2 % (c) The University of Glasgow 2006
3 % (c) The GRASP/AQUA Project, Glasgow University, 2000
6 FunDeps - functional dependencies
8 It's better to read it as: "if we know these, then we're going to know these"
12 Equation, pprEquation,
13 oclose, improveFromInstEnv, improveFromAnother,
14 checkInstCoverage, checkFunDeps,
18 #include "HsVersions.h"
32 import Data.List ( nubBy )
33 import Data.Maybe ( isJust )
37 %************************************************************************
39 \subsection{Close type variables}
41 %************************************************************************
43 oclose(vs,C) The result of extending the set of tyvars vs
44 using the functional dependencies from C
46 grow(vs,C) The result of extend the set of tyvars vs
47 using all conceivable links from C.
49 E.g. vs = {a}, C = {H [a] b, K (b,Int) c, Eq e}
50 Then grow(vs,C) = {a,b,c}
52 Note that grow(vs,C) `superset` grow(vs,simplify(C))
53 That is, simplfication can only shrink the result of grow.
56 oclose is conservative v `elem` oclose(vs,C)
57 one way: => v is definitely fixed by vs
59 grow is conservative if v might be fixed by vs
60 the other way: => v `elem` grow(vs,C)
62 ----------------------------------------------------------
63 (oclose preds tvs) closes the set of type variables tvs,
64 wrt functional dependencies in preds. The result is a superset
65 of the argument set. For example, if we have
66 class C a b | a->b where ...
68 oclose [C (x,y) z, C (x,p) q] {x,y} = {x,y,z}
69 because if we know x and y then that fixes z.
71 oclose is used (only) when generalising a type T; see extensive
74 Note [Important subtlety in oclose]
75 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
76 Consider (oclose (C Int t) {}), where class C a b | a->b
77 Then, since a->b, 't' is fully determined by Int, and the
78 uniform thing is to return {t}.
82 f x = e -- 'e' generates constraint (D s Int t)
84 Then, if (oclose (D s Int t) {}) = {t}, we'll make the function
85 monomorphic in 't', thus
86 f :: forall s. D s Int t => s -> s
88 But if this function is never called, 't' will never be instantiated;
89 the functional dependencies that fix 't' may well be instance decls in
90 some importing module. But the top-level defaulting of unconstrained
91 type variables will fix t=GHC.Prim.Any, and that's simply a bug.
93 Conclusion: oclose only returns a type variable as "fixed" if it
94 depends on at least one type variable in the input fixed_tvs.
96 Remember, it's always sound for oclose to return a smaller set.
97 An interesting example is tcfail093, where we get this inferred type:
99 dup :: forall h. (Call (IO Int) h) => () -> Int -> h
100 This is perhaps a bit silly, because 'h' is fixed by the (IO Int);
101 previously GHC rejected this saying 'no instance for Call (IO Int) h'.
102 But it's right on the borderline. If there was an extra, otherwise
103 uninvolved type variable, like 's' in the type of 'f' above, then
104 we must accept the function. So, for now anyway, we accept 'dup' too.
107 oclose :: [PredType] -> TyVarSet -> TyVarSet
108 oclose preds fixed_tvs
109 | null tv_fds = fixed_tvs -- Fast escape hatch for common case
110 | isEmptyVarSet fixed_tvs = emptyVarSet -- Note [Important subtlety in oclose]
111 | otherwise = loop fixed_tvs
114 | new_fixed_tvs `subVarSet` fixed_tvs = fixed_tvs
115 | otherwise = loop new_fixed_tvs
117 new_fixed_tvs = foldl extend fixed_tvs tv_fds
119 extend fixed_tvs (ls,rs)
120 | not (isEmptyVarSet ls) -- Note [Important subtlety in oclose]
121 , ls `subVarSet` fixed_tvs = fixed_tvs `unionVarSet` rs
122 | otherwise = fixed_tvs
124 tv_fds :: [(TyVarSet,TyVarSet)]
125 -- In our example, tv_fds will be [ ({x,y}, {z}), ({x,p},{q}) ]
126 -- Meaning "knowing x,y fixes z, knowing x,p fixes q"
127 tv_fds = [ (tyVarsOfTypes xs, tyVarsOfTypes ys)
128 | ClassP cls tys <- preds, -- Ignore implicit params
129 let (cls_tvs, cls_fds) = classTvsFds cls,
131 let (xs,ys) = instFD fd cls_tvs tys
136 %************************************************************************
138 \subsection{Generate equations from functional dependencies}
140 %************************************************************************
144 type Equation = (TyVarSet, [(Type, Type)])
145 -- These pairs of types should be equal, for some
146 -- substitution of the tyvars in the tyvar set
147 -- INVARIANT: corresponding types aren't already equal
149 -- It's important that we have a *list* of pairs of types. Consider
150 -- class C a b c | a -> b c where ...
151 -- instance C Int x x where ...
152 -- Then, given the constraint (C Int Bool v) we should improve v to Bool,
153 -- via the equation ({x}, [(Bool,x), (v,x)])
154 -- This would not happen if the class had looked like
155 -- class C a b c | a -> b, a -> c
157 -- To "execute" the equation, make fresh type variable for each tyvar in the set,
158 -- instantiate the two types with these fresh variables, and then unify.
160 -- For example, ({a,b}, (a,Int,b), (Int,z,Bool))
161 -- We unify z with Int, but since a and b are quantified we do nothing to them
162 -- We usually act on an equation by instantiating the quantified type varaibles
163 -- to fresh type variables, and then calling the standard unifier.
165 pprEquation :: Equation -> SDoc
166 pprEquation (qtvs, pairs)
167 = vcat [ptext (sLit "forall") <+> braces (pprWithCommas ppr (varSetElems qtvs)),
168 nest 2 (vcat [ ppr t1 <+> ptext (sLit "~") <+> ppr t2 | (t1,t2) <- pairs])]
171 Given a bunch of predicates that must hold, such as
173 C Int t1, C Int t2, C Bool t3, ?x::t4, ?x::t5
175 improve figures out what extra equations must hold.
176 For example, if we have
178 class C a b | a->b where ...
180 then improve will return
186 * improve does not iterate. It's possible that when we make
187 t1=t2, for example, that will in turn trigger a new equation.
188 This would happen if we also had
190 If t1=t2, we also get t7=t8.
192 improve does *not* do this extra step. It relies on the caller
195 * The equations unify types that are not already equal. So there
196 is no effect iff the result of improve is empty
201 type Pred_Loc = (PredType, SDoc) -- SDoc says where the Pred comes from
203 improveFromInstEnv :: (Class -> [Instance])
205 -> [(Equation,Pred_Loc,Pred_Loc)]
206 -- Improvement from top-level instances
207 improveFromInstEnv _inst_env pred
208 = improveOne _inst_env pred [] -- TODO: Refactor to directly use instance_eqnd?
211 improveFromAnother :: Pred_Loc
213 -> [(Equation, Pred_Loc, Pred_Loc)]
214 -- Improvement from another local (given or wanted) constraint
215 improveFromAnother pred1 pred2
216 = improveOne (\_ -> []) pred1 [pred2] -- TODO: Refactor to directly use pairwise_eqns?
219 improveOne :: (Class -> [Instance]) -- Gives instances for given class
220 -> Pred_Loc -- Do improvement triggered by this
221 -> [Pred_Loc] -- Current constraints
222 -> [(Equation,Pred_Loc,Pred_Loc)] -- Derived equalities that must also hold
223 -- (NB the above INVARIANT for type Equation)
224 -- The Pred_Locs explain which two predicates were
225 -- combined (for error messages)
226 -- Just do improvement triggered by a single, distinguised predicate
228 improveOne _inst_env pred@(IParam ip ty, _) preds
229 = [ ((emptyVarSet, [(ty,ty2)]), pred, p2)
230 | p2@(IParam ip2 ty2, _) <- preds
232 , not (ty `tcEqType` ty2)]
234 improveOne inst_env pred@(ClassP cls tys, _) preds
235 | tys `lengthAtLeast` 2
236 = instance_eqns ++ pairwise_eqns
237 -- NB: we put the instance equations first. This biases the
238 -- order so that we first improve individual constraints against the
239 -- instances (which are perhaps in a library and less likely to be
240 -- wrong; and THEN perform the pairwise checks.
241 -- The other way round, it's possible for the pairwise check to succeed
242 -- and cause a subsequent, misleading failure of one of the pair with an
243 -- instance declaration. See tcfail143.hs for an example
245 (cls_tvs, cls_fds) = classTvsFds cls
246 instances = inst_env cls
247 rough_tcs = roughMatchTcs tys
249 -- NOTE that we iterate over the fds first; they are typically
250 -- empty, which aborts the rest of the loop.
251 pairwise_eqns :: [(Equation,Pred_Loc,Pred_Loc)]
252 pairwise_eqns -- This group comes from pairwise comparison
255 , p2@(ClassP cls2 tys2, _) <- preds
257 , eqn <- checkClsFD emptyVarSet fd cls_tvs tys tys2
260 instance_eqns :: [(Equation,Pred_Loc,Pred_Loc)]
261 instance_eqns -- This group comes from comparing with instance decls
262 = [ (eqn, p_inst, pred)
263 | fd <- cls_fds -- Iterate through the fundeps first,
264 -- because there often are none!
265 , let trimmed_tcs = trimRoughMatchTcs cls_tvs fd rough_tcs
266 -- Trim the rough_tcs based on the head of the fundep.
267 -- Remember that instanceCantMatch treats both argumnents
268 -- symmetrically, so it's ok to trim the rough_tcs,
269 -- rather than trimming each inst_tcs in turn
270 , ispec@(Instance { is_tvs = qtvs, is_tys = tys_inst,
271 is_tcs = inst_tcs }) <- instances
272 , not (instanceCantMatch inst_tcs trimmed_tcs)
273 , eqn <- checkClsFD qtvs fd cls_tvs tys_inst tys
274 , let p_inst = (mkClassPred cls tys_inst,
275 sep [ ptext (sLit "arising from the dependency") <+> quotes (pprFunDep fd)
276 , ptext (sLit "in the instance declaration at")
277 <+> ppr (getSrcLoc ispec)])
284 checkClsFD :: TyVarSet -- Quantified type variables; see note below
285 -> FunDep TyVar -> [TyVar] -- One functional dependency from the class
289 checkClsFD qtvs fd clas_tvs tys1 tys2
290 -- 'qtvs' are the quantified type variables, the ones which an be instantiated
291 -- to make the types match. For example, given
292 -- class C a b | a->b where ...
293 -- instance C (Maybe x) (Tree x) where ..
295 -- and an Inst of form (C (Maybe t1) t2),
296 -- then we will call checkClsFD with
298 -- qtvs = {x}, tys1 = [Maybe x, Tree x]
299 -- tys2 = [Maybe t1, t2]
301 -- We can instantiate x to t1, and then we want to force
302 -- (Tree x) [t1/x] ~ t2
304 -- This function is also used when matching two Insts (rather than an Inst
305 -- against an instance decl. In that case, qtvs is empty, and we are doing
308 -- This function is also used by InstEnv.badFunDeps, which needs to *unify*
309 -- For the one-sided matching case, the qtvs are just from the template,
310 -- so we get matching
312 = ASSERT2( length tys1 == length tys2 &&
313 length tys1 == length clas_tvs
314 , ppr tys1 <+> ppr tys2 )
316 case tcUnifyTys bind_fn ls1 ls2 of
318 Just subst | isJust (tcUnifyTys bind_fn rs1' rs2')
319 -- Don't include any equations that already hold.
320 -- Reason: then we know if any actual improvement has happened,
321 -- in which case we need to iterate the solver
322 -- In making this check we must taking account of the fact that any
323 -- qtvs that aren't already instantiated can be instantiated to anything
327 | otherwise -- Aha! A useful equation
328 -> [ (qtvs', zip rs1' rs2')]
329 -- We could avoid this substTy stuff by producing the eqn
330 -- (qtvs, ls1++rs1, ls2++rs2)
331 -- which will re-do the ls1/ls2 unification when the equation is
332 -- executed. What we're doing instead is recording the partial
333 -- work of the ls1/ls2 unification leaving a smaller unification problem
335 rs1' = substTys subst rs1
336 rs2' = substTys subst rs2
337 qtvs' = filterVarSet (`notElemTvSubst` subst) qtvs
338 -- qtvs' are the quantified type variables
339 -- that have not been substituted out
341 -- Eg. class C a b | a -> b
342 -- instance C Int [y]
343 -- Given constraint C Int z
344 -- we generate the equation
347 bind_fn tv | tv `elemVarSet` qtvs = BindMe
350 (ls1, rs1) = instFD fd clas_tvs tys1
351 (ls2, rs2) = instFD fd clas_tvs tys2
353 instFD :: FunDep TyVar -> [TyVar] -> [Type] -> FunDep Type
354 instFD (ls,rs) tvs tys
355 = (map lookup ls, map lookup rs)
357 env = zipVarEnv tvs tys
358 lookup tv = lookupVarEnv_NF env tv
362 checkInstCoverage :: Class -> [Type] -> Bool
363 -- Check that the Coverage Condition is obeyed in an instance decl
364 -- For example, if we have
365 -- class theta => C a b | a -> b
367 -- Then we require fv(t2) `subset` fv(t1)
368 -- See Note [Coverage Condition] below
370 checkInstCoverage clas inst_taus
373 (tyvars, fds) = classTvsFds clas
374 fundep_ok fd = tyVarsOfTypes rs `subVarSet` tyVarsOfTypes ls
376 (ls,rs) = instFD fd tyvars inst_taus
379 Note [Coverage condition]
380 ~~~~~~~~~~~~~~~~~~~~~~~~~
381 For the coverage condition, we used to require only that
382 fv(t2) `subset` oclose(fv(t1), theta)
385 class Mul a b c | a b -> c where
388 instance Mul Int Int Int where (.*.) = (*)
389 instance Mul Int Float Float where x .*. y = fromIntegral x * y
390 instance Mul a b c => Mul a [b] [c] where x .*. v = map (x.*.) v
392 In the third instance, it's not the case that fv([c]) `subset` fv(a,[b]).
393 But it is the case that fv([c]) `subset` oclose( theta, fv(a,[b]) )
395 But it is a mistake to accept the instance because then this defn:
396 f = \ b x y -> if b then x .*. [y] else y
397 makes instance inference go into a loop, because it requires the constraint
401 %************************************************************************
403 Check that a new instance decl is OK wrt fundeps
405 %************************************************************************
407 Here is the bad case:
408 class C a b | a->b where ...
409 instance C Int Bool where ...
410 instance C Int Char where ...
412 The point is that a->b, so Int in the first parameter must uniquely
413 determine the second. In general, given the same class decl, and given
415 instance C s1 s2 where ...
416 instance C t1 t2 where ...
418 Then the criterion is: if U=unify(s1,t1) then U(s2) = U(t2).
420 Matters are a little more complicated if there are free variables in
423 class D a b c | a -> b
424 instance D a b => D [(a,a)] [b] Int
425 instance D a b => D [a] [b] Bool
427 The instance decls don't overlap, because the third parameter keeps
428 them separate. But we want to make sure that given any constraint
434 checkFunDeps :: (InstEnv, InstEnv) -> Instance
435 -> Maybe [Instance] -- Nothing <=> ok
436 -- Just dfs <=> conflict with dfs
437 -- Check wheher adding DFunId would break functional-dependency constraints
438 -- Used only for instance decls defined in the module being compiled
439 checkFunDeps inst_envs ispec
440 | null bad_fundeps = Nothing
441 | otherwise = Just bad_fundeps
443 (ins_tvs, _, clas, ins_tys) = instanceHead ispec
444 ins_tv_set = mkVarSet ins_tvs
445 cls_inst_env = classInstances inst_envs clas
446 bad_fundeps = badFunDeps cls_inst_env clas ins_tv_set ins_tys
448 badFunDeps :: [Instance] -> Class
449 -> TyVarSet -> [Type] -- Proposed new instance type
451 badFunDeps cls_insts clas ins_tv_set ins_tys
453 [ ispec | fd <- fds, -- fds is often empty, so do this first!
454 let trimmed_tcs = trimRoughMatchTcs clas_tvs fd rough_tcs,
455 ispec@(Instance { is_tcs = inst_tcs, is_tvs = tvs,
456 is_tys = tys }) <- cls_insts,
457 -- Filter out ones that can't possibly match,
458 -- based on the head of the fundep
459 not (instanceCantMatch inst_tcs trimmed_tcs),
460 notNull (checkClsFD (tvs `unionVarSet` ins_tv_set)
461 fd clas_tvs tys ins_tys)
464 (clas_tvs, fds) = classTvsFds clas
465 rough_tcs = roughMatchTcs ins_tys
466 eq_inst i1 i2 = instanceDFunId i1 == instanceDFunId i2
467 -- An single instance may appear twice in the un-nubbed conflict list
468 -- because it may conflict with more than one fundep. E.g.
469 -- class C a b c | a -> b, a -> c
470 -- instance C Int Bool Bool
471 -- instance C Int Char Char
472 -- The second instance conflicts with the first by *both* fundeps
474 trimRoughMatchTcs :: [TyVar] -> FunDep TyVar -> [Maybe Name] -> [Maybe Name]
475 -- Computing rough_tcs for a particular fundep
476 -- class C a b c | a -> b where ...
477 -- For each instance .... => C ta tb tc
478 -- we want to match only on the type ta; so our
479 -- rough-match thing must similarly be filtered.
480 -- Hence, we Nothing-ise the tb and tc types right here
481 trimRoughMatchTcs clas_tvs (ltvs, _) mb_tcs
482 = zipWith select clas_tvs mb_tcs
484 select clas_tv mb_tc | clas_tv `elem` ltvs = mb_tc
485 | otherwise = Nothing