# Single implementation to cover both single and multiple values in Python?

Say you have a value like this:

n = 5

and a method that returns the factorial of it, like so:

Factorial ( 5 )

How do you handle multiple values:

nums = [1,2,3,4,5]

Factorial ( nums )

so it returns the factorials of all these values as a list.

What's the cleanest way to handle this, without writing 2 methods? Does python have a good way to handle these kind of situations?

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 Could you provide some background on the use case for such a magical function that did one thing with scalars and another with vectors? – S.Lott Mar 9 '09 at 22:16 Sure. It's good for functions like Sum or Average, or the like even though a single value seems not so useful. There are lots of functions that can be used like this. – Joan Venge Mar 10 '09 at 16:22 No, please, if you have only a single value then use a list that contains this single value. Returning different types is ok when the objects behave similar. But this here is far over the limit. – unbeknown Mar 10 '09 at 17:25 /agree heikogerlach — Functions should want either one value or multiple values. To feed a single value into a multi function, use foo([single]). To feed multiple values into a single function, use [foo(x) for x in multi]. – Ben Blank Mar 10 '09 at 22:33

This is done sometimes.

``````def factorial( *args ):
def fact( n ):
if n == 0: return 1
return n*fact(n-1)
return [ fact(a) for a in args ]
``````

It gives an almost magical function that works with simple values as well as sequences.

``````>>> factorial(5)
[120]
>>> factorial( 5, 6, 7 )
[120, 720, 5040]
>>> factorial( *[5, 6, 7] )
[120, 720, 5040]
``````
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 Cleanest answer so far... – Nikhil Chelliah Mar 9 '09 at 22:28 Not good, as it returns a list even if the input is a simple number. – Georg Schölly Mar 9 '09 at 23:06 I'm completely unclear on what the requirements are for. The idea of a function that magically handles list and individual values in a "uniform" way is confusing. Or it's APL (or J or K). – S.Lott Mar 10 '09 at 1:13 S. Lott, does this also handle when you pass a collection directly, like list=[1,2,3,4,5] and then factorial (list)? – Joan Venge Mar 10 '09 at 16:27 In a way. I've updated the answer. Your use case is a very, very odd situation where you're trying to handle all these fundamentally different types in a single function. It doesn't really make a lot of sense. – S.Lott Mar 10 '09 at 17:14
``````def Factorial(arg):
try:
it = iter(arg)
except TypeError:
pass
else:
return [Factorial(x) for x in it]
return math.factorial(arg)
``````

If it's iterable, apply recursivly. Otherwise, proceed normally.

Alternatively, you could move the last `return` into the `except` block.

If you are sure the body of `Factorial` will never raise `TypeError`, it could be simplified to:

``````def Factorial(arg):
try:
return [Factorial(x) for x in arg]
except TypeError:
return math.factorial(arg)
``````
-
 getattr(obj, 'iter', False) is a way to check if 'obj' is iterable without try/except (which might be slower). – Andrey Fedorov Mar 10 '09 at 20:42 @Andrey Fedorov: in most cases, the try/except is actually faster. – S.Lott Mar 10 '09 at 20:49 @MizardX: The body of `Factorial` is in front of you. Therefore you can be sure that `TypeError` will be raised e.g., when `arg` is not an iterable. The above two versions of `Factorial` do the same thing, but one is simpler. – J.F. Sebastian Mar 11 '09 at 15:20 @J.F. Sebastian: Factorial([1,2+0j]) would try to call math.factorial(2+0j), catch the TypeError, and try to call math.factorial([1,2+0j]). The first TypeError will be swallowed. You only want to catch the TypeError if it resulted from the argument not being iterable. – Markus Jarderot Mar 11 '09 at 17:01
``````[fac(n) for n in nums]
``````

EDIT:

Sorry, I misunderstood, you want a method that handles both sequences and single values? I can't imagine why you wouldn't do this with two methods.

``````def factorial(n):
# implement factorial here

def factorial_list(nums):
return [factorial(n) for n in nums]
``````

The alternative would be to do some sort of type-checking, which is better avoided unless you have some terribly compelling reason to do so.

EDIT 2:

MizardX's answer is better, vote for that one. Cheers.

-
 Actually, I like your answer more. I think writing this as one function makes for much messier code. – daf Mar 9 '09 at 22:09 Well, so do I. :P But MizardX actually answered his question, which I didn't do, so its only fair he gets the votes. :) – bouvard Mar 9 '09 at 22:11 Thanks, how does python find the correct function when you used a collection? – Joan Venge Mar 10 '09 at 16:24 -Python- doesn't find anything. Its up to you to ensure that you are calling the correct function. What situation are you imagining in which you wouldn't know in advance if you were dealing with individual or structured values? I think that is likely a situation you want to avoid. – bouvard Mar 10 '09 at 16:27 If you really want to do this, then I would suggest converting your individual value to a list and always using the list form. That is: factorial_list([7]) works just as well as factorial_list([1,2,3]), you just now that your output will always be a list (which is a good thing). – bouvard Mar 10 '09 at 16:28

If you're asking if Python can do method overloading: no. Hence, doing multi-methods like that is a rather un-Pythonic way of defining a method. Also, naming convention usually upper-cases class names, and lower-cases functions/methods.

If you want to go ahead anyway, simplest way would be to just make a branch:

``````def Factorial(arg):
if getattr(arg, '__iter__', False): # checks if arg is iterable
return [Factorial(x) for x in arg]
else:
# ...
``````

Or, if you're feeling fancy, you could make a decorator that does this to any function:

``````def autoMap(f):
def mapped(arg):
if getattr(arg, '__iter__', False):
return [mapped(x) for x in arg]
else:
return f(arg)
return mapped

@autoMap
def fact(x):
if x == 1 or x == 0:
return 1
else:
return fact(x-1) + fact(x-2)

>>> fact(3)
3
>>> fact(4)
5
>>> fact(5)
8
>>> fact(6)
13
>>> fact([3,4,5,6])
[3, 5, 8, 13]
``````

Although a more Pythonic way is to use variable argument lengths:

``````def autoMap2(f):
def mapped(*arg):
if len(arg) != 1:
return [f(x) for x in arg]
else:
return f(arg[0])
return mapped

@autoMap2
def fact(n):
# ...

>>> fact(3,4,5,6)
[3, 5, 8, 13]
``````

Putting the two together into a deep mapping decorator:

``````def autoDeepMap(f):
def mapped(*args):
if len(args) != 1:
return [mapped(x) for x in args]
elif getattr(args[0], '__iter__', False):
return [mapped(x) for x in args[0]]
else:
return f(args[0])
return mapped

@autoDeepMap
def fact(n):
# ...

>>> fact(0)
1
>>> fact(0,1,2,3,4,5,6)
[1, 1, 2, 3, 5, 8, 13]
>>> fact([0,1,2,3,4,5,6])
[1, 1, 2, 3, 5, 8, 13]
>>> fact([0,1,2],[3,4,5,6])
[[1, 1, 2], [3, 5, 8, 13]]
>>> fact([0,1,2],[3,(4,5),6])
[[1, 1, 2], [3, [5, 8], 13]]
``````
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 You could make the decorator recursive by changing [f(x) for x in arg] to [mapped(x) for x in arg]. – Markus Jarderot Mar 9 '09 at 22:08 MizardX: you just blew my mind. Nice idea :) – Andrey Fedorov Mar 9 '09 at 22:11 But this is fibonacci... :) – Nikhil Chelliah Mar 9 '09 at 22:25 Nikhil: good call! :-P I'll leave it for the laugh, feel free to change it if you care to be encyclopedic. – Andrey Fedorov Mar 10 '09 at 1:43 +1: for decorators – J.F. Sebastian Mar 10 '09 at 14:46

You might want to take a look at NumPy/SciPy's vectorize.

In the numpy world, given your single-int-arg Factorial function, you'd do things like

``````  vFactorial=np.vectorize(Factorial)
vFactorial([1,2,3,4,5])
vFactorial(6)
``````

although note that the last case returns a single-element numpy array rather than a raw int.

-

Or if you don't like the list comprehension syntax, and wish to skip having a new method:

``````def factorial(num):
if num == 0:
return 1
elif num > 0:
return num * factorial(num - 1)
else:
raise Exception("Negative num has no factorial.")

nums = [1, 2, 3, 4, 5]
# [1, 2, 3, 4, 5]

map(factorial, nums)
# [1, 2, 6, 24, 120, 720]
``````
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