#include #include #include #include #include #include #include #include "uhd_dump.h" //#define DEBUG 1 void usage() { fprintf(stderr,"Usage: chdr_dump [-h host_ip] filename.pcap\n"); exit(2); } int main(int argc, char *argv[]) { struct pbuf_info *packet_buffer; // Store all packets of interest here struct in_addr host_addr; // Apparent Host IP addr in this capture struct in_addr usrp_addr; // Apparent USRP IP addr in this capture struct timeval *origin_ts; // Timestamp of first packet in file. long long origin_ts_in_us; int direction; // Flag to show direction of packet flow. 0=H->U, 1=U->H. int packet_count[2]; // Number of packets that match filter double size_average[2]; // Average size of packets Host to USRP int size_histogram[90][2]; // Array captures histogram of packet sizes Host to USRP in 100 byte bins int x; // Local integer scratch variables char *conversion_error[1]; int c; char buffer[26]; // Buffer to format GMT time stamp strings for output double time_since_start; // Time elapsed in seconds since start const struct ip_header *ip_header; u32 *dump_header; host_addr.s_addr = 0x0; //usrp_addr.s_addr = 0x0; while ((c = getopt(argc, argv, "h:u:")) != -1) { switch(c) { case 'h': // Explicit IP address for host on command line if (*optarg == '\0') usage(); host_addr.s_addr = strtol(strtok(optarg,"."),conversion_error,10) ; if (**conversion_error != '\0') usage(); host_addr.s_addr = host_addr.s_addr | strtol(strtok(NULL,"."),conversion_error,10) << 8; if (**conversion_error != '\0') usage(); host_addr.s_addr = host_addr.s_addr | strtol(strtok(NULL,"."),conversion_error,10) << 16; if (**conversion_error != '\0') usage(); host_addr.s_addr = host_addr.s_addr | strtol(strtok(NULL,"\0"),conversion_error,10) << 24; if (**conversion_error != '\0') usage(); break; case 'u': // Explicit IP address for USRP on command line if (*optarg == '\0') usage(); usrp_addr.s_addr = strtol(strtok(optarg,"."),conversion_error,10) ; if (**conversion_error != '\0') usage(); usrp_addr.s_addr = usrp_addr.s_addr | strtol(strtok(NULL,"."),conversion_error,10) << 8; if (**conversion_error != '\0') usage(); usrp_addr.s_addr = usrp_addr.s_addr | strtol(strtok(NULL,"."),conversion_error,10) << 16; if (**conversion_error != '\0') usage(); usrp_addr.s_addr = usrp_addr.s_addr | strtol(strtok(NULL,"\0"),conversion_error,10) << 24; if (**conversion_error != '\0') usage(); break; case'?': default: usage(); } } argc -= (optind - 1); argv += (optind -1); // Just a mandatory pcap filename for now, better parser and options later. if (argc != 2) { usage(); } // Init packet buffer packet_buffer = malloc(sizeof(struct pbuf_info)); // Init origin timestamp origin_ts = malloc(sizeof(struct timeval)); // Go read matching packets from capture file into memory get_udp_port_from_file(CHDR_PORT,argv[1],packet_buffer,origin_ts); // Extract origin tome of first packet and convert to uS. origin_ts_in_us = origin_ts->tv_sec * 1000000 + origin_ts->tv_usec; // Count number of packets in capture packet_buffer->current = packet_buffer->start; x = 0; while (packet_buffer->current != NULL) { x++; packet_buffer->current = packet_buffer->current->next; } fprintf(stdout,"\n===================================================================\n"); fprintf(stdout,"\n Total matching packet count in capture file: %d\n",x); fprintf(stdout,"\n===================================================================\n\n"); // If no packets were CHDR then just exit now if (x == 0) { exit(0); } // Determine host and USRP IP addresses so that we can classify direction of packet flow later. if (host_addr.s_addr == 0x0) get_connection_endpoints(packet_buffer,&host_addr,&usrp_addr); // Count packets in list. // Build histogram of packet sizes // Build histogram of Stream ID's packet_buffer->current = packet_buffer->start; for (x=0;x<90;x+=1) size_histogram[x][H2U] = size_histogram[x][U2H] = 0; size_average[H2U] = size_average[U2H] = 0; packet_count[H2U] = packet_count[U2H] = 0; while (packet_buffer->current != NULL) { // Overlay IP header on packet payload ip_header = (struct ip_header *)(packet_buffer->current->payload+ETH_SIZE); // Identify packet direction if (ip_header->ip_src.s_addr == host_addr.s_addr) direction = H2U; else direction = U2H; packet_count[direction]++; size_average[direction]+=(double)packet_buffer->current->size; if ((x=packet_buffer->current->size) > 9000) fprintf(stderr,"Current packet size = %d at absolute time %s, relative time %f, exceeds MTU! Skip counting.", x,format_gmt(&packet_buffer->current->ts,buffer),(relative_time(&packet_buffer->current->ts,origin_ts))); else size_histogram[x/100][direction]++; packet_buffer->current = packet_buffer->current->next; } fprintf(stdout,"\n===================================================================\n"); fprintf(stdout,"\n Average packet size Host -> USRP: %d\n",(int)(size_average[H2U]/packet_count[H2U])); fprintf(stdout,"\n Average packet size USRP -> Host: %d\n",(int)(size_average[U2H]/packet_count[U2H])); fprintf(stdout,"\n===================================================================\n\n"); // // Now produce packet by packet log // packet_buffer->current = packet_buffer->start; x = 0; while (packet_buffer->current != NULL) { x++; // Calculate time offset of this packet from start time_since_start = ((double) packet_buffer->current->ts.tv_sec * 1000000 + packet_buffer->current->ts.tv_usec - origin_ts_in_us)/1000000; dump_header = (u32 *) (packet_buffer->current->payload+ETH_SIZE+IP_SIZE+UDP_SIZE); /* fprintf(stdout,"DUMP: %08x %08x %08x %08x %08x %08x\n", */ /* swapint((int) *(dump_header)), */ /* swapint((int) *(dump_header+1)), */ /* swapint((int) *(dump_header+2)), */ /* swapint((int) *(dump_header+3)), */ /* swapint((int) *(dump_header+4)), */ /* swapint((int) *(dump_header+5))); */ // Extract the device portion of the SID to see which packet flow this belongs in fprintf(stdout,"%8d %f \t",x,time_since_start); print_direction(packet_buffer,&host_addr,&usrp_addr); fprintf(stdout,"\t"); print_size(packet_buffer); fprintf(stdout,"\t"); print_sid(packet_buffer); fprintf(stdout,"\t"); print_vita_header(packet_buffer,&host_addr); fprintf(stdout,"\n"); packet_buffer->current = packet_buffer->current->next; } // Normal Exit return(0); }