I'm struggling to understand why these two snippets produce different results under the so-called "poor man's strictness analysis".

The first example uses `data`

(assuming a correct Applicative instance):

```
data Parser t a = Parser {
getParser :: [t] -> Maybe ([t], a)
}
> getParser (pure (,) <*> literal ';' <*> undefined ) "abc"
*** Exception: Prelude.undefined
```

The second uses `newtype`

. There is no other difference:

```
newtype Parser t a = Parser {
getParser :: [t] -> Maybe ([t], a)
}
> getParser (pure (,) <*> literal ';' <*> undefined ) "abc"
Nothing
```

`literal x`

is a parser that succeeds consuming one token of input if its argument matches the first token. So in this example, it fails since `;`

doesn't match `a`

. However, the `data`

example still sees that the next parser is undefined, while the `newtype`

example doesn't.

I've read this, this, and this, but don't understand them well enough to get why the first example is undefined. It seems to me that in this example, `newtype`

is *more* lazy than `data`

, the opposite of what the answers said. (At least one other person has been confused by this too).

**Why does switching from data to newtype change the definedness of this example?**

Here's another thing I discovered: with this Applicative instance, the `data`

parser above outputs undefined:

```
instance Applicative (Parser s) where
Parser f <*> Parser x = Parser h
where
h xs =
f xs >>= \(ys, f') ->
x ys >>= \(zs, x') ->
Just (zs, f' x')
pure a = Parser (\xs -> Just (xs, a))
```

whereas with this instance, the `data`

parser above does *not* output undefined (assuming a correct Monad instance for `Parser s`

):

```
instance Applicative (Parser s) where
f <*> x =
f >>= \f' ->
x >>= \x' ->
pure (f' x')
pure = pure a = Parser (\xs -> Just (xs, a))
```

Full code snippet:

```
import Control.Applicative
import Control.Monad (liftM)
data Parser t a = Parser {
getParser :: [t] -> Maybe ([t], a)
}
instance Functor (Parser s) where
fmap = liftM
instance Applicative (Parser s) where
Parser f <*> Parser x = Parser h
where
h xs = f xs >>= \(ys, f') ->
x ys >>= \(zs, x') ->
Just (zs, f' x')
pure = return
instance Monad (Parser s) where
Parser m >>= f = Parser h
where
h xs =
m xs >>= \(ys,y) ->
getParser (f y) ys
return a = Parser (\xs -> Just (xs, a))
literal :: Eq t => t -> Parser t t
literal x = Parser f
where
f (y:ys)
| x == y = Just (ys, x)
| otherwise = Nothing
f [] = Nothing
```

`Functor`

and`Monad`

instances, and`literal`

), so that people don't have to guess at exactly how you wrote the functions (as you've pointed out, even small changes can make a difference in behavior). – shachaf Nov 26 '12 at 14:41`data`

and`newtype`

with respect to strictness/laziness?" Sorry if that's not clear from the question. – Matt Fenwick Nov 26 '12 at 14:44`Parser f`

and`Parser x`

are forced. (E.g`f (Just x) (Just y) = x; f (Just 1) undefined`

throws an exception.) – dbaupp Nov 26 '12 at 14:51