1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
9 -- Copyright (C) 1992-2015, Free Software Foundation, Inc. --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
24 ------------------------------------------------------------------------------
26 with Aspects
; use Aspects
;
27 with Atree
; use Atree
;
28 with Checks
; use Checks
;
29 with Debug
; use Debug
;
30 with Einfo
; use Einfo
;
31 with Elists
; use Elists
;
32 with Errout
; use Errout
;
33 with Exp_Ch3
; use Exp_Ch3
;
34 with Exp_Ch7
; use Exp_Ch7
;
35 with Exp_Disp
; use Exp_Disp
;
36 with Exp_Pakd
; use Exp_Pakd
;
37 with Exp_Util
; use Exp_Util
;
38 with Exp_Tss
; use Exp_Tss
;
39 with Ghost
; use Ghost
;
40 with Layout
; use Layout
;
42 with Namet
; use Namet
;
43 with Nlists
; use Nlists
;
44 with Nmake
; use Nmake
;
46 with Restrict
; use Restrict
;
47 with Rident
; use Rident
;
48 with Rtsfind
; use Rtsfind
;
50 with Sem_Aux
; use Sem_Aux
;
51 with Sem_Cat
; use Sem_Cat
;
52 with Sem_Ch6
; use Sem_Ch6
;
53 with Sem_Ch7
; use Sem_Ch7
;
54 with Sem_Ch8
; use Sem_Ch8
;
55 with Sem_Ch13
; use Sem_Ch13
;
56 with Sem_Eval
; use Sem_Eval
;
57 with Sem_Mech
; use Sem_Mech
;
58 with Sem_Prag
; use Sem_Prag
;
59 with Sem_Res
; use Sem_Res
;
60 with Sem_Util
; use Sem_Util
;
61 with Sinfo
; use Sinfo
;
62 with Snames
; use Snames
;
63 with Stand
; use Stand
;
64 with Targparm
; use Targparm
;
65 with Tbuild
; use Tbuild
;
66 with Ttypes
; use Ttypes
;
67 with Uintp
; use Uintp
;
68 with Urealp
; use Urealp
;
69 with Warnsw
; use Warnsw
;
71 package body Freeze
is
73 -----------------------
74 -- Local Subprograms --
75 -----------------------
77 procedure Adjust_Esize_For_Alignment
(Typ
: Entity_Id
);
78 -- Typ is a type that is being frozen. If no size clause is given,
79 -- but a default Esize has been computed, then this default Esize is
80 -- adjusted up if necessary to be consistent with a given alignment,
81 -- but never to a value greater than Long_Long_Integer'Size. This
82 -- is used for all discrete types and for fixed-point types.
84 procedure Build_And_Analyze_Renamed_Body
87 After
: in out Node_Id
);
88 -- Build body for a renaming declaration, insert in tree and analyze
90 procedure Check_Address_Clause
(E
: Entity_Id
);
91 -- Apply legality checks to address clauses for object declarations,
92 -- at the point the object is frozen. Also ensure any initialization is
93 -- performed only after the object has been frozen.
95 procedure Check_Component_Storage_Order
96 (Encl_Type
: Entity_Id
;
99 Comp_ADC_Present
: out Boolean);
100 -- For an Encl_Type that has a Scalar_Storage_Order attribute definition
101 -- clause, verify that the component type has an explicit and compatible
102 -- attribute/aspect. For arrays, Comp is Empty; for records, it is the
103 -- entity of the component under consideration. For an Encl_Type that
104 -- does not have a Scalar_Storage_Order attribute definition clause,
105 -- verify that the component also does not have such a clause.
106 -- ADC is the attribute definition clause if present (or Empty). On return,
107 -- Comp_ADC_Present is set True if the component has a Scalar_Storage_Order
108 -- attribute definition clause.
110 procedure Check_Expression_Function
(N
: Node_Id
; Nam
: Entity_Id
);
111 -- When an expression function is frozen by a use of it, the expression
112 -- itself is frozen. Check that the expression does not include references
113 -- to deferred constants without completion. We report this at the freeze
114 -- point of the function, to provide a better error message.
116 -- In most cases the expression itself is frozen by the time the function
117 -- itself is frozen, because the formals will be frozen by then. However,
118 -- Attribute references to outer types are freeze points for those types;
119 -- this routine generates the required freeze nodes for them.
121 procedure Check_Strict_Alignment
(E
: Entity_Id
);
122 -- E is a base type. If E is tagged or has a component that is aliased
123 -- or tagged or contains something this is aliased or tagged, set
126 procedure Check_Unsigned_Type
(E
: Entity_Id
);
127 pragma Inline
(Check_Unsigned_Type
);
128 -- If E is a fixed-point or discrete type, then all the necessary work
129 -- to freeze it is completed except for possible setting of the flag
130 -- Is_Unsigned_Type, which is done by this procedure. The call has no
131 -- effect if the entity E is not a discrete or fixed-point type.
133 procedure Freeze_And_Append
136 Result
: in out List_Id
);
137 -- Freezes Ent using Freeze_Entity, and appends the resulting list of
138 -- nodes to Result, modifying Result from No_List if necessary. N has
139 -- the same usage as in Freeze_Entity.
141 procedure Freeze_Enumeration_Type
(Typ
: Entity_Id
);
142 -- Freeze enumeration type. The Esize field is set as processing
143 -- proceeds (i.e. set by default when the type is declared and then
144 -- adjusted by rep clauses. What this procedure does is to make sure
145 -- that if a foreign convention is specified, and no specific size
146 -- is given, then the size must be at least Integer'Size.
148 procedure Freeze_Static_Object
(E
: Entity_Id
);
149 -- If an object is frozen which has Is_Statically_Allocated set, then
150 -- all referenced types must also be marked with this flag. This routine
151 -- is in charge of meeting this requirement for the object entity E.
153 procedure Freeze_Subprogram
(E
: Entity_Id
);
154 -- Perform freezing actions for a subprogram (create extra formals,
155 -- and set proper default mechanism values). Note that this routine
156 -- is not called for internal subprograms, for which neither of these
157 -- actions is needed (or desirable, we do not want for example to have
158 -- these extra formals present in initialization procedures, where they
159 -- would serve no purpose). In this call E is either a subprogram or
160 -- a subprogram type (i.e. an access to a subprogram).
162 function Is_Fully_Defined
(T
: Entity_Id
) return Boolean;
163 -- True if T is not private and has no private components, or has a full
164 -- view. Used to determine whether the designated type of an access type
165 -- should be frozen when the access type is frozen. This is done when an
166 -- allocator is frozen, or an expression that may involve attributes of
167 -- the designated type. Otherwise freezing the access type does not freeze
168 -- the designated type.
170 procedure Process_Default_Expressions
172 After
: in out Node_Id
);
173 -- This procedure is called for each subprogram to complete processing of
174 -- default expressions at the point where all types are known to be frozen.
175 -- The expressions must be analyzed in full, to make sure that all error
176 -- processing is done (they have only been pre-analyzed). If the expression
177 -- is not an entity or literal, its analysis may generate code which must
178 -- not be executed. In that case we build a function body to hold that
179 -- code. This wrapper function serves no other purpose (it used to be
180 -- called to evaluate the default, but now the default is inlined at each
183 procedure Set_Component_Alignment_If_Not_Set
(Typ
: Entity_Id
);
184 -- Typ is a record or array type that is being frozen. This routine sets
185 -- the default component alignment from the scope stack values if the
186 -- alignment is otherwise not specified.
188 procedure Check_Debug_Info_Needed
(T
: Entity_Id
);
189 -- As each entity is frozen, this routine is called to deal with the
190 -- setting of Debug_Info_Needed for the entity. This flag is set if
191 -- the entity comes from source, or if we are in Debug_Generated_Code
192 -- mode or if the -gnatdV debug flag is set. However, it never sets
193 -- the flag if Debug_Info_Off is set. This procedure also ensures that
194 -- subsidiary entities have the flag set as required.
196 procedure Set_SSO_From_Default
(T
: Entity_Id
);
197 -- T is a record or array type that is being frozen. If it is a base type,
198 -- and if SSO_Set_Low/High_By_Default is set, then Reverse_Storage order
199 -- will be set appropriately. Note that an explicit occurrence of aspect
200 -- Scalar_Storage_Order or an explicit setting of this aspect with an
201 -- attribute definition clause occurs, then these two flags are reset in
202 -- any case, so call will have no effect.
204 procedure Undelay_Type
(T
: Entity_Id
);
205 -- T is a type of a component that we know to be an Itype. We don't want
206 -- this to have a Freeze_Node, so ensure it doesn't. Do the same for any
207 -- Full_View or Corresponding_Record_Type.
209 procedure Warn_Overlay
213 -- Expr is the expression for an address clause for entity Nam whose type
214 -- is Typ. If Typ has a default initialization, and there is no explicit
215 -- initialization in the source declaration, check whether the address
216 -- clause might cause overlaying of an entity, and emit a warning on the
217 -- side effect that the initialization will cause.
219 -------------------------------
220 -- Adjust_Esize_For_Alignment --
221 -------------------------------
223 procedure Adjust_Esize_For_Alignment
(Typ
: Entity_Id
) is
227 if Known_Esize
(Typ
) and then Known_Alignment
(Typ
) then
228 Align
:= Alignment_In_Bits
(Typ
);
230 if Align
> Esize
(Typ
)
231 and then Align
<= Standard_Long_Long_Integer_Size
233 Set_Esize
(Typ
, Align
);
236 end Adjust_Esize_For_Alignment
;
238 ------------------------------------
239 -- Build_And_Analyze_Renamed_Body --
240 ------------------------------------
242 procedure Build_And_Analyze_Renamed_Body
245 After
: in out Node_Id
)
247 Body_Decl
: constant Node_Id
:= Unit_Declaration_Node
(New_S
);
248 Ent
: constant Entity_Id
:= Defining_Entity
(Decl
);
250 Renamed_Subp
: Entity_Id
;
253 -- If the renamed subprogram is intrinsic, there is no need for a
254 -- wrapper body: we set the alias that will be called and expanded which
255 -- completes the declaration. This transformation is only legal if the
256 -- renamed entity has already been elaborated.
258 -- Note that it is legal for a renaming_as_body to rename an intrinsic
259 -- subprogram, as long as the renaming occurs before the new entity
260 -- is frozen (RM 8.5.4 (5)).
262 if Nkind
(Body_Decl
) = N_Subprogram_Renaming_Declaration
263 and then Is_Entity_Name
(Name
(Body_Decl
))
265 Renamed_Subp
:= Entity
(Name
(Body_Decl
));
267 Renamed_Subp
:= Empty
;
270 if Present
(Renamed_Subp
)
271 and then Is_Intrinsic_Subprogram
(Renamed_Subp
)
273 (not In_Same_Source_Unit
(Renamed_Subp
, Ent
)
274 or else Sloc
(Renamed_Subp
) < Sloc
(Ent
))
276 -- We can make the renaming entity intrinsic if the renamed function
277 -- has an interface name, or if it is one of the shift/rotate
278 -- operations known to the compiler.
281 (Present
(Interface_Name
(Renamed_Subp
))
282 or else Nam_In
(Chars
(Renamed_Subp
), Name_Rotate_Left
,
286 Name_Shift_Right_Arithmetic
))
288 Set_Interface_Name
(Ent
, Interface_Name
(Renamed_Subp
));
290 if Present
(Alias
(Renamed_Subp
)) then
291 Set_Alias
(Ent
, Alias
(Renamed_Subp
));
293 Set_Alias
(Ent
, Renamed_Subp
);
296 Set_Is_Intrinsic_Subprogram
(Ent
);
297 Set_Has_Completion
(Ent
);
300 Body_Node
:= Build_Renamed_Body
(Decl
, New_S
);
301 Insert_After
(After
, Body_Node
);
302 Mark_Rewrite_Insertion
(Body_Node
);
306 end Build_And_Analyze_Renamed_Body
;
308 ------------------------
309 -- Build_Renamed_Body --
310 ------------------------
312 function Build_Renamed_Body
314 New_S
: Entity_Id
) return Node_Id
316 Loc
: constant Source_Ptr
:= Sloc
(New_S
);
317 -- We use for the source location of the renamed body, the location of
318 -- the spec entity. It might seem more natural to use the location of
319 -- the renaming declaration itself, but that would be wrong, since then
320 -- the body we create would look as though it was created far too late,
321 -- and this could cause problems with elaboration order analysis,
322 -- particularly in connection with instantiations.
324 N
: constant Node_Id
:= Unit_Declaration_Node
(New_S
);
325 Nam
: constant Node_Id
:= Name
(N
);
327 Spec
: constant Node_Id
:= New_Copy_Tree
(Specification
(Decl
));
328 Actuals
: List_Id
:= No_List
;
333 O_Formal
: Entity_Id
;
334 Param_Spec
: Node_Id
;
336 Pref
: Node_Id
:= Empty
;
337 -- If the renamed entity is a primitive operation given in prefix form,
338 -- the prefix is the target object and it has to be added as the first
339 -- actual in the generated call.
342 -- Determine the entity being renamed, which is the target of the call
343 -- statement. If the name is an explicit dereference, this is a renaming
344 -- of a subprogram type rather than a subprogram. The name itself is
347 if Nkind
(Nam
) = N_Selected_Component
then
348 Old_S
:= Entity
(Selector_Name
(Nam
));
350 elsif Nkind
(Nam
) = N_Explicit_Dereference
then
351 Old_S
:= Etype
(Nam
);
353 elsif Nkind
(Nam
) = N_Indexed_Component
then
354 if Is_Entity_Name
(Prefix
(Nam
)) then
355 Old_S
:= Entity
(Prefix
(Nam
));
357 Old_S
:= Entity
(Selector_Name
(Prefix
(Nam
)));
360 elsif Nkind
(Nam
) = N_Character_Literal
then
361 Old_S
:= Etype
(New_S
);
364 Old_S
:= Entity
(Nam
);
367 if Is_Entity_Name
(Nam
) then
369 -- If the renamed entity is a predefined operator, retain full name
370 -- to ensure its visibility.
372 if Ekind
(Old_S
) = E_Operator
373 and then Nkind
(Nam
) = N_Expanded_Name
375 Call_Name
:= New_Copy
(Name
(N
));
377 Call_Name
:= New_Occurrence_Of
(Old_S
, Loc
);
381 if Nkind
(Nam
) = N_Selected_Component
382 and then Present
(First_Formal
(Old_S
))
384 (Is_Controlling_Formal
(First_Formal
(Old_S
))
385 or else Is_Class_Wide_Type
(Etype
(First_Formal
(Old_S
))))
388 -- Retrieve the target object, to be added as a first actual
391 Call_Name
:= New_Occurrence_Of
(Old_S
, Loc
);
392 Pref
:= Prefix
(Nam
);
395 Call_Name
:= New_Copy
(Name
(N
));
398 -- Original name may have been overloaded, but is fully resolved now
400 Set_Is_Overloaded
(Call_Name
, False);
403 -- For simple renamings, subsequent calls can be expanded directly as
404 -- calls to the renamed entity. The body must be generated in any case
405 -- for calls that may appear elsewhere. This is not done in the case
406 -- where the subprogram is an instantiation because the actual proper
407 -- body has not been built yet.
409 if Ekind_In
(Old_S
, E_Function
, E_Procedure
)
410 and then Nkind
(Decl
) = N_Subprogram_Declaration
411 and then not Is_Generic_Instance
(Old_S
)
413 Set_Body_To_Inline
(Decl
, Old_S
);
416 -- Check whether the return type is a limited view. If the subprogram
417 -- is already frozen the generated body may have a non-limited view
418 -- of the type, that must be used, because it is the one in the spec
419 -- of the renaming declaration.
421 if Ekind
(Old_S
) = E_Function
422 and then Is_Entity_Name
(Result_Definition
(Spec
))
425 Ret_Type
: constant Entity_Id
:= Etype
(Result_Definition
(Spec
));
427 if Has_Non_Limited_View
(Ret_Type
) then
428 Set_Result_Definition
429 (Spec
, New_Occurrence_Of
(Non_Limited_View
(Ret_Type
), Loc
));
434 -- The body generated for this renaming is an internal artifact, and
435 -- does not constitute a freeze point for the called entity.
437 Set_Must_Not_Freeze
(Call_Name
);
439 Formal
:= First_Formal
(Defining_Entity
(Decl
));
441 if Present
(Pref
) then
443 Pref_Type
: constant Entity_Id
:= Etype
(Pref
);
444 Form_Type
: constant Entity_Id
:= Etype
(First_Formal
(Old_S
));
447 -- The controlling formal may be an access parameter, or the
448 -- actual may be an access value, so adjust accordingly.
450 if Is_Access_Type
(Pref_Type
)
451 and then not Is_Access_Type
(Form_Type
)
454 (Make_Explicit_Dereference
(Loc
, Relocate_Node
(Pref
)));
456 elsif Is_Access_Type
(Form_Type
)
457 and then not Is_Access_Type
(Pref
)
461 Make_Attribute_Reference
(Loc
,
462 Attribute_Name
=> Name_Access
,
463 Prefix
=> Relocate_Node
(Pref
)));
465 Actuals
:= New_List
(Pref
);
469 elsif Present
(Formal
) then
476 if Present
(Formal
) then
477 while Present
(Formal
) loop
478 Append
(New_Occurrence_Of
(Formal
, Loc
), Actuals
);
479 Next_Formal
(Formal
);
483 -- If the renamed entity is an entry, inherit its profile. For other
484 -- renamings as bodies, both profiles must be subtype conformant, so it
485 -- is not necessary to replace the profile given in the declaration.
486 -- However, default values that are aggregates are rewritten when
487 -- partially analyzed, so we recover the original aggregate to insure
488 -- that subsequent conformity checking works. Similarly, if the default
489 -- expression was constant-folded, recover the original expression.
491 Formal
:= First_Formal
(Defining_Entity
(Decl
));
493 if Present
(Formal
) then
494 O_Formal
:= First_Formal
(Old_S
);
495 Param_Spec
:= First
(Parameter_Specifications
(Spec
));
496 while Present
(Formal
) loop
497 if Is_Entry
(Old_S
) then
498 if Nkind
(Parameter_Type
(Param_Spec
)) /=
501 Set_Etype
(Formal
, Etype
(O_Formal
));
502 Set_Entity
(Parameter_Type
(Param_Spec
), Etype
(O_Formal
));
505 elsif Nkind
(Default_Value
(O_Formal
)) = N_Aggregate
506 or else Nkind
(Original_Node
(Default_Value
(O_Formal
))) /=
507 Nkind
(Default_Value
(O_Formal
))
509 Set_Expression
(Param_Spec
,
510 New_Copy_Tree
(Original_Node
(Default_Value
(O_Formal
))));
513 Next_Formal
(Formal
);
514 Next_Formal
(O_Formal
);
519 -- If the renamed entity is a function, the generated body contains a
520 -- return statement. Otherwise, build a procedure call. If the entity is
521 -- an entry, subsequent analysis of the call will transform it into the
522 -- proper entry or protected operation call. If the renamed entity is
523 -- a character literal, return it directly.
525 if Ekind
(Old_S
) = E_Function
526 or else Ekind
(Old_S
) = E_Operator
527 or else (Ekind
(Old_S
) = E_Subprogram_Type
528 and then Etype
(Old_S
) /= Standard_Void_Type
)
531 Make_Simple_Return_Statement
(Loc
,
533 Make_Function_Call
(Loc
,
535 Parameter_Associations
=> Actuals
));
537 elsif Ekind
(Old_S
) = E_Enumeration_Literal
then
539 Make_Simple_Return_Statement
(Loc
,
540 Expression
=> New_Occurrence_Of
(Old_S
, Loc
));
542 elsif Nkind
(Nam
) = N_Character_Literal
then
544 Make_Simple_Return_Statement
(Loc
, Expression
=> Call_Name
);
548 Make_Procedure_Call_Statement
(Loc
,
550 Parameter_Associations
=> Actuals
);
553 -- Create entities for subprogram body and formals
555 Set_Defining_Unit_Name
(Spec
,
556 Make_Defining_Identifier
(Loc
, Chars
=> Chars
(New_S
)));
558 Param_Spec
:= First
(Parameter_Specifications
(Spec
));
559 while Present
(Param_Spec
) loop
560 Set_Defining_Identifier
(Param_Spec
,
561 Make_Defining_Identifier
(Loc
,
562 Chars
=> Chars
(Defining_Identifier
(Param_Spec
))));
567 Make_Subprogram_Body
(Loc
,
568 Specification
=> Spec
,
569 Declarations
=> New_List
,
570 Handled_Statement_Sequence
=>
571 Make_Handled_Sequence_Of_Statements
(Loc
,
572 Statements
=> New_List
(Call_Node
)));
574 if Nkind
(Decl
) /= N_Subprogram_Declaration
then
576 Make_Subprogram_Declaration
(Loc
,
577 Specification
=> Specification
(N
)));
580 -- Link the body to the entity whose declaration it completes. If
581 -- the body is analyzed when the renamed entity is frozen, it may
582 -- be necessary to restore the proper scope (see package Exp_Ch13).
584 if Nkind
(N
) = N_Subprogram_Renaming_Declaration
585 and then Present
(Corresponding_Spec
(N
))
587 Set_Corresponding_Spec
(Body_Node
, Corresponding_Spec
(N
));
589 Set_Corresponding_Spec
(Body_Node
, New_S
);
593 end Build_Renamed_Body
;
595 --------------------------
596 -- Check_Address_Clause --
597 --------------------------
599 procedure Check_Address_Clause
(E
: Entity_Id
) is
600 Addr
: constant Node_Id
:= Address_Clause
(E
);
602 Decl
: constant Node_Id
:= Declaration_Node
(E
);
603 Loc
: constant Source_Ptr
:= Sloc
(Decl
);
604 Typ
: constant Entity_Id
:= Etype
(E
);
606 Tag_Assign
: Node_Id
;
609 if Present
(Addr
) then
610 Expr
:= Expression
(Addr
);
612 if Needs_Constant_Address
(Decl
, Typ
) then
613 Check_Constant_Address_Clause
(Expr
, E
);
615 -- Has_Delayed_Freeze was set on E when the address clause was
616 -- analyzed, and must remain set because we want the address
617 -- clause to be elaborated only after any entity it references
618 -- has been elaborated.
621 -- If Rep_Clauses are to be ignored, remove address clause from
622 -- list attached to entity, because it may be illegal for gigi,
623 -- for example by breaking order of elaboration..
625 if Ignore_Rep_Clauses
then
630 Rep
:= First_Rep_Item
(E
);
633 Set_First_Rep_Item
(E
, Next_Rep_Item
(Addr
));
637 and then Next_Rep_Item
(Rep
) /= Addr
639 Rep
:= Next_Rep_Item
(Rep
);
643 if Present
(Rep
) then
644 Set_Next_Rep_Item
(Rep
, Next_Rep_Item
(Addr
));
648 -- And now remove the address clause
650 Kill_Rep_Clause
(Addr
);
652 elsif not Error_Posted
(Expr
)
653 and then not Needs_Finalization
(Typ
)
655 Warn_Overlay
(Expr
, Typ
, Name
(Addr
));
658 if Present
(Expression
(Decl
)) then
660 -- Capture initialization value at point of declaration,
661 -- and make explicit assignment legal, because object may
664 Remove_Side_Effects
(Expression
(Decl
));
665 Lhs
:= New_Occurrence_Of
(E
, Loc
);
666 Set_Assignment_OK
(Lhs
);
668 -- Move initialization to freeze actions (once the object has
669 -- been frozen, and the address clause alignment check has been
672 Append_Freeze_Action
(E
,
673 Make_Assignment_Statement
(Loc
,
675 Expression
=> Expression
(Decl
)));
677 Set_No_Initialization
(Decl
);
679 -- If the objet is tagged, check whether the tag must be
680 -- reassigned expliitly.
682 Tag_Assign
:= Make_Tag_Assignment
(Decl
);
683 if Present
(Tag_Assign
) then
684 Append_Freeze_Action
(E
, Tag_Assign
);
688 end Check_Address_Clause
;
690 -----------------------------
691 -- Check_Compile_Time_Size --
692 -----------------------------
694 procedure Check_Compile_Time_Size
(T
: Entity_Id
) is
696 procedure Set_Small_Size
(T
: Entity_Id
; S
: Uint
);
697 -- Sets the compile time known size (32 bits or less) in the Esize
698 -- field, of T checking for a size clause that was given which attempts
699 -- to give a smaller size, and also checking for an alignment clause.
701 function Size_Known
(T
: Entity_Id
) return Boolean;
702 -- Recursive function that does all the work
704 function Static_Discriminated_Components
(T
: Entity_Id
) return Boolean;
705 -- If T is a constrained subtype, its size is not known if any of its
706 -- discriminant constraints is not static and it is not a null record.
707 -- The test is conservative and doesn't check that the components are
708 -- in fact constrained by non-static discriminant values. Could be made
715 procedure Set_Small_Size
(T
: Entity_Id
; S
: Uint
) is
720 -- Check for bad size clause given
722 elsif Has_Size_Clause
(T
) then
723 if RM_Size
(T
) < S
then
724 Error_Msg_Uint_1
:= S
;
726 ("size for& too small, minimum allowed is ^",
730 -- Set size if not set already
732 elsif Unknown_RM_Size
(T
) then
741 function Size_Known
(T
: Entity_Id
) return Boolean is
749 if Size_Known_At_Compile_Time
(T
) then
752 -- Always True for scalar types. This is true even for generic formal
753 -- scalar types. We used to return False in the latter case, but the
754 -- size is known at compile time, even in the template, we just do
755 -- not know the exact size but that's not the point of this routine.
757 elsif Is_Scalar_Type
(T
)
758 or else Is_Task_Type
(T
)
764 elsif Is_Array_Type
(T
) then
766 -- String literals always have known size, and we can set it
768 if Ekind
(T
) = E_String_Literal_Subtype
then
769 Set_Small_Size
(T
, Component_Size
(T
)
770 * String_Literal_Length
(T
));
773 -- Unconstrained types never have known at compile time size
775 elsif not Is_Constrained
(T
) then
778 -- Don't do any recursion on type with error posted, since we may
779 -- have a malformed type that leads us into a loop.
781 elsif Error_Posted
(T
) then
784 -- Otherwise if component size unknown, then array size unknown
786 elsif not Size_Known
(Component_Type
(T
)) then
790 -- Check for all indexes static, and also compute possible size
791 -- (in case it is less than 32 and may be packable).
794 Esiz
: Uint
:= Component_Size
(T
);
798 Index
:= First_Index
(T
);
799 while Present
(Index
) loop
800 if Nkind
(Index
) = N_Range
then
801 Get_Index_Bounds
(Index
, Low
, High
);
803 elsif Error_Posted
(Scalar_Range
(Etype
(Index
))) then
807 Low
:= Type_Low_Bound
(Etype
(Index
));
808 High
:= Type_High_Bound
(Etype
(Index
));
811 if not Compile_Time_Known_Value
(Low
)
812 or else not Compile_Time_Known_Value
(High
)
813 or else Etype
(Index
) = Any_Type
818 Dim
:= Expr_Value
(High
) - Expr_Value
(Low
) + 1;
830 Set_Small_Size
(T
, Esiz
);
834 -- Access types always have known at compile time sizes
836 elsif Is_Access_Type
(T
) then
839 -- For non-generic private types, go to underlying type if present
841 elsif Is_Private_Type
(T
)
842 and then not Is_Generic_Type
(T
)
843 and then Present
(Underlying_Type
(T
))
845 -- Don't do any recursion on type with error posted, since we may
846 -- have a malformed type that leads us into a loop.
848 if Error_Posted
(T
) then
851 return Size_Known
(Underlying_Type
(T
));
856 elsif Is_Record_Type
(T
) then
858 -- A class-wide type is never considered to have a known size
860 if Is_Class_Wide_Type
(T
) then
863 -- A subtype of a variant record must not have non-static
864 -- discriminated components.
866 elsif T
/= Base_Type
(T
)
867 and then not Static_Discriminated_Components
(T
)
871 -- Don't do any recursion on type with error posted, since we may
872 -- have a malformed type that leads us into a loop.
874 elsif Error_Posted
(T
) then
878 -- Now look at the components of the record
881 -- The following two variables are used to keep track of the
882 -- size of packed records if we can tell the size of the packed
883 -- record in the front end. Packed_Size_Known is True if so far
884 -- we can figure out the size. It is initialized to True for a
885 -- packed record, unless the record has discriminants or atomic
886 -- components or independent components.
888 -- The reason we eliminate the discriminated case is that
889 -- we don't know the way the back end lays out discriminated
890 -- packed records. If Packed_Size_Known is True, then
891 -- Packed_Size is the size in bits so far.
893 Packed_Size_Known
: Boolean :=
895 and then not Has_Discriminants
(T
)
896 and then not Has_Atomic_Components
(T
)
897 and then not Has_Independent_Components
(T
);
899 Packed_Size
: Uint
:= Uint_0
;
900 -- Size in bits so far
903 -- Test for variant part present
905 if Has_Discriminants
(T
)
906 and then Present
(Parent
(T
))
907 and then Nkind
(Parent
(T
)) = N_Full_Type_Declaration
908 and then Nkind
(Type_Definition
(Parent
(T
))) =
910 and then not Null_Present
(Type_Definition
(Parent
(T
)))
912 Present
(Variant_Part
913 (Component_List
(Type_Definition
(Parent
(T
)))))
915 -- If variant part is present, and type is unconstrained,
916 -- then we must have defaulted discriminants, or a size
917 -- clause must be present for the type, or else the size
918 -- is definitely not known at compile time.
920 if not Is_Constrained
(T
)
922 No
(Discriminant_Default_Value
(First_Discriminant
(T
)))
923 and then Unknown_RM_Size
(T
)
929 -- Loop through components
931 Comp
:= First_Component_Or_Discriminant
(T
);
932 while Present
(Comp
) loop
933 Ctyp
:= Etype
(Comp
);
935 -- We do not know the packed size if there is a component
936 -- clause present (we possibly could, but this would only
937 -- help in the case of a record with partial rep clauses.
938 -- That's because in the case of full rep clauses, the
939 -- size gets figured out anyway by a different circuit).
941 if Present
(Component_Clause
(Comp
)) then
942 Packed_Size_Known
:= False;
945 -- We do not know the packed size for an atomic/VFA type
946 -- or component, or an independent type or component, or a
947 -- by-reference type or aliased component (because packing
948 -- does not touch these).
950 if Is_Atomic_Or_VFA
(Ctyp
)
951 or else Is_Atomic_Or_VFA
(Comp
)
952 or else Is_Independent
(Ctyp
)
953 or else Is_Independent
(Comp
)
954 or else Is_By_Reference_Type
(Ctyp
)
955 or else Is_Aliased
(Comp
)
957 Packed_Size_Known
:= False;
960 -- We need to identify a component that is an array where
961 -- the index type is an enumeration type with non-standard
962 -- representation, and some bound of the type depends on a
965 -- This is because gigi computes the size by doing a
966 -- substitution of the appropriate discriminant value in
967 -- the size expression for the base type, and gigi is not
968 -- clever enough to evaluate the resulting expression (which
969 -- involves a call to rep_to_pos) at compile time.
971 -- It would be nice if gigi would either recognize that
972 -- this expression can be computed at compile time, or
973 -- alternatively figured out the size from the subtype
974 -- directly, where all the information is at hand ???
976 if Is_Array_Type
(Etype
(Comp
))
977 and then Present
(Packed_Array_Impl_Type
(Etype
(Comp
)))
980 Ocomp
: constant Entity_Id
:=
981 Original_Record_Component
(Comp
);
982 OCtyp
: constant Entity_Id
:= Etype
(Ocomp
);
988 Ind
:= First_Index
(OCtyp
);
989 while Present
(Ind
) loop
990 Indtyp
:= Etype
(Ind
);
992 if Is_Enumeration_Type
(Indtyp
)
993 and then Has_Non_Standard_Rep
(Indtyp
)
995 Lo
:= Type_Low_Bound
(Indtyp
);
996 Hi
:= Type_High_Bound
(Indtyp
);
998 if Is_Entity_Name
(Lo
)
999 and then Ekind
(Entity
(Lo
)) = E_Discriminant
1003 elsif Is_Entity_Name
(Hi
)
1004 and then Ekind
(Entity
(Hi
)) = E_Discriminant
1015 -- Clearly size of record is not known if the size of one of
1016 -- the components is not known.
1018 if not Size_Known
(Ctyp
) then
1022 -- Accumulate packed size if possible
1024 if Packed_Size_Known
then
1026 -- We can only deal with elementary types, since for
1027 -- non-elementary components, alignment enters into the
1028 -- picture, and we don't know enough to handle proper
1029 -- alignment in this context. Packed arrays count as
1030 -- elementary if the representation is a modular type.
1032 if Is_Elementary_Type
(Ctyp
)
1033 or else (Is_Array_Type
(Ctyp
)
1035 (Packed_Array_Impl_Type
(Ctyp
))
1036 and then Is_Modular_Integer_Type
1037 (Packed_Array_Impl_Type
(Ctyp
)))
1039 -- Packed size unknown if we have an atomic/VFA type
1040 -- or a by-reference type, since the back end knows
1041 -- how these are layed out.
1043 if Is_Atomic_Or_VFA
(Ctyp
)
1044 or else Is_By_Reference_Type
(Ctyp
)
1046 Packed_Size_Known
:= False;
1048 -- If RM_Size is known and static, then we can keep
1049 -- accumulating the packed size
1051 elsif Known_Static_RM_Size
(Ctyp
) then
1053 -- A little glitch, to be removed sometime ???
1054 -- gigi does not understand zero sizes yet.
1056 if RM_Size
(Ctyp
) = Uint_0
then
1057 Packed_Size_Known
:= False;
1059 -- Normal case where we can keep accumulating the
1060 -- packed array size.
1063 Packed_Size
:= Packed_Size
+ RM_Size
(Ctyp
);
1066 -- If we have a field whose RM_Size is not known then
1067 -- we can't figure out the packed size here.
1070 Packed_Size_Known
:= False;
1073 -- If we have a non-elementary type we can't figure out
1074 -- the packed array size (alignment issues).
1077 Packed_Size_Known
:= False;
1081 Next_Component_Or_Discriminant
(Comp
);
1084 if Packed_Size_Known
then
1085 Set_Small_Size
(T
, Packed_Size
);
1091 -- All other cases, size not known at compile time
1098 -------------------------------------
1099 -- Static_Discriminated_Components --
1100 -------------------------------------
1102 function Static_Discriminated_Components
1103 (T
: Entity_Id
) return Boolean
1105 Constraint
: Elmt_Id
;
1108 if Has_Discriminants
(T
)
1109 and then Present
(Discriminant_Constraint
(T
))
1110 and then Present
(First_Component
(T
))
1112 Constraint
:= First_Elmt
(Discriminant_Constraint
(T
));
1113 while Present
(Constraint
) loop
1114 if not Compile_Time_Known_Value
(Node
(Constraint
)) then
1118 Next_Elmt
(Constraint
);
1123 end Static_Discriminated_Components
;
1125 -- Start of processing for Check_Compile_Time_Size
1128 Set_Size_Known_At_Compile_Time
(T
, Size_Known
(T
));
1129 end Check_Compile_Time_Size
;
1131 -----------------------------------
1132 -- Check_Component_Storage_Order --
1133 -----------------------------------
1135 procedure Check_Component_Storage_Order
1136 (Encl_Type
: Entity_Id
;
1139 Comp_ADC_Present
: out Boolean)
1141 Comp_Type
: Entity_Id
;
1145 Comp_Byte_Aligned
: Boolean;
1146 -- Set for the record case, True if Comp starts on a byte boundary
1147 -- (in which case it is allowed to have different storage order).
1149 Comp_SSO_Differs
: Boolean;
1150 -- Set True when the component is a nested composite, and it does not
1151 -- have the same scalar storage order as Encl_Type.
1153 Component_Aliased
: Boolean;
1158 if Present
(Comp
) then
1160 Comp_Type
:= Etype
(Comp
);
1162 if Is_Tag
(Comp
) then
1163 Comp_Byte_Aligned
:= True;
1164 Component_Aliased
:= False;
1167 -- If a component clause is present, check if the component starts
1168 -- on a storage element boundary. Otherwise conservatively assume
1169 -- it does so only in the case where the record is not packed.
1171 if Present
(Component_Clause
(Comp
)) then
1172 Comp_Byte_Aligned
:=
1173 Normalized_First_Bit
(Comp
) mod System_Storage_Unit
= 0;
1175 Comp_Byte_Aligned
:= not Is_Packed
(Encl_Type
);
1178 Component_Aliased
:= Is_Aliased
(Comp
);
1184 Err_Node
:= Encl_Type
;
1185 Comp_Type
:= Component_Type
(Encl_Type
);
1187 Component_Aliased
:= Has_Aliased_Components
(Encl_Type
);
1190 -- Note: the Reverse_Storage_Order flag is set on the base type, but
1191 -- the attribute definition clause is attached to the first subtype.
1193 Comp_Type
:= Base_Type
(Comp_Type
);
1194 Comp_ADC
:= Get_Attribute_Definition_Clause
1195 (First_Subtype
(Comp_Type
),
1196 Attribute_Scalar_Storage_Order
);
1197 Comp_ADC_Present
:= Present
(Comp_ADC
);
1199 -- Case of record or array component: check storage order compatibility
1201 if Is_Record_Type
(Comp_Type
) or else Is_Array_Type
(Comp_Type
) then
1203 Reverse_Storage_Order
(Encl_Type
)
1205 Reverse_Storage_Order
(Comp_Type
);
1207 -- Parent and extension must have same storage order
1209 if Present
(Comp
) and then Chars
(Comp
) = Name_uParent
then
1210 if Comp_SSO_Differs
then
1212 ("record extension must have same scalar storage order as "
1213 & "parent", Err_Node
);
1216 -- If enclosing composite has explicit SSO then nested composite must
1217 -- have explicit SSO as well.
1219 elsif Present
(ADC
) and then No
(Comp_ADC
) then
1220 Error_Msg_N
("nested composite must have explicit scalar "
1221 & "storage order", Err_Node
);
1223 -- If component and composite SSO differs, check that component
1224 -- falls on byte boundaries and isn't packed.
1226 elsif Comp_SSO_Differs
then
1228 -- Component SSO differs from enclosing composite:
1230 -- Reject if component is a packed array, as it may be represented
1231 -- as a scalar internally.
1233 if Is_Packed_Array
(Comp_Type
) then
1235 ("type of packed component must have same scalar "
1236 & "storage order as enclosing composite", Err_Node
);
1238 -- Reject if composite is a packed array, as it may be rewritten
1239 -- into an array of scalars.
1241 elsif Is_Packed_Array
(Encl_Type
) then
1242 Error_Msg_N
("type of packed array must have same scalar "
1243 & "storage order as component", Err_Node
);
1245 -- Reject if not byte aligned
1247 elsif Is_Record_Type
(Encl_Type
)
1248 and then not Comp_Byte_Aligned
1251 ("type of non-byte-aligned component must have same scalar "
1252 & "storage order as enclosing composite", Err_Node
);
1256 -- Enclosing type has explicit SSO: non-composite component must not
1259 elsif Present
(ADC
) and then Component_Aliased
then
1261 ("aliased component not permitted for type with "
1262 & "explicit Scalar_Storage_Order", Err_Node
);
1264 end Check_Component_Storage_Order
;
1266 -----------------------------
1267 -- Check_Debug_Info_Needed --
1268 -----------------------------
1270 procedure Check_Debug_Info_Needed
(T
: Entity_Id
) is
1272 if Debug_Info_Off
(T
) then
1275 elsif Comes_From_Source
(T
)
1276 or else Debug_Generated_Code
1277 or else Debug_Flag_VV
1278 or else Needs_Debug_Info
(T
)
1280 Set_Debug_Info_Needed
(T
);
1282 end Check_Debug_Info_Needed
;
1284 -------------------------------
1285 -- Check_Expression_Function --
1286 -------------------------------
1288 procedure Check_Expression_Function
(N
: Node_Id
; Nam
: Entity_Id
) is
1291 function Find_Constant
(Nod
: Node_Id
) return Traverse_Result
;
1292 -- Function to search for deferred constant
1298 function Find_Constant
(Nod
: Node_Id
) return Traverse_Result
is
1300 -- When a constant is initialized with the result of a dispatching
1301 -- call, the constant declaration is rewritten as a renaming of the
1302 -- displaced function result. This scenario is not a premature use of
1303 -- a constant even though the Has_Completion flag is not set.
1305 if Is_Entity_Name
(Nod
)
1306 and then Present
(Entity
(Nod
))
1307 and then Ekind
(Entity
(Nod
)) = E_Constant
1308 and then Scope
(Entity
(Nod
)) = Current_Scope
1309 and then Nkind
(Declaration_Node
(Entity
(Nod
))) =
1310 N_Object_Declaration
1311 and then not Is_Imported
(Entity
(Nod
))
1312 and then not Has_Completion
(Entity
(Nod
))
1315 ("premature use of& in call or instance", N
, Entity
(Nod
));
1317 elsif Nkind
(Nod
) = N_Attribute_Reference
then
1318 Analyze
(Prefix
(Nod
));
1320 if Is_Entity_Name
(Prefix
(Nod
))
1321 and then Is_Type
(Entity
(Prefix
(Nod
)))
1323 Freeze_Before
(N
, Entity
(Prefix
(Nod
)));
1330 procedure Check_Deferred
is new Traverse_Proc
(Find_Constant
);
1332 -- Start of processing for Check_Expression_Function
1335 Decl
:= Original_Node
(Unit_Declaration_Node
(Nam
));
1337 if Scope
(Nam
) = Current_Scope
1338 and then Nkind
(Decl
) = N_Expression_Function
1340 Check_Deferred
(Expression
(Decl
));
1342 end Check_Expression_Function
;
1344 ----------------------------
1345 -- Check_Strict_Alignment --
1346 ----------------------------
1348 procedure Check_Strict_Alignment
(E
: Entity_Id
) is
1352 if Is_Tagged_Type
(E
) or else Is_Concurrent_Type
(E
) then
1353 Set_Strict_Alignment
(E
);
1355 elsif Is_Array_Type
(E
) then
1356 Set_Strict_Alignment
(E
, Strict_Alignment
(Component_Type
(E
)));
1358 elsif Is_Record_Type
(E
) then
1359 if Is_Limited_Record
(E
) then
1360 Set_Strict_Alignment
(E
);
1364 Comp
:= First_Component
(E
);
1365 while Present
(Comp
) loop
1366 if not Is_Type
(Comp
)
1367 and then (Strict_Alignment
(Etype
(Comp
))
1368 or else Is_Aliased
(Comp
))
1370 Set_Strict_Alignment
(E
);
1374 Next_Component
(Comp
);
1377 end Check_Strict_Alignment
;
1379 -------------------------
1380 -- Check_Unsigned_Type --
1381 -------------------------
1383 procedure Check_Unsigned_Type
(E
: Entity_Id
) is
1384 Ancestor
: Entity_Id
;
1389 if not Is_Discrete_Or_Fixed_Point_Type
(E
) then
1393 -- Do not attempt to analyze case where range was in error
1395 if No
(Scalar_Range
(E
)) or else Error_Posted
(Scalar_Range
(E
)) then
1399 -- The situation that is non trivial is something like
1401 -- subtype x1 is integer range -10 .. +10;
1402 -- subtype x2 is x1 range 0 .. V1;
1403 -- subtype x3 is x2 range V2 .. V3;
1404 -- subtype x4 is x3 range V4 .. V5;
1406 -- where Vn are variables. Here the base type is signed, but we still
1407 -- know that x4 is unsigned because of the lower bound of x2.
1409 -- The only way to deal with this is to look up the ancestor chain
1413 if Ancestor
= Any_Type
or else Etype
(Ancestor
) = Any_Type
then
1417 Lo_Bound
:= Type_Low_Bound
(Ancestor
);
1419 if Compile_Time_Known_Value
(Lo_Bound
) then
1420 if Expr_Rep_Value
(Lo_Bound
) >= 0 then
1421 Set_Is_Unsigned_Type
(E
, True);
1427 Ancestor
:= Ancestor_Subtype
(Ancestor
);
1429 -- If no ancestor had a static lower bound, go to base type
1431 if No
(Ancestor
) then
1433 -- Note: the reason we still check for a compile time known
1434 -- value for the base type is that at least in the case of
1435 -- generic formals, we can have bounds that fail this test,
1436 -- and there may be other cases in error situations.
1438 Btyp
:= Base_Type
(E
);
1440 if Btyp
= Any_Type
or else Etype
(Btyp
) = Any_Type
then
1444 Lo_Bound
:= Type_Low_Bound
(Base_Type
(E
));
1446 if Compile_Time_Known_Value
(Lo_Bound
)
1447 and then Expr_Rep_Value
(Lo_Bound
) >= 0
1449 Set_Is_Unsigned_Type
(E
, True);
1456 end Check_Unsigned_Type
;
1458 -----------------------------
1459 -- Is_Atomic_VFA_Aggregate --
1460 -----------------------------
1462 function Is_Atomic_VFA_Aggregate
1464 Typ
: Entity_Id
) return Boolean
1466 Loc
: constant Source_Ptr
:= Sloc
(E
);
1474 -- Array may be qualified, so find outer context
1476 if Nkind
(Par
) = N_Qualified_Expression
then
1477 Par
:= Parent
(Par
);
1480 if Nkind_In
(Par
, N_Object_Declaration
, N_Assignment_Statement
)
1481 and then Comes_From_Source
(Par
)
1483 Temp
:= Make_Temporary
(Loc
, 'T', E
);
1485 Make_Object_Declaration
(Loc
,
1486 Defining_Identifier
=> Temp
,
1487 Object_Definition
=> New_Occurrence_Of
(Typ
, Loc
),
1488 Expression
=> Relocate_Node
(E
));
1489 Insert_Before
(Par
, New_N
);
1492 Set_Expression
(Par
, New_Occurrence_Of
(Temp
, Loc
));
1498 end Is_Atomic_VFA_Aggregate
;
1500 -----------------------------------------------
1501 -- Explode_Initialization_Compound_Statement --
1502 -----------------------------------------------
1504 procedure Explode_Initialization_Compound_Statement
(E
: Entity_Id
) is
1505 Init_Stmts
: constant Node_Id
:= Initialization_Statements
(E
);
1508 if Present
(Init_Stmts
)
1509 and then Nkind
(Init_Stmts
) = N_Compound_Statement
1511 Insert_List_Before
(Init_Stmts
, Actions
(Init_Stmts
));
1513 -- Note that we rewrite Init_Stmts into a NULL statement, rather than
1514 -- just removing it, because Freeze_All may rely on this particular
1515 -- Node_Id still being present in the enclosing list to know where to
1518 Rewrite
(Init_Stmts
, Make_Null_Statement
(Sloc
(Init_Stmts
)));
1520 Set_Initialization_Statements
(E
, Empty
);
1522 end Explode_Initialization_Compound_Statement
;
1528 -- Note: the easy coding for this procedure would be to just build a
1529 -- single list of freeze nodes and then insert them and analyze them
1530 -- all at once. This won't work, because the analysis of earlier freeze
1531 -- nodes may recursively freeze types which would otherwise appear later
1532 -- on in the freeze list. So we must analyze and expand the freeze nodes
1533 -- as they are generated.
1535 procedure Freeze_All
(From
: Entity_Id
; After
: in out Node_Id
) is
1539 procedure Freeze_All_Ent
(From
: Entity_Id
; After
: in out Node_Id
);
1540 -- This is the internal recursive routine that does freezing of entities
1541 -- (but NOT the analysis of default expressions, which should not be
1542 -- recursive, we don't want to analyze those till we are sure that ALL
1543 -- the types are frozen).
1545 --------------------
1546 -- Freeze_All_Ent --
1547 --------------------
1549 procedure Freeze_All_Ent
(From
: Entity_Id
; After
: in out Node_Id
) is
1554 procedure Process_Flist
;
1555 -- If freeze nodes are present, insert and analyze, and reset cursor
1556 -- for next insertion.
1562 procedure Process_Flist
is
1564 if Is_Non_Empty_List
(Flist
) then
1565 Lastn
:= Next
(After
);
1566 Insert_List_After_And_Analyze
(After
, Flist
);
1568 if Present
(Lastn
) then
1569 After
:= Prev
(Lastn
);
1571 After
:= Last
(List_Containing
(After
));
1576 -- Start or processing for Freeze_All_Ent
1580 while Present
(E
) loop
1582 -- If the entity is an inner package which is not a package
1583 -- renaming, then its entities must be frozen at this point. Note
1584 -- that such entities do NOT get frozen at the end of the nested
1585 -- package itself (only library packages freeze).
1587 -- Same is true for task declarations, where anonymous records
1588 -- created for entry parameters must be frozen.
1590 if Ekind
(E
) = E_Package
1591 and then No
(Renamed_Object
(E
))
1592 and then not Is_Child_Unit
(E
)
1593 and then not Is_Frozen
(E
)
1596 Install_Visible_Declarations
(E
);
1597 Install_Private_Declarations
(E
);
1599 Freeze_All
(First_Entity
(E
), After
);
1601 End_Package_Scope
(E
);
1603 if Is_Generic_Instance
(E
)
1604 and then Has_Delayed_Freeze
(E
)
1606 Set_Has_Delayed_Freeze
(E
, False);
1607 Expand_N_Package_Declaration
(Unit_Declaration_Node
(E
));
1610 elsif Ekind
(E
) in Task_Kind
1611 and then Nkind_In
(Parent
(E
), N_Task_Type_Declaration
,
1612 N_Single_Task_Declaration
)
1615 Freeze_All
(First_Entity
(E
), After
);
1618 -- For a derived tagged type, we must ensure that all the
1619 -- primitive operations of the parent have been frozen, so that
1620 -- their addresses will be in the parent's dispatch table at the
1621 -- point it is inherited.
1623 elsif Ekind
(E
) = E_Record_Type
1624 and then Is_Tagged_Type
(E
)
1625 and then Is_Tagged_Type
(Etype
(E
))
1626 and then Is_Derived_Type
(E
)
1629 Prim_List
: constant Elist_Id
:=
1630 Primitive_Operations
(Etype
(E
));
1636 Prim
:= First_Elmt
(Prim_List
);
1637 while Present
(Prim
) loop
1638 Subp
:= Node
(Prim
);
1640 if Comes_From_Source
(Subp
)
1641 and then not Is_Frozen
(Subp
)
1643 Flist
:= Freeze_Entity
(Subp
, After
);
1652 if not Is_Frozen
(E
) then
1653 Flist
:= Freeze_Entity
(E
, After
);
1656 -- If already frozen, and there are delayed aspects, this is where
1657 -- we do the visibility check for these aspects (see Sem_Ch13 spec
1658 -- for a description of how we handle aspect visibility).
1660 elsif Has_Delayed_Aspects
(E
) then
1662 -- Retrieve the visibility to the discriminants in order to
1663 -- analyze properly the aspects.
1665 Push_Scope_And_Install_Discriminants
(E
);
1671 Ritem
:= First_Rep_Item
(E
);
1672 while Present
(Ritem
) loop
1673 if Nkind
(Ritem
) = N_Aspect_Specification
1674 and then Entity
(Ritem
) = E
1675 and then Is_Delayed_Aspect
(Ritem
)
1677 Check_Aspect_At_End_Of_Declarations
(Ritem
);
1680 Ritem
:= Next_Rep_Item
(Ritem
);
1684 Uninstall_Discriminants_And_Pop_Scope
(E
);
1687 -- If an incomplete type is still not frozen, this may be a
1688 -- premature freezing because of a body declaration that follows.
1689 -- Indicate where the freezing took place. Freezing will happen
1690 -- if the body comes from source, but not if it is internally
1691 -- generated, for example as the body of a type invariant.
1693 -- If the freezing is caused by the end of the current declarative
1694 -- part, it is a Taft Amendment type, and there is no error.
1696 if not Is_Frozen
(E
)
1697 and then Ekind
(E
) = E_Incomplete_Type
1700 Bod
: constant Node_Id
:= Next
(After
);
1703 -- The presence of a body freezes all entities previously
1704 -- declared in the current list of declarations, but this
1705 -- does not apply if the body does not come from source.
1706 -- A type invariant is transformed into a subprogram body
1707 -- which is placed at the end of the private part of the
1708 -- current package, but this body does not freeze incomplete
1709 -- types that may be declared in this private part.
1711 if (Nkind_In
(Bod
, N_Subprogram_Body
,
1716 or else Nkind
(Bod
) in N_Body_Stub
)
1718 List_Containing
(After
) = List_Containing
(Parent
(E
))
1719 and then Comes_From_Source
(Bod
)
1721 Error_Msg_Sloc
:= Sloc
(Next
(After
));
1723 ("type& is frozen# before its full declaration",
1733 -- Start of processing for Freeze_All
1736 Freeze_All_Ent
(From
, After
);
1738 -- Now that all types are frozen, we can deal with default expressions
1739 -- that require us to build a default expression functions. This is the
1740 -- point at which such functions are constructed (after all types that
1741 -- might be used in such expressions have been frozen).
1743 -- For subprograms that are renaming_as_body, we create the wrapper
1744 -- bodies as needed.
1746 -- We also add finalization chains to access types whose designated
1747 -- types are controlled. This is normally done when freezing the type,
1748 -- but this misses recursive type definitions where the later members
1749 -- of the recursion introduce controlled components.
1751 -- Loop through entities
1754 while Present
(E
) loop
1755 if Is_Subprogram
(E
) then
1756 if not Default_Expressions_Processed
(E
) then
1757 Process_Default_Expressions
(E
, After
);
1760 if not Has_Completion
(E
) then
1761 Decl
:= Unit_Declaration_Node
(E
);
1763 if Nkind
(Decl
) = N_Subprogram_Renaming_Declaration
then
1764 if Error_Posted
(Decl
) then
1765 Set_Has_Completion
(E
);
1767 Build_And_Analyze_Renamed_Body
(Decl
, E
, After
);
1770 elsif Nkind
(Decl
) = N_Subprogram_Declaration
1771 and then Present
(Corresponding_Body
(Decl
))
1773 Nkind
(Unit_Declaration_Node
(Corresponding_Body
(Decl
)))
1774 = N_Subprogram_Renaming_Declaration
1776 Build_And_Analyze_Renamed_Body
1777 (Decl
, Corresponding_Body
(Decl
), After
);
1781 elsif Ekind
(E
) in Task_Kind
1782 and then Nkind_In
(Parent
(E
), N_Task_Type_Declaration
,
1783 N_Single_Task_Declaration
)
1789 Ent
:= First_Entity
(E
);
1790 while Present
(Ent
) loop
1792 and then not Default_Expressions_Processed
(Ent
)
1794 Process_Default_Expressions
(Ent
, After
);
1802 -- Historical note: We used to create a finalization master for an
1803 -- access type whose designated type is not controlled, but contains
1804 -- private controlled compoments. This form of postprocessing is no
1805 -- longer needed because the finalization master is now created when
1806 -- the access type is frozen (see Exp_Ch3.Freeze_Type).
1812 -----------------------
1813 -- Freeze_And_Append --
1814 -----------------------
1816 procedure Freeze_And_Append
1819 Result
: in out List_Id
)
1821 L
: constant List_Id
:= Freeze_Entity
(Ent
, N
);
1823 if Is_Non_Empty_List
(L
) then
1824 if Result
= No_List
then
1827 Append_List
(L
, Result
);
1830 end Freeze_And_Append
;
1836 procedure Freeze_Before
(N
: Node_Id
; T
: Entity_Id
) is
1837 Freeze_Nodes
: constant List_Id
:= Freeze_Entity
(T
, N
);
1840 if Ekind
(T
) = E_Function
then
1841 Check_Expression_Function
(N
, T
);
1844 if Is_Non_Empty_List
(Freeze_Nodes
) then
1845 Insert_Actions
(N
, Freeze_Nodes
);
1853 function Freeze_Entity
(E
: Entity_Id
; N
: Node_Id
) return List_Id
is
1854 GM
: constant Ghost_Mode_Type
:= Ghost_Mode
;
1855 -- Save the current Ghost mode in effect in case the entity being frozen
1856 -- sets a different mode.
1858 Loc
: constant Source_Ptr
:= Sloc
(N
);
1865 Test_E
: Entity_Id
:= E
;
1866 -- This could use a comment ???
1868 Late_Freezing
: Boolean := False;
1869 -- Used to detect attempt to freeze function declared in another unit
1871 Result
: List_Id
:= No_List
;
1872 -- List of freezing actions, left at No_List if none
1874 Has_Default_Initialization
: Boolean := False;
1875 -- This flag gets set to true for a variable with default initialization
1877 procedure Add_To_Result
(N
: Node_Id
);
1878 -- N is a freezing action to be appended to the Result
1880 function After_Last_Declaration
return Boolean;
1881 -- If Loc is a freeze_entity that appears after the last declaration
1882 -- in the scope, inhibit error messages on late completion.
1884 procedure Check_Current_Instance
(Comp_Decl
: Node_Id
);
1885 -- Check that an Access or Unchecked_Access attribute with a prefix
1886 -- which is the current instance type can only be applied when the type
1889 procedure Check_Suspicious_Modulus
(Utype
: Entity_Id
);
1890 -- Give warning for modulus of 8, 16, 32, or 64 given as an explicit
1891 -- integer literal without an explicit corresponding size clause. The
1892 -- caller has checked that Utype is a modular integer type.
1894 procedure Freeze_Array_Type
(Arr
: Entity_Id
);
1895 -- Freeze array type, including freezing index and component types
1897 procedure Freeze_Object_Declaration
(E
: Entity_Id
);
1898 -- Perform checks and generate freeze node if needed for a constant or
1899 -- variable declared by an object declaration.
1901 function Freeze_Generic_Entities
(Pack
: Entity_Id
) return List_Id
;
1902 -- Create Freeze_Generic_Entity nodes for types declared in a generic
1903 -- package. Recurse on inner generic packages.
1905 function Freeze_Profile
(E
: Entity_Id
) return Boolean;
1906 -- Freeze formals and return type of subprogram. If some type in the
1907 -- profile is a limited view, freezing of the entity will take place
1908 -- elsewhere, and the function returns False. This routine will be
1909 -- modified if and when we can implement AI05-019 efficiently ???
1911 procedure Freeze_Record_Type
(Rec
: Entity_Id
);
1912 -- Freeze record type, including freezing component types, and freezing
1913 -- primitive operations if this is a tagged type.
1915 function Has_Boolean_Aspect_Import
(E
: Entity_Id
) return Boolean;
1916 -- Determine whether an arbitrary entity is subject to Boolean aspect
1917 -- Import and its value is specified as True.
1919 procedure Late_Freeze_Subprogram
(E
: Entity_Id
);
1920 -- Following AI05-151, a function can return a limited view of a type
1921 -- declared elsewhere. In that case the function cannot be frozen at
1922 -- the end of its enclosing package. If its first use is in a different
1923 -- unit, it cannot be frozen there, but if the call is legal the full
1924 -- view of the return type is available and the subprogram can now be
1925 -- frozen. However the freeze node cannot be inserted at the point of
1926 -- call, but rather must go in the package holding the function, so that
1927 -- the backend can process it in the proper context.
1929 procedure Restore_Globals
;
1930 -- Restore the values of all saved global variables
1932 procedure Wrap_Imported_Subprogram
(E
: Entity_Id
);
1933 -- If E is an entity for an imported subprogram with pre/post-conditions
1934 -- then this procedure will create a wrapper to ensure that proper run-
1935 -- time checking of the pre/postconditions. See body for details.
1941 procedure Add_To_Result
(N
: Node_Id
) is
1944 Result
:= New_List
(N
);
1950 ----------------------------
1951 -- After_Last_Declaration --
1952 ----------------------------
1954 function After_Last_Declaration
return Boolean is
1955 Spec
: constant Node_Id
:= Parent
(Current_Scope
);
1958 if Nkind
(Spec
) = N_Package_Specification
then
1959 if Present
(Private_Declarations
(Spec
)) then
1960 return Loc
>= Sloc
(Last
(Private_Declarations
(Spec
)));
1961 elsif Present
(Visible_Declarations
(Spec
)) then
1962 return Loc
>= Sloc
(Last
(Visible_Declarations
(Spec
)));
1970 end After_Last_Declaration
;
1972 ----------------------------
1973 -- Check_Current_Instance --
1974 ----------------------------
1976 procedure Check_Current_Instance
(Comp_Decl
: Node_Id
) is
1978 function Is_Aliased_View_Of_Type
(Typ
: Entity_Id
) return Boolean;
1979 -- Determine whether Typ is compatible with the rules for aliased
1980 -- views of types as defined in RM 3.10 in the various dialects.
1982 function Process
(N
: Node_Id
) return Traverse_Result
;
1983 -- Process routine to apply check to given node
1985 -----------------------------
1986 -- Is_Aliased_View_Of_Type --
1987 -----------------------------
1989 function Is_Aliased_View_Of_Type
(Typ
: Entity_Id
) return Boolean is
1990 Typ_Decl
: constant Node_Id
:= Parent
(Typ
);
1995 if Nkind
(Typ_Decl
) = N_Full_Type_Declaration
1996 and then Limited_Present
(Type_Definition
(Typ_Decl
))
2000 -- The following paragraphs describe what a legal aliased view of
2001 -- a type is in the various dialects of Ada.
2005 -- The current instance of a limited type, and a formal parameter
2006 -- or generic formal object of a tagged type.
2008 -- Ada 95 limited type
2009 -- * Type with reserved word "limited"
2010 -- * A protected or task type
2011 -- * A composite type with limited component
2013 elsif Ada_Version
<= Ada_95
then
2014 return Is_Limited_Type
(Typ
);
2018 -- The current instance of a limited tagged type, a protected
2019 -- type, a task type, or a type that has the reserved word
2020 -- "limited" in its full definition ... a formal parameter or
2021 -- generic formal object of a tagged type.
2023 -- Ada 2005 limited type
2024 -- * Type with reserved word "limited", "synchronized", "task"
2026 -- * A composite type with limited component
2027 -- * A derived type whose parent is a non-interface limited type
2029 elsif Ada_Version
= Ada_2005
then
2031 (Is_Limited_Type
(Typ
) and then Is_Tagged_Type
(Typ
))
2033 (Is_Derived_Type
(Typ
)
2034 and then not Is_Interface
(Etype
(Typ
))
2035 and then Is_Limited_Type
(Etype
(Typ
)));
2037 -- Ada 2012 and beyond
2039 -- The current instance of an immutably limited type ... a formal
2040 -- parameter or generic formal object of a tagged type.
2042 -- Ada 2012 limited type
2043 -- * Type with reserved word "limited", "synchronized", "task"
2045 -- * A composite type with limited component
2046 -- * A derived type whose parent is a non-interface limited type
2047 -- * An incomplete view
2049 -- Ada 2012 immutably limited type
2050 -- * Explicitly limited record type
2051 -- * Record extension with "limited" present
2052 -- * Non-formal limited private type that is either tagged
2053 -- or has at least one access discriminant with a default
2055 -- * Task type, protected type or synchronized interface
2056 -- * Type derived from immutably limited type
2060 Is_Immutably_Limited_Type
(Typ
)
2061 or else Is_Incomplete_Type
(Typ
);
2063 end Is_Aliased_View_Of_Type
;
2069 function Process
(N
: Node_Id
) return Traverse_Result
is
2072 when N_Attribute_Reference
=>
2073 if Nam_In
(Attribute_Name
(N
), Name_Access
,
2074 Name_Unchecked_Access
)
2075 and then Is_Entity_Name
(Prefix
(N
))
2076 and then Is_Type
(Entity
(Prefix
(N
)))
2077 and then Entity
(Prefix
(N
)) = E
2079 if Ada_Version
< Ada_2012
then
2081 ("current instance must be a limited type",
2085 ("current instance must be an immutably limited "
2086 & "type (RM-2012, 7.5 (8.1/3))", Prefix
(N
));
2095 when others => return OK
;
2099 procedure Traverse
is new Traverse_Proc
(Process
);
2103 Rec_Type
: constant Entity_Id
:=
2104 Scope
(Defining_Identifier
(Comp_Decl
));
2106 -- Start of processing for Check_Current_Instance
2109 if not Is_Aliased_View_Of_Type
(Rec_Type
) then
2110 Traverse
(Comp_Decl
);
2112 end Check_Current_Instance
;
2114 ------------------------------
2115 -- Check_Suspicious_Modulus --
2116 ------------------------------
2118 procedure Check_Suspicious_Modulus
(Utype
: Entity_Id
) is
2119 Decl
: constant Node_Id
:= Declaration_Node
(Underlying_Type
(Utype
));
2122 if not Warn_On_Suspicious_Modulus_Value
then
2126 if Nkind
(Decl
) = N_Full_Type_Declaration
then
2128 Tdef
: constant Node_Id
:= Type_Definition
(Decl
);
2131 if Nkind
(Tdef
) = N_Modular_Type_Definition
then
2133 Modulus
: constant Node_Id
:=
2134 Original_Node
(Expression
(Tdef
));
2137 if Nkind
(Modulus
) = N_Integer_Literal
then
2139 Modv
: constant Uint
:= Intval
(Modulus
);
2140 Sizv
: constant Uint
:= RM_Size
(Utype
);
2143 -- First case, modulus and size are the same. This
2144 -- happens if you have something like mod 32, with
2145 -- an explicit size of 32, this is for sure a case
2146 -- where the warning is given, since it is seems
2147 -- very unlikely that someone would want e.g. a
2148 -- five bit type stored in 32 bits. It is much
2149 -- more likely they wanted a 32-bit type.
2154 -- Second case, the modulus is 32 or 64 and no
2155 -- size clause is present. This is a less clear
2156 -- case for giving the warning, but in the case
2157 -- of 32/64 (5-bit or 6-bit types) these seem rare
2158 -- enough that it is a likely error (and in any
2159 -- case using 2**5 or 2**6 in these cases seems
2160 -- clearer. We don't include 8 or 16 here, simply
2161 -- because in practice 3-bit and 4-bit types are
2162 -- more common and too many false positives if
2163 -- we warn in these cases.
2165 elsif not Has_Size_Clause
(Utype
)
2166 and then (Modv
= Uint_32
or else Modv
= Uint_64
)
2170 -- No warning needed
2176 -- If we fall through, give warning
2178 Error_Msg_Uint_1
:= Modv
;
2180 ("?M?2 '*'*^' may have been intended here",
2188 end Check_Suspicious_Modulus
;
2190 -----------------------
2191 -- Freeze_Array_Type --
2192 -----------------------
2194 procedure Freeze_Array_Type
(Arr
: Entity_Id
) is
2195 FS
: constant Entity_Id
:= First_Subtype
(Arr
);
2196 Ctyp
: constant Entity_Id
:= Component_Type
(Arr
);
2199 Non_Standard_Enum
: Boolean := False;
2200 -- Set true if any of the index types is an enumeration type with a
2201 -- non-standard representation.
2204 Freeze_And_Append
(Ctyp
, N
, Result
);
2206 Indx
:= First_Index
(Arr
);
2207 while Present
(Indx
) loop
2208 Freeze_And_Append
(Etype
(Indx
), N
, Result
);
2210 if Is_Enumeration_Type
(Etype
(Indx
))
2211 and then Has_Non_Standard_Rep
(Etype
(Indx
))
2213 Non_Standard_Enum
:= True;
2219 -- Processing that is done only for base types
2221 if Ekind
(Arr
) = E_Array_Type
then
2223 -- Deal with default setting of reverse storage order
2225 Set_SSO_From_Default
(Arr
);
2227 -- Propagate flags for component type
2229 if Is_Controlled
(Component_Type
(Arr
))
2230 or else Has_Controlled_Component
(Ctyp
)
2232 Set_Has_Controlled_Component
(Arr
);
2235 if Has_Unchecked_Union
(Component_Type
(Arr
)) then
2236 Set_Has_Unchecked_Union
(Arr
);
2239 -- Warn for pragma Pack overriding foreign convention
2241 if Has_Foreign_Convention
(Ctyp
)
2242 and then Has_Pragma_Pack
(Arr
)
2245 CN
: constant Name_Id
:=
2246 Get_Convention_Name
(Convention
(Ctyp
));
2247 PP
: constant Node_Id
:=
2248 Get_Pragma
(First_Subtype
(Arr
), Pragma_Pack
);
2250 if Present
(PP
) then
2251 Error_Msg_Name_1
:= CN
;
2252 Error_Msg_Sloc
:= Sloc
(Arr
);
2254 ("pragma Pack affects convention % components #??", PP
);
2255 Error_Msg_Name_1
:= CN
;
2257 ("\array components may not have % compatible "
2258 & "representation??", PP
);
2263 -- If packing was requested or if the component size was
2264 -- set explicitly, then see if bit packing is required. This
2265 -- processing is only done for base types, since all of the
2266 -- representation aspects involved are type-related.
2268 -- This is not just an optimization, if we start processing the
2269 -- subtypes, they interfere with the settings on the base type
2270 -- (this is because Is_Packed has a slightly different meaning
2271 -- before and after freezing).
2278 if (Is_Packed
(Arr
) or else Has_Pragma_Pack
(Arr
))
2279 and then Known_Static_RM_Size
(Ctyp
)
2280 and then not Has_Component_Size_Clause
(Arr
)
2282 Csiz
:= UI_Max
(RM_Size
(Ctyp
), 1);
2284 elsif Known_Component_Size
(Arr
) then
2285 Csiz
:= Component_Size
(Arr
);
2287 elsif not Known_Static_Esize
(Ctyp
) then
2291 Esiz
:= Esize
(Ctyp
);
2293 -- We can set the component size if it is less than 16,
2294 -- rounding it up to the next storage unit size.
2298 elsif Esiz
<= 16 then
2304 -- Set component size up to match alignment if it would
2305 -- otherwise be less than the alignment. This deals with
2306 -- cases of types whose alignment exceeds their size (the
2307 -- padded type cases).
2311 A
: constant Uint
:= Alignment_In_Bits
(Ctyp
);
2320 -- Case of component size that may result in packing
2322 if 1 <= Csiz
and then Csiz
<= 64 then
2324 Ent
: constant Entity_Id
:=
2325 First_Subtype
(Arr
);
2326 Pack_Pragma
: constant Node_Id
:=
2327 Get_Rep_Pragma
(Ent
, Name_Pack
);
2328 Comp_Size_C
: constant Node_Id
:=
2329 Get_Attribute_Definition_Clause
2330 (Ent
, Attribute_Component_Size
);
2333 -- Warn if we have pack and component size so that the
2336 -- Note: here we must check for the presence of a
2337 -- component size before checking for a Pack pragma to
2338 -- deal with the case where the array type is a derived
2339 -- type whose parent is currently private.
2341 if Present
(Comp_Size_C
)
2342 and then Has_Pragma_Pack
(Ent
)
2343 and then Warn_On_Redundant_Constructs
2345 Error_Msg_Sloc
:= Sloc
(Comp_Size_C
);
2347 ("?r?pragma Pack for& ignored!", Pack_Pragma
, Ent
);
2349 ("\?r?explicit component size given#!", Pack_Pragma
);
2350 Set_Is_Packed
(Base_Type
(Ent
), False);
2351 Set_Is_Bit_Packed_Array
(Base_Type
(Ent
), False);
2354 -- Set component size if not already set by a component
2357 if not Present
(Comp_Size_C
) then
2358 Set_Component_Size
(Arr
, Csiz
);
2361 -- Check for base type of 8, 16, 32 bits, where an
2362 -- unsigned subtype has a length one less than the
2363 -- base type (e.g. Natural subtype of Integer).
2365 -- In such cases, if a component size was not set
2366 -- explicitly, then generate a warning.
2368 if Has_Pragma_Pack
(Arr
)
2369 and then not Present
(Comp_Size_C
)
2370 and then (Csiz
= 7 or else Csiz
= 15 or else Csiz
= 31)
2371 and then Esize
(Base_Type
(Ctyp
)) = Csiz
+ 1
2373 Error_Msg_Uint_1
:= Csiz
;
2375 if Present
(Pack_Pragma
) then
2377 ("??pragma Pack causes component size to be ^!",
2380 ("\??use Component_Size to set desired value!",
2385 -- Actual packing is not needed for 8, 16, 32, 64. Also
2386 -- not needed for 24 if alignment is 1.
2392 or else (Csiz
= 24 and then Alignment
(Ctyp
) = 1)
2394 -- Here the array was requested to be packed, but
2395 -- the packing request had no effect, so Is_Packed
2398 -- Note: semantically this means that we lose track
2399 -- of the fact that a derived type inherited a pragma
2400 -- Pack that was non- effective, but that seems fine.
2402 -- We regard a Pack pragma as a request to set a
2403 -- representation characteristic, and this request
2406 Set_Is_Packed
(Base_Type
(Arr
), False);
2407 Set_Is_Bit_Packed_Array
(Base_Type
(Arr
), False);
2409 if Known_Static_Esize
(Component_Type
(Arr
))
2410 and then Esize
(Component_Type
(Arr
)) = Csiz
2412 Set_Has_Non_Standard_Rep
(Base_Type
(Arr
), False);
2415 -- In all other cases, packing is indeed needed
2418 Set_Has_Non_Standard_Rep
(Base_Type
(Arr
), True);
2419 Set_Is_Bit_Packed_Array
(Base_Type
(Arr
), True);
2420 Set_Is_Packed
(Base_Type
(Arr
), True);
2426 -- Check for Aliased or Atomic_Components/Atomic/VFA with
2427 -- unsuitable packing or explicit component size clause given.
2429 if (Has_Aliased_Components
(Arr
)
2430 or else Has_Atomic_Components
(Arr
)
2431 or else Is_Atomic_Or_VFA
(Ctyp
))
2433 (Has_Component_Size_Clause
(Arr
) or else Is_Packed
(Arr
))
2435 Alias_Atomic_Check
: declare
2437 procedure Complain_CS
(T
: String);
2438 -- Outputs error messages for incorrect CS clause or pragma
2439 -- Pack for aliased or atomic/VFA components (T is "aliased"
2440 -- or "atomic/vfa");
2446 procedure Complain_CS
(T
: String) is
2448 if Has_Component_Size_Clause
(Arr
) then
2450 Get_Attribute_Definition_Clause
2451 (FS
, Attribute_Component_Size
);
2454 ("incorrect component size for "
2455 & T
& " components", Clause
);
2456 Error_Msg_Uint_1
:= Esize
(Ctyp
);
2458 ("\only allowed value is^", Clause
);
2462 ("cannot pack " & T
& " components",
2463 Get_Rep_Pragma
(FS
, Name_Pack
));
2467 -- Start of processing for Alias_Atomic_Check
2470 -- If object size of component type isn't known, we cannot
2471 -- be sure so we defer to the back end.
2473 if not Known_Static_Esize
(Ctyp
) then
2476 -- Case where component size has no effect. First check for
2477 -- object size of component type multiple of the storage
2480 elsif Esize
(Ctyp
) mod System_Storage_Unit
= 0
2482 -- OK in both packing case and component size case if RM
2483 -- size is known and static and same as the object size.
2486 ((Known_Static_RM_Size
(Ctyp
)
2487 and then Esize
(Ctyp
) = RM_Size
(Ctyp
))
2489 -- Or if we have an explicit component size clause and
2490 -- the component size and object size are equal.
2493 (Has_Component_Size_Clause
(Arr
)
2494 and then Component_Size
(Arr
) = Esize
(Ctyp
)))
2498 elsif Has_Aliased_Components
(Arr
) then
2499 Complain_CS
("aliased");
2501 elsif Has_Atomic_Components
(Arr
)
2502 or else Is_Atomic
(Ctyp
)
2504 Complain_CS
("atomic");
2506 elsif Is_Volatile_Full_Access
(Ctyp
) then
2507 Complain_CS
("volatile full access");
2509 end Alias_Atomic_Check
;
2512 -- Check for Independent_Components/Independent with unsuitable
2513 -- packing or explicit component size clause given.
2515 if (Has_Independent_Components
(Arr
) or else Is_Independent
(Ctyp
))
2517 (Has_Component_Size_Clause
(Arr
) or else Is_Packed
(Arr
))
2520 -- If object size of component type isn't known, we cannot
2521 -- be sure so we defer to the back end.
2523 if not Known_Static_Esize
(Ctyp
) then
2526 -- Case where component size has no effect. First check for
2527 -- object size of component type multiple of the storage
2530 elsif Esize
(Ctyp
) mod System_Storage_Unit
= 0
2532 -- OK in both packing case and component size case if RM
2533 -- size is known and multiple of the storage unit size.
2536 ((Known_Static_RM_Size
(Ctyp
)
2537 and then RM_Size
(Ctyp
) mod System_Storage_Unit
= 0)
2539 -- Or if we have an explicit component size clause and
2540 -- the component size is larger than the object size.
2543 (Has_Component_Size_Clause
(Arr
)
2544 and then Component_Size
(Arr
) >= Esize
(Ctyp
)))
2549 if Has_Component_Size_Clause
(Arr
) then
2551 Get_Attribute_Definition_Clause
2552 (FS
, Attribute_Component_Size
);
2555 ("incorrect component size for "
2556 & "independent components", Clause
);
2557 Error_Msg_Uint_1
:= Esize
(Ctyp
);
2559 ("\minimum allowed is^", Clause
);
2563 ("cannot pack independent components",
2564 Get_Rep_Pragma
(FS
, Name_Pack
));
2570 -- Warn for case of atomic type
2572 Clause
:= Get_Rep_Pragma
(FS
, Name_Atomic
);
2575 and then not Addressable
(Component_Size
(FS
))
2578 ("non-atomic components of type& may not be "
2579 & "accessible by separate tasks??", Clause
, Arr
);
2581 if Has_Component_Size_Clause
(Arr
) then
2582 Error_Msg_Sloc
:= Sloc
(Get_Attribute_Definition_Clause
2583 (FS
, Attribute_Component_Size
));
2584 Error_Msg_N
("\because of component size clause#??", Clause
);
2586 elsif Has_Pragma_Pack
(Arr
) then
2587 Error_Msg_Sloc
:= Sloc
(Get_Rep_Pragma
(FS
, Name_Pack
));
2588 Error_Msg_N
("\because of pragma Pack#??", Clause
);
2592 -- Check for scalar storage order
2597 Check_Component_Storage_Order
2600 ADC
=> Get_Attribute_Definition_Clause
2601 (First_Subtype
(Arr
),
2602 Attribute_Scalar_Storage_Order
),
2603 Comp_ADC_Present
=> Dummy
);
2606 -- Processing that is done only for subtypes
2609 -- Acquire alignment from base type
2611 if Unknown_Alignment
(Arr
) then
2612 Set_Alignment
(Arr
, Alignment
(Base_Type
(Arr
)));
2613 Adjust_Esize_Alignment
(Arr
);
2617 -- Specific checks for bit-packed arrays
2619 if Is_Bit_Packed_Array
(Arr
) then
2621 -- Check number of elements for bit packed arrays that come from
2622 -- source and have compile time known ranges. The bit-packed
2623 -- arrays circuitry does not support arrays with more than
2624 -- Integer'Last + 1 elements, and when this restriction is
2625 -- violated, causes incorrect data access.
2627 -- For the case where this is not compile time known, a run-time
2628 -- check should be generated???
2630 if Comes_From_Source
(Arr
) and then Is_Constrained
(Arr
) then
2639 Index
:= First_Index
(Arr
);
2640 while Present
(Index
) loop
2641 Ityp
:= Etype
(Index
);
2643 -- Never generate an error if any index is of a generic
2644 -- type. We will check this in instances.
2646 if Is_Generic_Type
(Ityp
) then
2652 Make_Attribute_Reference
(Loc
,
2653 Prefix
=> New_Occurrence_Of
(Ityp
, Loc
),
2654 Attribute_Name
=> Name_Range_Length
);
2655 Analyze_And_Resolve
(Ilen
);
2657 -- No attempt is made to check number of elements if not
2658 -- compile time known.
2660 if Nkind
(Ilen
) /= N_Integer_Literal
then
2665 Elmts
:= Elmts
* Intval
(Ilen
);
2669 if Elmts
> Intval
(High_Bound
2670 (Scalar_Range
(Standard_Integer
))) + 1
2673 ("bit packed array type may not have "
2674 & "more than Integer''Last+1 elements", Arr
);
2681 if Known_RM_Size
(Arr
) then
2683 SizC
: constant Node_Id
:= Size_Clause
(Arr
);
2687 -- It is not clear if it is possible to have no size clause
2688 -- at this stage, but it is not worth worrying about. Post
2689 -- error on the entity name in the size clause if present,
2690 -- else on the type entity itself.
2692 if Present
(SizC
) then
2693 Check_Size
(Name
(SizC
), Arr
, RM_Size
(Arr
), Discard
);
2695 Check_Size
(Arr
, Arr
, RM_Size
(Arr
), Discard
);
2701 -- If any of the index types was an enumeration type with a non-
2702 -- standard rep clause, then we indicate that the array type is
2703 -- always packed (even if it is not bit packed).
2705 if Non_Standard_Enum
then
2706 Set_Has_Non_Standard_Rep
(Base_Type
(Arr
));
2707 Set_Is_Packed
(Base_Type
(Arr
));
2710 Set_Component_Alignment_If_Not_Set
(Arr
);
2712 -- If the array is packed, we must create the packed array type to be
2713 -- used to actually implement the type. This is only needed for real
2714 -- array types (not for string literal types, since they are present
2715 -- only for the front end).
2718 and then Ekind
(Arr
) /= E_String_Literal_Subtype
2720 Create_Packed_Array_Impl_Type
(Arr
);
2721 Freeze_And_Append
(Packed_Array_Impl_Type
(Arr
), N
, Result
);
2723 -- Make sure that we have the necessary routines to implement the
2724 -- packing, and complain now if not. Note that we only test this
2725 -- for constrained array types.
2727 if Is_Constrained
(Arr
)
2728 and then Is_Bit_Packed_Array
(Arr
)
2729 and then Present
(Packed_Array_Impl_Type
(Arr
))
2730 and then Is_Array_Type
(Packed_Array_Impl_Type
(Arr
))
2733 CS
: constant Uint
:= Component_Size
(Arr
);
2734 RE
: constant RE_Id
:= Get_Id
(UI_To_Int
(CS
));
2738 and then not RTE_Available
(RE
)
2741 ("packing of " & UI_Image
(CS
) & "-bit components",
2742 First_Subtype
(Etype
(Arr
)));
2744 -- Cancel the packing
2746 Set_Is_Packed
(Base_Type
(Arr
), False);
2747 Set_Is_Bit_Packed_Array
(Base_Type
(Arr
), False);
2748 Set_Packed_Array_Impl_Type
(Arr
, Empty
);
2754 -- Size information of packed array type is copied to the array
2755 -- type, since this is really the representation. But do not
2756 -- override explicit existing size values. If the ancestor subtype
2757 -- is constrained the Packed_Array_Impl_Type will be inherited
2758 -- from it, but the size may have been provided already, and
2759 -- must not be overridden either.
2761 if not Has_Size_Clause
(Arr
)
2763 (No
(Ancestor_Subtype
(Arr
))
2764 or else not Has_Size_Clause
(Ancestor_Subtype
(Arr
)))
2766 Set_Esize
(Arr
, Esize
(Packed_Array_Impl_Type
(Arr
)));
2767 Set_RM_Size
(Arr
, RM_Size
(Packed_Array_Impl_Type
(Arr
)));
2770 if not Has_Alignment_Clause
(Arr
) then
2771 Set_Alignment
(Arr
, Alignment
(Packed_Array_Impl_Type
(Arr
)));
2777 -- For non-packed arrays set the alignment of the array to the
2778 -- alignment of the component type if it is unknown. Skip this
2779 -- in atomic/VFA case (atomic/VFA arrays may need larger alignments).
2781 if not Is_Packed
(Arr
)
2782 and then Unknown_Alignment
(Arr
)
2783 and then Known_Alignment
(Ctyp
)
2784 and then Known_Static_Component_Size
(Arr
)
2785 and then Known_Static_Esize
(Ctyp
)
2786 and then Esize
(Ctyp
) = Component_Size
(Arr
)
2787 and then not Is_Atomic_Or_VFA
(Arr
)
2789 Set_Alignment
(Arr
, Alignment
(Component_Type
(Arr
)));
2791 end Freeze_Array_Type
;
2793 -------------------------------
2794 -- Freeze_Object_Declaration --
2795 -------------------------------
2797 procedure Freeze_Object_Declaration
(E
: Entity_Id
) is
2799 -- Abstract type allowed only for C++ imported variables or constants
2801 -- Note: we inhibit this check for objects that do not come from
2802 -- source because there is at least one case (the expansion of
2803 -- x'Class'Input where x is abstract) where we legitimately
2804 -- generate an abstract object.
2806 if Is_Abstract_Type
(Etype
(E
))
2807 and then Comes_From_Source
(Parent
(E
))
2808 and then not (Is_Imported
(E
) and then Is_CPP_Class
(Etype
(E
)))
2810 Error_Msg_N
("type of object cannot be abstract",
2811 Object_Definition
(Parent
(E
)));
2813 if Is_CPP_Class
(Etype
(E
)) then
2815 ("\} may need a cpp_constructor",
2816 Object_Definition
(Parent
(E
)), Etype
(E
));
2818 elsif Present
(Expression
(Parent
(E
))) then
2819 Error_Msg_N
-- CODEFIX
2820 ("\maybe a class-wide type was meant",
2821 Object_Definition
(Parent
(E
)));
2825 -- For object created by object declaration, perform required
2826 -- categorization (preelaborate and pure) checks. Defer these
2827 -- checks to freeze time since pragma Import inhibits default
2828 -- initialization and thus pragma Import affects these checks.
2830 Validate_Object_Declaration
(Declaration_Node
(E
));
2832 -- If there is an address clause, check that it is valid
2833 -- and if need be move initialization to the freeze node.
2835 Check_Address_Clause
(E
);
2837 -- Similar processing is needed for aspects that may affect
2838 -- object layout, like Alignment, if there is an initialization
2841 if Has_Delayed_Aspects
(E
)
2842 and then Expander_Active
2843 and then Is_Array_Type
(Etype
(E
))
2844 and then Present
(Expression
(Parent
(E
)))
2847 Decl
: constant Node_Id
:= Parent
(E
);
2848 Lhs
: constant Node_Id
:= New_Occurrence_Of
(E
, Loc
);
2852 -- Capture initialization value at point of declaration, and
2853 -- make explicit assignment legal, because object may be a
2856 Remove_Side_Effects
(Expression
(Decl
));
2857 Set_Assignment_OK
(Lhs
);
2859 -- Move initialization to freeze actions.
2861 Append_Freeze_Action
(E
,
2862 Make_Assignment_Statement
(Loc
,
2864 Expression
=> Expression
(Decl
)));
2866 Set_No_Initialization
(Decl
);
2867 -- Set_Is_Frozen (E, False);
2871 -- Reset Is_True_Constant for non-constant aliased object. We
2872 -- consider that the fact that a non-constant object is aliased may
2873 -- indicate that some funny business is going on, e.g. an aliased
2874 -- object is passed by reference to a procedure which captures the
2875 -- address of the object, which is later used to assign a new value,
2876 -- even though the compiler thinks that it is not modified. Such
2877 -- code is highly dubious, but we choose to make it "work" for
2878 -- non-constant aliased objects.
2880 -- Note that we used to do this for all aliased objects, whether or
2881 -- not constant, but this caused anomalies down the line because we
2882 -- ended up with static objects that were not Is_True_Constant. Not
2883 -- resetting Is_True_Constant for (aliased) constant objects ensures
2884 -- that this anomaly never occurs.
2886 -- However, we don't do that for internal entities. We figure that if
2887 -- we deliberately set Is_True_Constant for an internal entity, e.g.
2888 -- a dispatch table entry, then we mean it.
2890 if Ekind
(E
) /= E_Constant
2891 and then (Is_Aliased
(E
) or else Is_Aliased
(Etype
(E
)))
2892 and then not Is_Internal_Name
(Chars
(E
))
2894 Set_Is_True_Constant
(E
, False);
2897 -- If the object needs any kind of default initialization, an error
2898 -- must be issued if No_Default_Initialization applies. The check
2899 -- doesn't apply to imported objects, which are not ever default
2900 -- initialized, and is why the check is deferred until freezing, at
2901 -- which point we know if Import applies. Deferred constants are also
2902 -- exempted from this test because their completion is explicit, or
2903 -- through an import pragma.
2905 if Ekind
(E
) = E_Constant
and then Present
(Full_View
(E
)) then
2908 elsif Comes_From_Source
(E
)
2909 and then not Is_Imported
(E
)
2910 and then not Has_Init_Expression
(Declaration_Node
(E
))
2912 ((Has_Non_Null_Base_Init_Proc
(Etype
(E
))
2913 and then not No_Initialization
(Declaration_Node
(E
))
2914 and then not Is_Value_Type
(Etype
(E
))
2915 and then not Initialization_Suppressed
(Etype
(E
)))
2917 (Needs_Simple_Initialization
(Etype
(E
))
2918 and then not Is_Internal
(E
)))
2920 Has_Default_Initialization
:= True;
2922 (No_Default_Initialization
, Declaration_Node
(E
));
2925 -- Check that a Thread_Local_Storage variable does not have
2926 -- default initialization, and any explicit initialization must
2927 -- either be the null constant or a static constant.
2929 if Has_Pragma_Thread_Local_Storage
(E
) then
2931 Decl
: constant Node_Id
:= Declaration_Node
(E
);
2933 if Has_Default_Initialization
2935 (Has_Init_Expression
(Decl
)
2937 (No
(Expression
(Decl
))
2939 (Is_OK_Static_Expression
(Expression
(Decl
))
2940 or else Nkind
(Expression
(Decl
)) = N_Null
)))
2943 ("Thread_Local_Storage variable& is "
2944 & "improperly initialized", Decl
, E
);
2946 ("\only allowed initialization is explicit "
2947 & "NULL or static expression", Decl
, E
);
2952 -- For imported objects, set Is_Public unless there is also an
2953 -- address clause, which means that there is no external symbol
2954 -- needed for the Import (Is_Public may still be set for other
2955 -- unrelated reasons). Note that we delayed this processing
2956 -- till freeze time so that we can be sure not to set the flag
2957 -- if there is an address clause. If there is such a clause,
2958 -- then the only purpose of the Import pragma is to suppress
2959 -- implicit initialization.
2961 if Is_Imported
(E
) and then No
(Address_Clause
(E
)) then
2965 -- For source objects that are not Imported and are library
2966 -- level, if no linker section pragma was given inherit the
2967 -- appropriate linker section from the corresponding type.
2969 if Comes_From_Source
(E
)
2970 and then not Is_Imported
(E
)
2971 and then Is_Library_Level_Entity
(E
)
2972 and then No
(Linker_Section_Pragma
(E
))
2974 Set_Linker_Section_Pragma
2975 (E
, Linker_Section_Pragma
(Etype
(E
)));
2978 -- For convention C objects of an enumeration type, warn if the
2979 -- size is not integer size and no explicit size given. Skip
2980 -- warning for Boolean, and Character, assume programmer expects
2981 -- 8-bit sizes for these cases.
2983 if (Convention
(E
) = Convention_C
2985 Convention
(E
) = Convention_CPP
)
2986 and then Is_Enumeration_Type
(Etype
(E
))
2987 and then not Is_Character_Type
(Etype
(E
))
2988 and then not Is_Boolean_Type
(Etype
(E
))
2989 and then Esize
(Etype
(E
)) < Standard_Integer_Size
2990 and then not Has_Size_Clause
(E
)
2992 Error_Msg_Uint_1
:= UI_From_Int
(Standard_Integer_Size
);
2994 ("??convention C enumeration object has size less than ^", E
);
2995 Error_Msg_N
("\??use explicit size clause to set size", E
);
2997 end Freeze_Object_Declaration
;
2999 -----------------------------
3000 -- Freeze_Generic_Entities --
3001 -----------------------------
3003 function Freeze_Generic_Entities
(Pack
: Entity_Id
) return List_Id
is
3010 E
:= First_Entity
(Pack
);
3011 while Present
(E
) loop
3012 if Is_Type
(E
) and then not Is_Generic_Type
(E
) then
3013 F
:= Make_Freeze_Generic_Entity
(Sloc
(Pack
));
3015 Append_To
(Flist
, F
);
3017 elsif Ekind
(E
) = E_Generic_Package
then
3018 Append_List_To
(Flist
, Freeze_Generic_Entities
(E
));
3025 end Freeze_Generic_Entities
;
3027 --------------------
3028 -- Freeze_Profile --
3029 --------------------
3031 function Freeze_Profile
(E
: Entity_Id
) return Boolean is
3034 Warn_Node
: Node_Id
;
3037 -- Loop through formals
3039 Formal
:= First_Formal
(E
);
3040 while Present
(Formal
) loop
3041 F_Type
:= Etype
(Formal
);
3043 -- AI05-0151: incomplete types can appear in a profile. By the
3044 -- time the entity is frozen, the full view must be available,
3045 -- unless it is a limited view.
3047 if Is_Incomplete_Type
(F_Type
)
3048 and then Present
(Full_View
(F_Type
))
3049 and then not From_Limited_With
(F_Type
)
3051 F_Type
:= Full_View
(F_Type
);
3052 Set_Etype
(Formal
, F_Type
);
3055 if not From_Limited_With
(F_Type
) then
3056 Freeze_And_Append
(F_Type
, N
, Result
);
3059 if Is_Private_Type
(F_Type
)
3060 and then Is_Private_Type
(Base_Type
(F_Type
))
3061 and then No
(Full_View
(Base_Type
(F_Type
)))
3062 and then not Is_Generic_Type
(F_Type
)
3063 and then not Is_Derived_Type
(F_Type
)
3065 -- If the type of a formal is incomplete, subprogram is being
3066 -- frozen prematurely. Within an instance (but not within a
3067 -- wrapper package) this is an artifact of our need to regard
3068 -- the end of an instantiation as a freeze point. Otherwise it
3069 -- is a definite error.
3072 Set_Is_Frozen
(E
, False);
3076 elsif not After_Last_Declaration
3077 and then not Freezing_Library_Level_Tagged_Type
3079 Error_Msg_Node_1
:= F_Type
;
3081 ("type & must be fully defined before this point", Loc
);
3085 -- Check suspicious parameter for C function. These tests apply
3086 -- only to exported/imported subprograms.
3088 if Warn_On_Export_Import
3089 and then Comes_From_Source
(E
)
3090 and then (Convention
(E
) = Convention_C
3092 Convention
(E
) = Convention_CPP
)
3093 and then (Is_Imported
(E
) or else Is_Exported
(E
))
3094 and then Convention
(E
) /= Convention
(Formal
)
3095 and then not Has_Warnings_Off
(E
)
3096 and then not Has_Warnings_Off
(F_Type
)
3097 and then not Has_Warnings_Off
(Formal
)
3099 -- Qualify mention of formals with subprogram name
3101 Error_Msg_Qual_Level
:= 1;
3103 -- Check suspicious use of fat C pointer
3105 if Is_Access_Type
(F_Type
)
3106 and then Esize
(F_Type
) > Ttypes
.System_Address_Size
3109 ("?x?type of & does not correspond to C pointer!", Formal
);
3111 -- Check suspicious return of boolean
3113 elsif Root_Type
(F_Type
) = Standard_Boolean
3114 and then Convention
(F_Type
) = Convention_Ada
3115 and then not Has_Warnings_Off
(F_Type
)
3116 and then not Has_Size_Clause
(F_Type
)
3117 and then VM_Target
= No_VM
3120 ("& is an 8-bit Ada Boolean?x?", Formal
);
3122 ("\use appropriate corresponding type in C "
3123 & "(e.g. char)?x?", Formal
);
3125 -- Check suspicious tagged type
3127 elsif (Is_Tagged_Type
(F_Type
)
3129 (Is_Access_Type
(F_Type
)
3130 and then Is_Tagged_Type
(Designated_Type
(F_Type
))))
3131 and then Convention
(E
) = Convention_C
3134 ("?x?& involves a tagged type which does not "
3135 & "correspond to any C type!", Formal
);
3137 -- Check wrong convention subprogram pointer
3139 elsif Ekind
(F_Type
) = E_Access_Subprogram_Type
3140 and then not Has_Foreign_Convention
(F_Type
)
3143 ("?x?subprogram pointer & should "
3144 & "have foreign convention!", Formal
);
3145 Error_Msg_Sloc
:= Sloc
(F_Type
);
3147 ("\?x?add Convention pragma to declaration of &#",
3151 -- Turn off name qualification after message output
3153 Error_Msg_Qual_Level
:= 0;
3156 -- Check for unconstrained array in exported foreign convention
3159 if Has_Foreign_Convention
(E
)
3160 and then not Is_Imported
(E
)
3161 and then Is_Array_Type
(F_Type
)
3162 and then not Is_Constrained
(F_Type
)
3163 and then Warn_On_Export_Import
3165 -- Exclude VM case, since both .NET and JVM can handle
3166 -- unconstrained arrays without a problem.
3168 and then VM_Target
= No_VM
3170 Error_Msg_Qual_Level
:= 1;
3172 -- If this is an inherited operation, place the warning on
3173 -- the derived type declaration, rather than on the original
3176 if Nkind
(Original_Node
(Parent
(E
))) = N_Full_Type_Declaration
3178 Warn_Node
:= Parent
(E
);
3180 if Formal
= First_Formal
(E
) then
3181 Error_Msg_NE
("??in inherited operation&", Warn_Node
, E
);
3184 Warn_Node
:= Formal
;
3187 Error_Msg_NE
("?x?type of argument& is unconstrained array",
3189 Error_Msg_NE
("?x?foreign caller must pass bounds explicitly",
3191 Error_Msg_Qual_Level
:= 0;
3194 if not From_Limited_With
(F_Type
) then
3195 if Is_Access_Type
(F_Type
) then
3196 F_Type
:= Designated_Type
(F_Type
);
3199 -- If the formal is an anonymous_access_to_subprogram
3200 -- freeze the subprogram type as well, to prevent
3201 -- scope anomalies in gigi, because there is no other
3202 -- clear point at which it could be frozen.
3204 if Is_Itype
(Etype
(Formal
))
3205 and then Ekind
(F_Type
) = E_Subprogram_Type
3207 Freeze_And_Append
(F_Type
, N
, Result
);
3211 Next_Formal
(Formal
);
3214 -- Case of function: similar checks on return type
3216 if Ekind
(E
) = E_Function
then
3218 -- Check whether function is declared elsewhere.
3221 Get_Source_Unit
(E
) /= Get_Source_Unit
(N
)
3222 and then Returns_Limited_View
(E
)
3223 and then not In_Open_Scopes
(Scope
(E
));
3225 -- Freeze return type
3227 R_Type
:= Etype
(E
);
3229 -- AI05-0151: the return type may have been incomplete
3230 -- at the point of declaration. Replace it with the full
3231 -- view, unless the current type is a limited view. In
3232 -- that case the full view is in a different unit, and
3233 -- gigi finds the non-limited view after the other unit
3236 if Ekind
(R_Type
) = E_Incomplete_Type
3237 and then Present
(Full_View
(R_Type
))
3238 and then not From_Limited_With
(R_Type
)
3240 R_Type
:= Full_View
(R_Type
);
3241 Set_Etype
(E
, R_Type
);
3243 -- If the return type is a limited view and the non-limited
3244 -- view is still incomplete, the function has to be frozen at a
3245 -- later time. If the function is abstract there is no place at
3246 -- which the full view will become available, and no code to be
3247 -- generated for it, so mark type as frozen.
3249 elsif Ekind
(R_Type
) = E_Incomplete_Type
3250 and then From_Limited_With
(R_Type
)
3251 and then Ekind
(Non_Limited_View
(R_Type
)) = E_Incomplete_Type
3253 if Is_Abstract_Subprogram
(E
) then
3256 Set_Is_Frozen
(E
, False);
3257 Set_Returns_Limited_View
(E
);
3262 Freeze_And_Append
(R_Type
, N
, Result
);
3264 -- Check suspicious return type for C function
3266 if Warn_On_Export_Import
3267 and then (Convention
(E
) = Convention_C
3269 Convention
(E
) = Convention_CPP
)
3270 and then (Is_Imported
(E
) or else Is_Exported
(E
))
3272 -- Check suspicious return of fat C pointer
3274 if Is_Access_Type
(R_Type
)
3275 and then Esize
(R_Type
) > Ttypes
.System_Address_Size
3276 and then not Has_Warnings_Off
(E
)
3277 and then not Has_Warnings_Off
(R_Type
)
3279 Error_Msg_N
("?x?return type of& does not "
3280 & "correspond to C pointer!", E
);
3282 -- Check suspicious return of boolean
3284 elsif Root_Type
(R_Type
) = Standard_Boolean
3285 and then Convention
(R_Type
) = Convention_Ada
3286 and then VM_Target
= No_VM
3287 and then not Has_Warnings_Off
(E
)
3288 and then not Has_Warnings_Off
(R_Type
)
3289 and then not Has_Size_Clause
(R_Type
)
3292 N
: constant Node_Id
:=
3293 Result_Definition
(Declaration_Node
(E
));
3296 ("return type of & is an 8-bit Ada Boolean?x?", N
, E
);
3298 ("\use appropriate corresponding type in C "
3299 & "(e.g. char)?x?", N
, E
);
3302 -- Check suspicious return tagged type
3304 elsif (Is_Tagged_Type
(R_Type
)
3305 or else (Is_Access_Type
(R_Type
)
3308 (Designated_Type
(R_Type
))))
3309 and then Convention
(E
) = Convention_C
3310 and then not Has_Warnings_Off
(E
)
3311 and then not Has_Warnings_Off
(R_Type
)
3313 Error_Msg_N
("?x?return type of & does not "
3314 & "correspond to C type!", E
);
3316 -- Check return of wrong convention subprogram pointer
3318 elsif Ekind
(R_Type
) = E_Access_Subprogram_Type
3319 and then not Has_Foreign_Convention
(R_Type
)
3320 and then not Has_Warnings_Off
(E
)
3321 and then not Has_Warnings_Off
(R_Type
)
3323 Error_Msg_N
("?x?& should return a foreign "
3324 & "convention subprogram pointer", E
);
3325 Error_Msg_Sloc
:= Sloc
(R_Type
);
3327 ("\?x?add Convention pragma to declaration of& #",
3332 -- Give warning for suspicious return of a result of an
3333 -- unconstrained array type in a foreign convention function.
3335 if Has_Foreign_Convention
(E
)
3337 -- We are looking for a return of unconstrained array
3339 and then Is_Array_Type
(R_Type
)
3340 and then not Is_Constrained
(R_Type
)
3342 -- Exclude imported routines, the warning does not belong on
3343 -- the import, but rather on the routine definition.
3345 and then not Is_Imported
(E
)
3347 -- Exclude VM case, since both .NET and JVM can handle return
3348 -- of unconstrained arrays without a problem.
3350 and then VM_Target
= No_VM
3352 -- Check that general warning is enabled, and that it is not
3353 -- suppressed for this particular case.
3355 and then Warn_On_Export_Import
3356 and then not Has_Warnings_Off
(E
)
3357 and then not Has_Warnings_Off
(R_Type
)
3359 Error_Msg_N
("?x?foreign convention function& should not " &
3360 "return unconstrained array!", E
);
3364 -- Check suspicious use of Import in pure unit (cases where the RM
3365 -- allows calls to be omitted).
3369 -- It might be suspicious if the compilation unit has the Pure
3372 and then Has_Pragma_Pure
(Cunit_Entity
(Current_Sem_Unit
))
3374 -- The RM allows omission of calls only in the case of
3375 -- library-level subprograms (see RM-10.2.1(18)).
3377 and then Is_Library_Level_Entity
(E
)
3379 -- Ignore internally generated entity. This happens in some cases
3380 -- of subprograms in specs, where we generate an implied body.
3382 and then Comes_From_Source
(Import_Pragma
(E
))
3384 -- Assume run-time knows what it is doing
3386 and then not GNAT_Mode
3388 -- Assume explicit Pure_Function means import is pure
3390 and then not Has_Pragma_Pure_Function
(E
)
3392 -- Don't need warning in relaxed semantics mode
3394 and then not Relaxed_RM_Semantics
3396 -- Assume convention Intrinsic is OK, since this is specialized.
3397 -- This deals with the DEC unit current_exception.ads
3399 and then Convention
(E
) /= Convention_Intrinsic
3401 -- Assume that ASM interface knows what it is doing. This deals
3402 -- with unsigned.ads in the AAMP back end.
3404 and then Convention
(E
) /= Convention_Assembler
3407 ("pragma Import in Pure unit??", Import_Pragma
(E
));
3409 ("\calls to & may be omitted (RM 10.2.1(18/3))??",
3410 Import_Pragma
(E
), E
);
3416 ------------------------
3417 -- Freeze_Record_Type --
3418 ------------------------
3420 procedure Freeze_Record_Type
(Rec
: Entity_Id
) is
3427 pragma Warnings
(Off
, Junk
);
3429 Rec_Pushed
: Boolean := False;
3430 -- Set True if the record type scope Rec has been pushed on the scope
3431 -- stack. Needed for the analysis of delayed aspects specified to the
3432 -- components of Rec.
3435 -- Scalar_Storage_Order attribute definition clause for the record
3437 Unplaced_Component
: Boolean := False;
3438 -- Set True if we find at least one component with no component
3439 -- clause (used to warn about useless Pack pragmas).
3441 Placed_Component
: Boolean := False;
3442 -- Set True if we find at least one component with a component
3443 -- clause (used to warn about useless Bit_Order pragmas, and also
3444 -- to detect cases where Implicit_Packing may have an effect).
3446 Aliased_Component
: Boolean := False;
3447 -- Set True if we find at least one component which is aliased. This
3448 -- is used to prevent Implicit_Packing of the record, since packing
3449 -- cannot modify the size of alignment of an aliased component.
3451 SSO_ADC_Component
: Boolean := False;
3452 -- Set True if we find at least one component whose type has a
3453 -- Scalar_Storage_Order attribute definition clause.
3455 All_Scalar_Components
: Boolean := True;
3456 -- Set False if we encounter a component of a non-scalar type
3458 Scalar_Component_Total_RM_Size
: Uint
:= Uint_0
;
3459 Scalar_Component_Total_Esize
: Uint
:= Uint_0
;
3460 -- Accumulates total RM_Size values and total Esize values of all
3461 -- scalar components. Used for processing of Implicit_Packing.
3463 function Check_Allocator
(N
: Node_Id
) return Node_Id
;
3464 -- If N is an allocator, possibly wrapped in one or more level of
3465 -- qualified expression(s), return the inner allocator node, else
3468 procedure Check_Itype
(Typ
: Entity_Id
);
3469 -- If the component subtype is an access to a constrained subtype of
3470 -- an already frozen type, make the subtype frozen as well. It might
3471 -- otherwise be frozen in the wrong scope, and a freeze node on
3472 -- subtype has no effect. Similarly, if the component subtype is a
3473 -- regular (not protected) access to subprogram, set the anonymous
3474 -- subprogram type to frozen as well, to prevent an out-of-scope
3475 -- freeze node at some eventual point of call. Protected operations
3476 -- are handled elsewhere.
3478 procedure Freeze_Choices_In_Variant_Part
(VP
: Node_Id
);
3479 -- Make sure that all types mentioned in Discrete_Choices of the
3480 -- variants referenceed by the Variant_Part VP are frozen. This is
3481 -- a recursive routine to deal with nested variants.
3483 ---------------------
3484 -- Check_Allocator --
3485 ---------------------
3487 function Check_Allocator
(N
: Node_Id
) return Node_Id
is
3492 if Nkind
(Inner
) = N_Allocator
then
3494 elsif Nkind
(Inner
) = N_Qualified_Expression
then
3495 Inner
:= Expression
(Inner
);
3500 end Check_Allocator
;
3506 procedure Check_Itype
(Typ
: Entity_Id
) is
3507 Desig
: constant Entity_Id
:= Designated_Type
(Typ
);
3510 if not Is_Frozen
(Desig
)
3511 and then Is_Frozen
(Base_Type
(Desig
))
3513 Set_Is_Frozen
(Desig
);
3515 -- In addition, add an Itype_Reference to ensure that the
3516 -- access subtype is elaborated early enough. This cannot be
3517 -- done if the subtype may depend on discriminants.
3519 if Ekind
(Comp
) = E_Component
3520 and then Is_Itype
(Etype
(Comp
))
3521 and then not Has_Discriminants
(Rec
)
3523 IR
:= Make_Itype_Reference
(Sloc
(Comp
));
3524 Set_Itype
(IR
, Desig
);
3528 elsif Ekind
(Typ
) = E_Anonymous_Access_Subprogram_Type
3529 and then Convention
(Desig
) /= Convention_Protected
3531 Set_Is_Frozen
(Desig
);
3535 ------------------------------------
3536 -- Freeze_Choices_In_Variant_Part --
3537 ------------------------------------
3539 procedure Freeze_Choices_In_Variant_Part
(VP
: Node_Id
) is
3540 pragma Assert
(Nkind
(VP
) = N_Variant_Part
);
3547 -- Loop through variants
3549 Variant
:= First_Non_Pragma
(Variants
(VP
));
3550 while Present
(Variant
) loop
3552 -- Loop through choices, checking that all types are frozen
3554 Choice
:= First_Non_Pragma
(Discrete_Choices
(Variant
));
3555 while Present
(Choice
) loop
3556 if Nkind
(Choice
) in N_Has_Etype
3557 and then Present
(Etype
(Choice
))
3559 Freeze_And_Append
(Etype
(Choice
), N
, Result
);
3562 Next_Non_Pragma
(Choice
);
3565 -- Check for nested variant part to process
3567 CL
:= Component_List
(Variant
);
3569 if not Null_Present
(CL
) then
3570 if Present
(Variant_Part
(CL
)) then
3571 Freeze_Choices_In_Variant_Part
(Variant_Part
(CL
));
3575 Next_Non_Pragma
(Variant
);
3577 end Freeze_Choices_In_Variant_Part
;
3579 -- Start of processing for Freeze_Record_Type
3582 -- Deal with delayed aspect specifications for components. The
3583 -- analysis of the aspect is required to be delayed to the freeze
3584 -- point, thus we analyze the pragma or attribute definition
3585 -- clause in the tree at this point. We also analyze the aspect
3586 -- specification node at the freeze point when the aspect doesn't
3587 -- correspond to pragma/attribute definition clause.
3589 Comp
:= First_Entity
(Rec
);
3590 while Present
(Comp
) loop
3591 if Ekind
(Comp
) = E_Component
3592 and then Has_Delayed_Aspects
(Comp
)
3594 if not Rec_Pushed
then
3598 -- The visibility to the discriminants must be restored in
3599 -- order to properly analyze the aspects.
3601 if Has_Discriminants
(Rec
) then
3602 Install_Discriminants
(Rec
);
3606 Analyze_Aspects_At_Freeze_Point
(Comp
);
3612 -- Pop the scope if Rec scope has been pushed on the scope stack
3613 -- during the delayed aspect analysis process.
3616 if Has_Discriminants
(Rec
) then
3617 Uninstall_Discriminants
(Rec
);
3623 -- Freeze components and embedded subtypes
3625 Comp
:= First_Entity
(Rec
);
3627 while Present
(Comp
) loop
3628 if Is_Aliased
(Comp
) then
3629 Aliased_Component
:= True;
3632 -- Handle the component and discriminant case
3634 if Ekind_In
(Comp
, E_Component
, E_Discriminant
) then
3636 CC
: constant Node_Id
:= Component_Clause
(Comp
);
3639 -- Freezing a record type freezes the type of each of its
3640 -- components. However, if the type of the component is
3641 -- part of this record, we do not want or need a separate
3642 -- Freeze_Node. Note that Is_Itype is wrong because that's
3643 -- also set in private type cases. We also can't check for
3644 -- the Scope being exactly Rec because of private types and
3645 -- record extensions.
3647 if Is_Itype
(Etype
(Comp
))
3648 and then Is_Record_Type
(Underlying_Type
3649 (Scope
(Etype
(Comp
))))
3651 Undelay_Type
(Etype
(Comp
));
3654 Freeze_And_Append
(Etype
(Comp
), N
, Result
);
3656 -- Warn for pragma Pack overriding foreign convention
3658 if Has_Foreign_Convention
(Etype
(Comp
))
3659 and then Has_Pragma_Pack
(Rec
)
3661 -- Don't warn for aliased components, since override
3662 -- cannot happen in that case.
3664 and then not Is_Aliased
(Comp
)
3667 CN
: constant Name_Id
:=
3668 Get_Convention_Name
(Convention
(Etype
(Comp
)));
3669 PP
: constant Node_Id
:=
3670 Get_Pragma
(Rec
, Pragma_Pack
);
3672 if Present
(PP
) then
3673 Error_Msg_Name_1
:= CN
;
3674 Error_Msg_Sloc
:= Sloc
(Comp
);
3676 ("pragma Pack affects convention % component#??",
3678 Error_Msg_Name_1
:= CN
;
3680 ("\component & may not have % compatible "
3681 & "representation??", PP
, Comp
);
3686 -- Check for error of component clause given for variable
3687 -- sized type. We have to delay this test till this point,
3688 -- since the component type has to be frozen for us to know
3689 -- if it is variable length.
3691 if Present
(CC
) then
3692 Placed_Component
:= True;
3694 -- We omit this test in a generic context, it will be
3695 -- applied at instantiation time.
3697 if Inside_A_Generic
then
3700 -- Also omit this test in CodePeer mode, since we do not
3701 -- have sufficient info on size and rep clauses.
3703 elsif CodePeer_Mode
then
3706 -- Omit check if component has a generic type. This can
3707 -- happen in an instantiation within a generic in ASIS
3708 -- mode, where we force freeze actions without full
3711 elsif Is_Generic_Type
(Etype
(Comp
)) then
3717 Size_Known_At_Compile_Time
3718 (Underlying_Type
(Etype
(Comp
)))
3721 ("component clause not allowed for variable " &
3722 "length component", CC
);
3726 Unplaced_Component
:= True;
3729 -- Case of component requires byte alignment
3731 if Must_Be_On_Byte_Boundary
(Etype
(Comp
)) then
3733 -- Set the enclosing record to also require byte align
3735 Set_Must_Be_On_Byte_Boundary
(Rec
);
3737 -- Check for component clause that is inconsistent with
3738 -- the required byte boundary alignment.
3741 and then Normalized_First_Bit
(Comp
) mod
3742 System_Storage_Unit
/= 0
3745 ("component & must be byte aligned",
3746 Component_Name
(Component_Clause
(Comp
)));
3752 -- Gather data for possible Implicit_Packing later. Note that at
3753 -- this stage we might be dealing with a real component, or with
3754 -- an implicit subtype declaration.
3756 if not Is_Scalar_Type
(Etype
(Comp
)) then
3757 All_Scalar_Components
:= False;
3759 Scalar_Component_Total_RM_Size
:=
3760 Scalar_Component_Total_RM_Size
+ RM_Size
(Etype
(Comp
));
3761 Scalar_Component_Total_Esize
:=
3762 Scalar_Component_Total_Esize
+ Esize
(Etype
(Comp
));
3765 -- If the component is an Itype with Delayed_Freeze and is either
3766 -- a record or array subtype and its base type has not yet been
3767 -- frozen, we must remove this from the entity list of this record
3768 -- and put it on the entity list of the scope of its base type.
3769 -- Note that we know that this is not the type of a component
3770 -- since we cleared Has_Delayed_Freeze for it in the previous
3771 -- loop. Thus this must be the Designated_Type of an access type,
3772 -- which is the type of a component.
3775 and then Is_Type
(Scope
(Comp
))
3776 and then Is_Composite_Type
(Comp
)
3777 and then Base_Type
(Comp
) /= Comp
3778 and then Has_Delayed_Freeze
(Comp
)
3779 and then not Is_Frozen
(Base_Type
(Comp
))
3782 Will_Be_Frozen
: Boolean := False;
3786 -- We have a difficult case to handle here. Suppose Rec is
3787 -- subtype being defined in a subprogram that's created as
3788 -- part of the freezing of Rec'Base. In that case, we know
3789 -- that Comp'Base must have already been frozen by the time
3790 -- we get to elaborate this because Gigi doesn't elaborate
3791 -- any bodies until it has elaborated all of the declarative
3792 -- part. But Is_Frozen will not be set at this point because
3793 -- we are processing code in lexical order.
3795 -- We detect this case by going up the Scope chain of Rec
3796 -- and seeing if we have a subprogram scope before reaching
3797 -- the top of the scope chain or that of Comp'Base. If we
3798 -- do, then mark that Comp'Base will actually be frozen. If
3799 -- so, we merely undelay it.
3802 while Present
(S
) loop
3803 if Is_Subprogram
(S
) then
3804 Will_Be_Frozen
:= True;
3806 elsif S
= Scope
(Base_Type
(Comp
)) then
3813 if Will_Be_Frozen
then
3814 Undelay_Type
(Comp
);
3817 if Present
(Prev
) then
3818 Set_Next_Entity
(Prev
, Next_Entity
(Comp
));
3820 Set_First_Entity
(Rec
, Next_Entity
(Comp
));
3823 -- Insert in entity list of scope of base type (which
3824 -- must be an enclosing scope, because still unfrozen).
3826 Append_Entity
(Comp
, Scope
(Base_Type
(Comp
)));
3830 -- If the component is an access type with an allocator as default
3831 -- value, the designated type will be frozen by the corresponding
3832 -- expression in init_proc. In order to place the freeze node for
3833 -- the designated type before that for the current record type,
3836 -- Same process if the component is an array of access types,
3837 -- initialized with an aggregate. If the designated type is
3838 -- private, it cannot contain allocators, and it is premature
3839 -- to freeze the type, so we check for this as well.
3841 elsif Is_Access_Type
(Etype
(Comp
))
3842 and then Present
(Parent
(Comp
))
3843 and then Present
(Expression
(Parent
(Comp
)))
3846 Alloc
: constant Node_Id
:=
3847 Check_Allocator
(Expression
(Parent
(Comp
)));
3850 if Present
(Alloc
) then
3852 -- If component is pointer to a class-wide type, freeze
3853 -- the specific type in the expression being allocated.
3854 -- The expression may be a subtype indication, in which
3855 -- case freeze the subtype mark.
3857 if Is_Class_Wide_Type
3858 (Designated_Type
(Etype
(Comp
)))
3860 if Is_Entity_Name
(Expression
(Alloc
)) then
3862 (Entity
(Expression
(Alloc
)), N
, Result
);
3864 elsif Nkind
(Expression
(Alloc
)) = N_Subtype_Indication
3867 (Entity
(Subtype_Mark
(Expression
(Alloc
))),
3871 elsif Is_Itype
(Designated_Type
(Etype
(Comp
))) then
3872 Check_Itype
(Etype
(Comp
));
3876 (Designated_Type
(Etype
(Comp
)), N
, Result
);
3881 elsif Is_Access_Type
(Etype
(Comp
))
3882 and then Is_Itype
(Designated_Type
(Etype
(Comp
)))
3884 Check_Itype
(Etype
(Comp
));
3886 -- Freeze the designated type when initializing a component with
3887 -- an aggregate in case the aggregate contains allocators.
3890 -- type T_Ptr is access all T;
3891 -- type T_Array is array ... of T_Ptr;
3893 -- type Rec is record
3894 -- Comp : T_Array := (others => ...);
3897 elsif Is_Array_Type
(Etype
(Comp
))
3898 and then Is_Access_Type
(Component_Type
(Etype
(Comp
)))
3901 Comp_Par
: constant Node_Id
:= Parent
(Comp
);
3902 Desig_Typ
: constant Entity_Id
:=
3904 (Component_Type
(Etype
(Comp
)));
3907 -- The only case when this sort of freezing is not done is
3908 -- when the designated type is class-wide and the root type
3909 -- is the record owning the component. This scenario results
3910 -- in a circularity because the class-wide type requires
3911 -- primitives that have not been created yet as the root
3912 -- type is in the process of being frozen.
3914 -- type Rec is tagged;
3915 -- type Rec_Ptr is access all Rec'Class;
3916 -- type Rec_Array is array ... of Rec_Ptr;
3918 -- type Rec is record
3919 -- Comp : Rec_Array := (others => ...);
3922 if Is_Class_Wide_Type
(Desig_Typ
)
3923 and then Root_Type
(Desig_Typ
) = Rec
3927 elsif Is_Fully_Defined
(Desig_Typ
)
3928 and then Present
(Comp_Par
)
3929 and then Nkind
(Comp_Par
) = N_Component_Declaration
3930 and then Present
(Expression
(Comp_Par
))
3931 and then Nkind
(Expression
(Comp_Par
)) = N_Aggregate
3933 Freeze_And_Append
(Desig_Typ
, N
, Result
);
3942 -- Deal with default setting of reverse storage order
3944 Set_SSO_From_Default
(Rec
);
3946 -- Check consistent attribute setting on component types
3948 SSO_ADC
:= Get_Attribute_Definition_Clause
3949 (Rec
, Attribute_Scalar_Storage_Order
);
3952 Comp_ADC_Present
: Boolean;
3954 Comp
:= First_Component
(Rec
);
3955 while Present
(Comp
) loop
3956 Check_Component_Storage_Order
3960 Comp_ADC_Present
=> Comp_ADC_Present
);
3961 SSO_ADC_Component
:= SSO_ADC_Component
or Comp_ADC_Present
;
3962 Next_Component
(Comp
);
3966 -- Now deal with reverse storage order/bit order issues
3968 if Present
(SSO_ADC
) then
3970 -- Check compatibility of Scalar_Storage_Order with Bit_Order, if
3971 -- the former is specified.
3973 if Reverse_Bit_Order
(Rec
) /= Reverse_Storage_Order
(Rec
) then
3975 -- Note: report error on Rec, not on SSO_ADC, as ADC may apply
3976 -- to some ancestor type.
3978 Error_Msg_Sloc
:= Sloc
(SSO_ADC
);
3980 ("scalar storage order for& specified# inconsistent with "
3981 & "bit order", Rec
);
3984 -- Warn if there is an Scalar_Storage_Order attribute definition
3985 -- clause but no component clause, no component that itself has
3986 -- such an attribute definition, and no pragma Pack.
3988 if not (Placed_Component
3995 ("??scalar storage order specified but no component clause",
4000 -- Deal with Bit_Order aspect
4002 ADC
:= Get_Attribute_Definition_Clause
(Rec
, Attribute_Bit_Order
);
4004 if Present
(ADC
) and then Base_Type
(Rec
) = Rec
then
4005 if not (Placed_Component
4006 or else Present
(SSO_ADC
)
4007 or else Is_Packed
(Rec
))
4009 -- Warn if clause has no effect when no component clause is
4010 -- present, but suppress warning if the Bit_Order is required
4011 -- due to the presence of a Scalar_Storage_Order attribute.
4014 ("??bit order specification has no effect", ADC
);
4016 ("\??since no component clauses were specified", ADC
);
4018 -- Here is where we do the processing to adjust component clauses
4019 -- for reversed bit order, when not using reverse SSO.
4021 elsif Reverse_Bit_Order
(Rec
)
4022 and then not Reverse_Storage_Order
(Rec
)
4024 Adjust_Record_For_Reverse_Bit_Order
(Rec
);
4026 -- Case where we have both an explicit Bit_Order and the same
4027 -- Scalar_Storage_Order: leave record untouched, the back-end
4028 -- will take care of required layout conversions.
4036 -- Complete error checking on record representation clause (e.g.
4037 -- overlap of components). This is called after adjusting the
4038 -- record for reverse bit order.
4041 RRC
: constant Node_Id
:= Get_Record_Representation_Clause
(Rec
);
4043 if Present
(RRC
) then
4044 Check_Record_Representation_Clause
(RRC
);
4048 -- Set OK_To_Reorder_Components depending on debug flags
4050 if Is_Base_Type
(Rec
) and then Convention
(Rec
) = Convention_Ada
then
4051 if (Has_Discriminants
(Rec
) and then Debug_Flag_Dot_V
)
4053 (not Has_Discriminants
(Rec
) and then Debug_Flag_Dot_R
)
4055 Set_OK_To_Reorder_Components
(Rec
);
4059 -- Check for useless pragma Pack when all components placed. We only
4060 -- do this check for record types, not subtypes, since a subtype may
4061 -- have all its components placed, and it still makes perfectly good
4062 -- sense to pack other subtypes or the parent type. We do not give
4063 -- this warning if Optimize_Alignment is set to Space, since the
4064 -- pragma Pack does have an effect in this case (it always resets
4065 -- the alignment to one).
4067 if Ekind
(Rec
) = E_Record_Type
4068 and then Is_Packed
(Rec
)
4069 and then not Unplaced_Component
4070 and then Optimize_Alignment
/= 'S'
4072 -- Reset packed status. Probably not necessary, but we do it so
4073 -- that there is no chance of the back end doing something strange
4074 -- with this redundant indication of packing.
4076 Set_Is_Packed
(Rec
, False);
4078 -- Give warning if redundant constructs warnings on
4080 if Warn_On_Redundant_Constructs
then
4081 Error_Msg_N
-- CODEFIX
4082 ("??pragma Pack has no effect, no unplaced components",
4083 Get_Rep_Pragma
(Rec
, Name_Pack
));
4087 -- If this is the record corresponding to a remote type, freeze the
4088 -- remote type here since that is what we are semantically freezing.
4089 -- This prevents the freeze node for that type in an inner scope.
4091 if Ekind
(Rec
) = E_Record_Type
then
4092 if Present
(Corresponding_Remote_Type
(Rec
)) then
4093 Freeze_And_Append
(Corresponding_Remote_Type
(Rec
), N
, Result
);
4096 -- Check for controlled components and unchecked unions.
4098 Comp
:= First_Component
(Rec
);
4099 while Present
(Comp
) loop
4101 -- Do not set Has_Controlled_Component on a class-wide
4102 -- equivalent type. See Make_CW_Equivalent_Type.
4104 if not Is_Class_Wide_Equivalent_Type
(Rec
)
4106 (Has_Controlled_Component
(Etype
(Comp
))
4108 (Chars
(Comp
) /= Name_uParent
4109 and then Is_Controlled
(Etype
(Comp
)))
4111 (Is_Protected_Type
(Etype
(Comp
))
4113 Present
(Corresponding_Record_Type
(Etype
(Comp
)))
4115 Has_Controlled_Component
4116 (Corresponding_Record_Type
(Etype
(Comp
)))))
4118 Set_Has_Controlled_Component
(Rec
);
4121 if Has_Unchecked_Union
(Etype
(Comp
)) then
4122 Set_Has_Unchecked_Union
(Rec
);
4125 -- Scan component declaration for likely misuses of current
4126 -- instance, either in a constraint or a default expression.
4128 if Has_Per_Object_Constraint
(Comp
) then
4129 Check_Current_Instance
(Parent
(Comp
));
4132 Next_Component
(Comp
);
4136 -- Enforce the restriction that access attributes with a current
4137 -- instance prefix can only apply to limited types. This comment
4138 -- is floating here, but does not seem to belong here???
4140 -- Set component alignment if not otherwise already set
4142 Set_Component_Alignment_If_Not_Set
(Rec
);
4144 -- For first subtypes, check if there are any fixed-point fields with
4145 -- component clauses, where we must check the size. This is not done
4146 -- till the freeze point since for fixed-point types, we do not know
4147 -- the size until the type is frozen. Similar processing applies to
4148 -- bit packed arrays.
4150 if Is_First_Subtype
(Rec
) then
4151 Comp
:= First_Component
(Rec
);
4152 while Present
(Comp
) loop
4153 if Present
(Component_Clause
(Comp
))
4154 and then (Is_Fixed_Point_Type
(Etype
(Comp
))
4155 or else Is_Bit_Packed_Array
(Etype
(Comp
)))
4158 (Component_Name
(Component_Clause
(Comp
)),
4164 Next_Component
(Comp
);
4168 -- Generate warning for applying C or C++ convention to a record
4169 -- with discriminants. This is suppressed for the unchecked union
4170 -- case, since the whole point in this case is interface C. We also
4171 -- do not generate this within instantiations, since we will have
4172 -- generated a message on the template.
4174 if Has_Discriminants
(E
)
4175 and then not Is_Unchecked_Union
(E
)
4176 and then (Convention
(E
) = Convention_C
4178 Convention
(E
) = Convention_CPP
)
4179 and then Comes_From_Source
(E
)
4180 and then not In_Instance
4181 and then not Has_Warnings_Off
(E
)
4182 and then not Has_Warnings_Off
(Base_Type
(E
))
4185 Cprag
: constant Node_Id
:= Get_Rep_Pragma
(E
, Name_Convention
);
4189 if Present
(Cprag
) then
4190 A2
:= Next
(First
(Pragma_Argument_Associations
(Cprag
)));
4192 if Convention
(E
) = Convention_C
then
4194 ("?x?variant record has no direct equivalent in C",
4198 ("?x?variant record has no direct equivalent in C++",
4203 ("\?x?use of convention for type& is dubious", A2
, E
);
4208 -- See if Size is too small as is (and implicit packing might help)
4210 if not Is_Packed
(Rec
)
4212 -- No implicit packing if even one component is explicitly placed
4214 and then not Placed_Component
4216 -- Or even one component is aliased
4218 and then not Aliased_Component
4220 -- Must have size clause and all scalar components
4222 and then Has_Size_Clause
(Rec
)
4223 and then All_Scalar_Components
4225 -- Do not try implicit packing on records with discriminants, too
4226 -- complicated, especially in the variant record case.
4228 and then not Has_Discriminants
(Rec
)
4230 -- We can implicitly pack if the specified size of the record is
4231 -- less than the sum of the object sizes (no point in packing if
4232 -- this is not the case).
4234 and then RM_Size
(Rec
) < Scalar_Component_Total_Esize
4236 -- And the total RM size cannot be greater than the specified size
4237 -- since otherwise packing will not get us where we have to be.
4239 and then RM_Size
(Rec
) >= Scalar_Component_Total_RM_Size
4241 -- Never do implicit packing in CodePeer or SPARK modes since
4242 -- we don't do any packing in these modes, since this generates
4243 -- over-complex code that confuses static analysis, and in
4244 -- general, neither CodePeer not GNATprove care about the
4245 -- internal representation of objects.
4247 and then not (CodePeer_Mode
or GNATprove_Mode
)
4249 -- If implicit packing enabled, do it
4251 if Implicit_Packing
then
4252 Set_Is_Packed
(Rec
);
4254 -- Otherwise flag the size clause
4258 Sz
: constant Node_Id
:= Size_Clause
(Rec
);
4260 Error_Msg_NE
-- CODEFIX
4261 ("size given for& too small", Sz
, Rec
);
4262 Error_Msg_N
-- CODEFIX
4263 ("\use explicit pragma Pack "
4264 & "or use pragma Implicit_Packing", Sz
);
4269 -- The following checks are only relevant when SPARK_Mode is on as
4270 -- they are not standard Ada legality rules.
4272 if SPARK_Mode
= On
then
4273 if Is_Effectively_Volatile
(Rec
) then
4275 -- A discriminated type cannot be effectively volatile
4276 -- (SPARK RM C.6(4)).
4278 if Has_Discriminants
(Rec
) then
4279 Error_Msg_N
("discriminated type & cannot be volatile", Rec
);
4281 -- A tagged type cannot be effectively volatile
4282 -- (SPARK RM C.6(5)).
4284 elsif Is_Tagged_Type
(Rec
) then
4285 Error_Msg_N
("tagged type & cannot be volatile", Rec
);
4288 -- A non-effectively volatile record type cannot contain
4289 -- effectively volatile components (SPARK RM C.6(2)).
4292 Comp
:= First_Component
(Rec
);
4293 while Present
(Comp
) loop
4294 if Comes_From_Source
(Comp
)
4295 and then Is_Effectively_Volatile
(Etype
(Comp
))
4297 Error_Msg_Name_1
:= Chars
(Rec
);
4299 ("component & of non-volatile type % cannot be "
4300 & "volatile", Comp
);
4303 Next_Component
(Comp
);
4308 -- Make sure that if we have an iterator aspect, then we have
4309 -- either Constant_Indexing or Variable_Indexing.
4312 Iterator_Aspect
: Node_Id
;
4315 Iterator_Aspect
:= Find_Aspect
(Rec
, Aspect_Iterator_Element
);
4317 if No
(Iterator_Aspect
) then
4318 Iterator_Aspect
:= Find_Aspect
(Rec
, Aspect_Default_Iterator
);
4321 if Present
(Iterator_Aspect
) then
4322 if Has_Aspect
(Rec
, Aspect_Constant_Indexing
)
4324 Has_Aspect
(Rec
, Aspect_Variable_Indexing
)
4329 ("Iterator_Element requires indexing aspect",
4335 -- All done if not a full record definition
4337 if Ekind
(Rec
) /= E_Record_Type
then
4341 -- Finally we need to check the variant part to make sure that
4342 -- all types within choices are properly frozen as part of the
4343 -- freezing of the record type.
4345 Check_Variant_Part
: declare
4346 D
: constant Node_Id
:= Declaration_Node
(Rec
);
4351 -- Find component list
4355 if Nkind
(D
) = N_Full_Type_Declaration
then
4356 T
:= Type_Definition
(D
);
4358 if Nkind
(T
) = N_Record_Definition
then
4359 C
:= Component_List
(T
);
4361 elsif Nkind
(T
) = N_Derived_Type_Definition
4362 and then Present
(Record_Extension_Part
(T
))
4364 C
:= Component_List
(Record_Extension_Part
(T
));
4368 -- Case of variant part present
4370 if Present
(C
) and then Present
(Variant_Part
(C
)) then
4371 Freeze_Choices_In_Variant_Part
(Variant_Part
(C
));
4374 -- Note: we used to call Check_Choices here, but it is too early,
4375 -- since predicated subtypes are frozen here, but their freezing
4376 -- actions are in Analyze_Freeze_Entity, which has not been called
4377 -- yet for entities frozen within this procedure, so we moved that
4378 -- call to the Analyze_Freeze_Entity for the record type.
4380 end Check_Variant_Part
;
4382 -- Check that all the primitives of an interface type are abstract
4383 -- or null procedures.
4385 if Is_Interface
(Rec
)
4386 and then not Error_Posted
(Parent
(Rec
))
4393 Elmt
:= First_Elmt
(Primitive_Operations
(Rec
));
4394 while Present
(Elmt
) loop
4395 Subp
:= Node
(Elmt
);
4397 if not Is_Abstract_Subprogram
(Subp
)
4399 -- Avoid reporting the error on inherited primitives
4401 and then Comes_From_Source
(Subp
)
4403 Error_Msg_Name_1
:= Chars
(Subp
);
4405 if Ekind
(Subp
) = E_Procedure
then
4406 if not Null_Present
(Parent
(Subp
)) then
4408 ("interface procedure % must be abstract or null",
4413 ("interface function % must be abstract",
4422 end Freeze_Record_Type
;
4424 -------------------------------
4425 -- Has_Boolean_Aspect_Import --
4426 -------------------------------
4428 function Has_Boolean_Aspect_Import
(E
: Entity_Id
) return Boolean is
4429 Decl
: constant Node_Id
:= Declaration_Node
(E
);
4434 if Has_Aspects
(Decl
) then
4435 Asp
:= First
(Aspect_Specifications
(Decl
));
4436 while Present
(Asp
) loop
4437 Expr
:= Expression
(Asp
);
4439 -- The value of aspect Import is True when the expression is
4440 -- either missing or it is explicitly set to True.
4442 if Get_Aspect_Id
(Asp
) = Aspect_Import
4444 or else (Compile_Time_Known_Value
(Expr
)
4445 and then Is_True
(Expr_Value
(Expr
))))
4455 end Has_Boolean_Aspect_Import
;
4457 ----------------------------
4458 -- Late_Freeze_Subprogram --
4459 ----------------------------
4461 procedure Late_Freeze_Subprogram
(E
: Entity_Id
) is
4462 Spec
: constant Node_Id
:=
4463 Specification
(Unit_Declaration_Node
(Scope
(E
)));
4467 if Present
(Private_Declarations
(Spec
)) then
4468 Decls
:= Private_Declarations
(Spec
);
4470 Decls
:= Visible_Declarations
(Spec
);
4473 Append_List
(Result
, Decls
);
4474 end Late_Freeze_Subprogram
;
4476 ---------------------
4477 -- Restore_Globals --
4478 ---------------------
4480 procedure Restore_Globals
is
4483 end Restore_Globals
;
4485 ------------------------------
4486 -- Wrap_Imported_Subprogram --
4487 ------------------------------
4489 -- The issue here is that our normal approach of checking preconditions
4490 -- and postconditions does not work for imported procedures, since we
4491 -- are not generating code for the body. To get around this we create
4492 -- a wrapper, as shown by the following example:
4494 -- procedure K (A : Integer);
4495 -- pragma Import (C, K);
4497 -- The spec is rewritten by removing the effects of pragma Import, but
4498 -- leaving the convention unchanged, as though the source had said:
4500 -- procedure K (A : Integer);
4501 -- pragma Convention (C, K);
4503 -- and we create a body, added to the entity K freeze actions, which
4506 -- procedure K (A : Integer) is
4507 -- procedure K (A : Integer);
4508 -- pragma Import (C, K);
4513 -- Now the contract applies in the normal way to the outer procedure,
4514 -- and the inner procedure has no contracts, so there is no problem
4515 -- in just calling it to get the original effect.
4517 -- In the case of a function, we create an appropriate return statement
4518 -- for the subprogram body that calls the inner procedure.
4520 procedure Wrap_Imported_Subprogram
(E
: Entity_Id
) is
4521 Loc
: constant Source_Ptr
:= Sloc
(E
);
4522 CE
: constant Name_Id
:= Chars
(E
);
4531 -- Nothing to do if not imported
4533 if not Is_Imported
(E
) then
4536 -- Test enabling conditions for wrapping
4538 elsif Is_Subprogram
(E
)
4539 and then Present
(Contract
(E
))
4540 and then Present
(Pre_Post_Conditions
(Contract
(E
)))
4541 and then not GNATprove_Mode
4543 -- Here we do the wrap
4545 -- Note on calls to Copy_Separate_Tree. The trees we are copying
4546 -- here are fully analyzed, but we definitely want fully syntactic
4547 -- unanalyzed trees in the body we construct, so that the analysis
4548 -- generates the right visibility, and that is exactly what the
4549 -- calls to Copy_Separate_Tree give us.
4551 -- Acquire copy of Inline pragma, and indicate that it does not
4552 -- come from an aspect, as it applies to an internal entity.
4554 Iprag
:= Copy_Separate_Tree
(Import_Pragma
(E
));
4555 Set_From_Aspect_Specification
(Iprag
, False);
4557 -- Fix up spec to be not imported any more
4559 Set_Is_Imported
(E
, False);
4560 Set_Interface_Name
(E
, Empty
);
4561 Set_Has_Completion
(E
, False);
4562 Set_Import_Pragma
(E
, Empty
);
4564 -- Grab the subprogram declaration and specification
4566 Spec
:= Declaration_Node
(E
);
4568 -- Build parameter list that we need
4571 Forml
:= First_Formal
(E
);
4572 while Present
(Forml
) loop
4573 Append_To
(Parms
, Make_Identifier
(Loc
, Chars
(Forml
)));
4574 Next_Formal
(Forml
);
4579 if Ekind_In
(E
, E_Function
, E_Generic_Function
) then
4581 Make_Simple_Return_Statement
(Loc
,
4583 Make_Function_Call
(Loc
,
4584 Name
=> Make_Identifier
(Loc
, CE
),
4585 Parameter_Associations
=> Parms
));
4589 Make_Procedure_Call_Statement
(Loc
,
4590 Name
=> Make_Identifier
(Loc
, CE
),
4591 Parameter_Associations
=> Parms
);
4594 -- Now build the body
4597 Make_Subprogram_Body
(Loc
,
4599 Copy_Separate_Tree
(Spec
),
4600 Declarations
=> New_List
(
4601 Make_Subprogram_Declaration
(Loc
,
4603 Copy_Separate_Tree
(Spec
)),
4605 Handled_Statement_Sequence
=>
4606 Make_Handled_Sequence_Of_Statements
(Loc
,
4607 Statements
=> New_List
(Stmt
),
4608 End_Label
=> Make_Identifier
(Loc
, CE
)));
4610 -- Append the body to freeze result
4612 Add_To_Result
(Bod
);
4615 -- Case of imported subprogram that does not get wrapped
4618 -- Set Is_Public. All imported entities need an external symbol
4619 -- created for them since they are always referenced from another
4620 -- object file. Note this used to be set when we set Is_Imported
4621 -- back in Sem_Prag, but now we delay it to this point, since we
4622 -- don't want to set this flag if we wrap an imported subprogram.
4626 end Wrap_Imported_Subprogram
;
4628 -- Start of processing for Freeze_Entity
4631 -- The entity being frozen may be subject to pragma Ghost with policy
4632 -- Ignore. Set the mode now to ensure that any nodes generated during
4633 -- freezing are properly flagged as ignored Ghost.
4635 Set_Ghost_Mode_For_Freeze
(E
, N
);
4637 -- We are going to test for various reasons why this entity need not be
4638 -- frozen here, but in the case of an Itype that's defined within a
4639 -- record, that test actually applies to the record.
4641 if Is_Itype
(E
) and then Is_Record_Type
(Scope
(E
)) then
4642 Test_E
:= Scope
(E
);
4643 elsif Is_Itype
(E
) and then Present
(Underlying_Type
(Scope
(E
)))
4644 and then Is_Record_Type
(Underlying_Type
(Scope
(E
)))
4646 Test_E
:= Underlying_Type
(Scope
(E
));
4649 -- Do not freeze if already frozen since we only need one freeze node
4651 if Is_Frozen
(E
) then
4655 -- It is improper to freeze an external entity within a generic because
4656 -- its freeze node will appear in a non-valid context. The entity will
4657 -- be frozen in the proper scope after the current generic is analyzed.
4658 -- However, aspects must be analyzed because they may be queried later
4659 -- within the generic itself, and the corresponding pragma or attribute
4660 -- definition has not been analyzed yet.
4662 elsif Inside_A_Generic
and then External_Ref_In_Generic
(Test_E
) then
4663 if Has_Delayed_Aspects
(E
) then
4664 Analyze_Aspects_At_Freeze_Point
(E
);
4670 -- AI05-0213: A formal incomplete type does not freeze the actual. In
4671 -- the instance, the same applies to the subtype renaming the actual.
4673 elsif Is_Private_Type
(E
)
4674 and then Is_Generic_Actual_Type
(E
)
4675 and then No
(Full_View
(Base_Type
(E
)))
4676 and then Ada_Version
>= Ada_2012
4681 -- Formal subprograms are never frozen
4683 elsif Is_Formal_Subprogram
(E
) then
4687 -- Generic types are never frozen as they lack delayed semantic checks
4689 elsif Is_Generic_Type
(E
) then
4693 -- Do not freeze a global entity within an inner scope created during
4694 -- expansion. A call to subprogram E within some internal procedure
4695 -- (a stream attribute for example) might require freezing E, but the
4696 -- freeze node must appear in the same declarative part as E itself.
4697 -- The two-pass elaboration mechanism in gigi guarantees that E will
4698 -- be frozen before the inner call is elaborated. We exclude constants
4699 -- from this test, because deferred constants may be frozen early, and
4700 -- must be diagnosed (e.g. in the case of a deferred constant being used
4701 -- in a default expression). If the enclosing subprogram comes from
4702 -- source, or is a generic instance, then the freeze point is the one
4703 -- mandated by the language, and we freeze the entity. A subprogram that
4704 -- is a child unit body that acts as a spec does not have a spec that
4705 -- comes from source, but can only come from source.
4707 elsif In_Open_Scopes
(Scope
(Test_E
))
4708 and then Scope
(Test_E
) /= Current_Scope
4709 and then Ekind
(Test_E
) /= E_Constant
4716 while Present
(S
) loop
4717 if Is_Overloadable
(S
) then
4718 if Comes_From_Source
(S
)
4719 or else Is_Generic_Instance
(S
)
4720 or else Is_Child_Unit
(S
)
4733 -- Similarly, an inlined instance body may make reference to global
4734 -- entities, but these references cannot be the proper freezing point
4735 -- for them, and in the absence of inlining freezing will take place in
4736 -- their own scope. Normally instance bodies are analyzed after the
4737 -- enclosing compilation, and everything has been frozen at the proper
4738 -- place, but with front-end inlining an instance body is compiled
4739 -- before the end of the enclosing scope, and as a result out-of-order
4740 -- freezing must be prevented.
4742 elsif Front_End_Inlining
4743 and then In_Instance_Body
4744 and then Present
(Scope
(Test_E
))
4750 S
:= Scope
(Test_E
);
4751 while Present
(S
) loop
4752 if Is_Generic_Instance
(S
) then
4765 elsif Ekind
(E
) = E_Generic_Package
then
4766 Result
:= Freeze_Generic_Entities
(E
);
4772 -- Add checks to detect proper initialization of scalars that may appear
4773 -- as subprogram parameters.
4775 if Is_Subprogram
(E
) and then Check_Validity_Of_Parameters
then
4776 Apply_Parameter_Validity_Checks
(E
);
4779 -- Deal with delayed aspect specifications. The analysis of the aspect
4780 -- is required to be delayed to the freeze point, thus we analyze the
4781 -- pragma or attribute definition clause in the tree at this point. We
4782 -- also analyze the aspect specification node at the freeze point when
4783 -- the aspect doesn't correspond to pragma/attribute definition clause.
4785 if Has_Delayed_Aspects
(E
) then
4786 Analyze_Aspects_At_Freeze_Point
(E
);
4789 -- Here to freeze the entity
4793 -- Case of entity being frozen is other than a type
4795 if not Is_Type
(E
) then
4797 -- If entity is exported or imported and does not have an external
4798 -- name, now is the time to provide the appropriate default name.
4799 -- Skip this if the entity is stubbed, since we don't need a name
4800 -- for any stubbed routine. For the case on intrinsics, if no
4801 -- external name is specified, then calls will be handled in
4802 -- Exp_Intr.Expand_Intrinsic_Call, and no name is needed. If an
4803 -- external name is provided, then Expand_Intrinsic_Call leaves
4804 -- calls in place for expansion by GIGI.
4806 if (Is_Imported
(E
) or else Is_Exported
(E
))
4807 and then No
(Interface_Name
(E
))
4808 and then Convention
(E
) /= Convention_Stubbed
4809 and then Convention
(E
) /= Convention_Intrinsic
4811 Set_Encoded_Interface_Name
4812 (E
, Get_Default_External_Name
(E
));
4814 -- If entity is an atomic object appearing in a declaration and
4815 -- the expression is an aggregate, assign it to a temporary to
4816 -- ensure that the actual assignment is done atomically rather
4817 -- than component-wise (the assignment to the temp may be done
4818 -- component-wise, but that is harmless).
4820 elsif Is_Atomic_Or_VFA
(E
)
4821 and then Nkind
(Parent
(E
)) = N_Object_Declaration
4822 and then Present
(Expression
(Parent
(E
)))
4823 and then Nkind
(Expression
(Parent
(E
))) = N_Aggregate
4825 Is_Atomic_VFA_Aggregate
(Expression
(Parent
(E
)), Etype
(E
))
4832 if Is_Subprogram
(E
) then
4834 -- Check for needing to wrap imported subprogram
4836 Wrap_Imported_Subprogram
(E
);
4838 -- Freeze all parameter types and the return type (RM 13.14(14)).
4839 -- However skip this for internal subprograms. This is also where
4840 -- any extra formal parameters are created since we now know
4841 -- whether the subprogram will use a foreign convention.
4843 -- In Ada 2012, freezing a subprogram does not always freeze
4844 -- the corresponding profile (see AI05-019). An attribute
4845 -- reference is not a freezing point of the profile.
4846 -- Other constructs that should not freeze ???
4848 -- This processing doesn't apply to internal entities (see below)
4850 if not Is_Internal
(E
) then
4851 if not Freeze_Profile
(E
) then
4857 -- Must freeze its parent first if it is a derived subprogram
4859 if Present
(Alias
(E
)) then
4860 Freeze_And_Append
(Alias
(E
), N
, Result
);
4863 -- We don't freeze internal subprograms, because we don't normally
4864 -- want addition of extra formals or mechanism setting to happen
4865 -- for those. However we do pass through predefined dispatching
4866 -- cases, since extra formals may be needed in some cases, such as
4867 -- for the stream 'Input function (build-in-place formals).
4869 if not Is_Internal
(E
)
4870 or else Is_Predefined_Dispatching_Operation
(E
)
4872 Freeze_Subprogram
(E
);
4875 if Late_Freezing
then
4876 Late_Freeze_Subprogram
(E
);
4881 -- If warning on suspicious contracts then check for the case of
4882 -- a postcondition other than False for a No_Return subprogram.
4885 and then Warn_On_Suspicious_Contract
4886 and then Present
(Contract
(E
))
4889 Prag
: Node_Id
:= Pre_Post_Conditions
(Contract
(E
));
4893 while Present
(Prag
) loop
4894 if Nam_In
(Pragma_Name
(Prag
), Name_Post
,
4900 (First
(Pragma_Argument_Associations
(Prag
)));
4902 if Nkind
(Exp
) /= N_Identifier
4903 or else Chars
(Exp
) /= Name_False
4906 ("useless postcondition, & is marked "
4907 & "No_Return?T?", Exp
, E
);
4911 Prag
:= Next_Pragma
(Prag
);
4916 -- Here for other than a subprogram or type
4919 -- If entity has a type, and it is not a generic unit, then
4920 -- freeze it first (RM 13.14(10)).
4922 if Present
(Etype
(E
))
4923 and then Ekind
(E
) /= E_Generic_Function
4925 Freeze_And_Append
(Etype
(E
), N
, Result
);
4927 -- For an object of an anonymous array type, aspects on the
4928 -- object declaration apply to the type itself. This is the
4929 -- case for Atomic_Components, Volatile_Components, and
4930 -- Independent_Components. In these cases analysis of the
4931 -- generated pragma will mark the anonymous types accordingly,
4932 -- and the object itself does not require a freeze node.
4934 if Ekind
(E
) = E_Variable
4935 and then Is_Itype
(Etype
(E
))
4936 and then Is_Array_Type
(Etype
(E
))
4937 and then Has_Delayed_Aspects
(E
)
4939 Set_Has_Delayed_Aspects
(E
, False);
4940 Set_Has_Delayed_Freeze
(E
, False);
4941 Set_Freeze_Node
(E
, Empty
);
4945 -- Special processing for objects created by object declaration
4947 if Nkind
(Declaration_Node
(E
)) = N_Object_Declaration
then
4948 Freeze_Object_Declaration
(E
);
4951 -- Check that a constant which has a pragma Volatile[_Components]
4952 -- or Atomic[_Components] also has a pragma Import (RM C.6(13)).
4954 -- Note: Atomic[_Components] also sets Volatile[_Components]
4956 if Ekind
(E
) = E_Constant
4957 and then (Has_Volatile_Components
(E
) or else Is_Volatile
(E
))
4958 and then not Is_Imported
(E
)
4959 and then not Has_Boolean_Aspect_Import
(E
)
4961 -- Make sure we actually have a pragma, and have not merely
4962 -- inherited the indication from elsewhere (e.g. an address
4963 -- clause, which is not good enough in RM terms).
4965 if Has_Rep_Pragma
(E
, Name_Atomic
)
4967 Has_Rep_Pragma
(E
, Name_Atomic_Components
)
4970 ("stand alone atomic constant must be " &
4971 "imported (RM C.6(13))", E
);
4973 elsif Has_Rep_Pragma
(E
, Name_Volatile
)
4975 Has_Rep_Pragma
(E
, Name_Volatile_Components
)
4978 ("stand alone volatile constant must be " &
4979 "imported (RM C.6(13))", E
);
4983 -- Static objects require special handling
4985 if (Ekind
(E
) = E_Constant
or else Ekind
(E
) = E_Variable
)
4986 and then Is_Statically_Allocated
(E
)
4988 Freeze_Static_Object
(E
);
4991 -- Remaining step is to layout objects
4993 if Ekind_In
(E
, E_Variable
, E_Constant
, E_Loop_Parameter
)
4994 or else Is_Formal
(E
)
4999 -- For an object that does not have delayed freezing, and whose
5000 -- initialization actions have been captured in a compound
5001 -- statement, move them back now directly within the enclosing
5002 -- statement sequence.
5004 if Ekind_In
(E
, E_Constant
, E_Variable
)
5005 and then not Has_Delayed_Freeze
(E
)
5007 Explode_Initialization_Compound_Statement
(E
);
5011 -- Case of a type or subtype being frozen
5014 -- We used to check here that a full type must have preelaborable
5015 -- initialization if it completes a private type specified with
5016 -- pragma Preelaborable_Initialization, but that missed cases where
5017 -- the types occur within a generic package, since the freezing
5018 -- that occurs within a containing scope generally skips traversal
5019 -- of a generic unit's declarations (those will be frozen within
5020 -- instances). This check was moved to Analyze_Package_Specification.
5022 -- The type may be defined in a generic unit. This can occur when
5023 -- freezing a generic function that returns the type (which is
5024 -- defined in a parent unit). It is clearly meaningless to freeze
5025 -- this type. However, if it is a subtype, its size may be determi-
5026 -- nable and used in subsequent checks, so might as well try to
5029 -- In Ada 2012, Freeze_Entities is also used in the front end to
5030 -- trigger the analysis of aspect expressions, so in this case we
5031 -- want to continue the freezing process.
5033 if Present
(Scope
(E
))
5034 and then Is_Generic_Unit
(Scope
(E
))
5036 (not Has_Predicates
(E
)
5037 and then not Has_Delayed_Freeze
(E
))
5039 Check_Compile_Time_Size
(E
);
5044 -- Check for error of Type_Invariant'Class applied to an untagged
5045 -- type (check delayed to freeze time when full type is available).
5048 Prag
: constant Node_Id
:= Get_Pragma
(E
, Pragma_Invariant
);
5051 and then Class_Present
(Prag
)
5052 and then not Is_Tagged_Type
(E
)
5055 ("Type_Invariant''Class cannot be specified for &",
5058 ("\can only be specified for a tagged type", Prag
);
5062 -- A Ghost type cannot be effectively volatile (SPARK RM 6.9(8))
5064 if Is_Ghost_Entity
(E
)
5065 and then Is_Effectively_Volatile
(E
)
5067 Error_Msg_N
("ghost type & cannot be volatile", E
);
5070 -- Deal with special cases of freezing for subtype
5072 if E
/= Base_Type
(E
) then
5074 -- Before we do anything else, a specialized test for the case of
5075 -- a size given for an array where the array needs to be packed,
5076 -- but was not so the size cannot be honored. This is the case
5077 -- where implicit packing may apply. The reason we do this so
5078 -- early is that if we have implicit packing, the layout of the
5079 -- base type is affected, so we must do this before we freeze
5082 -- We could do this processing only if implicit packing is enabled
5083 -- since in all other cases, the error would be caught by the back
5084 -- end. However, we choose to do the check even if we do not have
5085 -- implicit packing enabled, since this allows us to give a more
5086 -- useful error message (advising use of pragmas Implicit_Packing
5089 if Is_Array_Type
(E
) then
5091 Ctyp
: constant Entity_Id
:= Component_Type
(E
);
5092 Rsiz
: constant Uint
:= RM_Size
(Ctyp
);
5093 SZ
: constant Node_Id
:= Size_Clause
(E
);
5094 Btyp
: constant Entity_Id
:= Base_Type
(E
);
5101 -- Number of elements in array
5104 -- Check enabling conditions. These are straightforward
5105 -- except for the test for a limited composite type. This
5106 -- eliminates the rare case of a array of limited components
5107 -- where there are issues of whether or not we can go ahead
5108 -- and pack the array (since we can't freely pack and unpack
5109 -- arrays if they are limited).
5111 -- Note that we check the root type explicitly because the
5112 -- whole point is we are doing this test before we have had
5113 -- a chance to freeze the base type (and it is that freeze
5114 -- action that causes stuff to be inherited).
5116 if Has_Size_Clause
(E
)
5117 and then Known_Static_RM_Size
(E
)
5118 and then not Is_Packed
(E
)
5119 and then not Has_Pragma_Pack
(E
)
5120 and then not Has_Component_Size_Clause
(E
)
5121 and then Known_Static_RM_Size
(Ctyp
)
5122 and then RM_Size
(Ctyp
) < 64
5123 and then not Is_Limited_Composite
(E
)
5124 and then not Is_Packed
(Root_Type
(E
))
5125 and then not Has_Component_Size_Clause
(Root_Type
(E
))
5126 and then not (CodePeer_Mode
or GNATprove_Mode
)
5128 -- Compute number of elements in array
5130 Num_Elmts
:= Uint_1
;
5131 Indx
:= First_Index
(E
);
5132 while Present
(Indx
) loop
5133 Get_Index_Bounds
(Indx
, Lo
, Hi
);
5135 if not (Compile_Time_Known_Value
(Lo
)
5137 Compile_Time_Known_Value
(Hi
))
5139 goto No_Implicit_Packing
;
5145 Expr_Value
(Hi
) - Expr_Value
(Lo
) + 1);
5149 -- What we are looking for here is the situation where
5150 -- the RM_Size given would be exactly right if there was
5151 -- a pragma Pack (resulting in the component size being
5152 -- the same as the RM_Size). Furthermore, the component
5153 -- type size must be an odd size (not a multiple of
5154 -- storage unit). If the component RM size is an exact
5155 -- number of storage units that is a power of two, the
5156 -- array is not packed and has a standard representation.
5158 if RM_Size
(E
) = Num_Elmts
* Rsiz
5159 and then Rsiz
mod System_Storage_Unit
/= 0
5161 -- For implicit packing mode, just set the component
5164 if Implicit_Packing
then
5165 Set_Component_Size
(Btyp
, Rsiz
);
5166 Set_Is_Bit_Packed_Array
(Btyp
);
5167 Set_Is_Packed
(Btyp
);
5168 Set_Has_Non_Standard_Rep
(Btyp
);
5170 -- Otherwise give an error message
5174 ("size given for& too small", SZ
, E
);
5175 Error_Msg_N
-- CODEFIX
5176 ("\use explicit pragma Pack "
5177 & "or use pragma Implicit_Packing", SZ
);
5180 elsif RM_Size
(E
) = Num_Elmts
* Rsiz
5181 and then Implicit_Packing
5183 (Rsiz
/ System_Storage_Unit
= 1
5185 Rsiz
/ System_Storage_Unit
= 2
5187 Rsiz
/ System_Storage_Unit
= 4)
5189 -- Not a packed array, but indicate the desired
5190 -- component size, for the back-end.
5192 Set_Component_Size
(Btyp
, Rsiz
);
5198 <<No_Implicit_Packing
>>
5200 -- If ancestor subtype present, freeze that first. Note that this
5201 -- will also get the base type frozen. Need RM reference ???
5203 Atype
:= Ancestor_Subtype
(E
);
5205 if Present
(Atype
) then
5206 Freeze_And_Append
(Atype
, N
, Result
);
5208 -- No ancestor subtype present
5211 -- See if we have a nearest ancestor that has a predicate.
5212 -- That catches the case of derived type with a predicate.
5213 -- Need RM reference here ???
5215 Atype
:= Nearest_Ancestor
(E
);
5217 if Present
(Atype
) and then Has_Predicates
(Atype
) then
5218 Freeze_And_Append
(Atype
, N
, Result
);
5221 -- Freeze base type before freezing the entity (RM 13.14(15))
5223 if E
/= Base_Type
(E
) then
5224 Freeze_And_Append
(Base_Type
(E
), N
, Result
);
5228 -- A subtype inherits all the type-related representation aspects
5229 -- from its parents (RM 13.1(8)).
5231 Inherit_Aspects_At_Freeze_Point
(E
);
5233 -- For a derived type, freeze its parent type first (RM 13.14(15))
5235 elsif Is_Derived_Type
(E
) then
5236 Freeze_And_Append
(Etype
(E
), N
, Result
);
5237 Freeze_And_Append
(First_Subtype
(Etype
(E
)), N
, Result
);
5239 -- A derived type inherits each type-related representation aspect
5240 -- of its parent type that was directly specified before the
5241 -- declaration of the derived type (RM 13.1(15)).
5243 Inherit_Aspects_At_Freeze_Point
(E
);
5246 -- Check for incompatible size and alignment for record type
5248 if Warn_On_Size_Alignment
5249 and then Is_Record_Type
(E
)
5250 and then Has_Size_Clause
(E
) and then Has_Alignment_Clause
(E
)
5252 -- If explicit Object_Size clause given assume that the programmer
5253 -- knows what he is doing, and expects the compiler behavior.
5255 and then not Has_Object_Size_Clause
(E
)
5257 -- Check for size not a multiple of alignment
5259 and then RM_Size
(E
) mod (Alignment
(E
) * System_Storage_Unit
) /= 0
5262 SC
: constant Node_Id
:= Size_Clause
(E
);
5263 AC
: constant Node_Id
:= Alignment_Clause
(E
);
5265 Abits
: constant Uint
:= Alignment
(E
) * System_Storage_Unit
;
5268 if Present
(SC
) and then Present
(AC
) then
5272 if Sloc
(SC
) > Sloc
(AC
) then
5275 ("?Z?size is not a multiple of alignment for &",
5277 Error_Msg_Sloc
:= Sloc
(AC
);
5278 Error_Msg_Uint_1
:= Alignment
(E
);
5279 Error_Msg_N
("\?Z?alignment of ^ specified #", Loc
);
5284 ("?Z?size is not a multiple of alignment for &",
5286 Error_Msg_Sloc
:= Sloc
(SC
);
5287 Error_Msg_Uint_1
:= RM_Size
(E
);
5288 Error_Msg_N
("\?Z?size of ^ specified #", Loc
);
5291 Error_Msg_Uint_1
:= ((RM_Size
(E
) / Abits
) + 1) * Abits
;
5292 Error_Msg_N
("\?Z?Object_Size will be increased to ^", Loc
);
5299 if Is_Array_Type
(E
) then
5300 Freeze_Array_Type
(E
);
5302 -- For a class-wide type, the corresponding specific type is
5303 -- frozen as well (RM 13.14(15))
5305 elsif Is_Class_Wide_Type
(E
) then
5306 Freeze_And_Append
(Root_Type
(E
), N
, Result
);
5308 -- If the base type of the class-wide type is still incomplete,
5309 -- the class-wide remains unfrozen as well. This is legal when
5310 -- E is the formal of a primitive operation of some other type
5311 -- which is being frozen.
5313 if not Is_Frozen
(Root_Type
(E
)) then
5314 Set_Is_Frozen
(E
, False);
5319 -- The equivalent type associated with a class-wide subtype needs
5320 -- to be frozen to ensure that its layout is done.
5322 if Ekind
(E
) = E_Class_Wide_Subtype
5323 and then Present
(Equivalent_Type
(E
))
5325 Freeze_And_Append
(Equivalent_Type
(E
), N
, Result
);
5328 -- Generate an itype reference for a library-level class-wide type
5329 -- at the freeze point. Otherwise the first explicit reference to
5330 -- the type may appear in an inner scope which will be rejected by
5334 and then Is_Compilation_Unit
(Scope
(E
))
5337 Ref
: constant Node_Id
:= Make_Itype_Reference
(Loc
);
5342 -- From a gigi point of view, a class-wide subtype derives
5343 -- from its record equivalent type. As a result, the itype
5344 -- reference must appear after the freeze node of the
5345 -- equivalent type or gigi will reject the reference.
5347 if Ekind
(E
) = E_Class_Wide_Subtype
5348 and then Present
(Equivalent_Type
(E
))
5350 Insert_After
(Freeze_Node
(Equivalent_Type
(E
)), Ref
);
5352 Add_To_Result
(Ref
);
5357 -- For a record type or record subtype, freeze all component types
5358 -- (RM 13.14(15)). We test for E_Record_(sub)Type here, rather than
5359 -- using Is_Record_Type, because we don't want to attempt the freeze
5360 -- for the case of a private type with record extension (we will do
5361 -- that later when the full type is frozen).
5363 elsif Ekind_In
(E
, E_Record_Type
, E_Record_Subtype
)
5364 and then not (Present
(Scope
(E
))
5365 and then Is_Generic_Unit
(Scope
(E
)))
5367 Freeze_Record_Type
(E
);
5369 -- For a concurrent type, freeze corresponding record type. This does
5370 -- not correspond to any specific rule in the RM, but the record type
5371 -- is essentially part of the concurrent type. Also freeze all local
5372 -- entities. This includes record types created for entry parameter
5373 -- blocks and whatever local entities may appear in the private part.
5375 elsif Is_Concurrent_Type
(E
) then
5376 if Present
(Corresponding_Record_Type
(E
)) then
5377 Freeze_And_Append
(Corresponding_Record_Type
(E
), N
, Result
);
5380 Comp
:= First_Entity
(E
);
5381 while Present
(Comp
) loop
5382 if Is_Type
(Comp
) then
5383 Freeze_And_Append
(Comp
, N
, Result
);
5385 elsif (Ekind
(Comp
)) /= E_Function
then
5387 -- The guard on the presence of the Etype seems to be needed
5388 -- for some CodePeer (-gnatcC) cases, but not clear why???
5390 if Present
(Etype
(Comp
)) then
5391 if Is_Itype
(Etype
(Comp
))
5392 and then Underlying_Type
(Scope
(Etype
(Comp
))) = E
5394 Undelay_Type
(Etype
(Comp
));
5397 Freeze_And_Append
(Etype
(Comp
), N
, Result
);
5404 -- Private types are required to point to the same freeze node as
5405 -- their corresponding full views. The freeze node itself has to
5406 -- point to the partial view of the entity (because from the partial
5407 -- view, we can retrieve the full view, but not the reverse).
5408 -- However, in order to freeze correctly, we need to freeze the full
5409 -- view. If we are freezing at the end of a scope (or within the
5410 -- scope) of the private type, the partial and full views will have
5411 -- been swapped, the full view appears first in the entity chain and
5412 -- the swapping mechanism ensures that the pointers are properly set
5415 -- If we encounter the partial view before the full view (e.g. when
5416 -- freezing from another scope), we freeze the full view, and then
5417 -- set the pointers appropriately since we cannot rely on swapping to
5418 -- fix things up (subtypes in an outer scope might not get swapped).
5420 -- If the full view is itself private, the above requirements apply
5421 -- to the underlying full view instead of the full view. But there is
5422 -- no swapping mechanism for the underlying full view so we need to
5423 -- set the pointers appropriately in both cases.
5425 elsif Is_Incomplete_Or_Private_Type
(E
)
5426 and then not Is_Generic_Type
(E
)
5428 -- The construction of the dispatch table associated with library
5429 -- level tagged types forces freezing of all the primitives of the
5430 -- type, which may cause premature freezing of the partial view.
5434 -- type T is tagged private;
5435 -- type DT is new T with private;
5436 -- procedure Prim (X : in out T; Y : in out DT'Class);
5438 -- type T is tagged null record;
5440 -- type DT is new T with null record;
5443 -- In this case the type will be frozen later by the usual
5444 -- mechanism: an object declaration, an instantiation, or the
5445 -- end of a declarative part.
5447 if Is_Library_Level_Tagged_Type
(E
)
5448 and then not Present
(Full_View
(E
))
5450 Set_Is_Frozen
(E
, False);
5454 -- Case of full view present
5456 elsif Present
(Full_View
(E
)) then
5458 -- If full view has already been frozen, then no further
5459 -- processing is required
5461 if Is_Frozen
(Full_View
(E
)) then
5462 Set_Has_Delayed_Freeze
(E
, False);
5463 Set_Freeze_Node
(E
, Empty
);
5465 -- Otherwise freeze full view and patch the pointers so that
5466 -- the freeze node will elaborate both views in the back end.
5467 -- However, if full view is itself private, freeze underlying
5468 -- full view instead and patch the pointers so that the freeze
5469 -- node will elaborate the three views in the back end.
5473 Full
: Entity_Id
:= Full_View
(E
);
5476 if Is_Private_Type
(Full
)
5477 and then Present
(Underlying_Full_View
(Full
))
5479 Full
:= Underlying_Full_View
(Full
);
5482 Freeze_And_Append
(Full
, N
, Result
);
5484 if Full
/= Full_View
(E
)
5485 and then Has_Delayed_Freeze
(Full_View
(E
))
5487 F_Node
:= Freeze_Node
(Full
);
5489 if Present
(F_Node
) then
5490 Set_Freeze_Node
(Full_View
(E
), F_Node
);
5491 Set_Entity
(F_Node
, Full_View
(E
));
5494 Set_Has_Delayed_Freeze
(Full_View
(E
), False);
5495 Set_Freeze_Node
(Full_View
(E
), Empty
);
5499 if Has_Delayed_Freeze
(E
) then
5500 F_Node
:= Freeze_Node
(Full_View
(E
));
5502 if Present
(F_Node
) then
5503 Set_Freeze_Node
(E
, F_Node
);
5504 Set_Entity
(F_Node
, E
);
5507 -- {Incomplete,Private}_Subtypes with Full_Views
5508 -- constrained by discriminants.
5510 Set_Has_Delayed_Freeze
(E
, False);
5511 Set_Freeze_Node
(E
, Empty
);
5517 Check_Debug_Info_Needed
(E
);
5519 -- AI-117 requires that the convention of a partial view be the
5520 -- same as the convention of the full view. Note that this is a
5521 -- recognized breach of privacy, but it's essential for logical
5522 -- consistency of representation, and the lack of a rule in
5523 -- RM95 was an oversight.
5525 Set_Convention
(E
, Convention
(Full_View
(E
)));
5527 Set_Size_Known_At_Compile_Time
(E
,
5528 Size_Known_At_Compile_Time
(Full_View
(E
)));
5530 -- Size information is copied from the full view to the
5531 -- incomplete or private view for consistency.
5533 -- We skip this is the full view is not a type. This is very
5534 -- strange of course, and can only happen as a result of
5535 -- certain illegalities, such as a premature attempt to derive
5536 -- from an incomplete type.
5538 if Is_Type
(Full_View
(E
)) then
5539 Set_Size_Info
(E
, Full_View
(E
));
5540 Set_RM_Size
(E
, RM_Size
(Full_View
(E
)));
5546 -- Case of underlying full view present
5548 elsif Is_Private_Type
(E
)
5549 and then Present
(Underlying_Full_View
(E
))
5551 if not Is_Frozen
(Underlying_Full_View
(E
)) then
5552 Freeze_And_Append
(Underlying_Full_View
(E
), N
, Result
);
5555 -- Patch the pointers so that the freeze node will elaborate
5556 -- both views in the back end.
5558 if Has_Delayed_Freeze
(E
) then
5559 F_Node
:= Freeze_Node
(Underlying_Full_View
(E
));
5561 if Present
(F_Node
) then
5562 Set_Freeze_Node
(E
, F_Node
);
5563 Set_Entity
(F_Node
, E
);
5566 Set_Has_Delayed_Freeze
(E
, False);
5567 Set_Freeze_Node
(E
, Empty
);
5571 Check_Debug_Info_Needed
(E
);
5576 -- Case of no full view present. If entity is derived or subtype,
5577 -- it is safe to freeze, correctness depends on the frozen status
5578 -- of parent. Otherwise it is either premature usage, or a Taft
5579 -- amendment type, so diagnosis is at the point of use and the
5580 -- type might be frozen later.
5582 elsif E
/= Base_Type
(E
) or else Is_Derived_Type
(E
) then
5586 Set_Is_Frozen
(E
, False);
5591 -- For access subprogram, freeze types of all formals, the return
5592 -- type was already frozen, since it is the Etype of the function.
5593 -- Formal types can be tagged Taft amendment types, but otherwise
5594 -- they cannot be incomplete.
5596 elsif Ekind
(E
) = E_Subprogram_Type
then
5597 Formal
:= First_Formal
(E
);
5598 while Present
(Formal
) loop
5599 if Ekind
(Etype
(Formal
)) = E_Incomplete_Type
5600 and then No
(Full_View
(Etype
(Formal
)))
5601 and then not Is_Value_Type
(Etype
(Formal
))
5603 if Is_Tagged_Type
(Etype
(Formal
)) then
5606 -- AI05-151: Incomplete types are allowed in access to
5607 -- subprogram specifications.
5609 elsif Ada_Version
< Ada_2012
then
5611 ("invalid use of incomplete type&", E
, Etype
(Formal
));
5615 Freeze_And_Append
(Etype
(Formal
), N
, Result
);
5616 Next_Formal
(Formal
);
5619 Freeze_Subprogram
(E
);
5621 -- For access to a protected subprogram, freeze the equivalent type
5622 -- (however this is not set if we are not generating code or if this
5623 -- is an anonymous type used just for resolution).
5625 elsif Is_Access_Protected_Subprogram_Type
(E
) then
5626 if Present
(Equivalent_Type
(E
)) then
5627 Freeze_And_Append
(Equivalent_Type
(E
), N
, Result
);
5631 -- Generic types are never seen by the back-end, and are also not
5632 -- processed by the expander (since the expander is turned off for
5633 -- generic processing), so we never need freeze nodes for them.
5635 if Is_Generic_Type
(E
) then
5640 -- Some special processing for non-generic types to complete
5641 -- representation details not known till the freeze point.
5643 if Is_Fixed_Point_Type
(E
) then
5644 Freeze_Fixed_Point_Type
(E
);
5646 -- Some error checks required for ordinary fixed-point type. Defer
5647 -- these till the freeze-point since we need the small and range
5648 -- values. We only do these checks for base types
5650 if Is_Ordinary_Fixed_Point_Type
(E
) and then Is_Base_Type
(E
) then
5651 if Small_Value
(E
) < Ureal_2_M_80
then
5652 Error_Msg_Name_1
:= Name_Small
;
5654 ("`&''%` too small, minimum allowed is 2.0'*'*(-80)", E
);
5656 elsif Small_Value
(E
) > Ureal_2_80
then
5657 Error_Msg_Name_1
:= Name_Small
;
5659 ("`&''%` too large, maximum allowed is 2.0'*'*80", E
);
5662 if Expr_Value_R
(Type_Low_Bound
(E
)) < Ureal_M_10_36
then
5663 Error_Msg_Name_1
:= Name_First
;
5665 ("`&''%` too small, minimum allowed is -10.0'*'*36", E
);
5668 if Expr_Value_R
(Type_High_Bound
(E
)) > Ureal_10_36
then
5669 Error_Msg_Name_1
:= Name_Last
;
5671 ("`&''%` too large, maximum allowed is 10.0'*'*36", E
);
5675 elsif Is_Enumeration_Type
(E
) then
5676 Freeze_Enumeration_Type
(E
);
5678 elsif Is_Integer_Type
(E
) then
5679 Adjust_Esize_For_Alignment
(E
);
5681 if Is_Modular_Integer_Type
(E
)
5682 and then Warn_On_Suspicious_Modulus_Value
5684 Check_Suspicious_Modulus
(E
);
5687 -- The pool applies to named and anonymous access types, but not
5688 -- to subprogram and to internal types generated for 'Access
5691 elsif Is_Access_Type
(E
)
5692 and then not Is_Access_Subprogram_Type
(E
)
5693 and then Ekind
(E
) /= E_Access_Attribute_Type
5695 -- If a pragma Default_Storage_Pool applies, and this type has no
5696 -- Storage_Pool or Storage_Size clause (which must have occurred
5697 -- before the freezing point), then use the default. This applies
5698 -- only to base types.
5700 -- None of this applies to access to subprograms, for which there
5701 -- are clearly no pools.
5703 if Present
(Default_Pool
)
5704 and then Is_Base_Type
(E
)
5705 and then not Has_Storage_Size_Clause
(E
)
5706 and then No
(Associated_Storage_Pool
(E
))
5708 -- Case of pragma Default_Storage_Pool (null)
5710 if Nkind
(Default_Pool
) = N_Null
then
5711 Set_No_Pool_Assigned
(E
);
5713 -- Case of pragma Default_Storage_Pool (storage_pool_NAME)
5716 Set_Associated_Storage_Pool
(E
, Entity
(Default_Pool
));
5720 -- Check restriction for standard storage pool
5722 if No
(Associated_Storage_Pool
(E
)) then
5723 Check_Restriction
(No_Standard_Storage_Pools
, E
);
5726 -- Deal with error message for pure access type. This is not an
5727 -- error in Ada 2005 if there is no pool (see AI-366).
5729 if Is_Pure_Unit_Access_Type
(E
)
5730 and then (Ada_Version
< Ada_2005
5731 or else not No_Pool_Assigned
(E
))
5732 and then not Is_Generic_Unit
(Scope
(E
))
5734 Error_Msg_N
("named access type not allowed in pure unit", E
);
5736 if Ada_Version
>= Ada_2005
then
5738 ("\would be legal if Storage_Size of 0 given??", E
);
5740 elsif No_Pool_Assigned
(E
) then
5742 ("\would be legal in Ada 2005??", E
);
5746 ("\would be legal in Ada 2005 if "
5747 & "Storage_Size of 0 given??", E
);
5752 -- Case of composite types
5754 if Is_Composite_Type
(E
) then
5756 -- AI-117 requires that all new primitives of a tagged type must
5757 -- inherit the convention of the full view of the type. Inherited
5758 -- and overriding operations are defined to inherit the convention
5759 -- of their parent or overridden subprogram (also specified in
5760 -- AI-117), which will have occurred earlier (in Derive_Subprogram
5761 -- and New_Overloaded_Entity). Here we set the convention of
5762 -- primitives that are still convention Ada, which will ensure
5763 -- that any new primitives inherit the type's convention. Class-
5764 -- wide types can have a foreign convention inherited from their
5765 -- specific type, but are excluded from this since they don't have
5766 -- any associated primitives.
5768 if Is_Tagged_Type
(E
)
5769 and then not Is_Class_Wide_Type
(E
)
5770 and then Convention
(E
) /= Convention_Ada
5773 Prim_List
: constant Elist_Id
:= Primitive_Operations
(E
);
5777 Prim
:= First_Elmt
(Prim_List
);
5778 while Present
(Prim
) loop
5779 if Convention
(Node
(Prim
)) = Convention_Ada
then
5780 Set_Convention
(Node
(Prim
), Convention
(E
));
5788 -- If the type is a simple storage pool type, then this is where
5789 -- we attempt to locate and validate its Allocate, Deallocate, and
5790 -- Storage_Size operations (the first is required, and the latter
5791 -- two are optional). We also verify that the full type for a
5792 -- private type is allowed to be a simple storage pool type.
5794 if Present
(Get_Rep_Pragma
(E
, Name_Simple_Storage_Pool_Type
))
5795 and then (Is_Base_Type
(E
) or else Has_Private_Declaration
(E
))
5797 -- If the type is marked Has_Private_Declaration, then this is
5798 -- a full type for a private type that was specified with the
5799 -- pragma Simple_Storage_Pool_Type, and here we ensure that the
5800 -- pragma is allowed for the full type (for example, it can't
5801 -- be an array type, or a nonlimited record type).
5803 if Has_Private_Declaration
(E
) then
5804 if (not Is_Record_Type
(E
) or else not Is_Limited_View
(E
))
5805 and then not Is_Private_Type
(E
)
5807 Error_Msg_Name_1
:= Name_Simple_Storage_Pool_Type
;
5809 ("pragma% can only apply to full type that is an " &
5810 "explicitly limited type", E
);
5814 Validate_Simple_Pool_Ops
: declare
5815 Pool_Type
: Entity_Id
renames E
;
5816 Address_Type
: constant Entity_Id
:= RTE
(RE_Address
);
5817 Stg_Cnt_Type
: constant Entity_Id
:= RTE
(RE_Storage_Count
);
5819 procedure Validate_Simple_Pool_Op_Formal
5820 (Pool_Op
: Entity_Id
;
5821 Pool_Op_Formal
: in out Entity_Id
;
5822 Expected_Mode
: Formal_Kind
;
5823 Expected_Type
: Entity_Id
;
5824 Formal_Name
: String;
5825 OK_Formal
: in out Boolean);
5826 -- Validate one formal Pool_Op_Formal of the candidate pool
5827 -- operation Pool_Op. The formal must be of Expected_Type
5828 -- and have mode Expected_Mode. OK_Formal will be set to
5829 -- False if the formal doesn't match. If OK_Formal is False
5830 -- on entry, then the formal will effectively be ignored
5831 -- (because validation of the pool op has already failed).
5832 -- Upon return, Pool_Op_Formal will be updated to the next
5835 procedure Validate_Simple_Pool_Operation
5836 (Op_Name
: Name_Id
);
5837 -- Search for and validate a simple pool operation with the
5838 -- name Op_Name. If the name is Allocate, then there must be
5839 -- exactly one such primitive operation for the simple pool
5840 -- type. If the name is Deallocate or Storage_Size, then
5841 -- there can be at most one such primitive operation. The
5842 -- profile of the located primitive must conform to what
5843 -- is expected for each operation.
5845 ------------------------------------
5846 -- Validate_Simple_Pool_Op_Formal --
5847 ------------------------------------
5849 procedure Validate_Simple_Pool_Op_Formal
5850 (Pool_Op
: Entity_Id
;
5851 Pool_Op_Formal
: in out Entity_Id
;
5852 Expected_Mode
: Formal_Kind
;
5853 Expected_Type
: Entity_Id
;
5854 Formal_Name
: String;
5855 OK_Formal
: in out Boolean)
5858 -- If OK_Formal is False on entry, then simply ignore
5859 -- the formal, because an earlier formal has already
5862 if not OK_Formal
then
5865 -- If no formal is passed in, then issue an error for a
5868 elsif not Present
(Pool_Op_Formal
) then
5870 ("simple storage pool op missing formal " &
5871 Formal_Name
& " of type&", Pool_Op
, Expected_Type
);
5877 if Etype
(Pool_Op_Formal
) /= Expected_Type
then
5879 -- If the pool type was expected for this formal, then
5880 -- this will not be considered a candidate operation
5881 -- for the simple pool, so we unset OK_Formal so that
5882 -- the op and any later formals will be ignored.
5884 if Expected_Type
= Pool_Type
then
5891 ("wrong type for formal " & Formal_Name
&
5892 " of simple storage pool op; expected type&",
5893 Pool_Op_Formal
, Expected_Type
);
5897 -- Issue error if formal's mode is not the expected one
5899 if Ekind
(Pool_Op_Formal
) /= Expected_Mode
then
5901 ("wrong mode for formal of simple storage pool op",
5905 -- Advance to the next formal
5907 Next_Formal
(Pool_Op_Formal
);
5908 end Validate_Simple_Pool_Op_Formal
;
5910 ------------------------------------
5911 -- Validate_Simple_Pool_Operation --
5912 ------------------------------------
5914 procedure Validate_Simple_Pool_Operation
5918 Found_Op
: Entity_Id
:= Empty
;
5924 (Nam_In
(Op_Name
, Name_Allocate
,
5926 Name_Storage_Size
));
5928 Error_Msg_Name_1
:= Op_Name
;
5930 -- For each homonym declared immediately in the scope
5931 -- of the simple storage pool type, determine whether
5932 -- the homonym is an operation of the pool type, and,
5933 -- if so, check that its profile is as expected for
5934 -- a simple pool operation of that name.
5936 Op
:= Get_Name_Entity_Id
(Op_Name
);
5937 while Present
(Op
) loop
5938 if Ekind_In
(Op
, E_Function
, E_Procedure
)
5939 and then Scope
(Op
) = Current_Scope
5941 Formal
:= First_Entity
(Op
);
5945 -- The first parameter must be of the pool type
5946 -- in order for the operation to qualify.
5948 if Op_Name
= Name_Storage_Size
then
5949 Validate_Simple_Pool_Op_Formal
5950 (Op
, Formal
, E_In_Parameter
, Pool_Type
,
5953 Validate_Simple_Pool_Op_Formal
5954 (Op
, Formal
, E_In_Out_Parameter
, Pool_Type
,
5958 -- If another operation with this name has already
5959 -- been located for the type, then flag an error,
5960 -- since we only allow the type to have a single
5963 if Present
(Found_Op
) and then Is_OK
then
5965 ("only one % operation allowed for " &
5966 "simple storage pool type&", Op
, Pool_Type
);
5969 -- In the case of Allocate and Deallocate, a formal
5970 -- of type System.Address is required.
5972 if Op_Name
= Name_Allocate
then
5973 Validate_Simple_Pool_Op_Formal
5974 (Op
, Formal
, E_Out_Parameter
,
5975 Address_Type
, "Storage_Address", Is_OK
);
5977 elsif Op_Name
= Name_Deallocate
then
5978 Validate_Simple_Pool_Op_Formal
5979 (Op
, Formal
, E_In_Parameter
,
5980 Address_Type
, "Storage_Address", Is_OK
);
5983 -- In the case of Allocate and Deallocate, formals
5984 -- of type Storage_Count are required as the third
5985 -- and fourth parameters.
5987 if Op_Name
/= Name_Storage_Size
then
5988 Validate_Simple_Pool_Op_Formal
5989 (Op
, Formal
, E_In_Parameter
,
5990 Stg_Cnt_Type
, "Size_In_Storage_Units", Is_OK
);
5991 Validate_Simple_Pool_Op_Formal
5992 (Op
, Formal
, E_In_Parameter
,
5993 Stg_Cnt_Type
, "Alignment", Is_OK
);
5996 -- If no mismatched formals have been found (Is_OK)
5997 -- and no excess formals are present, then this
5998 -- operation has been validated, so record it.
6000 if not Present
(Formal
) and then Is_OK
then
6008 -- There must be a valid Allocate operation for the type,
6009 -- so issue an error if none was found.
6011 if Op_Name
= Name_Allocate
6012 and then not Present
(Found_Op
)
6014 Error_Msg_N
("missing % operation for simple " &
6015 "storage pool type", Pool_Type
);
6017 elsif Present
(Found_Op
) then
6019 -- Simple pool operations can't be abstract
6021 if Is_Abstract_Subprogram
(Found_Op
) then
6023 ("simple storage pool operation must not be " &
6024 "abstract", Found_Op
);
6027 -- The Storage_Size operation must be a function with
6028 -- Storage_Count as its result type.
6030 if Op_Name
= Name_Storage_Size
then
6031 if Ekind
(Found_Op
) = E_Procedure
then
6033 ("% operation must be a function", Found_Op
);
6035 elsif Etype
(Found_Op
) /= Stg_Cnt_Type
then
6037 ("wrong result type for%, expected type&",
6038 Found_Op
, Stg_Cnt_Type
);
6041 -- Allocate and Deallocate must be procedures
6043 elsif Ekind
(Found_Op
) = E_Function
then
6045 ("% operation must be a procedure", Found_Op
);
6048 end Validate_Simple_Pool_Operation
;
6050 -- Start of processing for Validate_Simple_Pool_Ops
6053 Validate_Simple_Pool_Operation
(Name_Allocate
);
6054 Validate_Simple_Pool_Operation
(Name_Deallocate
);
6055 Validate_Simple_Pool_Operation
(Name_Storage_Size
);
6056 end Validate_Simple_Pool_Ops
;
6060 -- Now that all types from which E may depend are frozen, see if the
6061 -- size is known at compile time, if it must be unsigned, or if
6062 -- strict alignment is required
6064 Check_Compile_Time_Size
(E
);
6065 Check_Unsigned_Type
(E
);
6067 if Base_Type
(E
) = E
then
6068 Check_Strict_Alignment
(E
);
6071 -- Do not allow a size clause for a type which does not have a size
6072 -- that is known at compile time
6074 if Has_Size_Clause
(E
)
6075 and then not Size_Known_At_Compile_Time
(E
)
6077 -- Suppress this message if errors posted on E, even if we are
6078 -- in all errors mode, since this is often a junk message
6080 if not Error_Posted
(E
) then
6082 ("size clause not allowed for variable length type",
6087 -- Now we set/verify the representation information, in particular
6088 -- the size and alignment values. This processing is not required for
6089 -- generic types, since generic types do not play any part in code
6090 -- generation, and so the size and alignment values for such types
6091 -- are irrelevant. Ditto for types declared within a generic unit,
6092 -- which may have components that depend on generic parameters, and
6093 -- that will be recreated in an instance.
6095 if Inside_A_Generic
then
6098 -- Otherwise we call the layout procedure
6104 -- If this is an access to subprogram whose designated type is itself
6105 -- a subprogram type, the return type of this anonymous subprogram
6106 -- type must be decorated as well.
6108 if Ekind
(E
) = E_Anonymous_Access_Subprogram_Type
6109 and then Ekind
(Designated_Type
(E
)) = E_Subprogram_Type
6111 Layout_Type
(Etype
(Designated_Type
(E
)));
6114 -- If the type has a Defaut_Value/Default_Component_Value aspect,
6115 -- this is where we analye the expression (after the type is frozen,
6116 -- since in the case of Default_Value, we are analyzing with the
6117 -- type itself, and we treat Default_Component_Value similarly for
6118 -- the sake of uniformity).
6120 if Is_First_Subtype
(E
) and then Has_Default_Aspect
(E
) then
6127 if Is_Scalar_Type
(E
) then
6128 Nam
:= Name_Default_Value
;
6130 Exp
:= Default_Aspect_Value
(Typ
);
6132 Nam
:= Name_Default_Component_Value
;
6133 Typ
:= Component_Type
(E
);
6134 Exp
:= Default_Aspect_Component_Value
(E
);
6137 Analyze_And_Resolve
(Exp
, Typ
);
6139 if Etype
(Exp
) /= Any_Type
then
6140 if not Is_OK_Static_Expression
(Exp
) then
6141 Error_Msg_Name_1
:= Nam
;
6142 Flag_Non_Static_Expr
6143 ("aspect% requires static expression", Exp
);
6149 -- End of freeze processing for type entities
6152 -- Here is where we logically freeze the current entity. If it has a
6153 -- freeze node, then this is the point at which the freeze node is
6154 -- linked into the result list.
6156 if Has_Delayed_Freeze
(E
) then
6158 -- If a freeze node is already allocated, use it, otherwise allocate
6159 -- a new one. The preallocation happens in the case of anonymous base
6160 -- types, where we preallocate so that we can set First_Subtype_Link.
6161 -- Note that we reset the Sloc to the current freeze location.
6163 if Present
(Freeze_Node
(E
)) then
6164 F_Node
:= Freeze_Node
(E
);
6165 Set_Sloc
(F_Node
, Loc
);
6168 F_Node
:= New_Node
(N_Freeze_Entity
, Loc
);
6169 Set_Freeze_Node
(E
, F_Node
);
6170 Set_Access_Types_To_Process
(F_Node
, No_Elist
);
6171 Set_TSS_Elist
(F_Node
, No_Elist
);
6172 Set_Actions
(F_Node
, No_List
);
6175 Set_Entity
(F_Node
, E
);
6176 Add_To_Result
(F_Node
);
6178 -- A final pass over record types with discriminants. If the type
6179 -- has an incomplete declaration, there may be constrained access
6180 -- subtypes declared elsewhere, which do not depend on the discrimi-
6181 -- nants of the type, and which are used as component types (i.e.
6182 -- the full view is a recursive type). The designated types of these
6183 -- subtypes can only be elaborated after the type itself, and they
6184 -- need an itype reference.
6186 if Ekind
(E
) = E_Record_Type
6187 and then Has_Discriminants
(E
)
6195 Comp
:= First_Component
(E
);
6196 while Present
(Comp
) loop
6197 Typ
:= Etype
(Comp
);
6199 if Ekind
(Comp
) = E_Component
6200 and then Is_Access_Type
(Typ
)
6201 and then Scope
(Typ
) /= E
6202 and then Base_Type
(Designated_Type
(Typ
)) = E
6203 and then Is_Itype
(Designated_Type
(Typ
))
6205 IR
:= Make_Itype_Reference
(Sloc
(Comp
));
6206 Set_Itype
(IR
, Designated_Type
(Typ
));
6207 Append
(IR
, Result
);
6210 Next_Component
(Comp
);
6216 -- When a type is frozen, the first subtype of the type is frozen as
6217 -- well (RM 13.14(15)). This has to be done after freezing the type,
6218 -- since obviously the first subtype depends on its own base type.
6221 Freeze_And_Append
(First_Subtype
(E
), N
, Result
);
6223 -- If we just froze a tagged non-class wide record, then freeze the
6224 -- corresponding class-wide type. This must be done after the tagged
6225 -- type itself is frozen, because the class-wide type refers to the
6226 -- tagged type which generates the class.
6228 if Is_Tagged_Type
(E
)
6229 and then not Is_Class_Wide_Type
(E
)
6230 and then Present
(Class_Wide_Type
(E
))
6232 Freeze_And_Append
(Class_Wide_Type
(E
), N
, Result
);
6236 Check_Debug_Info_Needed
(E
);
6238 -- Special handling for subprograms
6240 if Is_Subprogram
(E
) then
6242 -- If subprogram has address clause then reset Is_Public flag, since
6243 -- we do not want the backend to generate external references.
6245 if Present
(Address_Clause
(E
))
6246 and then not Is_Library_Level_Entity
(E
)
6248 Set_Is_Public
(E
, False);
6256 -----------------------------
6257 -- Freeze_Enumeration_Type --
6258 -----------------------------
6260 procedure Freeze_Enumeration_Type
(Typ
: Entity_Id
) is
6262 -- By default, if no size clause is present, an enumeration type with
6263 -- Convention C is assumed to interface to a C enum, and has integer
6264 -- size. This applies to types. For subtypes, verify that its base
6265 -- type has no size clause either. Treat other foreign conventions
6266 -- in the same way, and also make sure alignment is set right.
6268 if Has_Foreign_Convention
(Typ
)
6269 and then not Has_Size_Clause
(Typ
)
6270 and then not Has_Size_Clause
(Base_Type
(Typ
))
6271 and then Esize
(Typ
) < Standard_Integer_Size
6273 -- Don't do this if Short_Enums on target
6275 and then not Target_Short_Enums
6277 Init_Esize
(Typ
, Standard_Integer_Size
);
6278 Set_Alignment
(Typ
, Alignment
(Standard_Integer
));
6280 -- Normal Ada case or size clause present or not Long_C_Enums on target
6283 -- If the enumeration type interfaces to C, and it has a size clause
6284 -- that specifies less than int size, it warrants a warning. The
6285 -- user may intend the C type to be an enum or a char, so this is
6286 -- not by itself an error that the Ada compiler can detect, but it
6287 -- it is a worth a heads-up. For Boolean and Character types we
6288 -- assume that the programmer has the proper C type in mind.
6290 if Convention
(Typ
) = Convention_C
6291 and then Has_Size_Clause
(Typ
)
6292 and then Esize
(Typ
) /= Esize
(Standard_Integer
)
6293 and then not Is_Boolean_Type
(Typ
)
6294 and then not Is_Character_Type
(Typ
)
6296 -- Don't do this if Short_Enums on target
6298 and then not Target_Short_Enums
6301 ("C enum types have the size of a C int??", Size_Clause
(Typ
));
6304 Adjust_Esize_For_Alignment
(Typ
);
6306 end Freeze_Enumeration_Type
;
6308 -----------------------
6309 -- Freeze_Expression --
6310 -----------------------
6312 procedure Freeze_Expression
(N
: Node_Id
) is
6313 In_Spec_Exp
: constant Boolean := In_Spec_Expression
;
6316 Desig_Typ
: Entity_Id
;
6320 Freeze_Outside
: Boolean := False;
6321 -- This flag is set true if the entity must be frozen outside the
6322 -- current subprogram. This happens in the case of expander generated
6323 -- subprograms (_Init_Proc, _Input, _Output, _Read, _Write) which do
6324 -- not freeze all entities like other bodies, but which nevertheless
6325 -- may reference entities that have to be frozen before the body and
6326 -- obviously cannot be frozen inside the body.
6328 function Find_Aggregate_Component_Desig_Type
return Entity_Id
;
6329 -- If the expression is an array aggregate, the type of the component
6330 -- expressions is also frozen. If the component type is an access type
6331 -- and the expressions include allocators, the designed type is frozen
6334 function In_Expanded_Body
(N
: Node_Id
) return Boolean;
6335 -- Given an N_Handled_Sequence_Of_Statements node N, determines whether
6336 -- it is the handled statement sequence of an expander-generated
6337 -- subprogram (init proc, stream subprogram, or renaming as body).
6338 -- If so, this is not a freezing context.
6340 -----------------------------------------
6341 -- Find_Aggregate_Component_Desig_Type --
6342 -----------------------------------------
6344 function Find_Aggregate_Component_Desig_Type
return Entity_Id
is
6349 if Present
(Expressions
(N
)) then
6350 Exp
:= First
(Expressions
(N
));
6351 while Present
(Exp
) loop
6352 if Nkind
(Exp
) = N_Allocator
then
6353 return Designated_Type
(Component_Type
(Etype
(N
)));
6360 if Present
(Component_Associations
(N
)) then
6361 Assoc
:= First
(Component_Associations
(N
));
6362 while Present
(Assoc
) loop
6363 if Nkind
(Expression
(Assoc
)) = N_Allocator
then
6364 return Designated_Type
(Component_Type
(Etype
(N
)));
6372 end Find_Aggregate_Component_Desig_Type
;
6374 ----------------------
6375 -- In_Expanded_Body --
6376 ----------------------
6378 function In_Expanded_Body
(N
: Node_Id
) return Boolean is
6383 if Nkind
(N
) = N_Subprogram_Body
then
6389 if Nkind
(P
) /= N_Subprogram_Body
then
6393 Id
:= Defining_Unit_Name
(Specification
(P
));
6395 -- The following are expander-created bodies, or bodies that
6396 -- are not freeze points.
6398 if Nkind
(Id
) = N_Defining_Identifier
6399 and then (Is_Init_Proc
(Id
)
6400 or else Is_TSS
(Id
, TSS_Stream_Input
)
6401 or else Is_TSS
(Id
, TSS_Stream_Output
)
6402 or else Is_TSS
(Id
, TSS_Stream_Read
)
6403 or else Is_TSS
(Id
, TSS_Stream_Write
)
6404 or else Nkind_In
(Original_Node
(P
),
6405 N_Subprogram_Renaming_Declaration
,
6406 N_Expression_Function
))
6413 end In_Expanded_Body
;
6415 -- Start of processing for Freeze_Expression
6418 -- Immediate return if freezing is inhibited. This flag is set by the
6419 -- analyzer to stop freezing on generated expressions that would cause
6420 -- freezing if they were in the source program, but which are not
6421 -- supposed to freeze, since they are created.
6423 if Must_Not_Freeze
(N
) then
6427 -- If expression is non-static, then it does not freeze in a default
6428 -- expression, see section "Handling of Default Expressions" in the
6429 -- spec of package Sem for further details. Note that we have to make
6430 -- sure that we actually have a real expression (if we have a subtype
6431 -- indication, we can't test Is_OK_Static_Expression). However, we
6432 -- exclude the case of the prefix of an attribute of a static scalar
6433 -- subtype from this early return, because static subtype attributes
6434 -- should always cause freezing, even in default expressions, but
6435 -- the attribute may not have been marked as static yet (because in
6436 -- Resolve_Attribute, the call to Eval_Attribute follows the call of
6437 -- Freeze_Expression on the prefix).
6440 and then Nkind
(N
) in N_Subexpr
6441 and then not Is_OK_Static_Expression
(N
)
6442 and then (Nkind
(Parent
(N
)) /= N_Attribute_Reference
6443 or else not (Is_Entity_Name
(N
)
6444 and then Is_Type
(Entity
(N
))
6445 and then Is_OK_Static_Subtype
(Entity
(N
))))
6450 -- Freeze type of expression if not frozen already
6454 if Nkind
(N
) in N_Has_Etype
then
6455 if not Is_Frozen
(Etype
(N
)) then
6458 -- Base type may be an derived numeric type that is frozen at
6459 -- the point of declaration, but first_subtype is still unfrozen.
6461 elsif not Is_Frozen
(First_Subtype
(Etype
(N
))) then
6462 Typ
:= First_Subtype
(Etype
(N
));
6466 -- For entity name, freeze entity if not frozen already. A special
6467 -- exception occurs for an identifier that did not come from source.
6468 -- We don't let such identifiers freeze a non-internal entity, i.e.
6469 -- an entity that did come from source, since such an identifier was
6470 -- generated by the expander, and cannot have any semantic effect on
6471 -- the freezing semantics. For example, this stops the parameter of
6472 -- an initialization procedure from freezing the variable.
6474 if Is_Entity_Name
(N
)
6475 and then not Is_Frozen
(Entity
(N
))
6476 and then (Nkind
(N
) /= N_Identifier
6477 or else Comes_From_Source
(N
)
6478 or else not Comes_From_Source
(Entity
(N
)))
6482 if Present
(Nam
) and then Ekind
(Nam
) = E_Function
then
6483 Check_Expression_Function
(N
, Nam
);
6490 -- For an allocator freeze designated type if not frozen already
6492 -- For an aggregate whose component type is an access type, freeze the
6493 -- designated type now, so that its freeze does not appear within the
6494 -- loop that might be created in the expansion of the aggregate. If the
6495 -- designated type is a private type without full view, the expression
6496 -- cannot contain an allocator, so the type is not frozen.
6498 -- For a function, we freeze the entity when the subprogram declaration
6499 -- is frozen, but a function call may appear in an initialization proc.
6500 -- before the declaration is frozen. We need to generate the extra
6501 -- formals, if any, to ensure that the expansion of the call includes
6502 -- the proper actuals. This only applies to Ada subprograms, not to
6509 Desig_Typ
:= Designated_Type
(Etype
(N
));
6512 if Is_Array_Type
(Etype
(N
))
6513 and then Is_Access_Type
(Component_Type
(Etype
(N
)))
6516 -- Check whether aggregate includes allocators.
6518 Desig_Typ
:= Find_Aggregate_Component_Desig_Type
;
6521 when N_Selected_Component |
6522 N_Indexed_Component |
6525 if Is_Access_Type
(Etype
(Prefix
(N
))) then
6526 Desig_Typ
:= Designated_Type
(Etype
(Prefix
(N
)));
6529 when N_Identifier
=>
6531 and then Ekind
(Nam
) = E_Function
6532 and then Nkind
(Parent
(N
)) = N_Function_Call
6533 and then Convention
(Nam
) = Convention_Ada
6535 Create_Extra_Formals
(Nam
);
6542 if Desig_Typ
/= Empty
6543 and then (Is_Frozen
(Desig_Typ
)
6544 or else (not Is_Fully_Defined
(Desig_Typ
)))
6549 -- All done if nothing needs freezing
6553 and then No
(Desig_Typ
)
6558 -- Examine the enclosing context by climbing the parent chain. The
6559 -- traversal serves two purposes - to detect scenarios where freezeing
6560 -- is not needed and to find the proper insertion point for the freeze
6561 -- nodes. Although somewhat similar to Insert_Actions, this traversal
6562 -- is freezing semantics-sensitive. Inserting freeze nodes blindly in
6563 -- the tree may result in types being frozen too early.
6567 Parent_P
:= Parent
(P
);
6569 -- If we don't have a parent, then we are not in a well-formed tree.
6570 -- This is an unusual case, but there are some legitimate situations
6571 -- in which this occurs, notably when the expressions in the range of
6572 -- a type declaration are resolved. We simply ignore the freeze
6573 -- request in this case. Is this right ???
6575 if No
(Parent_P
) then
6579 -- See if we have got to an appropriate point in the tree
6581 case Nkind
(Parent_P
) is
6583 -- A special test for the exception of (RM 13.14(8)) for the case
6584 -- of per-object expressions (RM 3.8(18)) occurring in component
6585 -- definition or a discrete subtype definition. Note that we test
6586 -- for a component declaration which includes both cases we are
6587 -- interested in, and furthermore the tree does not have explicit
6588 -- nodes for either of these two constructs.
6590 when N_Component_Declaration
=>
6592 -- The case we want to test for here is an identifier that is
6593 -- a per-object expression, this is either a discriminant that
6594 -- appears in a context other than the component declaration
6595 -- or it is a reference to the type of the enclosing construct.
6597 -- For either of these cases, we skip the freezing
6599 if not In_Spec_Expression
6600 and then Nkind
(N
) = N_Identifier
6601 and then (Present
(Entity
(N
)))
6603 -- We recognize the discriminant case by just looking for
6604 -- a reference to a discriminant. It can only be one for
6605 -- the enclosing construct. Skip freezing in this case.
6607 if Ekind
(Entity
(N
)) = E_Discriminant
then
6610 -- For the case of a reference to the enclosing record,
6611 -- (or task or protected type), we look for a type that
6612 -- matches the current scope.
6614 elsif Entity
(N
) = Current_Scope
then
6619 -- If we have an enumeration literal that appears as the choice in
6620 -- the aggregate of an enumeration representation clause, then
6621 -- freezing does not occur (RM 13.14(10)).
6623 when N_Enumeration_Representation_Clause
=>
6625 -- The case we are looking for is an enumeration literal
6627 if (Nkind
(N
) = N_Identifier
or Nkind
(N
) = N_Character_Literal
)
6628 and then Is_Enumeration_Type
(Etype
(N
))
6630 -- If enumeration literal appears directly as the choice,
6631 -- do not freeze (this is the normal non-overloaded case)
6633 if Nkind
(Parent
(N
)) = N_Component_Association
6634 and then First
(Choices
(Parent
(N
))) = N
6638 -- If enumeration literal appears as the name of function
6639 -- which is the choice, then also do not freeze. This
6640 -- happens in the overloaded literal case, where the
6641 -- enumeration literal is temporarily changed to a function
6642 -- call for overloading analysis purposes.
6644 elsif Nkind
(Parent
(N
)) = N_Function_Call
6646 Nkind
(Parent
(Parent
(N
))) = N_Component_Association
6648 First
(Choices
(Parent
(Parent
(N
)))) = Parent
(N
)
6654 -- Normally if the parent is a handled sequence of statements,
6655 -- then the current node must be a statement, and that is an
6656 -- appropriate place to insert a freeze node.
6658 when N_Handled_Sequence_Of_Statements
=>
6660 -- An exception occurs when the sequence of statements is for
6661 -- an expander generated body that did not do the usual freeze
6662 -- all operation. In this case we usually want to freeze
6663 -- outside this body, not inside it, and we skip past the
6664 -- subprogram body that we are inside.
6666 if In_Expanded_Body
(Parent_P
) then
6668 Subp
: constant Node_Id
:= Parent
(Parent_P
);
6672 -- Freeze the entity only when it is declared inside the
6673 -- body of the expander generated procedure. This case
6674 -- is recognized by the scope of the entity or its type,
6675 -- which is either the spec for some enclosing body, or
6676 -- (in the case of init_procs, for which there are no
6677 -- separate specs) the current scope.
6679 if Nkind
(Subp
) = N_Subprogram_Body
then
6680 Spec
:= Corresponding_Spec
(Subp
);
6682 if (Present
(Typ
) and then Scope
(Typ
) = Spec
)
6684 (Present
(Nam
) and then Scope
(Nam
) = Spec
)
6689 and then Scope
(Typ
) = Current_Scope
6690 and then Defining_Entity
(Subp
) = Current_Scope
6696 -- An expression function may act as a completion of
6697 -- a function declaration. As such, it can reference
6698 -- entities declared between the two views:
6701 -- function F return ...;
6703 -- function Hidden return ...;
6704 -- function F return ... is (Hidden); -- 2
6706 -- Refering to the example above, freezing the expression
6707 -- of F (2) would place Hidden's freeze node (1) in the
6708 -- wrong place. Avoid explicit freezing and let the usual
6709 -- scenarios do the job - for example, reaching the end
6710 -- of the private declarations, or a call to F.
6712 if Nkind
(Original_Node
(Subp
)) =
6713 N_Expression_Function
6717 -- Freeze outside the body
6720 Parent_P
:= Parent
(Parent_P
);
6721 Freeze_Outside
:= True;
6725 -- Here if normal case where we are in handled statement
6726 -- sequence and want to do the insertion right there.
6732 -- If parent is a body or a spec or a block, then the current node
6733 -- is a statement or declaration and we can insert the freeze node
6736 when N_Block_Statement |
6739 N_Package_Specification |
6742 N_Task_Body
=> exit;
6744 -- The expander is allowed to define types in any statements list,
6745 -- so any of the following parent nodes also mark a freezing point
6746 -- if the actual node is in a list of statements or declarations.
6748 when N_Abortable_Part |
6749 N_Accept_Alternative |
6751 N_Case_Statement_Alternative |
6752 N_Compilation_Unit_Aux |
6753 N_Conditional_Entry_Call |
6754 N_Delay_Alternative |
6756 N_Entry_Call_Alternative |
6757 N_Exception_Handler |
6758 N_Extended_Return_Statement |
6762 N_Selective_Accept |
6763 N_Triggering_Alternative
=>
6765 exit when Is_List_Member
(P
);
6767 -- Freeze nodes produced by an expression coming from the Actions
6768 -- list of a N_Expression_With_Actions node must remain within the
6769 -- Actions list. Inserting the freeze nodes further up the tree
6770 -- may lead to use before declaration issues in the case of array
6773 when N_Expression_With_Actions
=>
6774 if Is_List_Member
(P
)
6775 and then List_Containing
(P
) = Actions
(Parent_P
)
6780 -- Note: N_Loop_Statement is a special case. A type that appears
6781 -- in the source can never be frozen in a loop (this occurs only
6782 -- because of a loop expanded by the expander), so we keep on
6783 -- going. Otherwise we terminate the search. Same is true of any
6784 -- entity which comes from source. (if they have predefined type,
6785 -- that type does not appear to come from source, but the entity
6786 -- should not be frozen here).
6788 when N_Loop_Statement
=>
6789 exit when not Comes_From_Source
(Etype
(N
))
6790 and then (No
(Nam
) or else not Comes_From_Source
(Nam
));
6792 -- For all other cases, keep looking at parents
6798 -- We fall through the case if we did not yet find the proper
6799 -- place in the free for inserting the freeze node, so climb.
6804 -- If the expression appears in a record or an initialization procedure,
6805 -- the freeze nodes are collected and attached to the current scope, to
6806 -- be inserted and analyzed on exit from the scope, to insure that
6807 -- generated entities appear in the correct scope. If the expression is
6808 -- a default for a discriminant specification, the scope is still void.
6809 -- The expression can also appear in the discriminant part of a private
6810 -- or concurrent type.
6812 -- If the expression appears in a constrained subcomponent of an
6813 -- enclosing record declaration, the freeze nodes must be attached to
6814 -- the outer record type so they can eventually be placed in the
6815 -- enclosing declaration list.
6817 -- The other case requiring this special handling is if we are in a
6818 -- default expression, since in that case we are about to freeze a
6819 -- static type, and the freeze scope needs to be the outer scope, not
6820 -- the scope of the subprogram with the default parameter.
6822 -- For default expressions and other spec expressions in generic units,
6823 -- the Move_Freeze_Nodes mechanism (see sem_ch12.adb) takes care of
6824 -- placing them at the proper place, after the generic unit.
6826 if (In_Spec_Exp
and not Inside_A_Generic
)
6827 or else Freeze_Outside
6828 or else (Is_Type
(Current_Scope
)
6829 and then (not Is_Concurrent_Type
(Current_Scope
)
6830 or else not Has_Completion
(Current_Scope
)))
6831 or else Ekind
(Current_Scope
) = E_Void
6834 N
: constant Node_Id
:= Current_Scope
;
6835 Freeze_Nodes
: List_Id
:= No_List
;
6836 Pos
: Int
:= Scope_Stack
.Last
;
6839 if Present
(Desig_Typ
) then
6840 Freeze_And_Append
(Desig_Typ
, N
, Freeze_Nodes
);
6843 if Present
(Typ
) then
6844 Freeze_And_Append
(Typ
, N
, Freeze_Nodes
);
6847 if Present
(Nam
) then
6848 Freeze_And_Append
(Nam
, N
, Freeze_Nodes
);
6851 -- The current scope may be that of a constrained component of
6852 -- an enclosing record declaration, or of a loop of an enclosing
6853 -- quantified expression, which is above the current scope in the
6854 -- scope stack. Indeed in the context of a quantified expression,
6855 -- a scope is created and pushed above the current scope in order
6856 -- to emulate the loop-like behavior of the quantified expression.
6857 -- If the expression is within a top-level pragma, as for a pre-
6858 -- condition on a library-level subprogram, nothing to do.
6860 if not Is_Compilation_Unit
(Current_Scope
)
6861 and then (Is_Record_Type
(Scope
(Current_Scope
))
6862 or else Nkind
(Parent
(Current_Scope
)) =
6863 N_Quantified_Expression
)
6868 if Is_Non_Empty_List
(Freeze_Nodes
) then
6869 if No
(Scope_Stack
.Table
(Pos
).Pending_Freeze_Actions
) then
6870 Scope_Stack
.Table
(Pos
).Pending_Freeze_Actions
:=
6873 Append_List
(Freeze_Nodes
,
6874 Scope_Stack
.Table
(Pos
).Pending_Freeze_Actions
);
6882 -- Now we have the right place to do the freezing. First, a special
6883 -- adjustment, if we are in spec-expression analysis mode, these freeze
6884 -- actions must not be thrown away (normally all inserted actions are
6885 -- thrown away in this mode. However, the freeze actions are from static
6886 -- expressions and one of the important reasons we are doing this
6887 -- special analysis is to get these freeze actions. Therefore we turn
6888 -- off the In_Spec_Expression mode to propagate these freeze actions.
6889 -- This also means they get properly analyzed and expanded.
6891 In_Spec_Expression
:= False;
6893 -- Freeze the designated type of an allocator (RM 13.14(13))
6895 if Present
(Desig_Typ
) then
6896 Freeze_Before
(P
, Desig_Typ
);
6899 -- Freeze type of expression (RM 13.14(10)). Note that we took care of
6900 -- the enumeration representation clause exception in the loop above.
6902 if Present
(Typ
) then
6903 Freeze_Before
(P
, Typ
);
6906 -- Freeze name if one is present (RM 13.14(11))
6908 if Present
(Nam
) then
6909 Freeze_Before
(P
, Nam
);
6912 -- Restore In_Spec_Expression flag
6914 In_Spec_Expression
:= In_Spec_Exp
;
6915 end Freeze_Expression
;
6917 -----------------------------
6918 -- Freeze_Fixed_Point_Type --
6919 -----------------------------
6921 -- Certain fixed-point types and subtypes, including implicit base types
6922 -- and declared first subtypes, have not yet set up a range. This is
6923 -- because the range cannot be set until the Small and Size values are
6924 -- known, and these are not known till the type is frozen.
6926 -- To signal this case, Scalar_Range contains an unanalyzed syntactic range
6927 -- whose bounds are unanalyzed real literals. This routine will recognize
6928 -- this case, and transform this range node into a properly typed range
6929 -- with properly analyzed and resolved values.
6931 procedure Freeze_Fixed_Point_Type
(Typ
: Entity_Id
) is
6932 Rng
: constant Node_Id
:= Scalar_Range
(Typ
);
6933 Lo
: constant Node_Id
:= Low_Bound
(Rng
);
6934 Hi
: constant Node_Id
:= High_Bound
(Rng
);
6935 Btyp
: constant Entity_Id
:= Base_Type
(Typ
);
6936 Brng
: constant Node_Id
:= Scalar_Range
(Btyp
);
6937 BLo
: constant Node_Id
:= Low_Bound
(Brng
);
6938 BHi
: constant Node_Id
:= High_Bound
(Brng
);
6939 Small
: constant Ureal
:= Small_Value
(Typ
);
6946 -- Save original bounds (for shaving tests)
6949 -- Actual size chosen
6951 function Fsize
(Lov
, Hiv
: Ureal
) return Nat
;
6952 -- Returns size of type with given bounds. Also leaves these
6953 -- bounds set as the current bounds of the Typ.
6959 function Fsize
(Lov
, Hiv
: Ureal
) return Nat
is
6961 Set_Realval
(Lo
, Lov
);
6962 Set_Realval
(Hi
, Hiv
);
6963 return Minimum_Size
(Typ
);
6966 -- Start of processing for Freeze_Fixed_Point_Type
6969 -- If Esize of a subtype has not previously been set, set it now
6971 if Unknown_Esize
(Typ
) then
6972 Atype
:= Ancestor_Subtype
(Typ
);
6974 if Present
(Atype
) then
6975 Set_Esize
(Typ
, Esize
(Atype
));
6977 Set_Esize
(Typ
, Esize
(Base_Type
(Typ
)));
6981 -- Immediate return if the range is already analyzed. This means that
6982 -- the range is already set, and does not need to be computed by this
6985 if Analyzed
(Rng
) then
6989 -- Immediate return if either of the bounds raises Constraint_Error
6991 if Raises_Constraint_Error
(Lo
)
6992 or else Raises_Constraint_Error
(Hi
)
6997 Loval
:= Realval
(Lo
);
6998 Hival
:= Realval
(Hi
);
7003 -- Ordinary fixed-point case
7005 if Is_Ordinary_Fixed_Point_Type
(Typ
) then
7007 -- For the ordinary fixed-point case, we are allowed to fudge the
7008 -- end-points up or down by small. Generally we prefer to fudge up,
7009 -- i.e. widen the bounds for non-model numbers so that the end points
7010 -- are included. However there are cases in which this cannot be
7011 -- done, and indeed cases in which we may need to narrow the bounds.
7012 -- The following circuit makes the decision.
7014 -- Note: our terminology here is that Incl_EP means that the bounds
7015 -- are widened by Small if necessary to include the end points, and
7016 -- Excl_EP means that the bounds are narrowed by Small to exclude the
7017 -- end-points if this reduces the size.
7019 -- Note that in the Incl case, all we care about is including the
7020 -- end-points. In the Excl case, we want to narrow the bounds as
7021 -- much as permitted by the RM, to give the smallest possible size.
7024 Loval_Incl_EP
: Ureal
;
7025 Hival_Incl_EP
: Ureal
;
7027 Loval_Excl_EP
: Ureal
;
7028 Hival_Excl_EP
: Ureal
;
7034 First_Subt
: Entity_Id
;
7039 -- First step. Base types are required to be symmetrical. Right
7040 -- now, the base type range is a copy of the first subtype range.
7041 -- This will be corrected before we are done, but right away we
7042 -- need to deal with the case where both bounds are non-negative.
7043 -- In this case, we set the low bound to the negative of the high
7044 -- bound, to make sure that the size is computed to include the
7045 -- required sign. Note that we do not need to worry about the
7046 -- case of both bounds negative, because the sign will be dealt
7047 -- with anyway. Furthermore we can't just go making such a bound
7048 -- symmetrical, since in a twos-complement system, there is an
7049 -- extra negative value which could not be accommodated on the
7053 and then not UR_Is_Negative
(Loval
)
7054 and then Hival
> Loval
7057 Set_Realval
(Lo
, Loval
);
7060 -- Compute the fudged bounds. If the number is a model number,
7061 -- then we do nothing to include it, but we are allowed to backoff
7062 -- to the next adjacent model number when we exclude it. If it is
7063 -- not a model number then we straddle the two values with the
7064 -- model numbers on either side.
7066 Model_Num
:= UR_Trunc
(Loval
/ Small
) * Small
;
7068 if Loval
= Model_Num
then
7069 Loval_Incl_EP
:= Model_Num
;
7071 Loval_Incl_EP
:= Model_Num
- Small
;
7074 -- The low value excluding the end point is Small greater, but
7075 -- we do not do this exclusion if the low value is positive,
7076 -- since it can't help the size and could actually hurt by
7077 -- crossing the high bound.
7079 if UR_Is_Negative
(Loval_Incl_EP
) then
7080 Loval_Excl_EP
:= Loval_Incl_EP
+ Small
;
7082 -- If the value went from negative to zero, then we have the
7083 -- case where Loval_Incl_EP is the model number just below
7084 -- zero, so we want to stick to the negative value for the
7085 -- base type to maintain the condition that the size will
7086 -- include signed values.
7089 and then UR_Is_Zero
(Loval_Excl_EP
)
7091 Loval_Excl_EP
:= Loval_Incl_EP
;
7095 Loval_Excl_EP
:= Loval_Incl_EP
;
7098 -- Similar processing for upper bound and high value
7100 Model_Num
:= UR_Trunc
(Hival
/ Small
) * Small
;
7102 if Hival
= Model_Num
then
7103 Hival_Incl_EP
:= Model_Num
;
7105 Hival_Incl_EP
:= Model_Num
+ Small
;
7108 if UR_Is_Positive
(Hival_Incl_EP
) then
7109 Hival_Excl_EP
:= Hival_Incl_EP
- Small
;
7111 Hival_Excl_EP
:= Hival_Incl_EP
;
7114 -- One further adjustment is needed. In the case of subtypes, we
7115 -- cannot go outside the range of the base type, or we get
7116 -- peculiarities, and the base type range is already set. This
7117 -- only applies to the Incl values, since clearly the Excl values
7118 -- are already as restricted as they are allowed to be.
7121 Loval_Incl_EP
:= UR_Max
(Loval_Incl_EP
, Realval
(BLo
));
7122 Hival_Incl_EP
:= UR_Min
(Hival_Incl_EP
, Realval
(BHi
));
7125 -- Get size including and excluding end points
7127 Size_Incl_EP
:= Fsize
(Loval_Incl_EP
, Hival_Incl_EP
);
7128 Size_Excl_EP
:= Fsize
(Loval_Excl_EP
, Hival_Excl_EP
);
7130 -- No need to exclude end-points if it does not reduce size
7132 if Fsize
(Loval_Incl_EP
, Hival_Excl_EP
) = Size_Excl_EP
then
7133 Loval_Excl_EP
:= Loval_Incl_EP
;
7136 if Fsize
(Loval_Excl_EP
, Hival_Incl_EP
) = Size_Excl_EP
then
7137 Hival_Excl_EP
:= Hival_Incl_EP
;
7140 -- Now we set the actual size to be used. We want to use the
7141 -- bounds fudged up to include the end-points but only if this
7142 -- can be done without violating a specifically given size
7143 -- size clause or causing an unacceptable increase in size.
7145 -- Case of size clause given
7147 if Has_Size_Clause
(Typ
) then
7149 -- Use the inclusive size only if it is consistent with
7150 -- the explicitly specified size.
7152 if Size_Incl_EP
<= RM_Size
(Typ
) then
7153 Actual_Lo
:= Loval_Incl_EP
;
7154 Actual_Hi
:= Hival_Incl_EP
;
7155 Actual_Size
:= Size_Incl_EP
;
7157 -- If the inclusive size is too large, we try excluding
7158 -- the end-points (will be caught later if does not work).
7161 Actual_Lo
:= Loval_Excl_EP
;
7162 Actual_Hi
:= Hival_Excl_EP
;
7163 Actual_Size
:= Size_Excl_EP
;
7166 -- Case of size clause not given
7169 -- If we have a base type whose corresponding first subtype
7170 -- has an explicit size that is large enough to include our
7171 -- end-points, then do so. There is no point in working hard
7172 -- to get a base type whose size is smaller than the specified
7173 -- size of the first subtype.
7175 First_Subt
:= First_Subtype
(Typ
);
7177 if Has_Size_Clause
(First_Subt
)
7178 and then Size_Incl_EP
<= Esize
(First_Subt
)
7180 Actual_Size
:= Size_Incl_EP
;
7181 Actual_Lo
:= Loval_Incl_EP
;
7182 Actual_Hi
:= Hival_Incl_EP
;
7184 -- If excluding the end-points makes the size smaller and
7185 -- results in a size of 8,16,32,64, then we take the smaller
7186 -- size. For the 64 case, this is compulsory. For the other
7187 -- cases, it seems reasonable. We like to include end points
7188 -- if we can, but not at the expense of moving to the next
7189 -- natural boundary of size.
7191 elsif Size_Incl_EP
/= Size_Excl_EP
7192 and then Addressable
(Size_Excl_EP
)
7194 Actual_Size
:= Size_Excl_EP
;
7195 Actual_Lo
:= Loval_Excl_EP
;
7196 Actual_Hi
:= Hival_Excl_EP
;
7198 -- Otherwise we can definitely include the end points
7201 Actual_Size
:= Size_Incl_EP
;
7202 Actual_Lo
:= Loval_Incl_EP
;
7203 Actual_Hi
:= Hival_Incl_EP
;
7206 -- One pathological case: normally we never fudge a low bound
7207 -- down, since it would seem to increase the size (if it has
7208 -- any effect), but for ranges containing single value, or no
7209 -- values, the high bound can be small too large. Consider:
7211 -- type t is delta 2.0**(-14)
7212 -- range 131072.0 .. 0;
7214 -- That lower bound is *just* outside the range of 32 bits, and
7215 -- does need fudging down in this case. Note that the bounds
7216 -- will always have crossed here, since the high bound will be
7217 -- fudged down if necessary, as in the case of:
7219 -- type t is delta 2.0**(-14)
7220 -- range 131072.0 .. 131072.0;
7222 -- So we detect the situation by looking for crossed bounds,
7223 -- and if the bounds are crossed, and the low bound is greater
7224 -- than zero, we will always back it off by small, since this
7225 -- is completely harmless.
7227 if Actual_Lo
> Actual_Hi
then
7228 if UR_Is_Positive
(Actual_Lo
) then
7229 Actual_Lo
:= Loval_Incl_EP
- Small
;
7230 Actual_Size
:= Fsize
(Actual_Lo
, Actual_Hi
);
7232 -- And of course, we need to do exactly the same parallel
7233 -- fudge for flat ranges in the negative region.
7235 elsif UR_Is_Negative
(Actual_Hi
) then
7236 Actual_Hi
:= Hival_Incl_EP
+ Small
;
7237 Actual_Size
:= Fsize
(Actual_Lo
, Actual_Hi
);
7242 Set_Realval
(Lo
, Actual_Lo
);
7243 Set_Realval
(Hi
, Actual_Hi
);
7246 -- For the decimal case, none of this fudging is required, since there
7247 -- are no end-point problems in the decimal case (the end-points are
7248 -- always included).
7251 Actual_Size
:= Fsize
(Loval
, Hival
);
7254 -- At this stage, the actual size has been calculated and the proper
7255 -- required bounds are stored in the low and high bounds.
7257 if Actual_Size
> 64 then
7258 Error_Msg_Uint_1
:= UI_From_Int
(Actual_Size
);
7260 ("size required (^) for type& too large, maximum allowed is 64",
7265 -- Check size against explicit given size
7267 if Has_Size_Clause
(Typ
) then
7268 if Actual_Size
> RM_Size
(Typ
) then
7269 Error_Msg_Uint_1
:= RM_Size
(Typ
);
7270 Error_Msg_Uint_2
:= UI_From_Int
(Actual_Size
);
7272 ("size given (^) for type& too small, minimum allowed is ^",
7273 Size_Clause
(Typ
), Typ
);
7276 Actual_Size
:= UI_To_Int
(Esize
(Typ
));
7279 -- Increase size to next natural boundary if no size clause given
7282 if Actual_Size
<= 8 then
7284 elsif Actual_Size
<= 16 then
7286 elsif Actual_Size
<= 32 then
7292 Init_Esize
(Typ
, Actual_Size
);
7293 Adjust_Esize_For_Alignment
(Typ
);
7296 -- If we have a base type, then expand the bounds so that they extend to
7297 -- the full width of the allocated size in bits, to avoid junk range
7298 -- checks on intermediate computations.
7300 if Base_Type
(Typ
) = Typ
then
7301 Set_Realval
(Lo
, -(Small
* (Uint_2
** (Actual_Size
- 1))));
7302 Set_Realval
(Hi
, (Small
* (Uint_2
** (Actual_Size
- 1) - 1)));
7305 -- Final step is to reanalyze the bounds using the proper type
7306 -- and set the Corresponding_Integer_Value fields of the literals.
7308 Set_Etype
(Lo
, Empty
);
7309 Set_Analyzed
(Lo
, False);
7312 -- Resolve with universal fixed if the base type, and the base type if
7313 -- it is a subtype. Note we can't resolve the base type with itself,
7314 -- that would be a reference before definition.
7317 Resolve
(Lo
, Universal_Fixed
);
7322 -- Set corresponding integer value for bound
7324 Set_Corresponding_Integer_Value
7325 (Lo
, UR_To_Uint
(Realval
(Lo
) / Small
));
7327 -- Similar processing for high bound
7329 Set_Etype
(Hi
, Empty
);
7330 Set_Analyzed
(Hi
, False);
7334 Resolve
(Hi
, Universal_Fixed
);
7339 Set_Corresponding_Integer_Value
7340 (Hi
, UR_To_Uint
(Realval
(Hi
) / Small
));
7342 -- Set type of range to correspond to bounds
7344 Set_Etype
(Rng
, Etype
(Lo
));
7346 -- Set Esize to calculated size if not set already
7348 if Unknown_Esize
(Typ
) then
7349 Init_Esize
(Typ
, Actual_Size
);
7352 -- Set RM_Size if not already set. If already set, check value
7355 Minsiz
: constant Uint
:= UI_From_Int
(Minimum_Size
(Typ
));
7358 if RM_Size
(Typ
) /= Uint_0
then
7359 if RM_Size
(Typ
) < Minsiz
then
7360 Error_Msg_Uint_1
:= RM_Size
(Typ
);
7361 Error_Msg_Uint_2
:= Minsiz
;
7363 ("size given (^) for type& too small, minimum allowed is ^",
7364 Size_Clause
(Typ
), Typ
);
7368 Set_RM_Size
(Typ
, Minsiz
);
7372 -- Check for shaving
7374 if Comes_From_Source
(Typ
) then
7375 if Orig_Lo
< Expr_Value_R
(Lo
) then
7377 ("declared low bound of type & is outside type range??", Typ
);
7379 ("\low bound adjusted up by delta (RM 3.5.9(13))??", Typ
);
7382 if Orig_Hi
> Expr_Value_R
(Hi
) then
7384 ("declared high bound of type & is outside type range??", Typ
);
7386 ("\high bound adjusted down by delta (RM 3.5.9(13))??", Typ
);
7389 end Freeze_Fixed_Point_Type
;
7395 procedure Freeze_Itype
(T
: Entity_Id
; N
: Node_Id
) is
7399 Set_Has_Delayed_Freeze
(T
);
7400 L
:= Freeze_Entity
(T
, N
);
7402 if Is_Non_Empty_List
(L
) then
7403 Insert_Actions
(N
, L
);
7407 --------------------------
7408 -- Freeze_Static_Object --
7409 --------------------------
7411 procedure Freeze_Static_Object
(E
: Entity_Id
) is
7413 Cannot_Be_Static
: exception;
7414 -- Exception raised if the type of a static object cannot be made
7415 -- static. This happens if the type depends on non-global objects.
7417 procedure Ensure_Expression_Is_SA
(N
: Node_Id
);
7418 -- Called to ensure that an expression used as part of a type definition
7419 -- is statically allocatable, which means that the expression type is
7420 -- statically allocatable, and the expression is either static, or a
7421 -- reference to a library level constant.
7423 procedure Ensure_Type_Is_SA
(Typ
: Entity_Id
);
7424 -- Called to mark a type as static, checking that it is possible
7425 -- to set the type as static. If it is not possible, then the
7426 -- exception Cannot_Be_Static is raised.
7428 -----------------------------
7429 -- Ensure_Expression_Is_SA --
7430 -----------------------------
7432 procedure Ensure_Expression_Is_SA
(N
: Node_Id
) is
7436 Ensure_Type_Is_SA
(Etype
(N
));
7438 if Is_OK_Static_Expression
(N
) then
7441 elsif Nkind
(N
) = N_Identifier
then
7445 and then Ekind
(Ent
) = E_Constant
7446 and then Is_Library_Level_Entity
(Ent
)
7452 raise Cannot_Be_Static
;
7453 end Ensure_Expression_Is_SA
;
7455 -----------------------
7456 -- Ensure_Type_Is_SA --
7457 -----------------------
7459 procedure Ensure_Type_Is_SA
(Typ
: Entity_Id
) is
7464 -- If type is library level, we are all set
7466 if Is_Library_Level_Entity
(Typ
) then
7470 -- We are also OK if the type already marked as statically allocated,
7471 -- which means we processed it before.
7473 if Is_Statically_Allocated
(Typ
) then
7477 -- Mark type as statically allocated
7479 Set_Is_Statically_Allocated
(Typ
);
7481 -- Check that it is safe to statically allocate this type
7483 if Is_Scalar_Type
(Typ
) or else Is_Real_Type
(Typ
) then
7484 Ensure_Expression_Is_SA
(Type_Low_Bound
(Typ
));
7485 Ensure_Expression_Is_SA
(Type_High_Bound
(Typ
));
7487 elsif Is_Array_Type
(Typ
) then
7488 N
:= First_Index
(Typ
);
7489 while Present
(N
) loop
7490 Ensure_Type_Is_SA
(Etype
(N
));
7494 Ensure_Type_Is_SA
(Component_Type
(Typ
));
7496 elsif Is_Access_Type
(Typ
) then
7497 if Ekind
(Designated_Type
(Typ
)) = E_Subprogram_Type
then
7501 T
: constant Entity_Id
:= Etype
(Designated_Type
(Typ
));
7504 if T
/= Standard_Void_Type
then
7505 Ensure_Type_Is_SA
(T
);
7508 F
:= First_Formal
(Designated_Type
(Typ
));
7509 while Present
(F
) loop
7510 Ensure_Type_Is_SA
(Etype
(F
));
7516 Ensure_Type_Is_SA
(Designated_Type
(Typ
));
7519 elsif Is_Record_Type
(Typ
) then
7520 C
:= First_Entity
(Typ
);
7521 while Present
(C
) loop
7522 if Ekind
(C
) = E_Discriminant
7523 or else Ekind
(C
) = E_Component
7525 Ensure_Type_Is_SA
(Etype
(C
));
7527 elsif Is_Type
(C
) then
7528 Ensure_Type_Is_SA
(C
);
7534 elsif Ekind
(Typ
) = E_Subprogram_Type
then
7535 Ensure_Type_Is_SA
(Etype
(Typ
));
7537 C
:= First_Formal
(Typ
);
7538 while Present
(C
) loop
7539 Ensure_Type_Is_SA
(Etype
(C
));
7544 raise Cannot_Be_Static
;
7546 end Ensure_Type_Is_SA
;
7548 -- Start of processing for Freeze_Static_Object
7551 Ensure_Type_Is_SA
(Etype
(E
));
7554 when Cannot_Be_Static
=>
7556 -- If the object that cannot be static is imported or exported, then
7557 -- issue an error message saying that this object cannot be imported
7558 -- or exported. If it has an address clause it is an overlay in the
7559 -- current partition and the static requirement is not relevant.
7560 -- Do not issue any error message when ignoring rep clauses.
7562 if Ignore_Rep_Clauses
then
7565 elsif Is_Imported
(E
) then
7566 if No
(Address_Clause
(E
)) then
7568 ("& cannot be imported (local type is not constant)", E
);
7571 -- Otherwise must be exported, something is wrong if compiler
7572 -- is marking something as statically allocated which cannot be).
7574 else pragma Assert
(Is_Exported
(E
));
7576 ("& cannot be exported (local type is not constant)", E
);
7578 end Freeze_Static_Object
;
7580 -----------------------
7581 -- Freeze_Subprogram --
7582 -----------------------
7584 procedure Freeze_Subprogram
(E
: Entity_Id
) is
7589 -- Subprogram may not have an address clause unless it is imported
7591 if Present
(Address_Clause
(E
)) then
7592 if not Is_Imported
(E
) then
7594 ("address clause can only be given " &
7595 "for imported subprogram",
7596 Name
(Address_Clause
(E
)));
7600 -- Reset the Pure indication on an imported subprogram unless an
7601 -- explicit Pure_Function pragma was present or the subprogram is an
7602 -- intrinsic. We do this because otherwise it is an insidious error
7603 -- to call a non-pure function from pure unit and have calls
7604 -- mysteriously optimized away. What happens here is that the Import
7605 -- can bypass the normal check to ensure that pure units call only pure
7608 -- The reason for the intrinsic exception is that in general, intrinsic
7609 -- functions (such as shifts) are pure anyway. The only exceptions are
7610 -- the intrinsics in GNAT.Source_Info, and that unit is not marked Pure
7611 -- in any case, so no problem arises.
7614 and then Is_Pure
(E
)
7615 and then not Has_Pragma_Pure_Function
(E
)
7616 and then not Is_Intrinsic_Subprogram
(E
)
7618 Set_Is_Pure
(E
, False);
7621 -- For non-foreign convention subprograms, this is where we create
7622 -- the extra formals (for accessibility level and constrained bit
7623 -- information). We delay this till the freeze point precisely so
7624 -- that we know the convention.
7626 if not Has_Foreign_Convention
(E
) then
7627 Create_Extra_Formals
(E
);
7630 -- If this is convention Ada and a Valued_Procedure, that's odd
7632 if Ekind
(E
) = E_Procedure
7633 and then Is_Valued_Procedure
(E
)
7634 and then Convention
(E
) = Convention_Ada
7635 and then Warn_On_Export_Import
7638 ("??Valued_Procedure has no effect for convention Ada", E
);
7639 Set_Is_Valued_Procedure
(E
, False);
7642 -- Case of foreign convention
7647 -- For foreign conventions, warn about return of unconstrained array
7649 if Ekind
(E
) = E_Function
then
7650 Retype
:= Underlying_Type
(Etype
(E
));
7652 -- If no return type, probably some other error, e.g. a
7653 -- missing full declaration, so ignore.
7658 -- If the return type is generic, we have emitted a warning
7659 -- earlier on, and there is nothing else to check here. Specific
7660 -- instantiations may lead to erroneous behavior.
7662 elsif Is_Generic_Type
(Etype
(E
)) then
7665 -- Display warning if returning unconstrained array
7667 elsif Is_Array_Type
(Retype
)
7668 and then not Is_Constrained
(Retype
)
7670 -- Check appropriate warning is enabled (should we check for
7671 -- Warnings (Off) on specific entities here, probably so???)
7673 and then Warn_On_Export_Import
7675 -- Exclude the VM case, since return of unconstrained arrays
7676 -- is properly handled in both the JVM and .NET cases.
7678 and then VM_Target
= No_VM
7681 ("?x?foreign convention function& should not return " &
7682 "unconstrained array", E
);
7687 -- If any of the formals for an exported foreign convention
7688 -- subprogram have defaults, then emit an appropriate warning since
7689 -- this is odd (default cannot be used from non-Ada code)
7691 if Is_Exported
(E
) then
7692 F
:= First_Formal
(E
);
7693 while Present
(F
) loop
7694 if Warn_On_Export_Import
7695 and then Present
(Default_Value
(F
))
7698 ("?x?parameter cannot be defaulted in non-Ada call",
7707 -- Pragma Inline_Always is disallowed for dispatching subprograms
7708 -- because the address of such subprograms is saved in the dispatch
7709 -- table to support dispatching calls, and dispatching calls cannot
7710 -- be inlined. This is consistent with the restriction against using
7711 -- 'Access or 'Address on an Inline_Always subprogram.
7713 if Is_Dispatching_Operation
(E
)
7714 and then Has_Pragma_Inline_Always
(E
)
7717 ("pragma Inline_Always not allowed for dispatching subprograms", E
);
7720 -- Because of the implicit representation of inherited predefined
7721 -- operators in the front-end, the overriding status of the operation
7722 -- may be affected when a full view of a type is analyzed, and this is
7723 -- not captured by the analysis of the corresponding type declaration.
7724 -- Therefore the correctness of a not-overriding indicator must be
7725 -- rechecked when the subprogram is frozen.
7727 if Nkind
(E
) = N_Defining_Operator_Symbol
7728 and then not Error_Posted
(Parent
(E
))
7730 Check_Overriding_Indicator
(E
, Empty
, Is_Primitive
(E
));
7732 end Freeze_Subprogram
;
7734 ----------------------
7735 -- Is_Fully_Defined --
7736 ----------------------
7738 function Is_Fully_Defined
(T
: Entity_Id
) return Boolean is
7740 if Ekind
(T
) = E_Class_Wide_Type
then
7741 return Is_Fully_Defined
(Etype
(T
));
7743 elsif Is_Array_Type
(T
) then
7744 return Is_Fully_Defined
(Component_Type
(T
));
7746 elsif Is_Record_Type
(T
)
7747 and not Is_Private_Type
(T
)
7749 -- Verify that the record type has no components with private types
7750 -- without completion.
7756 Comp
:= First_Component
(T
);
7757 while Present
(Comp
) loop
7758 if not Is_Fully_Defined
(Etype
(Comp
)) then
7762 Next_Component
(Comp
);
7767 -- For the designated type of an access to subprogram, all types in
7768 -- the profile must be fully defined.
7770 elsif Ekind
(T
) = E_Subprogram_Type
then
7775 F
:= First_Formal
(T
);
7776 while Present
(F
) loop
7777 if not Is_Fully_Defined
(Etype
(F
)) then
7784 return Is_Fully_Defined
(Etype
(T
));
7788 return not Is_Private_Type
(T
)
7789 or else Present
(Full_View
(Base_Type
(T
)));
7791 end Is_Fully_Defined
;
7793 ---------------------------------
7794 -- Process_Default_Expressions --
7795 ---------------------------------
7797 procedure Process_Default_Expressions
7799 After
: in out Node_Id
)
7801 Loc
: constant Source_Ptr
:= Sloc
(E
);
7808 Set_Default_Expressions_Processed
(E
);
7810 -- A subprogram instance and its associated anonymous subprogram share
7811 -- their signature. The default expression functions are defined in the
7812 -- wrapper packages for the anonymous subprogram, and should not be
7813 -- generated again for the instance.
7815 if Is_Generic_Instance
(E
)
7816 and then Present
(Alias
(E
))
7817 and then Default_Expressions_Processed
(Alias
(E
))
7822 Formal
:= First_Formal
(E
);
7823 while Present
(Formal
) loop
7824 if Present
(Default_Value
(Formal
)) then
7826 -- We work with a copy of the default expression because we
7827 -- do not want to disturb the original, since this would mess
7828 -- up the conformance checking.
7830 Dcopy
:= New_Copy_Tree
(Default_Value
(Formal
));
7832 -- The analysis of the expression may generate insert actions,
7833 -- which of course must not be executed. We wrap those actions
7834 -- in a procedure that is not called, and later on eliminated.
7835 -- The following cases have no side-effects, and are analyzed
7838 if Nkind
(Dcopy
) = N_Identifier
7839 or else Nkind_In
(Dcopy
, N_Expanded_Name
,
7841 N_Character_Literal
,
7844 or else (Nkind
(Dcopy
) = N_Attribute_Reference
7845 and then Attribute_Name
(Dcopy
) = Name_Null_Parameter
)
7846 or else Known_Null
(Dcopy
)
7848 -- If there is no default function, we must still do a full
7849 -- analyze call on the default value, to ensure that all error
7850 -- checks are performed, e.g. those associated with static
7851 -- evaluation. Note: this branch will always be taken if the
7852 -- analyzer is turned off (but we still need the error checks).
7854 -- Note: the setting of parent here is to meet the requirement
7855 -- that we can only analyze the expression while attached to
7856 -- the tree. Really the requirement is that the parent chain
7857 -- be set, we don't actually need to be in the tree.
7859 Set_Parent
(Dcopy
, Declaration_Node
(Formal
));
7862 -- Default expressions are resolved with their own type if the
7863 -- context is generic, to avoid anomalies with private types.
7865 if Ekind
(Scope
(E
)) = E_Generic_Package
then
7868 Resolve
(Dcopy
, Etype
(Formal
));
7871 -- If that resolved expression will raise constraint error,
7872 -- then flag the default value as raising constraint error.
7873 -- This allows a proper error message on the calls.
7875 if Raises_Constraint_Error
(Dcopy
) then
7876 Set_Raises_Constraint_Error
(Default_Value
(Formal
));
7879 -- If the default is a parameterless call, we use the name of
7880 -- the called function directly, and there is no body to build.
7882 elsif Nkind
(Dcopy
) = N_Function_Call
7883 and then No
(Parameter_Associations
(Dcopy
))
7887 -- Else construct and analyze the body of a wrapper procedure
7888 -- that contains an object declaration to hold the expression.
7889 -- Given that this is done only to complete the analysis, it
7890 -- simpler to build a procedure than a function which might
7891 -- involve secondary stack expansion.
7894 Dnam
:= Make_Temporary
(Loc
, 'D');
7897 Make_Subprogram_Body
(Loc
,
7899 Make_Procedure_Specification
(Loc
,
7900 Defining_Unit_Name
=> Dnam
),
7902 Declarations
=> New_List
(
7903 Make_Object_Declaration
(Loc
,
7904 Defining_Identifier
=> Make_Temporary
(Loc
, 'T'),
7905 Object_Definition
=>
7906 New_Occurrence_Of
(Etype
(Formal
), Loc
),
7907 Expression
=> New_Copy_Tree
(Dcopy
))),
7909 Handled_Statement_Sequence
=>
7910 Make_Handled_Sequence_Of_Statements
(Loc
,
7911 Statements
=> Empty_List
));
7913 Set_Scope
(Dnam
, Scope
(E
));
7914 Set_Assignment_OK
(First
(Declarations
(Dbody
)));
7915 Set_Is_Eliminated
(Dnam
);
7916 Insert_After
(After
, Dbody
);
7922 Next_Formal
(Formal
);
7924 end Process_Default_Expressions
;
7926 ----------------------------------------
7927 -- Set_Component_Alignment_If_Not_Set --
7928 ----------------------------------------
7930 procedure Set_Component_Alignment_If_Not_Set
(Typ
: Entity_Id
) is
7932 -- Ignore if not base type, subtypes don't need anything
7934 if Typ
/= Base_Type
(Typ
) then
7938 -- Do not override existing representation
7940 if Is_Packed
(Typ
) then
7943 elsif Has_Specified_Layout
(Typ
) then
7946 elsif Component_Alignment
(Typ
) /= Calign_Default
then
7950 Set_Component_Alignment
7951 (Typ
, Scope_Stack
.Table
7952 (Scope_Stack
.Last
).Component_Alignment_Default
);
7954 end Set_Component_Alignment_If_Not_Set
;
7956 --------------------------
7957 -- Set_SSO_From_Default --
7958 --------------------------
7960 procedure Set_SSO_From_Default
(T
: Entity_Id
) is
7964 -- Set default SSO for an array or record base type, except in case of
7965 -- a type extension (which always inherits the SSO of its parent type).
7968 and then (Is_Array_Type
(T
)
7969 or else (Is_Record_Type
(T
)
7970 and then not (Is_Tagged_Type
(T
)
7971 and then Is_Derived_Type
(T
))))
7974 (Bytes_Big_Endian
and then SSO_Set_Low_By_Default
(T
))
7976 (not Bytes_Big_Endian
and then SSO_Set_High_By_Default
(T
));
7978 if (SSO_Set_Low_By_Default
(T
) or else SSO_Set_High_By_Default
(T
))
7980 -- For a record type, if bit order is specified explicitly,
7981 -- then do not set SSO from default if not consistent. Note that
7982 -- we do not want to look at a Bit_Order attribute definition
7983 -- for a parent: if we were to inherit Bit_Order, then both
7984 -- SSO_Set_*_By_Default flags would have been cleared already
7985 -- (by Inherit_Aspects_At_Freeze_Point).
7990 Has_Rep_Item
(T
, Name_Bit_Order
, Check_Parents
=> False)
7991 and then Reverse_Bit_Order
(T
) /= Reversed
)
7993 -- If flags cause reverse storage order, then set the result. Note
7994 -- that we would have ignored the pragma setting the non default
7995 -- storage order in any case, hence the assertion at this point.
7998 (not Reversed
or else Support_Nondefault_SSO_On_Target
);
8000 Set_Reverse_Storage_Order
(T
, Reversed
);
8002 -- For a record type, also set reversed bit order. Note: if a bit
8003 -- order has been specified explicitly, then this is a no-op.
8005 if Is_Record_Type
(T
) then
8006 Set_Reverse_Bit_Order
(T
, Reversed
);
8010 end Set_SSO_From_Default
;
8016 procedure Undelay_Type
(T
: Entity_Id
) is
8018 Set_Has_Delayed_Freeze
(T
, False);
8019 Set_Freeze_Node
(T
, Empty
);
8021 -- Since we don't want T to have a Freeze_Node, we don't want its
8022 -- Full_View or Corresponding_Record_Type to have one either.
8024 -- ??? Fundamentally, this whole handling is unpleasant. What we really
8025 -- want is to be sure that for an Itype that's part of record R and is a
8026 -- subtype of type T, that it's frozen after the later of the freeze
8027 -- points of R and T. We have no way of doing that directly, so what we
8028 -- do is force most such Itypes to be frozen as part of freezing R via
8029 -- this procedure and only delay the ones that need to be delayed
8030 -- (mostly the designated types of access types that are defined as part
8033 if Is_Private_Type
(T
)
8034 and then Present
(Full_View
(T
))
8035 and then Is_Itype
(Full_View
(T
))
8036 and then Is_Record_Type
(Scope
(Full_View
(T
)))
8038 Undelay_Type
(Full_View
(T
));
8041 if Is_Concurrent_Type
(T
)
8042 and then Present
(Corresponding_Record_Type
(T
))
8043 and then Is_Itype
(Corresponding_Record_Type
(T
))
8044 and then Is_Record_Type
(Scope
(Corresponding_Record_Type
(T
)))
8046 Undelay_Type
(Corresponding_Record_Type
(T
));
8054 procedure Warn_Overlay
8059 Ent
: constant Entity_Id
:= Entity
(Nam
);
8060 -- The object to which the address clause applies
8063 Old
: Entity_Id
:= Empty
;
8067 -- No warning if address clause overlay warnings are off
8069 if not Address_Clause_Overlay_Warnings
then
8073 -- No warning if there is an explicit initialization
8075 Init
:= Original_Node
(Expression
(Declaration_Node
(Ent
)));
8077 if Present
(Init
) and then Comes_From_Source
(Init
) then
8081 -- We only give the warning for non-imported entities of a type for
8082 -- which a non-null base init proc is defined, or for objects of access
8083 -- types with implicit null initialization, or when Normalize_Scalars
8084 -- applies and the type is scalar or a string type (the latter being
8085 -- tested for because predefined String types are initialized by inline
8086 -- code rather than by an init_proc). Note that we do not give the
8087 -- warning for Initialize_Scalars, since we suppressed initialization
8088 -- in this case. Also, do not warn if Suppress_Initialization is set.
8091 and then not Is_Imported
(Ent
)
8092 and then not Initialization_Suppressed
(Typ
)
8093 and then (Has_Non_Null_Base_Init_Proc
(Typ
)
8094 or else Is_Access_Type
(Typ
)
8095 or else (Normalize_Scalars
8096 and then (Is_Scalar_Type
(Typ
)
8097 or else Is_String_Type
(Typ
))))
8099 if Nkind
(Expr
) = N_Attribute_Reference
8100 and then Is_Entity_Name
(Prefix
(Expr
))
8102 Old
:= Entity
(Prefix
(Expr
));
8104 elsif Is_Entity_Name
(Expr
)
8105 and then Ekind
(Entity
(Expr
)) = E_Constant
8107 Decl
:= Declaration_Node
(Entity
(Expr
));
8109 if Nkind
(Decl
) = N_Object_Declaration
8110 and then Present
(Expression
(Decl
))
8111 and then Nkind
(Expression
(Decl
)) = N_Attribute_Reference
8112 and then Is_Entity_Name
(Prefix
(Expression
(Decl
)))
8114 Old
:= Entity
(Prefix
(Expression
(Decl
)));
8116 elsif Nkind
(Expr
) = N_Function_Call
then
8120 -- A function call (most likely to To_Address) is probably not an
8121 -- overlay, so skip warning. Ditto if the function call was inlined
8122 -- and transformed into an entity.
8124 elsif Nkind
(Original_Node
(Expr
)) = N_Function_Call
then
8128 -- If a pragma Import follows, we assume that it is for the current
8129 -- target of the address clause, and skip the warning. There may be
8130 -- a source pragma or an aspect that specifies import and generates
8131 -- the corresponding pragma. These will indicate that the entity is
8132 -- imported and that is checked above so that the spurious warning
8133 -- (generated when the entity is frozen) will be suppressed. The
8134 -- pragma may be attached to the aspect, so it is not yet a list
8137 if Is_List_Member
(Parent
(Expr
)) then
8138 Decl
:= Next
(Parent
(Expr
));
8141 and then Nkind
(Decl
) = N_Pragma
8142 and then Pragma_Name
(Decl
) = Name_Import
8148 -- Otherwise give warning message
8150 if Present
(Old
) then
8151 Error_Msg_Node_2
:= Old
;
8153 ("default initialization of & may modify &??",
8157 ("default initialization of & may modify overlaid storage??",
8161 -- Add friendly warning if initialization comes from a packed array
8164 if Is_Record_Type
(Typ
) then
8169 Comp
:= First_Component
(Typ
);
8170 while Present
(Comp
) loop
8171 if Nkind
(Parent
(Comp
)) = N_Component_Declaration
8172 and then Present
(Expression
(Parent
(Comp
)))
8175 elsif Is_Array_Type
(Etype
(Comp
))
8176 and then Present
(Packed_Array_Impl_Type
(Etype
(Comp
)))
8179 ("\packed array component& " &
8180 "will be initialized to zero??",
8184 Next_Component
(Comp
);
8191 ("\use pragma Import for & to " &
8192 "suppress initialization (RM B.1(24))??",