algebraic-graphs-0.0.1: test/Algebra/Graph/Test/Relation.hs
{-# LANGUAGE ViewPatterns #-}
-----------------------------------------------------------------------------
-- |
-- Module : Algebra.Graph.Test.Relation
-- Copyright : (c) Andrey Mokhov 2016-2017
-- License : MIT (see the file LICENSE)
-- Maintainer : andrey.mokhov@gmail.com
-- Stability : experimental
--
-- Testsuite for 'Relation'.
--
-----------------------------------------------------------------------------
module Algebra.Graph.Test.Relation (
-- * Testsuite
testRelation
) where
import Algebra.Graph.Relation
import Algebra.Graph.Relation.Internal
import Algebra.Graph.Relation.Symmetric
import Algebra.Graph.Test
import qualified Algebra.Graph.Class as C
import qualified Data.Set as Set
type RI = Relation Int
type II = Int -> Int
type IB = Int -> Bool
sizeLimit :: Testable prop => prop -> Property
sizeLimit = mapSize (min 10)
testRelation :: IO ()
testRelation = do
putStrLn "\n============ Relation ============"
test "Axioms of graphs" $ sizeLimit $ (axioms :: GraphTestsuite RI)
test "Consistency of arbitraryRelation" $ \(m :: RI) ->
consistent m
test "Consistency of fromAdjacencyList" $ \xs ->
consistent (fromAdjacencyList xs :: RI)
putStrLn "\n============ Show ============"
test "show (empty :: Relation Int) == \"empty\"" $
show (empty :: Relation Int) == "empty"
test "show (1 :: Relation Int) == \"vertex 1\"" $
show (1 :: Relation Int) == "vertex 1"
test "show (1 + 2 :: Relation Int) == \"vertices [1,2]\"" $
show (1 + 2 :: Relation Int) == "vertices [1,2]"
test "show (1 * 2 :: Relation Int) == \"edge 1 2\"" $
show (1 * 2 :: Relation Int) == "edge 1 2"
test "show (1 * 2 * 3 :: Relation Int) == \"edges [(1,2),(1,3),(2,3)]\"" $
show (1 * 2 * 3 :: Relation Int) == "edges [(1,2),(1,3),(2,3)]"
test "show (1 * 2 + 3 :: Relation Int) == \"graph [1,2,3] [(1,2)]\"" $
show (1 * 2 + 3 :: Relation Int) == "graph [1,2,3] [(1,2)]"
putStrLn "\n============ empty ============"
test "isEmpty empty == True" $
isEmpty (empty :: RI) == True
test "hasVertex x empty == False" $ \(x :: Int) ->
hasVertex x empty == False
test "vertexCount empty == 0" $
vertexCount(empty :: RI) == 0
test "edgeCount empty == 0" $
edgeCount (empty :: RI) == 0
putStrLn "\n============ vertex ============"
test "isEmpty (vertex x) == False" $ \(x :: Int) ->
isEmpty (vertex x) == False
test "hasVertex x (vertex x) == True" $ \(x :: Int) ->
hasVertex x (vertex x) == True
test "hasVertex 1 (vertex 2) == False" $
hasVertex 1 (vertex 2 :: RI) == False
test "vertexCount (vertex x) == 1" $ \(x :: Int) ->
vertexCount (vertex x) == 1
test "edgeCount (vertex x) == 0" $ \(x :: Int) ->
edgeCount (vertex x) == 0
putStrLn "\n============ edge ============"
test "edge x y == connect (vertex x) (vertex y)" $ \(x :: Int) y ->
(edge x y :: RI) == connect (vertex x) (vertex y)
test "hasEdge x y (edge x y) == True" $ \(x :: Int) y ->
hasEdge x y (edge x y) == True
test "edgeCount (edge x y) == 1" $ \(x :: Int) y ->
edgeCount (edge x y) == 1
test "vertexCount (edge 1 1) == 1" $
vertexCount (edge 1 1 :: RI) == 1
test "vertexCount (edge 1 2) == 2" $
vertexCount (edge 1 2 :: RI) == 2
putStrLn "\n============ overlay ============"
test "isEmpty (overlay x y) == isEmpty x && isEmpty y" $ \(x :: RI) y ->
isEmpty (overlay x y) == (isEmpty x && isEmpty y)
test "hasVertex z (overlay x y) == hasVertex z x || hasVertex z y" $ \(x :: RI) y z ->
hasVertex z (overlay x y) == (hasVertex z x || hasVertex z y)
test "vertexCount (overlay x y) >= vertexCount x" $ \(x :: RI) y ->
vertexCount (overlay x y) >= vertexCount x
test "vertexCount (overlay x y) <= vertexCount x + vertexCount y" $ \(x :: RI) y ->
vertexCount (overlay x y) <= vertexCount x + vertexCount y
test "edgeCount (overlay x y) >= edgeCount x" $ \(x :: RI) y ->
edgeCount (overlay x y) >= edgeCount x
test "edgeCount (overlay x y) <= edgeCount x + edgeCount y" $ \(x :: RI) y ->
edgeCount (overlay x y) <= edgeCount x + edgeCount y
test "vertexCount (overlay 1 2) == 2" $
vertexCount (overlay 1 2 :: RI) == 2
test "edgeCount (overlay 1 2) == 0" $
edgeCount (overlay 1 2 :: RI) == 0
putStrLn "\n============ connect ============"
test "isEmpty (connect x y) == isEmpty x && isEmpty y" $ \(x :: RI) y ->
isEmpty (connect x y) == (isEmpty x && isEmpty y)
test "hasVertex z (connect x y) == hasVertex z x || hasVertex z y" $ \(x :: RI) y z ->
hasVertex z (connect x y) == (hasVertex z x || hasVertex z y)
test "vertexCount (connect x y) >= vertexCount x" $ \(x :: RI) y ->
vertexCount (connect x y) >= vertexCount x
test "vertexCount (connect x y) <= vertexCount x + vertexCount y" $ \(x :: RI) y ->
vertexCount (connect x y) <= vertexCount x + vertexCount y
test "edgeCount (connect x y) >= edgeCount x" $ \(x :: RI) y ->
edgeCount (connect x y) >= edgeCount x
test "edgeCount (connect x y) >= edgeCount y" $ \(x :: RI) y ->
edgeCount (connect x y) >= edgeCount y
test "edgeCount (connect x y) >= vertexCount x * vertexCount y" $ \(x :: RI) y ->
edgeCount (connect x y) >= vertexCount x * vertexCount y
test "edgeCount (connect x y) <= vertexCount x * vertexCount y + edgeCount x + edgeCount y" $ \(x :: RI) y ->
edgeCount (connect x y) <= vertexCount x * vertexCount y + edgeCount x + edgeCount y
test "vertexCount (connect 1 2) == 2" $
vertexCount (connect 1 2 :: RI) == 2
test "edgeCount (connect 1 2) == 1" $
edgeCount (connect 1 2 :: RI) == 1
putStrLn "\n============ vertices ============"
test "vertices [] == empty" $
vertices [] == (empty :: RI)
test "vertices [x] == vertex x" $ \(x :: Int) ->
vertices [x] == (vertex x :: RI)
test "hasVertex x . vertices == elem x" $ \x (xs :: [Int]) ->
(hasVertex x . vertices) xs == elem x xs
test "vertexCount . vertices == length . nub" $ \(xs :: [Int]) ->
(vertexCount . vertices) xs == (length . nubOrd) xs
test "vertexSet . vertices == Set.fromList" $ \(xs :: [Int]) ->
(vertexSet . vertices) xs == Set.fromList xs
putStrLn "\n============ edges ============"
test "edges [] == empty" $
edges [] == (empty :: RI)
test "edges [(x,y)] == edge x y" $ \(x :: Int) y ->
edges [(x,y)] == (edge x y :: RI)
test "edgeCount . edges == length . nub" $ \(xs :: [(Int, Int)]) ->
(edgeCount . edges) xs == (length . nubOrd) xs
putStrLn "\n============ overlays ============"
test "overlays [] == empty" $
overlays [] == (empty :: RI)
test "overlays [x] == x" $ \(x :: RI) ->
overlays [x] == x
test "overlays [x,y] == overlay x y" $ \(x :: RI) y ->
overlays [x,y] == overlay x y
test "isEmpty . overlays == all isEmpty" $ mapSize (min 10) $ \(xs :: [RI]) ->
(isEmpty . overlays) xs == all isEmpty xs
putStrLn "\n============ connects ============"
test "connects [] == empty" $
connects [] == (empty :: RI)
test "connects [x] == x" $ \(x :: RI) ->
connects [x] == x
test "connects [x,y] == connect x y" $ \(x :: RI) y ->
connects [x,y] == connect x y
test "isEmpty . connects == all isEmpty" $ mapSize (min 10) $ \(xs :: [RI]) ->
(isEmpty . connects) xs == all isEmpty xs
putStrLn "\n============ graph ============"
test "graph [] [] == empty" $
graph [] [] == (empty :: RI)
test "graph [x] [] == vertex x" $ \(x :: Int) ->
graph [x] [] == (vertex x :: RI)
test "graph [] [(x,y)] == edge x y" $ \(x :: Int) y ->
graph [] [(x,y)] == (edge x y :: RI)
test "graph vs es == overlay (vertices vs) (edges es)" $ \(vs :: [Int]) es ->
graph vs es == (overlay (vertices vs) (edges es) :: RI)
putStrLn "\n============ fromAdjacencyList ============"
test "fromAdjacencyList [] == empty" $
fromAdjacencyList [] == (empty :: RI)
test "fromAdjacencyList [(x, [])] == vertex x" $ \(x :: Int) ->
fromAdjacencyList [(x, [])] == vertex x
test "fromAdjacencyList [(x, [y])] == edge x y" $ \(x :: Int) y ->
fromAdjacencyList [(x, [y])] == edge x y
test "overlay (fromAdjacencyList xs) (fromAdjacencyList ys) == fromAdjacencyList (xs ++ ys)" $ \xs ys ->
overlay (fromAdjacencyList xs) (fromAdjacencyList ys) ==(fromAdjacencyList (xs ++ ys) :: RI)
putStrLn "\n============ isSubgraphOf ============"
test "isSubgraphOf empty x == True" $ \(x :: RI) ->
isSubgraphOf empty x == True
test "isSubgraphOf (vertex x) empty == False" $ \x ->
isSubgraphOf (vertex x) (empty :: RI) == False
test "isSubgraphOf x (overlay x y) == True" $ \(x :: RI) y ->
isSubgraphOf x (overlay x y) == True
test "isSubgraphOf (overlay x y) (connect x y) == True" $ \(x :: RI) y ->
isSubgraphOf (overlay x y) (connect x y) == True
test "isSubgraphOf (path xs) (circuit xs) == True" $ \xs ->
isSubgraphOf (path xs :: RI)(circuit xs) == True
putStrLn "\n============ isEmpty ============"
test "isEmpty empty == True" $
isEmpty (empty :: RI) == True
test "isEmpty (overlay empty empty) == True" $
isEmpty (overlay empty empty :: RI) == True
test "isEmpty (vertex x) == False" $ \(x :: Int) ->
isEmpty (vertex x) == False
test "isEmpty (removeVertex x $ vertex x) == True" $ \(x :: Int) ->
isEmpty (removeVertex x $ vertex x) == True
test "isEmpty (removeEdge x y $ edge x y) == False" $ \(x :: Int) y ->
isEmpty (removeEdge x y $ edge x y) == False
putStrLn "\n============ hasVertex ============"
test "hasVertex x empty == False" $ \(x :: Int) ->
hasVertex x empty == False
test "hasVertex x (vertex x) == True" $ \(x :: Int) ->
hasVertex x (vertex x) == True
test "hasVertex x . removeVertex x == const False" $ \(x :: Int) y ->
hasVertex x (removeVertex x y)==const False y
putStrLn "\n============ hasEdge ============"
test "hasEdge x y empty == False" $ \(x :: Int) y ->
hasEdge x y empty == False
test "hasEdge x y (vertex z) == False" $ \(x :: Int) y z ->
hasEdge x y (vertex z) == False
test "hasEdge x y (edge x y) == True" $ \(x :: Int) y ->
hasEdge x y (edge x y) == True
test "hasEdge x y . removeEdge x y == const False" $ \(x :: Int) y z ->
hasEdge x y (removeEdge x y z)==const False z
putStrLn "\n============ vertexCount ============"
test "vertexCount empty == 0" $
vertexCount (empty :: RI) == 0
test "vertexCount (vertex x) == 1" $ \(x :: Int) ->
vertexCount (vertex x) == 1
test "vertexCount == length . vertexList" $ \(x :: RI) ->
vertexCount x == (length . vertexList) x
putStrLn "\n============ edgeCount ============"
test "edgeCount empty == 0" $
edgeCount (empty :: RI) == 0
test "edgeCount (vertex x) == 0" $ \(x :: Int) ->
edgeCount (vertex x) == 0
test "edgeCount (edge x y) == 1" $ \(x :: Int) y ->
edgeCount (edge x y) == 1
test "edgeCount == length . edgeList" $ \(x :: RI) ->
edgeCount x == (length . edgeList) x
putStrLn "\n============ vertexList ============"
test "vertexList empty == []" $
vertexList (empty :: RI) == []
test "vertexList (vertex x) == [x]" $ \(x :: Int) ->
vertexList (vertex x) == [x]
test "vertexList . vertices == nub . sort" $ \(xs :: [Int]) ->
(vertexList . vertices) xs == (nubOrd . sort) xs
putStrLn "\n============ edgeList ============"
test "edgeList empty == []" $
edgeList (empty :: RI ) == []
test "edgeList (vertex x) == []" $ \(x :: Int) ->
edgeList (vertex x) == []
test "edgeList (edge x y) == [(x,y)]" $ \(x :: Int) y ->
edgeList (edge x y) == [(x,y)]
test "edgeList (star 2 [3,1]) == [(2,1), (2,3)]" $
edgeList (star 2 [3,1]) == [(2,1), (2,3 :: Int)]
test "edgeList . edges == nub . sort" $ \(xs :: [(Int, Int)]) ->
(edgeList . edges) xs == (nubOrd . sort) xs
putStrLn "\n============ vertexSet ============"
test "vertexSet empty == Set.empty" $
vertexSet(empty :: RI)== Set.empty
test "vertexSet . vertex == Set.singleton" $ \(x :: Int) ->
(vertexSet . vertex) x== Set.singleton x
test "vertexSet . vertices == Set.fromList" $ \(xs :: [Int]) ->
(vertexSet . vertices) xs == Set.fromList xs
test "vertexSet . clique == Set.fromList" $ \(xs :: [Int]) ->
(vertexSet . clique) xs == Set.fromList xs
putStrLn "\n============ edgeSet ============"
test "edgeSet empty == Set.empty" $
edgeSet (empty :: RI) == Set.empty
test "edgeSet (vertex x) == Set.empty" $ \(x :: Int) ->
edgeSet (vertex x) == Set.empty
test "edgeSet (edge x y) == Set.singleton (x,y)" $ \(x :: Int) y ->
edgeSet (edge x y) == Set.singleton (x,y)
test "edgeSet . edges == Set.fromList" $ \(xs :: [(Int, Int)]) ->
(edgeSet . edges) xs== Set.fromList xs
putStrLn "\n============ preset ============"
test "preset x empty == Set.empty" $ \(x :: Int) ->
preset x empty == Set.empty
test "preset x (vertex x) == Set.empty" $ \(x :: Int) ->
preset x (vertex x) == Set.empty
test "preset 1 (edge 1 2) == Set.empty" $
preset 1 (edge 1 2) ==(Set.empty :: Set.Set Int)
test "preset y (edge x y) == Set.fromList [x]" $ \(x :: Int) y ->
preset y (edge x y) ==(Set.fromList [x] :: Set.Set Int)
putStrLn "\n============ postset ============"
test "postset x empty == Set.empty" $ \(x :: Int) ->
postset x empty == Set.empty
test "postset x (vertex x) == Set.empty" $ \(x :: Int) ->
postset x (vertex x) == Set.empty
test "postset x (edge x y) == Set.fromList [y]" $ \(x :: Int) y ->
postset x (edge x y) == Set.fromList [y]
test "postset 2 (edge 1 2) == Set.empty" $
postset 2 (edge 1 2) ==(Set.empty :: Set.Set Int)
putStrLn "\n============ path ============"
test "path [] == empty" $
path [] == (empty :: RI)
test "path [x] == vertex x" $ \(x :: Int) ->
path [x] == (vertex x :: RI)
test "path [x,y] == edge x y" $ \(x :: Int) y ->
path [x,y] == (edge x y :: RI)
putStrLn "\n============ circuit ============"
test "circuit [] == empty" $
circuit [] == (empty :: RI)
test "circuit [x] == edge x x" $ \(x :: Int) ->
circuit [x] == (edge x x :: RI)
test "circuit [x,y] == edges [(x,y), (y,x)]" $ \(x :: Int) y ->
circuit [x,y] == (edges [(x,y), (y,x)] :: RI)
putStrLn "\n============ clique ============"
test "clique [] == empty" $
clique [] == (empty :: RI)
test "clique [x] == vertex x" $ \(x :: Int) ->
clique [x] == (vertex x :: RI)
test "clique [x,y] == edge x y" $ \(x :: Int) y ->
clique [x,y] == (edge x y :: RI)
test "clique [x,y,z] == edges [(x,y), (x,z), (y,z)]" $ \(x :: Int) y z ->
clique [x,y,z] == (edges [(x,y), (x,z), (y,z)] :: RI)
putStrLn "\n============ biclique ============"
test "biclique [] [] == empty" $
biclique [] [] == (empty :: RI)
test "biclique [x] [] == vertex x" $ \(x :: Int) ->
biclique [x] [] == (vertex x :: RI)
test "biclique [] [y] == vertex y" $ \(y :: Int) ->
biclique [] [y] == (vertex y :: RI)
test "biclique [x1,x2] [y1,y2] == edges [(x1,y1), (x1,y2), (x2,y1), (x2,y2)]" $ \(x1 :: Int) x2 y1 y2 ->
biclique [x1,x2] [y1,y2] == (edges [(x1,y1), (x1,y2), (x2,y1), (x2,y2)] :: RI)
putStrLn "\n============ star ============"
test "star x [] == vertex x" $ \(x :: Int) ->
star x [] == (vertex x :: RI)
test "star x [y] == edge x y" $ \(x :: Int) y ->
star x [y] == (edge x y :: RI)
test "star x [y,z] == edges [(x,y), (x,z)]" $ \(x :: Int) y z ->
star x [y,z] == (edges [(x,y), (x,z)] :: RI)
putStrLn "\n============ removeVertex ============"
test "removeVertex x (vertex x) == empty" $ \(x :: Int) ->
removeVertex x (vertex x) == (empty :: RI)
test "removeVertex x . removeVertex x == removeVertex x" $ \x (y :: RI) ->
(removeVertex x . removeVertex x)y==(removeVertex x y :: RI)
putStrLn "\n============ removeEdge ============"
test "removeEdge x y (edge x y) == vertices [x, y]" $ \(x :: Int) y ->
removeEdge x y (edge x y) == (vertices [x, y] :: RI)
test "removeEdge x y . removeEdge x y == removeEdge x y" $ \(x :: Int) y z ->
(removeEdge x y . removeEdge x y)z==(removeEdge x y z :: RI)
test "removeEdge x y . removeVertex x == removeVertex x" $ \(x :: Int) y z ->
(removeEdge x y . removeVertex x)z==(removeVertex x z :: RI)
test "removeEdge 1 1 (1 * 1 * 2 * 2) == 1 * 2 * 2" $
removeEdge 1 1 (1 * 1 * 2 * 2) == (1 * 2 * (2 :: RI))
test "removeEdge 1 2 (1 * 1 * 2 * 2) == 1 * 1 + 2 * 2" $
removeEdge 1 2 (1 * 1 * 2 * 2) == (1 * 1 + 2 * (2 :: RI))
putStrLn "\n============ replaceVertex ============"
test "replaceVertex x x == id" $ \x (y :: RI) ->
replaceVertex x x y == y
test "replaceVertex x y (vertex x) == vertex y" $ \x (y :: Int) ->
replaceVertex x y (vertex x) == (vertex y :: RI)
test "replaceVertex x y == mergeVertices (== x) y" $ \x y z ->
replaceVertex x y z == (mergeVertices (== x) y z :: RI)
putStrLn "\n============ mergeVertices ============"
test "mergeVertices (const False) x == id" $ \x (y :: RI) ->
mergeVertices (const False) x y == y
test "mergeVertices (== x) y == replaceVertex x y" $ \x y (z :: RI) ->
mergeVertices (== x) y z == (replaceVertex x y z :: RI)
test "mergeVertices even 1 (0 * 2) == 1 * 1" $
mergeVertices even 1 (0 * 2) == (1 * 1 :: RI)
test "mergeVertices odd 1 (3 + 4 * 5) == 4 * 1" $
mergeVertices odd 1 (3 + 4 * 5) == (4 * 1 :: RI)
putStrLn "\n============ gmap ============"
test "gmap f empty == empty" $ \(apply -> f :: II) ->
gmap f empty == empty
test "gmap f (vertex x) == vertex (f x)" $ \(apply -> f :: II) x ->
gmap f (vertex x) == vertex (f x)
test "gmap f (edge x y) == edge (f x) (f y)" $ \(apply -> f :: II) x y ->
gmap f (edge x y) == edge (f x) (f y)
test "gmap id == id" $ \x ->
gmap id x == (x :: RI)
test "gmap f . gmap g == gmap (f . g)" $ \(apply -> f :: II) (apply -> g :: II) x ->
(gmap f . gmap g) x== gmap (f . g) x
putStrLn "\n============ induce ============"
test "induce (const True) x == x" $ \(x :: RI) ->
induce (const True) x == x
test "induce (const False) x == empty" $ \(x :: RI) ->
induce (const False) x == (empty :: RI)
test "induce (/= x) == removeVertex x" $ \x (y :: RI) ->
induce (/= x) y == (removeVertex x y :: RI)
test "induce p . induce q == induce (\\x -> p x && q x)" $ \(apply -> p :: IB) (apply -> q :: IB) (y :: RI) ->
(induce p . induce q) y == (induce (\x -> p x && q x) y :: RI)
test "isSubgraphOf (induce p x) x == True" $ \(apply -> p :: IB) (x :: RI) ->
isSubgraphOf (induce p x) x == True
putStrLn "\n============ reflexiveClosure ============"
test "reflexiveClosure empty == empty" $
reflexiveClosure empty ==(empty :: RI)
test "reflexiveClosure (vertex x) == edge x x" $ \(x :: Int) ->
reflexiveClosure (vertex x) == edge x x
putStrLn "\n============ symmetricClosure ============"
test "symmetricClosure empty == empty" $
symmetricClosure empty ==(empty :: RI)
test "symmetricClosure (vertex x) == vertex x" $ \(x :: Int) ->
symmetricClosure (vertex x) == vertex x
test "symmetricClosure (edge x y) == edges [(x, y), (y, x)]" $ \(x :: Int) y ->
symmetricClosure (edge x y) == edges [(x, y), (y, x)]
putStrLn "\n============ transitiveClosure ============"
test "transitiveClosure empty == empty" $
transitiveClosure empty ==(empty :: RI)
test "transitiveClosure (vertex x) == vertex x" $ \(x :: Int) ->
transitiveClosure (vertex x) == vertex x
test "transitiveClosure (path $ nub xs) == clique (nub $ xs)" $ \(xs :: [Int]) ->
transitiveClosure (path $ nubOrd xs) == clique (nubOrd $ xs)
putStrLn "\n============ preorderClosure ============"
test "preorderClosure empty == empty" $
preorderClosure empty ==(empty :: RI)
test "preorderClosure (vertex x) == edge x x" $ \(x :: Int) ->
preorderClosure (vertex x) == edge x x
test "preorderClosure (path $ nub xs) == reflexiveClosure (clique $ nub xs)" $ \(xs :: [Int]) ->
preorderClosure (path $ nubOrd xs) == reflexiveClosure (clique $ nubOrd xs)
putStrLn "\n============ ReflexiveRelation ============"
test "Axioms of reflexive graphs" $ sizeLimit
(reflexiveAxioms :: GraphTestsuite (ReflexiveRelation Int))
putStrLn "\n============ SymmetricRelation ============"
test "Axioms of undirected graphs" $ sizeLimit
(undirectedAxioms :: GraphTestsuite (SymmetricRelation Int))
putStrLn "\n============ neighbours ============"
test "neighbours x empty == Set.empty" $ \(x :: Int) ->
neighbours x C.empty == Set.empty
test "neighbours x (vertex x) == Set.empty" $ \(x :: Int) ->
neighbours x (C.vertex x) == Set.empty
test "neighbours x (edge x y) == Set.fromList [y]" $ \(x :: Int) y ->
neighbours x (C.edge x y) == Set.fromList [y]
test "neighbours y (edge x y) == Set.fromList [x]" $ \(x :: Int) y ->
neighbours y (C.edge x y) == Set.fromList [x]
putStrLn "\n============ TransitiveRelation ============"
test "Axioms of transitive graphs" $ sizeLimit
(transitiveAxioms :: GraphTestsuite (TransitiveRelation Int))
test "path xs == (clique xs :: TransitiveRelation Int)" $ sizeLimit $ \xs ->
C.path xs == (C.clique xs :: TransitiveRelation Int)
putStrLn "\n============ PreorderRelation ============"
test "Axioms of preorder graphs" $ sizeLimit
(preorderAxioms :: GraphTestsuite (PreorderRelation Int))
test "path xs == (clique xs :: PreorderRelation Int)" $ sizeLimit $ \xs ->
C.path xs == (C.clique xs :: PreorderRelation Int)