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authorMaZderMind <github@mazdermind.de>2015-07-09 18:20:32 +0200
committerMaZderMind <github@mazdermind.de>2015-07-09 18:20:32 +0200
commitbeea5f6f54513e0a94e567dc945c28e570cb79df (patch)
tree981a632974dfee75d663b3b12de9756d86ce8ec4
parent16cfb8c85896d9b1d4ad9a0d92c28e8dcc1324ca (diff)
First run of Documentation
-rw-r--r--README.md14
-rw-r--r--voctocore/README.md64
2 files changed, 67 insertions, 11 deletions
diff --git a/README.md b/README.md
index 24c341b..661aac4 100644
--- a/README.md
+++ b/README.md
@@ -1,4 +1,14 @@
# Voctomix
-Building a HD-Compatible, Multi-Track-Audio-Capable Software-Based Live-Video-Mixer for the VOC.
+The [C3Voc](https://c3voc.de/) creates Lecture Recordings from German Hacker/Nerd Conferences. We have used [dvswitch](http://dvswitch.alioth.debian.org/wiki/) very successfully in the past but it has some serious limitations, which in 2014 we started looking for a replacement. We tested [snowmix](http://sourceforge.net/projects/snowmix/) and [gst-switch](https://github.com/timvideos/gst-switch) and while both did some things we wanted right, we realised that no existing tool would be able to fulfil all our whishes. Furthermore both are a nightmare to extend. So we decided to build our own Implementation of a Live-Video-Mixer.
-Testet on Ubuntu 14.10 with the bundled gstreamer 1.4.3
+## Subprojects
+The Voctomix Project consists of three parts:
+ - [VoctoVore](./voctocore/), the videomixer core-process that does the actual video- and audio crunching
+ - [Voctogui](./voctogui/), a GUI implementation in GTK controlling the core's functionality and giving visual feedback of the mixed video
+ - Voctotools (tbd.), a Collection of Tools and Examples on how to talk to the core-process, feeding and reciving video-streams
+
+## Patch policy
+The main Goal of Voxtomix is to build a Videomixer that suites the C3Vocs requirements, which means it will not directly suite your Requirements. We are not planning to make it an all-purpose Tool. Instead, you are encouraged to fork Voctomix and modify it to your needs. The code should be simple enough to do this and we will help you deciding with that, if required. Because of this we probably won't accept Feature-Patches which add features the C3Voc doesn't need.
+
+## Contact
+To get in touch with us we'd ask to join #voc on the hackint IRC network.
diff --git a/voctocore/README.md b/voctocore/README.md
index e47ec51..14855e9 100644
--- a/voctocore/README.md
+++ b/voctocore/README.md
@@ -1,13 +1,31 @@
-# Server-Pipeline Structure
-````
+# Voctocore - The videomixer core-process
+
+## Design goals
+Our Design is heavily influenced by gst-switch. We wanted a small videomixer core-process, whose sourcecode can be read and understand in about a weekend.
+All Sources (Cameras, Slide-Grabbers) and Sinks (Streaming, Recording) should be separate Processes. As far as possible we wanted to reuse our existing and well-tested ffmpeg Commandlines for streaming and recording. It should be possible to connect additional Sinks at any time while the number of Sources is predefined in our Setup. All sources and sinks should be able to die and get restarted without taking the core process down.
+While Sources ans Sinks all run on the same Machine, Control- or Monitoring-Clients, for example a GUI, should be able to run on a different machine and connect to the core-process via Gigabit Ethernet. The core-process should be controllable by a very simple protocol which can easily be scripted or spoken with usual networking tools.
+
+## Design decisions
+To meet our goal of "read and understand in about a weekend" python was chosen as language for the high-level parts, with [GStreamer](http://gstreamer.freedesktop.org/) for the low-level media handling. GStreamer can be controlled via the [PyGI](https://wiki.gnome.org/action/show/Projects/PyGObject) bindings from Python.
+As an Idea borrowed from gst-switch, all Video- and Audio-Streams to and from the core are handled via TCP-Connections. Because they transport raw Video-Frames the only reasonable transport is via the loopback interface or a dedicated GBit-NIC (1920×1080×2 (I420)×8 (Bits)×25 (fps) = ~830 MBit/s). Nevertheless TCP is a quite efficient and good supported transport mechanism. For compatibility with ffmpeg and because of its good properties when streamed over TCP, [Matroska](http://www.matroska.org/) was chosen as a Container.
+
+The ubiquitous Input/Output-Format into the core-process is therefore Raw I420 Frames and Raw S16LE Audio in a Matroska container for Timestamping via TCP over localhost. Network handling is done in python, because it allows for greater flexibility. After the TCP connection is ready, its file descriptor is passed to GStreamer which handles the low-level read/write operations. To be able to attach/detach sinks, the `multifdsink`-Element can be used. For the Sources it's more complicated:
+
+When a source is not connected, its video and audio stream must be substituted with black frames ans silence, to that the remaining parts of the pipeline can keep on running. To achive this, a separate GStreamer-Pipeline is launched for an incoming Source-Connection and destroyed in case of a disconnect or an error. To pass Video -and Audio-Buffers between the Source-Pipelines and the other parts of the Mixer, we make use of the `inter(audio/video)(sink/source)`-Elements. `intervideosrc` and `interaudiosrc` implement the creation of black frames and silence, in case no source is connected or the source broke down somehow.
-17000… VSource (Stream-Blanker) -----\
-18000 ASource (Stream-Blanker) ------\
+If enabled in Config, the core process offers two formats for most outputs: Raw-Frames in mkv as described above, which should be used to feed recording or streaming processes running on the same machine. For the GUI which usually runs on a different computer, they are not suited because of the bandwidth requirements (1920×1080 I420 @25fps = 791 MBit/s). For this reason the Servers offers Preview-Ports for each Input and the Main-Mix, which serves the same content, but the video frames there are jpeg compressed, combined with uncompressed S16LE audio and encapsulated in mkv.
+
+Also, if enabled in Config, another Building-Block is chained after the Main-Mix: the StreamBlanker. It is used in Cases when there should be no Stream, for example in Breaks between
+
+## Block-Level Diagram
+````
+17000… VSource** (Stream-Blanker) ---\
+18000 ASource** (Stream-Blanker) ----\
\
16000 VSource (Background) \
\ \
--> VideoMix \
- / \ -> StreamBlanker -> StreamOutputPort 15000
+ / \ -> StreamBlanker** -> StreamOutputPort** 15000
/ \ /
/ ------> OutputPort 11000
/ / \-> Encoder* -> PreviewPort* 12000
@@ -17,11 +35,37 @@
10000… AVSource --> MirrorPort 13000…
\-> Encoder* -> PreviewPort* 14000…
-*) only when encode_previews=true is configured
+9999 Control-Server
+
+*) only when [previews] enabled=true is configured
+**) only when [stream-blanker] enabled=true is configured
````
-# Control Protocol
-TCP-Port 9999
+## Network Ports Listing
+Ports that will accept Raw I420 Frames and Raw S16LE Audio in a Matroska container:
+ - 10000, 10001, … – Main Video-Sources, depending on the number of configured Sources
+
+Ports that will accept Raw I420 Frames without Audio in a Matroska container:
+ - 16000 Mixer – Background Loop
+ - 17000, 17001, … – Stream-Blanker Video-Input, depending on the number of configured Sources
+
+Ports that will accept Raw S16LE Audio wihout Video in a Matroska container:
+ - 18000 – Stream-Blanker Audio-Input
+
+Ports that will provide Raw I420 Frames and Raw S16LE Audio in a Matroska container:
+ - 13000, 13001, … – Main Video-Source Mirrors, depending on the number of configured Sources
+ - 11000 – Main Mixer Output
+ - 15000 – Stream Output – only when [stream-blanker] enabled=true is configured
+
+Ports that will provide JPEG Frames and Raw S16LE Audio in a Matroska container – only when [previews] enabled=true is configured
+ - 14000, 14001, … – Main Video-Source Mirrors, depending on the number of configured Sources
+ - 12000 – Main Mixer Output
+
+Port 9999 will Accept Control Protocol Connections.
+
+## Control Protocol
+To Control operation of the Video-Mixer, a simple line-based TCP-Protocol is used. TCP-Port 9999 // FIXME
+
````
< set_video_a cam1
> ok
@@ -54,7 +98,7 @@ TCP-Port 9999
````
-# Messages
+## Messages
Messages are Client-to-Client information that don't touch the server, while being distributed on its control-socket:
````
< message foo bar moo
@@ -64,3 +108,5 @@ Messages are Client-to-Client information that don't touch the server, while bei
> signal message foo bar moo
````
+
+## Configuration