Reinstate monomorphism-restriction warnings
[ghc.git] / compiler / typecheck / TcRnDriver.hs
1 {-
2 (c) The University of Glasgow 2006
3 (c) The GRASP/AQUA Project, Glasgow University, 1992-1998
4
5 \section[TcMovectle]{Typechecking a whole module}
6
7 https://ghc.haskell.org/trac/ghc/wiki/Commentary/Compiler/TypeChecker
8 -}
9
10 {-# LANGUAGE CPP, NondecreasingIndentation #-}
11
12 module TcRnDriver (
13 #ifdef GHCI
14 tcRnStmt, tcRnExpr, tcRnType,
15 tcRnImportDecls,
16 tcRnLookupRdrName,
17 getModuleInterface,
18 tcRnDeclsi,
19 isGHCiMonad,
20 runTcInteractive, -- Used by GHC API clients (Trac #8878)
21 #endif
22 tcRnLookupName,
23 tcRnGetInfo,
24 tcRnModule, tcRnModuleTcRnM,
25 tcTopSrcDecls,
26 ) where
27
28 #ifdef GHCI
29 import {-# SOURCE #-} TcSplice ( runQuasi )
30 import RnSplice ( rnTopSpliceDecls, traceSplice, SpliceInfo(..) )
31 import IfaceEnv( externaliseName )
32 import TcType ( isUnitTy, isTauTy )
33 import TcHsType
34 import TcMatches
35 import RnTypes
36 import RnExpr
37 import MkId
38 import TidyPgm ( globaliseAndTidyId )
39 import TysWiredIn ( unitTy, mkListTy )
40 import DynamicLoading ( loadPlugins )
41 import Plugins ( tcPlugin )
42 #endif
43
44 import DynFlags
45 import StaticFlags
46 import HsSyn
47 import PrelNames
48 import RdrName
49 import TcHsSyn
50 import TcExpr
51 import TcRnMonad
52 import TcEvidence
53 import PprTyThing( pprTyThing )
54 import Coercion( pprCoAxiom )
55 import FamInst
56 import InstEnv
57 import FamInstEnv
58 import TcAnnotations
59 import TcBinds
60 import HeaderInfo ( mkPrelImports )
61 import TcDefaults
62 import TcEnv
63 import TcRules
64 import TcForeign
65 import TcInstDcls
66 import TcIface
67 import TcMType
68 import MkIface
69 import TcSimplify
70 import TcTyClsDecls
71 import LoadIface
72 import TidyPgm ( mkBootModDetailsTc )
73 import RnNames
74 import RnEnv
75 import RnSource
76 import ErrUtils
77 import Id
78 import IdInfo( IdDetails( VanillaId ) )
79 import VarEnv
80 import Module
81 import UniqFM
82 import Name
83 import NameEnv
84 import NameSet
85 import Avail
86 import TyCon
87 import SrcLoc
88 import HscTypes
89 import ListSetOps
90 import Outputable
91 import ConLike
92 import DataCon
93 import Type
94 import Class
95 import BasicTypes hiding( SuccessFlag(..) )
96 import CoAxiom
97 import Annotations
98 import Data.List ( sortBy )
99 import Data.Ord
100 import FastString
101 import Maybes
102 import Util
103 import Bag
104
105 import Control.Monad
106
107 #include "HsVersions.h"
108
109 {-
110 ************************************************************************
111 * *
112 Typecheck and rename a module
113 * *
114 ************************************************************************
115 -}
116
117 -- | Top level entry point for typechecker and renamer
118 tcRnModule :: HscEnv
119 -> HscSource
120 -> Bool -- True <=> save renamed syntax
121 -> HsParsedModule
122 -> IO (Messages, Maybe TcGblEnv)
123
124 tcRnModule hsc_env hsc_src save_rn_syntax
125 parsedModule@HsParsedModule {hpm_module=L loc this_module}
126 | RealSrcSpan real_loc <- loc
127 = do { showPass (hsc_dflags hsc_env) "Renamer/typechecker" ;
128
129 ; initTc hsc_env hsc_src save_rn_syntax this_mod real_loc $
130 withTcPlugins hsc_env $
131 tcRnModuleTcRnM hsc_env hsc_src parsedModule pair }
132
133 | otherwise
134 = return ((emptyBag, unitBag err_msg), Nothing)
135
136 where
137 err_msg = mkPlainErrMsg (hsc_dflags hsc_env) loc $
138 text "Module does not have a RealSrcSpan:" <+> ppr this_mod
139
140 this_pkg = thisPackage (hsc_dflags hsc_env)
141
142 pair :: (Module, SrcSpan)
143 pair@(this_mod,_)
144 | Just (L mod_loc mod) <- hsmodName this_module
145 = (mkModule this_pkg mod, mod_loc)
146
147 | otherwise -- 'module M where' is omitted
148 = (mAIN, srcLocSpan (srcSpanStart loc))
149
150
151 -- To be called at the beginning of renaming hsig files.
152 -- If we're processing a signature, load up the RdrEnv
153 -- specified by sig-of so that
154 -- when we process top-level bindings, we pull in the right
155 -- original names. We also need to add in dependencies from
156 -- the implementation (orphans, family instances, packages),
157 -- similar to how rnImportDecl handles things.
158 -- ToDo: Handle SafeHaskell
159 tcRnSignature :: DynFlags -> HscSource -> TcRn TcGblEnv
160 tcRnSignature dflags hsc_src
161 = do { tcg_env <- getGblEnv ;
162 case tcg_sig_of tcg_env of {
163 Just sof
164 | hsc_src /= HsBootFile -> do
165 { modname <- fmap moduleName getModule
166 ; addErr (text "Found -sig-of entry for" <+> ppr modname
167 <+> text "which is not hs-boot." $$
168 text "Try removing" <+> ppr modname <+>
169 text "from -sig-of")
170 ; return tcg_env
171 }
172 | otherwise -> do
173 { sig_iface <- initIfaceTcRn $ loadSysInterface (text "sig-of") sof
174 ; let { gr = mkGlobalRdrEnv
175 (gresFromAvails Nothing (mi_exports sig_iface))
176 ; avails = calculateAvails dflags
177 sig_iface False{- safe -} False{- boot -} }
178 ; return (tcg_env
179 { tcg_impl_rdr_env = Just gr
180 , tcg_imports = tcg_imports tcg_env `plusImportAvails` avails
181 })
182 } ;
183 Nothing -> return tcg_env
184 }
185 }
186
187 checkHsigIface :: HscEnv -> TcGblEnv -> TcRn ()
188 checkHsigIface hsc_env tcg_env
189 = case tcg_impl_rdr_env tcg_env of
190 Just gr -> do { sig_details <- liftIO $ mkBootModDetailsTc hsc_env tcg_env
191 ; checkHsigIface' gr sig_details
192 }
193 Nothing -> return ()
194
195 checkHsigIface' :: GlobalRdrEnv -> ModDetails -> TcRn ()
196 checkHsigIface' gr
197 ModDetails { md_insts = sig_insts, md_fam_insts = sig_fam_insts,
198 md_types = sig_type_env, md_exports = sig_exports}
199 = do { traceTc "checkHsigIface" $ vcat
200 [ ppr sig_type_env, ppr sig_insts, ppr sig_exports ]
201 ; mapM_ check_export sig_exports
202 ; unless (null sig_fam_insts) $
203 panic ("TcRnDriver.checkHsigIface: Cannot handle family " ++
204 "instances in hsig files yet...")
205 ; mapM_ check_inst sig_insts
206 ; failIfErrsM
207 }
208 where
209 check_export sig_avail
210 -- Skip instances, we'll check them later
211 | name `elem` dfun_names = return ()
212 | otherwise = do
213 { -- Lookup local environment only (don't want to accidentally pick
214 -- up the backing copy.) We consult tcg_type_env because we want
215 -- to pick up wired in names too (which get dropped by the iface
216 -- creation process); it's OK for a signature file to mention
217 -- a wired in name.
218 env <- getGblEnv
219 ; case lookupNameEnv (tcg_type_env env) name of
220 Nothing
221 -- All this means is no local definition is available: but we
222 -- could have created the export this way:
223 --
224 -- module ASig(f) where
225 -- import B(f)
226 --
227 -- In this case, we have to just lookup the identifier in
228 -- the backing implementation and make sure it matches.
229 | [GRE { gre_name = name' }]
230 <- lookupGlobalRdrEnv gr (nameOccName name)
231 , name == name' -> return ()
232 -- TODO: Possibly give a different error if the identifier
233 -- is exported, but it's a different original name
234 | otherwise -> addErrAt (nameSrcSpan name)
235 (missingBootThing False name "exported by")
236 Just sig_thing -> do {
237 -- We use tcLookupImported_maybe because we want to EXCLUDE
238 -- tcg_env.
239 ; r <- tcLookupImported_maybe name
240 ; case r of
241 Failed err -> addErr err
242 Succeeded real_thing -> checkBootDeclM False sig_thing real_thing
243 }}
244 where
245 name = availName sig_avail
246
247 dfun_names = map getName sig_insts
248
249 -- In general, for hsig files we can't assume that the implementing
250 -- file actually implemented the instances (they may be reexported
251 -- from elsewhere). Where should we look for the instances? We do
252 -- the same as we would otherwise: consult the EPS. This isn't
253 -- perfect (we might conclude the module exports an instance
254 -- when it doesn't, see #9422), but we will never refuse to compile
255 -- something
256 check_inst :: ClsInst -> TcM ()
257 check_inst sig_inst
258 = do eps <- getEps
259 when (not (memberInstEnv (eps_inst_env eps) sig_inst)) $
260 addErrTc (instMisMatch False sig_inst)
261
262 tcRnModuleTcRnM :: HscEnv
263 -> HscSource
264 -> HsParsedModule
265 -> (Module, SrcSpan)
266 -> TcRn TcGblEnv
267 -- Factored out separately from tcRnModule so that a Core plugin can
268 -- call the type checker directly
269 tcRnModuleTcRnM hsc_env hsc_src
270 (HsParsedModule {
271 hpm_module =
272 (L loc (HsModule maybe_mod export_ies
273 import_decls local_decls mod_deprec
274 maybe_doc_hdr)),
275 hpm_src_files = src_files
276 })
277 (this_mod, prel_imp_loc)
278 = setSrcSpan loc $
279 do { let { dflags = hsc_dflags hsc_env
280 ; explicit_mod_hdr = isJust maybe_mod } ;
281
282 tcg_env <- tcRnSignature dflags hsc_src ;
283 setGblEnv tcg_env $ do {
284
285 -- Load the hi-boot interface for this module, if any
286 -- We do this now so that the boot_names can be passed
287 -- to tcTyAndClassDecls, because the boot_names are
288 -- automatically considered to be loop breakers
289 --
290 -- Do this *after* tcRnImports, so that we know whether
291 -- a module that we import imports us; and hence whether to
292 -- look for a hi-boot file
293 boot_info <- tcHiBootIface hsc_src this_mod ;
294 setGblEnv (tcg_env { tcg_self_boot = boot_info }) $ do {
295
296 -- Deal with imports; first add implicit prelude
297 implicit_prelude <- xoptM Opt_ImplicitPrelude;
298 let { prel_imports = mkPrelImports (moduleName this_mod) prel_imp_loc
299 implicit_prelude import_decls } ;
300
301 whenWOptM Opt_WarnImplicitPrelude $
302 when (notNull prel_imports) $ addWarn (implicitPreludeWarn) ;
303
304 tcg_env <- {-# SCC "tcRnImports" #-}
305 tcRnImports hsc_env (prel_imports ++ import_decls) ;
306
307 -- If the whole module is warned about or deprecated
308 -- (via mod_deprec) record that in tcg_warns. If we do thereby add
309 -- a WarnAll, it will override any subseqent depracations added to tcg_warns
310 let { tcg_env1 = case mod_deprec of
311 Just (L _ txt) -> tcg_env { tcg_warns = WarnAll txt }
312 Nothing -> tcg_env
313 } ;
314
315 setGblEnv tcg_env1 $ do {
316
317 -- Rename and type check the declarations
318 traceRn (text "rn1a") ;
319 tcg_env <- if isHsBoot hsc_src then
320 tcRnHsBootDecls hsc_src local_decls
321 else
322 {-# SCC "tcRnSrcDecls" #-}
323 tcRnSrcDecls explicit_mod_hdr export_ies local_decls ;
324 setGblEnv tcg_env $ do {
325
326 -- Process the export list
327 traceRn (text "rn4a: before exports");
328 tcg_env <- rnExports explicit_mod_hdr export_ies tcg_env ;
329 traceRn (text "rn4b: after exports") ;
330
331 -- Check that main is exported (must be after rnExports)
332 checkMainExported tcg_env ;
333
334 -- Compare the hi-boot iface (if any) with the real thing
335 -- Must be done after processing the exports
336 tcg_env <- checkHiBootIface tcg_env boot_info ;
337
338 -- Compare the hsig tcg_env with the real thing
339 checkHsigIface hsc_env tcg_env ;
340
341 -- Nub out type class instances now that we've checked them,
342 -- if we're compiling an hsig with sig-of.
343 -- See Note [Signature files and type class instances]
344 tcg_env <- (case tcg_sig_of tcg_env of
345 Just _ -> return tcg_env {
346 tcg_inst_env = emptyInstEnv,
347 tcg_fam_inst_env = emptyFamInstEnv,
348 tcg_insts = [],
349 tcg_fam_insts = []
350 }
351 Nothing -> return tcg_env) ;
352
353 -- The new type env is already available to stuff slurped from
354 -- interface files, via TcEnv.updateGlobalTypeEnv
355 -- It's important that this includes the stuff in checkHiBootIface,
356 -- because the latter might add new bindings for boot_dfuns,
357 -- which may be mentioned in imported unfoldings
358
359 -- Don't need to rename the Haddock documentation,
360 -- it's not parsed by GHC anymore.
361 tcg_env <- return (tcg_env { tcg_doc_hdr = maybe_doc_hdr }) ;
362
363 -- Report unused names
364 reportUnusedNames export_ies tcg_env ;
365
366 -- add extra source files to tcg_dependent_files
367 addDependentFiles src_files ;
368
369 -- Dump output and return
370 tcDump tcg_env ;
371 return tcg_env
372 }}}}}
373
374 implicitPreludeWarn :: SDoc
375 implicitPreludeWarn
376 = ptext (sLit "Module `Prelude' implicitly imported")
377
378 {-
379 ************************************************************************
380 * *
381 Import declarations
382 * *
383 ************************************************************************
384 -}
385
386 tcRnImports :: HscEnv -> [LImportDecl RdrName] -> TcM TcGblEnv
387 tcRnImports hsc_env import_decls
388 = do { (rn_imports, rdr_env, imports, hpc_info) <- rnImports import_decls ;
389
390 ; this_mod <- getModule
391 ; let { dep_mods :: ModuleNameEnv (ModuleName, IsBootInterface)
392 ; dep_mods = imp_dep_mods imports
393
394 -- We want instance declarations from all home-package
395 -- modules below this one, including boot modules, except
396 -- ourselves. The 'except ourselves' is so that we don't
397 -- get the instances from this module's hs-boot file. This
398 -- filtering also ensures that we don't see instances from
399 -- modules batch (@--make@) compiled before this one, but
400 -- which are not below this one.
401 ; want_instances :: ModuleName -> Bool
402 ; want_instances mod = mod `elemUFM` dep_mods
403 && mod /= moduleName this_mod
404 ; (home_insts, home_fam_insts) = hptInstances hsc_env
405 want_instances
406 } ;
407
408 -- Record boot-file info in the EPS, so that it's
409 -- visible to loadHiBootInterface in tcRnSrcDecls,
410 -- and any other incrementally-performed imports
411 ; updateEps_ (\eps -> eps { eps_is_boot = dep_mods }) ;
412
413 -- Update the gbl env
414 ; updGblEnv ( \ gbl ->
415 gbl {
416 tcg_rdr_env = tcg_rdr_env gbl `plusGlobalRdrEnv` rdr_env,
417 tcg_imports = tcg_imports gbl `plusImportAvails` imports,
418 tcg_rn_imports = rn_imports,
419 tcg_inst_env = extendInstEnvList (tcg_inst_env gbl) home_insts,
420 tcg_fam_inst_env = extendFamInstEnvList (tcg_fam_inst_env gbl)
421 home_fam_insts,
422 tcg_hpc = hpc_info
423 }) $ do {
424
425 ; traceRn (text "rn1" <+> ppr (imp_dep_mods imports))
426 -- Fail if there are any errors so far
427 -- The error printing (if needed) takes advantage
428 -- of the tcg_env we have now set
429 -- ; traceIf (text "rdr_env: " <+> ppr rdr_env)
430 ; failIfErrsM
431
432 -- Load any orphan-module and family instance-module
433 -- interfaces, so that their rules and instance decls will be
434 -- found. But filter out a self hs-boot: these instances
435 -- will be checked when we define them locally.
436 ; loadModuleInterfaces (ptext (sLit "Loading orphan modules"))
437 (filter (/= this_mod) (imp_orphs imports))
438
439 -- Check type-family consistency
440 ; traceRn (text "rn1: checking family instance consistency")
441 ; let { dir_imp_mods = moduleEnvKeys
442 . imp_mods
443 $ imports }
444 ; checkFamInstConsistency (imp_finsts imports) dir_imp_mods ;
445
446 ; getGblEnv } }
447
448 {-
449 ************************************************************************
450 * *
451 Type-checking the top level of a module
452 * *
453 ************************************************************************
454 -}
455
456 tcRnSrcDecls :: Bool -- False => no 'module M(..) where' header at all
457 -> Maybe (Located [LIE RdrName]) -- Exports
458 -> [LHsDecl RdrName] -- Declarations
459 -> TcM TcGblEnv
460 -- Returns the variables free in the decls
461 -- Reason: solely to report unused imports and bindings
462 tcRnSrcDecls explicit_mod_hdr exports decls
463 = do { -- Do all the declarations
464 ((tcg_env, tcl_env), lie) <- captureConstraints $
465 do { (tcg_env, tcl_env) <- tc_rn_src_decls decls ;
466 ; tcg_env <- setEnvs (tcg_env, tcl_env) $
467 checkMain explicit_mod_hdr
468 ; return (tcg_env, tcl_env) }
469 ; setEnvs (tcg_env, tcl_env) $ do {
470
471 #ifdef GHCI
472 -- Run all module finalizers
473 let th_modfinalizers_var = tcg_th_modfinalizers tcg_env
474 ; modfinalizers <- readTcRef th_modfinalizers_var
475 ; writeTcRef th_modfinalizers_var []
476 ; mapM_ runQuasi modfinalizers
477 #endif /* GHCI */
478
479 -- wanted constraints from static forms
480 ; stWC <- tcg_static_wc <$> getGblEnv >>= readTcRef
481
482 -- Finish simplifying class constraints
483 --
484 -- simplifyTop deals with constant or ambiguous InstIds.
485 -- How could there be ambiguous ones? They can only arise if a
486 -- top-level decl falls under the monomorphism restriction
487 -- and no subsequent decl instantiates its type.
488 --
489 -- We do this after checkMain, so that we use the type info
490 -- that checkMain adds
491 --
492 -- We do it with both global and local env in scope:
493 -- * the global env exposes the instances to simplifyTop
494 -- * the local env exposes the local Ids to simplifyTop,
495 -- so that we get better error messages (monomorphism restriction)
496 ; new_ev_binds <- {-# SCC "simplifyTop" #-}
497 simplifyTop (andWC stWC lie)
498 ; traceTc "Tc9" empty
499
500 ; failIfErrsM -- Don't zonk if there have been errors
501 -- It's a waste of time; and we may get debug warnings
502 -- about strangely-typed TyCons!
503
504 -- Zonk the final code. This must be done last.
505 -- Even simplifyTop may do some unification.
506 -- This pass also warns about missing type signatures
507 ; let { TcGblEnv { tcg_type_env = type_env,
508 tcg_binds = binds,
509 tcg_sigs = sig_ns,
510 tcg_ev_binds = cur_ev_binds,
511 tcg_imp_specs = imp_specs,
512 tcg_rules = rules,
513 tcg_vects = vects,
514 tcg_fords = fords } = tcg_env
515 ; all_ev_binds = cur_ev_binds `unionBags` new_ev_binds } ;
516
517 ; (bind_ids, ev_binds', binds', fords', imp_specs', rules', vects')
518 <- {-# SCC "zonkTopDecls" #-}
519 zonkTopDecls all_ev_binds binds exports sig_ns rules vects
520 imp_specs fords ;
521
522 ; let { final_type_env = extendTypeEnvWithIds type_env bind_ids
523 ; tcg_env' = tcg_env { tcg_binds = binds',
524 tcg_ev_binds = ev_binds',
525 tcg_imp_specs = imp_specs',
526 tcg_rules = rules',
527 tcg_vects = vects',
528 tcg_fords = fords' } } ;
529
530 ; setGlobalTypeEnv tcg_env' final_type_env
531
532 } }
533
534 tc_rn_src_decls :: [LHsDecl RdrName]
535 -> TcM (TcGblEnv, TcLclEnv)
536 -- Loops around dealing with each top level inter-splice group
537 -- in turn, until it's dealt with the entire module
538 tc_rn_src_decls ds
539 = {-# SCC "tc_rn_src_decls" #-}
540 do { (first_group, group_tail) <- findSplice ds
541 -- If ds is [] we get ([], Nothing)
542
543 -- Deal with decls up to, but not including, the first splice
544 ; (tcg_env, rn_decls) <- rnTopSrcDecls first_group
545 -- rnTopSrcDecls fails if there are any errors
546
547 #ifdef GHCI
548 -- Get TH-generated top-level declarations and make sure they don't
549 -- contain any splices since we don't handle that at the moment
550 ; th_topdecls_var <- fmap tcg_th_topdecls getGblEnv
551 ; th_ds <- readTcRef th_topdecls_var
552 ; writeTcRef th_topdecls_var []
553
554 ; (tcg_env, rn_decls) <-
555 if null th_ds
556 then return (tcg_env, rn_decls)
557 else do { (th_group, th_group_tail) <- findSplice th_ds
558 ; case th_group_tail of
559 { Nothing -> return () ;
560 ; Just (SpliceDecl (L loc _) _, _)
561 -> setSrcSpan loc $
562 addErr (ptext (sLit "Declaration splices are not permitted inside top-level declarations added with addTopDecls"))
563 } ;
564
565 -- Rename TH-generated top-level declarations
566 ; (tcg_env, th_rn_decls) <- setGblEnv tcg_env $
567 rnTopSrcDecls th_group
568
569 -- Dump generated top-level declarations
570 ; let msg = "top-level declarations added with addTopDecls"
571 ; traceSplice $ SpliceInfo { spliceDescription = msg
572 , spliceIsDecl = True
573 , spliceSource = Nothing
574 , spliceGenerated = ppr th_rn_decls }
575
576 ; return (tcg_env, appendGroups rn_decls th_rn_decls)
577 }
578 #endif /* GHCI */
579
580 -- Type check all declarations
581 ; (tcg_env, tcl_env) <- setGblEnv tcg_env $
582 tcTopSrcDecls rn_decls
583
584 -- If there is no splice, we're nearly done
585 ; setEnvs (tcg_env, tcl_env) $
586 case group_tail of
587 { Nothing -> return (tcg_env, tcl_env)
588
589 #ifndef GHCI
590 -- There shouldn't be a splice
591 ; Just (SpliceDecl {}, _) ->
592 failWithTc (text "Can't do a top-level splice; need a bootstrapped compiler")
593 }
594 #else
595 -- If there's a splice, we must carry on
596 ; Just (SpliceDecl (L _ splice) _, rest_ds) ->
597 do { -- Rename the splice expression, and get its supporting decls
598 (spliced_decls, splice_fvs) <- checkNoErrs (rnTopSpliceDecls splice)
599
600 -- Glue them on the front of the remaining decls and loop
601 ; setGblEnv (tcg_env `addTcgDUs` usesOnly splice_fvs) $
602 tc_rn_src_decls (spliced_decls ++ rest_ds)
603 }
604 }
605 #endif /* GHCI */
606 }
607
608 {-
609 ************************************************************************
610 * *
611 Compiling hs-boot source files, and
612 comparing the hi-boot interface with the real thing
613 * *
614 ************************************************************************
615 -}
616
617 tcRnHsBootDecls :: HscSource -> [LHsDecl RdrName] -> TcM TcGblEnv
618 tcRnHsBootDecls hsc_src decls
619 = do { (first_group, group_tail) <- findSplice decls
620
621 -- Rename the declarations
622 ; (tcg_env, HsGroup {
623 hs_tyclds = tycl_decls,
624 hs_instds = inst_decls,
625 hs_derivds = deriv_decls,
626 hs_fords = for_decls,
627 hs_defds = def_decls,
628 hs_ruleds = rule_decls,
629 hs_vects = vect_decls,
630 hs_annds = _,
631 hs_valds = val_binds }) <- rnTopSrcDecls first_group
632 -- The empty list is for extra dependencies coming from .hs-boot files
633 -- See Note [Extra dependencies from .hs-boot files] in RnSource
634 ; (gbl_env, lie) <- captureConstraints $ setGblEnv tcg_env $ do {
635
636
637 -- Check for illegal declarations
638 ; case group_tail of
639 Just (SpliceDecl d _, _) -> badBootDecl hsc_src "splice" d
640 Nothing -> return ()
641 ; mapM_ (badBootDecl hsc_src "foreign") for_decls
642 ; mapM_ (badBootDecl hsc_src "default") def_decls
643 ; mapM_ (badBootDecl hsc_src "rule") rule_decls
644 ; mapM_ (badBootDecl hsc_src "vect") vect_decls
645
646 -- Typecheck type/class/isntance decls
647 ; traceTc "Tc2 (boot)" empty
648 ; (tcg_env, inst_infos, _deriv_binds)
649 <- tcTyClsInstDecls tycl_decls inst_decls deriv_decls
650 ; setGblEnv tcg_env $ do {
651
652 -- Typecheck value declarations
653 ; traceTc "Tc5" empty
654 ; val_ids <- tcHsBootSigs val_binds
655
656 -- Wrap up
657 -- No simplification or zonking to do
658 ; traceTc "Tc7a" empty
659 ; gbl_env <- getGblEnv
660
661 -- Make the final type-env
662 -- Include the dfun_ids so that their type sigs
663 -- are written into the interface file.
664 ; let { type_env0 = tcg_type_env gbl_env
665 ; type_env1 = extendTypeEnvWithIds type_env0 val_ids
666 -- Don't add the dictionaries for non-recursive case, we don't
667 -- actually want to /define/ the instance, just an export list
668 ; type_env2 | Just _ <- tcg_impl_rdr_env gbl_env = type_env1
669 | otherwise = extendTypeEnvWithIds type_env1 dfun_ids
670 ; dfun_ids = map iDFunId inst_infos
671 }
672
673 ; setGlobalTypeEnv gbl_env type_env2
674 }}
675 ; traceTc "boot" (ppr lie); return gbl_env }
676
677 badBootDecl :: HscSource -> String -> Located decl -> TcM ()
678 badBootDecl _hsc_src what (L loc _)
679 = addErrAt loc (char 'A' <+> text what
680 <+> text "declaration is not (currently) allowed in a hs-boot file")
681
682 {-
683 Once we've typechecked the body of the module, we want to compare what
684 we've found (gathered in a TypeEnv) with the hi-boot details (if any).
685 -}
686
687 checkHiBootIface :: TcGblEnv -> SelfBootInfo -> TcM TcGblEnv
688 -- Compare the hi-boot file for this module (if there is one)
689 -- with the type environment we've just come up with
690 -- In the common case where there is no hi-boot file, the list
691 -- of boot_names is empty.
692
693 checkHiBootIface tcg_env boot_info
694 | NoSelfBoot <- boot_info -- Common case
695 = return tcg_env
696
697 | HsBootFile <- tcg_src tcg_env -- Current module is already a hs-boot file!
698 = return tcg_env
699
700 | SelfBoot { sb_mds = boot_details } <- boot_info
701 , TcGblEnv { tcg_binds = binds
702 , tcg_insts = local_insts
703 , tcg_type_env = local_type_env
704 , tcg_exports = local_exports } <- tcg_env
705 = do { dfun_prs <- checkHiBootIface' local_insts local_type_env
706 local_exports boot_details
707 ; let boot_dfuns = map fst dfun_prs
708 dfun_binds = listToBag [ mkVarBind boot_dfun (nlHsVar dfun)
709 | (boot_dfun, dfun) <- dfun_prs ]
710 type_env' = extendTypeEnvWithIds local_type_env boot_dfuns
711 tcg_env' = tcg_env { tcg_binds = binds `unionBags` dfun_binds }
712
713 ; setGlobalTypeEnv tcg_env' type_env' }
714 -- Update the global type env *including* the knot-tied one
715 -- so that if the source module reads in an interface unfolding
716 -- mentioning one of the dfuns from the boot module, then it
717 -- can "see" that boot dfun. See Trac #4003
718
719 | otherwise = panic "checkHiBootIface: unreachable code"
720
721 checkHiBootIface' :: [ClsInst] -> TypeEnv -> [AvailInfo]
722 -> ModDetails -> TcM [(Id, Id)]
723 -- Variant which doesn't require a full TcGblEnv; you could get the
724 -- local components from another ModDetails.
725 --
726 -- We return a list of "impedance-matching" bindings for the dfuns
727 -- defined in the hs-boot file, such as
728 -- $fxEqT = $fEqT
729 -- We need these because the module and hi-boot file might differ in
730 -- the name it chose for the dfun.
731
732 checkHiBootIface'
733 local_insts local_type_env local_exports
734 (ModDetails { md_insts = boot_insts, md_fam_insts = boot_fam_insts,
735 md_types = boot_type_env, md_exports = boot_exports })
736 = do { traceTc "checkHiBootIface" $ vcat
737 [ ppr boot_type_env, ppr boot_insts, ppr boot_exports]
738
739 -- Check the exports of the boot module, one by one
740 ; mapM_ check_export boot_exports
741
742 -- Check for no family instances
743 ; unless (null boot_fam_insts) $
744 panic ("TcRnDriver.checkHiBootIface: Cannot handle family " ++
745 "instances in boot files yet...")
746 -- FIXME: Why? The actual comparison is not hard, but what would
747 -- be the equivalent to the dfun bindings returned for class
748 -- instances? We can't easily equate tycons...
749
750 -- Check instance declarations
751 -- and generate an impedance-matching binding
752 ; mb_dfun_prs <- mapM check_inst boot_insts
753
754 ; failIfErrsM
755
756 ; return (catMaybes mb_dfun_prs) }
757
758 where
759 check_export boot_avail -- boot_avail is exported by the boot iface
760 | name `elem` dfun_names = return ()
761 | isWiredInName name = return () -- No checking for wired-in names. In particular,
762 -- 'error' is handled by a rather gross hack
763 -- (see comments in GHC.Err.hs-boot)
764
765 -- Check that the actual module exports the same thing
766 | not (null missing_names)
767 = addErrAt (nameSrcSpan (head missing_names))
768 (missingBootThing True (head missing_names) "exported by")
769
770 -- If the boot module does not *define* the thing, we are done
771 -- (it simply re-exports it, and names match, so nothing further to do)
772 | isNothing mb_boot_thing = return ()
773
774 -- Check that the actual module also defines the thing, and
775 -- then compare the definitions
776 | Just real_thing <- lookupTypeEnv local_type_env name,
777 Just boot_thing <- mb_boot_thing
778 = checkBootDeclM True boot_thing real_thing
779
780 | otherwise
781 = addErrTc (missingBootThing True name "defined in")
782 where
783 name = availName boot_avail
784 mb_boot_thing = lookupTypeEnv boot_type_env name
785 missing_names = case lookupNameEnv local_export_env name of
786 Nothing -> [name]
787 Just avail -> availNames boot_avail `minusList` availNames avail
788
789 dfun_names = map getName boot_insts
790
791 local_export_env :: NameEnv AvailInfo
792 local_export_env = availsToNameEnv local_exports
793
794 check_inst :: ClsInst -> TcM (Maybe (Id, Id))
795 -- Returns a pair of the boot dfun in terms of the equivalent real dfun
796 check_inst boot_inst
797 = case [dfun | inst <- local_insts,
798 let dfun = instanceDFunId inst,
799 idType dfun `eqType` boot_dfun_ty ] of
800 [] -> do { traceTc "check_inst" $ vcat
801 [ text "local_insts" <+> vcat (map (ppr . idType . instanceDFunId) local_insts)
802 , text "boot_inst" <+> ppr boot_inst
803 , text "boot_dfun_ty" <+> ppr boot_dfun_ty
804 ]
805 ; addErrTc (instMisMatch True boot_inst); return Nothing }
806 (dfun:_) -> return (Just (local_boot_dfun, dfun))
807 where
808 local_boot_dfun = Id.mkExportedLocalId VanillaId boot_dfun_name (idType dfun)
809 -- Name from the /boot-file/ ClsInst, but type from the dfun
810 -- defined in /this module/. That ensures that the TyCon etc
811 -- inside the type are the ones defined in this module, not
812 -- the ones gotten from the hi-boot file, which may have
813 -- a lot less info (Trac #T8743, comment:10).
814 where
815 boot_dfun = instanceDFunId boot_inst
816 boot_dfun_ty = idType boot_dfun
817 boot_dfun_name = idName boot_dfun
818
819 -- This has to compare the TyThing from the .hi-boot file to the TyThing
820 -- in the current source file. We must be careful to allow alpha-renaming
821 -- where appropriate, and also the boot declaration is allowed to omit
822 -- constructors and class methods.
823 --
824 -- See rnfail055 for a good test of this stuff.
825
826 -- | Compares two things for equivalence between boot-file and normal code,
827 -- reporting an error if they don't match up.
828 checkBootDeclM :: Bool -- ^ True <=> an hs-boot file (could also be a sig)
829 -> TyThing -> TyThing -> TcM ()
830 checkBootDeclM is_boot boot_thing real_thing
831 = whenIsJust (checkBootDecl boot_thing real_thing) $ \ err ->
832 addErrAt (nameSrcSpan (getName boot_thing))
833 (bootMisMatch is_boot err real_thing boot_thing)
834
835 -- | Compares the two things for equivalence between boot-file and normal
836 -- code. Returns @Nothing@ on success or @Just "some helpful info for user"@
837 -- failure. If the difference will be apparent to the user, @Just empty@ is
838 -- perfectly suitable.
839 checkBootDecl :: TyThing -> TyThing -> Maybe SDoc
840
841 checkBootDecl (AnId id1) (AnId id2)
842 = ASSERT(id1 == id2)
843 check (idType id1 `eqType` idType id2)
844 (text "The two types are different")
845
846 checkBootDecl (ATyCon tc1) (ATyCon tc2)
847 = checkBootTyCon tc1 tc2
848
849 checkBootDecl (AConLike (RealDataCon dc1)) (AConLike (RealDataCon _))
850 = pprPanic "checkBootDecl" (ppr dc1)
851
852 checkBootDecl _ _ = Just empty -- probably shouldn't happen
853
854 -- | Combines two potential error messages
855 andThenCheck :: Maybe SDoc -> Maybe SDoc -> Maybe SDoc
856 Nothing `andThenCheck` msg = msg
857 msg `andThenCheck` Nothing = msg
858 Just d1 `andThenCheck` Just d2 = Just (d1 $$ d2)
859 infixr 0 `andThenCheck`
860
861 -- | If the test in the first parameter is True, succeed with @Nothing@;
862 -- otherwise, return the provided check
863 checkUnless :: Bool -> Maybe SDoc -> Maybe SDoc
864 checkUnless True _ = Nothing
865 checkUnless False k = k
866
867 -- | Run the check provided for every pair of elements in the lists.
868 -- The provided SDoc should name the element type, in the plural.
869 checkListBy :: (a -> a -> Maybe SDoc) -> [a] -> [a] -> SDoc
870 -> Maybe SDoc
871 checkListBy check_fun as bs whats = go [] as bs
872 where
873 herald = text "The" <+> whats <+> text "do not match"
874
875 go [] [] [] = Nothing
876 go docs [] [] = Just (hang (herald <> colon) 2 (vcat $ reverse docs))
877 go docs (x:xs) (y:ys) = case check_fun x y of
878 Just doc -> go (doc:docs) xs ys
879 Nothing -> go docs xs ys
880 go _ _ _ = Just (hang (herald <> colon)
881 2 (text "There are different numbers of" <+> whats))
882
883 -- | If the test in the first parameter is True, succeed with @Nothing@;
884 -- otherwise, fail with the given SDoc.
885 check :: Bool -> SDoc -> Maybe SDoc
886 check True _ = Nothing
887 check False doc = Just doc
888
889 -- | A more perspicuous name for @Nothing@, for @checkBootDecl@ and friends.
890 checkSuccess :: Maybe SDoc
891 checkSuccess = Nothing
892
893 ----------------
894 checkBootTyCon :: TyCon -> TyCon -> Maybe SDoc
895 checkBootTyCon tc1 tc2
896 | not (eqKind (tyConKind tc1) (tyConKind tc2))
897 = Just $ text "The types have different kinds" -- First off, check the kind
898
899 | Just c1 <- tyConClass_maybe tc1
900 , Just c2 <- tyConClass_maybe tc2
901 , let (clas_tvs1, clas_fds1, sc_theta1, _, ats1, op_stuff1)
902 = classExtraBigSig c1
903 (clas_tvs2, clas_fds2, sc_theta2, _, ats2, op_stuff2)
904 = classExtraBigSig c2
905 , Just env <- eqTyVarBndrs emptyRnEnv2 clas_tvs1 clas_tvs2
906 = let
907 eqSig (id1, def_meth1) (id2, def_meth2)
908 = check (name1 == name2)
909 (text "The names" <+> pname1 <+> text "and" <+> pname2 <+>
910 text "are different") `andThenCheck`
911 check (eqTypeX env op_ty1 op_ty2)
912 (text "The types of" <+> pname1 <+>
913 text "are different") `andThenCheck`
914 check (def_meth1 == def_meth2)
915 (text "The default methods associated with" <+> pname1 <+>
916 text "are different")
917 where
918 name1 = idName id1
919 name2 = idName id2
920 pname1 = quotes (ppr name1)
921 pname2 = quotes (ppr name2)
922 (_, rho_ty1) = splitForAllTys (idType id1)
923 op_ty1 = funResultTy rho_ty1
924 (_, rho_ty2) = splitForAllTys (idType id2)
925 op_ty2 = funResultTy rho_ty2
926
927 eqAT (ATI tc1 def_ats1) (ATI tc2 def_ats2)
928 = checkBootTyCon tc1 tc2 `andThenCheck`
929 check (eqATDef def_ats1 def_ats2)
930 (text "The associated type defaults differ")
931
932 -- Ignore the location of the defaults
933 eqATDef Nothing Nothing = True
934 eqATDef (Just (ty1, _loc1)) (Just (ty2, _loc2)) = eqTypeX env ty1 ty2
935 eqATDef _ _ = False
936
937 eqFD (as1,bs1) (as2,bs2) =
938 eqListBy (eqTypeX env) (mkTyVarTys as1) (mkTyVarTys as2) &&
939 eqListBy (eqTypeX env) (mkTyVarTys bs1) (mkTyVarTys bs2)
940 in
941 check (roles1 == roles2) roles_msg `andThenCheck`
942 -- Checks kind of class
943 check (eqListBy eqFD clas_fds1 clas_fds2)
944 (text "The functional dependencies do not match") `andThenCheck`
945 checkUnless (null sc_theta1 && null op_stuff1 && null ats1) $
946 -- Above tests for an "abstract" class
947 check (eqListBy (eqPredX env) sc_theta1 sc_theta2)
948 (text "The class constraints do not match") `andThenCheck`
949 checkListBy eqSig op_stuff1 op_stuff2 (text "methods") `andThenCheck`
950 checkListBy eqAT ats1 ats2 (text "associated types")
951
952 | Just syn_rhs1 <- synTyConRhs_maybe tc1
953 , Just syn_rhs2 <- synTyConRhs_maybe tc2
954 , Just env <- eqTyVarBndrs emptyRnEnv2 (tyConTyVars tc1) (tyConTyVars tc2)
955 = ASSERT(tc1 == tc2)
956 check (roles1 == roles2) roles_msg `andThenCheck`
957 check (eqTypeX env syn_rhs1 syn_rhs2) empty -- nothing interesting to say
958
959 | Just fam_flav1 <- famTyConFlav_maybe tc1
960 , Just fam_flav2 <- famTyConFlav_maybe tc2
961 = ASSERT(tc1 == tc2)
962 let eqFamFlav OpenSynFamilyTyCon OpenSynFamilyTyCon = True
963 eqFamFlav AbstractClosedSynFamilyTyCon (ClosedSynFamilyTyCon {}) = True
964 eqFamFlav (ClosedSynFamilyTyCon {}) AbstractClosedSynFamilyTyCon = True
965 eqFamFlav (ClosedSynFamilyTyCon ax1) (ClosedSynFamilyTyCon ax2)
966 = eqClosedFamilyAx ax1 ax2
967 eqFamFlav (BuiltInSynFamTyCon _) (BuiltInSynFamTyCon _) = tc1 == tc2
968 eqFamFlav _ _ = False
969 injInfo1 = familyTyConInjectivityInfo tc1
970 injInfo2 = familyTyConInjectivityInfo tc2
971 in
972 -- check equality of roles, family flavours and injectivity annotations
973 check (roles1 == roles2) roles_msg `andThenCheck`
974 check (eqFamFlav fam_flav1 fam_flav2) empty `andThenCheck`
975 check (injInfo1 == injInfo2) empty
976
977 | isAlgTyCon tc1 && isAlgTyCon tc2
978 , Just env <- eqTyVarBndrs emptyRnEnv2 (tyConTyVars tc1) (tyConTyVars tc2)
979 = ASSERT(tc1 == tc2)
980 check (roles1 == roles2) roles_msg `andThenCheck`
981 check (eqListBy (eqPredX env)
982 (tyConStupidTheta tc1) (tyConStupidTheta tc2))
983 (text "The datatype contexts do not match") `andThenCheck`
984 eqAlgRhs tc1 (algTyConRhs tc1) (algTyConRhs tc2)
985
986 | otherwise = Just empty -- two very different types -- should be obvious
987 where
988 roles1 = tyConRoles tc1
989 roles2 = tyConRoles tc2
990 roles_msg = text "The roles do not match." $$
991 (text "Roles on abstract types default to" <+>
992 quotes (text "representational") <+> text "in boot files.")
993
994 eqAlgRhs tc (AbstractTyCon dis1) rhs2
995 | dis1 = check (isGenInjAlgRhs rhs2) --Check compatibility
996 (text "The natures of the declarations for" <+>
997 quotes (ppr tc) <+> text "are different")
998 | otherwise = checkSuccess
999 eqAlgRhs _ DataFamilyTyCon{} DataFamilyTyCon{} = checkSuccess
1000 eqAlgRhs _ tc1@DataTyCon{} tc2@DataTyCon{} =
1001 checkListBy eqCon (data_cons tc1) (data_cons tc2) (text "constructors")
1002 eqAlgRhs _ tc1@NewTyCon{} tc2@NewTyCon{} =
1003 eqCon (data_con tc1) (data_con tc2)
1004 eqAlgRhs _ _ _ = Just (text "Cannot match a" <+> quotes (text "data") <+>
1005 text "definition with a" <+> quotes (text "newtype") <+>
1006 text "definition")
1007
1008 eqCon c1 c2
1009 = check (name1 == name2)
1010 (text "The names" <+> pname1 <+> text "and" <+> pname2 <+>
1011 text "differ") `andThenCheck`
1012 check (dataConIsInfix c1 == dataConIsInfix c2)
1013 (text "The fixities of" <+> pname1 <+>
1014 text "differ") `andThenCheck`
1015 check (eqListBy eqHsBang (dataConImplBangs c1) (dataConImplBangs c2))
1016 (text "The strictness annotations for" <+> pname1 <+>
1017 text "differ") `andThenCheck`
1018 check (dataConFieldLabels c1 == dataConFieldLabels c2)
1019 (text "The record label lists for" <+> pname1 <+>
1020 text "differ") `andThenCheck`
1021 check (eqType (dataConUserType c1) (dataConUserType c2))
1022 (text "The types for" <+> pname1 <+> text "differ")
1023 where
1024 name1 = dataConName c1
1025 name2 = dataConName c2
1026 pname1 = quotes (ppr name1)
1027 pname2 = quotes (ppr name2)
1028
1029 eqClosedFamilyAx Nothing Nothing = True
1030 eqClosedFamilyAx Nothing (Just _) = False
1031 eqClosedFamilyAx (Just _) Nothing = False
1032 eqClosedFamilyAx (Just (CoAxiom { co_ax_branches = branches1 }))
1033 (Just (CoAxiom { co_ax_branches = branches2 }))
1034 = numBranches branches1 == numBranches branches2
1035 && (and $ zipWith eqClosedFamilyBranch branch_list1 branch_list2)
1036 where
1037 branch_list1 = fromBranches branches1
1038 branch_list2 = fromBranches branches2
1039
1040 eqClosedFamilyBranch (CoAxBranch { cab_tvs = tvs1, cab_lhs = lhs1, cab_rhs = rhs1 })
1041 (CoAxBranch { cab_tvs = tvs2, cab_lhs = lhs2, cab_rhs = rhs2 })
1042 | Just env <- eqTyVarBndrs emptyRnEnv2 tvs1 tvs2
1043 = eqListBy (eqTypeX env) lhs1 lhs2 &&
1044 eqTypeX env rhs1 rhs2
1045
1046 | otherwise = False
1047
1048 emptyRnEnv2 :: RnEnv2
1049 emptyRnEnv2 = mkRnEnv2 emptyInScopeSet
1050
1051 ----------------
1052 missingBootThing :: Bool -> Name -> String -> SDoc
1053 missingBootThing is_boot name what
1054 = quotes (ppr name) <+> ptext (sLit "is exported by the")
1055 <+> (if is_boot then ptext (sLit "hs-boot") else ptext (sLit "signature"))
1056 <+> ptext (sLit "file, but not")
1057 <+> text what <+> ptext (sLit "the module")
1058
1059 bootMisMatch :: Bool -> SDoc -> TyThing -> TyThing -> SDoc
1060 bootMisMatch is_boot extra_info real_thing boot_thing
1061 = vcat [ppr real_thing <+>
1062 ptext (sLit "has conflicting definitions in the module"),
1063 ptext (sLit "and its") <+>
1064 (if is_boot then ptext (sLit "hs-boot file")
1065 else ptext (sLit "signature file")),
1066 ptext (sLit "Main module:") <+> PprTyThing.pprTyThing real_thing,
1067 (if is_boot
1068 then ptext (sLit "Boot file: ")
1069 else ptext (sLit "Signature file: "))
1070 <+> PprTyThing.pprTyThing boot_thing,
1071 extra_info]
1072
1073 instMisMatch :: Bool -> ClsInst -> SDoc
1074 instMisMatch is_boot inst
1075 = hang (ppr inst)
1076 2 (ptext (sLit "is defined in the") <+>
1077 (if is_boot then ptext (sLit "hs-boot") else ptext (sLit "signature"))
1078 <+> ptext (sLit "file, but not in the module itself"))
1079
1080 {-
1081 ************************************************************************
1082 * *
1083 Type-checking the top level of a module (continued)
1084 * *
1085 ************************************************************************
1086 -}
1087
1088 rnTopSrcDecls :: HsGroup RdrName -> TcM (TcGblEnv, HsGroup Name)
1089 -- Fails if there are any errors
1090 rnTopSrcDecls group
1091 = do { -- Rename the source decls
1092 traceTc "rn12" empty ;
1093 (tcg_env, rn_decls) <- checkNoErrs $ rnSrcDecls group ;
1094 traceTc "rn13" empty ;
1095
1096 -- save the renamed syntax, if we want it
1097 let { tcg_env'
1098 | Just grp <- tcg_rn_decls tcg_env
1099 = tcg_env{ tcg_rn_decls = Just (appendGroups grp rn_decls) }
1100 | otherwise
1101 = tcg_env };
1102
1103 -- Dump trace of renaming part
1104 rnDump (ppr rn_decls) ;
1105
1106 return (tcg_env', rn_decls)
1107 }
1108
1109 tcTopSrcDecls :: HsGroup Name -> TcM (TcGblEnv, TcLclEnv)
1110 tcTopSrcDecls (HsGroup { hs_tyclds = tycl_decls,
1111 hs_instds = inst_decls,
1112 hs_derivds = deriv_decls,
1113 hs_fords = foreign_decls,
1114 hs_defds = default_decls,
1115 hs_annds = annotation_decls,
1116 hs_ruleds = rule_decls,
1117 hs_vects = vect_decls,
1118 hs_valds = val_binds })
1119 = do { -- Type-check the type and class decls, and all imported decls
1120 -- The latter come in via tycl_decls
1121 traceTc "Tc2 (src)" empty ;
1122
1123 -- Source-language instances, including derivings,
1124 -- and import the supporting declarations
1125 traceTc "Tc3" empty ;
1126 (tcg_env, inst_infos, deriv_binds)
1127 <- tcTyClsInstDecls tycl_decls inst_decls deriv_decls ;
1128 setGblEnv tcg_env $ do {
1129
1130
1131 -- Generate Applicative/Monad proposal (AMP) warnings
1132 traceTc "Tc3b" empty ;
1133
1134 -- Foreign import declarations next.
1135 traceTc "Tc4" empty ;
1136 (fi_ids, fi_decls, fi_gres) <- tcForeignImports foreign_decls ;
1137 tcExtendGlobalValEnv fi_ids $ do {
1138
1139 -- Default declarations
1140 traceTc "Tc4a" empty ;
1141 default_tys <- tcDefaults default_decls ;
1142 updGblEnv (\gbl -> gbl { tcg_default = default_tys }) $ do {
1143
1144 -- Now GHC-generated derived bindings, generics, and selectors
1145 -- Do not generate warnings from compiler-generated code;
1146 -- hence the use of discardWarnings
1147 tc_envs <- discardWarnings (tcTopBinds deriv_binds) ;
1148 setEnvs tc_envs $ do {
1149
1150 -- Value declarations next
1151 traceTc "Tc5" empty ;
1152 tc_envs@(tcg_env, tcl_env) <- tcTopBinds val_binds;
1153 setEnvs tc_envs $ do { -- Environment doesn't change now
1154
1155 -- Second pass over class and instance declarations,
1156 -- now using the kind-checked decls
1157 traceTc "Tc6" empty ;
1158 inst_binds <- tcInstDecls2 (tyClGroupConcat tycl_decls) inst_infos ;
1159
1160 -- Foreign exports
1161 traceTc "Tc7" empty ;
1162 (foe_binds, foe_decls, foe_gres) <- tcForeignExports foreign_decls ;
1163
1164 -- Annotations
1165 annotations <- tcAnnotations annotation_decls ;
1166
1167 -- Rules
1168 rules <- tcRules rule_decls ;
1169
1170 -- Vectorisation declarations
1171 vects <- tcVectDecls vect_decls ;
1172
1173 -- Wrap up
1174 traceTc "Tc7a" empty ;
1175 let { all_binds = inst_binds `unionBags`
1176 foe_binds
1177
1178 ; fo_gres = fi_gres `unionBags` foe_gres
1179 ; fo_fvs = foldrBag (\gre fvs -> fvs `addOneFV` gre_name gre)
1180 emptyFVs fo_gres
1181 ; fo_rdr_names :: [RdrName]
1182 ; fo_rdr_names = foldrBag gre_to_rdr_name [] fo_gres
1183
1184 ; sig_names = mkNameSet (collectHsValBinders val_binds)
1185 `minusNameSet` getTypeSigNames val_binds
1186
1187 -- Extend the GblEnv with the (as yet un-zonked)
1188 -- bindings, rules, foreign decls
1189 ; tcg_env' = tcg_env { tcg_binds = tcg_binds tcg_env `unionBags` all_binds
1190 , tcg_sigs = tcg_sigs tcg_env `unionNameSet` sig_names
1191 , tcg_rules = tcg_rules tcg_env
1192 ++ flattenRuleDecls rules
1193 , tcg_vects = tcg_vects tcg_env ++ vects
1194 , tcg_anns = tcg_anns tcg_env ++ annotations
1195 , tcg_ann_env = extendAnnEnvList (tcg_ann_env tcg_env) annotations
1196 , tcg_fords = tcg_fords tcg_env ++ foe_decls ++ fi_decls
1197 , tcg_dus = tcg_dus tcg_env `plusDU` usesOnly fo_fvs } } ;
1198 -- tcg_dus: see Note [Newtype constructor usage in foreign declarations]
1199
1200 addUsedRdrNames fo_rdr_names ;
1201 return (tcg_env', tcl_env)
1202 }}}}}}
1203 where
1204 gre_to_rdr_name :: GlobalRdrElt -> [RdrName] -> [RdrName]
1205 -- For *imported* newtype data constructors, we want to
1206 -- make sure that at least one of the imports for them is used
1207 -- See Note [Newtype constructor usage in foreign declarations]
1208 gre_to_rdr_name gre rdrs
1209 | isLocalGRE gre = rdrs
1210 | otherwise = greUsedRdrName gre : rdrs
1211
1212 ---------------------------
1213 tcTyClsInstDecls :: [TyClGroup Name]
1214 -> [LInstDecl Name]
1215 -> [LDerivDecl Name]
1216 -> TcM (TcGblEnv, -- The full inst env
1217 [InstInfo Name], -- Source-code instance decls to process;
1218 -- contains all dfuns for this module
1219 HsValBinds Name) -- Supporting bindings for derived instances
1220
1221 tcTyClsInstDecls tycl_decls inst_decls deriv_decls
1222 = tcExtendKindEnv2 [ (con, APromotionErr FamDataConPE)
1223 | lid <- inst_decls, con <- get_cons lid ] $
1224 -- Note [AFamDataCon: not promoting data family constructors]
1225 do { tcg_env <- tcTyAndClassDecls tycl_decls ;
1226 ; setGblEnv tcg_env $
1227 tcInstDecls1 tycl_decls inst_decls deriv_decls }
1228 where
1229 -- get_cons extracts the *constructor* bindings of the declaration
1230 get_cons :: LInstDecl Name -> [Name]
1231 get_cons (L _ (TyFamInstD {})) = []
1232 get_cons (L _ (DataFamInstD { dfid_inst = fid })) = get_fi_cons fid
1233 get_cons (L _ (ClsInstD { cid_inst = ClsInstDecl { cid_datafam_insts = fids } }))
1234 = concatMap (get_fi_cons . unLoc) fids
1235
1236 get_fi_cons :: DataFamInstDecl Name -> [Name]
1237 get_fi_cons (DataFamInstDecl { dfid_defn = HsDataDefn { dd_cons = cons } })
1238 = map unLoc $ concatMap (con_names . unLoc) cons
1239
1240 {-
1241 Note [AFamDataCon: not promoting data family constructors]
1242 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1243 Consider
1244 data family T a
1245 data instance T Int = MkT
1246 data Proxy (a :: k)
1247 data S = MkS (Proxy 'MkT)
1248
1249 Is it ok to use the promoted data family instance constructor 'MkT' in
1250 the data declaration for S? No, we don't allow this. It *might* make
1251 sense, but at least it would mean that we'd have to interleave
1252 typechecking instances and data types, whereas at present we do data
1253 types *then* instances.
1254
1255 So to check for this we put in the TcLclEnv a binding for all the family
1256 constructors, bound to AFamDataCon, so that if we trip over 'MkT' when
1257 type checking 'S' we'll produce a decent error message.
1258
1259
1260 ************************************************************************
1261 * *
1262 Checking for 'main'
1263 * *
1264 ************************************************************************
1265 -}
1266
1267 checkMain :: Bool -- False => no 'module M(..) where' header at all
1268 -> TcM TcGblEnv
1269 -- If we are in module Main, check that 'main' is defined.
1270 checkMain explicit_mod_hdr
1271 = do { dflags <- getDynFlags
1272 ; tcg_env <- getGblEnv
1273 ; check_main dflags tcg_env explicit_mod_hdr }
1274
1275 check_main :: DynFlags -> TcGblEnv -> Bool -> TcM TcGblEnv
1276 check_main dflags tcg_env explicit_mod_hdr
1277 | mod /= main_mod
1278 = traceTc "checkMain not" (ppr main_mod <+> ppr mod) >>
1279 return tcg_env
1280
1281 | otherwise
1282 = do { mb_main <- lookupGlobalOccRn_maybe main_fn
1283 -- Check that 'main' is in scope
1284 -- It might be imported from another module!
1285 ; case mb_main of {
1286 Nothing -> do { traceTc "checkMain fail" (ppr main_mod <+> ppr main_fn)
1287 ; complain_no_main
1288 ; return tcg_env } ;
1289 Just main_name -> do
1290
1291 { traceTc "checkMain found" (ppr main_mod <+> ppr main_fn)
1292 ; let loc = srcLocSpan (getSrcLoc main_name)
1293 ; ioTyCon <- tcLookupTyCon ioTyConName
1294 ; res_ty <- newFlexiTyVarTy liftedTypeKind
1295 ; main_expr
1296 <- addErrCtxt mainCtxt $
1297 tcMonoExpr (L loc (HsVar main_name)) (mkTyConApp ioTyCon [res_ty])
1298
1299 -- See Note [Root-main Id]
1300 -- Construct the binding
1301 -- :Main.main :: IO res_ty = runMainIO res_ty main
1302 ; run_main_id <- tcLookupId runMainIOName
1303 ; let { root_main_name = mkExternalName rootMainKey rOOT_MAIN
1304 (mkVarOccFS (fsLit "main"))
1305 (getSrcSpan main_name)
1306 ; root_main_id = Id.mkExportedLocalId VanillaId root_main_name
1307 (mkTyConApp ioTyCon [res_ty])
1308 ; co = mkWpTyApps [res_ty]
1309 ; rhs = nlHsApp (mkLHsWrap co (nlHsVar run_main_id)) main_expr
1310 ; main_bind = mkVarBind root_main_id rhs }
1311
1312 ; return (tcg_env { tcg_main = Just main_name,
1313 tcg_binds = tcg_binds tcg_env
1314 `snocBag` main_bind,
1315 tcg_dus = tcg_dus tcg_env
1316 `plusDU` usesOnly (unitFV main_name)
1317 -- Record the use of 'main', so that we don't
1318 -- complain about it being defined but not used
1319 })
1320 }}}
1321 where
1322 mod = tcg_mod tcg_env
1323 main_mod = mainModIs dflags
1324 main_fn = getMainFun dflags
1325 interactive = ghcLink dflags == LinkInMemory
1326
1327 complain_no_main = checkTc (interactive && not explicit_mod_hdr) noMainMsg
1328 -- In interactive mode, without an explicit module header, don't
1329 -- worry about the absence of 'main'.
1330 -- In other modes, fail altogether, so that we don't go on
1331 -- and complain a second time when processing the export list.
1332
1333 mainCtxt = ptext (sLit "When checking the type of the") <+> pp_main_fn
1334 noMainMsg = ptext (sLit "The") <+> pp_main_fn
1335 <+> ptext (sLit "is not defined in module") <+> quotes (ppr main_mod)
1336 pp_main_fn = ppMainFn main_fn
1337
1338 -- | Get the unqualified name of the function to use as the \"main\" for the main module.
1339 -- Either returns the default name or the one configured on the command line with -main-is
1340 getMainFun :: DynFlags -> RdrName
1341 getMainFun dflags = case mainFunIs dflags of
1342 Just fn -> mkRdrUnqual (mkVarOccFS (mkFastString fn))
1343 Nothing -> main_RDR_Unqual
1344
1345 -- If we are in module Main, check that 'main' is exported.
1346 checkMainExported :: TcGblEnv -> TcM ()
1347 checkMainExported tcg_env
1348 = case tcg_main tcg_env of
1349 Nothing -> return () -- not the main module
1350 Just main_name ->
1351 do { dflags <- getDynFlags
1352 ; let main_mod = mainModIs dflags
1353 ; checkTc (main_name `elem` concatMap availNames (tcg_exports tcg_env)) $
1354 ptext (sLit "The") <+> ppMainFn (nameRdrName main_name) <+>
1355 ptext (sLit "is not exported by module") <+> quotes (ppr main_mod) }
1356
1357 ppMainFn :: RdrName -> SDoc
1358 ppMainFn main_fn
1359 | rdrNameOcc main_fn == mainOcc
1360 = ptext (sLit "IO action") <+> quotes (ppr main_fn)
1361 | otherwise
1362 = ptext (sLit "main IO action") <+> quotes (ppr main_fn)
1363
1364 mainOcc :: OccName
1365 mainOcc = mkVarOccFS (fsLit "main")
1366
1367 {-
1368 Note [Root-main Id]
1369 ~~~~~~~~~~~~~~~~~~~
1370 The function that the RTS invokes is always :Main.main, which we call
1371 root_main_id. (Because GHC allows the user to have a module not
1372 called Main as the main module, we can't rely on the main function
1373 being called "Main.main". That's why root_main_id has a fixed module
1374 ":Main".)
1375
1376 This is unusual: it's a LocalId whose Name has a Module from another
1377 module. Tiresomely, we must filter it out again in MkIface, les we
1378 get two defns for 'main' in the interface file!
1379
1380
1381 *********************************************************
1382 * *
1383 GHCi stuff
1384 * *
1385 *********************************************************
1386 -}
1387
1388 runTcInteractive :: HscEnv -> TcRn a -> IO (Messages, Maybe a)
1389 -- Initialise the tcg_inst_env with instances from all home modules.
1390 -- This mimics the more selective call to hptInstances in tcRnImports
1391 runTcInteractive hsc_env thing_inside
1392 = initTcInteractive hsc_env $ withTcPlugins hsc_env $
1393 do { traceTc "setInteractiveContext" $
1394 vcat [ text "ic_tythings:" <+> vcat (map ppr (ic_tythings icxt))
1395 , text "ic_insts:" <+> vcat (map (pprBndr LetBind . instanceDFunId) ic_insts)
1396 , text "ic_rn_gbl_env (LocalDef)" <+>
1397 vcat (map ppr [ local_gres | gres <- occEnvElts (ic_rn_gbl_env icxt)
1398 , let local_gres = filter isLocalGRE gres
1399 , not (null local_gres) ]) ]
1400 ; let getOrphans m = fmap (\iface -> mi_module iface
1401 : dep_orphs (mi_deps iface))
1402 (loadSrcInterface (text "runTcInteractive") m
1403 False Nothing)
1404 ; orphs <- fmap concat . forM (ic_imports icxt) $ \i ->
1405 case i of
1406 IIModule n -> getOrphans n
1407 IIDecl i -> getOrphans (unLoc (ideclName i))
1408 ; let imports = emptyImportAvails {
1409 imp_orphs = orphs
1410 }
1411 ; (gbl_env, lcl_env) <- getEnvs
1412 ; let gbl_env' = gbl_env {
1413 tcg_rdr_env = ic_rn_gbl_env icxt
1414 , tcg_type_env = type_env
1415 , tcg_inst_env = extendInstEnvList
1416 (extendInstEnvList (tcg_inst_env gbl_env) ic_insts)
1417 home_insts
1418 , tcg_fam_inst_env = extendFamInstEnvList
1419 (extendFamInstEnvList (tcg_fam_inst_env gbl_env)
1420 ic_finsts)
1421 home_fam_insts
1422 , tcg_field_env = RecFields (mkNameEnv con_fields)
1423 (mkNameSet (concatMap snd con_fields))
1424 -- setting tcg_field_env is necessary
1425 -- to make RecordWildCards work (test: ghci049)
1426 , tcg_fix_env = ic_fix_env icxt
1427 , tcg_default = ic_default icxt
1428 -- must calculate imp_orphs of the ImportAvails
1429 -- so that instance visibility is done correctly
1430 , tcg_imports = imports
1431 }
1432
1433 ; lcl_env' <- tcExtendLocalTypeEnv lcl_env lcl_ids
1434 ; setEnvs (gbl_env', lcl_env') thing_inside }
1435 where
1436 (home_insts, home_fam_insts) = hptInstances hsc_env (\_ -> True)
1437
1438 icxt = hsc_IC hsc_env
1439 (ic_insts, ic_finsts) = ic_instances icxt
1440 (lcl_ids, top_ty_things) = partitionWith is_closed (ic_tythings icxt)
1441
1442 is_closed :: TyThing -> Either (Name, TcTyThing) TyThing
1443 -- Put Ids with free type variables (always RuntimeUnks)
1444 -- in the *local* type environment
1445 -- See Note [Initialising the type environment for GHCi]
1446 is_closed thing
1447 | AnId id <- thing
1448 , NotTopLevel <- isClosedLetBndr id
1449 = Left (idName id, ATcId { tct_id = id, tct_closed = NotTopLevel })
1450 | otherwise
1451 = Right thing
1452
1453 type_env1 = mkTypeEnvWithImplicits top_ty_things
1454 type_env = extendTypeEnvWithIds type_env1 (map instanceDFunId ic_insts)
1455 -- Putting the dfuns in the type_env
1456 -- is just to keep Core Lint happy
1457
1458 con_fields = [ (dataConName c, dataConFieldLabels c)
1459 | ATyCon t <- top_ty_things
1460 , c <- tyConDataCons t ]
1461
1462
1463 {- Note [Initialising the type environment for GHCi]
1464 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1465 Most of the the Ids in ic_things, defined by the user in 'let' stmts,
1466 have closed types. E.g.
1467 ghci> let foo x y = x && not y
1468
1469 However the GHCi debugger creates top-level bindings for Ids whose
1470 types have free RuntimeUnk skolem variables, standing for unknown
1471 types. If we don't register these free TyVars as global TyVars then
1472 the typechecker will try to quantify over them and fall over in
1473 zonkQuantifiedTyVar. so we must add any free TyVars to the
1474 typechecker's global TyVar set. That is most conveniently by using
1475 tcExtendLocalTypeEnv, which automatically extends the global TyVar
1476 set.
1477
1478 We do this by splitting out the Ids with open types, using 'is_closed'
1479 to do the partition. The top-level things go in the global TypeEnv;
1480 the open, NotTopLevel, Ids, with free RuntimeUnk tyvars, go in the
1481 local TypeEnv.
1482
1483 Note that we don't extend the local RdrEnv (tcl_rdr); all the in-scope
1484 things are already in the interactive context's GlobalRdrEnv.
1485 Extending the local RdrEnv isn't terrible, but it means there is an
1486 entry for the same Name in both global and local RdrEnvs, and that
1487 lead to duplicate "perhaps you meant..." suggestions (e.g. T5564).
1488
1489 We don't bother with the tcl_th_bndrs environment either.
1490 -}
1491
1492 #ifdef GHCI
1493 -- | The returned [Id] is the list of new Ids bound by this statement. It can
1494 -- be used to extend the InteractiveContext via extendInteractiveContext.
1495 --
1496 -- The returned TypecheckedHsExpr is of type IO [ () ], a list of the bound
1497 -- values, coerced to ().
1498 tcRnStmt :: HscEnv -> GhciLStmt RdrName
1499 -> IO (Messages, Maybe ([Id], LHsExpr Id, FixityEnv))
1500 tcRnStmt hsc_env rdr_stmt
1501 = runTcInteractive hsc_env $ do {
1502
1503 -- The real work is done here
1504 ((bound_ids, tc_expr), fix_env) <- tcUserStmt rdr_stmt ;
1505 zonked_expr <- zonkTopLExpr tc_expr ;
1506 zonked_ids <- zonkTopBndrs bound_ids ;
1507
1508 -- None of the Ids should be of unboxed type, because we
1509 -- cast them all to HValues in the end!
1510 mapM_ bad_unboxed (filter (isUnLiftedType . idType) zonked_ids) ;
1511
1512 traceTc "tcs 1" empty ;
1513 this_mod <- getModule ;
1514 global_ids <- mapM (externaliseAndTidyId this_mod) zonked_ids ;
1515 -- Note [Interactively-bound Ids in GHCi] in HscTypes
1516
1517 {- ---------------------------------------------
1518 At one stage I removed any shadowed bindings from the type_env;
1519 they are inaccessible but might, I suppose, cause a space leak if we leave them there.
1520 However, with Template Haskell they aren't necessarily inaccessible. Consider this
1521 GHCi session
1522 Prelude> let f n = n * 2 :: Int
1523 Prelude> fName <- runQ [| f |]
1524 Prelude> $(return $ AppE fName (LitE (IntegerL 7)))
1525 14
1526 Prelude> let f n = n * 3 :: Int
1527 Prelude> $(return $ AppE fName (LitE (IntegerL 7)))
1528 In the last line we use 'fName', which resolves to the *first* 'f'
1529 in scope. If we delete it from the type env, GHCi crashes because
1530 it doesn't expect that.
1531
1532 Hence this code is commented out
1533
1534 -------------------------------------------------- -}
1535
1536 traceOptTcRn Opt_D_dump_tc
1537 (vcat [text "Bound Ids" <+> pprWithCommas ppr global_ids,
1538 text "Typechecked expr" <+> ppr zonked_expr]) ;
1539
1540 return (global_ids, zonked_expr, fix_env)
1541 }
1542 where
1543 bad_unboxed id = addErr (sep [ptext (sLit "GHCi can't bind a variable of unlifted type:"),
1544 nest 2 (ppr id <+> dcolon <+> ppr (idType id))])
1545
1546 {-
1547 --------------------------------------------------------------------------
1548 Typechecking Stmts in GHCi
1549
1550 Here is the grand plan, implemented in tcUserStmt
1551
1552 What you type The IO [HValue] that hscStmt returns
1553 ------------- ------------------------------------
1554 let pat = expr ==> let pat = expr in return [coerce HVal x, coerce HVal y, ...]
1555 bindings: [x,y,...]
1556
1557 pat <- expr ==> expr >>= \ pat -> return [coerce HVal x, coerce HVal y, ...]
1558 bindings: [x,y,...]
1559
1560 expr (of IO type) ==> expr >>= \ it -> return [coerce HVal it]
1561 [NB: result not printed] bindings: [it]
1562
1563 expr (of non-IO type, ==> let it = expr in print it >> return [coerce HVal it]
1564 result showable) bindings: [it]
1565
1566 expr (of non-IO type,
1567 result not showable) ==> error
1568 -}
1569
1570 -- | A plan is an attempt to lift some code into the IO monad.
1571 type PlanResult = ([Id], LHsExpr Id)
1572 type Plan = TcM PlanResult
1573
1574 -- | Try the plans in order. If one fails (by raising an exn), try the next.
1575 -- If one succeeds, take it.
1576 runPlans :: [Plan] -> TcM PlanResult
1577 runPlans [] = panic "runPlans"
1578 runPlans [p] = p
1579 runPlans (p:ps) = tryTcLIE_ (runPlans ps) p
1580
1581 -- | Typecheck (and 'lift') a stmt entered by the user in GHCi into the
1582 -- GHCi 'environment'.
1583 --
1584 -- By 'lift' and 'environment we mean that the code is changed to
1585 -- execute properly in an IO monad. See Note [Interactively-bound Ids
1586 -- in GHCi] in HscTypes for more details. We do this lifting by trying
1587 -- different ways ('plans') of lifting the code into the IO monad and
1588 -- type checking each plan until one succeeds.
1589 tcUserStmt :: GhciLStmt RdrName -> TcM (PlanResult, FixityEnv)
1590
1591 -- An expression typed at the prompt is treated very specially
1592 tcUserStmt (L loc (BodyStmt expr _ _ _))
1593 = do { (rn_expr, fvs) <- checkNoErrs (rnLExpr expr)
1594 -- Don't try to typecheck if the renamer fails!
1595 ; ghciStep <- getGhciStepIO
1596 ; uniq <- newUnique
1597 ; interPrintName <- getInteractivePrintName
1598 ; let fresh_it = itName uniq loc
1599 matches = [mkMatch [] rn_expr emptyLocalBinds]
1600 -- [it = expr]
1601 the_bind = L loc $ (mkTopFunBind FromSource (L loc fresh_it) matches) { bind_fvs = fvs }
1602 -- Care here! In GHCi the expression might have
1603 -- free variables, and they in turn may have free type variables
1604 -- (if we are at a breakpoint, say). We must put those free vars
1605
1606 -- [let it = expr]
1607 let_stmt = L loc $ LetStmt $ HsValBinds $
1608 ValBindsOut [(NonRecursive,unitBag the_bind)] []
1609
1610 -- [it <- e]
1611 bind_stmt = L loc $ BindStmt (L loc (VarPat fresh_it))
1612 (nlHsApp ghciStep rn_expr)
1613 (HsVar bindIOName) noSyntaxExpr
1614
1615 -- [; print it]
1616 print_it = L loc $ BodyStmt (nlHsApp (nlHsVar interPrintName) (nlHsVar fresh_it))
1617 (HsVar thenIOName) noSyntaxExpr placeHolderType
1618
1619 -- The plans are:
1620 -- A. [it <- e; print it] but not if it::()
1621 -- B. [it <- e]
1622 -- C. [let it = e; print it]
1623 --
1624 -- Ensure that type errors don't get deferred when type checking the
1625 -- naked expression. Deferring type errors here is unhelpful because the
1626 -- expression gets evaluated right away anyway. It also would potentially
1627 -- emit two redundant type-error warnings, one from each plan.
1628 ; plan <- unsetGOptM Opt_DeferTypeErrors $ runPlans [
1629 -- Plan A
1630 do { stuff@([it_id], _) <- tcGhciStmts [bind_stmt, print_it]
1631 ; it_ty <- zonkTcType (idType it_id)
1632 ; when (isUnitTy $ it_ty) failM
1633 ; return stuff },
1634
1635 -- Plan B; a naked bind statment
1636 tcGhciStmts [bind_stmt],
1637
1638 -- Plan C; check that the let-binding is typeable all by itself.
1639 -- If not, fail; if so, try to print it.
1640 -- The two-step process avoids getting two errors: one from
1641 -- the expression itself, and one from the 'print it' part
1642 -- This two-step story is very clunky, alas
1643 do { _ <- checkNoErrs (tcGhciStmts [let_stmt])
1644 --- checkNoErrs defeats the error recovery of let-bindings
1645 ; tcGhciStmts [let_stmt, print_it] } ]
1646
1647 ; fix_env <- getFixityEnv
1648 ; return (plan, fix_env) }
1649
1650 tcUserStmt rdr_stmt@(L loc _)
1651 = do { (([rn_stmt], fix_env), fvs) <- checkNoErrs $
1652 rnStmts GhciStmtCtxt rnLExpr [rdr_stmt] $ \_ -> do
1653 fix_env <- getFixityEnv
1654 return (fix_env, emptyFVs)
1655 -- Don't try to typecheck if the renamer fails!
1656 ; traceRn (text "tcRnStmt" <+> vcat [ppr rdr_stmt, ppr rn_stmt, ppr fvs])
1657 ; rnDump (ppr rn_stmt) ;
1658
1659 ; ghciStep <- getGhciStepIO
1660 ; let gi_stmt
1661 | (L loc (BindStmt pat expr op1 op2)) <- rn_stmt
1662 = L loc $ BindStmt pat (nlHsApp ghciStep expr) op1 op2
1663 | otherwise = rn_stmt
1664
1665 ; opt_pr_flag <- goptM Opt_PrintBindResult
1666 ; let print_result_plan
1667 | opt_pr_flag -- The flag says "print result"
1668 , [v] <- collectLStmtBinders gi_stmt -- One binder
1669 = [mk_print_result_plan gi_stmt v]
1670 | otherwise = []
1671
1672 -- The plans are:
1673 -- [stmt; print v] if one binder and not v::()
1674 -- [stmt] otherwise
1675 ; plan <- runPlans (print_result_plan ++ [tcGhciStmts [gi_stmt]])
1676 ; return (plan, fix_env) }
1677 where
1678 mk_print_result_plan stmt v
1679 = do { stuff@([v_id], _) <- tcGhciStmts [stmt, print_v]
1680 ; v_ty <- zonkTcType (idType v_id)
1681 ; when (isUnitTy v_ty || not (isTauTy v_ty)) failM
1682 ; return stuff }
1683 where
1684 print_v = L loc $ BodyStmt (nlHsApp (nlHsVar printName) (nlHsVar v))
1685 (HsVar thenIOName) noSyntaxExpr
1686 placeHolderType
1687
1688 -- | Typecheck the statements given and then return the results of the
1689 -- statement in the form 'IO [()]'.
1690 tcGhciStmts :: [GhciLStmt Name] -> TcM PlanResult
1691 tcGhciStmts stmts
1692 = do { ioTyCon <- tcLookupTyCon ioTyConName ;
1693 ret_id <- tcLookupId returnIOName ; -- return @ IO
1694 let {
1695 ret_ty = mkListTy unitTy ;
1696 io_ret_ty = mkTyConApp ioTyCon [ret_ty] ;
1697 tc_io_stmts = tcStmtsAndThen GhciStmtCtxt tcDoStmt stmts io_ret_ty ;
1698 names = collectLStmtsBinders stmts ;
1699 } ;
1700
1701 -- OK, we're ready to typecheck the stmts
1702 traceTc "TcRnDriver.tcGhciStmts: tc stmts" empty ;
1703 ((tc_stmts, ids), lie) <- captureConstraints $
1704 tc_io_stmts $ \ _ ->
1705 mapM tcLookupId names ;
1706 -- Look up the names right in the middle,
1707 -- where they will all be in scope
1708
1709 -- wanted constraints from static forms
1710 stWC <- tcg_static_wc <$> getGblEnv >>= readTcRef ;
1711
1712 -- Simplify the context
1713 traceTc "TcRnDriver.tcGhciStmts: simplify ctxt" empty ;
1714 const_binds <- checkNoErrs (simplifyInteractive (andWC stWC lie)) ;
1715 -- checkNoErrs ensures that the plan fails if context redn fails
1716
1717 traceTc "TcRnDriver.tcGhciStmts: done" empty ;
1718 let { -- mk_return builds the expression
1719 -- returnIO @ [()] [coerce () x, .., coerce () z]
1720 --
1721 -- Despite the inconvenience of building the type applications etc,
1722 -- this *has* to be done in type-annotated post-typecheck form
1723 -- because we are going to return a list of *polymorphic* values
1724 -- coerced to type (). If we built a *source* stmt
1725 -- return [coerce x, ..., coerce z]
1726 -- then the type checker would instantiate x..z, and we wouldn't
1727 -- get their *polymorphic* values. (And we'd get ambiguity errs
1728 -- if they were overloaded, since they aren't applied to anything.)
1729 ret_expr = nlHsApp (nlHsTyApp ret_id [ret_ty])
1730 (noLoc $ ExplicitList unitTy Nothing (map mk_item ids)) ;
1731 mk_item id = nlHsApp (nlHsTyApp unsafeCoerceId [idType id, unitTy])
1732 (nlHsVar id) ;
1733 stmts = tc_stmts ++ [noLoc (mkLastStmt ret_expr)]
1734 } ;
1735 return (ids, mkHsDictLet (EvBinds const_binds) $
1736 noLoc (HsDo GhciStmtCtxt stmts io_ret_ty))
1737 }
1738
1739 -- | Generate a typed ghciStepIO expression (ghciStep :: Ty a -> IO a)
1740 getGhciStepIO :: TcM (LHsExpr Name)
1741 getGhciStepIO = do
1742 ghciTy <- getGHCiMonad
1743 fresh_a <- newUnique
1744 loc <- getSrcSpanM
1745 let a_tv = mkInternalName fresh_a (mkTyVarOccFS (fsLit "a")) loc
1746 ghciM = nlHsAppTy (nlHsTyVar ghciTy) (nlHsTyVar a_tv)
1747 ioM = nlHsAppTy (nlHsTyVar ioTyConName) (nlHsTyVar a_tv)
1748
1749 stepTy :: LHsType Name -- Renamed, so needs all binders in place
1750 stepTy = noLoc $ HsForAllTy Implicit Nothing
1751 (HsQTvs { hsq_tvs = [noLoc (UserTyVar a_tv)]
1752 , hsq_kvs = [] })
1753 (noLoc [])
1754 (nlHsFunTy ghciM ioM)
1755 step = noLoc $ ExprWithTySig (nlHsVar ghciStepIoMName) stepTy []
1756 return step
1757
1758 isGHCiMonad :: HscEnv -> String -> IO (Messages, Maybe Name)
1759 isGHCiMonad hsc_env ty
1760 = runTcInteractive hsc_env $ do
1761 rdrEnv <- getGlobalRdrEnv
1762 let occIO = lookupOccEnv rdrEnv (mkOccName tcName ty)
1763 case occIO of
1764 Just [n] -> do
1765 let name = gre_name n
1766 ghciClass <- tcLookupClass ghciIoClassName
1767 userTyCon <- tcLookupTyCon name
1768 let userTy = mkTyConApp userTyCon []
1769 _ <- tcLookupInstance ghciClass [userTy]
1770 return name
1771
1772 Just _ -> failWithTc $ text "Ambigous type!"
1773 Nothing -> failWithTc $ text ("Can't find type:" ++ ty)
1774
1775 -- tcRnExpr just finds the type of an expression
1776
1777 tcRnExpr :: HscEnv
1778 -> LHsExpr RdrName
1779 -> IO (Messages, Maybe Type)
1780 -- Type checks the expression and returns its most general type
1781 tcRnExpr hsc_env rdr_expr
1782 = runTcInteractive hsc_env $
1783 do {
1784
1785 (rn_expr, _fvs) <- rnLExpr rdr_expr ;
1786 failIfErrsM ;
1787
1788 -- Now typecheck the expression, and generalise its type
1789 -- it might have a rank-2 type (e.g. :t runST)
1790 uniq <- newUnique ;
1791 let { fresh_it = itName uniq (getLoc rdr_expr) } ;
1792 ((_tc_expr, res_ty), tclvl, lie) <- pushLevelAndCaptureConstraints $
1793 tcInferRho rn_expr ;
1794 ((qtvs, dicts, _), lie_top) <- captureConstraints $
1795 {-# SCC "simplifyInfer" #-}
1796 simplifyInfer tclvl
1797 False {- No MR for now -}
1798 [] {- No sig vars -}
1799 [(fresh_it, res_ty)]
1800 lie ;
1801 -- Wanted constraints from static forms
1802 stWC <- tcg_static_wc <$> getGblEnv >>= readTcRef ;
1803
1804 -- Ignore the dictionary bindings
1805 _ <- simplifyInteractive (andWC stWC lie_top) ;
1806
1807 let { all_expr_ty = mkForAllTys qtvs (mkPiTypes dicts res_ty) } ;
1808 ty <- zonkTcType all_expr_ty ;
1809
1810 -- We normalise type families, so that the type of an expression is the
1811 -- same as of a bound expression (TcBinds.mkInferredPolyId). See Trac
1812 -- #10321 for further discussion.
1813 fam_envs <- tcGetFamInstEnvs ;
1814 -- normaliseType returns a coercion which we discard, so the Role is
1815 -- irrelevant
1816 return (snd (normaliseType fam_envs Nominal ty))
1817 }
1818
1819 --------------------------
1820 tcRnImportDecls :: HscEnv
1821 -> [LImportDecl RdrName]
1822 -> IO (Messages, Maybe GlobalRdrEnv)
1823 -- Find the new chunk of GlobalRdrEnv created by this list of import
1824 -- decls. In contract tcRnImports *extends* the TcGblEnv.
1825 tcRnImportDecls hsc_env import_decls
1826 = runTcInteractive hsc_env $
1827 do { gbl_env <- updGblEnv zap_rdr_env $
1828 tcRnImports hsc_env import_decls
1829 ; return (tcg_rdr_env gbl_env) }
1830 where
1831 zap_rdr_env gbl_env = gbl_env { tcg_rdr_env = emptyGlobalRdrEnv }
1832
1833 -- tcRnType just finds the kind of a type
1834
1835 tcRnType :: HscEnv
1836 -> Bool -- Normalise the returned type
1837 -> LHsType RdrName
1838 -> IO (Messages, Maybe (Type, Kind))
1839 tcRnType hsc_env normalise rdr_type
1840 = runTcInteractive hsc_env $
1841 setXOptM Opt_PolyKinds $ -- See Note [Kind-generalise in tcRnType]
1842 do { (rn_type, _fvs, wcs) <- rnLHsTypeWithWildCards GHCiCtx rdr_type
1843 ; failIfErrsM
1844
1845 -- Now kind-check the type
1846 -- It can have any rank or kind
1847 ; (ty, kind) <- tcWildcardBinders wcs $ \_ ->
1848 tcLHsType rn_type
1849
1850 -- Do kind generalisation; see Note [Kind-generalise in tcRnType]
1851 ; kvs <- zonkTcTypeAndFV kind
1852 ; kvs <- kindGeneralize kvs
1853 ; ty <- zonkTcTypeToType emptyZonkEnv ty
1854
1855 ; ty' <- if normalise
1856 then do { fam_envs <- tcGetFamInstEnvs
1857 ; return (snd (normaliseType fam_envs Nominal ty)) }
1858 -- normaliseType returns a coercion
1859 -- which we discard, so the Role is irrelevant
1860 else return ty ;
1861
1862 ; return (ty', mkForAllTys kvs (typeKind ty')) }
1863
1864 {- Note [Kind-generalise in tcRnType]
1865 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
1866 We switch on PolyKinds when kind-checking a user type, so that we will
1867 kind-generalise the type, even when PolyKinds is not otherwise on.
1868 This gives the right default behaviour at the GHCi prompt, where if
1869 you say ":k T", and T has a polymorphic kind, you'd like to see that
1870 polymorphism. Of course. If T isn't kind-polymorphic you won't get
1871 anything unexpected, but the apparent *loss* of polymorphism, for
1872 types that you know are polymorphic, is quite surprising. See Trac
1873 #7688 for a discussion.
1874
1875 Note that the goal is to generalise the *kind of the type*, not
1876 the type itself! Example:
1877 ghci> data T m a = MkT (m a) -- T :: forall . (k -> *) -> k -> *
1878 ghci> :k T
1879 We instantiate T to get (T kappa). We do not want to kind-generalise
1880 that to forall k. T k! Rather we want to take its kind
1881 T kappa :: (kappa -> *) -> kappa -> *
1882 and now kind-generalise that kind, to forall k. (k->*) -> k -> *
1883 (It was Trac #10122 that made me realise how wrong the previous
1884 approach was.) -}
1885
1886
1887 {-
1888 ************************************************************************
1889 * *
1890 tcRnDeclsi
1891 * *
1892 ************************************************************************
1893
1894 tcRnDeclsi exists to allow class, data, and other declarations in GHCi.
1895 -}
1896
1897 tcRnDeclsi :: HscEnv
1898 -> [LHsDecl RdrName]
1899 -> IO (Messages, Maybe TcGblEnv)
1900 tcRnDeclsi hsc_env local_decls
1901 = runTcInteractive hsc_env $
1902 tcRnSrcDecls False Nothing local_decls
1903
1904 externaliseAndTidyId :: Module -> Id -> TcM Id
1905 externaliseAndTidyId this_mod id
1906 = do { name' <- externaliseName this_mod (idName id)
1907 ; return (globaliseAndTidyId (setIdName id name')) }
1908
1909 #endif /* GHCi */
1910
1911 {-
1912 ************************************************************************
1913 * *
1914 More GHCi stuff, to do with browsing and getting info
1915 * *
1916 ************************************************************************
1917 -}
1918
1919 #ifdef GHCI
1920 -- | ASSUMES that the module is either in the 'HomePackageTable' or is
1921 -- a package module with an interface on disk. If neither of these is
1922 -- true, then the result will be an error indicating the interface
1923 -- could not be found.
1924 getModuleInterface :: HscEnv -> Module -> IO (Messages, Maybe ModIface)
1925 getModuleInterface hsc_env mod
1926 = runTcInteractive hsc_env $
1927 loadModuleInterface (ptext (sLit "getModuleInterface")) mod
1928
1929 tcRnLookupRdrName :: HscEnv -> Located RdrName
1930 -> IO (Messages, Maybe [Name])
1931 -- ^ Find all the Names that this RdrName could mean, in GHCi
1932 tcRnLookupRdrName hsc_env (L loc rdr_name)
1933 = runTcInteractive hsc_env $
1934 setSrcSpan loc $
1935 do { -- If the identifier is a constructor (begins with an
1936 -- upper-case letter), then we need to consider both
1937 -- constructor and type class identifiers.
1938 let rdr_names = dataTcOccs rdr_name
1939 ; names_s <- mapM lookupInfoOccRn rdr_names
1940 ; let names = concat names_s
1941 ; when (null names) (addErrTc (ptext (sLit "Not in scope:") <+> quotes (ppr rdr_name)))
1942 ; return names }
1943 #endif
1944
1945 tcRnLookupName :: HscEnv -> Name -> IO (Messages, Maybe TyThing)
1946 tcRnLookupName hsc_env name
1947 = runTcInteractive hsc_env $
1948 tcRnLookupName' name
1949
1950 -- To look up a name we have to look in the local environment (tcl_lcl)
1951 -- as well as the global environment, which is what tcLookup does.
1952 -- But we also want a TyThing, so we have to convert:
1953
1954 tcRnLookupName' :: Name -> TcRn TyThing
1955 tcRnLookupName' name = do
1956 tcthing <- tcLookup name
1957 case tcthing of
1958 AGlobal thing -> return thing
1959 ATcId{tct_id=id} -> return (AnId id)
1960 _ -> panic "tcRnLookupName'"
1961
1962 tcRnGetInfo :: HscEnv
1963 -> Name
1964 -> IO (Messages, Maybe (TyThing, Fixity, [ClsInst], [FamInst]))
1965
1966 -- Used to implement :info in GHCi
1967 --
1968 -- Look up a RdrName and return all the TyThings it might be
1969 -- A capitalised RdrName is given to us in the DataName namespace,
1970 -- but we want to treat it as *both* a data constructor
1971 -- *and* as a type or class constructor;
1972 -- hence the call to dataTcOccs, and we return up to two results
1973 tcRnGetInfo hsc_env name
1974 = runTcInteractive hsc_env $
1975 do { loadUnqualIfaces hsc_env (hsc_IC hsc_env)
1976 -- Load the interface for all unqualified types and classes
1977 -- That way we will find all the instance declarations
1978 -- (Packages have not orphan modules, and we assume that
1979 -- in the home package all relevant modules are loaded.)
1980
1981 ; thing <- tcRnLookupName' name
1982 ; fixity <- lookupFixityRn name
1983 ; (cls_insts, fam_insts) <- lookupInsts thing
1984 ; return (thing, fixity, cls_insts, fam_insts) }
1985
1986 lookupInsts :: TyThing -> TcM ([ClsInst],[FamInst])
1987 lookupInsts (ATyCon tc)
1988 = do { InstEnvs { ie_global = pkg_ie, ie_local = home_ie, ie_visible = vis_mods } <- tcGetInstEnvs
1989 ; (pkg_fie, home_fie) <- tcGetFamInstEnvs
1990 -- Load all instances for all classes that are
1991 -- in the type environment (which are all the ones
1992 -- we've seen in any interface file so far)
1993
1994 -- Return only the instances relevant to the given thing, i.e.
1995 -- the instances whose head contains the thing's name.
1996 ; let cls_insts =
1997 [ ispec -- Search all
1998 | ispec <- instEnvElts home_ie ++ instEnvElts pkg_ie
1999 , instIsVisible vis_mods ispec
2000 , tc_name `elemNameSet` orphNamesOfClsInst ispec ]
2001 ; let fam_insts =
2002 [ fispec
2003 | fispec <- famInstEnvElts home_fie ++ famInstEnvElts pkg_fie
2004 , tc_name `elemNameSet` orphNamesOfFamInst fispec ]
2005 ; return (cls_insts, fam_insts) }
2006 where
2007 tc_name = tyConName tc
2008
2009 lookupInsts _ = return ([],[])
2010
2011 loadUnqualIfaces :: HscEnv -> InteractiveContext -> TcM ()
2012 -- Load the interface for everything that is in scope unqualified
2013 -- This is so that we can accurately report the instances for
2014 -- something
2015 loadUnqualIfaces hsc_env ictxt
2016 = initIfaceTcRn $ do
2017 mapM_ (loadSysInterface doc) (moduleSetElts (mkModuleSet unqual_mods))
2018 where
2019 this_pkg = thisPackage (hsc_dflags hsc_env)
2020
2021 unqual_mods = [ nameModule name
2022 | gre <- globalRdrEnvElts (ic_rn_gbl_env ictxt)
2023 , let name = gre_name gre
2024 , nameIsFromExternalPackage this_pkg name
2025 , isTcOcc (nameOccName name) -- Types and classes only
2026 , unQualOK gre ] -- In scope unqualified
2027 doc = ptext (sLit "Need interface for module whose export(s) are in scope unqualified")
2028
2029
2030 {-
2031 ************************************************************************
2032 * *
2033 Degugging output
2034 * *
2035 ************************************************************************
2036 -}
2037
2038 rnDump :: SDoc -> TcRn ()
2039 -- Dump, with a banner, if -ddump-rn
2040 rnDump doc = do { traceOptTcRn Opt_D_dump_rn (mkDumpDoc "Renamer" doc) }
2041
2042 tcDump :: TcGblEnv -> TcRn ()
2043 tcDump env
2044 = do { dflags <- getDynFlags ;
2045
2046 -- Dump short output if -ddump-types or -ddump-tc
2047 when (dopt Opt_D_dump_types dflags || dopt Opt_D_dump_tc dflags)
2048 (printForUserTcRn short_dump) ;
2049
2050 -- Dump bindings if -ddump-tc
2051 traceOptTcRn Opt_D_dump_tc (mkDumpDoc "Typechecker" full_dump)
2052 }
2053 where
2054 short_dump = pprTcGblEnv env
2055 full_dump = pprLHsBinds (tcg_binds env)
2056 -- NB: foreign x-d's have undefined's in their types;
2057 -- hence can't show the tc_fords
2058
2059 -- It's unpleasant having both pprModGuts and pprModDetails here
2060 pprTcGblEnv :: TcGblEnv -> SDoc
2061 pprTcGblEnv (TcGblEnv { tcg_type_env = type_env,
2062 tcg_insts = insts,
2063 tcg_fam_insts = fam_insts,
2064 tcg_rules = rules,
2065 tcg_vects = vects,
2066 tcg_imports = imports })
2067 = vcat [ ppr_types insts type_env
2068 , ppr_tycons fam_insts type_env
2069 , ppr_insts insts
2070 , ppr_fam_insts fam_insts
2071 , vcat (map ppr rules)
2072 , vcat (map ppr vects)
2073 , ptext (sLit "Dependent modules:") <+>
2074 ppr (sortBy cmp_mp $ eltsUFM (imp_dep_mods imports))
2075 , ptext (sLit "Dependent packages:") <+>
2076 ppr (sortBy stablePackageKeyCmp $ imp_dep_pkgs imports)]
2077 where -- The two uses of sortBy are just to reduce unnecessary
2078 -- wobbling in testsuite output
2079 cmp_mp (mod_name1, is_boot1) (mod_name2, is_boot2)
2080 = (mod_name1 `stableModuleNameCmp` mod_name2)
2081 `thenCmp`
2082 (is_boot1 `compare` is_boot2)
2083
2084 ppr_types :: [ClsInst] -> TypeEnv -> SDoc
2085 ppr_types insts type_env
2086 = text "TYPE SIGNATURES" $$ nest 2 (ppr_sigs ids)
2087 where
2088 dfun_ids = map instanceDFunId insts
2089 ids = [id | id <- typeEnvIds type_env, want_sig id]
2090 want_sig id | opt_PprStyle_Debug = True
2091 | otherwise = isLocalId id &&
2092 isExternalName (idName id) &&
2093 not (id `elem` dfun_ids)
2094 -- isLocalId ignores data constructors, records selectors etc.
2095 -- The isExternalName ignores local dictionary and method bindings
2096 -- that the type checker has invented. Top-level user-defined things
2097 -- have External names.
2098
2099 ppr_tycons :: [FamInst] -> TypeEnv -> SDoc
2100 ppr_tycons fam_insts type_env
2101 = vcat [ text "TYPE CONSTRUCTORS"
2102 , nest 2 (ppr_tydecls tycons)
2103 , text "COERCION AXIOMS"
2104 , nest 2 (vcat (map pprCoAxiom (typeEnvCoAxioms type_env))) ]
2105 where
2106 fi_tycons = famInstsRepTyCons fam_insts
2107 tycons = [tycon | tycon <- typeEnvTyCons type_env, want_tycon tycon]
2108 want_tycon tycon | opt_PprStyle_Debug = True
2109 | otherwise = not (isImplicitTyCon tycon) &&
2110 isExternalName (tyConName tycon) &&
2111 not (tycon `elem` fi_tycons)
2112
2113 ppr_insts :: [ClsInst] -> SDoc
2114 ppr_insts [] = empty
2115 ppr_insts ispecs = text "INSTANCES" $$ nest 2 (pprInstances ispecs)
2116
2117 ppr_fam_insts :: [FamInst] -> SDoc
2118 ppr_fam_insts [] = empty
2119 ppr_fam_insts fam_insts =
2120 text "FAMILY INSTANCES" $$ nest 2 (pprFamInsts fam_insts)
2121
2122 ppr_sigs :: [Var] -> SDoc
2123 ppr_sigs ids
2124 -- Print type signatures; sort by OccName
2125 = vcat (map ppr_sig (sortBy (comparing getOccName) ids))
2126 where
2127 ppr_sig id = hang (ppr id <+> dcolon) 2 (ppr (tidyTopType (idType id)))
2128
2129 ppr_tydecls :: [TyCon] -> SDoc
2130 ppr_tydecls tycons
2131 -- Print type constructor info; sort by OccName
2132 = vcat (map ppr_tycon (sortBy (comparing getOccName) tycons))
2133 where
2134 ppr_tycon tycon = vcat [ ppr (tyThingToIfaceDecl (ATyCon tycon)) ]
2135
2136 {-
2137 ********************************************************************************
2138
2139 Type Checker Plugins
2140
2141 ********************************************************************************
2142 -}
2143
2144 withTcPlugins :: HscEnv -> TcM a -> TcM a
2145 withTcPlugins hsc_env m =
2146 do plugins <- liftIO (loadTcPlugins hsc_env)
2147 case plugins of
2148 [] -> m -- Common fast case
2149 _ -> do (solvers,stops) <- unzip `fmap` mapM startPlugin plugins
2150 -- This ensures that tcPluginStop is called even if a type
2151 -- error occurs during compilation (Fix of #10078)
2152 eitherRes <- tryM $ do
2153 updGblEnv (\e -> e { tcg_tc_plugins = solvers }) m
2154 mapM_ (flip runTcPluginM Nothing) stops
2155 case eitherRes of
2156 Left _ -> failM
2157 Right res -> return res
2158 where
2159 startPlugin (TcPlugin start solve stop) =
2160 do s <- runTcPluginM start Nothing
2161 return (solve s, stop s)
2162
2163 loadTcPlugins :: HscEnv -> IO [TcPlugin]
2164 #ifndef GHCI
2165 loadTcPlugins _ = return []
2166 #else
2167 loadTcPlugins hsc_env =
2168 do named_plugins <- loadPlugins hsc_env
2169 return $ catMaybes $ map load_plugin named_plugins
2170 where
2171 load_plugin (_, plug, opts) = tcPlugin plug opts
2172 #endif