5 * Copyright 1998 Mike Hall <mlh@io.com>
7 * Wireshark - Network traffic analyzer
8 * By Gerald Combs <gerald@wireshark.org>
9 * Copyright 1998 Gerald Combs
11 * This program is free software; you can redistribute it and/or
12 * modify it under the terms of the GNU General Public License
13 * as published by the Free Software Foundation; either version 2
14 * of the License, or (at your option) any later version.
16 * This program is distributed in the hope that it will be useful,
17 * but WITHOUT ANY WARRANTY; without even the implied warranty of
18 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
19 * GNU General Public License for more details.
21 * You should have received a copy of the GNU General Public License
22 * along with this program; if not, write to the Free Software
23 * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
39 #include <epan/packet.h>
42 #define MAX_IPADDR_LEN 16
44 typedef struct _tcp_frag {
49 struct _tcp_frag *next;
52 FILE* data_out_file = NULL;
54 gboolean incomplete_tcp_stream = FALSE;
56 static guint8 ip_address[2][MAX_IPADDR_LEN];
57 static guint tcp_port[2];
58 static guint bytes_written[2];
59 static gboolean is_ipv6 = FALSE;
61 static int check_fragments( int, tcp_stream_chunk * );
62 static void write_packet_data( int, tcp_stream_chunk *, const char * );
65 follow_tcp_stats(follow_tcp_stats_t* stats)
69 for (i = 0; i < 2 ; i++) {
70 memcpy(stats->ip_address[i], ip_address[i], MAX_IPADDR_LEN);
71 stats->tcp_port[i] = tcp_port[i];
72 stats->bytes_written[i] = bytes_written[i];
73 stats->is_ipv6 = is_ipv6;
77 /* this will build libpcap filter text that will only
78 pass the packets related to the stream. There is a
79 chance that two streams could intersect, but not a
82 build_follow_filter( packet_info *pi ) {
85 if( pi->net_src.type == AT_IPv4 && pi->net_dst.type == AT_IPv4
86 && pi->ipproto == 6 ) {
88 buf = g_strdup_printf(
89 "(ip.addr eq %s and ip.addr eq %s) and (tcp.port eq %d and tcp.port eq %d)",
90 ip_to_str( pi->net_src.data),
91 ip_to_str( pi->net_dst.data),
92 pi->srcport, pi->destport );
96 else if( pi->net_src.type == AT_IPv6 && pi->net_dst.type == AT_IPv6
97 && pi->ipproto == 6 ) {
99 buf = g_strdup_printf(
100 "(ipv6.addr eq %s and ipv6.addr eq %s) and (tcp.port eq %d and tcp.port eq %d)",
101 ip6_to_str((const struct e_in6_addr *)pi->net_src.data),
102 ip6_to_str((const struct e_in6_addr *)pi->net_dst.data),
103 pi->srcport, pi->destport );
110 memcpy(ip_address[0], pi->net_src.data, len);
111 memcpy(ip_address[1], pi->net_dst.data, len);
112 tcp_port[0] = pi->srcport;
113 tcp_port[1] = pi->destport;
117 /* here we are going to try and reconstruct the data portion of a TCP
118 session. We will try and handle duplicates, TCP fragments, and out
119 of order packets in a smart way. */
121 static tcp_frag *frags[2] = { 0, 0 };
122 static gulong seq[2];
123 static guint8 src_addr[2][MAX_IPADDR_LEN];
124 static guint src_port[2] = { 0, 0 };
127 reassemble_tcp( gulong sequence, gulong length, const char* data,
128 gulong data_length, int synflag, address *net_src,
129 address *net_dst, guint srcport, guint dstport) {
130 guint8 srcx[MAX_IPADDR_LEN], dstx[MAX_IPADDR_LEN];
131 int src_index, j, first = 0, len;
138 /* First, check if this packet should be processed. */
140 if ((net_src->type != AT_IPv4 && net_src->type != AT_IPv6) ||
141 (net_dst->type != AT_IPv4 && net_dst->type != AT_IPv6))
144 if (net_src->type == AT_IPv4)
149 /* Now check if the packet is for this connection. */
150 memcpy(srcx, net_src->data, len);
151 memcpy(dstx, net_dst->data, len);
154 memcmp(srcx, ip_address[0], len) == 0 &&
155 memcmp(dstx, ip_address[1], len) == 0 &&
156 srcport == tcp_port[0] &&
157 dstport == tcp_port[1]
160 memcmp(srcx, ip_address[1], len) == 0 &&
161 memcmp(dstx, ip_address[0], len) == 0 &&
162 srcport == tcp_port[1] &&
163 dstport == tcp_port[0]
168 /* Initialize our stream chunk. This data gets written to disk. */
169 memcpy(sc.src_addr, srcx, len);
170 sc.src_port = srcport;
171 sc.dlen = data_length;
173 /* Check to see if we have seen this source IP and port before.
174 (Yes, we have to check both source IP and port; the connection
175 might be between two different ports on the same machine.) */
176 for( j=0; j<2; j++ ) {
177 if (memcmp(src_addr[j], srcx, len) == 0 && src_port[j] == srcport ) {
181 /* we didn't find it if src_index == -1 */
182 if( src_index < 0 ) {
183 /* assign it to a src_index and get going */
184 for( j=0; j<2; j++ ) {
185 if( src_port[j] == 0 ) {
186 memcpy(src_addr[j], srcx, len);
187 src_port[j] = srcport;
194 if( src_index < 0 ) {
195 fprintf( stderr, "ERROR in reassemble_tcp: Too many addresses!\n");
199 if( data_length < length ) {
200 incomplete_tcp_stream = TRUE;
203 /* now that we have filed away the srcs, lets get the sequence number stuff
206 /* this is the first time we have seen this src's sequence number */
207 seq[src_index] = sequence + length;
211 /* write out the packet data */
212 write_packet_data( src_index, &sc, data );
215 /* if we are here, we have already seen this src, let's
216 try and figure out if this packet is in the right place */
217 if( sequence < seq[src_index] ) {
218 /* this sequence number seems dated, but
219 check the end to make sure it has no more
220 info than we have already seen */
221 newseq = sequence + length;
222 if( newseq > seq[src_index] ) {
225 /* this one has more than we have seen. let's get the
226 payload that we have not seen. */
228 new_len = seq[src_index] - sequence;
230 if ( data_length <= new_len ) {
233 incomplete_tcp_stream = TRUE;
236 data_length -= new_len;
238 sc.dlen = data_length;
239 sequence = seq[src_index];
240 length = newseq - seq[src_index];
242 /* this will now appear to be right on time :) */
245 if ( sequence == seq[src_index] ) {
247 seq[src_index] += length;
248 if( synflag ) seq[src_index]++;
250 write_packet_data( src_index, &sc, data );
252 /* done with the packet, see if it caused a fragment to fit */
253 while( check_fragments( src_index, &sc ) )
257 /* out of order packet */
258 if(data_length > 0 && sequence > seq[src_index] ) {
259 tmp_frag = (tcp_frag *)g_malloc( sizeof( tcp_frag ) );
260 tmp_frag->data = (guchar *)g_malloc( data_length );
261 tmp_frag->seq = sequence;
262 tmp_frag->len = length;
263 tmp_frag->data_len = data_length;
264 memcpy( tmp_frag->data, data, data_length );
265 if( frags[src_index] ) {
266 tmp_frag->next = frags[src_index];
268 tmp_frag->next = NULL;
270 frags[src_index] = tmp_frag;
273 } /* end reassemble_tcp */
275 /* here we search through all the frag we have collected to see if
278 check_fragments( int index, tcp_stream_chunk *sc ) {
279 tcp_frag *prev = NULL;
281 current = frags[index];
283 if( current->seq == seq[index] ) {
284 /* this fragment fits the stream */
285 if( current->data ) {
286 sc->dlen = current->data_len;
287 write_packet_data( index, sc, current->data );
289 seq[index] += current->len;
291 prev->next = current->next;
293 frags[index] = current->next;
295 g_free( current->data );
300 current = current->next;
305 /* this should always be called before we start to reassemble a stream */
307 reset_tcp_reassembly() {
308 tcp_frag *current, *next;
310 incomplete_tcp_stream = FALSE;
311 for( i=0; i<2; i++ ) {
313 memset(src_addr[i], '\0', MAX_IPADDR_LEN);
315 memset(ip_address[i], '\0', MAX_IPADDR_LEN);
317 bytes_written[i] = 0;
320 next = current->next;
321 g_free( current->data );
330 write_packet_data( int index, tcp_stream_chunk *sc, const char *data )
332 fwrite( sc, 1, sizeof(tcp_stream_chunk), data_out_file );
333 fwrite( data, 1, sc->dlen, data_out_file );
334 bytes_written[index] += sc->dlen;