class MMSrcModule
special MMModule
# The related AST node
- readable attr _node: AModule
+ readable var _node: AModule
# Concrete NIT source local classs by name
- readable attr _src_local_classes: Map[Symbol, MMSrcLocalClass]
+ readable var _src_local_classes: Map[Symbol, MMSrcLocalClass]
- init(c: MMContext, source: AModule, dir: MMDirectory, name: Symbol)
+ init(c: MMContext, source: AModule, dir: MMDirectory, name: Symbol, filename: String)
do
- super(name, dir, c)
+ super(name, dir, c, filename)
_node = source
_src_local_classes = new HashMap[Symbol, MMSrcLocalClass]
end
redef class MMGlobalClass
# Check that a module can access a class
- meth check_visibility(v: AbsSyntaxVisitor, n: PNode, cm: MMSrcModule): Bool do
+ fun check_visibility(v: AbsSyntaxVisitor, n: PNode, cm: MMSrcModule): Bool do
var pm = intro.module
assert pm isa MMSrcModule
var vpm = cm.visibility_for(pm)
class MMSrcLocalClass
special MMConcreteClass
# The related AST nodes
- readable attr _nodes: Array[PClassdef]
+ readable var _nodes: Array[PClassdef]
# Concrete NIT source generic formal parameter by name
- readable writable attr _formal_dict: Map[Symbol, MMTypeFormalParameter]
+ readable var _formal_dict: Map[Symbol, MMTypeFormalParameter] = new HashMap[Symbol, MMTypeFormalParameter]
# Concrete NIT source properties by name
- readable attr _src_local_properties: Map[Symbol, MMLocalProperty]
+ readable var _src_local_properties: Map[Symbol, MMLocalProperty]
init(mod: MMSrcModule, n: Symbol, cla: PClassdef, a: Int)
do
redef class MMGlobalProperty
# Check that a module can access a property
- meth check_visibility(v: AbsSyntaxVisitor, n: PNode, cm: MMSrcModule, allows_protected: Bool): Bool do
+ fun check_visibility(v: AbsSyntaxVisitor, n: PNode, cm: MMSrcModule, allows_protected: Bool): Bool do
var pm = local_class.module
assert pm isa MMSrcModule
var vpm = cm.visibility_for(pm)
redef class MMLocalProperty
# The attached node (if any)
- meth node: PNode do return null
+ fun node: nullable PNode do return null
# Is the concrete method defined as init
- meth is_init: Bool do return false
+ fun is_init: Bool do return false
end
# Concrete NIT source attribute
class MMSrcAttribute
special MMAttribute
- redef readable attr _node: AAttrPropdef
+ redef readable var _node: AAttrPropdef
init(name: Symbol, cla: MMLocalClass, n: AAttrPropdef)
do
super(name, cla)
# Concrete NIT source method for an automatic accesor
class MMAttrImplementationMethod
special MMSrcMethod
- redef readable attr _node: AAttrPropdef
+ redef readable var _node: AAttrPropdef
init(name: Symbol, cla: MMLocalClass, n: AAttrPropdef)
do
super(name, cla)
# Concrete NIT source method for an explicit method
class MMMethSrcMethod
special MMSrcMethod
- redef meth is_init do return _node isa AConcreteInitPropdef
- redef readable attr _node: AMethPropdef
- init(name: Symbol, cla: MMLocalClass, n: AMethPropdef)
+ redef fun is_init do return _node isa AConcreteInitPropdef
+ redef readable var _node: nullable AMethPropdef
+ init(name: Symbol, cla: MMLocalClass, n: nullable AMethPropdef)
do
super(name, cla)
_node = n
class MMSrcTypeProperty
special MMLocalProperty
special MMTypeProperty
- redef readable attr _node: ATypePropdef
+ redef readable var _node: ATypePropdef
init(name: Symbol, cla: MMLocalClass, n: ATypePropdef)
do
super(name, cla)
# Concrete NIT implicit constructor
class MMImplicitInit
special MMMethSrcMethod
- redef meth is_init do return true
- readable attr _unassigned_attributes: Array[MMSrcAttribute]
- readable attr _super_inits: Array[MMLocalProperty]
+ redef fun is_init do return true
+ readable var _unassigned_attributes: Array[MMSrcAttribute]
+ readable var _super_inits: Array[MMLocalProperty]
init(cla: MMLocalClass, unassigned_attributes: Array[MMSrcAttribute], super_inits: Array[MMLocalProperty])
do
super(once "init".to_symbol, cla, null)
# Local variables
abstract class Variable
# Name of the variable
- readable attr _name: Symbol
+ readable var _name: Symbol
# Declaration AST node
- readable attr _decl: PNode
+ readable var _decl: nullable PNode
# Static type
- readable writable attr _stype: MMType
+ readable writable var _stype: nullable MMType
- redef meth to_s do return _name.to_s
+ redef fun to_s do return _name.to_s
- meth kind: String is abstract
+ fun kind: String is abstract
- init(n: Symbol, d: PNode)
+ init(n: Symbol, d: nullable PNode)
do
- #assert n != null
- #assert d != null
_name = n
_decl = d
end
# Variable declared with 'var'
class VarVariable
special Variable
- redef meth kind do return once "variable"
+ redef fun kind do return once "variable"
init(n: Symbol, d: PNode) do super
end
# Parameter of method (declared in signature)
class ParamVariable
special Variable
- redef meth kind do return once "parameter"
- init(n: Symbol, d: PNode) do super
+ redef fun kind do return once "parameter"
+ init(n: Symbol, d: nullable PNode) do super
end
# Automatic variable (like in the 'for' statement)
class AutoVariable
special Variable
- redef meth kind do return once "automatic variable"
+ redef fun kind do return once "automatic variable"
init(n: Symbol, d: PNode) do super
end
# Lives in the same namespace than variables
class ClosureVariable
special Variable
- redef meth kind do return once "closure"
+ redef fun kind do return once "closure"
# The signature of the closure
- readable attr _closure: MMClosure
+ readable var _closure: MMClosure
init(n: Symbol, d: PNode, c: MMClosure)
do
class AbsSyntaxVisitor
special Visitor
# The root type Object
- meth type_object: MMType
+ fun type_object: MMType
do
return _module.class_by_name(once ("Object".to_symbol)).get_type
end
# The primitive type Bool
- meth type_bool: MMType
+ fun type_bool: MMType
do
return _module.class_by_name(once ("Bool".to_symbol)).get_type
end
# The primitive type Int
- meth type_int: MMType
+ fun type_int: MMType
do
return _module.class_by_name(once ("Int".to_symbol)).get_type
end
# The primitive type Float
- meth type_float: MMType
+ fun type_float: MMType
do
return _module.class_by_name(once ("Float".to_symbol)).get_type
end
# The primitive type Char
- meth type_char: MMType
+ fun type_char: MMType
do
return _module.class_by_name(once ("Char".to_symbol)).get_type
end
# The primitive type String
- meth type_string: MMType
+ fun type_string: MMType
do
return _module.class_by_name(once ("String".to_symbol)).get_type
end
- # The primitive type Collection[Object]
- meth type_collection: MMType
+ # The primitive type Collection[nullable Object]
+ fun type_collection: MMType
do
- return _module.class_by_name(once ("Collection".to_symbol)).get_type
+ return _module.class_by_name(once ("Collection".to_symbol)).get_instantiate_type([type_object.as_nullable])
end
# The primitive type Array[?]
- meth type_array(stype: MMType): MMType
+ fun type_array(stype: MMType): MMType
do
return _module.class_by_name(once ("Array".to_symbol)).get_instantiate_type([stype])
end
# The primitive type Discrete
- meth type_discrete: MMType
+ fun type_discrete: MMType
do
return _module.class_by_name(once ("Discrete".to_symbol)).get_type
end
# The primitive type Range[?]
- meth type_range(stype: MMType): MMType
+ fun type_range(stype: MMType): MMType
do
return _module.class_by_name(once ("Range".to_symbol)).get_instantiate_type([stype])
end
# The primitive type of null
- meth type_none: MMType
+ fun type_none: MMType
do
return _module.type_none
end
# The current module
- readable writable attr _module: MMSrcModule
+ readable var _module: MMSrcModule
# The current class
- readable writable attr _local_class: MMSrcLocalClass
+ fun local_class: MMSrcLocalClass do return _local_class.as(not null)
+ writable var _local_class: nullable MMSrcLocalClass
# The current property
- readable writable attr _local_property: MMLocalProperty
+ fun local_property: MMLocalProperty do return _local_property.as(not null)
+ writable var _local_property: nullable MMLocalProperty
# The current tool configuration/status
- readable attr _tc: ToolContext
+ readable var _tc: ToolContext
# Display an error for a given syntax node
- meth error(n: PNode, s: String)
+ fun error(n: nullable PNode, s: String)
do
_tc.error("{locate(n)}: {s}")
end
# Display a warning for a given syntax node
- meth warning(n: PNode, s: String)
+ fun warning(n: nullable PNode, s: String)
do
_tc.warning("{locate(n)}: {s}")
end
#
- meth locate(n: PNode): String
+ fun locate(n: nullable PNode): String
do
if n != null then return n.locate
return _module.filename
end
# Check conformity and display error
- meth check_conform(n: PNode, subtype: MMType, stype: MMType): Bool
+ fun check_conform(n: PNode, subtype: nullable MMType, stype: nullable MMType): Bool
do
if stype == null or subtype == null then
return false
end
- if subtype < stype then
+ if subtype < stype then
return true
end
- #error(n, "Type error: expected {stype}'{stype.module}, got {subtype}'{subtype.module}")
- #abort
error(n, "Type error: expected {stype}, got {subtype}")
return false
end
-
+
# Check that an expression has a static type and that
# Display an error and return false if n is a statement
# Require that the static type of n is known
- meth check_expr(n: PExpr): Bool
+ fun check_expr(n: PExpr): Bool
do
if not n.is_typed then
+ if tc.error_count == 0 then
+ print("{n.locate} not typed but not error")
+ abort
+ end
# An error occured in a sub node,
# sillently cascade fail
return false
- else if tc.error_count == 0 and n.is_statement then # FIXME remove 'tc.error_count == 0'
- #if tc.error_count == 0 and n.stype == null then
+ else if n.is_statement then
error(n, "Type error: expected expression.")
return false
end
end
# Combine check_conform and check_expr
- meth check_conform_expr(n: PExpr, stype: MMType): Bool
+ fun check_conform_expr(n: PExpr, stype: nullable MMType): Bool
do
+ if stype == null then return false
if check_expr(n) then return check_conform(n, n.stype, stype) else return false
end
# Conformance is granted if among them there is a most general type
# Return the most general type if a conformance is found
# Display an error and return null if no conformance is found
+ # The only allowed combinaison is with the nullable marker
# @param stype is a possible additional type (without node)
# Examples:
# Int, Int, Object => return Object
# Int, Float => display error, return null
- meth check_conform_multiexpr(stype: MMType, nodes: Collection[PExpr]): MMType
+ # nullable Int, Object => return nullable Object
+ fun check_conform_multiexpr(stype: nullable MMType, nodes: Collection[PExpr]): nullable MMType
do
- var node: PExpr = null # candidate node
+ var node: nullable PExpr = null # candidate node
for n in nodes do
if not check_expr(n) then return null
var ntype = n.stype
- if stype == null or (ntype != null and stype < ntype) then
+ if stype != null and stype.is_nullable != ntype.is_nullable then
+ # nullable combinaison: if one of them is nulable, considers that both are
+ stype = stype.as_nullable
+ ntype = ntype.as_nullable
+ end
+ if stype == null or stype < ntype then
stype = ntype
node = n
end
end
for n in nodes do
- if not n.stype < stype then
+ if not n.stype < stype.as(not null) then
if node == null then
error(n, "Type error: no most general type. Got {n.stype} and {stype}.")
else
###############################################################################
redef class PNode
- protected meth accept_abs_syntax_visitor(v: AbsSyntaxVisitor) do visit_all(v)
+ protected fun accept_abs_syntax_visitor(v: AbsSyntaxVisitor) do visit_all(v)
end
redef class Token
- attr _symbol: Symbol
+ var _symbol_cache: nullable Symbol
# Symbol associated with the text
# Lazily computed
- meth to_symbol: Symbol
+ fun to_symbol: Symbol
do
- var s = _symbol
+ var s = _symbol_cache
if s == null then
s = text.to_symbol
- _symbol = s
+ _symbol_cache = s
end
return s
end
redef class PClassdef
# Associated class (MM entity)
- meth local_class: MMSrcLocalClass is abstract
+ fun local_class: MMSrcLocalClass is abstract
end
redef class AAttrPropdef
# Associated attribute (MM entity)
- meth prop: MMSrcAttribute is abstract
+ fun prop: MMSrcAttribute is abstract
# Associated read accessor (MM entity)
- meth readmethod: MMSrcMethod is abstract
+ fun readmethod: nullable MMSrcMethod is abstract
# Associated write accessor (MM entity)
- meth writemethod: MMSrcMethod is abstract
+ fun writemethod: nullable MMSrcMethod is abstract
end
redef class AMethPropdef
# Associated method (MM entity)
- meth method: MMMethSrcMethod is abstract
+ fun method: MMMethSrcMethod is abstract
# Associated 'self' variable
- meth self_var: ParamVariable is abstract
+ fun self_var: ParamVariable is abstract
end
redef class ATypePropdef
# Associated formal type (MM entity)
- meth prop: MMSrcTypeProperty is abstract
+ fun prop: MMSrcTypeProperty is abstract
end
redef class PParam
# Position in the signature
- meth position: Int is abstract
+ fun position: Int is abstract
# Associated local variable
- meth variable: ParamVariable is abstract
+ fun variable: ParamVariable is abstract
end
redef class PClosureDecl
# Associated closure variable
- meth variable: ClosureVariable is abstract
+ fun variable: ClosureVariable is abstract
end
redef class PType
# Retrieve the local class corresponding to the type.
# Display an error and return null if there is no class
# Display an error and return null if the type is not class based (formal one)
- meth get_local_class(v: AbsSyntaxVisitor): MMLocalClass is abstract
+ fun get_local_class(v: AbsSyntaxVisitor): nullable MMLocalClass is abstract
# Retrieve corresponding static type.
# Display an error and return null if there is a problem
- meth get_stype(v: AbsSyntaxVisitor): MMType is abstract
+ fun get_stype(v: AbsSyntaxVisitor): nullable MMType is abstract
# Retrieve corresponding static type.
# Display an error and return null if there is a problem
# But do not performs any subtype check.
# get_unchecked_stype should be called to check that the static type is fully valid
- meth get_unchecked_stype(v: AbsSyntaxVisitor): MMType is abstract
+ fun get_unchecked_stype(v: AbsSyntaxVisitor): nullable MMType is abstract
# Check that a static definition type is conform with regard to formal types
# Useful with get_unchecked_stype
# Remember that conformance check need that ancestors are totaly computed
- meth check_conform(v: AbsSyntaxVisitor) is abstract
+ fun check_conform(v: AbsSyntaxVisitor) is abstract
end
redef class AType
- attr _stype_cache: MMType
- attr _stype_cached: Bool = false
+ var _stype_cache: nullable MMType = null
+ var _stype_cached: Bool = false
- redef meth get_local_class(v)
+ redef fun get_local_class(v)
do
var name = n_id.to_symbol
var mod = v.module
var cla = v.local_class
- if (cla.formal_dict != null and cla.formal_dict.has_key(name)) or (cla.global_properties != null and cla.has_global_property_by_name(name)) then
+ if cla.formal_dict.has_key(name) or cla.has_global_property_by_name(name) then
v.error(n_id, "Type error: {name} is a formal type")
_stype_cached = true
return null
return local_class
end
- redef meth get_unchecked_stype(v)
+ redef fun get_unchecked_stype(v)
do
if _stype_cached then return _stype_cache
_stype_cached = true
var name = n_id.to_symbol
var mod = v.module
var cla = v.local_class
+ var t: nullable MMType
if cla.formal_dict.has_key(name) then
if n_types.length > 0 then
v.error(self, "Type error: formal type {name} cannot have formal parameters.")
return null
end
- var formal = cla.formal_dict[name]
- _stype_cache = formal
- return formal
+ t = cla.formal_dict[name]
+ if n_kwnullable != null then t = t.as_nullable
+ _stype_cache = t
+ return t
end
- if cla.global_properties != null and cla.has_global_property_by_name(name) then
+ if cla.has_global_property_by_name(name) then
if n_types.length > 0 then
v.error(self, "Type error: formal type {name} cannot have formal parameters.")
return null
end
- var t = cla.get_type.local_class.select_virtual_type(name).stype_for(cla.get_type)
+ t = cla.get_type.local_class.select_virtual_type(name).stype_for(cla.get_type)
if t == null then
v.error(self, "Type error: circular definition in formal type {name}.")
return null
end
+ if n_kwnullable != null then t = t.as_nullable
_stype_cache = t
return t
end
if arity > 0 then
var tab = new Array[MMType]
for p in n_types do
- tab.add(p.get_unchecked_stype(v))
+ var t2 = p.get_unchecked_stype(v)
+ if t2 == null then return null
+ tab.add(t2)
end
- var t = local_class.get_instantiate_type(tab)
- _stype_cache = t
- return t
+ t = local_class.get_instantiate_type(tab)
else
- var t = local_class.get_type
- _stype_cache = t
- return t
+ t = local_class.get_type
end
+ if n_kwnullable != null then t = t.as_nullable
+ _stype_cache = t
+ return t
end
- redef meth get_stype(v)
+ redef fun get_stype(v)
do
var t = get_unchecked_stype(v)
- if t != null then check_conform(v)
+ if t == null then return null
+ if not t.is_valid then return null
+ check_conform(v)
return t
end
- redef meth check_conform(v)
+ redef fun check_conform(v)
do
var st = get_unchecked_stype(v)
if st == null then return
for i in [0..arity[ do
var p = n_types[i]
var pt = p.get_stype(v)
- var bt = local_class.get_formal(i).bound
- if bt == null then return
+ var b = local_class.get_formal(i)
+ if not b.is_valid then return
+ var bt = b.bound
bt = bt.adapt_to(st) # We need to abapt because of F-genericity
v.check_conform(p, pt, bt)
end
# Is the expression node correcly typed
# Return false if typed was not yet computed or
# if an error occured during the typing computation
- meth is_typed: Bool is abstract
+ fun is_typed: Bool is abstract
# Is the expression node a statement? (ie has no return value)
# require: is_typed
- meth is_statement: Bool is abstract
+ fun is_statement: Bool is abstract
# The static type of the expression
# require: is_typed and not is_statement
- meth stype: MMType is abstract
+ fun stype: MMType is abstract
end
redef class AVardeclExpr
# Assiociated local variable
- readable writable attr _variable: VarVariable
+ fun variable: VarVariable is abstract
+ #readable writable var _variable: nullable VarVariable
end
redef class AForExpr
# Associated automatic local variable
- readable writable attr _variable: AutoVariable
+ fun variable: AutoVariable is abstract
+ #readable writable var _variable: nullable AutoVariable
end
redef class ASelfExpr
# Associated local variable
- readable writable attr _variable: ParamVariable
+ fun variable: ParamVariable is abstract
+ #readable writable var _variable: nullable ParamVariable
end
redef class AVarFormExpr
# Associated local variable
- readable writable attr _variable: Variable
+ fun variable: Variable is abstract
+ #readable writable var _variable: nullable Variable
end
redef class AClosureCallExpr
# Associated closure variable
- readable writable attr _variable: ClosureVariable
+ fun variable: ClosureVariable is abstract
+ #readable writable var _variable: nullable ClosureVariable
end
redef class PClosureDef
# Associated closure
- readable writable attr _closure: MMClosure
+ #readable writable var _closure: nullable MMClosure
+ fun closure: MMClosure is abstract
# Automatic variables
- readable writable attr _variables: Array[AutoVariable]
+ readable writable var _variables: nullable Array[AutoVariable]
end