pixelplanet/src/ui/Sky.js

/**
 * From example code at:
 * https://github.com/mrdoob/three.js/blob/dev/examples/js/objects/Sky.js
 *
 * Based on "A Practical Analytic Model for Daylight"
 * aka The Preetham Model, the de facto standard analytic skydome model
 * https://www.researchgate.net/publication/220720443_A_Practical_Analytic_Model_for_Daylight
 *
 * First implemented by Simon Wallner
 * http://simonwallner.at/project/atmospheric-scattering/
 *
 * Improved by Martin Upitis
 * http://blenderartists.org/forum/showthread.php?245954-preethams-sky-impementation-HDR
 *
 * Three.js integration by zz85 http://twitter.com/blurspline
*/

/* eslint-disable max-len */

import {
  Vector3,
  Mesh,
  ShaderMaterial,
  BackSide,
  BoxGeometry,
  UniformsUtils,
} from 'three';

export default class Sky extends Mesh {
  static isSky = true;

  constructor() {
    const shader = Sky.SkyShader;
    const material = new ShaderMaterial({
      name: 'SkyShader',
      fragmentShader: shader.fragmentShader,
      vertexShader: shader.vertexShader,
      uniforms: UniformsUtils.clone(shader.uniforms),
      side: BackSide,
      depthWrite: false,
    });
    super(new BoxGeometry(1, 1, 1), material);
  }
}

Sky.SkyShader = {
  uniforms: {
    turbidity: {
      value: 2,
    },
    rayleigh: {
      value: 1,
    },
    mieCoefficient: {
      value: 0.005,
    },
    mieDirectionalG: {
      value: 0.8,
    },
    sunPosition: {
      value: new Vector3(),
    },
    up: {
      value: new Vector3(0, 1, 0),
    },
  },
  vertexShader:
/* glsl */
`
  uniform vec3 sunPosition;
  uniform float rayleigh;
  uniform float turbidity;
  uniform float mieCoefficient;
  uniform vec3 up;

  varying vec3 vWorldPosition;
  varying vec3 vSunDirection;
  varying float vSunfade;
  varying vec3 vBetaR;
  varying vec3 vBetaM;
  varying float vSunE;

  // constants for atmospheric scattering
  const float e = 2.71828182845904523536028747135266249775724709369995957;
  const float pi = 3.141592653589793238462643383279502884197169;

  // wavelength of used primaries, according to preetham
  const vec3 lambda = vec3( 680E-9, 550E-9, 450E-9 );
  // this pre-calculation replaces older TotalRayleigh(vec3 lambda) function:
  // (8.0 * pow(pi, 3.0) * pow(pow(n, 2.0) - 1.0, 2.0) * (6.0 + 3.0 * pn)) / (3.0 * N * pow(lambda, vec3(4.0)) * (6.0 - 7.0 * pn))
  const vec3 totalRayleigh = vec3( 5.804542996261093E-6, 1.3562911419845635E-5, 3.0265902468824876E-5 );

  // mie stuff
  // K coefficient for the primaries
  const float v = 4.0;
  const vec3 K = vec3( 0.686, 0.678, 0.666 );
  // MieConst = pi * pow( ( 2.0 * pi ) / lambda, vec3( v - 2.0 ) ) * K
  const vec3 MieConst = vec3( 1.8399918514433978E14, 2.7798023919660528E14, 4.0790479543861094E14 );

  // earth shadow hack
  // cutoffAngle = pi / 1.95;
  const float cutoffAngle = 1.6110731556870734;
  const float steepness = 1.5;
  const float EE = 1000.0;

  float sunIntensity( float zenithAngleCos ) {
    zenithAngleCos = clamp( zenithAngleCos, -1.0, 1.0 );
    return EE * max( 0.0, 1.0 - pow( e, -( ( cutoffAngle - acos( zenithAngleCos ) ) / steepness ) ) );
  }

  vec3 totalMie( float T ) {
    float c = ( 0.2 * T ) * 10E-18;
    return 0.434 * c * MieConst;
  }

  void main() {

    vec4 worldPosition = modelMatrix * vec4( position, 1.0 );
    vWorldPosition = worldPosition.xyz;

    gl_Position = projectionMatrix * modelViewMatrix * vec4( position, 1.0 );
    gl_Position.z = gl_Position.w; // set z to camera.far

    vSunDirection = normalize( sunPosition );

    vSunE = sunIntensity( dot( vSunDirection, up ) );

    vSunfade = 1.0 - clamp( 1.0 - exp( ( sunPosition.y / 450000.0 ) ), 0.0, 1.0 );

    float rayleighCoefficient = rayleigh - ( 1.0 * ( 1.0 - vSunfade ) );

    // extinction (absorption + out scattering)
    // rayleigh coefficients
    vBetaR = totalRayleigh * rayleighCoefficient;

    // mie coefficients
    vBetaM = totalMie( turbidity ) * mieCoefficient;

  }`,
  fragmentShader:
/* glsl */
`
  varying vec3 vWorldPosition;
  varying vec3 vSunDirection;
  varying float vSunfade;
  varying vec3 vBetaR;
  varying vec3 vBetaM;
  varying float vSunE;

  uniform float mieDirectionalG;
  uniform vec3 up;

  const vec3 cameraPos = vec3( 0.0, 0.0, 0.0 );

  // constants for atmospheric scattering
  const float pi = 3.141592653589793238462643383279502884197169;

  const float n = 1.0003; // refractive index of air
  const float N = 2.545E25; // number of molecules per unit volume for air at 288.15K and 1013mb (sea level -45 celsius)

  // optical length at zenith for molecules
  const float rayleighZenithLength = 8.4E3;
  const float mieZenithLength = 1.25E3;
  // 66 arc seconds -> degrees, and the cosine of that
  const float sunAngularDiameterCos = 0.999956676946448443553574619906976478926848692873900859324;

  // 3.0 / ( 16.0 * pi )
  const float THREE_OVER_SIXTEENPI = 0.05968310365946075;
  // 1.0 / ( 4.0 * pi )
  const float ONE_OVER_FOURPI = 0.07957747154594767;

  float rayleighPhase( float cosTheta ) {
    return THREE_OVER_SIXTEENPI * ( 1.0 + pow( cosTheta, 2.0 ) );
  }

  float hgPhase( float cosTheta, float g ) {
    float g2 = pow( g, 2.0 );
    float inverse = 1.0 / pow( 1.0 - 2.0 * g * cosTheta + g2, 1.5 );
    return ONE_OVER_FOURPI * ( ( 1.0 - g2 ) * inverse );
  }

  void main() {

    vec3 direction = normalize( vWorldPosition - cameraPos );

    // optical length
    // cutoff angle at 90 to avoid singularity in next formula.
    float zenithAngle = acos( max( 0.0, dot( up, direction ) ) );
    float inverse = 1.0 / ( cos( zenithAngle ) + 0.15 * pow( 93.885 - ( ( zenithAngle * 180.0 ) / pi ), -1.253 ) );
    float sR = rayleighZenithLength * inverse;
    float sM = mieZenithLength * inverse;

    // combined extinction factor
    vec3 Fex = exp( -( vBetaR * sR + vBetaM * sM ) );

    // in scattering
    float cosTheta = dot( direction, vSunDirection );

    float rPhase = rayleighPhase( cosTheta * 0.5 + 0.5 );
    vec3 betaRTheta = vBetaR * rPhase;

    float mPhase = hgPhase( cosTheta, mieDirectionalG );
    vec3 betaMTheta = vBetaM * mPhase;

    vec3 Lin = pow( vSunE * ( ( betaRTheta + betaMTheta ) / ( vBetaR + vBetaM ) ) * ( 1.0 - Fex ), vec3( 1.5 ) );
    Lin *= mix( vec3( 1.0 ), pow( vSunE * ( ( betaRTheta + betaMTheta ) / ( vBetaR + vBetaM ) ) * Fex, vec3( 1.0 / 2.0 ) ), clamp( pow( 1.0 - dot( up, vSunDirection ), 5.0 ), 0.0, 1.0 ) );

    // nightsky
    float theta = acos( direction.y ); // elevation --> y-axis, [-pi/2, pi/2]
    float phi = atan( direction.z, direction.x ); // azimuth --> x-axis [-pi/2, pi/2]
    vec2 uv = vec2( phi, theta ) / vec2( 2.0 * pi, pi ) + vec2( 0.5, 0.0 );
    vec3 L0 = vec3( 0.1 ) * Fex;

    // composition + solar disc
    float sundisk = smoothstep( sunAngularDiameterCos, sunAngularDiameterCos + 0.00002, cosTheta );
    L0 += ( vSunE * 19000.0 * Fex ) * sundisk;

    vec3 texColor = ( Lin + L0 ) * 0.04 + vec3( 0.0, 0.0003, 0.00075 );

    vec3 retColor = pow( texColor, vec3( 1.0 / ( 1.2 + ( 1.2 * vSunfade ) ) ) );

    gl_FragColor = vec4( retColor, 1.0 );

    #include <tonemapping_fragment>
    #include <encodings_fragment>

  }`,
};