Shader "Fog Volume/Skybox" { Properties { [hideininspector][KeywordEnum(None, Miranda, High Quality)] _SunDisk ("Sun", Int) = 1 _SunSize ("Sun Size", Range(0,1)) = 0.04 _SunDiscEdges("Sun Disk Edges", Range(.5,3)) = 1 _SunIntensity("Sun Intensity", Range(0,1000)) = 40 _AtmosphereThickness ("Atmoshpere Thickness", Range(0,5)) = 1.0 _SkyTint ("Sky Tint", Color) = (.5, .5, .5, 1) _GroundColor ("Ground", Color) = (.369, .349, .341, 1) _Exposure("Exposure", Range(0, 8)) = 1.3 } SubShader { Tags { "Queue"="Background" "RenderType"="Background" "PreviewType"="Skybox" } Cull Off ZWrite Off Pass { CGPROGRAM #pragma vertex vert #pragma fragment frag #include "UnityCG.cginc" #include "Lighting.cginc" #pragma multi_compile _SUNDISK_NONE _SUNDISK_SIMPLE _SUNDISK_HIGH_QUALITY uniform half _Exposure; // HDR exposure uniform half3 _GroundColor; uniform half _SunSize; uniform half3 _SkyTint; uniform half _AtmosphereThickness; uniform half _SunIntensity, _SunDiscEdges; #if defined(UNITY_COLORSPACE_GAMMA) #define GAMMA 2 #define COLOR_2_GAMMA(color) color #define COLOR_2_LINEAR(color) color*color #define LINEAR_2_OUTPUT(color) sqrt(color) #else #define GAMMA 2.2 // HACK: to get gfx-tests in Gamma mode to agree until UNITY_ACTIVE_COLORSPACE_IS_GAMMA is working properly #define COLOR_2_GAMMA(color) ((unity_ColorSpaceDouble.r>2.0) ? pow(color,1.0/GAMMA) : color) #define COLOR_2_LINEAR(color) color #define LINEAR_2_LINEAR(color) color #endif // RGB wavelengths // .35 (.62=158), .43 (.68=174), .525 (.75=190) static const float3 kDefaultScatteringWavelength = float3(.65, .57, .475); static const float3 kVariableRangeForScatteringWavelength = float3(.15, .15, .15); #define OUTER_RADIUS 1.025 static const float kOuterRadius = OUTER_RADIUS; static const float kOuterRadius2 = OUTER_RADIUS*OUTER_RADIUS; static const float kInnerRadius = 1.0; static const float kInnerRadius2 = 1.0; static const float kCameraHeight = 0.0001; #define kRAYLEIGH (lerp(0, 0.0025, pow(_AtmosphereThickness,2.5))) // Rayleigh constant #define kMIE 0.0010 // Mie constant #define kSUN_BRIGHTNESS 20.0 // Sun brightness #define kMAX_SCATTER 50.0 // Maximum scattering value, to prevent math overflows on Adrenos static const half kSunScale = 400.0 * kSUN_BRIGHTNESS; static const float kKmESun = kMIE * kSUN_BRIGHTNESS; static const float kKm4PI = kMIE * 4.0 * 3.14159265; static const float kScale = 1.0 / (OUTER_RADIUS - 1.0); static const float kScaleDepth = 0.25; static const float kScaleOverScaleDepth = (1.0 / (OUTER_RADIUS - 1.0)) / 0.25; static const float kSamples = 2.0; // THIS IS UNROLLED MANUALLY, DON'T TOUCH #define MIE_G (-0.990) #define MIE_G2 0.9801 #define SKY_GROUND_THRESHOLD 0.02 // fine tuning of performance. You can override defines here if you want some specific setup // or keep as is and allow later code to set it according to target api // if set vprog will output color in final color space (instead of linear always) // in case of rendering in gamma mode that means that we will do lerps in gamma mode too, so there will be tiny difference around horizon // #define SKYBOX_COLOR_IN_TARGET_COLOR_SPACE 0 // sun disk rendering: // no sun disk - the fastest option #define SKYBOX_SUNDISK_NONE 0 // simplistic sun disk - without mie phase function #define SKYBOX_SUNDISK_SIMPLE 1 // full calculation - uses mie phase function #define SKYBOX_SUNDISK_HQ 2 // uncomment this line and change SKYBOX_SUNDISK_SIMPLE to override material settings // #define SKYBOX_SUNDISK SKYBOX_SUNDISK_SIMPLE #ifndef SKYBOX_SUNDISK #if defined(_SUNDISK_NONE) #define SKYBOX_SUNDISK SKYBOX_SUNDISK_NONE #elif defined(_SUNDISK_SIMPLE) #define SKYBOX_SUNDISK SKYBOX_SUNDISK_SIMPLE #else #define SKYBOX_SUNDISK SKYBOX_SUNDISK_HQ #endif #endif #ifndef SKYBOX_COLOR_IN_TARGET_COLOR_SPACE #if defined(SHADER_API_MOBILE) #define SKYBOX_COLOR_IN_TARGET_COLOR_SPACE 1 #else #define SKYBOX_COLOR_IN_TARGET_COLOR_SPACE 0 #endif #endif // Calculates the Rayleigh phase function half getRayleighPhase(half eyeCos2) { return 0.75 + 0.75*eyeCos2; } half getRayleighPhase(half3 light, half3 ray) { half eyeCos = dot(light, ray); return getRayleighPhase(eyeCos * eyeCos); } struct appdata_t { float4 vertex : POSITION; }; struct v2f { float4 pos : SV_POSITION; #if SKYBOX_SUNDISK == SKYBOX_SUNDISK_HQ // for HQ sun disk, we need vertex itself to calculate ray-dir per-pixel half3 vertex : TEXCOORD0; #elif SKYBOX_SUNDISK == SKYBOX_SUNDISK_SIMPLE half3 rayDir : TEXCOORD0; #else // as we dont need sun disk we need just rayDir.y (sky/ground threshold) half skyGroundFactor : TEXCOORD0; #endif // calculate sky colors in vprog half3 groundColor : TEXCOORD1; half3 skyColor : TEXCOORD2; #if SKYBOX_SUNDISK != SKYBOX_SUNDISK_NONE half3 sunColor : TEXCOORD3; #endif }; float scale(float inCos) { float x = 1.0 - inCos; #if defined(SHADER_API_N3DS) // The polynomial expansion here generates too many swizzle instructions for the 3DS vertex assembler // Approximate by removing x^1 and x^2 return 0.25 * exp(-0.00287 + x*x*x*(-6.80 + x*5.25)); #else return 0.25 * exp(-0.00287 + x*(0.459 + x*(3.83 + x*(-6.80 + x*5.25)))); #endif } v2f vert (appdata_t v) { v2f OUT; OUT.pos = UnityObjectToClipPos(v.vertex); float3 kSkyTintInGammaSpace = COLOR_2_GAMMA(_SkyTint); // convert tint from Linear back to Gamma float3 kScatteringWavelength = lerp ( kDefaultScatteringWavelength-kVariableRangeForScatteringWavelength, kDefaultScatteringWavelength+kVariableRangeForScatteringWavelength, half3(1,1,1) - kSkyTintInGammaSpace); // using Tint in sRGB gamma allows for more visually linear interpolation and to keep (.5) at (128, gray in sRGB) point float3 kInvWavelength = 1.0 / pow(kScatteringWavelength, 4); float kKrESun = kRAYLEIGH * kSUN_BRIGHTNESS; float kKr4PI = kRAYLEIGH * 4.0 * 3.14159265; float3 cameraPos = float3(0,kInnerRadius + kCameraHeight,0); // The camera's current position // Get the ray from the camera to the vertex and its length (which is the far point of the ray passing through the atmosphere) float3 eyeRay = normalize(mul((float3x3)unity_ObjectToWorld, v.vertex.xyz)); float far = 0.0; half3 cIn, cOut; if(eyeRay.y >= 0.0) { // Sky // Calculate the length of the "atmosphere" far = sqrt(kOuterRadius2 + kInnerRadius2 * eyeRay.y * eyeRay.y - kInnerRadius2) - kInnerRadius * eyeRay.y; float3 pos = cameraPos + far * eyeRay; // Calculate the ray's starting position, then calculate its scattering offset float height = kInnerRadius + kCameraHeight; float depth = exp(kScaleOverScaleDepth * (-kCameraHeight)); float startAngle = dot(eyeRay, cameraPos) / height; float startOffset = depth*scale(startAngle); // Initialize the scattering loop variables float sampleLength = far / kSamples; float scaledLength = sampleLength * kScale; float3 sampleRay = eyeRay * sampleLength; float3 samplePoint = cameraPos + sampleRay * 0.5; // Now loop through the sample rays float3 frontColor = float3(0.0, 0.0, 0.0); // Weird workaround: WP8 and desktop FL_9_1 do not like the for loop here // (but an almost identical loop is perfectly fine in the ground calculations below) // Just unrolling this manually seems to make everything fine again. // for(int i=0; i 1 [eyeRay.y < -SKY_GROUND_THRESHOLD] - ground // if y >= 0 and < 1 [eyeRay.y <= 0 and > -SKY_GROUND_THRESHOLD] - horizon // if y < 0 [eyeRay.y > 0] - sky #if SKYBOX_SUNDISK == SKYBOX_SUNDISK_HQ half3 ray = normalize(mul((float3x3)unity_ObjectToWorld, IN.vertex)); half y = ray.y / SKY_GROUND_THRESHOLD; #elif SKYBOX_SUNDISK == SKYBOX_SUNDISK_SIMPLE half3 ray = IN.rayDir.xyz; half y = ray.y / SKY_GROUND_THRESHOLD; #else half y = IN.skyGroundFactor; #endif // if we did precalculate color in vprog: just do lerp between them col = lerp(IN.skyColor, IN.groundColor, saturate(y)); #if SKYBOX_SUNDISK != SKYBOX_SUNDISK_NONE if(y < 0.0) { #if SKYBOX_SUNDISK == SKYBOX_SUNDISK_SIMPLE half mie = calcSunSpot(_WorldSpaceLightPos0.xyz, -ray); #else // SKYBOX_SUNDISK_HQ half eyeCos = dot(_WorldSpaceLightPos0.xyz, ray); half eyeCos2 = eyeCos * eyeCos; half mie = getMiePhase(eyeCos, eyeCos2); #endif mie = pow(mie,_SunDiscEdges); mie = min(_SunIntensity, mie); col += mie * IN.sunColor; } #endif #if defined(UNITY_COLORSPACE_GAMMA) && !SKYBOX_COLOR_IN_TARGET_COLOR_SPACE col = LINEAR_2_OUTPUT(col); #endif return half4(col,1.0); } ENDCG } } Fallback Off }