{-|
Module      : IRTS.CodegenJavaScript
Description : The JavaScript code generator.
Copyright   :
License     : BSD3
Maintainer  : The Idris Community.
-}
{-# LANGUAGE PatternGuards #-}
{-# LANGUAGE OverloadedStrings #-}
module IRTS.CodegenJavaScript (codegenJavaScript
                             , codegenNode
                             , JSTarget(..)
                             ) where

import IRTS.JavaScript.AST

import Idris.AbsSyntax hiding (TypeCase)
import IRTS.Bytecode
import IRTS.Lang
import IRTS.Exports
import IRTS.Simplified
import IRTS.Defunctionalise
import IRTS.CodegenCommon
import Idris.Core.TT
import IRTS.System
import Util.System

import Control.Arrow
import Control.Monad (mapM)
import Control.Applicative ((<$>), (<*>), pure)
import Control.Monad.RWS hiding (mapM)
import Control.Monad.State
import Data.Char
import Numeric
import Data.List
import Data.Maybe
import Data.Word
import Data.Traversable hiding (mapM)
import System.IO
import System.Directory
import System.FilePath

import qualified Data.Map.Strict as M
import qualified Data.Text as T
import qualified Data.Text.IO as TIO


data CompileInfo = CompileInfo { compileInfoApplyCases  :: [Int]
                               , compileInfoEvalCases   :: [Int]
                               , compileInfoNeedsBigInt :: Bool
                               }


initCompileInfo :: [(Name, [BC])] -> CompileInfo
initCompileInfo bc =
  CompileInfo (collectCases "APPLY" bc) (collectCases "EVAL" bc) (lookupBigInt bc)
  where
    lookupBigInt :: [(Name, [BC])] -> Bool
    lookupBigInt = any (needsBigInt . snd)
      where
        needsBigInt :: [BC] -> Bool
        needsBigInt bc = any testBCForBigInt bc
          where
            testBCForBigInt :: BC -> Bool
            testBCForBigInt (ASSIGNCONST _ c)  =
              testConstForBigInt c

            testBCForBigInt (CONSTCASE _ c d) =
                 maybe False needsBigInt d
              || any (needsBigInt . snd) c
              || any (testConstForBigInt . fst) c

            testBCForBigInt (CASE _ _ c d) =
                 maybe False needsBigInt d
              || any (needsBigInt . snd) c

            testBCForBigInt _ = False

            testConstForBigInt :: Const -> Bool
            testConstForBigInt (BI _)  = True
            testConstForBigInt (B64 _) = True
            testConstForBigInt _       = False


    collectCases :: String ->  [(Name, [BC])] -> [Int]
    collectCases fun bc = getCases $ findFunction fun bc

    findFunction :: String -> [(Name, [BC])] -> [BC]
    findFunction f ((MN 0 fun, bc):_)
      | fun == txt f = bc
    findFunction f (_:bc) = findFunction f bc

    getCases :: [BC] -> [Int]
    getCases = concatMap analyze
      where
        analyze :: BC -> [Int]
        analyze (CASE _ _ b _) = map fst b
        analyze _              = []


data JSTarget = Node | JavaScript deriving Eq


codegenJavaScript :: CodeGenerator
codegenJavaScript ci =
  codegenJS_all JavaScript (simpleDecls ci)
    (includes ci) [] (outputFile ci) (exportDecls ci) (outputType ci)

codegenNode :: CodeGenerator
codegenNode ci =
  codegenJS_all Node (simpleDecls ci)
    (includes ci) (compileLibs ci) (outputFile ci) (exportDecls ci) (outputType ci)

codegenJS_all
  :: JSTarget
  -> [(Name, SDecl)]
  -> [FilePath]
  -> [String]
  -> FilePath
  -> [ExportIFace]
  -> OutputType
  -> IO ()
codegenJS_all target definitions includes libs filename exports outputType = do
  let bytecode = map toBC definitions
  let info = initCompileInfo bytecode
  let js = concatMap (translateDecl info) bytecode
  let full = concatMap processFunction js
  let exportedNames = map translateName ((getExpNames exports) ++ [sUN "call__IO"])
  let code = deadCodeElim exportedNames full
  let ext = takeExtension filename
  let isHtml = target == JavaScript && ext == ".html"
  let htmlPrologue = T.pack "<!doctype html><html><head><script>\n"
  let htmlEpilogue = T.pack "\n</script></head><body></body></html>"
  let (cons, opt) = optimizeConstructors code
  let (header, rt) = case target of
                          Node -> ("#!/usr/bin/env node\n", "-node")
                          JavaScript -> ("", "-browser")

  included   <- concat <$> getIncludes includes
  path       <- (++) <$> getDataDir <*> (pure "/jsrts/")
  idrRuntime <- readFile $ path ++ "Runtime-common.js"
  tgtRuntime <- readFile $ concat [path, "Runtime", rt, ".js"]
  jsbn       <- if compileInfoNeedsBigInt info
                   then readFile $ path ++ "jsbn/jsbn.js"
                   else return ""
  let runtime = (  header
                ++ includeLibs libs
                ++ included
                ++ jsbn
                ++ idrRuntime
                ++ tgtRuntime
                )
  let jsSource = T.pack runtime
                 `T.append` T.concat (map compileJS opt)
                 `T.append` T.concat (map compileJS cons)
                 `T.append` T.concat (map compileJS (map genInterface (concatMap getExps exports)))
                 `T.append` main
                 `T.append` invokeMain
  let source = if isHtml
                    then htmlPrologue `T.append` jsSource `T.append` htmlEpilogue
                    else jsSource
  writeSourceText filename source
  setPermissions filename (emptyPermissions { readable   = True
                                            , executable = target == Node
                                            , writable   = True
                                            })
    where
      deadCodeElim :: [String] -> [JS] -> [JS]
      deadCodeElim exports js = concatMap (collectFunctions exports) js
        where
          collectFunctions :: [String] -> JS -> [JS]
          collectFunctions _ fun@(JSAlloc name _)
            | name == translateName (sMN 0 "runMain") = [fun]

          collectFunctions exports fun@(JSAlloc name _)
            | name `elem` exports = [fun]

          collectFunctions _ fun@(JSAlloc name (Just (JSFunction _ body))) =
            let invokations = sum $ map (
                    \x -> execState (countInvokations name x) 0
                  ) js
             in if invokations == 0
                   then []
                   else [fun]

          countInvokations :: String -> JS -> State Int ()
          countInvokations name (JSAlloc _ (Just (JSFunction _ body))) =
            countInvokations name body

          countInvokations name (JSSeq seq) =
            void $ traverse (countInvokations name) seq

          countInvokations name (JSAssign _ rhs) =
            countInvokations name rhs

          countInvokations name (JSCond conds) =
            void $ traverse (
                runKleisli $ arr id *** Kleisli (countInvokations name)
              ) conds

          countInvokations name (JSSwitch _ conds def) =
            void $ traverse (
              runKleisli $ arr id *** Kleisli (countInvokations name)
            ) conds >> traverse (countInvokations name) def

          countInvokations name (JSApp lhs rhs) =
            void $ countInvokations name lhs >> traverse (countInvokations name) rhs

          countInvokations name (JSNew _ args) =
            void $ traverse (countInvokations name) args

          countInvokations name (JSArray args) =
            void $ traverse (countInvokations name) args

          countInvokations name (JSIdent name')
            | name == name' = get >>= put . (+1)
            | otherwise     = return ()

          countInvokations _ _ = return ()

      processFunction :: JS -> [JS]
      processFunction =
        collectSplitFunctions . (\x -> evalRWS (splitFunction x) () 0)

      includeLibs :: [String] -> String
      includeLibs =
        concatMap (\lib -> "var " ++ lib ++ " = require(\"" ++ lib ++"\");\n")

      getIncludes :: [FilePath] -> IO [String]
      getIncludes = mapM readFile

      main :: T.Text
      main =
        compileJS $ JSAlloc "main" (Just $
          JSFunction [] (
            case target of
                 Node       -> mainFun
                 JavaScript -> jsMain
          )
        )

      jsMain :: JS
      jsMain =
        JSCond [ (exists document `jsAnd` isReady, mainFun)
               , (exists window, windowMainFun)
               , (JSTrue, mainFun)
               ]
        where
          exists :: JS -> JS
          exists js = jsTypeOf js `jsNotEq` JSString "undefined"

          window :: JS
          window = JSIdent "window"

          document :: JS
          document = JSIdent "document"

          windowMainFun :: JS
          windowMainFun =
            jsMeth window "addEventListener" [ JSString "DOMContentLoaded"
                                             , JSFunction [] ( mainFun )
                                             , JSFalse
                                             ]

          isReady :: JS
          isReady = JSParens $ readyState `jsEq` JSString "complete" `jsOr` readyState `jsEq` JSString "loaded"

          readyState :: JS
          readyState = JSProj (JSIdent "document") "readyState"

      mainFun :: JS
      mainFun =
        JSSeq [ JSAlloc "vm" (Just $ JSNew "i$VM" [])
              , JSApp (JSIdent "i$SCHED") [JSIdent "vm"]
              , JSApp (
                  JSIdent (translateName (sMN 0 "runMain"))
                ) [JSNew "i$POINTER" [JSNum (JSInt 0)]]
              , JSApp (JSIdent "i$RUN") []
              ]

      invokeMain :: T.Text
      invokeMain = compileJS $ JSApp (JSIdent "main") []
      getExps (Export _ _ exp) = exp

optimizeConstructors :: [JS] -> ([JS], [JS])
optimizeConstructors js =
    let (js', cons) = runState (traverse optimizeConstructor' js) M.empty in
        (map (allocCon . snd) (M.toList cons), js')
  where
    allocCon :: (String, JS) -> JS
    allocCon (name, con) = JSAlloc name (Just con)

    newConstructor :: Int -> String
    newConstructor n = "i$CON$" ++ show n

    optimizeConstructor' :: JS -> State (M.Map Int (String, JS)) JS
    optimizeConstructor' js@(JSNew "i$CON" [ JSNum (JSInt tag)
                                           , JSArray []
                                           , a
                                           , e
                                           ]) = do
      s <- get
      case M.lookup tag s of
           Just (i, c) -> return $ JSIdent i
           Nothing     -> do let n = newConstructor tag
                             put $ M.insert tag (n, js) s
                             return $ JSIdent n

    optimizeConstructor' (JSSeq seq) =
      JSSeq <$> traverse optimizeConstructor' seq

    optimizeConstructor' (JSSwitch reg cond def) = do
      cond' <- traverse (runKleisli $ arr id *** Kleisli optimizeConstructor') cond
      def'  <- traverse optimizeConstructor' def
      return $ JSSwitch reg cond' def'

    optimizeConstructor' (JSCond cond) =
      JSCond <$> traverse (runKleisli $ arr id *** Kleisli optimizeConstructor') cond

    optimizeConstructor' (JSAlloc fun (Just (JSFunction args body))) = do
      body' <- optimizeConstructor' body
      return $ JSAlloc fun (Just (JSFunction args body'))

    optimizeConstructor' (JSAssign lhs rhs) = do
      lhs' <- optimizeConstructor' lhs
      rhs' <- optimizeConstructor' rhs
      return $ JSAssign lhs' rhs'

    optimizeConstructor' js = return js

collectSplitFunctions :: (JS, [(Int,JS)]) -> [JS]
collectSplitFunctions (fun, splits) = map generateSplitFunction splits ++ [fun]
  where
    generateSplitFunction :: (Int,JS) -> JS
    generateSplitFunction (depth, JSAlloc name fun) =
      JSAlloc (name ++ "$" ++ show depth) fun

splitFunction :: JS -> RWS () [(Int,JS)] Int JS
splitFunction (JSAlloc name (Just (JSFunction args body@(JSSeq _)))) = do
  body' <- splitSequence body
  return $ JSAlloc name (Just (JSFunction args body'))
    where
      splitCondition :: JS -> RWS () [(Int,JS)] Int JS
      splitCondition js
        | JSCond branches <- js =
            JSCond <$> processBranches branches
        | JSSwitch cond branches def <- js =
            JSSwitch cond <$> (processBranches branches) <*> (traverse splitSequence def)
        | otherwise = return js
        where
          processBranches :: [(JS,JS)] -> RWS () [(Int,JS)] Int [(JS,JS)]
          processBranches =
            traverse (runKleisli (arr id *** Kleisli splitSequence))

      splitSequence :: JS -> RWS () [(Int, JS)] Int JS
      splitSequence js@(JSSeq seq) =
        let (pre,post) = break isBranch seq in
            case post of
                 [_] -> JSSeq <$> traverse splitCondition seq
                 [call@(JSCond _),rest@(JSApp _ _)]     -> do
                   rest' <- splitCondition rest
                   call' <- splitCondition call
                   return $ JSSeq (pre ++ [rest', call'])
                 [call@(JSSwitch _ _ _),rest@(JSApp _ _)] -> do
                   rest' <- splitCondition rest
                   call' <- splitCondition call
                   return $ JSSeq (pre ++ [rest', call'])
                 (call:rest) -> do
                   depth <- get
                   put (depth + 1)
                   new <- splitFunction (newFun rest)
                   tell [(depth, new)]
                   call' <- splitCondition call
                   return $ JSSeq (pre ++ (newCall depth : [call']))
                 _ -> JSSeq <$> traverse splitCondition seq

      splitSequence js = return js

      isBranch :: JS -> Bool
      isBranch (JSApp (JSIdent "i$CALL") _) = True
      isBranch (JSCond _)                   = True
      isBranch (JSSwitch _ _ _)             = True
      isBranch _                            = False

      newCall :: Int -> JS
      newCall depth =
        JSApp (JSIdent "i$CALL") [ JSIdent $ name ++ "$" ++ show depth
                                 , JSArray [jsOLDBASE, jsMYOLDBASE]
                                 ]

      newFun :: [JS] -> JS
      newFun seq =
        JSAlloc name (Just $ JSFunction ["oldbase", "myoldbase"] (JSSeq seq))

splitFunction js = return js

translateDecl :: CompileInfo -> (Name, [BC]) -> [JS]
translateDecl info (name@(MN 0 fun), bc)
  | txt "APPLY" == fun =
         allocCaseFunctions (snd body)
      ++ [ JSAlloc (
               translateName name
           ) (Just $ JSFunction ["oldbase"] (
               JSSeq $ jsFUNPRELUDE ++ map (translateBC info) (fst body) ++ [
                 JSCond [ ( (translateReg $ caseReg (snd body)) `jsInstanceOf` "i$CON" `jsAnd` (JSProj (translateReg $ caseReg (snd body)) "app")
                          , JSApp (JSProj (translateReg $ caseReg (snd body)) "app") [jsOLDBASE, jsMYOLDBASE]
                          )
                          , ( JSNoop
                            , JSSeq $ map (translateBC info) (defaultCase (snd body))
                            )
                        ]
               ]
             )
           )
         ]

  | txt "EVAL" == fun =
         allocCaseFunctions (snd body)
      ++ [ JSAlloc (
               translateName name
           ) (Just $ JSFunction ["oldbase"] (
               JSSeq $ jsFUNPRELUDE ++ map (translateBC info) (fst body) ++ [
                 JSCond [ ( (translateReg $ caseReg (snd body)) `jsInstanceOf` "i$CON" `jsAnd` (JSProj (translateReg $ caseReg (snd body)) "ev")
                          , JSApp (JSProj (translateReg $ caseReg (snd body)) "ev") [jsOLDBASE, jsMYOLDBASE]
                          )
                          , ( JSNoop
                            , JSSeq $ map (translateBC info) (defaultCase (snd body))
                            )
                        ]
               ]
             )
           )
         ]
  where
    body :: ([BC], [BC])
    body = break isCase bc

    isCase :: BC -> Bool
    isCase bc
      | CASE {} <- bc = True
      | otherwise          = False

    defaultCase :: [BC] -> [BC]
    defaultCase ((CASE _ _ _ (Just d)):_) = d

    caseReg :: [BC] -> Reg
    caseReg ((CASE _ r _ _):_) = r

    allocCaseFunctions :: [BC] -> [JS]
    allocCaseFunctions ((CASE _ _ c _):_) = splitBranches c
    allocCaseFunctions _                  = []

    splitBranches :: [(Int, [BC])] -> [JS]
    splitBranches = map prepBranch

    prepBranch :: (Int, [BC]) -> JS
    prepBranch (tag, code) =
      JSAlloc (
        translateName name ++ "$" ++ show tag
      ) (Just $ JSFunction ["oldbase", "myoldbase"] (
          JSSeq $ map (translateBC info) code
        )
      )

translateDecl info (name, bc) =
  [ JSAlloc (
       translateName name
     ) (Just $ JSFunction ["oldbase"] (
         JSSeq $ jsFUNPRELUDE ++ map (translateBC info)bc
       )
     )
  ]

jsFUNPRELUDE :: [JS]
jsFUNPRELUDE = [jsALLOCMYOLDBASE]

jsALLOCMYOLDBASE :: JS
jsALLOCMYOLDBASE = JSAlloc "myoldbase" (Just $ JSNew "i$POINTER" [])

translateReg :: Reg -> JS
translateReg reg
  | RVal <- reg = jsRET
  | Tmp  <- reg = JSRaw "//TMPREG"
  | L n  <- reg = jsLOC n
  | T n  <- reg = jsTOP n

translateConstant :: Const -> JS
translateConstant (I i)                    = JSNum (JSInt i)
translateConstant (Fl f)                   = JSNum (JSFloat f)
translateConstant (Ch c)                   = JSString $ translateChar c
translateConstant (Str s)                  = JSString $ concatMap translateChar s
translateConstant (AType (ATInt ITNative)) = JSType JSIntTy
translateConstant StrType                  = JSType JSStringTy
translateConstant (AType (ATInt ITBig))    = JSType JSIntegerTy
translateConstant (AType ATFloat)          = JSType JSFloatTy
translateConstant (AType (ATInt ITChar))   = JSType JSCharTy
translateConstant Forgot                   = JSType JSForgotTy
translateConstant (BI 0)                   = JSNum (JSInteger JSBigZero)
translateConstant (BI 1)                   = JSNum (JSInteger JSBigOne)
translateConstant (BI i)                   = jsBigInt (JSString $ show i)
translateConstant (B8 b)                   = JSWord (JSWord8 b)
translateConstant (B16 b)                  = JSWord (JSWord16 b)
translateConstant (B32 b)                  = JSWord (JSWord32 b)
translateConstant (B64 b)                  = JSWord (JSWord64 b)
translateConstant c =
  JSError $ "Unimplemented Constant: " ++ show c


translateChar :: Char -> String
translateChar ch
  | '\a'   <- ch       = "\\u0007"
  | '\b'   <- ch       = "\\b"
  | '\f'   <- ch       = "\\f"
  | '\n'   <- ch       = "\\n"
  | '\r'   <- ch       = "\\r"
  | '\t'   <- ch       = "\\t"
  | '\v'   <- ch       = "\\v"
  | '\SO'  <- ch       = "\\u000E"
  | '\DEL' <- ch       = "\\u007F"
  | '\\'   <- ch       = "\\\\"
  | '\"'   <- ch       = "\\\""
  | '\''   <- ch       = "\\\'"
  | ch `elem` asciiTab = "\\u" ++ fill (showHex (ord ch) "")
  | ord ch > 255       = "\\u" ++ fill (showHex (ord ch) "")
  | otherwise          = [ch]
  where
    fill :: String -> String
    fill s = case length s of
                  1 -> "000" ++ s
                  2 -> "00"  ++ s
                  3 -> "0"   ++ s
                  _ ->          s

    asciiTab =
      ['\NUL', '\SOH', '\STX', '\ETX', '\EOT', '\ENQ', '\ACK', '\BEL',
       '\BS',  '\HT',  '\LF',  '\VT',  '\FF',  '\CR',  '\SO',  '\SI',
       '\DLE', '\DC1', '\DC2', '\DC3', '\DC4', '\NAK', '\SYN', '\ETB',
       '\CAN', '\EM',  '\SUB', '\ESC', '\FS',  '\GS',  '\RS',  '\US']

translateName :: Name -> String
translateName n = "_idris_" ++ concatMap cchar (showCG n)
  where cchar x | isAlphaNum x = [x]
                | otherwise    = "_" ++ show (fromEnum x) ++ "_"

jsASSIGN :: CompileInfo -> Reg -> Reg -> JS
jsASSIGN _ r1 r2 = JSAssign (translateReg r1) (translateReg r2)

jsASSIGNCONST :: CompileInfo -> Reg -> Const -> JS
jsASSIGNCONST _ r c = JSAssign (translateReg r) (translateConstant c)

jsCALL :: CompileInfo -> Name -> JS
jsCALL _ n =
  JSApp (
    JSIdent "i$CALL"
  ) [JSIdent (translateName n), JSArray [jsMYOLDBASE]]

jsTAILCALL :: CompileInfo -> Name -> JS
jsTAILCALL _ n =
  JSApp (
    JSIdent "i$CALL"
  ) [JSIdent (translateName n), JSArray [jsOLDBASE]]

jsFOREIGN :: CompileInfo -> Reg -> String -> [(FType, Reg)] -> JS
jsFOREIGN _ reg n args
  | n == "isNull"
  , [(FPtr, arg)] <- args =
      JSAssign (
        translateReg reg
      ) (
        JSBinOp "==" (translateReg arg) JSNull
      )

  | n == "idris_eqPtr"
  , [(_, lhs),(_, rhs)] <- args =
      JSAssign (
        translateReg reg
      ) (
        JSBinOp "==" (translateReg lhs) (translateReg rhs)
      )
  | otherwise =
     JSAssign (
       translateReg reg
     ) (
       JSFFI n (map generateWrapper args)
     )
    where
      generateWrapper :: (FType, Reg) -> JS
      generateWrapper (ty, reg)
        | FFunction   <- ty =
            JSApp (JSIdent "i$ffiWrap") [ translateReg reg
                                        , JSIdent "oldbase"
                                        , JSIdent "myoldbase"
                                        ]
        | FFunctionIO <- ty =
            JSApp (JSIdent "i$ffiWrap") [ translateReg reg
                                        , JSIdent "oldbase"
                                        , JSIdent "myoldbase"
                                        ]

      generateWrapper (_, reg) =
        translateReg reg

jsREBASE :: CompileInfo -> JS
jsREBASE _ = JSAssign jsSTACKBASE (JSProj jsOLDBASE "addr")

jsSTOREOLD :: CompileInfo ->JS
jsSTOREOLD _ = JSAssign (JSProj jsMYOLDBASE "addr") jsSTACKBASE

jsADDTOP :: CompileInfo -> Int -> JS
jsADDTOP info n
  | 0 <- n    = JSNoop
  | otherwise =
      JSBinOp "+=" jsSTACKTOP (JSNum (JSInt n))

jsTOPBASE :: CompileInfo -> Int -> JS
jsTOPBASE _ 0  = JSAssign jsSTACKTOP jsSTACKBASE
jsTOPBASE _ n  = JSAssign jsSTACKTOP (JSBinOp "+" jsSTACKBASE (JSNum (JSInt n)))


jsBASETOP :: CompileInfo -> Int -> JS
jsBASETOP _ 0 = JSAssign jsSTACKBASE jsSTACKTOP
jsBASETOP _ n = JSAssign jsSTACKBASE (JSBinOp "+" jsSTACKTOP (JSNum (JSInt n)))

jsNULL :: CompileInfo -> Reg -> JS
jsNULL _ r = JSClear (translateReg r)

jsERROR :: CompileInfo -> String -> JS
jsERROR _ = JSError

jsSLIDE :: CompileInfo -> Int -> JS
jsSLIDE _ 1 = JSAssign (jsLOC 0) (jsTOP 0)
jsSLIDE _ n = JSApp (JSIdent "i$SLIDE") [JSNum (JSInt n)]

jsMKCON :: CompileInfo -> Reg -> Int -> [Reg] -> JS
jsMKCON info r t rs =
  JSAssign (translateReg r) (
    JSNew "i$CON" [ JSNum (JSInt t)
                  , JSArray (map translateReg rs)
                  , if t `elem` compileInfoApplyCases info
                       then JSIdent $ translateName (sMN 0 "APPLY") ++ "$" ++ show t
                       else JSNull
                  , if t `elem` compileInfoEvalCases info
                       then JSIdent $ translateName (sMN 0 "EVAL") ++ "$" ++ show t
                       else JSNull
                  ]
  )

jsCASE :: CompileInfo -> Bool -> Reg -> [(Int, [BC])] -> Maybe [BC] -> JS
jsCASE info safe reg cases def =
  JSSwitch (tag safe $ translateReg reg) (
    map ((JSNum . JSInt) *** prepBranch) cases
  ) (fmap prepBranch def)
    where
      tag :: Bool -> JS -> JS
      tag True  = jsCTAG
      tag False = jsTAG

      prepBranch :: [BC] -> JS
      prepBranch bc = JSSeq $ map (translateBC info) bc

      jsTAG :: JS -> JS
      jsTAG js =
        (JSTernary (js `jsInstanceOf` "i$CON") (
          JSProj js "tag"
        ) (JSNum (JSInt $ negate 1)))

      jsCTAG :: JS -> JS
      jsCTAG js = JSProj js "tag"


jsCONSTCASE :: CompileInfo -> Reg -> [(Const, [BC])] -> Maybe [BC] -> JS
jsCONSTCASE info reg cases def =
  JSCond $ (
    map (jsEq (translateReg reg) . translateConstant *** prepBranch) cases
  ) ++ (maybe [] ((:[]) . ((,) JSNoop) . prepBranch) def)
    where
      prepBranch :: [BC] -> JS
      prepBranch bc = JSSeq $ map (translateBC info) bc

jsPROJECT :: CompileInfo -> Reg -> Int -> Int -> JS
jsPROJECT _ reg loc 0  = JSNoop
jsPROJECT _ reg loc 1  =
  JSAssign (jsLOC loc) (
    JSIndex (
      JSProj (translateReg reg) "args"
    ) (
      JSNum (JSInt 0)
    )
  )
jsPROJECT _ reg loc ar =
  JSApp (JSIdent "i$PROJECT") [ translateReg reg
                              , JSNum (JSInt loc)
                              , JSNum (JSInt ar)
                              ]

jsOP :: CompileInfo -> Reg -> PrimFn -> [Reg] -> JS
jsOP _ reg op args = JSAssign (translateReg reg) jsOP'
  where
    jsOP' :: JS
    jsOP'
      | LNoOp <- op = translateReg (last args)

      | LWriteStr <- op,
        (_:str:_) <- args = JSApp (JSIdent "i$putStr") [translateReg str]

      | LReadStr <- op  = JSApp (JSIdent "i$getLine") []

      | (LZExt (ITFixed IT8) ITNative)  <- op = jsUnPackBits $ translateReg (last args)
      | (LZExt (ITFixed IT16) ITNative) <- op = jsUnPackBits $ translateReg (last args)
      | (LZExt (ITFixed IT32) ITNative) <- op = jsUnPackBits $ translateReg (last args)

      | (LZExt _ ITBig)        <- op = jsBigInt $ JSApp  (JSIdent "String") [translateReg (last args)]
      | (LPlus (ATInt ITBig))  <- op
      , (lhs:rhs:_)            <- args = invokeMeth lhs "add" [rhs]
      | (LMinus (ATInt ITBig)) <- op
      , (lhs:rhs:_)            <- args = invokeMeth lhs "subtract" [rhs]
      | (LTimes (ATInt ITBig)) <- op
      , (lhs:rhs:_)            <- args = invokeMeth lhs "multiply" [rhs]
      | (LSDiv (ATInt ITBig))  <- op
      , (lhs:rhs:_)            <- args = invokeMeth lhs "divide" [rhs]
      | (LSRem (ATInt ITBig))  <- op
      , (lhs:rhs:_)            <- args = invokeMeth lhs "mod" [rhs]
      | (LEq (ATInt ITBig))    <- op
      , (lhs:rhs:_)            <- args = JSPreOp "+" $ invokeMeth lhs "equals" [rhs]
      | (LSLt (ATInt ITBig))   <- op
      , (lhs:rhs:_)            <- args = JSPreOp "+" $ invokeMeth lhs "lesser" [rhs]
      | (LSLe (ATInt ITBig))   <- op
      , (lhs:rhs:_)            <- args = JSPreOp "+" $ invokeMeth lhs "lesserOrEquals" [rhs]
      | (LSGt (ATInt ITBig))   <- op
      , (lhs:rhs:_)            <- args = JSPreOp "+" $ invokeMeth lhs "greater" [rhs]
      | (LSGe (ATInt ITBig))   <- op
      , (lhs:rhs:_)            <- args = JSPreOp "+" $ invokeMeth lhs "greaterOrEquals" [rhs]

      | (LPlus ATFloat)  <- op
      , (lhs:rhs:_)      <- args = translateBinaryOp "+" lhs rhs
      | (LMinus ATFloat) <- op
      , (lhs:rhs:_)      <- args = translateBinaryOp "-" lhs rhs
      | (LTimes ATFloat) <- op
      , (lhs:rhs:_)      <- args = translateBinaryOp "*" lhs rhs
      | (LSDiv ATFloat)  <- op
      , (lhs:rhs:_)      <- args = translateBinaryOp "/" lhs rhs
      | (LEq ATFloat)    <- op
      , (lhs:rhs:_)      <- args = translateCompareOp "==" lhs rhs
      | (LSLt ATFloat)   <- op
      , (lhs:rhs:_)      <- args = translateCompareOp "<" lhs rhs
      | (LSLe ATFloat)   <- op
      , (lhs:rhs:_)      <- args = translateCompareOp "<=" lhs rhs
      | (LSGt ATFloat)   <- op
      , (lhs:rhs:_)      <- args = translateCompareOp ">" lhs rhs
      | (LSGe ATFloat)   <- op
      , (lhs:rhs:_)      <- args = translateCompareOp ">=" lhs rhs

      | (LPlus (ATInt ITChar)) <- op
      , (lhs:rhs:_)            <- args =
          jsCall "i$fromCharCode" [
            JSBinOp "+" (
              jsCall "i$charCode" [translateReg lhs]
            ) (
              jsCall "i$charCode" [translateReg rhs]
            )
          ]

      | (LTrunc (ITFixed IT16) (ITFixed IT8)) <- op
      , (arg:_)                               <- args =
          jsPackUBits8 (
            JSBinOp "&" (jsUnPackBits $ translateReg arg) (JSNum (JSInt 0xFF))
          )

      | (LTrunc (ITFixed IT32) (ITFixed IT16)) <- op
      , (arg:_)                                <- args =
          jsPackUBits16 (
            JSBinOp "&" (jsUnPackBits $ translateReg arg) (JSNum (JSInt 0xFFFF))
          )

      | (LTrunc (ITFixed IT64) (ITFixed IT32)) <- op
      , (arg:_)                                <- args =
          jsPackUBits32 (
            jsMeth (jsMeth (translateReg arg) "and" [
              jsBigInt (JSString $ show 0xFFFFFFFF)
            ]) "intValue" []
          )

      | (LTrunc ITBig (ITFixed IT64)) <- op
      , (arg:_)                       <- args =
          jsMeth (translateReg arg) "and" [
            jsBigInt (JSString $ show 0xFFFFFFFFFFFFFFFF)
          ]

      | (LLSHR (ITFixed IT8)) <- op
      , (lhs:rhs:_)           <- args = jsPackUBits8 $ bitsBinaryOp ">>" lhs rhs

      | (LLSHR (ITFixed IT16)) <- op
      , (lhs:rhs:_)            <- args = jsPackUBits16 $ bitsBinaryOp ">>" lhs rhs

      | (LLSHR (ITFixed IT32)) <- op
      , (lhs:rhs:_)            <- args = jsPackUBits32 $ bitsBinaryOp ">>" lhs rhs

      | (LLSHR (ITFixed IT64)) <- op
      , (lhs:rhs:_)            <- args =
          jsMeth (translateReg lhs) "shiftRight" [translateReg rhs]

      | (LSHL (ITFixed IT8)) <- op
      , (lhs:rhs:_)          <- args = jsPackUBits8 $ bitsBinaryOp "<<" lhs rhs

      | (LSHL (ITFixed IT16)) <- op
      , (lhs:rhs:_)           <- args = jsPackUBits16 $ bitsBinaryOp "<<" lhs rhs

      | (LSHL (ITFixed IT32)) <- op
      , (lhs:rhs:_)           <- args = jsPackUBits32 $ bitsBinaryOp "<<" lhs rhs

      | (LSHL (ITFixed IT64)) <- op
      , (lhs:rhs:_)           <- args =
          jsMeth (jsMeth (translateReg lhs) "shiftLeft" [translateReg rhs]) "and" [
            jsBigInt (JSString $ show 0xFFFFFFFFFFFFFFFF)
          ]

      | (LAnd (ITFixed IT8)) <- op
      , (lhs:rhs:_)          <- args = jsPackUBits8 $ bitsBinaryOp "&" lhs rhs

      | (LAnd (ITFixed IT16)) <- op
      , (lhs:rhs:_)           <- args = jsPackUBits16 $ bitsBinaryOp "&" lhs rhs

      | (LAnd (ITFixed IT32)) <- op
      , (lhs:rhs:_)           <- args = jsPackUBits32 $ bitsBinaryOp "&" lhs rhs

      | (LAnd (ITFixed IT64)) <- op
      , (lhs:rhs:_)           <- args =
          jsMeth (translateReg lhs) "and" [translateReg rhs]

      | (LOr (ITFixed IT8)) <- op
      , (lhs:rhs:_)         <- args = jsPackUBits8 $ bitsBinaryOp "|" lhs rhs

      | (LOr (ITFixed IT16)) <- op
      , (lhs:rhs:_)          <- args = jsPackUBits16 $ bitsBinaryOp "|" lhs rhs

      | (LOr (ITFixed IT32)) <- op
      , (lhs:rhs:_)          <- args = jsPackUBits32 $ bitsBinaryOp "|" lhs rhs

      | (LOr (ITFixed IT64)) <- op
      , (lhs:rhs:_)          <- args =
          jsMeth (translateReg lhs) "or" [translateReg rhs]

      | (LXOr (ITFixed IT8)) <- op
      , (lhs:rhs:_)          <- args = jsPackUBits8 $ bitsBinaryOp "^" lhs rhs

      | (LXOr (ITFixed IT16)) <- op
      , (lhs:rhs:_)           <- args = jsPackUBits16 $ bitsBinaryOp "^" lhs rhs

      | (LXOr (ITFixed IT32)) <- op
      , (lhs:rhs:_)           <- args = jsPackUBits32 $ bitsBinaryOp "^" lhs rhs

      | (LXOr (ITFixed IT64)) <- op
      , (lhs:rhs:_)           <- args =
          jsMeth (translateReg lhs) "xor" [translateReg rhs]

      | (LPlus (ATInt (ITFixed IT8))) <- op
      , (lhs:rhs:_)                   <- args = jsPackUBits8 $ bitsBinaryOp "+" lhs rhs

      | (LPlus (ATInt (ITFixed IT16))) <- op
      , (lhs:rhs:_)                    <- args = jsPackUBits16 $ bitsBinaryOp "+" lhs rhs

      | (LPlus (ATInt (ITFixed IT32))) <- op
      , (lhs:rhs:_)                    <- args = jsPackUBits32 $ bitsBinaryOp "+" lhs rhs

      | (LPlus (ATInt (ITFixed IT64))) <- op
      , (lhs:rhs:_)                    <- args =
          jsMeth (jsMeth (translateReg lhs) "add" [translateReg rhs]) "and" [
            jsBigInt (JSString $ show 0xFFFFFFFFFFFFFFFF)
          ]

      | (LMinus (ATInt (ITFixed IT8))) <- op
      , (lhs:rhs:_)                    <- args = jsPackUBits8 $ bitsBinaryOp "-" lhs rhs

      | (LMinus (ATInt (ITFixed IT16))) <- op
      , (lhs:rhs:_)                     <- args = jsPackUBits16 $ bitsBinaryOp "-" lhs rhs

      | (LMinus (ATInt (ITFixed IT32))) <- op
      , (lhs:rhs:_)                     <- args = jsPackUBits32 $ bitsBinaryOp "-" lhs rhs

      | (LMinus (ATInt (ITFixed IT64))) <- op
      , (lhs:rhs:_)                     <- args =
          jsMeth (jsMeth (translateReg lhs) "subtract" [translateReg rhs]) "and" [
            jsBigInt (JSString $ show 0xFFFFFFFFFFFFFFFF)
          ]

      | (LTimes (ATInt (ITFixed IT8))) <- op
      , (lhs:rhs:_)                    <- args = jsPackUBits8 $ bitsBinaryOp "*" lhs rhs

      | (LTimes (ATInt (ITFixed IT16))) <- op
      , (lhs:rhs:_)                     <- args = jsPackUBits16 $ bitsBinaryOp "*" lhs rhs

      | (LTimes (ATInt (ITFixed IT32))) <- op
      , (lhs:rhs:_)                     <- args = jsPackUBits32 $ bitsBinaryOp "*" lhs rhs

      | (LTimes (ATInt (ITFixed IT64))) <- op
      , (lhs:rhs:_)                     <- args =
          jsMeth (jsMeth (translateReg lhs) "multiply" [translateReg rhs]) "and" [
            jsBigInt (JSString $ show 0xFFFFFFFFFFFFFFFF)
          ]

      | (LEq (ATInt (ITFixed IT8))) <- op
      , (lhs:rhs:_)                 <- args = bitsCompareOp "==" lhs rhs

      | (LEq (ATInt (ITFixed IT16))) <- op
      , (lhs:rhs:_)                  <- args = bitsCompareOp "==" lhs rhs

      | (LEq (ATInt (ITFixed IT32))) <- op
      , (lhs:rhs:_)                  <- args = bitsCompareOp "==" lhs rhs

      | (LEq (ATInt (ITFixed IT64))) <- op
      , (lhs:rhs:_)                  <- args = JSPreOp "+" $ invokeMeth lhs "equals" [rhs]

      | (LLt (ITFixed IT8)) <- op
      , (lhs:rhs:_)         <- args = bitsCompareOp "<" lhs rhs

      | (LLt (ITFixed IT16)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp "<" lhs rhs

      | (LLt (ITFixed IT32)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp "<" lhs rhs

      | (LLt (ITFixed IT64)) <- op
      , (lhs:rhs:_)          <- args = JSPreOp "+" $ invokeMeth lhs "lesser" [rhs]

      | (LLe (ITFixed IT8)) <- op
      , (lhs:rhs:_)         <- args = bitsCompareOp "<=" lhs rhs

      | (LLe (ITFixed IT16)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp "<=" lhs rhs

      | (LLe (ITFixed IT32)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp "<=" lhs rhs

      | (LLe (ITFixed IT64)) <- op
      , (lhs:rhs:_)          <- args = JSPreOp "+" $ invokeMeth lhs "lesserOrEquals" [rhs]

      | (LGt (ITFixed IT8)) <- op
      , (lhs:rhs:_)         <- args = bitsCompareOp ">" lhs rhs

      | (LGt (ITFixed IT16)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp ">" lhs rhs
      | (LGt (ITFixed IT32)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp ">" lhs rhs

      | (LGt (ITFixed IT64)) <- op
      , (lhs:rhs:_)          <- args = JSPreOp "+" $ invokeMeth lhs "greater" [rhs]

      | (LGe (ITFixed IT8)) <- op
      , (lhs:rhs:_)         <- args = bitsCompareOp ">=" lhs rhs

      | (LGe (ITFixed IT16)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp ">=" lhs rhs
      | (LGe (ITFixed IT32)) <- op
      , (lhs:rhs:_)          <- args = bitsCompareOp ">=" lhs rhs

      | (LGe (ITFixed IT64)) <- op
      , (lhs:rhs:_)          <- args = JSPreOp "+" $ invokeMeth lhs "greaterOrEquals" [rhs]

      | (LUDiv (ITFixed IT8)) <- op
      , (lhs:rhs:_)           <- args =
          jsPackUBits8 (
            JSBinOp "/" (jsUnPackBits (translateReg lhs)) (jsUnPackBits (translateReg rhs))
          )

      | (LUDiv (ITFixed IT16)) <- op
      , (lhs:rhs:_)            <- args =
          jsPackUBits16 (
            JSBinOp "/" (jsUnPackBits (translateReg lhs)) (jsUnPackBits (translateReg rhs))
          )

      | (LUDiv (ITFixed IT32)) <- op
      , (lhs:rhs:_)            <- args =
          jsPackUBits32 (
            JSBinOp "/" (jsUnPackBits (translateReg lhs)) (jsUnPackBits (translateReg rhs))
          )

      | (LUDiv (ITFixed IT64)) <- op
      , (lhs:rhs:_)            <- args = invokeMeth lhs "divide" [rhs]

      | (LSDiv (ATInt (ITFixed IT8))) <- op
      , (lhs:rhs:_)                   <- args =
          jsPackSBits8 (
            JSBinOp "/" (
              jsUnPackBits $ jsPackSBits8 $ jsUnPackBits (translateReg lhs)
            ) (
              jsUnPackBits $ jsPackSBits8 $ jsUnPackBits (translateReg rhs)
            )
          )

      | (LSDiv (ATInt (ITFixed IT16))) <- op
      , (lhs:rhs:_)                    <- args =
          jsPackSBits16 (
            JSBinOp "/" (
              jsUnPackBits $ jsPackSBits16 $ jsUnPackBits (translateReg lhs)
            ) (
              jsUnPackBits $ jsPackSBits16 $ jsUnPackBits (translateReg rhs)
            )
          )

      | (LSDiv (ATInt (ITFixed IT32))) <- op
      , (lhs:rhs:_)                    <- args =
          jsPackSBits32 (
            JSBinOp "/" (
              jsUnPackBits $ jsPackSBits32 $ jsUnPackBits (translateReg lhs)
            ) (
              jsUnPackBits $ jsPackSBits32 $ jsUnPackBits (translateReg rhs)
            )
          )

      | (LSDiv (ATInt (ITFixed IT64))) <- op
      , (lhs:rhs:_)                    <- args = invokeMeth lhs "divide" [rhs]

      | (LSRem (ATInt (ITFixed IT8))) <- op
      , (lhs:rhs:_)                   <- args =
          jsPackSBits8 (
            JSBinOp "%" (
              jsUnPackBits $ jsPackSBits8 $ jsUnPackBits (translateReg lhs)
            ) (
              jsUnPackBits $ jsPackSBits8 $ jsUnPackBits (translateReg rhs)
            )
          )

      | (LSRem (ATInt (ITFixed IT16))) <- op
      , (lhs:rhs:_)                    <- args =
          jsPackSBits16 (
            JSBinOp "%" (
              jsUnPackBits $ jsPackSBits16 $ jsUnPackBits (translateReg lhs)
            ) (
              jsUnPackBits $ jsPackSBits16 $ jsUnPackBits (translateReg rhs)
            )
          )

      | (LSRem (ATInt (ITFixed IT32))) <- op
      , (lhs:rhs:_)                    <- args =
          jsPackSBits32 (
            JSBinOp "%" (
              jsUnPackBits $ jsPackSBits32 $ jsUnPackBits (translateReg lhs)
            ) (
              jsUnPackBits $ jsPackSBits32 $ jsUnPackBits (translateReg rhs)
            )
          )

      | (LSRem (ATInt (ITFixed IT64))) <- op
      , (lhs:rhs:_)                    <- args = invokeMeth lhs "mod" [rhs]

      | (LCompl (ITFixed IT8)) <- op
      , (arg:_)                <- args =
          jsPackSBits8 $ JSPreOp "~" $ jsUnPackBits (translateReg arg)

      | (LCompl (ITFixed IT16)) <- op
      , (arg:_)                 <- args =
          jsPackSBits16 $ JSPreOp "~" $ jsUnPackBits (translateReg arg)

      | (LCompl (ITFixed IT32)) <- op
      , (arg:_)                 <- args =
          jsPackSBits32 $ JSPreOp "~" $ jsUnPackBits (translateReg arg)

      | (LCompl (ITFixed IT64)) <- op
      , (arg:_)                 <- args = invokeMeth arg "not" []

      | (LPlus _)   <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "+" lhs rhs
      | (LMinus _)  <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "-" lhs rhs
      | (LTimes _)  <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "*" lhs rhs
      | (LSDiv _)   <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "/" lhs rhs
      | (LSRem _)   <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "%" lhs rhs
      | (LEq _)     <- op
      , (lhs:rhs:_) <- args = translateCompareOp "==" lhs rhs
      | (LSLt _)    <- op
      , (lhs:rhs:_) <- args = translateCompareOp "<" lhs rhs
      | (LSLe _)    <- op
      , (lhs:rhs:_) <- args = translateCompareOp "<=" lhs rhs
      | (LSGt _)    <- op
      , (lhs:rhs:_) <- args = translateCompareOp ">" lhs rhs
      | (LSGe _)    <- op
      , (lhs:rhs:_) <- args = translateCompareOp ">=" lhs rhs
      | (LAnd _)    <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "&" lhs rhs
      | (LOr _)     <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "|" lhs rhs
      | (LXOr _)    <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "^" lhs rhs
      | (LSHL _)    <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "<<" rhs lhs
      | (LASHR _)   <- op
      , (lhs:rhs:_) <- args = translateBinaryOp ">>" rhs lhs
      | (LCompl _)  <- op
      , (arg:_)     <- args = JSPreOp "~" (translateReg arg)

      | LStrConcat  <- op
      , (lhs:rhs:_) <- args = translateBinaryOp "+" lhs rhs
      | LStrEq      <- op
      , (lhs:rhs:_) <- args = translateCompareOp "==" lhs rhs
      | LStrLt      <- op
      , (lhs:rhs:_) <- args = translateCompareOp "<" lhs rhs
      | LStrLen     <- op
      , (arg:_)     <- args = JSProj (translateReg arg) "length"
      | (LStrInt ITNative)      <- op
      , (arg:_)                 <- args = jsCall "parseInt" [translateReg arg]
      | (LIntStr ITNative)      <- op
      , (arg:_)                 <- args = jsCall "String" [translateReg arg]
      | (LSExt ITNative ITBig)  <- op
      , (arg:_)                 <- args = jsBigInt $ jsCall "String" [translateReg arg]
      | (LTrunc ITBig ITNative) <- op
      , (arg:_)                 <- args = jsMeth (translateReg arg) "intValue" []
      | (LIntStr ITBig)         <- op
      , (arg:_)                 <- args = jsMeth (translateReg arg) "toString" []
      | (LStrInt ITBig)         <- op
      , (arg:_)                 <- args = jsBigInt $ translateReg arg
      | LFloatStr               <- op
      , (arg:_)                 <- args = jsCall "String" [translateReg arg]
      | LStrFloat               <- op
      , (arg:_)                 <- args = jsCall "parseFloat" [translateReg arg]
      | (LIntFloat ITNative)    <- op
      , (arg:_)                 <- args = translateReg arg
      | (LIntFloat ITBig)       <- op
      , (arg:_)                 <- args = jsMeth (translateReg arg) "intValue" []
      | (LFloatInt ITNative)    <- op
      , (arg:_)                 <- args = translateReg arg
      | (LChInt ITNative)       <- op
      , (arg:_)                 <- args = jsCall "i$charCode" [translateReg arg]
      | (LIntCh ITNative)       <- op
      , (arg:_)                 <- args = jsCall "i$fromCharCode" [translateReg arg]

      | LFExp       <- op
      , (arg:_)     <- args = jsCall "Math.exp" [translateReg arg]
      | LFLog       <- op
      , (arg:_)     <- args = jsCall "Math.log" [translateReg arg]
      | LFSin       <- op
      , (arg:_)     <- args = jsCall "Math.sin" [translateReg arg]
      | LFCos       <- op
      , (arg:_)     <- args = jsCall "Math.cos" [translateReg arg]
      | LFTan       <- op
      , (arg:_)     <- args = jsCall "Math.tan" [translateReg arg]
      | LFASin      <- op
      , (arg:_)     <- args = jsCall "Math.asin" [translateReg arg]
      | LFACos      <- op
      , (arg:_)     <- args = jsCall "Math.acos" [translateReg arg]
      | LFATan      <- op
      , (arg:_)     <- args = jsCall "Math.atan" [translateReg arg]
      | LFSqrt      <- op
      , (arg:_)     <- args = jsCall "Math.sqrt" [translateReg arg]
      | LFFloor     <- op
      , (arg:_)     <- args = jsCall "Math.floor" [translateReg arg]
      | LFCeil      <- op
      , (arg:_)     <- args = jsCall "Math.ceil" [translateReg arg]
      | LFNegate    <- op
      , (arg:_)     <- args = JSPreOp "-" (translateReg arg)

      | LStrCons    <- op
      , (lhs:rhs:_) <- args = invokeMeth lhs "concat" [rhs]
      | LStrHead    <- op
      , (arg:_)     <- args = JSIndex (translateReg arg) (JSNum (JSInt 0))
      | LStrRev     <- op
      , (arg:_)     <- args = JSProj (translateReg arg) "split('').reverse().join('')"
      | LStrIndex   <- op
      , (lhs:rhs:_) <- args = JSIndex (translateReg lhs) (translateReg rhs)
      | LStrTail    <- op
      , (arg:_)     <- args =
          let v = translateReg arg in
              JSApp (JSProj v "substr") [
                JSNum (JSInt 1),
                JSBinOp "-" (JSProj v "length") (JSNum (JSInt 1))
              ]
      | LStrSubstr <- op
      , (offset:length:string:_) <- args =
        let off = translateReg offset
            len = translateReg length
            str = translateReg string
        in JSApp (JSProj str "substr") [
             jsCall "Math.max" [JSNum (JSInt 0), off],
             jsCall "Math.max" [JSNum (JSInt 0), len]
           ]

      | LSystemInfo <- op
      , (arg:_) <- args = jsCall "i$systemInfo"  [translateReg arg]
      | LExternal nul <- op
      , nul == sUN "prim__null"
      , _ <- args = JSNull
      | LExternal ex <- op
      , ex == sUN "prim__eqPtr"
      , [lhs, rhs] <- args = translateCompareOp "==" lhs rhs
      | otherwise = JSError $ "Not implemented: " ++ show op
        where
          translateBinaryOp :: String -> Reg -> Reg -> JS
          translateBinaryOp op lhs rhs =
            JSBinOp op (translateReg lhs) (translateReg rhs)

          translateCompareOp :: String -> Reg -> Reg -> JS
          translateCompareOp op lhs rhs =
            JSPreOp "+" $ translateBinaryOp op lhs rhs

          bitsBinaryOp :: String -> Reg -> Reg -> JS
          bitsBinaryOp op lhs rhs =
            JSBinOp op (jsUnPackBits (translateReg lhs)) (jsUnPackBits (translateReg rhs))

          bitsCompareOp :: String -> Reg -> Reg -> JS
          bitsCompareOp op lhs rhs =
            JSPreOp "+" $ bitsBinaryOp op lhs rhs

          invokeMeth :: Reg -> String -> [Reg] -> JS
          invokeMeth obj meth args =
            JSApp (JSProj (translateReg obj) meth) $ map translateReg args


jsRESERVE :: CompileInfo -> Int -> JS
jsRESERVE _ _ = JSNoop

jsSTACK :: JS
jsSTACK = JSIdent "i$valstack"

jsCALLSTACK :: JS
jsCALLSTACK = JSIdent "i$callstack"

jsSTACKBASE :: JS
jsSTACKBASE = JSIdent "i$valstack_base"

jsSTACKTOP :: JS
jsSTACKTOP = JSIdent "i$valstack_top"

jsOLDBASE :: JS
jsOLDBASE = JSIdent "oldbase"

jsMYOLDBASE :: JS
jsMYOLDBASE = JSIdent "myoldbase"

jsRET :: JS
jsRET = JSIdent "i$ret"

jsLOC :: Int -> JS
jsLOC 0 = JSIndex jsSTACK jsSTACKBASE
jsLOC n = JSIndex jsSTACK (JSBinOp "+" jsSTACKBASE (JSNum (JSInt n)))

jsTOP :: Int -> JS
jsTOP 0 = JSIndex jsSTACK jsSTACKTOP
jsTOP n = JSIndex jsSTACK (JSBinOp "+" jsSTACKTOP (JSNum (JSInt n)))

jsPUSH :: [JS] -> JS
jsPUSH args = JSApp (JSProj jsCALLSTACK "push") args

jsPOP :: JS
jsPOP = JSApp (JSProj jsCALLSTACK "pop") []

genInterface :: Export -> JS
genInterface (ExportData name) = JSNoop
genInterface (ExportFun name (FStr jsName) ret args) = JSAlloc jsName
        (Just (JSFunction [] (JSSeq  $
            jsFUNPRELUDE ++
            pushArgs nargs ++
            [jsSTOREOLD d,
             jsBASETOP d 0,
             jsADDTOP d nargs,
             jsCALL d name] ++
            retval ret)))
    where
        nargs = length args
        d = CompileInfo [] [] False
        pushArg n = JSAssign (jsTOP n) (JSIndex (JSIdent "arguments") (JSNum (JSInt n)))
        pushArgs 0 = []
        pushArgs n = (pushArg (n-1)):pushArgs (n-1)
        retval (FIO t) = [JSApp (JSIdent "i$RUN") [],
                          JSAssign (jsTOP 0) JSNull,
                          JSAssign (jsTOP 1) JSNull,
                          JSAssign (jsTOP 2) (translateReg RVal),
                          jsSTOREOLD d,
                          jsBASETOP d 0,
                          jsADDTOP d 3,
                          jsCALL d (sUN "call__IO")] ++ retval t
        retval t = [JSApp (JSIdent "i$RUN") [], JSReturn (translateReg RVal)]

translateBC :: CompileInfo -> BC -> JS
translateBC info bc
  | ASSIGN r1 r2          <- bc = jsASSIGN info r1 r2
  | ASSIGNCONST r c       <- bc = jsASSIGNCONST info r c
  | UPDATE r1 r2          <- bc = jsASSIGN info r1 r2
  | ADDTOP n              <- bc = jsADDTOP info n
  | NULL r                <- bc = jsNULL info r
  | CALL n                <- bc = jsCALL info n
  | TAILCALL n            <- bc = jsTAILCALL info n
  | FOREIGNCALL r _ (FStr n) args
                          <- bc = jsFOREIGN info r n (map fcall args)
  | FOREIGNCALL _ _ _ _   <- bc = error "JS FFI call not statically known"
  | TOPBASE n             <- bc = jsTOPBASE info n
  | BASETOP n             <- bc = jsBASETOP info n
  | STOREOLD              <- bc = jsSTOREOLD info
  | SLIDE n               <- bc = jsSLIDE info n
  | REBASE                <- bc = jsREBASE info
  | RESERVE n             <- bc = jsRESERVE info n
  | MKCON r _ t rs        <- bc = jsMKCON info r t rs
  | CASE s r c d          <- bc = jsCASE info s r c d
  | CONSTCASE r c d       <- bc = jsCONSTCASE info r c d
  | PROJECT r l a         <- bc = jsPROJECT info r l a
  | OP r o a              <- bc = jsOP info r o a
  | ERROR e               <- bc = jsERROR info e
  | otherwise                   = JSRaw $ "//" ++ show bc
 where fcall (t, arg) = (toFType t, arg)

toAType (FCon i)
    | i == sUN "JS_IntChar" = ATInt ITChar
    | i == sUN "JS_IntNative" = ATInt ITNative
toAType t = error (show t ++ " not defined in toAType")

toFnType (FApp c [_,_,s,t])
    | c == sUN "JS_Fn" = toFnType t
toFnType (FApp c [_,_,r])
    | c == sUN "JS_FnIO" = FFunctionIO
toFnType (FApp c [_,r])
    | c == sUN "JS_FnBase" = FFunction
toFnType t = error (show t ++ " not defined in toFnType")

toFType (FCon c)
    | c == sUN "JS_Str" = FString
    | c == sUN "JS_Float" = FArith ATFloat
    | c == sUN "JS_Ptr" = FPtr
    | c == sUN "JS_Unit" = FUnit
toFType (FApp c [_,ity])
    | c == sUN "JS_IntT" = FArith (toAType ity)
toFType (FApp c [_,fty])
    | c == sUN "JS_FnT" = toFnType fty
toFType t = error (show t ++ " not yet defined in toFType")