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434 行
18 KiB
434 行
18 KiB
#ifndef UNITY_COMMON_LIGHTING_INCLUDED
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#define UNITY_COMMON_LIGHTING_INCLUDED
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// These clamping function to max of floating point 16 bit are use to prevent INF in code in case of extreme value
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TEMPLATE_1_REAL(ClampToFloat16Max, value, return min(value, HALF_MAX))
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// Ligthing convention
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// Light direction is oriented backward (-Z). i.e in shader code, light direction is -lightData.forward
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//-----------------------------------------------------------------------------
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// Helper functions
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//-----------------------------------------------------------------------------
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// Performs the mapping of the vector 'v' centered within the axis-aligned cube
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// of dimensions [-1, 1]^3 to a vector centered within the unit sphere.
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// The function expects 'v' to be within the cube (possibly unexpected results otherwise).
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// Ref: http://mathproofs.blogspot.com/2005/07/mapping-cube-to-sphere.html
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real3 MapCubeToSphere(real3 v)
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{
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real3 v2 = v * v;
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real2 vr3 = v2.xy * rcp(3.0);
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return v * sqrt((real3)1.0 - 0.5 * v2.yzx - 0.5 * v2.zxy + vr3.yxx * v2.zzy);
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}
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// Computes the squared magnitude of the vector computed by MapCubeToSphere().
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real ComputeCubeToSphereMapSqMagnitude(real3 v)
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{
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real3 v2 = v * v;
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// Note: dot(v, v) is often computed before this function is called,
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// so the compiler should optimize and use the precomputed result here.
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return dot(v, v) - v2.x * v2.y - v2.y * v2.z - v2.z * v2.x + v2.x * v2.y * v2.z;
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}
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// texelArea = 4.0 / (resolution * resolution).
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// Ref: http://bpeers.com/blog/?itemid=1017
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// This version is less accurate, but much faster than this one:
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// http://www.rorydriscoll.com/2012/01/15/cubemap-texel-solid-angle/
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real ComputeCubemapTexelSolidAngle(real3 L, real texelArea)
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{
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// Stretch 'L' by (1/d) so that it points at a side of a [-1, 1]^2 cube.
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real d = Max3(abs(L.x), abs(L.y), abs(L.z));
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// Since 'L' is a unit vector, we can directly compute its
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// new (inverse) length without dividing 'L' by 'd' first.
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real invDist = d;
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// dw = dA * cosTheta / (dist * dist), cosTheta = 1.0 / dist,
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// where 'dA' is the area of the cube map texel.
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return texelArea * invDist * invDist * invDist;
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}
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// Only makes sense for Monte-Carlo integration.
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// Normalize by dividing by the total weight (or the number of samples) in the end.
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// Integrate[6*(u^2+v^2+1)^(-3/2), {u,-1,1},{v,-1,1}] = 4 * Pi
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// Ref: "Stupid Spherical Harmonics Tricks", p. 9.
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real ComputeCubemapTexelSolidAngle(real2 uv)
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{
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float u = uv.x, v = uv.y;
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return pow(1 + u * u + v * v, -1.5);
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}
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real ConvertEvToLuminance(real ev)
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{
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return exp2(ev - 3.0);
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}
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real ConvertLuminanceToEv(real luminance)
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{
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real k = 12.5f;
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return log2((luminance * 100.0) / k);
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}
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//-----------------------------------------------------------------------------
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// Attenuation functions
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//-----------------------------------------------------------------------------
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// Ref: Moving Frostbite to PBR.
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// Non physically based hack to limit light influence to attenuationRadius.
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// Square the result to smoothen the function.
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real DistanceWindowing(real distSquare, real rangeAttenuationScale, real rangeAttenuationBias)
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{
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// If (range attenuation is enabled)
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// rangeAttenuationScale = 1 / r^2
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// rangeAttenuationBias = 1
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// Else
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// rangeAttenuationScale = 2^12 / r^2
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// rangeAttenuationBias = 2^24
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return saturate(rangeAttenuationBias - Sq(distSquare * rangeAttenuationScale));
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}
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real SmoothDistanceWindowing(real distSquare, real rangeAttenuationScale, real rangeAttenuationBias)
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{
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real factor = DistanceWindowing(distSquare, rangeAttenuationScale, rangeAttenuationBias);
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return Sq(factor);
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}
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#define PUNCTUAL_LIGHT_THRESHOLD 0.01 // 1cm (in Unity 1 is 1m)
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// Return physically based quadratic attenuation + influence limit to reach 0 at attenuationRadius
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real SmoothWindowedDistanceAttenuation(real distSquare, real distRcp, real rangeAttenuationScale, real rangeAttenuationBias)
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{
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real attenuation = min(distRcp, 1.0 / PUNCTUAL_LIGHT_THRESHOLD);
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attenuation *= DistanceWindowing(distSquare, rangeAttenuationScale, rangeAttenuationBias);
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// Effectively results in (distRcp)^2 * SmoothDistanceWindowing(...).
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return Sq(attenuation);
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}
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// Square the result to smoothen the function.
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real AngleAttenuation(real cosFwd, real lightAngleScale, real lightAngleOffset)
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{
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return saturate(cosFwd * lightAngleScale + lightAngleOffset);
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}
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real SmoothAngleAttenuation(real cosFwd, real lightAngleScale, real lightAngleOffset)
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{
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real attenuation = AngleAttenuation(cosFwd, lightAngleScale, lightAngleOffset);
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return Sq(attenuation);
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}
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// Combines SmoothWindowedDistanceAttenuation() and SmoothAngleAttenuation() in an efficient manner.
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// distances = {d, d^2, 1/d, d_proj}, where d_proj = dot(lightToSample, lightData.forward).
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real PunctualLightAttenuation(real4 distances, real rangeAttenuationScale, real rangeAttenuationBias,
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real lightAngleScale, real lightAngleOffset)
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{
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real distSq = distances.y;
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real distRcp = distances.z;
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real distProj = distances.w;
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real cosFwd = distProj * distRcp;
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real attenuation = min(distRcp, 1.0 / PUNCTUAL_LIGHT_THRESHOLD);
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attenuation *= DistanceWindowing(distSq, rangeAttenuationScale, rangeAttenuationBias);
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attenuation *= AngleAttenuation(cosFwd, lightAngleScale, lightAngleOffset);
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// Effectively results in SmoothWindowedDistanceAttenuation(...) * SmoothAngleAttenuation(...).
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return Sq(attenuation);
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}
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// Applies SmoothDistanceWindowing() after transforming the attenuation ellipsoid into a sphere.
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// If r = rsqrt(invSqRadius), then the ellipsoid is defined s.t. r1 = r / invAspectRatio, r2 = r3 = r.
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// The transformation is performed along the major axis of the ellipsoid (corresponding to 'r1').
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// Both the ellipsoid (e.i. 'axis') and 'unL' should be in the same coordinate system.
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// 'unL' should be computed from the center of the ellipsoid.
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real EllipsoidalDistanceAttenuation(real3 unL, real3 axis, real invAspectRatio,
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real rangeAttenuationScale, real rangeAttenuationBias)
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{
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// Project the unnormalized light vector onto the axis.
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real projL = dot(unL, axis);
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// Transform the light vector so that we can work with
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// with the ellipsoid as if it was a sphere with the radius of light's range.
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real diff = projL - projL * invAspectRatio;
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unL -= diff * axis;
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real sqDist = dot(unL, unL);
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return SmoothDistanceWindowing(sqDist, rangeAttenuationScale, rangeAttenuationBias);
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}
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// Applies SmoothDistanceWindowing() using the axis-aligned ellipsoid of the given dimensions.
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// Both the ellipsoid and 'unL' should be in the same coordinate system.
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// 'unL' should be computed from the center of the ellipsoid.
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real EllipsoidalDistanceAttenuation(real3 unL, real3 invHalfDim,
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real rangeAttenuationScale, real rangeAttenuationBias)
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{
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// Transform the light vector so that we can work with
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// with the ellipsoid as if it was a unit sphere.
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unL *= invHalfDim;
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real sqDist = dot(unL, unL);
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return SmoothDistanceWindowing(sqDist, rangeAttenuationScale, rangeAttenuationBias);
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}
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// Applies SmoothDistanceWindowing() after mapping the axis-aligned box to a sphere.
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// If the diagonal of the box is 'd', invHalfDim = rcp(0.5 * d).
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// Both the box and 'unL' should be in the same coordinate system.
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// 'unL' should be computed from the center of the box.
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real BoxDistanceAttenuation(real3 unL, real3 invHalfDim,
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real rangeAttenuationScale, real rangeAttenuationBias)
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{
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float attenuation = 0.0;
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// Transform the light vector so that we can work with
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// with the box as if it was a [-1, 1]^2 cube.
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unL *= invHalfDim;
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// Our algorithm expects the input vector to be within the cube.
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if (!(Max3(abs(unL.x), abs(unL.y), abs(unL.z)) > 1.0))
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{
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real sqDist = ComputeCubeToSphereMapSqMagnitude(unL);
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attenuation = SmoothDistanceWindowing(sqDist, rangeAttenuationScale, rangeAttenuationBias);
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}
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return attenuation;
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}
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//-----------------------------------------------------------------------------
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// IES Helper
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//-----------------------------------------------------------------------------
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real2 GetIESTextureCoordinate(real3x3 lightToWord, real3 L)
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{
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// IES need to be sample in light space
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real3 dir = mul(lightToWord, -L); // Using matrix on left side do a transpose
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// convert to spherical coordinate
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real2 sphericalCoord; // .x is theta, .y is phi
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// Texture is encoded with cos(phi), scale from -1..1 to 0..1
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sphericalCoord.y = (dir.z * 0.5) + 0.5;
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real theta = atan2(dir.y, dir.x);
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sphericalCoord.x = theta * INV_TWO_PI;
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return sphericalCoord;
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}
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//-----------------------------------------------------------------------------
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// Lighting functions
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//-----------------------------------------------------------------------------
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// Ref: Horizon Occlusion for Normal Mapped Reflections: http://marmosetco.tumblr.com/post/81245981087
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real GetHorizonOcclusion(real3 V, real3 normalWS, real3 vertexNormal, real horizonFade)
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{
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real3 R = reflect(-V, normalWS);
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real specularOcclusion = saturate(1.0 + horizonFade * dot(R, vertexNormal));
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// smooth it
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return specularOcclusion * specularOcclusion;
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}
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// Ref: Moving Frostbite to PBR - Gotanda siggraph 2011
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// Return specular occlusion based on ambient occlusion (usually get from SSAO) and view/roughness info
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real GetSpecularOcclusionFromAmbientOcclusion(real NdotV, real ambientOcclusion, real roughness)
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{
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return saturate(PositivePow(NdotV + ambientOcclusion, exp2(-16.0 * roughness - 1.0)) - 1.0 + ambientOcclusion);
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}
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// ref: Practical Realtime Strategies for Accurate Indirect Occlusion
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// Update ambient occlusion to colored ambient occlusion based on statitics of how light is bouncing in an object and with the albedo of the object
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real3 GTAOMultiBounce(real visibility, real3 albedo)
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{
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real3 a = 2.0404 * albedo - 0.3324;
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real3 b = -4.7951 * albedo + 0.6417;
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real3 c = 2.7552 * albedo + 0.6903;
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real x = visibility;
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return max(x, ((x * a + b) * x + c) * x);
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}
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// Based on Oat and Sander's 2008 technique
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// Area/solidAngle of intersection of two cone
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real SphericalCapIntersectionSolidArea(real cosC1, real cosC2, real cosB)
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{
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real r1 = FastACos(cosC1);
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real r2 = FastACos(cosC2);
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real rd = FastACos(cosB);
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real area = 0.0;
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if (rd <= max(r1, r2) - min(r1, r2))
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{
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// One cap is completely inside the other
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area = TWO_PI - TWO_PI * max(cosC1, cosC2);
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}
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else if (rd >= r1 + r2)
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{
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// No intersection exists
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area = 0.0;
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}
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else
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{
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real diff = abs(r1 - r2);
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real den = r1 + r2 - diff;
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real x = 1.0 - saturate((rd - diff) / max(den, 0.0001));
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area = smoothstep(0.0, 1.0, x);
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area *= TWO_PI - TWO_PI * max(cosC1, cosC2);
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}
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return area;
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}
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// ref: Practical Realtime Strategies for Accurate Indirect Occlusion
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// http://blog.selfshadow.com/publications/s2016-shading-course/#course_content
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// Original Cone-Cone method with cosine weighted assumption (p129 s2016_pbs_activision_occlusion)
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real GetSpecularOcclusionFromBentAO(real3 V, real3 bentNormalWS, real3 normalWS, real ambientOcclusion, real roughness)
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{
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// Retrieve cone angle
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// Ambient occlusion is cosine weighted, thus use following equation. See slide 129
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real cosAv = sqrt(1.0 - ambientOcclusion);
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roughness = max(roughness, 0.01); // Clamp to 0.01 to avoid edge cases
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real cosAs = exp2((-log(10.0) / log(2.0)) * Sq(roughness));
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real cosB = dot(bentNormalWS, reflect(-V, normalWS));
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return SphericalCapIntersectionSolidArea(cosAv, cosAs, cosB) / (TWO_PI * (1.0 - cosAs));
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}
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// Ref: Steve McAuley - Energy-Conserving Wrapped Diffuse
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real ComputeWrappedDiffuseLighting(real NdotL, real w)
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{
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return saturate((NdotL + w) / ((1.0 + w) * (1.0 + w)));
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}
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// Jimenez variant for eye
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real ComputeWrappedPowerDiffuseLighting(real NdotL, real w, real p)
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{
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return pow(saturate((NdotL + w) / (1.0 + w)), p) * (p + 1) / (w * 2.0 + 2.0);
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}
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// Ref: The Technical Art of Uncharted 4 - Brinck and Maximov 2016
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real ComputeMicroShadowing(real AO, real NdotL, real opacity)
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{
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real aperture = 2.0 * AO * AO;
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real microshadow = saturate(NdotL + aperture - 1.0);
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return lerp(1.0, microshadow, opacity);
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}
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real3 ComputeShadowColor(real shadow, real3 shadowTint)
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{
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return float3(1.0, 1.0, 1.0) - ((1.0 - shadow) * (float3(1.0, 1.0, 1.0) - shadowTint));
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}
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//-----------------------------------------------------------------------------
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// Helper functions
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//-----------------------------------------------------------------------------
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// Ref: "Crafting a Next-Gen Material Pipeline for The Order: 1886".
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float ClampNdotV(float NdotV)
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{
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return max(NdotV, 0.0001); // Approximately 0.0057 degree bias
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}
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// Helper function to return a set of common angle used when evaluating BSDF
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// NdotL and NdotV are unclamped
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void GetBSDFAngle(float3 V, float3 L, float NdotL, float NdotV,
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out float LdotV, out float NdotH, out float LdotH, out float invLenLV)
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{
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// Optimized math. Ref: PBR Diffuse Lighting for GGX + Smith Microsurfaces (slide 114).
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LdotV = dot(L, V);
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invLenLV = rsqrt(max(2.0 * LdotV + 2.0, FLT_EPS)); // invLenLV = rcp(length(L + V)), clamp to avoid rsqrt(0) = inf, inf * 0 = NaN
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NdotH = saturate((NdotL + NdotV) * invLenLV);
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LdotH = saturate(invLenLV * LdotV + invLenLV);
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}
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// Inputs: normalized normal and view vectors.
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// Outputs: front-facing normal, and the new non-negative value of the cosine of the view angle.
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// Important: call Orthonormalize() on the tangent and recompute the bitangent afterwards.
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real3 GetViewReflectedNormal(real3 N, real3 V, out real NdotV)
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{
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// Fragments of front-facing geometry can have back-facing normals due to interpolation,
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// normal mapping and decals. This can cause visible artifacts from both direct (negative or
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// extremely high values) and indirect (incorrect lookup direction) lighting.
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// There are several ways to avoid this problem. To list a few:
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//
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// 1. Setting { NdotV = max(<N,V>, SMALL_VALUE) }. This effectively removes normal mapping
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// from the affected fragments, making the surface appear flat.
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//
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// 2. Setting { NdotV = abs(<N,V>) }. This effectively reverses the convexity of the surface.
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// It also reduces light leaking from non-shadow-casting lights. Note that 'NdotV' can still
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// be 0 in this case.
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//
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// It's important to understand that simply changing the value of the cosine is insufficient.
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// For one, it does not solve the incorrect lookup direction problem, since the normal itself
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// is not modified. There is a more insidious issue, however. 'NdotV' is a constituent element
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// of the mathematical system describing the relationships between different vectors - and
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// not just normal and view vectors, but also light vectors, half vectors, tangent vectors, etc.
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// Changing only one angle (or its cosine) leaves the system in an inconsistent state, where
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// certain relationships can take on different values depending on whether 'NdotV' is used
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// in the calculation or not. Therefore, it is important to change the normal (or another
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// vector) in order to leave the system in a consistent state.
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//
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// We choose to follow the conceptual approach (2) by reflecting the normal around the
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// (<N,V> = 0) boundary if necessary, as it allows us to preserve some normal mapping details.
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NdotV = dot(N, V);
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// N = (NdotV >= 0.0) ? N : (N - 2.0 * NdotV * V);
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N += (2.0 * saturate(-NdotV)) * V;
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NdotV = abs(NdotV);
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return N;
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}
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// Generates an orthonormal (row-major) basis from a unit vector. TODO: make it column-major.
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// The resulting rotation matrix has the determinant of +1.
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// Ref: 'ortho_basis_pixar_r2' from http://marc-b-reynolds.github.io/quaternions/2016/07/06/Orthonormal.html
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real3x3 GetLocalFrame(real3 localZ)
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{
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real x = localZ.x;
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real y = localZ.y;
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real z = localZ.z;
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real sz = FastSign(z);
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real a = 1 / (sz + z);
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real ya = y * a;
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real b = x * ya;
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real c = x * sz;
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real3 localX = real3(c * x * a - 1, sz * b, c);
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real3 localY = real3(b, y * ya - sz, y);
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// Note: due to the quaternion formulation, the generated frame is rotated by 180 degrees,
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// s.t. if localZ = {0, 0, 1}, then localX = {-1, 0, 0} and localY = {0, -1, 0}.
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return real3x3(localX, localY, localZ);
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}
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// Generates an orthonormal (row-major) basis from a unit vector. TODO: make it column-major.
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// The resulting rotation matrix has the determinant of +1.
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real3x3 GetLocalFrame(real3 localZ, real3 localX)
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{
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real3 localY = cross(localZ, localX);
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return real3x3(localX, localY, localZ);
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}
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// Construct a right-handed view-dependent orthogonal basis around the normal:
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// b0-b2 is the view-normal aka reflection plane.
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real3x3 GetOrthoBasisViewNormal(real3 V, real3 N, real unclampedNdotV, bool testSingularity = false)
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{
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real3x3 orthoBasisViewNormal;
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if (testSingularity && (abs(1.0 - unclampedNdotV) <= FLT_EPS))
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{
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// In this case N == V, and azimuth orientation around N shouldn't matter for the caller,
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// we can use any quaternion-based method, like Frisvad or Reynold's (Pixar):
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orthoBasisViewNormal = GetLocalFrame(N);
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}
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else
|
|
{
|
|
orthoBasisViewNormal[0] = normalize(V - N * unclampedNdotV);
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|
orthoBasisViewNormal[2] = N;
|
|
orthoBasisViewNormal[1] = cross(orthoBasisViewNormal[2], orthoBasisViewNormal[0]);
|
|
}
|
|
return orthoBasisViewNormal;
|
|
}
|
|
|
|
// Move this here since it's used by both LightLoop.hlsl and RaytracingLightLoop.hlsl
|
|
bool IsMatchingLightLayer(uint lightLayers, uint renderingLayers)
|
|
{
|
|
return (lightLayers & renderingLayers) != 0;
|
|
}
|
|
|
|
#endif // UNITY_COMMON_LIGHTING_INCLUDED
|