1
1
mirror of https://github.com/github/semantic.git synced 2024-12-21 13:51:44 +03:00
semantic/test/AlignmentSpec.hs
2017-05-04 17:36:03 -04:00

322 lines
17 KiB
Haskell

{-# LANGUAGE DataKinds #-}
module AlignmentSpec where
import Alignment
import Control.Monad.State
import Data.Align hiding (align)
import Data.Bifunctor
import Data.Bifunctor.Join
import Data.Functor.Both as Both
import Data.Functor.Listable
import Data.List (nub)
import Data.Monoid hiding ((<>))
import Data.Record
import qualified Data.Text as Text
import Data.These
import Patch
import Prologue hiding (fst, snd)
import qualified Prologue
import Range
import qualified Source
import SplitDiff
import Syntax
import Term
import Test.Hspec (Spec, describe, it, parallel)
import Test.Hspec.Expectations.Pretty
import Test.Hspec.LeanCheck
import Test.LeanCheck
import GHC.Show (Show(..))
spec :: Spec
spec = parallel $ do
describe "alignBranch" $ do
it "produces symmetrical context" $
alignBranch getRange ([] :: [Join These (SplitDiff (Syntax Text) (Record '[Range]))]) (both [Range 0 2, Range 2 4] [Range 0 2, Range 2 4]) `shouldBe`
[ Join (These (Range 0 2, [])
(Range 0 2, []))
, Join (These (Range 2 4, [])
(Range 2 4, []))
]
it "produces asymmetrical context" $
alignBranch getRange ([] :: [Join These (SplitDiff (Syntax Text) (Record '[Range]))]) (both [Range 0 2, Range 2 4] [Range 0 1]) `shouldBe`
[ Join (These (Range 0 2, [])
(Range 0 1, []))
, Join (This (Range 2 4, []))
]
prop "covers every input line" $
\ elements -> let (_, children, ranges) = toAlignBranchInputs elements in
join <$> traverse (modifyJoin (fromThese [] []) . fmap (pure . Prologue.fst)) (alignBranch Prologue.snd children ranges) `shouldBe` ranges
prop "covers every input child" $
\ elements -> let (_, children, ranges) = toAlignBranchInputs elements in
sort (nub (keysOfAlignedChildren (alignBranch Prologue.snd children ranges))) `shouldBe` sort (nub (catMaybes (branchElementKey <$> elements)))
prop "covers every line of every input child" $
\ elements -> let (_, children, ranges) = toAlignBranchInputs elements in
sort (keysOfAlignedChildren (alignBranch Prologue.snd children ranges)) `shouldBe` sort (do
line <- children
these (pure . Prologue.fst) (pure . Prologue.fst) (\ (k1, _) (k2, _) -> [ k1, k2 ]) . runJoin $ line)
describe "alignDiff" $ do
it "aligns identical branches on a single line" $
let sources = both (Source.fromText "[ foo ]") (Source.fromText "[ foo ]") in
align sources (pure (info 0 7) `branch` [ pure (info 2 5) `leaf` "foo" ]) `shouldBe` prettyDiff sources
[ Join (These (info 0 7 `branch` [ info 2 5 `leaf` "foo" ])
(info 0 7 `branch` [ info 2 5 `leaf` "foo" ])) ]
it "aligns identical branches spanning multiple lines" $
let sources = both (Source.fromText "[\nfoo\n]") (Source.fromText "[\nfoo\n]") in
align sources (pure (info 0 7) `branch` [ pure (info 2 5) `leaf` "foo" ]) `shouldBe` prettyDiff sources
[ Join (These (info 0 2 `branch` [])
(info 0 2 `branch` []))
, Join (These (info 2 6 `branch` [ info 2 5 `leaf` "foo" ])
(info 2 6 `branch` [ info 2 5 `leaf` "foo" ]))
, Join (These (info 6 7 `branch` [])
(info 6 7 `branch` []))
]
it "aligns reformatted branches" $
let sources = both (Source.fromText "[ foo ]") (Source.fromText "[\nfoo\n]") in
align sources (pure (info 0 7) `branch` [ pure (info 2 5) `leaf` "foo" ]) `shouldBe` prettyDiff sources
[ Join (That (info 0 2 `branch` []))
, Join (These (info 0 7 `branch` [ info 2 5 `leaf` "foo" ])
(info 2 6 `branch` [ info 2 5 `leaf` "foo" ]))
, Join (That (info 6 7 `branch` []))
]
it "aligns nodes following reformatted branches" $
let sources = both (Source.fromText "[ foo ]\nbar\n") (Source.fromText "[\nfoo\n]\nbar\n") in
align sources (pure (info 0 12) `branch` [ pure (info 0 7) `branch` [ pure (info 2 5) `leaf` "foo" ], pure (info 8 11) `leaf` "bar" ]) `shouldBe` prettyDiff sources
[ Join (That (info 0 2 `branch` [ info 0 2 `branch` [] ]))
, Join (These (info 0 8 `branch` [ info 0 7 `branch` [ info 2 5 `leaf` "foo" ] ])
(info 2 6 `branch` [ info 2 6 `branch` [ info 2 5 `leaf` "foo" ] ]))
, Join (That (info 6 8 `branch` [ info 6 7 `branch` [] ]))
, Join (These (info 8 12 `branch` [ info 8 11 `leaf` "bar" ])
(info 8 12 `branch` [ info 8 11 `leaf` "bar" ]))
, Join (These (info 12 12 `branch` [])
(info 12 12 `branch` []))
]
it "aligns identical branches with multiple children on the same line" $
let sources = pure (Source.fromText "[ foo, bar ]") in
align sources (pure (info 0 12) `branch` [ pure (info 2 5) `leaf` "foo", pure (info 7 10) `leaf` "bar" ]) `shouldBe` prettyDiff sources
[ Join (runBothWith These (pure (info 0 12 `branch` [ info 2 5 `leaf` "foo", info 7 10 `leaf` "bar" ])) ) ]
it "aligns insertions" $
let sources = both (Source.fromText "a") (Source.fromText "a\nb") in
align sources (both (info 0 1) (info 0 3) `branch` [ pure (info 0 1) `leaf` "a", insert (info 2 3 `leaf` "b") ]) `shouldBe` prettyDiff sources
[ Join (These (info 0 1 `branch` [ info 0 1 `leaf` "a" ])
(info 0 2 `branch` [ info 0 1 `leaf` "a" ]))
, Join (That (info 2 3 `branch` [ insert (info 2 3 `leaf` "b") ]))
]
it "aligns total insertions" $
let sources = both (Source.fromText "") (Source.fromText "a") in
align sources (insert (info 0 1 `leaf` "a")) `shouldBe` prettyDiff sources
[ Join (That (insert (info 0 1 `leaf` "a"))) ]
it "aligns insertions into empty branches" $
let sources = both (Source.fromText "[ ]") (Source.fromText "[a]") in
align sources (pure (info 0 3) `branch` [ insert (info 1 2 `leaf` "a") ]) `shouldBe` prettyDiff sources
[ Join (That (info 0 3 `branch` [ insert (info 1 2 `leaf` "a") ]))
, Join (This (info 0 3 `branch` []))
]
it "aligns symmetrically following insertions" $
let sources = both (Source.fromText "a\nc") (Source.fromText "a\nb\nc") in
align sources (both (info 0 3) (info 0 5) `branch` [ pure (info 0 1) `leaf` "a", insert (info 2 3 `leaf` "b"), both (info 2 3) (info 4 5) `leaf` "c" ])
`shouldBe` prettyDiff sources
[ Join (These (info 0 2 `branch` [ info 0 1 `leaf` "a" ])
(info 0 2 `branch` [ info 0 1 `leaf` "a" ]))
, Join (That (info 2 4 `branch` [ insert (info 2 3 `leaf` "b") ]))
, Join (These (info 2 3 `branch` [ info 2 3 `leaf` "c" ])
(info 4 5 `branch` [ info 4 5 `leaf` "c" ]))
]
it "symmetrical nodes force the alignment of asymmetrical nodes on both sides" $
let sources = both (Source.fromText "[ a, b ]") (Source.fromText "[ b, c ]") in
align sources (pure (info 0 8) `branch` [ delete (info 2 3 `leaf` "a"), both (info 5 6) (info 2 3) `leaf` "b", insert (info 5 6 `leaf` "c") ]) `shouldBe` prettyDiff sources
[ Join (These (info 0 8 `branch` [ delete (info 2 3 `leaf` "a"), info 5 6 `leaf` "b" ])
(info 0 8 `branch` [ info 2 3 `leaf` "b", insert (info 5 6 `leaf` "c") ])) ]
it "when one of two symmetrical nodes must be split, splits the latter" $
let sources = both (Source.fromText "[ a, b ]") (Source.fromText "[ a\n, b\n]") in
align sources (both (info 0 8) (info 0 9) `branch` [ pure (info 2 3) `leaf` "a", both (info 5 6) (info 6 7) `leaf` "b" ]) `shouldBe` prettyDiff sources
[ Join (These (info 0 8 `branch` [ info 2 3 `leaf` "a", info 5 6 `leaf` "b" ])
(info 0 4 `branch` [ info 2 3 `leaf` "a" ]))
, Join (That (info 4 8 `branch` [ info 6 7 `leaf` "b" ]))
, Join (That (info 8 9 `branch` []))
]
it "aligns deletions before insertions" $
let sources = both (Source.fromText "[ a ]") (Source.fromText "[ b ]") in
align sources (pure (info 0 5) `branch` [ delete (info 2 3 `leaf` "a"), insert (info 2 3 `leaf` "b") ]) `shouldBe` prettyDiff sources
[ Join (This (info 0 5 `branch` [ delete (info 2 3 `leaf` "a") ]))
, Join (That (info 0 5 `branch` [ insert (info 2 3 `leaf` "b") ]))
]
it "aligns context-only lines symmetrically" $
let sources = both (Source.fromText "[\n a\n,\n b\n]") (Source.fromText "[\n a, b\n\n\n]") in
align sources (both (info 0 13) (info 0 12) `branch` [ pure (info 4 5) `leaf` "a", both (info 10 11) (info 7 8) `leaf` "b" ]) `shouldBe` prettyDiff sources
[ Join (These (info 0 2 `branch` [])
(info 0 2 `branch` []))
, Join (These (info 2 6 `branch` [ info 4 5 `leaf` "a" ])
(info 2 9 `branch` [ info 4 5 `leaf` "a", info 7 8 `leaf` "b" ]))
, Join (These (info 6 8 `branch` [])
(info 9 10 `branch` []))
, Join (This (info 8 12 `branch` [ info 10 11 `leaf` "b" ]))
, Join (These (info 12 13 `branch` [])
(info 10 11 `branch` []))
, Join (That (info 11 12 `branch` []))
]
it "aligns asymmetrical nodes preceding their symmetrical siblings conservatively" $
let sources = both (Source.fromText "[ b, c ]") (Source.fromText "[ a\n, c\n]") in
align sources (both (info 0 8) (info 0 9) `branch` [ insert (info 2 3 `leaf` "a"), delete (info 2 3 `leaf` "b"), both (info 5 6) (info 6 7) `leaf` "c" ]) `shouldBe` prettyDiff sources
[ Join (That (info 0 4 `branch` [ insert (info 2 3 `leaf` "a") ]))
, Join (These (info 0 8 `branch` [ delete (info 2 3 `leaf` "b"), info 5 6 `leaf` "c" ])
(info 4 8 `branch` [ info 6 7 `leaf` "c" ]))
, Join (That (info 8 9 `branch` []))
]
it "aligns symmetrical reformatted nodes" $
let sources = both (Source.fromText "a [ b ]\nc") (Source.fromText "a [\nb\n]\nc") in
align sources (pure (info 0 9) `branch` [ pure (info 0 1) `leaf` "a", pure (info 2 7) `branch` [ pure (info 4 5) `leaf` "b" ], pure (info 8 9) `leaf` "c" ]) `shouldBe` prettyDiff sources
[ Join (These (info 0 8 `branch` [ info 0 1 `leaf` "a", info 2 7 `branch` [ info 4 5 `leaf` "b" ] ])
(info 0 4 `branch` [ info 0 1 `leaf` "a", info 2 4 `branch` [] ]))
, Join (That (info 4 6 `branch` [ info 4 6 `branch` [ info 4 5 `leaf` "b" ] ]))
, Join (That (info 6 8 `branch` [ info 6 7 `branch` [] ]))
, Join (These (info 8 9 `branch` [ info 8 9 `leaf` "c" ])
(info 8 9 `branch` [ info 8 9 `leaf` "c" ]))
]
describe "numberedRows" $ do
prop "counts only non-empty values" $
\ xs -> counts (numberedRows (unListableF <$> xs :: [Join These Char])) `shouldBe` length . catMaybes <$> Join (unalign (runJoin . unListableF <$> xs))
data BranchElement
= Child Text (Join These Text)
| Margin (Join These Text)
deriving Show
branchElementKey :: BranchElement -> Maybe Text
branchElementKey (Child key _) = Just key
branchElementKey _ = Nothing
toAlignBranchInputs :: [BranchElement] -> (Both Source.Source, [Join These (Text, Range)], Both [Range])
toAlignBranchInputs elements = (sources, join . (`evalState` both 0 0) . traverse go $ elements, ranges)
where go :: BranchElement -> State (Both Int) [Join These (Text, Range)]
go child@(Child key _) = do
lines <- traverse (\ (Child _ contents) -> do
prev <- get
let next = (+) <$> prev <*> modifyJoin (fromThese 0 0) (Text.length <$> contents)
put next
pure $! modifyJoin (runBothWith bimap (const <$> (Range <$> prev <*> next))) contents) (alignBranchElement child)
pure $! fmap ((,) key) <$> lines
go (Margin contents) = do
prev <- get
put $ (+) <$> prev <*> modifyJoin (fromThese 0 0) (Text.length <$> contents)
pure []
alignBranchElement element = case element of
Child key contents -> Child key <$> joinCrosswalk lines contents
Margin contents -> Margin <$> joinCrosswalk lines contents
where lines = fmap Source.toText . Source.actualLines . Source.fromText
sources = foldMap Source.fromText <$> bothContents elements
ranges = fmap (filter (\ (Range start end) -> start /= end)) $ Source.actualLineRanges <$> (Source.totalRange <$> sources) <*> sources
bothContents = foldMap (modifyJoin (fromThese [] []) . fmap (:[]) . branchElementContents)
branchElementContents (Child _ contents) = contents
branchElementContents (Margin contents) = contents
keysOfAlignedChildren :: [Join These (Range, [(Text, Range)])] -> [Text]
keysOfAlignedChildren lines = lines >>= these identity identity (<>) . runJoin . fmap (fmap Prologue.fst . Prologue.snd)
joinCrosswalk :: Bicrosswalk p => Align f => (a -> f b) -> Join p a -> f (Join p b)
joinCrosswalk f = fmap Join . bicrosswalk f f . runJoin
instance Listable BranchElement where
tiers = oneof [ (\ key -> Child key `mapT` joinTheseOf (contents key)) `concatMapT` key
, Margin `mapT` joinTheseOf (Text.singleton `mapT` padding '-') ]
where key = Text.singleton `mapT` [['a'..'z'] <> ['A'..'Z'] <> ['0'..'9']]
contents key = (wrap key . Text.singleton) `mapT` padding '*'
wrap key contents = "(" <> key <> contents <> ")" :: Text
padding :: Char -> [Tier Char]
padding char = frequency [ (10, [[char]])
, (1, [['\n']]) ]
joinTheseOf g = oneof [ (Join . This) `mapT` g
, (Join . That) `mapT` g
, productWith ((Join .) . These) g g ]
frequency :: [(Int, [Tier a])] -> [Tier a]
frequency = concatT . foldr ((\/) . pure . uncurry replicate) []
oneof :: [[[a]]] -> [[a]]
oneof = frequency . fmap ((,) 1)
counts :: [Join These (Int, a)] -> Both Int
counts numbered = fromMaybe 0 . getLast . mconcat . fmap Last <$> Join (unalign (runJoin . fmap Prologue.fst <$> numbered))
align :: Both Source.Source -> ConstructibleFree (Syntax Text) (Patch (Term (Syntax Text) (Record '[Range]))) (Both (Record '[Range])) -> PrettyDiff (SplitDiff [] (Record '[Range]))
align sources = PrettyDiff sources . fmap (fmap (getRange &&& identity)) . alignDiff sources . deconstruct
info :: Int -> Int -> Record '[Range]
info start end = Range start end :. Nil
prettyDiff :: Both Source.Source -> [Join These (ConstructibleFree [] (SplitPatch (Term [] (Record '[Range]))) (Record '[Range]))] -> PrettyDiff (SplitDiff [] (Record '[Range]))
prettyDiff sources = PrettyDiff sources . fmap (fmap ((getRange &&& identity) . deconstruct))
data PrettyDiff a = PrettyDiff { unPrettySources :: Both Source.Source, unPrettyLines :: [Join These (Range, a)] }
deriving Eq
instance Show (PrettyDiff a) where
showsPrec _ (PrettyDiff sources lines) = (prettyPrinted ++) -- . (("\n" ++ show lines) ++)
where prettyPrinted = showLine (maximum (0 : (maximum . fmap length <$> shownLines))) <$> shownLines >>= ('\n':)
shownLines = catMaybes $ toBoth <$> lines
showLine n line = uncurry ((<>) . (++ " | ")) (fromThese (replicate n ' ') (replicate n ' ') (runJoin (pad n <$> line)))
showDiff (range, _) = filter (/= '\n') . Text.unpack . Source.toText . Source.slice range
pad n string = (<>) (take n string) (replicate (max 0 (n - length string)) ' ')
toBoth them = showDiff <$> them `applyThese` modifyJoin (uncurry These) sources
newtype ConstructibleFree f patch annotation = ConstructibleFree { deconstruct :: Free (CofreeF f annotation) patch }
class PatchConstructible p where
insert :: Term (Syntax Text) (Record '[Range]) -> p
delete :: Term (Syntax Text) (Record '[Range]) -> p
instance PatchConstructible (Patch (Term (Syntax Text) (Record '[Range]))) where
insert = Insert
delete = Delete
instance PatchConstructible (SplitPatch (Term (Syntax Text) (Record '[Range]))) where
insert = SplitInsert
delete = SplitDelete
instance PatchConstructible (SplitPatch (Term [] (Record '[Range]))) where
insert = SplitInsert . hoistCofree toList
delete = SplitDelete . hoistCofree toList
instance (Functor f, PatchConstructible patch) => PatchConstructible (ConstructibleFree f patch annotation) where
insert = ConstructibleFree . pure . insert
delete = ConstructibleFree . pure . delete
class SyntaxConstructible s where
leaf :: annotation -> Text -> s annotation
branch :: annotation -> [s annotation] -> s annotation
instance SyntaxConstructible (ConstructibleFree (Syntax Text) patch) where
leaf info = ConstructibleFree . free . Free . (info :<) . Leaf
branch info = ConstructibleFree . free . Free . (info :<) . Indexed . fmap deconstruct
instance SyntaxConstructible (ConstructibleFree [] patch) where
leaf info = ConstructibleFree . free . Free . (info :<) . const []
branch info = ConstructibleFree . free . Free . (info :<) . fmap deconstruct
instance SyntaxConstructible (Cofree (Syntax Text)) where
info `leaf` value = cofree $ info :< Leaf value
info `branch` children = cofree $ info :< Indexed children
instance SyntaxConstructible (Cofree []) where
info `leaf` _ = cofree $ info :< []
info `branch` children = cofree $ info :< children