FreeCalypso > hg > gsm-codec-lib
view pcap/rtp-jitter-view.c @ 183:452c1d5a6268
libgsmefr BFI w/o data: emit zero output after decoder reset
In real-life usage, each EFR decoder session will most likely begin
with lots of BFI frames before the first real frame arrives. However,
because the spec-defined home state of the decoder is speech rather
than CN, our regular logic for BFI w/o data would have to feed
pseudorandom noise to the decoder (in the "fixed codebook excitation
pulses" part), which is silly to do at the beginning of the decoder
session right out of reset. Therefore, let's check reset_flag_old,
and if we are still in the reset state, simply emit zero output.
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Tue, 03 Jan 2023 00:12:18 +0000 |
parents | 693a0958a303 |
children | 10f11a2d4042 |
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/* * This program reads a pcap file, extracts packets belonging to a * particular RTP stream as identified by a source or destination * IP:port, checks its continuity at the packet header level * (verifies that the sequence number always increments by 1 and * that the timestamp always increments by 160 units) and prints out * the Rx time delta of each stream packet (the capture time of * the current packet minus the capture time of the previous packet) * on stdout, allowing visual analysis of timing jitter. * * The codec can be anything, and this program can also be used to * examine the jitter of RTP streams coming from PSTN/SIP, but the * core assumption is that packets must arrive every 20 ms, with * the timestamp field incrementing by 160 units each time. */ #include <sys/types.h> #include <sys/socket.h> #include <sys/time.h> #include <netinet/in.h> #include <arpa/inet.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <strings.h> #include <pcap/pcap.h> static pcap_t *pcap; static in_addr_t match_ip_addr; static u_short match_udp_port; static unsigned iphdr_addr_offset, udphdr_port_offset; static unsigned link_hdr_len, ethertype_offset; static int stream_init_flag; static unsigned last_seq, last_tstamp, stream_ssrc; static struct timeval last_pkt_time; static void check_dl_type() { int dltype; dltype = pcap_datalink(pcap); switch (dltype) { case DLT_EN10MB: link_hdr_len = 14; ethertype_offset = 12; break; case DLT_RAW: link_hdr_len = 0; break; case DLT_LINUX_SLL: link_hdr_len = 16; ethertype_offset = 14; break; default: fprintf(stderr, "error: unsupported data link type %d\n", dltype); exit(1); } } static void rtp_stream_logic(rtp_hdr, pkt_idx, pkt_time) u_char *rtp_hdr; unsigned pkt_idx; struct timeval *pkt_time; { unsigned cur_seq, cur_tstamp, cur_ssrc; struct timeval deltat; cur_seq = (rtp_hdr[2] << 8) | rtp_hdr[3]; cur_tstamp = (rtp_hdr[4] << 24) | (rtp_hdr[5] << 16) | (rtp_hdr[6] << 8) | rtp_hdr[7]; cur_ssrc = (rtp_hdr[8] << 24) | (rtp_hdr[9] << 16) | (rtp_hdr[10] << 8) | rtp_hdr[11]; if (stream_init_flag) { if (cur_ssrc != stream_ssrc) { fprintf(stderr, "error in packet #%u: SSRC change from 0x%08X to 0x%08X\n", pkt_idx, stream_ssrc, cur_ssrc); exit(1); } if (cur_seq != last_seq + 1) { fprintf(stderr, "error in packet #%u: seq break from 0x%04X to 0x%04X\n", pkt_idx, last_seq, cur_seq); exit(1); } if (cur_tstamp != last_tstamp + 160) { fprintf(stderr, "error in packet #%u: timestamp break from 0x%08X to 0x%08X\n", pkt_idx, last_tstamp, cur_tstamp); exit(1); } if (timercmp(pkt_time, &last_pkt_time, <)) { fprintf(stderr, "packet #%u timing error: Rx time goes backward\n", pkt_idx); exit(1); } timersub(pkt_time, &last_pkt_time, &deltat); if (deltat.tv_sec) { fprintf(stderr, "packet #%u timing error: Rx time gap >= 1 s\n", pkt_idx); exit(1); } printf("Packet #%u: time delta %u us\n", pkt_idx, (unsigned) deltat.tv_usec); } else { stream_init_flag = 1; stream_ssrc = cur_ssrc; } last_seq = cur_seq; last_tstamp = cur_tstamp; bcopy(pkt_time, &last_pkt_time, sizeof(struct timeval)); } static void process_packet(pkt, caplen, pkt_idx, pkt_time) u_char *pkt; unsigned caplen, pkt_idx; struct timeval *pkt_time; { unsigned udplen; if (caplen < link_hdr_len + 28) return; if (link_hdr_len) { if (pkt[ethertype_offset] != 0x08) return; if (pkt[ethertype_offset+1] != 0x00) return; pkt += link_hdr_len; caplen -= link_hdr_len; } /* check IP header */ if (pkt[0] != 0x45) return; if (pkt[9] != 17) /* UDP */ return; if (bcmp(pkt + iphdr_addr_offset, &match_ip_addr, 4)) return; /* check UDP header */ if (bcmp(pkt + 20 + udphdr_port_offset, &match_udp_port, 2)) return; /* it is our target - now scrutinize it */ udplen = (pkt[24] << 8) | pkt[25]; if (caplen < udplen + 20) { fprintf(stderr, "error: packet #%u is truncated in the capture\n", pkt_idx); exit(1); } if (udplen < 20) { fprintf(stderr, "error in packet #%u: UDP length is too short for RTP header\n", pkt_idx); exit(1); } if (pkt[28] != 0x80) { fprintf(stderr, "error in packet #%u: unsupported RTP header structure\n", pkt_idx); exit(1); } rtp_stream_logic(pkt + 28, pkt_idx, pkt_time); } main(argc, argv) char **argv; { char errbuf[PCAP_ERRBUF_SIZE]; u_char *pkt; struct pcap_pkthdr pkthdr; unsigned pkt_idx; if (argc != 5) { fprintf(stderr, "usage: %s pcap-file src|dest ip-addr udp-port\n", argv[0]); exit(1); } pcap = pcap_open_offline(argv[1], errbuf); if (!pcap) { fprintf(stderr, "%s: %s\n", argv[1], errbuf); exit(1); } check_dl_type(); if (!strcmp(argv[2], "src")) { iphdr_addr_offset = 12; udphdr_port_offset = 0; } else if (!strcmp(argv[2], "dest")) { iphdr_addr_offset = 16; udphdr_port_offset = 2; } else { fprintf(stderr, "error: direction argument must be \"src\" or \"dest\"\n"); exit(1); } match_ip_addr = inet_addr(argv[3]); if (match_ip_addr == INADDR_NONE) { fprintf(stderr, "error: IP address argument is invalid\n"); exit(1); } match_udp_port = htons(strtoul(argv[4], 0, 0)); for (pkt_idx = 0; ; pkt_idx++) { pkt = pcap_next(pcap, &pkthdr); if (!pkt) break; process_packet(pkt, (unsigned) pkthdr.caplen, pkt_idx, &pkthdr.ts); } if (!stream_init_flag) { fprintf(stderr, "error: specified RTP stream not found\n"); exit(1); } exit(0); }