tl;dr upfront: `seq`

is the only way.

Since the implementation of `IO`

is not prescribed by the standard, we can only look at specific implementations. If we look at GHC's implementation, as it is available from the source (it might be that some of the behind-the-scenes special treatment of `IO`

introduces violations of the monad laws, but I'm not aware of any such occurrence),

```
-- in GHC.Types (ghc-prim)
newtype IO a = IO (State# RealWorld -> (# State# RealWorld, a #))
-- in GHC.Base (base)
instance Monad IO where
{-# INLINE return #-}
{-# INLINE (>>) #-}
{-# INLINE (>>=) #-}
m >> k = m >>= \ _ -> k
return = returnIO
(>>=) = bindIO
fail s = failIO s
returnIO :: a -> IO a
returnIO x = IO $ \ s -> (# s, x #)
bindIO :: IO a -> (a -> IO b) -> IO b
bindIO (IO m) k = IO $ \ s -> case m s of (# new_s, a #) -> unIO (k a) new_s
thenIO :: IO a -> IO b -> IO b
thenIO (IO m) k = IO $ \ s -> case m s of (# new_s, _ #) -> unIO k new_s
unIO :: IO a -> (State# RealWorld -> (# State# RealWorld, a #))
unIO (IO a) = a
```

it's implemented as a (strict) state monad. So any violation of the monad laws `IO`

makes, is also made by `Control.Monad.State[.Strict]`

.

Let's look at the monad laws and see what happens in `IO`

:

```
return x >>= f ≡ f x:
return x >>= f = IO $ \s -> case (\t -> (# t, x #)) s of
(# new_s, a #) -> unIO (f a) new_s
= IO $ \s -> case (# s, x #) of
(# new_s, a #) -> unIO (f a) new_s
= IO $ \s -> unIO (f x) s
```

Ignoring the newtype wrapper, that means `return x >>= f`

becomes `\s -> (f x) s`

. The only way to (possibly) distinguish that from `f x`

is `seq`

. (And `seq`

can only distinguish it if `f x ≡ undefined`

.)

```
m >>= return ≡ m:
(IO k) >>= return = IO $ \s -> case k s of
(# new_s, a #) -> unIO (return a) new_s
= IO $ \s -> case k s of
(# new_s, a #) -> (\t -> (# t, a #)) new_s
= IO $ \s -> case k s of
(# new_s, a #) -> (# new_s, a #)
= IO $ \s -> k s
```

ignoring the newtype wrapper again, `k`

is replaced by `\s -> k s`

, which again is only distinguishable by `seq`

, and only if `k ≡ undefined`

.

```
m >>= (\x -> g x >>= h) ≡ (m >>= g) >>= h:
(IO k) >>= (\x -> g x >>= h) = IO $ \s -> case k s of
(# new_s, a #) -> unIO ((\x -> g x >>= h) a) new_s
= IO $ \s -> case k s of
(# new_s, a #) -> unIO (g a >>= h) new_s
= IO $ \s -> case k s of
(# new_s, a #) -> (\t -> case unIO (g a) t of
(# new_t, b #) -> unIO (h b) new_t) new_s
= IO $ \s -> case k s of
(# new_s, a #) -> case unIO (g a) new_s of
(# new_t, b #) -> unIO (h b) new_t
((IO k) >>= g) >>= h = IO $ \s -> case (\t -> case k t of
(# new_s, a #) -> unIO (g a) new_s) s of
(# new_t, b #) -> unIO (h b) new_t
= IO $ \s -> case (case k s of
(# new_s, a #) -> unIO (g a) new_s) of
(# new_t, b #) -> unIO (h b) new_t
```

Now, we generally have

```
case (case e of case e of
pat1 -> ex1) of ≡ pat1 -> case ex1 of
pat2 -> ex2 pat2 -> ex2
```

per equation 3.17.3.(a) of the language report, so this law holds not only modulo `seq`

.

Summarising, `IO`

satisfies the monad laws, except for the fact that `seq`

can distinguish `undefined`

and `\s -> undefined s`

. The same holds for `State[T]`

, `Reader[T]`

, `(->) a`

, and any other monads wrapping a function type.

`seq`

?`IO`

.