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tock-mirror/frontends/OccamTypes.hs
Adam Sampson 62a0873d3d Implement channel direction decorators. 
This is mostly straightforward: modify the parser to allow direction
decorators in the right places, and extend the type checker to match.
There's some slight awkwardness in that some of the Types functions
have to perform the same checks as the type checker (e.g. directing a
non-channel), so I've tidied up their error messages a bit.

At the backend, I've just added a little pass to strip out all the
DirectedVariables, since the other backend passes don't handle them
gracefully. From the occam/C point of view this is fine, but I'm not
sure if it's going to cause problems for C++.
2008-06-09 21:35:20 +00:00

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{-
Tock: a compiler for parallel languages
Copyright (C) 2008 University of Kent
This program is free software; you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by the
Free Software Foundation, either version 2 of the License, or (at your
option) any later version.
This program is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
General Public License for more details.
You should have received a copy of the GNU General Public License along
with this program. If not, see <http://www.gnu.org/licenses/>.
-}
-- | The occam typechecker.
module OccamTypes (inferTypes, checkTypes) where
import Control.Monad.State
import Data.Generics
import Data.List
import qualified AST as A
import CompState
import Errors
import EvalConstants
import Intrinsics
import Metadata
import Pass
import qualified Properties as Prop
import ShowCode
import Traversal
import Types
import Utils
-- | A successful check.
ok :: PassM ()
ok = return ()
--{{{ type checks
-- | Are two types the same?
sameType :: A.Type -> A.Type -> PassM Bool
sameType (A.Array (A.Dimension e1 : ds1) t1)
(A.Array (A.Dimension e2 : ds2) t2)
= do n1 <- evalIntExpression e1
n2 <- evalIntExpression e2
same <- sameType (A.Array ds1 t1) (A.Array ds2 t2)
return $ (n1 == n2) && same
sameType (A.Array (A.UnknownDimension : ds1) t1)
(A.Array (A.UnknownDimension : ds2) t2)
= sameType (A.Array ds1 t1) (A.Array ds2 t2)
sameType a b = return $ a == b
-- | Check that the second dimension can be used in a context where the first
-- is expected.
isValidDimension :: A.Dimension -> A.Dimension -> PassM Bool
isValidDimension A.UnknownDimension A.UnknownDimension = return True
isValidDimension A.UnknownDimension (A.Dimension _) = return True
isValidDimension (A.Dimension e1) (A.Dimension e2)
= do n1 <- evalIntExpression e1
n2 <- evalIntExpression e2
return $ n1 == n2
isValidDimension _ _ = return False
-- | Check that the second second of dimensions can be used in a context where
-- the first is expected.
areValidDimensions :: [A.Dimension] -> [A.Dimension] -> PassM Bool
areValidDimensions [] [] = return True
areValidDimensions (d1:ds1) (d2:ds2)
= do valid <- isValidDimension d1 d2
if valid
then areValidDimensions ds1 ds2
else return False
areValidDimensions _ _ = return False
-- | Check that the second direction can be used in a context where the first
-- is expected.
isValidDirection :: A.Direction -> A.Direction -> Bool
isValidDirection _ A.DirUnknown = True
isValidDirection ed rd = ed == rd
-- | Check that a type we've inferred matches the type we expected.
checkType :: Meta -> A.Type -> A.Type -> PassM ()
checkType m et rt
= case (et, rt) of
(A.Infer, _) -> ok
(A.Array ds t, A.Array ds' t') ->
do valid <- areValidDimensions ds ds'
if valid
then checkType m t t'
else bad
(A.Chan dir ca t, A.Chan dir' ca' t') ->
if isValidDirection dir dir' && (ca == ca')
then checkType m t t'
else bad
_ ->
do same <- sameType rt et
when (not same) $ bad
where
bad :: PassM ()
bad = diePC m $ formatCode "Type mismatch: found %, expected %" rt et
-- | Check a type against a predicate.
checkTypeClass :: (A.Type -> Bool) -> String -> Meta -> A.Type -> PassM ()
checkTypeClass f adjective m rawT
= do t <- underlyingType m rawT
if f t
then ok
else diePC m $ formatCode ("Expected " ++ adjective ++ " type; found %") t
-- | Check that a type is numeric.
checkNumeric :: Meta -> A.Type -> PassM ()
checkNumeric = checkTypeClass isNumericType "numeric"
-- | Check that a type is integral.
checkInteger :: Meta -> A.Type -> PassM ()
checkInteger = checkTypeClass isIntegerType "integer"
-- | Check that a type is case-selectable.
checkCaseable :: Meta -> A.Type -> PassM ()
checkCaseable = checkTypeClass isCaseableType "case-selectable"
-- | Check that a type is scalar.
checkScalar :: Meta -> A.Type -> PassM ()
checkScalar = checkTypeClass isScalarType "scalar"
-- | Check that a type is usable as a 'DataType'
checkDataType :: Meta -> A.Type -> PassM ()
checkDataType = checkTypeClass isDataType "data"
-- | Check that a type is communicable.
checkCommunicable :: Meta -> A.Type -> PassM ()
checkCommunicable m (A.Counted ct rawAT)
= do checkInteger m ct
at <- resolveUserType m rawAT
case at of
A.Array (A.UnknownDimension:ds) t ->
do checkCommunicable m t
mapM_ (checkFullDimension m) ds
_ -> dieP m "Expected array type with unknown first dimension"
checkCommunicable m A.Any = ok
checkCommunicable m t = checkTypeClass isCommunicableType "communicable" m t
-- | Check that a type is a sequence.
checkSequence :: Meta -> A.Type -> PassM ()
checkSequence = checkTypeClass isSequenceType "array or list"
-- | Check that a type is an array.
checkArray :: Meta -> A.Type -> PassM ()
checkArray m rawT
= do t <- resolveUserType m rawT
case t of
A.Array _ _ -> ok
_ -> diePC m $ formatCode "Expected array type; found %" t
-- | Check that a dimension isn't unknown.
checkFullDimension :: Meta -> A.Dimension -> PassM ()
checkFullDimension m A.UnknownDimension
= dieP m $ "Type contains unknown dimensions"
checkFullDimension _ _ = ok
-- | Check that a type is a list.
checkList :: Meta -> A.Type -> PassM ()
checkList m rawT
= do t <- resolveUserType m rawT
case t of
A.List _ -> ok
_ -> diePC m $ formatCode "Expected list type; found %" t
-- | Check the type of an expression.
checkExpressionType :: A.Type -> A.Expression -> PassM ()
checkExpressionType et e = astTypeOf e >>= checkType (findMeta e) et
-- | Check that an expression is of integer type.
checkExpressionInt :: Check A.Expression
checkExpressionInt e = checkExpressionType A.Int e
-- | Check that an expression is of boolean type.
checkExpressionBool :: Check A.Expression
checkExpressionBool e = checkExpressionType A.Bool e
-- | Pick the more specific of a pair of types.
betterType :: A.Type -> A.Type -> A.Type
betterType t1 t2
= case betterType' t1 t2 of
Left () -> t1
Right () -> t2
where
betterType' :: A.Type -> A.Type -> Either () ()
betterType' A.Infer t = Right ()
betterType' t A.Infer = Left ()
betterType' t@(A.UserDataType _) _ = Left ()
betterType' _ t@(A.UserDataType _) = Right ()
betterType' t1@(A.Array ds1 et1) t2@(A.Array ds2 et2)
| length ds1 == length ds2 = betterType' et1 et2
| length ds1 < length ds2 = Left ()
betterType' t _ = Left ()
--}}}
--{{{ more complex checks
-- | Check that an array literal's length matches its type.
checkArraySize :: Meta -> A.Type -> Int -> PassM ()
checkArraySize m rawT want
= do t <- resolveUserType m rawT
case t of
A.Array (A.UnknownDimension:_) _ -> ok
A.Array (A.Dimension e:_) _ ->
do n <- evalIntExpression e
when (n /= want) $
dieP m $ "Array literal has wrong number of elements: found " ++ show n ++ ", expected " ++ show want
_ -> checkArray m t
-- | Check that a record field name is valid.
checkRecordField :: Meta -> A.Type -> A.Name -> PassM ()
checkRecordField m t n
= do rfs <- recordFields m t
let validNames = map fst rfs
when (not $ n `elem` validNames) $
diePC m $ formatCode "Invalid field name % in record type %" n t
-- | Check a subscript.
checkSubscript :: Meta -> A.Subscript -> A.Type -> PassM ()
checkSubscript m s rawT
= do -- Check the type of the thing being subscripted.
t <- resolveUserType m rawT
case s of
-- A record subscript.
A.SubscriptField m n ->
checkRecordField m t n
-- A sequence subscript.
A.Subscript _ _ _ -> checkSequence m t
-- An array slice.
_ -> checkArray m t
-- Check the subscript itself.
case s of
A.Subscript m _ e -> checkExpressionInt e
A.SubscriptFromFor m _ e f ->
checkExpressionInt e >> checkExpressionInt f
A.SubscriptFrom m _ e -> checkExpressionInt e
A.SubscriptFor m _ e -> checkExpressionInt e
_ -> ok
-- | Classes of operators.
data OpClass = NumericOp | IntegerOp | ShiftOp | BooleanOp | ComparisonOp
| ListOp
-- | Figure out the class of a monadic operator.
classifyMOp :: A.MonadicOp -> OpClass
classifyMOp A.MonadicSubtr = NumericOp
classifyMOp A.MonadicMinus = NumericOp
classifyMOp A.MonadicBitNot = IntegerOp
classifyMOp A.MonadicNot = BooleanOp
-- | Figure out the class of a dyadic operator.
classifyOp :: A.DyadicOp -> OpClass
classifyOp A.Add = NumericOp
classifyOp A.Subtr = NumericOp
classifyOp A.Mul = NumericOp
classifyOp A.Div = NumericOp
classifyOp A.Rem = NumericOp
classifyOp A.Plus = NumericOp
classifyOp A.Minus = NumericOp
classifyOp A.Times = NumericOp
classifyOp A.BitAnd = IntegerOp
classifyOp A.BitOr = IntegerOp
classifyOp A.BitXor = IntegerOp
classifyOp A.LeftShift = ShiftOp
classifyOp A.RightShift = ShiftOp
classifyOp A.And = BooleanOp
classifyOp A.Or = BooleanOp
classifyOp A.Eq = ComparisonOp
classifyOp A.NotEq = ComparisonOp
classifyOp A.Less = ComparisonOp
classifyOp A.More = ComparisonOp
classifyOp A.LessEq = ComparisonOp
classifyOp A.MoreEq = ComparisonOp
classifyOp A.After = ComparisonOp
classifyOp A.Concat = ListOp
-- | Check a monadic operator.
checkMonadicOp :: A.MonadicOp -> A.Expression -> PassM ()
checkMonadicOp op e
= do t <- astTypeOf e
let m = findMeta e
case classifyMOp op of
NumericOp -> checkNumeric m t
IntegerOp -> checkInteger m t
BooleanOp -> checkType m A.Bool t
-- | Check a dyadic operator.
checkDyadicOp :: A.DyadicOp -> A.Expression -> A.Expression -> PassM ()
checkDyadicOp op l r
= do lt <- astTypeOf l
let lm = findMeta l
rt <- astTypeOf r
let rm = findMeta r
case classifyOp op of
NumericOp ->
checkNumeric lm lt >> checkNumeric rm rt >> checkType rm lt rt
IntegerOp ->
checkInteger lm lt >> checkInteger rm rt >> checkType rm lt rt
ShiftOp ->
checkNumeric lm lt >> checkType rm A.Int rt
BooleanOp ->
checkType lm A.Bool lt >> checkType rm A.Bool rt
ComparisonOp ->
checkScalar lm lt >> checkScalar rm rt >> checkType rm lt rt
ListOp ->
checkList lm lt >> checkList rm rt >> checkType rm lt rt
-- | Check an abbreviation.
-- Is the second abbrev mode a valid abbreviation of the first?
checkAbbrev :: Meta -> A.AbbrevMode -> A.AbbrevMode -> PassM ()
checkAbbrev m orig new
= case (orig, new) of
(_, A.Original) -> bad
(A.ValAbbrev, A.ValAbbrev) -> ok
(A.ValAbbrev, A.InitialAbbrev) -> ok
(A.ValAbbrev, _) -> bad
_ -> ok
where
bad :: PassM ()
bad = dieP m $ "You can't abbreviate " ++ showAM orig ++ " as " ++ showAM new
showAM :: A.AbbrevMode -> String
showAM A.Original = "an original declaration"
showAM A.Abbrev = "a reference abbreviation"
showAM A.ValAbbrev = "a VAL abbreviation"
showAM A.InitialAbbrev = "an INITIAL abbreviation"
showAM A.ResultAbbrev = "a RESULT abbreviation"
-- | Check a list of actuals is the right length for a list of formals.
checkActualCount :: Meta -> A.Name -> [A.Formal] -> [a] -> PassM ()
checkActualCount m n fs as
= do when (length fs /= length as) $
diePC m $ formatCode ("% called with wrong number of arguments; found " ++ (show $ length as) ++ ", expected " ++ (show $ length fs)) n
-- | Check a set of actuals against the formals they're meant to match.
checkActuals :: Meta -> A.Name -> [A.Formal] -> [A.Actual] -> PassM ()
checkActuals m n fs as
= do checkActualCount m n fs as
sequence_ [checkActual f a
| (f, a) <- zip fs as]
-- | Check an actual against its matching formal.
checkActual :: A.Formal -> A.Actual -> PassM ()
checkActual (A.Formal newAM et _) a
= do rt <- case a of
A.ActualVariable v -> astTypeOf v
A.ActualExpression e -> astTypeOf e
checkType (findMeta a) et rt
origAM <- case a of
A.ActualVariable v -> abbrevModeOfVariable v
A.ActualExpression _ -> return A.ValAbbrev
checkAbbrev (findMeta a) origAM newAM
-- | Check a function exists.
checkFunction :: Meta -> A.Name -> PassM ([A.Type], [A.Formal])
checkFunction m n
= do st <- specTypeOfName n
case st of
A.Function _ _ rs fs _ -> return (rs, fs)
_ -> diePC m $ formatCode "% is not a function" n
-- | Check a 'Proc' exists.
checkProc :: Meta -> A.Name -> PassM [A.Formal]
checkProc m n
= do st <- specTypeOfName n
case st of
A.Proc _ _ fs _ -> return fs
_ -> diePC m $ formatCode "% is not a procedure" n
-- | Check a function call.
checkFunctionCall :: Meta -> A.Name -> [A.Expression] -> PassM [A.Type]
checkFunctionCall m n es
= do (rs, fs) <- checkFunction m n
checkActuals m n fs (map A.ActualExpression es)
return rs
-- | Check an intrinsic function call.
checkIntrinsicFunctionCall :: Meta -> String -> [A.Expression] -> PassM ()
checkIntrinsicFunctionCall m n es
= case lookup n intrinsicFunctions of
Just (rs, args) ->
do when (length rs /= 1) $
dieP m $ "Function " ++ n ++ " used in an expression returns more than one value"
let fs = [A.Formal A.ValAbbrev t (A.Name m s)
| (t, s) <- args]
checkActuals m (A.Name m n)
fs (map A.ActualExpression es)
Nothing -> dieP m $ n ++ " is not an intrinsic function"
-- | Check a mobile allocation.
checkAllocMobile :: Meta -> A.Type -> Maybe A.Expression -> PassM ()
checkAllocMobile m rawT me
= do t <- resolveUserType m rawT
case t of
A.Mobile innerT ->
do case innerT of
A.Array ds _ -> mapM_ (checkFullDimension m) ds
_ -> ok
case me of
Just e ->
do et <- astTypeOf e
checkType (findMeta e) innerT et
Nothing -> ok
_ -> diePC m $ formatCode "Expected mobile type in allocation; found %" t
-- | Check that a variable is writable.
checkWritable :: Check A.Variable
checkWritable v
= do am <- abbrevModeOfVariable v
case am of
A.ValAbbrev -> dieP (findMeta v) $ "Expected a writable variable"
_ -> ok
-- | Check that is a variable is a channel that can be used in the given
-- direction.
-- If the direction passed is 'DirUnknown', no direction or sharedness checks
-- will be performed.
-- Return the type carried by the channel.
checkChannel :: A.Direction -> A.Variable -> PassM A.Type
checkChannel wantDir c
= do -- Check it's a channel.
t <- astTypeOf c >>= resolveUserType m
case t of
A.Chan dir (A.ChanAttributes ws rs) innerT ->
do -- Check the direction is appropriate
case (wantDir, dir) of
(A.DirUnknown, _) -> ok
(_, A.DirUnknown) -> ok
(a, b) -> when (a /= b) $
dieP m $ "Channel directions do not match"
-- Check it's not shared in the direction we're using.
case (ws, rs, wantDir) of
(False, _, A.DirOutput) -> ok
(_, False, A.DirInput) -> ok
(_, _, A.DirUnknown) -> ok
_ -> dieP m $ "Shared channel must be claimed before use"
return innerT
_ -> diePC m $ formatCode "Expected channel; found %" t
where
m = findMeta c
-- | Check that a variable is a timer.
-- Return the type of the timer's value.
checkTimer :: A.Variable -> PassM A.Type
checkTimer tim
= do t <- astTypeOf tim >>= resolveUserType m
case t of
A.Timer A.OccamTimer -> return A.Int
A.Timer A.RainTimer -> return A.Time
_ -> diePC m $ formatCode "Expected timer; found %" t
where
m = findMeta tim
-- | Return the list of types carried by a protocol.
-- For a variant protocol, the second argument should be 'Just' the tag.
-- For a non-variant protocol, the second argument should be 'Nothing'.
protocolTypes :: Meta -> A.Type -> Maybe A.Name -> PassM [A.Type]
protocolTypes m t tag
= case t of
-- A user-defined protocol.
A.UserProtocol n ->
do st <- specTypeOfName n
case (st, tag) of
-- A simple protocol.
(A.Protocol _ ts, Nothing) -> return ts
(A.Protocol _ _, Just tagName) ->
diePC m $ formatCode "Tag % specified for non-variant protocol %" tagName n
-- A variant protocol.
(A.ProtocolCase _ ntss, Just tagName) ->
case lookup tagName ntss of
Just ts -> return ts
Nothing -> diePC m $ formatCode "Tag % not found in protocol %; expected one of %" tagName n (map fst ntss)
(A.ProtocolCase _ ntss, Nothing) ->
diePC m $ formatCode "No tag specified for variant protocol %; expected one of %" n (map fst ntss)
-- Not actually a protocol.
_ -> diePC m $ formatCode "% is not a protocol" n
-- Not a protocol (e.g. CHAN INT); just return it.
_ -> return [t]
-- | Check a protocol communication.
-- Figure out the types of the items that should be involved in a protocol
-- communication, and run the supplied check against each item with its type.
checkProtocol :: Meta -> A.Type -> Maybe A.Name
-> [t] -> (A.Type -> t -> PassM ()) -> PassM ()
checkProtocol m t tag items doItem
= do its <- protocolTypes m t tag
when (length its /= length items) $
dieP m $ "Wrong number of items in protocol communication; found "
++ (show $ length items) ++ ", expected "
++ (show $ length its)
sequence_ [doItem it item
| (it, item) <- zip its items]
-- | Check an 'ExpressionList' matches a set of types.
checkExpressionList :: [A.Type] -> A.ExpressionList -> PassM ()
checkExpressionList ets el
= case el of
A.FunctionCallList m n es ->
do rs <- checkFunctionCall m n es
when (length ets /= length rs) $
diePC m $ formatCode ("Function % has wrong number of return values; found " ++ (show $ length rs) ++ ", expected " ++ (show $ length ets)) n
sequence_ [checkType m et rt
| (et, rt) <- zip ets rs]
A.ExpressionList m es ->
do when (length ets /= length es) $
dieP m $ "Wrong number of items in expression list; found "
++ (show $ length es) ++ ", expected "
++ (show $ length ets)
sequence_ [do rt <- astTypeOf e
checkType (findMeta e) et rt
| (e, et) <- zip es ets]
-- | Check a set of names are distinct.
checkNamesDistinct :: Meta -> [A.Name] -> PassM ()
checkNamesDistinct m ns
= when (dupes /= []) $
diePC m $ formatCode "List contains duplicate names: %" dupes
where
dupes :: [A.Name]
dupes = nub (ns \\ nub ns)
-- | Check a 'Structured', applying the given check to each item found inside
-- it. This assumes that processes and specifications will be checked
-- elsewhere.
checkStructured :: Data t => Check t -> Check (A.Structured t)
checkStructured doInner s = transformOnly checkInner s >> return ()
where
checkInner m v
= do doInner v
return $ A.Only m v
--}}}
--{{{ retyping checks
-- | Check that one type can be retyped to another.
checkRetypes :: Meta -> A.Type -> A.Type -> PassM ()
checkRetypes m fromT toT
= do (fromBI, fromN) <- evalBytesInType fromT
(toBI, toN) <- evalBytesInType toT
case (fromBI, toBI, fromN, toN) of
(_, BIManyFree, _, _) ->
dieP m "Multiple free dimensions in retype destination type"
(BIJust _, BIJust _, Just a, Just b) ->
when (a /= b) $
dieP m "Sizes do not match in retype"
(BIJust _, BIOneFree _ _, Just a, Just b) ->
when (not ((b <= a) && (a `mod` b == 0))) $
dieP m "Sizes do not match in retype"
(BIOneFree _ _, BIJust _, Just a, Just b) ->
when (not ((a <= b) && (b `mod` a == 0))) $
dieP m "Sizes do not match in retype"
-- Otherwise we must do a runtime check.
_ -> return ()
-- | Evaluate 'BytesIn' for a type.
-- If the size isn't known at compile type, return 'Nothing'.
evalBytesInType :: A.Type -> PassM (BytesInResult, Maybe Int)
evalBytesInType t
= do bi <- bytesInType t
n <- case bi of
BIJust e -> foldEval e
BIOneFree e _ -> foldEval e
_ -> return Nothing
return (bi, n)
where
foldEval :: A.Expression -> PassM (Maybe Int)
foldEval e
= do (e', isConst, _) <- constantFold e
if isConst
then evalIntExpression e' >>* Just
else return Nothing
--}}}
--{{{ type context management
-- | Run an operation in a given type context.
inTypeContext :: Maybe A.Type -> PassM a -> PassM a
inTypeContext ctx body
= do pushTypeContext (case ctx of
Just A.Infer -> Nothing
_ -> ctx)
v <- body
popTypeContext
return v
-- | Run an operation in the type context 'Nothing'.
noTypeContext :: PassM a -> PassM a
noTypeContext = inTypeContext Nothing
-- | Run an operation in the type context that results from subscripting
-- the current type context.
-- If the current type context is 'Nothing', the resulting one will be too.
inSubscriptedContext :: Meta -> PassM a -> PassM a
inSubscriptedContext m body
= do ctx <- getTypeContext
subCtx <- case ctx of
Just t@(A.Array _ _) ->
trivialSubscriptType m t >>* Just
Just t -> diePC m $ formatCode "Attempting to subscript non-array type %" t
Nothing -> return Nothing
inTypeContext subCtx body
--}}}
--{{{ inferTypes
-- | Infer types.
inferTypes :: Pass
inferTypes = occamOnlyPass "Infer types"
[]
[Prop.inferredTypesRecorded]
recurse
where
ops :: Ops
ops = baseOp
`extOp` doExpression
`extOp` doDimension
`extOp` doSubscript
`extOp` doArrayConstr
`extOp` doReplicator
`extOp` doAlternative
`extOp` doInputMode
`extOp` doSpecification
`extOp` doProcess
`extOp` doVariable
recurse :: Recurse
recurse = makeRecurse ops
descend :: Descend
descend = makeDescend ops
doExpression :: Transform A.Expression
doExpression outer
= case outer of
-- Literals are what we're really looking for here.
A.Literal m t lr ->
do t' <- recurse t
ctx <- getTypeContext
let wantT = case (ctx, t') of
-- No type specified on the literal,
-- but there's a context, so use that.
(Just ct, A.Infer) -> ct
-- Use the explicit type of the literal, or the
-- default.
_ -> t'
(realT, realLR) <- doLiteral (wantT, lr)
return $ A.Literal m realT realLR
-- Expressions that aren't literals, but that modify the type
-- context.
A.Dyadic m op le re ->
let -- Both types are the same.
bothSame
= do lt <- recurse le >>= astTypeOf
rt <- recurse re >>= astTypeOf
inTypeContext (Just $ betterType lt rt) $
descend outer
-- The RHS type is always A.Int.
intOnRight
= do le' <- recurse le
re' <- inTypeContext (Just A.Int) $ recurse re
return $ A.Dyadic m op le' re'
in case classifyOp op of
ComparisonOp -> noTypeContext $ bothSame
ShiftOp -> intOnRight
_ -> bothSame
A.SizeExpr _ _ -> noTypeContext $ descend outer
A.Conversion _ _ _ _ -> noTypeContext $ descend outer
A.FunctionCall m n es ->
do es' <- doFunctionCall m n es
return $ A.FunctionCall m n es'
A.IntrinsicFunctionCall _ _ _ -> noTypeContext $ descend outer
A.SubscriptedExpr m s e ->
do ctx <- getTypeContext
ctx' <- case ctx of
Just t -> unsubscriptType s t >>* Just
Nothing -> return Nothing
e' <- inTypeContext ctx' $ recurse e
t <- astTypeOf e'
s' <- recurse s >>= fixSubscript t
return $ A.SubscriptedExpr m s' e'
A.BytesInExpr _ _ -> noTypeContext $ descend outer
-- FIXME: ExprConstr
-- FIXME: AllocMobile
-- Other expressions don't modify the type context.
_ -> descend outer
doFunctionCall :: Meta -> A.Name -> Transform [A.Expression]
doFunctionCall m n es
= do (_, fs) <- checkFunction m n
doActuals m n fs es
doActuals :: Data a => Meta -> A.Name -> [A.Formal] -> Transform [a]
doActuals m n fs as
= do checkActualCount m n fs as
sequence [inTypeContext (Just t) $ recurse a
| (A.Formal _ t _, a) <- zip fs as]
doDimension :: Transform A.Dimension
doDimension dim = inTypeContext (Just A.Int) $ descend dim
doSubscript :: Transform A.Subscript
doSubscript s = inTypeContext (Just A.Int) $ descend s
-- FIXME: RepConstr shouldn't contain the type -- and this won't fill it in.
-- (That is, it should just be a kind of literal.)
doArrayConstr :: Transform A.ArrayConstr
doArrayConstr ac
= case ac of
A.RangeConstr m t _ _ -> inSubscriptedContext m $ descend ac
A.RepConstr m t _ _ _ -> inSubscriptedContext m $ descend ac
doExpressionList :: [A.Type] -> Transform A.ExpressionList
doExpressionList ts el
= case el of
A.FunctionCallList m n es ->
do es' <- doFunctionCall m n es
return $ A.FunctionCallList m n es'
A.ExpressionList m es ->
do es' <- sequence [inTypeContext (Just t) $ recurse e
| (t, e) <- zip ts es]
return $ A.ExpressionList m es'
doReplicator :: Transform A.Replicator
doReplicator rep
= case rep of
A.For _ _ _ -> inTypeContext (Just A.Int) $ descend rep
A.ForEach _ _ -> noTypeContext $ descend rep
doAlternative :: Transform A.Alternative
doAlternative a = inTypeContext (Just A.Bool) $ descend a
doInputMode :: Transform A.InputMode
doInputMode im = inTypeContext (Just A.Int) $ descend im
-- FIXME: This should be shared with foldConstants.
doSpecification :: Transform A.Specification
doSpecification s@(A.Specification m n st)
= do st' <- doSpecType st
-- Update the definition of each name after we handle it.
modifyName n (\nd -> nd { A.ndSpecType = st' })
return $ A.Specification m n st'
doSpecType :: Transform A.SpecType
doSpecType st
= case st of
A.Place _ _ -> inTypeContext (Just A.Int) $ descend st
A.Is m am t v ->
do am' <- recurse am
t' <- recurse t
v' <- inTypeContext (Just t') $ recurse v
t'' <- case t' of
A.Infer -> astTypeOf v'
_ -> return t'
return $ A.Is m am' t'' v'
A.IsExpr m am t e ->
do am' <- recurse am
t' <- recurse t
e' <- inTypeContext (Just t') $ recurse e
t'' <- case t' of
A.Infer -> astTypeOf e'
_ -> return t'
return $ A.IsExpr m am' t'' e'
A.IsChannelArray m t vs ->
-- No expressions in this -- but we may need to infer the type
-- of the variable if it's something like "cs IS [c]:".
do t' <- recurse t
vs' <- mapM recurse vs
let dim = makeDimension m $ length vs'
t'' <- case (t', vs') of
(A.Infer, (v:_)) ->
do elemT <- astTypeOf v
return $ addDimensions [dim] elemT
(A.Infer, []) ->
dieP m "Cannot infer type of empty channel array"
_ -> return $ applyDimension dim t'
return $ A.IsChannelArray m t'' vs'
A.Function m sm ts fs (Left sel) ->
do sm' <- recurse sm
ts' <- recurse ts
fs' <- recurse fs
sel' <- doFuncDef ts sel
return $ A.Function m sm' ts' fs' (Left sel')
A.RetypesExpr _ _ _ _ -> noTypeContext $ descend st
_ -> descend st
where
-- | This is a bit ugly: walk down a Structured to find the single
-- ExpressionList that must be in there.
-- (This can go away once we represent all functions in the new Process
-- form.)
doFuncDef :: [A.Type] -> Transform (A.Structured A.ExpressionList)
doFuncDef ts (A.Spec m spec s)
= do spec' <- recurse spec
s' <- doFuncDef ts s
return $ A.Spec m spec' s'
doFuncDef ts (A.ProcThen m p s)
= do p' <- recurse p
s' <- doFuncDef ts s
return $ A.ProcThen m p' s'
doFuncDef ts (A.Only m el)
= do el' <- doExpressionList ts el
return $ A.Only m el'
doProcess :: Transform A.Process
doProcess p
= case p of
A.Assign m vs el ->
do vs' <- recurse vs
ts <- mapM astTypeOf vs'
el' <- doExpressionList ts el
return $ A.Assign m vs' el'
A.Output m v ois ->
do v' <- recurse v
-- At this point we must resolve the "c ! x" ambiguity:
-- we definitely know what c is, and we must know what x is
-- before trying to infer its type.
tagged <- isTagged v'
if tagged
-- Tagged protocol -- convert (wrong) variable to tag.
then case ois of
((A.OutExpression _ (A.ExprVariable _ (A.Variable _ wrong))):ois) ->
do tag <- nameToUnscoped wrong
ois' <- doOutputItems m v' (Just tag) ois
return $ A.OutputCase m v' tag ois'
_ -> diePC m $ formatCode "This channel carries a variant protocol; expected a list starting with a tag, but found %" ois
-- Regular protocol -- proceed as before.
else do ois' <- doOutputItems m v' Nothing ois
return $ A.Output m v' ois'
A.OutputCase m v tag ois ->
do v' <- recurse v
ois' <- doOutputItems m v' (Just tag) ois
return $ A.OutputCase m v' tag ois'
A.If _ _ -> inTypeContext (Just A.Bool) $ descend p
A.Case m e so ->
do e' <- recurse e
t <- astTypeOf e'
so' <- inTypeContext (Just t) $ recurse so
return $ A.Case m e' so'
A.While _ _ _ -> inTypeContext (Just A.Bool) $ descend p
A.Processor _ _ _ -> inTypeContext (Just A.Int) $ descend p
A.ProcCall m n as ->
do fs <- checkProc m n
as' <- doActuals m n fs as
return $ A.ProcCall m n as'
A.IntrinsicProcCall _ _ _ -> noTypeContext $ descend p
_ -> descend p
where
-- | Does a channel carry a tagged protocol?
isTagged :: A.Variable -> PassM Bool
isTagged c
= do protoT <- checkChannel A.DirOutput c
case protoT of
A.UserProtocol n ->
do st <- specTypeOfName n
case st of
A.ProtocolCase _ _ -> return True
_ -> return False
_ -> return False
doOutputItems :: Meta -> A.Variable -> Maybe A.Name
-> Transform [A.OutputItem]
doOutputItems m v tag ois
= do chanT <- checkChannel A.DirOutput v
ts <- protocolTypes m chanT tag
sequence [doOutputItem t oi | (t, oi) <- zip ts ois]
doOutputItem :: A.Type -> Transform A.OutputItem
doOutputItem (A.Counted ct at) (A.OutCounted m ce ae)
= do ce' <- inTypeContext (Just ct) $ recurse ce
ae' <- inTypeContext (Just at) $ recurse ae
return $ A.OutCounted m ce' ae'
doOutputItem A.Any o = noTypeContext $ recurse o
doOutputItem t o = inTypeContext (Just t) $ recurse o
doVariable :: Transform A.Variable
doVariable (A.SubscriptedVariable m s v)
= do v' <- recurse v
t <- astTypeOf v'
s' <- recurse s >>= fixSubscript t
return $ A.SubscriptedVariable m s' v'
doVariable v = descend v
-- | Resolve the @v[s]@ ambiguity: this takes the type that @v@ is, and
-- returns the correct 'Subscript'.
fixSubscript :: A.Type -> A.Subscript -> PassM A.Subscript
fixSubscript t s@(A.Subscript m _ (A.ExprVariable _ (A.Variable _ wrong)))
= do underT <- resolveUserType m t
case underT of
A.Record _ ->
do n <- nameToUnscoped wrong
return $ A.SubscriptField m n
_ -> return s
fixSubscript _ s = return s
-- | Given a name that should really have been a tag, make it one.
nameToUnscoped :: A.Name -> PassM A.Name
nameToUnscoped n@(A.Name m _)
= do nd <- lookupName n
findUnscopedName (A.Name m (A.ndOrigName nd))
-- | Process a 'LiteralRepr', taking the type it's meant to represent or
-- 'Infer', and returning the type it really is.
doLiteral :: Transform (A.Type, A.LiteralRepr)
doLiteral (wantT, lr)
= case lr of
A.ArrayLiteral m aes ->
do (t, A.ArrayElemArray aes') <-
doArrayElem wantT (A.ArrayElemArray aes)
lr' <- buildTable t aes'
return (t, lr')
_ ->
do lr' <- descend lr
(defT, isT) <-
case lr' of
A.RealLiteral _ _ -> return (A.Real32, isRealType)
A.IntLiteral _ _ -> return (A.Int, isIntegerType)
A.HexLiteral _ _ -> return (A.Int, isIntegerType)
A.ByteLiteral _ _ -> return (A.Byte, isIntegerType)
_ -> dieP m $ "Unexpected LiteralRepr: " ++ show lr'
underT <- resolveUserType m wantT
case (wantT, isT underT) of
(A.Infer, _) -> return (defT, lr')
(_, True) -> return (wantT, lr')
(_, False) -> diePC m $ formatCode "Literal of default type % is not valid for type %" defT wantT
where
m = findMeta lr
doArrayElem :: A.Type -> A.ArrayElem -> PassM (A.Type, A.ArrayElem)
-- A table: this could be an array or a record.
doArrayElem wantT (A.ArrayElemArray aes)
= do underT <- resolveUserType m wantT
case underT of
A.Array _ _ ->
do subT <- trivialSubscriptType m underT
(elemT, aes') <- doElems subT aes
let dim = makeDimension m (length aes)
return (applyDimension dim wantT,
A.ArrayElemArray aes')
A.Record _ ->
do nts <- recordFields m underT
aes <- sequence [doArrayElem t ae >>* snd
| ((_, t), ae) <- zip nts aes]
return (wantT, A.ArrayElemArray aes)
-- If we don't know, assume it's an array.
A.Infer ->
do (elemT, aes') <- doElems A.Infer aes
when (elemT == A.Infer) $
dieP m "Cannot infer type of (empty?) array"
let dims = [makeDimension m (length aes)]
return (addDimensions dims elemT,
A.ArrayElemArray aes')
_ -> diePC m $ formatCode "Table literal is not valid for type %" wantT
where
doElems :: A.Type -> [A.ArrayElem] -> PassM (A.Type, [A.ArrayElem])
doElems t aes
= do ts <- mapM (\ae -> doArrayElem t ae >>* fst) aes
let bestT = foldl betterType t ts
aes' <- mapM (\ae -> doArrayElem bestT ae >>* snd) aes
return (bestT, aes')
-- An expression: descend into it with the right context.
doArrayElem wantT (A.ArrayElemExpr e)
= do e' <- inTypeContext (Just wantT) $ doExpression e
t <- astTypeOf e'
checkType (findMeta e') wantT t
return (t, A.ArrayElemExpr e')
-- | Turn a raw table literal into the appropriate combination of
-- arrays and records.
buildTable :: A.Type -> [A.ArrayElem] -> PassM A.LiteralRepr
buildTable t aes
= do underT <- resolveUserType m t
case underT of
A.Array _ _ ->
do elemT <- trivialSubscriptType m t
aes' <- mapM (buildElem elemT) aes
return $ A.ArrayLiteral m aes'
A.Record _ ->
do nts <- recordFields m underT
aes' <- sequence [buildExpr elemT ae
| ((_, elemT), ae) <- zip nts aes]
return $ A.RecordLiteral m aes'
where
buildExpr :: A.Type -> A.ArrayElem -> PassM A.Expression
buildExpr t (A.ArrayElemArray aes)
= do lr <- buildTable t aes
return $ A.Literal m t lr
buildExpr _ (A.ArrayElemExpr e) = return e
buildElem :: A.Type -> A.ArrayElem -> PassM A.ArrayElem
buildElem t ae
= do underT <- resolveUserType m t
case (underT, ae) of
(A.Array _ _, A.ArrayElemArray aes) ->
do A.ArrayLiteral _ aes' <- buildTable t aes
return $ A.ArrayElemArray aes'
(A.Record _, A.ArrayElemArray _) ->
do e <- buildExpr t ae
return $ A.ArrayElemExpr e
(_, A.ArrayElemExpr _) -> return ae
--}}}
--{{{ checkTypes
-- | Check the AST for type consistency.
-- This is actually a series of smaller passes that check particular types
-- inside the AST, but it doesn't really make sense to split it up.
checkTypes :: Pass
checkTypes = occamOnlyPass "Check types"
[Prop.inferredTypesRecorded, Prop.ambiguitiesResolved]
[Prop.expressionTypesChecked, Prop.processTypesChecked,
Prop.functionTypesChecked, Prop.retypesChecked]
( checkVariables >.>
checkExpressions >.>
checkSpecTypes >.>
checkProcesses
)
--{{{ checkVariables
checkVariables :: PassType
checkVariables = checkDepthM doVariable
where
doVariable :: Check A.Variable
doVariable (A.SubscriptedVariable m s v)
= do t <- astTypeOf v
checkSubscript m s t
doVariable (A.DirectedVariable m dir v)
= do t <- astTypeOf v >>= resolveUserType m
case t of
A.Chan oldDir _ _ -> checkDir oldDir
A.Array _ (A.Chan oldDir _ _) -> checkDir oldDir
_ -> dieP m $ "Direction specified on non-channel variable"
where
checkDir oldDir
= if isValidDirection dir oldDir
then ok
else dieP m "Direction specified does not match existing direction"
doVariable (A.DerefVariable m v)
= do t <- astTypeOf v >>= resolveUserType m
case t of
A.Mobile _ -> ok
_ -> dieP m $ "Dereference applied to non-mobile variable"
doVariable _ = ok
--}}}
--{{{ checkExpressions
checkExpressions :: PassType
checkExpressions = checkDepthM doExpression
where
doExpression :: Check A.Expression
doExpression (A.Monadic _ op e) = checkMonadicOp op e
doExpression (A.Dyadic _ op le re) = checkDyadicOp op le re
doExpression (A.MostPos m t) = checkNumeric m t
doExpression (A.MostNeg m t) = checkNumeric m t
doExpression (A.SizeType m t) = checkSequence m t
doExpression (A.SizeExpr m e)
= do t <- astTypeOf e
checkSequence m t
doExpression (A.SizeVariable m v)
= do t <- astTypeOf v
checkSequence m t
doExpression (A.Conversion m _ t e)
= do et <- astTypeOf e
checkScalar m t >> checkScalar (findMeta e) et
doExpression (A.Literal m t lr) = doLiteralRepr t lr
doExpression (A.FunctionCall m n es)
= do rs <- checkFunctionCall m n es
when (length rs /= 1) $
diePC m $ formatCode "Function % used in an expression returns more than one value" n
doExpression (A.IntrinsicFunctionCall m s es)
= checkIntrinsicFunctionCall m s es
doExpression (A.SubscriptedExpr m s e)
= do t <- astTypeOf e
checkSubscript m s t
doExpression (A.OffsetOf m rawT n)
= do t <- resolveUserType m rawT
checkRecordField m t n
doExpression (A.AllocMobile m t me) = checkAllocMobile m t me
doExpression _ = ok
doLiteralRepr :: A.Type -> A.LiteralRepr -> PassM ()
doLiteralRepr t (A.ArrayLiteral m aes)
= doArrayElem m t (A.ArrayElemArray aes)
doLiteralRepr t (A.RecordLiteral m es)
= do rfs <- resolveUserType m t >>= recordFields m
when (length es /= length rfs) $
dieP m $ "Record literal has wrong number of fields: found " ++ (show $ length es) ++ ", expected " ++ (show $ length rfs)
sequence_ [checkExpressionType ft fe
| ((_, ft), fe) <- zip rfs es]
doLiteralRepr _ _ = ok
doArrayElem :: Meta -> A.Type -> A.ArrayElem -> PassM ()
doArrayElem m t (A.ArrayElemArray aes)
= do checkArraySize m t (length aes)
t' <- subscriptType (A.Subscript m A.NoCheck undefined) t
sequence_ $ map (doArrayElem m t') aes
doArrayElem _ t (A.ArrayElemExpr e) = checkExpressionType t e
--}}}
--{{{ checkSpecTypes
checkSpecTypes :: PassType
checkSpecTypes = checkDepthM doSpecType
where
doSpecType :: Check A.SpecType
doSpecType (A.Place _ e) = checkExpressionInt e
doSpecType (A.Declaration _ _) = ok
doSpecType (A.Is m am t v)
= do tv <- astTypeOf v
checkType (findMeta v) t tv
checkRefAM m am
amv <- abbrevModeOfVariable v
checkAbbrev m amv am
doSpecType (A.IsExpr m am t e)
= do te <- astTypeOf e
checkType (findMeta e) t te
checkValAM m am
checkAbbrev m A.ValAbbrev am
doSpecType (A.IsChannelArray m rawT cs)
= do t <- resolveUserType m rawT
case t of
A.Array [d] et@(A.Chan _ _ _) ->
do sequence_ [do rt <- astTypeOf c
checkType (findMeta c) et rt
am <- abbrevModeOfVariable c
checkAbbrev m am A.Abbrev
| c <- cs]
case d of
A.UnknownDimension -> ok
A.Dimension e ->
do v <- evalIntExpression e
when (v /= length cs) $
dieP m $ "Wrong number of elements in channel array abbreviation: found " ++ (show $ length cs) ++ ", expected " ++ show v
_ -> dieP m "Expected 1D channel array type"
doSpecType (A.DataType m t)
= checkDataType m t
doSpecType (A.RecordType m _ nts)
= do sequence_ [checkDataType (findMeta n) t
| (n, t) <- nts]
checkNamesDistinct m (map fst nts)
doSpecType (A.Protocol m ts)
= do when (length ts == 0) $
dieP m "A protocol cannot be empty"
mapM_ (checkCommunicable m) ts
doSpecType (A.ProtocolCase m ntss)
= do sequence_ [mapM_ (checkCommunicable (findMeta n)) ts
| (n, ts) <- ntss]
checkNamesDistinct m (map fst ntss)
doSpecType (A.Proc m _ fs _)
= sequence_ [when (am == A.Original) $ unexpectedAM m
| A.Formal am _ n <- fs]
doSpecType (A.Function m _ rs fs body)
= do when (length rs == 0) $
dieP m "A function must have at least one return type"
sequence_ [do when (am /= A.ValAbbrev) $
diePC (findMeta n) $ formatCode "Argument % is not a value abbreviation" n
checkDataType (findMeta n) t
| A.Formal am t n <- fs]
-- FIXME: Run this test again after free name removal
doFunctionBody rs body
where
doFunctionBody :: [A.Type]
-> Either (A.Structured A.ExpressionList) A.Process
-> PassM ()
doFunctionBody rs (Left s) = checkStructured (checkExpressionList rs) s
-- FIXME: Need to know the name of the function to do this
doFunctionBody rs (Right p) = dieP m "Cannot check function process body"
doSpecType (A.Retypes m am t v)
= do fromT <- astTypeOf v
checkRetypes m fromT t
checkRefAM m am
amv <- abbrevModeOfVariable v
checkAbbrev m amv am
doSpecType (A.RetypesExpr m am t e)
= do fromT <- astTypeOf e
checkRetypes m fromT t
checkValAM m am
checkAbbrev m A.ValAbbrev am
doSpecType (A.Rep _ (A.For _ start count))
= do checkExpressionInt start
checkExpressionInt count
doSpecType (A.Rep _ (A.ForEach _ e))
= do t <- astTypeOf e
checkSequence (findMeta e) t
checkValAM :: Meta -> A.AbbrevMode -> PassM ()
checkValAM m am
= case am of
A.ValAbbrev -> ok
A.InitialAbbrev -> ok
_ -> unexpectedAM m
checkRefAM :: Meta -> A.AbbrevMode -> PassM ()
checkRefAM m am
= case am of
A.Abbrev -> ok
A.ResultAbbrev -> ok
_ -> unexpectedAM m
unexpectedAM :: Check Meta
unexpectedAM m = dieP m "Unexpected abbreviation mode"
--}}}
--{{{ checkProcesses
checkProcesses :: PassType
checkProcesses = checkDepthM doProcess
where
doProcess :: Check A.Process
doProcess (A.Assign m vs el)
-- We ignore dimensions here because we do the check at runtime.
-- (That is, [2]INT := []INT is legal.)
= do vts <- sequence [astTypeOf v >>* removeFixedDimensions
| v <- vs]
mapM_ checkWritable vs
checkExpressionList vts el
doProcess (A.Input _ v im) = doInput v im
doProcess (A.Output m v ois) = doOutput m v ois
doProcess (A.OutputCase m v tag ois) = doOutputCase m v tag ois
doProcess (A.ClearMobile _ v)
= do t <- astTypeOf v
case t of
A.Mobile _ -> ok
_ -> diePC (findMeta v) $ formatCode "Expected mobile type; found %" t
checkWritable v
doProcess (A.Skip _) = ok
doProcess (A.Stop _) = ok
doProcess (A.Seq _ s) = checkStructured (\p -> ok) s
doProcess (A.If _ s) = checkStructured doChoice s
doProcess (A.Case _ e s)
= do t <- astTypeOf e
checkCaseable (findMeta e) t
checkStructured (doOption t) s
doProcess (A.While _ e _) = checkExpressionBool e
doProcess (A.Par _ _ s) = checkStructured (\p -> ok) s
doProcess (A.Processor _ e _) = checkExpressionInt e
doProcess (A.Alt _ _ s) = checkStructured doAlternative s
doProcess (A.ProcCall m n as)
= do fs <- checkProc m n
checkActuals m n fs as
doProcess (A.IntrinsicProcCall m n as)
= case lookup n intrinsicProcs of
Just args ->
do let fs = [A.Formal am t (A.Name m s)
| (am, t, s) <- args]
checkActuals m (A.Name m n) fs as
Nothing -> dieP m $ n ++ " is not an intrinsic procedure"
doAlternative :: Check A.Alternative
doAlternative (A.Alternative m e v im p)
= do checkExpressionBool e
case im of
A.InputTimerRead _ _ ->
dieP m $ "Timer read not permitted as alternative"
_ -> doInput v im
doAlternative (A.AlternativeSkip _ e _)
= checkExpressionBool e
doChoice :: Check A.Choice
doChoice (A.Choice _ e _) = checkExpressionBool e
doInput :: A.Variable -> A.InputMode -> PassM ()
doInput c (A.InputSimple m iis)
= do t <- checkChannel A.DirInput c
checkProtocol m t Nothing iis doInputItem
doInput c (A.InputCase _ s)
= do t <- checkChannel A.DirInput c
checkStructured (doVariant t) s
where
doVariant :: A.Type -> A.Variant -> PassM ()
doVariant t (A.Variant m tag iis _)
= checkProtocol m t (Just tag) iis doInputItem
doInput c (A.InputTimerRead m ii)
= do t <- checkTimer c
doInputItem t ii
doInput c (A.InputTimerAfter m e)
= do t <- checkTimer c
et <- astTypeOf e
checkType (findMeta e) t et
doInput c (A.InputTimerFor m e)
= do t <- checkTimer c
et <- astTypeOf e
checkType (findMeta e) t et
doInputItem :: A.Type -> A.InputItem -> PassM ()
doInputItem (A.Counted wantCT wantAT) (A.InCounted m cv av)
= do ct <- astTypeOf cv
checkType (findMeta cv) wantCT ct
checkWritable cv
at <- astTypeOf av
checkType (findMeta cv) wantAT at
checkWritable av
doInputItem t@(A.Counted _ _) (A.InVariable m v)
= diePC m $ formatCode "Expected counted item of type %; found %" t v
doInputItem wantT (A.InVariable _ v)
= do t <- astTypeOf v
case wantT of
A.Any -> checkCommunicable (findMeta v) t
_ -> checkType (findMeta v) wantT t
checkWritable v
doOption :: A.Type -> A.Option -> PassM ()
doOption et (A.Option _ es _)
= sequence_ [do rt <- astTypeOf e
checkType (findMeta e) et rt
| e <- es]
doOption _ (A.Else _ _) = ok
doOutput :: Meta -> A.Variable -> [A.OutputItem] -> PassM ()
doOutput m c ois
= do t <- checkChannel A.DirOutput c
checkProtocol m t Nothing ois doOutputItem
doOutputCase :: Meta -> A.Variable -> A.Name -> [A.OutputItem] -> PassM ()
doOutputCase m c tag ois
= do t <- checkChannel A.DirOutput c
checkProtocol m t (Just tag) ois doOutputItem
doOutputItem :: A.Type -> A.OutputItem -> PassM ()
doOutputItem (A.Counted wantCT wantAT) (A.OutCounted m ce ae)
= do ct <- astTypeOf ce
checkType (findMeta ce) wantCT ct
at <- astTypeOf ae
checkType (findMeta ae) wantAT at
doOutputItem t@(A.Counted _ _) (A.OutExpression m e)
= diePC m $ formatCode "Expected counted item of type %; found %" t e
doOutputItem wantT (A.OutExpression _ e)
= do t <- astTypeOf e
case wantT of
A.Any -> checkCommunicable (findMeta e) t
_ -> checkType (findMeta e) wantT t
--}}}
--}}}
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