This document is based on “The RFB Protocol” by Tristan Richardson of RealVNC Ltd (formerly of Olivetti Research Ltd / AT&T Labs Cambridge).
Contents
RFB (“remote framebuffer”) is a simple protocol for remote access to graphical user interfaces. Because it works at the framebuffer level it is applicable to all windowing systems and applications, including X11, Windows and Macintosh. RFB is the protocol used in VNC (Virtual Network Computing).
The remote endpoint where the user sits (i.e. the display plus keyboard and/or pointer) is called the RFB client or viewer. The endpoint where changes to the framebuffer originate (i.e. the windowing system and applications) is known as the RFB server.
RFB is truly a “thin client” protocol. The emphasis in the design of the RFB protocol is to make very few requirements of the client. In this way, clients can run on the widest range of hardware, and the task of implementing a client is made as simple as possible.
The protocol also makes the client stateless. If a client disconnects from a given server and subsequently reconnects to that same server, the state of the user interface is preserved. Furthermore, a different client endpoint can be used to connect to the same RFB server. At the new endpoint, the user will see exactly the same graphical user interface as at the original endpoint. In effect, the interface to the user’s applications becomes completely mobile. Wherever suitable network connectivity exists, the user can access their own personal applications, and the state of these applications is preserved between accesses from different locations. This provides the user with a familiar, uniform view of the computing infrastructure wherever they go.
The display side of the protocol is based around a single graphics primitive: “put a rectangle of pixel data at a given x,y position”. At first glance this might seem an inefficient way of drawing many user interface components. However, allowing various different encodings for the pixel data gives us a large degree of flexibility in how to trade off various parameters such as network bandwidth, client drawing speed and server processing speed.
A sequence of these rectangles makes a framebuffer update (or simply update). An update represents a change from one valid framebuffer state to another, so in some ways is similar to a frame of video. The rectangles in an update are usually disjoint but this is not necessarily the case.
The update protocol is demand-driven by the client. That is, an update is only sent from the server to the client in response to an explicit request from the client. This gives the protocol an adaptive quality. The slower the client and the network are, the lower the rate of updates becomes. With typical applications, changes to the same area of the framebuffer tend to happen soon after one another. With a slow client and/or network, transient states of the framebuffer can be ignored, resulting in less network traffic and less drawing for the client.
In its simplest form, the RFB protocol uses a single, rectangular framebuffer. All updates are contained within this buffer and may not extend outside of it. A client with basic functionality simply presents this buffer to the user, padding or cropping it as necessary to fit the user’s display.
More advanced RFB clients and servers have the ability to extend this model and add multiple screens. The purpose being to create a server-side representation of the client’s physical layout. Applications can use this information to properly position themselves with regard to screen borders.
In the multiple-screen model, there is still just a single framebuffer and framebuffer updates are unaffected by the screen layout. This assures compatibility between basic clients and advanced servers. Screens are added to this model and act like viewports into the framebuffer. A basic client acts as if there is a single screen covering the entire framebuffer.
The server may support up to 255 screens, which must be contained fully within the current framebuffer. Multiple screens may overlap partially or completely.
The client must keep track of the contents of the entire framebuffer, not just the areas currently covered by a screen. Similarly, the server is free to use encodings that rely on contents currently not visible inside any screen. For example it may issue a CopyRect rectangle from any part of the framebuffer that should already be known to the client.
The client can request changes to the framebuffer size and screen layout. The server is free to approve or deny these requests at will, but must always inform the client of the result. See the SetDesktopSize message for details.
If the framebuffer size changes, for whatever reason, then all data in it is invalidated and considered undefined. The server must not use any encoding that relies on the previous framebuffer contents. Note however that the semantics for DesktopSize are not well-defined and do not follow this behaviour in all server implementations. See the DesktopSize Pseudo-encoding chapter for full details.
Changing only the screen layout does not affect the framebuffer contents. The client must therefore keep track of the current framebuffer dimensions and compare it with the one received in the ExtendedDesktopSize rectangle. Only when they differ may it discard the framebuffer contents.
The input side of the protocol is based on a standard workstation model of a keyboard and multi-button pointing device. Input events are simply sent to the server by the client whenever the user presses a key or pointer button, or whenever the pointing device is moved. These input events can also be synthesised from other non-standard I/O devices. For example, a pen-based handwriting recognition engine might generate keyboard events.
If you have an input source that does not fit this standard workstation model, the General Input Interface (gii) protocol extension provides possibilities for input sources with more axes, relative movement and more buttons.
Initial interaction between the RFB client and server involves a negotiation of the format and encoding with which pixel data will be sent. This negotiation has been designed to make the job of the client as easy as possible. The bottom line is that the server must always be able to supply pixel data in the form the client wants. However if the client is able to cope equally with several different formats or encodings, it may choose one which is easier for the server to produce.
Pixel format refers to the representation of individual colours by pixel values. The most common pixel formats are 24-bit or 16-bit “true colour”, where bit-fields within the pixel value translate directly to red, green and blue intensities, and 8-bit “colour map” where an arbitrary mapping can be used to translate from pixel values to the RGB intensities.
Encoding refers to how a rectangle of pixel data will be sent on the wire. Every rectangle of pixel data is prefixed by a header giving the X,Y position of the rectangle on the screen, the width and height of the rectangle, and an encoding type which specifies the encoding of the pixel data. The data itself then follows using the specified encoding.
There are a number of ways in which the protocol can be extended:
Under no circumstances should you use a different protocol version number. If you use a different protocol version number then you are not RFB / VNC compatible.
All three mechanisms for extensions are handled by RealVNC Ltd. To ensure that you stay compatible with the RFB protocol it is important that you contact RealVNC Ltd to make sure that your encoding types and security types do not clash. Please see the RealVNC website at http://www.realvnc.com for details of how to contact them.
The encoding used for strings in the protocol has historically often been unspecified, or has changed between versions of the protocol. As a result, there are a lot of implementations which use different, incompatible encodings. Commonly those encodings have been ISO 8859-1 (also known as Latin-1) or Windows code pages.
It is strongly recommended that new implementations use the UTF-8 encoding for these strings. This allows full unicode support, yet retains good compatibility with older RFB implementations.
New protocol additions that do not have a legacy problem should mandate the UTF-8 encoding to provide full character support and to avoid any issues with ambiguity.
All clients and servers should be prepared to receive invalid UTF-8 sequences at all times. These can occur as a result of historical ambiguity or because of bugs. Neither case should result in lost protocol synchronization.
Handling an invalid UTF-8 sequence is largely dependent on the role that string plays. Modifying the string should only be done when the string is only used in the user interface. It should be obvious in that case that the string has been modified, e.g. by appending a notice to the string.
The RFB protocol can operate over any reliable transport, either byte- stream or message-based. Conventionally it is used over a TCP/IP connection. There are three stages to the protocol. First is the handshaking phase, the purpose of which is to agree upon the protocol version and the type of security to be used. The second stage is an initialisation phase where the client and server exchange ClientInit and ServerInit messages. The final stage is the normal protocol interaction. The client can send whichever messages it wants, and may receive messages from the server as a result. All these messages begin with a message-type byte, followed by any message-specific data.
The following descriptions of protocol messages use the basic types U8, U16, U32, S8, S16, S32. These represent respectively 8, 16 and 32-bit unsigned integers and 8, 16 and 32-bit signed integers. All multiple byte integers (other than pixel values themselves) are in big endian order (most significant byte first).
However, some protocol extensions use protocol messages that have types that may be in little endian order. These endian agnostic types are EU16, EU32, ES16, ES32, with some extension specific indicator of the endianess.
The type PIXEL is taken to mean a pixel value of bytesPerPixel bytes, where 8 * bytesPerPixel is the number of bits-per-pixel as agreed by the client and server, either in the ServerInit message (ServerInit) or a SetPixelFormat message (SetPixelFormat).
Handshaking begins by the server sending the client a ProtocolVersion message. This lets the client know which is the highest RFB protocol version number supported by the server. The client then replies with a similar message giving the version number of the protocol which should actually be used (which may be different to that quoted by the server). A client should never request a protocol version higher than that offered by the server. It is intended that both clients and servers may provide some level of backwards compatibility by this mechanism.
The only published protocol versions at this time are 3.3, 3.7, 3.8 (version 3.5 was wrongly reported by some clients, but this should be interpreted by all servers as 3.3). Addition of a new encoding or pseudo-encoding type does not require a change in protocol version, since a server can simply ignore encodings it does not understand.
The ProtocolVersion message consists of 12 bytes interpreted as a string of ASCII characters in the format “RFB xxx.yyy\n” where xxx and yyy are the major and minor version numbers, padded with zeros.
No. of bytes | Value |
---|---|
12 | “RFB 003.003\n” (hex 52 46 42 20 30 30 33 2e 30 30 33 0a) |
or
No. of bytes | Value |
---|---|
12 | “RFB 003.007\n” (hex 52 46 42 20 30 30 33 2e 30 30 37 0a) |
or
No. of bytes | Value |
---|---|
12 | “RFB 003.008\n” (hex 52 46 42 20 30 30 33 2e 30 30 38 0a) |
Once the protocol version has been decided, the server and client must agree on the type of security to be used on the connection.
The server lists the security types which it supports:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | number-of-security-types |
number-of-security-types | U8 array | security-types |
If the server listed at least one valid security type supported by the client, the client sends back a single byte indicating which security type is to be used on the connection:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | security-type |
If number-of-security-types is zero, then for some reason the connection failed (e.g. the server cannot support the desired protocol version). This is followed by a string describing the reason (where a string is specified as a length followed by that many ASCII characters):
No. of bytes | Type | Description |
---|---|---|
4 | U32 | reason-length |
reason-length | U8 array | reason-string |
The server closes the connection after sending the reason-string.
The server decides the security type and sends a single word:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | security-type |
The security-type may only take the value 0, 1 or 2. A value of 0 means that the connection has failed and is followed by a string giving the reason, as described above.
The security types defined in this document are:
Number | Name |
---|---|
0 | Invalid |
1 | None |
2 | VNC Authentication |
16 | Tight Security Type |
Other registered security types are:
Number | Name |
---|---|
3-4 | RealVNC |
5 | RA2 |
6 | RA2ne |
7-15 | RealVNC |
17 | Ultra |
18 | TLS |
19 | VeNCrypt |
20 | SASL |
21 | MD5 hash authentication |
22 | xvp |
30-35 | Apple Inc. |
128-255 | RealVNC |
The official, up-to-date list is maintained by IANA [1].
[1] | (1, 2, 3, 4) http://www.iana.org/assignments/rfb/rfb.xml |
Once the security-type has been decided, data specific to that security-type follows (see Security Types for details). At the end of the security handshaking phase, the protocol normally continues with the SecurityResult message.
Note that after the security handshaking phase, it is possible that further protocol data is over an encrypted or otherwise altered channel.
The server sends a word to inform the client whether the security handshaking was successful.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
4 | U32 | status: | |
0 | OK | ||
1 | failed | ||
2 | failed, too many attempts [2] |
[2] | Only valid if the Tight Security Type is enabled. |
If successful, the protocol passes to the initialisation phase (Initialisation Messages).
If unsuccessful, the server sends a string describing the reason for the failure, and then closes the connection:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | reason-length |
reason-length | U8 array | reason-string |
No authentication is needed and protocol data is to be sent unencrypted.
VNC authentication is to be used and protocol data is to be sent unencrypted. The server sends a random 16-byte challenge:
No. of bytes | Type | Description |
---|---|---|
16 | U8 | challenge |
The client encrypts the challenge with DES, using a password supplied by the user as the key, and sends the resulting 16-byte response:
No. of bytes | Type | Description |
---|---|---|
16 | U8 | response |
The protocol continues with the SecurityResult message.
The Tight security type is a generic protocol extension that allows for three things:
The Tight security type is under the control of the TightVNC project, and any new numbers must be registered with that project before they can be added to any of the lists of Tight capabilities. It is strongly recommended that any messages and security types registered with RealVNC are also registered with the TightVNC project (register security types as Tight authentication capabilities) in order to eliminate clashes as much as is possible. Same thing with new encodings, but in that case the problem is not as severe as the TightVNC project are not using any encodings that are not registered with RealVNC. Please see the TightVNC website at http://www.tightvnc.com/ for details on how to contact the project.
After the Tight security type has been selected, the server starts by sending a list of supported tunnels, in order of preference:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | number-of-tunnels |
followed by number-of-tunnels repetitions of the following:
No. of bytes | Type | Description |
---|---|---|
16 | CAPABILITY | tunnel |
where CAPABILITY is
No. of bytes | Type | Description |
---|---|---|
4 | S32 | code |
4 | U8 array | vendor |
8 | U8 array | signature |
Note that the code is not the only thing identifying a capability. The client must ensure that all members of the structure match before using the capability. Also note that code is U32 in the original Tight documentation and implementation, but since code is used to hold encoding numbers we have selected S32 in this document.
The following tunnel capabilities are registered:
Code | Vendor | Signature | Description |
---|---|---|---|
0 | “TGHT“ | “NOTUNNEL“ | No tunneling |
If number-of-tunnels is non-zero, the client has to request a tunnel from the list with a tunneling method request:
No. of bytes | Type | Description |
---|---|---|
4 | S32 | code |
If number-of-tunnels is zero, the client must make no such request, instead the server carries on with sending the list of supported authentication types, in order of preference:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | number-of-auth-types |
followed by number-of-auth-types repetitions of the following:
No. of bytes | Type | Description |
---|---|---|
16 | CAPABILITY | auth-type |
The following authentication capabilities are registered:
Code | Vendor | Signature | Description |
---|---|---|---|
1 | “STDV“ | “NOAUTH__“ | None |
2 | “STDV“ | “VNCAUTH_“ | VNC Authentication |
19 | “VENC“ | “VENCRYPT“ | VeNCrypt Security |
20 | “GTKV“ | “SASL____“ | Simple Authentication and Security Layer (SASL) |
129 | “TGHT“ | “ULGNAUTH“ | Unix Login Authentication |
130 | “TGHT“ | “XTRNAUTH“ | External Authentication |
If number-of-auth-types is non-zero, the client has to request an authentication type from the list with an authentication scheme request:
No. of bytes | Type | Description |
---|---|---|
4 | S32 | code |
For code 1, the protocol the proceeds at security type None and for code 2 it proceeds at security type VNC Authentication.
If number-of-auth-types is zero, the protocol the proceeds directly at security type None.
Note that the ServerInit message is extended when the Tight security type has been activated.
Once the client and server are sure that they’re happy to talk to one another using the agreed security type, the protocol passes to the initialisation phase. The client sends a ClientInit message followed by the server sending a ServerInit message.
No. of bytes | Type | Description |
---|---|---|
1 | U8 | shared-flag |
Shared-flag is non-zero (true) if the server should try to share the desktop by leaving other clients connected, zero (false) if it should give exclusive access to this client by disconnecting all other clients.
After receiving the ClientInit message, the server sends a ServerInit message. This tells the client the width and height of the server’s framebuffer, its pixel format and the name associated with the desktop:
No. of bytes | Type | Description |
---|---|---|
2 | U16 | framebuffer-width |
2 | U16 | framebuffer-height |
16 | PIXEL_FORMAT | server-pixel-format |
4 | U32 | name-length |
name-length | U8 array | name-string |
The text encoding used for name-string is historically undefined but it is strongly recommended to use UTF-8 (see String Encodings for more details).
PIXEL_FORMAT is defined as:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | bits-per-pixel |
1 | U8 | depth |
1 | U8 | big-endian-flag |
1 | U8 | true-colour-flag |
2 | U16 | red-max |
2 | U16 | green-max |
2 | U16 | blue-max |
1 | U8 | red-shift |
1 | U8 | green-shift |
1 | U8 | blue-shift |
3 | padding |
Server-pixel-format specifies the server’s natural pixel format. This pixel format will be used unless the client requests a different format using the SetPixelFormat message (SetPixelFormat).
Bits-per-pixel is the number of bits used for each pixel value on the wire. This must be greater than or equal to the depth which is the number of useful bits in the pixel value. Currently bits-per-pixel must be 8, 16 or 32. Less than 8-bit pixels are not yet supported. Big-endian-flag is non-zero (true) if multi-byte pixels are interpreted as big endian. Of course this is meaningless for 8 bits-per-pixel.
If true-colour-flag is non-zero (true) then the last six items specify how to extract the red, green and blue intensities from the pixel value. Red-max is the maximum red value (= 2^n - 1 where n is the number of bits used for red). Note this value is always in big endian order. Red-shift is the number of shifts needed to get the red value in a pixel to the least significant bit. Green-max, green-shift and blue-max, blue-shift are similar for green and blue. For example, to find the red value (between 0 and red-max) from a given pixel, do the following:
If true-colour-flag is zero (false) then the server uses pixel values which are not directly composed from the red, green and blue intensities, but which serve as indices into a colour map. Entries in the colour map are set by the server using the SetColourMapEntries message (SetColourMapEntries).
If the Tight Security Type is activated, the server init message is extended with an interaction capabilities section:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
2 | U16 | number-of-server-messages | |
2 | U16 | number-of-client-messages | |
2 | U16 | number-of-encodings | |
2 | U16 | 0 | padding |
followed by number-of-server-messages repetitions of the following:
No. of bytes | Type | Description |
---|---|---|
16 | CAPABILITY | server-message |
followed by number-of-client-messages repetitions of the following:
No. of bytes | Type | Description |
---|---|---|
16 | CAPABILITY | client-message |
followed by number-of-encodings repetitions of the following:
No. of bytes | Type | Description |
---|---|---|
16 | CAPABILITY | encoding |
The following server-message capabilities are registered:
Code | Vendor | Signature | Description |
---|---|---|---|
130 | “TGHT“ | “FTS_LSDT“ | File List Data |
131 | “TGHT“ | “FTS_DNDT“ | File Download Data |
132 | “TGHT“ | “FTS_UPCN“ | File Upload Cancel |
133 | “TGHT“ | “FTS_DNFL“ | File Download Failed |
150 | “TGHT“ | “CUS_EOCU“ | End Of Continuous Updates |
253 | “GGI_“ | “GII_SERV“ | gii Server Message |
The following client-message capabilities are registered:
Code | Vendor | Signature | Description |
---|---|---|---|
130 | “TGHT“ | “FTC_LSRQ“ | File List Request |
131 | “TGHT“ | “FTC_DNRQ“ | File Download Request |
132 | “TGHT“ | “FTC_UPRQ“ | File Upload Request |
133 | “TGHT“ | “FTC_UPDT“ | File Upload Data |
134 | “TGHT“ | “FTC_DNCN“ | File Download Cancel |
135 | “TGHT“ | “FTC_UPFL“ | File Upload Failed |
136 | “TGHT“ | “FTC_FCDR“ | File Create Directory Request |
150 | “TGHT“ | “CUC_ENCU“ | Enable/Disable Continuous Updates |
151 | “TGHT“ | “VRECTSEL“ | Video Rectangle Selection |
253 | “GGI_“ | “GII_CLNT“ | gii Client Message |
The following encoding capabilities are registered:
Code | Vendor | Signature | Description |
---|---|---|---|
0 | “STDV“ | “RAW_____“ | Raw Encoding |
1 | “STDV“ | “COPYRECT“ | CopyRect Encoding |
2 | “STDV“ | “RRE_____“ | RRE Encoding |
4 | “STDV“ | “CORRE___“ | CoRRE Encoding |
5 | “STDV“ | “HEXTILE_“ | Hextile Encoding |
6 | “TRDV“ | “ZLIB____“ | ZLib Encoding |
7 | “TGHT“ | “TIGHT___“ | Tight Encoding |
8 | “TRDV“ | “ZLIBHEX_“ | ZLibHex Encoding |
-32 | “TGHT“ | “JPEGQLVL“ | JPEG Quality Level Pseudo-encoding |
-223 | “TGHT“ | “NEWFBSIZ“ | DesktopSize Pseudo-encoding (New FB Size) |
-224 | “TGHT“ | “LASTRECT“ | LastRect Pseudo-encoding |
-232 | “TGHT“ | “POINTPOS“ | Pointer Position |
-239 | “TGHT“ | “RCHCURSR“ | Cursor Pseudo-encoding (Rich Cursor) |
-240 | “TGHT“ | “X11CURSR“ | X Cursor Pseudo-encoding |
-256 | “TGHT“ | “COMPRLVL“ | Compression Level Pseudo-encoding |
-305 | “GGI_“ | “GII_____“ | gii Pseudo-encoding |
-512 | “TRBO“ | “FINEQLVL“ | JPEG Fine-Grained Quality Level Pseudo-encoding |
-768 | “TRBO“ | “SSAMPLVL“ | JPEG Subsampling Level Pseudo-encoding |
Note that the server need not (but it may) list the “RAW_____” capability since it must be supported anyway.
The client to server message types that all servers must support are:
Number | Name |
---|---|
0 | SetPixelFormat |
2 | SetEncodings |
3 | FramebufferUpdateRequest |
4 | KeyEvent |
5 | PointerEvent |
6 | ClientCutText |
Optional message types are:
Number | Name |
---|---|
7 | FileTransfer |
8 | SetScale |
9 | SetServerInput |
10 | SetSW |
11 | TextChat |
12 | KeyFrameRequest |
13 | KeepAlive |
14 | Possibly used in UltraVNC |
15 | SetScaleFactor |
16-19 | Possibly used in UltraVNC |
20 | RequestSession |
21 | SetSession |
80 | NotifyPluginStreaming |
127 | VMWare |
128 | Car Connectivity |
150 | EnableContinuousUpdates |
248 | ClientFence |
249 | OLIVE Call Control |
250 | xvp Client Message |
251 | SetDesktopSize |
252 | tight |
253 | gii Client Message |
254 | VMWare |
255 | QEMU Client Message |
The official, up-to-date list is maintained by IANA [1].
Note that before sending a message with an optional message type a client must have determined that the server supports the relevant extension by receiving some extension-specific confirmation from the server.
Sets the format in which pixel values should be sent in FramebufferUpdate messages. If the client does not send a SetPixelFormat message then the server sends pixel values in its natural format as specified in the ServerInit message (ServerInit).
If true-colour-flag is zero (false) then this indicates that a “colour map” is to be used. The server can set any of the entries in the colour map using the SetColourMapEntries message (SetColourMapEntries). Immediately after the client has sent this message the colour map is empty, even if entries had previously been set by the server.
Note that a client must not have an outstanding FramebufferUpdateRequest when it sends SetPixelFormat as it would be impossible to determine if the next FramebufferUpdate is using the new or the previous pixel format.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 0 | message-type |
3 | padding | ||
16 | PIXEL_FORMAT | pixel-format |
where PIXEL_FORMAT is as described in ServerInit:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | bits-per-pixel |
1 | U8 | depth |
1 | U8 | big-endian-flag |
1 | U8 | true-colour-flag |
2 | U16 | red-max |
2 | U16 | green-max |
2 | U16 | blue-max |
1 | U8 | red-shift |
1 | U8 | green-shift |
1 | U8 | blue-shift |
3 | padding |
Sets the encoding types in which pixel data can be sent by the server. The order of the encoding types given in this message is a hint by the client as to its preference (the first encoding specified being most preferred). The server may or may not choose to make use of this hint. Pixel data may always be sent in raw encoding even if not specified explicitly here.
In addition to genuine encodings, a client can request “pseudo-encodings” to declare to the server that it supports certain extensions to the protocol. A server which does not support the extension will simply ignore the pseudo-encoding. Note that this means the client must assume that the server does not support the extension until it gets some extension-specific confirmation from the server.
See Encodings for a description of each encoding and Pseudo-encodings for the meaning of pseudo-encodings.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 2 | message-type |
1 | padding | ||
2 | U16 | number-of-encodings |
followed by number-of-encodings repetitions of the following:
No. of bytes | Type | Description |
---|---|---|
4 | S32 | encoding-type |
Notifies the server that the client is interested in the area of the framebuffer specified by x-position, y-position, width and height. The server usually responds to a FramebufferUpdateRequest by sending a FramebufferUpdate. Note however that a single FramebufferUpdate may be sent in reply to several FramebufferUpdateRequests.
The server assumes that the client keeps a copy of all parts of the framebuffer in which it is interested. This means that normally the server only needs to send incremental updates to the client.
However, if for some reason the client has lost the contents of a particular area which it needs, then the client sends a FramebufferUpdateRequest with incremental set to zero (false). This requests that the server send the entire contents of the specified area as soon as possible. The area will not be updated using the CopyRect encoding.
If the client has not lost any contents of the area in which it is interested, then it sends a FramebufferUpdateRequest with incremental set to non-zero (true). If and when there are changes to the specified area of the framebuffer, the server will send a FramebufferUpdate. Note that there may be an indefinite period between the FramebufferUpdateRequest and the FramebufferUpdate.
In the case of a fast client, the client may want to regulate the rate at which it sends incremental FramebufferUpdateRequests to avoid hogging the network.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 3 | message-type |
1 | U8 | incremental | |
2 | U16 | x-position | |
2 | U16 | y-position | |
2 | U16 | width | |
2 | U16 | height |
A request for an area that partly falls outside the current framebuffer must be cropped so that it fits within the framebuffer dimensions.
Note that an empty area can still solicit a FramebufferUpdate even though that update will only contain pseudo-encodings.
A key press or release. Down-flag is non-zero (true) if the key is now pressed, zero (false) if it is now released. The key itself is specified using the “keysym” values defined by the X Window System.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 4 | message-type |
1 | U8 | down-flag | |
2 | padding | ||
4 | U32 | key |
Auto repeating of keys when a key is held down should be handled on the client. The rationale being that high latency on the network can make it seem like a key is being held for a very long time, yet the problem is that the KeyEvent message releasing the button has been delayed.
The client should send only repeated “down” KeyEvent messages, no “up” messages, when a key is automatically repeated. This allows the server to tell the difference between automatic repeat and actual repeated entry by the user.
For most ordinary keys, the “keysym” is the same as the corresponding ASCII value. For full details, see The Xlib Reference Manual, published by O’Reilly & Associates, or see the header file <X11/keysymdef.h> from any X Window System installation. Some other common keys are:
Key name | Keysym value |
---|---|
BackSpace | 0xff08 |
Tab | 0xff09 |
Return or Enter | 0xff0d |
Escape | 0xff1b |
Insert | 0xff63 |
Delete | 0xffff |
Home | 0xff50 |
End | 0xff57 |
Page Up | 0xff55 |
Page Down | 0xff56 |
Left | 0xff51 |
Up | 0xff52 |
Right | 0xff53 |
Down | 0xff54 |
F1 | 0xffbe |
F2 | 0xffbf |
F3 | 0xffc0 |
F4 | 0xffc1 |
... | ... |
F12 | 0xffc9 |
Shift (left) | 0xffe1 |
Shift (right) | 0xffe2 |
Control (left) | 0xffe3 |
Control (right) | 0xffe4 |
Meta (left) | 0xffe7 |
Meta (right) | 0xffe8 |
Alt (left) | 0xffe9 |
Alt (right) | 0xffea |
The interpretation of keysyms is a complex area. In order to be as widely interoperable as possible the following guidelines should be used:
Indicates either pointer movement or a pointer button press or release. The pointer is now at (x-position, y-position), and the current state of buttons 1 to 8 are represented by bits 0 to 7 of button-mask respectively, 0 meaning up, 1 meaning down (pressed).
On a conventional mouse, buttons 1, 2 and 3 correspond to the left, middle and right buttons on the mouse. On a wheel mouse, each step of the wheel is represented by a press and release of a certain button. Button 4 means up, button 5 means down, button 6 means left and button 7 means right.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 5 | message-type |
1 | U8 | button-mask | |
2 | U16 | x-position | |
2 | U16 | y-position |
The QEMU Pointer Motion Change Psuedo-encoding allows for the negotiation of an alternative interpretation for the x-position and y-position fields, as relative deltas.
The client has new ISO 8859-1 (Latin-1) text in its cut buffer. Ends of lines are represented by the linefeed / newline character (value 10) alone. No carriage-return (value 13) is needed. There is currently no way to transfer text outside the Latin-1 character set.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 6 | message-type |
3 | padding | ||
4 | U32 | length | |
length | U8 array | text |
This message informs the server to switch between only sending FramebufferUpdate messages as a result of a FramebufferUpdateRequest message, or sending FramebufferUpdate messages continuously.
Note that there is currently no way to determine if the server supports this message except for using the Tight Security Type authentication.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 150 | message-type |
1 | U8 | enable-flag | |
2 | U16 | x-position | |
2 | U16 | y-position | |
2 | U16 | width | |
2 | U16 | height |
If enable-flag is non-zero, then the server can start sending FramebufferUpdate messages as needed for the area specified by x-position, y-position, width, and height. If continuous updates are already active, then they must remain active active and the coordinates must be replaced with the last message seen.
If enable-flag is zero, then the server must only send FramebufferUpdate messages as a result of receiving FramebufferUpdateRequest messages. The server must also immediately send out a EndOfContinuousUpdates message. This message must be sent out even if continuous updates were already disabled.
The server must ignore all incremental update requests (FramebufferUpdateRequest with incremental set to non-zero) as long as continuous updates are active. Non-incremental updates must however be honored, even if the area in such a request does not overlap the area specified for continuous updates.
A client supporting the Fence extension sends this to request a synchronisation of the data stream.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 248 | message-type |
3 | padding | ||
4 | U32 | flags | |
1 | U8 | length | |
length | U8 array | payload |
The flags byte informs the server if this is a new request, or a response to a server request sent earlier, as well as what kind of synchronisation that is desired. The server should not delay the response more than necessary, even if the synchronisation requirements would allow it.
Bit | Description |
---|---|
0 | BlockBefore |
1 | BlockAfter |
2 | SyncNext |
3-30 | Currently unused |
31 | Request |
The server should respond with a ServerFence with the Request bit cleared, as well as clearing any bits it does not understand. The remaining bits should remain set in the response. This allows the client to determine which flags the server supports when new ones are defined in the future.
The message following this one must be executed in an atomic manner so that anything preceeding the fence response must not be affected by the message, and anything following the fence response must be affected by the message. The primary purpose of this synchronisation is to allow safe usage of stream altering commands such as SetPixelFormat.
If BlockAfter is set then that synchronisation must be relaxed to allow processing of the following message. Any message after that will still be affected by both flags though.
The client can also include a chunk of data to differentiate between responses and to avoid keeping state. This data is specified using length and payload. The size of this data is limited to 64 bytes in order to minimise the disturbance to highly parallel clients and servers.
A client supporting the xvp extension sends this to request that the server initiate a clean shutdown, clean reboot or abrupt reset of the system whose framebuffer the client is displaying.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 250 | message-type |
1 | padding | ||
1 | U8 | 1 | xvp-extension-version |
1 | U8 | xvp-message-code |
The possible values for xvp-message-code are: 2 - XVP_SHUTDOWN, 3 - XVP_REBOOT, and 4 - XVP_RESET. The client must have already established that the server supports this extension, by requesting the xvp Pseudo-encoding.
Requests a change of desktop size. This message is an extension and may only be sent if the client has previously received an ExtendedDesktopSize rectangle.
The server must send an ExtendedDesktopSize rectangle for every SetDesktopSize message received. Several rectangles may be sent in a single FramebufferUpdate message, but the rectangles must not be merged or reordered in any way. Note that rectangles sent for other reasons may be interleaved with the ones generated as a result of SetDesktopSize messages.
Upon a successful request the server must send an ExtendedDesktopSize rectangle to the requesting client with the exact same information the client provided in the corresponding SetDesktopSize message. x-position must be set to 1, indicating a client initiated event, and y-position must be set to 0, indicating success.
The server must also send an ExtendedDesktopSize rectangle to all other connected clients, but with x-position set to 2, indicating a change initiated by another client.
If the server can not or will not satisfy the request, it must send an ExtendedDesktopSize rectangle to the requesting client with x-position set to 1 and y-position set to the relevant error code. All remaining fields are undefined, although the basic structure must still be followed. The server must not send an ExtendedDesktopSize rectangle to any other connected clients.
All ExtendedDesktopSize rectangles that are sent as a result of a SetDesktopSize message should be sent as soon as possible.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 251 | message-type |
2 | padding | ||
2 | U16 | width | |
2 | U16 | height | |
1 | U8 | number-of-screens | |
1 | padding | ||
number-of-screens * 16 | SCREEN array | screens |
The width and height indicates the framebuffer size requested. This structure is followed by number-of-screens number of SCREEN structures, which is defined in ExtendedDesktopSize Pseudo-encoding:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | id |
2 | U16 | x-position |
2 | U16 | y-position |
2 | U16 | width |
2 | U16 | height |
4 | U32 | flags |
The id field must be preserved upon modification as it determines the difference between a moved screen and a newly created one. The client should make every effort to preserve the fields it does not wish to modify, including any unknown flags bits.
This message is an extension and may only be sent if the client has previously received a gii Server Message confirming that the server supports the General Input Interface extension.
The client response to a gii Version message from the server is the following response:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 253 | message-type |
1 | U8 | 1 or 129 | endian-and-sub-type |
2 | EU16 | 4 | length |
2 | EU16 | 1 | version |
endian-and-sub-type is a bit-field with the leftmost bit indicating big endian if set, and little endian if cleared. The rest of the bits are the actual message sub type.
version is set by the client and ultimately decides the version of gii protocol extension to use. It should be in the range given by the server in the gii Version message. If the server doesn’t support any version that the client supports, the client should instead stop using the gii extension at this point.
After establishing the gii protocol extension version, the client proceeds by requesting creation of one or more devices.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 253 | message-type |
1 | U8 | 2 or 130 | endian-and-sub-type |
2 | EU16 | 2 | length |
31 | U8 array | device-name | |
1 | U8 | 0 | nul-terminator |
4 | EU32 | vendor-id | |
4 | EU32 | product-id | |
4 | EVENT_MASK | can-generate | |
4 | EU32 | num-registers | |
4 | EU32 | num-valuators | |
4 | EU32 | num-buttons | |
num-valuators * 116 | VALUATOR |
endian-and-sub-type is a bit-field with the leftmost bit indicating big endian if set, and little endian if cleared. The rest of the bits are the actual message sub type.
EVENT_MASK is a bit-field indicating which events the device can generate.
Value | Bit name |
---|---|
0x00000020 | Key press |
0x00000040 | Key release |
0x00000080 | Key repeat |
0x00000100 | Pointer relative |
0x00000200 | Pointer absolute |
0x00000400 | Pointer button press |
0x00000800 | Pointer button release |
0x00001000 | Valuator relative |
0x00002000 | Valuator absolute |
and VALUATOR is
No. of bytes | Type | [Value] | Description |
---|---|---|---|
4 | EU32 | index | |
74 | U8 array | long-name | |
1 | U8 | 0 | nul-terminator |
4 | U8 array | short-name | |
1 | U8 | 0 | nul-terminator |
4 | ES32 | range-min | |
4 | ES32 | range-center | |
4 | ES32 | range-max | |
4 | EU32 | SI-unit | |
4 | ES32 | SI-add | |
4 | ES32 | SI-mul | |
4 | ES32 | SI-div | |
4 | ES32 | SI-shift |
The SI-unit field is defined as:
Number | SI-unit | Description |
---|---|---|
0 | unknown | |
1 | s | time |
2 | 1/s | frequency |
3 | m | length |
4 | m/s | velocity |
5 | m/s^2 | acceleration |
6 | rad | angle |
7 | rad/s | angular velocity |
8 | rad/s^2 | angular acceleration |
9 | m^2 | area |
10 | m^3 | volume |
11 | kg | mass |
12 | N (kg*m/s^2) | force |
13 | N/m^2 (Pa) | pressure |
14 | Nm | torque |
15 | Nm, VAs, J | energy |
16 | Nm/s, VA, W | power |
17 | K | temperature |
18 | A | current |
19 | V (kg*m^2/(As^3)) | voltage |
20 | V/A (Ohm) | resistance |
21 | As/V | capacity |
22 | Vs/A | inductivity |
The SI-add, SI-mul, SI-div and SI-shift fields of the VALUATOR indicate how the raw value should be translated to the SI-unit using the below formula.
float SI = (float) (SI_add + value[n]) * (float) SI_mul / (float) SI_div * pow(2.0, SI_shift);
Setting SI-mul to zero indicates that the valuator is non-linear or that the factor is unknown.
The client can destroy a device with a device destruct message.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 253 | message-type |
1 | U8 | 3 or 131 | endian-and-sub-type |
2 | EU16 | 4 | length |
4 | EU32 | device-origin |
endian-and-sub-type is a bit-field with the leftmost bit indicating big endian if set, and little endian if cleared. The rest of the bits are the actual message sub type.
device-origin is the handle retrieved with a prior device creation request.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 253 | message-type |
1 | U8 | 0 or 128 | endian-and-sub-type |
2 | EU16 | length |
followed by length bytes of EVENT entries
endian-and-sub-type is a bit-field with the leftmost bit indicating big endian if set, and little endian if cleared. The rest of the bits are the actual message sub type.
EVENT is one of KEY_EVENT, PTR_MOVE_EVENT, PTR_BUTTON_EVENT and VALUATOR_EVENT.
KEY_EVENT is:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 24 | event-size |
1 | U8 | 5, 6 or 7 | event-type |
2 | EU16 | padding | |
4 | EU32 | device-origin | |
4 | EU32 | modifiers | |
4 | EU32 | symbol | |
4 | EU32 | label | |
4 | EU32 | button |
The possible values for event-type are: 5 - key pressed, 6 - key released and 7 - key repeat. XXX describe modifiers, symbol, label and button. Meanwhile, see http://www.ggi-project.org/documentation/libgii/current/gii_key_event.3.html for details.
device-origin is the handle retrieved with a prior device creation request.
PTR_MOVE_EVENT is:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 24 | event-size |
1 | U8 | 8 or 9 | event-type |
2 | EU16 | padding | |
4 | EU32 | device-origin | |
4 | ES32 | x | |
4 | ES32 | y | |
4 | ES32 | z | |
4 | ES32 | wheel |
The possible values for event-type are: 8 - pointer relative and 9 - pointer absolute.
device-origin is the handle retrieved with a prior device creation request.
PTR_BUTTON_EVENT is:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 12 | event-size |
1 | U8 | 10 or 11 | event-type |
2 | EU16 | padding | |
4 | EU32 | device-origin | |
4 | EU32 | button-number |
The possible values for event-type are: 10 - pointer button press and 11 - pointer button release.
device-origin is the handle retrieved with a prior device creation request.
button-number 1 is the primary or left button, button-number 2 is the secondary or right button and button-number 3 is the tertiary or middle button. Other values for button-number are also valid.
VALUATOR_EVENT is:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 16 + 4 * count | event-size |
1 | U8 | 12 or 13 | event-type |
2 | EU16 | padding | |
4 | EU32 | device-origin | |
4 | EU32 | first | |
4 | EU32 | count | |
4 * count | ES32 array | value |
The possible values for event-type are: 12 - relative valuator and 13 - absolute valuator.
device-origin is the handle retrieved with a prior device creation request.
The event reports count valuators starting with first.
This message may only be sent if the client has previously received a FrameBufferUpdate that confirms support for the intended submessage-type. Every QEMU Client Message begins with a standard header
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | submessage-type |
This header is then followed by arbitrary data whose format is determined by the submessage-type. Possible values for submessage-type and their associated psuedo encodings are
Submessage Type | Psuedo Encoding | Description |
---|---|---|
0 | -258 | Extended key events |
1 | -259 | Audio |
This submessage allows the client to send an extended key event containing a keycode, in addition to a keysym. The advantage of providing the keycode is that it enables the server to interpret the key event independantly of the clients’ locale specific keymap. This can be important for virtual desktops whose key input device requires scancodes, for example, virtual machines emulating a PS/2 keycode. Prior to this extension, RFB servers for such virtualization software would have to be configured with a keymap matching the client. With this extension it is sufficient for the guest operating system to be configured with the matching keymap. The VNC server is keymap independant.
The full message is:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | 0 | submessage-type |
2 | U16 | down-flag | |
4 | U32 | keysym | |
4 | U32 | keycode |
The keysym and down-flag fields also take the same values as described for the KeyEvent message. Auto repeating behaviour of keys is also as described for the KeyEvent message.
The keycode is the XT keycode that produced the keysym. An XT keycode is an XT make scancode sequence encoded to fit in a single U32 quantity. Single byte XT scancodes with a byte value less than 0x7f are encoded as is. 2-byte XT scancodes whose first byte is 0xe0 and second byte is less than 0x7f are encoded with the high bit of the first byte set. Some example mappings are
XT scancode | X11 keysym | RFB keycode | down-flag |
---|---|---|---|
0x1e | XK_A (0x41) | 0x1e | 1 |
0x9e | XK_A (0x41) | 0x1e | 0 |
0xe0 0x4d | XK_Right (0xff53) | 0xcd | 1 |
0xe0 0xcd | XK_Right (0xff53) | 0xcd | 0 |
This submessage allows the client to control how the audio data stream is received. There are three operations that can be invoked with this submessage, the payload varies according to which operation is requested.
The first operation enables audio capture from the server:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | 1 | submessage-type |
2 | U16 | 0 | operation |
After invoking this operation, the client will receive a QEMU Audio Server Message when an audio stream begins.
The second operation is the inverse, to disable audio capture on the server:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | 1 | submessage-type |
2 | U16 | 1 | operation |
Due to inherant race conditions in the protocol, after invoking this operation, the client may still receive further QEMU Audio Server Message messages for a short time.
The third and final operation is to set the audio sample format. This should be set before audio capture is enabled on the server, otherwise the client will not be able to reliably interpret the receiving audio buffers:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | 1 | submessage-type |
2 | U16 | 2 | operation |
1 | U8 | sample-format | |
1 | U8 | nchannels | |
4 | U32 | frequency |
The sample-format field must take one of the following values, and this describes the number of bytes that each sample will consume:
Value | No. of bytes | Type |
---|---|---|
0 | 1 | U8 |
1 | 1 | S8 |
2 | 2 | U16 |
3 | 2 | S16 |
4 | 4 | U32 |
5 | 4 | S32 |
The nchannels field must be either 1 (mono) or 2 (stereo).
The server to client message types that all clients must support are:
Number | Name |
---|---|
0 | FramebufferUpdate |
1 | SetColourMapEntries |
2 | Bell |
3 | ServerCutText |
Optional message types are:
Number | Name |
---|---|
4 | ResizeFrameBuffer |
5 | KeyFrameUpdate |
6 | Possibly used in UltraVNC |
7 | FileTransfer |
8-10 | Possibly used in UltraVNC |
11 | TextChat |
12 | Possibly used in UltraVNC |
13 | KeepAlive |
14 | Possibly used in UltraVNC |
15 | ResizeFrameBuffer |
127 | VMWare |
128 | Car Connectivity |
150 | EndOfContinuousUpdates |
173 | ServerState |
248 | ServerFence |
249 | OLIVE Call Control |
250 | xvp Server Message |
252 | tight |
253 | gii Server Message |
254 | VMWare |
255 | QEMU Server Message |
The official, up-to-date list is maintained by IANA [1].
Note that before sending a message with an optional message type a server must have determined that the client supports the relevant extension by receiving some extension-specific confirmation from the client; usually a request for a given pseudo-encoding.
A framebuffer update consists of a sequence of rectangles of pixel data which the client should put into its framebuffer. It is sent in response to a FramebufferUpdateRequest from the client. Note that there may be an indefinite period between the FramebufferUpdateRequest and the FramebufferUpdate.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 0 | message-type |
1 | padding | ||
2 | U16 | number-of-rectangles |
This is followed by number-of-rectangles rectangles of pixel data. Each rectangle consists of:
No. of bytes | Type | Description |
---|---|---|
2 | U16 | x-position |
2 | U16 | y-position |
2 | U16 | width |
2 | U16 | height |
4 | S32 | encoding-type |
followed by the pixel data in the specified encoding. See Encodings for the format of the data for each encoding and Pseudo-encodings for the meaning of pseudo-encodings.
Note that a framebuffer update marks a transition from one valid framebuffer state to another. That means that a single update handles all received FramebufferUpdateRequest up to the point where the update is sent out.
However, because there is no strong connection between a FramebufferUpdateRequest and a subsequent FramebufferUpdate, a client that has more than one FramebufferUpdateRequest pending at any given time cannot be sure that it has received all framebuffer updates.
See the LastRect Pseudo-encoding for an extension to this message.
When the pixel format uses a “colour map”, this message tells the client that the specified pixel values should be mapped to the given RGB intensities.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 1 | message-type |
1 | padding | ||
2 | U16 | first-colour | |
2 | U16 | number-of-colours |
followed by number-of-colours repetitions of the following:
No. of bytes | Type | Description |
---|---|---|
2 | U16 | red |
2 | U16 | green |
2 | U16 | blue |
Ring a bell on the client if it has one.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 2 | message-type |
The server has new ISO 8859-1 (Latin-1) text in its cut buffer. Ends of lines are represented by the linefeed / newline character (value 10) alone. No carriage-return (value 13) is needed. There is currently no way to transfer text outside the Latin-1 character set.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 3 | message-type |
3 | padding | ||
4 | U32 | length | |
length | U8 array | text |
This message is sent whenever the server sees a EnableContinuousUpdates message with enable set to a non-zero value. It indicates that the server has stopped sending continuous updates and is now only reacting to FramebufferUpdateRequest messages.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 150 | message-type |
A server supporting the Fence extension sends this to request a synchronisation of the data stream.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 248 | message-type |
3 | padding | ||
4 | U32 | flags | |
1 | U8 | length | |
length | U8 array | payload |
The format and semantics is identical to ClientFence, but with the roles of the client and server reversed.
This has the following format:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 250 | message-type |
1 | padding | ||
1 | U8 | 1 | xvp-extension-version |
1 | U8 | xvp-message-code |
The possible values for xvp-message-code are: 0 - XVP_FAIL and 1 - XVP_INIT.
A server which supports the xvp extension declares this by sending a message with an XVP_INIT xvp-message-code when it receives a request from the client to use the xvp Pseudo-encoding. The server must specify in this message the highest xvp-extension-version it supports: the client may assume that the server supports all versions from 1 up to this value. The client is then free to use any supported version. Currently, only version 1 is defined.
A server which subsequently receives an xvp Client Message requesting an operation which it is unable to perform, informs the client of this by sending a message with an XVP_FAIL xvp-message-code, and the same xvp-extension-version as included in the client’s operation request.
This message is an extension and may only be sent if the server has previously received a SetEncodings message confirming that the client supports the General Input Interface extension via the gii Pseudo-encoding.
The server response from a server with gii capabilities to a client declaring gii capabilities is a gii version message:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 253 | message-type |
1 | SUB_TYPE | 1 or 129 | endian-and-sub-type |
2 | EU16 | 4 | length |
2 | EU16 | 1 | maximum-version |
2 | EU16 | 1 | minimum-version |
endian-and-sub-type is a bit-field with the leftmost bit indicating big endian if set, and little endian if cleared. The rest of the bits are the actual message sub type.
The server response to a gii Device Creation request from the client is the following response:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 253 | message-type |
1 | SUB_TYPE | 2 or 130 | endian-and-sub-type |
2 | EU16 | 4 | length |
4 | EU32 | device-origin |
endian-and-sub-type is a bit-field with the leftmost bit indicating big endian if set, and little endian if cleared. The rest of the bits are the actual message sub type.
device-origin is used as a handle to the device in subsequent communications. A device-origin of zero indicates device creation failure.
This message may only be sent if the client has previously received a FrameBufferUpdate that confirms support for the intended submessage-type. Every QEMU Server Message begins with a standard header
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | submessage-type |
This header is then followed by arbitrary data whose format is determined by the submessage-type. Possible values for submessage-type and their associated psuedo encodings are
Submessage Type | Psuedo Encoding | Description |
---|---|---|
1 | -259 | Audio |
Submessage type 0 is unused, since the QEMU Extended Key Event Psuedo-encoding does not require any server messages.
This submessage allows the server to send an audio data stream to the client. There are three operations that can be invoked with this submessage, the payload varies according to which operation is requested.
The first operation informs the client that an audio stream is about to start
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | 1 | submessage-type |
2 | U16 | 1 | operation |
The second operation informs the client that an audio stream has now finished:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | 1 | submessage-type |
2 | U16 | 0 | operation |
The third and final operation is to provide audio data.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | 255 | message-type |
1 | U8 | 1 | submessage-type |
2 | U16 | 2 | operation |
4 | U32 | data-length | |
data-length | U8 array | data |
The data-length will be a multiple of (sample-format * nchannels) as requested by the client in an earlier QEMU Audio Client Message.
The encodings defined in this document are:
Number | Name |
---|---|
0 | Raw Encoding |
1 | CopyRect Encoding |
2 | RRE Encoding |
4 | CoRRE Encoding |
5 | Hextile Encoding |
6 | zlib Encoding |
7 | Tight Encoding |
8 | zlibhex Encoding |
16 | ZRLE Encoding |
-23 to -32 | JPEG Quality Level Pseudo-encoding |
-223 | DesktopSize Pseudo-encoding |
-224 | LastRect Pseudo-encoding |
-239 | Cursor Pseudo-encoding |
-240 | X Cursor Pseudo-encoding |
-247 to -256 | Compression Level Pseudo-encoding |
-257 | QEMU Pointer Motion Change Psuedo-encoding |
-258 | QEMU Extended Key Event Psuedo-encoding |
-259 | QEMU Audio Psuedo-encoding |
-305 | gii Pseudo-encoding |
-307 | DesktopName Pseudo-encoding |
-308 | ExtendedDesktopSize Pseudo-encoding |
-309 | xvp Pseudo-encoding |
-312 | Fence Pseudo-encoding |
-313 | ContinuousUpdates Pseudo-encoding |
-412 to -512 | JPEG Fine-Grained Quality Level Pseudo-encoding |
-763 to -768 | JPEG Subsampling Level Pseudo-encoding |
Other registered encodings are:
Number | Name |
---|---|
9 | Ultra |
10 | Ultra2 |
15 | TRLE |
17 | Hitachi ZYWRLE |
1000 to 1002 | Apple Inc. |
1011 | Apple Inc. |
1024 to 1099 | RealVNC |
1100 to 1105 | Apple Inc. |
-1 to -22 | Tight options |
-33 to -222 | Tight options |
-225 | PointerPos |
-226 to -238 | Tight options |
-241 to -246 | Tight options |
-260 to -272 | QEMU |
-273 to -304 | VMWare |
-306 | popa |
-310 | OLIVE Call Control |
-311 | ClientRedirect |
-523 to -528 | Car Connectivity |
0x574d5600 to 0x574d56ff | VMWare |
0xc0a1e5ce | ExtendedClipboard |
0xc0a1e5cf | PluginStreaming |
0xffff0000 | Cache |
0xffff0001 | CacheEnable |
0xffff0002 | XOR zlib |
0xffff0003 | XORMonoRect zlib |
0xffff0004 | XORMultiColor zlib |
0xffff0005 | SolidColor |
0xffff0006 | XOREnable |
0xffff0007 | CacheZip |
0xffff0008 | SolMonoZip |
0xffff0009 | UltraZip |
0xffff8000 | ServerState |
0xffff8001 | EnableKeepAlive |
0xffff8002 | FTProtocolVersion |
0xffff8003 | Session |
The official, up-to-date list is maintained by IANA [1].
The simplest encoding type is raw pixel data. In this case the data consists of width * height pixel values (where width and height are the width and height of the rectangle). The values simply represent each pixel in left-to-right scanline order. All RFB clients must be able to cope with pixel data in this raw encoding, and RFB servers should only produce raw encoding unless the client specifically asks for some other encoding type.
No. of bytes | Type | Description |
---|---|---|
width * height * bytesPerPixel | PIXEL array | pixels |
The CopyRect (copy rectangle) encoding is a very simple and efficient encoding which can be used when the client already has the same pixel data elsewhere in its framebuffer. The encoding on the wire simply consists of an X,Y coordinate. This gives a position in the framebuffer from which the client can copy the rectangle of pixel data. This can be used in a variety of situations, the most obvious of which are when the user moves a window across the screen, and when the contents of a window are scrolled. A less obvious use is for optimising drawing of text or other repeating patterns. An intelligent server may be able to send a pattern explicitly only once, and knowing the previous position of the pattern in the framebuffer, send subsequent occurrences of the same pattern using the CopyRect encoding.
No. of bytes | Type | Description |
---|---|---|
2 | U16 | src-x-position |
2 | U16 | src-y-position |
RRE stands for rise-and-run-length encoding and as its name implies, it is essentially a two-dimensional analogue of run-length encoding. RRE-encoded rectangles arrive at the client in a form which can be rendered immediately and efficiently by the simplest of graphics engines. RRE is not appropriate for complex desktops, but can be useful in some situations.
The basic idea behind RRE is the partitioning of a rectangle of pixel data into rectangular subregions (subrectangles) each of which consists of pixels of a single value and the union of which comprises the original rectangular region. The near-optimal partition of a given rectangle into such subrectangles is relatively easy to compute.
The encoding consists of a background pixel value, Vb (typically the most prevalent pixel value in the rectangle) and a count N, followed by a list of N subrectangles, each of which consists of a tuple <v, x, y, w, h> where v (!= Vb) is the pixel value, (x, y) are the coordinates of the subrectangle relative to the top-left corner of the rectangle, and (w, h) are the width and height of the subrectangle. The client can render the original rectangle by drawing a filled rectangle of the background pixel value and then drawing a filled rectangle corresponding to each subrectangle.
On the wire, the data begins with the header:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | number-of-subrectangles |
bytesPerPixel | PIXEL | background-pixel-value |
This is followed by number-of-subrectangles instances of the following structure:
No. of bytes | Type | Description |
---|---|---|
bytesPerPixel | PIXEL | subrect-pixel-value |
2 | U16 | x-position |
2 | U16 | y-position |
2 | U16 | width |
2 | U16 | height |
CoRRE stands for compressed rise-and-run-length encoding and as its name implies, it is a variant of the above RRE Encoding and as such essentially a two-dimensional analogue of run-length encoding.
The only difference between CoRRE and RRE is that the position, width and height of the subrectangles are limited to a maximum of 255 pixels. Because of this, the server needs to produce several rectangles in order to cover a larger area. The Hextile Encoding is probably a better choice in the majority of cases.
On the wire, the data begins with the header:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | number-of-subrectangles |
bytesPerPixel | PIXEL | background-pixel-value |
This is followed by number-of-subrectangles instances of the following structure:
No. of bytes | Type | Description |
---|---|---|
bytesPerPixel | PIXEL | subrect-pixel-value |
1 | U8 | x-position |
1 | U8 | y-position |
1 | U8 | width |
1 | U8 | height |
Hextile is a variation on the RRE idea. Rectangles are split up into 16x16 tiles, allowing the dimensions of the subrectangles to be specified in 4 bits each, 16 bits in total. The rectangle is split into tiles starting at the top left going in left-to-right, top-to-bottom order. The encoded contents of the tiles simply follow one another in the predetermined order. If the width of the whole rectangle is not an exact multiple of 16 then the width of the last tile in each row will be correspondingly smaller. Similarly if the height of the whole rectangle is not an exact multiple of 16 then the height of each tile in the final row will also be smaller.
Each tile is either encoded as raw pixel data, or as a variation on RRE. Each tile has a background pixel value, as before. The background pixel value does not need to be explicitly specified for a given tile if it is the same as the background of the previous tile. However the background pixel value may not be carried over if the previous tile was raw. If all of the subrectangles of a tile have the same pixel value, this can be specified once as a foreground pixel value for the whole tile. As with the background, the foreground pixel value can be left unspecified, meaning it is carried over from the previous tile. The foreground pixel value may not be carried over if the previous tile was raw or had the SubrectsColored bit set. It may, however, be carried over from a previous tile with the AnySubrects bit clear, as long as that tile itself carried over a valid foreground from its previous tile.
So the data consists of each tile encoded in order. Each tile begins with a subencoding type byte, which is a mask made up of a number of bits:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | subencoding-mask: | |
1 | Raw | ||
2 | BackgroundSpecified | ||
4 | ForegroundSpecified | ||
8 | AnySubrects | ||
16 | SubrectsColoured |
If the Raw bit is set then the other bits are irrelevant; width * height pixel values follow (where width and height are the width and height of the tile). Otherwise the other bits in the mask are as follows:
If set, a pixel value follows which specifies the background colour for this tile:
No. of bytes | Type | Description |
---|---|---|
bytesPerPixel | PIXEL | background-pixel-value |
The first non-raw tile in a rectangle must have this bit set. If this bit isn’t set then the background is the same as the last tile.
If set, a pixel value follows which specifies the foreground colour to be used for all subrectangles in this tile:
No. of bytes | Type | Description |
---|---|---|
bytesPerPixel | PIXEL | foreground-pixel-value |
If this bit is set then the SubrectsColoured bit must be zero.
If set, a single byte follows giving the number of subrectangles following:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | number-of-subrectangles |
If not set, there are no subrectangles (i.e. the whole tile is just solid background colour).
If set then each subrectangle is preceded by a pixel value giving the colour of that subrectangle, so a subrectangle is:
No. of bytes | Type | Description |
---|---|---|
bytesPerPixel | PIXEL | subrect-pixel-value |
1 | U8 | x-and-y-position |
1 | U8 | width-and-height |
If not set, all subrectangles are the same colour, the foreground colour; if the ForegroundSpecified bit wasn’t set then the foreground is the same as the last tile. A subrectangle is:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | x-and-y-position |
1 | U8 | width-and-height |
The position and size of each subrectangle is specified in two bytes, x-and-y-position and width-and-height. The most-significant four bits of x-and-y-position specify the X position, the least-significant specify the Y position. The most-significant four bits of width-and-height specify the width minus one, the least-significant specify the height minus one.
The zlib encoding uses zlib [3] to compress rectangles encoded according to the Raw Encoding. A single zlib “stream” object is used for a given RFB connection, so that zlib rectangles must be encoded and decoded strictly in order.
[3] | (1, 2, 3) see http://www.gzip.org/zlib/ |
No. of bytes | Type | Description |
---|---|---|
4 | U32 | length |
length | U8 array | zlibData |
The zlibData, when uncompressed, represents a rectangle according to the Raw Encoding.
Tight encoding provides efficient compression for pixel data. To reduce implementation complexity, the width of any Tight-encoded rectangle cannot exceed 2048 pixels. If a wider rectangle is desired, it must be split into several rectangles and each one should be encoded separately.
The first byte of each Tight-encoded rectangle is a compression-control byte:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | compression-control |
The least significant four bits of the compression-control byte inform the client which zlib compression streams should be reset before decoding the rectangle. Each bit is independent and corresponds to a separate zlib stream that should be reset:
Bit | Description |
---|---|
0 | Reset stream 0 |
1 | Reset stream 1 |
2 | Reset stream 2 |
3 | Reset stream 3 |
One of three possible compression methods are supported in the Tight encoding. These are BasicCompression, FillCompression and JpegCompression. If the bit 7 (the most significant bit) of the compression-control byte is 0, then the compression type is BasicCompression. In that case, bits 7-4 (the most significant four bits) of compression-control should be interpreted as follows:
Bits | Binary value | Description |
---|---|---|
5-4 | 00 | Use stream 0 |
01 | Use stream 1 | |
10 | Use stream 2 | |
11 | Use stream 3 | |
6 | 0 | — |
1 | read-filter-id | |
7 | 0 | BasicCompression |
Otherwise, if the bit 7 of compression-control is set to 1, then the compression method is either FillCompression or JpegCompression, depending on other bits of the same byte:
Bits | Binary value | Description |
---|---|---|
7-4 | 1000 | FillCompression |
1001 | JpegCompression | |
any other | Invalid |
Note: JpegCompression may only be used when bits-per-pixel is either 16 or 32 and the client has advertized a quality level using the JPEG Quality Level Pseudo-encoding.
The Tight encoding makes use of a new type TPIXEL (Tight pixel). This is the same as a PIXEL for the agreed pixel format, except where true-colour-flag is non-zero, bits-per-pixel is 32, depth is 24 and all of the bits making up the red, green and blue intensities are exactly 8 bits wide. In this case a TPIXEL is only 3 bytes long, where the first byte is the red component, the second byte is the green component, and the third byte is the blue component of the pixel color value.
The data following the compression-control byte depends on the compression method.
If the compression type is JpegCompression, the following data stream looks like this:
No. of bytes | Type | Description |
---|---|---|
1-3 | length in compact representation | |
length | U8 array | jpeg-data |
length is compactly represented in one, two or three bytes, according to the following scheme:
Value | Description |
---|---|
0xxxxxxx | for values 0..127 |
1xxxxxxx 0yyyyyyy | for values 128..16383 |
1xxxxxxx 1yyyyyyy zzzzzzzz | for values 16384..4194303 |
Here each character denotes one bit, xxxxxxx are the least significant 7 bits of the value (bits 0-6), yyyyyyy are bits 7-13, and zzzzzzzz are the most significant 8 bits (bits 14-21). For example, decimal value 10000 should be represented as two bytes: binary 10010000 01001110, or hexadecimal 90 4E.
The jpeg-data is a JFIF stream.
If the compression type is BasicCompression and bit 6 (the read-filter-id bit) of the compression-control byte was set to 1, then the next (second) byte specifies filter-id which tells the decoder what filter type was used by the encoder to pre-process pixel data before the compression. The filter-id byte can be one of the following:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | filter-id | |
0 | CopyFilter (no filter) | ||
1 | PaletteFilter | ||
2 | GradientFilter |
If bit 6 of the compression-control byte is set to 0 (no filter-id byte), then the CopyFilter is used.
The GradientFilter pre-processes pixel data with a simple algorithm which converts each color component to a difference between a “predicted” intensity and the actual intensity. Such a technique does not affect uncompressed data size, but helps to compress photo-like images better. Pseudo-code for converting intensities to differences follows:
P[i,j] := V[i-1,j] + V[i,j-1] - V[i-1,j-1];
if (P[i,j] < 0) then P[i,j] := 0;
if (P[i,j] > MAX) then P[i,j] := MAX;
D[i,j] := V[i,j] - P[i,j];
Here V[i,j] is the intensity of a color component for a pixel at coordinates (i,j). For pixels outside the current rectangle, V[i,j] is assumed to be zero (which is relevant for P[i,0] and P[0,j]). MAX is the maximum intensity value for a color component.
Note: The GradientFilter may only be used when bits-per-pixel is either 16 or 32.
After the pixel data has been filtered with one of the above three filters, it is compressed using the zlib library. But if the data size after applying the filter but before the compression is less then 12, then the data is sent as is, uncompressed. Four separate zlib streams (0..3) can be used and the decoder should read the actual stream id from the compression-control byte (see [NOTE1]).
If the compression is not used, then the pixel data is sent as is, otherwise the data stream looks like this:
No. of bytes | Type | Description |
---|---|---|
1-3 | length in compact representation | |
length | U8 array | zlibData |
length is compactly represented in one, two or three bytes, just like in the JpegCompression method (see above).
[NOTE1] | The decoder must reset the zlib streams before decoding the rectangle, if some of the bits 0, 1, 2 and 3 in the compression-control byte are set to 1. Note that the decoder must reset the indicated zlib streams even if the compression type is FillCompression or JpegCompression. |
The zlibhex encoding uses zlib [3] to optionally compress subrectangles according to the Hextile Encoding. Refer to the hextile encoding for information on how the rectangle is divided into subrectangles and other basic properties of subrectangles. One zlib “stream” object is used for subrectangles encoded according to the Raw subencoding and one zlib “stream” object is used for all other subrectangles.
The hextile subencoding bitfield is extended with these bits:
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | subencoding-mask: | |
32 | ZlibRaw | ||
64 | Zlib |
If either of the ZlibRaw or the Zlib bit is set, the subrectangle is compressed using zlib, like this:
No. of bytes | Type | Description |
---|---|---|
2 | U16 | length |
length | U8 array | zlibData |
Like the Raw bit in hextile, the ZlibRaw bit in zlibhex cancels all other bits and the subrectangle is encoded using the first zlib “stream” object. The zlibData, when uncompressed, should in this case be interpreted as the Raw data in the hextile encoding.
If the Zlib bit is set, the rectangle is encoded using the second zlib “stream” object. The zlibData, when uncompressed, represents a plain hextile rectangle according to the lower 5 bits in the subencoding.
If neither the ZlibRaw nor the Zlib bit is set, the subrectangle follows the rules described in the Hextile Encoding.
ZRLE stands for Zlib [3] Run-Length Encoding, and combines zlib compression, tiling, palettisation and run-length encoding. On the wire, the rectangle begins with a 4-byte length field, and is followed by that many bytes of zlib-compressed data. A single zlib “stream” object is used for a given RFB protocol connection, so that ZRLE rectangles must be encoded and decoded strictly in order.
No. of bytes | Type | Description |
---|---|---|
4 | U32 | length |
length | U8 array | zlibData |
The zlibData when uncompressed represents tiles of 64x64 pixels in left-to-right, top-to-bottom order, similar to hextile. If the width of the rectangle is not an exact multiple of 64 then the width of the last tile in each row is smaller, and if the height of the rectangle is not an exact multiple of 64 then the height of each tile in the final row is smaller.
ZRLE makes use of a new type CPIXEL (compressed pixel). This is the same as a PIXEL for the agreed pixel format, except where true-colour-flag is non-zero, bits-per-pixel is 32, depth is 24 or less and all of the bits making up the red, green and blue intensities fit in either the least significant 3 bytes or the most significant 3 bytes. In this case a CPIXEL is only 3 bytes long, and contains the least significant or the most significant 3 bytes as appropriate. bytesPerCPixel is the number of bytes in a CPIXEL.
Note that for the corner case where bits-per-pixel is 32 and depth is 16 or less (this is a corner case, since the client is much better off using 16 or even 8 bits-per-pixels) a CPIXEL is still 3 bytes long. By convention, the three least significant bytes are used when both the three least and the three most significant bytes would cover the used bits.
Each tile begins with a subencoding type byte. The top bit of this byte is set if the tile has been run-length encoded, clear otherwise. The bottom seven bits indicate the size of the palette used: zero means no palette, one means that the tile is of a single colour, 2 to 127 indicate a palette of that size. The possible values of subencoding are:
Raw pixel data. width * height pixel values follow (where width and height are the width and height of the tile):
No. of bytes | Type | Description |
---|---|---|
width * height * bytesPerCPixel | CPIXEL array | pixels |
A solid tile consisting of a single colour. The pixel value follows:
No. of bytes | Type | Description |
---|---|---|
bytesPerCPixel | CPIXEL | pixelValue |
Packed palette types. Followed by the palette, consisting of paletteSize (=*subencoding*) pixel values. Then the packed pixels follow, each pixel represented as a bit field yielding an index into the palette (0 meaning the first palette entry). For paletteSize 2, a 1-bit field is used, for paletteSize 3 or 4 a 2-bit field is used and for paletteSize from 5 to 16 a 4-bit field is used. The bit fields are packed into bytes, the most significant bits representing the leftmost pixel (i.e. big endian). For tiles not a multiple of 8, 4 or 2 pixels wide (as appropriate), padding bits are used to align each row to an exact number of bytes.
No. of bytes | Type | Description |
---|---|---|
paletteSize * bytesPerCPixel | CPIXEL array | palette |
m | U8 array | packedPixels |
where m is the number of bytes representing the packed pixels. For paletteSize of 2 this is floor((width + 7) / 8) * height, for paletteSize of 3 or 4 this is floor((width + 3) / 4) * height, for paletteSize of 5 to 16 this is floor((width + 1) / 2) * height.
Plain RLE. Consists of a number of runs, repeated until the tile is done. Runs may continue from the end of one row to the beginning of the next. Each run is a represented by a single pixel value followed by the length of the run. The length is represented as one or more bytes. The length is calculated as one more than the sum of all the bytes representing the length. Any byte value other than 255 indicates the final byte. So for example length 1 is represented as [0], 255 as [254], 256 as [255,0], 257 as [255,1], 510 as [255,254], 511 as [255,255,0] and so on.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
bytesPerCPixel | CPIXEL | pixelValue | |
r | U8 array | 255 | |
1 | U8 | (runLength - 1) % 255 |
Where r is floor((runLength - 1) / 255).
Palette RLE. Followed by the palette, consisting of paletteSize = (subencoding - 128) pixel values:
No. of bytes | Type | Description |
---|---|---|
paletteSize * bytesPerCPixel | CPIXEL array | palette |
Then as with plain RLE, consists of a number of runs, repeated until the tile is done. A run of length one is represented simply by a palette index:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | paletteIndex |
A run of length more than one is represented by a palette index with the top bit set, followed by the length of the run as for plain RLE.
No. of bytes | Type | [Value] | Description |
---|---|---|---|
1 | U8 | paletteIndex + 128 | |
r | U8 array | 255 | |
1 | U8 | (runLength - 1) % 255 |
Where r is floor((runLength - 1) / 255).
Specifies the desired quality from the JPEG encoder. Encoding number -23 implies high JPEG quality and -32 implies low JPEG quality. Low quality can be useful in low bandwidth situations. If the JPEG quality level is not specified, JpegCompression is not used in the Tight Encoding.
The quality level concerns lossy compression and hence the setting is a tradeoff between image quality and bandwidth. The specification defines neither what bandwidth is required at a certain quality level nor what image quality you can expect. The quality level is also just a hint to the server.
A client which requests the Cursor pseudo-encoding is declaring that it is capable of drawing a mouse cursor locally. This can significantly improve perceived performance over slow links. The server sets the cursor shape by sending a pseudo-rectangle with the Cursor pseudo-encoding as part of an update. The pseudo-rectangle’s x-position and y-position indicate the hotspot of the cursor, and width and height indicate the width and height of the cursor in pixels. The data consists of width * height pixel values followed by a bitmask. The bitmask consists of left-to-right, top-to-bottom scanlines, where each scanline is padded to a whole number of bytes floor((width + 7) / 8). Within each byte the most significant bit represents the leftmost pixel, with a 1-bit meaning the corresponding pixel in the cursor is valid.
No. of bytes | Type | Description |
---|---|---|
width * height * bytesPerPixel | PIXEL array | cursor-pixels |
floor((width + 7) / 8) * height | U8 array | bitmask |
A client which requests the X Cursor pseudo-encoding is declaring that it is capable of drawing a mouse cursor locally. This can significantly improve perceived performance over slow links. The server sets the cursor shape by sending a pseudo-rectangle with the X Cursor pseudo-encoding as part of an update.
The pseudo-rectangle’s x-position and y-position indicate the hotspot of the cursor, and width and height indicate the width and height of the cursor in pixels.
The data consists of the primary and secondary colours for the cursor, followed by one bitmap for the colour and one bitmask for the transparency. The bitmap and bitmask both consist of left-to-right, top-to-bottom scanlines, where each scanline is padded to a whole number of bytes floor((width + 7) / 8). Within each byte the most significant bit represents the leftmost pixel, with a 1-bit meaning the corresponding pixel should use the primary colour, or that the pixel is valid.
No. of bytes | Type | Description |
---|---|---|
1 | U8 | primary-r |
1 | U8 | primary-g |
1 | U8 | primary-b |
1 | U8 | secondary-r |
1 | U8 | secondary-g |
1 | U8 | secondary-b |
floor((width + 7) / 8) * height | U8 array | bitmap |
floor((width + 7) / 8) * height | U8 array | bitmask |
A client which requests the DesktopSize pseudo-encoding is declaring that it is capable of coping with a change in the framebuffer width and/or height.
The server changes the desktop size by sending a pseudo-rectangle with the DesktopSize pseudo-encoding. The pseudo-rectangle’s x-position and y-position are ignored, and width and height indicate the new width and height of the framebuffer. There is no further data associated with the pseudo-rectangle.
The semantics of the DesktopSize pseudo-encoding were originally not clearly defined and as a results there are multiple differing implementations in the wild. Both the client and server need to take special steps to ensure maximum compatibility.
In the initial implementation the DesktopSize pseudo-rectangle was sent in its own update without any modifications to the framebuffer data. The client would discard the framebuffer contents upon receiving this pseudo-rectangle and the server would consider the entire framebuffer to be modified.
A later implementation sent the DesktopSize pseudo-rectangle together with modifications to the framebuffer data. It also expected the client to retain the framebuffer contents as those modifications could be from after the framebuffer resize had occurred on the server.
The semantics defined here retain compatibility with both of two older implementations.
The update containing the pseudo-rectangle should not contain any rectangles that change the framebuffer data as that will most likely be discarded by the client and will have to be resent later.
The server should assume that the client discards the framebuffer data when receiving a DesktopSize pseudo-rectangle. It should therefore not use any encoding that relies on the previous contents of the framebuffer. The server should also consider the entire framebuffer to be modified.
Some early client implementations require the DesktopSize pseudo-rectangle to be the very last rectangle in an update. Servers should make every effort to support these.
The server should only send a DesktopSize pseudo-rectangle when an actual change of the framebuffer dimensions has occurred. Some clients respond to a DesktopSize pseudo-rectangle in a way that could send the system into an infinite loop if the server sent out the pseudo-rectangle for anything other than an actual change.
The client should assume that the server expects the framebuffer data to be retained when the framebuffer dimensions change. This requirement can be satisfied either by actually retaining the framebuffer data, or by making sure that incremental is set to non-zero in the next FramebufferUpdateRequest.
The principle of one framebuffer update being a transition from one valid state to another does not hold for updates with the DesktopSize pseudo-rectangle as the framebuffer contents can temporarily be partially or completely undefined. Clients should try to handle this gracefully, e.g. by showing a black framebuffer or delay the screen update until a proper update of the framebuffer contents has been received.
A client which requests the LastRect pseudo-encoding is declaring that it does not need the exact number of rectangles in a FramebufferUpdate message. Instead, it will stop parsing when it reaches a LastRect rectangle. A server may thus start transmitting the FramebufferUpdate message before it knows exactly how many rectangles it is going to transmit, and the server typically advertises this situation by saying that it is going to send 65535 rectangles, but it then stops with a LastRect instead of sending all of them. There is no further data associated with the pseudo-rectangle.
Specifies the desired compression level. Encoding number -247 implies high compression level, -255 implies low compression level. Low compression level can be useful to get low latency in medium to high bandwidth situations and high compression level can be useful in low bandwidth situations.
The compression level concerns lossless compression, and hence the setting is a tradoff between CPU time and bandwidth. It is therefore probably difficult to define exact cut-off points for which compression levels should be used for any given bandwidth. The compression level is just a hint for the server, and there is no specification for what a specific compression level means.
A client that supports this encoding declares that is able to send pointer motion events either as absolute coordinates, or relative deltas. The server can switch between different pointer motion modes by sending a FrameBufferUpdate message. If the x-position in the update is 1, the server is requesting absolute coordinates, which is the RFB protocol default when this encoding is not supported. If the x-position in the update is 0, the server is requesting relative deltas.
When relative delta mode is active, the semantics of the PointerEvent message are changed. The x-position and y-position fields are to be treated as S16 quantities, denoting the delta from the last position. A client can compute the signed deltas with the logic:
uint16 dx = x + 0x7FFF - last_x
uint16 dy = y + 0x7FFF - last_y
If the client needs to send an updated button-mask without any associated motion, it should use the value 0x7FFF in the x-position and y-position fields of the PointerEvent
Servers are advised to implement this psuedo-encoding if the virtual desktop is associated a input device that expects relative coordinates, for example, a virtual machine with a PS/2 mouse. Prior to this extension, a server with such a input device would have to perform the absolute to relative delta conversion itself. This can result in the client pointer hitting an “invisible wall”.
Clients are advised that when generating events in relative pointer mode, they should grab and hide the local pointer. When the local pointer hits any edge of the client window, it should be warped back by 100 pixels. This ensures that continued movement of the user’s input device will continue to generate relative deltas and thus avoid the “invisible wall” problem.
A client that supports this encoding is indicating that it is able to provide raw keycodes as an alternative to keysyms. If a server wishes to receive raw keycodes it will send a FrameBufferUpdate with the matching psuedo-encoding and the num-rectanges field set to 1, however, no rectanges will actually be sent. After receiving this notification, clients may optionally use the QEMU Extended Key Event Message to send key events, in preference to the traditional KeyEvent message.
A client that supports this encoding is indicating that it is able to receive an audio data stream. If a server wishes to send audio data it will send a FrameBufferUpdate with the matching psuedo-encoding and the num-rectangles field set to 1, however, no rectangles will actually be sent. After receiving this notification, clients may optionally use the QEMU Audio Client Message.
A client that supports the General Input Interface extension starts by requesting the gii pseudo-encoding declaring that it is capable of accepting the gii Server Message. The server, in turn, declares that it is capable of accepting the gii Client Message by sending a gii Server Message of subtype version.
Requesting the gii pseudo-encoding is the first step when a client wants to use the gii extension of the RFB protocol. The gii extension is used to provide a more powerful input protocol for cases where the standard input model is insufficient. It supports relative mouse movements, mouses with more than 8 buttons and mouses with more than three axes. It even supports joysticks and gamepads.
A client which requests the DesktopName pseudo-encoding is declaring that it is capable of coping with a change of the desktop name. The server changes the desktop name by sending a pseudo-rectangle with the DesktopName pseudo-encoding in an update. The pseudo-rectangle’s x-position, y-position, width, and height must be zero. After the rectangle header, a string with the new name follows.
No. of bytes | Type | Description |
---|---|---|
4 | U32 | name-length |
name-length | U8 array | name-string |
The text encoding used for name-string is UTF-8.
A client which requests the ExtendedDesktopSize pseudo-encoding is declaring that it is capable of coping with a change in the framebuffer width, height, and/or screen configuration. This encoding is used in conjunction with the SetDesktopSize message. If a server supports the ExtendedDesktopSize encoding, it must also have basic support for the SetDesktopSize message although it may deny all requests to change the screen layout.
The ExtendedDesktopSize pseudo-encoding is designed to replace the simpler DesktopSize one. Servers and clients should support both for maximum compatibility, but a server must only send the extended version to a client asking for both. The semantics of DesktopSize are not as well-defined as for ExtendedDesktopSize and handling both at the same time would require needless complexity in the client.
The server must send an ExtendedDesktopSize rectangle in response to a FramebufferUpdateRequest with incremental set to zero, assuming the client has requested the ExtendedDesktopSize pseudo-encoding using the SetEncodings message. This requirement is needed so that the client has a reliable way of fetching the initial screen configuration, and to determine if the server supports the SetDesktopSize message.
A consequence of this is that a client must not respond to an ExtendedDesktopSize rectangle by sending a FramebufferUpdateRequest with incremental set to zero. Doing so would make the system go into an infinite loop.
The server must also send an ExtendedDesktopSize rectangle in response to a SetDesktopSize message, indicating the result.
For a full description of server behaviour as a result of the SetDesktopSize message, SetDesktopSize.
Rectangles sent as a result of a SetDesktopSize message must be sent as soon as possible. Rectangles sent for other reasons may be subjected to delays imposed by the server.
An update containing an ExtendedDesktopSize rectangle must not contain any changes to the framebuffer data, neither before nor after the ExtendedDesktopSize rectangle.
The pseudo-rectangle’s x-position indicates the reason for the change:
More reasons may be added in the future. Clients should treat an unknown value as a server-side change (i.e. as if x-position was set to zero).
The pseudo-rectangle’s y-position indicates the status code for a change requested by a client:
Code | Description |
---|---|
0 | No error |
1 | Resize is administratively prohibited |
2 | Out of resources |
3 | Invalid screen layout |
This field shall be set to zero by the server and ignored by clients when not defined. Other error codes may be added in the future and clients must treat them as an unknown failure.
The width and height indicates the new width and height of the framebuffer.
The encoding data is defined as:
No. of bytes | Type | Description |
---|---|---|
1 | U8 | number-of-screens |
3 | padding | |
number-of-screens * 16 | SCREEN array | screens |
The number-of-screens field indicates the number of active screens and allows for multi head configurations. It also indicates how many SCREEN structures that follows. These are defined as:
No. of bytes | Type | Description |
---|---|---|
4 | U32 | id |
2 | U16 | x-position |
2 | U16 | y-position |
2 | U16 | width |
2 | U16 | height |
4 | U32 | flags |
The id field contains an arbitrary value that the server and client can use to map RFB screens to physical screens. The value must be unique in the current set of screens and must be preserved for the lifetime of that RFB screen. New ids are assigned by whichever side creates the screen. An id may be reused if there has been a subsequent update of the screen layout where the id was not used.
The flags field is currently unused. Clients and servers must ignore, but preserve, any bits it does not understand. For new screens, those bits must be set to zero.
Note that a simple client which does not support multi head does not need to parse the list of screens and can simply display the entire framebuffer.
A client which requests the xvp pseudo-encoding is declaring that it wishes to use the xvp extension. If the server supports this, it replies with a message of type xvp Server Message, using an xvp-message-code of XVP_INIT. This informs the client that it may then subsequently send messages of type xvp Client Message.
A client which requests the Fence pseudo-encoding is declaring that it supports and/or wishes to use the Fence extension. The server should send a ServerFence the first time it sees a SetEncodings message with the Fence pseudo-encoding, in order to inform the client that this extension is supported. The message can use any flags or payload.
A client which requests the ContinuousUpdates pseudo-encoding is declaring that it wishes to use the EnableContinuousUpdates extension. The server must send a EndOfContinuousUpdates message the first time it sees a SetEncodings message with the ContinuousUpdates pseudo-encoding, in order to inform the client that the extension is supported.
The JPEG Fine-Grained Quality Level pseudo-encoding allows the image quality to be specified on a 0 to 100 scale, with -512 corresponding to image quality 0 and -412 corresponding to image quality 100. This pseudo-encoding was originally intended for use with JPEG-encoded subrectangles, but it could be used with other types of image encoding as well.
The JPEG Subsampling Level pseudo-encoding allows the level of chrominance subsampling to be specified. When a JPEG image is encoded, the RGB pixels are first converted to YCbCr, a colorspace in which brightness (luminance) is separated from color (chrominance.) Since the human eye is more sensitive to spatial changes in brightness than to spatial changes in color, the chrominance components (Cb, Cr) can be subsampled to save bandwidth without losing much image quality (on smooth images, such as photographs, chrominance subsampling is often not distinguishable by the human eye.) Subsampling can be implemented either by averaging together groups of chrominance components or by simply picking one component from the group and discarding the rest.
The values for this pseudo-encoding are defined as follows:
This pseudo-encoding was originally intended for use with JPEG-encoded subrectangles, but it could be used with other types of image encoding as well.
_TigerVNC: http://tigervnc.svn.sourceforge.net/viewvc/tigervnc/rfbproto/