sbin/newfs/mkfs.c

1.30    bouyer /*	$NetBSD: mkfs.c,v 1.30 1998/03/18 17:10:15 bouyer Exp $	*/
1.19       cgd
 1.1       cgd /*
 1.9   mycroft  * Copyright (c) 1980, 1989, 1993
 1.9   mycroft  *	The Regents of the University of California.  All rights reserved.
 1.1       cgd  *
 1.1       cgd  * Redistribution and use in source and binary forms, with or without
 1.1       cgd  * modification, are permitted provided that the following conditions
 1.1       cgd  * are met:
 1.1       cgd  * 1. Redistributions of source code must retain the above copyright
 1.1       cgd  *    notice, this list of conditions and the following disclaimer.
 1.1       cgd  * 2. Redistributions in binary form must reproduce the above copyright
 1.1       cgd  *    notice, this list of conditions and the following disclaimer in the
 1.1       cgd  *    documentation and/or other materials provided with the distribution.
 1.1       cgd  * 3. All advertising materials mentioning features or use of this software
 1.1       cgd  *    must display the following acknowledgement:
 1.1       cgd  *	This product includes software developed by the University of
 1.1       cgd  *	California, Berkeley and its contributors.
 1.1       cgd  * 4. Neither the name of the University nor the names of its contributors
 1.1       cgd  *    may be used to endorse or promote products derived from this software
 1.1       cgd  *    without specific prior written permission.
 1.1       cgd  *
 1.1       cgd  * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
 1.1       cgd  * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 1.1       cgd  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 1.1       cgd  * ARE DISCLAIMED.  IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
 1.1       cgd  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1       cgd  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 1.1       cgd  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1       cgd  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1       cgd  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1       cgd  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1       cgd  * SUCH DAMAGE.
 1.1       cgd  */
 1.1       cgd
1.26  christos #include <sys/cdefs.h>
 1.1       cgd #ifndef lint
1.19       cgd #if 0
1.27     lukem static char sccsid[] = "@(#)mkfs.c	8.11 (Berkeley) 5/3/95";
1.19       cgd #else
1.30    bouyer __RCSID("$NetBSD: mkfs.c,v 1.30 1998/03/18 17:10:15 bouyer Exp $");
1.19       cgd #endif
 1.1       cgd #endif /* not lint */
 1.1       cgd
 1.1       cgd #include <sys/param.h>
 1.1       cgd #include <sys/time.h>
 1.1       cgd #include <sys/resource.h>
 1.9   mycroft #include <ufs/ufs/dinode.h>
 1.9   mycroft #include <ufs/ufs/dir.h>
1.30    bouyer #include <ufs/ufs/ufs_bswap.h>
 1.9   mycroft #include <ufs/ffs/fs.h>
1.30    bouyer #include <ufs/ffs/ffs_extern.h>
 1.1       cgd #include <sys/disklabel.h>
 1.9   mycroft
1.14       cgd #include <string.h>
1.14       cgd #include <unistd.h>
1.26  christos #include <stdlib.h>
1.14       cgd
 1.9   mycroft #ifndef STANDALONE
 1.9   mycroft #include <a.out.h>
 1.9   mycroft #include <stdio.h>
 1.9   mycroft #endif
1.26  christos #include <extern.h>
 1.1       cgd
1.26  christos
1.26  christos static void initcg __P((int, time_t));
1.26  christos static void fsinit __P((time_t));
1.26  christos static int makedir __P((struct direct *, int));
1.26  christos static daddr_t alloc __P((int, int));
1.26  christos static void iput __P((struct dinode *, ino_t));
1.26  christos static void rdfs __P((daddr_t, int, void *));
1.26  christos static void wtfs __P((daddr_t, int, void *));
1.26  christos static int isblock __P((struct fs *, unsigned char *, int));
1.26  christos static void clrblock __P((struct fs *, unsigned char *, int));
1.26  christos static void setblock __P((struct fs *, unsigned char *, int));
1.27     lukem static int32_t calcipg __P((int32_t, int32_t, off_t *));
1.30    bouyer static void swap_cg __P((struct cg *, struct cg *));
1.27     lukem
 1.1       cgd /*
 1.1       cgd  * make file system for cylinder-group style file systems
 1.1       cgd  */
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * We limit the size of the inode map to be no more than a
 1.1       cgd  * third of the cylinder group space, since we must leave at
 1.1       cgd  * least an equal amount of space for the block map.
 1.1       cgd  *
 1.1       cgd  * N.B.: MAXIPG must be a multiple of INOPB(fs).
 1.1       cgd  */
 1.1       cgd #define MAXIPG(fs)	roundup((fs)->fs_bsize * NBBY / 3, INOPB(fs))
 1.1       cgd
 1.1       cgd #define UMASK		0755
 1.1       cgd #define MAXINOPB	(MAXBSIZE / sizeof(struct dinode))
 1.1       cgd #define POWEROF2(num)	(((num) & ((num) - 1)) == 0)
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * variables set up by front end.
 1.1       cgd  */
 1.1       cgd extern int	mfs;		/* run as the memory based filesystem */
 1.1       cgd extern int	Nflag;		/* run mkfs without writing file system */
 1.9   mycroft extern int	Oflag;		/* format as an 4.3BSD file system */
 1.1       cgd extern int	fssize;		/* file system size */
 1.1       cgd extern int	ntracks;	/* # tracks/cylinder */
 1.1       cgd extern int	nsectors;	/* # sectors/track */
 1.1       cgd extern int	nphyssectors;	/* # sectors/track including spares */
 1.1       cgd extern int	secpercyl;	/* sectors per cylinder */
 1.1       cgd extern int	sectorsize;	/* bytes/sector */
 1.1       cgd extern int	rpm;		/* revolutions/minute of drive */
 1.1       cgd extern int	interleave;	/* hardware sector interleave */
 1.1       cgd extern int	trackskew;	/* sector 0 skew, per track */
 1.1       cgd extern int	headswitch;	/* head switch time, usec */
 1.1       cgd extern int	trackseek;	/* track-to-track seek, usec */
 1.1       cgd extern int	fsize;		/* fragment size */
 1.1       cgd extern int	bsize;		/* block size */
 1.1       cgd extern int	cpg;		/* cylinders/cylinder group */
 1.1       cgd extern int	cpgflg;		/* cylinders/cylinder group flag was given */
 1.1       cgd extern int	minfree;	/* free space threshold */
 1.1       cgd extern int	opt;		/* optimization preference (space or time) */
 1.1       cgd extern int	density;	/* number of bytes per inode */
 1.1       cgd extern int	maxcontig;	/* max contiguous blocks to allocate */
 1.1       cgd extern int	rotdelay;	/* rotational delay between blocks */
 1.1       cgd extern int	maxbpg;		/* maximum blocks per file in a cyl group */
 1.1       cgd extern int	nrpos;		/* # of distinguished rotational positions */
 1.1       cgd extern int	bbsize;		/* boot block size */
 1.1       cgd extern int	sbsize;		/* superblock size */
 1.1       cgd extern u_long	memleft;	/* virtual memory available */
 1.1       cgd extern caddr_t	membase;	/* start address of memory based filesystem */
1.30    bouyer extern int needswap;		/* Filesystem not in native byte order */
 1.1       cgd
 1.1       cgd union {
 1.1       cgd 	struct fs fs;
 1.1       cgd 	char pad[SBSIZE];
 1.1       cgd } fsun;
 1.1       cgd #define	sblock	fsun.fs
 1.1       cgd struct	csum *fscs;
 1.1       cgd
 1.1       cgd union {
 1.1       cgd 	struct cg cg;
 1.1       cgd 	char pad[MAXBSIZE];
 1.1       cgd } cgun;
 1.1       cgd #define	acg	cgun.cg
 1.1       cgd
 1.1       cgd struct dinode zino[MAXBSIZE / sizeof(struct dinode)];
 1.1       cgd
1.30    bouyer char writebuf[MAXBSIZE];
1.30    bouyer
 1.1       cgd int	fsi, fso;
 1.1       cgd
1.26  christos void
 1.1       cgd mkfs(pp, fsys, fi, fo)
 1.1       cgd 	struct partition *pp;
 1.1       cgd 	char *fsys;
 1.1       cgd 	int fi, fo;
 1.1       cgd {
1.27     lukem 	int32_t i, mincpc, mincpg, inospercg;
1.27     lukem 	int32_t cylno, rpos, blk, j, warn = 0;
1.27     lukem 	int32_t used, mincpgcnt, bpcg;
1.27     lukem 	off_t usedb;
1.27     lukem 	int32_t mapcramped, inodecramped;
1.27     lukem 	int32_t postblsize, rotblsize, totalsbsize;
 1.1       cgd 	time_t utime;
 1.9   mycroft 	quad_t sizepb;
 1.1       cgd
 1.1       cgd #ifndef STANDALONE
 1.1       cgd 	time(&utime);
 1.1       cgd #endif
 1.1       cgd 	if (mfs) {
 1.1       cgd 		(void)malloc(0);
 1.1       cgd 		if (fssize * sectorsize > memleft)
 1.1       cgd 			fssize = (memleft - 16384) / sectorsize;
 1.1       cgd 		if ((membase = malloc(fssize * sectorsize)) == 0)
 1.1       cgd 			exit(12);
 1.1       cgd 	}
 1.1       cgd 	fsi = fi;
 1.1       cgd 	fso = fo;
 1.9   mycroft 	if (Oflag) {
 1.9   mycroft 		sblock.fs_inodefmt = FS_42INODEFMT;
 1.9   mycroft 		sblock.fs_maxsymlinklen = 0;
 1.9   mycroft 	} else {
 1.9   mycroft 		sblock.fs_inodefmt = FS_44INODEFMT;
 1.9   mycroft 		sblock.fs_maxsymlinklen = MAXSYMLINKLEN;
 1.9   mycroft 	}
 1.1       cgd 	/*
 1.1       cgd 	 * Validate the given file system size.
 1.1       cgd 	 * Verify that its last block can actually be accessed.
 1.1       cgd 	 */
 1.1       cgd 	if (fssize <= 0)
 1.1       cgd 		printf("preposterous size %d\n", fssize), exit(13);
 1.1       cgd 	wtfs(fssize - 1, sectorsize, (char *)&sblock);
1.30    bouyer
 1.1       cgd 	/*
 1.1       cgd 	 * collect and verify the sector and track info
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_nsect = nsectors;
 1.1       cgd 	sblock.fs_ntrak = ntracks;
 1.1       cgd 	if (sblock.fs_ntrak <= 0)
 1.1       cgd 		printf("preposterous ntrak %d\n", sblock.fs_ntrak), exit(14);
 1.1       cgd 	if (sblock.fs_nsect <= 0)
 1.1       cgd 		printf("preposterous nsect %d\n", sblock.fs_nsect), exit(15);
 1.1       cgd 	/*
 1.1       cgd 	 * collect and verify the block and fragment sizes
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_bsize = bsize;
 1.1       cgd 	sblock.fs_fsize = fsize;
 1.1       cgd 	if (!POWEROF2(sblock.fs_bsize)) {
 1.1       cgd 		printf("block size must be a power of 2, not %d\n",
 1.1       cgd 		    sblock.fs_bsize);
 1.1       cgd 		exit(16);
 1.1       cgd 	}
 1.1       cgd 	if (!POWEROF2(sblock.fs_fsize)) {
 1.1       cgd 		printf("fragment size must be a power of 2, not %d\n",
 1.1       cgd 		    sblock.fs_fsize);
 1.1       cgd 		exit(17);
 1.1       cgd 	}
 1.1       cgd 	if (sblock.fs_fsize < sectorsize) {
 1.1       cgd 		printf("fragment size %d is too small, minimum is %d\n",
 1.1       cgd 		    sblock.fs_fsize, sectorsize);
 1.1       cgd 		exit(18);
 1.1       cgd 	}
 1.1       cgd 	if (sblock.fs_bsize < MINBSIZE) {
 1.1       cgd 		printf("block size %d is too small, minimum is %d\n",
 1.1       cgd 		    sblock.fs_bsize, MINBSIZE);
 1.1       cgd 		exit(19);
 1.1       cgd 	}
 1.1       cgd 	if (sblock.fs_bsize < sblock.fs_fsize) {
 1.1       cgd 		printf("block size (%d) cannot be smaller than fragment size (%d)\n",
 1.1       cgd 		    sblock.fs_bsize, sblock.fs_fsize);
 1.1       cgd 		exit(20);
 1.1       cgd 	}
 1.1       cgd 	sblock.fs_bmask = ~(sblock.fs_bsize - 1);
 1.1       cgd 	sblock.fs_fmask = ~(sblock.fs_fsize - 1);
 1.9   mycroft 	sblock.fs_qbmask = ~sblock.fs_bmask;
 1.9   mycroft 	sblock.fs_qfmask = ~sblock.fs_fmask;
 1.1       cgd 	for (sblock.fs_bshift = 0, i = sblock.fs_bsize; i > 1; i >>= 1)
 1.1       cgd 		sblock.fs_bshift++;
 1.1       cgd 	for (sblock.fs_fshift = 0, i = sblock.fs_fsize; i > 1; i >>= 1)
 1.1       cgd 		sblock.fs_fshift++;
 1.1       cgd 	sblock.fs_frag = numfrags(&sblock, sblock.fs_bsize);
 1.1       cgd 	for (sblock.fs_fragshift = 0, i = sblock.fs_frag; i > 1; i >>= 1)
 1.1       cgd 		sblock.fs_fragshift++;
 1.1       cgd 	if (sblock.fs_frag > MAXFRAG) {
1.30    bouyer 		printf("fragment size %d is too small, "
1.30    bouyer 			"minimum with block size %d is %d\n",
 1.1       cgd 		    sblock.fs_fsize, sblock.fs_bsize,
 1.1       cgd 		    sblock.fs_bsize / MAXFRAG);
 1.1       cgd 		exit(21);
 1.1       cgd 	}
 1.1       cgd 	sblock.fs_nrpos = nrpos;
 1.1       cgd 	sblock.fs_nindir = sblock.fs_bsize / sizeof(daddr_t);
 1.1       cgd 	sblock.fs_inopb = sblock.fs_bsize / sizeof(struct dinode);
 1.1       cgd 	sblock.fs_nspf = sblock.fs_fsize / sectorsize;
 1.1       cgd 	for (sblock.fs_fsbtodb = 0, i = NSPF(&sblock); i > 1; i >>= 1)
 1.1       cgd 		sblock.fs_fsbtodb++;
 1.1       cgd 	sblock.fs_sblkno =
 1.1       cgd 	    roundup(howmany(bbsize + sbsize, sblock.fs_fsize), sblock.fs_frag);
 1.1       cgd 	sblock.fs_cblkno = (daddr_t)(sblock.fs_sblkno +
 1.1       cgd 	    roundup(howmany(sbsize, sblock.fs_fsize), sblock.fs_frag));
 1.1       cgd 	sblock.fs_iblkno = sblock.fs_cblkno + sblock.fs_frag;
 1.1       cgd 	sblock.fs_cgoffset = roundup(
 1.1       cgd 	    howmany(sblock.fs_nsect, NSPF(&sblock)), sblock.fs_frag);
 1.1       cgd 	for (sblock.fs_cgmask = 0xffffffff, i = sblock.fs_ntrak; i > 1; i >>= 1)
 1.1       cgd 		sblock.fs_cgmask <<= 1;
 1.1       cgd 	if (!POWEROF2(sblock.fs_ntrak))
 1.1       cgd 		sblock.fs_cgmask <<= 1;
 1.9   mycroft 	sblock.fs_maxfilesize = sblock.fs_bsize * NDADDR - 1;
 1.9   mycroft 	for (sizepb = sblock.fs_bsize, i = 0; i < NIADDR; i++) {
 1.9   mycroft 		sizepb *= NINDIR(&sblock);
 1.9   mycroft 		sblock.fs_maxfilesize += sizepb;
 1.9   mycroft 	}
 1.1       cgd 	/*
 1.1       cgd 	 * Validate specified/determined secpercyl
 1.1       cgd 	 * and calculate minimum cylinders per group.
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_spc = secpercyl;
 1.1       cgd 	for (sblock.fs_cpc = NSPB(&sblock), i = sblock.fs_spc;
 1.1       cgd 	     sblock.fs_cpc > 1 && (i & 1) == 0;
 1.1       cgd 	     sblock.fs_cpc >>= 1, i >>= 1)
 1.1       cgd 		/* void */;
 1.1       cgd 	mincpc = sblock.fs_cpc;
 1.1       cgd 	bpcg = sblock.fs_spc * sectorsize;
 1.1       cgd 	inospercg = roundup(bpcg / sizeof(struct dinode), INOPB(&sblock));
 1.1       cgd 	if (inospercg > MAXIPG(&sblock))
 1.1       cgd 		inospercg = MAXIPG(&sblock);
 1.1       cgd 	used = (sblock.fs_iblkno + inospercg / INOPF(&sblock)) * NSPF(&sblock);
 1.1       cgd 	mincpgcnt = howmany(sblock.fs_cgoffset * (~sblock.fs_cgmask) + used,
 1.1       cgd 	    sblock.fs_spc);
 1.1       cgd 	mincpg = roundup(mincpgcnt, mincpc);
 1.1       cgd 	/*
 1.9   mycroft 	 * Ensure that cylinder group with mincpg has enough space
 1.9   mycroft 	 * for block maps.
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_cpg = mincpg;
 1.1       cgd 	sblock.fs_ipg = inospercg;
 1.9   mycroft 	if (maxcontig > 1)
 1.9   mycroft 		sblock.fs_contigsumsize = MIN(maxcontig, FS_MAXCONTIG);
 1.1       cgd 	mapcramped = 0;
 1.1       cgd 	while (CGSIZE(&sblock) > sblock.fs_bsize) {
 1.1       cgd 		mapcramped = 1;
 1.1       cgd 		if (sblock.fs_bsize < MAXBSIZE) {
 1.1       cgd 			sblock.fs_bsize <<= 1;
 1.1       cgd 			if ((i & 1) == 0) {
 1.1       cgd 				i >>= 1;
 1.1       cgd 			} else {
 1.1       cgd 				sblock.fs_cpc <<= 1;
 1.1       cgd 				mincpc <<= 1;
 1.1       cgd 				mincpg = roundup(mincpgcnt, mincpc);
 1.1       cgd 				sblock.fs_cpg = mincpg;
 1.1       cgd 			}
 1.1       cgd 			sblock.fs_frag <<= 1;
 1.1       cgd 			sblock.fs_fragshift += 1;
 1.1       cgd 			if (sblock.fs_frag <= MAXFRAG)
 1.1       cgd 				continue;
 1.1       cgd 		}
 1.1       cgd 		if (sblock.fs_fsize == sblock.fs_bsize) {
 1.1       cgd 			printf("There is no block size that");
 1.1       cgd 			printf(" can support this disk\n");
 1.1       cgd 			exit(22);
 1.1       cgd 		}
 1.1       cgd 		sblock.fs_frag >>= 1;
 1.1       cgd 		sblock.fs_fragshift -= 1;
 1.1       cgd 		sblock.fs_fsize <<= 1;
 1.1       cgd 		sblock.fs_nspf <<= 1;
 1.1       cgd 	}
 1.1       cgd 	/*
 1.9   mycroft 	 * Ensure that cylinder group with mincpg has enough space for inodes.
 1.1       cgd 	 */
 1.1       cgd 	inodecramped = 0;
1.27     lukem 	inospercg = calcipg(mincpg, bpcg, &usedb);
 1.1       cgd 	sblock.fs_ipg = inospercg;
 1.1       cgd 	while (inospercg > MAXIPG(&sblock)) {
 1.1       cgd 		inodecramped = 1;
 1.1       cgd 		if (mincpc == 1 || sblock.fs_frag == 1 ||
 1.1       cgd 		    sblock.fs_bsize == MINBSIZE)
 1.1       cgd 			break;
1.27     lukem 		printf("With a block size of %d %s %d\n", sblock.fs_bsize,
1.27     lukem 		       "minimum bytes per inode is",
1.27     lukem 		       (int)((mincpg * (off_t)bpcg - usedb)
1.27     lukem 			     / MAXIPG(&sblock) + 1));
 1.1       cgd 		sblock.fs_bsize >>= 1;
 1.1       cgd 		sblock.fs_frag >>= 1;
 1.1       cgd 		sblock.fs_fragshift -= 1;
 1.1       cgd 		mincpc >>= 1;
 1.1       cgd 		sblock.fs_cpg = roundup(mincpgcnt, mincpc);
 1.1       cgd 		if (CGSIZE(&sblock) > sblock.fs_bsize) {
 1.1       cgd 			sblock.fs_bsize <<= 1;
 1.1       cgd 			break;
 1.1       cgd 		}
 1.1       cgd 		mincpg = sblock.fs_cpg;
1.27     lukem 		inospercg = calcipg(mincpg, bpcg, &usedb);
 1.1       cgd 		sblock.fs_ipg = inospercg;
 1.1       cgd 	}
 1.1       cgd 	if (inodecramped) {
 1.1       cgd 		if (inospercg > MAXIPG(&sblock)) {
1.27     lukem 			printf("Minimum bytes per inode is %d\n",
1.27     lukem 			       (int)((mincpg * (off_t)bpcg - usedb)
1.27     lukem 				     / MAXIPG(&sblock) + 1));
 1.1       cgd 		} else if (!mapcramped) {
 1.1       cgd 			printf("With %d bytes per inode, ", density);
1.27     lukem 			printf("minimum cylinders per group is %d\n", mincpg);
 1.1       cgd 		}
 1.1       cgd 	}
 1.1       cgd 	if (mapcramped) {
 1.1       cgd 		printf("With %d sectors per cylinder, ", sblock.fs_spc);
1.27     lukem 		printf("minimum cylinders per group is %d\n", mincpg);
 1.1       cgd 	}
 1.1       cgd 	if (inodecramped || mapcramped) {
 1.1       cgd 		if (sblock.fs_bsize != bsize)
 1.1       cgd 			printf("%s to be changed from %d to %d\n",
 1.1       cgd 			    "This requires the block size",
 1.1       cgd 			    bsize, sblock.fs_bsize);
 1.1       cgd 		if (sblock.fs_fsize != fsize)
 1.1       cgd 			printf("\t%s to be changed from %d to %d\n",
 1.1       cgd 			    "and the fragment size",
 1.1       cgd 			    fsize, sblock.fs_fsize);
 1.1       cgd 		exit(23);
 1.1       cgd 	}
 1.1       cgd 	/*
 1.1       cgd 	 * Calculate the number of cylinders per group
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_cpg = cpg;
 1.1       cgd 	if (sblock.fs_cpg % mincpc != 0) {
1.27     lukem 		printf("%s groups must have a multiple of %d cylinders\n",
 1.1       cgd 			cpgflg ? "Cylinder" : "Warning: cylinder", mincpc);
 1.1       cgd 		sblock.fs_cpg = roundup(sblock.fs_cpg, mincpc);
 1.1       cgd 		if (!cpgflg)
 1.1       cgd 			cpg = sblock.fs_cpg;
 1.1       cgd 	}
 1.1       cgd 	/*
 1.9   mycroft 	 * Must ensure there is enough space for inodes.
 1.1       cgd 	 */
1.27     lukem 	sblock.fs_ipg = calcipg(sblock.fs_cpg, bpcg, &usedb);
 1.1       cgd 	while (sblock.fs_ipg > MAXIPG(&sblock)) {
 1.1       cgd 		inodecramped = 1;
 1.1       cgd 		sblock.fs_cpg -= mincpc;
1.27     lukem 		sblock.fs_ipg = calcipg(sblock.fs_cpg, bpcg, &usedb);
 1.1       cgd 	}
 1.1       cgd 	/*
 1.9   mycroft 	 * Must ensure there is enough space to hold block map.
 1.1       cgd 	 */
 1.1       cgd 	while (CGSIZE(&sblock) > sblock.fs_bsize) {
 1.1       cgd 		mapcramped = 1;
 1.1       cgd 		sblock.fs_cpg -= mincpc;
1.27     lukem 		sblock.fs_ipg = calcipg(sblock.fs_cpg, bpcg, &usedb);
 1.1       cgd 	}
 1.1       cgd 	sblock.fs_fpg = (sblock.fs_cpg * sblock.fs_spc) / NSPF(&sblock);
 1.1       cgd 	if ((sblock.fs_cpg * sblock.fs_spc) % NSPB(&sblock) != 0) {
1.26  christos 		printf("panic (fs_cpg * fs_spc) %% NSPF != 0");
 1.1       cgd 		exit(24);
 1.1       cgd 	}
 1.1       cgd 	if (sblock.fs_cpg < mincpg) {
1.27     lukem 		printf("cylinder groups must have at least %d cylinders\n",
 1.1       cgd 			mincpg);
 1.1       cgd 		exit(25);
 1.1       cgd 	} else if (sblock.fs_cpg != cpg) {
 1.1       cgd 		if (!cpgflg)
 1.1       cgd 			printf("Warning: ");
 1.1       cgd 		else if (!mapcramped && !inodecramped)
 1.1       cgd 			exit(26);
 1.1       cgd 		if (mapcramped && inodecramped)
 1.1       cgd 			printf("Block size and bytes per inode restrict");
 1.1       cgd 		else if (mapcramped)
 1.1       cgd 			printf("Block size restricts");
 1.1       cgd 		else
 1.1       cgd 			printf("Bytes per inode restrict");
 1.1       cgd 		printf(" cylinders per group to %d.\n", sblock.fs_cpg);
 1.1       cgd 		if (cpgflg)
 1.1       cgd 			exit(27);
 1.1       cgd 	}
 1.1       cgd 	sblock.fs_cgsize = fragroundup(&sblock, CGSIZE(&sblock));
 1.1       cgd 	/*
 1.1       cgd 	 * Now have size for file system and nsect and ntrak.
 1.1       cgd 	 * Determine number of cylinders and blocks in the file system.
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_size = fssize = dbtofsb(&sblock, fssize);
 1.1       cgd 	sblock.fs_ncyl = fssize * NSPF(&sblock) / sblock.fs_spc;
 1.1       cgd 	if (fssize * NSPF(&sblock) > sblock.fs_ncyl * sblock.fs_spc) {
 1.1       cgd 		sblock.fs_ncyl++;
 1.1       cgd 		warn = 1;
 1.1       cgd 	}
 1.1       cgd 	if (sblock.fs_ncyl < 1) {
 1.1       cgd 		printf("file systems must have at least one cylinder\n");
 1.1       cgd 		exit(28);
 1.1       cgd 	}
 1.1       cgd 	/*
 1.1       cgd 	 * Determine feasability/values of rotational layout tables.
 1.1       cgd 	 *
 1.1       cgd 	 * The size of the rotational layout tables is limited by the
 1.1       cgd 	 * size of the superblock, SBSIZE. The amount of space available
 1.1       cgd 	 * for tables is calculated as (SBSIZE - sizeof (struct fs)).
 1.1       cgd 	 * The size of these tables is inversely proportional to the block
 1.1       cgd 	 * size of the file system. The size increases if sectors per track
 1.1       cgd 	 * are not powers of two, because more cylinders must be described
 1.1       cgd 	 * by the tables before the rotational pattern repeats (fs_cpc).
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_interleave = interleave;
 1.1       cgd 	sblock.fs_trackskew = trackskew;
 1.1       cgd 	sblock.fs_npsect = nphyssectors;
 1.1       cgd 	sblock.fs_postblformat = FS_DYNAMICPOSTBLFMT;
 1.1       cgd 	sblock.fs_sbsize = fragroundup(&sblock, sizeof(struct fs));
 1.1       cgd 	if (sblock.fs_ntrak == 1) {
 1.1       cgd 		sblock.fs_cpc = 0;
 1.1       cgd 		goto next;
 1.1       cgd 	}
1.20       cgd 	postblsize = sblock.fs_nrpos * sblock.fs_cpc * sizeof(int16_t);
 1.1       cgd 	rotblsize = sblock.fs_cpc * sblock.fs_spc / NSPB(&sblock);
 1.1       cgd 	totalsbsize = sizeof(struct fs) + rotblsize;
 1.1       cgd 	if (sblock.fs_nrpos == 8 && sblock.fs_cpc <= 16) {
 1.1       cgd 		/* use old static table space */
 1.1       cgd 		sblock.fs_postbloff = (char *)(&sblock.fs_opostbl[0][0]) -
1.15       cgd 		    (char *)(&sblock.fs_firstfield);
 1.1       cgd 		sblock.fs_rotbloff = &sblock.fs_space[0] -
1.15       cgd 		    (u_char *)(&sblock.fs_firstfield);
 1.1       cgd 	} else {
 1.1       cgd 		/* use dynamic table space */
 1.1       cgd 		sblock.fs_postbloff = &sblock.fs_space[0] -
1.15       cgd 		    (u_char *)(&sblock.fs_firstfield);
 1.1       cgd 		sblock.fs_rotbloff = sblock.fs_postbloff + postblsize;
 1.1       cgd 		totalsbsize += postblsize;
 1.1       cgd 	}
 1.1       cgd 	if (totalsbsize > SBSIZE ||
 1.1       cgd 	    sblock.fs_nsect > (1 << NBBY) * NSPB(&sblock)) {
 1.1       cgd 		printf("%s %s %d %s %d.%s",
 1.1       cgd 		    "Warning: insufficient space in super block for\n",
 1.1       cgd 		    "rotational layout tables with nsect", sblock.fs_nsect,
 1.1       cgd 		    "and ntrak", sblock.fs_ntrak,
 1.1       cgd 		    "\nFile system performance may be impaired.\n");
 1.1       cgd 		sblock.fs_cpc = 0;
 1.1       cgd 		goto next;
 1.1       cgd 	}
 1.1       cgd 	sblock.fs_sbsize = fragroundup(&sblock, totalsbsize);
 1.1       cgd 	/*
 1.1       cgd 	 * calculate the available blocks for each rotational position
 1.1       cgd 	 */
 1.1       cgd 	for (cylno = 0; cylno < sblock.fs_cpc; cylno++)
 1.1       cgd 		for (rpos = 0; rpos < sblock.fs_nrpos; rpos++)
 1.1       cgd 			fs_postbl(&sblock, cylno)[rpos] = -1;
 1.1       cgd 	for (i = (rotblsize - 1) * sblock.fs_frag;
 1.1       cgd 	     i >= 0; i -= sblock.fs_frag) {
 1.1       cgd 		cylno = cbtocylno(&sblock, i);
 1.1       cgd 		rpos = cbtorpos(&sblock, i);
 1.1       cgd 		blk = fragstoblks(&sblock, i);
 1.1       cgd 		if (fs_postbl(&sblock, cylno)[rpos] == -1)
 1.1       cgd 			fs_rotbl(&sblock)[blk] = 0;
 1.1       cgd 		else
1.30    bouyer 			fs_rotbl(&sblock)[blk] = fs_postbl(&sblock, cylno)[rpos] - blk;
 1.1       cgd 		fs_postbl(&sblock, cylno)[rpos] = blk;
 1.1       cgd 	}
 1.1       cgd next:
 1.1       cgd 	/*
 1.1       cgd 	 * Compute/validate number of cylinder groups.
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_ncg = sblock.fs_ncyl / sblock.fs_cpg;
 1.1       cgd 	if (sblock.fs_ncyl % sblock.fs_cpg)
 1.1       cgd 		sblock.fs_ncg++;
 1.1       cgd 	sblock.fs_dblkno = sblock.fs_iblkno + sblock.fs_ipg / INOPF(&sblock);
 1.1       cgd 	i = MIN(~sblock.fs_cgmask, sblock.fs_ncg - 1);
 1.1       cgd 	if (cgdmin(&sblock, i) - cgbase(&sblock, i) >= sblock.fs_fpg) {
1.27     lukem 		printf("inode blocks/cyl group (%d) >= data blocks (%d)\n",
 1.1       cgd 		    cgdmin(&sblock, i) - cgbase(&sblock, i) / sblock.fs_frag,
 1.1       cgd 		    sblock.fs_fpg / sblock.fs_frag);
 1.1       cgd 		printf("number of cylinders per cylinder group (%d) %s.\n",
 1.1       cgd 		    sblock.fs_cpg, "must be increased");
 1.1       cgd 		exit(29);
 1.1       cgd 	}
 1.1       cgd 	j = sblock.fs_ncg - 1;
 1.1       cgd 	if ((i = fssize - j * sblock.fs_fpg) < sblock.fs_fpg &&
 1.1       cgd 	    cgdmin(&sblock, j) - cgbase(&sblock, j) > i) {
 1.1       cgd 		if (j == 0) {
 1.1       cgd 			printf("Filesystem must have at least %d sectors\n",
 1.1       cgd 			    NSPF(&sblock) *
 1.1       cgd 			    (cgdmin(&sblock, 0) + 3 * sblock.fs_frag));
 1.1       cgd 			exit(30);
 1.1       cgd 		}
1.30    bouyer 		printf("Warning: inode blocks/cyl group (%d) >= "
1.30    bouyer 			"data blocks (%d) in last\n",
 1.1       cgd 		    (cgdmin(&sblock, j) - cgbase(&sblock, j)) / sblock.fs_frag,
 1.1       cgd 		    i / sblock.fs_frag);
1.30    bouyer 		printf("    cylinder group. This implies %d sector(s) "
1.30    bouyer 			"cannot be allocated.\n",
 1.1       cgd 		    i * NSPF(&sblock));
 1.1       cgd 		sblock.fs_ncg--;
 1.1       cgd 		sblock.fs_ncyl -= sblock.fs_ncyl % sblock.fs_cpg;
 1.1       cgd 		sblock.fs_size = fssize = sblock.fs_ncyl * sblock.fs_spc /
 1.1       cgd 		    NSPF(&sblock);
 1.1       cgd 		warn = 0;
 1.1       cgd 	}
 1.1       cgd 	if (warn && !mfs) {
 1.1       cgd 		printf("Warning: %d sector(s) in last cylinder unallocated\n",
 1.1       cgd 		    sblock.fs_spc -
 1.1       cgd 		    (fssize * NSPF(&sblock) - (sblock.fs_ncyl - 1)
 1.1       cgd 		    * sblock.fs_spc));
 1.1       cgd 	}
 1.1       cgd 	/*
 1.1       cgd 	 * fill in remaining fields of the super block
 1.1       cgd 	 */
 1.1       cgd 	sblock.fs_csaddr = cgdmin(&sblock, 0);
 1.1       cgd 	sblock.fs_cssize =
 1.1       cgd 	    fragroundup(&sblock, sblock.fs_ncg * sizeof(struct csum));
 1.1       cgd 	i = sblock.fs_bsize / sizeof(struct csum);
 1.1       cgd 	sblock.fs_csmask = ~(i - 1);
 1.1       cgd 	for (sblock.fs_csshift = 0; i > 1; i >>= 1)
 1.1       cgd 		sblock.fs_csshift++;
 1.1       cgd 	fscs = (struct csum *)calloc(1, sblock.fs_cssize);
 1.1       cgd 	sblock.fs_magic = FS_MAGIC;
 1.1       cgd 	sblock.fs_rotdelay = rotdelay;
 1.1       cgd 	sblock.fs_minfree = minfree;
 1.1       cgd 	sblock.fs_maxcontig = maxcontig;
 1.1       cgd 	sblock.fs_headswitch = headswitch;
 1.1       cgd 	sblock.fs_trkseek = trackseek;
 1.1       cgd 	sblock.fs_maxbpg = maxbpg;
 1.1       cgd 	sblock.fs_rps = rpm / 60;
 1.1       cgd 	sblock.fs_optim = opt;
 1.1       cgd 	sblock.fs_cgrotor = 0;
 1.1       cgd 	sblock.fs_cstotal.cs_ndir = 0;
 1.1       cgd 	sblock.fs_cstotal.cs_nbfree = 0;
 1.1       cgd 	sblock.fs_cstotal.cs_nifree = 0;
 1.1       cgd 	sblock.fs_cstotal.cs_nffree = 0;
 1.1       cgd 	sblock.fs_fmod = 0;
1.21   mycroft 	sblock.fs_clean = FS_ISCLEAN;
 1.1       cgd 	sblock.fs_ronly = 0;
1.27     lukem 	sblock.fs_clean = 1;
 1.1       cgd 	/*
 1.1       cgd 	 * Dump out summary information about file system.
 1.1       cgd 	 */
 1.1       cgd 	if (!mfs) {
 1.1       cgd 		printf("%s:\t%d sectors in %d %s of %d tracks, %d sectors\n",
 1.1       cgd 		    fsys, sblock.fs_size * NSPF(&sblock), sblock.fs_ncyl,
 1.1       cgd 		    "cylinders", sblock.fs_ntrak, sblock.fs_nsect);
 1.9   mycroft #define B2MBFACTOR (1 / (1024.0 * 1024.0))
 1.1       cgd 		printf("\t%.1fMB in %d cyl groups (%d c/g, %.2fMB/g, %d i/g)\n",
 1.9   mycroft 		    (float)sblock.fs_size * sblock.fs_fsize * B2MBFACTOR,
 1.1       cgd 		    sblock.fs_ncg, sblock.fs_cpg,
 1.9   mycroft 		    (float)sblock.fs_fpg * sblock.fs_fsize * B2MBFACTOR,
 1.1       cgd 		    sblock.fs_ipg);
 1.9   mycroft #undef B2MBFACTOR
 1.1       cgd 	}
 1.1       cgd 	/*
 1.1       cgd 	 * Now build the cylinders group blocks and
 1.1       cgd 	 * then print out indices of cylinder groups.
 1.1       cgd 	 */
 1.1       cgd 	if (!mfs)
 1.1       cgd 		printf("super-block backups (for fsck -b #) at:");
 1.1       cgd 	for (cylno = 0; cylno < sblock.fs_ncg; cylno++) {
 1.1       cgd 		initcg(cylno, utime);
 1.1       cgd 		if (mfs)
 1.1       cgd 			continue;
1.11       cgd 		if (cylno % 8 == 0)
 1.1       cgd 			printf("\n");
1.27     lukem 		printf(" %d,", fsbtodb(&sblock, cgsblock(&sblock, cylno)));
1.22       jtc 		fflush(stdout);
 1.1       cgd 	}
 1.1       cgd 	if (!mfs)
 1.1       cgd 		printf("\n");
 1.1       cgd 	if (Nflag && !mfs)
 1.1       cgd 		exit(0);
 1.1       cgd 	/*
 1.1       cgd 	 * Now construct the initial file system,
 1.1       cgd 	 * then write out the super-block.
 1.1       cgd 	 */
 1.1       cgd 	fsinit(utime);
 1.1       cgd 	sblock.fs_time = utime;
1.30    bouyer 	memcpy(writebuf, &sblock, sbsize);
1.30    bouyer 	if (needswap)
1.30    bouyer 		ffs_sb_swap(&sblock, (struct fs*)writebuf, 1);
1.30    bouyer 	wtfs((int)SBOFF / sectorsize, sbsize, writebuf);
 1.1       cgd 	/*
 1.1       cgd 	 * Write out the duplicate super blocks
 1.1       cgd 	 */
 1.1       cgd 	for (cylno = 0; cylno < sblock.fs_ncg; cylno++)
 1.1       cgd 		wtfs(fsbtodb(&sblock, cgsblock(&sblock, cylno)),
1.30    bouyer 		    sbsize, writebuf);
1.30    bouyer 	if (needswap)
1.30    bouyer 		ffs_csum_swap(fscs, (struct csum*)writebuf, sblock.fs_cssize);
1.30    bouyer 	else
1.30    bouyer 		memcpy(writebuf, fscs, sblock.fs_cssize);
1.30    bouyer 	for (i = 0; i < sblock.fs_cssize; i += sblock.fs_bsize)
1.30    bouyer 		wtfs(fsbtodb(&sblock, sblock.fs_csaddr + numfrags(&sblock, i)),
1.30    bouyer 			sblock.fs_cssize - i < sblock.fs_bsize ?
1.30    bouyer 			    sblock.fs_cssize - i : sblock.fs_bsize,
1.30    bouyer 			((char *)writebuf) + i);
 1.1       cgd 	/*
 1.1       cgd 	 * Update information about this partion in pack
 1.1       cgd 	 * label, to that it may be updated on disk.
 1.1       cgd 	 */
 1.1       cgd 	pp->p_fstype = FS_BSDFFS;
 1.1       cgd 	pp->p_fsize = sblock.fs_fsize;
 1.1       cgd 	pp->p_frag = sblock.fs_frag;
 1.1       cgd 	pp->p_cpg = sblock.fs_cpg;
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * Initialize a cylinder group.
 1.1       cgd  */
1.26  christos void
 1.1       cgd initcg(cylno, utime)
 1.1       cgd 	int cylno;
 1.1       cgd 	time_t utime;
 1.1       cgd {
 1.9   mycroft 	daddr_t cbase, d, dlower, dupper, dmax, blkno;
1.27     lukem 	int32_t i;
1.26  christos 	struct csum *cs;
 1.1       cgd
 1.1       cgd 	/*
 1.1       cgd 	 * Determine block bounds for cylinder group.
 1.1       cgd 	 * Allow space for super block summary information in first
 1.1       cgd 	 * cylinder group.
 1.1       cgd 	 */
 1.1       cgd 	cbase = cgbase(&sblock, cylno);
 1.1       cgd 	dmax = cbase + sblock.fs_fpg;
 1.1       cgd 	if (dmax > sblock.fs_size)
 1.1       cgd 		dmax = sblock.fs_size;
 1.1       cgd 	dlower = cgsblock(&sblock, cylno) - cbase;
 1.1       cgd 	dupper = cgdmin(&sblock, cylno) - cbase;
 1.1       cgd 	if (cylno == 0)
 1.1       cgd 		dupper += howmany(sblock.fs_cssize, sblock.fs_fsize);
 1.1       cgd 	cs = fscs + cylno;
1.12   mycroft 	memset(&acg, 0, sblock.fs_cgsize);
 1.1       cgd 	acg.cg_time = utime;
 1.1       cgd 	acg.cg_magic = CG_MAGIC;
 1.1       cgd 	acg.cg_cgx = cylno;
 1.1       cgd 	if (cylno == sblock.fs_ncg - 1)
 1.1       cgd 		acg.cg_ncyl = sblock.fs_ncyl % sblock.fs_cpg;
 1.1       cgd 	else
 1.1       cgd 		acg.cg_ncyl = sblock.fs_cpg;
 1.1       cgd 	acg.cg_niblk = sblock.fs_ipg;
 1.1       cgd 	acg.cg_ndblk = dmax - cbase;
 1.9   mycroft 	if (sblock.fs_contigsumsize > 0)
 1.9   mycroft 		acg.cg_nclusterblks = acg.cg_ndblk / sblock.fs_frag;
1.15       cgd 	acg.cg_btotoff = &acg.cg_space[0] - (u_char *)(&acg.cg_firstfield);
1.14       cgd 	acg.cg_boff = acg.cg_btotoff + sblock.fs_cpg * sizeof(int32_t);
 1.1       cgd 	acg.cg_iusedoff = acg.cg_boff +
1.20       cgd 		sblock.fs_cpg * sblock.fs_nrpos * sizeof(int16_t);
 1.1       cgd 	acg.cg_freeoff = acg.cg_iusedoff + howmany(sblock.fs_ipg, NBBY);
 1.9   mycroft 	if (sblock.fs_contigsumsize <= 0) {
 1.9   mycroft 		acg.cg_nextfreeoff = acg.cg_freeoff +
 1.9   mycroft 		   howmany(sblock.fs_cpg * sblock.fs_spc / NSPF(&sblock), NBBY);
 1.9   mycroft 	} else {
 1.9   mycroft 		acg.cg_clustersumoff = acg.cg_freeoff + howmany
 1.9   mycroft 		    (sblock.fs_cpg * sblock.fs_spc / NSPF(&sblock), NBBY) -
1.14       cgd 		    sizeof(int32_t);
 1.9   mycroft 		acg.cg_clustersumoff =
1.14       cgd 		    roundup(acg.cg_clustersumoff, sizeof(int32_t));
 1.9   mycroft 		acg.cg_clusteroff = acg.cg_clustersumoff +
1.14       cgd 		    (sblock.fs_contigsumsize + 1) * sizeof(int32_t);
 1.9   mycroft 		acg.cg_nextfreeoff = acg.cg_clusteroff + howmany
 1.9   mycroft 		    (sblock.fs_cpg * sblock.fs_spc / NSPB(&sblock), NBBY);
 1.9   mycroft 	}
1.27     lukem 	if (acg.cg_nextfreeoff -
1.27     lukem 	    (int32_t)(&acg.cg_firstfield) > sblock.fs_cgsize) {
 1.9   mycroft 		printf("Panic: cylinder group too big\n");
 1.9   mycroft 		exit(37);
 1.1       cgd 	}
 1.1       cgd 	acg.cg_cs.cs_nifree += sblock.fs_ipg;
 1.1       cgd 	if (cylno == 0)
 1.1       cgd 		for (i = 0; i < ROOTINO; i++) {
1.30    bouyer 			setbit(cg_inosused(&acg, 0), i);
 1.1       cgd 			acg.cg_cs.cs_nifree--;
 1.1       cgd 		}
 1.1       cgd 	for (i = 0; i < sblock.fs_ipg / INOPF(&sblock); i += sblock.fs_frag)
 1.1       cgd 		wtfs(fsbtodb(&sblock, cgimin(&sblock, cylno) + i),
 1.1       cgd 		    sblock.fs_bsize, (char *)zino);
 1.1       cgd 	if (cylno > 0) {
 1.1       cgd 		/*
 1.1       cgd 		 * In cylno 0, beginning space is reserved
 1.1       cgd 		 * for boot and super blocks.
 1.1       cgd 		 */
 1.1       cgd 		for (d = 0; d < dlower; d += sblock.fs_frag) {
 1.9   mycroft 			blkno = d / sblock.fs_frag;
1.30    bouyer 			setblock(&sblock, cg_blksfree(&acg, 0), blkno);
 1.9   mycroft 			if (sblock.fs_contigsumsize > 0)
1.30    bouyer 				setbit(cg_clustersfree(&acg, 0), blkno);
 1.1       cgd 			acg.cg_cs.cs_nbfree++;
1.30    bouyer 			cg_blktot(&acg, 0)[cbtocylno(&sblock, d)]++;
1.30    bouyer 			cg_blks(&sblock, &acg, cbtocylno(&sblock, d), 0)
 1.1       cgd 			    [cbtorpos(&sblock, d)]++;
 1.1       cgd 		}
 1.1       cgd 		sblock.fs_dsize += dlower;
 1.1       cgd 	}
 1.1       cgd 	sblock.fs_dsize += acg.cg_ndblk - dupper;
1.26  christos 	if ((i = (dupper % sblock.fs_frag)) != 0) {
 1.1       cgd 		acg.cg_frsum[sblock.fs_frag - i]++;
 1.1       cgd 		for (d = dupper + sblock.fs_frag - i; dupper < d; dupper++) {
1.30    bouyer 			setbit(cg_blksfree(&acg, 0), dupper);
 1.1       cgd 			acg.cg_cs.cs_nffree++;
 1.1       cgd 		}
 1.1       cgd 	}
 1.1       cgd 	for (d = dupper; d + sblock.fs_frag <= dmax - cbase; ) {
 1.9   mycroft 		blkno = d / sblock.fs_frag;
1.30    bouyer 		setblock(&sblock, cg_blksfree(&acg, 0), blkno);
 1.9   mycroft 		if (sblock.fs_contigsumsize > 0)
1.30    bouyer 			setbit(cg_clustersfree(&acg, 0), blkno);
 1.1       cgd 		acg.cg_cs.cs_nbfree++;
1.30    bouyer 		cg_blktot(&acg, 0)[cbtocylno(&sblock, d)]++;
1.30    bouyer 		cg_blks(&sblock, &acg, cbtocylno(&sblock, d), 0)
 1.1       cgd 		    [cbtorpos(&sblock, d)]++;
 1.1       cgd 		d += sblock.fs_frag;
 1.1       cgd 	}
 1.1       cgd 	if (d < dmax - cbase) {
 1.1       cgd 		acg.cg_frsum[dmax - cbase - d]++;
 1.1       cgd 		for (; d < dmax - cbase; d++) {
1.30    bouyer 			setbit(cg_blksfree(&acg, 0), d);
 1.1       cgd 			acg.cg_cs.cs_nffree++;
 1.1       cgd 		}
 1.1       cgd 	}
 1.9   mycroft 	if (sblock.fs_contigsumsize > 0) {
1.30    bouyer 		int32_t *sump = cg_clustersum(&acg, 0);
1.30    bouyer 		u_char *mapp = cg_clustersfree(&acg, 0);
 1.9   mycroft 		int map = *mapp++;
 1.9   mycroft 		int bit = 1;
 1.9   mycroft 		int run = 0;
 1.9   mycroft
 1.9   mycroft 		for (i = 0; i < acg.cg_nclusterblks; i++) {
 1.9   mycroft 			if ((map & bit) != 0) {
 1.9   mycroft 				run++;
 1.9   mycroft 			} else if (run != 0) {
 1.9   mycroft 				if (run > sblock.fs_contigsumsize)
 1.9   mycroft 					run = sblock.fs_contigsumsize;
 1.9   mycroft 				sump[run]++;
 1.9   mycroft 				run = 0;
 1.9   mycroft 			}
 1.9   mycroft 			if ((i & (NBBY - 1)) != (NBBY - 1)) {
 1.9   mycroft 				bit <<= 1;
 1.9   mycroft 			} else {
 1.9   mycroft 				map = *mapp++;
 1.9   mycroft 				bit = 1;
 1.9   mycroft 			}
 1.9   mycroft 		}
 1.9   mycroft 		if (run != 0) {
 1.9   mycroft 			if (run > sblock.fs_contigsumsize)
 1.9   mycroft 				run = sblock.fs_contigsumsize;
 1.9   mycroft 			sump[run]++;
 1.9   mycroft 		}
 1.9   mycroft 	}
 1.1       cgd 	sblock.fs_cstotal.cs_ndir += acg.cg_cs.cs_ndir;
 1.1       cgd 	sblock.fs_cstotal.cs_nffree += acg.cg_cs.cs_nffree;
 1.1       cgd 	sblock.fs_cstotal.cs_nbfree += acg.cg_cs.cs_nbfree;
 1.1       cgd 	sblock.fs_cstotal.cs_nifree += acg.cg_cs.cs_nifree;
 1.1       cgd 	*cs = acg.cg_cs;
1.30    bouyer 	memcpy(writebuf, &acg, sblock.fs_bsize);
1.30    bouyer 	if (needswap)
1.30    bouyer 		swap_cg(&acg, (struct cg*)writebuf);
 1.1       cgd 	wtfs(fsbtodb(&sblock, cgtod(&sblock, cylno)),
1.30    bouyer 		sblock.fs_bsize, writebuf);
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * initialize the file system
 1.1       cgd  */
 1.1       cgd struct dinode node;
 1.1       cgd
 1.1       cgd #ifdef LOSTDIR
 1.1       cgd #define PREDEFDIR 3
 1.1       cgd #else
 1.1       cgd #define PREDEFDIR 2
 1.1       cgd #endif
 1.1       cgd
 1.1       cgd struct direct root_dir[] = {
 1.9   mycroft 	{ ROOTINO, sizeof(struct direct), DT_DIR, 1, "." },
 1.9   mycroft 	{ ROOTINO, sizeof(struct direct), DT_DIR, 2, ".." },
 1.9   mycroft #ifdef LOSTDIR
 1.9   mycroft 	{ LOSTFOUNDINO, sizeof(struct direct), DT_DIR, 10, "lost+found" },
 1.9   mycroft #endif
 1.9   mycroft };
 1.9   mycroft struct odirect {
1.14       cgd 	u_int32_t d_ino;
1.14       cgd 	u_int16_t d_reclen;
1.14       cgd 	u_int16_t d_namlen;
 1.9   mycroft 	u_char	d_name[MAXNAMLEN + 1];
 1.9   mycroft } oroot_dir[] = {
 1.1       cgd 	{ ROOTINO, sizeof(struct direct), 1, "." },
 1.1       cgd 	{ ROOTINO, sizeof(struct direct), 2, ".." },
 1.1       cgd #ifdef LOSTDIR
 1.1       cgd 	{ LOSTFOUNDINO, sizeof(struct direct), 10, "lost+found" },
 1.1       cgd #endif
 1.1       cgd };
 1.1       cgd #ifdef LOSTDIR
 1.1       cgd struct direct lost_found_dir[] = {
 1.9   mycroft 	{ LOSTFOUNDINO, sizeof(struct direct), DT_DIR, 1, "." },
 1.9   mycroft 	{ ROOTINO, sizeof(struct direct), DT_DIR, 2, ".." },
 1.9   mycroft 	{ 0, DIRBLKSIZ, 0, 0, 0 },
 1.9   mycroft };
 1.9   mycroft struct odirect olost_found_dir[] = {
 1.1       cgd 	{ LOSTFOUNDINO, sizeof(struct direct), 1, "." },
 1.1       cgd 	{ ROOTINO, sizeof(struct direct), 2, ".." },
 1.1       cgd 	{ 0, DIRBLKSIZ, 0, 0 },
 1.1       cgd };
 1.1       cgd #endif
 1.1       cgd char buf[MAXBSIZE];
1.30    bouyer static void copy_dir __P((struct direct *, struct direct *));
 1.1       cgd
1.26  christos void
 1.1       cgd fsinit(utime)
 1.1       cgd 	time_t utime;
 1.1       cgd {
1.26  christos #ifdef LOSTDIR
 1.1       cgd 	int i;
1.26  christos #endif
 1.1       cgd
 1.1       cgd 	/*
 1.1       cgd 	 * initialize the node
 1.1       cgd 	 */
1.25       cgd 	node.di_atime = utime;
1.25       cgd 	node.di_mtime = utime;
1.25       cgd 	node.di_ctime = utime;
1.30    bouyer
 1.1       cgd #ifdef LOSTDIR
 1.1       cgd 	/*
 1.1       cgd 	 * create the lost+found directory
 1.1       cgd 	 */
 1.9   mycroft 	if (Oflag) {
 1.9   mycroft 		(void)makedir((struct direct *)olost_found_dir, 2);
 1.9   mycroft 		for (i = DIRBLKSIZ; i < sblock.fs_bsize; i += DIRBLKSIZ)
1.30    bouyer 			copy_dir((struct direct*)&olost_found_dir[2],
1.30    bouyer 				(struct direct*)&buf[i]);
 1.9   mycroft 	} else {
 1.9   mycroft 		(void)makedir(lost_found_dir, 2);
 1.9   mycroft 		for (i = DIRBLKSIZ; i < sblock.fs_bsize; i += DIRBLKSIZ)
1.30    bouyer 			copy_dir(&lost_found_dir[2], (struct direct*)&buf[i]);
 1.9   mycroft 	}
 1.1       cgd 	node.di_mode = IFDIR | UMASK;
 1.1       cgd 	node.di_nlink = 2;
 1.1       cgd 	node.di_size = sblock.fs_bsize;
 1.1       cgd 	node.di_db[0] = alloc(node.di_size, node.di_mode);
 1.1       cgd 	node.di_blocks = btodb(fragroundup(&sblock, node.di_size));
 1.1       cgd 	wtfs(fsbtodb(&sblock, node.di_db[0]), node.di_size, buf);
 1.1       cgd 	iput(&node, LOSTFOUNDINO);
 1.1       cgd #endif
 1.1       cgd 	/*
 1.1       cgd 	 * create the root directory
 1.1       cgd 	 */
 1.1       cgd 	if (mfs)
 1.1       cgd 		node.di_mode = IFDIR | 01777;
 1.1       cgd 	else
 1.1       cgd 		node.di_mode = IFDIR | UMASK;
 1.1       cgd 	node.di_nlink = PREDEFDIR;
 1.9   mycroft 	if (Oflag)
 1.9   mycroft 		node.di_size = makedir((struct direct *)oroot_dir, PREDEFDIR);
 1.9   mycroft 	else
 1.9   mycroft 		node.di_size = makedir(root_dir, PREDEFDIR);
 1.1       cgd 	node.di_db[0] = alloc(sblock.fs_fsize, node.di_mode);
 1.1       cgd 	node.di_blocks = btodb(fragroundup(&sblock, node.di_size));
 1.1       cgd 	wtfs(fsbtodb(&sblock, node.di_db[0]), sblock.fs_fsize, buf);
 1.1       cgd 	iput(&node, ROOTINO);
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * construct a set of directory entries in "buf".
 1.1       cgd  * return size of directory.
 1.1       cgd  */
1.26  christos int
 1.1       cgd makedir(protodir, entries)
1.26  christos 	struct direct *protodir;
 1.1       cgd 	int entries;
 1.1       cgd {
 1.1       cgd 	char *cp;
 1.1       cgd 	int i, spcleft;
 1.1       cgd
 1.1       cgd 	spcleft = DIRBLKSIZ;
 1.1       cgd 	for (cp = buf, i = 0; i < entries - 1; i++) {
1.30    bouyer 		protodir[i].d_reclen = DIRSIZ(Oflag, &protodir[i], 0);
1.30    bouyer 		copy_dir(&protodir[i], (struct direct*)cp);
 1.1       cgd 		cp += protodir[i].d_reclen;
 1.1       cgd 		spcleft -= protodir[i].d_reclen;
 1.1       cgd 	}
 1.1       cgd 	protodir[i].d_reclen = spcleft;
1.30    bouyer 	copy_dir(&protodir[i], (struct direct*)cp);
 1.1       cgd 	return (DIRBLKSIZ);
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * allocate a block or frag
 1.1       cgd  */
 1.1       cgd daddr_t
 1.1       cgd alloc(size, mode)
 1.1       cgd 	int size;
 1.1       cgd 	int mode;
 1.1       cgd {
 1.1       cgd 	int i, frag;
 1.9   mycroft 	daddr_t d, blkno;
 1.1       cgd
1.26  christos 	rdfs(fsbtodb(&sblock, cgtod(&sblock, 0)), sblock.fs_cgsize, &acg);
1.30    bouyer 	/* fs -> host byte order */
1.30    bouyer 	if (needswap)
1.30    bouyer 		swap_cg(&acg, &acg);
 1.1       cgd 	if (acg.cg_magic != CG_MAGIC) {
 1.1       cgd 		printf("cg 0: bad magic number\n");
 1.1       cgd 		return (0);
 1.1       cgd 	}
 1.1       cgd 	if (acg.cg_cs.cs_nbfree == 0) {
 1.1       cgd 		printf("first cylinder group ran out of space\n");
 1.1       cgd 		return (0);
 1.1       cgd 	}
 1.1       cgd 	for (d = 0; d < acg.cg_ndblk; d += sblock.fs_frag)
1.30    bouyer 		if (isblock(&sblock, cg_blksfree(&acg, 0), d / sblock.fs_frag))
 1.1       cgd 			goto goth;
 1.1       cgd 	printf("internal error: can't find block in cyl 0\n");
 1.1       cgd 	return (0);
 1.1       cgd goth:
 1.9   mycroft 	blkno = fragstoblks(&sblock, d);
1.30    bouyer 	clrblock(&sblock, cg_blksfree(&acg, 0), blkno);
1.10       cgd 	if (sblock.fs_contigsumsize > 0)
1.30    bouyer 		clrbit(cg_clustersfree(&acg, 0), blkno);
 1.1       cgd 	acg.cg_cs.cs_nbfree--;
 1.1       cgd 	sblock.fs_cstotal.cs_nbfree--;
 1.1       cgd 	fscs[0].cs_nbfree--;
 1.1       cgd 	if (mode & IFDIR) {
 1.1       cgd 		acg.cg_cs.cs_ndir++;
 1.1       cgd 		sblock.fs_cstotal.cs_ndir++;
 1.1       cgd 		fscs[0].cs_ndir++;
 1.1       cgd 	}
1.30    bouyer 	cg_blktot(&acg, 0)[cbtocylno(&sblock, d)]--;
1.30    bouyer 	cg_blks(&sblock, &acg, cbtocylno(&sblock, d), 0)[cbtorpos(&sblock, d)]--;
 1.1       cgd 	if (size != sblock.fs_bsize) {
 1.1       cgd 		frag = howmany(size, sblock.fs_fsize);
 1.1       cgd 		fscs[0].cs_nffree += sblock.fs_frag - frag;
 1.1       cgd 		sblock.fs_cstotal.cs_nffree += sblock.fs_frag - frag;
 1.1       cgd 		acg.cg_cs.cs_nffree += sblock.fs_frag - frag;
 1.1       cgd 		acg.cg_frsum[sblock.fs_frag - frag]++;
 1.1       cgd 		for (i = frag; i < sblock.fs_frag; i++)
1.30    bouyer 			setbit(cg_blksfree(&acg, 0), d + i);
 1.1       cgd 	}
1.30    bouyer 	/* host -> fs byte order */
1.30    bouyer 	if (needswap)
1.30    bouyer 		swap_cg(&acg, &acg);
 1.1       cgd 	wtfs(fsbtodb(&sblock, cgtod(&sblock, 0)), sblock.fs_cgsize,
 1.1       cgd 	    (char *)&acg);
 1.1       cgd 	return (d);
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
1.27     lukem  * Calculate number of inodes per group.
1.27     lukem  */
1.27     lukem int32_t
1.27     lukem calcipg(cpg, bpcg, usedbp)
1.27     lukem 	int32_t cpg;
1.27     lukem 	int32_t bpcg;
1.27     lukem 	off_t *usedbp;
1.27     lukem {
1.27     lukem 	int i;
1.27     lukem 	int32_t ipg, new_ipg, ncg, ncyl;
1.27     lukem 	off_t usedb;
1.28    jeremy #if __GNUC__ /* XXX work around gcc 2.7.2 initialization bug */
1.28    jeremy 	(void)&usedb;
1.28    jeremy #endif
1.27     lukem
1.27     lukem 	/*
1.27     lukem 	 * Prepare to scale by fssize / (number of sectors in cylinder groups).
1.27     lukem 	 * Note that fssize is still in sectors, not filesystem blocks.
1.27     lukem 	 */
1.27     lukem 	ncyl = howmany(fssize, secpercyl);
1.27     lukem 	ncg = howmany(ncyl, cpg);
1.27     lukem 	/*
1.27     lukem 	 * Iterate a few times to allow for ipg depending on itself.
1.27     lukem 	 */
1.27     lukem 	ipg = 0;
1.27     lukem 	for (i = 0; i < 10; i++) {
1.27     lukem 		usedb = (sblock.fs_iblkno + ipg / INOPF(&sblock))
1.27     lukem 			* NSPF(&sblock) * (off_t)sectorsize;
1.27     lukem 		new_ipg = (cpg * (quad_t)bpcg - usedb) / density * fssize
1.27     lukem 			  / ncg / secpercyl / cpg;
1.27     lukem 		new_ipg = roundup(new_ipg, INOPB(&sblock));
1.27     lukem 		if (new_ipg == ipg)
1.27     lukem 			break;
1.27     lukem 		ipg = new_ipg;
1.27     lukem 	}
1.27     lukem 	*usedbp = usedb;
1.27     lukem 	return (ipg);
1.27     lukem }
1.27     lukem
1.27     lukem /*
 1.1       cgd  * Allocate an inode on the disk
 1.1       cgd  */
1.26  christos static void
 1.1       cgd iput(ip, ino)
1.26  christos 	struct dinode *ip;
1.26  christos 	ino_t ino;
 1.1       cgd {
 1.1       cgd 	struct dinode buf[MAXINOPB];
 1.1       cgd 	daddr_t d;
1.30    bouyer 	int c, i;
 1.1       cgd
 1.9   mycroft 	c = ino_to_cg(&sblock, ino);
1.26  christos 	rdfs(fsbtodb(&sblock, cgtod(&sblock, 0)), sblock.fs_cgsize, &acg);
1.30    bouyer 	/* fs -> host byte order */
1.30    bouyer 	if (needswap)
1.30    bouyer 		swap_cg(&acg, &acg);
 1.1       cgd 	if (acg.cg_magic != CG_MAGIC) {
 1.1       cgd 		printf("cg 0: bad magic number\n");
 1.1       cgd 		exit(31);
 1.1       cgd 	}
 1.1       cgd 	acg.cg_cs.cs_nifree--;
1.30    bouyer 	setbit(cg_inosused(&acg, 0), ino);
1.30    bouyer 	/* host -> fs byte order */
1.30    bouyer 	if (needswap)
1.30    bouyer 		swap_cg(&acg, &acg);
 1.1       cgd 	wtfs(fsbtodb(&sblock, cgtod(&sblock, 0)), sblock.fs_cgsize,
 1.1       cgd 	    (char *)&acg);
 1.1       cgd 	sblock.fs_cstotal.cs_nifree--;
 1.1       cgd 	fscs[0].cs_nifree--;
 1.1       cgd 	if (ino >= sblock.fs_ipg * sblock.fs_ncg) {
 1.1       cgd 		printf("fsinit: inode value out of range (%d).\n", ino);
 1.1       cgd 		exit(32);
 1.1       cgd 	}
 1.9   mycroft 	d = fsbtodb(&sblock, ino_to_fsba(&sblock, ino));
 1.1       cgd 	rdfs(d, sblock.fs_bsize, buf);
1.30    bouyer 	if (needswap) {
1.30    bouyer 		ffs_dinode_swap(ip, (struct dinode*)&buf[ino_to_fsbo(&sblock, ino)]);
1.30    bouyer 		/* ffs_dinode_swap() doesn't swap blocks addrs */
1.30    bouyer 		for (i=0; i<NDADDR + NIADDR; i++)
1.30    bouyer 			((struct dinode*)&buf[ino_to_fsbo(&sblock, ino)])->di_db[i] =
1.30    bouyer 				bswap32(ip->di_db[i]);
1.30    bouyer 	} else
1.30    bouyer 		buf[ino_to_fsbo(&sblock, ino)] = *ip;
 1.1       cgd 	wtfs(d, sblock.fs_bsize, buf);
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * Replace libc function with one suited to our needs.
 1.1       cgd  */
1.26  christos void *
 1.1       cgd malloc(size)
1.26  christos 	size_t size;
 1.1       cgd {
 1.9   mycroft 	char *base, *i;
 1.1       cgd 	static u_long pgsz;
 1.1       cgd 	struct rlimit rlp;
 1.1       cgd
 1.1       cgd 	if (pgsz == 0) {
 1.1       cgd 		base = sbrk(0);
 1.1       cgd 		pgsz = getpagesize() - 1;
 1.9   mycroft 		i = (char *)((u_long)(base + pgsz) &~ pgsz);
 1.1       cgd 		base = sbrk(i - base);
 1.1       cgd 		if (getrlimit(RLIMIT_DATA, &rlp) < 0)
 1.1       cgd 			perror("getrlimit");
 1.1       cgd 		rlp.rlim_cur = rlp.rlim_max;
 1.1       cgd 		if (setrlimit(RLIMIT_DATA, &rlp) < 0)
 1.1       cgd 			perror("setrlimit");
 1.9   mycroft 		memleft = rlp.rlim_max - (u_long)base;
 1.1       cgd 	}
 1.1       cgd 	size = (size + pgsz) &~ pgsz;
 1.1       cgd 	if (size > memleft)
 1.1       cgd 		size = memleft;
 1.1       cgd 	memleft -= size;
 1.1       cgd 	if (size == 0)
 1.1       cgd 		return (0);
 1.1       cgd 	return ((caddr_t)sbrk(size));
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * Replace libc function with one suited to our needs.
 1.1       cgd  */
1.26  christos void *
 1.1       cgd realloc(ptr, size)
1.26  christos 	void *ptr;
1.26  christos 	size_t size;
 1.1       cgd {
 1.9   mycroft 	void *p;
 1.1       cgd
 1.9   mycroft 	if ((p = malloc(size)) == NULL)
 1.9   mycroft 		return (NULL);
1.27     lukem 	memmove(p, ptr, size);
 1.9   mycroft 	free(ptr);
 1.9   mycroft 	return (p);
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * Replace libc function with one suited to our needs.
 1.1       cgd  */
1.26  christos void *
 1.1       cgd calloc(size, numelm)
1.26  christos 	size_t size, numelm;
 1.1       cgd {
1.26  christos 	void *base;
 1.1       cgd
 1.1       cgd 	size *= numelm;
 1.1       cgd 	base = malloc(size);
1.12   mycroft 	memset(base, 0, size);
1.27     lukem 	return (base);
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * Replace libc function with one suited to our needs.
 1.1       cgd  */
1.26  christos void
 1.1       cgd free(ptr)
1.26  christos 	void *ptr;
 1.1       cgd {
 1.1       cgd
 1.1       cgd 	/* do not worry about it for now */
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * read a block from the file system
 1.1       cgd  */
1.26  christos void
 1.1       cgd rdfs(bno, size, bf)
 1.1       cgd 	daddr_t bno;
 1.1       cgd 	int size;
1.26  christos 	void *bf;
 1.1       cgd {
 1.1       cgd 	int n;
1.18       cgd 	off_t offset;
 1.1       cgd
 1.1       cgd 	if (mfs) {
1.27     lukem 		memmove(bf, membase + bno * sectorsize, size);
 1.1       cgd 		return;
 1.1       cgd 	}
1.18       cgd 	offset = bno;
1.18       cgd 	offset *= sectorsize;
1.18       cgd 	if (lseek(fsi, offset, SEEK_SET) < 0) {
1.26  christos 		printf("seek error: %d\n", bno);
 1.1       cgd 		perror("rdfs");
 1.1       cgd 		exit(33);
 1.1       cgd 	}
 1.1       cgd 	n = read(fsi, bf, size);
 1.9   mycroft 	if (n != size) {
1.26  christos 		printf("read error: %d\n", bno);
 1.1       cgd 		perror("rdfs");
 1.1       cgd 		exit(34);
 1.1       cgd 	}
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * write a block to the file system
 1.1       cgd  */
1.26  christos void
 1.1       cgd wtfs(bno, size, bf)
 1.1       cgd 	daddr_t bno;
 1.1       cgd 	int size;
1.26  christos 	void *bf;
 1.1       cgd {
 1.1       cgd 	int n;
1.18       cgd 	off_t offset;
 1.1       cgd
 1.1       cgd 	if (mfs) {
1.27     lukem 		memmove(membase + bno * sectorsize, bf, size);
 1.1       cgd 		return;
 1.1       cgd 	}
 1.1       cgd 	if (Nflag)
 1.1       cgd 		return;
1.18       cgd 	offset = bno;
1.18       cgd 	offset *= sectorsize;
1.18       cgd 	if (lseek(fso, offset, SEEK_SET) < 0) {
1.26  christos 		printf("seek error: %d\n", bno);
 1.1       cgd 		perror("wtfs");
 1.1       cgd 		exit(35);
 1.1       cgd 	}
 1.1       cgd 	n = write(fso, bf, size);
 1.9   mycroft 	if (n != size) {
1.26  christos 		printf("write error: %d\n", bno);
 1.1       cgd 		perror("wtfs");
 1.1       cgd 		exit(36);
 1.1       cgd 	}
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * check if a block is available
 1.1       cgd  */
1.26  christos int
 1.1       cgd isblock(fs, cp, h)
 1.1       cgd 	struct fs *fs;
 1.1       cgd 	unsigned char *cp;
 1.1       cgd 	int h;
 1.1       cgd {
 1.1       cgd 	unsigned char mask;
 1.1       cgd
 1.1       cgd 	switch (fs->fs_frag) {
 1.1       cgd 	case 8:
 1.1       cgd 		return (cp[h] == 0xff);
 1.1       cgd 	case 4:
 1.1       cgd 		mask = 0x0f << ((h & 0x1) << 2);
 1.1       cgd 		return ((cp[h >> 1] & mask) == mask);
 1.1       cgd 	case 2:
 1.1       cgd 		mask = 0x03 << ((h & 0x3) << 1);
 1.1       cgd 		return ((cp[h >> 2] & mask) == mask);
 1.1       cgd 	case 1:
 1.1       cgd 		mask = 0x01 << (h & 0x7);
 1.1       cgd 		return ((cp[h >> 3] & mask) == mask);
 1.1       cgd 	default:
 1.1       cgd #ifdef STANDALONE
 1.1       cgd 		printf("isblock bad fs_frag %d\n", fs->fs_frag);
 1.1       cgd #else
 1.1       cgd 		fprintf(stderr, "isblock bad fs_frag %d\n", fs->fs_frag);
 1.1       cgd #endif
 1.1       cgd 		return (0);
 1.1       cgd 	}
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * take a block out of the map
 1.1       cgd  */
1.26  christos void
 1.1       cgd clrblock(fs, cp, h)
 1.1       cgd 	struct fs *fs;
 1.1       cgd 	unsigned char *cp;
 1.1       cgd 	int h;
 1.1       cgd {
 1.1       cgd 	switch ((fs)->fs_frag) {
 1.1       cgd 	case 8:
 1.1       cgd 		cp[h] = 0;
 1.1       cgd 		return;
 1.1       cgd 	case 4:
 1.1       cgd 		cp[h >> 1] &= ~(0x0f << ((h & 0x1) << 2));
 1.1       cgd 		return;
 1.1       cgd 	case 2:
 1.1       cgd 		cp[h >> 2] &= ~(0x03 << ((h & 0x3) << 1));
 1.1       cgd 		return;
 1.1       cgd 	case 1:
 1.1       cgd 		cp[h >> 3] &= ~(0x01 << (h & 0x7));
 1.1       cgd 		return;
 1.1       cgd 	default:
 1.1       cgd #ifdef STANDALONE
 1.1       cgd 		printf("clrblock bad fs_frag %d\n", fs->fs_frag);
 1.1       cgd #else
 1.1       cgd 		fprintf(stderr, "clrblock bad fs_frag %d\n", fs->fs_frag);
 1.1       cgd #endif
 1.1       cgd 		return;
 1.1       cgd 	}
 1.1       cgd }
 1.1       cgd
 1.1       cgd /*
 1.1       cgd  * put a block into the map
 1.1       cgd  */
1.26  christos void
 1.1       cgd setblock(fs, cp, h)
 1.1       cgd 	struct fs *fs;
 1.1       cgd 	unsigned char *cp;
 1.1       cgd 	int h;
 1.1       cgd {
 1.1       cgd 	switch (fs->fs_frag) {
 1.1       cgd 	case 8:
 1.1       cgd 		cp[h] = 0xff;
 1.1       cgd 		return;
 1.1       cgd 	case 4:
 1.1       cgd 		cp[h >> 1] |= (0x0f << ((h & 0x1) << 2));
 1.1       cgd 		return;
 1.1       cgd 	case 2:
 1.1       cgd 		cp[h >> 2] |= (0x03 << ((h & 0x3) << 1));
 1.1       cgd 		return;
 1.1       cgd 	case 1:
 1.1       cgd 		cp[h >> 3] |= (0x01 << (h & 0x7));
 1.1       cgd 		return;
 1.1       cgd 	default:
 1.1       cgd #ifdef STANDALONE
 1.1       cgd 		printf("setblock bad fs_frag %d\n", fs->fs_frag);
 1.1       cgd #else
 1.1       cgd 		fprintf(stderr, "setblock bad fs_frag %d\n", fs->fs_frag);
 1.1       cgd #endif
 1.1       cgd 		return;
1.30    bouyer 	}
1.30    bouyer }
1.30    bouyer
1.30    bouyer /* swap byte order of cylinder group */
1.30    bouyer static void
1.30    bouyer swap_cg(o, n)
1.30    bouyer 	struct cg *o, *n;
1.30    bouyer {
1.30    bouyer 	int i, btotsize, fbsize;
1.30    bouyer 	u_int32_t *n32, *o32;
1.30    bouyer 	u_int16_t *n16, *o16;
1.30    bouyer
1.30    bouyer 	n->cg_firstfield = bswap32(o->cg_firstfield);
1.30    bouyer 	n->cg_magic = bswap32(o->cg_magic);
1.30    bouyer 	n->cg_time = bswap32(o->cg_time);
1.30    bouyer 	n->cg_cgx = bswap32(o->cg_cgx);
1.30    bouyer 	n->cg_ncyl = bswap16(o->cg_ncyl);
1.30    bouyer 	n->cg_niblk = bswap16(o->cg_niblk);
1.30    bouyer 	n->cg_ndblk = bswap32(o->cg_ndblk);
1.30    bouyer 	n->cg_cs.cs_ndir = bswap32(o->cg_cs.cs_ndir);
1.30    bouyer 	n->cg_cs.cs_nbfree = bswap32(o->cg_cs.cs_nbfree);
1.30    bouyer 	n->cg_cs.cs_nifree = bswap32(o->cg_cs.cs_nifree);
1.30    bouyer 	n->cg_cs.cs_nffree = bswap32(o->cg_cs.cs_nffree);
1.30    bouyer 	n->cg_rotor = bswap32(o->cg_rotor);
1.30    bouyer 	n->cg_frotor = bswap32(o->cg_frotor);
1.30    bouyer 	n->cg_irotor = bswap32(o->cg_irotor);
1.30    bouyer 	n->cg_btotoff = bswap32(o->cg_btotoff);
1.30    bouyer 	n->cg_boff = bswap32(o->cg_boff);
1.30    bouyer 	n->cg_iusedoff = bswap32(o->cg_iusedoff);
1.30    bouyer 	n->cg_freeoff = bswap32(o->cg_freeoff);
1.30    bouyer 	n->cg_nextfreeoff = bswap32(o->cg_nextfreeoff);
1.30    bouyer 	n->cg_clustersumoff = bswap32(o->cg_clustersumoff);
1.30    bouyer 	n->cg_clusteroff = bswap32(o->cg_clusteroff);
1.30    bouyer 	n->cg_nclusterblks = bswap32(o->cg_nclusterblks);
1.30    bouyer 	for (i=0; i < MAXFRAG; i++)
1.30    bouyer 		n->cg_frsum[i] = bswap32(o->cg_frsum[i]);
1.30    bouyer
1.30    bouyer 	/* alays new format */
1.30    bouyer 	if (n->cg_magic == CG_MAGIC) {
1.30    bouyer 		btotsize = n->cg_boff - n->cg_btotoff;
1.30    bouyer 		fbsize = n->cg_iusedoff - n->cg_boff;
1.30    bouyer 		n32 = (u_int32_t*)((u_int8_t*)n + n->cg_btotoff);
1.30    bouyer 		o32 = (u_int32_t*)((u_int8_t*)o + n->cg_btotoff);
1.30    bouyer 		n16 = (u_int16_t*)((u_int8_t*)n + n->cg_boff);
1.30    bouyer 		o16 = (u_int16_t*)((u_int8_t*)o + n->cg_boff);
1.30    bouyer 	} else {
1.30    bouyer 		btotsize = bswap32(n->cg_boff) - bswap32(n->cg_btotoff);
1.30    bouyer 		fbsize = bswap32(n->cg_iusedoff) - bswap32(n->cg_boff);
1.30    bouyer 		n32 = (u_int32_t*)((u_int8_t*)n + bswap32(n->cg_btotoff));
1.30    bouyer 		o32 = (u_int32_t*)((u_int8_t*)o + bswap32(n->cg_btotoff));
1.30    bouyer 		n16 = (u_int16_t*)((u_int8_t*)n + bswap32(n->cg_boff));
1.30    bouyer 		o16 = (u_int16_t*)((u_int8_t*)o + bswap32(n->cg_boff));
1.30    bouyer 	}
1.30    bouyer 	for (i=0; i < btotsize / sizeof(u_int32_t); i++)
1.30    bouyer 		n32[i] = bswap32(o32[i]);
1.30    bouyer
1.30    bouyer 	for (i=0; i < fbsize/sizeof(u_int16_t); i++)
1.30    bouyer 		n16[i] = bswap16(o16[i]);
1.30    bouyer
1.30    bouyer 	if (n->cg_magic == CG_MAGIC) {
1.30    bouyer 		n32 = (u_int32_t*)((u_int8_t*)n + n->cg_clustersumoff);
1.30    bouyer 		o32 = (u_int32_t*)((u_int8_t*)o + n->cg_clustersumoff);
1.30    bouyer 	} else {
1.30    bouyer 		n32 = (u_int32_t*)((u_int8_t*)n + bswap32(n->cg_clustersumoff));
1.30    bouyer 		o32 = (u_int32_t*)((u_int8_t*)o + bswap32(n->cg_clustersumoff));
1.30    bouyer 	}
1.30    bouyer 	for (i = 0; i < sblock.fs_contigsumsize + 1; i++)
1.30    bouyer 		n32[i] = bswap32(o32[i]);
1.30    bouyer }
1.30    bouyer
1.30    bouyer /* copy a direntry to a buffer, in fs byte order */
1.30    bouyer static void
1.30    bouyer copy_dir(dir, dbuf)
1.30    bouyer 	struct direct *dir;
1.30    bouyer 	struct direct *dbuf;
1.30    bouyer {
1.30    bouyer 	memcpy(dbuf, dir, DIRSIZ(Oflag, dir, 0));
1.30    bouyer 	if (needswap) {
1.30    bouyer 		dbuf->d_ino = bswap32(dir->d_ino);
1.30    bouyer 		dbuf->d_reclen = bswap16(dir->d_reclen);
1.30    bouyer 		if (Oflag)
1.30    bouyer 			((struct odirect*)dbuf)->d_namlen =
1.30    bouyer 				bswap16(((struct odirect*)dir)->d_namlen);
 1.1       cgd 	}
 1.1       cgd }