/**************************************************************************** ** ** Copyright (C) 2011 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. ** ** $QT_BEGIN_LICENSE:FDL$ ** 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. ** ** Other Usage ** Alternatively, this file may be used in accordance with the terms ** and conditions contained in a signed written agreement between you ** and Nokia. ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ /*! \example webkit/imageanalyzer \startpage {index.html}{Qt Reference Documentation} \title The Webkit Bridge Tutorial - Hybrid Client Application In this example, we will show how to write a hybrid application using \l{The QtWebKit Bridge}{QtWebKit Bridge}, which distinguishes itself from a thin client in that it performs heavy calculations on the client side in C++, like a native application, but presents nothing more than a \c QWebView for its user interface, displaying web content written in HTML/JavaScript. The application uses QtConcurrent to distribute its work across as many CPU cores as are available from the system, so it can process each image in parallel. For the full reference documentation of QtWebKit hybrid development, see \l{qtwebkit-bridge.html}{The QtWebKit Bridge}. Initially, you will see a user interface with an empty list of images. Clicking on some of the images in the lower pane below adds them to the list view above, as shown in the screenshot below. \image webkit-imageanalyzer-screenshot.png Now, we can click on \bold Analyze, and each image is analyzed using some computationally intensive C++ function, in parallel and on different cores. Progress is shown while the analysis is proceeding. \image webkit-imageanalyzer-progress.png and in the end, we will see something like this, where the average RGB values of each image are shown. \image webkit-imageanalyzer-complete.png The MainWindow is defined in C++, and creates a \l QNetworkDiskCache and a \l QWebView, and tells the \l QWebView to load the starting page, providing us with a user interface for the client. \snippet examples/webkit/imageanalyzer/mainwindow.cpp MainWindow - constructor In this example, the sample content is addressed with the \tt qrc:/index.html URL. \tt qrc:/ indicates that the file is stored as a Qt resource (attached to the executable). In a real-world application, the content and images would likely be retrieved from the network rather than from resources. We wish to initialize an object reference in the JavaScript web page to point to our \tt ImageAnalyzer before any other scripts are run. To do this, we connect the \l{QWebFrame::}{javaScriptWindowObjectCleared()} signal to a slot which does the object creation and handoff to JavaScript. \snippet examples/webkit/imageanalyzer/mainwindow.cpp MainWindow - addJSObject The ImageAnalyzer object is created and added to a JavaScript object on the web page's mainFrame with \c addToJavaScriptWindowObject(). The start page is resources/index.html. In one of its
regions, we have images, each with an \c onClick() handler that calls \c addImage(). \snippet examples/webkit/imageanalyzer/resources/index.html sample images Clicking an image adds it to an images list. \snippet examples/webkit/imageanalyzer/resources/index.html addImage The \bold {Analyze} button at the bottom of the image list is clicked when we want to start the analysis: \snippet examples/webkit/imageanalyzer/resources/index.html images list When the user clicks the \bold {Analyze} button, \c analyzeImages() is called, another regular JavaScript method, shown below. Notice it assumes the \c imageAnalyzer object is already defined and initialized in JavaScript space, but we guaranteed that by connecting our setup slot to the appropriate signal, \l{QWebFrame::}{javaScriptWindowObjectCleared()}. \snippet examples/webkit/imageanalyzer/resources/index.html analyzeImages The only methods on \c ImageAnalyzer that we can or do call from JavaScript are those which are exposed through \{The Meta-Object System}{Qt's MetaObject} system: \l{The Property System}{property} getter/setter methods, \c public \l {Signals & Slots}{signals and slots}, and other \l{Q_INVOKABLE}{Q_INVOKABLE} functions. \snippet examples/webkit/imageanalyzer/imageanalyzer.h ImageAnalyzer - public interface \dots \snippet examples/webkit/imageanalyzer/imageanalyzer.h ImageAnalyzer - private members Most of the members are set up in the constructor: \snippet examples/webkit/imageanalyzer/imageanalyzer.cpp ImageAnalyzer - Constructor Back on the JavaScript side, we want to connect signals from this object to JavaScript functions on our web page, after the web page is loaded, but before the images are analyzed. From \c connectSlots(), we can see how to connect signals from the imageAnalyzer object to regular JavaScript functions, which can also behave like slots. We use this to monitor and display progress from the C++ side. \snippet examples/webkit/imageanalyzer/resources/index.html connect slots The only public slot is \c startAnalysis(), called to place a list of URLs into the image analyzer's QtConcurrent processing queue from JavaScript space. \snippet examples/webkit/imageanalyzer/imageanalyzer.cpp ImageAnalyzer - startAnalysis The images need to be loaded again now, which is why fetchURLs first checks the cache to see if we can save an extra network get. \snippet examples/webkit/imageanalyzer/imageanalyzer.cpp ImageAnalyzer - fetchURLs For the images that were not in the cache, \c handleReply() will load them into a QImage when the data is ready. \snippet examples/webkit/imageanalyzer/imageanalyzer.cpp ImageAnalyzer - handleReply After the images are loaded, they are queued up in preparation to be sent in a batch for analysis to a \l QFutureWatcher, which will distribute the processing across multiple threads and cores, depending on how many are available. \snippet examples/webkit/imageanalyzer/imageanalyzer.cpp ImageAnalyzer - queueImage The function that gets performed on each image is \c averageRGB(), as specified in argument 2 to the \l{QtConcurrent::mapped()} function. Notice it repeats the same calculations 100 times on each pixel to keep the CPU very busy. This is done only for the purposes of the demo so that the analysis takes a noticeable time to complete. \snippet examples/webkit/imageanalyzer/imageanalyzer.cpp ImageAnalyzer - averageRGB */