import {-# SOURCE #-} TcUnify( unifyTauTy )
import TcEnv -- temp
-import HsSyn ( HsBind(..), LHsBinds, HsExpr(..), LHsExpr )
+import HsSyn ( HsBind(..), HsExpr(..), LHsExpr, emptyLHsBinds )
import TcHsSyn ( TcId, TcDictBinds, mkHsApp, mkHsTyApp, mkHsDictApp )
import TcRnMonad
import Inst ( lookupInst, LookupInstResult(..),
- tyVarsOfInst, fdPredsOfInsts, fdPredsOfInst, newDicts,
+ tyVarsOfInst, fdPredsOfInsts, newDicts,
isDict, isClassDict, isLinearInst, linearInstType,
isStdClassTyVarDict, isMethodFor, isMethod,
instToId, tyVarsOfInsts, cloneDict,
ipNamesOfInsts, ipNamesOfInst, dictPred,
- instBindingRequired,
+ instBindingRequired, fdPredsOfInst,
newDictsFromOld, tcInstClassOp,
getDictClassTys, isTyVarDict,
instLoc, zonkInst, tidyInsts, tidyMoreInsts,
- Inst, pprInsts, pprInstsInFull, tcGetInstEnvs,
- isIPDict, isInheritableInst, pprDFuns
+ Inst, pprInsts, pprDictsInFull, pprInstInFull, tcGetInstEnvs,
+ isInheritableInst, pprDFuns, pprDictsTheta
)
-import TcEnv ( tcGetGlobalTyVars, tcLookupId, findGlobals )
-import InstEnv ( lookupInstEnv, classInstEnv )
+import TcEnv ( tcGetGlobalTyVars, tcLookupId, findGlobals, pprBinders )
+import InstEnv ( lookupInstEnv, classInstances )
import TcMType ( zonkTcTyVarsAndFV, tcInstTyVars, checkAmbiguity )
-import TcType ( TcTyVar, TcTyVarSet, ThetaType, TyVarDetails(VanillaTv),
- mkClassPred, isOverloadedTy, mkTyConApp,
+import TcType ( TcTyVar, TcTyVarSet, ThetaType,
+ mkClassPred, isOverloadedTy, mkTyConApp,
mkTyVarTy, tcGetTyVar, isTyVarClassPred, mkTyVarTys,
- tyVarsOfPred, tcEqType )
+ tyVarsOfPred, tcEqType, pprPred )
import Id ( idType, mkUserLocal )
import Var ( TyVar )
-import Name ( getOccName, getSrcLoc )
+import Name ( Name, getOccName, getSrcLoc )
import NameSet ( NameSet, mkNameSet, elemNameSet )
import Class ( classBigSig, classKey )
import FunDeps ( oclose, grow, improve, pprEquationDoc )
import PrelInfo ( isNumericClass )
import PrelNames ( splitName, fstName, sndName, integerTyConName,
showClassKey, eqClassKey, ordClassKey )
-import Subst ( mkTopTyVarSubst, substTheta, substTy )
+import Type ( zipTopTvSubst, substTheta, substTy )
import TysWiredIn ( pairTyCon, doubleTy )
import ErrUtils ( Message )
+import BasicTypes ( TopLevelFlag, isNotTopLevel )
import VarSet
import VarEnv ( TidyEnv )
import FiniteMap
%************************************************************************
--------------------------------------
+ Notes on functional dependencies (a bug)
+ --------------------------------------
+
+| > class Foo a b | a->b
+| >
+| > class Bar a b | a->b
+| >
+| > data Obj = Obj
+| >
+| > instance Bar Obj Obj
+| >
+| > instance (Bar a b) => Foo a b
+| >
+| > foo:: (Foo a b) => a -> String
+| > foo _ = "works"
+| >
+| > runFoo:: (forall a b. (Foo a b) => a -> w) -> w
+| > runFoo f = f Obj
+|
+| *Test> runFoo foo
+|
+| <interactive>:1:
+| Could not deduce (Bar a b) from the context (Foo a b)
+| arising from use of `foo' at <interactive>:1
+| Probable fix:
+| Add (Bar a b) to the expected type of an expression
+| In the first argument of `runFoo', namely `foo'
+| In the definition of `it': it = runFoo foo
+|
+| Why all of the sudden does GHC need the constraint Bar a b? The
+| function foo didn't ask for that...
+
+The trouble is that to type (runFoo foo), GHC has to solve the problem:
+
+ Given constraint Foo a b
+ Solve constraint Foo a b'
+
+Notice that b and b' aren't the same. To solve this, just do
+improvement and then they are the same. But GHC currently does
+ simplify constraints
+ apply improvement
+ and loop
+
+That is usually fine, but it isn't here, because it sees that Foo a b is
+not the same as Foo a b', and so instead applies the instance decl for
+instance Bar a b => Foo a b. And that's where the Bar constraint comes
+from.
+
+The Right Thing is to improve whenever the constraint set changes at
+all. Not hard in principle, but it'll take a bit of fiddling to do.
+
+
+
+ --------------------------------------
Notes on quantification
--------------------------------------
--------------------------------------
+ The need for forall's in constraints
+ --------------------------------------
+
+[Exchange on Haskell Cafe 5/6 Dec 2000]
+
+ class C t where op :: t -> Bool
+ instance C [t] where op x = True
+
+ p y = (let f :: c -> Bool; f x = op (y >> return x) in f, y ++ [])
+ q y = (y ++ [], let f :: c -> Bool; f x = op (y >> return x) in f)
+
+The definitions of p and q differ only in the order of the components in
+the pair on their right-hand sides. And yet:
+
+ ghc and "Typing Haskell in Haskell" reject p, but accept q;
+ Hugs rejects q, but accepts p;
+ hbc rejects both p and q;
+ nhc98 ... (Malcolm, can you fill in the blank for us!).
+
+The type signature for f forces context reduction to take place, and
+the results of this depend on whether or not the type of y is known,
+which in turn depends on which component of the pair the type checker
+analyzes first.
+
+Solution: if y::m a, float out the constraints
+ Monad m, forall c. C (m c)
+When m is later unified with [], we can solve both constraints.
+
+
+ --------------------------------------
Notes on implicit parameters
--------------------------------------
we follow the argument of Question 2 and generalise over ?y.
+Question 4: top level
+~~~~~~~~~~~~~~~~~~~~~
+At the top level, monomorhism makes no sense at all.
+
+ module Main where
+ main = let ?x = 5 in print foo
+
+ foo = woggle 3
+
+ woggle :: (?x :: Int) => Int -> Int
+ woggle y = ?x + y
+
+We definitely don't want (foo :: Int) with a top-level implicit parameter
+(?x::Int) becuase there is no way to bind it.
+
Possible choices
~~~~~~~~~~~~~~~~
| isClassDict inst = DontReduceUnlessConstant -- Dicts
| otherwise = ReduceMe -- Lits and Methods
in
- traceTc (text "infloop" <+> vcat [ppr tau_tvs', ppr wanteds', ppr preds, ppr (grow preds tau_tvs'), ppr qtvs]) `thenM_`
+ traceTc (text "infloop" <+> vcat [ppr tau_tvs', ppr wanteds', ppr preds,
+ ppr (grow preds tau_tvs'), ppr qtvs]) `thenM_`
-- Step 2
reduceContext doc try_me [] wanteds' `thenM` \ (no_improvement, frees, binds, irreds) ->
givens wanted_lie `thenM` \ (qtvs', binds) ->
returnM binds
where
- get_qtvs = zonkTcTyVarsAndFV qtvs
+-- get_qtvs = zonkTcTyVarsAndFV qtvs
+ get_qtvs = return (mkVarSet qtvs)
-- tcSimplifyInferCheck is used when we know the constraints we are to simplify
%* *
%************************************************************************
+tcSimplifyRestricted infers which type variables to quantify for a
+group of restricted bindings. This isn't trivial.
+
+Eg1: id = \x -> x
+ We want to quantify over a to get id :: forall a. a->a
+
+Eg2: eq = (==)
+ We do not want to quantify over a, because there's an Eq a
+ constraint, so we get eq :: a->a->Bool (notice no forall)
+
+So, assume:
+ RHS has type 'tau', whose free tyvars are tau_tvs
+ RHS has constraints 'wanteds'
+
+Plan A (simple)
+ Quantify over (tau_tvs \ ftvs(wanteds))
+ This is bad. The constraints may contain (Monad (ST s))
+ where we have instance Monad (ST s) where...
+ so there's no need to be monomorphic in s!
+
+ Also the constraint might be a method constraint,
+ whose type mentions a perfectly innocent tyvar:
+ op :: Num a => a -> b -> a
+ Here, b is unconstrained. A good example would be
+ foo = op (3::Int)
+ We want to infer the polymorphic type
+ foo :: forall b. b -> b
+
+
+Plan B (cunning, used for a long time up to and including GHC 6.2)
+ Step 1: Simplify the constraints as much as possible (to deal
+ with Plan A's problem). Then set
+ qtvs = tau_tvs \ ftvs( simplify( wanteds ) )
+
+ Step 2: Now simplify again, treating the constraint as 'free' if
+ it does not mention qtvs, and trying to reduce it otherwise.
+ The reasons for this is to maximise sharing.
+
+ This fails for a very subtle reason. Suppose that in the Step 2
+ a constraint (Foo (Succ Zero) (Succ Zero) b) gets thrown upstairs as 'free'.
+ In the Step 1 this constraint might have been simplified, perhaps to
+ (Foo Zero Zero b), AND THEN THAT MIGHT BE IMPROVED, to bind 'b' to 'T'.
+ This won't happen in Step 2... but that in turn might prevent some other
+ constraint (Baz [a] b) being simplified (e.g. via instance Baz [a] T where {..})
+ and that in turn breaks the invariant that no constraints are quantified over.
+
+ Test typecheck/should_compile/tc177 (which failed in GHC 6.2) demonstrates
+ the problem.
+
+
+Plan C (brutal)
+ Step 1: Simplify the constraints as much as possible (to deal
+ with Plan A's problem). Then set
+ qtvs = tau_tvs \ ftvs( simplify( wanteds ) )
+ Return the bindings from Step 1.
+
+
+A note about Plan C (arising from "bug" reported by George Russel March 2004)
+Consider this:
+
+ instance (HasBinary ty IO) => HasCodedValue ty
+
+ foo :: HasCodedValue a => String -> IO a
+
+ doDecodeIO :: HasCodedValue a => () -> () -> IO a
+ doDecodeIO codedValue view
+ = let { act = foo "foo" } in act
+
+You might think this should work becuase the call to foo gives rise to a constraint
+(HasCodedValue t), which can be satisfied by the type sig for doDecodeIO. But the
+restricted binding act = ... calls tcSimplifyRestricted, and PlanC simplifies the
+constraint using the (rather bogus) instance declaration, and now we are stuffed.
+
+I claim this is not really a bug -- but it bit Sergey as well as George. So here's
+plan D
+
+
+Plan D (a variant of plan B)
+ Step 1: Simplify the constraints as much as possible (to deal
+ with Plan A's problem), BUT DO NO IMPROVEMENT. Then set
+ qtvs = tau_tvs \ ftvs( simplify( wanteds ) )
+
+ Step 2: Now simplify again, treating the constraint as 'free' if
+ it does not mention qtvs, and trying to reduce it otherwise.
+
+ The point here is that it's generally OK to have too few qtvs; that is,
+ to make the thing more monomorphic than it could be. We don't want to
+ do that in the common cases, but in wierd cases it's ok: the programmer
+ can always add a signature.
+
+ Too few qtvs => too many wanteds, which is what happens if you do less
+ improvement.
+
+
\begin{code}
tcSimplifyRestricted -- Used for restricted binding groups
-- i.e. ones subject to the monomorphism restriction
:: SDoc
+ -> TopLevelFlag
+ -> [Name] -- Things bound in this group
-> TcTyVarSet -- Free in the type of the RHSs
-> [Inst] -- Free in the RHSs
-> TcM ([TcTyVar], -- Tyvars to quantify (zonked)
TcDictBinds) -- Bindings
+ -- tcSimpifyRestricted returns no constraints to
+ -- quantify over; by definition there are none.
+ -- They are all thrown back in the LIE
-tcSimplifyRestricted doc tau_tvs wanteds
- = -- First squash out all methods, to find the constrained tyvars
- -- We can't just take the free vars of wanted_lie because that'll
- -- have methods that may incidentally mention entirely unconstrained variables
- -- e.g. a call to f :: Eq a => a -> b -> b
- -- Here, b is unconstrained. A good example would be
- -- foo = f (3::Int)
- -- We want to infer the polymorphic type
- -- foo :: forall b. b -> b
-
- -- 'reduceMe': Reduce as far as we can. Don't stop at
+tcSimplifyRestricted doc top_lvl bndrs tau_tvs wanteds
+ -- Zonk everything in sight
+ = mappM zonkInst wanteds `thenM` \ wanteds' ->
+ zonkTcTyVarsAndFV (varSetElems tau_tvs) `thenM` \ tau_tvs' ->
+ tcGetGlobalTyVars `thenM` \ gbl_tvs' ->
+
+ -- 'reduceMe': Reduce as far as we can. Don't stop at
-- dicts; the idea is to get rid of as many type
-- variables as possible, and we don't want to stop
-- at (say) Monad (ST s), because that reduces
-- immediately, with no constraint on s.
- simpleReduceLoop doc reduceMe wanteds `thenM` \ (foo_frees, foo_binds, constrained_dicts) ->
+ --
+ -- BUT do no improvement! See Plan D above
+ reduceContextWithoutImprovement
+ doc reduceMe wanteds' `thenM` \ (_frees, _binds, constrained_dicts) ->
-- Next, figure out the tyvars we will quantify over
- zonkTcTyVarsAndFV (varSetElems tau_tvs) `thenM` \ tau_tvs' ->
- tcGetGlobalTyVars `thenM` \ gbl_tvs ->
let
constrained_tvs = tyVarsOfInsts constrained_dicts
- qtvs = (tau_tvs' `minusVarSet` oclose (fdPredsOfInsts constrained_dicts) gbl_tvs)
+ qtvs = (tau_tvs' `minusVarSet` oclose (fdPredsOfInsts constrained_dicts) gbl_tvs')
`minusVarSet` constrained_tvs
in
traceTc (text "tcSimplifyRestricted" <+> vcat [
- pprInsts wanteds, pprInsts foo_frees, pprInsts constrained_dicts,
- ppr foo_binds,
+ pprInsts wanteds, pprInsts _frees, pprInsts constrained_dicts,
+ ppr _binds,
ppr constrained_tvs, ppr tau_tvs', ppr qtvs ]) `thenM_`
-- The first step may have squashed more methods than
- -- necessary, so try again, this time knowing the exact
+ -- necessary, so try again, this time more gently, knowing the exact
-- set of type variables to quantify over.
--
-- We quantify only over constraints that are captured by qtvs;
-- Remember that we may need to do *some* simplification, to
-- (for example) squash {Monad (ST s)} into {}. It's not enough
-- just to float all constraints
- restrict_loop doc qtvs wanteds
- -- We still need a loop because improvement can take place
- -- E.g. if we have (C (T a)) and the instance decl
- -- instance D Int b => C (T a) where ...
- -- and there's a functional dependency for D. Then we may improve
- -- the tyep variable 'b'.
-
-restrict_loop doc qtvs wanteds
- = mappM zonkInst wanteds `thenM` \ wanteds' ->
- zonkTcTyVarsAndFV (varSetElems qtvs) `thenM` \ qtvs' ->
+ --
+ -- At top level, we *do* squash methods becuase we want to
+ -- expose implicit parameters to the test that follows
let
- try_me inst | isFreeWrtTyVars qtvs' inst = Free
- | otherwise = ReduceMe
+ is_nested_group = isNotTopLevel top_lvl
+ try_me inst | isFreeWrtTyVars qtvs inst,
+ (is_nested_group || isDict inst) = Free
+ | otherwise = ReduceMe
in
- reduceContext doc try_me [] wanteds' `thenM` \ (no_improvement, frees, binds, irreds) ->
- if no_improvement then
- ASSERT( null irreds )
- extendLIEs frees `thenM_`
- returnM (varSetElems qtvs', binds)
+ reduceContextWithoutImprovement
+ doc try_me wanteds' `thenM` \ (frees, binds, irreds) ->
+ ASSERT( null irreds )
+
+ -- See "Notes on implicit parameters, Question 4: top level"
+ if is_nested_group then
+ extendLIEs frees `thenM_`
+ returnM (varSetElems qtvs, binds)
else
- restrict_loop doc qtvs' (irreds ++ frees) `thenM` \ (qtvs1, binds1) ->
- returnM (qtvs1, binds `unionBags` binds1)
+ let
+ (non_ips, bad_ips) = partition isClassDict frees
+ in
+ addTopIPErrs bndrs bad_ips `thenM_`
+ extendLIEs non_ips `thenM_`
+ returnM (varSetElems qtvs, binds)
\end{code}
forall dIntegralInt, dNumInt.
fromIntegral Int Int dIntegralInt dNumInt = id Int
-Hence "DontReduce NoSCs"
+Hence "WithoutSCs"
\begin{code}
tcSimplifyToDicts :: [Inst] -> TcM (TcDictBinds)
doc = text "tcSimplifyToDicts"
-- Reduce methods and lits only; stop as soon as we get a dictionary
- try_me inst | isDict inst = DontReduce NoSCs -- See notes above for why NoSCs
+ try_me inst | isDict inst = KeepDictWithoutSCs -- See notes above re "WithoutSCs"
| otherwise = ReduceMe
\end{code}
@LIE@), as well as the @HsBinds@ generated.
\begin{code}
-bindInstsOfLocalFuns :: [Inst] -> [TcId] -> TcM (LHsBinds TcId)
+bindInstsOfLocalFuns :: [Inst] -> [TcId] -> TcM TcDictBinds
+-- Simlifies only MethodInsts, and generate only bindings of form
+-- fm = f tys dicts
+-- We're careful not to even generate bindings of the form
+-- d1 = d2
+-- You'd think that'd be fine, but it interacts with what is
+-- arguably a bug in Match.tidyEqnInfo (see notes there)
bindInstsOfLocalFuns wanteds local_ids
| null overloaded_ids
-- Common case
= extendLIEs wanteds `thenM_`
- returnM emptyBag
+ returnM emptyLHsBinds
| otherwise
- = simpleReduceLoop doc try_me wanteds `thenM` \ (frees, binds, irreds) ->
+ = simpleReduceLoop doc try_me for_me `thenM` \ (frees, binds, irreds) ->
ASSERT( null irreds )
+ extendLIEs not_for_me `thenM_`
extendLIEs frees `thenM_`
returnM binds
where
doc = text "bindInsts" <+> ppr local_ids
overloaded_ids = filter is_overloaded local_ids
is_overloaded id = isOverloadedTy (idType id)
+ (for_me, not_for_me) = partition (isMethodFor overloaded_set) wanteds
overloaded_set = mkVarSet overloaded_ids -- There can occasionally be a lot of them
-- so it's worth building a set, so that
-- lookup (in isMethodFor) is faster
-
- try_me inst | isMethodFor overloaded_set inst = ReduceMe
- | otherwise = Free
+ try_me inst | isMethod inst = ReduceMe
+ | otherwise = Free
\end{code}
-- produce an error message of any kind.
-- It might be quite legitimate such as (Eq a)!
- | DontReduce WantSCs -- Return as irreducible
+ | KeepDictWithoutSCs -- Return as irreducible; don't add its superclasses
+ -- Rather specialised: see notes with tcSimplifyToDicts
| DontReduceUnlessConstant -- Return as irreducible unless it can
-- be reduced to a constant in one step
\begin{code}
type Avails = FiniteMap Inst Avail
+emptyAvails = emptyFM
data Avail
= IsFree -- Used for free Insts
])) `thenM_`
-- Build the Avail mapping from "givens"
- foldlM addGiven emptyFM givens `thenM` \ init_state ->
+ foldlM addGiven emptyAvails givens `thenM` \ init_state ->
-- Do the real work
reduceList (0,[]) try_me wanteds init_state `thenM` \ avails ->
returnM (no_improvement, frees, binds, irreds)
+-- reduceContextWithoutImprovement differs from reduceContext
+-- (a) no improvement
+-- (b) 'givens' is assumed empty
+reduceContextWithoutImprovement doc try_me wanteds
+ =
+ traceTc (text "reduceContextWithoutImprovement" <+> (vcat [
+ text "----------------------",
+ doc,
+ text "wanted" <+> ppr wanteds,
+ text "----------------------"
+ ])) `thenM_`
+
+ -- Do the real work
+ reduceList (0,[]) try_me wanteds emptyAvails `thenM` \ avails ->
+ extractResults avails wanteds `thenM` \ (binds, irreds, frees) ->
+
+ traceTc (text "reduceContextWithoutImprovement end" <+> (vcat [
+ text "----------------------",
+ doc,
+ text "wanted" <+> ppr wanteds,
+ text "----",
+ text "avails" <+> pprAvails avails,
+ text "frees" <+> ppr frees,
+ text "----------------------"
+ ])) `thenM_`
+
+ returnM (frees, binds, irreds)
+
tcImprove :: Avails -> TcM Bool -- False <=> no change
-- Perform improvement using all the predicates in Avails
tcImprove avails
- = tcGetInstEnvs `thenM` \ (home_ie, pkg_ie) ->
+ = tcGetInstEnvs `thenM` \ inst_envs ->
let
preds = [ (pred, pp_loc)
- | inst <- keysFM avails,
- let pp_loc = pprInstLoc (instLoc inst),
- pred <- fdPredsOfInst inst
+ | (inst, avail) <- fmToList avails,
+ pred <- get_preds inst avail,
+ let pp_loc = pprInstLoc (instLoc inst)
]
-- Avails has all the superclasses etc (good)
-- It also has all the intermediates of the deduction (good)
-- It does not have duplicates (good)
-- NB that (?x::t1) and (?x::t2) will be held separately in avails
-- so that improve will see them separate
+
+ -- For free Methods, we want to take predicates from their context,
+ -- but for Methods that have been squished their context will already
+ -- be in Avails, and we don't want duplicates. Hence this rather
+ -- horrid get_preds function
+ get_preds inst IsFree = fdPredsOfInst inst
+ get_preds inst other | isDict inst = [dictPred inst]
+ | otherwise = []
+
eqns = improve get_insts preds
- get_insts clas = classInstEnv home_ie clas ++ classInstEnv pkg_ie clas
+ get_insts clas = classInstances inst_envs clas
in
if null eqns then
returnM True
mappM_ unify eqns `thenM_`
returnM False
where
- unify ((qtvs, t1, t2), doc)
- = addErrCtxt doc $
- tcInstTyVars VanillaTv (varSetElems qtvs) `thenM` \ (_, _, tenv) ->
- unifyTauTy (substTy tenv t1) (substTy tenv t2)
+ unify ((qtvs, pairs), doc)
+ = addErrCtxt doc $
+ tcInstTyVars (varSetElems qtvs) `thenM` \ (_, _, tenv) ->
+ mapM_ (unif_pr tenv) pairs
+ unif_pr tenv (ty1,ty2) = unifyTauTy (substTy tenv ty1) (substTy tenv ty2)
\end{code}
The main context-reduction function is @reduce@. Here's its game plan.
=
#ifdef DEBUG
(if n > 8 then
- pprTrace "Jeepers! ReduceContext:" (reduceDepthMsg n stack)
+ pprTrace "Interesting! Context reduction stack deeper than 8:"
+ (nest 2 (pprStack stack))
else (\x->x))
#endif
go wanteds state
| otherwise
= case try_me wanted of {
- DontReduce want_scs -> addIrred want_scs avails wanted
+ KeepDictWithoutSCs -> addIrred NoSCs avails wanted
; DontReduceUnlessConstant -> -- It's irreducible (or at least should not be reduced)
-- First, see if the inst can be reduced to a constant in one step
avails1 = addToFM avails inst avail
is_loop inst = any (`tcEqType` idType (instToId inst)) dep_tys
-- Note: this compares by *type*, not by Unique
- deps = findAllDeps emptyVarSet avail
+ deps = findAllDeps (unitVarSet (instToId inst)) avail
dep_tys = map idType (varSetElems deps)
findAllDeps :: IdSet -> Avail -> IdSet
-- See Note [SUPERCLASS-LOOP]
-- Watch out, though. Since the avails may contain loops
-- (see Note [RECURSIVE DICTIONARIES]), so we need to track the ones we've seen so far
- findAllDeps so_far (Rhs _ kids)
- = foldl findAllDeps
- (extendVarSetList so_far (map instToId kids)) -- Add the kids to so_far
- [a | Just a <- map (lookupFM avails) kids] -- Find the kids' Avail
- findAllDeps so_far other = so_far
-
+ findAllDeps so_far (Rhs _ kids) = foldl find_all so_far kids
+ findAllDeps so_far other = so_far
+
+ find_all :: IdSet -> Inst -> IdSet
+ find_all so_far kid
+ | kid_id `elemVarSet` so_far = so_far
+ | Just avail <- lookupFM avails kid = findAllDeps so_far' avail
+ | otherwise = so_far'
+ where
+ so_far' = extendVarSet so_far kid_id -- Add the new kid to so_far
+ kid_id = instToId kid
addSCs :: (Inst -> Bool) -> Avails -> Inst -> TcM Avails
-- Add all the superclasses of the Inst to Avails
where
(clas, tys) = getDictClassTys dict
(tyvars, sc_theta, sc_sels, _) = classBigSig clas
- sc_theta' = substTheta (mkTopTyVarSubst tyvars tys) sc_theta
+ sc_theta' = substTheta (zipTopTvSubst tyvars tys) sc_theta
add_sc avails (sc_dict, sc_sel) -- Add it, and its superclasses
| add_me sc_dict = addSCs is_loop avails' sc_dict
non_std_tyvars = unionVarSets (map tyVarsOfInst non_stds)
-- Collect together all the bad guys
- bad_guys = non_stds ++ concat std_bads
- (bad_ips, non_ips) = partition isIPDict bad_guys
- (no_insts, ambigs) = partition no_inst non_ips
- no_inst d = not (isTyVarDict d)
- -- Previously, there was a more elaborate no_inst definition:
- -- no_inst d = not (isTyVarDict d) || tyVarsOfInst d `subVarSet` fixed_tvs
- -- fixed_tvs = oclose (fdPredsOfInsts tidy_dicts) emptyVarSet
- -- But that seems over-elaborate to me; it only bites for class decls with
- -- fundeps like this: class C a b | -> b where ...
+ bad_guys = non_stds ++ concat std_bads
+ (non_ips, bad_ips) = partition isClassDict bad_guys
+ (ambigs, no_insts) = partition is_ambig non_ips
+ is_ambig d = not (tyVarsOfInst d `subVarSet` fixed_tvs)
+ fixed_tvs = oclose (fdPredsOfInsts irreds) emptyVarSet
+ -- If the dict has free type variables, it's almost certainly ambiguous,
+ -- and that's the first thing to fix.
+ -- Otherwise, addNoInstanceErrs does the right thing
+ -- I say "almost certain" because we might have
+ -- class C a b | a -> B where ...
+ -- plus an Inst (C Int x). Then the 'x' isn't ambiguous; it's just that
+ -- there's no instance decl for (C Int ...). Hence the oclose.
in
-- Report definite errors
groupErrs (addNoInstanceErrs Nothing []) no_insts `thenM_`
- addTopIPErrs bad_ips `thenM_`
+ strangeTopIPErrs bad_ips `thenM_`
-- Deal with ambiguity errors, but only if
-- if there has not been an error so far; errors often
-> TcM ThetaType -- Needed
tcSimplifyDeriv tyvars theta
- = tcInstTyVars VanillaTv tyvars `thenM` \ (tvs, _, tenv) ->
+ = tcInstTyVars tyvars `thenM` \ (tvs, _, tenv) ->
-- The main loop may do unification, and that may crash if
-- it doesn't see a TcTyVar, so we have to instantiate. Sigh
-- ToDo: what if two of them do get unified?
- newDicts DataDeclOrigin (substTheta tenv theta) `thenM` \ wanteds ->
+ newDicts DerivOrigin (substTheta tenv theta) `thenM` \ wanteds ->
simpleReduceLoop doc reduceMe wanteds `thenM` \ (frees, _, irreds) ->
ASSERT( null frees ) -- reduceMe never returns Free
doptM Opt_AllowUndecidableInstances `thenM` \ undecidable_ok ->
let
tv_set = mkVarSet tvs
- simpl_theta = map dictPred irreds -- reduceMe squashes all non-dicts
-
- check_pred pred
- | isEmptyVarSet pred_tyvars -- Things like (Eq T) should be rejected
- = addErrTc (noInstErr pred)
-
- | not undecidable_ok && not (isTyVarClassPred pred)
- -- Check that the returned dictionaries are all of form (C a b)
- -- (where a, b are type variables).
- -- We allow this if we had -fallow-undecidable-instances,
- -- but note that risks non-termination in the 'deriving' context-inference
- -- fixpoint loop. It is useful for situations like
- -- data Min h a = E | M a (h a)
- -- which gives the instance decl
- -- instance (Eq a, Eq (h a)) => Eq (Min h a)
- = addErrTc (noInstErr pred)
+
+ (bad_insts, ok_insts) = partition is_bad_inst irreds
+ is_bad_inst dict
+ = let pred = dictPred dict -- reduceMe squashes all non-dicts
+ in isEmptyVarSet (tyVarsOfPred pred)
+ -- Things like (Eq T) are bad
+ || (not undecidable_ok && not (isTyVarClassPred pred))
+ -- The returned dictionaries should be of form (C a b)
+ -- (where a, b are type variables).
+ -- We allow non-tyvar dicts if we had -fallow-undecidable-instances,
+ -- but note that risks non-termination in the 'deriving' context-inference
+ -- fixpoint loop. It is useful for situations like
+ -- data Min h a = E | M a (h a)
+ -- which gives the instance decl
+ -- instance (Eq a, Eq (h a)) => Eq (Min h a)
- | not (pred_tyvars `subVarSet` tv_set)
+ simpl_theta = map dictPred ok_insts
+ weird_preds = [pred | pred <- simpl_theta
+ , not (tyVarsOfPred pred `subVarSet` tv_set)]
-- Check for a bizarre corner case, when the derived instance decl should
-- have form instance C a b => D (T a) where ...
-- Note that 'b' isn't a parameter of T. This gives rise to all sorts
-- of problems; in particular, it's hard to compare solutions for
-- equality when finding the fixpoint. So I just rule it out for now.
- = addErrTc (badDerivedPred pred)
- | otherwise
- = returnM ()
- where
- pred_tyvars = tyVarsOfPred pred
-
- rev_env = mkTopTyVarSubst tvs (mkTyVarTys tyvars)
+ rev_env = zipTopTvSubst tvs (mkTyVarTys tyvars)
-- This reverse-mapping is a Royal Pain,
-- but the result should mention TyVars not TcTyVars
in
- mappM check_pred simpl_theta `thenM_`
- checkAmbiguity tvs simpl_theta tv_set `thenM_`
+ addNoInstanceErrs Nothing [] bad_insts `thenM_`
+ mapM_ (addErrTc . badDerivedPred) weird_preds `thenM_`
+ checkAmbiguity tvs simpl_theta tv_set `thenM_`
returnM (substTheta rev_env simpl_theta)
where
doc = ptext SLIT("deriving classes for a data type")
-> TcM ()
tcSimplifyDefault theta
- = newDicts DataDeclOrigin theta `thenM` \ wanteds ->
+ = newDicts DefaultOrigin theta `thenM` \ wanteds ->
simpleReduceLoop doc reduceMe wanteds `thenM` \ (frees, _, irreds) ->
ASSERT( null frees ) -- try_me never returns Free
- mappM (addErrTc . noInstErr) irreds `thenM_`
+ addNoInstanceErrs Nothing [] irreds `thenM_`
if null irreds then
returnM ()
else
plural [x] = empty
plural xs = char 's'
-addTopIPErrs dicts
+addTopIPErrs :: [Name] -> [Inst] -> TcM ()
+addTopIPErrs bndrs []
+ = return ()
+addTopIPErrs bndrs ips
+ = addErrTcM (tidy_env, mk_msg tidy_ips)
+ where
+ (tidy_env, tidy_ips) = tidyInsts ips
+ mk_msg ips = vcat [sep [ptext SLIT("Implicit parameters escape from the monomorphic top-level binding(s) of"),
+ pprBinders bndrs <> colon],
+ nest 2 (vcat (map ppr_ip ips)),
+ monomorphism_fix]
+ ppr_ip ip = pprPred (dictPred ip) <+> pprInstLoc (instLoc ip)
+
+strangeTopIPErrs :: [Inst] -> TcM ()
+strangeTopIPErrs dicts -- Strange, becuase addTopIPErrs should have caught them all
= groupErrs report tidy_dicts
where
(tidy_env, tidy_dicts) = tidyInsts dicts
report dicts = addErrTcM (tidy_env, mk_msg dicts)
mk_msg dicts = addInstLoc dicts (ptext SLIT("Unbound implicit parameter") <>
- plural tidy_dicts <+> pprInsts tidy_dicts)
+ plural tidy_dicts <+> pprDictsTheta tidy_dicts)
addNoInstanceErrs :: Maybe SDoc -- Nothing => top level
-- Just d => d describes the construct
addNoInstanceErrs mb_what givens dicts
= -- Some of the dicts are here because there is no instances
-- and some because there are too many instances (overlap)
- -- The first thing we do is separate them
getDOpts `thenM` \ dflags ->
tcGetInstEnvs `thenM` \ inst_envs ->
let
| not (isClassDict dict) = (overlap_doc, dict : no_inst_dicts)
| otherwise
= case lookupInstEnv dflags inst_envs clas tys of
- res@(ms, _)
- | length ms > 1 -> (mk_overlap_msg dict res $$ overlap_doc, no_inst_dicts)
- | otherwise -> (overlap_doc, dict : no_inst_dicts) -- No match
- -- NB: there can be exactly one match, in the case where we have
- -- instance C a where ...
- -- (In this case, lookupInst doesn't bother to look up,
- -- unless -fallow-undecidable-instances is set.)
- -- So we report this as "no instance" rather than "overlap"; the fix is
- -- to specify -fallow-undecidable-instances, but we leave that to the programmer!
+ -- The case of exactly one match and no unifiers means
+ -- a successful lookup. That can't happen here, becuase
+ -- dicts only end up here if they didn't match in Inst.lookupInst
+#ifdef DEBUG
+ ([m],[]) -> pprPanic "addNoInstanceErrs" (ppr dict)
+#endif
+ ([], _) -> (overlap_doc, dict : no_inst_dicts) -- No match
+ res -> (mk_overlap_msg dict res $$ overlap_doc, no_inst_dicts)
where
(clas,tys) = getDictClassTys dict
in
- mk_probable_fix tidy_env2 mb_what no_inst_dicts `thenM` \ (tidy_env3, probable_fix) ->
+
+ -- Now generate a good message for the no-instance bunch
+ mk_probable_fix tidy_env2 no_inst_dicts `thenM` \ (tidy_env3, probable_fix) ->
let
no_inst_doc | null no_inst_dicts = empty
| otherwise = vcat [addInstLoc no_inst_dicts heading, probable_fix]
heading | null givens = ptext SLIT("No instance") <> plural no_inst_dicts <+>
- ptext SLIT("for") <+> pprInsts no_inst_dicts
- | otherwise = sep [ptext SLIT("Could not deduce") <+> pprInsts no_inst_dicts,
- nest 2 $ ptext SLIT("from the context") <+> pprInsts tidy_givens]
+ ptext SLIT("for") <+> pprDictsTheta no_inst_dicts
+ | otherwise = sep [ptext SLIT("Could not deduce") <+> pprDictsTheta no_inst_dicts,
+ nest 2 $ ptext SLIT("from the context") <+> pprDictsTheta tidy_givens]
in
+ -- And emit both the non-instance and overlap messages
addErrTcM (tidy_env3, no_inst_doc $$ overlap_doc)
-
where
mk_overlap_msg dict (matches, unifiers)
- = vcat [ addInstLoc [dict] ((ptext SLIT("Overlapping instances for") <+> ppr dict)),
+ = vcat [ addInstLoc [dict] ((ptext SLIT("Overlapping instances for")
+ <+> pprPred (dictPred dict))),
sep [ptext SLIT("Matching instances") <> colon,
- nest 2 (pprDFuns (dfuns ++ unifiers))],
- if null unifiers
- then empty
- else parens (ptext SLIT("The choice depends on the instantiation of") <+>
- quotes (pprWithCommas ppr (varSetElems (tyVarsOfInst dict))))]
+ nest 2 (vcat [pprDFuns dfuns, pprDFuns unifiers])],
+ ASSERT( not (null matches) )
+ if not (isSingleton matches)
+ then -- Two or more matches
+ empty
+ else -- One match, plus some unifiers
+ ASSERT( not (null unifiers) )
+ parens (vcat [ptext SLIT("The choice depends on the instantiation of") <+>
+ quotes (pprWithCommas ppr (varSetElems (tyVarsOfInst dict))),
+ ptext SLIT("Use -fallow-incoherent-instances to use the first choice above")])]
where
dfuns = [df | (_, (_,_,df)) <- matches]
- mk_probable_fix tidy_env Nothing dicts -- Top level
- = mkMonomorphismMsg tidy_env dicts
- mk_probable_fix tidy_env (Just what) dicts -- Nested (type signatures, instance decls)
- = returnM (tidy_env, sep [ptext SLIT("Probable fix:"), nest 2 fix1, nest 2 fix2])
+ mk_probable_fix tidy_env dicts
+ = returnM (tidy_env, sep [ptext SLIT("Probable fix:"), nest 2 (vcat fixes)])
where
- fix1 = sep [ptext SLIT("Add") <+> pprInsts dicts,
- ptext SLIT("to the") <+> what]
+ fixes = add_ors (fix1 ++ fix2)
- fix2 | null instance_dicts = empty
- | otherwise = ptext SLIT("Or add an instance declaration for")
- <+> pprInsts instance_dicts
+ fix1 = case mb_what of
+ Nothing -> [] -- Top level
+ Just what -> -- Nested (type signatures, instance decls)
+ [ sep [ ptext SLIT("add") <+> pprDictsTheta dicts,
+ ptext SLIT("to the") <+> what] ]
+
+ fix2 | null instance_dicts = []
+ | otherwise = [ ptext SLIT("add an instance declaration for")
+ <+> pprDictsTheta instance_dicts ]
instance_dicts = [d | d <- dicts, isClassDict d, not (isTyVarDict d)]
-- Insts for which it is worth suggesting an adding an instance declaration
-- Exclude implicit parameters, and tyvar dicts
+ add_ors :: [SDoc] -> [SDoc]
+ add_ors (f1:fs) = f1 : map (ptext SLIT("or") <+>) fs
addTopAmbigErrs dicts
-- Divide into groups that share a common set of ambiguous tyvars
report :: [(Inst,[TcTyVar])] -> TcM ()
report pairs@((inst,tvs) : _) -- The pairs share a common set of ambiguous tyvars
- = mkMonomorphismMsg tidy_env dicts `thenM` \ (tidy_env, mono_msg) ->
- addSrcSpan (instLocSrcSpan (instLoc inst)) $
+ = mkMonomorphismMsg tidy_env tvs `thenM` \ (tidy_env, mono_msg) ->
+ setSrcSpan (instLocSrcSpan (instLoc inst)) $
-- the location of the first one will do for the err message
addErrTcM (tidy_env, msg $$ mono_msg)
where
dicts = map fst pairs
msg = sep [text "Ambiguous type variable" <> plural tvs <+>
- pprQuotedList tvs <+> in_msg,
- nest 2 (pprInstsInFull dicts)]
- in_msg | isSingleton dicts = text "in the top-level constraint:"
- | otherwise = text "in these top-level constraints:"
+ pprQuotedList tvs <+> in_msg,
+ nest 2 (pprDictsInFull dicts)]
+ in_msg = text "in the constraint" <> plural dicts <> colon
-mkMonomorphismMsg :: TidyEnv -> [Inst] -> TcM (TidyEnv, Message)
+mkMonomorphismMsg :: TidyEnv -> [TcTyVar] -> TcM (TidyEnv, Message)
-- There's an error with these Insts; if they have free type variables
-- it's probably caused by the monomorphism restriction.
-- Try to identify the offending variable
-- ASSUMPTION: the Insts are fully zonked
-mkMonomorphismMsg tidy_env insts
- | isEmptyVarSet inst_tvs
- = returnM (tidy_env, empty)
- | otherwise
- = findGlobals inst_tvs tidy_env `thenM` \ (tidy_env, docs) ->
+mkMonomorphismMsg tidy_env inst_tvs
+ = findGlobals (mkVarSet inst_tvs) tidy_env `thenM` \ (tidy_env, docs) ->
returnM (tidy_env, mk_msg docs)
-
where
- inst_tvs = tyVarsOfInsts insts
-
- mk_msg [] = empty -- This happens in things like
- -- f x = show (read "foo")
- -- whre monomorphism doesn't play any role
+ mk_msg [] = ptext SLIT("Probable fix: add a type signature that fixes these type variable(s)")
+ -- This happens in things like
+ -- f x = show (read "foo")
+ -- whre monomorphism doesn't play any role
mk_msg docs = vcat [ptext SLIT("Possible cause: the monomorphism restriction applied to the following:"),
nest 2 (vcat docs),
- ptext SLIT("Probable fix: give these definition(s) an explicit type signature")]
+ monomorphism_fix
+ ]
+monomorphism_fix :: SDoc
+monomorphism_fix = ptext SLIT("Probable fix:") <+>
+ (ptext SLIT("give these definition(s) an explicit type signature")
+ $$ ptext SLIT("or use -fno-monomorphism-restriction"))
warnDefault dicts default_ty
= doptM Opt_WarnTypeDefaults `thenM` \ warn_flag ->
(_, tidy_dicts) = tidyInsts dicts
warn_msg = vcat [ptext SLIT("Defaulting the following constraint(s) to type") <+>
quotes (ppr default_ty),
- pprInstsInFull tidy_dicts]
+ pprDictsInFull tidy_dicts]
-- Used for the ...Thetas variants; all top level
-noInstErr pred = ptext SLIT("No instance for") <+> quotes (ppr pred)
-
badDerivedPred pred
= vcat [ptext SLIT("Can't derive instances where the instance context mentions"),
ptext SLIT("type variables that are not data type parameters"),
reduceDepthErr n stack
= vcat [ptext SLIT("Context reduction stack overflow; size =") <+> int n,
ptext SLIT("Use -fcontext-stack20 to increase stack size to (e.g.) 20"),
- nest 4 (pprInstsInFull stack)]
+ nest 4 (pprStack stack)]
-reduceDepthMsg n stack = nest 4 (pprInstsInFull stack)
+pprStack stack = vcat (map pprInstInFull stack)
\end{code}