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/****************************************************************************
**
** 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.
**
**
**
**
** $QT_END_LICENSE$
**
****************************************************************************/
/*!
\title Scalability
\page scalability.html
\preliminary
\omit preliminary docs for next SDK release \endomit
\omit Somewhere I need to mention applications with more than
one page (top-level layouts). \endomit
A scalable application is an application that can run on more than
one form factor. In particular, it can cope with different screen
sizes, DPI, and aspect ratios. You need to consider scalability
when:
\list
\o your application will be deployed to more than one device
handset, or more than one device form factor.
\o your application will be deployed for a long period of time,
so that new device handsets might appear on the market after
your initial deployment.
\endlist
This document discusses how scalable applications can be created.
\section1 Developing Scalable UIs
This section shows the basics of how we advice scalable
applications to be implemented using QML. We recommend that you
follow these techniques:
\list
\o Create separate top-level layout
definitions for each form factor.
\o Keep the layouts small and let components
scale relative to their immediate parent.
\o Define device independent measurements, such as dp
(device independent pixels), and use
these to scale components and for layout measurement.
\o Define layouts in a
proportional way using the built-in layout features of QML.
\endlist
Using small top-level layouts makes your codebase smaller and
easier to maintain. Also, components that scales relative to their
parent are more reusable. The layouts should be children of the
application's root item. You can change between them by, for
instance, using the opacity property of Item; that is, if your
application has more tham one top-level layout. Such a top-level
layout is also often referred to as a page, i.e., a layout that
uses the entire screen. For instance, an organizer application
will typically have separate pages for showing the calender and
editing todo items.
You should define the measurements separate from the UI, for
instance by using a JavaScript object that you fill in with a
script on application start up.
QML provides several ways of laying out components, e.g, using
anchor based layout, the more classic Grid; Column; and Row
elements, and by setting the dimensions of Items directly. When
laying out components in scalable applications, you should
generally prefer using anchors and set width and height based on
parent size where possible. Layouts are not only relevant to
top-level layouts; components often contain child Items.
The following sections describe in more detail the different
aspects of scalability that should be considered in order to
achieve the desired level of flexibility within your application.
\section1 Implementing the Top-Level Layouts
As mentioned, each application should use separate top-level
layout QML definitions to support separate layout configurations /
form factors.
Consider an application that has to be deployed to at least two
devices, which both have very different screen sizes and DPI
values. The two form factors of the application will share many
common components and attributes, and will most likely connect to
the same data model.
Therefore, the top-level definitions should be quite
straightforward and short, with the majority of the functionality
refactored into contained Components. It is important to try to
avoid unnecessary duplication between these top-level definitions,
in order to improve maintainability.
There are some patterns that you might consider when designing
your top level layouts:
\list
\o In some cases, the contents of an entire page in a smaller
handset could form a component element of a layout in a
larger device. Therefore, consider making that a separate
component (i.e. defined in a separate QML file), and in the
smaller handset, the Page will simply contain an instance of
that component. On the larger device, there may be enough
space to show two separate items. For example, in an email
viewer, if the screen is large enough, it may be possible to
show the email list view, and the email reader view side by
side.
\o In some cases, the contents of a view might be quite similar
on all screen sizes, but with an expanded content area. In
this case, it may be possible to re-use the same layout
definition, if defined appropriately using anchors.
\endlist
The \l{Loader} component can be used to load separate QML files
based on some criteria, such as Device Profile (configuration of
screen pixel resolution and DPI density). In the case of form
factor, this information will not change during the application's
lifetime, therefore there is no issue with memory usage or
performance.
\section1 Defining Measurements
When you are defining the measurements within an application or
component layout, there are a number aspects to consider:
\list
\o The layout structure, the high-level relationship between
items. Which item is the parent? How are the items arranged
relatively on the screen? Are they in a grid or column?
\o The layout measurements. How big is an item, or a margin
inside the edge of an item, or an anchor between items?
\o The implicit size of contained items. Some child items will
require a certain amount of space, such as a button
containing a text. That may also depend on the current
platform and style. How do you ensure that you leave enough
space, and what happens if your children change size?
\endlist
These aspects combine together to resolve the final layout for a
given Device Profile. However, although there are dependencies
between them, it is important to manage and control the different
aspects separately.
It is strongly recommended that Layout measurements should be
stored in a separate place from the component layout structure
definition files. The reason for this is that layout structure,
for a given form factor, can be re-used for different Device
Profiles. However, measurements will almost always vary between
Device Profiles or Device Categories.
If the opposite approach (complete duplication of entire QML
files) was taken, then all of the layout states and structure
definitions would be duplicated between the copied QML files, and
only the measurement values would change.
The main benefit of using separate measurement definition files
are:
\list
\o To reduce the amount of duplication, and hence increase
maintainability.
\o It becomes much easier to change the layout structure,
perhaps due to subsequent specification changes. In that
case, the layout structure can be modified once, and many or
all of the layout measurements would remain unchanged.
\o It becomes much easier to add support for additional Device
Profiles, simply by adding another measurement definition
file.
\endlist
\section1 Using QML's Layout Features
For a given form factor, top-level Layouts structure definitions,
or component layout structure definitions, should in general be
defined in a proportional way using a combination of
\list
\o \l{Item::anchors.top}{anchors} within an Item
\o \l{Row} / \l{Column} / \l{Grid}
\o simple JavaScript expressions such as width: Math.round(parent.width / 3.0).
\endlist
These basic building blocks, along with the powerful evaluation
capabilities of JavaScript expressions within every QML binding,
are designed to allow the majority of the layout structure
definition to be defined in a Device Profile independent way.
There are some limitations of the basic grid type layouts. They
are designed to accommodate a number of Items, but use the current
sizes of those items. There is a similar issue with the basic
anchor type layout. In particular, it can be difficult to spread a
number of child items proportionately across an area of their
container.
By combining the features of the layout managers with simple
JavaScript expressions, a richer variety of designs can be
expressed, without having to resort to additional layout
measurement parameters or measurement values.
Here are some things not to do with layouts:
\list
\o Don't define complex JavaScript functions that are regularly
evaluated. This will cause poor performance, particularly
during animated transitions.
\o Don't define all of your layouts using x, y, width and
height. Reserve this for items that cannot easily be defined
using anchors (anchors are evaluated in a more efficient
way).
\o Don't make assumptions about the container size, or about
the size of child items. Try to make flexible layout
definitions that can absorb changes in the available space.
\endlist
\section1 Orientation Switches
Application top-level page definitions, and reusable component
definitions, should use one QML layout definition for the layout
structure. This single definition should include the layout design
for separate Device Orientations and Aspect Ratios. The reason for
this is that performance during an orientation switch is critical,
and it is therefore a good idea to ensure that all of the
components needed by both orientations are loaded when the
orientation changes.
On the contrary, you should perform thorough tests if you choose
to use a \l{Loader} to load additional QML that is needed in separate
orientations, as this will affect the performance of the
orientation change.
In order to enable layout animations between the orientations, the
anchor definitions must reside within the same containing
component. Therefore the structure of a page or a component
should consist of a common set of child components, a common set
of anchor definitions, and a collection of states (defined in a
StateGroup) representing the different aspect ratios supported by
the component. (However note that orientation change animations
are not possible on Symbian due to compatibility support for S60
applications).
If a component contained within a page needs to be
hosted in numerous different form factor definitions, then the
layout states of the view should depend on the aspect ratio of the
page (its immediate container). Similarly, different instances of
a component might be situated within numerous different containers
in a UI, and so its layout states should be determined by the
aspect ratio of its parent. The conclusion is that layout states
should always follow the aspect ratio of the direct container (not
the "orientation" of the current device screen).
Within each layout \l{State}, you should define the relationships
between items using native QML layout definitions. See below for
more information. During transitions between the states (triggered
by the top level orientation change), in the case of anchor
layouts, AnchorAnimation elements can be used to control the
transitions. In some cases, you can also use a NumberAnimation on
e.g. the width of an item. Remember to avoid complex JavaScript
calculations during each frame of animation. Using simple anchor
definitions and anchor animations can help with this in the
majority of cases.
There are a few additional cases to consider:
\list
\o What if you have a single page that looks completely
different between landscape and portrait, i.e. all of the
child items are different? For each page, have two child
components, with separate layout definitions, and make one
or other of the items have zero opacity in each state. You
can use a cross-fade animation by simply applying a
NumberAnimation transition to the opacity.
\o What if you have a single page that shares 30% or more of
the same layout contents between portrait and landscape? In
that case, consider having one component with landscape and
portrait states, and a collection of separate child items
whose opacity (or position) depends on the orientation
state. This will enable you to use layout animations for the
items that are shared between the orientations, whilst the
other items are either faded in/out, or animated on/off
screen.
\o What if you have two pages on a handheld device that need to
be on screen at the same time, for example on a larger form
factor device? In this case, notice that your view component
will no longer be occupying the full screen. Therefore it's
important to remember in all components (in particular, list
delegate items) should depend on the size of the containing
component width, not on the screen width. It may be
necessary to set the width in a Component.onCompleted()
handler in this case, to ensure that the list item delegate
has been constructed before the value is set.
\o What if the two orientations take up too much memory to have
them both in memory at once? Use a \l{Loader} if necessary, if
you cannot keep both versions of the view in memory at once,
but beware performance on the cross-fade animation during
layout switch. One solution could be to have two "splash
screen" items that are children of the Page, then you cross
fade between those during rotation. Then you can use a
\l{Loader} to load another child component that loads the actual
model data to another child Item, and cross-fade to that
when the \l{Loader} has completed.
\endlist
*/
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