# Reconstruct the world space positions of pixels from the depth texture The Unity shader in this example reconstructs the world space positions for pixels using a depth texture and screen space UV coordinates. The shader draws a checkerboard pattern on a mesh to visualize the positions. The following illustration shows the end result: ![Checkerboard pattern visualizing the reconstructed world space positions.](Images/shader-examples/urp-shader-tutorial-reconstruct-world-positions-from-depth.png) This page contains the following sections: * [Create the sample scene](#create-the-sample-scene) * [Edit the ShaderLab code](#edit-the-shaderlab-code) * [The complete ShaderLab code](#the-complete-shaderlab-code) ## Create the sample scene Create the sample scene to follow the steps in this section: 1. Install URP into an existing Unity project, or create a new project using the [__Universal Project Template__](creating-a-new-project-with-urp.md). 2. In the sample Scene, create a plane GameObject and place it so that it occludes some of the GameObjects. ![Create a plane](Images/shader-examples/urp-shader-tutorial-create-place-gameobj.png) 3. Create a new Material and assign it to the plane. 4. Create a new shader and assign it to the material. Copy and paste the Unity shader source code from the page [URP unlit basic shader](writing-shaders-urp-basic-unlit-structure.md). 5. Select the URP Asset. If you created the project using the Universal Render Pipeline template, the URP Asset path is `Assets/Settings/UniversalRP-HighQuality`. 6. In the URP Asset, in the General section, enable `Depth Texture`. ![In URP Asset, enable Depth Texture](Images/shader-examples/urp-asset-depth-texture.png) 7. Open the shader you created on step 4. ## Edit the ShaderLab code This section assumes that you copied the source code from the page [URP unlit basic shader](writing-shaders-urp-basic-unlit-structure.md). Make the following changes to the ShaderLab code: 1. In the `HLSLPROGRAM` block, add the include declaration for the depth texture shader header. For example, place it under the existing include declaration for `Core.hlsl`. ```c++ #include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Core.hlsl" // The DeclareDepthTexture.hlsl file contains utilities for sampling the Camera // depth texture. #include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/DeclareDepthTexture.hlsl" ``` The `DeclareDepthTexture.hlsl` file contains functions for sampling the Camera depth texture. This example uses the `SampleSceneDepth` function for sampling the Z coordinate for pixels. 2. In the fragment shader definition, add `Varyings IN` as input. ```c++ half4 frag(Varyings IN) : SV_Target ``` In this example, the fragment shader uses the `positionHCS` property from the `Varyings` struct to get locations of pixels. 3. In the fragment shader, to calculate the UV coordinates for sampling the depth buffer, divide the pixel location by the render target resolution `_ScaledScreenParams`. The property `_ScaledScreenParams.xy` takes into account any scaling of the render target, such as Dynamic Resolution. ```c++ float2 UV = IN.positionHCS.xy / _ScaledScreenParams.xy; ``` 4. In the fragment shader, use the `SampleSceneDepth` functions to sample the depth buffer. ```c++ #if UNITY_REVERSED_Z real depth = SampleSceneDepth(UV); #else // Adjust z to match NDC for OpenGL real depth = lerp(UNITY_NEAR_CLIP_VALUE, 1, SampleSceneDepth(UV)); #endif ``` The `SampleSceneDepth` function comes from the `DeclareDepthTexture.hlsl` file. It returns the Z value in the range `[0, 1]`. For the reconstruction function (`ComputeWorldSpacePosition`) to work, the depth value must be in the normalized device coordinate (NDC) space. In D3D, Z is in range `[0,1]`, in OpenGL, Z is in range `[-1, 1]`. This example uses the `UNITY_REVERSED_Z` constant to determine the platform and adjust the Z value range. See step 6 in this example for more explanations. The `UNITY_NEAR_CLIP_VALUE` variable is a platform independent near clipping plane value for the clip space. For more information, see [Platform-specific rendering differences](https://docs.unity3d.com/Manual/SL-PlatformDifferences.html). 5. Reconstruct world space positions from the UV and Z coordinates of pixels. ```c++ float3 worldPos = ComputeWorldSpacePosition(UV, depth, UNITY_MATRIX_I_VP); ``` `ComputeWorldSpacePosition` is a utility function that calculates the world space position from the UV and the depth (Z) values. This function is defined in the `Common.hlsl` file of the SRP Core package. `UNITY_MATRIX_I_VP` is an inverse view projection matrix which transforms points from the clip space to the world space. 6. To visualize the world space positions of pixels, create the checkboard effect. ```c++ uint scale = 10; uint3 worldIntPos = uint3(abs(worldPos.xyz * scale)); bool white = (worldIntPos.x & 1) ^ (worldIntPos.y & 1) ^ (worldIntPos.z & 1); half4 color = white ? half4(1,1,1,1) : half4(0,0,0,1); ``` The `scale` is the inverse scale of the checkboard pattern size. The `abs` function mirrors the pattern to the negative coordinate side. The `uint3` declaration for the `worldIntPos` variable snaps the coordinate positions to integers. The `AND` operator in the expresion ` & 1` checks if the value is even (0) or odd (1). The expression lets the code divide the surface into squares. The `XOR` operator in the expresion ` ^ ` flips the square color. The depth buffer might not have valid values for areas where no geometry is rendered. The following code draws black color in such areas. ```c++ #if UNITY_REVERSED_Z if(depth < 0.0001) return half4(0,0,0,1); #else if(depth > 0.9999) return half4(0,0,0,1); #endif ``` Different platforms use different Z values for far clipping planes (0 == far, or 1 == far). The `UNITY_REVERSED_Z` constant lets the code handle all platforms correctly. Save the shader code, the example is ready. The following illustration shows the end result: ![3D Checkerboard](Images/shader-examples/urp-shader-tutorial-reconstruct-world-positions-from-depth.png) ## The complete ShaderLab code Below is the complete ShaderLab code for this example. ```c++ // This Unity shader reconstructs the world space positions for pixels using a depth // texture and screen space UV coordinates. The shader draws a checkerboard pattern // on a mesh to visualize the positions. Shader "Example/URPReconstructWorldPos" { Properties { } // The SubShader block containing the Shader code. SubShader { // SubShader Tags define when and under which conditions a SubShader block or // a pass is executed. Tags { "RenderType" = "Opaque" "RenderPipeline" = "UniversalPipeline" } Pass { HLSLPROGRAM // This line defines the name of the vertex shader. #pragma vertex vert // This line defines the name of the fragment shader. #pragma fragment frag // The Core.hlsl file contains definitions of frequently used HLSL // macros and functions, and also contains #include references to other // HLSL files (for example, Common.hlsl, SpaceTransforms.hlsl, etc.). #include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/Core.hlsl" // The DeclareDepthTexture.hlsl file contains utilities for sampling the // Camera depth texture. #include "Packages/com.unity.render-pipelines.universal/ShaderLibrary/DeclareDepthTexture.hlsl" // This example uses the Attributes structure as an input structure in // the vertex shader. struct Attributes { // The positionOS variable contains the vertex positions in object // space. float4 positionOS : POSITION; }; struct Varyings { // The positions in this struct must have the SV_POSITION semantic. float4 positionHCS : SV_POSITION; }; // The vertex shader definition with properties defined in the Varyings // structure. The type of the vert function must match the type (struct) // that it returns. Varyings vert(Attributes IN) { // Declaring the output object (OUT) with the Varyings struct. Varyings OUT; // The TransformObjectToHClip function transforms vertex positions // from object space to homogenous clip space. OUT.positionHCS = TransformObjectToHClip(IN.positionOS.xyz); // Returning the output. return OUT; } // The fragment shader definition. // The Varyings input structure contains interpolated values from the // vertex shader. The fragment shader uses the `positionHCS` property // from the `Varyings` struct to get locations of pixels. half4 frag(Varyings IN) : SV_Target { // To calculate the UV coordinates for sampling the depth buffer, // divide the pixel location by the render target resolution // _ScaledScreenParams. float2 UV = IN.positionHCS.xy / _ScaledScreenParams.xy; // Sample the depth from the Camera depth texture. #if UNITY_REVERSED_Z real depth = SampleSceneDepth(UV); #else // Adjust Z to match NDC for OpenGL ([-1, 1]) real depth = lerp(UNITY_NEAR_CLIP_VALUE, 1, SampleSceneDepth(UV)); #endif // Reconstruct the world space positions. float3 worldPos = ComputeWorldSpacePosition(UV, depth, UNITY_MATRIX_I_VP); // The following part creates the checkerboard effect. // Scale is the inverse size of the squares. uint scale = 10; // Scale, mirror and snap the coordinates. uint3 worldIntPos = uint3(abs(worldPos.xyz * scale)); // Divide the surface into squares. Calculate the color ID value. bool white = ((worldIntPos.x) & 1) ^ (worldIntPos.y & 1) ^ (worldIntPos.z & 1); // Color the square based on the ID value (black or white). half4 color = white ? half4(1,1,1,1) : half4(0,0,0,1); // Set the color to black in the proximity to the far clipping // plane. #if UNITY_REVERSED_Z // Case for platforms with REVERSED_Z, such as D3D. if(depth < 0.0001) return half4(0,0,0,1); #else // Case for platforms without REVERSED_Z, such as OpenGL. if(depth > 0.9999) return half4(0,0,0,1); #endif return color; } ENDHLSL } } } ```