Protocol v12r

From XAP Automation
Revision as of 18:22, 31 March 2009 by Edward (Talk | contribs)

Jump to: navigation, search

Specification v1.2 (remastered)


  • Patrick Lidstone
  • Mark Harrison
  • Kevin Hawkins
  • John Tankard
  • Stuart Poulton

Many members of the xAP group mailing list have contributed directly and indirectly to this specification. Special thanks to: Ian Lowe, James Brett and Jon Whiten, as well as the xAP specification sub-committee: Mark Harrison, Kevin Hawkins, John Tankard and Stuart Poulton. Copyright © 2002 Patrick Lidstone, Mark Harrison, Kevin Hawkins, John Tankard

Specification v1.2 Published 1st December, 2002

This document (remastered) April 2009


This document is an RFC that seeks to establish an open, extensible communications protocol to allow appliances and software applications to interact within the domestic environment.

The v1.2 specification is owned and maintained by Patrick Lidstone (

This remastered version (2009) does not supercede the 2002 document, which remains the official specification of xAP v1.2. This version has had various errata applied, some grammatical errors corrected and has been remastered in DocBook XML to improve maintaibability. It is not the objective of this document version to change the xAP v1.2 specification; if changes applied to this version seem in conflict (unintentionally) with the 2002 version then the 2002 version is authoratative version.


xAP is an open protocol intended to support the integration of telemetry and control devices primarily within the home - it is the glue that supports the interconnectivity of Home Automation devices.

The primary design objectives are:

  • Minimalist, elegant and simple, easy to implement/retrofit
  • Suitable for use with a wide range of processing capabilities, from embedded controllers to fully fledged PC's
  • Operating system agnostic
  • Programming language agnostic
  • Network agnostic

These are lofty design goals, and initial implementation is currently focused on IP based networks, PC's running Linux, Win32, Rabbit and PIC embedded microcontrollers.

The chosen implementation mechanism for xAP:

  • reuses existing infrastructure where possible (for example it is able to co-exist on a wireless LAN)
  • requires no central controller
  • provides a highly distributed and fault tolerant architecture tat allows continued operation of systems wherever possible even in the event of individual component failure.


The official xAP web site:

Discussion mailing list for all things xAP related:

Reference code implementation of xAP for Win32 PCs, Linux (including the TiVO PVR), Mac OS-X, Pocket PC (Windows CE 2002), as well as for the PIC and Rabbit microcontrollers is available via the xAP website under the xAP Apps section.

Change History

Version Date Comments
v1.2 remastered April 2009 Remastered using DocBook XML
Applied accumulated errata
v1.2 November 2002 Compact form of source.instance
Introduction of targeted addressing mode (through target tag)
Introduction of uid unique identifier tag
Deprecation of "style" tag
Wild card addressing
Variable depth instances
Header tag order revised
v1.1 2002 Introduces the keyword "class" into the header
Sequence of all header tags is fixed
Messages containing multiple sections are explicitly identified through the use of "style= multi" tag in the header
ASCII hex case specified

Protocol Basics

A xAP-enabled device or application may be a sender, receiver, or both. It is connected to a communications network including, but are not limited to: Ethernet ("computer" networks); RS232, and RS485 serial networks;and wireless.

As a sender, a xAP-enabled application broadcasts a message. This message contains sufficient information to uniquely identify the sender and the semantics of the message (the significance of the contents and what they mean.) The message does not necessarily identify an intended recipient but it always identifies the source.

As a receiver, a xAP-enabled application listens to broadcasted messages. The receiver inspects each message header to identify whether the message contains information that is of interest to it. Accordingly, the receiver then either discards the message or processes it.

It is possible for many receivers to intercept the same broadcast message at the same time. It is also possible for receivers to receive and process messages from more than one source. This allows for ad-hoc, many-to-many relationships on an implicit basis, without the need to configure explicit connections between various devices.

xAP-enabled applications that are connected to different physical networks (RS232, Ethernet, radio) may intercommunicate. In order to pass messages between the different physical networks, a protocol converter (bridge) is required. In order to limit the traffic passing between networks, the bridge may optionally be configured to only forward messages that originate from specifically nominated sources.

Depending on the physical network, a xAP message may be wrapped in an additional transport layer wrapper.

Message Structure

Irrespective of transport, a xAP message is text over a number of lines. Groups of lines make up blocks.

There is header followed by a message body containing one or more message blocks. The layout of the header and message blocks is similar.

Anatomy of a xAP message

Figure 1. Anatomy of a xAP message

The header is mandatory and its schema (structure) is defined by the xAP protocol, see the section on headers. The schema of each message block is defined by the application. Recommended schemas for commonly encountered Home Automation devices (e.g. thermostats, caller id units) are maintained by the xAP group and may be re-used as required.

Since xAP messages are often targeted at low power, limited capability devices, such as PIC's, the use of multiple message blocks is discouraged, although, under certain circumstances, it may be unavoidable.

Each block is named.

Block contents follow enclosed between curly braces {..}. Each line is terminated by a linefeed <LF> character (ASCII 10 decimal).

Each block contains zero or more name-value pairs. An example of a name-value pair is temp=25, which might convey the fact that the internal room temperature is 25°C.

A xAP message conveying this temperature information might look like this:


The indentation in this and following examples is to show the message structure clearly; it is not present in the transmited wire form.

xAP promotes the use of common data definitions wherever possible. Commonly encountered elements (e.g., caller id information, X-10 control messages etc) can be represented using standard schema. A device intercepts and acts on messages. A message comprises a number of message blocks. The semantics of a specific message block are determined by the schema.

A xAP class defines the collection of message blocks (schema) to be expected in the message body. It effectively defines the structure of the entire message in terms of message blocks. Schema represent entities that are commonly encountered in the home control environment - such as temperature, phone numbers, device status and device control. These entities can be used in many different contexts. A class defines a context within which one or more schema are applied.

xAP identifies the schema that applies to a given message through the class=<class>.<type> name-value pair in the message header. A class may comprise one or more subtypes, each of which is identified by the type field. This is discussed in more detail below.

Message Grammar

A message is a header bock followed by zero or more body blocks. Header and body blocks have the same structure:


Block Keyword

Each block is introduced and identified by a keyword line.

This keyword uses alpha-numeric printable characters A..Z (A through Z), a..z (a through z) 0-9 (zero through nine), _ (underscore), - (dash) and space (ASCII character 32 decimal).

Leading and trailing space characters are not permitted. Message block names may include embedded spaces.

The maximum keyword length is 32 characters. This value is arbitrary, but chosen to suit the limited storage capabilities of low-end devices.

Keywords are not case sensitive. Thus "my thing", "My Thing" and "MY THING" are all equivalent.

The message block name does not have to be unique within the message - that is, the same message sections may be repeated if required (albeit, usually with different content).

Block Body

The start of a block body follows the keyword line.

A block body starts with { (open brace, ASCII character 123 decimal), and is terminated by } (close brace, ASCII character 125 decimal).

Braces always appear on their own line.

Message blocks may be nested if required.

A message block is always explicitly named.

Message block bodies contain successive lines defining name-value pairs.

The order of name-value pairs in message blocks is not significant.

Name-Value Pair

Each name-value pair within a message block comprises a keyword, a delimiter and a value.

The keyword follows the same rules as described above for a message block keyword.

The delimiter can be = (equals, ASCII character 61 decimal) or ! (pling, ASCII character 33 decimal) and indicates the value encoding method.

  • = indicates that the value is encoded as an ASCII string.This is the preferred encoding method.
  • ! indicates that the value is encoded as an ASCII hex representation.This allows for the broadcast of raw binary data. Whilst unavoidable under certain circumstances, its use is discouraged because of the issues with portability (numeric representations differ across processor types)

ASCII character strings denoted by = may represent any arbitrary value, including integer and floating point numbers. Embedded spaces are permitted.

ASCII hex strings denoted by ! are case sensitive and should use upper case. (i.e. 0A is acceptable and represents decimal value 10, 0a is illegal and has no meaning). Embedded spaces are not permitted.

Each name-value pair is terminated with a <LF> (linefeed) control character (ASCII value 10 decimal).

The default behaviour is for leading and trailing white space to be treated as significant in the value field. All white space between the = and terminating <LF> character is considered significant. This allows for the inclusion of leading white space and trailing white space in string literal values.

The value is case sensitive and is interpreted literally. Thus fred=hello and fred=HELLO assign literally different values (hello, HELLO) to the element fred.

The use of hex encoding with the ! character is strongly discouraged since the meaning of messages becomes opaque, and device interoperability promoted by the use of xAP is compromised. Where hex encoding is used, it is mandatory, and a requirement for xAP compliance, to publicly document the packet format.

The order of name-value pairs within a block has no significance. The same name may be used more than once in the same section if required, although by convention, multiple entities are usually differentiated through the use of an index element (e.g. my.thing.0, my.thing.1).

Maximum Message Size

xAP does not currently support fragmentation or re-concatenation of messages. The maximum message size is determined by the capabilities of the xAP device and the network infrastructure. For example, the maximum message size supported by xAP over Ethernet is typically 1,500 bytes (the conventional maximum packet size for a UDP datagram).

Example Messages

The following illustrates the use of the message grammar to construct a conventional ASCII string value based message. For clarity, the linefeed <LF> terminators have been omitted and the message has been padded with white space which would not normally be present in the message when transmitted on the wire. The following message might be generated by a caller-id unit to notify a new incoming call.

  number=0207 2828 2929

The corresponding on the wire form of this message, removing the white space and showing the <LF> characters explicitly is:

number=0207 2828 2929<LF>

The next example illustrates the use of the ASCII hex value encoding. The message sends a byte-encoded equivalent of "hello" (ASCII characters 0x68, 0x65, 0x6C, 0x6C, 0x6F respectively).


The corresponding on the wire form of this message, removing the white space and showing the <LF> characters is:


Message Header

Every xAP-compliant message must include a header section. It is mandatory that this header is the first section of a xAP message. A receiver should discard any malformed message. The order of items in the header is fixed to make parsing easier for simple devices, however not all items in the header are mandatory.

The example below shows a typical xAP header:


The xAP header name-value pairs are specified below. The order in which the name-value pairs are included in the message header is significant and must follow the order specified here.

Version (mandatory)
Always has value of "12" indicating the message follows this v1.2 xAP specification. The first digit indicates the major version, the second the minor version.
Hop Count (mandatory)
Always has value of "1" set by the originator. This value will be incremented each time a message traverses a bridge or gateway (but not when it traverses a hub).
Unique Identifier (mandatory)
Uniquely identifies a particular hardware device on a xAP network. The UID is represented as ASCII hex number, with all characters in upper case, of the form nn dd dd ss. The first two digits, nn, of the UID are reserved for future use and must be FF by default. The digits dd dd are assigned at device configuration time to ensure that the hardware device is uniquely identified within the local xAP domain. The last two digits identify the device sub address, if supported, or are otherwise zero. E.g. FF123400. A UID value is exactly eight hex digits The UID is usually configured at device install time.
Message Class (mandatory)
Provides a cue that indicates how the remainder of the message is composed, in terms of which schema it uses. The xAP group maintain standard message classes (and associated schema) for common source types and is happy to accept contributions from developers. Standard classes can be identified through the use of the reserved prefix "xap-".<class> Identifies the collection of schema applicable to this message.<type> Identifies the sub-schema applicable to this message.
Example: class=xap-x10.command identifies that the message content that follows on from the header represents a xAP group standard x10 command, and should follow a prescribed (but implicit) format for x10 commands.
Example: class=xap-x10.status identifies that the message that follows on from the header is a xAP group standard x10 status request, and should follow the prescribed (but implicit) format for x10 status requests.
Message Source (mandatory)
Provides a means of uniquely identifying the application or device originating this message. The <vendor>.<device>.<instance1..n> combination is assigned when the device is connected to a xAP network for the first time, and should be unique within the network. The remaining elements of the address identify a specific end-point within a specific device. As such they are required to be unique within the device
Identifies the vendor of the device (or application) originating the xAP message. Vendor names are managed and allocated upon request by the xAP group to ensure that they are unique. This element is fixed, and determined by the programmer at design time. The vendor id may be no longer than 8 characters.
Identifies the physical device or application originating the xAP message. Examples include: CM12U (an X-10 controller), Meteor (a caller id unit), Outlook (the Microsoft e-mail application). This element is fixed, and determined by the programmer at design time. The device id may be no longer than 8 characters.
<instance1> [.<instance2..n>]
Identifies this instance of the device or application. Typically reflects the geographic location of a device or system (e.g. "sitting-room"). First element is mandatory, additional elements may added if required. The instance field(s), in conjunction with the vendor and device field, uniquely identifies the originator of the message at the level of "that instance of the application [on a known host] on my network", and so provides a cue which indicates how the message content should be handled. The value of the instance field is usually determined by the end-user at the time when the device or application is installed for the first time. Each element is delimited by a period.
(Optional) Used for subaddressing of a multi-function device or application. The value of the field(s) may be determined either by the programmer at design time or by the end-user at run time when the device or application is installed for the first time, depending on the application. The subaddress is separated from the device logical address by a : (colon), multiple elements are separated by a . (period).It is recommended overall length of a source address is limited to 128 characters inclusive of delimiters.
Example: source=acme.cm12.node0 identifies a CM12U sited at node 0 which is connected to the xAP network using software written by the mythical vendor Acme.
Example: source=xapcorp.cid.home.line1 identifies a caller id unit manufactured by the mythical xAPCorp. The device is connected to the home phone system's line #1.
Message Target (optional)
Provides a means of targeting a specific application or device family interested in this message or event. Composition is the same as for source address. Devices are not required to support target based addressing, but when they do, they must also include support for target address wildcarding.

A receiving device should ignore any unknown name-value pairs included in the header.

Message Body

A message body comprises one or more message blocks. Messages that do not include a body are legal, the heartbeat message is one such example, but they are limited to status reporting, and their general use is discouraged. Where possible, the use of single message-block messages is encouraged because they are readily accessible to low power devices.

Each message block is introduced by a block name. Multiple message blocks may share the same name if, and only if, they use the same schema. In array type situations, it is recommended that message blocks are labelled with an index (e.g. my.block.0, my.block.1) to differentiate them. Within a message, the message block name is used as a cue to indicate the schema used to encode that message block, and thus which name, value pairs a receiver might expect to find within the message block and their semantic significance.

Address Schemes

xAP is a broadcast protocol; all messages are received by all devices. The design of xAP enforces identification of the sender in all circumstances.

Unique Identifier (UID)

Each device on a xAP network, and any logical endpoints included within the device, are identified by a unique identifier, its UID.

The unique identifier element of the address is assigned at configuration time, prior to the device being connected to the xAP network for the first time. The UID, a hexadecimal number, identifies a particular hardware device for life, even if remaining elements of the address are reconfigured. Most receivers will generally act on messages irrespective of the sender's UID, choosing to act instead on its logical name (vendor, device and instance ). Low power devices may prefer to filter messages based on UID, allowing for memory efficient configuration and address management.

The UID is generated as a six-digit, upper-case ASCII hex number, comprising nnddddss where nn is the xAP network and domain identifier (FF by default), dddd is the device identifier and ss is a subaddress node within the device. For all elements of the UID, the values FF and 00 are specifically defined by this specification or reserved for future use. Sub addressing is explained in more detail below.

xAP Addresses

In addition to the UID, every xAP device supports a human readable address. Messages always include the source address of the originator and may optionally include a target address which indicates that a message is of specific interest to a particular device or devices. Even when targeted in this way, the message will still be received by all other connected xAP devices, although they will usually ignore it.

A xAP source or target address comprises two parts: a logical name and an optional sub-address. For instance, Source=AVendor.ADevice.AnInstance:AnOutput.

Structure of xAP source and target addresses

Figure 2. Structure of xAP source and target addresses

Logical Name

The logical name for a device contains the fields: vendor, device, and one or more instance fields. The combined fields should uniquely identify a physical hardware device or software application on the xAP network.

  • The vendor field is assigned to the device developer by the xAP group.
  • The device field identifies the hardware or software application.
  • The instance field identifies an instance of that hardware or software application.

Typically the instance reflects the physical location of the device or some other application-specific identifier. For example, one copy of an Outlook mail connector that notifies new mail to the xAP network, might have a logical name acme.outlook.mark for Mark's mail box, whilst another instance connected to Mary's mailbox (on the same xAP network) might have the logical name acme.outlook.mary. Similarly, a lamp controller in the lounge might have the logical name acme.lamp.lounge. If required, one or more instance fields may be concatenated. This allows structured naming of devices - for example, two physically separate lamp controllers might be identified as acme.lamp.lounge.table and acme.lamp.lounge.ceiling. This feature is particularly powerful when combined with wildcarding, since it permits a primitive form of group addressing.

As a consequence of the fact that the logical name uniquely identifies a device (or software application), there are constraints imposed on the allocation of logical names. If a device exists on the xAP network with a logical name a.b.c, a second device may not use the logical name a.b.c.d.


The optional sub-address is typically used when a number of inputs or outputs are served by a single item of xAP hardware. For example, a light switch that provides four switches on a single faceplate would use sub-addressing to identify these individually to the xAP network. Sub-addressing is also relevant to more complex multi-function devices, such as a Homevision controller, that include, say, both analogue and digital ports. While the logical name identifies the physical device which will receive a message, the sub-address allows a specific sub-section within the device to be uniquely addressed. For example, in the case of Homevision, sub-addresses: parallel.input, parallel.output, analogue.input and analogue.output might be appropriate.

In this way, all endpoints within a device are visible to the network and may be uniquely addressed. A sub-address is separated from the logical name by a : (colon) separator.

Like the instance part of the logical name, sub-addresses can be of variable depth, :a or :a.b or :a.b.c etc.

Address Size

The recommended maximum length for the entire xAP address is 128 characters. This provides a compromise between the use of meaningful naming schemes, storage requirements, and the time taken to transmit data over a slow serial connection.

While the instance and sub-address elements are variable depth with no maximum depth limit imposed,a combined maximum depth of 4 should be adequate for most applications.

Much consideration has been given to balancing the requirements of a flexible addressing scheme against the limited storage capability of small devices. Note that in many instances it is possible for devices to identify the originator of a message solely from the UID, minimising the requirements for string storage space.

Addressing Modes

On receipt of a message, all devices inspect the message header. On the basis of the name, value pairs contained in the header, the device decides whether a message warrants further processing, or should be discarded. Two alternative addressing schemes are supported to allow devices to determine whether or not they should act on a given message.

Source-Based Addressing

A receiving device determines whether the message is of interest by inspecting (among other header items) the source of the message. This mode of addressing works well for one-to-many relationships. There are many possible receivers of data broadcast by a temperature sensor located in a particular room, for example, and they may all intercept the same message concurrently provided they know its source. Source based addressing is available to any receiver, since it is mandatory for senders to include their source address, and the address is guaranteed to uniquely identify the sender. If required, low powered devices may choose to filter on incoming messages based on the UID rather than the source address. Whilst very limited storage is required to identify the source of incoming messages using that method it also precludes the use of wildcards.

Source-based addressing

Figure 3. Source-based addressing

Target-Based Addressing

A sending device may wish to target a message at a specific device. It does this by including the address of the target device in the header using the target keyword. This addressing mode is particularly useful for simple devices that may not be capable of filtering messages that originate from multiple sources. For example, a command sent to a simple window-blind controller to close a specific set of blinds. The controller need only recognise messages aimed at itself rather than retaining a list of all possible originators. Nevertheless, the targeted message is still broadcast and may be intercepted by nodes on the network other than the target - for example, a display device that tracks the state of all the house's windows. Whether a device, as a receiver, chooses to support target addressing is determined by the implementer and is dependent on the functionality offered by the device.

Target-based addressing

Figure 4. Target-based addressing

Wildcarding of Header Addresses

Target addresses may be wildcarded in certain circumstances. A matched wildcard address indicates that the entire message (whether a single block or multi-block message) is intended for the recipient.

If a device supports target addressing, it must support wildcarding of target addresses. Wildcards are specified on a per field basis, using the reserved characters * and >.

* indicates that any value may be substituted for the current field.
> indicates that any further input is matched.

Thus a device with a source address of a.b.c.d is expected to respond to messages with a target of target=a.*.c.d. It would not be expected to respond to a message with the target address target=a.*.c because the last field does not match. A device with source address a.b.c.d would be expected to respond to messages containing target=a.b.c.>.

Unless a wildcarded target address contains it, any : (colon) sub-address separator in the address of the receiver is treated like a . (dot) separator. Exact matching against a : is required when the wildcarded target address contains it.

A sender can use wildcards in the target address of messages it sends. A receiver can use wildcards as filters for either the source or target addresses of messages it receives. A sender is not allowed to place wildcards in its source address. Wildcarding is simple to implement yet surprisingly powerful leading to complex control scenarios.

Basic Wildcard Modes

Target address wildcarding
The sender sends a message with a wildcarded target target=acme.K400.lounge.curtain.* to multiple fixed-target-filtering receivers such as all window-blind controllers in a single room having addresses acme.K400.lounge.curtain.0, acme.K400.lounge.curtain.1 etc.

Sending a message with a wildcarded target address

Figure 5. Sending a message with a wildcarded target address

Source filter wildcarding
Senders send messages with no target to a wildcard-source-filtering receiver. The receiver filters messages from multiple sources by applying a single wildcarded filter to the messages' source address. For example, a receiver could match messages using the filter source=acme.digitstat.> in order to display the temperatures broadcast by all acme thermostats in the house. Avoiding the need to explicitly list and configure the addresses of each individual thermostat at the receiver. Additional thermostats can also be added at any time without the need to modify the existing configuration. Useful for low power devices.

Receiving messages using a wildcarded source address filter

Figure 6. Receiving messages using a wildcarded source address filter

Advanced Wildcard Modes

These wildcard modes are included here for completeness. Any device that is capable of supporting the basic wildcarding modes is inherently capable of supporting the advanced modes. Since the relationships between devices in these modes is complex, they are unlikely to find widespread application.

Target filter wildcarding
Sources send messages with fixed target to a wildcard-target-filtering receiver. The receiver filters on target address using a wildcard. This allows a receiver to respond to multiple target addresses using a single parameter. For example, a receiving device that has multiple output ports might use the filter target=acme.iodevice.port.* to intercept messages with targets acme.iodevice.port.1, acme.iodevice.port.2 etc. Such messages might originate from many different sources on the network.
Target address and target filter wildcarding
Senders send messages with wildcarded targets to wildcard-target-filtering receivers. Wildcarded filters can work on wildcarded addresses. This mode may be used to create sets of many-to-many relationships.

Restrictions on Wildcarding

It is neither legal nor meaningful for a sending device to wildcard its own source. The source address should always provide a means of unambiguously identifying the originating device.

A receiving device must implement target-based wildcarding if it supports target-based addressing. This ensures that any sender can successfully control a receiving device using a wildcarded target address.

A receiving device may implement source-based filtering on a wildcard basis at the developer's discretion.

Wildcarding of Targets in Multi-Block Messages

Any multi-block message with a wildcarded header target address may optionally include additional target filters within each message body. This allows selected parts of a message to be targeted at individual receivers. The receiver first matches the header target tag. On finding a match, it may then choose to inspect the target tag in each message block, processing the message block if it is a good match. Inclusion of the target tag within a message block is optional. Message blocks which do not include a target tag are assumed to be aimed at all recipients.

For example, the following message illustrates how multiple message blocks in a single message can be used to achieve selective control over a number of instances of the same device:

  ... message block aimed at lounge instance of barDevice ...
  ... message block aimed at bedroom instance of barDevice ...
  ... message block aimed at all instances of barDevice ...

Receiver support for body wildcarding is not mandatory. However, if a given message schema is supported by a receiver, and that message schema uses body wildcarding, then the receiver must correctly apply filtering to that message.

Standard Message Schema

The structure of a message is defined by a class. The name of a class provides an implicit indication to the receiver as to which message blocks within the message may be anticipated in the message body. Each message block is itself defined by a schema. The schema simply defines the name-value pairs contained in the message block, and the semantic significance. Schema are often re-used from class to class. This means that developers do not have to waste time re-inventing a message which represents a phone number, or a temperature, for example, but can adopt a common representation for that entity. In xAP terminology, a class is therefore simply a collection of schema.

Recognising that interoperability is key to the widespread adoption of xAP, the xAP group maintain a list of standard device schema. It is strongly recommended that wherever possible developers use the standard device schema in their own work. The group welcomes the submission of new schema and requests for extensions to existing schema.

Standard device schema can be identified from the use of the prefix "xap-" in the header class field.

The relationship between class and schema

Figure 7. The relationship between class and schema

Device Monitoring - Heartbeats

In order to allow health monitoring of all xAP-enabled components within the home, it is strongly recommended that a xAP enabled device generates a periodic heartbeat. It is, however, recognised that some low-end (embedded) devices may not be able to support this functionality.

The heartbeat message has the following minimum structure:


Heartbeats are sent at device-level so the source address of a heartbeat will have no subaddress part and the sub-address part of the UID will always be "00".

The class name-value pair of a heartbeat is: class=xap-hbeat.alive.

Following the normal header name-value pairs, the heartbeat also includes:

Heartbeat Interval (mandatory)
Specifies the period between heartbeats in seconds. The interval should be not less than five seconds, in most applications once a minute (interval=60) is sufficient.
Ethernet Port (optional)
port=<port number>
Defines the UDP port on which the application listens for xAP messages. Applicable to Ethernet based xAP devices only, see Ethernet Hub Protocol
Example: port=50322 indicates that a device is listening for inbound xAP messages on port 50322
Process ID (optional)
pid=<ip_address>:<process number>
Defines the IP address and process ID of the sending application. Receivers (especially hubs), may use the process ID part to identify that an application has re-started. xAP-aware management applications may use this to facilitate inter-process messaging at an operating system level. Note that inter-process messaging should only be used to control the visual appearance of an application, and should not be used to subsume communications which would otherwise be performed by the xAP protocol itself.
Example: pid=

The order of the name-value pairs in the heartbeat message is fixed, and must follow the sequence prescribed above.

Additional network specific message sections may be added to the heartbeat to convey xAP routing configuration information.

Since xAP heartbeats, like xAP messages, are broadcast, it is possible to monitor the health of the entire xAP infrastructure from any point on the network. Automatic monitoring software is available to detect, for example, the failure of a specific process and raise an appropriate alert automatically.

Since every device on the network receives heartbeat messages, it is strongly recommended that devices do not transmit heartbeats more frequently than absolutely necessary. An application will typically send a heartbeat immediately on start-up, to ensure immediate recognition by any local hub, and then subsequently at intervals of a minute or more.


xAP is network agnostic, as far as it practicable. Where xAP messages are to be passed between two different physical networks, a software bridge is used. The bridge understands the implementation details of the xAP protocol on each physical network, and performs the necessary protocol conversions to pass the message from one network to another.

In some cases, the bridge may provide a configuration interface to allow traffic in one or both directions to be restricted.

Messages passed over the bridge always have the xAP-header hop count increased. A bridge may be configured to discard messages with hop-count > n to prevent looping/broadcast storms.


A gateway provides access to a xAP network from a remote point over the same physical network medium. For example, an Ethernet gateway might allow access to the home xAP network over the Internet. Typically a gateway acts a bridge, but uses point-to-point or connection oriented protocols to connect the two bridges. Gateways may elect to filter messages, depending on the capabilities of the bridged network, in order to restrict either traffic volumes or message size.

Transport Wrappers

Depending on the chosen network infrastructure, it may be necessary to encapsulate the basic xAP message in an additional transport wrapper. Examples of networks which might require this are those based on RS232 serial data links, where an indication of the start and end of a message, and a checksum, are useful because corruption over such a link is not uncommon, or those with specialized addressing requirements, such as SNAP.

Basic Ethernet Wrapper

The use of xAP over Ethernet does not require any additional wrapper. Messages are usually sent as UDP broadcast datagrams, although in special cases they may also be sent using connection oriented protocols if required.

Basic Serial Transport Wrapper

The xAP transport wrapper for a basic serial connection is defined as follows:

  • The xAP message is prefixed with the ASCII control character<STX> (ASCII character decimal 2)
  • The core xAP message is transmitted. Any instances of the<STX> character and<ETX> character (ASCII characters decimal 2 and decimal 3 respectively) are escaped by prefixing the character with <ESC> (ASCII character 27). i.e. an embedded <STX> becomes <ESC> <STX> and an embedded <ETX> becomes <ESC> <ETX> . This mechanism is defined here for completeness; in practice it would be very unusual to transmit non-printable characters as part of a xAP message.
  • Instances of the <ESC> character (ASCII character 27) are also escaped. i.e.<ESC> becomes<ESC> <ESC>. Again, it would be rare to embed <ESC> characters within a xAP message in practice.
  • At the end of the xAP message a 16-bit CRC checksum is appended as four ASCII-hex digits (i.e. human-readable, not binary). The checksum is applied to all data within the message envelope: the <STX>, checksum itself, and <ETX> character are not included in the CRC calculation. Hex digits A-F are represented in upper case. Source code examples illustrating the calculation of 16-bit CRC checksums can be found at
  • If the checksum is not calculated, four dashes (ASCII code decimal 45) are substituted in its place.
  • The checksum is immediately followed by <ETX> (ASCII character decimal 3)

Ethernet Hub Protocol

On startup, a xAP-enabled application that is a hub client will look for a free UDP port on the loopback interface ( in the IANA recommended ephemeral port range 49152 to 65535. Once a free port has been identified and bound to the application, it sends a heartbeat message on the broadcast address using the IANA allocated xAP port 3639. The heartbeat includes the port name-value pair identifying the bound port number.

For example, a device with the logical name acme.cid.home.line1 that has found the free port 49167 and bound to it, sends the following heartbeat message:


Subsequently, the application will send all outgoing messages to the host broadcast address on port 3639 and will receive all incoming messages, via the hub, on loopback port 49167.

A software hub, located on the same host as the client application, behaves as follows:

  • On startup, it binds an inbound socket to port 3639 and opens an outbound socket on the loopback interface.
  • Any incoming heartbeat on the primary interface is inspected and the originating IP address validated. If the heartbeat originates from the same host as the hub, the port value is added to a client list. The heartbeat is forwarded to all client applications known to the hub.
  • Any incoming message received on the primary network interface that is not a locally generated heartbeat is forwarded to all ports on the client list using the loopback interface.
  • If no heartbeat is received from a client for two heartbeat intervals, it is removed from the client list.

In choosing the heartbeat interval for a xAP-enabled application, bear in mind that the recovery time for the application, should the hub restart, will be, on average, the same as the heartbeat interval. Recovery following restart of a hub is automatic and an application need take no specific corrective action. If required, a xAP-enabled application may detect a loss of connection with the local hub by listening for echoes of its own heartbeat (on the loopback port). Failure to receive the heartbeat echo indicates a defective or non-existent hub.

Reference software hubs are available for Win32, PocketPC and Linux. See the Resources section at the beginning of this document. The IANA port allocations can be found at

Example Implementation

xAP over Ethernet uses UDP Broadcast. UDP broadcasts are only visible within the subnet within which they originate, and are limited to 1,500 bytes in size. A broadcast may be received by any device within the subnet.

xAP has been allocated a dedicated UDP port 3639 by IANA on which to communicate. This port is used in the examples that follow.

Sending a xAP message from, say, Visual Basic, is very straightforward. The code fragment below (courtesy Mark Harrison) illustrates how to construct a message with the schema:

  unread=<number of unread waiting>

The <uid> marker would be replaced with a true unique identifier for this instance of this application in real life. This would have the form FFABCD00 or similar.

xAPMessageBody = xAPMessageBody & "xAP-header" & Chr$(10)
    ' mandatory header

xAPMessageBody = xAPMessageBody & "{" & Chr$(10)
    ' start of header section

xAPMessageBody = xAPMessageBody & "v = 12"& Chr$(10)
    ' mandatory version number

xAPMessageBody = xAPMessageBody & "hop = 1"& Chr$(10)
    ' mandatory hop count
    ' must always be set to 1 by an input plugin (changed by bridges)

xAPMessageBody = xAPMessageBody & "uid = FFABCD00"& Chr$(10)
    ' mandatory UID, unique to this application in this xAP domain

xAPMessageBody = xAPMessageBody & "class=mail.notification" & Chr$(10)
    ' mandatory class = class.type ' identifies message schema

xAPMessageBody = xAPMessageBody & "source = <uid>.Acme.Outlook" &oUserName & Chr$(10)
    ' mandatory source = vendor. application. instance
    ' must reflect the name of the application providing the information
    ' and is guaranteed to be unique within this xAP network
    ' NB note use of instance to identify user, allows several copies
    ' of Outlook "his n hers!" to run the plugin

xAPMessageBody = xAPMessageBody & "}" & Chr$(10)
    ' mandatory end of header section

APMessageBody = xAPMessageBody & "inbox.unread" & Chr$(10)
    ' message body defines <schema>.<schemaType> by convention

xAPMessageBody = xAPMessageBody & "{" & Chr$(10)
    ' start of message body section

xAPMessageBody = xAPMessageBody & "unread=" & Trim$(Str$(UnreadMessagesInInbox)) & Chr$(10)
    ' unread is a plugin-specific keyname, and must be letters and numbers only
    ' = is a reserved character to separate the key from the value
    ' the value follows (in this case, a variable cast to a string type

xAPMessageBody = xAPMessageBody & "}" & Chr$(10)
    ' mandatory close message body for the source

This message can then be broadcast by calling the SendData method of VB's TCP/IP control. The TCP/IP control should be configured as follows:

LocalPort =3639 Host = <Broadcast IP> Port = 3639 Protocol = 1 (sckUDPProtocol)

Those unfamiliar with TCP/IP networking may find this link useful in assisting with the calculation of the broadcast address.

This example shows how to send a xAP message in its simplest form. In most cases, though, it will be a requirement to deploy more than one xAP-enabled application on a single computer. Basic limitations in the way TCP/IP sockets are implemented mean that although it is possible to have several senders on the same host, there can only be one receiver active at a time. For this reason, xAP uses a software hub in situations where there is more than one listener on a single host. Embedded systems rarely, if ever, need a hub.

Example Application

xAP Home Display LCD's are displays that can be located at any convenient point in the home and are able to display information from a variety of live sources. The display has a small on-board controller and is connected to an Ethernet network. The device may be configured through a web browser, for example, such that each line of the display will display a prescribed name-value pair from any arbitrary xAP message.

In the simplest implementation, the display might be used as a straightforward read-out for a thermostat. In this instance, the thermostat might broadcast a message:


The display might be configured as follows:

"Current Temp "+ Acme.DigiStat.SittingRoom:Thermostat.Status:Current.Status:temp + "°C"
"Target Temp "+ Acme.DigiStat.SittingRoom:Thermostat.Status:Current.Status:Setpoint + "°C"
"Heating System "+ Acme.DigiStat.SittingRoom:Thermostat.Status:Current.Status:Output

With the end result (updating in real-time):

Current Temp 22°C
Target Temp 25°C
Heating System On

Although useful, this is rather unimaginative. Things get more interesting when a bit of intelligence is added to the chain. The display could be more intelligent. Perhaps it would be useful to use the bottom line to display either the number of unread e-mail messages or, if the phone rings, the name of the caller.

In this case, the display configuration is extended for line 4 to include:

FooCorp.Outlook.<username>:mail.notification:inbox.unread:Unread + " unread mails"
or + "calling"

The first item, Outlook.<code><username>.Unread</code>, might be generated by an Outlook plug-in running on the end-users laptop.

The Outlook plug-in generates a message with the schema:

  unread=<number of unread waiting>

The second item is more interesting. It might be generated by xAP-enabled database service.

The server-based application listens for CID.notification messages from Acme.CID.Home.Line1:


and performs a name lookup against the number. The application then re-broadcasts this information in a new message:

  name=Fred Bloggs
  number=020 7828 2929

The result is a display that shows:

Current Temp 22°C
Target Temp 25°C
Heating System On
28 unread mails

and changes to:

Current Temp 22°C
Target Temp 25°C
Heating System On
Fred Bloggs calling

when there is an incoming phone call from Fred Bloggs.

The above illustration supposes that the display has sufficient on-board intelligence to allow the definition of relatively complex xAP message filters. This won't always be the case - the simplest display device will only be able to extract values from a single field and display that as text, or perhaps even just light a solitary LED. In these cases, the formatting of display information would have to be performed by an intermediate process, perhaps a server-based application.

Another useful twist with xAP is that there can be many recipients of the same message. For example, a text to speech engine could also intercept messages and announce the name of the caller over a loudspeaker simultaneously.