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// Copyright (C) 2021 The Qt Company Ltd.
// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR GFDL-1.3-no-invariants-only
/*!
* \title Qt Wayland Compositor Examples - IVI Compositor
* \example ivi-compositor
* \brief IVI Compositor is an example that demonstrates how to use the IviApplication extension.
* \ingroup qtwaylandcompositor-examples
*
* \section1 Introduction
*
* This example demonstrates using the \l IviApplication shell extension in a Wayland display
* server (also known as a Wayland compositor).
*
* For an introduction to the basic principles of creating a \l{Qt Wayland Compositor} with Qt,
* see the \l{Qt Wayland Compositor Examples - Minimal QML}{Minimal QML example}.
*
* \section1 The Protocol
*
* \l IviApplication is a \l{Shell Extensions - Qt Wayland Compositor}{shell extension} that was
* designed specifically for making In-vehice Infotainment systems.
*
* It is a minimalistic protocol, and only provides the following functionality:
*
* \list 1
* \li The client can identify itself with an \e{IVI-id}.
* \li The server can request that the client resizes itself.
* \endlist
*
* \section2 The Identification Numbers
*
* In a typical \l IviApplication setup, you will have a predefined set of applications that can
* connect to the server. Since these applications are already known when the system is designed,
* they can be assigned hardcoded numbers that identify them. Given that the client and server
* agree on these numbers ahead of time, semantics can be built into the ID numbers.
*
* For instance, if a client identifies itself as the navigation application, the server can
* recognize this and allocate a large, centered part of the screen for its window. An application
* identifying itself as a clock, on the other hand, might be delegated to a smaller area in the
* margins of the screen.
*
* By default, Qt applications will advertise their system PIDs ("process IDs") as the \e{IVI-id}.
* The client can override this by setting \c{QT_IVI_SURFACE_ID} in its environment before
* connecting to the server.
*
* \section1 The Example
*
* A Qt Wayland Compositor may support multiple shell extensions at once, but the
* \e{IVICompositor example} only supports the \l IviApplication protocol. This means that the
* clients have to also support this shell extension in order to connect to the server.
*
* The compositor window in the example is split into two horizontally: A left area which is
* designated for a specialized application with the id "1337", and a right area which is for all
* other applications.
*
* \image ivi-compositor-1.png
*
* \section2 Creating the Layout
*
* The layout of the window is created inside a \l WaylandOutput. This typically corresponds to
* a physical screen available to the compositor. If a single \l WaylandOutput is created, as in
* the \e{IVICompositor example}, it will usually correspond to the primary screen.
*
* \snippet ivi-compositor/main.qml wayland output
*
* The code creates a \l WaylandOutput for the screen and creates a \l Window on this as the top
* level container of all compositor contents. Inside this window, it creates two rectangles that
* will serve as containers for applications as they connect.
*
* \section2 Connecting Clients
*
* If no additional configuration has been done, a Qt application will connect with an \e{IVI-id}
* equal to its process ID. For instance, if we run another Qt example application with
* \c{-platform wayland}, it will be delegated to the right-hand side of the layout, granted that
* its ID is different from "1337".
*
* \image ivi-compositor-2.png
*
* However, if we set the \c{QT_IVI_SURFACE_ID} environment variable to "1337" before starting
* the example, it will be delegated to the left-hand side of the layout.
*
* \image ivi-compositor-3.png
*
* When a client connects to the \c IVIApplication interface, it will emit the \c{iviSurfaceCreated}
* signal. This is where the positioning of the application's surface is handled.
*
* \snippet ivi-compositor/main.qml connecting
*
* The \c{iviSurfaceCreated} signal receives an \l IviSurface argument which can be used to access
* the client's ID. The compositor then creates a \l ShellSurfaceItem for the surface (as defined by
* the \c chromeComponent). \c ShellSurfaceItem is the class used for placing shell surfaces into
* the Qt Quick scene, and you will see this same pattern in all the Qt Wayland Compositor examples.
*
* What makes the \e{IVICompositor example} special is that it checks the \c iviId property of the
* incoming shell surface and decides on a parent for the \l ShellSurfaceItem depending on what
* this is. If the ID is equal to "1337" it will be parented to the \c leftArea, and if not it will
* be in the \c rightArea.
*
* The implementation of the \l ShellSurfaceItem handles resizing by informing the client whenever
* the size changes (which can happen if the compositor is running inside a desktop-style windowing
* system and its window is resized).
*
* \snippet ivi-compositor/main.qml resizing
*
* The \c{sendConfigure()} method is defined in \l IviSurface and will send an event to the client.
* The client will receive a resize event with the new size, so it can relayout its contents.
*
* If multiple applications connect to the same area in the layout, they will simply be stacked
* according to normal Qt Quick ordering rules. There are no built-in mechanisms for closing
* applications or managing state, but this can easily be added as ordinary Qt Quick code.
*/
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