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VncProxy CircleCI MIT Licensed

An RFB proxy, written in go that can save and replay FBS files

Executables (see releases)

Usage:

recorder -recFile=./recording.rbs -targHost=192.168.0.100 -targPort=5903 -targPass=@@@@@
player -fbsFile=./myrec.fbs -tcpPort=5905
proxy -recDir=./recordings/ -targHost=192.168.0.100 -targPort=5903 -targPass=@@@@@ -tcpPort=5903 -wsPort=5905 -vncPass=@!@!@!

Code usage examples

Architecture

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Communication to vnc-server & vnc-client are done in the RFB binary protocol in the standard ways. Internal communication inside the proxy is done by listeners (a pub-sub system) that provide a stream of bytes, parsed by delimiters which provide information about RFB message start & type / rectangle start / communication closed, etc. This method allows for minimal delays in transfer, while retaining the ability to buffer and manipulate any part of the protocol.

For the client messages which are smaller, we send fully parsed messages going trough the same listener system. Currently client messages are used to determine the correct pixel format, since the client can change it by sending a SetPixelFormatMessage.

Tracking the bytes that are read from the actual vnc-server is made simple by using the RfbReadHelper (implements io.Reader) which sends the bytes to the listeners, this negates the need for manually keeping track of each byte read in order to write it into the recorder.

RFB Encoding-reader implementations do not decode pixel information, since this is not required for the proxy implementation.

This listener system was chosen over direct use of channels, since it allows the listening side to decide whether or not it wants to run in parallel, in contrast having channels inside the server/client objects which require you to create go routines (this creates problems when using go's native websocket implementation)

The Recorder uses channels and runs in parallel to avoid hampering the communication through the proxy.

Image of Arch

The code is based on several implementations of go-vnc including the original one by Mitchell Hashimoto, and the recentely active fork by Vasiliy Tolstov.