RigidBody3D
Inherits: PhysicsBody3D < CollisionObject3D < Node3D < Node < Object
Inherited By: VehicleBody3D
A 3D physics body that is moved by a physics simulation.
Description
RigidBody3D implements full 3D physics. It cannot be controlled directly, instead, you must apply forces to it (gravity, impulses, etc.), and the physics simulation will calculate the resulting movement, rotation, react to collisions, and affect other physics bodies in its path.
The body’s behavior can be adjusted via lock_rotation, freeze, and freeze_mode. By changing various properties of the object, such as mass, you can control how the physics simulation acts on it.
A rigid body will always maintain its shape and size, even when forces are applied to it. It is useful for objects that can be interacted with in an environment, such as a tree that can be knocked over or a stack of crates that can be pushed around.
If you need to override the default physics behavior, you can write a custom force integration function. See custom_integrator.
Note: Changing the 3D transform or linear_velocity of a RigidBody3D very often may lead to some unpredictable behaviors. If you need to directly affect the body, prefer _integrate_forces as it allows you to directly access the physics state.
Tutorials
Properties
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Methods
void | _integrate_forces(state: PhysicsDirectBodyState3D) virtual |
void | add_constant_central_force(force: Vector3) |
void | add_constant_force(force: Vector3, position: Vector3 = Vector3(0, 0, 0)) |
void | add_constant_torque(torque: Vector3) |
void | apply_central_force(force: Vector3) |
void | apply_central_impulse(impulse: Vector3) |
void | apply_force(force: Vector3, position: Vector3 = Vector3(0, 0, 0)) |
void | apply_impulse(impulse: Vector3, position: Vector3 = Vector3(0, 0, 0)) |
void | apply_torque(torque: Vector3) |
void | apply_torque_impulse(impulse: Vector3) |
get_colliding_bodies() const | |
get_contact_count() const | |
get_inverse_inertia_tensor() const | |
void | set_axis_velocity(axis_velocity: Vector3) |
Signals
Emitted when a collision with another PhysicsBody3D or GridMap occurs. Requires contact_monitor to be set to true
and max_contacts_reported to be set high enough to detect all the collisions. GridMaps are detected if the MeshLibrary has Collision Shape3Ds.
body
the Node, if it exists in the tree, of the other PhysicsBody3D or GridMap.
Emitted when the collision with another PhysicsBody3D or GridMap ends. Requires contact_monitor to be set to true
and max_contacts_reported to be set high enough to detect all the collisions. GridMaps are detected if the MeshLibrary has Collision Shape3Ds.
body
the Node, if it exists in the tree, of the other PhysicsBody3D or GridMap.
body_shape_entered(body_rid: RID, body: Node, body_shape_index: int, local_shape_index: int) 🔗
Emitted when one of this RigidBody3D’s Shape3Ds collides with another PhysicsBody3D or GridMap‘s Shape3Ds. Requires contact_monitor to be set to true
and max_contacts_reported to be set high enough to detect all the collisions. GridMaps are detected if the MeshLibrary has Collision Shape3Ds.
body_rid
the RID of the other PhysicsBody3D or MeshLibrary‘s CollisionObject3D used by the PhysicsServer3D.
body
the Node, if it exists in the tree, of the other PhysicsBody3D or GridMap.
body_shape_index
the index of the Shape3D of the other PhysicsBody3D or GridMap used by the PhysicsServer3D. Get the CollisionShape3D node with body.shape_owner_get_owner(body.shape_find_owner(body_shape_index))
.
local_shape_index
the index of the Shape3D of this RigidBody3D used by the PhysicsServer3D. Get the CollisionShape3D node with self.shape_owner_get_owner(self.shape_find_owner(local_shape_index))
.
body_shape_exited(body_rid: RID, body: Node, body_shape_index: int, local_shape_index: int) 🔗
Emitted when the collision between one of this RigidBody3D’s Shape3Ds and another PhysicsBody3D or GridMap‘s Shape3Ds ends. Requires contact_monitor to be set to true
and max_contacts_reported to be set high enough to detect all the collisions. GridMaps are detected if the MeshLibrary has Collision Shape3Ds.
body_rid
the RID of the other PhysicsBody3D or MeshLibrary‘s CollisionObject3D used by the PhysicsServer3D. GridMaps are detected if the Meshes have Shape3Ds.
body
the Node, if it exists in the tree, of the other PhysicsBody3D or GridMap.
body_shape_index
the index of the Shape3D of the other PhysicsBody3D or GridMap used by the PhysicsServer3D. Get the CollisionShape3D node with body.shape_owner_get_owner(body.shape_find_owner(body_shape_index))
.
local_shape_index
the index of the Shape3D of this RigidBody3D used by the PhysicsServer3D. Get the CollisionShape3D node with self.shape_owner_get_owner(self.shape_find_owner(local_shape_index))
.
sleeping_state_changed() 🔗
Emitted when the physics engine changes the body’s sleeping state.
Note: Changing the value sleeping will not trigger this signal. It is only emitted if the sleeping state is changed by the physics engine or emit_signal("sleeping_state_changed")
is used.
Enumerations
enum FreezeMode: 🔗
FreezeMode FREEZE_MODE_STATIC = 0
Static body freeze mode (default). The body is not affected by gravity and forces. It can be only moved by user code and doesn’t collide with other bodies along its path.
FreezeMode FREEZE_MODE_KINEMATIC = 1
Kinematic body freeze mode. Similar to FREEZE_MODE_STATIC, but collides with other bodies along its path when moved. Useful for a frozen body that needs to be animated.
enum CenterOfMassMode: 🔗
CenterOfMassMode CENTER_OF_MASS_MODE_AUTO = 0
In this mode, the body’s center of mass is calculated automatically based on its shapes. This assumes that the shapes’ origins are also their center of mass.
CenterOfMassMode CENTER_OF_MASS_MODE_CUSTOM = 1
In this mode, the body’s center of mass is set through center_of_mass. Defaults to the body’s origin position.
enum DampMode: 🔗
DampMode DAMP_MODE_COMBINE = 0
In this mode, the body’s damping value is added to any value set in areas or the default value.
DampMode DAMP_MODE_REPLACE = 1
In this mode, the body’s damping value replaces any value set in areas or the default value.
Property Descriptions
Damps the body’s rotation. By default, the body will use the Default Angular Damp in Project > Project Settings > Physics > 3d or any value override set by an Area3D the body is in. Depending on angular_damp_mode, you can set angular_damp to be added to or to replace the body’s damping value.
See ProjectSettings.physics/3d/default_angular_damp for more details about damping.
DampMode angular_damp_mode = 0
🔗
Defines how angular_damp is applied. See DampMode for possible values.
Vector3 angular_velocity = Vector3(0, 0, 0)
🔗
The RigidBody3D’s rotational velocity in radians per second.
If true
, the body can enter sleep mode when there is no movement. See sleeping.
Vector3 center_of_mass = Vector3(0, 0, 0)
🔗
The body’s custom center of mass, relative to the body’s origin position, when center_of_mass_mode is set to CENTER_OF_MASS_MODE_CUSTOM. This is the balanced point of the body, where applied forces only cause linear acceleration. Applying forces outside of the center of mass causes angular acceleration.
When center_of_mass_mode is set to CENTER_OF_MASS_MODE_AUTO (default value), the center of mass is automatically computed.
CenterOfMassMode center_of_mass_mode = 0
🔗
void set_center_of_mass_mode(value: CenterOfMassMode)
CenterOfMassMode get_center_of_mass_mode()
Defines the way the body’s center of mass is set. See CenterOfMassMode for possible values.
Vector3 constant_force = Vector3(0, 0, 0)
🔗
The body’s total constant positional forces applied during each physics update.
See add_constant_force and add_constant_central_force.
Vector3 constant_torque = Vector3(0, 0, 0)
🔗
The body’s total constant rotational forces applied during each physics update.
See add_constant_torque.
bool contact_monitor = false
🔗
If true
, the RigidBody3D will emit signals when it collides with another body.
Note: By default the maximum contacts reported is set to 0, meaning nothing will be recorded, see max_contacts_reported.
void set_use_continuous_collision_detection(value: bool)
bool is_using_continuous_collision_detection()
If true
, continuous collision detection is used.
Continuous collision detection tries to predict where a moving body will collide, instead of moving it and correcting its movement if it collided. Continuous collision detection is more precise, and misses fewer impacts by small, fast-moving objects. Not using continuous collision detection is faster to compute, but can miss small, fast-moving objects.
bool custom_integrator = false
🔗
If true
, the standard force integration (like gravity or damping) will be disabled for this body. Other than collision response, the body will only move as determined by the _integrate_forces method, if that virtual method is overridden.
Setting this property will call the method PhysicsServer3D.body_set_omit_force_integration internally.
If true
, the body is frozen. Gravity and forces are not applied anymore.
See freeze_mode to set the body’s behavior when frozen.
For a body that is always frozen, use StaticBody3D or AnimatableBody3D instead.
FreezeMode freeze_mode = 0
🔗
void set_freeze_mode(value: FreezeMode)
FreezeMode get_freeze_mode()
The body’s freeze mode. Can be used to set the body’s behavior when freeze is enabled. See FreezeMode for possible values.
For a body that is always frozen, use StaticBody3D or AnimatableBody3D instead.
This is multiplied by the global 3D gravity setting found in Project > Project Settings > Physics > 3d to produce RigidBody3D’s gravity. For example, a value of 1 will be normal gravity, 2 will apply double gravity, and 0.5 will apply half gravity to this object.
Vector3 inertia = Vector3(0, 0, 0)
🔗
The body’s moment of inertia. This is like mass, but for rotation: it determines how much torque it takes to rotate the body on each axis. The moment of inertia is usually computed automatically from the mass and the shapes, but this property allows you to set a custom value.
If set to Vector3.ZERO, inertia is automatically computed (default value).
Note: This value does not change when inertia is automatically computed. Use PhysicsServer3D to get the computed inertia.
GDScriptC#
@onready var ball = $Ball
func get_ball_inertia():
return PhysicsServer3D.body_get_direct_state(ball.get_rid()).inverse_inertia.inverse()
private RigidBody3D _ball;
public override void _Ready()
{
_ball = GetNode<RigidBody3D>("Ball");
}
private Vector3 GetBallInertia()
{
return PhysicsServer3D.BodyGetDirectState(_ball.GetRid()).InverseInertia.Inverse();
}
Damps the body’s movement. By default, the body will use the Default Linear Damp in Project > Project Settings > Physics > 3d or any value override set by an Area3D the body is in. Depending on linear_damp_mode, you can set linear_damp to be added to or to replace the body’s damping value.
See ProjectSettings.physics/3d/default_linear_damp for more details about damping.
DampMode linear_damp_mode = 0
🔗
Defines how linear_damp is applied. See DampMode for possible values.
Vector3 linear_velocity = Vector3(0, 0, 0)
🔗
The body’s linear velocity in units per second. Can be used sporadically, but don’t set this every frame, because physics may run in another thread and runs at a different granularity. Use _integrate_forces as your process loop for precise control of the body state.
If true
, the body cannot rotate. Gravity and forces only apply linear movement.
The body’s mass.
int max_contacts_reported = 0
🔗
The maximum number of contacts that will be recorded. Requires a value greater than 0 and contact_monitor to be set to true
to start to register contacts. Use get_contact_count to retrieve the count or get_colliding_bodies to retrieve bodies that have been collided with.
Note: The number of contacts is different from the number of collisions. Collisions between parallel edges will result in two contacts (one at each end), and collisions between parallel faces will result in four contacts (one at each corner).
PhysicsMaterial physics_material_override 🔗
void set_physics_material_override(value: PhysicsMaterial)
PhysicsMaterial get_physics_material_override()
The physics material override for the body.
If a material is assigned to this property, it will be used instead of any other physics material, such as an inherited one.
If true
, the body will not move and will not calculate forces until woken up by another body through, for example, a collision, or by using the apply_impulse or apply_force methods.
Method Descriptions
void _integrate_forces(state: PhysicsDirectBodyState3D) virtual 🔗
Called during physics processing, allowing you to read and safely modify the simulation state for the object. By default, it is called before the standard force integration, but the custom_integrator property allows you to disable the standard force integration and do fully custom force integration for a body.
void add_constant_central_force(force: Vector3) 🔗
Adds a constant directional force without affecting rotation that keeps being applied over time until cleared with constant_force = Vector3(0, 0, 0)
.
This is equivalent to using add_constant_force at the body’s center of mass.
void add_constant_force(force: Vector3, position: Vector3 = Vector3(0, 0, 0)) 🔗
Adds a constant positioned force to the body that keeps being applied over time until cleared with constant_force = Vector3(0, 0, 0)
.
position
is the offset from the body origin in global coordinates.
void add_constant_torque(torque: Vector3) 🔗
Adds a constant rotational force without affecting position that keeps being applied over time until cleared with constant_torque = Vector3(0, 0, 0)
.
void apply_central_force(force: Vector3) 🔗
Applies a directional force without affecting rotation. A force is time dependent and meant to be applied every physics update.
This is equivalent to using apply_force at the body’s center of mass.
void apply_central_impulse(impulse: Vector3) 🔗
Applies a directional impulse without affecting rotation.
An impulse is time-independent! Applying an impulse every frame would result in a framerate-dependent force. For this reason, it should only be used when simulating one-time impacts (use the “_force” functions otherwise).
This is equivalent to using apply_impulse at the body’s center of mass.
void apply_force(force: Vector3, position: Vector3 = Vector3(0, 0, 0)) 🔗
Applies a positioned force to the body. A force is time dependent and meant to be applied every physics update.
position
is the offset from the body origin in global coordinates.
void apply_impulse(impulse: Vector3, position: Vector3 = Vector3(0, 0, 0)) 🔗
Applies a positioned impulse to the body.
An impulse is time-independent! Applying an impulse every frame would result in a framerate-dependent force. For this reason, it should only be used when simulating one-time impacts (use the “_force” functions otherwise).
position
is the offset from the body origin in global coordinates.
void apply_torque(torque: Vector3) 🔗
Applies a rotational force without affecting position. A force is time dependent and meant to be applied every physics update.
Note: inertia is required for this to work. To have inertia, an active CollisionShape3D must be a child of the node, or you can manually set inertia.
void apply_torque_impulse(impulse: Vector3) 🔗
Applies a rotational impulse to the body without affecting the position.
An impulse is time-independent! Applying an impulse every frame would result in a framerate-dependent force. For this reason, it should only be used when simulating one-time impacts (use the “_force” functions otherwise).
Note: inertia is required for this to work. To have inertia, an active CollisionShape3D must be a child of the node, or you can manually set inertia.
Array[Node3D] get_colliding_bodies() const 🔗
Returns a list of the bodies colliding with this one. Requires contact_monitor to be set to true
and max_contacts_reported to be set high enough to detect all the collisions.
Note: The result of this test is not immediate after moving objects. For performance, list of collisions is updated once per frame and before the physics step. Consider using signals instead.
int get_contact_count() const 🔗
Returns the number of contacts this body has with other bodies. By default, this returns 0 unless bodies are configured to monitor contacts (see contact_monitor).
Note: To retrieve the colliding bodies, use get_colliding_bodies.
Basis get_inverse_inertia_tensor() const 🔗
Returns the inverse inertia tensor basis. This is used to calculate the angular acceleration resulting from a torque applied to the RigidBody3D.
void set_axis_velocity(axis_velocity: Vector3) 🔗
Sets an axis velocity. The velocity in the given vector axis will be set as the given vector length. This is useful for jumping behavior.
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