# Flatten (an irregular) list of lists in Python

Yes, I know this subject has been covered before (here, here, here, here), but as far as I know, all solutions, except for one, fail on a list like this:

``````L = [[[1, 2, 3], [4, 5]], 6]
``````

Where the desired output is

``````[1, 2, 3, 4, 5, 6]
``````

Or perhaps even better, an iterator. The only solution I saw that works for an arbitrary nesting is found in this question:

``````def flatten(x):
result = []
for el in x:
if hasattr(el, "__iter__") and not isinstance(el, basestring):
result.extend(flatten(el))
else:
result.append(el)
return result

flatten(L)
``````

Is this the best model? Did I overlook something? Any problems?

-
list(ast.literal_eval(str(l).replace('[','').replace(']',''))) –  VIKASH JAISWAL Nov 7 at 9:59

Using generator functions can make your example a little easier to read and probably boost the performance.

``````def flatten(l):
for el in l:
if isinstance(el, collections.Iterable) and not isinstance(el, basestring):
for sub in flatten(el):
yield sub
else:
yield el
``````

I used the Iterable ABC added in 2.6.

-
I like that this is a generator, and very clear. Adding a guard against having a string in the list (not in the original spec, but will definitely blow the recursion limit), would make it perfect. –  telliott99 Jan 29 '10 at 0:04
You're right. I added a string check. –  Cristian Jan 29 '10 at 0:24
Of all the suggestions on this page, this is the only one that flattened this list `l = ([[chr(i),chr(i-32)] for i in xrange(ord('a'), ord('z')+1)] + range(0,9))` in a snap when i did this `list(flatten(l))`. All the others, would start working and take forever! –  nemesisfixx Jun 7 '12 at 15:04
This flattened my tuple of strings and lists containing strings that I was using as `*args` in a function I wrote... thank you! –  2rs2ts May 31 at 23:33

Generator version of @unutbu's non-recursive solution, as requested by @Andrew in a comment:

``````def genflat(l, ltypes=collections.Sequence):
l = list(l)
i = 0
while i < len(l):
while isinstance(l[i], ltypes):
if not l[i]:
l.pop(i)
i -= 1
break
else:
l[i:i + 1] = l[i]
yield l[i]
i += 1
``````

Slightly simplified version of this generator:

``````def genflat(l, ltypes=collections.Sequence):
l = list(l)
while l:
while l and isinstance(l[0], ltypes):
l[0:1] = l[0]
if l: yield l.pop(0)
``````
-
Thanks, Alex. I will study and try to "grok", as the cool kids say. –  telliott99 Jan 29 '10 at 0:37
it's a pre-order traversal of the tree formed by the nested lists. only the leaves are returned. Note that this implementation will consume the original data structure, for better or worse. Could be fun to write one that both preserves the original tree, but also doesn't have to copy the list entries. –  Andrew Wagner Jan 29 '10 at 8:21
I think you need to test for strings -- eg add "and not isinstance(l[0], basestring)" as in Cristian's solution. Otherwise you get an infinite loop around l[0:1] = l[0] –  c-urchin Nov 30 '10 at 15:21
This is a good example of making a generator, but as c-urchin mentions, the algorithm itself fails when the sequence contains strings. –  Daniel 'Dang' Griffith Oct 26 '12 at 11:58

My solution:

``````def flatten(x):
if isinstance(x, collections.Iterable):
return [a for i in x for a in flatten(i)]
else:
return [x]
``````

A little more concise, but pretty much the same.

-
`import collections` is required, but it works fine for `[[[1, 2, 3], [4, 5]], 6]` –  ferkulat May 24 at 14:17
You can do this without importing anything if you just `try: iter(x)` to test whether it's iterable… But I don't think having to import a stdlib module is a downside worth avoiding. –  abarnert Jul 5 at 8:03

You could simply use the flatten function in the compiler.ast module.

``````>>> from compiler.ast import flatten
>>> flatten([0, [1, 2], [3, 4, [5, 6]], 7])
[0, 1, 2, 3, 4, 5, 6, 7]
``````
-
Nice, but is this documented anywhere? I couldn't find anything on the compiler page. –  snth Feb 27 at 10:52
Just a fair warning that compiler is deprecated. –  2rs2ts May 31 at 23:24

This version of `flatten` avoids python's recursion limit (and thus works with arbitrarily deep, nested iterables). It is a generator which can handle strings and arbitrary iterables (even infinite ones).

``````import itertools as IT
import collections

def flatten(iterable, ltypes=collections.Iterable):
iterable = iter(iterable)
remainder = iterable
while True:
first = next(remainder)
if isinstance(first, ltypes) and not isinstance(first, basestring):
remainder = IT.chain(first, remainder)
first = next(iter(first))
else:
yield first
``````

Here are some examples demonstrating its use:

``````print(list(IT.islice(flatten(IT.repeat(1)),10)))
# [1, 1, 1, 1, 1, 1, 1, 1, 1, 1]

print(list(IT.islice(flatten(IT.chain(IT.repeat(2,3),
{10,20,30},
'foo bar'.split(),
IT.repeat(1),)),10)))
# [2, 2, 2, 10, 20, 30, 'foo', 'bar', 1, 1]

print(list(flatten([[1,2,[3,4]]])))
# [1, 2, 3, 4]

seq = ([[chr(i),chr(i-32)] for i in xrange(ord('a'), ord('z')+1)] + range(0,9))
print(list(flatten(seq)))
# ['a', 'A', 'b', 'B', 'c', 'C', 'd', 'D', 'e', 'E', 'f', 'F', 'g', 'G', 'h', 'H',
# 'i', 'I', 'j', 'J', 'k', 'K', 'l', 'L', 'm', 'M', 'n', 'N', 'o', 'O', 'p', 'P',
# 'q', 'Q', 'r', 'R', 's', 'S', 't', 'T', 'u', 'U', 'v', 'V', 'w', 'W', 'x', 'X',
# 'y', 'Y', 'z', 'Z', 0, 1, 2, 3, 4, 5, 6, 7, 8]
``````

Although `flatten` can handle infinite generators, it can not handle infinite nesting:

``````def infinitely_nested():
while True:
yield IT.chain(infinitely_nested(), IT.repeat(1))

print(list(IT.islice(flatten(infinitely_nested()), 10)))
# hangs
``````
-
So the best answer would be to somehow make this a generator. –  Andrew McGregor Jan 28 '10 at 23:11
Thanks. I will have to study this one a bit. –  telliott99 Jan 29 '10 at 0:07
The L[i:i+1] = L[i] is like magic. Very nice. –  telliott99 Jan 29 '10 at 22:42
great, but avoid calling a variable `l` –  wim Sep 15 at 16:24
@wim: Good idea, thanks. –  unutbu Sep 15 at 17:15

Here is my functional version of recursive flatten which handles both tuples and lists, and lets you throw in any mix of positional arguments. Returns a generator which produces the entire sequence in order, arg by arg:

``````flatten = lambda *n: (e for a in n
for e in (flatten(*a) if isinstance(a, (tuple, list)) else (a,)))
``````

Usage:

``````l1 = ['a', ['b', ('c', 'd')]]
l2 = [0, 1, (2, 3), [[4, 5, (6, 7, (8,), [9]), 10]], (11,)]
print list(flatten(l1, -2, -1, l2))
['a', 'b', 'c', 'd', -2, -1, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11]
``````
-
Got here via a recent dupe of this question –  samplebias Mar 23 '11 at 17:43
great solution, however would be much helpful if you added some comment to describe what `e`, `a`, `n` refer to –  Wolfgang Kuehne Nov 20 at 14:16
``````def flatten(xs):
res = []
def loop(ys):
for i in ys:
if isinstance(i, list):
loop(i)
else:
res.append(i)
loop(xs)
return res
``````
-

Here's another answer that is even more interesting...

``````import re

def Flatten(TheList):
a = str(TheList)
b,crap = re.subn(r'[\[,\]]', ' ', a)
c = b.split()
d = [int(x) for x in c]

return(d)
``````

Basically, it converts the nested list to a string, uses a regex to strip out the nested syntax, and then converts the result back to a (flattened) list.

-

I prefer simple answers. No generators. No recursion or recursion limits. Just iteration:

``````def flatten(TheList):
listIsNested = True

while listIsNested:                 #outer loop
keepChecking = False
Temp = []

for element in TheList:         #inner loop
if isinstance(element,list):
Temp.extend(element)
keepChecking = True
else:
Temp.append(element)

listIsNested = keepChecking     #determine if outer loop exits
TheList = Temp[:]

return TheList
``````

This works with two lists: an inner for loop and an outer while loop.

The inner for loop iterates through the list. If it finds a list element, it (1) uses list.extend() to flatten that part one level of nesting and (2) switches keepChecking to True. keepchecking is used to control the outer while loop. If the outer loop gets set to true, it triggers the inner loop for another pass.

Those passes keep happening until no more nested lists are found. When a pass finally occurs where none are found, keepChecking never gets tripped to true, which means listIsNested stays false and the outer while loop exits.

The flattened list is then returned.

Test-run

``````flatten([1,2,3,4,[100,200,300,[1000,2000,3000]]])
``````

`[1, 2, 3, 4, 100, 200, 300, 1000, 2000, 3000]`

-
I like simple too. In this case though, you iterate over the list as many times as there are nestings or levels. Could get expensive. –  telliott99 Jan 13 '11 at 11:56
@telliott99: You're right if your lists are really big and/or nested to great depths. However, if that isn't the case, then the simpler solution works just as well, and without the deep magic of some of the other answers. There is a place for multi-stage recursive generator comprehensions, but I'm not convinced that should be where you look first. (I guess you know where I fall in the "Worse is Better" debate.) –  clay Jan 14 '11 at 15:11
@telliott99: Or to put that another way, you won't have to "try to Grok" my solution. If performance isn't a bottleneck, what matters most to you as a programmer? –  clay Jan 14 '11 at 15:18

Generator using recursion and duck typing:

``````def flatten(L):
for item in L:
try:
for i in flatten(item):
yield i
except TypeError:
yield item

list(flatten([[[1, 2, 3], [4, 5]], 6]))
>>>[1, 2, 3, 4, 5, 6]
``````
-
+1 for awesomeness! I stole the idea of divide and conquer from merge sort, but it isn't anywhere near as elegant as you answer –  Nick Burns Jul 5 at 10:20
You could make it a little shorter as shown in this answer. –  Noctis Skytower Jul 25 at 20:53

Although an elegant and very pythonic answer has been selected I would present my solution just for the review:

``````def flat(l):
ret = []
for i in l:
if isinstance(i, list) or isinstance(i, tuple):
ret.extend(flat(i))
else:
ret.append(i)
return ret
``````

-
Use `isinstance(i, (tuple, list))`. Initializing empty variables is a flag for me to look to alternate code structures, typically comprehensions, generators, recursion, etc. –  dansalmo Jul 6 at 19:19

I don't see anything like this posted around here and just got here from a closed question on the same subject, but why not just do something like this(if you know the type of the list you want to split):

``````>>> a = [1, 2, 3, 5, 10, [1, 25, 11, [1, 0]]]
>>> g = str(a).replace('[', '').replace(']', '')
>>> b = [int(x) for x in g.split(',') if x.strip()]
``````

You would need to know the type of the elements but I think this can be generalised and in terms of speed I think it would be faster.

-
This is clever (and probably fast)... but it's not very pythonic. –  DanB Jun 9 '12 at 4:54
"why not just do something like this" you say? Because it is very easy to break! Very bad idea. One example, what if your items are strings, not ints? Then if a string contains a '[' you are doomed. And what if your items have no good (or very long) string representation? –  gb. Aug 23 '12 at 4:40

It was fun trying to create a function that could flatten irregular list in Python, but of course that is what Python is for (to make programming fun). The following generator works fairly well with some caveats:

``````def flatten(iterable):
try:
for item in iterable:
yield from flatten(item)
except TypeError:
yield iterable
``````

It will flatten datatypes that you might want left alone (like `bytearray`, `bytes`, and `str` objects). Also, the code relies on the fact that requesting an iterator from a non-iterable raises a `TypeError`.

``````>>> L = [[[1, 2, 3], [4, 5]], 6]
>>> def flatten(iterable):
try:
for item in iterable:
yield from flatten(item)
except TypeError:
yield iterable

>>> list(flatten(L))
[1, 2, 3, 4, 5, 6]
>>>
``````
-

If you like recursion, this might be a solution of interest to you:

``````def f(E):
if E==[]:
return []
elif type(E) != list:
return [E]
else:
a = f(E[0])
b = f(E[1:])
a.extend(b)
return a
``````

I actually adapted this from some practice Scheme code that I had written a while back.

Enjoy!

-

I'm new to python and come from a lisp background. This is what I came up with (check out the var names for lulz):

``````def flatten(lst):
if lst:
car,*cdr=lst
if isinstance(car,(list,tuple)):
if cdr: return flatten(car) + flatten(cdr)
return flatten(car)
if cdr: return [car] + flatten(cdr)
return [car]
``````

Seems to work. Test:

``````flatten((1,2,3,(4,5,6,(7,8,(((1,2)))))))
``````

returns:

``````[1, 2, 3, 4, 5, 6, 7, 8, 1, 2]
``````
-
``````L2 = [o for k in [[j] if not isinstance(j,list) else j for j in [k for i in [[m] if not
isinstance(m,list) else m for m in L] for k in i]] for o in k]
``````
-
That is... nearly impossible to read. –  michaelb958 Jul 2 at 14:28
just one way to solve this problem, it's not graceful indeed –  fotocoder Sep 5 at 8:27

Here's the `compiler.ast.flatten` implementation in 2.7.5:

``````def flatten(seq):
l = []
for elt in seq:
t = type(elt)
if t is tuple or t is list:
for elt2 in flatten(elt):
l.append(elt2)
else:
l.append(elt)
return l
``````

There are better, faster methods (If you've reached here, you have seen them already)

Also note:

Deprecated since version 2.6: The compiler package has been removed in Python 3.

-

This has worked for me (what I needed was to convert a list [of lists]* of strings into a whole string):

``````import itertools

def flatten(input_list):
try:
return "".join(itertools.chain(*input_list))
except TypeError:
return flatten(itertools.chain(*input_list))
``````
-
This is not a valid answer to the question. Try `flatten(L)` on the `L` given by the question. In fact, it seems your function does not work at all as listed. It returns the empty string `''`. You might want to look at the usage of `*` in the argument list. –  cfi Jun 27 at 8:40
I've updated my comment to reflect that the usage was meant for a list [of lists]* of string objects (hence the "" @ line 3 of the flatten function). Thank you for the heads up ;) –  Jay Vercellone Sep 10 at 21:33

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