/* * Copyright (c) 2017 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. */ #ifndef API_RTP_HEADERS_H_ #define API_RTP_HEADERS_H_ #include #include #include #include "absl/types/optional.h" #include "api/array_view.h" #include "api/units/timestamp.h" #include "api/video/color_space.h" #include "api/video/video_content_type.h" #include "api/video/video_rotation.h" #include "api/video/video_timing.h" namespace webrtc { struct FeedbackRequest { // Determines whether the recv delta as specified in // https://tools.ietf.org/html/draft-holmer-rmcat-transport-wide-cc-extensions-01 // should be included. bool include_timestamps; // Include feedback of received packets in the range [sequence_number - // sequence_count + 1, sequence_number]. That is, no feedback will be sent if // sequence_count is zero. int sequence_count; }; // The Absolute Capture Time extension is used to stamp RTP packets with a NTP // timestamp showing when the first audio or video frame in a packet was // originally captured. The intent of this extension is to provide a way to // accomplish audio-to-video synchronization when RTCP-terminating intermediate // systems (e.g. mixers) are involved. See: // http://www.webrtc.org/experiments/rtp-hdrext/abs-capture-time struct AbsoluteCaptureTime { // Absolute capture timestamp is the NTP timestamp of when the first frame in // a packet was originally captured. This timestamp MUST be based on the same // clock as the clock used to generate NTP timestamps for RTCP sender reports // on the capture system. // // It’s not always possible to do an NTP clock readout at the exact moment of // when a media frame is captured. A capture system MAY postpone the readout // until a more convenient time. A capture system SHOULD have known delays // (e.g. from hardware buffers) subtracted from the readout to make the final // timestamp as close to the actual capture time as possible. // // This field is encoded as a 64-bit unsigned fixed-point number with the high // 32 bits for the timestamp in seconds and low 32 bits for the fractional // part. This is also known as the UQ32.32 format and is what the RTP // specification defines as the canonical format to represent NTP timestamps. uint64_t absolute_capture_timestamp; // Estimated capture clock offset is the sender’s estimate of the offset // between its own NTP clock and the capture system’s NTP clock. The sender is // here defined as the system that owns the NTP clock used to generate the NTP // timestamps for the RTCP sender reports on this stream. The sender system is // typically either the capture system or a mixer. // // This field is encoded as a 64-bit two’s complement signed fixed-point // number with the high 32 bits for the seconds and low 32 bits for the // fractional part. It’s intended to make it easy for a receiver, that knows // how to estimate the sender system’s NTP clock, to also estimate the capture // system’s NTP clock: // // Capture NTP Clock = Sender NTP Clock + Capture Clock Offset absl::optional estimated_capture_clock_offset; }; inline bool operator==(const AbsoluteCaptureTime& lhs, const AbsoluteCaptureTime& rhs) { return (lhs.absolute_capture_timestamp == rhs.absolute_capture_timestamp) && (lhs.estimated_capture_clock_offset == rhs.estimated_capture_clock_offset); } inline bool operator!=(const AbsoluteCaptureTime& lhs, const AbsoluteCaptureTime& rhs) { return !(lhs == rhs); } struct RTPHeaderExtension { RTPHeaderExtension(); RTPHeaderExtension(const RTPHeaderExtension& other); RTPHeaderExtension& operator=(const RTPHeaderExtension& other); static constexpr int kAbsSendTimeFraction = 18; Timestamp GetAbsoluteSendTimestamp() const { RTC_DCHECK(hasAbsoluteSendTime); RTC_DCHECK(absoluteSendTime < (1ul << 24)); return Timestamp::Micros((absoluteSendTime * 1000000ll) / (1 << kAbsSendTimeFraction)); } bool hasTransmissionTimeOffset; int32_t transmissionTimeOffset; bool hasAbsoluteSendTime; uint32_t absoluteSendTime; absl::optional absolute_capture_time; bool hasTransportSequenceNumber; uint16_t transportSequenceNumber; absl::optional feedback_request; // Audio Level includes both level in dBov and voiced/unvoiced bit. See: // https://tools.ietf.org/html/rfc6464#section-3 bool hasAudioLevel; bool voiceActivity; uint8_t audioLevel; // For Coordination of Video Orientation. See // http://www.etsi.org/deliver/etsi_ts/126100_126199/126114/12.07.00_60/ // ts_126114v120700p.pdf bool hasVideoRotation; VideoRotation videoRotation; // TODO(ilnik): Refactor this and one above to be absl::optional() and remove // a corresponding bool flag. bool hasVideoContentType; VideoContentType videoContentType; bool has_video_timing; VideoSendTiming video_timing; VideoPlayoutDelay playout_delay; // For identification of a stream when ssrc is not signaled. See // https://tools.ietf.org/html/rfc8852 std::string stream_id; std::string repaired_stream_id; // For identifying the media section used to interpret this RTP packet. See // https://tools.ietf.org/html/rfc8843 std::string mid; absl::optional color_space; }; enum { kRtpCsrcSize = 15 }; // RFC 3550 page 13 struct RTPHeader { RTPHeader(); RTPHeader(const RTPHeader& other); RTPHeader& operator=(const RTPHeader& other); bool markerBit; uint8_t payloadType; uint16_t sequenceNumber; uint32_t timestamp; uint32_t ssrc; uint8_t numCSRCs; uint32_t arrOfCSRCs[kRtpCsrcSize]; size_t paddingLength; size_t headerLength; int payload_type_frequency; RTPHeaderExtension extension; }; // RTCP mode to use. Compound mode is described by RFC 4585 and reduced-size // RTCP mode is described by RFC 5506. enum class RtcpMode { kOff, kCompound, kReducedSize }; enum NetworkState { kNetworkUp, kNetworkDown, }; } // namespace webrtc #endif // API_RTP_HEADERS_H_