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mirror of https://github.com/anoma/juvix.git synced 2024-12-15 01:52:11 +03:00

[abstract] Add InfoTableBuilder for scoped to abstract

This commit is contained in:
Paul Cadman 2022-03-29 11:48:29 +01:00
parent 9e8a64fd7c
commit 9fea7b1ba0
4 changed files with 96 additions and 21 deletions

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@ -9,7 +9,8 @@ newtype FunctionInfo = FunctionInfo {
_functionInfoDef :: FunctionDef
}
newtype ConstructorInfo = ConstructorInfo {
data ConstructorInfo = ConstructorInfo {
_constructorInfoInductive :: InductiveInfo,
_constructorInfoType :: Expression
}

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@ -0,0 +1,62 @@
-- |
module MiniJuvix.Syntax.Abstract.InfoTableBuilder
( module MiniJuvix.Syntax.Abstract.InfoTableBuilder,
module MiniJuvix.Syntax.Abstract.InfoTable)
where
import qualified Data.HashMap.Strict as HashMap
import MiniJuvix.Syntax.Abstract.InfoTable
import MiniJuvix.Prelude
import MiniJuvix.Syntax.Abstract.Language
import MiniJuvix.Syntax.Concrete.Scoped.Name (unqualifiedSymbol)
data InfoTableBuilder m a where
RegisterAxiom :: AxiomDef -> InfoTableBuilder m ()
RegisterConstructor :: InductiveInfo -> InductiveConstructorDef -> InfoTableBuilder m ()
RegisterInductive :: InductiveDef -> InfoTableBuilder m InductiveInfo
RegisterFunction :: FunctionDef -> InfoTableBuilder m ()
makeSem ''InfoTableBuilder
registerFunction' ::
Member InfoTableBuilder r =>
FunctionDef -> Sem r FunctionDef
registerFunction' ts = registerFunction ts $> ts
registerAxiom' :: Member InfoTableBuilder r =>
AxiomDef -> Sem r AxiomDef
registerAxiom' a = registerAxiom a $> a
toState :: Sem (InfoTableBuilder ': r) a -> Sem (State InfoTable ': r) a
toState = reinterpret $ \case
RegisterAxiom d ->
let ref = AxiomRef (unqualifiedSymbol (d ^. axiomName))
info = AxiomInfo {
_axiomInfoType = d ^. axiomType,
_axiomInfoBackends = d ^. axiomBackendItems
}
in modify (over infoAxioms (HashMap.insert ref info))
RegisterConstructor _constructorInfoInductive def -> let
ref = ConstructorRef (unqualifiedSymbol (def ^. constructorName))
info = ConstructorInfo {
_constructorInfoType = def ^. constructorType,
..
}
in modify (over infoConstructors (HashMap.insert ref info))
RegisterInductive ity -> let
ref = InductiveRef (unqualifiedSymbol (ity ^. inductiveName))
info = InductiveInfo {
_inductiveInfoDef = ity
}
in modify (over infoInductives (HashMap.insert ref info)) $> info
RegisterFunction _functionInfoDef -> let
ref = FunctionRef (unqualifiedSymbol (_functionInfoDef ^. funDefName))
info = FunctionInfo {
..
}
in modify (over infoFunctions (HashMap.insert ref info))
runInfoTableBuilder :: Sem (InfoTableBuilder ': r) a -> Sem r (InfoTable, a)
runInfoTableBuilder = runState emptyInfoTable . toState

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@ -203,6 +203,7 @@ makeLenses ''FunctionRef
makeLenses ''ConstructorRef
makeLenses ''InductiveRef
makeLenses ''AxiomRef
makeLenses ''AxiomDef
idenName :: Iden -> Name
idenName = \case

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@ -6,27 +6,29 @@ import qualified MiniJuvix.Syntax.Abstract.Language as A
import MiniJuvix.Syntax.Concrete.Language
import qualified MiniJuvix.Syntax.Concrete.Language as C
import qualified MiniJuvix.Syntax.Concrete.Scoped.Name as S
import MiniJuvix.Syntax.Abstract.InfoTableBuilder
import MiniJuvix.Syntax.Abstract.Language (FunctionDef(_funDefTypeSig))
type Err = Text
unsupported :: Members '[Error Err] r => Err -> Sem r a
unsupported msg = throw $ msg <> " not yet supported"
translateModule :: Module 'Scoped 'ModuleTop -> Either Err A.TopModule
translateModule = run . runError . goTopModule
translateModule :: Module 'Scoped 'ModuleTop -> Either Err (InfoTable, A.TopModule)
translateModule = run . runError . runInfoTableBuilder . goTopModule
goTopModule :: Members '[Error Err] r => Module 'Scoped 'ModuleTop -> Sem r A.TopModule
goTopModule :: Members '[Error Err, InfoTableBuilder] r => Module 'Scoped 'ModuleTop -> Sem r A.TopModule
goTopModule = goModule
goLocalModule :: Members '[Error Err] r => Module 'Scoped 'ModuleLocal -> Sem r A.LocalModule
goLocalModule :: Members '[Error Err, InfoTableBuilder] r => Module 'Scoped 'ModuleLocal -> Sem r A.LocalModule
goLocalModule = goModule
goModule :: (Members '[Error Err] r, ModulePathType 'Scoped t ~ S.Name' c) => Module 'Scoped t -> Sem r (A.Module c)
goModule :: (Members '[Error Err, InfoTableBuilder] r, ModulePathType 'Scoped t ~ S.Name' c) => Module 'Scoped t -> Sem r (A.Module c)
goModule (Module n par b) = case par of
[] -> A.Module n <$> goModuleBody b
_ -> unsupported "Module parameters"
goModuleBody :: forall r. Members '[Error Err] r => [Statement 'Scoped] -> Sem r A.ModuleBody
goModuleBody :: forall r. Members '[Error Err, InfoTableBuilder] r => [Statement 'Scoped] -> Sem r A.ModuleBody
goModuleBody ss' = do
_moduleInductives <- inductives
_moduleLocalModules <- locals
@ -70,8 +72,7 @@ goModuleBody ss' = do
[ (name, Indexed i <$> funDef)
| Indexed i sig <- sigs,
let name = sig ^. sigName,
let clauses = mapM goFunctionClause (getClauses name),
let funDef = liftA2 (A.FunctionDef name) (goExpression (sig ^. sigType)) clauses
let funDef = goFunctionDef sig (getClauses name)
]
where
getClauses :: S.Symbol -> NonEmpty (FunctionClause 'Scoped)
@ -83,6 +84,13 @@ goModuleBody ss' = do
sigs :: [Indexed (TypeSignature 'Scoped)]
sigs = [Indexed i t | (Indexed i (StatementTypeSignature t)) <- ss]
goFunctionDef :: forall r. Members '[Error Err, InfoTableBuilder] r => TypeSignature 'Scoped -> NonEmpty (FunctionClause 'Scoped) -> Sem r A.FunctionDef
goFunctionDef sig clauses = do
let _funDefName = sig ^. sigName
_funDefClauses <- mapM goFunctionClause clauses
_funDefTypeSig <- goExpression (sig ^. sigType)
registerFunction' A.FunctionDef {..}
goFunctionClause :: forall r. Members '[Error Err] r => FunctionClause 'Scoped -> Sem r A.FunctionClause
goFunctionClause FunctionClause {..} = do
_clausePatterns' <- mapM goPattern _clausePatterns
@ -109,19 +117,22 @@ goInductiveParameter InductiveParameter {..} = do
_paramUsage = UsageOmega
}
goInductive :: Members '[Error Err] r => InductiveDef 'Scoped -> Sem r A.InductiveDef
goInductive :: Members '[Error Err, InfoTableBuilder] r => InductiveDef 'Scoped -> Sem r A.InductiveDef
goInductive InductiveDef {..} = do
_inductiveParameters' <- mapM goInductiveParameter _inductiveParameters
_inductiveType' <- sequence $ goExpression <$> _inductiveType
_inductiveConstructors' <- mapM goConstructorDef _inductiveConstructors
return
A.InductiveDef
inductiveInfo <- registerInductive A.InductiveDef
{ _inductiveParameters = _inductiveParameters',
_inductiveName = _inductiveName,
_inductiveType = _inductiveType',
_inductiveConstructors = _inductiveConstructors'
}
forM_ _inductiveConstructors' (registerConstructor inductiveInfo)
return (inductiveInfo ^. inductiveInfoDef)
goConstructorDef :: Members '[Error Err] r => InductiveConstructorDef 'Scoped -> Sem r A.InductiveConstructorDef
goConstructorDef (InductiveConstructorDef c ty) = A.InductiveConstructorDef c <$> goExpression ty
@ -232,7 +243,7 @@ goPattern p = case p of
PatternWildcard -> return A.PatternWildcard
PatternEmpty -> return A.PatternEmpty
goAxiom :: Members '[Error Err] r => AxiomDef 'Scoped -> Sem r A.AxiomDef
goAxiom (AxiomDef n m bs) = do
e <- goExpression m
return (A.AxiomDef n e bs)
goAxiom :: Members '[Error Err, InfoTableBuilder] r => AxiomDef 'Scoped -> Sem r A.AxiomDef
goAxiom (AxiomDef {..}) = do
_axiomType' <- goExpression _axiomType
registerAxiom' A.AxiomDef { _axiomType = _axiomType', ..}