edge.c

/**
 * (C) 2007-09 - Luca Deri <deri@ntop.org>
 *               Richard Andrews <andrews@ntop.org>
 *
 * 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 3 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 see see <http://www.gnu.org/licenses/>
 *
 * Code contributions courtesy of:
 * Don Bindner <don.bindner@gmail.com>
 * Sylwester Sosnowski <syso-n2n@no-route.org>
 * Wilfried "Wonka" Klaebe
 * Lukasz Taczuk
 *
 */

#include "edge.h"

/** Return the IP address of the current supernode in the ring. */
static const char * supernode_ip( const n2n_edge_t * eee )
{
    return (eee->sn_ip_array)[eee->sn_idx];
}


#ifndef BUILD_FRONTEND
static
#endif
void supernode2addr(n2n_sock_t * sn, const n2n_sn_name_t addr);

static void send_packet2net(n2n_edge_t * eee,
			    uint8_t *decrypted_msg, size_t len);


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

/* parse the configuration file */
static int readConfFile(const char * filename, char * const linebuffer) {
  struct stat stats;
  FILE    *   fd;
  char    *   buffer = NULL;

  buffer = (char *)malloc(MAX_CONFFILE_LINE_LENGTH);
  if (!buffer) {
    traceEvent( TRACE_ERROR, "Unable to allocate memory");
    return -1;
  }

  if (stat(filename, &stats)) {
    if (errno == ENOENT)
      traceEvent(TRACE_ERROR, "parameter file %s not found/unable to access\n", filename);
    else
      traceEvent(TRACE_ERROR, "cannot stat file %s, errno=%d\n",filename, errno);
    free(buffer);
    return -1;
  }

  fd = fopen(filename, "rb");
  if (!fd) {
    traceEvent(TRACE_ERROR, "Unable to open parameter file '%s' (%d)...\n",filename,errno);
    free(buffer);
    return -1;
  }
  while(fgets(buffer, MAX_CONFFILE_LINE_LENGTH,fd)) {
    char    *   p = NULL;

    /* strip out comments */
    p = strchr(buffer, '#');
    if (p) *p ='\0';

    /* remove \n */
    p = strchr(buffer, '\n');
    if (p) *p ='\0';

    /* strip out heading spaces */
    p = buffer;
    while(*p == ' ' && *p != '\0') ++p;
    if (p != buffer) strncpy(buffer,p,strlen(p)+1);

    /* strip out trailing spaces */
    while(strlen(buffer) && buffer[strlen(buffer)-1]==' ')
      buffer[strlen(buffer)-1]= '\0';

    /* check for nested @file option */
    if (strchr(buffer, '@')) {
      traceEvent(TRACE_ERROR, "@file in file nesting is not supported\n");
      free(buffer);
      return -1;
    }
    if ((strlen(linebuffer)+strlen(buffer)+2)< MAX_CMDLINE_BUFFER_LENGTH) {
      strncat(linebuffer, " ", 1);
      strncat(linebuffer, buffer, strlen(buffer));
    } else {
      traceEvent(TRACE_ERROR, "too many argument");
      free(buffer);
      return -1;
    }
  }

  free(buffer);
  fclose(fd);

  return 0;
}

/* Create the argv vector */
static char ** buildargv(int * effectiveargc, char * const linebuffer) {
  const int  INITIAL_MAXARGC = 16;	/* Number of args + NULL in initial argv */
  int     maxargc;
  int     argc=0;
  char ** argv;
  char *  buffer, * buff;

  *effectiveargc = 0;
  buffer = (char *)calloc(1, strlen(linebuffer)+2);
  if (!buffer) {
    traceEvent( TRACE_ERROR, "Unable to allocate memory");
    return NULL;
  }
  strncpy(buffer, linebuffer,strlen(linebuffer));

  maxargc = INITIAL_MAXARGC;
  argv = (char **)malloc(maxargc * sizeof(char*));
  if (argv == NULL) {
    traceEvent( TRACE_ERROR, "Unable to allocate memory");
    return NULL;
  }
  buff = buffer;
  while(buff) {
    char * p = strchr(buff,' ');
    if (p) {
      *p='\0';
      argv[argc++] = strdup(buff);
      while(*++p == ' ' && *p != '\0');
      buff=p;
      if (argc >= maxargc) {
	maxargc *= 2;
	argv = (char **)realloc(argv, maxargc * sizeof(char*));
	if (argv == NULL) {
	  traceEvent(TRACE_ERROR, "Unable to re-allocate memory");
	  free(buffer);
	  return NULL;
	}
      }
    } else {
      argv[argc++] = strdup(buff);
      break;
    }
  }
  free(buffer);
  *effectiveargc = argc;
  return argv;
}



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


/** Initialise an edge to defaults.
 *
 *  This also initialises the NULL transform operation opstruct.
 */
#ifndef BUILD_FRONTEND
static
#endif
int edge_init(n2n_edge_t * eee)
{
#ifdef WIN32
    initWin32();
#endif
    memset(eee, 0, sizeof(n2n_edge_t));
    eee->start_time = time(NULL);

    transop_null_init(    &(eee->transop[N2N_TRANSOP_NULL_IDX]) );
    transop_twofish_init( &(eee->transop[N2N_TRANSOP_TF_IDX]  ) );
    transop_aes_init( &(eee->transop[N2N_TRANSOP_AESCBC_IDX]  ) );

    eee->tx_transop_idx = N2N_TRANSOP_NULL_IDX; /* No guarantee the others have been setup */

    eee->daemon = 1;    /* By default run in daemon mode. */
    eee->re_resolve_supernode_ip = 0;
    /* keyschedule set to NULLs by memset */
    /* community_name set to NULLs by memset */
    eee->null_transop   = 0;
    eee->udp_sock       = -1;
    eee->udp_mgmt_sock  = -1;
    eee->dyn_ip_mode    = 0;
    eee->allow_routing  = 0;
    eee->drop_multicast = 1;
    eee->known_peers    = NULL;
    eee->pending_peers  = NULL;
    eee->last_register_req = 0;
    eee->register_lifetime = REGISTER_SUPER_INTERVAL_DFL;
    eee->last_p2p = 0;
    eee->last_sup = 0;
    eee->sup_attempts = N2N_EDGE_SUP_ATTEMPTS;

    if(lzo_init() != LZO_E_OK)
    {
        traceEvent(TRACE_ERROR, "LZO compression error");
        return(-1);
    }

    return(0);
}



/* Called in main() after options are parsed. */
#ifndef BUILD_FRONTEND
static
#endif
int edge_init_twofish( n2n_edge_t * eee, uint8_t *encrypt_pwd, uint32_t encrypt_pwd_len )
{
    return transop_twofish_setup( &(eee->transop[N2N_TRANSOP_TF_IDX]), 0, encrypt_pwd, encrypt_pwd_len );
}


/** Find the transop op-struct for the transform enumeration required.
 *
 * @return - index into the transop array, or -1 on failure.
 */
static int transop_enum_to_index( n2n_transform_t id )
{
    switch (id)
    {
    case N2N_TRANSFORM_ID_TWOFISH:
        return N2N_TRANSOP_TF_IDX;
        break;
    case N2N_TRANSFORM_ID_NULL:
        return N2N_TRANSOP_NULL_IDX;
        break;
    case N2N_TRANSFORM_ID_AESCBC:
        return N2N_TRANSOP_AESCBC_IDX;
        break;
    default:
        return -1;
    }
}


/** Called periodically to roll keys and do any periodic maintenance in the
 *  tranform operations state machines. */
#ifndef BUILD_FRONTEND
static
#endif
int n2n_tick_transop( n2n_edge_t * eee, time_t now )
{
    n2n_tostat_t tst;
    size_t trop = eee->tx_transop_idx;

    /* Tests are done in order that most preferred transform is last and causes
     * tx_transop_idx to be left at most preferred valid transform. */
    tst = (eee->transop[N2N_TRANSOP_NULL_IDX].tick)( &(eee->transop[N2N_TRANSOP_NULL_IDX]), now );
    tst = (eee->transop[N2N_TRANSOP_AESCBC_IDX].tick)( &(eee->transop[N2N_TRANSOP_AESCBC_IDX]), now );
    if ( tst.can_tx )
    {
        traceEvent( TRACE_DEBUG, "can_tx AESCBC (idx=%u)", (unsigned int)N2N_TRANSOP_AESCBC_IDX );
        trop = N2N_TRANSOP_AESCBC_IDX;
    }

    tst = (eee->transop[N2N_TRANSOP_TF_IDX].tick)( &(eee->transop[N2N_TRANSOP_TF_IDX]), now );
    if ( tst.can_tx )
    {
        traceEvent( TRACE_DEBUG, "can_tx TF (idx=%u)", (unsigned int)N2N_TRANSOP_TF_IDX );
        trop = N2N_TRANSOP_TF_IDX;
    }

    if ( trop != eee->tx_transop_idx )
    {
        eee->tx_transop_idx = trop;
        traceEvent( TRACE_NORMAL, "Chose new tx_transop_idx=%u", (unsigned int)(eee->tx_transop_idx) );
    }

    return 0;
}



/** Read in a key-schedule file, parse the lines and pass each line to the
 *  appropriate trans_op for parsing of key-data and adding key-schedule
 *  entries. The lookup table of time->trans_op is constructed such that
 *  encoding can be passed to the correct trans_op. The trans_op internal table
 *  will then determine the best SA for that trans_op from the key schedule to
 *  use for encoding. */
#ifndef BUILD_FRONTEND
static
#endif
int edge_init_keyschedule( n2n_edge_t * eee )
{

#define N2N_NUM_CIPHERSPECS 32

    int retval = -1;
    ssize_t numSpecs=0;
    n2n_cipherspec_t specs[N2N_NUM_CIPHERSPECS];
    size_t i;
    time_t now = time(NULL);

    numSpecs = n2n_read_keyfile( specs, N2N_NUM_CIPHERSPECS, eee->keyschedule );

    if ( numSpecs > 0 )
    {
        traceEvent( TRACE_NORMAL, "keyfile = %s read -> %d specs.\n", optarg, (signed int)numSpecs);

        for ( i=0; i < (size_t)numSpecs; ++i )
        {
            int idx;

            idx = transop_enum_to_index( specs[i].t );

            switch (idx) 
            {
            case N2N_TRANSOP_TF_IDX:
            case N2N_TRANSOP_AESCBC_IDX:
            {
                retval = (eee->transop[idx].addspec)( &(eee->transop[idx]),
                                                      &(specs[i]) );
                break;
            }
            default:
                retval = -1;
            }

            if (0 != retval)
            {
                traceEvent( TRACE_ERROR, "keyschedule failed to add spec[%u] to transop[%d].\n", 
                            (unsigned int)i, idx);

                return retval;
            }
        }

        n2n_tick_transop( eee, now );
    }
    else
    {
        traceEvent( TRACE_ERROR, "Failed to process '%s'", eee->keyschedule );
    }

    return retval;
}


/** Deinitialise the edge and deallocate any owned memory. */
#ifndef BUILD_FRONTEND
static
#endif
void edge_deinit(n2n_edge_t * eee)
{
    if ( eee->udp_sock >=0 )
    {
        closesocket( eee->udp_sock );
    }

    if ( eee->udp_mgmt_sock >= 0 )
    {
        closesocket(eee->udp_mgmt_sock);
    }

    clear_peer_list( &(eee->pending_peers) );
    clear_peer_list( &(eee->known_peers) );

    (eee->transop[N2N_TRANSOP_TF_IDX].deinit)(&eee->transop[N2N_TRANSOP_TF_IDX]);
    (eee->transop[N2N_TRANSOP_NULL_IDX].deinit)(&eee->transop[N2N_TRANSOP_NULL_IDX]);
}

#ifndef BUILD_FRONTEND
static
#endif
void readFromIPSocket( n2n_edge_t * eee );

#ifndef BUILD_FRONTEND
static
#endif
void readFromMgmtSocket( n2n_edge_t * eee, int * keep_running );

#ifndef BUILD_FRONTEND
static void help() {
  print_n2n_version();

  printf("edge "
#if defined(N2N_CAN_NAME_IFACE)
	 "-d <tun device> "
#endif /* #if defined(N2N_CAN_NAME_IFACE) */
	 "-a [static:|dhcp:]<tun IP address> "
	 "-c <community> "
	 "[-k <encrypt key> | -K <key file>] "
	 "[-s <netmask>] "
#if defined(N2N_HAVE_SETUID)
	 "[-u <uid> -g <gid>]"
#endif /* #ifndef N2N_HAVE_SETUID */

#if defined(N2N_HAVE_DAEMON)
	 "[-f]"
#endif /* #if defined(N2N_HAVE_DAEMON) */
	 "[-m <MAC address>]"
	 "\n"
	 "-l <supernode host:port> "
	 "[-p <local port>] [-M <mtu>] "
	 "[-r] [-E] [-v] [-t <mgmt port>] [-b] [-h]\n\n");

#ifdef __linux__
  printf("-d <tun device>          | tun device name\n");
#endif

  printf("-a <mode:address>        | Set interface address. For DHCP use '-r -a dhcp:0.0.0.0'\n");
  printf("-c <community>           | n2n community name the edge belongs to.\n");
  printf("-k <encrypt key>         | Encryption key (ASCII) - also N2N_KEY=<encrypt key>. Not with -K.\n");
  printf("-K <key file>            | Specify a key schedule file to load. Not with -k.\n");
  printf("-s <netmask>             | Edge interface netmask in dotted decimal notation (255.255.255.0).\n");
  printf("-l <supernode host:port> | Supernode IP:port\n");
  printf("-b                       | Periodically resolve supernode IP\n");
  printf("                         : (when supernodes are running on dynamic IPs)\n");
  printf("-p <local port>          | Fixed local UDP port.\n");
#ifndef WIN32
  printf("-u <UID>                 | User ID (numeric) to use when privileges are dropped.\n");
  printf("-g <GID>                 | Group ID (numeric) to use when privileges are dropped.\n");
#endif /* ifndef WIN32 */
#ifdef N2N_HAVE_DAEMON
  printf("-f                       | Do not fork and run as a daemon; rather run in foreground.\n");
#endif /* #ifdef N2N_HAVE_DAEMON */
  printf("-m <MAC address>         | Fix MAC address for the TAP interface (otherwise it may be random)\n"
         "                         : eg. -m 01:02:03:04:05:06\n");
  printf("-M <mtu>                 | Specify n2n MTU of edge interface (default %d).\n", DEFAULT_MTU);
  printf("-r                       | Enable packet forwarding through n2n community.\n");
  printf("-E                       | Accept multicast MAC addresses (default=drop).\n");
  printf("-v                       | Make more verbose. Repeat as required.\n");
  printf("-t                       | Management UDP Port (for multiple edges on a machine).\n");

  printf("\nEnvironment variables:\n");
  printf("  N2N_KEY                | Encryption key (ASCII). Not with -K or -k.\n" );

  exit(0);
}
#endif


/** Send a datagram to a socket defined by a n2n_sock_t */
static ssize_t sendto_sock( int fd, const void * buf, size_t len, const n2n_sock_t * dest )
{
    struct sockaddr_in peer_addr;
    ssize_t sent;

    fill_sockaddr( (struct sockaddr *) &peer_addr,
                   sizeof(peer_addr),
                   dest );

    sent = sendto( fd, buf, len, 0/*flags*/,
                   (struct sockaddr *)&peer_addr, sizeof(struct sockaddr_in) );
    if ( sent < 0 )
    {
        char * c = strerror(errno);
        traceEvent( TRACE_ERROR, "sendto failed (%d) %s", errno, c );
    }
    else
    {
        traceEvent( TRACE_DEBUG, "sendto sent=%d to ", (signed int)sent );
    }

    return sent;
}


/** Send a REGISTER packet to another edge. */
static void send_register( n2n_edge_t * eee,
                           const n2n_sock_t * remote_peer)
{
    uint8_t pktbuf[N2N_PKT_BUF_SIZE];
    size_t idx;
    ssize_t sent;
    n2n_common_t cmn;
    n2n_REGISTER_t reg;
    n2n_sock_str_t sockbuf;

    memset(&cmn, 0, sizeof(cmn) );
    memset(&reg, 0, sizeof(reg) );
    cmn.ttl=N2N_DEFAULT_TTL;
    cmn.pc = n2n_register;
    cmn.flags = 0;
    memcpy( cmn.community, eee->community_name, N2N_COMMUNITY_SIZE );

    idx=0;
    encode_uint32( reg.cookie, &idx, 123456789 );
    idx=0;
    encode_mac( reg.srcMac, &idx, eee->device.mac_addr );

    idx=0;
    encode_REGISTER( pktbuf, &idx, &cmn, &reg );

    traceEvent( TRACE_INFO, "send REGISTER %s",
                sock_to_cstr( sockbuf, remote_peer ) );


    sent = sendto_sock( eee->udp_sock, pktbuf, idx, remote_peer );

}


/** Send a REGISTER_SUPER packet to the current supernode. */
static void send_register_super( n2n_edge_t * eee,
                                 const n2n_sock_t * supernode)
{
    uint8_t pktbuf[N2N_PKT_BUF_SIZE];
    size_t idx;
    ssize_t sent;
    n2n_common_t cmn;
    n2n_REGISTER_SUPER_t reg;
    n2n_sock_str_t sockbuf;

    memset(&cmn, 0, sizeof(cmn) );
    memset(&reg, 0, sizeof(reg) );
    cmn.ttl=N2N_DEFAULT_TTL;
    cmn.pc = n2n_register_super;
    cmn.flags = 0;
    memcpy( cmn.community, eee->community_name, N2N_COMMUNITY_SIZE );

    for( idx=0; idx < N2N_COOKIE_SIZE; ++idx )
    {
        eee->last_cookie[idx] = rand() % 0xff;
    }

    memcpy( reg.cookie, eee->last_cookie, N2N_COOKIE_SIZE );
    reg.auth.scheme=0; /* No auth yet */

    idx=0;
    encode_mac( reg.edgeMac, &idx, eee->device.mac_addr );

    idx=0;
    encode_REGISTER_SUPER( pktbuf, &idx, &cmn, &reg );

    traceEvent( TRACE_INFO, "send REGISTER_SUPER to %s",
                sock_to_cstr( sockbuf, supernode ) );


    sent = sendto_sock( eee->udp_sock, pktbuf, idx, supernode );

}


/** Send a REGISTER_ACK packet to a peer edge. */
static void send_register_ack( n2n_edge_t * eee,
                               const n2n_sock_t * remote_peer,
                               const n2n_REGISTER_t * reg )
{
    uint8_t pktbuf[N2N_PKT_BUF_SIZE];
    size_t idx;
    ssize_t sent;
    n2n_common_t cmn;
    n2n_REGISTER_ACK_t ack;
    n2n_sock_str_t sockbuf;

    memset(&cmn, 0, sizeof(cmn) );
    memset(&ack, 0, sizeof(reg) );
    cmn.ttl=N2N_DEFAULT_TTL;
    cmn.pc = n2n_register_ack;
    cmn.flags = 0;
    memcpy( cmn.community, eee->community_name, N2N_COMMUNITY_SIZE );

    memset( &ack, 0, sizeof(ack) );
    memcpy( ack.cookie, reg->cookie, N2N_COOKIE_SIZE );
    memcpy( ack.srcMac, eee->device.mac_addr, N2N_MAC_SIZE );
    memcpy( ack.dstMac, reg->srcMac, N2N_MAC_SIZE );

    idx=0;
    encode_REGISTER_ACK( pktbuf, &idx, &cmn, &ack );

    traceEvent( TRACE_INFO, "send REGISTER_ACK %s",
                sock_to_cstr( sockbuf, remote_peer ) );


    sent = sendto_sock( eee->udp_sock, pktbuf, idx, remote_peer );
}


/** NOT IMPLEMENTED
 *
 *  This would send a DEREGISTER packet to a peer edge or supernode to indicate
 *  the edge is going away.
 */
#ifndef BUILD_FRONTEND
static
#endif
void send_deregister(n2n_edge_t * eee,
                            n2n_sock_t * remote_peer)
{
    /* Marshall and send message */
}


static int is_empty_ip_address( const n2n_sock_t * sock );
static void update_peer_address(n2n_edge_t * eee,
                                uint8_t from_supernode,
                                const n2n_mac_t mac,
                                const n2n_sock_t * peer,
                                time_t when);
void check_peer( n2n_edge_t * eee,
                 uint8_t from_supernode,
                 const n2n_mac_t mac,
                 const n2n_sock_t * peer );
void try_send_register( n2n_edge_t * eee,
                        uint8_t from_supernode,
                        const n2n_mac_t mac,
                        const n2n_sock_t * peer );
void set_peer_operational( n2n_edge_t * eee,
                           const n2n_mac_t mac,
                           const n2n_sock_t * peer );



/** Start the registration process.
 *
 *  If the peer is already in pending_peers, ignore the request.
 *  If not in pending_peers, add it and send a REGISTER.
 *
 *  If hdr is for a direct peer-to-peer packet, try to register back to sender
 *  even if the MAC is in pending_peers. This is because an incident direct
 *  packet indicates that peer-to-peer exchange should work so more aggressive
 *  registration can be permitted (once per incoming packet) as this should only
 *  last for a small number of packets..
 *
 *  Called from the main loop when Rx a packet for our device mac.
 */
void try_send_register( n2n_edge_t * eee,
                        uint8_t from_supernode,
                        const n2n_mac_t mac,
                        const n2n_sock_t * peer )
{
    /* REVISIT: purge of pending_peers not yet done. */
    struct peer_info * scan = find_peer_by_mac( eee->pending_peers, mac );
    macstr_t mac_buf;
    n2n_sock_str_t sockbuf;

    if ( NULL == scan )
    {
        scan = calloc( 1, sizeof( struct peer_info ) );

        memcpy(scan->mac_addr, mac, N2N_MAC_SIZE);
        scan->sock = *peer;
        scan->last_seen = time(NULL); /* Don't change this it marks the pending peer for removal. */

        peer_list_add( &(eee->pending_peers), scan );

        traceEvent( TRACE_DEBUG, "=== new pending %s -> %s",
                    macaddr_str( mac_buf, scan->mac_addr ),
                    sock_to_cstr( sockbuf, &(scan->sock) ) );

        traceEvent( TRACE_INFO, "Pending peers list size=%u",
                    (unsigned int)peer_list_size( eee->pending_peers ) );

        /* trace Sending REGISTER */

        send_register(eee, &(scan->sock) );

        /* pending_peers now owns scan. */
    }
    else
    {
    }
}


/** Update the last_seen time for this peer, or get registered. */
void check_peer( n2n_edge_t * eee,
                 uint8_t from_supernode,
                 const n2n_mac_t mac,
                 const n2n_sock_t * peer )
{
    struct peer_info * scan = find_peer_by_mac( eee->known_peers, mac );

    if ( NULL == scan )
    {
        /* Not in known_peers - start the REGISTER process. */
        try_send_register( eee, from_supernode, mac, peer );
    }
    else
    {
        /* Already in known_peers. */
        update_peer_address( eee, from_supernode, mac, peer, time(NULL) );
    }
}


/* Move the peer from the pending_peers list to the known_peers lists.
 *
 * peer must be a pointer to an element of the pending_peers list.
 *
 * Called by main loop when Rx a REGISTER_ACK.
 */
void set_peer_operational( n2n_edge_t * eee,
                        const n2n_mac_t mac,
                        const n2n_sock_t * peer )
{
    struct peer_info * prev = NULL;
    struct peer_info * scan;
    macstr_t mac_buf;
    n2n_sock_str_t sockbuf;

    traceEvent( TRACE_INFO, "set_peer_operational: %s -> %s",
                macaddr_str( mac_buf, mac),
                sock_to_cstr( sockbuf, peer ) );

    scan=eee->pending_peers;

    while ( NULL != scan )
    {
        if ( 0 == memcmp( scan->mac_addr, mac, N2N_MAC_SIZE ) )
        {
            break; /* found. */
        }

        prev = scan;
        scan = scan->next;
    }

    if ( scan )
    {


        /* Remove scan from pending_peers. */
        if ( prev )
        {
            prev->next = scan->next;
        }
        else
        {
            eee->pending_peers = scan->next;
        }

        /* Add scan to known_peers. */
        scan->next = eee->known_peers;
        eee->known_peers = scan;

        scan->sock = *peer;

        traceEvent( TRACE_DEBUG, "=== new peer %s -> %s",
                    macaddr_str( mac_buf, scan->mac_addr),
                    sock_to_cstr( sockbuf, &(scan->sock) ) );

        traceEvent( TRACE_INFO, "Pending peers list size=%u",
                    (unsigned int)peer_list_size( eee->pending_peers ) );

        traceEvent( TRACE_INFO, "Operational peers list size=%u",
                    (unsigned int)peer_list_size( eee->known_peers ) );


        scan->last_seen = time(NULL);
    }
    else
    {
        traceEvent( TRACE_DEBUG, "Failed to find sender in pending_peers." );
    }
}


n2n_mac_t broadcast_mac = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff };

static int is_empty_ip_address( const n2n_sock_t * sock )
{
    const uint8_t * ptr=NULL;
    size_t len=0;
    size_t i;

    if ( AF_INET6 == sock->family )
    {
        ptr = sock->addr.v6;
        len = 16;
    }
    else
    {
        ptr = sock->addr.v4;
        len = 4;
    }

    for (i=0; i<len; ++i)
    {
        if ( 0 != ptr[i] )
        {
            /* found a non-zero byte in address */
            return 0;
        }
    }

    return 1;
}


/** Keep the known_peers list straight.
 *
 *  Ignore broadcast L2 packets, and packets with invalid public_ip.
 *  If the dst_mac is in known_peers make sure the entry is correct:
 *  - if the public_ip socket has changed, erase the entry
 *  - if the same, update its last_seen = when
 */
static void update_peer_address(n2n_edge_t * eee,
                                uint8_t from_supernode,
                                const n2n_mac_t mac,
                                const n2n_sock_t * peer,
                                time_t when)
{
    struct peer_info *scan = eee->known_peers;
    struct peer_info *prev = NULL; /* use to remove bad registrations. */
    n2n_sock_str_t sockbuf1;
    n2n_sock_str_t sockbuf2; /* don't clobber sockbuf1 if writing two addresses to trace */
    macstr_t mac_buf;

    if ( is_empty_ip_address( peer ) )
    {
        /* Not to be registered. */
        return;
    }

    if ( 0 == memcmp( mac, broadcast_mac, N2N_MAC_SIZE ) )
    {
        /* Not to be registered. */
        return;
    }


    while(scan != NULL)
    {
        if(memcmp(mac, scan->mac_addr, N2N_MAC_SIZE) == 0)
        {
            break;
        }

        prev = scan;
        scan = scan->next;
    }

    if ( NULL == scan )
    {
        /* Not in known_peers. */
        return;
    }

    if ( 0 != sock_equal( &(scan->sock), peer))
    {
        if ( 0 == from_supernode )
        {
            traceEvent( TRACE_NORMAL, "Peer changed %s: %s -> %s",
                        macaddr_str( mac_buf, scan->mac_addr ),
                        sock_to_cstr(sockbuf1, &(scan->sock)),
                        sock_to_cstr(sockbuf2, peer) );

            /* The peer has changed public socket. It can no longer be assumed to be reachable. */
            /* Remove the peer. */
            if ( NULL == prev )
            {
                /* scan was head of list */
                eee->known_peers = scan->next;
            }
            else
            {
                prev->next = scan->next;
            }
            free(scan);

            try_send_register( eee, from_supernode, mac, peer );
        }
        else
        {
            /* Don't worry about what the supernode reports, it could be seeing a different socket. */
        }
    }
    else
    {
        /* Found and unchanged. */
        scan->last_seen = when;
    }
}



#if defined(DUMMY_ID_00001) /* Disabled waiting for config option to enable it */



static char gratuitous_arp[] = {
  0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, /* Dest mac */
  0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* Src mac */
  0x08, 0x06, /* ARP */
  0x00, 0x01, /* Ethernet */
  0x08, 0x00, /* IP */
  0x06, /* Hw Size */
  0x04, /* Protocol Size */
  0x00, 0x01, /* ARP Request */
  0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* Src mac */
  0x00, 0x00, 0x00, 0x00, /* Src IP */
  0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* Target mac */
  0x00, 0x00, 0x00, 0x00 /* Target IP */
};


/** Build a gratuitous ARP packet for a /24 layer 3 (IP) network. */
static int build_gratuitous_arp(char *buffer, uint16_t buffer_len) {
  if(buffer_len < sizeof(gratuitous_arp)) return(-1);

  memcpy(buffer, gratuitous_arp, sizeof(gratuitous_arp));
  memcpy(&buffer[6], device.mac_addr, 6);
  memcpy(&buffer[22], device.mac_addr, 6);
  memcpy(&buffer[28], &device.ip_addr, 4);

  /* REVISIT: BbMaj7 - use a real netmask here. This is valid only by accident
   * for /24 IPv4 networks. */
  buffer[31] = 0xFF; /* Use a faked broadcast address */
  memcpy(&buffer[38], &device.ip_addr, 4);
  return(sizeof(gratuitous_arp));
}

/** Called from update_supernode_reg to periodically send gratuitous ARP
 *  broadcasts. */
static void send_grat_arps(n2n_edge_t * eee,) {
  char buffer[48];
  size_t len;

  traceEvent(TRACE_NORMAL, "Sending gratuitous ARP...");
  len = build_gratuitous_arp(buffer, sizeof(buffer));
  send_packet2net(eee, buffer, len);
  send_packet2net(eee, buffer, len); /* Two is better than one :-) */
}
#endif /* #if defined(DUMMY_ID_00001) */




/** @brief Check to see if we should re-register with the supernode.
 *
 *  This is frequently called by the main loop.
 */
#ifndef BUILD_FRONTEND
static
#endif
void update_supernode_reg( n2n_edge_t * eee, time_t nowTime )
{
    if ( eee->sn_wait && ( nowTime > (eee->last_register_req + (eee->register_lifetime/10) ) ) )
    {
        /* fall through */
        traceEvent( TRACE_DEBUG, "update_supernode_reg: doing fast retry." );
    }
    else if ( nowTime < (eee->last_register_req + eee->register_lifetime))
    {
        return; /* Too early */
    }

    if ( 0 == eee->sup_attempts )
    {
        /* Give up on that supernode and try the next one. */
        ++(eee->sn_idx);

        if (eee->sn_idx >= eee->sn_num)
        {
            /* Got to end of list, go back to the start. Also works for list of one entry. */
            eee->sn_idx=0;
        }

        traceEvent(TRACE_WARNING, "Supernode not responding - moving to %u of %u", 
                   (unsigned int)eee->sn_idx, (unsigned int)eee->sn_num );

        eee->sup_attempts = N2N_EDGE_SUP_ATTEMPTS;
    }
    else
    {
        --(eee->sup_attempts);
    }

    if(eee->re_resolve_supernode_ip || (eee->sn_num > 1) )
    {
        supernode2addr(&(eee->supernode), eee->sn_ip_array[eee->sn_idx] );
    }

    traceEvent(TRACE_DEBUG, "Registering with supernode (%s) (attempts left %u)",
               supernode_ip(eee), (unsigned int)eee->sup_attempts);

    send_register_super( eee, &(eee->supernode) );

    eee->sn_wait=1;

    /* REVISIT: turn-on gratuitous ARP with config option. */
    /* send_grat_arps(sock_fd, is_udp_sock); */

    eee->last_register_req = nowTime;
}



/* @return 1 if destination is a peer, 0 if destination is supernode */
static int find_peer_destination(n2n_edge_t * eee,
                                 n2n_mac_t mac_address,
                                 n2n_sock_t * destination)
{
    const struct peer_info *scan = eee->known_peers;
    macstr_t mac_buf;
    n2n_sock_str_t sockbuf;
    int retval=0;

    traceEvent(TRACE_DEBUG, "Searching destination peer for MAC %02X:%02X:%02X:%02X:%02X:%02X",
               mac_address[0] & 0xFF, mac_address[1] & 0xFF, mac_address[2] & 0xFF,
               mac_address[3] & 0xFF, mac_address[4] & 0xFF, mac_address[5] & 0xFF);

    while(scan != NULL) {
        traceEvent(TRACE_DEBUG, "Evaluating peer [MAC=%02X:%02X:%02X:%02X:%02X:%02X]",
                   scan->mac_addr[0] & 0xFF, scan->mac_addr[1] & 0xFF, scan->mac_addr[2] & 0xFF,
                   scan->mac_addr[3] & 0xFF, scan->mac_addr[4] & 0xFF, scan->mac_addr[5] & 0xFF
            );

        if((scan->last_seen > 0) &&
           (memcmp(mac_address, scan->mac_addr, N2N_MAC_SIZE) == 0))
        {
            memcpy(destination, &scan->sock, sizeof(n2n_sock_t));
            retval=1;
            break;
        }
        scan = scan->next;
    }

    if ( 0 == retval )
    {
        memcpy(destination, &(eee->supernode), sizeof(struct sockaddr_in));
    }

    traceEvent(TRACE_DEBUG, "find_peer_address (%s) -> [%s]",
               macaddr_str( mac_buf, mac_address ),
               sock_to_cstr( sockbuf, destination ) );

    return retval;
}




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

static const struct option long_options[] = {
  { "community",       required_argument, NULL, 'c' },
  { "supernode-list",  required_argument, NULL, 'l' },
  { "tun-device",      required_argument, NULL, 'd' },
  { "euid",            required_argument, NULL, 'u' },
  { "egid",            required_argument, NULL, 'g' },
  { "help"   ,         no_argument,       NULL, 'h' },
  { "verbose",         no_argument,       NULL, 'v' },
  { NULL,              0,                 NULL,  0  }
};

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


/** Send an ecapsulated ethernet PACKET to a destination edge or broadcast MAC
 *  address. */
static int send_PACKET( n2n_edge_t * eee,
                        n2n_mac_t dstMac,
                        const uint8_t * pktbuf,
                        size_t pktlen )
{
    int dest;
    ssize_t s;
    n2n_sock_str_t sockbuf;
    n2n_sock_t destination;

    /* hexdump( pktbuf, pktlen ); */

    dest = find_peer_destination(eee, dstMac, &destination);

    if ( dest )
    {
        ++(eee->tx_p2p);
    }
    else
    {
        ++(eee->tx_sup);
    }

    traceEvent( TRACE_INFO, "send_PACKET to %s", sock_to_cstr( sockbuf, &destination ) );

    s = sendto_sock( eee->udp_sock, pktbuf, pktlen, &destination );

    return 0;
}


/* Choose the transop for Tx. This should be based on the newest valid
 * cipherspec in the key schedule. 
 *
 * Never fall back to NULL tranform unless no key sources were specified. It is
 * better to render edge inoperative than to expose user data in the clear. In
 * the case where all SAs are expired an arbitrary transform will be chosen for
 * Tx. It will fail having no valid SAs but one must be selected.
 */
static size_t edge_choose_tx_transop( const n2n_edge_t * eee )
{
    if ( eee->null_transop)
    {
        return N2N_TRANSOP_NULL_IDX;
    }

    return eee->tx_transop_idx;
}


/** A layer-2 packet was received at the tunnel and needs to be sent via UDP. */
static void send_packet2net(n2n_edge_t * eee,
                            uint8_t *tap_pkt, size_t len)
{
    ipstr_t ip_buf;
    n2n_mac_t destMac;

    n2n_common_t cmn;
    n2n_PACKET_t pkt;

    uint8_t pktbuf[N2N_PKT_BUF_SIZE];
    size_t idx=0;
    size_t tx_transop_idx=0;

    ether_hdr_t eh;

    /* tap_pkt is not aligned so we have to copy to aligned memory */
    memcpy( &eh, tap_pkt, sizeof(ether_hdr_t) );

    /* Discard IP packets that are not originated by this hosts */
    if(!(eee->allow_routing)) {
        if(ntohs(eh.type) == 0x0800) {
            /* This is an IP packet from the local source address - not forwarded. */
#define ETH_FRAMESIZE 14
#define IP4_SRCOFFSET 12
            uint32_t *dst = (uint32_t*)&tap_pkt[ETH_FRAMESIZE + IP4_SRCOFFSET];

            /* Note: all elements of the_ip are in network order */
            if( *dst != eee->device.ip_addr) {
		/* This is a packet that needs to be routed */
		traceEvent(TRACE_INFO, "Discarding routed packet [%s]",
                           intoa(ntohl(*dst), ip_buf, sizeof(ip_buf)));
		return;
            } else {
                /* This packet is originated by us */
                /* traceEvent(TRACE_INFO, "Sending non-routed packet"); */
            }
        }
    }

    /* Optionally compress then apply transforms, eg encryption. */

    /* Once processed, send to destination in PACKET */

    memcpy( destMac, tap_pkt, N2N_MAC_SIZE ); /* dest MAC is first in ethernet header */

    memset( &cmn, 0, sizeof(cmn) );
    cmn.ttl = N2N_DEFAULT_TTL;
    cmn.pc = n2n_packet;
    cmn.flags=0; /* no options, not from supernode, no socket */
    memcpy( cmn.community, eee->community_name, N2N_COMMUNITY_SIZE );

    memset( &pkt, 0, sizeof(pkt) );
    memcpy( pkt.srcMac, eee->device.mac_addr, N2N_MAC_SIZE);
    memcpy( pkt.dstMac, destMac, N2N_MAC_SIZE);

    tx_transop_idx = edge_choose_tx_transop( eee );

    pkt.sock.family=0; /* do not encode sock */
    pkt.transform = eee->transop[tx_transop_idx].transform_id;

    idx=0;
    encode_PACKET( pktbuf, &idx, &cmn, &pkt );
    traceEvent( TRACE_DEBUG, "encoded PACKET header of size=%u transform %u (idx=%u)", 
                (unsigned int)idx, (unsigned int)pkt.transform, (unsigned int)tx_transop_idx );

    idx += eee->transop[tx_transop_idx].fwd( &(eee->transop[tx_transop_idx]),
                                             pktbuf+idx, N2N_PKT_BUF_SIZE-idx,
                                             tap_pkt, len );
    ++(eee->transop[tx_transop_idx].tx_cnt); /* stats */

    send_PACKET( eee, destMac, pktbuf, idx ); /* to peer or supernode */
}


/** Destination MAC 33:33:0:00:00:00 - 33:33:FF:FF:FF:FF is reserved for IPv6
 *  neighbour discovery.
 */
static int is_ip6_discovery( const void * buf, size_t bufsize )
{
    int retval = 0;

    if ( bufsize >= sizeof(ether_hdr_t) )
    {
        /* copy to aligned memory */
        ether_hdr_t eh;
        memcpy( &eh, buf, sizeof(ether_hdr_t) );

        if ( (0x33 == eh.dhost[0]) &&
             (0x33 == eh.dhost[1]) )
        {
            retval = 1; /* This is an IPv6 multicast packet [RFC2464]. */
        }
    }
    return retval;
}

/** Destination 01:00:5E:00:00:00 - 01:00:5E:7F:FF:FF is multicast ethernet.
 */
static int is_ethMulticast( const void * buf, size_t bufsize )
{
    int retval = 0;

    /* Match 01:00:5E:00:00:00 - 01:00:5E:7F:FF:FF */
    if ( bufsize >= sizeof(ether_hdr_t) )
    {
        /* copy to aligned memory */
        ether_hdr_t eh;
        memcpy( &eh, buf, sizeof(ether_hdr_t) );

        if ( (0x01 == eh.dhost[0]) &&
             (0x00 == eh.dhost[1]) &&
             (0x5E == eh.dhost[2]) &&
             (0 == (0x80 & eh.dhost[3])) )
        {
            retval = 1; /* This is an ethernet multicast packet [RFC1112]. */
        }
    }
    return retval;
}



/** Read a single packet from the TAP interface, process it and write out the
 *  corresponding packet to the cooked socket.
 */
#ifndef BUILD_FRONTEND
static
#endif
void readFromTAPSocket( n2n_edge_t * eee )
{
    /* tun -> remote */
    uint8_t             eth_pkt[N2N_PKT_BUF_SIZE];
    macstr_t            mac_buf;
    ssize_t             len;

    len = tuntap_read( &(eee->device), eth_pkt, N2N_PKT_BUF_SIZE );

    if( (len <= 0) || (len > N2N_PKT_BUF_SIZE) )
    {
        traceEvent(TRACE_WARNING, "read()=%d [%d/%s]",
                   (signed int)len, errno, strerror(errno));
    }
    else
    {
        const uint8_t * mac = eth_pkt;
        traceEvent(TRACE_INFO, "### Rx TAP packet (%4d) for %s",
                   (signed int)len, macaddr_str(mac_buf, mac) );

        if ( eee->drop_multicast &&
             ( is_ip6_discovery( eth_pkt, len ) ||
               is_ethMulticast( eth_pkt, len)
                 )
            )
        {
            traceEvent(TRACE_DEBUG, "Dropping multicast");
        }
        else
        {
            send_packet2net(eee, eth_pkt, len);
        }
    }
}



/** A PACKET has arrived containing an encapsulated ethernet datagram - usually
 *  encrypted. */
static int handle_PACKET( n2n_edge_t * eee,
                          const n2n_common_t * cmn,
                          const n2n_PACKET_t * pkt,
                          const n2n_sock_t * orig_sender,
                          uint8_t * payload,
                          size_t psize )
{
    ssize_t             data_sent_len;
    uint8_t             from_supernode;
    uint8_t *           eth_payload=NULL;
    int                 retval = -1;
    time_t              now;

    now = time(NULL);

    traceEvent( TRACE_DEBUG, "handle_PACKET size %u transform %u", 
                (unsigned int)psize, (unsigned int)pkt->transform );
    /* hexdump( payload, psize ); */

    from_supernode= cmn->flags & N2N_FLAGS_FROM_SUPERNODE;

    if ( from_supernode )
    {
        ++(eee->rx_sup);
        eee->last_sup=now;
    }
    else
    {
        ++(eee->rx_p2p);
        eee->last_p2p=now;
    }

    /* Update the sender in peer table entry */
    check_peer( eee, from_supernode, pkt->srcMac, orig_sender );

    /* Handle transform. */
    {
        uint8_t decodebuf[N2N_PKT_BUF_SIZE];
        size_t eth_size;
        size_t rx_transop_idx=0;

        rx_transop_idx = transop_enum_to_index(pkt->transform);

        if ( rx_transop_idx >=0 )
        {
            eth_payload = decodebuf;
            eth_size = eee->transop[rx_transop_idx].rev( &(eee->transop[rx_transop_idx]),
                                                         eth_payload, N2N_PKT_BUF_SIZE,
                                                         payload, psize );
            ++(eee->transop[rx_transop_idx].rx_cnt); /* stats */

            /* Write ethernet packet to tap device. */
            traceEvent( TRACE_INFO, "sending to TAP %u", (unsigned int)eth_size );
            data_sent_len = tuntap_write(&(eee->device), eth_payload, eth_size);

            if (data_sent_len == eth_size)
            {
                retval = 0;
            }
        }
        else
        {
            traceEvent( TRACE_ERROR, "handle_PACKET dropped unknown transform enum %u", 
                        (unsigned int)pkt->transform );
        }
    }

    return retval;
}


/** Read a datagram from the management UDP socket and take appropriate
 *  action. */
#ifndef BUILD_FRONTEND
static
#endif
void readFromMgmtSocket( n2n_edge_t * eee, int * keep_running )
{
    uint8_t             udp_buf[N2N_PKT_BUF_SIZE];      /* Compete UDP packet */
    ssize_t             recvlen;
    ssize_t             sendlen;
    struct sockaddr_in  sender_sock;
    socklen_t           i;
    size_t              msg_len;
    time_t              now;

    now = time(NULL);
    i = sizeof(sender_sock);
    recvlen=recvfrom(eee->udp_mgmt_sock, udp_buf, N2N_PKT_BUF_SIZE, 0/*flags*/,
		     (struct sockaddr *)&sender_sock, (socklen_t*)&i);

    if ( recvlen < 0 )
    {
        traceEvent(TRACE_ERROR, "mgmt recvfrom failed with %s", strerror(errno) );

        return; /* failed to receive data from UDP */
    }

    if ( recvlen >= 4 )
    {
        if ( 0 == memcmp( udp_buf, "stop", 4 ) )
        {
            traceEvent( TRACE_ERROR, "stop command received." );
            *keep_running = 0;
            return;
        }

        if ( 0 == memcmp( udp_buf, "help", 4 ) )
        {
            msg_len=0;
            ++traceLevel;

            msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                                 "Help for edge management console:\n"
                                 "  stop    Gracefully exit edge\n"
                                 "  help    This help message\n"
                                 "  +verb   Increase verbosity of logging\n"
                                 "  -verb   Decrease verbosity of logging\n"
                                 "  reload  Re-read the keyschedule\n"
                                 "  <enter> Display statistics\n\n");

            sendto( eee->udp_mgmt_sock, udp_buf, msg_len, 0/*flags*/,
                    (struct sockaddr *)&sender_sock, sizeof(struct sockaddr_in) );

            return;
        }

    }

    if ( recvlen >= 5 )
    {
        if ( 0 == memcmp( udp_buf, "+verb", 5 ) )
        {
            msg_len=0;
            ++traceLevel;

            traceEvent( TRACE_ERROR, "+verb traceLevel=%u", (unsigned int)traceLevel );
            msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                                     "> +OK traceLevel=%u\n", (unsigned int)traceLevel );

            sendto( eee->udp_mgmt_sock, udp_buf, msg_len, 0/*flags*/,
                    (struct sockaddr *)&sender_sock, sizeof(struct sockaddr_in) );

            return;
        }

        if ( 0 == memcmp( udp_buf, "-verb", 5 ) )
        {
            msg_len=0;

            if ( traceLevel > 0 )
            {
                --traceLevel;
                msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                                     "> -OK traceLevel=%u\n", traceLevel );
            }
            else
            {
                msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                                     "> -NOK traceLevel=%u\n", traceLevel );
            }

            traceEvent( TRACE_ERROR, "-verb traceLevel=%u", (unsigned int)traceLevel );

            sendto( eee->udp_mgmt_sock, udp_buf, msg_len, 0/*flags*/,
                    (struct sockaddr *)&sender_sock, sizeof(struct sockaddr_in) );
            return;
        }
    }

    if ( recvlen >= 6 )
    {
        if ( 0 == memcmp( udp_buf, "reload", 6 ) )
        {
            if ( strlen( eee->keyschedule ) > 0 )
            {
                if ( edge_init_keyschedule(eee) == 0 )
                {
                    msg_len=0;
                    msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                                         "> OK\n" );
                    sendto( eee->udp_mgmt_sock, udp_buf, msg_len, 0/*flags*/,
                            (struct sockaddr *)&sender_sock, sizeof(struct sockaddr_in) );
                }
                return;
            }
        }
    }

    traceEvent(TRACE_DEBUG, "mgmt status rq" );

    msg_len=0;
    msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                         "Statistics for edge\n" );

    msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                         "uptime %lu\n",
                         time(NULL) - eee->start_time );

    msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                         "paths  super:%u,%u p2p:%u,%u\n",
                         (unsigned int)eee->tx_sup,
			 (unsigned int)eee->rx_sup,
			 (unsigned int)eee->tx_p2p,
			 (unsigned int)eee->rx_p2p );

    msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                         "trans:null |%6u|%6u|\n"
                         "trans:tf   |%6u|%6u|\n"
                         "trans:aes  |%6u|%6u|\n",
                         (unsigned int)eee->transop[N2N_TRANSOP_NULL_IDX].tx_cnt,
                         (unsigned int)eee->transop[N2N_TRANSOP_NULL_IDX].rx_cnt,
                         (unsigned int)eee->transop[N2N_TRANSOP_TF_IDX].tx_cnt,
                         (unsigned int)eee->transop[N2N_TRANSOP_TF_IDX].rx_cnt,
                         (unsigned int)eee->transop[N2N_TRANSOP_AESCBC_IDX].tx_cnt,
                         (unsigned int)eee->transop[N2N_TRANSOP_AESCBC_IDX].rx_cnt );

    msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                         "peers  pend:%u full:%u\n",
                         (unsigned int)peer_list_size( eee->pending_peers ), 
			 (unsigned int)peer_list_size( eee->known_peers ) );

    msg_len += snprintf( (char *)(udp_buf+msg_len), (N2N_PKT_BUF_SIZE-msg_len),
                         "last   super:%lu(%ld sec ago) p2p:%lu(%ld sec ago)\n",
                         eee->last_sup, (now-eee->last_sup), eee->last_p2p, (now-eee->last_p2p) );

    traceEvent(TRACE_DEBUG, "mgmt status sending: %s", udp_buf );


    sendlen = sendto( eee->udp_mgmt_sock, udp_buf, msg_len, 0/*flags*/,
                      (struct sockaddr *)&sender_sock, sizeof(struct sockaddr_in) );

}


/** Read a datagram from the main UDP socket to the internet. */
#ifndef BUILD_FRONTEND
static
#endif
void readFromIPSocket( n2n_edge_t * eee )
{
    n2n_common_t        cmn; /* common fields in the packet header */

    n2n_sock_str_t      sockbuf1;
    n2n_sock_str_t      sockbuf2; /* don't clobber sockbuf1 if writing two addresses to trace */
    macstr_t            mac_buf1;
    macstr_t            mac_buf2;

    uint8_t             udp_buf[N2N_PKT_BUF_SIZE];      /* Compete UDP packet */
    ssize_t             recvlen;
    size_t              rem;
    size_t              idx;
    size_t              msg_type;
    uint8_t             from_supernode;
    struct sockaddr_in  sender_sock;
    n2n_sock_t          sender;
    n2n_sock_t *        orig_sender=NULL;
    time_t              now=0;

    size_t              i;

    i = sizeof(sender_sock);
    recvlen=recvfrom(eee->udp_sock, udp_buf, N2N_PKT_BUF_SIZE, 0/*flags*/,
                     (struct sockaddr *)&sender_sock, (socklen_t*)&i);

    if ( recvlen < 0 )
    {
        traceEvent(TRACE_ERROR, "recvfrom failed with %s", strerror(errno) );

        return; /* failed to receive data from UDP */
    }

    /* REVISIT: when UDP/IPv6 is supported we will need a flag to indicate which
     * IP transport version the packet arrived on. May need to UDP sockets. */
    sender.family = AF_INET; /* udp_sock was opened PF_INET v4 */
    sender.port = ntohs(sender_sock.sin_port);
    memcpy( &(sender.addr.v4), &(sender_sock.sin_addr.s_addr), IPV4_SIZE );

    /* The packet may not have an orig_sender socket spec. So default to last
     * hop as sender. */
    orig_sender=&sender;

    traceEvent(TRACE_INFO, "### Rx N2N UDP (%d) from %s", 
               (signed int)recvlen, sock_to_cstr(sockbuf1, &sender) );

    /* hexdump( udp_buf, recvlen ); */

    rem = recvlen; /* Counts down bytes of packet to protect against buffer overruns. */
    idx = 0; /* marches through packet header as parts are decoded. */
    if ( decode_common(&cmn, udp_buf, &rem, &idx) < 0 )
    {
        traceEvent( TRACE_ERROR, "Failed to decode common section in N2N_UDP" );
        return; /* failed to decode packet */
    }

    now = time(NULL);

    msg_type = cmn.pc; /* packet code */
    from_supernode= cmn.flags & N2N_FLAGS_FROM_SUPERNODE;

    if( 0 == memcmp(cmn.community, eee->community_name, N2N_COMMUNITY_SIZE) )
    {
        if( msg_type == MSG_TYPE_PACKET)
        {
            /* process PACKET - most frequent so first in list. */
            n2n_PACKET_t pkt;

            decode_PACKET( &pkt, &cmn, udp_buf, &rem, &idx );

            if ( pkt.sock.family )
            {
                orig_sender = &(pkt.sock);
            }

            traceEvent(TRACE_INFO, "Rx PACKET from %s (%s)",
                       sock_to_cstr(sockbuf1, &sender),
                       sock_to_cstr(sockbuf2, orig_sender) );

            handle_PACKET( eee, &cmn, &pkt, orig_sender, udp_buf+idx, recvlen-idx );
        }
        else if(msg_type == MSG_TYPE_REGISTER)
        {
            /* Another edge is registering with us */
            n2n_REGISTER_t reg;

            decode_REGISTER( &reg, &cmn, udp_buf, &rem, &idx );

            if ( reg.sock.family )
            {
                orig_sender = &(reg.sock);
            }

            traceEvent(TRACE_INFO, "Rx REGISTER src=%s dst=%s from peer %s (%s)",
                       macaddr_str( mac_buf1, reg.srcMac ),
                       macaddr_str( mac_buf2, reg.dstMac ),
                       sock_to_cstr(sockbuf1, &sender),
                       sock_to_cstr(sockbuf2, orig_sender) );

            if ( 0 == memcmp(reg.dstMac, (eee->device.mac_addr), 6) )
            {
                check_peer( eee, from_supernode, reg.srcMac, orig_sender );
            }

            send_register_ack(eee, orig_sender, &reg);
        }
        else if(msg_type == MSG_TYPE_REGISTER_ACK)
        {
            /* Peer edge is acknowledging our register request */
            n2n_REGISTER_ACK_t ra;

            decode_REGISTER_ACK( &ra, &cmn, udp_buf, &rem, &idx );

            if ( ra.sock.family )
            {
                orig_sender = &(ra.sock);
            }

            traceEvent(TRACE_INFO, "Rx REGISTER_ACK src=%s dst=%s from peer %s (%s)",
                       macaddr_str( mac_buf1, ra.srcMac ),
                       macaddr_str( mac_buf2, ra.dstMac ),
                       sock_to_cstr(sockbuf1, &sender),
                       sock_to_cstr(sockbuf2, orig_sender) );

            /* Move from pending_peers to known_peers; ignore if not in pending. */
            set_peer_operational( eee, ra.srcMac, &sender );
        }
        else if(msg_type == MSG_TYPE_REGISTER_SUPER_ACK)
        {
            n2n_REGISTER_SUPER_ACK_t ra;

            if ( eee->sn_wait )
            {
                decode_REGISTER_SUPER_ACK( &ra, &cmn, udp_buf, &rem, &idx );

                if ( ra.sock.family )
                {
                    orig_sender = &(ra.sock);
                }

                traceEvent(TRACE_NORMAL, "Rx REGISTER_SUPER_ACK myMAC=%s [%s] (external %s). Attempts %u",
                           macaddr_str( mac_buf1, ra.edgeMac ),
                           sock_to_cstr(sockbuf1, &sender),
                           sock_to_cstr(sockbuf2, orig_sender), 
                           (unsigned int)eee->sup_attempts );

                if ( 0 == memcmp( ra.cookie, eee->last_cookie, N2N_COOKIE_SIZE ) )
                {
                    if ( ra.num_sn > 0 )
                    {
                        traceEvent(TRACE_NORMAL, "Rx REGISTER_SUPER_ACK backup supernode at %s",
                                   sock_to_cstr(sockbuf1, &(ra.sn_bak) ) );
                    }

                    eee->last_sup = now;
                    eee->sn_wait=0;
                    eee->sup_attempts = N2N_EDGE_SUP_ATTEMPTS; /* refresh because we got a response */

                    /* REVISIT: store sn_back */
                    eee->register_lifetime = ra.lifetime;
                    eee->register_lifetime = MAX( eee->register_lifetime, REGISTER_SUPER_INTERVAL_MIN );
                    eee->register_lifetime = MIN( eee->register_lifetime, REGISTER_SUPER_INTERVAL_MAX );
                }
                else
                {
                    traceEvent( TRACE_WARNING, "Rx REGISTER_SUPER_ACK with wrong or old cookie." );
                }
            }
            else
            {
                traceEvent( TRACE_WARNING, "Rx REGISTER_SUPER_ACK with no outstanding REGISTER_SUPER." );
            }
        }
        else
        {
            /* Not a known message type */
            traceEvent(TRACE_WARNING, "Unable to handle packet type %d: ignored", (signed int)msg_type);
            return;
        }
    } /* if (community match) */
    else
    {
        traceEvent(TRACE_WARNING, "Received packet with invalid community");
    }

}

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


#ifdef WIN32
static DWORD tunReadThread(LPVOID lpArg )
{
    n2n_edge_t *eee = (n2n_edge_t*)lpArg;

    while(1)
    {
        readFromTAPSocket(eee);
    }

    return((DWORD)NULL);
}


/** Start a second thread in Windows because TUNTAP interfaces do not expose
 *  file descriptors. */
static void startTunReadThread(n2n_edge_t *eee)
{
    HANDLE hThread;
    DWORD dwThreadId;

    hThread = CreateThread(NULL,         /* security attributes */
                           0,            /* use default stack size */
                           (LPTHREAD_START_ROUTINE)tunReadThread, /* thread function */
                           (void*)eee,   /* argument to thread function */
                           0,            /* thread creation flags */
                           &dwThreadId); /* thread id out */
}
#endif

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

/** Resolve the supernode IP address.
 *
 *  REVISIT: This is a really bad idea. The edge will block completely while the
 *           hostname resolution is performed. This could take 15 seconds.
 */
#ifndef BUILD_FRONTEND
static
#endif
void supernode2addr(n2n_sock_t * sn, const n2n_sn_name_t addrIn)
{
    n2n_sn_name_t addr;
	const char *supernode_host;

    memcpy( addr, addrIn, N2N_EDGE_SN_HOST_SIZE );

    supernode_host = strtok(addr, ":");

    if(supernode_host)
    {
        in_addr_t sn_addr;
        char *supernode_port = strtok(NULL, ":");
        const struct addrinfo aihints = {0, PF_INET, 0, 0, 0, NULL, NULL, NULL};
        struct addrinfo * ainfo = NULL;
        int nameerr;

        if ( supernode_port )
            sn->port = atoi(supernode_port);
        else
            traceEvent(TRACE_WARNING, "Bad supernode parameter (-l <host:port>) %s %s:%s",
                       addr, supernode_host, supernode_port);

        nameerr = getaddrinfo( supernode_host, NULL, &aihints, &ainfo );

        if( 0 == nameerr )
        {
            struct sockaddr_in * saddr;

            /* ainfo s the head of a linked list if non-NULL. */
            if ( ainfo && (PF_INET == ainfo->ai_family) )
            {
                /* It is definitely and IPv4 address -> sockaddr_in */
                saddr = (struct sockaddr_in *)ainfo->ai_addr;

                memcpy( sn->addr.v4, &(saddr->sin_addr.s_addr), IPV4_SIZE );
                sn->family=AF_INET;
            }
            else
            {
                /* Should only return IPv4 addresses due to aihints. */
                traceEvent(TRACE_WARNING, "Failed to resolve supernode IPv4 address for %s", supernode_host);
            }

            freeaddrinfo(ainfo); /* free everything allocated by getaddrinfo(). */
            ainfo = NULL;
        } else {
            traceEvent(TRACE_WARNING, "Failed to resolve supernode host %s, assuming numeric", supernode_host);
            sn_addr = inet_addr(supernode_host); /* uint32_t */
            memcpy( sn->addr.v4, &(sn_addr), IPV4_SIZE );
            sn->family=AF_INET;
        }

    } else
        traceEvent(TRACE_WARNING, "Wrong supernode parameter (-l <host:port>)");
}

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


/** Find the address and IP mode for the tuntap device.
 *
 *  s is one of these forms:
 *
 *  <host> := <hostname> | A.B.C.D
 *
 *  <host> | static:<host> | dhcp:<host>
 *
 *  If the mode is present (colon required) then fill ip_mode with that value
 *  otherwise do not change ip_mode. Fill ip_mode with everything after the
 *  colon if it is present; or s if colon is not present.
 *
 *  ip_add and ip_mode are NULL terminated if modified.
 *
 *  return 0 on success and -1 on error
 */
#ifndef BUILD_FRONTEND
static
#endif
int scan_address( char * ip_addr, size_t addr_size,
                         char * ip_mode, size_t mode_size,
                         const char * s )
{
    int retval = -1;
    char * p;

    if ( ( NULL == s ) || ( NULL == ip_addr) )
    {
        return -1;
    }

    memset(ip_addr, 0, addr_size);

    p = strpbrk(s, ":");

    if ( p )
    {
        /* colon is present */
        if ( ip_mode )
        {
            size_t end=0;

            memset(ip_mode, 0, mode_size);
            end = MIN( p-s, (ssize_t)(mode_size-1) ); /* ensure NULL term */
            strncpy( ip_mode, s, end );
            strncpy( ip_addr, p+1, addr_size-1 ); /* ensure NULL term */
            retval = 0;
        }
    }
    else
    {
        /* colon is not present */
        strncpy( ip_addr, s, addr_size );
    }

    return retval;
}

static int run_loop(n2n_edge_t * eee );

/** Entry point to program from kernel. */
#ifndef BUILD_FRONTEND
int main(int argc, char* argv[])
{
    int     opt;
    int     local_port = 0 /* any port */;
    int     mgmt_port = N2N_EDGE_MGMT_PORT; /* 5644 by default */
    char    tuntap_dev_name[N2N_IFNAMSIZ] = "edge0";
    char    ip_mode[N2N_IF_MODE_SIZE]="static";
    char    ip_addr[N2N_NETMASK_STR_SIZE] = "";
    char    netmask[N2N_NETMASK_STR_SIZE]="255.255.255.0";
    int     mtu = DEFAULT_MTU;
    int     got_s = 0;

#ifndef WIN32
    uid_t   userid=0; /* root is the only guaranteed ID */
    gid_t   groupid=0; /* root is the only guaranteed ID */
#endif

    char    device_mac[N2N_MACNAMSIZ]="";
    char *  encrypt_key=NULL;

    int     i, effectiveargc=0;
    char ** effectiveargv=NULL;
    char  * linebuffer = NULL;

    n2n_edge_t eee; /* single instance for this program */

    if (-1 == edge_init(&eee) )
    {
        traceEvent( TRACE_ERROR, "Failed in edge_init" );
        exit(1);
    }

    if( getenv( "N2N_KEY" ))
    {
        encrypt_key = strdup( getenv( "N2N_KEY" ));
    }

#ifdef WIN32
    tuntap_dev_name[0] = '\0';
#endif
    memset(&(eee.supernode), 0, sizeof(eee.supernode));
    eee.supernode.family = AF_INET;

    linebuffer = (char *)malloc(MAX_CMDLINE_BUFFER_LENGTH);
    if (!linebuffer)
    {
        traceEvent( TRACE_ERROR, "Unable to allocate memory");
        exit(1);
    }
    snprintf(linebuffer, MAX_CMDLINE_BUFFER_LENGTH, "%s",argv[0]);

#ifdef WIN32
    for(i=0; i < (int)strlen(linebuffer); i++)
        if(linebuffer[i] == '\\') linebuffer[i] = '/';
#endif

    for(i=1;i<argc;++i)
    {
        if(argv[i][0] == '@')
        {
            if (readConfFile(&argv[i][1], linebuffer)<0) exit(1); /* <<<<----- check */
        }
        else if ((strlen(linebuffer)+strlen(argv[i])+2) < MAX_CMDLINE_BUFFER_LENGTH)
        {
            strncat(linebuffer, " ", 1);
            strncat(linebuffer, argv[i], strlen(argv[i]));
        }
        else
        {
            traceEvent( TRACE_ERROR, "too many argument");
            exit(1);
        }
    }
    /*  strip trailing spaces */
    while(strlen(linebuffer) && linebuffer[strlen(linebuffer)-1]==' ')
        linebuffer[strlen(linebuffer)-1]= '\0';

    /* build the new argv from the linebuffer */
    effectiveargv = buildargv(&effectiveargc, linebuffer);

    if (linebuffer)
    {
        free(linebuffer);
        linebuffer = NULL;
    }

    /* {int k;for(k=0;k<effectiveargc;++k)  printf("%s\n",effectiveargv[k]);} */

    optarg = NULL;
    while((opt = getopt_long(effectiveargc,
                             effectiveargv,
                             "K:k:a:bc:Eu:g:m:M:s:d:l:p:fvhrt", long_options, NULL)) != EOF)
    {
        switch (opt)
        {
        case'K':
        {
            if ( encrypt_key )
            {
                fprintf(stderr, "Error: -K and -k options are mutually exclusive.\n");
                exit(1);
            }
            else
            {
                strncpy( eee.keyschedule, optarg, N2N_PATHNAME_MAXLEN-1 );
                eee.keyschedule[N2N_PATHNAME_MAXLEN-1]=0; /* strncpy does not add NULL if the source has no NULL. */
                traceEvent(TRACE_DEBUG, "keyfile = '%s'\n", eee.keyschedule);
                fprintf(stderr, "keyfile = '%s'\n", eee.keyschedule);
            }
            break;
        }
        case 'a': /* IP address and mode of TUNTAP interface */
        {
            scan_address(ip_addr, N2N_NETMASK_STR_SIZE,
                         ip_mode, N2N_IF_MODE_SIZE,
                         optarg );
            break;
        }
        case 'c': /* community as a string */
        {
            memset( eee.community_name, 0, N2N_COMMUNITY_SIZE );
            strncpy( (char *)eee.community_name, optarg, N2N_COMMUNITY_SIZE);
            break;
        }
        case 'E': /* multicast ethernet addresses accepted. */
        {
            eee.drop_multicast=0;
            traceEvent(TRACE_DEBUG, "Enabling ethernet multicast traffic\n");
            break;
        }

#ifndef WIN32
        case 'u': /* unprivileged uid */
        {
            userid = atoi(optarg);
            break;
        }
        case 'g': /* unprivileged uid */
        {
            groupid = atoi(optarg);
            break;
        }
#endif
#ifdef N2N_HAVE_DAEMON
        case 'f' : /* do not fork as daemon */
        {
            eee.daemon=0;
            break;
        }
#endif /* #ifdef N2N_HAVE_DAEMON */

        case 'm' : /* TUNTAP MAC address */
        {
            strncpy(device_mac,optarg,N2N_MACNAMSIZ);
            break;
        }

        case 'M' : /* TUNTAP MTU */
        {
            mtu = atoi(optarg);
            break;
        }

        case 'k': /* encrypt key */
        {
            if (strlen(eee.keyschedule) > 0 )
            {
                fprintf(stderr, "Error: -K and -k options are mutually exclusive.\n");
                exit(1);
            } else {
                traceEvent(TRACE_DEBUG, "encrypt_key = '%s'\n", encrypt_key);
                encrypt_key = strdup(optarg);
            }
            break;
        }
        case 'r': /* enable packet routing across n2n endpoints */
        {
            eee.allow_routing = 1;
            break;
        }

        case 'l': /* supernode-list */
        {
            if ( eee.sn_num < N2N_EDGE_NUM_SUPERNODES )
            {
                strncpy( (eee.sn_ip_array[eee.sn_num]), optarg, N2N_EDGE_SN_HOST_SIZE);
                traceEvent(TRACE_DEBUG, "Adding supernode[%u] = %s\n", (unsigned int)eee.sn_num, (eee.sn_ip_array[eee.sn_num]) );
                ++eee.sn_num;
            }
            else
            {
                fprintf(stderr, "Too many supernodes!\n" );
                exit(1);
            }
            break;
        }

#if defined(N2N_CAN_NAME_IFACE)
        case 'd': /* TUNTAP name */
        {
            strncpy(tuntap_dev_name, optarg, N2N_IFNAMSIZ);
            break;
        }
#endif

        case 'b':
        {
            eee.re_resolve_supernode_ip = 1;
            break;
        }

        case 'p':
        {
            local_port = atoi(optarg);
            break;
        }
        
        case 't':
        {
            mgmt_port = atoi(optarg);
            break;
        }

        case 's': /* Subnet Mask */
        {
            if (0 != got_s)
            {
                traceEvent(TRACE_WARNING, "Multiple subnet masks supplied.");
            }
            strncpy(netmask, optarg, N2N_NETMASK_STR_SIZE);
            got_s = 1;
            break;
        }

        case 'h': /* help */
        {
            help();
            break;
        }

        case 'v': /* verbose */
        {
            ++traceLevel; /* do 2 -v flags to increase verbosity to DEBUG level*/
            break;
        }

        } /* end switch */
    }


#ifdef N2N_HAVE_DAEMON
    if ( eee.daemon )
    {
        useSyslog=1; /* traceEvent output now goes to syslog. */
        if ( -1 == daemon( 0, 0 ) )
        {
            traceEvent( TRACE_ERROR, "Failed to become daemon." );
            exit(-5);
        }
    }
#endif /* #ifdef N2N_HAVE_DAEMON */


    traceEvent( TRACE_NORMAL, "Starting n2n edge %s %s", n2n_sw_version, n2n_sw_buildDate );


    for (i=0; i< N2N_EDGE_NUM_SUPERNODES; ++i )
    {
        traceEvent( TRACE_NORMAL, "supernode %u => %s\n", i, (eee.sn_ip_array[i]) );
    }

    supernode2addr( &(eee.supernode), eee.sn_ip_array[eee.sn_idx] );


    for ( i=0; i<effectiveargc; ++i )
    {
        free( effectiveargv[i] );
    }
    free( effectiveargv );
    effectiveargv = 0;
    effectiveargc = 0;

    if(!(
#ifdef __linux__
           (tuntap_dev_name[0] != 0) &&
#endif
           (eee.community_name[0] != 0) &&
           (ip_addr[0] != 0)
           ) )
    {
        help();
    }

    if ( (NULL == encrypt_key ) && ( 0 == strlen(eee.keyschedule)) )
    {
        traceEvent(TRACE_WARNING, "Encryption is disabled in edge.");
        
        eee.null_transop = 1;
    }


#ifndef WIN32
    /* If running suid root then we need to setuid before using the force. */
    setuid( 0 );
    /* setgid( 0 ); */
#endif

    if ( 0 == strcmp( "dhcp", ip_mode ) )
    {
        traceEvent(TRACE_NORMAL, "Dynamic IP address assignment enabled.");

        eee.dyn_ip_mode = 1;
    }
    else
    {
        traceEvent(TRACE_NORMAL, "ip_mode='%s'", ip_mode);        
    }

    if(tuntap_open(&(eee.device), tuntap_dev_name, ip_mode, ip_addr, netmask, device_mac, mtu) < 0)
        return(-1);

#ifndef WIN32
    if ( (userid != 0) || (groupid != 0 ) ) {
        traceEvent(TRACE_NORMAL, "Interface up. Dropping privileges to uid=%d, gid=%d", 
                   (signed int)userid, (signed int)groupid);

        /* Finished with the need for root privileges. Drop to unprivileged user. */
        setreuid( userid, userid );
        setregid( groupid, groupid );
    }
#endif

    if(local_port > 0)
        traceEvent(TRACE_NORMAL, "Binding to local port %d", (signed int)local_port);

    if ( encrypt_key ) {
        if(edge_init_twofish( &eee, (uint8_t *)(encrypt_key), strlen(encrypt_key) ) < 0) {
            fprintf(stderr, "Error: twofish setup failed.\n" );
            return(-1);
        }
    } else if ( strlen(eee.keyschedule) > 0 ) {
        if (edge_init_keyschedule( &eee ) != 0 ) {
            fprintf(stderr, "Error: keyschedule setup failed.\n" );
            return(-1);
        }

    }
    /* else run in NULL mode */


    eee.udp_sock = open_socket(local_port, 1 /*bind ANY*/ );
    if(eee.udp_sock < 0)
    {
        traceEvent( TRACE_ERROR, "Failed to bind main UDP port %u", (signed int)local_port );
        return(-1);
    }

    eee.udp_mgmt_sock = open_socket(mgmt_port, 0 /* bind LOOPBACK*/ );

    if(eee.udp_mgmt_sock < 0)
    {
        traceEvent( TRACE_ERROR, "Failed to bind management UDP port %u", (unsigned int)N2N_EDGE_MGMT_PORT );
        return(-1);
    }


    traceEvent(TRACE_NORMAL, "edge started");

    update_supernode_reg(&eee, time(NULL) );

    return run_loop(&eee);
}

static int run_loop(n2n_edge_t * eee )
{
    int   keep_running=1;
    size_t numPurged;
    time_t lastIfaceCheck=0;
    time_t lastTransop=0;


#ifdef WIN32
    startTunReadThread(eee);
#endif

    /* Main loop
     *
     * select() is used to wait for input on either the TAP fd or the UDP/TCP
     * socket. When input is present the data is read and processed by either
     * readFromIPSocket() or readFromTAPSocket()
     */

    while(keep_running)
    {
        int rc, max_sock = 0;
        fd_set socket_mask;
        struct timeval wait_time;
        time_t nowTime;

        FD_ZERO(&socket_mask);
        FD_SET(eee->udp_sock, &socket_mask);
        FD_SET(eee->udp_mgmt_sock, &socket_mask);
        max_sock = max( eee->udp_sock, eee->udp_mgmt_sock );
#ifndef WIN32
        FD_SET(eee->device.fd, &socket_mask);
        max_sock = max( max_sock, eee->device.fd );
#endif

        wait_time.tv_sec = SOCKET_TIMEOUT_INTERVAL_SECS; wait_time.tv_usec = 0;

        rc = select(max_sock+1, &socket_mask, NULL, NULL, &wait_time);
        nowTime=time(NULL);

        /* Make sure ciphers are updated before the packet is treated. */
        if ( ( nowTime - lastTransop ) > TRANSOP_TICK_INTERVAL )
        {
            lastTransop = nowTime;

            n2n_tick_transop( eee, nowTime );
        }

        if(rc > 0)
        {
            /* Any or all of the FDs could have input; check them all. */

            if(FD_ISSET(eee->udp_sock, &socket_mask))
            {
                /* Read a cooked socket from the internet socket. Writes on the TAP
                 * socket. */
                readFromIPSocket(eee);
            }

            if(FD_ISSET(eee->udp_mgmt_sock, &socket_mask))
            {
                /* Read a cooked socket from the internet socket. Writes on the TAP
                 * socket. */
                readFromMgmtSocket(eee, &keep_running);
            }

#ifndef WIN32
            if(FD_ISSET(eee->device.fd, &socket_mask))
            {
                /* Read an ethernet frame from the TAP socket. Write on the IP
                 * socket. */
                readFromTAPSocket(eee);
            }
#endif
        }

        /* Finished processing select data. */


        update_supernode_reg(eee, nowTime);

        numPurged =  purge_expired_registrations( &(eee->known_peers) );
        numPurged += purge_expired_registrations( &(eee->pending_peers) );
        if ( numPurged > 0 )
        {
            traceEvent( TRACE_NORMAL, "Peer removed: pending=%u, operational=%u",
                        (unsigned int)peer_list_size( eee->pending_peers ), 
                        (unsigned int)peer_list_size( eee->known_peers ) );
        }

        if ( eee->dyn_ip_mode && 
             (( nowTime - lastIfaceCheck ) > IFACE_UPDATE_INTERVAL ) )
        {
            traceEvent(TRACE_NORMAL, "Re-checking dynamic IP address.");
            tuntap_get_address( &(eee->device) );
            lastIfaceCheck = nowTime;
        }

    } /* while */

    send_deregister( eee, &(eee->supernode));

    closesocket(eee->udp_sock);
    tuntap_close(&(eee->device));

    edge_deinit( eee );

    return(0);
}

#endif