# Function chaining in Python

On Codewars.com I encountered the following task:

Create a function `add` that adds numbers together when called in succession. So `add(1)` should return `1`, `add(1)(2)` should return `1+2`, ...

While I'm familiar with the basics of Python, I've never encountered a function that is able to be called in such succession, i.e. a function `f(x)` that can be called as `f(x)(y)(z)...`. Thus far, I'm not even sure how to interpret this notation.

As a mathematician, I'd suspect that `f(x)(y)` is a function that assigns to every `x` a function `g_{x}` and then returns `g_{x}(y)` and likewise for `f(x)(y)(z)`.

Should this interpretation be correct, Python would allow me to dynamically create functions which seems very interesting to me. I've searched the web for the past hour, but wasn't able to find a lead in the right direction. Since I don't know how this programming concept is called, however, this may not be too surprising.

How do you call this concept and where can I read more about it?

• Looks like you are looking for currying functions Aug 19, 2016 at 11:50
• Hint: A nested function is dynamically created, has access to its parent function's locals, and is able to be returned as a (callable) object. Aug 19, 2016 at 11:51
• @JonathonReinhart That's the way I was thinking about the problem. But I didn't really see how to implement it. Aug 19, 2016 at 12:05
• As an aside: Python will definitely allow you to dynamically create functions. If you're interested, here's a couple of related concepts to read up on: WP: First-class functions | How do you make a higher order function in Python? | `functools.partial()` | WP: Closures Aug 19, 2016 at 12:06
• @LukasGraf I'll have a look at it. Thank you! Aug 19, 2016 at 12:07

I don't know whether this is function chaining as much as it's callable chaining, but, since functions are callables I guess there's no harm done. Either way, there's two ways I can think of doing this:

### Sub-classing `int` and defining `__call__`:

The first way would be with a custom `int` subclass that defines `__call__` which returns a new instance of itself with the updated value:

``````class CustomInt(int):
def __call__(self, v):
return CustomInt(self + v)
``````

Function `add` can now be defined to return a `CustomInt` instance, which, as a callable that returns an updated value of itself, can be called in succession:

``````>>> def add(v):
...    return CustomInt(v)
1
3
>>> add(1)(2)(3)(44)  # and so on..
50
``````

In addition, as an `int` subclass, the returned value retains the `__repr__` and `__str__` behavior of `int`s. For more complex operations though, you should define other dunders appropriately.

As @Caridorc noted in a comment, `add` could also be simply written as:

``````add = CustomInt
``````

Renaming the class to `add` instead of `CustomInt` also works similarly.

### Define a closure, requires extra call to yield value:

The only other way I can think of involves a nested function that requires an extra empty argument call in order to return the result. I'm not using `nonlocal` and opt for attaching attributes to the function objects to make it portable between Pythons:

``````def add(v):
"""
if val is None we return _inner_adder.v
else we increment and return ourselves
"""
if val is None:
_inner_adder.v = v  # save value
``````

This continuously returns itself (`_inner_adder`) which, if a `val` is supplied, increments it (`_inner_adder += val`) and if not, returns the value as it is. Like I mentioned, it requires an extra `()` call in order to return the incremented value:

``````>>> add(1)(2)()
3
>>> add(1)(2)(3)()  # and so on..
6
``````
• In the interactive code `add = CostumInt` should work too and be simpler. Aug 19, 2016 at 12:42
• The problem with subclassing built-ins is that `(2*add(1)(2))(3)` fails with a `TypeError` because `int` is not callable. Basically the `CustomInt` is converted to plain `int` when used in any context except when calling. For a more robust solution you basically have to re-implement all `__*__` methods including the `__r*__` versions... Aug 19, 2016 at 14:30
• @Caridorc Or don't call it `CustomInt` at all but `add` when defining it. Aug 23, 2016 at 22:30

You can hate me, but here is a one-liner :)

``````add = lambda v: type("", (int,), {"__call__": lambda self, v: self.__class__(self + v)})(v)
``````

Edit: Ok, how this works? The code is identical to answer of @Jim, but everything happens on a single line.

1. `type` can be used to construct new types: `type(name, bases, dict) -> a new type`. For `name` we provide empty string, as name is not really needed in this case. For `bases` (tuple) we provide an `(int,)`, which is identical to inheriting `int`. `dict` are the class attributes, where we attach the `__call__` lambda.
2. `self.__class__(self + v)` is identical to `return CustomInt(self + v)`
3. The new type is constructed and returned within the outer lambda.
• Or even shorter: `class add(int):__call__ = lambda self, v: add(self+v)` Aug 19, 2016 at 14:32
• The code inside a class is executed exactly like normal code so you can define special methods by assignments. The only difference is that the class scope is a bit... peculiar. Aug 19, 2016 at 14:39

Simply:

``````class add(int):
def __call__(self, n):
``````
• This is easily the best answer! Dec 6, 2020 at 16:36
• To clarify, you are subclassing int into a callable form (function/class) called add, which adds to itself when referenced as a function. Mar 25 at 9:35

If you want to define a function to be called multiple times, first you need to return a callable object each time (for example a function) otherwise you have to create your own object by defining a `__call__` attribute, in order for it to be callable.

The next point is that you need to preserve all the arguments, which in this case means you might want to use Coroutines or a recursive function. But note that Coroutines are much more optimized/flexible than recursive functions, specially for such tasks.

Here is a sample function using Coroutines, that preserves the latest state of itself. Note that it can't be called multiple times since the return value is an `integer` which is not callable, but you might think about turning this into your expected object ;-).

``````def add():
current = yield
while True:
value = yield current
current = value + current

next(it)
print(it.send(10))
print(it.send(2))
print(it.send(4))

10
12
16
``````

If you are willing to accept an additional `()` in order to retrieve the result you can use `functools.partial`:

``````from functools import partial

return partial(add, result=sum(args)+result) if args else result
``````

For example:

``````>>> add(1)
3
``````

This also allows specifying multiple numbers at once:

``````>>> add(1, 2, 3)(4, 5)(6)()
21
``````

If you want to restrict it to a single number you can do the following:

``````def add(x=None, *, result=0):
return partial(add, result=x+result) if x is not None else result
``````

If you want `add(x)(y)(z)` to readily return the result and be further callable then sub-classing `int` is the way to go.

The pythonic way to do this would be to use dynamic arguments:

``````def add(*args):
return sum(args)
``````

This is not the answer you're looking for, and you may know this, but I thought I would give it anyway because if someone was wondering about doing this not out of curiosity but for work. They should probably have the "right thing to do" answer.

• I removed your 'P.S' note, nichochar. We are all aware of how elegant Python is :-) I don't think it belongs in the body of the answer. Aug 25, 2016 at 15:27
• I do think you could have just done `add = sum` if were gonna go that route Oct 2, 2017 at 21:03
• There is a slight difference in that `add(1,2,3)` is valid and returns 6 but `sum(1,2,3)` gives an error Jul 24, 2022 at 20:28