The second approach, using tools like check or quickcheck, but...
Duplicating implementation details
If your duplicating then you're doing it wrong. In your code you write what the task is and how how the task is performed to a precise degree. In the test you give some invariants about the result.
A note on Known Answer Tests (KATs)
Like most generalizations, there are situations where this doesn't apply. One big area where KATs are dominant over random test vectors is cryptography (e.g. block ciphers) because there aren't supposed to be many visible invariants outside of what most type systems enforce (ex: block size). One property to check would be
decrypt(key,encrypt(key,msg)) == msg.
Simple geometry has a somewhat different problem in that no set of invariants is really a good check - you can say
0 < area(triangle) < triangle.width * triangle.height but that's just as bad. What I'm getting at here is you should be writing tests for a slightly higher level of code - something more complex that actually have a good chance of changing or being deceptively wrong.
Situations For Random Test Vectors
Some properties of code that indicate a good place for quick check properties include
- clear invariants
Trivial example using concatenation (combining two lists in series to form one new list):
Say I have a function
concat(xs,ys) = xs ++ ys. What can I check? Anything I expect to be true! Length? Yes! Elements? Yes!
prop_len(xs,ys) = len(xs) + len(ys) = len(concat(xs,ys))
let cs = concat(xs,ys)
elem(head xs, cs) && elem(head ys, cs) && prop_elem(tail xs,ys) && prop_elem(xs,tail ys)
// Yes, I left out the error checking for empty list, sue me.
Get the drift?