#ifndef UNITY_VOLUMEPROJECTION_INCLUDED #define UNITY_VOLUMEPROJECTION_INCLUDED #define ENVMAP_FEATURE_PERFACEINFLUENCE #define ENVMAP_FEATURE_PERFACEFADE #define ENVMAP_FEATURE_INFLUENCENORMAL #include "LightDefinition.cs.hlsl" float3x3 WorldToProxySpace(EnvProxyData proxyData) { return transpose(float3x3(proxyData.right, proxyData.up, proxyData.forward)); // worldToLocal assume no scaling } float3 WorldToProxyPosition(EnvProxyData proxyData, float3x3 worldToPS, float3 positionWS) { float3 positionPS = positionWS - proxyData.positionWS; positionPS = mul(positionPS, worldToPS).xyz; return positionPS; } float IntersectSphereProxy(EnvProxyData proxyData, float3 dirPS, float3 positionPS) { float sphereOuterDistance = proxyData.extents.x; float projectionDistance = IntersectRaySphereSimple(positionPS, dirPS, sphereOuterDistance); projectionDistance = max(projectionDistance, proxyData.minProjectionDistance); // Setup projection to infinite if requested (mean no projection shape) return projectionDistance; } float IntersectBoxProxy(EnvProxyData proxyData, float3 dirPS, float3 positionPS) { float3 boxOuterDistance = proxyData.extents; float projectionDistance = IntersectRayAABBSimple(positionPS, dirPS, -boxOuterDistance, boxOuterDistance); projectionDistance = max(projectionDistance, proxyData.minProjectionDistance); // Setup projection to infinite if requested (mean no projection shape) return projectionDistance; } float InfluenceSphereWeight(EnvLightData lightData, BSDFData bsdfData, float3 positionWS, float3 positionLS, float3 dirLS) { float lengthPositionLS = length(positionLS); float sphereInfluenceDistance = lightData.influenceExtents.x - lightData.blendDistancePositive.x; float distFade = max(lengthPositionLS - sphereInfluenceDistance, 0.0); float alpha = saturate(1.0 - distFade / max(lightData.blendDistancePositive.x, 0.0001)); // avoid divide by zero #if defined(ENVMAP_FEATURE_INFLUENCENORMAL) float insideInfluenceNormalVolume = lengthPositionLS <= (lightData.influenceExtents.x - lightData.blendNormalDistancePositive.x) ? 1.0 : 0.0; float insideWeight = InfluenceFadeNormalWeight(bsdfData.normalWS, normalize(positionWS - lightData.capturePositionWS)); alpha *= insideInfluenceNormalVolume ? 1.0 : insideWeight; #endif return alpha; } float InfluenceBoxWeight(EnvLightData lightData, BSDFData bsdfData, float3 positionWS, float3 positionLS, float3 dirLS) { float3 boxOuterDistance = lightData.influenceExtents; // 2. Process the position influence // Calculate falloff value, so reflections on the edges of the volume would gradually blend to previous reflection. #if defined(ENVMAP_FEATURE_PERFACEINFLUENCE) || defined(ENVMAP_FEATURE_INFLUENCENORMAL) || defined(ENVMAP_FEATURE_PERFACEFADE) // Distance to each cube face float3 negativeDistance = boxOuterDistance + positionLS; float3 positiveDistance = boxOuterDistance - positionLS; #endif #if defined(ENVMAP_FEATURE_PERFACEINFLUENCE) // Influence falloff for each face float3 negativeFalloff = negativeDistance / max(0.0001, lightData.blendDistanceNegative); float3 positiveFalloff = positiveDistance / max(0.0001, lightData.blendDistancePositive); // Fallof is the min for all faces float influenceFalloff = min( min(min(negativeFalloff.x, negativeFalloff.y), negativeFalloff.z), min(min(positiveFalloff.x, positiveFalloff.y), positiveFalloff.z)); float alpha = saturate(influenceFalloff); #else float distFace = DistancePointBox(positionLS, -lightData.influenceExtents + lightData.blendDistancePositive.x, lightData.influenceExtents - lightData.blendDistancePositive.x); float alpha = saturate(1.0 - distFace / max(lightData.blendDistancePositive.x, 0.0001)); #endif #if defined(ENVMAP_FEATURE_INFLUENCENORMAL) // 3. Process the normal influence // Calculate a falloff value to discard normals pointing outward the center of the environment light float3 belowPositiveInfluenceNormalVolume = positiveDistance / max(0.0001, lightData.blendNormalDistancePositive); float3 aboveNegativeInfluenceNormalVolume = negativeDistance / max(0.0001, lightData.blendNormalDistanceNegative); float insideInfluenceNormalVolume = all(belowPositiveInfluenceNormalVolume >= 1.0) && all(aboveNegativeInfluenceNormalVolume >= 1.0) ? 1.0 : 0; float insideWeight = InfluenceFadeNormalWeight(bsdfData.normalWS, normalize(positionWS - lightData.capturePositionWS)); alpha *= insideInfluenceNormalVolume ? 1.0 : insideWeight; #endif #if defined(ENVMAP_FEATURE_PERFACEFADE) // 4. Fade specific cubemap faces // For each axes (both positive and negative ones), we want to fade from the center of one face to another // So we normalized the sample direction (R) and use its component to fade for each axis // We consider R.x as cos(X) and then fade as angle from 60°(=acos(1/2)) to 75°(=acos(1/4)) // For positive axes: axisFade = (R - 1/4) / (1/2 - 1/4) // <=> axisFace = 4 * R - 1; float3 faceFade = saturate((4 * dirLS - 1) * lightData.boxSideFadePositive) + saturate((-4 * dirLS - 1) * lightData.boxSideFadeNegative); alpha *= saturate(faceFade.x + faceFade.y + faceFade.z); #endif return alpha; } float3x3 WorldToLightSpace(EnvLightData lightData) { return transpose(float3x3(lightData.right, lightData.up, lightData.forward)); // worldToLocal assume no scaling } float3 WorldToLightPosition(EnvLightData lightData, float3x3 worldToLS, float3 positionWS) { float3 positionLS = positionWS - lightData.positionWS; positionLS = mul(positionLS, worldToLS).xyz; return positionLS; } #endif // UNITY_VOLUMEPROJECTION_INCLUDED