# Writing a faster backtracking algorithm in Python

I am learning backtracking algorithms and I have written a program of subset sums. Here's the program:

``````items = range(1, 10)
result = []
def backtracking(array, target, temparray= []):
if target == 0:
result.append(temparray)
return

for index, item in enumerate(array):
if item > target:
return
temparray.append(item)
backtracking(array[index+1:], target - item, temparray[:])
temparray.pop()
return

backtracking(items, 8)
[print(arr) for arr in result]
``````

That is to get a sum of 8 from the values of 1 to 9 (No repetition), we get this output:-

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

The output is well and good but when I do same for any number above 50, it keeps on running like forever. I waited almost an hour and still couldn't get the result so I Had to terminate the programme abruptly. Same has been my experience with other `backtracking` problems when the values tend to get close to 40-50. Seems like `backtracking` is inherently very slow as it involves `recursion` and lots of `function calls`.

I want to ask if there is anything to speed things in general while implementing `backtracking algorithms`. Is there any other more efficient `algorithms` to be used in its place. `Memoization` doesn't work as list as arguments are not hashable.

I have devised some cool solutions to some of the Project Euler questions but am unable to get an answer for larger values. I know my algorithm is correct but is very slow. Please help.

• Just a note, using a mutable object like a list as a default argument is a recipe for pain. See this post. – wbadart Dec 6 '18 at 18:09
• The indentation of your code sample is not quite right. – Tomalak Dec 6 '18 at 18:13