var mvisibility: nullable MVisibility
var arity = 0
var names = new Array[String]
+ var mclass
if nclassdef isa AStdClassdef then
- name = nclassdef.n_id.text
+ var qid = nclassdef.n_qid
+ assert qid != null
+ name = qid.n_id.text
nkind = nclassdef.n_classkind
mkind = nkind.mkind
nvisibility = nclassdef.n_visibility
var nfd = nclassdef.n_formaldefs[i]
var ptname = nfd.n_id.text
if names.has(ptname) then
- error(nfd, "Error: A formal parameter type `{ptname}' already exists")
+ error(nfd, "Error: a formal parameter type `{ptname}` already exists.")
return
end
for c in ptname.chars do if c >= 'a' and c<= 'z' then
- warning(nfd, "formal-type-name", "Warning: lowercase in the formal parameter type {ptname}")
+ warning(nfd, "formal-type-name", "Warning: lowercase in the formal parameter type `{ptname}`.")
break
end
names.add(ptname)
end
+ mclass = try_get_mclass_by_qid(qid, mmodule)
+ if mclass == null and (qid.n_qualified != null or nclassdef.n_kwredef != null) then
+ class_not_found(qid, mmodule)
+ nclassdef.is_broken = true
+ return
+ end
- else if nclassdef isa ATopClassdef then
+ else if nclassdef isa ATopClassdef and nclassdef.n_propdefs.first.as(AMethPropdef).n_methid.collect_text == "sys" then
+ # Special case to keep `sys` in object.
+ # Needed to keep working bootstrap and a working java FFI together.
+ # TODO: remove once safe to remove
name = "Object"
nkind = null
mkind = interface_kind
nvisibility = null
mvisibility = public_visibility
- else if nclassdef isa AMainClassdef then
+ mclass = try_get_mclass_by_name(nclassdef, mmodule, name)
+ else
name = "Sys"
nkind = null
mkind = concrete_kind
nvisibility = null
mvisibility = public_visibility
- else
- abort
+ mclass = try_get_mclass_by_name(nclassdef, mmodule, name)
end
- var mclass = try_get_mclass_by_name(nclassdef, mmodule, name)
if mclass == null then
- if nclassdef isa AStdClassdef and nclassdef.n_kwredef != null then
- error(nclassdef, "Redef error: No imported class {name} to refine.")
- return
- end
-
- # Check for conflicting class full-names in the project
+ # Check for conflicting class full-names in the package
if mmodule.mgroup != null and mvisibility >= protected_visibility then
var mclasses = model.get_mclasses_by_name(name)
if mclasses != null then for other in mclasses do
- if other.intro_mmodule.mgroup != null and other.intro_mmodule.mgroup.mproject == mmodule.mgroup.mproject then
+ if other.intro_mmodule.mgroup != null and other.intro_mmodule.mgroup.mpackage == mmodule.mgroup.mpackage then
# Skip classes that are buggy
if other.try_intro == null then continue
- warning(nclassdef, "full-name-conflict", "Error: A class named `{other.full_name}` is already defined in module `{other.intro_mmodule}` at {other.intro.location}.")
+ warning(nclassdef, "full-name-conflict", "Error: a class named `{other.full_name}` is already defined in module `{other.intro_mmodule}` at {other.intro.location}.")
break
end
end
end
- mclass = new MClass(mmodule, name, names, mkind, mvisibility)
+ mclass = new MClass(mmodule, name, nclassdef.location, names, mkind, mvisibility)
#print "new class {mclass}"
else if nclassdef isa AStdClassdef and nmodule.mclass2nclassdef.has_key(mclass) then
- error(nclassdef, "Error: A class {name} is already defined at line {nmodule.mclass2nclassdef[mclass].location.line_start}.")
+ error(nclassdef, "Error: a class `{name}` is already defined at line {nmodule.mclass2nclassdef[mclass].location.line_start}.")
+ mclass.is_broken = true
return
else if nclassdef isa AStdClassdef and nclassdef.n_kwredef == null then
- error(nclassdef, "Redef error: {name} is an imported class. Add the redef keyword to refine it.")
+ error(nclassdef, "Redef Error: `{name}` is an imported class. Add the `redef` keyword to refine it.")
+ mclass.is_broken = true
return
else if arity != 0 and mclass.arity != arity then
- error(nclassdef, "Redef error: Formal parameter arity missmatch; got {arity}, expected {mclass.arity}.")
+ error(nclassdef, "Redef Error: expected {mclass.arity} formal parameter(s) for {mclass.signature_to_s}; got {arity}.")
+ mclass.is_broken = true
return
else if nkind != null and mkind != concrete_kind and mclass.kind != mkind then
- error(nkind, "Error: refinement changed the kind from a {mclass.kind} to a {mkind}")
+ error(nkind, "Redef Error: refinement changed the kind from `{mclass.kind}` to `{mkind}`.")
else if nvisibility != null and mvisibility != public_visibility and mclass.visibility != mvisibility then
- error(nvisibility, "Error: refinement changed the visibility from a {mclass.visibility} to a {mvisibility}")
+ error(nvisibility, "Redef Error: refinement changed the visibility from `{mclass.visibility}` to `{mvisibility}`")
end
nclassdef.mclass = mclass
if not nmodule.mclass2nclassdef.has_key(mclass) then
var nfd = nclassdef.n_formaldefs[i]
var pname = mclass.mparameters[i].name
if nfd.n_id.text != pname then
- error(nfd.n_id, "Error: Formal parameter type #{i} `{nfd.n_id.text}` must be named `{pname}' as in the original definition in module `{mclass.intro.mmodule}`.")
+ error(nfd.n_id, "Error: formal parameter type #{i} `{nfd.n_id.text}` must be named `{pname}` as in the original definition in module `{mclass.intro.mmodule}`.")
end
var nfdt = nfd.n_type
if nfdt != null then
if bound == null then return # Forward error
if bound.need_anchor then
# No F-bounds!
- error(nfd, "Error: Formal parameter type `{pname}' bounded with a formal parameter type")
+ error(nfd, "Error: formal parameter type `{pname}` bounded with a formal parameter type.")
else
bounds.add(bound)
nfd.bound = bound
end
if bound isa MClassType and bound.mclass.kind == enum_kind then
- warning(nfdt, "useless-bound", "Warning: Useless formal parameter type since `{bound}` cannnot have subclasses.")
+ warning(nfdt, "useless-bound", "Warning: useless formal parameter type since `{bound}` cannot have subclasses.")
end
else if mclass.mclassdefs.is_empty then
if objectclass == null then
- error(nfd, "Error: Formal parameter type `{pname}' unbounded but no Object class exist.")
+ error(nfd, "Error: formal parameter type `{pname}` unbounded but no `Object` class exists.")
return
end
# No bound, then implicitely bound by nullable Object
if mclassdef.is_intro then
self.toolcontext.info("{mclassdef} introduces new {mclass.kind} {mclass.full_name}", 3)
else
- self.toolcontext.info("{mclassdef} refine {mclass.kind} {mclass.full_name}", 3)
+ self.toolcontext.info("{mclassdef} refines {mclass.kind} {mclass.full_name}", 3)
end
end
var mtype = resolve_mtype_unchecked(mmodule, mclassdef, 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: supertypes cannot be a formal type.")
return
end
if not mclass.kind.can_specialize(mtype.mclass.kind) then
- error(ntype, "Error: {mclass.kind} {mclass} cannot specialize {mtype.mclass.kind} {mtype.mclass}")
+ error(ntype, "Error: {mclass.kind} `{mclass}` cannot specialize {mtype.mclass.kind} `{mtype.mclass}`.")
end
supertypes.add mtype
#print "new super : {mclass} < {mtype}"
if mclassdef.is_intro and objectclass != null then
if mclass.kind == extern_kind and mclass.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
+ end
if specpointer then supertypes.add pointerclass.mclass_type
- else if specobject and mclass.name != "Object" then
- # it is a standard class without super class (but is not Object)
- supertypes.add objectclass.mclass_type
+ else if specobject then
+ if mclass.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
+ error(nclassdef, "Error: `Object` must be an {interface_kind}.")
+ return
+ end
end
end
for s in mclassdef.supertypes do
if s.is_subtype(mmodule, mclassdef.bound_mtype, mclassdef.bound_mtype) then
- error(nclassdef, "Error: Inheritance loop for class {mclass} with type {s}")
+ error(nclassdef, "Error: inheritance loop for class `{mclass}` with type `{s}`.")
end
end
end
# Build the classes of the module `nmodule`.
- # REQUIRE: classes of imported modules are already build. (let `phase` do the job)
private fun build_classes(nmodule: AModule)
do
- var errcount = toolcontext.error_count
# Force building recursively
if nmodule.build_classes_is_done then return
nmodule.build_classes_is_done = true
if nimp != null then build_classes(nimp)
end
- if errcount != toolcontext.error_count then return
-
# Create all classes
# process AStdClassdef before so that non-AStdClassdef classes can be attached to existing ones, if any
for nclassdef in nmodule.n_classdefs do
self.build_a_mclass(nmodule, nclassdef)
end
- if errcount != toolcontext.error_count then return
-
# Create all classdefs
for nclassdef in nmodule.n_classdefs do
if not nclassdef isa AStdClassdef then continue
self.build_a_mclassdef(nmodule, nclassdef)
end
- if errcount != toolcontext.error_count then return
-
# Create inheritance on all classdefs
for nclassdef in nmodule.n_classdefs do
self.collect_a_mclassdef_inheritance(nmodule, nclassdef)
end
- if errcount != toolcontext.error_count then return
-
# Create the mclassdef hierarchy
for mclassdef in mmodule.mclassdefs do
mclassdef.add_in_hierarchy
end
- if errcount != toolcontext.error_count then return
-
# Check inheritance
for nclassdef in nmodule.n_classdefs do
self.check_supertypes(nmodule, nclassdef)
end
- if errcount != toolcontext.error_count then return
-
# Check unchecked ntypes
for nclassdef in nmodule.n_classdefs do
if nclassdef isa AStdClassdef then
end
end
- if errcount != toolcontext.error_count then return
-
# Check clash of ancestors
for nclassdef in nmodule.n_classdefs do
var mclassdef = nclassdef.mclassdef
var st1 = superclasses[st.mclass].resolve_for(mclassdef.mclass.mclass_type, mclassdef.bound_mtype, mmodule, false)
var st2 = st.resolve_for(mclassdef.mclass.mclass_type, mclassdef.bound_mtype, mmodule, false)
if st1 != st2 then
- error(nclassdef, "Error: Incompatibles ancestors for {mclassdef.mclass}: {st1}, {st2}")
+ error(nclassdef, "Error: incompatible ancestors for `{mclassdef.mclass}`; conflict: `{st1}` and `{st2}`")
end
end
end
end
end
- if errcount != toolcontext.error_count then return
-
# TODO: Check that the super-class is not intrusive
# Check that the superclasses are not already known (by transitivity)
for nclassdef in nmodule.n_classdefs do
- if not nclassdef isa AStdClassdef then continue
+ if not nclassdef isa AStdClassdef or nclassdef.is_broken then continue
var mclassdef = nclassdef.mclassdef
if mclassdef == null then continue
if not parents.has(sc) or sc == objectclass then
# Skip the warning on generated code
if ntype.location.file != null and not ntype.location.file.filename.is_empty then
- warning(ntype, "useless-superclass", "Warning: superfluous super-class {mtype} in class {mclassdef.mclass}.")
+ warning(ntype, "useless-superclass", "Warning: superfluous super-class `{mtype}` in class `{mclassdef.mclass}`.")
end
else if not seen_parents.has_key(sc) then
seen_parents[sc] = ntype
else
- warning(ntype, "useless-superclass", "Warning: duplicated super-class {mtype} in class {mclassdef.mclass}.")
+ warning(ntype, "useless-superclass", "Warning: duplicated super-class `{mtype}` in class `{mclassdef.mclass}`.")
end
end
end
# Registration of the nclassdef associated to each mclassdef
private var mclassdef2nclassdef = new HashMap[MClassDef, AClassdef]
+
+ # Retrieve the associated AST node of a mclassdef.
+ #
+ # This method is used to associate model entity with syntactic entities.
+ # If the class definition is not associated with a node, returns `null`.
+ fun mclassdef2node(mclassdef: MClassDef): nullable AClassdef do
+ return mclassdef2nclassdef.get_or_null(mclassdef)
+ end
end
redef class AModule