Exemple #1
0
        TextureHandle RenderPostProcess(RenderGraph renderGraph,
                                        PrepassOutput prepassOutput,
                                        TextureHandle inputColor,
                                        TextureHandle backBuffer,
                                        CullingResults cullResults,
                                        HDCamera hdCamera)
        {
            PostProcessParameters parameters = PreparePostProcess(cullResults, hdCamera);

            TextureHandle afterPostProcessBuffer = renderGraph.defaultResources.blackTextureXR;
            TextureHandle dest = HDUtils.PostProcessIsFinalPass(parameters.hdCamera) ? backBuffer : renderGraph.CreateTexture(
                new TextureDesc(Vector2.one, true, true)
            {
                colorFormat = GetColorBufferFormat(), name = "Intermediate Postprocess buffer"
            });

            if (hdCamera.frameSettings.IsEnabled(FrameSettingsField.AfterPostprocess))
            {
                // We render AfterPostProcess objects first into a separate buffer that will be composited in the final post process pass
                using (var builder = renderGraph.AddRenderPass <AfterPostProcessPassData>("After Post-Process", out var passData, ProfilingSampler.Get(HDProfileId.AfterPostProcessing)))
                {
                    passData.parameters             = parameters;
                    passData.afterPostProcessBuffer = builder.UseColorBuffer(renderGraph.CreateTexture(
                                                                                 new TextureDesc(Vector2.one, true, true)
                    {
                        colorFormat = GraphicsFormat.R8G8B8A8_SRGB, clearBuffer = true, clearColor = Color.black, name = "OffScreen AfterPostProcess"
                    }), 0);
                    if (passData.parameters.useDepthBuffer)
                    {
                        passData.depthStencilBuffer = builder.UseDepthBuffer(prepassOutput.depthBuffer, DepthAccess.ReadWrite);
                    }
                    passData.opaqueAfterPostprocessRL      = builder.UseRendererList(renderGraph.CreateRendererList(passData.parameters.opaqueAfterPPDesc));
                    passData.transparentAfterPostprocessRL = builder.UseRendererList(renderGraph.CreateRendererList(passData.parameters.transparentAfterPPDesc));

                    builder.SetRenderFunc(
                        (AfterPostProcessPassData data, RenderGraphContext ctx) =>
                    {
                        RenderAfterPostProcess(data.parameters
                                               , ctx.resources.GetRendererList(data.opaqueAfterPostprocessRL)
                                               , ctx.resources.GetRendererList(data.transparentAfterPostprocessRL)
                                               , ctx.renderContext, ctx.cmd);
                    });

                    afterPostProcessBuffer = passData.afterPostProcessBuffer;
                }
            }

            m_PostProcessSystem.Render(
                renderGraph,
                parameters.hdCamera,
                parameters.blueNoise,
                inputColor,
                afterPostProcessBuffer,
                prepassOutput.resolvedDepthBuffer,
                prepassOutput.depthPyramidTexture,
                prepassOutput.resolvedMotionVectorsBuffer,
                dest,
                parameters.flipYInPostProcess
                );

            return(dest);
        }
Exemple #2
0
 public void AllocateCoarseStencilBuffer(int width, int height, int viewCount)
 {
     if (width > 8 && height > 8)
     {
         m_CoarseStencilBuffer = new ComputeBuffer(HDUtils.DivRoundUp(width, 8) * HDUtils.DivRoundUp(height, 8) * viewCount, sizeof(uint));
     }
 }
Exemple #3
0
        void BuildLightData(CommandBuffer cmd, HDCamera hdCamera, HDRayTracingLights rayTracingLights, DebugDisplaySettings debugDisplaySettings)
        {
            // If no lights, exit
            if (rayTracingLights.lightCount == 0)
            {
                ResizeLightDataBuffer(1);
                return;
            }

            // Also we need to build the light list data
            if (m_LightDataGPUArray == null || m_LightDataGPUArray.count != rayTracingLights.lightCount)
            {
                ResizeLightDataBuffer(rayTracingLights.lightCount);
            }

            m_LightDataCPUArray.Clear();

            // Grab the shadow settings
            var hdShadowSettings = hdCamera.volumeStack.GetComponent <HDShadowSettings>();
            BoolScalableSetting contactShadowScalableSetting = HDAdditionalLightData.ScalableSettings.UseContactShadow(m_RenderPipeline.asset);

            // Build the data for every light
            for (int lightIdx = 0; lightIdx < rayTracingLights.hdLightArray.Count; ++lightIdx)
            {
                // Grab the additinal light data to process
                HDAdditionalLightData additionalLightData = rayTracingLights.hdLightArray[lightIdx];

                LightData lightData = new LightData();
                // When the user deletes a light source in the editor, there is a single frame where the light is null before the collection of light in the scene is triggered
                // the workaround for this is simply to add an invalid light for that frame
                if (additionalLightData == null)
                {
                    m_LightDataCPUArray.Add(lightData);
                    continue;
                }

                // Evaluate all the light type data that we need
                LightCategory   lightCategory   = LightCategory.Count;
                GPULightType    gpuLightType    = GPULightType.Point;
                LightVolumeType lightVolumeType = LightVolumeType.Count;
                HDLightType     lightType       = additionalLightData.type;
                HDRenderPipeline.EvaluateGPULightType(lightType, additionalLightData.spotLightShape, additionalLightData.areaLightShape, ref lightCategory, ref gpuLightType, ref lightVolumeType);

                // Fetch the light component for this light
                additionalLightData.gameObject.TryGetComponent(out lightComponent);

                // Build the processed light data  that we need
                ProcessedLightData processedData = new ProcessedLightData();
                processedData.additionalLightData = additionalLightData;
                processedData.lightType           = additionalLightData.type;
                processedData.lightCategory       = lightCategory;
                processedData.gpuLightType        = gpuLightType;
                processedData.lightVolumeType     = lightVolumeType;
                // Both of these positions are non-camera-relative.
                processedData.distanceToCamera       = (additionalLightData.gameObject.transform.position - hdCamera.camera.transform.position).magnitude;
                processedData.lightDistanceFade      = HDUtils.ComputeLinearDistanceFade(processedData.distanceToCamera, additionalLightData.fadeDistance);
                processedData.volumetricDistanceFade = HDUtils.ComputeLinearDistanceFade(processedData.distanceToCamera, additionalLightData.volumetricFadeDistance);
                processedData.isBakedShadowMask      = HDRenderPipeline.IsBakedShadowMaskLight(lightComponent);

                // Build a visible light
                Color finalColor = lightComponent.color.linear * lightComponent.intensity;
                if (additionalLightData.useColorTemperature)
                {
                    finalColor *= Mathf.CorrelatedColorTemperatureToRGB(lightComponent.colorTemperature);
                }
                visibleLight.finalColor = finalColor;
                visibleLight.range      = lightComponent.range;
                // This should be done explicitely, localtoworld matrix doesn't work here
                localToWorldMatrix.SetColumn(3, lightComponent.gameObject.transform.position);
                localToWorldMatrix.SetColumn(2, lightComponent.transform.forward);
                localToWorldMatrix.SetColumn(1, lightComponent.transform.up);
                localToWorldMatrix.SetColumn(0, lightComponent.transform.right);
                visibleLight.localToWorldMatrix = localToWorldMatrix;
                visibleLight.spotAngle          = lightComponent.spotAngle;

                int     shadowIndex            = additionalLightData.shadowIndex;
                int     screenSpaceShadowIndex = -1;
                int     screenSpaceChannelSlot = -1;
                Vector3 lightDimensions        = new Vector3(0.0f, 0.0f, 0.0f);

                // Use the shared code to build the light data
                m_RenderPipeline.GetLightData(cmd, hdCamera, hdShadowSettings, visibleLight, lightComponent, in processedData,
                                              shadowIndex, contactShadowScalableSetting, isRasterization: false, ref lightDimensions, ref screenSpaceShadowIndex, ref screenSpaceChannelSlot, ref lightData);

                // We make the light position camera-relative as late as possible in order
                // to allow the preceding code to work with the absolute world space coordinates.
                Vector3 camPosWS = hdCamera.mainViewConstants.worldSpaceCameraPos;
                HDRenderPipeline.UpdateLightCameraRelativetData(ref lightData, camPosWS);

                // Set the data for this light
                m_LightDataCPUArray.Add(lightData);
            }

            // Push the data to the GPU
            m_LightDataGPUArray.SetData(m_LightDataCPUArray);
        }
Exemple #4
0
        void BuildLightData(CommandBuffer cmd, HDCamera hdCamera, HDRayTracingLights rayTracingLights)
        {
            // If no lights, exit
            if (rayTracingLights.lightCount == 0)
            {
                ResizeLightDataBuffer(1);
                return;
            }

            // Also we need to build the light list data
            if (m_LightDataGPUArray == null || m_LightDataGPUArray.count != rayTracingLights.lightCount)
            {
                ResizeLightDataBuffer(rayTracingLights.lightCount);
            }

            m_LightDataCPUArray.Clear();

            // Build the data for every light
            for (int lightIdx = 0; lightIdx < rayTracingLights.hdLightArray.Count; ++lightIdx)
            {
                var lightData = new LightData();

                HDAdditionalLightData additionalLightData = rayTracingLights.hdLightArray[lightIdx];
                // When the user deletes a light source in the editor, there is a single frame where the light is null before the collection of light in the scene is triggered
                // the workaround for this is simply to add an invalid light for that frame
                if (additionalLightData == null)
                {
                    m_LightDataCPUArray.Add(lightData);
                    continue;
                }
                Light light = additionalLightData.gameObject.GetComponent <Light>();

                // Both of these positions are non-camera-relative.
                float distanceToCamera  = (light.gameObject.transform.position - hdCamera.camera.transform.position).magnitude;
                float lightDistanceFade = HDUtils.ComputeLinearDistanceFade(distanceToCamera, additionalLightData.fadeDistance);

                bool contributesToLighting = ((additionalLightData.lightDimmer > 0) && (additionalLightData.affectDiffuse || additionalLightData.affectSpecular)) || (additionalLightData.volumetricDimmer > 0);
                contributesToLighting = contributesToLighting && (lightDistanceFade > 0);

                if (!contributesToLighting)
                {
                    continue;
                }

                lightData.lightLayers = additionalLightData.GetLightLayers();
                LightCategory   lightCategory   = LightCategory.Count;
                GPULightType    gpuLightType    = GPULightType.Point;
                LightVolumeType lightVolumeType = LightVolumeType.Count;
                HDLightType     lightType       = additionalLightData.type;
                HDRenderPipeline.EvaluateGPULightType(lightType, additionalLightData.spotLightShape, additionalLightData.areaLightShape, ref lightCategory, ref gpuLightType, ref lightVolumeType);

                lightData.lightType = gpuLightType;

                lightData.positionRWS = light.gameObject.transform.position;

                bool applyRangeAttenuation = additionalLightData.applyRangeAttenuation && (gpuLightType != GPULightType.ProjectorBox);

                lightData.range = light.range;

                if (applyRangeAttenuation)
                {
                    lightData.rangeAttenuationScale = 1.0f / (light.range * light.range);
                    lightData.rangeAttenuationBias  = 1.0f;

                    if (lightData.lightType == GPULightType.Rectangle)
                    {
                        // Rect lights are currently a special case because they use the normalized
                        // [0, 1] attenuation range rather than the regular [0, r] one.
                        lightData.rangeAttenuationScale = 1.0f;
                    }
                }
                else // Don't apply any attenuation but do a 'step' at range
                {
                    // Solve f(x) = b - (a * x)^2 where x = (d/r)^2.
                    // f(0) = huge -> b = huge.
                    // f(1) = 0    -> huge - a^2 = 0 -> a = sqrt(huge).
                    const float hugeValue = 16777216.0f;
                    const float sqrtHuge  = 4096.0f;
                    lightData.rangeAttenuationScale = sqrtHuge / (light.range * light.range);
                    lightData.rangeAttenuationBias  = hugeValue;

                    if (lightData.lightType == GPULightType.Rectangle)
                    {
                        // Rect lights are currently a special case because they use the normalized
                        // [0, 1] attenuation range rather than the regular [0, r] one.
                        lightData.rangeAttenuationScale = sqrtHuge;
                    }
                }

                Color value = light.color.linear * light.intensity;
                if (additionalLightData.useColorTemperature)
                {
                    value *= Mathf.CorrelatedColorTemperatureToRGB(light.colorTemperature);
                }
                lightData.color = new Vector3(value.r, value.g, value.b);

                lightData.forward = light.transform.forward;
                lightData.up      = light.transform.up;
                lightData.right   = light.transform.right;

                lightData.boxLightSafeExtent = 1.0f;
                if (lightData.lightType == GPULightType.ProjectorBox)
                {
                    // Rescale for cookies and windowing.
                    lightData.right *= 2.0f / Mathf.Max(additionalLightData.shapeWidth, 0.001f);
                    lightData.up    *= 2.0f / Mathf.Max(additionalLightData.shapeHeight, 0.001f);
                }
                else if (lightData.lightType == GPULightType.ProjectorPyramid)
                {
                    // Get width and height for the current frustum
                    var spotAngle = light.spotAngle;

                    float frustumWidth, frustumHeight;

                    if (additionalLightData.aspectRatio >= 1.0f)
                    {
                        frustumHeight = 2.0f * Mathf.Tan(spotAngle * 0.5f * Mathf.Deg2Rad);
                        frustumWidth  = frustumHeight * additionalLightData.aspectRatio;
                    }
                    else
                    {
                        frustumWidth  = 2.0f * Mathf.Tan(spotAngle * 0.5f * Mathf.Deg2Rad);
                        frustumHeight = frustumWidth / additionalLightData.aspectRatio;
                    }

                    // Rescale for cookies and windowing.
                    lightData.right *= 2.0f / frustumWidth;
                    lightData.up    *= 2.0f / frustumHeight;
                }

                if (lightData.lightType == GPULightType.Spot)
                {
                    var spotAngle = light.spotAngle;

                    var innerConePercent      = additionalLightData.innerSpotPercent01;
                    var cosSpotOuterHalfAngle = Mathf.Clamp(Mathf.Cos(spotAngle * 0.5f * Mathf.Deg2Rad), 0.0f, 1.0f);
                    var sinSpotOuterHalfAngle = Mathf.Sqrt(1.0f - cosSpotOuterHalfAngle * cosSpotOuterHalfAngle);
                    var cosSpotInnerHalfAngle = Mathf.Clamp(Mathf.Cos(spotAngle * 0.5f * innerConePercent * Mathf.Deg2Rad), 0.0f, 1.0f); // inner cone

                    var val = Mathf.Max(0.0001f, (cosSpotInnerHalfAngle - cosSpotOuterHalfAngle));
                    lightData.angleScale  = 1.0f / val;
                    lightData.angleOffset = -cosSpotOuterHalfAngle * lightData.angleScale;

                    // Rescale for cookies and windowing.
                    float cotOuterHalfAngle = cosSpotOuterHalfAngle / sinSpotOuterHalfAngle;
                    lightData.up    *= cotOuterHalfAngle;
                    lightData.right *= cotOuterHalfAngle;
                }
                else
                {
                    // These are the neutral values allowing GetAngleAnttenuation in shader code to return 1.0
                    lightData.angleScale  = 0.0f;
                    lightData.angleOffset = 1.0f;
                }

                if (lightData.lightType != GPULightType.Directional && lightData.lightType != GPULightType.ProjectorBox)
                {
                    // Store the squared radius of the light to simulate a fill light.
                    lightData.size = new Vector2(additionalLightData.shapeRadius * additionalLightData.shapeRadius, 0);
                }

                if (lightData.lightType == GPULightType.Rectangle || lightData.lightType == GPULightType.Tube)
                {
                    lightData.size = new Vector2(additionalLightData.shapeWidth, additionalLightData.shapeHeight);
                }

                lightData.lightDimmer           = lightDistanceFade * (additionalLightData.lightDimmer);
                lightData.diffuseDimmer         = lightDistanceFade * (additionalLightData.affectDiffuse ? additionalLightData.lightDimmer : 0);
                lightData.specularDimmer        = lightDistanceFade * (additionalLightData.affectSpecular ? additionalLightData.lightDimmer * hdCamera.frameSettings.specularGlobalDimmer : 0);
                lightData.volumetricLightDimmer = lightDistanceFade * (additionalLightData.volumetricDimmer);

                lightData.cookieMode             = CookieMode.None;
                lightData.contactShadowMask      = 0;
                lightData.cookieIndex            = -1;
                lightData.shadowIndex            = -1;
                lightData.screenSpaceShadowIndex = -1;


                if (light != null && light.cookie != null)
                {
                    // TODO: add texture atlas support for cookie textures.
                    switch (lightType)
                    {
                    case HDLightType.Spot:
                        lightData.cookieMode        = (additionalLightData.legacyLight.cookie.wrapMode == TextureWrapMode.Repeat) ? CookieMode.Repeat : CookieMode.Clamp;
                        lightData.cookieScaleOffset = m_RenderPipeline.m_TextureCaches.lightCookieManager.Fetch2DCookie(cmd, light.cookie);
                        break;

                    case HDLightType.Point:
                        lightData.cookieMode  = CookieMode.Clamp;
                        lightData.cookieIndex = m_RenderPipeline.m_TextureCaches.lightCookieManager.FetchCubeCookie(cmd, light.cookie);
                        break;
                    }
                }
                else if (lightType == HDLightType.Spot && additionalLightData.spotLightShape != SpotLightShape.Cone)
                {
                    // Projectors lights must always have a cookie texture.
                    // As long as the cache is a texture array and not an atlas, the 4x4 white texture will be rescaled to 128
                    lightData.cookieMode        = CookieMode.Clamp;
                    lightData.cookieScaleOffset = m_RenderPipeline.m_TextureCaches.lightCookieManager.Fetch2DCookie(cmd, Texture2D.whiteTexture);
                }
                else if (lightData.lightType == GPULightType.Rectangle && additionalLightData.areaLightCookie != null)
                {
                    lightData.cookieMode        = CookieMode.Clamp;
                    lightData.cookieScaleOffset = m_RenderPipeline.m_TextureCaches.lightCookieManager.FetchAreaCookie(cmd, additionalLightData.areaLightCookie);
                }

                {
                    lightData.shadowDimmer           = 1.0f;
                    lightData.volumetricShadowDimmer = 1.0f;
                }

                {
                    // fix up shadow information
                    lightData.shadowIndex = additionalLightData.shadowIndex;
                }

                // Value of max smoothness is from artists point of view, need to convert from perceptual smoothness to roughness
                lightData.minRoughness = (1.0f - additionalLightData.maxSmoothness) * (1.0f - additionalLightData.maxSmoothness);

                // No usage for the shadow masks
                lightData.shadowMaskSelector = Vector4.zero;
                {
                    // use -1 to say that we don't use shadow mask
                    lightData.shadowMaskSelector.x = -1.0f;
                    lightData.nonLightMappedOnly   = 0;
                }

                if (ShaderConfig.s_CameraRelativeRendering != 0)
                {
                    // Caution: 'LightData.positionWS' is camera-relative after this point.
                    Vector3 camPosWS = hdCamera.mainViewConstants.worldSpaceCameraPos;
                    lightData.positionRWS -= camPosWS;
                }

                // Set the data for this light
                m_LightDataCPUArray.Add(lightData);
            }

            // Push the data to the GPU
            m_LightDataGPUArray.SetData(m_LightDataCPUArray);
        }
Exemple #5
0
 internal Vector3 ComputeViewportLimit(Vector3Int bufferSize)
 {
     return(new Vector3(HDUtils.ComputeViewportLimit(viewportSize.x, bufferSize.x),
                        HDUtils.ComputeViewportLimit(viewportSize.y, bufferSize.y),
                        HDUtils.ComputeViewportLimit(viewportSize.z, bufferSize.z)));
 }
Exemple #6
0
        void RenderReflectionsPerformance(HDCamera hdCamera, CommandBuffer cmd, RTHandle outputTexture, ScriptableRenderContext renderContext, int frameCount, bool transparent)
        {
            // Fetch the required resources
            BlueNoise        blueNoise           = GetBlueNoiseManager();
            RayTracingShader reflectionShaderRT  = m_Asset.renderPipelineRayTracingResources.reflectionRaytracingRT;
            ComputeShader    reflectionShaderCS  = m_Asset.renderPipelineRayTracingResources.reflectionRaytracingCS;
            ComputeShader    reflectionFilter    = m_Asset.renderPipelineRayTracingResources.reflectionBilateralFilterCS;
            RTHandle         intermediateBuffer0 = GetRayTracingBuffer(InternalRayTracingBuffers.RGBA0);
            RTHandle         intermediateBuffer1 = GetRayTracingBuffer(InternalRayTracingBuffers.RGBA1);

            CoreUtils.SetRenderTarget(cmd, intermediateBuffer1, m_SharedRTManager.GetDepthStencilBuffer(), ClearFlag.Color, clearColor: Color.black);

            // Fetch all the settings
            var                settings             = hdCamera.volumeStack.GetComponent <ScreenSpaceReflection>();
            LightCluster       lightClusterSettings = hdCamera.volumeStack.GetComponent <LightCluster>();
            RayTracingSettings rtSettings           = hdCamera.volumeStack.GetComponent <RayTracingSettings>();

            // Texture dimensions
            int texWidth  = hdCamera.actualWidth;
            int texHeight = hdCamera.actualHeight;

            // Evaluate the dispatch parameters
            int areaTileSize = 8;
            int numTilesXHR = 0, numTilesYHR = 0;
            int currentKernel = 0;
            RenderTargetIdentifier clearCoatMaskTexture;

            using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.RaytracingIntegrateReflection)))
            {
                // Fetch the new sample kernel
                if (settings.fullResolution)
                {
                    currentKernel = transparent ? m_RaytracingReflectionsTransparentFullResKernel : m_RaytracingReflectionsFullResKernel;
                }
                else
                {
                    currentKernel = transparent ? m_RaytracingReflectionsTransparentHalfResKernel : m_RaytracingReflectionsHalfResKernel;
                }

                // Inject the ray-tracing sampling data
                blueNoise.BindDitheredRNGData8SPP(cmd);

                // Bind all the required textures
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                clearCoatMaskTexture = hdCamera.frameSettings.litShaderMode == LitShaderMode.Deferred ? m_GbufferManager.GetBuffersRTI()[2] : TextureXR.GetBlackTexture();
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._SsrClearCoatMaskTexture, clearCoatMaskTexture);
                cmd.SetComputeIntParam(reflectionShaderCS, HDShaderIDs._SsrStencilBit, (int)StencilUsage.TraceReflectionRay);
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._StencilTexture, m_SharedRTManager.GetDepthStencilBuffer(), 0, RenderTextureSubElement.Stencil);

                // Bind all the required scalars
                m_ShaderVariablesRayTracingCB._RaytracingIntensityClamp = settings.clampValue;
                m_ShaderVariablesRayTracingCB._RaytracingIncludeSky     = settings.reflectSky.value ? 1 : 0;
                ConstantBuffer.PushGlobal(cmd, m_ShaderVariablesRayTracingCB, HDShaderIDs._ShaderVariablesRaytracing);

                // Bind the output buffers
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._RaytracingDirectionBuffer, intermediateBuffer1);

                if (settings.fullResolution)
                {
                    // Evaluate the dispatch parameters
                    numTilesXHR = (texWidth + (areaTileSize - 1)) / areaTileSize;
                    numTilesYHR = (texHeight + (areaTileSize - 1)) / areaTileSize;
                }
                else
                {
                    // Evaluate the dispatch parameters
                    numTilesXHR = (texWidth / 2 + (areaTileSize - 1)) / areaTileSize;
                    numTilesYHR = (texHeight / 2 + (areaTileSize - 1)) / areaTileSize;
                }

                // Compute the directions
                cmd.DispatchCompute(reflectionShaderCS, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                // Prepare the components for the deferred lighting
                DeferredLightingRTParameters deferredParamters = PrepareReflectionDeferredLightingRTParameters(hdCamera);
                DeferredLightingRTResources  deferredResources = PrepareDeferredLightingRTResources(hdCamera, intermediateBuffer1, intermediateBuffer0);

                // Evaluate the deferred lighting
                RenderRaytracingDeferredLighting(cmd, deferredParamters, deferredResources);

                // Fetch the right filter to use
                if (settings.fullResolution)
                {
                    currentKernel = reflectionFilter.FindKernel("ReflectionIntegrationUpscaleFullRes");
                }
                else
                {
                    currentKernel = reflectionFilter.FindKernel("ReflectionIntegrationUpscaleHalfRes");
                }

                // Inject all the parameters for the compute
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrLightingTextureRW, intermediateBuffer0);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrHitPointTexture, intermediateBuffer1);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._BlueNoiseTexture, blueNoise.textureArray16RGB);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_RaytracingReflectionTexture", outputTexture);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._ScramblingTexture, m_Asset.renderPipelineResources.textures.scramblingTex);
                cmd.SetComputeIntParam(reflectionFilter, HDShaderIDs._SpatialFilterRadius, settings.upscaleRadius);
                cmd.SetComputeIntParam(reflectionFilter, HDShaderIDs._RaytracingDenoiseRadius, settings.denoise ? settings.denoiserRadius : 0);

                numTilesXHR = (texWidth + (areaTileSize - 1)) / areaTileSize;
                numTilesYHR = (texHeight + (areaTileSize - 1)) / areaTileSize;

                // Bind the right texture for clear coat support
                clearCoatMaskTexture = hdCamera.frameSettings.litShaderMode == LitShaderMode.Deferred ? m_GbufferManager.GetBuffersRTI()[2] : TextureXR.GetBlackTexture();
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrClearCoatMaskTexture, clearCoatMaskTexture);

                // Compute the texture
                cmd.DispatchCompute(reflectionFilter, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);
            }

            using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.RaytracingFilterReflection)))
            {
                if (settings.denoise && !transparent)
                {
                    // Grab the history buffer
                    RTHandle reflectionHistory = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedReflection)
                                                 ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedReflection, ReflectionHistoryBufferAllocatorFunction, 1);

                    float historyValidity = 1.0f;
#if UNITY_HDRP_DXR_TESTS_DEFINE
                    if (Application.isPlaying)
                    {
                        historyValidity = 0.0f;
                    }
                    else
#endif
                    // We need to check if something invalidated the history buffers
                    historyValidity *= ValidRayTracingHistory(hdCamera) ? 1.0f : 0.0f;

                    HDReflectionDenoiser reflectionDenoiser = GetReflectionDenoiser();
                    reflectionDenoiser.DenoiseBuffer(cmd, hdCamera, settings.denoiserRadius, outputTexture, reflectionHistory, intermediateBuffer0, historyValidity: historyValidity);
                    HDUtils.BlitCameraTexture(cmd, intermediateBuffer0, outputTexture);
                }
            }
        }
 public static long GetApproxCacheSizeInByte(int nbElement, int resolution, bool hasMipmap, GraphicsFormat format)
 => (long)(nbElement * resolution * resolution * (double)((hasMipmap ? k_MipmapFactorApprox : 1.0f) * HDUtils.GetFormatSizeInBytes(format)));
Exemple #8
0
        public static int GetMaxElementCountForWeightInByte(long weight, int elementSize, int elementCount, GraphicsFormat format, bool hasMipMaps)
        {
            long elementSizeInByte = (long)((long)elementSize * elementSize * elementSize * HDUtils.GetFormatSizeInBytes(format) * (hasMipMaps ? k_MipmapFactorApprox : 1.0f));

            return((int)Mathf.Clamp(weight / elementSizeInByte, 1, elementCount));
        }
 public Vector4 ComputeUvScaleAndLimit(Vector2Int bufferSize)
 {
     // The slice count is fixed for now.
     return(HDUtils.ComputeUvScaleAndLimit(new Vector2Int(viewportSize.x, viewportSize.y), bufferSize));
 }
        public void RenderAO(HDCamera hdCamera, CommandBuffer cmd, RTHandle outputTexture, ShaderVariablesRaytracing globalCB, ScriptableRenderContext renderContext, int frameCount)
        {
            // If any of the previous requirements is missing, the effect is not requested or no acceleration structure, set the default one and leave right away
            if (!m_RenderPipeline.GetRayTracingState())
            {
                SetDefaultAmbientOcclusionTexture(cmd);
                return;
            }

            RayTracingShader aoShaderRT     = m_PipelineRayTracingResources.aoRaytracingRT;
            var             aoSettings      = hdCamera.volumeStack.GetComponent <AmbientOcclusion>();
            RayCountManager rayCountManager = m_RenderPipeline.GetRayCountManager();

            using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.RaytracingAmbientOcclusion)))
            {
                // Grab the acceleration structure for the target camera
                RayTracingAccelerationStructure accelerationStructure = m_RenderPipeline.RequestAccelerationStructure();

                // Define the shader pass to use for the reflection pass
                cmd.SetRayTracingShaderPass(aoShaderRT, "VisibilityDXR");

                // Set the acceleration structure for the pass
                cmd.SetRayTracingAccelerationStructure(aoShaderRT, HDShaderIDs._RaytracingAccelerationStructureName, accelerationStructure);

                // Inject the ray generation data (be careful of the global constant buffer limitation)
                globalCB._RaytracingRayMaxLength = aoSettings.rayLength;
                globalCB._RaytracingNumSamples   = aoSettings.sampleCount;
                ConstantBuffer.PushGlobal(cmd, globalCB, HDShaderIDs._ShaderVariablesRaytracing);

                // Set the data for the ray generation
                cmd.SetRayTracingTextureParam(aoShaderRT, HDShaderIDs._DepthTexture, m_RenderPipeline.sharedRTManager.GetDepthStencilBuffer());
                cmd.SetRayTracingTextureParam(aoShaderRT, HDShaderIDs._NormalBufferTexture, m_RenderPipeline.sharedRTManager.GetNormalBuffer());

                // Inject the ray-tracing sampling data
                BlueNoise blueNoise = m_RenderPipeline.GetBlueNoiseManager();
                blueNoise.BindDitheredRNGData8SPP(cmd);


                // Set the output textures
                cmd.SetRayTracingTextureParam(aoShaderRT, HDShaderIDs._RayCountTexture, rayCountManager.GetRayCountTexture());
                cmd.SetRayTracingTextureParam(aoShaderRT, HDShaderIDs._AmbientOcclusionTextureRW, m_AOIntermediateBuffer0);

                // Run the computation
                cmd.DispatchRays(aoShaderRT, m_RayGenShaderName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, (uint)hdCamera.viewCount);
            }

            using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.RaytracingFilterAmbientOcclusion)))
            {
                if (aoSettings.denoise)
                {
                    // Grab the history buffer
                    RTHandle ambientOcclusionHistory = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedAmbientOcclusion)
                                                       ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedAmbientOcclusion, AmbientOcclusionHistoryBufferAllocatorFunction, 1);

                    float historyValidity = 1.0f;
                    #if UNITY_HDRP_DXR_TESTS_DEFINE
                    if (Application.isPlaying)
                    {
                        historyValidity = 0.0f;
                    }
                    else
                    #endif
                    // We need to check if something invalidated the history buffers
                    historyValidity = m_RenderPipeline.ValidRayTracingHistory(hdCamera) ? 1.0f : 0.0f;

                    // Apply the temporal denoiser
                    HDTemporalFilter temporalFilter = m_RenderPipeline.GetTemporalFilter();
                    temporalFilter.DenoiseBuffer(cmd, hdCamera, m_AOIntermediateBuffer0, ambientOcclusionHistory, m_AOIntermediateBuffer1, historyValidity: historyValidity);

                    // Apply the diffuse denoiser
                    HDDiffuseDenoiser diffuseDenoiser = m_RenderPipeline.GetDiffuseDenoiser();
                    diffuseDenoiser.DenoiseBuffer(cmd, hdCamera, m_AOIntermediateBuffer1, outputTexture, aoSettings.denoiserRadius);
                }
                else
                {
                    HDUtils.BlitCameraTexture(cmd, m_AOIntermediateBuffer0, outputTexture);
                }

                ComputeShader aoShaderCS = m_PipelineRayTracingResources.aoRaytracingCS;
                cmd.SetComputeFloatParam(aoShaderCS, HDShaderIDs._RaytracingAOIntensity, aoSettings.intensity.value);
                cmd.SetComputeTextureParam(aoShaderCS, m_RTAOApplyIntensityKernel, HDShaderIDs._AmbientOcclusionTextureRW, outputTexture);
                int texWidth     = hdCamera.actualWidth;
                int texHeight    = hdCamera.actualHeight;
                int areaTileSize = 8;
                int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
                int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;
                cmd.DispatchCompute(aoShaderCS, m_RTAOApplyIntensityKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);
            }

            // Bind the textures and the params
            cmd.SetGlobalTexture(HDShaderIDs._AmbientOcclusionTexture, outputTexture);

            // TODO: All the push-debug stuff should be centralized somewhere
            (RenderPipelineManager.currentPipeline as HDRenderPipeline).PushFullScreenDebugTexture(hdCamera, cmd, outputTexture, FullScreenDebugMode.ScreenSpaceAmbientOcclusion);
        }
Exemple #11
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        static void ExecuteTemporalFilterArray(CommandBuffer cmd, TemporalFilterArrayParameters tfaParams, TemporalFilterArrayResources tfaResources)
        {
            if (tfaResources.historyDepthTexture == null || tfaResources.historyNormalTexture == null)
            {
                HDUtils.BlitCameraTexture(cmd, tfaResources.noisyBuffer, tfaResources.historyBuffer);
                HDUtils.BlitCameraTexture(cmd, tfaResources.noisyBuffer, tfaResources.outputBuffer);
                if (tfaResources.distanceBuffer != null && tfaResources.distanceHistorySignal != null && tfaResources.outputDistanceSignal != null)
                {
                    HDUtils.BlitCameraTexture(cmd, tfaResources.distanceBuffer, tfaResources.distanceHistorySignal);
                    HDUtils.BlitCameraTexture(cmd, tfaResources.distanceBuffer, tfaResources.outputDistanceSignal);
                }
                return;
            }

            // Evaluate the dispatch parameters
            int tfTileSize = 8;
            int numTilesX  = (tfaParams.texWidth + (tfTileSize - 1)) / tfTileSize;
            int numTilesY  = (tfaParams.texHeight + (tfTileSize - 1)) / tfTileSize;

            // First of all we need to validate the history to know where we can or cannot use the history signal
            // Bind all the input buffers
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.validateHistoryKernel, HDShaderIDs._DepthTexture, tfaResources.depthStencilBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.validateHistoryKernel, HDShaderIDs._HistoryDepthTexture, tfaResources.historyDepthTexture);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.validateHistoryKernel, HDShaderIDs._NormalBufferTexture, tfaResources.normalBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.validateHistoryKernel, HDShaderIDs._HistoryNormalTexture, tfaResources.historyNormalTexture);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.validateHistoryKernel, HDShaderIDs._VelocityBuffer, tfaResources.velocityBuffer);

            // Bind the constants
            cmd.SetComputeFloatParam(tfaParams.temporalFilterCS, HDShaderIDs._HistoryValidity, tfaParams.historyValidity);
            cmd.SetComputeFloatParam(tfaParams.temporalFilterCS, HDShaderIDs._PixelSpreadAngleTangent, tfaParams.pixelSpreadTangent);

            // Bind the output buffer
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.validateHistoryKernel, HDShaderIDs._ValidationBufferRW, tfaResources.validationBuffer);

            // Evaluate the validity
            cmd.DispatchCompute(tfaParams.temporalFilterCS, tfaParams.validateHistoryKernel, numTilesX, numTilesY, tfaParams.viewCount);

            // Now that we have validated our history, let's accumulate
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, HDShaderIDs._DenoiseInputTexture, tfaResources.noisyBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, HDShaderIDs._HistoryBuffer, tfaResources.historyBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, HDShaderIDs._HistoryValidityBuffer, tfaResources.validationHistoryBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, HDShaderIDs._DepthTexture, tfaResources.depthStencilBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, HDShaderIDs._ValidationBuffer, tfaResources.validationBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, HDShaderIDs._VelocityBuffer, tfaResources.velocityBuffer);

            // Bind the constants
            cmd.SetComputeIntParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistorySlice, tfaParams.sliceIndex);
            cmd.SetComputeVectorParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistoryMask, tfaParams.channelMask);

            // Bind the output buffer
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, HDShaderIDs._DenoiseOutputTextureRW, tfaResources.outputBuffer);

            // Combine with the history
            cmd.DispatchCompute(tfaParams.temporalFilterCS, tfaParams.temporalAccKernel, numTilesX, numTilesY, tfaParams.viewCount);

            // Make sure to copy the new-accumulated signal in our history buffer
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.copyHistoryKernel, HDShaderIDs._DenoiseInputTexture, tfaResources.outputBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.copyHistoryKernel, HDShaderIDs._DenoiseOutputTextureRW, tfaResources.historyBuffer);
            cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.copyHistoryKernel, HDShaderIDs._ValidityOutputTextureRW, tfaResources.validationHistoryBuffer);
            cmd.SetComputeIntParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistorySlice, tfaParams.sliceIndex);
            cmd.SetComputeVectorParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistoryMask, tfaParams.channelMask);
            cmd.DispatchCompute(tfaParams.temporalFilterCS, tfaParams.copyHistoryKernel, numTilesX, numTilesY, tfaParams.viewCount);

            if (tfaResources.distanceBuffer != null && tfaResources.distanceHistorySignal != null && tfaResources.outputDistanceSignal != null)
            {
                // Bind the input buffers
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, HDShaderIDs._DenoiseInputTexture, tfaResources.distanceBuffer);
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, HDShaderIDs._HistoryBuffer, tfaResources.distanceHistorySignal);
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, HDShaderIDs._HistoryValidityBuffer, tfaResources.validationHistoryBuffer);
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, HDShaderIDs._DepthTexture, tfaResources.depthStencilBuffer);
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, HDShaderIDs._ValidationBuffer, tfaResources.validationBuffer);
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, HDShaderIDs._VelocityBuffer, tfaResources.velocityBuffer);

                // Bind the constant inputs
                cmd.SetComputeIntParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistorySlice, tfaParams.sliceIndex);
                cmd.SetComputeVectorParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistoryMask, tfaParams.distanceChannelMask);

                // Bind the output buffers
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, HDShaderIDs._DenoiseOutputTextureRW, tfaResources.outputDistanceSignal);

                // Dispatch the temporal accumulation
                cmd.DispatchCompute(tfaParams.temporalFilterCS, tfaParams.temporalAccSingleKernel, numTilesX, numTilesY, tfaParams.viewCount);

                // Make sure to copy the new-accumulated signal in our history buffer
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.copyHistoryNoValidityKernel, HDShaderIDs._DenoiseInputTexture, tfaResources.outputDistanceSignal);
                cmd.SetComputeTextureParam(tfaParams.temporalFilterCS, tfaParams.copyHistoryNoValidityKernel, HDShaderIDs._DenoiseOutputTextureRW, tfaResources.distanceHistorySignal);
                cmd.SetComputeIntParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistorySlice, tfaParams.sliceIndex);
                cmd.SetComputeVectorParam(tfaParams.temporalFilterCS, HDShaderIDs._DenoisingHistoryMask, tfaParams.distanceChannelMask);
                cmd.DispatchCompute(tfaParams.temporalFilterCS, tfaParams.copyHistoryNoValidityKernel, numTilesX, numTilesY, tfaParams.viewCount);
            }
        }
        void BuildLightData(CommandBuffer cmd, HDCamera hdCamera, HDRayTracingLights rayTracingLights, DebugDisplaySettings debugDisplaySettings)
        {
            // If no lights, exit
            if (rayTracingLights.lightCount == 0)
            {
                ResizeLightDataBuffer(1);
                return;
            }

            // Also we need to build the light list data
            if (m_LightDataGPUArray == null || m_LightDataGPUArray.count != rayTracingLights.lightCount)
            {
                ResizeLightDataBuffer(rayTracingLights.lightCount);
            }

            m_LightDataCPUArray.Clear();

            // Grab the shadow settings
            var hdShadowSettings = hdCamera.volumeStack.GetComponent <HDShadowSettings>();
            BoolScalableSetting contactShadowScalableSetting = HDAdditionalLightData.ScalableSettings.UseContactShadow(m_RenderPipeline.asset);

            // Build the data for every light
            HDLightRenderDatabase lightEntities = HDLightRenderDatabase.instance;
            var processedLightEntity            = new HDProcessedVisibleLight()
            {
                shadowMapFlags = HDProcessedVisibleLightsBuilder.ShadowMapFlags.None
            };

            var globalConfig     = HDGpuLightsBuilder.CreateGpuLightDataJobGlobalConfig.Create(hdCamera, hdShadowSettings);
            var shadowInitParams = m_RenderPipeline.currentPlatformRenderPipelineSettings.hdShadowInitParams;

            for (int lightIdx = 0; lightIdx < rayTracingLights.hdLightEntityArray.Count; ++lightIdx)
            {
                // Grab the additinal light data to process
                int dataIndex = lightEntities.GetEntityDataIndex(rayTracingLights.hdLightEntityArray[lightIdx]);
                HDAdditionalLightData additionalLightData = lightEntities.hdAdditionalLightData[dataIndex];

                LightData lightData = new LightData();
                // When the user deletes a light source in the editor, there is a single frame where the light is null before the collection of light in the scene is triggered
                // the workaround for this is simply to add an invalid light for that frame
                if (additionalLightData == null)
                {
                    m_LightDataCPUArray.Add(lightData);
                    continue;
                }

                // Evaluate all the light type data that we need
                LightCategory   lightCategory   = LightCategory.Count;
                GPULightType    gpuLightType    = GPULightType.Point;
                LightVolumeType lightVolumeType = LightVolumeType.Count;
                HDLightType     lightType       = additionalLightData.type;
                HDRenderPipeline.EvaluateGPULightType(lightType, additionalLightData.spotLightShape, additionalLightData.areaLightShape, ref lightCategory, ref gpuLightType, ref lightVolumeType);

                // Fetch the light component for this light
                additionalLightData.gameObject.TryGetComponent(out lightComponent);

                ref HDLightRenderData lightRenderData = ref lightEntities.GetLightDataAsRef(dataIndex);

                // Build the processed light data  that we need
                processedLightEntity.dataIndex                   = dataIndex;
                processedLightEntity.gpuLightType                = gpuLightType;
                processedLightEntity.lightType                   = additionalLightData.type;
                processedLightEntity.distanceToCamera            = (additionalLightData.transform.position - hdCamera.camera.transform.position).magnitude;
                processedLightEntity.lightDistanceFade           = HDUtils.ComputeLinearDistanceFade(processedLightEntity.distanceToCamera, lightRenderData.fadeDistance);
                processedLightEntity.lightVolumetricDistanceFade = HDUtils.ComputeLinearDistanceFade(processedLightEntity.distanceToCamera, lightRenderData.volumetricFadeDistance);
                processedLightEntity.isBakedShadowMask           = HDRenderPipeline.IsBakedShadowMaskLight(lightComponent);

                // Build a visible light
                visibleLight.finalColor = LightUtils.EvaluateLightColor(lightComponent, additionalLightData);
                visibleLight.range      = lightComponent.range;
                // This should be done explicitly, localToWorld matrix doesn't work here
                localToWorldMatrix.SetColumn(3, lightComponent.gameObject.transform.position);
                localToWorldMatrix.SetColumn(2, lightComponent.transform.forward);
                localToWorldMatrix.SetColumn(1, lightComponent.transform.up);
                localToWorldMatrix.SetColumn(0, lightComponent.transform.right);
                visibleLight.localToWorldMatrix = localToWorldMatrix;
                visibleLight.spotAngle          = lightComponent.spotAngle;

                int     shadowIndex     = additionalLightData.shadowIndex;
                Vector3 lightDimensions = new Vector3(0.0f, 0.0f, 0.0f);

                // Use the shared code to build the light data
                HDGpuLightsBuilder.CreateGpuLightDataJob.ConvertLightToGPUFormat(
                    lightCategory, gpuLightType, globalConfig,
                    lightComponent.lightShadowCasterMode, lightComponent.bakingOutput,
                    visibleLight, processedLightEntity, lightRenderData, out var _, ref lightData);
                m_RenderPipeline.gpuLightList.ProcessLightDataShadowIndex(cmd, shadowInitParams, lightType, lightComponent, additionalLightData, shadowIndex, ref lightData);

                // We make the light position camera-relative as late as possible in order
                // to allow the preceding code to work with the absolute world space coordinates.
                Vector3 camPosWS = hdCamera.mainViewConstants.worldSpaceCameraPos;
                HDRenderPipeline.UpdateLightCameraRelativetData(ref lightData, camPosWS);

                // Set the data for this light
                m_LightDataCPUArray.Add(lightData);
            }
        /// <summary>
        /// Execute the DrawRenderers with parameters setup from the editor
        /// </summary>
        /// <param name="ctx">The context of the custom pass. Contains command buffer, render context, buffer, etc.</param>
        protected override void Execute(CustomPassContext ctx)
        {
            var shaderPasses = GetShaderTagIds();

            if (overrideMaterial != null)
            {
                shaderPasses[shaderPasses.Length - 1] = new ShaderTagId(overrideMaterialPassName);
                overrideMaterial.SetFloat(fadeValueId, fadeValue);
            }

            if (shaderPasses.Length == 0)
            {
                Debug.LogWarning("Attempt to call DrawRenderers with an empty shader passes. Skipping the call to avoid errors");
                return;
            }

            var mask = overrideDepthState ? RenderStateMask.Depth : 0;

            mask |= overrideDepthState && !depthWrite ? RenderStateMask.Stencil : 0;
            var stateBlock = new RenderStateBlock(mask)
            {
                depthState = new DepthState(depthWrite, depthCompareFunction),
                // We disable the stencil when the depth is overwritten but we don't write to it, to prevent writing to the stencil.
                stencilState = new StencilState(false),
            };

            PerObjectData renderConfig = ctx.hdCamera.frameSettings.IsEnabled(FrameSettingsField.Shadowmask) ? HDUtils.GetBakedLightingWithShadowMaskRenderConfig() : HDUtils.GetBakedLightingRenderConfig();

            var result = new RendererListDesc(shaderPasses, ctx.cullingResults, ctx.hdCamera.camera)
            {
                rendererConfiguration      = renderConfig,
                renderQueueRange           = GetRenderQueueRange(renderQueueType),
                sortingCriteria            = sortingCriteria,
                excludeObjectMotionVectors = false,
                overrideMaterial           = overrideMaterial,
                overrideMaterialPassIndex  = (overrideMaterial != null) ? overrideMaterial.FindPass(overrideMaterialPassName) : 0,
                stateBlock = stateBlock,
                layerMask  = layerMask,
            };

            CoreUtils.DrawRendererList(ctx.renderContext, ctx.cmd, RendererList.Create(result));
        }
Exemple #14
0
        public void RenderAO(HDCamera hdCamera, CommandBuffer cmd, RTHandle outputTexture, ScriptableRenderContext renderContext, int frameCount)
        {
            // Let's check all the resources
            HDRaytracingEnvironment rtEnvironment = m_RaytracingManager.CurrentEnvironment();


            // Check if the state is valid for evaluating ambient occlusion
            bool invalidState = rtEnvironment == null;

            // If any of the previous requirements is missing, the effect is not requested or no acceleration structure, set the default one and leave right away
            if (invalidState)
            {
                SetDefaultAmbientOcclusionTexture(cmd);
                return;
            }

            RayTracingShader aoShader = m_PipelineRayTracingResources.aoRaytracing;
            var aoSettings            = VolumeManager.instance.stack.GetComponent <AmbientOcclusion>();

            // Grab the acceleration structure for the target camera
            RayTracingAccelerationStructure accelerationStructure = m_RaytracingManager.RequestAccelerationStructure(rtEnvironment.aoLayerMask);

            // Define the shader pass to use for the reflection pass
            cmd.SetRayTracingShaderPass(aoShader, "VisibilityDXR");

            // Set the acceleration structure for the pass
            cmd.SetRayTracingAccelerationStructure(aoShader, HDShaderIDs._RaytracingAccelerationStructureName, accelerationStructure);

            // Inject the ray-tracing sampling data
            cmd.SetGlobalTexture(HDShaderIDs._OwenScrambledRGTexture, m_PipelineResources.textures.owenScrambledRGBATex);
            cmd.SetGlobalTexture(HDShaderIDs._OwenScrambledTexture, m_PipelineResources.textures.owenScrambled256Tex);
            cmd.SetGlobalTexture(HDShaderIDs._ScramblingTexture, m_PipelineResources.textures.scramblingTex);

            // Inject the ray generation data
            cmd.SetRayTracingFloatParams(aoShader, HDShaderIDs._RaytracingRayBias, rtEnvironment.rayBias);
            cmd.SetRayTracingFloatParams(aoShader, HDShaderIDs._RaytracingRayMaxLength, aoSettings.rayLength.value);
            cmd.SetRayTracingIntParams(aoShader, HDShaderIDs._RaytracingNumSamples, aoSettings.numSamples.value);

            // Set the data for the ray generation
            cmd.SetRayTracingTextureParam(aoShader, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
            cmd.SetRayTracingTextureParam(aoShader, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
            int frameIndex = hdCamera.IsTAAEnabled() ? hdCamera.taaFrameIndex : (int)frameCount % 8;

            cmd.SetGlobalInt(HDShaderIDs._RaytracingFrameIndex, frameIndex);

            // Value used to scale the ao intensity
            cmd.SetRayTracingFloatParam(aoShader, HDShaderIDs._RaytracingAOIntensity, aoSettings.intensity.value);

            cmd.SetRayTracingIntParam(aoShader, HDShaderIDs._RayCountEnabled, m_RaytracingManager.rayCountManager.RayCountIsEnabled());
            cmd.SetRayTracingTextureParam(aoShader, HDShaderIDs._RayCountTexture, m_RaytracingManager.rayCountManager.rayCountTexture);

            // Set the output textures
            cmd.SetRayTracingTextureParam(aoShader, HDShaderIDs._AmbientOcclusionTextureRW, m_IntermediateBuffer);
            cmd.SetRayTracingTextureParam(aoShader, HDShaderIDs._RaytracingVSNormalTexture, m_ViewSpaceNormalBuffer);

            // Run the computation
            cmd.DispatchRays(aoShader, m_RayGenShaderName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);

            using (new ProfilingSample(cmd, "Filter Reflection", CustomSamplerId.RaytracingAmbientOcclusion.GetSampler()))
            {
                if (aoSettings.enableFilter.value)
                {
                    // Grab the history buffer
                    RTHandle ambientOcclusionHistory = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedAmbientOcclusion)
                                                       ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedAmbientOcclusion, AmbientOcclusionHistoryBufferAllocatorFunction, 1);

                    // Apply the simple denoiser
                    HDSimpleDenoiser simpleDenoiser = m_RaytracingManager.GetSimpleDenoiser();
                    simpleDenoiser.DenoiseBuffer(cmd, hdCamera, m_IntermediateBuffer, ambientOcclusionHistory, outputTexture, aoSettings.filterRadius.value, singleChannel: true);
                }
                else
                {
                    HDUtils.BlitCameraTexture(cmd, m_IntermediateBuffer, outputTexture);
                }
            }

            // Bind the textures and the params
            cmd.SetGlobalTexture(HDShaderIDs._AmbientOcclusionTexture, outputTexture);
            cmd.SetGlobalVector(HDShaderIDs._AmbientOcclusionParam, new Vector4(0f, 0f, 0f, VolumeManager.instance.stack.GetComponent <AmbientOcclusion>().directLightingStrength.value));

            // TODO: All the push-debug stuff should be centralized somewhere
            (RenderPipelineManager.currentPipeline as HDRenderPipeline).PushFullScreenDebugTexture(hdCamera, cmd, outputTexture, FullScreenDebugMode.SSAO);
        }
Exemple #15
0
 void LateUpdate()
 {
     if (m_Handle != null)
     {
         if (transform.hasChanged == true)
         {
             Matrix4x4 sizeOffset = Matrix4x4.Translate(decalOffset) * Matrix4x4.Scale(decalSize);
             DecalSystem.instance.UpdateCachedData(position, rotation, sizeOffset, m_DrawDistance, m_FadeScale, uvScaleBias, m_AffectsTransparency, m_Handle, gameObject.layer, HDUtils.GetSceneCullingMaskFromGameObject(gameObject), m_FadeFactor);
             transform.hasChanged = false;
         }
     }
 }
        void RenderSubsurfaceScattering(HDCamera hdCamera, CommandBuffer cmd, RTHandle colorBufferRT,
                                        RTHandle diffuseBufferRT, RTHandle depthStencilBufferRT, RTHandle depthTextureRT)
        {
            if (!hdCamera.frameSettings.IsEnabled(FrameSettingsField.SubsurfaceScattering))
            {
                return;
            }

            BuildCoarseStencilAndResolveIfNeeded(hdCamera, cmd);

            var settings = hdCamera.volumeStack.GetComponent <SubSurfaceScattering>();

            // If ray tracing is enabled for the camera, if the volume override is active and if the RAS is built, we want to do ray traced SSS
            if (hdCamera.frameSettings.IsEnabled(FrameSettingsField.RayTracing) && settings.rayTracing.value && GetRayTracingState())
            {
                using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.SubsurfaceScattering)))
                {
                    // Evaluate the dispatch parameters
                    int areaTileSize = 8;
                    int numTilesXHR  = (hdCamera.actualWidth + (areaTileSize - 1)) / areaTileSize;
                    int numTilesYHR  = (hdCamera.actualHeight + (areaTileSize - 1)) / areaTileSize;

                    // Clear the integration texture first
                    cmd.SetComputeTextureParam(m_ScreenSpaceShadowsCS, m_ClearShadowTexture, HDShaderIDs._RaytracedShadowIntegration, diffuseBufferRT);
                    cmd.DispatchCompute(m_ScreenSpaceShadowsCS, m_ClearShadowTexture, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                    // Fetch the volume overrides that we shall be using
                    RayTracingShader   subSurfaceShader   = m_Asset.renderPipelineRayTracingResources.subSurfaceRayTracing;
                    RayTracingSettings rayTracingSettings = hdCamera.volumeStack.GetComponent <RayTracingSettings>();
                    ComputeShader      deferredRayTracing = m_Asset.renderPipelineRayTracingResources.deferredRaytracingCS;

                    // Fetch all the intermediate buffers that we need
                    RTHandle intermediateBuffer0 = GetRayTracingBuffer(InternalRayTracingBuffers.RGBA0);
                    RTHandle intermediateBuffer1 = GetRayTracingBuffer(InternalRayTracingBuffers.RGBA1);
                    RTHandle intermediateBuffer2 = GetRayTracingBuffer(InternalRayTracingBuffers.RGBA2);
                    RTHandle intermediateBuffer3 = GetRayTracingBuffer(InternalRayTracingBuffers.RGBA3);
                    RTHandle directionBuffer     = GetRayTracingBuffer(InternalRayTracingBuffers.Direction);

                    // Grab the acceleration structure for the target camera
                    RayTracingAccelerationStructure accelerationStructure = RequestAccelerationStructure();

                    // Define the shader pass to use for the reflection pass
                    cmd.SetRayTracingShaderPass(subSurfaceShader, "SubSurfaceDXR");

                    // Set the acceleration structure for the pass
                    cmd.SetRayTracingAccelerationStructure(subSurfaceShader, HDShaderIDs._RaytracingAccelerationStructureName, accelerationStructure);

                    // Inject the ray-tracing sampling data
                    BlueNoise blueNoise = GetBlueNoiseManager();
                    blueNoise.BindDitheredRNGData8SPP(cmd);

                    // For every sample that we need to process
                    for (int sampleIndex = 0; sampleIndex < settings.sampleCount.value; ++sampleIndex)
                    {
                        // Inject the ray generation data
                        cmd.SetGlobalFloat(HDShaderIDs._RaytracingRayBias, rayTracingSettings.rayBias.value);
                        cmd.SetGlobalInt(HDShaderIDs._RaytracingNumSamples, settings.sampleCount.value);
                        cmd.SetGlobalInt(HDShaderIDs._RaytracingSampleIndex, sampleIndex);
                        int frameIndex = RayTracingFrameIndex(hdCamera);
                        cmd.SetGlobalInt(HDShaderIDs._RaytracingFrameIndex, frameIndex);

                        // Bind the textures for ray generation
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._DepthTexture, sharedRTManager.GetDepthStencilBuffer());
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._NormalBufferTexture, sharedRTManager.GetNormalBuffer());
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._SSSBufferTexture, m_SSSColor);
                        cmd.SetGlobalTexture(HDShaderIDs._StencilTexture, sharedRTManager.GetDepthStencilBuffer(), RenderTextureSubElement.Stencil);

                        // Set the output textures
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._ThroughputTextureRW, intermediateBuffer0);
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._NormalTextureRW, intermediateBuffer1);
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._PositionTextureRW, intermediateBuffer2);
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._DiffuseLightingTextureRW, intermediateBuffer3);
                        cmd.SetRayTracingTextureParam(subSurfaceShader, HDShaderIDs._DirectionTextureRW, directionBuffer);

                        // Run the computation
                        cmd.DispatchRays(subSurfaceShader, m_RayGenSubSurfaceShaderName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, (uint)hdCamera.viewCount);

                        // Now let's do the deferred shading pass on the samples
                        // TODO: Do this only once in the init pass
                        int currentKernel = deferredRayTracing.FindKernel("RaytracingDiffuseDeferred");

                        // Bind the lightLoop data
                        HDRaytracingLightCluster lightCluster = RequestLightCluster();
                        lightCluster.BindLightClusterData(cmd);

                        // Bind the input textures
                        cmd.SetComputeTextureParam(deferredRayTracing, currentKernel, HDShaderIDs._DepthTexture, sharedRTManager.GetDepthStencilBuffer());
                        cmd.SetComputeTextureParam(deferredRayTracing, currentKernel, HDShaderIDs._ThroughputTextureRW, intermediateBuffer0);
                        cmd.SetComputeTextureParam(deferredRayTracing, currentKernel, HDShaderIDs._NormalTextureRW, intermediateBuffer1);
                        cmd.SetComputeTextureParam(deferredRayTracing, currentKernel, HDShaderIDs._PositionTextureRW, intermediateBuffer2);
                        cmd.SetComputeTextureParam(deferredRayTracing, currentKernel, HDShaderIDs._DirectionTextureRW, directionBuffer);
                        cmd.SetComputeTextureParam(deferredRayTracing, currentKernel, HDShaderIDs._DiffuseLightingTextureRW, intermediateBuffer3);

                        // Bind the output texture (it is used for accumulation read and write)
                        cmd.SetComputeTextureParam(deferredRayTracing, currentKernel, HDShaderIDs._RaytracingLitBufferRW, diffuseBufferRT);

                        // Compute the Lighting
                        cmd.DispatchCompute(deferredRayTracing, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);
                    }

                    // Grab the history buffer
                    RTHandle subsurfaceHistory = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RayTracedSubSurface)
                                                 ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RayTracedSubSurface, SubSurfaceHistoryBufferAllocatorFunction, 1);

                    // Check if we need to invalidate the history
                    float historyValidity = 1.0f;
#if UNITY_HDRP_DXR_TESTS_DEFINE
                    if (Application.isPlaying)
                    {
                        historyValidity = 0.0f;
                    }
                    else
#endif
                    // We need to check if something invalidated the history buffers
                    historyValidity *= ValidRayTracingHistory(hdCamera) ? 1.0f : 0.0f;

                    // Apply temporal filtering to the buffer
                    HDTemporalFilter temporalFilter = GetTemporalFilter();
                    temporalFilter.DenoiseBuffer(cmd, hdCamera, diffuseBufferRT, subsurfaceHistory, intermediateBuffer0, singleChannel: false, historyValidity: historyValidity);

                    // Push this version of the texture for debug
                    PushFullScreenDebugTexture(hdCamera, cmd, intermediateBuffer0, FullScreenDebugMode.RayTracedSubSurface);

                    // Combine it with the rest of the lighting
                    m_CombineLightingPass.SetTexture(HDShaderIDs._IrradianceSource, intermediateBuffer0);
                    HDUtils.DrawFullScreen(cmd, m_CombineLightingPass, colorBufferRT, depthStencilBufferRT, shaderPassId: 1);
                }
            }
            else
            {
                using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.SubsurfaceScattering)))
                {
                    var parameters = PrepareSubsurfaceScatteringParameters(hdCamera);
                    var resources  = new SubsurfaceScatteringResources();
                    resources.colorBuffer           = colorBufferRT;
                    resources.diffuseBuffer         = diffuseBufferRT;
                    resources.depthStencilBuffer    = depthStencilBufferRT;
                    resources.depthTexture          = depthTextureRT;
                    resources.cameraFilteringBuffer = m_SSSCameraFilteringBuffer;
                    resources.coarseStencilBuffer   = parameters.coarseStencilBuffer;
                    resources.sssBuffer             = m_SSSColor;

                    // For Jimenez we always need an extra buffer, for Disney it depends on platform
                    if (parameters.needTemporaryBuffer)
                    {
                        // Clear the SSS filtering target
                        using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.ClearSSSFilteringTarget)))
                        {
                            CoreUtils.SetRenderTarget(cmd, m_SSSCameraFilteringBuffer, ClearFlag.Color, Color.clear);
                        }
                    }

                    RenderSubsurfaceScattering(parameters, resources, cmd);
                }
            }
        }
 /// <summary>Compute the projection matrix based on the mode and settings provided.</summary>
 /// <returns>The projection matrix.</returns>
 public Matrix4x4 ComputeProjectionMatrix()
 {
     return(Matrix4x4.Perspective(HDUtils.ClampFOV(fieldOfView), aspect, nearClipPlane, farClipPlane));
 }
        public void UpdateEnvironment(HDCamera hdCamera, Light sunLight, int frameIndex, CommandBuffer cmd)
        {
            bool isRegularPreview = HDUtils.IsRegularPreviewCamera(hdCamera.camera);

            SkyAmbientMode ambientMode = VolumeManager.instance.stack.GetComponent <VisualEnvironment>().skyAmbientMode.value;

            // Preview should never use dynamic ambient or they will conflict with main view (async readback of sky texture will update ambient probe for main view one frame later)
            if (isRegularPreview)
            {
                ambientMode = SkyAmbientMode.Static;
            }

            m_CurrentSkyRenderingContext.UpdateEnvironment(m_CurrentSky, sunLight, hdCamera.mainViewConstants.worldSpaceCameraPos, m_UpdateRequired, ambientMode == SkyAmbientMode.Dynamic, frameIndex, cmd);
            StaticLightingSky staticLightingSky = GetStaticLightingSky();

            // We don't want to update the static sky during preview because it contains custom lights that may change the result.
            // The consequence is that previews will use main scene static lighting but we consider this to be acceptable.
            if (staticLightingSky != null && !isRegularPreview)
            {
                m_StaticLightingSky.skySettings = staticLightingSky.skySettings;
                m_StaticLightingSkyRenderingContext.UpdateEnvironment(m_StaticLightingSky, sunLight, hdCamera.mainViewConstants.worldSpaceCameraPos, false, true, frameIndex, cmd);
            }

            bool useRealtimeGI = true;

#if UNITY_EDITOR
            useRealtimeGI = UnityEditor.Lightmapping.realtimeGI;
#endif
            // Working around GI current system
            // When using baked lighting, setting up the ambient probe should be sufficient => We only need to update RenderSettings.ambientProbe with either the static or visual sky ambient probe (computed from GPU)
            // When using real time GI. Enlighten will pull sky information from Skybox material. So in order for dynamic GI to work, we update the skybox material texture and then set the ambient mode to SkyBox
            // Problem: We can't check at runtime if realtime GI is enabled so we need to take extra care (see useRealtimeGI usage below)
            RenderSettings.ambientMode = AmbientMode.Custom; // Needed to specify ourselves the ambient probe (this will update internal ambient probe data passed to shaders)
            if (ambientMode == SkyAmbientMode.Static)
            {
                RenderSettings.ambientProbe = GetStaticLightingAmbientProbe();
                m_StandardSkyboxMaterial.SetTexture("_Tex", GetStaticLightingTexture());
            }
            else
            {
                RenderSettings.ambientProbe = m_CurrentSkyRenderingContext.ambientProbe;
                // Workaround in the editor:
                // When in the editor, if we use baked lighting, we need to setup the skybox material with the static lighting texture otherwise when baking, the dynamic texture will be used
                if (useRealtimeGI)
                {
                    m_StandardSkyboxMaterial.SetTexture("_Tex", m_CurrentSky.IsValid() ? (Texture)m_CurrentSkyRenderingContext.cubemapRT : CoreUtils.blackCubeTexture);
                }
                else
                {
                    m_StandardSkyboxMaterial.SetTexture("_Tex", GetStaticLightingTexture());
                }
            }

            // This is only needed if we use realtime GI otherwise enlighten won't get the right sky information
            RenderSettings.skybox              = m_StandardSkyboxMaterial; // Setup this material as the default to be use in RenderSettings
            RenderSettings.ambientIntensity    = 1.0f;
            RenderSettings.ambientMode         = AmbientMode.Skybox;       // Force skybox for our HDRI
            RenderSettings.reflectionIntensity = 1.0f;
            RenderSettings.customReflection    = null;

            m_UpdateRequired = false;

            SetGlobalSkyTexture(cmd);
            if (IsLightingSkyValid())
            {
                cmd.SetGlobalInt(HDShaderIDs._EnvLightSkyEnabled, 1);
            }
            else
            {
                cmd.SetGlobalInt(HDShaderIDs._EnvLightSkyEnabled, 0);
            }
        }
        TextureHandle TraceSSGI(RenderGraph renderGraph, HDCamera hdCamera, GlobalIllumination giSettings, TextureHandle depthPyramid, TextureHandle normalBuffer, TextureHandle stencilBuffer, TextureHandle motionVectorsBuffer, ComputeBufferHandle lightList)
        {
            using (var builder = renderGraph.AddRenderPass <TraceSSGIPassData>("Trace SSGI", out var passData, ProfilingSampler.Get(HDProfileId.SSGITrace)))
            {
                builder.EnableAsyncCompute(false);

                //if (true)
                {
                    passData.texWidth  = hdCamera.actualWidth;
                    passData.texHeight = hdCamera.actualHeight;
                    passData.halfScreenSize.Set(passData.texWidth * 0.5f, passData.texHeight * 0.5f, 2.0f / passData.texWidth, 2.0f / passData.texHeight);
                }

                /*
                 * else
                 * {
                 *  passData.texWidth = hdCamera.actualWidth / 2;
                 *  passData.texHeight = hdCamera.actualHeight / 2;
                 *  passData.halfScreenSize.Set(passData.texWidth, passData.texHeight, 1.0f / passData.texWidth, 1.0f / passData.texHeight);
                 * }
                 */
                passData.viewCount = hdCamera.viewCount;

                // Set the generation parameters
                passData.nearClipPlane    = hdCamera.camera.nearClipPlane;
                passData.farClipPlane     = hdCamera.camera.farClipPlane;
                passData.fullResolutionSS = true;
                passData.thickness        = giSettings.depthBufferThickness.value;
                passData.raySteps         = giSettings.maxRaySteps;
                passData.frameIndex       = RayTracingFrameIndex(hdCamera, 16);
                passData.colorPyramidUvScaleAndLimitPrevFrame = HDUtils.ComputeViewportScaleAndLimit(hdCamera.historyRTHandleProperties.previousViewportSize, hdCamera.historyRTHandleProperties.previousRenderTargetSize);
                passData.fallbackHierarchy = (int)giSettings.fallbackHierarchy.value;

                // Grab the right kernel
                passData.ssGICS        = asset.renderPipelineResources.shaders.screenSpaceGlobalIlluminationCS;
                passData.traceKernel   = true ? m_TraceGlobalIlluminationKernel : m_TraceGlobalIlluminationHalfKernel;
                passData.projectKernel = true ? m_ReprojectGlobalIlluminationKernel : m_ReprojectGlobalIlluminationHalfKernel;

                BlueNoise blueNoise = GetBlueNoiseManager();
                passData.ditheredTextureSet          = blueNoise.DitheredTextureSet8SPP();
                passData.shaderVariablesRayTracingCB = m_ShaderVariablesRayTracingCB;
                passData.offsetBuffer = m_DepthBufferMipChainInfo.GetOffsetBufferData(m_DepthPyramidMipLevelOffsetsBuffer);

                passData.lightList     = builder.ReadComputeBuffer(lightList);
                passData.depthTexture  = builder.ReadTexture(depthPyramid);
                passData.normalBuffer  = builder.ReadTexture(normalBuffer);
                passData.stencilBuffer = builder.ReadTexture(stencilBuffer);

                if (!hdCamera.frameSettings.IsEnabled(FrameSettingsField.ObjectMotionVectors))
                {
                    passData.motionVectorsBuffer = builder.ReadTexture(renderGraph.defaultResources.blackTextureXR);
                }
                else
                {
                    passData.motionVectorsBuffer = builder.ReadTexture(motionVectorsBuffer);
                }

                // History buffers
                var colorPyramid = hdCamera.GetPreviousFrameRT((int)HDCameraFrameHistoryType.ColorBufferMipChain);
                passData.colorPyramid = colorPyramid != null?builder.ReadTexture(renderGraph.ImportTexture(colorPyramid)) : renderGraph.defaultResources.blackTextureXR;

                var historyDepth = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.Depth);
                passData.historyDepth = historyDepth != null?builder.ReadTexture(renderGraph.ImportTexture(historyDepth)) : renderGraph.defaultResources.blackTextureXR;

                // Temporary textures
                passData.hitPointBuffer = builder.CreateTransientTexture(new TextureDesc(Vector2.one, true, true)
                {
                    colorFormat = GraphicsFormat.R16G16_SFloat, enableRandomWrite = true, name = "SSGI Hit Point"
                });

                // Output textures
                passData.outputBuffer = builder.WriteTexture(renderGraph.CreateTexture(new TextureDesc(Vector2.one, true, true)
                {
                    colorFormat = GraphicsFormat.R16G16B16A16_SFloat, enableRandomWrite = true, name = "SSGI Color"
                }));

                builder.SetRenderFunc(
                    (TraceSSGIPassData data, RenderGraphContext ctx) =>
                {
                    ctx.cmd.SetGlobalBuffer(HDShaderIDs.g_vLightListGlobal, data.lightList);

                    int ssgiTileSize = 8;
                    int numTilesXHR  = (data.texWidth + (ssgiTileSize - 1)) / ssgiTileSize;
                    int numTilesYHR  = (data.texHeight + (ssgiTileSize - 1)) / ssgiTileSize;

                    // Inject all the input scalars
                    float n = data.nearClipPlane;
                    float f = data.farClipPlane;
                    float thicknessScale = 1.0f / (1.0f + data.thickness);
                    float thicknessBias  = -n / (f - n) * (data.thickness * thicknessScale);
                    ctx.cmd.SetComputeFloatParam(data.ssGICS, HDShaderIDs._RayMarchingThicknessScale, thicknessScale);
                    ctx.cmd.SetComputeFloatParam(data.ssGICS, HDShaderIDs._RayMarchingThicknessBias, thicknessBias);
                    ctx.cmd.SetComputeIntParam(data.ssGICS, HDShaderIDs._RayMarchingSteps, data.raySteps);
                    ctx.cmd.SetComputeIntParam(data.ssGICS, HDShaderIDs._RayMarchingReflectSky, 1);
                    ctx.cmd.SetComputeIntParam(data.ssGICS, HDShaderIDs._IndirectDiffuseFrameIndex, data.frameIndex);
                    // Inject half screen size if required
                    if (!data.fullResolutionSS)
                    {
                        ctx.cmd.SetComputeVectorParam(data.ssGICS, HDShaderIDs._HalfScreenSize, data.halfScreenSize);
                    }

                    // Inject the ray-tracing sampling data
                    BlueNoise.BindDitheredTextureSet(ctx.cmd, data.ditheredTextureSet);

                    // Inject all the input textures/buffers
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.traceKernel, HDShaderIDs._DepthTexture, data.depthTexture);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.traceKernel, HDShaderIDs._NormalBufferTexture, data.normalBuffer);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.traceKernel, HDShaderIDs._IndirectDiffuseHitPointTextureRW, data.hitPointBuffer);
                    ctx.cmd.SetComputeBufferParam(data.ssGICS, data.traceKernel, HDShaderIDs._DepthPyramidMipLevelOffsets, data.offsetBuffer);

                    // Do the ray marching
                    ctx.cmd.DispatchCompute(data.ssGICS, data.traceKernel, numTilesXHR, numTilesYHR, data.viewCount);

                    // Update global constant buffer.
                    // This should probably be a shader specific uniform instead of reusing the global constant buffer one since it's the only one updated here.
                    ConstantBuffer.PushGlobal(ctx.cmd, data.shaderVariablesRayTracingCB, HDShaderIDs._ShaderVariablesRaytracing);

                    // Inject all the input scalars
                    ctx.cmd.SetComputeVectorParam(data.ssGICS, HDShaderIDs._ColorPyramidUvScaleAndLimitPrevFrame, data.colorPyramidUvScaleAndLimitPrevFrame);
                    ctx.cmd.SetComputeIntParam(data.ssGICS, HDShaderIDs._ObjectMotionStencilBit, (int)StencilUsage.ObjectMotionVector);
                    ctx.cmd.SetComputeIntParam(data.ssGICS, HDShaderIDs._RayMarchingFallbackHierarchy, data.fallbackHierarchy);

                    // Bind all the input buffers
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._DepthTexture, data.depthTexture);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._StencilTexture, data.stencilBuffer, 0, RenderTextureSubElement.Stencil);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._NormalBufferTexture, data.normalBuffer);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._CameraMotionVectorsTexture, data.motionVectorsBuffer);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._IndirectDiffuseHitPointTexture, data.hitPointBuffer);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._ColorPyramidTexture, data.colorPyramid);
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._HistoryDepthTexture, data.historyDepth);
                    ctx.cmd.SetComputeBufferParam(data.ssGICS, data.projectKernel, HDShaderIDs._DepthPyramidMipLevelOffsets, data.offsetBuffer);

                    // Bind the output texture
                    ctx.cmd.SetComputeTextureParam(data.ssGICS, data.projectKernel, HDShaderIDs._IndirectDiffuseTextureRW, data.outputBuffer);

                    // Do the reprojection
                    ctx.cmd.DispatchCompute(data.ssGICS, data.projectKernel, numTilesXHR, numTilesYHR, data.viewCount);
                });

                return(passData.outputBuffer);
            }
        }
Exemple #20
0
        void RenderDirectionalLightScreenSpaceShadow(CommandBuffer cmd, HDCamera hdCamera)
        {
            // Render directional screen space shadow if required
            if (m_CurrentSunLightAdditionalLightData != null && m_CurrentSunLightAdditionalLightData.WillRenderScreenSpaceShadow())
            {
#if ENABLE_RAYTRACING
                // Grab the ray tracing environment
                HDRaytracingEnvironment rtEnvironment = m_RayTracingManager.CurrentEnvironment();

                // If the shadow is flagged as ray traced, we need to evaluate it completely
                if (rtEnvironment != null && hdCamera.frameSettings.IsEnabled(FrameSettingsField.RayTracing) &&
                    m_CurrentSunLightAdditionalLightData.WillRenderRayTracedShadow())
                {
                    // Texture dimensions
                    int texWidth  = hdCamera.actualWidth;
                    int texHeight = hdCamera.actualHeight;

                    // Evaluate the dispatch parameters
                    int areaTileSize = 8;
                    int numTilesX    = (texWidth + (areaTileSize - 1)) / areaTileSize;
                    int numTilesY    = (texHeight + (areaTileSize - 1)) / areaTileSize;

                    // Clear the integration texture
                    cmd.SetComputeTextureParam(m_ScreenSpaceShadowsCS, m_ClearShadowTexture, HDShaderIDs._RaytracedDirectionalShadowIntegration, m_ShadowIntermediateBufferRGBA0);
                    cmd.DispatchCompute(m_ScreenSpaceShadowsCS, m_ClearShadowTexture, numTilesX, numTilesY, 1);

                    // Grab and bind the acceleration structure for the target camera
                    RayTracingAccelerationStructure accelerationStructure = m_RayTracingManager.RequestAccelerationStructure(rtEnvironment.shadowLayerMask);
                    cmd.SetRayTracingAccelerationStructure(m_ScreenSpaceShadowsRT, HDShaderIDs._RaytracingAccelerationStructureName, accelerationStructure);

                    // Inject the ray-tracing sampling data
                    m_BlueNoise.BindDitheredRNGData8SPP(cmd);

                    // Compute the current frame index
                    int frameIndex = hdCamera.IsTAAEnabled() ? hdCamera.taaFrameIndex : (int)m_FrameCount % 8;
                    cmd.SetComputeIntParam(m_ScreenSpaceShadowsCS, HDShaderIDs._RaytracingFrameIndex, frameIndex);

                    // Inject the ray generation data
                    cmd.SetGlobalFloat(HDShaderIDs._RaytracingRayBias, rtEnvironment.rayBias);

                    // Loop through the samples of this frame
                    for (int sampleIdx = 0; sampleIdx < m_CurrentSunLightAdditionalLightData.numRayTracingSamples; ++sampleIdx)
                    {
                        // Bind the light & sampling data
                        cmd.SetComputeBufferParam(m_ScreenSpaceShadowsCS, m_RaytracingDirectionalShadowSample, HDShaderIDs._DirectionalLightDatas, m_LightLoopLightData.directionalLightData);
                        cmd.SetComputeIntParam(m_ScreenSpaceShadowsCS, HDShaderIDs._DirectionalShadowIndex, m_CurrentShadowSortedSunLightIndex);
                        cmd.SetComputeFloatParam(m_ScreenSpaceShadowsCS, HDShaderIDs._DirectionalLightAngle, m_CurrentSunLightAdditionalLightData.sunLightConeAngle);
                        cmd.SetComputeIntParam(m_ScreenSpaceShadowsCS, HDShaderIDs._RaytracingSampleIndex, sampleIdx);
                        cmd.SetComputeIntParam(m_ScreenSpaceShadowsCS, HDShaderIDs._RaytracingNumSamples, m_CurrentSunLightAdditionalLightData.numRayTracingSamples);

                        // Input Buffer
                        cmd.SetComputeTextureParam(m_ScreenSpaceShadowsCS, m_RaytracingDirectionalShadowSample, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetComputeTextureParam(m_ScreenSpaceShadowsCS, m_RaytracingDirectionalShadowSample, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());

                        // Output buffer
                        cmd.SetComputeTextureParam(m_ScreenSpaceShadowsCS, m_RaytracingDirectionalShadowSample, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);

                        // Generate a new direction
                        cmd.DispatchCompute(m_ScreenSpaceShadowsCS, m_RaytracingDirectionalShadowSample, numTilesX, numTilesY, 1);

                        // Define the shader pass to use for the shadow pass
                        cmd.SetRayTracingShaderPass(m_ScreenSpaceShadowsRT, "VisibilityDXR");

                        // Set ray count texture
                        cmd.SetRayTracingIntParam(m_ScreenSpaceShadowsRT, HDShaderIDs._RayCountEnabled, m_RayTracingManager.rayCountManager.RayCountIsEnabled());
                        cmd.SetRayTracingTextureParam(m_ScreenSpaceShadowsRT, HDShaderIDs._RayCountTexture, m_RayTracingManager.rayCountManager.GetRayCountTexture());

                        // Input buffers
                        cmd.SetRayTracingTextureParam(m_ScreenSpaceShadowsRT, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetRayTracingTextureParam(m_ScreenSpaceShadowsRT, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                        cmd.SetRayTracingTextureParam(m_ScreenSpaceShadowsRT, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                        cmd.SetRayTracingIntParam(m_ScreenSpaceShadowsRT, HDShaderIDs._RaytracingNumSamples, m_CurrentSunLightAdditionalLightData.numRayTracingSamples);

                        // Output buffer
                        cmd.SetRayTracingTextureParam(m_ScreenSpaceShadowsRT, HDShaderIDs._RaytracedDirectionalShadowIntegration, m_ShadowIntermediateBufferRGBA0);

                        // Evaluate the visibility
                        cmd.DispatchRays(m_ScreenSpaceShadowsRT, m_RayGenDirectionalShadowSingleName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);
                    }

                    // Grab the history buffer for shadows
                    RTHandle shadowHistoryArray = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedShadow)
                                                  ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedShadow, ShadowHistoryBufferAllocatorFunction, 1);

                    // Apply the simple denoiser (if required)
                    if (m_CurrentSunLightAdditionalLightData.filterTracedShadow)
                    {
                        // Apply the temporal denoiser
                        HDTemporalFilter temporalFilter = m_RayTracingManager.GetTemporalFilter();
                        temporalFilter.DenoiseBuffer(cmd, hdCamera, m_ShadowIntermediateBufferRGBA0, shadowHistoryArray, m_ShadowIntermediateBufferRGBA1, singleChannel: true, slotIndex: m_CurrentSunLightDirectionalLightData.screenSpaceShadowIndex);

                        // Apply the spatial denoiser
                        HDSimpleDenoiser simpleDenoiser = m_RayTracingManager.GetSimpleDenoiser();
                        simpleDenoiser.DenoiseBufferNoHistory(cmd, hdCamera, m_ShadowIntermediateBufferRGBA1, m_ShadowIntermediateBufferRGBA0, m_CurrentSunLightAdditionalLightData.filterSizeTraced, singleChannel: true);
                    }

                    cmd.SetComputeTextureParam(m_ScreenSpaceShadowsCS, m_OutputShadowTextureKernel, HDShaderIDs._RaytracedDirectionalShadowIntegration, m_ShadowIntermediateBufferRGBA0);
                    cmd.SetComputeTextureParam(m_ScreenSpaceShadowsCS, m_OutputShadowTextureKernel, HDShaderIDs._ScreenSpaceShadowsTextureRW, m_ScreenSpaceShadowTextureArray);
                    cmd.SetComputeIntParam(m_ScreenSpaceShadowsCS, HDShaderIDs._RaytracingShadowSlot, m_CurrentSunLightDirectionalLightData.screenSpaceShadowIndex);
                    cmd.DispatchCompute(m_ScreenSpaceShadowsCS, m_OutputShadowTextureKernel, numTilesX, numTilesY, 1);
                }
                else
#endif
                {
                    // If it is screen space but not ray traced, then we can rely on the shadow map
                    CoreUtils.SetRenderTarget(cmd, m_ScreenSpaceShadowTextureArray, depthSlice: m_CurrentSunLightDirectionalLightData.screenSpaceShadowIndex);
                    HDUtils.DrawFullScreen(cmd, s_ScreenSpaceShadowsMat, m_ScreenSpaceShadowTextureArray);
                }
            }
        }
Exemple #21
0
        void RenderDirectionalLightScreenSpaceShadow(CommandBuffer cmd, HDCamera hdCamera, int frameCount)
        {
            // Render directional screen space shadow if required
            if (m_CurrentSunLightAdditionalLightData != null && m_CurrentSunLightAdditionalLightData.WillRenderScreenSpaceShadow())
            {
#if ENABLE_RAYTRACING
                // Grab the ray tracing environment
                HDRaytracingEnvironment rtEnvironment = m_RayTracingManager.CurrentEnvironment();

                // If the shadow is flagged as ray traced, we need to evaluate it completely
                if (rtEnvironment != null && hdCamera.frameSettings.IsEnabled(FrameSettingsField.RayTracing) && m_CurrentSunLightAdditionalLightData.WillRenderRayTracedShadow())
                {
                    BlueNoise        blueNoise      = m_RayTracingManager.GetBlueNoiseManager();
                    ComputeShader    shadowsCompute = m_Asset.renderPipelineRayTracingResources.shadowRaytracingCS;
                    RayTracingShader shadowRayTrace = m_Asset.renderPipelineRayTracingResources.shadowRaytracingRT;

                    // Texture dimensions
                    int texWidth  = hdCamera.actualWidth;
                    int texHeight = hdCamera.actualHeight;

                    // Evaluate the dispatch parameters
                    int areaTileSize = 8;
                    int numTilesX    = (texWidth + (areaTileSize - 1)) / areaTileSize;
                    int numTilesY    = (texHeight + (areaTileSize - 1)) / areaTileSize;

                    int shadowComputeKernel = shadowsCompute.FindKernel("ClearShadowTexture");
                    cmd.SetComputeBufferParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._LightDatas, m_LightLoopLightData.lightData);
                    cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracedDirectionalShadowIntegration, m_DenoiseBuffer0);
                    cmd.DispatchCompute(shadowsCompute, shadowComputeKernel, numTilesX, numTilesY, 1);

                    // Inject the ray-tracing sampling data
                    blueNoise.BindDitheredRNGData8SPP(cmd);

                    for (int i = 0; i < m_CurrentSunLightAdditionalLightData.numRayTracingSamples; ++i)
                    {
                        shadowComputeKernel = shadowsCompute.FindKernel("RaytracingDirectionalShadowSample");

                        int frameIndex = hdCamera.IsTAAEnabled() ? hdCamera.taaFrameIndex : (int)frameCount % 8;

                        // This pass evaluates the analytic value and the generates and outputs the first sample
                        cmd.SetComputeBufferParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._LightDatas, m_LightLoopLightData.lightData);
                        cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingFrameIndex, frameIndex);
                        cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingNumSamples, m_CurrentSunLightAdditionalLightData.numRayTracingSamples);
                        cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingSampleIndex, i);
                        cmd.SetComputeMatrixParam(shadowsCompute, HDShaderIDs._RaytracingAreaWorldToLocal, worldToLocalArea);
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracedDirectionalShadowIntegration, m_DenoiseBuffer0);
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                        cmd.SetComputeFloatParam(shadowsCompute, HDShaderIDs._DirectionalLightAngle, m_CurrentSunLightAdditionalLightData.sunLightConeAngle);

                        cmd.DispatchCompute(shadowsCompute, shadowComputeKernel, numTilesX, numTilesY, 1);

                        // Grab the acceleration structure for the target camera
                        RayTracingAccelerationStructure accelerationStructure = m_RayTracingManager.RequestAccelerationStructure(rtEnvironment.shadowLayerMask);

                        // Define the shader pass to use for the reflection pass
                        cmd.SetRayTracingShaderPass(shadowRayTrace, "VisibilityDXR");

                        // Set the acceleration structure for the pass
                        cmd.SetRayTracingAccelerationStructure(shadowRayTrace, HDShaderIDs._RaytracingAccelerationStructureName, accelerationStructure);

                        // Set ray count texture
                        // This pass will use the previously generated sample and add it to the integration buffer
                        cmd.SetRayTracingTextureParam(shadowRayTrace, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetRayTracingTextureParam(shadowRayTrace, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                        cmd.SetRayTracingIntParam(shadowRayTrace, HDShaderIDs._RayCountEnabled, m_RayTracingManager.rayCountManager.RayCountIsEnabled());
                        cmd.SetRayTracingTextureParam(shadowRayTrace, HDShaderIDs._RayCountTexture, m_RayTracingManager.rayCountManager.GetRayCountTexture());
                        cmd.SetRayTracingTextureParam(shadowRayTrace, HDShaderIDs._RaytracedDirectionalShadowIntegration, m_DenoiseBuffer0);
                        cmd.SetRayTracingTextureParam(shadowRayTrace, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                        cmd.SetRayTracingFloatParam(shadowRayTrace, HDShaderIDs._DirectionalLightAngle, m_CurrentSunLightAdditionalLightData.sunLightConeAngle);
                        cmd.SetRayTracingIntParam(shadowRayTrace, HDShaderIDs._RaytracingNumSamples, 1);
                        cmd.DispatchRays(shadowRayTrace, m_RayGenDirectionalShadowSingleName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);
                    }

                    RTHandle shadowHistoryArray = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedShadow)
                                                  ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedShadow, ShadowHistoryBufferAllocatorFunction, 1);

                    // Apply the simple denoiser (if required)
                    if (m_CurrentSunLightAdditionalLightData.filterTracedShadow)
                    {
                        // Apply the temporal denoiser
                        HDTemporalFilter temporalFilter = m_RayTracingManager.GetTemporalFilter();
                        temporalFilter.DenoiseBuffer(cmd, hdCamera, m_DenoiseBuffer0, shadowHistoryArray, m_DenoiseBuffer1, singleChannel: true, slotIndex: m_CurrentSunLightDirectionalLightData.screenSpaceShadowIndex);

                        // Apply the spatial denoiser
                        HDSimpleDenoiser simpleDenoiser = m_RayTracingManager.GetSimpleDenoiser();
                        simpleDenoiser.DenoiseBufferNoHistory(cmd, hdCamera, m_DenoiseBuffer1, m_DenoiseBuffer0, m_CurrentSunLightAdditionalLightData.filterSizeTraced, singleChannel: true);
                    }

                    shadowComputeKernel = shadowsCompute.FindKernel("OutputShadowTexture");
                    cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracedDirectionalShadowIntegration, m_DenoiseBuffer0);
                    cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._ScreenSpaceShadowsTextureRW, m_ScreenSpaceShadowTextureArray);
                    cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingShadowSlot, m_CurrentSunLightDirectionalLightData.screenSpaceShadowIndex);
                    cmd.DispatchCompute(shadowsCompute, shadowComputeKernel, numTilesX, numTilesY, 1);
                }
                else
#endif
                {
                    // If it is screen space but not ray traced, then we can rely on the shadow map
                    CoreUtils.SetRenderTarget(cmd, m_ScreenSpaceShadowTextureArray, depthSlice: m_CurrentSunLightDirectionalLightData.screenSpaceShadowIndex);
                    HDUtils.DrawFullScreen(cmd, s_ScreenSpaceShadowsMat, m_ScreenSpaceShadowTextureArray);
                }
            }
        }
Exemple #22
0
        void OnEnable()
        {
            InitMaterial();

            if (m_Handle != null)
            {
                DecalSystem.instance.RemoveDecal(m_Handle);
                m_Handle = null;
            }

            Matrix4x4 sizeOffset = Matrix4x4.Translate(decalOffset) * Matrix4x4.Scale(decalSize);

            m_Handle      = DecalSystem.instance.AddDecal(position, rotation, Vector3.one, sizeOffset, m_DrawDistance, m_FadeScale, uvScaleBias, m_AffectsTransparency, m_Material, gameObject.layer, HDUtils.GetSceneCullingMaskFromGameObject(gameObject), m_FadeFactor);
            m_OldMaterial = m_Material;

#if UNITY_EDITOR
            m_Layer = gameObject.layer;
            // Handle scene visibility
            UnityEditor.SceneVisibilityManager.visibilityChanged += UpdateDecalVisibility;
#endif
        }
Exemple #23
0
        void RenderIndirectDiffusePerformance(HDCamera hdCamera, CommandBuffer cmd, ScriptableRenderContext renderContext, int frameCount)
        {
            // Fetch the required resources
            var       settings  = hdCamera.volumeStack.GetComponent <GlobalIllumination>();
            BlueNoise blueNoise = GetBlueNoiseManager();

            // Fetch all the settings
            LightCluster       lightClusterSettings = hdCamera.volumeStack.GetComponent <LightCluster>();
            RayTracingSettings rtSettings           = hdCamera.volumeStack.GetComponent <RayTracingSettings>();

            ComputeShader indirectDiffuseCS = m_Asset.renderPipelineRayTracingResources.indirectDiffuseRaytracingCS;

            // Request the intermediate texture we will be using
            RTHandle directionBuffer     = GetRayTracingBuffer(InternalRayTracingBuffers.Direction);
            RTHandle intermediateBuffer1 = GetRayTracingBuffer(InternalRayTracingBuffers.RGBA1);

            using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.RaytracingIntegrateIndirectDiffuse)))
            {
                // Fetch the new sample kernel
                int currentKernel = indirectDiffuseCS.FindKernel(settings.fullResolution.value ? "RaytracingIndirectDiffuseFullRes" : "RaytracingIndirectDiffuseHalfRes");

                // Inject the ray-tracing sampling data
                blueNoise.BindDitheredRNGData8SPP(cmd);

                // Bind all the required textures
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());

                // Bind all the required scalars
                cmd.SetGlobalFloat(HDShaderIDs._RaytracingIntensityClamp, settings.clampValue.value);

                // Bind the output buffers
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._RaytracingDirectionBuffer, directionBuffer);

                // Texture dimensions
                int texWidth  = hdCamera.actualWidth;
                int texHeight = hdCamera.actualHeight;

                // Evaluate the dispatch parameters
                int areaTileSize = 8;
                int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
                int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;

                // Compute the directions
                cmd.DispatchCompute(indirectDiffuseCS, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                // Prepare the components for the deferred lighting
                DeferredLightingRTParameters deferredParamters = PrepareIndirectDiffuseDeferredLightingRTParameters(hdCamera);
                DeferredLightingRTResources  deferredResources = PrepareDeferredLightingRTResources(hdCamera, directionBuffer, m_IndirectDiffuseBuffer);

                // Evaluate the deferred lighting
                RenderRaytracingDeferredLighting(cmd, deferredParamters, deferredResources);
            }

            using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.RaytracingFilterIndirectDiffuse)))
            {
                // Fetch the right filter to use
                int currentKernel = indirectDiffuseCS.FindKernel(settings.fullResolution.value ? "IndirectDiffuseIntegrationUpscaleFullRes" : "IndirectDiffuseIntegrationUpscaleHalfRes");

                // Inject all the parameters for the compute
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._IndirectDiffuseTexture, m_IndirectDiffuseBuffer);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._RaytracingDirectionBuffer, directionBuffer);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._BlueNoiseTexture, blueNoise.textureArray16RGB);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._UpscaledIndirectDiffuseTextureRW, intermediateBuffer1);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._ScramblingTexture, m_Asset.renderPipelineResources.textures.scramblingTex);
                cmd.SetComputeIntParam(indirectDiffuseCS, HDShaderIDs._SpatialFilterRadius, settings.upscaleRadius.value);

                // Texture dimensions
                int texWidth  = hdCamera.actualWidth;
                int texHeight = hdCamera.actualHeight;

                // Evaluate the dispatch parameters
                int areaTileSize = 8;
                int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
                int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;

                // Compute the texture
                cmd.DispatchCompute(indirectDiffuseCS, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                // Copy the data back to the right buffer
                HDUtils.BlitCameraTexture(cmd, intermediateBuffer1, m_IndirectDiffuseBuffer);

                // Denoise if required
                if (settings.denoise.value)
                {
                    DenoiseIndirectDiffuseBuffer(hdCamera, cmd, settings);
                }
            }
        }
Exemple #24
0
 void UpdateDecalVisibility()
 {
     // Fade out the decal when it is hidden by the scene visibility
     if (UnityEditor.SceneVisibilityManager.instance.IsHidden(gameObject) && m_Handle != null)
     {
         DecalSystem.instance.RemoveDecal(m_Handle);
         m_Handle = null;
     }
     else if (m_Handle == null)
     {
         Matrix4x4 sizeOffset = Matrix4x4.Translate(decalOffset) * Matrix4x4.Scale(decalSize);
         m_Handle = DecalSystem.instance.AddDecal(position, rotation, Vector3.one, sizeOffset, m_DrawDistance, m_FadeScale, uvScaleBias, m_AffectsTransparency, m_Material, gameObject.layer, HDUtils.GetSceneCullingMaskFromGameObject(gameObject), m_FadeFactor);
     }
 }
        void RenderSSGI(HDCamera hdCamera, CommandBuffer cmd, ScriptableRenderContext renderContext, int frameCount)
        {
            // Grab the global illumination volume component
            GlobalIllumination giSettings = hdCamera.volumeStack.GetComponent <GlobalIllumination>();

            // Grab the noise texture manager
            BlueNoise blueNoise = GetBlueNoiseManager();

            // Grab the shaders we shall be using
            ComputeShader ssGICS = m_Asset.renderPipelineResources.shaders.screenSpaceGlobalIlluminationCS;

            // Evaluate the dispatch parameters
            int texWidth, texHeight;

            if (giSettings.fullResolutionSS)
            {
                texWidth  = hdCamera.actualWidth;
                texHeight = hdCamera.actualHeight;
                halfScreenSize.Set(texWidth * 0.5f, texHeight * 0.5f, 2.0f / texWidth, 2.0f / texHeight);
            }
            else
            {
                texWidth  = hdCamera.actualWidth / 2;
                texHeight = hdCamera.actualHeight / 2;
                halfScreenSize.Set(texWidth, texHeight, 1.0f / texWidth, 1.0f / texHeight);
            }
            int areaTileSize = 8;
            int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
            int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;

            // Based on if we are doing it in half resolution or full, we need to define initial and final buffer to avoid a useless blit
            RTHandle buffer0, buffer1;

            if (!giSettings.fullResolutionSS)
            {
                buffer0 = m_IndirectDiffuseBuffer0;
                buffer1 = m_IndirectDiffuseBuffer1;
            }
            else
            {
                buffer0 = m_IndirectDiffuseBuffer1;
                buffer1 = m_IndirectDiffuseBuffer0;
            }

            using (new ProfilingScope(cmd, ProfilingSampler.Get(HDProfileId.SsgiPass)))
            {
                // Fetch the right tracing kernel
                int currentKernel = giSettings.fullResolutionSS ? m_TraceGlobalIlluminationKernel : m_TraceGlobalIlluminationHalfKernel;

                // Inject all the input scalars
                float n              = hdCamera.camera.nearClipPlane;
                float f              = hdCamera.camera.farClipPlane;
                float thickness      = giSettings.depthBufferThickness.value;
                float thicknessScale = 1.0f / (1.0f + thickness);
                float thicknessBias  = -n / (f - n) * (thickness * thicknessScale);
                cmd.SetComputeFloatParam(ssGICS, HDShaderIDs._IndirectDiffuseThicknessScale, thicknessScale);
                cmd.SetComputeFloatParam(ssGICS, HDShaderIDs._IndirectDiffuseThicknessBias, thicknessBias);
                cmd.SetComputeIntParam(ssGICS, HDShaderIDs._IndirectDiffuseSteps, giSettings.raySteps);
                cmd.SetComputeFloatParam(ssGICS, HDShaderIDs._IndirectDiffuseMaximalRadius, giSettings.maximalRadius);
                // Inject half screen size if required
                if (!giSettings.fullResolutionSS)
                {
                    cmd.SetComputeVectorParam(ssGICS, HDShaderIDs._HalfScreenSize, halfScreenSize);
                }

                // Inject the ray-tracing sampling data
                blueNoise.BindDitheredRNGData1SPP(cmd);

                // Inject all the input textures/buffers
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthTexture());
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._IndirectDiffuseHitPointTextureRW, m_IndirectDiffuseHitPointBuffer);
                var info = m_SharedRTManager.GetDepthBufferMipChainInfo();
                cmd.SetComputeBufferParam(ssGICS, currentKernel, HDShaderIDs._DepthPyramidMipLevelOffsets, info.GetOffsetBufferData(m_DepthPyramidMipLevelOffsetsBuffer));
                cmd.SetGlobalBuffer(HDShaderIDs.g_vLightListGlobal, m_TileAndClusterData.lightList);

                // Do the ray marching
                cmd.DispatchCompute(ssGICS, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                // Fetch the right kernel to use
                currentKernel = giSettings.fullResolutionSS ? m_ReprojectGlobalIlluminationKernel : m_ReprojectGlobalIlluminationHalfKernel;

                // Update global constant buffer.
                // This should probably be a shader specific uniform instead of reusing the global constant buffer one since it's the only one udpated here.
                m_ShaderVariablesRayTracingCB._RaytracingIntensityClamp = giSettings.clampValueSS;
                ConstantBuffer.PushGlobal(cmd, m_ShaderVariablesRayTracingCB, HDShaderIDs._ShaderVariablesRaytracing);

                // Inject all the input scalars
                cmd.SetComputeVectorParam(ssGICS, HDShaderIDs._ColorPyramidUvScaleAndLimitPrevFrame, HDUtils.ComputeViewportScaleAndLimit(hdCamera.historyRTHandleProperties.previousViewportSize, hdCamera.historyRTHandleProperties.previousRenderTargetSize));

                // Bind all the input buffers
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._IndirectDiffuseHitPointTexture, m_IndirectDiffuseHitPointBuffer);
                var previousColorPyramid = hdCamera.GetPreviousFrameRT((int)HDCameraFrameHistoryType.ColorBufferMipChain);
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._ColorPyramidTexture, previousColorPyramid != null ? previousColorPyramid : TextureXR.GetBlackTexture());
                var historyDepthBuffer = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.Depth);
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._HistoryDepthTexture, historyDepthBuffer != null ? historyDepthBuffer : TextureXR.GetBlackTexture());
                cmd.SetComputeBufferParam(ssGICS, currentKernel, HDShaderIDs._DepthPyramidMipLevelOffsets, info.GetOffsetBufferData(m_DepthPyramidMipLevelOffsetsBuffer));

                // Bind the output texture
                cmd.SetComputeTextureParam(ssGICS, currentKernel, HDShaderIDs._IndirectDiffuseTextureRW, buffer1);

                // Do the reprojection
                cmd.DispatchCompute(ssGICS, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                float historyValidity = 1.0f;
#if UNITY_HDRP_DXR_TESTS_DEFINE
                if (Application.isPlaying)
                {
                    historyValidity = 0.0f;
                }
                else
#endif
                // We need to check if something invalidated the history buffers
                historyValidity *= ValidRayTracingHistory(hdCamera) ? 1.0f : 0.0f;

                // Do the denoising part
                SSGIDenoiser ssgiDenoiser = GetSSGIDenoiser();
                ssgiDenoiser.Denoise(cmd, hdCamera, buffer1, buffer0, halfResolution: !giSettings.fullResolutionSS, historyValidity: historyValidity);

                // If this was a half resolution effect, we still have to upscale it
                if (!giSettings.fullResolutionSS)
                {
                    ComputeShader bilateralUpsampleCS = m_Asset.renderPipelineResources.shaders.bilateralUpsampleCS;

                    // Re-evaluate the dispatch parameters (we are evaluating the upsample in full resolution)
                    numTilesXHR = (hdCamera.actualWidth + (areaTileSize - 1)) / areaTileSize;
                    numTilesYHR = (hdCamera.actualHeight + (areaTileSize - 1)) / areaTileSize;

                    // Inject the input scalars
                    cmd.SetComputeVectorParam(bilateralUpsampleCS, HDShaderIDs._HalfScreenSize, halfScreenSize);
                    firstMipOffset.Set(HDShadowUtils.Asfloat((uint)info.mipLevelOffsets[1].x), HDShadowUtils.Asfloat((uint)info.mipLevelOffsets[1].y));
                    cmd.SetComputeVectorParam(bilateralUpsampleCS, HDShaderIDs._DepthPyramidFirstMipLevelOffset, firstMipOffset);

                    // Inject all the input buffers
                    cmd.SetComputeTextureParam(bilateralUpsampleCS, m_BilateralUpSampleColorTMKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthTexture());
                    cmd.SetComputeTextureParam(bilateralUpsampleCS, m_BilateralUpSampleColorTMKernel, HDShaderIDs._LowResolutionTexture, buffer1);
                    cmd.SetComputeBufferParam(bilateralUpsampleCS, m_BilateralUpSampleColorTMKernel, HDShaderIDs._DepthPyramidMipLevelOffsets, info.GetOffsetBufferData(m_DepthPyramidMipLevelOffsetsBuffer));

                    // Inject the output textures
                    cmd.SetComputeTextureParam(bilateralUpsampleCS, m_BilateralUpSampleColorTMKernel, HDShaderIDs._OutputUpscaledTexture, buffer0);

                    // Upscale the buffer to full resolution
                    cmd.DispatchCompute(bilateralUpsampleCS, m_BilateralUpSampleColorTMKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);
                }

                (RenderPipelineManager.currentPipeline as HDRenderPipeline).PushFullScreenDebugTexture(hdCamera, cmd, m_IndirectDiffuseBuffer0, FullScreenDebugMode.ScreenSpaceGlobalIllumination);
            }
        }
Exemple #26
0
        internal void OnValidate()
        {
            if (m_Handle != null) // don't do anything if OnEnable hasn't been called yet when scene is loading.
            {
                if (m_Material == null)
                {
                    DecalSystem.instance.RemoveDecal(m_Handle);
                }

                Matrix4x4 sizeOffset = Matrix4x4.Translate(decalOffset) * Matrix4x4.Scale(decalSize);
                // handle material changes, because decals are stored as sets sorted by material, if material changes decal needs to be removed and re-added to that it goes into correct set
                if (m_OldMaterial != m_Material)
                {
                    DecalSystem.instance.RemoveDecal(m_Handle);

                    if (m_Material != null)
                    {
                        m_Handle = DecalSystem.instance.AddDecal(position, rotation, Vector3.one, sizeOffset, m_DrawDistance, m_FadeScale, uvScaleBias, m_AffectsTransparency, m_Material, gameObject.layer, HDUtils.GetSceneCullingMaskFromGameObject(gameObject), m_FadeFactor);

                        if (!DecalSystem.IsHDRenderPipelineDecal(m_Material.shader)) // non HDRP/decal shaders such as shader graph decal do not affect transparency
                        {
                            m_AffectsTransparency = false;
                        }
                    }

                    // notify the editor that material has changed so it can update the shader foldout
                    if (OnMaterialChange != null)
                    {
                        OnMaterialChange();
                    }

                    m_OldMaterial = m_Material;
                }
                else // no material change, just update whatever else changed
                {
                    DecalSystem.instance.UpdateCachedData(position, rotation, sizeOffset, m_DrawDistance, m_FadeScale, uvScaleBias, m_AffectsTransparency, m_Handle, gameObject.layer, HDUtils.GetSceneCullingMaskFromGameObject(gameObject), m_FadeFactor);
                }
            }
        }
        internal void EvictLight(HDAdditionalLightData lightData)
        {
            m_RegisteredLightDataPendingPlacement.Remove(lightData.lightIdxForCachedShadows);
            RemoveTransformFromCache(lightData);

            int numberOfShadows = (lightData.type == HDLightType.Point) ? 6 : 1;

            int lightIdx = lightData.lightIdxForCachedShadows;

            lightData.lightIdxForCachedShadows = -1;

            for (int i = 0; i < numberOfShadows; ++i)
            {
                bool valueFound = false;
                int  shadowIdx  = lightIdx + i;

                m_RecordsPendingPlacement.Remove(shadowIdx);

                valueFound = m_PlacedShadows.TryGetValue(shadowIdx, out CachedShadowRecord recordToRemove);

                if (valueFound)
                {
#if UNITY_2020_2_OR_NEWER
                    lightData.legacyLight.useViewFrustumForShadowCasterCull = true;
#endif
                    m_PlacedShadows.Remove(shadowIdx);
                    m_ShadowsPendingRendering.Remove(shadowIdx);

                    MarkEntries((int)recordToRemove.offsetInAtlas.z, (int)recordToRemove.offsetInAtlas.w, HDUtils.DivRoundUp(recordToRemove.viewportSize, m_MinSlotSize), false);
                    m_CanTryPlacement = true;
                }
            }
        }
Exemple #28
0
 void Update() // only run in editor
 {
     if (m_Layer != gameObject.layer)
     {
         Matrix4x4 sizeOffset = Matrix4x4.Translate(decalOffset) * Matrix4x4.Scale(decalSize);
         m_Layer = gameObject.layer;
         DecalSystem.instance.UpdateCachedData(position, rotation, sizeOffset, m_DrawDistance, m_FadeScale, uvScaleBias, m_AffectsTransparency, m_Handle, gameObject.layer, HDUtils.GetSceneCullingMaskFromGameObject(gameObject), m_FadeFactor);
     }
 }
Exemple #29
0
        public void RenderReflectionsT1(HDCamera hdCamera, CommandBuffer cmd, RTHandle outputTexture, ScriptableRenderContext renderContext, int frameCount)
        {
            // Fetch the required resources
            HDRaytracingEnvironment rtEnvironment = m_RayTracingManager.CurrentEnvironment();
            BlueNoise        blueNoise            = m_RayTracingManager.GetBlueNoiseManager();
            RayTracingShader reflectionShaderRT   = m_Asset.renderPipelineRayTracingResources.reflectionRaytracingRT;
            ComputeShader    reflectionShaderCS   = m_Asset.renderPipelineRayTracingResources.reflectionRaytracingCS;
            ComputeShader    reflectionFilter     = m_Asset.renderPipelineRayTracingResources.reflectionBilateralFilterCS;

            // Fetch all the settings
            var          settings             = VolumeManager.instance.stack.GetComponent <ScreenSpaceReflection>();
            LightCluster lightClusterSettings = VolumeManager.instance.stack.GetComponent <LightCluster>();

            if (settings.deferredMode.value)
            {
                // Fetch the new sample kernel
                int currentKernel = reflectionShaderCS.FindKernel(settings.fullResolution.value ? "RaytracingReflectionsFullRes" : "RaytracingReflectionsHalfRes");

                // Bind all the required textures
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._OwenScrambledRGTexture, m_Asset.renderPipelineResources.textures.owenScrambledRGBATex);
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._OwenScrambledTexture, m_Asset.renderPipelineResources.textures.owenScrambled256Tex);
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._ScramblingTexture, m_Asset.renderPipelineResources.textures.scramblingTex);
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                RenderTargetIdentifier clearCoatMaskTexture = hdCamera.frameSettings.litShaderMode == LitShaderMode.Deferred ? m_GbufferManager.GetBuffersRTI()[2] : TextureXR.GetBlackTexture();
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._SsrClearCoatMaskTexture, clearCoatMaskTexture);

                // Bind all the required scalars
                cmd.SetComputeFloatParam(reflectionShaderCS, HDShaderIDs._RaytracingIntensityClamp, settings.clampValue.value);
                cmd.SetComputeFloatParam(reflectionShaderCS, HDShaderIDs._RaytracingReflectionMinSmoothness, settings.minSmoothness.value);
                cmd.SetComputeIntParam(reflectionShaderCS, HDShaderIDs._RaytracingIncludeSky, settings.reflectSky.value ? 1 : 0);

                // Bind the sampling data
                int frameIndex = hdCamera.IsTAAEnabled() ? hdCamera.taaFrameIndex : (int)m_FrameCount % 8;
                cmd.SetComputeIntParam(reflectionShaderCS, HDShaderIDs._RaytracingFrameIndex, frameIndex);

                // Bind the output buffers
                cmd.SetComputeTextureParam(reflectionShaderCS, currentKernel, HDShaderIDs._RaytracingDirectionBuffer, m_ReflIntermediateTexture1);

                // Texture dimensions
                int texWidth  = hdCamera.actualWidth;
                int texHeight = hdCamera.actualHeight;

                if (settings.fullResolution.value)
                {
                    // Evaluate the dispatch parameters
                    int areaTileSize = 8;
                    int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
                    int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;

                    // Compute the directions
                    cmd.DispatchCompute(reflectionShaderCS, currentKernel, numTilesXHR, numTilesYHR, 1);
                }
                else
                {
                    // Evaluate the dispatch parameters
                    int areaTileSize = 8;
                    int numTilesXHR  = (texWidth / 2 + (areaTileSize - 1)) / areaTileSize;
                    int numTilesYHR  = (texHeight / 2 + (areaTileSize - 1)) / areaTileSize;

                    // Compute the directions
                    cmd.DispatchCompute(reflectionShaderCS, currentKernel, numTilesXHR, numTilesYHR, 1);
                }
                // Prepare the components for the deferred lighting
                DeferredLightingRTParameters deferredParamters = PrepareReflectionDeferredLightingRTParameters(hdCamera, rtEnvironment);
                DeferredLightingRTResources  deferredResources = PrepareDeferredLightingRTResources(m_ReflIntermediateTexture1, m_ReflIntermediateTexture0);

                // Evaluate the deferred lighting
                RenderRaytracingDeferredLighting(cmd, deferredParamters, deferredResources);
            }
            else
            {
                // Bind all the required data for ray tracing
                BindRayTracedReflectionData(cmd, hdCamera, rtEnvironment, reflectionShaderRT, settings, lightClusterSettings);

                // Set the data for the ray miss
                cmd.SetRayTracingTextureParam(reflectionShaderRT, HDShaderIDs._SkyTexture, m_SkyManager.skyReflection);

                // Run the computation
                if (settings.fullResolution.value)
                {
                    cmd.DispatchRays(reflectionShaderRT, m_RayGenReflectionFullResName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);
                }
                else
                {
                    // Run the computation
                    cmd.DispatchRays(reflectionShaderRT, m_RayGenReflectionHalfResName, (uint)(hdCamera.actualWidth / 2), (uint)(hdCamera.actualHeight / 2), 1);
                }
            }

            using (new ProfilingSample(cmd, "Filter Reflection", CustomSamplerId.RaytracingFilterReflection.GetSampler()))
            {
                // Fetch the right filter to use
                int currentKernel = 0;
                if (settings.fullResolution.value)
                {
                    currentKernel = reflectionFilter.FindKernel("ReflectionIntegrationUpscaleFullRes");
                }
                else
                {
                    currentKernel = reflectionFilter.FindKernel("ReflectionIntegrationUpscaleHalfRes");
                }

                // Inject all the parameters for the compute
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrLightingTextureRW, m_ReflIntermediateTexture0);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrHitPointTexture, m_ReflIntermediateTexture1);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_NoiseTexture", blueNoise.textureArray16RGB);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_RaytracingReflectionTexture", outputTexture);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._ScramblingTexture, m_Asset.renderPipelineResources.textures.scramblingTex);
                cmd.SetComputeIntParam(reflectionFilter, HDShaderIDs._SpatialFilterRadius, settings.spatialFilterRadius.value);
                cmd.SetComputeIntParam(reflectionFilter, HDShaderIDs._RaytracingDenoiseRadius, settings.enableFilter.value ? settings.filterRadius.value : 0);
                cmd.SetComputeFloatParam(reflectionFilter, HDShaderIDs._RaytracingReflectionMinSmoothness, settings.minSmoothness.value);

                // Texture dimensions
                int texWidth  = hdCamera.actualWidth;
                int texHeight = hdCamera.actualHeight;

                // Evaluate the dispatch parameters
                int areaTileSize = 8;
                int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
                int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;

                // Bind the right texture for clear coat support
                RenderTargetIdentifier clearCoatMaskTexture = hdCamera.frameSettings.litShaderMode == LitShaderMode.Deferred ? m_GbufferManager.GetBuffersRTI()[2] : TextureXR.GetBlackTexture();
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrClearCoatMaskTexture, clearCoatMaskTexture);

                // Compute the texture
                cmd.DispatchCompute(reflectionFilter, currentKernel, numTilesXHR, numTilesYHR, 1);

                using (new ProfilingSample(cmd, "Filter Reflection", CustomSamplerId.RaytracingFilterReflection.GetSampler()))
                {
                    if (settings.enableFilter.value)
                    {
                        // Grab the history buffer
                        RTHandle reflectionHistory = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedReflection)
                                                     ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedReflection, ReflectionHistoryBufferAllocatorFunction, 1);

                        HDSimpleDenoiser simpleDenoiser = m_RayTracingManager.GetSimpleDenoiser();
                        simpleDenoiser.DenoiseBuffer(cmd, hdCamera, outputTexture, reflectionHistory, m_ReflIntermediateTexture0, settings.filterRadius.value, singleChannel: false);
                        HDUtils.BlitCameraTexture(cmd, m_ReflIntermediateTexture0, outputTexture);
                    }
                }
            }
        }
        public void RenderIndirectDiffuseT1(HDCamera hdCamera, CommandBuffer cmd, ScriptableRenderContext renderContext, int frameCount)
        {
            // Fetch the required resources
            var       settings  = VolumeManager.instance.stack.GetComponent <GlobalIllumination>();
            BlueNoise blueNoise = GetBlueNoiseManager();

            // Fetch all the settings
            LightCluster       lightClusterSettings = VolumeManager.instance.stack.GetComponent <LightCluster>();
            RayTracingSettings rtSettings           = VolumeManager.instance.stack.GetComponent <RayTracingSettings>();

            ComputeShader indirectDiffuseCS = m_Asset.renderPipelineRayTracingResources.indirectDiffuseRaytracingCS;

            using (new ProfilingSample(cmd, "Ray Trace Indirect Diffuse", CustomSamplerId.RaytracingIntegrateIndirectDiffuse.GetSampler()))
            {
                if (settings.deferredMode.value)
                {
                    // Fetch the new sample kernel
                    int currentKernel = indirectDiffuseCS.FindKernel(settings.fullResolution.value ? "RaytracingIndirectDiffuseFullRes" : "RaytracingIndirectDiffuseHalfRes");

                    // Inject the ray-tracing sampling data
                    blueNoise.BindDitheredRNGData8SPP(cmd);

                    // Bind all the required textures
                    cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                    cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());

                    // Bind all the required scalars
                    cmd.SetComputeFloatParam(indirectDiffuseCS, HDShaderIDs._RaytracingIntensityClamp, settings.clampValue.value);

                    // Bind the sampling data
                    int frameIndex = hdCamera.IsTAAEnabled() ? hdCamera.taaFrameIndex : (int)m_FrameCount % 8;
                    cmd.SetComputeIntParam(indirectDiffuseCS, HDShaderIDs._RaytracingFrameIndex, frameIndex);

                    // Bind the output buffers
                    cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);

                    // Texture dimensions
                    int texWidth  = hdCamera.actualWidth;
                    int texHeight = hdCamera.actualHeight;

                    // Evaluate the dispatch parameters
                    int areaTileSize = 8;
                    int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
                    int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;

                    // Compute the directions
                    cmd.DispatchCompute(indirectDiffuseCS, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                    // Prepare the components for the deferred lighting
                    DeferredLightingRTParameters deferredParamters = PrepareIndirectDiffuseDeferredLightingRTParameters(hdCamera);
                    DeferredLightingRTResources  deferredResources = PrepareDeferredLightingRTResources(m_RaytracingDirectionBuffer, m_IDIntermediateBuffer0);

                    // Evaluate the deferred lighting
                    RenderRaytracingDeferredLighting(cmd, deferredParamters, deferredResources);
                }
                else
                {
                    RayTracingShader indirectDiffuseRT = m_Asset.renderPipelineRayTracingResources.indirectDiffuseRaytracingRT;

                    BindRayTracedIndirectDiffuseData(cmd, hdCamera, indirectDiffuseRT, settings, lightClusterSettings, rtSettings);

                    // Run the computation
                    CoreUtils.SetKeyword(cmd, "DIFFUSE_LIGHTING_ONLY", true);
                    CoreUtils.SetKeyword(cmd, "MULTI_BOUNCE_INDIRECT", false);

                    // Run the computation
                    cmd.DispatchRays(indirectDiffuseRT, m_RayGenIndirectDiffuseFullResName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, (uint)hdCamera.viewCount);

                    CoreUtils.SetKeyword(cmd, "DIFFUSE_LIGHTING_ONLY", false);
                }
            }

            using (new ProfilingSample(cmd, "Filter Indirect Diffuse", CustomSamplerId.RaytracingFilterIndirectDiffuse.GetSampler()))
            {
                // Fetch the right filter to use
                int currentKernel = indirectDiffuseCS.FindKernel(settings.fullResolution.value ? "IndirectDiffuseIntegrationUpscaleFullRes" : "IndirectDiffuseIntegrationUpscaleHalfRes");

                // Inject all the parameters for the compute
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._IndirectDiffuseTexture, m_IDIntermediateBuffer0);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._BlueNoiseTexture, blueNoise.textureArray16RGB);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._UpscaledIndirectDiffuseTextureRW, m_IDIntermediateBuffer1);
                cmd.SetComputeTextureParam(indirectDiffuseCS, currentKernel, HDShaderIDs._ScramblingTexture, m_Asset.renderPipelineResources.textures.scramblingTex);
                cmd.SetComputeIntParam(indirectDiffuseCS, HDShaderIDs._SpatialFilterRadius, settings.upscaleRadius.value);

                // Texture dimensions
                int texWidth  = hdCamera.actualWidth;
                int texHeight = hdCamera.actualHeight;

                // Evaluate the dispatch parameters
                int areaTileSize = 8;
                int numTilesXHR  = (texWidth + (areaTileSize - 1)) / areaTileSize;
                int numTilesYHR  = (texHeight + (areaTileSize - 1)) / areaTileSize;

                // Compute the texture
                cmd.DispatchCompute(indirectDiffuseCS, currentKernel, numTilesXHR, numTilesYHR, hdCamera.viewCount);

                // Copy the data back to the right buffer
                HDUtils.BlitCameraTexture(cmd, m_IDIntermediateBuffer1, m_IDIntermediateBuffer0);

                // Denoise if required
                if (settings.denoise.value)
                {
                    DenoiseIndirectDiffuseBuffer(hdCamera, cmd, settings);
                }
            }
        }