-- http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#Warnings
-- for details
-module TcPat ( tcLetPat, tcLamPat, tcLamPats, tcOverloadedLit,
+module TcPat ( tcLetPat, tcLamPat, tcLamPats, tcProcPat, tcOverloadedLit,
addDataConStupidTheta, badFieldCon, polyPatSig ) where
#include "HsVersions.h"
import Maybes
import Outputable
import FastString
+import Monad
\end{code}
-- 5. Check that no existentials escape
tcLamPats pats tys res_ty thing_inside
- = tc_lam_pats (zipEqual "tcLamPats" pats tys)
+ = tc_lam_pats LamPat (zipEqual "tcLamPats" pats tys)
(emptyRefinement, res_ty) thing_inside
tcLamPat :: LPat Name -> BoxySigmaType
-> (Refinement,BoxyRhoType) -- Result type
-> ((Refinement,BoxyRhoType) -> TcM a) -- Checker for body, given its result type
-> TcM (LPat TcId, a)
-tcLamPat pat pat_ty res_ty thing_inside
- = do { ([pat'],thing) <- tc_lam_pats [(pat, pat_ty)] res_ty thing_inside
+
+tcProcPat = tc_lam_pat ProcPat
+tcLamPat = tc_lam_pat LamPat
+
+tc_lam_pat ctxt pat pat_ty res_ty thing_inside
+ = do { ([pat'],thing) <- tc_lam_pats ctxt [(pat, pat_ty)] res_ty thing_inside
; return (pat', thing) }
-----------------
-tc_lam_pats :: [(LPat Name,BoxySigmaType)]
+tc_lam_pats :: PatCtxt
+ -> [(LPat Name,BoxySigmaType)]
-> (Refinement,BoxyRhoType) -- Result type
-> ((Refinement,BoxyRhoType) -> TcM a) -- Checker for body, given its result type
-> TcM ([LPat TcId], a)
-tc_lam_pats pat_ty_prs (reft, res_ty) thing_inside
- = do { let init_state = PS { pat_ctxt = LamPat, pat_reft = reft, pat_eqs = False }
+tc_lam_pats ctxt pat_ty_prs (reft, res_ty) thing_inside
+ = do { let init_state = PS { pat_ctxt = ctxt, pat_reft = reft, pat_eqs = False }
; (pats', ex_tvs, res) <- tcMultiple tc_lpat_pr pat_ty_prs init_state $ \ pstate' ->
refineEnvironment (pat_reft pstate') (pat_eqs pstate') $
data PatCtxt
= LamPat
+ | ProcPat -- The pattern in (proc pat -> ...)
+ -- see Note [Arrows and patterns]
| LetPat (Name -> Maybe TcRhoType) -- Used for let(rec) bindings
patSigCtxt :: PatState -> UserTypeCtxt
\begin{code}
tcPatBndr :: PatState -> Name -> BoxySigmaType -> TcM TcId
-tcPatBndr (PS { pat_ctxt = LamPat }) bndr_name pat_ty
- = do { pat_ty' <- unBoxPatBndrType pat_ty bndr_name
- -- We have an undecorated binder, so we do rule ABS1,
- -- by unboxing the boxy type, forcing any un-filled-in
- -- boxes to become monotypes
- -- NB that pat_ty' can still be a polytype:
- -- data T = MkT (forall a. a->a)
- -- f t = case t of { MkT g -> ... }
- -- Here, the 'g' must get type (forall a. a->a) from the
- -- MkT context
- ; return (Id.mkLocalId bndr_name pat_ty') }
-
tcPatBndr (PS { pat_ctxt = LetPat lookup_sig }) bndr_name pat_ty
| Just mono_ty <- lookup_sig bndr_name
= do { mono_name <- newLocalName bndr_name
; mono_name <- newLocalName bndr_name
; return (Id.mkLocalId mono_name pat_ty') }
+tcPatBndr (PS { pat_ctxt = _lam_or_proc }) bndr_name pat_ty
+ = do { pat_ty' <- unBoxPatBndrType pat_ty bndr_name
+ -- We have an undecorated binder, so we do rule ABS1,
+ -- by unboxing the boxy type, forcing any un-filled-in
+ -- boxes to become monotypes
+ -- NB that pat_ty' can still be a polytype:
+ -- data T = MkT (forall a. a->a)
+ -- f t = case t of { MkT g -> ... }
+ -- Here, the 'g' must get type (forall a. a->a) from the
+ -- MkT context
+ ; return (Id.mkLocalId bndr_name pat_ty') }
+
-------------------
bindInstsOfPatId :: TcId -> TcM a -> TcM (a, LHsBinds TcId)
-- (view -> f) where view :: _ -> forall b. b
-- we will only be able to use view at one instantation in the
-- rest of the view
- ; (expr_coerc, pat_ty) <- tcInfer (\ pat_ty -> tcSubExp (expr'_expected pat_ty) expr'_inferred)
+ ; (expr_coerc, pat_ty) <- tcInfer $ \ pat_ty ->
+ tcSubExp ViewPatOrigin (expr'_expected pat_ty) expr'_inferred
+
-- pattern must have pat_ty
; (pat', tvs, res) <- tc_lpat pat pat_ty pstate thing_inside
-- this should get zonked later on, but we unBox it here
-- Lists, tuples, arrays
tc_pat pstate (ListPat pats _) pat_ty thing_inside
= do { (elt_ty, coi) <- boxySplitListTy pat_ty
+ ; let scoi = mkSymCoI coi
; (pats', pats_tvs, res) <- tcMultiple (\p -> tc_lpat p elt_ty)
pats pstate thing_inside
- ; return (mkCoPatCoI coi (ListPat pats' elt_ty) pat_ty, pats_tvs, res) }
+ ; return (mkCoPatCoI scoi (ListPat pats' elt_ty) pat_ty, pats_tvs, res)
+ }
tc_pat pstate (PArrPat pats _) pat_ty thing_inside
= do { (elt_ty, coi) <- boxySplitPArrTy pat_ty
+ ; let scoi = mkSymCoI coi
; (pats', pats_tvs, res) <- tcMultiple (\p -> tc_lpat p elt_ty)
pats pstate thing_inside
; ifM (null pats) (zapToMonotype pat_ty) -- c.f. ExplicitPArr in TcExpr
- ; return (mkCoPatCoI coi (PArrPat pats' elt_ty) pat_ty, pats_tvs, res) }
+ ; return (mkCoPatCoI scoi (PArrPat pats' elt_ty) pat_ty, pats_tvs, res)
+ }
tc_pat pstate (TuplePat pats boxity _) pat_ty thing_inside
= do { let tc = tupleTyCon boxity (length pats)
; (arg_tys, coi) <- boxySplitTyConApp tc pat_ty
+ ; let scoi = mkSymCoI coi
; (pats', pats_tvs, res) <- tcMultiple tc_lpat_pr (pats `zip` arg_tys)
pstate thing_inside
| otherwise = unmangled_result
; ASSERT( length arg_tys == length pats ) -- Syntactically enforced
- return (mkCoPatCoI coi possibly_mangled_result pat_ty, pats_tvs, res)
+ return (mkCoPatCoI scoi possibly_mangled_result pat_ty, pats_tvs, res)
}
------------------------
-> HsConPatDetails Name -> (PatState -> TcM a)
-> TcM (Pat TcId, [TcTyVar], a)
tcConPat pstate con_span data_con tycon pat_ty arg_pats thing_inside
- = do { let (univ_tvs, ex_tvs, eq_spec, eq_theta, dict_theta, arg_tys, _) = dataConFullSig data_con
- skol_info = PatSkol data_con
- origin = SigOrigin skol_info
+ = do { let (univ_tvs, ex_tvs, eq_spec, eq_theta, dict_theta, arg_tys, _)
+ = dataConFullSig data_con
+ skol_info = PatSkol data_con
+ origin = SigOrigin skol_info
+ full_theta = eq_theta ++ dict_theta
-- Instantiate the constructor type variables [a->ty]
+ -- This may involve doing a family-instance coercion, and building a
+ -- wrapper
; (ctxt_res_tys, coi) <- boxySplitTyConAppWithFamily tycon pat_ty
- ; ex_tvs' <- tcInstSkolTyVars skol_info ex_tvs -- Get location from monad,
- -- not from ex_tvs
+ ; let sym_coi = mkSymCoI coi -- boxy split coercion oriented wrongly
+ pat_ty' = mkTyConApp tycon ctxt_res_tys
+ -- pat_ty' /= pat_ty iff coi /= IdCo
+
+ wrap_res_pat res_pat = mkCoPatCoI sym_coi uwScrut pat_ty
+ where
+ uwScrut = unwrapFamInstScrutinee tycon ctxt_res_tys res_pat
+
+ ; traceTc $ case sym_coi of
+ IdCo -> text "sym_coi:IdCo"
+ ACo co -> text "sym_coi: ACoI" <+> ppr co
+
+ -- Add the stupid theta
+ ; addDataConStupidTheta data_con ctxt_res_tys
+
+ ; ex_tvs' <- tcInstSkolTyVars skol_info ex_tvs
+ -- Get location from monad, not from ex_tvs
+
; let tenv = zipTopTvSubst (univ_tvs ++ ex_tvs)
(ctxt_res_tys ++ mkTyVarTys ex_tvs')
- eq_spec' = substEqSpec tenv eq_spec
- theta' = substTheta tenv (eq_theta ++ dict_theta)
- arg_tys' = substTys tenv arg_tys
-
- ; co_vars <- newCoVars eq_spec' -- Make coercion variables
- ; traceTc (text "tcConPat: refineAlt")
- ; pstate' <- refineAlt data_con pstate ex_tvs' co_vars pat_ty
- ; traceTc (text "tcConPat: refineAlt done!")
-
+ arg_tys' = substTys tenv arg_tys
+
+ ; if null ex_tvs && null eq_spec && null full_theta
+ then do { -- The common case; no class bindings etc
+ -- (see Note [Arrows and patterns])
+ (arg_pats', inner_tvs, res) <- tcConArgs data_con arg_tys'
+ arg_pats pstate thing_inside
+ ; let res_pat = ConPatOut { pat_con = L con_span data_con,
+ pat_tvs = [], pat_dicts = [],
+ pat_binds = emptyLHsBinds,
+ pat_args = arg_pats',
+ pat_ty = pat_ty' }
+
+ ; return (wrap_res_pat res_pat, inner_tvs, res) }
+
+ else do -- The general case, with existential, and local equality
+ -- constraints
+ { let eq_preds = [mkEqPred (mkTyVarTy tv, ty) | (tv, ty) <- eq_spec]
+ theta' = substTheta tenv (eq_preds ++ full_theta)
+ -- order is *important* as we generate the list of
+ -- dictionary binders from theta'
+ ctxt = pat_ctxt pstate
+ ; checkTc (case ctxt of { ProcPat -> False; other -> True })
+ (existentialProcPat data_con)
+
+ -- Need to test for rigidity if *any* constraints in theta as class
+ -- constraints may have superclass equality constraints. However,
+ -- we don't want to check for rigidity if we got here only because
+ -- ex_tvs was non-null.
+-- ; unless (null theta') $
+ -- FIXME: AT THE MOMENT WE CHEAT! We only perform the rigidity test
+ -- if we explicit or implicit (by a GADT def) have equality
+ -- constraints.
+ ; unless (all (not . isEqPred) theta') $
+ checkTc (isRigidTy pat_ty) (nonRigidMatch data_con)
+
; ((arg_pats', inner_tvs, res), lie_req) <- getLIE $
- tcConArgs data_con arg_tys' arg_pats pstate' thing_inside
+ tcConArgs data_con arg_tys' arg_pats pstate thing_inside
; loc <- getInstLoc origin
; dicts <- newDictBndrs loc theta'
- ; dict_binds <- tcSimplifyCheckPat loc co_vars (pat_reft pstate')
- ex_tvs' dicts lie_req
+ ; dict_binds <- tcSimplifyCheckPat loc [] emptyRefinement
+ ex_tvs' dicts lie_req
- ; addDataConStupidTheta data_con ctxt_res_tys
-
- ; let pat_ty' = mkTyConApp tycon ctxt_res_tys
- -- pat_ty /= pat_ty iff coi /= IdCo
- res_pat = ConPatOut { pat_con = L con_span data_con,
- pat_tvs = ex_tvs' ++ co_vars,
+ ; let res_pat = ConPatOut { pat_con = L con_span data_con,
+ pat_tvs = ex_tvs',
pat_dicts = map instToVar dicts,
pat_binds = dict_binds,
pat_args = arg_pats', pat_ty = pat_ty' }
- ; return
- (mkCoPatCoI coi
- (unwrapFamInstScrutinee tycon ctxt_res_tys res_pat) pat_ty,
- ex_tvs' ++ inner_tvs, res)
- }
+ ; return (wrap_res_pat res_pat, ex_tvs' ++ inner_tvs, res)
+ } }
where
-- Split against the family tycon if the pattern constructor
-- belongs to a family instance tycon.
con_arity = dataConSourceArity data_con
no_of_args = length arg_pats
-tcConArgs data_con [arg_ty1,arg_ty2] (InfixCon p1 p2) pstate thing_inside
+tcConArgs data_con arg_tys (InfixCon p1 p2) pstate thing_inside
= do { checkTc (con_arity == 2) -- Check correct arity
(arityErr "Constructor" data_con con_arity 2)
+ ; let [arg_ty1,arg_ty2] = arg_tys -- This can't fail after the arity check
; ([p1',p2'], tvs, res) <- tcMultiple tcConArg [(p1,arg_ty1),(p2,arg_ty2)]
pstate thing_inside
; return (InfixCon p1' p2', tvs, res) }
inst_theta = substTheta tenv stupid_theta
\end{code}
+Note [Arrows and patterns]
+~~~~~~~~~~~~~~~~~~~~~~~~~~
+(Oct 07) Arrow noation has the odd property that it involves "holes in the scope".
+For example:
+ expr :: Arrow a => a () Int
+ expr = proc (y,z) -> do
+ x <- term -< y
+ expr' -< x
+
+Here the 'proc (y,z)' binding scopes over the arrow tails but not the
+arrow body (e.g 'term'). As things stand (bogusly) all the
+constraints from the proc body are gathered together, so constraints
+from 'term' will be seen by the tcPat for (y,z). But we must *not*
+bind constraints from 'term' here, becuase the desugarer will not make
+these bindings scope over 'term'.
+
+The Right Thing is not to confuse these constraints together. But for
+now the Easy Thing is to ensure that we do not have existential or
+GADT constraints in a 'proc', and to short-cut the constraint
+simplification for such vanilla patterns so that it binds no
+constraints. Hence the 'fast path' in tcConPat; but it's also a good
+plan for ordinary vanilla patterns to bypass the constraint
+simplification step.
+
%************************************************************************
%* *
polyPatSig :: TcType -> SDoc
polyPatSig sig_ty
= hang (ptext SLIT("Illegal polymorphic type signature in pattern:"))
- 4 (ppr sig_ty)
+ 2 (ppr sig_ty)
badTypePat pat = ptext SLIT("Illegal type pattern") <+> ppr pat
+existentialProcPat :: DataCon -> SDoc
+existentialProcPat con
+ = hang (ptext SLIT("Illegal constructor") <+> quotes (ppr con) <+> ptext SLIT("in a 'proc' pattern"))
+ 2 (ptext SLIT("Proc patterns cannot use existentials or GADTs"))
+
lazyPatErr pat tvs
= failWithTc $
hang (ptext SLIT("A lazy (~) pattern cannot bind existential type variables"))