# Python - How to sort multidimensional list to two-dimensional list?

How i can sort multidimensional list to two-dimensional list?

Multidimensional input: `[8, [6, 7, [-1], [4, [[10]]], 2], 1]`

Desired two-dimensional output: `[[8, 1], [6, 7, 2], [-1, 4], [], [10]]`

all same depth list items need to be in same list.

• what's the logic behind this? – Sociopath Dec 5 at 12:59
• Please try to solve the problem by yourself first. – Maroun Dec 5 at 12:59
• @Sociopath he is reorganizing the list by layer depth – James Dec 5 at 13:01
• compute the "depth" of each element, then rebuild a list of lists – Jean-François Fabre Dec 5 at 13:01
• Can you please tell me whether `[[8, 1], [6, 7, 2], [4], [], [10], [-1]]` is an acceptable result, and if not, then why? – coldspeed Dec 5 at 13:07

The idea is basically the same that the one in @TerryA answer, but using setdefault and checking at the end of the for loop if something of the depth was added:

``````lst = [8, [6, 7, [-1], [4, [[10]]], 2], 1]

def depths(l):
def flatten(l, start=0, depth={}):

for e in l:
if isinstance(e, list):
flatten(e, start=start + 1, depth=depth)
else:
depth.setdefault(start, []).append(e)
if start not in depth:
depth[start] = []

d = {}
flatten(l, depth=d)

return [d[i] for i in range(max(d) + 1)]

result = depths(lst)
print(result)
``````

Output

``````[[8, 1], [6, 7, 2], [-1, 4], [], [10]]
``````

You could perhaps use a defaultdict here to measure the depth of each element, along with recursion:

``````from collections import defaultdict
L = [8, [6, 7, [-1], [4, [[10]]], 2], 1]
res = defaultdict(list)
def myfunc(L, depth):
for i in L:
if isinstance(i, list):
myfunc(i, depth+1)
else:
res[depth].append(i)

myfunc(L, 0)
``````

The defaultdict will then look like this:

``````defaultdict(<class 'list'>, {0: [8, 1], 1: [6, 7, 2], 2: [-1, 4], 4: [10]})
``````

You'll then need to translate the defaultdict back to what you want. Note that the default dict will not contain an empty list because it can't detect it (ie: `[[10]]` and `[10]` are both lists), but what it will have is a gap in the range (notice how the depth `3` is missing in the defaultdict).

``````final = []
for i in range(max(res)+1):
if i not in res:
final.append([])
else:
final.append(res[i])

print(final)
``````

Very messy, I'm sure improvements could be made.

• `i in res` is better than `if res.get(i) is None` – Jean-François Fabre Dec 5 at 13:18
• @Jean-FrançoisFabre yup, ty – TerryA Dec 5 at 13:18

My option with recursion and without any dependencies:

``````lst = [8, [6, 7, [-1], [4, [[10]]], 2], 1]

def flat_group(lst, deep = 0, res = None):
if res == None: res = []
for item in lst:
if len(res) <= deep: res.append([])
if not type(item) == list:
res[deep].append((item))
else:
flat_group(item, deep + 1, res)
return res

print(flat_group(lst))
#=> [[8, 1], [6, 7, 2], [-1, 4], [], [10]]
``````

To show How it works, I split the method in two:

``````def flat(lst, deep = 0, res = []):
for item in lst:
if not type(item) == list:
res.append((deep, item))
else:
flat(item, deep + 1, res)
return res

def group(lst):
flatten = flat(lst)
max_n = max(flatten)[0]
res = [[] for _ in range(0,max_n+1)]
for deep, item in flatten:
res[deep].append(item)
return res

print(group(lst))
#=> [[8, 1], [6, 7, 2], [-1, 4], [], [10]]
``````

`flat(lst)` is a recursive method that builds a flat list of tuples where each tuple contains the value and the deep inside the original list. So the call `flat(lst)` returns:

``````# [(0, 8), (1, 6), (1, 7), (2, -1), (2, 4), (4, 10), (1, 2), (0, 1)]
``````

Then `group(lst)` builds a list of `n+1` empty sub-list, where `n` is the maximum depth, it iterates over the result of `flat(lst)` and append each element by index to the proper sub-list.

The `flat_group(lst)` does almost the same.

• This breaks if there are multiple levels of a sublist without an item, such as `[8, [6, 7, [-1], [4, [[[10]]]], 2], 1]`. Also, using a mutable object as a default parameter value would result in incorrect results if the function is called more than once. – blhsing Dec 5 at 18:55
• @blhsing, thanks for the advice!! I suppose I fixed the first part, but I'm not able to find a workaround for the object mutation... (with Ruby there is not this issue). Can you address me? – iGian Dec 5 at 22:10
• @blhsing then I suppose I fixed also the default param.. – iGian Dec 5 at 22:17
• Yes you did fix it. +1 – blhsing Dec 5 at 23:01

You can do this by first generating a dictionary of elements at each depth (with depth as key in this dictionary and list of elements of that depth as value). The recursive function `get_elements_by_depth` below does this. Then all you need to do is flatten the values of that dictionary. (the function `flatten_by_depth` below does what you need).

``````from collections import defaultdict

def get_elements_by_depth(ls, cur_depth, cur_dict):
"""
returns a dictionary with depth as key and a list of all
elements that have that depth as value
"""
for x in ls:
if isinstance(x, list):
get_elements_by_depth(x, cur_depth + 1, cur_dict)
else:
cur_dict[cur_depth].append(x)
return cur_dict

def flatten_by_depth(ls):
"""
returns a list of lists, where the list at index i
contains all elements of depth i
"""
elements_by_depth = get_elements_by_depth(ls, 0, defaultdict(list))
max_depth = max(elements_by_depth.keys())
# Since we're using a defaultdict, we don't have to worry about
# missing keys in elements_by_depth
return [
elements_by_depth[i]
for i in xrange(max_depth + 1)
]
``````

``````> flatten_by_depth([8, [6, 7, [-1], [4, [[10]]], 2], 1])
[[8, 1], [6, 7, 2], [-1, 4], [], [10]]
``````

The recursive approach taken by the other answers comes with the recursion limit imposed by Python and the overhead of two passes. A more efficient one-pass iterative approach is to implement breadth-first search using a queue of tuples of lists and associated depths:

``````from collections import deque
def flatten(lst):
output = []
q = deque([(lst, 0)])
while q:
l, depth = q.popleft()
for i in l:
if isinstance(i, list):
q.append((i, depth + 1))
else:
while depth >= len(output):
output.append([])
output[-1].append(i)
return output
``````

so that:

``````flatten([8, [6, 7, [-1], [4, [[10]]], 2], 1])
``````

returns:

``````[[8, 1], [6, 7, 2], [-1, 4], [], [10]]
``````

Somebody recently posted a similar question which, by the time I composed my answer, was closed as a duplicate. So I figured I'd add my answer here.

``````def extract_entries(nested_list, new_list=[]):
# Add the list of all of the items in <nested_list> that are NOT lists themselves.
new_list.append( [ e for e in nested_list if type(e) != list ] )

# Look at entries in <nested_list> that ARE lists themselves.
for entry in nested_list:
if type(entry) == list:
extract_entries(entry, new_list)

return new_list
``````

Testing:

``````M = [8, [6, 7, [-1], [4, [[10]]], 2], 1]
print(extract_entries(M))
# Returns: [[8, 1], [6, 7, 2], [-1], [4], [], [10]]
``````