# How do I constrain QuickCheck when using type synonyms?

I am using QuickCheck to run arbitrary test cases on my code. However, in one portion of my code I have the type synonym:

``````type Vector = [Double]
``````

I also have a few functions that accept a number of `Vector`s as input. However, all of these functions require that the `Vector`s be of the same length.

Is there a way to constrain QuickCheck so that it only generates lists of length n?

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A simple solution is to not have an arbitrary instance but instead to do something like

``````import Test.QuickCheck

prop_vec :: Int -> Gen [Double]
prop_vec = flip replicateM arbitrary . abs

prop_addComm :: Int -> Gen Bool
prop_addComm i  = do
v <- prop_vec i
u <- prop_vec i
return \$ u + v = v + u --assuming you'd added a Num instance for your vectors
``````

There's never a typeclass so you get less helpful failures, but it's simpler to whip up.

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I'm not qualified to judge which answer is best - so I am selecting this answer because I was looking for a quick solution. –  sdasdadas Nov 4 '13 at 5:51
This actually seems to take quite a long time to hit the 100 test case cap for QuickCheck... I'm only adding the vectors together using `zipWith`. –  sdasdadas Nov 5 '13 at 7:24
@sdasdadas Try constraining the size of the number, I can show an example of this in a bit –  jozefg Nov 5 '13 at 12:47

The other obvious solution is to generate a list of tuples and unzip them. For example, in ghci:

``````> let allSameLength (xs:xss) = all (==length xs) (map length xss)
> quickCheck (\xys -> let (xs, ys) = unzip xys in allSameLength [xs, ys])
+++ OK, passed 100 tests.
> :{
| quickCheck (\wxyzs -> let
|   (wxs, yzs) = unzip wxyzs
|   (ws, xs) = unzip wxs
|   (ys, zs) = unzip yzs
|   in allSameLength [ws, xs, ys, zs])
| :}
+++ OK, passed 100 tests.
``````
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You can set constraints with the `==>` notation.

an example is:

``````prop_test xs = minimum xs == (head \$ sort xs)
``````

which fails:

``````*** Failed! Exception: 'Prelude.minimum: empty list' (after 1 test):
[]
``````

now with a constraint:

``````prop_test xs = not (null xs) ==> minimum xs == (head \$ sort xs)
``````

it works:

``````*Main> quickCheck prop_test
+++ OK, passed 100 tests.
``````

``````prop_test xs ys = length xs == length ys ==> undefined -- whatever you want
``````
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This can be really really slow though, the chances of coming up with two lists of the same size when your randomly generating them is slim. –  jozefg Nov 4 '13 at 4:29

Here's one possibility. We'll define a new class for types that can build a size-dependent random value. Then you can make a type-level list or tree or whatever and declare one `Arbitrary` instance for these once and for all.

``````import Control.Monad
import Test.QuickCheck

class SizedArbitrary a where
sizedArbitrary :: Int -> Gen a

instance Arbitrary a => SizedArbitrary [a] where
sizedArbitrary n = replicateM n arbitrary

data Branch a b = a :+ b deriving (Eq, Ord, Show, Read)
instance (SizedArbitrary a, SizedArbitrary b) => SizedArbitrary (Branch a b) where
sizedArbitrary n = liftM2 (:+) (sizedArbitrary n) (sizedArbitrary n)

instance (SizedArbitrary a, SizedArbitrary b) => Arbitrary (Branch a b) where
arbitrary = arbitrarySizedIntegral >>= sizedArbitrary . abs
``````

Then we can load it up in ghci and check out that it works:

``````*Main> let allSameLength (xs:xss) = all (==length xs) (map length xss)
*Main> quickCheck (\(xs :+ ys) -> allSameLength [xs, ys])
+++ OK, passed 100 tests.
*Main> quickCheck (\(ws :+ xs :+ ys :+ zs) -> allSameLength [ws, xs, ys, zs])
+++ OK, passed 100 tests.
``````
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