache_vget(vp);
 1.36   hannken 		if (error == ENOENT)
 1.36   hannken 			goto again;
 1.36   hannken 		if (error == 0)
 1.36   hannken 			*vpp = vp;
 1.36   hannken 		KASSERT((error != 0) == (*vpp == NULL));
 1.36   hannken 		return error;
 1.36   hannken 	}
 1.69   hannken 	mutex_exit(&vcache_lock);
 1.36   hannken
 1.36   hannken 	/* Allocate and initialize a new vcache / vnode pair. */
 1.87   hannken 	error = vfs_busy(mp);
 1.36   hannken 	if (error)
 1.36   hannken 		return error;
 1.70   hannken 	new_vip = vcache_alloc();
 1.70   hannken 	new_vip->vi_key = vcache_key;
 1.70   hannken 	vp = VIMPL_TO_VNODE(new_vip);
 1.69   hannken 	mutex_enter(&vcache_lock);
 1.70   hannken 	vip = vcache_hash_lookup(&vcache_key, hash);
 1.70   hannken 	if (vip == NULL) {
 1.69   hannken 		SLIST_INSERT_HEAD(&vcache_hashtab[hash & vcache_hashmask],
 1.70   hannken 		    new_vip, vi_hash);
 1.70   hannken 		vip = new_vip;
 1.36   hannken 	}
 1.36   hannken
 1.36   hannken 	/* If another thread beat us inserting this node, retry. */
 1.70   hannken 	if (vip != new_vip) {
 1.79   hannken 		vcache_dealloc(new_vip);
 1.87   hannken 		vfs_unbusy(mp);
 1.36   hannken 		goto again;
 1.36   hannken 	}
 1.69   hannken 	mutex_exit(&vcache_lock);
 1.36   hannken
 1.57   hannken 	/* Load the fs node.  Exclusive as new_node is VS_LOADING. */
 1.36   hannken 	error = VFS_LOADVNODE(mp, vp, key, key_len, &new_key);
 1.36   hannken 	if (error) {
 1.69   hannken 		mutex_enter(&vcache_lock);
 1.69   hannken 		SLIST_REMOVE(&vcache_hashtab[hash & vcache_hashmask],
 1.70   hannken 		    new_vip, vnode_impl, vi_hash);
 1.79   hannken 		vcache_dealloc(new_vip);
 1.87   hannken 		vfs_unbusy(mp);
 1.36   hannken 		KASSERT(*vpp == NULL);
 1.36   hannken 		return error;
 1.36   hannken 	}
 1.36   hannken 	KASSERT(new_key != NULL);
 1.36   hannken 	KASSERT(memcmp(key, new_key, key_len) == 0);
 1.36   hannken 	KASSERT(vp->v_op != NULL);
 1.36   hannken 	vfs_insmntque(vp, mp);
 1.36   hannken 	if ((mp->mnt_iflag & IMNT_MPSAFE) != 0)
 1.36   hannken 		vp->v_vflag |= VV_MPSAFE;
 1.87   hannken 	vfs_ref(mp);
 1.87   hannken 	vfs_unbusy(mp);
 1.36   hannken
 1.36   hannken 	/* Finished loading, finalize node. */
 1.69   hannken 	mutex_enter(&vcache_lock);
 1.70   hannken 	new_vip->vi_key.vk_key = new_key;
 1.39   hannken 	mutex_enter(vp->v_interlock);
 1.94   hannken 	VSTATE_CHANGE(vp, VS_LOADING, VS_LOADED);
 1.39   hannken 	mutex_exit(vp->v_interlock);
 1.69   hannken 	mutex_exit(&vcache_lock);
 1.36   hannken 	*vpp = vp;
 1.36   hannken 	return 0;
 1.36   hannken }
 1.36   hannken
 1.36   hannken /*
 1.40   hannken  * Create a new vnode / fs node pair and return it referenced through vpp.
 1.40   hannken  */
 1.40   hannken int
 1.40   hannken vcache_new(struct mount *mp, struct vnode *dvp, struct vattr *vap,
1.101   hannken     kauth_cred_t cred, void *extra, struct vnode **vpp)
 1.40   hannken {
 1.40   hannken 	int error;
 1.40   hannken 	uint32_t hash;
 1.70   hannken 	struct vnode *vp, *ovp;
 1.70   hannken 	vnode_impl_t *vip, *ovip;
 1.40   hannken
 1.40   hannken 	*vpp = NULL;
 1.40   hannken
 1.40   hannken 	/* Allocate and initialize a new vcache / vnode pair. */
 1.87   hannken 	error = vfs_busy(mp);
 1.40   hannken 	if (error)
 1.40   hannken 		return error;
 1.70   hannken 	vip = vcache_alloc();
 1.70   hannken 	vip->vi_key.vk_mount = mp;
 1.70   hannken 	vp = VIMPL_TO_VNODE(vip);
 1.40   hannken
 1.40   hannken 	/* Create and load the fs node. */
1.101   hannken 	error = VFS_NEWVNODE(mp, dvp, vp, vap, cred, extra,
 1.70   hannken 	    &vip->vi_key.vk_key_len, &vip->vi_key.vk_key);
 1.40   hannken 	if (error) {
 1.69   hannken 		mutex_enter(&vcache_lock);
 1.79   hannken 		vcache_dealloc(vip);
 1.87   hannken 		vfs_unbusy(mp);
 1.40   hannken 		KASSERT(*vpp == NULL);
 1.40   hannken 		return error;
 1.40   hannken 	}
 1.40   hannken 	KASSERT(vp->v_op != NULL);
 1.97   hannken 	KASSERT((vip->vi_key.vk_key_len == 0) == (mp == dead_rootmount));
 1.97   hannken 	if (vip->vi_key.vk_key_len > 0) {
 1.97   hannken 		KASSERT(vip->vi_key.vk_key != NULL);
 1.97   hannken 		hash = vcache_hash(&vip->vi_key);
 1.40   hannken
 1.97   hannken 		/*
 1.97   hannken 		 * Wait for previous instance to be reclaimed,
 1.97   hannken 		 * then insert new node.
 1.97   hannken 		 */
 1.97   hannken 		mutex_enter(&vcache_lock);
 1.97   hannken 		while ((ovip = vcache_hash_lookup(&vip->vi_key, hash))) {
 1.97   hannken 			ovp = VIMPL_TO_VNODE(ovip);
 1.97   hannken 			mutex_enter(ovp->v_interlock);
 1.97   hannken 			mutex_exit(&vcache_lock);
 1.97   hannken 			error = vcache_vget(ovp);
 1.97   hannken 			KASSERT(error == ENOENT);
 1.97   hannken 			mutex_enter(&vcache_lock);
 1.97   hannken 		}
 1.97   hannken 		SLIST_INSERT_HEAD(&vcache_hashtab[hash & vcache_hashmask],
 1.97   hannken 		    vip, vi_hash);
 1.69   hannken 		mutex_exit(&vcache_lock);
 1.40   hannken 	}
 1.40   hannken 	vfs_insmntque(vp, mp);
 1.40   hannken 	if ((mp->mnt_iflag & IMNT_MPSAFE) != 0)
 1.40   hannken 		vp->v_vflag |= VV_MPSAFE;
 1.87   hannken 	vfs_ref(mp);
 1.87   hannken 	vfs_unbusy(mp);
 1.40   hannken
 1.40   hannken 	/* Finished loading, finalize node. */
 1.69   hannken 	mutex_enter(&vcache_lock);
 1.52   hannken 	mutex_enter(vp->v_interlock);
 1.94   hannken 	VSTATE_CHANGE(vp, VS_LOADING, VS_LOADED);
 1.69   hannken 	mutex_exit(&vcache_lock);
 1.40   hannken 	mutex_exit(vp->v_interlock);
 1.40   hannken 	*vpp = vp;
 1.40   hannken 	return 0;
 1.40   hannken }
 1.40   hannken
 1.40   hannken /*
 1.65   hannken  * Prepare key change: update old cache nodes key and lock new cache node.
 1.37   hannken  * Return an error if the new node already exists.
 1.37   hannken  */
 1.37   hannken int
 1.37   hannken vcache_rekey_enter(struct mount *mp, struct vnode *vp,
 1.37   hannken     const void *old_key, size_t old_key_len,
 1.37   hannken     const void *new_key, size_t new_key_len)
 1.37   hannken {
 1.37   hannken 	uint32_t old_hash, new_hash;
 1.37   hannken 	struct vcache_key old_vcache_key, new_vcache_key;
 1.70   hannken 	vnode_impl_t *vip, *new_vip;
 1.37   hannken
 1.37   hannken 	old_vcache_key.vk_mount = mp;
 1.37   hannken 	old_vcache_key.vk_key = old_key;
 1.37   hannken 	old_vcache_key.vk_key_len = old_key_len;
 1.37   hannken 	old_hash = vcache_hash(&old_vcache_key);
 1.37   hannken
 1.37   hannken 	new_vcache_key.vk_mount = mp;
 1.37   hannken 	new_vcache_key.vk_key = new_key;
 1.37   hannken 	new_vcache_key.vk_key_len = new_key_len;
 1.37   hannken 	new_hash = vcache_hash(&new_vcache_key);
 1.37   hannken
 1.70   hannken 	new_vip = vcache_alloc();
 1.70   hannken 	new_vip->vi_key = new_vcache_key;
 1.37   hannken
 1.52   hannken 	/* Insert locked new node used as placeholder. */
 1.69   hannken 	mutex_enter(&vcache_lock);
 1.70   hannken 	vip = vcache_hash_lookup(&new_vcache_key, new_hash);
 1.70   hannken 	if (vip != NULL) {
 1.79   hannken 		vcache_dealloc(new_vip);
 1.37   hannken 		return EEXIST;
 1.37   hannken 	}
 1.69   hannken 	SLIST_INSERT_HEAD(&vcache_hashtab[new_hash & vcache_hashmask],
 1.70   hannken 	    new_vip, vi_hash);
 1.49   hannken
 1.65   hannken 	/* Replace old nodes key with the temporary copy. */
 1.70   hannken 	vip = vcache_hash_lookup(&old_vcache_key, old_hash);
 1.70   hannken 	KASSERT(vip != NULL);
 1.70   hannken 	KASSERT(VIMPL_TO_VNODE(vip) == vp);
 1.70   hannken 	KASSERT(vip->vi_key.vk_key != old_vcache_key.vk_key);
 1.70   hannken 	vip->vi_key = old_vcache_key;
 1.69   hannken 	mutex_exit(&vcache_lock);
 1.37   hannken 	return 0;
 1.37   hannken }
 1.37   hannken
 1.37   hannken /*
 1.65   hannken  * Key change complete: update old node and remove placeholder.
 1.37   hannken  */
 1.37   hannken void
 1.37   hannken vcache_rekey_exit(struct mount *mp, struct vnode *vp,
 1.37   hannken     const void *old_key, size_t old_key_len,
 1.37   hannken     const void *new_key, size_t new_key_len)
 1.37   hannken {
 1.37   hannken 	uint32_t old_hash, new_hash;
 1.37   hannken 	struct vcache_key old_vcache_key, new_vcache_key;
 1.70   hannken 	vnode_impl_t *vip, *new_vip;
 1.70   hannken 	struct vnode *new_vp;
 1.37   hannken
 1.37   hannken 	old_vcache_key.vk_mount = mp;
 1.37   hannken 	old_vcache_key.vk_key = old_key;
 1.37   hannken 	old_vcache_key.vk_key_len = old_key_len;
 1.37   hannken 	old_hash = vcache_hash(&old_vcache_key);
 1.37   hannken
 1.37   hannken 	new_vcache_key.vk_mount = mp;
 1.37   hannken 	new_vcache_key.vk_key = new_key;
 1.37   hannken 	new_vcache_key.vk_key_len = new_key_len;
 1.37   hannken 	new_hash = vcache_hash(&new_vcache_key);
 1.37   hannken
 1.69   hannken 	mutex_enter(&vcache_lock);
 1.49   hannken
 1.49   hannken 	/* Lookup old and new node. */
 1.70   hannken 	vip = vcache_hash_lookup(&old_vcache_key, old_hash);
 1.70   hannken 	KASSERT(vip != NULL);
 1.70   hannken 	KASSERT(VIMPL_TO_VNODE(vip) == vp);
 1.70   hannken
 1.70   hannken 	new_vip = vcache_hash_lookup(&new_vcache_key, new_hash);
 1.70   hannken 	KASSERT(new_vip != NULL);
 1.70   hannken 	KASSERT(new_vip->vi_key.vk_key_len == new_key_len);
 1.70   hannken 	new_vp = VIMPL_TO_VNODE(new_vip);
 1.70   hannken 	mutex_enter(new_vp->v_interlock);
 1.70   hannken 	VSTATE_ASSERT(VIMPL_TO_VNODE(new_vip), VS_LOADING);
 1.79   hannken 	mutex_exit(new_vp->v_interlock);
 1.49   hannken
 1.49   hannken 	/* Rekey old node and put it onto its new hashlist. */
 1.70   hannken 	vip->vi_key = new_vcache_key;
 1.49   hannken 	if (old_hash != new_hash) {
 1.69   hannken 		SLIST_REMOVE(&vcache_hashtab[old_hash & vcache_hashmask],
 1.70   hannken 		    vip, vnode_impl, vi_hash);
 1.69   hannken 		SLIST_INSERT_HEAD(&vcache_hashtab[new_hash & vcache_hashmask],
 1.70   hannken 		    vip, vi_hash);
 1.49   hannken 	}
 1.49   hannken
 1.49   hannken 	/* Remove new node used as placeholder. */
 1.69   hannken 	SLIST_REMOVE(&vcache_hashtab[new_hash & vcache_hashmask],
 1.70   hannken 	    new_vip, vnode_impl, vi_hash);
 1.79   hannken 	vcache_dealloc(new_vip);
 1.37   hannken }
 1.37   hannken
 1.37   hannken /*
 1.54   hannken  * Disassociate the underlying file system from a vnode.
 1.54   hannken  *
 1.54   hannken  * Must be called with vnode locked and will return unlocked.
 1.54   hannken  * Must be called with the interlock held, and will return with it held.
 1.54   hannken  */
 1.54   hannken static void
 1.54   hannken vcache_reclaim(vnode_t *vp)
 1.54   hannken {
 1.54   hannken 	lwp_t *l = curlwp;
 1.70   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.74   hannken 	struct mount *mp = vp->v_mount;
 1.55   hannken 	uint32_t hash;
 1.55   hannken 	uint8_t temp_buf[64], *temp_key;
 1.55   hannken 	size_t temp_key_len;
1.141  riastrad 	bool recycle;
 1.54   hannken 	int error;
 1.54   hannken
1.139   hannken 	KASSERT(VOP_ISLOCKED(vp) == LK_EXCLUSIVE);
 1.54   hannken 	KASSERT(mutex_owned(vp->v_interlock));
1.120        ad 	KASSERT(vrefcnt(vp) != 0);
 1.54   hannken
 1.70   hannken 	temp_key_len = vip->vi_key.vk_key_len;
 1.54   hannken 	/*
 1.54   hannken 	 * Prevent the vnode from being recycled or brought into use
 1.54   hannken 	 * while we clean it out.
 1.54   hannken 	 */
1.123        ad 	VSTATE_CHANGE(vp, VS_BLOCKED, VS_RECLAIMING);
1.111        ad 	mutex_exit(vp->v_interlock);
1.111        ad
1.111        ad 	rw_enter(vp->v_uobj.vmobjlock, RW_WRITER);
1.111        ad 	mutex_enter(vp->v_interlock);
1.125        ad 	if ((vp->v_iflag & VI_EXECMAP) != 0) {
1.105        ad 		cpu_count(CPU_COUNT_EXECPAGES, -vp->v_uobj.uo_npages);
 1.54   hannken 	}
 1.54   hannken 	vp->v_iflag &= ~(VI_TEXT|VI_EXECMAP);
1.116        ad 	vp->v_iflag |= VI_DEADCHECK; /* for genfs_getpages() */
 1.54   hannken 	mutex_exit(vp->v_interlock);
1.111        ad 	rw_exit(vp->v_uobj.vmobjlock);
 1.54   hannken
1.114        ad 	/*
1.114        ad 	 * With vnode state set to reclaiming, purge name cache immediately
1.114        ad 	 * to prevent new handles on vnode, and wait for existing threads
1.114        ad 	 * trying to get a handle to notice VS_RECLAIMED status and abort.
1.114        ad 	 */
1.114        ad 	cache_purge(vp);
1.114        ad
 1.55   hannken 	/* Replace the vnode key with a temporary copy. */
 1.70   hannken 	if (vip->vi_key.vk_key_len > sizeof(temp_buf)) {
 1.55   hannken 		temp_key = kmem_alloc(temp_key_len, KM_SLEEP);
 1.55   hannken 	} else {
 1.55   hannken 		temp_key = temp_buf;
 1.55   hannken 	}
 1.97   hannken 	if (vip->vi_key.vk_key_len > 0) {
 1.97   hannken 		mutex_enter(&vcache_lock);
 1.97   hannken 		memcpy(temp_key, vip->vi_key.vk_key, temp_key_len);
 1.97   hannken 		vip->vi_key.vk_key = temp_key;
 1.97   hannken 		mutex_exit(&vcache_lock);
 1.97   hannken 	}
 1.55   hannken
 1.96   hannken 	fstrans_start(mp);
 1.74   hannken
 1.54   hannken 	/*
 1.54   hannken 	 * Clean out any cached data associated with the vnode.
 1.54   hannken 	 */
 1.54   hannken 	error = vinvalbuf(vp, V_SAVE, NOCRED, l, 0, 0);
 1.54   hannken 	if (error != 0) {
 1.54   hannken 		if (wapbl_vphaswapbl(vp))
 1.54   hannken 			WAPBL_DISCARD(wapbl_vptomp(vp));
 1.54   hannken 		error = vinvalbuf(vp, 0, NOCRED, l, 0, 0);
 1.54   hannken 	}
 1.54   hannken 	KASSERTMSG((error == 0), "vinvalbuf failed: %d", error);
 1.54   hannken 	KASSERT((vp->v_iflag & VI_ONWORKLST) == 0);
1.141  riastrad 	if (vp->v_type == VBLK || vp->v_type == VCHR) {
 1.54   hannken 		 spec_node_revoke(vp);
 1.54   hannken 	}
 1.54   hannken
 1.60   hannken 	/*
 1.60   hannken 	 * Disassociate the underlying file system from the vnode.
 1.90  riastrad 	 * VOP_INACTIVE leaves the vnode locked; VOP_RECLAIM unlocks
 1.90  riastrad 	 * the vnode, and may destroy the vnode so that VOP_UNLOCK
 1.90  riastrad 	 * would no longer function.
 1.60   hannken 	 */
 1.60   hannken 	VOP_INACTIVE(vp, &recycle);
1.139   hannken 	KASSERT(VOP_ISLOCKED(vp) == LK_EXCLUSIVE);
 1.54   hannken 	if (VOP_RECLAIM(vp)) {
 1.54   hannken 		vnpanic(vp, "%s: cannot reclaim", __func__);
 1.54   hannken 	}
 1.54   hannken
 1.54   hannken 	KASSERT(vp->v_data == NULL);
1.113        ad 	KASSERT((vp->v_iflag & VI_PAGES) == 0);
 1.54   hannken
 1.54   hannken 	if (vp->v_type == VREG && vp->v_ractx != NULL) {
 1.54   hannken 		uvm_ra_freectx(vp->v_ractx);
 1.54   hannken 		vp->v_ractx = NULL;
 1.54   hannken 	}
 1.54   hannken
 1.97   hannken 	if (vip->vi_key.vk_key_len > 0) {
 1.55   hannken 	/* Remove from vnode cache. */
 1.97   hannken 		hash = vcache_hash(&vip->vi_key);
 1.97   hannken 		mutex_enter(&vcache_lock);
 1.97   hannken 		KASSERT(vip == vcache_hash_lookup(&vip->vi_key, hash));
 1.97   hannken 		SLIST_REMOVE(&vcache_hashtab[hash & vcache_hashmask],
 1.97   hannken 		    vip, vnode_impl, vi_hash);
 1.97   hannken 		mutex_exit(&vcache_lock);
 1.97   hannken 	}
 1.55   hannken 	if (temp_key != temp_buf)
 1.55   hannken 		kmem_free(temp_key, temp_key_len);
 1.55   hannken
 1.54   hannken 	/* Done with purge, notify sleepers of the grim news. */
 1.54   hannken 	mutex_enter(vp->v_interlock);
 1.54   hannken 	vp->v_op = dead_vnodeop_p;
 1.57   hannken 	VSTATE_CHANGE(vp, VS_RECLAIMING, VS_RECLAIMED);
 1.54   hannken 	vp->v_tag = VT_NON;
1.128   thorpej 	/*
1.128   thorpej 	 * Don't check for interest in NOTE_REVOKE; it's always posted
1.128   thorpej 	 * because it sets EV_EOF.
1.128   thorpej 	 */
1.144   thorpej 	KNOTE(&vp->v_klist->vk_klist, NOTE_REVOKE);
 1.80   hannken 	mutex_exit(vp->v_interlock);
 1.54   hannken
 1.80   hannken 	/*
 1.80   hannken 	 * Move to dead mount.  Must be after changing the operations
 1.80   hannken 	 * vector as vnode operations enter the mount before using the
 1.80   hannken 	 * operations vector.  See sys/kern/vnode_if.c.
 1.80   hannken 	 */
 1.80   hannken 	vp->v_vflag &= ~VV_ROOT;
 1.86   hannken 	vfs_ref(dead_rootmount);
 1.80   hannken 	vfs_insmntque(vp, dead_rootmount);
 1.80   hannken
1.110        ad #ifdef PAX_SEGVGUARD
1.110        ad 	pax_segvguard_cleanup(vp);
1.110        ad #endif /* PAX_SEGVGUARD */
1.110        ad
 1.80   hannken 	mutex_enter(vp->v_interlock);
 1.74   hannken 	fstrans_done(mp);
 1.54   hannken 	KASSERT((vp->v_iflag & VI_ONWORKLST) == 0);
 1.54   hannken }
 1.54   hannken
 1.54   hannken /*
 1.98   hannken  * Disassociate the underlying file system from an open device vnode
 1.98   hannken  * and make it anonymous.
 1.98   hannken  *
 1.98   hannken  * Vnode unlocked on entry, drops a reference to the vnode.
 1.98   hannken  */
 1.98   hannken void
 1.98   hannken vcache_make_anon(vnode_t *vp)
 1.98   hannken {
 1.98   hannken 	vnode_impl_t *vip = VNODE_TO_VIMPL(vp);
 1.98   hannken 	uint32_t hash;
 1.98   hannken 	bool recycle;
 1.98   hannken
 1.98   hannken 	KASSERT(vp->v_type == VBLK || vp->v_type == VCHR);
1.103   hannken 	KASSERT(vp->v_mount == dead_rootmount || fstrans_is_owner(vp->v_mount));
 1.98   hannken 	VSTATE_ASSERT_UNLOCKED(vp, VS_ACTIVE);
 1.98   hannken
 1.98   hannken 	/* Remove from vnode cache. */
 1.98   hannken 	hash = vcache_hash(&vip->vi_key);
 1.98   hannken 	mutex_enter(&vcache_lock);
 1.98   hannken 	KASSERT(vip == vcache_hash_lookup(&vip->vi_key, hash));
 1.98   hannken 	SLIST_REMOVE(&vcache_hashtab[hash & vcache_hashmask],
 1.98   hannken 	    vip, vnode_impl, vi_hash);
 1.98   hannken 	vip->vi_key.vk_mount = dead_rootmount;
 1.98   hannken 	vip->vi_key.vk_key_len = 0;
 1.98   hannken 	vip->vi_key.vk_key = NULL;
 1.98   hannken 	mutex_exit(&vcache_lock);
 1.98   hannken
 1.98   hannken 	/*
 1.98   hannken 	 * Disassociate the underlying file system from the vnode.
 1.98   hannken 	 * VOP_INACTIVE leaves the vnode locked; VOP_RECLAIM unlocks
 1.98   hannken 	 * the vnode, and may destroy the vnode so that VOP_UNLOCK
 1.98   hannken 	 * would no longer function.
 1.98   hannken 	 */
 1.98   hannken 	if (vn_lock(vp, LK_EXCLUSIVE)) {
 1.98   hannken 		vnpanic(vp, "%s: cannot lock", __func__);
 1.98   hannken 	}
 1.98   hannken 	VOP_INACTIVE(vp, &recycle);
1.139   hannken 	KASSERT(VOP_ISLOCKED(vp) == LK_EXCLUSIVE);
 1.98   hannken 	if (VOP_RECLAIM(vp)) {
 1.98   hannken 		vnpanic(vp, "%s: cannot reclaim", __func__);
 1.98   hannken 	}
 1.98   hannken
 1.98   hannken 	/* Purge name cache. */
 1.98   hannken 	cache_purge(vp);
 1.98   hannken
 1.98   hannken 	/* Done with purge, change operations vector. */
 1.98   hannken 	mutex_enter(vp->v_interlock);
 1.98   hannken 	vp->v_op = spec_vnodeop_p;
1.139   hannken 	vp->v_vflag |= VV_MPSAFE;
 1.98   hannken 	mutex_exit(vp->v_interlock);
 1.98   hannken
 1.98   hannken 	/*
 1.98   hannken 	 * Move to dead mount.  Must be after changing the operations
 1.98   hannken 	 * vector as vnode operations enter the mount before using the
 1.98   hannken 	 * operations vector.  See sys/kern/vnode_if.c.
 1.98   hannken 	 */
 1.98   hannken 	vfs_ref(dead_rootmount);
 1.98   hannken 	vfs_insmntque(vp, dead_rootmount);
 1.98   hannken
 1.98   hannken 	vrele(vp);
 1.98   hannken }
 1.98   hannken
 1.98   hannken /*
  1.1     rmind  * Update outstanding I/O count and do wakeup if requested.
  1.1     rmind  */
  1.1     rmind void
  1.1     rmind vwakeup(struct buf *bp)
  1.1     rmind {
  1.1     rmind 	vnode_t *vp;
  1.1     rmind
  1.1     rmind 	if ((vp = bp->b_vp) == NULL)
  1.1     rmind 		return;
  1.1     rmind
  1.9     rmind 	KASSERT(bp->b_objlock == vp->v_interlock);
  1.1     rmind 	KASSERT(mutex_owned(bp->b_objlock));
  1.1     rmind
  1.1     rmind 	if (--vp->v_numoutput < 0)
 1.11  christos 		vnpanic(vp, "%s: neg numoutput, vp %p", __func__, vp);
  1.1     rmind 	if (vp->v_numoutput == 0)
  1.1     rmind 		cv_broadcast(&vp->v_cv);
  1.1     rmind }
  1.1     rmind
  1.1     rmind /*
 1.35   hannken  * Test a vnode for being or becoming dead.  Returns one of:
 1.35   hannken  * EBUSY:  vnode is becoming dead, with "flags == VDEAD_NOWAIT" only.
 1.35   hannken  * ENOENT: vnode is dead.
 1.35   hannken  * 0:      otherwise.
 1.35   hannken  *
 1.35   hannken  * Whenever this function returns a non-zero value all future
 1.35   hannken  * calls will also return a non-zero value.
 1.35   hannken  */
 1.35   hannken int
 1.35   hannken vdead_check(struct vnode *vp, int flags)
 1.35   hannken {
 1.35   hannken
 1.35   hannken 	KASSERT(mutex_owned(vp->v_interlock));
 1.35   hannken
 1.52   hannken 	if (! ISSET(flags, VDEAD_NOWAIT))
 1.52   hannken 		VSTATE_WAIT_STABLE(vp);
  1.1     rmind
 1.57   hannken 	if (VSTATE_GET(vp) == VS_RECLAIMING) {
 1.52   hannken 		KASSERT(ISSET(flags, VDEAD_NOWAIT));
 1.52   hannken 		return EBUSY;
 1.57   hannken 	} else if (VSTATE_GET(vp) == VS_RECLAIMED) {
 1.52   hannken 		return ENOENT;
 1.52   hannken 	}
  1.1     rmind
 1.52   hannken 	return 0;
  1.1     rmind }
  1.1     rmind
  1.1     rmind int
 1.61   hannken vfs_drainvnodes(void)
  1.1     rmind {
 1.63   hannken 	int i, gen;
 1.61   hannken
 1.63   hannken 	mutex_enter(&vdrain_lock);
 1.63   hannken 	for (i = 0; i < 2; i++) {
 1.63   hannken 		gen = vdrain_gen;
 1.63   hannken 		while (gen == vdrain_gen) {
 1.63   hannken 			cv_broadcast(&vdrain_cv);
 1.63   hannken 			cv_wait(&vdrain_gen_cv, &vdrain_lock);
 1.63   hannken 		}
 1.61   hannken 	}
 1.63   hannken 	mutex_exit(&vdrain_lock);
 1.12   hannken
 1.63   hannken 	if (numvnodes >= desiredvnodes)
 1.63   hannken 		return EBUSY;
 1.12   hannken
 1.69   hannken 	if (vcache_hashsize != desiredvnodes)
 1.61   hannken 		vcache_reinit();
 1.36   hannken
  1.1     rmind 	return 0;
  1.1     rmind }
  1.1     rmind
  1.1     rmind void
 1.11  christos vnpanic(vnode_t *vp, const char *fmt, ...)
  1.1     rmind {
 1.11  christos 	va_list ap;
 1.11  christos
  1.1     rmind #ifdef DIAGNOSTIC
  1.1     rmind 	vprint(NULL, vp);
  1.1     rmind #endif
 1.11  christos 	va_start(ap, fmt);
 1.11  christos 	vpanic(fmt, ap);
 1.11  christos 	va_end(ap);
  1.1     rmind }
1.111        ad
1.111        ad void
1.111        ad vshareilock(vnode_t *tvp, vnode_t *fvp)
1.111        ad {
1.111        ad 	kmutex_t *oldlock;
1.111        ad
1.111        ad 	oldlock = tvp->v_interlock;
1.111        ad 	mutex_obj_hold(fvp->v_interlock);
1.111        ad 	tvp->v_interlock = fvp->v_interlock;
1.111        ad 	mutex_obj_free(oldlock);
1.111        ad }
1.144   thorpej
1.144   thorpej void
1.144   thorpej vshareklist(vnode_t *tvp, vnode_t *fvp)
1.144   thorpej {
1.144   thorpej 	/*
1.144   thorpej 	 * If two vnodes share klist state, they must also share
1.144   thorpej 	 * an interlock.
1.144   thorpej 	 */
1.144   thorpej 	KASSERT(tvp->v_interlock == fvp->v_interlock);
1.144   thorpej
1.144   thorpej 	/*
1.144   thorpej 	 * We make the following assumptions:
1.144   thorpej 	 *
1.144   thorpej 	 * ==> Some other synchronization is happening outside of
1.144   thorpej 	 *     our view to make this safe.
1.144   thorpej 	 *
1.144   thorpej 	 * ==> That the "to" vnode will have the necessary references
1.144   thorpej 	 *     on the "from" vnode so that the storage for the klist
1.144   thorpej 	 *     won't be yanked out from beneath us (the vnode_impl).
1.144   thorpej 	 *
1.144   thorpej 	 * ==> If "from" is also sharing, we then assume that "from"
1.144   thorpej 	 *     has the necessary references, and so on.
1.144   thorpej 	 */
1.144   thorpej 	tvp->v_klist = fvp->v_klist;
1.144   thorpej }