using System; using UnityEngine.Rendering; using UnityEngine.Rendering.PostProcessing; using UnityEngine.XR; namespace UnityEngine.Experimental.Rendering.LightweightPipeline { [Serializable] public class ShadowSettings { public bool enabled; public int shadowAtlasWidth; public int shadowAtlasHeight; public float maxShadowDistance; public int directionalLightCascadeCount; public Vector3 directionalLightCascades; public float directionalLightNearPlaneOffset; static ShadowSettings defaultShadowSettings = null; public static ShadowSettings Default { get { if (defaultShadowSettings == null) { defaultShadowSettings = new ShadowSettings(); defaultShadowSettings.enabled = true; defaultShadowSettings.shadowAtlasHeight = defaultShadowSettings.shadowAtlasWidth = 4096; defaultShadowSettings.directionalLightCascadeCount = 1; defaultShadowSettings.directionalLightCascades = new Vector3(0.05F, 0.2F, 0.3F); defaultShadowSettings.directionalLightCascadeCount = 4; defaultShadowSettings.directionalLightNearPlaneOffset = 5; defaultShadowSettings.maxShadowDistance = 1000.0F; } return defaultShadowSettings; } } } public struct ShadowSliceData { public Matrix4x4 shadowTransform; public int atlasX; public int atlasY; public int shadowResolution; } public struct LightData { public int pixelLightsCount; public int vertexLightsCount; public int shadowLightIndex; public bool isSingleLight; public bool shadowsRendered; } public class LightweightPipeline : RenderPipeline { private readonly LightweightPipelineAsset m_Asset; // Max amount of visible lights. This controls the lights constant buffers in shader but not the max shaded lights. // Lights are set per-object and the max shaded lights for each object are controlled by the max pixel lights in pipeline asset and kMaxVertexLights. private static readonly int kMaxVisibleLights = 16; private static readonly int kMaxPerObjectLights = 4; private Vector4[] m_LightPositions = new Vector4[kMaxVisibleLights]; private Vector4[] m_LightColors = new Vector4[kMaxVisibleLights]; private Vector4[] m_LightAttenuations = new Vector4[kMaxVisibleLights]; private Vector4[] m_LightSpotDirections = new Vector4[kMaxVisibleLights]; private Camera m_CurrCamera = null; private LightType m_SingleLightType = LightType.Directional; private int m_LightIndicesCount = 0; private ComputeBuffer m_LightIndexListBuffer; private static readonly int kMaxCascades = 4; private int m_ShadowCasterCascadesCount = kMaxCascades; private int m_ShadowMapProperty; private int m_CameraRTProperty; private RenderTargetIdentifier m_ShadowMapRTID; private RenderTargetIdentifier m_CameraRTID; private bool m_RenderToIntermediateTarget = false; private bool m_IntermediateTextureArray = false; private const int kShadowDepthBufferBits = 16; private const int kCameraDepthBufferBits = 32; private Vector4[] m_DirectionalShadowSplitDistances = new Vector4[kMaxCascades]; private ShadowSettings m_ShadowSettings = ShadowSettings.Default; private ShadowSliceData[] m_ShadowSlices = new ShadowSliceData[kMaxCascades]; private static readonly ShaderPassName m_LitPassName = new ShaderPassName("LightweightForward"); private static readonly ShaderPassName m_UnlitPassName = new ShaderPassName("SRPDefaultUnlit"); private RenderTextureFormat m_ColorFormat = RenderTextureFormat.ARGB32; private PostProcessRenderContext m_PostProcessRenderContext; public LightweightPipeline(LightweightPipelineAsset asset) { m_Asset = asset; BuildShadowSettings(); m_ShadowMapProperty = Shader.PropertyToID("_ShadowMap"); m_CameraRTProperty = Shader.PropertyToID("_CameraRT"); m_ShadowMapRTID = new RenderTargetIdentifier(m_ShadowMapProperty); m_CameraRTID = new RenderTargetIdentifier(m_CameraRTProperty); m_PostProcessRenderContext = new PostProcessRenderContext(); // Let engine know we have MSAA on for cases where we support MSAA backbuffer if (QualitySettings.antiAliasing != m_Asset.MSAASampleCount) QualitySettings.antiAliasing = m_Asset.MSAASampleCount; Shader.globalRenderPipeline = "LightweightPipeline"; } public override void Dispose() { base.Dispose(); Shader.globalRenderPipeline = ""; if (m_LightIndexListBuffer != null) { m_LightIndexListBuffer.Dispose(); m_LightIndexListBuffer = null; m_LightIndicesCount = 0; } } CullResults m_CullResults; public override void Render(ScriptableRenderContext context, Camera[] cameras) { base.Render(context, cameras); bool stereoEnabled = XRSettings.isDeviceActive; foreach (Camera camera in cameras) { m_CurrCamera = camera; ScriptableCullingParameters cullingParameters; if (!CullResults.GetCullingParameters(m_CurrCamera, stereoEnabled, out cullingParameters)) continue; cullingParameters.shadowDistance = Mathf.Min(m_ShadowSettings.maxShadowDistance, m_CurrCamera.farClipPlane); CullResults.Cull(ref cullingParameters, context,ref m_CullResults); VisibleLight[] visibleLights = m_CullResults.visibleLights.ToArray(); LightData lightData; InitializeLightData(visibleLights, out lightData); // Render Shadow Map if (lightData.shadowLightIndex > -1) lightData.shadowsRendered = RenderShadows(ref m_CullResults, ref visibleLights[lightData.shadowLightIndex], lightData.shadowLightIndex, ref context); // Setup camera matrices and RT context.SetupCameraProperties(m_CurrCamera, stereoEnabled); // Setup light and shadow shader constants SetupShaderLightConstants(visibleLights, ref lightData, ref m_CullResults, ref context); if (lightData.shadowsRendered) SetupShadowShaderConstants(ref context, ref visibleLights[lightData.shadowLightIndex], lightData.shadowLightIndex, m_ShadowCasterCascadesCount); SetShaderKeywords(ref lightData, ref context); RendererConfiguration configuration = RendererConfiguration.PerObjectReflectionProbes; if (m_Asset.EnableLightmap) configuration |= RendererConfiguration.PerObjectLightmaps; if (m_Asset.EnableAmbientProbe) configuration |= RendererConfiguration.PerObjectLightProbe; if (!lightData.isSingleLight) configuration |= RendererConfiguration.PerObjectLightIndices8; PostProcessLayer postProcessLayer = GetCurrCameraPostProcessLayer(); bool postProcessEnabled = postProcessLayer != null && postProcessLayer.enabled; m_RenderToIntermediateTarget = postProcessEnabled || GetRenderToIntermediateTarget(); BeginForwardRendering(ref context, stereoEnabled); var litDrawSettings = new DrawRendererSettings(m_CurrCamera, m_LitPassName); litDrawSettings.sorting.flags = SortFlags.CommonOpaque; litDrawSettings.rendererConfiguration = configuration; var unlitDrawSettings = new DrawRendererSettings(m_CurrCamera, m_UnlitPassName); unlitDrawSettings.sorting.flags = SortFlags.CommonTransparent; // Render Opaques var opaqueFilterSettings = new FilterRenderersSettings(true) {renderQueueRange = RenderQueueRange.opaque}; context.DrawRenderers(m_CullResults.visibleRenderers, ref litDrawSettings, opaqueFilterSettings); // TODO: Check skybox shader context.DrawSkybox(m_CurrCamera); // Render Alpha blended var transparentFilterSettings = new FilterRenderersSettings(true) {renderQueueRange = RenderQueueRange.transparent}; litDrawSettings.sorting.flags = SortFlags.CommonTransparent; context.DrawRenderers(m_CullResults.visibleRenderers, ref litDrawSettings, transparentFilterSettings); context.DrawRenderers(m_CullResults.visibleRenderers, ref unlitDrawSettings, transparentFilterSettings); if (postProcessEnabled) RenderPostProcess(ref context, postProcessLayer); EndForwardRendering(ref context, stereoEnabled, postProcessEnabled); // Release temporary RT var discardRT = CommandBufferPool.Get(); discardRT.ReleaseTemporaryRT(m_ShadowMapProperty); discardRT.ReleaseTemporaryRT(m_CameraRTProperty); context.ExecuteCommandBuffer(discardRT); CommandBufferPool.Release(discardRT); } context.Submit(); } private void BuildShadowSettings() { m_ShadowSettings = ShadowSettings.Default; m_ShadowSettings.directionalLightCascadeCount = m_Asset.CascadeCount; m_ShadowSettings.shadowAtlasWidth = m_Asset.ShadowAtlasResolution; m_ShadowSettings.shadowAtlasHeight = m_Asset.ShadowAtlasResolution; m_ShadowSettings.maxShadowDistance = m_Asset.ShadowDistance; switch (m_ShadowSettings.directionalLightCascadeCount) { case 1: m_ShadowSettings.directionalLightCascades = new Vector3(1.0f, 0.0f, 0.0f); break; case 2: m_ShadowSettings.directionalLightCascades = new Vector3(m_Asset.Cascade2Split, 1.0f, 0.0f); break; default: m_ShadowSettings.directionalLightCascades = m_Asset.Cascade4Split; break; } } private void InitializeLightData(VisibleLight[] lights, out LightData lightData) { int lightsCount = lights.Length; int maxPerPixelLights = Math.Min(m_Asset.MaxSupportedPixelLights, kMaxPerObjectLights); lightData.pixelLightsCount = Math.Min(lightsCount, maxPerPixelLights); lightData.vertexLightsCount = (m_Asset.SupportsVertexLight) ? Math.Min(lightsCount - lightData.pixelLightsCount, kMaxPerObjectLights) : 0; // TODO: Handle Vertex lights in this case lightData.isSingleLight = lightData.pixelLightsCount <= 1; if (lightData.isSingleLight) m_SingleLightType = (lightData.pixelLightsCount == 1) ? lights[0].lightType : LightType.Directional; lightData.shadowsRendered = false; InitializeMainShadowLightIndex(lights, out lightData.shadowLightIndex); } private void SetupShaderLightConstants(VisibleLight[] lights, ref LightData lightData, ref CullResults cullResults, ref ScriptableRenderContext context) { if (lightData.isSingleLight) SetupShaderSingleLightConstants(lights, (lightData.pixelLightsCount > 0) ? 0 : -1, ref context); else SetupShaderLightListConstants(lights, ref lightData, ref context); } private void InitializeLightConstants(VisibleLight[] lights, int lightIndex, out Vector4 lightPos, out Vector4 lightColor, out Vector4 lightSpotDir, out Vector4 lightAttenuationParams) { lightPos = Vector4.zero; lightColor = Color.black; lightAttenuationParams = new Vector4(0.0f, 1.0f, 0.0f, 0.0f); lightSpotDir = new Vector4(0.0f, 0.0f, 1.0f, 0.0f); // When no lights are available in the pipeline or maxPixelLights is set to 0 // In this case we want to initialize the lightData to default values and return if (lightIndex < 0) return; VisibleLight light = lights[lightIndex]; if (light.lightType == LightType.Directional) { Vector4 dir = -light.localToWorld.GetColumn(2); lightPos = new Vector4(dir.x, dir.y, dir.z, 0.0f); } else { Vector4 pos = light.localToWorld.GetColumn(3); lightPos = new Vector4(pos.x, pos.y, pos.z, 1.0f); } lightColor = light.finalColor; float rangeSq = light.range * light.range; float quadAtten = 0.0f; if (light.lightType != LightType.Directional) quadAtten = (m_Asset.AttenuationTexture != null) ? 1.0f : 25.0f / rangeSq; if (light.lightType == LightType.Spot) { Vector4 dir = light.localToWorld.GetColumn(2); lightSpotDir = new Vector4(-dir.x, -dir.y, -dir.z, 0.0f); float spotAngle = Mathf.Deg2Rad * light.spotAngle; float cosOuterAngle = Mathf.Cos(spotAngle * 0.5f); float cosInneAngle = Mathf.Cos(spotAngle * 0.25f); float angleRange = cosInneAngle - cosOuterAngle; lightAttenuationParams = new Vector4(cosOuterAngle, Mathf.Approximately(angleRange, 0.0f) ? 1.0f : angleRange, quadAtten, rangeSq); } else { lightSpotDir = new Vector4(0.0f, 0.0f, 1.0f, 0.0f); lightAttenuationParams = new Vector4(-1.0f, 1.0f, quadAtten, rangeSq); } } private void SetupShaderSingleLightConstants(VisibleLight[] lights, int lightIndex, ref ScriptableRenderContext context) { Vector4 lightPos, lightColor, lightSpotDir, lightAttenuationParams; InitializeLightConstants(lights, lightIndex, out lightPos, out lightColor, out lightSpotDir, out lightAttenuationParams); CommandBuffer cmd = new CommandBuffer() { name = "SetupSingleLightConstants" }; cmd.SetGlobalVector("_LightPosition", lightPos); cmd.SetGlobalColor("_LightColor", lightColor); cmd.SetGlobalVector("_LightSpotDir", lightSpotDir); cmd.SetGlobalVector("_LightAttenuationParams", lightAttenuationParams); if (m_Asset.AttenuationTexture != null) cmd.SetGlobalTexture("_AttenuationTexture", m_Asset.AttenuationTexture); context.ExecuteCommandBuffer(cmd); cmd.Dispose(); } private void SetupShaderLightListConstants(VisibleLight[] lights, ref LightData lightData, ref ScriptableRenderContext context) { int maxLights = Math.Min(kMaxVisibleLights, lights.Length); for (int i = 0; i < maxLights; ++i) InitializeLightConstants(lights, i, out m_LightPositions[i], out m_LightColors[i], out m_LightSpotDirections[i], out m_LightAttenuations[i]); // Lightweight pipeline only upload kMaxVisibleLights to shader cbuffer. // We tell the pipe to disable remaining lights by setting it to -1. int[] lightIndexMap = m_CullResults.GetLightIndexMap(); for (int i = kMaxVisibleLights; i < lightIndexMap.Length; ++i) lightIndexMap[i] = -1; m_CullResults.SetLightIndexMap(lightIndexMap); CommandBuffer cmd = CommandBufferPool.Get("SetupLightShaderConstants"); cmd.SetGlobalVector("globalLightCount", new Vector4 (lightData.pixelLightsCount, lightData.vertexLightsCount, 0.0f, 0.0f)); cmd.SetGlobalVectorArray ("globalLightPos", m_LightPositions); cmd.SetGlobalVectorArray ("globalLightColor", m_LightColors); cmd.SetGlobalVectorArray ("globalLightAtten", m_LightAttenuations); cmd.SetGlobalVectorArray ("globalLightSpotDir", m_LightSpotDirections); if (m_Asset.AttenuationTexture != null) cmd.SetGlobalTexture("_AttenuationTexture", m_Asset.AttenuationTexture); context.ExecuteCommandBuffer(cmd); CommandBufferPool.Release(cmd); } private void SetShaderKeywords(ref LightData lightData, ref ScriptableRenderContext context) { CommandBuffer cmd = new CommandBuffer() { name = "SetShaderKeywords" }; SetShaderKeywords(cmd, lightData.shadowsRendered, lightData.isSingleLight, lightData.vertexLightsCount > 0); context.ExecuteCommandBuffer(cmd); cmd.Dispose(); } private bool RenderShadows(ref CullResults cullResults, ref VisibleLight shadowLight, int shadowLightIndex, ref ScriptableRenderContext context) { m_ShadowCasterCascadesCount = m_ShadowSettings.directionalLightCascadeCount; if (shadowLight.lightType == LightType.Spot) m_ShadowCasterCascadesCount = 1; int shadowResolution = GetMaxTileResolutionInAtlas(m_ShadowSettings.shadowAtlasWidth, m_ShadowSettings.shadowAtlasHeight, m_ShadowCasterCascadesCount); Bounds bounds; if (!cullResults.GetShadowCasterBounds(shadowLightIndex, out bounds)) return false; var setRenderTargetCommandBuffer = CommandBufferPool.Get(); setRenderTargetCommandBuffer.name = "Render packed shadows"; setRenderTargetCommandBuffer.GetTemporaryRT(m_ShadowMapProperty, m_ShadowSettings.shadowAtlasWidth, m_ShadowSettings.shadowAtlasHeight, kShadowDepthBufferBits, FilterMode.Bilinear, RenderTextureFormat.Depth); setRenderTargetCommandBuffer.SetRenderTarget(m_ShadowMapRTID); setRenderTargetCommandBuffer.ClearRenderTarget(true, true, Color.black); context.ExecuteCommandBuffer(setRenderTargetCommandBuffer); CommandBufferPool.Release(setRenderTargetCommandBuffer); float shadowNearPlane = m_Asset.ShadowNearOffset; Vector3 splitRatio = m_ShadowSettings.directionalLightCascades; Matrix4x4 view, proj; var settings = new DrawShadowsSettings(cullResults, shadowLightIndex); bool needRendering = false; if (shadowLight.lightType == LightType.Spot) { needRendering = cullResults.ComputeSpotShadowMatricesAndCullingPrimitives(shadowLightIndex, out view, out proj, out settings.splitData); if (!needRendering) return false; SetupShadowSliceTransform(0, shadowResolution, proj, view); RenderShadowSlice(ref context, 0, proj, view, settings); } else if (shadowLight.lightType == LightType.Directional) { for (int cascadeIdx = 0; cascadeIdx < m_ShadowCasterCascadesCount; ++cascadeIdx) { needRendering = cullResults.ComputeDirectionalShadowMatricesAndCullingPrimitives(shadowLightIndex, cascadeIdx, m_ShadowCasterCascadesCount, splitRatio, shadowResolution, shadowNearPlane, out view, out proj, out settings.splitData); m_DirectionalShadowSplitDistances[cascadeIdx] = settings.splitData.cullingSphere; m_DirectionalShadowSplitDistances[cascadeIdx].w *= settings.splitData.cullingSphere.w; if (!needRendering) return false; SetupShadowSliceTransform(cascadeIdx, shadowResolution, proj, view); RenderShadowSlice(ref context, cascadeIdx, proj, view, settings); } } else { Debug.LogWarning("Only spot and directional shadow casters are supported in lightweight pipeline"); return false; } return true; } private void SetupShadowSliceTransform(int cascadeIndex, int shadowResolution, Matrix4x4 proj, Matrix4x4 view) { // Assumes MAX_CASCADES = 4 m_ShadowSlices[cascadeIndex].atlasX = (cascadeIndex % 2) * shadowResolution; m_ShadowSlices[cascadeIndex].atlasY = (cascadeIndex / 2) * shadowResolution; m_ShadowSlices[cascadeIndex].shadowResolution = shadowResolution; m_ShadowSlices[cascadeIndex].shadowTransform = Matrix4x4.identity; var matScaleBias = Matrix4x4.identity; matScaleBias.m00 = 0.5f; matScaleBias.m11 = 0.5f; matScaleBias.m22 = 0.5f; matScaleBias.m03 = 0.5f; matScaleBias.m23 = 0.5f; matScaleBias.m13 = 0.5f; // Later down the pipeline the proj matrix will be scaled to reverse-z in case of DX. // We need account for that scale in the shadowTransform. if (SystemInfo.usesReversedZBuffer) matScaleBias.m22 = -0.5f; var matTile = Matrix4x4.identity; matTile.m00 = (float)m_ShadowSlices[cascadeIndex].shadowResolution / (float)m_ShadowSettings.shadowAtlasWidth; matTile.m11 = (float)m_ShadowSlices[cascadeIndex].shadowResolution / (float)m_ShadowSettings.shadowAtlasHeight; matTile.m03 = (float)m_ShadowSlices[cascadeIndex].atlasX / (float)m_ShadowSettings.shadowAtlasWidth; matTile.m13 = (float)m_ShadowSlices[cascadeIndex].atlasY / (float)m_ShadowSettings.shadowAtlasHeight; m_ShadowSlices[cascadeIndex].shadowTransform = matTile * matScaleBias * proj * view; } private void RenderShadowSlice(ref ScriptableRenderContext context, int cascadeIndex, Matrix4x4 proj, Matrix4x4 view, DrawShadowsSettings settings) { var buffer = CommandBufferPool.Get("Prepare Shadowmap Slice"); buffer.SetViewport(new Rect(m_ShadowSlices[cascadeIndex].atlasX, m_ShadowSlices[cascadeIndex].atlasY, m_ShadowSlices[cascadeIndex].shadowResolution, m_ShadowSlices[cascadeIndex].shadowResolution)); buffer.SetViewProjectionMatrices(view, proj); context.ExecuteCommandBuffer(buffer); context.DrawShadows(ref settings); CommandBufferPool.Release(buffer); } private int GetMaxTileResolutionInAtlas(int atlasWidth, int atlasHeight, int tileCount) { int resolution = Mathf.Min(atlasWidth, atlasHeight); if (tileCount > Mathf.Log(resolution)) { Debug.LogError( String.Format( "Cannot fit {0} tiles into current shadowmap atlas of size ({1}, {2}). ShadowMap Resolution set to zero.", tileCount, atlasWidth, atlasHeight)); return 0; } int currentTileCount = atlasWidth / resolution * atlasHeight / resolution; while (currentTileCount < tileCount) { resolution = resolution >> 1; currentTileCount = atlasWidth / resolution * atlasHeight / resolution; } return resolution; } private void SetupShadowShaderConstants(ref ScriptableRenderContext context, ref VisibleLight shadowLight, int shadowLightIndex, int cascadeCount) { Vector3 shadowLightDir = Vector3.Normalize(shadowLight.localToWorld.GetColumn(2)); float bias = shadowLight.light.shadowBias * 0.1f; float normalBias = shadowLight.light.shadowNormalBias; float shadowResolution = m_ShadowSlices[0].shadowResolution; const int maxShadowCascades = 4; Matrix4x4[] shadowMatrices = new Matrix4x4[maxShadowCascades]; for (int i = 0; i < cascadeCount; ++i) shadowMatrices[i] = (cascadeCount >= i) ? m_ShadowSlices[i].shadowTransform : Matrix4x4.identity; // TODO: shadow resolution per cascade in case cascades endup being supported. float invShadowResolution = 1.0f / shadowResolution; float[] pcfKernel = { -0.5f * invShadowResolution, 0.5f * invShadowResolution, 0.5f * invShadowResolution, 0.5f * invShadowResolution, -0.5f * invShadowResolution, -0.5f * invShadowResolution, 0.5f * invShadowResolution, -0.5f * invShadowResolution }; var setupShadow = CommandBufferPool.Get("SetupShadowShaderConstants"); setupShadow.SetGlobalMatrixArray("_WorldToShadow", shadowMatrices); setupShadow.SetGlobalVectorArray("_DirShadowSplitSpheres", m_DirectionalShadowSplitDistances); setupShadow.SetGlobalVector("_ShadowLightDirection", new Vector4(-shadowLightDir.x, -shadowLightDir.y, -shadowLightDir.z, 0.0f)); setupShadow.SetGlobalVector("_ShadowData", new Vector4(shadowLightIndex, bias, normalBias, 0.0f)); setupShadow.SetGlobalFloatArray("_PCFKernel", pcfKernel); context.ExecuteCommandBuffer(setupShadow); CommandBufferPool.Release(setupShadow); } private void SetKeyword(CommandBuffer cmd, string keyword, bool enable) { if (enable) cmd.EnableShaderKeyword(keyword); else cmd.DisableShaderKeyword(keyword); } private void SetShaderKeywords(CommandBuffer cmd, bool renderShadows, bool singleLight, bool vertexLightSupport) { SetKeyword(cmd, "LIGHTWEIGHT_LINEAR", m_Asset.ForceLinearRendering); SetKeyword(cmd, "_VERTEX_LIGHTS", vertexLightSupport); SetKeyword(cmd, "_ATTENUATION_TEXTURE", m_Asset.AttenuationTexture != null); SetKeyword(cmd, "_LIGHT_PROBES_ON", m_Asset.EnableAmbientProbe); SetKeyword(cmd, "LIGHTWEIGHT_LINEAR", m_Asset.ForceLinearRendering); if (!singleLight) { SetKeyword(cmd, "_SINGLE_DIRECTIONAL_LIGHT", false); SetKeyword(cmd, "_SINGLE_SPOT_LIGHT", false); SetKeyword(cmd, "_SINGLE_POINT_LIGHT", false); } else { switch (m_SingleLightType) { case LightType.Directional: SetKeyword(cmd, "_SINGLE_DIRECTIONAL_LIGHT", true); SetKeyword(cmd, "_SINGLE_SPOT_LIGHT", false); SetKeyword(cmd, "_SINGLE_POINT_LIGHT", false); break; case LightType.Spot: SetKeyword(cmd, "_SINGLE_DIRECTIONAL_LIGHT", false); SetKeyword(cmd, "_SINGLE_SPOT_LIGHT", true); SetKeyword(cmd, "_SINGLE_POINT_LIGHT", false); break; case LightType.Point: SetKeyword(cmd, "_SINGLE_DIRECTIONAL_LIGHT", false); SetKeyword(cmd, "_SINGLE_SPOT_LIGHT", false); SetKeyword(cmd, "_SINGLE_POINT_LIGHT", true); break; } } string[] shadowKeywords = new string[] { "_HARD_SHADOWS", "_SOFT_SHADOWS", "_HARD_SHADOWS_CASCADES", "_SOFT_SHADOWS_CASCADES" }; for (int i = 0; i < shadowKeywords.Length; ++i) cmd.DisableShaderKeyword(shadowKeywords[i]); if (renderShadows && m_Asset.CurrShadowType != ShadowType.NO_SHADOW) { int keywordIndex = (int)m_Asset.CurrShadowType - 1; if (m_Asset.CascadeCount > 1) keywordIndex += 2; cmd.EnableShaderKeyword(shadowKeywords[keywordIndex]); } } private void InitializeMainShadowLightIndex(VisibleLight[] lights, out int shadowIndex) { shadowIndex = -1; if (m_Asset.CurrShadowType == ShadowType.NO_SHADOW) return; float maxIntensity = -1; for (int i = 0; i < lights.Length; ++i) { Light light = lights[i].light; if (light.shadows != LightShadows.None && IsSupportedShadowType(light.type) && light.intensity > maxIntensity) { shadowIndex = i; maxIntensity = light.intensity; } } } private bool IsSupportedShadowType(LightType type) { return (type == LightType.Directional || type == LightType.Spot); } private void BeginForwardRendering(ref ScriptableRenderContext context, bool stereoEnabled) { if (stereoEnabled) context.StartMultiEye(m_CurrCamera); var cmd = CommandBufferPool.Get("SetCameraRenderTarget"); if (m_RenderToIntermediateTarget) { if (m_CurrCamera.activeTexture == null) { m_IntermediateTextureArray = false; if (stereoEnabled) { RenderTextureDescriptor xrDesc = XRSettings.eyeTextureDesc; xrDesc.depthBufferBits = kCameraDepthBufferBits; xrDesc.colorFormat = m_ColorFormat; xrDesc.msaaSamples = m_Asset.MSAASampleCount; m_IntermediateTextureArray = (xrDesc.dimension == TextureDimension.Tex2DArray); cmd.GetTemporaryRT(m_CameraRTProperty, xrDesc, FilterMode.Bilinear); } else { cmd.GetTemporaryRT(m_CameraRTProperty, Screen.width, Screen.height, kCameraDepthBufferBits, FilterMode.Bilinear, m_ColorFormat, RenderTextureReadWrite.Default, m_Asset.MSAASampleCount); } if (m_IntermediateTextureArray) cmd.SetRenderTarget(m_CameraRTID, 0, CubemapFace.Unknown, -1); else cmd.SetRenderTarget(m_CameraRTID); } else { cmd.SetRenderTarget(new RenderTargetIdentifier(m_CurrCamera.activeTexture)); } } else { cmd.SetRenderTarget(BuiltinRenderTextureType.CurrentActive); } // Clear RenderTarget to avoid tile initialization on mobile GPUs // https://community.arm.com/graphics/b/blog/posts/mali-performance-2-how-to-correctly-handle-framebuffers if (m_CurrCamera.clearFlags != CameraClearFlags.Nothing) { bool clearDepth = (m_CurrCamera.clearFlags != CameraClearFlags.Nothing); bool clearColor = (m_CurrCamera.clearFlags == CameraClearFlags.Color); cmd.ClearRenderTarget(clearDepth, clearColor, m_CurrCamera.backgroundColor); } context.ExecuteCommandBuffer(cmd); CommandBufferPool.Release(cmd); } private void EndForwardRendering(ref ScriptableRenderContext context, bool stereoEnabled, bool postProcessing) { if (m_RenderToIntermediateTarget || postProcessing) { var cmd = CommandBufferPool.Get("Blit"); if (m_IntermediateTextureArray) { cmd.SetRenderTarget(BuiltinRenderTextureType.CameraTarget, 0, CubemapFace.Unknown, -1); cmd.Blit(m_CameraRTID, BuiltinRenderTextureType.CurrentActive); } // If PostProcessing is enabled, it is already blitted to CameraTarget. else if (!postProcessing) cmd.Blit(BuiltinRenderTextureType.CurrentActive, BuiltinRenderTextureType.CameraTarget); cmd.SetRenderTarget(BuiltinRenderTextureType.CameraTarget); context.ExecuteCommandBuffer(cmd); CommandBufferPool.Release(cmd); } if (stereoEnabled) { context.StopMultiEye(m_CurrCamera); context.StereoEndRender(m_CurrCamera); } } private void RenderPostProcess(ref ScriptableRenderContext renderContext, PostProcessLayer postProcessLayer) { var postProcessCommand = CommandBufferPool.Get("Post Processing"); m_PostProcessRenderContext.Reset(); m_PostProcessRenderContext.camera = m_CurrCamera; m_PostProcessRenderContext.source = BuiltinRenderTextureType.CurrentActive; m_PostProcessRenderContext.sourceFormat = m_ColorFormat; m_PostProcessRenderContext.destination = BuiltinRenderTextureType.CameraTarget; m_PostProcessRenderContext.command = postProcessCommand; m_PostProcessRenderContext.flip = true; postProcessLayer.Render(m_PostProcessRenderContext); renderContext.ExecuteCommandBuffer(postProcessCommand); CommandBufferPool.Release(postProcessCommand); } private bool GetRenderToIntermediateTarget() { bool allowMSAA = m_CurrCamera.allowMSAA && m_Asset.MSAASampleCount > 1 && !PlatformSupportsMSAABackBuffer(); if (m_CurrCamera.cameraType == CameraType.SceneView || allowMSAA || m_CurrCamera.activeTexture != null) return true; return false; } private PostProcessLayer GetCurrCameraPostProcessLayer() { return m_CurrCamera.GetComponent(); } private bool PlatformSupportsMSAABackBuffer() { #if UNITY_ANDROID || UNITY_IPHONE || UNITY_TVOS || UNITY_SAMSUNGTV return true; #else return false; #endif } } }