NetBSD/dist/ntp/ntpd/ntp_monitor.c
2006-06-11 19:34:07 +00:00

340 lines
8.0 KiB
C

/* $NetBSD: ntp_monitor.c,v 1.3 2006/06/11 19:34:11 kardel Exp $ */
/*
* ntp_monitor - monitor ntpd statistics
*/
#ifdef HAVE_CONFIG_H
# include <config.h>
#endif
#include "ntpd.h"
#include "ntp_io.h"
#include "ntp_if.h"
#include "ntp_stdlib.h"
#include <ntp_random.h>
#include <stdio.h>
#include <signal.h>
#ifdef HAVE_SYS_IOCTL_H
# include <sys/ioctl.h>
#endif
/*
* I'm still not sure I like what I've done here. It certainly consumes
* memory like it is going out of style, and also may not be as low
* overhead as I'd imagined.
*
* Anyway, we record statistics based on source address, mode and
* version (for now, anyway. Check the code). The receive procedure
* calls us with the incoming rbufp before it does anything else.
*
* Each entry is doubly linked into two lists, a hash table and a
* most-recently-used list. When a packet arrives it is looked up in
* the hash table. If found, the statistics are updated and the entry
* relinked at the head of the MRU list. If not found, a new entry is
* allocated, initialized and linked into both the hash table and at the
* head of the MRU list.
*
* Memory is usually allocated by grabbing a big chunk of new memory and
* cutting it up into littler pieces. The exception to this when we hit
* the memory limit. Then we free memory by grabbing entries off the
* tail for the MRU list, unlinking from the hash table, and
* reinitializing.
*
* trimmed back memory consumption ... jdg 8/94
*/
/*
* Limits on the number of structures allocated. This limit is picked
* with the illicit knowlege that we can only return somewhat less
* than 8K bytes in a mode 7 response packet, and that each structure
* will require about 20 bytes of space in the response.
*
* ... I don't believe the above is true anymore ... jdg
*/
#ifndef MAXMONMEM
#define MAXMONMEM 600 /* we allocate up to 600 structures */
#endif
#ifndef MONMEMINC
#define MONMEMINC 40 /* allocate them 40 at a time */
#endif
/*
* Hashing stuff
*/
#define MON_HASH_SIZE 128
#define MON_HASH_MASK (MON_HASH_SIZE-1)
#define MON_HASH(addr) sock_hash(addr)
/*
* Pointers to the hash table, the MRU list and the count table. Memory
* for the hash and count tables is only allocated if monitoring is
* turned on.
*/
static struct mon_data *mon_hash[MON_HASH_SIZE]; /* list ptrs */
struct mon_data mon_mru_list;
/*
* List of free structures structures, and counters of free and total
* structures. The free structures are linked with the hash_next field.
*/
static struct mon_data *mon_free; /* free list or null if none */
static int mon_total_mem; /* total structures allocated */
static int mon_mem_increments; /* times called malloc() */
/*
* Initialization state. We may be monitoring, we may not. If
* we aren't, we may not even have allocated any memory yet.
*/
int mon_enabled; /* enable switch */
u_long mon_age = 3000; /* preemption limit */
static int mon_have_memory;
static void mon_getmoremem P((void));
static void remove_from_hash P((struct mon_data *));
/*
* init_mon - initialize monitoring global data
*/
void
init_mon(void)
{
/*
* Don't do much of anything here. We don't allocate memory
* until someone explicitly starts us.
*/
mon_enabled = MON_OFF;
mon_have_memory = 0;
mon_total_mem = 0;
mon_mem_increments = 0;
mon_free = NULL;
memset(&mon_hash[0], 0, sizeof mon_hash);
memset(&mon_mru_list, 0, sizeof mon_mru_list);
}
/*
* mon_start - start up the monitoring software
*/
void
mon_start(
int mode
)
{
if (mon_enabled != MON_OFF) {
mon_enabled |= mode;
return;
}
if (mode == MON_OFF)
return;
if (!mon_have_memory) {
mon_total_mem = 0;
mon_mem_increments = 0;
mon_free = NULL;
mon_getmoremem();
mon_have_memory = 1;
}
mon_mru_list.mru_next = &mon_mru_list;
mon_mru_list.mru_prev = &mon_mru_list;
mon_enabled = mode;
}
/*
* mon_stop - stop the monitoring software
*/
void
mon_stop(
int mode
)
{
register struct mon_data *md, *md_next;
register int i;
if (mon_enabled == MON_OFF)
return;
if ((mon_enabled & mode) == 0 || mode == MON_OFF)
return;
mon_enabled &= ~mode;
if (mon_enabled != MON_OFF)
return;
/*
* Put everything back on the free list
*/
for (i = 0; i < MON_HASH_SIZE; i++) {
md = mon_hash[i]; /* get next list */
mon_hash[i] = NULL; /* zero the list head */
while (md != NULL) {
md_next = md->hash_next;
md->hash_next = mon_free;
mon_free = md;
md = md_next;
}
}
mon_mru_list.mru_next = &mon_mru_list;
mon_mru_list.mru_prev = &mon_mru_list;
}
/*
* ntp_monitor - record stats about this packet
*/
void
ntp_monitor(
struct recvbuf *rbufp
)
{
register struct pkt *pkt;
register struct mon_data *md;
struct sockaddr_storage addr;
register int hash;
register int mode;
if (mon_enabled == MON_OFF)
return;
pkt = &rbufp->recv_pkt;
memset(&addr, 0, sizeof(addr));
memcpy(&addr, &(rbufp->recv_srcadr), sizeof(addr));
hash = MON_HASH(&addr);
mode = PKT_MODE(pkt->li_vn_mode);
md = mon_hash[hash];
while (md != NULL) {
/*
* Match address only to conserve MRU size.
*/
if (SOCKCMP(&md->rmtadr, &addr)) {
md->drop_count = current_time - md->lasttime;
md->lasttime = current_time;
md->count++;
md->rmtport = NSRCPORT(&rbufp->recv_srcadr);
md->mode = (u_char) mode;
md->version = PKT_VERSION(pkt->li_vn_mode);
/*
* Shuffle to the head of the MRU list.
*/
md->mru_next->mru_prev = md->mru_prev;
md->mru_prev->mru_next = md->mru_next;
md->mru_next = mon_mru_list.mru_next;
md->mru_prev = &mon_mru_list;
mon_mru_list.mru_next->mru_prev = md;
mon_mru_list.mru_next = md;
return;
}
md = md->hash_next;
}
/*
* If we got here, this is the first we've heard of this
* guy. Get him some memory, either from the free list
* or from the tail of the MRU list.
*/
if (mon_free == NULL && mon_total_mem >= MAXMONMEM) {
/*
* Preempt from the MRU list if old enough.
*/
md = mon_mru_list.mru_prev;
/* We get 31 bits from ntp_random() */
if (((u_long)ntp_random()) / FRAC >
(double)(current_time - md->lasttime) / mon_age)
return;
md->mru_prev->mru_next = &mon_mru_list;
mon_mru_list.mru_prev = md->mru_prev;
remove_from_hash(md);
} else {
if (mon_free == NULL)
mon_getmoremem();
md = mon_free;
mon_free = md->hash_next;
}
/*
* Got one, initialize it
*/
md->avg_interval = 0;
md->lasttime = current_time;
md->count = 1;
md->drop_count = 0;
memset(&md->rmtadr, 0, sizeof(md->rmtadr));
memcpy(&md->rmtadr, &addr, sizeof(addr));
md->rmtport = NSRCPORT(&rbufp->recv_srcadr);
md->mode = (u_char) mode;
md->version = PKT_VERSION(pkt->li_vn_mode);
md->interface = rbufp->dstadr;
md->cast_flags = (u_char)(((rbufp->dstadr->flags & INT_MCASTOPEN) &&
rbufp->fd == md->interface->fd) ? MDF_MCAST: rbufp->fd ==
md->interface->bfd ? MDF_BCAST : MDF_UCAST);
/*
* Drop him into front of the hash table. Also put him on top of
* the MRU list.
*/
md->hash_next = mon_hash[hash];
mon_hash[hash] = md;
md->mru_next = mon_mru_list.mru_next;
md->mru_prev = &mon_mru_list;
mon_mru_list.mru_next->mru_prev = md;
mon_mru_list.mru_next = md;
}
/*
* mon_getmoremem - get more memory and put it on the free list
*/
static void
mon_getmoremem(void)
{
register struct mon_data *md;
register int i;
struct mon_data *freedata; /* 'old' free list (null) */
md = (struct mon_data *)emalloc(MONMEMINC *
sizeof(struct mon_data));
freedata = mon_free;
mon_free = md;
for (i = 0; i < (MONMEMINC-1); i++) {
md->hash_next = (md + 1);
md++;
}
/*
* md now points at the last. Link in the rest of the chain.
*/
md->hash_next = freedata;
mon_total_mem += MONMEMINC;
mon_mem_increments++;
}
static void
remove_from_hash(
struct mon_data *md
)
{
register int hash;
register struct mon_data *md_prev;
hash = MON_HASH(&md->rmtadr);
if (mon_hash[hash] == md) {
mon_hash[hash] = md->hash_next;
} else {
md_prev = mon_hash[hash];
while (md_prev->hash_next != md) {
md_prev = md_prev->hash_next;
if (md_prev == NULL) {
/* logic error */
return;
}
}
md_prev->hash_next = md->hash_next;
}
}