-- | -- Module : Test.LeanCheck.Function.ListsOfPairs -- Copyright : (c) 2015-2018 Rudy Matela -- License : 3-Clause BSD (see the file LICENSE) -- Maintainer : Rudy Matela <rudy@matela.com.br> -- -- This module is part of LeanCheck, -- a simple enumerative property-based testing library. -- -- This module exports means to enumerate functions via lists of pairs. -- -- This module considers functions as a finite list of exceptional input-output -- cases to a default value (list of pairs of arguments and results). module Test.LeanCheck.Function.ListsOfPairs ( (-->>) , exceptionPairs ) where import Test.LeanCheck import Test.LeanCheck.Tiers import Data.Maybe (fromMaybe) -- | Given tiers of argument and result values, -- return tiers of functional values. (-->>) :: Eq a => [[a]] -> [[b]] -> [[a->b]] xss -->> yss | finite xss = mapT ((undefined `mutate`) . zip (concat xss)) (products $ replicate (length $ concat xss) yss) | otherwise = concatMapT (\(r,yss) -> mapT (const r `mutate`) (exceptionPairs xss yss)) (choices yss) mutate :: Eq a => (a -> b) -> [(a,b)] -> (a -> b) mutate f ms = foldr mut f ms where mut (x',fx') f x = if x == x' then fx' else f x -- | Given tiers of input values and tiers of output values, -- return tiers with all possible lists of input-output pairs. -- These represent functional relations. -- In the implementation of '-->>', -- they represent exceptions to a constant function, -- hence the name 'exceptionPairs'. exceptionPairs :: [[a]] -> [[b]] -> [[ [(a,b)] ]] exceptionPairs xss yss = concatMapT exceptionsFor (incompleteSetsOf xss) where --exceptionsFor :: [a] -> [[ [(a,b)] ]] exceptionsFor xs = zip xs `mapT` products (const yss `map` xs) -- incompleteSetsOf is needed, instead of setsOf, because mutating *all* values -- of a constant function makes no sense (we would have already enumerated that -- function anyway). As of 2c23c1a, it makes no difference whether -- incompleteSetsOf is used instead of setsOf for types with less than 12 -- values because of the finite guard on `-->>`. -- | Returns tiers of sets excluding the universe set. -- -- > incompleteSetsOf (tiers :: [[Bool]]) = [[],[[False],[True]],[]] -- > incompleteSetsOf (tiers :: [[()]]) = [[]] -- -- This is the same as 'setsOf' on types with infinite values: -- -- > incompleteSetsOf (tiers :: [[Int]]) = setsOf (tiers :: [[Int]]) incompleteSetsOf :: [[a]] -> [[ [a] ]] incompleteSetsOf = init . setsOf -- the above implementation works because, and depends on the fact that: -- the last tier returned by setsOf contains only the complete set