cryptol-3.1.0: src/Cryptol/ModuleSystem/Renamer.hs
-- |
-- Module : Cryptol.ModuleSystem.Renamer
-- Copyright : (c) 2013-2016 Galois, Inc.
-- License : BSD3
-- Maintainer : cryptol@galois.com
-- Stability : provisional
-- Portability : portable
{-# Language RecordWildCards #-}
{-# Language FlexibleInstances #-}
{-# Language FlexibleContexts #-}
{-# Language BlockArguments #-}
{-# Language OverloadedStrings #-}
module Cryptol.ModuleSystem.Renamer (
NamingEnv(), shadowing
, BindsNames, InModule(..)
, shadowNames
, Rename(..), runRenamer, RenameM()
, RenamerError(..)
, RenamerWarning(..)
, renameVar
, renameType
, renameModule
, renameTopDecls
, RenamerInfo(..)
, NameType(..)
, RenamedModule(..)
) where
import Prelude ()
import Prelude.Compat
import Data.Either(partitionEithers)
import Data.Maybe(mapMaybe)
import Data.List(find,groupBy,sortBy)
import Data.Function(on)
import Data.Foldable(toList)
import Data.Map(Map)
import qualified Data.Map.Strict as Map
import qualified Data.Set as Set
import Data.Graph(SCC(..))
import Data.Graph.SCC(stronglyConnComp)
import MonadLib hiding (mapM, mapM_)
import Cryptol.ModuleSystem.Name
import Cryptol.ModuleSystem.Names
import Cryptol.ModuleSystem.NamingEnv
import Cryptol.ModuleSystem.Exports
import Cryptol.Parser.Position(Range)
import Cryptol.Parser.AST
import Cryptol.Parser.Selector(selName)
import Cryptol.Utils.Panic (panic)
import Cryptol.Utils.RecordMap
import Cryptol.Utils.Ident(allNamespaces,OrigName(..),modPathCommon,
undefinedModName)
import Cryptol.Utils.PP
import Cryptol.ModuleSystem.Interface
import Cryptol.ModuleSystem.Renamer.Error
import Cryptol.ModuleSystem.Binds
import Cryptol.ModuleSystem.Renamer.Monad
import Cryptol.ModuleSystem.Renamer.Imports
import Cryptol.ModuleSystem.Renamer.ImplicitImports
{-
The Renamer Algorithm
=====================
1. Add implicit imports for visible nested modules
2. Compute what each module defines (see "Cryptol.ModuleSystem.Binds")
- This assigns unique names to names introduces by various declarations
- Here we detect repeated top-level definitions in a module.
- Module instantiations also get a name, but are not yet resolved, so
we don't know what's defined by them.
- We do not generate unique names for functor parameters---those will
be matched textually to the arguments when applied.
- We *do* generate unique names for declarations in "signatures"
* those are only really needed when renaming the signature (step 4)
(e.g., to determine if a name refers to something declared in the
signature or something else).
* when validating a module against a signature the names of the declarations
are matched textually, *not* using the unique names
(e.g., `x` in a signature is matched with the thing named `x` in a module,
even though these two `x`s will have different unique `id`s)
3. Resolve imports and instantiations (see "Cryptol.ModuleSystem.Imports")
- Resolves names in submodule imports
- Resolves functor instantiations:
* generate new names for declarations in the functors.
* this includes any nested modules, and things nested within them.
- At this point we have enough information to know what's exported by
each module.
4. Do the renaming (this module)
- Using step 3 we compute the scoping environment for each module/signature
- We traverse all declarations and replace the parser names with the
corresponding names in scope:
* Here we detect ambiguity and undefined errors
* During this pass is also where we keep track of information of what
names are used by declarations:
- this is used to compute the dependencies between declarations
- which are in turn used to order the declarations in dependency order
* this is assumed by the TC
* here we also report errors about invalid recursive dependencies
* During this stage we also issue warning about unused type names
(and we should probably do unused value names too one day)
- During the rewriting we also do:
- rebalance expression trees using the operator fixities
- desugar record update notation
-}
-- | The result of renaming a module
data RenamedModule = RenamedModule
{ rmModule :: Module Name -- ^ The renamed module
, rmDefines :: NamingEnv -- ^ What this module defines
, rmImported :: IfaceDecls
-- ^ Imported declarations. This provides the types for external
-- names (used by the type-checker).
}
-- | Entry point. This is used for renaming a top-level module.
renameModule :: Module PName -> RenameM RenamedModule
renameModule m0 =
do -- Step 1: add implicit imports
let m = m0 { mDef =
case mDef m0 of
NormalModule ds ->
NormalModule (addImplicitNestedImports ds)
FunctorInstance f as i -> FunctorInstance f as i
InterfaceModule s -> InterfaceModule s
}
-- Step 2: compute what's defined
(defs,errs) <- liftSupply (modBuilder (topModuleDefs m))
mapM_ recordError errs
-- Step 3: resolve imports
extern <- getExternal
resolvedMods <- liftSupply (resolveImports extern defs)
let pathToName = Map.fromList [ (Nested (nameModPath x) (nameIdent x), x)
| ImpNested x <- Map.keys resolvedMods ]
let mname = ImpTop (thing (mName m))
setResolvedLocals resolvedMods $
setNestedModule pathToName
do (ifs,m1) <- collectIfaceDeps (renameModule' mname m)
env <- rmodDefines <$> lookupResolved mname
pure RenamedModule
{ rmModule = m1
, rmDefines = env
, rmImported = ifs
-- XXX: maybe we should keep the nested defines too?
}
{- | Entry point. Rename a list of top-level declarations.
This is used for declaration that don't live in a module
(e.g., define on the command line.)
We assume that these declarations do not contain any nested modules.
-}
renameTopDecls ::
ModName -> [TopDecl PName] -> RenameM (NamingEnv,[TopDecl Name])
renameTopDecls m ds0 =
do -- Step 1: add implicit imports
let ds = addImplicitNestedImports ds0
-- Step 2: compute what's defined
(defs,errs) <- liftSupply (modBuilder (topDeclsDefs (TopModule m) ds))
mapM_ recordError errs
-- Step 3: resolve imports
extern <- getExternal
resolvedMods <- liftSupply (resolveImports extern (TopMod m defs))
let pathToName = Map.fromList [ (Nested (nameModPath x) (nameIdent x), x)
| ImpNested x <- Map.keys resolvedMods ]
setResolvedLocals resolvedMods $
setNestedModule pathToName
do env <- rmodDefines <$> lookupResolved (ImpTop m)
-- we already checked for duplicates in Step 2
ds1 <- shadowNames' CheckNone env (renameTopDecls' ds)
-- record a use of top-level names to avoid
-- unused name warnings
let exports = exportedDecls ds1
mapM_ recordUse (exported NSType exports)
pure (env,ds1)
--------------------------------------------------------------------------------
-- Stuff below is related to Step 4 of the algorithm.
class Rename f where
rename :: f PName -> RenameM (f Name)
-- | This is used for both top-level and nested modules.
-- Returns:
--
-- * Things defined in the module
-- * Renamed module
renameModule' ::
ImpName Name {- ^ Resolved name for this module -} ->
ModuleG mname PName ->
RenameM (ModuleG mname Name)
renameModule' mname m =
setCurMod (impNameModPath mname)
do resolved <- lookupResolved mname
shadowNames' CheckNone (rmodImports resolved)
case mDef m of
NormalModule ds ->
do let env = rmodDefines resolved
(paramEnv,params) <-
shadowNames' CheckNone env
(doModParams (mModParams m))
-- we check that defined names and ones that came
-- from parameters do not clash, as this would be
-- very confusing.
shadowNames' CheckOverlap (env <> paramEnv) $
setModParams params
do ds1 <- renameTopDecls' ds
let exports = exportedDecls ds1
mapM_ recordUse (exported NSType exports)
inScope <- getNamingEnv
pure m { mDef = NormalModule ds1, mInScope = inScope }
-- The things defined by this module are the *results*
-- of the instantiation, so we should *not* add them
-- in scope when resolving.
FunctorInstance f as _ ->
do f' <- rnLocated rename f
as' <- rename as
checkFunctorArgs as'
let l = Just (srcRange f')
imap <- mkInstMap l mempty (thing f') mname
-- This inScope is incomplete; it only contains names from the
-- enclosing scope, but we also want the names in scope from the
-- functor, for ease of testing at the command line. We will fix
-- this up in doFunctorInst in the typechecker, because right now
-- we don't have access yet to the inScope of the functor.
inScope <- getNamingEnv
pure m { mDef = FunctorInstance f' as' imap, mInScope = inScope }
InterfaceModule s ->
shadowNames' CheckNone (rmodDefines resolved)
do d <- InterfaceModule <$> renameIfaceModule mname s
inScope <- getNamingEnv
pure m { mDef = d, mInScope = inScope }
checkFunctorArgs :: ModuleInstanceArgs Name -> RenameM ()
checkFunctorArgs args =
case args of
DefaultInstAnonArg {} ->
panic "checkFunctorArgs" ["Nested DefaultInstAnonArg"]
DefaultInstArg l -> checkArg l
NamedInstArgs as -> mapM_ checkNamedArg as
where
checkNamedArg (ModuleInstanceNamedArg _ l) = checkArg l
checkArg l =
case thing l of
ModuleArg m
| isFakeName m -> pure ()
| otherwise -> checkIsModule (srcRange l) m AModule
ParameterArg {} -> pure () -- we check these in the type checker
AddParams -> pure ()
mkInstMap :: Maybe Range -> Map Name Name -> ImpName Name -> ImpName Name ->
RenameM (Map Name Name)
mkInstMap checkFun acc0 ogname iname
| isFakeName ogname = pure Map.empty
| otherwise =
do case checkFun of
Nothing -> pure ()
Just r -> checkIsModule r ogname AFunctor
(onames,osubs) <- lookupDefinesAndSubs ogname
inames <- lookupDefines iname
let mp = zipByTextName onames inames
subs = [ (ImpNested k, ImpNested v)
| k <- Set.toList osubs, Just v <- [Map.lookup k mp]
]
foldM doSub (Map.union mp acc0) subs
where
doSub acc (k,v) = mkInstMap Nothing acc k v
-- | This is used to rename local declarations (e.g. `where`)
renameDecls :: [Decl PName] -> RenameM [Decl Name]
renameDecls ds =
do (ds1,deps) <- depGroup (traverse rename ds)
let toNode d = let x = NamedThing (declName d)
in ((d,x), x, map NamedThing
$ Set.toList
$ Map.findWithDefault Set.empty x deps)
ordered = toList (stronglyConnComp (map toNode ds1))
fromSCC x =
case x of
AcyclicSCC (d,_) -> pure [d]
CyclicSCC ds_xs ->
let (rds,xs) = unzip ds_xs
in case mapM validRecursiveD rds of
Nothing -> do recordError (InvalidDependency xs)
pure rds
Just bs ->
do checkSameModule xs
pure [DRec bs]
concat <$> mapM fromSCC ordered
-- | Rename declarations in a signature (i.e., type/prop synonyms)
renameSigDecls :: [SigDecl PName] -> RenameM [SigDecl Name]
renameSigDecls ds =
do (ds1,deps) <- depGroup (traverse rename ds)
let toNode d = let nm = case d of
SigTySyn ts _ -> thing (tsName ts)
SigPropSyn ps _ -> thing (psName ps)
x = NamedThing nm
in ((d,x), x, map NamedThing
$ Set.toList
$ Map.findWithDefault Set.empty x deps)
ordered = toList (stronglyConnComp (map toNode ds1))
fromSCC x =
case x of
AcyclicSCC (d,_) -> pure [d]
CyclicSCC ds_xs ->
do let (rds,xs) = unzip ds_xs
recordError (InvalidDependency xs)
pure rds
concat <$> mapM fromSCC ordered
validRecursiveD :: Decl name -> Maybe (Bind name)
validRecursiveD d =
case d of
DBind b -> Just b
DLocated d' _ -> validRecursiveD d'
_ -> Nothing
checkSameModule :: [DepName] -> RenameM ()
checkSameModule xs =
case ms of
a : as | let bad = [ fst b | b <- as, snd a /= snd b ]
, not (null bad) ->
recordError (InvalidDependency $ map NamedThing $ fst a : bad)
_ -> pure ()
where
ms = [ (x,ogModule og)
| NamedThing x <- xs, GlobalName _ og <- [ nameInfo x ]
]
{- NOTE: Dependencies on Top Level Constraints
===========================================
For the new module system, things using a parameter depend on the parameter
declaration (i.e., `import signature`), which depends on the signature,
so dependencies on constraints in there should be OK.
However, we'd like to have a mechanism for declaring top level constraints in
a functor, that can impose constraints across types from *different*
parameters. For the moment, we reuse `parameter type constraint C` for this.
Such constraints need to be:
1. After the signature import
2. After any type synonyms/newtypes using the parameters
3. Before any value or type declarations that need to use the parameters.
Note that type declarations used by a constraint cannot use the constraint,
so they need to be well formed without it.
For other types, we use the following rule to determine if they use a
constraint:
If:
1. We have a constraint and type declaration
2. They both mention the same type parameter
3. There is no explicit dependency of the constraint on the DECL
Then:
The type declaration depends on the constraint.
Example:
type T = 10 // Does not depend on anything so can go first
signature A where
type n : #
import signature A // Depends on A, so need to be after A
parameter type constraint n > T
// Depends on the import (for @n@) and T
type Q = [n-T] // Depends on the top-level constraint
-}
-- This assumes imports have already been processed
renameTopDecls' :: [TopDecl PName] -> RenameM [TopDecl Name]
renameTopDecls' ds =
do -- rename and compute what names we depend on
(ds1,deps) <- depGroup (traverse rename ds)
fromParams <- getNamesFromModParams
localParams <- getLocalModParamDeps
let rawDepsFor x = Map.findWithDefault Set.empty x deps
isTyParam x = nameNamespace x == NSType && x `Map.member` fromParams
(noNameDs,nameDs) = partitionEithers (map topDeclName ds1)
ctrs = [ nm | (_,nm@(ConstratintAt {}),_) <- nameDs ]
indirect = Map.fromList [ (y,x)
| (_,x,ys) <- nameDs, y <- ys ]
mkDepName x = case Map.lookup x fromParams of
Just dn -> dn
Nothing -> NamedThing x
depsFor x =
[ Map.findWithDefault (mkDepName y) (NamedThing y) indirect
| y <- Set.toList (Map.findWithDefault Set.empty x deps)
]
{- See [NOTE: Dependencies on Top Level Constraints] -}
addCtr nm ctr =
case nm of
NamedThing x
| nameNamespace x == NSType
, let ctrDeps = rawDepsFor ctr
tyDeps = rawDepsFor nm
, not (x `Set.member` ctrDeps)
, not (Set.null (Set.intersection
(Set.filter isTyParam ctrDeps)
(Set.filter isTyParam tyDeps)))
-> Just ctr
_ -> Nothing
addCtrs (d,x)
| usesCtrs d = ctrs
| otherwise = mapMaybe (addCtr x) ctrs
addModParams d =
case d of
DModule tl | NestedModule m <- tlValue tl
, FunctorInstance _ as _ <- mDef m ->
case as of
DefaultInstArg arg -> depsOfArg arg
NamedInstArgs args -> concatMap depsOfNamedArg args
DefaultInstAnonArg {} -> []
where depsOfNamedArg (ModuleInstanceNamedArg _ a) = depsOfArg a
depsOfArg a = case thing a of
AddParams -> []
ModuleArg {} -> []
ParameterArg p ->
case Map.lookup p localParams of
Just i -> [i]
Nothing -> []
_ -> []
toNode (d,x,_) = ((d,x),x, addCtrs (d,x) ++
addModParams d ++
depsFor x)
ordered = stronglyConnComp (map toNode nameDs)
fromSCC x =
case x of
AcyclicSCC (d,_) -> pure [d]
CyclicSCC ds_xs ->
let (rds,xs) = unzip ds_xs
in case mapM valid rds of
Nothing -> do recordError (InvalidDependency xs)
pure rds
Just bs ->
do checkSameModule xs
pure [Decl TopLevel
{ tlDoc = Nothing
, tlExport = Public
, tlValue = DRec bs
}]
where
valid d = case d of
Decl tl -> validRecursiveD (tlValue tl)
_ -> Nothing
rds <- mapM fromSCC ordered
pure (concat (noNameDs:rds))
where
-- This indicates if a declaration might depend on the constraints in scope.
-- Since uses of constraints are not implicitly named, value declarations
-- are assumed to potentially use the constraints.
-- XXX: This is inaccurate, and *I think* it amounts to checking that something
-- is in the value namespace. Perhaps the rule should be that a value
-- depends on a parameter constraint if it mentions at least one
-- type parameter somewhere.
-- XXX: Besides, types might need constraints for well-formedness...
-- This is just bogus
-- Although not that type/prop synonyms may be defined wherever as they
-- keep the validity constraints they need and emit them at the *use* sites.
usesCtrs td =
case td of
Decl tl -> isValDecl (tlValue tl)
DPrimType {} -> False
TDNewtype {} -> False
TDEnum {} -> False
DParamDecl {} -> False
DInterfaceConstraint {} -> False
DModule tl -> any usesCtrs (mDecls m)
where NestedModule m = tlValue tl
DImport {} -> False
DModParam {} -> False -- no definitions here
Include {} -> bad "Include"
isValDecl d =
case d of
DLocated d' _ -> isValDecl d'
DBind {} -> True
DRec {} -> True
DType {} -> False
DProp {} -> False
DSignature {} -> bad "DSignature"
DFixity {} -> bad "DFixity"
DPragma {} -> bad "DPragma"
DPatBind {} -> bad "DPatBind"
bad msg = panic "renameTopDecls'" [msg]
declName :: Decl Name -> Name
declName decl =
case decl of
DLocated d _ -> declName d
DBind b -> thing (bName b)
DType (TySyn x _ _ _) -> thing x
DProp (PropSyn x _ _ _) -> thing x
DSignature {} -> bad "DSignature"
DFixity {} -> bad "DFixity"
DPragma {} -> bad "DPragma"
DPatBind {} -> bad "DPatBind"
DRec {} -> bad "DRec"
where
bad x = panic "declName" [x]
topDeclName ::
TopDecl Name ->
Either (TopDecl Name) (TopDecl Name, DepName, [DepName])
topDeclName topDecl =
case topDecl of
Decl d -> hasName (declName (tlValue d))
DPrimType d -> hasName (thing (primTName (tlValue d)))
TDNewtype d -> hasName' (thing (nName (tlValue d)))
[ nConName (tlValue d) ]
TDEnum d -> hasName' (thing (eName (tlValue d)))
(map (thing . ecName . tlValue)
(eCons (tlValue d)))
DModule d -> hasName (thing (mName m))
where NestedModule m = tlValue d
DInterfaceConstraint _ ds -> special (ConstratintAt (srcRange ds))
DImport {} -> noName
DModParam m -> special (ModParamName (srcRange (mpSignature m))
(mpName m))
Include {} -> bad "Include"
DParamDecl {} -> bad "DParamDecl"
where
noName = Left topDecl
hasName n = hasName' n []
hasName' n ms = Right (topDecl, NamedThing n, map NamedThing ms)
special x = Right (topDecl, x, [])
bad x = panic "topDeclName" [x]
{- | Compute the names introduced by a module parameter.
This should be run in a context containing everything that's in scope
except for the module parameters. We don't need to compute a fixed point here
because the signatures (and hence module parameters) cannot contain signatures.
The resulting naming environment contains the new names introduced by this
parameter.
-}
doModParam ::
ModParam PName ->
RenameM (NamingEnv, RenModParam)
doModParam mp =
do let sigName = mpSignature mp
loc = srcRange sigName
withLoc loc
do me <- getCurMod
(sigName',isFake) <-
case thing sigName of
ImpTop t -> pure (ImpTop t, False)
-- XXX: should we record a dependency here?
-- Not sure what the dependencies are for..
ImpNested n ->
do mb <- resolveNameMaybe NameUse NSModule n
(nm,isFake) <- case mb of
Just rnm -> pure (rnm,False)
Nothing ->
do rnm <- reportUnboundName NSModule n
pure (rnm,True)
case modPathCommon me (nameModPath nm) of
Just (_,[],_) ->
recordError
(InvalidDependency [ModPath me, NamedThing nm])
_ -> pure ()
pure (ImpNested nm, isFake)
unless isFake
(checkIsModule (srcRange sigName) sigName' ASignature)
sigEnv <- if isFake then pure mempty else lookupDefines sigName'
{- XXX: It seems a bit odd to use "newModParam" for the names to
be used for the instantiated type synonyms,
but what other name could we use? -}
let newP x = do y <- lift (newModParam me (mpName mp) loc x)
sets_ (Map.insert y x)
pure y
(newEnv',nameMap) <- runStateT Map.empty (travNamingEnv newP sigEnv)
let paramName = mpAs mp
let newEnv = case paramName of
Nothing -> newEnv'
Just q -> qualify q newEnv'
pure ( newEnv
, RenModParam
{ renModParamName = mpName mp
, renModParamRange = loc
, renModParamSig = sigName'
, renModParamInstance = nameMap
}
)
{- | Process the parameters of a module.
Should be executed in a context where everything's already in the context,
except the module parameters.
-}
doModParams :: [ModParam PName] -> RenameM (NamingEnv, [RenModParam])
doModParams srcParams =
do (paramEnvs,params) <- unzip <$> mapM doModParam srcParams
let repeated = groupBy ((==) `on` renModParamName)
$ sortBy (compare `on` renModParamName) params
forM_ repeated \ps ->
case ps of
[] -> panic "doModParams" ["[]"]
[_] -> pure ()
(p : _) -> recordError (MultipleModParams (renModParamName p)
(map renModParamRange ps))
pure (mconcat paramEnvs,params)
--------------------------------------------------------------------------------
rnLocated :: (a -> RenameM b) -> Located a -> RenameM (Located b)
rnLocated f loc = withLoc loc $
do a' <- f (thing loc)
return loc { thing = a' }
instance Rename TopDecl where
rename td =
case td of
Decl d -> Decl <$> traverse rename d
DPrimType d -> DPrimType <$> traverse rename d
TDNewtype n -> TDNewtype <$> traverse rename n
TDEnum n -> TDEnum <$> traverse rename n
Include n -> return (Include n)
DModule m -> DModule <$> traverse rename m
DImport li -> DImport <$> renI li
DModParam mp -> DModParam <$> rename mp
DInterfaceConstraint d ds ->
depsOf (ConstratintAt (srcRange ds))
(DInterfaceConstraint d <$> rnLocated (mapM rename) ds)
DParamDecl {} -> panic "rename" ["DParamDecl"]
renI :: Located (ImportG (ImpName PName)) ->
RenameM (Located (ImportG (ImpName Name)))
renI li =
withLoc (srcRange li)
do m <- rename (iModule i)
unless (isFakeName m) (recordImport (srcRange li) m)
pure li { thing = i { iModule = m } }
where
i = thing li
instance Rename ModParam where
rename mp =
do x <- rnLocated rename (mpSignature mp)
depsOf (ModParamName (srcRange (mpSignature mp)) (mpName mp))
do ren <- renModParamInstance <$> getModParam (mpName mp)
{- Here we add 2 "uses" to all type-level names introduced,
so that we don't get unused warnings for type parameters.
-}
mapM_ recordUse [ s | t <- Map.keys ren, nameNamespace t == NSType
, s <- [t,t] ]
pure mp { mpSignature = x, mpRenaming = ren }
renameIfaceModule :: ImpName Name -> Signature PName -> RenameM (Signature Name)
renameIfaceModule nm sig =
do env <- rmodDefines <$> lookupResolved nm
let depName = case nm of
ImpNested n -> NamedThing n
ImpTop t -> ModPath (TopModule t)
shadowNames' CheckOverlap env $
depsOf depName
do imps <- traverse renI (sigImports sig)
tps <- traverse rename (sigTypeParams sig)
ds <- renameSigDecls (sigDecls sig)
cts <- traverse (rnLocated rename) (sigConstraints sig)
fun <- traverse rename (sigFunParams sig)
-- we record a use here to avoid getting a warning in interfaces
-- that declare only types, and so appear "unused".
forM_ tps \tp -> recordUse (thing (ptName tp))
forM_ ds \d -> recordUse $ case d of
SigTySyn ts _ -> thing (tsName ts)
SigPropSyn ps _ -> thing (psName ps)
pure Signature
{ sigImports = imps
, sigTypeParams = tps
, sigDecls = ds
, sigConstraints = cts
, sigFunParams = fun
}
instance Rename ImpName where
rename i =
case i of
ImpTop m -> pure (ImpTop m)
ImpNested m -> ImpNested <$> resolveName NameUse NSModule m
instance Rename ModuleInstanceArgs where
rename args =
case args of
DefaultInstArg a -> DefaultInstArg <$> rnLocated rename a
NamedInstArgs xs -> NamedInstArgs <$> traverse rename xs
DefaultInstAnonArg {} -> panic "rename" ["DefaultInstAnonArg"]
instance Rename ModuleInstanceNamedArg where
rename (ModuleInstanceNamedArg x m) =
ModuleInstanceNamedArg x <$> rnLocated rename m
instance Rename ModuleInstanceArg where
rename arg =
case arg of
ModuleArg m -> ModuleArg <$> rename m
ParameterArg a -> pure (ParameterArg a)
AddParams -> pure AddParams
instance Rename NestedModule where
rename (NestedModule m) =
do let lnm = mName m
nm = thing lnm
n <- resolveName NameBind NSModule nm
depsOf (NamedThing n)
do let m' = m { mName = ImpNested <$> mName m }
m1 <- renameModule' (ImpNested n) m'
pure (NestedModule m1 { mName = lnm { thing = n } })
instance Rename PrimType where
rename pt =
do x <- rnLocated (renameType NameBind) (primTName pt)
depsOf (NamedThing (thing x))
do let (as,ps) = primTCts pt
(_,cts) <- renameQual as ps $ \as' ps' -> pure (as',ps')
-- Record an additional use for each parameter since we checked
-- earlier that all the parameters are used exactly once in the
-- body of the signature. This prevents incorrect warnings
-- about unused names.
mapM_ (recordUse . tpName) (fst cts)
pure pt { primTCts = cts, primTName = x }
instance Rename ParameterType where
rename a =
do n' <- rnLocated (renameType NameBind) (ptName a)
return a { ptName = n' }
instance Rename ParameterFun where
rename a =
do n' <- rnLocated (renameVar NameBind) (pfName a)
depsOf (NamedThing (thing n'))
do sig' <- renameSchema (pfSchema a)
return a { pfName = n', pfSchema = snd sig' }
instance Rename SigDecl where
rename decl =
case decl of
SigTySyn ts mb -> SigTySyn <$> rename ts <*> pure mb
SigPropSyn ps mb -> SigPropSyn <$> rename ps <*> pure mb
instance Rename Decl where
rename d = case d of
DBind b -> DBind <$> rename b
DType syn -> DType <$> rename syn
DProp syn -> DProp <$> rename syn
DLocated d' r -> withLoc r
$ DLocated <$> rename d' <*> pure r
DFixity{} -> panic "rename" [ "DFixity" ]
DSignature {} -> panic "rename" [ "DSignature" ]
DPragma {} -> panic "rename" [ "DPragma" ]
DPatBind {} -> panic "rename" [ "DPatBind " ]
DRec {} -> panic "rename" [ "DRec" ]
instance Rename Newtype where
rename n =
shadowNames (nParams n) $
do nameT <- rnLocated (renameType NameBind) (nName n)
nameC <- renameCon NameBind (nConName n)
depsOf (NamedThing nameC) (addDep (thing nameT))
depsOf (NamedThing (thing nameT)) $
do ps' <- traverse rename (nParams n)
body' <- traverse (traverse rename) (nBody n)
return Newtype { nName = nameT
, nConName = nameC
, nParams = ps'
, nBody = body' }
instance Rename EnumDecl where
rename n =
shadowNames (eParams n) $
do nameT <- rnLocated (renameType NameBind) (eName n)
nameCs <- forM (eCons n) \tlEc ->
do let con = tlValue tlEc
nameC <- rnLocated (renameCon NameBind) (ecName con)
depsOf (NamedThing (thing nameC)) (addDep (thing nameT))
pure (nameC,tlEc)
depsOf (NamedThing (thing nameT)) $
do ps' <- traverse rename (eParams n)
cons <- forM nameCs \(c,tlEc) ->
do ts' <- traverse rename (ecFields (tlValue tlEc))
let con = EnumCon { ecName = c, ecFields = ts' }
pure tlEc { tlValue = con }
pure EnumDecl { eName = nameT
, eParams = ps'
, eCons = cons
}
-- | Try to resolve a name.
-- SPECIAL CASE: if we have a NameUse for NSValue, we also look in NSConstructor
resolveNameMaybe :: NameType -> Namespace -> PName -> RenameM (Maybe Name)
resolveNameMaybe nt expected qn =
do ro <- RenameM ask
let lkpIn here = Map.lookup qn (namespaceMap here (roNames ro))
use = case expected of
NSType -> recordUse
_ -> const (pure ())
checkCon = case (nt,expected) of
(NameUse, NSValue) -> lkpIn NSConstructor
_ -> Nothing
found = case (lkpIn expected, checkCon) of
(Just a, Just b) -> Just (a <> b)
(Nothing, y) -> y
(x, Nothing) -> x
case found of
Just xs ->
case xs of
One n ->
do case nt of
NameBind -> pure ()
NameUse -> addDep n
use n -- for warning
return (Just n)
Ambig symSet ->
do let syms = Set.toList symSet
mapM_ use syms -- mark as used to avoid unused warnings
n <- located qn
recordError (MultipleSyms n syms)
return (Just (head syms))
Nothing -> pure Nothing
reportUnboundName :: Namespace -> PName -> RenameM Name
reportUnboundName expected qn =
do ro <- RenameM ask
let lkpIn here = Map.lookup qn (namespaceMap here (roNames ro))
others = [ ns | ns <- allNamespaces
, ns /= expected
, Just _ <- [lkpIn ns] ]
nm <- located qn
case others of
-- name exists in a different namespace
actual : _ -> recordError (WrongNamespace expected actual nm)
-- the value is just missing
[] -> recordError (UnboundName expected nm)
mkFakeName expected qn
isFakeName :: ImpName Name -> Bool
isFakeName m =
case m of
ImpTop x -> x == undefinedModName
ImpNested x ->
case nameTopModuleMaybe x of
Just y -> y == undefinedModName
Nothing -> False
-- | Resolve a name, and report error on failure.
resolveName :: NameType -> Namespace -> PName -> RenameM Name
resolveName nt expected qn =
do mb <- resolveNameMaybe nt expected qn
case mb of
Just n -> pure n
Nothing -> reportUnboundName expected qn
renameVar :: NameType -> PName -> RenameM Name
renameVar nt = resolveName nt NSValue
renameCon :: NameType -> PName -> RenameM Name
renameCon nt = resolveName nt NSConstructor
renameType :: NameType -> PName -> RenameM Name
renameType nt = resolveName nt NSType
-- | Assuming an error has been recorded already, construct a fake name that's
-- not expected to make it out of the renamer.
mkFakeName :: Namespace -> PName -> RenameM Name
mkFakeName ns pn =
do ro <- RenameM ask
liftSupply (mkDeclared ns (TopModule undefinedModName)
SystemName (getIdent pn) Nothing (roLoc ro))
-- | Rename a schema, assuming that none of its type variables are already in
-- scope.
instance Rename Schema where
rename s = snd `fmap` renameSchema s
-- | Rename a schema, assuming that the type variables have already been brought
-- into scope.
renameSchema :: Schema PName -> RenameM (NamingEnv,Schema Name)
renameSchema (Forall ps p ty loc) =
renameQual ps p $ \ps' p' ->
do ty' <- rename ty
pure (Forall ps' p' ty' loc)
-- | Rename a qualified thing.
renameQual :: [TParam PName] -> [Prop PName] ->
([TParam Name] -> [Prop Name] -> RenameM a) ->
RenameM (NamingEnv, a)
renameQual as ps k =
do env <- liftSupply (defsOf as)
res <- shadowNames env $ do as' <- traverse rename as
ps' <- traverse rename ps
k as' ps'
pure (env,res)
instance Rename TParam where
rename TParam { .. } =
do n <- renameType NameBind tpName
return TParam { tpName = n, .. }
instance Rename Prop where
rename (CType t) = CType <$> rename t
instance Rename Type where
rename ty0 =
case ty0 of
TFun a b -> TFun <$> rename a <*> rename b
TSeq n a -> TSeq <$> rename n <*> rename a
TBit -> return TBit
TNum c -> return (TNum c)
TChar c -> return (TChar c)
TUser qn ps -> TUser <$> renameType NameUse qn <*> traverse rename ps
TTyApp fs -> TTyApp <$> traverse (traverse rename) fs
TRecord fs -> TRecord <$> traverse (traverse rename) fs
TTuple fs -> TTuple <$> traverse rename fs
TWild -> return TWild
TLocated t' r -> withLoc r (TLocated <$> rename t' <*> pure r)
TParens t' k -> (`TParens` k) <$> rename t'
TInfix a o _ b -> do o' <- renameTypeOp o
a' <- rename a
b' <- rename b
mkTInfix a' o' b'
mkTInfix ::
Type Name -> (Located Name, Fixity) -> Type Name -> RenameM (Type Name)
mkTInfix t@(TInfix x o1 f1 y) op@(o2,f2) z =
case compareFixity f1 f2 of
FCLeft -> return (TInfix t o2 f2 z)
FCRight -> do r <- mkTInfix y op z
return (TInfix x o1 f1 r)
FCError -> do recordError (FixityError o1 f1 o2 f2)
return (TInfix t o2 f2 z)
mkTInfix (TLocated t' _) op z =
mkTInfix t' op z
mkTInfix t (o,f) z =
return (TInfix t o f z)
-- | Rename a binding.
instance Rename Bind where
rename b =
do n' <- rnLocated (renameVar NameBind) (bName b)
depsOf (NamedThing (thing n'))
do mbSig <- traverse renameSchema (bSignature b)
shadowNames (fst `fmap` mbSig) $
do (patEnv,pats') <- renamePats (bParams b)
-- NOTE: renamePats will generate warnings,
-- so we don't need to trigger them again here.
e' <- shadowNames' CheckNone patEnv (rnLocated rename (bDef b))
return b { bName = n'
, bParams = pats'
, bDef = e'
, bSignature = snd `fmap` mbSig
, bPragmas = bPragmas b
}
instance Rename BindDef where
rename DPrim = return DPrim
rename (DForeign i) = DForeign <$> traverse rename i
rename (DImpl i) = DImpl <$> rename i
instance Rename BindImpl where
rename (DExpr e) = DExpr <$> rename e
rename (DPropGuards cases) = DPropGuards <$> traverse rename cases
instance Rename PropGuardCase where
rename g = PropGuardCase <$> traverse (rnLocated rename) (pgcProps g)
<*> rename (pgcExpr g)
instance Rename Pattern where
rename p = case p of
PVar lv -> PVar <$> rnLocated (renameVar NameBind) lv
PCon c ps -> PCon <$> rnLocated (renameCon NameUse) c
<*> traverse rename ps
PWild -> pure PWild
PTuple ps -> PTuple <$> traverse rename ps
PRecord nps -> PRecord <$> traverse (traverse rename) nps
PList elems -> PList <$> traverse rename elems
PTyped p' t -> PTyped <$> rename p' <*> rename t
PSplit l r -> PSplit <$> rename l <*> rename r
PLocated p' loc -> withLoc loc
$ PLocated <$> rename p' <*> pure loc
-- | Note that after this point the @->@ updates have an explicit function
-- and there are no more nested updates.
instance Rename UpdField where
rename (UpdField h ls e) =
-- The plan:
-- x = e ~~~> x = e
-- x -> e ~~~> x -> \x -> e
-- x.y = e ~~~> x -> { _ | y = e }
-- x.y -> e ~~~> x -> { _ | y -> e }
case ls of
l : more ->
case more of
[] -> case h of
UpdSet -> UpdField UpdSet [l] <$> rename e
UpdFun -> UpdField UpdFun [l] <$>
rename (EFun emptyFunDesc [PVar p] e)
where
p = UnQual . selName <$> last ls
_ -> UpdField UpdFun [l] <$> rename (EUpd Nothing [ UpdField h more e])
[] -> panic "rename@UpdField" [ "Empty label list." ]
instance Rename FunDesc where
rename (FunDesc nm offset) =
do nm' <- traverse (renameVar NameBind) nm
pure (FunDesc nm' offset)
instance Rename Expr where
rename expr = case expr of
EVar n -> EVar <$> renameVar NameUse n
ELit l -> return (ELit l)
EGenerate e -> EGenerate
<$> rename e
ETuple es -> ETuple <$> traverse rename es
ERecord fs -> ERecord <$> traverse (traverse rename) fs
ESel e' s -> ESel <$> rename e' <*> pure s
EUpd mb fs -> do checkLabels fs
EUpd <$> traverse rename mb <*> traverse rename fs
EList es -> EList <$> traverse rename es
EFromTo s n e t -> EFromTo <$> rename s
<*> traverse rename n
<*> rename e
<*> traverse rename t
EFromToBy isStrict s e b t ->
EFromToBy isStrict
<$> rename s
<*> rename e
<*> rename b
<*> traverse rename t
EFromToDownBy isStrict s e b t ->
EFromToDownBy isStrict
<$> rename s
<*> rename e
<*> rename b
<*> traverse rename t
EFromToLessThan s e t ->
EFromToLessThan <$> rename s
<*> rename e
<*> traverse rename t
EInfFrom a b -> EInfFrom<$> rename a <*> traverse rename b
EComp e' bs -> do arms' <- traverse renameArm bs
let (envs,bs') = unzip arms'
-- NOTE: renameArm will generate shadowing warnings; we only
-- need to check for repeated names across multiple arms
shadowNames' CheckOverlap envs (EComp <$> rename e' <*> pure bs')
EApp f x -> EApp <$> rename f <*> rename x
EAppT f ti -> EAppT <$> rename f <*> traverse rename ti
EIf b t f -> EIf <$> rename b <*> rename t <*> rename f
ECase e as -> ECase <$> rename e <*> traverse rename as
EWhere e' ds -> shadowNames (map (InModule Nothing) ds) $
EWhere <$> rename e' <*> renameDecls ds
ETyped e' ty -> ETyped <$> rename e' <*> rename ty
ETypeVal ty -> ETypeVal<$> rename ty
EFun desc ps e' -> do desc' <- rename desc
(env,ps') <- renamePats ps
-- NOTE: renamePats will generate warnings, so we don't
-- need to duplicate them here
shadowNames' CheckNone env (EFun desc' ps' <$> rename e')
ELocated e' r -> withLoc r
$ ELocated <$> rename e' <*> pure r
ESplit e -> ESplit <$> rename e
EParens p -> EParens <$> rename p
EInfix x y _ z -> do op <- renameOp y
x' <- rename x
z' <- rename z
mkEInfix x' op z'
EPrefix op e -> EPrefix op <$> rename e
checkLabels :: [UpdField PName] -> RenameM ()
checkLabels = foldM_ check [] . map labs
where
labs (UpdField _ ls _) = ls
check done l =
do case find (overlap l) done of
Just l' -> recordError (OverlappingRecordUpdate (reLoc l) (reLoc l'))
Nothing -> pure ()
pure (l : done)
overlap xs ys =
case (xs,ys) of
([],_) -> True
(_, []) -> True
(x : xs', y : ys') -> same x y && overlap xs' ys'
same x y =
case (thing x, thing y) of
(TupleSel a _, TupleSel b _) -> a == b
(ListSel a _, ListSel b _) -> a == b
(RecordSel a _, RecordSel b _) -> a == b
_ -> False
reLoc xs = (head xs) { thing = map thing xs }
mkEInfix :: Expr Name -- ^ May contain infix expressions
-> (Located Name,Fixity) -- ^ The operator to use
-> Expr Name -- ^ Will not contain infix expressions
-> RenameM (Expr Name)
mkEInfix e@(EInfix x o1 f1 y) op@(o2,f2) z =
case compareFixity f1 f2 of
FCLeft -> return (EInfix e o2 f2 z)
FCRight -> do r <- mkEInfix y op z
return (EInfix x o1 f1 r)
FCError -> do recordError (FixityError o1 f1 o2 f2)
return (EInfix e o2 f2 z)
mkEInfix e@(EPrefix o1 x) op@(o2, f2) y =
case compareFixity (prefixFixity o1) f2 of
FCRight -> do
let warning = PrefixAssocChanged o1 x o2 f2 y
RenameM $ sets_ (\rw -> rw {rwWarnings = warning : rwWarnings rw})
r <- mkEInfix x op y
return (EPrefix o1 r)
-- Even if the fixities conflict, we make the prefix operator take
-- precedence.
_ -> return (EInfix e o2 f2 y)
-- Note that for prefix operator on RHS of infix operator we make the prefix
-- operator always have precedence, so we allow a * -b instead of requiring
-- a * (-b).
mkEInfix (ELocated e' _) op z =
mkEInfix e' op z
mkEInfix e (o,f) z =
return (EInfix e o f z)
renameOp :: Located PName -> RenameM (Located Name, Fixity)
renameOp ln =
withLoc ln $
do n <- renameVar NameUse (thing ln)
fixity <- lookupFixity n
return (ln { thing = n }, fixity)
renameTypeOp :: Located PName -> RenameM (Located Name, Fixity)
renameTypeOp ln =
withLoc ln $
do n <- renameType NameUse (thing ln)
fixity <- lookupFixity n
return (ln { thing = n }, fixity)
lookupFixity :: Name -> RenameM Fixity
lookupFixity n =
case nameFixity n of
Just fixity -> return fixity
Nothing -> return defaultFixity -- FIXME: should we raise an error instead?
instance Rename TypeInst where
rename ti = case ti of
NamedInst nty -> NamedInst <$> traverse rename nty
PosInst ty -> PosInst <$> rename ty
renameArm :: [Match PName] -> RenameM (NamingEnv,[Match Name])
renameArm (m:ms) =
do (me,m') <- renameMatch m
-- NOTE: renameMatch will generate warnings, so we don't
-- need to duplicate them here
shadowNames' CheckNone me $
do (env,rest) <- renameArm ms
-- NOTE: the inner environment shadows the outer one, for examples
-- like this:
--
-- [ x | x <- xs, let x = 10 ]
return (env `shadowing` me, m':rest)
renameArm [] =
return (mempty,[])
-- | The name environment generated by a single match.
renameMatch :: Match PName -> RenameM (NamingEnv,Match Name)
renameMatch (Match p e) =
do (pe,p') <- renamePat p
e' <- rename e
return (pe,Match p' e')
renameMatch (MatchLet b) =
do be <- liftSupply (defsOf (InModule Nothing b))
b' <- shadowNames be (rename b)
return (be,MatchLet b')
-- | Rename patterns, and collect the new environment that they introduce.
renamePat :: Pattern PName -> RenameM (NamingEnv, Pattern Name)
renamePat p =
do pe <- patternEnv p
p' <- shadowNames pe (rename p)
return (pe, p')
-- | Rename patterns, and collect the new environment that they introduce.
renamePats :: [Pattern PName] -> RenameM (NamingEnv,[Pattern Name])
renamePats = loop
where
loop ps = case ps of
p:rest -> do
pe <- patternEnv p
shadowNames pe $
do p' <- rename p
(env',rest') <- loop rest
return (pe `mappend` env', p':rest')
[] -> return (mempty, [])
patternEnv :: Pattern PName -> RenameM NamingEnv
patternEnv = go
where
go (PVar Located { .. }) =
do n <- liftSupply (mkLocal NSValue (getIdent thing) srcRange)
-- XXX: for deps, we should record a use
return (singletonNS NSValue thing n)
go (PCon _ ps) = bindVars ps
go PWild = return mempty
go (PTuple ps) = bindVars ps
go (PRecord fs) = bindVars (fmap snd (recordElements fs))
go (PList ps) = foldMap go ps
go (PTyped p ty) = go p `mappend` typeEnv ty
go (PSplit a b) = go a `mappend` go b
go (PLocated p loc) = withLoc loc (go p)
bindVars [] = return mempty
bindVars (p:ps) =
do env <- go p
shadowNames env $
do rest <- bindVars ps
return (env `mappend` rest)
typeEnv (TFun a b) = bindTypes [a,b]
typeEnv (TSeq a b) = bindTypes [a,b]
typeEnv TBit = return mempty
typeEnv TNum{} = return mempty
typeEnv TChar{} = return mempty
typeEnv (TUser pn ps) =
do mb <- resolveNameMaybe NameUse NSType pn
case mb of
-- The type is already bound, don't introduce anything.
Just _ -> bindTypes ps
Nothing
-- The type isn't bound, and has no parameters, so it names a portion
-- of the type of the pattern.
| null ps ->
do loc <- curLoc
n <- liftSupply (mkLocal NSType (getIdent pn) loc)
return (singletonNS NSType pn n)
-- This references a type synonym that's not in scope. Record an
-- error and continue with a made up name.
| otherwise ->
do loc <- curLoc
recordError (UnboundName NSType (Located loc pn))
n <- liftSupply (mkLocal NSType (getIdent pn) loc)
return (singletonNS NSType pn n)
typeEnv (TRecord fs) = bindTypes (map snd (recordElements fs))
typeEnv (TTyApp fs) = bindTypes (map value fs)
typeEnv (TTuple ts) = bindTypes ts
typeEnv TWild = return mempty
typeEnv (TLocated ty loc) = withLoc loc (typeEnv ty)
typeEnv (TParens ty _) = typeEnv ty
typeEnv (TInfix a _ _ b) = bindTypes [a,b]
bindTypes [] = return mempty
bindTypes (t:ts) =
do env' <- typeEnv t
shadowNames env' $
do res <- bindTypes ts
return (env' `mappend` res)
instance Rename CaseAlt where
rename (CaseAlt p e) = shadowNames p (CaseAlt <$> rename p <*> rename e)
instance Rename Match where
rename m = case m of
Match p e -> Match <$> rename p <*> rename e
MatchLet b -> shadowNames (InModule Nothing b) (MatchLet <$> rename b)
instance Rename TySyn where
rename (TySyn n f ps ty) =
shadowNames ps
do n' <- rnLocated (renameType NameBind) n
depsOf (NamedThing (thing n')) $
TySyn n' <$> pure f <*> traverse rename ps <*> rename ty
instance Rename PropSyn where
rename (PropSyn n f ps cs) =
shadowNames ps
do n' <- rnLocated (renameType NameBind) n
PropSyn n' <$> pure f <*> traverse rename ps <*> traverse rename cs
--------------------------------------------------------------------------------
instance PP RenamedModule where
ppPrec _ rn = updPPCfg (\cfg -> cfg { ppcfgShowNameUniques = True }) doc
where
doc =
vcat [ "// --- Defines -----------------------------"
, pp (rmDefines rn)
, "// -- Module -------------------------------"
, pp (rmModule rn)
, "// -----------------------------------------"
]