The GTK Input Model3GTK LibraryThe GTK Input Model
input and event handling in detail
Overview of GTK input and event handling
This chapter describes in detail how GTK handles input. If you are interested
in what happens to translate a key press or mouse motion of the users into a
change of a GTK widget, you should read this chapter. This knowledge will also
be useful if you decide to implement your own widgets.
Devices and events
The most basic input devices that every computer user has interacted with are
keyboards and mice; beyond these, GTK supports touchpads, touchscreens and
more exotic input devices such as graphics tablets. Inside GTK, every such
input device is represented by a #GdkDevice object.
To simplify dealing with the variability between these input devices, GTK
has a concept of master and slave devices. The concrete physical devices that
have many different characteristics (mice may have 2 or 3 or 8 buttons,
keyboards have different layouts and may or may not have a separate number
block, etc) are represented as slave devices. Each slave device is
associated with a virtual master device. Master devices always come in
pointer/keyboard pairs - you can think of such a pair as a 'seat'.
GTK widgets generally deal with the master devices, and thus can be used
with any pointing device or keyboard.
When a user interacts with an input device (e.g. moves a mouse or presses
a key on the keyboard), GTK receives events from the windowing system.
These are typically directed at a specific surface - for pointer events,
the surface under the pointer (grabs complicate this), for keyboard events,
the surface with the keyboard focus.
GDK translates these raw windowing system events into #GdkEvents.
Typical input events are:
button clickspointer motionkey pressesfocus changestouch events
These are all represented as #GdkEvents, but you can differentiate
between different events by looking at their type, using
gdk_event_get_event_type().
Some events, such as touch events or button press-release pairs,
are connected in to each other in an “event sequence” that
univocally identifies events that are related to the same
interaction.
When GTK creates a GdkSurface, it connects to the #GdkSurface::event
signal on it, which receives all of these input events. Surfaces have
have signals and properties, e.g. to deal with window management
related events.
Event propagation
The function which initially receives input events on the GTK
side is responsible for a number of tasks.
Find the widget which got the event.
Generate crossing (i.e. enter and leave) events when the focus or hover
location change from one widget to another.
Then the event is pushed onto a stack so you can query the currently
handled event with gtk_get_current_event().
The event is sent to a widget. If a grab is active all events for widgets
that are not in the contained in the grab widget are sent to the latter
with a few exceptions:
Deletion and destruction events are still sent to the event widget for
obvious reasons.
Events which directly relate to the visual representation of the event
widget.
Leave events are delivered to the event widget if there was an enter
event delivered to it before without the paired leave event.
Drag events are not redirected because it is unclear what the semantics
of that would be.
After finishing the delivery the event is popped from the event stack.
An event is propagated down and up the widget hierarchy in three phases
(see #GtkPropagationPhase) towards a target widget.
For key events, the top-level window gets a first shot at activating
mnemonics and accelerators. If that does not consume the events,
the target widget for event propagation is window's current focus
widget (see gtk_window_get_focus()).
For pointer events, the target widget is determined by picking
the widget at the events coordinates (see gtk_window_pick()).
In the first phase (the “capture” phase) the event is
delivered to each widget from the top-most (the top-level
#GtkWindow or grab widget) down to the target #GtkWidget.
Event
controllers that are attached with %GTK_PHASE_CAPTURE
get a chance to react to the event.
After the “capture” phase, the widget that was intended to be the
destination of the event will run event controllers attached to
it with %GTK_PHASE_TARGET. This is known as the “target” phase,
and only happens on that widget.
In the last phase (the “bubble” phase), the event is delivered
to each widget from the target to the top-most, and event
controllers attached with %GTK_PHASE_BUBBLE are run.
Events are not delivered to a widget which is insensitive or
unmapped.
Any time during the propagation phase, a controller may indicate
that a received event was consumed and propagation should
therefore be stopped. If gestures are used, this may happen
when the gesture claims the event touch sequence (or the
pointer events) for its own. See the “gesture states” section
below to learn more about gestures and sequences.
Keyboard input
Every #GtkWindow maintains a single focus location (in the
#GtkWindow:focus-widget property). The focus widget is the target
widget for key events sent to the window. Only widgets which have
#GtkWidget:can-focus set to %TRUE can become the focus. Typically
these are input controls such as entries or text fields, but e.g.
buttons can take the focus too.
Input widgets can be given the focus by clicking on them, but focus
can also be moved around with certain key events (this is known as
“keyboard navigation”). GTK reserves the Tab key to move the focus
to the next location, and Shift-Tab to move it back to the previous
one. In addition many containers allow “directional navigation” with
the arrow keys.
Many widgets can be “activated” to trigger and action. E.g., you can
activate a button or switch by clicking on them, but you can also
activate them with the keyboard, by using the Enter or Space keys.
Apart from keyboard navigation, activation and directly typing into
entries or text views, GTK widgets can use key events for activating
“shortcuts”. Shortcuts generally act as a quick way to move the focus
around or to activate a widget that does not currently have the focus.
GTK has traditionally supported different kinds of shortcuts:
Mnmemonics
Mnemonics are usually triggered using Alt as a modifier for a letter.
They are used in places where a label is associated with a control,
and are indicated by underlining the letter in the label. As a special
case, inside menus (i.e. inside #GtkPopoverMenu), mnemonics can be
trigered without the modifier.
Key bindings
Key bindings are specific to individual widgets, such as Ctrl-C or
Ctrl-V in an entry copy to or paste from the clipboard. They are only
triggered when the widget has focus.
Accelerators
Accelerators are any other shortcuts that can be activated regardless
of where the focus is, and typically trigger global actions, such as
Ctrl-Q to quit an application.
Under the hood, all shortcuts are represented as instances of #GtkShortcut,
and they are managed by #GtkShortcutController.
Event controllers and gestures
Event controllers are standalone objects that can perform
specific actions upon received #GdkEvents. These are tied
to a #GtkWidget, and can be told of the event propagation
phase at which they will manage the events.
Gestures are a set of specific controllers that are prepared
to handle pointer and/or touch events, each gesture
implementation attempts to recognize specific actions out the
received events, notifying of the state/progress accordingly to
let the widget react to those. On multi-touch gestures, every
interacting touch sequence will be tracked independently.
Since gestures are “simple” units, it is not uncommon to tie
several together to perform higher level actions, grouped
gestures handle the same event sequences simultaneously, and
those sequences share a same state across all grouped
gestures. Some examples of grouping may be:
A “drag” and a “swipe” gestures may want grouping.
The former will report events as the dragging happens,
the latter will tell the swipe X/Y velocities only after
recognition has finished.
Grouping a “drag” gesture with a “pan” gesture will only
effectively allow dragging in the panning orientation, as
both gestures share state.
If “press” and “long press” are wanted simultaneously,
those would need grouping.
Shortcuts are handled by #GtkShortcutController, which is
a complex event handler that can either activate shortcuts
itself, or propagate them to another controller, depending
on its #GtkShortcutController:scope.
Gesture states
Gestures have a notion of “state” for each individual touch
sequence. When events from a touch sequence are first received,
the touch sequence will have “none” state, this means the touch
sequence is being handled by the gesture to possibly trigger
actions, but the event propagation will not be stopped.
When the gesture enters recognition, or at a later point in time,
the widget may choose to claim the touch sequences (individually
or as a group), hence stopping event propagation after the event
is run through every gesture in that widget and propagation phase.
Anytime this happens, the touch sequences are cancelled downwards
the propagation chain, to let these know that no further events
will be sent.
Alternatively, or at a later point in time, the widget may choose
to deny the touch sequences, thus letting those go through again
in event propagation. When this happens in the capture phase, and
if there are no other claiming gestures in the widget,
a %GDK_TOUCH_BEGIN/%GDK_BUTTON_PRESS event will be emulated and
propagated downwards, in order to preserve consistency.
Grouped gestures always share the same state for a given touch
sequence, so setting the state on one does transfer the state to
the others. They also are mutually exclusive, within a widget
there may be only one gesture group claiming a given sequence.
If another gesture group claims later that same sequence, the
first group will deny the sequence.