Flattening a list of NumPy arrays?

It appears that I have data in the format of a list of NumPy arrays (`type() = np.ndarray`):

``````[array([[ 0.00353654]]), array([[ 0.00353654]]), array([[ 0.00353654]]),
array([[ 0.00353654]]), array([[ 0.00353654]]), array([[ 0.00353654]]),
array([[ 0.00353654]]), array([[ 0.00353654]]), array([[ 0.00353654]]),
array([[ 0.00353654]]), array([[ 0.00353654]]), array([[ 0.00353654]]),
array([[ 0.00353654]])]
``````

I am trying to put this into a polyfit function:

``````m1 = np.polyfit(x, y, deg=2)
``````

However, it returns the error: `TypeError: expected 1D vector for x`

I assume I need to flatten my data into something like:

``````[0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654 ...]
``````

I have tried a list comprehension which usually works on lists of lists, but this as expected has not worked:

``````[val for sublist in risks for val in sublist]
``````

What would be the best way to do this?

• @Divakar Thanks! Works for me! Nov 14, 2015 at 19:05
• concatenate assumes that all the arrays are the same size, which may always be the case for you, otherwise check out something like stackoverflow.com/a/406822/1240268. Nov 14, 2015 at 19:40
• Do the arrays all have the same length? Aug 20, 2018 at 16:26
• Not sure if duplicate but definitely related stackoverflow.com/q/28930465/4755520. Jun 13, 2019 at 6:33

You could use `numpy.concatenate`, which as the name suggests, basically concatenates all the elements of such an input list into a single NumPy array, like so -

``````import numpy as np
out = np.concatenate(input_list).ravel()
``````

If you wish the final output to be a list, you can extend the solution, like so -

``````out = np.concatenate(input_list).ravel().tolist()
``````

Sample run -

``````In [24]: input_list
Out[24]:
[array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]])]

In [25]: np.concatenate(input_list).ravel()
Out[25]:
array([ 0.00353654,  0.00353654,  0.00353654,  0.00353654,  0.00353654,
0.00353654,  0.00353654,  0.00353654,  0.00353654,  0.00353654,
0.00353654,  0.00353654,  0.00353654])
``````

Convert to list -

``````In [26]: np.concatenate(input_list).ravel().tolist()
Out[26]:
[0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654,
0.00353654]
``````
• by doing so, I get `ValueError: all the input array dimensions except for the concatenation axis must match exactly` Feb 11, 2018 at 12:09
• @Athena Post a new question please. It's not clear what exactly is the data format. Feb 11, 2018 at 12:36
• @Athena I think I had the same issue: it's because the arrays in the list have different shapes. I was able to get a flattened array using: `np.concatenate(input_list, axis=None).ravel()` Apr 15, 2022 at 5:23

Can also be done by

``````np.array(list_of_arrays).flatten().tolist()
``````

resulting in

``````[0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654]
``````

Update

As @aydow points out in the comments, using `numpy.ndarray.ravel` can be faster if one doesn't care about getting a copy or a view

``````np.array(list_of_arrays).ravel()
``````

Although, according to docs

When a view is desired in as many cases as possible, `arr.reshape(-1)` may be preferable.

In other words

``````np.array(list_of_arrays).reshape(-1)
``````

The initial suggestion of mine was to use `numpy.ndarray.flatten` that returns a copy every time which affects performance.

Let's now see how the time complexity of the above-listed solutions compares using `perfplot` package for a setup similar to the one of the OP

``````import perfplot

perfplot.show(
setup=lambda n: np.random.rand(n, 2),
kernels=[lambda a: a.ravel(),
lambda a: a.flatten(),
lambda a: a.reshape(-1)],
labels=['ravel', 'flatten', 'reshape'],
n_range=[2**k for k in range(16)],
xlabel='N')
``````

Here `flatten` demonstrates piecewise linear complexity which can be reasonably explained by it making a copy of the initial array compare to constant complexities of `ravel` and `reshape` that return a view.

It's also worth noting that, quite predictably, converting the outputs `.tolist()` evens out the performance of all three to equally linear.

• `np.flatten` works, but it's worth noting that it's significantly slower than `np.ravel`. this difference gets worse as the `array` length increases Jun 12, 2019 at 0:27
• @aydow hmm, how so? `np.flatten` is indeed slower but not significantly. I just `%%timeit` both on `list(map(np.array, np.random.rand(1_000_000, 10)))` and `np.concatenate(list_of_arrays).ravel()` takes `290 ms ± 2.49 ms` against `np.array(list_of_arrays).flatten()`'s `446 ms ± 26.5 ms` with both performing seemingly instantaneously without `%%timeit` on my laptop. Jun 12, 2019 at 11:34
• hi @ayorgo, i'm deviating slightly from the OP question. i'm assuming an `np.array` of `np.array`s (which pertained to my own question) rather than a `list` of `np.array`s. using just `np.ravel` takes `249 ns ± 8.43 ns` while using just `np.flatten` takes `25.4 ms ± 244 µs`!! adding `np.concatenate` and `np.array` slows it down to the numbers you've mentioned. apologies for not specifying this in my initial comment Jun 13, 2019 at 0:47
• @aydow haha, indeed! What I believe makes such a difference in performance is that `np.flatten` always returns a copy unlike 'np.ravel' (stackoverflow.com/a/28930580/4755520). The interesting thing also is that the accepted answer doesn't need to use `np.concatenate`. Simply converting to `np.array` and `.ravel()` would suffice. Jun 13, 2019 at 6:32

Another way using `itertools` for flattening the array:

``````import itertools

# Recreating array from question
a = [np.array([[0.00353654]])] * 13

# Make an iterator to yield items of the flattened list and create a list from that iterator
flattened = list(itertools.chain.from_iterable(a))
``````

This solution should be very fast, see https://stackoverflow.com/a/408281/5993892 for more explanation.

If the resulting data structure should be a `numpy` array instead, use `numpy.fromiter()` to exhaust the iterator into an array:

``````# Make an iterator to yield items of the flattened list and create a numpy array from that iterator
flattened_array = np.fromiter(itertools.chain.from_iterable(a), float)
``````

Docs for `itertools.chain.from_iterable()`: https://docs.python.org/3/library/itertools.html#itertools.chain.from_iterable

Docs for `numpy.fromiter()`: https://docs.scipy.org/doc/numpy/reference/generated/numpy.fromiter.html

Another simple approach would be to use `numpy.hstack()` followed by removing the singleton dimension using `squeeze()` as in:

``````In [61]: np.hstack(list_of_arrs).squeeze()
Out[61]:
array([0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654,
0.00353654, 0.00353654, 0.00353654, 0.00353654, 0.00353654,
0.00353654, 0.00353654, 0.00353654])
``````

I came across this same issue and found a solution that combines 1-D numpy arrays of variable length:

``````np.column_stack(input_list).ravel()
``````

Example with variable-length arrays with your example data:

``````In [135]: input_list
Out[135]:
[array([[ 0.00353654,  0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654]]),
array([[ 0.00353654,  0.00353654,  0.00353654]])]

In [136]: [i.size for i in input_list]    # variable size arrays
Out[136]: [2, 1, 1, 3]

In [137]: np.column_stack(input_list).ravel()
Out[137]:
array([ 0.00353654,  0.00353654,  0.00353654,  0.00353654,  0.00353654,
0.00353654,  0.00353654])
``````

Note: Only tested on Python 2.7.12

• I tried this and got `ValueError: all the input array dimensions except for the concatenation axis must match exactly` :(
– Shir
May 2, 2019 at 9:20
• I was able to make it work using `np.hstack` instead of `np.column_stack`. I think this is because my arrays are 1d, and I didn't read the original question carefully enough. Thanks anyway :)
– Shir
May 2, 2019 at 9:30