vault backup: 2024-02-21 17:22:42

2024-02-21 17:22:42 +08:00 · 2024-02-21 17:22:42 +08:00 · eff20979fa
commit eff20979fa
parent 415fd0fa8f
8 changed files with 28938 additions and 21855 deletions
--- a/.obsidian/appearance.json
+++ b/.obsidian/appearance.json
@ -12,9 +12,9 @@
    "S - Encoded Icons",
    "S - External Link Icons",
    "S - Kanban",
-    "【日记】Time",
    "【自定义】mytools 样式",
-    "【图标】iconfont"
+    "【图标】iconfont",
+    "【日记】Time"
  ],
  "baseFontSizeAction": false,
  "accentColor": ""
--- a/.obsidian/plugins/obsidian-style-settings/data.json
+++ b/.obsidian/plugins/obsidian-style-settings/data.json
@ -1,11 +1,9 @@
 {
-  "blue-topaz-theme@@light-background-color-files": false,
  "blue-topaz-theme@@style-options-for-calendar-plugin": "style-options-for-calendar-plugin-default",
  "blue-topaz-theme@@background-image-settings-markdown-page-random-options": "background-image-settings-markdown-page-random-blue",
  "blue-topaz-theme@@background-image-settings-markdown-page-random": false,
  "blue-topaz-theme@@remove-file-icons": true,
  "blue-topaz-theme@@color-scheme-options": "color-scheme-options-default",
-  "blue-topaz-theme@@translucent-setting-panel": false,
  "blue-topaz-theme@@background-settings-workplace-background-image": false,
  "checkbox@@check-color": true,
  "blue-topaz-theme@@style-options-for-kanban-plugin-static": "style-options-for-kanban-plugin-static-default",
@ -14,7 +12,6 @@
  "blue-topaz-theme@@print-strong-color@@light": "#820FC0",
  "blue-topaz-theme@@background-image-settings-switch": true,
  "blue-topaz-theme@@hide-vault-name": true,
-  "blue-topaz-theme@@bt-status-off": true,
  "time@@time-color@@light": "#4E62CD",
  "time@@time-color@@dark": "#4E62CD",
  "blue-topaz-theme@@list-style-change-options": "list-no-border",
--- a/.obsidian/plugins/various-complements/data.json
+++ b/.obsidian/plugins/various-complements/data.json
@ -174,6 +174,14 @@
          "lastUpdated": 1708410052197
        }
      }
+    },
+    "gpu": {
+      "gpu": {
+        "internalLink": {
+          "count": 1,
+          "lastUpdated": 1708493734216
+        }
+      }
    }
  }
 }
--- a/.obsidian/themes/Blue
+++ b/.obsidian/themes/Blue
--- a/.obsidian/themes/Blue
+++ b/.obsidian/themes/Blue
@ -0,0 +1,7 @@
+{
+  "name": "Blue Topaz",
+  "version": "2023112601",
+  "minAppVersion": "1.0.0",
+  "author": "WhyI & Pkmer",
+  "authorUrl": "https://github.com/whyt-byte"
+}
--- a/.obsidian/themes/Blue
+++ b/.obsidian/themes/Blue
--- a/03-UnrealEngine/Rendering/RenderFeature/Lumen学习笔记（2）——原理笔记.md
+++ b/03-UnrealEngine/Rendering/RenderFeature/Lumen学习笔记（2）——原理笔记.md
@ -5,8 +5,10 @@ excerpt:
 tags: Lumen
 rating: ⭐
 ---
-
+## 前言
 本文的内容为丛越的知乎文章的知识点浓缩。
+
+**SIGGRAPH2022 Lumen**:https://advances.realtimerendering.com/s2022/SIGGRAPH2022-Advances-Lumen-Wright%20et%20al.pdf
 ## Lumen相关可视化命令
 - r.Lumen.Visualize.CardPlacement 1：开启Lumen Card的显示。
 - r.Lumen.RadianceCache.Visualize 1：开启World Space Probe。
--- a/03-UnrealEngine/Rendering/RenderingPipeline/VirtualTexture学习笔记.md
+++ b/03-UnrealEngine/Rendering/RenderingPipeline/VirtualTexture学习笔记.md
@ -6,7 +6,17 @@ tags:
 rating: ⭐
 ---
 # 前言
- https://zhuanlan.zhihu.com/p/642580472
+- UE4 Runtime Virtual Texture 实现机制及源码解析:https://zhuanlan.zhihu.com/p/143709152
+- UE Virtual Texture图文浅析:https://zhuanlan.zhihu.com/p/642580472
+
+## 相关概念
+- Virtual Texture：虚拟纹理，以下简称 VT
+- Runtime Virtual Texture：UE4 运行时虚拟纹理系统，以下简称 RVT
+- VT feedback：存储当前屏幕像素对应的 VT Page 信息，用于加载 VT 数据。
+- VT Physical Texture：虚拟纹理对应的物理纹理资源
+- PageTable：虚拟纹理页表，用来寻址 VT Physical Texture Page 数据。
+- PageTable Texture：包含虚拟纹理页表数据的纹理资源，通过此纹理资源可查询 Physical Texture Page 信息。有些 VT 系统也叫 Indirection Texture，由于本文分析 UE4 VT 的内容，这里采用 UE4 术语。
+- PageTable Buffer：包含虚拟纹理页表数据内容的 GPU Buffer 资源。

 相关类：
 - URuntimeVirtualTexture（UObject）
@ -23,5 +33,353 @@ https://zhuanlan.zhihu.com/p/575398476
 		- **UHeightfieldMinMaxTexture**
 			- BuildTexture()
 	- FVirtualHeightfieldMeshSceneProxy
+	- FVirtualHeightfieldMeshRendererExtension
+		- AddWork()
+		- **SubmitWork()**
+	- FVirtualTextureFeedbackBuffer 参考[[#Pass1的补充VirtualTextureFeedback]]
 - UNiagaraDataInterfaceLandscape
- URuntimeVirtualTextureComponent
+- UNiagaraDataInterfaceVirtualTexture(**NiagaraDataInterfaceVirtualTextureTemplate.ush**)
+	- GetAttributesValid()
+	- SampleRVTLayer()
+	- SampleRVT()
+- URuntimeVirtualTextureComponent
+
+## VirtualHeightfieldMesh
+首先是MinMaxTexture。全称**UHeightfieldMinMaxTexture**（下简称MinMaxTexture），可以说是整个VHM中最重要的部分之一。它是离线生成的，目的主要是以下几个：
+1. 用作Instance的剔除（遮挡剔除查询＋Frustum剔除）
+2. 用作决定VHM的LOD
+3. 用作平滑VHM的顶点位置
+
+其中比较关键的几个成员变量为：
+- TObjectPtr<class UTexture2D> Texture：BGRA8格式、贴图大小与RVT的Tile数量一致、有全部mipmap。每个像素存储RVT一个Tile中的最小值以及最大值，各为16bit、encode在RGBA的4个通道上。
+- TObjectPtr<class UTexture2D> LodBiasTexture：G8格式、贴图大小与RTV的Tile数量一致、无mipmap。每个像素存储了Texture对应像素周围3x3blur之后的结果。
+- TObjectPtr<class UTexture2D> LodBiasMinMaxTexture：BGRA8格式、贴图大小与RTV的Tile数量一致、有全部mipmap。类似于HZB、每个像素存储LodBiasTexture的最小值以及最大值，各为8bit、存在RG两个通道上。
+- int32 MaxCPULevels：表示共需要在CPU端存储多少层level的数据。
+- TArray`<FVector2D>` TextureData：CPU端存储Texture贴图的数据，共MaxCPULevels层mipmap。
+
+### TextureData的获取
+因此要生成MinMaxTexture、最关键的就是要得到TextureData，其入口函数为位于**HeightfieldMinMaxTextureBuilder.cpp**的**VirtualHeightfieldmesh::BuildMinMaxTexture**中。由于Texture存储的是RVT中每个Tile中最小最大值，因此不难想象到其大致流程可以分为以下几步：
+1. 遍历RVT的每个Tile并绘制到一张中间贴图上，然后计算这张中间纹理的最小最大值、存储至目标贴图对应的位置上；
+2. 为目标贴图生成mipmap；
+3. 将目标贴图回读至CPU、得到TextureData。
+
+将Tile绘制到一张中间贴图使用的是自带的***RuntimeVirtualTexture::RenderPagesStandAlone***函数；计算最小最大值是通过Downsample的方式计算而成。如下图所示为2x2Tiles、4TileSize的RVT，计算Tile0的最小最大值的示意过程图：
+![](https://pic1.zhimg.com/80/v2-77747e03d3ed0c82ac4e5fde77481ef8_720w.webp)
+
+Downsample的ComputeShader为**TMinMaxTextureCS**。遍历计算完每个Tile的最小最大值后，同样通过Downsample为目标贴图生成全mipmap。
+
+最后为了将贴图回读到CPU，先是通过CopyTexture的方式将目标贴图的各个mipmap复制到各自带有CPUReadback Flag的贴图后，再通过MapStagingSurface/UnmapStagingSurface的方式复制到CPU内存上。由于是比较常规的操作，就不过多介绍了。
+
+至此也就得到了带有所有mipmap的CPU端的TextureData，接着将此作为参数调用UHeightfieldMinMaxTexture::BuildTexture以生成剩下的内容（即Texture、LodBiasTexture、LodBiasMinMaxTexture）。
+
+### FVirtualHeightfieldMeshSceneProxy
+至此离线生成的MinMaxTexture介绍完毕，后面都是实时渲染内容的介绍部分。所有内容都围绕着VHM的SceneProxy也就是**FVirtualHeightfieldMeshSceneProxy**展开。
+
+####  遮挡剔除
+> 关于硬件的遮挡剔除用法可以参考DX12的官方sample[[8]](https://zhuanlan.zhihu.com/p/575398476#ref_8)
+
+首先是遮挡剔除部分，VHM做了Tile级别且带有LOD的遮挡剔除。VHM的SceneProxy重写了函数GetOcclusionQueries，函数实现只是简单地返回OcclusionVolumes：
+![](https://pic3.zhimg.com/80/v2-cbd74e7df53d61b693ea76a6e9fcdd52_720w.webp)
+OcclusionVolumes的构建在函数BuildOcclusionVolumes中，其基本思路为取MinMaxTexture中**CPU端的TextureData**的数据、获得每个Tile的高度最小最大值来创建该Tile的Bounds信息。
+
+可以看到OcclusionVolumes是带有Lod的。当然实际上这里的代码的LodIndex不一定从0开始，因为Component中有一项成员变量**NumOcclusionLod**、表示创建多少层mipmap的OcclusionVolumes。另外有一点需要注意的是，NumOcclusionLod默认值为0、也就是说VHM的遮挡剔除默认没有开启。
+![](https://pic4.zhimg.com/80/v2-07fe400ddc004833a8816ba59c124217_720w.webp)
+
+由于VHM需要在ComputePass中动态地构建Instance绘制的IndirectArgs、因此SceneProxy还重写了函数AcceptOcclusionResults，用以获取遮挡剔除的结果。具体是将UE返回的遮挡剔除的结果存在贴图OcclusionTexture上、以便能够作为SRV在后续的Pass中访问：
+```cpp
+void FVirtualHeightfieldMeshSceneProxy::AcceptOcclusionResults(FSceneView const* View, TArray<bool>* Results, int32 ResultsStart, int32 NumResults)
+{
+    // 由于构建IndirectArgs跟SceneProxy不在同一个地方，因此用了一个全局变量来保存遮挡剔除的结果
+    FOcclusionResults& OcclusionResults = GOcclusionResults.Emplace(FOcclusionResultsKey(this, View));
+    OcclusionResults.TextureSize = OcclusionGridSize;
+    OcclusionResults.NumTextureMips = NumOcclusionLods;
+        
+    // 创建贴图，并将遮挡剔除结果Copy至贴图上
+    FRHIResourceCreateInfo CreateInfo(TEXT("VirtualHeightfieldMesh.OcclusionTexture"));
+    OcclusionResults.OcclusionTexture = RHICreateTexture2D(OcclusionGridSize.X, OcclusionGridSize.Y, PF_G8, NumOcclusionLods, 1, TexCreate_ShaderResource, CreateInfo);
+    bool const* Src = Results->GetData() + ResultsStart;
+    FIntPoint Size = OcclusionGridSize;
+    for (int32 MipIndex = 0; MipIndex < NumOcclusionLods; ++MipIndex)
+    {
+        uint32 Stride;
+        uint8* Dst = (uint8*)RHILockTexture2D(OcclusionResults.OcclusionTexture, MipIndex, RLM_WriteOnly, Stride, false);
+        for (int Y = 0; Y < Size.Y; ++Y)
+        {
+            for (int X = 0; X < Size.X; ++X)
+            {
+                Dst[Y * Stride + X] = *(Src++) ? 255 : 0;
+            }
+        }
+        RHIUnlockTexture2D(OcclusionResults.OcclusionTexture, MipIndex, false);
+
+        Size.X = FMath::Max(Size.X / 2, 1);
+        Size.Y = FMath::Max(Size.Y / 2, 1);
+    }       
+}
+```
+
+### 整体思路
+至此就开始真正的VHM的Mesh的数据构建了。为了后续的代码细节能够更加易懂，这里再说明一下VHM构建mesh的整体思路：假设我们有一个工作队列为QueueBuffer，每一项工作就是从QueueBuffer中取出一项工作（更准确地说，取出一个Quad）、对这个Quad判断是否需要进行细化、如果需要细分则将这个Quad细分为4个Quad并塞入QueueBuffer中。
+
+重复这个取出→处理→放回的过程，直到QueueBuffer中没有工作为止。示意图如下：
+
+![](https://pic3.zhimg.com/80/v2-cc719d48e269b018c4acec257c6f09ea_720w.webp)
+
+### RVT相关代码（Pass1：CollectQuad）
+如果不能细分，那么就会增加一个Instance、将其Instance的数据写入RWQuadBuffer中。RWQuadBuffer将会用在后续的CullInstance Pass中，以真正地构建IndirectArgs：
+```c++
+// 无法继续细分的情况
+// 用以后续对RVT进行采样
+uint PhysicalAddress = PageTableTexture.Load(int3(Pos, Level));
+
+InterlockAdd(RWQuadInfo.Write, 1, Write);
+RWQuadBuffer[Write] = Pack(InitQuadRenderItem(Pos, Level, PhysicalAddress, bCull | bOcclude));
+```
+
+> 其中的RWQuadInfo是我编的变量名、实际的代码中并不存在。或者说实际上这里的变量名是RWIndirectArgsBuffer，但是并不是前面所说的用以绘制的IndirectArgs。为了不让大家混淆，这里改了下变量名  
+> 另外也能由此看出的是，VHM也许曾经想过利用IndirectArgs数组来绘制（即DXSample中将符合条件的生成IndirectArgs放进数组中）。但是最后改成的是一个IndirectArgs但是Instance的绘制方式
+
+PS. PageTableTexture的类型为**RHITextuire**。相关Shader代码位于**VirtualHeightfieldMesh.usf**
+
+#### Pass1的补充VirtualTextureFeedback
+不再继续进行细分后、说明后续就要对该Level的RVT进行采样，因此需要处理对应的Feedback信息、让虚幻可以加载对应的Page。shader代码如下图所示：
+![](https://pic2.zhimg.com/80/v2-49057653549e0465a8ae0ec0049cb731_720w.webp)
+
+c++中则要将这个RWFeedbackBuffer喂给虚幻的函数**SubmitVirtualTextureFeedbackBuffer**：
+![](https://pic4.zhimg.com/80/v2-d08c53985729b0d03f5ecf1d317cfc87_720w.webp)
+
+### 相关代码段
+```c++
+FVertexFactoryIntermediates GetVertexFactoryIntermediates(FVertexFactoryInput Input)
+{
+...
+
+// Sample height from virtual texture.  
+VTUniform Uniform = VTUniform_Unpack(VHM.VTPackedUniform);  
+Uniform.vPageBorderSize -= .5f * VHM.PhysicalTextureSize.y; // Half texel offset is used in VT write and in sampling because we want texel locations to match landscape vertices.  
+VTPageTableUniform PageTableUniform = VTPageTableUniform_Unpack(VHM.VTPackedPageTableUniform0, VHM.VTPackedPageTableUniform1);  
+VTPageTableResult VTResult0 = TextureLoadVirtualPageTableLevel(VHM.PageTableTexture, PageTableUniform, NormalizedPos, VTADDRESSMODE_CLAMP, VTADDRESSMODE_CLAMP, floor(SampleLevel));  
+float2 UV0 = VTComputePhysicalUVs(VTResult0, 0, Uniform);  
+float Height0 = VHM.HeightTexture.SampleLevel(VHM.HeightSampler, UV0, 0);  
+VTPageTableResult VTResult1 = TextureLoadVirtualPageTableLevel(VHM.PageTableTexture, PageTableUniform, NormalizedPos, VTADDRESSMODE_CLAMP, VTADDRESSMODE_CLAMP, ceil(SampleLevel));  
+float2 UV1 = VTComputePhysicalUVs(VTResult1, 0, Uniform);  
+float Height1 = VHM.HeightTexture.SampleLevel(VHM.HeightSampler, UV1, 0);  
+float Height = lerp(Height0.x, Height1.x, frac(SampleLevel));
+
+...
+}
+```
+
+渲染线程创建VT的相关逻辑：
+```c++  
+void FVirtualHeightfieldMeshSceneProxy::CreateRenderThreadResources()
+{
+	if (RuntimeVirtualTexture != nullptr)
+	{
+		if (!bCallbackRegistered)
+		{
+			GetRendererModule().AddVirtualTextureProducerDestroyedCallback(RuntimeVirtualTexture->GetProducerHandle(), &OnVirtualTextureDestroyedCB, this);
+			bCallbackRegistered = true;
+		}
+
+		//URuntimeVirtualTexture* RuntimeVirtualTexture;
+		if (RuntimeVirtualTexture->GetMaterialType() == ERuntimeVirtualTextureMaterialType::WorldHeight)
+		{
+			AllocatedVirtualTexture = RuntimeVirtualTexture->GetAllocatedVirtualTexture();
+			NumQuadsPerTileSide = RuntimeVirtualTexture->GetTileSize();
+
+			if (AllocatedVirtualTexture != nullptr)
+			{
+				// Gather vertex factory uniform parameters.
+				FVirtualHeightfieldMeshVertexFactoryParameters UniformParams;
+				UniformParams.PageTableTexture = AllocatedVirtualTexture->GetPageTableTexture(0);
+				UniformParams.HeightTexture = AllocatedVirtualTexture->GetPhysicalTextureSRV(0, false);
+				UniformParams.HeightSampler = TStaticSamplerState<SF_Bilinear>::GetRHI();
+				UniformParams.LodBiasTexture = LodBiasTexture ? LodBiasTexture->GetResource()->TextureRHI : GBlackTexture->TextureRHI;
+				UniformParams.LodBiasSampler = TStaticSamplerState<SF_Point>::GetRHI();
+				UniformParams.NumQuadsPerTileSide = NumQuadsPerTileSide;
+
+				FUintVector4 PackedUniform;
+				AllocatedVirtualTexture->GetPackedUniform(&PackedUniform, 0);
+				UniformParams.VTPackedUniform = PackedUniform;
+				FUintVector4 PackedPageTableUniform[2];
+				AllocatedVirtualTexture->GetPackedPageTableUniform(PackedPageTableUniform);
+				UniformParams.VTPackedPageTableUniform0 = PackedPageTableUniform[0];
+				UniformParams.VTPackedPageTableUniform1 = PackedPageTableUniform[1];
+
+				const float PageTableSizeX = AllocatedVirtualTexture->GetWidthInTiles();
+				const float PageTableSizeY = AllocatedVirtualTexture->GetHeightInTiles();
+				UniformParams.PageTableSize = FVector4f(PageTableSizeX, PageTableSizeY, 1.f / PageTableSizeX, 1.f / PageTableSizeY);
+
+				const float PhysicalTextureSize = AllocatedVirtualTexture->GetPhysicalTextureSize(0);
+				UniformParams.PhysicalTextureSize = FVector2f(PhysicalTextureSize, 1.f / PhysicalTextureSize);
+
+				UniformParams.VirtualHeightfieldToLocal = FMatrix44f(UVToLocal);
+				UniformParams.VirtualHeightfieldToWorld = FMatrix44f(UVToWorld);		// LWC_TODO: Precision loss
+
+				UniformParams.MaxLod = AllocatedVirtualTexture->GetMaxLevel();
+				UniformParams.LodBiasScale = LodBiasScale;
+
+				// Create vertex factory.
+				VertexFactory = new FVirtualHeightfieldMeshVertexFactory(GetScene().GetFeatureLevel(), UniformParams);
+				VertexFactory->InitResource(FRHICommandListImmediate::Get());
+			}
+		}
+	}
+}
+```
+
+# RVT生成相关
+
+# RVT相关操作总结
+CPU端创建：
+```c++
+
+```
+
+作为UniformParameter传递到GPU端：
+```c++
+AllocatedVirtualTexture = RuntimeVirtualTexture->GetAllocatedVirtualTexture();
+
+//PageTableTexture、Texture&Sampler
+FVirtualHeightfieldMeshVertexFactoryParameters UniformParams;  
+UniformParams.PageTableTexture = AllocatedVirtualTexture->GetPageTableTexture(0);  
+UniformParams.HeightTexture = AllocatedVirtualTexture->GetPhysicalTextureSRV(0, false);  
+UniformParams.HeightSampler = TStaticSamplerState<SF_Bilinear>::GetRHI();
+
+//VTPackedUniform&VTPackedPageTableUniform
+FUintVector4 PackedUniform;  
+AllocatedVirtualTexture->GetPackedUniform(&PackedUniform, 0);  
+UniformParams.VTPackedUniform = PackedUniform;  
+FUintVector4 PackedPageTableUniform[2];  
+AllocatedVirtualTexture->GetPackedPageTableUniform(PackedPageTableUniform);  
+UniformParams.VTPackedPageTableUniform0 = PackedPageTableUniform[0];  
+UniformParams.VTPackedPageTableUniform1 = PackedPageTableUniform[1];  
+
+//PageTableSize
+const float PageTableSizeX = AllocatedVirtualTexture->GetWidthInTiles();  
+const float PageTableSizeY = AllocatedVirtualTexture->GetHeightInTiles();  
+UniformParams.PageTableSize = FVector4f(PageTableSizeX, PageTableSizeY, 1.f / PageTableSizeX, 1.f / PageTableSizeY);  
+
+//PhysicalTextureSize
+const float PhysicalTextureSize = AllocatedVirtualTexture->GetPhysicalTextureSize(0);  
+UniformParams.PhysicalTextureSize = FVector2f(PhysicalTextureSize, 1.f / PhysicalTextureSize);  
+
+//Local <=> World Matrix
+UniformParams.VirtualHeightfieldToLocal = FMatrix44f(UVToLocal);  
+UniformParams.VirtualHeightfieldToWorld = FMatrix44f(UVToWorld);       // LWC_TODO: Precision loss  
+
+//MaxLod
+UniformParams.MaxLod = AllocatedVirtualTexture->GetMaxLevel();  
+```
+
+GPU端采样：
+```c++
+VTUniform Uniform = VTUniform_Unpack(VHM.VTPackedUniform);  
+Uniform.vPageBorderSize -= .5f * VHM.PhysicalTextureSize.y; // Half texel offset is used in VT write and in sampling because we want texel locations to match landscape vertices.  
+VTPageTableUniform PageTableUniform = VTPageTableUniform_Unpack(VHM.VTPackedPageTableUniform0, VHM.VTPackedPageTableUniform1);  
+VTPageTableResult VTResult0 = TextureLoadVirtualPageTableLevel(VHM.PageTableTexture, PageTableUniform, NormalizedPos, VTADDRESSMODE_CLAMP, VTADDRESSMODE_CLAMP, floor(SampleLevel));  
+float2 UV0 = VTComputePhysicalUVs(VTResult0, 0, Uniform);  
+float Height0 = VHM.HeightTexture.SampleLevel(VHM.HeightSampler, UV0, 0);  
+VTPageTableResult VTResult1 = TextureLoadVirtualPageTableLevel(VHM.PageTableTexture, PageTableUniform, NormalizedPos, VTADDRESSMODE_CLAMP, VTADDRESSMODE_CLAMP, ceil(SampleLevel));  
+float2 UV1 = VTComputePhysicalUVs(VTResult1, 0, Uniform);  
+float Height1 = VHM.HeightTexture.SampleLevel(VHM.HeightSampler, UV1, 0);  
+float Height = lerp(Height0.x, Height1.x, frac(SampleLevel));
+```
+
+**NiagaraDataInterfaceVirtualTextureTemplate.ush**中的代码：
+```c++
+//其他相关VT操作函数位于VirtualTextureCommon.ush
+
+float4 SampleRVTLayer_{ParameterName}(float2 SampleUV, Texture2D InTexture, Texture2D<uint4> InPageTable, uint4 InTextureUniforms)
+{
+	VTPageTableResult PageTable = TextureLoadVirtualPageTableLevel(InPageTable, VTPageTableUniform_Unpack({ParameterName}_PageTableUniforms[0], {ParameterName}_PageTableUniforms[1]), SampleUV, VTADDRESSMODE_CLAMP, VTADDRESSMODE_CLAMP, 0.0f);
+	return TextureVirtualSample(InTexture, {ParameterName}_SharedSampler, PageTable, 0, VTUniform_Unpack(InTextureUniforms));
+}
+
+void SampleRVT_{ParameterName}(in float3 WorldPosition, out bool bInsideVolume, out float3 BaseColor, out float Specular, out float Roughness, out float3 Normal, out float WorldHeight, out float Mask)
+{
+	bInsideVolume = false;
+	BaseColor = float3(0.0f, 0.0f, 0.0f);
+	Specular = 0.5f;
+	Roughness = 0.5f;
+	Normal = float3(0.0f, 0.0f, 1.0f);
+	WorldHeight = 0.0f;
+	Mask = 1.0f;
+
+	// Get Sample Location
+	FLWCVector3 LWCWorldPosition = MakeLWCVector3({ParameterName}_SystemLWCTile, WorldPosition);
+	FLWCVector3 LWCUVOrigin = MakeLWCVector3({ParameterName}_SystemLWCTile, {ParameterName}_UVUniforms[0].xyz);
+
+	float2 SampleUV = VirtualTextureWorldToUV(LWCWorldPosition, LWCUVOrigin, {ParameterName}_UVUniforms[1].xyz, {ParameterName}_UVUniforms[2].xyz);
+
+	// Test to see if we are inside the volume, but still take the samples as it will clamp to the edge
+	bInsideVolume = all(SampleUV >- 0.0f) && all(SampleUV < 1.0f);
+
+	// Sample Textures
+	float4 LayerSample[3];
+	LayerSample[0] = ({ParameterName}_ValidLayersMask & 0x1) != 0 ? SampleRVTLayer_{ParameterName}(SampleUV, {ParameterName}_VirtualTexture0, {ParameterName}_VirtualTexture0PageTable, {ParameterName}_VirtualTexture0TextureUniforms) : 0;
+	LayerSample[1] = ({ParameterName}_ValidLayersMask & 0x2) != 0 ? SampleRVTLayer_{ParameterName}(SampleUV, {ParameterName}_VirtualTexture1, {ParameterName}_VirtualTexture1PageTable, {ParameterName}_VirtualTexture1TextureUniforms) : 0;
+	LayerSample[2] = ({ParameterName}_ValidLayersMask & 0x4) != 0 ? SampleRVTLayer_{ParameterName}(SampleUV, {ParameterName}_VirtualTexture2, {ParameterName}_VirtualTexture2PageTable, {ParameterName}_VirtualTexture2TextureUniforms) : 0;
+
+	// Sample Available Attributes
+	switch ( {ParameterName}_MaterialType )
+	{
+		case ERuntimeVirtualTextureMaterialType_BaseColor:
+		{
+			BaseColor = LayerSample[0].xyz;
+			break;
+		}
+
+		case ERuntimeVirtualTextureMaterialType_BaseColor_Normal_Roughness:
+		{
+			BaseColor = VirtualTextureUnpackBaseColorSRGB(LayerSample[0]);
+			Roughness = LayerSample[1].y;
+			Normal = VirtualTextureUnpackNormalBGR565(LayerSample[1]);
+			break;
+		}
+
+		case ERuntimeVirtualTextureMaterialType_BaseColor_Normal_DEPRECATED:
+		case ERuntimeVirtualTextureMaterialType_BaseColor_Normal_Specular:
+		{
+			BaseColor = LayerSample[0].xyz;
+			Specular = LayerSample[1].x;
+			Roughness = LayerSample[1].y;
+			Normal = VirtualTextureUnpackNormalBC3BC3(LayerSample[0], LayerSample[1]);
+			break;
+		}
+		
+		case ERuntimeVirtualTextureMaterialType_BaseColor_Normal_Specular_YCoCg:
+		{
+			BaseColor = VirtualTextureUnpackBaseColorYCoCg(LayerSample[0]);
+			Specular = LayerSample[2].x;
+			Roughness = LayerSample[2].y;
+			Normal = VirtualTextureUnpackNormalBC5BC1(LayerSample[1], LayerSample[2]);
+			break;
+		}
+		
+		case ERuntimeVirtualTextureMaterialType_BaseColor_Normal_Specular_Mask_YCoCg:
+		{
+			BaseColor = VirtualTextureUnpackBaseColorYCoCg(LayerSample[0]);
+			Specular = LayerSample[2].x;
+			Roughness = LayerSample[2].y;
+			Normal = VirtualTextureUnpackNormalBC5BC1(LayerSample[1], LayerSample[2]);
+			Mask = LayerSample[2].w;
+			break;
+		}
+		
+		case ERuntimeVirtualTextureMaterialType_WorldHeight:
+		{
+			WorldHeight = VirtualTextureUnpackHeight(LayerSample[0], {ParameterName}_WorldHeightUnpack);
+			break;
+		}
+	}
+}
+```
+
+VT还存在一个反馈机制，具体可以参考：[[#Pass1的补充VirtualTextureFeedback]]
+```c++
+/** GPU fence pool. Contains a fence array that is kept in sync with the FeedbackItems ring buffer. Fences are used to know when a transfer is ready to Map() without stalling. */  
+/** GPU 栅栏池。其中包含一个与 FeedbackItems 环形缓冲区保持同步的栅栏数组。栅栏用于了解传输何时准备就绪，可在不停滞的情况下进行 Map()。 */
+class FFeedbackGPUFencePool* Fences;
+```