/*! \page qmlboost Using the QML booster This section describes how to use the QML (QDeclarative) booster. The booster provides the application with the key libraries already present in the process, and instances of \c QApplication and \c QDeclarativeView waiting in the cache. Note: This functionality is currently included in the Qt Quick application template provided by the Qt SDK. To enable QML booster in your application, select Make application boostable checkbox when creating a new project with the template. \section qmlboostprereq Prerequisites The launcher can start an application if the following prerequisites are met: - The QML application uses a C++-based runner. - The runner uses \c QApplication and \c QDeclarativeView directly, that is, does not inherit from the classes. - \c applauncherd-dev package is installed. \section qmlboostcompiling 1. Compiling and linking for launcher If you intend to run a binary with \c applauncherd, compile it with \c -fPIC option to produce position-independent code. It is recommended that you link them either as shared libraries, or, preferably, as position-independent executables, which can be executed both traditionally and with the launcher. The \c -pie and \c -rdynamic linker flags accomplish this. To improve linking and loading times of shared object libraries, it is recommended that you hide any unnecessary symbols from the resulting binary by using \c -fvisibility=hidden and \c -fvisibility-inlines-hidden flags as well. However, \c applauncherd needs to find the entry point for your application, so the symbol \c main needs to be explicitly made visible. This can be done as follows: \code #include Q_DECL_EXPORT int main(int argc, char **argv) { ... } \endcode If your application loads a plug-in that needs to access some symbols in the main application, the symbols also need to be exported. In addition, you must use the \c --global-syms invoker parameter, as described in \ref invokerparameters "Advanced invoker command line parameters". Normally you do not need to worry about the compiler and linker flags, as the \c applauncherd-dev package provides configuration options for \c qmake, \c CMake, and \c pkg-config. If you are building a Debian package, make your package build-depend on \c applauncherd-dev and your application binary package depend on \c applauncherd. For details on how to get the compiler and linker flags, see \ref usingqmake "Using qmake", \ref usingcmake "Using CMake", or \ref usingpkgconfig "Using pkg-config". \section qmlboostcache 2. Utilising the booster cache Instantiating \c QApplication and \c QDeclarativeView is a relatively expensive operation. The QML booster helps reduce application startup latency by creating instances of the classes in MDeclarativeCache. In order to make use of this functionality, the applications need to pick up the instances from the cache. Thus, if the application code instantiates the classes as follows: \code QApplication app(argc, argv); QDeclarativeView view; \endcode Modify it as follows: \code QApplication *app = MDeclarativeCache::qApplication(argc, argv); QDeclarativeView *window = MDeclarativeCache::qDeclarativeView(); \endcode You also need to add: \code #include \endcode The cache class works both with the booster and without it. In the non-boosted case there are no pre-created instances, so the cache class simply creates the instances on the fly. The ownership of the instances is transferred from the cache to the application code. The instances need to be deleted in the correct order, deleting the \c QApplication instance before the \c QDeclarativeView instance is known to cause crashes. \section qmlboostexit 3. Adapting application source code Making use of the cache is typically the only modification needed to the application. However, if the application has explicit calls to \c exit(), these should be changed to use \c _exit() instead. The brief explanation is that this prevents cleanup actions related to shared libraries to be performed multiple times. For more details see \ref limitations "Limitations and known issues". \section qmlboostinvoker 4. Launching the application Now everything should be in place for launching the application. The linker flags create a Position Independent Binary (PIE), so the application can still be invoked from the command line. In order to verify that the modifications done to the application and the build scripts have not broken anything, it is a good idea at this point to check that the application still starts and functions normally from the command line: \code $ ./myApp \endcode The next step is to use the \c invoker to launch the application. In order for this to work, you need to have \c applauncherd and \c booster-d (the QML booster process) running. To check that this is the case, you can do: \code $ ps ax | grep booster-d \endcode If you do not see the booster process, you need to start \c applauncherd manually. In MeeGo 1.2 Harmattan, \c applauncherd should be running as part of the UI session. Once you have verified that the booster process is running, you can use the following command line to ask the booster process to turn into your application: \code /usr/bin/invoker --type=d ./myApp \endcode Your application should start exactly as if it had been invoked from the command line, just a little bit faster. You can now proceed to change the \c .desktop file or \c .service file that launches the application to use the invoker command. \section qmlboostfinishingtouch 5. Finishing touches The invoker can also provide single instance behaviour for your application as follows. For more details, see \ref singleinstance "Enabling single instance support for an application". \code /usr/bin/invoker --single-instance --type=d /usr/bin/myApp \endcode */