# Translate from monad to applicative

OK, so I know what the `Applicative` type class contains, and why that's useful. But I can't quite wrap my brain around how you'd use it in a non-trivial example.

Consider, for example, the following fairly simple Parsec parser:

``````integer :: Parser Integer
integer = do
many1 space
ds <- many1 digit
``````

Now how the heck would you write that without using the `Monad` instance for `Parser`? Lots of people claim that this can be done and is a good idea, but I can't figure out how exactly.

-

``````integer :: Parser Integer
integer = read <\$> (many1 space *> many1 digit)
``````

Or

``````integer = const read <\$> many1 space <*> many1 digit
``````

Whether you think either of these are more readable is up to you.

-
Why the `const`? – MathematicalOrchid Feb 28 '13 at 19:30
We want to ignore the value (but not the effect) of `many1 space`, and apply `read` to the value of `many1 digit`. (Sorry, I've just got in, it's late, I'm tired: I'm playing fast and loose with the terminology.) If you imagine `s` and `d` represent the values of `many1 space` and `many1 digit` respectively, then the value (ignoring effects) of `const read <\$> many1 space <*> many1 digit` is `const read s d` = `read d`. – dave4420 Feb 28 '13 at 22:33

I'd write

``````integer :: Parser Integer
integer = read <\$ many1 space <*> many1 digit
``````

There's a bunch of left associative (like application) parser-building operators `<\$>`, `<*>`, `<\$`, `<*`. The thing in the far left should be the pure function which assembles the result value from the component values. The thing on the right of each operator should be a parser, collectively giving the components of the grammar left-to-right. Which operator to use depends on two choices, as follows.

``````  the thing to the right is    signal  / noise
_________________________
the thing to the left is \
+-------------------
pure /  |   <\$>       <\$
a parser  |   <*>       <*
``````

So, having chosen `read :: String -> Integer` as the pure function which is going to deliver the semantics of the parser, we can classify the leading space as "noise" and the bunch of digits as "signal", hence

`````` read <\$ many1 space <*> many1 digit
(..)    (.........)     (.........)
pure    noise parser     |
(.................)      |
parser              signal parser
(.................................)
parser
``````

You can combine multiple possibilities with

``````p1 <|> ... <|> pn
``````

and express impossibility with

``````empty
``````

It's seldom necessary to name components in parsers, and the resulting code looks more like a grammar with added semantics.

-
Wow, I knew about `<\$`, but I only ever used it if the thing to the left of it was a constant and the right was a simple value... I never thought about what would happen if I put a function to the left :P Nice trick – Niklas B. Feb 27 '13 at 23:10

Your example can be progressively rewritten to a form which more clearly resembles an Applicative:

``````do
many1 space
ds <- many1 digit
``````
1. definition of `do` notation:

``````many1 space >> (many1 digit >>= \ds -> return \$ read ds)
``````
2. definition of `\$`:

``````many1 space >> (many1 digit >>= \ds -> return (read ds))
``````
3. definition of `.`:

``````many1 space >> (many1 digit >>= (return . read))
``````

``````(many1 space >> many1 digit) >>= (return . read)
``````
5. definition of `liftM` (in non-`do` notation):

``````liftM read (many1 space >> many1 digit)
``````

This is (or should be, if I haven't messed up :)) identical in behavior to your example.

Now, if you replace `liftM` with `fmap` with `<\$>`, and `>>` with `*>`, you get the Applicative:

``````read <\$> (many1 space *> many1 digit)
``````

This is valid because `liftM`, `fmap`, and `<\$>` are generally supposed to be synonyms, as are `>>` and `*>`.

This all works and we can do this because the original example didn't use the result of any parser to build a following parser.

-
Cool! Another way to write `read <\$ many1 space <*> many1 digit`. :) The last sentence is very important. Does that mean that this style corresponds to context-free grammars, and more general grammars must be parsed with monadic style? – Will Ness Mar 5 '13 at 14:52
@WillNess I'm not an expert on this, but I do believe that's the case. – Matt Fenwick Mar 5 '13 at 19:38