import toolcontext
import phase
+private import more_collections
+
###
redef class ToolContext
fun modelbuilder: ModelBuilder do return modelbuilder_real.as(not null)
private var modelbuilder_real: nullable ModelBuilder = null
- var modelize_class_phase: Phase = new ModelizeClassPhase(self, null)
-end
-
-private class ModelizeClassPhase
- super Phase
-
- redef fun process_nmodule(nmodule)
- do
- toolcontext.modelbuilder.build_classes(nmodule)
- end
end
# A model builder knows how to load nit source files and build the associated model
nmodules.add(mmodule2nmodule[mm])
end
toolcontext.run_phases(nmodules)
+
+ if toolcontext.opt_only_metamodel.value then
+ self.toolcontext.info("*** ONLY METAMODEL", 1)
+ exit(0)
+ end
end
# Instantiate a modelbuilder for a model and a toolcontext
self.toolcontext.info("*** END PARSE: {time1-time0} ***", 2)
self.toolcontext.check_errors
+
+ if toolcontext.opt_only_parse.value then
+ self.toolcontext.info("*** ONLY PARSE...", 1)
+ exit(0)
+ end
+
return mmodules
end
if sup == null then continue # Skip error
imported_modules.add(sup)
var mvisibility = aimport.n_visibility.mvisibility
+ if mvisibility == protected_visibility then
+ error(aimport.n_visibility, "Error: only properties can be protected.")
+ return
+ end
mmodule.set_visibility_for(sup, mvisibility)
end
if stdimport then
# All the loaded modules
var nmodules: Array[AModule] = new Array[AModule]
- # Visit the AST and create the MClass objects
- private fun build_a_mclass(nmodule: AModule, nclassdef: AClassdef)
- do
- var mmodule = nmodule.mmodule.as(not null)
-
- var name: String
- var nkind: nullable AClasskind
- var mkind: MClassKind
- var nvisibility: nullable AVisibility
- var mvisibility: nullable MVisibility
- var arity = 0
- if nclassdef isa AStdClassdef then
- name = nclassdef.n_id.text
- nkind = nclassdef.n_classkind
- mkind = nkind.mkind
- nvisibility = nclassdef.n_visibility
- mvisibility = nvisibility.mvisibility
- arity = nclassdef.n_formaldefs.length
- else if nclassdef isa ATopClassdef then
- name = "Object"
- nkind = null
- mkind = interface_kind
- nvisibility = null
- mvisibility = public_visibility
- else if nclassdef isa AMainClassdef then
- name = "Sys"
- nkind = null
- mkind = concrete_kind
- nvisibility = null
- mvisibility = public_visibility
- else
- abort
- end
-
- var mclass = try_get_mclass_by_name(nclassdef, mmodule, name)
- if mclass == null then
- mclass = new MClass(mmodule, name, arity, 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}.")
- 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.")
- return
- else if mclass.arity != arity then
- error(nclassdef, "Redef error: Formal parameter arity missmatch; got {arity}, expected {mclass.arity}.")
- 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}")
- 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}")
- end
- nclassdef.mclass = mclass
- nmodule.mclass2nclassdef[mclass] = nclassdef
- end
-
- # Visit the AST and create the MClassDef objects
- private fun build_a_mclassdef(nmodule: AModule, nclassdef: AClassdef)
- do
- var mmodule = nmodule.mmodule.as(not null)
- var objectclass = try_get_mclass_by_name(nmodule, mmodule, "Object")
- var mclass = nclassdef.mclass
- if mclass == null then return # Skip error
- #var mclassdef = nclassdef.mclassdef.as(not null)
-
- var names = new Array[String]
- var bounds = new Array[MType]
- if nclassdef isa AStdClassdef and mclass.arity > 0 then
- # Collect formal parameter names
- for i in [0..mclass.arity[ do
- 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")
- return
- end
- names.add(ptname)
- end
-
- # Revolve bound for formal parameter names
- for i in [0..mclass.arity[ do
- var nfd = nclassdef.n_formaldefs[i]
- var nfdt = nfd.n_type
- if nfdt != null then
- var bound = resolve_mtype_unchecked(nclassdef, nfdt, false)
- if bound == null then return # Forward error
- if bound.need_anchor then
- # No F-bounds!
- error(nfd, "Error: Formal parameter type `{names[i]}' bounded with a formal parameter type")
- else
- bounds.add(bound)
- end
- else if mclass.mclassdefs.is_empty then
- # No bound, then implicitely bound by nullable Object
- bounds.add(objectclass.mclass_type.as_nullable)
- else
- # Inherit the bound
- bounds.add(mclass.intro.bound_mtype.arguments[i])
- end
- end
- end
-
- var bound_mtype = mclass.get_mtype(bounds)
- var mclassdef = new MClassDef(mmodule, bound_mtype, nclassdef.location, names)
- nclassdef.mclassdef = mclassdef
- self.mclassdef2nclassdef[mclassdef] = nclassdef
-
- 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)
- end
- end
-
- # Visit the AST and set the super-types of the MClassdef objects
- private fun collect_a_mclassdef_inheritance(nmodule: AModule, nclassdef: AClassdef)
- do
- var mmodule = nmodule.mmodule.as(not null)
- var objectclass = try_get_mclass_by_name(nmodule, mmodule, "Object")
- var mclass = nclassdef.mclass.as(not null)
- var mclassdef = nclassdef.mclassdef.as(not null)
-
- var specobject = true
- var supertypes = new Array[MClassType]
- if nclassdef isa AStdClassdef then
- for nsc in nclassdef.n_superclasses do
- specobject = false
- var ntype = nsc.n_type
- var mtype = resolve_mtype_unchecked(nclassdef, 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")
- return
- end
- supertypes.add mtype
- #print "new super : {mclass} < {mtype}"
- end
- end
- if specobject and mclass.name != "Object" and objectclass != null and mclassdef.is_intro then
- supertypes.add objectclass.mclass_type
- end
-
- mclassdef.set_supertypes(supertypes)
- if not supertypes.is_empty then self.toolcontext.info("{mclassdef} new super-types: {supertypes.join(", ")}", 3)
- end
-
- # Check the validity of the specialization heirarchy
- private fun check_supertypes(nmodule: AModule, nclassdef: AClassdef)
- do
- var mmodule = nmodule.mmodule.as(not null)
- var objectclass = try_get_mclass_by_name(nmodule, mmodule, "Object")
- var mclass = nclassdef.mclass.as(not null)
- var mclassdef = nclassdef.mclassdef.as(not null)
-
- 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}")
- 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
- # Force building recursively
- if nmodule.build_classes_is_done then return
- nmodule.build_classes_is_done = true
- var mmodule = nmodule.mmodule.as(not null)
- for imp in mmodule.in_importation.direct_greaters do
-
- build_classes(mmodule2nmodule[imp])
- end
-
- # Create all classes
- for nclassdef in nmodule.n_classdefs do
- self.build_a_mclass(nmodule, nclassdef)
- end
-
- # Create all classdefs
- for nclassdef in nmodule.n_classdefs do
- self.build_a_mclassdef(nmodule, nclassdef)
- end
-
- for nclassdef in nmodule.n_classdefs do
- if nclassdef.mclassdef == null then return # forward error
- end
-
- # Create inheritance on all classdefs
- for nclassdef in nmodule.n_classdefs do
- self.collect_a_mclassdef_inheritance(nmodule, nclassdef)
- end
-
- # Create the mclassdef hierarchy
- for nclassdef in nmodule.n_classdefs do
- var mclassdef = nclassdef.mclassdef.as(not null)
- mclassdef.add_in_hierarchy
- end
-
- # Check inheritance
- for nclassdef in nmodule.n_classdefs do
- self.check_supertypes(nmodule, nclassdef)
- end
-
- # Check unchecked ntypes
- for nclassdef in nmodule.n_classdefs do
- if nclassdef isa AStdClassdef then
- # check bound of formal parameter
- for nfd in nclassdef.n_formaldefs do
- var nfdt = nfd.n_type
- if nfdt != null and nfdt.mtype != null then
- var bound = resolve_mtype(nclassdef, nfdt)
- if bound == null then return # Forward error
- end
- end
- # check declared super types
- for nsc in nclassdef.n_superclasses do
- var ntype = nsc.n_type
- if ntype.mtype != null then
- var mtype = resolve_mtype(nclassdef, ntype)
- if mtype == null then return # Forward error
- end
- end
- end
-
- end
-
- # TODO: Check that the super-class is not intrusive
-
- # TODO: Check that the super-class is not already known (by transitivity)
- end
-
# Register the nmodule associated to each mmodule
# FIXME: why not refine the MModule class with a nullable attribute?
var mmodule2nmodule: HashMap[MModule, AModule] = new HashMap[MModule, AModule]
- # Register the nclassdef associated to each mclassdef
- # FIXME: why not refine the MClassDef class with a nullable attribute?
- var mclassdef2nclassdef: HashMap[MClassDef, AClassdef] = new HashMap[MClassDef, AClassdef]
-
- # Return the static type associated to the node `ntype'.
- # `classdef' is the context where the call is made (used to understand formal types)
- # The mmodule used as context is `nclassdef.mmodule'
- # In case of problem, an error is displayed on `ntype' and null is returned.
- # FIXME: the name "resolve_mtype" is awful
- fun resolve_mtype_unchecked(nclassdef: AClassdef, ntype: AType, with_virtual: Bool): nullable MType
- do
- var name = ntype.n_id.text
- var mclassdef = nclassdef.mclassdef
- var mmodule = nclassdef.parent.as(AModule).mmodule.as(not null)
- var res: MType
-
- # Check virtual type
- if mclassdef != null and with_virtual then
- var prop = try_get_mproperty_by_name(ntype, mclassdef, name).as(nullable MVirtualTypeProp)
- if prop != null then
- if not ntype.n_types.is_empty then
- error(ntype, "Type error: formal type {name} cannot have formal parameters.")
- end
- res = prop.mvirtualtype
- if ntype.n_kwnullable != null then res = res.as_nullable
- ntype.mtype = res
- return res
- end
- end
-
- # Check parameter type
- if mclassdef != null and mclassdef.parameter_names.has(name) then
- if not ntype.n_types.is_empty then
- error(ntype, "Type error: formal type {name} cannot have formal parameters.")
- end
- for i in [0..mclassdef.parameter_names.length[ do
- if mclassdef.parameter_names[i] == name then
- res = mclassdef.mclass.mclass_type.arguments[i]
- if ntype.n_kwnullable != null then res = res.as_nullable
- ntype.mtype = res
- return res
- end
- end
- abort
- end
-
- # Check class
- var mclass = try_get_mclass_by_name(ntype, mmodule, name)
- if mclass != null then
- var arity = ntype.n_types.length
- if arity != mclass.arity then
- if arity == 0 then
- error(ntype, "Type error: '{name}' is a generic class.")
- else if mclass.arity == 0 then
- error(ntype, "Type error: '{name}' is not a generic class.")
- else
- error(ntype, "Type error: '{name}' has {mclass.arity} parameters ({arity} are provided).")
- end
- return null
- end
- if arity == 0 then
- res = mclass.mclass_type
- if ntype.n_kwnullable != null then res = res.as_nullable
- ntype.mtype = res
- return res
- else
- var mtypes = new Array[MType]
- for nt in ntype.n_types do
- var mt = resolve_mtype_unchecked(nclassdef, nt, with_virtual)
- if mt == null then return null # Forward error
- mtypes.add(mt)
- end
- res = mclass.get_mtype(mtypes)
- if ntype.n_kwnullable != null then res = res.as_nullable
- ntype.mtype = res
- return res
- end
- end
-
- # If everything fail, then give up :(
- error(ntype, "Type error: class {name} not found in module {mmodule}.")
- return null
- end
-
- # Return the static type associated to the node `ntype'.
- # `classdef' is the context where the call is made (used to understand formal types)
- # The mmodule used as context is `nclassdef.mmodule'
- # In case of problem, an error is displayed on `ntype' and null is returned.
- # FIXME: the name "resolve_mtype" is awful
- fun resolve_mtype(nclassdef: AClassdef, ntype: AType): nullable MType
- do
- var mtype = ntype.mtype
- if mtype == null then mtype = resolve_mtype_unchecked(nclassdef, ntype, true)
- if mtype == null then return null # Forward error
-
- if ntype.checked_mtype then return mtype
- if mtype isa MGenericType then
- var mmodule = nclassdef.parent.as(AModule).mmodule.as(not null)
- var mclassdef = nclassdef.mclassdef
- var mclass = mtype.mclass
- for i in [0..mclass.arity[ do
- var bound = mclass.intro.bound_mtype.arguments[i]
- var nt = ntype.n_types[i]
- var mt = resolve_mtype(nclassdef, nt)
- if mt == null then return null # forward error
- if not mt.is_subtype(mmodule, mclassdef.bound_mtype, bound) then
- error(nt, "Type error: expected {bound}, got {mt}")
- return null
- end
- end
- end
- ntype.checked_mtype = true
- return mtype
- end
# Helper function to display an error on a node.
# Alias for `self.toolcontext.error(n.hot_location, text)'
end
# Force to get the primitive method named `name' on the type `recv' or do a fatal error on `n'
- fun force_get_primitive_method(n: ANode, name: String, recv: MType, mmodule: MModule): MMethod
+ fun force_get_primitive_method(n: ANode, name: String, recv: MClass, mmodule: MModule): MMethod
do
var res = mmodule.try_get_primitive_method(name, recv)
if res == null then
var mmodule: nullable MModule
# Flag that indicate if the importation is already completed
var is_importation_done: Bool = false
- # Flag that indicate if the class and prop building is already completed
- var build_classes_is_done: Bool = false
- # What is the AClassdef associated to a MClass?
- # Used to check multiple definition of a class.
- var mclass2nclassdef: Map[MClass, AClassdef] = new HashMap[MClass, AClassdef]
-
-end
-
-redef class AClassdef
- # The associated MClass once build by a `ModelBuilder'
- var mclass: nullable MClass
- # The associated MClassDef once build by a `ModelBuilder'
- var mclassdef: nullable MClassDef
-end
-
-redef class AClasskind
- # The class kind associated with the AST node class
- private fun mkind: MClassKind is abstract
-end
-redef class AConcreteClasskind
- redef fun mkind do return concrete_kind
-end
-redef class AAbstractClasskind
- redef fun mkind do return abstract_kind
-end
-redef class AInterfaceClasskind
- redef fun mkind do return interface_kind
-end
-redef class AEnumClasskind
- redef fun mkind do return enum_kind
-end
-redef class AExternClasskind
- redef fun mkind do return extern_kind
end
redef class AVisibility
redef class APrivateVisibility
redef fun mvisibility do return private_visibility
end
-
-redef class AType
- # The mtype associated to the node
- var mtype: nullable MType = null
-
- # Is the mtype a valid one?
- var checked_mtype: Bool = false
-end
\ No newline at end of file