module IRTS.Compiler where
import IRTS.Lang
import IRTS.Defunctionalise
import IRTS.Simplified
import IRTS.CodegenCommon
import IRTS.CodegenC
import IRTS.CodegenJava
import IRTS.DumpBC
import IRTS.CodegenJavaScript
#ifdef IDRIS_LLVM
import IRTS.CodegenLLVM
#else
import Util.LLVMStubs
#endif
import IRTS.Inliner
import Idris.AbsSyntax
import Idris.UnusedArgs
import Idris.Error
import Idris.Core.TT
import Idris.Core.Evaluate
import Idris.Core.CaseTree
import Control.Monad.State
import Data.List
import System.Process
import System.IO
import System.Directory
import System.Environment
import System.FilePath ((</>), addTrailingPathSeparator)
import Paths_idris
compile :: Codegen -> FilePath -> Term -> Idris ()
compile codegen f tm
= do checkMVs
let tmnames = namesUsed (STerm tm)
usedIn <- mapM (allNames []) tmnames
let used = [sUN "prim__subBigInt", sUN "prim__addBigInt"] : usedIn
defsIn <- mkDecls tm (concat used)
findUnusedArgs (concat used)
maindef <- irMain tm
objs <- getObjectFiles codegen
libs <- getLibs codegen
flags <- getFlags codegen
hdrs <- getHdrs codegen
impdirs <- allImportDirs
let defs = defsIn ++ [(sMN 0 "runMain", maindef)]
let (nexttag, tagged) = addTags 65536 (liftAll defs)
let ctxtIn = addAlist tagged emptyContext
iLOG "Defunctionalising"
let defuns_in = defunctionalise nexttag ctxtIn
logLvl 5 $ show defuns_in
iLOG "Inlining"
let defuns = inline defuns_in
logLvl 5 $ show defuns
iLOG "Resolving variables for CG"
let checked = checkDefs defuns (toAlist defuns)
outty <- outputTy
dumpCases <- getDumpCases
dumpDefun <- getDumpDefun
case dumpCases of
Nothing -> return ()
Just f -> runIO $ writeFile f (showCaseTrees defs)
case dumpDefun of
Nothing -> return ()
Just f -> runIO $ writeFile f (dumpDefuns defuns)
triple <- targetTriple
cpu <- targetCPU
optimize <- optLevel
iLOG "Building output"
case checked of
OK c -> runIO $ case codegen of
ViaC ->
codegenC c f outty hdrs
(concatMap mkObj objs)
(concatMap mkLib libs)
(concatMap mkFlag flags ++
concatMap incdir impdirs) NONE
ViaJava ->
codegenJava [] c f hdrs libs outty
ViaJavaScript ->
codegenJavaScript JavaScript c f outty
ViaNode ->
codegenJavaScript Node c f outty
ViaLLVM -> codegenLLVM c triple cpu optimize f outty
Bytecode -> dumpBC c f
Error e -> ierror e
where checkMVs = do i <- getIState
case map fst (idris_metavars i) \\ primDefs of
[] -> return ()
ms -> ifail $ "There are undefined metavariables: " ++ show ms
inDir d h = do let f = d </> h
ex <- doesFileExist f
if ex then return f else return h
mkObj f = f ++ " "
mkLib l = "-l" ++ l ++ " "
mkFlag l = l ++ " "
incdir i = "-I" ++ i ++ " "
irMain :: TT Name -> Idris LDecl
irMain tm = do i <- ir tm
return $ LFun [] (sMN 0 "runMain") [] (LForce i)
mkDecls :: Term -> [Name] -> Idris [(Name, LDecl)]
mkDecls t used
= do i <- getIState
let ds = filter (\ (n, d) -> n `elem` used || isCon d) $ ctxtAlist (tt_ctxt i)
mapM traceUnused used
decls <- mapM build ds
return decls
showCaseTrees :: [(Name, LDecl)] -> String
showCaseTrees ds = showSep "\n\n" (map showCT ds)
where
showCT (n, LFun _ f args lexp)
= show n ++ " " ++ showSep " " (map show args) ++ " =\n\t "
++ show lexp
showCT (n, LConstructor c t a) = "data " ++ show n ++ " " ++ show a
isCon (TyDecl _ _) = True
isCon _ = False
class ToIR a where
ir :: a -> Idris LExp
build :: (Name, Def) -> Idris (Name, LDecl)
build (n, d)
= do i <- getIState
case lookup n (idris_scprims 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 . Glob) (take ar args)))))
_ -> do def <- mkLDecl n d
logLvl 3 $ "Compiled " ++ show n ++ " =\n\t" ++ show def
return (n, def)
getPrim :: IState -> Name -> [LExp] -> Maybe LExp
getPrim i n args = case lookup n (idris_scprims i) of
Just (ar, op) ->
if (ar == length args)
then return (LOp op args)
else Nothing
_ -> 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 _) = do e <- ir tm
return (declArgs [] True n e)
mkLDecl n (CaseOp ci _ _ _ pats cd)
= let (args, sc) = cases_runtime cd in
do e <- ir (args, sc)
return (declArgs [] (case_inlinable ci) n e)
mkLDecl n (TyDecl (DCon t a) _) = return $ LConstructor n t a
mkLDecl n (TyDecl (TCon t a) _) = return $ LConstructor n (1) a
mkLDecl n _ = return (LFun [] n [] (LError ("Impossible declaration " ++ show n)))
instance ToIR (TT Name) where
ir tm = ir' [] tm where
ir' env tm@(App f a)
| (P _ (UN m) _, args) <- unApply tm,
m == txt "mkForeignPrim"
= doForeign env args
| (P _ (UN u) _, [_, arg]) <- unApply tm,
u == txt "unsafePerformPrimIO"
= ir' env arg
| (P _ (UN r) _, [_, _, _, _, _, arg]) <- unApply tm,
r == txt "replace"
= ir' env arg
| (P _ (UN l) _, [_, arg]) <- unApply tm,
l == txt "lazy"
= do arg' <- ir' env arg
return $ LLazyExp arg'
| (P _ (UN a) _, [_, _, arg]) <- unApply tm,
a == txt "assert_smaller"
= ir' env arg
| (P _ (UN a) _, [_, arg]) <- unApply tm,
a == txt "assert_total"
= ir' env arg
| (P _ (UN p) _, [_, arg]) <- unApply tm,
p == txt "par"
= do arg' <- ir' env arg
return $ LOp LPar [LLazyExp arg']
| (P _ (UN pf) _, [arg]) <- unApply tm,
pf == txt "prim_fork"
= do arg' <- ir' env arg
return $ LOp LFork [LLazyExp arg']
| (P _ (UN m) _, [_,size,t]) <- unApply tm,
m == txt "malloc"
= do size' <- ir' env size
t' <- ir' env t
return t'
| (P _ (UN tm) _, [_,t]) <- unApply tm,
tm == txt "trace_malloc"
= do t' <- ir' env t
return t'
| (P (DCon t a) n _, args) <- unApply tm
= irCon env t a n args
| (P (TCon t a) n _, args) <- unApply tm
= return LNothing
| (P _ n _, args) <- unApply tm
= do i <- getIState
args' <- mapM (ir' env) args
case getPrim i n args' of
Just tm -> return tm
_ -> do
let collapse
= case lookupCtxtExact n
(idris_optimisation i) of
Just oi -> collapsible oi
_ -> False
let unused
= case lookupCtxtExact n
(idris_callgraph i) of
Just (CGInfo _ _ _ _ unusedpos) ->
unusedpos
_ -> []
if collapse
then return LNothing
else return (LApp False (LV (Glob n))
(mkUnused unused 0 args'))
| (f, args) <- unApply tm
= do f' <- ir' env f
args' <- mapM (ir' env) args
return (LApp False f' args')
where mkUnused u i [] = []
mkUnused u i (x : xs) | i `elem` u = LNothing : mkUnused u (i + 1) xs
| otherwise = x : mkUnused u (i + 1) xs
ir' env (P _ n _) = return $ LV (Glob n)
ir' env (V i) | i >= 0 && i < length env = return $ LV (Glob (env!!i))
| otherwise = ifail $ "IR fail " ++ show i ++ " " ++ show tm
ir' env (Bind n (Lam _) sc)
= do let n' = uniqueName n env
sc' <- ir' (n' : env) sc
return $ LLam [n'] sc'
ir' env (Bind n (Let _ v) sc)
= do sc' <- ir' (n : env) sc
v' <- ir' env v
return $ LLet n v' sc'
ir' env (Bind _ _ _) = return $ LNothing
ir' env (Proj t i) | i == 1
= do t' <- ir' env t
return $ LOp (LMinus (ATInt ITBig))
[t', LConst (BI 1)]
ir' env (Proj t i) = do t' <- ir' env t
return $ LProj t' i
ir' env (Constant c) = return $ LConst c
ir' env (TType _) = return $ LNothing
ir' env Erased = return $ LNothing
ir' env Impossible = return $ LNothing
irCon env t arity n args
| length args == arity = buildApp env (LV (Glob n)) args
| otherwise = let extra = satArgs (arity length args) in
do sc' <- irCon env t arity n
(args ++ map (\n -> P Bound n undefined) extra)
return $ LLam extra sc'
satArgs n = map (\i -> sMN i "sat") [1..n]
buildApp env e [] = return e
buildApp env e xs = do xs' <- mapM (ir' env) xs
return $ LApp False e xs'
doForeign :: [Name] -> [TT Name] -> Idris LExp
doForeign env (_ : fgn : args)
| (_, (Constant (Str fgnName) : fgnArgTys : ret : [])) <- unApply fgn
= let maybeTys = getFTypes fgnArgTys
rty = mkIty' ret in
case maybeTys of
Nothing -> ifail $ "Foreign type specification is not a constant list: " ++ show (fgn:args)
Just tys -> do
args' <- mapM (ir' env) (init args)
return $
LForeign LANG_C rty fgnName (zip tys args')
| otherwise = ifail "Badly formed foreign function call"
getFTypes :: TT Name -> Maybe [FType]
getFTypes tm = case unApply tm of
(nil, []) -> Just []
(cons, [ty, xs]) ->
fmap (mkIty' ty :) (getFTypes xs)
_ -> Nothing
mkIty' (P _ (UN ty) _) = mkIty (str ty)
mkIty' (App (P _ (UN fi) _) (P _ (UN intTy) _))
| fi == txt "FIntT" = mkIntIty (str intTy)
mkIty' (App (App (P _ (UN ff) _) _) (App (P _ (UN fa) _) (App (P _ (UN io) _) _)))
| ff == txt "FFunction" && fa == txt "FAny" &&
io == txt "IO"
= FFunctionIO
mkIty' (App (App (P _ (UN ff) _) _) _)
| ff == txt "FFunction" = FFunction
mkIty' _ = FAny
mkIty "FFloat" = FArith ATFloat
mkIty "FInt" = mkIntIty "ITNative"
mkIty "FChar" = mkIntIty "ITChar"
mkIty "FByte" = mkIntIty "IT8"
mkIty "FShort" = mkIntIty "IT16"
mkIty "FLong" = mkIntIty "IT64"
mkIty "FBits8" = mkIntIty "IT8"
mkIty "FBits16" = mkIntIty "IT16"
mkIty "FBits32" = mkIntIty "IT32"
mkIty "FBits64" = mkIntIty "IT64"
mkIty "FString" = FString
mkIty "FPtr" = FPtr
mkIty "FUnit" = FUnit
mkIty "FFunction" = FFunction
mkIty "FFunctionIO" = FFunctionIO
mkIty "FBits8x16" = FArith (ATInt (ITVec IT8 16))
mkIty "FBits16x8" = FArith (ATInt (ITVec IT16 8))
mkIty "FBits32x4" = FArith (ATInt (ITVec IT32 4))
mkIty "FBits64x2" = FArith (ATInt (ITVec IT64 2))
mkIty x = error $ "Unknown type " ++ x
mkIntIty "ITNative" = FArith (ATInt ITNative)
mkIntIty "ITChar" = FArith (ATInt ITChar)
mkIntIty "IT8" = FArith (ATInt (ITFixed IT8))
mkIntIty "IT16" = FArith (ATInt (ITFixed IT16))
mkIntIty "IT32" = FArith (ATInt (ITFixed IT32))
mkIntIty "IT64" = FArith (ATInt (ITFixed IT64))
zname = sNS (sUN "Z") ["Nat","Prelude"]
sname = sNS (sUN "S") ["Nat","Prelude"]
instance ToIR ([Name], SC) where
ir (args, tree) = do logLvl 3 $ "Compiling " ++ show args ++ "\n" ++ show tree
tree' <- ir tree
return $ LLam args tree'
instance ToIR SC where
ir t = ir' t where
ir' (STerm t) = ir t
ir' (UnmatchedCase str) = return $ LError str
ir' (ProjCase tm alts) = do tm' <- ir tm
alts' <- mapM (mkIRAlt tm') alts
return $ LCase tm' alts'
ir' (Case n alts) = do alts' <- mapM (mkIRAlt (LV (Glob n))) alts
return $ LCase (LV (Glob n)) alts'
ir' ImpossibleCase = return LNothing
mkIRAlt _ (ConCase n t args rhs)
= do rhs' <- ir rhs
return $ LConCase (1) n args rhs'
mkIRAlt _ (ConstCase x rhs)
| matchable x
= do rhs' <- ir rhs
return $ LConstCase x rhs'
| matchableTy x
= do rhs' <- ir rhs
return $ LDefaultCase rhs'
mkIRAlt tm (SucCase n rhs)
= do rhs' <- ir rhs
return $ LDefaultCase (LLet n (LOp (LMinus (ATInt ITBig))
[tm,
LConst (BI 1)]) rhs')
mkIRAlt _ (ConstCase c rhs)
= ifail $ "Can't match on (" ++ show c ++ ")"
mkIRAlt _ (DefaultCase rhs)
= do rhs' <- ir rhs
return $ LDefaultCase rhs'
matchable (I _) = True
matchable (BI _) = True
matchable (Ch _) = True
matchable (Str _) = 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