123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252253254255256257258259260261262263264265266267268269270271272273274275276277278279280281282283284285286287288289290291292293294295296297298299300301302303304305306307308309310311312313314315316317318319320321322323324325326327328329330331332333334335336337338339340341342343344345346347348349350351352353354355356357358359360361362363364365366367368369370371372373374375376377378379380381382383384385386387388389390391392393394395396397398399400401402403404405406407408409410411412413414415416417418419420421422423424425426427428429430431432433434435436437438439440441442443444445446447448449450451452453454455456457458459460461462463464465466467468469470471472473474475476477478479480481482483484485486487488489490491492493494495496497498499500501502503504505506507508509510511512513514515516517518519520521522523524525526527528529530531532533534535536537538539540541542543544545546547548549550551552553554555556557558559560561562563564565566567568569570571572573574575576577578579580581582583584585586587588589590591592593594595596597598599600601602603604605606607608609610611612613614615616617618619620621622623624625626627628629630631632633634635636637638639640641642643644645646 |
- .. _doc_matrices_and_transforms:
- Matrices and transforms
- =======================
- Introduction
- ------------
- Before reading this tutorial, we recommend that you thoroughly read
- and understand the :ref:`doc_vector_math` tutorial, as this tutorial
- requires a knowledge of vectors.
- This tutorial is about *transformations* and how we represent them
- in Godot using matrices. It is not a full in-depth guide to matrices.
- Transformations are most of the time applied as translation, rotation,
- and scale, so we will focus on how to represent those with matrices.
- Most of this guide focuses on 2D, using :ref:`class_Transform2D` and
- :ref:`class_Vector2`, but the way things work in 3D is very similar.
- .. note:: As mentioned in the previous tutorial, it is important to
- remember that in Godot, the Y axis points *down* in 2D.
- This is the opposite of how most schools teach linear
- algebra, with the Y axis pointing up.
- .. note:: The convention is that the X axis is red, the Y axis is
- green, and the Z axis is blue. This tutorial is color-coded
- to match these conventions, but we will also represent
- the origin vector with a blue color.
- Matrix components and the Identity matrix
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- The identity matrix represents a transform with no translation,
- no rotation, and no scale. Let's start by looking at the identity
- matrix and how its components relate to how it visually appears.
- .. image:: img/matrices_and_transforms/identity.png
- Matrices have rows and columns, and a transformation matrix has
- specific conventions on what each does.
- In the image above, we can see that the red X vector is represented
- by the first column of the matrix, and the green Y vector is
- likewise represented by the second column. A change to the columns
- will change these vectors. We will see how they can be manipulated
- in the next few examples.
- You should not worry about manipulating rows directly, as we usually
- work with columns. However, you can think of the rows of the matrix
- as showing which vectors contribute to moving in a given direction.
- When we refer to a value such as ``t.x.y``, that's the Y component of
- the X column vector. In other words, the bottom-left of the matrix.
- Similarly, ``t.x.x`` is top-left, ``t.y.x`` is top-right, and ``t.y.y``
- is bottom-right, where ``t`` is the Transform2D.
- Scaling the transformation matrix
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Applying a scale is one of the easiest operations to understand.
- Let's start by placing the Godot logo underneath our vectors
- so that we can visually see the effects on an object:
- .. image:: img/matrices_and_transforms/identity-godot.png
- Now, to scale the matrix, all we need to do is multiply each
- component by the scale we want. Let's scale it up by 2. 1 times 2
- becomes 2, and 0 times 2 becomes 0, so we end up with this:
- .. image:: img/matrices_and_transforms/scale.png
- To do this in code, we multiply each of the vectors:
- .. tabs::
- .. code-tab:: gdscript GDScript
- var t = Transform2D()
- # Scale
- t.x *= 2
- t.y *= 2
- transform = t # Change the node's transform to what we calculated.
- .. code-tab:: csharp
- Transform2D t = Transform2D.Identity;
- // Scale
- t.X *= 2;
- t.Y *= 2;
- Transform = t; // Change the node's transform to what we calculated.
- If we wanted to return it to its original scale, we can multiply
- each component by 0.5. That's pretty much all there is to scaling
- a transformation matrix.
- To calculate the object's scale from an existing transformation
- matrix, you can use ``length()`` on each of the column vectors.
- .. note:: In actual projects, you can use the ``scaled()``
- method to perform scaling.
- Rotating the transformation matrix
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- We'll start the same way as earlier, with the Godot logo underneath
- the identity matrix:
- .. image:: img/matrices_and_transforms/identity-godot.png
- As an example, let's say we want to rotate our Godot logo clockwise
- by 90 degrees. Right now the X axis points right and the Y axis
- points down. If we rotate these in our head, we would logically
- see that the new X axis should point down and the new Y axis
- should point left.
- You can imagine that you grab both the Godot logo and its vectors,
- and then spin it around the center. Wherever you finish spinning,
- the orientation of the vectors determines what the matrix is.
- We need to represent "down" and "left" in normal coordinates,
- so means we'll set X to (0, 1) and Y to (-1, 0). These are
- also the values of ``Vector2.DOWN`` and ``Vector2.LEFT``.
- When we do this, we get the desired result of rotating the object:
- .. image:: img/matrices_and_transforms/rotate1.png
- If you have trouble understanding the above, try this exercise:
- Cut a square of paper, draw X and Y vectors on top of it, place
- it on graph paper, then rotate it and note the endpoints.
- To perform rotation in code, we need to be able to calculate
- the values programmatically. This image shows the formulas needed
- to calculate the transformation matrix from a rotation angle.
- Don't worry if this part seems complicated, I promise it's the
- hardest thing you need to know.
- .. image:: img/matrices_and_transforms/rotate2.png
- .. note:: Godot represents all rotations with radians, not degrees.
- A full turn is `TAU` or `PI*2` radians, and a quarter
- turn of 90 degrees is `TAU/4` or `PI/2` radians. Working
- with `TAU` usually results in more readable code.
- .. note:: Fun fact: In addition to Y being *down* in Godot, rotation
- is represented clockwise. This means that all the math and
- trig functions behave the same as a Y-is-up CCW system,
- since these differences "cancel out". You can think of
- rotations in both systems being "from X to Y".
- In order to perform a rotation of 0.5 radians (about 28.65 degrees),
- we plug in a value of 0.5 to the formula above and evaluate
- to find what the actual values should be:
- .. image:: img/matrices_and_transforms/rotate3.png
- Here's how that would be done in code (place the script on a Node2D):
- .. tabs::
- .. code-tab:: gdscript GDScript
- var rot = 0.5 # The rotation to apply.
- var t = Transform2D()
- t.x.x = cos(rot)
- t.y.y = cos(rot)
- t.x.y = sin(rot)
- t.y.x = -sin(rot)
- transform = t # Change the node's transform to what we calculated.
- .. code-tab:: csharp
- float rot = 0.5f; // The rotation to apply.
- Transform2D t = Transform2D.Identity;
- t.X.X = t.Y.Y = Mathf.Cos(rot);
- t.X.Y = t.Y.X = Mathf.Sin(rot);
- t.Y.X *= -1;
- Transform = t; // Change the node's transform to what we calculated.
- To calculate the object's rotation from an existing transformation
- matrix, you can use ``atan2(t.x.y, t.x.x)``, where t is the Transform2D.
- .. note:: In actual projects, you can use the ``rotated()``
- method to perform rotations.
- Basis of the transformation matrix
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- So far we have only been working with the ``x`` and ``y``, vectors, which
- are in charge of representing rotation, scale, and/or shearing
- (advanced, covered at the end). The X and Y vectors are together
- called the *basis* of the transformation matrix. The terms "basis"
- and "basis vectors" are important to know.
- You might have noticed that :ref:`class_Transform2D` actually
- has three :ref:`class_Vector2` values: ``x``, ``y``, and ``origin``.
- The ``origin`` value is not part of the basis, but it is part of the
- transform, and we need it to represent position. From now on we'll
- keep track of the origin vector in all examples. You can think of
- origin as another column, but it's often better to think of it as
- completely separate.
- Note that in 3D, Godot has a separate :ref:`class_Basis` structure
- for holding the three :ref:`class_Vector3` values of the basis,
- since the code can get complex and it makes sense to separate
- it from :ref:`class_Transform3D` (which is composed of one
- :ref:`class_Basis` and one extra :ref:`class_Vector3` for the origin).
- Translating the transformation matrix
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Changing the ``origin`` vector is called *translating* the transformation
- matrix. Translating is basically a technical term for "moving" the
- object, but it explicitly does not involve any rotation.
- Let's work through an example to help understand this. We will start
- with the identity transform like last time, except we will keep track
- of the origin vector this time.
- .. image:: img/matrices_and_transforms/identity-origin.png
- If we want to move the object to a position of (1, 2), we need
- to set its ``origin`` vector to (1, 2):
- .. image:: img/matrices_and_transforms/translate.png
- There is also a ``translated_local()`` method, which performs a different
- operation to adding or changing ``origin`` directly. The ``translated_local()``
- method will translate the object *relative to its own rotation*.
- For example, an object rotated 90 degrees clockwise will move to
- the right when ``translated_local()`` with ``Vector2.UP``. To translate
- *relative to the global/parent frame* use ``translated()`` instead.
- .. note:: Godot's 2D uses coordinates based on pixels, so in actual
- projects you will want to translate by hundreds of units.
- Putting it all together
- ~~~~~~~~~~~~~~~~~~~~~~~
- We're going to apply everything we mentioned so far onto one transform.
- To follow along, create a project with a Sprite2D node and use the
- Godot logo for the texture resource.
- Let's set the translation to (350, 150), rotate by -0.5 rad, and scale by 3.
- I've posted a screenshot, and the code to reproduce it, but I encourage
- you to try and reproduce the screenshot without looking at the code!
- .. image:: img/matrices_and_transforms/putting-all-together.png
- .. tabs::
- .. code-tab:: gdscript GDScript
- var t = Transform2D()
- # Translation
- t.origin = Vector2(350, 150)
- # Rotation
- var rot = -0.5 # The rotation to apply.
- t.x.x = cos(rot)
- t.y.y = cos(rot)
- t.x.y = sin(rot)
- t.y.x = -sin(rot)
- # Scale
- t.x *= 3
- t.y *= 3
- transform = t # Change the node's transform to what we calculated.
- .. code-tab:: csharp
- Transform2D t = Transform2D.Identity;
- // Translation
- t.Origin = new Vector2(350, 150);
- // Rotation
- float rot = -0.5f; // The rotation to apply.
- t.X.X = t.Y.Y = Mathf.Cos(rot);
- t.X.Y = t.Y.X = Mathf.Sin(rot);
- t.Y.X *= -1;
- // Scale
- t.X *= 3;
- t.Y *= 3;
- Transform = t; // Change the node's transform to what we calculated.
- Shearing the transformation matrix (advanced)
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- .. note:: If you are only looking for how to *use* transformation matrices,
- feel free to skip this section of the tutorial. This section
- explores an uncommonly used aspect of transformation matrices
- for the purpose of building an understanding of them.
- Node2D provides a shearing property out of the box.
- You may have noticed that a transform has more degrees of freedom than
- the combination of the above actions. The basis of a 2D transformation
- matrix has four total numbers in two :ref:`class_Vector2` values, while
- a rotation value and a Vector2 for scale only has 3 numbers. The high-level
- concept for the missing degree of freedom is called *shearing*.
- Normally, you will always have the basis vectors perpendicular to each
- other. However, shearing can be useful in some situations, and
- understanding shearing helps you understand how transforms work.
- To show you visually how it will look, let's overlay a grid onto the Godot
- logo:
- .. image:: img/matrices_and_transforms/identity-grid.png
- Each point on this grid is obtained by adding the basis vectors together.
- The bottom-right corner is X + Y, while the top-right corner is X - Y.
- If we change the basis vectors, the entire grid moves with it, as the
- grid is composed of the basis vectors. All lines on the grid that are
- currently parallel will remain parallel no matter what changes we make to
- the basis vectors.
- As an example, let's set Y to (1, 1):
- .. image:: img/matrices_and_transforms/shear.png
- .. tabs::
- .. code-tab:: gdscript GDScript
- var t = Transform2D()
- # Shear by setting Y to (1, 1)
- t.y = Vector2.ONE
- transform = t # Change the node's transform to what we calculated.
- .. code-tab:: csharp
- Transform2D t = Transform2D.Identity;
- // Shear by setting Y to (1, 1)
- t.Y = Vector2.One;
- Transform = t; // Change the node's transform to what we calculated.
- .. note:: You can't set the raw values of a Transform2D in the editor,
- so you *must* use code if you want to shear the object.
- Due to the vectors no longer being perpendicular, the object has been
- sheared. The bottom-center of the grid, which is (0, 1) relative
- to itself, is now located at a world position of (1, 1).
- The intra-object coordinates are called UV coordinates in textures,
- so let's borrow that terminology for here. To find the world position
- from a relative position, the formula is U * X + V * Y, where U and V
- are numbers and X and Y are the basis vectors.
- The bottom-right corner of the grid, which is always at the UV position
- of (1, 1), is at the world position of (2, 1), which is calculated from
- X*1 + Y*1, which is (1, 0) + (1, 1), or (1 + 1, 0 + 1), or (2, 1).
- This matches up with our observation of where the bottom-right corner
- of the image is.
- Similarly, the top-right corner of the grid, which is always at the UV
- position of (1, -1), is at the world position of (0, -1), which is calculated
- from X*1 + Y*-1, which is (1, 0) - (1, 1), or (1 - 1, 0 - 1), or (0, -1).
- This matches up with our observation of where the top-right corner
- of the image is.
- Hopefully you now fully understand how a transformation matrix affects
- the object, and the relationship between the basis vectors and how the
- object's "UV" or "intra-coordinates" have their world position changed.
- .. note:: In Godot, all transform math is done relative to the parent node.
- When we refer to "world position", that would be relative to the
- node's parent instead, if the node had a parent.
- If you would like additional explanation, you should check out
- 3Blue1Brown's excellent video about linear transformations:
- https://www.youtube.com/watch?v=kYB8IZa5AuE
- Practical applications of transforms
- ------------------------------------
- In actual projects, you will usually be working with transforms inside
- transforms by having multiple :ref:`class_Node2D` or :ref:`class_Node3D`
- nodes parented to each other.
- However, it's useful to understand how to manually calculate the values we
- need. We will go over how you could use :ref:`class_Transform2D` or
- :ref:`class_Transform3D` to manually calculate transforms of nodes.
- Converting positions between transforms
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- There are many cases where you'd want to convert a position in and out of
- a transform. For example, if you have a position relative to the player
- and would like to find the world (parent-relative) position, or if you
- have a world position and want to know where it is relative to the player.
- We can find what a vector relative to the player would be defined in
- world space as using the ``*`` operator:
- .. tabs::
- .. code-tab:: gdscript GDScript
- # World space vector 100 units below the player.
- print(transform * Vector2(0, 100))
- .. code-tab:: csharp
- // World space vector 100 units below the player.
- GD.Print(Transform * new Vector2(0, 100));
- And we can use the ``*`` operator in the opposite order to find a what world
- space position would be if it was defined relative to the player:
- .. tabs::
- .. code-tab:: gdscript GDScript
- # Where is (0, 100) relative to the player?
- print(Vector2(0, 100) * transform)
- .. code-tab:: csharp
- // Where is (0, 100) relative to the player?
- GD.Print(new Vector2(0, 100) * Transform);
- .. note:: If you know in advance that the transform is positioned at
- (0, 0), you can use the "basis_xform" or "basis_xform_inv"
- methods instead, which skip dealing with translation.
- Moving an object relative to itself
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- A common operation, especially in 3D games, is to move an object relative
- to itself. For example, in first-person shooter games, you would want the
- character to move forward (-Z axis) when you press :kbd:`W`.
- Since the basis vectors are the orientation relative to the parent,
- and the origin vector is the position relative to the parent, we can
- add multiples of the basis vectors to move an object relative to itself.
- This code moves an object 100 units to its own right:
- .. tabs::
- .. code-tab:: gdscript GDScript
- transform.origin += transform.x * 100
- .. code-tab:: csharp
- Transform2D t = Transform;
- t.Origin += t.X * 100;
- Transform = t;
- For moving in 3D, you would need to replace "x" with "basis.x".
- .. note:: In actual projects, you can use ``translate_object_local`` in 3D
- or ``move_local_x`` and ``move_local_y`` in 2D to do this.
- Applying transforms onto transforms
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- One of the most important things to know about transforms is how you
- can use several of them together. A parent node's transform affects
- all of its children. Let's dissect an example.
- In this image, the child node has a "2" after the component names
- to distinguish them from the parent node. It might look a bit
- overwhelming with so many numbers, but remember that each number
- is displayed twice (next to the arrows and also in the matrices),
- and that almost half of the numbers are zero.
- .. image:: img/matrices_and_transforms/apply.png
- The only transformations going on here are that the parent node has
- been given a scale of (2, 1), the child has been given a scale of
- (0.5, 0.5), and both nodes have been given positions.
- All child transformations are affected by the parent transformations.
- The child has a scale of (0.5, 0.5), so you would expect it to be
- a 1:1 ratio square, and it is, but only relative to the parent.
- The child's X vector ends up being (1, 0) in world space, because
- it is scaled by the parent's basis vectors.
- Similarly, the child node's ``origin`` vector is set to (1, 1), but this
- actually moves it (2, 1) in world space, due to the parent node's
- basis vectors.
- To calculate a child transform's world space transform manually, this is
- the code we would use:
- .. tabs::
- .. code-tab:: gdscript GDScript
- # Set up transforms like in the image, except make positions be 100 times bigger.
- var parent = Transform2D(Vector2(2, 0), Vector2(0, 1), Vector2(100, 200))
- var child = Transform2D(Vector2(0.5, 0), Vector2(0, 0.5), Vector2(100, 100))
- # Calculate the child's world space transform
- # origin = (2, 0) * 100 + (0, 1) * 100 + (100, 200)
- var origin = parent.x * child.origin.x + parent.y * child.origin.y + parent.origin
- # basis_x = (2, 0) * 0.5 + (0, 1) * 0
- var basis_x = parent.x * child.x.x + parent.y * child.x.y
- # basis_y = (2, 0) * 0 + (0, 1) * 0.5
- var basis_y = parent.x * child.y.x + parent.y * child.y.y
- # Change the node's transform to what we calculated.
- transform = Transform2D(basis_x, basis_y, origin)
- .. code-tab:: csharp
- // Set up transforms like in the image, except make positions be 100 times bigger.
- Transform2D parent = new Transform2D(2, 0, 0, 1, 100, 200);
- Transform2D child = new Transform2D(0.5f, 0, 0, 0.5f, 100, 100);
- // Calculate the child's world space transform
- // origin = (2, 0) * 100 + (0, 1) * 100 + (100, 200)
- Vector2 origin = parent.X * child.Origin.X + parent.Y * child.Origin.Y + parent.Origin;
- // basisX = (2, 0) * 0.5 + (0, 1) * 0 = (0.5, 0)
- Vector2 basisX = parent.X * child.X.X + parent.Y * child.X.Y;
- // basisY = (2, 0) * 0 + (0, 1) * 0.5 = (0.5, 0)
- Vector2 basisY = parent.X * child.Y.X + parent.Y * child.Y.Y;
- // Change the node's transform to what we calculated.
- Transform = new Transform2D(basisX, basisY, origin);
- In actual projects, we can find the world transform of the child by
- applying one transform onto another using the ``*`` operator:
- .. tabs::
- .. code-tab:: gdscript GDScript
- # Set up transforms like in the image, except make positions be 100 times bigger.
- var parent = Transform2D(Vector2(2, 0), Vector2(0, 1), Vector2(100, 200))
- var child = Transform2D(Vector2(0.5, 0), Vector2(0, 0.5), Vector2(100, 100))
- # Change the node's transform to what would be the child's world transform.
- transform = parent * child
- .. code-tab:: csharp
- // Set up transforms like in the image, except make positions be 100 times bigger.
- Transform2D parent = new Transform2D(2, 0, 0, 1, 100, 200);
- Transform2D child = new Transform2D(0.5f, 0, 0, 0.5f, 100, 100);
- // Change the node's transform to what would be the child's world transform.
- Transform = parent * child;
- .. note:: When multiplying matrices, order matters! Don't mix them up.
- Lastly, applying the identity transform will always do nothing.
- If you would like additional explanation, you should check out
- 3Blue1Brown's excellent video about matrix composition:
- https://www.youtube.com/watch?v=XkY2DOUCWMU
- Inverting a transformation matrix
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- The "affine_inverse" function returns a transform that "undoes" the
- previous transform. This can be useful in some situations.
- Let's take a look at a few examples.
- Multiplying an inverse transform by the normal transform undoes all
- transformations:
- .. tabs::
- .. code-tab:: gdscript GDScript
- var ti = transform.affine_inverse()
- var t = ti * transform
- # The transform is the identity transform.
- .. code-tab:: csharp
- Transform2D ti = Transform.AffineInverse();
- Transform2D t = ti * Transform;
- // The transform is the identity transform.
- Transforming a position by a transform and its inverse results in the
- same position:
- .. tabs::
- .. code-tab:: gdscript GDScript
- var ti = transform.affine_inverse()
- position = transform * position
- position = ti * position
- # The position is the same as before.
- .. code-tab:: csharp
- Transform2D ti = Transform.AffineInverse();
- Position = Transform * Position;
- Position = ti * Position;
- // The position is the same as before.
- How does it all work in 3D?
- ---------------------------
- One of the great things about transformation matrices is that they
- work very similarly between 2D and 3D transformations.
- All the code and formulas used above for 2D work the same in 3D,
- with 3 exceptions: the addition of a third axis, that each
- axis is of type :ref:`class_Vector3`, and also that Godot stores
- the :ref:`class_Basis` separately from the :ref:`class_Transform3D`,
- since the math can get complex and it makes sense to separate it.
- All of the concepts for how translation, rotation, scale, and shearing
- work in 3D are all the same compared to 2D. To scale, we take each
- component and multiply it; to rotate, we change where each basis vector
- is pointing; to translate, we manipulate the origin; and to shear, we
- change the basis vectors to be non-perpendicular.
- .. image:: img/matrices_and_transforms/3d-identity.png
- If you would like, it's a good idea to play around with transforms
- to get an understanding of how they work. Godot allows you to edit
- 3D transform matrices directly from the inspector. You can download
- this project which has colored lines and cubes to help visualize the
- :ref:`class_Basis` vectors and the origin in both 2D and 3D:
- https://github.com/godotengine/godot-demo-projects/tree/master/misc/matrix_transform
- .. UPDATE: May change in future. When you can edit a Node2D's transform matrix
- .. directly, remove or update this note.
- .. note:: You cannot edit Node2D's transform matrix directly in Godot 4.0's
- inspector. This may be changed in a future release of Godot.
- If you would like additional explanation, you should check out
- 3Blue1Brown's excellent video about 3D linear transformations:
- https://www.youtube.com/watch?v=rHLEWRxRGiM
- Representing rotation in 3D (advanced)
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- The biggest difference between 2D and 3D transformation matrices is
- how you represent rotation by itself without the basis vectors.
- With 2D, we have an easy way (atan2) to switch between a transformation
- matrix and an angle. In 3D, rotation is too complex to represent as one
- number. There is something called Euler angles, which can represent
- rotations as a set of 3 numbers, however, they are limited and not very
- useful, except for trivial cases.
- In 3D we do not typically use angles, we either use a transformation basis
- (used pretty much everywhere in Godot), or we use quaternions. Godot can
- represent quaternions using the :ref:`class_Quaternion` struct. My suggestion
- to you is to completely ignore how they work under-the-hood, because
- they are very complicated and unintuitive.
- However, if you really must know how it works, here are some great
- resources, which you can follow in order:
- https://www.youtube.com/watch?v=mvmuCPvRoWQ
- https://www.youtube.com/watch?v=d4EgbgTm0Bg
- https://eater.net/quaternions
|