akella/noise.glsl

## noise.glsl
//
// GLSL textureless classic 3D noise "cnoise",
// with an RSL-style periodic variant "pnoise".
// Author:  Stefan Gustavson (stefan.gustavson@liu.se)
// Version: 2011-10-11
//
// Many thanks to Ian McEwan of Ashima Arts for the
// ideas for permutation and gradient selection.
//
// Copyright (c) 2011 Stefan Gustavson. All rights reserved.
// Distributed under the MIT license. See LICENSE file.
// https://github.com/stegu/webgl-noise
//

vec3 mod289(vec3 x)
{
  return x - floor(x * (1.0 / 289.0)) * 289.0;
}

vec4 mod289(vec4 x)
{
  return x - floor(x * (1.0 / 289.0)) * 289.0;
}

vec4 permute(vec4 x)
{
  return mod289(((x*34.0)+10.0)*x);
}

vec4 taylorInvSqrt(vec4 r)
{
  return 1.79284291400159 - 0.85373472095314 * r;
}

vec3 fade(vec3 t) {
  return t*t*t*(t*(t*6.0-15.0)+10.0);
}

// Classic Perlin noise
float cnoise(vec3 P)
{
  vec3 Pi0 = floor(P); // Integer part for indexing
  vec3 Pi1 = Pi0 + vec3(1.0); // Integer part + 1
  Pi0 = mod289(Pi0);
  Pi1 = mod289(Pi1);
  vec3 Pf0 = fract(P); // Fractional part for interpolation
  vec3 Pf1 = Pf0 - vec3(1.0); // Fractional part - 1.0
  vec4 ix = vec4(Pi0.x, Pi1.x, Pi0.x, Pi1.x);
  vec4 iy = vec4(Pi0.yy, Pi1.yy);
  vec4 iz0 = Pi0.zzzz;
  vec4 iz1 = Pi1.zzzz;

  vec4 ixy = permute(permute(ix) + iy);
  vec4 ixy0 = permute(ixy + iz0);
  vec4 ixy1 = permute(ixy + iz1);

  vec4 gx0 = ixy0 * (1.0 / 7.0);
  vec4 gy0 = fract(floor(gx0) * (1.0 / 7.0)) - 0.5;
  gx0 = fract(gx0);
  vec4 gz0 = vec4(0.5) - abs(gx0) - abs(gy0);
  vec4 sz0 = step(gz0, vec4(0.0));
  gx0 -= sz0 * (step(0.0, gx0) - 0.5);
  gy0 -= sz0 * (step(0.0, gy0) - 0.5);

  vec4 gx1 = ixy1 * (1.0 / 7.0);
  vec4 gy1 = fract(floor(gx1) * (1.0 / 7.0)) - 0.5;
  gx1 = fract(gx1);
  vec4 gz1 = vec4(0.5) - abs(gx1) - abs(gy1);
  vec4 sz1 = step(gz1, vec4(0.0));
  gx1 -= sz1 * (step(0.0, gx1) - 0.5);
  gy1 -= sz1 * (step(0.0, gy1) - 0.5);

  vec3 g000 = vec3(gx0.x,gy0.x,gz0.x);
  vec3 g100 = vec3(gx0.y,gy0.y,gz0.y);
  vec3 g010 = vec3(gx0.z,gy0.z,gz0.z);
  vec3 g110 = vec3(gx0.w,gy0.w,gz0.w);
  vec3 g001 = vec3(gx1.x,gy1.x,gz1.x);
  vec3 g101 = vec3(gx1.y,gy1.y,gz1.y);
  vec3 g011 = vec3(gx1.z,gy1.z,gz1.z);
  vec3 g111 = vec3(gx1.w,gy1.w,gz1.w);

  vec4 norm0 = taylorInvSqrt(vec4(dot(g000, g000), dot(g010, g010), dot(g100, g100), dot(g110, g110)));
  g000 *= norm0.x;
  g010 *= norm0.y;
  g100 *= norm0.z;
  g110 *= norm0.w;
  vec4 norm1 = taylorInvSqrt(vec4(dot(g001, g001), dot(g011, g011), dot(g101, g101), dot(g111, g111)));
  g001 *= norm1.x;
  g011 *= norm1.y;
  g101 *= norm1.z;
  g111 *= norm1.w;

  float n000 = dot(g000, Pf0);
  float n100 = dot(g100, vec3(Pf1.x, Pf0.yz));
  float n010 = dot(g010, vec3(Pf0.x, Pf1.y, Pf0.z));
  float n110 = dot(g110, vec3(Pf1.xy, Pf0.z));
  float n001 = dot(g001, vec3(Pf0.xy, Pf1.z));
  float n101 = dot(g101, vec3(Pf1.x, Pf0.y, Pf1.z));
  float n011 = dot(g011, vec3(Pf0.x, Pf1.yz));
  float n111 = dot(g111, Pf1);

  vec3 fade_xyz = fade(Pf0);
  vec4 n_z = mix(vec4(n000, n100, n010, n110), vec4(n001, n101, n011, n111), fade_xyz.z);
  vec2 n_yz = mix(n_z.xy, n_z.zw, fade_xyz.y);
  float n_xyz = mix(n_yz.x, n_yz.y, fade_xyz.x);
  return 2.2 * n_xyz;
}

// Classic Perlin noise, periodic variant
float pnoise(vec3 P, vec3 rep)
{
  vec3 Pi0 = mod(floor(P), rep); // Integer part, modulo period
  vec3 Pi1 = mod(Pi0 + vec3(1.0), rep); // Integer part + 1, mod period
  Pi0 = mod289(Pi0);
  Pi1 = mod289(Pi1);
  vec3 Pf0 = fract(P); // Fractional part for interpolation
  vec3 Pf1 = Pf0 - vec3(1.0); // Fractional part - 1.0
  vec4 ix = vec4(Pi0.x, Pi1.x, Pi0.x, Pi1.x);
  vec4 iy = vec4(Pi0.yy, Pi1.yy);
  vec4 iz0 = Pi0.zzzz;
  vec4 iz1 = Pi1.zzzz;

  vec4 ixy = permute(permute(ix) + iy);
  vec4 ixy0 = permute(ixy + iz0);
  vec4 ixy1 = permute(ixy + iz1);

  vec4 gx0 = ixy0 * (1.0 / 7.0);
  vec4 gy0 = fract(floor(gx0) * (1.0 / 7.0)) - 0.5;
  gx0 = fract(gx0);
  vec4 gz0 = vec4(0.5) - abs(gx0) - abs(gy0);
  vec4 sz0 = step(gz0, vec4(0.0));
  gx0 -= sz0 * (step(0.0, gx0) - 0.5);
  gy0 -= sz0 * (step(0.0, gy0) - 0.5);

  vec4 gx1 = ixy1 * (1.0 / 7.0);
  vec4 gy1 = fract(floor(gx1) * (1.0 / 7.0)) - 0.5;
  gx1 = fract(gx1);
  vec4 gz1 = vec4(0.5) - abs(gx1) - abs(gy1);
  vec4 sz1 = step(gz1, vec4(0.0));
  gx1 -= sz1 * (step(0.0, gx1) - 0.5);
  gy1 -= sz1 * (step(0.0, gy1) - 0.5);

  vec3 g000 = vec3(gx0.x,gy0.x,gz0.x);
  vec3 g100 = vec3(gx0.y,gy0.y,gz0.y);
  vec3 g010 = vec3(gx0.z,gy0.z,gz0.z);
  vec3 g110 = vec3(gx0.w,gy0.w,gz0.w);
  vec3 g001 = vec3(gx1.x,gy1.x,gz1.x);
  vec3 g101 = vec3(gx1.y,gy1.y,gz1.y);
  vec3 g011 = vec3(gx1.z,gy1.z,gz1.z);
  vec3 g111 = vec3(gx1.w,gy1.w,gz1.w);

  vec4 norm0 = taylorInvSqrt(vec4(dot(g000, g000), dot(g010, g010), dot(g100, g100), dot(g110, g110)));
  g000 *= norm0.x;
  g010 *= norm0.y;
  g100 *= norm0.z;
  g110 *= norm0.w;
  vec4 norm1 = taylorInvSqrt(vec4(dot(g001, g001), dot(g011, g011), dot(g101, g101), dot(g111, g111)));
  g001 *= norm1.x;
  g011 *= norm1.y;
  g101 *= norm1.z;
  g111 *= norm1.w;

  float n000 = dot(g000, Pf0);
  float n100 = dot(g100, vec3(Pf1.x, Pf0.yz));
  float n010 = dot(g010, vec3(Pf0.x, Pf1.y, Pf0.z));
  float n110 = dot(g110, vec3(Pf1.xy, Pf0.z));
  float n001 = dot(g001, vec3(Pf0.xy, Pf1.z));
  float n101 = dot(g101, vec3(Pf1.x, Pf0.y, Pf1.z));
  float n011 = dot(g011, vec3(Pf0.x, Pf1.yz));
  float n111 = dot(g111, Pf1);

  vec3 fade_xyz = fade(Pf0);
  vec4 n_z = mix(vec4(n000, n100, n010, n110), vec4(n001, n101, n011, n111), fade_xyz.z);
  vec2 n_yz = mix(n_z.xy, n_z.zw, fade_xyz.y);
  float n_xyz = mix(n_yz.x, n_yz.y, fade_xyz.x);
  return 2.2 * n_xyz;
}


mat3 rotation3dY(float angle) {
  float s = sin(angle);
  float c = cos(angle);

  return mat3(
    c, 0.0, -s,
    0.0, 1.0, 0.0,
    s, 0.0, c
  );
}

float saturate(float x)
{
  return clamp(x, 0.0, 1.0);
}

vec3 curl_noise(vec3 p)
{

  // return curlNoise(p);
  const float step = 0.01;
  float ddx = cnoise(p+vec3(step, 0.0, 0.0)) - cnoise(p-vec3(step, 0.0, 0.0));
  float ddy = cnoise(p+vec3(0.0, step, 0.0)) - cnoise(p-vec3(0.0, step, 0.0));
  float ddz = cnoise(p+vec3(0.0, 0.0, step)) - cnoise(p-vec3(0.0, 0.0, step));

  const float divisor = 1.0 / ( 2.0 * step );
  return ( vec3(ddy - ddz, ddz - ddx, ddx - ddy) * divisor );
}

vec3 fbm_vec3(vec3 p, float frequency, float offset)
{
  return vec3(
    cnoise((p+vec3(offset))*frequency),
    cnoise((p+vec3(offset+20.0))*frequency),
    cnoise((p+vec3(offset-30.0))*frequency)
  );
}
	//
	// GLSL textureless classic 3D noise "cnoise",
	// with an RSL-style periodic variant "pnoise".
	// Author: Stefan Gustavson (stefan.gustavson@liu.se)
	// Version: 2011-10-11
	//
	// Many thanks to Ian McEwan of Ashima Arts for the
	// ideas for permutation and gradient selection.
	//
	// Copyright (c) 2011 Stefan Gustavson. All rights reserved.
	// Distributed under the MIT license. See LICENSE file.
	// https://github.com/stegu/webgl-noise
	//

	vec3 mod289(vec3 x)
	{
	return x - floor(x * (1.0 / 289.0)) * 289.0;
	}

	vec4 mod289(vec4 x)
	{
	return x - floor(x * (1.0 / 289.0)) * 289.0;
	}

	vec4 permute(vec4 x)
	{
	return mod289(((x34.0)+10.0)x);
	}

	vec4 taylorInvSqrt(vec4 r)
	{
	return 1.79284291400159 - 0.85373472095314 * r;
	}

	vec3 fade(vec3 t) {
	return ttt(t(t*6.0-15.0)+10.0);
	}

	// Classic Perlin noise
	float cnoise(vec3 P)
	{
	vec3 Pi0 = floor(P); // Integer part for indexing
	vec3 Pi1 = Pi0 + vec3(1.0); // Integer part + 1
	Pi0 = mod289(Pi0);
	Pi1 = mod289(Pi1);
	vec3 Pf0 = fract(P); // Fractional part for interpolation
	vec3 Pf1 = Pf0 - vec3(1.0); // Fractional part - 1.0
	vec4 ix = vec4(Pi0.x, Pi1.x, Pi0.x, Pi1.x);
	vec4 iy = vec4(Pi0.yy, Pi1.yy);
	vec4 iz0 = Pi0.zzzz;
	vec4 iz1 = Pi1.zzzz;

	vec4 ixy = permute(permute(ix) + iy);
	vec4 ixy0 = permute(ixy + iz0);
	vec4 ixy1 = permute(ixy + iz1);

	vec4 gx0 = ixy0 * (1.0 / 7.0);
	vec4 gy0 = fract(floor(gx0) * (1.0 / 7.0)) - 0.5;
	gx0 = fract(gx0);
	vec4 gz0 = vec4(0.5) - abs(gx0) - abs(gy0);
	vec4 sz0 = step(gz0, vec4(0.0));
	gx0 -= sz0 * (step(0.0, gx0) - 0.5);
	gy0 -= sz0 * (step(0.0, gy0) - 0.5);

	vec4 gx1 = ixy1 * (1.0 / 7.0);
	vec4 gy1 = fract(floor(gx1) * (1.0 / 7.0)) - 0.5;
	gx1 = fract(gx1);
	vec4 gz1 = vec4(0.5) - abs(gx1) - abs(gy1);
	vec4 sz1 = step(gz1, vec4(0.0));
	gx1 -= sz1 * (step(0.0, gx1) - 0.5);
	gy1 -= sz1 * (step(0.0, gy1) - 0.5);

	vec3 g000 = vec3(gx0.x,gy0.x,gz0.x);
	vec3 g100 = vec3(gx0.y,gy0.y,gz0.y);
	vec3 g010 = vec3(gx0.z,gy0.z,gz0.z);
	vec3 g110 = vec3(gx0.w,gy0.w,gz0.w);
	vec3 g001 = vec3(gx1.x,gy1.x,gz1.x);
	vec3 g101 = vec3(gx1.y,gy1.y,gz1.y);
	vec3 g011 = vec3(gx1.z,gy1.z,gz1.z);
	vec3 g111 = vec3(gx1.w,gy1.w,gz1.w);

	vec4 norm0 = taylorInvSqrt(vec4(dot(g000, g000), dot(g010, g010), dot(g100, g100), dot(g110, g110)));
	g000 *= norm0.x;
	g010 *= norm0.y;
	g100 *= norm0.z;
	g110 *= norm0.w;
	vec4 norm1 = taylorInvSqrt(vec4(dot(g001, g001), dot(g011, g011), dot(g101, g101), dot(g111, g111)));
	g001 *= norm1.x;
	g011 *= norm1.y;
	g101 *= norm1.z;
	g111 *= norm1.w;

	float n000 = dot(g000, Pf0);
	float n100 = dot(g100, vec3(Pf1.x, Pf0.yz));
	float n010 = dot(g010, vec3(Pf0.x, Pf1.y, Pf0.z));
	float n110 = dot(g110, vec3(Pf1.xy, Pf0.z));
	float n001 = dot(g001, vec3(Pf0.xy, Pf1.z));
	float n101 = dot(g101, vec3(Pf1.x, Pf0.y, Pf1.z));
	float n011 = dot(g011, vec3(Pf0.x, Pf1.yz));
	float n111 = dot(g111, Pf1);

	vec3 fade_xyz = fade(Pf0);
	vec4 n_z = mix(vec4(n000, n100, n010, n110), vec4(n001, n101, n011, n111), fade_xyz.z);
	vec2 n_yz = mix(n_z.xy, n_z.zw, fade_xyz.y);
	float n_xyz = mix(n_yz.x, n_yz.y, fade_xyz.x);
	return 2.2 * n_xyz;
	}

	// Classic Perlin noise, periodic variant
	float pnoise(vec3 P, vec3 rep)
	{
	vec3 Pi0 = mod(floor(P), rep); // Integer part, modulo period
	vec3 Pi1 = mod(Pi0 + vec3(1.0), rep); // Integer part + 1, mod period
	Pi0 = mod289(Pi0);
	Pi1 = mod289(Pi1);
	vec3 Pf0 = fract(P); // Fractional part for interpolation
	vec3 Pf1 = Pf0 - vec3(1.0); // Fractional part - 1.0
	vec4 ix = vec4(Pi0.x, Pi1.x, Pi0.x, Pi1.x);
	vec4 iy = vec4(Pi0.yy, Pi1.yy);
	vec4 iz0 = Pi0.zzzz;
	vec4 iz1 = Pi1.zzzz;

	vec4 ixy = permute(permute(ix) + iy);
	vec4 ixy0 = permute(ixy + iz0);
	vec4 ixy1 = permute(ixy + iz1);

	vec4 gx0 = ixy0 * (1.0 / 7.0);
	vec4 gy0 = fract(floor(gx0) * (1.0 / 7.0)) - 0.5;
	gx0 = fract(gx0);
	vec4 gz0 = vec4(0.5) - abs(gx0) - abs(gy0);
	vec4 sz0 = step(gz0, vec4(0.0));
	gx0 -= sz0 * (step(0.0, gx0) - 0.5);
	gy0 -= sz0 * (step(0.0, gy0) - 0.5);

	vec4 gx1 = ixy1 * (1.0 / 7.0);
	vec4 gy1 = fract(floor(gx1) * (1.0 / 7.0)) - 0.5;
	gx1 = fract(gx1);
	vec4 gz1 = vec4(0.5) - abs(gx1) - abs(gy1);
	vec4 sz1 = step(gz1, vec4(0.0));
	gx1 -= sz1 * (step(0.0, gx1) - 0.5);
	gy1 -= sz1 * (step(0.0, gy1) - 0.5);

	vec3 g000 = vec3(gx0.x,gy0.x,gz0.x);
	vec3 g100 = vec3(gx0.y,gy0.y,gz0.y);
	vec3 g010 = vec3(gx0.z,gy0.z,gz0.z);
	vec3 g110 = vec3(gx0.w,gy0.w,gz0.w);
	vec3 g001 = vec3(gx1.x,gy1.x,gz1.x);
	vec3 g101 = vec3(gx1.y,gy1.y,gz1.y);
	vec3 g011 = vec3(gx1.z,gy1.z,gz1.z);
	vec3 g111 = vec3(gx1.w,gy1.w,gz1.w);

	vec4 norm0 = taylorInvSqrt(vec4(dot(g000, g000), dot(g010, g010), dot(g100, g100), dot(g110, g110)));
	g000 *= norm0.x;
	g010 *= norm0.y;
	g100 *= norm0.z;
	g110 *= norm0.w;
	vec4 norm1 = taylorInvSqrt(vec4(dot(g001, g001), dot(g011, g011), dot(g101, g101), dot(g111, g111)));
	g001 *= norm1.x;
	g011 *= norm1.y;
	g101 *= norm1.z;
	g111 *= norm1.w;

	float n000 = dot(g000, Pf0);
	float n100 = dot(g100, vec3(Pf1.x, Pf0.yz));
	float n010 = dot(g010, vec3(Pf0.x, Pf1.y, Pf0.z));
	float n110 = dot(g110, vec3(Pf1.xy, Pf0.z));
	float n001 = dot(g001, vec3(Pf0.xy, Pf1.z));
	float n101 = dot(g101, vec3(Pf1.x, Pf0.y, Pf1.z));
	float n011 = dot(g011, vec3(Pf0.x, Pf1.yz));
	float n111 = dot(g111, Pf1);

	vec3 fade_xyz = fade(Pf0);
	vec4 n_z = mix(vec4(n000, n100, n010, n110), vec4(n001, n101, n011, n111), fade_xyz.z);
	vec2 n_yz = mix(n_z.xy, n_z.zw, fade_xyz.y);
	float n_xyz = mix(n_yz.x, n_yz.y, fade_xyz.x);
	return 2.2 * n_xyz;
	}


	mat3 rotation3dY(float angle) {
	float s = sin(angle);
	float c = cos(angle);

	return mat3(
	c, 0.0, -s,
	0.0, 1.0, 0.0,
	s, 0.0, c
	);
	}

	float saturate(float x)
	{
	return clamp(x, 0.0, 1.0);
	}

	vec3 curl_noise(vec3 p)
	{

	// return curlNoise(p);
	const float step = 0.01;
	float ddx = cnoise(p+vec3(step, 0.0, 0.0)) - cnoise(p-vec3(step, 0.0, 0.0));
	float ddy = cnoise(p+vec3(0.0, step, 0.0)) - cnoise(p-vec3(0.0, step, 0.0));
	float ddz = cnoise(p+vec3(0.0, 0.0, step)) - cnoise(p-vec3(0.0, 0.0, step));

	const float divisor = 1.0 / ( 2.0 * step );
	return ( vec3(ddy - ddz, ddz - ddx, ddx - ddy) * divisor );
	}

	vec3 fbm_vec3(vec3 p, float frequency, float offset)
	{
	return vec3(
	cnoise((p+vec3(offset))*frequency),
	cnoise((p+vec3(offset+20.0))*frequency),
	cnoise((p+vec3(offset-30.0))*frequency)
	);
	}