From Unity to Godot Engine¶
This guide provides an overview of Godot Engine from the viewpoint of a Unity user, and aims to help you migrate your existing Unity experience into the world of Godot.
|License||Proprietary, closed, free license with revenue caps and usage restrictions||MIT license, free and fully open source without any restriction|
|OS (editor)||Windows, macOS, Linux (unofficial and unsupported)||Windows, macOS, X11 (Linux, *BSD)|
||Scene tree and nodes, allowing scenes to be nested and/or inherit other scenes|
|Third-party tools||Visual Studio or VS Code|
Godot Engine provides a rich-featured editor that allows you to build your games. The pictures below display both editors with colored blocks to indicate common functionalities.
Note that Godot editor allows you to dock each panel at the side of the scene editor you wish.
While both editors may seem similar, there are many differences below the surface. Both let you organize the project using the filesystem, but Godot’s approach is simpler with a single configuration file, minimalist text format, and no metadata. All this contributes to Godot being much friendlier to VCS systems, such as Git, Subversion, or Mercurial.
Godot’s Scene panel is similar to Unity’s Hierarchy panel but, as each node has a specific function, the approach used by Godot is more visually descriptive. In other words, it’s easier to understand what a specific scene does at a glance.
The Inspector in Godot is more minimalist and designed to only show properties. Thanks to this, objects can export a much larger amount of useful parameters to the user without having to hide functionality in language APIs. As a plus, Godot allows animating any of those properties visually, so changing colors, textures, enumerations, or even links to resources in real-time is possible without involving code.
Finally, the Toolbar at the top of the screen is similar in the sense that it allows controlling the project playback, but projects in Godot run in a separate window, as they don’t execute inside the editor (but the tree and objects can still be explored in the debugger window).
This approach has the disadvantage that the running game can’t be explored from different angles (though this may be supported in the future and displaying collision gizmos in the running game is already possible), but in exchange has several advantages:
- Running the project and closing it is fast (Unity has to save, run the project, close the project, and then reload the previous state).
- Live editing is a lot more useful because changes done to the editor take effect immediately in the game and are not lost (nor have to be synced) when the game is closed. This allows fantastic workflows, like creating levels while you play them.
- The editor is more stable because the game runs in a separate process.
Finally, the top toolbar includes a menu for remote debugging. These options make it simple to deploy to a device (connected phone, tablet, or browser via HTML5), and debug/live edit on it after the game was exported.
The scene system¶
This is the most important difference between Unity and Godot and, actually, the favourite feature of most Godot users.
Unity’s scene system consists of embedding all the required assets in a scene and linking them together by setting components and scripts to them.
Godot’s scene system is different: it actually consists of a tree made of nodes. Each node serves a purpose: Sprite, Mesh, Light, etc. Basically, this is similar to the Unity scene system. However, each node can have multiple children, which makes each a subscene of the main scene. This means you can compose a whole scene with different scenes stored in different files.
For example, think of a platformer level. You would compose it with multiple elements:
- The player
- The enemies
In Unity, you would put all the GameObjects in the scene: the player, multiple instances of enemies, bricks everywhere to form the ground of the level and then multiple instances of coins all over the level. You would then add various components to each element to link them and add logic in the level: For example, you’d add a BoxCollider2D to all the elements of the scene so that they can collide. This principle is different in Godot.
In Godot, you would split your whole scene into 3 separate, smaller scenes, which you would then instance in the main scene.
- First, a scene for the Player alone.
Consider the player as a reusable element in other levels. It is composed of one node in particular: an AnimatedSprite node, which contains the sprite textures to form various animations (for example, walking animation)
- Second, a scene for the Enemy.
There again, an enemy is a reusable element in other levels. It is almost the same as the Player node - the only differences are the script (that manages AI, mostly) and sprite textures used by the AnimatedSprite.
- Lastly, the Level scene.
It is composed of Bricks (for platforms), Coins (for the player to grab) and a certain number of instances of the previous Enemy scene. These will be different, separate enemies, whose behaviour and appearance will be the same as defined in the Enemy scene. Each instance is then considered as a node in the Level scene tree. Of course, you can set different properties for each Enemy node (to change its color, for example).
Finally, the main scene would then be composed of one root node with 2 children: a Player instance node, and a Level instance node. The root node can be anything, generally a “root” type such as “Node” which is the most global type, or “Node2D” (root type of all 2D-related nodes), “Spatial” (root type of all 3D-related nodes) or “Control” (root type of all GUI-related nodes).
As you can see, every scene is organized as a tree. The same goes for nodes’ properties: you don’t add a collision component to a node to make it collidable like Unity does. Instead, you make this node a child of a new specific node that has collision properties. Godot features various collision types nodes, depending on the usage (see the Physics introduction).
Question: What are the advantages of this system? Wouldn’t this system potentially increase the depth of the scene tree? Besides, Unity allows organizing GameObjects by putting them in empty GameObjects.
- First, this system is closer to the well-known object-oriented paradigm: Godot provides a number of nodes which are not clearly “Game Objects”, but they provide their children with their own capabilities: this is inheritance.
- Second, it allows the extraction of a subtree of the scene to make it a scene of its own, which answers the second and third questions: even if a scene tree gets too deep, it can be split into smaller subtrees. This also allows a better solution for reusability, as you can include any subtree as a child of any node. Putting multiple nodes in an empty GameObject in Unity does not provide the same possibility, apart from a visual organization.
These are the most important concepts you need to remember: “node”, “parent node”, and “child node”.
We previously observed that there is no perfect solution to set a project architecture. Any solution will work for Unity and Godot, so this point has a lesser importance.
However, we often observe a common architecture for Unity projects, which consists of having one Assets folder in the root directory that contains various folders, one per type of asset: Audio, Graphics, Models, Materials, Scripts, Scenes, etc.
As described before, the Godot scene system allows splitting scenes into smaller scenes. Since each scene and subscene is actually one scene file in the project, we recommend organizing your project a bit differently. This wiki provides a page for this: Project organization.
Where are my prefabs?¶
The concept of prefabs as provided by Unity is a ‘template’ element of the scene. It is reusable, and each instance of the prefab that exists in the scene has an existence of its own, but all of them have the same properties as defined by the prefab.
Godot does not provide prefabs as such, but this functionality is here, again, filled thanks to its scene system: As we saw, the scene system is organized as a tree. Godot allows you to save a subtree of a scene as its own scene, thus saved into its own file. This new scene can then be instanced as many times as you want. Any change you make to this new, separate scene will be applied to its instances. However, any change you make to the instance will not have any impact on the ‘template’ scene.
To be precise, you can modify the parameters of the instance in the Inspector panel. However, the nodes that compose this instance are locked although you can unlock them if you need to by right-clicking the instance in the Scene tree and selecting “Editable children” in the menu. You don’t need to do this to add new children nodes to this node, but it is possible. Remember that these new children will belong to the instance, not the ‘template’ scene. If you want to add new children to all the instances of your ‘template’ scene, then you need to add them in the ‘template’ scene.
- GameObject -> Node
- Add a component -> Inheriting
- Prefab -> Externalized branch
Scripting: GDScript, C# and Visual Script¶
As you may know already, Unity supports C#. C# benefits from its integration with Visual Studio and other features, such as static typing.
Godot provides its own scripting language, GDScript as well as support for Visual Script and C#. GDScript borrows its syntax from Python, but is not related to it. If you wonder about the reasoning for a custom scripting language, please read the GDScript basics and Frequently asked questions pages. GDScript is strongly attached to the Godot API and is really easy to learn: Between one evening for an experienced programmer and a week for a complete beginner.
Unity allows you to attach as many scripts as you want to a GameObject. Each script adds a behaviour to the GameObject: For example, you can attach a script so that it reacts to the player’s controls, and another that controls its specific game logic.
In Godot, you can only attach one script per node. You can use either an external GDScript file or include the script directly in the node. If you need to attach more scripts to one node, then you may consider two solutions, depending on your scene and on what you want to achieve:
- either add a new node between your target node and its current parent, then add a script to this new node.
- or, you can split your target node into multiple children and attach one script to each of them.
As you can see, it can be easy to turn a scene tree to a mess. This is why it is important to have a real reflection and consider splitting a complicated scene into multiple, smaller branches.
Connections: groups and signals¶
You can control nodes by accessing them via script and calling built-in or user-defined functions on them. You can also place nodes in a group and call functions on all nodes in this group. See more in the scripting documentation.
Nodes can send a signal when a specified action occurs. A signal can be set to call any function. You can define custom signals and specify when they are triggered. See more in the signals documentation.
Unity can handle script serialization in two ways:
- Implicit: All public fields in a class are automatically serialized if the type is a serializable type (
Dictionaryis not serializable).
- Explicit: Non-public fields can be serialized using the
Godot also has a built-in script serialization system, but it works only explicitly.
You can serialize any serializable type (built-in and various engine types,
including Array and Dictionary) using the
See the exports documentation for details.
Unity also has a data type called
ScriptableObject used to serialize custom asset objects.
Its equivalent in Godot is the base class for all resources: Resource.
Creating a script that inherits Resource will allow you to create custom serializable objects. More information about resources can be found here.
Using Godot in C++¶
Godot allows you to develop your project directly in C++ by using its API, which is not possible with Unity at the moment. As an example, you can consider Godot Engine’s editor as a “game” written in C++ using the Godot API.
If you are interested in using Godot in C++, you may want to start reading the Developing in C++ page.