When should I use function currying?

Question

When should I write my functions in curried form? does not match my thought, need to correct myself.

As part of my learning link, this is what I understand from function currying. Below is one example:

def curry2(f):
    """Returns a function g such that g(x)(y) == f(x, y)

    >>> from operator import add
    >>> add_three = curry2(add)(3)
    >>> add_three(4)
    """
    def g(x):
        def h(y):
            return f(x, y)
        return h
    return g

In any application, if I know that the number of arguments are fixed (say 2 arguments) and function name is normalise_range(say), then I will define def normalise_range(x, y): function and use it in my application directly by calling normalise_range(x, y).

In any application, if I know that, the number of arguments are fixed (say 2 arguments), but the function name is varying (can be normalise_range/average/I don't know..), then I will use def curry2(f): as shown above, which will accept all functions that take two arguments (fixed).

My question:

1. Is my understanding correct?
2. If yes, can we think of currying for functions of variable number of arguments?

Answer 1

The purpose of function currying is to easily get specialized functions from more general functions. You achieve this by pre-setting some parameters at a different time and keeping them fixed afterwards.

It has nothing to do with the naming. In Python you can rename a variable/function easily at all times.

Example:

def simple_function(a):
    def line(b=0):
        def compute(x):
            return [a+b * xi for xi in x]
        return compute
    return line

x = range(-4, 4, 1)
print('x {}'.format(list(x)))
print('constant {}'.format(simple_function(3)()(x)))
print('line {}'.format(simple_function(3)(-2)(x)))

gives

x [-4, -3, -2, -1, 0, 1, 2, 3]
constant [3, 3, 3, 3, 3, 3, 3, 3]
line [11, 9, 7, 5, 3, 1, -1, -3]

Now this was not yet that exciting. It only replaced functions calls of type f(a,b,c) with calls of type f(a)(b)(c) which might even be seen as the less elegant style in Python.

But it allows you to do:

line_through_zero = simple_function(0)
print('line through zero {}'.format(line_through_zero(1)(x))) # only slope and x

which gives

line through zero [-4, -3, -2, -1, 0, 1, 2, 3]

So the advantage of currying is that you get specialized functions that have fixed parameters and can be used instead of writing the more general form and setting the parameters fixed at each single call.

Alternatives to currying are: partial, lambda and default parameters. So in practice currying might be useful but you can also get around it if you want.

See also Currying in Python

Answer 2

Currying has at-least two advantages I can think of:

1) It keeps your code (and in turn your thinking) DRY.

Say you are have a function like:

def call_me(context, args):
    ...

by currying you can get a specialized function for that context which can be tossed around etc. You don't have to repeat the context again.

2) Thinking in terms of a single input function is much easier than n arguments; this can be debatable at times though.

See also: What is the difference between currying and partial application?

Answer 3

In many ways, this combination of currying and the partial application of arguments to functions emulates what in Object Oriented Programming we would call the "Factory Pattern". Currying lets the programmer to create specialized functions, as others have pointed out in this forum. For instance, check this (not efficient by elegant) implementation of quicksort below:

leq = lambda x: lambda y: x <= y
gth = lambda x: lambda y: x > y

def qsort(L):
    if L:
        smalls = filter(gth(L[0]), L[1:])
        bigs = filter(leq(L[0]), L[1:])
        return qsort(smalls) + [L[0]] + qsort(bigs)
    else:
        return L

print(qsort([2, 4, 1, 4, 2]))