PR tree-optimization/85699
[official-gcc.git] / gcc / ada / exp_dbug.adb
bloba50dad9c02ca749cad7b828ff36775d952b9b6ae
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- E X P _ D B U G --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1996-2018, 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 Alloc;
27 with Atree; use Atree;
28 with Debug; use Debug;
29 with Einfo; use Einfo;
30 with Nlists; use Nlists;
31 with Nmake; use Nmake;
32 with Opt; use Opt;
33 with Output; use Output;
34 with Sem_Aux; use Sem_Aux;
35 with Sem_Eval; use Sem_Eval;
36 with Sem_Util; use Sem_Util;
37 with Sinfo; use Sinfo;
38 with Stand; use Stand;
39 with Stringt; use Stringt;
40 with Table;
41 with Tbuild; use Tbuild;
42 with Urealp; use Urealp;
44 package body Exp_Dbug is
46 -- The following table is used to queue up the entities passed as
47 -- arguments to Qualify_Entity_Names for later processing when
48 -- Qualify_All_Entity_Names is called.
50 package Name_Qualify_Units is new Table.Table (
51 Table_Component_Type => Node_Id,
52 Table_Index_Type => Nat,
53 Table_Low_Bound => 1,
54 Table_Initial => Alloc.Name_Qualify_Units_Initial,
55 Table_Increment => Alloc.Name_Qualify_Units_Increment,
56 Table_Name => "Name_Qualify_Units");
58 --------------------------------
59 -- Use of Qualification Flags --
60 --------------------------------
62 -- There are two flags used to keep track of qualification of entities
64 -- Has_Fully_Qualified_Name
65 -- Has_Qualified_Name
67 -- The difference between these is as follows. Has_Qualified_Name is
68 -- set to indicate that the name has been qualified as required by the
69 -- spec of this package. As described there, this may involve the full
70 -- qualification for the name, but for some entities, notably procedure
71 -- local variables, this full qualification is not required.
73 -- The flag Has_Fully_Qualified_Name is set if indeed the name has been
74 -- fully qualified in the Ada sense. If Has_Fully_Qualified_Name is set,
75 -- then Has_Qualified_Name is also set, but the other way round is not
76 -- the case.
78 -- Consider the following example:
80 -- with ...
81 -- procedure X is
82 -- B : Ddd.Ttt;
83 -- procedure Y is ..
85 -- Here B is a procedure local variable, so it does not need fully
86 -- qualification. The flag Has_Qualified_Name will be set on the
87 -- first attempt to qualify B, to indicate that the job is done
88 -- and need not be redone.
90 -- But Y is qualified as x__y, since procedures are always fully
91 -- qualified, so the first time that an attempt is made to qualify
92 -- the name y, it will be replaced by x__y, and both flags are set.
94 -- Why the two flags? Well there are cases where we derive type names
95 -- from object names. As noted in the spec, type names are always
96 -- fully qualified. Suppose for example that the backend has to build
97 -- a padded type for variable B. then it will construct the PAD name
98 -- from B, but it requires full qualification, so the fully qualified
99 -- type name will be x__b___PAD. The two flags allow the circuit for
100 -- building this name to realize efficiently that b needs further
101 -- qualification.
103 --------------------
104 -- Homonym_Suffix --
105 --------------------
107 -- The string defined here (and its associated length) is used to gather
108 -- the homonym string that will be appended to Name_Buffer when the name
109 -- is complete. Strip_Suffixes appends to this string as does
110 -- Append_Homonym_Number, and Output_Homonym_Numbers_Suffix appends the
111 -- string to the end of Name_Buffer.
113 Homonym_Numbers : String (1 .. 256);
114 Homonym_Len : Natural := 0;
116 ----------------------
117 -- Local Procedures --
118 ----------------------
120 procedure Add_Uint_To_Buffer (U : Uint);
121 -- Add image of universal integer to Name_Buffer, updating Name_Len
123 procedure Add_Real_To_Buffer (U : Ureal);
124 -- Add nnn_ddd to Name_Buffer, where nnn and ddd are integer values of
125 -- the normalized numerator and denominator of the given real value.
127 procedure Append_Homonym_Number (E : Entity_Id);
128 -- If the entity E has homonyms in the same scope, then make an entry
129 -- in the Homonym_Numbers array, bumping Homonym_Count accordingly.
131 function Bounds_Match_Size (E : Entity_Id) return Boolean;
132 -- Determine whether the bounds of E match the size of the type. This is
133 -- used to determine whether encoding is required for a discrete type.
135 function Is_Handled_Scale_Factor (U : Ureal) return Boolean;
136 -- The argument U is the Small_Value of a fixed-point type. This function
137 -- determines whether the back-end can handle this scale factor. When it
138 -- cannot, we have to output a GNAT encoding for the corresponding type.
140 procedure Output_Homonym_Numbers_Suffix;
141 -- If homonym numbers are stored, then output them into Name_Buffer
143 procedure Prepend_String_To_Buffer (S : String);
144 -- Prepend given string to the contents of the string buffer, updating
145 -- the value in Name_Len (i.e. string is added at start of buffer).
147 procedure Prepend_Uint_To_Buffer (U : Uint);
148 -- Prepend image of universal integer to Name_Buffer, updating Name_Len
150 procedure Qualify_Entity_Name (Ent : Entity_Id);
151 -- If not already done, replaces the Chars field of the given entity
152 -- with the appropriate fully qualified name.
154 procedure Reset_Buffers;
155 -- Reset the contents of Name_Buffer and Homonym_Numbers by setting their
156 -- respective lengths to zero.
158 procedure Strip_Suffixes (BNPE_Suffix_Found : in out Boolean);
159 -- Given an qualified entity name in Name_Buffer, remove any plain X or
160 -- X{nb} qualification suffix. The contents of Name_Buffer is not changed
161 -- but Name_Len may be adjusted on return to remove the suffix. If a
162 -- BNPE suffix is found and stripped, then BNPE_Suffix_Found is set to
163 -- True. If no suffix is found, then BNPE_Suffix_Found is not modified.
164 -- This routine also searches for a homonym suffix, and if one is found
165 -- it is also stripped, and the entries are added to the global homonym
166 -- list (Homonym_Numbers) so that they can later be put back.
168 ------------------------
169 -- Add_Real_To_Buffer --
170 ------------------------
172 procedure Add_Real_To_Buffer (U : Ureal) is
173 begin
174 Add_Uint_To_Buffer (Norm_Num (U));
175 Add_Str_To_Name_Buffer ("_");
176 Add_Uint_To_Buffer (Norm_Den (U));
177 end Add_Real_To_Buffer;
179 ------------------------
180 -- Add_Uint_To_Buffer --
181 ------------------------
183 procedure Add_Uint_To_Buffer (U : Uint) is
184 begin
185 if U < 0 then
186 Add_Uint_To_Buffer (-U);
187 Add_Char_To_Name_Buffer ('m');
188 else
189 UI_Image (U, Decimal);
190 Add_Str_To_Name_Buffer (UI_Image_Buffer (1 .. UI_Image_Length));
191 end if;
192 end Add_Uint_To_Buffer;
194 ---------------------------
195 -- Append_Homonym_Number --
196 ---------------------------
198 procedure Append_Homonym_Number (E : Entity_Id) is
200 procedure Add_Nat_To_H (Nr : Nat);
201 -- Little procedure to append Nr to Homonym_Numbers
203 ------------------
204 -- Add_Nat_To_H --
205 ------------------
207 procedure Add_Nat_To_H (Nr : Nat) is
208 begin
209 if Nr >= 10 then
210 Add_Nat_To_H (Nr / 10);
211 end if;
213 Homonym_Len := Homonym_Len + 1;
214 Homonym_Numbers (Homonym_Len) :=
215 Character'Val (Nr mod 10 + Character'Pos ('0'));
216 end Add_Nat_To_H;
218 -- Start of processing for Append_Homonym_Number
220 begin
221 if Has_Homonym (E) then
222 declare
223 H : Entity_Id := Homonym (E);
224 Nr : Nat := 1;
226 begin
227 while Present (H) loop
228 if Scope (H) = Scope (E) then
229 Nr := Nr + 1;
230 end if;
232 H := Homonym (H);
233 end loop;
235 if Homonym_Len > 0 then
236 Homonym_Len := Homonym_Len + 1;
237 Homonym_Numbers (Homonym_Len) := '_';
238 end if;
240 Add_Nat_To_H (Nr);
241 end;
242 end if;
243 end Append_Homonym_Number;
245 -----------------------
246 -- Bounds_Match_Size --
247 -----------------------
249 function Bounds_Match_Size (E : Entity_Id) return Boolean is
250 Siz : Uint;
252 begin
253 if not Is_OK_Static_Subtype (E) then
254 return False;
256 elsif Is_Integer_Type (E)
257 and then Subtypes_Statically_Match (E, Base_Type (E))
258 then
259 return True;
261 -- Here we check if the static bounds match the natural size, which is
262 -- the size passed through with the debugging information. This is the
263 -- Esize rounded up to 8, 16, 32 or 64 as appropriate.
265 else
266 declare
267 Umark : constant Uintp.Save_Mark := Uintp.Mark;
268 Result : Boolean;
270 begin
271 if Esize (E) <= 8 then
272 Siz := Uint_8;
273 elsif Esize (E) <= 16 then
274 Siz := Uint_16;
275 elsif Esize (E) <= 32 then
276 Siz := Uint_32;
277 else
278 Siz := Uint_64;
279 end if;
281 if Is_Modular_Integer_Type (E) or else Is_Enumeration_Type (E) then
282 Result :=
283 Expr_Rep_Value (Type_Low_Bound (E)) = 0
284 and then
285 2 ** Siz - Expr_Rep_Value (Type_High_Bound (E)) = 1;
287 else
288 Result :=
289 Expr_Rep_Value (Type_Low_Bound (E)) + 2 ** (Siz - 1) = 0
290 and then
291 2 ** (Siz - 1) - Expr_Rep_Value (Type_High_Bound (E)) = 1;
292 end if;
294 Release (Umark);
295 return Result;
296 end;
297 end if;
298 end Bounds_Match_Size;
300 --------------------------------
301 -- Debug_Renaming_Declaration --
302 --------------------------------
304 function Debug_Renaming_Declaration (N : Node_Id) return Node_Id is
305 Loc : constant Source_Ptr := Sloc (N);
306 Ent : constant Node_Id := Defining_Entity (N);
307 Nam : constant Node_Id := Name (N);
308 Ren : Node_Id;
309 Typ : Entity_Id;
310 Obj : Entity_Id;
311 Res : Node_Id;
313 Enable : Boolean := Nkind (N) = N_Package_Renaming_Declaration;
314 -- By default, we do not generate an encoding for renaming. This is
315 -- however done (in which case this is set to True) in a few cases:
316 -- - when a package is renamed,
317 -- - when the renaming involves a packed array,
318 -- - when the renaming involves a packed record.
320 Last_Is_Indexed_Comp : Boolean := False;
321 -- Whether the last subscript value was an indexed component access (XS)
323 procedure Enable_If_Packed_Array (N : Node_Id);
324 -- Enable encoding generation if N is a packed array
326 function Output_Subscript (N : Node_Id; S : String) return Boolean;
327 -- Outputs a single subscript value as ?nnn (subscript is compile time
328 -- known value with value nnn) or as ?e (subscript is local constant
329 -- with name e), where S supplies the proper string to use for ?.
330 -- Returns False if the subscript is not of an appropriate type to
331 -- output in one of these two forms. The result is prepended to the
332 -- name stored in Name_Buffer.
334 function Scope_Contains (Sc : Node_Id; Ent : Entity_Id) return Boolean;
335 -- Return whether Ent belong to the Sc scope
337 ----------------------------
338 -- Enable_If_Packed_Array --
339 ----------------------------
341 procedure Enable_If_Packed_Array (N : Node_Id) is
342 T : constant Entity_Id := Underlying_Type (Etype (N));
344 begin
345 Enable :=
346 Enable
347 or else
348 (Ekind (T) in Array_Kind
349 and then Present (Packed_Array_Impl_Type (T)));
350 end Enable_If_Packed_Array;
352 ----------------------
353 -- Output_Subscript --
354 ----------------------
356 function Output_Subscript (N : Node_Id; S : String) return Boolean is
357 begin
358 if Compile_Time_Known_Value (N) then
359 Prepend_Uint_To_Buffer (Expr_Value (N));
361 elsif Nkind (N) = N_Identifier
362 and then Scope_Contains (Scope (Entity (N)), Ent)
363 and then (Ekind (Entity (N)) = E_Constant
364 or else Ekind (Entity (N)) = E_In_Parameter)
365 then
366 Prepend_String_To_Buffer (Get_Name_String (Chars (Entity (N))));
368 else
369 return False;
370 end if;
372 Prepend_String_To_Buffer (S);
373 return True;
374 end Output_Subscript;
376 --------------------
377 -- Scope_Contains --
378 --------------------
380 function Scope_Contains (Sc : Node_Id; Ent : Entity_Id) return Boolean is
381 Cur : Node_Id := Scope (Ent);
383 begin
384 while Present (Cur) loop
385 if Cur = Sc then
386 return True;
387 end if;
389 Cur := Scope (Cur);
390 end loop;
392 return False;
393 end Scope_Contains;
395 -- Start of processing for Debug_Renaming_Declaration
397 begin
398 if not Comes_From_Source (N) and then not Needs_Debug_Info (Ent) then
399 return Empty;
400 end if;
402 -- Get renamed entity and compute suffix
404 Name_Len := 0;
405 Ren := Nam;
406 loop
407 -- The expression that designates the renamed object is sometimes
408 -- expanded into bit-wise operations. We want to work instead on
409 -- array/record components accesses, so try to analyze the unexpanded
410 -- forms.
412 Ren := Original_Node (Ren);
414 case Nkind (Ren) is
415 when N_Expanded_Name
416 | N_Identifier
418 if not Present (Renamed_Object (Entity (Ren))) then
419 exit;
420 end if;
422 -- This is a renaming of a renaming: traverse until the final
423 -- renaming to see if anything is packed along the way.
425 Ren := Renamed_Object (Entity (Ren));
427 when N_Selected_Component =>
428 declare
429 Sel_Id : constant Entity_Id :=
430 Entity (Selector_Name (Ren));
431 First_Bit : Uint;
433 begin
434 -- If the renaming involves a call to a primitive function,
435 -- we are out of the scope of renaming encodings. We will
436 -- very likely create a variable to hold the renamed value
437 -- anyway, so the renaming entity will be available in
438 -- debuggers.
440 exit when not Ekind_In (Sel_Id, E_Component, E_Discriminant);
442 First_Bit := Normalized_First_Bit (Sel_Id);
443 Enable :=
444 Enable
445 or else Is_Packed
446 (Underlying_Type (Etype (Prefix (Ren))))
447 or else (First_Bit /= No_Uint
448 and then First_Bit /= Uint_0);
449 end;
451 Prepend_String_To_Buffer
452 (Get_Name_String (Chars (Selector_Name (Ren))));
453 Prepend_String_To_Buffer ("XR");
454 Ren := Prefix (Ren);
455 Last_Is_Indexed_Comp := False;
457 when N_Indexed_Component =>
458 declare
459 X : Node_Id;
461 begin
462 Enable_If_Packed_Array (Prefix (Ren));
464 X := Last (Expressions (Ren));
465 while Present (X) loop
466 if not Output_Subscript (X, "XS") then
467 Set_Materialize_Entity (Ent);
468 return Empty;
469 end if;
471 Prev (X);
472 Last_Is_Indexed_Comp := True;
473 end loop;
474 end;
476 Ren := Prefix (Ren);
478 when N_Slice =>
480 -- Assuming X is an array:
481 -- X (Y1 .. Y2) (Y3)
483 -- is equivalent to:
484 -- X (Y3)
486 -- GDB cannot handle packed array slices, so avoid describing
487 -- the slice if we can avoid it.
489 if not Last_Is_Indexed_Comp then
490 Enable_If_Packed_Array (Prefix (Ren));
491 Typ := Etype (First_Index (Etype (Ren)));
493 if not Output_Subscript (Type_High_Bound (Typ), "XS") then
494 Set_Materialize_Entity (Ent);
495 return Empty;
496 end if;
498 if not Output_Subscript (Type_Low_Bound (Typ), "XL") then
499 Set_Materialize_Entity (Ent);
500 return Empty;
501 end if;
503 Last_Is_Indexed_Comp := False;
504 end if;
506 Ren := Prefix (Ren);
508 when N_Explicit_Dereference =>
509 Prepend_String_To_Buffer ("XA");
510 Ren := Prefix (Ren);
511 Last_Is_Indexed_Comp := False;
513 -- For now, anything else simply results in no translation
515 when others =>
516 Set_Materialize_Entity (Ent);
517 return Empty;
518 end case;
519 end loop;
521 -- If we found no reason here to emit an encoding, stop now
523 if not Enable then
524 Set_Materialize_Entity (Ent);
525 return Empty;
526 end if;
528 Prepend_String_To_Buffer ("___XE");
530 -- Include the designation of the form of renaming
532 case Nkind (N) is
533 when N_Object_Renaming_Declaration =>
534 Prepend_String_To_Buffer ("___XR");
536 when N_Exception_Renaming_Declaration =>
537 Prepend_String_To_Buffer ("___XRE");
539 when N_Package_Renaming_Declaration =>
540 Prepend_String_To_Buffer ("___XRP");
542 when others =>
543 return Empty;
544 end case;
546 -- Add the name of the renaming entity to the front
548 Prepend_String_To_Buffer (Get_Name_String (Chars (Ent)));
550 -- If it is a child unit create a fully qualified name, to disambiguate
551 -- multiple child units with the same name and different parents.
553 if Nkind (N) = N_Package_Renaming_Declaration
554 and then Is_Child_Unit (Ent)
555 then
556 Prepend_String_To_Buffer ("__");
557 Prepend_String_To_Buffer
558 (Get_Name_String (Chars (Scope (Ent))));
559 end if;
561 -- Create the special object whose name is the debug encoding for the
562 -- renaming declaration.
564 -- For now, the object name contains the suffix encoding for the renamed
565 -- object, but not the name of the leading entity. The object is linked
566 -- the renamed entity using the Debug_Renaming_Link field. Then the
567 -- Qualify_Entity_Name procedure uses this link to create the proper
568 -- fully qualified name.
570 -- The reason we do things this way is that we really need to copy the
571 -- qualification of the renamed entity, and it is really much easier to
572 -- do this after the renamed entity has itself been fully qualified.
574 Obj := Make_Defining_Identifier (Loc, Chars => Name_Enter);
575 Res :=
576 Make_Object_Declaration (Loc,
577 Defining_Identifier => Obj,
578 Object_Definition => New_Occurrence_Of
579 (Standard_Debug_Renaming_Type, Loc));
581 Set_Debug_Renaming_Link (Obj, Entity (Ren));
583 Set_Debug_Info_Needed (Obj);
585 -- The renamed entity may be a temporary, e.g. the result of an
586 -- implicit dereference in an iterator. Indicate that the temporary
587 -- itself requires debug information. If the renamed entity comes
588 -- from source this is a no-op.
590 Set_Debug_Info_Needed (Entity (Ren));
592 -- Mark the object as internal so that it won't be initialized when
593 -- pragma Initialize_Scalars or Normalize_Scalars is in use.
595 Set_Is_Internal (Obj);
597 return Res;
599 -- If we get an exception, just figure it is a case that we cannot
600 -- successfully handle using our current approach, since this is
601 -- only for debugging, no need to take the compilation with us.
603 exception
604 when others =>
605 return Make_Null_Statement (Loc);
606 end Debug_Renaming_Declaration;
608 -----------------------------
609 -- Is_Handled_Scale_Factor --
610 -----------------------------
612 function Is_Handled_Scale_Factor (U : Ureal) return Boolean is
613 begin
614 -- Keep in sync with gigi (see E_*_Fixed_Point_Type handling in
615 -- decl.c:gnat_to_gnu_entity).
617 if UI_Eq (Numerator (U), Uint_1) then
618 if Rbase (U) = 2 or else Rbase (U) = 10 then
619 return True;
620 end if;
621 end if;
623 return
624 (UI_Is_In_Int_Range (Norm_Num (U))
625 and then
626 UI_Is_In_Int_Range (Norm_Den (U)));
627 end Is_Handled_Scale_Factor;
629 ----------------------
630 -- Get_Encoded_Name --
631 ----------------------
633 -- Note: see spec for details on encodings
635 procedure Get_Encoded_Name (E : Entity_Id) is
636 Has_Suffix : Boolean;
638 begin
639 -- If not generating code, there is no need to create encoded names, and
640 -- problems when the back-end is called to annotate types without full
641 -- code generation. See comments in Get_External_Name for additional
642 -- details.
644 -- However we do create encoded names if the back end is active, even
645 -- if Operating_Mode got reset. Otherwise any serious error reported
646 -- by the backend calling Error_Msg changes the Compilation_Mode to
647 -- Check_Semantics, which disables the functionality of this routine,
648 -- causing the generation of spurious additional errors.
650 -- Couldn't we just test Original_Operating_Mode here? ???
652 if Operating_Mode /= Generate_Code and then not Generating_Code then
653 return;
654 end if;
656 Get_Name_String (Chars (E));
658 -- Nothing to do if we do not have a type
660 if not Is_Type (E)
662 -- Or if this is an enumeration base type
664 or else (Is_Enumeration_Type (E) and then Is_Base_Type (E))
666 -- Or if this is a dummy type for a renaming
668 or else (Name_Len >= 3 and then
669 Name_Buffer (Name_Len - 2 .. Name_Len) = "_XR")
671 or else (Name_Len >= 4 and then
672 (Name_Buffer (Name_Len - 3 .. Name_Len) = "_XRE"
673 or else
674 Name_Buffer (Name_Len - 3 .. Name_Len) = "_XRP"))
676 -- For all these cases, just return the name unchanged
678 then
679 Name_Buffer (Name_Len + 1) := ASCII.NUL;
680 return;
681 end if;
683 Has_Suffix := True;
685 -- Fixed-point case: generate GNAT encodings when asked to or when we
686 -- know the back-end will not be able to handle the scale factor.
688 if Is_Fixed_Point_Type (E)
689 and then (GNAT_Encodings /= DWARF_GNAT_Encodings_Minimal
690 or else not Is_Handled_Scale_Factor (Small_Value (E)))
691 then
692 Get_External_Name (E, True, "XF_");
693 Add_Real_To_Buffer (Delta_Value (E));
695 if Small_Value (E) /= Delta_Value (E) then
696 Add_Str_To_Name_Buffer ("_");
697 Add_Real_To_Buffer (Small_Value (E));
698 end if;
700 -- Discrete case where bounds do not match size. Not necessary if we can
701 -- emit standard DWARF.
703 elsif GNAT_Encodings /= DWARF_GNAT_Encodings_Minimal
704 and then Is_Discrete_Type (E)
705 and then not Bounds_Match_Size (E)
706 then
707 declare
708 Lo : constant Node_Id := Type_Low_Bound (E);
709 Hi : constant Node_Id := Type_High_Bound (E);
711 Lo_Con : constant Boolean := Compile_Time_Known_Value (Lo);
712 Hi_Con : constant Boolean := Compile_Time_Known_Value (Hi);
714 Lo_Discr : constant Boolean :=
715 Nkind (Lo) = N_Identifier
716 and then Ekind (Entity (Lo)) = E_Discriminant;
718 Hi_Discr : constant Boolean :=
719 Nkind (Hi) = N_Identifier
720 and then Ekind (Entity (Hi)) = E_Discriminant;
722 Lo_Encode : constant Boolean := Lo_Con or Lo_Discr;
723 Hi_Encode : constant Boolean := Hi_Con or Hi_Discr;
725 Biased : constant Boolean := Has_Biased_Representation (E);
727 begin
728 if Biased then
729 Get_External_Name (E, True, "XB");
730 else
731 Get_External_Name (E, True, "XD");
732 end if;
734 if Lo_Encode or Hi_Encode then
735 if Biased then
736 Add_Str_To_Name_Buffer ("_");
737 else
738 if Lo_Encode then
739 if Hi_Encode then
740 Add_Str_To_Name_Buffer ("LU_");
741 else
742 Add_Str_To_Name_Buffer ("L_");
743 end if;
744 else
745 Add_Str_To_Name_Buffer ("U_");
746 end if;
747 end if;
749 if Lo_Con then
750 Add_Uint_To_Buffer (Expr_Rep_Value (Lo));
751 elsif Lo_Discr then
752 Get_Name_String_And_Append (Chars (Entity (Lo)));
753 end if;
755 if Lo_Encode and Hi_Encode then
756 Add_Str_To_Name_Buffer ("__");
757 end if;
759 if Hi_Con then
760 Add_Uint_To_Buffer (Expr_Rep_Value (Hi));
761 elsif Hi_Discr then
762 Get_Name_String_And_Append (Chars (Entity (Hi)));
763 end if;
764 end if;
765 end;
767 -- For all other cases, the encoded name is the normal type name
769 else
770 Has_Suffix := False;
771 Get_External_Name (E);
772 end if;
774 if Debug_Flag_B and then Has_Suffix then
775 Write_Str ("**** type ");
776 Write_Name (Chars (E));
777 Write_Str (" is encoded as ");
778 Write_Str (Name_Buffer (1 .. Name_Len));
779 Write_Eol;
780 end if;
782 Name_Buffer (Name_Len + 1) := ASCII.NUL;
783 end Get_Encoded_Name;
785 -----------------------
786 -- Get_External_Name --
787 -----------------------
789 procedure Get_External_Name
790 (Entity : Entity_Id;
791 Has_Suffix : Boolean := False;
792 Suffix : String := "")
794 procedure Get_Qualified_Name_And_Append (Entity : Entity_Id);
795 -- Appends fully qualified name of given entity to Name_Buffer
797 -----------------------------------
798 -- Get_Qualified_Name_And_Append --
799 -----------------------------------
801 procedure Get_Qualified_Name_And_Append (Entity : Entity_Id) is
802 begin
803 -- If the entity is a compilation unit, its scope is Standard,
804 -- there is no outer scope, and the no further qualification
805 -- is required.
807 -- If the front end has already computed a fully qualified name,
808 -- then it is also the case that no further qualification is
809 -- required.
811 if Present (Scope (Scope (Entity)))
812 and then not Has_Fully_Qualified_Name (Entity)
813 then
814 Get_Qualified_Name_And_Append (Scope (Entity));
815 Add_Str_To_Name_Buffer ("__");
816 Get_Name_String_And_Append (Chars (Entity));
817 Append_Homonym_Number (Entity);
819 else
820 Get_Name_String_And_Append (Chars (Entity));
821 end if;
822 end Get_Qualified_Name_And_Append;
824 -- Local variables
826 E : Entity_Id := Entity;
828 -- Start of processing for Get_External_Name
830 begin
831 -- If we are not in code generation mode, this procedure may still be
832 -- called from Back_End (more specifically - from gigi for doing type
833 -- representation annotation or some representation-specific checks).
834 -- But in this mode there is no need to mess with external names.
836 -- Furthermore, the call causes difficulties in this case because the
837 -- string representing the homonym number is not correctly reset as a
838 -- part of the call to Output_Homonym_Numbers_Suffix (which is not
839 -- called in gigi).
841 if Operating_Mode /= Generate_Code then
842 return;
843 end if;
845 Reset_Buffers;
847 -- If this is a child unit, we want the child
849 if Nkind (E) = N_Defining_Program_Unit_Name then
850 E := Defining_Identifier (Entity);
851 end if;
853 -- Case of interface name being used
855 if Ekind_In (E, E_Constant,
856 E_Exception,
857 E_Function,
858 E_Procedure,
859 E_Variable)
860 and then Present (Interface_Name (E))
861 and then No (Address_Clause (E))
862 and then not Has_Suffix
863 then
864 Append (Global_Name_Buffer, Strval (Interface_Name (E)));
866 -- All other cases besides the interface name case
868 else
869 -- If this is a library level subprogram (i.e. a subprogram that is a
870 -- compilation unit other than a subunit), then we prepend _ada_ to
871 -- ensure distinctions required as described in the spec.
873 -- Check explicitly for child units, because those are not flagged
874 -- as Compilation_Units by lib. Should they be ???
876 if Is_Subprogram (E)
877 and then (Is_Compilation_Unit (E) or Is_Child_Unit (E))
878 and then not Has_Suffix
879 then
880 Add_Str_To_Name_Buffer ("_ada_");
881 end if;
883 -- If the entity is a subprogram instance that is not a compilation
884 -- unit, generate the name of the original Ada entity, which is the
885 -- one gdb needs.
887 if Is_Generic_Instance (E)
888 and then Is_Subprogram (E)
889 and then not Is_Compilation_Unit (Scope (E))
890 and then Ekind_In (Scope (E), E_Package, E_Package_Body)
891 and then Present (Related_Instance (Scope (E)))
892 then
893 E := Related_Instance (Scope (E));
894 end if;
896 Get_Qualified_Name_And_Append (E);
897 end if;
899 if Has_Suffix then
900 Add_Str_To_Name_Buffer ("___");
901 Add_Str_To_Name_Buffer (Suffix);
902 end if;
904 -- Add a special prefix to distinguish Ghost entities. In Ignored Ghost
905 -- mode, these entities should not leak in the "living" space and they
906 -- should be removed by the compiler in a post-processing pass. Thus,
907 -- the prefix allows anyone to check that the final executable indeed
908 -- does not contain such entities, in such a case. Do not insert this
909 -- prefix for compilation units, whose name is used as a basis for the
910 -- name of the generated elaboration procedure and (when appropriate)
911 -- the executable produced. Only insert this prefix once, for Ghost
912 -- entities declared inside other Ghost entities. Three leading
913 -- underscores are used so that "___ghost_" is a unique substring of
914 -- names produced for Ghost entities, while "__ghost_" can appear in
915 -- names of entities inside a child/local package called "Ghost".
917 if Is_Ghost_Entity (E)
918 and then not Is_Compilation_Unit (E)
919 and then (Name_Len < 9
920 or else Name_Buffer (1 .. 9) /= "___ghost_")
921 then
922 Insert_Str_In_Name_Buffer ("___ghost_", 1);
923 end if;
925 Name_Buffer (Name_Len + 1) := ASCII.NUL;
926 end Get_External_Name;
928 --------------------------
929 -- Get_Variant_Encoding --
930 --------------------------
932 procedure Get_Variant_Encoding (V : Node_Id) is
933 Choice : Node_Id;
935 procedure Choice_Val (Typ : Character; Choice : Node_Id);
936 -- Output encoded value for a single choice value. Typ is the key
937 -- character ('S', 'F', or 'T') that precedes the choice value.
939 ----------------
940 -- Choice_Val --
941 ----------------
943 procedure Choice_Val (Typ : Character; Choice : Node_Id) is
944 begin
945 if Nkind (Choice) = N_Integer_Literal then
946 Add_Char_To_Name_Buffer (Typ);
947 Add_Uint_To_Buffer (Intval (Choice));
949 -- Character literal with no entity present (this is the case
950 -- Standard.Character or Standard.Wide_Character as root type)
952 elsif Nkind (Choice) = N_Character_Literal
953 and then No (Entity (Choice))
954 then
955 Add_Char_To_Name_Buffer (Typ);
956 Add_Uint_To_Buffer (Char_Literal_Value (Choice));
958 else
959 declare
960 Ent : constant Entity_Id := Entity (Choice);
962 begin
963 if Ekind (Ent) = E_Enumeration_Literal then
964 Add_Char_To_Name_Buffer (Typ);
965 Add_Uint_To_Buffer (Enumeration_Rep (Ent));
967 else
968 pragma Assert (Ekind (Ent) = E_Constant);
969 Choice_Val (Typ, Constant_Value (Ent));
970 end if;
971 end;
972 end if;
973 end Choice_Val;
975 -- Start of processing for Get_Variant_Encoding
977 begin
978 Name_Len := 0;
980 Choice := First (Discrete_Choices (V));
981 while Present (Choice) loop
982 if Nkind (Choice) = N_Others_Choice then
983 Add_Char_To_Name_Buffer ('O');
985 elsif Nkind (Choice) = N_Range then
986 Choice_Val ('R', Low_Bound (Choice));
987 Choice_Val ('T', High_Bound (Choice));
989 elsif Is_Entity_Name (Choice)
990 and then Is_Type (Entity (Choice))
991 then
992 Choice_Val ('R', Type_Low_Bound (Entity (Choice)));
993 Choice_Val ('T', Type_High_Bound (Entity (Choice)));
995 elsif Nkind (Choice) = N_Subtype_Indication then
996 declare
997 Rang : constant Node_Id :=
998 Range_Expression (Constraint (Choice));
999 begin
1000 Choice_Val ('R', Low_Bound (Rang));
1001 Choice_Val ('T', High_Bound (Rang));
1002 end;
1004 else
1005 Choice_Val ('S', Choice);
1006 end if;
1008 Next (Choice);
1009 end loop;
1011 Name_Buffer (Name_Len + 1) := ASCII.NUL;
1013 if Debug_Flag_B then
1014 declare
1015 VP : constant Node_Id := Parent (V); -- Variant_Part
1016 CL : constant Node_Id := Parent (VP); -- Component_List
1017 RD : constant Node_Id := Parent (CL); -- Record_Definition
1018 FT : constant Node_Id := Parent (RD); -- Full_Type_Declaration
1020 begin
1021 Write_Str ("**** variant for type ");
1022 Write_Name (Chars (Defining_Identifier (FT)));
1023 Write_Str (" is encoded as ");
1024 Write_Str (Name_Buffer (1 .. Name_Len));
1025 Write_Eol;
1026 end;
1027 end if;
1028 end Get_Variant_Encoding;
1030 -----------------------------------------
1031 -- Build_Subprogram_Instance_Renamings --
1032 -----------------------------------------
1034 procedure Build_Subprogram_Instance_Renamings
1035 (N : Node_Id;
1036 Wrapper : Entity_Id)
1038 Loc : Source_Ptr;
1039 Decl : Node_Id;
1040 E : Entity_Id;
1042 begin
1043 E := First_Entity (Wrapper);
1044 while Present (E) loop
1045 if Nkind (Parent (E)) = N_Object_Declaration
1046 and then Is_Elementary_Type (Etype (E))
1047 then
1048 Loc := Sloc (Expression (Parent (E)));
1049 Decl := Make_Object_Renaming_Declaration (Loc,
1050 Defining_Identifier =>
1051 Make_Defining_Identifier (Loc, Chars (E)),
1052 Subtype_Mark => New_Occurrence_Of (Etype (E), Loc),
1053 Name => New_Occurrence_Of (E, Loc));
1055 Append (Decl, Declarations (N));
1056 Set_Needs_Debug_Info (Defining_Identifier (Decl));
1057 end if;
1059 Next_Entity (E);
1060 end loop;
1061 end Build_Subprogram_Instance_Renamings;
1063 ------------------------------------
1064 -- Get_Secondary_DT_External_Name --
1065 ------------------------------------
1067 procedure Get_Secondary_DT_External_Name
1068 (Typ : Entity_Id;
1069 Ancestor_Typ : Entity_Id;
1070 Suffix_Index : Int)
1072 begin
1073 Get_External_Name (Typ);
1075 if Ancestor_Typ /= Typ then
1076 declare
1077 Len : constant Natural := Name_Len;
1078 Save_Str : constant String (1 .. Name_Len)
1079 := Name_Buffer (1 .. Name_Len);
1080 begin
1081 Get_External_Name (Ancestor_Typ);
1083 -- Append the extended name of the ancestor to the
1084 -- extended name of Typ
1086 Name_Buffer (Len + 2 .. Len + Name_Len + 1) :=
1087 Name_Buffer (1 .. Name_Len);
1088 Name_Buffer (1 .. Len) := Save_Str;
1089 Name_Buffer (Len + 1) := '_';
1090 Name_Len := Len + Name_Len + 1;
1091 end;
1092 end if;
1094 Add_Nat_To_Name_Buffer (Suffix_Index);
1095 end Get_Secondary_DT_External_Name;
1097 ---------------------------------
1098 -- Make_Packed_Array_Impl_Type_Name --
1099 ---------------------------------
1101 function Make_Packed_Array_Impl_Type_Name
1102 (Typ : Entity_Id;
1103 Csize : Uint)
1104 return Name_Id
1106 begin
1107 Get_Name_String (Chars (Typ));
1108 Add_Str_To_Name_Buffer ("___XP");
1109 Add_Uint_To_Buffer (Csize);
1110 return Name_Find;
1111 end Make_Packed_Array_Impl_Type_Name;
1113 -----------------------------------
1114 -- Output_Homonym_Numbers_Suffix --
1115 -----------------------------------
1117 procedure Output_Homonym_Numbers_Suffix is
1118 J : Natural;
1120 begin
1121 if Homonym_Len > 0 then
1123 -- Check for all 1's, in which case we do not output
1125 J := 1;
1126 loop
1127 exit when Homonym_Numbers (J) /= '1';
1129 -- If we reached end of string we do not output
1131 if J = Homonym_Len then
1132 Homonym_Len := 0;
1133 return;
1134 end if;
1136 exit when Homonym_Numbers (J + 1) /= '_';
1137 J := J + 2;
1138 end loop;
1140 -- If we exit the loop then suffix must be output
1142 Add_Str_To_Name_Buffer ("__");
1143 Add_Str_To_Name_Buffer (Homonym_Numbers (1 .. Homonym_Len));
1144 Homonym_Len := 0;
1145 end if;
1146 end Output_Homonym_Numbers_Suffix;
1148 ------------------------------
1149 -- Prepend_String_To_Buffer --
1150 ------------------------------
1152 procedure Prepend_String_To_Buffer (S : String) is
1153 N : constant Integer := S'Length;
1154 begin
1155 Name_Buffer (1 + N .. Name_Len + N) := Name_Buffer (1 .. Name_Len);
1156 Name_Buffer (1 .. N) := S;
1157 Name_Len := Name_Len + N;
1158 end Prepend_String_To_Buffer;
1160 ----------------------------
1161 -- Prepend_Uint_To_Buffer --
1162 ----------------------------
1164 procedure Prepend_Uint_To_Buffer (U : Uint) is
1165 begin
1166 if U < 0 then
1167 Prepend_String_To_Buffer ("m");
1168 Prepend_Uint_To_Buffer (-U);
1169 else
1170 UI_Image (U, Decimal);
1171 Prepend_String_To_Buffer (UI_Image_Buffer (1 .. UI_Image_Length));
1172 end if;
1173 end Prepend_Uint_To_Buffer;
1175 ------------------------------
1176 -- Qualify_All_Entity_Names --
1177 ------------------------------
1179 procedure Qualify_All_Entity_Names is
1180 E : Entity_Id;
1181 Ent : Entity_Id;
1182 Nod : Node_Id;
1184 begin
1185 for J in Name_Qualify_Units.First .. Name_Qualify_Units.Last loop
1186 Nod := Name_Qualify_Units.Table (J);
1188 -- When a scoping construct is ignored Ghost, it is rewritten as
1189 -- a null statement. Skip such constructs as they no longer carry
1190 -- names.
1192 if Nkind (Nod) = N_Null_Statement then
1193 goto Continue;
1194 end if;
1196 E := Defining_Entity (Nod);
1197 Reset_Buffers;
1198 Qualify_Entity_Name (E);
1200 -- Normally entities in the qualification list are scopes, but in the
1201 -- case of a library-level package renaming there is an associated
1202 -- variable that encodes the debugger name and that variable is
1203 -- entered in the list since it occurs in the Aux_Decls list of the
1204 -- compilation and doesn't have a normal scope.
1206 if Ekind (E) /= E_Variable then
1207 Ent := First_Entity (E);
1208 while Present (Ent) loop
1209 Reset_Buffers;
1210 Qualify_Entity_Name (Ent);
1211 Next_Entity (Ent);
1213 -- There are odd cases where Last_Entity (E) = E. This happens
1214 -- in the case of renaming of packages. This test avoids
1215 -- getting stuck in such cases.
1217 exit when Ent = E;
1218 end loop;
1219 end if;
1221 <<Continue>>
1222 null;
1223 end loop;
1224 end Qualify_All_Entity_Names;
1226 -------------------------
1227 -- Qualify_Entity_Name --
1228 -------------------------
1230 procedure Qualify_Entity_Name (Ent : Entity_Id) is
1232 Full_Qualify_Name : String (1 .. Name_Buffer'Length);
1233 Full_Qualify_Len : Natural := 0;
1234 -- Used to accumulate fully qualified name of subprogram
1236 procedure Fully_Qualify_Name (E : Entity_Id);
1237 -- Used to qualify a subprogram or type name, where full
1238 -- qualification up to Standard is always used. Name is set
1239 -- in Full_Qualify_Name with the length in Full_Qualify_Len.
1240 -- Note that this routine does not prepend the _ada_ string
1241 -- required for library subprograms (this is done in the back end).
1243 function Is_BNPE (S : Entity_Id) return Boolean;
1244 -- Determines if S is a BNPE, i.e. Body-Nested Package Entity, which
1245 -- is defined to be a package which is immediately nested within a
1246 -- package body.
1248 function Qualify_Needed (S : Entity_Id) return Boolean;
1249 -- Given a scope, determines if the scope is to be included in the
1250 -- fully qualified name, True if so, False if not. Blocks and loops
1251 -- are excluded from a qualified name.
1253 procedure Set_BNPE_Suffix (E : Entity_Id);
1254 -- Recursive routine to append the BNPE qualification suffix. Works
1255 -- from right to left with E being the current entity in the list.
1256 -- The result does NOT have the trailing n's and trailing b stripped.
1257 -- The caller must do this required stripping.
1259 procedure Set_Entity_Name (E : Entity_Id);
1260 -- Internal recursive routine that does most of the work. This routine
1261 -- leaves the result sitting in Name_Buffer and Name_Len.
1263 BNPE_Suffix_Needed : Boolean := False;
1264 -- Set true if a body-nested package entity suffix is required
1266 Save_Chars : constant Name_Id := Chars (Ent);
1267 -- Save original name
1269 ------------------------
1270 -- Fully_Qualify_Name --
1271 ------------------------
1273 procedure Fully_Qualify_Name (E : Entity_Id) is
1274 Discard : Boolean := False;
1276 begin
1277 -- Ignore empty entry (can happen in error cases)
1279 if No (E) then
1280 return;
1282 -- If this we are qualifying entities local to a generic instance,
1283 -- use the name of the original instantiation, not that of the
1284 -- anonymous subprogram in the wrapper package, so that gdb doesn't
1285 -- have to know about these.
1287 elsif Is_Generic_Instance (E)
1288 and then Is_Subprogram (E)
1289 and then not Comes_From_Source (E)
1290 and then not Is_Compilation_Unit (Scope (E))
1291 then
1292 Fully_Qualify_Name (Related_Instance (Scope (E)));
1293 return;
1294 end if;
1296 -- If we reached fully qualified name, then just copy it
1298 if Has_Fully_Qualified_Name (E) then
1299 Get_Name_String (Chars (E));
1300 Strip_Suffixes (Discard);
1301 Full_Qualify_Name (1 .. Name_Len) := Name_Buffer (1 .. Name_Len);
1302 Full_Qualify_Len := Name_Len;
1303 Set_Has_Fully_Qualified_Name (Ent);
1305 -- Case of non-fully qualified name
1307 else
1308 if Scope (E) = Standard_Standard then
1309 Set_Has_Fully_Qualified_Name (Ent);
1310 else
1311 Fully_Qualify_Name (Scope (E));
1312 Full_Qualify_Name (Full_Qualify_Len + 1) := '_';
1313 Full_Qualify_Name (Full_Qualify_Len + 2) := '_';
1314 Full_Qualify_Len := Full_Qualify_Len + 2;
1315 end if;
1317 if Has_Qualified_Name (E) then
1318 Get_Unqualified_Name_String (Chars (E));
1319 else
1320 Get_Name_String (Chars (E));
1321 end if;
1323 -- Here we do one step of the qualification
1325 Full_Qualify_Name
1326 (Full_Qualify_Len + 1 .. Full_Qualify_Len + Name_Len) :=
1327 Name_Buffer (1 .. Name_Len);
1328 Full_Qualify_Len := Full_Qualify_Len + Name_Len;
1329 Append_Homonym_Number (E);
1330 end if;
1332 if Is_BNPE (E) then
1333 BNPE_Suffix_Needed := True;
1334 end if;
1335 end Fully_Qualify_Name;
1337 -------------
1338 -- Is_BNPE --
1339 -------------
1341 function Is_BNPE (S : Entity_Id) return Boolean is
1342 begin
1343 return Ekind (S) = E_Package and then Is_Package_Body_Entity (S);
1344 end Is_BNPE;
1346 --------------------
1347 -- Qualify_Needed --
1348 --------------------
1350 function Qualify_Needed (S : Entity_Id) return Boolean is
1351 begin
1352 -- If we got all the way to Standard, then we have certainly
1353 -- fully qualified the name, so set the flag appropriately,
1354 -- and then return False, since we are most certainly done.
1356 if S = Standard_Standard then
1357 Set_Has_Fully_Qualified_Name (Ent, True);
1358 return False;
1360 -- Otherwise figure out if further qualification is required
1362 else
1363 return Is_Subprogram (Ent)
1364 or else Ekind (Ent) = E_Subprogram_Body
1365 or else (Ekind (S) /= E_Block
1366 and then Ekind (S) /= E_Loop
1367 and then not Is_Dynamic_Scope (S));
1368 end if;
1369 end Qualify_Needed;
1371 ---------------------
1372 -- Set_BNPE_Suffix --
1373 ---------------------
1375 procedure Set_BNPE_Suffix (E : Entity_Id) is
1376 S : constant Entity_Id := Scope (E);
1378 begin
1379 if Qualify_Needed (S) then
1380 Set_BNPE_Suffix (S);
1382 if Is_BNPE (E) then
1383 Add_Char_To_Name_Buffer ('b');
1384 else
1385 Add_Char_To_Name_Buffer ('n');
1386 end if;
1388 else
1389 Add_Char_To_Name_Buffer ('X');
1390 end if;
1391 end Set_BNPE_Suffix;
1393 ---------------------
1394 -- Set_Entity_Name --
1395 ---------------------
1397 procedure Set_Entity_Name (E : Entity_Id) is
1398 S : constant Entity_Id := Scope (E);
1400 begin
1401 -- If we reach an already qualified name, just take the encoding
1402 -- except that we strip the package body suffixes, since these
1403 -- will be separately put on later.
1405 if Has_Qualified_Name (E) then
1406 Get_Name_String_And_Append (Chars (E));
1407 Strip_Suffixes (BNPE_Suffix_Needed);
1409 -- If the top level name we are adding is itself fully
1410 -- qualified, then that means that the name that we are
1411 -- preparing for the Fully_Qualify_Name call will also
1412 -- generate a fully qualified name.
1414 if Has_Fully_Qualified_Name (E) then
1415 Set_Has_Fully_Qualified_Name (Ent);
1416 end if;
1418 -- Case where upper level name is not encoded yet
1420 else
1421 -- Recurse if further qualification required
1423 if Qualify_Needed (S) then
1424 Set_Entity_Name (S);
1425 Add_Str_To_Name_Buffer ("__");
1426 end if;
1428 -- Otherwise get name and note if it is a BNPE
1430 Get_Name_String_And_Append (Chars (E));
1432 if Is_BNPE (E) then
1433 BNPE_Suffix_Needed := True;
1434 end if;
1436 Append_Homonym_Number (E);
1437 end if;
1438 end Set_Entity_Name;
1440 -- Start of processing for Qualify_Entity_Name
1442 begin
1443 if Has_Qualified_Name (Ent) then
1444 return;
1446 -- In formal verification mode, simply append a suffix for homonyms.
1447 -- We used to qualify entity names as full expansion does, but this was
1448 -- removed as this prevents the verification back-end from using a short
1449 -- name for debugging and user interaction. The verification back-end
1450 -- already takes care of qualifying names when needed. Still mark the
1451 -- name as being qualified, as Qualify_Entity_Name may be called more
1452 -- than once on the same entity.
1454 elsif GNATprove_Mode then
1455 if Has_Homonym (Ent) then
1456 Get_Name_String (Chars (Ent));
1457 Append_Homonym_Number (Ent);
1458 Output_Homonym_Numbers_Suffix;
1459 Set_Chars (Ent, Name_Enter);
1460 end if;
1462 Set_Has_Qualified_Name (Ent);
1463 return;
1465 -- If the entity is a variable encoding the debug name for an object
1466 -- renaming, then the qualified name of the entity associated with the
1467 -- renamed object can now be incorporated in the debug name.
1469 elsif Ekind (Ent) = E_Variable
1470 and then Present (Debug_Renaming_Link (Ent))
1471 then
1472 Name_Len := 0;
1473 Qualify_Entity_Name (Debug_Renaming_Link (Ent));
1474 Get_Name_String (Chars (Ent));
1476 -- Retrieve the now-qualified name of the renamed entity and insert
1477 -- it in the middle of the name, just preceding the suffix encoding
1478 -- describing the renamed object.
1480 declare
1481 Renamed_Id : constant String :=
1482 Get_Name_String (Chars (Debug_Renaming_Link (Ent)));
1483 Insert_Len : constant Integer := Renamed_Id'Length + 1;
1484 Index : Natural := Name_Len - 3;
1486 begin
1487 -- Loop backwards through the name to find the start of the "___"
1488 -- sequence associated with the suffix.
1490 while Index >= Name_Buffer'First
1491 and then (Name_Buffer (Index + 1) /= '_'
1492 or else Name_Buffer (Index + 2) /= '_'
1493 or else Name_Buffer (Index + 3) /= '_')
1494 loop
1495 Index := Index - 1;
1496 end loop;
1498 pragma Assert (Name_Buffer (Index + 1 .. Index + 3) = "___");
1500 -- Insert an underscore separator and the entity name just in
1501 -- front of the suffix.
1503 Name_Buffer (Index + 1 + Insert_Len .. Name_Len + Insert_Len) :=
1504 Name_Buffer (Index + 1 .. Name_Len);
1505 Name_Buffer (Index + 1) := '_';
1506 Name_Buffer (Index + 2 .. Index + Insert_Len) := Renamed_Id;
1507 Name_Len := Name_Len + Insert_Len;
1508 end;
1510 -- Reset the name of the variable to the new name that includes the
1511 -- name of the renamed entity.
1513 Set_Chars (Ent, Name_Enter);
1515 -- If the entity needs qualification by its scope then develop it
1516 -- here, add the variable's name, and again reset the entity name.
1518 if Qualify_Needed (Scope (Ent)) then
1519 Name_Len := 0;
1520 Set_Entity_Name (Scope (Ent));
1521 Add_Str_To_Name_Buffer ("__");
1523 Get_Name_String_And_Append (Chars (Ent));
1525 Set_Chars (Ent, Name_Enter);
1526 end if;
1528 Set_Has_Qualified_Name (Ent);
1529 return;
1531 elsif Is_Subprogram (Ent)
1532 or else Ekind (Ent) = E_Subprogram_Body
1533 or else Is_Type (Ent)
1534 then
1535 Fully_Qualify_Name (Ent);
1536 Name_Len := Full_Qualify_Len;
1537 Name_Buffer (1 .. Name_Len) := Full_Qualify_Name (1 .. Name_Len);
1539 -- Qualification needed for enumeration literals when generating C code
1540 -- (to simplify their management in the backend).
1542 elsif Modify_Tree_For_C
1543 and then Ekind (Ent) = E_Enumeration_Literal
1544 and then Scope (Ultimate_Alias (Ent)) /= Standard_Standard
1545 then
1546 Fully_Qualify_Name (Ent);
1547 Name_Len := Full_Qualify_Len;
1548 Name_Buffer (1 .. Name_Len) := Full_Qualify_Name (1 .. Name_Len);
1550 elsif Qualify_Needed (Scope (Ent)) then
1551 Name_Len := 0;
1552 Set_Entity_Name (Ent);
1554 else
1555 Set_Has_Qualified_Name (Ent);
1557 -- If a variable is hidden by a subsequent loop variable, qualify
1558 -- the name of that loop variable to prevent visibility issues when
1559 -- translating to C. Note that gdb probably never handled properly
1560 -- this accidental hiding, given that loops are not scopes at
1561 -- runtime. We also qualify a name if it hides an outer homonym,
1562 -- and both are declared in blocks.
1564 if Modify_Tree_For_C and then Ekind (Ent) = E_Variable then
1565 if Present (Hiding_Loop_Variable (Ent)) then
1566 declare
1567 Var : constant Entity_Id := Hiding_Loop_Variable (Ent);
1569 begin
1570 Set_Entity_Name (Var);
1571 Add_Str_To_Name_Buffer ("L");
1572 Set_Chars (Var, Name_Enter);
1573 end;
1575 elsif Present (Homonym (Ent))
1576 and then Ekind (Scope (Ent)) = E_Block
1577 and then Ekind (Scope (Homonym (Ent))) = E_Block
1578 then
1579 Set_Entity_Name (Ent);
1580 Add_Str_To_Name_Buffer ("B");
1581 Set_Chars (Ent, Name_Enter);
1582 end if;
1583 end if;
1585 return;
1586 end if;
1588 -- Fall through with a fully qualified name in Name_Buffer/Name_Len
1590 Output_Homonym_Numbers_Suffix;
1592 -- Add body-nested package suffix if required
1594 if BNPE_Suffix_Needed
1595 and then Ekind (Ent) /= E_Enumeration_Literal
1596 then
1597 Set_BNPE_Suffix (Ent);
1599 -- Strip trailing n's and last trailing b as required. note that
1600 -- we know there is at least one b, or no suffix would be generated.
1602 while Name_Buffer (Name_Len) = 'n' loop
1603 Name_Len := Name_Len - 1;
1604 end loop;
1606 Name_Len := Name_Len - 1;
1607 end if;
1609 Set_Chars (Ent, Name_Enter);
1610 Set_Has_Qualified_Name (Ent);
1612 if Debug_Flag_BB then
1613 Write_Str ("*** ");
1614 Write_Name (Save_Chars);
1615 Write_Str (" qualified as ");
1616 Write_Name (Chars (Ent));
1617 Write_Eol;
1618 end if;
1619 end Qualify_Entity_Name;
1621 --------------------------
1622 -- Qualify_Entity_Names --
1623 --------------------------
1625 procedure Qualify_Entity_Names (N : Node_Id) is
1626 begin
1627 Name_Qualify_Units.Append (N);
1628 end Qualify_Entity_Names;
1630 -------------------
1631 -- Reset_Buffers --
1632 -------------------
1634 procedure Reset_Buffers is
1635 begin
1636 Name_Len := 0;
1637 Homonym_Len := 0;
1638 end Reset_Buffers;
1640 --------------------
1641 -- Strip_Suffixes --
1642 --------------------
1644 procedure Strip_Suffixes (BNPE_Suffix_Found : in out Boolean) is
1645 SL : Natural;
1647 pragma Warnings (Off, BNPE_Suffix_Found);
1648 -- Since this procedure only ever sets the flag
1650 begin
1651 -- Search for and strip BNPE suffix
1653 for J in reverse 2 .. Name_Len loop
1654 if Name_Buffer (J) = 'X' then
1655 Name_Len := J - 1;
1656 BNPE_Suffix_Found := True;
1657 exit;
1658 end if;
1660 exit when Name_Buffer (J) /= 'b' and then Name_Buffer (J) /= 'n';
1661 end loop;
1663 -- Search for and strip homonym numbers suffix
1665 for J in reverse 2 .. Name_Len - 2 loop
1666 if Name_Buffer (J) = '_'
1667 and then Name_Buffer (J + 1) = '_'
1668 then
1669 if Name_Buffer (J + 2) in '0' .. '9' then
1670 if Homonym_Len > 0 then
1671 Homonym_Len := Homonym_Len + 1;
1672 Homonym_Numbers (Homonym_Len) := '-';
1673 end if;
1675 SL := Name_Len - (J + 1);
1677 Homonym_Numbers (Homonym_Len + 1 .. Homonym_Len + SL) :=
1678 Name_Buffer (J + 2 .. Name_Len);
1679 Name_Len := J - 1;
1680 Homonym_Len := Homonym_Len + SL;
1681 end if;
1683 exit;
1684 end if;
1685 end loop;
1686 end Strip_Suffixes;
1688 end Exp_Dbug;