ghcide-2.12.0.0: src/Development/IDE/Spans/AtPoint.hs
-- Copyright (c) 2019 The DAML Authors. All rights reserved.
-- SPDX-License-Identifier: Apache-2.0
{-# LANGUAGE CPP #-}
{-# LANGUAGE GADTs #-}
-- | Gives information about symbols at a given point in DAML files.
-- These are all pure functions that should execute quickly.
module Development.IDE.Spans.AtPoint (
atPoint
, gotoDefinition
, gotoTypeDefinition
, gotoImplementation
, documentHighlight
, pointCommand
, referencesAtPoint
, computeTypeReferences
, FOIReferences(..)
, defRowToSymbolInfo
, getNamesAtPoint
, toCurrentLocation
, rowToLoc
, nameToLocation
, LookupModule
) where
import GHC.Data.FastString (lengthFS)
import qualified GHC.Utils.Outputable as O
import Development.IDE.GHC.Error
import Development.IDE.GHC.Orphans ()
import Development.IDE.Types.Location
import Language.LSP.Protocol.Types hiding
(SemanticTokenAbsolute (..))
import Prelude hiding (mod)
-- compiler and infrastructure
import Development.IDE.Core.Compile (setNonHomeFCHook)
import Development.IDE.Core.PositionMapping
import Development.IDE.Core.RuleTypes
import Development.IDE.GHC.Compat
import qualified Development.IDE.GHC.Compat.Util as Util
import Development.IDE.GHC.Util (printOutputable)
import Development.IDE.Spans.Common
import Development.IDE.Types.Options
import Control.Applicative
import Control.Monad.Extra
import Control.Monad.IO.Class
import Control.Monad.Trans.Class
import Control.Monad.Trans.Maybe
import Data.Coerce (coerce)
import qualified Data.HashMap.Strict as HM
import qualified Data.Map.Strict as M
import Data.Maybe
import qualified Data.Text as T
import qualified Data.Array as A
import Data.Either
import Data.List.Extra (dropEnd1, nubOrd)
import Data.Either.Extra (eitherToMaybe)
import Data.List (isSuffixOf, sortOn)
import Data.Tree
import qualified Data.Tree as T
import Data.Version (showVersion)
import Development.IDE.Types.Shake (WithHieDb)
import GHC.Iface.Ext.Types (EvVarSource (..),
HieAST (..),
HieASTs (..),
HieArgs (..),
HieType (..), Identifier,
IdentifierDetails (..),
NodeInfo (..), Scope,
Span)
import GHC.Iface.Ext.Utils (EvidenceInfo (..),
RefMap, getEvidenceTree,
getScopeFromContext,
hieTypeToIface,
isEvidenceContext,
isEvidenceUse,
isOccurrence, nodeInfo,
recoverFullType,
selectSmallestContaining)
import HieDb hiding (pointCommand,
withHieDb)
import System.Directory (doesFileExist)
-- | Gives a Uri for the module, given the .hie file location and the the module info
-- The Bool denotes if it is a boot module
type LookupModule m = FilePath -> ModuleName -> Unit -> Bool -> MaybeT m Uri
-- | HieFileResult for files of interest, along with the position mappings
newtype FOIReferences = FOIReferences (HM.HashMap NormalizedFilePath (HieAstResult, PositionMapping))
computeTypeReferences :: Foldable f => f (HieAST Type) -> M.Map Name [Span]
computeTypeReferences = foldr (\ast m -> M.unionWith (++) (go ast) m) M.empty
where
go ast = M.unionsWith (++) (this : map go (nodeChildren ast))
where
this = M.fromListWith (++)
$ map (, [nodeSpan ast])
$ concatMap namesInType
$ mapMaybe (\x -> guard (not $ all isOccurrence $ identInfo x) *> identType x)
$ M.elems
$ nodeIdentifiers $ nodeInfo ast
-- | Given a file and position, return the names at a point, the references for
-- those names in the FOIs, and a list of file paths we already searched through
foiReferencesAtPoint
:: NormalizedFilePath
-> Position
-> FOIReferences
-> ([Name],[Location],[FilePath])
foiReferencesAtPoint file pos (FOIReferences asts) =
case HM.lookup file asts of
Nothing -> ([],[],[])
Just (HAR _ hf _ _ _,mapping) ->
let names = getNamesAtPoint hf pos mapping
adjustedLocs = HM.foldr go [] asts
go (HAR _ _ rf tr _, goMapping) xs = refs ++ typerefs ++ xs
where
refs = concatMap (mapMaybe (toCurrentLocation goMapping . realSrcSpanToLocation . fst))
(mapMaybe (\n -> M.lookup (Right n) rf) names)
typerefs = concatMap (mapMaybe (toCurrentLocation goMapping . realSrcSpanToLocation))
(mapMaybe (`M.lookup` tr) names)
in (names, adjustedLocs,map fromNormalizedFilePath $ HM.keys asts)
getNamesAtPoint :: HieASTs a -> Position -> PositionMapping -> [Name]
getNamesAtPoint hf pos mapping =
concat $ pointCommand hf posFile (rights . M.keys . getSourceNodeIds)
where
posFile = fromMaybe pos $ fromCurrentPosition mapping pos
toCurrentLocation :: PositionMapping -> Location -> Maybe Location
toCurrentLocation mapping (Location uri range) =
Location uri <$> toCurrentRange mapping range
referencesAtPoint
:: MonadIO m
=> WithHieDb
-> NormalizedFilePath -- ^ The file the cursor is in
-> Position -- ^ position in the file
-> FOIReferences -- ^ references data for FOIs
-> m [Location]
referencesAtPoint withHieDb nfp pos refs = do
-- The database doesn't have up2date references data for the FOIs so we must collect those
-- from the Shake graph.
let (names, foiRefs, exclude) = foiReferencesAtPoint nfp pos refs
nonFOIRefs <- forM names $ \name ->
case nameModule_maybe name of
Nothing -> pure []
Just mod -> do
-- Look for references (strictly in project files, not dependencies),
-- excluding the files in the FOIs (since those are in foiRefs)
rows <- liftIO $ withHieDb (\hieDb -> findReferences hieDb True (nameOccName name) (Just $ moduleName mod) (Just $ moduleUnit mod) exclude)
pure $ mapMaybe rowToLoc rows
typeRefs <- forM names $ \name ->
case nameModule_maybe name of
Just mod | isTcClsNameSpace (occNameSpace $ nameOccName name) -> do
refs' <- liftIO $ withHieDb (\hieDb -> findTypeRefs hieDb True (nameOccName name) (Just $ moduleName mod) (Just $ moduleUnit mod) exclude)
pure $ mapMaybe typeRowToLoc refs'
_ -> pure []
pure $ nubOrd $ foiRefs ++ concat nonFOIRefs ++ concat typeRefs
rowToLoc :: Res RefRow -> Maybe Location
rowToLoc (row:.info) = flip Location range <$> mfile
where
range = Range start end
start = Position (fromIntegral $ refSLine row - 1) (fromIntegral $ refSCol row -1)
end = Position (fromIntegral $ refELine row - 1) (fromIntegral $ refECol row -1)
mfile = case modInfoSrcFile info of
Just f -> Just $ toUri f
Nothing -> Nothing
typeRowToLoc :: Res TypeRef -> Maybe Location
typeRowToLoc (row:.info) = do
file <- modInfoSrcFile info
pure $ Location (toUri file) range
where
range = Range start end
start = Position (fromIntegral $ typeRefSLine row - 1) (fromIntegral $ typeRefSCol row -1)
end = Position (fromIntegral $ typeRefELine row - 1) (fromIntegral $ typeRefECol row -1)
documentHighlight
:: Monad m
=> HieASTs a
-> RefMap a
-> Position
-> MaybeT m [DocumentHighlight]
documentHighlight hf rf pos = pure highlights
where
-- We don't want to show document highlights for evidence variables, which are supposed to be invisible
notEvidence = not . any isEvidenceContext . identInfo
ns = concat $ pointCommand hf pos (rights . M.keys . M.filter notEvidence . getSourceNodeIds)
highlights = do
n <- ns
ref <- fromMaybe [] (M.lookup (Right n) rf)
maybeToList (makeHighlight n ref)
makeHighlight n (sp,dets)
| isTvNameSpace (nameNameSpace n) && isBadSpan n sp = Nothing
| otherwise = Just $ DocumentHighlight (realSrcSpanToRange sp) (Just $ highlightType $ identInfo dets)
highlightType s =
if any (isJust . getScopeFromContext) s
then DocumentHighlightKind_Write
else DocumentHighlightKind_Read
isBadSpan :: Name -> RealSrcSpan -> Bool
isBadSpan n sp = srcSpanStartLine sp /= srcSpanEndLine sp || (srcSpanEndCol sp - srcSpanStartCol sp > lengthFS (occNameFS $ nameOccName n))
-- | Locate the type definition of the name at a given position.
gotoTypeDefinition
:: MonadIO m
=> WithHieDb
-> LookupModule m
-> IdeOptions
-> HieAstResult
-> Position
-> MaybeT m [(Location, Identifier)]
gotoTypeDefinition withHieDb lookupModule ideOpts srcSpans pos
= lift $ typeLocationsAtPoint withHieDb lookupModule ideOpts pos srcSpans
-- | Locate the definition of the name at a given position.
gotoDefinition
:: MonadIO m
=> WithHieDb
-> LookupModule m
-> IdeOptions
-> M.Map ModuleName NormalizedFilePath
-> HieAstResult
-> Position
-> MaybeT m [(Location, Identifier)]
gotoDefinition withHieDb getHieFile ideOpts imports srcSpans pos
= lift $ locationsAtPoint withHieDb getHieFile ideOpts imports pos srcSpans
-- | Locate the implementation definition of the name at a given position.
-- Goto Implementation for an overloaded function.
gotoImplementation
:: MonadIO m
=> WithHieDb
-> LookupModule m
-> IdeOptions
-> HieAstResult
-> Position
-> MaybeT m [Location]
gotoImplementation withHieDb getHieFile ideOpts srcSpans pos
= lift $ instanceLocationsAtPoint withHieDb getHieFile ideOpts pos srcSpans
-- | Synopsis for the name at a given position.
atPoint
:: IdeOptions
-> HieAstResult
-> DocAndTyThingMap
-> HscEnv
-> Position
-> IO (Maybe (Maybe Range, [T.Text]))
atPoint IdeOptions{} (HAR _ (hf :: HieASTs a) rf _ (kind :: HieKind hietype)) (DKMap dm km _am) env pos =
listToMaybe <$> sequence (pointCommand hf pos hoverInfo)
where
-- Hover info for values/data
hoverInfo :: HieAST hietype -> IO (Maybe Range, [T.Text])
hoverInfo ast = do
prettyNames <- mapM prettyName names
pure (Just range, prettyNames ++ pTypes)
where
pTypes :: [T.Text]
pTypes
| Prelude.length names == 1 = dropEnd1 $ map wrapHaskell prettyTypes
| otherwise = map wrapHaskell prettyTypes
range :: Range
range = realSrcSpanToRange $ nodeSpan ast
wrapHaskell :: T.Text -> T.Text
wrapHaskell x = "\n```haskell\n"<>x<>"\n```\n"
info :: NodeInfo hietype
info = nodeInfoH kind ast
-- We want evidence variables to be displayed last.
-- Evidence trees contain information of secondary relevance.
names :: [(Identifier, IdentifierDetails hietype)]
names = sortOn (any isEvidenceUse . identInfo . snd) $ M.assocs $ nodeIdentifiers info
prettyName :: (Either ModuleName Name, IdentifierDetails hietype) -> IO T.Text
prettyName (Right n, dets)
-- We want to print evidence variable using a readable tree structure.
-- Evidence variables contain information why a particular instance or
-- type equality was chosen, paired with location information.
| any isEvidenceUse (identInfo dets) =
let
-- The evidence tree may not be present for some reason, e.g., the 'Name' is not
-- present in the tree.
-- Thus, we need to handle it here, but in practice, this should never be 'Nothing'.
evidenceTree = maybe "" (printOutputable . renderEvidenceTree) (getEvidenceTree rf n)
in
pure $ evidenceTree <> "\n"
-- Identifier details that are not evidence variables are used to display type information and
-- documentation of that name.
| otherwise =
let
typeSig = wrapHaskell (printOutputable n <> maybe "" (" :: " <>) ((prettyType <$> identType dets) <|> maybeKind))
definitionLoc = maybeToList (pretty (definedAt n) (prettyPackageName n))
docs = maybeToList (T.unlines . spanDocToMarkdown <$> lookupNameEnv dm n)
in
pure $ T.unlines $
[typeSig] ++ definitionLoc ++ docs
where maybeKind = fmap printOutputable $ safeTyThingType =<< lookupNameEnv km n
pretty Nothing Nothing = Nothing
pretty (Just define) Nothing = Just $ define <> "\n"
pretty Nothing (Just pkgName) = Just $ pkgName <> "\n"
pretty (Just define) (Just pkgName) = Just $ define <> " " <> pkgName <> "\n"
prettyName (Left m,_) = packageNameForImportStatement m
prettyPackageName :: Name -> Maybe T.Text
prettyPackageName n = do
m <- nameModule_maybe n
pkgTxt <- packageNameWithVersion m
pure $ "*(" <> pkgTxt <> ")*"
-- Return the module text itself and
-- the package(with version) this `ModuleName` belongs to.
packageNameForImportStatement :: ModuleName -> IO T.Text
packageNameForImportStatement mod = do
mpkg <- findImportedModule (setNonHomeFCHook env) mod :: IO (Maybe Module)
let moduleName = printOutputable mod
case mpkg >>= packageNameWithVersion of
Nothing -> pure moduleName
Just pkgWithVersion -> pure $ moduleName <> "\n\n" <> pkgWithVersion
-- Return the package name and version of a module.
-- For example, given module `Data.List`, it should return something like `base-4.x`.
packageNameWithVersion :: Module -> Maybe T.Text
packageNameWithVersion m = do
let pid = moduleUnit m
conf <- lookupUnit env pid
let pkgName = T.pack $ unitPackageNameString conf
version = T.pack $ showVersion (unitPackageVersion conf)
pure $ pkgName <> "-" <> version
-- Type info for the current node, it may contain several symbols
-- for one range, like wildcard
types :: [hietype]
types = nodeType info
prettyTypes :: [T.Text]
prettyTypes = map (("_ :: "<>) . prettyType) types
prettyType :: hietype -> T.Text
prettyType = printOutputable . expandType
expandType :: a -> SDoc
expandType t = case kind of
HieFresh -> ppr t
HieFromDisk full_file -> ppr $ hieTypeToIface $ recoverFullType t (hie_types full_file)
definedAt :: Name -> Maybe T.Text
definedAt name =
-- do not show "at <no location info>" and similar messages
-- see the code of 'pprNameDefnLoc' for more information
case nameSrcLoc name of
UnhelpfulLoc {} | isInternalName name || isSystemName name -> Nothing
_ -> Just $ "*Defined " <> printOutputable (pprNameDefnLoc name) <> "*"
-- We want to render the root constraint even if it is a let,
-- but we don't want to render any subsequent lets
renderEvidenceTree :: Tree (EvidenceInfo a) -> SDoc
-- However, if the root constraint is simply a<n indirection (via let) to a single other constraint,
-- we can still skip rendering it
-- The evidence ghc generates is made up of a few primitives, like @WpLet@ (let bindings),
-- @WpEvLam@ (lambda abstractions) and so on.
-- The let binding refers to these lets.
--
-- For example, evidence for @Show ([Int], Bool)@ might look like:
--
-- @
-- $dShow,[]IntBool = $fShow,[]IntBool
-- -- indirection, we don't gain anything by printing this
-- $fShow,[]IntBool = $dShow, $fShow[]Int $fShowBool
-- -- This is the root "let" we render as a tree
-- $fShow[]Int = $dShow[] $fShowInt
-- -- second level let, collapse it into its parent $fShow,[]IntBool
-- $fShowInt = base:Data.Int.$dShowInt
-- -- indirection, remove it
-- $fShowBool = base:Data.Bool.$dShowBool
-- -- indirection, remove it
--
-- in $dShow,[]IntBool
-- @
--
-- On doing this we end up with the tree @Show ([Int], Bool) -> (Show (,), Show [], Show Int, Show Bool)@
--
-- It is also quite helpful to look at the @.hie@ file directly to see how the
-- evidence information is presented on disk. @hiedb dump <mod.hie>@
renderEvidenceTree (T.Node (EvidenceInfo{evidenceDetails=Just (EvLetBind _,_,_)}) [x])
= renderEvidenceTree x
renderEvidenceTree (T.Node (EvidenceInfo{evidenceDetails=Just (EvLetBind _,_,_), ..}) xs)
= hang (text "Evidence of constraint `" O.<> expandType evidenceType O.<> "`") 2 $
vcat $ text "constructed using:" : map renderEvidenceTree' xs
renderEvidenceTree (T.Node (EvidenceInfo{..}) _)
= hang (text "Evidence of constraint `" O.<> expandType evidenceType O.<> "`") 2 $
vcat $ printDets evidenceSpan evidenceDetails : map (text . T.unpack) (maybeToList $ definedAt evidenceVar)
-- renderEvidenceTree' skips let bound evidence variables and prints the children directly
renderEvidenceTree' (T.Node (EvidenceInfo{evidenceDetails=Just (EvLetBind _,_,_)}) xs)
= vcat (map renderEvidenceTree' xs)
renderEvidenceTree' (T.Node (EvidenceInfo{..}) _)
= hang (text "- `" O.<> expandType evidenceType O.<> "`") 2 $
vcat $
printDets evidenceSpan evidenceDetails : map (text . T.unpack) (maybeToList $ definedAt evidenceVar)
printDets :: RealSrcSpan -> Maybe (EvVarSource, Scope, Maybe Span) -> SDoc
printDets _ Nothing = text "using an external instance"
printDets ospn (Just (src,_,mspn)) = pprSrc
$$ text "at" <+> text (T.unpack $ srcSpanToMdLink location)
where
location = realSrcSpanToLocation spn
-- Use the bind span if we have one, else use the occurrence span
spn = fromMaybe ospn mspn
pprSrc = case src of
-- Users don't know what HsWrappers are
EvWrapperBind -> "bound by type signature or pattern"
_ -> ppr src
-- | Find 'Location's of type definition at a specific point and return them along with their 'Identifier's.
typeLocationsAtPoint
:: forall m
. MonadIO m
=> WithHieDb
-> LookupModule m
-> IdeOptions
-> Position
-> HieAstResult
-> m [(Location, Identifier)]
typeLocationsAtPoint withHieDb lookupModule _ideOptions pos (HAR _ ast _ _ hieKind) =
case hieKind of
HieFromDisk hf ->
let arr = hie_types hf
ts = concat $ pointCommand ast pos getts
unfold = map (arr A.!)
getts x = nodeType ni ++ mapMaybe identType (M.elems $ nodeIdentifiers ni)
where ni = nodeInfo' x
getTypes' ts' = flip concatMap (unfold ts') $ \case
HTyVarTy n -> [n]
HAppTy a (HieArgs xs) -> getTypes' (a : map snd xs)
HTyConApp tc (HieArgs xs) -> ifaceTyConName tc : getTypes' (map snd xs)
HForAllTy _ a -> getTypes' [a]
HFunTy a b c -> getTypes' [a,b,c]
HQualTy a b -> getTypes' [a,b]
HCastTy a -> getTypes' [a]
_ -> []
in fmap nubOrd $ concatMapM (\n -> fmap (maybe [] (fmap (,Right n))) (nameToLocation withHieDb lookupModule n)) (getTypes' ts)
HieFresh ->
let ts = concat $ pointCommand ast pos getts
getts x = nodeType ni ++ mapMaybe identType (M.elems $ nodeIdentifiers ni)
where ni = nodeInfo x
in fmap nubOrd $ concatMapM (\n -> fmap (maybe [] (fmap (,Right n))) (nameToLocation withHieDb lookupModule n)) (getTypes ts)
namesInType :: Type -> [Name]
namesInType (TyVarTy n) = [varName n]
namesInType (AppTy a b) = getTypes [a,b]
namesInType (TyConApp tc ts) = tyConName tc : getTypes ts
namesInType (ForAllTy b t) = varName (binderVar b) : namesInType t
namesInType (FunTy _ a b) = getTypes [a,b]
namesInType (CastTy t _) = namesInType t
namesInType (LitTy _) = []
namesInType _ = []
getTypes :: [Type] -> [Name]
getTypes = concatMap namesInType
-- | Find 'Location's of definition at a specific point and return them along with their 'Identifier's.
locationsAtPoint
:: forall m
. MonadIO m
=> WithHieDb
-> LookupModule m
-> IdeOptions
-> M.Map ModuleName NormalizedFilePath
-> Position
-> HieAstResult
-> m [(Location, Identifier)]
locationsAtPoint withHieDb lookupModule _ideOptions imports pos (HAR _ ast _rm _ _) =
let ns = concat $ pointCommand ast pos (M.keys . getNodeIds)
zeroPos = Position 0 0
zeroRange = Range zeroPos zeroPos
modToLocation m = fmap (\fs -> pure (Location (fromNormalizedUri $ filePathToUri' fs) zeroRange)) $ M.lookup m imports
in fmap (nubOrd . concat) $ mapMaybeM
(either (\m -> pure ((fmap $ fmap (,Left m)) (modToLocation m)))
(\n -> fmap (fmap $ fmap (,Right n)) (nameToLocation withHieDb lookupModule n)))
ns
-- | Find 'Location's of a implementation definition at a specific point.
instanceLocationsAtPoint
:: forall m
. MonadIO m
=> WithHieDb
-> LookupModule m
-> IdeOptions
-> Position
-> HieAstResult
-> m [Location]
instanceLocationsAtPoint withHieDb lookupModule _ideOptions pos (HAR _ ast _rm _ _) =
let ns = concat $ pointCommand ast pos (M.keys . getNodeIds)
evTrees = mapMaybe (eitherToMaybe >=> getEvidenceTree _rm) ns
evNs = concatMap (map evidenceVar . T.flatten) evTrees
in fmap (nubOrd . concat) $ mapMaybeM
(nameToLocation withHieDb lookupModule)
evNs
-- | Given a 'Name' attempt to find the location where it is defined.
nameToLocation :: MonadIO m => WithHieDb -> LookupModule m -> Name -> m (Maybe [Location])
nameToLocation withHieDb lookupModule name = runMaybeT $
case nameSrcSpan name of
sp@(RealSrcSpan rsp _)
-- Lookup in the db if we got a location in a boot file
| fs <- Util.unpackFS (srcSpanFile rsp)
, not $ "boot" `isSuffixOf` fs
-> do
itExists <- liftIO $ doesFileExist fs
if itExists
then MaybeT $ pure $ fmap pure $ srcSpanToLocation sp
-- When reusing .hie files from a cloud cache,
-- the paths may not match the local file system.
-- Let's fall back to the hiedb in case it contains local paths
else fallbackToDb sp
sp -> fallbackToDb sp
where
fallbackToDb sp = do
guard (sp /= wiredInSrcSpan)
-- This case usually arises when the definition is in an external package.
-- In this case the interface files contain garbage source spans
-- so we instead read the .hie files to get useful source spans.
mod <- MaybeT $ return $ nameModule_maybe name
erow <- liftIO $ withHieDb (\hieDb -> findDef hieDb (nameOccName name) (Just $ moduleName mod) (Just $ moduleUnit mod))
case erow of
[] -> do
-- If the lookup failed, try again without specifying a unit-id.
-- This is a hack to make find definition work better with ghcide's nascent multi-component support,
-- where names from a component that has been indexed in a previous session but not loaded in this
-- session may end up with different unit ids
erow' <- liftIO $ withHieDb (\hieDb -> findDef hieDb (nameOccName name) (Just $ moduleName mod) Nothing)
case erow' of
[] -> MaybeT $ pure Nothing
xs -> lift $ mapMaybeM (runMaybeT . defRowToLocation lookupModule) xs
xs -> lift $ mapMaybeM (runMaybeT . defRowToLocation lookupModule) xs
defRowToLocation :: Monad m => LookupModule m -> Res DefRow -> MaybeT m Location
defRowToLocation lookupModule (row:.info) = do
let start = Position (fromIntegral $ defSLine row - 1) (fromIntegral $ defSCol row - 1)
end = Position (fromIntegral $ defELine row - 1) (fromIntegral $ defECol row - 1)
range = Range start end
file <- case modInfoSrcFile info of
Just src -> pure $ toUri src
Nothing -> lookupModule (defSrc row) (modInfoName info) (modInfoUnit info) (modInfoIsBoot info)
pure $ Location file range
toUri :: FilePath -> Uri
toUri = fromNormalizedUri . filePathToUri' . toNormalizedFilePath'
defRowToSymbolInfo :: Res DefRow -> Maybe SymbolInformation
defRowToSymbolInfo (DefRow{..}:.(modInfoSrcFile -> Just srcFile))
= Just $ SymbolInformation (printOutputable defNameOcc) kind Nothing Nothing Nothing loc
where
kind
| isVarOcc defNameOcc = SymbolKind_Variable
| isDataOcc defNameOcc = SymbolKind_Constructor
| isTcOcc defNameOcc = SymbolKind_Struct
-- This used to be (SkUnknown 1), buth there is no SymbolKind_Unknown.
-- Changing this to File, as that is enum representation of 1
| otherwise = SymbolKind_File
loc = Location file range
file = fromNormalizedUri . filePathToUri' . toNormalizedFilePath' $ srcFile
range = Range start end
start = Position (fromIntegral $ defSLine - 1) (fromIntegral $ defSCol - 1)
end = Position (fromIntegral $ defELine - 1) (fromIntegral $ defECol - 1)
defRowToSymbolInfo _ = Nothing
pointCommand :: HieASTs t -> Position -> (HieAST t -> a) -> [a]
pointCommand hf pos k =
M.elems $ flip M.mapMaybeWithKey (getAsts hf) $ \fs ast ->
-- Since GHC 9.2:
-- getAsts :: Map HiePath (HieAst a)
-- type HiePath = LexicalFastString
--
-- but before:
-- getAsts :: Map HiePath (HieAst a)
-- type HiePath = FastString
--
-- 'coerce' here to avoid an additional function for maintaining
-- backwards compatibility.
case selectSmallestContaining (sp $ coerce fs) ast of
Nothing -> Nothing
Just ast' -> Just $ k ast'
where
sloc fs = mkRealSrcLoc fs (fromIntegral $ line+1) (fromIntegral $ cha+1)
sp fs = mkRealSrcSpan (sloc fs) (sloc fs)
line :: UInt
line = _line pos
cha = _character pos
-- In ghc9, nodeInfo is monomorphic, so we need a case split here
nodeInfoH :: HieKind a -> HieAST a -> NodeInfo a
nodeInfoH (HieFromDisk _) = nodeInfo'
nodeInfoH HieFresh = nodeInfo