The chapter on Partial Functions from the book Learn You a Haskell For Great Good contains the following code:

```
multThree :: (Num a) => a -> a -> a -> a
multThree x y z = x * y * z
ghci> let multTwoWithNine = multThree 9
ghci> multTwoWithNine 2 3
54
ghci> let multWithEighteen = multTwoWithNine 2
ghci> multWithEighteen 10
180
```

I am currently playing with the functools library in Python, and managed to replicate the behavior of those functions using it.

```
from functools import partial
def multThree(x,y,z):
return x * y * z
>>> multTwoWithNine = partial(multThree,9)
>>> multTwoWithNine(2,3)
>>> multWithEighteen = partial(multTwoWithNine,2)
>>> multWithEighteen(10)
180
```

One thing I would now like to do is see if I can replicate some of the more interesting higher-order functions from the same book chapter, such as:

```
zipWith' :: (a -> b -> c) -> [a] -> [b] -> [c]
zipWith' _ [] _ = []
zipWith' _ _ [] = []
zipWith' f (x:xs) (y:ys) = f x y : zipWith' f xs ys
```

However, I'm not sure how to do this, or if `partial()`

is even useful here.

`partial`

in any conversion, since all Haskell functions are automatically curried, and`partial`

emulates the ability curried functions have to be partially applied. Or you can write the python versions as curried functions, but then you have to call them like`foo(a)(b)(c)`

. – Wes Feb 10 '13 at 4:57