9.4 Protected Units and Protected Objects
A
protected object provides coordinated access to shared data, through
calls on its visible
protected operations, which can be
protected
subprograms or
protected entries.
A
protected unit is declared by a
protected declaration,
which has a corresponding
protected_body.
A protected declaration may be a
protected_type_declaration,
in which case it declares a named protected type; alternatively, it may
be a
single_protected_declaration,
in which case it defines an anonymous protected type, as well as declaring
a named protected object of that type.
Syntax
Paragraph 10 was
deleted.
Static Semantics
For a protected declaration with an
interface_list,
the protected type inherits user-defined primitive subprograms from each
progenitor type (see
3.9.4), in the same
way that a derived type inherits user-defined primitive subprograms from
its progenitor types (see
3.4). If the first
parameter of a primitive inherited subprogram is of the protected type
or an access parameter designating the protected type, and there is a
protected_operation_declaration
for a protected subprogram or single entry with the same identifier within
the protected declaration, whose profile is type conformant with the
prefixed view profile of the inherited subprogram, the inherited subprogram
is said to be
implemented by the conforming protected subprogram
or entry using an implicitly declared nonabstract subprogram which has
the same profile as the inherited subprogram and which overrides it
.
Legality Rules
A protected declaration requires
a completion, which shall be a
protected_body,
and every
protected_body
shall be the completion of some protected declaration.
Each
interface_subtype_mark
of an
interface_list
appearing within a protected declaration shall denote a limited interface
type that is not a task interface.
The prefixed view profile of an explicitly declared
primitive subprogram of a tagged protected type shall not be type conformant
with any protected operation of the protected type, if the subprogram
has the same defining name as the protected operation and the first parameter
of the subprogram is of the protected type or is an access parameter
designating the protected type.
For each primitive
subprogram inherited by the type declared by a protected declaration,
at most one of the following shall apply:
the inherited subprogram is overridden with a primitive
subprogram of the protected type, in which case the overriding subprogram
shall be subtype conformant with the inherited subprogram and not abstract;
or
the inherited subprogram is implemented by a protected
subprogram or single entry of the protected type, in which case its prefixed
view profile shall be subtype conformant with that of the protected subprogram
or entry.
If neither applies, the inherited subprogram shall
be a null procedure.
In addition to the places where
Legality Rules normally apply (see
12.3),
these rules also apply in the private part of an instance of a generic
unit.
If an inherited subprogram is implemented by a
protected procedure or an entry, then the first parameter of the inherited
subprogram shall be of mode out or in out, or an access-to-variable
parameter. If an inherited subprogram is implemented by a protected function,
then the first parameter of the inherited subprogram shall be of mode
in, but not an access-to-variable parameter.
If a protected subprogram
declaration has an
overriding_indicator,
then at the point of the declaration:
if the
overriding_indicator
is
overriding, then the subprogram shall implement an inherited
subprogram;
if the
overriding_indicator
is
not overriding, then the subprogram shall not implement any
inherited subprogram.
In addition to the places
where Legality Rules normally apply (see
12.3),
these rules also apply in the private part of an instance of a generic
unit.
Dynamic Semantics
As part of the initialization
of a protected object, any per-object constraints (see
3.8)
are elaborated.
The elaboration of a
protected_body
has no other effect than to establish that protected operations of the
type can from then on be called without failing the Elaboration_Check.
The content of an object
of a given protected type includes:
The values of the components of the protected object,
including (implicitly) an entry queue for each entry declared for the
protected object;
A representation of the state
of the execution resource
associated with the protected object
(one such resource is associated with each protected object).
The execution resource associated with a protected
object has to be acquired to read or update any components of the protected
object; it can be acquired (as part of a protected action — see
9.5.1) either for concurrent read-only access,
or for exclusive read-write access.
As the first
step of the
finalization of a protected object, each call remaining
on any entry queue of the object is removed from its queue and Program_Error
is raised at the place of the corresponding
entry_call_statement.
Bounded (Run-Time) Errors
It is a bounded error to call
an entry or subprogram of a protected object after that object is finalized.
If the error is detected, Program_Error is raised. Otherwise, the call
proceeds normally, which may leave a task queued forever.
13 Within the declaration or body of a
protected unit other than in an
access_definition,
the name of the protected unit denotes the current instance of the unit
(see
8.6), rather than the first subtype of
the corresponding protected type (and thus the name cannot be used as
a
subtype_mark).
14 A
selected_component
can be used to denote a discriminant of a protected object (see
4.1.3).
Within a protected unit, the name of a discriminant of the protected
type denotes the corresponding discriminant of the current instance of
the unit.
15 A protected type is a limited type (see
7.5), and hence precludes use of
assignment_statements
and predefined equality operators.
16 The bodies of the protected operations
given in the
protected_body
define the actions that take place upon calls to the protected operations.
17 The declarations in the private part
are only visible within the private part and the body of the protected
unit.
Examples
Example of declaration
of protected type and corresponding body:
protected type Resource is
entry Seize;
procedure Release;
private
Busy : Boolean := False;
end Resource;
protected body Resource is
entry Seize when not Busy is
begin
Busy := True;
end Seize;
procedure Release is
begin
Busy := False;
end Release;
end Resource;
Example of a
single protected declaration and corresponding body:
protected Shared_Array is
-- Index, Item, and Item_Array are global types
function Component (N : in Index) return Item;
procedure Set_Component(N : in Index; E : in Item);
private
Table : Item_Array(Index) := (others => Null_Item);
end Shared_Array;
protected body Shared_Array is
function Component(N : in Index) return Item is
begin
return Table(N);
end Component;
procedure Set_Component(N : in Index; E : in Item) is
begin
Table(N) := E;
end Set_Component;
end Shared_Array;
Examples of protected
objects:
Control : Resource;
Flags : array(1 .. 100) of Resource;
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