# Efficient Vector / Point class in Python

What is the best way of implementing an efficient Vector / Point class (or even better: is there one already), that can be used both in Python 2.7+ and 3.x?

I've found the blender-mathutils, but they seem to only support Python 3.x. Then there's this Vector class, that uses numpy, but it's only a 3D vector. Using a list for a Vector like kivy's vector class (sourcecode) that has static attributes (x and y) seems weird too. (There are all these list-methods.)

At the moment I'm using a class that extends namedtuple (as you can see below), but this has the disadvantage of not being able to change the coordinates. I think this can become a performance problem, when thousands of objects are moving and a new (vector) tuple is created everytime. (right?)

``````class Vector2D(namedtuple('Vector2D', ('x', 'y'))):
__slots__ = ()

def __abs__(self):
return type(self)(abs(self.x), abs(self.y))

def __int__(self):
return type(self)(int(self.x), int(self.y))

return type(self)(self.x + other.x, self.y + other.y)

def __sub__(self, other):
return type(self)(self.x - other.x, self.y - other.y)

def __mul__(self, other):
return type(self)(self.x * other, self.y * other)

def __div__(self, other):
return type(self)(self.x / other, self.y / other)

def dot_product(self, other):
return self.x * other.x + self.y * other.y

def distance_to(self, other):
""" uses the Euclidean norm to calculate the distance """
return hypot((self.x - other.x), (self.y - other.y))
``````

Edit: I did some testing and it seems that using `numpy.array` or `numpy.ndarray` as a vector is too slow. (For example getting an item takes almost twice as long, not to mention creating an array. I think it's more optimized for doing calculations on a large number of items.)

So, I'm looking more for a lightweight vector class with a fixed number of fields (in my case just `x` and `y`) that can be used for games. (I don't want to re-invent the wheel if there's already a well-tested one.)

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–  Cody Piersall Oct 18 '13 at 20:50
I think if you're worried so much about performance, you're using the wrong language (don't get me wrong, python's awesome, but CPython is slow; you could try PyPy if you're not relying on third party packages). –  Jonas Wielicki Oct 19 '13 at 15:19
You can try PyPy even if you are relying on (some) third-party packages. :) In particular, pure-Python packages should work, and some non pure-Python packages have been ported, or are being ported (at least partially). –  EOL Oct 20 '13 at 9:58
Good point, about the speed comparison between `namedtuple` and `ndarray`. I obtain similar results for the sum and multiplication by a number (NumPy is slower on 2 coordinates). –  EOL Oct 20 '13 at 10:03
I checked another pure-Python implementation of a 2D vector, but it is slower than what you propose, for coordinate access. It is also more general… I have never seen a 2D or 3D optimized vector implementation for Python: I would guess that implementing it yourself is the best option. You can even publish the result on the Python Package Index. :) –  EOL Oct 20 '13 at 10:12

Yeah, there is a vector class: it's in the de facto standard NumPy module. You create vectors like so:

``````>>> v = numpy.array([1, 10, 123])
>>> 2*v
array([  2,  20, 246])
>>> u = numpy.array([1, 1, 1])
>>> v-u
array([  0,   9, 122])
``````

NumPy is very rich and gives you access to fast array operations: dot product (`numpy.dot()`), norm (`numpy.linalg.norm()`), etc.

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Thanks! Do you know a clean wrapper class that uses numpy for 2D vectors? (numpy.array is full of other methods that aren't needed for vectors) –  Joschua Oct 18 '13 at 20:34
There is a subclass of `np.ndarray` called `np.matrix`. It's not cleaner, but if you have two `matrix`es, `A*B` provides the matrix product of the two (as in, `np.dot(A,B)` if they are dual vectors) –  askewchan Oct 18 '13 at 20:48
I updated my question in regard to using numpy. –  Joschua Oct 19 '13 at 10:35

The vector class in `numpy` in terms of linear algebra would probably be the `numpy.matrix` which is a subclass of `numpy.ndarray`. It's not cleaner per se but it makes your code cleaner because algebraic operations are assumed instead of elementwise.

``````In [77]: a = np.array([1,2])

In [78]: b = np.array([3,3])

In [79]: a*b
Out[79]: array([3, 6])

In [80]: np.dot(a,b)
Out[80]: 9

In [81]: np.outer(a,b)
Out[81]:
array([[3, 3],
[6, 6]])

In [82]: a = np.matrix(a).T

In [83]: b = np.matrix(b)

In [84]: b*a
Out[84]: matrix([[9]])

In [85]: a*b
Out[85]:
matrix([[3, 3],
[6, 6]])
``````

If you want to create your own, base it on one of these, for example:

``````class v2d(np.ndarray):
def __abs__(self):
return np.linalg.norm(self)
def dist(self,other):
return np.linalg.norm(self-other)
def dot(self, other):
return np.dot(self, other)
# and so on
``````

Which in the simplest case you can just make by viewing an `ndarray` as your new class:

``````In [63]: a = np.array([1,2]).view(v2d)

In [64]: b = np.array([3,3]).view(v2d)

In [65]: a
Out[65]: v2d([1, 2])

In [66]: abs(b)
Out[66]: 4.2426406871192848

In [67]: a - b
Out[67]: v2d([-2, -1])

In [68]: a*b
Out[68]: v2d([3, 6])

In [69]: a*3
Out[69]: v2d([3, 6])

In [70]: a.dist(b)
Out[70]: 2.2360679774997898

In [71]: b.dist(a)
Out[71]: 2.2360679774997898

In [72]: a.dot(b)
Out[72]: 9
``````

Here is more information on subclassing the `ndarray`.

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Thank you, but I updated my question in regard to numpy. –  Joschua Oct 19 '13 at 10:36