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//
// easing.c
//
// Copyright (c) 2011, Auerhaus Development, LLC
//
// This program is free software. It comes without any warranty, to
// the extent permitted by applicable law. You can redistribute it
// and/or modify it under the terms of the Do What The Fuck You Want
// To Public License, Version 2, as published by Sam Hocevar. See
// http://sam.zoy.org/wtfpl/COPYING for more details.
//
#include <math.h>
#include "easing.h"
// Modeled after the line y = x
AHFloat LinearInterpolation(AHFloat p)
{
return p;
}
// Modeled after the parabola y = x^2
AHFloat QuadraticEaseIn(AHFloat p)
{
return p * p;
}
// Modeled after the parabola y = -x^2 + 2x
AHFloat QuadraticEaseOut(AHFloat p)
{
return -(p * (p - 2));
}
// Modeled after the piecewise quadratic
// y = (1/2)((2x)^2) ; [0, 0.5)
// y = -(1/2)((2x-1)*(2x-3) - 1) ; [0.5, 1]
AHFloat QuadraticEaseInOut(AHFloat p)
{
if (p < 0.5) {
return 2 * p * p;
} else {
return (-2 * p * p) + (4 * p) - 1;
}
}
// Modeled after the cubic y = x^3
AHFloat CubicEaseIn(AHFloat p)
{
return p * p * p;
}
// Modeled after the cubic y = (x - 1)^3 + 1
AHFloat CubicEaseOut(AHFloat p)
{
AHFloat f = (p - 1);
return f * f * f + 1;
}
// Modeled after the piecewise cubic
// y = (1/2)((2x)^3) ; [0, 0.5)
// y = (1/2)((2x-2)^3 + 2) ; [0.5, 1]
AHFloat CubicEaseInOut(AHFloat p)
{
if (p < 0.5) {
return 4 * p * p * p;
} else {
AHFloat f = ((2 * p) - 2);
return 0.5f * f * f * f + 1;
}
}
// Modeled after the quartic x^4
AHFloat QuarticEaseIn(AHFloat p)
{
return p * p * p * p;
}
// Modeled after the quartic y = 1 - (x - 1)^4
AHFloat QuarticEaseOut(AHFloat p)
{
AHFloat f = (p - 1);
return f * f * f * (1 - p) + 1;
}
// Modeled after the piecewise quartic
// y = (1/2)((2x)^4) ; [0, 0.5)
// y = -(1/2)((2x-2)^4 - 2) ; [0.5, 1]
AHFloat QuarticEaseInOut(AHFloat p)
{
if (p < 0.5) {
return 8 * p * p * p * p;
} else {
AHFloat f = (p - 1);
return -8 * f * f * f * f + 1;
}
}
// Modeled after the quintic y = x^5
AHFloat QuinticEaseIn(AHFloat p)
{
return p * p * p * p * p;
}
// Modeled after the quintic y = (x - 1)^5 + 1
AHFloat QuinticEaseOut(AHFloat p)
{
AHFloat f = (p - 1);
return f * f * f * f * f + 1;
}
// Modeled after the piecewise quintic
// y = (1/2)((2x)^5) ; [0, 0.5)
// y = (1/2)((2x-2)^5 + 2) ; [0.5, 1]
AHFloat QuinticEaseInOut(AHFloat p)
{
if (p < 0.5) {
return 16 * p * p * p * p * p;
} else {
AHFloat f = ((2 * p) - 2);
return 0.5f * f * f * f * f * f + 1;
}
}
// Modeled after quarter-cycle of sine wave
AHFloat SineEaseIn(AHFloat p)
{
return (AHFloat)sin((p - 1) * M_PI_2) + 1;
}
// Modeled after quarter-cycle of sine wave (different phase)
AHFloat SineEaseOut(AHFloat p)
{
return (AHFloat)sin(p * M_PI_2);
}
// Modeled after half sine wave
AHFloat SineEaseInOut(AHFloat p)
{
return (AHFloat)(0.5 * (1 - cos(p * M_PI)));
}
// Modeled after shifted quadrant IV of unit circle
AHFloat CircularEaseIn(AHFloat p)
{
return (AHFloat)(1 - sqrt(1 - (p * p)));
}
// Modeled after shifted quadrant II of unit circle
AHFloat CircularEaseOut(AHFloat p)
{
return (AHFloat)sqrt((2 - p) * p);
}
// Modeled after the piecewise circular function
// y = (1/2)(1 - sqrt(1 - 4x^2)) ; [0, 0.5)
// y = (1/2)(sqrt(-(2x - 3)*(2x - 1)) + 1) ; [0.5, 1]
AHFloat CircularEaseInOut(AHFloat p)
{
if (p < 0.5) {
return (AHFloat)(0.5 * (1 - sqrt(1 - 4 * (p * p))));
} else {
return (AHFloat)(0.5 * (sqrt(-((2 * p) - 3) * ((2 * p) - 1)) + 1));
}
}
// Modeled after the exponential function y = 2^(10(x - 1))
AHFloat ExponentialEaseIn(AHFloat p)
{
return (AHFloat)((p == 0.0) ? p : pow(2, 10 * (p - 1)));
}
// Modeled after the exponential function y = -2^(-10x) + 1
AHFloat ExponentialEaseOut(AHFloat p)
{
return (AHFloat)((p == 1.0) ? p : 1 - pow(2, -10 * p));
}
// Modeled after the piecewise exponential
// y = (1/2)2^(10(2x - 1)) ; [0,0.5)
// y = -(1/2)*2^(-10(2x - 1))) + 1 ; [0.5,1]
AHFloat ExponentialEaseInOut(AHFloat p)
{
if (p == 0.0 || p == 1.0)
return p;
if (p < 0.5) {
return (AHFloat)(0.5 * pow(2, (20 * p) - 10));
} else {
return (AHFloat)(-0.5 * pow(2, (-20 * p) + 10) + 1);
}
}
// Modeled after the damped sine wave y = sin(13pi/2*x)*pow(2, 10 * (x - 1))
AHFloat ElasticEaseIn(AHFloat p)
{
return (AHFloat)(sin(13 * M_PI_2 * p) * pow(2, 10 * (p - 1)));
}
// Modeled after the damped sine wave y = sin(-13pi/2*(x + 1))*pow(2, -10x) + 1
AHFloat ElasticEaseOut(AHFloat p)
{
return (AHFloat)(sin(-13 * M_PI_2 * (p + 1)) * pow(2, -10 * p) + 1);
}
// Modeled after the piecewise exponentially-damped sine wave:
// y = (1/2)*sin(13pi/2*(2*x))*pow(2, 10 * ((2*x) - 1)) ; [0,0.5)
// y = (1/2)*(sin(-13pi/2*((2x-1)+1))*pow(2,-10(2*x-1)) + 2) ; [0.5, 1]
AHFloat ElasticEaseInOut(AHFloat p)
{
if (p < 0.5) {
return (AHFloat)(0.5 * sin(13 * M_PI_2 * (2 * p)) * pow(2, 10 * ((2 * p) - 1)));
} else {
return (AHFloat)(0.5 * (sin(-13 * M_PI_2 * ((2 * p - 1) + 1)) * pow(2, -10 * (2 * p - 1)) + 2));
}
}
// Modeled after the overshooting cubic y = x^3-x*sin(x*pi)
AHFloat BackEaseIn(AHFloat p)
{
return (AHFloat)(p * p * p - p * sin(p * M_PI));
}
// Modeled after overshooting cubic y = 1-((1-x)^3-(1-x)*sin((1-x)*pi))
AHFloat BackEaseOut(AHFloat p)
{
AHFloat f = (1 - p);
return (AHFloat)(1 - (f * f * f - f * sin(f * M_PI)));
}
// Modeled after the piecewise overshooting cubic function:
// y = (1/2)*((2x)^3-(2x)*sin(2*x*pi)) ; [0, 0.5)
// y = (1/2)*(1-((1-x)^3-(1-x)*sin((1-x)*pi))+1) ; [0.5, 1]
AHFloat BackEaseInOut(AHFloat p)
{
if (p < 0.5) {
AHFloat f = 2 * p;
return (AHFloat)(0.5 * (f * f * f - f * sin(f * M_PI)));
} else {
AHFloat f = (1 - (2 * p - 1));
return (AHFloat)(0.5 * (1 - (f * f * f - f * sin(f * M_PI))) + 0.5);
}
}
AHFloat BounceEaseIn(AHFloat p)
{
return 1 - BounceEaseOut(1 - p);
}
AHFloat BounceEaseOut(AHFloat p)
{
if (p < 4 / 11.0) {
return (121 * p * p) / 16.0f;
} else if (p < 8 / 11.0) {
return (363 / 40.0f * p * p) - (99 / 10.0f * p) + 17 / 5.0f;
} else if (p < 9 / 10.0) {
return (4356 / 361.0f * p * p) - (35442 / 1805.0f * p) + 16061 / 1805.0f;
} else {
return (54 / 5.0f * p * p) - (513 / 25.0f * p) + 268 / 25.0f;
}
}
AHFloat BounceEaseInOut(AHFloat p)
{
if (p < 0.5) {
return 0.5f * BounceEaseIn(p * 2);
} else {
return 0.5f * BounceEaseOut(p * 2 - 1) + 0.5f;
}
}
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