#ifndef UNITY_VBUFFER_INCLUDED #define UNITY_VBUFFER_INCLUDED // Interpolation in the log space is non-linear. // Therefore, given 'logEncodedDepth', we compute a new depth value // which allows us to perform HW interpolation which is linear in the view space. float ComputeLerpPositionForLogEncoding(float linearDepth, float logEncodedDepth, float4 VBufferScaleAndSliceCount, float4 VBufferDepthDecodingParams) { float z = linearDepth; float d = logEncodedDepth; float numSlices = VBufferScaleAndSliceCount.z; float rcpNumSlices = VBufferScaleAndSliceCount.w; float s0 = floor(d * numSlices - 0.5); float s1 = ceil(d * numSlices - 0.5); float d0 = saturate(s0 * rcpNumSlices + (0.5 * rcpNumSlices)); float d1 = saturate(s1 * rcpNumSlices + (0.5 * rcpNumSlices)); float z0 = DecodeLogarithmicDepthGeneralized(d0, VBufferDepthDecodingParams); float z1 = DecodeLogarithmicDepthGeneralized(d1, VBufferDepthDecodingParams); // Compute the linear interpolation weight. float t = saturate((z - z0) / (z1 - z0)); return d0 + t * rcpNumSlices; } // Performs trilinear reconstruction of the V-Buffer. // If (clampToEdge == false), out-of-bounds loads return 0. float4 SampleVBuffer(TEXTURE3D_ARGS(VBufferLighting, trilinearSampler), bool clampToEdge, float2 positionNDC, float linearDepth, float4 VBufferScaleAndSliceCount, float4 VBufferDepthEncodingParams, float4 VBufferDepthDecodingParams) { float numSlices = VBufferScaleAndSliceCount.z; float rcpNumSlices = VBufferScaleAndSliceCount.w; // Account for the visible area of the V-Buffer. float2 uv = positionNDC * VBufferScaleAndSliceCount.xy; // The distance between slices is log-encoded. float z = linearDepth; float d = EncodeLogarithmicDepthGeneralized(z, VBufferDepthEncodingParams); // Unity doesn't support samplers clamping to border, so we have to do it ourselves. // TODO: add the proper sampler support. bool isInBounds = Min3(uv.x, uv.y, d) > 0 && Max3(uv.x, uv.y, d) < 1; [branch] if (clampToEdge || isInBounds) { #if 1 // Ignore non-linearity (for performance reasons) at the cost of accuracy. // The results are exact for a stationary camera, but can potentially cause some judder in motion. float w = d; #else // Adjust the texture coordinate for HW trilinear sampling. float w = ComputeLerpPositionForLogEncoding(z, d, VBufferScaleAndSliceCount, VBufferDepthDecodingParams); #endif return SAMPLE_TEXTURE3D_LOD(VBufferLighting, trilinearSampler, float3(uv, w), 0); } else { return 0; } } // Returns interpolated {volumetric radiance, transmittance}. The sampler clamps to edge. float4 SampleInScatteredRadianceAndTransmittance(TEXTURE3D_ARGS(VBufferLighting, trilinearSampler), float2 positionNDC, float linearDepth, float4 VBufferResolution, float4 VBufferScaleAndSliceCount, float4 VBufferDepthEncodingParams, float4 VBufferDepthDecodingParams) { #ifdef RECONSTRUCTION_FILTER_TRILINEAR float4 L = SampleVBuffer(TEXTURE3D_PARAM(VBufferLighting, trilinearSampler), true, positionNDC, linearDepth, VBufferScaleAndSliceCount, VBufferDepthEncodingParams, VBufferDepthDecodingParams); #else // Perform biquadratic reconstruction in XY, linear in Z, using 4x trilinear taps. // Account for the visible area of the V-Buffer. float2 xy = positionNDC * (VBufferResolution.xy * VBufferScaleAndSliceCount.xy); float2 ic = floor(xy); float2 fc = frac(xy); // The distance between slices is log-encoded. float z = linearDepth; float d = EncodeLogarithmicDepthGeneralized(z, VBufferDepthEncodingParams); #if 0 // Ignore non-linearity (for performance reasons) at the cost of accuracy. // The results are exact for a stationary camera, but can potentially cause some judder in motion. float w = d; #else // Adjust the texture coordinate for HW trilinear sampling. float w = ComputeLerpPositionForLogEncoding(z, d, VBufferScaleAndSliceCount, VBufferDepthDecodingParams); #endif float2 weights[2], offsets[2]; BiquadraticFilter(1 - fc, weights, offsets); // Inverse-translate the filter centered around 0.5 float2 rcpRes = VBufferResolution.zw; // TODO: reconstruction should be performed in the perceptual space (e.i., after tone mapping). // But our VBuffer is linear. How to achieve that? // See "A Fresh Look at Generalized Sampling", p. 51. float4 L = (weights[0].x * weights[0].y) * SAMPLE_TEXTURE3D_LOD(VBufferLighting, trilinearSampler, float3((ic + float2(offsets[0].x, offsets[0].y)) * rcpRes, w), 0) // Top left + (weights[1].x * weights[0].y) * SAMPLE_TEXTURE3D_LOD(VBufferLighting, trilinearSampler, float3((ic + float2(offsets[1].x, offsets[0].y)) * rcpRes, w), 0) // Top right + (weights[0].x * weights[1].y) * SAMPLE_TEXTURE3D_LOD(VBufferLighting, trilinearSampler, float3((ic + float2(offsets[0].x, offsets[1].y)) * rcpRes, w), 0) // Bottom left + (weights[1].x * weights[1].y) * SAMPLE_TEXTURE3D_LOD(VBufferLighting, trilinearSampler, float3((ic + float2(offsets[1].x, offsets[1].y)) * rcpRes, w), 0); // Bottom right #endif // TODO: add some animated noise to the reconstructed radiance. return float4(L.rgb, Transmittance(L.a)); } #endif // UNITY_VBUFFER_INCLUDED