# Using KinematicBody2D¶

## Introduction¶

Godot offers a number of collision objects to provide both collision detection and response. Trying to decide which one to use for your project can be confusing. You can avoid problems and simplify development if you understand how each of them works and what their pros and cons are. In this tutorial, we’ll look at the KinematicBody2D node and show some examples of how it can be used.

Note

This document assumes you’re familiar with Godot’s various physics bodies. Please read Physics introduction first.

## What is a kinematic body?¶

`KinematicBody2D` is for implementing bodies that are to be controlled via code. They detect collisions with other bodies when moving, but are not affected by engine physics properties like gravity or friction. While this means that you have to write some code to create their behavior, it also means you have more precise control over how they move and react.

Tip

A KinematicBody2D can be affected by gravity and other forces, but you must calculate the movement in code. The physics engine will not move a KinematicBody2D.

## Movement and Collision¶

When moving a `KinematicBody2D`, you should not set its `position` property directly. Instead, you use the `move_and_collide()` or `move_and_slide()` methods. These methods move the body along a given vector and will instantly stop if a collision is detected with another body. After a KinematicBody2D has collided, any collision response must be coded manually.

Warning

Kinematic body movement should only be done in the `_physics_process()` callback.

The two movement methods serve different purposes, and later in this tutorial you’ll see examples of how they work.

### `move_and_collide`¶

This method takes one parameter: a Vector2 indicating the body’s relative movement. Typically, this is your velocity vector multiplied by the frame timestep (`delta`). If the engine detects a collision anywhere along this vector, the body will immediately stop moving. If this happens, the method will return a KinematicCollision2D object.

`KinematicCollision2D` is an object containing data about the collision and the colliding object. Using this data you can calculate your collision response.

### `move_and_slide`¶

The `move_and_slide()` method is intended to simplify the collision response in the common case where you want one body to slide along the other. This is especially useful in platformers or top-down games, for example.

Tip

`move_and_slide()` automatically calculates frame-based movement using `delta`. Do not multiply your velocity vector by `delta` before passing it to `move_and_slide()`.

In addition to the velocity vector, `move_and_slide()` takes a number of other parameters allowing you to customize the slide behavior:

• `floor_normal` - default value: `Vector2( 0, 0 )`

This parameter allows you to define what surfaces the engine should consider to be the floor. Setting this lets you use the `is_on_floor()`, `is_on_wall()`, and `is_on_ceiling()` methods to detect what type of surface the body is in contact with. The default value means that all surfaces are considered walls.

• `slope_stop_min_velocity` - default value: `5`

This is the minimum velocity when standing on a slope. This prevents a body from sliding down a slope when standing still.

• `max_bounces` - default value: `4`

This is the maximum number of collisions before the body stops moving. Setting this too low may prevent movement entirely.

• `floor_max_angle` - default value: `0.785398` (in radians, equivalent to `45` degrees)

This is the maximum angle before a surface is no longer considered a “floor”.

## Which movement method to use?¶

A common question from new Godot users is: “How do you decide which movement function to use?” Often the response is to use `move_and_slide()` because it’s “simpler”, but this is not necessarily the case. One way to think of it is that `move_and_slide()` is a special case, and `move_and_collide()` is more general. For example, the following two code snippets result in the same collision response:

```# using move_and_collide
var collision = move_and_collide(velocity * delta)
if collision:
velocity = velocity.slide(collision.normal)

# using move_and_slide
velocity = move_and_slide(velocity)
```
```// using MoveAndCollide
var collision = MoveAndCollide(velocity * delta);
if (collision != null)
{
velocity = velocity.Slide(collision.Normal);
}
// using MoveAndSlide
velocity = MoveAndSlide(velocity);
```

Anything you do with `move_and_slide()` can also be done with `move_and_collide()`, but it might take a little more code. However, as we’ll see in the examples below, there are cases where `move_and_slide()` doesn’t provide the response you want.

## Examples¶

To see these examples in action, download the sample project: `using_kinematic2d.zip`.

### Movement and walls¶

If you’ve downloaded the sample project, this example is in the “BasicMovement.tscn” scene.

For this example, Add a `KinematicBody2D` with two children: a `Sprite` and a `CollisionShape2D`. Use the Godot “icon.png” as the Sprite’s texture (drag it from the Filesystem dock to the Texture property of the `Sprite`). In the `CollisionShape2D`’s Shape property, select “New RectangleShape2D” and size the rectangle to fit over the sprite image.

Note

See 2D Movement Overview for examples of implementing 2D movement schemes.

Attach a script to the KinematicBody2D and add the following code:

```extends KinematicBody2D

var speed = 250
var velocity = Vector2()

func get_input():
# Detect up/down/left/right keystate and only move when pressed
velocity = Vector2()
if Input.is_action_pressed('ui_right'):
velocity.x += 1
if Input.is_action_pressed('ui_left'):
velocity.x -= 1
if Input.is_action_pressed('ui_down'):
velocity.y += 1
if Input.is_action_pressed('ui_up'):
velocity.y -= 1
velocity = velocity.normalized() * speed

func _physics_process(delta):
get_input()
move_and_collide(velocity * delta)
```
```using Godot;
using System;

public class KBExample : KinematicBody2D
{
public int Speed = 250;
private Vector2 _velocity = new Vector2();

public void getInput()
{
// Detect up/down/left/right keystate and only move when pressed
_velocity = new Vector2();
if (Input.IsActionPressed("ui_right"))
{
_velocity.x += 1;
}
if (Input.IsActionPressed("ui_left"))
{
_velocity.x -= 1;
}
if (Input.IsActionPressed("ui_down"))
{
_velocity.y += 1;
}
if (Input.IsActionPressed("ui_up"))
{
_velocity.y -= 1;
}
}

public override void _PhysicsProcess(float delta)
{
getInput();
MoveAndCollide(velocity * delta);
}
}
```

Run this scene and you’ll see that `move_and_collide()` works as expected, moving the body along the velocity vector. Now let’s see what happens when you add some obstacles. Add a StaticBody2D with a rectangular collision shape. For visibility, you can use a sprite, a Polygon2D, or turn on “Visible Collision Shapes” from the “Debug” menu.

Run the scene again and try moving into the obstacle. You’ll see that the `KinematicBody2D` can’t penetrate the obstacle. However, try moving into the obstacle at an angle and you’ll find that the obstacle acts like glue - it feels like the body gets stuck.

This happens because there is no collision response. `move_and_collide()` stops the body’s movement when a collision occurs. We need to code whatever response we want from the collision.

Try changing the function to `move_and_slide(velocity)` and running again. Note that we removed `delta` from the velocity calculation.

`move_and_slide()` provides a default collision response of sliding the body along the collision object. This is useful for a great many game types, and may be all you need to get the behavior you want.

### Bouncing/reflecting¶

What if you don’t want a sliding collision response? For this example (“BounceandCollide.tscn” in the sample project), we have a character shooting bullets and we want the bullets to bounce off the walls.

This example uses three scenes. The main scene contains the Player and Walls. The Bullet and Wall are separate scenes so that they can be instanced.

The Player is controlled by the w and s keys for forward and back. Aiming uses the mouse pointer. Here is the code for the Player, using `move_and_slide()`:

```extends KinematicBody2D

var Bullet = preload("res://Bullet.tscn")
var speed = 200
var velocity = Vector2()

func get_input():
# add these actions in Project Settings -> Input Map
velocity = Vector2()
if Input.is_action_pressed('backward'):
velocity = Vector2(-speed/3, 0).rotated(rotation)
if Input.is_action_pressed('forward'):
velocity = Vector2(speed, 0).rotated(rotation)
if Input.is_action_just_pressed('mouse_click'):
shoot()

func shoot():
# "Muzzle" is a Position2D placed at the barrel of the gun
var b = Bullet.instance()
b.start(\$Muzzle.global_position, rotation)

func _physics_process(delta):
get_input()
var dir = get_global_mouse_position() - global_position
# Don't move if too close to the mouse pointer
if dir.length() > 5:
rotation = dir.angle()
velocity = move_and_slide(velocity)
```
```using Godot;
using System;

public class KBExample : KinematicBody2D
{
private PackedScene _bullet = (PackedScene)GD.Load("res://Bullet.tscn");
public int Speed = 200;
private Vector2 _velocity = new Vector2();

public void getInput()
{
// add these actions in Project Settings -> Input Map
_velocity = new Vector2();
if (Input.IsActionPressed("backward"))
{
_velocity = new Vector2(-speed/3, 0).Rotated(Rotation);
}
if (Input.IsActionPressed("forward"))
{
_velocity = new Vector2(speed, 0).Rotated(Rotation);
}
if (Input.IsActionPressed("mouse_click"))
{
Shoot();
}
}

public void Shoot()
{
// "Muzzle" is a Position2D placed at the barrel of the gun
var b = (Bullet)_bullet.Instance();
b.Start(((Node2D)GetNode("Muzzle")).GlobalPosition, Rotation);
}

public override void _PhysicsProcess(float delta)
{
getInput();
var dir = GetGlobalMousePosition() - GlobalPosition;
// Don't move if too close to the mouse pointer
if (dir.Length() > 5)
{
Rotation = dir.Angle();
_velocity = MoveAndSlide(_velocity);
}
}
}
```

And the code for the Bullet:

```extends KinematicBody2D

var speed = 750
var velocity = Vector2()

func start(pos, dir):
rotation = dir
position = pos
velocity = Vector2(speed, 0).rotated(rotation)

func _physics_process(delta):
var collision = move_and_collide(velocity * delta)
if collision:
velocity = velocity.bounce(collision.normal)
if collision.collider.has_method("hit"):
collision.collider.hit()

func _on_VisibilityNotifier2D_screen_exited():
queue_free()
```
```using Godot;
using System;

public class Bullet : KinematicBody2D
{
public int Speed = 750;
private Vector2 _velocity = new Vector2();

public void Start(Vector2 pos, float dir)
{
Rotation = dir;
Position = pos;
_velocity = new Vector2(speed, 0).Rotated(Rotation);
}

public override void _PhysicsProcess(float delta)
{
var collsion = MoveAndCollide(_velocity * delta);
if (collsion != null)
{
_velocity = _velocity.Bounce(collsion.Normal);
if (collsion.Collider.HasMethod("Hit"))
{
collsion.Collider.Hit();
}
}
}

public void OnVisibilityNotifier2DScreenExited()
{
QueueFree();
}
}
```

The action happens in `_physics_process()`. After using `move_and_collide()` if a collision occurs, a `KinematicCollision2D` object is returned (otherwise, the return is `Nil`).

If there is a returned collision, we use the `normal` of the collision to reflect the bullet’s `velocity` with the `Vector2.bounce()` method.

If the colliding object (`collider`) has a `hit` method, we also call it. In the example project, we’ve added a flashing color effect to the Wall to demonstrate this.

### Platformer movement¶

Let’s try one more popular example: the 2D platformer. `move_and_slide()` is ideal for quickly getting a functional character controller up and running. If you’ve downloaded the sample project, you can find this in “Platformer.tscn”.

For this example, we’ll assume you have a level made of `StaticBody2D` objects. They can be any shape and size. In the sample project, we’re using Polygon2D to create the platform shapes.

Here’s the code for the player body:

```extends KinematicBody2D

export (int) var run_speed = 100
export (int) var jump_speed = -400
export (int) var gravity = 1200

var velocity = Vector2()
var jumping = false

func get_input():
velocity.x = 0
var right = Input.is_action_pressed('ui_right')
var left = Input.is_action_pressed('ui_left')
var jump = Input.is_action_just_pressed('ui_select')

if jump and is_on_floor():
jumping = true
velocity.y = jump_speed
if right:
velocity.x += run_speed
if left:
velocity.x -= run_speed

func _physics_process(delta):
get_input()
velocity.y += gravity * delta
if jumping and is_on_floor():
jumping = false
velocity = move_and_slide(velocity, Vector2(0, -1))
```
```using Godot;
using System;

public class KBExample : KinematicBody2D
{
[Export] public int RunSpeed = 100;
[Export] public int JumpSpeed = -400;
[Export] public int Gravity = 1200;

Vector2 velocity = new Vector2();
bool jumping = false;

public void getInput()
{
velocity.x = 0;
bool right = Input.IsActionPressed("ui_right");
bool left = Input.IsActionPressed("ui_left");
bool jump = Input.IsActionPressed("ui_select");

if (jump && IsOnFloor())
{
jumping = true;
velocity.y = JumpSpeed;
}
if (right)
{
velocity.x += RunSpeed;
}
if (left)
{
velocity.x -= RunSpeed;
}
}

public override void _PhysicsProcess(float delta)
{
getInput();
velocity.y += Gravity * delta;
if (jumping && IsOnFloor())
{
jumping = false;
}
velocity = MoveAndSlide(velocity, new Vector2(0, -1));
}
}
```

When using `move_and_slide()` the function returns a vector representing the movement that remained after the slide collision occurred. Setting that value back to the character’s `velocity` allows us to smoothly move up and down slopes. Try removing `velocity =` and see what happens if you don’t do this.

Also note that we’ve added `Vector2(0, -1)` as the floor normal. This is a vector pointing straight upward. This means that if the character collides with an object that has this normal, it will be considered a floor.

Using the floor normal allows us to make jumping work, using `is_on_floor()`. This function will only return `true` after a `move_and_slide()` collision where the colliding body’s normal is within 45 degrees of the given floor vector (this can be adjusted by setting `floor_max_angle`).

This also allows you to implement other features like wall jumps using `is_on_wall()`, for example.