import qualified Data.Map as Map
from Data.Func import $
+import Data.Maybe
import Data.Either
+import Data.Functor
+import Control.Applicative
+import Control.Monad
import Control.Monad.State
+import Control.Monad.Identity
+import Math.Random
import StdMisc
+from StdFunc import id, const, o
+import StdString
+import StdTuple
+import StdList
+
+from Text import class Text(concat), instance Text String
import AST
-from parse import :: ParserOutput
-from yard import :: Error
+from parse import :: ParserOutput, :: Error
+
+:: Gamma :== ('Map'.Map String Type, [String])
+:: Env a :== (State Gamma (Either SemError a))
+
+get = state $ \s -> (s,s)
+
+getRandomStream :: Int -> [String]
+getRandomStream i = genIdents $ filter (isAlpha o toChar) (genRandInt i)
+ where
+ genIdents r = let (ic, r) = splitAt 5 r in [toString ic: genIdents r]
+
+freshIdent :: Gamma -> (String, Gamma)
+freshIdent (st, [ident:rest]) = case 'Map'.get ident st of
+ Nothing = (ident, (st, rest))
+ _ = freshIdent (st, rest)
+
+putIdent :: String Type -> Env Void
+putIdent i t = gets (\(st, r)->'Map'.get i st) >>= \mt -> case mt of
+ Nothing = pure <$> modify (\(st, r)->('Map'.put i t st, r))
+ Just t2 = unify t t2 >>= \r -> case r of
+ Left e = pure $ Left e
+ Right t3 = pure <$> modify (\(st, r)->('Map'.put i t3 st, r))
+
+instance toString SemError where
+ toString (ParseError p e) = concat [
+ toString p,"SemError: ParseError: ", e]
+ toString (Error e) = "SemError: " +++ e
+ toString (UnifyErrorStub t1 t2) = toString (UnifyError {line=0,col=0} t1 t2)
+ toString (UnifyError p t1 t2) = concat [
+ toString p,
+ "SemError: Cannot unify types. Expected: ",
+ toString t1, ". Given: ", toString t2]
-:: Gamma :== 'Map'.Map String Type
-:: Env a :== State Gamma a
+sem :: AST -> SemOutput
+sem (AST vd fd)
+# (eithervds, gamma) = runState (mapM semVarDecl vd) ('Map'.newMap, getRandomStream 0)
+# (eitherfds, gamma) = runState (mapM semFunDecl fd) gamma
+= case splitEithers eithervds of
+ (Left errs) = Left $ errs ++ [x\\(Left x)<-eitherfds]
+ (Right vds) = case splitEithers eitherfds of
+ (Left errs) = Left errs
+ (Right fds) = Right $ AST vds fds
-sem :: ParserOutput -> SemOutput
-sem (Left p) = Left p
-sem (Right (AST vd fd)) = Right $ AST vd fd
-// foldM semVarDecl vd
-// >>= \gamma ->foldM typecheck gamma fd
+splitEithers :: [Either a b] -> Either [a] [b]
+splitEithers [] = Right []
+splitEithers [Right x:xs] = splitEithers xs >>= \rest->Right [x:rest]
+splitEithers xs = Left $ [x\\(Left x)<-xs]
+
+semFunDecl :: FunDecl -> Env FunDecl
+semFunDecl f = pure $ Right f
semVarDecl :: VarDecl -> Env VarDecl
-semVarDecl (Vardecl pos type ident expr) = undef
-
+semVarDecl vd=:(VarDecl pos type ident ex) = unify type ex
+ >>= \et->case et of
+ Left err = pure $ Left err
+ Right t = putIdent ident t >>| pure (Right $ VarDecl pos t ident ex)
+
+typeExpr :: Expr -> Env Type
+typeExpr (IntExpr _ _) = pure $ Right IntType
+typeExpr (CharExpr _ _) = pure $ Right CharType
+typeExpr (BoolExpr _ _) = pure $ Right BoolType
+typeExpr (Op1Expr p UnNegation expr) = unify BoolType expr
+typeExpr (Op1Expr p UnMinus expr) = unify IntType expr
+typeExpr (TupleExpr p (e1, e2)) = typeExpr e1
+ >>= \ete1->typeExpr e2 >>= \ete2->pure (
+ ete1 >>= \te1->ete2 >>= \te2->Right $ TupleType (te1, te2))
+//Int
+typeExpr (Op2Expr p e1 BiPlus e2) = unify IntType e1 >>| unify IntType e2
+typeExpr (Op2Expr p e1 BiMinus e2) = unify IntType e1 >>| unify IntType e2
+typeExpr (Op2Expr p e1 BiTimes e2) = unify IntType e1 >>| unify IntType e2
+typeExpr (Op2Expr p e1 BiDivide e2) = unify IntType e1 >>| unify IntType e2
+typeExpr (Op2Expr p e1 BiMod e2) = unify IntType e1 >>| unify IntType e2
+//bool, char of int
+typeExpr (Op2Expr p e1 BiEquals e2) = undef
+typeExpr (Op2Expr p e1 BiUnEqual e2) = undef
+//char of int
+typeExpr (Op2Expr p e1 BiLesser e2) = undef
+typeExpr (Op2Expr p e1 BiGreater e2) = undef
+typeExpr (Op2Expr p e1 BiLesserEq e2) = undef
+typeExpr (Op2Expr p e1 BiGreaterEq e2) = undef
+//bool
+typeExpr (Op2Expr p e1 BiAnd e2) = undef
+typeExpr (Op2Expr p e1 BiOr e2) = undef
+//a
+typeExpr (Op2Expr p e1 BiCons e2) = undef
+//typeExpr (FunExpr Pos FunCall) = undef
+//typeExpr (EmptyListExpr Pos) = undef
+//typeExpr (VarExpr Pos VarDef) = undef //when checking var-expr, be sure to
+//put the infered type
+ //in the context
+
+class unify a :: Type a -> Env Type
+
+instance unify Expr where
+ unify (_ ->> _) e = pure $ Left $ ParseError (extrPos e)
+ "Expression cannot be a higher order function. Yet..."
+ unify VoidType e = pure $ Left $ ParseError (extrPos e)
+ "Expression cannot be a Void type."
+ unify (IdType _) e = pure $ Left $ ParseError (extrPos e)
+ "Expression cannot be an polymorf type."
+ unify VarType e = typeExpr e
+ unify t e = typeExpr e
+ >>= \eithertype->case eithertype of
+ Left e = pure $ Left e
+ Right tex = unify t tex >>= \eitherun->case eitherun of
+ Left err = pure $ Left $ decErr e err
+ Right t = pure $ Right t
+
+instance unify Type where
+ unify IntType IntType = pure $ Right IntType
+ unify BoolType BoolType = pure $ Right BoolType
+ unify CharType CharType = pure $ Right CharType
+ unify t1 t2 = pure $ Left $ UnifyError zero t1 t2
+
+instance zero Pos where
+ zero = {line=0,col=0}
+decErr :: Expr SemError -> SemError
+decErr e (UnifyError _ t1 t2) = UnifyError (extrPos e) t1 t2
+decErr e (ParseError _ s) = ParseError (extrPos e) s
+decErr e err = err
-
+extrPos :: Expr -> Pos
+extrPos (VarExpr p _) = p
+extrPos (Op2Expr p _ _ _) = p
+extrPos (Op1Expr p _ _) = p
+extrPos (IntExpr p _) = p
+extrPos (CharExpr p _) = p
+extrPos (BoolExpr p _) = p
+extrPos (FunExpr p _) = p
+extrPos (EmptyListExpr p) = p
+extrPos (TupleExpr p _) = p