- UfSCC cc -> returnTc (Note (SCC cc) expr')
-
-tcCoreNote (UfSCC cc) = returnTc (SCC cc)
-tcCoreNote UfInlineCall = returnTc InlineCall
-
-
--- rationalTy isn't built in so, we have to construct it
--- (the "ty" part of the incoming literal is simply bottom)
-tcUfCon (UfLitCon (NoRepRational lit _))
- = tcLookupTyConByKey rationalTyConKey `thenNF_Tc` \ rational_tycon ->
- let
- rational_ty = mkSynTy rational_tycon []
- in
- returnTc (Literal (NoRepRational lit rational_ty))
-
--- Similarly for integers and strings, except that they are wired in
-tcUfCon (UfLitCon (NoRepInteger lit _))
- = returnTc (Literal (NoRepInteger lit integerTy))
-tcUfCon (UfLitCon (NoRepStr lit _))
- = returnTc (Literal (NoRepStr lit stringTy))
-
-tcUfCon (UfLitCon other_lit)
- = returnTc (Literal other_lit)
-
--- The dreaded lit-lits are also similar, except here the type
--- is read in explicitly rather than being implicit
-tcUfCon (UfLitLitCon lit ty)
- = tcHsType ty `thenTc` \ ty' ->
- returnTc (Literal (MachLitLit lit ty'))
-
-tcUfCon (UfDataCon name) = tcUfDataCon name
-
-tcUfCon (UfPrimOp name)
- = tcVar name `thenTc` \ op_id ->
- case isPrimitiveId_maybe op_id of
- Just op -> returnTc (PrimOp op)
- Nothing -> failWithTc (badPrimOp name)
-
-tcUfCon (UfCCallOp str is_dyn casm gc)
- = case is_dyn of
- True ->
- tcGetUnique `thenNF_Tc` \ u ->
- returnTc (PrimOp (CCallOp (Right u) casm gc cCallConv))
- False -> returnTc (PrimOp (CCallOp (Left str) casm gc cCallConv))
-
-tcUfDataCon name
- = tcVar name `thenTc` \ con_id ->
- case isDataConId_maybe con_id of
- Just con -> returnTc (DataCon con)
- Nothing -> failWithTc (badCon name)