[project @ 2001-11-06 11:04:16 by simonmar]

[ghc-hetmet.git] / ghc / compiler / rename / RnIfaces.lhs

%
% (c) The GRASP/AQUA Project, Glasgow University, 1992-1998
%
\section[RnIfaces]{Cacheing and Renaming of Interfaces}

\begin{code}
module RnIfaces
     (
        recordLocalSlurps, 
        mkImportInfo, 

        slurpImpDecls, closeDecls,

        RecompileRequired, outOfDate, upToDate, recompileRequired
       )
where

#include "HsVersions.h"

import CmdLineOpts      ( opt_IgnoreIfacePragmas, opt_NoPruneDecls )
import HscTypes
import HsSyn            ( HsDecl(..), Sig(..), TyClDecl(..), ConDecl(..), ConDetails(..),
                          InstDecl(..), HsType(..), hsTyVarNames, getBangType
                        )
import HsImpExp         ( ImportDecl(..) )
import RdrHsSyn         ( RdrNameTyClDecl, RdrNameInstDecl, RdrNameRuleDecl )
import RnHsSyn          ( RenamedHsDecl, RenamedTyClDecl,
                          extractHsTyNames, extractHsCtxtTyNames, 
                          tyClDeclFVs, ruleDeclFVs, instDeclFVs
                        )
import RnHiFiles        ( tryLoadInterface, loadHomeInterface, 
                          loadOrphanModules
                        )
import RnSource         ( rnTyClDecl, rnInstDecl, rnIfaceRuleDecl )
import RnEnv
import RnMonad
import Id               ( idType, idName, globalIdDetails )
import IdInfo           ( GlobalIdDetails(..) )
import TcType           ( namesOfType )
import FieldLabel       ( fieldLabelTyCon )
import DataCon          ( dataConTyCon )
import TyCon            ( isSynTyCon, getSynTyConDefn, tyConClass_maybe, tyConName )
import Class            ( className )
import Name             ( Name {-instance NamedThing-}, nameOccName,
                          nameModule, isLocalName, NamedThing(..)
                         )
import NameEnv          ( elemNameEnv, delFromNameEnv, lookupNameEnv )
import NameSet
import Module           ( Module, ModuleEnv, 
                          moduleName, isHomeModule,
                          ModuleName, WhereFrom(..),
                          emptyModuleEnv, 
                          extendModuleEnv_C, foldModuleEnv, lookupModuleEnv,
                          elemModuleSet, extendModuleSet
                        )
import PrelInfo         ( wiredInThingEnv, hasKey, fractionalClassKey, numClassKey, 
                          integerTyConName, doubleTyConName )
import Maybes           ( maybeToBool )
import FiniteMap
import Outputable
import Bag
import Util             ( sortLt )
\end{code}


%*********************************************************
%*                                                      *
\subsection{Keeping track of what we've slurped, and version numbers}
%*                                                      *
%*********************************************************

mkImportInfo figures out what the ``usage information'' for this
moudule is; that is, what it must record in its interface file as the
things it uses.  

We produce a line for every module B below the module, A, currently being
compiled:
        import B <n> ;
to record the fact that A does import B indirectly.  This is used to decide
to look to look for B.hi rather than B.hi-boot when compiling a module that
imports A.  This line says that A imports B, but uses nothing in it.
So we'll get an early bale-out when compiling A if B's version changes.

The usage information records:

\begin{itemize}
\item   (a) anything reachable from its body code
\item   (b) any module exported with a @module Foo@
\item   (c) anything reachable from an exported item
\end{itemize}

Why (b)?  Because if @Foo@ changes then this module's export list
will change, so we must recompile this module at least as far as
making a new interface file --- but in practice that means complete
recompilation.

Why (c)?  Consider this:
\begin{verbatim}
        module A( f, g ) where  |       module B( f ) where
          import B( f )         |         f = h 3
          g = ...               |         h = ...
\end{verbatim}

Here, @B.f@ isn't used in A.  Should we nevertheless record @B.f@ in
@A@'s usages?  Our idea is that we aren't going to touch A.hi if it is
*identical* to what it was before.  If anything about @B.f@ changes
than anyone who imports @A@ should be recompiled in case they use
@B.f@ (they'll get an early exit if they don't).  So, if anything
about @B.f@ changes we'd better make sure that something in A.hi
changes, and the convenient way to do that is to record the version
number @B.f@ in A.hi in the usage list.  If B.f changes that'll force a
complete recompiation of A, which is overkill but it's the only way to 
write a new, slightly different, A.hi.

But the example is tricker.  Even if @B.f@ doesn't change at all,
@B.h@ may do so, and this change may not be reflected in @f@'s version
number.  But with -O, a module that imports A must be recompiled if
@B.h@ changes!  So A must record a dependency on @B.h@.  So we treat
the occurrence of @B.f@ in the export list *just as if* it were in the
code of A, and thereby haul in all the stuff reachable from it.

        *** Conclusion: if A mentions B.f in its export list,
            behave just as if A mentioned B.f in its source code,
            and slurp in B.f and all its transitive closure ***

[NB: If B was compiled with -O, but A isn't, we should really *still*
haul in all the unfoldings for B, in case the module that imports A *is*
compiled with -O.  I think this is the case.]

\begin{code}
mkImportInfo :: ModuleName                      -- Name of this module
             -> [ImportDecl n]                  -- The import decls
             -> RnMG [ImportVersion Name]

mkImportInfo this_mod imports
  = getIfacesRn                                 `thenRn` \ ifaces ->
    getHomeIfaceTableRn                         `thenRn` \ hit -> 
    let
        (imp_pkg_mods, imp_home_names) = iVSlurp ifaces
        pit                            = iPIT    ifaces

        import_all_mods :: [ModuleName]
                -- Modules where we imported all the names
                -- (apart from hiding some, perhaps)
        import_all_mods = [ m | ImportDecl m _ _ _ imp_list _ <- imports,
                                import_all imp_list ]
          where
           import_all (Just (False, _)) = False -- Imports are spec'd explicitly
           import_all other             = True  -- Everything is imported

        -- mv_map groups together all the things imported and used
        -- from a particular module in this package
        -- We use a finite map because we want the domain
        mv_map :: ModuleEnv [Name]
        mv_map  = foldNameSet add_mv emptyModuleEnv imp_home_names
        add_mv name mv_map = extendModuleEnv_C add_item mv_map mod [name]
                           where
                             mod = nameModule name
                             add_item names _ = name:names

        -- In our usage list we record
        --
        --      a) Specifically: Detailed version info for imports
        --         from modules in this package Gotten from iVSlurp plus
        --         import_all_mods
        --
        --      b) Everything: Just the module version for imports
        --         from modules in other packages Gotten from iVSlurp plus
        --         import_all_mods
        --
        --      c) NothingAtAll: The name only of modules, Baz, in
        --         this package that are 'below' us, but which we didn't need
        --         at all (this is needed only to decide whether to open Baz.hi
        --         or Baz.hi-boot higher up the tree).  This happens when a
        --         module, Foo, that we explicitly imported has 'import Baz' in
        --         its interface file, recording that Baz is below Foo in the
        --         module dependency hierarchy.  We want to propagate this
        --         info.  These modules are in a combination of HIT/PIT and
        --         iImpModInfo
        --
        --      d) NothingAtAll: The name only of all orphan modules
        --         we know of (this is needed so that anyone who imports us can
        --         find the orphan modules) These modules are in a combination
        --         of HIT/PIT and iImpModInfo

        import_info0 = foldModuleEnv mk_imp_info  []           pit
        import_info1 = foldModuleEnv mk_imp_info  import_info0 hit
        import_info  = not_even_opened_imports ++ import_info1

                -- Recall that iImpModInfo describes modules that have
                -- been mentioned in the import lists of interfaces we
                -- have opened, but which we have not even opened when
                -- compiling this module
        not_even_opened_imports =
          [ (mod_name, orphans, is_boot, NothingAtAll) 
          | (mod_name, (orphans, is_boot)) <- fmToList (iImpModInfo ifaces) ]

        
        mk_imp_info :: ModIface -> [ImportVersion Name] -> [ImportVersion Name]
        mk_imp_info iface so_far

          | Just ns <- lookupModuleEnv mv_map mod       -- Case (a)
          = go_for_it (Specifically mod_vers maybe_export_vers 
                                    (mk_import_items ns) rules_vers)

          | mod `elemModuleSet` imp_pkg_mods            -- Case (b)
          = go_for_it (Everything mod_vers)

          | import_all_mod                              -- Case (a) and (b); the import-all part
          = if is_home_pkg_mod then
                go_for_it (Specifically mod_vers (Just export_vers) [] rules_vers)
                -- Since the module isn't in the mv_map, presumably we
                -- didn't actually import anything at all from it
            else
                go_for_it (Everything mod_vers)
                
          | is_home_pkg_mod || has_orphans              -- Case (c) or (d)
          = go_for_it NothingAtAll

          | otherwise = so_far
          where
            go_for_it exports = (mod_name, has_orphans, mi_boot iface, exports) : so_far

            mod             = mi_module iface
            mod_name        = moduleName mod
            is_home_pkg_mod = isHomeModule mod
            version_info    = mi_version iface
            version_env     = vers_decls   version_info
            mod_vers        = vers_module  version_info
            rules_vers      = vers_rules   version_info
            export_vers     = vers_exports version_info
            import_all_mod  = mod_name `elem` import_all_mods
            has_orphans     = mi_orphan iface
            
                -- The sort is to put them into canonical order
            mk_import_items ns = [(n,v) | n <- sortLt lt_occ ns, 
                                          let v = lookupVersion version_env n
                                 ]
                         where
                           lt_occ n1 n2 = nameOccName n1 < nameOccName n2

            maybe_export_vers | import_all_mod = Just (vers_exports version_info)
                              | otherwise      = Nothing
    in
    returnRn import_info
\end{code}

%*********************************************************
%*                                                       *
\subsection{Slurping declarations}
%*                                                       *
%*********************************************************

\begin{code}
-------------------------------------------------------
slurpImpDecls source_fvs
  = traceRn (text "slurpImp" <+> fsep (map ppr (nameSetToList source_fvs))) `thenRn_`

        -- The current slurped-set records all local things
    slurpSourceRefs source_fvs  `thenRn` \ (decls, needed) ->

        -- Then get everything else
    closeDecls decls needed


-------------------------------------------------------
slurpSourceRefs :: FreeVars                     -- Variables referenced in source
                -> RnMG ([RenamedHsDecl],
                         FreeVars)              -- Un-satisfied needs
-- The declaration (and hence home module) of each gate has
-- already been loaded

slurpSourceRefs source_fvs
  = go_outer []                         -- Accumulating decls
             emptyFVs                   -- Unsatisfied needs
             emptyFVs                   -- Accumulating gates
             (nameSetToList source_fvs) -- Things whose defn hasn't been loaded yet
  where
        -- The outer loop repeatedly slurps the decls for the current gates
        -- and the instance decls 

        -- The outer loop is needed because consider
        --      instance Foo a => Baz (Maybe a) where ...
        -- It may be that Baz and Maybe are used in the source module,
        -- but not Foo; so we need to chase Foo too.
        --
        -- We also need to follow superclass refs.  In particular, 'chasing Foo' must
        -- include actually getting in Foo's class decl
        --      class Wib a => Foo a where ..
        -- so that its superclasses are discovered.  The point is that Wib is a gate too.
        -- We do this for tycons too, so that we look through type synonyms.

    go_outer decls fvs all_gates []     
        = returnRn (decls, fvs)

    go_outer decls fvs all_gates refs   -- refs are not necessarily slurped yet
        = traceRn (text "go_outer" <+> ppr refs)                `thenRn_`
          foldlRn go_inner (decls, fvs, emptyFVs) refs          `thenRn` \ (decls1, fvs1, gates1) ->
          getImportedInstDecls (all_gates `plusFV` gates1)      `thenRn` \ inst_decls ->
          rnIfaceInstDecls decls1 fvs1 gates1 inst_decls        `thenRn` \ (decls2, fvs2, gates2) ->
          go_outer decls2 fvs2 (all_gates `plusFV` gates2)
                               (nameSetToList (gates2 `minusNameSet` all_gates))
                -- Knock out the all_gates because even if we don't slurp any new
                -- decls we can get some apparently-new gates from wired-in names
                -- and we get an infinite loop

    go_inner (decls, fvs, gates) wanted_name
        = importDecl wanted_name                `thenRn` \ import_result ->
          case import_result of
            AlreadySlurped     -> returnRn (decls, fvs, gates)
            InTypeEnv ty_thing -> returnRn (decls, fvs, gates `plusFV` getWiredInGates ty_thing)
                        
            HereItIs decl -> rnIfaceTyClDecl decl               `thenRn` \ (new_decl, fvs1) ->
                             returnRn (TyClD new_decl : decls, 
                                       fvs1 `plusFV` fvs,
                                       gates `plusFV` getGates source_fvs new_decl)
\end{code}


\begin{code}
-------------------------------------------------------
-- closeDecls keeps going until the free-var set is empty
closeDecls decls needed
  | not (isEmptyFVs needed)
  = slurpDecls decls needed     `thenRn` \ (decls1, needed1) ->
    closeDecls decls1 needed1

  | otherwise
  = getImportedRules                    `thenRn` \ rule_decls ->
    case rule_decls of
        []    -> returnRn decls -- No new rules, so we are done
        other -> rnIfaceDecls rnIfaceRuleDecl rule_decls        `thenRn` \ rule_decls' ->
                 let
                        rule_fvs = plusFVs (map ruleDeclFVs rule_decls')
                 in
                 traceRn (text "closeRules" <+> ppr rule_decls' $$ fsep (map ppr (nameSetToList rule_fvs)))     `thenRn_`
                 closeDecls (map RuleD rule_decls' ++ decls) rule_fvs

                 

-------------------------------------------------------
-- Augment decls with any decls needed by needed.
-- Return also free vars of the new decls (only)
slurpDecls decls needed
  = go decls emptyFVs (nameSetToList needed) 
  where
    go decls fvs []         = returnRn (decls, fvs)
    go decls fvs (ref:refs) = slurpDecl decls fvs ref   `thenRn` \ (decls1, fvs1) ->
                              go decls1 fvs1 refs

-------------------------------------------------------
slurpDecl decls fvs wanted_name
  = importDecl wanted_name              `thenRn` \ import_result ->
    case import_result of
        -- Found a declaration... rename it
        HereItIs decl -> rnIfaceTyClDecl decl           `thenRn` \ (new_decl, fvs1) ->
                         returnRn (TyClD new_decl:decls, fvs1 `plusFV` fvs)

        -- No declaration... (wired in thing, or deferred, or already slurped)
        other -> returnRn (decls, fvs)


-------------------------------------------------------
rnIfaceDecls rn decls      = mapRn (rnIfaceDecl rn) decls
rnIfaceDecl rn (mod, decl) = initIfaceRnMS mod (rn decl)        

rnIfaceInstDecls decls fvs gates inst_decls
  = rnIfaceDecls rnInstDecl inst_decls  `thenRn` \ inst_decls' ->
    returnRn (map InstD inst_decls' ++ decls,
              fvs `plusFV` plusFVs (map instDeclFVs inst_decls'),
              gates `plusFV` plusFVs (map getInstDeclGates inst_decls'))

rnIfaceTyClDecl (mod, decl) = initIfaceRnMS mod (rnTyClDecl decl)       `thenRn` \ decl' ->
                              returnRn (decl', tyClDeclFVs decl')
\end{code}


\begin{code}
recordDeclSlurp ifaces@(Ifaces { iDecls  = (decls_map, n_slurped),
                                 iSlurp  = slurped_names, 
                                 iVSlurp = vslurp })
            avail
  = ASSERT2( not (isLocalName (availName avail)), ppr avail )
    ifaces { iDecls = (new_decls_map, n_slurped+1),
             iSlurp  = new_slurped_names, 
             iVSlurp = updateVSlurp vslurp (availName avail) }
  where
    new_decls_map     = foldl delFromNameEnv decls_map (availNames avail)
    new_slurped_names = addAvailToNameSet slurped_names avail


-- recordTypeEnvSlurp is used when we slurp something that's
-- already in the type environment, that was not slurped in an earlier compilation.
-- We record it in the iVSlurp set, because that's used to
-- generate usage information

recordTypeEnvSlurp ifaces ty_thing
  = ifaces { iVSlurp = updateVSlurp (iVSlurp ifaces) (get_main_name ty_thing) }
  where
        -- Tiresomely, we must get the "main" name for the 
        -- thing, because that's what VSlurp contains, and what
        -- is recorded in the usage information
    get_main_name (AClass cl) = className cl
    get_main_name (ATyCon tc)
        | Just clas <- tyConClass_maybe tc = get_main_name (AClass clas)
        | otherwise                        = tyConName tc
    get_main_name (AnId id)
        = case globalIdDetails id of
            DataConId     dc -> get_main_name (ATyCon (dataConTyCon dc))
            DataConWrapId dc -> get_main_name (ATyCon (dataConTyCon dc))
            RecordSelId lbl  -> get_main_name (ATyCon (fieldLabelTyCon lbl))
            other            -> idName id

updateVSlurp (imp_mods, imp_names) main_name
  | isHomeModule mod = (imp_mods,                     addOneToNameSet imp_names main_name)
  | otherwise        = (extendModuleSet imp_mods mod, imp_names)
  where
    mod = nameModule main_name
  
recordLocalSlurps new_names
  = getIfacesRn         `thenRn` \ ifaces ->
    setIfacesRn (ifaces { iSlurp  = iSlurp ifaces `unionNameSets` new_names })
\end{code}



%*********************************************************
%*                                                       *
\subsection{Extracting the `gates'}
%*                                                       *
%*********************************************************

The gating story
~~~~~~~~~~~~~~~~~
We want to avoid sucking in too many instance declarations.
An instance decl is only useful if the types and classes mentioned in
its 'head' are all available in the program being compiled.  E.g.

        instance (..) => C (T1 a) (T2 b) where ...

is only useful if C, T1 and T2 are all "available".  So we keep
instance decls that have been parsed from .hi files, but not yet
slurped in, in a pool called the 'gated instance pool'.
Each has its set of 'gates': {C, T1, T2} in the above example.

More precisely, the gates of a module are the types and classes 
that are mentioned in:

        a) the source code
        b) the type of an Id that's mentioned in the source code
           [includes constructors and selectors]
        c) the RHS of a type synonym that is a gate
        d) the superclasses of a class that is a gate
        e) the context of an instance decl that is slurped in

We slurp in an instance decl from the gated instance pool iff
        
        all its gates are either in the gates of the module, 
        or are a previously-loaded class.  

The latter constraint is because there might have been an instance
decl slurped in during an earlier compilation, like this:

        instance Foo a => Baz (Maybe a) where ...

In the module being compiled we might need (Baz (Maybe T)), where T
is defined in this module, and hence we need (Foo T).  So @Foo@ becomes
a gate.  But there's no way to 'see' that, so 

        we simply treat all previously-loaded classes as gates.

Consructors and class operations
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When we import a declaration like

        data T = T1 Wibble | T2 Wobble

we don't want to treat @Wibble@ and @Wobble@ as gates {\em unless}
@T1@, @T2@ respectively are mentioned by the user program. If only
@T@ is mentioned we want only @T@ to be a gate; that way we don't suck
in useless instance decls for (say) @Eq Wibble@, when they can't
possibly be useful.

And that's just what (b) says: we only treat T1's type as a gate if
T1 is mentioned.  getGates, which deals with decls we are slurping in,
has to be a bit careful, because a mention of T1 will slurp in T's whole
declaration.

-----------------------------
@getGates@ takes a newly imported (and renamed) decl, and the free
vars of the source program, and extracts from the decl the gate names.

\begin{code}
getGates :: FreeVars            -- Things mentioned in the source program
                                -- Used for the cunning "constructors and 
                                -- class ops" story described 10 lines above.
         -> RenamedTyClDecl
         -> FreeVars

getGates source_fvs decl 
  = get_gates (\n -> n `elemNameSet` source_fvs) decl

get_gates is_used (ForeignType {tcdName = tycon}) = unitNameSet tycon
get_gates is_used (IfaceSig    {tcdType = ty})    = extractHsTyNames ty

get_gates is_used (ClassDecl { tcdCtxt = ctxt, tcdName = cls, tcdTyVars = tvs, tcdSigs = sigs})
  = (super_cls_and_sigs `addOneToNameSet` cls) `unionNameSets` 
    implicitClassGates cls
  where
    super_cls_and_sigs = delListFromNameSet (foldr (plusFV . get) (extractHsCtxtTyNames ctxt) sigs)
                                            (hsTyVarNames tvs)
    get (ClassOpSig n _ ty _) 
        | is_used n = extractHsTyNames ty
        | otherwise = emptyFVs

get_gates is_used (TySynonym {tcdTyVars = tvs, tcdSynRhs = ty})
  = delListFromNameSet (extractHsTyNames ty) (hsTyVarNames tvs)
        -- A type synonym type constructor isn't a "gate" for instance decls

get_gates is_used (TyData {tcdCtxt = ctxt, tcdName = tycon, tcdTyVars = tvs, tcdCons = cons})
  = delListFromNameSet (foldr (plusFV . get) (extractHsCtxtTyNames ctxt) cons)
                       (hsTyVarNames tvs)
    `addOneToNameSet` tycon
  where
    get (ConDecl n _ tvs ctxt details _)
        | is_used n
                -- If the constructor is method, get fvs from all its fields
        = delListFromNameSet (get_details details `plusFV` 
                              extractHsCtxtTyNames ctxt)
                             (hsTyVarNames tvs)
    get (ConDecl n _ tvs ctxt (RecCon fields) _)
                -- Even if the constructor isn't mentioned, the fields
                -- might be, as selectors.  They can't mention existentially
                -- bound tyvars (typechecker checks for that) so no need for 
                -- the deleteListFromNameSet part
        = foldr (plusFV . get_field) emptyFVs fields
        
    get other_con = emptyFVs

    get_details (VanillaCon tys) = plusFVs (map get_bang tys)
    get_details (InfixCon t1 t2) = get_bang t1 `plusFV` get_bang t2
    get_details (RecCon fields)  = plusFVs [get_bang t | (_, t) <- fields]

    get_field (fs,t) | any is_used fs = get_bang t
                     | otherwise      = emptyFVs

    get_bang bty = extractHsTyNames (getBangType bty)

implicitClassGates :: Name -> FreeVars
implicitClassGates cls
        -- If we load class Num, add Integer to the free gates
        -- This takes account of the fact that Integer might be needed for
        -- defaulting, but we don't want to load Integer (and all its baggage)
        -- if there's no numeric stuff needed.
        -- Similarly for class Fractional and Double
        --
        -- NB: adding T to the gates will force T to be loaded
        --
        -- NB: If we load (say) Floating, we'll end up loading Fractional too,
        --     since Fractional is a superclass of Floating
  | cls `hasKey` numClassKey        = unitFV integerTyConName
  | cls `hasKey` fractionalClassKey = unitFV doubleTyConName
  | otherwise                       = emptyFVs
\end{code}

@getWiredInGates@ is just like @getGates@, but it sees a previously-loaded
thing rather than a declaration.

\begin{code}
getWiredInGates :: TyThing -> FreeVars
-- The TyThing is one that we already have in our type environment, either
--      a) because the TyCon or Id is wired in, or
--      b) from a previous compile
-- Either way, we might have instance decls in the (persistent) collection
-- of parsed-but-not-slurped instance decls that should be slurped in.
-- This might be the first module that mentions both the type and the class
-- for that instance decl, even though both the type and the class were
-- mentioned in other modules, and hence are in the type environment

getWiredInGates (AnId the_id) = namesOfType (idType the_id)
getWiredInGates (AClass cl)   = implicitClassGates (getName cl)
        -- The superclasses must also be previously
        -- loaded, and hence are automatically gates
        -- All previously-loaded classes are automatically gates
        -- See "The gating story" above
getWiredInGates (ATyCon tc)
  | isSynTyCon tc = delListFromNameSet (namesOfType ty) (map getName tyvars)
  | otherwise     = unitFV (getName tc)
  where
    (tyvars,ty)  = getSynTyConDefn tc

getInstDeclGates (InstDecl inst_ty _ _ _ _) = extractHsTyNames inst_ty
\end{code}

\begin{code}
getImportedInstDecls :: NameSet -> RnMG [(Module,RdrNameInstDecl)]
getImportedInstDecls gates
  =     -- First, load any orphan-instance modules that aren't aready loaded
        -- Orphan-instance modules are recorded in the module dependecnies
    getIfacesRn                                         `thenRn` \ ifaces ->
    let
        orphan_mods =
          [mod | (mod, (True, _)) <- fmToList (iImpModInfo ifaces)]
    in
    loadOrphanModules orphan_mods                       `thenRn_` 

        -- Now we're ready to grab the instance declarations
        -- Find the un-gated ones and return them, 
        -- removing them from the bag kept in Ifaces
    getIfacesRn                                         `thenRn` \ ifaces ->
    getTypeEnvRn                                        `thenRn` \ lookup ->
    let
        available n
          | n `elemNameSet` gates = True
          | otherwise             = case lookup n of { Just (AClass c) -> True; other -> False }
                -- See "The gating story" above for the AClass thing

        (decls, new_insts) = selectGated available (iInsts ifaces)
    in
    setIfacesRn (ifaces { iInsts = new_insts })         `thenRn_`

    traceRn (sep [text "getImportedInstDecls:", 
                  nest 4 (fsep (map ppr gate_list)),
                  text "Slurped" <+> int (length decls) <+> text "instance declarations",
                  nest 4 (vcat (map ppr_brief_inst_decl decls))])       `thenRn_`
    returnRn decls
  where
    gate_list      = nameSetToList gates

ppr_brief_inst_decl (mod, InstDecl inst_ty _ _ _ _)
  = case inst_ty of
        HsForAllTy _ _ tau -> ppr tau
        other              -> ppr inst_ty

getImportedRules :: RnMG [(Module,RdrNameRuleDecl)]
getImportedRules 
  | opt_IgnoreIfacePragmas = returnRn []
  | otherwise
  = getIfacesRn         `thenRn` \ ifaces ->
    getTypeEnvRn        `thenRn` \ lookup ->
    let
                -- Slurp rules for anything that is slurped, 
                -- either now or previously
        gates              = iSlurp ifaces      
        available n        = n `elemNameSet` gates || maybeToBool (lookup n)
        (decls, new_rules) = selectGated available (iRules ifaces)
    in
    if null decls then
        returnRn []
    else
    setIfacesRn (ifaces { iRules = new_rules })              `thenRn_`
    traceRn (sep [text "getImportedRules:", 
                  text "Slurped" <+> int (length decls) <+> text "rules"])   `thenRn_`
    returnRn decls

selectGated :: (Name->Bool) -> GatedDecls d
            -> ([(Module,d)], GatedDecls d)
selectGated available (decl_bag, n_slurped)
        -- Select only those decls whose gates are *all* available
#ifdef DEBUG
  | opt_NoPruneDecls    -- Just to try the effect of not gating at all
  = let
        decls = foldrBag (\ (_,d) ds -> d:ds) [] decl_bag       -- Grab them all
    in
    (decls, (emptyBag, n_slurped + length decls))

  | otherwise
#endif
  = case foldrBag select ([], emptyBag) decl_bag of
        (decls, new_bag) -> (decls, (new_bag, n_slurped + length decls))
  where
    select (gate_fn, decl) (yes, no)
        | gate_fn available  = (decl:yes, no)
        | otherwise          = (yes,      (gate_fn,decl) `consBag` no)
\end{code}


%*********************************************************
%*                                                      *
\subsection{Getting in a declaration}
%*                                                      *
%*********************************************************

\begin{code}
importDecl :: Name -> RnMG ImportDeclResult

data ImportDeclResult
  = AlreadySlurped
  | InTypeEnv TyThing
  | HereItIs (Module, RdrNameTyClDecl)

importDecl name
  =     -- STEP 1: Check if we've slurped it in while compiling this module
    getIfacesRn                         `thenRn` \ ifaces ->
    if name `elemNameSet` iSlurp ifaces then    
        returnRn AlreadySlurped 
    else


        -- STEP 2: Check if it's already in the type environment
    getTypeEnvRn                        `thenRn` \ lookup ->
    case lookup name of {
        Just ty_thing 
            |   name `elemNameEnv` wiredInThingEnv
            ->  -- When we find a wired-in name we must load its home
                -- module so that we find any instance decls lurking therein
                loadHomeInterface wi_doc name   `thenRn_`
                returnRn (InTypeEnv ty_thing)

            |   otherwise
            ->  -- Very important: record that we've seen it
                -- See comments with recordTypeEnvSlurp
                setIfacesRn (recordTypeEnvSlurp ifaces ty_thing)        `thenRn_`
                returnRn (InTypeEnv ty_thing) ;

        Nothing -> 

        -- STEP 3: OK, we have to slurp it in from an interface file
        --         First load the interface file
    traceRn nd_doc                      `thenRn_`
    loadHomeInterface nd_doc name       `thenRn_`
    getIfacesRn                         `thenRn` \ ifaces ->

        -- STEP 4: Get the declaration out
    let
        (decls_map, _) = iDecls ifaces
    in
    case lookupNameEnv decls_map name of
      Just (avail,_,decl) -> setIfacesRn (recordDeclSlurp ifaces avail) `thenRn_`
                             returnRn (HereItIs decl)

      Nothing -> addErrRn (getDeclErr name)     `thenRn_` 
                 returnRn AlreadySlurped
    }
  where
    wi_doc = ptext SLIT("need home module for wired in thing") <+> ppr name
    nd_doc = ptext SLIT("need decl for") <+> ppr name

\end{code}


%********************************************************
%*                                                      *
\subsection{Checking usage information}
%*                                                      *
%********************************************************

@recompileRequired@ is called from the HscMain.   It checks whether
a recompilation is required.  It needs access to the persistent state,
finder, etc, because it may have to load lots of interface files to
check their versions.

\begin{code}
type RecompileRequired = Bool
upToDate  = False       -- Recompile not required
outOfDate = True        -- Recompile required

recompileRequired :: FilePath           -- Only needed for debug msgs
                  -> ModIface           -- Old interface
                  -> RnMG RecompileRequired
recompileRequired iface_path iface
  = traceHiDiffsRn (text "Considering whether compilation is required for" <+> text iface_path <> colon)        `thenRn_`

        -- Source code unchanged and no errors yet... carry on 
    checkList [checkModUsage u | u <- mi_usages iface]

checkList :: [RnMG RecompileRequired] -> RnMG RecompileRequired
checkList []             = returnRn upToDate
checkList (check:checks) = check        `thenRn` \ recompile ->
                           if recompile then 
                                returnRn outOfDate
                           else
                                checkList checks
\end{code}
        
\begin{code}
checkModUsage :: ImportVersion Name -> RnMG RecompileRequired
-- Given the usage information extracted from the old
-- M.hi file for the module being compiled, figure out
-- whether M needs to be recompiled.

checkModUsage (mod_name, _, _, NothingAtAll)
        -- If CurrentModule.hi contains 
        --      import Foo :: ;
        -- then that simply records that Foo lies below CurrentModule in the
        -- hierarchy, but CurrentModule doesn't depend in any way on Foo.
        -- In this case we don't even want to open Foo's interface.
  = up_to_date (ptext SLIT("Nothing used from:") <+> ppr mod_name)

checkModUsage (mod_name, _, is_boot, whats_imported)
  =     -- Load the imported interface is possible
        -- We use tryLoadInterface, because failure is not an error
        -- (might just be that the old .hi file for this module is out of date)
        -- We use ImportByUser/ImportByUserSource as the 'from' flag, 
        --      a) because we need to know whether to load the .hi-boot file
        --      b) because loadInterface things matters are amiss if we 
        --         ImportBySystem an interface it knows nothing about
    let
        doc_str = sep [ptext SLIT("need version info for"), ppr mod_name]
        from    | is_boot   = ImportByUserSource
                | otherwise = ImportByUser
    in
    traceHiDiffsRn (text "Checking usages for module" <+> ppr mod_name) `thenRn_`
    tryLoadInterface doc_str mod_name from      `thenRn` \ (iface, maybe_err) ->

    case maybe_err of {
        Just err -> out_of_date (sep [ptext SLIT("Can't find version number for module"), 
                                      ppr mod_name]) ;
                -- Couldn't find or parse a module mentioned in the
                -- old interface file.  Don't complain -- it might just be that
                -- the current module doesn't need that import and it's been deleted

        Nothing -> 
    let
        new_vers      = mi_version iface
        new_decl_vers = vers_decls new_vers
    in
    case whats_imported of {    -- NothingAtAll dealt with earlier

      Everything old_mod_vers -> checkModuleVersion old_mod_vers new_vers       `thenRn` \ recompile ->
                                 if recompile then
                                        out_of_date (ptext SLIT("...and I needed the whole module"))
                                 else
                                        returnRn upToDate ;

      Specifically old_mod_vers maybe_old_export_vers old_decl_vers old_rule_vers ->

        -- CHECK MODULE
    checkModuleVersion old_mod_vers new_vers    `thenRn` \ recompile ->
    if not recompile then
        returnRn upToDate
    else
                                 
        -- CHECK EXPORT LIST
    if checkExportList maybe_old_export_vers new_vers then
        out_of_date (ptext SLIT("Export list changed"))
    else

        -- CHECK RULES
    if old_rule_vers /= vers_rules new_vers then
        out_of_date (ptext SLIT("Rules changed"))
    else

        -- CHECK ITEMS ONE BY ONE
    checkList [checkEntityUsage new_decl_vers u | u <- old_decl_vers]   `thenRn` \ recompile ->
    if recompile then
        returnRn outOfDate      -- This one failed, so just bail out now
    else
        up_to_date (ptext SLIT("...but the bits I use haven't."))

    }}

------------------------
checkModuleVersion old_mod_vers new_vers
  | vers_module new_vers == old_mod_vers
  = up_to_date (ptext SLIT("Module version unchanged"))

  | otherwise
  = out_of_date (ptext SLIT("Module version has changed"))

------------------------
checkExportList Nothing  new_vers = upToDate
checkExportList (Just v) new_vers = v /= vers_exports new_vers

------------------------
checkEntityUsage new_vers (name,old_vers)
  = case lookupNameEnv new_vers name of

        Nothing       ->        -- We used it before, but it ain't there now
                          out_of_date (sep [ptext SLIT("No longer exported:"), ppr name])

        Just new_vers   -- It's there, but is it up to date?
          | new_vers == old_vers -> traceHiDiffsRn (text "Up to date" <+> ppr name <+> parens (ppr new_vers)) `thenRn_`
                                    returnRn upToDate
          | otherwise            -> out_of_date (sep [ptext SLIT("Out of date:"), ppr name, ppr 
                                                      old_vers, ptext SLIT("->"), ppr new_vers])

up_to_date  msg = traceHiDiffsRn msg `thenRn_` returnRn upToDate
out_of_date msg = traceHiDiffsRn msg `thenRn_` returnRn outOfDate
\end{code}


%*********************************************************
%*                                                       *
\subsection{Errors}
%*                                                       *
%*********************************************************

\begin{code}
getDeclErr name
  = vcat [ptext SLIT("Failed to find interface decl for") <+> quotes (ppr name),
          ptext SLIT("from module") <+> quotes (ppr (nameModule name))
         ]
\end{code}