usr.bin/vmstat/vmstat.c

1.1      cgd /*
1.1      cgd  * Copyright (c) 1980, 1986, 1991 The Regents of the University of California.
1.1      cgd  * 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
1.1      cgd #ifndef lint
1.1      cgd char copyright[] =
1.1      cgd "@(#) Copyright (c) 1980, 1986, 1991 The Regents of the University of California.\n\
1.1      cgd  All rights reserved.\n";
1.1      cgd #endif /* not lint */
1.1      cgd
1.1      cgd #ifndef lint
1.6  mycroft /*static char sccsid[] = "from: @(#)vmstat.c	5.31 (Berkeley) 7/2/91";*/
1.9  deraadt static char rcsid[] = "$Id: vmstat.c,v 1.9 1993/11/10 15:00:41 deraadt Exp $";
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/proc.h>
1.1      cgd #include <sys/user.h>
1.1      cgd #include <sys/dkstat.h>
1.1      cgd #include <sys/buf.h>
1.1      cgd #include <sys/namei.h>
1.1      cgd #include <sys/malloc.h>
1.1      cgd #include <sys/signal.h>
1.1      cgd #include <sys/fcntl.h>
1.1      cgd #include <sys/ioctl.h>
1.1      cgd #include <sys/vmmeter.h>
1.1      cgd #include <vm/vm.h>
1.1      cgd #include <vm/vm_statistics.h>
1.1      cgd #include <time.h>
1.1      cgd #include <nlist.h>
1.1      cgd #include <kvm.h>
1.1      cgd #include <errno.h>
1.1      cgd #include <unistd.h>
1.1      cgd #include <stdio.h>
1.1      cgd #include <ctype.h>
1.1      cgd #include <stdlib.h>
1.1      cgd #include <string.h>
1.1      cgd #include <paths.h>
1.1      cgd
1.1      cgd #define NEWVM			/* XXX till old has been updated or purged */
1.1      cgd struct nlist nl[] = {
1.1      cgd #define	X_CPTIME	0
1.1      cgd 	{ "_cp_time" },
1.1      cgd #define X_TOTAL		1
1.1      cgd 	{ "_total" },
1.1      cgd #define X_SUM		2
1.1      cgd 	{ "_cnt" },		/* XXX for now that's where it is */
1.1      cgd #define	X_BOOTTIME	3
1.1      cgd 	{ "_boottime" },
1.1      cgd #define	X_DKXFER	4
1.1      cgd 	{ "_dk_xfer" },
1.1      cgd #define X_HZ		5
1.1      cgd 	{ "_hz" },
1.1      cgd #define X_PHZ		6
1.1      cgd 	{ "_phz" },
1.1      cgd #define X_NCHSTATS	7
1.1      cgd 	{ "_nchstats" },
1.1      cgd #define	X_INTRNAMES	8
1.1      cgd 	{ "_intrnames" },
1.1      cgd #define	X_EINTRNAMES	9
1.1      cgd 	{ "_eintrnames" },
1.1      cgd #define	X_INTRCNT	10
1.1      cgd 	{ "_intrcnt" },
1.1      cgd #define	X_EINTRCNT	11
1.1      cgd 	{ "_eintrcnt" },
1.1      cgd #define	X_DK_NDRIVE	12
1.1      cgd 	{ "_dk_ndrive" },
1.1      cgd #define	X_KMEMSTAT	13
1.1      cgd 	{ "_kmemstats" },
1.1      cgd #define	X_KMEMBUCKETS	14
1.1      cgd 	{ "_bucket" },
1.1      cgd #define	X_VMSTAT	15
1.1      cgd 	{ "_vm_stat" },
1.7      cgd #define	X_FREE		16
1.7      cgd 	{ "_vm_page_free_count" },
1.7      cgd #define	X_ACTIVE	17
1.7      cgd 	{ "_vm_page_active_count" },
1.7      cgd #define	X_INACTIVE	18
1.7      cgd 	{ "_vm_page_inactive_count" },
1.7      cgd #define	X_WIRED		19
1.7      cgd 	{ "_vm_page_wire_count" },
1.7      cgd #define	X_PAGESIZE	20
1.7      cgd 	{ "_page_size" },
1.1      cgd #ifdef notdef
1.1      cgd #define	X_DEFICIT	15
1.1      cgd 	{ "_deficit" },
1.1      cgd #define	X_FORKSTAT	16
1.1      cgd 	{ "_forkstat" },
1.1      cgd #define X_REC		17
1.1      cgd 	{ "_rectime" },
1.1      cgd #define X_PGIN		18
1.1      cgd 	{ "_pgintime" },
1.1      cgd #define	X_XSTATS	19
1.1      cgd 	{ "_xstats" },
1.1      cgd #define X_END		19
1.1      cgd #else
1.7      cgd #define X_END		20
1.1      cgd #endif
1.1      cgd #ifdef hp300
1.1      cgd #define	X_HPDINIT	(X_END+1)
1.1      cgd 	{ "_hp_dinit" },
1.1      cgd #endif
1.1      cgd #ifdef tahoe
1.1      cgd #define	X_VBDINIT	(X_END+1)
1.1      cgd 	{ "_vbdinit" },
1.1      cgd #define	X_CKEYSTATS	(X_END+2)
1.1      cgd 	{ "_ckeystats" },
1.1      cgd #define	X_DKEYSTATS	(X_END+3)
1.1      cgd 	{ "_dkeystats" },
1.1      cgd #endif
1.1      cgd #ifdef vax
1.1      cgd #define X_MBDINIT	(X_END+1)
1.1      cgd 	{ "_mbdinit" },
1.1      cgd #define X_UBDINIT	(X_END+2)
1.1      cgd 	{ "_ubdinit" },
1.1      cgd #endif
1.2  deraadt #ifdef i386
1.7      cgd #define	X_ISA_BIO	(X_END+1)
1.2  deraadt 	{ "_isa_subdev" },
1.2  deraadt #endif i386
1.1      cgd 	{ "" },
1.1      cgd };
1.1      cgd
1.1      cgd struct _disk {
1.1      cgd 	long time[CPUSTATES];
1.1      cgd 	long *xfer;
1.1      cgd } cur, last;
1.1      cgd
1.1      cgd struct	vm_statistics vm_stat, ostat;
1.1      cgd struct	vmmeter sum, osum;
1.1      cgd char	*vmunix = _PATH_UNIX;
1.1      cgd char	**dr_name;
1.1      cgd int	*dr_select, dk_ndrive, ndrives;
1.1      cgd #ifdef __386BSD__
1.1      cgd       /* to make up for statistics that don't get updated */
1.1      cgd int	size, free_count, active_count, inactive, wired;
1.1      cgd #endif
1.1      cgd
1.1      cgd int	winlines = 20;
1.1      cgd
1.1      cgd #define	FORKSTAT	0x01
1.1      cgd #define	INTRSTAT	0x02
1.1      cgd #define	MEMSTAT		0x04
1.1      cgd #define	SUMSTAT		0x08
1.1      cgd #define	TIMESTAT	0x10
1.1      cgd #define	VMSTAT		0x20
1.1      cgd
1.1      cgd #include "names.c"			/* disk names -- machine dependent */
1.1      cgd
1.1      cgd void	cpustats(), dkstats(), dointr(), domem(), dosum();
1.1      cgd void	dovmstat(), kread(), usage();
1.1      cgd #ifdef notdef
1.1      cgd void	dotimes(), doforkst();
1.1      cgd #endif
1.1      cgd
1.1      cgd main(argc, argv)
1.1      cgd 	register int argc;
1.1      cgd 	register char **argv;
1.1      cgd {
1.1      cgd 	extern int optind;
1.1      cgd 	extern char *optarg;
1.1      cgd 	register int c, todo;
1.1      cgd 	u_int interval;
1.1      cgd 	int reps;
1.1      cgd 	char *kmem;
1.1      cgd
1.1      cgd 	kmem = NULL;
1.1      cgd 	interval = reps = todo = 0;
1.1      cgd 	while ((c = getopt(argc, argv, "c:fiM:mN:stw:")) != EOF) {
1.1      cgd 		switch (c) {
1.1      cgd 		case 'c':
1.1      cgd 			reps = atoi(optarg);
1.1      cgd 			break;
1.1      cgd #ifndef notdef
1.1      cgd 		case 'f':
1.1      cgd 			todo |= FORKSTAT;
1.1      cgd 			break;
1.1      cgd #endif
1.1      cgd 		case 'i':
1.1      cgd 			todo |= INTRSTAT;
1.1      cgd 			break;
1.1      cgd 		case 'M':
1.1      cgd 			kmem = optarg;
1.1      cgd 			break;
1.1      cgd 		case 'm':
1.1      cgd 			todo |= MEMSTAT;
1.1      cgd 			break;
1.1      cgd 		case 'N':
1.1      cgd 			vmunix = optarg;
1.1      cgd 			break;
1.1      cgd 		case 's':
1.1      cgd 			todo |= SUMSTAT;
1.1      cgd 			break;
1.1      cgd #ifndef notdef
1.1      cgd 		case 't':
1.1      cgd 			todo |= TIMESTAT;
1.1      cgd 			break;
1.1      cgd #endif
1.1      cgd 		case 'w':
1.1      cgd 			interval = atoi(optarg);
1.1      cgd 			break;
1.1      cgd 		case '?':
1.1      cgd 		default:
1.1      cgd 			usage();
1.1      cgd 		}
1.1      cgd 	}
1.1      cgd 	argc -= optind;
1.1      cgd 	argv += optind;
1.1      cgd
1.1      cgd 	if (todo == 0)
1.1      cgd 		todo = VMSTAT;
1.1      cgd
1.1      cgd 	if (kvm_openfiles(vmunix, kmem, NULL) < 0) {
1.1      cgd 		(void)fprintf(stderr,
1.1      cgd 		    "vmstat: kvm_openfiles: %s\n", kvm_geterr());
1.1      cgd 		exit(1);
1.1      cgd 	}
1.1      cgd
1.1      cgd 	if ((c = kvm_nlist(nl)) != 0) {
1.1      cgd 		if (c > 0) {
1.1      cgd 			(void)fprintf(stderr,
1.1      cgd 			    "vmstat: undefined symbols in %s:", vmunix);
1.1      cgd 			for (c = 0; c < sizeof(nl)/sizeof(nl[0]); c++)
1.1      cgd 				if (nl[c].n_type == 0)
1.1      cgd 					fprintf(stderr, " %s", nl[c].n_name);
1.1      cgd 			(void)fputc('\n', stderr);
1.1      cgd 		} else
1.1      cgd 			(void)fprintf(stderr, "vmstat: kvm_nlist: %s\n",
1.1      cgd 			    kvm_geterr());
1.1      cgd 		exit(1);
1.1      cgd 	}
1.1      cgd
1.1      cgd 	if (todo & VMSTAT) {
1.1      cgd 		char **getdrivedata();
1.1      cgd 		struct winsize winsize;
1.1      cgd
1.1      cgd 		argv = getdrivedata(argv);
1.1      cgd 		winsize.ws_row = 0;
1.1      cgd 		(void) ioctl(STDOUT_FILENO, TIOCGWINSZ, (char *)&winsize);
1.1      cgd 		if (winsize.ws_row > 0)
1.1      cgd 			winlines = winsize.ws_row;
1.1      cgd
1.1      cgd 	}
1.1      cgd
1.1      cgd #define	BACKWARD_COMPATIBILITY
1.1      cgd #ifdef	BACKWARD_COMPATIBILITY
1.1      cgd 	if (*argv) {
1.1      cgd 		interval = atoi(*argv);
1.1      cgd 		if (*++argv)
1.1      cgd 			reps = atoi(*argv);
1.1      cgd 	}
1.1      cgd #endif
1.1      cgd
1.1      cgd 	if (interval) {
1.1      cgd 		if (!reps)
1.1      cgd 			reps = -1;
1.1      cgd 	} else if (reps)
1.1      cgd 		interval = 1;
1.1      cgd
1.1      cgd #ifdef notdef
1.1      cgd 	if (todo & FORKSTAT)
1.1      cgd 		doforkst();
1.1      cgd #endif
1.1      cgd 	if (todo & MEMSTAT)
1.1      cgd 		domem();
1.1      cgd 	if (todo & SUMSTAT)
1.1      cgd 		dosum();
1.1      cgd #ifdef notdef
1.1      cgd 	if (todo & TIMESTAT)
1.1      cgd 		dotimes();
1.1      cgd #endif
1.1      cgd 	if (todo & INTRSTAT)
1.1      cgd 		dointr();
1.1      cgd 	if (todo & VMSTAT)
1.1      cgd 		dovmstat(interval, reps);
1.1      cgd 	exit(0);
1.1      cgd }
1.1      cgd
1.1      cgd char **
1.1      cgd getdrivedata(argv)
1.1      cgd 	char **argv;
1.1      cgd {
1.1      cgd 	register int i;
1.1      cgd 	register char **cp;
1.1      cgd 	char buf[30];
1.1      cgd
1.1      cgd 	kread(X_DK_NDRIVE, &dk_ndrive, sizeof(dk_ndrive));
1.1      cgd 	if (dk_ndrive <= 0) {
1.1      cgd 		(void)fprintf(stderr, "vmstat: dk_ndrive %d\n", dk_ndrive);
1.1      cgd 		exit(1);
1.1      cgd 	}
1.1      cgd 	dr_select = calloc((size_t)dk_ndrive, sizeof(int));
1.1      cgd 	dr_name = calloc((size_t)dk_ndrive, sizeof(char *));
1.1      cgd 	for (i = 0; i < dk_ndrive; i++)
1.1      cgd 		dr_name[i] = NULL;
1.1      cgd 	cur.xfer = calloc((size_t)dk_ndrive, sizeof(long));
1.1      cgd 	last.xfer = calloc((size_t)dk_ndrive, sizeof(long));
1.1      cgd 	read_names();
1.1      cgd 	for (i = 0; i < dk_ndrive; i++)
1.1      cgd 		if (dr_name[i] == NULL) {
1.1      cgd 			(void)sprintf(buf, "??%d", i);
1.1      cgd 			dr_name[i] = strdup(buf);
1.1      cgd 		}
1.1      cgd
1.1      cgd 	/*
1.1      cgd 	 * Choose drives to be displayed.  Priority goes to (in order) drives
1.1      cgd 	 * supplied as arguments, default drives.  If everything isn't filled
1.1      cgd 	 * in and there are drives not taken care of, display the first few
1.1      cgd 	 * that fit.
1.1      cgd 	 */
1.1      cgd #define BACKWARD_COMPATIBILITY
1.1      cgd 	for (ndrives = 0; *argv; ++argv) {
1.1      cgd #ifdef	BACKWARD_COMPATIBILITY
1.1      cgd 		if (isdigit(**argv))
1.1      cgd 			break;
1.1      cgd #endif
1.1      cgd 		for (i = 0; i < dk_ndrive; i++) {
1.1      cgd 			if (strcmp(dr_name[i], *argv))
1.1      cgd 				continue;
1.1      cgd 			dr_select[i] = 1;
1.1      cgd 			++ndrives;
1.1      cgd 			break;
1.1      cgd 		}
1.1      cgd 	}
1.1      cgd 	for (i = 0; i < dk_ndrive && ndrives < 4; i++) {
1.1      cgd 		if (dr_select[i])
1.1      cgd 			continue;
1.1      cgd 		for (cp = defdrives; *cp; cp++)
1.1      cgd 			if (strcmp(dr_name[i], *cp) == 0) {
1.1      cgd 				dr_select[i] = 1;
1.1      cgd 				++ndrives;
1.1      cgd 				break;
1.1      cgd 			}
1.1      cgd 	}
1.1      cgd 	for (i = 0; i < dk_ndrive && ndrives < 4; i++) {
1.1      cgd 		if (dr_select[i])
1.1      cgd 			continue;
1.1      cgd 		dr_select[i] = 1;
1.1      cgd 		++ndrives;
1.1      cgd 	}
1.1      cgd 	return(argv);
1.1      cgd }
1.1      cgd
1.1      cgd #ifdef __386BSD__
1.1      cgd /*
1.1      cgd  * Make up for the fact that under 0.1, VM doesn't update all of the
1.1      cgd  * fields in the statistics structures.
1.1      cgd  */
1.1      cgd
1.1      cgd void
1.1      cgd fill_in_vm_stat(vm_stat)
1.1      cgd         struct vm_statistics *vm_stat;
1.1      cgd {
1.1      cgd 	kread(X_FREE, &vm_stat->free_count, sizeof(vm_stat->free_count));
1.1      cgd 	kread(X_ACTIVE, &vm_stat->active_count, sizeof(vm_stat->active_count));
1.1      cgd 	kread(X_INACTIVE, &vm_stat->inactive_count,
1.1      cgd 	      sizeof(vm_stat->inactive_count));
1.1      cgd 	kread(X_WIRED, &vm_stat->wire_count, sizeof(vm_stat->wire_count));
1.1      cgd 	kread(X_PAGESIZE, &vm_stat->pagesize, sizeof(vm_stat->pagesize));
1.1      cgd }
1.1      cgd #endif
1.1      cgd
1.1      cgd long
1.1      cgd getuptime()
1.1      cgd {
1.1      cgd 	static time_t now, boottime;
1.1      cgd 	time_t uptime;
1.1      cgd
1.1      cgd 	if (boottime == 0)
1.1      cgd 		kread(X_BOOTTIME, &boottime, sizeof(boottime));
1.1      cgd 	(void)time(&now);
1.1      cgd 	uptime = now - boottime;
1.1      cgd 	if (uptime <= 0 || uptime > 60*60*24*365*10) {
1.1      cgd 		(void)fprintf(stderr,
1.1      cgd 		    "vmstat: time makes no sense; namelist must be wrong.\n");
1.1      cgd 		exit(1);
1.1      cgd 	}
1.1      cgd 	return(uptime);
1.1      cgd }
1.1      cgd
1.1      cgd int	hz, hdrcnt;
1.1      cgd
1.1      cgd void
1.1      cgd dovmstat(interval, reps)
1.1      cgd 	u_int interval;
1.1      cgd 	int reps;
1.1      cgd {
1.1      cgd 	struct vmtotal total;
1.1      cgd 	time_t uptime, halfuptime;
1.1      cgd 	void needhdr();
1.1      cgd #ifndef notdef
1.1      cgd 	int deficit;
1.1      cgd #endif
1.1      cgd
1.1      cgd 	uptime = getuptime();
1.1      cgd 	halfuptime = uptime / 2;
1.1      cgd 	(void)signal(SIGCONT, needhdr);
1.1      cgd
1.1      cgd 	if (nl[X_PHZ].n_type != 0 && nl[X_PHZ].n_value != 0)
1.1      cgd 		kread(X_PHZ, &hz, sizeof(hz));
1.1      cgd 	if (!hz)
1.1      cgd 		kread(X_HZ, &hz, sizeof(hz));
1.1      cgd
1.1      cgd 	for (hdrcnt = 1;;) {
1.1      cgd 		if (!--hdrcnt)
1.1      cgd 			printhdr();
1.1      cgd 		kread(X_CPTIME, cur.time, sizeof(cur.time));
1.1      cgd 		kread(X_DKXFER, cur.xfer, sizeof(*cur.xfer * dk_ndrive));
1.1      cgd 		kread(X_SUM, &sum, sizeof(sum));
1.1      cgd 		kread(X_TOTAL, &total, sizeof(total));
1.1      cgd 		kread(X_VMSTAT, &vm_stat, sizeof(vm_stat));
1.1      cgd #ifdef __386BSD__
1.1      cgd 		fill_in_vm_stat (&vm_stat);
1.1      cgd #endif
1.1      cgd #ifdef notdef
1.1      cgd 		kread(X_DEFICIT, &deficit, sizeof(deficit));
1.1      cgd #endif
1.1      cgd 		(void)printf("%2d %1d %1d ",
1.1      cgd 		    total.t_rq, total.t_dw + total.t_pw, total.t_sw);
1.1      cgd #define pgtok(a) ((a)*NBPG >> 10)
1.1      cgd #define	rate(x)	(((x) + halfuptime) / uptime)	/* round */
1.1      cgd 		(void)printf("%5ld %5ld ",
1.1      cgd #ifdef __386BSD__
1.1      cgd 		    pgtok(vm_stat.active_count), pgtok(vm_stat.free_count));
1.1      cgd #else
1.1      cgd 		    pgtok(total.t_avm), pgtok(total.t_free));
1.1      cgd #endif
1.1      cgd #ifdef NEWVM
1.1      cgd 		(void)printf("%4lu ", rate(vm_stat.faults - ostat.faults));
1.1      cgd 		(void)printf("%3lu ",
1.1      cgd 		    rate(vm_stat.reactivations - ostat.reactivations));
1.1      cgd 		(void)printf("%3lu ", rate(vm_stat.pageins - ostat.pageins));
1.1      cgd 		(void)printf("%3lu %3lu ",
1.1      cgd 		    rate(vm_stat.pageouts - ostat.pageouts), 0);
1.1      cgd #else
1.1      cgd 		(void)printf("%3lu %2lu ",
1.1      cgd 		    rate(sum.v_pgrec - (sum.v_xsfrec+sum.v_xifrec) -
1.1      cgd 		    (osum.v_pgrec - (osum.v_xsfrec+osum.v_xifrec))),
1.1      cgd 		    rate(sum.v_xsfrec + sum.v_xifrec -
1.1      cgd 		    osum.v_xsfrec - osum.v_xifrec));
1.1      cgd 		(void)printf("%3lu ",
1.1      cgd 		    rate(pgtok(sum.v_pgpgin - osum.v_pgpgin)));
1.1      cgd 		(void)printf("%3lu %3lu ",
1.1      cgd 		    rate(pgtok(sum.v_pgpgout - osum.v_pgpgout)),
1.1      cgd 		    rate(pgtok(sum.v_dfree - osum.v_dfree)));
1.1      cgd 		(void)printf("%3d ", pgtok(deficit));
1.1      cgd #endif
1.1      cgd 		(void)printf("%3lu ", rate(sum.v_scan - osum.v_scan));
1.1      cgd 		dkstats();
1.1      cgd 		(void)printf("%4lu %4lu %3lu ",
1.1      cgd 		    rate(sum.v_intr - osum.v_intr),
1.1      cgd 		    rate(sum.v_syscall - osum.v_syscall),
1.1      cgd 		    rate(sum.v_swtch - osum.v_swtch));
1.1      cgd 		cpustats();
1.1      cgd 		(void)printf("\n");
1.1      cgd 		(void)fflush(stdout);
1.1      cgd 		if (reps >= 0 && --reps <= 0)
1.1      cgd 			break;
1.1      cgd 		osum = sum;
1.1      cgd 		ostat = vm_stat;
1.1      cgd 		uptime = interval;
1.1      cgd 		/*
1.1      cgd 		 * We round upward to avoid losing low-frequency events
1.1      cgd 		 * (i.e., >= 1 per interval but < 1 per second).
1.1      cgd 		 */
1.1      cgd 		halfuptime = (uptime + 1) / 2;
1.1      cgd 		(void)sleep(interval);
1.1      cgd 	}
1.1      cgd }
1.1      cgd
1.1      cgd printhdr()
1.1      cgd {
1.1      cgd 	register int i;
1.1      cgd
1.1      cgd 	(void)printf(" procs   memory     page%*s", 20, "");
1.1      cgd 	if (ndrives > 1)
1.1      cgd 		(void)printf("disks %*s  faults      cpu\n",
1.1      cgd 		   ndrives * 3 - 6, "");
1.1      cgd 	else
1.1      cgd 		(void)printf("%*s  faults      cpu\n", ndrives * 3, "");
1.1      cgd #ifndef NEWVM
1.1      cgd 	(void)printf(" r b w   avm   fre  re at  pi  po  fr  de  sr ");
1.1      cgd #else
1.1      cgd 	(void)printf(" r b w   avm   fre  flt  re  pi  po  fr  sr ");
1.1      cgd #endif
1.1      cgd 	for (i = 0; i < dk_ndrive; i++)
1.1      cgd 		if (dr_select[i])
1.1      cgd 			(void)printf("%c%c ", dr_name[i][0],
1.1      cgd 			    dr_name[i][strlen(dr_name[i]) - 1]);
1.1      cgd 	(void)printf("  in   sy  cs us sy id\n");
1.1      cgd 	hdrcnt = winlines - 2;
1.1      cgd }
1.1      cgd
1.1      cgd /*
1.1      cgd  * Force a header to be prepended to the next output.
1.1      cgd  */
1.1      cgd void
1.1      cgd needhdr()
1.1      cgd {
1.1      cgd
1.1      cgd 	hdrcnt = 1;
1.1      cgd }
1.1      cgd
1.1      cgd #ifdef notdef
1.1      cgd void
1.1      cgd dotimes()
1.1      cgd {
1.1      cgd 	u_int pgintime, rectime;
1.1      cgd
1.1      cgd 	kread(X_REC, &rectime, sizeof(rectime));
1.1      cgd 	kread(X_PGIN, &pgintime, sizeof(pgintime));
1.1      cgd 	kread(X_SUM, &sum, sizeof(sum));
1.1      cgd 	(void)printf("%u reclaims, %u total time (usec)\n",
1.1      cgd 	    sum.v_pgrec, rectime);
1.1      cgd 	(void)printf("average: %u usec / reclaim\n", rectime / sum.v_pgrec);
1.1      cgd 	(void)printf("\n");
1.1      cgd 	(void)printf("%u page ins, %u total time (msec)\n",
1.1      cgd 	    sum.v_pgin, pgintime / 10);
1.1      cgd 	(void)printf("average: %8.1f msec / page in\n",
1.1      cgd 	    pgintime / (sum.v_pgin * 10.0));
1.1      cgd }
1.1      cgd #endif
1.1      cgd
1.1      cgd pct(top, bot)
1.1      cgd 	long top, bot;
1.1      cgd {
1.1      cgd 	if (bot == 0)
1.1      cgd 		return(0);
1.1      cgd 	return((top * 100) / bot);
1.1      cgd }
1.1      cgd
1.1      cgd #define	PCT(top, bot) pct((long)(top), (long)(bot))
1.1      cgd
1.1      cgd #if defined(tahoe)
1.1      cgd #include <machine/cpu.h>
1.1      cgd #endif
1.1      cgd
1.1      cgd void
1.1      cgd dosum()
1.1      cgd {
1.1      cgd 	struct nchstats nchstats;
1.1      cgd #ifndef NEWVM
1.1      cgd 	struct xstats xstats;
1.1      cgd #endif
1.1      cgd 	long nchtotal;
1.1      cgd #if defined(tahoe)
1.1      cgd 	struct keystats keystats;
1.1      cgd #endif
1.1      cgd
1.1      cgd 	kread(X_SUM, &sum, sizeof(sum));
1.1      cgd #ifdef NEWVM
1.1      cgd 	kread(X_VMSTAT, &vm_stat, sizeof(vm_stat));
1.1      cgd #ifdef __386BSD__
1.1      cgd 	fill_in_vm_stat(&vm_stat);
1.1      cgd #endif
1.1      cgd #else
1.1      cgd 	(void)printf("%9u swap ins\n", sum.v_swpin);
1.1      cgd 	(void)printf("%9u swap outs\n", sum.v_swpout);
1.1      cgd 	(void)printf("%9u pages swapped in\n", sum.v_pswpin / CLSIZE);
1.1      cgd 	(void)printf("%9u pages swapped out\n", sum.v_pswpout / CLSIZE);
1.1      cgd 	(void)printf("%9u total address trans. faults taken\n", sum.v_faults);
1.1      cgd 	(void)printf("%9u page ins\n", sum.v_pgin);
1.1      cgd 	(void)printf("%9u page outs\n", sum.v_pgout);
1.1      cgd 	(void)printf("%9u pages paged in\n", sum.v_pgpgin);
1.1      cgd 	(void)printf("%9u pages paged out\n", sum.v_pgpgout);
1.1      cgd 	(void)printf("%9u sequential process pages freed\n", sum.v_seqfree);
1.1      cgd 	(void)printf("%9u total reclaims (%d%% fast)\n", sum.v_pgrec,
1.1      cgd 	    PCT(sum.v_fastpgrec, sum.v_pgrec));
1.1      cgd 	(void)printf("%9u reclaims from free list\n", sum.v_pgfrec);
1.1      cgd 	(void)printf("%9u intransit blocking page faults\n", sum.v_intrans);
1.1      cgd 	(void)printf("%9u zero fill pages created\n", sum.v_nzfod / CLSIZE);
1.1      cgd 	(void)printf("%9u zero fill page faults\n", sum.v_zfod / CLSIZE);
1.1      cgd 	(void)printf("%9u executable fill pages created\n",
1.1      cgd 	    sum.v_nexfod / CLSIZE);
1.1      cgd 	(void)printf("%9u executable fill page faults\n",
1.1      cgd 	    sum.v_exfod / CLSIZE);
1.1      cgd 	(void)printf("%9u swap text pages found in free list\n",
1.1      cgd 	    sum.v_xsfrec);
1.1      cgd 	(void)printf("%9u inode text pages found in free list\n",
1.1      cgd 	    sum.v_xifrec);
1.1      cgd 	(void)printf("%9u file fill pages created\n", sum.v_nvrfod / CLSIZE);
1.1      cgd 	(void)printf("%9u file fill page faults\n", sum.v_vrfod / CLSIZE);
1.1      cgd 	(void)printf("%9u pages examined by the clock daemon\n", sum.v_scan);
1.1      cgd 	(void)printf("%9u revolutions of the clock hand\n", sum.v_rev);
1.1      cgd 	(void)printf("%9u pages freed by the clock daemon\n",
1.1      cgd 	    sum.v_dfree / CLSIZE);
1.1      cgd #endif
1.1      cgd 	(void)printf("%9u cpu context switches\n", sum.v_swtch);
1.1      cgd 	(void)printf("%9u device interrupts\n", sum.v_intr);
1.1      cgd 	(void)printf("%9u software interrupts\n", sum.v_soft);
1.1      cgd #ifdef vax
1.1      cgd 	(void)printf("%9u pseudo-dma dz interrupts\n", sum.v_pdma);
1.1      cgd #endif
1.1      cgd 	(void)printf("%9u traps\n", sum.v_trap);
1.1      cgd 	(void)printf("%9u system calls\n", sum.v_syscall);
1.1      cgd #ifdef NEWVM
1.1      cgd 	(void)printf("%9u bytes per page\n", vm_stat.pagesize);
1.1      cgd 	(void)printf("%9u pages free\n", vm_stat.free_count);
1.1      cgd 	(void)printf("%9u pages active\n", vm_stat.active_count);
1.1      cgd 	(void)printf("%9u pages inactive\n", vm_stat.inactive_count);
1.1      cgd 	(void)printf("%9u pages wired down\n", vm_stat.wire_count);
1.1      cgd 	(void)printf("%9u zero-fill pages\n", vm_stat.zero_fill_count);
1.1      cgd 	(void)printf("%9u pages reactivated\n", vm_stat.reactivations);
1.1      cgd 	(void)printf("%9u pageins\n", vm_stat.pageins);
1.1      cgd 	(void)printf("%9u pageouts\n", vm_stat.pageouts);
1.1      cgd 	(void)printf("%9u VM faults\n", vm_stat.faults);
1.1      cgd 	(void)printf("%9u copy-on-write faults\n", vm_stat.cow_faults);
1.1      cgd 	(void)printf("%9u VM object cache lookups\n", vm_stat.lookups);
1.1      cgd 	(void)printf("%9u VM object hits\n", vm_stat.hits);
1.1      cgd #endif
1.1      cgd
1.1      cgd 	kread(X_NCHSTATS, &nchstats, sizeof(nchstats));
1.1      cgd 	nchtotal = nchstats.ncs_goodhits + nchstats.ncs_neghits +
1.1      cgd 	    nchstats.ncs_badhits + nchstats.ncs_falsehits +
1.1      cgd 	    nchstats.ncs_miss + nchstats.ncs_long;
1.1      cgd 	(void)printf("%9ld total name lookups\n", nchtotal);
1.1      cgd 	(void)printf(
1.1      cgd 	    "%9s cache hits (%d%% pos + %d%% neg) system %d%% per-process\n",
1.1      cgd 	    "", PCT(nchstats.ncs_goodhits, nchtotal),
1.1      cgd 	    PCT(nchstats.ncs_neghits, nchtotal),
1.1      cgd 	    PCT(nchstats.ncs_pass2, nchtotal));
1.1      cgd 	(void)printf("%9s deletions %d%%, falsehits %d%%, toolong %d%%\n", "",
1.1      cgd 	    PCT(nchstats.ncs_badhits, nchtotal),
1.1      cgd 	    PCT(nchstats.ncs_falsehits, nchtotal),
1.1      cgd 	    PCT(nchstats.ncs_long, nchtotal));
1.1      cgd #ifndef NEWVM
1.1      cgd 	kread(X_XSTATS, &xstats, sizeof(xstats));
1.1      cgd 	(void)printf("%9lu total calls to xalloc (cache hits %d%%)\n",
1.1      cgd 	    xstats.alloc, PCT(xstats.alloc_cachehit, xstats.alloc));
1.1      cgd 	(void)printf("%9s sticky %lu flushed %lu unused %lu\n", "",
1.1      cgd 	    xstats.alloc_inuse, xstats.alloc_cacheflush, xstats.alloc_unused);
1.1      cgd 	(void)printf("%9lu total calls to xfree", xstats.free);
1.1      cgd 	(void)printf(" (sticky %lu cached %lu swapped %lu)\n",
1.1      cgd 	    xstats.free_inuse, xstats.free_cache, xstats.free_cacheswap);
1.1      cgd #endif
1.1      cgd #if defined(tahoe)
1.1      cgd 	kread(X_CKEYSTATS, &keystats, sizeof(keystats));
1.1      cgd 	(void)printf("%9d %s (free %d%% norefs %d%% taken %d%% shared %d%%)\n",
1.1      cgd 	    keystats.ks_allocs, "code cache keys allocated",
1.1      cgd 	    PCT(keystats.ks_allocfree, keystats.ks_allocs),
1.1      cgd 	    PCT(keystats.ks_norefs, keystats.ks_allocs),
1.1      cgd 	    PCT(keystats.ks_taken, keystats.ks_allocs),
1.1      cgd 	    PCT(keystats.ks_shared, keystats.ks_allocs));
1.1      cgd 	kread(X_DKEYSTATS, &keystats, sizeof(keystats));
1.1      cgd 	(void)printf("%9d %s (free %d%% norefs %d%% taken %d%% shared %d%%)\n",
1.1      cgd 	    keystats.ks_allocs, "data cache keys allocated",
1.1      cgd 	    PCT(keystats.ks_allocfree, keystats.ks_allocs),
1.1      cgd 	    PCT(keystats.ks_norefs, keystats.ks_allocs),
1.1      cgd 	    PCT(keystats.ks_taken, keystats.ks_allocs),
1.1      cgd 	    PCT(keystats.ks_shared, keystats.ks_allocs));
1.1      cgd #endif
1.1      cgd }
1.1      cgd
1.1      cgd #ifdef notdef
1.1      cgd void
1.1      cgd doforkst()
1.1      cgd {
1.1      cgd 	struct forkstat fks;
1.1      cgd
1.1      cgd 	kread(X_FORKSTAT, &fks, sizeof(struct forkstat));
1.1      cgd 	(void)printf("%d forks, %d pages, average %.2f\n",
1.1      cgd 	    fks.cntfork, fks.sizfork, (double)fks.sizfork / fks.cntfork);
1.1      cgd 	(void)printf("%d vforks, %d pages, average %.2f\n",
1.1      cgd 	    fks.cntvfork, fks.sizvfork, (double)fks.sizvfork / fks.cntvfork);
1.1      cgd }
1.1      cgd #endif
1.1      cgd
1.1      cgd void
1.1      cgd dkstats()
1.1      cgd {
1.1      cgd 	register int dn, state;
1.1      cgd 	double etime;
1.1      cgd 	long tmp;
1.1      cgd
1.1      cgd 	for (dn = 0; dn < dk_ndrive; ++dn) {
1.1      cgd 		tmp = cur.xfer[dn];
1.1      cgd 		cur.xfer[dn] -= last.xfer[dn];
1.1      cgd 		last.xfer[dn] = tmp;
1.1      cgd 	}
1.1      cgd 	etime = 0;
1.1      cgd 	for (state = 0; state < CPUSTATES; ++state) {
1.1      cgd 		tmp = cur.time[state];
1.1      cgd 		cur.time[state] -= last.time[state];
1.1      cgd 		last.time[state] = tmp;
1.1      cgd 		etime += cur.time[state];
1.1      cgd 	}
1.1      cgd 	if (etime == 0)
1.1      cgd 		etime = 1;
1.1      cgd 	etime /= hz;
1.1      cgd 	for (dn = 0; dn < dk_ndrive; ++dn) {
1.1      cgd 		if (!dr_select[dn])
1.1      cgd 			continue;
1.1      cgd 		(void)printf("%2.0f ", cur.xfer[dn] / etime);
1.1      cgd 	}
1.1      cgd }
1.1      cgd
1.1      cgd void
1.1      cgd cpustats()
1.1      cgd {
1.1      cgd 	register int state;
1.1      cgd 	double pct, total;
1.1      cgd
1.1      cgd 	total = 0;
1.1      cgd 	for (state = 0; state < CPUSTATES; ++state)
1.1      cgd 		total += cur.time[state];
1.1      cgd 	if (total)
1.1      cgd 		pct = 100 / total;
1.1      cgd 	else
1.1      cgd 		pct = 0;
1.1      cgd 	(void)printf("%2.0f ",				/* user + nice */
1.1      cgd 	    (cur.time[0] + cur.time[1]) * pct);
1.1      cgd 	(void)printf("%2.0f ", cur.time[2] * pct);	/* system */
1.1      cgd 	(void)printf("%2.0f", cur.time[3] * pct);	/* idle */
1.1      cgd }
1.1      cgd
1.1      cgd void
1.1      cgd dointr()
1.1      cgd {
1.5      cgd 	register unsigned long *intrcnt, inttotal, uptime;
1.1      cgd 	register int nintr, inamlen;
1.1      cgd 	register char *intrname;
1.1      cgd
1.1      cgd 	uptime = getuptime();
1.1      cgd 	nintr = nl[X_EINTRCNT].n_value - nl[X_INTRCNT].n_value;
1.1      cgd 	inamlen = nl[X_EINTRNAMES].n_value - nl[X_INTRNAMES].n_value;
1.1      cgd 	intrcnt = malloc((size_t)nintr);
1.1      cgd 	intrname = malloc((size_t)inamlen);
1.1      cgd 	if (intrcnt == NULL || intrname == NULL) {
1.1      cgd 		(void)fprintf(stderr, "vmstat: %s.\n", strerror(errno));
1.1      cgd 		exit(1);
1.1      cgd 	}
1.1      cgd 	kread(X_INTRCNT, intrcnt, (size_t)nintr);
1.1      cgd 	kread(X_INTRNAMES, intrname, (size_t)inamlen);
1.5      cgd 	(void)printf("%-12s %10s %8s\n", "interrupt", "count", "rate");
1.1      cgd 	inttotal = 0;
1.1      cgd 	nintr /= sizeof(long);
1.1      cgd 	while (--nintr >= 0) {
1.1      cgd 		if (*intrcnt)
1.5      cgd 			(void)printf("%-12s %10lu %8lu\n", intrname,
1.1      cgd 			    *intrcnt, *intrcnt / uptime);
1.1      cgd 		intrname += strlen(intrname) + 1;
1.1      cgd 		inttotal += *intrcnt++;
1.1      cgd 	}
1.5      cgd 	(void)printf("%-12s %10lu %8lu\n", "Total", inttotal, inttotal / uptime);
1.1      cgd }
1.1      cgd
1.1      cgd /*
1.1      cgd  * These names are defined in <sys/malloc.h>.
1.1      cgd  */
1.1      cgd char *kmemnames[] = INITKMEMNAMES;
1.1      cgd
1.1      cgd void
1.1      cgd domem()
1.1      cgd {
1.1      cgd 	register struct kmembuckets *kp;
1.1      cgd 	register struct kmemstats *ks;
1.1      cgd 	register int i;
1.1      cgd 	int size;
1.9  deraadt 	long totuse = 0, totfree = 0, totreq = 0, totwaste = 0;
1.4      cgd 	struct kmemstats kmemstats[M_LAST + 1];
1.1      cgd 	struct kmembuckets buckets[MINBUCKET + 16];
1.1      cgd
1.1      cgd 	kread(X_KMEMBUCKETS, buckets, sizeof(buckets));
1.1      cgd 	(void)printf("Memory statistics by bucket size\n");
1.1      cgd 	(void)printf(
1.1      cgd 	    "    Size   In Use   Free   Requests  HighWater  Couldfree\n");
1.1      cgd 	for (i = MINBUCKET, kp = &buckets[i]; i < MINBUCKET + 16; i++, kp++) {
1.1      cgd 		if (kp->kb_calls == 0)
1.1      cgd 			continue;
1.1      cgd 		size = 1 << i;
1.1      cgd 		(void)printf("%8d %8ld %6ld %10ld %7ld %10ld\n", size,
1.1      cgd 			kp->kb_total - kp->kb_totalfree,
1.1      cgd 			kp->kb_totalfree, kp->kb_calls,
1.1      cgd 			kp->kb_highwat, kp->kb_couldfree);
1.1      cgd 		totfree += size * kp->kb_totalfree;
1.9  deraadt 		if (kp->kb_highwat < kp->kb_totalfree)
1.9  deraadt 			totwaste += (kp->kb_totalfree - kp->kb_highwat) * size;
1.1      cgd 	}
1.1      cgd
1.1      cgd 	kread(X_KMEMSTAT, kmemstats, sizeof(kmemstats));
1.1      cgd 	(void)printf("\nMemory statistics by type\n");
1.1      cgd 	(void)printf(
1.8      cgd "        Type  In Use  MemUse   HighUse  Limit Requests  TypeLimit KernLimit\n");
1.4      cgd 	for (i = 0, ks = &kmemstats[0]; i <= M_LAST; i++, ks++) {
1.1      cgd 		if (ks->ks_calls == 0)
1.1      cgd 			continue;
1.8      cgd 		(void)printf("%12s %6ld %7ldK %8ldK %5ldK %8ld %6u %9u\n",
1.1      cgd 		    kmemnames[i] ? kmemnames[i] : "undefined",
1.1      cgd 		    ks->ks_inuse, (ks->ks_memuse + 1023) / 1024,
1.1      cgd 		    (ks->ks_maxused + 1023) / 1024,
1.1      cgd 		    (ks->ks_limit + 1023) / 1024, ks->ks_calls,
1.1      cgd 		    ks->ks_limblocks, ks->ks_mapblocks);
1.1      cgd 		totuse += ks->ks_memuse;
1.1      cgd 		totreq += ks->ks_calls;
1.1      cgd 	}
1.9  deraadt 	(void)printf("\nMemory Totals:  In Use    Free   Wasted   Requests\n");
1.9  deraadt 	(void)printf("              %7ldK %6ldK  %6ldK   %8ld\n",
1.9  deraadt 	     (totuse + 1023) / 1024, (totfree + 1023) / 1024,
1.9  deraadt 	     (totwaste + 1023) / 1024, totreq);
1.1      cgd }
1.1      cgd
1.1      cgd /*
1.1      cgd  * kread reads something from the kernel, given its nlist index.
1.1      cgd  */
1.1      cgd void
1.1      cgd kread(nlx, addr, size)
1.1      cgd 	int nlx;
1.1      cgd 	void *addr;
1.1      cgd 	size_t size;
1.1      cgd {
1.1      cgd 	char *sym;
1.1      cgd
1.1      cgd 	if (nl[nlx].n_type == 0 || nl[nlx].n_value == 0) {
1.1      cgd 		sym = nl[nlx].n_name;
1.1      cgd 		if (*sym == '_')
1.1      cgd 			++sym;
1.1      cgd 		(void)fprintf(stderr,
1.1      cgd 		    "vmstat: %s: symbol %s not defined\n", vmunix, sym);
1.1      cgd 		exit(1);
1.1      cgd 	}
1.1      cgd 	if (kvm_read((void *)nl[nlx].n_value, addr, size) != size) {
1.1      cgd 		sym = nl[nlx].n_name;
1.1      cgd 		if (*sym == '_')
1.1      cgd 			++sym;
1.1      cgd 		(void)fprintf(stderr, "vmstat: %s: %s\n", sym, kvm_geterr());
1.1      cgd 		exit(1);
1.1      cgd 	}
1.1      cgd }
1.1      cgd
1.1      cgd void
1.1      cgd usage()
1.1      cgd {
1.1      cgd 	(void)fprintf(stderr,
1.1      cgd #ifndef NEWVM
1.1      cgd 	    "usage: vmstat [-fimst] [-c count] [-M core] \
1.1      cgd [-N system] [-w wait] [disks]\n");
1.1      cgd #else
1.1      cgd 	    "usage: vmstat [-ims] [-c count] [-M core] \
1.1      cgd [-N system] [-w wait] [disks]\n");
1.1      cgd #endif
1.1      cgd 	exit(1);
1.1      cgd }