module UnitTests( allUnitTests ) where import Test.HUnit import qualified Data.Graph.Inductive.Graph as ING import qualified Data.Graph.Inductive.PatriciaTree as FGR import Data.List(foldl', sort, sortOn) import Translate(translateStringToSyntaxGraph) import TranslateCore(syntaxGraphToFglGraph, SyntaxGraph(..), SgBind(..)) import Types(SgNamedNode(..), Edge(..), SyntaxNode(..), IngSyntaxGraph, NodeName(..), LikeApplyFlavor(..), NameAndPort(..)) import qualified GraphAlgorithms import Util(fromMaybeError) -- Unit Test Helpers -- assertAllEqual :: (Eq a, Show a) => [a] -> Test assertAllEqual items = case items of [] -> TestCase $ assertFailure "assertAllEqual: argument is empty list" (first : rest) -> TestList $ fmap (first ~=?) rest assertEqualSyntaxGraphs :: [String] -> Test assertEqualSyntaxGraphs ls = assertAllEqual $ fmap (renameGraph . translateStringToSyntaxGraph) ls -- BEGIN renameGraph -- type NameMap = [(NodeName, NodeName)] renameNode :: NameMap -> Int -> SgNamedNode -> (SgNamedNode, NameMap, Int) renameNode nameMap counter (SgNamedNode nodeName syntaxNode) = (newNamedNode, nameMap3, newCounter) where newNodeName = NodeName counter nameMap2 = (nodeName, newNodeName) : nameMap (newSyntaxNode, nameMap3, newCounter) = renameSyntaxNode nameMap2 syntaxNode (counter + 1) newNamedNode = SgNamedNode newNodeName newSyntaxNode maybeRenameNodeFolder :: ([Maybe SgNamedNode], NameMap, Int) -> Maybe SgNamedNode -> ([Maybe SgNamedNode], NameMap, Int) maybeRenameNodeFolder (renamedNodes, nameMap, counter) mNode = case mNode of Nothing -> (Nothing:renamedNodes, nameMap, counter) Just node -> (Just newNamedNode:renamedNodes, newNameMap, newCounter) where (newNamedNode, newNameMap, newCounter) = renameNode nameMap counter node renameSyntaxNode :: NameMap -> SyntaxNode -> Int -> (SyntaxNode, NameMap, Int) renameSyntaxNode nameMap node counter = case node of -- TODO Keep the Nothing subNodes NestedPatternApplyNode s subNodes -> (NestedPatternApplyNode s (reverse renamedSubNodes), newNameMap, counter2) where (renamedSubNodes, newNameMap, counter2) = foldl' maybeRenameNodeFolder ([], nameMap, counter) subNodes _ -> (node, nameMap, counter) renameNodeFolder :: ([SgNamedNode], NameMap, Int) -> SgNamedNode -> ([SgNamedNode], NameMap, Int) renameNodeFolder state@(renamedNodes, nameMap, counter) node@(SgNamedNode nodeName _) = case lookup nodeName nameMap of Nothing -> (newNamedNode:renamedNodes, newNameMap, newCounter) where (newNamedNode, newNameMap, newCounter) = renameNode nameMap counter node Just _ -> error $ "renameNode: node already in name map. State = " ++ show state ++ " Node = " ++ show node renameNamePort :: NameMap -> NameAndPort -> NameAndPort renameNamePort nameMap nameAndPort@(NameAndPort name port) = NameAndPort newName port where newName = fromMaybeError errorStr $ lookup name nameMap errorStr = "renameNamePort: name not found. name = " ++ show name ++ "\nNameAndPort = " ++ show nameAndPort ++ "\nNameMap = " ++ show nameMap renameEdge :: NameMap -> Edge -> Edge renameEdge nameMap (Edge options ends (np1, np2)) = Edge options ends (renameNamePort nameMap np1, renameNamePort nameMap np2) renameSource :: NameMap -> SgBind -> SgBind renameSource nameMap (SgBind str ref) = SgBind str newRef where newRef = case ref of Left _ -> ref Right namePort@(NameAndPort _ _) -> Right $ renameNamePort nameMap namePort renameEmbed :: NameMap -> (NodeName, NodeName) -> (NodeName, NodeName) renameEmbed nameMap (leftName, rightName) = (newLeftName, newRightName) where newLeftName = fromMaybeError "renameEmbed: leftName not found" (lookup leftName nameMap) newRightName = fromMaybeError "renameEmbed: RightName not found" (lookup rightName nameMap) -- TODO May want to remove names for sub-nodes removeNames :: SgNamedNode -> SyntaxNode removeNames (SgNamedNode _ syntaxNode) = syntaxNode -- TODO Rename sinks -- TODO Add unit tests for renameGraph renameGraph :: SyntaxGraph -> SyntaxGraph renameGraph (SyntaxGraph nodes edges sinks sources embedMap) = SyntaxGraph renamedNodes renamedEdges sinks renamedSources renamedEmbedMap where (renamedNodes, nameMap, _) = foldl' renameNodeFolder ([], [], 0) $ sortOn removeNames nodes renamedEdges = sort $ fmap (renameEdge nameMap) edges renamedSources = sort $ fmap (renameSource nameMap) sources renamedEmbedMap = sort $ fmap (renameEmbed nameMap) embedMap -- END renameGraph -- END Unit Test Helpers -- -- 0:(toName "app02",ApplyNode 1)->[] -- 1:(toName "f0",LiteralNode "f")->[(Edge {edgeOptions = [], edgeEnds = (EndNone,EndNone), edgeConnection = (NameAndPort (toName "f0") Nothing,NameAndPort (toName "app02") (Just 0))},0)] -- 2:(toName "x1",LiteralNode "x")->[(Edge {edgeOptions = [], edgeEnds = (EndNone,EndNone), edgeConnection = (NameAndPort (toName "x1") Nothing,NameAndPort (toName "app02") (Just 2))},0)] -- 3:(toName "y3",NameNode "y")->[(Edge {edgeOptions = [], edgeEnds = (EndNone,EndNone), edgeConnection = (NameAndPort (toName "y3") Nothing,NameAndPort (toName "app02") (Just 1))},0)] singleApplyGraph :: FGR.Gr SgNamedNode Edge singleApplyGraph = syntaxGraphToFglGraph $ translateStringToSyntaxGraph "y = f x" makeTreeRootTest :: (String, [Maybe SgNamedNode], String) -> Test makeTreeRootTest (testName, expected, haskellString) = TestCase $ assertEqual testName expected actual where actual = fmap (ING.lab graph) treeRoots graph = syntaxGraphToFglGraph $ translateStringToSyntaxGraph haskellString treeRoots = GraphAlgorithms.findTreeRoots graph treeRootTests :: Test treeRootTests = TestList $ fmap makeTreeRootTest treeRootTestList where treeRootTestList = [ ("single apply", [Just $ SgNamedNode (NodeName 2) (LikeApplyNode ApplyNodeFlavor 1)], "y = f x"), -- TODO Fix test below ("double apply", [Just $ SgNamedNode (NodeName 3) (LikeApplyNode ComposeNodeFlavor 2)], "y = f (g x)"), ("recursive apply", [Just $ SgNamedNode (NodeName 3) (LikeApplyNode ComposeNodeFlavor 2)], "y = f (g y)") ] makeChildCanBeEmbeddedTest :: ING.Graph gr => (String, IngSyntaxGraph gr, ING.Node, Bool) -> Test makeChildCanBeEmbeddedTest (testName, graph, node, expected) =TestCase $ assertEqual testName expected canBeEmbedded where canBeEmbedded = GraphAlgorithms.nodeWillBeEmbedded graph node -- TODO Add more cases for childCanBeEmbeddedTests -- TODO Fix these tests childCanBeEmbeddedTests :: Test childCanBeEmbeddedTests = TestList $ fmap makeChildCanBeEmbeddedTest childCanBeEmbeddedList where childCanBeEmbeddedList = [ ("single apply, ap", singleApplyGraph, 0, False), ("single apply, f", singleApplyGraph, 1, True), ("single apply, x", singleApplyGraph, 2, True), ("single apply, y", singleApplyGraph, 3, False) ] collapseUnitTests :: Test collapseUnitTests = TestList[ TestLabel "findTreeRoots" treeRootTests --TestLabel "childCanBeEmbedded" childCanBeEmbeddedTests ] -- Translate unit tests applyTests :: Test applyTests = TestList [ TestLabel "dollarTests1" $ assertEqualSyntaxGraphs [ "y = f x", "y = f $ x" ] , TestLabel "dollarTests2" $ assertEqualSyntaxGraphs [ "y = f (g x)", "y = f $ (g x)", "y = f $ g $ x", "y = f (g $ x)" ] , TestLabel "dollarTests3" $ assertEqualSyntaxGraphs [ "y = f 1 (g 2)", "y = f 1 $ g 2" ] , assertEqualSyntaxGraphs [ "y = f 3 4", "y = (f 3) 4" ] ] composeApplyTests :: Test composeApplyTests = TestList [ TestLabel "composeApplyTests1" $ assertEqualSyntaxGraphs [ "y = f (g x)", "y = (f . g) x", "y = f . g $ x" ] , TestLabel "composeApplyTests2" $ assertEqualSyntaxGraphs [ "y = f3 (f2 (f1 x))", "y = f3 . f2 . f1 $ x", "y = (f3 . f2 . f1) x" ] ] infixTests :: Test infixTests = TestList [ TestLabel "infixTests1" $ assertEqualSyntaxGraphs [ "y = (+) 1 2", "y = ((+) 1) 2", "y = 1 + 2", "y = (1 +) 2" ] , TestLabel "infixTests2" $ assertEqualSyntaxGraphs [ "y = f (1 +) 2", "y = f ((+) 1) 2" ] ] letTests :: Test letTests = TestList [ TestLabel "letTests1" $ assertEqualSyntaxGraphs [ "y = f 1", "y = let x = 1 in f x", "y = let {b = a; a = 1} in f b" ] , assertEqualSyntaxGraphs [ "y = 2", "y = let z = 2 in z", "y = let {z = 2; z2 = z} in z2" ] , assertEqualSyntaxGraphs [ "y = f y", "y = let x = f x in x" ] , assertEqualSyntaxGraphs [ "y = f 7 5", "y = let {a = 7; b = f a 5} in b" ] , assertEqualSyntaxGraphs [ "y x = x", "y x = let z = x in z" ] , assertEqualSyntaxGraphs [ "fibs = let {y = cons 0 (cons 1 (zipWith (+) y (tail y)))} in y", "fibs = cons 0 (cons 1 (zipWith (+) fibs (tail fibs)))" ] , assertEqualSyntaxGraphs [ "y x = y x", "y = let {z = (\\x -> y x)} in z", "y = let {z x = y x} in z " ] , assertEqualSyntaxGraphs [ "y = f 3 y", "y = x where x = f 3 y", "y = let x = f 3 y in x" ] , assertEqualSyntaxGraphs [ "y x1 = f x1", "y x1 = let {x2 = x1; x3 = x2; x4 = f x3} in x4" ] , -- TODO Fix this test. The second line has two apply icons instead of one. -- See VisualTranslateTests/letTests -- assertEqualSyntaxGraphs [ -- "y x1 = (f x1) x1", -- "y x1 = let x2 = f x1 in x2 x1" -- ] assertEqualSyntaxGraphs [ "y x = 3", "y x = let x = 3 in x" ] -- TODO Fix test. Second line should use compose apply. -- See VisualTranslateTests/letTests -- assertEqualSyntaxGraphs [ -- "y = g $ f y", -- "y = let {a = f b; b = g a} in b" -- ] ] negateTests :: Test negateTests = TestList [ assertEqualSyntaxGraphs [ "y = negate 1", "y = -1" ] , assertEqualSyntaxGraphs [ "y = negate ((/) 1 2)", "y = -1/2" ] , assertEqualSyntaxGraphs [ "y = negate x", "y = -x" ] ] enumTests :: Test enumTests = TestList [ assertEqualSyntaxGraphs [ "y = enumFrom 1", "y = [1..]" ] , assertEqualSyntaxGraphs [ "y = enumFromThen 1 2", "y = [1,2..]" ] , assertEqualSyntaxGraphs [ "y = enumFromTo 0 10", "y = [0..10]" ] , assertEqualSyntaxGraphs [ "y = enumFromThenTo 0 1 10", "y = [0,1..10]" ] ] patternTests :: Test patternTests = TestList [ assertEqualSyntaxGraphs [ "y (F x) = x", "y = (\\(F x) -> x)" ] , assertEqualSyntaxGraphs [ "y = let {F x y = 3} in x y", "y = let {g = 3; F x y = g} in x y" ] ] lambdaTests :: Test lambdaTests = TestList [ assertEqualSyntaxGraphs [ "y x = (\\z -> x)", "y = (\\x -> (\\z -> x))" ] , -- TODO These tests fail since the lambda node has a " tempvar" param name. -- assertEqualSyntaxGraphs [ -- "y x = case x of {0 -> 1; 3 -> 5}", -- "{y 0 = 1; y 3 = 5}" -- ] -- , -- assertEqualSyntaxGraphs [ -- "y p = case p of {F x -> x; G x -> x}", -- "{y (F x) = x; y (G x) = x}" -- ] -- , -- assertEqualSyntaxGraphs [ -- -- TODO Since there are no patterns for z, this should just be "case p of" -- "y p z = case (p, z) of {((F x), z') -> x z'; ((G x), z') -> z' x}", -- "{y (F x) z = x z; y (G x) z = z x}" -- ] -- , assertEqualSyntaxGraphs [ "y x = f x y", "y x = z where z = f x y" ] ] fmapTests :: Test fmapTests = TestList [ assertEqualSyntaxGraphs [ "y = fmap f x", "y = f <$> x" ] , assertEqualSyntaxGraphs [ "y = f1 (fmap f2 (f3 x))", "y = f1 $ f2 <$> f3 x" ] ] -- Yes, the commas get their own line translateUnitTests :: Test translateUnitTests = TestList [ TestLabel "fmapTest" fmapTests , TestLabel "applyTests" applyTests , TestLabel "composeApplyTests" composeApplyTests , TestLabel "infixTests" infixTests , TestLabel "letTests" letTests , TestLabel "negateTests" negateTests , TestLabel "enumTests" enumTests , TestLabel "patternTests" patternTests , TestLabel "lambdaTests" lambdaTests ] allUnitTests :: Test allUnitTests = TestList[ TestLabel "collapseUnitTests" collapseUnitTests, TestLabel "translateTests" translateUnitTests ]