401 lines
15 KiB
Haskell
401 lines
15 KiB
Haskell
{-# OPTIONS_GHC -W #-}
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module Generate.JavaScript (generate) where
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import Control.Arrow (first,(***))
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import Control.Applicative ((<$>),(<*>))
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import Control.Monad.State
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import qualified Data.List as List
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import qualified Data.Map as Map
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import qualified Data.Set as Set
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import qualified Generate.Cases as Case
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import qualified Generate.Markdown as MD
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import qualified SourceSyntax.Helpers as Help
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import SourceSyntax.Literal
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import SourceSyntax.Pattern as Pattern
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import SourceSyntax.Location
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import SourceSyntax.Expression
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import SourceSyntax.Module
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import Language.ECMAScript3.Syntax
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import Language.ECMAScript3.PrettyPrint
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import qualified Transform.SafeNames as MakeSafe
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split :: String -> [String]
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split = go []
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where
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go vars str =
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case break (=='.') str of
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(x,_:rest) | Help.isOp x -> vars ++ [x ++ '.' : rest]
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| otherwise -> go (vars ++ [x]) rest
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(x,[]) -> vars ++ [x]
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var name = Id () name
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ref name = VarRef () (var name)
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prop name = PropId () (var name)
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f <| x = CallExpr () f [x]
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args ==> e = FuncExpr () Nothing (map var args) [ ReturnStmt () (Just e) ]
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function args stmts = FuncExpr () Nothing (map var args) stmts
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call = CallExpr ()
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string = StringLit ()
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dotSep vars =
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case vars of
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x:xs -> foldl (DotRef ()) (ref x) (map var xs)
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[] -> error "dotSep must be called on a non-empty list of variables"
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obj = dotSep . split
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varDecl :: String -> Expression () -> VarDecl ()
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varDecl x expr =
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VarDecl () (var x) (Just expr)
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include alias moduleName =
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varDecl alias (obj (moduleName ++ ".make") <| ref "_elm")
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internalImports name =
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VarDeclStmt ()
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[ varDecl "_N" (obj "Elm.Native")
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, include "_U" "_N.Utils"
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, include "_L" "_N.List"
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, include "_E" "_N.Error"
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, include "_J" "_N.JavaScript"
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, varDecl "$moduleName" (string name)
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]
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literal :: Literal -> Expression ()
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literal lit =
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case lit of
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Chr c -> obj "_U.chr" <| string [c]
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Str s -> string s
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IntNum n -> IntLit () n
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FloatNum n -> NumLit () n
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Boolean b -> BoolLit () b
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expression :: LExpr -> State Int (Expression ())
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expression (L span expr) =
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case expr of
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Var x -> return $ ref x
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Literal lit -> return $ literal lit
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Range lo hi ->
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do lo' <- expression lo
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hi' <- expression hi
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return $ obj "_L.range" `call` [lo',hi']
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Access e x ->
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do e' <- expression e
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return $ DotRef () e' (var x)
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Remove e x ->
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do e' <- expression e
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return $ obj "_U.remove" `call` [string x, e']
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Insert e x v ->
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do v' <- expression v
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e' <- expression e
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return $ obj "_U.insert" `call` [string x, v', e']
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Modify e fs ->
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do e' <- expression e
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fs' <- forM fs $ \(f,v) -> do
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v' <- expression v
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return $ ArrayLit () [string f, v']
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return $ obj "_U.replace" `call` [ArrayLit () fs', e']
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Record fields ->
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do fields' <- forM fields $ \(f,e) -> do
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(,) f <$> expression e
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let fieldMap = List.foldl' combine Map.empty fields'
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return $ ObjectLit () $ (PropId () (var "_"), hidden fieldMap) : visible fieldMap
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where
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combine r (k,v) = Map.insertWith (++) k [v] r
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prop = PropId () . var
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hidden fs = ObjectLit () . map (prop *** ArrayLit ()) .
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Map.toList . Map.filter (not . null) $ Map.map tail fs
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visible fs = map (first prop) . Map.toList $ Map.map head fs
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Binop op e1 e2 -> binop span op e1 e2
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Lambda p e@(L s _) ->
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do (args, body) <- foldM depattern ([], innerBody) (reverse patterns)
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body' <- expression body
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return $ case length args < 2 || length args > 9 of
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True -> foldr (==>) body' (map (:[]) args)
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False -> ref ("F" ++ show (length args)) <| (args ==> body')
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where
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depattern (args, body) pattern =
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case pattern of
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PVar x -> return (args ++ [x], body)
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_ -> do arg <- Case.newVar
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return (args ++ [arg], L s (Case (L s (Var arg)) [(pattern, body)]))
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(patterns, innerBody) = collect [p] e
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collect patterns lexpr@(L _ expr) =
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case expr of
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Lambda p e -> collect (p:patterns) e
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_ -> (patterns, lexpr)
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App e1 e2 ->
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do func' <- expression func
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args' <- mapM expression args
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return $ case args' of
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[arg] -> func' <| arg
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_ | length args' <= 9 -> ref aN `call` (func':args')
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| otherwise -> foldl1 (<|) (func':args')
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where
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aN = "A" ++ show (length args)
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(func, args) = getArgs e1 [e2]
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getArgs func args =
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case func of
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(L _ (App f arg)) -> getArgs f (arg : args)
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_ -> (func, args)
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Let defs e ->
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do let (defs',e') = flattenLets defs e
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stmts <- concat <$> mapM definition defs'
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exp <- expression e'
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return $ function [] (stmts ++ [ ReturnStmt () (Just exp) ]) `call` []
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MultiIf branches ->
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do branches' <- forM branches $ \(b,e) -> (,) <$> expression b <*> expression e
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return $ case last branches of
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(L _ (Var "Basics.otherwise"), _) -> safeIfs branches'
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(L _ (Literal (Boolean True)), _) -> safeIfs branches'
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_ -> ifs branches' (obj "_E.If" `call` [ ref "$moduleName", string (show span) ])
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where
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safeIfs branches = ifs (init branches) (snd (last branches))
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ifs branches finally = foldr iff finally branches
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iff (if', then') else' = CondExpr () if' then' else'
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Case e cases ->
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do (tempVar,initialMatch) <- Case.toMatch cases
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(revisedMatch, stmt) <-
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case e of
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L _ (Var x) -> return (Case.matchSubst [(tempVar,x)] initialMatch, [])
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_ -> do e' <- expression e
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return (initialMatch, [VarDeclStmt () [varDecl tempVar e']])
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match' <- match span revisedMatch
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return (function [] (stmt ++ match') `call` [])
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ExplicitList es ->
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do es' <- mapM expression es
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return $ obj "_J.toList" <| ArrayLit () es'
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Data name es ->
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do es' <- mapM expression es
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return $ ObjectLit () (ctor : fields es')
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where
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ctor = (prop "ctor", string name)
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fields = zipWith (\n e -> (prop ("_" ++ show n), e)) [0..]
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Markdown uid doc es ->
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do es' <- mapM expression es
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return $ obj "Text.markdown" `call` (string md : string uid : es')
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where
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pad = "<div style=\"height:0;width:0;\"> </div>"
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md = pad ++ MD.toHtml doc ++ pad
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PortIn name _ _ handler ->
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do handler' <- expression handler
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return $ obj "Native.Ports.portIn" `call` [ string name, handler' ]
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PortOut name _ signal ->
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do signal' <- expression signal
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return $ obj "Native.Ports.portOut" `call` [ string name, signal' ]
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definition :: Def -> State Int [Statement ()]
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definition (Definition pattern expr@(L span _) _) = do
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expr' <- expression expr
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let assign x = varDecl x expr'
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case pattern of
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PVar x
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| Help.isOp x ->
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let op = LBracket () (ref "_op") (string x) in
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return [ ExprStmt () $ AssignExpr () OpAssign op expr' ]
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| otherwise ->
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return [ VarDeclStmt () [ assign x ] ]
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PRecord fields ->
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let setField f = varDecl f (dotSep ["$",f]) in
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return [ VarDeclStmt () (assign "$" : map setField fields) ]
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PData name patterns | vars /= Nothing ->
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return [ VarDeclStmt () (setup (zipWith decl (maybe [] id vars) [0..])) ]
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where
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vars = getVars patterns
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getVars patterns =
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case patterns of
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PVar x : rest -> (x:) `fmap` getVars rest
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[] -> Just []
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_ -> Nothing
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decl x n = varDecl x (dotSep ["$","_" ++ show n])
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setup vars
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| Help.isTuple name = assign "$" : vars
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| otherwise = assign "$raw" : safeAssign : vars
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safeAssign = varDecl "$" (CondExpr () if' (obj "$raw") exception)
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if' = InfixExpr () OpStrictEq (obj "$raw.ctor") (string name)
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exception = obj "_E.Case" `call` [ref "$moduleName", string (show span)]
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_ ->
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do defs' <- concat <$> mapM toDef vars
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return (VarDeclStmt () [assign "$"] : defs')
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where
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vars = Set.toList $ Pattern.boundVars pattern
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mkVar = L span . Var
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toDef y = let expr = L span $ Case (mkVar "$") [(pattern, mkVar y)]
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in definition $ Definition (PVar y) expr Nothing
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match :: (Show a) => a -> Case.Match -> State Int [Statement ()]
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match span mtch =
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case mtch of
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Case.Match name clauses mtch' ->
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do (isChars, clauses') <- unzip <$> mapM (clause span name) clauses
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mtch'' <- match span mtch'
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return (SwitchStmt () (format isChars (access name)) clauses' : mtch'')
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where
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isLiteral p = case p of
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Case.Clause (Right _) _ _ -> True
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_ -> False
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access name = if any isLiteral clauses then ref name else dotSep [name,"ctor"]
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format isChars e
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| or isChars = InfixExpr () OpAdd e (string "")
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| otherwise = e
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Case.Fail ->
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return [ ExprStmt () (obj "_E.Case" `call` [ref "$moduleName", string (show span)]) ]
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Case.Break -> return [BreakStmt () Nothing]
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Case.Other e ->
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do e' <- expression e
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return [ ReturnStmt () (Just e') ]
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Case.Seq ms -> concat <$> mapM (match span) (dropEnd [] ms)
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where
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dropEnd acc [] = acc
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dropEnd acc (m:ms) =
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case m of
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Case.Other _ -> acc ++ [m]
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_ -> dropEnd (acc ++ [m]) ms
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clause span variable (Case.Clause value vars mtch) =
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(,) isChar . CaseClause () pattern <$> match span (Case.matchSubst (zip vars vars') mtch)
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where
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vars' = map (\n -> variable ++ "._" ++ show n) [0..]
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(isChar, pattern) =
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case value of
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Right (Chr c) -> (True, string [c])
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_ -> (,) False $ case value of
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Right (Boolean b) -> BoolLit () b
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Right lit -> literal lit
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Left name -> string $ case List.elemIndices '.' name of
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[] -> name
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is -> drop (last is + 1) name
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flattenLets defs lexpr@(L _ expr) =
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case expr of
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Let ds body -> flattenLets (defs ++ ds) body
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_ -> (defs, lexpr)
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generate :: MetadataModule -> String
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generate unsafeModule =
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show . prettyPrint $ setup (Just "Elm") (names modul ++ ["make"]) ++
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[ assign ("Elm" : names modul ++ ["make"]) (function ["_elm"] programStmts) ]
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where
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modul = MakeSafe.metadataModule unsafeModule
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thisModule = dotSep ("_elm" : names modul ++ ["values"])
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programStmts =
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concat
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[ setup (Just "_elm") (names modul ++ ["values"])
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, [ IfSingleStmt () thisModule (ReturnStmt () (Just thisModule)) ]
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, [ internalImports (List.intercalate "." (names modul)) ]
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, concatMap jsImport . Set.toList . Set.fromList . map fst $ imports modul
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, [ assign ["_op"] (ObjectLit () []) ]
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, concat $ evalState (mapM definition . fst . flattenLets [] $ program modul) 0
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, [ jsExports ]
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, [ ReturnStmt () (Just thisModule) ]
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]
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jsExports = assign ("_elm" : names modul ++ ["values"]) (ObjectLit () exs)
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where
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exs = map entry . filter (not . Help.isOp) $ "_op" : exports modul
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entry x = (PropId () (var x), ref x)
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assign path expr =
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case path of
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[x] -> VarDeclStmt () [ varDecl x expr ]
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_ -> ExprStmt () $
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AssignExpr () OpAssign (LDot () (dotSep (init path)) (last path)) expr
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jsImport modul = setup Nothing path ++ [ include ]
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where
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path = split modul
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include = assign path $ dotSep ("Elm" : path ++ ["make"]) <| ref "_elm"
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setup namespace path = map create paths
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where
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create name = assign name (InfixExpr () OpLOr (dotSep name) (ObjectLit () []))
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paths = case namespace of
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Nothing -> tail . init $ List.inits path
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Just nmspc -> drop 2 . init . List.inits $ nmspc : path
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binop span op e1 e2 =
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case op of
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"Basics.." ->
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do es <- mapM expression (e1 : collect [] e2)
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return $ ["$"] ==> foldr (<|) (ref "$") es
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"Basics.<|" ->
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do e2' <- expression e2
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es <- mapM expression (collect [] e1)
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return $ foldr (<|) e2' es
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"List.++" ->
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do e1' <- expression e1
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e2' <- expression e2
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return $ obj "_L.append" `call` [e1', e2']
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"::" -> expression (L span (Data "::" [e1,e2]))
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_ ->
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do e1' <- expression e1
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e2' <- expression e2
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return $ case Map.lookup op opDict of
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Just f -> f e1' e2'
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Nothing -> ref "A2" `call` [ func, e1', e2' ]
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where
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collect es e =
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case e of
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L _ (Binop op e1 e2) | op == "Basics.." -> collect (es ++ [e1]) e2
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_ -> es ++ [e]
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func | Help.isOp operator = BracketRef () (dotSep (init parts ++ ["_op"])) (string operator)
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| otherwise = dotSep parts
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where
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parts = split op
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operator = last parts
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opDict = Map.fromList (infixOps ++ specialOps)
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specialOp str func = [ (str, func), ("Basics." ++ str, func) ]
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infixOp str op = specialOp str (InfixExpr () op)
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infixOps = concat
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[ infixOp "+" OpAdd
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, infixOp "-" OpSub
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, infixOp "*" OpMul
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, infixOp "/" OpDiv
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, infixOp "&&" OpLAnd
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, infixOp "||" OpLOr
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]
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specialOps = concat
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[ specialOp "^" $ \a b -> obj "Math.pow" `call` [a,b]
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, specialOp "|>" $ flip (<|)
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, specialOp "==" $ \a b -> obj "_U.eq" `call` [a,b]
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, specialOp "/=" $ \a b -> PrefixExpr () PrefixLNot (obj "_U.eq" `call` [a,b])
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, specialOp "<" $ cmp OpLT 0
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, specialOp ">" $ cmp OpGT 0
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, specialOp "<=" $ cmp OpLT 1
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, specialOp ">=" $ cmp OpGT (-1)
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, specialOp "div" $ \a b -> InfixExpr () OpBOr (InfixExpr () OpDiv a b) (IntLit () 0)
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]
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cmp op n a b = InfixExpr () op (obj "_U.cmp" `call` [a,b]) (IntLit () n)
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