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364 lines
9.0 KiB
C#
364 lines
9.0 KiB
C#
using UnityEngine;
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using System.Collections;
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namespace RootMotion {
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/// <summary>
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/// Interpolation mode.
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/// </summary>
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[System.Serializable]
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public enum InterpolationMode
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{
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None,
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InOutCubic,
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InOutQuintic,
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InOutSine,
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InQuintic,
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InQuartic,
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InCubic,
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InQuadratic,
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InElastic,
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InElasticSmall,
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InElasticBig,
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InSine,
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InBack,
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OutQuintic,
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OutQuartic,
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OutCubic,
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OutInCubic,
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OutInQuartic,
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OutElastic,
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OutElasticSmall,
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OutElasticBig,
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OutSine,
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OutBack,
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OutBackCubic,
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OutBackQuartic,
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BackInCubic,
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BackInQuartic,
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};
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/// <summary>
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/// Class for various interpolation methods.
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/// </summary>
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public class Interp
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{
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#region Public methods
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/// <summary>
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/// Interpolate the specified t by InterpolationMode mode.
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/// </summary>
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/// <param name='t'>
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/// T.
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/// </param>
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/// <param name='mode'>
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/// InterpolationMode.
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/// </param>
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public static float Float(float t, InterpolationMode mode) {
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float interpT = 0;
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switch (mode) {
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case InterpolationMode.None:
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interpT = Interp.None(t, 0, 1);
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break;
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case InterpolationMode.InOutCubic:
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interpT = Interp.InOutCubic(t, 0, 1);
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break;
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case InterpolationMode.InOutQuintic:
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interpT = Interp.InOutQuintic(t, 0, 1);
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break;
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case InterpolationMode.InQuintic:
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interpT = Interp.InQuintic(t, 0, 1);
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break;
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case InterpolationMode.InQuartic:
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interpT = Interp.InQuartic(t, 0, 1);
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break;
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case InterpolationMode.InCubic:
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interpT = Interp.InCubic(t, 0, 1);
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break;
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case InterpolationMode.InQuadratic:
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interpT = Interp.InQuadratic(t, 0, 1);
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break;
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case InterpolationMode.OutQuintic:
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interpT = Interp.OutQuintic(t, 0, 1);
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break;
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case InterpolationMode.OutQuartic:
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interpT = Interp.OutQuartic(t, 0, 1);
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break;
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case InterpolationMode.OutCubic:
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interpT = Interp.OutCubic(t, 0, 1);
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break;
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case InterpolationMode.OutInCubic:
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interpT = Interp.OutInCubic(t, 0, 1);
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break;
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case InterpolationMode.OutInQuartic:
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interpT = Interp.OutInCubic(t, 0, 1);
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break;
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case InterpolationMode.BackInCubic:
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interpT = Interp.BackInCubic(t, 0, 1);
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break;
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case InterpolationMode.BackInQuartic:
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interpT = Interp.BackInQuartic(t, 0, 1);
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break;
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case InterpolationMode.OutBackCubic:
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interpT = Interp.OutBackCubic(t, 0, 1);
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break;
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case InterpolationMode.OutBackQuartic:
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interpT = Interp.OutBackQuartic(t, 0, 1);
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break;
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case InterpolationMode.OutElasticSmall:
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interpT = Interp.OutElasticSmall(t, 0, 1);
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break;
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case InterpolationMode.OutElasticBig:
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interpT = Interp.OutElasticBig(t, 0, 1);
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break;
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case InterpolationMode.InElasticSmall:
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interpT = Interp.InElasticSmall(t, 0, 1);
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break;
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case InterpolationMode.InElasticBig:
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interpT = Interp.InElasticBig(t, 0, 1);
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break;
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case InterpolationMode.InSine:
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interpT = Interp.InSine(t, 0, 1);
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break;
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case InterpolationMode.OutSine:
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interpT = Interp.OutSine(t, 0, 1);
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break;
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case InterpolationMode.InOutSine:
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interpT = Interp.InOutSine(t, 0, 1);
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break;
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case InterpolationMode.InElastic:
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interpT = Interp.OutElastic(t, 0, 1);
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break;
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case InterpolationMode.OutElastic:
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interpT = Interp.OutElastic(t, 0, 1);
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break;
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case InterpolationMode.InBack:
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interpT = Interp.InBack(t, 0, 1);
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break;
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case InterpolationMode.OutBack:
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interpT = Interp.OutBack(t, 0, 1);
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break;
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default: interpT = 0;
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break;
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}
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return interpT;
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}
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/// <summary>
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/// Interpolate between two verctors by InterpolationMode mode
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/// </summary>
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public static Vector3 V3(Vector3 v1, Vector3 v2, float t, InterpolationMode mode) {
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float interpT = Interp.Float(t, mode);
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return ((1 - interpT) * v1) + (interpT * v2);
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}
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/// <summary>
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/// Linear interpolation of value towards target.
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/// </summary>
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public static float LerpValue(float value, float target, float increaseSpeed, float decreaseSpeed) {
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if (value == target) return target;
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if (value < target) return Mathf.Clamp(value + Time.deltaTime * increaseSpeed, -Mathf.Infinity, target);
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else return Mathf.Clamp(value - Time.deltaTime * decreaseSpeed, target, Mathf.Infinity);
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}
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#endregion Public methods
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#region Interpolation modes
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private static float None (float t, float b, float c) { // time, b, distance,
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return b + c * (t);
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}
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private static float InOutCubic(float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (-2 * tc + 3 * ts);
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}
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private static float InOutQuintic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (6 * tc * ts + -15 * ts * ts + 10 * tc);
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}
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private static float InQuintic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (tc * ts);
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}
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private static float InQuartic (float t, float b, float c) {
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float ts = t * t;
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return b + c * (ts * ts);
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}
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private static float InCubic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (tc);
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}
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private static float InQuadratic (float t, float b, float c) {
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float ts = t * t;
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return b + c * (ts);
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}
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private static float OutQuintic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (tc * ts + -5 * ts * ts + 10 * tc + -10 * ts + 5 * t);
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}
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private static float OutQuartic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (-1 * ts * ts + 4 * tc + -6 * ts + 4 * t);
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}
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private static float OutCubic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (tc + -3 * ts + 3 * t);
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}
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private static float OutInCubic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (4 * tc + -6 * ts + 3 * t);
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}
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private static float OutInQuartic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (6 * tc + -9 * ts + 4 * t);
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}
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private static float BackInCubic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c *(4 * tc + -3 * ts);
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}
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private static float BackInQuartic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (2 * ts * ts + 2 * tc + -3 * ts);
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}
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private static float OutBackCubic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (4 * tc + -9 * ts + 6 * t);
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}
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private static float OutBackQuartic (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (-2 * ts * ts + 10 * tc + -15 * ts + 8 * t);
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}
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private static float OutElasticSmall (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (33 * tc * ts + -106 * ts * ts + 126 * tc + -67 * ts + 15 * t);
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}
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private static float OutElasticBig (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b+c*(56*tc*ts + -175*ts*ts + 200*tc + -100*ts + 20*t);
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}
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private static float InElasticSmall (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (33 * tc * ts + -59 * ts * ts + 32 * tc + -5 * ts);
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}
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private static float InElasticBig (float t, float b, float c) {
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float ts = t * t;
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float tc = ts * t;
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return b + c * (56 * tc * ts + -105 * ts * ts + 60 * tc + -10 * ts);
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}
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private static float InSine (float t, float b, float c) {
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c -= b;
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return -c * Mathf.Cos(t / 1 * (Mathf.PI / 2)) + c + b;
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}
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private static float OutSine (float t, float b, float c) {
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c -= b;
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return c * Mathf.Sin(t / 1 * (Mathf.PI / 2)) + b;
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}
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private static float InOutSine (float t, float b, float c) {
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c -= b;
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return -c / 2 * (Mathf.Cos(Mathf.PI * t / 1) - 1) + b;
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}
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private static float InElastic (float t, float b, float c) {
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c -= b;
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float d = 1f;
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float p = d * .3f;
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float s = 0;
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float a = 0;
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if (t == 0) return b;
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if ((t /= d) == 1) return b + c;
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if (a == 0f || a < Mathf.Abs(c)){
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a = c;
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s = p / 4;
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}else{
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s = p / (2 * Mathf.PI) * Mathf.Asin(c / a);
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}
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return -(a * Mathf.Pow(2, 10 * (t-=1)) * Mathf.Sin((t * d - s) * (2 * Mathf.PI) / p)) + b;
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}
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private static float OutElastic (float t, float b, float c) {
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c -= b;
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float d = 1f;
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float p = d * .3f;
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float s = 0;
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float a = 0;
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if (t == 0) return b;
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if ((t /= d) == 1) return b + c;
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if (a == 0f || a < Mathf.Abs(c)){
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a = c;
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s = p / 4;
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}else{
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s = p / (2 * Mathf.PI) * Mathf.Asin(c / a);
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}
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return (a * Mathf.Pow(2, -10 * t) * Mathf.Sin((t * d - s) * (2 * Mathf.PI) / p) + c + b);
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}
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private static float InBack(float t, float b, float c){
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c -= b;
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t /= 1;
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float s = 1.70158f;
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return c * (t) * t * ((s + 1) * t - s) + b;
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}
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private static float OutBack (float t, float b, float c) {
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float s = 1.70158f;
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c -= b;
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t = (t / 1) - 1;
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return c * ((t) * t * ((s + 1) * t + s) + 1) + b;
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}
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#endregion Interpolation modes
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}
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}
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