#
# It also provide an API to build and query models.
#
-# All model classes starts with the M letter (MModule, MClass, etc.)
+# All model classes starts with the M letter (`MModule`, `MClass`, etc.)
#
# TODO: better doc
#
-# TODO: liearization, closures, extern stuff
+# TODO: liearization, extern stuff
# FIXME: better handling of the types
module model
import poset
import location
-import model_base
+import mmodule
+import mdoc
+private import more_collections
redef class Model
# All known classes
# Collections of classes grouped by their short name
private var mclasses_by_name: MultiHashMap[String, MClass] = new MultiHashMap[String, MClass]
- # Return all class named `name'.
+ # Return all class named `name`.
#
# If such a class does not exist, null is returned
# (instead of an empty array)
# Collections of properties grouped by their short name
private var mproperties_by_name: MultiHashMap[String, MProperty] = new MultiHashMap[String, MProperty]
- # Return all properties named `name'.
+ # Return all properties named `name`.
#
# If such a property does not exist, null is returned
# (instead of an empty array)
# (introduction and refinement)
var mclassdefs: Array[MClassDef] = new Array[MClassDef]
- # Does the current module has a given class `mclass'?
+ # Does the current module has a given class `mclass`?
# Return true if the mmodule introduces, refines or imports a class.
# Visibility is not considered.
fun has_mclass(mclass: MClass): Bool
for m in self.in_importation.greaters do
for cd in m.mclassdefs do
var c = cd.mclass
+ res.add_node(c)
for s in cd.supertypes do
res.add_edge(c, s.mclass)
end
return res
end
+ # Sort a given array of classes using the linerarization order of the module
+ # The most general is first, the most specific is last
+ fun linearize_mclasses(mclasses: Array[MClass])
+ do
+ self.flatten_mclass_hierarchy.sort(mclasses)
+ end
+
+ # Sort a given array of class definitions using the linerarization order of the module
+ # the refinement link is stronger than the specialisation link
+ # The most general is first, the most specific is last
+ fun linearize_mclassdefs(mclassdefs: Array[MClassDef])
+ do
+ var sorter = new MClassDefSorter(self)
+ sorter.sort(mclassdefs)
+ end
+
+ # Sort a given array of property definitions using the linerarization order of the module
+ # the refinement link is stronger than the specialisation link
+ # The most general is first, the most specific is last
+ fun linearize_mpropdefs(mpropdefs: Array[MPropDef])
+ do
+ var sorter = new MPropDefSorter(self)
+ sorter.sort(mpropdefs)
+ end
+
private var flatten_mclass_hierarchy_cache: nullable POSet[MClass] = null
- # The primitive type Object, the root of the class hierarchy
+ # The primitive type `Object`, the root of the class hierarchy
fun object_type: MClassType
do
var res = self.object_type_cache
private var object_type_cache: nullable MClassType
- # The primitive type Bool
+ # The primitive type `Bool`
fun bool_type: MClassType
do
var res = self.bool_type_cache
private var bool_type_cache: nullable MClassType
- # The primitive type Sys, the main type of the program, if any
+ # The primitive type `Sys`, the main type of the program, if any
fun sys_type: nullable MClassType
do
var clas = self.model.get_mclasses_by_name("Sys")
return get_primitive_class("Sys").mclass_type
end
- # Force to get the primitive class named `name' or abort
+ # Force to get the primitive class named `name` or abort
fun get_primitive_class(name: String): MClass
do
var cla = self.model.get_mclasses_by_name(name)
print("Fatal Error: no primitive class {name}")
exit(1)
end
- assert cla.length == 1 else print cla.join(", ")
+ if cla.length != 1 then
+ var msg = "Fatal Error: more than one primitive class {name}:"
+ for c in cla do msg += " {c.full_name}"
+ print msg
+ exit(1)
+ end
return cla.first
end
- # Try to get the primitive method named `name' on the type `recv'
- fun try_get_primitive_method(name: String, recv: MType): nullable MMethod
+ # Try to get the primitive method named `name` on the type `recv`
+ fun try_get_primitive_method(name: String, recv: MClass): nullable MMethod
do
var props = self.model.get_mproperties_by_name(name)
if props == null then return null
var res: nullable MMethod = null
for mprop in props do
assert mprop isa MMethod
- if not recv.has_mproperty(self, mprop) then continue
- if res == null then
- res = mprop
- else
- print("Fatal Error: ambigous property name '{name}'; conflict between {mprop.full_name} and {res.full_name}")
- abort
+ var intro = mprop.intro_mclassdef
+ for mclassdef in recv.mclassdefs do
+ if not self.in_importation.greaters.has(mclassdef.mmodule) then continue
+ if not mclassdef.in_hierarchy.greaters.has(intro) then continue
+ if res == null then
+ res = mprop
+ else if res != mprop then
+ print("Fatal Error: ambigous property name '{name}'; conflict between {mprop.full_name} and {res.full_name}")
+ abort
+ end
end
end
return res
end
end
+private class MClassDefSorter
+ super AbstractSorter[MClassDef]
+ var mmodule: MModule
+ redef fun compare(a, b)
+ do
+ var ca = a.mclass
+ var cb = b.mclass
+ if ca != cb then return mmodule.flatten_mclass_hierarchy.compare(ca, cb)
+ return mmodule.model.mclassdef_hierarchy.compare(a, b)
+ end
+end
+
+private class MPropDefSorter
+ super AbstractSorter[MPropDef]
+ var mmodule: MModule
+ redef fun compare(pa, pb)
+ do
+ var a = pa.mclassdef
+ var b = pb.mclassdef
+ var ca = a.mclass
+ var cb = b.mclass
+ if ca != cb then return mmodule.flatten_mclass_hierarchy.compare(ca, cb)
+ return mmodule.model.mclassdef_hierarchy.compare(a, b)
+ end
+end
+
# A named class
#
-# MClass are global to the model; it means that a MClass is not bound to a
+# `MClass` are global to the model; it means that a `MClass` is not bound to a
# specific `MModule`.
#
# This characteristic helps the reasoning about classes in a program since a
-# single MClass object always denote the same class.
-# However, because a MClass is global, it does not really have properties nor
+# single `MClass` object always denote the same class.
+# However, because a `MClass` is global, it does not really have properties nor
# belong to a hierarchy since the property and the
# hierarchy of a class depends of a module.
class MClass
+ super MEntity
+
# The module that introduce the class
# While classes are not bound to a specific module,
# the introducing module is used for naming an visibility
var name: String
# The canonical name of the class
- # Example: "owner::module::MyClass"
+ # Example: `"owner::module::MyClass"`
fun full_name: String
do
return "{self.intro_mmodule.full_name}::{name}"
# All class definitions (introduction and refinements)
var mclassdefs: Array[MClassDef] = new Array[MClassDef]
- # Alias for `name'
+ # Alias for `name`
redef fun to_s do return self.name
# The definition that introduced the class
- # Warning: the introduction is the first `MClassDef' object associated
+ # Warning: the introduction is the first `MClassDef` object associated
# to self. If self is just created without having any associated
# definition, this method will abort
- private fun intro: MClassDef
+ fun intro: MClassDef
do
assert has_a_first_definition: not mclassdefs.is_empty
return mclassdefs.first
end
- # Return the class `self' in the class hierarchy of the module `mmodule'.
+ # Return the class `self` in the class hierarchy of the module `mmodule`.
#
- # SEE: MModule::flatten_mclass_hierarchy
- # REQUIRE: mmodule.has_mclass(self)
+ # SEE: `MModule::flatten_mclass_hierarchy`
+ # REQUIRE: `mmodule.has_mclass(self)`
fun in_hierarchy(mmodule: MModule): POSetElement[MClass]
do
return mmodule.flatten_mclass_hierarchy[self]
# The principal static type of the class.
#
- # For non-generic class, mclass_type is the only MClassType based
+ # For non-generic class, mclass_type is the only `MClassType` based
# on self.
#
# For a generic class, the arguments are the formal parameters.
- # i.e.: for the class `Array[E:Object]', the mtype is Array[E].
- # If you want `Array[Object]' the see `MClassDef::bound_mtype'
+ # i.e.: for the class Array[E:Object], the `mclass_type` is Array[E].
+ # If you want Array[Object] the see `MClassDef::bound_mtype`
#
# For generic classes, the mclass_type is also the way to get a formal
# generic parameter type.
#
- # To get other types based on a generic class, see `get_mtype'.
+ # To get other types based on a generic class, see `get_mtype`.
#
- # ENSURE: mclass_type.mclass == self
+ # ENSURE: `mclass_type.mclass == self`
var mclass_type: MClassType
# Return a generic type based on the class
- # Is the class is not generic, then the result is `mclass_type'
+ # Is the class is not generic, then the result is `mclass_type`
#
- # REQUIRE: type_arguments.length == self.arity
+ # REQUIRE: `mtype_arguments.length == self.arity`
fun get_mtype(mtype_arguments: Array[MType]): MClassType
do
assert mtype_arguments.length == self.arity
# A definition (an introduction or a refinement) of a class in a module
#
-# A MClassDef is associated with an explicit (or almost) definition of a
-# class. Unlike MClass, a MClassDef is a local definition that belong to
+# A `MClassDef` is associated with an explicit (or almost) definition of a
+# class. Unlike `MClass`, a `MClassDef` is a local definition that belong to
# a specific module
class MClassDef
+ super MEntity
+
# The module where the definition is
var mmodule: MModule
- # The associated MClass
+ # The associated `MClass`
var mclass: MClass
# The bounded type associated to the mclassdef
#
- # For a non-generic class, `bound_mtype' and `mclass.mclass_type'
+ # For a non-generic class, `bound_mtype` and `mclass.mclass_type`
# are the same type.
#
# Example:
# For the classdef Array[E: Object], the bound_mtype is Array[Object].
- # If you want Array[E], then see `mclass.mclass_type'
+ # If you want Array[E], then see `mclass.mclass_type`
#
- # ENSURE: bound_mtype.mclass = self.mclass
+ # ENSURE: `bound_mtype.mclass == self.mclass`
var bound_mtype: MClassType
# Name of each formal generic parameter (in order of declaration)
# Internal name combining the module and the class
# Example: "mymodule#MyClass"
- redef fun to_s do return "{mmodule}#{mclass}"
+ redef var to_s: String
init(mmodule: MModule, bound_mtype: MClassType, location: Location, parameter_names: Array[String])
do
mmodule.mclassdefs.add(self)
mclass.mclassdefs.add(self)
self.parameter_names = parameter_names
+ self.to_s = "{mmodule}#{mclass}"
end
# All declared super-types
# Register some super-types for the class (ie "super SomeType")
#
# The hierarchy must not already be set
- # REQUIRE: self.in_hierarchy == null
+ # REQUIRE: `self.in_hierarchy == null`
fun set_supertypes(supertypes: Array[MClassType])
do
assert unique_invocation: self.in_hierarchy == null
# Collect the super-types (set by set_supertypes) to build the hierarchy
#
# This function can only invoked once by class
- # REQUIRE: self.in_hierarchy == null
- # ENSURE: self.in_hierarchy != null
+ # REQUIRE: `self.in_hierarchy == null`
+ # ENSURE: `self.in_hierarchy != null`
fun add_in_hierarchy
do
assert unique_invocation: self.in_hierarchy == null
end
end
- # The view of the class definition in `mclassdef_hierarchy'
+ # The view of the class definition in `mclassdef_hierarchy`
var in_hierarchy: nullable POSetElement[MClassDef] = null
# Is the definition the one that introduced `mclass`?
# A global static type
#
-# MType are global to the model; it means that a MType is not bound to a
+# MType are global to the model; it means that a `MType` is not bound to a
# specific `MModule`.
# This characteristic helps the reasoning about static types in a program
-# since a single MType object always denote the same type.
+# since a single `MType` object always denote the same type.
#
-# However, because a MType is global, it does not really have properties
+# However, because a `MType` is global, it does not really have properties
# nor have subtypes to a hierarchy since the property and the class hierarchy
# depends of a module.
# Moreover, virtual types an formal generic parameter types also depends on
# The anchor is used to know what is the bound of the virtual types and formal
# generic parameter types.
#
-# MType are not directly usable to get properties. See the `anchor_to' method
-# and the `MClassType' class.
+# MType are not directly usable to get properties. See the `anchor_to` method
+# and the `MClassType` class.
#
# FIXME: the order of the parameters is not the best. We mus pick on from:
# * foo(mmodule, anchor, othertype)
# * foo(othertype, anchor, mmodule)
# * foo(anchor, mmodule, othertype)
# * foo(othertype, mmodule, anchor)
-#
-# FIXME: Add a 'is_valid_anchor' to improve imputability.
-# Currently, anchors are used "as it" without check thus if the caller gives a
-# bad anchor, then the method will likely crash (abort) in a bad case
-#
-# FIXME: maybe allways add an anchor with a nullable type (as in is_subtype)
abstract class MType
+ super MEntity
# The model of the type
fun model: Model is abstract
- # Return true if `self' is an subtype of `sup'.
+ # Return true if `self` is an subtype of `sup`.
# The typing is done using the standard typing policy of Nit.
#
- # REQUIRE: anchor == null implies not self.need_anchor and not sup.need_anchor
+ # REQUIRE: `anchor == null implies not self.need_anchor and not sup.need_anchor`
+ # REQUIRE: `anchor != null implies self.can_resolve_for(anchor, null, mmodule) and sup.can_resolve_for(anchor, null, mmodule)`
fun is_subtype(mmodule: MModule, anchor: nullable MClassType, sup: MType): Bool
do
var sub = self
if anchor == null then
assert not sub.need_anchor
assert not sup.need_anchor
+ else
+ assert sub.can_resolve_for(anchor, null, mmodule)
+ assert sup.can_resolve_for(anchor, null, mmodule)
end
- # First, resolve the types
+
+ # First, resolve the formal types to a common version in the receiver
+ # The trick here is that fixed formal type will be associed to the bound
+ # And unfixed formal types will be associed to a canonical formal type.
if sub isa MParameterType or sub isa MVirtualType then
assert anchor != null
- sub = sub.resolve_for(anchor, anchor, mmodule, false)
+ sub = sub.resolve_for(anchor.mclass.mclass_type, anchor, mmodule, false)
end
if sup isa MParameterType or sup isa MVirtualType then
assert anchor != null
- sup = sup.resolve_for(anchor, anchor, mmodule, false)
+ sup = sup.resolve_for(anchor.mclass.mclass_type, anchor, mmodule, false)
end
- if sup isa MParameterType or sup isa MVirtualType or sup isa MNullType then
+ # Does `sup` accept null or not?
+ # Discard the nullable marker if it exists
+ var sup_accept_null = false
+ if sup isa MNullableType then
+ sup_accept_null = true
+ sup = sup.mtype
+ else if sup isa MNullType then
+ sup_accept_null = true
+ end
+
+ # Can `sub` provide null or not?
+ # Thus we can match with `sup_accept_null`
+ # Also discard the nullable marker if it exists
+ if sub isa MNullableType then
+ if not sup_accept_null then return false
+ sub = sub.mtype
+ else if sub isa MNullType then
+ return sup_accept_null
+ end
+ # Now the case of direct null and nullable is over.
+
+ # A unfixed formal type can only accept itself
+ if sup isa MParameterType or sup isa MVirtualType then
return sub == sup
end
+
+ # If `sub` is a formal type, then it is accepted if its bound is accepted
if sub isa MParameterType or sub isa MVirtualType then
assert anchor != null
sub = sub.anchor_to(mmodule, anchor)
- end
- if sup isa MNullableType then
- if sub isa MNullType then
- return true
- else if sub isa MNullableType then
- return sub.mtype.is_subtype(mmodule, anchor, sup.mtype)
- else if sub isa MClassType then
- return sub.is_subtype(mmodule, anchor, sup.mtype)
- else
- abort
+
+ # Manage the second layer of null/nullable
+ if sub isa MNullableType then
+ if not sup_accept_null then return false
+ sub = sub.mtype
+ else if sub isa MNullType then
+ return sup_accept_null
end
end
- assert sup isa MClassType # It is the only remaining type
- if sub isa MNullableType or sub isa MNullType then
+ assert sub isa MClassType # It is the only remaining type
+
+ if sup isa MNullType then
+ # `sup` accepts only null
return false
end
+ assert sup isa MClassType # It is the only remaining type
+
+ # Now both are MClassType, we need to dig
+
if sub == sup then return true
- assert sub isa MClassType # It is the only remaining type
if anchor == null then anchor = sub # UGLY: any anchor will work
var resolved_sub = sub.anchor_to(mmodule, anchor)
var res = resolved_sub.collect_mclasses(mmodule).has(sup.mclass)
if not sup isa MGenericType then return true
var sub2 = sub.supertype_to(mmodule, anchor, sup.mclass)
assert sub2.mclass == sup.mclass
- assert sub2 isa MGenericType
for i in [0..sup.mclass.arity[ do
var sub_arg = sub2.arguments[i]
var sup_arg = sup.arguments[i]
# types to their bounds.
#
# Example
+ # class A end
+ # class B super A end
+ # class X end
+ # class Y super X end
# class G[T: A]
# type U: X
# end
# class H
- # super G[C]
+ # super G[B]
# redef type U: Y
# end
- # Map[T,U] anchor_to H #-> Map[C,Y]
+ # Map[T,U] anchor_to H #-> Map[B,Y]
#
# Explanation of the example:
- # In H, T is set to C, because "H super G[C]", and U is bound to Y,
+ # In H, T is set to B, because "H super G[B]", and U is bound to Y,
# because "redef type U: Y". Therefore, Map[T, U] is bound to
- # Map[C, Y]
+ # Map[B, Y]
#
- # ENSURE: not self.need_anchor implies return == self
- # ENSURE: not return.need_anchor
+ # ENSURE: `not self.need_anchor implies result == self`
+ # ENSURE: `not result.need_anchor`
fun anchor_to(mmodule: MModule, anchor: MClassType): MType
do
if not need_anchor then return self
assert not anchor.need_anchor
# Just resolve to the anchor and clear all the virtual types
- var res = self.resolve_for(anchor, anchor, mmodule, true)
+ var res = self.resolve_for(anchor, null, mmodule, true)
assert not res.need_anchor
return res
end
- # Does `self' contain a virtual type or a formal generic parameter type?
- # In order to remove those types, you usually want to use `anchor_to'.
+ # Does `self` contain a virtual type or a formal generic parameter type?
+ # In order to remove those types, you usually want to use `anchor_to`.
fun need_anchor: Bool do return true
# Return the supertype when adapted to a class.
# In Nit, for each super-class of a type, there is a equivalent super-type.
#
# Example:
- # class G[T, U]
- # class H[V] super G[V, Bool]
+ # class G[T, U] end
+ # class H[V] super G[V, Bool] end
# H[Int] supertype_to G #-> G[Int, Bool]
#
- # REQUIRE: `super_mclass' is a super-class of `self'
- # ENSURE: return.mclass = mclass
- fun supertype_to(mmodule: MModule, anchor: MClassType, super_mclass: MClass): MClassType
+ # REQUIRE: `super_mclass` is a super-class of `self`
+ # REQUIRE: `self.need_anchor implies anchor != null and self.can_resolve_for(anchor, null, mmodule)`
+ # ENSURE: `result.mclass = super_mclass`
+ fun supertype_to(mmodule: MModule, anchor: nullable MClassType, super_mclass: MClass): MClassType
do
if super_mclass.arity == 0 then return super_mclass.mclass_type
if self isa MClassType and self.mclass == super_mclass then return self
- var resolved_self = self.anchor_to(mmodule, anchor)
+ var resolved_self
+ if self.need_anchor then
+ assert anchor != null
+ resolved_self = self.anchor_to(mmodule, anchor)
+ else
+ resolved_self = self
+ end
var supertypes = resolved_self.collect_mtypes(mmodule)
for supertype in supertypes do
if supertype.mclass == super_mclass then
abort
end
- # Replace formals generic types in self with resolved values in `mtype'
- # If `cleanup_virtual' is true, then virtual types are also replaced
+ # Replace formals generic types in self with resolved values in `mtype`
+ # If `cleanup_virtual` is true, then virtual types are also replaced
# with their bounds
#
- # This function returns self if `need_anchor' is false.
+ # This function returns self if `need_anchor` is false.
#
- # Example:
- # class G[E]
- # class H[F] super G[F]
- # Array[E] resolve_for H[Int] #-> Array[Int]
+ # ## Example 1
+ #
+ # class G[E] end
+ # class H[F] super G[F] end
+ # class X[Z] end
+ #
+ # * Array[E].resolve_for(H[Int]) #-> Array[Int]
+ # * Array[E].resolve_for(G[Z], X[Int]) #-> Array[Z]
#
# Explanation of the example:
- # * Array[E].need_anchor is true because there is a formal generic
- # parameter type E
- # * E makes sense for H[Int] because E is a formal parameter of G
- # and H specialize G
+ # * Array[E].need_anchor is true because there is a formal generic parameter type E
+ # * E makes sense for H[Int] because E is a formal parameter of G and H specialize G
# * Since "H[F] super G[F]", E is in fact F for H
# * More specifically, in H[Int], E is Int
# * So, in H[Int], Array[E] is Array[Int]
#
# This function is mainly used to inherit a signature.
- # Because, unlike `anchor_type', we do not want a full resolution of
+ # Because, unlike `anchor_to`, we do not want a full resolution of
# a type but only an adapted version of it.
#
- # Example:
- # class A[E]
- # foo(e:E):E
+ # ## Example 2
+ #
+ # class A[E]
+ # fun foo(e:E):E is abstract
# end
# class B super A[Int] end
#
# The signature on foo is (e: E): E
# If we resolve the signature for B, we get (e:Int):Int
#
+ # ## Example 3
+ #
+ # class A[E]
+ # fun foo(e:E) is abstract
+ # end
+ # class B[F]
+ # var a: A[Array[F]]
+ # fun bar do a.foo(x) # <- x is here
+ # end
+ #
+ # The first question is: is foo available on `a`?
+ #
+ # The static type of a is `A[Array[F]]`, that is an open type.
+ # in order to find a method `foo`, whe must look at a resolved type.
+ #
+ # A[Array[F]].anchor_to(B[nullable Object]) #-> A[Array[nullable Object]]
+ #
+ # the method `foo` exists in `A[Array[nullable Object]]`, therefore `foo` exists for `a`.
+ #
+ # The next question is: what is the accepted types for `x`?
+ #
+ # the signature of `foo` is `foo(e:E)`, thus we must resolve the type E
+ #
+ # E.resolve_for(A[Array[F]],B[nullable Object]) #-> Array[F]
+ #
+ # The resolution can be done because `E` make sense for the class A (see `can_resolve_for`)
+ #
# TODO: Explain the cleanup_virtual
#
- # FIXME: the parameter `cleanup_virtual' is just a bad idea, but having
+ # FIXME: the parameter `cleanup_virtual` is just a bad idea, but having
# two function instead of one seems also to be a bad idea.
#
- # ENSURE: not self.need_anchor implies return == self
- fun resolve_for(mtype: MType, anchor: MClassType, mmodule: MModule, cleanup_virtual: Bool): MType is abstract
+ # REQUIRE: `can_resolve_for(mtype, anchor, mmodule)`
+ # ENSURE: `not self.need_anchor implies result == self`
+ fun resolve_for(mtype: MType, anchor: nullable MClassType, mmodule: MModule, cleanup_virtual: Bool): MType is abstract
+
+ # Can the type be resolved?
+ #
+ # In order to resolve open types, the formal types must make sence.
+ #
+ # ## Example
+ #
+ # class A[E]
+ # end
+ # class B[F]
+ # end
+ #
+ # * E.can_resolve_for(A[Int]) #-> true, E make sense in A
+ # * E.can_resolve_for(B[Int]) #-> false, E does not make sense in B
+ # * B[E].can_resolve_for(A[F], B[Object]) #-> true,
+ # B[E] is a red hearing only the E is important,
+ # E make sense in A
+ #
+ # REQUIRE: `anchor != null implies not anchor.need_anchor`
+ # REQUIRE: `mtype.need_anchor implies anchor != null and mtype.can_resolve_for(anchor, null, mmodule)`
+ # ENSURE: `not self.need_anchor implies result == true`
+ fun can_resolve_for(mtype: MType, anchor: nullable MClassType, mmodule: MModule): Bool is abstract
# Return the nullable version of the type
# If the type is already nullable then self is returned
- #
- # FIXME: DO NOT WORK YET
fun as_nullable: MType
do
var res = self.as_nullable_cache
private var as_nullable_cache: nullable MType = null
+
+ # The deph of the type seen as a tree.
+ #
+ # * A -> 1
+ # * G[A] -> 2
+ # * H[A, B] -> 2
+ # * H[G[A], B] -> 3
+ #
+ # Formal types have a depth of 1.
+ fun depth: Int
+ do
+ return 1
+ end
+
+ # The length of the type seen as a tree.
+ #
+ # * A -> 1
+ # * G[A] -> 2
+ # * H[A, B] -> 3
+ # * H[G[A], B] -> 4
+ #
+ # Formal types have a length of 1.
+ fun length: Int
+ do
+ return 1
+ end
+
# Compute all the classdefs inherited/imported.
# The returned set contains:
# * the class definitions from `mmodule` and its imported modules
#
# This function is used mainly internally.
#
- # REQUIRE: not self.need_anchor
+ # REQUIRE: `not self.need_anchor`
fun collect_mclassdefs(mmodule: MModule): Set[MClassDef] is abstract
# Compute all the super-classes.
# This function is used mainly internally.
#
- # REQUIRE: not self.need_anchor
+ # REQUIRE: `not self.need_anchor`
fun collect_mclasses(mmodule: MModule): Set[MClass] is abstract
# Compute all the declared super-types.
# Super-types are returned as declared in the classdefs (verbatim).
# This function is used mainly internally.
#
- # REQUIRE: not self.need_anchor
+ # REQUIRE: `not self.need_anchor`
fun collect_mtypes(mmodule: MModule): Set[MClassType] is abstract
# Is the property in self for a given module
# This method does not filter visibility or whatever
#
- # REQUIRE: not self.need_anchor
+ # REQUIRE: `not self.need_anchor`
fun has_mproperty(mmodule: MModule, mproperty: MProperty): Bool
do
assert not self.need_anchor
# A type based on a class.
#
-# MClassType have properties (see `has_property').
+# `MClassType` have properties (see `has_mproperty`).
class MClassType
super MType
self.mclass = mclass
end
+ # The formal arguments of the type
+ # ENSURE: `result.length == self.mclass.arity`
+ var arguments: Array[MType] = new Array[MType]
+
redef fun to_s do return mclass.to_s
redef fun need_anchor do return false
return super.as(MClassType)
end
- redef fun resolve_for(mtype: MType, anchor: MClassType, mmodule: MModule, cleanup_virtual: Bool): MClassType do return self
+ redef fun resolve_for(mtype: MType, anchor: nullable MClassType, mmodule: MModule, cleanup_virtual: Bool): MClassType do return self
+
+ redef fun can_resolve_for(mtype, anchor, mmodule) do return true
redef fun collect_mclassdefs(mmodule)
do
return cache[mmodule]
end
- # common implementation for `collect_mclassdefs', `collect_mclasses', and `collect_mtypes'.
+ # common implementation for `collect_mclassdefs`, `collect_mclasses`, and `collect_mtypes`.
private fun collect_things(mmodule: MModule)
do
var res = new HashSet[MClassDef]
break
end
end
- end
- # The formal arguments of the type
- # ENSURE: return.length == self.mclass.arity
- var arguments: Array[MType]
+ self.to_s = "{mclass}[{arguments.join(", ")}]"
+ end
# Recursively print the type of the arguments within brackets.
- # Example: "Map[String,List[Int]]"
- redef fun to_s
- do
- return "{mclass}[{arguments.join(",")}]"
- end
+ # Example: `"Map[String, List[Int]]"`
+ redef var to_s: String
redef var need_anchor: Bool
redef fun resolve_for(mtype, anchor, mmodule, cleanup_virtual)
do
if not need_anchor then return self
+ assert can_resolve_for(mtype, anchor, mmodule)
var types = new Array[MType]
for t in arguments do
types.add(t.resolve_for(mtype, anchor, mmodule, cleanup_virtual))
end
return mclass.get_mtype(types)
end
+
+ redef fun can_resolve_for(mtype, anchor, mmodule)
+ do
+ if not need_anchor then return true
+ for t in arguments do
+ if not t.can_resolve_for(mtype, anchor, mmodule) then return false
+ end
+ return true
+ end
+
+
+ redef fun depth
+ do
+ var dmax = 0
+ for a in self.arguments do
+ var d = a.depth
+ if d > dmax then dmax = d
+ end
+ return dmax + 1
+ end
+
+ redef fun length
+ do
+ var res = 1
+ for a in self.arguments do
+ res += a.length
+ end
+ return res
+ end
end
# A virtual formal type.
redef fun resolve_for(mtype, anchor, mmodule, cleanup_virtual)
do
- if not cleanup_virtual then return self
+ assert can_resolve_for(mtype, anchor, mmodule)
# self is a virtual type declared (or inherited) in mtype
# The point of the function it to get the bound of the virtual type that make sense for mtype
# But because mtype is maybe a virtual/formal type, we need to get a real receiver first
#print "{class_name}: {self}/{mtype}/{anchor}?"
- var resolved_reciever = mtype.resolve_for(anchor, anchor, mmodule, true)
+ var resolved_reciever
+ if mtype.need_anchor then
+ assert anchor != null
+ resolved_reciever = mtype.resolve_for(anchor, null, mmodule, true)
+ else
+ resolved_reciever = mtype
+ end
# Now, we can get the bound
var verbatim_bound = lookup_bound(mmodule, resolved_reciever)
# The bound is exactly as declared in the "type" property, so we must resolve it again
- var res = verbatim_bound.resolve_for(mtype, anchor, mmodule, true)
+ var res = verbatim_bound.resolve_for(mtype, anchor, mmodule, cleanup_virtual)
#print "{class_name}: {self}/{mtype}/{anchor} -> {self}/{resolved_reciever}/{anchor} -> {verbatim_bound}/{mtype}/{anchor} -> {res}"
- return res
+
+ # What to return here? There is a bunch a special cases:
+ # If 'cleanup_virtual' we must return the resolved type, since we cannot return self
+ if cleanup_virtual then return res
+ # If the reciever is a intern class, then the virtual type cannot be redefined since there is no possible subclass. self is just fixed. so simply return the resolution
+ if resolved_reciever isa MNullableType then resolved_reciever = resolved_reciever.mtype
+ if resolved_reciever.as(MClassType).mclass.kind == enum_kind then return res
+ # If the resolved type isa MVirtualType, it means that self was bound to it, and cannot be unbound. self is just fixed. so return the resolution.
+ if res isa MVirtualType then return res
+ # It the resolved type isa intern class, then there is no possible valid redefinition is any potentiel subclass. self is just fixed. so simply return the resolution
+ if res isa MClassType and res.mclass.kind == enum_kind then return res
+ # TODO: Add 'fixed' virtual type in the specification.
+ # TODO: What if bound to a MParameterType?
+ # Note that Nullable types can always be redefined by the non nullable version, so there is no specific case on it.
+
+ # If anything apply, then `self' cannot be resolved, so return self
+ return self
+ end
+
+ redef fun can_resolve_for(mtype, anchor, mmodule)
+ do
+ if mtype.need_anchor then
+ assert anchor != null
+ mtype = mtype.anchor_to(mmodule, anchor)
+ end
+ return mtype.has_mproperty(mmodule, mproperty)
end
redef fun to_s do return self.mproperty.to_s
# class B[F]
# super A[Array[F]]
# end
-# In the class definition B[F], `F' is a valid type but `E' is not.
-# However, `self.e' is a valid method call, and the signature of `e' is
-# declared `e: E'.
+# In the class definition B[F], `F` is a valid type but `E` is not.
+# However, `self.e` is a valid method call, and the signature of `e` is
+# declared `e: E`.
#
# Note that parameter types are shared among class refinements.
-# Therefore parameter only have an internal name (see `to_s' for details).
-# TODO: Add a 'name_for' to get better messages.
+# Therefore parameter only have an internal name (see `to_s` for details).
+# TODO: Add a `name_for` to get better messages.
class MParameterType
super MType
redef fun model do return self.mclass.intro_mmodule.model
# The position of the parameter (0 for the first parameter)
- # FIXME: is `position' a better name?
+ # FIXME: is `position` a better name?
var rank: Int
# Internal name of the parameter type
if t.mclass == goalclass then
# Yeah! c specialize goalclass with a "super `t'". So the question is what is the argument of f
# FIXME: Here, we stop on the first goal. Should we check others and detect inconsistencies?
- assert t isa MGenericType
var res = t.arguments[self.rank]
return res
end
redef fun resolve_for(mtype, anchor, mmodule, cleanup_virtual)
do
+ assert can_resolve_for(mtype, anchor, mmodule)
#print "{class_name}: {self}/{mtype}/{anchor}?"
if mtype isa MGenericType and mtype.mclass == self.mclass then
# The point of the function it to get the bound of the virtual type that make sense for mtype
# But because mtype is maybe a virtual/formal type, we need to get a real receiver first
# FIXME: What happend here is far from clear. Thus this part must be validated and clarified
- var resolved_receiver = mtype.resolve_for(anchor.mclass.mclass_type, anchor, mmodule, true)
+ var resolved_receiver
+ if mtype.need_anchor then
+ assert anchor != null
+ resolved_receiver = mtype.resolve_for(anchor.mclass.mclass_type, anchor, mmodule, true)
+ else
+ resolved_receiver = mtype
+ end
if resolved_receiver isa MNullableType then resolved_receiver = resolved_receiver.mtype
if resolved_receiver isa MParameterType then
assert resolved_receiver.mclass == anchor.mclass
- resolved_receiver = anchor.as(MGenericType).arguments[resolved_receiver.rank]
+ resolved_receiver = anchor.arguments[resolved_receiver.rank]
if resolved_receiver isa MNullableType then resolved_receiver = resolved_receiver.mtype
end
- assert resolved_receiver isa MClassType else print "{class_name}: {self}/{mtype}/{anchor}? {resolved_receiver}"
+ assert resolved_receiver isa MClassType
# Eh! The parameter is in the current class.
# So we return the corresponding argument, no mater what!
if resolved_receiver.mclass == self.mclass then
- assert resolved_receiver isa MGenericType
var res = resolved_receiver.arguments[self.rank]
#print "{class_name}: {self}/{mtype}/{anchor} -> direct {res}"
return res
end
- resolved_receiver = resolved_receiver.resolve_for(anchor, anchor, mmodule, false)
+ if resolved_receiver.need_anchor then
+ assert anchor != null
+ resolved_receiver = resolved_receiver.resolve_for(anchor, null, mmodule, false)
+ end
# Now, we can get the bound
var verbatim_bound = lookup_bound(mmodule, resolved_receiver)
# The bound is exactly as declared in the "type" property, so we must resolve it again
return res
end
+ redef fun can_resolve_for(mtype, anchor, mmodule)
+ do
+ if mtype.need_anchor then
+ assert anchor != null
+ mtype = mtype.anchor_to(mmodule, anchor)
+ end
+ return mtype.collect_mclassdefs(mmodule).has(mclass.intro)
+ end
+
init(mclass: MClass, rank: Int)
do
self.mclass = mclass
end
# A type prefixed with "nullable"
-# FIXME Stub implementation
class MNullableType
super MType
init(mtype: MType)
do
self.mtype = mtype
+ self.to_s = "nullable {mtype}"
end
- redef fun to_s do return "nullable {mtype}"
+ redef var to_s: String
redef fun need_anchor do return mtype.need_anchor
redef fun as_nullable do return self
return res.as_nullable
end
+ redef fun can_resolve_for(mtype, anchor, mmodule)
+ do
+ return self.mtype.can_resolve_for(mtype, anchor, mmodule)
+ end
+
+ redef fun depth do return self.mtype.depth
+
+ redef fun length do return self.mtype.length
+
redef fun collect_mclassdefs(mmodule)
do
assert not self.need_anchor
# The type of the only value null
#
-# The is only one null type per model, see `MModel::null_type'.
+# The is only one null type per model, see `MModel::null_type`.
class MNullType
super MType
redef var model: Model
redef fun as_nullable do return self
redef fun need_anchor do return false
redef fun resolve_for(mtype, anchor, mmodule, cleanup_virtual) do return self
+ redef fun can_resolve_for(mtype, anchor, mmodule) do return true
redef fun collect_mclassdefs(mmodule) do return new HashSet[MClassDef]
redef fun collect_mtypes(mmodule) do return new HashSet[MClassType]
end
-# A signature of a method (or a closure)
+# A signature of a method
class MSignature
super MType
# The each parameter (in order)
var mparameters: Array[MParameter]
- var mclosures = new Array[MParameter]
-
# The return type (null for a procedure)
var return_mtype: nullable MType
+ redef fun depth
+ do
+ var dmax = 0
+ var t = self.return_mtype
+ if t != null then dmax = t.depth
+ for p in mparameters do
+ var d = p.mtype.depth
+ if d > dmax then dmax = d
+ end
+ return dmax + 1
+ end
+
+ redef fun length
+ do
+ var res = 1
+ var t = self.return_mtype
+ if t != null then res += t.length
+ for p in mparameters do
+ res += p.mtype.length
+ end
+ return res
+ end
+
# REQUIRE: 1 <= mparameters.count p -> p.is_vararg
init(mparameters: Array[MParameter], return_mtype: nullable MType)
do
self.vararg_rank = vararg_rank
end
- # The rank of the ellipsis (...) for vararg (starting from 0).
+ # The rank of the ellipsis (`...`) for vararg (starting from 0).
# value is -1 if there is no vararg.
# Example: for "(a: Int, b: Bool..., c: Char)" #-> vararg_rank=1
var vararg_rank: Int
redef fun to_s
do
- var b = new Buffer
+ var b = new FlatBuffer
if not mparameters.is_empty then
b.append("(")
for i in [0..mparameters.length[ do
return b.to_s
end
- redef fun resolve_for(mtype: MType, anchor: MClassType, mmodule: MModule, cleanup_virtual: Bool): MSignature
+ redef fun resolve_for(mtype: MType, anchor: nullable MClassType, mmodule: MModule, cleanup_virtual: Bool): MSignature
do
var params = new Array[MParameter]
for p in self.mparameters do
ret = ret.resolve_for(mtype, anchor, mmodule, cleanup_virtual)
end
var res = new MSignature(params, ret)
- for p in self.mclosures do
- res.mclosures.add(p.resolve_for(mtype, anchor, mmodule, cleanup_virtual))
- end
return res
end
end
# Is the parameter a vararg?
var is_vararg: Bool
- fun resolve_for(mtype: MType, anchor: MClassType, mmodule: MModule, cleanup_virtual: Bool): MParameter
+ redef fun to_s
+ do
+ if is_vararg then
+ return "{name}: {mtype}..."
+ else
+ return "{name}: {mtype}"
+ end
+ end
+
+ fun resolve_for(mtype: MType, anchor: nullable MClassType, mmodule: MModule, cleanup_virtual: Bool): MParameter
do
if not self.mtype.need_anchor then return self
var newtype = self.mtype.resolve_for(mtype, anchor, mmodule, cleanup_virtual)
# A service (global property) that generalize method, attribute, etc.
#
-# MProperty are global to the model; it means that a MProperty is not bound
+# `MProperty` are global to the model; it means that a `MProperty` is not bound
# to a specific `MModule` nor a specific `MClass`.
#
-# A MProperty gather definitions (see `mpropdefs') ; one for the introduction
+# A MProperty gather definitions (see `mpropdefs`) ; one for the introduction
# and the other in subclasses and in refinements.
#
-# A MProperty is used to denotes services in polymorphic way (ie. independent
+# A `MProperty` is used to denotes services in polymorphic way (ie. independent
# of any dynamic type).
-# For instance, a call site "x.foo" is associated to a MProperty.
+# For instance, a call site "x.foo" is associated to a `MProperty`.
abstract class MProperty
+ super MEntity
+
# The associated MPropDef subclass.
# The two specialization hierarchy are symmetric.
type MPROPDEF: MPropDef
var mpropdefs: Array[MPROPDEF] = new Array[MPROPDEF]
# The definition that introduced the property
- # Warning: the introduction is the first `MPropDef' object
+ # Warning: the introduction is the first `MPropDef` object
# associated to self. If self is just created without having any
# associated definition, this method will abort
fun intro: MPROPDEF do return mpropdefs.first
- # Alias for `name'
+ # Alias for `name`
redef fun to_s do return name
# Return the most specific property definitions defined or inherited by a type.
end
# Second, filter the most specific ones
- var res = new Array[MPROPDEF]
- for pd1 in candidates do
- var cd1 = pd1.mclassdef
- var c1 = cd1.mclass
- var keep = true
- for pd2 in candidates do
- if pd2 == pd1 then continue # do not compare with self!
- var cd2 = pd2.mclassdef
- var c2 = cd2.mclass
- if c2.mclass_type == c1.mclass_type then
- if cd2.mmodule.in_importation <= cd1.mmodule then
- # cd2 refines cd1; therefore we skip pd1
- keep = false
- break
- end
- else if cd2.bound_mtype.is_subtype(mmodule, null, cd1.bound_mtype) then
- # cd2 < cd1; therefore we skip pd1
- keep = false
- break
- end
- end
- if keep then
- res.add(pd1)
- end
- end
- if res.is_empty then
- print "All lost! {candidates.join(", ")}"
- # FIXME: should be abort!
- end
- self.lookup_definitions_cache[mmodule, mtype] = res
- return res
+ return select_most_specific(mmodule, candidates)
end
private var lookup_definitions_cache: HashMap2[MModule, MType, Array[MPROPDEF]] = new HashMap2[MModule, MType, Array[MPROPDEF]]
#
# If you want the really most specific property, then look at `lookup_next_definition`
#
- # FIXME: Move to MPropDef?
- fun lookup_super_definitions(mmodule: MModule, mtype: MType): Array[MPropDef]
+ # FIXME: Move to `MPropDef`?
+ fun lookup_super_definitions(mmodule: MModule, mtype: MType): Array[MPROPDEF]
do
assert not mtype.need_anchor
if mtype isa MNullableType then mtype = mtype.mtype
# First, select all candidates
- var candidates = new Array[MPropDef]
+ var candidates = new Array[MPROPDEF]
for mpropdef in self.mpropdefs do
# If the definition is not imported by the module, then skip
if not mmodule.in_importation <= mpropdef.mclassdef.mmodule then continue
if candidates.length <= 1 then return candidates
# Second, filter the most specific ones
- var res = new Array[MPropDef]
+ return select_most_specific(mmodule, candidates)
+ end
+
+ # Return an array containing olny the most specific property definitions
+ # This is an helper function for `lookup_definitions` and `lookup_super_definitions`
+ private fun select_most_specific(mmodule: MModule, candidates: Array[MPROPDEF]): Array[MPROPDEF]
+ do
+ var res = new Array[MPROPDEF]
for pd1 in candidates do
var cd1 = pd1.mclassdef
var c1 = cd1.mclass
var cd2 = pd2.mclassdef
var c2 = cd2.mclass
if c2.mclass_type == c1.mclass_type then
- if cd2.mmodule.in_importation <= cd1.mmodule then
+ if cd2.mmodule.in_importation < cd1.mmodule then
# cd2 refines cd1; therefore we skip pd1
keep = false
break
end
- else if cd2.bound_mtype.is_subtype(mmodule, null, cd1.bound_mtype) then
+ else if cd2.bound_mtype.is_subtype(mmodule, null, cd1.bound_mtype) and cd2.bound_mtype != cd1.bound_mtype then
# cd2 < cd1; therefore we skip pd1
keep = false
break
end
# Return the most specific definition in the linearization of `mtype`.
- # If mtype does not know mproperty then null is returned.
#
# If you want to know the next properties in the linearization,
# look at `MPropDef::lookup_next_definition`.
#
- # FIXME: NOT YET IMPLEMENTED
+ # FIXME: the linearisation is still unspecified
#
- # REQUIRE: not mtype.need_anchor
- fun lookup_first_definition(mmodule: MModule, mtype: MType): nullable MPROPDEF
+ # REQUIRE: `not mtype.need_anchor`
+ # REQUIRE: `mtype.has_mproperty(mmodule, self)`
+ fun lookup_first_definition(mmodule: MModule, mtype: MType): MPROPDEF
+ do
+ assert mtype.has_mproperty(mmodule, self)
+ return lookup_all_definitions(mmodule, mtype).first
+ end
+
+ # Return all definitions in a linearisation order
+ # Most speficic first, most general last
+ fun lookup_all_definitions(mmodule: MModule, mtype: MType): Array[MPROPDEF]
do
assert not mtype.need_anchor
- return null
+ if mtype isa MNullableType then mtype = mtype.mtype
+
+ var cache = self.lookup_all_definitions_cache[mmodule, mtype]
+ if cache != null then return cache
+
+ #print "select prop {mproperty} for {mtype} in {self}"
+ # First, select all candidates
+ var candidates = new Array[MPROPDEF]
+ for mpropdef in self.mpropdefs do
+ # If the definition is not imported by the module, then skip
+ if not mmodule.in_importation <= mpropdef.mclassdef.mmodule then continue
+ # If the definition is not inherited by the type, then skip
+ if not mtype.is_subtype(mmodule, null, mpropdef.mclassdef.bound_mtype) then continue
+ # Else, we keep it
+ candidates.add(mpropdef)
+ end
+ # Fast track for only one candidate
+ if candidates.length <= 1 then
+ self.lookup_all_definitions_cache[mmodule, mtype] = candidates
+ return candidates
+ end
+
+ mmodule.linearize_mpropdefs(candidates)
+ candidates = candidates.reversed
+ self.lookup_all_definitions_cache[mmodule, mtype] = candidates
+ return candidates
end
+
+ private var lookup_all_definitions_cache: HashMap2[MModule, MType, Array[MPROPDEF]] = new HashMap2[MModule, MType, Array[MPROPDEF]]
end
# A global method
super
end
+ # Is the property defined at the top_level of the module?
+ # Currently such a property are stored in `Object`
+ var is_toplevel: Bool writable = false
+
# Is the property a constructor?
# Warning, this property can be inherited by subclasses with or without being a constructor
- # therefore, you should use `is_init_for' the verify if the property is a legal constructor for a given class
+ # therefore, you should use `is_init_for` the verify if the property is a legal constructor for a given class
var is_init: Bool writable = false
# The the property a 'new' contructor?
# A definition of a property (local property)
#
-# Unlike MProperty, a MPropDef is a local definition that belong to a
+# Unlike `MProperty`, a `MPropDef` is a local definition that belong to a
# specific class definition (which belong to a specific module)
abstract class MPropDef
+ super MEntity
- # The associated MProperty subclass.
+ # The associated `MProperty` subclass.
# the two specialization hierarchy are symmetric
type MPROPERTY: MProperty
self.location = location
mclassdef.mpropdefs.add(self)
mproperty.mpropdefs.add(self)
+ self.to_s = "{mclassdef}#{mproperty}"
end
# Internal name combining the module, the class and the property
# Example: "mymodule#MyClass#mymethod"
- redef fun to_s
- do
- return "{mclassdef}#{mproperty}"
- end
+ redef var to_s: String
# Is self the definition that introduce the property?
fun is_intro: Bool do return mproperty.intro == self
# Return the next definition in linearization of `mtype`.
- # If there is no next method then null is returned.
#
# This method is used to determine what method is called by a super.
#
- # FIXME: NOT YET IMPLEMENTED
- #
- # REQUIRE: not mtype.need_anchor
- fun lookup_next_definition(mmodule: MModule, mtype: MType): nullable MPROPDEF
+ # REQUIRE: `not mtype.need_anchor`
+ fun lookup_next_definition(mmodule: MModule, mtype: MType): MPROPDEF
do
assert not mtype.need_anchor
- return null
+
+ var mpropdefs = self.mproperty.lookup_all_definitions(mmodule, mtype)
+ var i = mpropdefs.iterator
+ while i.is_ok and i.item != self do i.next
+ assert has_property: i.is_ok
+ i.next
+ assert has_next_property: i.is_ok
+ return i.item
end
end
# The signature attached to the property definition
var msignature: nullable MSignature writable = null
+
+ # Is the method definition abstract?
+ var is_abstract: Bool writable = false
+
+ # Is the method definition intern?
+ var is_intern writable = false
+
+ # Is the method definition extern?
+ var is_extern writable = false
end
# A local definition of an attribute
# A kind of class.
#
-# * abstract_kind
-# * concrete_kind
-# * interface_kind
-# * enum_kind
-# * extern_kind
+# * `abstract_kind`
+# * `concrete_kind`
+# * `interface_kind`
+# * `enum_kind`
+# * `extern_kind`
#
# Note this class is basically an enum.
# FIXME: use a real enum once user-defined enums are available
self.to_s = s
self.need_init = need_init
end
+
+ # Can a class of kind `self` specializes a class of kine `other`?
+ fun can_specialize(other: MClassKind): Bool
+ do
+ if other == interface_kind then return true # everybody can specialize interfaces
+ if self == interface_kind or self == enum_kind then
+ # no other case for interfaces
+ return false
+ else if self == extern_kind then
+ # only compatible with themselve
+ return self == other
+ else if other == enum_kind or other == extern_kind then
+ # abstract_kind and concrete_kind are incompatible
+ return false
+ end
+ # remain only abstract_kind and concrete_kind
+ return true
+ end
end
fun abstract_kind: MClassKind do return once new MClassKind("abstract class", true)
fun concrete_kind: MClassKind do return once new MClassKind("class", true)
fun interface_kind: MClassKind do return once new MClassKind("interface", false)
fun enum_kind: MClassKind do return once new MClassKind("enum", false)
-fun extern_kind: MClassKind do return once new MClassKind("extern", false)
+fun extern_kind: MClassKind do return once new MClassKind("extern class", false)