OpenSolaris_b135/cmd/sa/sadc.c
/*
* CDDL HEADER START
*
* The contents of this file are subject to the terms of the
* Common Development and Distribution License, Version 1.0 only
* (the "License"). You may not use this file except in compliance
* with the License.
*
* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
* or http://www.opensolaris.org/os/licensing.
* See the License for the specific language governing permissions
* and limitations under the License.
*
* When distributing Covered Code, include this CDDL HEADER in each
* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
* If applicable, add the following below this CDDL HEADER, with the
* fields enclosed by brackets "[]" replaced with your own identifying
* information: Portions Copyright [yyyy] [name of copyright owner]
*
* CDDL HEADER END
*/
/*
* Copyright 2005 Sun Microsystems, Inc. All rights reserved.
* Use is subject to license terms.
*/
#pragma ident "%Z%%M% %I% %E% SMI"
/* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */
/* All Rights Reserved */
/*
* sadc.c writes system activity binary data to a file or stdout.
*
* Usage: sadc [t n] [file]
*
* if t and n are not specified, it writes a dummy record to data file. This
* usage is particularly used at system booting. If t and n are specified, it
* writes system data n times to file every t seconds. In both cases, if file
* is not specified, it writes data to stdout.
*/
#include <sys/fcntl.h>
#include <sys/flock.h>
#include <sys/proc.h>
#include <sys/stat.h>
#include <sys/sysinfo.h>
#include <sys/time.h>
#include <sys/types.h>
#include <sys/var.h>
#include <ctype.h>
#include <errno.h>
#include <fcntl.h>
#include <kstat.h>
#include <memory.h>
#include <nlist.h>
#include <signal.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <unistd.h>
#include <strings.h>
#include "sa.h"
#define MAX(x1, x2) ((x1) >= (x2) ? (x1) : (x2))
static kstat_ctl_t *kc; /* libkstat cookie */
static int ncpus;
static int oncpus;
static kstat_t **cpu_stat_list = NULL;
static kstat_t **ocpu_stat_list = NULL;
static int ncaches;
static kstat_t **kmem_cache_list = NULL;
static kstat_t *sysinfo_ksp, *vminfo_ksp, *var_ksp;
static kstat_t *system_misc_ksp, *ufs_inode_ksp, *kmem_oversize_ksp;
static kstat_t *file_cache_ksp;
static kstat_named_t *ufs_inode_size_knp, *nproc_knp;
static kstat_named_t *file_total_knp, *file_avail_knp;
static kstat_named_t *oversize_alloc_knp, *oversize_fail_knp;
static int slab_create_index, slab_destroy_index, slab_size_index;
static int buf_size_index, buf_avail_index, alloc_fail_index;
static struct iodevinfo zeroiodev = { NULL, NULL };
static struct iodevinfo *firstiodev = NULL;
static struct iodevinfo *lastiodev = NULL;
static struct iodevinfo *snip = NULL;
static ulong_t niodevs;
static void all_stat_init(void);
static int all_stat_load(void);
static void fail(int, char *, ...);
static void safe_zalloc(void **, int, int);
static kid_t safe_kstat_read(kstat_ctl_t *, kstat_t *, void *);
static kstat_t *safe_kstat_lookup(kstat_ctl_t *, char *, int, char *);
static void *safe_kstat_data_lookup(kstat_t *, char *);
static int safe_kstat_data_index(kstat_t *, char *);
static void init_iodevs(void);
static int iodevinfo_load(void);
static int kstat_copy(const kstat_t *, kstat_t *);
static void diff_two_arrays(kstat_t ** const [], size_t, size_t,
kstat_t ** const []);
static void compute_cpu_stat_adj(void);
static char *cmdname = "sadc";
static struct var var;
static struct sa d;
static int64_t cpu_stat_adj[CPU_STATES] = {0};
static long ninode;
int
main(int argc, char *argv[])
{
int ct;
unsigned ti;
int fp;
time_t min;
struct stat buf;
char *fname;
struct iodevinfo *iodev;
off_t flength;
ct = argc >= 3? atoi(argv[2]): 0;
min = time((time_t *)0);
ti = argc >= 3? atoi(argv[1]): 0;
if ((kc = kstat_open()) == NULL)
fail(1, "kstat_open(): can't open /dev/kstat");
all_stat_init();
init_iodevs();
if (argc == 3 || argc == 1) {
/*
* no data file is specified, direct data to stdout.
*/
fp = 1;
} else {
struct flock lock;
fname = (argc == 2) ? argv[1] : argv[3];
/*
* Open or Create a data file. If the file doesn't exist, then
* it will be created.
*/
if ((fp = open(fname, O_WRONLY | O_APPEND | O_CREAT, 0644))
== -1)
fail(1, "can't open data file");
/*
* Lock the entire data file to prevent data corruption
*/
lock.l_type = F_WRLCK;
lock.l_whence = SEEK_SET;
lock.l_start = 0;
lock.l_len = 0;
if (fcntl(fp, F_SETLK, &lock) == -1)
fail(1, "can't lock data file");
/*
* Get data file statistics for use in determining whether
* truncation required and where rollback recovery should
* be applied.
*/
if (fstat(fp, &buf) == -1)
fail(1, "can't get data file information");
/*
* If the data file was opened and is too old, truncate it
*/
if (min - buf.st_mtime > 86400)
if (ftruncate(fp, 0) == -1)
fail(1, "can't truncate data file");
/*
* Remember filesize for rollback on error (bug #1223549)
*/
flength = buf.st_size;
}
memset(&d, 0, sizeof (d));
/*
* If n == 0, write the additional dummy record.
*/
if (ct == 0) {
d.valid = 0;
d.ts = min;
d.niodevs = niodevs;
if (write(fp, &d, sizeof (struct sa)) != sizeof (struct sa))
ftruncate(fp, flength), fail(1, "write failed");
for (iodev = firstiodev; iodev; iodev = iodev->next) {
if (write(fp, iodev, sizeof (struct iodevinfo)) !=
sizeof (struct iodevinfo))
ftruncate(fp, flength), fail(1, "write failed");
}
}
for (;;) {
do {
(void) kstat_chain_update(kc);
all_stat_init();
init_iodevs();
} while (all_stat_load() || iodevinfo_load());
d.ts = time((time_t *)0);
d.valid = 1;
d.niodevs = niodevs;
if (write(fp, &d, sizeof (struct sa)) != sizeof (struct sa))
ftruncate(fp, flength), fail(1, "write failed");
for (iodev = firstiodev; iodev; iodev = iodev->next) {
if (write(fp, iodev, sizeof (struct iodevinfo)) !=
sizeof (struct iodevinfo))
ftruncate(fp, flength), fail(1, "write failed");
}
if (--ct > 0) {
sleep(ti);
} else {
close(fp);
return (0);
}
}
/*NOTREACHED*/
}
/*
* Get various KIDs for subsequent all_stat_load operations.
*/
static void
all_stat_init(void)
{
kstat_t *ksp;
/*
* Initialize global statistics
*/
sysinfo_ksp = safe_kstat_lookup(kc, "unix", 0, "sysinfo");
vminfo_ksp = safe_kstat_lookup(kc, "unix", 0, "vminfo");
kmem_oversize_ksp = safe_kstat_lookup(kc, "vmem", -1, "kmem_oversize");
var_ksp = safe_kstat_lookup(kc, "unix", 0, "var");
system_misc_ksp = safe_kstat_lookup(kc, "unix", 0, "system_misc");
file_cache_ksp = safe_kstat_lookup(kc, "unix", 0, "file_cache");
ufs_inode_ksp = kstat_lookup(kc, "ufs", 0, "inode_cache");
safe_kstat_read(kc, system_misc_ksp, NULL);
nproc_knp = safe_kstat_data_lookup(system_misc_ksp, "nproc");
safe_kstat_read(kc, file_cache_ksp, NULL);
file_avail_knp = safe_kstat_data_lookup(file_cache_ksp, "buf_avail");
file_total_knp = safe_kstat_data_lookup(file_cache_ksp, "buf_total");
safe_kstat_read(kc, kmem_oversize_ksp, NULL);
oversize_alloc_knp = safe_kstat_data_lookup(kmem_oversize_ksp,
"mem_total");
oversize_fail_knp = safe_kstat_data_lookup(kmem_oversize_ksp, "fail");
if (ufs_inode_ksp != NULL) {
safe_kstat_read(kc, ufs_inode_ksp, NULL);
ufs_inode_size_knp = safe_kstat_data_lookup(ufs_inode_ksp,
"size");
ninode = ((kstat_named_t *)
safe_kstat_data_lookup(ufs_inode_ksp,
"maxsize"))->value.l;
}
/*
* Load constant values now -- no need to reread each time
*/
safe_kstat_read(kc, var_ksp, (void *) &var);
/*
* Initialize per-CPU and per-kmem-cache statistics
*/
ncpus = ncaches = 0;
for (ksp = kc->kc_chain; ksp; ksp = ksp->ks_next) {
if (strncmp(ksp->ks_name, "cpu_stat", 8) == 0)
ncpus++;
if (strcmp(ksp->ks_class, "kmem_cache") == 0)
ncaches++;
}
safe_zalloc((void **)&cpu_stat_list, ncpus * sizeof (kstat_t *), 1);
safe_zalloc((void **)&kmem_cache_list, ncaches * sizeof (kstat_t *), 1);
ncpus = ncaches = 0;
for (ksp = kc->kc_chain; ksp; ksp = ksp->ks_next) {
if (strncmp(ksp->ks_name, "cpu_stat", 8) == 0 &&
kstat_read(kc, ksp, NULL) != -1)
cpu_stat_list[ncpus++] = ksp;
if (strcmp(ksp->ks_class, "kmem_cache") == 0 &&
kstat_read(kc, ksp, NULL) != -1)
kmem_cache_list[ncaches++] = ksp;
}
if (ncpus == 0)
fail(1, "can't find any cpu statistics");
if (ncaches == 0)
fail(1, "can't find any kmem_cache statistics");
ksp = kmem_cache_list[0];
safe_kstat_read(kc, ksp, NULL);
buf_size_index = safe_kstat_data_index(ksp, "buf_size");
slab_create_index = safe_kstat_data_index(ksp, "slab_create");
slab_destroy_index = safe_kstat_data_index(ksp, "slab_destroy");
slab_size_index = safe_kstat_data_index(ksp, "slab_size");
buf_avail_index = safe_kstat_data_index(ksp, "buf_avail");
alloc_fail_index = safe_kstat_data_index(ksp, "alloc_fail");
}
/*
* load statistics, summing across CPUs where needed
*/
static int
all_stat_load(void)
{
int i, j;
cpu_stat_t cs;
ulong_t *np, *tp;
uint64_t cpu_tick[4] = {0, 0, 0, 0};
memset(&d, 0, sizeof (d));
/*
* Global statistics
*/
safe_kstat_read(kc, sysinfo_ksp, (void *) &d.si);
safe_kstat_read(kc, vminfo_ksp, (void *) &d.vmi);
safe_kstat_read(kc, system_misc_ksp, NULL);
safe_kstat_read(kc, file_cache_ksp, NULL);
if (ufs_inode_ksp != NULL) {
safe_kstat_read(kc, ufs_inode_ksp, NULL);
d.szinode = ufs_inode_size_knp->value.ul;
}
d.szfile = file_total_knp->value.ui64 - file_avail_knp->value.ui64;
d.szproc = nproc_knp->value.ul;
d.mszinode = (ninode > d.szinode) ? ninode : d.szinode;
d.mszfile = d.szfile;
d.mszproc = var.v_proc;
/*
* Per-CPU statistics.
*/
for (i = 0; i < ncpus; i++) {
if (kstat_read(kc, cpu_stat_list[i], (void *) &cs) == -1)
return (1);
np = (ulong_t *)&d.csi;
tp = (ulong_t *)&cs.cpu_sysinfo;
/*
* Accumulate cpu ticks for CPU_IDLE, CPU_USER, CPU_KERNEL and
* CPU_WAIT with respect to each of the cpus.
*/
for (j = 0; j < CPU_STATES; j++)
cpu_tick[j] += tp[j];
for (j = 0; j < sizeof (cpu_sysinfo_t); j += sizeof (ulong_t))
*np++ += *tp++;
np = (ulong_t *)&d.cvmi;
tp = (ulong_t *)&cs.cpu_vminfo;
for (j = 0; j < sizeof (cpu_vminfo_t); j += sizeof (ulong_t))
*np++ += *tp++;
}
/*
* Per-cache kmem statistics.
*/
for (i = 0; i < ncaches; i++) {
kstat_named_t *knp;
u_longlong_t slab_create, slab_destroy, slab_size, mem_total;
u_longlong_t buf_size, buf_avail, alloc_fail;
int kmi_index;
if (kstat_read(kc, kmem_cache_list[i], NULL) == -1)
return (1);
knp = kmem_cache_list[i]->ks_data;
slab_create = knp[slab_create_index].value.ui64;
slab_destroy = knp[slab_destroy_index].value.ui64;
slab_size = knp[slab_size_index].value.ui64;
buf_size = knp[buf_size_index].value.ui64;
buf_avail = knp[buf_avail_index].value.ui64;
alloc_fail = knp[alloc_fail_index].value.ui64;
if (buf_size <= 256)
kmi_index = KMEM_SMALL;
else
kmi_index = KMEM_LARGE;
mem_total = (slab_create - slab_destroy) * slab_size;
d.kmi.km_mem[kmi_index] += (ulong_t)mem_total;
d.kmi.km_alloc[kmi_index] +=
(ulong_t)mem_total - buf_size * buf_avail;
d.kmi.km_fail[kmi_index] += (ulong_t)alloc_fail;
}
safe_kstat_read(kc, kmem_oversize_ksp, NULL);
d.kmi.km_alloc[KMEM_OSIZE] = d.kmi.km_mem[KMEM_OSIZE] =
oversize_alloc_knp->value.ui64;
d.kmi.km_fail[KMEM_OSIZE] = oversize_fail_knp->value.ui64;
/*
* Adjust CPU statistics so the delta calculations in sar will
* be correct when facing changes to the set of online CPUs.
*/
compute_cpu_stat_adj();
for (i = 0; i < CPU_STATES; i++)
d.csi.cpu[i] = (cpu_tick[i] + cpu_stat_adj[i]) / ncpus;
return (0);
}
static void
fail(int do_perror, char *message, ...)
{
va_list args;
va_start(args, message);
fprintf(stderr, "%s: ", cmdname);
vfprintf(stderr, message, args);
va_end(args);
if (do_perror)
fprintf(stderr, ": %s", strerror(errno));
fprintf(stderr, "\n");
exit(2);
}
static void
safe_zalloc(void **ptr, int size, int free_first)
{
if (free_first && *ptr != NULL)
free(*ptr);
if ((*ptr = malloc(size)) == NULL)
fail(1, "malloc failed");
memset(*ptr, 0, size);
}
static kid_t
safe_kstat_read(kstat_ctl_t *kc, kstat_t *ksp, void *data)
{
kid_t kstat_chain_id = kstat_read(kc, ksp, data);
if (kstat_chain_id == -1)
fail(1, "kstat_read(%x, '%s') failed", kc, ksp->ks_name);
return (kstat_chain_id);
}
static kstat_t *
safe_kstat_lookup(kstat_ctl_t *kc, char *ks_module, int ks_instance,
char *ks_name)
{
kstat_t *ksp = kstat_lookup(kc, ks_module, ks_instance, ks_name);
if (ksp == NULL)
fail(0, "kstat_lookup('%s', %d, '%s') failed",
ks_module == NULL ? "" : ks_module,
ks_instance,
ks_name == NULL ? "" : ks_name);
return (ksp);
}
static void *
safe_kstat_data_lookup(kstat_t *ksp, char *name)
{
void *fp = kstat_data_lookup(ksp, name);
if (fp == NULL)
fail(0, "kstat_data_lookup('%s', '%s') failed",
ksp->ks_name, name);
return (fp);
}
static int
safe_kstat_data_index(kstat_t *ksp, char *name)
{
return ((int)((char *)safe_kstat_data_lookup(ksp, name) -
(char *)ksp->ks_data) / (ksp->ks_data_size / ksp->ks_ndata));
}
static int
kscmp(kstat_t *ks1, kstat_t *ks2)
{
int cmp;
cmp = strcmp(ks1->ks_module, ks2->ks_module);
if (cmp != 0)
return (cmp);
cmp = ks1->ks_instance - ks2->ks_instance;
if (cmp != 0)
return (cmp);
return (strcmp(ks1->ks_name, ks2->ks_name));
}
static void
init_iodevs(void)
{
struct iodevinfo *iodev, *previodev, *comp;
kstat_t *ksp;
iodev = &zeroiodev;
niodevs = 0;
/*
* Patch the snip in the iodevinfo list (see below)
*/
if (snip)
lastiodev->next = snip;
for (ksp = kc->kc_chain; ksp; ksp = ksp->ks_next) {
if (ksp->ks_type != KSTAT_TYPE_IO)
continue;
previodev = iodev;
if (iodev->next)
iodev = iodev->next;
else {
safe_zalloc((void **) &iodev->next,
sizeof (struct iodevinfo), 0);
iodev = iodev->next;
iodev->next = NULL;
}
iodev->ksp = ksp;
iodev->ks = *ksp;
memset((void *)&iodev->kios, 0, sizeof (kstat_io_t));
iodev->kios.wlastupdate = iodev->ks.ks_crtime;
iodev->kios.rlastupdate = iodev->ks.ks_crtime;
/*
* Insertion sort on (ks_module, ks_instance, ks_name)
*/
comp = &zeroiodev;
while (kscmp(&iodev->ks, &comp->next->ks) > 0)
comp = comp->next;
if (previodev != comp) {
previodev->next = iodev->next;
iodev->next = comp->next;
comp->next = iodev;
iodev = previodev;
}
niodevs++;
}
/*
* Put a snip in the linked list of iodevinfos. The idea:
* If there was a state change such that now there are fewer
* iodevs, we snip the list and retain the tail, rather than
* freeing it. At the next state change, we clip the tail back on.
* This prevents a lot of malloc/free activity, and it's simpler.
*/
lastiodev = iodev;
snip = iodev->next;
iodev->next = NULL;
firstiodev = zeroiodev.next;
}
static int
iodevinfo_load(void)
{
struct iodevinfo *iodev;
for (iodev = firstiodev; iodev; iodev = iodev->next) {
if (kstat_read(kc, iodev->ksp, (void *) &iodev->kios) == -1)
return (1);
}
return (0);
}
static int
kstat_copy(const kstat_t *src, kstat_t *dst)
{
*dst = *src;
if (src->ks_data != NULL) {
if ((dst->ks_data = malloc(src->ks_data_size)) == NULL)
return (-1);
bcopy(src->ks_data, dst->ks_data, src->ks_data_size);
} else {
dst->ks_data = NULL;
dst->ks_data_size = 0;
}
return (0);
}
/*
* Determine what is different between two sets of kstats; s[0] and s[1]
* are arrays of kstats of size ns0 and ns1, respectively, and sorted by
* instance number. u[0] and u[1] are two arrays which must be
* caller-zallocated; each must be of size MAX(ns0, ns1). When the
* function terminates, u[0] contains all s[0]-unique items and u[1]
* contains all s[1]-unique items. Any unused entries in u[0] and u[1]
* are left NULL.
*/
static void
diff_two_arrays(kstat_t ** const s[], size_t ns0, size_t ns1,
kstat_t ** const u[])
{
kstat_t **s0p = s[0], **s1p = s[1];
kstat_t **u0p = u[0], **u1p = u[1];
int i = 0, j = 0;
while (i < ns0 && j < ns1) {
if ((*s0p)->ks_instance == (*s1p)->ks_instance) {
if ((*s0p)->ks_kid != (*s1p)->ks_kid) {
/*
* The instance is the same, but this
* CPU has been offline during the
* interval, so we consider *u0p to
* be s0p-unique, and similarly for
* *u1p.
*/
*(u0p++) = *s0p;
*(u1p++) = *s1p;
}
s0p++;
i++;
s1p++;
j++;
} else if ((*s0p)->ks_instance < (*s1p)->ks_instance) {
*(u0p++) = *(s0p++);
i++;
} else {
*(u1p++) = *(s1p++);
j++;
}
}
while (i < ns0) {
*(u0p++) = *(s0p++);
i++;
}
while (j < ns1) {
*(u1p++) = *(s1p++);
j++;
}
}
static int
cpuid_compare(const void *p1, const void *p2)
{
return ((*(kstat_t **)p1)->ks_instance -
(*(kstat_t **)p2)->ks_instance);
}
/*
* Identify those CPUs which were not present for the whole interval so
* their statistics can be removed from the aggregate.
*/
static void
compute_cpu_stat_adj(void)
{
int i, j;
if (ocpu_stat_list) {
kstat_t **s[2];
kstat_t **inarray[2];
int max_cpus = MAX(ncpus, oncpus);
qsort(cpu_stat_list, ncpus, sizeof (*cpu_stat_list),
cpuid_compare);
qsort(ocpu_stat_list, oncpus, sizeof (*ocpu_stat_list),
cpuid_compare);
s[0] = ocpu_stat_list;
s[1] = cpu_stat_list;
safe_zalloc((void *)&inarray[0], sizeof (**inarray) * max_cpus,
0);
safe_zalloc((void *)&inarray[1], sizeof (**inarray) * max_cpus,
0);
diff_two_arrays(s, oncpus, ncpus, inarray);
for (i = 0; i < max_cpus; i++) {
if (inarray[0][i])
for (j = 0; j < CPU_STATES; j++)
cpu_stat_adj[j] +=
((cpu_stat_t *)inarray[0][i]
->ks_data)->cpu_sysinfo.cpu[j];
if (inarray[1][i])
for (j = 0; j < CPU_STATES; j++)
cpu_stat_adj[j] -=
((cpu_stat_t *)inarray[1][i]
->ks_data)->cpu_sysinfo.cpu[j];
}
free(inarray[0]);
free(inarray[1]);
}
/*
* Preserve the last interval's CPU stats.
*/
if (cpu_stat_list) {
for (i = 0; i < oncpus; i++)
free(ocpu_stat_list[i]->ks_data);
oncpus = ncpus;
safe_zalloc((void **)&ocpu_stat_list, oncpus *
sizeof (*ocpu_stat_list), 1);
for (i = 0; i < ncpus; i++) {
safe_zalloc((void *)&ocpu_stat_list[i],
sizeof (*ocpu_stat_list[0]), 0);
if (kstat_copy(cpu_stat_list[i], ocpu_stat_list[i]))
fail(1, "kstat_copy() failed");
}
}
}