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Web Application Messaging Protocol

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WebSocket subprotocol registered at IANA
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WAMP is a WebSocket subprotocol registered at IANA, specified to offer routed RPC and PubSub. Its design goal is to provide an open standard for soft, real-time message exchange between application components and ease the creation of loosely coupled architectures based on microservices. Because of this, it is a suitable enterprise service bus (ESB), fit for developing responsive web applications or coordinating multiple connected IoT devices.

Characteristics

Structure

WAMP requires a reliable, ordered, full-duplex message channel as a transport layer, and by default uses Websocket. However, implementations can use other transports matching these characteristics and communicate with WAMP over e.g. raw sockets, Unix sockets, or HTTP long poll.

Message serialization assumes integers, strings and ordered sequence types are available, and defaults to JSON as the most common format offering these. Implementations often provide MessagePack as a faster alternative to JSON at the cost of an additional dependency.

Workflow

WAMP is architectured around client–client communications with a central software, the router, dispatching messages between them. The typical data exchange workflow is:

  • Clients connect to the router using a transport, establishing a session.
  • The router identifies the clients and gives them permissions for the current session.
  • Clients send messages to the router which dispatches them to the proper targets using the attached URIs.

The clients send these messages using the two high-level primitives that are RPC and PUB/SUB, doing four core interactions:

  • register: a client exposes a procedure to be called remotely.
  • call: a client asks the router to get the result of an exposed procedure from another client.
  • subscribe: a client notifies its interest in a topic.
  • publish: a client publishes information about this topic.

This can have subtle variations depending on the underlying transport. However, implementation details are hidden to the end-user who only programs with the two high-level primitives that are RPC and PubSub.

Security

As WAMP uses Websocket, connections can be wrapped in TLS for encryption. Even when full confidentiality is not established, several mechanisms are implemented to isolate components and avoid man-in-the-middle attacks. Default implementations ensure that trying to register an already registered procedure will fail.

Routers can define realms as administrative domains, and clients must specify which realm they want to join upon connection. Once joined, the realm will act as a namespace, preventing clients connected to a realm from using IDs defined in another for RPC and PubSub. Realms also have permissions attached and can limit the clients to one subset of the REGISTER/CALL/PubSub actions available.

Some realms can only be joined by authenticated clients, using various authentication methods such as using TLS certificate, cookies or a simple ticket.

Routed RPCs

Unlike with traditional RPCs, which are addressed directly from a caller to the entity offering the procedure (typically a server backend) and are strictly unidirectional (client-to-server), RPCs in WAMP are routed by a middleware and work bidirectionally.

Registration of RPCs is with the WAMP router, and calls to procedures are similarly issued to the WAMP router. This means first of all that a client can issue all RPCs via the single connection to the WAMP router, and does not need to have any knowledge what client is currently offering the procedure, where that client resides or how to address it. This can indeed change between calls, opening up the possibility for advanced features such as load-balancing or fail-over for procedure calls.

It additionally means that all WAMP clients are equal in that they can offer procedures for calling. This avoids the traditional distinction between clients and server backends, and allows architectures where browser clients call procedures on other browser clients, with an API that feels like peer to peer communication.

However, even with multi-tiers architectures, the router is still a single point of failure. For this reason, some router implementation roadmaps include clustering features.

Implementations

Clients

As WAMP main targets are Web applications and the Internet of Things, the first client implementations are in languages well established in these industries (only WAMP v2 clients listed):

Client library Language
AngularWAMP JavaScript for the AngularJS framework
AutobahnCpp C++ 11
wamplv LabVIEW (G)
AutobahnJS JavaScript (browser and Node.js)
AutobahnPython Python
wampy Python
Net::WAMP Perl
backbone.WAMP JavaScript for the Backbone.js library
CppWAMP C++ 11
Erwa Erlang
Jawampa Java
Loowy Lua
MDWamp Objective-C
Minion PHP
rx.wamp JavaScript for the React library
Thruway PHP
WAMP POCO C++
wampcc C++
WampSharp C#
Wampy.js JavaScript (browser only)
nexus Go

The minimum requirements to build a WAMP client are the abilities to use sockets and to serialise to JSON. Thus, many modern languages already fulfill these requirements with their standard library. Additional features which would add dependencies, such as TLS encryptions or MessagePack serialization, are optional.

However, the persistent nature of WebSocket connections requires the use of non-blocking libraries and asynchronous APIs. In languages with one official mechanism such as JavaScript, Erlang or Go, this is not an issue. But for languages with several competing solutions for asynchronous programming, such as Python or PHP, it forces the client author to commit to a specific part of the ecosystem.

For the same reason, integrating legacy projects can also require work. As an example, most popular Web Python frameworks are using WSGI, a synchronous API, and running a WAMP client inside a WSGI worker needs manual adapters such as crochet.

Routers

While routers can technically be embedded directly into the application code and some client libraries also provide a router, this architecture is discouraged by the specification.

Since the router is a moving part, it is best used as a swappable black box just like one would consider Apache or Nginx for HTTP:

Router Language
Bondy Erlang
Crossbar.io Python (CPython and PyPy)
Erwa Erlang
wampcc C++
Jawampa Java
Thruway PHP
wamp.rt JavaScript (Node.js only)
WampSharp C#
Wiola Lua
Nightlife-Rabbit JavaScript (Node.js only)
nexus Go

Tavendo, the company from which originated the protocol, is also the author of Crossbar.io, which promotes itself as the de facto router implementation. As they are promoting microservice-based architectures, Crossbar.io embeds a service manager for hosting and monitoring WAMP app components, a static file Web server, and a WSGI container. Being written with the Twisted library, it is one of the implementations that can be set up in production without a proxy, aiming to replace stacks such as Nginx associated with Supervisor and Gunicorn.

Use cases

Being a WebSocket sub-protocol, WAMP fits naturally anywhere one would use raw web sockets, as a way to synchronize clients such as Web browsers, push notifications to them and allow soft real-time collaboration between users. It has also the same limitations, requiring client support, which is missing for Internet Explorer versions older than 10. This is mitigated by the existence of polyfills using more portable technologies such as Flash or the use of HTTP Longpoll as a fallback. In that sense, WAMP is a competitor to Meteor's DDP.

WAMP also targets the IoT, where it is used in the same way as MQTT as a light and efficient medium to orchestrate clusters of connected objects. The implementations in various languages make it suitable to control and monitor small devices such as the Raspberry Pi (in Python) or the Tessel (in JavaScript).

And last but not least, WAMP can act as an enterprise service bus, serving as the link between microservices like one would do with CORBA, ZeroMQ, Apache Thrift, SOAP or AMQP.

Evolution

WAMP is currently in version 2 which introduced routed RPC. As of now, all routers are compatible with version 2. Some clients remain unported: Wamp.io, AutobahnAndroid, and cljWAMP.

The version 2 of the specification is divided into two parts: the basic profile, including the router RPC and Pub/Sub, and the advanced profile, featuring trust levels, URI pattern matching, and client listing. The basic profile is considered stable and is what current libraries are implementing while the advanced profile is still in evolution.

Comparison

The WAMP website claims the following selling points for the technology:

  • Native PubSub: supports Publish & Subscribe out of the box (no extension required).
  • RPC: supports Remote Procedure Calls out of the box (no extension required).
  • Routed RPC: supports routed (not only point-to-point) Remote Procedure Calls.
  • Web native: runs natively on the Web (without tunneling or bridging).
  • Cross Language: works on and between different programming languages and run-times.
  • Open Standard: Is an open, official specification implemented by different vendors.

On the other hand, WAMP does not try to achieve some goals of other protocols:

  • Full object passing like CORBA.
  • Data synchronization like DDP.
  • Peer-to-peer communication like ZeroMQ.
  • Multi-media streaming like WebRTC.
  • Large file transfer like HTTP.

Nevertheless, numerous protocols share some characteristics with WAMP:

Technology PubSub RPC Routed RPC Web native Cross Language Open Standard
WAMP Yes Yes Yes Yes Yes Yes
AJAX Yes Yes Yes
AMQP Yes Yes Yes Yes
Apache Thrift Yes Yes
Capn'n'Proto Yes Yes
Comet Yes Yes
OMG DDS Yes Yes Yes
D-Bus Yes
CORBA Yes Yes Yes Yes
DCOM Yes Yes Yes
Java JMS Yes Yes
Java RMI Yes Yes
JSON-RPC Yes Yes Yes Yes
MQTT Yes Yes Yes Yes
REST Yes Yes Yes
SOAP Yes Yes Yes Yes
Socket.io Yes Yes
SockJS Yes Yes
STOMP Yes Yes Yes Yes
XML-RPC Yes Yes Yes Yes
XMPP Yes Yes Yes Yes Yes
ZeroMQ Yes Yes
DDP Yes Yes Yes Yes

Although, it is important to note that while DDP does Pub/Sub under the hood to synchronize data sets, it does not expose PubSub primitives. It also is an open specification with several implementations, but not registered as a standard.

References

  1. IANA protocols listing page
  2. WAMP basic profile specifications
  3. "Using WAMP you can build distributed systems out of application components which are loosely coupled and communicate in (soft) real-time".
  4. A few words about WAMP
  5. Bahga, Arshdeep; Madisetti, Vijay (9 August 2014). In this chapter [...] you will learn about the Web Application Messaging Protocol [...] which provide tools and services for developing IoT solutions. ISBN 9780996025515.
  6. "Crossbar.io router transport". Archived from the original on 2015-01-12. Retrieved 2015-01-12.
  7. "WAMP can run over Raw transports instead of WebSocket. Each message is prefixed with a uint32 (big endian) that provides the (serialized) length of the following WAMP message". GitHub.
  8. WAMP serialization
  9. "Wampy default serializer is JSON, but it also supports msgpack as a serializer, but you need to include msgpack.js as dependency".
  10. WAMP internals bird view diagram
  11. "The Long-Poll Transport is able to transmit a WAMP session over plain old HTTP 1.0/1.1. This is realized by the Client issuing HTTP/POSTs requests, one for sending, and one for receiving". GitHub.
  12. "Crossbar node architecture". Archived from the original on 2015-01-12. Retrieved 2015-04-20.
  13. "Brokers and Dealers are responsible for generic call and event routing and do not run application code". GitHub.
  14. "Crossbar.io is the name of the most full-featured router". 26 December 2014.
  15. WAMP and AngularJS
  16. "Can is use websockets ?".
  17. Web socket polyfills
  18. "Moreover, we compared WAMP with other registered WebSocket subprotocols (MBWS, SOAP and STOMP) in terms of the related features; and with other potential protocols (CoAP and MQTT), in terms of the related practical deployments" (PDF). Archived from the original (PDF) on 2016-05-13. Retrieved 2015-01-12.
  19. Tessel alarm app with Crossbar.io
  20. WAMP 2 specification menu
  21. WAMP compared
  22. DDP specs
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