/*
    SPDX-FileCopyrightText: 2006 Lubos Lunak <l.lunak@kde.org>
    SPDX-FileCopyrightText: 2009 Lucas Murray <lmurray@undefinedfire.com>
    SPDX-FileCopyrightText: 2010, 2011 Martin Gräßlin <mgraesslin@kde.org>

    SPDX-License-Identifier: GPL-2.0-or-later
*/

#pragma once

#include "effect/effecthandler.h"

namespace KWin
{

/**
 * @internal
 */
template<typename T>
class KWIN_EXPORT Motion
{
public:
    /**
     * Creates a new motion object. "Strength" is the amount of
     * acceleration that is applied to the object when the target
     * changes and "smoothness" relates to how fast the object
     * can change its direction and speed.
     */
    explicit Motion(T initial, double strength, double smoothness);
    /**
     * Creates an exact copy of another motion object, including
     * position, target and velocity.
     */
    Motion(const Motion<T> &other);
    ~Motion();

    inline T value() const
    {
        return m_value;
    }
    inline void setValue(const T value)
    {
        m_value = value;
    }
    inline T target() const
    {
        return m_target;
    }
    inline void setTarget(const T target)
    {
        m_start = m_value;
        m_target = target;
    }
    inline T velocity() const
    {
        return m_velocity;
    }
    inline void setVelocity(const T velocity)
    {
        m_velocity = velocity;
    }

    inline double strength() const
    {
        return m_strength;
    }
    inline void setStrength(const double strength)
    {
        m_strength = strength;
    }
    inline double smoothness() const
    {
        return m_smoothness;
    }
    inline void setSmoothness(const double smoothness)
    {
        m_smoothness = smoothness;
    }
    inline T startValue()
    {
        return m_start;
    }

    /**
     * The distance between the current position and the target.
     */
    inline T distance() const
    {
        return m_target - m_value;
    }

    /**
     * Calculates the new position if not at the target. Called
     * once per frame only.
     */
    void calculate(const int msec);
    /**
     * Place the object on top of the target immediately,
     * bypassing all movement calculation.
     */
    void finish();

private:
    T m_value;
    T m_start;
    T m_target;
    T m_velocity;
    double m_strength;
    double m_smoothness;
};

/**
 * @short A single 1D motion dynamics object.
 *
 * This class represents a single object that can be moved around a
 * 1D space. Although it can be used directly by itself it is
 * recommended to use a motion manager instead.
 */
class KWIN_EXPORT Motion1D : public Motion<double>
{
public:
    explicit Motion1D(double initial = 0.0, double strength = 0.08, double smoothness = 4.0);
    Motion1D(const Motion1D &other);
    ~Motion1D();
};

/**
 * @short A single 2D motion dynamics object.
 *
 * This class represents a single object that can be moved around a
 * 2D space. Although it can be used directly by itself it is
 * recommended to use a motion manager instead.
 */
class KWIN_EXPORT Motion2D : public Motion<QPointF>
{
public:
    explicit Motion2D(QPointF initial = QPointF(), double strength = 0.08, double smoothness = 4.0);
    Motion2D(const Motion2D &other);
    ~Motion2D();
};

/**
 * @short Helper class for motion dynamics in KWin effects.
 *
 * This motion manager class is intended to help KWin effect authors
 * move windows across the screen smoothly and naturally. Once
 * windows are registered by the manager the effect can issue move
 * commands with the moveWindow() methods. The position of any
 * managed window can be determined in realtime by the
 * transformedGeometry() method. As the manager knows if any windows
 * are moving at any given time it can also be used as a notifier as
 * to see whether the effect is active or not.
 */
class KWIN_EXPORT WindowMotionManager
{
public:
    /**
     * Creates a new window manager object.
     */
    explicit WindowMotionManager(bool useGlobalAnimationModifier = true);
    ~WindowMotionManager();

    /**
     * Register a window for managing.
     */
    void manage(EffectWindow *w);
    /**
     * Register a list of windows for managing.
     */
    inline void manage(const QList<EffectWindow *> &list)
    {
        for (int i = 0; i < list.size(); i++) {
            manage(list.at(i));
        }
    }
    /**
     * Deregister a window. All transformations applied to the
     * window will be permanently removed and cannot be recovered.
     */
    void unmanage(EffectWindow *w);
    /**
     * Deregister all windows, returning the manager to its
     * originally initiated state.
     */
    void unmanageAll();
    /**
     * Determine the new positions for windows that have not
     * reached their target. Called once per frame, usually in
     * prePaintScreen(). Remember to set the
     * Effect::PAINT_SCREEN_WITH_TRANSFORMED_WINDOWS flag.
     */
    void calculate(int time);
    /**
     * Modify a registered window's paint data to make it appear
     * at its real location on the screen. Usually called in
     * paintWindow(). Remember to flag the window as having been
     * transformed in prePaintWindow() by calling
     * WindowPrePaintData::setTransformed()
     */
    void apply(EffectWindow *w, WindowPaintData &data);
    /**
     * Set all motion targets and values back to where the
     * windows were before transformations. The same as
     * unmanaging then remanaging all windows.
     */
    void reset();
    /**
     * Resets the motion target and current value of a single
     * window.
     */
    void reset(EffectWindow *w);

    /**
     * Ask the manager to move the window to the target position
     * with the specified scale. If `yScale` is not provided or
     * set to 0.0, `scale` will be used as the scale in the
     * vertical direction as well as in the horizontal direction.
     */
    void moveWindow(EffectWindow *w, QPoint target, double scale = 1.0, double yScale = 0.0);
    /**
     * This is an overloaded method, provided for convenience.
     *
     * Ask the manager to move the window to the target rectangle.
     * Automatically determines scale.
     */
    inline void moveWindow(EffectWindow *w, QRect target)
    {
        // TODO: Scale might be slightly different in the comparison due to rounding
        moveWindow(w, target.topLeft(),
                   target.width() / double(w->width()), target.height() / double(w->height()));
    }

    /**
     * Retrieve the current tranformed geometry of a registered
     * window.
     */
    QRectF transformedGeometry(EffectWindow *w) const;
    /**
     * Sets the current transformed geometry of a registered window to the given geometry.
     * @see transformedGeometry
     * @since 4.5
     */
    void setTransformedGeometry(EffectWindow *w, const QRectF &geometry);
    /**
     * Retrieve the current target geometry of a registered
     * window.
     */
    QRectF targetGeometry(EffectWindow *w) const;
    /**
     * Return the window that has its transformed geometry under
     * the specified point. It is recommended to use the stacking
     * order as it's what the user sees, but it is slightly
     * slower to process.
     */
    EffectWindow *windowAtPoint(QPoint point, bool useStackingOrder = true) const;

    /**
     * Return a list of all currently registered windows.
     */
    inline QList<EffectWindow *> managedWindows() const
    {
        return m_managedWindows.keys();
    }
    /**
     * Returns whether or not a specified window is being managed
     * by this manager object.
     */
    inline bool isManaging(EffectWindow *w) const
    {
        return m_managedWindows.contains(w);
    }
    /**
     * Returns whether or not this manager object is actually
     * managing any windows or not.
     */
    inline bool managingWindows() const
    {
        return !m_managedWindows.empty();
    }
    /**
     * Returns whether all windows have reached their targets yet
     * or not. Can be used to see if an effect should be
     * processed and displayed or not.
     */
    inline bool areWindowsMoving() const
    {
        return !m_movingWindowsSet.isEmpty();
    }
    /**
     * Returns whether a window has reached its targets yet
     * or not.
     */
    inline bool isWindowMoving(EffectWindow *w) const
    {
        return m_movingWindowsSet.contains(w);
    }

private:
    bool m_useGlobalAnimationModifier;
    struct WindowMotion
    {
        // TODO: Rotation, etc?
        Motion2D translation; // Absolute position
        Motion2D scale; // xScale and yScale
    };
    QHash<EffectWindow *, WindowMotion> m_managedWindows;
    QSet<EffectWindow *> m_movingWindowsSet;
};

template<typename T>
Motion<T>::Motion(T initial, double strength, double smoothness)
    : m_value(initial)
    , m_start(initial)
    , m_target(initial)
    , m_velocity()
    , m_strength(strength)
    , m_smoothness(smoothness)
{
}

template<typename T>
Motion<T>::Motion(const Motion &other)
    : m_value(other.value())
    , m_start(other.target())
    , m_target(other.target())
    , m_velocity(other.velocity())
    , m_strength(other.strength())
    , m_smoothness(other.smoothness())
{
}

template<typename T>
Motion<T>::~Motion()
{
}

template<typename T>
void Motion<T>::calculate(const int msec)
{
    if (m_value == m_target && m_velocity == T()) { // At target and not moving
        return;
    }

    // Poor man's time independent calculation
    int steps = std::max(1, msec / 5);
    for (int i = 0; i < steps; i++) {
        T diff = m_target - m_value;
        T strength = diff * m_strength;
        m_velocity = (m_smoothness * m_velocity + strength) / (m_smoothness + 1.0);
        m_value += m_velocity;
    }
}

template<typename T>
void Motion<T>::finish()
{
    m_value = m_target;
    m_velocity = T();
}

} // namespace KWin