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/****************************************************************************
**
** Copyright (C) 2012 Digia Plc and/or its subsidiary(-ies).
** Contact: http://www.qt-project.org/legal
**
** This file is part of the documentation of the Qt Toolkit.
**
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** Documentation License version 1.3 as published by the Free Software
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** this file. Please review the following information to ensure
** the GNU Free Documentation License version 1.3 requirements
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****************************************************************************/
/*!
\example animation/stickman
\title Stickman Example
\brief The Stickman example shows how to animate transitions in a state machine to implement key frame
animations.
\image stickman-example.png
In this example, we will write a small application which animates the joints in a skeleton and
projects a stickman figure on top. The stickman can be either "alive" or "dead", and when in the
"alive" state, he can be performing different actions defined by key frame animations.
Animations are implemented as composite states. Each child state of the animation state
represents a frame in the animation by setting the position of each joint in the stickman's
skeleton to the positions defined for the particular frame. The frames are then bound together
with animated transitions that trigger on the source state's propertiesAssigned() signal. Thus,
the machine will enter the state representing the next frame in the animation immediately after
it has finished animating into the previous frame.
\image stickman-example1.png
The states for an animation is constructed by reading a custom animation file format and
creating states that assign values to the the "position" properties of each of the nodes in the
skeleton graph.
\snippet examples/animation/stickman/lifecycle.cpp 1
The states are then bound together with signal transitions that listen to the
propertiesAssigned() signal.
\snippet examples/animation/stickman/lifecycle.cpp 2
The last frame state is given a transition to the first one, so that the animation will loop
until it is interrupted when a transition out from the animation state is taken. To get smooth
animations between the different key frames, we set a default animation on the state machine.
This is a parallel animation group which contains animations for all the "position" properties
and will be selected by default when taking any transition that leads into a state that assigns
values to these properties.
\snippet examples/animation/stickman/lifecycle.cpp 3
Several such animation states are constructed, and are placed together as children of a top
level "alive" state which represents the stickman life cycle. Transitions go from the parent
state to the child state to ensure that each of the child states inherit them.
\image stickman-example2.png
This saves us the effort of connect every state to every state with identical transitions. The
state machine makes sure that transitions between the key frame animations are also smooth by
applying the default animation when interrupting one and starting another.
Finally, there is a transition out from the "alive" state and into the "dead" state. This is
a custom transition type called LightningSrikesTransition which samples every second and
triggers at random (one out of fifty times on average.)
\snippet examples/animation/stickman/lifecycle.cpp 4
When it triggers, the machine will first enter a "lightningBlink" state which uses a timer to
pause for a brief period of time while the background color of the scene is white. This gives us
a flash effect when the lightning strikes.
\snippet examples/animation/stickman/lifecycle.cpp 5
We start and stop a QTimer object when entering and exiting the state. Then we transition into
the "dead" state when the timer times out.
\snippet examples/animation/stickman/lifecycle.cpp 0
When the machine is in the "dead" state, it will be unresponsive. This is because the "dead"
state has no transitions leading out.
\image stickman-example3.png
*/
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