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C# basics

Introduction

Warning

.NET support has been heavily modified between Godot 3 and 4. As such, you may still run into some issues, or find spots where the documentation could be improved.

Please report issues with C# in Godot on the engine GitHub page, and any documentation issues on the documentation GitHub page.

This page provides a brief introduction to C#, both what it is and how to use it in Godot. Afterwards, you may want to look at how to use specific features, read about the differences between the C# and the GDScript API, and (re)visit the Scripting section of the step-by-step tutorial.

C# is a high-level programming language developed by Microsoft. In Godot, it is implemented with .NET 6.0.

Attention

Projects written in C# using Godot 4.x currently cannot be exported to Android, iOS and web platforms. To use C# on those platforms, use Godot 3 instead.

Note

This is not a full-scale tutorial on the C# language as a whole. If you aren’t already familiar with its syntax or features, see the Microsoft C# guide or look for a suitable introduction elsewhere.

Prerequisites

Godot bundles the parts of .NET needed to run already compiled games. However, Godot does not bundle the tools required to build and compile games, such as MSBuild and the C# compiler. These are included in the .NET SDK, and need to be installed separately.

In summary, you must have installed the .NET SDK and the .NET-enabled version of Godot.

Download and install the latest stable version of the SDK from the .NET download page.

Important

Be sure to install the 64-bit version of the SDK(s) if you are using the 64-bit version of Godot.

If you are building Godot from source, make sure to follow the steps to enable .NET support in your build as outlined in the Compiling with .NET page.

Configuring an external editor

C# support in Godot’s built-in script editor is minimal. Consider using an external IDE or editor, such as Visual Studio Code or MonoDevelop. These provide autocompletion, debugging, and other useful features for C#. To select an external editor in Godot, click on Editor → Editor Settings and scroll down to Dotnet. Under Dotnet, click on Editor, and select your external editor of choice. Godot currently supports the following external editors:

  • Visual Studio 2019

  • Visual Studio 2022

  • Visual Studio Code

  • MonoDevelop

  • Visual Studio for Mac

  • JetBrains Rider

See the following sections for how to configure an external editor:

JetBrains Rider

After reading the “Prerequisites” section, you can download and install JetBrains Rider.

In Godot’s Editor → Editor Settings menu:

  • Set Dotnet -> Editor -> External Editor to JetBrains Rider.

In Rider:

  • Set MSBuild version to .NET Core.

  • Install the Godot support plugin.

Visual Studio Code

After reading the “Prerequisites” section, you can download and install Visual Studio Code (aka VS Code).

In Godot’s Editor → Editor Settings menu:

  • Set Dotnet -> Editor -> External Editor to Visual Studio Code.

In Visual Studio Code:

  • Install the C# extension.

Note

If you are using Linux you need to install the Mono SDK for the C# tools plugin to work.

To configure a project for debugging, you need a tasks.json and launch.json file in the .vscode folder with the necessary configuration. An example configuration can be found here . In the tasks.json file, make sure the program parameter points to your Godot executable, either by changing it to the path of the executable or by defining a GODOT4 environment variable that points to the executable. Now, when you start the debugger in Visual Studio Code, your Godot project will run.

Note

There is also a C# Tools for Godot Visual Studio Code extension, that is meant to make this setup easier and to provide further useful tools. But it is not yet updated to work with Godot 4.

Visual Studio (Windows only)

Download and install the latest version of Visual Studio. Visual Studio will include the required SDKs if you have the correct workloads selected, so you don’t need to manually install the things listed in the “Prerequisites” section.

While installing Visual Studio, select this workload:

  • .NET desktop development

In Godot’s Editor → Editor Settings menu:

  • Set Dotnet -> Editor -> External Editor to Visual Studio.

Next, you can download the Godot Visual Studio extension from github here. Double click on the downloaded file and follow the installation process.

Note

The option to debug your game in Visual Studio may not appear after installing the extension. To enable debugging, there is a workaround for Visual Studio 2019. There is a separate issue about this problem in Visual Studio 2022.

Note

If you see an error like “Unable to find package Godot.NET.Sdk”, your NuGet configuration may be incorrect and need to be fixed.

A simple way to fix the NuGet configuration file is to regenerate it. In a file explorer window, go to %AppData%\NuGet. Rename or delete the NuGet.Config file. When you build your Godot project again, the file will be automatically created with default values.

Creating a C# script

After you successfully set up C# for Godot, you should see the following option when selecting Attach Script in the context menu of a node in your scene:

../../../_images/attachcsharpscript.webp

Note that while some specifics change, most concepts work the same when using C# for scripting. If you’re new to Godot, you may want to follow the tutorials on Scripting languages at this point. While some documentation pages still lack C# examples, most notions can be transferred from GDScript.

Project setup and workflow

When you create the first C# script, Godot initializes the C# project files for your Godot project. This includes generating a C# solution (.sln) and a project file (.csproj), as well as some utility files and folders (.godot/mono). All of these but .godot/mono are important and should be committed to your version control system. Everything under .godot can be safely added to the ignore list of your VCS. When troubleshooting, it can sometimes help to delete the .godot/mono folder and let it regenerate.

Example

Here’s a blank C# script with some comments to demonstrate how it works.

  1. using Godot;
  2. public partial class YourCustomClass : Node
  3. {
  4. // Member variables here, example:
  5. private int _a = 2;
  6. private string _b = "textvar";
  7. public override void _Ready()
  8. {
  9. // Called every time the node is added to the scene.
  10. // Initialization here.
  11. GD.Print("Hello from C# to Godot :)");
  12. }
  13. public override void _Process(double delta)
  14. {
  15. // Called every frame. Delta is time since the last frame.
  16. // Update game logic here.
  17. }
  18. }

As you can see, functions normally in global scope in GDScript like Godot’s print function are available in the GD static class which is part of the Godot namespace. For a full list of methods in the GD class, see the class reference pages for @GDScript and @GlobalScope.

Note

Keep in mind that the class you wish to attach to your node should have the same name as the .cs file. Otherwise, you will get the following error:

“Cannot find class XXX for script res://XXX.cs”

General differences between C# and GDScript

The C# API uses PascalCase instead of snake_case in GDScript/C++. Where possible, fields and getters/setters have been converted to properties. In general, the C# Godot API strives to be as idiomatic as is reasonably possible.

For more information, see the C# API differences to GDScript page.

Warning

You need to (re)build the project assemblies whenever you want to see new exported variables or signals in the editor. This build can be manually triggered by clicking the word Build in the top right corner of the editor. You can also click MSBuild at the bottom of the editor window to reveal the MSBuild panel, then click the Build button to reveal a dropdown, then click the Build Solution option.

You will also need to rebuild the project assemblies to apply changes in “tool” scripts.

Current gotchas and known issues

As C# support is quite new in Godot, there are some growing pains and things that need to be ironed out. Below is a list of the most important issues you should be aware of when diving into C# in Godot, but if in doubt, also take a look over the official issue tracker for .NET issues.

  • Writing editor plugins is possible, but it is currently quite convoluted.

  • State is currently not saved and restored when hot-reloading, with the exception of exported variables.

  • Attached C# scripts should refer to a class that has a class name that matches the file name.

  • There are some methods such as Get()/Set(), Call()/CallDeferred() and signal connection method Connect() that rely on Godot’s snake_case API naming conventions. So when using e.g. CallDeferred("AddChild"), AddChild will not work because the API is expecting the original snake_case version add_child. However, you can use any custom properties or methods without this limitation. Prefer using the exposed StringName in the PropertyName, MethodName and SignalName to avoid extra StringName allocations and worrying about snake_case naming.

As of Godot 4.0, exporting .NET projects is supported for desktop platforms (Linux, Windows and macOS). Other platforms will gain support in future 4.x releases.

Common pitfalls

You might encounter the following error when trying to modify some values in Godot objects, e.g. when trying to change the X coordinate of a Node2D:

  1. public partial class MyNode2D : Node2D
  2. {
  3. public override _Ready()
  4. {
  5. Position.X = 100.0f;
  6. // CS1612: Cannot modify the return value of 'Node2D.Position' because
  7. // it is not a variable.
  8. }
  9. }

This is perfectly normal. Structs (in this example, a Vector2) in C# are copied on assignment, meaning that when you retrieve such an object from a property or an indexer, you get a copy of it, not the object itself. Modifying said copy without reassigning it afterwards won’t achieve anything.

The workaround is simple: retrieve the entire struct, modify the value you want to modify, and reassign the property.

  1. var newPosition = Position;
  2. newPosition.X = 100.0f;
  3. Position = newPosition;

Since C# 10, it is also possible to use with expressions on structs, allowing you to do the same thing in a single line.

  1. Position = Position with { X = 100.0f };

You can read more about this error on the C# language reference.

Performance of C# in Godot

According to some preliminary benchmarks, the performance of C# in Godot — while generally in the same order of magnitude — is roughly ~4× that of GDScript in some naive cases. C++ is still a little faster; the specifics are going to vary according to your use case. GDScript is likely fast enough for most general scripting workloads.

Most properties of Godot C# objects that are based on GodotObject (e.g. any Node like Control or Node3D like Camera3D) require native (interop) calls as they talk to Godot’s C++ core. Consider assigning values of such properties into a local variable if you need to modify or read them multiple times at a single code location:

  1. using Godot;
  2. public partial class YourCustomClass : Node3D
  3. {
  4. private void ExpensiveReposition()
  5. {
  6. for (var i = 0; i < 10; i++)
  7. {
  8. // Position is read and set 10 times which incurs native interop.
  9. // Furthermore the object is repositioned 10 times in 3D space which
  10. // takes additional time.
  11. Position += new Vector3(i, i);
  12. }
  13. }
  14. private void Reposition()
  15. {
  16. // A variable is used to avoid native interop for Position on every loop.
  17. var newPosition = Position;
  18. for (var i = 0; i < 10; i++)
  19. {
  20. newPosition += new Vector3(i, i);
  21. }
  22. // Setting Position only once avoids native interop and repositioning in 3D space.
  23. Position = newPosition;
  24. }
  25. }

Passing raw arrays (such as byte[]) or string to Godot’s C# API requires marshalling which is comparatively pricey.

The implicit conversion from string to NodePath or StringName incur both the native interop and marshalling costs as the string has to be marshalled and passed to the respective native constructor.

Using NuGet packages in Godot

NuGet packages can be installed and used with Godot, as with any C# project. Many IDEs are able to add packages directly. They can also be added manually by adding the package reference in the .csproj file located in the project root:

  1. <ItemGroup>
  2. <PackageReference Include="Newtonsoft.Json" Version="11.0.2" />
  3. </ItemGroup>
  4. ...
  5. </Project>

As of Godot 3.2.3, Godot automatically downloads and sets up newly added NuGet packages the next time it builds the project.

Profiling your C# code

The following tools may be used for performance and memory profiling of your managed code:

  • JetBrains Rider with dotTrace/dotMemory plugin.

  • Standalone JetBrains dotTrace/dotMemory.

  • Visual Studio.

Profiling managed and unmanaged code at once is possible with both JetBrains tools and Visual Studio, but limited to Windows.