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/*
* Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include "webrtc/system_wrappers/interface/rtp_to_ntp.h"
#include "webrtc/system_wrappers/interface/clock.h"
#include <assert.h>
namespace webrtc {
RtcpMeasurement::RtcpMeasurement()
: ntp_secs(0), ntp_frac(0), rtp_timestamp(0) {}
RtcpMeasurement::RtcpMeasurement(uint32_t ntp_secs, uint32_t ntp_frac,
uint32_t timestamp)
: ntp_secs(ntp_secs), ntp_frac(ntp_frac), rtp_timestamp(timestamp) {}
// Calculates the RTP timestamp frequency from two pairs of NTP and RTP
// timestamps.
bool CalculateFrequency(
int64_t rtcp_ntp_ms1,
uint32_t rtp_timestamp1,
int64_t rtcp_ntp_ms2,
uint32_t rtp_timestamp2,
double* frequency_khz) {
if (rtcp_ntp_ms1 <= rtcp_ntp_ms2) {
return false;
}
*frequency_khz = static_cast<double>(rtp_timestamp1 - rtp_timestamp2) /
static_cast<double>(rtcp_ntp_ms1 - rtcp_ntp_ms2);
return true;
}
// Detects if there has been a wraparound between |old_timestamp| and
// |new_timestamp|, and compensates by adding 2^32 if that is the case.
bool CompensateForWrapAround(uint32_t new_timestamp,
uint32_t old_timestamp,
int64_t* compensated_timestamp) {
assert(compensated_timestamp);
int64_t wraps = CheckForWrapArounds(new_timestamp, old_timestamp);
if (wraps < 0) {
// Reordering, don't use this packet.
return false;
}
*compensated_timestamp = new_timestamp + (wraps << 32);
return true;
}
bool UpdateRtcpList(uint32_t ntp_secs,
uint32_t ntp_frac,
uint32_t rtp_timestamp,
RtcpList* rtcp_list,
bool* new_rtcp_sr) {
*new_rtcp_sr = false;
if (ntp_secs == 0 && ntp_frac == 0) {
return false;
}
RtcpMeasurement measurement;
measurement.ntp_secs = ntp_secs;
measurement.ntp_frac = ntp_frac;
measurement.rtp_timestamp = rtp_timestamp;
for (RtcpList::iterator it = rtcp_list->begin();
it != rtcp_list->end(); ++it) {
if (measurement.ntp_secs == (*it).ntp_secs &&
measurement.ntp_frac == (*it).ntp_frac) {
// This RTCP has already been added to the list.
return true;
}
}
// We need two RTCP SR reports to map between RTP and NTP. More than two will
// not improve the mapping.
if (rtcp_list->size() == 2) {
rtcp_list->pop_back();
}
rtcp_list->push_front(measurement);
*new_rtcp_sr = true;
return true;
}
// Converts |rtp_timestamp| to the NTP time base using the NTP and RTP timestamp
// pairs in |rtcp|. The converted timestamp is returned in
// |rtp_timestamp_in_ms|. This function compensates for wrap arounds in RTP
// timestamps and returns false if it can't do the conversion due to reordering.
bool RtpToNtpMs(int64_t rtp_timestamp,
const RtcpList& rtcp,
int64_t* rtp_timestamp_in_ms) {
assert(rtcp.size() == 2);
int64_t rtcp_ntp_ms_new = Clock::NtpToMs(rtcp.front().ntp_secs,
rtcp.front().ntp_frac);
int64_t rtcp_ntp_ms_old = Clock::NtpToMs(rtcp.back().ntp_secs,
rtcp.back().ntp_frac);
int64_t rtcp_timestamp_new = rtcp.front().rtp_timestamp;
int64_t rtcp_timestamp_old = rtcp.back().rtp_timestamp;
if (!CompensateForWrapAround(rtcp_timestamp_new,
rtcp_timestamp_old,
&rtcp_timestamp_new)) {
return false;
}
double freq_khz;
if (!CalculateFrequency(rtcp_ntp_ms_new,
rtcp_timestamp_new,
rtcp_ntp_ms_old,
rtcp_timestamp_old,
&freq_khz)) {
return false;
}
double offset = rtcp_timestamp_new - freq_khz * rtcp_ntp_ms_new;
int64_t rtp_timestamp_unwrapped;
if (!CompensateForWrapAround(rtp_timestamp, rtcp_timestamp_old,
&rtp_timestamp_unwrapped)) {
return false;
}
double rtp_timestamp_ntp_ms = (static_cast<double>(rtp_timestamp_unwrapped) -
offset) / freq_khz + 0.5f;
if (rtp_timestamp_ntp_ms < 0) {
return false;
}
*rtp_timestamp_in_ms = rtp_timestamp_ntp_ms;
return true;
}
int CheckForWrapArounds(uint32_t new_timestamp, uint32_t old_timestamp) {
if (new_timestamp < old_timestamp) {
// This difference should be less than -2^31 if we have had a wrap around
// (e.g. |new_timestamp| = 1, |rtcp_rtp_timestamp| = 2^32 - 1). Since it is
// cast to a int32_t, it should be positive.
if (static_cast<int32_t>(new_timestamp - old_timestamp) > 0) {
// Forward wrap around.
return 1;
}
} else if (static_cast<int32_t>(old_timestamp - new_timestamp) > 0) {
// This difference should be less than -2^31 if we have had a backward wrap
// around. Since it is cast to a int32_t, it should be positive.
return -1;
}
return 0;
}
} // namespace webrtc