There is no dedicated type for Euler angles. Instead you would use … drum roll … Vector3
.
In fact, if you see the rotation_degrees
property, you will find it is defined as a Vector3
.
That, of course, isn't the only way to represent rotations/orientations. Ultimately, the Transform has two parts:
- A
Vector3
called origin
which represents the translation.
- A
Basis
called basis
which represent the rest of the transformation (rotation, scaling and reflection, and shear or skewing).
A Basis
can be thought of a trio of Vector3
each representing one of the axis of the coordinate system. Another way to think of Basis
is as a 3 by 3 matrix.
Thus whatever you use to represent rotations or orientations will ultimately be converted to a Basis
(and then either replace or be composed with the Basis
of the transform).
Now, you want to interpolate the rotations, right? Euler angles aren't good for interpolation. Instead you could interpolate:
- Transformations (
Transform
using interpolate_with Transform.interpolate_with
).
- Basis (
Basis
using Basis.slerp
).
- Quaternions (
Quat
using Quat.slerp
).
On the other hand, Euler angles are good for input. In this particular case that means it is relative easy to wrap your head around what the numbers mean compared to writing any of these in the inspector.
Thus, we have two avenues:
- Convert Euler angles to either
Transform
, Basis
or Quat
.
- Find an easy way to input a
Transform
, Basis
or Quat
.
Euler angle to Quat
The Quat
has a constructor that takes a vector for Euler angles. The catch is that it is Euler angles in radians. So we need to convert degrees to radians (which we can do with deg2rad
). Like this:
var target_quat := Quat(
Vector3(
deg2rad(degrees.x),
deg2rad(degrees.y),
deg2rad(degrees.z)
)
)
Alternatively, you could do this:
var target_quat := Quat(degrees * PI / 180.0)
We also need to get the current quaternion from the transform:
var current_quat := transform.basis.get_rotation_quat()
Interpolate them:
var new_quat := current_quat.slerp(target_quat, LEAN_LERP * delta)
And replace the quat:
transform = Transform(
Basis(new_quat).scaled(transform.basis.get_scale()),
transform.origin
)
The above line assumes the transformation is only rotation, scaling, and translation. If we want to keep skewing, we can do this:
transform = Transform(
Basis(new_quat) * Basis(current_quat).inverse() * transform.basis,
transform.origin
)
The explanation for that is in the below section.
Notice we ended up converting the Quat
to a Basis
. So perhaps we are better off avoiding quaternions entirely.
Euler angle to Basis
The Basis
class also has a constructor that works like the one we found in Quat
. So we can do this:
var target_basis := Basis(degrees * PI / 180.0)
The catch this time is that Basis
does not only represent rotation. So if we do that, we are losing scaling (and any other transformation the Basis
has). We can preserve the scaling like this:
target_basis = target_basis.scaled(transform.basis.get_scale())
Ah, of course, the current Basis
is this:
var current_basis := transform.basis
We interpolate like this:
var new_basis := current_basis.slerp(target_basis, LEAN_LERP * delta)
And we replace the Basis
like this:
transform.basis = new_basis
To be honest, I'm not happy with the above approach. I'll show you a way to have the Basis
you interpolate be only for rotation (so it can preserve any skewing the original Basis
had, not only its scale), but it is a little more involved. Let us start here again:
var target_rotation := Basis(degrees * PI / 180.0)
And we will not scale that, instead we want to get a Basis
that is only the rotation of the current one. We can do that by going from Basis
to Quat
and back:
var current_rotation := Basis(transform.basis.get_rotation_quat())
We interpolate the same way as before:
var new_rotation := current_rotation.slerp(target_rotation, LEAN_LERP * delta)
But to replace the Basis
we want to keep everything about the old Basis
that wasn't the rotation. In other words we are going to:
Take the Basis
:
transform.basis
Remove its rotation (i.e. compose it with the inverse of its rotation):
Basis(transform.basis.get_rotation_quat()).inverse() * transform.basis
Which is the same as:
current_rotation.inverse() * transform.basis
And apply the new rotation:
new_rotation * current_rotation.inverse() * transform.basis
And that is what we set:
transform.basis = new_rotation * current_rotation.inverse() * transform.basis
I have tested to make sure the composition order is correct. And, yes, code for preserving skewing with Quat
I showed above is based on this.
Euler angle to Transform
The way to create a Transform
from Euler angles is via a Basis
:
var target_transform := Transform(Basis(degrees * PI / 180.0), Vector3.ZERO)
We could preserve scale and translation with this approach:
var target_transform := Transform(
Basis(degrees * PI / 180.0).scaled(trasnform.basis.get_scale()),
transform.origin
)
If you want to interpolate translation at the same time, you can set your target position instead of transform.origin
.
The current transform is, of course:
var current_transform := transform
We interpolate them like this:
var new_transform = current_transform.interpolate_with(target_transform, LEAN_LERP * delta)
And we can set that:
transform = new_trasnform
If we inline these variables, we have this:
transform = transform.interpolated_with(target_transform, LEAN_LERP * delta)
If you want to preserve skewing, use the Basis
approach.
Alternative input to Euler angles
We have found out that interpolating transforms is actually very easy. Is there a way to easily input a Transform
? Rhetorical question. We can add some Position3D
to the scene. Position and rotate them (and even scale them, even though Position3D
has no size), and then use the Transform
from them.
We can make the Position3D
children of your Spatial
(which is somewhat odd, but don't think too hard about it), or as sibling. Regardless, the idea is that we are going to take the transform
from these Position3D
and use it to interpolate the transform
of your Spatial
. It is the same code as before:
transform = transform.interpolated_with(position.transform, LEAN_LERP * delta)
In fact, while we are at it, why not have three Position3D
:
- The lean left target.
- The lean right target.
- The default target.
Then you pick which target to use depending on input, and interpolate to that:
extends Spatial
const LEAN_LERP = 5
onready var left_target:Position3D = get_node(…)
onready var right_target:Position3D = get_node(…)
onready var default_target:Position3D = get_node(…)
func _process(delta):
var left := Input.is_action_pressed("LeanLeft")
var right := Input.is_action_pressed("LeanRight")
var target := default_target
if left and not right:
target = left_target
if right and not left:
target = right_target
transform = transform.interpolate_with(target, LEAN_LERP * delta)
Put the node paths where I left ...
.
Ok, Ok, here is one of the Euler angles versions:
extends Spatial
const LEAN_LERP = 5
export var default_degrees : Vector3
export var leaning_degrees : Vector3
func _process(delta):
var left := Input.is_action_pressed("LeanLeft")
var right := Input.is_action_pressed("LeanRight")
var degrees := default_degrees
if left and not right:
degrees = -leaning_degrees
if right and not left:
degrees = leaning_degrees
var target_rotation := Basis(degrees * PI / 180.0)
var current_rotation := Basis(transform.basis.get_rotation_quat())
var new_rotation := current_rotation.slerp(target_rotation, LEAN_LERP * delta)
transform.basis = new_rotation * current_rotation.inverse() * transform.basis