# How do I make a flat list out of a list of lists?

I have a list of lists like

``````[
[1, 2, 3],
[4, 5, 6],
[7],
[8, 9]
]
``````

How can I flatten it to get `[1, 2, 3, 4, 5, 6, 7, 8, 9]`?

If your list of lists comes from a nested list comprehension, the problem can be solved more simply/directly by fixing the comprehension; please see How can I get a flat result from a list comprehension instead of a nested list?.

The most popular solutions here generally only flatten one "level" of the nested list. See Flatten an irregular (arbitrarily nested) list of lists for solutions that completely flatten a deeply nested structure (recursively, in general).

A list of lists named `xss` can be flattened using a nested list comprehension:

``````flat_list = [
x
for xs in xss
for x in xs
]
``````

The above is equivalent to:

``````flat_list = []

for xs in xss:
for x in xs:
flat_list.append(x)
``````

Here is the corresponding function:

``````def flatten(xss):
return [x for xs in xss for x in xs]
``````

This is the fastest method. As evidence, using the `timeit` module in the standard library, we see:

``````\$ python -mtimeit -s'xss=[[1,2,3],[4,5,6],[7],[8,9]]*99' '[x for xs in xss for x in xs]'
10000 loops, best of 3: 143 usec per loop

\$ python -mtimeit -s'xss=[[1,2,3],[4,5,6],[7],[8,9]]*99' 'sum(xss, [])'
1000 loops, best of 3: 969 usec per loop

\$ python -mtimeit -s'xss=[[1,2,3],[4,5,6],[7],[8,9]]*99' 'reduce(lambda xs, ys: xs + ys, xss)'
1000 loops, best of 3: 1.1 msec per loop
``````

Explanation: the methods based on `+` (including the implied use in `sum`) are, of necessity, `O(L**2)` when there are L sublists -- as the intermediate result list keeps getting longer, at each step a new intermediate result list object gets allocated, and all the items in the previous intermediate result must be copied over (as well as a few new ones added at the end). So, for simplicity and without actual loss of generality, say you have L sublists of M items each: the first M items are copied back and forth `L-1` times, the second M items `L-2` times, and so on; total number of copies is M times the sum of x for x from 1 to L excluded, i.e., `M * (L**2)/2`.

The list comprehension just generates one list, once, and copies each item over (from its original place of residence to the result list) also exactly once.

• I tried a test with the same data, using `itertools.chain.from_iterable` : `\$ python -mtimeit -s'from itertools import chain; l=[[1,2,3],[4,5,6], [7], [8,9]]*99' 'list(chain.from_iterable(l))'`. It runs a bit more than twice as fast as the nested list comprehension that's the fastest of the alternatives shown here. Commented Oct 15, 2010 at 1:21
• I found the syntax hard to understand until I realized you can think of it exactly like nested for loops. for sublist in l: for item in sublist: yield item Commented Jul 27, 2011 at 16:43
• [leaf for tree in forest for leaf in tree] might be easier to comprehend and apply. Commented Aug 29, 2013 at 1:38
• @RobCrowell Same here. To me the list comprehension one doesn't read right, something feels off about it - I always seem to get it wrong and end up googling. To me this reads right `[leaf for leaf in tree for tree in forest]`. I wish this is how it was. I am sure I am missing something about the grammar here, and I would appreciate if anyone could point that out. Commented Jul 12, 2021 at 17:19
• I kept looking here every time I wanted to flatten a list, but this gif is what drove it home: i.sstatic.net/0GoV5.gif Commented Aug 11, 2021 at 12:04

You can use `itertools.chain()`:

``````>>> import itertools
>>> list2d = [[1,2,3], [4,5,6], [7], [8,9]]
>>> merged = list(itertools.chain(*list2d))
``````

Or you can use `itertools.chain.from_iterable()` which doesn't require unpacking the list with the `*` operator:

``````>>> import itertools
>>> list2d = [[1,2,3], [4,5,6], [7], [8,9]]
>>> merged = list(itertools.chain.from_iterable(list2d))
``````

This approach is arguably more readable than `[item for sublist in l for item in sublist]` and appears to be faster too:

``````\$ python3 -mtimeit -s'l=[[1,2,3],[4,5,6], [7], [8,9]]*99;import itertools' 'list(itertools.chain.from_iterable(l))'
20000 loops, best of 5: 10.8 usec per loop
\$ python3 -mtimeit -s'l=[[1,2,3],[4,5,6], [7], [8,9]]*99' '[item for sublist in l for item in sublist]'
10000 loops, best of 5: 21.7 usec per loop
\$ python3 -mtimeit -s'l=[[1,2,3],[4,5,6], [7], [8,9]]*99' 'sum(l, [])'
1000 loops, best of 5: 258 usec per loop
\$ python3 -mtimeit -s'l=[[1,2,3],[4,5,6], [7], [8,9]]*99;from functools import reduce' 'reduce(lambda x,y: x+y,l)'
1000 loops, best of 5: 292 usec per loop
\$ python3 --version
Python 3.7.5rc1
``````
• The `*` is the tricky thing that makes `chain` less straightforward than the list comprehension. You have to know that chain only joins together the iterables passed as parameters, and the * causes the top-level list to be expanded into parameters, so `chain` joins together all those iterables, but doesn't descend further. I think this makes the comprehension more readable than the use of chain in this case. Commented Sep 3, 2014 at 14:13
• @TimDierks: I'm not sure "this requires you to understand Python syntax" is an argument against using a given technique in Python. Sure, complex usage could confuse, but the "splat" operator is generally useful in many circumstances, and this isn't using it in a particularly obscure way; rejecting all language features that aren't necessarily obvious to beginning users means you're tying one hand behind your back. May as well throw out list comprehensions too while you're at it; users from other backgrounds would find a `for` loop that repeatedly `append`s more obvious. Commented Nov 12, 2015 at 20:26
• * creates an intermediary tuple.! `from_iterable` fetch the nested lists directly from the top list. Commented Oct 21, 2021 at 3:35
• To make this more readable, you can make a simple function: `def flatten_list(deep_list: list[list[object]]):` `return list(chain.from_iterable(deep_list))`. The type hinting improves the clarity of what's going on (modern IDEs would interpret this as returning a `list[object]` type). Commented Oct 25, 2021 at 14:34
• Even shorter is `[*chain(*l)]` (`python3.5+`, released 2015) Commented Mar 13, 2023 at 11:51

Note from the author: This is very inefficient. But fun, because monoids are awesome.

``````>>> xss = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
>>> sum(xss, [])
[1, 2, 3, 4, 5, 6, 7, 8, 9]
``````

`sum` sums the elements of the iterable `xss`, and uses the second argument as the initial value `[]` for the sum. (The default initial value is `0`, which is not a list.)

Because you are summing nested lists, you actually get `[1,3]+[2,4]` as a result of `sum([[1,3],[2,4]],[])`, which is equal to `[1,3,2,4]`.

Note that only works on lists of lists. For lists of lists of lists, you'll need another solution.

• that's pretty neat and clever but I wouldn't use it because it's confusing to read. Commented Jun 15, 2010 at 18:55
• This is a Shlemiel the painter's algorithm joelonsoftware.com/articles/fog0000000319.html -- unnecessarily inefficient as well as unnecessarily ugly. Commented Apr 25, 2012 at 18:24
• The append operation on lists forms a `Monoid`, which is one of the most convenient abstractions for thinking of a `+` operation in a general sense (not limited to numbers only). So this answer deserves a +1 from me for (correct) treatment of lists as a monoid. The performance is concerning though... Commented Dec 3, 2014 at 10:35
• this is a very inefficient way because of the quadratic aspect of the sum. Commented Jul 31, 2017 at 18:04
• This article explains the maths of the inefficiency mathieularose.com/how-not-to-flatten-a-list-of-lists-in-python Commented Jan 4, 2018 at 16:46

I tested most suggested solutions with perfplot (a pet project of mine, essentially a wrapper around `timeit`), and found

``````import functools
import operator
functools.reduce(operator.iconcat, a, [])
``````

to be the fastest solution, both when many small lists and few long lists are concatenated. (`operator.iadd` is equally fast.)

A simpler and also acceptable variant is

``````out = []
for sublist in a:
out.extend(sublist)
``````

If the number of sublists is large, this performs a little worse than the above suggestion.

Code to reproduce the plot:

``````import functools
import itertools
import operator

import numpy as np
import perfplot

def forfor(a):
return [item for sublist in a for item in sublist]

def sum_brackets(a):
return sum(a, [])

def functools_reduce(a):
return functools.reduce(operator.concat, a)

def functools_reduce_iconcat(a):
return functools.reduce(operator.iconcat, a, [])

def itertools_chain(a):
return list(itertools.chain.from_iterable(a))

def numpy_flat(a):
return list(np.array(a).flat)

def numpy_concatenate(a):
return list(np.concatenate(a))

def extend(a):
out = []
for sublist in a:
out.extend(sublist)
return out

b = perfplot.bench(
setup=lambda n: [list(range(10))] * n,
# setup=lambda n: [list(range(n))] * 10,
kernels=[
forfor,
sum_brackets,
functools_reduce,
functools_reduce_iconcat,
itertools_chain,
numpy_flat,
numpy_concatenate,
extend,
],
n_range=[2 ** k for k in range(16)],
xlabel="num lists (of length 10)",
# xlabel="len lists (10 lists total)"
)
b.save("out.png")
b.show()
``````
• For huge nested lists,' list(numpy.array(a).flat)' is the fastest among all functions above.
– Sara
Commented Jan 20, 2019 at 13:57
• Is there a way to do a 3-d perfplot? number of arrays by average size of array?
– Leo
Commented Apr 30, 2020 at 0:31
• @Sara can you define "huge" please?
– user3064538
Commented Nov 14, 2020 at 6:05
• Tried `numpy_flat` on the test example from Rossetta Code (link) and got `VisibleDeprecationWarning: Creating an ndarray from ragged nested sequences (which is a list-or-tuple of lists-or-tuples-or ndarrays with different lengths or shapes) is deprecated. If you meant to do this, you must specify 'dtype=object' when creating the ndarray` Commented Dec 5, 2020 at 11:08
• For different sublist lengths, np.array `flat` doesn't work. E.g., `a = [ [1,2], [1,2,3]]` `list(np.array(a).flat)` will return the original list. It's safer to use `list(np.concatenate(a))` Commented Jan 16, 2022 at 6:15

Using `functools.reduce`, which adds an accumulated list `xs` to the next list `ys`:

``````from functools import reduce
xss = [[1,2,3], [4,5,6], [7], [8,9]]
out = reduce(lambda xs, ys: xs + ys, xss)
``````

Output:

``````[1, 2, 3, 4, 5, 6, 7, 8, 9]
``````

A faster way using `operator.concat`:

``````from functools import reduce
import operator
xss = [[1,2,3], [4,5,6], [7], [8,9]]
out = reduce(operator.concat, xss)
``````

Output:

``````[1, 2, 3, 4, 5, 6, 7, 8, 9]
``````
• This is a Shlemiel the painter's algorithm joelonsoftware.com/articles/fog0000000319.html Commented Apr 25, 2012 at 18:26
• `reduce` is very inefficient for this use case as it will repeat copies and generate many unused temporary lists (O(n^2) in both time and possibly space, depending on how the GC decides to clean). It's better to use append or extend. Commented Oct 2, 2020 at 17:00
• this fails if either inner or outer list is empty Commented Apr 26, 2023 at 7:38
• @gntskn: Changing it to `operator.iconcat` (expands `list` in-place, rather than building new one), and passing a third argument of `[]` (so it doesn't modify the first `list` in the input) to `reduce` will fix that issue. Commented Jun 14 at 17:39

Here is a general approach that applies to objects (e.g. numbers, strings) in nested and mixed containers. This can flatten both simple and complicated containers (see also Demo).

Code

``````from typing import Iterable
#from collections import Iterable                            # < py38

def flatten(items):
"""Yield items from any nested iterable; see Reference."""
for x in items:
if isinstance(x, Iterable) and not isinstance(x, (str, bytes)):
for sub_x in flatten(x):
yield sub_x
else:
yield x
``````

Notes:

• In Python 3, `yield from flatten(x)` can replace `for sub_x in flatten(x): yield sub_x`
• In Python 3.8, abstract base classes are moved from `collection.abc` to the `typing` module.

Demo

``````simple = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
list(flatten(simple))
# [1, 2, 3, 4, 5, 6, 7, 8, 9]

complicated = [[1, [2]], (3, 4, {5, 6}, 7), 8, "9"]              # numbers, strs, nested & mixed
list(flatten(complicated))
# [1, 2, 3, 4, 5, 6, 7, 8, '9']
``````

Reference

• This solution is modified from a recipe in Beazley, D. and B. Jones. Recipe 4.14, Python Cookbook 3rd Ed., O'Reilly Media Inc. Sebastopol, CA: 2013.
• Found an earlier SO post, possibly the original demonstration.
• I just wrote pretty much the same, because I didn't see your solution ... here is what I looked for "recursively flatten complete multiple lists" ... (+1) Commented Mar 25, 2017 at 15:32
• @MartinThoma Much appreciated. FYI, if flattening nested iterables is a common practice for you, there are some third-party packages that handle this well. This may save from reinventing the wheel. I've mentioned `more_itertools` among others discussed in this post. Cheers. Commented Mar 25, 2017 at 17:51
• You can check `if hasattr(x, '__iter__')` instead of importing/checking against `Iterable` and that will exclude strings as well. Commented Apr 30, 2018 at 16:46
• the above code doesnt seem to work for if one of the nested lists is having a list of strings. [1, 2, [3, 4], [4], [], 9, 9.5, 'ssssss', ['str', 'sss', 'ss'], [3, 4, 5]] output:- [1, 2, 3, 4, 4, 9, 9.5, 'ssssss', 3, 4, 5] Commented Jun 12, 2019 at 21:35
• @sunnyX It seems to work when I try your input, even with a deeply nested list of strings, e.g. `list(flatten([["a", "b", ["c", "d", ["e", "f", ["g"]]]]]))` -> `['a', 'b', 'c', 'd', 'e', 'f', 'g']`. What version of Python are you using? Commented Jun 12, 2019 at 22:52

To flatten a data-structure that is deeply nested, use `iteration_utilities.deepflatten`1:

``````>>> from iteration_utilities import deepflatten

>>> l = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
>>> list(deepflatten(l, depth=1))
[1, 2, 3, 4, 5, 6, 7, 8, 9]

>>> l = [[1, 2, 3], [4, [5, 6]], 7, [8, 9]]
>>> list(deepflatten(l))
[1, 2, 3, 4, 5, 6, 7, 8, 9]
``````

It's a generator so you need to cast the result to a `list` or explicitly iterate over it.

To flatten only one level and if each of the items is itself iterable you can also use `iteration_utilities.flatten` which itself is just a thin wrapper around `itertools.chain.from_iterable`:

``````>>> from iteration_utilities import flatten
>>> l = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
>>> list(flatten(l))
[1, 2, 3, 4, 5, 6, 7, 8, 9]
``````

Just to add some timings (based on Nico Schlömer's answer that didn't include the function presented in this answer):

It's a log-log plot to accommodate for the huge range of values spanned. For qualitative reasoning: Lower is better.

The results show that if the iterable contains only a few inner iterables then `sum` will be fastest, however for long iterables only the `itertools.chain.from_iterable`, `iteration_utilities.deepflatten` or the nested comprehension have reasonable performance with `itertools.chain.from_iterable` being the fastest (as already noticed by Nico Schlömer).

``````from itertools import chain
from functools import reduce
from collections import Iterable  # or from collections.abc import Iterable
import operator
from iteration_utilities import deepflatten

def nested_list_comprehension(lsts):
return [item for sublist in lsts for item in sublist]

def itertools_chain_from_iterable(lsts):
return list(chain.from_iterable(lsts))

def pythons_sum(lsts):
return sum(lsts, [])

return reduce(lambda x, y: x + y, lsts)

def pylangs_flatten(lsts):
return list(flatten(lsts))

def flatten(items):
"""Yield items from any nested iterable; see REF."""
for x in items:
if isinstance(x, Iterable) and not isinstance(x, (str, bytes)):
yield from flatten(x)
else:
yield x

def reduce_concat(lsts):
return reduce(operator.concat, lsts)

def iteration_utilities_deepflatten(lsts):
return list(deepflatten(lsts, depth=1))

from simple_benchmark import benchmark

b = benchmark(
pylangs_flatten, reduce_concat, iteration_utilities_deepflatten],
arguments={2**i: [[0]*5]*(2**i) for i in range(1, 13)},
argument_name='number of inner lists'
)

b.plot()
``````

1 Disclaimer: I'm the author of that library

The following seems simplest to me:

``````>>> import numpy as np
>>> l = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
>>> print(np.concatenate(l))
[1 2 3 4 5 6 7 8 9]
``````
• OP doesn't mention they want to use numpy. Python has good ways of doing this without relying on a library Commented Oct 3, 2021 at 1:01

Consider installing the `more_itertools` package.

``````> pip install more_itertools
``````

It ships with an implementation for `flatten` (source, from the itertools recipes):

``````import more_itertools

lst = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
list(more_itertools.flatten(lst))
# [1, 2, 3, 4, 5, 6, 7, 8, 9]
``````

Note: as mentioned in the docs, `flatten` requires a list of lists. See below on flattening more irregular inputs.

As of version 2.4, you can flatten more complicated, nested iterables with `more_itertools.collapse` (source, contributed by abarnet).

``````lst = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
list(more_itertools.collapse(lst))
# [1, 2, 3, 4, 5, 6, 7, 8, 9]

lst = [[1, 2, 3], [[4, 5, 6]], [[[7]]], 8, 9]              # complex nesting
list(more_itertools.collapse(lst))
# [1, 2, 3, 4, 5, 6, 7, 8, 9]
``````
• If you can afford adding a package to your project - this answer is best Commented Mar 5, 2020 at 15:53
• it fails when all elements are not list. (e.g. lst=[1, [2,3]]). of course integer is not iterable. Commented Sep 8, 2020 at 8:32
• also, mind that list of strings will be flattened to a list of characters Commented Oct 30, 2020 at 2:05
• I'd reverse the answer, emphasizing `collapse` over `flatten` (leaving it for special case of pure lists of lists). Commented Apr 19, 2023 at 19:23

According your list `[[1, 2, 3], [4, 5, 6], [7], [8, 9]]` which is 1 list level, we can simply use `sum(list,[])` without using any libraries

``````sum([[1, 2, 3], [4, 5, 6], [7], [8, 9]],[])
# [1, 2, 3, 4, 5, 6, 7, 8, 9]
``````

To extend the advantage of this method when there is a tuple or number existing inside. Simply adding a mapping function for each element by `map` to the list

``````#For only tuple
sum(list(map(list,[[1, 2, 3], (4, 5, 6), (7,), [8, 9]])),[])
# [1, 2, 3, 4, 5, 6, 7, 8, 9]

#In general

def convert(x):
if type(x) is int or type(x) is float:
return [x]
else:
return list(x)

sum(list(map(convert,[[1, 2, 3], (4, 5, 6), 7, [8, 9]])),[])
# [1, 2, 3, 4, 5, 6, 7, 8, 9]
``````

In here, there is a clear explanation of the drawback in terms of memory for this approach. In short, it recursively creates list objects, which should be avoided :(

• This answer is already up in this question: stackoverflow.com/a/952946/14273548 Commented Dec 9, 2021 at 9:24
• Neat! Though the other answer here, stackoverflow.com/a/952946/14273548, explains the reasons this solution should generally be avoided (it's inefficient and confusing.)
– Arel
Commented Dec 29, 2021 at 20:29
• Will also give a TypeError if your list contains a tuple Commented Jan 31, 2022 at 18:42

The reason your function didn't work is because the extend extends an array in-place and doesn't return it. You can still return x from lambda, using something like this:

``````reduce(lambda x,y: x.extend(y) or x, l)
``````

Note: extend is more efficient than + on lists.

• `extend` is better used as `newlist = []`, `extend = newlist.extend`, `for sublist in l: extend(l)` as it avoids the (rather large) overhead of the `lambda`, the attribute lookup on `x`, and the `or`.
– agf
Commented Sep 24, 2011 at 10:12
• for python 3 add `from functools import reduce` Commented Jul 2, 2019 at 12:24

`matplotlib.cbook.flatten()` will work for nested lists even if they nest more deeply than the example.

``````import matplotlib
l = [[1, 2, 3], [4, 5, 6], [7], [8, 9]]
print(list(matplotlib.cbook.flatten(l)))
l2 = [[1, 2, 3], [4, 5, 6], [7], [8, [9, 10, [11, 12, [13]]]]]
print(list(matplotlib.cbook.flatten(l2)))
``````

Result:

``````[1, 2, 3, 4, 5, 6, 7, 8, 9]
[1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13]
``````

This is 18x faster than underscore._.flatten:

``````Average time over 1000 trials of matplotlib.cbook.flatten: 2.55e-05 sec
Average time over 1000 trials of underscore._.flatten: 4.63e-04 sec
(time for underscore._)/(time for matplotlib.cbook) = 18.1233394636
``````

One can also use NumPy's flat:

``````import numpy as np
list(np.array(l).flat)
``````

It only works when sublists have identical dimensions.

You can use the `list` `extend` method. It shows to be the fastest:

``````flat_list = []
for sublist in l:
flat_list.extend(sublist)
``````

Performance:

``````import functools
import itertools
import numpy
import operator
import perfplot

def functools_reduce_iconcat(a):
return functools.reduce(operator.iconcat, a, [])

def itertools_chain(a):
return list(itertools.chain.from_iterable(a))

def numpy_flat(a):
return list(numpy.array(a).flat)

def extend(a):
n = []

list(map(n.extend, a))

return n

perfplot.show(
setup = lambda n: [list(range(10))] * n,
kernels = [
functools_reduce_iconcat, extend, itertools_chain, numpy_flat
],
n_range = [2**k for k in range(16)],
xlabel = 'num lists',
)
``````

Output:

There are several answers with the same recursive appending scheme as below, but none makes use of `try`, which makes the solution more robust and Pythonic.

``````def flatten(itr):
for x in itr:
try:
yield from flatten(x)
except TypeError:
yield x
``````

Usage: this is a generator, and you typically want to enclose it in an iterable builder like `list()` or `tuple()` or use it in a `for` loop.

• works with any kind of iterable (even future ones!)
• works with any combination and deepness of nesting
• works also if top level contains bare items
• no dependencies
• fast and efficient (you can flatten the nested iterable partially, without wasting time on the remaining part you don't need)
• versatile (you can use it to build an iterable of your choice or in a loop)

N.B.: Since all iterables are flattened, strings are decomposed into sequences of single characters. If you don't like/want such behavior, you can use the following version which filters out from flattening iterables like strings and bytes:

``````def flatten(itr):
if type(itr) in (str,bytes):
yield itr
else:
for x in itr:
try:
yield from flatten(x)
except TypeError:
yield x
``````
• Wouldn't it be marginally faster if the tuple of types was a hash set? Commented Mar 5, 2023 at 22:14
• @VladimirVilimaitis As stated in answer, the code returns a generator, you can use it directly or create with it a sequence whose type is unrelated to the flattening process, it depends on your needs.
– mmj
Commented Mar 7, 2023 at 9:29

Note: Below applies to Python 3.3+ because it uses `yield_from`. `six` is also a third-party package, though it is stable. Alternately, you could use `sys.version`.

In the case of `obj = [[1, 2,], [3, 4], [5, 6]]`, all of the solutions here are good, including list comprehension and `itertools.chain.from_iterable`.

However, consider this slightly more complex case:

``````>>> obj = [[1, 2, 3], [4, 5], 6, 'abc', [7], [8, [9, 10]]]
``````

There are several problems here:

• One element, `6`, is just a scalar; it's not iterable, so the above routes will fail here.
• One element, `'abc'`, is technically iterable (all `str`s are). However, reading between the lines a bit, you don't want to treat it as such--you want to treat it as a single element.
• The final element, `[8, [9, 10]]` is itself a nested iterable. Basic list comprehension and `chain.from_iterable` only extract "1 level down."

You can remedy this as follows:

``````>>> from collections import Iterable
>>> from six import string_types

>>> def flatten(obj):
...     for i in obj:
...         if isinstance(i, Iterable) and not isinstance(i, string_types):
...             yield from flatten(i)
...         else:
...             yield i

>>> list(flatten(obj))
[1, 2, 3, 4, 5, 6, 'abc', 7, 8, 9, 10]
``````

Here, you check that the sub-element (1) is iterable with `Iterable`, an ABC from `itertools`, but also want to ensure that (2) the element is not "string-like."

• If you are still interested in Python 2 compatibility, change `yield from` to a `for` loop, e.g. `for x in flatten(i): yield x` Commented Jun 19, 2018 at 19:06

If you are willing to give up a tiny amount of speed for a cleaner look, then you could use `numpy.concatenate().tolist()` or `numpy.concatenate().ravel().tolist()`:

``````import numpy

l = [[1, 2, 3], [4, 5, 6], [7], [8, 9]] * 99

%timeit numpy.concatenate(l).ravel().tolist()
1000 loops, best of 3: 313 µs per loop

%timeit numpy.concatenate(l).tolist()
1000 loops, best of 3: 312 µs per loop

%timeit [item for sublist in l for item in sublist]
1000 loops, best of 3: 31.5 µs per loop
``````

You can find out more here in the documentation, numpy.concatenate and numpy.ravel.

• Doesn't work for unevenly nested lists like `[1, 2, [3], [[4]], [5, [6]]]` Commented Apr 22, 2019 at 21:39
• @juanpa.arrivillaga it's a simple and natural extension of the question, though. Answers that can handle greater depth of nesting are more likely to be useful to someone who finds this question. Commented Aug 2, 2021 at 19:53
``````def flatten(alist):
if alist == []:
return []
elif type(alist) is not list:
return [alist]
else:
return flatten(alist[0]) + flatten(alist[1:])
``````
• Fails for python2.7 for the example nested list in the question: `[[1, 2, 3], [4, 5, 6], [7], [8, 9]]` Commented Apr 22, 2019 at 21:34

I wanted a solution which can deal with multiple nesting (`[[1], [[[2]], [3]]], [1, 2, 3]` for example), but would also not be recursive (I had a big level of recursion and I got a recursion error.

This is what I came up with:

``````def _flatten(l) -> Iterator[Any]:
stack = l.copy()
while stack:
item = stack.pop()
if isinstance(item, list):
stack.extend(item)
else:
yield item

def flatten(l) -> Iterator[Any]:
return reversed(list(_flatten(l)))
``````

and tests:

``````@pytest.mark.parametrize('input_list, expected_output', [
([1, 2, 3], [1, 2, 3]),
([[1], 2, 3], [1, 2, 3]),
([[1], [2], 3], [1, 2, 3]),
([[1], [2], [3]], [1, 2, 3]),
([[1], [[2]], [3]], [1, 2, 3]),
([[1], [[[2]], [3]]], [1, 2, 3]),
])
def test_flatten(input_list, expected_output):
assert list(flatten(input_list)) == expected_output
``````

This may not be the most efficient way, but I thought to put a one-liner (actually a two-liner). Both versions will work on arbitrary hierarchy nested lists, and exploits language features (Python 3.5) and recursion.

``````def make_list_flat (l):
flist = []
flist.extend ([l]) if (type (l) is not list) else [flist.extend (make_list_flat (e)) for e in l]
return flist

a = [[1, 2], [[[[3, 4, 5], 6]]], 7, [8, [9, [10, 11], 12, [13, 14, [15, [[16, 17], 18]]]]]]
flist = make_list_flat(a)
print (flist)
``````

The output is

``````[1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18]
``````

This works in a depth first manner. The recursion goes down until it finds a non-list element, then extends the local variable `flist` and then rolls back it to the parent. Whenever `flist` is returned, it is extended to the parent's `flist` in the list comprehension. Therefore, at the root, a flat list is returned.

The above one creates several local lists and returns them which are used to extend the parent's list. I think the way around for this may be creating a gloabl `flist`, like below.

``````a = [[1, 2], [[[[3, 4, 5], 6]]], 7, [8, [9, [10, 11], 12, [13, 14, [15, [[16, 17], 18]]]]]]
flist = []
def make_list_flat (l):
flist.extend ([l]) if (type (l) is not list) else [make_list_flat (e) for e in l]

make_list_flat(a)
print (flist)
``````

The output is again

``````[1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18]
``````

Although I am not sure at this time about the efficiency.

• Why extend([l]) instead of append(l)? Commented Apr 9, 2020 at 18:31

If you want to unnest everything and keep a distinct list of elements, you could use this as well.

``````list_of_lists = [[1,2], [2,3], [3,4]]
list(set.union(*[set(s) for s in list_of_lists]))
``````

Here's an approach I didn't see in the other answers. It supports any level of nesting, works iteratively and without libraries:

``````mylist = [[1,2,4,5],[[0,8,9],5,7],[3,11,[44,45,46],25]]

for i,_ in enumerate(mylist):          # indexes, including extended positions
while isinstance(mylist[i],list):  # drill down/extend current position
mylist[i:i+1] = mylist[i]      # as long as item is a list

print(mylist)
[1, 2, 4, 5, 0, 8, 9, 5, 7, 3, 11, 44, 45, 46, 25]
``````
• Nice not to use stack, but it has very bad time complexity.
– Ry-
Commented Mar 21, 2023 at 22:28

Another unusual approach that works for hetero- and homogeneous lists of integers:

``````from typing import List

def flatten(l: list) -> List[int]:
"""Flatten an arbitrary deep nested list of lists of integers.

Examples:
>>> flatten([1, 2, [1, [10]]])
[1, 2, 1, 10]

Args:
l: Union[l, Union[int, List[int]]

Returns:
Flatted list of integer
"""
return [int(i.strip('[ ]')) for i in str(l).split(',')]
``````
• That's just a more complicated and a bit slower way of what ᴡʜᴀᴄᴋᴀᴍᴀᴅᴏᴏᴅʟᴇ3000 already posted before. I reinvented his proposal yesterday, so this approach seems quite popular these days ;) Commented Jan 10, 2018 at 22:03
• Not quite: `wierd_list = [[1, 2, 3], [4, 5, 6], [7], [8, 9], 10]` >> `nice_list=[1, 2, 3, 4, 5, 6, 7, 8, 9, 1, 0]` Commented Jan 11, 2018 at 8:17
• my code as one liner would be : `flat_list = [int(e.replace('[','').replace(']','')) for e in str(deep_list).split(',')]` Commented Jan 11, 2018 at 8:32
• You are indeed right +1, ᴡʜᴀᴄᴋᴀᴍᴀᴅᴏᴏᴅʟᴇ3000's proposal won't work with multiple digit numbers, I also didn't test this before although it should be obvious. You could simplify your code and write `[int(e.strip('[ ]')) for e in str(deep_list).split(',')]`. But I'd suggest to stick with Deleet's proposal for real use cases. It doesn't contain hacky type transformations, it's faster and more versatile because it naturally also handles lists with mixed types. Commented Jan 11, 2018 at 16:31
• Unfortunately no. But I saw this code recently here: Python Practice Book 6.1.2 Commented Jan 15, 2018 at 8:18

A non-recursive function to flatten lists of lists of any depth:

``````def flatten_list(list1):
out = []
inside = list1
while inside:
x = inside.pop(0)
if isinstance(x, list):
inside[0:0] = x
else:
out.append(x)
return out

l = [[[1,2],3,[4,[[5,6],7],[8]]],[9,10,11]]
flatten_list(l)
# [1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11]
``````

Not a one-liner, but seeing all the answers here, I guess this long list missed some pattern matching, so here it is :)

The two methods are probably not efficient, but anyway, it's easy to read (to me at least; perhaps I'm spoiled by functional programming):

``````def flat(x):
match x:
case []:
return []
case [[*sublist], *r]:
return [*sublist, *flat(r)]
``````

The second version considers lists of lists of lists... whatever the nesting:

``````def flat(x):
match x:
case []:
return []
case [[*sublist], *r]:
return [*flat(sublist), *flat(r)]
case [h, *r]:
return [h, *flat(r)]
``````

If you have a numpy array `a`:

``````a = np.array([[1,2], [3,4]])
a.flatten('C')
``````

produces:

``````[1, 2, 3, 4]
``````

`np.flatten` also accepts other parameters:

• `C`:
• `F`
• `A`
• `K`

More details about parameters are available here.

• This answer only works for rectangular array (matrix) structures and not when the lengths of contained lists are not equal. Commented Apr 19, 2023 at 20:01

I would suggest using generators with a yield statement and yield from.

Here's an example:

``````from collections.abc import Iterable

def flatten(items, ignore_types=(bytes, str)):
"""
Flatten all of the nested lists to the one. Ignoring flatting of iterable types str and bytes by default.
"""
for x in items:
if isinstance(x, Iterable) and not isinstance(x, ignore_types):
yield from flatten(x)
else:
yield x

values = [7, [4, 3, 5, [7, 3], (3, 4), ('A', {'B', 'C'})]]

for v in flatten(values):
print(v)
``````

If I want to add something to the great previous answers, here is my recursive `flatten` function which can flatten not only nested lists, but also any given container or any generally any object which can throw out items. This does also work for any depth of nesting and it is a lazy iterator which yields the items as requested:

``````def flatten(iterable):
# These types won't considered a sequence or generally a container
exclude = str, bytes

for i in iterable:
try:
if isinstance(i, exclude):
raise TypeError
iter(i)
except TypeError:
yield i
else:
yield from flatten(i)
``````

This way, you can exclude types you don't want to be flattened, like `str` or what else.

The idea is if an object can pass the `iter()` it's ready to yield items. So the iterable can have even generator expressions as an item.

Someone could argue: Why did you write this that generic when the OP didn't ask for it? OK, you're right. I just felt like this might help someone (like it did for myself).

Test cases:

``````lst1 = [1, {3}, (1, 6), [[3, 8]], [[[5]]], 9, ((((2,),),),)]
lst2 = ['3', B'A', [[[(i ** 2 for i in range(3))]]], range(3)]

print(list(flatten(lst1)))
print(list(flatten(lst2)))
``````

Output:

``````[1, 3, 1, 6, 3, 8, 5, 9, 2]
['3', b'A', 0, 1, 4, 0, 1, 2]
``````

This uses `parsel.utils.flatten` which is great when it comes to flattening multiple levels of list nesting. I found it useful to avoid overhead of NumPy.

I'll use numbers here for the purpose of simplicity, but but I predominantly used it with strings, which worked pretty fast for my purposes (200 nested lists with each about 40 elements).

``````nested_list = [[1, 2, [3, 4]], [5, [6, [7, 8]]]]
flattened_list = parsel.utils.flatten(nested_list)
print(flattened_list)
-> [1, 2, 3, 4, 5, 6, 7, 8]
``````

I like to add a high performant generator solution which can fatten nested lists (or any kind of iterable) of any depth not (only two-dimensional-lists):

``````from itertools import chain

def flatten_deep_generator(iterable):
iterator = iter(iterable)
try:
while 1: # StopIteration will break the loop
item = next(iterator)
# Check if item contains sub-items
if not hasattr(item,'__trunc__'):
iterator = chain(iter(item), iterator)
else:
yield item
except StopIteration:
pass
``````

Depending on your needs a generators have huge advantages over lists. E.g. If you want add `filter()` functions afterwards. The resulting list should be instanced only at the end after you have constructed the full generator incl. the filtering by this you avoid multiple iterations over the items.

Remark: Compared to the other proposed generator solution this is an iterative and not a recursive solution which avoids RecursionErrors in case of deep nested iterables.

• what is the role of `__trunc__` in this "high performant generator solution"? and why Commented Jun 27, 2023 at 10:21
• The `__trunc__` attribute is used to identify a numerical item or in other words a no more iterable item. It can be that we have some cornercases not covered then you must switch to the slower but more secured way: `hastattr(item,'__iter__') or hasattr(item,'__next__')` The solution should work on any iterable object so we cannot use a checlk like `type(item) is list`. E.g. the solution works on nested iterators, tuples and even strings would be flattend to single characters.
– B.R.
Commented Jun 28, 2023 at 16:49