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|
-----------------------------------------------------------------------------
--
-- GHC Interactive support for inspecting arbitrary closures at runtime
--
-- Pepe Iborra (supported by Google SoC) 2006
--
-----------------------------------------------------------------------------
{-# OPTIONS -fno-warn-tabs #-}
-- The above warning supression flag is a temporary kludge.
-- While working on this module you are encouraged to remove it and
-- detab the module (please do the detabbing in a separate patch). See
-- http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#TabsvsSpaces
-- for details
module RtClosureInspect(
cvObtainTerm, -- :: HscEnv -> Int -> Bool -> Maybe Type -> HValue -> IO Term
cvReconstructType,
improveRTTIType,
Term(..),
isTerm, isSuspension, isPrim, isFun, isFunLike, isNewtypeWrap,
isFullyEvaluated, isFullyEvaluatedTerm,
termType, mapTermType, termTyVars,
foldTerm, TermFold(..), foldTermM, TermFoldM(..), idTermFold,
pprTerm, cPprTerm, cPprTermBase, CustomTermPrinter,
-- unsafeDeepSeq,
Closure(..), getClosureData, ClosureType(..), isConstr, isIndirection
) where
#include "HsVersions.h"
import DebuggerUtils
import ByteCodeItbls ( StgInfoTable, peekItbl )
import qualified ByteCodeItbls as BCI( StgInfoTable(..) )
import BasicTypes ( HValue )
import HscTypes
import DataCon
import Type
import qualified Unify as U
import Var
import TcRnMonad
import TcType
import TcMType
import TcHsSyn ( zonkTcTypeToType, mkEmptyZonkEnv )
import TcUnify
import TcEnv
import TyCon
import Name
import VarEnv
import Util
import VarSet
import BasicTypes ( TupleSort(UnboxedTuple) )
import TysPrim
import PrelNames
import TysWiredIn
import DynFlags
import Outputable as Ppr
import GHC.Arr ( Array(..) )
import GHC.Exts
import GHC.IO ( IO(..) )
import StaticFlags( opt_PprStyle_Debug )
import Control.Monad
import Data.Maybe
import Data.Array.Base
import Data.Ix
import Data.List
import qualified Data.Sequence as Seq
import Data.Monoid (mappend)
import Data.Sequence (viewl, ViewL(..))
import Foreign.Safe
import System.IO.Unsafe
---------------------------------------------
-- * A representation of semi evaluated Terms
---------------------------------------------
data Term = Term { ty :: RttiType
, dc :: Either String DataCon
-- Carries a text representation if the datacon is
-- not exported by the .hi file, which is the case
-- for private constructors in -O0 compiled libraries
, val :: HValue
, subTerms :: [Term] }
| Prim { ty :: RttiType
, value :: [Word] }
| Suspension { ctype :: ClosureType
, ty :: RttiType
, val :: HValue
, bound_to :: Maybe Name -- Useful for printing
}
| NewtypeWrap{ -- At runtime there are no newtypes, and hence no
-- newtype constructors. A NewtypeWrap is just a
-- made-up tag saying "heads up, there used to be
-- a newtype constructor here".
ty :: RttiType
, dc :: Either String DataCon
, wrapped_term :: Term }
| RefWrap { -- The contents of a reference
ty :: RttiType
, wrapped_term :: Term }
isTerm, isSuspension, isPrim, isFun, isFunLike, isNewtypeWrap :: Term -> Bool
isTerm Term{} = True
isTerm _ = False
isSuspension Suspension{} = True
isSuspension _ = False
isPrim Prim{} = True
isPrim _ = False
isNewtypeWrap NewtypeWrap{} = True
isNewtypeWrap _ = False
isFun Suspension{ctype=Fun} = True
isFun _ = False
isFunLike s@Suspension{ty=ty} = isFun s || isFunTy ty
isFunLike _ = False
termType :: Term -> RttiType
termType t = ty t
isFullyEvaluatedTerm :: Term -> Bool
isFullyEvaluatedTerm Term {subTerms=tt} = all isFullyEvaluatedTerm tt
isFullyEvaluatedTerm Prim {} = True
isFullyEvaluatedTerm NewtypeWrap{wrapped_term=t} = isFullyEvaluatedTerm t
isFullyEvaluatedTerm RefWrap{wrapped_term=t} = isFullyEvaluatedTerm t
isFullyEvaluatedTerm _ = False
instance Outputable (Term) where
ppr t | Just doc <- cPprTerm cPprTermBase t = doc
| otherwise = panic "Outputable Term instance"
-------------------------------------------------------------------------
-- Runtime Closure Datatype and functions for retrieving closure related stuff
-------------------------------------------------------------------------
data ClosureType = Constr
| Fun
| Thunk Int
| ThunkSelector
| Blackhole
| AP
| PAP
| Indirection Int
| MutVar Int
| MVar Int
| Other Int
deriving (Show, Eq)
data Closure = Closure { tipe :: ClosureType
, infoPtr :: Ptr ()
, infoTable :: StgInfoTable
, ptrs :: Array Int HValue
, nonPtrs :: [Word]
}
instance Outputable ClosureType where
ppr = text . show
#include "../includes/rts/storage/ClosureTypes.h"
aP_CODE, pAP_CODE :: Int
aP_CODE = AP
pAP_CODE = PAP
#undef AP
#undef PAP
getClosureData :: DynFlags -> a -> IO Closure
getClosureData dflags a =
case unpackClosure# a of
(# iptr, ptrs, nptrs #) -> do
let iptr'
| ghciTablesNextToCode =
Ptr iptr
| otherwise =
-- the info pointer we get back from unpackClosure#
-- is to the beginning of the standard info table,
-- but the Storable instance for info tables takes
-- into account the extra entry pointer when
-- !ghciTablesNextToCode, so we must adjust here:
Ptr iptr `plusPtr` negate (wORD_SIZE dflags)
itbl <- peekItbl dflags iptr'
let tipe = readCType (BCI.tipe itbl)
elems = fromIntegral (BCI.ptrs itbl)
ptrsList = Array 0 (elems - 1) elems ptrs
nptrs_data = [W# (indexWordArray# nptrs i)
| I# i <- [0.. fromIntegral (BCI.nptrs itbl)-1] ]
ASSERT(elems >= 0) return ()
ptrsList `seq`
return (Closure tipe (Ptr iptr) itbl ptrsList nptrs_data)
readCType :: Integral a => a -> ClosureType
readCType i
| i >= CONSTR && i <= CONSTR_NOCAF_STATIC = Constr
| i >= FUN && i <= FUN_STATIC = Fun
| i >= THUNK && i < THUNK_SELECTOR = Thunk i'
| i == THUNK_SELECTOR = ThunkSelector
| i == BLACKHOLE = Blackhole
| i >= IND && i <= IND_STATIC = Indirection i'
| i' == aP_CODE = AP
| i == AP_STACK = AP
| i' == pAP_CODE = PAP
| i == MUT_VAR_CLEAN || i == MUT_VAR_DIRTY= MutVar i'
| i == MVAR_CLEAN || i == MVAR_DIRTY = MVar i'
| otherwise = Other i'
where i' = fromIntegral i
isConstr, isIndirection, isThunk :: ClosureType -> Bool
isConstr Constr = True
isConstr _ = False
isIndirection (Indirection _) = True
isIndirection _ = False
isThunk (Thunk _) = True
isThunk ThunkSelector = True
isThunk AP = True
isThunk _ = False
isFullyEvaluated :: DynFlags -> a -> IO Bool
isFullyEvaluated dflags a = do
closure <- getClosureData dflags a
case tipe closure of
Constr -> do are_subs_evaluated <- amapM (isFullyEvaluated dflags) (ptrs closure)
return$ and are_subs_evaluated
_ -> return False
where amapM f = sequence . amap' f
-- TODO: Fix it. Probably the otherwise case is failing, trace/debug it
{-
unsafeDeepSeq :: a -> b -> b
unsafeDeepSeq = unsafeDeepSeq1 2
where unsafeDeepSeq1 0 a b = seq a $! b
unsafeDeepSeq1 i a b -- 1st case avoids infinite loops for non reducible thunks
| not (isConstr tipe) = seq a $! unsafeDeepSeq1 (i-1) a b
-- | unsafePerformIO (isFullyEvaluated a) = b
| otherwise = case unsafePerformIO (getClosureData a) of
closure -> foldl' (flip unsafeDeepSeq) b (ptrs closure)
where tipe = unsafePerformIO (getClosureType a)
-}
-----------------------------------
-- * Traversals for Terms
-----------------------------------
type TermProcessor a b = RttiType -> Either String DataCon -> HValue -> [a] -> b
data TermFold a = TermFold { fTerm :: TermProcessor a a
, fPrim :: RttiType -> [Word] -> a
, fSuspension :: ClosureType -> RttiType -> HValue
-> Maybe Name -> a
, fNewtypeWrap :: RttiType -> Either String DataCon
-> a -> a
, fRefWrap :: RttiType -> a -> a
}
data TermFoldM m a =
TermFoldM {fTermM :: TermProcessor a (m a)
, fPrimM :: RttiType -> [Word] -> m a
, fSuspensionM :: ClosureType -> RttiType -> HValue
-> Maybe Name -> m a
, fNewtypeWrapM :: RttiType -> Either String DataCon
-> a -> m a
, fRefWrapM :: RttiType -> a -> m a
}
foldTerm :: TermFold a -> Term -> a
foldTerm tf (Term ty dc v tt) = fTerm tf ty dc v (map (foldTerm tf) tt)
foldTerm tf (Prim ty v ) = fPrim tf ty v
foldTerm tf (Suspension ct ty v b) = fSuspension tf ct ty v b
foldTerm tf (NewtypeWrap ty dc t) = fNewtypeWrap tf ty dc (foldTerm tf t)
foldTerm tf (RefWrap ty t) = fRefWrap tf ty (foldTerm tf t)
foldTermM :: Monad m => TermFoldM m a -> Term -> m a
foldTermM tf (Term ty dc v tt) = mapM (foldTermM tf) tt >>= fTermM tf ty dc v
foldTermM tf (Prim ty v ) = fPrimM tf ty v
foldTermM tf (Suspension ct ty v b) = fSuspensionM tf ct ty v b
foldTermM tf (NewtypeWrap ty dc t) = foldTermM tf t >>= fNewtypeWrapM tf ty dc
foldTermM tf (RefWrap ty t) = foldTermM tf t >>= fRefWrapM tf ty
idTermFold :: TermFold Term
idTermFold = TermFold {
fTerm = Term,
fPrim = Prim,
fSuspension = Suspension,
fNewtypeWrap = NewtypeWrap,
fRefWrap = RefWrap
}
mapTermType :: (RttiType -> Type) -> Term -> Term
mapTermType f = foldTerm idTermFold {
fTerm = \ty dc hval tt -> Term (f ty) dc hval tt,
fSuspension = \ct ty hval n ->
Suspension ct (f ty) hval n,
fNewtypeWrap= \ty dc t -> NewtypeWrap (f ty) dc t,
fRefWrap = \ty t -> RefWrap (f ty) t}
mapTermTypeM :: Monad m => (RttiType -> m Type) -> Term -> m Term
mapTermTypeM f = foldTermM TermFoldM {
fTermM = \ty dc hval tt -> f ty >>= \ty' -> return $ Term ty' dc hval tt,
fPrimM = (return.) . Prim,
fSuspensionM = \ct ty hval n ->
f ty >>= \ty' -> return $ Suspension ct ty' hval n,
fNewtypeWrapM= \ty dc t -> f ty >>= \ty' -> return $ NewtypeWrap ty' dc t,
fRefWrapM = \ty t -> f ty >>= \ty' -> return $ RefWrap ty' t}
termTyVars :: Term -> TyVarSet
termTyVars = foldTerm TermFold {
fTerm = \ty _ _ tt ->
tyVarsOfType ty `plusVarEnv` concatVarEnv tt,
fSuspension = \_ ty _ _ -> tyVarsOfType ty,
fPrim = \ _ _ -> emptyVarEnv,
fNewtypeWrap= \ty _ t -> tyVarsOfType ty `plusVarEnv` t,
fRefWrap = \ty t -> tyVarsOfType ty `plusVarEnv` t}
where concatVarEnv = foldr plusVarEnv emptyVarEnv
----------------------------------
-- Pretty printing of terms
----------------------------------
type Precedence = Int
type TermPrinter = Precedence -> Term -> SDoc
type TermPrinterM m = Precedence -> Term -> m SDoc
app_prec,cons_prec, max_prec ::Int
max_prec = 10
app_prec = max_prec
cons_prec = 5 -- TODO Extract this info from GHC itself
pprTerm :: TermPrinter -> TermPrinter
pprTerm y p t | Just doc <- pprTermM (\p -> Just . y p) p t = doc
pprTerm _ _ _ = panic "pprTerm"
pprTermM, ppr_termM, pprNewtypeWrap :: Monad m => TermPrinterM m -> TermPrinterM m
pprTermM y p t = pprDeeper `liftM` ppr_termM y p t
ppr_termM y p Term{dc=Left dc_tag, subTerms=tt} = do
tt_docs <- mapM (y app_prec) tt
return $ cparen (not (null tt) && p >= app_prec)
(text dc_tag <+> pprDeeperList fsep tt_docs)
ppr_termM y p Term{dc=Right dc, subTerms=tt}
{- | dataConIsInfix dc, (t1:t2:tt') <- tt --TODO fixity
= parens (ppr_term1 True t1 <+> ppr dc <+> ppr_term1 True ppr t2)
<+> hsep (map (ppr_term1 True) tt)
-} -- TODO Printing infix constructors properly
| null sub_terms_to_show
= return (ppr dc)
| otherwise
= do { tt_docs <- mapM (y app_prec) sub_terms_to_show
; return $ cparen (p >= app_prec) $
sep [ppr dc, nest 2 (pprDeeperList fsep tt_docs)] }
where
sub_terms_to_show -- Don't show the dictionary arguments to
-- constructors unless -dppr-debug is on
| opt_PprStyle_Debug = tt
| otherwise = dropList (dataConTheta dc) tt
ppr_termM y p t@NewtypeWrap{} = pprNewtypeWrap y p t
ppr_termM y p RefWrap{wrapped_term=t} = do
contents <- y app_prec t
return$ cparen (p >= app_prec) (text "GHC.Prim.MutVar#" <+> contents)
-- The constructor name is wired in here ^^^ for the sake of simplicity.
-- I don't think mutvars are going to change in a near future.
-- In any case this is solely a presentation matter: MutVar# is
-- a datatype with no constructors, implemented by the RTS
-- (hence there is no way to obtain a datacon and print it).
ppr_termM _ _ t = ppr_termM1 t
ppr_termM1 :: Monad m => Term -> m SDoc
ppr_termM1 Prim{value=words, ty=ty} =
return $ repPrim (tyConAppTyCon ty) words
ppr_termM1 Suspension{ty=ty, bound_to=Nothing} =
return (char '_' <+> ifPprDebug (text "::" <> ppr ty))
ppr_termM1 Suspension{ty=ty, bound_to=Just n}
-- | Just _ <- splitFunTy_maybe ty = return$ ptext (sLit("<function>")
| otherwise = return$ parens$ ppr n <> text "::" <> ppr ty
ppr_termM1 Term{} = panic "ppr_termM1 - Term"
ppr_termM1 RefWrap{} = panic "ppr_termM1 - RefWrap"
ppr_termM1 NewtypeWrap{} = panic "ppr_termM1 - NewtypeWrap"
pprNewtypeWrap y p NewtypeWrap{ty=ty, wrapped_term=t}
| Just (tc,_) <- tcSplitTyConApp_maybe ty
, ASSERT(isNewTyCon tc) True
, Just new_dc <- tyConSingleDataCon_maybe tc = do
real_term <- y max_prec t
return $ cparen (p >= app_prec) (ppr new_dc <+> real_term)
pprNewtypeWrap _ _ _ = panic "pprNewtypeWrap"
-------------------------------------------------------
-- Custom Term Pretty Printers
-------------------------------------------------------
-- We can want to customize the representation of a
-- term depending on its type.
-- However, note that custom printers have to work with
-- type representations, instead of directly with types.
-- We cannot use type classes here, unless we employ some
-- typerep trickery (e.g. Weirich's RepLib tricks),
-- which I didn't. Therefore, this code replicates a lot
-- of what type classes provide for free.
type CustomTermPrinter m = TermPrinterM m
-> [Precedence -> Term -> (m (Maybe SDoc))]
-- | Takes a list of custom printers with a explicit recursion knot and a term,
-- and returns the output of the first succesful printer, or the default printer
cPprTerm :: Monad m => CustomTermPrinter m -> Term -> m SDoc
cPprTerm printers_ = go 0 where
printers = printers_ go
go prec t = do
let default_ = Just `liftM` pprTermM go prec t
mb_customDocs = [pp prec t | pp <- printers] ++ [default_]
Just doc <- firstJustM mb_customDocs
return$ cparen (prec>app_prec+1) doc
firstJustM (mb:mbs) = mb >>= maybe (firstJustM mbs) (return . Just)
firstJustM [] = return Nothing
-- Default set of custom printers. Note that the recursion knot is explicit
cPprTermBase :: forall m. Monad m => CustomTermPrinter m
cPprTermBase y =
[ ifTerm (isTupleTy.ty) (\_p -> liftM (parens . hcat . punctuate comma)
. mapM (y (-1))
. subTerms)
, ifTerm (\t -> isTyCon listTyCon (ty t) && subTerms t `lengthIs` 2)
ppr_list
, ifTerm (isTyCon intTyCon . ty) ppr_int
, ifTerm (isTyCon charTyCon . ty) ppr_char
, ifTerm (isTyCon floatTyCon . ty) ppr_float
, ifTerm (isTyCon doubleTyCon . ty) ppr_double
, ifTerm (isIntegerTy . ty) ppr_integer
]
where
ifTerm :: (Term -> Bool)
-> (Precedence -> Term -> m SDoc)
-> Precedence -> Term -> m (Maybe SDoc)
ifTerm pred f prec t@Term{}
| pred t = Just `liftM` f prec t
ifTerm _ _ _ _ = return Nothing
isTupleTy ty = fromMaybe False $ do
(tc,_) <- tcSplitTyConApp_maybe ty
return (isBoxedTupleTyCon tc)
isTyCon a_tc ty = fromMaybe False $ do
(tc,_) <- tcSplitTyConApp_maybe ty
return (a_tc == tc)
isIntegerTy ty = fromMaybe False $ do
(tc,_) <- tcSplitTyConApp_maybe ty
return (tyConName tc == integerTyConName)
ppr_int, ppr_char, ppr_float, ppr_double, ppr_integer
:: Precedence -> Term -> m SDoc
ppr_int _ v = return (Ppr.int (unsafeCoerce# (val v)))
ppr_char _ v = return (Ppr.char '\'' <> Ppr.char (unsafeCoerce# (val v)) <> Ppr.char '\'')
ppr_float _ v = return (Ppr.float (unsafeCoerce# (val v)))
ppr_double _ v = return (Ppr.double (unsafeCoerce# (val v)))
ppr_integer _ v = return (Ppr.integer (unsafeCoerce# (val v)))
--Note pprinting of list terms is not lazy
ppr_list :: Precedence -> Term -> m SDoc
ppr_list p (Term{subTerms=[h,t]}) = do
let elems = h : getListTerms t
isConsLast = not(termType(last elems) `eqType` termType h)
is_string = all (isCharTy . ty) elems
print_elems <- mapM (y cons_prec) elems
if is_string
then return (Ppr.doubleQuotes (Ppr.text (unsafeCoerce# (map val elems))))
else if isConsLast
then return $ cparen (p >= cons_prec)
$ pprDeeperList fsep
$ punctuate (space<>colon) print_elems
else return $ brackets
$ pprDeeperList fcat
$ punctuate comma print_elems
where getListTerms Term{subTerms=[h,t]} = h : getListTerms t
getListTerms Term{subTerms=[]} = []
getListTerms t@Suspension{} = [t]
getListTerms t = pprPanic "getListTerms" (ppr t)
ppr_list _ _ = panic "doList"
repPrim :: TyCon -> [Word] -> SDoc
repPrim t = rep where
rep x
| t == charPrimTyCon = text $ show (build x :: Char)
| t == intPrimTyCon = text $ show (build x :: Int)
| t == wordPrimTyCon = text $ show (build x :: Word)
| t == floatPrimTyCon = text $ show (build x :: Float)
| t == doublePrimTyCon = text $ show (build x :: Double)
| t == int32PrimTyCon = text $ show (build x :: Int32)
| t == word32PrimTyCon = text $ show (build x :: Word32)
| t == int64PrimTyCon = text $ show (build x :: Int64)
| t == word64PrimTyCon = text $ show (build x :: Word64)
| t == addrPrimTyCon = text $ show (nullPtr `plusPtr` build x)
| t == stablePtrPrimTyCon = text "<stablePtr>"
| t == stableNamePrimTyCon = text "<stableName>"
| t == statePrimTyCon = text "<statethread>"
| t == proxyPrimTyCon = text "<proxy>"
| t == realWorldTyCon = text "<realworld>"
| t == threadIdPrimTyCon = text "<ThreadId>"
| t == weakPrimTyCon = text "<Weak>"
| t == arrayPrimTyCon = text "<array>"
| t == byteArrayPrimTyCon = text "<bytearray>"
| t == mutableArrayPrimTyCon = text "<mutableArray>"
| t == mutableByteArrayPrimTyCon = text "<mutableByteArray>"
| t == mutVarPrimTyCon = text "<mutVar>"
| t == mVarPrimTyCon = text "<mVar>"
| t == tVarPrimTyCon = text "<tVar>"
| otherwise = char '<' <> ppr t <> char '>'
where build ww = unsafePerformIO $ withArray ww (peek . castPtr)
-- This ^^^ relies on the representation of Haskell heap values being
-- the same as in a C array.
-----------------------------------
-- Type Reconstruction
-----------------------------------
{-
Type Reconstruction is type inference done on heap closures.
The algorithm walks the heap generating a set of equations, which
are solved with syntactic unification.
A type reconstruction equation looks like:
<datacon reptype> = <actual heap contents>
The full equation set is generated by traversing all the subterms, starting
from a given term.
The only difficult part is that newtypes are only found in the lhs of equations.
Right hand sides are missing them. We can either (a) drop them from the lhs, or
(b) reconstruct them in the rhs when possible.
The function congruenceNewtypes takes a shot at (b)
-}
-- A (non-mutable) tau type containing
-- existentially quantified tyvars.
-- (since GHC type language currently does not support
-- existentials, we leave these variables unquantified)
type RttiType = Type
-- An incomplete type as stored in GHCi:
-- no polymorphism: no quantifiers & all tyvars are skolem.
type GhciType = Type
-- The Type Reconstruction monad
--------------------------------
type TR a = TcM a
runTR :: HscEnv -> TR a -> IO a
runTR hsc_env thing = do
mb_val <- runTR_maybe hsc_env thing
case mb_val of
Nothing -> error "unable to :print the term"
Just x -> return x
runTR_maybe :: HscEnv -> TR a -> IO (Maybe a)
runTR_maybe hsc_env = fmap snd . initTc hsc_env HsSrcFile False iNTERACTIVE
traceTR :: SDoc -> TR ()
traceTR = liftTcM . traceOptTcRn Opt_D_dump_rtti
-- Semantically different to recoverM in TcRnMonad
-- recoverM retains the errors in the first action,
-- whereas recoverTc here does not
recoverTR :: TR a -> TR a -> TR a
recoverTR recover thing = do
(_,mb_res) <- tryTcErrs thing
case mb_res of
Nothing -> recover
Just res -> return res
trIO :: IO a -> TR a
trIO = liftTcM . liftIO
liftTcM :: TcM a -> TR a
liftTcM = id
newVar :: Kind -> TR TcType
newVar = liftTcM . newFlexiTyVarTy
instTyVars :: [TyVar] -> TR ([TcTyVar], [TcType], TvSubst)
-- Instantiate fresh mutable type variables from some TyVars
-- This function preserves the print-name, which helps error messages
instTyVars = liftTcM . tcInstTyVars
type RttiInstantiation = [(TcTyVar, TyVar)]
-- Associates the typechecker-world meta type variables
-- (which are mutable and may be refined), to their
-- debugger-world RuntimeUnk counterparts.
-- If the TcTyVar has not been refined by the runtime type
-- elaboration, then we want to turn it back into the
-- original RuntimeUnk
-- | Returns the instantiated type scheme ty', and the
-- mapping from new (instantiated) -to- old (skolem) type variables
instScheme :: QuantifiedType -> TR (TcType, RttiInstantiation)
instScheme (tvs, ty)
= liftTcM $ do { (tvs', _, subst) <- tcInstTyVars tvs
; let rtti_inst = [(tv',tv) | (tv',tv) <- tvs' `zip` tvs]
; return (substTy subst ty, rtti_inst) }
applyRevSubst :: RttiInstantiation -> TR ()
-- Apply the *reverse* substitution in-place to any un-filled-in
-- meta tyvars. This recovers the original debugger-world variable
-- unless it has been refined by new information from the heap
applyRevSubst pairs = liftTcM (mapM_ do_pair pairs)
where
do_pair (tc_tv, rtti_tv)
= do { tc_ty <- zonkTcTyVar tc_tv
; case tcGetTyVar_maybe tc_ty of
Just tv | isMetaTyVar tv -> writeMetaTyVar tv (mkTyVarTy rtti_tv)
_ -> return () }
-- Adds a constraint of the form t1 == t2
-- t1 is expected to come from walking the heap
-- t2 is expected to come from a datacon signature
-- Before unification, congruenceNewtypes needs to
-- do its magic.
addConstraint :: TcType -> TcType -> TR ()
addConstraint actual expected = do
traceTR (text "add constraint:" <+> fsep [ppr actual, equals, ppr expected])
recoverTR (traceTR $ fsep [text "Failed to unify", ppr actual,
text "with", ppr expected]) $
do { (ty1, ty2) <- congruenceNewtypes actual expected
; _ <- captureConstraints $ unifyType ty1 ty2
; return () }
-- TOMDO: what about the coercion?
-- we should consider family instances
-- Type & Term reconstruction
------------------------------
cvObtainTerm :: HscEnv -> Int -> Bool -> RttiType -> HValue -> IO Term
cvObtainTerm hsc_env max_depth force old_ty hval = runTR hsc_env $ do
-- we quantify existential tyvars as universal,
-- as this is needed to be able to manipulate
-- them properly
let quant_old_ty@(old_tvs, old_tau) = quantifyType old_ty
sigma_old_ty = mkForAllTys old_tvs old_tau
traceTR (text "Term reconstruction started with initial type " <> ppr old_ty)
term <-
if null old_tvs
then do
term <- go max_depth sigma_old_ty sigma_old_ty hval
term' <- zonkTerm term
return $ fixFunDictionaries $ expandNewtypes term'
else do
(old_ty', rev_subst) <- instScheme quant_old_ty
my_ty <- newVar openTypeKind
when (check1 quant_old_ty) (traceTR (text "check1 passed") >>
addConstraint my_ty old_ty')
term <- go max_depth my_ty sigma_old_ty hval
new_ty <- zonkTcType (termType term)
if isMonomorphic new_ty || check2 (quantifyType new_ty) quant_old_ty
then do
traceTR (text "check2 passed")
addConstraint new_ty old_ty'
applyRevSubst rev_subst
zterm' <- zonkTerm term
return ((fixFunDictionaries . expandNewtypes) zterm')
else do
traceTR (text "check2 failed" <+> parens
(ppr term <+> text "::" <+> ppr new_ty))
-- we have unsound types. Replace constructor types in
-- subterms with tyvars
zterm' <- mapTermTypeM
(\ty -> case tcSplitTyConApp_maybe ty of
Just (tc, _:_) | tc /= funTyCon
-> newVar openTypeKind
_ -> return ty)
term
zonkTerm zterm'
traceTR (text "Term reconstruction completed." $$
text "Term obtained: " <> ppr term $$
text "Type obtained: " <> ppr (termType term))
return term
where
dflags = hsc_dflags hsc_env
go :: Int -> Type -> Type -> HValue -> TcM Term
-- [SPJ May 11] I don't understand the difference between my_ty and old_ty
go max_depth _ _ _ | seq max_depth False = undefined
go 0 my_ty _old_ty a = do
traceTR (text "Gave up reconstructing a term after" <>
int max_depth <> text " steps")
clos <- trIO $ getClosureData dflags a
return (Suspension (tipe clos) my_ty a Nothing)
go max_depth my_ty old_ty a = do
let monomorphic = not(isTyVarTy my_ty)
-- This ^^^ is a convention. The ancestor tests for
-- monomorphism and passes a type instead of a tv
clos <- trIO $ getClosureData dflags a
case tipe clos of
-- Thunks we may want to force
t | isThunk t && force -> traceTR (text "Forcing a " <> text (show t)) >>
seq a (go (pred max_depth) my_ty old_ty a)
-- Blackholes are indirections iff the payload is not TSO or BLOCKING_QUEUE. So we
-- treat them like indirections; if the payload is TSO or BLOCKING_QUEUE, we'll end up
-- showing '_' which is what we want.
Blackhole -> do traceTR (text "Following a BLACKHOLE")
appArr (go max_depth my_ty old_ty) (ptrs clos) 0
-- We always follow indirections
Indirection i -> do traceTR (text "Following an indirection" <> parens (int i) )
go max_depth my_ty old_ty $! (ptrs clos ! 0)
-- We also follow references
MutVar _ | Just (tycon,[world,contents_ty]) <- tcSplitTyConApp_maybe old_ty
-> do
-- Deal with the MutVar# primitive
-- It does not have a constructor at all,
-- so we simulate the following one
-- MutVar# :: contents_ty -> MutVar# s contents_ty
traceTR (text "Following a MutVar")
contents_tv <- newVar liftedTypeKind
contents <- trIO$ IO$ \w -> readMutVar# (unsafeCoerce# a) w
ASSERT(isUnliftedTypeKind $ typeKind my_ty) return ()
(mutvar_ty,_) <- instScheme $ quantifyType $ mkFunTy
contents_ty (mkTyConApp tycon [world,contents_ty])
addConstraint (mkFunTy contents_tv my_ty) mutvar_ty
x <- go (pred max_depth) contents_tv contents_ty contents
return (RefWrap my_ty x)
-- The interesting case
Constr -> do
traceTR (text "entering a constructor " <>
if monomorphic
then parens (text "already monomorphic: " <> ppr my_ty)
else Ppr.empty)
Right dcname <- dataConInfoPtrToName (infoPtr clos)
(_,mb_dc) <- tryTcErrs (tcLookupDataCon dcname)
case mb_dc of
Nothing -> do -- This can happen for private constructors compiled -O0
-- where the .hi descriptor does not export them
-- In such case, we return a best approximation:
-- ignore the unpointed args, and recover the pointeds
-- This preserves laziness, and should be safe.
traceTR (text "Not constructor" <+> ppr dcname)
let dflags = hsc_dflags hsc_env
tag = showPpr dflags dcname
vars <- replicateM (length$ elems$ ptrs clos)
(newVar liftedTypeKind)
subTerms <- sequence [appArr (go (pred max_depth) tv tv) (ptrs clos) i
| (i, tv) <- zip [0..] vars]
return (Term my_ty (Left ('<' : tag ++ ">")) a subTerms)
Just dc -> do
traceTR (text "Is constructor" <+> (ppr dc $$ ppr my_ty))
subTtypes <- getDataConArgTys dc my_ty
subTerms <- extractSubTerms (\ty -> go (pred max_depth) ty ty) clos subTtypes
return (Term my_ty (Right dc) a subTerms)
-- The otherwise case: can be a Thunk,AP,PAP,etc.
tipe_clos ->
return (Suspension tipe_clos my_ty a Nothing)
-- insert NewtypeWraps around newtypes
expandNewtypes = foldTerm idTermFold { fTerm = worker } where
worker ty dc hval tt
| Just (tc, args) <- tcSplitTyConApp_maybe ty
, isNewTyCon tc
, wrapped_type <- newTyConInstRhs tc args
, Just dc' <- tyConSingleDataCon_maybe tc
, t' <- worker wrapped_type dc hval tt
= NewtypeWrap ty (Right dc') t'
| otherwise = Term ty dc hval tt
-- Avoid returning types where predicates have been expanded to dictionaries.
fixFunDictionaries = foldTerm idTermFold {fSuspension = worker} where
worker ct ty hval n | isFunTy ty = Suspension ct (dictsView ty) hval n
| otherwise = Suspension ct ty hval n
extractSubTerms :: (Type -> HValue -> TcM Term)
-> Closure -> [Type] -> TcM [Term]
extractSubTerms recurse clos = liftM thirdOf3 . go 0 (nonPtrs clos)
where
go ptr_i ws [] = return (ptr_i, ws, [])
go ptr_i ws (ty:tys)
| Just (tc, elem_tys) <- tcSplitTyConApp_maybe ty
, isUnboxedTupleTyCon tc
= do (ptr_i, ws, terms0) <- go ptr_i ws elem_tys
(ptr_i, ws, terms1) <- go ptr_i ws tys
return (ptr_i, ws, unboxedTupleTerm ty terms0 : terms1)
| otherwise
= case repType ty of
UnaryRep rep_ty -> do
(ptr_i, ws, term0) <- go_rep ptr_i ws ty (typePrimRep rep_ty)
(ptr_i, ws, terms1) <- go ptr_i ws tys
return (ptr_i, ws, term0 : terms1)
UbxTupleRep rep_tys -> do
(ptr_i, ws, terms0) <- go_unary_types ptr_i ws rep_tys
(ptr_i, ws, terms1) <- go ptr_i ws tys
return (ptr_i, ws, unboxedTupleTerm ty terms0 : terms1)
go_unary_types ptr_i ws [] = return (ptr_i, ws, [])
go_unary_types ptr_i ws (rep_ty:rep_tys) = do
tv <- newVar liftedTypeKind
(ptr_i, ws, term0) <- go_rep ptr_i ws tv (typePrimRep rep_ty)
(ptr_i, ws, terms1) <- go_unary_types ptr_i ws rep_tys
return (ptr_i, ws, term0 : terms1)
go_rep ptr_i ws ty rep = case rep of
PtrRep -> do
t <- appArr (recurse ty) (ptrs clos) ptr_i
return (ptr_i + 1, ws, t)
_ -> do
dflags <- getDynFlags
let (ws0, ws1) = splitAt (primRepSizeW dflags rep) ws
return (ptr_i, ws1, Prim ty ws0)
unboxedTupleTerm ty terms = Term ty (Right (tupleCon UnboxedTuple (length terms)))
(error "unboxedTupleTerm: no HValue for unboxed tuple") terms
-- Fast, breadth-first Type reconstruction
------------------------------------------
cvReconstructType :: HscEnv -> Int -> GhciType -> HValue -> IO (Maybe Type)
cvReconstructType hsc_env max_depth old_ty hval = runTR_maybe hsc_env $ do
traceTR (text "RTTI started with initial type " <> ppr old_ty)
let sigma_old_ty@(old_tvs, _) = quantifyType old_ty
new_ty <-
if null old_tvs
then return old_ty
else do
(old_ty', rev_subst) <- instScheme sigma_old_ty
my_ty <- newVar openTypeKind
when (check1 sigma_old_ty) (traceTR (text "check1 passed") >>
addConstraint my_ty old_ty')
search (isMonomorphic `fmap` zonkTcType my_ty)
(\(ty,a) -> go ty a)
(Seq.singleton (my_ty, hval))
max_depth
new_ty <- zonkTcType my_ty
if isMonomorphic new_ty || check2 (quantifyType new_ty) sigma_old_ty
then do
traceTR (text "check2 passed" <+> ppr old_ty $$ ppr new_ty)
addConstraint my_ty old_ty'
applyRevSubst rev_subst
zonkRttiType new_ty
else traceTR (text "check2 failed" <+> parens (ppr new_ty)) >>
return old_ty
traceTR (text "RTTI completed. Type obtained:" <+> ppr new_ty)
return new_ty
where
dflags = hsc_dflags hsc_env
-- search :: m Bool -> ([a] -> [a] -> [a]) -> [a] -> m ()
search _ _ _ 0 = traceTR (text "Failed to reconstruct a type after " <>
int max_depth <> text " steps")
search stop expand l d =
case viewl l of
EmptyL -> return ()
x :< xx -> unlessM stop $ do
new <- expand x
search stop expand (xx `mappend` Seq.fromList new) $! (pred d)
-- returns unification tasks,since we are going to want a breadth-first search
go :: Type -> HValue -> TR [(Type, HValue)]
go my_ty a = do
traceTR (text "go" <+> ppr my_ty)
clos <- trIO $ getClosureData dflags a
case tipe clos of
Blackhole -> appArr (go my_ty) (ptrs clos) 0 -- carefully, don't eval the TSO
Indirection _ -> go my_ty $! (ptrs clos ! 0)
MutVar _ -> do
contents <- trIO$ IO$ \w -> readMutVar# (unsafeCoerce# a) w
tv' <- newVar liftedTypeKind
world <- newVar liftedTypeKind
addConstraint my_ty (mkTyConApp mutVarPrimTyCon [world,tv'])
return [(tv', contents)]
Constr -> do
Right dcname <- dataConInfoPtrToName (infoPtr clos)
traceTR (text "Constr1" <+> ppr dcname)
(_,mb_dc) <- tryTcErrs (tcLookupDataCon dcname)
case mb_dc of
Nothing-> do
-- TODO: Check this case
forM [0..length (elems $ ptrs clos)] $ \i -> do
tv <- newVar liftedTypeKind
return$ appArr (\e->(tv,e)) (ptrs clos) i
Just dc -> do
arg_tys <- getDataConArgTys dc my_ty
(_, itys) <- findPtrTyss 0 arg_tys
traceTR (text "Constr2" <+> ppr dcname <+> ppr arg_tys)
return $ [ appArr (\e-> (ty,e)) (ptrs clos) i
| (i,ty) <- itys]
_ -> return []
findPtrTys :: Int -- Current pointer index
-> Type -- Type
-> TR (Int, [(Int, Type)])
findPtrTys i ty
| Just (tc, elem_tys) <- tcSplitTyConApp_maybe ty
, isUnboxedTupleTyCon tc
= findPtrTyss i elem_tys
| otherwise
= case repType ty of
UnaryRep rep_ty | typePrimRep rep_ty == PtrRep -> return (i + 1, [(i, ty)])
| otherwise -> return (i, [])
UbxTupleRep rep_tys -> foldM (\(i, extras) rep_ty -> if typePrimRep rep_ty == PtrRep
then newVar liftedTypeKind >>= \tv -> return (i + 1, extras ++ [(i, tv)])
else return (i, extras))
(i, []) rep_tys
findPtrTyss :: Int
-> [Type]
-> TR (Int, [(Int, Type)])
findPtrTyss i tys = foldM step (i, []) tys
where step (i, discovered) elem_ty = findPtrTys i elem_ty >>= \(i, extras) -> return (i, discovered ++ extras)
-- Compute the difference between a base type and the type found by RTTI
-- improveType <base_type> <rtti_type>
-- The types can contain skolem type variables, which need to be treated as normal vars.
-- In particular, we want them to unify with things.
improveRTTIType :: HscEnv -> RttiType -> RttiType -> Maybe TvSubst
improveRTTIType _ base_ty new_ty
= U.tcUnifyTys (const U.BindMe) [base_ty] [new_ty]
getDataConArgTys :: DataCon -> Type -> TR [Type]
-- Given the result type ty of a constructor application (D a b c :: ty)
-- return the types of the arguments. This is RTTI-land, so 'ty' might
-- not be fully known. Moreover, the arg types might involve existentials;
-- if so, make up fresh RTTI type variables for them
getDataConArgTys dc con_app_ty
= do { (_, ex_tys, ex_subst) <- instTyVars ex_tvs
; let UnaryRep rep_con_app_ty = repType con_app_ty
; traceTR (text "getDataConArgTys 1" <+> (ppr con_app_ty $$ ppr rep_con_app_ty))
; ty_args <- case tcSplitTyConApp_maybe rep_con_app_ty of
Just (tc, ty_args) | dataConTyCon dc == tc
-> ASSERT( univ_tvs `equalLength` ty_args)
return ty_args
_ -> do { (_, ty_args, univ_subst) <- instTyVars univ_tvs
; let res_ty = substTy ex_subst (substTy univ_subst (dataConOrigResTy dc))
-- See Note [Constructor arg types]
; addConstraint rep_con_app_ty res_ty
; return ty_args }
-- It is necessary to check dataConTyCon dc == tc
-- because it may be the case that tc is a recursive
-- newtype and tcSplitTyConApp has not removed it. In
-- that case, we happily give up and don't match
; let subst = zipTopTvSubst (univ_tvs ++ ex_tvs) (ty_args ++ ex_tys)
; traceTR (text "getDataConArgTys 2" <+> (ppr rep_con_app_ty $$ ppr ty_args $$ ppr subst))
; return (substTys subst (dataConRepArgTys dc)) }
where
univ_tvs = dataConUnivTyVars dc
ex_tvs = dataConExTyVars dc
{- Note [Constructor arg types]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider a GADT (cf Trac #7386)
data family D a b
data instance D [a] b where
MkT :: b -> D [a] (Maybe b)
In getDataConArgTys
* con_app_ty is the known type (from outside) of the constructor application,
say D [Int] Bool
* The data constructor MkT has a (representation) dataConTyCon = DList,
say where
data DList a b where
MkT :: b -> DList a (Maybe b)
So the dataConTyCon of the data constructor, DList, differs from
the "outside" type, D. So we can't straightforwardly decompose the
"outside" type, and we end up in the "_" branch of the case.
Then we match the dataConOrigResTy of the data constructor against the
outside type, hoping to get a substitution that tells how to instantiate
the *representation* type constructor. This looks a bit delicate to
me, but it seems to work.
-}
-- Soundness checks
--------------------
{-
This is not formalized anywhere, so hold to your seats!
RTTI in the presence of newtypes can be a tricky and unsound business.
Example:
~~~~~~~~~
Suppose we are doing RTTI for a partially evaluated
closure t, the real type of which is t :: MkT Int, for
newtype MkT a = MkT [Maybe a]
The table below shows the results of RTTI and the improvement
calculated for different combinations of evaluatedness and :type t.
Regard the two first columns as input and the next two as output.
# | t | :type t | rtti(t) | improv. | result
------------------------------------------------------------
1 | _ | t b | a | none | OK
2 | _ | MkT b | a | none | OK
3 | _ | t Int | a | none | OK
If t is not evaluated at *all*, we are safe.
4 | (_ : _) | t b | [a] | t = [] | UNSOUND
5 | (_ : _) | MkT b | MkT a | none | OK (compensating for the missing newtype)
6 | (_ : _) | t Int | [Int] | t = [] | UNSOUND
If a is a minimal whnf, we run into trouble. Note that
row 5 above does newtype enrichment on the ty_rtty parameter.
7 | (Just _:_)| t b |[Maybe a] | t = [], | UNSOUND
| | | b = Maybe a|
8 | (Just _:_)| MkT b | MkT a | none | OK
9 | (Just _:_)| t Int | FAIL | none | OK
And if t is any more evaluated than whnf, we are still in trouble.
Because constraints are solved in top-down order, when we reach the
Maybe subterm what we got is already unsound. This explains why the
row 9 fails to complete.
10 | (Just _:_)| t Int | [Maybe a] | FAIL | OK
11 | (Just 1:_)| t Int | [Maybe Int] | FAIL | OK
We can undo the failure in row 9 by leaving out the constraint
coming from the type signature of t (i.e., the 2nd column).
Note that this type information is still used
to calculate the improvement. But we fail
when trying to calculate the improvement, as there is no unifier for
t Int = [Maybe a] or t Int = [Maybe Int].
Another set of examples with t :: [MkT (Maybe Int)] \equiv [[Maybe (Maybe Int)]]
# | t | :type t | rtti(t) | improvement | result
---------------------------------------------------------------------
1 |(Just _:_) | [t (Maybe a)] | [[Maybe b]] | t = [] |
| | | | b = Maybe a |
The checks:
~~~~~~~~~~~
Consider a function obtainType that takes a value and a type and produces
the Term representation and a substitution (the improvement).
Assume an auxiliar rtti' function which does the actual job if recovering
the type, but which may produce a false type.
In pseudocode:
rtti' :: a -> IO Type -- Does not use the static type information
obtainType :: a -> Type -> IO (Maybe (Term, Improvement))
obtainType v old_ty = do
rtti_ty <- rtti' v
if monomorphic rtti_ty || (check rtti_ty old_ty)
then ...
else return Nothing
where check rtti_ty old_ty = check1 rtti_ty &&
check2 rtti_ty old_ty
check1 :: Type -> Bool
check2 :: Type -> Type -> Bool
Now, if rtti' returns a monomorphic type, we are safe.
If that is not the case, then we consider two conditions.
1. To prevent the class of unsoundness displayed by
rows 4 and 7 in the example: no higher kind tyvars
accepted.
check1 (t a) = NO
check1 (t Int) = NO
check1 ([] a) = YES
2. To prevent the class of unsoundness shown by row 6,
the rtti type should be structurally more
defined than the old type we are comparing it to.
check2 :: NewType -> OldType -> Bool
check2 a _ = True
check2 [a] a = True
check2 [a] (t Int) = False
check2 [a] (t a) = False -- By check1 we never reach this equation
check2 [Int] a = True
check2 [Int] (t Int) = True
check2 [Maybe a] (t Int) = False
check2 [Maybe Int] (t Int) = True
check2 (Maybe [a]) (m [Int]) = False
check2 (Maybe [Int]) (m [Int]) = True
-}
check1 :: QuantifiedType -> Bool
check1 (tvs, _) = not $ any isHigherKind (map tyVarKind tvs)
where
isHigherKind = not . null . fst . splitKindFunTys
check2 :: QuantifiedType -> QuantifiedType -> Bool
check2 (_, rtti_ty) (_, old_ty)
| Just (_, rttis) <- tcSplitTyConApp_maybe rtti_ty
= case () of
_ | Just (_,olds) <- tcSplitTyConApp_maybe old_ty
-> and$ zipWith check2 (map quantifyType rttis) (map quantifyType olds)
_ | Just _ <- splitAppTy_maybe old_ty
-> isMonomorphicOnNonPhantomArgs rtti_ty
_ -> True
| otherwise = True
-- Dealing with newtypes
--------------------------
{-
congruenceNewtypes does a parallel fold over two Type values,
compensating for missing newtypes on both sides.
This is necessary because newtypes are not present
in runtime, but sometimes there is evidence available.
Evidence can come from DataCon signatures or
from compile-time type inference.
What we are doing here is an approximation
of unification modulo a set of equations derived
from newtype definitions. These equations should be the
same as the equality coercions generated for newtypes
in System Fc. The idea is to perform a sort of rewriting,
taking those equations as rules, before launching unification.
The caller must ensure the following.
The 1st type (lhs) comes from the heap structure of ptrs,nptrs.
The 2nd type (rhs) comes from a DataCon type signature.
Rewriting (i.e. adding/removing a newtype wrapper) can happen
in both types, but in the rhs it is restricted to the result type.
Note that it is very tricky to make this 'rewriting'
work with the unification implemented by TcM, where
substitutions are operationally inlined. The order in which
constraints are unified is vital as we cannot modify
anything that has been touched by a previous unification step.
Therefore, congruenceNewtypes is sound only if the types
recovered by the RTTI mechanism are unified Top-Down.
-}
congruenceNewtypes :: TcType -> TcType -> TR (TcType,TcType)
congruenceNewtypes lhs rhs = go lhs rhs >>= \rhs' -> return (lhs,rhs')
where
go l r
-- TyVar lhs inductive case
| Just tv <- getTyVar_maybe l
, isTcTyVar tv
, isMetaTyVar tv
= recoverTR (return r) $ do
Indirect ty_v <- readMetaTyVar tv
traceTR $ fsep [text "(congruence) Following indirect tyvar:",
ppr tv, equals, ppr ty_v]
go ty_v r
-- FunTy inductive case
| Just (l1,l2) <- splitFunTy_maybe l
, Just (r1,r2) <- splitFunTy_maybe r
= do r2' <- go l2 r2
r1' <- go l1 r1
return (mkFunTy r1' r2')
-- TyconApp Inductive case; this is the interesting bit.
| Just (tycon_l, _) <- tcSplitTyConApp_maybe lhs
, Just (tycon_r, _) <- tcSplitTyConApp_maybe rhs
, tycon_l /= tycon_r
= upgrade tycon_l r
| otherwise = return r
where upgrade :: TyCon -> Type -> TR Type
upgrade new_tycon ty
| not (isNewTyCon new_tycon) = do
traceTR (text "(Upgrade) Not matching newtype evidence: " <>
ppr new_tycon <> text " for " <> ppr ty)
return ty
| otherwise = do
traceTR (text "(Upgrade) upgraded " <> ppr ty <>
text " in presence of newtype evidence " <> ppr new_tycon)
(_, vars, _) <- instTyVars (tyConTyVars new_tycon)
let ty' = mkTyConApp new_tycon vars
UnaryRep rep_ty = repType ty'
_ <- liftTcM (unifyType ty rep_ty)
-- assumes that reptype doesn't ^^^^ touch tyconApp args
return ty'
zonkTerm :: Term -> TcM Term
zonkTerm = foldTermM (TermFoldM
{ fTermM = \ty dc v tt -> zonkRttiType ty >>= \ty' ->
return (Term ty' dc v tt)
, fSuspensionM = \ct ty v b -> zonkRttiType ty >>= \ty ->
return (Suspension ct ty v b)
, fNewtypeWrapM = \ty dc t -> zonkRttiType ty >>= \ty' ->
return$ NewtypeWrap ty' dc t
, fRefWrapM = \ty t -> return RefWrap `ap`
zonkRttiType ty `ap` return t
, fPrimM = (return.) . Prim })
zonkRttiType :: TcType -> TcM Type
-- Zonk the type, replacing any unbound Meta tyvars
-- by skolems, safely out of Meta-tyvar-land
zonkRttiType = zonkTcTypeToType (mkEmptyZonkEnv zonk_unbound_meta)
where
zonk_unbound_meta tv
= ASSERT( isTcTyVar tv )
do { tv' <- skolemiseUnboundMetaTyVar tv RuntimeUnk
-- This is where RuntimeUnks are born:
-- otherwise-unconstrained unification variables are
-- turned into RuntimeUnks as they leave the
-- typechecker's monad
; return (mkTyVarTy tv') }
--------------------------------------------------------------------------------
-- Restore Class predicates out of a representation type
dictsView :: Type -> Type
dictsView ty = ty
-- Use only for RTTI types
isMonomorphic :: RttiType -> Bool
isMonomorphic ty = noExistentials && noUniversals
where (tvs, _, ty') = tcSplitSigmaTy ty
noExistentials = isEmptyVarSet (tyVarsOfType ty')
noUniversals = null tvs
-- Use only for RTTI types
isMonomorphicOnNonPhantomArgs :: RttiType -> Bool
isMonomorphicOnNonPhantomArgs ty
| UnaryRep rep_ty <- repType ty
, Just (tc, all_args) <- tcSplitTyConApp_maybe rep_ty
, phantom_vars <- tyConPhantomTyVars tc
, concrete_args <- [ arg | (tyv,arg) <- tyConTyVars tc `zip` all_args
, tyv `notElem` phantom_vars]
= all isMonomorphicOnNonPhantomArgs concrete_args
| Just (ty1, ty2) <- splitFunTy_maybe ty
= all isMonomorphicOnNonPhantomArgs [ty1,ty2]
| otherwise = isMonomorphic ty
tyConPhantomTyVars :: TyCon -> [TyVar]
tyConPhantomTyVars tc
| isAlgTyCon tc
, Just dcs <- tyConDataCons_maybe tc
, dc_vars <- concatMap dataConUnivTyVars dcs
= tyConTyVars tc \\ dc_vars
tyConPhantomTyVars _ = []
type QuantifiedType = ([TyVar], Type) -- Make the free type variables explicit
quantifyType :: Type -> QuantifiedType
-- Generalize the type: find all free tyvars and wrap in the appropiate ForAll.
quantifyType ty = (varSetElems (tyVarsOfType ty), ty)
unlessM :: Monad m => m Bool -> m () -> m ()
unlessM condM acc = condM >>= \c -> unless c acc
-- Strict application of f at index i
appArr :: Ix i => (e -> a) -> Array i e -> Int -> a
appArr f a@(Array _ _ _ ptrs#) i@(I# i#)
= ASSERT2(i < length(elems a), ppr(length$ elems a, i))
case indexArray# ptrs# i# of
(# e #) -> f e
amap' :: (t -> b) -> Array Int t -> [b]
amap' f (Array i0 i _ arr#) = map g [0 .. i - i0]
where g (I# i#) = case indexArray# arr# i# of
(# e #) -> f e
|