1 // This program is a UDP based tunneling of stdin/out Ethernet packets.
3 // A rrqnet program is a bi-directional networking plug that channels
4 // packets between a UDP port and stdin/out. It is configured on the
5 // command line with channel rules that declares which remotes it may
6 // communicate with. Allowed remotes are specified in the format
7 // "ip[/n][:port][=key]", to indicate which subnet and port to accept,
8 // and nominating the associated keyfile to use for channel
11 // The program maintains a table of actualized connections, as an
12 // association between MAC addresses and IP:port addresses. This table
13 // is used for resolving destination for outgoing packets, including
14 // the forwarding of broadcasts.
20 #include <linux/if_tun.h>
25 #include <sys/ioctl.h>
28 #include <sys/types.h>
37 // "Private Shared Key" details.
40 unsigned int seed; // Encryption seed
41 unsigned char *key; // Encryption key
42 unsigned int key_length; // Encryption key length
45 // Compacted IP address ipv4/ipv6
47 int width; // 4=ipv4 and 16=ipv6
49 unsigned char bytes[16];
55 // Details of channel rules.
57 char *source; // Orginal rule
59 unsigned int bits; // Bits of IP prefix
60 unsigned short port; // Port (0=any)
61 struct PSK psk; // Associated key
62 htable ignored_mac; // MAC to ignore by this spec
65 // Details of actualized connections.
67 struct SockAddr uaddr;
68 struct Allowed *spec; // Rule being instantiated
69 struct timeval rec_when; // Last received packet time, in seconds
72 // Details of an interface at a remote.
74 unsigned char mac[6]; // MAC address used last (key for by_mac table)
75 struct timeval rec_when; // Last packet time, in seconds
76 struct Remote *remote;
79 // Maximal packet size .. allow for jumbo frames (9000)
82 typedef struct _PacketItem {
87 unsigned char buffer[ BUFSIZE ];
90 typedef struct _ReaderData {
94 // heartbeat interval, in seconds
96 #define HEARTBEAT_MICROS ( HEARTBEAT * 1000000 )
98 // Macros for timing, for struct timeval variables
99 #define TIME_MICROS(TM) (((int64_t) (TM)->tv_sec * 1000000) + (TM)->tv_usec )
100 #define DIFF_MICROS(TM1,TM2) ( TIME_MICROS(TM1) - TIME_MICROS(TM2) )
102 // RECENT_MICROS(T,M) is the time logic for requiring a gap time (in
103 // milliseconds) before shifting a MAC to a new remote. The limit is
104 // 6s for broadcast and 20s for unicast.
105 #define RECENT_MICROS(T,M) ((M) < ((T)? 6000000 : 20000000 ))
107 // VERYOLD_MICROSS is used for discarding downlink remotes whose latest
108 // activity is older than this.
109 #define VERYOLD_MICROS 180000000
113 // Allowed remote specs are held in a table sorted by IP prefix.
115 struct Allowed **table;
119 // Actual remotes are kept in a hash table keyed by their +uaddr+
120 // field, and another hash table keps Interface records for all MAC
121 // addresses sourced from some remote, keyed by their +mac+ field. The
122 // latter is used both for resolving destinations for outgoing
123 // packets, and for limiting broadcast cycles. The former table is
124 // used for limiting incoming packets to allowed sources, and then
125 // decrypt the payload accordingly.
126 static int hashcode_uaddr(struct _htable *table,unsigned char *key);
127 static int hashcode_mac(struct _htable *table,unsigned char *key);
129 htable by_mac; // struct Interface hash table
130 htable by_addr; // struct Remote hash table
132 .by_mac = HTABLEINIT( struct Interface, mac, hashcode_mac ),
133 .by_addr = HTABLEINIT( struct Remote, uaddr, hashcode_uaddr )
136 #define Interface_LOCK if ( pthread_mutex_lock( &remotes.by_mac.lock ) ) { \
137 perror( "FATAL" ); exit( 1 ); }
139 #define Interface_UNLOCK if (pthread_mutex_unlock( &remotes.by_mac.lock ) ) { \
140 perror( "FATAL" ); exit( 1 ); }
142 #define Interface_FIND(m,r) \
143 htfind( &remotes.by_mac, m, (unsigned char **)&r )
145 #define Interface_ADD(r) \
146 htadd( &remotes.by_mac, (unsigned char *)r )
148 #define Interface_DEL(r) \
149 htdelete( &remotes.by_mac, (unsigned char *) r )
151 #define Remote_LOCK if ( pthread_mutex_lock( &remotes.by_addr.lock ) ) { \
152 perror( "FATAL" ); exit( 1 ); }
154 #define Remote_UNLOCK if ( pthread_mutex_unlock( &remotes.by_addr.lock ) ) { \
155 perror( "FATAL" ); exit( 1 ); }
157 #define Remote_FIND(a,r) \
158 htfind( &remotes.by_addr, (unsigned char *)a, (unsigned char **) &r )
160 #define Remote_ADD(r) \
161 htadd( &remotes.by_addr, (unsigned char *) r )
163 #define Remote_DEL(r) \
164 htdelete( &remotes.by_addr, (unsigned char *) r )
166 #define Ignored_FIND(a,m,x) \
167 htfind( &a->ignored_mac, m, (unsigned char **)&x )
169 #define Ignored_ADD(a,x) \
170 htadd( &a->ignored_mac, (unsigned char *)x )
173 static int stdio = 0; // Default is neither stdio nor tap
174 static char *tap = 0; // Name of tap, if any, or "-" for stdio
175 static int tap_fd = 0; // Also used for stdin in stdio mode
177 static int threads_count = 0;
178 static int buffers_count = 0;
180 // Setup for multicast channel
182 struct ip_mreqn group;
183 struct SockAddr sock;
188 // Flag to signal the UDP socket as being ipv6 or not (forced ipv4)
191 // Flag to indicate tpg transport patch = avoid UDP payload of 1470
192 // bytes by adding 2 tag-along bytes
193 static int tpg_quirk = 0;
195 // Flag whether to make some stderr outputs or not.
196 // 1 = normal verbosity, 2 = more output, 3 = source debug level stuff
199 // Note: allows a thread to lock/unlock recursively
200 static pthread_mutex_t crypting = PTHREAD_MUTEX_INITIALIZER;
202 // Note: allows a thread to lock/unlock recursively
203 static pthread_mutex_t printing = PTHREAD_RECURSIVE_MUTEX_INITIALIZER_NP;
206 if ( pthread_mutex_lock( &printing ) ) { perror( "FATAL" ); exit(1); }
208 #define PRINTUNLOCK \
209 if ( pthread_mutex_unlock( &printing ) ) { perror( "FATAL" ); exit(1); }
211 #define PRINT( X ) { PRINTLOCK; X; PRINTUNLOCK; }
213 #define VERBOSEOUT(fmt, ...) \
214 if ( verbose >= 1 ) PRINT( fprintf( stderr, fmt, ##__VA_ARGS__ ) )
216 #define VERBOSE2OUT(fmt, ...) \
217 if ( verbose >= 2 ) PRINT( fprintf( stderr, fmt, ##__VA_ARGS__ ) )
219 #define VERBOSE3OUT(fmt, ...) \
220 if ( verbose >= 3 ) PRINT( fprintf( stderr, fmt, ##__VA_ARGS__ ) )
222 // The actual name of this program (argv[0])
223 static unsigned char *progname;
225 // Compute a hashcode for the given SockAddr key
226 static int hashcode_uaddr(
227 __attribute__((unused)) struct _htable *table,unsigned char *key)
229 struct SockAddr *s = (struct SockAddr *) key;
230 key = (unsigned char*) &s->in;
231 unsigned char *e = key + ( ( s->in.sa_family == AF_INET )?
232 sizeof( struct sockaddr_in ) :
233 sizeof( struct sockaddr_in6 ) );
241 // Compute a hashcode for the given MAC addr key
242 static int hashcode_mac(struct _htable *table,unsigned char *key) {
245 if ( table->size == 256 ) {
246 for ( ; i < 6; i++ ) {
251 uint16_t *p = (uint16_t *) key;
252 for ( ; i < 3; i++ ) {
258 // Make a text representation of bytes as ipv4 or ipv6
259 static char *inet_nmtoa(unsigned char *b,int w) {
260 static char buffer[20000];
264 sprintf( p,"%d.%d.%d.%d", b[0], b[1], b[2], b[3] );
265 } else if ( w == 16 ){
267 "%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x",
268 b[0], b[1], b[2], b[3],
269 b[4], b[5], b[6], b[7],
270 b[8], b[9], b[10], b[11],
271 b[12], b[13], b[14], b[15] );
273 VERBOSE3OUT( "HEX data of %d bytes\n", w );
274 for ( ; i < w && i < 19000; i++, p += 3 ) {
275 sprintf( p, "%02x:", b[i] );
284 // Form a MAC address string from 6 MAC address bytes, into one of the
285 // 4 static buffer, whose use are cycled.
286 static char *inet_mtoa(unsigned char *mac) {
287 static char buffer[4][30];
292 sprintf( buffer[i], "%02x:%02x:%02x:%02x:%02x:%02x",
293 mac[0], mac[1], mac[2], mac[3], mac[4], mac[5] );
297 // Form a socket address string from Sockaddr, into one of the
298 // 4 static buffer, whose use are cycled.
299 static char *inet_stoa(struct SockAddr *a) {
300 static char buffer[1000];
301 static char out[4][1000];
306 if ( a->in.sa_family == AF_INET ) {
307 sprintf( out[i], "%s:%d",
308 inet_ntop( AF_INET, &a->in4.sin_addr, buffer, 100 ),
309 ntohs( a->in4.sin_port ) );
310 } else if ( a->in.sa_family == AF_INET6 ) {
311 sprintf( out[i], "[%s]:%d",
312 inet_ntop( AF_INET6, &a->in6.sin6_addr, buffer, 100 ),
313 ntohs( a->in6.sin6_port ) );
315 sprintf( out[i], "<tap/stdio>" );
320 // Debugging: string representation of an Allowed record.
321 static char *show_allowed(struct Allowed *a) {
322 static char buffer[20000];
324 sprintf( buffer, "{tap/stdio}" );
326 sprintf( buffer, "%hd (%d) %s %p",
327 a->port, a->bits, inet_nmtoa( a->addr.bytes, a->addr.width ),
333 // Recognize uplink specification
334 static int is_uplink(struct Allowed *a) {
335 return a->bits == (unsigned int) ( a->addr.width * 8 ) && a->port != 0;
338 // Add a new Interface for a Remote. If non-null, the interface is
339 // also added to the interface table.
340 static struct Interface *add_interface(unsigned char *mac,struct Remote *r) {
341 struct Interface *x = calloc( 1, sizeof( struct Interface ) );
342 memcpy( x->mac, mac, sizeof( x->mac ) );
350 // Add a new remote for a given address and spec.
351 static struct Remote *add_remote(struct SockAddr *a,struct Allowed *s) {
352 struct Remote *r = calloc( 1, sizeof( struct Remote ) );
354 memcpy( &r->uaddr, a, sizeof( r->uaddr ) );
357 VERBOSE2OUT( "add_remote %s from spec: %s\n",
358 inet_stoa( &r->uaddr ),
359 ( s == 0 )? ( (a == 0)? "{tap/stdio}" : "{multicast}" )
360 : show_allowed( s ) );
365 // Add a new ignored interface on a channel
366 static int add_ignored(struct Allowed *link,unsigned char *mac) {
367 struct Interface *x = add_interface( mac, 0 );
369 return 1; // error: out of memory
371 Ignored_ADD( link, x );
375 // Parse ignored interfaces
376 // Comma separated list of MAC addresses
377 static int parse_ignored_interfaces(char *arg,struct Allowed *link) {
378 int a, b, c, d, e, f, g;
380 if ( sscanf( arg,"%x:%x:%x:%x:%x:%x%n",&a,&b,&c,&d,&e,&f,&g ) != 6 ) {
384 if ( (a|b|c|d|e|f) & ~0xff ) {
385 return 1; // some %x is not hex
387 unsigned char mac[6] = { a, b, c, d, e, f };
388 if ( add_ignored( link, mac ) ) {
392 VERBOSEOUT( "Ignoring: %s on channel %s\n",
393 inet_mtoa( mac ), link->source );
398 if ( *(arg++) != ',' ) {
399 return 1; // Not comma separated
405 //** IP address parsing utility
406 // Clear bits after <bits>
407 static void clearbitsafter(struct CharAddr *a,unsigned int bits) {
408 unsigned int max = a->width * 8;
410 for ( i = a->width; i < 16; i++ ) {
413 for ( i = a->width - 1; i >= 0; i--, max -= 8 ) {
414 if ( max - 8 < bits ) {
419 if ( i >= 0 && max >= bits ) {
420 a->bytes[ i ] &= ( 0xFF << ( bits - max ) );
424 //** IP address parsing utility
425 // Find the PSK for the given +file+ in the +loaded+ table (of +count+ size)
426 static struct PSK *findLoadedKeyfile(char *file,struct PSK *loaded,int count) {
427 VERBOSE3OUT( "find %s\n", file );
428 for ( count--; count >= 0; count-- ) {
429 if ( strcmp( file, loaded[ count ].keyfile ) ) {
430 VERBOSE3OUT( "found %d\n", count );
431 return &loaded[ count ];
434 VERBOSE3OUT( "found nothing\n" );
438 //** IP address parsing utility
439 // Load a key file into dynamically allocated memory, and update the
440 // given PSK header for it.
441 static void loadkey(struct PSK *psk) {
442 static struct PSK *loaded = 0;
443 static int count = 0;
444 if ( psk->keyfile == 0 ) {
447 struct PSK *old = findLoadedKeyfile( psk->keyfile, loaded, count );
449 memcpy( psk, old, sizeof( struct PSK ) );
455 struct stat filestat;
456 psk->keyfile = strdup( psk->keyfile );
457 int fd = open( (char*) psk->keyfile, O_RDONLY );
460 perror( "open key file" );
463 if ( fstat( fd, &filestat ) ) {
464 perror( "stat of key file" );
467 psk->key_length = filestat.st_size;
468 if ( psk->key_length < 256 ) {
469 fprintf( stderr, "Too small key file: %d %s\n", psk->key_length,
473 psk->key = malloc( psk->key_length );
474 if ( psk->key == 0 ) {
475 fprintf( stderr, "Cannot allocate %d bytes for %s\n",
476 psk->key_length, psk->keyfile );
481 while ( ( n = read( fd, p, e ) ) > 0 ) {
487 fprintf( stderr, "Failed loading key %s\n", psk->keyfile );
490 for ( e = 0; (unsigned) e < psk->key_length; e++ ) {
491 psk->seed += psk->key[ e ];
493 if ( psk->seed == 0 ) {
494 fprintf( stderr, "Bad key %s; adds up to 0\n", psk->keyfile );
499 loaded = realloc( loaded, ( count * sizeof( struct PSK ) ) );
501 loaded = malloc( sizeof( struct PSK ) );
503 memcpy( &loaded[ count-1 ], psk, sizeof( struct PSK ) );
504 VERBOSE3OUT( "%d: %s %d %p %d\n", count-1, psk->keyfile, psk->seed,
505 psk->key, psk->key_length );
508 //** IP address parsing utility
509 // Fill out a CharAddr and *port from a SockAddr
510 static void set_charaddrport(
511 struct CharAddr *ca,unsigned short *port,struct SockAddr *sa)
513 memset( ca, 0, sizeof( struct CharAddr ) );
514 ca->width = ( sa->in.sa_family == AF_INET )? 4 : 16;
515 if ( ca->width == 4 ) {
516 memcpy( &ca->in4, &sa->in4.sin_addr, 4 );
517 *port = ntohs( sa->in4.sin_port );
519 memcpy( &ca->in6, &sa->in6.sin6_addr, 16 );
520 *port = ntohs( sa->in6.sin6_port );
524 //** IP address parsing utility
525 // Fill out a SockAddr from a CharAddr and port
526 static void set_sockaddr(struct SockAddr *sa,struct CharAddr *ca,int port) {
527 memset( sa, 0, sizeof( struct SockAddr ) );
528 if ( ca->width == 4 ) {
529 sa->in4.sin_family = AF_INET;
530 sa->in4.sin_port = htons( port );
531 memcpy( &sa->in4.sin_addr, &ca->in4, 4 );
533 sa->in6.sin6_family = AF_INET6;
534 sa->in6.sin6_port = htons( port );
535 memcpy( &sa->in6.sin6_addr, &ca->in6, 16 );
539 //** IP address parsing utility
540 // Capture an optional port sub phrase [:<port>]
541 static int parse_port(char *port,struct Allowed *into) {
546 if ( sscanf( port, "%d", &p ) != 1 || p < 1 || p > 65535 ) {
555 //** IP address parsing utility
556 // Capture an optional bits sub phrase [/<bits>]
557 static int parse_bits(char *bits,int max,struct Allowed *into) {
562 if ( sscanf( bits, "%d", &b ) != 1 || b < 0 || b > max ) {
570 //** IP address parsing utility
571 // Parse a command line argument as a declaration of an allowed
572 // remote into the given <addr>.
573 // Return 0 if ok and 1 otherwise
574 // Formats: <ipv4-address>[/<bits>][:<port>][=keyfile]
575 // Formats: <ipv6-address>[/<bits>][=keyfile]
576 // Formats: \[<ipv6-address>[/<bits>]\][:<port>][=keyfile]
577 // Formats: hostname:port[=keyfile]
578 static int parse_allowed(char *arg,struct Allowed *into) {
579 static char buffer[10000];
580 int n = strlen( arg );
582 return 1; // excessively large argument
584 strcpy( buffer, arg );
586 char * keyfile = strchr( buffer, '=' );
589 into->psk.keyfile = keyfile;
591 #define B(b) b, b+1, b+2, b+3
592 if ( sscanf( buffer, "%hhu.%hhu.%hhu.%hhu", B(into->addr.bytes) ) == 4 ) {
595 into->addr.width = 4;
596 if ( parse_port( strchr( buffer, ':' ), into ) ) {
597 fprintf( stderr, "bad port\n" );
600 if ( parse_bits( strchr( buffer, '/' ), 32, into ) ) {
601 fprintf( stderr, "bad bits\n" );
607 char * address = buffer;
609 if ( *buffer == '[' ) {
610 // bracketed form, necessary for port
611 char *end = strchr( buffer, ']' );
613 return 1; // bad argument
617 if ( *end == ':' && parse_port( end, into ) ) {
621 into->addr.width = 16;
622 if ( parse_bits( strchr( address, '/' ), 128, into ) ) {
625 if ( inet_pton( AF_INET6, address, into->addr.bytes ) != 1 ) {
626 return 1; // Bad IPv6
631 //** IP address parsing utility
632 // Add a new channel spec into the <allowed> table
633 // spec == 0 for the tap/stdio channel
634 static struct Allowed *add_allowed(char *spec) {
635 struct Allowed *into = calloc( 1, sizeof(struct Allowed) );
636 htable x = HTABLEINIT( struct Interface, mac, hashcode_mac );
637 into->ignored_mac = x;
639 if ( parse_allowed( spec, into ) ) {
640 fprintf( stderr, "Bad remote spec: %s\n", spec );
645 if ( allowed.table == 0 ) {
647 allowed.table = calloc( 1, sizeof(struct Allowed*) );
652 allowed.table = realloc( allowed.table,
653 allowed.count * sizeof(struct Allowed*) );
654 if ( allowed.table == 0 ) {
655 fprintf( stderr, "OUT OF MEMORY\n" );
659 allowed.table[i] = into;
661 loadkey( &into->psk );
662 VERBOSE3OUT( "Allowed %s { %s }\n", into->source, show_allowed( into ) );
663 if ( is_uplink( into ) ) {
664 struct SockAddr addr;
665 set_sockaddr( &addr, &into->addr, into->port );
666 VERBOSEOUT( "Add uplink %s\n", show_allowed( into ) );
667 (void) add_remote( &addr, into );
672 static int parse_threads_count(char *arg) {
673 if ( ( sscanf( arg, "%u", &threads_count ) != 1 ) || threads_count < 1 ) {
676 VERBOSEOUT( "** Threads count = %d\n", threads_count );
680 static int parse_buffers_count(char *arg) {
681 if ( ( sscanf( arg, "%u", &buffers_count ) != 1 ) || buffers_count < 1 ) {
684 VERBOSEOUT( "** Buffers count = %d\n", buffers_count );
688 //** IP address parsing utility for multicast phrase
689 // Return 0 if ok and 1 otherwise
690 // Formats: <ipv4-address>:<port>[=keyfile]
691 // The ipv4 address should be a multicast address in ranges
692 // 224.0.0.0/22, 232.0.0.0/7, 234.0.0.0/8 or 239.0.0.0/8
693 // though it's not checked here.
694 static int parse_mcast(char *arg) {
695 static char buffer[10000];
696 int n = strlen( arg );
698 return 1; // excessively large argument
700 memcpy( buffer, arg, n );
701 char *p = buffer + n - 1;
702 for ( ; p > buffer && *p != ':' && *p != '='; p-- ) { }
704 mcast.psk.keyfile = p+1;
706 loadkey( &mcast.psk );
707 for ( ; p > buffer && *p != ':' ; p-- ) { }
710 fprintf( stderr, "Multicast port is required\n" );
711 return 1; // Port number is required
714 if ( inet_pton( AF_INET, buffer, &mcast.group.imr_multiaddr.s_addr )==0 ) {
715 fprintf( stderr, "Multicast address required\n" );
719 long int port = strtol( p, &e, 10 );
720 if ( *e != 0 || port < 1 || port > 65535 ) {
721 fprintf( stderr, "Bad multicast port\n" );
724 mcast.group.imr_address.s_addr = htonl(INADDR_ANY);
725 mcast.sock.in4.sin_family = AF_INET;
726 mcast.sock.in4.sin_addr.s_addr = htonl(INADDR_ANY);
727 mcast.sock.in4.sin_port = htons( atoi( p ) );
731 // Utility that sets upt the multicast socket, which is used for
732 // receiving multicast packets.
733 static void setup_mcast() {
734 // set up ipv4 socket
735 if ( ( mcast.fd = socket( AF_INET, SOCK_DGRAM, 0 ) ) == 0 ) {
736 perror( "creating socket");
739 if ( setsockopt( mcast.fd, IPPROTO_IP, IP_ADD_MEMBERSHIP,
740 (char *) &mcast.group, sizeof( mcast.group ) ) < 0) {
741 perror( "Joining multicast group" );
745 if ( setsockopt( mcast.fd, SOL_SOCKET, SO_REUSEADDR,
746 &reuse, sizeof( int ) ) < 0 ) {
747 perror( "SO_REUSEADDR" );
750 if ( bind( mcast.fd, (struct sockaddr*) &mcast.sock.in,
751 sizeof( struct sockaddr ) ) ) {
752 fprintf( stderr, "Error binding socket!\n");
755 // Change mcast address to be the group multiaddress, and add
756 // a persistent "remote" for it.
757 mcast.sock.in4.sin_addr.s_addr = mcast.group.imr_multiaddr.s_addr;
758 add_remote( &mcast.sock, 0 );
761 // Find the applicable channel rule for a given ip:port address
762 static struct Allowed *is_allowed_remote(struct SockAddr *addr) {
764 int width = ( addr->in.sa_family == AF_INET )? 4 : 16;
767 for ( ; (unsigned) i < allowed.count; i++ ) {
768 struct Allowed *a = allowed.table[i];
769 if ( a->addr.width != width ) {
772 set_charaddrport( &ca, &port, addr );
773 if ( a->port != 0 && a->port != port ) {
776 clearbitsafter( &ca, a->bits );
777 if ( memcmp( &ca, &a->addr, sizeof( struct CharAddr ) ) == 0 ) {
781 return 0; // Disallowed
784 // Simple PSK encryption:
786 // First, xor each byte with a key byte that is picked from the key
787 // by means of an index that includes the prior encoding. Also,
788 // compute the sum of encrypted bytes into a "magic" that is added the
789 // "seed" for seeding the random number generator. Secondly reorder
790 // the bytes using successive rand number picks from the seeded
793 static void encrypt(unsigned char *buf,unsigned int n,struct PSK *psk) {
798 VERBOSE3OUT( "encrypt by %s %p\n", psk->keyfile, psk->key );
799 for ( k = 0, r = 0, magic = 0; k < n; k++ ) {
800 r = ( r + magic + k ) % psk->key_length;
801 buf[k] ^= psk->key[ r ];
804 pthread_mutex_lock( &crypting );
805 srand( psk->seed + magic );
806 for ( k = 0; k < n; k++ ) {
812 pthread_mutex_unlock( &crypting );
815 // Corresponding decryption procedure .
816 static void decrypt(unsigned char *buf,unsigned int n,struct PSK *psk) {
817 unsigned int randoms[ BUFSIZE ];
821 unsigned int magic = 0;
822 for ( k = 0; k < n; k++ ) {
825 pthread_mutex_lock( &crypting );
826 srand( psk->seed + magic );
827 for ( k = 0; k < n; k++ ) {
828 randoms[k] = rand() % n;
830 pthread_mutex_unlock( &crypting );
831 for ( k = n; k > 0; ) {
837 for ( k = 0, r = 0, magic = 0; k < n; k++ ) {
838 r = ( r + magic + k ) % psk->key_length;
840 buf[k] ^= psk->key[r];
844 // Write a buffer data to given file descriptor (basically tap_fd in
845 // this program). This is never fragmented.
846 static int dowrite(int fd, unsigned char *buf, int n) {
848 if ( ( w = write( fd, buf, n ) ) < 0){
849 perror( "Writing data" );
855 // Write to the tap/stdio; adding length prefix for stdio
856 static int write_tap(unsigned char *buf, int n) {
857 uint8_t tag0 = *( buf + 12 );
859 uint16_t size = ntohs( *(uint16_t*)(buf + 16) );
860 if ( size <= 1500 ) {
861 if ( ( verbose >= 2 ) && ( n != size + 14 ) ) {
862 VERBOSEOUT( "clip %d to %d\n", n, size + 14 );
864 n = size + 14; // Clip of any tail
868 uint16_t plength = htons( n );
869 if ( dowrite( 1, (unsigned char *) &plength,
870 sizeof( plength ) ) < 0 ) {
873 return dowrite( 1, buf, n );
875 return dowrite( tap_fd, buf, n );
878 // Write a packet via the given Interface with encryption as specified.
879 static void write_remote(unsigned char *buf, int n,struct Remote *r) {
881 unsigned char output[ BUFSIZE ];
883 VERBOSE2OUT( "SEND %d bytes to %s\n", n, inet_stoa( &r->uaddr ) );
885 VERBOSE2OUT( "SEND %d bytes %s -> %s to %s\n", n,
886 inet_mtoa( buf+6 ), inet_mtoa( buf ),
887 inet_stoa( &r->uaddr ) );
889 memcpy( output, buf, n ); // Use the private buffer for delivery
890 // Apply the TPG quirk
891 if ( tpg_quirk && ( n > 1460 ) && ( n < 1478 ) ) {
892 VERBOSE2OUT( "tpg quirk applied\n" );
893 n = 1478; // Add some "random" tag-along bytes
895 if ( r->spec == 0 ) {
896 if ( r->uaddr.in.sa_family == 0 ) {
897 // Output to tap/stdio
898 if ( write_tap( buf, n ) < 0 ) {
900 fprintf( stderr, "Cannot write to tap/stdio: exiting!\n" );
905 // Fall through for multicast
906 if ( mcast.psk.keyfile ) {
907 encrypt( output, n, &mcast.psk );
909 } else if ( r->spec->psk.keyfile ) {
910 encrypt( output, n, &r->spec->psk );
912 struct sockaddr *sock = &r->uaddr.in;
914 if ( sock->sa_family == AF_INET6 ) {
915 // Note that the size of +struct sockaddr_in6+ is actually
916 // larger than the size of +struct sockaddr+ (due to the
917 // addition of the +sin6_flowinfo+ field). It results in the
918 // following cuteness for passing arguments to +sendto+.
919 size = sizeof( struct sockaddr_in6 );
920 VERBOSE2OUT( "IPv6 UDP %d %s\n",
921 udp_fd, inet_stoa( (struct SockAddr*) sock ) );
923 size = sizeof( struct sockaddr_in );
924 VERBOSE2OUT( "IPv4 UDP %d %s\n",
925 udp_fd, inet_stoa( (struct SockAddr*) sock ) );
927 VERBOSE2OUT( "SEND %d bytes to %s [%s -> %s]\n",
928 n, inet_stoa( (struct SockAddr*) sock ),
929 ( n < 12 )? "" : inet_mtoa( buf+6 ),
930 ( n < 12 )? "" : inet_mtoa( buf )
932 // IS sendto thread safe??
933 if ( sendto( udp_fd, output, n, 0, sock, size ) < n ) {
934 perror( "Writing socket" );
935 // Invalidate remote temporarily instead? But if it's an
936 // "uplink" it should be retried eventually...
937 // For now: just ignore the error.
942 // Delete a Remote and all its interfaces
943 static void delete_remote(struct Remote *r) {
944 VERBOSE2OUT( "DELETE Remote and all its interfaces %s\n",
945 inet_stoa( &r->uaddr ) );
949 for ( ; i < remotes.by_mac.size; i++ ) {
950 unsigned char *tmp = remotes.by_mac.data[i];
951 if ( tmp == 0 || tmp == (unsigned char *)1 ) {
954 x = (struct Interface *) tmp;
955 if ( x->remote == r ) {
965 // Unmap an ipv4-mapped ipv6 address
966 static void unmap_if_mapped(struct SockAddr *s) {
967 if ( s->in.sa_family != AF_INET6 ||
968 memcmp( "\000\000\000\000\000\000\000\000\000\000\377\377",
969 &s->in6.sin6_addr, 12 ) ) {
972 VERBOSE2OUT( "unmap %s\n",
973 inet_nmtoa( (unsigned char*) s, sizeof( struct SockAddr ) ) );
974 s->in.sa_family = AF_INET;
975 memcpy( &s->in4.sin_addr, s->in6.sin6_addr.s6_addr + 12, 4 );
976 memset( s->in6.sin6_addr.s6_addr + 4, 0, 12 );
977 VERBOSE2OUT( "becomes %s\n",
978 inet_nmtoa( (unsigned char*) s, sizeof( struct SockAddr ) ) );
981 // Route the packet from the given src
982 static struct Interface *input_check(
983 unsigned char *buf,ssize_t len,struct SockAddr *src )
985 VERBOSE2OUT( "RECV %ld bytes from %s\n", len, inet_stoa( src ) );
986 struct Remote *r = 0;
987 struct timeval now = { 0 };
988 if ( gettimeofday( &now, 0 ) ) {
989 perror( "RECV time" );
990 now.tv_sec = time( 0 );
992 Remote_FIND( src, r );
994 struct Allowed *a = is_allowed_remote( src );
996 VERBOSEOUT( "Ignoring %s\n", inet_stoa( src ) );
997 return 0; // Disallowed
999 VERBOSEOUT( "New remote %s by %s\n", inet_stoa( src ), a->source );
1000 r = add_remote( src, a );
1001 //r->rec_when = now; // Set activity stamp of new remote
1004 // Ignore short data, but maintain channel
1005 r->rec_when = now; // Update activity stamp touched remote
1007 VERBOSEOUT( "Ignoring %ld bytes from %s\n",
1008 len, inet_stoa( src ) );
1012 // Now decrypt the data as needed
1014 if ( r->spec->psk.seed ) {
1015 decrypt( buf, len, &r->spec->psk );
1017 } else if ( r->uaddr.in.sa_family == 0 && mcast.psk.keyfile ) {
1018 decrypt( buf, len, &mcast.psk );
1020 VERBOSE2OUT( "RECV %s -> %s from %s\n",
1021 inet_mtoa( buf+6 ), inet_mtoa( buf ),
1022 inet_stoa( &r->uaddr ) );
1023 // Note: the payload is now decrypted, and known to be from +r+
1024 struct Interface *x = 0;
1025 // Packets concerning an ignored interface should be ignored.
1026 if ( r->spec && r->spec->ignored_mac.data ) {
1027 Ignored_FIND( r->spec, buf+6, x );
1029 VERBOSE2OUT( "Dropped MAC %s from %s on %s\n",
1030 inet_mtoa( buf+6 ), inet_stoa( &r->uaddr ),
1034 Ignored_FIND( r->spec, buf, x );
1036 VERBOSE2OUT( "Dropped MAC %s to %s on %s\n",
1037 inet_mtoa( buf ), inet_stoa( &r->uaddr ),
1042 Interface_FIND( buf+6, x );
1044 // Totally new MAC. Should bind it to the remote
1045 VERBOSEOUT( "New MAC %s from %s\n",
1046 inet_mtoa( buf+6 ), inet_stoa( src ) );
1047 x = add_interface( buf+6, r );
1048 r->rec_when = now; // Update activity stamp for remote
1052 // Seen that MAC already
1053 if ( x->remote == r ) {
1054 VERBOSE2OUT( "RECV %s from %s again\n",
1055 inet_mtoa( buf+6 ), inet_stoa( &x->remote->uaddr ) );
1056 r->rec_when = now; // Update activity stamp
1057 x->rec_when = now; // Update activity stamp
1060 // MAC clash from two different connections
1062 // x->remote = previous
1063 VERBOSE2OUT( "RECV %s from %s previously from %s\n",
1065 inet_stoa( &r->uaddr ),
1066 inet_stoa( &x->remote->uaddr ) );
1068 // The packet source MAC has arrived on other than its
1069 // previous channel. It thus gets dropped if tap/stdin is the
1070 // primary channel, or the time since the last packet for that
1071 // interface is less than RECENT_MICROS, with different limits
1072 // for broadcast and unicast.
1073 int64_t dmac = DIFF_MICROS( &now, &x->rec_when);
1074 if ( x->remote->spec == 0 || RECENT_MICROS( *buf & 1, dmac ) ) {
1075 if ( verbose >= 2 ) {
1078 "Dropped. MAC %s (%ld) from %s, should be %s\n",
1079 inet_mtoa( buf+6 ), dmac,
1080 inet_stoa( src ), inet_stoa( &x->remote->uaddr ) );
1084 // Check if previous package on the interface was recent
1085 } else if ( r->uaddr.in.sa_family ) {
1086 // Multicast incoming clashing with tap/stdio
1087 VERBOSE3OUT( "Dropped multicast loopback\n" );
1091 // New remote takes over the MAC
1092 VERBOSEOUT( "MAC %s from %s cancels previous %s\n",
1093 inet_mtoa( buf+6 ), inet_stoa( src ),
1094 inet_stoa( &x->remote->uaddr ) );
1095 x->remote = r; // Change remote for MAC
1096 // Note that this may leave the old x->remote without any interface
1097 r->rec_when = now; // Update activity stamp
1098 x->rec_when = now; // Update activity stamp
1102 // Check packet and deliver out
1103 static void route_packet(unsigned char *buf,int len,struct SockAddr *src) {
1104 struct Interface *x = input_check( buf, len, src );
1106 return; // not a nice packet
1108 if ( ( *buf & 1 ) == 0 ) {
1110 struct Interface *y = 0; // reuse for destination interface
1111 Interface_FIND( buf, y );
1113 VERBOSE2OUT( "RECV %s -> %s from %s without channel and dropped\n",
1114 inet_mtoa( buf+6 ), inet_mtoa( buf ),
1115 inet_stoa( &x->remote->uaddr ) );
1118 if ( x->remote == y->remote ) {
1119 VERBOSEOUT( "RECV loop for %s -> %s from %s to %s\n",
1120 inet_mtoa( buf+6 ), inet_mtoa( buf ),
1121 inet_stoa( &x->remote->uaddr ),
1122 inet_stoa( &y->remote->uaddr ) );
1123 Interface_DEL( y ); // Need to see this interface again
1126 VERBOSE2OUT( "RECV route %s -> %s to %s\n",
1127 inet_mtoa( buf+6 ), inet_mtoa( buf ),
1128 inet_stoa( &y->remote->uaddr ) );
1129 write_remote( buf, len, y->remote );
1132 // broadcast. +x+ is source interface
1133 // x->rec_when is not updated
1134 struct timeval now = { 0 };
1135 if ( gettimeofday( &now, 0 ) ) {
1136 perror( "RECV time" );
1137 now.tv_sec = time( 0 );
1139 VERBOSE2OUT( "BC %s -> %s from %s\n",
1140 inet_mtoa( buf+6 ), inet_mtoa( buf ),
1141 inet_stoa( &x->remote->uaddr ) );
1145 for ( ; i < remotes.by_addr.size; i++ ) {
1146 unsigned char *tmp = remotes.by_addr.data[i];
1147 if ( tmp == 0 || tmp == (unsigned char *)1 ) {
1150 r = (struct Remote *) tmp;
1151 VERBOSE3OUT( "BC check %s\n", inet_stoa( &r->uaddr ) );
1152 if ( r == x->remote ) {
1153 VERBOSE3OUT( "BC r == x->remote\n" );
1156 if ( r->spec && ! is_uplink( r->spec ) &&
1157 DIFF_MICROS( &now, &r->rec_when ) > VERYOLD_MICROS ) {
1158 // remove old downlink connection
1159 VERBOSEOUT( "Old remote discarded %s (%ld)\n",
1160 inet_stoa( &r->uaddr ),
1161 TIME_MICROS( &r->rec_when ) );
1162 // Removing a downlink might have threading implications
1166 // Send packet to the remote
1167 // Only no-clash or to the tap/stdin
1168 write_remote( buf, len, r );
1173 // The packet handling queues
1180 // The threadcontrol program for handling packets.
1181 static void *packet_handler(void *data) {
1184 PacketItem *todo = (PacketItem *) Queue_getItem( &todolist.full );
1185 if ( todo->fd == mcast.fd ) {
1186 // Patch multicast address as source for multicast packet
1187 route_packet( todo->buffer, todo->len, &mcast.sock );
1190 unmap_if_mapped( &todo->src );
1192 route_packet( todo->buffer, todo->len, &todo->src );
1194 Queue_addItem( &todolist.free, (QueueItem*) todo );
1199 void todolist_initialize(int nbuf,int nthr) {
1200 if ( pthread_mutex_init( &todolist.full.mutex, 0 ) ||
1201 sem_init( &todolist.full.count, 0, 0 ) ) {
1205 if ( pthread_mutex_init( &todolist.free.mutex, 0 ) ||
1206 sem_init( &todolist.free.count, 0, 0 ) ) {
1210 if ( sem_init( &todolist.reading, 0, 1 ) ) {
1214 Queue_initialize( &todolist.free, nbuf, sizeof( PacketItem ) );
1215 for ( ; nthr > 0; nthr-- ) {
1216 pthread_t thread; // Temporary thread id
1217 pthread_create( &thread, 0, packet_handler, 0 );
1221 // Read a full UDP packet into the given buffer, associate with a
1222 // connection, or create a new connection, the decrypt the as
1223 // specified, and capture the sender MAC address. The connection table
1224 // is updated for the new MAC address, However, if there is then a MAC
1225 // address clash in the connection table, then the associated remote
1226 // is removed, and the packet is dropped.
1227 static void *doreadUDP(void *data) {
1228 int fd = ((ReaderData *) data)->fd;
1230 PacketItem *todo = (PacketItem *) Queue_getItem( &todolist.free );
1232 udp6? sizeof( todo->src.in6 ) : sizeof( todo->src.in4 );
1233 memset( &todo->src, 0, sizeof( todo->src ) );
1235 todo->len = recvfrom(
1236 fd, todo->buffer, BUFSIZE, 0, &todo->src.in, &addrlen );
1237 if ( todo->len == -1) {
1238 perror( "Receiving UDP" );
1242 if ( todo->len == 17 &&
1243 memcmp( todo->buffer, "STOPSTOPSTOPSTOP", 16 ) == 0 ) {
1247 Queue_addItem( &todolist.full, (QueueItem*) todo );
1252 // Read up to n bytes from the given file descriptor into the buffer
1253 static int doread(int fd, unsigned char *buf, int n) {
1255 if ( ( len = read( fd, buf, n ) ) < 0 ) {
1256 perror( "Reading stdin" );
1262 // Read n bytes from the given file descriptor into the buffer.
1263 // If partial is allowed, then return amount read, otherwise keep
1264 // reading until full.
1265 static int read_into(int fd, unsigned char *buf, int n,int partial) {
1268 if ( (r = doread( fd, buf, x ) ) == 0 ) {
1280 // Go through all uplinks and issue a "heart beat"
1281 static void heartbeat(int fd) {
1282 static unsigned char data[10];
1283 VERBOSE3OUT( "heartbeat fd=%d\n", fd );
1287 if ( gettimeofday( &now, 0 ) ) {
1288 perror( "HEARTBEAT time" );
1289 now.tv_sec = time( 0 );
1293 for ( ; i < remotes.by_addr.size; i++ ) {
1294 unsigned char *tmp = remotes.by_addr.data[i];
1295 if ( tmp == 0 || tmp == (unsigned char *)1 ) {
1298 r = (struct Remote *) tmp;
1299 VERBOSE3OUT( "heartbeat check %s\n", inet_stoa( &r->uaddr ) );
1300 if ( r->spec && is_uplink( r->spec ) ) {
1301 if ( DIFF_MICROS( &now, &r->rec_when ) > HEARTBEAT_MICROS ) {
1302 VERBOSE3OUT( "heartbeat %s\n", inet_stoa( &r->uaddr ) );
1303 write_remote( data, 0, r );
1310 // Tell how to use this program and exit with failure.
1311 static void usage(void) {
1312 fprintf( stderr, "Packet tunneling over UDP, multiple channels, " );
1313 fprintf( stderr, "version 1.5.3\n" );
1314 fprintf( stderr, "Usage: " );
1316 "%s [-v] [-tpg] [-4] [-B n] [-T n] [-m mcast] [-t tap] port [remote]+ \n",
1321 // Open the given tap
1322 static int tun_alloc(char *dev, int flags) {
1325 if ( ( fd = open( "/dev/net/tun", O_RDWR ) ) < 0 ) {
1326 perror( "Opening /dev/net/tun" );
1329 memset( &ifr, 0, sizeof( ifr ) );
1330 ifr.ifr_flags = flags;
1332 strcpy( ifr.ifr_name, dev );
1334 if ( ( err = ioctl( fd, TUNSETIFF, (void *) &ifr ) ) < 0 ) {
1335 perror( "ioctl(TUNSETIFF)" );
1339 strcpy( dev, ifr.ifr_name );
1343 // Handle packet received on the tap/stdio channel
1344 static void initialize_tap() {
1345 // Ensure there is a Remote for this
1346 static struct Remote *tap_remote = 0;
1347 if ( tap_remote == 0 ) {
1349 if ( tap_remote == 0 ) {
1350 tap_remote = add_remote( 0, 0 );
1356 // Thread to handle tap/stdio input
1357 static void *doreadTap(void *data) {
1358 int fd = ((ReaderData*) data)->fd;
1359 unsigned int end = 0; // Packet size
1360 unsigned int cur = 0; // Amount read so far
1362 PacketItem *todo = (PacketItem*) Queue_getItem( &todolist.free );
1366 int n = read_into( 0, (unsigned char *) &plength,
1367 sizeof( plength ), 0 );
1369 // Tap/stdio closed => exit silently
1372 end = ntohs( plength );
1374 while ( ( e = ( end - cur ) ) != 0 ) {
1375 unsigned char *p = todo->buffer + cur;
1376 if ( end > BUFSIZE ) {
1377 // Oversize packets should be read and discarded
1378 if ( e > BUFSIZE ) {
1383 cur += read_into( 0, p, e, 1 );
1386 end = doread( fd, todo->buffer, BUFSIZE );
1389 VERBOSE3OUT( "TAP/stdio input %d bytes\n", end );
1390 if ( end <= BUFSIZE ) {
1393 Queue_addItem( &todolist.full, (QueueItem*) todo );
1394 todo = (PacketItem*) Queue_getItem( &todolist.free );
1401 // Application main function
1402 // Parentheses mark optional
1403 // $* = (-v) (-4) (-B n) (-T n) (-m mcast) (-t port) (ip:)port (remote)+
1404 // remote = ipv4(/maskwidth)(:port)(=key)
1405 // remote = ipv6(/maskwidth)(=key)
1406 // remote = [ipv6(/maskwidth)](:port)(=key)
1407 // ip = ipv4 | [ipv6]
1408 int main(int argc, char *argv[]) {
1409 pthread_t thread; // Temporary thread id
1411 progname = (unsigned char *) argv[0];
1412 ///// Parse command line arguments
1414 #define ENSUREARGS(n) if ( argc < i + n ) usage()
1416 // First: optional -v, -vv or -vvv
1417 if ( strncmp( "-v", argv[i], 2 ) == 0 ) {
1418 if ( strncmp( "-v", argv[i], 3 ) == 0 ) {
1420 } else if ( strncmp( "-vv", argv[i], 4 ) == 0 ) {
1422 } else if ( strncmp( "-vvv", argv[i], 5 ) == 0 ) {
1430 if ( strncmp( "-tpg", argv[i], 4 ) == 0 ) {
1435 // then: optional -4
1436 if ( strncmp( "-4", argv[i], 2 ) == 0 ) {
1441 // then: optional -B buffers
1442 if ( strncmp( "-B", argv[i], 2 ) == 0 ) {
1444 if ( parse_buffers_count( argv[i+1] ) ) {
1450 // then: optional -T threads
1451 if ( strncmp( "-T", argv[i], 2 ) == 0 ) {
1453 if ( parse_threads_count( argv[i+1] ) ) {
1459 // then: optional -m mcast
1460 if ( strncmp( "-m", argv[i], 2 ) == 0 ) {
1462 if ( parse_mcast( argv[i+1] ) ) {
1468 // then: optional -t tap
1469 if ( strncmp( "-t", argv[i], 2 ) == 0 ) {
1475 // then: required port
1476 if ( sscanf( argv[i++], "%d", &port ) != 1 ) {
1477 fprintf( stderr, "Bad local port: %s\n", argv[i-1] );
1480 // then: any number of allowed remotes
1481 struct Allowed *last_allowed = 0;
1482 for ( ; i < argc; i++ ) {
1483 if ( last_allowed ) {
1484 // optionally adding ignored interfaces
1485 if ( strncmp( "-i", argv[i], 2 ) == 0 ) {
1487 if ( parse_ignored_interfaces( argv[i+1], last_allowed ) ) {
1494 if ( ( last_allowed = add_allowed( argv[i] ) ) == 0 ) {
1495 fprintf( stderr, "Cannot load remote %s. Exiting.\n", argv[i] );
1499 // end of command line parsing
1501 // Initialize buffers and threads
1502 if ( threads_count == 0 ) {
1505 if ( buffers_count < threads_count ) {
1506 buffers_count = 2 * threads_count;
1508 todolist_initialize( buffers_count, threads_count );
1510 // Set up the tap/stdio channel
1512 // set up the nominated tap
1513 if ( strcmp( "-", tap ) ) { // Unless "-"
1514 tap_fd = tun_alloc( tap, IFF_TAP | IFF_NO_PI );
1516 fprintf( stderr, "Error connecting to interface %s!\n", tap);
1519 VERBOSEOUT( "Using tap %s at %d\n", tap, tap_fd );
1521 // pretend a zero packet on the tap, for initializing.
1524 // set up for stdin/stdout local traffix
1525 setbuf( stdout, NULL ); // No buffering on stdout.
1526 tap_fd = 0; // actually stdin
1532 // Set up the multicast UDP channel (all interfaces)
1533 if ( mcast.group.imr_multiaddr.s_addr ) {
1535 unsigned char *x = (unsigned char *) &mcast.group.imr_multiaddr.s_addr;
1536 VERBOSEOUT( "Using multicast %s:%d at %d\n",
1537 inet_nmtoa( x, 4 ), ntohs( mcast.sock.in4.sin_port ),
1540 // Set up the unicast UPD channel (all interfaces)
1542 // set up ipv4 socket
1543 if ( ( udp_fd = socket( AF_INET, SOCK_DGRAM, 0 ) ) == 0 ) {
1544 perror( "creating socket");
1547 struct sockaddr_in udp_addr = {
1548 .sin_family = AF_INET,
1549 .sin_port = htons( port ),
1550 .sin_addr.s_addr = htonl(INADDR_ANY),
1552 if ( bind( udp_fd, (struct sockaddr*) &udp_addr, sizeof(udp_addr))) {
1553 fprintf( stderr, "Error binding socket!\n");
1556 VERBOSEOUT( "Using ipv4 UDP at %d\n", udp_fd );
1558 // set up ipv6 socket
1559 if ( ( udp_fd = socket( AF_INET6, SOCK_DGRAM, 0 ) ) == 0 ) {
1560 perror( "creating socket");
1563 struct sockaddr_in6 udp6_addr = {
1564 .sin6_family = AF_INET6,
1565 .sin6_port = htons( port ),
1566 .sin6_addr = IN6ADDR_ANY_INIT,
1568 if ( bind( udp_fd, (struct sockaddr*) &udp6_addr, sizeof(udp6_addr))) {
1569 fprintf( stderr, "Error binding socket!\n");
1572 VERBOSEOUT( "Using ipv6 UDP at %d\n", udp_fd );
1574 // If not using stdio for local traffic, then stdin and stdout are
1575 // closed here, so as to avoid that any other traffic channel gets
1576 // 0 or 1 as its file descriptor. Note: stderr (2) is left open.
1581 VERBOSE2OUT( "Socket loop tap=%d mcast=%d udp=%d\n",
1582 tap_fd, mcast.fd, udp_fd );
1585 ReaderData udp_reader = { .fd = udp_fd };
1586 pthread_create( &thread, 0, doreadUDP, &udp_reader );
1588 if ( mcast.group.imr_multiaddr.s_addr ) {
1589 ReaderData mcast_reader = { .fd = mcast.fd };
1590 pthread_create( &thread, 0, doreadUDP, &mcast_reader );
1593 if ( tap_fd || stdio ) {
1594 ReaderData tap_reader = { .fd = tap_fd };
1595 pthread_create( &thread, 0, doreadTap, &tap_reader );
1598 // Start heartbeating to uplinks
1601 heartbeat( udp_fd );