//-------------------------------------------------------------------------------------- // Defines //-------------------------------------------------------------------------------------- //#define OCCLUDED_PIXEL_RAYVALUE float4(1, 0, 0, 0) // Use very large value for aplha to help edge detection #define OCCLUDED_PIXEL_RAYVALUE float4(1, 0, 0, 100000) #define NEARCLIPPED_PIXEL_RAYPOS float3(0, -1, 0) // Z for skybox is zero, so patch this in shader #define Z_EPSILON 0.00001 // Value for skybox depth #define Z_MAX 100000 //-------------------------------------------------------------------------------------- // Textures //-------------------------------------------------------------------------------------- Texture2D sceneDepthTex; Texture3D colorTex; Texture2D rayDataTex; Texture2D rayDataTexSmall; Texture2D rayCastTex; Texture2D edgeTex; Texture2D jitterTex; Texture2D fireTransferFunction; //-------------------------------------------------------------------------------------- // Samplers //-------------------------------------------------------------------------------------- sampler samPointClamp; sampler samLinearClamp; sampler samRepeat; //-------------------------------------------------------------------------------------- // Variables //-------------------------------------------------------------------------------------- // Set once per volume // Use for all rendering passes cbuffer FluidRenderConfig { float RTWidth; float RTHeight; float4 DiffuseLight; float4x4 WorldViewProjection; float4x4 InvWorldViewProjection; float ZNear; float ZFar; float4 gridDim; // float3 float4 recGridDim; // float3 float maxGridDim; float gridScaleFactor = 1.0; float4 eyeOnGrid; // float3 } //static float edgeThreshold = 0.2; //static float edgeThreshold = 0.1; static float edgeThreshold = 0.01; static const bool g_bRaycastFilterTricubic = false; // true: tricubic; false: trilinear //static const bool g_bRaycastFilterTricubic = true; // true: tricubic; false: trilinear #include "fluid_common_tricubic.h" // Fire setup static const float RednessFactor = 5.0f; static const float fireAlphaMultiplier = 0.95f; //static const float smokeAlphaMultiplier = 0.05f; static const float smokeAlphaMultiplier = 0.5f; //static const float smokeColorMultiplier = 2.00f; static const float smokeColorMultiplier = 0.02f; //-------------------------------------------------------------------------------------- // Structs //-------------------------------------------------------------------------------------- struct VS_INPUT { float3 pos : POSITION; }; struct PS_INPUT_RAYDATA_BACK { float4 pos : SV_Position; float depth : TEXCOORD0; }; struct PS_INPUT_RAYDATA_FRONT { float4 pos : SV_Position; float3 posInGrid: POSITION; float depth : TEXCOORD0; }; struct PS_INPUT_RAYCAST { float4 pos : SV_Position; float3 posInGrid: POSITION; }; struct VS_OUTPUT_EDGE { // There's no textureUV11 because its weight is zero. float4 position : SV_Position; // vertex position float2 textureUV00 : TEXCOORD0; // kernel tap texture coords float2 textureUV01 : TEXCOORD1; // kernel tap texture coords float2 textureUV02 : TEXCOORD2; // kernel tap texture coords float2 textureUV10 : TEXCOORD3; // kernel tap texture coords float2 textureUV12 : TEXCOORD4; // kernel tap texture coords float2 textureUV20 : TEXCOORD5; // kernel tap texture coords float2 textureUV21 : TEXCOORD6; // kernel tap texture coords float2 textureUV22 : TEXCOORD7; // kernel tap texture coords }; //-------------------------------------------------------------------------------------- // Functions //-------------------------------------------------------------------------------------- float EdgeDetectScalar(float sx, float sy, float threshold) { float dist = (sx*sx+sy*sy); float e = (dist > threshold*ZFar)? 1: 0; return e; } /* // We can select either back=to-front or front-to-back raycasting and blending. // front-to-back may be slightly more expensive, but if the smoke is dense it allows // early-out when the opacity gets saturated (close to 1.0), making it a bit cheaper // // Define BACK_TO_FRONT to use back-to-front raycasting //#define BACK_TO_FRONT 1 void DoSample(float weight, float3 O, inout float4 color ) { // This value can be tuned to produce denser or thinner looking smoke // Alternatively a transfer function could be used #define OPACITY_MODULATOR 0.1 float3 texcoords; float4 sample; float t; texcoords = float3( O.x, 1 - O.y, O.z) ; // sample = weight * colorTex.SampleLevel(samLinearClamp, texcoords, 0); // sample = weight * abs(SampleTricubic(colorTex, texcoords)); // sample = weight * abs(SampleTrilinear(colorTex, texcoords)); sample = weight * abs(Sample(colorTex, texcoords)); sample.a = (sample.r) * OPACITY_MODULATOR; #ifdef BACK_TO_FRONT // back-to-front blending color.rgb = (1 - sample.a) * color.r + sample.a * sample.r; color.a = (1 - sample.a) * color.a + sample.a; #else // front-to-back blending t = sample.a * (1.0-color.a); color.rgb += t * sample.r; color.a += t; #endif } float4 Raycast( PS_INPUT_RAYCAST input ) { float4 color = 0; float4 rayData = rayDataTex.Sample(samLinearClamp, float2(input.pos.x/RTWidth,input.pos.y/RTHeight)); // Don't raycast if the starting position is negative // (see use of OCCLUDED_PIXEL_RAYVALUE in PS_RAYDATA_FRONT) if(rayData.x < 0) return color; // If the front face of the box was clipped here by the near plane of the camera // (see use of NEARCLIPPED_PIXEL_RAYPOS in PS_RAYDATA_BACK) if(rayData.y < 0) { // Initialize the position of the fragment and adjust the depth rayData.xyz = input.posInGrid; rayData.w = rayData.w - ZNear; // return float4 (1,0,0,saturate(rayData.w/5)); } float3 rayOrigin = rayData.xyz; float Offset = jitterTex.Sample( samRepeat, input.pos.xy / 256.0 ).r; float rayLength = rayData.w; // Sample twice per voxel float fSamples = ( rayLength / gridScaleFactor * maxGridDim ) * 2.0; int nSamples = floor(fSamples); float3 stepVec = normalize( (rayOrigin - eyeOnGrid) * gridDim ) * recGridDim * 0.5; float3 O = rayOrigin + stepVec*Offset; #ifdef BACK_TO_FRONT // In back-to-front blending we start raycasting from the surface point and step towards the eye O += fSamples * stepVec; stepVec = -stepVec; #endif for( int i=0; i 0.99 ) break; #endif } // The last sample is weighted by the fractional part of the ray length in voxel // space (fSamples), thus avoiding banding artifacts when the smoke is blended against the scene if( i == nSamples ) { DoSample(frac(fSamples), O, color); } return color; } */ //#define RENDER_FIRE void DoSample(float weight, float3 O, inout float4 color ) { // This value can be tuned to produce denser or thinner looking smoke // Alternatively a transfer function could be used #define OPACITY_MODULATOR 0.1 float3 texcoords; texcoords = float3( O.x, 1 - O.y, O.z) ; #ifndef RENDER_FIRE //render smoke with front to back blending float t; float4 sample = weight * abs(Sample(colorTex, texcoords)); sample.a = (sample.r) * 0.1; t = sample.a * (1.0-color.a); color.rgb += t * sample.r; color.a += t; #else // RENDER_FIRE //render fire and smoke with back to front blending //dont render the area below where the fire originates // if(O.z < OBSTACLE_MAX_HEIGHT/gridDim.z) // return; //this is the threshold at which we decide whether to render fire or smoke float threshold = 1.4; float maxValue = 3; float s = colorTex.SampleLevel(samLinearClamp, texcoords, 0).x; s = clamp(s,0,maxValue); if(s>threshold) { //render fire float lookUpVal = ( (s-threshold)/(maxValue-threshold) ); lookUpVal = 1.0 - pow(lookUpVal,RednessFactor); lookUpVal = clamp(lookUpVal,0,1); float3 interpColor = fireTransferFunction.SampleLevel(samLinearClamp,float2(lookUpVal,0),0); float mult = (s-threshold); color += float4(weight*interpColor.rgb,weight*mult*mult*fireAlphaMultiplier); } else { //render smoke float4 sample = weight*s; sample.a = sample.r*0.1*smokeAlphaMultiplier; float3 smokeColor = float3(0.9,0.35,0.055); color.rgb = (1 - sample.a) * color.rgb + sample.a * sample.rrr * smokeColor * smokeColorMultiplier * 5.0; color.a = (1 - sample.a) * color.a + sample.a; } #endif // RENDER_FIRE } float4 Raycast( PS_INPUT_RAYCAST input ) { float4 color = 0; float4 rayData = rayDataTex.Sample(samLinearClamp, float2(input.pos.x/RTWidth,input.pos.y/RTHeight)); // Don't raycast if the starting position is negative // (see use of OCCLUDED_PIXEL_RAYVALUE in PS_RAYDATA_FRONT) if(rayData.x < 0) return color; // If the front face of the box was clipped here by the near plane of the camera // (see use of NEARCLIPPED_PIXEL_RAYPOS in PS_RAYDATA_BACK) if(rayData.y < 0) { // Initialize the position of the fragment and adjust the depth rayData.xyz = input.posInGrid; rayData.w = rayData.w - ZNear; // return float4 (1,0,0,saturate(rayData.w/5)); } float3 rayOrigin = rayData.xyz; float Offset = jitterTex.Sample( samRepeat, input.pos.xy / 256.0 ).r; float rayLength = rayData.w; // Sample twice per voxel float fSamples = ( rayLength / gridScaleFactor * maxGridDim ) * 2.0; int nSamples = floor(fSamples); float3 stepVec = normalize( (rayOrigin - eyeOnGrid) * gridDim ) * recGridDim * 0.5; float3 O = rayOrigin + stepVec*Offset; #ifdef RENDER_FIRE // In back-to-front blending we start raycasting from the surface point and step towards the eye O += fSamples * stepVec; stepVec = -stepVec; #endif // RENDER_FIRE for( int i=0; i 0.99 ) break; #endif // RENDER_FIRE } // The last sample is weighted by the fractional part of the ray length in voxel // space (fSamples), thus avoiding banding artifacts when the smoke is blended against the scene if( i == nSamples ) { DoSample(frac(fSamples), O, color); } return color; }