NetBSD/usr.bin/systat/vmstat.c

936 lines
24 KiB
C

/* $NetBSD: vmstat.c,v 1.88 2020/03/02 09:50:12 mrg Exp $ */
/*-
* Copyright (c) 1983, 1989, 1992, 1993
* The Regents of the University of California. All rights reserved.
*
* 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. 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.
*/
#include <sys/cdefs.h>
#ifndef lint
#if 0
static char sccsid[] = "@(#)vmstat.c 8.2 (Berkeley) 1/12/94";
#endif
__RCSID("$NetBSD: vmstat.c,v 1.88 2020/03/02 09:50:12 mrg Exp $");
#endif /* not lint */
/*
* Cursed vmstat -- from Robert Elz.
*/
#include <sys/param.h>
#include <sys/uio.h>
#include <sys/namei.h>
#include <sys/sysctl.h>
#include <sys/evcnt.h>
#include <uvm/uvm_extern.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <util.h>
#include "systat.h"
#include "extern.h"
#include "drvstats.h"
#include "utmpentry.h"
#include "vmstat.h"
static struct Info {
struct uvmexp_sysctl uvmexp;
struct vmtotal Total;
struct nchstats nchstats;
long nchcount;
long *intrcnt;
u_int64_t *evcnt;
} s, s1, s2, z;
enum display_mode display_mode = TIME;
static void allocinfo(struct Info *);
static void copyinfo(struct Info *, struct Info *);
static float cputime(int);
static void dinfo(int, int, int);
static void getinfo(struct Info *);
static int ucount(void);
static char buf[26];
static u_int64_t temp;
static int nintr;
static long *intrloc;
static char **intrname;
static int nextintsrow;
static int disk_horiz = 1;
static u_int nbuf;
WINDOW *
openvmstat(void)
{
return (stdscr);
}
void
closevmstat(WINDOW *w)
{
if (w == NULL)
return;
wclear(w);
wrefresh(w);
}
static struct nlist namelist[] = {
#define X_INTRNAMES 0
{ .n_name = "_intrnames" },
#define X_EINTRNAMES 1
{ .n_name = "_eintrnames" },
#define X_INTRCNT 2
{ .n_name = "_intrcnt" },
#define X_EINTRCNT 3
{ .n_name = "_eintrcnt" },
#define X_ALLEVENTS 4
{ .n_name = "_allevents" },
{ .n_name = NULL }
};
/*
* These constants define where the major pieces are laid out
*/
#define STATROW 0 /* uses 1 row and 68 cols */
#define STATCOL 2
#define MEMROW 9 /* uses 5 rows and 31 cols */
#define MEMCOL 0
#define PAGEROW 2 /* uses 4 rows and 26 cols */
#define PAGECOL 54
#define INTSROW 9 /* uses all rows to bottom and 17 cols */
#define INTSCOL 40
#define INTSCOLEND (VMSTATCOL - 0)
#define PROCSROW 2 /* uses 2 rows and 20 cols */
#define PROCSCOL 0
#define GENSTATROW 2 /* uses 2 rows and 30 cols */
#define GENSTATCOL 17
#define VMSTATROW 7 /* uses 17 rows and 15 cols */
#define VMSTATCOL 64
#define GRAPHROW 5 /* uses 3 rows and 51 cols */
#define GRAPHCOL 0
#define NAMEIROW 15 /* uses 3 rows and 38 cols (must be MEMROW + 5 + 1) */
#define NAMEICOL 0
#define DISKROW 19 /* uses 5 rows and 50 cols (for 9 drives) */
#define DISKCOL 0
#define DISKCOLWIDTH 8
#define DISKCOLEND INTSCOL
typedef struct intr_evcnt intr_evcnt_t;
struct intr_evcnt {
char *ie_group;
char *ie_name;
u_int64_t *ie_count; /* kernel address... */
int ie_loc; /* screen row */
} *ie_head;
int nevcnt;
static void
get_interrupt_events(void)
{
struct evcntlist allevents;
struct evcnt evcnt, *evptr;
intr_evcnt_t *ie;
intr_evcnt_t *n;
if (!NREAD(X_ALLEVENTS, &allevents, sizeof allevents))
return;
evptr = TAILQ_FIRST(&allevents);
for (; evptr != NULL; evptr = TAILQ_NEXT(&evcnt, ev_list)) {
if (!KREAD(evptr, &evcnt, sizeof evcnt))
return;
if (evcnt.ev_type != EVCNT_TYPE_INTR)
continue;
n = realloc(ie_head, sizeof *ie * (nevcnt + 1));
if (n == NULL) {
error("realloc failed");
die(0);
}
ie_head = n;
ie = ie_head + nevcnt;
ie->ie_group = malloc(evcnt.ev_grouplen + 1);
ie->ie_name = malloc(evcnt.ev_namelen + 1);
if (ie->ie_group == NULL || ie->ie_name == NULL)
return;
if (!KREAD(evcnt.ev_group, ie->ie_group, evcnt.ev_grouplen + 1))
return;
if (!KREAD(evcnt.ev_name, ie->ie_name, evcnt.ev_namelen + 1))
return;
ie->ie_count = &evptr->ev_count;
ie->ie_loc = 0;
nevcnt++;
}
}
int
initvmstat(void)
{
static char *intrnamebuf;
char *cp;
int i;
if (intrnamebuf)
free(intrnamebuf);
if (intrname)
free(intrname);
if (intrloc)
free(intrloc);
if (namelist[0].n_type == 0) {
if (kvm_nlist(kd, namelist) &&
namelist[X_ALLEVENTS].n_type == 0) {
nlisterr(namelist);
return(0);
}
}
hertz = stathz ? stathz : hz;
if (!drvinit(1))
return(0);
/* Old style interrupt counts - deprecated */
nintr = (namelist[X_EINTRCNT].n_value -
namelist[X_INTRCNT].n_value) / sizeof (long);
if (nintr) {
intrloc = calloc(nintr, sizeof (long));
intrname = calloc(nintr, sizeof (long));
intrnamebuf = malloc(namelist[X_EINTRNAMES].n_value -
namelist[X_INTRNAMES].n_value);
if (intrnamebuf == NULL || intrname == 0 || intrloc == 0) {
error("Out of memory\n");
nintr = 0;
return(0);
}
NREAD(X_INTRNAMES, intrnamebuf, NVAL(X_EINTRNAMES) -
NVAL(X_INTRNAMES));
for (cp = intrnamebuf, i = 0; i < nintr; i++) {
intrname[i] = cp;
cp += strlen(cp) + 1;
}
}
/* event counter interrupt counts */
get_interrupt_events();
nextintsrow = INTSROW + 1;
allocinfo(&s);
allocinfo(&s1);
allocinfo(&s2);
allocinfo(&z);
getinfo(&s2);
copyinfo(&s2, &s1);
return(1);
}
void
fetchvmstat(void)
{
time_t now;
time(&now);
strlcpy(buf, ctime(&now), sizeof(buf));
buf[19] = '\0';
getinfo(&s);
}
static void
print_ie_title(int i)
{
int width, name_width, group_width;
width = INTSCOLEND - (INTSCOL + 9);
if (width <= 0)
return;
move(ie_head[i].ie_loc, INTSCOL + 9);
group_width = strlen(ie_head[i].ie_group);
name_width = strlen(ie_head[i].ie_name);
width -= group_width + 1 + name_width;
if (width < 0) {
/*
* Screen to narrow for full strings
* This is all rather horrid, in some cases there are a lot
* of events in the same group, and in others the event
* name is "intr". There are also names which need 7 or 8
* columns before they become meaningful.
* This is a bad compromise.
*/
width = -width;
group_width -= (width + 1) / 2;
name_width -= width / 2;
/* some have the 'useful' name "intr", display their group */
if (strcasecmp(ie_head[i].ie_name, "intr") == 0) {
group_width += name_width + 1;
name_width = 0;
} else {
if (group_width <= 3 || name_width < 0) {
/* don't display group */
name_width += group_width + 1;
group_width = 0;
}
}
}
if (group_width != 0) {
printw("%-.*s", group_width, ie_head[i].ie_group);
if (name_width != 0)
printw(" ");
}
if (name_width != 0)
printw("%-.*s", name_width, ie_head[i].ie_name);
}
void
labelvmstat_top(void)
{
clear();
mvprintw(STATROW, STATCOL + 4, "users Load");
mvprintw(GENSTATROW, GENSTATCOL, " Csw Traps SysCal Intr Soft Fault");
mvprintw(GRAPHROW, GRAPHCOL,
" . %% Sy . %% Us . %% Ni . %% In . %% Id");
mvprintw(PROCSROW, PROCSCOL, "Proc:r d s");
mvprintw(GRAPHROW + 1, GRAPHCOL,
"| | | | | | | | | | |");
mvprintw(PAGEROW, PAGECOL + 8, "PAGING SWAPPING ");
mvprintw(PAGEROW + 1, PAGECOL, " in out in out ");
mvprintw(PAGEROW + 2, PAGECOL, " ops ");
mvprintw(PAGEROW + 3, PAGECOL, "pages ");
}
void
labelvmstat(void)
{
int i;
/* Top few lines first */
labelvmstat_top();
/* Left hand column */
mvprintw(MEMROW + 0, MEMCOL, "Anon %% zero ");
mvprintw(MEMROW + 1, MEMCOL, "Exec %% wired ");
mvprintw(MEMROW + 2, MEMCOL, "File %% inact ");
mvprintw(MEMROW + 3, MEMCOL, "Meta %% bufs ");
mvprintw(MEMROW + 4, MEMCOL, " (kB) real swaponly free");
mvprintw(MEMROW + 5, MEMCOL, "Active ");
mvprintw(NAMEIROW, NAMEICOL, "Namei Sys-cache Proc-cache");
mvprintw(NAMEIROW + 1, NAMEICOL,
" Calls hits %% hits %%");
mvprintw(DISKROW, DISKCOL, "%*s", DISKCOLWIDTH, "Disks:");
if (disk_horiz) {
mvprintw(DISKROW + 1, DISKCOL + 1, "seeks");
mvprintw(DISKROW + 2, DISKCOL + 1, "xfers");
mvprintw(DISKROW + 3, DISKCOL + 1, "bytes");
mvprintw(DISKROW + 4, DISKCOL + 1, "%%busy");
} else {
mvprintw(DISKROW, DISKCOL + 1 * DISKCOLWIDTH, "%*s", DISKCOLWIDTH, "seeks");
mvprintw(DISKROW, DISKCOL + 2 * DISKCOLWIDTH, "%*s", DISKCOLWIDTH, "xfers");
mvprintw(DISKROW, DISKCOL + 3 * DISKCOLWIDTH, "%*s", DISKCOLWIDTH, "bytes");
mvprintw(DISKROW, DISKCOL + 4 * DISKCOLWIDTH, "%*s", DISKCOLWIDTH, "%busy");
}
/* Middle column */
mvprintw(INTSROW, INTSCOL + 9, "Interrupts");
for (i = 0; i < nintr; i++) {
if (intrloc[i] == 0)
continue;
mvprintw(intrloc[i], INTSCOL + 9, "%-.*s",
INTSCOLEND - (INTSCOL + 9), intrname[i]);
}
for (i = 0; i < nevcnt; i++) {
if (ie_head[i].ie_loc == 0)
continue;
print_ie_title(i);
}
/* Right hand column */
mvprintw(VMSTATROW + 0, VMSTATCOL + 10, "forks");
mvprintw(VMSTATROW + 1, VMSTATCOL + 10, "fkppw");
mvprintw(VMSTATROW + 2, VMSTATCOL + 10, "fksvm");
mvprintw(VMSTATROW + 3, VMSTATCOL + 10, "pwait");
mvprintw(VMSTATROW + 4, VMSTATCOL + 10, "relck");
mvprintw(VMSTATROW + 5, VMSTATCOL + 10, "rlkok");
mvprintw(VMSTATROW + 6, VMSTATCOL + 10, "noram");
mvprintw(VMSTATROW + 7, VMSTATCOL + 10, "ndcpy");
mvprintw(VMSTATROW + 8, VMSTATCOL + 10, "fltcp");
mvprintw(VMSTATROW + 9, VMSTATCOL + 10, "zfod");
mvprintw(VMSTATROW + 10, VMSTATCOL + 10, "cow");
mvprintw(VMSTATROW + 11, VMSTATCOL + 10, "fmin");
mvprintw(VMSTATROW + 12, VMSTATCOL + 10, "ftarg");
mvprintw(VMSTATROW + 13, VMSTATCOL + 10, "itarg");
mvprintw(VMSTATROW + 14, VMSTATCOL + 10, "flnan");
mvprintw(VMSTATROW + 15, VMSTATCOL + 10, "pdfre");
if (LINES - 1 > VMSTATROW + 16)
mvprintw(VMSTATROW + 16, VMSTATCOL + 10, "pdscn");
}
#define X(s, s1, fld) {temp = (s).fld[i]; (s).fld[i] -= (s1).fld[i]; \
if (display_mode == TIME) (s1).fld[i] = temp;}
#define Z(s, s1, fld) {temp = (s).nchstats.fld; \
(s).nchstats.fld -= (s1).nchstats.fld; \
if (display_mode == TIME) (s1).nchstats.fld = temp;}
#define PUTRATE(s, s1, fld, l, c, w) \
{temp = (s).fld; (s).fld -= (s1).fld; \
if (display_mode == TIME) (s1).fld = temp; \
putint((int)((float)(s).fld/etime + 0.5), l, c, w);}
static char cpuchar[CPUSTATES] = { '=' , '>', '-', '%', ' ' };
static char cpuorder[CPUSTATES] = { CP_SYS, CP_USER, CP_NICE, CP_INTR, CP_IDLE };
void
show_vmstat_top(vmtotal_t *Total, uvmexp_sysctl_t *uvm, uvmexp_sysctl_t *uvm1)
{
float f1, f2;
int psiz;
int i, l, c;
struct {
struct uvmexp_sysctl *uvmexp;
} us, us1;
us.uvmexp = uvm;
us1.uvmexp = uvm1;
putint(ucount(), STATROW, STATCOL, 3);
putfloat(avenrun[0], STATROW, STATCOL + 17, 6, 2, 0);
putfloat(avenrun[1], STATROW, STATCOL + 23, 6, 2, 0);
putfloat(avenrun[2], STATROW, STATCOL + 29, 6, 2, 0);
mvaddstr(STATROW, STATCOL + 53, buf);
putint(Total->t_rq - 1, PROCSROW + 1, PROCSCOL + 3, 3);
putint(Total->t_dw, PROCSROW + 1, PROCSCOL + 6, 3);
putint(Total->t_sl, PROCSROW + 1, PROCSCOL + 9, 3);
PUTRATE(us, us1, uvmexp->swtch, GENSTATROW + 1, GENSTATCOL - 1, 7);
PUTRATE(us, us1, uvmexp->traps, GENSTATROW + 1, GENSTATCOL + 7, 6);
PUTRATE(us, us1, uvmexp->syscalls, GENSTATROW + 1, GENSTATCOL + 14, 6);
PUTRATE(us, us1, uvmexp->intrs, GENSTATROW + 1, GENSTATCOL + 21, 5);
PUTRATE(us, us1, uvmexp->softs, GENSTATROW + 1, GENSTATCOL + 27, 6);
PUTRATE(us, us1, uvmexp->faults, GENSTATROW + 1, GENSTATCOL + 34, 6);
/*
* XXX it sure would be nice if this did what top(1) does and showed
* the utilization of each CPU on a separate line, though perhaps IFF
* the screen is tall enough
*/
/* Last CPU state not calculated yet. */
for (f2 = 0.0, psiz = 0, c = 0; c < CPUSTATES; c++) {
i = cpuorder[c];
f1 = cputime(i);
f2 += f1;
l = (int) ((f2 + 1.0) / 2.0) - psiz;
if (c == 0)
putfloat(f1, GRAPHROW, GRAPHCOL + 1, 5, 1, 0);
else
putfloat(f1, GRAPHROW, GRAPHCOL + 10 * c + 1, 5, 1, 0);
mvhline(GRAPHROW + 2, psiz, cpuchar[c], l);
psiz += l;
}
PUTRATE(us, us1, uvmexp->pageins, PAGEROW + 2, PAGECOL + 5, 5);
PUTRATE(us, us1, uvmexp->pdpageouts, PAGEROW + 2, PAGECOL + 10, 5);
PUTRATE(us, us1, uvmexp->pgswapin, PAGEROW + 3, PAGECOL + 5, 5);
PUTRATE(us, us1, uvmexp->pgswapout, PAGEROW + 3, PAGECOL + 10, 5);
}
void
showvmstat(void)
{
int inttotal;
int i, l, r, c;
static int failcnt = 0;
static int relabel = 0;
static int last_disks = 0;
static u_long bufmem;
struct buf_sysctl *buffers;
int mib[6];
size_t size;
int extraslop = 0;
if (relabel) {
labelvmstat();
relabel = 0;
}
cpuswap();
if (display_mode == TIME) {
drvswap();
if (toofast(&failcnt))
return;
} else
etime = 1.0;
show_vmstat_top(&s.Total, &s.uvmexp, &s1.uvmexp);
/* Memory totals */
#define pgtokb(pg) ((pg) * (s.uvmexp.pagesize / 1024))
putint(pgtokb(s.uvmexp.anonpages), MEMROW + 0, MEMCOL + 7, 10);
putint((s.uvmexp.anonpages * 100 + 0.5) / s.uvmexp.npages, MEMROW + 0, MEMCOL + 17, 4);
putint(pgtokb(s.uvmexp.zeropages), MEMROW + 0, MEMCOL + 30, 8);
putint(pgtokb(s.uvmexp.execpages), MEMROW + 1, MEMCOL + 7, 10);
putint((s.uvmexp.execpages * 100 + 0.5) / s.uvmexp.npages, MEMROW + 1, MEMCOL + 17, 4);
putint(pgtokb(s.uvmexp.wired), MEMROW + 1, MEMCOL + 30, 8);
putint(pgtokb(s.uvmexp.filepages), MEMROW + 2, MEMCOL + 7, 10);
putint((s.uvmexp.filepages * 100 + 0.5) / s.uvmexp.npages, MEMROW + 2, MEMCOL + 17, 4);
putint(pgtokb(s.uvmexp.inactive), MEMROW + 2, MEMCOL + 30, 8);
/* Get total size of metadata buffers */
size = sizeof(bufmem);
if (sysctlbyname("vm.bufmem", &bufmem, &size, NULL, 0) < 0) {
error("can't get buffers size: %s\n", strerror(errno));
return;
}
/* Get number of metadata buffers */
size = 0;
buffers = NULL;
mib[0] = CTL_KERN;
mib[1] = KERN_BUF;
mib[2] = KERN_BUF_ALL;
mib[3] = KERN_BUF_ALL;
mib[4] = (int)sizeof(struct buf_sysctl);
mib[5] = INT_MAX; /* we want them all */
again:
if (sysctl(mib, 6, NULL, &size, NULL, 0) < 0) {
error("can't get buffers size: %s\n", strerror(errno));
return;
}
if (size == 0) {
error("buffers size is zero: %s\n", strerror(errno));
return;
}
size += extraslop * sizeof(struct buf_sysctl);
buffers = malloc(size);
if (buffers == NULL) {
error("can't allocate buffers: %s\n", strerror(errno));
return;
}
if (sysctl(mib, 6, buffers, &size, NULL, 0) < 0) {
free(buffers);
if (extraslop < 1000) {
extraslop += 100;
goto again;
}
error("can't get buffers: %s\n", strerror(errno));
return;
}
free(buffers); /* XXX there must be a better way! */
nbuf = size / sizeof(struct buf_sysctl);
putint((int) (bufmem / 1024), MEMROW + 3, MEMCOL + 5, 12);
putint((int) ((bufmem * 100) + 0.5) / s.uvmexp.pagesize / s.uvmexp.npages,
MEMROW + 3, MEMCOL + 17, 4);
putint(nbuf, MEMROW + 3, MEMCOL + 30, 8);
putint(pgtokb(s.uvmexp.active), MEMROW + 5, MEMCOL + 7, 10);
putint(pgtokb(s.uvmexp.swpgonly), MEMROW + 5, MEMCOL + 18, 10);
putint(pgtokb(s.uvmexp.free), MEMROW + 5, MEMCOL + 28, 10);
#undef pgtokb
/* Namei cache */
Z(s, s1, ncs_goodhits); Z(s, s1, ncs_badhits); Z(s, s1, ncs_miss);
Z(s, s1, ncs_long); Z(s, s1, ncs_pass2); Z(s, s1, ncs_2passes);
s.nchcount = s.nchstats.ncs_goodhits + s.nchstats.ncs_badhits +
s.nchstats.ncs_miss + s.nchstats.ncs_long +
s.nchstats.ncs_pass2 + s.nchstats.ncs_2passes;
if (display_mode == TIME)
s1.nchcount = s.nchcount;
putint(s.nchcount, NAMEIROW + 2, NAMEICOL, 9);
putint(s.nchstats.ncs_goodhits, NAMEIROW + 2, NAMEICOL + 9, 9);
#define nz(x) ((x) ? (x) : 1)
putfloat(s.nchstats.ncs_goodhits * 100.0 / nz(s.nchcount),
NAMEIROW + 2, NAMEICOL + 19, 4, 0, 1);
putint(s.nchstats.ncs_pass2, NAMEIROW + 2, NAMEICOL + 23, 9);
putfloat(s.nchstats.ncs_pass2 * 100.0 / nz(s.nchcount),
NAMEIROW + 2, NAMEICOL + 34, 4, 0, 1);
#undef nz
/* Disks */
for (l = 0, i = 0, r = DISKROW, c = DISKCOL;
i < (int)ndrive; i++) {
if (!drv_select[i])
continue;
if (disk_horiz)
c += DISKCOLWIDTH;
else
r++;
if (c + DISKCOLWIDTH > DISKCOLEND) {
if (disk_horiz && LINES - 1 - DISKROW >
(DISKCOLEND - DISKCOL) / DISKCOLWIDTH) {
disk_horiz = 0;
relabel = 1;
}
break;
}
if (r >= LINES - 1) {
if (!disk_horiz && LINES - 1 - DISKROW <
(DISKCOLEND - DISKCOL) / DISKCOLWIDTH) {
disk_horiz = 1;
relabel = 1;
}
break;
}
l++;
dinfo(i, r, c);
}
/* blank out if we lost any disks */
for (i = l; i < last_disks; i++) {
int j;
if (disk_horiz)
c += DISKCOLWIDTH;
else
r++;
for (j = 0; j < 5; j++) {
if (disk_horiz)
mvprintw(r+j, c, "%*s", DISKCOLWIDTH, "");
else
mvprintw(r, c+j*DISKCOLWIDTH, "%*s", DISKCOLWIDTH, "");
}
}
last_disks = l;
/* Interrupts */
failcnt = 0;
inttotal = 0;
for (i = 0; i < nintr; i++) {
if (s.intrcnt[i] == 0)
continue;
if (intrloc[i] == 0) {
if (nextintsrow == LINES)
continue;
intrloc[i] = nextintsrow++;
mvprintw(intrloc[i], INTSCOL + 9, "%-.*s",
INTSCOLEND - (INTSCOL + 9), intrname[i]);
}
X(s, s1, intrcnt);
l = (int)((float)s.intrcnt[i]/etime + 0.5);
inttotal += l;
putint(l, intrloc[i], INTSCOL, 8);
}
for (i = 0; i < nevcnt; i++) {
if (s.evcnt[i] == 0)
continue;
if (ie_head[i].ie_loc == 0) {
if (nextintsrow == LINES)
continue;
ie_head[i].ie_loc = nextintsrow++;
print_ie_title(i);
}
X(s, s1, evcnt);
l = (int)((float)s.evcnt[i]/etime + 0.5);
inttotal += l;
putint(l, ie_head[i].ie_loc, INTSCOL, 8);
}
putint(inttotal, INTSROW, INTSCOL, 8);
PUTRATE(s, s1, uvmexp.forks, VMSTATROW + 0, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.forks_ppwait, VMSTATROW + 1, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.forks_sharevm, VMSTATROW + 2, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.fltpgwait, VMSTATROW + 3, VMSTATCOL + 4, 5);
PUTRATE(s, s1, uvmexp.fltrelck, VMSTATROW + 4, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.fltrelckok, VMSTATROW + 5, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.fltnoram, VMSTATROW + 6, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.fltamcopy, VMSTATROW + 7, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.flt_prcopy, VMSTATROW + 8, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.flt_przero, VMSTATROW + 9, VMSTATCOL + 3, 6);
PUTRATE(s, s1, uvmexp.flt_acow, VMSTATROW + 10, VMSTATCOL, 9);
putint(s.uvmexp.freemin, VMSTATROW + 11, VMSTATCOL, 9);
putint(s.uvmexp.freetarg, VMSTATROW + 12, VMSTATCOL, 9);
putint(s.uvmexp.inactarg, VMSTATROW + 13, VMSTATCOL, 9);
putint(s.uvmexp.fltnoanon, VMSTATROW + 14, VMSTATCOL, 9);
PUTRATE(s, s1, uvmexp.pdfreed, VMSTATROW + 15, VMSTATCOL, 9);
if (LINES - 1 > VMSTATROW + 16)
PUTRATE(s, s1, uvmexp.pdscans, VMSTATROW + 16, VMSTATCOL, 9);
}
void
vmstat_boot(char *args)
{
copyinfo(&z, &s1);
display_mode = BOOT;
}
void
vmstat_run(char *args)
{
copyinfo(&s1, &s2);
display_mode = RUN;
}
void
vmstat_time(char *args)
{
display_mode = TIME;
}
void
vmstat_zero(char *args)
{
if (display_mode == RUN)
getinfo(&s1);
}
/* calculate number of users on the system */
static int
ucount(void)
{
static int onusers = -1;
int nusers = 0;
struct utmpentry *ehead;
nusers = getutentries(NULL, &ehead);
if (nusers != onusers) {
if (nusers == 1)
mvprintw(STATROW, STATCOL + 8, " ");
else
mvprintw(STATROW, STATCOL + 8, "s");
}
onusers = nusers;
return (nusers);
}
static float
cputime(int indx)
{
double t;
int i;
t = 0;
for (i = 0; i < CPUSTATES; i++)
t += cur.cp_time[i];
if (t == 0.0)
t = 1.0;
return (cur.cp_time[indx] * 100.0 / t);
}
void
puthumanint_scale(u_int64_t n, int l, int c, int w, int scale)
{
char b[128];
if (move(l, c) != OK)
return;
if (n == 0) {
hline(' ', w);
return;
}
if (humanize_number(b, w, n, "", scale, HN_NOSPACE) == -1 ) {
hline('*', w);
return;
}
printw("%*s", w, b);
}
void
puthumanint_sticky(u_int64_t n, int l, int c, int w, int *scale)
{
char b[128];
int sc;
sc = humanize_number(b, w, n, "", HN_GETSCALE, HN_NOSPACE);
if (sc > *scale)
*scale = sc;
else
sc = *scale;
puthumanint_scale(n, l, c, w, sc);
}
void
puthumanint(u_int64_t n, int l, int c, int w)
{
puthumanint_scale(n, l, c, w, HN_AUTOSCALE);
}
void
putint(int n, int l, int c, int w)
{
char b[128];
if (move(l, c) != OK)
return;
if (n == 0) {
hline(' ', w);
return;
}
(void)snprintf(b, sizeof b, "%*d", w, n);
if ((int)strlen(b) > w) {
if (display_mode == TIME)
hline('*', w);
else
puthumanint(n, l, c, w);
return;
}
addstr(b);
}
void
putfloat(double f, int l, int c, int w, int d, int nz)
{
char b[128];
if (move(l, c) != OK)
return;
if (nz && f == 0.0) {
hline(' ', w);
return;
}
(void)snprintf(b, sizeof b, "%*.*f", w, d, f);
if ((int)strlen(b) > w) {
hline('*', w);
return;
}
addstr(b);
}
static void
getinfo(struct Info *stats)
{
int mib[2];
size_t size;
int i;
cpureadstats();
drvreadstats();
size = sizeof(stats->nchstats);
if (sysctlbyname("vfs.namecache_stats", &stats->nchstats, &size,
NULL, 0) < 0) {
error("can't get namecache statistics: %s\n", strerror(errno));
memset(&stats->nchstats, 0, sizeof(stats->nchstats));
}
if (nintr)
NREAD(X_INTRCNT, stats->intrcnt, nintr * sizeof(long));
for (i = 0; i < nevcnt; i++)
KREAD(ie_head[i].ie_count, &stats->evcnt[i],
sizeof stats->evcnt[i]);
size = sizeof(stats->uvmexp);
mib[0] = CTL_VM;
mib[1] = VM_UVMEXP2;
if (sysctl(mib, 2, &stats->uvmexp, &size, NULL, 0) < 0) {
error("can't get uvmexp: %s\n", strerror(errno));
memset(&stats->uvmexp, 0, sizeof(stats->uvmexp));
}
size = sizeof(stats->Total);
mib[0] = CTL_VM;
mib[1] = VM_METER;
if (sysctl(mib, 2, &stats->Total, &size, NULL, 0) < 0) {
error("Can't get kernel info: %s\n", strerror(errno));
memset(&stats->Total, 0, sizeof(stats->Total));
}
}
static void
allocinfo(struct Info *stats)
{
if (nintr &&
(stats->intrcnt = calloc(nintr, sizeof(long))) == NULL) {
error("calloc failed");
die(0);
}
if ((stats->evcnt = calloc(nevcnt, sizeof(u_int64_t))) == NULL) {
error("calloc failed");
die(0);
}
}
static void
copyinfo(struct Info *from, struct Info *to)
{
long *intrcnt;
u_int64_t *evcnt;
intrcnt = to->intrcnt;
evcnt = to->evcnt;
*to = *from;
memmove(to->intrcnt = intrcnt, from->intrcnt, nintr * sizeof *intrcnt);
memmove(to->evcnt = evcnt, from->evcnt, nevcnt * sizeof *evcnt);
}
static void
dinfo(int dn, int r, int c)
{
double atime, dtime;
#define ADV if (disk_horiz) r++; else c += DISKCOLWIDTH
/* elapsed time for disk stats */
dtime = etime;
if (cur.timestamp[dn].tv_sec || cur.timestamp[dn].tv_usec) {
dtime = (double)cur.timestamp[dn].tv_sec +
((double)cur.timestamp[dn].tv_usec / (double)1000000);
}
mvprintw(r, c, "%*.*s", DISKCOLWIDTH, DISKCOLWIDTH, dr_name[dn]);
ADV;
putint((int)(cur.seek[dn]/dtime+0.5), r, c, DISKCOLWIDTH);
ADV;
putint((int)((cur.rxfer[dn]+cur.wxfer[dn])/dtime+0.5),
r, c, DISKCOLWIDTH);
ADV;
puthumanint_sticky((cur.rbytes[dn] + cur.wbytes[dn]) / dtime + 0.5,
r, c, DISKCOLWIDTH, &cur.scale[dn]);
ADV;
/* time busy in disk activity */
atime = cur.time[dn].tv_sec + cur.time[dn].tv_usec / 1000000.0;
atime = atime * 100.0 / dtime;
if (atime >= 100)
putint(100, r, c, DISKCOLWIDTH);
else
putfloat(atime, r, c, DISKCOLWIDTH, 1, 1);
}