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/****************************************************************************
**
** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies).
** All rights reserved.
** Contact: Nokia Corporation (qt-info@nokia.com)
**
** This file is part of the documentation of the Qt Toolkit.
**
** $QT_BEGIN_LICENSE:FDL$
** No Commercial Usage
** This file contains pre-release code and may not be distributed.
** You may use this file in accordance with the terms and conditions
** contained in the Technology Preview License Agreement accompanying
** this package.
**
** GNU Free Documentation License
** Alternatively, this file may be used under the terms of the GNU Free
** Documentation License version 1.3 as published by the Free Software
** Foundation and appearing in the file included in the packaging of this
** file.
**
** If you have questions regarding the use of this file, please contact
** Nokia at qt-info@nokia.com.
** $QT_END_LICENSE$
**
****************************************************************************/
/*!
\group network
\title Network Programming API
\brief Classes for Network Programming
\ingroup groups
*/
/*!
\page network-programming.html
\title Network Programming
\ingroup qt-network
\brief An Introduction to Network Programming with Qt
The QtNetwork module offers classes that allow you to write TCP/IP clients
and servers. It offers classes such as QFtp that implement specific
application-level protocols, lower-level classes such as QTcpSocket,
QTcpServer and QUdpSocket that represent low level network concepts,
and high level classes such as QNetworkRequest, QNetworkReply and
QNetworkAccessManager to perform network operations using common protocols.
It also offers classes such as QNetworkConfiguration,
QNetworkConfigurationManager and QNetworkSession that implement bearer
management.
\tableofcontents
\section1 Qt's Classes for Network Programming
The following classes provide support for network programming in Qt.
\annotatedlist network
\section1 High Level Network Operations for HTTP and FTP
The Network Access API is a collection of classes for performing
common network operations. The API provides an abstraction layer
over the specific operations and protocols used (for example,
getting and posting data over HTTP), and only exposes classes,
functions, and signals for general or high level concepts.
Network requests are represented by the QNetworkRequest class,
which also acts as a general container for information associated
with a request, such as any header information and the encryption
used. The URL specified when a request object is constructed
determines the protocol used for a request.
Currently HTTP, FTP and local file URLs are supported for uploading
and downloading.
The coordination of network operations is performed by the
QNetworkAccessManager class. Once a request has been created,
this class is used to dispatch it and emit signals to report on
its progress. The manager also coordinates the use of
\l{QNetworkCookieJar}{cookies} to store data on the client,
authentication requests, and the use of proxies.
Replies to network requests are represented by the QNetworkReply
class; these are created by QNetworkAccessManager when a request
is dispatched. The signals provided by QNetworkReply can be used
to monitor each reply individually, or developers may choose to
use the manager's signals for this purpose instead and discard
references to replies. Since QNetworkReply is a subclass of
QIODevice, replies can be handled synchronously or asynchronously;
i.e., as blocking or non-blocking operations.
Each application or library can create one or more instances of
QNetworkAccessManager to handle network communication.
\section1 Writing FTP Clients with QFtp
FTP (File Transfer Protocol) is a protocol used almost exclusively
for browsing remote directories and for transferring files.
\image httpstack.png FTP Client and Server
FTP uses two network connections, one for sending
commands and one for transferring data. The
FTP protocol has a state and requires the client to send several
commands before a file transfer takes place.
FTP clients establish a connection
and keeps it open throughout the session. In each session, multiple
transfers can occur.
The QFtp class provides client-side support for FTP.
It has the following characteristics:
\list
\o \e{Non-blocking behavior.} QFtp is asynchronous.
You can schedule a series of commands which are executed later,
when control returns to Qt's event loop.
\o \e{Command IDs.} Each command has a unique ID number that you
can use to follow the execution of the command. For example, QFtp
emits the \l{QFtp::commandStarted()}{commandStarted()} and
\l{QFtp::commandFinished()}{commandFinished()} signal with the
command ID for each command that is executed.
\o \e{Data transfer progress indicators.} QFtp emits signals
whenever data is transferred (QFtp::dataTransferProgress(),
QNetworkReply::downloadProgress(), and
QNetworkReply::uploadProgress()). You could connect these signals
to QProgressBar::setProgress() or QProgressDialog::setProgress(),
for example.
\o \e{QIODevice support.} The class supports convenient
uploading from and downloading to \l{QIODevice}s, in addition to a
QByteArray-based API.
\endlist
There are two main ways of using QFtp. The most common
approach is to keep track of the command IDs and follow the
execution of every command by connecting to the appropriate
signals. The other approach is to schedule all commands at once
and only connect to the done() signal, which is emitted when all
scheduled commands have been executed. The first approach
requires more work, but it gives you more control over the
execution of individual commands and allows you to initiate new
commands based on the result of a previous command. It also
enables you to provide detailed feedback to the user.
The \l{network/qftp}{FTP} example
illustrates how to write an FTP client.
Writing your own FTP (or HTTP) server is possible using the
lower-level classes QTcpSocket and QTcpServer.
\section1 Using TCP with QTcpSocket and QTcpServer
TCP (Transmission Control Protocol) is a low-level network
protocol used by most Internet protocols, including HTTP and FTP,
for data transfer. It is a reliable, stream-oriented,
connection-oriented transport protocol. It is particularly well
suited to the continuous transmission of data.
\image tcpstream.png A TCP Stream
The QTcpSocket class provides an interface for TCP. You can use
QTcpSocket to implement standard network protocols such as POP3,
SMTP, and NNTP, as well as custom protocols.
A TCP connection must be established to a remote host and port
before any data transfer can begin. Once the connection has been
established, the IP address and port of the peer are available
through QTcpSocket::peerAddress() and QTcpSocket::peerPort(). At
any time, the peer can close the connection, and data transfer
will then stop immediately.
QTcpSocket works asynchronously and emits signals to report status
changes and errors, just like QNetworkAccessManager and QFtp. It
relies on the event loop to detect incoming data and to
automatically flush outgoing data. You can write data to the
socket using QTcpSocket::write(), and read data using
QTcpSocket::read(). QTcpSocket represents two independent streams
of data: one for reading and one for writing.
Since QTcpSocket inherits QIODevice, you can use it with
QTextStream and QDataStream. When reading from a QTcpSocket, you
must make sure that enough data is available by calling
QTcpSocket::bytesAvailable() beforehand.
If you need to handle incoming TCP connections (e.g., in a server
application), use the QTcpServer class. Call QTcpServer::listen()
to set up the server, and connect to the
QTcpServer::newConnection() signal, which is emitted once for
every client that connects. In your slot, call
QTcpServer::nextPendingConnection() to accept the connection and
use the returned QTcpSocket to communicate with the client.
Although most of its functions work asynchronously, it's possible
to use QTcpSocket synchronously (i.e., blocking). To get blocking
behavior, call QTcpSocket's waitFor...() functions; these suspend
the calling thread until a signal has been emitted. For example,
after calling the non-blocking QTcpSocket::connectToHost()
function, call QTcpSocket::waitForConnected() to block the thread
until the \l{QTcpSocket::connected()}{connected()} signal has
been emitted.
Synchronous sockets often lead to code with a simpler flow of
control. The main disadvantage of the waitFor...() approach is
that events won't be processed while a waitFor...() function is
blocking. If used in the GUI thread, this might freeze the
application's user interface. For this reason, we recommend that
you use synchronous sockets only in non-GUI threads. When used
synchronously, QTcpSocket doesn't require an event loop.
The \l{network/fortuneclient}{Fortune Client} and
\l{network/fortuneserver}{Fortune Server} examples show how to use
QTcpSocket and QTcpServer to write TCP client-server
applications. See also \l{network/blockingfortuneclient}{Blocking
Fortune Client} for an example on how to use a synchronous
QTcpSocket in a separate thread (without using an event loop),
and \l{network/threadedfortuneserver}{Threaded Fortune Server}
for an example of a multithreaded TCP server with one thread per
active client.
\section1 Using UDP with QUdpSocket
UDP (User Datagram Protocol) is a lightweight, unreliable,
datagram-oriented, connectionless protocol. It can be used when
reliability isn't important. For example, a server that reports
the time of day could choose UDP. If a datagram with the time of
day is lost, the client can simply make another request.
\image udppackets.png UDP Packets
The QUdpSocket class allows you to send and receive UDP
datagrams. It inherits QAbstractSocket, and it therefore shares
most of QTcpSocket's interface. The main difference is that
QUdpSocket transfers data as datagrams instead of as a continuous
stream of data. In short, a datagram is a data packet of limited
size (normally smaller than 512 bytes), containing the IP address
and port of the datagram's sender and receiver in addition to the
data being transferred.
QUdpSocket supports IPv4 broadcasting. Broadcasting is often used
to implement network discovery protocols, such as finding which
host on the network has the most free hard disk space. One host
broadcasts a datagram to the network that all other hosts
receive. Each host that receives a request then sends a reply
back to the sender with its current amount of free disk space.
The originator waits until it has received replies from all
hosts, and can then choose the server with most free space to
store data. To broadcast a datagram, simply send it to the
special address QHostAddress::Broadcast (255.255.255.255), or
to your local network's broadcast address.
QUdpSocket::bind() prepares the socket for accepting incoming
datagrams, much like QTcpServer::listen() for TCP servers.
Whenever one or more datagrams arrive, QUdpSocket emits the
\l{QUdpSocket::readyRead()}{readyRead()} signal. Call
QUdpSocket::readDatagram() to read the datagram.
The \l{network/broadcastsender}{Broadcast Sender} and
\l{network/broadcastreceiver}{Broadcast Receiver} examples show
how to write a UDP sender and a UDP receiver using Qt.
\section1 Resolving Host Names using QHostInfo
Before establishing a network connection, QTcpSocket and
QUdpSocket perform a name lookup, translating the host name
you're connecting to into an IP address. This operation is
usually performed using the DNS (Domain Name Service) protocol.
QHostInfo provides a static function that lets you perform such a
lookup yourself. By calling QHostInfo::lookupHost() with a host
name, a QObject pointer, and a slot signature, QHostInfo will
perform the name lookup and invoke the given slot when the
results are ready. The actual lookup is done in a separate
thread, making use of the operating system's own methods for
performing name lookups.
QHostInfo also provides a static function called
QHostInfo::fromName() that takes the host name as argument and
returns the results. In this case, the name lookup is performed
in the same thread as the caller. This overload is useful for
non-GUI applications or for doing name lookups in a separate,
non-GUI thread. (Calling this function in a GUI thread may cause
your user interface to freeze while the function blocks as
it performs the lookup.)
\section1 Support for Network Proxies
Network communication with Qt can be performed through proxies,
which direct or filter network traffic between local and remote
connections.
Individual proxies are represented by the QNetworkProxy class,
which is used to describe and configure the connection to a proxy.
Proxy types which operate on different levels of network communication
are supported, with SOCKS 5 support allowing proxying of network
traffic at a low level, and HTTP and FTP proxying working at the
protocol level. See QNetworkProxy::ProxyType for more information.
Proxying can be enabled on a per-socket basis or for all network
communication in an application. A newly opened socket can be
made to use a proxy by calling its QAbstractSocket::setProxy()
function before it is connected. Application-wide proxying can
be enabled for all subsequent socket connections through the use
of the QNetworkProxy::setApplicationProxy() function.
Proxy factories are used to create policies for proxy use.
QNetworkProxyFactory supplies proxies based on queries for specific
proxy types. The queries themselves are encoded in QNetworkProxyQuery
objects which enable proxies to be selected based on key criteria,
such as the purpose of the proxy (TCP, UDP, TCP server, URL request),
local port, remote host and port, and the protocol in use (HTTP, FTP,
etc.).
QNetworkProxyFactory::proxyForQuery() is used to query the factory
directly. An application-wide policy for proxying can be implemented
by passing a factory to QNetworkProxyFactory::setApplicationProxyFactory()
and a custom proxying policy can be created by subclassing
QNetworkProxyFactory; see the class documentation for details.
\section1 Bearer Management Support
Bearer Management controls the connectivity state of the device such that
the application can start or stop network interfaces and roam
transparently between access points.
The QNetworkConfigurationManager class manages the list of network
configurations known to the device. A network configuration describes the
set of parameters used to start a network interface and is represented by
the QNetworkConfiguration class.
A network interface is started by openning a QNetworkSession based on a
given network configuration. In most situations creating a network session
based on the platform specified default network configuration is
appropriate. The default network configuration is returned by the
QNetworkConfigurationManager::defaultConfiguration() function.
On some platforms it is a platform requirement that the application open a
network session before any network operations can be performed. This can be
tested by the presents of the
QNetworkConfigurationManager::NetworkSessionRequired flag in the value
returned by the QNetworkConfigurationManager::capabilities() function.
\sa {Bearer Management}
*/
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