156 lines
5.3 KiB
GLSL
156 lines
5.3 KiB
GLSL
/* Various sky functions
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* =====================
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*
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* Nishita model is based on https://github.com/wwwtyro/glsl-atmosphere (Unlicense License)
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*
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* Changes to the original implementation:
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* - r and pSun parameters of nishita_atmosphere() are already normalized
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* - Some original parameters of nishita_atmosphere() are replaced with pre-defined values
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* - Implemented air, dust and ozone density node parameters (see Blender source)
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* - Replaced the inner integral calculation with a LUT lookup
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*
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* Reference for the sun's limb darkening and ozone calculations:
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* [Hill] Sebastien Hillaire. Physically Based Sky, Atmosphere and Cloud Rendering in Frostbite
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* (https://media.contentapi.ea.com/content/dam/eacom/frostbite/files/s2016-pbs-frostbite-sky-clouds-new.pdf)
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*
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* Cycles code used for reference: blender/intern/sky/source/sky_nishita.cpp
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* (https://github.com/blender/blender/blob/4429b4b77ef6754739a3c2b4fabd0537999e9bdc/intern/sky/source/sky_nishita.cpp)
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*/
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#ifndef _SKY_GLSL_
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#define _SKY_GLSL_
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#include "std/math.glsl"
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uniform sampler2D nishitaLUT;
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uniform vec2 nishitaDensity;
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#ifndef PI
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#define PI 3.141592
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#endif
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#ifndef HALF_PI
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#define HALF_PI 1.570796
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#endif
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#define nishita_iSteps 16
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// These values are taken from Cycles code if they
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// exist there, otherwise they are taken from the example
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// in the glsl-atmosphere repo
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#define nishita_sun_intensity 22.0
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#define nishita_atmo_radius 6420e3
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#define nishita_rayleigh_scale 8e3
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#define nishita_rayleigh_coeff vec3(5.5e-6, 13.0e-6, 22.4e-6)
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#define nishita_mie_scale 1.2e3
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#define nishita_mie_coeff 2e-5
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#define nishita_mie_dir 0.76 // Aerosols anisotropy ("direction")
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#define nishita_mie_dir_sq 0.5776 // Squared aerosols anisotropy
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// Values from [Hill: 60]
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#define sun_limb_darkening_col vec3(0.397, 0.503, 0.652)
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vec3 nishita_lookupLUT(const float height, const float sunTheta) {
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vec2 coords = vec2(
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sqrt(height * (1 / nishita_atmo_radius)),
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0.5 + 0.5 * sign(sunTheta - HALF_PI) * sqrt(abs(sunTheta * (1 / HALF_PI) - 1))
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);
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return textureLod(nishitaLUT, coords, 0.0).rgb;
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}
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/* See raySphereIntersection() in leenkx/Sources/renderpath/Nishita.hx */
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vec2 nishita_rsi(const vec3 r0, const vec3 rd, const float sr) {
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float a = dot(rd, rd);
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float b = 2.0 * dot(rd, r0);
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float c = dot(r0, r0) - (sr * sr);
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float d = (b*b) - 4.0*a*c;
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// If d < 0.0 the ray does not intersect the sphere
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return (d < 0.0) ? vec2(1e5,-1e5) : vec2((-b - sqrt(d))/(2.0*a), (-b + sqrt(d))/(2.0*a));
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}
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/*
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* r: normalized ray direction
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* r0: ray origin
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* pSun: normalized sun direction
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* rPlanet: planet radius
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*/
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vec3 nishita_atmosphere(const vec3 r, const vec3 r0, const vec3 pSun, const float rPlanet) {
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// Calculate the step size of the primary ray
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vec2 p = nishita_rsi(r0, r, nishita_atmo_radius);
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if (p.x > p.y) return vec3(0.0);
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p.y = min(p.y, nishita_rsi(r0, r, rPlanet).x);
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float iStepSize = (p.y - p.x) / float(nishita_iSteps);
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// Primary ray time
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float iTime = 0.0;
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// Accumulators for Rayleigh and Mie scattering.
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vec3 totalRlh = vec3(0,0,0);
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vec3 totalMie = vec3(0,0,0);
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// Optical depth accumulators for the primary ray
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float iOdRlh = 0.0;
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float iOdMie = 0.0;
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// Calculate the Rayleigh and Mie phases
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float mu = dot(r, pSun);
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float mumu = mu * mu;
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float pRlh = 3.0 / (16.0 * PI) * (1.0 + mumu);
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float pMie = 3.0 / (8.0 * PI) * ((1.0 - nishita_mie_dir_sq) * (mumu + 1.0)) / (pow(1.0 + nishita_mie_dir_sq - 2.0 * mu * nishita_mie_dir, 1.5) * (2.0 + nishita_mie_dir_sq));
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// Sample the primary ray
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for (int i = 0; i < nishita_iSteps; i++) {
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// Calculate the primary ray sample position and height
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vec3 iPos = r0 + r * (iTime + iStepSize * 0.5);
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float iHeight = length(iPos) - rPlanet;
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// Calculate the optical depth of the Rayleigh and Mie scattering for this step
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float odStepRlh = exp(-iHeight / nishita_rayleigh_scale) * nishitaDensity.x * iStepSize;
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float odStepMie = exp(-iHeight / nishita_mie_scale) * nishitaDensity.y * iStepSize;
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// Accumulate optical depth
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iOdRlh += odStepRlh;
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iOdMie += odStepMie;
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// Idea behind this: "Rotate" everything by iPos (-> iPos is the new zenith) and then all calculations for the
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// inner integral only depend on the sample height (iHeight) and sunTheta (angle between sun and new zenith).
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float sunTheta = safe_acos(dot(normalize(iPos), normalize(pSun)));
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vec3 jAttn = nishita_lookupLUT(iHeight, sunTheta);
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// Calculate attenuation
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vec3 iAttn = exp(-(
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nishita_mie_coeff * iOdMie
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+ nishita_rayleigh_coeff * iOdRlh
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// + 0 for ozone
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));
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vec3 attn = iAttn * jAttn;
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// Apply dithering to reduce visible banding
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attn *= 0.98 + rand(r.xy) * 0.04;
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// Accumulate scattering
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totalRlh += odStepRlh * attn;
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totalMie += odStepMie * attn;
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iTime += iStepSize;
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}
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return nishita_sun_intensity * (pRlh * nishita_rayleigh_coeff * totalRlh + pMie * nishita_mie_coeff * totalMie);
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}
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vec3 sun_disk(const vec3 n, const vec3 light_dir, const float disk_size, const float intensity) {
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// Normalized SDF
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float dist = distance(n, light_dir) / disk_size;
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// Darken the edges of the sun
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// [Hill: 28, 60] (according to [Nec96])
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float invDist = 1.0 - dist;
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float mu = sqrt(invDist * invDist);
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vec3 limb_darkening = 1.0 - (1.0 - pow(vec3(mu), sun_limb_darkening_col));
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return 1 + (1.0 - step(1.0, dist)) * nishita_sun_intensity * intensity * limb_darkening;
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}
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#endif
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