{-|
Module      : IRTS.Compiler
Description : Coordinates the compilation process.

License     : BSD3
Maintainer  : The Idris Community.
-}
{-# LANGUAGE CPP, FlexibleContexts, PatternGuards, TypeSynonymInstances #-}

module IRTS.Compiler(compile, generate) where

import Idris.AbsSyntax
import Idris.ASTUtils
import Idris.Core.CaseTree
import Idris.Core.Evaluate
import Idris.Core.TT
import Idris.Erasure
import Idris.Error
import Idris.Options
import Idris.Output
import IRTS.CodegenC
import IRTS.CodegenCommon
import IRTS.Defunctionalise
import IRTS.DumpBC
import IRTS.Exports
import IRTS.Inliner
import IRTS.LangOpts
import IRTS.Portable
import IRTS.Simplified

import Prelude hiding (id, (.))

import Control.Category
import Control.Monad.State
import Data.List
import qualified Data.Map as M
import Data.Ord
import qualified Data.Set as S
import System.Directory
import System.Exit
import System.IO
import System.Process

-- |  Compile to simplified forms and return CodegenInfo
compile :: Codegen -> FilePath -> Maybe Term -> Idris CodegenInfo
compile codegen f mtm = do
        logCodeGen 1 "Compiling Output."
        iReport 2 "Compiling Output."
        checkMVs  -- check for undefined metavariables
        checkTotality -- refuse to compile if there are totality problems
        exports <- findExports
        let rootNames = case mtm of
                             Nothing -> []
                             Just t -> freeNames t

        logCodeGen 1 "Running Erasure Analysis"
        iReport 3 "Running Erasure Analysis"
        reachableNames <- performUsageAnalysis
                              (rootNames ++ getExpNames exports)
        maindef <- case mtm of
                        Nothing -> return []
                        Just tm -> do md <- irMain tm
                                      logCodeGen 1 $ "MAIN: " ++ show md
                                      return [(sMN 0 "runMain", md)]
        objs <- getObjectFiles codegen
        libs <- getLibs codegen
        flags <- getFlags codegen
        hdrs <- getHdrs codegen
        impdirs <- rankedImportDirs f
        ttDeclarations <- getDeclarations reachableNames
        defsIn <- mkDecls reachableNames
        -- if no 'main term' given, generate interface files
        let iface = case mtm of
                         Nothing -> True
                         Just _ -> False

        let defs = defsIn ++ maindef

        -- Inlined top level LDecl made here
        let defsInlined = inlineAll defs
        let defsUniq = map (allocUnique (addAlist defsInlined emptyContext))
                           defsInlined

        logCodeGen 1 "Inlining"

        dumpCases <- getDumpCases
        case dumpCases of
            Nothing -> return ()
            Just f -> runIO $ writeFile f (showCaseTrees defsUniq)

        let (nexttag, tagged) = addTags 65536 (liftAll defsInlined)
        let ctxtIn = addAlist tagged emptyContext

        logCodeGen 1 "Defunctionalising"
        iReport 3 "Defunctionalising"
        let defuns_in = defunctionalise nexttag ctxtIn
        logCodeGen 5 $ show defuns_in
        logCodeGen 1 "Inlining"
        iReport 3 "Inlining"
        let defuns = inline defuns_in
        logCodeGen 5 $ show defuns
        logCodeGen 1 "Resolving variables for CG"

        let checked = simplifyDefs defuns (toAlist defuns)
        outty <- outputTy
        dumpDefun <- getDumpDefun
        case dumpDefun of
            Nothing -> return ()
            Just f -> runIO $ writeFile f (dumpDefuns defuns)
        triple <- Idris.AbsSyntax.targetTriple
        cpu <- Idris.AbsSyntax.targetCPU
        logCodeGen 1 "Generating Code."
        iReport 2 "Generating Code."
        case checked of
            OK c -> do return $ CodegenInfo f outty triple cpu
                                            hdrs impdirs objs libs flags
                                            NONE c (toAlist defuns)
                                            tagged iface exports
                                            ttDeclarations
            Error e -> ierror e
  where checkMVs = do i <- getIState
                      case map fst (idris_metavars i) \\ primDefs of
                            [] -> return ()
                            ms -> do iputStrLn $ "WARNING: There are incomplete holes:\n " ++ show ms
                                     iputStrLn "\nEvaluation of any of these will crash at run time."
                                     return ()
        checkTotality = do i <- getIState
                           case idris_totcheckfail i of
                             [] -> return ()
                             ((fc, msg):fs) -> ierror . At fc . Msg $ "Cannot compile:\n  " ++ msg

generate :: Codegen -> FilePath -> CodegenInfo -> IO ()
generate codegen mainmod ir
  = case codegen of
       -- Built-in code generators (FIXME: lift these out!)
       Via _ "c" -> codegenC ir
       -- Any external code generator
       Via fm cg -> do input <- case fm of
                                    IBCFormat -> return mainmod
                                    JSONFormat -> do
                                        tempdir <- getTemporaryDirectory
                                        (fn, h) <- openTempFile tempdir "idris-cg.json"
                                        writePortable h ir
                                        hClose h
                                        return fn
                       let cmd = "idris-codegen-" ++ cg
                           args = [input, "-o", outputFile ir] ++ compilerFlags ir
                       exit <- rawSystem cmd (if interfaces ir then "--interface" : args else args)
                       when (exit /= ExitSuccess) $
                            putStrLn ("FAILURE: " ++ show cmd ++ " " ++ show args)
       Bytecode -> dumpBC (simpleDecls ir) (outputFile ir)

irMain :: TT Name -> Idris LDecl
irMain tm = do
    i <- irTerm (sMN 0 "runMain") M.empty [] tm
    return $ LFun [] (sMN 0 "runMain") [] (LForce i)

mkDecls :: [Name] -> Idris [(Name, LDecl)]
mkDecls used
    = do i <- getIState
         let ds = filter (\(n, d) -> n `elem` used || isCon d) $ ctxtAlist (tt_ctxt i)
         decls <- mapM build ds
         return decls

getDeclarations :: [Name] -> Idris ([(Name, TTDecl)])
getDeclarations used
    = do i <- getIState
         let ds = filter (\(n, (d,_,_,_,_,_)) -> n `elem` used || isCon d) $ ((toAlist . definitions . tt_ctxt) i)
         return ds

showCaseTrees :: [(Name, LDecl)] -> String
showCaseTrees = showSep "\n\n" . map showCT . sortBy (comparing defnRank)
  where
    showCT (n, LFun opts f args lexp)
       = showOpts ++
         show n ++ " " ++ showSep " " (map show args) ++ " =\n\t"
            ++ show lexp
      where
        showOpts | Inline `elem` opts = "%inline "
                 | otherwise = ""
    showCT (n, LConstructor c t a) = "data " ++ show n ++ " " ++ show a

    defnRank :: (Name, LDecl) -> String
    defnRank (n, LFun _ _ _ _)       = "1" ++ nameRank n
    defnRank (n, LConstructor _ _ _) = "2" ++ nameRank n

    nameRank :: Name -> String
    nameRank (UN s)   = "1" ++ show s
    nameRank (MN i s) = "2" ++ show s ++ show i
    nameRank (NS n ns) = "3" ++ concatMap show (reverse ns) ++ nameRank n
    nameRank (SN sn) = "4" ++ snRank sn
    nameRank n = "5" ++ show n

    snRank :: SpecialName -> String
    snRank (WhereN i n n') = "1" ++ nameRank n' ++ nameRank n ++ show i
    snRank (ImplementationN n args) = "2" ++ nameRank n ++ concatMap show args
    snRank (ParentN n s) = "3" ++ nameRank n ++ show s
    snRank (MethodN n) = "4" ++ nameRank n
    snRank (CaseN _ n) = "5" ++ nameRank n
    snRank (ElimN n) = "6" ++ nameRank n
    snRank (ImplementationCtorN n) = "7" ++ nameRank n
    snRank (WithN i n) = "8" ++ nameRank n ++ show i

isCon (TyDecl _ _) = True
isCon _ = False

build :: (Name, Def) -> Idris (Name, LDecl)
build (n, d)
    = do i <- getIState
         case getPrim n i of
              Just (ar, op) ->
                  let args = map (\x -> sMN x "op") [0..] in
                      return (n, (LFun [] n (take ar args)
                                         (LOp op (map LV (take ar args)))))
              _ -> do def <- mkLDecl n d
                      logCodeGen 3 $ "Compiled " ++ show n ++ " =\n\t" ++ show def
                      return (n, def)
   where getPrim n i
             | Just (ar, op) <- lookup n (idris_scprims i)
                  = Just (ar, op)
             | Just ar <- lookup n (S.toList (idris_externs i))
                  = Just (ar, LExternal n)
         getPrim n i = Nothing

declArgs args inl n (LLam xs x) = declArgs (args ++ xs) inl n x
declArgs args inl n x = LFun (if inl then [Inline] else []) n args x

mkLDecl n (Function tm _)
    = declArgs [] True n <$> irTerm n M.empty [] tm

mkLDecl n (CaseOp ci _ _ _ pats cd)
    = declArgs [] (case_inlinable ci || caseName n) n <$> irTree n args sc
  where
    (args, sc) = cases_runtime cd

    -- Always attempt to inline functions arising from 'case' expressions
    caseName (SN (CaseN _ _)) = True
    caseName (SN (WithN _ _)) = True
    caseName (NS n _) = caseName n
    caseName _ = False

mkLDecl n (TyDecl (DCon tag arity _) _) =
    LConstructor n tag . length <$> fgetState (cg_usedpos . ist_callgraph n)

mkLDecl n (TyDecl (TCon t a) _) = return $ LConstructor n (-1) a
mkLDecl n _ = return $ (declArgs [] True n LNothing) -- postulate, never run

data VarInfo = VI
    { viMethod :: Maybe Name
    }
    deriving Show

type Vars = M.Map Name VarInfo

irTerm :: Name -> Vars -> [Name] -> Term -> Idris LExp
irTerm top vs env tm@(App _ f a) = do
  ist <- getIState
  case unApply tm of
    (P _ n _, args)
        | n `elem` map fst (idris_metavars ist) \\ primDefs
        -> return $ LError $ "ABORT: Attempt to evaluate hole " ++ show n
    (P _ (UN m) _, args)
        | m == txt "mkForeignPrim"
        -> doForeign vs env (reverse (drop 4 args)) -- drop implicits

    (P _ (UN u) _, [_, arg])
        | u == txt "unsafePerformPrimIO"
        -> irTerm top vs env arg

    (P _ (UN u) _, _)
        | u == txt "assert_unreachable"
        -> return $ LError $ "ABORT: Reached an unreachable case in " ++ show top

    (P _ (UN u) _, [_, msg])
        | u == txt "idris_crash"
        -> do msg' <- irTerm top vs env msg
              return $ LOp LCrash [msg']

    -- TMP HACK - until we get inlining.
    (P _ (UN r) _, [_, _, _, _, _, arg])
        | r == txt "replace"
        -> irTerm top vs env arg

    -- 'void' doesn't have any pattern clauses and only gets called on
    -- erased things in higher order contexts (also a TMP HACK...)
    (P _ (UN r) _, _)
        | r == txt "void"
        -> return LNothing

    -- Laziness, the old way
    (P _ (UN l) _, [_, arg])
        | l == txt "lazy"
        -> error "lazy has crept in somehow"

    (P _ (UN l) _, [_, arg])
        | l == txt "force"
        -> LForce <$> irTerm top vs env arg

    -- Laziness, the new way
    (P _ (UN l) _, [_, _, arg])
        | l == txt "Delay"
        -> LLazyExp <$> irTerm top vs env arg

    (P _ (UN l) _, [_, _, arg])
        | l == txt "Force"
        -> LForce <$> irTerm top vs env arg

    (P _ (UN a) _, [_, _, _, arg])
        | a == txt "assert_smaller"
        -> irTerm top vs env arg

    (P _ (UN a) _, [_, arg])
        | a == txt "assert_total"
        -> irTerm top vs env arg

    (P _ (UN p) _, [_, arg])
        | p == txt "par"
        -> do arg' <- irTerm top vs env arg
              return $ LOp LPar [LLazyExp arg']

    (P _ (UN pf) _, [arg])
        | pf == txt "prim_fork"
        -> do arg' <- irTerm top vs env arg
              return $ LOp LFork [LLazyExp arg']

    (P _ (UN m) _, [_,size,t])
        | m == txt "malloc"
        -> irTerm top vs env t

    (P _ (UN tm) _, [_,t])
        | tm == txt "trace_malloc"
        -> irTerm top vs env t -- TODO

    -- This case is here until we get more general inlining. It's just
    -- a really common case, and the laziness hurts...
    (P _ (NS (UN be) [b,p]) _, [_,x,(App _ (App _ (App _ (P _ (UN d) _) _) _) t),
                                    (App _ (App _ (App _ (P _ (UN d') _) _) _) e)])
        | be == txt "ifThenElse"
        , d  == txt "Delay"
        , d' == txt "Delay"
        , b  == txt "Bool"
        , p  == txt "Prelude"
        -> do
            x' <- irTerm top vs env x
            t' <- irTerm top vs env t
            e' <- irTerm top vs env e
            return (LCase Shared x'
                             [LConCase 0 (sNS (sUN "False") ["Bool","Prelude"]) [] e'
                             ,LConCase 1 (sNS (sUN "True" ) ["Bool","Prelude"]) [] t'
                             ])

    -- data constructor
    (P (DCon t arity _) n _, args) -> do
        detag <- fgetState (opt_detaggable . ist_optimisation n)
        used  <- map fst <$> fgetState (cg_usedpos . ist_callgraph n)

        let isNewtype = length used == 1 && detag
        let argsPruned = [a | (i,a) <- zip [0..] args, i `elem` used]

        -- The following code removes fields from data constructors
        -- and performs the newtype optimisation.
        --
        -- The general rule here is:
        -- Everything we get as input is not touched by erasure,
        -- so it conforms to the official arities and types
        -- and we can reason about it like it's plain TT.
        --
        -- It's only the data that leaves this point that's erased
        -- and possibly no longer typed as the original TT version.
        --
        -- Especially, underapplied constructors must yield functions
        -- even if all the remaining arguments are erased
        -- (the resulting function *will* be applied, to NULLs).
        --
        -- This will probably need rethinking when we get erasure from functions.

        -- "padLams" will wrap our term in LLam-bdas and give us
        -- the "list of future unerased args" coming from these lambdas.
        --
        -- We can do whatever we like with the list of unerased args,
        -- hence it takes a lambda: \unerased_argname_list -> resulting_LExp.
        let padLams = padLambdas used (length args) arity

        case compare (length args) arity of

            -- overapplied
            GT  -> ifail ("overapplied data constructor: " ++ show tm ++
                          "\nDEBUG INFO:\n" ++
                          "Arity: " ++ show arity ++ "\n" ++
                          "Arguments: " ++ show args ++ "\n" ++
                          "Pruned arguments: " ++ show argsPruned)

            -- exactly saturated
            EQ  | isNewtype
                -> irTerm top vs env (head argsPruned)

                | otherwise  -- not newtype, plain data ctor
                -> buildApp (LV n) argsPruned

            -- not saturated, underapplied
            LT  | isNewtype               -- newtype
                , length argsPruned == 1  -- and we already have the value
                -> padLams . (\tm [] -> tm)  -- the [] asserts there are no unerased args
                    <$> irTerm top vs env (head argsPruned)

                | isNewtype  -- newtype but the value is not among args yet
                -> return . padLams $ \[vn] -> LApp False (LV n) [LV vn]

                -- not a newtype, just apply to a constructor
                | otherwise
                -> padLams . applyToNames <$> buildApp (LV n) argsPruned

    -- type constructor
    (P (TCon t a) n _, args) -> return LNothing

    -- an external name applied to arguments
    (P _ n _, args) | S.member (n, length args) (idris_externs ist) -> do
        LOp (LExternal n) <$> mapM (irTerm top vs env) args

    -- a name applied to arguments
    (P _ n _, args) -> do
        case lookup n (idris_scprims ist) of
            -- if it's a primitive that is already saturated,
            -- compile to the corresponding op here already to save work
            Just (arity, op) | length args == arity
                -> LOp op <$> mapM (irTerm top vs env) args

            -- otherwise, just apply the name
            _   -> applyName n ist args

    -- turn de bruijn vars into regular named references and try again
    (V i, args) -> irTerm top vs env $ mkApp (P Bound (env !! i) Erased) args

    (f, args)
        -> LApp False
            <$> irTerm top vs env f
            <*> mapM (irTerm top vs env) args

  where
    buildApp :: LExp -> [Term] -> Idris LExp
    buildApp e [] = return e
    buildApp e xs = LApp False e <$> mapM (irTerm top vs env) xs

    applyToNames :: LExp -> [Name] -> LExp
    applyToNames tm [] = tm
    applyToNames tm ns = LApp False tm $ map LV ns

    padLambdas :: [Int] -> Int -> Int -> ([Name] -> LExp) -> LExp
    padLambdas used startIdx endSIdx mkTerm
        = LLam allNames $ mkTerm nonerasedNames
      where
        allNames       = [sMN i "sat" | i <- [startIdx .. endSIdx-1]]
        nonerasedNames = [sMN i "sat" | i <- [startIdx .. endSIdx-1], i `elem` used]

    applyName :: Name -> IState -> [Term] -> Idris LExp
    applyName n ist args =
        LApp False (LV n) <$> mapM (irTerm top vs env . erase) (zip [0..] args)
      where
        erase (i, x)
            | i >= arity || i `elem` used = x
            | otherwise = Erased

        arity = case fst4 <$> lookupCtxtExact n (definitions . tt_ctxt $ ist) of
            Just (CaseOp ci ty tys def tot cdefs) -> length tys
            Just (TyDecl (DCon tag ar _) _)       -> ar
            Just (TyDecl Ref ty)                  -> length $ getArgTys ty
            Just (Operator ty ar op)              -> ar
            Just def -> error $ "unknown arity: " ++ show (n, def)
            Nothing  -> 0  -- no definition, probably local name => can't erase anything

        -- name for purposes of usage info lookup
        uName
            | Just n' <- viMethod =<< M.lookup n vs = n'
            | otherwise = n

        used = maybe [] (map fst . usedpos) $ lookupCtxtExact uName (idris_callgraph ist)
        fst4 (x,_,_,_,_,_) = x

irTerm top vs env (P _ n _) = return $ LV n
irTerm top vs env (V i)
    | i >= 0 && i < length env = return $ LV (env!!i)
    | otherwise = ifail $ "bad de bruijn index: " ++ show i

irTerm top vs env (Bind n (Lam _ _) sc) = LLam [n'] <$> irTerm top vs (n':env) sc
  where
    n' = uniqueName n env

irTerm top vs env (Bind n (Let _ _ v) sc)
    = LLet n <$> irTerm top vs env v <*> irTerm top vs (n : env) sc

irTerm top vs env (Bind _ _ _) = return $ LNothing

irTerm top vs env (Proj t (-1)) = do
    t' <- irTerm top vs env t
    return $ LOp (LMinus (ATInt ITBig))
                 [t', LConst (BI 1)]

irTerm top vs env (Proj t i)   = LProj <$> irTerm top vs env t <*> pure i
irTerm top vs env (Constant TheWorld) = return LNothing
irTerm top vs env (Constant c)        = return (LConst c)
irTerm top vs env (TType _)           = return LNothing
irTerm top vs env Erased              = return LNothing
irTerm top vs env Impossible          = return LNothing

doForeign :: Vars -> [Name] -> [Term] -> Idris LExp
doForeign vs env (ret : fname : world : args)
     = do args' <- mapM splitArg args
          let fname' = toFDesc fname
          let ret' = toFDesc ret
          return $ LForeign ret' fname' args'
  where
    splitArg tm | (_, [_,_,l,r]) <- unApply tm -- pair, two implicits
        = do let l' = toFDesc l
             r' <- irTerm (sMN 0 "__foreignCall") vs env r
             return (l', r')
    splitArg _ = ifail $ "Badly formed foreign function call: " ++
                         show (ret : fname : world : args)


    toFDesc (Constant (Str str)) = FStr str
    toFDesc tm
       | (P _ n _, []) <- unApply tm = FCon (deNS n)
       | (P _ n _, as) <- unApply tm = FApp (deNS n) (map toFDesc as)
    toFDesc _ = FUnknown

    deNS (NS n _) = n
    deNS n = n
doForeign vs env xs = ifail "Badly formed foreign function call"

irTree :: Name -> [Name] -> SC -> Idris LExp
irTree top args tree = do
    logCodeGen 3 $ "Compiling " ++ show args ++ "\n" ++ show tree
    LLam args <$> irSC top M.empty tree

irSC :: Name -> Vars -> SC -> Idris LExp
irSC top vs (STerm t) = irTerm top vs [] t
irSC top vs (UnmatchedCase str) = return $ LLazyExp $ LError str

irSC top vs (ProjCase tm alts) = do
    tm'   <- irTerm top vs [] tm
    alts' <- mapM (irAlt top vs tm') alts
    return $ LCase Shared tm' alts'

-- Transform matching on Delay to applications of Force.
irSC top vs (Case up n [ConCase (UN delay) i [_, _, n'] sc])
    | delay == txt "Delay"
    = do sc' <- irSC top vs sc -- mkForce n' n sc
         return $ lsubst n' (LForce (LV n)) sc'

-- There are two transformations in this case:
--
--  1. Newtype-case elimination:
--      case {e0} of
--          wrap({e1}) -> P({e1})   ==>   P({e0})
--
-- This is important because newtyped constructors are compiled away entirely
-- and we need to do that everywhere.
--
--  2. Unused-case elimination (only valid for singleton branches):
--      case {e0} of                                ==>     P
--          C(x,y) -> P[... x,y not used ...]
--
-- This is important for runtime because sometimes we case on irrelevant data:
--
-- In the example above, {e0} will most probably have been erased
-- so this vain projection would make the resulting program segfault
-- because the code generator still emits a PROJECT(...) G-machine instruction.
--
-- Hence, we check whether the variables are used at all
-- and erase the casesplit if they are not.
--
irSC top vs (Case up n [alt]) = do
    replacement <- case alt of
        ConCase cn a ns sc -> do
            detag <- fgetState (opt_detaggable . ist_optimisation cn)
            used  <- map fst <$> fgetState (cg_usedpos . ist_callgraph cn)
            if detag && length used == 1
                then return . Just $ substSC (ns !! head used) n sc
                else return Nothing
        _ -> return Nothing

    case replacement of
        Just sc -> irSC top vs sc
        _ -> do
            alt' <- irAlt top vs (LV n) alt
            return $ case namesBoundIn alt' `usedIn` subexpr alt' of
                [] -> subexpr alt'  -- strip the unused top-most case
                _  -> LCase up (LV n) [alt']
  where
    namesBoundIn :: LAlt -> [Name]
    namesBoundIn (LConCase cn i ns sc) = ns
    namesBoundIn (LConstCase c sc)     = []
    namesBoundIn (LDefaultCase sc)     = []

    subexpr :: LAlt -> LExp
    subexpr (LConCase _ _ _ e) = e
    subexpr (LConstCase _   e) = e
    subexpr (LDefaultCase   e) = e

-- FIXME: When we have a non-singleton case-tree of the form
--
--     case {e0} of
--         C(x) => ...
--         ...  => ...
--
-- and C is detaggable (the only constructor of the family), we can be sure
-- that the first branch will be always taken -- so we add special handling
-- to remove the dead default branch.
--
-- If we don't do so and C is newtype-optimisable, we will miss this newtype
-- transformation and the resulting code will probably segfault.
--
-- This work-around is not entirely optimal; the best approach would be
-- to ensure that such case trees don't arise in the first place.
--
irSC top vs (Case up n alts@[ConCase cn a ns sc, DefaultCase sc']) = do
    detag <- fgetState (opt_detaggable . ist_optimisation cn)
    if detag
        then irSC top vs (Case up n [ConCase cn a ns sc])
        else LCase up (LV n) <$> mapM (irAlt top vs (LV n)) alts

irSC top vs sc@(Case up n alts) = do
    -- check that neither alternative needs the newtype optimisation,
    -- see comment above
    goneWrong <- or <$> mapM isDetaggable alts
    when goneWrong
        $ ifail ("irSC: non-trivial case-match on detaggable data: " ++ show sc)

    -- everything okay
    LCase up (LV n) <$> mapM (irAlt top vs (LV n)) alts
  where
    isDetaggable (ConCase cn _ _ _) = fgetState $ opt_detaggable . ist_optimisation cn
    isDetaggable  _                 = return False

irSC top vs ImpossibleCase = return LNothing

irAlt :: Name -> Vars -> LExp -> CaseAlt -> Idris LAlt

-- this leaves out all unused arguments of the constructor
irAlt top vs _ (ConCase n t args sc) = do
    used <- map fst <$> fgetState (cg_usedpos . ist_callgraph n)
    let usedArgs = [a | (i,a) <- zip [0..] args, i `elem` used]
    LConCase (-1) n usedArgs <$> irSC top (methodVars `M.union` vs) sc
  where
    methodVars = case n of
        SN (ImplementationCtorN interfaceName)
            -> M.fromList [(v, VI
                { viMethod = Just $ mkFieldName n i
                }) | (v,i) <- zip args [0..]]
        _
            -> M.empty -- not an implementation constructor

irAlt top vs _ (ConstCase x rhs)
    | matchable   x = LConstCase x <$> irSC top vs rhs
    | matchableTy x = LDefaultCase <$> irSC top vs rhs
  where
    matchable (I _) = True
    matchable (BI _) = True
    matchable (Ch _) = True
    matchable (Str _) = True
    matchable (B8 _) = True
    matchable (B16 _) = True
    matchable (B32 _) = True
    matchable (B64 _) = True
    matchable _ = False

    matchableTy (AType (ATInt ITNative)) = True
    matchableTy (AType (ATInt ITBig)) = True
    matchableTy (AType (ATInt ITChar)) = True
    matchableTy StrType = True

    matchableTy (AType (ATInt (ITFixed IT8)))  = True
    matchableTy (AType (ATInt (ITFixed IT16))) = True
    matchableTy (AType (ATInt (ITFixed IT32))) = True
    matchableTy (AType (ATInt (ITFixed IT64))) = True

    matchableTy _ = False

irAlt top vs tm (SucCase n rhs) = do
    rhs' <- irSC top vs rhs
    return $ LDefaultCase (LLet n (LOp (LMinus (ATInt ITBig))
                                            [tm,
                                            LConst (BI 1)]) rhs')

irAlt top vs _ (ConstCase c rhs)
    = ifail $ "Can't match on (" ++ show c ++ ")"

irAlt top vs _ (DefaultCase rhs)
    = LDefaultCase <$> irSC top vs rhs