# Why isn't this this applicative statement being lazily evaluated, and how can I understand why?

``````abc :: IO (Int)
abc = do
print "abc"
pure \$ 10

xyz :: IO (Int)
xyz = undefined

main :: IO ()
main = do
x <- (((+) <\$> abc <*> abc) <* xyz)
print x

``````

Why in the above is `xyz` being evaluated? I would assume due to Haskell's lazy nature it would not need to evaluate `xyz` (and hence not reach the `undefined`)?

My assumption is based on the type of `<*`:

``````Prelude> :t (<*)
(<*) :: Applicative f => f a -> f b -> f a
``````

Following on with:

``````    -- | Sequence actions, discarding the value of the first argument.
(*>) :: f a -> f b -> f b
a1 *> a2 = (id <\$ a1) <*> a2
``````

And:

``````(<\$)        :: a -> f b -> f a
(<\$)        =  fmap . const
``````

And hence `f b` never gets used.

Is there a way I can understand / investigate why this is being evaluated strictly? Would looking at the GHC compiled Core be helpful in this?

Thanks to the discussion in the comments it seems (please someone correct me if I'm wrong) it's due to the `Monad` implementation of the `IO` because the following two statements seem to evaluate differently:

Identity:

``````runIdentity \$ const <\$> (pure 1 :: Identity Int) <*> undefined
1
``````

IO:

``````const <\$> (pure 1 :: IO Int) <*> undefined
*** Exception: Prelude.undefined

``````
• `(<*)` doesn't use the `b` values from the `f b`, but it does use the `f` effects (for instance, using `\x -> return x <* print x` will actually print `x`), so it must inspect the second argument. – duplode Jun 30 '19 at 17:33
• @ChrisStryczynski The runtime system executes `main`, and is responsible for discovering all the `IO` effects reachable from it. – Daniel Wagner Jun 30 '19 at 17:38
• This doesn't happen just with `IO`, either. For instance, while `Just 1 <* Just 2` is `Just 1`, `Just 1 <* Nothing` is `Nothing`. There is no way to figure that out without inspecting the second argument. – duplode Jun 30 '19 at 17:42
• Imagine if one wrote `putStrLn "Hello!" *> putStrLn "World!"`. What would the output be? – AJF Jun 30 '19 at 17:43
• consider `const <\$> Just 1 <*> Just undefined`, `const <\$> Just 1 <*> undefined`, `runIdentity \$ const <\$> Identity 1 <*> undefined` (you might need to `import Data.Functor.Identity` for the last one). So yes, it's in the definition of the applicative instance for the particular functor. (see also: stackoverflow.com/questions/24467803/…) – Will Ness Jun 30 '19 at 18:00

`(<*)` doesn't use the `b` values from the `f b`, but it does use the `f` effects, so it must inspect the second argument.

Why does [`putStrLn "Hello!" *> putStrLn "World!"`] execute both while `const (print "test") (print "test2")` does not?

In the type of `const`...

``````const :: a -> b -> a
``````

... both `a` and `b` are fully parametric, and there is nothing else to deal with. With `(<*)`, though, the situation is rather different. For starters, `(<*)` is a method of `Applicative`, so anyone writing an `Applicative` instance for `IO` can supply a concrete...

``````(<*) :: IO a -> IO b -> IO a
``````

... implementation that uses `IO`-specific functions to combine effects from the two arguments in whatever way is deemed necessary.

Furthermore, even if `(<*)` weren't a method of `Applicative`, its type...

``````(<*) :: Applicative f => f a -> f b -> f a
``````

... is such that, though `a` and `b` are fully parametric, `f` is not, because of the `Applicative` constraint. Its implementation can use other methods of `Applicative`, which can, and in most cases will, use the effects from both arguments.

Note that this is not an `IO`-specific issue. For instance, here is `(<*) @Maybe` not ignoring the effects of its second argument:

``````GHCi> Just 1 <* Just 2
Just 1
GHCi> Just 1 <* Nothing
Nothing
``````