# Understanding currying by example

I was reading about curried function somewhere, which sounded confusing. The example confused me even further. Lets say I have a function:

``````power :: (Int, Float) -> Float -- computes the nth power of b
power (n, b) =
if n == 0 then 1.0 else b * power (n-1, b)
``````

Now I define another function `powerc:: Int -> Float -> Float` such that

``````powerc n b =
if n == 0 then 1.0 else b * powerc (n-1) b
``````

Can someone please explain to me how is `powerc` a curried version of `power` function.

Because `powerc` allows partial application now:

``````square = powerc 2
``````

BTW,

``````powerc = curry power
``````
• How can we directly write square = powerc 2 – OneMoreError Oct 24 '12 at 14:27
• What is the value of b and n in that case ? – OneMoreError Oct 24 '12 at 14:27
• `square = powerc 2` defines a new function `square :: Float -> Float`. Intuitively, it's a version of `powerc` in which `n` is always 2. `b` will be whatever you pass to it; i.e. `square 4 == 16.0`. – jtobin Oct 24 '12 at 14:31
• The value of `n` is `2` as you have provided a value for this argument. Because `powerc` is a 2-ary function, the partial application `powerc 2` is an unary function. That is, you can apply `square` to an argument, which becomes the second argument of `powerc`. – Jan Christiansen Oct 24 '12 at 14:31
• see partial application, you can rewrite that statement as: `square b = powerc 2 b` or `square = \b → powerc 2 b`. – Cfr Oct 24 '12 at 14:31

The former is a function taking an `Int, Float` tuple, while the latter is essentially a chain of functions each taking a single argument and returning a function taking the next.

That is, `powerc` takes an `Int` and returns a function that takes a `Float` and returns a `Float`.

You could make use of this with partial application. For example `square = powerc 2` or `cube = powerc 3` which are each then simple `Float -> Float` functions with the value for `n` captured.

Non-curried functions don't afford this easy partial application. It's nice to use partial application when the leading arguments are a kind of one-time configuration of the function's behavior. It also becomes particularly useful when trying to reshape functions to be passed to higher-order functions. For example, you could map `powerc 2` (without defining) over a list to square them all.

Hope that helps!