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mass markdown reformatting
Add tables of contents (using the VS Code Markdown All-In-One extension) and reformat lists to consistently use 4-space indents. No content changes.
This commit is contained in:
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.vscode/settings.json
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.vscode/settings.json
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@ -21,7 +21,7 @@
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// I find Prettier's markdown style jarring, including converting `*`
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// bullets to `-` and two-column indents. It's not customizable either.
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// Don't use it.
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"editor.defaultFormatter": null
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"editor.defaultFormatter": "yzhang.markdown-all-in-one"
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},
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// Rust-specific overrides.
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@ -41,5 +41,7 @@
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"editor.defaultFormatter": "matklad.rust-analyzer"
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//"editor.defaultFormatter": null
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},
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"rust-analyzer.inlayHints.enable": false
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"rust-analyzer.inlayHints.enable": false,
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"markdown.extension.list.indentationSize": "inherit",
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"markdown.extension.toc.unorderedList.marker": "*"
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}
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@ -1,7 +1,27 @@
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# Moonfire NVR API
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# Moonfire NVR API <!-- omit in toc -->
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Status: **current**.
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* [Objective](#objective)
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* [Detailed design](#detailed-design)
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* [`POST /api/login`](#post-apilogin)
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* [`POST /api/logout`](#post-apilogout)
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* [`GET /api/`](#get-api)
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* [`GET /api/cameras/<uuid>/`](#get-apicamerasuuid)
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* [`GET /api/cameras/<uuid>/<stream>/recordings`](#get-apicamerasuuidstreamrecordings)
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* [`GET /api/cameras/<uuid>/<stream>/view.mp4`](#get-apicamerasuuidstreamviewmp4)
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* [`GET /api/cameras/<uuid>/<stream>/view.mp4.txt`](#get-apicamerasuuidstreamviewmp4txt)
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* [`GET /api/cameras/<uuid>/<stream>/view.m4s`](#get-apicamerasuuidstreamviewm4s)
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* [`GET /api/cameras/<uuid>/<stream>/view.m4s.txt`](#get-apicamerasuuidstreamviewm4stxt)
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* [`GET /api/cameras/<uuid>/<stream>/live.m4s`](#get-apicamerasuuidstreamlivem4s)
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* [`GET /api/init/<id>.mp4`](#get-apiinitidmp4)
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* [`GET /api/init/<id>.mp4.txt`](#get-apiinitidmp4txt)
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* [`GET /api/signals`](#get-apisignals)
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* [`POST /api/signals`](#post-apisignals)
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* [Request 1](#request-1)
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* [Request 2](#request-2)
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* [Request 3](#request-3)
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## Objective
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Allow a JavaScript-based web interface to list cameras and view recordings.
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@ -704,7 +724,7 @@ Response:
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}
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```
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### Request 3
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#### Request 3
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5 seconds later, the client observes motion has ended. It leaves the prior
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data alone and predicts no more motion.
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541
design/schema.md
541
design/schema.md
@ -1,4 +1,4 @@
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# Moonfire NVR Storage Schema
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# Moonfire NVR Storage Schema <!-- omit in toc -->
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Status: **current**.
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@ -6,42 +6,56 @@ This is the initial design for the most fundamental parts of the Moonfire NVR
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storage schema. See also [guide/schema.md](../guide/schema.md) for more
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administrator-focused documentation.
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* [Objective](#objective)
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* [Cameras](#cameras)
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* [Hard drives](#hard-drives)
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* [Overview](#overview)
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* [Detailed design](#detailed-design)
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* [SQLite3](#sqlite3)
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* [Duration of recordings](#duration-of-recordings)
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* [Lifecycle of a sample file directory](#lifecycle-of-a-sample-file-directory)
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* [Lifecycle of a recording](#lifecycle-of-a-recording)
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* [Verifying invariants](#verifying-invariants)
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* [Recording table](#recording-table)
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* [`video_index`](#video_index)
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* [<a href="on-demand"></a>On-demand `.mp4` construction](#on-demand-mp4-construction)
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## Objective
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Goals:
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* record streams from modern ONVIF/PSIA IP security cameras
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* support several cameras
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* maintain full fidelity of incoming compressed video streams
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* record continuously
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* support on-demand serving in different file formats / protocols
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(such as standard .mp4 files for arbitrary timespans, fragmented .mp4 files
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for MPEG-DASH or HTML5 Video Source Extensions, MPEG-TS files for HTTP Live
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Streaming, and "trick play" RTSP)
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* annotate camera timelines with metadata
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(such as motion detection, security alarm events, etc)
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* retain video segments with ~1-minute granularity based on metadata
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(e.g., extend retention of motion events)
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* take advantage of compact, inexpensive, low-power, commonly-available
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hardware such as the $35 [Raspberry Pi 2 Model B][pi2]
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* support high- and low-bandwidth playback
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* support near-live playback (~second old), including "trick play"
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* allow verifying database consistency with an `fsck` tool
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* record streams from modern ONVIF/PSIA IP security cameras
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* support several cameras
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* maintain full fidelity of incoming compressed video streams
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* record continuously
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* support on-demand serving in different file formats / protocols
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(such as standard .mp4 files for arbitrary timespans, fragmented .mp4 files
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for MPEG-DASH or HTML5 Video Source Extensions, MPEG-TS files for HTTP Live
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Streaming, and "trick play" RTSP)
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* annotate camera timelines with metadata
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(such as motion detection, security alarm events, etc)
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* retain video segments with ~1-minute granularity based on metadata
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(e.g., extend retention of motion events)
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* take advantage of compact, inexpensive, low-power, commonly-available
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hardware such as the $35 [Raspberry Pi 2 Model B][pi2]
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* support high- and low-bandwidth playback
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* support near-live playback (~second old), including "trick play"
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* allow verifying database consistency with an `fsck` tool
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Non-goals:
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* record streams from older cameras: JPEG/MJPEG USB "webcams" and analog
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security cameras/capture cards
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* allow users to directly access or manipulate the stored data with standard
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video or filesystem tools
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* support H.264 features not used by common IP camera encoders, such as
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B-frames and Periodic Infra Refresh.
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* support recovering the last ~minute of video after a crash or power loss
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* record streams from older cameras: JPEG/MJPEG USB "webcams" and analog
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security cameras/capture cards
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* allow users to directly access or manipulate the stored data with standard
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video or filesystem tools
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* support H.264 features not used by common IP camera encoders, such as
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B-frames and Periodic Infra Refresh.
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* support recovering the last ~minute of video after a crash or power loss
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Possible future goals:
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* record audio and/or other types of timestamped samples (such as
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[Xandem][xandem] tomography data).
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* record audio and/or other types of timestamped samples (such as
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[Xandem][xandem] tomography data).
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### Cameras
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@ -51,12 +65,12 @@ streams. They have many customizable settings, such as resolution, frame rate,
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compression quality, maximum bitrate, I-frame interval. A typical setup might be
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as follows:
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* the high-quality "main" stream as 1080p/30fps, 3000 kbps.
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This stream is well-suited to local viewing or forensics.
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* the low-bandwidth "sub" stream as 704x480/10fps, 100 kbps.
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This stream may be preferred for mobile/remote viewing, when viewing several
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streams side-by-side, and for real-time computer vision (such as salient
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motion detection).
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* the high-quality "main" stream as 1080p/30fps, 3000 kbps.
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This stream is well-suited to local viewing or forensics.
|
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* the low-bandwidth "sub" stream as 704x480/10fps, 100 kbps.
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This stream may be preferred for mobile/remote viewing, when viewing several
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streams side-by-side, and for real-time computer vision (such as salient
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motion detection).
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The dual pre-encoded H.264 video streams provide a tremendous advantage over
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older camera models (which provided raw video or JPEG-encoded frames) because
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@ -73,13 +87,17 @@ different quality settings as well.
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Decode:
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$ time ffmpeg -y -threads 1 -i input.mp4 \
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-f null /dev/null
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```
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$ time ffmpeg -y -threads 1 -i input.mp4 \
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-f null /dev/null
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```
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Combo (Decode + encode with libx264):
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$ time ffmpeg -y -threads 1 -i input.mp4 \
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-c:v libx264 -preset ultrafast -threads 1 -f mp4 /dev/null
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```
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$ time ffmpeg -y -threads 1 -i input.mp4 \
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-c:v libx264 -preset ultrafast -threads 1 -f mp4 /dev/null
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```
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| Processor | 1080p30 decode | 1080p30 combo | 704x480p10 decode | 704x480p10 combo |
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@ -115,8 +133,10 @@ only capable of 50 random accesses per second, and each one takes time that
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otherwise could be used to transfer 2+ MB. The constrained resource, *disk
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time fraction*, can be bounded as follows:
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disk time fraction <= (seek rate) / (50 seeks/sec) +
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(bandwidth) / (100 MB/sec)
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```
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disk time fraction <= (seek rate) / (50 seeks/sec) +
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(bandwidth) / (100 MB/sec)
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```
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## Overview
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@ -127,19 +147,20 @@ together.
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Each recording is stored in two places:
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* a sample file directory, intended to be stored on spinning disk.
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Each file in this directory is simply a concatenation of the compressed,
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timestamped video samples (also called "packets" or encoded frames), as
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received from the camera. In MPEG-4 terminology (see [ISO
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14496-12][iso-14496-12]), this is the contents of a `mdat` box for a `.mp4`
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file representing the segment. These files do not contain framing data (start
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and end byte offsets of samples) and thus are not meant to be decoded on
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their own.
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* the `recording` table in a [SQLite3][sqlite3] database, intended to be
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stored on flash if possible. A row in this table contains all the metadata
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associated with the segment, including the sample-by-sample contents of the
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MPEG-4 `stbl` box. At 30 fps, a row is expected to require roughly 4 KB of
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storage (2 bytes per sample, plus some fixed overhead).
|
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* a sample file directory, intended to be stored on spinning disk.
|
||||
Each file in this directory is simply a concatenation of the compressed,
|
||||
timestamped video samples (also called "packets" or encoded frames), as
|
||||
received from the camera. In MPEG-4 terminology (see [ISO
|
||||
14496-12][iso-14496-12]), this is the contents of a `mdat` box for a
|
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`.mp4` file representing the segment. These files do not contain framing
|
||||
data (start and end byte offsets of samples) and thus are not meant to be
|
||||
decoded on their own.
|
||||
* the `recording` table in a [SQLite3][sqlite3] database, intended to be
|
||||
stored on flash if possible. A row in this table contains all the
|
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metadata associated with the segment, including the sample-by-sample
|
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contents of the MPEG-4 `stbl` box. At 30 fps, a row is expected to
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require roughly 4 KB of storage (2 bytes per sample, plus some fixed
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overhead).
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Putting the metadata on flash means metadata operations can be fast
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(sub-millisecond random access, with parallelism) and do not take precious
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@ -167,17 +188,18 @@ All metadata, including the `recording` table and others, will be stored in
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the SQLite3 database using [write-ahead logging][sqlite3-wal]. There are
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several reasons for this decision:
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* No user administration required. SQLite3, unlike its heavier-weight friends
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MySQL and PostgreSQL, can be completely internal to the application. In many
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applications, end users are unaware of the existence of a RDBMS, and
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Moonfire NVR should be no exception.
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* Correctness. It's relatively easy to make guarantees about the state of an
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ACID database, and SQLite3 in particular has a robust implementation. (See
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[Files Are Hard][file-consistency].)
|
||||
* Developer ease and familiarity. SQL-based RDBMSs are quite common and
|
||||
provide a lot of high-level constructs that ease development. SQLite3 in
|
||||
particular is ubiquitous. Contributors are likely to come with some
|
||||
understanding of the database, and there are many resources to learn more.
|
||||
* No user administration required. SQLite3, unlike its heavier-weight friends
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||||
MySQL and PostgreSQL, can be completely internal to the application. In
|
||||
many applications, end users are unaware of the existence of a RDBMS, and
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||||
Moonfire NVR should be no exception.
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||||
* Correctness. It's relatively easy to make guarantees about the state of an
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||||
ACID database, and SQLite3 in particular has a robust implementation.
|
||||
(See [Files Are Hard][file-consistency].)
|
||||
* Developer ease and familiarity. SQL-based RDBMSs are quite common and
|
||||
provide a lot of high-level constructs that ease development. SQLite3 in
|
||||
particular is ubiquitous. Contributors are likely to come with some
|
||||
understanding of the database, and there are many resources to learn
|
||||
more.
|
||||
|
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Total database size is expected to be roughly 4 KB per minute at 30 fps, or
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1 GB for six camera-months of video. This will easily fit on a modest flash
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@ -189,40 +211,42 @@ to be a performance bottleneck.
|
||||
There are many constraints that influenced the choice of 1 minute as the
|
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duration of recordings.
|
||||
|
||||
* Per-recording metadata size. There is a fixed component to the size of each
|
||||
row, including the starting/ending timestamps, sample file UUID, etc. This
|
||||
should not cause the database to be too large to fit on low-cost flash
|
||||
devices. As described in the previous section, with 1 minute recordings the
|
||||
size is quite modest.
|
||||
* Disk seeks. Sample files should be large enough that even during
|
||||
simultaneous recording and playback of several streams, the disk seeks
|
||||
incurred when switching from one file to another should not be significant.
|
||||
At the extreme, a sample file per frame could cause an unacceptable 240
|
||||
seeks per second just to record 8 30 fps streams. At one minute recording
|
||||
time, 16 recording streams (2 per each of 8 cameras) and 4 playback streams
|
||||
would cause on average 20 seeks per minute, or under 1% disk time.
|
||||
* Internal fragmentation. Common Linux filesystems have a block size of 4 KiB
|
||||
(see `statvfs.f_frsize`). Up to this much space per file will be wasted at
|
||||
the end of each file. At the bitrates described in "Background", this is an
|
||||
insignicant .02% waste for main streams and .5% waste for sub streams.
|
||||
* Number of "slices" in .mp4 files. As described [below](#on-demand),
|
||||
`.mp4` files will be constructed on-demand for export. It should be
|
||||
possible to export an hours-long segment without too much overhead. In
|
||||
particular, it must be possible to iterate through all the recordings,
|
||||
assemble the list of slices, and calculate offsets and total size. One
|
||||
minute seems acceptable; though we will watch this as work proceeds.
|
||||
* Crashes. On program crash or power loss, ideally it's acceptable to simply
|
||||
discard any recordings in progress rather than add a checkpointing scheme.
|
||||
* Granularity of retention. It should be possible to extend retention time
|
||||
around motion events without forcing retention of too much additional data
|
||||
or copying bytes around on disk.
|
||||
* Per-recording metadata size. There is a fixed component to the size of each
|
||||
row, including the starting/ending timestamps, sample file UUID, etc.
|
||||
This should not cause the database to be too large to fit on low-cost
|
||||
flash devices. As described in the previous section, with 1 minute
|
||||
recordings the size is quite modest.
|
||||
* Disk seeks. Sample files should be large enough that even during
|
||||
simultaneous recording and playback of several streams, the disk seeks
|
||||
incurred when switching from one file to another should not be
|
||||
significant. At the extreme, a sample file per frame could cause an
|
||||
unacceptable 240 seeks per second just to record 8 30 fps streams. At one
|
||||
minute recording time, 16 recording streams (2 per each of 8 cameras) and
|
||||
4 playback streams would cause on average 20 seeks per minute, or under
|
||||
1% disk time.
|
||||
* Internal fragmentation. Common Linux filesystems have a block size of 4 KiB
|
||||
(see `statvfs.f_frsize`). Up to this much space per file will be wasted
|
||||
at the end of each file. At the bitrates described in "Background", this
|
||||
is an insignicant .02% waste for main streams and .5% waste for sub
|
||||
streams.
|
||||
* Number of "slices" in .mp4 files. As described [below](#on-demand),
|
||||
`.mp4` files will be constructed on-demand for export. It should be
|
||||
possible to export an hours-long segment without too much overhead. In
|
||||
particular, it must be possible to iterate through all the recordings,
|
||||
assemble the list of slices, and calculate offsets and total size. One
|
||||
minute seems acceptable; though we will watch this as work proceeds.
|
||||
* Crashes. On program crash or power loss, ideally it's acceptable to simply
|
||||
discard any recordings in progress rather than add a checkpointing scheme.
|
||||
* Granularity of retention. It should be possible to extend retention time
|
||||
around motion events without forcing retention of too much additional
|
||||
data or copying bytes around on disk.
|
||||
|
||||
The design avoids the need for the following constraints:
|
||||
|
||||
* Dealing with events crossing segment boundaries. This is meant to be
|
||||
invisible.
|
||||
* Serving close to live. It's possible to serve a recording as it is being
|
||||
written.
|
||||
* Dealing with events crossing segment boundaries. This is meant to be
|
||||
invisible.
|
||||
* Serving close to live. It's possible to serve a recording as it is being
|
||||
written.
|
||||
|
||||
### Lifecycle of a sample file directory
|
||||
|
||||
@ -230,19 +254,20 @@ One major disadvantage to splitting the state in two (the SQLite3 database in
|
||||
flash and the sample file directories on spinning disk) is the possibility of
|
||||
inconsistency. There are many ways this could arise:
|
||||
|
||||
* a sample file directory's disk is unexpectedly not mounted due to hardware
|
||||
failure or misconfiguration.
|
||||
* the administrator mixing up the mount points of two filesystems holding
|
||||
different sample file directories.
|
||||
* the administrator renaming a sample file directory without updating the database.
|
||||
* the administrator restoring the database from backup but not the sample file
|
||||
directory, or vice versa.
|
||||
* the administrator providing two sample file directory paths pointed at the
|
||||
same inode via symlinks or non-canonical paths. (Note that flock(2) has a
|
||||
design flaw in which multiple file descriptors can share a lock, so the current
|
||||
locking scheme is not sufficient to detect this otherwise.)
|
||||
* database and sample file directories forked from the same version, opened
|
||||
the same number of times, then crossed.
|
||||
* a sample file directory's disk is unexpectedly not mounted due to hardware
|
||||
failure or misconfiguration.
|
||||
* the administrator mixing up the mount points of two filesystems holding
|
||||
different sample file directories.
|
||||
* the administrator renaming a sample file directory without updating the
|
||||
database.
|
||||
* the administrator restoring the database from backup but not the sample file
|
||||
directory, or vice versa.
|
||||
* the administrator providing two sample file directory paths pointed at the
|
||||
same inode via symlinks or non-canonical paths. (Note that flock(2) has a
|
||||
design flaw in which multiple file descriptors can share a lock, so the
|
||||
current locking scheme is not sufficient to detect this otherwise.)
|
||||
* database and sample file directories forked from the same version, opened
|
||||
the same number of times, then crossed.
|
||||
|
||||
To combat this, each sample file directory has some metadata its database row
|
||||
and stored file called `meta`. These track uuids associated with the database
|
||||
@ -323,74 +348,74 @@ This is a sub-procedure used in several places below.
|
||||
Precondition: the directory's lock is held with `LOCK_EX` (exclusive) and
|
||||
there is an existing metadata file.
|
||||
|
||||
1. Open the metadata file.
|
||||
2. Rewrite the fixed-length data atomically.
|
||||
3. `fdatasync` the file.
|
||||
1. Open the metadata file.
|
||||
2. Rewrite the fixed-length data atomically.
|
||||
3. `fdatasync` the file.
|
||||
|
||||
*Open the database as read-only*
|
||||
|
||||
1. Lock the database directory with `LOCK_SH` (shared).
|
||||
2. Open the SQLite database with `SQLITE_OPEN_READ_ONLY`.
|
||||
1. Lock the database directory with `LOCK_SH` (shared).
|
||||
2. Open the SQLite database with `SQLITE_OPEN_READ_ONLY`.
|
||||
|
||||
*Open the database as read-write*
|
||||
|
||||
1. Lock the database directory with `LOCK_EX` (exclusive).
|
||||
2. Open the SQLite database with `SQLITE_OPEN_READ_WRITE`.
|
||||
3. Insert a new `open` table row with the new sequence number and uuid.
|
||||
1. Lock the database directory with `LOCK_EX` (exclusive).
|
||||
2. Open the SQLite database with `SQLITE_OPEN_READ_WRITE`.
|
||||
3. Insert a new `open` table row with the new sequence number and uuid.
|
||||
|
||||
*Create a sample file directory*
|
||||
|
||||
Precondition: database open read-write.
|
||||
|
||||
1. Lock the sample file directory with `LOCK_EX` (exclusive).
|
||||
2. Verify there is no metadata file or `last_complete_open` is unset.
|
||||
3. Write new metadata file with a fresh `dir_uuid` and a `in_progress_open`
|
||||
matching the database's current open.
|
||||
4. Add a matching row to the database with `last_complete_open_id` matching
|
||||
the current open.
|
||||
5. Update the metadata file to move `in_progress_open` to
|
||||
`last_complete_open`.
|
||||
1. Lock the sample file directory with `LOCK_EX` (exclusive).
|
||||
2. Verify there is no metadata file or `last_complete_open` is unset.
|
||||
3. Write new metadata file with a fresh `dir_uuid` and a `in_progress_open`
|
||||
matching the database's current open.
|
||||
4. Add a matching row to the database with `last_complete_open_id` matching
|
||||
the current open.
|
||||
5. Update the metadata file to move `in_progress_open` to
|
||||
`last_complete_open`.
|
||||
|
||||
*Open a sample file directory read-only*
|
||||
|
||||
Precondition: database open (read-only or read-write).
|
||||
|
||||
1. Lock the sample file directory with `LOCK_SH` (shared).
|
||||
2. Verify the metadata file matches the database:
|
||||
* database uuid matches.
|
||||
* dir uuid matches.
|
||||
* if the database's `last_complete_open` is set, it must match the
|
||||
directory's `last_complete_open` or `in_progress_open`.
|
||||
* if the database's `last_complete_open` is absent, the directory's
|
||||
must be as well.
|
||||
1. Lock the sample file directory with `LOCK_SH` (shared).
|
||||
2. Verify the metadata file matches the database:
|
||||
* database uuid matches.
|
||||
* dir uuid matches.
|
||||
* if the database's `last_complete_open` is set, it must match the
|
||||
directory's `last_complete_open` or `in_progress_open`.
|
||||
* if the database's `last_complete_open` is absent, the directory's
|
||||
must be as well.
|
||||
|
||||
*Open a sample file directory read-write*
|
||||
|
||||
Precondition: database open read-write.
|
||||
|
||||
1. Lock the sample file directory with `LOCK_EX` (exclusive).
|
||||
2. Verify the metadata file matches the database (as above).
|
||||
3. Update the metadata file with `in_progress_open` matching the current
|
||||
open.
|
||||
3. Update the database row with `last_complete_open_id` matching the current
|
||||
open.
|
||||
4. Update the metadata file with `last_complete_open` rather than
|
||||
`in_progress_open`.
|
||||
5. Run the recording startup procedure for this directory.
|
||||
1. Lock the sample file directory with `LOCK_EX` (exclusive).
|
||||
2. Verify the metadata file matches the database (as above).
|
||||
3. Update the metadata file with `in_progress_open` matching the current
|
||||
open.
|
||||
4. Update the database row with `last_complete_open_id` matching the current
|
||||
open.
|
||||
5. Update the metadata file with `last_complete_open` rather than
|
||||
`in_progress_open`.
|
||||
6. Run the recording startup procedure for this directory.
|
||||
|
||||
*Close a sample file directory*
|
||||
|
||||
1. Drop the sample file directory lock.
|
||||
1. Drop the sample file directory lock.
|
||||
|
||||
*Delete a sample file directory*
|
||||
|
||||
1. Remove all sample files (of all three categories described below:
|
||||
`recording` table rows, `garbage` table rows, and files with recording
|
||||
ids >= their stream's `cum_recordings`); see "delete a recording"
|
||||
procedure below.
|
||||
2. Rewrite the directory metadata with `in_progress_open` set to the current open,
|
||||
`last_complete_open` cleared.
|
||||
3. Delete the directory's row from the database.
|
||||
1. Remove all sample files (of all three categories described below:
|
||||
`recording` table rows, `garbage` table rows, and files with recording
|
||||
ids >= their stream's `cum_recordings`); see "delete a recording"
|
||||
procedure below.
|
||||
2. Rewrite the directory metadata with `in_progress_open` set to the current open,
|
||||
`last_complete_open` cleared.
|
||||
3. Delete the directory's row from the database.
|
||||
|
||||
### Lifecycle of a recording
|
||||
|
||||
@ -398,15 +423,15 @@ Because a major part of the recording state is outside the SQL database, care
|
||||
must be taken to guarantee consistency and durability. Moonfire NVR maintains
|
||||
three invariants about sample files:
|
||||
|
||||
1. `recording` table rows have sample files on disk with the indicated size
|
||||
and SHA-1 hash.
|
||||
2. Exactly one of the following statements is true for every sample file:
|
||||
* It has a `recording` table row.
|
||||
* It has a `garbage` table row.
|
||||
* Its recording id is greater than or equal to the `cum_recordings`
|
||||
for its stream.
|
||||
3. After an orderly shutdown of Moonfire NVR, there is a `recording` table row
|
||||
for every sample file, even if there have been previous crashes.
|
||||
1. `recording` table rows have sample files on disk with the indicated size
|
||||
and SHA-1 hash.
|
||||
2. Exactly one of the following statements is true for every sample file:
|
||||
* It has a `recording` table row.
|
||||
* It has a `garbage` table row.
|
||||
* Its recording id is greater than or equal to the `cum_recordings`
|
||||
for its stream.
|
||||
3. After an orderly shutdown of Moonfire NVR, there is a `recording` table row
|
||||
for every sample file, even if there have been previous crashes.
|
||||
|
||||
The first invariant provides certainty that a recording is properly stored. It
|
||||
would be prohibitively expensive to verify hashes on demand (when listing or
|
||||
@ -423,31 +448,31 @@ These invariants are updated through the following procedure:
|
||||
|
||||
*Create a recording:*
|
||||
|
||||
1. Write the sample file, aborting if `open(..., O\_WRONLY|O\_CREATE|O\_EXCL)`
|
||||
fails with `EEXIST`.
|
||||
3. `fsync()` the sample file.
|
||||
4. `fsync()` the sample file directory.
|
||||
5. Insert the `recording` row, marking its size and SHA-1 hash in the process.
|
||||
1. Write the sample file, aborting if `open(..., O\_WRONLY|O\_CREATE|O\_EXCL)`
|
||||
fails with `EEXIST`.
|
||||
3. `fsync()` the sample file.
|
||||
4. `fsync()` the sample file directory.
|
||||
5. Insert the `recording` row, marking its size and SHA-1 hash in the process.
|
||||
|
||||
*Delete a recording:*
|
||||
|
||||
1. Replace the `recording` row with a `garbage` row.
|
||||
2. `unlink()` the sample file, warning on `ENOENT`. (This would indicate
|
||||
invariant #2 is false.)
|
||||
3. `fsync()` the sample file directory.
|
||||
4. Delete the `garbage` row.
|
||||
1. Replace the `recording` row with a `garbage` row.
|
||||
2. `unlink()` the sample file, warning on `ENOENT`. (This would indicate
|
||||
invariant #2 is false.)
|
||||
3. `fsync()` the sample file directory.
|
||||
4. Delete the `garbage` row.
|
||||
|
||||
*Startup (crash recovery):*
|
||||
|
||||
1. Acquire a lock to guarantee this is the only Moonfire NVR process running
|
||||
against the given database. This lock is not released until program shutdown.
|
||||
2. Query `garbage` table and `cum_recordings` field in the `stream` table.
|
||||
3. `unlink()` all the sample files associated with garbage rows, ignoring
|
||||
`ENOENT`.
|
||||
4. For each stream, `unlink()` all the existing files with recording ids >=
|
||||
`cum_recordings`.
|
||||
4. `fsync()` the sample file directory.
|
||||
5. Delete all rows from the `garbage` table.
|
||||
1. Acquire a lock to guarantee this is the only Moonfire NVR process running
|
||||
against the given database. This lock is not released until program shutdown.
|
||||
2. Query `garbage` table and `cum_recordings` field in the `stream` table.
|
||||
3. `unlink()` all the sample files associated with garbage rows, ignoring
|
||||
`ENOENT`.
|
||||
4. For each stream, `unlink()` all the existing files with recording ids >=
|
||||
`cum_recordings`.
|
||||
4. `fsync()` the sample file directory.
|
||||
5. Delete all rows from the `garbage` table.
|
||||
|
||||
The procedures can be batched: while for a given recording, the steps must be
|
||||
strictly ordered, multiple recordings can be proceeding through the steps
|
||||
@ -471,9 +496,9 @@ problem.
|
||||
There should be a means to verify the invariants above. There are three
|
||||
possible levels of verification:
|
||||
|
||||
1. Compare presence of sample files.
|
||||
2. Compare size of sample files.
|
||||
3. Compare hashes of sample files.
|
||||
1. Compare presence of sample files.
|
||||
2. Compare size of sample files.
|
||||
3. Compare hashes of sample files.
|
||||
|
||||
Consider a database with a 6 camera-months of recordings at 3.1 Mbps (for
|
||||
both main and sub streams). There would be 0.5 million files, taking 5.9 TB.
|
||||
@ -487,15 +512,17 @@ The times are roughly:
|
||||
|
||||
The `readdir()` and `fstat()` times can be tested simply:
|
||||
|
||||
$ mkdir testdir
|
||||
$ cd testdir
|
||||
$ seq 1 $[60*24*365*6/12*2] | xargs touch
|
||||
$ sudo sh -c 'echo 1 > /proc/sys/vm/drop_caches'
|
||||
$ time ls -1 -f | wc -l
|
||||
$ sudo sh -c 'echo 1 > /proc/sys/vm/drop_caches'
|
||||
$ time ls -1 -f --size | wc -l
|
||||
```
|
||||
$ mkdir testdir
|
||||
$ cd testdir
|
||||
$ seq 1 $[60*24*365*6/12*2] | xargs touch
|
||||
$ sudo sh -c 'echo 1 > /proc/sys/vm/drop_caches'
|
||||
$ time ls -1 -f | wc -l
|
||||
$ sudo sh -c 'echo 1 > /proc/sys/vm/drop_caches'
|
||||
$ time ls -1 -f --size | wc -l
|
||||
```
|
||||
|
||||
(The system calls used by `ls` can be verified through strace.)
|
||||
(The system calls used by `ls` can be verified through strace.)
|
||||
|
||||
The hash verification time is easiest to calculate: reading 5.9 TB at 100
|
||||
MB/sec takes about 8 hours. On some systems, it will be even slower. On
|
||||
@ -515,42 +542,44 @@ the background at low priority.
|
||||
The snippet below is a illustrative excerpt of the SQLite schema; see
|
||||
`schema.sql` for the authoritative, up-to-date version.
|
||||
|
||||
-- A single, typically 60-second, recorded segment of video.
|
||||
create table recording (
|
||||
id integer primary key,
|
||||
open_id integer references open (id),
|
||||
camera_id integer references camera (id) not null,
|
||||
```sql
|
||||
-- A single, typically 60-second, recorded segment of video.
|
||||
create table recording (
|
||||
id integer primary key,
|
||||
open_id integer references open (id),
|
||||
camera_id integer references camera (id) not null,
|
||||
|
||||
sample_file_uuid blob unique not null,
|
||||
sample_file_blake3 blob,
|
||||
sample_file_size integer,
|
||||
sample_file_uuid blob unique not null,
|
||||
sample_file_blake3 blob,
|
||||
sample_file_size integer,
|
||||
|
||||
-- The starting time and duration of the recording, in 90 kHz units since
|
||||
-- 1970-01-01 00:00:00 UTC.
|
||||
start_time_90k integer not null,
|
||||
duration_90k integer,
|
||||
-- The starting time and duration of the recording, in 90 kHz units since
|
||||
-- 1970-01-01 00:00:00 UTC.
|
||||
start_time_90k integer not null,
|
||||
duration_90k integer,
|
||||
|
||||
video_samples integer,
|
||||
video_sample_entry_id blob references visual_sample_entry (id),
|
||||
video_index blob,
|
||||
video_samples integer,
|
||||
video_sample_entry_id blob references visual_sample_entry (id),
|
||||
video_index blob,
|
||||
|
||||
...
|
||||
);
|
||||
...
|
||||
);
|
||||
|
||||
-- A concrete box derived from a ISO/IEC 14496-12 section 8.5.2
|
||||
-- VisualSampleEntry box. Describes the codec, width, height, etc.
|
||||
create table visual_sample_entry (
|
||||
id integerprimary key,
|
||||
-- A concrete box derived from a ISO/IEC 14496-12 section 8.5.2
|
||||
-- VisualSampleEntry box. Describes the codec, width, height, etc.
|
||||
create table visual_sample_entry (
|
||||
id integerprimary key,
|
||||
|
||||
-- The width and height in pixels; must match values within
|
||||
-- `sample_entry_bytes`.
|
||||
width integer,
|
||||
height integer,
|
||||
-- The width and height in pixels; must match values within
|
||||
-- `sample_entry_bytes`.
|
||||
width integer,
|
||||
height integer,
|
||||
|
||||
-- A serialized SampleEntry box, including the leading length and box
|
||||
-- type (avcC in the case of H.264).
|
||||
data blob
|
||||
);
|
||||
-- A serialized SampleEntry box, including the leading length and box
|
||||
-- type (avcC in the case of H.264).
|
||||
data blob
|
||||
);
|
||||
```
|
||||
|
||||
As mentioned by the `start_time_90k` field above, recordings use a 90 kHz time
|
||||
base. This matches the RTP timestamp frequency used for H.264 and other video
|
||||
@ -579,21 +608,21 @@ only with certain firmware versions (see [thread][hikvision-sr]). Most likely
|
||||
it will be useful to have any available clock/timing information for
|
||||
diagnosing problems, such as the following:
|
||||
|
||||
* the NVR's wall clock time
|
||||
* the NVR's NTP server sync status
|
||||
* the NVR's uptime
|
||||
* the camera's time as of the RTP play response
|
||||
* the camera's time as of any RTCP Sender Reports, and the corresponding RTP
|
||||
timestamps
|
||||
* the NVR's wall clock time
|
||||
* the NVR's NTP server sync status
|
||||
* the NVR's uptime
|
||||
* the camera's time as of the RTP play response
|
||||
* the camera's time as of any RTCP Sender Reports, and the corresponding RTP
|
||||
timestamps
|
||||
|
||||
#### `video_index`
|
||||
|
||||
The `video_index` field conceptually holds three pieces of information about
|
||||
the samples:
|
||||
|
||||
1. the duration (in 90kHz units) of each sample
|
||||
2. the byte size of each sample
|
||||
3. which samples are "sync samples" (aka key frames or I-frames)
|
||||
1. the duration (in 90kHz units) of each sample
|
||||
2. the byte size of each sample
|
||||
3. which samples are "sync samples" (aka key frames or I-frames)
|
||||
|
||||
These correspond to [ISO/IEC 14496-12][iso-14496-12] `stts` (TimeToSampleBox,
|
||||
section 8.6.1.2), `stsz` (SampleSizeBox, section 8.7.3), and `stss`
|
||||
@ -614,16 +643,18 @@ This encoding is chosen so that values will be near zero, and thus the varints
|
||||
will be at their most compact possible form. An index might be written by the
|
||||
following pseudocode:
|
||||
|
||||
prev_duration = 0
|
||||
prev_bytes_key = 0
|
||||
prev_bytes_nonkey = 0
|
||||
for each frame:
|
||||
duration_delta = duration - prev_duration
|
||||
bytes_delta = bytes - (is_key ? prev_bytes_key : prev_bytes_nonkey)
|
||||
prev_duration_ms = duration_ms
|
||||
if key: prev_bytes_key = bytes else: prev_bytes_nonkey = bytes
|
||||
PutVarint((Zigzag(duration_delta) << 1) | is_key)
|
||||
PutVarint(Zigzag(bytes_delta)
|
||||
```
|
||||
prev_duration = 0
|
||||
prev_bytes_key = 0
|
||||
prev_bytes_nonkey = 0
|
||||
for each frame:
|
||||
duration_delta = duration - prev_duration
|
||||
bytes_delta = bytes - (is_key ? prev_bytes_key : prev_bytes_nonkey)
|
||||
prev_duration_ms = duration_ms
|
||||
if key: prev_bytes_key = bytes else: prev_bytes_nonkey = bytes
|
||||
PutVarint((Zigzag(duration_delta) << 1) | is_key)
|
||||
PutVarint(Zigzag(bytes_delta)
|
||||
```
|
||||
|
||||
See also the example below:
|
||||
|
||||
@ -643,10 +674,10 @@ See also the example below:
|
||||
A major goal of this format is to support on-demand serving in various formats,
|
||||
including two types of `.mp4` files:
|
||||
|
||||
* unfragmented `.mp4` files, for traditional video players.
|
||||
* fragmented `.mp4` files for MPEG-DASH or HTML5 Media Source Extensions
|
||||
(see [Media Source ISO BMFF Byte Stream Format][media-bmff]), for
|
||||
a browser-based user interface.
|
||||
* unfragmented `.mp4` files, for traditional video players.
|
||||
* fragmented `.mp4` files for MPEG-DASH or HTML5 Media Source Extensions
|
||||
(see [Media Source ISO BMFF Byte Stream Format][media-bmff]), for
|
||||
a browser-based user interface.
|
||||
|
||||
This does not require writing new `.mp4` files to disk. In fact, HTTP range
|
||||
requests (for "pseudo-streaming") can be satisfied on `.mp4` files aggregated
|
||||
@ -654,38 +685,6 @@ from several segments. The implementation details are outside the scope of this
|
||||
document, but this is possible in part due to the use of an on-flash database
|
||||
to store metadata and the simple, consistent format of sample indexes.
|
||||
|
||||
### Copyright
|
||||
|
||||
This file is part of Moonfire NVR, a security camera network video recorder.
|
||||
Copyright (C) 2016 The Moonfire NVR Authors
|
||||
|
||||
This program is free software: you can redistribute it and/or modify
|
||||
it under the terms of the GNU General Public License as published by
|
||||
the Free Software Foundation, either version 3 of the License, or
|
||||
(at your option) any later version.
|
||||
|
||||
In addition, as a special exception, the copyright holders give
|
||||
permission to link the code of portions of this program with the
|
||||
OpenSSL library under certain conditions as described in each
|
||||
individual source file, and distribute linked combinations including
|
||||
the two.
|
||||
|
||||
You must obey the GNU General Public License in all respects for all
|
||||
of the code used other than OpenSSL. If you modify file(s) with this
|
||||
exception, you may extend this exception to your version of the
|
||||
file(s), but you are not obligated to do so. If you do not wish to do
|
||||
so, delete this exception statement from your version. If you delete
|
||||
this exception statement from all source files in the program, then
|
||||
also delete it here.
|
||||
|
||||
This program is distributed in the hope that it will be useful,
|
||||
but WITHOUT ANY WARRANTY; without even the implied warranty of
|
||||
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
|
||||
GNU General Public License for more details.
|
||||
|
||||
You should have received a copy of the GNU General Public License
|
||||
along with this program. If not, see <http://www.gnu.org/licenses/>.
|
||||
|
||||
[pi2]: https://www.raspberrypi.org/products/raspberry-pi-2-model-b/
|
||||
[xandem]: http://www.xandemhome.com/
|
||||
[hikcam]: http://overseas.hikvision.com/us/Products_accessries_10533_i7696.html
|
||||
|
197
design/time.md
197
design/time.md
@ -1,4 +1,4 @@
|
||||
# Moonfire NVR Time Handling
|
||||
# Moonfire NVR Time Handling <!-- omit in toc -->
|
||||
|
||||
Status: **current**.
|
||||
|
||||
@ -7,6 +7,19 @@ Status: **current**.
|
||||
>
|
||||
> — Segal's law
|
||||
|
||||
* [Objective](#objective)
|
||||
* [Background](#background)
|
||||
* [Overview](#overview)
|
||||
* [Detailed design](#detailed-design)
|
||||
* [Caveats](#caveats)
|
||||
* [Stream mismatches](#stream-mismatches)
|
||||
* [Time discontinuities](#time-discontinuities)
|
||||
* [Leap seconds](#leap-seconds)
|
||||
* [Use `clock_gettime(CLOCK_TAI, ...)` timestamps](#use-clock_gettimeclock_tai--timestamps)
|
||||
* [Use a leap second table when calculating differences](#use-a-leap-second-table-when-calculating-differences)
|
||||
* [Use smeared time](#use-smeared-time)
|
||||
* [Alternatives considered](#alternatives-considered)
|
||||
|
||||
## Objective
|
||||
|
||||
Maximize the likelihood Moonfire NVR's timestamps are useful.
|
||||
@ -14,20 +27,20 @@ Maximize the likelihood Moonfire NVR's timestamps are useful.
|
||||
The timestamp corresponding to a video frame should roughly match timestamps
|
||||
from other sources:
|
||||
|
||||
* another video stream from the same camera. Given a video frame from the
|
||||
"main" stream, a video frame from the "sub" stream with a similar
|
||||
timestamp should have been recorded near the same time, and vice versa.
|
||||
This minimizes confusion when switching between views of these streams,
|
||||
and when viewing the "main" stream timestamps corresponding to a motion
|
||||
event gathered from the less CPU-intensive "sub" stream.
|
||||
* on-camera motion events from the same camera. If the video frame reflects
|
||||
the motion event, its timestamp should be roughly within the event's
|
||||
timespan.
|
||||
* streams from other cameras. Recorded views from two cameras of the same
|
||||
event should have similar timestamps.
|
||||
* events noted by the owner of the system, neighbors, police, etc., for the
|
||||
purpose of determining chronology, to the extent those persons use
|
||||
accurate clocks.
|
||||
* another video stream from the same camera. Given a video frame from the
|
||||
"main" stream, a video frame from the "sub" stream with a similar
|
||||
timestamp should have been recorded near the same time, and vice versa.
|
||||
This minimizes confusion when switching between views of these streams,
|
||||
and when viewing the "main" stream timestamps corresponding to a motion
|
||||
event gathered from the less CPU-intensive "sub" stream.
|
||||
* on-camera motion events from the same camera. If the video frame reflects
|
||||
the motion event, its timestamp should be roughly within the event's
|
||||
timespan.
|
||||
* streams from other cameras. Recorded views from two cameras of the same
|
||||
event should have similar timestamps.
|
||||
* events noted by the owner of the system, neighbors, police, etc., for the
|
||||
purpose of determining chronology, to the extent those persons use
|
||||
accurate clocks.
|
||||
|
||||
Two recordings from the same stream should not overlap. This would make it
|
||||
impossible for a user interface to present a simple timeline for accessing all
|
||||
@ -35,28 +48,28 @@ recorded video.
|
||||
|
||||
Durations should be useful over short timescales:
|
||||
|
||||
* If an object's motion is recorded, distance travelled divided by the
|
||||
duration of the frames over which this motion occurred should reflect the
|
||||
object's average speed.
|
||||
* Motion should appear smooth. There shouldn't be excessive frame-to-frame
|
||||
jitter due to such factors as differences in encoding time or network
|
||||
transmission.
|
||||
* If an object's motion is recorded, distance travelled divided by the
|
||||
duration of the frames over which this motion occurred should reflect the
|
||||
object's average speed.
|
||||
* Motion should appear smooth. There shouldn't be excessive frame-to-frame
|
||||
jitter due to such factors as differences in encoding time or network
|
||||
transmission.
|
||||
|
||||
This document describes an approach to achieving these goals when the
|
||||
following statements are true:
|
||||
|
||||
* the NVR's system clock is within a second of correct on startup. (True
|
||||
when NTP is functioning or when the system has a real-time clock battery
|
||||
to preserve a previous correct time.)
|
||||
* the NVR's system time does not experience forward or backward "step"
|
||||
corrections (as opposed to frequency correction) during operation.
|
||||
* the NVR's system time advances at roughly the correct frequency. (NTP
|
||||
achieves this through frequency correction when operating correctly.)
|
||||
* the cameras' clock frequencies are off by no more than 500 parts per
|
||||
million (roughly 43 seconds per day).
|
||||
* the cameras are geographically close to the NVR, so in most cases network
|
||||
transmission time is under 50 ms. (Occasional delays are to be expected,
|
||||
however.)
|
||||
* the NVR's system clock is within a second of correct on startup. (True
|
||||
when NTP is functioning or when the system has a real-time clock battery
|
||||
to preserve a previous correct time.)
|
||||
* the NVR's system time does not experience forward or backward "step"
|
||||
corrections (as opposed to frequency correction) during operation.
|
||||
* the NVR's system time advances at roughly the correct frequency. (NTP
|
||||
achieves this through frequency correction when operating correctly.)
|
||||
* the cameras' clock frequencies are off by no more than 500 parts per
|
||||
million (roughly 43 seconds per day).
|
||||
* the cameras are geographically close to the NVR, so in most cases network
|
||||
transmission time is under 50 ms. (Occasional delays are to be expected,
|
||||
however.)
|
||||
|
||||
When one or more of those statements are false, the system should degrade
|
||||
gracefully: preserve what properties it can, gather video anyway, and when
|
||||
@ -81,40 +94,40 @@ so such problems are to be expected.
|
||||
Moonfire NVR typically has access to the following sources of time
|
||||
information:
|
||||
|
||||
* the local `CLOCK_REALTIME`. Ideally this is maintained by `ntpd`:
|
||||
synchronized on startup, and frequency-corrected during operation. A
|
||||
hardware real-time clock and battery keep accurate time across restarts
|
||||
if the network is unavailable on startup. In the worst case, the system
|
||||
has no real-time clock or no battery and a network connection is
|
||||
unavailable. The time is far in the past on startup and is never
|
||||
corrected or is corrected via a step while Moonfire NVR is running.
|
||||
* the local `CLOCK_MONOTONIC`. This should be frequency-corrected by `ntpd`
|
||||
and guaranteed to never experience "steps", though its reference point is
|
||||
unspecified.
|
||||
* the local `ntpd`, which can be used to determine if the system is
|
||||
synchronized to NTP and quantify the precision of synchronization.
|
||||
* each camera's clock. The ONVIF specification mandates cameras must
|
||||
support synchronizing clocks via NTP, but in practice cameras appear to
|
||||
use SNTP clients which simply step time periodically and provide no
|
||||
interface to determine if the clock is currently synchronized. This
|
||||
document's author owns several cameras with clocks that run roughly 20
|
||||
ppm fast (2 seconds per day) and are adjusted via steps.
|
||||
* the RTP timestamps from each of a camera's streams. As described in
|
||||
[RFC 3550 section 5.1](https://tools.ietf.org/html/rfc3550#section-5.1),
|
||||
these are monotonically increasing with an unspecified reference point.
|
||||
They can't be directly compared to other cameras or other streams from
|
||||
the same camera. Emperically, budget cameras don't appear to do any
|
||||
frequency correction on these timestamps.
|
||||
* in some cases, RTCP sender reports, as described in
|
||||
[RFC 3550 section 6.4](https://tools.ietf.org/html/rfc3550#section-6.4).
|
||||
These correlate RTP timestamps with the camera's real time clock.
|
||||
However, these are only sent periodically, not necessarily at the
|
||||
beginning of the session. Some cameras omit them entirely depending on
|
||||
firmware version, as noted in
|
||||
[this forum post](https://www.cctvforum.com/topic/40914-video-sync-with-hikvision-ipcams-tech-query-about-rtcp/).
|
||||
Additionally, Moonfire NVR currently uses ffmpeg's libavformat for RTSP
|
||||
protocol handling; this library exposes these reports in a limited
|
||||
fashion.
|
||||
* the local `CLOCK_REALTIME`. Ideally this is maintained by `ntpd`:
|
||||
synchronized on startup, and frequency-corrected during operation. A
|
||||
hardware real-time clock and battery keep accurate time across restarts
|
||||
if the network is unavailable on startup. In the worst case, the system
|
||||
has no real-time clock or no battery and a network connection is
|
||||
unavailable. The time is far in the past on startup and is never
|
||||
corrected or is corrected via a step while Moonfire NVR is running.
|
||||
* the local `CLOCK_MONOTONIC`. This should be frequency-corrected by `ntpd`
|
||||
and guaranteed to never experience "steps", though its reference point is
|
||||
unspecified.
|
||||
* the local `ntpd`, which can be used to determine if the system is
|
||||
synchronized to NTP and quantify the precision of synchronization.
|
||||
* each camera's clock. The ONVIF specification mandates cameras must
|
||||
support synchronizing clocks via NTP, but in practice cameras appear to
|
||||
use SNTP clients which simply step time periodically and provide no
|
||||
interface to determine if the clock is currently synchronized. This
|
||||
document's author owns several cameras with clocks that run roughly 20
|
||||
ppm fast (2 seconds per day) and are adjusted via steps.
|
||||
* the RTP timestamps from each of a camera's streams. As described in
|
||||
[RFC 3550 section 5.1](https://tools.ietf.org/html/rfc3550#section-5.1),
|
||||
these are monotonically increasing with an unspecified reference point.
|
||||
They can't be directly compared to other cameras or other streams from
|
||||
the same camera. Emperically, budget cameras don't appear to do any
|
||||
frequency correction on these timestamps.
|
||||
* in some cases, RTCP sender reports, as described in
|
||||
[RFC 3550 section 6.4](https://tools.ietf.org/html/rfc3550#section-6.4).
|
||||
These correlate RTP timestamps with the camera's real time clock.
|
||||
However, these are only sent periodically, not necessarily at the
|
||||
beginning of the session. Some cameras omit them entirely depending on
|
||||
firmware version, as noted in
|
||||
[this forum post](https://www.cctvforum.com/topic/40914-video-sync-with-hikvision-ipcams-tech-query-about-rtcp/).
|
||||
Additionally, Moonfire NVR currently uses ffmpeg's libavformat for RTSP
|
||||
protocol handling; this library exposes these reports in a limited
|
||||
fashion.
|
||||
|
||||
The camera records video frames as in the diagram below:
|
||||
|
||||
@ -224,14 +237,14 @@ wall clock, and thus calculate the camera's time as of the first frame.
|
||||
The _start time_ of the first recording could be either its local start time
|
||||
or its camera start time, determined via the following rules:
|
||||
|
||||
1. if there is no camera start time (due to the lack of a RTCP sender
|
||||
report), the local start time wins by default.
|
||||
2. if the camera start time is before 2016-01-01 00:00:00 UTC, the local
|
||||
start time wins.
|
||||
3. if the local start time is before 2016-01-01 00:00:00 UTC, the camera
|
||||
start time wins.
|
||||
4. if the times differ by more than 5 seconds, the local start time wins.
|
||||
5. otherwise, the camera start time wins.
|
||||
1. if there is no camera start time (due to the lack of a RTCP sender
|
||||
report), the local start time wins by default.
|
||||
2. if the camera start time is before 2016-01-01 00:00:00 UTC, the local
|
||||
start time wins.
|
||||
3. if the local start time is before 2016-01-01 00:00:00 UTC, the camera
|
||||
start time wins.
|
||||
4. if the times differ by more than 5 seconds, the local start time wins.
|
||||
5. otherwise, the camera start time wins.
|
||||
|
||||
These rules are a compromise. When a system starts up without NTP or a clock
|
||||
battery, it typically reverts to a time in the distant past. Therefore times
|
||||
@ -259,10 +272,10 @@ happened](https://github.com/scottlamb/moonfire-nvr/issues/9#issuecomment-322663
|
||||
Moonfire NVR will continue to use the initial wall clock time for as long as
|
||||
the recording lasts. This can result in some unfortunate behaviors:
|
||||
|
||||
* a recording that lasts for months might have an incorrect time all the
|
||||
way through because `ntpd` took a few minutes on startup.
|
||||
* two recordings that were in fact simultaneous might be recorded with very
|
||||
different times because a time jump happened between their starts.
|
||||
* a recording that lasts for months might have an incorrect time all the
|
||||
way through because `ntpd` took a few minutes on startup.
|
||||
* two recordings that were in fact simultaneous might be recorded with very
|
||||
different times because a time jump happened between their starts.
|
||||
|
||||
It might be better to use the new time (assuming that ntpd has made a
|
||||
correction) retroactively. This is unimplemented, but the
|
||||
@ -299,18 +312,18 @@ Timestamps in the TAI clock system don't skip leap seconds. There's a system
|
||||
interface intended to provide timestamps in this clock system, and Moonfire
|
||||
NVR could use it. Unfortunately this has several problems:
|
||||
|
||||
* `CLOCK_TAI` is only available on Linux. It'd be preferable to handle
|
||||
timestamps in a consistent way on other platforms. (At least on macOS,
|
||||
Moonfire NVR's current primary development platform.)
|
||||
* `CLOCK_TAI` is wrong on startup and possibly adjusted later. The offset
|
||||
between TAI and UTC is initially assumed to be 0. It's corrected when/if
|
||||
a sufficiently new `ntpd` starts.
|
||||
* We'd need a leap second table to translate this into calendar time. One
|
||||
would have to be downloaded from the Internet periodically, and we'd need
|
||||
to consider the case in which the available table is expired.
|
||||
* `CLOCK_TAI` likely doesn't work properly with leap smear systems. Where
|
||||
the leap smear prevents a time jump for `CLOCK_REALTIME`, it likely
|
||||
introduces one for `CLOCK_TAI`.
|
||||
* `CLOCK_TAI` is only available on Linux. It'd be preferable to handle
|
||||
timestamps in a consistent way on other platforms. (At least on macOS,
|
||||
Moonfire NVR's current primary development platform.)
|
||||
* `CLOCK_TAI` is wrong on startup and possibly adjusted later. The offset
|
||||
between TAI and UTC is initially assumed to be 0. It's corrected when/if
|
||||
a sufficiently new `ntpd` starts.
|
||||
* We'd need a leap second table to translate this into calendar time. One
|
||||
would have to be downloaded from the Internet periodically, and we'd need
|
||||
to consider the case in which the available table is expired.
|
||||
* `CLOCK_TAI` likely doesn't work properly with leap smear systems. Where
|
||||
the leap smear prevents a time jump for `CLOCK_REALTIME`, it likely
|
||||
introduces one for `CLOCK_TAI`.
|
||||
|
||||
#### Use a leap second table when calculating differences
|
||||
|
||||
@ -345,4 +358,4 @@ Schema versions prior to 6 used a simpler database schema which didn't
|
||||
distinguish between "wall" and "media" time. Instead, the durations of video
|
||||
samples were adjusted for clock correction. This approach worked well for
|
||||
video. It couldn't be extended to audio without decoding and re-encoding to
|
||||
adjust same lengths and pitch.
|
||||
adjust same lengths and pitch.
|
||||
|
@ -1,4 +1,4 @@
|
||||
# Building Moonfire NVR
|
||||
# Building Moonfire NVR <!-- omit in toc -->
|
||||
|
||||
This document has notes for software developers on building Moonfire NVR from
|
||||
source code for development. If you just want to install precompiled
|
||||
@ -10,13 +10,12 @@ tracker](https://github.com/scottlamb/moonfire-nvr/issues) or
|
||||
[mailing list](https://groups.google.com/d/forum/moonfire-nvr-users) when
|
||||
stuck. Please also send pull requests to improve this doc.
|
||||
|
||||
* [Building Moonfire NVR](#building-moonfire-nvr)
|
||||
* [Downloading](#downloading)
|
||||
* [Docker builds](#docker-builds)
|
||||
* [Release procedure](#release-procedure)
|
||||
* [Non-Docker setup](#non-docker-setup)
|
||||
* [Running interactively straight from the working copy](#running-interactively-straight-from-the-working-copy)
|
||||
* [Running as a `systemd` service](#running-as-a-systemd-service)
|
||||
* [Downloading](#downloading)
|
||||
* [Docker builds](#docker-builds)
|
||||
* [Release procedure](#release-procedure)
|
||||
* [Non-Docker setup](#non-docker-setup)
|
||||
* [Running interactively straight from the working copy](#running-interactively-straight-from-the-working-copy)
|
||||
* [Running as a `systemd` service](#running-as-a-systemd-service)
|
||||
|
||||
## Downloading
|
||||
|
||||
@ -151,19 +150,19 @@ Linux VM and filesystem overlay.
|
||||
|
||||
To build the server, you will need the following C libraries installed:
|
||||
|
||||
* [ffmpeg](http://ffmpeg.org/) version 2.x or 3.x, including `libavutil`,
|
||||
`libavcodec` (to inspect H.264 frames), and `libavformat` (to connect to RTSP
|
||||
servers and write `.mp4` files).
|
||||
* [ffmpeg](http://ffmpeg.org/) version 2.x or 3.x, including `libavutil`,
|
||||
`libavcodec` (to inspect H.264 frames), and `libavformat` (to connect to
|
||||
RTSP servers and write `.mp4` files).
|
||||
|
||||
Note ffmpeg library versions older than 55.1.101, along with all versions of
|
||||
the competing project [libav](http://libav.org), don't support socket
|
||||
timeouts for RTSP. For reliable reconnections on error, it's strongly
|
||||
recommended to use ffmpeg library versions >= 55.1.101.
|
||||
Note ffmpeg library versions older than 55.1.101, along with all versions of
|
||||
the competing project [libav](http://libav.org), don't support socket
|
||||
timeouts for RTSP. For reliable reconnections on error, it's strongly
|
||||
recommended to use ffmpeg library versions >= 55.1.101.
|
||||
|
||||
* [SQLite3](https://www.sqlite.org/).
|
||||
* [SQLite3](https://www.sqlite.org/).
|
||||
|
||||
* [`ncursesw`](https://www.gnu.org/software/ncurses/), the UTF-8 version of
|
||||
the `ncurses` library.
|
||||
* [`ncursesw`](https://www.gnu.org/software/ncurses/), the UTF-8 version of
|
||||
the `ncurses` library.
|
||||
|
||||
To build the UI, you'll need [node and npm](https://nodejs.org/en/download/).
|
||||
|
||||
|
@ -1,4 +1,8 @@
|
||||
# Working on UI development
|
||||
# Working on UI development <!-- omit in toc -->
|
||||
|
||||
* [Getting started](#getting-started)
|
||||
* [Overriding defaults](#overriding-defaults)
|
||||
* [A note on `https`](#a-note-on-https)
|
||||
|
||||
The UI is presented from a single HTML page (index.html) and any number
|
||||
of Javascript files, css files, images, etc. These are "packed" together
|
||||
|
@ -1,4 +1,11 @@
|
||||
# Downloading, installing, and configuring Moonfire NVR with Docker
|
||||
# Installing Moonfire NVR <!-- omit in toc -->
|
||||
|
||||
* [Downloading, installing, and configuring Moonfire NVR with Docker](#downloading-installing-and-configuring-moonfire-nvr-with-docker)
|
||||
* [Dedicated hard drive setup](#dedicated-hard-drive-setup)
|
||||
* [Completing configuration through the UI](#completing-configuration-through-the-ui)
|
||||
* [Starting it up](#starting-it-up)
|
||||
|
||||
## Downloading, installing, and configuring Moonfire NVR with Docker
|
||||
|
||||
This document describes how to download, install, and configure Moonfire NVR
|
||||
via the prebuilt Docker images available for x86-64, arm64, and arm. If you
|
||||
@ -102,7 +109,7 @@ $ nvr init
|
||||
This will create a directory `/var/lib/moonfire-nvr/db` with a SQLite3 database
|
||||
within it.
|
||||
|
||||
## Dedicated hard drive setup
|
||||
### Dedicated hard drive setup
|
||||
|
||||
If a dedicated hard drive is available, set up the mount point:
|
||||
|
||||
@ -139,7 +146,7 @@ mount lines. It will look similar to this:
|
||||
--mount=type=bind,source=/media/nvr/sample,destination=/media/nvr/sample
|
||||
```
|
||||
|
||||
## Completing configuration through the UI
|
||||
### Completing configuration through the UI
|
||||
|
||||
Once your system is set up, it's time to initialize an empty database
|
||||
and add the cameras and sample directories. You can do this
|
||||
@ -159,28 +166,28 @@ In the user interface,
|
||||
|
||||
2. add cameras under "Cameras and streams".
|
||||
|
||||
* See the [wiki](https://github.com/scottlamb/moonfire-nvr/wiki) for notes
|
||||
about specific camera models.
|
||||
* See the [wiki](https://github.com/scottlamb/moonfire-nvr/wiki) for notes
|
||||
about specific camera models.
|
||||
|
||||
* There's a "Test" button to verify your settings directly from the add/edit
|
||||
camera dialog.
|
||||
* There's a "Test" button to verify your settings directly from the add/edit
|
||||
camera dialog.
|
||||
|
||||
* Be sure to assign each stream you want to capture to a sample file
|
||||
directory and check the "record" box.
|
||||
* Be sure to assign each stream you want to capture to a sample file
|
||||
directory and check the "record" box.
|
||||
|
||||
* `flush_if_sec` should typically be 120 seconds. This causes the database to
|
||||
be flushed when the first instant of one of this stream's completed
|
||||
recordings is 2 minutes old. A "recording" is a segment of a video
|
||||
stream that is 60–120 seconds when first establishing the stream, about
|
||||
60 seconds midstream, and shorter when an error or server shutdown
|
||||
terminates the stream. Thus, a value just below 60 will cause the
|
||||
database to be flushed once per minute per stream in the steady state. A
|
||||
value around 180 will cause the database to be once every 3 minutes per
|
||||
stream, or less frequently if other streams cause flushes first. Lower
|
||||
values cause less video to be lost on power loss. Higher values reduce
|
||||
wear on the SSD holding the SQLite database, particularly when you have
|
||||
many cameras and when you record both the "main" and "sub" streams of
|
||||
each camera.
|
||||
* `flush_if_sec` should typically be 120 seconds. This causes the database to
|
||||
be flushed when the first instant of one of this stream's completed
|
||||
recordings is 2 minutes old. A "recording" is a segment of a video
|
||||
stream that is 60–120 seconds when first establishing the stream,
|
||||
about 60 seconds midstream, and shorter when an error or server
|
||||
shutdown terminates the stream. Thus, a value just below 60 will
|
||||
cause the database to be flushed once per minute per stream in the
|
||||
steady state. A value around 180 will cause the database to be once
|
||||
every 3 minutes per stream, or less frequently if other streams cause
|
||||
flushes first. Lower values cause less video to be lost on power
|
||||
loss. Higher values reduce wear on the SSD holding the SQLite
|
||||
database, particularly when you have many cameras and when you record
|
||||
both the "main" and "sub" streams of each camera.
|
||||
|
||||
3. Assign disk space to your cameras back in "Directories and retention".
|
||||
Leave a little slack between the total limit and the filesystem capacity,
|
||||
@ -202,7 +209,7 @@ In the user interface,
|
||||
4. Add a user for yourself (and optionally others) under "Users". You'll need
|
||||
this to access the web UI once you enable authentication.
|
||||
|
||||
## Starting it up
|
||||
### Starting it up
|
||||
|
||||
Note that at this stage, Moonfire NVR's web interface is **insecure**: it
|
||||
doesn't use `https` and doesn't require you to authenticate
|
||||
|
@ -1,4 +1,12 @@
|
||||
# Moonfire NVR Schema Guide
|
||||
# Moonfire NVR Schema Guide <!-- omit in toc -->
|
||||
|
||||
* [Upgrading](#upgrading)
|
||||
* [Procedure](#procedure)
|
||||
* [Unversioned to version 0](#unversioned-to-version-0)
|
||||
* [Version 0 to version 1](#version-0-to-version-1)
|
||||
* [Version 1 to version 2 to version 3](#version-1-to-version-2-to-version-3)
|
||||
* [Version 3 to version 4 to version 5](#version-3-to-version-4-to-version-5)
|
||||
* [Version 6](#version-6)
|
||||
|
||||
This document has notes about the Moonfire NVR storage schema. As described in
|
||||
[README.md](../README.md), this consists of two kinds of state:
|
||||
@ -26,42 +34,46 @@ read-only mode prior to deleting the old database.
|
||||
First ensure there is sufficient space available for four copies of the
|
||||
SQLite database:
|
||||
|
||||
* copy 1: the copy to upgrade
|
||||
* copy 2: a backup you manually create so that you can restore if you
|
||||
discover a problem while running the new software against the upgraded
|
||||
database in read-only mode. If disk space is tight, you can save this
|
||||
to a different filesystem than the primary copy.
|
||||
* copies 3 and 4: internal copies made and destroyed by Moonfire NVR and
|
||||
SQLite during the upgrade:
|
||||
* copy 1: the copy to upgrade
|
||||
* copy 2: a backup you manually create so that you can restore if you
|
||||
discover a problem while running the new software against the upgraded
|
||||
database in read-only mode. If disk space is tight, you can save this
|
||||
to a different filesystem than the primary copy.
|
||||
* copies 3 and 4: internal copies made and destroyed by Moonfire NVR and
|
||||
SQLite during the upgrade:
|
||||
|
||||
* during earlier steps, possibly duplicate copies of tables, which
|
||||
may occupy space both in the main database and the journal
|
||||
* during the final vacuum step, a complete database copy
|
||||
* during earlier steps, possibly duplicate copies of tables, which
|
||||
may occupy space both in the main database and the journal
|
||||
* during the final vacuum step, a complete database copy
|
||||
|
||||
If disk space is tight, and you are _very careful_, you can skip these
|
||||
copies with the `--preset-journal=off --no-vacuum` arguments to
|
||||
the updater. If you aren't confident in your ability to do this, *don't
|
||||
do it*. If you are confident, take additional safety precautions anyway:
|
||||
If disk space is tight, and you are _very careful_, you can skip these
|
||||
copies with the `--preset-journal=off --no-vacuum` arguments to
|
||||
the updater. If you aren't confident in your ability to do this, *don't
|
||||
do it*. If you are confident, take additional safety precautions anyway:
|
||||
|
||||
* double-check you have the full backup described above. Without the
|
||||
journal any problems during the upgrade will corrupt your database
|
||||
and you will need to restore.
|
||||
* ensure you re-enable journalling via `pragma journal_mode = wal;`
|
||||
before using the upgraded database, or any problems after the
|
||||
upgrade will corrupt your database. The upgrade procedure should do
|
||||
this automatically, but you will want to verify by hand that you are
|
||||
no longer in the dangerous mode.
|
||||
* double-check you have the full backup described above. Without the
|
||||
journal any problems during the upgrade will corrupt your database
|
||||
and you will need to restore.
|
||||
* ensure you re-enable journalling via `pragma journal_mode = wal;`
|
||||
before using the upgraded database, or any problems after the
|
||||
upgrade will corrupt your database. The upgrade procedure should do
|
||||
this automatically, but you will want to verify by hand that you are
|
||||
no longer in the dangerous mode.
|
||||
|
||||
Next ensure Moonfire NVR is not running and does not automatically restart if
|
||||
the system is rebooted during the upgrade. If you followed the Docker
|
||||
instructions, you can do this as follows:
|
||||
|
||||
$ nvr stop
|
||||
```
|
||||
$ nvr stop
|
||||
```
|
||||
|
||||
Then back up your SQLite database. If you are using the default path, you can
|
||||
do so as follows:
|
||||
|
||||
$ sudo -u moonfire-nvr cp /var/lib/moonfire-nvr/db/db{,.pre-upgrade}
|
||||
```
|
||||
$ sudo -u moonfire-nvr cp /var/lib/moonfire-nvr/db/db{,.pre-upgrade}
|
||||
```
|
||||
|
||||
By default, the upgrade command will reset the SQLite `journal_mode` to
|
||||
`delete` prior to the upgrade. This works around a problem with
|
||||
@ -112,17 +124,17 @@ $ nvr run
|
||||
Hopefully your system is functioning correctly. If not, there are two options
|
||||
for restore; neither are easy:
|
||||
|
||||
* go back to your old database. There will be two classes of problems:
|
||||
* If the new system deleted any recordings, the old system will
|
||||
incorrectly believe they are still present. You could wait until all
|
||||
existing files are rotated away, or you could try to delete them
|
||||
manually from the database.
|
||||
* if the new system created any recordings, the old system will not
|
||||
know about them and will not delete them. Your disk may become full.
|
||||
You should find some way to discover these files and manually delete
|
||||
them.
|
||||
* undo the changes by hand. There's no documentation on this; you'll need
|
||||
to read the code and come up with a reverse transformation.
|
||||
* go back to your old database. There will be two classes of problems:
|
||||
* If the new system deleted any recordings, the old system will
|
||||
incorrectly believe they are still present. You could wait until all
|
||||
existing files are rotated away, or you could try to delete them
|
||||
manually from the database.
|
||||
* If the new system created any recordings, the old system will not
|
||||
know about them and will not delete them. Your disk may become full.
|
||||
You should find some way to discover these files and manually delete
|
||||
them.
|
||||
* undo the changes by hand. There's no documentation on this; you'll need
|
||||
to read the code and come up with a reverse transformation.
|
||||
|
||||
The `nvr check` command will show you what problems exist on your system.
|
||||
|
||||
@ -136,9 +148,9 @@ will also accept a version 0 database.
|
||||
|
||||
Version 0 makes two changes:
|
||||
|
||||
* it adds schema versioning, as described above.
|
||||
* it adds a column (`video_sync_samples`) to a database index to speed up
|
||||
certain operations.
|
||||
* it adds schema versioning, as described above.
|
||||
* it adds a column (`video_sync_samples`) to a database index to speed up
|
||||
certain operations.
|
||||
|
||||
There's a special procedure for this upgrade. The good news is that a backup
|
||||
is unnecessary; there's no risk with this procedure.
|
||||
@ -150,8 +162,10 @@ Then use `sqlite3` to manually edit the database. The default
|
||||
path is `/var/lib/moonfire-nvr/db/db`; if you've specified a different
|
||||
`--db_dir`, use that directory with a suffix of `/db`.
|
||||
|
||||
$ sudo -u moonfire-nvr sqlite3 /var/lib/moonfire-nvr/db/db
|
||||
sqlite3>
|
||||
```
|
||||
$ sudo -u moonfire-nvr sqlite3 /var/lib/moonfire-nvr/db/db
|
||||
sqlite3>
|
||||
```
|
||||
|
||||
At the prompt, run the following commands:
|
||||
|
||||
|
@ -1,4 +1,16 @@
|
||||
# Securing Moonfire NVR and exposing it to the Internet
|
||||
# Securing Moonfire NVR and exposing it to the Internet <!-- omit in toc -->
|
||||
|
||||
* [The problem](#the-problem)
|
||||
* [VPN or port forwarding?](#vpn-or-port-forwarding)
|
||||
* [Overview](#overview)
|
||||
* [1. Install a webserver](#1-install-a-webserver)
|
||||
* [2. Configure a static internal IP](#2-configure-a-static-internal-ip)
|
||||
* [3. Set up port forwarding](#3-set-up-port-forwarding)
|
||||
* [4. Configure a public DNS name](#4-configure-a-public-dns-name)
|
||||
* [5. Install a TLS certificate](#5-install-a-tls-certificate)
|
||||
* [6. Reconfigure Moonfire NVR](#6-reconfigure-moonfire-nvr)
|
||||
* [7. Configure the webserver](#7-configure-the-webserver)
|
||||
* [Verify it works](#verify-it-works)
|
||||
|
||||
## The problem
|
||||
|
||||
|
@ -1,27 +1,26 @@
|
||||
# Troubleshooting
|
||||
# Troubleshooting <!-- omit in toc -->
|
||||
|
||||
Here are some tips for diagnosing various problems with Moonfire NVR. Feel free
|
||||
to open an [issue](https://github.com/scottlamb/moonfire-nvr/issues) if you
|
||||
need more help.
|
||||
|
||||
* [Troubleshooting](#troubleshooting)
|
||||
* [Viewing Moonfire NVR's logs](#viewing-moonfire-nvrs-logs)
|
||||
* [Flushes](#flushes)
|
||||
* [Panic errors](#panic-errors)
|
||||
* [Slow operations](#slow-operations)
|
||||
* [Camera stream errors](#camera-stream-errors)
|
||||
* [Problems](#problems)
|
||||
* [Server errors](#server-errors)
|
||||
* [`Error: pts not monotonically increasing; got 26615520 then 26539470`](#error-pts-not-monotonically-increasing-got-26615520-then-26539470)
|
||||
* [Out of disk space](#out-of-disk-space)
|
||||
* [Database or filesystem corruption errors](#database-or-filesystem-corruption-errors)
|
||||
* [Configuration interface problems](#configuration-interface-problems)
|
||||
* [`moonfire-nvr config` displays garbage](#moonfire-nvr-config-displays-garbage)
|
||||
* [Browser user interface problems](#browser-user-interface-problems)
|
||||
* [Live stream always fails with `ws close: 1006`](#live-stream-always-fails-with-ws-close-1006)
|
||||
* [Errors in kernel logs](#errors-in-kernel-logs)
|
||||
* [UAS errors](#uas-errors)
|
||||
* [Filesystem errors](#filesystem-errors)
|
||||
* [Viewing Moonfire NVR's logs](#viewing-moonfire-nvrs-logs)
|
||||
* [Flushes](#flushes)
|
||||
* [Panic errors](#panic-errors)
|
||||
* [Slow operations](#slow-operations)
|
||||
* [Camera stream errors](#camera-stream-errors)
|
||||
* [Problems](#problems)
|
||||
* [Server errors](#server-errors)
|
||||
* [`Error: pts not monotonically increasing; got 26615520 then 26539470`](#error-pts-not-monotonically-increasing-got-26615520-then-26539470)
|
||||
* [Out of disk space](#out-of-disk-space)
|
||||
* [Database or filesystem corruption errors](#database-or-filesystem-corruption-errors)
|
||||
* [Configuration interface problems](#configuration-interface-problems)
|
||||
* [`moonfire-nvr config` displays garbage](#moonfire-nvr-config-displays-garbage)
|
||||
* [Browser user interface problems](#browser-user-interface-problems)
|
||||
* [Live stream always fails with `ws close: 1006`](#live-stream-always-fails-with-ws-close-1006)
|
||||
* [Errors in kernel logs](#errors-in-kernel-logs)
|
||||
* [UAS errors](#uas-errors)
|
||||
* [Filesystem errors](#filesystem-errors)
|
||||
|
||||
## Viewing Moonfire NVR's logs
|
||||
|
||||
|
Loading…
Reference in New Issue
Block a user