dns_flood_detector.c

/********************************************************************************

	Program: dns_flood_detector.c
	 Author: Dennis Opacki <dopacki@adotout.com>
	   Date: Tue Mar 18 16:46:53 EST 2003 
	Purpose: Monitor DNS servers for abusive usage levels
		 and alarm to syslog

	compile with:
	gcc -o dns_flood_detector -lpcap -lpthread -lm dns_flood_detector.c 
	
	command-line options:
	
	-i ifname	specify interface to listen on (default lets pcap pick)	
	-t n		alarm when more than n queries per second are observed
			(default 40)
	-a n		wait for n seconds before alarming again on same source
			(default 90)
	-w n		calculate statistics every n seconds 
			(default 10)
	-x n		use n buckets 
			(default 50)
	-m n		mark overall query rate every n seconds
			(default disabled)
	-A addr		filter for specific address
	-M mask		netmask for filter (in conjunction with -A)
	-Q		monitor any addresses (default is to filter only for
			primary addresses on chosen interface)
	-b		run in foreground in "bindsnap" mode
	-d		run in background in "daemon" mode
	-D		dump dns packets (implies -b)
	-v		detailed information (use twice for more detail)
        -s              send source IP stats to collector as JSON
        -z N.N.N.N      address to send stats to (default 226.1.1.2)
        -p N            UDP port to send stats to (default 2000)

	-h		usage info

    Copyright (C) 2003  Dennis Opacki

    This program is free software; you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation; either version 2 of the License, or
    (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program; if not, write to the Free Software
    Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA

    --- new in v1.05 ---
    8/18/2003 - FreeBSD target - Jim Westfall <jwestfall@surrealistic.net> 
    8/18/2003 - Moved to getopt(3) for compatibility <dopacki@adotout.com>
    8/19/2003 - Added OSX/BSDI make targets - <dopacki@adotout.com>
                Added ability to specify inteface - <dopacki@adotout.com>

    --- new in v1.06 ---
    8/20/2003 - Added Solaris9 make target - <dopacki@adotout.com>
    8/26/2003 - Fixed tcp qdcount bug - <dopacki@adotout.com>

    --- new in v1.07 ---
    8/27/2003 - Fixed alarm reset bug - <dopacki@adotout.com>
    8/28/2003 - Added malloc_fail function - <dopacki@adotout.com>
    8/28/2003 - Added mutex thread locking - <dopacki@adotout.com>
    8/30/2003 - Fixed wierd qtype segfault - <jwestfall@surrealistic.net>
					     <dopacki@adotout.com>

    --- new in v1.08 ---
    9/02/2003 - Added -v -v output in daemon mode - <dopacki@adotout.com>

    --- new in v1.09 ---
    10/19/2003 - Added stdout flushing to bindsnap mode - <dopacki@adotout.com>
    10/19/2003 - Changed logging priority to LOG_NOTICE - <dopacki@adotout.com>
    10/19/2003 - Fixed low traffic verbose logging bugs - <dopacki@adotout.com>

    --- new in v1.10 ---
    10/22/2003 - Added 'mark status' option via '-m' - <dopacki@adotout.com>
    10/23/2003 - Code cleanup in verbose syslogging - <dopacki@adotout.com>

    --- new in v1.11 ---
    06/14/2005 - added A6, AAAA, ANY qtypes - <jwestfall@surrealistic.net>
                 examine all packets with >= 1 qdcount - <jwestfall@surrealistic.net>
                 stop processing packet if invalid dns char - <jwestfall@surrealistic.net>
                 fix tcp parsing - <jwestfall@surrealistic.net>
                 add option_D to dump packets - <jwestfall@surrealistic.net>

    --- new in v1.12 ---
    03/03/2006 - added address filtering options - <erikm@buh.org>
                 fix segfault using argv[0] after getopt - <erikm@buh.org>
                 fix rounding from float/int conversions, use unsigned more consistently - <erikm@buh.org>
                 clean up to work with -Wall - <erikm@buh.org>
                 show fractional qps rates for totals - <erikm@buh.org> 
                 store addresses raw, instead of as text (speedup/reduce memory usage) - <erikm@buh.org>
                 fix crash on long syslog messages - <jwestfall@surrealistic.net>

    --- new in v1.2 ---
    05/10/2012 - added sending of source-IP telemetry to a network collector - <dopacki@adotout.com>

********************************************************************************/

#include <pcap.h>
#include <stdio.h>
#include <stdlib.h>
#include <fcntl.h>
#include <errno.h>
#include <netinet/in_systm.h>
#include <netinet/in.h>
#include <netinet/ip.h>
#include <netinet/tcp.h>
#include <netinet/udp.h>
#include <arpa/inet.h>
#ifdef __bsdi__
#include <net/if_ethernet.h>
#else
#ifdef __sun__
#include <sys/ethernet.h>
#else
#include <net/ethernet.h>
#endif
#endif
#include <pthread.h>
#include <unistd.h>
#include <time.h>
#include <math.h>
#include <signal.h>
#include <syslog.h>
#include <string.h>
#include <sys/stat.h>
#include "dns_flood_detector.h"
#include <sys/types.h>
#include <sys/socket.h>
#include <sys/select.h>

// global variables and their defaults
pthread_mutex_t stats_lock;
struct bucket **bb;
int option_t = 60;
int option_a = 90;
int option_w = 20;
int option_x = 10000;
int option_m = 0;
int option_b = 0;
int option_d = 0;
int option_D = 0;
int option_v = 0;
int option_h = 0;
int option_Q = 0;
int option_A = 0;
int option_M = 0;
int option_s = 0;
int totals = 0;

static char *target_ip = NULL;
int target_port = DEFAULT_PORT;
int mcast_ttl = 10;
char hostname[HOST_NAME_MAX];

char VERSION[] = "1.2";

// 255.255.255.255 is invalid as a src IP address; we'll use it to mark empty buckets
#define BCAST 0xffFFffFF

// this is our statistics thread
void *run_stats () {
  // prepare multicast socket
  struct sockaddr_in addr;
  int sock;
  sock = socket(AF_INET, SOCK_DGRAM,0);

  if  (sock<0) {
    perror("can't set up socket");
    exit(1);
  }

  // is it harmful to set this on non-multicast sockets?
  setsockopt(sock, IPPROTO_IP, IP_MULTICAST_TTL, (char *)&mcast_ttl, sizeof(mcast_ttl));

  bzero((char*)&addr, sizeof(addr));
  addr.sin_family = AF_INET;
  addr.sin_addr.s_addr = inet_addr(target_ip);
  addr.sin_port = htons(target_port);

  // get our hostname
  gethostname(hostname, HOST_NAME_MAX-1);

  while (1) {

    // check statistical stuff
    pthread_mutex_lock(&stats_lock);
    calculate_averages();
    saddr_stats(sock,addr,hostname);
    pthread_mutex_unlock(&stats_lock);
    sleep (option_w);
  }
}

// report saddr stats
int saddr_stats(int sock, struct sockaddr_in addr, char *hostname) {
  u_int i;
  int addrlen;
  char buff[MAXMESSAGE];
  int buffhead = 0;
  char st_time[10];
  time_t now = time(0);
  struct tm *raw_time = localtime(&now);
  addrlen = sizeof(addr);
  snprintf(st_time, 9, "%02d:%02d:%02d",raw_time->tm_hour,raw_time->tm_min,raw_time->tm_sec);

  // prepare jason structure for multicast datagrams
  char head[MAXHEAD];
  char *tail = "}}";
  snprintf(head,MAXHEAD,"{\"hostname\":\"%s\",\"type\":\"source\",\"data\":{",hostname);
  int netsize = MAXMESSAGE - strlen(head) - strlen(tail);
  if (netsize<=0) exit(EXIT_FAILURE); // this should never ever happen

  int avail = netsize;
  int dlen = 0;
  char datalet[MAXDATALET];

  // copy the initial json header into the buffer
  bzero(buff,sizeof(buff));
  memcpy(buff,head,strlen(head));
  buffhead = buffhead + strlen(head);

  // report all source address stats, cleaning up afterward
  for (i=0; ( (i < option_x) && ( bb[i]->ip_addr.s_addr != 0 ) ); i++) {

    if ( bb[i]->ip_addr.s_addr != BCAST ) {

      // prepare a datalet
      snprintf(datalet,MAXDATALET,"\"%s\":%d,",inet_ntoa(bb[i]->ip_addr),bb[i]->udp_count+bb[i]->tcp_count);
      dlen = strlen(datalet);

      // see if the current datagram has room for the datalet
      if ( avail > dlen ) {

        // append this datalet to the current datagram (minus null terminator)
        avail = avail - dlen;
        memcpy(buff+buffhead,datalet,dlen);
        buffhead = buffhead + dlen;
      }
      // no room in current dgram
      else {

        // remove trailing comma from the buffer so we can close it out
        buffhead = buffhead - 1;

        // add the tail
        strncpy(buff+buffhead,tail, strlen(tail));

        // send the transmission if option_s is set
        if (option_s > 0 ) {
          sendto(sock,buff,strlen(buff)+1,0,(struct sockaddr *) &addr, addrlen);
          microsleep(10);
        }

        // init next datagram
        bzero(buff,sizeof(buff));
        memcpy(buff,head,strlen(head));
        buffhead = strlen(head);
        avail = netsize;

        // append this datalet to the current datagram (minus null terminatin)
        avail = avail - dlen;
        memcpy(buff+buffhead,datalet,dlen);
        buffhead = buffhead + dlen;
      }
    }

    scour_bucket(i);    
  }

  // transmit final buffer contents if needed
  if ( ( option_b == 0) && (buffhead>strlen(head)) ) {

    // remove trailing comma
    buffhead = buffhead - 1;

    // add the tail
    strncpy(buff+buffhead,tail,strlen(tail));

    // send the multicast transmission
    sendto(sock,buff,strlen(buff)+1,0,(struct sockaddr *) &addr, addrlen);
    microsleep(10);

    bzero(buff,sizeof(buff));
  }
  return 1;
}


// calculate the running average within each bucket
int calculate_averages() {
  u_int i,j,delta,cursize,qps;
  int newsize;
  float qpsf;
  char st_time[10];
  time_t now = time(0);
  u_int types[] = {1,2,5,6,12,15,28,38,252,255,0};
  char *target;
  char *names[] = {"A","NS","CNAME","SOA","PTR","MX","AAAA","A6","AXFR","ANY",""};
  struct tm *raw_time = localtime(&now);
  snprintf(st_time, 9, "%02d:%02d:%02d",raw_time->tm_hour,raw_time->tm_min,raw_time->tm_sec);

  for (i=0; i<option_x; i++) {

    // only process valid buckets
    if ( bb[i]->ip_addr.s_addr != BCAST) {
      delta = now - bb[i]->first_packet;

      // let's try to avoid a divide-by-zero, shall we?
      if (delta > 1 ) {

        // round our average and save it in the bucket
        bb[i]->qps = (u_int)ceil( (bb[i]->tcp_count + bb[i]->udp_count) / (float)delta);

        // handle threshold crossing
        if ( bb[i]->qps > option_t ) {

          // display detail to either syslog or stdout
          if ( option_b ) {
            if ( ! option_v ) {
              printf("[%s] source [%s] - %u qps\n",st_time,inet_ntoa(bb[i]->ip_addr),bb[i]->qps);
              fflush(stdout);
            }
            else {
              printf("[%s] source [%s] - %u qps tcp : %u qps udp ",st_time,inet_ntoa(bb[i]->ip_addr),
              (u_int)ceil( ((float)bb[i]->tcp_count/delta)),
              (u_int)ceil( ((float)bb[i]->udp_count/delta)));

              if ( option_v >1 ) {
                for (j=0;types[j];j++) {
                  qps = (u_int)ceil((float)bb[i]->qstats[types[j]]/delta);
                  if (qps){
                    printf("[%u qps %s] ",qps,names[j]);
                  }
                }
              }
              printf("\n");
              fflush(stdout);
            }
          }
          else {
            // if running in background, use alarm reset timer
            if ((now-bb[i]->alarm_set)>option_a) {

              // display appropriate level of detail via syslog
              if ( ! option_v ) {
                syslog(LOG_NOTICE,"source [%s] - %u qps\n",inet_ntoa(bb[i]->ip_addr),bb[i]->qps);
              }
              else if (option_v > 1) {
                target = (char *)malloc(sizeof(char)*MAXSYSLOG);
                newsize = MAXSYSLOG;
                cursize = snprintf(target,newsize,"source [%s] - %u tcp qps : %u udp qps ",inet_ntoa(bb[i]->ip_addr),
                (u_int)ceil( ((float)bb[i]->tcp_count/delta)),				
                (u_int)ceil( ((float)bb[i]->udp_count/delta)));
                newsize-=cursize;
	
                for (j=0;types[j];j++ ) {
                  qps = (u_int)ceil(((float)bb[i]->qstats[types[j]]/delta));
                  if ( ( qps > 0)  && ( newsize > 1 ) ) {
                    cursize = snprintf(target+(MAXSYSLOG-newsize),newsize,"[%u qps %s] ",qps,names[j]);
                    newsize-=cursize;
                  }
                }
                if (newsize <= 0 ) {
                  target[MAXSYSLOG-1]='\0';
                }
                syslog(LOG_NOTICE,"%s",target);
                free(target);
              }
              else {
                syslog(LOG_NOTICE,"source [%s] - %u tcp qps - %u udp qps\n",inet_ntoa(bb[i]->ip_addr),
                (u_int)ceil( ((float)bb[i]->tcp_count/delta)),
                (u_int)ceil( ((float)bb[i]->udp_count/delta)));
              }

              // reset alarm
              bb[i]->alarm_set = now;
            }
          }
        }
      }
    }		
  }
	
  // 'mark stats' if required and it is time
  delta = (u_int)(now - bb[totals]->first_packet);
  if ( (option_m > 0)&&(delta > 1)&&(delta >= option_m) ) {

    // handle bindsnap mode 
    if (option_b) {
      printf("[%s] totals - %3.2f qps tcp : %3.2f qps udp ",st_time, ((float)bb[totals]->tcp_count/delta),((float)bb[totals]->udp_count/delta));
      if (option_v) {
        for (j=0;types[j];j++) {
          qpsf = ((float)bb[totals]->qstats[types[j]]/delta);
          if (qpsf > 0){
            printf("[%3.2f qps %s] ",qpsf,names[j]);
          }
        }
      }
      printf("\n");
      fflush(stdout);
    }
    else {
      // agonizing high verbosity code
      if (option_v) {
        target = (char *)malloc(sizeof(char)*MAXSYSLOG);
        newsize = MAXSYSLOG;
        cursize = snprintf(target,newsize,"[totals] - %3.2f tcp qps : %3.2f udp qps ",
        ((float)bb[totals]->tcp_count/delta),				
        ((float)bb[totals]->udp_count/delta));
        newsize-=cursize;
	
        for (j=0;types[j];j++ ) {
          qpsf = ((float)bb[totals]->qstats[types[j]]/delta);
          if ( ( qpsf > 0)  && ( newsize > 1 ) ) {
            cursize = snprintf(target+(MAXSYSLOG-newsize),newsize,"[%3.2f qps %s] ",qpsf,names[j]);
            newsize-=cursize;
          }
        }
        if (newsize <= 0 ) {
          target[MAXSYSLOG-1]='\0';
        }
        syslog(LOG_NOTICE,"%s",target);
        free(target);
      }
      else {
        syslog(LOG_NOTICE,"[totals] - %3.2f tcp qps : %3.2f udp qps\n",
        ((float)bb[totals]->tcp_count/delta),
        ((float)bb[totals]->udp_count/delta));
      }
    }	
    scour_bucket(totals);
  }
  return 1;
}

int valid_dns_char(char c) {

  if((c >= '0' && c <= '9') 
  || (c >= 'a' && c <= 'z')
  || (c >= 'A' && c <= 'Z')
  || (c == '-') 
  || (c == '_')) // is valid for SRV records. 
    return 1;

  return 0; 
}

// purge and initialize all buckets
void init_buckets() {
	u_int i;

  // create bucket brigade (final bucket is for totals)
  pthread_mutex_lock(&stats_lock);
  if ( ( bb = malloc( sizeof(struct bucket *) * (option_x+1)) ) == NULL ) malloc_fail("bb", sizeof(struct bucket *) * (option_x+1));
  for (i=0; i <=option_x; i++ ) {
    if ( ( bb[i] = (struct bucket *)malloc( sizeof(struct bucket) ) ) == NULL) malloc_fail("bb[i]", sizeof(struct bucket) );
    scour_bucket(i);
  }
  pthread_mutex_unlock(&stats_lock);
}

// clean out a bucket while avoiding obvious memory leak
int scour_bucket( int i ) {
  int j;

  bb[i]->ip_addr.s_addr=BCAST;
  bb[i]->tcp_count=0;
  bb[i]->udp_count=0;
  bb[i]->qps=0;
  bb[i]->first_packet=time(0);
  bb[i]->last_packet=(time_t)0;
  bb[i]->alarm_set=(time_t)0;
	
  for (j=0;j<256;j++) {
    bb[i]->qstats[j]=0;
  }

  return 1;
}

// add a packet to a bucket
int add_to_bucket ( struct in_addr *ip_src, int ip_proto, int num_queries, u_int8_t qtype) {
  int bucket = 0;

  // get the bucket to put packet in	
  pthread_mutex_lock(&stats_lock);
  bucket = find_bucket(ip_src);

  // set bucket fields
  bb[bucket]->last_packet = time(0);
  if (ip_proto == 6 ) {
    bb[bucket]->tcp_count+=num_queries;
    bb[totals]->tcp_count+=num_queries;
  }
  else {
    bb[bucket]->udp_count+=num_queries;
    bb[totals]->udp_count+=num_queries;
  }

  bb[bucket]->qstats[qtype]+=num_queries;
  bb[totals]->qstats[qtype]+=num_queries;
  pthread_mutex_unlock(&stats_lock);

  return 1;
}

// figure out where to put this packet
int find_bucket(struct in_addr *ip_src) {
  int i, bucket=0;
  time_t oldest=0;

  // look for an existing bucket for this IP
  for (i=0; i< option_x; i++ ){
    // ip field of bucket seems to match the ip we are checking
    if (bb[i]->ip_addr.s_addr == ip_src->s_addr) {
      return i;
    }
  }

  // look for unused buckets
  for (i=0; i< option_x; i++ ) {

    // found an unused one - clean it, init it, and return it
    if ( bb[i]->ip_addr.s_addr == BCAST ) {
      scour_bucket(i);
      bb[i]->ip_addr.s_addr = ip_src->s_addr;
      return i;
    }

    // find the most stagnant bucket in case we need it
    // avoids another loop through the buckets
    // TODO - should we autoflush buckets after some idle time,
    //        or after alarming?  fixes the case where
    //        alarms are unlikely to reappear even if a client
    //        resumes flooding if there isn't bucket contention
    //        churning them out and resetting the timer for the rate
    //        calculation...

    if ( ( bb[i]->last_packet != 0 ) && ((oldest==0)||( bb[i]->last_packet < oldest))) {
      oldest = bb[i]->last_packet;
      bucket = i;			
    }
  }

  // use the most stagnant bucket since all are in use
  // clean it, init it, and return it
  scour_bucket(bucket);
  bb[i]->ip_addr.s_addr = ip_src->s_addr;

  return bucket;
}

// handle all packets we throw at it 
void handle_IP(u_char *args, const struct pcap_pkthdr* pkthdr,const u_char* packet){
  const struct ip* ip;
  const struct my_dns *dns;
  const struct tcphdr *tcp;
  const struct udphdr *udp;
  u_int length = pkthdr->len;
  u_int caplen = pkthdr->caplen;
  u_int hlen,off,version;
  unsigned char dname[NS_MAXDNAME]="";
  struct in_addr ip_src;
  unsigned char *data;
  u_int len,dpos;
  u_int8_t qtype,tlen;

  // skip the ethernet header
  length -= sizeof(struct ether_header); 

  // make sure packet is a valid length
  if (length < sizeof(struct ip)) {
    return;
  }

  // snap off the ip portion
  ip = (struct ip*)(packet + sizeof(struct ether_header));

  // get utility params for sanity checking
  len     = ntohs(ip->ip_len);
  hlen    = ip->ip_hl;
  version = ip->ip_v;

  // let's not do ipv6 just yet
  if(version != 4) {
    return;
  }

  // make sure we have a sane header length
  if(hlen < 5 ) {
    return;
  }

  // do we have the everything we are supposed to?
  if(length < len) {
    return;
  }

  // make sure we are only processing the first fragment
  off = ntohs(ip->ip_off);
  if((off & 0x1fff) == 0 ) {

    // get the source ip
    ip_src.s_addr = ip->ip_src.s_addr;

    // process udp packets
    if ( ip->ip_p == 17 ) {
      udp = (struct udphdr *) ( (char *) packet + sizeof(struct ether_header)+ sizeof (struct ip) );

      // try to make sure it is safe to cast packet into dns structure
      if ( (sizeof(struct my_dns)+sizeof(struct ether_header)+sizeof(struct ip)+sizeof(struct udphdr)) >= caplen ) {
        return;
      }
      else {
        // populate dns header
        dns = (struct my_dns *) ( (char *) packet + sizeof(struct ether_header) + sizeof (struct ip) + sizeof (struct udphdr) );
        data = (unsigned char *) packet +sizeof(struct ether_header) + sizeof (struct ip) + sizeof (struct udphdr) + sizeof(struct my_dns);
      }
    }

    // process tcp packets
    else if ( ip->ip_p == 6 ) {
      tcp = (struct tcphdr *) ( (char *) packet + sizeof(struct ether_header)+ sizeof (struct ip) );

      // ignore packets without push flag set
      if (! (tcp->th_flags & TH_PUSH)) return;
	
      // try to make sure it is safe to cast packet into dns structure
      if ( (sizeof(struct my_dns)+sizeof(struct ether_header)+sizeof(struct ip)+(tcp->th_off * sizeof(u_int32_t)) + sizeof(u_int16_t)) >= caplen ) {
        return;
      }
      else {
        // populate dns header
        // tcp dns lookups also include a 16bit length field = dns header + data.
        dns = (struct my_dns *) ( (char *) packet + sizeof(struct ether_header)+ sizeof (struct ip) + (tcp->th_off * sizeof(u_int32_t) + sizeof(u_int16_t)));
        data = (unsigned char *) packet + sizeof(struct ether_header) + sizeof (struct ip) + (tcp->th_off * sizeof(u_int32_t)) + sizeof(struct my_dns) + sizeof(u_int16_t);
      }
    }

    // hmm.. not tcp, not udp.. move on.
    else {
      return;
    }

    // we only want queries, not responses
    if (  dns->dns_flags1 & 0x80 ) {
      return;
    }

    // ignore packets with no questions
    if (ntohs(dns->dns_qdcount) == 0) {
      return;
    }
		
    // get the domain name and query type
    tlen=dpos=0;
    for (;(*data)&&((void *)data<((void *)packet+caplen-1)); data++) {
      if (!tlen) tlen=*data;
      for (;(tlen&&((void *)data<((void *)packet+caplen-1)));tlen--){
        data++;
        // bail on an invalid dns char
        if(!valid_dns_char(*data)) {
          return;
        }
        if (dpos<NS_MAXDNAME) dname[dpos++] = *data;
      }
      if (dpos<NS_MAXDNAME) dname[dpos++] = '.';
    }
    dname[dpos]='\0';

    // be careful not to walk past the end of the captured data
    if ( (void *)data < ((void *)packet+caplen-3) ) {
      data+=2;
      qtype = *data;
    }
    else {
      return;
    }

    if( option_D ) {
      printf("src: %-15s  proto: %s  qtype: 0x%02x  domain: %s\n", (inet_ntoa(ip_src)), 
      (ip->ip_p == 17 ? "udp" : "tcp"), qtype, dname);
    }

    // add packet to bucket array
    if (ntohs(dns->dns_qdcount)&&qtype) {
      add_to_bucket( &ip_src, ip->ip_p, 1, qtype );
    }
  }
  return;
}

// main logic
// some pcap code borrowed from http://www.cet.nau.edu/~mc8/Socket/Tutorials/section1.html
  int main(int argc,char **argv){ 
  char *dev = NULL; 
  pthread_t thread;
  char errbuf[PCAP_ERRBUF_SIZE];
  pcap_t* descr;
  struct bpf_program fp;      /* hold compiled program     */
  bpf_u_int32 maskp=0;          /* subnet mask               */
  bpf_u_int32 netp=0;           /* ip                        */
  char *filter = NULL;
  char *dst_addr = NULL;
  char *dst_mask = NULL;
  struct sigaction sa;
  struct in_addr addr,tmpaddr;
  u_int f_size;
  char *name = NULL;
  u_int c = 0;

  if ( ( name = (char *)strdup(argv[0]) ) == NULL) malloc_fail("name", strlen(argv[0]) );

  // loop through command line options and get options 
  while(1) {
    c = getopt(argc, argv,"i:t:a:w:x:m:A:M:QbdDvsh");
		
    if (c==-1) break;
    switch(c) {
      case 0:
        break;
      case 'i':
        if (optarg) {
          if ( ( dev = (char *)strdup(optarg) ) == NULL) malloc_fail("dev", strlen(optarg) );
        }
        break;
      case 't':
        if (optarg) {
          if ( abs (atoi(optarg)) > 0) {
            option_t = abs( atoi(optarg));
          }
        }
        break;
      case 'a':
        if (optarg) {
          if ( abs (atoi(optarg)) > 10) {
            option_a = abs( atoi(optarg));
          }
        }
        break;
      case 'w':
        if (optarg) {
          if ( abs (atoi(optarg)) > 1) {
            option_w = abs( atoi(optarg));
          }
        }
        break;
      case 'x':
        if (optarg) {
          if ( abs (atoi(optarg)) > 10) {
            option_x = abs( atoi(optarg));
          }
        }
        break;
      case 'm':
        if (optarg) {
          if ( abs (atoi(optarg)) > 0) {
            option_m = abs( atoi(optarg));
          }
        }
        break;
      case 'M':
        if (optarg && (dst_mask == NULL) ) {
          if ( inet_aton(optarg, &tmpaddr) ) {
            if ( ( dst_mask = (char *)strdup(optarg) ) == NULL) malloc_fail("filter mask", strlen(optarg) );
            option_M=1;
          } else {
            fprintf(stderr,"Invalid filter mask \"%s\"\n",optarg);
            option_h = 1;
          }
        }
        break;
      case 'A':
        if (optarg && (dst_addr == NULL) ) {
          if ( inet_aton(optarg, &tmpaddr) ) {
            if ( ( dst_addr = (char *)strdup(optarg) ) == NULL) malloc_fail("dest filter", strlen(optarg) );
            option_A=1;
          } else {
            fprintf(stderr,"Invalid filter address \"%s\"\n",optarg);
            option_h = 1;
          }
        }
        break;
      case 'Q':
        option_Q = 1;
        break;
      case 'b':
        option_b = 1;
        break;
      case 'd':
        option_d = 1;
        break;
      case 'D':
        option_D = 1;
         break;
      case 'v':
        option_v++;
        break;
      case 's':
        option_s = 1;
        break;
      case 'h':
        option_h = 1;
        break;
      case 'z': 
        target_ip = optarg;
        break;
      case 'p':
        target_port = atoi(optarg);
        break;
      default:
        break;
    }
  }

  // display usage info if needed
  if (optind<argc) option_h = 1;

  if (option_h) {
    fprintf(stderr,"dns_flood_detector, version %s\n",VERSION);
    fprintf(stderr,"Usage: %s [OPTION]\n\n",name);
    fprintf(stderr,"-i IFNAME                 specify device name to listen on\n");
    fprintf(stderr,"-t N                      alarm at >N queries per second\n");
    fprintf(stderr,"-a N                      reset alarm after N seconds\n");
    fprintf(stderr,"-w N                      calculate stats every N seconds\n");
    fprintf(stderr,"-x N                      create N buckets\n");
    fprintf(stderr,"-m N                      report overall stats every N seconds\n");
    fprintf(stderr,"-A addr                   filter for specific address\n");
    fprintf(stderr,"-M mask                   netmask for filter (in conjunction with -A)\n");
    fprintf(stderr,"-Q                        don't filter by local interface address\n");
    fprintf(stderr,"-b                        run in foreground in bindsnap mode\n");
    fprintf(stderr,"-d                        run in background in daemon mode\n");
    fprintf(stderr,"-D                        dump dns packets (implies -b)\n");
    fprintf(stderr,"-v                        verbose output - use again for more verbosity\n");
    fprintf(stderr,"-s                        send source-IP data to network collector as JSON\n");
    fprintf(stderr,"-z addr                   address to send stats to (default 226.1.1.2)\n");
    fprintf(stderr,"-p N                      UDP port to send stats to (default 2000)\n");	
    fprintf(stderr,"-h                        display this usage information\n");
    exit(1);
  }

  if ( target_ip == NULL ) {
    target_ip = DEFAULT_IP;
  }

  // if dumping packets, force option_b and disable option_d
  if( option_D ) {
    if( ! option_b )
      option_b = 1;
		
    if( option_d )
      option_d = 0;
  }

  if ( ( option_Q ) && ( option_A ) ) {
    fprintf(stderr,"%s couldn't start\n",name);
    fprintf(stderr,"You can't specify both -A (address filter) and -Q (no filter)\n");
    exit(1);
  }

  if ( ( ! option_d ) && ( ! option_b ) ) {
    fprintf(stderr,"%s couldn't start\n",name);
    fprintf(stderr,"You must specify either -d (daemon) or -b (bindsnap)\n");
    exit(1);
  }
  free(name);

  // set up for daemonized operation unless running in bindsnap mode
  if ( ! option_b ) {
    openlog("dns_flood_detector",LOG_PID|LOG_CONS,LOG_DAEMON);
    syslog(LOG_NOTICE,"dns_flood_detector starting");

    // daemonize unless running in bindsnap mode
    daemonize();

    // set up signal handlers
    sa.sa_handler=exit;
    sa.sa_flags=0;
    if(sigaction(SIGTERM,&sa,NULL)) {
      syslog(LOG_ERR,"Unable to set signal handler: %s.  Exiting.",strerror(errno));
    }
  }

  // find a valid device to open
  if(dev == NULL && ( (dev=pcap_lookupdev(errbuf)) == NULL ) ){
    fprintf(stderr,"unable to bind to valid device\n");
    exit(1);
  }

  /* restrict to queries to primary local address? */
  if (option_Q) {
    f_size = strlen("port 53 ");
    if ( ( filter = (char *) malloc ( f_size+1) ) == NULL ) malloc_fail( "filter", f_size+1 );
    snprintf( filter, f_size, "port 53");
  } else {
    if (! option_A) {
      // get network address and netmask for device
      pcap_lookupnet(dev,&netp,&maskp,errbuf);
		
      // set up filter with local network
      addr.s_addr = (unsigned long int)netp;
      if ( ( dst_addr = (char *)malloc( strlen((char *)inet_ntoa(addr))+1) ) == NULL ) malloc_fail("dest_addr", strlen((char *)inet_ntoa(addr))+1 );
      strncpy(dst_addr,(char*)inet_ntoa(addr),strlen((char *)inet_ntoa(addr)));
      dst_addr[strlen((char *)inet_ntoa(addr))]='\0';
		
      addr.s_addr = (unsigned long int)maskp;

      if (!option_M) {
        if ( ( dst_mask = (char *)malloc( strlen((char *)inet_ntoa(addr))+1) ) == NULL ) malloc_fail("dest_mask", strlen((char *)inet_ntoa(addr))+1 );
        strncpy(dst_mask,(char*)inet_ntoa(addr),strlen((char *)inet_ntoa(addr)));
        dst_mask[strlen((char *)inet_ntoa(addr))]='\0';
      }
    } else {
      // we're using an address from -A
      if (!option_M) {
        // if no mask was specified, then use just a host mask
        if ( ( dst_mask = (char *)malloc(16) ) == NULL ) malloc_fail("dest_mask", 16);
        strncpy(dst_mask,"255.255.255.255",15);
      }
    }
	
    f_size = strlen("port 53 and dst net mask   ")+ strlen(dst_mask)+ strlen(dst_addr);
    if ( ( filter = (char *) malloc ( f_size+1) ) == NULL ) malloc_fail( "filter", f_size+1 );
    snprintf( filter, f_size, "port 53 and dst net %s mask %s", dst_addr, dst_mask);
	
    free (dst_mask);
    free (dst_addr);
  }

  if ( option_b && option_v ) {
    printf("using filter \"%s\" on dev %s\n", filter, dev);
  }

  // open device for reading only local traffic
  descr = pcap_open_live(dev,1500,0,1,errbuf);
  if(descr == NULL) { 
    fprintf(stderr,"unable to open device %s\n",dev);
    exit(1);
  }

  // compile filter
  if(pcap_compile(descr,&fp,filter,0,netp) == -1) { 
    fprintf(stderr,"error compiling filter: %s\n",pcap_geterr(descr));
    exit(1);
  }

  // set filter
  if(pcap_setfilter(descr,&fp) == -1){ 
    fprintf(stderr,"error setting filter: %s\n",pcap_geterr(descr));
    exit(1); 
  }

  // initialize buckets and mark overall stats bucket
  init_buckets();
  totals = option_x;

  // create mutex lock
  if (pthread_mutex_init(&stats_lock, NULL) < 0) {
    exit(1);
  }

  // launch watcher thread
  if (pthread_create (&thread, NULL, run_stats, (void *)0)) {
    exit(1);
  }

  // main pcap loop
  pcap_loop(descr,-1,&handle_IP,NULL);

  // done
  closelog();
  return 0;
}

// daemonize the process
int daemonize(void) {
  pid_t pid;
  int fd;   
  int a;

  fd=open("/dev/null",O_RDWR);
  if(fd<0) {
    syslog(LOG_ERR,"Failed to open /dev/null: %s.  Exiting.",strerror(errno));
    exit(1); 
  }
 
  dup2(fd,0);
  dup2(fd,1);
  dup2(fd,2);

  if((pid=fork())<0) {
    syslog(LOG_ERR,"Fork failed: %s.  Exiting.",strerror(errno));
    exit(1);
  } 
  else if (pid!=0) {
    exit(0);
  }
           
  setsid();  
  a = chdir("/");
  umask(0);
  return 0;  
}

int malloc_fail( char * var, int size ) {
  // print error to stderr if running in bindsnap mode
  if (option_b) {
    fprintf(stderr, "our OS wouldn't let me malloc %d bytes for a new %s. giving up", size, var);
  }
  else {
    syslog(LOG_ERR, "our OS wouldn't let me malloc %d bytes for a new %s. giving up", size, var);
  }
  exit(1);
}

int microsleep(unsigned int usec) {
  struct timeval        timeout;
  timeout.tv_sec = usec / 1000000;
  timeout.tv_usec = usec % 1000000;

  while ((select(0, (fd_set *) 0, (fd_set *) 0,(fd_set *) 0, &timeout) < 0) && (errno == EINTR));
  return(0);
}