# Implementing pointwise arithmetic with implicit type conversion

Suppose I have class `Function`, whose instances are callables that take one argument. I defined pointwise arithmetic for these classes in the straightforward way. Here's a simplified version of my code (I actually have more complex behavior in `__init__` and `__call__` but it's irrelevant for this question):

``````class Function:
'''
>>> f = Function(lambda x : x**2)
>>> g = Function(lambda x : x + 4)
>>> h = f/g
>>> h(6)
3.6
'''
def __init__(self, func):
self.func = func
def __call__(self, value):
return self.func(value)
def __truediv__(self, other):
if isinstance(other, Function):
return Function(lambda x:self(x)/other(x))
else:
return NotImplemented
# ...
``````

I'm stuck when I try to allow implicit type conversions. For example, I want to be able to write:

``````>>> f = Function(lambda x : x ** 2)
>>> g = f+1
>>> g(5)
26
``````

In other words, whenever I see a numeric object `v` in an arithmetic expression next to a `Function` instance, I want to convert `v` to `Function(lambda x : v)`.

In addition, I want to achieve similar behavior for some of my user-defined types (again, whenever I see them in the same binary arithmetic expression with a `Function` object).

While I can certainly code this logic with a brute force assortment of regular and reflected binary arithmetic operators, each checking `isinstance(v, numbers.Number)`, and `isinstance(v, MyUserDefinedType)`, I feel there might be a more elegant way.

Also, if there are any other improvements possible with my design, please let me know. (`Function` objects are created rarely, but called very often, so performance is of some interest.)

EDIT:

To address @Eric's comment, I should clarify that I have another user-defined class `Functional`:

``````class Functional:
'''
>>> c = [1, 2, 3]
>>> f = Functional(lambda x : x + 1)
>>> f(c)
[2, 3, 4]
>>> g = Functional(lambda x : x ** 2)
>>> h = f + g
>>> h(c)
[3, 7, 13]
'''
def __init__(self, func):
self.func = func
@staticmethod
def from_function(self, function):
return Functional(function.func)
def __call__(self, container):
return type(container)(self.func(c) for c in container)
if isinstance(other, Functional):
return Functional(lambda x : self.func(x) + other.func(x))
else:
return NotImplemented
``````

When I see both a `Function` and a `Functional` instance in the same arithmetic expression, I want `Function` to be implicitly converted to `Functional` using `Functional.from_function` method.

So, implicit type conversion hierarchy goes like this:

• Functional
• Function
• anything else

And I'd like to implicitly convert to the highest type in this hierarchy seen in a given arithmetic expression.

-
In general, don't you want to convert all non `Function`s to their lambda equivalent? –  Eric Dec 3 '12 at 8:30
@Eric Almost.. I actually have a higher level class, `Functional`, which operates on containers of values (creating a new container with each value processed by a certain function). When `Function` and `Functional` are in the same expression, I want both to be converted to `Functional`. Other than that, you're right. I'll update my question. –  max Dec 3 '12 at 8:32
Not sure what you mean by "brute force". Can't you write a utility function `funcOrLambda(obj)` that returns `obj` if the argument is a function or an instance of your `Function` class, otherwise returns `lambda x: obj` (or whatever logic you need)? Then you don't need to repeat the logic in every magic method. –  BrenBarn Dec 3 '12 at 8:32
If `Functional` subclasses `Function`, then operator lookup will happen first on the derived class. –  Eric Dec 3 '12 at 8:35
Have you looked at Sage as a CAS? –  katrielalex Dec 3 '12 at 8:48

Something like this for all operators would work well:

``````def __truediv__(self, other):
if callable(other):
return Function(lambda x:self(x)/other(x))
else:
return Function(lambda x:self(x)/other)
``````
-
Thanks, that would seem to work, and it might be a lot faster than the solution I am currently trying out (I'm going to post in a sec). But I'll need to deal with `Functional` separately, I guess. –  max Dec 3 '12 at 9:21

One option is to make all the operators in your `Function` class accept arbitrary values, which will be applied to the result of the underlying function if they're not functions themselves. For example, to extend allow `f / 5`, when `f` is a Function, simply modify the `__truediv__` implementation you have to:

``````def __truediv__(self, other):
if isinstance(other, Function):
return Function(lambda x:self(x)/other(x))
else:
return Function(lambda x:self(x)/other)
``````

You can optionally do some type checking to make sure that's sane (and raise errors early rather than later on), but it works without that.

-
Thx.. I'll probably go with the more general approach of checking `if callable` rather than `if isinstance(other, Function)`, since the only reason `Function` isn't an instance of built-in `function` is that I am not allowed to subclass `function`... So all callables look to me equivalent to `Function` instances. –  max Dec 3 '12 at 9:23

After reading the comments and the other answers, I tried this approach. I'm posting it to ask for feedback. I like that I can handle both `Function` and `Functional` in one swoop, but I'm afraid it might be very expensive in terms of performance:

``````class Function:
'''
>>> f = Function(lambda x : x**2)
>>> g = Function(lambda x : x + 4)
>>> h = f/g
>>> h(6)
3.6
>>> k = f + 1
>>> k(5)
26
>>> m = f + (lambda x : x + 1)
>>> m(5)
31
'''
def __init__(self, arg):
if isinstance(arg, Function):
self.func = arg.func
elif callable(arg):
self.func = arg
else:
self.func = lambda x : arg
def __call__(self, value):
return self.func(value)
def __truediv__(self, other):
return self.__class__(lambda x:Function(self)(x)/Function(other)(x))
def __rtruediv__(self, other):
return self.__class__(lambda x:Function(other)(x)/Function(self)(x))
return self.__class__(lambda x:Function(self)(x)+Function(other)(x))
return self.__class__(lambda x:Function(other)(x)+Function(self)(x))
# ...

class Functional(Function):
'''
>>> c = [1, 2, 3]
>>> f = Functional(lambda x : x + 1)
>>> f(c)
[2, 3, 4]
>>> g = Functional(lambda x : x ** 2)
>>> h = f + g
>>> h(c)
[3, 7, 13]
'''
def __call__(self, container):
return type(container)(self.func(c) for c in container)
``````
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