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Merge pull request #565 from Unity-Technologies/Unity-2017.3 

Unity 2017.3
/main
GitHub 7 年前
当前提交
aeb0b914
共有 34 个文件被更改,包括 973 次插入419 次删除
  1. 24
      ScriptableRenderPipeline/Core/CoreUtils.cs
  2. 1
      ScriptableRenderPipeline/Core/ShaderLibrary/Common.hlsl
  3. 9
      ScriptableRenderPipeline/Core/ShaderLibrary/CommonMaterial.hlsl
  4. 20
      ScriptableRenderPipeline/Core/ShaderLibrary/EntityLighting.hlsl
  5. 13
      ScriptableRenderPipeline/HDRenderPipeline/Debug/DebugDisplay.cs
  6. 22
      ScriptableRenderPipeline/HDRenderPipeline/Debug/DebugDisplay.cs.hlsl
  7. 32
      ScriptableRenderPipeline/HDRenderPipeline/Debug/DebugViewMaterialGBuffer.shader
  8. 124
      ScriptableRenderPipeline/HDRenderPipeline/HDRenderPipeline.cs
  9. 13
      ScriptableRenderPipeline/HDRenderPipeline/HDStringConstants.cs
  10. 1
      ScriptableRenderPipeline/HDRenderPipeline/HDUtils.cs
  11. 14
      ScriptableRenderPipeline/HDRenderPipeline/Lighting/Deferred.shader
  12. 10
      ScriptableRenderPipeline/HDRenderPipeline/Lighting/LightDefinition.cs
  13. 31
      ScriptableRenderPipeline/HDRenderPipeline/Lighting/LightDefinition.cs.hlsl
  14. 109
      ScriptableRenderPipeline/HDRenderPipeline/Lighting/TilePass/Deferred.compute
  15. 479
      ScriptableRenderPipeline/HDRenderPipeline/Lighting/TilePass/TilePass.cs
  16. 18
      ScriptableRenderPipeline/HDRenderPipeline/Lighting/TilePass/TilePassLoop.hlsl
  17. 21
      ScriptableRenderPipeline/HDRenderPipeline/Material/Builtin/BuiltinData.cs
  18. 32
      ScriptableRenderPipeline/HDRenderPipeline/Material/Builtin/BuiltinData.cs.hlsl
  19. 25
      ScriptableRenderPipeline/HDRenderPipeline/Material/Builtin/BuiltinData.hlsl
  20. 33
      ScriptableRenderPipeline/HDRenderPipeline/Material/LayeredLit/LayeredLit.shader
  21. 36
      ScriptableRenderPipeline/HDRenderPipeline/Material/LayeredLit/LayeredLitTessellation.shader
  22. 21
      ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Lit.cs
  23. 70
      ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Lit.hlsl
  24. 38
      ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Lit.shader
  25. 13
      ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/LitData.hlsl
  26. 36
      ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/LitTessellation.shader
  27. 7
      ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Resources/SubsurfaceScattering.compute
  28. 93
      ScriptableRenderPipeline/HDRenderPipeline/Material/Material.hlsl
  29. 23
      ScriptableRenderPipeline/HDRenderPipeline/Material/MaterialUtilities.hlsl
  30. 5
      ScriptableRenderPipeline/HDRenderPipeline/Material/Unlit/UnlitData.hlsl
  31. 2
      ScriptableRenderPipeline/HDRenderPipeline/SceneSettings/Resources/DrawTransmittanceGraph.shader
  32. 9
      ScriptableRenderPipeline/HDRenderPipeline/ShaderPass/ShaderPassForward.hlsl
  33. 2
      ScriptableRenderPipeline/HDRenderPipeline/ShaderPass/ShaderPassGBuffer.hlsl
  34. 6
      ScriptableRenderPipeline/HDRenderPipeline/ShaderVariables.hlsl

24
ScriptableRenderPipeline/Core/CoreUtils.cs
查看文件


public static class CoreUtils
{
// Note: Color.Black have alpha channel set to 1. Most of the time we want alpha channel set to 0 as we use black to clear render target
public static Color clearColorAllBlack { get { return new Color(0f, 0f, 0f, 0f); } }
// Render Target Management.
public static void SetRenderTarget(CommandBuffer cmd, RenderTargetIdentifier buffer, ClearFlag clearFlag, Color clearColor, int miplevel = 0, CubemapFace cubemapFace = CubemapFace.Unknown)
{

public static void SetRenderTarget(CommandBuffer cmd, RenderTargetIdentifier buffer, ClearFlag clearFlag = ClearFlag.None, int miplevel = 0, CubemapFace cubemapFace = CubemapFace.Unknown)
{
SetRenderTarget(cmd, buffer, clearFlag, Color.black, miplevel, cubemapFace);
SetRenderTarget(cmd, buffer, clearFlag, clearColorAllBlack, miplevel, cubemapFace);
SetRenderTarget(cmd, colorBuffer, depthBuffer, ClearFlag.None, Color.black, miplevel, cubemapFace);
SetRenderTarget(cmd, colorBuffer, depthBuffer, ClearFlag.None, clearColorAllBlack, miplevel, cubemapFace);
SetRenderTarget(cmd, colorBuffer, depthBuffer, clearFlag, Color.black, miplevel, cubemapFace);
SetRenderTarget(cmd, colorBuffer, depthBuffer, clearFlag, clearColorAllBlack, miplevel, cubemapFace);
}
public static void SetRenderTarget(CommandBuffer cmd, RenderTargetIdentifier colorBuffer, RenderTargetIdentifier depthBuffer, ClearFlag clearFlag, Color clearColor, int miplevel = 0, CubemapFace cubemapFace = CubemapFace.Unknown)

public static void SetRenderTarget(CommandBuffer cmd, RenderTargetIdentifier[] colorBuffers, RenderTargetIdentifier depthBuffer)
{
SetRenderTarget(cmd, colorBuffers, depthBuffer, ClearFlag.None, Color.black);
SetRenderTarget(cmd, colorBuffers, depthBuffer, ClearFlag.None, clearColorAllBlack);
SetRenderTarget(cmd, colorBuffers, depthBuffer, clearFlag, Color.black);
SetRenderTarget(cmd, colorBuffers, depthBuffer, clearFlag, clearColorAllBlack);
}
public static void SetRenderTarget(CommandBuffer cmd, RenderTargetIdentifier[] colorBuffers, RenderTargetIdentifier depthBuffer, ClearFlag clearFlag, Color clearColor)

public static void ClearCubemap(CommandBuffer cmd, RenderTargetIdentifier buffer, Color clearColor)
{
for(int i = 0; i < 6; ++i)
SetRenderTarget(cmd, buffer, ClearFlag.Color, Color.black, 0, (CubemapFace)i);
SetRenderTarget(cmd, buffer, ClearFlag.Color, clearColorAllBlack, 0, (CubemapFace)i);
}
// Draws a full screen triangle as a faster alternative to drawing a full screen quad.

return mat;
}
public static void SetKeyword(CommandBuffer cmd, string keyword, bool state)
{
if (state)
cmd.EnableShaderKeyword(keyword);
else
cmd.DisableShaderKeyword(keyword);
}
// Caution: such a call should not be use interlaced with command buffer command, as it is immediate
public static void SetKeyword(Material m, string keyword, bool state)
{
if (state)

1
ScriptableRenderPipeline/Core/ShaderLibrary/Common.hlsl
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#define HALF_PI 1.57079632679
#define INV_HALF_PI 0.636619772367
#define INFINITY asfloat(0x7F800000)
#define LOG2_E 1.44269504089
#define FLT_EPSILON 1.192092896e-07 // Smallest positive number, such that 1.0 + FLT_EPSILON != 1.0
#define FLT_MIN 1.175494351e-38 // Minimum representable positive floating-point number

9
ScriptableRenderPipeline/Core/ShaderLibrary/CommonMaterial.hlsl
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// Evaluate Int{0, inf}{2 * Pi * r * R(sqrt(r^2 + d^2))}, where R is the diffusion profile.
// Note: 'volumeAlbedo' should be premultiplied by 0.25.
// Ref: Approximate Reflectance Profiles for Efficient Subsurface Scattering by Pixar (BSSRDF only).
float3 ComputeTransmittance(float3 S, float3 volumeAlbedo, float thickness, float radiusScale)
float3 ComputeTransmittanceDisney(float3 S, float3 volumeAlbedo, float thickness, float radiusScale)
#if 0
#else
// Help the compiler.
float k = (-1.0 / 3.0) * LOG2_E;
float3 p = (k * thickness) * S;
float3 expOneThird = exp2(p);
#endif
// Premultiply & optimize: T = (1/4 * A) * (e^(-t * S) + 3 * e^(-1/3 * t * S))
return volumeAlbedo * (expOneThird * expOneThird * expOneThird + 3 * expOneThird);

20
ScriptableRenderPipeline/Core/ShaderLibrary/EntityLighting.hlsl
查看文件


}
// This sample a 3D volume storing SH
// Volume is store as 3D texture with 4 R, G, B, X set of 4 coefficient store atlas in same 3D texture. X is use for occlusion.
// TODO: the packing here is inefficient as we will fetch values far away from each other and they may not fit into the cache - Suggest we pack only RGB continuously
// Volume is store as 3D texture with 4 R, G, B, Occ set of 4 coefficient store atlas in same 3D texture. Occ is use for occlusion.
// TODO: the packing here is inefficient as we will fetch values far away from each other and they may not fit into the cache - Suggest we pack RGB continuously
float3 SampleProbeVolumeSH4(TEXTURE3D_ARGS(SHVolumeTexture, SHVolumeSampler), float3 positionWS, float3 normalWS, float4x4 WorldToTexture,
float3 SampleProbeVolumeSH4(TEXTURE3D_ARGS(SHVolumeTexture, SHVolumeSampler), float3 positionWS, float3 normalWS, float4x4 WorldToTexture,
float transformToLocal, float texelSizeX, float3 probeVolumeMin, float3 probeVolumeSizeInv)
{
float3 position = (transformToLocal == 1.0f) ? mul(WorldToTexture, float4(positionWS, 1.0)).xyz : positionWS;

float4 shAb = SAMPLE_TEXTURE3D(SHVolumeTexture, SHVolumeSampler, texCoord);
return SHEvalLinearL0L1(normalWS, shAr, shAg, shAb);
}
float4 SampleProbeOcclusion(TEXTURE3D_ARGS(SHVolumeTexture, SHVolumeSampler), float3 positionWS, float4x4 WorldToTexture,
float transformToLocal, float texelSizeX, float3 probeVolumeMin, float3 probeVolumeSizeInv)
{
float3 position = (transformToLocal == 1.0f) ? mul(WorldToTexture, float4(positionWS, 1.0)).xyz : positionWS;
float3 texCoord = (position - probeVolumeMin) * probeVolumeSizeInv.xyz;
// Sample fourth texture in the atlas
// We need to compute proper U coordinate to sample.
// Clamp the coordinate otherwize we'll have leaking between ShB coefficients and Probe Occlusion(Occ) info
texCoord.x = max(texCoord.x * 0.25 + 0.75, 0.75 + 0.5 * texelSizeX);
return SAMPLE_TEXTURE3D(SHVolumeTexture, SHVolumeSampler, texCoord);
}
// Following functions are to sample enlighten lightmaps (or lightmaps encoded the same way as our

13
ScriptableRenderPipeline/HDRenderPipeline/Debug/DebugDisplay.cs
查看文件


IndirectDiffuseOcclusionFromSsao,
IndirectDiffuseGtaoFromSsao,
IndirectSpecularOcclusionFromSsao,
IndirectSpecularGtaoFromSsao
IndirectSpecularGtaoFromSsao
}
public class DebugDisplaySettings

VertexNormalWS,
VertexColor,
VertexColorAlpha,
// caution if you add something here, it must start below
Last,
};
// Number must be contiguous

None = 0,
Depth = DebugViewVarying.VertexColorAlpha + 1,
Depth = DebugViewVarying.Last + 1,
BakeShadowMask0,
BakeShadowMask1,
BakeShadowMask2,
BakeShadowMask3,
Last,
}
// Number must be contiguous

None = 0,
Tessellation = DebugViewGbuffer.BakeDiffuseLightingWithAlbedoPlusEmissive + 1,
Tessellation = DebugViewGbuffer.Last + 1,
PixelDisplacement,
VertexDisplacement,
TessellationDisplacement,

22
ScriptableRenderPipeline/HDRenderPipeline/Debug/DebugDisplay.cs.hlsl
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#define DEBUGVIEWVARYING_VERTEX_NORMAL_WS (7)
#define DEBUGVIEWVARYING_VERTEX_COLOR (8)
#define DEBUGVIEWVARYING_VERTEX_COLOR_ALPHA (9)
#define DEBUGVIEWVARYING_LAST (10)
#define DEBUGVIEWGBUFFER_DEPTH (10)
#define DEBUGVIEWGBUFFER_BAKE_DIFFUSE_LIGHTING_WITH_ALBEDO_PLUS_EMISSIVE (11)
#define DEBUGVIEWGBUFFER_DEPTH (11)
#define DEBUGVIEWGBUFFER_BAKE_DIFFUSE_LIGHTING_WITH_ALBEDO_PLUS_EMISSIVE (12)
#define DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK0 (13)
#define DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK1 (14)
#define DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK2 (15)
#define DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK3 (16)
#define DEBUGVIEWGBUFFER_LAST (17)
#define DEBUGVIEWPROPERTIES_TESSELLATION (12)
#define DEBUGVIEWPROPERTIES_PIXEL_DISPLACEMENT (13)
#define DEBUGVIEWPROPERTIES_VERTEX_DISPLACEMENT (14)
#define DEBUGVIEWPROPERTIES_TESSELLATION_DISPLACEMENT (15)
#define DEBUGVIEWPROPERTIES_DEPTH_OFFSET (16)
#define DEBUGVIEWPROPERTIES_LIGHTMAP (17)
#define DEBUGVIEWPROPERTIES_TESSELLATION (18)
#define DEBUGVIEWPROPERTIES_PIXEL_DISPLACEMENT (19)
#define DEBUGVIEWPROPERTIES_VERTEX_DISPLACEMENT (20)
#define DEBUGVIEWPROPERTIES_TESSELLATION_DISPLACEMENT (21)
#define DEBUGVIEWPROPERTIES_DEPTH_OFFSET (22)
#define DEBUGVIEWPROPERTIES_LIGHTMAP (23)
//
// UnityEngine.Experimental.Rendering.HDPipeline.FullScreenDebugMode: static fields

32
ScriptableRenderPipeline/HDRenderPipeline/Debug/DebugViewMaterialGBuffer.shader
查看文件


#pragma vertex Vert
#pragma fragment Frag
#pragma multi_compile _ SHADOWS_SHADOWMASK
#include "../../Core/ShaderLibrary/Common.hlsl"
#include "../../Core/ShaderLibrary/Color.hlsl"

#include "../Material/Material.hlsl"
DECLARE_GBUFFER_TEXTURE(_GBufferTexture);
#ifdef SHADOWS_SHADOWMASK
TEXTURE2D(_ShadowMaskTexture);
#endif
struct Attributes
{

FETCH_GBUFFER(gbuffer, _GBufferTexture, posInput.unPositionSS);
BSDFData bsdfData;
float3 bakeDiffuseLighting;
DECODE_FROM_GBUFFER(gbuffer, 0xFFFFFFFF, bsdfData, bakeDiffuseLighting);
BakeLightingData bakeLightingData;
DECODE_FROM_GBUFFER(gbuffer, 0xFFFFFFFF, bsdfData, bakeLightingData.bakeDiffuseLighting);
#ifdef SHADOWS_SHADOWMASK
DecodeShadowMask(LOAD_TEXTURE2D(_ShadowMaskTexture, posInput.unPositionSS), bakeLightingData.bakeShadowMask);
#endif
// Init to not expected value
float3 result = float3(-666.0, 0.0, 0.0);

{
// TODO: require a remap
// TODO: we should not gamma correct, but easier to debug for now without correct high range value
result = bakeDiffuseLighting; needLinearToSRGB = true;
result = bakeLightingData.bakeDiffuseLighting; needLinearToSRGB = true;
#ifdef SHADOWS_SHADOWMASK
else if (_DebugViewMaterial == DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK0)
{
result = bakeLightingData.bakeShadowMask.xxx;
}
else if (_DebugViewMaterial == DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK1)
{
result = bakeLightingData.bakeShadowMask.yyy;
}
else if (_DebugViewMaterial == DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK2)
{
result = bakeLightingData.bakeShadowMask.zzz;
}
else if (_DebugViewMaterial == DEBUGVIEWGBUFFER_BAKE_SHADOW_MASK3)
{
result = bakeLightingData.bakeShadowMask.www;
}
#endif
GetBSDFDataDebug(_DebugViewMaterial, bsdfData, result, needLinearToSRGB);

124
ScriptableRenderPipeline/HDRenderPipeline/HDRenderPipeline.cs
查看文件


public int gbufferCount { get; set; }
int[] m_IDs = new int[k_MaxGbuffer];
RenderTextureFormat[] m_Formats = new RenderTextureFormat[k_MaxGbuffer];
RenderTextureReadWrite[] m_sRGBWrites = new RenderTextureReadWrite[k_MaxGbuffer];
public void SetBufferDescription(int index, string stringId, RenderTextureFormat inFormat, RenderTextureReadWrite inSRGBWrite)
public void InitGBuffers(int width, int height, RenderPipelineMaterial deferredMaterial, bool enableBakeShadowMask, CommandBuffer cmd)
m_IDs[index] = Shader.PropertyToID(stringId);
m_RTIDs[index] = new RenderTargetIdentifier(m_IDs[index]);
m_Formats[index] = inFormat;
m_sRGBWrites[index] = inSRGBWrite;
}
// Init Gbuffer description
gbufferCount = deferredMaterial.GetMaterialGBufferCount();
RenderTextureFormat[] rtFormat;
RenderTextureReadWrite[] rtReadWrite;
deferredMaterial.GetMaterialGBufferDescription(out rtFormat, out rtReadWrite);
for (int gbufferIndex = 0; gbufferIndex < gbufferCount; ++gbufferIndex)
{
cmd.GetTemporaryRT(HDShaderIDs._GBufferTexture[gbufferIndex], width, height, 0, FilterMode.Point, rtFormat[gbufferIndex], rtReadWrite[gbufferIndex]);
m_RTIDs[gbufferIndex] = new RenderTargetIdentifier(HDShaderIDs._GBufferTexture[gbufferIndex]);
}
public void InitGBuffers(int width, int height, CommandBuffer cmd)
{
for (int index = 0; index < gbufferCount; index++)
if (enableBakeShadowMask)
cmd.GetTemporaryRT(m_IDs[index], width, height, 0, FilterMode.Point, m_Formats[index], m_sRGBWrites[index]);
cmd.GetTemporaryRT(HDShaderIDs._ShadowMaskTexture, width, height, 0, FilterMode.Point, Builtin.GetShadowMaskBufferFormat(), Builtin.GetShadowMaskBufferReadWrite());
m_RTIDs[gbufferCount++] = new RenderTargetIdentifier(HDShaderIDs._ShadowMaskTexture);
}
if (ShaderConfig.s_VelocityInGbuffer == 1)
{
// If velocity is in GBuffer then it is in the last RT. Assign a different name to it.
cmd.GetTemporaryRT(HDShaderIDs._VelocityTexture, width, height, 0, FilterMode.Point, Builtin.GetVelocityBufferFormat(), Builtin.GetVelocityBufferReadWrite());
m_RTIDs[gbufferCount++] = new RenderTargetIdentifier(HDShaderIDs._VelocityTexture);
// TODO: check with THomas or Tim if wa can simply return m_ColorMRTs with null for extra RT
if (m_ColorMRTs == null || m_ColorMRTs.Length != gbufferCount)
m_ColorMRTs = new RenderTargetIdentifier[gbufferCount];

readonly GBufferManager m_GbufferManager = new GBufferManager();
// Renderer Bake configuration can vary depends on if shadow mask is enabled or no
RendererConfiguration m_currentRendererConfigurationBakedLighting = HDUtils.k_RendererConfigurationBakedLighting;
Material m_CopyStencilForSplitLighting;
Material m_CopyStencilForRegularLighting;
GPUCopy m_GPUCopy;

// Debug material
Material m_DebugViewMaterialGBuffer;
Material m_DebugViewMaterialGBufferShadowMask;
Material m_currentDebugViewMaterialGBuffer;
Material m_DebugDisplayLatlong;
Material m_DebugFullScreen;
Material m_ErrorMaterial;

// Old SSS Model >>>
readonly int m_CameraFilteringBuffer;
// <<< Old SSS Model
readonly int m_ShadowMaskBuffer;
readonly int m_VelocityBuffer;
readonly int m_DistortionBuffer;
readonly int m_GaussianPyramidColorBuffer;

RenderTargetIdentifier m_CameraStencilBufferCopyRT;
RenderTargetIdentifier m_HTileRT;
// The pass "SRPDefaultUnlit" is a fallback to legacy unlit rendering and is required to support unity 2d + unity UI that render in the scene.
// The pass "SRPDefaultUnlit" is a fall back to legacy unlit rendering and is required to support unity 2d + unity UI that render in the scene.
ShaderPassName[] m_ForwardAndForwardOnlyPassNames = { new ShaderPassName(), new ShaderPassName(), HDShaderPassNames.s_SRPDefaultUnlitName};
ShaderPassName[] m_ForwardOnlyPassNames = { new ShaderPassName(), HDShaderPassNames.s_SRPDefaultUnlitName};
ShaderPassName[] m_DepthOnlyAndDepthForwardOnlyPassNames = { HDShaderPassNames.s_DepthForwardOnlyName, HDShaderPassNames.s_DepthOnlyName };

InitializeDebugMaterials();
// Init Gbuffer description
m_GbufferManager.gbufferCount = m_DeferredMaterial.GetMaterialGBufferCount();
RenderTextureFormat[] rtFormat;
RenderTextureReadWrite[] rtReadWrite;
m_DeferredMaterial.GetMaterialGBufferDescription(out rtFormat, out rtReadWrite);
for (int gbufferIndex = 0; gbufferIndex < m_GbufferManager.gbufferCount; ++gbufferIndex)
{
m_GbufferManager.SetBufferDescription(gbufferIndex, "_GBufferTexture" + gbufferIndex, rtFormat[gbufferIndex], rtReadWrite[gbufferIndex]);
}
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.GetVelocityBufferFormat(), Builtin.GetVelocityBufferReadWrite());
m_GbufferManager.gbufferCount++;
}
m_VelocityBufferRT = new RenderTargetIdentifier(m_VelocityBuffer);
m_DistortionBuffer = HDShaderIDs._DistortionTexture;

void InitializeDebugMaterials()
{
m_DebugViewMaterialGBuffer = CoreUtils.CreateEngineMaterial(m_Asset.renderPipelineResources.debugViewMaterialGBufferShader);
m_DebugViewMaterialGBufferShadowMask = CoreUtils.CreateEngineMaterial(m_Asset.renderPipelineResources.debugViewMaterialGBufferShader);
m_DebugViewMaterialGBufferShadowMask.EnableKeyword("SHADOWS_SHADOWMASK");
m_DebugDisplayLatlong = CoreUtils.CreateEngineMaterial(m_Asset.renderPipelineResources.debugDisplayLatlongShader);
m_DebugFullScreen = CoreUtils.CreateEngineMaterial(m_Asset.renderPipelineResources.debugFullScreenShader);
m_ErrorMaterial = CoreUtils.CreateEngineMaterial("Hidden/InternalErrorShader");

m_MaterialList.ForEach(material => material.Cleanup());
CoreUtils.Destroy(m_DebugViewMaterialGBuffer);
CoreUtils.Destroy(m_DebugViewMaterialGBufferShadowMask);
CoreUtils.Destroy(m_DebugDisplayLatlong);
CoreUtils.Destroy(m_DebugFullScreen);
CoreUtils.Destroy(m_ErrorMaterial);

m_ShadowSettings.directionalLightNearPlaneOffset = commonSettings.shadowNearPlaneOffset;
}
public void ConfigureForShadowMask(bool enableBakeShadowMask, CommandBuffer cmd)
{
// Globally enable (for GBuffer shader and forward lit (opaque and transparent) the keyword SHADOWS_SHADOWMASK
CoreUtils.SetKeyword(cmd, "SHADOWS_SHADOWMASK", enableBakeShadowMask);
// Configure material to use depends on shadow mask option
m_currentRendererConfigurationBakedLighting = enableBakeShadowMask ? HDUtils.k_RendererConfigurationBakedLightingWithShadowMask : HDUtils.k_RendererConfigurationBakedLighting;
m_currentDebugViewMaterialGBuffer = enableBakeShadowMask ? m_DebugViewMaterialGBufferShadowMask : m_DebugViewMaterialGBuffer;
}
CullResults m_CullResults;
public override void Render(ScriptableRenderContext renderContext, Camera[] cameras)
{

return;
}
// The first thing to do is to go through all lights on the CPU side and prepare light for GPU.
// This allow us to deal with the flexibility of shadow mask that will do a GBuffer allocation on demand (in case of deferred rendering)
m_LightLoop.PrepareLightsForGPU(m_ShadowSettings, m_CullResults, camera);
// Note: Legacy Unity behave like this for ShadowMask
// When you select ShadowMask in Lighting panel it recompile shaders on the fly with the SHADOW_MASK keyword.
// However there is no C# function that we can query to know what mode have been select in Lighting Panel and it will be wrong anyway. Lighting Panel setup what will be the next bake mode. But until light is bake, it is wrong.
// Currently to know if you need shadow mask you need to go through all visible lights (of CullResult), check the LightBakingOutput struct and look at lightmapBakeType/mixedLightingMode. If one light have shadow mask bake mode, then you need shadow mask features (i.e extra Gbuffer).
// It mean that when we build a standalone player, if we detect a light with bake shadow mask, we generate all shader variant (with and without shadow mask) and at runtime, when a bake shadow mask light is visible, we dynamically allocate an extra GBuffer and switch the shader.
// So the first thing to do is to go through all the light: PrepareLightsForGPU
bool enableBakeShadowMask = m_LightLoop.PrepareLightsForGPU(m_ShadowSettings, m_CullResults, camera);
ConfigureForShadowMask(enableBakeShadowMask, cmd);
InitAndClearBuffer(hdCamera, cmd);
InitAndClearBuffer(hdCamera, enableBakeShadowMask, cmd);
RenderDepthPrepass(m_CullResults, camera, renderContext, cmd);

if (m_CurrentDebugDisplaySettings.IsDebugDisplayEnabled())
{
// When doing debug display, the shader has the clip instruction regardless of the depth prepass so we can use regular depth test.
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferDebugDisplayName, HDUtils.k_RendererConfigurationBakedLighting, RenderQueueRange.opaque, m_DepthStateOpaque);
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferDebugDisplayName, m_currentRendererConfigurationBakedLighting, RenderQueueRange.opaque, m_DepthStateOpaque);
}
else
{

var rangeOpaqueAlphaTest = new RenderQueueRange { min = (int)RenderQueue.AlphaTest, max = (int)RenderQueue.GeometryLast - 1 };
// When using depth prepass for opaque alpha test only we need to use regular depth test for normal opaque objects.
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferName, HDUtils.k_RendererConfigurationBakedLighting, rangeOpaqueNoAlphaTest, m_Asset.renderingSettings.renderAlphaTestOnlyInDeferredPrepass ? m_DepthStateOpaque : m_DepthStateOpaqueWithPrepass);
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferName, m_currentRendererConfigurationBakedLighting, rangeOpaqueNoAlphaTest, m_Asset.renderingSettings.renderAlphaTestOnlyInDeferredPrepass ? m_DepthStateOpaque : m_DepthStateOpaqueWithPrepass);
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferWithPrepassName, HDUtils.k_RendererConfigurationBakedLighting, rangeOpaqueAlphaTest, m_DepthStateOpaqueWithPrepass);
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferWithPrepassName, m_currentRendererConfigurationBakedLighting, rangeOpaqueAlphaTest, m_DepthStateOpaqueWithPrepass);
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferName, HDUtils.k_RendererConfigurationBakedLighting, RenderQueueRange.opaque, m_DepthStateOpaque);
RenderOpaqueRenderList(cull, camera, renderContext, cmd, HDShaderPassNames.s_GBufferName, m_currentRendererConfigurationBakedLighting, RenderQueueRange.opaque, m_DepthStateOpaque);
}
}
}

{
using (new ProfilingSample(cmd, "DebugViewMaterialGBuffer"))
{
CoreUtils.DrawFullScreen(cmd, m_DebugViewMaterialGBuffer, m_CameraColorBufferRT);
CoreUtils.DrawFullScreen(cmd, m_currentDebugViewMaterialGBuffer, m_CameraColorBufferRT);
CoreUtils.SetRenderTarget(cmd, m_CameraColorBufferRT, m_CameraDepthStencilBufferRT, ClearFlag.All, Color.black);
CoreUtils.SetRenderTarget(cmd, m_CameraColorBufferRT, m_CameraDepthStencilBufferRT, ClearFlag.All, CoreUtils.clearColorAllBlack);
RenderOpaqueRenderList(cull, hdCamera.camera, renderContext, cmd, HDShaderPassNames.s_ForwardDebugDisplayName, HDUtils.k_RendererConfigurationBakedLighting);
RenderOpaqueRenderList(cull, hdCamera.camera, renderContext, cmd, HDShaderPassNames.s_ForwardDebugDisplayName, m_currentRendererConfigurationBakedLighting);
RenderTransparentRenderList(cull, hdCamera.camera, renderContext, cmd, HDShaderPassNames.s_ForwardDebugDisplayName, HDUtils.k_RendererConfigurationBakedLighting);
RenderTransparentRenderList(cull, hdCamera.camera, renderContext, cmd, HDShaderPassNames.s_ForwardDebugDisplayName, m_currentRendererConfigurationBakedLighting);
}
}

{
var passNames = m_Asset.renderingSettings.ShouldUseForwardRenderingOnly() ? m_ForwardAndForwardOnlyPassNames : m_ForwardOnlyPassNames;
// Forward opaque material always have a prepass (whether or not we use deferred, whether or not there is option like alpha test only) so we pass the right depth state here.
RenderOpaqueRenderList(cullResults, camera, renderContext, cmd, passNames, HDUtils.k_RendererConfigurationBakedLighting, null, m_DepthStateOpaqueWithPrepass);
RenderOpaqueRenderList(cullResults, camera, renderContext, cmd, passNames, m_currentRendererConfigurationBakedLighting, null, m_DepthStateOpaqueWithPrepass);
RenderTransparentRenderList(cullResults, camera, renderContext, cmd, m_ForwardAndForwardOnlyPassNames, HDUtils.k_RendererConfigurationBakedLighting, preRefractionQueue: pass == ForwardPass.PreRefraction);
RenderTransparentRenderList(cullResults, camera, renderContext, cmd, m_ForwardAndForwardOnlyPassNames, m_currentRendererConfigurationBakedLighting, preRefractionQueue: pass == ForwardPass.PreRefraction);
}
}
}

}
}
void InitAndClearBuffer(HDCamera camera, CommandBuffer cmd)
void InitAndClearBuffer(HDCamera camera, bool enableBakeShadowMask, CommandBuffer cmd)
{
using (new ProfilingSample(cmd, "InitAndClearBuffer"))
{

// End
if (!m_Asset.renderingSettings.ShouldUseForwardRenderingOnly())
m_GbufferManager.InitGBuffers(w, h, cmd);
m_GbufferManager.InitGBuffers(w, h, m_DeferredMaterial, enableBakeShadowMask, cmd);
CoreUtils.SetRenderTarget(cmd, m_CameraColorBufferRT, m_CameraDepthStencilBufferRT, ClearFlag.Depth);
}

{
CoreUtils.SetRenderTarget(cmd, m_CameraSssDiffuseLightingBufferRT, ClearFlag.Color, Color.black);
CoreUtils.SetRenderTarget(cmd, m_CameraSssDiffuseLightingBufferRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);
}
// Old SSS Model >>>

using (new ProfilingSample(cmd, "Clear SSS filtering target"))
{
CoreUtils.SetRenderTarget(cmd, m_CameraFilteringBuffer, ClearFlag.Color, Color.black);
CoreUtils.SetRenderTarget(cmd, m_CameraFilteringBuffer, ClearFlag.Color, CoreUtils.clearColorAllBlack);
}
}
// <<< Old SSS Model

using (new ProfilingSample(cmd, "Clear stencil texture"))
{
CoreUtils.SetRenderTarget(cmd, m_CameraStencilBufferCopyRT, ClearFlag.Color, Color.black);
CoreUtils.SetRenderTarget(cmd, m_CameraStencilBufferCopyRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);
}
}

{
CoreUtils.SetRenderTarget(cmd, m_HTileRT, ClearFlag.Color, Color.black);
CoreUtils.SetRenderTarget(cmd, m_HTileRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);
// TEMP: As we are in development and have not all the setup pass we still clear the color in emissive buffer and gbuffer, but this will be removed later.
// TODO: As we are in development and have not all the setup pass we still clear the color in emissive buffer and gbuffer, but this will be removed later.
CoreUtils.SetRenderTarget(cmd, m_CameraColorBufferRT, m_CameraDepthStencilBufferRT, ClearFlag.Color, Color.black);
CoreUtils.SetRenderTarget(cmd, m_CameraColorBufferRT, m_CameraDepthStencilBufferRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);
}
// Clear GBuffers

{
CoreUtils.SetRenderTarget(cmd, m_GbufferManager.GetGBuffers(), m_CameraDepthStencilBufferRT, ClearFlag.Color, Color.black);
CoreUtils.SetRenderTarget(cmd, m_GbufferManager.GetGBuffers(), m_CameraDepthStencilBufferRT, ClearFlag.Color, CoreUtils.clearColorAllBlack);
}
}
// END TEMP

13
ScriptableRenderPipeline/HDRenderPipeline/HDStringConstants.cs
查看文件


public static readonly int _CameraFilteringBuffer = Shader.PropertyToID("_CameraFilteringTexture");
public static readonly int _IrradianceSource = Shader.PropertyToID("_IrradianceSource");
public static readonly int[] _GBufferTexture =
{
Shader.PropertyToID("_GBufferTexture0"),
Shader.PropertyToID("_GBufferTexture1"),
Shader.PropertyToID("_GBufferTexture2"),
Shader.PropertyToID("_GBufferTexture3"),
Shader.PropertyToID("_GBufferTexture4"),
Shader.PropertyToID("_GBufferTexture5"),
Shader.PropertyToID("_GBufferTexture6"),
Shader.PropertyToID("_GBufferTexture7")
};
public static readonly int _ShadowMaskTexture = Shader.PropertyToID("_ShadowMaskTexture");
public static readonly int _DistortionTexture = Shader.PropertyToID("_DistortionTexture");
public static readonly int _GaussianPyramidColorTexture = Shader.PropertyToID("_GaussianPyramidColorTexture");
public static readonly int _DepthPyramidTexture = Shader.PropertyToID("_PyramidDepthTexture");

1
ScriptableRenderPipeline/HDRenderPipeline/HDUtils.cs
查看文件


public class HDUtils
{
public const RendererConfiguration k_RendererConfigurationBakedLighting = RendererConfiguration.PerObjectLightProbe | RendererConfiguration.PerObjectLightmaps | RendererConfiguration.PerObjectLightProbeProxyVolume;
public const RendererConfiguration k_RendererConfigurationBakedLightingWithShadowMask = RendererConfiguration.PerObjectLightProbe | RendererConfiguration.PerObjectLightmaps | RendererConfiguration.PerObjectLightProbeProxyVolume;
public static List<RenderPipelineMaterial> GetRenderPipelineMaterialList()
{

14
ScriptableRenderPipeline/HDRenderPipeline/Lighting/Deferred.shader
查看文件


// Split lighting is utilized during the SSS pass.
#pragma multi_compile _ OUTPUT_SPLIT_LIGHTING
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile _ DEBUG_DISPLAY
//-------------------------------------------------------------------------------------

//-------------------------------------------------------------------------------------
DECLARE_GBUFFER_TEXTURE(_GBufferTexture);
#ifdef SHADOWS_SHADOWMASK
TEXTURE2D(_ShadowMaskTexture);
#endif
struct Attributes
{

FETCH_GBUFFER(gbuffer, _GBufferTexture, posInput.unPositionSS);
BSDFData bsdfData;
float3 bakeDiffuseLighting;
DECODE_FROM_GBUFFER(gbuffer, MATERIAL_FEATURE_MASK_FLAGS, bsdfData, bakeDiffuseLighting);
BakeLightingData bakeLightingData;
DECODE_FROM_GBUFFER(gbuffer, MATERIAL_FEATURE_MASK_FLAGS, bsdfData, bakeLightingData.bakeDiffuseLighting);
#ifdef SHADOWS_SHADOWMASK
DecodeShadowMask(LOAD_TEXTURE2D(_ShadowMaskTexture, posInput.unPositionSS), bakeLightingData.bakeShadowMask);
#endif
LightLoop(V, posInput, preLightData, bsdfData, bakeDiffuseLighting, LIGHT_FEATURE_MASK_FLAGS_OPAQUE, diffuseLighting, specularLighting);
LightLoop(V, posInput, preLightData, bsdfData, bakeLightingData, LIGHT_FEATURE_MASK_FLAGS_OPAQUE, diffuseLighting, specularLighting);
Outputs outputs;
#ifdef OUTPUT_SPLIT_LIGHTING

10
ScriptableRenderPipeline/HDRenderPipeline/Lighting/LightDefinition.cs
查看文件


public Vector3 up; // Rescaled by (2 / shapeWidth)
public float diffuseScale;
public bool dynamicShadowCasterOnly; // Use with ShadowMask feature
public Vector2 fadeDistanceScaleAndBias; // Use with ShadowMask feature
public float unused0;
public Vector4 shadowMaskSelector; // Use with ShadowMask feature
};
[GenerateHLSL]

public float angleScale; // Spot light
public float angleOffset; // Spot light
public float shadowDimmer;
public int unused0;
public bool dynamicShadowCasterOnly; // Use with ShadowMask feature
public Vector4 shadowMaskSelector; // Use with ShadowMask feature
};

31
ScriptableRenderPipeline/HDRenderPipeline/Lighting/LightDefinition.cs.hlsl
查看文件


float specularScale;
float3 up;
float diffuseScale;
bool dynamicShadowCasterOnly;
float2 fadeDistanceScaleAndBias;
float unused0;
float4 shadowMaskSelector;
};
// Generated from UnityEngine.Experimental.Rendering.HDPipeline.LightData

float angleScale;
float angleOffset;
float shadowDimmer;
int unused0;
bool dynamicShadowCasterOnly;
float4 shadowMaskSelector;
};
// Generated from UnityEngine.Experimental.Rendering.HDPipeline.EnvLightData

{
return value.diffuseScale;
}
bool GetDynamicShadowCasterOnly(DirectionalLightData value)
{
return value.dynamicShadowCasterOnly;
}
float2 GetFadeDistanceScaleAndBias(DirectionalLightData value)
{
return value.fadeDistanceScaleAndBias;
}
float GetUnused0(DirectionalLightData value)
{
return value.unused0;
}
float4 GetShadowMaskSelector(DirectionalLightData value)
{
return value.shadowMaskSelector;
}
//
// Accessors for UnityEngine.Experimental.Rendering.HDPipeline.LightData

{
return value.shadowDimmer;
}
int GetUnused0(LightData value)
bool GetDynamicShadowCasterOnly(LightData value)
return value.unused0;
return value.dynamicShadowCasterOnly;
}
float2 GetSize(LightData value)
{

float GetMinRoughness(LightData value)
{
return value.minRoughness;
}
float4 GetShadowMaskSelector(LightData value)
{
return value.shadowMaskSelector;
}
//

109
ScriptableRenderPipeline/HDRenderPipeline/Lighting/TilePass/Deferred.compute
查看文件


#pragma kernel Deferred_Direct_Fptl SHADE_OPAQUE_ENTRY=Deferred_Direct_Fptl USE_FPTL_LIGHTLIST
#pragma kernel Deferred_Direct_Fptl_DebugDisplay SHADE_OPAQUE_ENTRY=Deferred_Direct_Fptl_DebugDisplay USE_FPTL_LIGHTLIST DEBUG_DISPLAY
#pragma kernel Deferred_Direct_Clustered SHADE_OPAQUE_ENTRY=Deferred_Direct_Clustered USE_CLUSTERED_LIGHTLIST
#pragma kernel Deferred_Direct_Clustered_DebugDisplay SHADE_OPAQUE_ENTRY=Deferred_Direct_Clustered_DebugDisplay USE_CLUSTERED_LIGHTLIST DEBUG_DISPLAY
#pragma kernel Deferred_Direct_Fptl SHADE_OPAQUE_ENTRY=Deferred_Direct_Fptl USE_FPTL_LIGHTLIST
#pragma kernel Deferred_Direct_Fptl_DebugDisplay SHADE_OPAQUE_ENTRY=Deferred_Direct_Fptl_DebugDisplay USE_FPTL_LIGHTLIST DEBUG_DISPLAY
#pragma kernel Deferred_Direct_ShadowMask_Fptl SHADE_OPAQUE_ENTRY=Deferred_Direct_ShadowMask_Fptl USE_FPTL_LIGHTLIST SHADOWS_SHADOWMASK
#pragma kernel Deferred_Direct_ShadowMask_Fptl_DebugDisplay SHADE_OPAQUE_ENTRY=Deferred_Direct_ShadowMask_Fptl_DebugDisplay USE_FPTL_LIGHTLIST SHADOWS_SHADOWMASK DEBUG_DISPLAY
#pragma kernel Deferred_Direct_Clustered SHADE_OPAQUE_ENTRY=Deferred_Direct_Clustered USE_CLUSTERED_LIGHTLIST
#pragma kernel Deferred_Direct_Clustered_DebugDisplay SHADE_OPAQUE_ENTRY=Deferred_Direct_Clustered_DebugDisplay USE_CLUSTERED_LIGHTLIST DEBUG_DISPLAY
#pragma kernel Deferred_Direct_ShadowMask_Clustered SHADE_OPAQUE_ENTRY=Deferred_Direct_ShadowMask_Clustered USE_CLUSTERED_LIGHTLIST SHADOWS_SHADOWMASK
#pragma kernel Deferred_Direct_ShadowMask_Clustered_DebugDisplay SHADE_OPAQUE_ENTRY=Deferred_Direct_ShadowMask_Clustered_DebugDisplay USE_CLUSTERED_LIGHTLIST SHADOWS_SHADOWMASK DEBUG_DISPLAY
// Variant with and without shadowmask
#pragma kernel Deferred_Indirect_Fptl_Variant0 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant0 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=0
#pragma kernel Deferred_Indirect_Fptl_Variant1 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant1 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=1
#pragma kernel Deferred_Indirect_Fptl_Variant2 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant2 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=2
#pragma kernel Deferred_Indirect_Fptl_Variant3 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant3 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=3
#pragma kernel Deferred_Indirect_Fptl_Variant4 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant4 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=4
#pragma kernel Deferred_Indirect_Fptl_Variant5 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant5 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=5
#pragma kernel Deferred_Indirect_Fptl_Variant6 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant6 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=6
#pragma kernel Deferred_Indirect_Fptl_Variant7 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant7 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=7
#pragma kernel Deferred_Indirect_Fptl_Variant8 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant8 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=8
#pragma kernel Deferred_Indirect_Fptl_Variant9 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant9 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=9
#pragma kernel Deferred_Indirect_Fptl_Variant10 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant10 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=10
#pragma kernel Deferred_Indirect_Fptl_Variant11 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant11 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=11
#pragma kernel Deferred_Indirect_Fptl_Variant12 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant12 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=12
#pragma kernel Deferred_Indirect_Fptl_Variant13 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant13 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=13
#pragma kernel Deferred_Indirect_Fptl_Variant14 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant14 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=14
#pragma kernel Deferred_Indirect_Fptl_Variant15 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant15 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=15
#pragma kernel Deferred_Indirect_Fptl_Variant16 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant16 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=16
#pragma kernel Deferred_Indirect_Fptl_Variant17 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant17 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=17
#pragma kernel Deferred_Indirect_Fptl_Variant18 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant18 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=18
#pragma kernel Deferred_Indirect_Fptl_Variant19 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant19 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=19
#pragma kernel Deferred_Indirect_Fptl_Variant20 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant20 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=20
#pragma kernel Deferred_Indirect_Fptl_Variant21 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant21 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=21
#pragma kernel Deferred_Indirect_Fptl_Variant22 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant22 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=22
#pragma kernel Deferred_Indirect_Fptl_Variant23 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant23 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=23
#pragma kernel Deferred_Indirect_Fptl_Variant24 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant24 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=24
#pragma kernel Deferred_Indirect_Fptl_Variant25 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant25 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=25
#pragma kernel Deferred_Indirect_Fptl_Variant26 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant26 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=26
#pragma kernel Deferred_Indirect_Fptl_Variant0 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant0 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=0
#pragma kernel Deferred_Indirect_Fptl_Variant1 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant1 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=1
#pragma kernel Deferred_Indirect_Fptl_Variant2 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant2 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=2
#pragma kernel Deferred_Indirect_Fptl_Variant3 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant3 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=3
#pragma kernel Deferred_Indirect_Fptl_Variant4 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant4 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=4
#pragma kernel Deferred_Indirect_Fptl_Variant5 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant5 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=5
#pragma kernel Deferred_Indirect_Fptl_Variant6 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant6 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=6
#pragma kernel Deferred_Indirect_Fptl_Variant7 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant7 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=7
#pragma kernel Deferred_Indirect_Fptl_Variant8 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant8 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=8
#pragma kernel Deferred_Indirect_Fptl_Variant9 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant9 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=9
#pragma kernel Deferred_Indirect_Fptl_Variant10 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant10 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=10
#pragma kernel Deferred_Indirect_Fptl_Variant11 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant11 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=11
#pragma kernel Deferred_Indirect_Fptl_Variant12 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant12 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=12
#pragma kernel Deferred_Indirect_Fptl_Variant13 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant13 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=13
#pragma kernel Deferred_Indirect_Fptl_Variant14 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant14 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=14
#pragma kernel Deferred_Indirect_Fptl_Variant15 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant15 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=15
#pragma kernel Deferred_Indirect_Fptl_Variant16 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant16 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=16
#pragma kernel Deferred_Indirect_Fptl_Variant17 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant17 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=17
#pragma kernel Deferred_Indirect_Fptl_Variant18 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant18 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=18
#pragma kernel Deferred_Indirect_Fptl_Variant19 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant19 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=19
#pragma kernel Deferred_Indirect_Fptl_Variant20 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant20 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=20
#pragma kernel Deferred_Indirect_Fptl_Variant21 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant21 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=21
#pragma kernel Deferred_Indirect_Fptl_Variant22 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant22 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=22
#pragma kernel Deferred_Indirect_Fptl_Variant23 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant23 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=23
#pragma kernel Deferred_Indirect_Fptl_Variant24 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant24 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=24
#pragma kernel Deferred_Indirect_Fptl_Variant25 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant25 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=25
#pragma kernel Deferred_Indirect_Fptl_Variant26 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Fptl_Variant26 USE_FPTL_LIGHTLIST USE_INDIRECT VARIANT=26
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant0 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant0 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=0
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant1 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant1 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=1
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant2 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant2 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=2
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant3 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant3 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=3
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant4 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant4 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=4
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant5 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant5 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=5
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant6 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant6 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=6
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant7 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant7 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=7
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant8 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant8 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=8
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant9 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant9 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=9
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant10 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant10 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=10
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant11 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant11 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=11
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant12 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant12 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=12
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant13 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant13 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=13
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant14 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant14 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=14
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant15 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant15 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=15
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant16 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant16 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=16
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant17 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant17 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=17
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant18 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant18 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=18
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant19 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant19 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=19
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant20 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant20 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=20
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant21 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant21 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=21
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant22 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant22 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=22
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant23 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant23 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=23
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant24 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant24 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=24
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant25 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant25 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=25
#pragma kernel Deferred_Indirect_ShadowMask_Fptl_Variant26 SHADE_OPAQUE_ENTRY=Deferred_Indirect_ShadowMask_Fptl_Variant26 USE_FPTL_LIGHTLIST USE_INDIRECT SHADOWS_SHADOWMASK VARIANT=26
/* Tag: SUPPORT_COMPUTE_CLUSTER_OPAQUE - Uncomment this if you want to do cluster opaque with compute shader (by default we support only fptl on opaque)
#pragma kernel Deferred_Indirect_Clustered_Variant0 SHADE_OPAQUE_ENTRY=Deferred_Indirect_Clustered_Variant0 USE_CLUSTERED_LIGHTLIST USE_INDIRECT VARIANT=0

//-------------------------------------------------------------------------------------
DECLARE_GBUFFER_TEXTURE(_GBufferTexture);
#ifdef SHADOWS_SHADOWMASK
TEXTURE2D(_ShadowMaskTexture);
#endif
RWTexture2D<float3> diffuseLightingUAV;
RWTexture2D<float4> specularLightingUAV;

CBUFFER_END
#if USE_INDIRECT
#ifdef USE_INDIRECT
StructuredBuffer<uint> g_TileList;
// Indirect

FETCH_GBUFFER(gbuffer, _GBufferTexture, posInput.unPositionSS);
BSDFData bsdfData;
float3 bakeDiffuseLighting;
DECODE_FROM_GBUFFER(gbuffer, featureFlags, bsdfData, bakeDiffuseLighting);
BakeLightingData bakeLightingData;
DECODE_FROM_GBUFFER(gbuffer, featureFlags, bsdfData, bakeLightingData.bakeDiffuseLighting);
#ifdef SHADOWS_SHADOWMASK
DecodeShadowMask(LOAD_TEXTURE2D(_ShadowMaskTexture, posInput.unPositionSS), bakeLightingData.bakeShadowMask);
#endif
LightLoop(V, posInput, preLightData, bsdfData, bakeDiffuseLighting, featureFlags, diffuseLighting, specularLighting);
LightLoop(V, posInput, preLightData, bsdfData, bakeLightingData, featureFlags, diffuseLighting, specularLighting);
if (_EnableSSSAndTransmission != 0 && bsdfData.materialId == MATERIALID_LIT_SSS && HasMaterialFeatureFlag(MATERIALFEATUREFLAGS_LIT_SSS))
{

479
ScriptableRenderPipeline/HDRenderPipeline/Lighting/TilePass/TilePass.cs
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int m_punctualLightCount = 0;
int m_areaLightCount = 0;
int m_lightCount = 0;
bool m_enableBakeShadowMask = false; // Track if any light require shadow mask. In this case we will need to enable the keyword shadow mask
float m_maxShadowDistance = 0.0f; // Save value from shadow settings
private ComputeShader buildScreenAABBShader { get { return m_Resources.buildScreenAABBShader; } }
private ComputeShader buildPerTileLightListShader { get { return m_Resources.buildPerTileLightListShader; } }

static int s_BuildDispatchIndirectKernel;
static int s_BuildMaterialFlagsWriteKernel;
static int s_BuildMaterialFlagsOrKernel;
static int s_shadeOpaqueDirectShadowMaskClusteredKernel;
static int s_shadeOpaqueDirectShadowMaskFptlKernel;
static int s_shadeOpaqueDirectShadowMaskClusteredDebugDisplayKernel;
static int s_shadeOpaqueDirectShadowMaskFptlDebugDisplayKernel;
static int[] s_shadeOpaqueIndirectShadowMaskFptlKernels = new int[LightDefinitions.s_NumFeatureVariants];
static int s_deferredDirectionalShadowKernel;

}
}
Material m_DeferredAllMaterialSRT = null;
Material m_DeferredAllMaterialMRT = null;
// Following is an array of material of size eight for all combination of keyword: OUTPUT_SPLIT_LIGHTING - LIGHTLOOP_TILE_PASS - SHADOWS_SHADOWMASK - USE_FPTL_LIGHTLIST/USE_CLUSTERED_LIGHTLIST - DEBUG_DISPLAY
Material[, , , ,] m_lightingMaterial;
Material m_DebugViewTilesMaterial;
Material m_DebugViewTilesMaterial = null;
Material m_SingleDeferredMaterialSRT = null;
Material m_SingleDeferredMaterialMRT = null;
Light m_CurrentSunLight = null;
Light m_CurrentSunLight;
int m_CurrentSunLightShadowIndex = -1;
public Light GetCurrentSunLight() { return m_CurrentSunLight; }

s_shadeOpaqueDirectClusteredDebugDisplayKernel = deferredComputeShader.FindKernel("Deferred_Direct_Clustered_DebugDisplay");
s_shadeOpaqueDirectFptlDebugDisplayKernel = deferredComputeShader.FindKernel("Deferred_Direct_Fptl_DebugDisplay");
s_shadeOpaqueDirectShadowMaskClusteredKernel = deferredComputeShader.FindKernel("Deferred_Direct_ShadowMask_Clustered");
s_shadeOpaqueDirectShadowMaskFptlKernel = deferredComputeShader.FindKernel("Deferred_Direct_ShadowMask_Fptl");
s_shadeOpaqueDirectShadowMaskClusteredDebugDisplayKernel = deferredComputeShader.FindKernel("Deferred_Direct_ShadowMask_Clustered_DebugDisplay");
s_shadeOpaqueDirectShadowMaskFptlDebugDisplayKernel = deferredComputeShader.FindKernel("Deferred_Direct_ShadowMask_Fptl_DebugDisplay");
s_deferredDirectionalShadowKernel = deferredDirectionalShadowComputeShader.FindKernel("DeferredDirectionalShadow");
for (int variant = 0; variant < LightDefinitions.s_NumFeatureVariants; variant++)

s_shadeOpaqueIndirectFptlKernels[variant] = deferredComputeShader.FindKernel("Deferred_Indirect_Fptl_Variant" + variant);
s_shadeOpaqueIndirectShadowMaskFptlKernels[variant] = deferredComputeShader.FindKernel("Deferred_Indirect_ShadowMask_Fptl_Variant" + variant);
}
s_LightList = null;

m_DeferredAllMaterialSRT = CoreUtils.CreateEngineMaterial(m_Resources.deferredShader);
m_DeferredAllMaterialSRT.EnableKeyword("LIGHTLOOP_TILE_PASS");
m_DeferredAllMaterialSRT.DisableKeyword("OUTPUT_SPLIT_LIGHTING");
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.RegularLighting);
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._SrcBlend, (int)BlendMode.One);
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._DstBlend, (int)BlendMode.Zero);
m_DeferredAllMaterialMRT = CoreUtils.CreateEngineMaterial(m_Resources.deferredShader);
m_DeferredAllMaterialMRT.EnableKeyword("LIGHTLOOP_TILE_PASS");
m_DeferredAllMaterialMRT.EnableKeyword("OUTPUT_SPLIT_LIGHTING");
m_DeferredAllMaterialMRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.SplitLighting);
m_DeferredAllMaterialMRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
m_DeferredAllMaterialMRT.SetInt(HDShaderIDs._SrcBlend, (int)BlendMode.One);
m_DeferredAllMaterialMRT.SetInt(HDShaderIDs._DstBlend, (int)BlendMode.Zero);
// OUTPUT_SPLIT_LIGHTING - LIGHTLOOP_TILE_PASS - SHADOWS_SHADOWMASK - USE_FPTL_LIGHTLIST/USE_CLUSTERED_LIGHTLIST - DEBUG_DISPLAY
m_lightingMaterial = new Material[2, 2, 2, 2, 2];
m_SingleDeferredMaterialSRT = CoreUtils.CreateEngineMaterial(m_Resources.deferredShader);
m_SingleDeferredMaterialSRT.EnableKeyword("LIGHTLOOP_SINGLE_PASS");
m_SingleDeferredMaterialSRT.DisableKeyword("OUTPUT_SPLIT_LIGHTING");
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.RegularLighting);
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._SrcBlend, (int)BlendMode.One);
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._DstBlend, (int)BlendMode.Zero);
for (int outputSplitLighting = 0; outputSplitLighting < 2; ++outputSplitLighting)
{
for (int lightLoopTilePass = 0; lightLoopTilePass < 2; ++lightLoopTilePass)
{
for (int ShadowMask = 0; ShadowMask < 2; ++ShadowMask)
{
for (int clustered = 0; clustered < 2; ++clustered)
{
for (int debugDisplay = 0; debugDisplay < 2; ++debugDisplay)
{
m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay] = CoreUtils.CreateEngineMaterial(m_Resources.deferredShader);
CoreUtils.SetKeyword(m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay], "OUTPUT_SPLIT_LIGHTING", outputSplitLighting == 1);
CoreUtils.SelectKeyword(m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay], "LIGHTLOOP_TILE_PASS", "LIGHTLOOP_SINGLE_PASS", lightLoopTilePass == 1);
CoreUtils.SetKeyword(m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay], "SHADOWS_SHADOWMASK", ShadowMask == 1);
CoreUtils.SelectKeyword(m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay], "USE_CLUSTERED_LIGHTLIST", "USE_FPTL_LIGHTLIST", clustered == 1);
CoreUtils.SetKeyword(m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay], "DEBUG_DISPLAY", debugDisplay == 1);
m_SingleDeferredMaterialMRT = CoreUtils.CreateEngineMaterial(m_Resources.deferredShader);
m_SingleDeferredMaterialMRT.EnableKeyword("LIGHTLOOP_SINGLE_PASS");
m_SingleDeferredMaterialMRT.EnableKeyword("OUTPUT_SPLIT_LIGHTING");
m_SingleDeferredMaterialMRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.SplitLighting);
m_SingleDeferredMaterialMRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
m_SingleDeferredMaterialMRT.SetInt(HDShaderIDs._SrcBlend, (int)BlendMode.One);
m_SingleDeferredMaterialMRT.SetInt(HDShaderIDs._DstBlend, (int)BlendMode.Zero);
m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay].SetInt(HDShaderIDs._StencilRef, outputSplitLighting == 1 ? (int)StencilLightingUsage.SplitLighting : (int)StencilLightingUsage.RegularLighting);
m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay].SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay].SetInt(HDShaderIDs._SrcBlend, (int)BlendMode.One);
m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay].SetInt(HDShaderIDs._DstBlend, (int)BlendMode.Zero);
}
}
}
}
}
m_DebugViewTilesMaterial = CoreUtils.CreateEngineMaterial(m_Resources.debugViewTilesShader);

// enableClustered
CoreUtils.SafeRelease(s_GlobalLightListAtomic);
CoreUtils.Destroy(m_DeferredAllMaterialSRT);
CoreUtils.Destroy(m_DeferredAllMaterialMRT);
for (int outputSplitLighting = 0; outputSplitLighting < 2; ++outputSplitLighting)
{
for (int lightLoopTilePass = 0; lightLoopTilePass < 2; ++lightLoopTilePass)
{
for (int ShadowMask = 0; ShadowMask < 2; ++ShadowMask)
{
for (int clustered = 0; clustered < 2; ++clustered)
{
for (int debugDisplay = 0; debugDisplay < 2; ++debugDisplay)
{
CoreUtils.Destroy(m_lightingMaterial[outputSplitLighting, lightLoopTilePass, ShadowMask, clustered, debugDisplay]);
}
}
}
}
}
CoreUtils.Destroy(m_SingleDeferredMaterialSRT);
CoreUtils.Destroy(m_SingleDeferredMaterialMRT);
}
public void NewFrame()

m_CurrentSunLight = light.light;
m_CurrentSunLightShadowIndex = shadowIdx;
}
// TODO: Currently m_maxShadowDistance is based on shadow settings, but this value is define for a whole level. We should be able to change this value during gameplay
float scale;
float bias;
GetSCaleAndBiasForLinearDistanceFade(m_maxShadowDistance, out scale, out bias);
directionalLightData.fadeDistanceScaleAndBias = new Vector2(scale, bias);
directionalLightData.shadowMaskSelector = Vector4.zero;
if (IsBakedShadowMaskLight(light.light))
{
directionalLightData.shadowMaskSelector[light.light.bakingOutput.occlusionMaskChannel] = 1.0f;
// TODO: make this option per light, not global
directionalLightData.dynamicShadowCasterOnly = QualitySettings.shadowmaskMode == ShadowmaskMode.Shadowmask;
}
else
{
// use -1 to say that we don't use shadow mask
directionalLightData.shadowMaskSelector.x = -1.0f;
directionalLightData.dynamicShadowCasterOnly = false;
}
m_CurrentSunLight = m_CurrentSunLight == null ? light.light : m_CurrentSunLight;
m_lightList.directionalLights.Add(directionalLightData);

float ComputeLinearDistanceFade(float distanceToCamera, float fadeDistance)
void GetSCaleAndBiasForLinearDistanceFade(float fadeDistance, out float scale, out float bias)
return 1.0f - Mathf.Clamp01((distanceToCamera - distanceFadeNear) / (fadeDistance - distanceFadeNear));
scale = 1.0f / (fadeDistance - distanceFadeNear);
bias = - distanceFadeNear / (fadeDistance - distanceFadeNear);
}
float ComputeLinearDistanceFade(float distanceToCamera, float fadeDistance)
{
float scale;
float bias;
GetSCaleAndBiasForLinearDistanceFade(fadeDistance, out scale, out bias);
return 1.0f - Mathf.Clamp01(distanceToCamera * scale + bias);
}
public bool GetLightData(ShadowSettings shadowSettings, Camera camera, GPULightType gpuLightType, VisibleLight light, HDAdditionalLightData additionalLightData, AdditionalShadowData additionalshadowData, int lightIndex)

// Value of max smoothness is from artists point of view, need to convert from perceptual smoothness to roughness
lightData.minRoughness = (1.0f - additionalLightData.maxSmoothness) * (1.0f - additionalLightData.maxSmoothness);
lightData.shadowMaskSelector = Vector4.zero;
if (IsBakedShadowMaskLight(light.light))
{
lightData.shadowMaskSelector[light.light.bakingOutput.occlusionMaskChannel] = 1.0f;
// TODO: make this option per light, not global
lightData.dynamicShadowCasterOnly = QualitySettings.shadowmaskMode == ShadowmaskMode.Shadowmask;
}
else
{
// use -1 to say that we don't use shadow mask
lightData.shadowMaskSelector.x = -1.0f;
lightData.dynamicShadowCasterOnly = false;
}
m_lightList.lights.Add(lightData);
return true;

m_ShadowMgr.UpdateCullingParameters( ref cullingParams );
}
public void PrepareLightsForGPU(ShadowSettings shadowSettings, CullResults cullResults, Camera camera)
public bool IsBakedShadowMaskLight(Light light)
{
return light.bakingOutput.lightmapBakeType == LightmapBakeType.Mixed &&
light.bakingOutput.mixedLightingMode == MixedLightingMode.Shadowmask &&
light.bakingOutput.occlusionMaskChannel != -1; // We need to have an occlusion mask channel assign, else we have no shadow mask
}
// Return true if BakedShadowMask are enabled
public bool PrepareLightsForGPU(ShadowSettings shadowSettings, CullResults cullResults, Camera camera)
// If any light require it, we need to enabled bake shadow mask feature
m_enableBakeShadowMask = false;
m_lightList.Clear();
Vector3 camPosWS = camera.transform.position;

// Debug.Assert(additionalData == null, "Missing HDAdditionalData on a light - Should have been create by HDLightEditor");
if (additionalData == null)
return;
return false;
LightCategory lightCategory = LightCategory.Count;
GPULightType gpuLightType = GPULightType.Point;

int lightIndex = (int)(sortKey & 0xFFFF);
var light = cullResults.visibleLights[lightIndex];
m_enableBakeShadowMask = m_enableBakeShadowMask || IsBakedShadowMaskLight(light.light);
var additionalLightData = light.light.GetComponent<HDAdditionalLightData>();
var additionalShadowData = light.light.GetComponent<AdditionalShadowData>(); // Can be null

Debug.Assert(m_lightList.lightVolumes.Count == m_lightCount);
UpdateDataBuffers();
m_maxShadowDistance = shadowSettings.maxShadowDistance;
return m_enableBakeShadowMask;
}
void VoxelLightListGeneration(CommandBuffer cmd, Camera camera, Matrix4x4 projscr, Matrix4x4 invProjscr, RenderTargetIdentifier cameraDepthBufferRT)

cmd.SetComputeTextureParam(buildMaterialFlagsShader, buildMaterialFlagsKernel, HDShaderIDs._GBufferTexture1, HDShaderIDs._GBufferTexture1);
cmd.SetComputeTextureParam(buildMaterialFlagsShader, buildMaterialFlagsKernel, HDShaderIDs._GBufferTexture2, HDShaderIDs._GBufferTexture2);
cmd.SetComputeTextureParam(buildMaterialFlagsShader, buildMaterialFlagsKernel, HDShaderIDs._GBufferTexture3, HDShaderIDs._GBufferTexture3);
cmd.SetComputeTextureParam(buildMaterialFlagsShader, buildMaterialFlagsKernel, HDShaderIDs._ShadowMaskTexture, HDShaderIDs._ShadowMaskTexture);
cmd.SetComputeTextureParam(buildMaterialFlagsShader, buildMaterialFlagsKernel, HDShaderIDs._VelocityTexture, HDShaderIDs._VelocityTexture);
cmd.DispatchCompute(buildMaterialFlagsShader, buildMaterialFlagsKernel, numTilesX, numTilesY, 1);
}

m_ShadowMgr.RenderShadows(m_FrameId, renderContext, cmd, cullResults, cullResults.visibleLights);
}
private void SetupDebugDisplayMode(bool debugDisplayEnable)
{
CoreUtils.SetKeyword(m_DeferredAllMaterialSRT, "DEBUG_DISPLAY", debugDisplayEnable);
CoreUtils.SetKeyword(m_DeferredAllMaterialMRT, "DEBUG_DISPLAY", debugDisplayEnable);
CoreUtils.SetKeyword(m_SingleDeferredMaterialSRT, "DEBUG_DISPLAY", debugDisplayEnable);
CoreUtils.SetKeyword(m_SingleDeferredMaterialMRT, "DEBUG_DISPLAY", debugDisplayEnable);
}
public void RenderLightingDebug(HDCamera hdCamera, CommandBuffer cmd, RenderTargetIdentifier colorBuffer, DebugDisplaySettings debugDisplaySettings)
{
LightingDebugSettings lightingDebug = debugDisplaySettings.lightingDebugSettings;

{
var camera = hdCamera.camera;
SetupDebugDisplayMode(debugDisplaySettings.IsDebugDisplayEnabled());
if (!m_TileSettings.enableTileAndCluster)
{
PushGlobalParams(camera, cmd, null, 0);
// This is a debug brute force renderer to debug tile/cluster which render all the lights
if (options.outputSplitLighting)
{
CoreUtils.DrawFullScreen(cmd, m_SingleDeferredMaterialMRT, colorBuffers, depthStencilBuffer);
}
else
{
// If SSS is disable, do lighting for both split lighting and no split lighting
if (!debugDisplaySettings.renderingDebugSettings.enableSSSAndTransmission)
{
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.NoLighting);
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.NotEqual);
}
else
{
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.RegularLighting);
m_SingleDeferredMaterialSRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
}
CoreUtils.DrawFullScreen(cmd, m_SingleDeferredMaterialSRT, colorBuffers[0], depthStencilBuffer);
}
}
else
// Compute path
if (m_TileSettings.enableTileAndCluster && m_TileSettings.enableComputeLightEvaluation)
{
int w = camera.pixelWidth;
int h = camera.pixelHeight;

if (m_TileSettings.enableComputeLightEvaluation)
{
bool enableFeatureVariants = GetFeatureVariantsEnabled(m_TileSettings) && !debugDisplaySettings.IsDebugDisplayEnabled();
bool enableFeatureVariants = GetFeatureVariantsEnabled(m_TileSettings) && !debugDisplaySettings.IsDebugDisplayEnabled();
int numVariants = 1;
if (enableFeatureVariants)
numVariants = LightDefinitions.s_NumFeatureVariants;
int numVariants = 1;
if (enableFeatureVariants)
numVariants = LightDefinitions.s_NumFeatureVariants;
int debugViewMaterial = Shader.GetGlobalInt(HDShaderIDs._DebugViewMaterial);
int debugLightingMode = Shader.GetGlobalInt(HDShaderIDs._DebugLightingMode);
Vector4 debugLightingAlbedo = Shader.GetGlobalVector(HDShaderIDs._DebugLightingAlbedo);
Vector4 debugLightingSmoothness = Shader.GetGlobalVector(HDShaderIDs._DebugLightingSmoothness);
int debugViewMaterial = Shader.GetGlobalInt(HDShaderIDs._DebugViewMaterial);
int debugLightingMode = Shader.GetGlobalInt(HDShaderIDs._DebugLightingMode);
Vector4 debugLightingAlbedo = Shader.GetGlobalVector(HDShaderIDs._DebugLightingAlbedo);
Vector4 debugLightingSmoothness = Shader.GetGlobalVector(HDShaderIDs._DebugLightingSmoothness);
Texture ltcData = Shader.GetGlobalTexture(HDShaderIDs._LtcData);
Texture preIntegratedFGD = Shader.GetGlobalTexture(HDShaderIDs._PreIntegratedFGD);
Texture ltcGGXMatrix = Shader.GetGlobalTexture(HDShaderIDs._LtcGGXMatrix);
Texture ltcDisneyDiffuseMatrix = Shader.GetGlobalTexture(HDShaderIDs._LtcDisneyDiffuseMatrix);
Texture ltcMultiGGXFresnelDisneyDiffuse = Shader.GetGlobalTexture(HDShaderIDs._LtcMultiGGXFresnelDisneyDiffuse);
Texture ltcData = Shader.GetGlobalTexture(HDShaderIDs._LtcData);
Texture preIntegratedFGD = Shader.GetGlobalTexture(HDShaderIDs._PreIntegratedFGD);
Texture ltcGGXMatrix = Shader.GetGlobalTexture(HDShaderIDs._LtcGGXMatrix);
Texture ltcDisneyDiffuseMatrix = Shader.GetGlobalTexture(HDShaderIDs._LtcDisneyDiffuseMatrix);
Texture ltcMultiGGXFresnelDisneyDiffuse = Shader.GetGlobalTexture(HDShaderIDs._LtcMultiGGXFresnelDisneyDiffuse);
Matrix4x4 invScrProjection = Shader.GetGlobalMatrix(HDShaderIDs.g_mInvScrProjection);
int useTileLightList = Shader.GetGlobalInt(HDShaderIDs._UseTileLightList);
Matrix4x4 invScrProjection = Shader.GetGlobalMatrix(HDShaderIDs.g_mInvScrProjection);
int useTileLightList = Shader.GetGlobalInt(HDShaderIDs._UseTileLightList);
Vector4 time = Shader.GetGlobalVector(HDShaderIDs._Time);
Vector4 sinTime = Shader.GetGlobalVector(HDShaderIDs._SinTime);
Vector4 cosTime = Shader.GetGlobalVector(HDShaderIDs._CosTime);
Vector4 unity_DeltaTime = Shader.GetGlobalVector(HDShaderIDs.unity_DeltaTime);
int envLightSkyEnabled = Shader.GetGlobalInt(HDShaderIDs._EnvLightSkyEnabled);
Vector4 ambientOcclusionParam = Shader.GetGlobalVector(HDShaderIDs._AmbientOcclusionParam);
Vector4 time = Shader.GetGlobalVector(HDShaderIDs._Time);
Vector4 sinTime = Shader.GetGlobalVector(HDShaderIDs._SinTime);
Vector4 cosTime = Shader.GetGlobalVector(HDShaderIDs._CosTime);
Vector4 unity_DeltaTime = Shader.GetGlobalVector(HDShaderIDs.unity_DeltaTime);
int envLightSkyEnabled = Shader.GetGlobalInt(HDShaderIDs._EnvLightSkyEnabled);
Vector4 ambientOcclusionParam = Shader.GetGlobalVector(HDShaderIDs._AmbientOcclusionParam);
int enableSSSAndTransmission = Shader.GetGlobalInt(HDShaderIDs._EnableSSSAndTransmission);
int texturingModeFlags = Shader.GetGlobalInt(HDShaderIDs._TexturingModeFlags);
int transmissionFlags = Shader.GetGlobalInt(HDShaderIDs._TransmissionFlags);
int useDisneySSS = Shader.GetGlobalInt(HDShaderIDs._UseDisneySSS);
Vector4[] thicknessRemaps = Shader.GetGlobalVectorArray(HDShaderIDs._ThicknessRemaps);
Vector4[] shapeParams = Shader.GetGlobalVectorArray(HDShaderIDs._ShapeParams);
Vector4[] transmissionTints = Shader.GetGlobalVectorArray(HDShaderIDs._TransmissionTints);
Vector4[] halfRcpVariancesAndWeights = Shader.GetGlobalVectorArray(HDShaderIDs._HalfRcpVariancesAndWeights);
int enableSSSAndTransmission = Shader.GetGlobalInt(HDShaderIDs._EnableSSSAndTransmission);
int texturingModeFlags = Shader.GetGlobalInt(HDShaderIDs._TexturingModeFlags);
int transmissionFlags = Shader.GetGlobalInt(HDShaderIDs._TransmissionFlags);
int useDisneySSS = Shader.GetGlobalInt(HDShaderIDs._UseDisneySSS);
Vector4[] thicknessRemaps = Shader.GetGlobalVectorArray(HDShaderIDs._ThicknessRemaps);
Vector4[] shapeParams = Shader.GetGlobalVectorArray(HDShaderIDs._ShapeParams);
Vector4[] transmissionTints = Shader.GetGlobalVectorArray(HDShaderIDs._TransmissionTints);
Vector4[] halfRcpVariancesAndWeights = Shader.GetGlobalVectorArray(HDShaderIDs._HalfRcpVariancesAndWeights);
Texture skyTexture = Shader.GetGlobalTexture(HDShaderIDs._SkyTexture);
float skyTextureMipCount = Shader.GetGlobalFloat(HDShaderIDs._SkyTextureMipCount);
Texture skyTexture = Shader.GetGlobalTexture(HDShaderIDs._SkyTexture);
float skyTextureMipCount = Shader.GetGlobalFloat(HDShaderIDs._SkyTextureMipCount);
for (int variant = 0; variant < numVariants; variant++)
{
int kernel;
for (int variant = 0; variant < numVariants; variant++)
if (enableFeatureVariants)
int kernel;
if (enableFeatureVariants)
{
// Tag: SUPPORT_COMPUTE_CLUSTER_OPAQUE - Uncomment this if you want to do cluster opaque with compute shader (by default we support only fptl on opaque)
// kernel = usingFptl ? s_shadeOpaqueIndirectFptlKernels[variant] : s_shadeOpaqueIndirectClusteredKernels[variant];
kernel = s_shadeOpaqueIndirectFptlKernels[variant];
}
// Tag: SUPPORT_COMPUTE_CLUSTER_OPAQUE - Update the code with following comment this if you want to do cluster opaque with compute shader (by default we support only fptl on opaque)
// kernel = usingFptl ? s_shadeOpaqueIndirectFptlKernels[variant] : s_shadeOpaqueIndirectClusteredKernels[variant];
if (m_enableBakeShadowMask)
kernel = s_shadeOpaqueIndirectShadowMaskFptlKernels[variant];
kernel = s_shadeOpaqueIndirectFptlKernels[variant];
}
else
{
if (m_enableBakeShadowMask)
{
}
{
}
else
{
if (debugDisplaySettings.IsDebugDisplayEnabled())
kernel = usingFptl ? s_shadeOpaqueDirectShadowMaskFptlDebugDisplayKernel : s_shadeOpaqueDirectShadowMaskClusteredDebugDisplayKernel;
else
kernel = usingFptl ? s_shadeOpaqueDirectShadowMaskFptlKernel : s_shadeOpaqueDirectShadowMaskClusteredKernel;
}
}
// Pass global parameters to compute shader
// TODO: get rid of this by making global parameters visible to compute shaders
PushGlobalParams(camera, cmd, deferredComputeShader, kernel);
hdCamera.SetupComputeShader(deferredComputeShader, cmd);
// Pass global parameters to compute shader
// TODO: get rid of this by making global parameters visible to compute shaders
PushGlobalParams(camera, cmd, deferredComputeShader, kernel);
hdCamera.SetupComputeShader(deferredComputeShader, cmd);
// TODO: Update value like in ApplyDebugDisplaySettings() call. Sadly it is high likely that this will not be keep in sync. we really need to get rid of this by making global parameters visible to compute shaders
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._DebugViewMaterial, debugViewMaterial);
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._DebugLightingMode, debugLightingMode);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._DebugLightingAlbedo, debugLightingAlbedo);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._DebugLightingSmoothness, debugLightingSmoothness);
// TODO: Update value like in ApplyDebugDisplaySettings() call. Sadly it is high likely that this will not be keep in sync. we really need to get rid of this by making global parameters visible to compute shaders
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._DebugViewMaterial, debugViewMaterial);
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._DebugLightingMode, debugLightingMode);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._DebugLightingAlbedo, debugLightingAlbedo);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._DebugLightingSmoothness, debugLightingSmoothness);
cmd.SetComputeBufferParam(deferredComputeShader, kernel, HDShaderIDs.g_vLightListGlobal, bUseClusteredForDeferred ? s_PerVoxelLightLists : s_LightList);
cmd.SetComputeBufferParam(deferredComputeShader, kernel, HDShaderIDs.g_vLightListGlobal, bUseClusteredForDeferred ? s_PerVoxelLightLists : s_LightList);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._DeferredShadowTexture, deferredShadowTexture);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._DeferredShadowTexture, deferredShadowTexture);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._MainDepthTexture, depthTexture);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._MainDepthTexture, depthTexture);
// TODO: Don't know why but If we use Shader.GetGlobalTexture(HDShaderIDs._GBufferTexture0) instead of HDShaderIDs._GBufferTexture0 the screen start to flicker in SceneView...
// Need to investigate what is happening. But this may be unnecessary as development of SetGlobalTexture for compute shader have begin
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture0, HDShaderIDs._GBufferTexture0);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture1, HDShaderIDs._GBufferTexture1);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture2, HDShaderIDs._GBufferTexture2);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture3, HDShaderIDs._GBufferTexture3);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._AmbientOcclusionTexture, HDShaderIDs._AmbientOcclusionTexture);
// TODO: Don't know why but If we use Shader.GetGlobalTexture(HDShaderIDs._GBufferTexture0) instead of HDShaderIDs._GBufferTexture0 the screen start to flicker in SceneView...
// Need to investigate what is happening. But this may be unnecessary as development of SetGlobalTexture for compute shader have begin
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture0, HDShaderIDs._GBufferTexture0);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture1, HDShaderIDs._GBufferTexture1);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture2, HDShaderIDs._GBufferTexture2);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._GBufferTexture3, HDShaderIDs._GBufferTexture3);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._ShadowMaskTexture, HDShaderIDs._ShadowMaskTexture);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._VelocityTexture, HDShaderIDs._VelocityTexture);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._AmbientOcclusionTexture, HDShaderIDs._AmbientOcclusionTexture);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcData, ltcData);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._PreIntegratedFGD, preIntegratedFGD);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcGGXMatrix, ltcGGXMatrix);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcDisneyDiffuseMatrix, ltcDisneyDiffuseMatrix);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcMultiGGXFresnelDisneyDiffuse, ltcMultiGGXFresnelDisneyDiffuse);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcData, ltcData);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._PreIntegratedFGD, preIntegratedFGD);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcGGXMatrix, ltcGGXMatrix);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcDisneyDiffuseMatrix, ltcDisneyDiffuseMatrix);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._LtcMultiGGXFresnelDisneyDiffuse, ltcMultiGGXFresnelDisneyDiffuse);
cmd.SetComputeMatrixParam(deferredComputeShader, HDShaderIDs.g_mInvScrProjection, invScrProjection);
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._UseTileLightList, useTileLightList);
cmd.SetComputeMatrixParam(deferredComputeShader, HDShaderIDs.g_mInvScrProjection, invScrProjection);
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._UseTileLightList, useTileLightList);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._Time, time);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._SinTime, sinTime);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._CosTime, cosTime);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs.unity_DeltaTime, unity_DeltaTime);
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._EnvLightSkyEnabled, envLightSkyEnabled);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._AmbientOcclusionParam, ambientOcclusionParam);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._Time, time);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._SinTime, sinTime);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._CosTime, cosTime);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs.unity_DeltaTime, unity_DeltaTime);
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs._EnvLightSkyEnabled, envLightSkyEnabled);
cmd.SetComputeVectorParam(deferredComputeShader, HDShaderIDs._AmbientOcclusionParam, ambientOcclusionParam);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._SkyTexture, skyTexture ? skyTexture : m_DefaultTexture2DArray);
cmd.SetComputeFloatParam(deferredComputeShader, HDShaderIDs._SkyTextureMipCount, skyTextureMipCount);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs._SkyTexture, skyTexture ? skyTexture : m_DefaultTexture2DArray);
cmd.SetComputeFloatParam(deferredComputeShader, HDShaderIDs._SkyTextureMipCount, skyTextureMipCount);
// Set SSS parameters.
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._EnableSSSAndTransmission, enableSSSAndTransmission);
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._TexturingModeFlags, texturingModeFlags);
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._TransmissionFlags, transmissionFlags);
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._UseDisneySSS, useDisneySSS);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._ThicknessRemaps, thicknessRemaps);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._ShapeParams, shapeParams);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._TransmissionTints, transmissionTints);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._HalfRcpVariancesAndWeights, halfRcpVariancesAndWeights);
// Set SSS parameters.
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._EnableSSSAndTransmission, enableSSSAndTransmission);
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._TexturingModeFlags, texturingModeFlags);
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._TransmissionFlags, transmissionFlags);
cmd.SetComputeIntParam( deferredComputeShader, HDShaderIDs._UseDisneySSS, useDisneySSS);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._ThicknessRemaps, thicknessRemaps);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._ShapeParams, shapeParams);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._TransmissionTints, transmissionTints);
cmd.SetComputeVectorArrayParam(deferredComputeShader, HDShaderIDs._HalfRcpVariancesAndWeights, halfRcpVariancesAndWeights);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs.specularLightingUAV, colorBuffers[0]);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs.diffuseLightingUAV, colorBuffers[1]);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs.specularLightingUAV, colorBuffers[0]);
cmd.SetComputeTextureParam(deferredComputeShader, kernel, HDShaderIDs.diffuseLightingUAV, colorBuffers[1]);
// always do deferred lighting in blocks of 16x16 (not same as tiled light size)
// always do deferred lighting in blocks of 16x16 (not same as tiled light size)
if (enableFeatureVariants)
{
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs.g_TileListOffset, variant * numTiles);
cmd.SetComputeBufferParam(deferredComputeShader, kernel, HDShaderIDs.g_TileList, s_TileList);
cmd.DispatchCompute(deferredComputeShader, kernel, s_DispatchIndirectBuffer, (uint)variant * 3 * sizeof(uint));
}
else
{
cmd.DispatchCompute(deferredComputeShader, kernel, numTilesX, numTilesY, 1);
}
if (enableFeatureVariants)
{
cmd.SetComputeIntParam(deferredComputeShader, HDShaderIDs.g_TileListOffset, variant * numTiles);
cmd.SetComputeBufferParam(deferredComputeShader, kernel, HDShaderIDs.g_TileList, s_TileList);
cmd.DispatchCompute(deferredComputeShader, kernel, s_DispatchIndirectBuffer, (uint)variant * 3 * sizeof(uint));
}
else
{
cmd.DispatchCompute(deferredComputeShader, kernel, numTilesX, numTilesY, 1);
}
else // Pixel shader evaluation
{
// OUTPUT_SPLIT_LIGHTING - LIGHTLOOP_TILE_PASS - SHADOWS_SHADOWMASK - USE_FPTL_LIGHTLIST/USE_CLUSTERED_LIGHTLIST - DEBUG_DISPLAY
Material currentLightingMaterial = m_lightingMaterial[options.outputSplitLighting ? 1 : 0,
m_TileSettings.enableTileAndCluster ? 1 : 0,
m_enableBakeShadowMask ? 1 : 0,
bUseClusteredForDeferred ? 1 : 0,
debugDisplaySettings.IsDebugDisplayEnabled() ? 1 : 0];
PushGlobalParams(camera, cmd, null, 0);
if (options.outputSplitLighting)
{
CoreUtils.DrawFullScreen(cmd, currentLightingMaterial, colorBuffers, depthStencilBuffer);
}
// Pixel shader evaluation
PushGlobalParams(camera, cmd, null, 0);
if (options.outputSplitLighting)
// If SSS is disable, do lighting for both split lighting and no split lighting
// This is for debug purpose, so fine to use immediate material mode here to modify render state
if (!debugDisplaySettings.renderingDebugSettings.enableSSSAndTransmission)
CoreUtils.SelectKeyword(m_DeferredAllMaterialMRT, "USE_CLUSTERED_LIGHTLIST", "USE_FPTL_LIGHTLIST", bUseClusteredForDeferred);
CoreUtils.DrawFullScreen(cmd, m_DeferredAllMaterialMRT, colorBuffers, depthStencilBuffer);
currentLightingMaterial.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.NoLighting);
currentLightingMaterial.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.NotEqual);
// If SSS is disable, do lighting for both split lighting and no split lighting
if (!debugDisplaySettings.renderingDebugSettings.enableSSSAndTransmission)
{
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.NoLighting);
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.NotEqual);
}
else
{
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.RegularLighting);
m_DeferredAllMaterialSRT.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
}
currentLightingMaterial.SetInt(HDShaderIDs._StencilRef, (int)StencilLightingUsage.RegularLighting);
currentLightingMaterial.SetInt(HDShaderIDs._StencilCmp, (int)CompareFunction.Equal);
}
CoreUtils.SelectKeyword(m_DeferredAllMaterialSRT, "USE_CLUSTERED_LIGHTLIST", "USE_FPTL_LIGHTLIST", bUseClusteredForDeferred);
CoreUtils.DrawFullScreen(cmd, m_DeferredAllMaterialSRT, colorBuffers[0], depthStencilBuffer);
}
CoreUtils.DrawFullScreen(cmd, currentLightingMaterial, colorBuffers[0], depthStencilBuffer);
} // TilePass - Deferred Lighting Pass
} // End profiling
// Note: SHADOWS_SHADOWMASK keyword is enabled in HDRenderPipeline.cs ConfigureForShadowMask
// Note: if we use render opaque with deferred tiling we need to render a opaque depth pass for these opaque objects
if (!m_TileSettings.enableTileAndCluster)

18
ScriptableRenderPipeline/HDRenderPipeline/Lighting/TilePass/TilePassLoop.hlsl
查看文件


#endif // LIGHTLOOP_TILE_PASS
// bakeDiffuseLighting is part of the prototype so a user is able to implement a "base pass" with GI and multipass direct light (aka old unity rendering path)
void LightLoop( float3 V, PositionInputs posInput, PreLightData preLightData, BSDFData bsdfData, float3 bakeDiffuseLighting, uint featureFlags,
void LightLoop( float3 V, PositionInputs posInput, PreLightData preLightData, BSDFData bsdfData, BakeLightingData bakeLightingData, uint featureFlags,
out float3 diffuseLighting,
out float3 specularLighting)
{

{
for (i = 0; i < _DirectionalLightCount; ++i)
{
DirectLighting lighting = EvaluateBSDF_Directional(context, V, posInput, preLightData, _DirectionalLightDatas[i], bsdfData);
DirectLighting lighting = EvaluateBSDF_Directional(context, V, posInput, preLightData, _DirectionalLightDatas[i], bsdfData, bakeLightingData);
AccumulateDirectLighting(lighting, aggregateLighting);
}
}

for (i = 0; i < punctualLightCount; ++i)
{
int punctualIndex = FetchIndex(punctualLightStart, i);
DirectLighting lighting = EvaluateBSDF_Punctual(context, V, posInput, preLightData, _LightDatas[punctualIndex], bsdfData, _LightDatas[punctualIndex].lightType);
DirectLighting lighting = EvaluateBSDF_Punctual(context, V, posInput, preLightData, _LightDatas[punctualIndex], bsdfData, bakeLightingData, _LightDatas[punctualIndex].lightType);
AccumulateDirectLighting(lighting, aggregateLighting);
}

{
DirectLighting lighting = EvaluateBSDF_Punctual(context, V, posInput, preLightData, _LightDatas[i], bsdfData, _LightDatas[i].lightType);
DirectLighting lighting = EvaluateBSDF_Punctual(context, V, posInput, preLightData, _LightDatas[i], bsdfData, bakeLightingData, _LightDatas[i].lightType);
AccumulateDirectLighting(lighting, aggregateLighting);
}

while (i < areaLightCount && lightType == GPULIGHTTYPE_LINE)
{
DirectLighting lighting = EvaluateBSDF_Area(context, V, posInput, preLightData, _LightDatas[areaIndex], bsdfData, GPULIGHTTYPE_LINE);
DirectLighting lighting = EvaluateBSDF_Area(context, V, posInput, preLightData, _LightDatas[areaIndex], bsdfData, bakeLightingData, GPULIGHTTYPE_LINE);
i++;
areaIndex = i < areaLightCount ? FetchIndex(areaLightStart, i) : 0;
lightType = i < areaLightCount ? _LightDatas[areaIndex].lightType : 0xFF;

{
DirectLighting lighting = EvaluateBSDF_Area(context, V, posInput, preLightData, _LightDatas[areaIndex], bsdfData, GPULIGHTTYPE_RECTANGLE);
DirectLighting lighting = EvaluateBSDF_Area(context, V, posInput, preLightData, _LightDatas[areaIndex], bsdfData, bakeLightingData, GPULIGHTTYPE_RECTANGLE);
AccumulateDirectLighting(lighting, aggregateLighting);
i++;

for (i = _PunctualLightCount; i < _PunctualLightCount + _AreaLightCount; ++i)
{
DirectLighting lighting = EvaluateBSDF_Area(context, V, posInput, preLightData, _LightDatas[i], bsdfData, _LightDatas[i].lightType);
DirectLighting lighting = EvaluateBSDF_Area(context, V, posInput, preLightData, _LightDatas[i], bsdfData, bakeLightingData, _LightDatas[i].lightType);
AccumulateDirectLighting(lighting, aggregateLighting);
}

// Also Apply indiret diffuse (GI)
// PostEvaluateBSDF will perform any operation wanted by the material and sum everything into diffuseLighting and specularLighting
PostEvaluateBSDF( context, V, posInput, preLightData, bsdfData, bakeDiffuseLighting, aggregateLighting,
PostEvaluateBSDF( context, V, posInput, preLightData, bsdfData, bakeLightingData, aggregateLighting,
diffuseLighting, specularLighting);
ApplyDebug(context, posInput.positionWS, diffuseLighting, specularLighting);

21
ScriptableRenderPipeline/HDRenderPipeline/Material/Builtin/BuiltinData.cs
查看文件


[SurfaceDataAttributes("Bake Diffuse Lighting", false, true)]
public Vector3 bakeDiffuseLighting; // This is the result of sampling lightmap/lightprobe/proxyvolume
// Use for float instead of vector4 to ease the debug (no performance impact)
// Note: We have no way to remove these value automatically based on either SHADEROPTIONS_BAKED_SHADOW_MASK_ENABLE or s_BakedShadowMaskEnable here. Unless we make two structure... For now always keep this value
[SurfaceDataAttributes("Shadow Mask 0")]
public float shadowMask0;
[SurfaceDataAttributes("Shadow Mask 1")]
public float shadowMask1;
[SurfaceDataAttributes("Shadow Mask 2")]
public float shadowMask2;
[SurfaceDataAttributes("Shadow Mask 3")]
public float shadowMask3;
[SurfaceDataAttributes("Emissive Color", false, true)]
public Vector3 emissiveColor;
[SurfaceDataAttributes("Emissive Intensity")]

public Vector3 diffuseColor;
public Vector3 emissiveColor; // HDR value
};
public static RenderTextureFormat GetShadowMaskBufferFormat()
{
return RenderTextureFormat.ARGB32;
}
public static RenderTextureReadWrite GetShadowMaskBufferReadWrite()
{
return RenderTextureReadWrite.Linear;
}
public static RenderTextureFormat GetVelocityBufferFormat()
{

32
ScriptableRenderPipeline/HDRenderPipeline/Material/Builtin/BuiltinData.cs.hlsl
查看文件


//
#define DEBUGVIEW_BUILTIN_BUILTINDATA_OPACITY (100)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_BAKE_DIFFUSE_LIGHTING (101)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_EMISSIVE_COLOR (102)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_EMISSIVE_INTENSITY (103)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_VELOCITY (104)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_DISTORTION (105)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_DISTORTION_BLUR (106)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_DEPTH_OFFSET (107)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK0 (102)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK1 (103)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK2 (104)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK3 (105)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_EMISSIVE_COLOR (106)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_EMISSIVE_INTENSITY (107)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_VELOCITY (108)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_DISTORTION (109)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_DISTORTION_BLUR (110)
#define DEBUGVIEW_BUILTIN_BUILTINDATA_DEPTH_OFFSET (111)
//
// UnityEngine.Experimental.Rendering.HDPipeline.Builtin+LightTransportData: static fields

{
float opacity;
float3 bakeDiffuseLighting;
float shadowMask0;
float shadowMask1;
float shadowMask2;
float shadowMask3;
float3 emissiveColor;
float emissiveIntensity;
float2 velocity;

case DEBUGVIEW_BUILTIN_BUILTINDATA_BAKE_DIFFUSE_LIGHTING:
result = builtindata.bakeDiffuseLighting;
needLinearToSRGB = true;
break;
case DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK0:
result = builtindata.shadowMask0.xxx;
break;
case DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK1:
result = builtindata.shadowMask1.xxx;
break;
case DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK2:
result = builtindata.shadowMask2.xxx;
break;
case DEBUGVIEW_BUILTIN_BUILTINDATA_SHADOW_MASK3:
result = builtindata.shadowMask3.xxx;
break;
case DEBUGVIEW_BUILTIN_BUILTINDATA_EMISSIVE_COLOR:
result = builtindata.emissiveColor;

25
ScriptableRenderPipeline/HDRenderPipeline/Material/Builtin/BuiltinData.hlsl
查看文件


//-----------------------------------------------------------------------------
// common Encode/Decode functions
//-----------------------------------------------------------------------------
struct BakeLightingData
{
float3 bakeDiffuseLighting;
#ifdef SHADOWS_SHADOWMASK
float4 bakeShadowMask;
#endif
};
// Guideline for velocity buffer.
// We support various architecture for HDRenderPipeline
// - Forward only rendering

// - Same velocity buffer is use for all scenario, so if deferred define a velocity buffer, the same is reuse for forward case.
// For these reasons we chose to avoid to pack velocity buffer with anything else in case of PackgbufferInFP16 (and also in case the format change)
// Encode/Decode velocity/distortion in a buffer (either forward of deferred)
// Encode/Decode shadowmask/velocity/distortion in a buffer (either forward of deferred)
// Design note: We assume that shadowmask/velocity/distortion fit into a single buffer (i.e not spread on several buffer)
void EncodeShadowMask(float4 shadowMask, out float4 outBuffer)
{
// RT - RGBA
outBuffer = shadowMask;
}
void DecodeShadowMask(float4 inBuffer, out float4 shadowMask)
{
shadowMask = inBuffer;
}
// Design note: We assume that velocity/distortion fit into a single buffer (i.e not spread on several buffer)
void EncodeVelocity(float2 velocity, out float4 outBuffer)
{

break;
case DEBUGVIEW_BUILTIN_BUILTINDATA_DEPTH_OFFSET:
result = builtinData.depthOffset.xxx * 10.0; // * 10 assuming 1 unity is 1m
break;
break;
case DEBUGVIEW_BUILTIN_BUILTINDATA_DISTORTION:
result = float3((builtinData.distortion / (abs(builtinData.distortion) + 1) + 1) * 0.5, 0.5);
break;

33
ScriptableRenderPipeline/HDRenderPipeline/Material/LayeredLit/LayeredLit.shader
查看文件


// Note _MATID_STANDARD is not define as there is always the default case "_". We assign default as _MATID_STANDARD, so we never test _MATID_STANDARD
#pragma shader_feature _ _MATID_SSS
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
// enable dithering LOD crossfade
#pragma multi_compile _ LOD_FADE_CROSSFADE
// TODO: We should have this keyword only if VelocityInGBuffer is enable, how to do that ?

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#include "../../ShaderVariables.hlsl"
#include "../../Material/Material.hlsl"

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#define SHADERPASS_GBUFFER_BYPASS_ALPHA_TEST
#include "../../ShaderVariables.hlsl"

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define DEBUG_DISPLAY
#define SHADERPASS SHADERPASS_GBUFFER
#include "../../ShaderVariables.hlsl"

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
// TEMP until pragma work in include
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#include "../../Lighting/Lighting.hlsl"
#include "../Lit/ShaderPass/LitSharePass.hlsl"
#include "LayeredLitData.hlsl"

Cull[_CullMode]
HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#define DEBUG_DISPLAY
#define SHADERPASS SHADERPASS_FORWARD

36
ScriptableRenderPipeline/HDRenderPipeline/Material/LayeredLit/LayeredLitTessellation.shader
查看文件


// Note _MATID_STANDARD is not define as there is always the default case "_". We assign default as _MATID_STANDARD, so we never test _MATID_STANDARD
#pragma shader_feature _ _MATID_SSS
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
// enable dithering LOD crossfade
#pragma multi_compile _ LOD_FADE_CROSSFADE
// TODO: We should have this keyword only if VelocityInGBuffer is enable, how to do that ?

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#include "../../ShaderVariables.hlsl"
#include "../../Material/Material.hlsl"

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#define SHADERPASS_GBUFFER_BYPASS_ALPHA_TEST
#include "../../ShaderVariables.hlsl"

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define DEBUG_DISPLAY
#define SHADERPASS SHADERPASS_GBUFFER

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
// TEMP until pragma work in include
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#include "../../Lighting/Lighting.hlsl"
#include "../Lit/ShaderPass/LitSharePass.hlsl"
#include "LayeredLitData.hlsl"

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
// TEMP until pragma work in include
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#include "../../Lighting/Lighting.hlsl"
#include "../Lit/ShaderPass/LitSharePass.hlsl"
#include "LayeredLitData.hlsl"

21
ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Lit.cs
查看文件


public override int GetMaterialGBufferCount() { return (int)GBufferMaterial.Count; }
RenderTextureFormat[] m_RTFormat4 = { RenderTextureFormat.ARGB32, RenderTextureFormat.ARGB2101010, RenderTextureFormat.ARGB32, RenderTextureFormat.RGB111110Float };
RenderTextureReadWrite[] m_RTReadWrite4 = { RenderTextureReadWrite.sRGB, RenderTextureReadWrite.Linear, RenderTextureReadWrite.Linear, RenderTextureReadWrite.Linear };
// TODO: Just discovered that Unity doesn't support unsigned 16 RT format.
RenderTextureFormat[] m_RTFormat2 = { RenderTextureFormat.ARGBInt, RenderTextureFormat.ARGBInt };
RenderTextureReadWrite[] m_RTReadWrite2 = { RenderTextureReadWrite.Linear, RenderTextureReadWrite.Linear };
RTFormat = new RenderTextureFormat[(int)GBufferMaterial.Count];
RTReadWrite = new RenderTextureReadWrite[(int)GBufferMaterial.Count];
// TODO: Just discovered that Unity doesn't support unsigned 16 RT format.
RTFormat[0] = RenderTextureFormat.ARGBInt; RTReadWrite[0] = RenderTextureReadWrite.Linear;
RTFormat[1] = RenderTextureFormat.ARGBInt; RTReadWrite[1] = RenderTextureReadWrite.Linear;
RTFormat = m_RTFormat2;
RTReadWrite = m_RTReadWrite2;
RTFormat[0] = RenderTextureFormat.ARGB32; RTReadWrite[0] = RenderTextureReadWrite.sRGB;
RTFormat[1] = RenderTextureFormat.ARGB2101010; RTReadWrite[1] = RenderTextureReadWrite.Linear;
RTFormat[2] = RenderTextureFormat.ARGB32; RTReadWrite[2] = RenderTextureReadWrite.Linear;
RTFormat[3] = RenderTextureFormat.RGB111110Float; RTReadWrite[3] = RenderTextureReadWrite.Linear;
RTFormat = m_RTFormat4;
RTReadWrite = m_RTReadWrite4;
}
}

70
ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Lit.hlsl
查看文件


if (_UseDisneySSS)
{
bsdfData.transmittance = ComputeTransmittance(_ShapeParams[subsurfaceProfile].rgb,
_TransmissionTints[subsurfaceProfile].rgb,
bsdfData.thickness, bsdfData.subsurfaceRadius);
bsdfData.transmittance = ComputeTransmittanceDisney(_ShapeParams[subsurfaceProfile].rgb,
_TransmissionTints[subsurfaceProfile].rgb,
bsdfData.thickness, bsdfData.subsurfaceRadius);
}
else
{

DirectLighting EvaluateBSDF_Directional( LightLoopContext lightLoopContext,
float3 V, PositionInputs posInput, PreLightData preLightData,
DirectionalLightData lightData, BSDFData bsdfData)
DirectionalLightData lightData, BSDFData bsdfData, BakeLightingData bakeLightingData)
{
DirectLighting lighting;
ZERO_INITIALIZE(DirectLighting, lighting);

float NdotL = dot(bsdfData.normalWS, L);
float illuminance = saturate(NdotL);
float shadow = 1.0;
float shadow = 1.0;
float shadowMask = 1.0;
#ifdef SHADOWS_SHADOWMASK
// shadowMaskSelector.x is -1 if there is no shadow mask
// Note that we override shadow value (in case we don't have any dynamic shadow)
shadow = shadowMask = (lightData.shadowMaskSelector.x >= 0.0) ? dot(bakeLightingData.bakeShadowMask, lightData.shadowMaskSelector) : 1.0;
#endif
[branch] if (lightData.shadowIndex >= 0)
{

shadow = LOAD_TEXTURE2D(_DeferredShadowTexture, posInput.unPositionSS).x;
#endif
illuminance *= shadow;
#ifdef SHADOWS_SHADOWMASK
float fade = saturate(posInput.depthVS * lightData.fadeDistanceScaleAndBias.x + lightData.fadeDistanceScaleAndBias.y);
// See comment in EvaluateBSDF_Punctual
shadow = lightData.dynamicShadowCasterOnly ? min(shadowMask, shadow) : shadow;
shadow = lerp(shadow, shadowMask, fade); // Caution to lerp parameter: fade is the reverse of shadowDimmer
// Note: There is no shadowDimmer when there is no shadow mask
#endif
illuminance *= shadow;
[branch] if (lightData.cookieIndex >= 0)
{

DirectLighting EvaluateBSDF_Punctual( LightLoopContext lightLoopContext,
float3 V, PositionInputs posInput,
PreLightData preLightData, LightData lightData, BSDFData bsdfData, int GPULightType)
PreLightData preLightData, LightData lightData, BSDFData bsdfData, BakeLightingData bakeLightingData, int GPULightType)
{
DirectLighting lighting;
ZERO_INITIALIZE(DirectLighting, lighting);

lightData.specularScale *= attenuation;
float shadow = 1.0;
float shadowMask = 1.0;
#ifdef SHADOWS_SHADOWMASK
// shadowMaskSelector.x is -1 if there is no shadow mask
// Note that we override shadow value (in case we don't have any dynamic shadow)
shadow = shadowMask = (lightData.shadowMaskSelector.x >= 0.0) ? dot(bakeLightingData.bakeShadowMask, lightData.shadowMaskSelector) : 1.0;
#endif
[branch] if (lightData.shadowIndex >= 0)
{

shadow = GetPunctualShadowAttenuation(lightLoopContext.shadowContext, positionWS + offset, bsdfData.normalWS, lightData.shadowIndex, L_dist, posInput.unPositionSS);
#ifdef SHADOWS_SHADOWMASK
// Note: Legacy Unity have two shadow mask mode. ShadowMask (ShadowMask contain static objects shadow and ShadowMap contain only dynamic objects shadow, final result is the minimun of both value)
// and ShadowMask_Distance (ShadowMask contain static objects shadow and ShadowMap contain everything and is blend with ShadowMask based on distance (Global distance setup in QualitySettigns)).
// HDRenderPipeline change this behavior. Only ShadowMask mode is supported but we support both blend with distance AND minimun of both value. Distance is control by light.
// The following code do this.
// The min handle the case of having only dynamic objects in the ShadowMap
// The second case for blend with distance is handled with ShadowDimmer. ShadowDimmer is define manually and by shadowDistance by light.
// With distance, ShadowDimmer become one and only the ShadowMask appear, we get the blend with distance behavior.
shadow = lightData.dynamicShadowCasterOnly ? min(shadowMask, shadow) : shadow;
shadow = lerp(shadowMask, shadow, lightData.shadowDimmer);
#else
illuminance *= shadow;
#endif
illuminance *= shadow;
// Projector lights always have a cookies, so we can perform clipping inside the if().
[branch] if (lightData.cookieIndex >= 0)

DirectLighting EvaluateBSDF_Line( LightLoopContext lightLoopContext,
float3 V, PositionInputs posInput,
PreLightData preLightData, LightData lightData, BSDFData bsdfData)
PreLightData preLightData, LightData lightData, BSDFData bsdfData, BakeLightingData bakeLightingData)
{
DirectLighting lighting;
ZERO_INITIALIZE(DirectLighting, lighting);

axis, invAspectRatio);
// Terminate if the shaded point is too far away.
if (intensity == 0.0)
if (intensity == 0.0)
return lighting;
lightData.diffuseScale *= intensity;

DirectLighting EvaluateBSDF_Rect( LightLoopContext lightLoopContext,
float3 V, PositionInputs posInput,
PreLightData preLightData, LightData lightData, BSDFData bsdfData)
PreLightData preLightData, LightData lightData, BSDFData bsdfData, BakeLightingData bakeLightingData)
{
DirectLighting lighting;
ZERO_INITIALIZE(DirectLighting, lighting);

#endif
// Terminate if the shaded point is too far away.
if (intensity == 0.0)
if (intensity == 0.0)
return lighting;
lightData.diffuseScale *= intensity;

DirectLighting EvaluateBSDF_Area( LightLoopContext lightLoopContext,
float3 V, PositionInputs posInput,
PreLightData preLightData, LightData lightData, BSDFData bsdfData, int GPULightType)
PreLightData preLightData, LightData lightData, BSDFData bsdfData, BakeLightingData bakeLightingData, int GPULightType)
return EvaluateBSDF_Line(lightLoopContext, V, posInput, preLightData, lightData, bsdfData);
return EvaluateBSDF_Line(lightLoopContext, V, posInput, preLightData, lightData, bsdfData, bakeLightingData);
return EvaluateBSDF_Rect(lightLoopContext, V, posInput, preLightData, lightData, bsdfData);
return EvaluateBSDF_Rect(lightLoopContext, V, posInput, preLightData, lightData, bsdfData, bakeLightingData);
}
}

void PostEvaluateBSDF( LightLoopContext lightLoopContext,
float3 V, PositionInputs posInput,
PreLightData preLightData, BSDFData bsdfData, float3 bakeDiffuseLighting, AggregateLighting lighting,
PreLightData preLightData, BSDFData bsdfData, BakeLightingData bakeLightingData, AggregateLighting lighting,
float3 bakeDiffuseLighting = bakeLightingData.bakeDiffuseLighting;
// Use GTAOMultiBounce approximation for ambient occlusion (allow to get a tint from the baseColor)
#define GTAO_MULTIBOUNCE_APPROX 1

38
ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Lit.shader
查看文件


#pragma shader_feature _SUBSURFACE_RADIUS_MAP
#pragma shader_feature _THICKNESSMAP
#pragma shader_feature _SPECULARCOLORMAP
#pragma shader_feature _TRANSMITTANCECOLORMAP
#pragma shader_feature _TRANSMITTANCECOLORMAP
// Keyword for transparent
#pragma shader_feature _SURFACE_TYPE_TRANSPARENT

// Note _MATID_STANDARD is not define as there is always the default case "_". We assign default as _MATID_STANDARD, so we never test _MATID_STANDARD
#pragma shader_feature _ _MATID_SSS _MATID_ANISO _MATID_SPECULAR _MATID_CLEARCOAT
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
// enable dithering LOD crossfade
#pragma multi_compile _ LOD_FADE_CROSSFADE
// TODO: We should have this keyword only if VelocityInGBuffer is enable, how to do that ?

}
HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#include "../../ShaderVariables.hlsl"

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#define SHADERPASS_GBUFFER_BYPASS_ALPHA_TEST
#include "../../ShaderVariables.hlsl"

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define DEBUG_DISPLAY
#define SHADERPASS SHADERPASS_GBUFFER
#include "../../ShaderVariables.hlsl"

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
// TEMP until pragma work in include
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#include "../../Lighting/Lighting.hlsl"
#include "ShaderPass/LitSharePass.hlsl"
#include "LitData.hlsl"

HLSLPROGRAM
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
// TEMP until pragma work in include
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#include "../../Lighting/Lighting.hlsl"
#include "ShaderPass/LitSharePass.hlsl"
#include "LitData.hlsl"

13
ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/LitData.hlsl
查看文件


builtinData.bakeDiffuseLighting += SampleBakedGI(input.positionWS, -input.worldToTangent[2], input.texCoord1, input.texCoord2) * bsdfData.transmittance;
}
#ifdef SHADOWS_SHADOWMASK
float4 shadowMask = SampleShadowMask(input.positionWS, input.texCoord1);
builtinData.shadowMask0 = shadowMask.x;
builtinData.shadowMask1 = shadowMask.y;
builtinData.shadowMask2 = shadowMask.z;
builtinData.shadowMask3 = shadowMask.w;
#else
builtinData.shadowMask0 = 0.0;
builtinData.shadowMask1 = 0.0;
builtinData.shadowMask2 = 0.0;
builtinData.shadowMask3 = 0.0;
#endif
// Emissive Intensity is only use here, but is part of BuiltinData to enforce UI parameters as we want the users to fill one color and one intensity
builtinData.emissiveIntensity = _EmissiveIntensity; // We still store intensity here so we can reuse it with debug code

36
ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/LitTessellation.shader
查看文件


// Note _MATID_STANDARD is not define as there is always the default case "_". We assign default as _MATID_STANDARD, so we never test _MATID_STANDARD
#pragma shader_feature _ _MATID_SSS _MATID_ANISO _MATID_SPECULAR _MATID_CLEARCOAT
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
// enable dithering LOD crossfade
#pragma multi_compile _ LOD_FADE_CROSSFADE
// TODO: We should have this keyword only if VelocityInGBuffer is enable, how to do that ?

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#include "../../ShaderVariables.hlsl"
#include "../../Material/Material.hlsl"

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define SHADERPASS SHADERPASS_GBUFFER
#define SHADERPASS_GBUFFER_BYPASS_ALPHA_TEST
#include "../../ShaderVariables.hlsl"

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#define DEBUG_DISPLAY
#define SHADERPASS SHADERPASS_GBUFFER

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
// TEMP until pragma work in include
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#include "../../Lighting/Lighting.hlsl"
#include "ShaderPass/LitSharePass.hlsl"
#include "LitData.hlsl"

#pragma hull Hull
#pragma domain Domain
#pragma multi_compile LIGHTMAP_OFF LIGHTMAP_ON
#pragma multi_compile DIRLIGHTMAP_OFF DIRLIGHTMAP_COMBINED
#pragma multi_compile DYNAMICLIGHTMAP_OFF DYNAMICLIGHTMAP_ON
#pragma multi_compile _ SHADOWS_SHADOWMASK
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
// TEMP until pragma work in include
#pragma multi_compile LIGHTLOOP_SINGLE_PASS LIGHTLOOP_TILE_PASS
#include "../../Lighting/Lighting.hlsl"
#include "ShaderPass/LitSharePass.hlsl"
#include "LitData.hlsl"

7
ScriptableRenderPipeline/HDRenderPipeline/Material/Lit/Resources/SubsurfaceScattering.compute
查看文件


// We can drop the constant (s / (8 * Pi)) due to the subsequent weight renormalization.
float3 DisneyProfilePolar(float r, float3 S)
{
#if 0
#else
// Help the compiler.
float k = (-1.0 / 3.0) * LOG2_E;
float3 p = (k * r) * S;
float3 expOneThird = exp2(p);
#endif
return expOneThird + expOneThird * expOneThird * expOneThird;
}

93
ScriptableRenderPipeline/HDRenderPipeline/Material/Material.hlsl
查看文件


#define DECODE_FROM_GBUFFER(NAME, FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING) DecodeFromGBuffer(MERGE_NAME(NAME,0), MERGE_NAME(NAME,1), FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING)
#define MATERIAL_FEATURE_FLAGS_FROM_GBUFFER(NAME) MaterialFeatureFlagsFromGBuffer(MERGE_NAME(NAME,0), MERGE_NAME(NAME,1))
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target2
#ifdef SHADOWS_SHADOWMASK
#define OUTPUT_GBUFFER_SHADOWMASK(NAME) ,out float4 NAME : SV_Target2
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target3
#endif
#else
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target2
#endif
#endif
#elif GBUFFERMATERIAL_COUNT == 3

#define DECODE_FROM_GBUFFER(NAME, FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING) DecodeFromGBuffer(MERGE_NAME(NAME,0), MERGE_NAME(NAME,1), MERGE_NAME(NAME,2), FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING)
#define MATERIAL_FEATURE_FLAGS_FROM_GBUFFER(NAME) MaterialFeatureFlagsFromGBuffer(MERGE_NAME(NAME,0), MERGE_NAME(NAME,1), MERGE_NAME(NAME,2))
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target3
#ifdef SHADOWS_SHADOWMASK
#define OUTPUT_GBUFFER_SHADOWMASK(NAME) ,out float4 NAME : SV_Target3
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target4
#endif
#else
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target3
#endif
#endif
#elif GBUFFERMATERIAL_COUNT == 4

#define DECODE_FROM_GBUFFER(NAME, FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING) DecodeFromGBuffer(MERGE_NAME(NAME, 0), MERGE_NAME(NAME, 1), MERGE_NAME(NAME, 2), MERGE_NAME(NAME, 3), FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING)
#define MATERIAL_FEATURE_FLAGS_FROM_GBUFFER(NAME) MaterialFeatureFlagsFromGBuffer(MERGE_NAME(NAME, 0), MERGE_NAME(NAME, 1), MERGE_NAME(NAME, 2), MERGE_NAME(NAME, 3))
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target4
#ifdef SHADOWS_SHADOWMASK
#define OUTPUT_GBUFFER_SHADOWMASK(NAME) ,out float4 NAME : SV_Target4
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target5
#endif
#else
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target4
#endif
#endif
#elif GBUFFERMATERIAL_COUNT == 5

#define DECODE_FROM_GBUFFER(NAME, FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING) DecodeFromGBuffer(MERGE_NAME(NAME, 0), MERGE_NAME(NAME, 1), MERGE_NAME(NAME, 2), MERGE_NAME(NAME, 3), MERGE_NAME(NAME, 4), FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING)
#define MATERIAL_FEATURE_FLAGS_FROM_GBUFFER(NAME) MaterialFeatureFlagsFromGBuffer(MERGE_NAME(NAME, 0), MERGE_NAME(NAME, 1), MERGE_NAME(NAME, 2), MERGE_NAME(NAME, 3), MERGE_NAME(NAME, 4))
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target5
#ifdef SHADOWS_SHADOWMASK
#define OUTPUT_GBUFFER_SHADOWMASK(NAME) ,out float4 NAME : SV_Target5
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target6
#endif
#else
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target5
#endif
#endif
#elif GBUFFERMATERIAL_COUNT == 6
#define OUTPUT_GBUFFER(NAME) \
out GBufferType0 MERGE_NAME(NAME, 0) : SV_Target0, \
out GBufferType1 MERGE_NAME(NAME, 1) : SV_Target1, \
out GBufferType2 MERGE_NAME(NAME, 2) : SV_Target2, \
out GBufferType3 MERGE_NAME(NAME, 3) : SV_Target3, \
out GBufferType4 MERGE_NAME(NAME, 4) : SV_Target4, \
out GBufferType5 MERGE_NAME(NAME, 5) : SV_Target5
#define DECLARE_GBUFFER_TEXTURE(NAME) \
TEXTURE2D(MERGE_NAME(NAME, 0)); \
TEXTURE2D(MERGE_NAME(NAME, 1)); \
TEXTURE2D(MERGE_NAME(NAME, 2)); \
TEXTURE2D(MERGE_NAME(NAME, 3)); \
TEXTURE2D(MERGE_NAME(NAME, 4)); \
TEXTURE2D(MERGE_NAME(NAME, 5));
#define FETCH_GBUFFER(NAME, TEX, unCoord2) \
GBufferType0 MERGE_NAME(NAME, 0) = LOAD_TEXTURE2D(MERGE_NAME(TEX, 0), unCoord2); \
GBufferType1 MERGE_NAME(NAME, 1) = LOAD_TEXTURE2D(MERGE_NAME(TEX, 1), unCoord2); \
GBufferType2 MERGE_NAME(NAME, 2) = LOAD_TEXTURE2D(MERGE_NAME(TEX, 2), unCoord2); \
GBufferType3 MERGE_NAME(NAME, 3) = LOAD_TEXTURE2D(MERGE_NAME(TEX, 3), unCoord2); \
GBufferType4 MERGE_NAME(NAME, 4) = LOAD_TEXTURE2D(MERGE_NAME(TEX, 4), unCoord2); \
GBufferType5 MERGE_NAME(NAME, 5) = LOAD_TEXTURE2D(MERGE_NAME(TEX, 5), unCoord2);
#define ENCODE_INTO_GBUFFER(SURFACE_DATA, BAKE_DIFFUSE_LIGHTING, NAME) EncodeIntoGBuffer(SURFACE_DATA, BAKE_DIFFUSE_LIGHTING, MERGE_NAME(NAME, 0), MERGE_NAME(NAME, 1), MERGE_NAME(NAME, 2), MERGE_NAME(NAME, 3), MERGE_NAME(NAME, 4), MERGE_NAME(NAME, 5))
#define DECODE_FROM_GBUFFER(NAME, FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING) DecodeFromGBuffer(MERGE_NAME(NAME, 0), MERGE_NAME(NAME, 1), MERGE_NAME(NAME, 2), MERGE_NAME(NAME, 3), MERGE_NAME(NAME, 4), MERGE_NAME(NAME, 5), FEATURE_FLAGS, BSDF_DATA, BAKE_DIFFUSE_LIGHTING)
#define MATERIAL_FEATURE_FLAGS_FROM_GBUFFER(NAME) MaterialFeatureFlagsFromGBuffer(MERGE_NAME(NAME, 0), MERGE_NAME(NAME, 1), MERGE_NAME(NAME, 2), MERGE_NAME(NAME, 3), MERGE_NAME(NAME, 4), MERGE_NAME(NAME, 5))
#ifdef SHADOWS_SHADOWMASK
#define OUTPUT_GBUFFER_SHADOWMASK(NAME) ,out float4 NAME : SV_Target6
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target7
#endif
#else
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER
#define OUTPUT_GBUFFER_VELOCITY(NAME) ,out float4 NAME : SV_Target6
#endif
#endif
#ifdef SHADOWS_SHADOWMASK
#define ENCODE_SHADOWMASK_INTO_GBUFFER(SHADOWMASK, NAME) EncodeShadowMask(SHADOWMASK, NAME)
#else
#define OUTPUT_GBUFFER_SHADOWMASK(NAME)
#define ENCODE_SHADOWMASK_INTO_GBUFFER(SHADOWMASK, NAME)
#endif
#if SHADEROPTIONS_VELOCITY_IN_GBUFFER

23
ScriptableRenderPipeline/HDRenderPipeline/Material/MaterialUtilities.hlsl
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#endif
}
float4 SampleShadowMask(float3 positionWS, float2 uvStaticLightmap) // normalWS not use for now
{
#if defined(LIGHTMAP_ON)
float2 uv = uvStaticLightmap * unity_LightmapST.xy + unity_LightmapST.zw;
float4 rawOcclusionMask = SAMPLE_TEXTURE2D(unity_ShadowMask, samplerunity_Lightmap, uv); // Reuse sampler from Lightmap
#else
float4 rawOcclusionMask;
if (unity_ProbeVolumeParams.x == 1.0)
{
// TODO: We use GetAbsolutePositionWS(positionWS) to handle the camera relative case here but this should be part of the unity_ProbeVolumeWorldToObject matrix on C++ side (sadly we can't modify it for HDRenderPipeline...)
rawOcclusionMask = SampleProbeOcclusion(TEXTURE3D_PARAM(unity_ProbeVolumeSH, samplerunity_ProbeVolumeSH), GetAbsolutePositionWS(positionWS), unity_ProbeVolumeWorldToObject,
unity_ProbeVolumeParams.y, unity_ProbeVolumeParams.z, unity_ProbeVolumeMin, unity_ProbeVolumeSizeInv);
}
else
{
// Note: Default value when the feature is not enabled is float(1.0, 1.0, 1.0, 1.0) in C++
rawOcclusionMask = unity_ProbesOcclusion;
}
#endif
return rawOcclusionMask;
}
float2 CalculateVelocity(float4 positionCS, float4 previousPositionCS)
{
// This test on define is required to remove warning of divide by 0 when initializing empty struct

5
ScriptableRenderPipeline/HDRenderPipeline/Material/Unlit/UnlitData.hlsl
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builtinData.velocity = float2(0.0, 0.0);
builtinData.shadowMask0 = 0.0;
builtinData.shadowMask1 = 0.0;
builtinData.shadowMask2 = 0.0;
builtinData.shadowMask3 = 0.0;
#if (SHADERPASS == SHADERPASS_DISTORTION) || defined(DEBUG_DISPLAY)
float3 distortion = SAMPLE_TEXTURE2D(_DistortionVectorMap, sampler_DistortionVectorMap, input.texCoord0).rgb * 2.0 - 1.0;
builtinData.distortion = distortion.rg * _DistortionScale;

2
ScriptableRenderPipeline/HDRenderPipeline/SceneSettings/Resources/DrawTransmittanceGraph.shader
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if (_UseDisneySSS)
{
T = ComputeTransmittance(_ShapeParam.rgb, float3(0.25, 0.25, 0.25), d, 1);
T = ComputeTransmittanceDisney(_ShapeParam.rgb, float3(0.25, 0.25, 0.25), d, 1);
}
else
{

9
ScriptableRenderPipeline/HDRenderPipeline/ShaderPass/ShaderPassForward.hlsl
查看文件


#endif
float3 diffuseLighting;
float3 specularLighting;
float3 bakeDiffuseLighting = GetBakedDiffuseLigthing(surfaceData, builtinData, bsdfData, preLightData);
LightLoop(V, posInput, preLightData, bsdfData, bakeDiffuseLighting, featureFlags, diffuseLighting, specularLighting);
BakeLightingData bakeLightingData;
bakeLightingData.bakeDiffuseLighting = GetBakedDiffuseLigthing(surfaceData, builtinData, bsdfData, preLightData);
#ifdef SHADOWS_SHADOWMASK
bakeLightingData.bakeShadowMask = float4(builtinData.shadowMask0, builtinData.shadowMask1, builtinData.shadowMask2, builtinData.shadowMask3);
#endif
LightLoop(V, posInput, preLightData, bsdfData, bakeLightingData, featureFlags, diffuseLighting, specularLighting);
outColor = ApplyBlendMode(diffuseLighting, specularLighting, builtinData.opacity);
outColor = EvaluateAtmosphericScattering(posInput, outColor);
}

2
ScriptableRenderPipeline/HDRenderPipeline/ShaderPass/ShaderPassGBuffer.hlsl
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void Frag( PackedVaryingsToPS packedInput,
OUTPUT_GBUFFER(outGBuffer)
OUTPUT_GBUFFER_SHADOWMASK(outShadowMaskBuffer)
OUTPUT_GBUFFER_VELOCITY(outVelocityBuffer)
#ifdef _DEPTHOFFSET_ON
, out float outputDepth : SV_Depth

float3 bakeDiffuseLighting = GetBakedDiffuseLigthing(surfaceData, builtinData, bsdfData, preLightData);
ENCODE_INTO_GBUFFER(surfaceData, bakeDiffuseLighting, outGBuffer);
ENCODE_SHADOWMASK_INTO_GBUFFER(float4(builtinData.shadowMask0, builtinData.shadowMask1, builtinData.shadowMask2, builtinData.shadowMask3), outShadowMaskBuffer);
ENCODE_VELOCITY_INTO_GBUFFER(builtinData.velocity, outVelocityBuffer);
#ifdef _DEPTHOFFSET_ON

6
ScriptableRenderPipeline/HDRenderPipeline/ShaderVariables.hlsl
查看文件


float3 unity_ProbeVolumeSizeInv;
float3 unity_ProbeVolumeMin;
// This contain occlusion factor from 0 to 1 for dynamic objects (no SH here)
float4 unity_ProbesOcclusion;
CBUFFER_END
#if defined(USING_STEREO_MATRICES)

SAMPLER2D(samplerunity_DynamicLightmap);
TEXTURE2D(unity_DynamicDirectionality);
// We can have shadowMask only if we have lightmap, so no sampler
TEXTURE2D(unity_ShadowMask);
// TODO: Change code here so probe volume use only one transform instead of all this parameters!
TEXTURE3D_FLOAT(unity_ProbeVolumeSH);

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