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pcapreport.c
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pcapreport.c
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/*
* Report on a pcap (.pcap) file.
*
* <rrw@kynesim.co.uk> 2008-09-05
*
* ***** BEGIN LICENSE BLOCK *****
* Version: MPL 1.1
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
* http://www.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is the MPEG TS, PS and ES tools.
*
* The Initial Developer of the Original Code is Amino Communications Ltd.
* Portions created by the Initial Developer are Copyright (C) 2008
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
* Richard Watts, Kynesim <rrw@kynesim.co.uk>
*
* ***** END LICENSE BLOCK *****
*/
#include <stdio.h>
#include <stdlib.h>
#include <limits.h>
#include <errno.h>
#include <string.h>
#include <fcntl.h>
#include <limits.h>
#include <time.h>
#ifdef _WIN32
#include <stddef.h>
#else // _WIN32
#include <unistd.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#endif // _WIN32
#include "compat.h"
#include "pcap.h"
#include "ethernet.h"
#include "ipv4.h"
#include "version.h"
#include "misc_fns.h"
#include "ts_fns.h"
#include "fmtx.h"
typedef struct pcapreport_stream_struct pcapreport_stream_t;
#define JITTER_BUF_SIZE 1024
typedef struct jitter_el_struct {
uint32_t t;
int delta;
} jitter_el_t;
typedef struct jitter_env_struct {
int min_val;
int max_val;
int in_n;
int out_n;
int len;
jitter_el_t buf[JITTER_BUF_SIZE];
} jitter_env_t;
typedef struct pcapreport_section_struct pcapreport_section_t;
struct pcapreport_section_struct {
pcapreport_section_t * next;
unsigned int section_no;
unsigned int pcr_count;
unsigned int jitter_max;
uint32_t pkt_start;
uint32_t pkt_final;
uint64_t time_start; // 90kHz
uint64_t time_first; // time @ first PCR
uint64_t time_last; // time @ last PCR
uint64_t time_final;
uint64_t pcr_start; // 90kHz
uint64_t pcr_last;
int64_t skew_last;
int64_t skew_min;
int64_t skew_max;
uint64_t ts_byte_start;
uint64_t ts_byte_final;
int32_t rtp_skew_min;
int32_t rtp_skew_max;
};
typedef struct pcapreport_vlan_info_s
{
uint16_t vid;
uint16_t cfimap;
uint16_t pcpmap;
} pcapreport_vlan_info_t;
typedef struct pcapreport_rtp_info_s
{
uint16_t last_seq;
uint32_t n;
uint32_t ssrc;
int multiple_ssrc;
} pcapreport_rtp_info_t;
// RTP info (if any) in a packet
typedef struct rtp_header_s
{
int is_rtp_ts;
int is_rtp_raw;
int marker;
uint8_t payload_type;
uint16_t sequence_number;
uint32_t timestamp;
uint32_t ssrc;
uint32_t header_len;
uint32_t pad_len;
// CSRC ignored
// Extension ignored
} rtp_header_t;
struct pcapreport_stream_struct {
pcapreport_stream_t * hash_next;
const char *output_name;
FILE *output_file;
uint32_t output_dest_addr;
uint32_t output_dest_port;
FILE * csv_file;
const char * csv_name;
int stream_no;
int force; // We have an explicit filter - try harder
int ts_good; // Not a boolean -ve is bad, +ve is good
int seen_good; // Includes those seen_dodgy
int seen_bad;
int seen_dodgy; // Count of packets that we aren't completely happy with but have declared good
int multiple_pcr_pids;
TS_reader_p ts_r;
uint32_t pcr_pid;
// The temporary read buffer used by our ts reader.
byte *tmp_buf;
uint32_t tmp_len;
// ts packet counter for error reporting.
uint32_t ts_counter;
// Count overlength packets
uint32_t pkts_overlength;
/*! How far do we need to skew (in 90kHz units) to signal a discontinuity? */
int64_t skew_discontinuity_threshold;
int64_t last_time_offset;
uint64_t ts_bytes;
pcapreport_section_t * section_first;
pcapreport_section_t * section_last;
int vlan_count;
pcapreport_vlan_info_t vlans[ETHERNET_VLANS_MAX];
pcapreport_rtp_info_t rtp_info;
jitter_env_t jitter;
};
typedef struct pcapreport_fragment_struct
{
int in_use;
uint16_t ident;
uint16_t current_len;
byte pkt[65536];
} pcapreport_fragment_t;
typedef struct pcapreport_reassembly_struct
{
pcapreport_fragment_t frag;
} pcapreport_reassembly_t;
typedef struct pcapreport_ctx_struct
{
int use_stdin;
char *input_name;
const char * base_name;
int had_input_name;
int extract_data;
int dump_data;
int dump_extra;
int time_report;
int verbose;
int analyse;
int extract;
int stream_count;
int csv_gen;
int good_ts_only; // Only keep good pkts
int keep_bad; // Keep all packets (inc bad)
int file_split_section;
PCAP_reader_p pcreader;
pcap_hdr_t pcap_hdr;
unsigned int tfmt;
// packet counter.
uint32_t pkt_counter;
uint32_t filter_dest_addr;
uint32_t filter_dest_port;
const char * output_name_base;
int64_t opt_skew_discontinuity_threshold;
uint64_t time_start; // 90kHz
uint32_t time_usec;
time_t time_sec;
uint8_t rtp_raw_wanted[256];
pcapreport_stream_t * stream_hash[256];
pcapreport_reassembly_t reassembly_env;
} pcapreport_ctx_t;
static unsigned int
jitter_value(const jitter_env_t * const je)
{
return je->max_val - je->min_val;
}
static unsigned int
jitter_add(jitter_env_t * const je, const int delta, const uint32_t time, const uint32_t range)
{
jitter_el_t * const eob = je->buf + JITTER_BUF_SIZE;
jitter_el_t * const in_el = je->buf + je->in_n;
jitter_el_t * out_el = je->buf + je->out_n;
jitter_el_t * const next_el = (je->in_n == JITTER_BUF_SIZE - 1) ? je->buf : in_el + 1;
int needs_scan = FALSE;
// 1st expire anything we no longer want - in any case expire one if
// we are about to overflow.
while (in_el != out_el && (time - out_el->t > range || out_el == next_el))
{
if (out_el->delta == je->min_val || out_el->delta == je->max_val)
needs_scan = TRUE;
// Inc with wrap
if (++out_el >= eob)
out_el = je->buf;
}
if (needs_scan || in_el == out_el)
{
// Only recalc max & min for the buffer if we have expired a previous one
// also if empty then must force both to delta which this code will do
const jitter_el_t * el = out_el;
int min_val = delta;
int max_val = delta;
while (el != in_el)
{
if (el->delta > max_val)
max_val = el->delta;
if (el->delta < min_val)
min_val = el->delta;
if (++el >= eob)
el = je->buf;
}
je->max_val = max_val;
je->min_val = min_val;
}
else
{
// Otherwise check to see if this is a new max/min based on old values
if (delta > je->max_val)
je->max_val = delta;
if (delta < je->min_val)
je->min_val = delta;
}
// Now add to the end
in_el->t = time;
in_el->delta = delta;
// and update the environment
je->in_n = next_el - je->buf;
je->out_n = out_el - je->buf;
return jitter_value(je);
}
static void
jitter_clear(jitter_env_t * const je)
{
je->in_n = 0;
je->out_n = 0;
je->max_val = 0;
je->min_val = 0;
}
static uint64_t
pkt_time(const pcaprec_hdr_t * const pcap_pkt_hdr)
{
return (((int64_t)pcap_pkt_hdr->ts_usec*9)/100) +
((int64_t)pcap_pkt_hdr->ts_sec * 90000);
}
static char *
vlan_name(const char * prefix, const pcapreport_stream_t * const st, const size_t blen, char * const buf)
{
if (st->vlan_count == 0)
{
buf[0] = '\0';
}
else
{
int i;
size_t n = strlen(prefix);
char * p = buf;
char * const eob = buf + blen;
memcpy(p, prefix, n);
p += n;
for (i = 0; i < st->vlan_count && eob - p > 2; ++i)
{
const pcapreport_vlan_info_t * const vi = st->vlans + i;
if (i != 0)
*p++ = '.';
p += snprintf(p, eob - p, "%d", vi->vid);
}
}
return buf;
}
static char *
section_name(const pcapreport_ctx_t * const ctx, const pcapreport_stream_t * const st, char * const pbuf, const size_t pbuf_len)
{
if (!ctx->file_split_section)
{
*pbuf = '\0';
return pbuf;
}
snprintf(pbuf, pbuf_len, "_S%d", st->section_last == NULL ? 0 : st->section_last->section_no);
return pbuf;
}
static void
stream_gen_names2(const pcapreport_ctx_t * const ctx, pcapreport_stream_t * const st,
const rtp_header_t * const rtp_header)
{
const uint32_t dest_addr = st->output_dest_addr;
const uint32_t dest_port = st->output_dest_port;
char pbuf[32], pbuf2[32];
char identifier[64];
const char * const base_name = ctx->output_name_base != NULL ? ctx->output_name_base : ctx->base_name;
const size_t base_len = strlen(base_name);
int fixed_extract_name = FALSE;
if (ctx->filter_dest_addr == 0 || ctx->filter_dest_port == 0)
{
snprintf(identifier, 64, "%s_%u.%u.%u.%u_%u%s",
vlan_name("_V", st, sizeof(pbuf), pbuf),
dest_addr >> 24, (dest_addr >> 16) & 0xff,
(dest_addr >> 8) & 0xff, dest_addr & 0xff,
dest_port,
section_name(ctx, st, pbuf2, sizeof(pbuf2)));
}
else
{
identifier[0] = '\0';
// If we have been given a unique filter and a name then assume they
// actually want that name!
fixed_extract_name = (ctx->output_name_base != NULL);
}
if (ctx->extract)
{
char * name = malloc(base_len + 64);
memcpy(name, base_name, base_len + 1);
if (!fixed_extract_name)
snprintf(name + base_len, 64, "%s.%s", identifier,
(rtp_header != NULL && rtp_header->is_rtp_raw) ? "rtp" : "ts");
st->output_name = name;
}
if (ctx->csv_gen)
{
char * name = malloc(base_len + 64);
memcpy(name, ctx->base_name, base_len);
snprintf(name + base_len, 64, "%s.csv", identifier);
st->csv_name = name;
}
}
static void
stream_gen_names(const pcapreport_ctx_t * const ctx, pcapreport_stream_t * const st,
const rtp_header_t * const rtp_header)
{
// Only bother if there is some reason
if (ctx->extract || ctx->csv_gen)
stream_gen_names2(ctx, st, rtp_header);
}
static void
stream_close_files(const pcapreport_ctx_t * const ctx, pcapreport_stream_t * const st)
{
if (st->output_file != NULL)
{
if (st->seen_dodgy != 0)
{
fprint_msg(">%d> WARNING: %d dodgy packet%s written to: %s\n",
st->stream_no,
st->seen_dodgy, st->seen_dodgy == 1 ? "" : "s", st->output_name);
}
if (st->seen_bad != 0)
{
fprint_msg(">%d> WARNING: %d bad packet%s excluded from: %s\n",
st->stream_no,
st->seen_bad, st->seen_bad == 1 ? "" : "s", st->output_name);
}
fclose(st->output_file);
st->output_file = NULL;
}
if (st->csv_file != NULL)
{
fclose(st->csv_file);
st->csv_file = NULL;
}
}
static pcapreport_section_t *
section_create(const pcapreport_ctx_t * const ctx, pcapreport_stream_t * const st, const pcaprec_hdr_t * const pcap_pkt_hdr)
{
pcapreport_section_t * const tsect = calloc(1, sizeof(*tsect));
pcapreport_section_t * const last = st->section_last;
if (ctx->file_split_section)
stream_close_files(ctx, st);
if (tsect == NULL)
return NULL;
// Bind into stream
if (last == NULL)
{
// Empty chain - add as first el
st->section_first = tsect;
}
else
{
// Add to end
tsect->section_no = last->section_no + 1;
last->next = tsect;
}
st->section_last = tsect;
// Init "obvious" non-zero stuff
tsect->rtp_skew_max = -0x7fffffff;
tsect->rtp_skew_min = 0x7fffffff;
tsect->skew_max = -0x7fffffff;
tsect->skew_min = 0x7fffffff;
tsect->time_final =
tsect->time_start = pkt_time(pcap_pkt_hdr);
tsect->pkt_final =
tsect->pkt_start = ctx->pkt_counter;
tsect->ts_byte_start =
tsect->ts_byte_final = st->ts_bytes;
if (ctx->file_split_section || last == NULL)
stream_gen_names(ctx, st, NULL);
return tsect;
}
// Discontinuity threshold is 6s.
#define SKEW_DISCONTINUITY_THRESHOLD (6*90000)
static int digest_times_read(void *handle, byte *out_buf, size_t len)
{
pcapreport_stream_t * const st = handle;
int nr_bytes = (len < st->tmp_len ? len : st->tmp_len);
int new_tmp_len = st->tmp_len - nr_bytes;
memcpy(out_buf, st->tmp_buf, nr_bytes);
memmove(st->tmp_buf, &st->tmp_buf[nr_bytes],
new_tmp_len);
st->tmp_len = new_tmp_len;
// fprint_msg(">> read %d bytes from intermediate buffer. \n", nr_bytes);
return nr_bytes;
}
static int digest_times_seek(void *handle, offset_t val)
{
// Cannot seek in a ts stream.
return 1;
}
// 33 bit comparison
static int64_t
pts_diff(const uint64_t a, const uint64_t b)
{
return ((int64_t)(a - b) << 31) >> 31;
}
static int64_t
pts_diff_abs(const uint64_t a, const uint64_t b)
{
const int64_t t = pts_diff(a, b);
return t < 0 ? -t : t;
}
static int digest_times(pcapreport_ctx_t * const ctx,
pcapreport_stream_t * const st,
const pcaprec_hdr_t * const pcap_pkt_hdr,
const ethernet_packet_t * const epkt,
const ipv4_header_t * const ipv4_header,
const ipv4_udp_header_t * const udp_header,
const rtp_header_t * const rtp_header,
const byte * const data,
const uint32_t len)
{
int rv;
unsigned int rtp_seq_delta = 0;
// Deal with RTP contents - currently held with stream but could be moved to section
// especially if we do more timestamp analysis
if (rtp_header->is_rtp_ts)
{
pcapreport_rtp_info_t * const ri = &st->rtp_info;
if (ri->ssrc != rtp_header->ssrc && ri->n != 0 && !ri->multiple_ssrc)
{
fprint_msg("!%d! Multiple SSRCs detected: SSRCs: %u,%u,...\n", st->stream_no,
ri->ssrc, rtp_header->ssrc);
ri->multiple_ssrc = TRUE;
}
rtp_seq_delta = ri->n == 0 ? 0 :
(rtp_header->sequence_number - (ri->last_seq + 1)) & 0xffffU;
if (rtp_seq_delta != 0)
{
fprint_msg("!%d! @%u: RTP seq delta (%u->%u) != 1\n", st->stream_no, ctx->pkt_counter,
ri->last_seq, rtp_header->sequence_number);
}
++ri->n;
ri->ssrc = rtp_header->ssrc;
ri->last_seq = rtp_header->sequence_number;
}
if (st->ts_r == NULL)
{
rv = build_TS_reader_with_fns(st,
digest_times_read,
digest_times_seek,
&st->ts_r);
if (rv)
{
print_err( "### pcapreport: Cannot create ts reader.\n");
return 1;
}
}
// Add all our data to the pool.
{
unsigned int pkts = len / TS_PACKET_SIZE;
unsigned int pktlen = pkts * TS_PACKET_SIZE;
if (pktlen != len)
++st->pkts_overlength;
st->tmp_buf = (byte *)realloc(st->tmp_buf, st->tmp_len + pktlen);
memcpy(&st->tmp_buf[st->tmp_len], data, pktlen);
st->tmp_len += pktlen;
}
// Now read out all the ts packets we can.
while (1)
{
byte *pkt;
int rv;
rv = read_next_TS_packet(st->ts_r, &pkt);
if (rv == EOF)
{
// Got to EOF - return for more data
return 0;
}
// Right. Split it ..
{
const uint64_t t_pcr = pkt_time(pcap_pkt_hdr);
uint32_t pid;
int pusi;
byte *adapt;
int adapt_len;
byte *payload;
int payload_len;
rv = split_TS_packet(pkt, &pid, &pusi, &adapt, &adapt_len,
&payload, &payload_len);
if (rv)
{
fprint_msg(">%d> WARNING: TS packet %d [ packet %d @ %d.%d s ] cannot be split.\n",
st->stream_no,
st->ts_counter, ctx->pkt_counter,
pcap_pkt_hdr->ts_sec, pcap_pkt_hdr->ts_usec);
}
else
{
//int cc;
// PCR ?
if (adapt && adapt_len)
{
int has_pcr;
uint64_t pcr;
int64_t pcr_time_offset;
get_PCR_from_adaptation_field(adapt, adapt_len, &has_pcr,
&pcr);
if (has_pcr)
{
int64_t skew;
if (ctx->time_report)
{
fprint_msg(">%d> Found PCR %lld at %d.%d s \n", st->stream_no,
pcr, pcap_pkt_hdr->ts_sec, pcap_pkt_hdr->ts_usec);
}
if (st->pcr_pid == 0)
st->pcr_pid = pid;
if (pid != st->pcr_pid)
{
// *** If this happens often then fix to track each Pid
if (!st->multiple_pcr_pids)
{
fprint_msg("!%d! Multiple PCR pids detected: pids: %d,%d,...\n",
st->stream_no, st->pcr_pid, pid);
}
st->multiple_pcr_pids = TRUE;
}
else
{
pcapreport_section_t * tsect = st->section_last;
unsigned int cur_jitter;
// PCR pops out in 27MHz units. Let's do all our comparisons
// in 90kHz.
pcr /= 300;
// fprint_msg("pcr = %lld t_pcr = %lld diff = %lld\n",
// pcr, t_pcr, t_pcr - pcr);
pcr_time_offset = pts_diff(t_pcr, pcr);
skew = tsect->pcr_count == 0 ? 0LL :
pcr_time_offset - pts_diff(tsect->time_first, tsect->pcr_start);
// Change section if discontinuity too big
if (st->skew_discontinuity_threshold > 0 && tsect->pcr_count != 0)
{
const int64_t pcr_delta = pts_diff_abs(pcr, tsect->pcr_last);
const int64_t time_delta = pts_diff_abs(t_pcr, tsect->time_last);
const int64_t skew_delta = skew - tsect->skew_last;
if (pcr_delta > st->skew_discontinuity_threshold ||
time_delta > st->skew_discontinuity_threshold ||
skew_delta > st->skew_discontinuity_threshold)
{
section_create(ctx, st, pcap_pkt_hdr);
tsect = st->section_last;
}
}
if (tsect->pcr_count == 0)
{
if (tsect->section_no != 0)
{
fprint_msg(">%d> Skew discontinuity! Skew = %lld (> %lld) at"
" ts = %d network = %d (PCR %lld Time %d.%d)\n",
st->stream_no,
skew, st->skew_discontinuity_threshold,
st->ts_counter, ctx->pkt_counter,
pcr, pcap_pkt_hdr->ts_sec,
pcap_pkt_hdr->ts_usec);
}
tsect->pkt_final = ctx->pkt_counter;
tsect->pcr_last =
tsect->pcr_start = pcr;
tsect->time_last =
tsect->time_first = t_pcr;
jitter_clear(&st->jitter);
skew = 0;
st->last_time_offset = 0;
}
// Extract jitter over up to the last 10s. skew will be within
// an int by now
cur_jitter = jitter_add(&st->jitter, (int)skew,
(uint32_t)(t_pcr & 0xffffffffU), 90000 * 10);
if (tsect->skew_max < skew)
tsect->skew_max = skew;
if (tsect->skew_min > skew)
tsect->skew_min = skew;
if (tsect->jitter_max < cur_jitter)
tsect->jitter_max = cur_jitter;
if (rtp_header->is_rtp_ts)
{
// We have both PCR & RTP times - look for min & max
int32_t rtp_skew = (int32_t)(rtp_header->timestamp - (uint32_t)(t_pcr & 0xffffffffU));
if (tsect->rtp_skew_max < rtp_skew)
tsect->rtp_skew_max = rtp_skew;
if (tsect->rtp_skew_min > rtp_skew)
tsect->rtp_skew_min = rtp_skew;
}
if (ctx->time_report)
{
int64_t rel_tim = t_pcr - tsect->time_first; // 90kHz
double skew_rate = (rel_tim == 0) ? 0.0 :
(double)skew / ((double)((double)rel_tim / (60*90000)));
fprint_msg(">%d> [ts %d net %d ] PCR %lld Time %d.%d [rel %d.%d] - skew = %lld (delta = %lld, rate = %.4g PTS/min) - jitter=%u\n",
st->stream_no,
st->ts_counter, ctx->pkt_counter,
pcr,
pcap_pkt_hdr->ts_sec, pcap_pkt_hdr->ts_usec,
(int)(rel_tim / (int64_t)1000000),
(int)rel_tim%1000000,
skew, pcr_time_offset - st->last_time_offset,
skew_rate, cur_jitter);
}
if (st->csv_name != NULL) // We should be outputting to file
{
if (st->csv_file == NULL)
{
if ((st->csv_file = fopen(st->csv_name, "wt")) == NULL)
{
fprint_err("### pcapreport: Cannot open %s .\n",
st->csv_name);
exit(1);
}
fprintf(st->csv_file, "\"PKT\",\"Time\",\"PCR\",\"Skew\",\"Jitter\"\n");
}
fprintf(st->csv_file, "%d," LLU_FORMAT "," LLU_FORMAT "," LLD_FORMAT ",%u\n", ctx->pkt_counter,
t_pcr - ctx->time_start, pcr, skew, cur_jitter);
}
// Remember where we are for posterity
tsect->pcr_last = pcr;
tsect->time_last = t_pcr;
tsect->skew_last = skew;
st->last_time_offset = pcr_time_offset;
++tsect->pcr_count;
}
}
}
}
// Actions at end of TS packet
++st->ts_counter;
st->ts_bytes += TS_PACKET_SIZE;
{
pcapreport_section_t * const tsect = st->section_last;
if (tsect != NULL)
{
tsect->time_final = t_pcr;
tsect->ts_byte_final = st->ts_bytes;
tsect->pkt_final = ctx->pkt_counter;
}
}
}
}
}
static int write_out_packet(pcapreport_ctx_t * const ctx,
pcapreport_stream_t * const st,
const byte *data,
const uint32_t len)
{
int rv;
unsigned int pkts = len / 188;
if (st->output_name)
{
if (st->output_file == NULL)
{
fprint_msg("pcapreport: Dumping %s packets for %s:%d to %s\n",
ctx->good_ts_only ? "good ts" : ctx->keep_bad ? "all" : "ts",
ipv4_addr_to_string(st->output_dest_addr),
st->output_dest_port,
st->output_name);
st->output_file = fopen(st->output_name, "wb");
if (!st->output_file)
{
fprint_err("### pcapreport: Cannot open %s .\n",
st->output_name);
return 1;
}
}
if (ctx->verbose)
{
fprint_msg("++ Dumping %d bytes to output file.\n", len);
}
rv = fwrite(data, 188, pkts, st->output_file);
if (rv != pkts)
{
fprint_err( "### pcapreport: Couldn't write %d bytes"
" to %s (error = %d).\n",
len, st->output_name,
ferror(st->output_file));
return 1;
}
}
return 0;
}
static int
stream_ts_check(const pcapreport_ctx_t * const ctx, pcapreport_stream_t * const st,
const byte * const data,
const uint32_t len)
{
const byte * ptr;
int good = 0;
int bad = 0;
if (st->force)
st->ts_good = 10;
if (len % 188 != 0)
++bad;
else
++good;
for (ptr = data; ptr < data + len; ptr += 188)
{
if (*ptr != 0x47)
++bad;
else
++good;
}
st->ts_good += good - bad;
if (st->ts_good > 10)
st->ts_good = 10;
if (st->ts_good < -10)
st->ts_good = -10;
if (st->ts_good <= 0 || (bad != 0 && ctx->good_ts_only))
{
++st->seen_bad;
return FALSE;
}
if (bad != 0)
++st->seen_dodgy;
++st->seen_good;
return TRUE;
}
// RTP - RFC 3550
// RTP payload types - RFC 3551
// M2TS - RFC 2250
static int write_rtp_raw_packet(pcapreport_ctx_t * const ctx,
pcapreport_stream_t * const st,
const byte *data,
const uint32_t len)
{
if (st->output_name)
{
int rv;
if (st->output_file == NULL)
{
fprint_msg("pcapreport: Dumping raw RTP packets for %s:%d to %s\n",
ipv4_addr_to_string(st->output_dest_addr),
st->output_dest_port,
st->output_name);
st->output_file = fopen(st->output_name, "wb");
if (!st->output_file)
{
fprint_err("### pcapreport: Cannot open %s .\n",
st->output_name);
return 1;
}
}
if (ctx->verbose)
{
fprint_msg("++ Dumping %d bytes to output file.\n", len);
}
// need header
{
byte hdr[8];
hdr[0] = 'R';
hdr[1] = 'T';
hdr[2] = 'P';
hdr[3] = ' ';
hdr[4] = (len >> 24) & 0xff;
hdr[5] = (len >> 16) & 0xff;
hdr[6] = (len >> 8) & 0xff;
hdr[7] = len & 0xff;
rv = fwrite(hdr, sizeof(hdr), 1, st->output_file);
if (rv != 1)
{
fprint_err( "### pcapreport: Couldn't write RTP hdr bytes"
" to %s (error = %d).\n",
st->output_name,
ferror(st->output_file));
return 1;
}
}
rv = fwrite(data, 1, len, st->output_file);
if (rv != len)
{
fprint_err( "### pcapreport: Couldn't write %d bytes"
" to %s (error = %d).\n",
len, st->output_name,
ferror(st->output_file));
return 1;
}
}
return 0;
}
static int
stream_rtp_check(const pcapreport_ctx_t * const ctx, pcapreport_stream_t * const st,
const byte * const data,
const uint32_t len,
rtp_header_t * const rh)
{
uint32_t offset;
uint32_t padlen = 0;
unsigned int payload_type;
int is_raw = FALSE;
// Flatten output
memset(rh, 0, sizeof(*rh));
// Must contain at least the header!
if (len < 12)
return FALSE;
// Check version - must be 2
// Incidentally this will reject 0x47 which is good :-)
if ((data[0] & 0xc0) != 0x80)
return FALSE;
// We only deal with TS in RTP so check for that alone