/* follow.c * * Copyright 1998 Mike Hall * * Wireshark - Network traffic analyzer * By Gerald Combs * Copyright 1998 Gerald Combs * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * */ #include "config.h" #include #include #include #ifdef HAVE_UNISTD_H #include #endif #include #include #include #include #include #include "follow.h" #include #include #define MAX_IPADDR_LEN 16 typedef struct _tcp_frag { guint32 seq; guint32 len; guint32 data_len; gchar *data; struct _tcp_frag *next; } tcp_frag; WS_DLL_PUBLIC_DEF FILE* data_out_file = NULL; gboolean empty_tcp_stream; gboolean incomplete_tcp_stream; static guint32 stream_to_follow[MAX_STREAM] = {0}; static gboolean find_addr[MAX_STREAM] = {FALSE}; static gboolean find_index[MAX_STREAM] = {FALSE}; static address tcp_addr[2]; static guint8 ip_address[2][MAX_IPADDR_LEN]; static guint port[2]; static guint bytes_written[2]; static gboolean is_ipv6 = FALSE; static int check_fragments( int, tcp_stream_chunk *, guint32 ); static void write_packet_data( int, tcp_stream_chunk *, const char * ); void follow_stats(follow_stats_t* stats) { int i; for (i = 0; i < 2 ; i++) { memcpy(stats->ip_address[i], ip_address[i], MAX_IPADDR_LEN); stats->port[i] = port[i]; stats->bytes_written[i] = bytes_written[i]; stats->is_ipv6 = is_ipv6; } } /* This will build a display filter text that will only pass the packets related to the stream. There is a chance that two streams could intersect, but not a very good one */ gchar* build_follow_conv_filter( packet_info *pi ) { char* buf; int len; conversation_t *conv=NULL; struct tcp_analysis *tcpd; struct udp_analysis *udpd; wmem_list_frame_t* protos; int proto_id; const char* proto_name; gboolean is_tcp = FALSE, is_udp = FALSE; protos = wmem_list_head(pi->layers); /* walk the list of a available protocols in the packet to figure out if any of them affect context sensitivity */ while (protos != NULL) { proto_id = GPOINTER_TO_INT(wmem_list_frame_data(protos)); proto_name = proto_get_protocol_filter_name(proto_id); if (!strcmp(proto_name, "tcp")) { is_tcp = TRUE; } else if (!strcmp(proto_name, "udp")) { is_udp = TRUE; } protos = wmem_list_frame_next(protos); } if( ((pi->net_src.type == AT_IPv4 && pi->net_dst.type == AT_IPv4) || (pi->net_src.type == AT_IPv6 && pi->net_dst.type == AT_IPv6)) && is_tcp && (conv=find_conversation(pi->fd->num, &pi->src, &pi->dst, pi->ptype, pi->srcport, pi->destport, 0)) != NULL ) { /* TCP over IPv4/6 */ tcpd=get_tcp_conversation_data(conv, pi); if (tcpd) { buf = g_strdup_printf("tcp.stream eq %d", tcpd->stream); stream_to_follow[TCP_STREAM] = tcpd->stream; if (pi->net_src.type == AT_IPv4) { len = 4; is_ipv6 = FALSE; } else { len = 16; is_ipv6 = TRUE; } } else { return NULL; } } else if( ((pi->net_src.type == AT_IPv4 && pi->net_dst.type == AT_IPv4) || (pi->net_src.type == AT_IPv6 && pi->net_dst.type == AT_IPv6)) && is_udp && (conv=find_conversation(pi->fd->num, &pi->src, &pi->dst, pi->ptype, pi->srcport, pi->destport, 0)) != NULL ) { /* UDP over IPv4/6 */ udpd=get_udp_conversation_data(conv, pi); if (udpd) { buf = g_strdup_printf("udp.stream eq %d", udpd->stream); stream_to_follow[UDP_STREAM] = udpd->stream; if (pi->net_src.type == AT_IPv4) { len = 4; is_ipv6 = FALSE; } else { len = 16; is_ipv6 = TRUE; } } else { return NULL; } } else { return NULL; } memcpy(ip_address[0], pi->net_src.data, len); memcpy(ip_address[1], pi->net_dst.data, len); port[0] = pi->srcport; port[1] = pi->destport; return buf; } static gboolean udp_follow_packet(void *tapdata _U_, packet_info *pinfo, epan_dissect_t *edt _U_, const void *data _U_) { if (find_addr[UDP_STREAM]) { if (pinfo->net_src.type == AT_IPv6) { is_ipv6 = TRUE; } else { is_ipv6 = FALSE; } memcpy(ip_address[0], pinfo->net_src.data, pinfo->net_src.len); memcpy(ip_address[1], pinfo->net_dst.data, pinfo->net_dst.len); port[0] = pinfo->srcport; port[1] = pinfo->destport; find_addr[UDP_STREAM] = FALSE; } return FALSE; } void reset_udp_follow(void) { remove_tap_listener(&stream_to_follow[UDP_STREAM]); find_addr[UDP_STREAM] = FALSE; find_index[UDP_STREAM] = FALSE; } gchar* build_follow_index_filter(stream_type stream) { gchar *buf; find_addr[stream] = TRUE; if (stream == TCP_STREAM) { buf = g_strdup_printf("tcp.stream eq %d", stream_to_follow[TCP_STREAM]); } else { GString * error_string; buf = g_strdup_printf("udp.stream eq %d", stream_to_follow[UDP_STREAM]); error_string = register_tap_listener("udp_follow", &stream_to_follow[UDP_STREAM], buf, 0, NULL, udp_follow_packet, NULL); if (error_string) { g_string_free(error_string, TRUE); } } return buf; } /* select a tcp stream to follow via it's address/port pairs */ gboolean follow_addr(stream_type stream, const address *addr0, guint port0, const address *addr1, guint port1) { if (addr0 == NULL || addr1 == NULL || addr0->type != addr1->type || port0 > G_MAXUINT16 || port1 > G_MAXUINT16 ) { return FALSE; } if (find_index[stream] || find_addr[stream]) { return FALSE; } switch (addr0->type) { default: return FALSE; case AT_IPv4: case AT_IPv6: is_ipv6 = addr0->type == AT_IPv6; break; } memcpy(ip_address[0], addr0->data, addr0->len); port[0] = port0; memcpy(ip_address[1], addr1->data, addr1->len); port[1] = port1; if (stream == TCP_STREAM) { find_index[TCP_STREAM] = TRUE; SET_ADDRESS(&tcp_addr[0], addr0->type, addr0->len, ip_address[0]); SET_ADDRESS(&tcp_addr[1], addr1->type, addr1->len, ip_address[1]); } return TRUE; } /* select a stream to follow via its index */ gboolean follow_index(stream_type stream, guint32 indx) { if (find_index[stream] || find_addr[stream]) { return FALSE; } find_addr[stream] = TRUE; stream_to_follow[stream] = indx; memset(ip_address, 0, sizeof ip_address); port[0] = port[1] = 0; return TRUE; } guint32 get_follow_index(stream_type stream) { return stream_to_follow[stream]; } /* here we are going to try and reconstruct the data portion of a TCP session. We will try and handle duplicates, TCP fragments, and out of order packets in a smart way. */ static tcp_frag *frags[2] = { 0, 0 }; static guint32 seq[2]; static guint8 src_addr[2][MAX_IPADDR_LEN]; static guint src_port[2] = { 0, 0 }; void reassemble_tcp( guint32 tcp_stream, guint32 sequence, guint32 acknowledgement, guint32 length, const char* data, guint32 data_length, int synflag, address *net_src, address *net_dst, guint srcport, guint dstport, guint32 packet_num) { guint8 srcx[MAX_IPADDR_LEN], dstx[MAX_IPADDR_LEN]; int src_index, j, first = 0, len; guint32 newseq; tcp_frag *tmp_frag; tcp_stream_chunk sc; src_index = -1; /* First, check if this packet should be processed. */ if (find_index[TCP_STREAM]) { if ((port[0] == srcport && port[1] == dstport && ADDRESSES_EQUAL(&tcp_addr[0], net_src) && ADDRESSES_EQUAL(&tcp_addr[1], net_dst)) || (port[1] == srcport && port[0] == dstport && ADDRESSES_EQUAL(&tcp_addr[1], net_src) && ADDRESSES_EQUAL(&tcp_addr[0], net_dst))) { find_index[TCP_STREAM] = FALSE; stream_to_follow[TCP_STREAM] = tcp_stream; } else { return; } } else if ( tcp_stream != stream_to_follow[TCP_STREAM] ) return; if ((net_src->type != AT_IPv4 && net_src->type != AT_IPv6) || (net_dst->type != AT_IPv4 && net_dst->type != AT_IPv6)) return; if (net_src->type == AT_IPv4) len = 4; else len = 16; memcpy(srcx, net_src->data, len); memcpy(dstx, net_dst->data, len); /* follow_tcp_index() needs to learn address/port pairs */ if (find_addr[TCP_STREAM]) { find_addr[TCP_STREAM] = FALSE; memcpy(ip_address[0], net_src->data, net_src->len); port[0] = srcport; memcpy(ip_address[1], net_dst->data, net_dst->len); port[1] = dstport; if (net_src->type == AT_IPv6 && net_dst->type == AT_IPv6) { is_ipv6 = TRUE; } else { is_ipv6 = FALSE; } } /* Check to see if we have seen this source IP and port before. (Yes, we have to check both source IP and port; the connection might be between two different ports on the same machine.) */ for( j=0; j<2; j++ ) { if (memcmp(src_addr[j], srcx, len) == 0 && src_port[j] == srcport ) { src_index = j; } } /* we didn't find it if src_index == -1 */ if( src_index < 0 ) { /* assign it to a src_index and get going */ for( j=0; j<2; j++ ) { if( src_port[j] == 0 ) { memcpy(src_addr[j], srcx, len); src_port[j] = srcport; src_index = j; first = 1; break; } } } if( src_index < 0 ) { fprintf( stderr, "ERROR in reassemble_tcp: Too many addresses!\n"); return; } if( data_length < length ) { incomplete_tcp_stream = TRUE; } /* Before adding data for this flow to the data_out_file, check whether * this frame acks fragments that were already seen. This happens when * frames are not in the capture file, but were actually seen by the * receiving host (Fixes bug 592). */ if( frags[1-src_index] ) { memcpy(sc.src_addr, dstx, len); sc.src_port = dstport; sc.dlen = 0; /* Will be filled in in check_fragments */ while ( check_fragments( 1-src_index, &sc, acknowledgement ) ) ; } /* Initialize our stream chunk. This data gets written to disk. */ memcpy(sc.src_addr, srcx, len); sc.src_port = srcport; sc.dlen = data_length; sc.packet_num = packet_num; /* now that we have filed away the srcs, lets get the sequence number stuff figured out */ if( first ) { /* this is the first time we have seen this src's sequence number */ seq[src_index] = sequence + length; if( synflag ) { seq[src_index]++; } /* write out the packet data */ write_packet_data( src_index, &sc, data ); return; } /* if we are here, we have already seen this src, let's try and figure out if this packet is in the right place */ if( LT_SEQ(sequence, seq[src_index]) ) { /* this sequence number seems dated, but check the end to make sure it has no more info than we have already seen */ newseq = sequence + length; if( GT_SEQ(newseq, seq[src_index]) ) { guint32 new_len; /* this one has more than we have seen. let's get the payload that we have not seen. */ new_len = seq[src_index] - sequence; if ( data_length <= new_len ) { data = NULL; data_length = 0; incomplete_tcp_stream = TRUE; } else { data += new_len; data_length -= new_len; } sc.dlen = data_length; sequence = seq[src_index]; length = newseq - seq[src_index]; /* this will now appear to be right on time :) */ } } if ( EQ_SEQ(sequence, seq[src_index]) ) { /* right on time */ seq[src_index] += length; if( synflag ) seq[src_index]++; if( data ) { write_packet_data( src_index, &sc, data ); } /* done with the packet, see if it caused a fragment to fit */ while( check_fragments( src_index, &sc, 0 ) ) ; } else { /* out of order packet */ if(data_length > 0 && GT_SEQ(sequence, seq[src_index]) ) { tmp_frag = (tcp_frag *)g_malloc( sizeof( tcp_frag ) ); tmp_frag->data = (gchar *)g_malloc( data_length ); tmp_frag->seq = sequence; tmp_frag->len = length; tmp_frag->data_len = data_length; memcpy( tmp_frag->data, data, data_length ); if( frags[src_index] ) { tmp_frag->next = frags[src_index]; } else { tmp_frag->next = NULL; } frags[src_index] = tmp_frag; } } } /* end reassemble_tcp */ /* here we search through all the frag we have collected to see if one fits */ static int check_fragments( int idx, tcp_stream_chunk *sc, guint32 acknowledged ) { tcp_frag *prev = NULL; tcp_frag *current; guint32 lowest_seq; gchar *dummy_str; current = frags[idx]; if( current ) { lowest_seq = current->seq; while( current ) { if( GT_SEQ(lowest_seq, current->seq) ) { lowest_seq = current->seq; } if( LT_SEQ(current->seq, seq[idx]) ) { guint32 newseq; /* this sequence number seems dated, but check the end to make sure it has no more info than we have already seen */ newseq = current->seq + current->len; if( GT_SEQ(newseq, seq[idx]) ) { guint32 new_pos; /* this one has more than we have seen. let's get the payload that we have not seen. This happens when part of this frame has been retransmitted */ new_pos = seq[idx] - current->seq; if ( current->data_len > new_pos ) { sc->dlen = current->data_len - new_pos; write_packet_data( idx, sc, current->data + new_pos ); } seq[idx] += (current->len - new_pos); } /* Remove the fragment from the list as the "new" part of it * has been processed or its data has been seen already in * another packet. */ if( prev ) { prev->next = current->next; } else { frags[idx] = current->next; } g_free( current->data ); g_free( current ); return 1; } if( EQ_SEQ(current->seq, seq[idx]) ) { /* this fragment fits the stream */ if( current->data ) { sc->dlen = current->data_len; write_packet_data( idx, sc, current->data ); } seq[idx] += current->len; if( prev ) { prev->next = current->next; } else { frags[idx] = current->next; } g_free( current->data ); g_free( current ); return 1; } prev = current; current = current->next; } if( GT_SEQ(acknowledged, lowest_seq) ) { /* There are frames missing in the capture file that were seen * by the receiving host. Add dummy stream chunk with the data * "[xxx bytes missing in capture file]". */ dummy_str = g_strdup_printf("[%d bytes missing in capture file]", (int)(lowest_seq - seq[idx]) ); sc->dlen = (guint32) strlen(dummy_str); write_packet_data( idx, sc, dummy_str ); g_free(dummy_str); seq[idx] = lowest_seq; return 1; } } return 0; } /* this should always be called before we start to reassemble a stream */ void reset_tcp_reassembly(void) { tcp_frag *current, *next; int i; empty_tcp_stream = TRUE; incomplete_tcp_stream = FALSE; find_addr[TCP_STREAM] = FALSE; find_index[TCP_STREAM] = FALSE; for( i=0; i<2; i++ ) { seq[i] = 0; memset(src_addr[i], '\0', MAX_IPADDR_LEN); src_port[i] = 0; memset(ip_address[i], '\0', MAX_IPADDR_LEN); port[i] = 0; bytes_written[i] = 0; current = frags[i]; while( current ) { next = current->next; g_free( current->data ); g_free( current ); current = next; } frags[i] = NULL; } } static void write_packet_data( int idx, tcp_stream_chunk *sc, const char *data ) { size_t ret; ret = fwrite( sc, 1, sizeof(tcp_stream_chunk), data_out_file ); DISSECTOR_ASSERT(sizeof(tcp_stream_chunk) == ret); ret = fwrite( data, 1, sc->dlen, data_out_file ); DISSECTOR_ASSERT(sc->dlen == ret); bytes_written[idx] += sc->dlen; empty_tcp_stream = FALSE; } /* * Editor modelines - http://www.wireshark.org/tools/modelines.html * * Local Variables: * c-basic-offset: 2 * tab-width: 8 * indent-tabs-mode: nil * End: * * ex: set shiftwidth=2 tabstop=8 expandtab: * :indentSize=2:tabSize=8:noTabs=true: */