In Haskell, I can easily map a list:
map (\x -> 2*x) [1,2]
gives me [2,4]
. Is there any "mapTuple" function which would work like that?
mapTuple (\x -> 2*x) (1,2)
with the result being (2,4)
.
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In Haskell, I can easily map a list:
map (\x -> 2*x) [1,2]
gives me [2,4]
. Is there any "mapTuple" function which would work like that?
mapTuple (\x -> 2*x) (1,2)
with the result being (2,4)
.
Searching at Hoogle gives no exact matches for (a -> b) -> (a, a) -> (b, b)
, which is the type you require, but it is pretty easy to do yourself:
mapTuple :: (a -> b) -> (a, a) -> (b, b)
mapTuple f (a1, a2) = (f a1, f a2)
Note, you will have to define a new function for 3-tuples, 4-tuples etc - although such a need might be a sign, that you are not using tuples like they were intended: In general, tuples hold values of different types, so wanting to apply a single function to all values is not very common.
Control.Arrow
is in the standard libs, and Control.Bifunctor
istn't too far away...
– Landei
Mar 15 '12 at 15:33
(bimap <$> id <*> id) (*2) (3,5)
– Landei
Mar 16 '12 at 8:02
Here's a rather short point-free solution:
import Control.Monad (join)
import Control.Arrow ((***))
mapTuple = join (***)
join
takes a function of two arguments with the same type, a->a->b
, and creates a new function with one argument a -> b
, passing that argument to both positions of the original function. This is because the Monad instance for functions is identical to the Reader
monad, giving join
type (a -> a -> b) -> a -> b
. I find it a little easier to work out when the arrows aren't written infix, e.g. join :: (a ->) ( (a ->) b) -> (a ->) b
.
– John L
Mar 15 '12 at 17:01
You could use Bifunctor
:
import Control.Monad (join)
import Data.Bifunctor (bimap)
join bimap (2*) (1,2)
This works not only for pairs, but for a number of other types as well, e.g. for Either
.
Bifunctor
is in base as of version 4.8. Previously it was provided by the bifunctors package.
Data.Graph.Inductive.Query.Monad
and then (*2) >< (*2)
is the function you're after. (I'm puzzled that this isn't in Data.Tuple, but perhaps that's just an accident of history.)
– James Jones
Feb 27 '17 at 17:58
You can use arrows from module Control.Arrow
to compose functions that work on tuples.
Prelude Control.Arrow> let f = (*2) *** (*2)
Prelude Control.Arrow> f (1,2)
(2,4)
Prelude Control.Arrow> let f' = (*2) *** (*3)
Prelude Control.Arrow> f (2,2)
(4,4)
Prelude Control.Arrow> f' (2,2)
(4,6)
Your mapTuple then becomes
mapTuple f = f *** f
If with your question you asked for a function that maps over tuples of arbitrary arity, then I'm afraid you can't because they would have different types (e.g. the tuple types (a,b)
and (a,b,c)
are totally different and unrelated).
Here is another way:
mapPair :: (a -> b) -> (a, a) -> (b, b) -- this is the inferred type
mapPair f = uncurry ((,) `on` f)
You need Data.Function
imported for on
function.
To add another solution to this colourful set... You can also map over arbitrary n-tuples using Scrap-Your-Boilerplate generic programming. For example:
import Data.Data
import Data.Generics.Aliases
double :: Int -> Int
double = (*2)
tuple :: (Int, Int, Int, Int)
tuple = gmapT (mkT double) (1,2,3,4)
Note that the explicit type annotations are important, as SYB selects the fields by type. If one makes one tuple element type Float
, for example, it wouldn't be doubled anymore.
Data.Data
documentation cites SYB, I'd wager that it's a direct descendant.
– Peter Wortmann
Mar 22 '12 at 11:43
The extra package provides the both
function in the Data.Tuple.Extra module. From the docs:
Apply a single function to both components of a pair.
> both succ (1,2) == (2,3)
both :: (a -> b) -> (a, a) -> (b, b)
You can also use Applicatives which have additional benefit of giving you possibility to apply different functions for each tuple element:
import Control.Applicative
mapTuple :: (a -> a') -> (b -> b') -> (a, b) -> (a', b')
mapTuple f g = (,) <$> f . fst <*> g . snd
Inline version:
(\f -> (,) <$> f . fst <*> f . snd) (*2) (3, 4)
or with different map functions and without lambda:
(,) <$> (*2) . fst <*> (*7) . snd $ (3, 4)
Other possibility would be to use Arrows:
import Control.Arrow
(+2) . fst &&& (+2) . snd $ (2, 3)
The uniplate package provides the descend function in the Data.Generics.Uniplate.Data module. This function will apply the function everywhere the types match, so can be applied to lists, tuples, Either, or most other data types. Some examples:
descend (\x -> 2*x) (1,2) == (2,4)
descend (\x -> 2*x) (1,"test",Just 2) == (2,"test",Just 4)
descend (\x -> 2*x) (1,2,3,4,5) == (2,4,6,8,10)
descend (\x -> 2*x) [1,2,3,4,5] == [2,4,6,8,10]
I just added a package tuples-homogenous-h98 to Hackage that solves this problem. It adds newtype
wrappers for tuples and defines Functor
, Applicative
, Foldable
and Traversable
instances for them. Using the package you can do things like:
untuple2 . fmap (2 *) . Tuple2 $ (1, 2)
or zip tuples like:
Tuple2 ((+ 1), (*2)) <*> Tuple2 (1, 10)
Yes, you would do:
map (\x -> (fst x *2, snd x *2)) [(1,2)]
fst
grabs the first data entry in a tuple, and snd
grabs the second; so, the line of code says "take a tuple, and return another tuple with the first and second items double the previous."
\(x,y) -> (x*2,y*2)
– danr
Mar 15 '12 at 15:20
map
on a list with a single element: the point here is the function in the parentheses in fact.
– awllower
Aug 24 '16 at 7:51
map (*2) [1,2,3]
would do the trick. – O.F. Nov 2 '15 at 6:32