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Is it possible to verify that a function was called in Haskell HSpec?

Assuming I had two functions foo and bar that transform my data.

foo :: Stuff -> Stuff
bar :: Stuff -> Stuff

And I have a function that applies either foo or bar on Stuff depending on whether it received 'f' or 'b' as its second argument and returns the result of the applied function.

apply :: Stuff -> Char -> Stuff

And In my tests, I have tested each of the functions foo and bar comprehensively that i would not want to test there effect with in apply.

Is it possible for me to verify that a function foo or bar was called? depending on what argument is passed to apply?

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can't you write a print or similar statement into the body of foo and bar to see which one gets called? Which monads have you loaded in? –  pqnet Aug 6 '14 at 16:46
    
I am thinking more in terms of TDD, asserting using Hspec. Like how we do in OOP/imperative languages like ruby-rspec expect(user).to receive(:save) Is such a thing possible in purely functionally language like Haskell? –  Mukiza Andrew Aug 6 '14 at 16:51
4  
if you are purely functional, you shouldn't be able to observe whether you are executing a function or not, or how many times (because invoking function shouldn't have any side effect, and observing that you have executed that is indeed a side effect). I don't know much about ruby-rspec or hspec though, so I'm not sure, however in a purely functional language if you can't distinguish between the two return values, you are actually invoking the same function –  pqnet Aug 6 '14 at 16:54
2  
basically if you add metadata to the return value to recognize which one has been called, you are doing a monadic transformation: the monads in haskell do this kind of operation transparently if you use the do syntax. If you found an answer and it satisfies you you should write it down here and accept it, for future reference –  pqnet Aug 6 '14 at 17:05
1  
If you are only using this for debugging and not production code, you could cheat a little and use Debug.Trace. –  David Young Aug 6 '14 at 17:56

2 Answers 2

up vote 2 down vote accepted

"I'm thinking more TDD, like in an OOP language. Is such a thing possible in Haskell?"

A better question is "is such a thing necessary in Haskell?" ;-)

[I realise that is not the question you actually asked. Feel free to ignore this answer.]

In an OO language, we build objects that talk to other objects to get their job done. To test such an object, we build a bunch of fake objects, hook the real object up to the fake ones, run the method(s) we want to test, and assert that it calls faked methods with the expected inputs, etc.

In Haskell, we write functions. The only thing a pure function does is take some input, and produce some output. So the way to test that is to just run the thing, feeding it known inputs and checking that it returns known outputs. What other functions it calls in the process of doing that doesn't matter; all we care about is whether the answer is right.

In particular, the reason we don't usually do this in OOP is that calling some arbitrary method might cause "real work" to happen — reading or writing disk files, opening network connections, talking to databases and other servers, etc. If you're just testing one part of your code, you don't want the test to depend on whether some database is running on a real network server somewhere; you just want to test one little part of your code.

With Haskell, we separate anything that can affect the Real World from stuff that just does data transformations. Testing stuff that just transforms data in memory is delightfully trivial! (Testing the parts of your code that do interact with the Real World is still hard, in general. But hopefully those parts are very small now.)

The Haskell test style of choice seems to be property-based testing. For example, if you've got a function to solve an equation, you write a QuickCheck property that randomly generates 100 equations, and for each one, it checks whether the number returned actually solves the original equation or not. It's a tiny handful of code that automatically tests just about everything you'd ever want to know! (But not quite: You need to make sure that the "randomly" chosen equations actually test all the code paths you care about.)

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I figured that much after having conversations with people who know a lot more about Haskell and functional programming than me ;-). Thanks for your response, i intended to post a similar answer but I guess I wouldn't have phrased it as well as you did. –  Mukiza Andrew Aug 7 '14 at 17:40

(No exactly Haskell, but close.)

fooP = point . foo
-- testable property: forall s. foo s = runIdenity $ fooP s

barP = point . bar
-- similar testable property

fooAndWitness :: Stuff -> Writer String Stuff
fooAndWitness = fooM >> tell "foo"
-- testable property forall s. (foo s, "foo") = runWriter $ fooAndWitness s

barAndWitness :: Stuff -> Writer String Stuff
barAndWitness = barM >> tell "bar"
-- similar testable property

applyOpen :: Pointed p => (Stuff -> p Stuff) -> (Stuff -> p Stuff) -> Stuff -> Char -> p Stuff
applyOpen onF _   x 'f' = onF x
applyOpen _   onB x 'b' = onB x
applyOpen _   _   x _   = point x
-- semi-testable property (must fix p):
-- forall f b s c. let a = applyOn f b s c in a `elem` [f s, b s, point s]
-- In particular, if we choose p carefully we can be, at least stochastically,
-- sure that either f, b, or neither were called by having p = Const [Int], and running several tests
-- where two random numbers are chosen, `f _ = Const $ [rand1]`, and `b _ = Const $ [rand2]`
-- and verifying we get one of those numbers, which could not have been known when applyOpen was written.

applyM = applyOpen fooM barM
-- similar testable property, although but be loose the "rigged" tests for variable f/b, so
-- some of our correctness may have to follow from the definition.

apply = (runIdentity .) . applyM
-- similar testable property and caveat

Pointed is a type class that fits between Functor and Applicative and provides point with the same semantics as pure or return. It's only law follows from parametricity: (. point) . fmap = (point .)

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