/* * Copyright (c) 1987, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * Symmetric Computer Systems. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #ifndef lint static const char copyright[] = "@(#) Copyright (c) 1987, 1993\n\ The Regents of the University of California. All rights reserved.\n"; #endif /* not lint */ #ifndef lint #if 0 static char sccsid[] = "@(#)disklabel.c 8.2 (Berkeley) 1/7/94"; /* from static char sccsid[] = "@(#)disklabel.c 1.2 (Symmetric) 11/28/85"; */ #endif static const char rcsid[] = "$FreeBSD$"; #endif /* not lint */ #include #include #include #include #define DKTYPENAMES #include #include #include #include #include #include #include #include #include #include #include #include "pathnames.h" /* * Disklabel: read and write disklabels. * The label is usually placed on one of the first sectors of the disk. * Many machines also place a bootstrap in the same area, * in which case the label is embedded in the bootstrap. * The bootstrap source must leave space at the proper offset * for the label on such machines. */ #ifndef BBSIZE #define BBSIZE 8192 /* size of boot area, with label */ #endif /* FIX! These are too low, but are traditional */ #define DEFAULT_NEWFS_BLOCK 8192U #define DEFAULT_NEWFS_FRAG 1024U #define DEFAULT_NEWFS_CPG 16U #define BIG_NEWFS_BLOCK 16384U #define BIG_NEWFS_FRAG 4096U #define BIG_NEWFS_CPG 64U #ifdef tahoe #define NUMBOOT 0 #else #if defined(__alpha__) || defined(hp300) || defined(hp800) #define NUMBOOT 1 #else #define NUMBOOT 2 #endif #endif void makelabel __P((char *, char *, struct disklabel *)); int writelabel __P((int, char *, struct disklabel *)); void l_perror __P((char *)); struct disklabel * readlabel __P((int)); struct disklabel * makebootarea __P((char *, struct disklabel *, int)); void display __P((FILE *, struct disklabel *)); int edit __P((struct disklabel *, int)); int editit __P((void)); char * skip __P((char *)); char * word __P((char *)); int getasciilabel __P((FILE *, struct disklabel *)); int checklabel __P((struct disklabel *)); void setbootflag __P((struct disklabel *)); void Warning (char *, ...); void usage __P((void)); struct disklabel * getvirginlabel __P((void)); #define DEFEDITOR _PATH_VI #define streq(a,b) (strcmp(a,b) == 0) char *dkname; char *specname; char tmpfil[] = PATH_TMPFILE; char namebuf[BBSIZE], *np = namebuf; struct disklabel lab; char bootarea[BBSIZE]; /* partition 'c' is the full disk and is special */ #define FULL_DISK_PART 2 #define MAX_PART ('z') #define MAX_NUM_PARTS (1 + MAX_PART - 'a') char part_size_type[MAX_NUM_PARTS]; char part_offset_type[MAX_NUM_PARTS]; int part_set[MAX_NUM_PARTS]; #if NUMBOOT > 0 int installboot; /* non-zero if we should install a boot program */ char *bootbuf; /* pointer to buffer with remainder of boot prog */ int bootsize; /* size of remaining boot program */ char *xxboot; /* primary boot */ char *bootxx; /* secondary boot */ char boot0[MAXPATHLEN]; char boot1[MAXPATHLEN]; #endif enum { UNSPEC, EDIT, NOWRITE, READ, RESTORE, WRITE, WRITEABLE, WRITEBOOT } op = UNSPEC; int rflag; int disable_write; /* set to disable writing to disk label */ #ifdef DEBUG int debug; #define OPTIONS "BNRWb:denrs:w" #else #define OPTIONS "BNRWb:enrs:w" #endif int main(argc, argv) int argc; char *argv[]; { register struct disklabel *lp; FILE *t; int ch, f = 0, flag, error = 0; char *name = 0; while ((ch = getopt(argc, argv, OPTIONS)) != -1) switch (ch) { #if NUMBOOT > 0 case 'B': ++installboot; break; case 'b': xxboot = optarg; break; #if NUMBOOT > 1 case 's': bootxx = optarg; break; #endif #endif case 'N': if (op != UNSPEC) usage(); op = NOWRITE; break; case 'n': disable_write = 1; break; case 'R': if (op != UNSPEC) usage(); op = RESTORE; break; case 'W': if (op != UNSPEC) usage(); op = WRITEABLE; break; case 'e': if (op != UNSPEC) usage(); op = EDIT; break; case 'r': ++rflag; break; case 'w': if (op != UNSPEC) usage(); op = WRITE; break; #ifdef DEBUG case 'd': debug++; break; #endif case '?': default: usage(); } argc -= optind; argv += optind; #if NUMBOOT > 0 if (installboot) { rflag++; if (op == UNSPEC) op = WRITEBOOT; } else { if (op == UNSPEC) op = READ; xxboot = bootxx = 0; } #else if (op == UNSPEC) op = READ; #endif if (argc < 1) usage(); dkname = argv[0]; if (dkname[0] != '/') { (void)sprintf(np, "%s%s%c", _PATH_DEV, dkname, 'a' + RAW_PART); specname = np; np += strlen(specname) + 1; } else specname = dkname; f = open(specname, op == READ ? O_RDONLY : O_RDWR); if (f < 0 && errno == ENOENT && dkname[0] != '/') { (void)sprintf(specname, "%s%s", _PATH_DEV, dkname); np = namebuf + strlen(specname) + 1; f = open(specname, op == READ ? O_RDONLY : O_RDWR); } if (f < 0) err(4, "%s", specname); switch(op) { case UNSPEC: break; case EDIT: if (argc != 1) usage(); lp = readlabel(f); error = edit(lp, f); break; case NOWRITE: flag = 0; if (ioctl(f, DIOCWLABEL, (char *)&flag) < 0) err(4, "ioctl DIOCWLABEL"); break; case READ: if (argc != 1) usage(); lp = readlabel(f); display(stdout, lp); error = checklabel(lp); break; case RESTORE: #if NUMBOOT > 0 if (installboot && argc == 3) { makelabel(argv[2], 0, &lab); argc--; /* * We only called makelabel() for its side effect * of setting the bootstrap file names. Discard * all changes to `lab' so that all values in the * final label come from the ASCII label. */ bzero((char *)&lab, sizeof(lab)); } #endif if (argc != 2) usage(); if (!(t = fopen(argv[1], "r"))) err(4, "%s", argv[1]); if (!getasciilabel(t, &lab)) exit(1); lp = makebootarea(bootarea, &lab, f); *lp = lab; error = writelabel(f, bootarea, lp); break; case WRITE: if (argc == 3) { name = argv[2]; argc--; } if (argc != 2) usage(); makelabel(argv[1], name, &lab); lp = makebootarea(bootarea, &lab, f); *lp = lab; if (checklabel(lp) == 0) error = writelabel(f, bootarea, lp); break; case WRITEABLE: flag = 1; if (ioctl(f, DIOCWLABEL, (char *)&flag) < 0) err(4, "ioctl DIOCWLABEL"); break; #if NUMBOOT > 0 case WRITEBOOT: { struct disklabel tlab; lp = readlabel(f); tlab = *lp; if (argc == 2) makelabel(argv[1], 0, &lab); lp = makebootarea(bootarea, &lab, f); *lp = tlab; if (checklabel(lp) == 0) error = writelabel(f, bootarea, lp); break; } #endif } exit(error); } /* * Construct a prototype disklabel from /etc/disktab. As a side * effect, set the names of the primary and secondary boot files * if specified. */ void makelabel(type, name, lp) char *type, *name; register struct disklabel *lp; { register struct disklabel *dp; if (strcmp(type, "auto") == 0) dp = getvirginlabel(); else dp = getdiskbyname(type); if (dp == NULL) errx(1, "%s: unknown disk type", type); *lp = *dp; #if NUMBOOT > 0 /* * Set bootstrap name(s). * 1. If set from command line, use those, * 2. otherwise, check if disktab specifies them (b0 or b1), * 3. otherwise, makebootarea() will choose ones based on the name * of the disk special file. E.g. /dev/ra0 -> raboot, bootra */ if (!xxboot && lp->d_boot0) { if (*lp->d_boot0 != '/') (void)sprintf(boot0, "%s/%s", _PATH_BOOTDIR, lp->d_boot0); else (void)strcpy(boot0, lp->d_boot0); xxboot = boot0; } #if NUMBOOT > 1 if (!bootxx && lp->d_boot1) { if (*lp->d_boot1 != '/') (void)sprintf(boot1, "%s/%s", _PATH_BOOTDIR, lp->d_boot1); else (void)strcpy(boot1, lp->d_boot1); bootxx = boot1; } #endif #endif /* d_packname is union d_boot[01], so zero */ bzero(lp->d_packname, sizeof(lp->d_packname)); if (name) (void)strncpy(lp->d_packname, name, sizeof(lp->d_packname)); } int writelabel(f, boot, lp) int f; char *boot; register struct disklabel *lp; { int flag; #ifdef __alpha__ u_long *p, sum; int i; #endif #ifdef vax register int i; #endif if (disable_write) { Warning("write to disk label supressed - label was as follows:"); display(stdout, lp); return (0); } else { setbootflag(lp); lp->d_magic = DISKMAGIC; lp->d_magic2 = DISKMAGIC; lp->d_checksum = 0; lp->d_checksum = dkcksum(lp); if (rflag) { /* * First set the kernel disk label, * then write a label to the raw disk. * If the SDINFO ioctl fails because it is unimplemented, * keep going; otherwise, the kernel consistency checks * may prevent us from changing the current (in-core) * label. */ if (ioctl(f, DIOCSDINFO, lp) < 0 && errno != ENODEV && errno != ENOTTY) { l_perror("ioctl DIOCSDINFO"); return (1); } (void)lseek(f, (off_t)0, SEEK_SET); #ifdef __alpha__ /* * Generate the bootblock checksum for the SRM console. */ for (p = (u_long *)boot, i = 0, sum = 0; i < 63; i++) sum += p[i]; p[63] = sum; #endif /* * write enable label sector before write (if necessary), * disable after writing. */ flag = 1; if (ioctl(f, DIOCWLABEL, &flag) < 0) warn("ioctl DIOCWLABEL"); if (write(f, boot, lp->d_bbsize) != lp->d_bbsize) { warn("write"); return (1); } #if NUMBOOT > 0 /* * Output the remainder of the disklabel */ if (bootbuf && write(f, bootbuf, bootsize) != bootsize) { warn("write"); return(1); } #endif flag = 0; (void) ioctl(f, DIOCWLABEL, &flag); } else if (ioctl(f, DIOCWDINFO, lp) < 0) { l_perror("ioctl DIOCWDINFO"); return (1); } #ifdef vax if (lp->d_type == DTYPE_SMD && lp->d_flags & D_BADSECT) { daddr_t alt; alt = lp->d_ncylinders * lp->d_secpercyl - lp->d_nsectors; for (i = 1; i < 11 && i < lp->d_nsectors; i += 2) { (void)lseek(f, (off_t)((alt + i) * lp->d_secsize), SEEK_SET); if (write(f, boot, lp->d_secsize) < lp->d_secsize) warn("alternate label %d write", i/2); } } #endif } return (0); } void l_perror(s) char *s; { switch (errno) { case ESRCH: warnx("%s: no disk label on disk;", s); fprintf(stderr, "add \"-r\" to install initial label\n"); break; case EINVAL: warnx("%s: label magic number or checksum is wrong!", s); fprintf(stderr, "(disklabel or kernel is out of date?)\n"); break; case EBUSY: warnx("%s: open partition would move or shrink", s); break; case EXDEV: warnx("%s: '%c' partition must start at beginning of disk", s, 'a' + RAW_PART); break; default: warn((char *)NULL); break; } } /* * Fetch disklabel for disk. * Use ioctl to get label unless -r flag is given. */ struct disklabel * readlabel(f) int f; { register struct disklabel *lp; if (rflag) { if (read(f, bootarea, BBSIZE) < BBSIZE) err(4, "%s", specname); for (lp = (struct disklabel *)bootarea; lp <= (struct disklabel *)(bootarea + BBSIZE - sizeof(*lp)); lp = (struct disklabel *)((char *)lp + 16)) if (lp->d_magic == DISKMAGIC && lp->d_magic2 == DISKMAGIC) break; if (lp > (struct disklabel *)(bootarea+BBSIZE-sizeof(*lp)) || lp->d_magic != DISKMAGIC || lp->d_magic2 != DISKMAGIC || dkcksum(lp) != 0) errx(1, "bad pack magic number (label is damaged, or pack is unlabeled)"); } else { lp = &lab; if (ioctl(f, DIOCGDINFO, lp) < 0) err(4, "ioctl DIOCGDINFO"); } return (lp); } /* * Construct a bootarea (d_bbsize bytes) in the specified buffer ``boot'' * Returns a pointer to the disklabel portion of the bootarea. */ struct disklabel * makebootarea(boot, dp, f) char *boot; register struct disklabel *dp; int f; { struct disklabel *lp; register char *p; int b; #if NUMBOOT > 0 char *dkbasename; struct stat sb; #endif #ifdef __alpha__ u_long *bootinfo; int n; #endif #ifdef __i386__ char *tmpbuf; int i, found; #endif /* XXX */ if (dp->d_secsize == 0) { dp->d_secsize = DEV_BSIZE; dp->d_bbsize = BBSIZE; } lp = (struct disklabel *) (boot + (LABELSECTOR * dp->d_secsize) + LABELOFFSET); bzero((char *)lp, sizeof *lp); #if NUMBOOT > 0 /* * If we are not installing a boot program but we are installing a * label on disk then we must read the current bootarea so we don't * clobber the existing boot. */ if (!installboot) { if (rflag) { if (read(f, boot, BBSIZE) < BBSIZE) err(4, "%s", specname); bzero((char *)lp, sizeof *lp); } return (lp); } /* * We are installing a boot program. Determine the name(s) and * read them into the appropriate places in the boot area. */ if (!xxboot || !bootxx) { dkbasename = np; if ((p = rindex(dkname, '/')) == NULL) p = dkname; else p++; while (*p && !isdigit(*p)) *np++ = *p++; *np++ = '\0'; if (!xxboot) { (void)sprintf(boot0, "%s/boot1", _PATH_BOOTDIR); xxboot = boot0; } #if NUMBOOT > 1 if (!bootxx) { (void)sprintf(boot1, "%s/boot2", _PATH_BOOTDIR); bootxx = boot1; } #endif } #ifdef DEBUG if (debug) fprintf(stderr, "bootstraps: xxboot = %s, bootxx = %s\n", xxboot, bootxx ? bootxx : "NONE"); #endif /* * Strange rules: * 1. One-piece bootstrap (hp300/hp800) * up to d_bbsize bytes of ``xxboot'' go in bootarea, the rest * is remembered and written later following the bootarea. * 2. Two-piece bootstraps (vax/i386?/mips?) * up to d_secsize bytes of ``xxboot'' go in first d_secsize * bytes of bootarea, remaining d_bbsize-d_secsize filled * from ``bootxx''. */ b = open(xxboot, O_RDONLY); if (b < 0) err(4, "%s", xxboot); #if NUMBOOT > 1 #ifdef __i386__ /* * XXX Botch alert. * The i386 has the so-called fdisk table embedded into the * primary bootstrap. We take care to not clobber it, but * only if it does already contain some data. (Otherwise, * the xxboot provides a template.) */ if ((tmpbuf = (char *)malloc((int)dp->d_secsize)) == 0) err(4, "%s", xxboot); memcpy((void *)tmpbuf, (void *)boot, (int)dp->d_secsize); #endif /* i386 */ if (read(b, boot, (int)dp->d_secsize) < 0) err(4, "%s", xxboot); (void)close(b); #ifdef __i386__ for (i = DOSPARTOFF, found = 0; !found && i < DOSPARTOFF + NDOSPART*sizeof(struct dos_partition); i++) found = tmpbuf[i] != 0; if (found) memcpy((void *)&boot[DOSPARTOFF], (void *)&tmpbuf[DOSPARTOFF], NDOSPART * sizeof(struct dos_partition)); free(tmpbuf); #endif /* i386 */ b = open(bootxx, O_RDONLY); if (b < 0) err(4, "%s", bootxx); if (fstat(b, &sb) != 0) err(4, "%s", bootxx); if (dp->d_secsize + sb.st_size > dp->d_bbsize) errx(4, "%s too large", bootxx); if (read(b, &boot[dp->d_secsize], (int)(dp->d_bbsize-dp->d_secsize)) < 0) err(4, "%s", bootxx); #else /* !(NUMBOOT > 1) */ #ifdef __alpha__ /* * On the alpha, the primary bootstrap starts at the * second sector of the boot area. The first sector * contains the label and must be edited to contain the * size and location of the primary bootstrap. */ n = read(b, boot + dp->d_secsize, (int)dp->d_bbsize); if (n < 0) err(4, "%s", xxboot); bootinfo = (u_long *)(boot + 480); bootinfo[0] = (n + dp->d_secsize - 1) / dp->d_secsize; bootinfo[1] = 1; /* start at sector 1 */ bootinfo[2] = 0; /* flags (must be zero) */ #else /* !__alpha__ */ if (read(b, boot, (int)dp->d_bbsize) < 0) err(4, "%s", xxboot); #endif /* __alpha__ */ if (fstat(b, &sb) != 0) err(4, "%s", xxboot); bootsize = (int)sb.st_size - dp->d_bbsize; if (bootsize > 0) { /* XXX assume d_secsize is a power of two */ bootsize = (bootsize + dp->d_secsize-1) & ~(dp->d_secsize-1); bootbuf = (char *)malloc((size_t)bootsize); if (bootbuf == 0) err(4, "%s", xxboot); if (read(b, bootbuf, bootsize) < 0) { free(bootbuf); err(4, "%s", xxboot); } } #endif /* NUMBOOT > 1 */ (void)close(b); #endif /* NUMBOOT > 0 */ /* * Make sure no part of the bootstrap is written in the area * reserved for the label. */ for (p = (char *)lp; p < (char *)lp + sizeof(struct disklabel); p++) if (*p) errx(2, "bootstrap doesn't leave room for disk label"); return (lp); } void display(f, lp) FILE *f; register struct disklabel *lp; { register int i, j; register struct partition *pp; fprintf(f, "# %s:\n", specname); if ((unsigned) lp->d_type < DKMAXTYPES) fprintf(f, "type: %s\n", dktypenames[lp->d_type]); else fprintf(f, "type: %u\n", lp->d_type); fprintf(f, "disk: %.*s\n", (int)sizeof(lp->d_typename), lp->d_typename); fprintf(f, "label: %.*s\n", (int)sizeof(lp->d_packname), lp->d_packname); fprintf(f, "flags:"); if (lp->d_flags & D_REMOVABLE) fprintf(f, " removeable"); if (lp->d_flags & D_ECC) fprintf(f, " ecc"); if (lp->d_flags & D_BADSECT) fprintf(f, " badsect"); fprintf(f, "\n"); fprintf(f, "bytes/sector: %lu\n", (u_long)lp->d_secsize); fprintf(f, "sectors/track: %lu\n", (u_long)lp->d_nsectors); fprintf(f, "tracks/cylinder: %lu\n", (u_long)lp->d_ntracks); fprintf(f, "sectors/cylinder: %lu\n", (u_long)lp->d_secpercyl); fprintf(f, "cylinders: %lu\n", (u_long)lp->d_ncylinders); fprintf(f, "sectors/unit: %lu\n", (u_long)lp->d_secperunit); fprintf(f, "rpm: %u\n", lp->d_rpm); fprintf(f, "interleave: %u\n", lp->d_interleave); fprintf(f, "trackskew: %u\n", lp->d_trackskew); fprintf(f, "cylinderskew: %u\n", lp->d_cylskew); fprintf(f, "headswitch: %lu\t\t# milliseconds\n", (u_long)lp->d_headswitch); fprintf(f, "track-to-track seek: %ld\t# milliseconds\n", (u_long)lp->d_trkseek); fprintf(f, "drivedata: "); for (i = NDDATA - 1; i >= 0; i--) if (lp->d_drivedata[i]) break; if (i < 0) i = 0; for (j = 0; j <= i; j++) fprintf(f, "%lu ", (u_long)lp->d_drivedata[j]); fprintf(f, "\n\n%u partitions:\n", lp->d_npartitions); fprintf(f, "# size offset fstype [fsize bsize bps/cpg]\n"); pp = lp->d_partitions; for (i = 0; i < lp->d_npartitions; i++, pp++) { if (pp->p_size) { fprintf(f, " %c: %8lu %8lu ", 'a' + i, (u_long)pp->p_size, (u_long)pp->p_offset); if ((unsigned) pp->p_fstype < FSMAXTYPES) fprintf(f, "%8.8s", fstypenames[pp->p_fstype]); else fprintf(f, "%8d", pp->p_fstype); switch (pp->p_fstype) { case FS_UNUSED: /* XXX */ fprintf(f, " %5lu %5lu %5.5s ", (u_long)pp->p_fsize, (u_long)(pp->p_fsize * pp->p_frag), ""); break; case FS_BSDFFS: fprintf(f, " %5lu %5lu %5u ", (u_long)pp->p_fsize, (u_long)(pp->p_fsize * pp->p_frag), pp->p_cpg); break; case FS_BSDLFS: fprintf(f, " %5lu %5lu %5d", (u_long)pp->p_fsize, (u_long)(pp->p_fsize * pp->p_frag), pp->p_cpg); break; default: fprintf(f, "%20.20s", ""); break; } fprintf(f, "\t# (Cyl. %4lu", (u_long)(pp->p_offset / lp->d_secpercyl)); if (pp->p_offset % lp->d_secpercyl) putc('*', f); else putc(' ', f); fprintf(f, "- %lu", (u_long)((pp->p_offset + pp->p_size + lp->d_secpercyl - 1) / lp->d_secpercyl - 1)); if (pp->p_size % lp->d_secpercyl) putc('*', f); fprintf(f, ")\n"); } } fflush(f); } int edit(lp, f) struct disklabel *lp; int f; { register int c, fd; struct disklabel label; FILE *fp; if ((fd = mkstemp(tmpfil)) == -1 || (fp = fdopen(fd, "w")) == NULL) { warnx("can't create %s", tmpfil); return (1); } display(fp, lp); fclose(fp); for (;;) { if (!editit()) break; fp = fopen(tmpfil, "r"); if (fp == NULL) { warnx("can't reopen %s for reading", tmpfil); break; } bzero((char *)&label, sizeof(label)); if (getasciilabel(fp, &label)) { *lp = label; if (writelabel(f, bootarea, lp) == 0) { fclose(fp); (void) unlink(tmpfil); return (0); } } fclose(fp); printf("re-edit the label? [y]: "); fflush(stdout); c = getchar(); if (c != EOF && c != (int)'\n') while (getchar() != (int)'\n') ; if (c == (int)'n') break; } (void) unlink(tmpfil); return (1); } int editit() { register int pid, xpid; int stat, omask; omask = sigblock(sigmask(SIGINT)|sigmask(SIGQUIT)|sigmask(SIGHUP)); while ((pid = fork()) < 0) { if (errno == EPROCLIM) { warnx("you have too many processes"); return(0); } if (errno != EAGAIN) { warn("fork"); return(0); } sleep(1); } if (pid == 0) { register char *ed; sigsetmask(omask); setgid(getgid()); setuid(getuid()); if ((ed = getenv("EDITOR")) == (char *)0) ed = DEFEDITOR; execlp(ed, ed, tmpfil, 0); err(1, "%s", ed); } while ((xpid = wait(&stat)) >= 0) if (xpid == pid) break; sigsetmask(omask); return(!stat); } char * skip(cp) register char *cp; { while (*cp != '\0' && isspace(*cp)) cp++; if (*cp == '\0' || *cp == '#') return ((char *)NULL); return (cp); } char * word(cp) register char *cp; { register char c; while (*cp != '\0' && !isspace(*cp) && *cp != '#') cp++; if ((c = *cp) != '\0') { *cp++ = '\0'; if (c != '#') return (skip(cp)); } return ((char *)NULL); } /* * Read an ascii label in from fd f, * in the same format as that put out by display(), * and fill in lp. */ int getasciilabel(f, lp) FILE *f; register struct disklabel *lp; { register char **cpp, *cp; register struct partition *pp; unsigned int part; char *tp, *s, line[BUFSIZ]; int v, lineno = 0, errors = 0; lp->d_bbsize = BBSIZE; /* XXX */ lp->d_sbsize = SBSIZE; /* XXX */ while (fgets(line, sizeof(line) - 1, f)) { lineno++; if ((cp = index(line,'\n')) != 0) *cp = '\0'; cp = skip(line); if (cp == NULL) continue; tp = index(cp, ':'); if (tp == NULL) { fprintf(stderr, "line %d: syntax error\n", lineno); errors++; continue; } *tp++ = '\0', tp = skip(tp); if (streq(cp, "type")) { if (tp == NULL) tp = "unknown"; cpp = dktypenames; for (; cpp < &dktypenames[DKMAXTYPES]; cpp++) if ((s = *cpp) && streq(s, tp)) { lp->d_type = cpp - dktypenames; goto next; } v = atoi(tp); if ((unsigned)v >= DKMAXTYPES) fprintf(stderr, "line %d:%s %d\n", lineno, "Warning, unknown disk type", v); lp->d_type = v; continue; } if (streq(cp, "flags")) { for (v = 0; (cp = tp) && *cp != '\0';) { tp = word(cp); if (streq(cp, "removeable")) v |= D_REMOVABLE; else if (streq(cp, "ecc")) v |= D_ECC; else if (streq(cp, "badsect")) v |= D_BADSECT; else { fprintf(stderr, "line %d: %s: bad flag\n", lineno, cp); errors++; } } lp->d_flags = v; continue; } if (streq(cp, "drivedata")) { register int i; for (i = 0; (cp = tp) && *cp != '\0' && i < NDDATA;) { lp->d_drivedata[i++] = atoi(cp); tp = word(cp); } continue; } if (sscanf(cp, "%d partitions", &v) == 1) { if (v == 0 || (unsigned)v > MAXPARTITIONS) { fprintf(stderr, "line %d: bad # of partitions\n", lineno); lp->d_npartitions = MAXPARTITIONS; errors++; } else lp->d_npartitions = v; continue; } if (tp == NULL) tp = ""; if (streq(cp, "disk")) { strncpy(lp->d_typename, tp, sizeof (lp->d_typename)); continue; } if (streq(cp, "label")) { strncpy(lp->d_packname, tp, sizeof (lp->d_packname)); continue; } if (streq(cp, "bytes/sector")) { v = atoi(tp); if (v <= 0 || (v % DEV_BSIZE) != 0) { fprintf(stderr, "line %d: %s: bad sector size\n", lineno, tp); errors++; } else lp->d_secsize = v; continue; } if (streq(cp, "sectors/track")) { v = atoi(tp); if (v <= 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_nsectors = v; continue; } if (streq(cp, "sectors/cylinder")) { v = atoi(tp); if (v <= 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_secpercyl = v; continue; } if (streq(cp, "tracks/cylinder")) { v = atoi(tp); if (v <= 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_ntracks = v; continue; } if (streq(cp, "cylinders")) { v = atoi(tp); if (v <= 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_ncylinders = v; continue; } if (streq(cp, "sectors/unit")) { v = atoi(tp); if (v <= 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_secperunit = v; continue; } if (streq(cp, "rpm")) { v = atoi(tp); if (v <= 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_rpm = v; continue; } if (streq(cp, "interleave")) { v = atoi(tp); if (v <= 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_interleave = v; continue; } if (streq(cp, "trackskew")) { v = atoi(tp); if (v < 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_trackskew = v; continue; } if (streq(cp, "cylinderskew")) { v = atoi(tp); if (v < 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_cylskew = v; continue; } if (streq(cp, "headswitch")) { v = atoi(tp); if (v < 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_headswitch = v; continue; } if (streq(cp, "track-to-track seek")) { v = atoi(tp); if (v < 0) { fprintf(stderr, "line %d: %s: bad %s\n", lineno, tp, cp); errors++; } else lp->d_trkseek = v; continue; } /* the ':' was removed above */ if ('a' <= *cp && *cp <= MAX_PART && cp[1] == '\0') { part = *cp - 'a'; if (part >= lp->d_npartitions) { fprintf(stderr, "line %d: partition name out of range a-%c: %s\n", lineno, 'a' + lp->d_npartitions - 1, cp); errors++; continue; } pp = &lp->d_partitions[part]; part_set[part] = 1; #define NXTNUM(n) { \ if (tp == NULL) { \ fprintf(stderr, "line %d: too few numeric fields\n", lineno); \ errors++; \ break; \ } else { \ cp = tp, tp = word(cp); \ if (tp == NULL) \ tp = cp; \ (n) = atoi(cp); \ } \ } /* retain 1 character following number */ #define NXTWORD(w,n) { \ if (tp == NULL) { \ fprintf(stderr, "line %d: too few numeric fields\n", lineno); \ errors++; \ break; \ } else { \ char *tmp; \ cp = tp, tp = word(cp); \ if (tp == NULL) \ tp = cp; \ (n) = strtol(cp,&tmp,10); \ if (tmp) (w) = *tmp; \ } \ } v = 0; NXTWORD(part_size_type[part],v); if (v < 0 || (v == 0 && part_size_type[part] != '*')) { fprintf(stderr, "line %d: %s: bad partition size\n", lineno, cp); errors++; break; } else { pp->p_size = v; v = 0; NXTWORD(part_offset_type[part],v); if (v < 0 || (v == 0 && part_offset_type[part] != '*' && part_offset_type[part] != '\0')) { fprintf(stderr, "line %d: %s: bad partition offset\n", lineno, cp); errors++; break; } else { pp->p_offset = v; cp = tp, tp = word(cp); cpp = fstypenames; for (; cpp < &fstypenames[FSMAXTYPES]; cpp++) if ((s = *cpp) && streq(s, cp)) { pp->p_fstype = cpp - fstypenames; goto gottype; } if (isdigit(*cp)) v = atoi(cp); else v = FSMAXTYPES; if ((unsigned)v >= FSMAXTYPES) { fprintf(stderr, "line %d: Warning, unknown " "filesystem type %s\n", lineno, cp); v = FS_UNUSED; } pp->p_fstype = v; gottype:; /* * Note: NXTNUM will break us out of the * switch only! */ switch (pp->p_fstype) { case FS_UNUSED: /* * allow us to accept defaults for * fsize/frag/cpg */ if (tp) { NXTNUM(pp->p_fsize); if (pp->p_fsize == 0) break; NXTNUM(v); pp->p_frag = v / pp->p_fsize; } /* else default to 0's */ break; /* These happen to be the same */ case FS_BSDFFS: case FS_BSDLFS: if (tp) { NXTNUM(pp->p_fsize); if (pp->p_fsize == 0) break; NXTNUM(v); pp->p_frag = v / pp->p_fsize; NXTNUM(pp->p_cpg); } else { /* * FIX! poor attempt at * adaptive */ /* 1 GB */ if (pp->p_size < 1*1024*1024*1024/lp->d_secsize) { /* FIX! These are too low, but are traditional */ pp->p_fsize = DEFAULT_NEWFS_BLOCK; pp->p_frag = (unsigned char) DEFAULT_NEWFS_FRAG; pp->p_cpg = DEFAULT_NEWFS_CPG; } else { pp->p_fsize = BIG_NEWFS_BLOCK; pp->p_frag = (unsigned char) BIG_NEWFS_FRAG; pp->p_cpg = BIG_NEWFS_CPG; } } break; default: break; } /* * note: we may not have * gotten all the entries for * the fs though if we didn't, * errors will be set. */ } } continue; } fprintf(stderr, "line %d: %s: Unknown disklabel field\n", lineno, cp); errors++; next:; } errors += checklabel(lp); return (errors == 0); } /* * Check disklabel for errors and fill in * derived fields according to supplied values. */ int checklabel(lp) register struct disklabel *lp; { register struct partition *pp; int i, errors = 0; char part; unsigned long total_size, total_percent, current_offset; int seen_default_offset; int hog_part; int j; struct partition *pp2; if (lp->d_secsize == 0) { fprintf(stderr, "sector size 0\n"); return (1); } if (lp->d_nsectors == 0) { fprintf(stderr, "sectors/track 0\n"); return (1); } if (lp->d_ntracks == 0) { fprintf(stderr, "tracks/cylinder 0\n"); return (1); } if (lp->d_ncylinders == 0) { fprintf(stderr, "cylinders/unit 0\n"); errors++; } if (lp->d_rpm == 0) Warning("revolutions/minute 0"); if (lp->d_secpercyl == 0) lp->d_secpercyl = lp->d_nsectors * lp->d_ntracks; if (lp->d_secperunit == 0) lp->d_secperunit = lp->d_secpercyl * lp->d_ncylinders; if (lp->d_bbsize == 0) { fprintf(stderr, "boot block size 0\n"); errors++; } else if (lp->d_bbsize % lp->d_secsize) Warning("boot block size %% sector-size != 0"); if (lp->d_sbsize == 0) { fprintf(stderr, "super block size 0\n"); errors++; } else if (lp->d_sbsize % lp->d_secsize) Warning("super block size %% sector-size != 0"); if (lp->d_npartitions > MAXPARTITIONS) Warning("number of partitions (%lu) > MAXPARTITIONS (%d)", (u_long)lp->d_npartitions, MAXPARTITIONS); /* first allocate space to the partitions, then offsets */ total_size = 0; /* in sectors */ total_percent = 0; /* in percent */ hog_part = -1; /* find all fixed partitions */ for (i = 0; i < lp->d_npartitions; i++) { pp = &lp->d_partitions[i]; if (part_set[i]) { if (part_size_type[i] == '*') { /* partition 2 ('c') is special */ if (i == FULL_DISK_PART) { pp->p_size = lp->d_secperunit; } else { if (hog_part != -1) Warning("Too many '*' partitions (%c and %c)", hog_part + 'a',i + 'a'); else hog_part = i; } } else { off_t size; size = pp->p_size; switch (part_size_type[i]) { case '%': total_percent += size; break; case 'k': case 'K': size *= 1024ULL; break; case 'm': case 'M': size *= 1024ULL * 1024ULL; break; case 'g': case 'G': size *= 1024ULL * 1024ULL * 1024ULL; break; case '\0': break; default: Warning("unknown size specifier '%c' (K/M/G are valid)",part_size_type[i]); break; } /* don't count %'s yet */ if (part_size_type[i] != '%') { /* * for all not in sectors, convert to * sectors */ if (part_size_type[i] != '\0') { if (size % lp->d_secsize != 0) Warning("partition %c not an integer number of sectors", i + 'a'); size /= lp->d_secsize; pp->p_size = size; } /* else already in sectors */ /* partition 2 ('c') is special */ if (i != FULL_DISK_PART) total_size += size; } } } } /* handle % partitions - note %'s don't need to add up to 100! */ if (total_percent != 0) { long free_space = lp->d_secperunit - total_size; if (total_percent > 100) { fprintf(stderr,"total percentage %d is greater than 100\n", total_percent); errors++; } if (free_space > 0) { for (i = 0; i < lp->d_npartitions; i++) { pp = &lp->d_partitions[i]; if (part_set[i] && part_size_type[i] == '%') { /* careful of overflows! and integer roundoff */ pp->p_size = ((double)pp->p_size/100) * free_space; total_size += pp->p_size; /* FIX we can lose a sector or so due to roundoff per partition. A more complex algorithm could avoid that */ } } } else { fprintf(stderr, "%ld sectors available to give to '*' and '%' partitions\n", free_space); errors++; /* fix? set all % partitions to size 0? */ } } /* give anything remaining to the hog partition */ if (hog_part != -1) { lp->d_partitions[hog_part].p_size = lp->d_secperunit - total_size; total_size = lp->d_secperunit; } /* Now set the offsets for each partition */ current_offset = 0; /* in sectors */ seen_default_offset = 0; for (i = 0; i < lp->d_npartitions; i++) { part = 'a' + i; pp = &lp->d_partitions[i]; if (part_set[i]) { if (part_offset_type[i] == '*') { /* partition 2 ('c') is special */ if (i == FULL_DISK_PART) { pp->p_offset = 0; } else { pp->p_offset = current_offset; seen_default_offset = 1; } } else { /* allow them to be out of order for old-style tables */ /* partition 2 ('c') is special */ if (pp->p_offset < current_offset && seen_default_offset && i != FULL_DISK_PART) { fprintf(stderr, "Offset %ld for partition %c overlaps previous partition which ends at %ld\n", pp->p_offset,i+'a',current_offset); fprintf(stderr, "Labels with any *'s for offset must be in ascending order by sector\n"); errors++; } else if (pp->p_offset != current_offset && i != FULL_DISK_PART && seen_default_offset) { /* * this may give unneeded warnings if * partitions are out-of-order */ Warning( "Offset %ld for partition %c doesn't match expected value %ld", pp->p_offset, i + 'a', current_offset); } } /* partition 2 ('c') is special */ if (i != FULL_DISK_PART) current_offset = pp->p_offset + pp->p_size; } } for (i = 0; i < lp->d_npartitions; i++) { part = 'a' + i; pp = &lp->d_partitions[i]; if (pp->p_size == 0 && pp->p_offset != 0) Warning("partition %c: size 0, but offset %lu", part, (u_long)pp->p_offset); #ifdef notdef if (pp->p_size % lp->d_secpercyl) Warning("partition %c: size %% cylinder-size != 0", part); if (pp->p_offset % lp->d_secpercyl) Warning("partition %c: offset %% cylinder-size != 0", part); #endif if (pp->p_offset > lp->d_secperunit) { fprintf(stderr, "partition %c: offset past end of unit\n", part); errors++; } if (pp->p_offset + pp->p_size > lp->d_secperunit) { fprintf(stderr, "partition %c: partition extends past end of unit\n", part); errors++; } if (i == FULL_DISK_PART) { if (pp->p_fstype != FS_UNUSED) Warning("partition %c is not marked as unused!",part); if (pp->p_offset != 0) Warning("partition %c doesn't start at 0!",part); if (pp->p_size != lp->d_secperunit) Warning("partition %c doesn't cover the whole unit!",part); if ((pp->p_fstype != FS_UNUSED) || (pp->p_offset != 0) || (pp->p_size != lp->d_secperunit)) { Warning("An incorrect partition %c may cause problems for " "standard system utilities",part); } } /* check for overlaps */ /* this will check for all possible overlaps once and only once */ for (j = 0; j < i; j++) { /* partition 2 ('c') is special */ if (j != FULL_DISK_PART && i != FULL_DISK_PART && part_set[i] && part_set[j]) { pp2 = &lp->d_partitions[j]; if (pp2->p_offset < pp->p_offset + pp->p_size && (pp2->p_offset + pp2->p_size > pp->p_offset || pp2->p_offset >= pp->p_offset)) { fprintf(stderr,"partitions %c and %c overlap!\n", j + 'a', i + 'a'); errors++; } } } } for (; i < MAXPARTITIONS; i++) { part = 'a' + i; pp = &lp->d_partitions[i]; if (pp->p_size || pp->p_offset) Warning("unused partition %c: size %d offset %lu", 'a' + i, pp->p_size, (u_long)pp->p_offset); } return (errors); } /* * When operating on a "virgin" disk, try getting an initial label * from the associated device driver. This might work for all device * drivers that are able to fetch some initial device parameters * without even having access to a (BSD) disklabel, like SCSI disks, * most IDE drives, or vn devices. * * The device name must be given in its "canonical" form. */ struct disklabel * getvirginlabel(void) { static struct disklabel lab; char namebuf[BBSIZE]; int f; if (dkname[0] == '/') { warnx("\"auto\" requires the usage of a canonical disk name"); return (NULL); } (void)snprintf(namebuf, BBSIZE, "%s%s", _PATH_DEV, dkname); if ((f = open(namebuf, O_RDONLY)) == -1) { warn("cannot open %s", namebuf); return (NULL); } /* * Try to use the new get-virgin-label ioctl. If it fails, * fallback to the old get-disdk-info ioctl. */ if (ioctl(f, DIOCGDVIRGIN, &lab) < 0) { if (ioctl(f, DIOCGDINFO, &lab) < 0) { warn("ioctl DIOCGDINFO"); close(f); return (NULL); } } close(f); lab.d_boot0 = NULL; lab.d_boot1 = NULL; return (&lab); } /* * If we are installing a boot program that doesn't fit in d_bbsize * we need to mark those partitions that the boot overflows into. * This allows newfs to prevent creation of a filesystem where it might * clobber bootstrap code. */ void setbootflag(lp) register struct disklabel *lp; { register struct partition *pp; int i, errors = 0; char part; u_long boffset; if (bootbuf == 0) return; boffset = bootsize / lp->d_secsize; for (i = 0; i < lp->d_npartitions; i++) { part = 'a' + i; pp = &lp->d_partitions[i]; if (pp->p_size == 0) continue; if (boffset <= pp->p_offset) { if (pp->p_fstype == FS_BOOT) pp->p_fstype = FS_UNUSED; } else if (pp->p_fstype != FS_BOOT) { if (pp->p_fstype != FS_UNUSED) { fprintf(stderr, "boot overlaps used partition %c\n", part); errors++; } else { pp->p_fstype = FS_BOOT; Warning("boot overlaps partition %c, %s", part, "marked as FS_BOOT"); } } } if (errors) errx(4, "cannot install boot program"); } /*VARARGS1*/ void Warning(char *fmt, ...) { va_list ap; fprintf(stderr, "Warning, "); va_start(ap, fmt); vfprintf(stderr, fmt, ap); fprintf(stderr, "\n"); va_end(ap); } void usage() { #if NUMBOOT > 0 fprintf(stderr, "%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n", "usage: disklabel [-r] disk", "\t\t(to read label)", " disklabel -w [-r] [-n] disk type [ packid ]", "\t\t(to write label with existing boot program)", " disklabel -e [-r] [-n] disk", "\t\t(to edit label)", " disklabel -R [-r] [-n] disk protofile", "\t\t(to restore label with existing boot program)", #if NUMBOOT > 1 " disklabel -B [-n] [ -b boot1 [ -s boot2 ] ] disk [ type ]", "\t\t(to install boot program with existing label)", " disklabel -w -B [-n] [ -b boot1 [ -s boot2 ] ] disk type [ packid ]", "\t\t(to write label and boot program)", " disklabel -R -B [-n] [ -b boot1 [ -s boot2 ] ] disk protofile [ type ]", "\t\t(to restore label and boot program)", #else " disklabel -B [-n] [ -b bootprog ] disk [ type ]", "\t\t(to install boot program with existing on-disk label)", " disklabel -w -B [-n] [ -b bootprog ] disk type [ packid ]", "\t\t(to write label and install boot program)", " disklabel -R -B [-n] [ -b bootprog ] disk protofile [ type ]", "\t\t(to restore label and install boot program)", #endif " disklabel [-NW] disk", "\t\t(to write disable/enable label)"); #else fprintf(stderr, "%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n%s\n", "usage: disklabel [-r] disk", "(to read label)", " disklabel -w [-r] [-n] disk type [ packid ]", "\t\t(to write label)", " disklabel -e [-r] [-n] disk", "\t\t(to edit label)", " disklabel -R [-r] [-n] disk protofile", "\t\t(to restore label)", " disklabel [-NW] disk", "\t\t(to write disable/enable label)"); #endif exit(1); }