fs/udf/udf_strat_rmw.c

1.3.6.2  mjf /* $NetBSD: udf_strat_rmw.c,v 1.3.6.2 2008/06/02 13:24:06 mjf Exp $ */
1.3.6.2  mjf
1.3.6.2  mjf /*
1.3.6.2  mjf  * Copyright (c) 2006, 2008 Reinoud Zandijk
1.3.6.2  mjf  * All rights reserved.
1.3.6.2  mjf  *
1.3.6.2  mjf  * Redistribution and use in source and binary forms, with or without
1.3.6.2  mjf  * modification, are permitted provided that the following conditions
1.3.6.2  mjf  * are met:
1.3.6.2  mjf  * 1. Redistributions of source code must retain the above copyright
1.3.6.2  mjf  *    notice, this list of conditions and the following disclaimer.
1.3.6.2  mjf  * 2. Redistributions in binary form must reproduce the above copyright
1.3.6.2  mjf  *    notice, this list of conditions and the following disclaimer in the
1.3.6.2  mjf  *    documentation and/or other materials provided with the distribution.
1.3.6.2  mjf  *
1.3.6.2  mjf  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
1.3.6.2  mjf  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
1.3.6.2  mjf  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
1.3.6.2  mjf  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
1.3.6.2  mjf  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
1.3.6.2  mjf  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
1.3.6.2  mjf  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
1.3.6.2  mjf  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
1.3.6.2  mjf  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
1.3.6.2  mjf  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
1.3.6.2  mjf  *
1.3.6.2  mjf  */
1.3.6.2  mjf
1.3.6.2  mjf #include <sys/cdefs.h>
1.3.6.2  mjf #ifndef lint
1.3.6.2  mjf __KERNEL_RCSID(0, "$NetBSD: udf_strat_rmw.c,v 1.3.6.2 2008/06/02 13:24:06 mjf Exp $");
1.3.6.2  mjf #endif /* not lint */
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf #if defined(_KERNEL_OPT)
1.3.6.2  mjf #include "opt_quota.h"
1.3.6.2  mjf #include "opt_compat_netbsd.h"
1.3.6.2  mjf #endif
1.3.6.2  mjf
1.3.6.2  mjf #include <sys/param.h>
1.3.6.2  mjf #include <sys/systm.h>
1.3.6.2  mjf #include <sys/sysctl.h>
1.3.6.2  mjf #include <sys/namei.h>
1.3.6.2  mjf #include <sys/proc.h>
1.3.6.2  mjf #include <sys/kernel.h>
1.3.6.2  mjf #include <sys/vnode.h>
1.3.6.2  mjf #include <miscfs/genfs/genfs_node.h>
1.3.6.2  mjf #include <sys/mount.h>
1.3.6.2  mjf #include <sys/buf.h>
1.3.6.2  mjf #include <sys/file.h>
1.3.6.2  mjf #include <sys/device.h>
1.3.6.2  mjf #include <sys/disklabel.h>
1.3.6.2  mjf #include <sys/ioctl.h>
1.3.6.2  mjf #include <sys/malloc.h>
1.3.6.2  mjf #include <sys/dirent.h>
1.3.6.2  mjf #include <sys/stat.h>
1.3.6.2  mjf #include <sys/conf.h>
1.3.6.2  mjf #include <sys/kauth.h>
1.3.6.2  mjf #include <sys/kthread.h>
1.3.6.2  mjf #include <dev/clock_subr.h>
1.3.6.2  mjf
1.3.6.2  mjf #include <fs/udf/ecma167-udf.h>
1.3.6.2  mjf #include <fs/udf/udf_mount.h>
1.3.6.2  mjf
1.3.6.2  mjf #if defined(_KERNEL_OPT)
1.3.6.2  mjf #include "opt_udf.h"
1.3.6.2  mjf #endif
1.3.6.2  mjf
1.3.6.2  mjf #include "udf.h"
1.3.6.2  mjf #include "udf_subr.h"
1.3.6.2  mjf #include "udf_bswap.h"
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf #define VTOI(vnode) ((struct udf_node *) (vnode)->v_data)
1.3.6.2  mjf #define PRIV(ump) ((struct strat_private *) (ump)->strategy_private)
1.3.6.2  mjf #define BTOE(buf) ((struct udf_eccline *) ((buf)->b_private))
1.3.6.2  mjf
1.3.6.2  mjf /* --------------------------------------------------------------------- */
1.3.6.2  mjf
1.3.6.2  mjf #define UDF_MAX_PACKET_SIZE	64			/* DONT change this */
1.3.6.2  mjf
1.3.6.2  mjf /* sheduler states */
1.3.6.2  mjf #define UDF_SHED_MAX		6
1.3.6.2  mjf #define UDF_SHED_READING	1
1.3.6.2  mjf #define UDF_SHED_WRITING	2
1.3.6.2  mjf #define UDF_SHED_SEQWRITING	3
1.3.6.2  mjf #define UDF_SHED_IDLE		4			/* resting */
1.3.6.2  mjf #define UDF_SHED_FREE		5			/* recycleable */
1.3.6.2  mjf
1.3.6.2  mjf /* flags */
1.3.6.2  mjf #define ECC_LOCKED		0x01			/* prevent access   */
1.3.6.2  mjf #define ECC_WANTED		0x02			/* trying access    */
1.3.6.2  mjf #define ECC_SEQWRITING		0x04			/* sequential queue */
1.3.6.2  mjf #define ECC_FLOATING		0x08			/* not queued yet   */
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf TAILQ_HEAD(ecclineq, udf_eccline);
1.3.6.2  mjf struct udf_eccline {
1.3.6.2  mjf 	struct udf_mount	 *ump;
1.3.6.2  mjf 	uint64_t		  present;		/* preserve these */
1.3.6.2  mjf 	uint64_t		  readin;		/* bitmap */
1.3.6.2  mjf 	uint64_t		  dirty;		/* bitmap */
1.3.6.2  mjf 	uint64_t		  error;		/* bitmap */
1.3.6.2  mjf 	uint32_t		  refcnt;
1.3.6.2  mjf
1.3.6.2  mjf 	uint32_t		  flags;
1.3.6.2  mjf 	uint32_t		  start_sector;		/* physical */
1.3.6.2  mjf
1.3.6.2  mjf 	struct buf		 *buf;
1.3.6.2  mjf 	void			 *blob;
1.3.6.2  mjf
1.3.6.2  mjf 	struct buf		 *bufs[UDF_MAX_PACKET_SIZE];
1.3.6.2  mjf 	uint32_t		  bufs_bpos[UDF_MAX_PACKET_SIZE];
1.3.6.2  mjf 	int			  bufs_len[UDF_MAX_PACKET_SIZE];
1.3.6.2  mjf
1.3.6.2  mjf 	int			  queued_on;		/* on which BUFQ list */
1.3.6.2  mjf 	LIST_ENTRY(udf_eccline)   hashchain;		/* on sector lookup  */
1.3.6.2  mjf };
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf struct strat_private {
1.3.6.2  mjf 	lwp_t			 *queue_lwp;
1.3.6.2  mjf 	kcondvar_t		  discstrat_cv;		/* to wait on       */
1.3.6.2  mjf 	kmutex_t		  discstrat_mutex;	/* disc strategy    */
1.3.6.2  mjf 	kmutex_t		  seqwrite_mutex;	/* protect mappings */
1.3.6.2  mjf
1.3.6.2  mjf 	int			  run_thread;		/* thread control */
1.3.6.2  mjf 	int			  thread_finished;	/* thread control */
1.3.6.2  mjf 	int			  cur_queue;
1.3.6.2  mjf
1.3.6.2  mjf 	int			  num_floating;
1.3.6.2  mjf 	int			  num_queued[UDF_SHED_MAX];
1.3.6.2  mjf 	struct bufq_state	 *queues[UDF_SHED_MAX];
1.3.6.2  mjf 	struct timespec		  last_queued[UDF_SHED_MAX];
1.3.6.2  mjf 	struct disk_strategy	  old_strategy_setting;
1.3.6.2  mjf
1.3.6.2  mjf 	struct pool		  eccline_pool;
1.3.6.2  mjf 	struct pool		  ecclineblob_pool;
1.3.6.2  mjf 	LIST_HEAD(, udf_eccline)  eccline_hash[UDF_ECCBUF_HASHSIZE];
1.3.6.2  mjf };
1.3.6.2  mjf
1.3.6.2  mjf /* --------------------------------------------------------------------- */
1.3.6.2  mjf
1.3.6.2  mjf #define UDF_LOCK_ECCLINE(eccline) udf_lock_eccline(eccline)
1.3.6.2  mjf #define UDF_UNLOCK_ECCLINE(eccline) udf_unlock_eccline(eccline)
1.3.6.2  mjf
1.3.6.2  mjf /* can be called with or without discstrat lock */
1.3.6.2  mjf static void
1.3.6.2  mjf udf_lock_eccline(struct udf_eccline *eccline)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct strat_private *priv = PRIV(eccline->ump);
1.3.6.2  mjf 	int waslocked, ret;
1.3.6.2  mjf
1.3.6.2  mjf 	waslocked = mutex_owned(&priv->discstrat_mutex);
1.3.6.2  mjf 	if (!waslocked)
1.3.6.2  mjf 		mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	/* wait until its unlocked first */
1.3.6.2  mjf 	while (eccline->flags & ECC_LOCKED) {
1.3.6.2  mjf 		eccline->flags |= ECC_WANTED;
1.3.6.2  mjf 		ret = cv_timedwait(&priv->discstrat_cv, &priv->discstrat_mutex,
1.3.6.2  mjf 			hz/8);
1.3.6.2  mjf 		if (ret == EWOULDBLOCK)
1.3.6.2  mjf 			DPRINTF(LOCKING, ("eccline lock helt, waiting for "
1.3.6.2  mjf 				"release"));
1.3.6.2  mjf 	}
1.3.6.2  mjf 	eccline->flags |= ECC_LOCKED;
1.3.6.2  mjf 	eccline->flags &= ~ECC_WANTED;
1.3.6.2  mjf
1.3.6.2  mjf 	if (!waslocked)
1.3.6.2  mjf 		mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf /* can be called with or without discstrat lock */
1.3.6.2  mjf static void
1.3.6.2  mjf udf_unlock_eccline(struct udf_eccline *eccline)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct strat_private *priv = PRIV(eccline->ump);
1.3.6.2  mjf 	int waslocked;
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(mutex_owned(&priv->discstrat_mutex));
1.3.6.2  mjf
1.3.6.2  mjf 	waslocked = mutex_owned(&priv->discstrat_mutex);
1.3.6.2  mjf 	if (!waslocked)
1.3.6.2  mjf 		mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	eccline->flags &= ~ECC_LOCKED;
1.3.6.2  mjf 	cv_broadcast(&priv->discstrat_cv);
1.3.6.2  mjf
1.3.6.2  mjf 	if (!waslocked)
1.3.6.2  mjf 		mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf /* NOTE discstrat_mutex should be held! */
1.3.6.2  mjf static void
1.3.6.2  mjf udf_dispose_eccline(struct udf_eccline *eccline)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct strat_private *priv = PRIV(eccline->ump);
1.3.6.2  mjf 	struct buf *ret;
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(mutex_owned(&priv->discstrat_mutex));
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(eccline->refcnt == 0);
1.3.6.2  mjf 	KASSERT(eccline->dirty  == 0);
1.3.6.2  mjf
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("dispose eccline with start sector %d, "
1.3.6.2  mjf 		"present %0"PRIx64"\n", eccline->start_sector,
1.3.6.2  mjf 		eccline->present));
1.3.6.2  mjf
1.3.6.2  mjf 	if (eccline->queued_on) {
1.3.6.2  mjf 		ret = BUFQ_CANCEL(priv->queues[eccline->queued_on], eccline->buf);
1.3.6.2  mjf 		KASSERT(ret == eccline->buf);
1.3.6.2  mjf 		priv->num_queued[eccline->queued_on]--;
1.3.6.2  mjf 	}
1.3.6.2  mjf 	LIST_REMOVE(eccline, hashchain);
1.3.6.2  mjf
1.3.6.2  mjf 	if (eccline->flags & ECC_FLOATING) {
1.3.6.2  mjf 		eccline->flags &= ~ECC_FLOATING;
1.3.6.2  mjf 		priv->num_floating--;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	putiobuf(eccline->buf);
1.3.6.2  mjf 	pool_put(&priv->ecclineblob_pool, eccline->blob);
1.3.6.2  mjf 	pool_put(&priv->eccline_pool, eccline);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf /* NOTE discstrat_mutex should be held! */
1.3.6.2  mjf static void
1.3.6.2  mjf udf_push_eccline(struct udf_eccline *eccline, int newqueue)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct strat_private *priv = PRIV(eccline->ump);
1.3.6.2  mjf 	struct buf *ret;
1.3.6.2  mjf 	int curqueue;
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(mutex_owned(&priv->discstrat_mutex));
1.3.6.2  mjf
1.3.6.2  mjf 	DPRINTF(PARANOIA, ("DEBUG: buf %p pushed on queue %d\n", eccline->buf, newqueue));
1.3.6.2  mjf
1.3.6.2  mjf 	/* requeue */
1.3.6.2  mjf 	curqueue = eccline->queued_on;
1.3.6.2  mjf 	if (curqueue) {
1.3.6.2  mjf 		ret = BUFQ_CANCEL(priv->queues[curqueue], eccline->buf);
1.3.6.2  mjf
1.3.6.2  mjf 		DPRINTF(PARANOIA, ("push_eccline BUFQ_CANCEL returned %p when "
1.3.6.2  mjf 			"requested to remove %p from queue %d\n", ret,
1.3.6.2  mjf 			eccline->buf, curqueue));
1.3.6.2  mjf #ifdef DIAGNOSTIC
1.3.6.2  mjf 		if (ret == NULL) {
1.3.6.2  mjf 			int i;
1.3.6.2  mjf
1.3.6.2  mjf 			printf("udf_push_eccline: bufq_cancel can't find "
1.3.6.2  mjf 				"buffer; dumping queues\n");
1.3.6.2  mjf 			for (i = 1; i < UDF_SHED_MAX; i++) {
1.3.6.2  mjf 				printf("queue %d\n\t", i);
1.3.6.2  mjf 				ret = BUFQ_GET(priv->queues[i]);
1.3.6.2  mjf 				while (ret) {
1.3.6.2  mjf 					printf("%p ", ret);
1.3.6.2  mjf 					if (ret == eccline->buf)
1.3.6.2  mjf 						printf("[<-] ");
1.3.6.2  mjf 					ret = BUFQ_GET(priv->queues[i]);
1.3.6.2  mjf 				}
1.3.6.2  mjf 				printf("\n");
1.3.6.2  mjf 			}
1.3.6.2  mjf 			panic("fatal queue bug; exit");
1.3.6.2  mjf 		}
1.3.6.2  mjf #endif
1.3.6.2  mjf
1.3.6.2  mjf 		KASSERT(ret == eccline->buf);
1.3.6.2  mjf 		priv->num_queued[curqueue]--;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	BUFQ_PUT(priv->queues[newqueue], eccline->buf);
1.3.6.2  mjf 	eccline->queued_on = newqueue;
1.3.6.2  mjf 	priv->num_queued[newqueue]++;
1.3.6.2  mjf 	vfs_timestamp(&priv->last_queued[newqueue]);
1.3.6.2  mjf
1.3.6.2  mjf 	if (eccline->flags & ECC_FLOATING) {
1.3.6.2  mjf 		eccline->flags &= ~ECC_FLOATING;
1.3.6.2  mjf 		priv->num_floating--;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	if ((newqueue != UDF_SHED_FREE) && (newqueue != UDF_SHED_IDLE))
1.3.6.2  mjf 		cv_signal(&priv->discstrat_cv);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static struct udf_eccline *
1.3.6.2  mjf udf_pop_eccline(struct strat_private *priv, int queued_on)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	struct buf *buf;
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(mutex_owned(&priv->discstrat_mutex));
1.3.6.2  mjf
1.3.6.2  mjf 	buf = BUFQ_GET(priv->queues[queued_on]);
1.3.6.2  mjf 	if (!buf) {
1.3.6.2  mjf 		KASSERT(priv->num_queued[queued_on] == 0);
1.3.6.2  mjf 		return NULL;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	eccline = BTOE(buf);
1.3.6.2  mjf 	KASSERT(eccline->queued_on == queued_on);
1.3.6.2  mjf 	eccline->queued_on = 0;
1.3.6.2  mjf 	priv->num_queued[queued_on]--;
1.3.6.2  mjf
1.3.6.2  mjf 	if (eccline->flags & ECC_FLOATING)
1.3.6.2  mjf 		panic("popping already marked floating eccline");
1.3.6.2  mjf 	eccline->flags |= ECC_FLOATING;
1.3.6.2  mjf 	priv->num_floating++;
1.3.6.2  mjf
1.3.6.2  mjf 	DPRINTF(PARANOIA, ("DEBUG: buf %p popped from queue %d\n",
1.3.6.2  mjf 		eccline->buf, queued_on));
1.3.6.2  mjf
1.3.6.2  mjf 	return eccline;
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static struct udf_eccline *
1.3.6.2  mjf udf_geteccline(struct udf_mount *ump, uint32_t sector, int flags)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct strat_private *priv = PRIV(ump);
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	uint32_t start_sector, lb_size, blobsize;
1.3.6.2  mjf 	uint8_t *eccline_blob;
1.3.6.2  mjf 	int line, line_offset;
1.3.6.2  mjf 	int num_busy, ret;
1.3.6.2  mjf
1.3.6.2  mjf 	line_offset  = sector % ump->packet_size;
1.3.6.2  mjf 	start_sector = sector - line_offset;
1.3.6.2  mjf 	line = (start_sector/ump->packet_size) & UDF_ECCBUF_HASHMASK;
1.3.6.2  mjf
1.3.6.2  mjf 	mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf retry:
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("get line sector %d, line %d\n", sector, line));
1.3.6.2  mjf 	LIST_FOREACH(eccline, &priv->eccline_hash[line], hashchain) {
1.3.6.2  mjf 		if (eccline->start_sector == start_sector) {
1.3.6.2  mjf 			DPRINTF(ECCLINE, ("\tfound eccline, start_sector %d\n",
1.3.6.2  mjf 				eccline->start_sector));
1.3.6.2  mjf
1.3.6.2  mjf 			UDF_LOCK_ECCLINE(eccline);
1.3.6.2  mjf 			/* move from freelist (!) */
1.3.6.2  mjf 			if (eccline->queued_on == UDF_SHED_FREE) {
1.3.6.2  mjf 				DPRINTF(ECCLINE, ("was on freelist\n"));
1.3.6.2  mjf 				KASSERT(eccline->refcnt == 0);
1.3.6.2  mjf 				udf_push_eccline(eccline, UDF_SHED_IDLE);
1.3.6.2  mjf 			}
1.3.6.2  mjf 			eccline->refcnt++;
1.3.6.2  mjf 			mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf 			return eccline;
1.3.6.2  mjf 		}
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("\tnot found in eccline cache\n"));
1.3.6.2  mjf 	/* not found in eccline cache */
1.3.6.2  mjf
1.3.6.2  mjf 	lb_size  = udf_rw32(ump->logical_vol->lb_size);
1.3.6.2  mjf 	blobsize = ump->packet_size * lb_size;
1.3.6.2  mjf
1.3.6.2  mjf 	/* dont allow too many pending requests */
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("\tallocating new eccline\n"));
1.3.6.2  mjf 	num_busy = (priv->num_queued[UDF_SHED_SEQWRITING] + priv->num_floating);
1.3.6.2  mjf 	if ((flags & ECC_SEQWRITING) && (num_busy > UDF_ECCLINE_MAXBUSY)) {
1.3.6.2  mjf 		ret = cv_timedwait(&priv->discstrat_cv,
1.3.6.2  mjf 			&priv->discstrat_mutex, hz/8);
1.3.6.2  mjf 		goto retry;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	eccline_blob = pool_get(&priv->ecclineblob_pool, PR_NOWAIT);
1.3.6.2  mjf 	eccline = pool_get(&priv->eccline_pool, PR_NOWAIT);
1.3.6.2  mjf 	if ((eccline_blob == NULL) || (eccline == NULL)) {
1.3.6.2  mjf 		if (eccline_blob)
1.3.6.2  mjf 			pool_put(&priv->ecclineblob_pool, eccline_blob);
1.3.6.2  mjf 		if (eccline)
1.3.6.2  mjf 			pool_put(&priv->eccline_pool, eccline);
1.3.6.2  mjf
1.3.6.2  mjf 		/* out of memory for now; canibalise freelist */
1.3.6.2  mjf 		eccline = udf_pop_eccline(priv, UDF_SHED_FREE);
1.3.6.2  mjf 		if (eccline == NULL) {
1.3.6.2  mjf 			/* serious trouble; wait and retry */
1.3.6.2  mjf 			cv_timedwait(&priv->discstrat_cv,
1.3.6.2  mjf 				&priv->discstrat_mutex, hz/8);
1.3.6.2  mjf 			goto retry;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		/* push back line if we're waiting for it */
1.3.6.2  mjf 		if (eccline->flags & ECC_WANTED) {
1.3.6.2  mjf 			udf_push_eccline(eccline, UDF_SHED_IDLE);
1.3.6.2  mjf 			goto retry;
1.3.6.2  mjf 		}
1.3.6.2  mjf
1.3.6.2  mjf 		/* unlink this entry */
1.3.6.2  mjf 		LIST_REMOVE(eccline, hashchain);
1.3.6.2  mjf
1.3.6.2  mjf 		KASSERT(eccline->flags & ECC_FLOATING);
1.3.6.2  mjf
1.3.6.2  mjf 		eccline_blob = eccline->blob;
1.3.6.2  mjf 		memset(eccline, 0, sizeof(struct udf_eccline));
1.3.6.2  mjf 		eccline->flags = ECC_FLOATING;
1.3.6.2  mjf 	} else {
1.3.6.2  mjf 		memset(eccline, 0, sizeof(struct udf_eccline));
1.3.6.2  mjf 		eccline->flags = ECC_FLOATING;
1.3.6.2  mjf 		priv->num_floating++;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	eccline->queued_on = 0;
1.3.6.2  mjf 	eccline->blob = eccline_blob;
1.3.6.2  mjf 	eccline->buf  = getiobuf(NULL, true);
1.3.6.2  mjf 	eccline->buf->b_private = eccline;	/* IMPORTANT */
1.3.6.2  mjf
1.3.6.2  mjf 	/* initialise eccline blob */
1.3.6.2  mjf 	memset(eccline->blob, 0, blobsize);
1.3.6.2  mjf
1.3.6.2  mjf 	eccline->ump = ump;
1.3.6.2  mjf 	eccline->present = eccline->readin = eccline->dirty = 0;
1.3.6.2  mjf 	eccline->error = 0;
1.3.6.2  mjf 	eccline->refcnt = 0;
1.3.6.2  mjf 	eccline->start_sector = start_sector;
1.3.6.2  mjf
1.3.6.2  mjf 	LIST_INSERT_HEAD(&priv->eccline_hash[line], eccline, hashchain);
1.3.6.2  mjf
1.3.6.2  mjf 	/*
1.3.6.2  mjf 	 * TODO possible optimalisation for checking overlap with partitions
1.3.6.2  mjf 	 * to get a clue on future eccline usage
1.3.6.2  mjf 	 */
1.3.6.2  mjf 	eccline->refcnt++;
1.3.6.2  mjf 	UDF_LOCK_ECCLINE(eccline);
1.3.6.2  mjf
1.3.6.2  mjf 	mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	return eccline;
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_puteccline(struct udf_eccline *eccline)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct strat_private *priv = PRIV(eccline->ump);
1.3.6.2  mjf 	struct udf_eccline *deccline;
1.3.6.2  mjf 	struct udf_mount *ump = eccline->ump;
1.3.6.2  mjf 	uint64_t allbits = ((uint64_t) 1 << ump->packet_size)-1;
1.3.6.2  mjf 	int newqueue, tries;
1.3.6.2  mjf
1.3.6.2  mjf 	mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	/* clear directly all readin requests from present ones */
1.3.6.2  mjf 	if (eccline->readin & eccline->present) {
1.3.6.2  mjf 		/* clear all read bits that are already read in */
1.3.6.2  mjf 		eccline->readin &= (~eccline->present) & allbits;
1.3.6.2  mjf 		wakeup(eccline);
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("put eccline start sector %d, refcnt %d\n",
1.3.6.2  mjf 		eccline->start_sector, eccline->refcnt));
1.3.6.2  mjf
1.3.6.2  mjf 	/* requeue */
1.3.6.2  mjf 	newqueue = UDF_SHED_FREE;
1.3.6.2  mjf 	if (eccline->refcnt > 1)
1.3.6.2  mjf 		newqueue = UDF_SHED_IDLE;
1.3.6.2  mjf 	if (eccline->flags & ECC_WANTED)
1.3.6.2  mjf 		newqueue = UDF_SHED_IDLE;
1.3.6.2  mjf 	if (eccline->dirty) {
1.3.6.2  mjf 		newqueue = UDF_SHED_WRITING;
1.3.6.2  mjf 		if (eccline->flags & ECC_SEQWRITING)
1.3.6.2  mjf 			newqueue = UDF_SHED_SEQWRITING;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	/* if we have active nodes */
1.3.6.2  mjf 	if (eccline->refcnt > 1) {
1.3.6.2  mjf 		/* we dont set it on seqwriting */
1.3.6.2  mjf 		eccline->flags &= ~ECC_SEQWRITING;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	/* if we need reading in or not all is yet present, queue reading */
1.3.6.2  mjf 	if ((eccline->readin) || (eccline->present != allbits))
1.3.6.2  mjf 		newqueue = UDF_SHED_READING;
1.3.6.2  mjf
1.3.6.2  mjf 	/* reduce the number of kept free buffers */
1.3.6.2  mjf 	tries = priv->num_queued[UDF_SHED_FREE] - UDF_ECCLINE_MAXFREE;
1.3.6.2  mjf 	while (tries > 0 /* priv->num_queued[UDF_SHED_FREE] > UDF_ECCLINE_MAXFREE */) {
1.3.6.2  mjf 		deccline = udf_pop_eccline(priv, UDF_SHED_FREE);
1.3.6.2  mjf 		KASSERT(deccline);
1.3.6.2  mjf 		KASSERT(deccline->refcnt == 0);
1.3.6.2  mjf 		if (deccline->flags & ECC_WANTED) {
1.3.6.2  mjf 			udf_push_eccline(deccline, UDF_SHED_IDLE);
1.3.6.2  mjf 			DPRINTF(ECCLINE, ("Tried removing, pushed back to free list\n"));
1.3.6.2  mjf 		} else {
1.3.6.2  mjf 			DPRINTF(ECCLINE, ("Removing entry from free list\n"));
1.3.6.2  mjf 			udf_dispose_eccline(deccline);
1.3.6.2  mjf 		}
1.3.6.2  mjf 		tries--;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	udf_push_eccline(eccline, newqueue);
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(eccline->refcnt >= 1);
1.3.6.2  mjf 	eccline->refcnt--;
1.3.6.2  mjf 	UDF_UNLOCK_ECCLINE(eccline);
1.3.6.2  mjf
1.3.6.2  mjf 	mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf /* --------------------------------------------------------------------- */
1.3.6.2  mjf
1.3.6.2  mjf static int
1.3.6.2  mjf udf_create_logvol_dscr_rmw(struct udf_strat_args *args)
1.3.6.2  mjf {
1.3.6.2  mjf 	union dscrptr   **dscrptr  = &args->dscr;
1.3.6.2  mjf 	struct udf_mount *ump      = args->ump;
1.3.6.2  mjf 	struct long_ad   *icb      = args->icb;
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	uint64_t bit;
1.3.6.2  mjf 	uint32_t sectornr, lb_size, dummy;
1.3.6.2  mjf 	uint8_t *mem;
1.3.6.2  mjf 	int error, eccsect;
1.3.6.2  mjf
1.3.6.2  mjf 	error = udf_translate_vtop(ump, icb, &sectornr, &dummy);
1.3.6.2  mjf 	if (error)
1.3.6.2  mjf 		return error;
1.3.6.2  mjf
1.3.6.2  mjf 	lb_size  = udf_rw32(ump->logical_vol->lb_size);
1.3.6.2  mjf
1.3.6.2  mjf 	/* get our eccline */
1.3.6.2  mjf 	eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 	eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf
1.3.6.2  mjf 	bit = (uint64_t) 1 << eccsect;
1.3.6.2  mjf 	eccline->readin  &= ~bit;	/* just in case */
1.3.6.2  mjf 	eccline->present |=  bit;
1.3.6.2  mjf 	eccline->dirty   &= ~bit;	/* Err... euhm... clean? */
1.3.6.2  mjf
1.3.6.2  mjf 	eccline->refcnt++;
1.3.6.2  mjf
1.3.6.2  mjf 	/* clear space */
1.3.6.2  mjf 	mem = ((uint8_t *) eccline->blob) + eccsect * lb_size;
1.3.6.2  mjf 	memset(mem, 0, lb_size);
1.3.6.2  mjf
1.3.6.2  mjf 	udf_puteccline(eccline);
1.3.6.2  mjf
1.3.6.2  mjf 	*dscrptr = (union dscrptr *) mem;
1.3.6.2  mjf 	return 0;
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_free_logvol_dscr_rmw(struct udf_strat_args *args)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_mount *ump  = args->ump;
1.3.6.2  mjf 	struct long_ad   *icb  = args->icb;
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	uint64_t bit;
1.3.6.2  mjf 	uint32_t sectornr, dummy;
1.3.6.2  mjf 	int error, eccsect;
1.3.6.2  mjf
1.3.6.2  mjf 	error = udf_translate_vtop(ump, icb, &sectornr, &dummy);
1.3.6.2  mjf 	if (error)
1.3.6.2  mjf 		return;
1.3.6.2  mjf
1.3.6.2  mjf 	/* get our eccline */
1.3.6.2  mjf 	eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 	eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf
1.3.6.2  mjf 	bit = (uint64_t) 1 << eccsect;
1.3.6.2  mjf 	eccline->readin &= ~bit;	/* just in case */
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(eccline->refcnt >= 1);
1.3.6.2  mjf 	eccline->refcnt--;
1.3.6.2  mjf
1.3.6.2  mjf 	udf_puteccline(eccline);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static int
1.3.6.2  mjf udf_read_logvol_dscr_rmw(struct udf_strat_args *args)
1.3.6.2  mjf {
1.3.6.2  mjf 	union dscrptr   **dscrptr = &args->dscr;
1.3.6.2  mjf 	struct udf_mount *ump = args->ump;
1.3.6.2  mjf 	struct long_ad   *icb = args->icb;
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	uint64_t bit;
1.3.6.2  mjf 	uint32_t sectornr, dummy;
1.3.6.2  mjf 	uint8_t *pos;
1.3.6.2  mjf 	int sector_size = ump->discinfo.sector_size;
1.3.6.2  mjf 	int lb_size = udf_rw32(ump->logical_vol->lb_size);
1.3.6.2  mjf 	int i, error, dscrlen, eccsect;
1.3.6.2  mjf
1.3.6.2  mjf 	lb_size = lb_size;
1.3.6.2  mjf 	KASSERT(sector_size == lb_size);
1.3.6.2  mjf 	error = udf_translate_vtop(ump, icb, &sectornr, &dummy);
1.3.6.2  mjf 	if (error)
1.3.6.2  mjf 		return error;
1.3.6.2  mjf
1.3.6.2  mjf 	/* get our eccline */
1.3.6.2  mjf 	eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 	eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf
1.3.6.2  mjf 	bit = (uint64_t) 1 << eccsect;
1.3.6.2  mjf 	if ((eccline->present & bit) == 0) {
1.3.6.2  mjf 		/* mark bit for readin */
1.3.6.2  mjf 		eccline->readin |= bit;
1.3.6.2  mjf 		eccline->refcnt++;	/* prevent recycling */
1.3.6.2  mjf 		KASSERT(eccline->bufs[eccsect] == NULL);
1.3.6.2  mjf 		udf_puteccline(eccline);
1.3.6.2  mjf
1.3.6.2  mjf 		/* wait for completion; XXX remodel to lock bit code */
1.3.6.2  mjf 		error = 0;
1.3.6.2  mjf 		while ((eccline->present & bit) == 0) {
1.3.6.2  mjf 			tsleep(eccline, PRIBIO+1, "udflvdrd", hz/8);
1.3.6.2  mjf 			if (eccline->error & bit) {
1.3.6.2  mjf 				KASSERT(eccline->refcnt >= 1);
1.3.6.2  mjf 				eccline->refcnt--;	/* undo temp refcnt */
1.3.6.2  mjf 				*dscrptr = NULL;
1.3.6.2  mjf 				return EIO;		/* XXX error code */
1.3.6.2  mjf 			}
1.3.6.2  mjf 		}
1.3.6.2  mjf
1.3.6.2  mjf 		/* reget our line */
1.3.6.2  mjf 		eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 		KASSERT(eccline->refcnt >= 1);
1.3.6.2  mjf 		eccline->refcnt--;	/* undo refcnt */
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	*dscrptr = (union dscrptr *)
1.3.6.2  mjf 		(((uint8_t *) eccline->blob) + eccsect * sector_size);
1.3.6.2  mjf
1.3.6.2  mjf 	/* code from read_phys_descr */
1.3.6.2  mjf 	/* check if its a valid tag */
1.3.6.2  mjf 	error = udf_check_tag(*dscrptr);
1.3.6.2  mjf 	if (error) {
1.3.6.2  mjf 		/* check if its an empty block */
1.3.6.2  mjf 		pos = (uint8_t *) *dscrptr;
1.3.6.2  mjf 		for (i = 0; i < sector_size; i++, pos++) {
1.3.6.2  mjf 			if (*pos) break;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		if (i == sector_size) {
1.3.6.2  mjf 			/* return no error but with no dscrptr */
1.3.6.2  mjf 			error = 0;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		*dscrptr = NULL;
1.3.6.2  mjf 		udf_puteccline(eccline);
1.3.6.2  mjf 		return error;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	/* calculate descriptor size */
1.3.6.2  mjf 	dscrlen = udf_tagsize(*dscrptr, sector_size);
1.3.6.2  mjf 	error = udf_check_tag_payload(*dscrptr, dscrlen);
1.3.6.2  mjf 	if (error) {
1.3.6.2  mjf 		*dscrptr = NULL;
1.3.6.2  mjf 		udf_puteccline(eccline);
1.3.6.2  mjf 		return error;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	eccline->refcnt++;
1.3.6.2  mjf 	udf_puteccline(eccline);
1.3.6.2  mjf
1.3.6.2  mjf 	return 0;
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static int
1.3.6.2  mjf udf_write_logvol_dscr_rmw(struct udf_strat_args *args)
1.3.6.2  mjf {
1.3.6.2  mjf 	union dscrptr    *dscrptr = args->dscr;
1.3.6.2  mjf 	struct udf_mount *ump = args->ump;
1.3.6.2  mjf 	struct long_ad   *icb = args->icb;
1.3.6.2  mjf 	struct udf_node *udf_node = args->udf_node;
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	uint64_t bit;
1.3.6.2  mjf 	uint32_t sectornr, logsectornr, dummy;
1.3.6.2  mjf 	// int waitfor  = args->waitfor;
1.3.6.2  mjf 	int sector_size = ump->discinfo.sector_size;
1.3.6.2  mjf 	int lb_size = udf_rw32(ump->logical_vol->lb_size);
1.3.6.2  mjf 	int error, eccsect;
1.3.6.2  mjf
1.3.6.2  mjf 	lb_size = lb_size;
1.3.6.2  mjf 	KASSERT(sector_size == lb_size);
1.3.6.2  mjf 	sectornr    = 0;
1.3.6.2  mjf 	error = udf_translate_vtop(ump, icb, &sectornr, &dummy);
1.3.6.2  mjf 	if (error)
1.3.6.2  mjf 		return error;
1.3.6.2  mjf
1.3.6.2  mjf 	/* get our eccline */
1.3.6.2  mjf 	eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 	eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf
1.3.6.2  mjf 	bit = (uint64_t) 1 << eccsect;
1.3.6.2  mjf
1.3.6.2  mjf 	/* old callback still pending? */
1.3.6.2  mjf 	if (eccline->bufs[eccsect]) {
1.3.6.2  mjf 		DPRINTF(WRITE, ("udf_write_logvol_dscr_rmw: writing descriptor"
1.3.6.2  mjf 					" over buffer?\n"));
1.3.6.2  mjf 		nestiobuf_done(eccline->bufs[eccsect],
1.3.6.2  mjf 				eccline->bufs_len[eccsect],
1.3.6.2  mjf 				0);
1.3.6.2  mjf 		eccline->bufs[eccsect] = NULL;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	UDF_LOCK_NODE(udf_node, IN_CALLBACK_ULK);
1.3.6.2  mjf
1.3.6.2  mjf 	/* set sector number in the descriptor and validate */
1.3.6.2  mjf 	dscrptr = (union dscrptr *)
1.3.6.2  mjf 		(((uint8_t *) eccline->blob) + eccsect * sector_size);
1.3.6.2  mjf 	KASSERT(dscrptr == args->dscr);
1.3.6.2  mjf
1.3.6.2  mjf 	logsectornr = udf_rw32(icb->loc.lb_num);
1.3.6.2  mjf 	dscrptr->tag.tag_loc = udf_rw32(logsectornr);
1.3.6.2  mjf 	udf_validate_tag_and_crc_sums(dscrptr);
1.3.6.2  mjf
1.3.6.2  mjf 	udf_fixup_node_internals(ump, (uint8_t *) dscrptr, UDF_C_NODE);
1.3.6.2  mjf
1.3.6.2  mjf 	/* set our flags */
1.3.6.2  mjf 	KASSERT(eccline->present & bit);
1.3.6.2  mjf 	eccline->dirty |= bit;
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(udf_tagsize(dscrptr, sector_size) <= sector_size);
1.3.6.2  mjf 	UDF_UNLOCK_NODE(udf_node, IN_CALLBACK_ULK);
1.3.6.2  mjf
1.3.6.2  mjf 	udf_puteccline(eccline);
1.3.6.2  mjf
1.3.6.2  mjf 	/* XXX waitfor not used */
1.3.6.2  mjf 	return 0;
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_queuebuf_rmw(struct udf_strat_args *args)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_mount *ump = args->ump;
1.3.6.2  mjf 	struct buf *buf = args->nestbuf;
1.3.6.2  mjf 	struct strat_private *priv = PRIV(ump);
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	struct long_ad *node_ad_cpy;
1.3.6.2  mjf 	uint64_t bit, *lmapping, *pmapping, *lmappos, *pmappos, blknr;
1.3.6.2  mjf 	uint32_t buf_len, len, sectornr, our_sectornr;
1.3.6.2  mjf 	uint32_t bpos;
1.3.6.2  mjf 	uint8_t *fidblk, *src, *dst;
1.3.6.2  mjf 	int sector_size = ump->discinfo.sector_size;
1.3.6.2  mjf 	int blks = sector_size / DEV_BSIZE;
1.3.6.2  mjf 	int eccsect, what, queue, error;
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(ump);
1.3.6.2  mjf 	KASSERT(buf);
1.3.6.2  mjf 	KASSERT(buf->b_iodone == nestiobuf_iodone);
1.3.6.2  mjf
1.3.6.2  mjf 	blknr        = buf->b_blkno;
1.3.6.2  mjf 	our_sectornr = blknr / blks;
1.3.6.2  mjf
1.3.6.2  mjf 	what = buf->b_udf_c_type;
1.3.6.2  mjf 	queue = UDF_SHED_READING;
1.3.6.2  mjf 	if ((buf->b_flags & B_READ) == 0) {
1.3.6.2  mjf 		/* writing */
1.3.6.2  mjf 		queue = UDF_SHED_SEQWRITING;
1.3.6.2  mjf 		if (what == UDF_C_DSCR)
1.3.6.2  mjf 			queue = UDF_SHED_WRITING;
1.3.6.2  mjf 		if (what == UDF_C_NODE)
1.3.6.2  mjf 			queue = UDF_SHED_WRITING;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	if (queue == UDF_SHED_READING) {
1.3.6.2  mjf 		DPRINTF(SHEDULE, ("\nudf_queuebuf_rmw READ %p : sector %d type %d,"
1.3.6.2  mjf 			"b_resid %d, b_bcount %d, b_bufsize %d\n",
1.3.6.2  mjf 			buf, (uint32_t) buf->b_blkno / blks, buf->b_udf_c_type,
1.3.6.2  mjf 			buf->b_resid, buf->b_bcount, buf->b_bufsize));
1.3.6.2  mjf
1.3.6.2  mjf 		/* mark bits for reading */
1.3.6.2  mjf 		buf_len = buf->b_bcount;
1.3.6.2  mjf 		sectornr = our_sectornr;
1.3.6.2  mjf 		eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 		eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf 		bpos = 0;
1.3.6.2  mjf 		while (buf_len) {
1.3.6.2  mjf 			len = MIN(buf_len, sector_size);
1.3.6.2  mjf 			if (eccsect == ump->packet_size) {
1.3.6.2  mjf 				udf_puteccline(eccline);
1.3.6.2  mjf 				eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 				eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf 			}
1.3.6.2  mjf 			bit = (uint64_t) 1 << eccsect;
1.3.6.2  mjf 			error = eccline->error & bit ? EIO : 0;
1.3.6.2  mjf 			if (eccline->present & bit) {
1.3.6.2  mjf 				src = (uint8_t *) eccline->blob +
1.3.6.2  mjf 					eccsect * sector_size;
1.3.6.2  mjf 				dst = (uint8_t *) buf->b_data + bpos;
1.3.6.2  mjf 				if (!error)
1.3.6.2  mjf 					memcpy(dst, src, len);
1.3.6.2  mjf 				nestiobuf_done(buf, len, error);
1.3.6.2  mjf 			} else {
1.3.6.2  mjf 				eccline->readin |= bit;
1.3.6.2  mjf 				KASSERT(eccline->bufs[eccsect] == NULL);
1.3.6.2  mjf 				eccline->bufs[eccsect] = buf;
1.3.6.2  mjf 				eccline->bufs_bpos[eccsect] = bpos;
1.3.6.2  mjf 				eccline->bufs_len[eccsect] = len;
1.3.6.2  mjf 			}
1.3.6.2  mjf 			bpos += sector_size;
1.3.6.2  mjf 			eccsect++;
1.3.6.2  mjf 			sectornr++;
1.3.6.2  mjf 			buf_len -= len;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		udf_puteccline(eccline);
1.3.6.2  mjf 		return;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	if (queue == UDF_SHED_WRITING) {
1.3.6.2  mjf 		DPRINTF(SHEDULE, ("\nudf_queuebuf_rmw WRITE %p : sector %d "
1.3.6.2  mjf 			"type %d, b_resid %d, b_bcount %d, b_bufsize %d\n",
1.3.6.2  mjf 			buf, (uint32_t) buf->b_blkno / blks, buf->b_udf_c_type,
1.3.6.2  mjf 			buf->b_resid, buf->b_bcount, buf->b_bufsize));
1.3.6.2  mjf 		/* if we have FIDs fixup using buffer's sector number(s) */
1.3.6.2  mjf 		if (buf->b_udf_c_type == UDF_C_FIDS) {
1.3.6.2  mjf 			panic("UDF_C_FIDS in SHED_WRITING!\n");
1.3.6.2  mjf #if 0
1.3.6.2  mjf 			buf_len = buf->b_bcount;
1.3.6.2  mjf 			sectornr = our_sectornr;
1.3.6.2  mjf 			bpos = 0;
1.3.6.2  mjf 			while (buf_len) {
1.3.6.2  mjf 				len = MIN(buf_len, sector_size);
1.3.6.2  mjf 				fidblk = (uint8_t *) buf->b_data + bpos;
1.3.6.2  mjf 				udf_fixup_fid_block(fidblk, sector_size,
1.3.6.2  mjf 					0, len, sectornr);
1.3.6.2  mjf 				sectornr++;
1.3.6.2  mjf 				bpos += len;
1.3.6.2  mjf 				buf_len -= len;
1.3.6.2  mjf 			}
1.3.6.2  mjf #endif
1.3.6.2  mjf 		}
1.3.6.2  mjf 		udf_fixup_node_internals(ump, buf->b_data, buf->b_udf_c_type);
1.3.6.2  mjf
1.3.6.2  mjf 		/* copy parts into the bufs and set for writing */
1.3.6.2  mjf 		buf_len = buf->b_bcount;
1.3.6.2  mjf 		sectornr = our_sectornr;
1.3.6.2  mjf 		eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 		eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf 		bpos = 0;
1.3.6.2  mjf 		while (buf_len) {
1.3.6.2  mjf 			len = MIN(buf_len, sector_size);
1.3.6.2  mjf 			if (eccsect == ump->packet_size) {
1.3.6.2  mjf 				udf_puteccline(eccline);
1.3.6.2  mjf 				eccline = udf_geteccline(ump, sectornr, 0);
1.3.6.2  mjf 				eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf 			}
1.3.6.2  mjf 			bit = (uint64_t) 1 << eccsect;
1.3.6.2  mjf 			KASSERT((eccline->readin & bit) == 0);
1.3.6.2  mjf 			eccline->present |= bit;
1.3.6.2  mjf 			eccline->dirty   |= bit;
1.3.6.2  mjf 			if (eccline->bufs[eccsect]) {
1.3.6.2  mjf 				/* old callback still pending */
1.3.6.2  mjf 				nestiobuf_done(eccline->bufs[eccsect],
1.3.6.2  mjf 						eccline->bufs_len[eccsect],
1.3.6.2  mjf 						0);
1.3.6.2  mjf 				eccline->bufs[eccsect] = NULL;
1.3.6.2  mjf 			}
1.3.6.2  mjf
1.3.6.2  mjf 			src = (uint8_t *) buf->b_data + bpos;
1.3.6.2  mjf 			dst = (uint8_t *) eccline->blob + eccsect * sector_size;
1.3.6.2  mjf 			if (len != sector_size)
1.3.6.2  mjf 				memset(dst, 0, sector_size);
1.3.6.2  mjf 			memcpy(dst, src, len);
1.3.6.2  mjf
1.3.6.2  mjf 			/* note that its finished for this extent */
1.3.6.2  mjf 			eccline->bufs[eccsect] = NULL;
1.3.6.2  mjf 			nestiobuf_done(buf, len, 0);
1.3.6.2  mjf
1.3.6.2  mjf 			bpos += sector_size;
1.3.6.2  mjf 			eccsect++;
1.3.6.2  mjf 			sectornr++;
1.3.6.2  mjf 			buf_len -= len;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		udf_puteccline(eccline);
1.3.6.2  mjf 		return;
1.3.6.2  mjf
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	/* sequential writing */
1.3.6.2  mjf 	KASSERT(queue == UDF_SHED_SEQWRITING);
1.3.6.2  mjf 	DPRINTF(SHEDULE, ("\nudf_queuebuf_rmw SEQWRITE %p : sector XXXX "
1.3.6.2  mjf 		"type %d, b_resid %d, b_bcount %d, b_bufsize %d\n",
1.3.6.2  mjf 		buf, buf->b_udf_c_type, buf->b_resid, buf->b_bcount,
1.3.6.2  mjf 		buf->b_bufsize));
1.3.6.2  mjf 	/*
1.3.6.2  mjf 	 * Buffers should not have been allocated to disc addresses yet on
1.3.6.2  mjf 	 * this queue. Note that a buffer can get multiple extents allocated.
1.3.6.2  mjf 	 * Note that it *looks* like the normal writing but its different in
1.3.6.2  mjf 	 * the details.
1.3.6.2  mjf 	 *
1.3.6.2  mjf 	 * lmapping contains lb_num relative to base partition.  pmapping
1.3.6.2  mjf 	 * contains lb_num as used for disc adressing.
1.3.6.2  mjf 	 */
1.3.6.2  mjf 	mutex_enter(&priv->seqwrite_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	lmapping    = ump->la_lmapping;
1.3.6.2  mjf 	pmapping    = ump->la_pmapping;
1.3.6.2  mjf 	node_ad_cpy = ump->la_node_ad_cpy;
1.3.6.2  mjf
1.3.6.2  mjf 	/*
1.3.6.2  mjf 	 * XXX should we try to claim/organize the allocated memory to block
1.3.6.2  mjf 	 * aligned pieces?
1.3.6.2  mjf 	 */
1.3.6.2  mjf 	/* allocate buf and get its logical and physical mappings */
1.3.6.2  mjf 	udf_late_allocate_buf(ump, buf, lmapping, pmapping, node_ad_cpy);
1.3.6.2  mjf
1.3.6.2  mjf 	/* if we have FIDs, fixup using the new allocation table */
1.3.6.2  mjf 	if (buf->b_udf_c_type == UDF_C_FIDS) {
1.3.6.2  mjf 		buf_len = buf->b_bcount;
1.3.6.2  mjf 		bpos = 0;
1.3.6.2  mjf 		lmappos = lmapping;
1.3.6.2  mjf 		while (buf_len) {
1.3.6.2  mjf 			sectornr = *lmappos++;
1.3.6.2  mjf 			len = MIN(buf_len, sector_size);
1.3.6.2  mjf 			fidblk = (uint8_t *) buf->b_data + bpos;
1.3.6.2  mjf 			udf_fixup_fid_block(fidblk, sector_size,
1.3.6.2  mjf 				0, len, sectornr);
1.3.6.2  mjf 			bpos += len;
1.3.6.2  mjf 			buf_len -= len;
1.3.6.2  mjf 		}
1.3.6.2  mjf 	}
1.3.6.2  mjf 	udf_fixup_node_internals(ump, buf->b_data, buf->b_udf_c_type);
1.3.6.2  mjf
1.3.6.2  mjf 	/* copy parts into the bufs and set for writing */
1.3.6.2  mjf 	pmappos = pmapping;
1.3.6.2  mjf 	buf_len = buf->b_bcount;
1.3.6.2  mjf 	sectornr = *pmappos++;
1.3.6.2  mjf 	eccline = udf_geteccline(ump, sectornr, ECC_SEQWRITING);
1.3.6.2  mjf 	eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf 	bpos = 0;
1.3.6.2  mjf 	while (buf_len) {
1.3.6.2  mjf 		len = MIN(buf_len, sector_size);
1.3.6.2  mjf 		eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf 		if ((eccsect < 0) || (eccsect >= ump->packet_size)) {
1.3.6.2  mjf 			eccline->flags |= ECC_SEQWRITING;
1.3.6.2  mjf 			udf_puteccline(eccline);
1.3.6.2  mjf 			eccline = udf_geteccline(ump, sectornr, ECC_SEQWRITING);
1.3.6.2  mjf 			eccsect = sectornr - eccline->start_sector;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		bit = (uint64_t) 1 << eccsect;
1.3.6.2  mjf 		KASSERT((eccline->readin & bit) == 0);
1.3.6.2  mjf 		eccline->present |= bit;
1.3.6.2  mjf 		eccline->dirty   |= bit;
1.3.6.2  mjf 		eccline->bufs[eccsect] = NULL;
1.3.6.2  mjf
1.3.6.2  mjf 		src = (uint8_t *) buf->b_data + bpos;
1.3.6.2  mjf 		dst = (uint8_t *)
1.3.6.2  mjf 			eccline->blob + eccsect * sector_size;
1.3.6.2  mjf 		if (len != sector_size)
1.3.6.2  mjf 			memset(dst, 0, sector_size);
1.3.6.2  mjf 		memcpy(dst, src, len);
1.3.6.2  mjf
1.3.6.2  mjf 		/* note that its finished for this extent */
1.3.6.2  mjf 		nestiobuf_done(buf, len, 0);
1.3.6.2  mjf
1.3.6.2  mjf 		bpos += sector_size;
1.3.6.2  mjf 		sectornr = *pmappos++;
1.3.6.2  mjf 		buf_len -= len;
1.3.6.2  mjf 	}
1.3.6.2  mjf 	eccline->flags |= ECC_SEQWRITING;
1.3.6.2  mjf 	udf_puteccline(eccline);
1.3.6.2  mjf 	mutex_exit(&priv->seqwrite_mutex);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf /* --------------------------------------------------------------------- */
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_shedule_read_callback(struct buf *buf)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_eccline *eccline = BTOE(buf);
1.3.6.2  mjf 	struct udf_mount *ump = eccline->ump;
1.3.6.2  mjf 	uint64_t bit;
1.3.6.2  mjf 	uint8_t *src, *dst;
1.3.6.2  mjf 	int sector_size = ump->discinfo.sector_size;
1.3.6.2  mjf 	int error, i, len;
1.3.6.2  mjf
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("read callback called\n"));
1.3.6.2  mjf 	/* post process read action */
1.3.6.2  mjf 	error = buf->b_error;
1.3.6.2  mjf 	for (i = 0; i < ump->packet_size; i++) {
1.3.6.2  mjf 		bit = (uint64_t) 1 << i;
1.3.6.2  mjf 		src = (uint8_t *) buf->b_data +   i * sector_size;
1.3.6.2  mjf 		dst = (uint8_t *) eccline->blob + i * sector_size;
1.3.6.2  mjf 		if (eccline->present & bit)
1.3.6.2  mjf 			continue;
1.3.6.2  mjf 		if (error) {
1.3.6.2  mjf 			eccline->error |= bit;
1.3.6.2  mjf 		} else {
1.3.6.2  mjf 			eccline->present |= bit;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		if (eccline->bufs[i]) {
1.3.6.2  mjf 			dst = (uint8_t *) eccline->bufs[i]->b_data +
1.3.6.2  mjf 				eccline->bufs_bpos[i];
1.3.6.2  mjf 			len = eccline->bufs_len[i];
1.3.6.2  mjf 			if (!error)
1.3.6.2  mjf 				memcpy(dst, src, len);
1.3.6.2  mjf 			nestiobuf_done(eccline->bufs[i], len, error);
1.3.6.2  mjf 			eccline->bufs[i] = NULL;
1.3.6.2  mjf 		}
1.3.6.2  mjf
1.3.6.2  mjf 	}
1.3.6.2  mjf 	KASSERT(buf->b_data == eccline->blob);
1.3.6.2  mjf 	KASSERT(eccline->present == ((uint64_t) 1 << ump->packet_size)-1);
1.3.6.2  mjf
1.3.6.2  mjf 	/*
1.3.6.2  mjf 	 * XXX TODO what to do on read errors? read in all sectors
1.3.6.2  mjf 	 * synchronously and allocate a sparable entry?
1.3.6.2  mjf 	 */
1.3.6.2  mjf
1.3.6.2  mjf 	wakeup(eccline);
1.3.6.2  mjf 	udf_puteccline(eccline);
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("read callback finished\n"));
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_shedule_write_callback(struct buf *buf)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_eccline *eccline = BTOE(buf);
1.3.6.2  mjf 	struct udf_mount *ump = eccline->ump;
1.3.6.2  mjf 	uint64_t bit;
1.3.6.2  mjf 	int error, i, len;
1.3.6.2  mjf
1.3.6.2  mjf 	DPRINTF(ECCLINE, ("write callback called\n"));
1.3.6.2  mjf 	/* post process write action */
1.3.6.2  mjf 	error = buf->b_error;
1.3.6.2  mjf 	for (i = 0; i < ump->packet_size; i++) {
1.3.6.2  mjf 		bit = (uint64_t) 1 << i;
1.3.6.2  mjf 		if ((eccline->dirty & bit) == 0)
1.3.6.2  mjf 			continue;
1.3.6.2  mjf 		if (error) {
1.3.6.2  mjf 			eccline->error |= bit;
1.3.6.2  mjf 		} else {
1.3.6.2  mjf 			eccline->dirty &= ~bit;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		if (eccline->bufs[i]) {
1.3.6.2  mjf 			len = eccline->bufs_len[i];
1.3.6.2  mjf 			nestiobuf_done(eccline->bufs[i], len, error);
1.3.6.2  mjf 			eccline->bufs[i] = NULL;
1.3.6.2  mjf 		}
1.3.6.2  mjf 	}
1.3.6.2  mjf 	KASSERT(eccline->dirty == 0);
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(error == 0);
1.3.6.2  mjf 	/*
1.3.6.2  mjf 	 * XXX TODO on write errors allocate a sparable entry
1.3.6.2  mjf 	 */
1.3.6.2  mjf
1.3.6.2  mjf 	wakeup(eccline);
1.3.6.2  mjf 	udf_puteccline(eccline);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_issue_eccline(struct udf_eccline *eccline, int queued_on)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_mount *ump = eccline->ump;
1.3.6.2  mjf 	struct strat_private *priv = PRIV(ump);
1.3.6.2  mjf 	struct buf *buf, *nestbuf;
1.3.6.2  mjf 	uint64_t bit, allbits = ((uint64_t) 1 << ump->packet_size)-1;
1.3.6.2  mjf 	uint32_t start;
1.3.6.2  mjf 	int sector_size = ump->discinfo.sector_size;
1.3.6.2  mjf 	int blks = sector_size / DEV_BSIZE;
1.3.6.2  mjf 	int i;
1.3.6.2  mjf
1.3.6.2  mjf 	if (queued_on == UDF_SHED_READING) {
1.3.6.2  mjf 		DPRINTF(SHEDULE, ("udf_issue_eccline reading : "));
1.3.6.2  mjf 		/* read all bits that are not yet present */
1.3.6.2  mjf 		eccline->readin = (~eccline->present) & allbits;
1.3.6.2  mjf 		KASSERT(eccline->readin);
1.3.6.2  mjf 		start = eccline->start_sector;
1.3.6.2  mjf 		buf = eccline->buf;
1.3.6.2  mjf 		buf_init(buf);
1.3.6.2  mjf 		buf->b_flags    = B_READ | B_ASYNC;
1.3.6.2  mjf 		buf->b_cflags   = BC_BUSY;	/* needed? */
1.3.6.2  mjf 		buf->b_oflags   = 0;
1.3.6.2  mjf 		buf->b_iodone   = udf_shedule_read_callback;
1.3.6.2  mjf 		buf->b_data     = eccline->blob;
1.3.6.2  mjf 		buf->b_bcount   = ump->packet_size * sector_size;
1.3.6.2  mjf 		buf->b_resid    = buf->b_bcount;
1.3.6.2  mjf 		buf->b_bufsize  = buf->b_bcount;
1.3.6.2  mjf 		buf->b_private  = eccline;
1.3.6.2  mjf 		BIO_SETPRIO(buf, BPRIO_DEFAULT);
1.3.6.2  mjf 		buf->b_lblkno   = buf->b_blkno = buf->b_rawblkno = start * blks;
1.3.6.2  mjf 		buf->b_proc     = NULL;
1.3.6.2  mjf
1.3.6.2  mjf 		if (eccline->present != 0) {
1.3.6.2  mjf 			for (i = 0; i < ump->packet_size; i++) {
1.3.6.2  mjf 				bit = (uint64_t) 1 << i;
1.3.6.2  mjf 				if (eccline->present & bit) {
1.3.6.2  mjf 					nestiobuf_done(buf, sector_size, 0);
1.3.6.2  mjf 					continue;
1.3.6.2  mjf 				}
1.3.6.2  mjf 				nestbuf = getiobuf(NULL, true);
1.3.6.2  mjf 				nestiobuf_setup(buf, nestbuf, i * sector_size,
1.3.6.2  mjf 					sector_size);
1.3.6.2  mjf 				/* adjust blocknumber to read */
1.3.6.2  mjf 				nestbuf->b_blkno = buf->b_blkno + i*blks;
1.3.6.2  mjf 				nestbuf->b_rawblkno = buf->b_rawblkno + i*blks;
1.3.6.2  mjf
1.3.6.2  mjf 				DPRINTF(SHEDULE, ("sector %d ",
1.3.6.2  mjf 					start + i));
1.3.6.2  mjf 				/* call asynchronous */
1.3.6.2  mjf 				VOP_STRATEGY(ump->devvp, nestbuf);
1.3.6.2  mjf 			}
1.3.6.2  mjf 			DPRINTF(SHEDULE, ("\n"));
1.3.6.2  mjf 			return;
1.3.6.2  mjf 		}
1.3.6.2  mjf 	} else {
1.3.6.2  mjf 		/* write or seqwrite */
1.3.6.2  mjf 		DPRINTF(SHEDULE, ("udf_issue_eccline writing or seqwriting : "));
1.3.6.2  mjf 		if (eccline->present != allbits) {
1.3.6.2  mjf 			/* requeue to read-only */
1.3.6.2  mjf 			DPRINTF(SHEDULE, ("\n\t-> not complete, requeue to "
1.3.6.2  mjf 				"reading\n"));
1.3.6.2  mjf 			udf_push_eccline(eccline, UDF_SHED_READING);
1.3.6.2  mjf 			return;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		start = eccline->start_sector;
1.3.6.2  mjf 		buf = eccline->buf;
1.3.6.2  mjf 		buf_init(buf);
1.3.6.2  mjf 		buf->b_flags    = B_WRITE | B_ASYNC;
1.3.6.2  mjf 		buf->b_cflags   = BC_BUSY;	/* needed? */
1.3.6.2  mjf 		buf->b_oflags   = 0;
1.3.6.2  mjf 		buf->b_iodone   = udf_shedule_write_callback;
1.3.6.2  mjf 		buf->b_data     = eccline->blob;
1.3.6.2  mjf 		buf->b_bcount   = ump->packet_size * sector_size;
1.3.6.2  mjf 		buf->b_resid    = buf->b_bcount;
1.3.6.2  mjf 		buf->b_bufsize  = buf->b_bcount;
1.3.6.2  mjf 		buf->b_private  = eccline;
1.3.6.2  mjf 		BIO_SETPRIO(buf, BPRIO_DEFAULT);
1.3.6.2  mjf 		buf->b_lblkno   = buf->b_blkno = buf->b_rawblkno = start * blks;
1.3.6.2  mjf 		buf->b_proc     = NULL;
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf 		/* call asynchronous */
1.3.6.2  mjf 		DPRINTF(SHEDULE, ("sector %d for %d\n",
1.3.6.2  mjf 			start, ump->packet_size));
1.3.6.2  mjf 		VOP_STRATEGY(ump->devvp, buf);
1.3.6.2  mjf 	mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_discstrat_thread(void *arg)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_mount *ump = (struct udf_mount *) arg;
1.3.6.2  mjf 	struct strat_private *priv = PRIV(ump);
1.3.6.2  mjf 	struct udf_eccline *eccline;
1.3.6.2  mjf 	struct timespec now, *last;
1.3.6.2  mjf 	int new_queue, wait, work;
1.3.6.2  mjf
1.3.6.2  mjf 	work = 1;
1.3.6.2  mjf 	mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf 	priv->num_floating = 0;
1.3.6.2  mjf 	while (priv->run_thread || work || priv->num_floating) {
1.3.6.2  mjf 		/* process the current selected queue */
1.3.6.2  mjf 		/* maintenance: free exess ecclines */
1.3.6.2  mjf 		while (priv->num_queued[UDF_SHED_FREE] > UDF_ECCLINE_MAXFREE) {
1.3.6.2  mjf 			eccline = udf_pop_eccline(priv, UDF_SHED_FREE);
1.3.6.2  mjf 			KASSERT(eccline);
1.3.6.2  mjf 			KASSERT(eccline->refcnt == 0);
1.3.6.2  mjf 			DPRINTF(ECCLINE, ("Removing entry from free list\n"));
1.3.6.2  mjf 			udf_dispose_eccline(eccline);
1.3.6.2  mjf 		}
1.3.6.2  mjf
1.3.6.2  mjf 		/* get our time */
1.3.6.2  mjf 		vfs_timestamp(&now);
1.3.6.2  mjf 		last = &priv->last_queued[priv->cur_queue];
1.3.6.2  mjf
1.3.6.2  mjf 		/* don't shedule too quickly when there is only one */
1.3.6.2  mjf 		if (priv->cur_queue == UDF_SHED_WRITING) {
1.3.6.2  mjf 			if (priv->num_queued[priv->cur_queue] <= 2) {
1.3.6.2  mjf 				if (now.tv_sec - last->tv_sec < 2) {
1.3.6.2  mjf 					/* wait some time */
1.3.6.2  mjf 					cv_timedwait(&priv->discstrat_cv,
1.3.6.2  mjf 						&priv->discstrat_mutex, hz);
1.3.6.2  mjf 				}
1.3.6.2  mjf 			}
1.3.6.2  mjf 		}
1.3.6.2  mjf
1.3.6.2  mjf 		/* get our line */
1.3.6.2  mjf 		eccline = udf_pop_eccline(priv, priv->cur_queue);
1.3.6.2  mjf 		if (eccline) {
1.3.6.2  mjf 			wait = 0;
1.3.6.2  mjf 			new_queue = priv->cur_queue;
1.3.6.2  mjf 			DPRINTF(ECCLINE, ("UDF_ISSUE_ECCLINE\n"));
1.3.6.2  mjf
1.3.6.2  mjf 			/* complete the `get' by locking and refcounting it */
1.3.6.2  mjf 			UDF_LOCK_ECCLINE(eccline);
1.3.6.2  mjf 			eccline->refcnt++;
1.3.6.2  mjf
1.3.6.2  mjf 			udf_issue_eccline(eccline, priv->cur_queue);
1.3.6.2  mjf 		} else {
1.3.6.2  mjf 			wait = 1;
1.3.6.2  mjf 			/* check if we can/should switch */
1.3.6.2  mjf 			new_queue = priv->cur_queue;
1.3.6.2  mjf 			if (BUFQ_PEEK(priv->queues[UDF_SHED_READING]))
1.3.6.2  mjf 				new_queue = UDF_SHED_READING;
1.3.6.2  mjf 			if (BUFQ_PEEK(priv->queues[UDF_SHED_WRITING]))
1.3.6.2  mjf 				new_queue = UDF_SHED_WRITING;
1.3.6.2  mjf 			if (BUFQ_PEEK(priv->queues[UDF_SHED_SEQWRITING]))
1.3.6.2  mjf 				new_queue = UDF_SHED_SEQWRITING;
1.3.6.2  mjf
1.3.6.2  mjf 			/* dont switch seqwriting too fast */
1.3.6.2  mjf 			if (priv->cur_queue == UDF_SHED_READING) {
1.3.6.2  mjf 				if (now.tv_sec - last->tv_sec < 1)
1.3.6.2  mjf 					new_queue = priv->cur_queue;
1.3.6.2  mjf 			}
1.3.6.2  mjf 			if (priv->cur_queue == UDF_SHED_WRITING) {
1.3.6.2  mjf 				if (now.tv_sec - last->tv_sec < 2)
1.3.6.2  mjf 					new_queue = priv->cur_queue;
1.3.6.2  mjf 			}
1.3.6.2  mjf 			if (priv->cur_queue == UDF_SHED_SEQWRITING) {
1.3.6.2  mjf 				if (now.tv_sec - last->tv_sec < 4)
1.3.6.2  mjf 					new_queue = priv->cur_queue;
1.3.6.2  mjf 			}
1.3.6.2  mjf 		}
1.3.6.2  mjf
1.3.6.2  mjf 		/* give room */
1.3.6.2  mjf 		mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 		if (new_queue != priv->cur_queue) {
1.3.6.2  mjf 			wait = 0;
1.3.6.2  mjf 			DPRINTF(SHEDULE, ("switching from %d to %d\n",
1.3.6.2  mjf 				priv->cur_queue, new_queue));
1.3.6.2  mjf 			priv->cur_queue = new_queue;
1.3.6.2  mjf 		}
1.3.6.2  mjf 		mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 		/* wait for more if needed */
1.3.6.2  mjf 		if (wait)
1.3.6.2  mjf 			cv_timedwait(&priv->discstrat_cv,
1.3.6.2  mjf 				&priv->discstrat_mutex, hz);	/* /8 */
1.3.6.2  mjf
1.3.6.2  mjf 		work  = (BUFQ_PEEK(priv->queues[UDF_SHED_READING]) != NULL);
1.3.6.2  mjf 		work |= (BUFQ_PEEK(priv->queues[UDF_SHED_WRITING]) != NULL);
1.3.6.2  mjf 		work |= (BUFQ_PEEK(priv->queues[UDF_SHED_SEQWRITING]) != NULL);
1.3.6.2  mjf
1.3.6.2  mjf 		DPRINTF(PARANOIA, ("work : (%d, %d, %d) -> work %d, float %d\n",
1.3.6.2  mjf 			(BUFQ_PEEK(priv->queues[UDF_SHED_READING]) != NULL),
1.3.6.2  mjf 			(BUFQ_PEEK(priv->queues[UDF_SHED_WRITING]) != NULL),
1.3.6.2  mjf 			(BUFQ_PEEK(priv->queues[UDF_SHED_SEQWRITING]) != NULL),
1.3.6.2  mjf 			work, priv->num_floating));
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	/* tear down remaining ecclines */
1.3.6.2  mjf 	mutex_enter(&priv->discstrat_mutex);
1.3.6.2  mjf 	KASSERT(priv->num_queued[UDF_SHED_IDLE] == 0);
1.3.6.2  mjf 	KASSERT(priv->num_queued[UDF_SHED_READING] == 0);
1.3.6.2  mjf 	KASSERT(priv->num_queued[UDF_SHED_WRITING] == 0);
1.3.6.2  mjf 	KASSERT(priv->num_queued[UDF_SHED_SEQWRITING] == 0);
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(BUFQ_PEEK(priv->queues[UDF_SHED_IDLE]) == NULL);
1.3.6.2  mjf 	KASSERT(BUFQ_PEEK(priv->queues[UDF_SHED_READING]) == NULL);
1.3.6.2  mjf 	KASSERT(BUFQ_PEEK(priv->queues[UDF_SHED_WRITING]) == NULL);
1.3.6.2  mjf 	KASSERT(BUFQ_PEEK(priv->queues[UDF_SHED_SEQWRITING]) == NULL);
1.3.6.2  mjf 	eccline = udf_pop_eccline(priv, UDF_SHED_FREE);
1.3.6.2  mjf 	while (eccline) {
1.3.6.2  mjf 		udf_dispose_eccline(eccline);
1.3.6.2  mjf 		eccline = udf_pop_eccline(priv, UDF_SHED_FREE);
1.3.6.2  mjf 	}
1.3.6.2  mjf 	KASSERT(priv->num_queued[UDF_SHED_FREE] == 0);
1.3.6.2  mjf 	mutex_exit(&priv->discstrat_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	priv->thread_finished = 1;
1.3.6.2  mjf 	wakeup(&priv->run_thread);
1.3.6.2  mjf 	kthread_exit(0);
1.3.6.2  mjf 	/* not reached */
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf /* --------------------------------------------------------------------- */
1.3.6.2  mjf
1.3.6.2  mjf /*
1.3.6.2  mjf  * Buffer memory pool allocator.
1.3.6.2  mjf  */
1.3.6.2  mjf
1.3.6.2  mjf static void *
1.3.6.2  mjf ecclinepool_page_alloc(struct pool *pp, int flags)
1.3.6.2  mjf {
1.3.6.2  mjf         return (void *)uvm_km_alloc(kernel_map,
1.3.6.2  mjf             MAXBSIZE, MAXBSIZE,
1.3.6.2  mjf             ((flags & PR_WAITOK) ? 0 : UVM_KMF_NOWAIT | UVM_KMF_TRYLOCK)
1.3.6.2  mjf 	    	| UVM_KMF_WIRED /* UVM_KMF_PAGABLE? */);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf ecclinepool_page_free(struct pool *pp, void *v)
1.3.6.2  mjf {
1.3.6.2  mjf         uvm_km_free(kernel_map, (vaddr_t)v, MAXBSIZE, UVM_KMF_WIRED);
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf static struct pool_allocator ecclinepool_allocator = {
1.3.6.2  mjf         .pa_alloc = ecclinepool_page_alloc,
1.3.6.2  mjf         .pa_free  = ecclinepool_page_free,
1.3.6.2  mjf         .pa_pagesz = MAXBSIZE,
1.3.6.2  mjf };
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_discstrat_init_rmw(struct udf_strat_args *args)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_mount *ump = args->ump;
1.3.6.2  mjf 	struct strat_private *priv = PRIV(ump);
1.3.6.2  mjf 	uint32_t lb_size, blobsize, hashline;
1.3.6.2  mjf 	int i;
1.3.6.2  mjf
1.3.6.2  mjf 	KASSERT(ump);
1.3.6.2  mjf 	KASSERT(ump->logical_vol);
1.3.6.2  mjf 	KASSERT(priv == NULL);
1.3.6.2  mjf
1.3.6.2  mjf 	lb_size = udf_rw32(ump->logical_vol->lb_size);
1.3.6.2  mjf 	blobsize = ump->packet_size * lb_size;
1.3.6.2  mjf 	KASSERT(lb_size > 0);
1.3.6.2  mjf 	KASSERT(ump->packet_size <= 64);
1.3.6.2  mjf
1.3.6.2  mjf 	/* initialise our memory space */
1.3.6.2  mjf 	ump->strategy_private = malloc(sizeof(struct strat_private),
1.3.6.2  mjf 		M_UDFTEMP, M_WAITOK);
1.3.6.2  mjf 	priv = ump->strategy_private;
1.3.6.2  mjf 	memset(priv, 0 , sizeof(struct strat_private));
1.3.6.2  mjf
1.3.6.2  mjf 	/* initialise locks */
1.3.6.2  mjf 	cv_init(&priv->discstrat_cv, "udfstrat");
1.3.6.2  mjf 	mutex_init(&priv->discstrat_mutex, MUTEX_DRIVER, IPL_BIO);
1.3.6.2  mjf 	mutex_init(&priv->seqwrite_mutex, MUTEX_DEFAULT, IPL_NONE);
1.3.6.2  mjf
1.3.6.2  mjf 	/* initialise struct eccline pool */
1.3.6.2  mjf 	pool_init(&priv->eccline_pool, sizeof(struct udf_eccline),
1.3.6.2  mjf 		0, 0, 0, "udf_eccline_pool", NULL, IPL_NONE);
1.3.6.2  mjf
1.3.6.2  mjf 	/* initialise eccline blob pool */
1.3.6.2  mjf 	pool_init(&priv->ecclineblob_pool, blobsize,
1.3.6.2  mjf 		0,0,0, "udf_eccline_blob", &ecclinepool_allocator, IPL_NONE);
1.3.6.2  mjf
1.3.6.2  mjf 	/* initialise main queues */
1.3.6.2  mjf 	for (i = 0; i < UDF_SHED_MAX; i++) {
1.3.6.2  mjf 		priv->num_queued[i] = 0;
1.3.6.2  mjf 		vfs_timestamp(&priv->last_queued[i]);
1.3.6.2  mjf 	}
1.3.6.2  mjf 	bufq_alloc(&priv->queues[UDF_SHED_READING], "disksort",
1.3.6.2  mjf 		BUFQ_SORT_RAWBLOCK);
1.3.6.2  mjf 	bufq_alloc(&priv->queues[UDF_SHED_WRITING], "disksort",
1.3.6.2  mjf 		BUFQ_SORT_RAWBLOCK);
1.3.6.2  mjf 	bufq_alloc(&priv->queues[UDF_SHED_SEQWRITING], "disksort", 0);
1.3.6.2  mjf
1.3.6.2  mjf 	/* initialise administrative queues */
1.3.6.2  mjf 	bufq_alloc(&priv->queues[UDF_SHED_IDLE], "fcfs", 0);
1.3.6.2  mjf 	bufq_alloc(&priv->queues[UDF_SHED_FREE], "fcfs", 0);
1.3.6.2  mjf
1.3.6.2  mjf 	for (hashline = 0; hashline < UDF_ECCBUF_HASHSIZE; hashline++) {
1.3.6.2  mjf 		LIST_INIT(&priv->eccline_hash[hashline]);
1.3.6.2  mjf 	}
1.3.6.2  mjf
1.3.6.2  mjf 	/* create our disk strategy thread */
1.3.6.2  mjf 	priv->cur_queue = UDF_SHED_READING;
1.3.6.2  mjf 	priv->thread_finished = 0;
1.3.6.2  mjf 	priv->run_thread      = 1;
1.3.6.2  mjf 	if (kthread_create(PRI_NONE, 0 /* KTHREAD_MPSAFE*/, NULL /* cpu_info*/,
1.3.6.2  mjf 		udf_discstrat_thread, ump, &priv->queue_lwp,
1.3.6.2  mjf 		"%s", "udf_rw")) {
1.3.6.2  mjf 		panic("fork udf_rw");
1.3.6.2  mjf 	}
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf
1.3.6.2  mjf static void
1.3.6.2  mjf udf_discstrat_finish_rmw(struct udf_strat_args *args)
1.3.6.2  mjf {
1.3.6.2  mjf 	struct udf_mount *ump = args->ump;
1.3.6.2  mjf 	struct strat_private *priv = PRIV(ump);
1.3.6.2  mjf 	int error;
1.3.6.2  mjf
1.3.6.2  mjf 	if (ump == NULL)
1.3.6.2  mjf 		return;
1.3.6.2  mjf
1.3.6.2  mjf 	/* stop our sheduling thread */
1.3.6.2  mjf 	KASSERT(priv->run_thread == 1);
1.3.6.2  mjf 	priv->run_thread = 0;
1.3.6.2  mjf 	wakeup(priv->queue_lwp);
1.3.6.2  mjf 	while (!priv->thread_finished) {
1.3.6.2  mjf 		error = tsleep(&priv->run_thread, PRIBIO+1,
1.3.6.2  mjf 			"udfshedfin", hz);
1.3.6.2  mjf 	}
1.3.6.2  mjf 	/* kthread should be finished now */
1.3.6.2  mjf
1.3.6.2  mjf 	/* cleanup our pools */
1.3.6.2  mjf 	pool_destroy(&priv->eccline_pool);
1.3.6.2  mjf 	pool_destroy(&priv->ecclineblob_pool);
1.3.6.2  mjf
1.3.6.2  mjf 	cv_destroy(&priv->discstrat_cv);
1.3.6.2  mjf 	mutex_destroy(&priv->discstrat_mutex);
1.3.6.2  mjf 	mutex_destroy(&priv->seqwrite_mutex);
1.3.6.2  mjf
1.3.6.2  mjf 	/* free our private space */
1.3.6.2  mjf 	free(ump->strategy_private, M_UDFTEMP);
1.3.6.2  mjf 	ump->strategy_private = NULL;
1.3.6.2  mjf }
1.3.6.2  mjf
1.3.6.2  mjf /* --------------------------------------------------------------------- */
1.3.6.2  mjf
1.3.6.2  mjf struct udf_strategy udf_strat_rmw =
1.3.6.2  mjf {
1.3.6.2  mjf 	udf_create_logvol_dscr_rmw,
1.3.6.2  mjf 	udf_free_logvol_dscr_rmw,
1.3.6.2  mjf 	udf_read_logvol_dscr_rmw,
1.3.6.2  mjf 	udf_write_logvol_dscr_rmw,
1.3.6.2  mjf 	udf_queuebuf_rmw,
1.3.6.2  mjf 	udf_discstrat_init_rmw,
1.3.6.2  mjf 	udf_discstrat_finish_rmw
1.3.6.2  mjf };
1.3.6.2  mjf