using UnityEngine; public static partial class SRMath { /** * * These tweening functions taken from https://wpf-animation.googlecode.com/svn/trunk/src/WPF/Animation/PennerDoubleAnimation.cs * Licensed under the new BSD License * * @author Darren David darren-code@lookorfeel.com * @version 1.0 * * Credit/Thanks: * Robert Penner - The easing equations we all know and love * (http://robertpenner.com/easing/) [See License.txt for license info] * * Lee Brimelow - initial port of Penner's equations to WPF * (http://thewpfblog.com/?p=12) * * Zeh Fernando - additional equations (out/in) from * caurina.transitions.Tweener (http://code.google.com/p/tweener/) * [See License.txt for license info] * */ private static class TweenFunctions { #region Equations #region Linear ///

/// Easing equation function for a simple linear tweening, with no easing. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float Linear(float t, float b, float c, float d) { return c*t/d + b; } #endregion #region Expo ///

/// Easing equation function for an exponential (2^t) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ExpoEaseOut(float t, float b, float c, float d) { return (t == d) ? b + c : c*(-Mathf.Pow(2, -10*t/d) + 1) + b; } ///

/// Easing equation function for an exponential (2^t) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ExpoEaseIn(float t, float b, float c, float d) { return (t == 0) ? b : c*Mathf.Pow(2, 10*(t/d - 1)) + b; } ///

/// Easing equation function for an exponential (2^t) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ExpoEaseInOut(float t, float b, float c, float d) { if (t == 0) { return b; } if (t == d) { return b + c; } if ((t /= d/2) < 1) { return c/2*Mathf.Pow(2, 10*(t - 1)) + b; } return c/2*(-Mathf.Pow(2, -10*--t) + 2) + b; } ///

/// Easing equation function for an exponential (2^t) easing out/in: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ExpoEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return ExpoEaseOut(t*2, b, c/2, d); } return ExpoEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Circular ///

/// Easing equation function for a circular (sqrt(1-t^2)) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CircEaseOut(float t, float b, float c, float d) { return c*Mathf.Sqrt(1 - (t = t/d - 1)*t) + b; } ///

/// Easing equation function for a circular (sqrt(1-t^2)) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CircEaseIn(float t, float b, float c, float d) { return -c*(Mathf.Sqrt(1 - (t /= d)*t) - 1) + b; } ///

/// Easing equation function for a circular (sqrt(1-t^2)) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CircEaseInOut(float t, float b, float c, float d) { if ((t /= d/2) < 1) { return -c/2*(Mathf.Sqrt(1 - t*t) - 1) + b; } return c/2*(Mathf.Sqrt(1 - (t -= 2)*t) + 1) + b; } ///

/// Easing equation function for a circular (sqrt(1-t^2)) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CircEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return CircEaseOut(t*2, b, c/2, d); } return CircEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Quad ///

/// Easing equation function for a quadratic (t^2) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuadEaseOut(float t, float b, float c, float d) { return -c*(t /= d)*(t - 2) + b; } ///

/// Easing equation function for a quadratic (t^2) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuadEaseIn(float t, float b, float c, float d) { return c*(t /= d)*t + b; } ///

/// Easing equation function for a quadratic (t^2) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuadEaseInOut(float t, float b, float c, float d) { if ((t /= d/2) < 1) { return c/2*t*t + b; } return -c/2*((--t)*(t - 2) - 1) + b; } ///

/// Easing equation function for a quadratic (t^2) easing out/in: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuadEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return QuadEaseOut(t*2, b, c/2, d); } return QuadEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Sine ///

/// Easing equation function for a sinusoidal (sin(t)) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float SineEaseOut(float t, float b, float c, float d) { return c*Mathf.Sin(t/d*(Mathf.PI/2)) + b; } ///

/// Easing equation function for a sinusoidal (sin(t)) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float SineEaseIn(float t, float b, float c, float d) { return -c*Mathf.Cos(t/d*(Mathf.PI/2)) + c + b; } ///

/// Easing equation function for a sinusoidal (sin(t)) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float SineEaseInOut(float t, float b, float c, float d) { if ((t /= d/2) < 1) { return c/2*(Mathf.Sin(Mathf.PI*t/2)) + b; } return -c/2*(Mathf.Cos(Mathf.PI*--t/2) - 2) + b; } ///

/// Easing equation function for a sinusoidal (sin(t)) easing in/out: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float SineEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return SineEaseOut(t*2, b, c/2, d); } return SineEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Cubic ///

/// Easing equation function for a cubic (t^3) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CubicEaseOut(float t, float b, float c, float d) { return c*((t = t/d - 1)*t*t + 1) + b; } ///

/// Easing equation function for a cubic (t^3) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CubicEaseIn(float t, float b, float c, float d) { return c*(t /= d)*t*t + b; } ///

/// Easing equation function for a cubic (t^3) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CubicEaseInOut(float t, float b, float c, float d) { if ((t /= d/2) < 1) { return c/2*t*t*t + b; } return c/2*((t -= 2)*t*t + 2) + b; } ///

/// Easing equation function for a cubic (t^3) easing out/in: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float CubicEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return CubicEaseOut(t*2, b, c/2, d); } return CubicEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Quartic ///

/// Easing equation function for a quartic (t^4) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuartEaseOut(float t, float b, float c, float d) { return -c*((t = t/d - 1)*t*t*t - 1) + b; } ///

/// Easing equation function for a quartic (t^4) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuartEaseIn(float t, float b, float c, float d) { return c*(t /= d)*t*t*t + b; } ///

/// Easing equation function for a quartic (t^4) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuartEaseInOut(float t, float b, float c, float d) { if ((t /= d/2) < 1) { return c/2*t*t*t*t + b; } return -c/2*((t -= 2)*t*t*t - 2) + b; } ///

/// Easing equation function for a quartic (t^4) easing out/in: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuartEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return QuartEaseOut(t*2, b, c/2, d); } return QuartEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Quintic ///

/// Easing equation function for a quintic (t^5) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuintEaseOut(float t, float b, float c, float d) { return c*((t = t/d - 1)*t*t*t*t + 1) + b; } ///

/// Easing equation function for a quintic (t^5) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuintEaseIn(float t, float b, float c, float d) { return c*(t /= d)*t*t*t*t + b; } ///

/// Easing equation function for a quintic (t^5) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuintEaseInOut(float t, float b, float c, float d) { if ((t /= d/2) < 1) { return c/2*t*t*t*t*t + b; } return c/2*((t -= 2)*t*t*t*t + 2) + b; } ///

/// Easing equation function for a quintic (t^5) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float QuintEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return QuintEaseOut(t*2, b, c/2, d); } return QuintEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Elastic ///

/// Easing equation function for an elastic (exponentially decaying sine wave) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ElasticEaseOut(float t, float b, float c, float d) { if ((t /= d) == 1) { return b + c; } var p = d*.3f; var s = p/4; return (c*Mathf.Pow(2, -10*t)*Mathf.Sin((t*d - s)*(2*Mathf.PI)/p) + c + b); } ///

/// Easing equation function for an elastic (exponentially decaying sine wave) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ElasticEaseIn(float t, float b, float c, float d) { if ((t /= d) == 1) { return b + c; } var p = d*.3f; var s = p/4; return -(c*Mathf.Pow(2, 10*(t -= 1))*Mathf.Sin((t*d - s)*(2*Mathf.PI)/p)) + b; } ///

/// Easing equation function for an elastic (exponentially decaying sine wave) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ElasticEaseInOut(float t, float b, float c, float d) { if ((t /= d/2) == 2) { return b + c; } var p = d*(.3f*1.5f); var s = p/4; if (t < 1) { return -.5f*(c*Mathf.Pow(2, 10*(t -= 1))*Mathf.Sin((t*d - s)*(2*Mathf.PI)/p)) + b; } return c*Mathf.Pow(2, -10*(t -= 1))*Mathf.Sin((t*d - s)*(2*Mathf.PI)/p)*.5f + c + b; } ///

/// Easing equation function for an elastic (exponentially decaying sine wave) easing out/in: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float ElasticEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return ElasticEaseOut(t*2, b, c/2, d); } return ElasticEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Bounce ///

/// Easing equation function for a bounce (exponentially decaying parabolic bounce) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BounceEaseOut(float t, float b, float c, float d) { if ((t /= d) < (1/2.75f)) { return c*(7.5625f*t*t) + b; } if (t < (2/2.75)) { return c*(7.5625f*(t -= (1.5f/2.75f))*t + .75f) + b; } if (t < (2.5/2.75)) { return c*(7.5625f*(t -= (2.25f/2.75f))*t + .9375f) + b; } return c*(7.5625f*(t -= (2.625f/2.75f))*t + .984375f) + b; } ///

/// Easing equation function for a bounce (exponentially decaying parabolic bounce) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BounceEaseIn(float t, float b, float c, float d) { return c - BounceEaseOut(d - t, 0, c, d) + b; } ///

/// Easing equation function for a bounce (exponentially decaying parabolic bounce) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BounceEaseInOut(float t, float b, float c, float d) { if (t < d/2) { return BounceEaseIn(t*2, 0, c, d)*.5f + b; } return BounceEaseOut(t*2 - d, 0, c, d)*.5f + c*.5f + b; } ///

/// Easing equation function for a bounce (exponentially decaying parabolic bounce) easing out/in: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BounceEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return BounceEaseOut(t*2, b, c/2, d); } return BounceEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #region Back ///

/// Easing equation function for a back (overshooting cubic easing: (s+1)*t^3 - s*t^2) easing out: /// decelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BackEaseOut(float t, float b, float c, float d) { return c*((t = t/d - 1)*t*((1.70158f + 1)*t + 1.70158f) + 1) + b; } ///

/// Easing equation function for a back (overshooting cubic easing: (s+1)*t^3 - s*t^2) easing in: /// accelerating from zero velocity. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BackEaseIn(float t, float b, float c, float d) { return c*(t /= d)*t*((1.70158f + 1)*t - 1.70158f) + b; } ///

/// Easing equation function for a back (overshooting cubic easing: (s+1)*t^3 - s*t^2) easing in/out: /// acceleration until halfway, then deceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BackEaseInOut(float t, float b, float c, float d) { var s = 1.70158f; if ((t /= d/2) < 1) { return c/2*(t*t*(((s *= (1.525f)) + 1)*t - s)) + b; } return c/2*((t -= 2)*t*(((s *= (1.525f)) + 1)*t + s) + 2) + b; } ///

/// Easing equation function for a back (overshooting cubic easing: (s+1)*t^3 - s*t^2) easing out/in: /// deceleration until halfway, then acceleration. ///

/// Current time in seconds. /// Starting value. /// Final value. /// Duration of animation. /// The correct value. public static float BackEaseOutIn(float t, float b, float c, float d) { if (t < d/2) { return BackEaseOut(t*2, b, c/2, d); } return BackEaseIn((t*2) - d, b + c/2, c/2, d); } #endregion #endregion } }