(You can write
1:2:3:4:5: more simply as
[1,2,3,4,5] or even
You'd like to use list comprehensions, so here it is:
subtractOne xs = [ x-1 | x <- xs ]
Here I'm using
xs to stand for the list I'm subtracting one from.
The first thing to notice is
x <- xs which you can read as "
x is taken from
xs". This means we're going to take each of the numbers in
xs in turn, and each time we'll call the number
x-1 is the value we're calculating and returning for each
For more examples, here's one that adds one to each element
[x+1|x<-xs] or squares each element
More than one list
Let's take list comprehension a little further, to write a function that finds the squares then the cubes of the numbers we give it, so
> squaresAndCubes [1..5]
squaresAndCubes xs = [x^p | p <- [2,3], x <- xs]
This means we take the powers
p to be 2 then 3, and for each power we take all the
xs, and calculate
x to the power
What happens if we do that the other way around?
squaresAndCubesTogether xs = = [x^p | x <- xs, p <- [2,3]]
> squaresAndCubesTogether [1..5]
Which takes each
x and then gives you the two powers of it straight after each other.
Conclusion - the order of the
<- bits tells you the order of the output.
What if we wanted to only allow some answers?
Which numbers between 2 and 100 can be written as
Here we allowed all
x and all
y as long as
Since we're doing exactly the same to each element, I'd write this in practice using
takeOne xs = map (subtract 1) xs
or shorter as
takeOne = map (subtract 1)
(I have to call it
subtract 1 because
- 1 would be parsed as negative 1.)