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Rob Rix 2015-12-17 13:43:00 -05:00
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1
semantic-diff.cabal
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@ -81,7 +81,6 @@ test-suite semantic-diff-test
type: exitcode-stdio-1.0
hs-source-dirs: test
main-is: Spec.hs
other-modules: OrderedMapSpec
build-depends: base
, containers
, free

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test/RangeSpec.hs Normal file
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module RangeSpec where
import Test.Hspec
import Range
spec :: Spec
spec = describe "rangesAndWordsFrom" $ do
it "should produce no ranges for the empty string" $
rangesAndWordsFrom 0 [] `shouldBe` []
it "should produce no ranges for whitespace" $
rangesAndWordsFrom 0 " \t\n " `shouldBe` []
it "should produce a list containing the range of the string for a single-word string" $
rangesAndWordsFrom 0 "word" `shouldBe` [ (Range 0 4, "word") ]
it "should produce a list of ranges for whitespace-separated words" $
rangesAndWordsFrom 0 "wordOne wordTwo" `shouldBe` [ (Range 0 7, "wordOne"), (Range 8 15, "wordTwo") ]
it "should skip multiple whitespace characters" $
rangesAndWordsFrom 0 "a b" `shouldBe` [ (Range 0 1, "a"), (Range 3 4, "b") ]
it "should skip whitespace at the start" $
rangesAndWordsFrom 0 " a b" `shouldBe` [ (Range 2 3, "a"), (Range 4 5, "b") ]
it "should skip whitespace at the end" $
rangesAndWordsFrom 0 "a b " `shouldBe` [ (Range 0 1, "a"), (Range 2 3, "b") ]
it "should produce ranges offset by its start index" $
rangesAndWordsFrom 100 "a b" `shouldBe` [ (Range 100 101, "a"), (Range 102 103, "b") ]

265
test/Spec.hs
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@ -1,264 +1 @@
module Main where
import qualified InterpreterSpec
import qualified OrderedMapSpec
import Categorizable
import Diff
import Interpreter
import Patch
import Range
import Split
import Syntax
import Term
import Control.Comonad.Cofree
import Control.Monad
import Control.Monad.Free hiding (unfold)
import qualified Data.List as List
import qualified OrderedMap as Map
import qualified Data.Set as Set
import GHC.Generics
import Test.Hspec
import Test.Hspec.QuickCheck
import Test.QuickCheck hiding (Fixed)
newtype ArbitraryTerm a annotation = ArbitraryTerm (annotation, (Syntax a (ArbitraryTerm a annotation)))
deriving (Show, Eq, Generic)
unTerm :: ArbitraryTerm a annotation -> Term a annotation
unTerm arbitraryTerm = unfold unpack arbitraryTerm
where unpack (ArbitraryTerm (annotation, syntax)) = (annotation, syntax)
instance (Eq a, Eq annotation, Arbitrary a, Arbitrary annotation) => Arbitrary (ArbitraryTerm a annotation) where
arbitrary = sized (\ x -> boundedTerm x x) -- first indicates the cube of the max length of lists, second indicates the cube of the max depth of the tree
where boundedTerm maxLength maxDepth = ArbitraryTerm <$> ((,) <$> arbitrary <*> boundedSyntax maxLength maxDepth)
boundedSyntax _ maxDepth | maxDepth <= 0 = liftM Leaf arbitrary
boundedSyntax maxLength maxDepth = frequency
[ (12, liftM Leaf arbitrary),
(1, liftM Indexed $ take maxLength <$> listOf (smallerTerm maxLength maxDepth)),
(1, liftM Fixed $ take maxLength <$> listOf (smallerTerm maxLength maxDepth)),
(1, liftM (Keyed . Map.fromList) $ take maxLength <$> listOf (arbitrary >>= (\x -> ((,) x) <$> smallerTerm maxLength maxDepth))) ]
smallerTerm maxLength maxDepth = boundedTerm (div maxLength 3) (div maxDepth 3)
shrink term@(ArbitraryTerm (annotation, syntax)) = (++) (subterms term) $ filter (/= term) $
ArbitraryTerm <$> ((,) <$> shrink annotation <*> case syntax of
Leaf a -> Leaf <$> shrink a
Indexed i -> Indexed <$> (List.subsequences i >>= recursivelyShrink)
Fixed f -> Fixed <$> (List.subsequences f >>= recursivelyShrink)
Keyed k -> Keyed . Map.fromList <$> (List.subsequences (Map.toList k) >>= recursivelyShrink))
data CategorySet = A | B | C | D deriving (Eq, Show)
instance Categorizable CategorySet where
categories A = Set.fromList [ "a" ]
categories B = Set.fromList [ "b" ]
categories C = Set.fromList [ "c" ]
categories D = Set.fromList [ "d" ]
instance Arbitrary CategorySet where
arbitrary = elements [ A, B, C, D ]
instance Arbitrary HTML where
arbitrary = oneof [
Text <$> arbitrary,
Span <$> arbitrary <*> arbitrary,
const Break <$> (arbitrary :: Gen ()) ]
instance Arbitrary Line where
arbitrary = oneof [
Line <$> arbitrary <*> arbitrary,
const EmptyLine <$> (arbitrary :: Gen ()) ]
instance Arbitrary Row where
arbitrary = oneof [
Row <$> arbitrary <*> arbitrary ]
main :: IO ()
main = hspec $ do
describe "Term" $ do
prop "equality is reflexive" $
\ a -> unTerm a == unTerm (a :: ArbitraryTerm String ())
describe "Diff" $ do
prop "equality is reflexive" $
\ a b -> let diff = interpret comparable (unTerm a) (unTerm (b :: ArbitraryTerm String CategorySet)) in
diff == diff
prop "equal terms produce identity diffs" $
\ a -> let term = unTerm (a :: ArbitraryTerm String CategorySet) in
diffCost (interpret comparable term term) == 0
describe "annotatedToRows" $ do
it "outputs one row for single-line unchanged leaves" $
annotatedToRows (unchanged "a" "leaf" (Leaf "")) "a" "a" `shouldBe` ([ Row (Line False [ span "a" ]) (Line False [ span "a" ]) ], (Range 0 1, Range 0 1))
it "outputs one row for single-line empty unchanged indexed nodes" $
annotatedToRows (unchanged "[]" "branch" (Indexed [])) "[]" "[]" `shouldBe` ([ Row (Line False [ Ul (Just "category-branch") [ Text "[]" ] ]) (Line False [ Ul (Just "category-branch") [ Text "[]" ] ]) ], (Range 0 2, Range 0 2))
it "outputs one row for single-line non-empty unchanged indexed nodes" $
annotatedToRows (unchanged "[ a, b ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 5 $ unchanged "b" "leaf" (Leaf "")
])) "[ a, b ]" "[ a, b ]" `shouldBe` ([ Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) ], (Range 0 8, Range 0 8))
it "outputs one row for single-line non-empty formatted indexed nodes" $
annotatedToRows (formatted "[ a, b ]" "[ a, b ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 6 $ unchanged "b" "leaf" (Leaf "")
])) "[ a, b ]" "[ a, b ]" `shouldBe` ([ Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) ], (Range 0 8, Range 0 9))
it "outputs two rows for two-line non-empty unchanged indexed nodes" $
annotatedToRows (unchanged "[ a,\nb ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 5 $ unchanged "b" "leaf" (Leaf "")
])) "[ a,\nb ]" "[ a,\nb ]" `shouldBe`
([
Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ",", Break ] ])
(Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ",", Break] ]),
Row (Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
(Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
], (Range 0 8, Range 0 8))
it "outputs two rows for two-line non-empty formatted indexed nodes" $
annotatedToRows (formatted "[ a,\nb ]" "[\na,\nb ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 5 $ unchanged "b" "leaf" (Leaf "")
])) "[ a,\nb ]" "[\na,\nb ]" `shouldBe`
([
Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ",", Break ] ])
(Line False [ Ul (Just "category-branch") [ Text "[", Break ] ]),
Row EmptyLine
(Line False [ Ul (Just "category-branch") [ span "a", Text ",", Break ] ]),
Row (Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
(Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
], (Range 0 8, Range 0 8))
it "" $
let (sourceA, sourceB) = ("[\na\n,\nb]", "[a,b]") in
annotatedToRows (formatted sourceA sourceB "branch" (Indexed [
Free . offsetAnnotated 2 1 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 6 3 $ unchanged "b" "leaf" (Leaf "")
])) sourceA sourceB `shouldBe`
([
Row (Line False [ Ul (Just "category-branch") [ Text "[", Break ] ])
(Line False [ Ul (Just "category-branch") [ Text "[", span "a", Text ",", span "b", Text "]" ] ]),
Row (Line False [ Ul (Just "category-branch") [ span "a", Break ] ])
EmptyLine,
Row (Line False [ Ul (Just "category-branch") [ Text ",", Break ] ])
EmptyLine,
Row (Line False [ Ul (Just "category-branch") [ span "b", Text "]" ] ])
EmptyLine
], (Range 0 8, Range 0 5))
it "should split multi-line deletions across multiple rows" $
let (sourceA, sourceB) = ("/*\n*/\na", "a") in
annotatedToRows (formatted sourceA sourceB "branch" (Indexed [
Pure . Delete $ (Info (Range 0 5) (Set.fromList ["leaf"]) :< (Leaf "")),
Free . offsetAnnotated 6 0 $ unchanged "a" "leaf" (Leaf "")
])) sourceA sourceB `shouldBe`
([
Row (Line True [ Ul (Just "category-branch") [ Div (Just "delete") [ span "/*", Break ] ] ]) EmptyLine,
Row (Line True [ Ul (Just "category-branch") [ Div (Just "delete") [ span "*/" ], Break ] ]) EmptyLine,
Row (Line False [ Ul (Just "category-branch") [ span "a" ] ]) (Line False [ Ul (Just "category-branch") [ span "a" ] ])
], (Range 0 7, Range 0 1))
describe "unicode" $
it "equivalent precomposed and decomposed characters are not equal" $
let (sourceA, sourceB) = ("t\776", "\7831")
syntax = Leaf . Pure $ Replace (info sourceA "leaf" :< (Leaf "")) (info sourceB "leaf" :< (Leaf ""))
in
annotatedToRows (formatted sourceA sourceB "leaf" syntax) sourceA sourceB `shouldBe`
([ Row (Line False [ span "t\776" ]) (Line False [ span "\7831"]) ], (Range 0 2, Range 0 1))
describe "adjoin2" $ do
prop "is idempotent for additions of empty rows" $
\ a -> adjoin2 (adjoin2 [ a ] mempty) mempty == (adjoin2 [ a ] mempty)
prop "is identity on top of empty rows" $
\ a -> adjoin2 [ mempty ] a == [ a ]
prop "is identity on top of no rows" $
\ a -> adjoin2 [] a == [ a ]
it "appends appends HTML onto incomplete lines" $
adjoin2 [ rightRowText "[" ] (rightRowText "a") `shouldBe`
[ rightRow [ Text "[", Text "a" ] ]
it "does not append HTML onto complete lines" $
adjoin2 [ leftRow [ Break ] ] (leftRowText ",") `shouldBe`
[ leftRowText ",", leftRow [ Break ] ]
it "appends breaks onto incomplete lines" $
adjoin2 [ leftRowText "a" ] (leftRow [ Break ]) `shouldBe`
[ leftRow [ Text "a", Break ] ]
it "does not promote HTML through empty lines onto complete lines" $
adjoin2 [ rightRowText "b", leftRow [ Break ] ] (leftRowText "a") `shouldBe`
[ leftRowText "a", rightRowText "b", leftRow [ Break ] ]
it "promotes breaks through empty lines onto incomplete lines" $
adjoin2 [ rightRowText "c", rowText "a" "b" ] (leftRow [ Break ]) `shouldBe`
[ rightRowText "c", Row (Line False [ Text "a", Break ]) (Line False [ Text "b" ]) ]
describe "termToLines" $ do
it "splits multi-line terms into multiple lines" $
termToLines (Info (Range 0 5) (Set.singleton "leaf") :< (Leaf "")) "/*\n*/"
`shouldBe`
([
Line True [ span "/*", Break ],
Line True [ span "*/" ]
], Range 0 5)
describe "openLine" $ do
it "should produce the earliest non-empty line in a list, if open" $
openLine [
Line True [ Div (Just "delete") [ span "*/" ] ],
Line True [ Div (Just "delete") [ span " * Debugging", Break ] ],
Line True [ Div (Just "delete") [ span "/*", Break ] ]
] `shouldBe` (Just $ Line True [ Div (Just "delete") [ span "*/" ] ])
it "should return Nothing if the earliest non-empty line is closed" $
openLine [
Line True [ Div (Just "delete") [ span " * Debugging", Break ] ]
] `shouldBe` Nothing
describe "rangesAndWordsFrom" $ do
it "should produce no ranges for the empty string" $
rangesAndWordsFrom 0 [] `shouldBe` []
it "should produce no ranges for whitespace" $
rangesAndWordsFrom 0 " \t\n " `shouldBe` []
it "should produce a list containing the range of the string for a single-word string" $
rangesAndWordsFrom 0 "word" `shouldBe` [ (Range 0 4, "word") ]
it "should produce a list of ranges for whitespace-separated words" $
rangesAndWordsFrom 0 "wordOne wordTwo" `shouldBe` [ (Range 0 7, "wordOne"), (Range 8 15, "wordTwo") ]
it "should skip multiple whitespace characters" $
rangesAndWordsFrom 0 "a b" `shouldBe` [ (Range 0 1, "a"), (Range 3 4, "b") ]
it "should skip whitespace at the start" $
rangesAndWordsFrom 0 " a b" `shouldBe` [ (Range 2 3, "a"), (Range 4 5, "b") ]
it "should skip whitespace at the end" $
rangesAndWordsFrom 0 "a b " `shouldBe` [ (Range 0 1, "a"), (Range 2 3, "b") ]
it "should produce ranges offset by its start index" $
rangesAndWordsFrom 100 "a b" `shouldBe` [ (Range 100 101, "a"), (Range 102 103, "b") ]
describe "OrderedMap" OrderedMapSpec.spec
describe "InterpreterSpec" InterpreterSpec.spec
where
rightRowText text = rightRow [ Text text ]
rightRow xs = Row EmptyLine (Line False xs)
leftRowText text = leftRow [ Text text ]
leftRow xs = Row (Line False xs) EmptyLine
rowText a b = Row (Line False [ Text a ]) (Line False [ Text b ])
info source category = Info (totalRange source) (Set.fromList [ category ])
unchanged source category = formatted source source category
formatted source1 source2 category = Annotated (info source1 category, info source2 category)
offsetInfo by (Info (Range start end) categories) = Info (Range (start + by) (end + by)) categories
offsetAnnotated by1 by2 (Annotated (left, right) syntax) = Annotated (offsetInfo by1 left, offsetInfo by2 right) syntax
span = Span (Just "category-leaf")
{-# OPTIONS_GHC -F -pgmF hspec-discover #-}

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test/SplitSpec.hs Normal file
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module SplitSpec where
import Test.Hspec
import Split
import qualified Data.Set as Set
import Diff
import Range
import Test.Hspec.QuickCheck
import Test.QuickCheck hiding (Fixed)
import Control.Comonad.Cofree
import Control.Monad.Free hiding (unfold)
import Patch
import Syntax
instance Arbitrary Row where
arbitrary = oneof [
Row <$> arbitrary <*> arbitrary ]
instance Arbitrary HTML where
arbitrary = oneof [
Text <$> arbitrary,
Span <$> arbitrary <*> arbitrary,
const Break <$> (arbitrary :: Gen ()) ]
instance Arbitrary Line where
arbitrary = oneof [
Line <$> arbitrary <*> arbitrary,
const EmptyLine <$> (arbitrary :: Gen ()) ]
spec :: Spec
spec = do
describe "annotatedToRows" $ do
it "outputs one row for single-line unchanged leaves" $
annotatedToRows (unchanged "a" "leaf" (Leaf "")) "a" "a" `shouldBe` ([ Row (Line False [ span "a" ]) (Line False [ span "a" ]) ], (Range 0 1, Range 0 1))
it "outputs one row for single-line empty unchanged indexed nodes" $
annotatedToRows (unchanged "[]" "branch" (Indexed [])) "[]" "[]" `shouldBe` ([ Row (Line False [ Ul (Just "category-branch") [ Text "[]" ] ]) (Line False [ Ul (Just "category-branch") [ Text "[]" ] ]) ], (Range 0 2, Range 0 2))
it "outputs one row for single-line non-empty unchanged indexed nodes" $
annotatedToRows (unchanged "[ a, b ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 5 $ unchanged "b" "leaf" (Leaf "")
])) "[ a, b ]" "[ a, b ]" `shouldBe` ([ Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) ], (Range 0 8, Range 0 8))
it "outputs one row for single-line non-empty formatted indexed nodes" $
annotatedToRows (formatted "[ a, b ]" "[ a, b ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 6 $ unchanged "b" "leaf" (Leaf "")
])) "[ a, b ]" "[ a, b ]" `shouldBe` ([ Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ", ", span "b", Text " ]" ] ]) ], (Range 0 8, Range 0 9))
it "outputs two rows for two-line non-empty unchanged indexed nodes" $
annotatedToRows (unchanged "[ a,\nb ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 5 $ unchanged "b" "leaf" (Leaf "")
])) "[ a,\nb ]" "[ a,\nb ]" `shouldBe`
([
Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ",", Break ] ])
(Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ",", Break] ]),
Row (Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
(Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
], (Range 0 8, Range 0 8))
it "outputs two rows for two-line non-empty formatted indexed nodes" $
annotatedToRows (formatted "[ a,\nb ]" "[\na,\nb ]" "branch" (Indexed [
Free . offsetAnnotated 2 2 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 5 5 $ unchanged "b" "leaf" (Leaf "")
])) "[ a,\nb ]" "[\na,\nb ]" `shouldBe`
([
Row (Line False [ Ul (Just "category-branch") [ Text "[ ", span "a", Text ",", Break ] ])
(Line False [ Ul (Just "category-branch") [ Text "[", Break ] ]),
Row EmptyLine
(Line False [ Ul (Just "category-branch") [ span "a", Text ",", Break ] ]),
Row (Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
(Line False [ Ul (Just "category-branch") [ span "b", Text " ]" ] ])
], (Range 0 8, Range 0 8))
it "" $
let (sourceA, sourceB) = ("[\na\n,\nb]", "[a,b]") in
annotatedToRows (formatted sourceA sourceB "branch" (Indexed [
Free . offsetAnnotated 2 1 $ unchanged "a" "leaf" (Leaf ""),
Free . offsetAnnotated 6 3 $ unchanged "b" "leaf" (Leaf "")
])) sourceA sourceB `shouldBe`
([
Row (Line False [ Ul (Just "category-branch") [ Text "[", Break ] ])
(Line False [ Ul (Just "category-branch") [ Text "[", span "a", Text ",", span "b", Text "]" ] ]),
Row (Line False [ Ul (Just "category-branch") [ span "a", Break ] ])
EmptyLine,
Row (Line False [ Ul (Just "category-branch") [ Text ",", Break ] ])
EmptyLine,
Row (Line False [ Ul (Just "category-branch") [ span "b", Text "]" ] ])
EmptyLine
], (Range 0 8, Range 0 5))
it "should split multi-line deletions across multiple rows" $
let (sourceA, sourceB) = ("/*\n*/\na", "a") in
annotatedToRows (formatted sourceA sourceB "branch" (Indexed [
Pure . Delete $ (Info (Range 0 5) (Set.fromList ["leaf"]) :< (Leaf "")),
Free . offsetAnnotated 6 0 $ unchanged "a" "leaf" (Leaf "")
])) sourceA sourceB `shouldBe`
([
Row (Line True [ Ul (Just "category-branch") [ Div (Just "delete") [ span "/*", Break ] ] ]) EmptyLine,
Row (Line True [ Ul (Just "category-branch") [ Div (Just "delete") [ span "*/" ], Break ] ]) EmptyLine,
Row (Line False [ Ul (Just "category-branch") [ span "a" ] ]) (Line False [ Ul (Just "category-branch") [ span "a" ] ])
], (Range 0 7, Range 0 1))
describe "unicode" $
it "equivalent precomposed and decomposed characters are not equal" $
let (sourceA, sourceB) = ("t\776", "\7831")
syntax = Leaf . Pure $ Replace (info sourceA "leaf" :< (Leaf "")) (info sourceB "leaf" :< (Leaf ""))
in
annotatedToRows (formatted sourceA sourceB "leaf" syntax) sourceA sourceB `shouldBe`
([ Row (Line False [ span "t\776" ]) (Line False [ span "\7831"]) ], (Range 0 2, Range 0 1))
describe "adjoin2" $ do
prop "is idempotent for additions of empty rows" $
\ a -> adjoin2 (adjoin2 [ a ] mempty) mempty == (adjoin2 [ a ] mempty)
prop "is identity on top of empty rows" $
\ a -> adjoin2 [ mempty ] a == [ a ]
prop "is identity on top of no rows" $
\ a -> adjoin2 [] a == [ a ]
it "appends appends HTML onto incomplete lines" $
adjoin2 [ rightRowText "[" ] (rightRowText "a") `shouldBe`
[ rightRow [ Text "[", Text "a" ] ]
it "does not append HTML onto complete lines" $
adjoin2 [ leftRow [ Break ] ] (leftRowText ",") `shouldBe`
[ leftRowText ",", leftRow [ Break ] ]
it "appends breaks onto incomplete lines" $
adjoin2 [ leftRowText "a" ] (leftRow [ Break ]) `shouldBe`
[ leftRow [ Text "a", Break ] ]
it "does not promote HTML through empty lines onto complete lines" $
adjoin2 [ rightRowText "b", leftRow [ Break ] ] (leftRowText "a") `shouldBe`
[ leftRowText "a", rightRowText "b", leftRow [ Break ] ]
it "promotes breaks through empty lines onto incomplete lines" $
adjoin2 [ rightRowText "c", rowText "a" "b" ] (leftRow [ Break ]) `shouldBe`
[ rightRowText "c", Row (Line False [ Text "a", Break ]) (Line False [ Text "b" ]) ]
describe "termToLines" $ do
it "splits multi-line terms into multiple lines" $
termToLines (Info (Range 0 5) (Set.singleton "leaf") :< (Leaf "")) "/*\n*/"
`shouldBe`
([
Line True [ span "/*", Break ],
Line True [ span "*/" ]
], Range 0 5)
describe "openLine" $ do
it "should produce the earliest non-empty line in a list, if open" $
openLine [
Line True [ Div (Just "delete") [ span "*/" ] ],
Line True [ Div (Just "delete") [ span " * Debugging", Break ] ],
Line True [ Div (Just "delete") [ span "/*", Break ] ]
] `shouldBe` (Just $ Line True [ Div (Just "delete") [ span "*/" ] ])
it "should return Nothing if the earliest non-empty line is closed" $
openLine [
Line True [ Div (Just "delete") [ span " * Debugging", Break ] ]
] `shouldBe` Nothing
where
rightRowText text = rightRow [ Text text ]
rightRow xs = Row EmptyLine (Line False xs)
leftRowText text = leftRow [ Text text ]
leftRow xs = Row (Line False xs) EmptyLine
rowText a b = Row (Line False [ Text a ]) (Line False [ Text b ])
info source category = Info (totalRange source) (Set.fromList [ category ])
unchanged source category = formatted source source category
formatted source1 source2 category = Annotated (info source1 category, info source2 category)
offsetInfo by (Info (Range start end) categories) = Info (Range (start + by) (end + by)) categories
offsetAnnotated by1 by2 (Annotated (left, right) syntax) = Annotated (offsetInfo by1 left, offsetInfo by2 right) syntax
span = Span (Just "category-leaf")

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test/TermSpec.hs Normal file
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module TermSpec where
import Test.Hspec
import Test.Hspec.QuickCheck
import Test.QuickCheck hiding (Fixed)
import Categorizable
import qualified OrderedMap as Map
import qualified Data.List as List
import qualified Data.Set as Set
import Interpreter
import Diff
import Control.Comonad.Cofree
import Control.Monad
import GHC.Generics
import Syntax
import Term
newtype ArbitraryTerm a annotation = ArbitraryTerm (annotation, (Syntax a (ArbitraryTerm a annotation)))
deriving (Show, Eq, Generic)
unTerm :: ArbitraryTerm a annotation -> Term a annotation
unTerm = unfold unpack
where unpack (ArbitraryTerm (annotation, syntax)) = (annotation, syntax)
instance (Eq a, Eq annotation, Arbitrary a, Arbitrary annotation) => Arbitrary (ArbitraryTerm a annotation) where
arbitrary = sized (\ x -> boundedTerm x x) -- first indicates the cube of the max length of lists, second indicates the cube of the max depth of the tree
where boundedTerm maxLength maxDepth = ArbitraryTerm <$> ((,) <$> arbitrary <*> boundedSyntax maxLength maxDepth)
boundedSyntax _ maxDepth | maxDepth <= 0 = liftM Leaf arbitrary
boundedSyntax maxLength maxDepth = frequency
[ (12, liftM Leaf arbitrary),
(1, liftM Indexed $ take maxLength <$> listOf (smallerTerm maxLength maxDepth)),
(1, liftM Fixed $ take maxLength <$> listOf (smallerTerm maxLength maxDepth)),
(1, liftM (Keyed . Map.fromList) $ take maxLength <$> listOf (arbitrary >>= (\x -> ((,) x) <$> smallerTerm maxLength maxDepth))) ]
smallerTerm maxLength maxDepth = boundedTerm (div maxLength 3) (div maxDepth 3)
shrink term@(ArbitraryTerm (annotation, syntax)) = (++) (subterms term) $ filter (/= term) $
ArbitraryTerm <$> ((,) <$> shrink annotation <*> case syntax of
Leaf a -> Leaf <$> shrink a
Indexed i -> Indexed <$> (List.subsequences i >>= recursivelyShrink)
Fixed f -> Fixed <$> (List.subsequences f >>= recursivelyShrink)
Keyed k -> Keyed . Map.fromList <$> (List.subsequences (Map.toList k) >>= recursivelyShrink))
data CategorySet = A | B | C | D deriving (Eq, Show)
instance Categorizable CategorySet where
categories A = Set.fromList [ "a" ]
categories B = Set.fromList [ "b" ]
categories C = Set.fromList [ "c" ]
categories D = Set.fromList [ "d" ]
instance Arbitrary CategorySet where
arbitrary = elements [ A, B, C, D ]
main :: IO ()
main = hspec spec
spec :: Spec
spec = do
describe "Term" $ do
prop "equality is reflexive" $
\ a -> unTerm a == unTerm (a :: ArbitraryTerm String ())
describe "Diff" $ do
prop "equality is reflexive" $
\ a b -> let diff = interpret comparable (unTerm a) (unTerm (b :: ArbitraryTerm String CategorySet)) in
diff == diff
prop "equal terms produce identity diffs" $
\ a -> let term = unTerm (a :: ArbitraryTerm String CategorySet) in
diffCost (interpret comparable term term) == 0