Not satisfied with my other answer, I have come up with an awesomer one.

```
-- arb.hs
import Test.QuickCheck
import Control.Monad (liftM)
data SimpleType = SimpleType Int Char Bool String deriving(Show, Eq)
uncurry4 f (a,b,c,d) = f a b c d
instance Arbitrary SimpleType where
arbitrary = uncurry4 SimpleType `liftM` arbitrary
-- ^ this line is teh pwnzors.
-- Note how easily it can be adapted to other "simple" data types
```

```
ghci> :l arb.hs
[1 of 1] Compiling Main ( arb.hs, interpreted )
Ok, modules loaded: Main.
ghci> sample (arbitrary :: Gen SimpleType)
>>>a bunch of "Loading package" statements<<<
SimpleType 1 'B' False ""
SimpleType 0 '\n' True ""
SimpleType 0 '\186' False "\208! \227"
...
```

**Lengthy explanation of how I figured this out**

So here's how I got it. I was wondering, "well how is there already an `Arbitrary`

instance for `(Int, Int, Int, Int)`

? I'm sure no one *wrote* it, so it must be derived somehow. Sure enough, I found the following in the docs for instances of Arbitrary:

```
(Arbitrary a, Arbitrary b, Arbitrary c, Arbitrary d) => Arbitrary (a, b, c, d)
```

Well, if they already have that defined, then why not abuse it? Simple types that are merely composed of smaller Arbitrary data types are not much different than just a tuple.

So now I need to somehow transform the "arbitrary" method for the 4-tuple so that it works for my type. Uncurrying is probably involved.

Stop. Hoogle time!

(We can easily define our own `uncurry4`

, so assume we already have this to operate with.)

I have a generator, `arbitrary :: Gen (q,r,s,t)`

(where q,r,s,t are all instances of Arbitrary). But let's just say it's `arbitrary :: Gen a`

. In other words, `a`

represents `(q,r,s,t)`

. I have a function, `uncurry4`

, which has type `(q -> r -> s -> t -> b) -> (q,r,s,t) -> b`

. We are obviously going to apply uncurry4 to our `SimpleType`

constructor. So `uncurry4 SimpleType`

has type `(q,r,s,t) -> SimpleType`

. Let's keep the return value generic, though, because Hoogle doesn't know about our SimpleType. So remembering our definition of `a`

, we have essentially `uncurry4 SimpleType :: a -> b`

.

So I've got a `Gen a`

and a function `a -> b`

. And I want a `Gen b`

result. (Remember, for our situation, `a`

is `(q,r,s,t)`

and `b`

is `SimpleType`

). So I am looking for a function with this type signature: `Gen a -> (a -> b) -> Gen b`

. Hoogling that, and knowing that `Gen`

is an instance of `Monad`

, I immediately recognize `liftM`

as the monadical-magical solution to my problems.

Hoogle saves the day again. I knew there was probably some "lifting" combinator to get the desired result, but I honestly didn't think to use liftM (durrr!) until I hoogled the type signature.