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328 lines
17 KiB
Markdown
328 lines
17 KiB
Markdown
# Moonfire NVR Time Handling
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Status: **current**
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> A man with a watch knows what time it is. A man with two watches is never
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> sure.
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>
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> — Segal's law
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## Objective
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Maximize the likelihood Moonfire NVR's timestamps are useful.
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The timestamp corresponding to a video frame should roughly match timestamps
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from other sources:
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* another video stream from the same camera. Given a video frame from the
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"main" stream, a video frame from the "sub" stream with a similar
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timestamp should have been recorded near the same time, and vice versa.
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This minimizes confusion when switching between views of these streams,
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and when viewing the "main" stream timestamps corresponding to a motion
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event gathered from the less CPU-intensive "sub" stream.
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* on-camera motion events from the same camera. If the video frame reflects
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the motion event, its timestamp should be roughly within the event's
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timespan.
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* streams from other cameras. Recorded views from two cameras of the same
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event should have similar timestamps.
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* events noted by the owner of the system, neighbors, police, etc., for the
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purpose of determining chronology, to the extent those persons use
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accurate clocks.
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Two segments of video recorded from the same stream of the same camera should
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not overlap. This would make it impossible for a user interface to present a
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simple timeline for accessing all recorded video.
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Durations should be useful over short timescales:
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* If an object's motion is recorded, distance travelled divided by the
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duration of the frames over which this motion occurred should reflect the
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object's average speed.
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* Motion should appear smooth. There shouldn't be excessive frame-to-frame
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jitter due to such factors as differences in encoding time or network
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transmission.
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This document describes an approach to achieving these goals when the
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following statements are true:
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* the NVR's system clock is within a second of correct on startup. (True
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when NTP is functioning or when the system has a real-time clock battery
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to preserve a previous correct time.)
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* the NVR's system time does not experience forward or backward "step"
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corrections (as opposed to frequency correction) during operation.
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* the NVR's system time advances at roughly the correct frequency. (NTP
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achieves this through frequency correction when operating correctly.)
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* the cameras' clock frequencies are off by no more than 500 parts per
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million (roughly 43 seconds per day).
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* the cameras are geographically close to the NVR, so in most cases network
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transmission time is under 50 ms. (Occasional delays are to be expected,
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however.)
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When one or more of those statements are false, the system should degrade
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gracefully: preserve what properties it can, gather video anyway, and when
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possible include sufficient metadata to assess trustworthiness.
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Additionally, the system should not require manual configuration of camera
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frequency corrections.
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## Background
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Time in a distributed system is notoriously tricky. [Falsehoods programmers
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believe about
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time](http://infiniteundo.com/post/25326999628/falsehoods-programmers-believe-about-time)
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and [More falsehoods programmers believe about time; "wisdom of the crowd"
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edition](http://infiniteundo.com/post/25509354022/more-falsehoods-programmers-believe-about-time)
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give a taste of the problems encountered. These problems are found even in
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datacenters with expensive, well-tested hardware and relatively reliable
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network connections. Moonfire NVR is meant to run on an inexpensive
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single-board computer and record video from budget, closed-source cameras,
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so such problems are to be expected.
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Moonfire NVR typically has access to the following sources of time
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information:
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* the local `CLOCK_REALTIME`. Ideally this is maintained by `ntpd`:
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synchronized on startup, and frequency-corrected during operation. A
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hardware real-time clock and battery keep accurate time across restarts
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if the network is unavailable on startup. In the worst case, the system
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has no real-time clock or no battery and a network connection is
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unavailable. The time is far in the past on startup and is never
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corrected or is corrected via a step while Moonfire NVR is running.
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* the local `CLOCK_MONOTONIC`. This should be frequency-corrected by `ntpd`
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and guaranteed to never experience "steps", though its reference point is
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unspecified.
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* the local `ntpd`, which can be used to determine if the system is
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synchronized to NTP and quantify the precision of synchronization.
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* each camera's clock. The ONVIF specification mandates cameras must
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support synchronizing clocks via NTP, but in practice cameras appear to
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use SNTP clients which simply step time periodically and provide no
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interface to determine if the clock is currently synchronized. This
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document's author owns several cameras with clocks that run roughly 20
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ppm fast (2 seconds per day) and are adjusted via steps.
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* the RTP timestamps from each of a camera's streams. As described in [RFC
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3550 section 5.1](https://tools.ietf.org/html/rfc3550#section-5.1), these
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are monotonically increasing with an unspecified reference point. They
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can't be directly compared to other cameras or other streams from the
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same camera. Emperically, budget cameras don't appear to do any frequency
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correction on these timestamps.
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* in some cases, RTCP sender reports, as described in [RFC 3550 section
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6.4](https://tools.ietf.org/html/rfc3550#section-6.4). These correlate
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RTP timestamps with the camera's real time clock. However, these are only
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sent periodically, not necessarily at the beginning of the session.
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Some cameras omit them entirely depending on firmware version, as noted
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in [this forum post](http://www.cctvforum.com/viewtopic.php). Additionally,
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Moonfire NVR currently uses ffmpeg's libavformat for RTSP protocol
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handling; this library exposes these reports in a limited fashion.
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The camera records video frames as in the diagram below:
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![Video frame timeline](time-frames.png)
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Each frame has an associated RTP timestamp. It's unclear from skimming RFC
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3550 exactly what time this represents, but it must be some time after the
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last frame and before the next frame. At a typical rate of 30 frames per
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second, this timespan is short enough that this uncertainty won't be the
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largest source of time error in the system. We'll assume arbitrarily that the
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timestamp refers to the start of exposure.
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RTP doesn't transmit the duration of each video frame; it must be calculated
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from the timestamp of the following frame. This means that if a stream is
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terminated, the final frame has unknown duration.
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As described in [schema.md](schema.md), Moonfire NVR saves RTSP video streams
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into roughly one-minute "recordings", with a fixed rotation offset after the
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minute in the NVR's wall time.
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## Overview
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Moonfire NVR will use the RTP timestamps to calculate video frames' durations.
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For the first segment of video, it will trust these completely. It will use
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them and the NVR's wall clock time to establish the start time of the
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recording. For following segments, it will slightly adjust durations to
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compensate for difference between the frequencies of the camera and NVR
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clock, trusting the latter to be accurate.
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## Detailed design
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On every frame of video, Moonfire NVR will get a timestamp from
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`CLOCK_MONOTONIC`. On the first frame, it will additionally get a timestamp
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from `CLOCK_REALTIME` and compute the difference. It uses these to compute a
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monotonically increasing real time of receipt for every frame, called the
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_local frame time_. Assuming the local clock is accurate, this time is an
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upper bound on when the frame was generated. The difference is the sum of the
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following items:
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* H.264 encoding
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* buffering on the camera (particularly when starting the stream—some
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cameras apparently send frames that were captured before the RTSP session
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was established)
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* network transmission time
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These values may produce some jitter, so the local frame time is not directly
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used to calculate frame durations. Instead, they are primarily taken from
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differences in RTP timestamps from one frame to the next. During the first
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segment of video, these RTP timestamp differences are used directly, without
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correcting for incorrect camera frequency. At the design limit of 500 ppm
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camera frequency error, and an upper bound of two minutes of recording for the
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initial segment (explained below), this causes a maximum of 60 milliseconds of
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error.
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The _local start time_ of a segment is calculated when ending it. It's defined
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as the minimum for all frames of the local frame time minus the duration of
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all previous frames. If there are many frames, this means neither initial
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buffering nor spikes of delay in H.264 encoding or network transmission cause
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the local start time to become inaccurate. The least delayed frame wins.
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The first segment either ends with the RTSP session (due to error/shutdown) or
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on rotation. In the former case, there may not be many samples to use in
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calculating the local start time; accuracy may suffer but the system degrades
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gracefully. Rotation doesn't happen until the second time the rotation offset
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is passed, so rotation happens after 1–2 minutes rather than 0–1 minutes to
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maximize accuracy.
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The _start time_ of the first segment is its local start time. The start time
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of following segments is the end time of the previous segment.
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The duration of following segments is adjusted to compensate for camera
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frequency error, assuming the NVR clock's frequency is more trustworthy. This
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is done as follows. The _local duration_ of segment _i_ is calculated as the
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local start time of segment _i+1_ minus the local start time of segment _i_.
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The _cumulative error_ as of segment _i_ is defined as the local duration of
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all previous segments minus the duration of all previous segments. The
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duration of segment _i_ should be adjusted by up to 500 ppm to eliminate
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cumulative error. (For a one-minute segment, this is 0.3 ms, or 27 90kHz units.)
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This correction should be spread out across the segment to minimize jitter.
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Each segment's local start time is also stored in the database as a delta to
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the segment's start time. These stored values aren't for normal system
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operation but may be handy in understanding and correcting errors.
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## Caveats
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### Stream mismatches
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There's no particular reason to believe this will produce perfectly matched
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streams between cameras or even of main and sub streams within a camera.
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If this is insufficient, there's an alternate calculation of start time that
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could be used in some circumstances: the _camera start time_. The first RTCP
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sender report could be used to correlate a RTP timestamp with the camera's
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wall clock, and thus calculate the camera's time as of the first frame.
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The _start time_ of the first segment could be either its local start time or
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its camera start time, determined via the following rules:
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1. if there is no camera start time (due to the lack of a RTCP sender
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report), the local start time wins by default.
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2. if the camera start time is before 2016-01-01 00:00:00 UTC, the local
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start time wins.
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3. if the local start time is before 2016-01-01 00:00:00 UTC, the camera
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start time wins.
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4. if the times differ by more than 5 seconds, the local start time wins.
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5. otherwise, the camera start time wins.
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These rules are a compromise. When a system starts up without NTP or a clock
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battery, it typically reverts to a time in the distant past. Therefore times
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before Moonfire NVR was written should be checked for and avoided. When both
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systems have a believably recent timestamp, the local time is typically more
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accurate, but the camera time allows a closer match between two streams of
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the same camera.
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This still doesn't completely solve the problem, and it's unclear it is even
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better. When using camera start times, different cameras' streams may be
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mismatched by up twice the 5-second threshold described above. This could even
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happen for two streams within the same camera if a significant step happens
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between their establishment. More frequent SNTP adjustments may help, so that
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individual steps are less frequent. Or Moonfire NVR could attempt to address
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this with more complexity: use sender reports of established RTSP sessions to
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detect and compensate for these clock splits.
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It's unclear if these additional mechanisms are desirable or worthwhile. The
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simplest approach will be adopted initially and adapted as necessary.
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### Time discontinuities
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If the local system's wall clock time jumps during a recording ([as has
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happened](https://github.com/scottlamb/moonfire-nvr/issues/9#issuecomment-322663674)),
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Moonfire NVR will continue to use the initial wall clock time for as long as
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the recording lasts. This can result in some unfortunate behaviors:
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* a recording that lasts for months might have an incorrect time all the
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way through because `ntpd` took a few minutes on startup.
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* two recordings that were in fact simultaneous might be recorded with very
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different times because a time jump happened between their starts.
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It might be better to use the new time (assuming that ntpd has made a
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correction) retroactively. This is unimplemented, but the
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`recording_integrity` database table has a `wall_time_delta_90k` field which
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could be used for this purpose, either automatically or interactively.
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It would also be possible to split a recording in two if a "significant" time
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jump is noted, or to allow manually restarting a recording without restarting
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the entire program.
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### Leap seconds
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UTC time is defined as the seconds since epoch _excluding
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leap seconds_. Thus, timestamps during the leap second are ambiguous, and
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durations across the leap second should be adjusted.
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In POSIX, the system clock (as returned by `clock_gettime(CLOCK_REALTIME,
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...`) is defined as representing UTC. Note that some
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systems may instead be following a [leap
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smear](https://developers.google.com/time/smear) policy in which instead of
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one second happening twice, the clock runs slower. For a 24-hour period, the
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clock runs slower by a factor of 1/86,400 (an extra ~11.6 μs/s).
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In Moonfire NVR, all wall times in the database are based on UTC as reported
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by the system, and it's assumed that `start + duration = end`. Thus, a leap
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second is similar to a one-second time jump (see "Time discontinuities"
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above).
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Here are some options for improvement:
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#### Use `clock_gettime(CLOCK_TAI, ...)` timestamps
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Timestamps in the TAI clock system don't skip leap seconds. There's a system
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interface intended to provide timestamps in this clock system, and Moonfire
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NVR could use it. Unfortunately this has several problems:
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* `CLOCK_TAI` is only available on Linux. It'd be preferable to handle
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timestamps in a consistent way on other platforms. (At least on macOS,
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Moonfire NVR's current primary development platform.)
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* `CLOCK_TAI` is wrong on startup and possibly adjusted later. The offset
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between TAI and UTC is initially assumed to be 0. It's corrected when/if
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a sufficiently new `ntpd` starts.
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* We'd need a leap second table to translate this into calendar time. One
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would have to be downloaded from the Internet periodically, and we'd need
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to consider the case in which the available table is expired.
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* `CLOCK_TAI` likely doesn't work properly with leap smear systems. Where
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the leap smear prevents a time jump for `CLOCK_REALTIME`, it likely
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introduces one for `CLOCK_TAI`.
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#### Use a leap second table when calculating differences
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Moonfire NVR could retrieve UTC timestamps from the system then translate then
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to TAI via a leap second table, either before writing them to the database or
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whenever doing math on timestamps.
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As with `CLOCK_TAI`, this would require downloading a leap second table from
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the Internet periodically.
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This would mostly solve the problem at the cost of complexity. Timestamps
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obtained from the system for a two-second period starting with each leap
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second would still be ambiguous.
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#### Use smeared time
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Moonfire NVR could make no code changes and ask the system administrator to
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use smeared time. This is the simplest option. On a leap smear system, there
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are no time jumps. The ~11.6 ppm frequency error and the maximum introduced
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absolute error of 0.5 sec can be considered acceptable.
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Alternatively, Moonfire NVR could assume a specific leap smear policy (such as
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24-hour linear smear from 12:00 the day before to 12:00 the day after) and
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attempt to correct the time into TAI with a leap second table. This behavior
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would work well on a system with the expected configuration and produce
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surprising results on other systems. It's unfortunate that there's no standard
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way to determine if a system is using a leap smear and with what policy.
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