<?xml version="1.0" ?> <!DOCTYPE book PUBLIC "-//OASIS//DTD DocBook XML V4.5//EN" "http://www.oasis-open.org/docbook/xml/4.5/docbookx.dtd"> <book> <title>Swiften Developer's Guide</title> <chapter> <title>Introduction</title> <section> <title>Prerequisites</title> <para> We assume that the reader is familiar with the basics of the XMPP protocol. For an overview of the XMPP protocol and its workings, see <citetitle>XMPP: The Definitive Guide</citetitle> <citation><biblioref linkend="XMPP-TDG"/></citation> </para> </section> <section> <title>Boost</title> <para> Swiften makes heavy use of <emphasis>Boost</emphasis> (<ulink url="http://boost.org"><uri>http://boost.org</uri></ulink>) libraries, including <emphasis>Signal</emphasis>, <emphasis>Bind</emphasis>, <emphasis>Optional</emphasis>, and <emphasis>Smart Pointers</emphasis>. We introduce the basic usage of these libraries in our API throughout this manual. For detailed documentation, we refer to the <ulink url="http://boost.org">Boost</ulink> website. </para> </section> </chapter> <chapter> <title>Tutorial: Writing an Echo Bot</title> <para> In this chapter, we guide you through the Swiften API by building an example XMPP application: an EchoBot. This example program, taken from <citetitle>XMPP: The Definitive Guide</citetitle> <citation><biblioref linkend="XMPP-TDG"/></citation>, connects to an XMPP server, logs in, and responds to all incoming messages with the exact same message. We build up our application using Swiften's basic building blocks for XMPP development, to help get a good understanding of how Swiften fundamental classes work and can be extended. In the last stage of this example, we introduce some of Swiften's convenience classes for standard XMPP tasks such as roster management. </para> <sect1> <title>Connecting to a server: Clients & event loops</title> <para> As a first step, we create an application that connects to a server. The code can be seen in <xref linkend="Example-EchoBot1"/>. </para> <example id="Example-EchoBot1"> <title>Connecting to a server</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoBot1.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> The first thing this program does is construct an <emphasis>Event Loop</emphasis>. An event loop is a seemingly infinite loop that waits for external events (e.g. incoming network packets, timers being activated, input happening) to happen; when such an event comes in, it notifies interested parties of this event, and then continues listening for the next event. Since many application frameworks (such as Qt, GLib, Cocoa) use their own event loop, Swiften comes prepackaged with classes that integrate with these event loops. These classes can be found in <literal>Swiften/EventLoop</literal>. In this example, however, we don't use such a framework, so we use Swiften's own <literal>SimpleEventLoop</literal>. This class is used by simply instantiating it at the beginning of the application, and calling <literal>run()</literal> after everything is set up, which will go into an infinite loop. Apart from constructing, passing, and (if necessary) starting the event loop, you will probably have no other contact with it in the rest of the application. </para> <para> Another prerequisite of Swiften's classes is an implementation of network interaction, provided through the <literal>NetworkFactories</literal> class. Swiften comes with a Boost-based network implementation, implemented in <literal>BoostNetworkFactories</literal>. As with the event loop, you probably will have no need to interact with this class apart from constructing it. </para> <para> Swiften's central class for implementing XMPP applications is <literal>Client</literal>. This class handles all the interaction with the XMPP network. After constructing it with the JID and password with which we want to connect, we call <literal>connect()</literal> to instruct the client to connect to the XMPP server with the given credentials. Note that this call returns immediately; it is only when starting the event loop that network the actual connection process will start. The call to <literal>setAlwaysTrustCertificates()</literal> before connecting avoids checks for certificate validity; this is convenient for the examples in this guide (because not all servers have trusted certificates), but for production software, you should not call this. </para> </sect1> <sect1> <title>Building EchoBot</title> <para> To build your application, you will need to set up your build environment to use the correct include and library paths for Swiften, and link against the Swiften library. This depends on both the compiler you are using, and the flags you used to build Swiften. To get the list of compiler options, Swiften comes with a program <literal>swiften-config</literal> (located in <literal>Swiften/Config</literal> in the Swiften tree). Calling this with the <literal>--libs</literal> option will return the list of link flags, whereas calling it with the <literal>--cflags</literal> option will return the list of C(++) compiler flags. </para> </sect1> <sect1> <title>Reacting to events: Signals, Slots & Bind</title> <para> Up to this point, our client doesn't do anything useful. In this section, we make the client react to XMPP events. The code can be seen in <xref linkend="Example-EchoBot2"/>. </para> <example id="Example-EchoBot2"> <title>Reacting to events: Notify whenever the client is connected to the network, and echo back incoming messages</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoBot2.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> A first thing we want to do is print out a message when the client is connected to the server. Swiften uses the <emphasis>signal/slot</emphasis> paradigm for notifying interested parties of events. A <emphasis>signal</emphasis> is an object representing a type of event. For example, <literal>Client</literal> has an <literal>onConnected</literal> signal for notifying whenever the client is connected to the network. If you are interested in a particular signal, you connect a <emphasis>slot</emphasis> to the signal. A slot represents a callback that will be called whenever a signal is emitted. Since we want to print out a message whenever we're connected to the network, we connect to the client's signal, and tell it to call <literal>handleConnected</literal> (which prints out a message): <programlisting>client->onConnected.connect(&handleConnected)</programlisting> </para> <para> Another event we're interested in is whenever a message comes in. For this purpose, <literal>Client</literal> provides a signal called <literal>onMessageReceived</literal>. The major difference with the previous <literal>onConnected</literal> signal is that this signal also can provide extra information to the callback: the actual message received. A signal can provide this extra information through one or more arguments, which will be passed to the slot's parameters. To be able to handle parameters to slots, there needs to be a more general representation of callbacks than just function pointers. This is where Boost's <literal>bind</literal> comes in: <literal>bind</literal> provides a way to construct <emphasis>functors</emphasis> (callbacks, slots, …), by combining function pointers and parameter values. For example, to connect the signal to our slot, we call: <programlisting>client->onMessageReceived.connect(bind(&handleMessageReceived, _1))</programlisting> This is essentially saying: when the <literal>onMessageReceived</literal> signal is emitted, call <literal>handleMessageReceived</literal>, and pass it the first parameter provided by the slot (which, in this case, is the actual message received). </para> <para> The implementation of <literal>handleMessageReceived</literal> should be straightforward: put the <emphasis>To</emphasis> address in place of the <emphasis>From</emphasis> address, and send the message to the server. One thing to note is that <literal>Message::ref</literal> represents a <emphasis>shared pointer</emphasis> to a <literal>Message</literal> stanza. Shared pointers behave the same as regular pointers, except that, when the last copy of the pointer goes away, the object it points to is deleted as well. <literal>Message::ref</literal> is in fact a typedef for <literal>boost::shared_ptr<Message></literal>. Although Swiften tends to prefer the use of the <literal>::ref</literal> notation, you will see both forms used intermixed. </para> <para> If you use a C++ compiler that supports C++0x lambda expressions (such as GCC 4.5 or Microsoft Visual Studio 2010), you can write this example in a more concise way, as illustrated in <xref linkend="Example-EchoBot0x"/>. However, for the remainder of this guide, we will not use this functionality. </para> <example id="Example-EchoBot0x"> <title>EchoBot using C++0x lambda expressions. This is currently only possible with a limited set of C++compilers.</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoBot0x.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> Before moving on to the next step, we are going to rearrange our code from <xref linkend="Example-EchoBot2"/> a bit, to make it a bit cleaner. Instead of using global variables, we are going to create an <literal>EchoBot</literal> class with the current code in it. The resulting code can be found in <xref linkend="Example-EchoBot3"/>. </para> <example id="Example-EchoBot3"> <title>Creating an EchoBot class</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoBot3.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> The important thing to consider in this step are the changes to the signal connections. Since we are now passing member variables of a class to the signal, we need to use <literal>bind</literal> to pass in the actual object on which this member variable is called as the first parameter. </para> <para> The only thing we added to this version is the <literal>ClientXMLTracer</literal>. This class will dump all incoming and outgoing XMPP messages to the console, which can be handy for debugging our bot. </para> </sect1> <sect1 id="Section-Requests"> <title>Presence Management: Requests</title> <para> The current version of our EchoBot does what it is supposed to do: it answers all incoming messages. However, although users can add the bot to their contact list, they will not see when it is online, since the bot doesn't do any presence handling yet. In this section, we explain the different steps involved in adding presence management, resulting in the code in <xref linkend="Example-EchoBot4"/>. </para> <example id="Example-EchoBot4"> <title>Adding presence management: Requesting the initial roster, and auto-approving incoming subscription requests.</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoBot4.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> First of all, our bot needs to listen to incoming subscription requests from users who want to add it to their roster, and automatically approve them. This is done by connecting to the <literal>onPresenceReceived</literal> signal, checking whether the incoming presence is a subscription request, and if so, respond to it with an approval (in <literal>handlePresenceReceived</literal>). </para> <para> The first version of the XMPP protocol states that a client will not get any presence subscriptions until it requests the roster. To make sure we handle this, we want to make sure our bot requests the roster at login. After getting the <literal>onConnected</literal> signal, we therefore send a <emphasis>request</emphasis> to retrieve the roster. Swiften's <literal>Request</literal> classes correspond to XMPP IQ Get or Set actions. Swiften provides a set of built-in request classes for the most common tasks in <literal>Swiften/Queries/Requests</literal>, and can be easily extended to use add your own (see <xref linkend="Section-Extending"/>). Requests have an <literal>onResponse</literal> signal, which is emitted when a response comes in. This signal has 2 parameters: the actual response data (the <emphasis>Payload</emphasis>), and an optional error payload in case there was an error executing the request. To use a <literal>Request</literal> class, you construct it with the correct parameters, connect to the <literal>onResponse</literal> signal, and then send the request by calling <literal>send()</literal> on it. In this case, we're not interested in the actual payload of the response (passed as the first parameter), so we pass it a slot with only the second parameter (the error payload). When we get the roster back, we send initial presence to all our subscribers, announcing them we're online. </para> </sect1> <sect1 id="Section-Responders"> <title>Publishing version information: Responders</title> <para> Most XMPP clients have support for querying software version information of a client through <citation><biblioref linkend="XEP-0092"/></citation>. These clients send out an IQ-Get request to an entity, which responds with the requested information. We would like our bot to listen to these requests, and respond with the correct information. Swiften uses <literal>Responder</literal> classes for the purpose of responding to IQ requests, and are therefore the dual of the <literal>Request</literal> clients discussed in the previous section. </para> <example id="Example-EchoBot5"> <title>Adding presence management: Requesting the initial roster, and auto-approving incoming subscription requests.</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoBot5.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> Using <literal>SoftwareVersionResponder</literal> is pretty straightforward, as can be seen in <xref linkend="Example-EchoBot5"/>: simply construct the responder, set the correct parameters, call <literal>start()</literal>, and it will automatically respond to the incoming requests. Other <literal>Responder</literal> classes may provide signals to notify of incoming requests, or may have some other behavior. For a detailed explanation of responders, see <xref linkend="Section-CustomQueries"/>. </para> </sect1> <sect1 id="Section-Extending"> <title>Extending Swiften with new payloads: Payloads, Parsers, and Serializers</title> <para> Swiften uses abstract datastructures for all the data that is received and sent over the XMPP network. The declaration of these datastructures can all be found in <literal>Swiften/Elements</literal>. For representing the XMPP stanzas, Swiften uses the <literal>Message</literal>, <literal>Presence</literal>, and <literal>IQ</literal> classes. Each stanza can have an arbitrary amount of child <emphasis>payloads</emphasis>, represented by the <literal>Payload</literal> class. A payload typically corresponds to a (namespaced) child XML element of a stanza; for example, the <literal><query xmlns="jabber:iq:roster"/></literal> element used for managing the roster is represented as a <literal>RosterPayload</literal>. </para> <para> If you want to extend Swiften with your own XMPP extension, you will first need to create a payload for this extension. For example, suppose we want to reate an extension for use in our Echo bot that contains a special textual message, and add this to all our outgoing messages, we create the <literal>EchoPayload</literal> illustrated in <xref linkend="Example-EchoPayload"/>. We can then append or retrieve this payload from the stanzas using <literal>Stanza::getPayload()</literal> and <literal>Stanza::addPayload()</literal>. For example, the version of our bot in <xref linkend="Example-EchoBot6"/> checks whether an incoming message contains the <literal>EchoPayload</literal>, and if not, echoes back the message, and adds an extension to the message with a descriptive text. </para> <example id="Example-EchoPayload"> <title>Extending Swiften with a new payload: <literal>EchoPayload</literal></title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoPayload.h.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <example id="Example-EchoBot6"> <title>Adding a custom extension: Using a custom element, and registering a parser (factory) and serializer for the element.</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoBot6.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> However, having the element is not enough; Swiften also needs to know how to extract this payload from the incoming stanzas, and know how to send it on outgoing stanzas. In order to do this, Swiften uses XML parsers and serializers for the payload. We therefore need to create a parser and serializer for our new payload, and register it with <literal>Client</literal>. Serializers are implemented as subclasses from <literal>PayloadSerializer</literal>, and provide the basic methods <literal>canSerialize()</literal> and <literal>serialize()</literal>. The serializer is registered using <literal>Client::addPayloadSerializer()</literal> (and unregistered using <literal>Client::removePayloadSerializer()</literal>). Parsers consist of 2 parts: a subclass of <literal>PayloadParser</literal>, which parses incoming XML in an event-driven way and builds up the payload, and a subclass of <literal>PayloadParserFactory</literal>, which is responsible for detecting whether a given parser can parse an incoming element, and creates a parser. The parser factory is registered with the client using <literal>Client::addPayloadParserFactory()</literal> (and unregistered using <literal>Client::removePayloadParserFactory()</literal>). </para> <para> Although you can subclass the base classes for parsers and serializers directly, Swiften comes with utility classes that contain common functionality for parsers and serializers. For example, for our EchoBot, the parser and serializer using these utility classes is shown in <xref linkend="Example-EchoPayloadParser"/> and <xref linkend="Example-EchoPayloadSerializer"/> respectively. Registration of the parser and serializer is shown in the constructor of our EchoBot in <xref linkend="Example-EchoBot6"/>. </para> <example id="Example-EchoPayloadParser"> <title>The parser and parser factory for <literal>EchoPayload</literal></title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoPayloadParserFactory.h.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <example id="Example-EchoPayloadSerializer"> <title>The serializer for <literal>EchoPayload</literal></title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoPayloadSerializer.h.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> <para> If you want to create your own parser and serializers, you can look at the built-in parsers and serializers in the Swiften library, located in <literal>Swiften/Parser/PayloadParsers</literal> and <literal>Swiften/Serializer/PayloadSerializers</literal>. </para> </sect1> <sect1 id="Section-CustomQueries"> <title>Extending Swiften with new queries and responders</title> <para> <xref linkend="Section-Requests"/> and <xref linkend="Section-Responders"/> explained that Swiften provides Requests and Responder classes for querying or responding to queries of specific payloads. If you extend Swiften with your own payloads, you can use these to create your own <literal>Request</literal> or <literal>Responder</literal> subclasses. Swiften also provides convenience classes such as <literal>GenericRequest</literal>, <literal>GetResponder</literal> and <literal>SetResponder</literal> for creating your requests and responders for your custom payloads. </para> </sect1> <sect1> <title>Using Swiften's convenience classes</title> <para> Swiften comes with flavors of the Client class: <literal>CoreClient</literal>, which implements only the basics of connecting to the XMPP server, without any built-in responders. If you want to build a client from scratch, this class is probably your preferred Swiften interface. However, most users of Swiften will not want to bother with explicitly instantiating responders to basic functionality such as software version information etc., and will want to have the convenience of built-in responders and utility classes. In this case, you can use the <literal>Client</literal> class (a subclass of <literal>CoreClient</literal>, which implements most of the common XMPP client functionality, including roster and subscription management, VCards, Avatars, Service Discovery, Multi-User Chats, ... </para> </sect1> <sect1> <title>Writing server components</title> <para> Swiften also provides classes for creating server components. The <literal>Component</literal> class has a similar interface as <literal>Client</literal>, but uses the component protocol to connect with the XMPP server. Except for a few classes, the same techniques and classes for writing clients can be applied to write components. <xref linkend="Example-EchoComponent"/> illustrates how we would build a component version of our Echo bot. </para> <example id="Example-EchoComponent"> <title>EchoBot as a server component</title> <include xmlns="http://www.w3.org/2001/XInclude" href="Examples/EchoBot/EchoComponent.cpp.xml" xpointer="xpointer(//programlisting|//calloutlist)"/> </example> </sect1> </chapter> <bibliography> <title>Bibliography</title> <biblioentry id="XMPP-TDG"> <abbrev>XMPP-TDG</abbrev> <title><ulink url="http://oreilly.com/catalog/9780596157197/">XMPP: The Definitive Guide</ulink></title> <author> <firstname>Peter</firstname> <surname>Saint-Andre</surname> </author> <author> <firstname>Kevin</firstname> <surname>Smith</surname> </author> <author> <firstname>Remko</firstname> <surname>Tronçon</surname> </author> </biblioentry> <biblioentry id='XEP-0092'> <abbrev>XEP-0092</abbrev> <title><ulink url='http://www.xmpp.org/extensions/xep-0092.html'>Software Version</ulink></title> <author> <firstname>Peter</firstname> <surname>Saint-Andre</surname> </author> </biblioentry> </bibliography> </book>