2013-05-03 Richard Biener <rguenther@suse.de>
[official-gcc.git] / gcc / ada / sem_type.adb
blob78e49224e590432d6ec9333aafcf665ddb077175
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- S E M _ T Y P E --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1992-2013, Free Software Foundation, Inc. --
10 -- --
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. --
20 -- --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
23 -- --
24 ------------------------------------------------------------------------------
26 with Atree; use Atree;
27 with Alloc;
28 with Debug; use Debug;
29 with Einfo; use Einfo;
30 with Elists; use Elists;
31 with Nlists; use Nlists;
32 with Errout; use Errout;
33 with Lib; use Lib;
34 with Namet; use Namet;
35 with Opt; use Opt;
36 with Output; use Output;
37 with Sem; use Sem;
38 with Sem_Aux; use Sem_Aux;
39 with Sem_Ch6; use Sem_Ch6;
40 with Sem_Ch8; use Sem_Ch8;
41 with Sem_Ch12; use Sem_Ch12;
42 with Sem_Disp; use Sem_Disp;
43 with Sem_Dist; use Sem_Dist;
44 with Sem_Util; use Sem_Util;
45 with Stand; use Stand;
46 with Sinfo; use Sinfo;
47 with Snames; use Snames;
48 with Table;
49 with Treepr; use Treepr;
50 with Uintp; use Uintp;
52 package body Sem_Type is
54 ---------------------
55 -- Data Structures --
56 ---------------------
58 -- The following data structures establish a mapping between nodes and
59 -- their interpretations. An overloaded node has an entry in Interp_Map,
60 -- which in turn contains a pointer into the All_Interp array. The
61 -- interpretations of a given node are contiguous in All_Interp. Each set
62 -- of interpretations is terminated with the marker No_Interp. In order to
63 -- speed up the retrieval of the interpretations of an overloaded node, the
64 -- Interp_Map table is accessed by means of a simple hashing scheme, and
65 -- the entries in Interp_Map are chained. The heads of clash lists are
66 -- stored in array Headers.
68 -- Headers Interp_Map All_Interp
70 -- _ +-----+ +--------+
71 -- |_| |_____| --->|interp1 |
72 -- |_|---------->|node | | |interp2 |
73 -- |_| |index|---------| |nointerp|
74 -- |_| |next | | |
75 -- |-----| | |
76 -- +-----+ +--------+
78 -- This scheme does not currently reclaim interpretations. In principle,
79 -- after a unit is compiled, all overloadings have been resolved, and the
80 -- candidate interpretations should be deleted. This should be easier
81 -- now than with the previous scheme???
83 package All_Interp is new Table.Table (
84 Table_Component_Type => Interp,
85 Table_Index_Type => Interp_Index,
86 Table_Low_Bound => 0,
87 Table_Initial => Alloc.All_Interp_Initial,
88 Table_Increment => Alloc.All_Interp_Increment,
89 Table_Name => "All_Interp");
91 type Interp_Ref is record
92 Node : Node_Id;
93 Index : Interp_Index;
94 Next : Int;
95 end record;
97 Header_Size : constant Int := 2 ** 12;
98 No_Entry : constant Int := -1;
99 Headers : array (0 .. Header_Size) of Int := (others => No_Entry);
101 package Interp_Map is new Table.Table (
102 Table_Component_Type => Interp_Ref,
103 Table_Index_Type => Int,
104 Table_Low_Bound => 0,
105 Table_Initial => Alloc.Interp_Map_Initial,
106 Table_Increment => Alloc.Interp_Map_Increment,
107 Table_Name => "Interp_Map");
109 function Hash (N : Node_Id) return Int;
110 -- A trivial hashing function for nodes, used to insert an overloaded
111 -- node into the Interp_Map table.
113 -------------------------------------
114 -- Handling of Overload Resolution --
115 -------------------------------------
117 -- Overload resolution uses two passes over the syntax tree of a complete
118 -- context. In the first, bottom-up pass, the types of actuals in calls
119 -- are used to resolve possibly overloaded subprogram and operator names.
120 -- In the second top-down pass, the type of the context (for example the
121 -- condition in a while statement) is used to resolve a possibly ambiguous
122 -- call, and the unique subprogram name in turn imposes a specific context
123 -- on each of its actuals.
125 -- Most expressions are in fact unambiguous, and the bottom-up pass is
126 -- sufficient to resolve most everything. To simplify the common case,
127 -- names and expressions carry a flag Is_Overloaded to indicate whether
128 -- they have more than one interpretation. If the flag is off, then each
129 -- name has already a unique meaning and type, and the bottom-up pass is
130 -- sufficient (and much simpler).
132 --------------------------
133 -- Operator Overloading --
134 --------------------------
136 -- The visibility of operators is handled differently from that of other
137 -- entities. We do not introduce explicit versions of primitive operators
138 -- for each type definition. As a result, there is only one entity
139 -- corresponding to predefined addition on all numeric types, etc. The
140 -- back-end resolves predefined operators according to their type. The
141 -- visibility of primitive operations then reduces to the visibility of the
142 -- resulting type: (a + b) is a legal interpretation of some primitive
143 -- operator + if the type of the result (which must also be the type of a
144 -- and b) is directly visible (either immediately visible or use-visible).
146 -- User-defined operators are treated like other functions, but the
147 -- visibility of these user-defined operations must be special-cased
148 -- to determine whether they hide or are hidden by predefined operators.
149 -- The form P."+" (x, y) requires additional handling.
151 -- Concatenation is treated more conventionally: for every one-dimensional
152 -- array type we introduce a explicit concatenation operator. This is
153 -- necessary to handle the case of (element & element => array) which
154 -- cannot be handled conveniently if there is no explicit instance of
155 -- resulting type of the operation.
157 -----------------------
158 -- Local Subprograms --
159 -----------------------
161 procedure All_Overloads;
162 pragma Warnings (Off, All_Overloads);
163 -- Debugging procedure: list full contents of Overloads table
165 function Binary_Op_Interp_Has_Abstract_Op
166 (N : Node_Id;
167 E : Entity_Id) return Entity_Id;
168 -- Given the node and entity of a binary operator, determine whether the
169 -- actuals of E contain an abstract interpretation with regards to the
170 -- types of their corresponding formals. Return the abstract operation or
171 -- Empty.
173 function Function_Interp_Has_Abstract_Op
174 (N : Node_Id;
175 E : Entity_Id) return Entity_Id;
176 -- Given the node and entity of a function call, determine whether the
177 -- actuals of E contain an abstract interpretation with regards to the
178 -- types of their corresponding formals. Return the abstract operation or
179 -- Empty.
181 function Has_Abstract_Op
182 (N : Node_Id;
183 Typ : Entity_Id) return Entity_Id;
184 -- Subsidiary routine to Binary_Op_Interp_Has_Abstract_Op and Function_
185 -- Interp_Has_Abstract_Op. Determine whether an overloaded node has an
186 -- abstract interpretation which yields type Typ.
188 procedure New_Interps (N : Node_Id);
189 -- Initialize collection of interpretations for the given node, which is
190 -- either an overloaded entity, or an operation whose arguments have
191 -- multiple interpretations. Interpretations can be added to only one
192 -- node at a time.
194 function Specific_Type (Typ_1, Typ_2 : Entity_Id) return Entity_Id;
195 -- If Typ_1 and Typ_2 are compatible, return the one that is not universal
196 -- or is not a "class" type (any_character, etc).
198 --------------------
199 -- Add_One_Interp --
200 --------------------
202 procedure Add_One_Interp
203 (N : Node_Id;
204 E : Entity_Id;
205 T : Entity_Id;
206 Opnd_Type : Entity_Id := Empty)
208 Vis_Type : Entity_Id;
210 procedure Add_Entry (Name : Entity_Id; Typ : Entity_Id);
211 -- Add one interpretation to an overloaded node. Add a new entry if
212 -- not hidden by previous one, and remove previous one if hidden by
213 -- new one.
215 function Is_Universal_Operation (Op : Entity_Id) return Boolean;
216 -- True if the entity is a predefined operator and the operands have
217 -- a universal Interpretation.
219 ---------------
220 -- Add_Entry --
221 ---------------
223 procedure Add_Entry (Name : Entity_Id; Typ : Entity_Id) is
224 Abstr_Op : Entity_Id := Empty;
225 I : Interp_Index;
226 It : Interp;
228 -- Start of processing for Add_Entry
230 begin
231 -- Find out whether the new entry references interpretations that
232 -- are abstract or disabled by abstract operators.
234 if Ada_Version >= Ada_2005 then
235 if Nkind (N) in N_Binary_Op then
236 Abstr_Op := Binary_Op_Interp_Has_Abstract_Op (N, Name);
237 elsif Nkind (N) = N_Function_Call then
238 Abstr_Op := Function_Interp_Has_Abstract_Op (N, Name);
239 end if;
240 end if;
242 Get_First_Interp (N, I, It);
243 while Present (It.Nam) loop
245 -- A user-defined subprogram hides another declared at an outer
246 -- level, or one that is use-visible. So return if previous
247 -- definition hides new one (which is either in an outer
248 -- scope, or use-visible). Note that for functions use-visible
249 -- is the same as potentially use-visible. If new one hides
250 -- previous one, replace entry in table of interpretations.
251 -- If this is a universal operation, retain the operator in case
252 -- preference rule applies.
254 if (((Ekind (Name) = E_Function or else Ekind (Name) = E_Procedure)
255 and then Ekind (Name) = Ekind (It.Nam))
256 or else (Ekind (Name) = E_Operator
257 and then Ekind (It.Nam) = E_Function))
259 and then Is_Immediately_Visible (It.Nam)
260 and then Type_Conformant (Name, It.Nam)
261 and then Base_Type (It.Typ) = Base_Type (T)
262 then
263 if Is_Universal_Operation (Name) then
264 exit;
266 -- If node is an operator symbol, we have no actuals with
267 -- which to check hiding, and this is done in full in the
268 -- caller (Analyze_Subprogram_Renaming) so we include the
269 -- predefined operator in any case.
271 elsif Nkind (N) = N_Operator_Symbol
272 or else (Nkind (N) = N_Expanded_Name
273 and then
274 Nkind (Selector_Name (N)) = N_Operator_Symbol)
275 then
276 exit;
278 elsif not In_Open_Scopes (Scope (Name))
279 or else Scope_Depth (Scope (Name)) <=
280 Scope_Depth (Scope (It.Nam))
281 then
282 -- If ambiguity within instance, and entity is not an
283 -- implicit operation, save for later disambiguation.
285 if Scope (Name) = Scope (It.Nam)
286 and then not Is_Inherited_Operation (Name)
287 and then In_Instance
288 then
289 exit;
290 else
291 return;
292 end if;
294 else
295 All_Interp.Table (I).Nam := Name;
296 return;
297 end if;
299 -- Avoid making duplicate entries in overloads
301 elsif Name = It.Nam
302 and then Base_Type (It.Typ) = Base_Type (T)
303 then
304 return;
306 -- Otherwise keep going
308 else
309 Get_Next_Interp (I, It);
310 end if;
312 end loop;
314 All_Interp.Table (All_Interp.Last) := (Name, Typ, Abstr_Op);
315 All_Interp.Append (No_Interp);
316 end Add_Entry;
318 ----------------------------
319 -- Is_Universal_Operation --
320 ----------------------------
322 function Is_Universal_Operation (Op : Entity_Id) return Boolean is
323 Arg : Node_Id;
325 begin
326 if Ekind (Op) /= E_Operator then
327 return False;
329 elsif Nkind (N) in N_Binary_Op then
330 return Present (Universal_Interpretation (Left_Opnd (N)))
331 and then Present (Universal_Interpretation (Right_Opnd (N)));
333 elsif Nkind (N) in N_Unary_Op then
334 return Present (Universal_Interpretation (Right_Opnd (N)));
336 elsif Nkind (N) = N_Function_Call then
337 Arg := First_Actual (N);
338 while Present (Arg) loop
339 if No (Universal_Interpretation (Arg)) then
340 return False;
341 end if;
343 Next_Actual (Arg);
344 end loop;
346 return True;
348 else
349 return False;
350 end if;
351 end Is_Universal_Operation;
353 -- Start of processing for Add_One_Interp
355 begin
356 -- If the interpretation is a predefined operator, verify that the
357 -- result type is visible, or that the entity has already been
358 -- resolved (case of an instantiation node that refers to a predefined
359 -- operation, or an internally generated operator node, or an operator
360 -- given as an expanded name). If the operator is a comparison or
361 -- equality, it is the type of the operand that matters to determine
362 -- whether the operator is visible. In an instance, the check is not
363 -- performed, given that the operator was visible in the generic.
365 if Ekind (E) = E_Operator then
366 if Present (Opnd_Type) then
367 Vis_Type := Opnd_Type;
368 else
369 Vis_Type := Base_Type (T);
370 end if;
372 if In_Open_Scopes (Scope (Vis_Type))
373 or else Is_Potentially_Use_Visible (Vis_Type)
374 or else In_Use (Vis_Type)
375 or else (In_Use (Scope (Vis_Type))
376 and then not Is_Hidden (Vis_Type))
377 or else Nkind (N) = N_Expanded_Name
378 or else (Nkind (N) in N_Op and then E = Entity (N))
379 or else In_Instance
380 or else Ekind (Vis_Type) = E_Anonymous_Access_Type
381 then
382 null;
384 -- If the node is given in functional notation and the prefix
385 -- is an expanded name, then the operator is visible if the
386 -- prefix is the scope of the result type as well. If the
387 -- operator is (implicitly) defined in an extension of system,
388 -- it is know to be valid (see Defined_In_Scope, sem_ch4.adb).
390 elsif Nkind (N) = N_Function_Call
391 and then Nkind (Name (N)) = N_Expanded_Name
392 and then (Entity (Prefix (Name (N))) = Scope (Base_Type (T))
393 or else Entity (Prefix (Name (N))) = Scope (Vis_Type)
394 or else Scope (Vis_Type) = System_Aux_Id)
395 then
396 null;
398 -- Save type for subsequent error message, in case no other
399 -- interpretation is found.
401 else
402 Candidate_Type := Vis_Type;
403 return;
404 end if;
406 -- In an instance, an abstract non-dispatching operation cannot be a
407 -- candidate interpretation, because it could not have been one in the
408 -- generic (it may be a spurious overloading in the instance).
410 elsif In_Instance
411 and then Is_Overloadable (E)
412 and then Is_Abstract_Subprogram (E)
413 and then not Is_Dispatching_Operation (E)
414 then
415 return;
417 -- An inherited interface operation that is implemented by some derived
418 -- type does not participate in overload resolution, only the
419 -- implementation operation does.
421 elsif Is_Hidden (E)
422 and then Is_Subprogram (E)
423 and then Present (Interface_Alias (E))
424 then
425 -- Ada 2005 (AI-251): If this primitive operation corresponds with
426 -- an immediate ancestor interface there is no need to add it to the
427 -- list of interpretations. The corresponding aliased primitive is
428 -- also in this list of primitive operations and will be used instead
429 -- because otherwise we have a dummy ambiguity between the two
430 -- subprograms which are in fact the same.
432 if not Is_Ancestor
433 (Find_Dispatching_Type (Interface_Alias (E)),
434 Find_Dispatching_Type (E))
435 then
436 Add_One_Interp (N, Interface_Alias (E), T);
437 end if;
439 return;
441 -- Calling stubs for an RACW operation never participate in resolution,
442 -- they are executed only through dispatching calls.
444 elsif Is_RACW_Stub_Type_Operation (E) then
445 return;
446 end if;
448 -- If this is the first interpretation of N, N has type Any_Type.
449 -- In that case place the new type on the node. If one interpretation
450 -- already exists, indicate that the node is overloaded, and store
451 -- both the previous and the new interpretation in All_Interp. If
452 -- this is a later interpretation, just add it to the set.
454 if Etype (N) = Any_Type then
455 if Is_Type (E) then
456 Set_Etype (N, T);
458 else
459 -- Record both the operator or subprogram name, and its type
461 if Nkind (N) in N_Op or else Is_Entity_Name (N) then
462 Set_Entity (N, E);
463 end if;
465 Set_Etype (N, T);
466 end if;
468 -- Either there is no current interpretation in the table for any
469 -- node or the interpretation that is present is for a different
470 -- node. In both cases add a new interpretation to the table.
472 elsif Interp_Map.Last < 0
473 or else
474 (Interp_Map.Table (Interp_Map.Last).Node /= N
475 and then not Is_Overloaded (N))
476 then
477 New_Interps (N);
479 if (Nkind (N) in N_Op or else Is_Entity_Name (N))
480 and then Present (Entity (N))
481 then
482 Add_Entry (Entity (N), Etype (N));
484 elsif Nkind (N) in N_Subprogram_Call
485 and then Is_Entity_Name (Name (N))
486 then
487 Add_Entry (Entity (Name (N)), Etype (N));
489 -- If this is an indirect call there will be no name associated
490 -- with the previous entry. To make diagnostics clearer, save
491 -- Subprogram_Type of first interpretation, so that the error will
492 -- point to the anonymous access to subprogram, not to the result
493 -- type of the call itself.
495 elsif (Nkind (N)) = N_Function_Call
496 and then Nkind (Name (N)) = N_Explicit_Dereference
497 and then Is_Overloaded (Name (N))
498 then
499 declare
500 It : Interp;
502 Itn : Interp_Index;
503 pragma Warnings (Off, Itn);
505 begin
506 Get_First_Interp (Name (N), Itn, It);
507 Add_Entry (It.Nam, Etype (N));
508 end;
510 else
511 -- Overloaded prefix in indexed or selected component, or call
512 -- whose name is an expression or another call.
514 Add_Entry (Etype (N), Etype (N));
515 end if;
517 Add_Entry (E, T);
519 else
520 Add_Entry (E, T);
521 end if;
522 end Add_One_Interp;
524 -------------------
525 -- All_Overloads --
526 -------------------
528 procedure All_Overloads is
529 begin
530 for J in All_Interp.First .. All_Interp.Last loop
532 if Present (All_Interp.Table (J).Nam) then
533 Write_Entity_Info (All_Interp.Table (J). Nam, " ");
534 else
535 Write_Str ("No Interp");
536 Write_Eol;
537 end if;
539 Write_Str ("=================");
540 Write_Eol;
541 end loop;
542 end All_Overloads;
544 --------------------------------------
545 -- Binary_Op_Interp_Has_Abstract_Op --
546 --------------------------------------
548 function Binary_Op_Interp_Has_Abstract_Op
549 (N : Node_Id;
550 E : Entity_Id) return Entity_Id
552 Abstr_Op : Entity_Id;
553 E_Left : constant Node_Id := First_Formal (E);
554 E_Right : constant Node_Id := Next_Formal (E_Left);
556 begin
557 Abstr_Op := Has_Abstract_Op (Left_Opnd (N), Etype (E_Left));
558 if Present (Abstr_Op) then
559 return Abstr_Op;
560 end if;
562 return Has_Abstract_Op (Right_Opnd (N), Etype (E_Right));
563 end Binary_Op_Interp_Has_Abstract_Op;
565 ---------------------
566 -- Collect_Interps --
567 ---------------------
569 procedure Collect_Interps (N : Node_Id) is
570 Ent : constant Entity_Id := Entity (N);
571 H : Entity_Id;
572 First_Interp : Interp_Index;
574 function Within_Instance (E : Entity_Id) return Boolean;
575 -- Within an instance there can be spurious ambiguities between a local
576 -- entity and one declared outside of the instance. This can only happen
577 -- for subprograms, because otherwise the local entity hides the outer
578 -- one. For an overloadable entity, this predicate determines whether it
579 -- is a candidate within the instance, or must be ignored.
581 ---------------------
582 -- Within_Instance --
583 ---------------------
585 function Within_Instance (E : Entity_Id) return Boolean is
586 Inst : Entity_Id;
587 Scop : Entity_Id;
589 begin
590 if not In_Instance then
591 return False;
592 end if;
594 Inst := Current_Scope;
595 while Present (Inst) and then not Is_Generic_Instance (Inst) loop
596 Inst := Scope (Inst);
597 end loop;
599 Scop := Scope (E);
600 while Present (Scop) and then Scop /= Standard_Standard loop
601 if Scop = Inst then
602 return True;
603 end if;
604 Scop := Scope (Scop);
605 end loop;
607 return False;
608 end Within_Instance;
610 -- Start of processing for Collect_Interps
612 begin
613 New_Interps (N);
615 -- Unconditionally add the entity that was initially matched
617 First_Interp := All_Interp.Last;
618 Add_One_Interp (N, Ent, Etype (N));
620 -- For expanded name, pick up all additional entities from the
621 -- same scope, since these are obviously also visible. Note that
622 -- these are not necessarily contiguous on the homonym chain.
624 if Nkind (N) = N_Expanded_Name then
625 H := Homonym (Ent);
626 while Present (H) loop
627 if Scope (H) = Scope (Entity (N)) then
628 Add_One_Interp (N, H, Etype (H));
629 end if;
631 H := Homonym (H);
632 end loop;
634 -- Case of direct name
636 else
637 -- First, search the homonym chain for directly visible entities
639 H := Current_Entity (Ent);
640 while Present (H) loop
641 exit when (not Is_Overloadable (H))
642 and then Is_Immediately_Visible (H);
644 if Is_Immediately_Visible (H)
645 and then H /= Ent
646 then
647 -- Only add interpretation if not hidden by an inner
648 -- immediately visible one.
650 for J in First_Interp .. All_Interp.Last - 1 loop
652 -- Current homograph is not hidden. Add to overloads
654 if not Is_Immediately_Visible (All_Interp.Table (J).Nam) then
655 exit;
657 -- Homograph is hidden, unless it is a predefined operator
659 elsif Type_Conformant (H, All_Interp.Table (J).Nam) then
661 -- A homograph in the same scope can occur within an
662 -- instantiation, the resulting ambiguity has to be
663 -- resolved later. The homographs may both be local
664 -- functions or actuals, or may be declared at different
665 -- levels within the instance. The renaming of an actual
666 -- within the instance must not be included.
668 if Within_Instance (H)
669 and then H /= Renamed_Entity (Ent)
670 and then not Is_Inherited_Operation (H)
671 then
672 All_Interp.Table (All_Interp.Last) :=
673 (H, Etype (H), Empty);
674 All_Interp.Append (No_Interp);
675 goto Next_Homograph;
677 elsif Scope (H) /= Standard_Standard then
678 goto Next_Homograph;
679 end if;
680 end if;
681 end loop;
683 -- On exit, we know that current homograph is not hidden
685 Add_One_Interp (N, H, Etype (H));
687 if Debug_Flag_E then
688 Write_Str ("Add overloaded interpretation ");
689 Write_Int (Int (H));
690 Write_Eol;
691 end if;
692 end if;
694 <<Next_Homograph>>
695 H := Homonym (H);
696 end loop;
698 -- Scan list of homographs for use-visible entities only
700 H := Current_Entity (Ent);
702 while Present (H) loop
703 if Is_Potentially_Use_Visible (H)
704 and then H /= Ent
705 and then Is_Overloadable (H)
706 then
707 for J in First_Interp .. All_Interp.Last - 1 loop
709 if not Is_Immediately_Visible (All_Interp.Table (J).Nam) then
710 exit;
712 elsif Type_Conformant (H, All_Interp.Table (J).Nam) then
713 goto Next_Use_Homograph;
714 end if;
715 end loop;
717 Add_One_Interp (N, H, Etype (H));
718 end if;
720 <<Next_Use_Homograph>>
721 H := Homonym (H);
722 end loop;
723 end if;
725 if All_Interp.Last = First_Interp + 1 then
727 -- The final interpretation is in fact not overloaded. Note that the
728 -- unique legal interpretation may or may not be the original one,
729 -- so we need to update N's entity and etype now, because once N
730 -- is marked as not overloaded it is also expected to carry the
731 -- proper interpretation.
733 Set_Is_Overloaded (N, False);
734 Set_Entity (N, All_Interp.Table (First_Interp).Nam);
735 Set_Etype (N, All_Interp.Table (First_Interp).Typ);
736 end if;
737 end Collect_Interps;
739 ------------
740 -- Covers --
741 ------------
743 function Covers (T1, T2 : Entity_Id) return Boolean is
744 BT1 : Entity_Id;
745 BT2 : Entity_Id;
747 function Full_View_Covers (Typ1, Typ2 : Entity_Id) return Boolean;
748 -- In an instance the proper view may not always be correct for
749 -- private types, but private and full view are compatible. This
750 -- removes spurious errors from nested instantiations that involve,
751 -- among other things, types derived from private types.
753 function Real_Actual (T : Entity_Id) return Entity_Id;
754 -- If an actual in an inner instance is the formal of an enclosing
755 -- generic, the actual in the enclosing instance is the one that can
756 -- create an accidental ambiguity, and the check on compatibily of
757 -- generic actual types must use this enclosing actual.
759 ----------------------
760 -- Full_View_Covers --
761 ----------------------
763 function Full_View_Covers (Typ1, Typ2 : Entity_Id) return Boolean is
764 begin
765 return
766 Is_Private_Type (Typ1)
767 and then
768 ((Present (Full_View (Typ1))
769 and then Covers (Full_View (Typ1), Typ2))
770 or else Base_Type (Typ1) = Typ2
771 or else Base_Type (Typ2) = Typ1);
772 end Full_View_Covers;
774 -----------------
775 -- Real_Actual --
776 -----------------
778 function Real_Actual (T : Entity_Id) return Entity_Id is
779 Par : constant Node_Id := Parent (T);
780 RA : Entity_Id;
782 begin
783 -- Retrieve parent subtype from subtype declaration for actual
785 if Nkind (Par) = N_Subtype_Declaration
786 and then not Comes_From_Source (Par)
787 and then Is_Entity_Name (Subtype_Indication (Par))
788 then
789 RA := Entity (Subtype_Indication (Par));
791 if Is_Generic_Actual_Type (RA) then
792 return RA;
793 end if;
794 end if;
796 -- Otherwise actual is not the actual of an enclosing instance
798 return T;
799 end Real_Actual;
801 -- Start of processing for Covers
803 begin
804 -- If either operand missing, then this is an error, but ignore it (and
805 -- pretend we have a cover) if errors already detected, since this may
806 -- simply mean we have malformed trees or a semantic error upstream.
808 if No (T1) or else No (T2) then
809 if Total_Errors_Detected /= 0 then
810 return True;
811 else
812 raise Program_Error;
813 end if;
814 end if;
816 -- Trivial case: same types are always compatible
818 if T1 = T2 then
819 return True;
820 end if;
822 -- First check for Standard_Void_Type, which is special. Subsequent
823 -- processing in this routine assumes T1 and T2 are bona fide types;
824 -- Standard_Void_Type is a special entity that has some, but not all,
825 -- properties of types.
827 if (T1 = Standard_Void_Type) /= (T2 = Standard_Void_Type) then
828 return False;
829 end if;
831 BT1 := Base_Type (T1);
832 BT2 := Base_Type (T2);
834 -- Handle underlying view of records with unknown discriminants
835 -- using the original entity that motivated the construction of
836 -- this underlying record view (see Build_Derived_Private_Type).
838 if Is_Underlying_Record_View (BT1) then
839 BT1 := Underlying_Record_View (BT1);
840 end if;
842 if Is_Underlying_Record_View (BT2) then
843 BT2 := Underlying_Record_View (BT2);
844 end if;
846 -- Simplest case: types that have the same base type and are not generic
847 -- actuals are compatible. Generic actuals belong to their class but are
848 -- not compatible with other types of their class, and in particular
849 -- with other generic actuals. They are however compatible with their
850 -- own subtypes, and itypes with the same base are compatible as well.
851 -- Similarly, constrained subtypes obtained from expressions of an
852 -- unconstrained nominal type are compatible with the base type (may
853 -- lead to spurious ambiguities in obscure cases ???)
855 -- Generic actuals require special treatment to avoid spurious ambi-
856 -- guities in an instance, when two formal types are instantiated with
857 -- the same actual, so that different subprograms end up with the same
858 -- signature in the instance. If a generic actual is the actual of an
859 -- enclosing instance, it is that actual that we must compare: generic
860 -- actuals are only incompatible if they appear in the same instance.
862 if BT1 = BT2
863 or else BT1 = T2
864 or else BT2 = T1
865 then
866 if not Is_Generic_Actual_Type (T1)
867 or else
868 not Is_Generic_Actual_Type (T2)
869 then
870 return True;
872 -- Both T1 and T2 are generic actual types
874 else
875 declare
876 RT1 : constant Entity_Id := Real_Actual (T1);
877 RT2 : constant Entity_Id := Real_Actual (T2);
878 begin
879 return RT1 = RT2
880 or else Is_Itype (T1)
881 or else Is_Itype (T2)
882 or else Is_Constr_Subt_For_U_Nominal (T1)
883 or else Is_Constr_Subt_For_U_Nominal (T2)
884 or else Scope (RT1) /= Scope (RT2);
885 end;
886 end if;
888 -- Literals are compatible with types in a given "class"
890 elsif (T2 = Universal_Integer and then Is_Integer_Type (T1))
891 or else (T2 = Universal_Real and then Is_Real_Type (T1))
892 or else (T2 = Universal_Fixed and then Is_Fixed_Point_Type (T1))
893 or else (T2 = Any_Fixed and then Is_Fixed_Point_Type (T1))
894 or else (T2 = Any_String and then Is_String_Type (T1))
895 or else (T2 = Any_Character and then Is_Character_Type (T1))
896 or else (T2 = Any_Access and then Is_Access_Type (T1))
897 then
898 return True;
900 -- The context may be class wide, and a class-wide type is compatible
901 -- with any member of the class.
903 elsif Is_Class_Wide_Type (T1)
904 and then Is_Ancestor (Root_Type (T1), T2)
905 then
906 return True;
908 elsif Is_Class_Wide_Type (T1)
909 and then Is_Class_Wide_Type (T2)
910 and then Base_Type (Etype (T1)) = Base_Type (Etype (T2))
911 then
912 return True;
914 -- Ada 2005 (AI-345): A class-wide abstract interface type covers a
915 -- task_type or protected_type that implements the interface.
917 elsif Ada_Version >= Ada_2005
918 and then Is_Class_Wide_Type (T1)
919 and then Is_Interface (Etype (T1))
920 and then Is_Concurrent_Type (T2)
921 and then Interface_Present_In_Ancestor
922 (Typ => BT2, Iface => Etype (T1))
923 then
924 return True;
926 -- Ada 2005 (AI-251): A class-wide abstract interface type T1 covers an
927 -- object T2 implementing T1.
929 elsif Ada_Version >= Ada_2005
930 and then Is_Class_Wide_Type (T1)
931 and then Is_Interface (Etype (T1))
932 and then Is_Tagged_Type (T2)
933 then
934 if Interface_Present_In_Ancestor (Typ => T2,
935 Iface => Etype (T1))
936 then
937 return True;
938 end if;
940 declare
941 E : Entity_Id;
942 Elmt : Elmt_Id;
944 begin
945 if Is_Concurrent_Type (BT2) then
946 E := Corresponding_Record_Type (BT2);
947 else
948 E := BT2;
949 end if;
951 -- Ada 2005 (AI-251): A class-wide abstract interface type T1
952 -- covers an object T2 that implements a direct derivation of T1.
953 -- Note: test for presence of E is defense against previous error.
955 if No (E) then
956 Check_Error_Detected;
958 elsif Present (Interfaces (E)) then
959 Elmt := First_Elmt (Interfaces (E));
960 while Present (Elmt) loop
961 if Is_Ancestor (Etype (T1), Node (Elmt)) then
962 return True;
963 end if;
965 Next_Elmt (Elmt);
966 end loop;
967 end if;
969 -- We should also check the case in which T1 is an ancestor of
970 -- some implemented interface???
972 return False;
973 end;
975 -- In a dispatching call, the formal is of some specific type, and the
976 -- actual is of the corresponding class-wide type, including a subtype
977 -- of the class-wide type.
979 elsif Is_Class_Wide_Type (T2)
980 and then
981 (Class_Wide_Type (T1) = Class_Wide_Type (T2)
982 or else Base_Type (Root_Type (T2)) = BT1)
983 then
984 return True;
986 -- Some contexts require a class of types rather than a specific type.
987 -- For example, conditions require any boolean type, fixed point
988 -- attributes require some real type, etc. The built-in types Any_XXX
989 -- represent these classes.
991 elsif (T1 = Any_Integer and then Is_Integer_Type (T2))
992 or else (T1 = Any_Boolean and then Is_Boolean_Type (T2))
993 or else (T1 = Any_Real and then Is_Real_Type (T2))
994 or else (T1 = Any_Fixed and then Is_Fixed_Point_Type (T2))
995 or else (T1 = Any_Discrete and then Is_Discrete_Type (T2))
996 then
997 return True;
999 -- An aggregate is compatible with an array or record type
1001 elsif T2 = Any_Composite
1002 and then Is_Aggregate_Type (T1)
1003 then
1004 return True;
1006 -- If the expected type is an anonymous access, the designated type must
1007 -- cover that of the expression. Use the base type for this check: even
1008 -- though access subtypes are rare in sources, they are generated for
1009 -- actuals in instantiations.
1011 elsif Ekind (BT1) = E_Anonymous_Access_Type
1012 and then Is_Access_Type (T2)
1013 and then Covers (Designated_Type (T1), Designated_Type (T2))
1014 then
1015 return True;
1017 -- Ada 2012 (AI05-0149): Allow an anonymous access type in the context
1018 -- of a named general access type. An implicit conversion will be
1019 -- applied. For the resolution, one designated type must cover the
1020 -- other.
1022 elsif Ada_Version >= Ada_2012
1023 and then Ekind (BT1) = E_General_Access_Type
1024 and then Ekind (BT2) = E_Anonymous_Access_Type
1025 and then (Covers (Designated_Type (T1), Designated_Type (T2))
1026 or else Covers (Designated_Type (T2), Designated_Type (T1)))
1027 then
1028 return True;
1030 -- An Access_To_Subprogram is compatible with itself, or with an
1031 -- anonymous type created for an attribute reference Access.
1033 elsif (Ekind (BT1) = E_Access_Subprogram_Type
1034 or else
1035 Ekind (BT1) = E_Access_Protected_Subprogram_Type)
1036 and then Is_Access_Type (T2)
1037 and then (not Comes_From_Source (T1)
1038 or else not Comes_From_Source (T2))
1039 and then (Is_Overloadable (Designated_Type (T2))
1040 or else
1041 Ekind (Designated_Type (T2)) = E_Subprogram_Type)
1042 and then
1043 Type_Conformant (Designated_Type (T1), Designated_Type (T2))
1044 and then
1045 Mode_Conformant (Designated_Type (T1), Designated_Type (T2))
1046 then
1047 return True;
1049 -- Ada 2005 (AI-254): An Anonymous_Access_To_Subprogram is compatible
1050 -- with itself, or with an anonymous type created for an attribute
1051 -- reference Access.
1053 elsif (Ekind (BT1) = E_Anonymous_Access_Subprogram_Type
1054 or else
1055 Ekind (BT1)
1056 = E_Anonymous_Access_Protected_Subprogram_Type)
1057 and then Is_Access_Type (T2)
1058 and then (not Comes_From_Source (T1)
1059 or else not Comes_From_Source (T2))
1060 and then (Is_Overloadable (Designated_Type (T2))
1061 or else
1062 Ekind (Designated_Type (T2)) = E_Subprogram_Type)
1063 and then
1064 Type_Conformant (Designated_Type (T1), Designated_Type (T2))
1065 and then
1066 Mode_Conformant (Designated_Type (T1), Designated_Type (T2))
1067 then
1068 return True;
1070 -- The context can be a remote access type, and the expression the
1071 -- corresponding source type declared in a categorized package, or
1072 -- vice versa.
1074 elsif Is_Record_Type (T1)
1075 and then (Is_Remote_Call_Interface (T1)
1076 or else Is_Remote_Types (T1))
1077 and then Present (Corresponding_Remote_Type (T1))
1078 then
1079 return Covers (Corresponding_Remote_Type (T1), T2);
1081 -- and conversely.
1083 elsif Is_Record_Type (T2)
1084 and then (Is_Remote_Call_Interface (T2)
1085 or else Is_Remote_Types (T2))
1086 and then Present (Corresponding_Remote_Type (T2))
1087 then
1088 return Covers (Corresponding_Remote_Type (T2), T1);
1090 -- Synchronized types are represented at run time by their corresponding
1091 -- record type. During expansion one is replaced with the other, but
1092 -- they are compatible views of the same type.
1094 elsif Is_Record_Type (T1)
1095 and then Is_Concurrent_Type (T2)
1096 and then Present (Corresponding_Record_Type (T2))
1097 then
1098 return Covers (T1, Corresponding_Record_Type (T2));
1100 elsif Is_Concurrent_Type (T1)
1101 and then Present (Corresponding_Record_Type (T1))
1102 and then Is_Record_Type (T2)
1103 then
1104 return Covers (Corresponding_Record_Type (T1), T2);
1106 -- During analysis, an attribute reference 'Access has a special type
1107 -- kind: Access_Attribute_Type, to be replaced eventually with the type
1108 -- imposed by context.
1110 elsif Ekind (T2) = E_Access_Attribute_Type
1111 and then Ekind_In (BT1, E_General_Access_Type, E_Access_Type)
1112 and then Covers (Designated_Type (T1), Designated_Type (T2))
1113 then
1114 -- If the target type is a RACW type while the source is an access
1115 -- attribute type, we are building a RACW that may be exported.
1117 if Is_Remote_Access_To_Class_Wide_Type (BT1) then
1118 Set_Has_RACW (Current_Sem_Unit);
1119 end if;
1121 return True;
1123 -- Ditto for allocators, which eventually resolve to the context type
1125 elsif Ekind (T2) = E_Allocator_Type
1126 and then Is_Access_Type (T1)
1127 then
1128 return Covers (Designated_Type (T1), Designated_Type (T2))
1129 or else
1130 (From_With_Type (Designated_Type (T1))
1131 and then Covers (Designated_Type (T2), Designated_Type (T1)));
1133 -- A boolean operation on integer literals is compatible with modular
1134 -- context.
1136 elsif T2 = Any_Modular
1137 and then Is_Modular_Integer_Type (T1)
1138 then
1139 return True;
1141 -- The actual type may be the result of a previous error
1143 elsif BT2 = Any_Type then
1144 return True;
1146 -- A packed array type covers its corresponding non-packed type. This is
1147 -- not legitimate Ada, but allows the omission of a number of otherwise
1148 -- useless unchecked conversions, and since this can only arise in
1149 -- (known correct) expanded code, no harm is done.
1151 elsif Is_Array_Type (T2)
1152 and then Is_Packed (T2)
1153 and then T1 = Packed_Array_Type (T2)
1154 then
1155 return True;
1157 -- Similarly an array type covers its corresponding packed array type
1159 elsif Is_Array_Type (T1)
1160 and then Is_Packed (T1)
1161 and then T2 = Packed_Array_Type (T1)
1162 then
1163 return True;
1165 -- In instances, or with types exported from instantiations, check
1166 -- whether a partial and a full view match. Verify that types are
1167 -- legal, to prevent cascaded errors.
1169 elsif In_Instance
1170 and then
1171 (Full_View_Covers (T1, T2)
1172 or else Full_View_Covers (T2, T1))
1173 then
1174 return True;
1176 elsif Is_Type (T2)
1177 and then Is_Generic_Actual_Type (T2)
1178 and then Full_View_Covers (T1, T2)
1179 then
1180 return True;
1182 elsif Is_Type (T1)
1183 and then Is_Generic_Actual_Type (T1)
1184 and then Full_View_Covers (T2, T1)
1185 then
1186 return True;
1188 -- In the expansion of inlined bodies, types are compatible if they
1189 -- are structurally equivalent.
1191 elsif In_Inlined_Body
1192 and then (Underlying_Type (T1) = Underlying_Type (T2)
1193 or else (Is_Access_Type (T1)
1194 and then Is_Access_Type (T2)
1195 and then
1196 Designated_Type (T1) = Designated_Type (T2))
1197 or else (T1 = Any_Access
1198 and then Is_Access_Type (Underlying_Type (T2)))
1199 or else (T2 = Any_Composite
1200 and then
1201 Is_Composite_Type (Underlying_Type (T1))))
1202 then
1203 return True;
1205 -- Ada 2005 (AI-50217): Additional branches to make the shadow entity
1206 -- obtained through a limited_with compatible with its real entity.
1208 elsif From_With_Type (T1) then
1210 -- If the expected type is the non-limited view of a type, the
1211 -- expression may have the limited view. If that one in turn is
1212 -- incomplete, get full view if available.
1214 if Is_Incomplete_Type (T1) then
1215 return Covers (Get_Full_View (Non_Limited_View (T1)), T2);
1217 elsif Ekind (T1) = E_Class_Wide_Type then
1218 return
1219 Covers (Class_Wide_Type (Non_Limited_View (Etype (T1))), T2);
1220 else
1221 return False;
1222 end if;
1224 elsif From_With_Type (T2) then
1226 -- If units in the context have Limited_With clauses on each other,
1227 -- either type might have a limited view. Checks performed elsewhere
1228 -- verify that the context type is the nonlimited view.
1230 if Is_Incomplete_Type (T2) then
1231 return Covers (T1, Get_Full_View (Non_Limited_View (T2)));
1233 elsif Ekind (T2) = E_Class_Wide_Type then
1234 return
1235 Present (Non_Limited_View (Etype (T2)))
1236 and then
1237 Covers (T1, Class_Wide_Type (Non_Limited_View (Etype (T2))));
1238 else
1239 return False;
1240 end if;
1242 -- Ada 2005 (AI-412): Coverage for regular incomplete subtypes
1244 elsif Ekind (T1) = E_Incomplete_Subtype then
1245 return Covers (Full_View (Etype (T1)), T2);
1247 elsif Ekind (T2) = E_Incomplete_Subtype then
1248 return Covers (T1, Full_View (Etype (T2)));
1250 -- Ada 2005 (AI-423): Coverage of formal anonymous access types
1251 -- and actual anonymous access types in the context of generic
1252 -- instantiations. We have the following situation:
1254 -- generic
1255 -- type Formal is private;
1256 -- Formal_Obj : access Formal; -- T1
1257 -- package G is ...
1259 -- package P is
1260 -- type Actual is ...
1261 -- Actual_Obj : access Actual; -- T2
1262 -- package Instance is new G (Formal => Actual,
1263 -- Formal_Obj => Actual_Obj);
1265 elsif Ada_Version >= Ada_2005
1266 and then Ekind (T1) = E_Anonymous_Access_Type
1267 and then Ekind (T2) = E_Anonymous_Access_Type
1268 and then Is_Generic_Type (Directly_Designated_Type (T1))
1269 and then Get_Instance_Of (Directly_Designated_Type (T1)) =
1270 Directly_Designated_Type (T2)
1271 then
1272 return True;
1274 -- Otherwise, types are not compatible!
1276 else
1277 return False;
1278 end if;
1279 end Covers;
1281 ------------------
1282 -- Disambiguate --
1283 ------------------
1285 function Disambiguate
1286 (N : Node_Id;
1287 I1, I2 : Interp_Index;
1288 Typ : Entity_Id) return Interp
1290 I : Interp_Index;
1291 It : Interp;
1292 It1, It2 : Interp;
1293 Nam1, Nam2 : Entity_Id;
1294 Predef_Subp : Entity_Id;
1295 User_Subp : Entity_Id;
1297 function Inherited_From_Actual (S : Entity_Id) return Boolean;
1298 -- Determine whether one of the candidates is an operation inherited by
1299 -- a type that is derived from an actual in an instantiation.
1301 function In_Same_Declaration_List
1302 (Typ : Entity_Id;
1303 Op_Decl : Entity_Id) return Boolean;
1304 -- AI05-0020: a spurious ambiguity may arise when equality on anonymous
1305 -- access types is declared on the partial view of a designated type, so
1306 -- that the type declaration and equality are not in the same list of
1307 -- declarations. This AI gives a preference rule for the user-defined
1308 -- operation. Same rule applies for arithmetic operations on private
1309 -- types completed with fixed-point types: the predefined operation is
1310 -- hidden; this is already handled properly in GNAT.
1312 function Is_Actual_Subprogram (S : Entity_Id) return Boolean;
1313 -- Determine whether a subprogram is an actual in an enclosing instance.
1314 -- An overloading between such a subprogram and one declared outside the
1315 -- instance is resolved in favor of the first, because it resolved in
1316 -- the generic. Within the instance the actual is represented by a
1317 -- constructed subprogram renaming.
1319 function Matches (Actual, Formal : Node_Id) return Boolean;
1320 -- Look for exact type match in an instance, to remove spurious
1321 -- ambiguities when two formal types have the same actual.
1323 function Operand_Type return Entity_Id;
1324 -- Determine type of operand for an equality operation, to apply
1325 -- Ada 2005 rules to equality on anonymous access types.
1327 function Standard_Operator return Boolean;
1328 -- Check whether subprogram is predefined operator declared in Standard.
1329 -- It may given by an operator name, or by an expanded name whose prefix
1330 -- is Standard.
1332 function Remove_Conversions return Interp;
1333 -- Last chance for pathological cases involving comparisons on literals,
1334 -- and user overloadings of the same operator. Such pathologies have
1335 -- been removed from the ACVC, but still appear in two DEC tests, with
1336 -- the following notable quote from Ben Brosgol:
1338 -- [Note: I disclaim all credit/responsibility/blame for coming up with
1339 -- this example; Robert Dewar brought it to our attention, since it is
1340 -- apparently found in the ACVC 1.5. I did not attempt to find the
1341 -- reason in the Reference Manual that makes the example legal, since I
1342 -- was too nauseated by it to want to pursue it further.]
1344 -- Accordingly, this is not a fully recursive solution, but it handles
1345 -- DEC tests c460vsa, c460vsb. It also handles ai00136a, which pushes
1346 -- pathology in the other direction with calls whose multiple overloaded
1347 -- actuals make them truly unresolvable.
1349 -- The new rules concerning abstract operations create additional need
1350 -- for special handling of expressions with universal operands, see
1351 -- comments to Has_Abstract_Interpretation below.
1353 ---------------------------
1354 -- Inherited_From_Actual --
1355 ---------------------------
1357 function Inherited_From_Actual (S : Entity_Id) return Boolean is
1358 Par : constant Node_Id := Parent (S);
1359 begin
1360 if Nkind (Par) /= N_Full_Type_Declaration
1361 or else Nkind (Type_Definition (Par)) /= N_Derived_Type_Definition
1362 then
1363 return False;
1364 else
1365 return Is_Entity_Name (Subtype_Indication (Type_Definition (Par)))
1366 and then
1367 Is_Generic_Actual_Type (
1368 Entity (Subtype_Indication (Type_Definition (Par))));
1369 end if;
1370 end Inherited_From_Actual;
1372 ------------------------------
1373 -- In_Same_Declaration_List --
1374 ------------------------------
1376 function In_Same_Declaration_List
1377 (Typ : Entity_Id;
1378 Op_Decl : Entity_Id) return Boolean
1380 Scop : constant Entity_Id := Scope (Typ);
1382 begin
1383 return In_Same_List (Parent (Typ), Op_Decl)
1384 or else
1385 (Ekind_In (Scop, E_Package, E_Generic_Package)
1386 and then List_Containing (Op_Decl) =
1387 Visible_Declarations (Parent (Scop))
1388 and then List_Containing (Parent (Typ)) =
1389 Private_Declarations (Parent (Scop)));
1390 end In_Same_Declaration_List;
1392 --------------------------
1393 -- Is_Actual_Subprogram --
1394 --------------------------
1396 function Is_Actual_Subprogram (S : Entity_Id) return Boolean is
1397 begin
1398 return In_Open_Scopes (Scope (S))
1399 and then
1400 Nkind (Unit_Declaration_Node (S)) =
1401 N_Subprogram_Renaming_Declaration
1403 -- Why the Comes_From_Source test here???
1405 and then not Comes_From_Source (Unit_Declaration_Node (S))
1407 and then
1408 (Is_Generic_Instance (Scope (S))
1409 or else Is_Wrapper_Package (Scope (S)));
1410 end Is_Actual_Subprogram;
1412 -------------
1413 -- Matches --
1414 -------------
1416 function Matches (Actual, Formal : Node_Id) return Boolean is
1417 T1 : constant Entity_Id := Etype (Actual);
1418 T2 : constant Entity_Id := Etype (Formal);
1419 begin
1420 return T1 = T2
1421 or else
1422 (Is_Numeric_Type (T2)
1423 and then (T1 = Universal_Real or else T1 = Universal_Integer));
1424 end Matches;
1426 ------------------
1427 -- Operand_Type --
1428 ------------------
1430 function Operand_Type return Entity_Id is
1431 Opnd : Node_Id;
1433 begin
1434 if Nkind (N) = N_Function_Call then
1435 Opnd := First_Actual (N);
1436 else
1437 Opnd := Left_Opnd (N);
1438 end if;
1440 return Etype (Opnd);
1441 end Operand_Type;
1443 ------------------------
1444 -- Remove_Conversions --
1445 ------------------------
1447 function Remove_Conversions return Interp is
1448 I : Interp_Index;
1449 It : Interp;
1450 It1 : Interp;
1451 F1 : Entity_Id;
1452 Act1 : Node_Id;
1453 Act2 : Node_Id;
1455 function Has_Abstract_Interpretation (N : Node_Id) return Boolean;
1456 -- If an operation has universal operands the universal operation
1457 -- is present among its interpretations. If there is an abstract
1458 -- interpretation for the operator, with a numeric result, this
1459 -- interpretation was already removed in sem_ch4, but the universal
1460 -- one is still visible. We must rescan the list of operators and
1461 -- remove the universal interpretation to resolve the ambiguity.
1463 ---------------------------------
1464 -- Has_Abstract_Interpretation --
1465 ---------------------------------
1467 function Has_Abstract_Interpretation (N : Node_Id) return Boolean is
1468 E : Entity_Id;
1470 begin
1471 if Nkind (N) not in N_Op
1472 or else Ada_Version < Ada_2005
1473 or else not Is_Overloaded (N)
1474 or else No (Universal_Interpretation (N))
1475 then
1476 return False;
1478 else
1479 E := Get_Name_Entity_Id (Chars (N));
1480 while Present (E) loop
1481 if Is_Overloadable (E)
1482 and then Is_Abstract_Subprogram (E)
1483 and then Is_Numeric_Type (Etype (E))
1484 then
1485 return True;
1486 else
1487 E := Homonym (E);
1488 end if;
1489 end loop;
1491 -- Finally, if an operand of the binary operator is itself
1492 -- an operator, recurse to see whether its own abstract
1493 -- interpretation is responsible for the spurious ambiguity.
1495 if Nkind (N) in N_Binary_Op then
1496 return Has_Abstract_Interpretation (Left_Opnd (N))
1497 or else Has_Abstract_Interpretation (Right_Opnd (N));
1499 elsif Nkind (N) in N_Unary_Op then
1500 return Has_Abstract_Interpretation (Right_Opnd (N));
1502 else
1503 return False;
1504 end if;
1505 end if;
1506 end Has_Abstract_Interpretation;
1508 -- Start of processing for Remove_Conversions
1510 begin
1511 It1 := No_Interp;
1513 Get_First_Interp (N, I, It);
1514 while Present (It.Typ) loop
1515 if not Is_Overloadable (It.Nam) then
1516 return No_Interp;
1517 end if;
1519 F1 := First_Formal (It.Nam);
1521 if No (F1) then
1522 return It1;
1524 else
1525 if Nkind (N) in N_Subprogram_Call then
1526 Act1 := First_Actual (N);
1528 if Present (Act1) then
1529 Act2 := Next_Actual (Act1);
1530 else
1531 Act2 := Empty;
1532 end if;
1534 elsif Nkind (N) in N_Unary_Op then
1535 Act1 := Right_Opnd (N);
1536 Act2 := Empty;
1538 elsif Nkind (N) in N_Binary_Op then
1539 Act1 := Left_Opnd (N);
1540 Act2 := Right_Opnd (N);
1542 -- Use type of second formal, so as to include
1543 -- exponentiation, where the exponent may be
1544 -- ambiguous and the result non-universal.
1546 Next_Formal (F1);
1548 else
1549 return It1;
1550 end if;
1552 if Nkind (Act1) in N_Op
1553 and then Is_Overloaded (Act1)
1554 and then (Nkind (Right_Opnd (Act1)) = N_Integer_Literal
1555 or else Nkind (Right_Opnd (Act1)) = N_Real_Literal)
1556 and then Has_Compatible_Type (Act1, Standard_Boolean)
1557 and then Etype (F1) = Standard_Boolean
1558 then
1559 -- If the two candidates are the original ones, the
1560 -- ambiguity is real. Otherwise keep the original, further
1561 -- calls to Disambiguate will take care of others in the
1562 -- list of candidates.
1564 if It1 /= No_Interp then
1565 if It = Disambiguate.It1
1566 or else It = Disambiguate.It2
1567 then
1568 if It1 = Disambiguate.It1
1569 or else It1 = Disambiguate.It2
1570 then
1571 return No_Interp;
1572 else
1573 It1 := It;
1574 end if;
1575 end if;
1577 elsif Present (Act2)
1578 and then Nkind (Act2) in N_Op
1579 and then Is_Overloaded (Act2)
1580 and then Nkind_In (Right_Opnd (Act2), N_Integer_Literal,
1581 N_Real_Literal)
1582 and then Has_Compatible_Type (Act2, Standard_Boolean)
1583 then
1584 -- The preference rule on the first actual is not
1585 -- sufficient to disambiguate.
1587 goto Next_Interp;
1589 else
1590 It1 := It;
1591 end if;
1593 elsif Is_Numeric_Type (Etype (F1))
1594 and then Has_Abstract_Interpretation (Act1)
1595 then
1596 -- Current interpretation is not the right one because it
1597 -- expects a numeric operand. Examine all the other ones.
1599 declare
1600 I : Interp_Index;
1601 It : Interp;
1603 begin
1604 Get_First_Interp (N, I, It);
1605 while Present (It.Typ) loop
1607 not Is_Numeric_Type (Etype (First_Formal (It.Nam)))
1608 then
1609 if No (Act2)
1610 or else not Has_Abstract_Interpretation (Act2)
1611 or else not
1612 Is_Numeric_Type
1613 (Etype (Next_Formal (First_Formal (It.Nam))))
1614 then
1615 return It;
1616 end if;
1617 end if;
1619 Get_Next_Interp (I, It);
1620 end loop;
1622 return No_Interp;
1623 end;
1624 end if;
1625 end if;
1627 <<Next_Interp>>
1628 Get_Next_Interp (I, It);
1629 end loop;
1631 -- After some error, a formal may have Any_Type and yield a spurious
1632 -- match. To avoid cascaded errors if possible, check for such a
1633 -- formal in either candidate.
1635 if Serious_Errors_Detected > 0 then
1636 declare
1637 Formal : Entity_Id;
1639 begin
1640 Formal := First_Formal (Nam1);
1641 while Present (Formal) loop
1642 if Etype (Formal) = Any_Type then
1643 return Disambiguate.It2;
1644 end if;
1646 Next_Formal (Formal);
1647 end loop;
1649 Formal := First_Formal (Nam2);
1650 while Present (Formal) loop
1651 if Etype (Formal) = Any_Type then
1652 return Disambiguate.It1;
1653 end if;
1655 Next_Formal (Formal);
1656 end loop;
1657 end;
1658 end if;
1660 return It1;
1661 end Remove_Conversions;
1663 -----------------------
1664 -- Standard_Operator --
1665 -----------------------
1667 function Standard_Operator return Boolean is
1668 Nam : Node_Id;
1670 begin
1671 if Nkind (N) in N_Op then
1672 return True;
1674 elsif Nkind (N) = N_Function_Call then
1675 Nam := Name (N);
1677 if Nkind (Nam) /= N_Expanded_Name then
1678 return True;
1679 else
1680 return Entity (Prefix (Nam)) = Standard_Standard;
1681 end if;
1682 else
1683 return False;
1684 end if;
1685 end Standard_Operator;
1687 -- Start of processing for Disambiguate
1689 begin
1690 -- Recover the two legal interpretations
1692 Get_First_Interp (N, I, It);
1693 while I /= I1 loop
1694 Get_Next_Interp (I, It);
1695 end loop;
1697 It1 := It;
1698 Nam1 := It.Nam;
1699 while I /= I2 loop
1700 Get_Next_Interp (I, It);
1701 end loop;
1703 It2 := It;
1704 Nam2 := It.Nam;
1706 -- Check whether one of the entities is an Ada 2005/2012 and we are
1707 -- operating in an earlier mode, in which case we discard the Ada
1708 -- 2005/2012 entity, so that we get proper Ada 95 overload resolution.
1710 if Ada_Version < Ada_2005 then
1711 if Is_Ada_2005_Only (Nam1) or else Is_Ada_2012_Only (Nam1) then
1712 return It2;
1713 elsif Is_Ada_2005_Only (Nam2) or else Is_Ada_2012_Only (Nam1) then
1714 return It1;
1715 end if;
1716 end if;
1718 -- Check whether one of the entities is an Ada 2012 entity and we are
1719 -- operating in Ada 2005 mode, in which case we discard the Ada 2012
1720 -- entity, so that we get proper Ada 2005 overload resolution.
1722 if Ada_Version = Ada_2005 then
1723 if Is_Ada_2012_Only (Nam1) then
1724 return It2;
1725 elsif Is_Ada_2012_Only (Nam2) then
1726 return It1;
1727 end if;
1728 end if;
1730 -- Check for overloaded CIL convention stuff because the CIL libraries
1731 -- do sick things like Console.Write_Line where it matches two different
1732 -- overloads, so just pick the first ???
1734 if Convention (Nam1) = Convention_CIL
1735 and then Convention (Nam2) = Convention_CIL
1736 and then Ekind (Nam1) = Ekind (Nam2)
1737 and then (Ekind (Nam1) = E_Procedure
1738 or else Ekind (Nam1) = E_Function)
1739 then
1740 return It2;
1741 end if;
1743 -- If the context is universal, the predefined operator is preferred.
1744 -- This includes bounds in numeric type declarations, and expressions
1745 -- in type conversions. If no interpretation yields a universal type,
1746 -- then we must check whether the user-defined entity hides the prede-
1747 -- fined one.
1749 if Chars (Nam1) in Any_Operator_Name
1750 and then Standard_Operator
1751 then
1752 if Typ = Universal_Integer
1753 or else Typ = Universal_Real
1754 or else Typ = Any_Integer
1755 or else Typ = Any_Discrete
1756 or else Typ = Any_Real
1757 or else Typ = Any_Type
1758 then
1759 -- Find an interpretation that yields the universal type, or else
1760 -- a predefined operator that yields a predefined numeric type.
1762 declare
1763 Candidate : Interp := No_Interp;
1765 begin
1766 Get_First_Interp (N, I, It);
1767 while Present (It.Typ) loop
1768 if (Covers (Typ, It.Typ)
1769 or else Typ = Any_Type)
1770 and then
1771 (It.Typ = Universal_Integer
1772 or else It.Typ = Universal_Real)
1773 then
1774 return It;
1776 elsif Covers (Typ, It.Typ)
1777 and then Scope (It.Typ) = Standard_Standard
1778 and then Scope (It.Nam) = Standard_Standard
1779 and then Is_Numeric_Type (It.Typ)
1780 then
1781 Candidate := It;
1782 end if;
1784 Get_Next_Interp (I, It);
1785 end loop;
1787 if Candidate /= No_Interp then
1788 return Candidate;
1789 end if;
1790 end;
1792 elsif Chars (Nam1) /= Name_Op_Not
1793 and then (Typ = Standard_Boolean or else Typ = Any_Boolean)
1794 then
1795 -- Equality or comparison operation. Choose predefined operator if
1796 -- arguments are universal. The node may be an operator, name, or
1797 -- a function call, so unpack arguments accordingly.
1799 declare
1800 Arg1, Arg2 : Node_Id;
1802 begin
1803 if Nkind (N) in N_Op then
1804 Arg1 := Left_Opnd (N);
1805 Arg2 := Right_Opnd (N);
1807 elsif Is_Entity_Name (N) then
1808 Arg1 := First_Entity (Entity (N));
1809 Arg2 := Next_Entity (Arg1);
1811 else
1812 Arg1 := First_Actual (N);
1813 Arg2 := Next_Actual (Arg1);
1814 end if;
1816 if Present (Arg2)
1817 and then Present (Universal_Interpretation (Arg1))
1818 and then Universal_Interpretation (Arg2) =
1819 Universal_Interpretation (Arg1)
1820 then
1821 Get_First_Interp (N, I, It);
1822 while Scope (It.Nam) /= Standard_Standard loop
1823 Get_Next_Interp (I, It);
1824 end loop;
1826 return It;
1827 end if;
1828 end;
1829 end if;
1830 end if;
1832 -- If no universal interpretation, check whether user-defined operator
1833 -- hides predefined one, as well as other special cases. If the node
1834 -- is a range, then one or both bounds are ambiguous. Each will have
1835 -- to be disambiguated w.r.t. the context type. The type of the range
1836 -- itself is imposed by the context, so we can return either legal
1837 -- interpretation.
1839 if Ekind (Nam1) = E_Operator then
1840 Predef_Subp := Nam1;
1841 User_Subp := Nam2;
1843 elsif Ekind (Nam2) = E_Operator then
1844 Predef_Subp := Nam2;
1845 User_Subp := Nam1;
1847 elsif Nkind (N) = N_Range then
1848 return It1;
1850 -- Implement AI05-105: A renaming declaration with an access
1851 -- definition must resolve to an anonymous access type. This
1852 -- is a resolution rule and can be used to disambiguate.
1854 elsif Nkind (Parent (N)) = N_Object_Renaming_Declaration
1855 and then Present (Access_Definition (Parent (N)))
1856 then
1857 if Ekind_In (It1.Typ, E_Anonymous_Access_Type,
1858 E_Anonymous_Access_Subprogram_Type)
1859 then
1860 if Ekind (It2.Typ) = Ekind (It1.Typ) then
1862 -- True ambiguity
1864 return No_Interp;
1866 else
1867 return It1;
1868 end if;
1870 elsif Ekind_In (It2.Typ, E_Anonymous_Access_Type,
1871 E_Anonymous_Access_Subprogram_Type)
1872 then
1873 return It2;
1875 -- No legal interpretation
1877 else
1878 return No_Interp;
1879 end if;
1881 -- If two user defined-subprograms are visible, it is a true ambiguity,
1882 -- unless one of them is an entry and the context is a conditional or
1883 -- timed entry call, or unless we are within an instance and this is
1884 -- results from two formals types with the same actual.
1886 else
1887 if Nkind (N) = N_Procedure_Call_Statement
1888 and then Nkind (Parent (N)) = N_Entry_Call_Alternative
1889 and then N = Entry_Call_Statement (Parent (N))
1890 then
1891 if Ekind (Nam2) = E_Entry then
1892 return It2;
1893 elsif Ekind (Nam1) = E_Entry then
1894 return It1;
1895 else
1896 return No_Interp;
1897 end if;
1899 -- If the ambiguity occurs within an instance, it is due to several
1900 -- formal types with the same actual. Look for an exact match between
1901 -- the types of the formals of the overloadable entities, and the
1902 -- actuals in the call, to recover the unambiguous match in the
1903 -- original generic.
1905 -- The ambiguity can also be due to an overloading between a formal
1906 -- subprogram and a subprogram declared outside the generic. If the
1907 -- node is overloaded, it did not resolve to the global entity in
1908 -- the generic, and we choose the formal subprogram.
1910 -- Finally, the ambiguity can be between an explicit subprogram and
1911 -- one inherited (with different defaults) from an actual. In this
1912 -- case the resolution was to the explicit declaration in the
1913 -- generic, and remains so in the instance.
1915 -- The same sort of disambiguation needed for calls is also required
1916 -- for the name given in a subprogram renaming, and that case is
1917 -- handled here as well. We test Comes_From_Source to exclude this
1918 -- treatment for implicit renamings created for formal subprograms.
1920 elsif In_Instance
1921 and then not In_Generic_Actual (N)
1922 then
1923 if Nkind (N) in N_Subprogram_Call
1924 or else
1925 (Nkind (N) in N_Has_Entity
1926 and then
1927 Nkind (Parent (N)) = N_Subprogram_Renaming_Declaration
1928 and then Comes_From_Source (Parent (N)))
1929 then
1930 declare
1931 Actual : Node_Id;
1932 Formal : Entity_Id;
1933 Renam : Entity_Id := Empty;
1934 Is_Act1 : constant Boolean := Is_Actual_Subprogram (Nam1);
1935 Is_Act2 : constant Boolean := Is_Actual_Subprogram (Nam2);
1937 begin
1938 if Is_Act1 and then not Is_Act2 then
1939 return It1;
1941 elsif Is_Act2 and then not Is_Act1 then
1942 return It2;
1944 elsif Inherited_From_Actual (Nam1)
1945 and then Comes_From_Source (Nam2)
1946 then
1947 return It2;
1949 elsif Inherited_From_Actual (Nam2)
1950 and then Comes_From_Source (Nam1)
1951 then
1952 return It1;
1953 end if;
1955 -- In the case of a renamed subprogram, pick up the entity
1956 -- of the renaming declaration so we can traverse its
1957 -- formal parameters.
1959 if Nkind (N) in N_Has_Entity then
1960 Renam := Defining_Unit_Name (Specification (Parent (N)));
1961 end if;
1963 if Present (Renam) then
1964 Actual := First_Formal (Renam);
1965 else
1966 Actual := First_Actual (N);
1967 end if;
1969 Formal := First_Formal (Nam1);
1970 while Present (Actual) loop
1971 if Etype (Actual) /= Etype (Formal) then
1972 return It2;
1973 end if;
1975 if Present (Renam) then
1976 Next_Formal (Actual);
1977 else
1978 Next_Actual (Actual);
1979 end if;
1981 Next_Formal (Formal);
1982 end loop;
1984 return It1;
1985 end;
1987 elsif Nkind (N) in N_Binary_Op then
1988 if Matches (Left_Opnd (N), First_Formal (Nam1))
1989 and then
1990 Matches (Right_Opnd (N), Next_Formal (First_Formal (Nam1)))
1991 then
1992 return It1;
1993 else
1994 return It2;
1995 end if;
1997 elsif Nkind (N) in N_Unary_Op then
1998 if Etype (Right_Opnd (N)) = Etype (First_Formal (Nam1)) then
1999 return It1;
2000 else
2001 return It2;
2002 end if;
2004 else
2005 return Remove_Conversions;
2006 end if;
2007 else
2008 return Remove_Conversions;
2009 end if;
2010 end if;
2012 -- An implicit concatenation operator on a string type cannot be
2013 -- disambiguated from the predefined concatenation. This can only
2014 -- happen with concatenation of string literals.
2016 if Chars (User_Subp) = Name_Op_Concat
2017 and then Ekind (User_Subp) = E_Operator
2018 and then Is_String_Type (Etype (First_Formal (User_Subp)))
2019 then
2020 return No_Interp;
2022 -- If the user-defined operator is in an open scope, or in the scope
2023 -- of the resulting type, or given by an expanded name that names its
2024 -- scope, it hides the predefined operator for the type. Exponentiation
2025 -- has to be special-cased because the implicit operator does not have
2026 -- a symmetric signature, and may not be hidden by the explicit one.
2028 elsif (Nkind (N) = N_Function_Call
2029 and then Nkind (Name (N)) = N_Expanded_Name
2030 and then (Chars (Predef_Subp) /= Name_Op_Expon
2031 or else Hides_Op (User_Subp, Predef_Subp))
2032 and then Scope (User_Subp) = Entity (Prefix (Name (N))))
2033 or else Hides_Op (User_Subp, Predef_Subp)
2034 then
2035 if It1.Nam = User_Subp then
2036 return It1;
2037 else
2038 return It2;
2039 end if;
2041 -- Otherwise, the predefined operator has precedence, or if the user-
2042 -- defined operation is directly visible we have a true ambiguity.
2044 -- If this is a fixed-point multiplication and division in Ada 83 mode,
2045 -- exclude the universal_fixed operator, which often causes ambiguities
2046 -- in legacy code.
2048 -- Ditto in Ada 2012, where an ambiguity may arise for an operation
2049 -- on a partial view that is completed with a fixed point type. See
2050 -- AI05-0020 and AI05-0209. The ambiguity is resolved in favor of the
2051 -- user-defined type and subprogram, so that a client of the package
2052 -- has the same resolution as the body of the package.
2054 else
2055 if (In_Open_Scopes (Scope (User_Subp))
2056 or else Is_Potentially_Use_Visible (User_Subp))
2057 and then not In_Instance
2058 then
2059 if Is_Fixed_Point_Type (Typ)
2060 and then Nam_In (Chars (Nam1), Name_Op_Multiply, Name_Op_Divide)
2061 and then
2062 (Ada_Version = Ada_83
2063 or else (Ada_Version >= Ada_2012
2064 and then In_Same_Declaration_List
2065 (First_Subtype (Typ),
2066 Unit_Declaration_Node (User_Subp))))
2067 then
2068 if It2.Nam = Predef_Subp then
2069 return It1;
2070 else
2071 return It2;
2072 end if;
2074 -- Ada 2005, AI-420: preference rule for "=" on Universal_Access
2075 -- states that the operator defined in Standard is not available
2076 -- if there is a user-defined equality with the proper signature,
2077 -- declared in the same declarative list as the type. The node
2078 -- may be an operator or a function call.
2080 elsif Nam_In (Chars (Nam1), Name_Op_Eq, Name_Op_Ne)
2081 and then Ada_Version >= Ada_2005
2082 and then Etype (User_Subp) = Standard_Boolean
2083 and then Ekind (Operand_Type) = E_Anonymous_Access_Type
2084 and then
2085 In_Same_Declaration_List
2086 (Designated_Type (Operand_Type),
2087 Unit_Declaration_Node (User_Subp))
2088 then
2089 if It2.Nam = Predef_Subp then
2090 return It1;
2091 else
2092 return It2;
2093 end if;
2095 -- An immediately visible operator hides a use-visible user-
2096 -- defined operation. This disambiguation cannot take place
2097 -- earlier because the visibility of the predefined operator
2098 -- can only be established when operand types are known.
2100 elsif Ekind (User_Subp) = E_Function
2101 and then Ekind (Predef_Subp) = E_Operator
2102 and then Nkind (N) in N_Op
2103 and then not Is_Overloaded (Right_Opnd (N))
2104 and then
2105 Is_Immediately_Visible (Base_Type (Etype (Right_Opnd (N))))
2106 and then Is_Potentially_Use_Visible (User_Subp)
2107 then
2108 if It2.Nam = Predef_Subp then
2109 return It1;
2110 else
2111 return It2;
2112 end if;
2114 else
2115 return No_Interp;
2116 end if;
2118 elsif It1.Nam = Predef_Subp then
2119 return It1;
2121 else
2122 return It2;
2123 end if;
2124 end if;
2125 end Disambiguate;
2127 ---------------------
2128 -- End_Interp_List --
2129 ---------------------
2131 procedure End_Interp_List is
2132 begin
2133 All_Interp.Table (All_Interp.Last) := No_Interp;
2134 All_Interp.Increment_Last;
2135 end End_Interp_List;
2137 -------------------------
2138 -- Entity_Matches_Spec --
2139 -------------------------
2141 function Entity_Matches_Spec (Old_S, New_S : Entity_Id) return Boolean is
2142 begin
2143 -- Simple case: same entity kinds, type conformance is required. A
2144 -- parameterless function can also rename a literal.
2146 if Ekind (Old_S) = Ekind (New_S)
2147 or else (Ekind (New_S) = E_Function
2148 and then Ekind (Old_S) = E_Enumeration_Literal)
2149 then
2150 return Type_Conformant (New_S, Old_S);
2152 elsif Ekind (New_S) = E_Function
2153 and then Ekind (Old_S) = E_Operator
2154 then
2155 return Operator_Matches_Spec (Old_S, New_S);
2157 elsif Ekind (New_S) = E_Procedure
2158 and then Is_Entry (Old_S)
2159 then
2160 return Type_Conformant (New_S, Old_S);
2162 else
2163 return False;
2164 end if;
2165 end Entity_Matches_Spec;
2167 ----------------------
2168 -- Find_Unique_Type --
2169 ----------------------
2171 function Find_Unique_Type (L : Node_Id; R : Node_Id) return Entity_Id is
2172 T : constant Entity_Id := Etype (L);
2173 I : Interp_Index;
2174 It : Interp;
2175 TR : Entity_Id := Any_Type;
2177 begin
2178 if Is_Overloaded (R) then
2179 Get_First_Interp (R, I, It);
2180 while Present (It.Typ) loop
2181 if Covers (T, It.Typ) or else Covers (It.Typ, T) then
2183 -- If several interpretations are possible and L is universal,
2184 -- apply preference rule.
2186 if TR /= Any_Type then
2188 if (T = Universal_Integer or else T = Universal_Real)
2189 and then It.Typ = T
2190 then
2191 TR := It.Typ;
2192 end if;
2194 else
2195 TR := It.Typ;
2196 end if;
2197 end if;
2199 Get_Next_Interp (I, It);
2200 end loop;
2202 Set_Etype (R, TR);
2204 -- In the non-overloaded case, the Etype of R is already set correctly
2206 else
2207 null;
2208 end if;
2210 -- If one of the operands is Universal_Fixed, the type of the other
2211 -- operand provides the context.
2213 if Etype (R) = Universal_Fixed then
2214 return T;
2216 elsif T = Universal_Fixed then
2217 return Etype (R);
2219 -- Ada 2005 (AI-230): Support the following operators:
2221 -- function "=" (L, R : universal_access) return Boolean;
2222 -- function "/=" (L, R : universal_access) return Boolean;
2224 -- Pool specific access types (E_Access_Type) are not covered by these
2225 -- operators because of the legality rule of 4.5.2(9.2): "The operands
2226 -- of the equality operators for universal_access shall be convertible
2227 -- to one another (see 4.6)". For example, considering the type decla-
2228 -- ration "type P is access Integer" and an anonymous access to Integer,
2229 -- P is convertible to "access Integer" by 4.6 (24.11-24.15), but there
2230 -- is no rule in 4.6 that allows "access Integer" to be converted to P.
2232 elsif Ada_Version >= Ada_2005
2233 and then
2234 (Ekind (Etype (L)) = E_Anonymous_Access_Type
2235 or else
2236 Ekind (Etype (L)) = E_Anonymous_Access_Subprogram_Type)
2237 and then Is_Access_Type (Etype (R))
2238 and then Ekind (Etype (R)) /= E_Access_Type
2239 then
2240 return Etype (L);
2242 elsif Ada_Version >= Ada_2005
2243 and then
2244 (Ekind (Etype (R)) = E_Anonymous_Access_Type
2245 or else Ekind (Etype (R)) = E_Anonymous_Access_Subprogram_Type)
2246 and then Is_Access_Type (Etype (L))
2247 and then Ekind (Etype (L)) /= E_Access_Type
2248 then
2249 return Etype (R);
2251 else
2252 return Specific_Type (T, Etype (R));
2253 end if;
2254 end Find_Unique_Type;
2256 -------------------------------------
2257 -- Function_Interp_Has_Abstract_Op --
2258 -------------------------------------
2260 function Function_Interp_Has_Abstract_Op
2261 (N : Node_Id;
2262 E : Entity_Id) return Entity_Id
2264 Abstr_Op : Entity_Id;
2265 Act : Node_Id;
2266 Act_Parm : Node_Id;
2267 Form_Parm : Node_Id;
2269 begin
2270 -- Why is check on E needed below ???
2271 -- In any case this para needs comments ???
2273 if Is_Overloaded (N) and then Is_Overloadable (E) then
2274 Act_Parm := First_Actual (N);
2275 Form_Parm := First_Formal (E);
2276 while Present (Act_Parm)
2277 and then Present (Form_Parm)
2278 loop
2279 Act := Act_Parm;
2281 if Nkind (Act) = N_Parameter_Association then
2282 Act := Explicit_Actual_Parameter (Act);
2283 end if;
2285 Abstr_Op := Has_Abstract_Op (Act, Etype (Form_Parm));
2287 if Present (Abstr_Op) then
2288 return Abstr_Op;
2289 end if;
2291 Next_Actual (Act_Parm);
2292 Next_Formal (Form_Parm);
2293 end loop;
2294 end if;
2296 return Empty;
2297 end Function_Interp_Has_Abstract_Op;
2299 ----------------------
2300 -- Get_First_Interp --
2301 ----------------------
2303 procedure Get_First_Interp
2304 (N : Node_Id;
2305 I : out Interp_Index;
2306 It : out Interp)
2308 Int_Ind : Interp_Index;
2309 Map_Ptr : Int;
2310 O_N : Node_Id;
2312 begin
2313 -- If a selected component is overloaded because the selector has
2314 -- multiple interpretations, the node is a call to a protected
2315 -- operation or an indirect call. Retrieve the interpretation from
2316 -- the selector name. The selected component may be overloaded as well
2317 -- if the prefix is overloaded. That case is unchanged.
2319 if Nkind (N) = N_Selected_Component
2320 and then Is_Overloaded (Selector_Name (N))
2321 then
2322 O_N := Selector_Name (N);
2323 else
2324 O_N := N;
2325 end if;
2327 Map_Ptr := Headers (Hash (O_N));
2328 while Map_Ptr /= No_Entry loop
2329 if Interp_Map.Table (Map_Ptr).Node = O_N then
2330 Int_Ind := Interp_Map.Table (Map_Ptr).Index;
2331 It := All_Interp.Table (Int_Ind);
2332 I := Int_Ind;
2333 return;
2334 else
2335 Map_Ptr := Interp_Map.Table (Map_Ptr).Next;
2336 end if;
2337 end loop;
2339 -- Procedure should never be called if the node has no interpretations
2341 raise Program_Error;
2342 end Get_First_Interp;
2344 ---------------------
2345 -- Get_Next_Interp --
2346 ---------------------
2348 procedure Get_Next_Interp (I : in out Interp_Index; It : out Interp) is
2349 begin
2350 I := I + 1;
2351 It := All_Interp.Table (I);
2352 end Get_Next_Interp;
2354 -------------------------
2355 -- Has_Compatible_Type --
2356 -------------------------
2358 function Has_Compatible_Type
2359 (N : Node_Id;
2360 Typ : Entity_Id) return Boolean
2362 I : Interp_Index;
2363 It : Interp;
2365 begin
2366 if N = Error then
2367 return False;
2368 end if;
2370 if Nkind (N) = N_Subtype_Indication
2371 or else not Is_Overloaded (N)
2372 then
2373 return
2374 Covers (Typ, Etype (N))
2376 -- Ada 2005 (AI-345): The context may be a synchronized interface.
2377 -- If the type is already frozen use the corresponding_record
2378 -- to check whether it is a proper descendant.
2380 or else
2381 (Is_Record_Type (Typ)
2382 and then Is_Concurrent_Type (Etype (N))
2383 and then Present (Corresponding_Record_Type (Etype (N)))
2384 and then Covers (Typ, Corresponding_Record_Type (Etype (N))))
2386 or else
2387 (Is_Concurrent_Type (Typ)
2388 and then Is_Record_Type (Etype (N))
2389 and then Present (Corresponding_Record_Type (Typ))
2390 and then Covers (Corresponding_Record_Type (Typ), Etype (N)))
2392 or else
2393 (not Is_Tagged_Type (Typ)
2394 and then Ekind (Typ) /= E_Anonymous_Access_Type
2395 and then Covers (Etype (N), Typ));
2397 else
2398 Get_First_Interp (N, I, It);
2399 while Present (It.Typ) loop
2400 if (Covers (Typ, It.Typ)
2401 and then
2402 (Scope (It.Nam) /= Standard_Standard
2403 or else not Is_Invisible_Operator (N, Base_Type (Typ))))
2405 -- Ada 2005 (AI-345)
2407 or else
2408 (Is_Concurrent_Type (It.Typ)
2409 and then Present (Corresponding_Record_Type
2410 (Etype (It.Typ)))
2411 and then Covers (Typ, Corresponding_Record_Type
2412 (Etype (It.Typ))))
2414 or else (not Is_Tagged_Type (Typ)
2415 and then Ekind (Typ) /= E_Anonymous_Access_Type
2416 and then Covers (It.Typ, Typ))
2417 then
2418 return True;
2419 end if;
2421 Get_Next_Interp (I, It);
2422 end loop;
2424 return False;
2425 end if;
2426 end Has_Compatible_Type;
2428 ---------------------
2429 -- Has_Abstract_Op --
2430 ---------------------
2432 function Has_Abstract_Op
2433 (N : Node_Id;
2434 Typ : Entity_Id) return Entity_Id
2436 I : Interp_Index;
2437 It : Interp;
2439 begin
2440 if Is_Overloaded (N) then
2441 Get_First_Interp (N, I, It);
2442 while Present (It.Nam) loop
2443 if Present (It.Abstract_Op)
2444 and then Etype (It.Abstract_Op) = Typ
2445 then
2446 return It.Abstract_Op;
2447 end if;
2449 Get_Next_Interp (I, It);
2450 end loop;
2451 end if;
2453 return Empty;
2454 end Has_Abstract_Op;
2456 ----------
2457 -- Hash --
2458 ----------
2460 function Hash (N : Node_Id) return Int is
2461 begin
2462 -- Nodes have a size that is power of two, so to select significant
2463 -- bits only we remove the low-order bits.
2465 return ((Int (N) / 2 ** 5) mod Header_Size);
2466 end Hash;
2468 --------------
2469 -- Hides_Op --
2470 --------------
2472 function Hides_Op (F : Entity_Id; Op : Entity_Id) return Boolean is
2473 Btyp : constant Entity_Id := Base_Type (Etype (First_Formal (F)));
2474 begin
2475 return Operator_Matches_Spec (Op, F)
2476 and then (In_Open_Scopes (Scope (F))
2477 or else Scope (F) = Scope (Btyp)
2478 or else (not In_Open_Scopes (Scope (Btyp))
2479 and then not In_Use (Btyp)
2480 and then not In_Use (Scope (Btyp))));
2481 end Hides_Op;
2483 ------------------------
2484 -- Init_Interp_Tables --
2485 ------------------------
2487 procedure Init_Interp_Tables is
2488 begin
2489 All_Interp.Init;
2490 Interp_Map.Init;
2491 Headers := (others => No_Entry);
2492 end Init_Interp_Tables;
2494 -----------------------------------
2495 -- Interface_Present_In_Ancestor --
2496 -----------------------------------
2498 function Interface_Present_In_Ancestor
2499 (Typ : Entity_Id;
2500 Iface : Entity_Id) return Boolean
2502 Target_Typ : Entity_Id;
2503 Iface_Typ : Entity_Id;
2505 function Iface_Present_In_Ancestor (Typ : Entity_Id) return Boolean;
2506 -- Returns True if Typ or some ancestor of Typ implements Iface
2508 -------------------------------
2509 -- Iface_Present_In_Ancestor --
2510 -------------------------------
2512 function Iface_Present_In_Ancestor (Typ : Entity_Id) return Boolean is
2513 E : Entity_Id;
2514 AI : Entity_Id;
2515 Elmt : Elmt_Id;
2517 begin
2518 if Typ = Iface_Typ then
2519 return True;
2520 end if;
2522 -- Handle private types
2524 if Present (Full_View (Typ))
2525 and then not Is_Concurrent_Type (Full_View (Typ))
2526 then
2527 E := Full_View (Typ);
2528 else
2529 E := Typ;
2530 end if;
2532 loop
2533 if Present (Interfaces (E))
2534 and then Present (Interfaces (E))
2535 and then not Is_Empty_Elmt_List (Interfaces (E))
2536 then
2537 Elmt := First_Elmt (Interfaces (E));
2538 while Present (Elmt) loop
2539 AI := Node (Elmt);
2541 if AI = Iface_Typ or else Is_Ancestor (Iface_Typ, AI) then
2542 return True;
2543 end if;
2545 Next_Elmt (Elmt);
2546 end loop;
2547 end if;
2549 exit when Etype (E) = E
2551 -- Handle private types
2553 or else (Present (Full_View (Etype (E)))
2554 and then Full_View (Etype (E)) = E);
2556 -- Check if the current type is a direct derivation of the
2557 -- interface
2559 if Etype (E) = Iface_Typ then
2560 return True;
2561 end if;
2563 -- Climb to the immediate ancestor handling private types
2565 if Present (Full_View (Etype (E))) then
2566 E := Full_View (Etype (E));
2567 else
2568 E := Etype (E);
2569 end if;
2570 end loop;
2572 return False;
2573 end Iface_Present_In_Ancestor;
2575 -- Start of processing for Interface_Present_In_Ancestor
2577 begin
2578 -- Iface might be a class-wide subtype, so we have to apply Base_Type
2580 if Is_Class_Wide_Type (Iface) then
2581 Iface_Typ := Etype (Base_Type (Iface));
2582 else
2583 Iface_Typ := Iface;
2584 end if;
2586 -- Handle subtypes
2588 Iface_Typ := Base_Type (Iface_Typ);
2590 if Is_Access_Type (Typ) then
2591 Target_Typ := Etype (Directly_Designated_Type (Typ));
2592 else
2593 Target_Typ := Typ;
2594 end if;
2596 if Is_Concurrent_Record_Type (Target_Typ) then
2597 Target_Typ := Corresponding_Concurrent_Type (Target_Typ);
2598 end if;
2600 Target_Typ := Base_Type (Target_Typ);
2602 -- In case of concurrent types we can't use the Corresponding Record_Typ
2603 -- to look for the interface because it is built by the expander (and
2604 -- hence it is not always available). For this reason we traverse the
2605 -- list of interfaces (available in the parent of the concurrent type)
2607 if Is_Concurrent_Type (Target_Typ) then
2608 if Present (Interface_List (Parent (Target_Typ))) then
2609 declare
2610 AI : Node_Id;
2612 begin
2613 AI := First (Interface_List (Parent (Target_Typ)));
2614 while Present (AI) loop
2615 if Etype (AI) = Iface_Typ then
2616 return True;
2618 elsif Present (Interfaces (Etype (AI)))
2619 and then Iface_Present_In_Ancestor (Etype (AI))
2620 then
2621 return True;
2622 end if;
2624 Next (AI);
2625 end loop;
2626 end;
2627 end if;
2629 return False;
2630 end if;
2632 if Is_Class_Wide_Type (Target_Typ) then
2633 Target_Typ := Etype (Target_Typ);
2634 end if;
2636 if Ekind (Target_Typ) = E_Incomplete_Type then
2637 pragma Assert (Present (Non_Limited_View (Target_Typ)));
2638 Target_Typ := Non_Limited_View (Target_Typ);
2640 -- Protect the frontend against previously detected errors
2642 if Ekind (Target_Typ) = E_Incomplete_Type then
2643 return False;
2644 end if;
2645 end if;
2647 return Iface_Present_In_Ancestor (Target_Typ);
2648 end Interface_Present_In_Ancestor;
2650 ---------------------
2651 -- Intersect_Types --
2652 ---------------------
2654 function Intersect_Types (L, R : Node_Id) return Entity_Id is
2655 Index : Interp_Index;
2656 It : Interp;
2657 Typ : Entity_Id;
2659 function Check_Right_Argument (T : Entity_Id) return Entity_Id;
2660 -- Find interpretation of right arg that has type compatible with T
2662 --------------------------
2663 -- Check_Right_Argument --
2664 --------------------------
2666 function Check_Right_Argument (T : Entity_Id) return Entity_Id is
2667 Index : Interp_Index;
2668 It : Interp;
2669 T2 : Entity_Id;
2671 begin
2672 if not Is_Overloaded (R) then
2673 return Specific_Type (T, Etype (R));
2675 else
2676 Get_First_Interp (R, Index, It);
2677 loop
2678 T2 := Specific_Type (T, It.Typ);
2680 if T2 /= Any_Type then
2681 return T2;
2682 end if;
2684 Get_Next_Interp (Index, It);
2685 exit when No (It.Typ);
2686 end loop;
2688 return Any_Type;
2689 end if;
2690 end Check_Right_Argument;
2692 -- Start of processing for Intersect_Types
2694 begin
2695 if Etype (L) = Any_Type or else Etype (R) = Any_Type then
2696 return Any_Type;
2697 end if;
2699 if not Is_Overloaded (L) then
2700 Typ := Check_Right_Argument (Etype (L));
2702 else
2703 Typ := Any_Type;
2704 Get_First_Interp (L, Index, It);
2705 while Present (It.Typ) loop
2706 Typ := Check_Right_Argument (It.Typ);
2707 exit when Typ /= Any_Type;
2708 Get_Next_Interp (Index, It);
2709 end loop;
2711 end if;
2713 -- If Typ is Any_Type, it means no compatible pair of types was found
2715 if Typ = Any_Type then
2716 if Nkind (Parent (L)) in N_Op then
2717 Error_Msg_N ("incompatible types for operator", Parent (L));
2719 elsif Nkind (Parent (L)) = N_Range then
2720 Error_Msg_N ("incompatible types given in constraint", Parent (L));
2722 -- Ada 2005 (AI-251): Complete the error notification
2724 elsif Is_Class_Wide_Type (Etype (R))
2725 and then Is_Interface (Etype (Class_Wide_Type (Etype (R))))
2726 then
2727 Error_Msg_NE ("(Ada 2005) does not implement interface }",
2728 L, Etype (Class_Wide_Type (Etype (R))));
2730 else
2731 Error_Msg_N ("incompatible types", Parent (L));
2732 end if;
2733 end if;
2735 return Typ;
2736 end Intersect_Types;
2738 -----------------------
2739 -- In_Generic_Actual --
2740 -----------------------
2742 function In_Generic_Actual (Exp : Node_Id) return Boolean is
2743 Par : constant Node_Id := Parent (Exp);
2745 begin
2746 if No (Par) then
2747 return False;
2749 elsif Nkind (Par) in N_Declaration then
2750 if Nkind (Par) = N_Object_Declaration then
2751 return Present (Corresponding_Generic_Association (Par));
2752 else
2753 return False;
2754 end if;
2756 elsif Nkind (Par) = N_Object_Renaming_Declaration then
2757 return Present (Corresponding_Generic_Association (Par));
2759 elsif Nkind (Par) in N_Statement_Other_Than_Procedure_Call then
2760 return False;
2762 else
2763 return In_Generic_Actual (Parent (Par));
2764 end if;
2765 end In_Generic_Actual;
2767 -----------------
2768 -- Is_Ancestor --
2769 -----------------
2771 function Is_Ancestor
2772 (T1 : Entity_Id;
2773 T2 : Entity_Id;
2774 Use_Full_View : Boolean := False) return Boolean
2776 BT1 : Entity_Id;
2777 BT2 : Entity_Id;
2778 Par : Entity_Id;
2780 begin
2781 BT1 := Base_Type (T1);
2782 BT2 := Base_Type (T2);
2784 -- Handle underlying view of records with unknown discriminants using
2785 -- the original entity that motivated the construction of this
2786 -- underlying record view (see Build_Derived_Private_Type).
2788 if Is_Underlying_Record_View (BT1) then
2789 BT1 := Underlying_Record_View (BT1);
2790 end if;
2792 if Is_Underlying_Record_View (BT2) then
2793 BT2 := Underlying_Record_View (BT2);
2794 end if;
2796 if BT1 = BT2 then
2797 return True;
2799 -- The predicate must look past privacy
2801 elsif Is_Private_Type (T1)
2802 and then Present (Full_View (T1))
2803 and then BT2 = Base_Type (Full_View (T1))
2804 then
2805 return True;
2807 elsif Is_Private_Type (T2)
2808 and then Present (Full_View (T2))
2809 and then BT1 = Base_Type (Full_View (T2))
2810 then
2811 return True;
2813 else
2814 -- Obtain the parent of the base type of T2 (use the full view if
2815 -- allowed).
2817 if Use_Full_View
2818 and then Is_Private_Type (BT2)
2819 and then Present (Full_View (BT2))
2820 then
2821 -- No climbing needed if its full view is the root type
2823 if Full_View (BT2) = Root_Type (Full_View (BT2)) then
2824 return False;
2825 end if;
2827 Par := Etype (Full_View (BT2));
2829 else
2830 Par := Etype (BT2);
2831 end if;
2833 loop
2834 -- If there was a error on the type declaration, do not recurse
2836 if Error_Posted (Par) then
2837 return False;
2839 elsif BT1 = Base_Type (Par)
2840 or else (Is_Private_Type (T1)
2841 and then Present (Full_View (T1))
2842 and then Base_Type (Par) = Base_Type (Full_View (T1)))
2843 then
2844 return True;
2846 elsif Is_Private_Type (Par)
2847 and then Present (Full_View (Par))
2848 and then Full_View (Par) = BT1
2849 then
2850 return True;
2852 -- Root type found
2854 elsif Par = Root_Type (Par) then
2855 return False;
2857 -- Continue climbing
2859 else
2860 -- Use the full-view of private types (if allowed)
2862 if Use_Full_View
2863 and then Is_Private_Type (Par)
2864 and then Present (Full_View (Par))
2865 then
2866 Par := Etype (Full_View (Par));
2867 else
2868 Par := Etype (Par);
2869 end if;
2870 end if;
2871 end loop;
2872 end if;
2873 end Is_Ancestor;
2875 ---------------------------
2876 -- Is_Invisible_Operator --
2877 ---------------------------
2879 function Is_Invisible_Operator
2880 (N : Node_Id;
2881 T : Entity_Id) return Boolean
2883 Orig_Node : constant Node_Id := Original_Node (N);
2885 begin
2886 if Nkind (N) not in N_Op then
2887 return False;
2889 elsif not Comes_From_Source (N) then
2890 return False;
2892 elsif No (Universal_Interpretation (Right_Opnd (N))) then
2893 return False;
2895 elsif Nkind (N) in N_Binary_Op
2896 and then No (Universal_Interpretation (Left_Opnd (N)))
2897 then
2898 return False;
2900 else
2901 return Is_Numeric_Type (T)
2902 and then not In_Open_Scopes (Scope (T))
2903 and then not Is_Potentially_Use_Visible (T)
2904 and then not In_Use (T)
2905 and then not In_Use (Scope (T))
2906 and then
2907 (Nkind (Orig_Node) /= N_Function_Call
2908 or else Nkind (Name (Orig_Node)) /= N_Expanded_Name
2909 or else Entity (Prefix (Name (Orig_Node))) /= Scope (T))
2910 and then not In_Instance;
2911 end if;
2912 end Is_Invisible_Operator;
2914 --------------------
2915 -- Is_Progenitor --
2916 --------------------
2918 function Is_Progenitor
2919 (Iface : Entity_Id;
2920 Typ : Entity_Id) return Boolean
2922 begin
2923 return Implements_Interface (Typ, Iface, Exclude_Parents => True);
2924 end Is_Progenitor;
2926 -------------------
2927 -- Is_Subtype_Of --
2928 -------------------
2930 function Is_Subtype_Of (T1 : Entity_Id; T2 : Entity_Id) return Boolean is
2931 S : Entity_Id;
2933 begin
2934 S := Ancestor_Subtype (T1);
2935 while Present (S) loop
2936 if S = T2 then
2937 return True;
2938 else
2939 S := Ancestor_Subtype (S);
2940 end if;
2941 end loop;
2943 return False;
2944 end Is_Subtype_Of;
2946 ------------------
2947 -- List_Interps --
2948 ------------------
2950 procedure List_Interps (Nam : Node_Id; Err : Node_Id) is
2951 Index : Interp_Index;
2952 It : Interp;
2954 begin
2955 Get_First_Interp (Nam, Index, It);
2956 while Present (It.Nam) loop
2957 if Scope (It.Nam) = Standard_Standard
2958 and then Scope (It.Typ) /= Standard_Standard
2959 then
2960 Error_Msg_Sloc := Sloc (Parent (It.Typ));
2961 Error_Msg_NE ("\\& (inherited) declared#!", Err, It.Nam);
2963 else
2964 Error_Msg_Sloc := Sloc (It.Nam);
2965 Error_Msg_NE ("\\& declared#!", Err, It.Nam);
2966 end if;
2968 Get_Next_Interp (Index, It);
2969 end loop;
2970 end List_Interps;
2972 -----------------
2973 -- New_Interps --
2974 -----------------
2976 procedure New_Interps (N : Node_Id) is
2977 Map_Ptr : Int;
2979 begin
2980 All_Interp.Append (No_Interp);
2982 Map_Ptr := Headers (Hash (N));
2984 if Map_Ptr = No_Entry then
2986 -- Place new node at end of table
2988 Interp_Map.Increment_Last;
2989 Headers (Hash (N)) := Interp_Map.Last;
2991 else
2992 -- Place node at end of chain, or locate its previous entry
2994 loop
2995 if Interp_Map.Table (Map_Ptr).Node = N then
2997 -- Node is already in the table, and is being rewritten.
2998 -- Start a new interp section, retain hash link.
3000 Interp_Map.Table (Map_Ptr).Node := N;
3001 Interp_Map.Table (Map_Ptr).Index := All_Interp.Last;
3002 Set_Is_Overloaded (N, True);
3003 return;
3005 else
3006 exit when Interp_Map.Table (Map_Ptr).Next = No_Entry;
3007 Map_Ptr := Interp_Map.Table (Map_Ptr).Next;
3008 end if;
3009 end loop;
3011 -- Chain the new node
3013 Interp_Map.Increment_Last;
3014 Interp_Map.Table (Map_Ptr).Next := Interp_Map.Last;
3015 end if;
3017 Interp_Map.Table (Interp_Map.Last) := (N, All_Interp.Last, No_Entry);
3018 Set_Is_Overloaded (N, True);
3019 end New_Interps;
3021 ---------------------------
3022 -- Operator_Matches_Spec --
3023 ---------------------------
3025 function Operator_Matches_Spec (Op, New_S : Entity_Id) return Boolean is
3026 Op_Name : constant Name_Id := Chars (Op);
3027 T : constant Entity_Id := Etype (New_S);
3028 New_F : Entity_Id;
3029 Old_F : Entity_Id;
3030 Num : Int;
3031 T1 : Entity_Id;
3032 T2 : Entity_Id;
3034 begin
3035 -- To verify that a predefined operator matches a given signature,
3036 -- do a case analysis of the operator classes. Function can have one
3037 -- or two formals and must have the proper result type.
3039 New_F := First_Formal (New_S);
3040 Old_F := First_Formal (Op);
3041 Num := 0;
3042 while Present (New_F) and then Present (Old_F) loop
3043 Num := Num + 1;
3044 Next_Formal (New_F);
3045 Next_Formal (Old_F);
3046 end loop;
3048 -- Definite mismatch if different number of parameters
3050 if Present (Old_F) or else Present (New_F) then
3051 return False;
3053 -- Unary operators
3055 elsif Num = 1 then
3056 T1 := Etype (First_Formal (New_S));
3058 if Nam_In (Op_Name, Name_Op_Subtract, Name_Op_Add, Name_Op_Abs) then
3059 return Base_Type (T1) = Base_Type (T)
3060 and then Is_Numeric_Type (T);
3062 elsif Op_Name = Name_Op_Not then
3063 return Base_Type (T1) = Base_Type (T)
3064 and then Valid_Boolean_Arg (Base_Type (T));
3066 else
3067 return False;
3068 end if;
3070 -- Binary operators
3072 else
3073 T1 := Etype (First_Formal (New_S));
3074 T2 := Etype (Next_Formal (First_Formal (New_S)));
3076 if Nam_In (Op_Name, Name_Op_And, Name_Op_Or, Name_Op_Xor) then
3077 return Base_Type (T1) = Base_Type (T2)
3078 and then Base_Type (T1) = Base_Type (T)
3079 and then Valid_Boolean_Arg (Base_Type (T));
3081 elsif Nam_In (Op_Name, Name_Op_Eq, Name_Op_Ne) then
3082 return Base_Type (T1) = Base_Type (T2)
3083 and then not Is_Limited_Type (T1)
3084 and then Is_Boolean_Type (T);
3086 elsif Nam_In (Op_Name, Name_Op_Lt, Name_Op_Le,
3087 Name_Op_Gt, Name_Op_Ge)
3088 then
3089 return Base_Type (T1) = Base_Type (T2)
3090 and then Valid_Comparison_Arg (T1)
3091 and then Is_Boolean_Type (T);
3093 elsif Nam_In (Op_Name, Name_Op_Add, Name_Op_Subtract) then
3094 return Base_Type (T1) = Base_Type (T2)
3095 and then Base_Type (T1) = Base_Type (T)
3096 and then Is_Numeric_Type (T);
3098 -- For division and multiplication, a user-defined function does not
3099 -- match the predefined universal_fixed operation, except in Ada 83.
3101 elsif Op_Name = Name_Op_Divide then
3102 return (Base_Type (T1) = Base_Type (T2)
3103 and then Base_Type (T1) = Base_Type (T)
3104 and then Is_Numeric_Type (T)
3105 and then (not Is_Fixed_Point_Type (T)
3106 or else Ada_Version = Ada_83))
3108 -- Mixed_Mode operations on fixed-point types
3110 or else (Base_Type (T1) = Base_Type (T)
3111 and then Base_Type (T2) = Base_Type (Standard_Integer)
3112 and then Is_Fixed_Point_Type (T))
3114 -- A user defined operator can also match (and hide) a mixed
3115 -- operation on universal literals.
3117 or else (Is_Integer_Type (T2)
3118 and then Is_Floating_Point_Type (T1)
3119 and then Base_Type (T1) = Base_Type (T));
3121 elsif Op_Name = Name_Op_Multiply then
3122 return (Base_Type (T1) = Base_Type (T2)
3123 and then Base_Type (T1) = Base_Type (T)
3124 and then Is_Numeric_Type (T)
3125 and then (not Is_Fixed_Point_Type (T)
3126 or else Ada_Version = Ada_83))
3128 -- Mixed_Mode operations on fixed-point types
3130 or else (Base_Type (T1) = Base_Type (T)
3131 and then Base_Type (T2) = Base_Type (Standard_Integer)
3132 and then Is_Fixed_Point_Type (T))
3134 or else (Base_Type (T2) = Base_Type (T)
3135 and then Base_Type (T1) = Base_Type (Standard_Integer)
3136 and then Is_Fixed_Point_Type (T))
3138 or else (Is_Integer_Type (T2)
3139 and then Is_Floating_Point_Type (T1)
3140 and then Base_Type (T1) = Base_Type (T))
3142 or else (Is_Integer_Type (T1)
3143 and then Is_Floating_Point_Type (T2)
3144 and then Base_Type (T2) = Base_Type (T));
3146 elsif Nam_In (Op_Name, Name_Op_Mod, Name_Op_Rem) then
3147 return Base_Type (T1) = Base_Type (T2)
3148 and then Base_Type (T1) = Base_Type (T)
3149 and then Is_Integer_Type (T);
3151 elsif Op_Name = Name_Op_Expon then
3152 return Base_Type (T1) = Base_Type (T)
3153 and then Is_Numeric_Type (T)
3154 and then Base_Type (T2) = Base_Type (Standard_Integer);
3156 elsif Op_Name = Name_Op_Concat then
3157 return Is_Array_Type (T)
3158 and then (Base_Type (T) = Base_Type (Etype (Op)))
3159 and then (Base_Type (T1) = Base_Type (T)
3160 or else
3161 Base_Type (T1) = Base_Type (Component_Type (T)))
3162 and then (Base_Type (T2) = Base_Type (T)
3163 or else
3164 Base_Type (T2) = Base_Type (Component_Type (T)));
3166 else
3167 return False;
3168 end if;
3169 end if;
3170 end Operator_Matches_Spec;
3172 -------------------
3173 -- Remove_Interp --
3174 -------------------
3176 procedure Remove_Interp (I : in out Interp_Index) is
3177 II : Interp_Index;
3179 begin
3180 -- Find end of interp list and copy downward to erase the discarded one
3182 II := I + 1;
3183 while Present (All_Interp.Table (II).Typ) loop
3184 II := II + 1;
3185 end loop;
3187 for J in I + 1 .. II loop
3188 All_Interp.Table (J - 1) := All_Interp.Table (J);
3189 end loop;
3191 -- Back up interp index to insure that iterator will pick up next
3192 -- available interpretation.
3194 I := I - 1;
3195 end Remove_Interp;
3197 ------------------
3198 -- Save_Interps --
3199 ------------------
3201 procedure Save_Interps (Old_N : Node_Id; New_N : Node_Id) is
3202 Map_Ptr : Int;
3203 O_N : Node_Id := Old_N;
3205 begin
3206 if Is_Overloaded (Old_N) then
3207 if Nkind (Old_N) = N_Selected_Component
3208 and then Is_Overloaded (Selector_Name (Old_N))
3209 then
3210 O_N := Selector_Name (Old_N);
3211 end if;
3213 Map_Ptr := Headers (Hash (O_N));
3215 while Interp_Map.Table (Map_Ptr).Node /= O_N loop
3216 Map_Ptr := Interp_Map.Table (Map_Ptr).Next;
3217 pragma Assert (Map_Ptr /= No_Entry);
3218 end loop;
3220 New_Interps (New_N);
3221 Interp_Map.Table (Interp_Map.Last).Index :=
3222 Interp_Map.Table (Map_Ptr).Index;
3223 end if;
3224 end Save_Interps;
3226 -------------------
3227 -- Specific_Type --
3228 -------------------
3230 function Specific_Type (Typ_1, Typ_2 : Entity_Id) return Entity_Id is
3231 T1 : constant Entity_Id := Available_View (Typ_1);
3232 T2 : constant Entity_Id := Available_View (Typ_2);
3233 B1 : constant Entity_Id := Base_Type (T1);
3234 B2 : constant Entity_Id := Base_Type (T2);
3236 function Is_Remote_Access (T : Entity_Id) return Boolean;
3237 -- Check whether T is the equivalent type of a remote access type.
3238 -- If distribution is enabled, T is a legal context for Null.
3240 ----------------------
3241 -- Is_Remote_Access --
3242 ----------------------
3244 function Is_Remote_Access (T : Entity_Id) return Boolean is
3245 begin
3246 return Is_Record_Type (T)
3247 and then (Is_Remote_Call_Interface (T)
3248 or else Is_Remote_Types (T))
3249 and then Present (Corresponding_Remote_Type (T))
3250 and then Is_Access_Type (Corresponding_Remote_Type (T));
3251 end Is_Remote_Access;
3253 -- Start of processing for Specific_Type
3255 begin
3256 if T1 = Any_Type or else T2 = Any_Type then
3257 return Any_Type;
3258 end if;
3260 if B1 = B2 then
3261 return B1;
3263 elsif (T1 = Universal_Integer and then Is_Integer_Type (T2))
3264 or else (T1 = Universal_Real and then Is_Real_Type (T2))
3265 or else (T1 = Universal_Fixed and then Is_Fixed_Point_Type (T2))
3266 or else (T1 = Any_Fixed and then Is_Fixed_Point_Type (T2))
3267 then
3268 return B2;
3270 elsif (T2 = Universal_Integer and then Is_Integer_Type (T1))
3271 or else (T2 = Universal_Real and then Is_Real_Type (T1))
3272 or else (T2 = Universal_Fixed and then Is_Fixed_Point_Type (T1))
3273 or else (T2 = Any_Fixed and then Is_Fixed_Point_Type (T1))
3274 then
3275 return B1;
3277 elsif T2 = Any_String and then Is_String_Type (T1) then
3278 return B1;
3280 elsif T1 = Any_String and then Is_String_Type (T2) then
3281 return B2;
3283 elsif T2 = Any_Character and then Is_Character_Type (T1) then
3284 return B1;
3286 elsif T1 = Any_Character and then Is_Character_Type (T2) then
3287 return B2;
3289 elsif T1 = Any_Access
3290 and then (Is_Access_Type (T2) or else Is_Remote_Access (T2))
3291 then
3292 return T2;
3294 elsif T2 = Any_Access
3295 and then (Is_Access_Type (T1) or else Is_Remote_Access (T1))
3296 then
3297 return T1;
3299 -- In an instance, the specific type may have a private view. Use full
3300 -- view to check legality.
3302 elsif T2 = Any_Access
3303 and then Is_Private_Type (T1)
3304 and then Present (Full_View (T1))
3305 and then Is_Access_Type (Full_View (T1))
3306 and then In_Instance
3307 then
3308 return T1;
3310 elsif T2 = Any_Composite
3311 and then Is_Aggregate_Type (T1)
3312 then
3313 return T1;
3315 elsif T1 = Any_Composite
3316 and then Is_Aggregate_Type (T2)
3317 then
3318 return T2;
3320 elsif T1 = Any_Modular and then Is_Modular_Integer_Type (T2) then
3321 return T2;
3323 elsif T2 = Any_Modular and then Is_Modular_Integer_Type (T1) then
3324 return T1;
3326 -- ----------------------------------------------------------
3327 -- Special cases for equality operators (all other predefined
3328 -- operators can never apply to tagged types)
3329 -- ----------------------------------------------------------
3331 -- Ada 2005 (AI-251): T1 and T2 are class-wide types, and T2 is an
3332 -- interface
3334 elsif Is_Class_Wide_Type (T1)
3335 and then Is_Class_Wide_Type (T2)
3336 and then Is_Interface (Etype (T2))
3337 then
3338 return T1;
3340 -- Ada 2005 (AI-251): T1 is a concrete type that implements the
3341 -- class-wide interface T2
3343 elsif Is_Class_Wide_Type (T2)
3344 and then Is_Interface (Etype (T2))
3345 and then Interface_Present_In_Ancestor (Typ => T1,
3346 Iface => Etype (T2))
3347 then
3348 return T1;
3350 elsif Is_Class_Wide_Type (T1)
3351 and then Is_Ancestor (Root_Type (T1), T2)
3352 then
3353 return T1;
3355 elsif Is_Class_Wide_Type (T2)
3356 and then Is_Ancestor (Root_Type (T2), T1)
3357 then
3358 return T2;
3360 elsif (Ekind (B1) = E_Access_Subprogram_Type
3361 or else
3362 Ekind (B1) = E_Access_Protected_Subprogram_Type)
3363 and then Ekind (Designated_Type (B1)) /= E_Subprogram_Type
3364 and then Is_Access_Type (T2)
3365 then
3366 return T2;
3368 elsif (Ekind (B2) = E_Access_Subprogram_Type
3369 or else
3370 Ekind (B2) = E_Access_Protected_Subprogram_Type)
3371 and then Ekind (Designated_Type (B2)) /= E_Subprogram_Type
3372 and then Is_Access_Type (T1)
3373 then
3374 return T1;
3376 elsif (Ekind (T1) = E_Allocator_Type
3377 or else Ekind (T1) = E_Access_Attribute_Type
3378 or else Ekind (T1) = E_Anonymous_Access_Type)
3379 and then Is_Access_Type (T2)
3380 then
3381 return T2;
3383 elsif (Ekind (T2) = E_Allocator_Type
3384 or else Ekind (T2) = E_Access_Attribute_Type
3385 or else Ekind (T2) = E_Anonymous_Access_Type)
3386 and then Is_Access_Type (T1)
3387 then
3388 return T1;
3390 -- If none of the above cases applies, types are not compatible
3392 else
3393 return Any_Type;
3394 end if;
3395 end Specific_Type;
3397 ---------------------
3398 -- Set_Abstract_Op --
3399 ---------------------
3401 procedure Set_Abstract_Op (I : Interp_Index; V : Entity_Id) is
3402 begin
3403 All_Interp.Table (I).Abstract_Op := V;
3404 end Set_Abstract_Op;
3406 -----------------------
3407 -- Valid_Boolean_Arg --
3408 -----------------------
3410 -- In addition to booleans and arrays of booleans, we must include
3411 -- aggregates as valid boolean arguments, because in the first pass of
3412 -- resolution their components are not examined. If it turns out not to be
3413 -- an aggregate of booleans, this will be diagnosed in Resolve.
3414 -- Any_Composite must be checked for prior to the array type checks because
3415 -- Any_Composite does not have any associated indexes.
3417 function Valid_Boolean_Arg (T : Entity_Id) return Boolean is
3418 begin
3419 if Is_Boolean_Type (T)
3420 or else Is_Modular_Integer_Type (T)
3421 or else T = Universal_Integer
3422 or else T = Any_Composite
3423 then
3424 return True;
3426 elsif Is_Array_Type (T)
3427 and then T /= Any_String
3428 and then Number_Dimensions (T) = 1
3429 and then Is_Boolean_Type (Component_Type (T))
3430 and then
3431 ((not Is_Private_Composite (T)
3432 and then not Is_Limited_Composite (T))
3433 or else In_Instance
3434 or else Available_Full_View_Of_Component (T))
3435 then
3436 return True;
3438 else
3439 return False;
3440 end if;
3441 end Valid_Boolean_Arg;
3443 --------------------------
3444 -- Valid_Comparison_Arg --
3445 --------------------------
3447 function Valid_Comparison_Arg (T : Entity_Id) return Boolean is
3448 begin
3450 if T = Any_Composite then
3451 return False;
3453 elsif Is_Discrete_Type (T)
3454 or else Is_Real_Type (T)
3455 then
3456 return True;
3458 elsif Is_Array_Type (T)
3459 and then Number_Dimensions (T) = 1
3460 and then Is_Discrete_Type (Component_Type (T))
3461 and then (not Is_Private_Composite (T)
3462 or else In_Instance)
3463 and then (not Is_Limited_Composite (T)
3464 or else In_Instance)
3465 then
3466 return True;
3468 elsif Is_Array_Type (T)
3469 and then Number_Dimensions (T) = 1
3470 and then Is_Discrete_Type (Component_Type (T))
3471 and then Available_Full_View_Of_Component (T)
3472 then
3473 return True;
3475 elsif Is_String_Type (T) then
3476 return True;
3477 else
3478 return False;
3479 end if;
3480 end Valid_Comparison_Arg;
3482 ------------------
3483 -- Write_Interp --
3484 ------------------
3486 procedure Write_Interp (It : Interp) is
3487 begin
3488 Write_Str ("Nam: ");
3489 Print_Tree_Node (It.Nam);
3490 Write_Str ("Typ: ");
3491 Print_Tree_Node (It.Typ);
3492 Write_Str ("Abstract_Op: ");
3493 Print_Tree_Node (It.Abstract_Op);
3494 end Write_Interp;
3496 ----------------------
3497 -- Write_Interp_Ref --
3498 ----------------------
3500 procedure Write_Interp_Ref (Map_Ptr : Int) is
3501 begin
3502 Write_Str (" Node: ");
3503 Write_Int (Int (Interp_Map.Table (Map_Ptr).Node));
3504 Write_Str (" Index: ");
3505 Write_Int (Int (Interp_Map.Table (Map_Ptr).Index));
3506 Write_Str (" Next: ");
3507 Write_Int (Interp_Map.Table (Map_Ptr).Next);
3508 Write_Eol;
3509 end Write_Interp_Ref;
3511 ---------------------
3512 -- Write_Overloads --
3513 ---------------------
3515 procedure Write_Overloads (N : Node_Id) is
3516 I : Interp_Index;
3517 It : Interp;
3518 Nam : Entity_Id;
3520 begin
3521 Write_Str ("Overloads: ");
3522 Print_Node_Briefly (N);
3524 if Nkind (N) not in N_Has_Entity then
3525 return;
3526 end if;
3528 if not Is_Overloaded (N) then
3529 Write_Str ("Non-overloaded entity ");
3530 Write_Eol;
3531 Write_Entity_Info (Entity (N), " ");
3533 else
3534 Get_First_Interp (N, I, It);
3535 Write_Str ("Overloaded entity ");
3536 Write_Eol;
3537 Write_Str (" Name Type Abstract Op");
3538 Write_Eol;
3539 Write_Str ("===============================================");
3540 Write_Eol;
3541 Nam := It.Nam;
3543 while Present (Nam) loop
3544 Write_Int (Int (Nam));
3545 Write_Str (" ");
3546 Write_Name (Chars (Nam));
3547 Write_Str (" ");
3548 Write_Int (Int (It.Typ));
3549 Write_Str (" ");
3550 Write_Name (Chars (It.Typ));
3552 if Present (It.Abstract_Op) then
3553 Write_Str (" ");
3554 Write_Int (Int (It.Abstract_Op));
3555 Write_Str (" ");
3556 Write_Name (Chars (It.Abstract_Op));
3557 end if;
3559 Write_Eol;
3560 Get_Next_Interp (I, It);
3561 Nam := It.Nam;
3562 end loop;
3563 end if;
3564 end Write_Overloads;
3566 end Sem_Type;