I am using numpy. I have a matrix with 1 column and N rows and I want to get an array from with N elements.

For example, if i have M = matrix([[1], [2], [3], [4]]), I want to get A = array([1,2,3,4]).

To achieve it, I use A = np.array(M.T)[0]. Does anyone know a more elegant way to get the same result?



10 Answers 10


If you'd like something a bit more readable, you can do this:

A = np.squeeze(np.asarray(M))

Equivalently, you could also do: A = np.asarray(M).reshape(-1), but that's a bit less easy to read.

  • 15
    Little rant on my part...why does numpy have arrays and matrices as separate entities. It is so unpythonic IMHO. Thanks for this tip @Joe.
    – Naijaba
    Feb 13, 2015 at 6:37
  • 8
    @Naijaba - For what it's worth, the matrix class is effectively (but not formally) depreciated. It's there mostly for historical purposes. Removing numpy.matrix is a bit of a contentious issue, but the numpy devs very much agree with you that having both is unpythonic and annoying for a whole host of reasons. However, the amount of old, unmaintained code "in the wild" that uses matrix makes it difficult to fully remove it. Feb 13, 2015 at 14:03
  • 1
    Not to mention, true matrix multiplication was only added for arrays in Numpy 1.10, and is basically still in beta. This means that a lot of people (including myself) still have to use matrices instead of arrays to get done what we want done. docs.scipy.org/doc/numpy/reference/generated/numpy.matmul.html Dec 31, 2016 at 2:35
  • 2
    Sparse matrices are fundamental for memory-efficient machine learning (e.g., sklearn). In fact there are different sparse matrix types in scipy, which allow efficient access via rows or columns. I imagine this may be an issue for merging the concepts of matrix and array. That said, I'm wondering whether there could be introduced a sparse array type as well and whether there are any plans for doing that. Any clues?
    – pms
    Mar 4, 2017 at 11:41
  • I think .flatten() works as well as .squeeze(), as long as you want a 1D array in the end. Dec 9, 2017 at 3:35
result = M.A1


1-d base array
  • 8
    I think this answer is better than the accepted answer, performance-wise, and simplicity
    – dariush
    May 20, 2016 at 16:34
  • M.A1 is great, same implementation as "ravel" and "flatten" and in this case doesn't cause any data copy A thus remains linked to M which can cause surprises if A and/or M are mutable. M.flat genuine alternative returning "flatiter" generator (read-only semantics) np.squeeze(M) # gives a view removing dimensions of size 1, ok here too but not guaranteed to be 1-d for general M np.reshape(M,-1) # is usually a view depending on shape compatibility, this "-1" is a roundabout way to do A1/ravel/flatten
    – jayprich
    May 5, 2018 at 23:07
A, = np.array(M.T)

depends what you mean by elegance i suppose but thats what i would do


You can try the following variant:


If you care for speed; But if you care for memory:

  • 2
    It would improve the quality of your answer if you explained why Oct 10, 2019 at 10:45

Or you could try to avoid some temps with

A = M.view(np.ndarray)
A.shape = -1

First, Mv = numpy.asarray(M.T), which gives you a 4x1 but 2D array.

Then, perform A = Mv[0,:], which gives you what you want. You could put them together, as numpy.asarray(M.T)[0,:].


This will convert the matrix into array

A = np.ravel(M).T

ravel() and flatten() functions from numpy are two techniques that I would try here. I will like to add to the posts made by Joe, Siraj, bubble and Kevad.


A = M.ravel()
print A, A.shape
>>> [1 2 3 4] (4,)


M = np.array([[1], [2], [3], [4]])
A = M.flatten()
print A, A.shape
>>> [1 2 3 4] (4,)

numpy.ravel() is faster, since it is a library level function which does not make any copy of the array. However, any change in array A will carry itself over to the original array M if you are using numpy.ravel().

numpy.flatten() is slower than numpy.ravel(). But if you are using numpy.flatten() to create A, then changes in A will not get carried over to the original array M.

numpy.squeeze() and M.reshape(-1) are slower than numpy.flatten() and numpy.ravel().

%timeit M.ravel()
>>> 1000000 loops, best of 3: 309 ns per loop

%timeit M.flatten()
>>> 1000000 loops, best of 3: 650 ns per loop

%timeit M.reshape(-1)
>>> 1000000 loops, best of 3: 755 ns per loop

%timeit np.squeeze(M)
>>> 1000000 loops, best of 3: 886 ns per loop

Came in a little late, hope this helps someone,


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