Refactoring recursive “occurences of” function

``````def recursive_count(target, nested_num_list):
# This code finds all occurrences of "target" in "nested_num_list"
# Rewrite this code without a while/for loop that achieves
# the same results. Basically using only recursive calls and if's.

count = 0
i = 0
while i < len(nested_num_list):
if nested_num_list[i] == target:
count += 1
if type(nested_num_list[i]) == type([]):
count += recursive_count(target, nested_num_list[i])
i += 1
return count
``````

This was a bonus question (read the hashtags) that came up in my computation class. I've tried default parameters, tinkering with i and count numerous ways but I cant get it. How would you lovely people go about it?

• Hint: divide the list into the first element and the rest. – interjay Oct 13 '15 at 17:49

Here's another approach for Python 3 (that is easily translated to python 2). No modification of input parameters or use of other functions (except `isinstance`):

``````def recursive_count(target, nested_num_list):
if nested_num_list == []:
return 0
if isinstance(nested_num_list, int):
return nested_num_list == target
x, *y = nested_num_list
# x, y = nested_num_list, nested_num_list[1:]  # Python 2
return recursive_count(target, x) + recursive_count(target, y)

>>> recursive_count(1, [1,2,3,[1,1,1],])
5
``````
• Perfect! well done and elegant. – pythonnoob Oct 13 '15 at 18:16
``````def recursive_count(target, nested_num_list):
count = 0
# Make sure there's still stuff left.
if len(nested_num_list) is 0:
return 0
item = nested_num_list.pop(0)
if type(item) == type([]):
count += recursive_count(target, item)
elif target == item:
count += 1
count += recursive_count(target, nested_num_list)
return count
``````

If you don't mind modifying the input parameters, you can just pop the first item from the list every time and pass it back in. Edit: Added the nesting handling.

• your code returns less occurrences then it should given a nested list [1,2,3,[1,1,1],]. For target "1" your code results in 1 occurrence when the right answer is 5. And no you can modify the hell out of em! haha – pythonnoob Oct 13 '15 at 18:14
• Oh dang! Sorry, forgot it was on a tested loop. – Lyr Lunace Oct 13 '15 at 18:29

I'd write a recursive flattener and use its output.

``````def flattener(left, right):
try:
res = reduce(flattener, right, left)
except TypeError:
left.append(right)
res = left
return res

>>> nested_list = [, [1, [2, 3]], [4, 5], [6, , [8, 9]], 10, [[[]]], [], 12]
>>> flattened_list = reduce(flattener, nested_list, [])
>>> flattened_list
[0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12]
Go on with flattened_list ...
``````

Edit: So you want one single function that does this, and here's a version without `isinstance` or explicit length checking, or indexing, and with only one inline-`if`:

``````def countin(seq, predicate):
try:
iterseq = iter(seq)
except TypeError:
return 1 if predicate(seq) else 0
try:
except StopIteration:
return 0
c += countin(iterseq, predicate)
return c

>>> count_in(nested_list, lambda x: x % 2 == 0)  # count all even numbers
7
>>> len(filter(lambda x: x % 2 == 0, reduce(flattener, nested_list, [])))
7
``````
• everything has to be done within the func. No helpers :) – pythonnoob Oct 13 '15 at 18:05
• But `flat is better than nested`! ;) – Cong Ma Oct 13 '15 at 18:10
``````def recursive_count(target, nested_num_list):
return (recursive_count(nested_num_list[1:]) + (target == nested_num_list)) if nested_num_list else 0
``````
• `recursive_count` takes 2 arguments, and doesn't descend into nested lists. – AChampion Oct 13 '15 at 18:09