tcInstDecls1    -- Deal with both source-code and imported instance decls
   :: [LTyClDecl Name]          -- For deriving stuff
   -> [LInstDecl Name]          -- Source code instance decls
   -> [LDerivDecl Name]         -- Source code stand-alone deriving decls
   -> TcM (TcGblEnv,            -- The full inst env
           [InstInfo Name],     -- Source-code instance decls to process;
                                -- contains all dfuns for this module
           HsValBinds Name)     -- Supporting bindings for derived instances

tcInstDecls1 tycl_decls inst_decls deriv_decls
  = checkNoErrs $
    do {        -- Stop if addInstInfos etc discovers any errors
                -- (they recover, so that we get more than one error each
                -- round)

                -- (1) Do class and family instance declarations
       ; idx_tycons        <- mapAndRecoverM (tcFamInstDecl TopLevel) $
       	 		      filter (isFamInstDecl . unLoc) tycl_decls 
       ; local_info_tycons <- mapAndRecoverM tcLocalInstDecl1  inst_decls

       ; let { (local_info,
                at_tycons_s)   = unzip local_info_tycons
             ; at_idx_tycons   = concat at_tycons_s ++ idx_tycons
             ; implicit_things = concatMap implicitTyConThings at_idx_tycons
	     ; aux_binds       = mkRecSelBinds at_idx_tycons  }

                -- (2) Add the tycons of indexed types and their implicit
                --     tythings to the global environment
       ; tcExtendGlobalEnv (map ATyCon at_idx_tycons ++ implicit_things) $ do {


                -- Next, construct the instance environment so far, consisting
                -- of
                --   (a) local instance decls
                --   (b) local family instance decls
       ; addInsts local_info         $
         addFamInsts at_idx_tycons   $ do {

                -- (3) Compute instances from "deriving" clauses;
                -- This stuff computes a context for the derived instance
                -- decl, so it needs to know about all the instances possible
                -- NB: class instance declarations can contain derivings as
                --     part of associated data type declarations
	 failIfErrsM	-- If the addInsts stuff gave any errors, don't
			-- try the deriving stuff, because that may give
			-- more errors still
       ; (deriv_inst_info, deriv_binds, deriv_dus, deriv_tys, deriv_ty_insts) 
              <- tcDeriving tycl_decls inst_decls deriv_decls

       -- Extend the global environment also with the generated datatypes for
       -- the generic representation
       ; let all_tycons = map ATyCon (deriv_tys ++ deriv_ty_insts)
       ; gbl_env <- tcExtendGlobalEnv all_tycons $
                    tcExtendGlobalEnv (concatMap implicitTyThings all_tycons) $
                    addFamInsts deriv_ty_insts $
                    addInsts deriv_inst_info getGblEnv

       -- Check that if the module is compiled with -XSafe, there are no
       -- hand written instances of Typeable as then unsafe casts could be
       -- performed. Derivied instances are OK.
       ; dflags <- getDOpts
       ; when (safeLanguageOn dflags) $
             mapM_ (\x -> when (is_cls (iSpec x) `elem` typeableClassNames)
                               (addErrAt (getSrcSpan $ iSpec x) typInstErr))
                   local_info

       ; return ( addTcgDUs gbl_env deriv_dus,
                  deriv_inst_info ++ local_info,
                  aux_binds `plusHsValBinds` deriv_binds)
    }}}
  where
      typInstErr = ptext $ sLit $ "Can't create hand written instances of Typeable in Safe"
                                ++ " Haskell! Can only derive them"

addInsts :: [InstInfo Name] -> TcM a -> TcM a
addInsts infos thing_inside
  = tcExtendLocalInstEnv (map iSpec infos) thing_inside

addFamInsts :: [TyCon] -> TcM a -> TcM a
addFamInsts tycons thing_inside
  = tcExtendLocalFamInstEnv (map mkLocalFamInst tycons) thing_inside

tcLocalInstDecl1 :: LInstDecl Name
                 -> TcM (InstInfo Name, [TyCon])
        -- A source-file instance declaration
        -- Type-check all the stuff before the "where"
        --
        -- We check for respectable instance type, and context
tcLocalInstDecl1 (L loc (InstDecl poly_ty binds uprags ats))
  = setSrcSpan loc		        $
    addErrCtxt (instDeclCtxt1 poly_ty)  $

    do  { is_boot <- tcIsHsBoot
        ; checkTc (not is_boot || (isEmptyLHsBinds binds && null uprags))
                  badBootDeclErr

        ; (tyvars, theta, clas, inst_tys) <- tcHsInstHead poly_ty
        ; checkValidInstance poly_ty tyvars theta clas inst_tys

        -- Next, process any associated types.
        ; idx_tycons <- recoverM (return []) $
	  	     do { idx_tycons <- checkNoErrs $ 
                                        mapAndRecoverM (tcFamInstDecl NotTopLevel) ats
		     	; checkValidAndMissingATs clas (tyvars, inst_tys)
                          			  (zip ats idx_tycons)
			; return idx_tycons }

        -- Finally, construct the Core representation of the instance.
        -- (This no longer includes the associated types.)
        ; dfun_name <- newDFunName clas inst_tys (getLoc poly_ty)
		-- Dfun location is that of instance *header*
        ; overlap_flag <- getOverlapFlag
        ; let (eq_theta,dict_theta) = partition isEqPred theta
              theta'         = eq_theta ++ dict_theta
              dfun           = mkDictFunId dfun_name tyvars theta' clas inst_tys
              ispec          = mkLocalInstance dfun overlap_flag

        ; return (InstInfo { iSpec  = ispec, iBinds = VanillaInst binds uprags False },
                  idx_tycons)
        }
  where
    -- We pass in the source form and the type checked form of the ATs.  We
    -- really need the source form only to be able to produce more informative
    -- error messages.
    checkValidAndMissingATs :: Class
                            -> ([TyVar], [TcType])     -- instance types
                            -> [(LTyClDecl Name,       -- source form of AT
                                 TyCon)]    	       -- Core form of AT
                            -> TcM ()
    checkValidAndMissingATs clas inst_tys ats
      = do { -- Issue a warning for each class AT that is not defined in this
             -- instance.
           ; let class_ats   = map tyConName (classATs clas)
                 defined_ats = listToNameSet . map (tcdName.unLoc.fst)  $ ats
                 omitted     = filterOut (`elemNameSet` defined_ats) class_ats
           ; warn <- woptM Opt_WarnMissingMethods
           ; mapM_ (warnTc warn . omittedATWarn) omitted

             -- Ensure that all AT indexes that correspond to class parameters
             -- coincide with the types in the instance head.  All remaining
             -- AT arguments must be variables.  Also raise an error for any
             -- type instances that are not associated with this class.
           ; mapM_ (checkIndexes clas inst_tys) ats
           }

    checkIndexes clas inst_tys (hsAT, tycon)
-- !!!TODO: check that this does the Right Thing for indexed synonyms, too!
      = checkIndexes' clas inst_tys hsAT
                      (tyConTyVars tycon,
                       snd . fromJust . tyConFamInst_maybe $ tycon)

    checkIndexes' clas (instTvs, instTys) hsAT (atTvs, atTys)
      = let atName = tcdName . unLoc $ hsAT
        in
        setSrcSpan (getLoc hsAT)       $
        addErrCtxt (atInstCtxt atName) $
        case find ((atName ==) . tyConName) (classATs clas) of
          Nothing     -> addErrTc $ badATErr clas atName  -- not in this class
          Just atycon ->
                -- The following is tricky!  We need to deal with three
                -- complications: (1) The AT possibly only uses a subset of
                -- the class parameters as indexes and those it uses may be in
                -- a different order; (2) the AT may have extra arguments,
                -- which must be type variables; and (3) variables in AT and
                -- instance head will be different `Name's even if their
                -- source lexemes are identical.
		--
		-- e.g.    class C a b c where 
		-- 	     data D b a :: * -> *           -- NB (1) b a, omits c
		-- 	   instance C [x] Bool Char where 
		--	     data D Bool [x] v = MkD x [v]  -- NB (2) v
		--	     	  -- NB (3) the x in 'instance C...' have differnt
		--		  --        Names to x's in 'data D...'
                --
                -- Re (1), `poss' contains a permutation vector to extract the
                -- class parameters in the right order.
                --
                -- Re (2), we wrap the (permuted) class parameters in a Maybe
                -- type and use Nothing for any extra AT arguments.  (First
                -- equation of `checkIndex' below.)
                --
                -- Re (3), we replace any type variable in the AT parameters
                -- that has the same source lexeme as some variable in the
                -- instance types with the instance type variable sharing its
                -- source lexeme.
                --
                let poss :: [Int]
                    -- For *associated* type families, gives the position
                    -- of that 'TyVar' in the class argument list (0-indexed)
	   	    -- e.g.  class C a b c where { type F c a :: *->* }
           	    --       Then we get Just [2,0]
	            poss = catMaybes [ tv `elemIndex` classTyVars clas 
                                     | tv <- tyConTyVars atycon]
                       -- We will get Nothings for the "extra" type 
                       -- variables in an associated data type
                       -- e.g. class C a where { data D a :: *->* }
                       -- here D gets arity 2 and has two tyvars

                    relevantInstTys = map (instTys !!) poss
                    instArgs        = map Just relevantInstTys ++
                                      repeat Nothing  -- extra arguments
                    renaming        = substSameTyVar atTvs instTvs
                in
                zipWithM_ checkIndex (substTys renaming atTys) instArgs

    checkIndex ty Nothing
      | isTyVarTy ty         = return ()
      | otherwise            = addErrTc $ mustBeVarArgErr ty
    checkIndex ty (Just instTy)
      | ty `eqType` instTy = return ()
      | otherwise          = addErrTc $ wrongATArgErr ty instTy

    listToNameSet = addListToNameSet emptyNameSet

    substSameTyVar []       _            = emptyTvSubst
    substSameTyVar (tv:tvs) replacingTvs =
      let replacement = case find (tv `sameLexeme`) replacingTvs of
                        Nothing  -> mkTyVarTy tv
                        Just rtv -> mkTyVarTy rtv
          --
          tv1 `sameLexeme` tv2 =
            nameOccName (tyVarName tv1) == nameOccName (tyVarName tv2)
      in
      TcType.extendTvSubst (substSameTyVar tvs replacingTvs) tv replacement

tcFamInstDecl :: TopLevelFlag -> LTyClDecl Name -> TcM TyCon
tcFamInstDecl top_lvl (L loc decl)
  =	-- Prime error recovery, set source location
    setSrcSpan loc				$
    tcAddDeclCtxt decl				$
    do { -- type family instances require -XTypeFamilies
	 -- and can't (currently) be in an hs-boot file
       ; type_families <- xoptM Opt_TypeFamilies
       ; is_boot  <- tcIsHsBoot	  -- Are we compiling an hs-boot file?
       ; checkTc type_families $ badFamInstDecl (tcdLName decl)
       ; checkTc (not is_boot) $ badBootFamInstDeclErr

	 -- Perform kind and type checking
       ; tc <- tcFamInstDecl1 decl
       ; checkValidTyCon tc	-- Remember to check validity;
				-- no recursion to worry about here

       -- Check that toplevel type instances are not for associated types.
       ; when (isTopLevel top_lvl && isAssocFamily tc)
              (addErr $ assocInClassErr (tcdName decl))

       ; return tc }

isAssocFamily :: TyCon -> Bool	-- Is an assocaited type
isAssocFamily tycon
  = case tyConFamInst_maybe tycon of
          Nothing       -> panic "isAssocFamily: no family?!?"
          Just (fam, _) -> isTyConAssoc fam

assocInClassErr :: Name -> SDoc
assocInClassErr name
 = ptext (sLit "Associated type") <+> quotes (ppr name) <+>
   ptext (sLit "must be inside a class instance")



tcFamInstDecl1 :: TyClDecl Name -> TcM TyCon

  -- "type instance"
tcFamInstDecl1 (decl@TySynonym {tcdLName = L loc tc_name})
  = kcIdxTyPats decl $ \k_tvs k_typats resKind family ->
    do { -- check that the family declaration is for a synonym
         checkTc (isFamilyTyCon family) (notFamily family)
       ; checkTc (isSynTyCon family) (wrongKindOfFamily family)

       ; -- (1) kind check the right-hand side of the type equation
       ; k_rhs <- kcCheckLHsType (tcdSynRhs decl) (EK resKind EkUnk)
       	       	  -- ToDo: the ExpKind could be better

         -- we need the exact same number of type parameters as the family
         -- declaration 
       ; let famArity = tyConArity family
       ; checkTc (length k_typats == famArity) $ 
           wrongNumberOfParmsErr famArity

         -- (2) type check type equation
       ; tcTyVarBndrs k_tvs $ \t_tvs -> do {  -- turn kinded into proper tyvars
       ; t_typats <- mapM tcHsKindedType k_typats
       ; t_rhs    <- tcHsKindedType k_rhs

         -- (3) check the well-formedness of the instance
       ; checkValidTypeInst t_typats t_rhs

         -- (4) construct representation tycon
       ; rep_tc_name <- newFamInstTyConName tc_name t_typats loc
       ; buildSynTyCon rep_tc_name t_tvs (SynonymTyCon t_rhs) 
                       (typeKind t_rhs) 
                       NoParentTyCon (Just (family, t_typats))
       }}

  -- "newtype instance" and "data instance"
tcFamInstDecl1 (decl@TyData {tcdND = new_or_data, tcdLName = L loc tc_name,
			     tcdCons = cons})
  = kcIdxTyPats decl $ \k_tvs k_typats resKind fam_tycon ->
    do { -- check that the family declaration is for the right kind
         checkTc (isFamilyTyCon fam_tycon) (notFamily fam_tycon)
       ; checkTc (isAlgTyCon fam_tycon) (wrongKindOfFamily fam_tycon)

       ; -- (1) kind check the data declaration as usual
       ; k_decl <- kcDataDecl decl k_tvs
       ; let k_ctxt = tcdCtxt k_decl
	     k_cons = tcdCons k_decl

         -- result kind must be '*' (otherwise, we have too few patterns)
       ; checkTc (isLiftedTypeKind resKind) $ tooFewParmsErr (tyConArity fam_tycon)

         -- (2) type check indexed data type declaration
       ; tcTyVarBndrs k_tvs $ \t_tvs -> do {  -- turn kinded into proper tyvars

         -- kind check the type indexes and the context
       ; t_typats     <- mapM tcHsKindedType k_typats
       ; stupid_theta <- tcHsKindedContext k_ctxt

         -- (3) Check that
         --     (a) left-hand side contains no type family applications
         --         (vanilla synonyms are fine, though, and we checked for
         --         foralls earlier)
       ; mapM_ checkTyFamFreeness t_typats

       ; dataDeclChecks tc_name new_or_data stupid_theta k_cons

         -- (4) construct representation tycon
       ; rep_tc_name <- newFamInstTyConName tc_name t_typats loc
       ; let ex_ok = True	-- Existentials ok for type families!
       ; fixM (\ rep_tycon -> do 
	     { let orig_res_ty = mkTyConApp fam_tycon t_typats
	     ; data_cons <- tcConDecls ex_ok rep_tycon
				       (t_tvs, orig_res_ty) k_cons
	     ; tc_rhs <-
		 case new_or_data of
		   DataType -> return (mkDataTyConRhs data_cons)
		   NewType  -> ASSERT( not (null data_cons) )
			       mkNewTyConRhs rep_tc_name rep_tycon (head data_cons)
	     ; buildAlgTyCon rep_tc_name t_tvs stupid_theta tc_rhs Recursive
			     h98_syntax NoParentTyCon (Just (fam_tycon, t_typats))
                 -- We always assume that indexed types are recursive.  Why?
                 -- (1) Due to their open nature, we can never be sure that a
                 -- further instance might not introduce a new recursive
                 -- dependency.  (2) They are always valid loop breakers as
                 -- they involve a coercion.
	     })
       }}
       where
	 h98_syntax = case cons of 	-- All constructors have same shape
			L _ (ConDecl { con_res = ResTyGADT _ }) : _ -> False
			_ -> True

tcFamInstDecl1 d = pprPanic "tcFamInstDecl1" (ppr d)

-- Kind checking of indexed types
-- -

-- Kind check type patterns and kind annotate the embedded type variables.
--
-- * Here we check that a type instance matches its kind signature, but we do
--   not check whether there is a pattern for each type index; the latter
--   check is only required for type synonym instances.

kcIdxTyPats :: TyClDecl Name
	    -> ([LHsTyVarBndr Name] -> [LHsType Name] -> Kind -> TyCon -> TcM a)
	       -- ^^kinded tvs         ^^kinded ty pats  ^^res kind
	    -> TcM a
kcIdxTyPats decl thing_inside
  = kcHsTyVars (tcdTyVars decl) $ \tvs -> 
    do { let tc_name = tcdLName decl
       ; fam_tycon <- tcLookupLocatedTyCon tc_name
       ; let { (kinds, resKind) = splitKindFunTys (tyConKind fam_tycon)
	     ; hs_typats	= fromJust $ tcdTyPats decl }

         -- we may not have more parameters than the kind indicates
       ; checkTc (length kinds >= length hs_typats) $
	   tooManyParmsErr (tcdLName decl)

         -- type functions can have a higher-kinded result
       ; let resultKind = mkArrowKinds (drop (length hs_typats) kinds) resKind
       ; typats <- zipWithM kcCheckLHsType hs_typats 
       	 	   	    [ EK kind (EkArg (ppr tc_name) n) 
                            | (kind,n) <- kinds `zip` [1..]]
       ; thing_inside tvs typats resultKind fam_tycon
       }

tcInstDecls2 :: [LTyClDecl Name] -> [InstInfo Name]
             -> TcM (LHsBinds Id)
-- (a) From each class declaration,
--      generate any default-method bindings
-- (b) From each instance decl
--      generate the dfun binding

tcInstDecls2 tycl_decls inst_decls
  = do  { -- (a) Default methods from class decls
          let class_decls = filter (isClassDecl . unLoc) tycl_decls
        ; dm_binds_s <- mapM tcClassDecl2 class_decls
        ; let dm_binds = unionManyBags dm_binds_s
                                    
          -- (b) instance declarations
	; let dm_ids = collectHsBindsBinders dm_binds
	      -- Add the default method Ids (again)
	      -- See Note [Default methods and instances]
        ; inst_binds_s <- tcExtendIdEnv dm_ids $
                          mapM tcInstDecl2 inst_decls

          -- Done
        ; return (dm_binds `unionBags` unionManyBags inst_binds_s) }

tcInstDecl2 :: InstInfo Name -> TcM (LHsBinds Id)
            -- Returns a binding for the dfun
tcInstDecl2 (InstInfo { iSpec = ispec, iBinds = ibinds })
  = recoverM (return emptyLHsBinds)             $
    setSrcSpan loc                              $
    addErrCtxt (instDeclCtxt2 (idType dfun_id)) $ 
    do {  -- Instantiate the instance decl with skolem constants
       ; (inst_tyvars, dfun_theta, inst_head) <- tcSkolDFunType (idType dfun_id)
                     -- We instantiate the dfun_id with superSkolems.
                     -- See Note [Subtle interaction of recursion and overlap]
                     -- and Note [Binding when looking up instances]
       ; let (clas, inst_tys) = tcSplitDFunHead inst_head
             (class_tyvars, sc_theta, sc_sels, op_items) = classBigSig clas
             sc_theta' = substTheta (zipOpenTvSubst class_tyvars inst_tys) sc_theta
       ; dfun_ev_vars <- newEvVars dfun_theta

       ; (sc_args, sc_binds)
             <- mapAndUnzipM (tcSuperClass inst_tyvars dfun_ev_vars) 
                              (sc_sels `zip` sc_theta')

       -- Deal with 'SPECIALISE instance' pragmas
       -- See Note [SPECIALISE instance pragmas]
       ; spec_info@(spec_inst_prags,_) <- tcSpecInstPrags dfun_id ibinds

        -- Typecheck the methods
       ; (meth_ids, meth_binds) 
           <- tcExtendTyVarEnv inst_tyvars $
                -- The inst_tyvars scope over the 'where' part
                -- Those tyvars are inside the dfun_id's type, which is a bit
                -- bizarre, but OK so long as you realise it!
              tcInstanceMethods dfun_id clas inst_tyvars dfun_ev_vars
                                inst_tys spec_info
                                op_items ibinds

       -- Create the result bindings
       ; self_dict <- newEvVar (ClassP clas inst_tys)
       ; let class_tc      = classTyCon clas
             [dict_constr] = tyConDataCons class_tc
             dict_bind     = mkVarBind self_dict (L loc con_app_args)

                     -- We don't produce a binding for the dict_constr; instead we
                     -- rely on the simplifier to unfold this saturated application
                     -- We do this rather than generate an HsCon directly, because
                     -- it means that the special cases (e.g. dictionary with only one
                     -- member) are dealt with by the common MkId.mkDataConWrapId 
		     -- code rather than needing to be repeated here.
		     --    con_app_tys  = MkD ty1 ty2
		     --    con_app_scs  = MkD ty1 ty2 sc1 sc2
		     --    con_app_args = MkD ty1 ty2 sc1 sc2 op1 op2
             con_app_tys  = wrapId (mkWpTyApps inst_tys)
                                   (dataConWrapId dict_constr)
             con_app_scs  = mkHsWrap (mkWpEvApps (map mk_sc_ev_term sc_args)) con_app_tys
             con_app_args = foldl mk_app con_app_scs $
                            map (wrapId arg_wrapper) meth_ids

             mk_app :: HsExpr Id -> HsExpr Id -> HsExpr Id
             mk_app fun arg = HsApp (L loc fun) (L loc arg)

	     mk_sc_ev_term :: EvVar -> EvTerm
             mk_sc_ev_term sc 
               | null inst_tv_tys
               , null dfun_ev_vars = evVarTerm sc
               | otherwise         = EvDFunApp sc inst_tv_tys dfun_ev_vars

	     inst_tv_tys    = mkTyVarTys inst_tyvars
             arg_wrapper = mkWpEvVarApps dfun_ev_vars <.> mkWpTyApps inst_tv_tys

	        -- Do not inline the dfun; instead give it a magic DFunFunfolding
	        -- See Note [ClassOp/DFun selection]
		-- See also note [Single-method classes]
             dfun_id_w_fun
                | isNewTyCon class_tc
                = dfun_id `setInlinePragma` alwaysInlinePragma { inl_sat = Just 0 }
                | otherwise
                = dfun_id `setIdUnfolding`  mkDFunUnfolding dfun_ty dfun_args
                          `setInlinePragma` dfunInlinePragma

             dfun_args :: [CoreExpr]
             dfun_args = map varToCoreExpr sc_args ++
                         map Var           meth_ids

             main_bind = AbsBinds { abs_tvs = inst_tyvars
                                  , abs_ev_vars = dfun_ev_vars
                                  , abs_exports = [(inst_tyvars, dfun_id_w_fun, self_dict,
                                                    SpecPrags spec_inst_prags)]
                                  , abs_ev_binds = emptyTcEvBinds
                                  , abs_binds = unitBag dict_bind }

       ; return (unitBag (L loc main_bind) `unionBags`
                 listToBag meth_binds      `unionBags`
                 unionManyBags sc_binds)
       }
 where
   dfun_ty   = idType dfun_id
   dfun_id   = instanceDFunId ispec
   loc       = getSrcSpan dfun_id

------------------------------
tcSuperClass :: [TcTyVar] -> [EvVar] 
	     -> (Id, PredType) 
             -> TcM (TcId, LHsBinds TcId)

-- Build a top level decl like
--	sc_op = /\a \d. let sc = ... in
--			sc
-- and return sc_op, that binding

tcSuperClass tyvars ev_vars (sc_sel, sc_pred)
  = do { (ev_binds, sc_dict)
             <- newImplication InstSkol tyvars ev_vars $
                emitWanted ScOrigin sc_pred

       ; uniq <- newUnique
       ; let sc_op_ty   = mkForAllTys tyvars $ mkPiTypes ev_vars (varType sc_dict)
	     sc_op_name = mkDerivedInternalName mkClassOpAuxOcc uniq
						(getName sc_sel)
	     sc_op_id   = mkLocalId sc_op_name sc_op_ty
	     sc_op_bind = mkVarBind sc_op_id (L noSrcSpan $ wrapId sc_wrapper sc_dict)
             sc_wrapper = mkWpTyLams tyvars
                          <.> mkWpLams ev_vars
			  <.> mkWpLet ev_binds

       ; return (sc_op_id, unitBag sc_op_bind) }

------------------------------
tcSpecInstPrags :: DFunId -> InstBindings Name
                -> TcM ([Located TcSpecPrag], PragFun)
tcSpecInstPrags _ (NewTypeDerived {})
  = return ([], \_ -> [])
tcSpecInstPrags dfun_id (VanillaInst binds uprags _)
  = do { spec_inst_prags <- mapM (wrapLocM (tcSpecInst dfun_id)) $
                            filter isSpecInstLSig uprags
	     -- The filter removes the pragmas for methods
       ; return (spec_inst_prags, mkPragFun uprags binds) }

tcSpecInst :: Id -> Sig Name -> TcM TcSpecPrag
tcSpecInst dfun_id prag@(SpecInstSig hs_ty) 
  = addErrCtxt (spec_ctxt prag) $
    do  { let name = idName dfun_id
        ; (tyvars, theta, clas, tys) <- tcHsInstHead hs_ty
        ; let spec_dfun_ty = mkDictFunTy tyvars theta clas tys

        ; co_fn <- tcSubType (SpecPragOrigin name) SpecInstCtxt
                             (idType dfun_id) spec_dfun_ty
        ; return (SpecPrag dfun_id co_fn defaultInlinePragma) }
  where
    spec_ctxt prag = hang (ptext (sLit "In the SPECIALISE pragma")) 2 (ppr prag)

tcSpecInst _  _ = panic "tcSpecInst"

tcInstanceMethods :: DFunId -> Class -> [TcTyVar]
                  -> [EvVar]
	 	  -> [TcType]
                  -> ([Located TcSpecPrag], PragFun)
	  	  -> [(Id, DefMeth)]
                  -> InstBindings Name 
          	  -> TcM ([Id], [LHsBind Id])
	-- The returned inst_meth_ids all have types starting
	--	forall tvs. theta => ...
tcInstanceMethods dfun_id clas tyvars dfun_ev_vars inst_tys 
                  (spec_inst_prags, prag_fn)
                  op_items (VanillaInst binds _ standalone_deriv)
  = mapAndUnzipM tc_item op_items
  where
    ----------------------
    tc_item :: (Id, DefMeth) -> TcM (Id, LHsBind Id)
    tc_item (sel_id, dm_info)
      = case findMethodBind (idName sel_id) binds of
  	    Just user_bind -> tc_body sel_id standalone_deriv user_bind
  	    Nothing	   -> tc_default sel_id dm_info

    ----------------------
    tc_body :: Id -> Bool -> LHsBind Name -> TcM (TcId, LHsBind Id)
    tc_body sel_id generated_code rn_bind 
      = add_meth_ctxt sel_id generated_code rn_bind $
        do { (meth_id, local_meth_id) <- mkMethIds clas tyvars dfun_ev_vars 
                                                   inst_tys sel_id
           ; let prags = prag_fn (idName sel_id)
           ; meth_id1 <- addInlinePrags meth_id prags
           ; spec_prags <- tcSpecPrags meth_id1 prags
           ; bind <- tcInstanceMethodBody InstSkol
                          tyvars dfun_ev_vars
                          meth_id1 local_meth_id meth_sig_fn 
                          (mk_meth_spec_prags meth_id1 spec_prags)
                          rn_bind 
           ; return (meth_id1, bind) }

    ----------------------
    tc_default :: Id -> DefMeth -> TcM (TcId, LHsBind Id)

    tc_default sel_id (GenDefMeth dm_name)
      = do { meth_bind <- mkGenericDefMethBind clas inst_tys sel_id dm_name
           ; tc_body sel_id False {- Not generated code? -} meth_bind }

    tc_default sel_id NoDefMeth	    -- No default method at all
      = do { warnMissingMethod sel_id
    	   ; (meth_id, _) <- mkMethIds clas tyvars dfun_ev_vars 
                                         inst_tys sel_id
           ; return (meth_id, mkVarBind meth_id $ 
                              mkLHsWrap lam_wrapper error_rhs) }
      where
    	error_rhs    = L loc $ HsApp error_fun error_msg
    	error_fun    = L loc $ wrapId (WpTyApp meth_tau) nO_METHOD_BINDING_ERROR_ID
    	error_msg    = L loc (HsLit (HsStringPrim (mkFastString error_string)))
    	meth_tau     = funResultTy (applyTys (idType sel_id) inst_tys)
    	error_string = showSDoc (hcat [ppr loc, text "|", ppr sel_id ])
        lam_wrapper  = mkWpTyLams tyvars <.> mkWpLams dfun_ev_vars

    tc_default sel_id (DefMeth dm_name)	-- A polymorphic default method
      = do {   -- Build the typechecked version directly, 
    		 -- without calling typecheck_method; 
    		 -- see Note [Default methods in instances]
                 -- Generate   /\as.\ds. let self = df as ds
                 --                      in $dm inst_tys self
    		 -- The 'let' is necessary only because HsSyn doesn't allow
    		 -- you to apply a function to a dictionary *expression*.

           ; self_dict <- newEvVar (ClassP clas inst_tys)
           ; let self_ev_bind = EvBind self_dict $
                                EvDFunApp dfun_id (mkTyVarTys tyvars) dfun_ev_vars

           ; (meth_id, local_meth_id) <- mkMethIds clas tyvars dfun_ev_vars 
                                                   inst_tys sel_id
           ; dm_id <- tcLookupId dm_name
           ; let dm_inline_prag = idInlinePragma dm_id
                 rhs = HsWrap (mkWpEvVarApps [self_dict] <.> mkWpTyApps inst_tys) $
    		         HsVar dm_id 

    	         meth_bind = mkVarBind local_meth_id (L loc rhs)
                 meth_id1 = meth_id `setInlinePragma` dm_inline_prag
    		   	-- Copy the inline pragma (if any) from the default
    			-- method to this version. Note [INLINE and default methods]
    			    
                 bind = AbsBinds { abs_tvs = tyvars, abs_ev_vars = dfun_ev_vars
                                 , abs_exports = [( tyvars, meth_id1, local_meth_id
                                                  , mk_meth_spec_prags meth_id1 [])]
                                 , abs_ev_binds = EvBinds (unitBag self_ev_bind)
                                 , abs_binds    = unitBag meth_bind }
    	     -- Default methods in an instance declaration can't have their own 
    	     -- INLINE or SPECIALISE pragmas. It'd be possible to allow them, but
    	     -- currently they are rejected with 
    	     --		  "INLINE pragma lacks an accompanying binding"

           ; return (meth_id1, L loc bind) } 

    ----------------------
    mk_meth_spec_prags :: Id -> [LTcSpecPrag] -> TcSpecPrags
	-- Adapt the SPECIALISE pragmas to work for this method Id
        -- There are two sources: 
        --   * spec_inst_prags: {-# SPECIALISE instance :: <blah> #-}
        --     These ones have the dfun inside, but [perhaps surprisingly] 
        --     the correct wrapper
        --   * spec_prags_for_me: {-# SPECIALISE op :: <blah> #-}
    mk_meth_spec_prags meth_id spec_prags_for_me
      = SpecPrags (spec_prags_for_me ++ 
                   [ L loc (SpecPrag meth_id wrap inl)
        	   | L loc (SpecPrag _ wrap inl) <- spec_inst_prags])
   
    loc = getSrcSpan dfun_id
    meth_sig_fn _ = Just ([],loc)	-- The 'Just' says "yes, there's a type sig"
	-- But there are no scoped type variables from local_method_id
	-- Only the ones from the instance decl itself, which are already
	-- in scope.  Example:
	--	class C a where { op :: forall b. Eq b => ... }
	-- 	instance C [c] where { op = <rhs> }
	-- In <rhs>, 'c' is scope but 'b' is not!

        -- For instance decls that come from standalone deriving clauses
	-- we want to print out the full source code if there's an error
	-- because otherwise the user won't see the code at all
    add_meth_ctxt sel_id generated_code rn_bind thing 
      | generated_code = addLandmarkErrCtxt (derivBindCtxt sel_id clas inst_tys rn_bind) thing
      | otherwise      = thing


tcInstanceMethods dfun_id clas tyvars dfun_ev_vars inst_tys 
                  _ op_items (NewTypeDerived coi _)

-- Running example:
--   class Show b => Foo a b where
--     op :: a -> b -> b
--   newtype N a = MkN (Tree [a]) 
--   deriving instance (Show p, Foo Int p) => Foo Int (N p)
--		 -- NB: standalone deriving clause means
--		 --     that the contex is user-specified
-- Hence op :: forall a b. Foo a b => a -> b -> b
--
-- We're going to make an instance like
--   instance (Show p, Foo Int p) => Foo Int (N p)
--      op = $copT
--
--   $copT :: forall p. (Show p, Foo Int p) => Int -> N p -> N p
--   $copT p (d1:Show p) (d2:Foo Int p) 
--     = op Int (Tree [p]) rep_d |> op_co
--     where 
--       rep_d :: Foo Int (Tree [p]) = ...d1...d2...
--       op_co :: (Int -> Tree [p] -> Tree [p]) ~ (Int -> T p -> T p)
-- We get op_co by substituting [Int/a] and [co/b] in type for op
-- where co : [p] ~ T p
--
-- Notice that the dictionary bindings "..d1..d2.." must be generated
-- by the constraint solver, since the <context> may be
-- user-specified.

  = do { rep_d_stuff <- checkConstraints InstSkol tyvars dfun_ev_vars $
                        emitWanted ScOrigin rep_pred
                         
       ; mapAndUnzipM (tc_item rep_d_stuff) op_items }
  where
     loc = getSrcSpan dfun_id

     inst_tvs = fst (tcSplitForAllTys (idType dfun_id))
     Just (init_inst_tys, _) = snocView inst_tys
     rep_ty   = pFst (coercionKind co)  -- [p]
     rep_pred = mkClassPred clas (init_inst_tys ++ [rep_ty])

     -- co : [p] ~ T p
     co = substCoWithTys (mkInScopeSet (mkVarSet tyvars))
                         inst_tvs (mkTyVarTys tyvars) $
          mkSymCo coi

     ----------------
     tc_item :: (TcEvBinds, EvVar) -> (Id, DefMeth) -> TcM (TcId, LHsBind TcId)
     tc_item (rep_ev_binds, rep_d) (sel_id, _)
       = do { (meth_id, local_meth_id) <- mkMethIds clas tyvars dfun_ev_vars 
                                                    inst_tys sel_id

            ; let meth_rhs  = wrapId (mk_op_wrapper sel_id rep_d) sel_id
                  meth_bind = mkVarBind local_meth_id (L loc meth_rhs)
	          bind = AbsBinds { abs_tvs = tyvars, abs_ev_vars = dfun_ev_vars
                                   , abs_exports = [(tyvars, meth_id, 
                                                     local_meth_id, noSpecPrags)]
				   , abs_ev_binds = rep_ev_binds
                                   , abs_binds = unitBag $ meth_bind }

            ; return (meth_id, L loc bind) }

     ----------------
     mk_op_wrapper :: Id -> EvVar -> HsWrapper
     mk_op_wrapper sel_id rep_d 
       = WpCast (liftCoSubstWith sel_tvs (map mkReflCo init_inst_tys ++ [co])
                               local_meth_ty)
         <.> WpEvApp (EvId rep_d)
         <.> mkWpTyApps (init_inst_tys ++ [rep_ty]) 
       where
         (sel_tvs, sel_rho) = tcSplitForAllTys (idType sel_id)
         (_, local_meth_ty) = tcSplitPredFunTy_maybe sel_rho
                              `orElse` pprPanic "tcInstanceMethods" (ppr sel_id)

----------------------
mkMethIds :: Class -> [TcTyVar] -> [EvVar] -> [TcType] -> Id -> TcM (TcId, TcId)
mkMethIds clas tyvars dfun_ev_vars inst_tys sel_id
  = do  { uniq <- newUnique
  	; let meth_name = mkDerivedInternalName mkClassOpAuxOcc uniq sel_name
  	; local_meth_name <- newLocalName sel_name
  		  -- Base the local_meth_name on the selector name, becuase
  		  -- type errors from tcInstanceMethodBody come from here

  	; let meth_id       = mkLocalId meth_name meth_ty
  	      local_meth_id = mkLocalId local_meth_name local_meth_ty
        ; return (meth_id, local_meth_id) }
  where
    local_meth_ty = instantiateMethod clas sel_id inst_tys
    meth_ty = mkForAllTys tyvars $ mkPiTypes dfun_ev_vars local_meth_ty
    sel_name = idName sel_id

----------------------
wrapId :: HsWrapper -> id -> HsExpr id
wrapId wrapper id = mkHsWrap wrapper (HsVar id)

derivBindCtxt :: Id -> Class -> [Type ] -> LHsBind Name -> SDoc
derivBindCtxt sel_id clas tys _bind
   = vcat [ ptext (sLit "When typechecking the code for ") <+> quotes (ppr sel_id)
          , nest 2 (ptext (sLit "in a standalone derived instance for")
	  	    <+> quotes (pprClassPred clas tys) <> colon)
          , nest 2 $ ptext (sLit "To see the code I am typechecking, use -ddump-deriv") ]

-- Too voluminous
--	  , nest 2 $ pprSetDepth AllTheWay $ ppr bind ]

warnMissingMethod :: Id -> TcM ()
warnMissingMethod sel_id
  = do { warn <- woptM Opt_WarnMissingMethods		
       ; warnTc (warn  -- Warn only if -fwarn-missing-methods
                 && not (startsWithUnderscore (getOccName sel_id)))
					-- Don't warn about _foo methods
		(ptext (sLit "No explicit method nor default method for")
                 <+> quotes (ppr sel_id)) }

instDeclCtxt1 :: LHsType Name -> SDoc
instDeclCtxt1 hs_inst_ty
  = inst_decl_ctxt (case unLoc hs_inst_ty of
                        HsForAllTy _ _ _ (L _ (HsPredTy pred)) -> ppr pred
                        HsPredTy pred                    -> ppr pred
                        _                                -> ppr hs_inst_ty)     -- Don't expect this
instDeclCtxt2 :: Type -> SDoc
instDeclCtxt2 dfun_ty
  = inst_decl_ctxt (ppr (mkClassPred cls tys))
  where
    (_,_,cls,tys) = tcSplitDFunTy dfun_ty

inst_decl_ctxt :: SDoc -> SDoc
inst_decl_ctxt doc = ptext (sLit "In the instance declaration for") <+> quotes doc

atInstCtxt :: Name -> SDoc
atInstCtxt name = ptext (sLit "In the associated type instance for") <+>
                  quotes (ppr name)

mustBeVarArgErr :: Type -> SDoc
mustBeVarArgErr ty =
  sep [ ptext (sLit "Arguments that do not correspond to a class parameter") <+>
        ptext (sLit "must be variables")
      , ptext (sLit "Instead of a variable, found") <+> ppr ty
      ]

wrongATArgErr :: Type -> Type -> SDoc
wrongATArgErr ty instTy =
  sep [ ptext (sLit "Type indexes must match class instance head")
      , ptext (sLit "Found") <+> quotes (ppr ty)
        <+> ptext (sLit "but expected") <+> quotes (ppr instTy)
      ]

tooManyParmsErr :: Located Name -> SDoc
tooManyParmsErr tc_name
  = ptext (sLit "Family instance has too many parameters:") <+> 
    quotes (ppr tc_name)

tooFewParmsErr :: Arity -> SDoc
tooFewParmsErr arity
  = ptext (sLit "Family instance has too few parameters; expected") <+> 
    ppr arity

wrongNumberOfParmsErr :: Arity -> SDoc
wrongNumberOfParmsErr exp_arity
  = ptext (sLit "Number of parameters must match family declaration; expected")
    <+> ppr exp_arity

badBootFamInstDeclErr :: SDoc
badBootFamInstDeclErr
  = ptext (sLit "Illegal family instance in hs-boot file")

notFamily :: TyCon -> SDoc
notFamily tycon
  = vcat [ ptext (sLit "Illegal family instance for") <+> quotes (ppr tycon)
         , nest 2 $ parens (ppr tycon <+> ptext (sLit "is not an indexed type family"))]
  
wrongKindOfFamily :: TyCon -> SDoc
wrongKindOfFamily family
  = ptext (sLit "Wrong category of family instance; declaration was for a")
    <+> kindOfFamily
  where
    kindOfFamily | isSynTyCon family = ptext (sLit "type synonym")
		 | isAlgTyCon family = ptext (sLit "data type")
		 | otherwise = pprPanic "wrongKindOfFamily" (ppr family)