do
var mmodule = nmodule.mmodule
if mmodule == null then return
- var objectclass = try_get_mclass_by_name(nmodule, mmodule, "Object")
- var pointerclass = try_get_mclass_by_name(nmodule, mmodule, "Pointer")
var mclass = nclassdef.mclass
if mclass == null then return
var mclassdef = nclassdef.mclassdef
if mclassdef == null then return
+ var supertypes = collect_supertypes(nmodule, nclassdef, mclassdef.is_intro)
+ mclassdef.set_supertypes(supertypes)
+ if not supertypes.is_empty then self.toolcontext.info("{mclassdef} new super-types: {supertypes.join(", ")}", 3)
+ end
+
+ # List the supertypes specified or implied by `nclassdef`.
+ #
+ # REQUIRE: `nmodule.mmodule != null`
+ # REQUIRE: `nclassdef.mclass != null`
+ private fun collect_supertypes(nmodule: AModule, nclassdef: AClassdef,
+ is_intro: Bool): Array[MClassType]
+ do
+ var mmodule = nmodule.mmodule.as(not null)
+ var mclass = nclassdef.mclass.as(not null)
+ var name = mclass.name
+ var kind = mclass.kind
+
+ var objectclass = try_get_mclass_by_name(nmodule, mmodule, "Object")
+ var pointerclass = try_get_mclass_by_name(nmodule, mmodule, "Pointer")
+
# Do we need to specify Object as a super class?
var specobject = true
ntype, false)
if mtype == null then continue # Skip because of error
if not mtype isa MClassType then
- error(ntype, "Error: supertypes cannot be a formal type.")
+ error(ntype, "Error: a supertype cannot be a formal type.")
continue
end
- if not mclass.kind.can_specialize(mtype.mclass.kind) then
- error(ntype, "Error: {mclass.kind} `{mclass}` cannot specialize {mtype.mclass.kind} `{mtype.mclass}`.")
+ var superclass = mtype.mclass
+ var super_kind = superclass.kind
+ if not kind.can_specialize(super_kind) then
+ error(ntype, "Error: {kind} `{mclass}` cannot specialize {super_kind} `{superclass}`.")
end
supertypes.add mtype
#print "new super : {mclass} < {mtype}"
- if mtype.mclass.kind == extern_kind then specpointer = false
+ if super_kind == extern_kind then specpointer = false
end
end
- if mclassdef.is_intro and objectclass != null then
- if mclass.kind == extern_kind and mclass.name != "Pointer" then
+ if is_intro and objectclass != null then
+ if kind == extern_kind and name != "Pointer" then
# it is an extern class, but not a Pointer
if pointerclass == null then
error(nclassdef, "Error: `Pointer` must be defined first.")
- return
+ return supertypes
end
if specpointer then supertypes.add pointerclass.mclass_type
else if specobject then
- if mclass.name != "Object" then
+ if name != "Object" then
# it is a standard class without super class (but is not Object)
supertypes.add objectclass.mclass_type
- else if mclass.kind != interface_kind then
+ else if kind != interface_kind then
error(nclassdef, "Error: `Object` must be an {interface_kind}.")
- return
end
end
end
- mclassdef.set_supertypes(supertypes)
- if not supertypes.is_empty then self.toolcontext.info("{mclassdef} new super-types: {supertypes.join(", ")}", 3)
+ return supertypes
end
# Check the validity of the specialization heirarchy
for nsc in nclassdef.n_superclasses do
var ntype = nsc.n_type
var mtype = ntype.mtype
- if mtype == null then continue
- assert mtype isa MClassType
+
+ # If the supertype is `null` or don’t refer to a class, we
+ # already raised an error.
+ if not mtype isa MClassType then continue
+
var sc = mtype.mclass
if not parents.has(sc) or sc == objectclass then
# Skip the warning on generated code
redef class AExternClasskind
redef fun mkind do return extern_kind
end
+redef class ASubsetClasskind
+ redef fun mkind do return subset_kind
+end
redef class AFormaldef
# The associated parameter type