Ejemplo n.º 1
0
        private void SettingsUI(HDRenderPipeline renderContext)
        {
            EditorGUILayout.LabelField(styles.settingsLabel);
            EditorGUI.indentLevel++;

            EditorGUI.BeginChangeCheck();

            renderContext.lightLoopProducer = (LightLoopProducer)EditorGUILayout.ObjectField(new GUIContent("Light Loop"), renderContext.lightLoopProducer, typeof(LightLoopProducer), false);

            if (EditorGUI.EndChangeCheck())
            {
                HackSetDirty(renderContext); // Repaint
            }

            SssSettingsUI(renderContext);
            ShadowSettingsUI(renderContext);
            TextureSettingsUI(renderContext);
            RendereringSettingsUI(renderContext);
            //TilePassUI(renderContext);

            EditorGUI.indentLevel--;
        }
Ejemplo n.º 2
0
        public override void OnInspectorGUI()
        {
            var renderContext = target as HDRenderPipelineAsset;
            HDRenderPipeline renderpipeline = UnityEngine.Experimental.Rendering.RenderPipelineManager.currentPipeline as HDRenderPipeline;

            if (!renderContext || renderpipeline == null)
            {
                return;
            }

            serializedObject.Update();

            EditorGUILayout.LabelField(Styles.defaults, EditorStyles.boldLabel);
            EditorGUI.indentLevel++;
            EditorGUILayout.PropertyField(m_DefaultDiffuseMaterial, Styles.defaultDiffuseMaterial);
            EditorGUILayout.PropertyField(m_DefaultShader, Styles.defaultShader);
            EditorGUI.indentLevel--;

            SettingsUI(renderContext);

            serializedObject.ApplyModifiedProperties();
        }
Ejemplo n.º 3
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        public void Init(RenderPipelineSettings settings, RenderPipelineResources rpResources, HDRenderPipelineRayTracingResources rayTracingResources, BlueNoise blueNoise, HDRenderPipeline renderPipeline, SharedRTManager sharedRTManager, DebugDisplaySettings currentDebugDisplaySettings)
        {
            // Keep track of the resources
            m_Resources   = rpResources;
            m_RTResources = rayTracingResources;

            // Keep track of the settings
            m_Settings = settings;

            // Keep track of the render pipeline
            m_RenderPipeline = renderPipeline;

            // Keep track of the shared RT manager
            m_SharedRTManager = sharedRTManager;

            // Keep track of the blue noise manager
            m_BlueNoise = blueNoise;

            // Create the list of environments
            m_Environments = new List <HDRaytracingEnvironment>();

            // Grab all the ray-tracing graphs that have been created before (in case the order of initialization has not been respected, which happens when we open unity the first time)
            HDRaytracingEnvironment[] environmentArray = Object.FindObjectsOfType <HDRaytracingEnvironment>();
            for (int envIdx = 0; envIdx < environmentArray.Length; ++envIdx)
            {
                RegisterEnvironment(environmentArray[envIdx]);
            }

            // Init the ray count manager
            m_RayCountManager.Init(rayTracingResources, currentDebugDisplaySettings);

#if UNITY_EDITOR
            // We need to invalidate the acceleration structures in case the hierarchy changed
            EditorApplication.hierarchyChanged += OnHierarchyChanged;
#endif
        }
        private void DebuggingUI(HDRenderPipeline renderContext, HDRenderPipelineInstance renderpipelineInstance)
        {
            EditorGUILayout.LabelField(styles.debugging);

            // Debug Display settings
            EditorGUI.indentLevel++;
            EditorGUILayout.PropertyField(m_DebugDisplayMode, styles.debugDisplayMode);
            m_DebugOverlayRatio.floatValue = EditorGUILayout.Slider(styles.debugOverlayRatio, m_DebugOverlayRatio.floatValue, 0.1f, 1.0f);
            EditorGUILayout.Space();

            RenderingDebugSettingsUI(renderContext);
            if ((DebugDisplayMode)m_DebugDisplayMode.intValue == DebugDisplayMode.ViewMaterial)
            {
                MaterialDebugSettingsUI(renderContext);
            }
            else
            {
                LightingDebugSettingsUI(renderContext, renderpipelineInstance);
            }

            EditorGUILayout.Space();

            EditorGUI.indentLevel--;
        }
Ejemplo n.º 5
0
        // Combines specular lighting and diffuse lighting with subsurface scattering.
        public void SubsurfaceScatteringPass(HDCamera hdCamera, CommandBuffer cmd, SubsurfaceScatteringSettings sssParameters, FrameSettings frameSettings,
                                             RenderTargetIdentifier colorBufferRT, RenderTargetIdentifier diffuseBufferRT, RenderTargetIdentifier depthStencilBufferRT, RenderTargetIdentifier depthTextureRT)
        {
            if (sssParameters == null || !frameSettings.enableSSSAndTransmission)
            {
                return;
            }

            using (new ProfilingSample(cmd, "Subsurface Scattering", HDRenderPipeline.GetSampler(CustomSamplerId.SubsurfaceScattering)))
            {
                int w = hdCamera.camera.pixelWidth;
                int h = hdCamera.camera.pixelHeight;

                // For Jimenez we always need an extra buffer, for Disney it depends on platform
                if (!sssParameters.useDisneySSS ||
                    (sssParameters.useDisneySSS && NeedTemporarySubsurfaceBuffer()))
                {
                    // Caution: must be same format as m_CameraSssDiffuseLightingBuffer
                    cmd.ReleaseTemporaryRT(m_CameraFilteringBuffer);
                    cmd.GetTemporaryRT(m_CameraFilteringBuffer, w, h, 0, FilterMode.Point, RenderTextureFormat.RGB111110Float, RenderTextureReadWrite.Linear, 1, true); // Enable UAV
                                                                                                                                                                        // Clear the SSS filtering target
                    using (new ProfilingSample(cmd, "Clear SSS filtering target", HDRenderPipeline.GetSampler(CustomSamplerId.ClearSSSFilteringTarget)))
                    {
                        CoreUtils.SetRenderTarget(cmd, m_CameraFilteringBufferRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);
                    }
                }

                if (sssParameters.useDisneySSS)
                {
                    using (new ProfilingSample(cmd, "HTile for SSS", HDRenderPipeline.GetSampler(CustomSamplerId.HTileForSSS)))
                    {
                        // Currently, Unity does not offer a way to access the GCN HTile even on PS4 and Xbox One.
                        // Therefore, it's computed in a pixel shader, and optimized to only contain the SSS bit.
                        CoreUtils.SetRenderTarget(cmd, m_HTileRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);

                        cmd.SetRandomWriteTarget(1, m_HTile);
                        // Generate HTile for the split lighting stencil usage. Don't write into stencil texture (shaderPassId = 2)
                        // Use ShaderPassID 1 => "Pass 2 - Export HTILE for stencilRef to output"
                        CoreUtils.SetRenderTarget(cmd, depthStencilBufferRT); // No need for color buffer here
                        CoreUtils.DrawFullScreen(cmd, m_CopyStencilForSplitLighting, null, 2);
                        cmd.ClearRandomWriteTargets();
                    }

                    // TODO: Remove this once fix, see comment inside the function
                    hdCamera.SetupComputeShader(m_SubsurfaceScatteringCS, cmd);

                    unsafe
                    {
                        // Warning: Unity is not able to losslessly transfer integers larger than 2^24 to the shader system.
                        // Therefore, we bitcast uint to float in C#, and bitcast back to uint in the shader.
                        uint texturingModeFlags = sssParameters.texturingModeFlags;
                        cmd.SetComputeFloatParam(m_SubsurfaceScatteringCS, HDShaderIDs._TexturingModeFlags, *(float *)&texturingModeFlags);
                    }

                    cmd.SetComputeVectorArrayParam(m_SubsurfaceScatteringCS, HDShaderIDs._WorldScales, sssParameters.worldScales);
                    cmd.SetComputeVectorArrayParam(m_SubsurfaceScatteringCS, HDShaderIDs._FilterKernels, sssParameters.filterKernels);
                    cmd.SetComputeVectorArrayParam(m_SubsurfaceScatteringCS, HDShaderIDs._ShapeParams, sssParameters.shapeParams);

                    cmd.SetComputeTextureParam(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, HDShaderIDs._DepthTexture, depthTextureRT);
                    cmd.SetComputeTextureParam(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, HDShaderIDs._SSSHTile, m_HTileRT);
                    cmd.SetComputeTextureParam(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, HDShaderIDs._IrradianceSource, diffuseBufferRT);

                    for (int i = 0; i < sssBufferCount; ++i)
                    {
                        cmd.SetComputeTextureParam(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, HDShaderIDs._SSSBufferTexture[i], GetSSSBuffers(i));
                    }

                    if (NeedTemporarySubsurfaceBuffer())
                    {
                        // Caution: must be same format as m_CameraSssDiffuseLightingBuffer
                        cmd.ReleaseTemporaryRT(m_CameraFilteringBuffer);
                        cmd.GetTemporaryRT(m_CameraFilteringBuffer, w, h, 0, FilterMode.Point, RenderTextureFormat.RGB111110Float, RenderTextureReadWrite.Linear, 1, true); // Enable UAV
                        // Clear the SSS filtering target
                        using (new ProfilingSample(cmd, "Clear SSS filtering target", HDRenderPipeline.GetSampler(CustomSamplerId.ClearSSSFilteringTarget)))
                        {
                            CoreUtils.SetRenderTarget(cmd, m_CameraFilteringBufferRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);
                        }

                        cmd.SetComputeTextureParam(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, HDShaderIDs._CameraFilteringBuffer, m_CameraFilteringBufferRT);

                        // Perform the SSS filtering pass which fills 'm_CameraFilteringBufferRT'.
                        // We dispatch 4x swizzled 16x16 groups per a 32x32 macro tile.
                        cmd.DispatchCompute(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, 4, ((int)hdCamera.screenSize.x + 31) / 32, ((int)hdCamera.screenSize.y + 31) / 32);

                        cmd.SetGlobalTexture(HDShaderIDs._IrradianceSource, m_CameraFilteringBufferRT);  // Cannot set a RT on a material

                        // Additively blend diffuse and specular lighting into 'm_CameraColorBufferRT'.
                        CoreUtils.DrawFullScreen(cmd, m_CombineLightingPass, colorBufferRT, depthStencilBufferRT);
                    }
                    else
                    {
                        cmd.SetComputeTextureParam(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, HDShaderIDs._CameraColorTexture, colorBufferRT);

                        // Perform the SSS filtering pass which performs an in-place update of 'colorBuffer'.
                        // We dispatch 4x swizzled 16x16 groups per a 32x32 macro tile.
                        cmd.DispatchCompute(m_SubsurfaceScatteringCS, m_SubsurfaceScatteringKernel, 4, ((int)hdCamera.screenSize.x + 31) / 32, ((int)hdCamera.screenSize.y + 31) / 32);
                    }
                }
                else
                {
                    for (int i = 0; i < sssBufferCount; ++i)
                    {
                        cmd.SetGlobalTexture(HDShaderIDs._SSSBufferTexture[i], GetSSSBuffers(i));
                    }

                    cmd.SetGlobalTexture(HDShaderIDs._IrradianceSource, diffuseBufferRT);  // Cannot set a RT on a material
                    m_SssVerticalFilterPass.SetVectorArray(HDShaderIDs._FilterKernelsBasic, sssParameters.filterKernelsBasic);
                    m_SssVerticalFilterPass.SetVectorArray(HDShaderIDs._HalfRcpWeightedVariances, sssParameters.halfRcpWeightedVariances);
                    // Perform the vertical SSS filtering pass which fills 'm_CameraFilteringBufferRT'.
                    CoreUtils.DrawFullScreen(cmd, m_SssVerticalFilterPass, m_CameraFilteringBufferRT, depthStencilBufferRT);

                    cmd.SetGlobalTexture(HDShaderIDs._IrradianceSource, m_CameraFilteringBufferRT);  // Cannot set a RT on a material
                    m_SssHorizontalFilterAndCombinePass.SetVectorArray(HDShaderIDs._FilterKernelsBasic, sssParameters.filterKernelsBasic);
                    m_SssHorizontalFilterAndCombinePass.SetVectorArray(HDShaderIDs._HalfRcpWeightedVariances, sssParameters.halfRcpWeightedVariances);
                    // Perform the horizontal SSS filtering pass, and combine diffuse and specular lighting into 'm_CameraColorBufferRT'.
                    CoreUtils.DrawFullScreen(cmd, m_SssHorizontalFilterAndCombinePass, colorBufferRT, depthStencilBufferRT);
                }
            }
        }
Ejemplo n.º 6
0
        public HDRenderPipelineInstance(HDRenderPipeline owner)
        {
            m_Owner = owner;

            m_CameraColorBuffer            = Shader.PropertyToID("_CameraColorTexture");
            m_CameraSubsurfaceBuffer       = Shader.PropertyToID("_CameraSubsurfaceTexture");
            m_CameraFilteringBuffer        = Shader.PropertyToID("_CameraFilteringBuffer");
            m_CameraDepthStencilBuffer     = Shader.PropertyToID("_CameraDepthTexture");
            m_CameraDepthStencilBufferCopy = Shader.PropertyToID("_CameraDepthTextureCopy");
            m_CameraStencilBuffer          = Shader.PropertyToID("_CameraStencilTexture");

            m_CameraColorBufferRT            = new RenderTargetIdentifier(m_CameraColorBuffer);
            m_CameraSubsurfaceBufferRT       = new RenderTargetIdentifier(m_CameraSubsurfaceBuffer);
            m_CameraFilteringBufferRT        = new RenderTargetIdentifier(m_CameraFilteringBuffer);
            m_CameraDepthStencilBufferRT     = new RenderTargetIdentifier(m_CameraDepthStencilBuffer);
            m_CameraDepthStencilBufferCopyRT = new RenderTargetIdentifier(m_CameraDepthStencilBufferCopy);
            m_CameraStencilBufferRT          = new RenderTargetIdentifier(m_CameraStencilBuffer);

            m_DebugViewMaterialGBuffer = Utilities.CreateEngineMaterial("Hidden/HDRenderPipeline/DebugViewMaterialGBuffer");

            m_FilterSubsurfaceScattering = Utilities.CreateEngineMaterial("Hidden/HDRenderPipeline/CombineSubsurfaceScattering");
            m_FilterSubsurfaceScattering.DisableKeyword("FILTER_HORIZONTAL");
            m_FilterSubsurfaceScattering.SetFloat("_DstBlend", (float)BlendMode.Zero);

            m_FilterAndCombineSubsurfaceScattering = Utilities.CreateEngineMaterial("Hidden/HDRenderPipeline/CombineSubsurfaceScattering");
            m_FilterSubsurfaceScattering.EnableKeyword("FILTER_HORIZONTAL");
            m_FilterAndCombineSubsurfaceScattering.SetFloat("_DstBlend", (float)BlendMode.One);

            m_DebugDisplayShadowMap = Utilities.CreateEngineMaterial("Hidden/HDRenderPipeline/DebugDisplayShadowMap");

            m_ShadowPass = new ShadowRenderPass(owner.shadowSettings);

            // Init Gbuffer description
            m_gbufferManager.gbufferCount = m_LitRenderLoop.GetMaterialGBufferCount();
            RenderTextureFormat[]    RTFormat;
            RenderTextureReadWrite[] RTReadWrite;
            m_LitRenderLoop.GetMaterialGBufferDescription(out RTFormat, out RTReadWrite);

            for (int gbufferIndex = 0; gbufferIndex < m_gbufferManager.gbufferCount; ++gbufferIndex)
            {
                m_gbufferManager.SetBufferDescription(gbufferIndex, "_GBufferTexture" + gbufferIndex, RTFormat[gbufferIndex], RTReadWrite[gbufferIndex]);
            }

            m_VelocityBuffer = Shader.PropertyToID("_VelocityTexture");
            if (ShaderConfig.s_VelocityInGbuffer == 1)
            {
                // If velocity is in GBuffer then it is in the last RT. Assign a different name to it.
                m_gbufferManager.SetBufferDescription(m_gbufferManager.gbufferCount, "_VelocityTexture", Builtin.RenderLoop.GetVelocityBufferFormat(), Builtin.RenderLoop.GetVelocityBufferReadWrite());
                m_gbufferManager.gbufferCount++;
            }
            m_VelocityBufferRT = new RenderTargetIdentifier(m_VelocityBuffer);

            m_DistortionBuffer   = Shader.PropertyToID("_DistortionTexture");
            m_DistortionBufferRT = new RenderTargetIdentifier(m_DistortionBuffer);

            m_LitRenderLoop.Build();

            if (owner.lightLoopProducer)
            {
                m_LightLoop = owner.lightLoopProducer.CreateLightLoop();
            }

            if (m_LightLoop != null)
            {
                m_LightLoop.Build(owner.textureSettings);
            }

            m_SkyManager.Build();
            m_SkyManager.skySettings = owner.skySettingsToUse;
        }
Ejemplo n.º 7
0
        public bool RenderAreaShadows(HDCamera hdCamera, CommandBuffer cmd, ScriptableRenderContext renderContext, uint frameCount)
        {
            // NOTE: Here we cannot clear the area shadow texture because it is a texture array. So we need to bind it and make sure no material will try to read it in the shaders
            BindShadowTexture(cmd);

            // Let's check all the resources and states to see if we should render the effect
            HDRaytracingEnvironment rtEnvironement = m_RaytracingManager.CurrentEnvironment();

            RaytracingShader shadowRaytrace = m_PipelineAsset.renderPipelineResources.shaders.areaShadowsRaytracingRT;
            ComputeShader    shadowsCompute = m_PipelineAsset.renderPipelineResources.shaders.areaShadowRaytracingCS;
            ComputeShader    shadowFilter   = m_PipelineAsset.renderPipelineResources.shaders.areaShadowFilterCS;

            // Make sure everything is valid
            bool invalidState = rtEnvironement == null || rtEnvironement.raytracedShadows == false ||
                                hdCamera.frameSettings.litShaderMode != LitShaderMode.Deferred ||
                                shadowRaytrace == null || shadowsCompute == null || shadowFilter == null ||
                                m_PipelineResources.textures.owenScrambledTex == null || m_PipelineResources.textures.scramblingTex == null;

            // If invalid state or ray-tracing acceleration structure, we stop right away
            if (invalidState)
            {
                return(false);
            }

            // Grab the TAA history buffers (SN/UN and Analytic value)
            RTHandleSystem.RTHandle areaShadowHistoryArray = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedAreaShadow)
                                                             ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedAreaShadow, AreaShadowHistoryBufferAllocatorFunction, 1);
            RTHandleSystem.RTHandle areaAnalyticHistoryArray = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedAreaAnalytic)
                                                               ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedAreaAnalytic, AreaAnalyticHistoryBufferAllocatorFunction, 1);

            // Grab the acceleration structure for the target camera
            RaytracingAccelerationStructure accelerationStructure = m_RaytracingManager.RequestAccelerationStructure(rtEnvironement.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);

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

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

            cmd.SetGlobalInt(HDShaderIDs._RaytracingFrameIndex, frameIndex);

            // Grab the Filtering Kernels
            int copyTAAHistoryKernel  = shadowFilter.FindKernel("AreaShadowCopyTAAHistory");
            int applyTAAKernel        = shadowFilter.FindKernel("AreaShadowApplyTAA");
            int updateAnalyticHistory = shadowFilter.FindKernel("AreaAnalyticHistoryUpdate");
            int estimateNoiseKernel   = shadowFilter.FindKernel("AreaShadowEstimateNoise");
            int firstDenoiseKernel    = shadowFilter.FindKernel("AreaShadowDenoiseFirstPass");
            int secondDenoiseKernel   = shadowFilter.FindKernel("AreaShadowDenoiseSecondPass");

            // 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;

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

            int numLights = m_LightLoop.m_lightList.lights.Count;

            for (int lightIdx = 0; lightIdx < numLights; ++lightIdx)
            {
                // If this is not a rectangular area light or it won't have shadows, skip it
                if (m_LightLoop.m_lightList.lights[lightIdx].lightType != GPULightType.Rectangle || m_LightLoop.m_lightList.lights[lightIdx].rayTracedAreaShadowIndex == -1)
                {
                    continue;
                }
                using (new ProfilingSample(cmd, "Raytrace Area Shadow", CustomSamplerId.RaytracingShadowIntegration.GetSampler()))
                {
                    LightData currentLight = m_LightLoop.m_lightList.lights[lightIdx];

                    // We need to build the world to area light matrix
                    worldToLocalArea.SetColumn(0, currentLight.right);
                    worldToLocalArea.SetColumn(1, currentLight.up);
                    worldToLocalArea.SetColumn(2, currentLight.forward);

                    // Compensate the  relative rendering if active
                    Vector3 lightPositionWS = currentLight.positionRWS;
                    if (ShaderConfig.s_CameraRelativeRendering != 0)
                    {
                        lightPositionWS += hdCamera.camera.transform.position;
                    }
                    worldToLocalArea.SetColumn(3, lightPositionWS);
                    worldToLocalArea.m33 = 1.0f;
                    worldToLocalArea     = worldToLocalArea.inverse;

                    // We have noticed from extensive profiling that ray-trace shaders are not as effective for running per-pixel computation. In order to reduce that,
                    // we do a first prepass that compute the analytic term and probability and generates the first integration sample
                    if (rtEnvironement.splitIntegration)
                    {
                        int shadowComputeKernel = shadowsCompute.FindKernel("RaytracingAreaShadowPrepass");

                        // This pass evaluates the analytic value and the generates and outputs the first sample
                        cmd.SetComputeBufferParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._LightDatas, m_LightLoop.lightDatas);
                        cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingTargetAreaLight, lightIdx);
                        cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingNumSamples, rtEnvironement.shadowNumSamples);
                        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._GBufferTexture[0], m_GbufferManager.GetBuffer(0));
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._GBufferTexture[1], m_GbufferManager.GetBuffer(1));
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._GBufferTexture[2], m_GbufferManager.GetBuffer(2));
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._GBufferTexture[3], m_GbufferManager.GetBuffer(3));
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._AreaCookieTextures, m_LightLoop.areaLightCookieManager.GetTexCache());
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracedAreaShadowIntegration, m_DenoiseBuffer0);
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracedAreaShadowSample, m_DenoiseBuffer1);
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracingDistanceBuffer, m_RaytracingDistanceBuffer);
                        cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._AnalyticProbBuffer, m_AnalyticProbBuffer);
                        cmd.DispatchCompute(shadowsCompute, shadowComputeKernel, numTilesX, numTilesY, 1);

                        // This pass will use the previously generated sample and add it to the integration buffer
                        cmd.SetRaytracingBufferParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._LightDatas, m_LightLoop.lightDatas);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracedAreaShadowSample, m_DenoiseBuffer1);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracedAreaShadowIntegration, m_DenoiseBuffer0);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracingDistanceBuffer, m_RaytracingDistanceBuffer);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._AnalyticProbBuffer, m_AnalyticProbBuffer);
                        cmd.DispatchRays(shadowRaytrace, m_RayGenShadowSingleName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);

                        // Let's do the following samples (if any)
                        for (int sampleIndex = 1; sampleIndex < rtEnvironement.shadowNumSamples; ++sampleIndex)
                        {
                            shadowComputeKernel = shadowsCompute.FindKernel("RaytracingAreaShadowNewSample");

                            // This pass generates a new sample based on the initial pre-pass
                            cmd.SetComputeBufferParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._LightDatas, m_LightLoop.lightDatas);
                            cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingTargetAreaLight, lightIdx);
                            cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingNumSamples, rtEnvironement.shadowNumSamples);
                            cmd.SetComputeIntParam(shadowsCompute, HDShaderIDs._RaytracingSampleIndex, sampleIndex);
                            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._GBufferTexture[0], m_GbufferManager.GetBuffer(0));
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._GBufferTexture[1], m_GbufferManager.GetBuffer(1));
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._GBufferTexture[2], m_GbufferManager.GetBuffer(2));
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._GBufferTexture[3], m_GbufferManager.GetBuffer(3));
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._AreaCookieTextures, m_LightLoop.areaLightCookieManager.GetTexCache());
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracedAreaShadowIntegration, m_DenoiseBuffer0);
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracedAreaShadowSample, m_DenoiseBuffer1);
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._RaytracingDistanceBuffer, m_RaytracingDistanceBuffer);
                            cmd.SetComputeTextureParam(shadowsCompute, shadowComputeKernel, HDShaderIDs._AnalyticProbBuffer, m_AnalyticProbBuffer);
                            cmd.DispatchCompute(shadowsCompute, shadowComputeKernel, numTilesX, numTilesY, 1);

                            // This pass will use the previously generated sample and add it to the integration buffer
                            cmd.SetRaytracingBufferParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._LightDatas, m_LightLoop.lightDatas);
                            cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                            cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracedAreaShadowSample, m_DenoiseBuffer1);
                            cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracedAreaShadowIntegration, m_DenoiseBuffer0);
                            cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracingDirectionBuffer, m_RaytracingDirectionBuffer);
                            cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._RaytracingDistanceBuffer, m_RaytracingDistanceBuffer);
                            cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShadowSingleName, HDShaderIDs._AnalyticProbBuffer, m_AnalyticProbBuffer);
                            cmd.DispatchRays(shadowRaytrace, m_RayGenShadowSingleName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);
                        }
                    }
                    else
                    {
                        // This pass generates the analytic value and will do the full integration
                        cmd.SetRaytracingBufferParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._LightDatas, m_LightLoop.lightDatas);
                        cmd.SetRaytracingIntParam(shadowRaytrace, HDShaderIDs._RaytracingTargetAreaLight, lightIdx);
                        cmd.SetRaytracingIntParam(shadowRaytrace, HDShaderIDs._RaytracingNumSamples, rtEnvironement.shadowNumSamples);
                        cmd.SetRaytracingMatrixParam(shadowRaytrace, HDShaderIDs._RaytracingAreaWorldToLocal, worldToLocalArea);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._GBufferTexture[0], m_GbufferManager.GetBuffer(0));
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._GBufferTexture[1], m_GbufferManager.GetBuffer(1));
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._GBufferTexture[2], m_GbufferManager.GetBuffer(2));
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._GBufferTexture[3], m_GbufferManager.GetBuffer(3));
                        cmd.SetRaytracingIntParam(shadowRaytrace, HDShaderIDs._RayCountEnabled, m_RaytracingManager.rayCountManager.RayCountIsEnabled());
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._RayCountTexture, m_RaytracingManager.rayCountManager.rayCountTexture);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._AreaCookieTextures, m_LightLoop.areaLightCookieManager.GetTexCache());
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._AnalyticProbBuffer, m_AnalyticProbBuffer);
                        cmd.SetRaytracingTextureParam(shadowRaytrace, m_RayGenShaderName, HDShaderIDs._RaytracedAreaShadowIntegration, m_DenoiseBuffer0);
                        cmd.DispatchRays(shadowRaytrace, m_RayGenShaderName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);
                    }
                }

                using (new ProfilingSample(cmd, "Combine Area Shadow", CustomSamplerId.RaytracingShadowCombination.GetSampler()))
                {
                    // Global parameters
                    cmd.SetComputeIntParam(shadowFilter, HDShaderIDs._RaytracingDenoiseRadius, rtEnvironement.shadowFilterRadius);
                    cmd.SetComputeIntParam(shadowFilter, HDShaderIDs._RaytracingShadowSlot, m_LightLoop.m_lightList.lights[lightIdx].rayTracedAreaShadowIndex);

                    // Given that we can't read and write into the same buffer, we store the current frame value and the history in the denoisebuffer1
                    cmd.SetComputeTextureParam(shadowFilter, copyTAAHistoryKernel, HDShaderIDs._AreaShadowHistoryRW, areaShadowHistoryArray);
                    cmd.SetComputeTextureParam(shadowFilter, copyTAAHistoryKernel, HDShaderIDs._DenoiseInputTexture, m_DenoiseBuffer0);
                    cmd.SetComputeTextureParam(shadowFilter, copyTAAHistoryKernel, HDShaderIDs._DenoiseOutputTextureRW, m_DenoiseBuffer1);
                    cmd.DispatchCompute(shadowFilter, copyTAAHistoryKernel, numTilesX, numTilesY, 1);

                    // Apply a vectorized temporal filtering pass and store it back in the denoisebuffer0 with the analytic value in the third channel
                    var historyScale = new Vector2(hdCamera.actualWidth / (float)areaShadowHistoryArray.rt.width, hdCamera.actualHeight / (float)areaShadowHistoryArray.rt.height);
                    cmd.SetComputeVectorParam(shadowFilter, HDShaderIDs._ScreenToTargetScaleHistory, historyScale);
                    cmd.SetComputeTextureParam(shadowFilter, applyTAAKernel, HDShaderIDs._AnalyticProbBuffer, m_AnalyticProbBuffer);
                    cmd.SetComputeTextureParam(shadowFilter, applyTAAKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                    cmd.SetComputeTextureParam(shadowFilter, applyTAAKernel, HDShaderIDs._AnalyticHistoryBuffer, areaAnalyticHistoryArray);
                    cmd.SetComputeTextureParam(shadowFilter, applyTAAKernel, HDShaderIDs._DenoiseInputTexture, m_DenoiseBuffer1);
                    cmd.SetComputeTextureParam(shadowFilter, applyTAAKernel, HDShaderIDs._DenoiseOutputTextureRW, m_DenoiseBuffer0);
                    cmd.SetComputeTextureParam(shadowFilter, applyTAAKernel, HDShaderIDs._AreaShadowHistoryRW, areaShadowHistoryArray);
                    cmd.DispatchCompute(shadowFilter, applyTAAKernel, numTilesX, numTilesY, 1);

                    // Now that we do not need it anymore, update the anyltic history
                    cmd.SetComputeTextureParam(shadowFilter, updateAnalyticHistory, HDShaderIDs._AnalyticHistoryBuffer, areaAnalyticHistoryArray);
                    cmd.SetComputeTextureParam(shadowFilter, updateAnalyticHistory, HDShaderIDs._AnalyticProbBuffer, m_AnalyticProbBuffer);

                    cmd.DispatchCompute(shadowFilter, updateAnalyticHistory, numTilesX, numTilesY, 1);

                    if (rtEnvironement.shadowFilterRadius > 0)
                    {
                        // Inject parameters for noise estimation
                        cmd.SetComputeTextureParam(shadowFilter, estimateNoiseKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetComputeTextureParam(shadowFilter, estimateNoiseKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                        cmd.SetComputeTextureParam(shadowFilter, estimateNoiseKernel, HDShaderIDs._ScramblingTexture, m_PipelineResources.textures.scramblingTex);

                        // Noise estimation pre-pass
                        cmd.SetComputeTextureParam(shadowFilter, estimateNoiseKernel, HDShaderIDs._DenoiseInputTexture, m_DenoiseBuffer0);
                        cmd.SetComputeTextureParam(shadowFilter, estimateNoiseKernel, HDShaderIDs._DenoiseOutputTextureRW, m_DenoiseBuffer1);
                        cmd.DispatchCompute(shadowFilter, estimateNoiseKernel, numTilesX, numTilesY, 1);

                        // Reinject parameters for denoising
                        cmd.SetComputeTextureParam(shadowFilter, firstDenoiseKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                        cmd.SetComputeTextureParam(shadowFilter, firstDenoiseKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                        cmd.SetComputeTextureParam(shadowFilter, firstDenoiseKernel, HDShaderIDs._AreaShadowTextureRW, m_AreaShadowTextureArray);

                        // First denoising pass
                        cmd.SetComputeTextureParam(shadowFilter, firstDenoiseKernel, HDShaderIDs._DenoiseInputTexture, m_DenoiseBuffer1);
                        cmd.SetComputeTextureParam(shadowFilter, firstDenoiseKernel, HDShaderIDs._DenoiseOutputTextureRW, m_DenoiseBuffer0);
                        cmd.DispatchCompute(shadowFilter, firstDenoiseKernel, numTilesX, numTilesY, 1);
                    }

                    // Reinject parameters for denoising
                    cmd.SetComputeTextureParam(shadowFilter, secondDenoiseKernel, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
                    cmd.SetComputeTextureParam(shadowFilter, secondDenoiseKernel, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());
                    cmd.SetComputeTextureParam(shadowFilter, secondDenoiseKernel, HDShaderIDs._AreaShadowTextureRW, m_AreaShadowTextureArray);

                    // Second (and final) denoising pass
                    cmd.SetComputeTextureParam(shadowFilter, secondDenoiseKernel, HDShaderIDs._DenoiseInputTexture, m_DenoiseBuffer0);
                    cmd.DispatchCompute(shadowFilter, secondDenoiseKernel, numTilesX, numTilesY, 1);
                }
            }

            // If this is the right debug mode and we have at least one light, write the first shadow to the denoise texture
            HDRenderPipeline hdrp = (RenderPipelineManager.currentPipeline as HDRenderPipeline);

            if (FullScreenDebugMode.RaytracedAreaShadow == hdrp.m_CurrentDebugDisplaySettings.data.fullScreenDebugMode && numLights > 0)
            {
                int targetKernel = shadowFilter.FindKernel("WriteShadowTextureDebug");

                cmd.SetComputeIntParam(shadowFilter, HDShaderIDs._RaytracingShadowSlot, 0);
                cmd.SetComputeTextureParam(shadowFilter, targetKernel, HDShaderIDs._AreaShadowTextureRW, m_AreaShadowTextureArray);
                cmd.SetComputeTextureParam(shadowFilter, targetKernel, HDShaderIDs._DenoiseOutputTextureRW, m_DenoiseBuffer0);
                cmd.DispatchCompute(shadowFilter, targetKernel, numTilesX, numTilesY, 1);

                hdrp.PushFullScreenDebugTexture(hdCamera, cmd, m_DenoiseBuffer0, FullScreenDebugMode.RaytracedAreaShadow);
            }
            return(true);
        }
Ejemplo n.º 8
0
        public void RebuildTextures(int resolution)
        {
            bool updateNeeded = m_SkyboxCubemapRT == null || (m_SkyboxCubemapRT.rt.width != resolution);

            // Cleanup first if needed
            if (updateNeeded)
            {
                RTHandles.Release(m_SkyboxCubemapRT);
                m_SkyboxCubemapRT = null;

                RTHandles.Release(m_SkyboxBSDFCubemapIntermediate);
                m_SkyboxBSDFCubemapIntermediate = null;

                CoreUtils.Destroy(m_SkyboxBSDFCubemapArray);
                m_SkyboxBSDFCubemapArray = null;
            }

            // Reallocate everything
            if (m_SkyboxCubemapRT == null)
            {
                m_SkyboxCubemapRT = RTHandles.Alloc(resolution, resolution, colorFormat: HDRenderPipeline.OverrideRTGraphicsFormat(GraphicsFormat.R16G16B16A16_SFloat), dimension: TextureDimension.Cube, useMipMap: true, autoGenerateMips: false, filterMode: FilterMode.Trilinear, name: "SkyboxCubemap");
                if (m_SupportsConvolution)
                {
                    m_SkyboxBSDFCubemapIntermediate = RTHandles.Alloc(resolution, resolution, colorFormat: UnityEngine.Experimental.Rendering.HDPipeline.HDRenderPipeline.OverrideRTGraphicsFormat(GraphicsFormat.R16G16B16A16_SFloat), dimension: TextureDimension.Cube, useMipMap: true, autoGenerateMips: false, filterMode: FilterMode.Trilinear, name: "SkyboxBSDFIntermediate");
                    m_SkyboxBSDFCubemapArray        = new CubemapArray(resolution, m_IBLFilterArray.Length, TextureFormat.RGBAHalf, true)
                    {
                        hideFlags  = HideFlags.HideAndDontSave,
                        wrapMode   = TextureWrapMode.Repeat,
                        wrapModeV  = TextureWrapMode.Clamp,
                        filterMode = FilterMode.Trilinear,
                        anisoLevel = 0,
                        name       = "SkyboxCubemapConvolution"
                    };
                }
            }

            m_CubemapScreenSize = new Vector4((float)resolution, (float)resolution, 1.0f / (float)resolution, 1.0f / (float)resolution);

            if (updateNeeded)
            {
                m_NeedUpdate = true; // Special case. Even if update mode is set to OnDemand, we need to regenerate the environment after destroying the texture.
                RebuildSkyMatrices(resolution);
            }
        }
Ejemplo n.º 9
0
        public void Init(HDRenderPipelineAsset asset, HDRaytracingManager raytracingManager, SharedRTManager sharedRTManager, HDRenderPipeline renderPipeline, GBufferManager gbufferManager)
        {
            // Keep track of the pipeline asset
            m_PipelineAsset     = asset;
            m_PipelineResources = asset.renderPipelineResources;

            // keep track of the ray tracing manager
            m_RaytracingManager = raytracingManager;

            // Keep track of the shared rt manager
            m_SharedRTManager = sharedRTManager;

            // The render pipeline that holds all the lights of the scene
            m_RenderPipeline = renderPipeline;

            // GBuffer manager that holds all the data for shading the samples
            m_GbufferManager = gbufferManager;

            // Allocate the intermediate buffers
            m_AnalyticProbBuffer        = RTHandles.Alloc(Vector2.one, TextureXR.slices, colorFormat: GraphicsFormat.R16G16_SFloat, dimension: TextureXR.dimension, enableRandomWrite: true, useDynamicScale: true, useMipMap: false, name: "AnalyticProbBuffer");
            m_DenoiseBuffer0            = RTHandles.Alloc(Vector2.one, TextureXR.slices, colorFormat: GraphicsFormat.R16G16B16A16_SFloat, dimension: TextureXR.dimension, enableRandomWrite: true, useDynamicScale: true, useMipMap: false, name: "DenoiseBuffer0");
            m_DenoiseBuffer1            = RTHandles.Alloc(Vector2.one, TextureXR.slices, colorFormat: GraphicsFormat.R16G16B16A16_SFloat, dimension: TextureXR.dimension, enableRandomWrite: true, useDynamicScale: true, useMipMap: false, name: "DenoiseBuffer1");
            m_RaytracingDirectionBuffer = RTHandles.Alloc(Vector2.one, TextureXR.slices, colorFormat: GraphicsFormat.R16G16B16A16_SFloat, dimension: TextureXR.dimension, enableRandomWrite: true, useDynamicScale: true, useMipMap: false, name: "RaytracingDirectionBuffer");
            m_RaytracingDistanceBuffer  = RTHandles.Alloc(Vector2.one, TextureXR.slices, colorFormat: GraphicsFormat.R32_SFloat, dimension: TextureXR.dimension, enableRandomWrite: true, useDynamicScale: true, useMipMap: false, name: "RaytracingDistanceBuffer");

            // Allocate the final result texture
            m_AreaShadowTextureArray = RTHandles.Alloc(Vector2.one, slices: 4 * TextureXR.slices, dimension: TextureDimension.Tex2DArray, filterMode: FilterMode.Point, colorFormat: GraphicsFormat.R16_SFloat, enableRandomWrite: true, useDynamicScale: true, useMipMap: false, name: "AreaShadowArrayBuffer");
        }
Ejemplo n.º 10
0
        public void RenderReflectionsT1(HDCamera hdCamera, CommandBuffer cmd, RTHandleSystem.RTHandle outputTexture, ScriptableRenderContext renderContext, int frameCount)
        {
            // First thing to check is: Do we have a valid ray-tracing environment?
            HDRaytracingEnvironment rtEnvironment  = m_RaytracingManager.CurrentEnvironment();
            HDRenderPipeline        renderPipeline = m_RaytracingManager.GetRenderPipeline();
            BlueNoise        blueNoise             = m_RaytracingManager.GetBlueNoiseManager();
            ComputeShader    reflectionFilter      = m_PipelineAsset.renderPipelineRayTracingResources.reflectionBilateralFilterCS;
            RayTracingShader reflectionShader      = m_PipelineAsset.renderPipelineRayTracingResources.reflectionRaytracing;

            bool invalidState = rtEnvironment == null || blueNoise == null ||
                                reflectionFilter == null || reflectionShader == null ||
                                m_PipelineResources.textures.owenScrambledTex == null || m_PipelineResources.textures.scramblingTex == null;

            // If no acceleration structure available, end it now
            if (invalidState)
            {
                return;
            }

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

            // Grab the acceleration structures and the light cluster to use
            RayTracingAccelerationStructure accelerationStructure = m_RaytracingManager.RequestAccelerationStructure(rtEnvironment.reflLayerMask);
            HDRaytracingLightCluster        lightCluster          = m_RaytracingManager.RequestLightCluster(rtEnvironment.reflLayerMask);

            // Compute the actual resolution that is needed base on the quality
            string targetRayGen = m_RayGenHalfResName;

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

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

            // Inject the ray-tracing sampling data
            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._OwenScrambledTexture, m_PipelineResources.textures.owenScrambledTex);
            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._ScramblingTexture, m_PipelineResources.textures.scramblingTex);

            // Global reflection parameters
            cmd.SetRayTracingFloatParams(reflectionShader, HDShaderIDs._RaytracingIntensityClamp, settings.clampValue.value);
            cmd.SetRayTracingFloatParams(reflectionShader, HDShaderIDs._RaytracingReflectionMinSmoothness, settings.minSmoothness.value);
            cmd.SetRayTracingIntParams(reflectionShader, HDShaderIDs._RaytracingReflectSky, settings.reflectSky.value ? 1 : 0);

            // Inject the ray generation data
            cmd.SetGlobalFloat(HDShaderIDs._RaytracingRayBias, rtEnvironment.rayBias);
            cmd.SetGlobalFloat(HDShaderIDs._RaytracingRayMaxLength, settings.rayLength.value);
            cmd.SetRayTracingIntParams(reflectionShader, HDShaderIDs._RaytracingNumSamples, settings.numSamples.value);
            int frameIndex = hdCamera.IsTAAEnabled() ? hdCamera.taaFrameIndex : (int)frameCount % 8;

            cmd.SetGlobalInt(HDShaderIDs._RaytracingFrameIndex, frameIndex);

            // Set the data for the ray generation
            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._SsrLightingTextureRW, m_LightingTexture);
            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._SsrHitPointTexture, m_HitPdfTexture);
            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._NormalBufferTexture, m_SharedRTManager.GetNormalBuffer());

            // Set ray count tex
            cmd.SetRayTracingIntParam(reflectionShader, HDShaderIDs._RayCountEnabled, m_RaytracingManager.rayCountManager.RayCountIsEnabled());
            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._RayCountTexture, m_RaytracingManager.rayCountManager.rayCountTexture);

            // Compute the pixel spread value
            float pixelSpreadAngle = Mathf.Atan(2.0f * Mathf.Tan(hdCamera.camera.fieldOfView * Mathf.PI / 360.0f) / Mathf.Min(hdCamera.actualWidth, hdCamera.actualHeight));

            cmd.SetRayTracingFloatParam(reflectionShader, HDShaderIDs._RaytracingPixelSpreadAngle, pixelSpreadAngle);

            // LightLoop data
            cmd.SetGlobalBuffer(HDShaderIDs._RaytracingLightCluster, lightCluster.GetCluster());
            cmd.SetGlobalBuffer(HDShaderIDs._LightDatasRT, lightCluster.GetLightDatas());
            cmd.SetGlobalVector(HDShaderIDs._MinClusterPos, lightCluster.GetMinClusterPos());
            cmd.SetGlobalVector(HDShaderIDs._MaxClusterPos, lightCluster.GetMaxClusterPos());
            cmd.SetGlobalInt(HDShaderIDs._LightPerCellCount, lightClusterSettings.maxNumLightsPercell.value);
            cmd.SetGlobalInt(HDShaderIDs._PunctualLightCountRT, lightCluster.GetPunctualLightCount());
            cmd.SetGlobalInt(HDShaderIDs._AreaLightCountRT, lightCluster.GetAreaLightCount());

            // Note: Just in case, we rebind the directional light data (in case they were not)
            cmd.SetGlobalBuffer(HDShaderIDs._DirectionalLightDatas, renderPipeline.m_LightLoopLightData.directionalLightData);
            cmd.SetGlobalInt(HDShaderIDs._DirectionalLightCount, renderPipeline.m_lightList.directionalLights.Count);

            // Evaluate the clear coat mask texture based on the lit shader mode
            RenderTargetIdentifier clearCoatMaskTexture = hdCamera.frameSettings.litShaderMode == LitShaderMode.Deferred ? m_GbufferManager.GetBuffersRTI()[2] : TextureXR.GetBlackTexture();

            cmd.SetRayTracingTextureParam(reflectionShader, HDShaderIDs._SsrClearCoatMaskTexture, clearCoatMaskTexture);

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

            // Compute the actual resolution that is needed base on the quality
            uint widthResolution  = (uint)hdCamera.actualWidth / 2;
            uint heightResolution = (uint)hdCamera.actualHeight / 2;

            // Force to disable specular lighting
            cmd.SetGlobalInt(HDShaderIDs._EnableSpecularLighting, 0);

            // Run the computation
            cmd.DispatchRays(reflectionShader, targetRayGen, widthResolution, heightResolution, 1);

            // Restore the previous state of specular lighting
            cmd.SetGlobalInt(HDShaderIDs._EnableSpecularLighting, hdCamera.frameSettings.IsEnabled(FrameSettingsField.SpecularLighting) ? 1 : 0);

            using (new ProfilingSample(cmd, "Filter Reflection", CustomSamplerId.RaytracingFilterReflection.GetSampler()))
            {
                // Fetch the right filter to use
                int currentKernel = reflectionFilter.FindKernel("RaytracingReflectionFilter");

                // Inject all the parameters for the compute
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrLightingTextureRW, m_LightingTexture);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrHitPointTexture, m_HitPdfTexture);
                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, "_VarianceTexture", m_VarianceBuffer);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_MinColorRangeTexture", m_MinBoundBuffer);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_MaxColorRangeTexture", m_MaxBoundBuffer);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_RaytracingReflectionTexture", outputTexture);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._ScramblingTexture, m_PipelineResources.textures.scramblingTex);
                cmd.SetComputeIntParam(reflectionFilter, HDShaderIDs._SpatialFilterRadius, settings.spatialFilterRadius.value);
                cmd.SetComputeFloatParam(reflectionFilter, HDShaderIDs._RaytracingReflectionMinSmoothness, settings.minSmoothness.value);

                // Texture dimensions
                int texWidth  = outputTexture.rt.width;
                int texHeight = outputTexture.rt.height;

                // 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
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._SsrClearCoatMaskTexture, clearCoatMaskTexture);

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

                int numTilesXFR = (texWidth + (areaTileSize - 1)) / areaTileSize;
                int numTilesYFR = (texHeight + (areaTileSize - 1)) / areaTileSize;

                RTHandleSystem.RTHandle history = hdCamera.GetCurrentFrameRT((int)HDCameraFrameHistoryType.RaytracedReflection)
                                                  ?? hdCamera.AllocHistoryFrameRT((int)HDCameraFrameHistoryType.RaytracedReflection, ReflectionHistoryBufferAllocatorFunction, 1);

                // Fetch the right filter to use
                currentKernel = reflectionFilter.FindKernel("TemporalAccumulationFilter");
                cmd.SetComputeFloatParam(reflectionFilter, HDShaderIDs._TemporalAccumuationWeight, settings.temporalAccumulationWeight.value);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._AccumulatedFrameTexture, history);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, HDShaderIDs._CurrentFrameTexture, outputTexture);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_MinColorRangeTexture", m_MinBoundBuffer);
                cmd.SetComputeTextureParam(reflectionFilter, currentKernel, "_MaxColorRangeTexture", m_MaxBoundBuffer);
                cmd.DispatchCompute(reflectionFilter, currentKernel, numTilesXFR, numTilesYFR, 1);
            }
        }
        public void Initialize(RenderPipelineResources rpResources, HDRenderPipelineRayTracingResources rpRTResources, HDRaytracingManager raytracingManager, SharedRTManager sharedRTManager, HDRenderPipeline renderPipeline)
        {
            // Keep track of the external buffers
            m_RenderPipelineResources           = rpResources;
            m_RenderPipelineRayTracingResources = rpRTResources;
            m_RaytracingManager = raytracingManager;

            // Keep track of the render pipeline
            m_RenderPipeline = renderPipeline;

            // Keep track of the shader rt manager
            m_SharedRTManager = sharedRTManager;

            // Texture used to output debug information
            m_DebugLightClusterTexture = RTHandles.Alloc(Vector2.one, filterMode: FilterMode.Point, colorFormat: GraphicsFormat.R16G16B16A16_SFloat, enableRandomWrite: true, useDynamicScale: true, useMipMap: false, name: "DebugLightClusterTexture");

            // Pre allocate the cluster with a dummy size
            m_LightCluster = new ComputeBuffer(1, sizeof(uint));
        }
Ejemplo n.º 12
0
        // BufferedRTHandleSystem API expects an allocator function. We define it here.
        static RTHandleSystem.RTHandle HistoryBufferAllocatorFunction(string viewName, int frameIndex, RTHandleSystem rtHandleSystem)
        {
            frameIndex &= 1;
            var hdPipeline = (HDRenderPipeline)RenderPipelineManager.currentPipeline;

            return(rtHandleSystem.Alloc(Vector2.one, filterMode: FilterMode.Point, colorFormat: HDRenderPipeline.OverrideRTGraphicsFormat((GraphicsFormat)hdPipeline.currentPlatformRenderPipelineSettings.colorBufferFormat),
                                        enableRandomWrite: true, useMipMap: true, autoGenerateMips: false, xrInstancing: true,
                                        name: string.Format("CameraColorBufferMipChain{0}", frameIndex)));
        }
Ejemplo n.º 13
0
        private void SssSettingsUI(HDRenderPipeline pipe)
        {
            EditorGUILayout.Space();

            EditorGUILayout.LabelField(styles.sssSettings);
            EditorGUI.BeginChangeCheck();
            EditorGUI.indentLevel++;

            EditorGUI.BeginChangeCheck();

            EditorGUILayout.PropertyField(m_NumProfiles, styles.sssNumProfiles);
            m_TexturingMode.intValue = EditorGUILayout.Popup(styles.sssTexturingMode, m_TexturingMode.intValue, styles.sssTexturingModeOptions, (GUILayoutOption[])null);

            for (int i = 0, n = Math.Min(m_Profiles.arraySize, SubsurfaceScatteringSettings.maxNumProfiles); i < n; i++)
            {
                SerializedProperty profile = m_Profiles.GetArrayElementAtIndex(i);
                EditorGUILayout.PropertyField(profile, styles.sssProfiles[i]);

                if (profile.isExpanded)
                {
                    EditorGUI.indentLevel++;

                    SerializedProperty profileStdDev1        = profile.FindPropertyRelative("stdDev1");
                    SerializedProperty profileStdDev2        = profile.FindPropertyRelative("stdDev2");
                    SerializedProperty profileLerpWeight     = profile.FindPropertyRelative("lerpWeight");
                    SerializedProperty profileTransmission   = profile.FindPropertyRelative("enableTransmission");
                    SerializedProperty profileThicknessRemap = profile.FindPropertyRelative("thicknessRemap");

                    EditorGUILayout.PropertyField(profileStdDev1, styles.sssProfileStdDev1);
                    EditorGUILayout.PropertyField(profileStdDev2, styles.sssProfileStdDev2);
                    EditorGUILayout.PropertyField(profileLerpWeight, styles.sssProfileLerpWeight);
                    EditorGUILayout.PropertyField(profileTransmission, styles.sssProfileTransmission);

                    Vector2 thicknessRemap = profileThicknessRemap.vector2Value;
                    EditorGUILayout.LabelField("Min thickness: ", thicknessRemap.x.ToString());
                    EditorGUILayout.LabelField("Max thickness: ", thicknessRemap.y.ToString());
                    EditorGUILayout.MinMaxSlider(styles.sssProfileThicknessRemap, ref thicknessRemap.x, ref thicknessRemap.y, 0, 10);
                    profileThicknessRemap.vector2Value = thicknessRemap;

                    EditorGUILayout.Space();
                    EditorGUILayout.LabelField(styles.sssProfilePreview0, styles.centeredMiniBoldLabel);
                    EditorGUILayout.LabelField(styles.sssProfilePreview1, EditorStyles.centeredGreyMiniLabel);
                    EditorGUILayout.LabelField(styles.sssProfilePreview2, EditorStyles.centeredGreyMiniLabel);
                    EditorGUILayout.Space();

                    // Draw the profile.
                    m_ProfileMaterial.SetColor("_StdDev1", profileStdDev1.colorValue);
                    m_ProfileMaterial.SetColor("_StdDev2", profileStdDev2.colorValue);
                    m_ProfileMaterial.SetFloat("_LerpWeight", profileLerpWeight.floatValue);
                    EditorGUI.DrawPreviewTexture(GUILayoutUtility.GetRect(256, 256), m_ProfileImages[i], m_ProfileMaterial, ScaleMode.ScaleToFit, 1.0f);

                    EditorGUILayout.Space();
                    EditorGUILayout.LabelField(styles.sssTransmittancePreview0, styles.centeredMiniBoldLabel);
                    EditorGUILayout.LabelField(styles.sssTransmittancePreview1, EditorStyles.centeredGreyMiniLabel);
                    EditorGUILayout.Space();

                    // Draw the transmittance graph.
                    m_TransmittanceMaterial.SetColor("_StdDev1", profileStdDev1.colorValue);
                    m_TransmittanceMaterial.SetColor("_StdDev2", profileStdDev2.colorValue);
                    m_TransmittanceMaterial.SetFloat("_LerpWeight", profileLerpWeight.floatValue);
                    m_TransmittanceMaterial.SetVector("_ThicknessRemap", profileThicknessRemap.vector2Value);
                    EditorGUI.DrawPreviewTexture(GUILayoutUtility.GetRect(16, 16), m_TransmittanceImages[i], m_TransmittanceMaterial, ScaleMode.ScaleToFit, 16.0f);

                    EditorGUILayout.Space();

                    EditorGUI.indentLevel--;
                }
            }

            EditorGUI.indentLevel--;
        }
Ejemplo n.º 14
0
        Texture[] ConvolveProbeTexture(CommandBuffer cmd, Texture texture)
        {
            // Probes can be either Cubemaps (for baked probes) or RenderTextures (for realtime probes)
            Cubemap       cubeTexture   = texture as Cubemap;
            RenderTexture renderTexture = texture as RenderTexture;

            RenderTexture convolutionSourceTexture = null;

            if (cubeTexture != null)
            {
                // if the size if different from the cache probe size or if the input texture format is compressed, we need to convert it
                // 1) to a format for which we can generate mip maps
                // 2) to the proper reflection probe cache size
                bool sizeMismatch   = cubeTexture.width != m_ProbeSize || cubeTexture.height != m_ProbeSize;
                bool formatMismatch = cubeTexture.format != TextureFormat.RGBAHalf; // Temporary RT for convolution is always FP16
                if (formatMismatch || sizeMismatch)
                {
                    // We comment the following warning as they have no impact on the result but spam the console, it is just that we waste offline time and a bit of quality for nothing.
                    if (sizeMismatch)
                    {
                        // Debug.LogWarningFormat("Baked Reflection Probe {0} does not match HDRP Reflection Probe Cache size of {1}. Consider baking it at the same size for better loading performance.", texture.name, m_ProbeSize);
                    }
                    else if (cubeTexture.format == TextureFormat.BC6H)
                    {
                        // Debug.LogWarningFormat("Baked Reflection Probe {0} is compressed but the HDRP Reflection Probe Cache is not. Consider removing compression from the input texture for better quality.", texture.name);
                    }
                    ConvertTexture(cmd, cubeTexture, m_TempRenderTexture);
                }
                else
                {
                    for (int f = 0; f < 6; f++)
                    {
                        cmd.CopyTexture(cubeTexture, f, 0, m_TempRenderTexture, f, 0);
                    }
                }

                // Ideally if input is not compressed and has mipmaps, don't do anything here. Problem is, we can't know if mips have been already convolved offline...
                //cmd.GenerateMips(m_TempRenderTexture);
                HDRenderPipeline.RT_GenerateMips(cmd, m_TempRenderTexture);
                convolutionSourceTexture = m_TempRenderTexture;
            }
            else
            {
                Debug.Assert(renderTexture != null);
                if (renderTexture.dimension != TextureDimension.Cube)
                {
                    Debug.LogError("Realtime reflection probe should always be a Cube RenderTexture.");
                    return(null);
                }

                // TODO: Do a different case for downsizing, in this case, instead of doing ConvertTexture just use the relevant mipmaps.
                bool sizeMismatch = renderTexture.width != m_ProbeSize || renderTexture.height != m_ProbeSize;
                if (sizeMismatch)
                {
                    ConvertTexture(cmd, renderTexture, m_TempRenderTexture);
                    convolutionSourceTexture = m_TempRenderTexture;
                }
                else
                {
                    convolutionSourceTexture = renderTexture;
                }
                // Generate unfiltered mipmaps as a base for convolution
                // TODO: Make sure that we don't first convolve everything on the GPU with the legacy code path executed after rendering the probe.
                HDRenderPipeline.RT_GenerateMips(cmd, convolutionSourceTexture);
                //cmd.GenerateMips(convolutionSourceTexture);
            }

            for (int bsdfIdx = 0; bsdfIdx < m_IBLFilterBSDF.Length; ++bsdfIdx)
            {
                m_IBLFilterBSDF[bsdfIdx].FilterCubemap(cmd, convolutionSourceTexture, m_ConvolutionTargetTextureArray[bsdfIdx]);
            }

            return(m_ConvolutionTargetTextureArray);
        }
Ejemplo n.º 15
0
        private void DebugParametersUI(HDRenderPipeline renderContext)
        {
            m_ShowDebug.boolValue = EditorGUILayout.Foldout(m_ShowDebug.boolValue, styles.debugParameters);
            if (!m_ShowDebug.boolValue)
            {
                return;
            }

            var debugParameters = renderContext.debugParameters;

            EditorGUI.indentLevel++;
            EditorGUI.BeginChangeCheck();

            if (!styles.isDebugViewMaterialInit)
            {
                var varyingNames = Enum.GetNames(typeof(Attributes.DebugViewVarying));
                var gbufferNames = Enum.GetNames(typeof(Attributes.DebugViewGbuffer));

                // +1 for the zero case
                var num = 1 + varyingNames.Length
                          + gbufferNames.Length
                          + typeof(Builtin.BuiltinData).GetFields().Length * 2 // BuildtinData are duplicated for each material
                          + typeof(Lit.SurfaceData).GetFields().Length
                          + typeof(Lit.BSDFData).GetFields().Length
                          + typeof(Unlit.SurfaceData).GetFields().Length
                          + typeof(Unlit.BSDFData).GetFields().Length;

                styles.debugViewMaterialStrings = new GUIContent[num];
                styles.debugViewMaterialValues  = new int[num];

                var index = 0;

                // 0 is a reserved number
                styles.debugViewMaterialStrings[0] = new GUIContent("None");
                styles.debugViewMaterialValues[0]  = 0;
                index++;

                FillWithPropertiesEnum(typeof(Attributes.DebugViewVarying), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, GetSubNameSpaceName(typeof(Attributes.DebugViewVarying)), false, ref index);
                FillWithProperties(typeof(Builtin.BuiltinData), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, false, GetSubNameSpaceName(typeof(Lit.SurfaceData)), ref index);
                FillWithProperties(typeof(Lit.SurfaceData), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, false, GetSubNameSpaceName(typeof(Lit.SurfaceData)), ref index);
                FillWithProperties(typeof(Builtin.BuiltinData), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, false, GetSubNameSpaceName(typeof(Unlit.SurfaceData)), ref index);
                FillWithProperties(typeof(Unlit.SurfaceData), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, false, GetSubNameSpaceName(typeof(Unlit.SurfaceData)), ref index);

                // Engine
                FillWithPropertiesEnum(typeof(Attributes.DebugViewGbuffer), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, "", true, ref index);
                FillWithProperties(typeof(Lit.BSDFData), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, true, "", ref index);
                FillWithProperties(typeof(Unlit.BSDFData), styles.debugViewMaterialStrings, styles.debugViewMaterialValues, true, "", ref index);

                styles.isDebugViewMaterialInit = true;
            }

            debugParameters.debugViewMaterial = EditorGUILayout.IntPopup(styles.debugViewMaterial, (int)debugParameters.debugViewMaterial, styles.debugViewMaterialStrings, styles.debugViewMaterialValues);

            EditorGUILayout.Space();
            debugParameters.displayOpaqueObjects      = EditorGUILayout.Toggle(styles.displayOpaqueObjects, debugParameters.displayOpaqueObjects);
            debugParameters.displayTransparentObjects = EditorGUILayout.Toggle(styles.displayTransparentObjects, debugParameters.displayTransparentObjects);
            debugParameters.useForwardRenderingOnly   = EditorGUILayout.Toggle(styles.useForwardRenderingOnly, debugParameters.useForwardRenderingOnly);
            debugParameters.useDepthPrepass           = EditorGUILayout.Toggle(styles.useDepthPrepass, debugParameters.useDepthPrepass);
            debugParameters.useDistortion             = EditorGUILayout.Toggle(styles.useDistortion, debugParameters.useDistortion);

            if (EditorGUI.EndChangeCheck())
            {
                HackSetDirty(renderContext); // Repaint
            }
            EditorGUI.indentLevel--;
        }
Ejemplo n.º 16
0
        private void LightingDebugSettingsUI(HDRenderPipeline renderContext, HDRenderPipelineInstance renderpipelineInstance)
        {
            m_ShowLightingDebug.boolValue = EditorGUILayout.Foldout(m_ShowLightingDebug.boolValue, styles.lightingDebugSettings);
            if (!m_ShowLightingDebug.boolValue)
            {
                return;
            }

            HDRenderPipeline hdPipe = target as HDRenderPipeline;

            bool dirty = false;

            EditorGUI.BeginChangeCheck();
            EditorGUI.indentLevel++;
            EditorGUILayout.PropertyField(m_DebugShadowEnabled, styles.shadowDebugEnable);
            EditorGUILayout.PropertyField(m_ShadowDebugMode, styles.shadowDebugVisualizationMode);
            if (!m_ShadowDebugMode.hasMultipleDifferentValues)
            {
                if ((ShadowMapDebugMode)m_ShadowDebugMode.intValue == ShadowMapDebugMode.VisualizeShadowMap)
                {
                    EditorGUILayout.IntSlider(m_ShadowDebugShadowMapIndex, 0, renderpipelineInstance.GetCurrentShadowCount() - 1, styles.shadowDebugVisualizeShadowIndex);
                }
            }
            if (EditorGUI.EndChangeCheck())
            {
                dirty = true;
            }

            EditorGUI.BeginChangeCheck();
            int value = EditorGUILayout.IntPopup(styles.lightingVisualizationMode, (int)hdPipe.debugDisplaySettings.lightingDebugSettings.debugLightingMode, styles.debugViewLightingStrings, styles.debugViewLightingValues);

            if (EditorGUI.EndChangeCheck())
            {
                hdPipe.debugDisplaySettings.SetDebugLightingMode((DebugLightingMode)value);
                dirty = true;
            }

            EditorGUI.BeginChangeCheck();
            if (hdPipe.debugDisplaySettings.GetDebugLightingMode() == DebugLightingMode.DiffuseLighting)
            {
                EditorGUI.indentLevel++;
                EditorGUILayout.PropertyField(m_LightingDebugAlbedo, styles.lightingDebugAlbedo);
                EditorGUI.indentLevel--;
            }

            if (hdPipe.debugDisplaySettings.GetDebugLightingMode() == DebugLightingMode.SpecularLighting)
            {
                EditorGUI.indentLevel++;
                EditorGUILayout.PropertyField(m_LightingDebugOverrideSmoothness, styles.lightingDebugOverrideSmoothness);
                if (!m_LightingDebugOverrideSmoothness.hasMultipleDifferentValues && m_LightingDebugOverrideSmoothness.boolValue == true)
                {
                    EditorGUI.indentLevel++;
                    EditorGUILayout.PropertyField(m_LightingDebugOverrideSmoothnessValue, styles.lightingDebugOverrideSmoothnessValue);
                    EditorGUI.indentLevel--;
                }
                EditorGUI.indentLevel--;
            }

            EditorGUILayout.PropertyField(m_LightingDebugDisplaySkyReflection, styles.lightingDisplaySkyReflection);
            if (!m_LightingDebugDisplaySkyReflection.hasMultipleDifferentValues && m_LightingDebugDisplaySkyReflection.boolValue == true)
            {
                EditorGUI.indentLevel++;
                EditorGUILayout.PropertyField(m_LightingDebugDisplaySkyReflectionMipmap, styles.lightingDisplaySkyReflectionMipmap);
                EditorGUI.indentLevel--;
            }

            EditorGUI.indentLevel--;

            if (EditorGUI.EndChangeCheck())
            {
                dirty = true;
            }

            if (dirty)
            {
                HackSetDirty(renderContext);
            }
        }
Ejemplo n.º 17
0
        public void Render(HDCamera hdCamera, CommandBuffer cmd, RTHandleSystem.RTHandle outputTexture, ScriptableRenderContext renderContext, CullingResults cull)
        {
            // First thing to check is: Do we have a valid ray-tracing environment?
            HDRaytracingEnvironment rtEnvironement = m_RaytracingManager.CurrentEnvironment();
            LightLoop        lightLoop             = m_RaytracingManager.GetLightLoop();
            RaytracingShader forwardShader         = m_PipelineAsset.renderPipelineResources.shaders.forwardRaytracing;
            Shader           raytracingMask        = m_PipelineAsset.renderPipelineResources.shaders.raytracingFlagMask;

            // Check the validity of the state before computing the effect
            bool invalidState = rtEnvironement == null || !rtEnvironement.raytracedObjects ||
                                forwardShader == null || raytracingMask == null ||
                                m_PipelineResources.textures.owenScrambledTex == null || m_PipelineResources.textures.scramblingTex == null;

            // If any resource or game-object is missing We stop right away
            if (invalidState)
            {
                return;
            }

            // Grab the acceleration structure and the list of HD lights for the target camera
            RaytracingAccelerationStructure accelerationStructure = m_RaytracingManager.RequestAccelerationStructure(rtEnvironement.raytracedLayerMask);
            HDRaytracingLightCluster        lightCluster          = m_RaytracingManager.RequestLightCluster(rtEnvironement.raytracedLayerMask);

            if (m_RaytracingFlagMaterial == null)
            {
                m_RaytracingFlagMaterial = CoreUtils.CreateEngineMaterial(raytracingMask);
            }

            // Before going into raytracing, we need to flag which pixels needs to be raytracing
            EvaluateRaytracingMask(cull, hdCamera, cmd, renderContext);

            // Define the shader pass to use for the reflection pass
            cmd.SetRaytracingShaderPass(forwardShader, "ForwardDXR");

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

            // Inject the ray-tracing sampling data
            cmd.SetRaytracingTextureParam(forwardShader, m_RayGenShaderName, HDShaderIDs._OwenScrambledTexture, m_PipelineResources.textures.owenScrambledTex);
            cmd.SetRaytracingTextureParam(forwardShader, m_RayGenShaderName, HDShaderIDs._ScramblingTexture, m_PipelineResources.textures.scramblingTex);

            // Inject the ray generation data
            cmd.SetGlobalFloat(HDShaderIDs._RaytracingRayBias, rtEnvironement.rayBias);
            cmd.SetGlobalFloat(HDShaderIDs._RaytracingRayMaxLength, rtEnvironement.raytracingRayLength);
            cmd.SetGlobalFloat(HDShaderIDs._RaytracingMaxRecursion, rtEnvironement.rayMaxDepth);
            cmd.SetGlobalFloat(HDShaderIDs._RaytracingCameraNearPlane, hdCamera.camera.nearClipPlane);

            // Set the data for the ray generation
            cmd.SetRaytracingTextureParam(forwardShader, m_RayGenShaderName, HDShaderIDs._RaytracingFlagMask, m_RaytracingFlagTarget);
            cmd.SetRaytracingTextureParam(forwardShader, m_RayGenShaderName, HDShaderIDs._DepthTexture, m_SharedRTManager.GetDepthStencilBuffer());
            cmd.SetRaytracingTextureParam(forwardShader, m_RayGenShaderName, HDShaderIDs._CameraColorTextureRW, outputTexture);

            // Compute an approximate pixel spread angle value (in radians)
            float pixelSpreadAngle = hdCamera.camera.fieldOfView * (Mathf.PI / 180.0f) / Mathf.Min(hdCamera.actualWidth, hdCamera.actualHeight);

            cmd.SetGlobalFloat(HDShaderIDs._RaytracingPixelSpreadAngle, pixelSpreadAngle);

            // LightLoop data
            cmd.SetGlobalBuffer(HDShaderIDs._RaytracingLightCluster, lightCluster.GetCluster());
            cmd.SetGlobalBuffer(HDShaderIDs._LightDatasRT, lightCluster.GetLightDatas());
            cmd.SetGlobalVector(HDShaderIDs._MinClusterPos, lightCluster.GetMinClusterPos());
            cmd.SetGlobalVector(HDShaderIDs._MaxClusterPos, lightCluster.GetMaxClusterPos());
            cmd.SetGlobalInt(HDShaderIDs._LightPerCellCount, rtEnvironement.maxNumLightsPercell);
            cmd.SetGlobalInt(HDShaderIDs._PunctualLightCountRT, lightCluster.GetPunctualLightCount());
            cmd.SetGlobalInt(HDShaderIDs._AreaLightCountRT, lightCluster.GetAreaLightCount());

            // Note: Just in case, we rebind the directional light data (in case they were not)
            cmd.SetGlobalBuffer(HDShaderIDs._DirectionalLightDatas, lightLoop.directionalLightDatas);
            cmd.SetGlobalInt(HDShaderIDs._DirectionalLightCount, lightLoop.m_lightList.directionalLights.Count);

            // Set the data for the ray miss
            cmd.SetRaytracingTextureParam(forwardShader, m_MissShaderName, HDShaderIDs._SkyTexture, m_SkyManager.skyReflection);

            // If this is the right debug mode and we have at least one light, write the first shadow to the denoise texture
            HDRenderPipeline hdrp = (RenderPipelineManager.currentPipeline as HDRenderPipeline);

            cmd.SetRaytracingTextureParam(forwardShader, m_RayGenShaderName, HDShaderIDs._RaytracingPrimaryDebug, m_DebugRaytracingTexture);
            hdrp.PushFullScreenDebugTexture(hdCamera, cmd, m_DebugRaytracingTexture, FullScreenDebugMode.PrimaryVisibility);

            // Run the calculus
            cmd.DispatchRays(forwardShader, m_RayGenShaderName, (uint)hdCamera.actualWidth, (uint)hdCamera.actualHeight, 1);
        }
        public override void OnInspectorGUI()
        {
            serializedObject.Update();

            // Old SSS Model >>>
            bool useDisneySSS;

            {
                HDRenderPipeline hdPipeline = RenderPipelineManager.currentPipeline as HDRenderPipeline;
                useDisneySSS = hdPipeline.sssSettings.useDisneySSS;
            }
            // <<< Old SSS Model

            EditorGUI.BeginChangeCheck();
            {
                if (useDisneySSS)
                {
                    EditorGUILayout.PropertyField(m_ScatteringDistance, styles.sssProfileScatteringDistance);

                    GUI.enabled = false;
                    EditorGUILayout.PropertyField(m_MaxRadius, styles.sssProfileMaxRadius);
                    GUI.enabled = true;
                }
                else
                {
                    EditorGUILayout.PropertyField(m_ScatterDistance1, styles.sssProfileScatterDistance1);
                    EditorGUILayout.PropertyField(m_ScatterDistance2, styles.sssProfileScatterDistance2);
                    EditorGUILayout.PropertyField(m_LerpWeight, styles.sssProfileLerpWeight);
                }

                m_TexturingMode.intValue    = EditorGUILayout.Popup(styles.sssTexturingMode, m_TexturingMode.intValue, styles.sssTexturingModeOptions);
                m_TransmissionMode.intValue = EditorGUILayout.Popup(styles.sssProfileTransmissionMode, m_TransmissionMode.intValue, styles.sssTransmissionModeOptions);

                EditorGUILayout.PropertyField(m_TransmissionTint, styles.sssProfileTransmissionTint);
                EditorGUILayout.PropertyField(m_ThicknessRemap, styles.sssProfileMinMaxThickness);
                Vector2 thicknessRemap = m_ThicknessRemap.vector2Value;
                EditorGUILayout.MinMaxSlider(styles.sssProfileThicknessRemap, ref thicknessRemap.x, ref thicknessRemap.y, 0.0f, 50.0f);
                m_ThicknessRemap.vector2Value = thicknessRemap;
                EditorGUILayout.PropertyField(m_WorldScale, styles.sssProfileWorldScale);

                EditorGUILayout.Space();
                EditorGUILayout.LabelField(styles.sssProfilePreview0, styles.centeredMiniBoldLabel);
                EditorGUILayout.LabelField(styles.sssProfilePreview1, EditorStyles.centeredGreyMiniLabel);
                EditorGUILayout.LabelField(styles.sssProfilePreview2, EditorStyles.centeredGreyMiniLabel);
                EditorGUILayout.LabelField(styles.sssProfilePreview3, EditorStyles.centeredGreyMiniLabel);
                EditorGUILayout.Space();
            }

            float   r = m_MaxRadius.floatValue;
            Vector3 S = m_ShapeParam.vector3Value;
            Vector4 T = m_TransmissionTint.colorValue;
            Vector2 R = m_ThicknessRemap.vector2Value;
            bool    transmissionEnabled = m_TransmissionMode.intValue != (int)SubsurfaceScatteringProfile.TransmissionMode.None;

            // Draw the profile.
            m_ProfileMaterial.SetFloat("_MaxRadius", r);
            m_ProfileMaterial.SetVector("_ShapeParam", S);
            // Old SSS Model >>>
            Utilities.SelectKeyword(m_ProfileMaterial, "SSS_MODEL_DISNEY", "SSS_MODEL_BASIC", useDisneySSS);
            // Apply the three-sigma rule, and rescale.
            float s    = (1.0f / 3.0f) * SssConstants.SSS_BASIC_DISTANCE_SCALE;
            float rMax = Mathf.Max(m_ScatterDistance1.colorValue.r, m_ScatterDistance1.colorValue.g, m_ScatterDistance1.colorValue.b,
                                   m_ScatterDistance2.colorValue.r, m_ScatterDistance2.colorValue.g, m_ScatterDistance2.colorValue.b);
            Vector4 stdDev1 = new Vector4(s * m_ScatterDistance1.colorValue.r, s * m_ScatterDistance1.colorValue.g, s * m_ScatterDistance1.colorValue.b);
            Vector4 stdDev2 = new Vector4(s * m_ScatterDistance2.colorValue.r, s * m_ScatterDistance2.colorValue.g, s * m_ScatterDistance2.colorValue.b);

            m_ProfileMaterial.SetVector("_StdDev1", stdDev1);
            m_ProfileMaterial.SetVector("_StdDev2", stdDev2);
            m_ProfileMaterial.SetFloat("_LerpWeight", m_LerpWeight.floatValue);
            m_ProfileMaterial.SetFloat("_MaxRadius", rMax);
            // <<< Old SSS Model
            EditorGUI.DrawPreviewTexture(GUILayoutUtility.GetRect(256, 256), m_ProfileImage, m_ProfileMaterial, ScaleMode.ScaleToFit, 1.0f);

            EditorGUILayout.Space();
            EditorGUILayout.LabelField(styles.sssTransmittancePreview0, styles.centeredMiniBoldLabel);
            EditorGUILayout.LabelField(styles.sssTransmittancePreview1, EditorStyles.centeredGreyMiniLabel);
            EditorGUILayout.LabelField(styles.sssTransmittancePreview2, EditorStyles.centeredGreyMiniLabel);
            EditorGUILayout.Space();

            // Draw the transmittance graph.
            m_TransmittanceMaterial.SetVector("_ShapeParam", S);
            m_TransmittanceMaterial.SetVector("_TransmissionTint", transmissionEnabled ? T : Vector4.zero);
            m_TransmittanceMaterial.SetVector("_ThicknessRemap", R);
            EditorGUI.DrawPreviewTexture(GUILayoutUtility.GetRect(16, 16), m_TransmittanceImage, m_TransmittanceMaterial, ScaleMode.ScaleToFit, 16.0f);

            serializedObject.ApplyModifiedProperties();

            if (EditorGUI.EndChangeCheck())
            {
                HDRenderPipeline hdPipeline = RenderPipelineManager.currentPipeline as HDRenderPipeline;
                // Validate each individual asset and update caches.
                hdPipeline.sssSettings.OnValidate();
            }
        }
Ejemplo n.º 19
0
        Texture ConvolveProbeTexture(CommandBuffer cmd, Texture texture)
        {
            // Probes can be either Cubemaps (for baked probes) or RenderTextures (for realtime probes)
            Texture2D     texture2D     = texture as Texture2D;
            RenderTexture renderTexture = texture as RenderTexture;

            RenderTexture convolutionSourceTexture = null;

            if (texture2D != null)
            {
                // if the size if different from the cache probe size or if the input texture format is compressed, we need to convert it
                // 1) to a format for which we can generate mip maps
                // 2) to the proper reflection probe cache size
                var sizeMismatch   = texture2D.width != m_ProbeSize || texture2D.height != m_ProbeSize;
                var formatMismatch = texture2D.format != TextureFormat.RGBAHalf; // Temporary RT for convolution is always FP16
                if (formatMismatch || sizeMismatch)
                {
                    if (sizeMismatch)
                    {
                        Debug.LogWarningFormat("Baked Planar Reflection Probe {0} does not match HDRP Planar Reflection Probe Cache size of {1}. Consider baking it at the same size for better loading performance.", texture.name, m_ProbeSize);
                    }
                    else if (texture2D.format == TextureFormat.BC6H)
                    {
                        Debug.LogWarningFormat("Baked Planar Reflection Probe {0} is compressed but the HDRP Planar Reflection Probe Cache is not. Consider removing compression from the input texture for better quality.", texture.name);
                    }
                    ConvertTexture(cmd, texture2D, m_TempRenderTexture);
                }
                else
                {
                    cmd.CopyTexture(texture2D, 0, 0, m_TempRenderTexture, 0, 0);
                }

                // Ideally if input is not compressed and has mipmaps, don't do anything here. Problem is, we can't know if mips have been already convolved offline...
                //cmd.GenerateMips(m_TempRenderTexture);
                HDRenderPipeline.RT_GenerateMips(cmd, m_TempRenderTexture);
                convolutionSourceTexture = m_TempRenderTexture;
            }
            else
            {
                Debug.Assert(renderTexture != null);
                if (renderTexture.dimension != TextureDimension.Tex2D)
                {
                    Debug.LogError("Planar Realtime reflection probe should always be a 2D RenderTexture.");
                    return(null);
                }

                // TODO: Do a different case for downsizing, in this case, instead of doing ConvertTexture just use the relevant mipmaps.
                var sizeMismatch = renderTexture.width != m_ProbeSize || renderTexture.height != m_ProbeSize;
                if (sizeMismatch)
                {
                    ConvertTexture(cmd, renderTexture, m_TempRenderTexture);
                    convolutionSourceTexture = m_TempRenderTexture;
                }
                else
                {
                    convolutionSourceTexture = renderTexture;
                }
                // Generate unfiltered mipmaps as a base for convolution
                // TODO: Make sure that we don't first convolve everything on the GPU with the legacy code path executed after rendering the probe.
                //cmd.GenerateMips(convolutionSourceTexture);
                HDRenderPipeline.RT_GenerateMips(cmd, convolutionSourceTexture);
            }

            m_IBLFilterGGX.FilterPlanarTexture(cmd, convolutionSourceTexture, m_ConvolutionTargetTexture);

            return(m_ConvolutionTargetTexture);
        }