Fix GNU coding style for G_.
[official-gcc.git] / gcc / ada / sem_elab.adb
blobcc5d0456cdc1fe0ef84cbb705ff3285f92faf758
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- S E M _ E L A B --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 1997-2018, 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 Atree; use Atree;
27 with Checks; use Checks;
28 with Debug; use Debug;
29 with Einfo; use Einfo;
30 with Elists; use Elists;
31 with Errout; use Errout;
32 with Exp_Ch11; use Exp_Ch11;
33 with Exp_Tss; use Exp_Tss;
34 with Exp_Util; use Exp_Util;
35 with Expander; use Expander;
36 with Lib; use Lib;
37 with Lib.Load; use Lib.Load;
38 with Namet; use Namet;
39 with Nlists; use Nlists;
40 with Nmake; use Nmake;
41 with Opt; use Opt;
42 with Output; use Output;
43 with Restrict; use Restrict;
44 with Rident; use Rident;
45 with Rtsfind; use Rtsfind;
46 with Sem; use Sem;
47 with Sem_Aux; use Sem_Aux;
48 with Sem_Cat; use Sem_Cat;
49 with Sem_Ch7; use Sem_Ch7;
50 with Sem_Ch8; use Sem_Ch8;
51 with Sem_Prag; use Sem_Prag;
52 with Sem_Util; use Sem_Util;
53 with Sinfo; use Sinfo;
54 with Sinput; use Sinput;
55 with Snames; use Snames;
56 with Stand; use Stand;
57 with Table;
58 with Tbuild; use Tbuild;
59 with Uintp; use Uintp;
60 with Uname; use Uname;
62 with GNAT.HTable; use GNAT.HTable;
64 package body Sem_Elab is
66 -----------------------------------------
67 -- Access-before-elaboration mechanism --
68 -----------------------------------------
70 -- The access-before-elaboration (ABE) mechanism implemented in this unit
71 -- has the following objectives:
73 -- * Diagnose at compile-time or install run-time checks to prevent ABE
74 -- access to data and behaviour.
76 -- The high-level idea is to accurately diagnose ABE issues within a
77 -- single unit because the ABE mechanism can inspect the whole unit.
78 -- As soon as the elaboration graph extends to an external unit, the
79 -- diagnostics stop because the body of the unit may not be available.
80 -- Due to control and data flow, the ABE mechanism cannot accurately
81 -- determine whether a particular scenario will be elaborated or not.
82 -- Conditional ABE checks are therefore used to verify the elaboration
83 -- status of a local and external target at run time.
85 -- * Supply elaboration dependencies for a unit to binde
87 -- The ABE mechanism registers each outgoing elaboration edge for the
88 -- main unit in its ALI file. GNATbind and binde can then reconstruct
89 -- the full elaboration graph and determine the proper elaboration
90 -- order for all units in the compilation.
92 -- The ABE mechanism supports three models of elaboration:
94 -- * Dynamic model - This is the most permissive of the three models.
95 -- When the dynamic model is in effect, the mechanism performs very
96 -- little diagnostics and generates run-time checks to detect ABE
97 -- issues. The behaviour of this model is identical to that specified
98 -- by the Ada RM. This model is enabled with switch -gnatE.
100 -- * Static model - This is the middle ground of the three models. When
101 -- the static model is in effect, the mechanism diagnoses and installs
102 -- run-time checks to detect ABE issues in the main unit. In addition,
103 -- the mechanism generates implicit Elaborate or Elaborate_All pragmas
104 -- to ensure the prior elaboration of withed units. The model employs
105 -- textual order, with clause context, and elaboration-related source
106 -- pragmas. This is the default model.
108 -- * SPARK model - This is the most conservative of the three models and
109 -- impelements the semantics defined in SPARK RM 7.7. The SPARK model
110 -- is in effect only when a context resides in a SPARK_Mode On region,
111 -- otherwise the mechanism falls back to one of the previous models.
113 -- The ABE mechanism consists of a "recording" phase and a "processing"
114 -- phase.
116 -----------------
117 -- Terminology --
118 -----------------
120 -- * ABE - An attempt to activate, call, or instantiate a scenario which
121 -- has not been fully elaborated.
123 -- * Bridge target - A type of target. A bridge target is a link between
124 -- scenarios. It is usually a byproduct of expansion and does not have
125 -- any direct ABE ramifications.
127 -- * Call marker - A special node used to indicate the presence of a call
128 -- in the tree in case expansion transforms or eliminates the original
129 -- call. N_Call_Marker nodes do not have static and run-time semantics.
131 -- * Conditional ABE - A type of ABE. A conditional ABE occurs when the
132 -- elaboration or invocation of a target by a scenario within the main
133 -- unit causes an ABE, but does not cause an ABE for another scenarios
134 -- within the main unit.
136 -- * Declaration level - A type of enclosing level. A scenario or target is
137 -- at the declaration level when it appears within the declarations of a
138 -- block statement, entry body, subprogram body, or task body, ignoring
139 -- enclosing packages.
141 -- * Early call region - A section of code which ends at a subprogram body
142 -- and starts from the nearest non-preelaborable construct which precedes
143 -- the subprogram body. The early call region extends from a package body
144 -- to a package spec when the spec carries pragma Elaborate_Body.
146 -- * Generic library level - A type of enclosing level. A scenario or
147 -- target is at the generic library level if it appears in a generic
148 -- package library unit, ignoring enclosing packages.
150 -- * Guaranteed ABE - A type of ABE. A guaranteed ABE occurs when the
151 -- elaboration or invocation of a target by all scenarios within the
152 -- main unit causes an ABE.
154 -- * Instantiation library level - A type of enclosing level. A scenario
155 -- or target is at the instantiation library level if it appears in an
156 -- instantiation library unit, ignoring enclosing packages.
158 -- * Library level - A type of enclosing level. A scenario or target is at
159 -- the library level if it appears in a package library unit, ignoring
160 -- enclosng packages.
162 -- * Non-library-level encapsulator - A construct that cannot be elaborated
163 -- on its own and requires elaboration by a top-level scenario.
165 -- * Scenario - A construct or context which may be elaborated or executed
166 -- by elaboration code. The scenarios recognized by the ABE mechanism are
167 -- as follows:
169 -- - '[Unrestricted_]Access of entries, operators, and subprograms
171 -- - Assignments to variables
173 -- - Calls to entries, operators, and subprograms
175 -- - Derived type declarations
177 -- - Instantiations
179 -- - Pragma Refined_State
181 -- - Reads of variables
183 -- - Task activation
185 -- * Target - A construct referenced by a scenario. The targets recognized
186 -- by the ABE mechanism are as follows:
188 -- - For '[Unrestricted_]Access of entries, operators, and subprograms,
189 -- the target is the entry, operator, or subprogram.
191 -- - For assignments to variables, the target is the variable
193 -- - For calls, the target is the entry, operator, or subprogram
195 -- - For derived type declarations, the target is the derived type
197 -- - For instantiations, the target is the generic template
199 -- - For pragma Refined_State, the targets are the constituents
201 -- - For reads of variables, the target is the variable
203 -- - For task activation, the target is the task body
205 -- * Top-level scenario - A scenario which appears in a non-generic main
206 -- unit. Depending on the elaboration model is in effect, the following
207 -- addotional restrictions apply:
209 -- - Dynamic model - No restrictions
211 -- - SPARK model - Falls back to either the dynamic or static model
213 -- - Static model - The scenario must be at the library level
215 ---------------------
216 -- Recording phase --
217 ---------------------
219 -- The Recording phase coincides with the analysis/resolution phase of the
220 -- compiler. It has the following objectives:
222 -- * Record all top-level scenarios for examination by the Processing
223 -- phase.
225 -- Saving only a certain number of nodes improves the performance of
226 -- the ABE mechanism. This eliminates the need to examine the whole
227 -- tree in a separate pass.
229 -- * Record certain SPARK scenarios which are not necessarily executable
230 -- during elaboration, but still require elaboration-related checks.
232 -- Saving only a certain number of nodes improves the performance of
233 -- the ABE mechanism. This eliminates the need to examine the whole
234 -- tree in a separate pass.
236 -- * Detect and diagnose calls in preelaborable or pure units, including
237 -- generic bodies.
239 -- This diagnostic is carried out during the Recording phase because it
240 -- does not need the heavy recursive traversal done by the Processing
241 -- phase.
243 -- * Detect and diagnose guaranteed ABEs caused by instantiations,
244 -- calls, and task activation.
246 -- The issues detected by the ABE mechanism are reported as warnings
247 -- because they do not violate Ada semantics. Forward instantiations
248 -- may thus reach gigi, however gigi cannot handle certain kinds of
249 -- premature instantiations and may crash. To avoid this limitation,
250 -- the ABE mechanism must identify forward instantiations as early as
251 -- possible and suppress their bodies. Calls and task activations are
252 -- included in this category for completeness.
254 ----------------------
255 -- Processing phase --
256 ----------------------
258 -- The Processing phase is a separate pass which starts after instantiating
259 -- and/or inlining of bodies, but before the removal of Ghost code. It has
260 -- the following objectives:
262 -- * Examine all top-level scenarios saved during the Recording phase
264 -- The top-level scenarios act as roots for depth-first traversal of
265 -- the call/instantiation/task activation graph. The traversal stops
266 -- when an outgoing edge leaves the main unit.
268 -- * Examine all SPARK scenarios saved during the Recording phase
270 -- * Depending on the elaboration model in effect, perform the following
271 -- actions:
273 -- - Dynamic model - Install run-time conditional ABE checks.
275 -- - SPARK model - Enforce the SPARK elaboration rules
277 -- - Static model - Diagnose conditional ABEs, install run-time
278 -- conditional ABE checks, and guarantee the elaboration of
279 -- external units.
281 -- * Examine nested scenarios
283 -- Nested scenarios discovered during the depth-first traversal are
284 -- in turn subjected to the same actions outlined above and examined
285 -- for the next level of nested scenarios.
287 ------------------
288 -- Architecture --
289 ------------------
291 -- Analysis/Resolution
292 -- |
293 -- +- Build_Call_Marker
294 -- |
295 -- +- Build_Variable_Reference_Marker
296 -- |
297 -- +- | -------------------- Recording phase ---------------------------+
298 -- | v |
299 -- | Record_Elaboration_Scenario |
300 -- | | |
301 -- | +--> Check_Preelaborated_Call |
302 -- | | |
303 -- | +--> Process_Guaranteed_ABE |
304 -- | | | |
305 -- | | +--> Process_Guaranteed_ABE_Activation |
306 -- | | | |
307 -- | | +--> Process_Guaranteed_ABE_Call |
308 -- | | | |
309 -- | | +--> Process_Guaranteed_ABE_Instantiation |
310 -- | | |
311 -- +- | ----------------------------------------------------------------+
312 -- |
313 -- |
314 -- +--> SPARK_Scenarios
315 -- | +-----------+-----------+ .. +-----------+
316 -- | | Scenario1 | Scenario2 | .. | ScenarioN |
317 -- | +-----------+-----------+ .. +-----------+
318 -- |
319 -- +--> Top_Level_Scenarios
320 -- | +-----------+-----------+ .. +-----------+
321 -- | | Scenario1 | Scenario2 | .. | ScenarioN |
322 -- | +-----------+-----------+ .. +-----------+
323 -- |
324 -- End of Compilation
325 -- |
326 -- +- | --------------------- Processing phase -------------------------+
327 -- | v |
328 -- | Check_Elaboration_Scenarios |
329 -- | | |
330 -- | +--> Check_SPARK_Scenario |
331 -- | | | |
332 -- | | +--> Check_SPARK_Derived_Type |
333 -- | | | |
334 -- | | +--> Check_SPARK_Instantiation |
335 -- | | | |
336 -- | | +--> Check_SPARK_Refined_State_Pragma |
337 -- | | |
338 -- | +--> Process_Conditional_ABE <---------------------------+ |
339 -- | | | |
340 -- | +--> Process_Conditional_ABE_Access Is_Suitable_Scenario |
341 -- | | ^ |
342 -- | +--> Process_Conditional_ABE_Activation | |
343 -- | | | | |
344 -- | | +-----------------------------+ | |
345 -- | | | | |
346 -- | +--> Process_Conditional_ABE_Call +--------> Traverse_Body |
347 -- | | | | |
348 -- | | +-----------------------------+ |
349 -- | | |
350 -- | +--> Process_Conditional_ABE_Instantiation |
351 -- | | |
352 -- | +--> Process_Conditional_ABE_Variable_Assignment |
353 -- | | |
354 -- | +--> Process_Conditional_ABE_Variable_Reference |
355 -- | |
356 -- +--------------------------------------------------------------------+
358 ----------------------
359 -- Important points --
360 ----------------------
362 -- The Processing phase starts after the analysis, resolution, expansion
363 -- phase has completed. As a result, no current semantic information is
364 -- available. The scope stack is empty, global flags such as In_Instance
365 -- or Inside_A_Generic become useless. To remedy this, the ABE mechanism
366 -- must either save or recompute semantic information.
368 -- Expansion heavily transforms calls and to some extent instantiations. To
369 -- remedy this, the ABE mechanism generates N_Call_Marker nodes in order to
370 -- capture the target and relevant attributes of the original call.
372 -- The diagnostics of the ABE mechanism depend on accurate source locations
373 -- to determine the spacial relation of nodes.
375 --------------
376 -- Switches --
377 --------------
379 -- The following switches may be used to control the behavior of the ABE
380 -- mechanism.
382 -- -gnatd_a stop elaboration checks on accept or select statement
384 -- The ABE mechanism stops the traversal of a task body when it
385 -- encounters an accept or a select statement. This behavior is
386 -- equivalent to restriction No_Entry_Calls_In_Elaboration_Code,
387 -- but without penalizing actual entry calls during elaboration.
389 -- -gnatd_e ignore entry calls and requeue statements for elaboration
391 -- The ABE mechanism does not generate N_Call_Marker nodes for
392 -- protected or task entry calls as well as requeue statements.
393 -- As a result, the calls and requeues are not recorded or
394 -- processed.
396 -- -gnatdE elaboration checks on predefined units
398 -- The ABE mechanism considers scenarios which appear in internal
399 -- units (Ada, GNAT, Interfaces, System).
401 -- -gnatd.G ignore calls through generic formal parameters for elaboration
403 -- The ABE mechanism does not generate N_Call_Marker nodes for
404 -- calls which occur in expanded instances, and invoke generic
405 -- actual subprograms through generic formal subprograms. As a
406 -- result, the calls are not recorded or processed.
408 -- -gnatd_i ignore activations and calls to instances for elaboration
410 -- The ABE mechanism ignores calls and task activations when they
411 -- target a subprogram or task type defined an external instance.
412 -- As a result, the calls and task activations are not processed.
414 -- -gnatdL ignore external calls from instances for elaboration
416 -- The ABE mechanism does not generate N_Call_Marker nodes for
417 -- calls which occur in expanded instances, do not invoke generic
418 -- actual subprograms through formal subprograms, and the target
419 -- is external to the instance. As a result, the calls are not
420 -- recorded or processed.
422 -- -gnatd.o conservative elaboration order for indirect calls
424 -- The ABE mechanism treats '[Unrestricted_]Access of an entry,
425 -- operator, or subprogram as an immediate invocation of the
426 -- target. As a result, it performs ABE checks and diagnostics on
427 -- the immediate call.
429 -- -gnatd_p ignore assertion pragmas for elaboration
431 -- The ABE mechanism does not generate N_Call_Marker nodes for
432 -- calls to subprograms which verify the run-time semantics of
433 -- the following assertion pragmas:
435 -- Default_Initial_Condition
436 -- Initial_Condition
437 -- Invariant
438 -- Invariant'Class
439 -- Post
440 -- Post'Class
441 -- Postcondition
442 -- Type_Invariant
443 -- Type_Invariant_Class
445 -- As a result, the assertion expressions of the pragmas are not
446 -- processed.
448 -- -gnatd.U ignore indirect calls for static elaboration
450 -- The ABE mechanism does not consider '[Unrestricted_]Access of
451 -- entries, operators, and subprograms. As a result, the scenarios
452 -- are not recorder or processed.
454 -- -gnatd.v enforce SPARK elaboration rules in SPARK code
456 -- The ABE mechanism applies some of the SPARK elaboration rules
457 -- defined in the SPARK reference manual, chapter 7.7. Note that
458 -- certain rules are always enforced, regardless of whether the
459 -- switch is active.
461 -- -gnatd.y disable implicit pragma Elaborate_All on task bodies
463 -- The ABE mechanism does not generate implicit Elaborate_All when
464 -- the need for the pragma came from a task body.
466 -- -gnatE dynamic elaboration checking mode enabled
468 -- The ABE mechanism assumes that any scenario is elaborated or
469 -- invoked by elaboration code. The ABE mechanism performs very
470 -- little diagnostics and generates condintional ABE checks to
471 -- detect ABE issues at run-time.
473 -- -gnatel turn on info messages on generated Elaborate[_All] pragmas
475 -- The ABE mechanism produces information messages on generated
476 -- implicit Elabote[_All] pragmas along with traceback showing
477 -- why the pragma was generated. In addition, the ABE mechanism
478 -- produces information messages for each scenario elaborated or
479 -- invoked by elaboration code.
481 -- -gnateL turn off info messages on generated Elaborate[_All] pragmas
483 -- The complementary switch for -gnatel.
485 -- -gnatH legacy elaboration checking mode enabled
487 -- When this switch is in effect, the pre-18.x ABE model becomes
488 -- the defacto ABE model. This ammounts to cutting off all entry
489 -- points into the new ABE mechanism, and giving full control to
490 -- the old ABE mechanism.
492 -- -gnatJ permissive elaboration checking mode enabled
494 -- This switch activates the following switches:
496 -- -gnatd_a
497 -- -gnatd_e
498 -- -gnatd.G
499 -- -gnatd_i
500 -- -gnatdL
501 -- -gnatd_p
502 -- -gnatd.U
503 -- -gnatd.y
505 -- IMPORTANT: The behavior of the ABE mechanism becomes more
506 -- permissive at the cost of accurate diagnostics and runtime
507 -- ABE checks.
509 -- -gnatw.f turn on warnings for suspicious Subp'Access
511 -- The ABE mechanism treats '[Unrestricted_]Access of an entry,
512 -- operator, or subprogram as a pseudo invocation of the target.
513 -- As a result, it performs ABE diagnostics on the pseudo call.
515 -- -gnatw.F turn off warnings for suspicious Subp'Access
517 -- The complementary switch for -gnatw.f.
519 -- -gnatwl turn on warnings for elaboration problems
521 -- The ABE mechanism produces warnings on detected ABEs along with
522 -- a traceback showing the graph of the ABE.
524 -- -gnatwL turn off warnings for elaboration problems
526 -- The complementary switch for -gnatwl.
528 ---------------------------
529 -- Adding a new scenario --
530 ---------------------------
532 -- The following steps describe how to add a new elaboration scenario and
533 -- preserve the existing architecture. Note that not all of the steps may
534 -- need to be carried out.
536 -- 1) Update predicate Is_Scenario
538 -- 2) Add predicate Is_Suitable_xxx. Include a call to it in predicate
539 -- Is_Suitable_Scenario.
541 -- 3) Update routine Record_Elaboration_Scenario
543 -- 4) Add routine Process_Conditional_ABE_xxx. Include a call to it in
544 -- routine Process_Conditional_ABE.
546 -- 5) Add routine Process_Guaranteed_ABE_xxx. Include a call to it in
547 -- routine Process_Guaranteed_ABE.
549 -- 6) Add routine Check_SPARK_xxx. Include a call to it in routine
550 -- Check_SPARK_Scenario.
552 -- 7) Add routine Info_xxx. Include a call to it in routine
553 -- Process_Conditional_ABE_xxx.
555 -- 8) Add routine Output_xxx. Include a call to it in routine
556 -- Output_Active_Scenarios.
558 -- 9) Add routine Extract_xxx_Attributes
560 -- 10) Update routine Is_Potential_Scenario
562 -------------------------
563 -- Adding a new target --
564 -------------------------
566 -- The following steps describe how to add a new elaboration target and
567 -- preserve the existing architecture. Note that not all of the steps may
568 -- need to be carried out.
570 -- 1) Add predicate Is_xxx.
572 -- 2) Update the following predicates
574 -- Is_Ada_Semantic_Target
575 -- Is_Assertion_Pragma_Target
576 -- Is_Bridge_Target
577 -- Is_SPARK_Semantic_Target
579 -- If necessary, create a new category.
581 -- 3) Update the appropriate Info_xxx routine.
583 -- 4) Update the appropriate Output_xxx routine.
585 -- 5) Update routine Extract_Target_Attributes. If necessary, create a
586 -- new Extract_xxx routine.
588 --------------------------
589 -- Debugging ABE issues --
590 --------------------------
592 -- * If the issue involves a call, ensure that the call is eligible for ABE
593 -- processing and receives a corresponding call marker. The routines of
594 -- interest are
596 -- Build_Call_Marker
597 -- Record_Elaboration_Scenario
599 -- * If the issue involves an arbitrary scenario, ensure that the scenario
600 -- is either recorded, or is successfully recognized while traversing a
601 -- body. The routines of interest are
603 -- Record_Elaboration_Scenario
604 -- Process_Conditional_ABE
605 -- Process_Guaranteed_ABE
606 -- Traverse_Body
608 -- * If the issue involves a circularity in the elaboration order, examine
609 -- the ALI files and look for the following encodings next to units:
611 -- E indicates a source Elaborate
613 -- EA indicates a source Elaborate_All
615 -- AD indicates an implicit Elaborate_All
617 -- ED indicates an implicit Elaborate
619 -- If possible, compare these encodings with those generated by the old
620 -- ABE mechanism. The routines of interest are
622 -- Ensure_Prior_Elaboration
624 ----------------
625 -- Attributes --
626 ----------------
628 -- To minimize the amount of code within routines, the ABE mechanism relies
629 -- on "attribute" records to capture relevant information for a scenario or
630 -- a target.
632 -- The following type captures relevant attributes which pertain to a call
634 type Call_Attributes is record
635 Elab_Checks_OK : Boolean;
636 -- This flag is set when the call has elaboration checks enabled
638 Elab_Warnings_OK : Boolean;
639 -- This flag is set when the call has elaboration warnings elabled
641 From_Source : Boolean;
642 -- This flag is set when the call comes from source
644 Ghost_Mode_Ignore : Boolean;
645 -- This flag is set when the call appears in a region subject to pragma
646 -- Ghost with policy Ignore.
648 In_Declarations : Boolean;
649 -- This flag is set when the call appears at the declaration level
651 Is_Dispatching : Boolean;
652 -- This flag is set when the call is dispatching
654 SPARK_Mode_On : Boolean;
655 -- This flag is set when the call appears in a region subject to pragma
656 -- SPARK_Mode with value On.
657 end record;
659 -- The following type captures relevant attributes which pertain to the
660 -- prior elaboration of a unit. This type is coupled together with a unit
661 -- to form a key -> value relationship.
663 type Elaboration_Attributes is record
664 Source_Pragma : Node_Id;
665 -- This attribute denotes a source Elaborate or Elaborate_All pragma
666 -- which guarantees the prior elaboration of some unit with respect
667 -- to the main unit. The pragma may come from the following contexts:
669 -- * The main unit
670 -- * The spec of the main unit (if applicable)
671 -- * Any parent spec of the main unit (if applicable)
672 -- * Any parent subunit of the main unit (if applicable)
674 -- The attribute remains Empty if no such pragma is available. Source
675 -- pragmas play a role in satisfying SPARK elaboration requirements.
677 With_Clause : Node_Id;
678 -- This attribute denotes an internally generated or source with clause
679 -- for some unit withed by the main unit. With clauses carry flags which
680 -- represent implicit Elaborate or Elaborate_All pragmas. These clauses
681 -- play a role in supplying the elaboration dependencies to binde.
682 end record;
684 No_Elaboration_Attributes : constant Elaboration_Attributes :=
685 (Source_Pragma => Empty,
686 With_Clause => Empty);
688 -- The following type captures relevant attributes which pertain to an
689 -- instantiation.
691 type Instantiation_Attributes is record
692 Elab_Checks_OK : Boolean;
693 -- This flag is set when the instantiation has elaboration checks
694 -- enabled.
696 Elab_Warnings_OK : Boolean;
697 -- This flag is set when the instantiation has elaboration warnings
698 -- enabled.
700 Ghost_Mode_Ignore : Boolean;
701 -- This flag is set when the instantiation appears in a region subject
702 -- to pragma Ghost with policy ignore, or starts one such region.
704 In_Declarations : Boolean;
705 -- This flag is set when the instantiation appears at the declaration
706 -- level.
708 SPARK_Mode_On : Boolean;
709 -- This flag is set when the instantiation appears in a region subject
710 -- to pragma SPARK_Mode with value On, or starts one such region.
711 end record;
713 -- The following type captures relevant attributes which pertain to the
714 -- state of the Processing phase.
716 type Processing_Attributes is record
717 Suppress_Implicit_Pragmas : Boolean;
718 -- This flag is set when the Processing phase must not generate any
719 -- implicit Elaborate[_All] pragmas.
721 Within_Initial_Condition : Boolean;
722 -- This flag is set when the Processing phase is currently examining a
723 -- scenario which was reached from an initial condition procedure.
725 Within_Instance : Boolean;
726 -- This flag is set when the Processing phase is currently examining a
727 -- scenario which was reached from a scenario defined in an instance.
729 Within_Partial_Finalization : Boolean;
730 -- This flag is set when the Processing phase is currently examining a
731 -- scenario which was reached from a partial finalization procedure.
733 Within_Task_Body : Boolean;
734 -- This flag is set when the Processing phase is currently examining a
735 -- scenario which was reached from a task body.
736 end record;
738 Initial_State : constant Processing_Attributes :=
739 (Suppress_Implicit_Pragmas => False,
740 Within_Initial_Condition => False,
741 Within_Instance => False,
742 Within_Partial_Finalization => False,
743 Within_Task_Body => False);
745 -- The following type captures relevant attributes which pertain to a
746 -- target.
748 type Target_Attributes is record
749 Elab_Checks_OK : Boolean;
750 -- This flag is set when the target has elaboration checks enabled
752 From_Source : Boolean;
753 -- This flag is set when the target comes from source
755 Ghost_Mode_Ignore : Boolean;
756 -- This flag is set when the target appears in a region subject to
757 -- pragma Ghost with policy ignore, or starts one such region.
759 SPARK_Mode_On : Boolean;
760 -- This flag is set when the target appears in a region subject to
761 -- pragma SPARK_Mode with value On, or starts one such region.
763 Spec_Decl : Node_Id;
764 -- This attribute denotes the declaration of Spec_Id
766 Unit_Id : Entity_Id;
767 -- This attribute denotes the top unit where Spec_Id resides
769 -- The semantics of the following attributes depend on the target
771 Body_Barf : Node_Id;
772 Body_Decl : Node_Id;
773 Spec_Id : Entity_Id;
775 -- The target is a generic package or a subprogram
777 -- * Body_Barf - Empty
779 -- * Body_Decl - This attribute denotes the generic or subprogram
780 -- body.
782 -- * Spec_Id - This attribute denotes the entity of the generic
783 -- package or subprogram.
785 -- The target is a protected entry
787 -- * Body_Barf - This attribute denotes the body of the barrier
788 -- function if expansion took place, otherwise it is Empty.
790 -- * Body_Decl - This attribute denotes the body of the procedure
791 -- which emulates the entry if expansion took place, otherwise it
792 -- denotes the body of the protected entry.
794 -- * Spec_Id - This attribute denotes the entity of the procedure
795 -- which emulates the entry if expansion took place, otherwise it
796 -- denotes the protected entry.
798 -- The target is a protected subprogram
800 -- * Body_Barf - Empty
802 -- * Body_Decl - This attribute denotes the body of the protected or
803 -- unprotected version of the protected subprogram if expansion took
804 -- place, otherwise it denotes the body of the protected subprogram.
806 -- * Spec_Id - This attribute denotes the entity of the protected or
807 -- unprotected version of the protected subprogram if expansion took
808 -- place, otherwise it is the entity of the protected subprogram.
810 -- The target is a task entry
812 -- * Body_Barf - Empty
814 -- * Body_Decl - This attribute denotes the body of the procedure
815 -- which emulates the task body if expansion took place, otherwise
816 -- it denotes the body of the task type.
818 -- * Spec_Id - This attribute denotes the entity of the procedure
819 -- which emulates the task body if expansion took place, otherwise
820 -- it denotes the entity of the task type.
821 end record;
823 -- The following type captures relevant attributes which pertain to a task
824 -- type.
826 type Task_Attributes is record
827 Body_Decl : Node_Id;
828 -- This attribute denotes the declaration of the procedure body which
829 -- emulates the behaviour of the task body.
831 Elab_Checks_OK : Boolean;
832 -- This flag is set when the task type has elaboration checks enabled
834 Ghost_Mode_Ignore : Boolean;
835 -- This flag is set when the task type appears in a region subject to
836 -- pragma Ghost with policy ignore, or starts one such region.
838 SPARK_Mode_On : Boolean;
839 -- This flag is set when the task type appears in a region subject to
840 -- pragma SPARK_Mode with value On, or starts one such region.
842 Spec_Id : Entity_Id;
843 -- This attribute denotes the entity of the initial declaration of the
844 -- procedure body which emulates the behaviour of the task body.
846 Task_Decl : Node_Id;
847 -- This attribute denotes the declaration of the task type
849 Unit_Id : Entity_Id;
850 -- This attribute denotes the entity of the compilation unit where the
851 -- task type resides.
852 end record;
854 -- The following type captures relevant attributes which pertain to a
855 -- variable.
857 type Variable_Attributes is record
858 Unit_Id : Entity_Id;
859 -- This attribute denotes the entity of the compilation unit where the
860 -- variable resides.
861 end record;
863 ---------------------
864 -- Data structures --
865 ---------------------
867 -- The ABE mechanism employs lists and hash tables to store information
868 -- pertaining to scenarios and targets, as well as the Processing phase.
869 -- The need for data structures comes partly from the size limitation of
870 -- nodes. Note that the use of hash tables is conservative and operations
871 -- are carried out only when a particular hash table has at least one key
872 -- value pair (see xxx_In_Use flags).
874 -- The following table stores the early call regions of subprogram bodies
876 Early_Call_Regions_Max : constant := 101;
878 type Early_Call_Regions_Index is range 0 .. Early_Call_Regions_Max - 1;
880 function Early_Call_Regions_Hash
881 (Key : Entity_Id) return Early_Call_Regions_Index;
882 -- Obtain the hash value of entity Key
884 Early_Call_Regions_In_Use : Boolean := False;
885 -- This flag determines whether table Early_Call_Regions contains at least
886 -- least one key/value pair.
888 Early_Call_Regions_No_Element : constant Node_Id := Empty;
890 package Early_Call_Regions is new Simple_HTable
891 (Header_Num => Early_Call_Regions_Index,
892 Element => Node_Id,
893 No_Element => Early_Call_Regions_No_Element,
894 Key => Entity_Id,
895 Hash => Early_Call_Regions_Hash,
896 Equal => "=");
898 -- The following table stores the elaboration status of all units withed by
899 -- the main unit.
901 Elaboration_Statuses_Max : constant := 1009;
903 type Elaboration_Statuses_Index is range 0 .. Elaboration_Statuses_Max - 1;
905 function Elaboration_Statuses_Hash
906 (Key : Entity_Id) return Elaboration_Statuses_Index;
907 -- Obtain the hash value of entity Key
909 Elaboration_Statuses_In_Use : Boolean := False;
910 -- This flag flag determines whether table Elaboration_Statuses contains at
911 -- least one key/value pair.
913 Elaboration_Statuses_No_Element : constant Elaboration_Attributes :=
914 No_Elaboration_Attributes;
916 package Elaboration_Statuses is new Simple_HTable
917 (Header_Num => Elaboration_Statuses_Index,
918 Element => Elaboration_Attributes,
919 No_Element => Elaboration_Statuses_No_Element,
920 Key => Entity_Id,
921 Hash => Elaboration_Statuses_Hash,
922 Equal => "=");
924 -- The following table stores a status flag for each SPARK scenario saved
925 -- in table SPARK_Scenarios.
927 Recorded_SPARK_Scenarios_Max : constant := 127;
929 type Recorded_SPARK_Scenarios_Index is
930 range 0 .. Recorded_SPARK_Scenarios_Max - 1;
932 function Recorded_SPARK_Scenarios_Hash
933 (Key : Node_Id) return Recorded_SPARK_Scenarios_Index;
934 -- Obtain the hash value of Key
936 Recorded_SPARK_Scenarios_In_Use : Boolean := False;
937 -- This flag flag determines whether table Recorded_SPARK_Scenarios
938 -- contains at least one key/value pair.
940 Recorded_SPARK_Scenarios_No_Element : constant Boolean := False;
942 package Recorded_SPARK_Scenarios is new Simple_HTable
943 (Header_Num => Recorded_SPARK_Scenarios_Index,
944 Element => Boolean,
945 No_Element => Recorded_SPARK_Scenarios_No_Element,
946 Key => Node_Id,
947 Hash => Recorded_SPARK_Scenarios_Hash,
948 Equal => "=");
950 -- The following table stores a status flag for each top-level scenario
951 -- recorded in table Top_Level_Scenarios.
953 Recorded_Top_Level_Scenarios_Max : constant := 503;
955 type Recorded_Top_Level_Scenarios_Index is
956 range 0 .. Recorded_Top_Level_Scenarios_Max - 1;
958 function Recorded_Top_Level_Scenarios_Hash
959 (Key : Node_Id) return Recorded_Top_Level_Scenarios_Index;
960 -- Obtain the hash value of entity Key
962 Recorded_Top_Level_Scenarios_In_Use : Boolean := False;
963 -- This flag flag determines whether table Recorded_Top_Level_Scenarios
964 -- contains at least one key/value pair.
966 Recorded_Top_Level_Scenarios_No_Element : constant Boolean := False;
968 package Recorded_Top_Level_Scenarios is new Simple_HTable
969 (Header_Num => Recorded_Top_Level_Scenarios_Index,
970 Element => Boolean,
971 No_Element => Recorded_Top_Level_Scenarios_No_Element,
972 Key => Node_Id,
973 Hash => Recorded_Top_Level_Scenarios_Hash,
974 Equal => "=");
976 -- The following table stores all active scenarios in a recursive traversal
977 -- starting from a top-level scenario. This table must be maintained in a
978 -- FIFO fashion.
980 package Scenario_Stack is new Table.Table
981 (Table_Component_Type => Node_Id,
982 Table_Index_Type => Int,
983 Table_Low_Bound => 1,
984 Table_Initial => 50,
985 Table_Increment => 100,
986 Table_Name => "Scenario_Stack");
988 -- The following table stores SPARK scenarios which are not necessarily
989 -- executable during elaboration, but still require elaboration-related
990 -- checks.
992 package SPARK_Scenarios is new Table.Table
993 (Table_Component_Type => Node_Id,
994 Table_Index_Type => Int,
995 Table_Low_Bound => 1,
996 Table_Initial => 50,
997 Table_Increment => 100,
998 Table_Name => "SPARK_Scenarios");
1000 -- The following table stores all top-level scenario saved during the
1001 -- Recording phase. The contents of this table act as traversal roots
1002 -- later in the Processing phase. This table must be maintained in a
1003 -- LIFO fashion.
1005 package Top_Level_Scenarios is new Table.Table
1006 (Table_Component_Type => Node_Id,
1007 Table_Index_Type => Int,
1008 Table_Low_Bound => 1,
1009 Table_Initial => 1000,
1010 Table_Increment => 100,
1011 Table_Name => "Top_Level_Scenarios");
1013 -- The following table stores the bodies of all eligible scenarios visited
1014 -- during a traversal starting from a top-level scenario. The contents of
1015 -- this table must be reset upon each new traversal.
1017 Visited_Bodies_Max : constant := 511;
1019 type Visited_Bodies_Index is range 0 .. Visited_Bodies_Max - 1;
1021 function Visited_Bodies_Hash (Key : Node_Id) return Visited_Bodies_Index;
1022 -- Obtain the hash value of node Key
1024 Visited_Bodies_In_Use : Boolean := False;
1025 -- This flag determines whether table Visited_Bodies contains at least one
1026 -- key/value pair.
1028 Visited_Bodies_No_Element : constant Boolean := False;
1030 package Visited_Bodies is new Simple_HTable
1031 (Header_Num => Visited_Bodies_Index,
1032 Element => Boolean,
1033 No_Element => Visited_Bodies_No_Element,
1034 Key => Node_Id,
1035 Hash => Visited_Bodies_Hash,
1036 Equal => "=");
1038 -----------------------
1039 -- Local subprograms --
1040 -----------------------
1042 -- Multiple local subprograms are utilized to lower the semantic complexity
1043 -- of the Recording and Processing phase.
1045 procedure Check_Preelaborated_Call (Call : Node_Id);
1046 pragma Inline (Check_Preelaborated_Call);
1047 -- Verify that entry, operator, or subprogram call Call does not appear at
1048 -- the library level of a preelaborated unit.
1050 procedure Check_SPARK_Derived_Type (Typ_Decl : Node_Id);
1051 pragma Inline (Check_SPARK_Derived_Type);
1052 -- Verify that the freeze node of a derived type denoted by declaration
1053 -- Typ_Decl is within the early call region of each overriding primitive
1054 -- body that belongs to the derived type (SPARK RM 7.7(8)).
1056 procedure Check_SPARK_Instantiation (Exp_Inst : Node_Id);
1057 pragma Inline (Check_SPARK_Instantiation);
1058 -- Verify that expanded instance Exp_Inst does not precede the generic body
1059 -- it instantiates (SPARK RM 7.7(6)).
1061 procedure Check_SPARK_Model_In_Effect (N : Node_Id);
1062 pragma Inline (Check_SPARK_Model_In_Effect);
1063 -- Determine whether a suitable elaboration model is currently in effect
1064 -- for verifying the SPARK rules of scenario N. Emit a warning if this is
1065 -- not the case.
1067 procedure Check_SPARK_Scenario (N : Node_Id);
1068 pragma Inline (Check_SPARK_Scenario);
1069 -- Top-level dispatcher for verifying SPARK scenarios which are not always
1070 -- executable during elaboration but still need elaboration-related checks.
1072 procedure Check_SPARK_Refined_State_Pragma (N : Node_Id);
1073 pragma Inline (Check_SPARK_Refined_State_Pragma);
1074 -- Verify that each constituent of Refined_State pragma N which belongs to
1075 -- an abstract state mentioned in pragma Initializes has prior elaboration
1076 -- with respect to the main unit (SPARK RM 7.7.1(7)).
1078 function Compilation_Unit (Unit_Id : Entity_Id) return Node_Id;
1079 pragma Inline (Compilation_Unit);
1080 -- Return the N_Compilation_Unit node of unit Unit_Id
1082 function Early_Call_Region (Body_Id : Entity_Id) return Node_Id;
1083 pragma Inline (Early_Call_Region);
1084 -- Return the early call region associated with entry or subprogram body
1085 -- Body_Id. IMPORTANT: This routine does not find the early call region.
1086 -- To compute it, use routine Find_Early_Call_Region.
1088 procedure Elab_Msg_NE
1089 (Msg : String;
1090 N : Node_Id;
1091 Id : Entity_Id;
1092 Info_Msg : Boolean;
1093 In_SPARK : Boolean);
1094 pragma Inline (Elab_Msg_NE);
1095 -- Wrapper around Error_Msg_NE. Emit message Msg concerning arbitrary node
1096 -- N and entity. If flag Info_Msg is set, the routine emits an information
1097 -- message, otherwise it emits an error. If flag In_SPARK is set, then
1098 -- string " in SPARK" is added to the end of the message.
1100 function Elaboration_Status
1101 (Unit_Id : Entity_Id) return Elaboration_Attributes;
1102 pragma Inline (Elaboration_Status);
1103 -- Return the set of elaboration attributes associated with unit Unit_Id
1105 procedure Ensure_Prior_Elaboration
1106 (N : Node_Id;
1107 Unit_Id : Entity_Id;
1108 Prag_Nam : Name_Id;
1109 State : Processing_Attributes);
1110 -- Guarantee the elaboration of unit Unit_Id with respect to the main unit
1111 -- by installing pragma Elaborate or Elaborate_All denoted by Prag_Nam. N
1112 -- denotes the related scenario. State denotes the current state of the
1113 -- Processing phase.
1115 procedure Ensure_Prior_Elaboration_Dynamic
1116 (N : Node_Id;
1117 Unit_Id : Entity_Id;
1118 Prag_Nam : Name_Id);
1119 -- Guarantee the elaboration of unit Unit_Id with respect to the main unit
1120 -- by suggesting the use of Elaborate[_All] with name Prag_Nam. N denotes
1121 -- the related scenario.
1123 procedure Ensure_Prior_Elaboration_Static
1124 (N : Node_Id;
1125 Unit_Id : Entity_Id;
1126 Prag_Nam : Name_Id);
1127 -- Guarantee the elaboration of unit Unit_Id with respect to the main unit
1128 -- by installing an implicit Elaborate[_All] pragma with name Prag_Nam. N
1129 -- denotes the related scenario.
1131 function Extract_Assignment_Name (Asmt : Node_Id) return Node_Id;
1132 pragma Inline (Extract_Assignment_Name);
1133 -- Obtain the Name attribute of assignment statement Asmt
1135 procedure Extract_Call_Attributes
1136 (Call : Node_Id;
1137 Target_Id : out Entity_Id;
1138 Attrs : out Call_Attributes);
1139 pragma Inline (Extract_Call_Attributes);
1140 -- Obtain attributes Attrs associated with call Call. Target_Id is the
1141 -- entity of the call target.
1143 function Extract_Call_Name (Call : Node_Id) return Node_Id;
1144 pragma Inline (Extract_Call_Name);
1145 -- Obtain the Name attribute of entry or subprogram call Call
1147 procedure Extract_Instance_Attributes
1148 (Exp_Inst : Node_Id;
1149 Inst_Body : out Node_Id;
1150 Inst_Decl : out Node_Id);
1151 pragma Inline (Extract_Instance_Attributes);
1152 -- Obtain body Inst_Body and spec Inst_Decl of expanded instance Exp_Inst
1154 procedure Extract_Instantiation_Attributes
1155 (Exp_Inst : Node_Id;
1156 Inst : out Node_Id;
1157 Inst_Id : out Entity_Id;
1158 Gen_Id : out Entity_Id;
1159 Attrs : out Instantiation_Attributes);
1160 pragma Inline (Extract_Instantiation_Attributes);
1161 -- Obtain attributes Attrs associated with expanded instantiation Exp_Inst.
1162 -- Inst is the instantiation. Inst_Id is the entity of the instance. Gen_Id
1163 -- is the entity of the generic unit being instantiated.
1165 procedure Extract_Target_Attributes
1166 (Target_Id : Entity_Id;
1167 Attrs : out Target_Attributes);
1168 -- Obtain attributes Attrs associated with an entry, package, or subprogram
1169 -- denoted by Target_Id.
1171 procedure Extract_Task_Attributes
1172 (Typ : Entity_Id;
1173 Attrs : out Task_Attributes);
1174 pragma Inline (Extract_Task_Attributes);
1175 -- Obtain attributes Attrs associated with task type Typ
1177 procedure Extract_Variable_Reference_Attributes
1178 (Ref : Node_Id;
1179 Var_Id : out Entity_Id;
1180 Attrs : out Variable_Attributes);
1181 pragma Inline (Extract_Variable_Reference_Attributes);
1182 -- Obtain attributes Attrs associated with reference Ref that mentions
1183 -- variable Var_Id.
1185 function Find_Code_Unit (N : Node_Or_Entity_Id) return Entity_Id;
1186 pragma Inline (Find_Code_Unit);
1187 -- Return the code unit which contains arbitrary node or entity N. This
1188 -- is the unit of the file which physically contains the related construct
1189 -- denoted by N except when N is within an instantiation. In that case the
1190 -- unit is that of the top-level instantiation.
1192 function Find_Early_Call_Region
1193 (Body_Decl : Node_Id;
1194 Assume_Elab_Body : Boolean := False;
1195 Skip_Memoization : Boolean := False) return Node_Id;
1196 -- Find the start of the early call region which belongs to subprogram body
1197 -- Body_Decl as defined in SPARK RM 7.7. The behavior of the routine is to
1198 -- find the early call region, memoize it, and return it, but this behavior
1199 -- can be altered. Flag Assume_Elab_Body should be set when a package spec
1200 -- may lack pragma Elaborate_Body, but the routine must still examine that
1201 -- spec. Flag Skip_Memoization should be set when the routine must avoid
1202 -- memoizing the region.
1204 procedure Find_Elaborated_Units;
1205 -- Populate table Elaboration_Statuses with all units which have prior
1206 -- elaboration with respect to the main unit.
1208 function Find_Enclosing_Instance (N : Node_Id) return Node_Id;
1209 pragma Inline (Find_Enclosing_Instance);
1210 -- Find the declaration or body of the nearest expanded instance which
1211 -- encloses arbitrary node N. Return Empty if no such instance exists.
1213 function Find_Top_Unit (N : Node_Or_Entity_Id) return Entity_Id;
1214 pragma Inline (Find_Top_Unit);
1215 -- Return the top unit which contains arbitrary node or entity N. The unit
1216 -- is obtained by logically unwinding instantiations and subunits when N
1217 -- resides within one.
1219 function Find_Unit_Entity (N : Node_Id) return Entity_Id;
1220 pragma Inline (Find_Unit_Entity);
1221 -- Return the entity of unit N
1223 function First_Formal_Type (Subp_Id : Entity_Id) return Entity_Id;
1224 pragma Inline (First_Formal_Type);
1225 -- Return the type of subprogram Subp_Id's first formal parameter. If the
1226 -- subprogram lacks formal parameters, return Empty.
1228 function Has_Body (Pack_Decl : Node_Id) return Boolean;
1229 -- Determine whether package declaration Pack_Decl has a corresponding body
1230 -- or would eventually have one.
1232 function Has_Prior_Elaboration
1233 (Unit_Id : Entity_Id;
1234 Context_OK : Boolean := False;
1235 Elab_Body_OK : Boolean := False;
1236 Same_Unit_OK : Boolean := False) return Boolean;
1237 pragma Inline (Has_Prior_Elaboration);
1238 -- Determine whether unit Unit_Id is elaborated prior to the main unit.
1239 -- If flag Context_OK is set, the routine considers the following case
1240 -- as valid prior elaboration:
1242 -- * Unit_Id is in the elaboration context of the main unit
1244 -- If flag Elab_Body_OK is set, the routine considers the following case
1245 -- as valid prior elaboration:
1247 -- * Unit_Id has pragma Elaborate_Body and is not the main unit
1249 -- If flag Same_Unit_OK is set, the routine considers the following cases
1250 -- as valid prior elaboration:
1252 -- * Unit_Id is the main unit
1254 -- * Unit_Id denotes the spec of the main unit body
1256 function In_External_Instance
1257 (N : Node_Id;
1258 Target_Decl : Node_Id) return Boolean;
1259 pragma Inline (In_External_Instance);
1260 -- Determine whether a target desctibed by its declaration Target_Decl
1261 -- resides in a package instance which is external to scenario N.
1263 function In_Main_Context (N : Node_Id) return Boolean;
1264 pragma Inline (In_Main_Context);
1265 -- Determine whether arbitrary node N appears within the main compilation
1266 -- unit.
1268 function In_Same_Context
1269 (N1 : Node_Id;
1270 N2 : Node_Id;
1271 Nested_OK : Boolean := False) return Boolean;
1272 -- Determine whether two arbitrary nodes N1 and N2 appear within the same
1273 -- context ignoring enclosing library levels. Nested_OK should be set when
1274 -- the context of N1 can enclose that of N2.
1276 procedure Info_Call
1277 (Call : Node_Id;
1278 Target_Id : Entity_Id;
1279 Info_Msg : Boolean;
1280 In_SPARK : Boolean);
1281 -- Output information concerning call Call which invokes target Target_Id.
1282 -- If flag Info_Msg is set, the routine emits an information message,
1283 -- otherwise it emits an error. If flag In_SPARK is set, then the string
1284 -- " in SPARK" is added to the end of the message.
1286 procedure Info_Instantiation
1287 (Inst : Node_Id;
1288 Gen_Id : Entity_Id;
1289 Info_Msg : Boolean;
1290 In_SPARK : Boolean);
1291 pragma Inline (Info_Instantiation);
1292 -- Output information concerning instantiation Inst which instantiates
1293 -- generic unit Gen_Id. If flag Info_Msg is set, the routine emits an
1294 -- information message, otherwise it emits an error. If flag In_SPARK
1295 -- is set, then string " in SPARK" is added to the end of the message.
1297 procedure Info_Variable_Reference
1298 (Ref : Node_Id;
1299 Var_Id : Entity_Id;
1300 Info_Msg : Boolean;
1301 In_SPARK : Boolean);
1302 pragma Inline (Info_Variable_Reference);
1303 -- Output information concerning reference Ref which mentions variable
1304 -- Var_Id. If flag Info_Msg is set, the routine emits an information
1305 -- message, otherwise it emits an error. If flag In_SPARK is set, then
1306 -- string " in SPARK" is added to the end of the message.
1308 function Insertion_Node (N : Node_Id; Ins_Nod : Node_Id) return Node_Id;
1309 pragma Inline (Insertion_Node);
1310 -- Obtain the proper insertion node of an ABE check or failure for scenario
1311 -- N and candidate insertion node Ins_Nod.
1313 procedure Install_ABE_Check
1314 (N : Node_Id;
1315 Id : Entity_Id;
1316 Ins_Nod : Node_Id);
1317 -- Insert a run-time ABE check for elaboration scenario N which verifies
1318 -- whether arbitrary entity Id is elaborated. The check in inserted prior
1319 -- to node Ins_Nod.
1321 procedure Install_ABE_Check
1322 (N : Node_Id;
1323 Target_Id : Entity_Id;
1324 Target_Decl : Node_Id;
1325 Target_Body : Node_Id;
1326 Ins_Nod : Node_Id);
1327 -- Insert a run-time ABE check for elaboration scenario N which verifies
1328 -- whether target Target_Id with initial declaration Target_Decl and body
1329 -- Target_Body is elaborated. The check is inserted prior to node Ins_Nod.
1331 procedure Install_ABE_Failure (N : Node_Id; Ins_Nod : Node_Id);
1332 -- Insert a Program_Error concerning a guaranteed ABE for elaboration
1333 -- scenario N. The failure is inserted prior to node Node_Id.
1335 function Is_Accept_Alternative_Proc (Id : Entity_Id) return Boolean;
1336 pragma Inline (Is_Accept_Alternative_Proc);
1337 -- Determine whether arbitrary entity Id denotes an internally generated
1338 -- procedure which encapsulates the statements of an accept alternative.
1340 function Is_Activation_Proc (Id : Entity_Id) return Boolean;
1341 pragma Inline (Is_Activation_Proc);
1342 -- Determine whether arbitrary entity Id denotes a runtime procedure in
1343 -- charge with activating tasks.
1345 function Is_Ada_Semantic_Target (Id : Entity_Id) return Boolean;
1346 pragma Inline (Is_Ada_Semantic_Target);
1347 -- Determine whether arbitrary entity Id denodes a source or internally
1348 -- generated subprogram which emulates Ada semantics.
1350 function Is_Assertion_Pragma_Target (Id : Entity_Id) return Boolean;
1351 pragma Inline (Is_Assertion_Pragma_Target);
1352 -- Determine whether arbitrary entity Id denotes a procedure which varifies
1353 -- the run-time semantics of an assertion pragma.
1355 function Is_Bodiless_Subprogram (Subp_Id : Entity_Id) return Boolean;
1356 pragma Inline (Is_Bodiless_Subprogram);
1357 -- Determine whether subprogram Subp_Id will never have a body
1359 function Is_Controlled_Proc
1360 (Subp_Id : Entity_Id;
1361 Subp_Nam : Name_Id) return Boolean;
1362 pragma Inline (Is_Controlled_Proc);
1363 -- Determine whether subprogram Subp_Id denotes controlled type primitives
1364 -- Adjust, Finalize, or Initialize as denoted by name Subp_Nam.
1366 function Is_Default_Initial_Condition_Proc (Id : Entity_Id) return Boolean;
1367 pragma Inline (Is_Default_Initial_Condition_Proc);
1368 -- Determine whether arbitrary entity Id denotes internally generated
1369 -- routine Default_Initial_Condition.
1371 function Is_Finalizer_Proc (Id : Entity_Id) return Boolean;
1372 pragma Inline (Is_Finalizer_Proc);
1373 -- Determine whether arbitrary entity Id denotes internally generated
1374 -- routine _Finalizer.
1376 function Is_Guaranteed_ABE
1377 (N : Node_Id;
1378 Target_Decl : Node_Id;
1379 Target_Body : Node_Id) return Boolean;
1380 pragma Inline (Is_Guaranteed_ABE);
1381 -- Determine whether scenario N with a target described by its initial
1382 -- declaration Target_Decl and body Target_Decl results in a guaranteed
1383 -- ABE.
1385 function Is_Initial_Condition_Proc (Id : Entity_Id) return Boolean;
1386 pragma Inline (Is_Initial_Condition_Proc);
1387 -- Determine whether arbitrary entity Id denotes internally generated
1388 -- routine Initial_Condition.
1390 function Is_Initialized (Obj_Decl : Node_Id) return Boolean;
1391 pragma Inline (Is_Initialized);
1392 -- Determine whether object declaration Obj_Decl is initialized
1394 function Is_Invariant_Proc (Id : Entity_Id) return Boolean;
1395 pragma Inline (Is_Invariant_Proc);
1396 -- Determine whether arbitrary entity Id denotes an invariant procedure
1398 function Is_Non_Library_Level_Encapsulator (N : Node_Id) return Boolean;
1399 pragma Inline (Is_Non_Library_Level_Encapsulator);
1400 -- Determine whether arbitrary node N is a non-library encapsulator
1402 function Is_Partial_Invariant_Proc (Id : Entity_Id) return Boolean;
1403 pragma Inline (Is_Partial_Invariant_Proc);
1404 -- Determine whether arbitrary entity Id denotes a partial invariant
1405 -- procedure.
1407 function Is_Postconditions_Proc (Id : Entity_Id) return Boolean;
1408 pragma Inline (Is_Postconditions_Proc);
1409 -- Determine whether arbitrary entity Id denotes internally generated
1410 -- routine _Postconditions.
1412 function Is_Preelaborated_Unit (Id : Entity_Id) return Boolean;
1413 pragma Inline (Is_Preelaborated_Unit);
1414 -- Determine whether arbitrary entity Id denotes a unit which is subject to
1415 -- one of the following pragmas:
1417 -- * Preelaborable
1418 -- * Pure
1419 -- * Remote_Call_Interface
1420 -- * Remote_Types
1421 -- * Shared_Passive
1423 function Is_Protected_Entry (Id : Entity_Id) return Boolean;
1424 pragma Inline (Is_Protected_Entry);
1425 -- Determine whether arbitrary entity Id denotes a protected entry
1427 function Is_Protected_Subp (Id : Entity_Id) return Boolean;
1428 pragma Inline (Is_Protected_Subp);
1429 -- Determine whether entity Id denotes a protected subprogram
1431 function Is_Protected_Body_Subp (Id : Entity_Id) return Boolean;
1432 pragma Inline (Is_Protected_Body_Subp);
1433 -- Determine whether entity Id denotes the protected or unprotected version
1434 -- of a protected subprogram.
1436 function Is_Recorded_SPARK_Scenario (N : Node_Id) return Boolean;
1437 pragma Inline (Is_Recorded_SPARK_Scenario);
1438 -- Determine whether arbitrary node N is a recorded SPARK scenario which
1439 -- appears in table SPARK_Scenarios.
1441 function Is_Recorded_Top_Level_Scenario (N : Node_Id) return Boolean;
1442 pragma Inline (Is_Recorded_Top_Level_Scenario);
1443 -- Determine whether arbitrary node N is a recorded top-level scenario
1444 -- which appears in table Top_Level_Scenarios.
1446 function Is_Safe_Activation
1447 (Call : Node_Id;
1448 Task_Decl : Node_Id) return Boolean;
1449 pragma Inline (Is_Safe_Activation);
1450 -- Determine whether call Call which activates a task object described by
1451 -- declaration Task_Decl is always ABE-safe.
1453 function Is_Safe_Call
1454 (Call : Node_Id;
1455 Target_Attrs : Target_Attributes) return Boolean;
1456 pragma Inline (Is_Safe_Call);
1457 -- Determine whether call Call which invokes a target described by
1458 -- attributes Target_Attrs is always ABE-safe.
1460 function Is_Safe_Instantiation
1461 (Inst : Node_Id;
1462 Gen_Attrs : Target_Attributes) return Boolean;
1463 pragma Inline (Is_Safe_Instantiation);
1464 -- Determine whether instance Inst which instantiates a generic unit
1465 -- described by attributes Gen_Attrs is always ABE-safe.
1467 function Is_Same_Unit
1468 (Unit_1 : Entity_Id;
1469 Unit_2 : Entity_Id) return Boolean;
1470 pragma Inline (Is_Same_Unit);
1471 -- Determine whether entities Unit_1 and Unit_2 denote the same unit
1473 function Is_Scenario (N : Node_Id) return Boolean;
1474 pragma Inline (Is_Scenario);
1475 -- Determine whether attribute node N denotes a scenario. The scenario may
1476 -- not necessarily be eligible for ABE processing.
1478 function Is_SPARK_Semantic_Target (Id : Entity_Id) return Boolean;
1479 pragma Inline (Is_SPARK_Semantic_Target);
1480 -- Determine whether arbitrary entity Id nodes a source or internally
1481 -- generated subprogram which emulates SPARK semantics.
1483 function Is_Suitable_Access (N : Node_Id) return Boolean;
1484 pragma Inline (Is_Suitable_Access);
1485 -- Determine whether arbitrary node N denotes a suitable attribute for ABE
1486 -- processing.
1488 function Is_Suitable_Call (N : Node_Id) return Boolean;
1489 pragma Inline (Is_Suitable_Call);
1490 -- Determine whether arbitrary node N denotes a suitable call for ABE
1491 -- processing.
1493 function Is_Suitable_Instantiation (N : Node_Id) return Boolean;
1494 pragma Inline (Is_Suitable_Instantiation);
1495 -- Determine whether arbitrary node N is a suitable instantiation for ABE
1496 -- processing.
1498 function Is_Suitable_Scenario (N : Node_Id) return Boolean;
1499 pragma Inline (Is_Suitable_Scenario);
1500 -- Determine whether arbitrary node N is a suitable scenario for ABE
1501 -- processing.
1503 function Is_Suitable_SPARK_Derived_Type (N : Node_Id) return Boolean;
1504 pragma Inline (Is_Suitable_SPARK_Derived_Type);
1505 -- Determine whether arbitrary node N denotes a suitable derived type
1506 -- declaration for ABE processing using the SPARK rules.
1508 function Is_Suitable_SPARK_Instantiation (N : Node_Id) return Boolean;
1509 pragma Inline (Is_Suitable_SPARK_Instantiation);
1510 -- Determine whether arbitrary node N denotes a suitable instantiation for
1511 -- ABE processing using the SPARK rules.
1513 function Is_Suitable_SPARK_Refined_State_Pragma
1514 (N : Node_Id) return Boolean;
1515 pragma Inline (Is_Suitable_SPARK_Refined_State_Pragma);
1516 -- Determine whether arbitrary node N denotes a suitable Refined_State
1517 -- pragma for ABE processing using the SPARK rules.
1519 function Is_Suitable_Variable_Assignment (N : Node_Id) return Boolean;
1520 pragma Inline (Is_Suitable_Variable_Assignment);
1521 -- Determine whether arbitrary node N denotes a suitable assignment for ABE
1522 -- processing.
1524 function Is_Suitable_Variable_Reference (N : Node_Id) return Boolean;
1525 pragma Inline (Is_Suitable_Variable_Reference);
1526 -- Determine whether arbitrary node N is a suitable variable reference for
1527 -- ABE processing.
1529 function Is_Task_Entry (Id : Entity_Id) return Boolean;
1530 pragma Inline (Is_Task_Entry);
1531 -- Determine whether arbitrary entity Id denotes a task entry
1533 function Is_Up_Level_Target (Target_Decl : Node_Id) return Boolean;
1534 pragma Inline (Is_Up_Level_Target);
1535 -- Determine whether the current root resides at the declaration level. If
1536 -- this is the case, determine whether a target described by declaration
1537 -- Target_Decl is within a context which encloses the current root or is in
1538 -- a different unit.
1540 function Is_Visited_Body (Body_Decl : Node_Id) return Boolean;
1541 pragma Inline (Is_Visited_Body);
1542 -- Determine whether subprogram body Body_Decl is already visited during a
1543 -- recursive traversal started from a top-level scenario.
1545 procedure Meet_Elaboration_Requirement
1546 (N : Node_Id;
1547 Target_Id : Entity_Id;
1548 Req_Nam : Name_Id);
1549 -- Determine whether elaboration requirement Req_Nam for scenario N with
1550 -- target Target_Id is met by the context of the main unit using the SPARK
1551 -- rules. Req_Nam must denote either Elaborate or Elaborate_All. Emit an
1552 -- error if this is not the case.
1554 function Non_Private_View (Typ : Entity_Id) return Entity_Id;
1555 pragma Inline (Non_Private_View);
1556 -- Return the full view of private type Typ if available, otherwise return
1557 -- type Typ.
1559 procedure Output_Active_Scenarios (Error_Nod : Node_Id);
1560 -- Output the contents of the active scenario stack from earliest to latest
1561 -- to supplement an earlier error emitted for node Error_Nod.
1563 procedure Pop_Active_Scenario (N : Node_Id);
1564 pragma Inline (Pop_Active_Scenario);
1565 -- Pop the top of the scenario stack. A check is made to ensure that the
1566 -- scenario being removed is the same as N.
1568 generic
1569 with procedure Process_Single_Activation
1570 (Call : Node_Id;
1571 Call_Attrs : Call_Attributes;
1572 Obj_Id : Entity_Id;
1573 Task_Attrs : Task_Attributes;
1574 State : Processing_Attributes);
1575 -- Perform ABE checks and diagnostics for task activation call Call
1576 -- which activates task Obj_Id. Call_Attrs are the attributes of the
1577 -- activation call. Task_Attrs are the attributes of the task type.
1578 -- State is the current state of the Processing phase.
1580 procedure Process_Activation_Generic
1581 (Call : Node_Id;
1582 Call_Attrs : Call_Attributes;
1583 State : Processing_Attributes);
1584 -- Perform ABE checks and diagnostics for activation call Call by invoking
1585 -- routine Process_Single_Activation on each task object being activated.
1586 -- Call_Attrs are the attributes of the activation call. State is the
1587 -- current state of the Processing phase.
1589 procedure Process_Conditional_ABE
1590 (N : Node_Id;
1591 State : Processing_Attributes := Initial_State);
1592 -- Top-level dispatcher for processing of various elaboration scenarios.
1593 -- Perform conditional ABE checks and diagnostics for scenario N. State
1594 -- is the current state of the Processing phase.
1596 procedure Process_Conditional_ABE_Access
1597 (Attr : Node_Id;
1598 State : Processing_Attributes);
1599 -- Perform ABE checks and diagnostics for 'Access to entry, operator, or
1600 -- subprogram denoted by Attr. State is the current state of the Processing
1601 -- phase.
1603 procedure Process_Conditional_ABE_Activation_Impl
1604 (Call : Node_Id;
1605 Call_Attrs : Call_Attributes;
1606 Obj_Id : Entity_Id;
1607 Task_Attrs : Task_Attributes;
1608 State : Processing_Attributes);
1609 -- Perform common conditional ABE checks and diagnostics for call Call
1610 -- which activates task Obj_Id ignoring the Ada or SPARK rules. Call_Attrs
1611 -- are the attributes of the activation call. Task_Attrs are the attributes
1612 -- of the task type. State is the current state of the Processing phase.
1614 procedure Process_Conditional_ABE_Call
1615 (Call : Node_Id;
1616 Call_Attrs : Call_Attributes;
1617 Target_Id : Entity_Id;
1618 State : Processing_Attributes);
1619 -- Top-level dispatcher for processing of calls. Perform ABE checks and
1620 -- diagnostics for call Call which invokes target Target_Id. Call_Attrs
1621 -- are the attributes of the call. State is the current state of the
1622 -- Processing phase.
1624 procedure Process_Conditional_ABE_Call_Ada
1625 (Call : Node_Id;
1626 Call_Attrs : Call_Attributes;
1627 Target_Id : Entity_Id;
1628 Target_Attrs : Target_Attributes;
1629 State : Processing_Attributes);
1630 -- Perform ABE checks and diagnostics for call Call which invokes target
1631 -- Target_Id using the Ada rules. Call_Attrs are the attributes of the
1632 -- call. Target_Attrs are attributes of the target. State is the current
1633 -- state of the Processing phase.
1635 procedure Process_Conditional_ABE_Call_SPARK
1636 (Call : Node_Id;
1637 Target_Id : Entity_Id;
1638 Target_Attrs : Target_Attributes;
1639 State : Processing_Attributes);
1640 -- Perform ABE checks and diagnostics for call Call which invokes target
1641 -- Target_Id using the SPARK rules. Target_Attrs denotes the attributes of
1642 -- the target. State is the current state of the Processing phase.
1644 procedure Process_Conditional_ABE_Instantiation
1645 (Exp_Inst : Node_Id;
1646 State : Processing_Attributes);
1647 -- Top-level dispatcher for processing of instantiations. Perform ABE
1648 -- checks and diagnostics for expanded instantiation Exp_Inst. State is
1649 -- the current state of the Processing phase.
1651 procedure Process_Conditional_ABE_Instantiation_Ada
1652 (Exp_Inst : Node_Id;
1653 Inst : Node_Id;
1654 Inst_Attrs : Instantiation_Attributes;
1655 Gen_Id : Entity_Id;
1656 Gen_Attrs : Target_Attributes;
1657 State : Processing_Attributes);
1658 -- Perform ABE checks and diagnostics for expanded instantiation Exp_Inst
1659 -- of generic Gen_Id using the Ada rules. Inst is the instantiation node.
1660 -- Inst_Attrs are the attributes of the instance. Gen_Attrs denotes the
1661 -- attributes of the generic. State is the current state of the Processing
1662 -- phase.
1664 procedure Process_Conditional_ABE_Instantiation_SPARK
1665 (Inst : Node_Id;
1666 Gen_Id : Entity_Id;
1667 Gen_Attrs : Target_Attributes;
1668 State : Processing_Attributes);
1669 -- Perform ABE checks and diagnostics for instantiation Inst of generic
1670 -- Gen_Id using the SPARK rules. Gen_Attrs denotes the attributes of the
1671 -- generic. State is the current state of the Processing phase.
1673 procedure Process_Conditional_ABE_Variable_Assignment (Asmt : Node_Id);
1674 -- Top-level dispatcher for processing of variable assignments. Perform ABE
1675 -- checks and diagnostics for assignment statement Asmt.
1677 procedure Process_Conditional_ABE_Variable_Assignment_Ada
1678 (Asmt : Node_Id;
1679 Var_Id : Entity_Id);
1680 -- Perform ABE checks and diagnostics for assignment statement Asmt that
1681 -- updates the value of variable Var_Id using the Ada rules.
1683 procedure Process_Conditional_ABE_Variable_Assignment_SPARK
1684 (Asmt : Node_Id;
1685 Var_Id : Entity_Id);
1686 -- Perform ABE checks and diagnostics for assignment statement Asmt that
1687 -- updates the value of variable Var_Id using the SPARK rules.
1689 procedure Process_Conditional_ABE_Variable_Reference (Ref : Node_Id);
1690 -- Top-level dispatcher for processing of variable references. Perform ABE
1691 -- checks and diagnostics for variable reference Ref.
1693 procedure Process_Conditional_ABE_Variable_Reference_Read
1694 (Ref : Node_Id;
1695 Var_Id : Entity_Id;
1696 Attrs : Variable_Attributes);
1697 -- Perform ABE checks and diagnostics for reference Ref described by its
1698 -- attributes Attrs, that reads variable Var_Id.
1700 procedure Process_Guaranteed_ABE (N : Node_Id);
1701 -- Top-level dispatcher for processing of scenarios which result in a
1702 -- guaranteed ABE.
1704 procedure Process_Guaranteed_ABE_Activation_Impl
1705 (Call : Node_Id;
1706 Call_Attrs : Call_Attributes;
1707 Obj_Id : Entity_Id;
1708 Task_Attrs : Task_Attributes;
1709 State : Processing_Attributes);
1710 -- Perform common guaranteed ABE checks and diagnostics for call Call which
1711 -- activates task Obj_Id ignoring the Ada or SPARK rules. Call_Attrs are
1712 -- the attributes of the activation call. Task_Attrs are the attributes of
1713 -- the task type. State is provided for compatibility and is not used.
1715 procedure Process_Guaranteed_ABE_Call
1716 (Call : Node_Id;
1717 Call_Attrs : Call_Attributes;
1718 Target_Id : Entity_Id);
1719 -- Perform common guaranteed ABE checks and diagnostics for call Call which
1720 -- invokes target Target_Id ignoring the Ada or SPARK rules. Call_Attrs are
1721 -- the attributes of the call.
1723 procedure Process_Guaranteed_ABE_Instantiation (Exp_Inst : Node_Id);
1724 -- Perform common guaranteed ABE checks and diagnostics for expanded
1725 -- instantiation Exp_Inst of generic Gen_Id ignoring the Ada or SPARK
1726 -- rules.
1728 procedure Push_Active_Scenario (N : Node_Id);
1729 pragma Inline (Push_Active_Scenario);
1730 -- Push scenario N on top of the scenario stack
1732 procedure Record_SPARK_Elaboration_Scenario (N : Node_Id);
1733 pragma Inline (Record_SPARK_Elaboration_Scenario);
1734 -- Save SPARK scenario N in table SPARK_Scenarios for later processing
1736 procedure Reset_Visited_Bodies;
1737 pragma Inline (Reset_Visited_Bodies);
1738 -- Clear the contents of table Visited_Bodies
1740 function Root_Scenario return Node_Id;
1741 pragma Inline (Root_Scenario);
1742 -- Return the top-level scenario which started a recursive search for other
1743 -- scenarios. It is assumed that there is a valid top-level scenario on the
1744 -- active scenario stack.
1746 procedure Set_Early_Call_Region (Body_Id : Entity_Id; Start : Node_Id);
1747 pragma Inline (Set_Early_Call_Region);
1748 -- Associate an early call region with begins at construct Start with entry
1749 -- or subprogram body Body_Id.
1751 procedure Set_Elaboration_Status
1752 (Unit_Id : Entity_Id;
1753 Val : Elaboration_Attributes);
1754 pragma Inline (Set_Elaboration_Status);
1755 -- Associate an set of elaboration attributes with unit Unit_Id
1757 procedure Set_Is_Recorded_SPARK_Scenario
1758 (N : Node_Id;
1759 Val : Boolean := True);
1760 pragma Inline (Set_Is_Recorded_SPARK_Scenario);
1761 -- Mark scenario N as being recorded in table SPARK_Scenarios
1763 procedure Set_Is_Recorded_Top_Level_Scenario
1764 (N : Node_Id;
1765 Val : Boolean := True);
1766 pragma Inline (Set_Is_Recorded_Top_Level_Scenario);
1767 -- Mark scenario N as being recorded in table Top_Level_Scenarios
1769 procedure Set_Is_Visited_Body (Subp_Body : Node_Id);
1770 pragma Inline (Set_Is_Visited_Body);
1771 -- Mark subprogram body Subp_Body as being visited during a recursive
1772 -- traversal started from a top-level scenario.
1774 function Static_Elaboration_Checks return Boolean;
1775 pragma Inline (Static_Elaboration_Checks);
1776 -- Determine whether the static model is in effect
1778 procedure Traverse_Body (N : Node_Id; State : Processing_Attributes);
1779 -- Inspect the declarative and statement lists of subprogram body N for
1780 -- suitable elaboration scenarios and process them. State is the current
1781 -- state of the Processing phase.
1783 procedure Update_Elaboration_Scenario (New_N : Node_Id; Old_N : Node_Id);
1784 pragma Inline (Update_Elaboration_Scenario);
1785 -- Update all relevant internal data structures when scenario Old_N is
1786 -- transformed into scenario New_N by Atree.Rewrite.
1788 -----------------------
1789 -- Build_Call_Marker --
1790 -----------------------
1792 procedure Build_Call_Marker (N : Node_Id) is
1793 function In_External_Context
1794 (Call : Node_Id;
1795 Target_Attrs : Target_Attributes) return Boolean;
1796 pragma Inline (In_External_Context);
1797 -- Determine whether a target described by attributes Target_Attrs is
1798 -- external to call Call which must reside within an instance.
1800 function In_Premature_Context (Call : Node_Id) return Boolean;
1801 -- Determine whether call Call appears within a premature context
1803 function Is_Bridge_Target (Id : Entity_Id) return Boolean;
1804 pragma Inline (Is_Bridge_Target);
1805 -- Determine whether arbitrary entity Id denotes a bridge target
1807 function Is_Default_Expression (Call : Node_Id) return Boolean;
1808 pragma Inline (Is_Default_Expression);
1809 -- Determine whether call Call acts as the expression of a defaulted
1810 -- parameter within a source call.
1812 function Is_Generic_Formal_Subp (Subp_Id : Entity_Id) return Boolean;
1813 pragma Inline (Is_Generic_Formal_Subp);
1814 -- Determine whether subprogram Subp_Id denotes a generic formal
1815 -- subprogram which appears in the "prologue" of an instantiation.
1817 -------------------------
1818 -- In_External_Context --
1819 -------------------------
1821 function In_External_Context
1822 (Call : Node_Id;
1823 Target_Attrs : Target_Attributes) return Boolean
1825 Inst : Node_Id;
1826 Inst_Body : Node_Id;
1827 Inst_Decl : Node_Id;
1829 begin
1830 -- Performance note: parent traversal
1832 Inst := Find_Enclosing_Instance (Call);
1834 -- The call appears within an instance
1836 if Present (Inst) then
1838 -- The call comes from the main unit and the target does not
1840 if In_Extended_Main_Code_Unit (Call)
1841 and then not In_Extended_Main_Code_Unit (Target_Attrs.Spec_Decl)
1842 then
1843 return True;
1845 -- Otherwise the target declaration must not appear within the
1846 -- instance spec or body.
1848 else
1849 Extract_Instance_Attributes
1850 (Exp_Inst => Inst,
1851 Inst_Decl => Inst_Decl,
1852 Inst_Body => Inst_Body);
1854 -- Performance note: parent traversal
1856 return not In_Subtree
1857 (N => Target_Attrs.Spec_Decl,
1858 Root1 => Inst_Decl,
1859 Root2 => Inst_Body);
1860 end if;
1861 end if;
1863 return False;
1864 end In_External_Context;
1866 --------------------------
1867 -- In_Premature_Context --
1868 --------------------------
1870 function In_Premature_Context (Call : Node_Id) return Boolean is
1871 Par : Node_Id;
1873 begin
1874 -- Climb the parent chain looking for premature contexts
1876 Par := Parent (Call);
1877 while Present (Par) loop
1879 -- Aspect specifications and generic associations are premature
1880 -- contexts because nested calls has not been relocated to their
1881 -- final context.
1883 if Nkind_In (Par, N_Aspect_Specification,
1884 N_Generic_Association)
1885 then
1886 return True;
1888 -- Prevent the search from going too far
1890 elsif Is_Body_Or_Package_Declaration (Par) then
1891 exit;
1892 end if;
1894 Par := Parent (Par);
1895 end loop;
1897 return False;
1898 end In_Premature_Context;
1900 ----------------------
1901 -- Is_Bridge_Target --
1902 ----------------------
1904 function Is_Bridge_Target (Id : Entity_Id) return Boolean is
1905 begin
1906 return
1907 Is_Accept_Alternative_Proc (Id)
1908 or else Is_Finalizer_Proc (Id)
1909 or else Is_Partial_Invariant_Proc (Id)
1910 or else Is_Postconditions_Proc (Id)
1911 or else Is_TSS (Id, TSS_Deep_Adjust)
1912 or else Is_TSS (Id, TSS_Deep_Finalize)
1913 or else Is_TSS (Id, TSS_Deep_Initialize);
1914 end Is_Bridge_Target;
1916 ---------------------------
1917 -- Is_Default_Expression --
1918 ---------------------------
1920 function Is_Default_Expression (Call : Node_Id) return Boolean is
1921 Outer_Call : constant Node_Id := Parent (Call);
1922 Outer_Nam : Node_Id;
1924 begin
1925 -- To qualify, the node must appear immediately within a source call
1926 -- which invokes a source target.
1928 if Nkind_In (Outer_Call, N_Entry_Call_Statement,
1929 N_Function_Call,
1930 N_Procedure_Call_Statement)
1931 and then Comes_From_Source (Outer_Call)
1932 then
1933 Outer_Nam := Extract_Call_Name (Outer_Call);
1935 return
1936 Is_Entity_Name (Outer_Nam)
1937 and then Present (Entity (Outer_Nam))
1938 and then Is_Subprogram_Or_Entry (Entity (Outer_Nam))
1939 and then Comes_From_Source (Entity (Outer_Nam));
1940 end if;
1942 return False;
1943 end Is_Default_Expression;
1945 ----------------------------
1946 -- Is_Generic_Formal_Subp --
1947 ----------------------------
1949 function Is_Generic_Formal_Subp (Subp_Id : Entity_Id) return Boolean is
1950 Subp_Decl : constant Node_Id := Unit_Declaration_Node (Subp_Id);
1951 Context : constant Node_Id := Parent (Subp_Decl);
1953 begin
1954 -- To qualify, the subprogram must rename a generic actual subprogram
1955 -- where the enclosing context is an instantiation.
1957 return
1958 Nkind (Subp_Decl) = N_Subprogram_Renaming_Declaration
1959 and then not Comes_From_Source (Subp_Decl)
1960 and then Nkind_In (Context, N_Function_Specification,
1961 N_Package_Specification,
1962 N_Procedure_Specification)
1963 and then Present (Generic_Parent (Context));
1964 end Is_Generic_Formal_Subp;
1966 -- Local variables
1968 Call_Attrs : Call_Attributes;
1969 Call_Nam : Node_Id;
1970 Marker : Node_Id;
1971 Target_Attrs : Target_Attributes;
1972 Target_Id : Entity_Id;
1974 -- Start of processing for Build_Call_Marker
1976 begin
1977 -- Nothing to do when switch -gnatH (legacy elaboration checking mode
1978 -- enabled) is in effect because the legacy ABE mechanism does not need
1979 -- to carry out this action.
1981 if Legacy_Elaboration_Checks then
1982 return;
1984 -- Nothing to do for ASIS. As a result, ABE checks and diagnostics are
1985 -- not performed in this mode.
1987 elsif ASIS_Mode then
1988 return;
1990 -- Nothing to do when the call is being preanalyzed as the marker will
1991 -- be inserted in the wrong place.
1993 elsif Preanalysis_Active then
1994 return;
1996 -- Nothing to do when the input does not denote a call or a requeue
1998 elsif not Nkind_In (N, N_Entry_Call_Statement,
1999 N_Function_Call,
2000 N_Procedure_Call_Statement,
2001 N_Requeue_Statement)
2002 then
2003 return;
2005 -- Nothing to do when the input denotes entry call or requeue statement,
2006 -- and switch -gnatd_e (ignore entry calls and requeue statements for
2007 -- elaboration) is in effect.
2009 elsif Debug_Flag_Underscore_E
2010 and then Nkind_In (N, N_Entry_Call_Statement, N_Requeue_Statement)
2011 then
2012 return;
2013 end if;
2015 Call_Nam := Extract_Call_Name (N);
2017 -- Nothing to do when the call is erroneous or left in a bad state
2019 if not (Is_Entity_Name (Call_Nam)
2020 and then Present (Entity (Call_Nam))
2021 and then Is_Subprogram_Or_Entry (Entity (Call_Nam)))
2022 then
2023 return;
2025 -- Nothing to do when the call invokes a generic formal subprogram and
2026 -- switch -gnatd.G (ignore calls through generic formal parameters for
2027 -- elaboration) is in effect. This check must be performed with the
2028 -- direct target of the call to avoid the side effects of mapping
2029 -- actuals to formals using renamings.
2031 elsif Debug_Flag_Dot_GG
2032 and then Is_Generic_Formal_Subp (Entity (Call_Nam))
2033 then
2034 return;
2036 -- Nothing to do when the call is analyzed/resolved too early within an
2037 -- intermediate context. This check is saved for last because it incurs
2038 -- a performance penalty.
2040 -- Performance note: parent traversal
2042 elsif In_Premature_Context (N) then
2043 return;
2044 end if;
2046 Extract_Call_Attributes
2047 (Call => N,
2048 Target_Id => Target_Id,
2049 Attrs => Call_Attrs);
2051 Extract_Target_Attributes
2052 (Target_Id => Target_Id,
2053 Attrs => Target_Attrs);
2055 -- Nothing to do when the call appears within the expanded spec or
2056 -- body of an instantiated generic, the call does not invoke a generic
2057 -- formal subprogram, the target is external to the instance, and switch
2058 -- -gnatdL (ignore external calls from instances for elaboration) is in
2059 -- effect.
2061 if Debug_Flag_LL
2062 and then not Is_Generic_Formal_Subp (Entity (Call_Nam))
2064 -- Performance note: parent traversal
2066 and then In_External_Context
2067 (Call => N,
2068 Target_Attrs => Target_Attrs)
2069 then
2070 return;
2072 -- Nothing to do when the call invokes an assertion pragma procedure
2073 -- and switch -gnatd_p (ignore assertion pragmas for elaboration) is
2074 -- in effect.
2076 elsif Debug_Flag_Underscore_P
2077 and then Is_Assertion_Pragma_Target (Target_Id)
2078 then
2079 return;
2081 -- Source calls to source targets are always considered because they
2082 -- reflect the original call graph.
2084 elsif Target_Attrs.From_Source and then Call_Attrs.From_Source then
2085 null;
2087 -- A call to a source function which acts as the default expression in
2088 -- another call requires special detection.
2090 elsif Target_Attrs.From_Source
2091 and then Nkind (N) = N_Function_Call
2092 and then Is_Default_Expression (N)
2093 then
2094 null;
2096 -- The target emulates Ada semantics
2098 elsif Is_Ada_Semantic_Target (Target_Id) then
2099 null;
2101 -- The target acts as a link between scenarios
2103 elsif Is_Bridge_Target (Target_Id) then
2104 null;
2106 -- The target emulates SPARK semantics
2108 elsif Is_SPARK_Semantic_Target (Target_Id) then
2109 null;
2111 -- Otherwise the call is not suitable for ABE processing. This prevents
2112 -- the generation of call markers which will never play a role in ABE
2113 -- diagnostics.
2115 else
2116 return;
2117 end if;
2119 -- At this point it is known that the call will play some role in ABE
2120 -- checks and diagnostics. Create a corresponding call marker in case
2121 -- the original call is heavily transformed by expansion later on.
2123 Marker := Make_Call_Marker (Sloc (N));
2125 -- Inherit the attributes of the original call
2127 Set_Target (Marker, Target_Id);
2128 Set_Is_Declaration_Level_Node (Marker, Call_Attrs.In_Declarations);
2129 Set_Is_Dispatching_Call (Marker, Call_Attrs.Is_Dispatching);
2130 Set_Is_Elaboration_Checks_OK_Node
2131 (Marker, Call_Attrs.Elab_Checks_OK);
2132 Set_Is_Elaboration_Warnings_OK_Node
2133 (Marker, Call_Attrs.Elab_Warnings_OK);
2134 Set_Is_Ignored_Ghost_Node (Marker, Call_Attrs.Ghost_Mode_Ignore);
2135 Set_Is_Source_Call (Marker, Call_Attrs.From_Source);
2136 Set_Is_SPARK_Mode_On_Node (Marker, Call_Attrs.SPARK_Mode_On);
2138 -- The marker is inserted prior to the original call. This placement has
2139 -- several desirable effects:
2141 -- 1) The marker appears in the same context, in close proximity to
2142 -- the call.
2144 -- <marker>
2145 -- <call>
2147 -- 2) Inserting the marker prior to the call ensures that an ABE check
2148 -- will take effect prior to the call.
2150 -- <ABE check>
2151 -- <marker>
2152 -- <call>
2154 -- 3) The above two properties are preserved even when the call is a
2155 -- function which is subsequently relocated in order to capture its
2156 -- result. Note that if the call is relocated to a new context, the
2157 -- relocated call will receive a marker of its own.
2159 -- <ABE check>
2160 -- <maker>
2161 -- Temp : ... := Func_Call ...;
2162 -- ... Temp ...
2164 -- The insertion must take place even when the call does not occur in
2165 -- the main unit to keep the tree symmetric. This ensures that internal
2166 -- name serialization is consistent in case the call marker causes the
2167 -- tree to transform in some way.
2169 Insert_Action (N, Marker);
2171 -- The marker becomes the "corresponding" scenario for the call. Save
2172 -- the marker for later processing by the ABE phase.
2174 Record_Elaboration_Scenario (Marker);
2175 end Build_Call_Marker;
2177 -------------------------------------
2178 -- Build_Variable_Reference_Marker --
2179 -------------------------------------
2181 procedure Build_Variable_Reference_Marker
2182 (N : Node_Id;
2183 Read : Boolean;
2184 Write : Boolean)
2186 function In_Pragma (Nod : Node_Id) return Boolean;
2187 -- Determine whether arbitrary node Nod appears within a pragma
2189 ---------------
2190 -- In_Pragma --
2191 ---------------
2193 function In_Pragma (Nod : Node_Id) return Boolean is
2194 Par : Node_Id;
2196 begin
2197 Par := Nod;
2198 while Present (Par) loop
2199 if Nkind (Par) = N_Pragma then
2200 return True;
2202 -- Prevent the search from going too far
2204 elsif Is_Body_Or_Package_Declaration (Par) then
2205 exit;
2206 end if;
2208 Par := Parent (Par);
2209 end loop;
2211 return False;
2212 end In_Pragma;
2214 -- Local variables
2216 Marker : Node_Id;
2217 Prag : Node_Id;
2218 Var_Attrs : Variable_Attributes;
2219 Var_Id : Entity_Id;
2221 -- Start of processing for Build_Variable_Reference_Marker
2223 begin
2224 -- Nothing to do when switch -gnatH (legacy elaboration checking mode
2225 -- enabled) is in effect because the legacy ABE mechanism does not need
2226 -- to carry out this action.
2228 if Legacy_Elaboration_Checks then
2229 return;
2231 -- Nothing to do for ASIS. As a result, ABE checks and diagnostics are
2232 -- not performed in this mode.
2234 elsif ASIS_Mode then
2235 return;
2237 -- Nothing to do when the reference is being preanalyzed as the marker
2238 -- will be inserted in the wrong place.
2240 elsif Preanalysis_Active then
2241 return;
2243 -- Nothing to do when the input does not denote a reference
2245 elsif not Nkind_In (N, N_Expanded_Name, N_Identifier) then
2246 return;
2248 -- Nothing to do for internally-generated references
2250 elsif not Comes_From_Source (N) then
2251 return;
2253 -- Nothing to do when the reference is erroneous, left in a bad state,
2254 -- or does not denote a variable.
2256 elsif not (Present (Entity (N))
2257 and then Ekind (Entity (N)) = E_Variable
2258 and then Entity (N) /= Any_Id)
2259 then
2260 return;
2261 end if;
2263 Extract_Variable_Reference_Attributes
2264 (Ref => N,
2265 Var_Id => Var_Id,
2266 Attrs => Var_Attrs);
2268 Prag := SPARK_Pragma (Var_Id);
2270 if Comes_From_Source (Var_Id)
2272 -- Both the variable and the reference must appear in SPARK_Mode On
2273 -- regions because this scenario falls under the SPARK rules.
2275 and then Present (Prag)
2276 and then Get_SPARK_Mode_From_Annotation (Prag) = On
2277 and then Is_SPARK_Mode_On_Node (N)
2279 -- The reference must not be considered when it appears in a pragma.
2280 -- If the pragma has run-time semantics, then the reference will be
2281 -- reconsidered once the pragma is expanded.
2283 -- Performance note: parent traversal
2285 and then not In_Pragma (N)
2286 then
2287 null;
2289 -- Otherwise the reference is not suitable for ABE processing. This
2290 -- prevents the generation of variable markers which will never play
2291 -- a role in ABE diagnostics.
2293 else
2294 return;
2295 end if;
2297 -- At this point it is known that the variable reference will play some
2298 -- role in ABE checks and diagnostics. Create a corresponding variable
2299 -- marker in case the original variable reference is folded or optimized
2300 -- away.
2302 Marker := Make_Variable_Reference_Marker (Sloc (N));
2304 -- Inherit the attributes of the original variable reference
2306 Set_Target (Marker, Var_Id);
2307 Set_Is_Read (Marker, Read);
2308 Set_Is_Write (Marker, Write);
2310 -- The marker is inserted prior to the original variable reference. The
2311 -- insertion must take place even when the reference does not occur in
2312 -- the main unit to keep the tree symmetric. This ensures that internal
2313 -- name serialization is consistent in case the variable marker causes
2314 -- the tree to transform in some way.
2316 Insert_Action (N, Marker);
2318 -- The marker becomes the "corresponding" scenario for the reference.
2319 -- Save the marker for later processing for the ABE phase.
2321 Record_Elaboration_Scenario (Marker);
2322 end Build_Variable_Reference_Marker;
2324 ---------------------------------
2325 -- Check_Elaboration_Scenarios --
2326 ---------------------------------
2328 procedure Check_Elaboration_Scenarios is
2329 begin
2330 -- Nothing to do when switch -gnatH (legacy elaboration checking mode
2331 -- enabled) is in effect because the legacy ABE mechanism does not need
2332 -- to carry out this action.
2334 if Legacy_Elaboration_Checks then
2335 return;
2337 -- Nothing to do for ASIS. As a result, no ABE checks and diagnostics
2338 -- are performed in this mode.
2340 elsif ASIS_Mode then
2341 return;
2342 end if;
2344 -- Examine the context of the main unit and record all units with prior
2345 -- elaboration with respect to it.
2347 Find_Elaborated_Units;
2349 -- Examine each top-level scenario saved during the Recording phase for
2350 -- conditional ABEs and perform various actions depending on the model
2351 -- in effect. The table of visited bodies is created for each new top-
2352 -- level scenario.
2354 for Index in Top_Level_Scenarios.First .. Top_Level_Scenarios.Last loop
2355 Reset_Visited_Bodies;
2357 Process_Conditional_ABE (Top_Level_Scenarios.Table (Index));
2358 end loop;
2360 -- Examine each SPARK scenario saved during the Recording phase which
2361 -- is not necessarily executable during elaboration, but still requires
2362 -- elaboration-related checks.
2364 for Index in SPARK_Scenarios.First .. SPARK_Scenarios.Last loop
2365 Check_SPARK_Scenario (SPARK_Scenarios.Table (Index));
2366 end loop;
2367 end Check_Elaboration_Scenarios;
2369 ------------------------------
2370 -- Check_Preelaborated_Call --
2371 ------------------------------
2373 procedure Check_Preelaborated_Call (Call : Node_Id) is
2374 function In_Preelaborated_Context (N : Node_Id) return Boolean;
2375 -- Determine whether arbitrary node appears in a preelaborated context
2377 ------------------------------
2378 -- In_Preelaborated_Context --
2379 ------------------------------
2381 function In_Preelaborated_Context (N : Node_Id) return Boolean is
2382 Body_Id : constant Entity_Id := Find_Code_Unit (N);
2383 Spec_Id : constant Entity_Id := Unique_Entity (Body_Id);
2385 begin
2386 -- The node appears within a package body whose corresponding spec is
2387 -- subject to pragma Remote_Call_Interface or Remote_Types. This does
2388 -- not result in a preelaborated context because the package body may
2389 -- be on another machine.
2391 if Ekind (Body_Id) = E_Package_Body
2392 and then Ekind_In (Spec_Id, E_Generic_Package, E_Package)
2393 and then (Is_Remote_Call_Interface (Spec_Id)
2394 or else Is_Remote_Types (Spec_Id))
2395 then
2396 return False;
2398 -- Otherwise the node appears within a preelaborated context when the
2399 -- associated unit is preelaborated.
2401 else
2402 return Is_Preelaborated_Unit (Spec_Id);
2403 end if;
2404 end In_Preelaborated_Context;
2406 -- Local variables
2408 Call_Attrs : Call_Attributes;
2409 Level : Enclosing_Level_Kind;
2410 Target_Id : Entity_Id;
2412 -- Start of processing for Check_Preelaborated_Call
2414 begin
2415 Extract_Call_Attributes
2416 (Call => Call,
2417 Target_Id => Target_Id,
2418 Attrs => Call_Attrs);
2420 -- Nothing to do when the call is internally generated because it is
2421 -- assumed that it will never violate preelaboration.
2423 if not Call_Attrs.From_Source then
2424 return;
2425 end if;
2427 -- Performance note: parent traversal
2429 Level := Find_Enclosing_Level (Call);
2431 -- Library-level calls are always considered because they are part of
2432 -- the associated unit's elaboration actions.
2434 if Level in Library_Level then
2435 null;
2437 -- Calls at the library level of a generic package body must be checked
2438 -- because they would render an instantiation illegal if the template is
2439 -- marked as preelaborated. Note that this does not apply to calls at
2440 -- the library level of a generic package spec.
2442 elsif Level = Generic_Package_Body then
2443 null;
2445 -- Otherwise the call does not appear at the proper level and must not
2446 -- be considered for this check.
2448 else
2449 return;
2450 end if;
2452 -- The call appears within a preelaborated unit. Emit a warning only for
2453 -- internal uses, otherwise this is an error.
2455 if In_Preelaborated_Context (Call) then
2456 Error_Msg_Warn := GNAT_Mode;
2457 Error_Msg_N
2458 ("<<non-static call not allowed in preelaborated unit", Call);
2459 end if;
2460 end Check_Preelaborated_Call;
2462 ------------------------------
2463 -- Check_SPARK_Derived_Type --
2464 ------------------------------
2466 procedure Check_SPARK_Derived_Type (Typ_Decl : Node_Id) is
2467 Typ : constant Entity_Id := Defining_Entity (Typ_Decl);
2469 -- NOTE: The routines within Check_SPARK_Derived_Type are intentionally
2470 -- unnested to avoid deep indentation of code.
2472 Stop_Check : exception;
2473 -- This exception is raised when the freeze node violates the placement
2474 -- rules.
2476 procedure Check_Overriding_Primitive
2477 (Prim : Entity_Id;
2478 FNode : Node_Id);
2479 pragma Inline (Check_Overriding_Primitive);
2480 -- Verify that freeze node FNode is within the early call region of
2481 -- overriding primitive Prim's body.
2483 function Freeze_Node_Location (FNode : Node_Id) return Source_Ptr;
2484 pragma Inline (Freeze_Node_Location);
2485 -- Return a more accurate source location associated with freeze node
2486 -- FNode.
2488 function Precedes_Source_Construct (N : Node_Id) return Boolean;
2489 pragma Inline (Precedes_Source_Construct);
2490 -- Determine whether arbitrary node N appears prior to some source
2491 -- construct.
2493 procedure Suggest_Elaborate_Body
2494 (N : Node_Id;
2495 Body_Decl : Node_Id;
2496 Error_Nod : Node_Id);
2497 pragma Inline (Suggest_Elaborate_Body);
2498 -- Suggest the use of pragma Elaborate_Body when the pragma will allow
2499 -- for node N to appear within the early call region of subprogram body
2500 -- Body_Decl. The suggestion is attached to Error_Nod as a continuation
2501 -- error.
2503 --------------------------------
2504 -- Check_Overriding_Primitive --
2505 --------------------------------
2507 procedure Check_Overriding_Primitive
2508 (Prim : Entity_Id;
2509 FNode : Node_Id)
2511 Prim_Decl : constant Node_Id := Unit_Declaration_Node (Prim);
2512 Body_Decl : Node_Id;
2513 Body_Id : Entity_Id;
2514 Region : Node_Id;
2516 begin
2517 Body_Id := Corresponding_Body (Prim_Decl);
2519 -- Nothing to do when the primitive does not have a corresponding
2520 -- body. This can happen when the unit with the bodies is not the
2521 -- main unit subjected to ABE checks.
2523 if No (Body_Id) then
2524 return;
2526 -- The primitive overrides a parent or progenitor primitive
2528 elsif Present (Overridden_Operation (Prim)) then
2530 -- Nothing to do when overriding an interface primitive happens by
2531 -- inheriting a non-interface primitive as the check would be done
2532 -- on the parent primitive.
2534 if Present (Alias (Prim)) then
2535 return;
2536 end if;
2538 -- Nothing to do when the primitive is not overriding. The body of
2539 -- such a primitive cannot be targeted by a dispatching call which
2540 -- is executable during elaboration, and cannot cause an ABE.
2542 else
2543 return;
2544 end if;
2546 Body_Decl := Unit_Declaration_Node (Body_Id);
2547 Region := Find_Early_Call_Region (Body_Decl);
2549 -- The freeze node appears prior to the early call region of the
2550 -- primitive body.
2552 -- IMPORTANT: This check must always be performed even when -gnatd.v
2553 -- (enforce SPARK elaboration rules in SPARK code) is not specified
2554 -- because the static model cannot guarantee the absence of ABEs in
2555 -- in the presence of dispatching calls.
2557 if Earlier_In_Extended_Unit (FNode, Region) then
2558 Error_Msg_Node_2 := Prim;
2559 Error_Msg_NE
2560 ("first freezing point of type & must appear within early call "
2561 & "region of primitive body & (SPARK RM 7.7(8))",
2562 Typ_Decl, Typ);
2564 Error_Msg_Sloc := Sloc (Region);
2565 Error_Msg_N ("\region starts #", Typ_Decl);
2567 Error_Msg_Sloc := Sloc (Body_Decl);
2568 Error_Msg_N ("\region ends #", Typ_Decl);
2570 Error_Msg_Sloc := Freeze_Node_Location (FNode);
2571 Error_Msg_N ("\first freezing point #", Typ_Decl);
2573 -- If applicable, suggest the use of pragma Elaborate_Body in the
2574 -- associated package spec.
2576 Suggest_Elaborate_Body
2577 (N => FNode,
2578 Body_Decl => Body_Decl,
2579 Error_Nod => Typ_Decl);
2581 raise Stop_Check;
2582 end if;
2583 end Check_Overriding_Primitive;
2585 --------------------------
2586 -- Freeze_Node_Location --
2587 --------------------------
2589 function Freeze_Node_Location (FNode : Node_Id) return Source_Ptr is
2590 Context : constant Node_Id := Parent (FNode);
2591 Loc : constant Source_Ptr := Sloc (FNode);
2593 Prv_Decls : List_Id;
2594 Vis_Decls : List_Id;
2596 begin
2597 -- In general, the source location of the freeze node is as close as
2598 -- possible to the real freeze point, except when the freeze node is
2599 -- at the "bottom" of a package spec.
2601 if Nkind (Context) = N_Package_Specification then
2602 Prv_Decls := Private_Declarations (Context);
2603 Vis_Decls := Visible_Declarations (Context);
2605 -- The freeze node appears in the private declarations of the
2606 -- package.
2608 if Present (Prv_Decls)
2609 and then List_Containing (FNode) = Prv_Decls
2610 then
2611 null;
2613 -- The freeze node appears in the visible declarations of the
2614 -- package and there are no private declarations.
2616 elsif Present (Vis_Decls)
2617 and then List_Containing (FNode) = Vis_Decls
2618 and then (No (Prv_Decls) or else Is_Empty_List (Prv_Decls))
2619 then
2620 null;
2622 -- Otherwise the freeze node is not in the "last" declarative list
2623 -- of the package. Use the existing source location of the freeze
2624 -- node.
2626 else
2627 return Loc;
2628 end if;
2630 -- The freeze node appears at the "bottom" of the package when it
2631 -- is in the "last" declarative list and is either the last in the
2632 -- list or is followed by internal constructs only. In that case
2633 -- the more appropriate source location is that of the package end
2634 -- label.
2636 if not Precedes_Source_Construct (FNode) then
2637 return Sloc (End_Label (Context));
2638 end if;
2639 end if;
2641 return Loc;
2642 end Freeze_Node_Location;
2644 -------------------------------
2645 -- Precedes_Source_Construct --
2646 -------------------------------
2648 function Precedes_Source_Construct (N : Node_Id) return Boolean is
2649 Decl : Node_Id;
2651 begin
2652 Decl := Next (N);
2653 while Present (Decl) loop
2654 if Comes_From_Source (Decl) then
2655 return True;
2657 -- A generated body for a source expression function is treated as
2658 -- a source construct.
2660 elsif Nkind (Decl) = N_Subprogram_Body
2661 and then Was_Expression_Function (Decl)
2662 and then Comes_From_Source (Original_Node (Decl))
2663 then
2664 return True;
2665 end if;
2667 Next (Decl);
2668 end loop;
2670 return False;
2671 end Precedes_Source_Construct;
2673 ----------------------------
2674 -- Suggest_Elaborate_Body --
2675 ----------------------------
2677 procedure Suggest_Elaborate_Body
2678 (N : Node_Id;
2679 Body_Decl : Node_Id;
2680 Error_Nod : Node_Id)
2682 Unt : constant Node_Id := Unit (Cunit (Main_Unit));
2683 Region : Node_Id;
2685 begin
2686 -- The suggestion applies only when the subprogram body resides in a
2687 -- compilation package body, and a pragma Elaborate_Body would allow
2688 -- for the node to appear in the early call region of the subprogram
2689 -- body. This implies that all code from the subprogram body up to
2690 -- the node is preelaborable.
2692 if Nkind (Unt) = N_Package_Body then
2694 -- Find the start of the early call region again assuming that the
2695 -- package spec has pragma Elaborate_Body. Note that the internal
2696 -- data structures are intentionally not updated because this is a
2697 -- speculative search.
2699 Region :=
2700 Find_Early_Call_Region
2701 (Body_Decl => Body_Decl,
2702 Assume_Elab_Body => True,
2703 Skip_Memoization => True);
2705 -- If the node appears within the early call region, assuming that
2706 -- the package spec carries pragma Elaborate_Body, then it is safe
2707 -- to suggest the pragma.
2709 if Earlier_In_Extended_Unit (Region, N) then
2710 Error_Msg_Name_1 := Name_Elaborate_Body;
2711 Error_Msg_NE
2712 ("\consider adding pragma % in spec of unit &",
2713 Error_Nod, Defining_Entity (Unt));
2714 end if;
2715 end if;
2716 end Suggest_Elaborate_Body;
2718 -- Local variables
2720 FNode : constant Node_Id := Freeze_Node (Typ);
2721 Prims : constant Elist_Id := Direct_Primitive_Operations (Typ);
2723 Prim_Elmt : Elmt_Id;
2725 -- Start of processing for Check_SPARK_Derived_Type
2727 begin
2728 -- A type should have its freeze node set by the time SPARK scenarios
2729 -- are being verified.
2731 pragma Assert (Present (FNode));
2733 -- Verify that the freeze node of the derived type is within the early
2734 -- call region of each overriding primitive body (SPARK RM 7.7(8)).
2736 if Present (Prims) then
2737 Prim_Elmt := First_Elmt (Prims);
2738 while Present (Prim_Elmt) loop
2739 Check_Overriding_Primitive
2740 (Prim => Node (Prim_Elmt),
2741 FNode => FNode);
2743 Next_Elmt (Prim_Elmt);
2744 end loop;
2745 end if;
2747 exception
2748 when Stop_Check =>
2749 null;
2750 end Check_SPARK_Derived_Type;
2752 -------------------------------
2753 -- Check_SPARK_Instantiation --
2754 -------------------------------
2756 procedure Check_SPARK_Instantiation (Exp_Inst : Node_Id) is
2757 Gen_Attrs : Target_Attributes;
2758 Gen_Id : Entity_Id;
2759 Inst : Node_Id;
2760 Inst_Attrs : Instantiation_Attributes;
2761 Inst_Id : Entity_Id;
2763 begin
2764 Extract_Instantiation_Attributes
2765 (Exp_Inst => Exp_Inst,
2766 Inst => Inst,
2767 Inst_Id => Inst_Id,
2768 Gen_Id => Gen_Id,
2769 Attrs => Inst_Attrs);
2771 Extract_Target_Attributes (Gen_Id, Gen_Attrs);
2773 -- The instantiation and the generic body are both in the main unit
2775 if Present (Gen_Attrs.Body_Decl)
2776 and then In_Extended_Main_Code_Unit (Gen_Attrs.Body_Decl)
2778 -- If the instantiation appears prior to the generic body, then the
2779 -- instantiation is illegal (SPARK RM 7.7(6)).
2781 -- IMPORTANT: This check must always be performed even when -gnatd.v
2782 -- (enforce SPARK elaboration rules in SPARK code) is not specified
2783 -- because the rule prevents use-before-declaration of objects that
2784 -- may precede the generic body.
2786 and then Earlier_In_Extended_Unit (Inst, Gen_Attrs.Body_Decl)
2787 then
2788 Error_Msg_NE ("cannot instantiate & before body seen", Inst, Gen_Id);
2789 end if;
2790 end Check_SPARK_Instantiation;
2792 ---------------------------------
2793 -- Check_SPARK_Model_In_Effect --
2794 ---------------------------------
2796 SPARK_Model_Warning_Posted : Boolean := False;
2797 -- This flag prevents the same SPARK model-related warning from being
2798 -- emitted multiple times.
2800 procedure Check_SPARK_Model_In_Effect (N : Node_Id) is
2801 begin
2802 -- Do not emit the warning multiple times as this creates useless noise
2804 if SPARK_Model_Warning_Posted then
2805 null;
2807 -- SPARK rule verification requires the "strict" static model
2809 elsif Static_Elaboration_Checks and not Relaxed_Elaboration_Checks then
2810 null;
2812 -- Any other combination of models does not guarantee the absence of ABE
2813 -- problems for SPARK rule verification purposes. Note that there is no
2814 -- need to check for the legacy ABE mechanism because the legacy code
2815 -- has its own orthogonal processing for SPARK rules.
2817 else
2818 SPARK_Model_Warning_Posted := True;
2820 Error_Msg_N
2821 ("??SPARK elaboration checks require static elaboration model", N);
2823 if Dynamic_Elaboration_Checks then
2824 Error_Msg_N ("\dynamic elaboration model is in effect", N);
2825 else
2826 pragma Assert (Relaxed_Elaboration_Checks);
2827 Error_Msg_N ("\relaxed elaboration model is in effect", N);
2828 end if;
2829 end if;
2830 end Check_SPARK_Model_In_Effect;
2832 --------------------------
2833 -- Check_SPARK_Scenario --
2834 --------------------------
2836 procedure Check_SPARK_Scenario (N : Node_Id) is
2837 begin
2838 -- Ensure that a suitable elaboration model is in effect for SPARK rule
2839 -- verification.
2841 Check_SPARK_Model_In_Effect (N);
2843 -- Add the current scenario to the stack of active scenarios
2845 Push_Active_Scenario (N);
2847 if Is_Suitable_SPARK_Derived_Type (N) then
2848 Check_SPARK_Derived_Type (N);
2850 elsif Is_Suitable_SPARK_Instantiation (N) then
2851 Check_SPARK_Instantiation (N);
2853 elsif Is_Suitable_SPARK_Refined_State_Pragma (N) then
2854 Check_SPARK_Refined_State_Pragma (N);
2855 end if;
2857 -- Remove the current scenario from the stack of active scenarios once
2858 -- all ABE diagnostics and checks have been performed.
2860 Pop_Active_Scenario (N);
2861 end Check_SPARK_Scenario;
2863 --------------------------------------
2864 -- Check_SPARK_Refined_State_Pragma --
2865 --------------------------------------
2867 procedure Check_SPARK_Refined_State_Pragma (N : Node_Id) is
2869 -- NOTE: The routines within Check_SPARK_Refined_State_Pragma are
2870 -- intentionally unnested to avoid deep indentation of code.
2872 procedure Check_SPARK_Constituent (Constit_Id : Entity_Id);
2873 pragma Inline (Check_SPARK_Constituent);
2874 -- Ensure that a single constituent Constit_Id is elaborated prior to
2875 -- the main unit.
2877 procedure Check_SPARK_Constituents (Constits : Elist_Id);
2878 pragma Inline (Check_SPARK_Constituents);
2879 -- Ensure that all constituents found in list Constits are elaborated
2880 -- prior to the main unit.
2882 procedure Check_SPARK_Initialized_State (State : Node_Id);
2883 pragma Inline (Check_SPARK_Initialized_State);
2884 -- Ensure that the constituents of single abstract state State are
2885 -- elaborated prior to the main unit.
2887 procedure Check_SPARK_Initialized_States (Pack_Id : Entity_Id);
2888 pragma Inline (Check_SPARK_Initialized_States);
2889 -- Ensure that the constituents of all abstract states which appear in
2890 -- the Initializes pragma of package Pack_Id are elaborated prior to the
2891 -- main unit.
2893 -----------------------------
2894 -- Check_SPARK_Constituent --
2895 -----------------------------
2897 procedure Check_SPARK_Constituent (Constit_Id : Entity_Id) is
2898 Prag : Node_Id;
2900 begin
2901 -- Nothing to do for "null" constituents
2903 if Nkind (Constit_Id) = N_Null then
2904 return;
2906 -- Nothing to do for illegal constituents
2908 elsif Error_Posted (Constit_Id) then
2909 return;
2910 end if;
2912 Prag := SPARK_Pragma (Constit_Id);
2914 -- The check applies only when the constituent is subject to pragma
2915 -- SPARK_Mode On.
2917 if Present (Prag)
2918 and then Get_SPARK_Mode_From_Annotation (Prag) = On
2919 then
2920 -- An external constituent of an abstract state which appears in
2921 -- the Initializes pragma of a package spec imposes an Elaborate
2922 -- requirement on the context of the main unit. Determine whether
2923 -- the context has a pragma strong enough to meet the requirement.
2925 -- IMPORTANT: This check is performed only when -gnatd.v (enforce
2926 -- SPARK elaboration rules in SPARK code) is in effect because the
2927 -- static model can ensure the prior elaboration of the unit which
2928 -- contains a constituent by installing implicit Elaborate pragma.
2930 if Debug_Flag_Dot_V then
2931 Meet_Elaboration_Requirement
2932 (N => N,
2933 Target_Id => Constit_Id,
2934 Req_Nam => Name_Elaborate);
2936 -- Otherwise ensure that the unit with the external constituent is
2937 -- elaborated prior to the main unit.
2939 else
2940 Ensure_Prior_Elaboration
2941 (N => N,
2942 Unit_Id => Find_Top_Unit (Constit_Id),
2943 Prag_Nam => Name_Elaborate,
2944 State => Initial_State);
2945 end if;
2946 end if;
2947 end Check_SPARK_Constituent;
2949 ------------------------------
2950 -- Check_SPARK_Constituents --
2951 ------------------------------
2953 procedure Check_SPARK_Constituents (Constits : Elist_Id) is
2954 Constit_Elmt : Elmt_Id;
2956 begin
2957 if Present (Constits) then
2958 Constit_Elmt := First_Elmt (Constits);
2959 while Present (Constit_Elmt) loop
2960 Check_SPARK_Constituent (Node (Constit_Elmt));
2961 Next_Elmt (Constit_Elmt);
2962 end loop;
2963 end if;
2964 end Check_SPARK_Constituents;
2966 -----------------------------------
2967 -- Check_SPARK_Initialized_State --
2968 -----------------------------------
2970 procedure Check_SPARK_Initialized_State (State : Node_Id) is
2971 Prag : Node_Id;
2972 State_Id : Entity_Id;
2974 begin
2975 -- Nothing to do for "null" initialization items
2977 if Nkind (State) = N_Null then
2978 return;
2980 -- Nothing to do for illegal states
2982 elsif Error_Posted (State) then
2983 return;
2984 end if;
2986 State_Id := Entity_Of (State);
2988 -- Sanitize the state
2990 if No (State_Id) then
2991 return;
2993 elsif Error_Posted (State_Id) then
2994 return;
2996 elsif Ekind (State_Id) /= E_Abstract_State then
2997 return;
2998 end if;
3000 -- The check is performed only when the abstract state is subject to
3001 -- SPARK_Mode On.
3003 Prag := SPARK_Pragma (State_Id);
3005 if Present (Prag)
3006 and then Get_SPARK_Mode_From_Annotation (Prag) = On
3007 then
3008 Check_SPARK_Constituents (Refinement_Constituents (State_Id));
3009 end if;
3010 end Check_SPARK_Initialized_State;
3012 ------------------------------------
3013 -- Check_SPARK_Initialized_States --
3014 ------------------------------------
3016 procedure Check_SPARK_Initialized_States (Pack_Id : Entity_Id) is
3017 Prag : constant Node_Id := Get_Pragma (Pack_Id, Pragma_Initializes);
3018 Init : Node_Id;
3019 Inits : Node_Id;
3021 begin
3022 if Present (Prag) then
3023 Inits := Expression (Get_Argument (Prag, Pack_Id));
3025 -- Avoid processing a "null" initialization list. The only other
3026 -- alternative is an aggregate.
3028 if Nkind (Inits) = N_Aggregate then
3030 -- The initialization items appear in list form:
3032 -- (state1, state2)
3034 if Present (Expressions (Inits)) then
3035 Init := First (Expressions (Inits));
3036 while Present (Init) loop
3037 Check_SPARK_Initialized_State (Init);
3038 Next (Init);
3039 end loop;
3040 end if;
3042 -- The initialization items appear in associated form:
3044 -- (state1 => item1,
3045 -- state2 => (item2, item3))
3047 if Present (Component_Associations (Inits)) then
3048 Init := First (Component_Associations (Inits));
3049 while Present (Init) loop
3050 Check_SPARK_Initialized_State (Init);
3051 Next (Init);
3052 end loop;
3053 end if;
3054 end if;
3055 end if;
3056 end Check_SPARK_Initialized_States;
3058 -- Local variables
3060 Pack_Body : constant Node_Id := Find_Related_Package_Or_Body (N);
3062 -- Start of processing for Check_SPARK_Refined_State_Pragma
3064 begin
3065 -- Pragma Refined_State must be associated with a package body
3067 pragma Assert
3068 (Present (Pack_Body) and then Nkind (Pack_Body) = N_Package_Body);
3070 -- Verify that each external contitunent of an abstract state mentioned
3071 -- in pragma Initializes is properly elaborated.
3073 Check_SPARK_Initialized_States (Unique_Defining_Entity (Pack_Body));
3074 end Check_SPARK_Refined_State_Pragma;
3076 ----------------------
3077 -- Compilation_Unit --
3078 ----------------------
3080 function Compilation_Unit (Unit_Id : Entity_Id) return Node_Id is
3081 Comp_Unit : Node_Id;
3083 begin
3084 Comp_Unit := Parent (Unit_Id);
3086 -- Handle the case where a concurrent subunit is rewritten as a null
3087 -- statement due to expansion activities.
3089 if Nkind (Comp_Unit) = N_Null_Statement
3090 and then Nkind_In (Original_Node (Comp_Unit), N_Protected_Body,
3091 N_Task_Body)
3092 then
3093 Comp_Unit := Parent (Comp_Unit);
3094 pragma Assert (Nkind (Comp_Unit) = N_Subunit);
3096 -- Otherwise use the declaration node of the unit
3098 else
3099 Comp_Unit := Parent (Unit_Declaration_Node (Unit_Id));
3100 end if;
3102 -- Handle the case where a subprogram instantiation which acts as a
3103 -- compilation unit is expanded into an anonymous package that wraps
3104 -- the instantiated subprogram.
3106 if Nkind (Comp_Unit) = N_Package_Specification
3107 and then Nkind_In (Original_Node (Parent (Comp_Unit)),
3108 N_Function_Instantiation,
3109 N_Procedure_Instantiation)
3110 then
3111 Comp_Unit := Parent (Parent (Comp_Unit));
3113 -- Handle the case where the compilation unit is a subunit
3115 elsif Nkind (Comp_Unit) = N_Subunit then
3116 Comp_Unit := Parent (Comp_Unit);
3117 end if;
3119 pragma Assert (Nkind (Comp_Unit) = N_Compilation_Unit);
3121 return Comp_Unit;
3122 end Compilation_Unit;
3124 -----------------------
3125 -- Early_Call_Region --
3126 -----------------------
3128 function Early_Call_Region (Body_Id : Entity_Id) return Node_Id is
3129 begin
3130 pragma Assert (Ekind_In (Body_Id, E_Entry,
3131 E_Entry_Family,
3132 E_Function,
3133 E_Procedure,
3134 E_Subprogram_Body));
3136 if Early_Call_Regions_In_Use then
3137 return Early_Call_Regions.Get (Body_Id);
3138 end if;
3140 return Early_Call_Regions_No_Element;
3141 end Early_Call_Region;
3143 -----------------------------
3144 -- Early_Call_Regions_Hash --
3145 -----------------------------
3147 function Early_Call_Regions_Hash
3148 (Key : Entity_Id) return Early_Call_Regions_Index
3150 begin
3151 return Early_Call_Regions_Index (Key mod Early_Call_Regions_Max);
3152 end Early_Call_Regions_Hash;
3154 -----------------
3155 -- Elab_Msg_NE --
3156 -----------------
3158 procedure Elab_Msg_NE
3159 (Msg : String;
3160 N : Node_Id;
3161 Id : Entity_Id;
3162 Info_Msg : Boolean;
3163 In_SPARK : Boolean)
3165 function Prefix return String;
3166 -- Obtain the prefix of the message
3168 function Suffix return String;
3169 -- Obtain the suffix of the message
3171 ------------
3172 -- Prefix --
3173 ------------
3175 function Prefix return String is
3176 begin
3177 if Info_Msg then
3178 return "info: ";
3179 else
3180 return "";
3181 end if;
3182 end Prefix;
3184 ------------
3185 -- Suffix --
3186 ------------
3188 function Suffix return String is
3189 begin
3190 if In_SPARK then
3191 return " in SPARK";
3192 else
3193 return "";
3194 end if;
3195 end Suffix;
3197 -- Start of processing for Elab_Msg_NE
3199 begin
3200 Error_Msg_NE (Prefix & Msg & Suffix, N, Id);
3201 end Elab_Msg_NE;
3203 ------------------------
3204 -- Elaboration_Status --
3205 ------------------------
3207 function Elaboration_Status
3208 (Unit_Id : Entity_Id) return Elaboration_Attributes
3210 begin
3211 if Elaboration_Statuses_In_Use then
3212 return Elaboration_Statuses.Get (Unit_Id);
3213 end if;
3215 return Elaboration_Statuses_No_Element;
3216 end Elaboration_Status;
3218 -------------------------------
3219 -- Elaboration_Statuses_Hash --
3220 -------------------------------
3222 function Elaboration_Statuses_Hash
3223 (Key : Entity_Id) return Elaboration_Statuses_Index
3225 begin
3226 return Elaboration_Statuses_Index (Key mod Elaboration_Statuses_Max);
3227 end Elaboration_Statuses_Hash;
3229 ------------------------------
3230 -- Ensure_Prior_Elaboration --
3231 ------------------------------
3233 procedure Ensure_Prior_Elaboration
3234 (N : Node_Id;
3235 Unit_Id : Entity_Id;
3236 Prag_Nam : Name_Id;
3237 State : Processing_Attributes)
3239 begin
3240 pragma Assert (Nam_In (Prag_Nam, Name_Elaborate, Name_Elaborate_All));
3242 -- Nothing to do when the caller has suppressed the generation of
3243 -- implicit Elaborate[_All] pragmas.
3245 if State.Suppress_Implicit_Pragmas then
3246 return;
3248 -- Nothing to do when the need for prior elaboration came from a partial
3249 -- finalization routine which occurs in an initialization context. This
3250 -- behaviour parallels that of the old ABE mechanism.
3252 elsif State.Within_Partial_Finalization then
3253 return;
3255 -- Nothing to do when the need for prior elaboration came from a task
3256 -- body and switch -gnatd.y (disable implicit pragma Elaborate_All on
3257 -- task bodies) is in effect.
3259 elsif Debug_Flag_Dot_Y and then State.Within_Task_Body then
3260 return;
3262 -- Nothing to do when the unit is elaborated prior to the main unit.
3263 -- This check must also consider the following cases:
3265 -- * No check is made against the context of the main unit because this
3266 -- is specific to the elaboration model in effect and requires custom
3267 -- handling (see Ensure_xxx_Prior_Elaboration).
3269 -- * Unit_Id is subject to pragma Elaborate_Body. An implicit pragma
3270 -- Elaborate[_All] MUST be generated even though Unit_Id is always
3271 -- elaborated prior to the main unit. This is a conservative strategy
3272 -- which ensures that other units withed by Unit_Id will not lead to
3273 -- an ABE.
3275 -- package A is package body A is
3276 -- procedure ABE; procedure ABE is ... end ABE;
3277 -- end A; end A;
3279 -- with A;
3280 -- package B is package body B is
3281 -- pragma Elaborate_Body; procedure Proc is
3282 -- begin
3283 -- procedure Proc; A.ABE;
3284 -- package B; end Proc;
3285 -- end B;
3287 -- with B;
3288 -- package C is package body C is
3289 -- ... ...
3290 -- end C; begin
3291 -- B.Proc;
3292 -- end C;
3294 -- In the example above, the elaboration of C invokes B.Proc. B is
3295 -- subject to pragma Elaborate_Body. If no pragma Elaborate[_All] is
3296 -- generated for B in C, then the following elaboratio order will lead
3297 -- to an ABE:
3299 -- spec of A elaborated
3300 -- spec of B elaborated
3301 -- body of B elaborated
3302 -- spec of C elaborated
3303 -- body of C elaborated <-- calls B.Proc which calls A.ABE
3304 -- body of A elaborated <-- problem
3306 -- The generation of an implicit pragma Elaborate_All (B) ensures that
3307 -- the elaboration order mechanism will not pick the above order.
3309 -- An implicit Elaborate is NOT generated when the unit is subject to
3310 -- Elaborate_Body because both pragmas have the exact same effect.
3312 -- * Unit_Id is the main unit. An implicit pragma Elaborate[_All] MUST
3313 -- NOT be generated in this case because a unit cannot depend on its
3314 -- own elaboration. This case is therefore treated as valid prior
3315 -- elaboration.
3317 elsif Has_Prior_Elaboration
3318 (Unit_Id => Unit_Id,
3319 Same_Unit_OK => True,
3320 Elab_Body_OK => Prag_Nam = Name_Elaborate)
3321 then
3322 return;
3324 -- Suggest the use of pragma Prag_Nam when the dynamic model is in
3325 -- effect.
3327 elsif Dynamic_Elaboration_Checks then
3328 Ensure_Prior_Elaboration_Dynamic
3329 (N => N,
3330 Unit_Id => Unit_Id,
3331 Prag_Nam => Prag_Nam);
3333 -- Install an implicit pragma Prag_Nam when the static model is in
3334 -- effect.
3336 else
3337 pragma Assert (Static_Elaboration_Checks);
3339 Ensure_Prior_Elaboration_Static
3340 (N => N,
3341 Unit_Id => Unit_Id,
3342 Prag_Nam => Prag_Nam);
3343 end if;
3344 end Ensure_Prior_Elaboration;
3346 --------------------------------------
3347 -- Ensure_Prior_Elaboration_Dynamic --
3348 --------------------------------------
3350 procedure Ensure_Prior_Elaboration_Dynamic
3351 (N : Node_Id;
3352 Unit_Id : Entity_Id;
3353 Prag_Nam : Name_Id)
3355 procedure Info_Missing_Pragma;
3356 pragma Inline (Info_Missing_Pragma);
3357 -- Output information concerning missing Elaborate or Elaborate_All
3358 -- pragma with name Prag_Nam for scenario N, which would ensure the
3359 -- prior elaboration of Unit_Id.
3361 -------------------------
3362 -- Info_Missing_Pragma --
3363 -------------------------
3365 procedure Info_Missing_Pragma is
3366 begin
3367 -- Internal units are ignored as they cause unnecessary noise
3369 if not In_Internal_Unit (Unit_Id) then
3371 -- The name of the unit subjected to the elaboration pragma is
3372 -- fully qualified to improve the clarity of the info message.
3374 Error_Msg_Name_1 := Prag_Nam;
3375 Error_Msg_Qual_Level := Nat'Last;
3377 Error_Msg_NE ("info: missing pragma % for unit &", N, Unit_Id);
3378 Error_Msg_Qual_Level := 0;
3379 end if;
3380 end Info_Missing_Pragma;
3382 -- Local variables
3384 Elab_Attrs : Elaboration_Attributes;
3385 Level : Enclosing_Level_Kind;
3387 -- Start of processing for Ensure_Prior_Elaboration_Dynamic
3389 begin
3390 Elab_Attrs := Elaboration_Status (Unit_Id);
3392 -- Nothing to do when the unit is guaranteed prior elaboration by means
3393 -- of a source Elaborate[_All] pragma.
3395 if Present (Elab_Attrs.Source_Pragma) then
3396 return;
3397 end if;
3399 -- Output extra information on a missing Elaborate[_All] pragma when
3400 -- switch -gnatel (info messages on implicit Elaborate[_All] pragmas
3401 -- is in effect.
3403 if Elab_Info_Messages then
3405 -- Performance note: parent traversal
3407 Level := Find_Enclosing_Level (N);
3409 -- Declaration-level scenario
3411 if (Is_Suitable_Call (N) or else Is_Suitable_Instantiation (N))
3412 and then Level = Declaration_Level
3413 then
3414 null;
3416 -- Library-level scenario
3418 elsif Level in Library_Level then
3419 null;
3421 -- Instantiation library-level scenario
3423 elsif Level = Instantiation then
3424 null;
3426 -- Otherwise the scenario does not appear at the proper level and
3427 -- cannot possibly act as a top-level scenario.
3429 else
3430 return;
3431 end if;
3433 Info_Missing_Pragma;
3434 end if;
3435 end Ensure_Prior_Elaboration_Dynamic;
3437 -------------------------------------
3438 -- Ensure_Prior_Elaboration_Static --
3439 -------------------------------------
3441 procedure Ensure_Prior_Elaboration_Static
3442 (N : Node_Id;
3443 Unit_Id : Entity_Id;
3444 Prag_Nam : Name_Id)
3446 function Find_With_Clause
3447 (Items : List_Id;
3448 Withed_Id : Entity_Id) return Node_Id;
3449 pragma Inline (Find_With_Clause);
3450 -- Find a nonlimited with clause in the list of context items Items
3451 -- that withs unit Withed_Id. Return Empty if no such clause is found.
3453 procedure Info_Implicit_Pragma;
3454 pragma Inline (Info_Implicit_Pragma);
3455 -- Output information concerning an implicitly generated Elaborate or
3456 -- Elaborate_All pragma with name Prag_Nam for scenario N which ensures
3457 -- the prior elaboration of unit Unit_Id.
3459 ----------------------
3460 -- Find_With_Clause --
3461 ----------------------
3463 function Find_With_Clause
3464 (Items : List_Id;
3465 Withed_Id : Entity_Id) return Node_Id
3467 Item : Node_Id;
3469 begin
3470 -- Examine the context clauses looking for a suitable with. Note that
3471 -- limited clauses do not affect the elaboration order.
3473 Item := First (Items);
3474 while Present (Item) loop
3475 if Nkind (Item) = N_With_Clause
3476 and then not Error_Posted (Item)
3477 and then not Limited_Present (Item)
3478 and then Entity (Name (Item)) = Withed_Id
3479 then
3480 return Item;
3481 end if;
3483 Next (Item);
3484 end loop;
3486 return Empty;
3487 end Find_With_Clause;
3489 --------------------------
3490 -- Info_Implicit_Pragma --
3491 --------------------------
3493 procedure Info_Implicit_Pragma is
3494 begin
3495 -- Internal units are ignored as they cause unnecessary noise
3497 if not In_Internal_Unit (Unit_Id) then
3499 -- The name of the unit subjected to the elaboration pragma is
3500 -- fully qualified to improve the clarity of the info message.
3502 Error_Msg_Name_1 := Prag_Nam;
3503 Error_Msg_Qual_Level := Nat'Last;
3505 Error_Msg_NE
3506 ("info: implicit pragma % generated for unit &", N, Unit_Id);
3508 Error_Msg_Qual_Level := 0;
3509 Output_Active_Scenarios (N);
3510 end if;
3511 end Info_Implicit_Pragma;
3513 -- Local variables
3515 Main_Cunit : constant Node_Id := Cunit (Main_Unit);
3516 Loc : constant Source_Ptr := Sloc (Main_Cunit);
3517 Unit_Cunit : constant Node_Id := Compilation_Unit (Unit_Id);
3519 Clause : Node_Id;
3520 Elab_Attrs : Elaboration_Attributes;
3521 Items : List_Id;
3523 -- Start of processing for Ensure_Prior_Elaboration_Static
3525 begin
3526 Elab_Attrs := Elaboration_Status (Unit_Id);
3528 -- Nothing to do when the unit is guaranteed prior elaboration by means
3529 -- of a source Elaborate[_All] pragma.
3531 if Present (Elab_Attrs.Source_Pragma) then
3532 return;
3534 -- Nothing to do when the unit has an existing implicit Elaborate[_All]
3535 -- pragma installed by a previous scenario.
3537 elsif Present (Elab_Attrs.With_Clause) then
3539 -- The unit is already guaranteed prior elaboration by means of an
3540 -- implicit Elaborate pragma, however the current scenario imposes
3541 -- a stronger requirement of Elaborate_All. "Upgrade" the existing
3542 -- pragma to match this new requirement.
3544 if Elaborate_Desirable (Elab_Attrs.With_Clause)
3545 and then Prag_Nam = Name_Elaborate_All
3546 then
3547 Set_Elaborate_All_Desirable (Elab_Attrs.With_Clause);
3548 Set_Elaborate_Desirable (Elab_Attrs.With_Clause, False);
3549 end if;
3551 return;
3552 end if;
3554 -- At this point it is known that the unit has no prior elaboration
3555 -- according to pragmas and hierarchical relationships.
3557 Items := Context_Items (Main_Cunit);
3559 if No (Items) then
3560 Items := New_List;
3561 Set_Context_Items (Main_Cunit, Items);
3562 end if;
3564 -- Locate the with clause for the unit. Note that there may not be a
3565 -- clause if the unit is visible through a subunit-body, body-spec, or
3566 -- spec-parent relationship.
3568 Clause :=
3569 Find_With_Clause
3570 (Items => Items,
3571 Withed_Id => Unit_Id);
3573 -- Generate:
3574 -- with Id;
3576 -- Note that adding implicit with clauses is safe because analysis,
3577 -- resolution, and expansion have already taken place and it is not
3578 -- possible to interfere with visibility.
3580 if No (Clause) then
3581 Clause :=
3582 Make_With_Clause (Loc,
3583 Name => New_Occurrence_Of (Unit_Id, Loc));
3585 Set_Implicit_With (Clause);
3586 Set_Library_Unit (Clause, Unit_Cunit);
3588 Append_To (Items, Clause);
3589 end if;
3591 -- Mark the with clause depending on the pragma required
3593 if Prag_Nam = Name_Elaborate then
3594 Set_Elaborate_Desirable (Clause);
3595 else
3596 Set_Elaborate_All_Desirable (Clause);
3597 end if;
3599 -- The implicit Elaborate[_All] ensures the prior elaboration of the
3600 -- unit. Include the unit in the elaboration context of the main unit.
3602 Set_Elaboration_Status
3603 (Unit_Id => Unit_Id,
3604 Val => Elaboration_Attributes'(Source_Pragma => Empty,
3605 With_Clause => Clause));
3607 -- Output extra information on an implicit Elaborate[_All] pragma when
3608 -- switch -gnatel (info messages on implicit Elaborate[_All] pragmas is
3609 -- in effect.
3611 if Elab_Info_Messages then
3612 Info_Implicit_Pragma;
3613 end if;
3614 end Ensure_Prior_Elaboration_Static;
3616 -----------------------------
3617 -- Extract_Assignment_Name --
3618 -----------------------------
3620 function Extract_Assignment_Name (Asmt : Node_Id) return Node_Id is
3621 Nam : Node_Id;
3623 begin
3624 Nam := Name (Asmt);
3626 -- When the name denotes an array or record component, find the whole
3627 -- object.
3629 while Nkind_In (Nam, N_Explicit_Dereference,
3630 N_Indexed_Component,
3631 N_Selected_Component,
3632 N_Slice)
3633 loop
3634 Nam := Prefix (Nam);
3635 end loop;
3637 return Nam;
3638 end Extract_Assignment_Name;
3640 -----------------------------
3641 -- Extract_Call_Attributes --
3642 -----------------------------
3644 procedure Extract_Call_Attributes
3645 (Call : Node_Id;
3646 Target_Id : out Entity_Id;
3647 Attrs : out Call_Attributes)
3649 From_Source : Boolean;
3650 In_Declarations : Boolean;
3651 Is_Dispatching : Boolean;
3653 begin
3654 -- Extraction for call markers
3656 if Nkind (Call) = N_Call_Marker then
3657 Target_Id := Target (Call);
3658 From_Source := Is_Source_Call (Call);
3659 In_Declarations := Is_Declaration_Level_Node (Call);
3660 Is_Dispatching := Is_Dispatching_Call (Call);
3662 -- Extraction for entry calls, requeue, and subprogram calls
3664 else
3665 pragma Assert (Nkind_In (Call, N_Entry_Call_Statement,
3666 N_Function_Call,
3667 N_Procedure_Call_Statement,
3668 N_Requeue_Statement));
3670 Target_Id := Entity (Extract_Call_Name (Call));
3671 From_Source := Comes_From_Source (Call);
3673 -- Performance note: parent traversal
3675 In_Declarations := Find_Enclosing_Level (Call) = Declaration_Level;
3676 Is_Dispatching :=
3677 Nkind_In (Call, N_Function_Call, N_Procedure_Call_Statement)
3678 and then Present (Controlling_Argument (Call));
3679 end if;
3681 -- Obtain the original entry or subprogram which the target may rename
3682 -- except when the target is an instantiation. In this case the alias
3683 -- is the internally generated subprogram which appears within the the
3684 -- anonymous package created for the instantiation. Such an alias is not
3685 -- a suitable target.
3687 if not (Is_Subprogram (Target_Id)
3688 and then Is_Generic_Instance (Target_Id))
3689 then
3690 Target_Id := Get_Renamed_Entity (Target_Id);
3691 end if;
3693 -- Set all attributes
3695 Attrs.Elab_Checks_OK := Is_Elaboration_Checks_OK_Node (Call);
3696 Attrs.Elab_Warnings_OK := Is_Elaboration_Warnings_OK_Node (Call);
3697 Attrs.From_Source := From_Source;
3698 Attrs.Ghost_Mode_Ignore := Is_Ignored_Ghost_Node (Call);
3699 Attrs.In_Declarations := In_Declarations;
3700 Attrs.Is_Dispatching := Is_Dispatching;
3701 Attrs.SPARK_Mode_On := Is_SPARK_Mode_On_Node (Call);
3702 end Extract_Call_Attributes;
3704 -----------------------
3705 -- Extract_Call_Name --
3706 -----------------------
3708 function Extract_Call_Name (Call : Node_Id) return Node_Id is
3709 Nam : Node_Id;
3711 begin
3712 Nam := Name (Call);
3714 -- When the call invokes an entry family, the name appears as an indexed
3715 -- component.
3717 if Nkind (Nam) = N_Indexed_Component then
3718 Nam := Prefix (Nam);
3719 end if;
3721 -- When the call employs the object.operation form, the name appears as
3722 -- a selected component.
3724 if Nkind (Nam) = N_Selected_Component then
3725 Nam := Selector_Name (Nam);
3726 end if;
3728 return Nam;
3729 end Extract_Call_Name;
3731 ---------------------------------
3732 -- Extract_Instance_Attributes --
3733 ---------------------------------
3735 procedure Extract_Instance_Attributes
3736 (Exp_Inst : Node_Id;
3737 Inst_Body : out Node_Id;
3738 Inst_Decl : out Node_Id)
3740 Body_Id : Entity_Id;
3742 begin
3743 -- Assume that the attributes are unavailable
3745 Inst_Body := Empty;
3746 Inst_Decl := Empty;
3748 -- Generic package or subprogram spec
3750 if Nkind_In (Exp_Inst, N_Package_Declaration,
3751 N_Subprogram_Declaration)
3752 then
3753 Inst_Decl := Exp_Inst;
3754 Body_Id := Corresponding_Body (Inst_Decl);
3756 if Present (Body_Id) then
3757 Inst_Body := Unit_Declaration_Node (Body_Id);
3758 end if;
3760 -- Generic package or subprogram body
3762 else
3763 pragma Assert
3764 (Nkind_In (Exp_Inst, N_Package_Body, N_Subprogram_Body));
3766 Inst_Body := Exp_Inst;
3767 Inst_Decl := Unit_Declaration_Node (Corresponding_Spec (Inst_Body));
3768 end if;
3769 end Extract_Instance_Attributes;
3771 --------------------------------------
3772 -- Extract_Instantiation_Attributes --
3773 --------------------------------------
3775 procedure Extract_Instantiation_Attributes
3776 (Exp_Inst : Node_Id;
3777 Inst : out Node_Id;
3778 Inst_Id : out Entity_Id;
3779 Gen_Id : out Entity_Id;
3780 Attrs : out Instantiation_Attributes)
3782 begin
3783 Inst := Original_Node (Exp_Inst);
3784 Inst_Id := Defining_Entity (Inst);
3786 -- Traverse a possible chain of renamings to obtain the original generic
3787 -- being instantiatied.
3789 Gen_Id := Get_Renamed_Entity (Entity (Name (Inst)));
3791 -- Set all attributes
3793 Attrs.Elab_Checks_OK := Is_Elaboration_Checks_OK_Node (Inst);
3794 Attrs.Elab_Warnings_OK := Is_Elaboration_Warnings_OK_Node (Inst);
3795 Attrs.Ghost_Mode_Ignore := Is_Ignored_Ghost_Node (Inst);
3796 Attrs.In_Declarations := Is_Declaration_Level_Node (Inst);
3797 Attrs.SPARK_Mode_On := Is_SPARK_Mode_On_Node (Inst);
3798 end Extract_Instantiation_Attributes;
3800 -------------------------------
3801 -- Extract_Target_Attributes --
3802 -------------------------------
3804 procedure Extract_Target_Attributes
3805 (Target_Id : Entity_Id;
3806 Attrs : out Target_Attributes)
3808 procedure Extract_Package_Or_Subprogram_Attributes
3809 (Spec_Id : out Entity_Id;
3810 Body_Decl : out Node_Id);
3811 -- Obtain the attributes associated with a package or a subprogram.
3812 -- Spec_Id is the package or subprogram. Body_Decl is the declaration
3813 -- of the corresponding package or subprogram body.
3815 procedure Extract_Protected_Entry_Attributes
3816 (Spec_Id : out Entity_Id;
3817 Body_Decl : out Node_Id;
3818 Body_Barf : out Node_Id);
3819 -- Obtain the attributes associated with a protected entry [family].
3820 -- Spec_Id is the entity of the protected body subprogram. Body_Decl
3821 -- is the declaration of Spec_Id's corresponding body. Body_Barf is
3822 -- the declaration of the barrier function body.
3824 procedure Extract_Protected_Subprogram_Attributes
3825 (Spec_Id : out Entity_Id;
3826 Body_Decl : out Node_Id);
3827 -- Obtain the attributes associated with a protected subprogram. Formal
3828 -- Spec_Id is the entity of the protected body subprogram. Body_Decl is
3829 -- the declaration of Spec_Id's corresponding body.
3831 procedure Extract_Task_Entry_Attributes
3832 (Spec_Id : out Entity_Id;
3833 Body_Decl : out Node_Id);
3834 -- Obtain the attributes associated with a task entry [family]. Formal
3835 -- Spec_Id is the entity of the task body procedure. Body_Decl is the
3836 -- declaration of Spec_Id's corresponding body.
3838 ----------------------------------------------
3839 -- Extract_Package_Or_Subprogram_Attributes --
3840 ----------------------------------------------
3842 procedure Extract_Package_Or_Subprogram_Attributes
3843 (Spec_Id : out Entity_Id;
3844 Body_Decl : out Node_Id)
3846 Body_Id : Entity_Id;
3847 Init_Id : Entity_Id;
3848 Spec_Decl : Node_Id;
3850 begin
3851 -- Assume that the body is not available
3853 Body_Decl := Empty;
3854 Spec_Id := Target_Id;
3856 -- For body retrieval purposes, the entity of the initial declaration
3857 -- is that of the spec.
3859 Init_Id := Spec_Id;
3861 -- The only exception to the above is a function which returns a
3862 -- constrained array type in a SPARK-to-C compilation. In this case
3863 -- the function receives a corresponding procedure which has an out
3864 -- parameter. The proper body for ABE checks and diagnostics is that
3865 -- of the procedure.
3867 if Ekind (Init_Id) = E_Function
3868 and then Rewritten_For_C (Init_Id)
3869 then
3870 Init_Id := Corresponding_Procedure (Init_Id);
3871 end if;
3873 -- Extract the attributes of the body
3875 Spec_Decl := Unit_Declaration_Node (Init_Id);
3877 -- The initial declaration is a stand alone subprogram body
3879 if Nkind (Spec_Decl) = N_Subprogram_Body then
3880 Body_Decl := Spec_Decl;
3882 -- Otherwise the package or subprogram has a spec and a completing
3883 -- body.
3885 elsif Nkind_In (Spec_Decl, N_Generic_Package_Declaration,
3886 N_Generic_Subprogram_Declaration,
3887 N_Package_Declaration,
3888 N_Subprogram_Body_Stub,
3889 N_Subprogram_Declaration)
3890 then
3891 Body_Id := Corresponding_Body (Spec_Decl);
3893 if Present (Body_Id) then
3894 Body_Decl := Unit_Declaration_Node (Body_Id);
3895 end if;
3896 end if;
3897 end Extract_Package_Or_Subprogram_Attributes;
3899 ----------------------------------------
3900 -- Extract_Protected_Entry_Attributes --
3901 ----------------------------------------
3903 procedure Extract_Protected_Entry_Attributes
3904 (Spec_Id : out Entity_Id;
3905 Body_Decl : out Node_Id;
3906 Body_Barf : out Node_Id)
3908 Barf_Id : Entity_Id;
3909 Body_Id : Entity_Id;
3911 begin
3912 -- Assume that the bodies are not available
3914 Body_Barf := Empty;
3915 Body_Decl := Empty;
3917 -- When the entry [family] has already been expanded, it carries both
3918 -- the procedure which emulates the behavior of the entry [family] as
3919 -- well as the barrier function.
3921 if Present (Protected_Body_Subprogram (Target_Id)) then
3922 Spec_Id := Protected_Body_Subprogram (Target_Id);
3924 -- Extract the attributes of the barrier function
3926 Barf_Id :=
3927 Corresponding_Body
3928 (Unit_Declaration_Node (Barrier_Function (Target_Id)));
3930 if Present (Barf_Id) then
3931 Body_Barf := Unit_Declaration_Node (Barf_Id);
3932 end if;
3934 -- Otherwise no expansion took place
3936 else
3937 Spec_Id := Target_Id;
3938 end if;
3940 -- Extract the attributes of the entry body
3942 Body_Id := Corresponding_Body (Unit_Declaration_Node (Spec_Id));
3944 if Present (Body_Id) then
3945 Body_Decl := Unit_Declaration_Node (Body_Id);
3946 end if;
3947 end Extract_Protected_Entry_Attributes;
3949 ---------------------------------------------
3950 -- Extract_Protected_Subprogram_Attributes --
3951 ---------------------------------------------
3953 procedure Extract_Protected_Subprogram_Attributes
3954 (Spec_Id : out Entity_Id;
3955 Body_Decl : out Node_Id)
3957 Body_Id : Entity_Id;
3959 begin
3960 -- Assume that the body is not available
3962 Body_Decl := Empty;
3964 -- When the protected subprogram has already been expanded, it
3965 -- carries the subprogram which seizes the lock and invokes the
3966 -- original statements.
3968 if Present (Protected_Subprogram (Target_Id)) then
3969 Spec_Id :=
3970 Protected_Body_Subprogram (Protected_Subprogram (Target_Id));
3972 -- Otherwise no expansion took place
3974 else
3975 Spec_Id := Target_Id;
3976 end if;
3978 -- Extract the attributes of the body
3980 Body_Id := Corresponding_Body (Unit_Declaration_Node (Spec_Id));
3982 if Present (Body_Id) then
3983 Body_Decl := Unit_Declaration_Node (Body_Id);
3984 end if;
3985 end Extract_Protected_Subprogram_Attributes;
3987 -----------------------------------
3988 -- Extract_Task_Entry_Attributes --
3989 -----------------------------------
3991 procedure Extract_Task_Entry_Attributes
3992 (Spec_Id : out Entity_Id;
3993 Body_Decl : out Node_Id)
3995 Task_Typ : constant Entity_Id := Non_Private_View (Scope (Target_Id));
3996 Body_Id : Entity_Id;
3998 begin
3999 -- Assume that the body is not available
4001 Body_Decl := Empty;
4003 -- The the task type has already been expanded, it carries the
4004 -- procedure which emulates the behavior of the task body.
4006 if Present (Task_Body_Procedure (Task_Typ)) then
4007 Spec_Id := Task_Body_Procedure (Task_Typ);
4009 -- Otherwise no expansion took place
4011 else
4012 Spec_Id := Task_Typ;
4013 end if;
4015 -- Extract the attributes of the body
4017 Body_Id := Corresponding_Body (Unit_Declaration_Node (Spec_Id));
4019 if Present (Body_Id) then
4020 Body_Decl := Unit_Declaration_Node (Body_Id);
4021 end if;
4022 end Extract_Task_Entry_Attributes;
4024 -- Local variables
4026 Prag : constant Node_Id := SPARK_Pragma (Target_Id);
4027 Body_Barf : Node_Id;
4028 Body_Decl : Node_Id;
4029 Spec_Id : Entity_Id;
4031 -- Start of processing for Extract_Target_Attributes
4033 begin
4034 -- Assume that the body of the barrier function is not available
4036 Body_Barf := Empty;
4038 -- The target is a protected entry [family]
4040 if Is_Protected_Entry (Target_Id) then
4041 Extract_Protected_Entry_Attributes
4042 (Spec_Id => Spec_Id,
4043 Body_Decl => Body_Decl,
4044 Body_Barf => Body_Barf);
4046 -- The target is a protected subprogram
4048 elsif Is_Protected_Subp (Target_Id)
4049 or else Is_Protected_Body_Subp (Target_Id)
4050 then
4051 Extract_Protected_Subprogram_Attributes
4052 (Spec_Id => Spec_Id,
4053 Body_Decl => Body_Decl);
4055 -- The target is a task entry [family]
4057 elsif Is_Task_Entry (Target_Id) then
4058 Extract_Task_Entry_Attributes
4059 (Spec_Id => Spec_Id,
4060 Body_Decl => Body_Decl);
4062 -- Otherwise the target is a package or a subprogram
4064 else
4065 Extract_Package_Or_Subprogram_Attributes
4066 (Spec_Id => Spec_Id,
4067 Body_Decl => Body_Decl);
4068 end if;
4070 -- Set all attributes
4072 Attrs.Body_Barf := Body_Barf;
4073 Attrs.Body_Decl := Body_Decl;
4074 Attrs.Elab_Checks_OK := Is_Elaboration_Checks_OK_Id (Target_Id);
4075 Attrs.From_Source := Comes_From_Source (Target_Id);
4076 Attrs.Ghost_Mode_Ignore := Is_Ignored_Ghost_Entity (Target_Id);
4077 Attrs.SPARK_Mode_On :=
4078 Present (Prag) and then Get_SPARK_Mode_From_Annotation (Prag) = On;
4079 Attrs.Spec_Decl := Unit_Declaration_Node (Spec_Id);
4080 Attrs.Spec_Id := Spec_Id;
4081 Attrs.Unit_Id := Find_Top_Unit (Target_Id);
4083 -- At this point certain attributes should always be available
4085 pragma Assert (Present (Attrs.Spec_Decl));
4086 pragma Assert (Present (Attrs.Spec_Id));
4087 pragma Assert (Present (Attrs.Unit_Id));
4088 end Extract_Target_Attributes;
4090 -----------------------------
4091 -- Extract_Task_Attributes --
4092 -----------------------------
4094 procedure Extract_Task_Attributes
4095 (Typ : Entity_Id;
4096 Attrs : out Task_Attributes)
4098 Task_Typ : constant Entity_Id := Non_Private_View (Typ);
4100 Body_Decl : Node_Id;
4101 Body_Id : Entity_Id;
4102 Prag : Node_Id;
4103 Spec_Id : Entity_Id;
4105 begin
4106 -- Assume that the body of the task procedure is not available
4108 Body_Decl := Empty;
4110 -- The initial declaration is that of the task body procedure
4112 Spec_Id := Get_Task_Body_Procedure (Task_Typ);
4113 Body_Id := Corresponding_Body (Unit_Declaration_Node (Spec_Id));
4115 if Present (Body_Id) then
4116 Body_Decl := Unit_Declaration_Node (Body_Id);
4117 end if;
4119 Prag := SPARK_Pragma (Task_Typ);
4121 -- Set all attributes
4123 Attrs.Body_Decl := Body_Decl;
4124 Attrs.Elab_Checks_OK := Is_Elaboration_Checks_OK_Id (Task_Typ);
4125 Attrs.Ghost_Mode_Ignore := Is_Ignored_Ghost_Entity (Task_Typ);
4126 Attrs.SPARK_Mode_On :=
4127 Present (Prag) and then Get_SPARK_Mode_From_Annotation (Prag) = On;
4128 Attrs.Spec_Id := Spec_Id;
4129 Attrs.Task_Decl := Declaration_Node (Task_Typ);
4130 Attrs.Unit_Id := Find_Top_Unit (Task_Typ);
4132 -- At this point certain attributes should always be available
4134 pragma Assert (Present (Attrs.Spec_Id));
4135 pragma Assert (Present (Attrs.Task_Decl));
4136 pragma Assert (Present (Attrs.Unit_Id));
4137 end Extract_Task_Attributes;
4139 -------------------------------------------
4140 -- Extract_Variable_Reference_Attributes --
4141 -------------------------------------------
4143 procedure Extract_Variable_Reference_Attributes
4144 (Ref : Node_Id;
4145 Var_Id : out Entity_Id;
4146 Attrs : out Variable_Attributes)
4148 function Get_Renamed_Variable (Id : Entity_Id) return Entity_Id;
4149 -- Obtain the ultimate renamed variable of variable Id
4151 --------------------------
4152 -- Get_Renamed_Variable --
4153 --------------------------
4155 function Get_Renamed_Variable (Id : Entity_Id) return Entity_Id is
4156 Ren_Id : Entity_Id;
4158 begin
4159 Ren_Id := Id;
4160 while Present (Renamed_Entity (Ren_Id))
4161 and then Nkind (Renamed_Entity (Ren_Id)) in N_Entity
4162 loop
4163 Ren_Id := Renamed_Entity (Ren_Id);
4164 end loop;
4166 return Ren_Id;
4167 end Get_Renamed_Variable;
4169 -- Start of processing for Extract_Variable_Reference_Attributes
4171 begin
4172 -- Extraction for variable reference markers
4174 if Nkind (Ref) = N_Variable_Reference_Marker then
4175 Var_Id := Target (Ref);
4177 -- Extraction for expanded names and identifiers
4179 else
4180 Var_Id := Entity (Ref);
4181 end if;
4183 -- Obtain the original variable which the reference mentions
4185 Var_Id := Get_Renamed_Variable (Var_Id);
4186 Attrs.Unit_Id := Find_Top_Unit (Var_Id);
4188 -- At this point certain attributes should always be available
4190 pragma Assert (Present (Attrs.Unit_Id));
4191 end Extract_Variable_Reference_Attributes;
4193 --------------------
4194 -- Find_Code_Unit --
4195 --------------------
4197 function Find_Code_Unit (N : Node_Or_Entity_Id) return Entity_Id is
4198 begin
4199 return Find_Unit_Entity (Unit (Cunit (Get_Code_Unit (N))));
4200 end Find_Code_Unit;
4202 ----------------------------
4203 -- Find_Early_Call_Region --
4204 ----------------------------
4206 function Find_Early_Call_Region
4207 (Body_Decl : Node_Id;
4208 Assume_Elab_Body : Boolean := False;
4209 Skip_Memoization : Boolean := False) return Node_Id
4211 -- NOTE: The routines within Find_Early_Call_Region are intentionally
4212 -- unnested to avoid deep indentation of code.
4214 ECR_Found : exception;
4215 -- This exception is raised when the early call region has been found
4217 Start : Node_Id := Empty;
4218 -- The start of the early call region. This variable is updated by the
4219 -- various nested routines. Due to the use of exceptions, the variable
4220 -- must be global to the nested routines.
4222 -- The algorithm implemented in this routine attempts to find the early
4223 -- call region of a subprogram body by inspecting constructs in reverse
4224 -- declarative order, while navigating the tree. The algorithm consists
4225 -- of an Inspection phase and an Advancement phase. The pseudocode is as
4226 -- follows:
4228 -- loop
4229 -- inspection phase
4230 -- advancement phase
4231 -- end loop
4233 -- The infinite loop is terminated by raising exception ECR_Found. The
4234 -- algorithm utilizes two pointers, Curr and Start, to represent the
4235 -- current construct to inspect and the start of the early call region.
4237 -- IMPORTANT: The algorithm must maintain the following invariant at all
4238 -- time for it to function properly - a nested construct is entered only
4239 -- when it contains suitable constructs. This guarantees that leaving a
4240 -- nested or encapsulating construct functions properly.
4242 -- The Inspection phase determines whether the current construct is non-
4243 -- preelaborable, and if it is, the algorithm terminates.
4245 -- The Advancement phase walks the tree in reverse declarative order,
4246 -- while entering and leaving nested and encapsulating constructs. It
4247 -- may also terminate the elaborithm. There are several special cases
4248 -- of advancement.
4250 -- 1) General case:
4252 -- <construct 1>
4253 -- ...
4254 -- <construct N-1> <- Curr
4255 -- <construct N> <- Start
4256 -- <subprogram body>
4258 -- In the general case, a declarative or statement list is traversed in
4259 -- reverse order where Curr is the lead pointer, and Start indicates the
4260 -- last preelaborable construct.
4262 -- 2) Entering handled bodies
4264 -- package body Nested is <- Curr (2.3)
4265 -- <declarations> <- Curr (2.2)
4266 -- begin
4267 -- <statements> <- Curr (2.1)
4268 -- end Nested;
4269 -- <construct> <- Start
4271 -- In this case, the algorithm enters a handled body by starting from
4272 -- the last statement (2.1), or the last declaration (2.2), or the body
4273 -- is consumed (2.3) because it is empty and thus preelaborable.
4275 -- 3) Entering package declarations
4277 -- package Nested is <- Curr (2.3)
4278 -- <visible declarations> <- Curr (2.2)
4279 -- private
4280 -- <private declarations> <- Curr (2.1)
4281 -- end Nested;
4282 -- <construct> <- Start
4284 -- In this case, the algorithm enters a package declaration by starting
4285 -- from the last private declaration (2.1), the last visible declaration
4286 -- (2.2), or the package is consumed (2.3) because it is empty and thus
4287 -- preelaborable.
4289 -- 4) Transitioning from list to list of the same construct
4291 -- Certain constructs have two eligible lists. The algorithm must thus
4292 -- transition from the second to the first list when the second list is
4293 -- exhausted.
4295 -- declare <- Curr (4.2)
4296 -- <declarations> <- Curr (4.1)
4297 -- begin
4298 -- <statements> <- Start
4299 -- end;
4301 -- In this case, the algorithm has exhausted the second list (statements
4302 -- in the example), and continues with the last declaration (4.1) or the
4303 -- construct is consumed (4.2) because it contains only preelaborable
4304 -- code.
4306 -- 5) Transitioning from list to construct
4308 -- tack body Task is <- Curr (5.1)
4309 -- <- Curr (Empty)
4310 -- <construct 1> <- Start
4312 -- In this case, the algorithm has exhausted a list, Curr is Empty, and
4313 -- the owner of the list is consumed (5.1).
4315 -- 6) Transitioning from unit to unit
4317 -- A package body with a spec subject to pragma Elaborate_Body extends
4318 -- the possible range of the early call region to the package spec.
4320 -- package Pack is <- Curr (6.3)
4321 -- pragma Elaborate_Body; <- Curr (6.2)
4322 -- <visible declarations> <- Curr (6.2)
4323 -- private
4324 -- <private declarations> <- Curr (6.1)
4325 -- end Pack;
4327 -- package body Pack is <- Curr, Start
4329 -- In this case, the algorithm has reached a package body compilation
4330 -- unit whose spec is subject to pragma Elaborate_Body, or the caller
4331 -- of the algorithm has specified this behavior. This transition is
4332 -- equivalent to 3).
4334 -- 7) Transitioning from unit to termination
4336 -- Reaching a compilation unit always terminates the algorithm as there
4337 -- are no more lists to examine. This must take 6) into account.
4339 -- 8) Transitioning from subunit to stub
4341 -- package body Pack is separate; <- Curr (8.1)
4343 -- separate (...)
4344 -- package body Pack is <- Curr, Start
4346 -- Reaching a subunit continues the search from the corresponding stub
4347 -- (8.1).
4349 procedure Advance (Curr : in out Node_Id);
4350 pragma Inline (Advance);
4351 -- Update the Curr and Start pointers depending on their location in the
4352 -- tree to the next eligible construct. This routine raises ECR_Found.
4354 procedure Enter_Handled_Body (Curr : in out Node_Id);
4355 pragma Inline (Enter_Handled_Body);
4356 -- Update the Curr and Start pointers to enter a nested handled body if
4357 -- applicable. This routine raises ECR_Found.
4359 procedure Enter_Package_Declaration (Curr : in out Node_Id);
4360 pragma Inline (Enter_Package_Declaration);
4361 -- Update the Curr and Start pointers to enter a nested package spec if
4362 -- applicable. This routine raises ECR_Found.
4364 function Find_ECR (N : Node_Id) return Node_Id;
4365 pragma Inline (Find_ECR);
4366 -- Find an early call region starting from arbitrary node N
4368 function Has_Suitable_Construct (List : List_Id) return Boolean;
4369 pragma Inline (Has_Suitable_Construct);
4370 -- Determine whether list List contains at least one suitable construct
4371 -- for inclusion into an early call region.
4373 procedure Include (N : Node_Id; Curr : out Node_Id);
4374 pragma Inline (Include);
4375 -- Update the Curr and Start pointers to include arbitrary construct N
4376 -- in the early call region. This routine raises ECR_Found.
4378 function Is_OK_Preelaborable_Construct (N : Node_Id) return Boolean;
4379 pragma Inline (Is_OK_Preelaborable_Construct);
4380 -- Determine whether arbitrary node N denotes a preelaboration-safe
4381 -- construct.
4383 function Is_Suitable_Construct (N : Node_Id) return Boolean;
4384 pragma Inline (Is_Suitable_Construct);
4385 -- Determine whether arbitrary node N denotes a suitable construct for
4386 -- inclusion into the early call region.
4388 procedure Transition_Body_Declarations
4389 (Bod : Node_Id;
4390 Curr : in out Node_Id);
4391 pragma Inline (Transition_Body_Declarations);
4392 -- Update the Curr and Start pointers when construct Bod denotes a block
4393 -- statement or a suitable body. This routine raises ECR_Found.
4395 procedure Transition_Handled_Statements
4396 (HSS : Node_Id;
4397 Curr : in out Node_Id);
4398 pragma Inline (Transition_Handled_Statements);
4399 -- Update the Curr and Start pointers when node HSS denotes a handled
4400 -- sequence of statements. This routine raises ECR_Found.
4402 procedure Transition_Spec_Declarations
4403 (Spec : Node_Id;
4404 Curr : in out Node_Id);
4405 pragma Inline (Transition_Spec_Declarations);
4406 -- Update the Curr and Start pointers when construct Spec denotes
4407 -- a concurrent definition or a package spec. This routine raises
4408 -- ECR_Found.
4410 procedure Transition_Unit (Unit : Node_Id; Curr : in out Node_Id);
4411 pragma Inline (Transition_Unit);
4412 -- Update the Curr and Start pointers when node Unit denotes a potential
4413 -- compilation unit. This routine raises ECR_Found.
4415 -------------
4416 -- Advance --
4417 -------------
4419 procedure Advance (Curr : in out Node_Id) is
4420 Context : Node_Id;
4422 begin
4423 -- Curr denotes one of the following cases upon entry into this
4424 -- routine:
4426 -- * Empty - There is no current construct when a declarative or a
4427 -- statement list has been exhausted. This does not necessarily
4428 -- indicate that the early call region has been computed as it
4429 -- may still be possible to transition to another list.
4431 -- * Encapsulator - The current construct encapsulates declarations
4432 -- and/or statements. This indicates that the early call region
4433 -- may extend within the nested construct.
4435 -- * Preelaborable - The current construct is always preelaborable
4436 -- because Find_ECR would not invoke Advance if this was not the
4437 -- case.
4439 -- The current construct is an encapsulator or is preelaborable
4441 if Present (Curr) then
4443 -- Enter encapsulators by inspecting their declarations and/or
4444 -- statements.
4446 if Nkind_In (Curr, N_Block_Statement, N_Package_Body) then
4447 Enter_Handled_Body (Curr);
4449 elsif Nkind (Curr) = N_Package_Declaration then
4450 Enter_Package_Declaration (Curr);
4452 -- Early call regions have a property which can be exploited to
4453 -- optimize the algorithm.
4455 -- <preceding subprogram body>
4456 -- <preelaborable construct 1>
4457 -- ...
4458 -- <preelaborable construct N>
4459 -- <initiating subprogram body>
4461 -- If a traversal initiated from a subprogram body reaches a
4462 -- preceding subprogram body, then both bodies share the same
4463 -- early call region.
4465 -- The property results in the following desirable effects:
4467 -- * If the preceding body already has an early call region, then
4468 -- the initiating body can reuse it. This minimizes the amount
4469 -- of processing performed by the algorithm.
4471 -- * If the preceding body lack an early call region, then the
4472 -- algorithm can compute the early call region, and reuse it
4473 -- for the initiating body. This processing performs the same
4474 -- amount of work, but has the beneficial effect of computing
4475 -- the early call regions of all preceding bodies.
4477 elsif Nkind_In (Curr, N_Entry_Body, N_Subprogram_Body) then
4478 Start :=
4479 Find_Early_Call_Region
4480 (Body_Decl => Curr,
4481 Assume_Elab_Body => Assume_Elab_Body,
4482 Skip_Memoization => Skip_Memoization);
4484 raise ECR_Found;
4486 -- Otherwise current construct is preelaborable. Unpdate the early
4487 -- call region to include it.
4489 else
4490 Include (Curr, Curr);
4491 end if;
4493 -- Otherwise the current construct is missing, indicating that the
4494 -- current list has been exhausted. Depending on the context of the
4495 -- list, several transitions are possible.
4497 else
4498 -- The invariant of the algorithm ensures that Curr and Start are
4499 -- at the same level of nesting at the point of a transition. The
4500 -- algorithm can determine which list the traversal came from by
4501 -- examining Start.
4503 Context := Parent (Start);
4505 -- Attempt the following transitions:
4507 -- private declarations -> visible declarations
4508 -- private declarations -> upper level
4509 -- private declarations -> terminate
4510 -- visible declarations -> upper level
4511 -- visible declarations -> terminate
4513 if Nkind_In (Context, N_Package_Specification,
4514 N_Protected_Definition,
4515 N_Task_Definition)
4516 then
4517 Transition_Spec_Declarations (Context, Curr);
4519 -- Attempt the following transitions:
4521 -- statements -> declarations
4522 -- statements -> upper level
4523 -- statements -> corresponding package spec (Elab_Body)
4524 -- statements -> terminate
4526 elsif Nkind (Context) = N_Handled_Sequence_Of_Statements then
4527 Transition_Handled_Statements (Context, Curr);
4529 -- Attempt the following transitions:
4531 -- declarations -> upper level
4532 -- declarations -> corresponding package spec (Elab_Body)
4533 -- declarations -> terminate
4535 elsif Nkind_In (Context, N_Block_Statement,
4536 N_Entry_Body,
4537 N_Package_Body,
4538 N_Protected_Body,
4539 N_Subprogram_Body,
4540 N_Task_Body)
4541 then
4542 Transition_Body_Declarations (Context, Curr);
4544 -- Otherwise it is not possible to transition. Stop the search
4545 -- because there are no more declarations or statements to check.
4547 else
4548 raise ECR_Found;
4549 end if;
4550 end if;
4551 end Advance;
4553 --------------------------
4554 -- Enter_Handled_Body --
4555 --------------------------
4557 procedure Enter_Handled_Body (Curr : in out Node_Id) is
4558 Decls : constant List_Id := Declarations (Curr);
4559 HSS : constant Node_Id := Handled_Statement_Sequence (Curr);
4560 Stmts : List_Id := No_List;
4562 begin
4563 if Present (HSS) then
4564 Stmts := Statements (HSS);
4565 end if;
4567 -- The handled body has a non-empty statement sequence. The construct
4568 -- to inspect is the last statement.
4570 if Has_Suitable_Construct (Stmts) then
4571 Curr := Last (Stmts);
4573 -- The handled body lacks statements, but has non-empty declarations.
4574 -- The construct to inspect is the last declaration.
4576 elsif Has_Suitable_Construct (Decls) then
4577 Curr := Last (Decls);
4579 -- Otherwise the handled body lacks both declarations and statements.
4580 -- The construct to inspect is the node which precedes the handled
4581 -- body. Update the early call region to include the handled body.
4583 else
4584 Include (Curr, Curr);
4585 end if;
4586 end Enter_Handled_Body;
4588 -------------------------------
4589 -- Enter_Package_Declaration --
4590 -------------------------------
4592 procedure Enter_Package_Declaration (Curr : in out Node_Id) is
4593 Pack_Spec : constant Node_Id := Specification (Curr);
4594 Prv_Decls : constant List_Id := Private_Declarations (Pack_Spec);
4595 Vis_Decls : constant List_Id := Visible_Declarations (Pack_Spec);
4597 begin
4598 -- The package has a non-empty private declarations. The construct to
4599 -- inspect is the last private declaration.
4601 if Has_Suitable_Construct (Prv_Decls) then
4602 Curr := Last (Prv_Decls);
4604 -- The package lacks private declarations, but has non-empty visible
4605 -- declarations. In this case the construct to inspect is the last
4606 -- visible declaration.
4608 elsif Has_Suitable_Construct (Vis_Decls) then
4609 Curr := Last (Vis_Decls);
4611 -- Otherwise the package lacks any declarations. The construct to
4612 -- inspect is the node which precedes the package. Update the early
4613 -- call region to include the package declaration.
4615 else
4616 Include (Curr, Curr);
4617 end if;
4618 end Enter_Package_Declaration;
4620 --------------
4621 -- Find_ECR --
4622 --------------
4624 function Find_ECR (N : Node_Id) return Node_Id is
4625 Curr : Node_Id;
4627 begin
4628 -- The early call region starts at N
4630 Curr := Prev (N);
4631 Start := N;
4633 -- Inspect each node in reverse declarative order while going in and
4634 -- out of nested and enclosing constructs. Note that the only way to
4635 -- terminate this infinite loop is to raise exception ECR_Found.
4637 loop
4638 -- The current construct is not preelaboration-safe. Terminate the
4639 -- traversal.
4641 if Present (Curr)
4642 and then not Is_OK_Preelaborable_Construct (Curr)
4643 then
4644 raise ECR_Found;
4645 end if;
4647 -- Advance to the next suitable construct. This may terminate the
4648 -- traversal by raising ECR_Found.
4650 Advance (Curr);
4651 end loop;
4653 exception
4654 when ECR_Found =>
4655 return Start;
4656 end Find_ECR;
4658 ----------------------------
4659 -- Has_Suitable_Construct --
4660 ----------------------------
4662 function Has_Suitable_Construct (List : List_Id) return Boolean is
4663 Item : Node_Id;
4665 begin
4666 -- Examine the list in reverse declarative order, looking for a
4667 -- suitable construct.
4669 if Present (List) then
4670 Item := Last (List);
4671 while Present (Item) loop
4672 if Is_Suitable_Construct (Item) then
4673 return True;
4674 end if;
4676 Prev (Item);
4677 end loop;
4678 end if;
4680 return False;
4681 end Has_Suitable_Construct;
4683 -------------
4684 -- Include --
4685 -------------
4687 procedure Include (N : Node_Id; Curr : out Node_Id) is
4688 begin
4689 Start := N;
4691 -- The input node is a compilation unit. This terminates the search
4692 -- because there are no more lists to inspect and there are no more
4693 -- enclosing constructs to climb up to. The transitions are:
4695 -- private declarations -> terminate
4696 -- visible declarations -> terminate
4697 -- statements -> terminate
4698 -- declarations -> terminate
4700 if Nkind (Parent (Start)) = N_Compilation_Unit then
4701 raise ECR_Found;
4703 -- Otherwise the input node is still within some list
4705 else
4706 Curr := Prev (Start);
4707 end if;
4708 end Include;
4710 -----------------------------------
4711 -- Is_OK_Preelaborable_Construct --
4712 -----------------------------------
4714 function Is_OK_Preelaborable_Construct (N : Node_Id) return Boolean is
4715 begin
4716 -- Assignment statements are acceptable as long as they were produced
4717 -- by the ABE mechanism to update elaboration flags.
4719 if Nkind (N) = N_Assignment_Statement then
4720 return Is_Elaboration_Code (N);
4722 -- Block statements are acceptable even though they directly violate
4723 -- preelaborability. The intention is not to penalize the early call
4724 -- region when a block contains only preelaborable constructs.
4726 -- declare
4727 -- Val : constant Integer := 1;
4728 -- begin
4729 -- pragma Assert (Val = 1);
4730 -- null;
4731 -- end;
4733 -- Note that the Advancement phase does enter blocks, and will detect
4734 -- any non-preelaborable declarations or statements within.
4736 elsif Nkind (N) = N_Block_Statement then
4737 return True;
4738 end if;
4740 -- Otherwise the construct must be preelaborable. The check must take
4741 -- the syntactic and semantic structure of the construct. DO NOT use
4742 -- Is_Preelaborable_Construct here.
4744 return not Is_Non_Preelaborable_Construct (N);
4745 end Is_OK_Preelaborable_Construct;
4747 ---------------------------
4748 -- Is_Suitable_Construct --
4749 ---------------------------
4751 function Is_Suitable_Construct (N : Node_Id) return Boolean is
4752 Context : constant Node_Id := Parent (N);
4754 begin
4755 -- An internally-generated statement sequence which contains only a
4756 -- single null statement is not a suitable construct because it is a
4757 -- byproduct of the parser. Such a null statement should be excluded
4758 -- from the early call region because it carries the source location
4759 -- of the "end" keyword, and may lead to confusing diagnistics.
4761 if Nkind (N) = N_Null_Statement
4762 and then not Comes_From_Source (N)
4763 and then Present (Context)
4764 and then Nkind (Context) = N_Handled_Sequence_Of_Statements
4765 and then not Comes_From_Source (N)
4766 then
4767 return False;
4768 end if;
4770 -- Otherwise only constructs which correspond to pure Ada constructs
4771 -- are considered suitable.
4773 case Nkind (N) is
4774 when N_Call_Marker
4775 | N_Freeze_Entity
4776 | N_Freeze_Generic_Entity
4777 | N_Implicit_Label_Declaration
4778 | N_Itype_Reference
4779 | N_Pop_Constraint_Error_Label
4780 | N_Pop_Program_Error_Label
4781 | N_Pop_Storage_Error_Label
4782 | N_Push_Constraint_Error_Label
4783 | N_Push_Program_Error_Label
4784 | N_Push_Storage_Error_Label
4785 | N_SCIL_Dispatch_Table_Tag_Init
4786 | N_SCIL_Dispatching_Call
4787 | N_SCIL_Membership_Test
4788 | N_Variable_Reference_Marker
4790 return False;
4792 when others =>
4793 return True;
4794 end case;
4795 end Is_Suitable_Construct;
4797 ----------------------------------
4798 -- Transition_Body_Declarations --
4799 ----------------------------------
4801 procedure Transition_Body_Declarations
4802 (Bod : Node_Id;
4803 Curr : in out Node_Id)
4805 Decls : constant List_Id := Declarations (Bod);
4807 begin
4808 -- The search must come from the declarations of the body
4810 pragma Assert
4811 (Is_Non_Empty_List (Decls)
4812 and then List_Containing (Start) = Decls);
4814 -- The search finished inspecting the declarations. The construct
4815 -- to inspect is the node which precedes the handled body, unless
4816 -- the body is a compilation unit. The transitions are:
4818 -- declarations -> upper level
4819 -- declarations -> corresponding package spec (Elab_Body)
4820 -- declarations -> terminate
4822 Transition_Unit (Bod, Curr);
4823 end Transition_Body_Declarations;
4825 -----------------------------------
4826 -- Transition_Handled_Statements --
4827 -----------------------------------
4829 procedure Transition_Handled_Statements
4830 (HSS : Node_Id;
4831 Curr : in out Node_Id)
4833 Bod : constant Node_Id := Parent (HSS);
4834 Decls : constant List_Id := Declarations (Bod);
4835 Stmts : constant List_Id := Statements (HSS);
4837 begin
4838 -- The search must come from the statements of certain bodies or
4839 -- statements.
4841 pragma Assert (Nkind_In (Bod, N_Block_Statement,
4842 N_Entry_Body,
4843 N_Package_Body,
4844 N_Protected_Body,
4845 N_Subprogram_Body,
4846 N_Task_Body));
4848 -- The search must come from the statements of the handled sequence
4850 pragma Assert
4851 (Is_Non_Empty_List (Stmts)
4852 and then List_Containing (Start) = Stmts);
4854 -- The search finished inspecting the statements. The handled body
4855 -- has non-empty declarations. The construct to inspect is the last
4856 -- declaration. The transitions are:
4858 -- statements -> declarations
4860 if Has_Suitable_Construct (Decls) then
4861 Curr := Last (Decls);
4863 -- Otherwise the handled body lacks declarations. The construct to
4864 -- inspect is the node which precedes the handled body, unless the
4865 -- body is a compilation unit. The transitions are:
4867 -- statements -> upper level
4868 -- statements -> corresponding package spec (Elab_Body)
4869 -- statements -> terminate
4871 else
4872 Transition_Unit (Bod, Curr);
4873 end if;
4874 end Transition_Handled_Statements;
4876 ----------------------------------
4877 -- Transition_Spec_Declarations --
4878 ----------------------------------
4880 procedure Transition_Spec_Declarations
4881 (Spec : Node_Id;
4882 Curr : in out Node_Id)
4884 Prv_Decls : constant List_Id := Private_Declarations (Spec);
4885 Vis_Decls : constant List_Id := Visible_Declarations (Spec);
4887 begin
4888 pragma Assert (Present (Start) and then Is_List_Member (Start));
4890 -- The search came from the private declarations and finished their
4891 -- inspection.
4893 if Has_Suitable_Construct (Prv_Decls)
4894 and then List_Containing (Start) = Prv_Decls
4895 then
4896 -- The context has non-empty visible declarations. The node to
4897 -- inspect is the last visible declaration. The transitions are:
4899 -- private declarations -> visible declarations
4901 if Has_Suitable_Construct (Vis_Decls) then
4902 Curr := Last (Vis_Decls);
4904 -- Otherwise the context lacks visible declarations. The construct
4905 -- to inspect is the node which precedes the context unless the
4906 -- context is a compilation unit. The transitions are:
4908 -- private declarations -> upper level
4909 -- private declarations -> terminate
4911 else
4912 Transition_Unit (Parent (Spec), Curr);
4913 end if;
4915 -- The search came from the visible declarations and finished their
4916 -- inspections. The construct to inspect is the node which precedes
4917 -- the context, unless the context is a compilaton unit. The
4918 -- transitions are:
4920 -- visible declarations -> upper level
4921 -- visible declarations -> terminate
4923 elsif Has_Suitable_Construct (Vis_Decls)
4924 and then List_Containing (Start) = Vis_Decls
4925 then
4926 Transition_Unit (Parent (Spec), Curr);
4928 -- At this point both declarative lists are empty, but the traversal
4929 -- still came from within the spec. This indicates that the invariant
4930 -- of the algorithm has been violated.
4932 else
4933 pragma Assert (False);
4934 raise ECR_Found;
4935 end if;
4936 end Transition_Spec_Declarations;
4938 ---------------------
4939 -- Transition_Unit --
4940 ---------------------
4942 procedure Transition_Unit
4943 (Unit : Node_Id;
4944 Curr : in out Node_Id)
4946 Context : constant Node_Id := Parent (Unit);
4948 begin
4949 -- The unit is a compilation unit. This terminates the search because
4950 -- there are no more lists to inspect and there are no more enclosing
4951 -- constructs to climb up to.
4953 if Nkind (Context) = N_Compilation_Unit then
4955 -- A package body with a corresponding spec subject to pragma
4956 -- Elaborate_Body is an exception to the above. The annotation
4957 -- allows the search to continue into the package declaration.
4958 -- The transitions are:
4960 -- statements -> corresponding package spec (Elab_Body)
4961 -- declarations -> corresponding package spec (Elab_Body)
4963 if Nkind (Unit) = N_Package_Body
4964 and then (Assume_Elab_Body
4965 or else Has_Pragma_Elaborate_Body
4966 (Corresponding_Spec (Unit)))
4967 then
4968 Curr := Unit_Declaration_Node (Corresponding_Spec (Unit));
4969 Enter_Package_Declaration (Curr);
4971 -- Otherwise terminate the search. The transitions are:
4973 -- private declarations -> terminate
4974 -- visible declarations -> terminate
4975 -- statements -> terminate
4976 -- declarations -> terminate
4978 else
4979 raise ECR_Found;
4980 end if;
4982 -- The unit is a subunit. The construct to inspect is the node which
4983 -- precedes the corresponding stub. Update the early call region to
4984 -- include the unit.
4986 elsif Nkind (Context) = N_Subunit then
4987 Start := Unit;
4988 Curr := Corresponding_Stub (Context);
4990 -- Otherwise the unit is nested. The construct to inspect is the node
4991 -- which precedes the unit. Update the early call region to include
4992 -- the unit.
4994 else
4995 Include (Unit, Curr);
4996 end if;
4997 end Transition_Unit;
4999 -- Local variables
5001 Body_Id : constant Entity_Id := Defining_Entity (Body_Decl);
5002 Region : Node_Id;
5004 -- Start of processing for Find_Early_Call_Region
5006 begin
5007 -- The caller demands the start of the early call region without saving
5008 -- or retrieving it to/from internal data structures.
5010 if Skip_Memoization then
5011 Region := Find_ECR (Body_Decl);
5013 -- Default behavior
5015 else
5016 -- Check whether the early call region of the subprogram body is
5017 -- available.
5019 Region := Early_Call_Region (Body_Id);
5021 if No (Region) then
5023 -- Traverse the declarations in reverse order, starting from the
5024 -- subprogram body, searching for the nearest non-preelaborable
5025 -- construct. The early call region starts after this construct
5026 -- and ends at the subprogram body.
5028 Region := Find_ECR (Body_Decl);
5030 -- Associate the early call region with the subprogram body in
5031 -- case other scenarios need it.
5033 Set_Early_Call_Region (Body_Id, Region);
5034 end if;
5035 end if;
5037 -- A subprogram body must always have an early call region
5039 pragma Assert (Present (Region));
5041 return Region;
5042 end Find_Early_Call_Region;
5044 ---------------------------
5045 -- Find_Elaborated_Units --
5046 ---------------------------
5048 procedure Find_Elaborated_Units is
5049 procedure Add_Pragma (Prag : Node_Id);
5050 -- Determine whether pragma Prag denotes a legal Elaborate[_All] pragma.
5051 -- If this is the case, add the related unit to the elaboration context.
5052 -- For pragma Elaborate_All, include recursively all units withed by the
5053 -- related unit.
5055 procedure Add_Unit
5056 (Unit_Id : Entity_Id;
5057 Prag : Node_Id;
5058 Full_Context : Boolean);
5059 -- Add unit Unit_Id to the elaboration context. Prag denotes the pragma
5060 -- which prompted the inclusion of the unit to the elaboration context.
5061 -- If flag Full_Context is set, examine the nonlimited clauses of unit
5062 -- Unit_Id and add each withed unit to the context.
5064 procedure Find_Elaboration_Context (Comp_Unit : Node_Id);
5065 -- Examine the context items of compilation unit Comp_Unit for suitable
5066 -- elaboration-related pragmas and add all related units to the context.
5068 ----------------
5069 -- Add_Pragma --
5070 ----------------
5072 procedure Add_Pragma (Prag : Node_Id) is
5073 Prag_Args : constant List_Id := Pragma_Argument_Associations (Prag);
5074 Prag_Nam : constant Name_Id := Pragma_Name (Prag);
5075 Unit_Arg : Node_Id;
5077 begin
5078 -- Nothing to do if the pragma is not related to elaboration
5080 if not Nam_In (Prag_Nam, Name_Elaborate, Name_Elaborate_All) then
5081 return;
5083 -- Nothing to do when the pragma is illegal
5085 elsif Error_Posted (Prag) then
5086 return;
5087 end if;
5089 Unit_Arg := Get_Pragma_Arg (First (Prag_Args));
5091 -- The argument of the pragma may appear in package.package form
5093 if Nkind (Unit_Arg) = N_Selected_Component then
5094 Unit_Arg := Selector_Name (Unit_Arg);
5095 end if;
5097 Add_Unit
5098 (Unit_Id => Entity (Unit_Arg),
5099 Prag => Prag,
5100 Full_Context => Prag_Nam = Name_Elaborate_All);
5101 end Add_Pragma;
5103 --------------
5104 -- Add_Unit --
5105 --------------
5107 procedure Add_Unit
5108 (Unit_Id : Entity_Id;
5109 Prag : Node_Id;
5110 Full_Context : Boolean)
5112 Clause : Node_Id;
5113 Elab_Attrs : Elaboration_Attributes;
5115 begin
5116 -- Nothing to do when some previous error left a with clause or a
5117 -- pragma in a bad state.
5119 if No (Unit_Id) then
5120 return;
5121 end if;
5123 Elab_Attrs := Elaboration_Status (Unit_Id);
5125 -- The unit is already included in the context by means of pragma
5126 -- Elaborate[_All].
5128 if Present (Elab_Attrs.Source_Pragma) then
5130 -- Upgrade an existing pragma Elaborate when the unit is subject
5131 -- to Elaborate_All because the new pragma covers a larger set of
5132 -- units.
5134 if Pragma_Name (Elab_Attrs.Source_Pragma) = Name_Elaborate
5135 and then Pragma_Name (Prag) = Name_Elaborate_All
5136 then
5137 Elab_Attrs.Source_Pragma := Prag;
5139 -- Otherwise the unit retains its existing pragma and does not
5140 -- need to be included in the context again.
5142 else
5143 return;
5144 end if;
5146 -- The current unit is not part of the context. Prepare a new set of
5147 -- attributes.
5149 else
5150 Elab_Attrs :=
5151 Elaboration_Attributes'(Source_Pragma => Prag,
5152 With_Clause => Empty);
5153 end if;
5155 -- Add or update the attributes of the unit
5157 Set_Elaboration_Status (Unit_Id, Elab_Attrs);
5159 -- Includes all units withed by the current one when computing the
5160 -- full context.
5162 if Full_Context then
5164 -- Process all nonlimited with clauses found in the context of
5165 -- the current unit. Note that limited clauses do not impose an
5166 -- elaboration order.
5168 Clause := First (Context_Items (Compilation_Unit (Unit_Id)));
5169 while Present (Clause) loop
5170 if Nkind (Clause) = N_With_Clause
5171 and then not Error_Posted (Clause)
5172 and then not Limited_Present (Clause)
5173 then
5174 Add_Unit
5175 (Unit_Id => Entity (Name (Clause)),
5176 Prag => Prag,
5177 Full_Context => Full_Context);
5178 end if;
5180 Next (Clause);
5181 end loop;
5182 end if;
5183 end Add_Unit;
5185 ------------------------------
5186 -- Find_Elaboration_Context --
5187 ------------------------------
5189 procedure Find_Elaboration_Context (Comp_Unit : Node_Id) is
5190 Prag : Node_Id;
5192 begin
5193 pragma Assert (Nkind (Comp_Unit) = N_Compilation_Unit);
5195 -- Process all elaboration-related pragmas found in the context of
5196 -- the compilation unit.
5198 Prag := First (Context_Items (Comp_Unit));
5199 while Present (Prag) loop
5200 if Nkind (Prag) = N_Pragma then
5201 Add_Pragma (Prag);
5202 end if;
5204 Next (Prag);
5205 end loop;
5206 end Find_Elaboration_Context;
5208 -- Local variables
5210 Par_Id : Entity_Id;
5211 Unt : Node_Id;
5213 -- Start of processing for Find_Elaborated_Units
5215 begin
5216 -- Perform a traversal which examines the context of the main unit and
5217 -- populates the Elaboration_Context table with all units elaborated
5218 -- prior to the main unit. The traversal performs the following jumps:
5220 -- subunit -> parent subunit
5221 -- parent subunit -> body
5222 -- body -> spec
5223 -- spec -> parent spec
5224 -- parent spec -> grandparent spec and so on
5226 -- The traversal relies on units rather than scopes because the scope of
5227 -- a subunit is some spec, while this traversal must process the body as
5228 -- well. Given that protected and task bodies can also be subunits, this
5229 -- complicates the scope approach even further.
5231 Unt := Unit (Cunit (Main_Unit));
5233 -- Perform the following traversals when the main unit is a subunit
5235 -- subunit -> parent subunit
5236 -- parent subunit -> body
5238 while Present (Unt) and then Nkind (Unt) = N_Subunit loop
5239 Find_Elaboration_Context (Parent (Unt));
5241 -- Continue the traversal by going to the unit which contains the
5242 -- corresponding stub.
5244 if Present (Corresponding_Stub (Unt)) then
5245 Unt := Unit (Cunit (Get_Source_Unit (Corresponding_Stub (Unt))));
5247 -- Otherwise the subunit may be erroneous or left in a bad state
5249 else
5250 exit;
5251 end if;
5252 end loop;
5254 -- Perform the following traversal now that subunits have been taken
5255 -- care of, or the main unit is a body.
5257 -- body -> spec
5259 if Present (Unt)
5260 and then Nkind_In (Unt, N_Package_Body, N_Subprogram_Body)
5261 then
5262 Find_Elaboration_Context (Parent (Unt));
5264 -- Continue the traversal by going to the unit which contains the
5265 -- corresponding spec.
5267 if Present (Corresponding_Spec (Unt)) then
5268 Unt := Unit (Cunit (Get_Source_Unit (Corresponding_Spec (Unt))));
5269 end if;
5270 end if;
5272 -- Perform the following traversals now that the body has been taken
5273 -- care of, or the main unit is a spec.
5275 -- spec -> parent spec
5276 -- parent spec -> grandparent spec and so on
5278 if Present (Unt)
5279 and then Nkind_In (Unt, N_Generic_Package_Declaration,
5280 N_Generic_Subprogram_Declaration,
5281 N_Package_Declaration,
5282 N_Subprogram_Declaration)
5283 then
5284 Find_Elaboration_Context (Parent (Unt));
5286 -- Process a potential chain of parent units which ends with the
5287 -- main unit spec. The traversal can now safely rely on the scope
5288 -- chain.
5290 Par_Id := Scope (Defining_Entity (Unt));
5291 while Present (Par_Id) and then Par_Id /= Standard_Standard loop
5292 Find_Elaboration_Context (Compilation_Unit (Par_Id));
5294 Par_Id := Scope (Par_Id);
5295 end loop;
5296 end if;
5297 end Find_Elaborated_Units;
5299 -----------------------------
5300 -- Find_Enclosing_Instance --
5301 -----------------------------
5303 function Find_Enclosing_Instance (N : Node_Id) return Node_Id is
5304 Par : Node_Id;
5305 Spec_Id : Entity_Id;
5307 begin
5308 -- Climb the parent chain looking for an enclosing instance spec or body
5310 Par := N;
5311 while Present (Par) loop
5313 -- Generic package or subprogram spec
5315 if Nkind_In (Par, N_Package_Declaration,
5316 N_Subprogram_Declaration)
5317 and then Is_Generic_Instance (Defining_Entity (Par))
5318 then
5319 return Par;
5321 -- Generic package or subprogram body
5323 elsif Nkind_In (Par, N_Package_Body, N_Subprogram_Body) then
5324 Spec_Id := Corresponding_Spec (Par);
5326 if Present (Spec_Id) and then Is_Generic_Instance (Spec_Id) then
5327 return Par;
5328 end if;
5329 end if;
5331 Par := Parent (Par);
5332 end loop;
5334 return Empty;
5335 end Find_Enclosing_Instance;
5337 --------------------------
5338 -- Find_Enclosing_Level --
5339 --------------------------
5341 function Find_Enclosing_Level (N : Node_Id) return Enclosing_Level_Kind is
5342 function Level_Of (Unit : Node_Id) return Enclosing_Level_Kind;
5343 -- Obtain the corresponding level of unit Unit
5345 --------------
5346 -- Level_Of --
5347 --------------
5349 function Level_Of (Unit : Node_Id) return Enclosing_Level_Kind is
5350 Spec_Id : Entity_Id;
5352 begin
5353 if Nkind (Unit) in N_Generic_Instantiation then
5354 return Instantiation;
5356 elsif Nkind (Unit) = N_Generic_Package_Declaration then
5357 return Generic_Package_Spec;
5359 elsif Nkind (Unit) = N_Package_Declaration then
5360 return Package_Spec;
5362 elsif Nkind (Unit) = N_Package_Body then
5363 Spec_Id := Corresponding_Spec (Unit);
5365 -- The body belongs to a generic package
5367 if Present (Spec_Id)
5368 and then Ekind (Spec_Id) = E_Generic_Package
5369 then
5370 return Generic_Package_Body;
5372 -- Otherwise the body belongs to a non-generic package. This also
5373 -- treats an illegal package body without a corresponding spec as
5374 -- a non-generic package body.
5376 else
5377 return Package_Body;
5378 end if;
5379 end if;
5381 return No_Level;
5382 end Level_Of;
5384 -- Local variables
5386 Context : Node_Id;
5387 Curr : Node_Id;
5388 Prev : Node_Id;
5390 -- Start of processing for Find_Enclosing_Level
5392 begin
5393 -- Call markers and instantiations which appear at the declaration level
5394 -- but are later relocated in a different context retain their original
5395 -- declaration level.
5397 if Nkind_In (N, N_Call_Marker,
5398 N_Function_Instantiation,
5399 N_Package_Instantiation,
5400 N_Procedure_Instantiation)
5401 and then Is_Declaration_Level_Node (N)
5402 then
5403 return Declaration_Level;
5404 end if;
5406 -- Climb the parent chain looking at the enclosing levels
5408 Prev := N;
5409 Curr := Parent (Prev);
5410 while Present (Curr) loop
5412 -- A traversal from a subunit continues via the corresponding stub
5414 if Nkind (Curr) = N_Subunit then
5415 Curr := Corresponding_Stub (Curr);
5417 -- The current construct is a package. Packages are ignored because
5418 -- they are always elaborated when the enclosing context is invoked
5419 -- or elaborated.
5421 elsif Nkind_In (Curr, N_Package_Body, N_Package_Declaration) then
5422 null;
5424 -- The current construct is a block statement
5426 elsif Nkind (Curr) = N_Block_Statement then
5428 -- Ignore internally generated blocks created by the expander for
5429 -- various purposes such as abort defer/undefer.
5431 if not Comes_From_Source (Curr) then
5432 null;
5434 -- If the traversal came from the handled sequence of statments,
5435 -- then the node appears at the level of the enclosing construct.
5436 -- This is a more reliable test because transients scopes within
5437 -- the declarative region of the encapsulator are hard to detect.
5439 elsif Nkind (Prev) = N_Handled_Sequence_Of_Statements
5440 and then Handled_Statement_Sequence (Curr) = Prev
5441 then
5442 return Find_Enclosing_Level (Parent (Curr));
5444 -- Otherwise the traversal came from the declarations, the node is
5445 -- at the declaration level.
5447 else
5448 return Declaration_Level;
5449 end if;
5451 -- The current construct is a declaration-level encapsulator
5453 elsif Nkind_In (Curr, N_Entry_Body,
5454 N_Subprogram_Body,
5455 N_Task_Body)
5456 then
5457 -- If the traversal came from the handled sequence of statments,
5458 -- then the node cannot possibly appear at any level. This is
5459 -- a more reliable test because transients scopes within the
5460 -- declarative region of the encapsulator are hard to detect.
5462 if Nkind (Prev) = N_Handled_Sequence_Of_Statements
5463 and then Handled_Statement_Sequence (Curr) = Prev
5464 then
5465 return No_Level;
5467 -- Otherwise the traversal came from the declarations, the node is
5468 -- at the declaration level.
5470 else
5471 return Declaration_Level;
5472 end if;
5474 -- The current construct is a non-library-level encapsulator which
5475 -- indicates that the node cannot possibly appear at any level.
5476 -- Note that this check must come after the declaration-level check
5477 -- because both predicates share certain nodes.
5479 elsif Is_Non_Library_Level_Encapsulator (Curr) then
5480 Context := Parent (Curr);
5482 -- The sole exception is when the encapsulator is the compilation
5483 -- utit itself because the compilation unit node requires special
5484 -- processing (see below).
5486 if Present (Context)
5487 and then Nkind (Context) = N_Compilation_Unit
5488 then
5489 null;
5491 -- Otherwise the node is not at any level
5493 else
5494 return No_Level;
5495 end if;
5497 -- The current construct is a compilation unit. The node appears at
5498 -- the [generic] library level when the unit is a [generic] package.
5500 elsif Nkind (Curr) = N_Compilation_Unit then
5501 return Level_Of (Unit (Curr));
5502 end if;
5504 Prev := Curr;
5505 Curr := Parent (Prev);
5506 end loop;
5508 return No_Level;
5509 end Find_Enclosing_Level;
5511 -------------------
5512 -- Find_Top_Unit --
5513 -------------------
5515 function Find_Top_Unit (N : Node_Or_Entity_Id) return Entity_Id is
5516 begin
5517 return Find_Unit_Entity (Unit (Cunit (Get_Top_Level_Code_Unit (N))));
5518 end Find_Top_Unit;
5520 ----------------------
5521 -- Find_Unit_Entity --
5522 ----------------------
5524 function Find_Unit_Entity (N : Node_Id) return Entity_Id is
5525 Context : constant Node_Id := Parent (N);
5526 Orig_N : constant Node_Id := Original_Node (N);
5528 begin
5529 -- The unit denotes a package body of an instantiation which acts as
5530 -- a compilation unit. The proper entity is that of the package spec.
5532 if Nkind (N) = N_Package_Body
5533 and then Nkind (Orig_N) = N_Package_Instantiation
5534 and then Nkind (Context) = N_Compilation_Unit
5535 then
5536 return Corresponding_Spec (N);
5538 -- The unit denotes an anonymous package created to wrap a subprogram
5539 -- instantiation which acts as a compilation unit. The proper entity is
5540 -- that of the "related instance".
5542 elsif Nkind (N) = N_Package_Declaration
5543 and then Nkind_In (Orig_N, N_Function_Instantiation,
5544 N_Procedure_Instantiation)
5545 and then Nkind (Context) = N_Compilation_Unit
5546 then
5547 return
5548 Related_Instance (Defining_Entity (N, Concurrent_Subunit => True));
5550 -- Otherwise the proper entity is the defining entity
5552 else
5553 return Defining_Entity (N, Concurrent_Subunit => True);
5554 end if;
5555 end Find_Unit_Entity;
5557 -----------------------
5558 -- First_Formal_Type --
5559 -----------------------
5561 function First_Formal_Type (Subp_Id : Entity_Id) return Entity_Id is
5562 Formal_Id : constant Entity_Id := First_Formal (Subp_Id);
5563 Typ : Entity_Id;
5565 begin
5566 if Present (Formal_Id) then
5567 Typ := Etype (Formal_Id);
5569 -- Handle various combinations of concurrent and private types
5571 loop
5572 if Ekind_In (Typ, E_Protected_Type, E_Task_Type)
5573 and then Present (Anonymous_Object (Typ))
5574 then
5575 Typ := Anonymous_Object (Typ);
5577 elsif Is_Concurrent_Record_Type (Typ) then
5578 Typ := Corresponding_Concurrent_Type (Typ);
5580 elsif Is_Private_Type (Typ) and then Present (Full_View (Typ)) then
5581 Typ := Full_View (Typ);
5583 else
5584 exit;
5585 end if;
5586 end loop;
5588 return Typ;
5589 end if;
5591 return Empty;
5592 end First_Formal_Type;
5594 --------------
5595 -- Has_Body --
5596 --------------
5598 function Has_Body (Pack_Decl : Node_Id) return Boolean is
5599 function Find_Corresponding_Body (Spec_Id : Entity_Id) return Node_Id;
5600 -- Try to locate the corresponding body of spec Spec_Id. If no body is
5601 -- found, return Empty.
5603 function Find_Body
5604 (Spec_Id : Entity_Id;
5605 From : Node_Id) return Node_Id;
5606 -- Try to locate the corresponding body of spec Spec_Id in the node list
5607 -- which follows arbitrary node From. If no body is found, return Empty.
5609 function Load_Package_Body (Unit_Nam : Unit_Name_Type) return Node_Id;
5610 -- Attempt to load the body of unit Unit_Nam. If the load failed, return
5611 -- Empty. If the compilation will not generate code, return Empty.
5613 -----------------------------
5614 -- Find_Corresponding_Body --
5615 -----------------------------
5617 function Find_Corresponding_Body (Spec_Id : Entity_Id) return Node_Id is
5618 Context : constant Entity_Id := Scope (Spec_Id);
5619 Spec_Decl : constant Node_Id := Unit_Declaration_Node (Spec_Id);
5620 Body_Decl : Node_Id;
5621 Body_Id : Entity_Id;
5623 begin
5624 if Is_Compilation_Unit (Spec_Id) then
5625 Body_Id := Corresponding_Body (Spec_Decl);
5627 if Present (Body_Id) then
5628 return Unit_Declaration_Node (Body_Id);
5630 -- The package is at the library and requires a body. Load the
5631 -- corresponding body because the optional body may be declared
5632 -- there.
5634 elsif Unit_Requires_Body (Spec_Id) then
5635 return
5636 Load_Package_Body
5637 (Get_Body_Name (Unit_Name (Get_Source_Unit (Spec_Decl))));
5639 -- Otherwise there is no optional body
5641 else
5642 return Empty;
5643 end if;
5645 -- The immediate context is a package. The optional body may be
5646 -- within the body of that package.
5648 -- procedure Proc is
5649 -- package Nested_1 is
5650 -- package Nested_2 is
5651 -- generic
5652 -- package Pack is
5653 -- end Pack;
5654 -- end Nested_2;
5655 -- end Nested_1;
5657 -- package body Nested_1 is
5658 -- package body Nested_2 is separate;
5659 -- end Nested_1;
5661 -- separate (Proc.Nested_1.Nested_2)
5662 -- package body Nested_2 is
5663 -- package body Pack is -- optional body
5664 -- ...
5665 -- end Pack;
5666 -- end Nested_2;
5668 elsif Is_Package_Or_Generic_Package (Context) then
5669 Body_Decl := Find_Corresponding_Body (Context);
5671 -- The optional body is within the body of the enclosing package
5673 if Present (Body_Decl) then
5674 return
5675 Find_Body
5676 (Spec_Id => Spec_Id,
5677 From => First (Declarations (Body_Decl)));
5679 -- Otherwise the enclosing package does not have a body. This may
5680 -- be the result of an error or a genuine lack of a body.
5682 else
5683 return Empty;
5684 end if;
5686 -- Otherwise the immediate context is a body. The optional body may
5687 -- be within the same list as the spec.
5689 -- procedure Proc is
5690 -- generic
5691 -- package Pack is
5692 -- end Pack;
5694 -- package body Pack is -- optional body
5695 -- ...
5696 -- end Pack;
5698 else
5699 return
5700 Find_Body
5701 (Spec_Id => Spec_Id,
5702 From => Next (Spec_Decl));
5703 end if;
5704 end Find_Corresponding_Body;
5706 ---------------
5707 -- Find_Body --
5708 ---------------
5710 function Find_Body
5711 (Spec_Id : Entity_Id;
5712 From : Node_Id) return Node_Id
5714 Spec_Nam : constant Name_Id := Chars (Spec_Id);
5715 Item : Node_Id;
5716 Lib_Unit : Node_Id;
5718 begin
5719 Item := From;
5720 while Present (Item) loop
5722 -- The current item denotes the optional body
5724 if Nkind (Item) = N_Package_Body
5725 and then Chars (Defining_Entity (Item)) = Spec_Nam
5726 then
5727 return Item;
5729 -- The current item denotes a stub, the optional body may be in
5730 -- the subunit.
5732 elsif Nkind (Item) = N_Package_Body_Stub
5733 and then Chars (Defining_Entity (Item)) = Spec_Nam
5734 then
5735 Lib_Unit := Library_Unit (Item);
5737 -- The corresponding subunit was previously loaded
5739 if Present (Lib_Unit) then
5740 return Lib_Unit;
5742 -- Otherwise attempt to load the corresponding subunit
5744 else
5745 return Load_Package_Body (Get_Unit_Name (Item));
5746 end if;
5747 end if;
5749 Next (Item);
5750 end loop;
5752 return Empty;
5753 end Find_Body;
5755 -----------------------
5756 -- Load_Package_Body --
5757 -----------------------
5759 function Load_Package_Body (Unit_Nam : Unit_Name_Type) return Node_Id is
5760 Body_Decl : Node_Id;
5761 Unit_Num : Unit_Number_Type;
5763 begin
5764 -- The load is performed only when the compilation will generate code
5766 if Operating_Mode = Generate_Code then
5767 Unit_Num :=
5768 Load_Unit
5769 (Load_Name => Unit_Nam,
5770 Required => False,
5771 Subunit => False,
5772 Error_Node => Pack_Decl);
5774 -- The load failed most likely because the physical file is
5775 -- missing.
5777 if Unit_Num = No_Unit then
5778 return Empty;
5780 -- Otherwise the load was successful, return the body of the unit
5782 else
5783 Body_Decl := Unit (Cunit (Unit_Num));
5785 -- If the unit is a subunit with an available proper body,
5786 -- return the proper body.
5788 if Nkind (Body_Decl) = N_Subunit
5789 and then Present (Proper_Body (Body_Decl))
5790 then
5791 Body_Decl := Proper_Body (Body_Decl);
5792 end if;
5794 return Body_Decl;
5795 end if;
5796 end if;
5798 return Empty;
5799 end Load_Package_Body;
5801 -- Local variables
5803 Pack_Id : constant Entity_Id := Defining_Entity (Pack_Decl);
5805 -- Start of processing for Has_Body
5807 begin
5808 -- The body is available
5810 if Present (Corresponding_Body (Pack_Decl)) then
5811 return True;
5813 -- The body is required if the package spec contains a construct which
5814 -- requires a completion in a body.
5816 elsif Unit_Requires_Body (Pack_Id) then
5817 return True;
5819 -- The body may be optional
5821 else
5822 return Present (Find_Corresponding_Body (Pack_Id));
5823 end if;
5824 end Has_Body;
5826 ---------------------------
5827 -- Has_Prior_Elaboration --
5828 ---------------------------
5830 function Has_Prior_Elaboration
5831 (Unit_Id : Entity_Id;
5832 Context_OK : Boolean := False;
5833 Elab_Body_OK : Boolean := False;
5834 Same_Unit_OK : Boolean := False) return Boolean
5836 Main_Id : constant Entity_Id := Cunit_Entity (Main_Unit);
5838 begin
5839 -- A preelaborated unit is always elaborated prior to the main unit
5841 if Is_Preelaborated_Unit (Unit_Id) then
5842 return True;
5844 -- An internal unit is always elaborated prior to a non-internal main
5845 -- unit.
5847 elsif In_Internal_Unit (Unit_Id)
5848 and then not In_Internal_Unit (Main_Id)
5849 then
5850 return True;
5852 -- A unit has prior elaboration if it appears within the context of the
5853 -- main unit. Consider this case only when requested by the caller.
5855 elsif Context_OK
5856 and then Elaboration_Status (Unit_Id) /= No_Elaboration_Attributes
5857 then
5858 return True;
5860 -- A unit whose body is elaborated together with its spec has prior
5861 -- elaboration except with respect to itself. Consider this case only
5862 -- when requested by the caller.
5864 elsif Elab_Body_OK
5865 and then Has_Pragma_Elaborate_Body (Unit_Id)
5866 and then not Is_Same_Unit (Unit_Id, Main_Id)
5867 then
5868 return True;
5870 -- A unit has no prior elaboration with respect to itself, but does not
5871 -- require any means of ensuring its own elaboration either. Treat this
5872 -- case as valid prior elaboration only when requested by the caller.
5874 elsif Same_Unit_OK and then Is_Same_Unit (Unit_Id, Main_Id) then
5875 return True;
5876 end if;
5878 return False;
5879 end Has_Prior_Elaboration;
5881 --------------------------
5882 -- In_External_Instance --
5883 --------------------------
5885 function In_External_Instance
5886 (N : Node_Id;
5887 Target_Decl : Node_Id) return Boolean
5889 Dummy : Node_Id;
5890 Inst_Body : Node_Id;
5891 Inst_Decl : Node_Id;
5893 begin
5894 -- Performance note: parent traversal
5896 Inst_Decl := Find_Enclosing_Instance (Target_Decl);
5898 -- The target declaration appears within an instance spec. Visibility is
5899 -- ignored because internally generated primitives for private types may
5900 -- reside in the private declarations and still be invoked from outside.
5902 if Present (Inst_Decl)
5903 and then Nkind (Inst_Decl) = N_Package_Declaration
5904 then
5905 -- The scenario comes from the main unit and the instance does not
5907 if In_Extended_Main_Code_Unit (N)
5908 and then not In_Extended_Main_Code_Unit (Inst_Decl)
5909 then
5910 return True;
5912 -- Otherwise the scenario must not appear within the instance spec or
5913 -- body.
5915 else
5916 Extract_Instance_Attributes
5917 (Exp_Inst => Inst_Decl,
5918 Inst_Body => Inst_Body,
5919 Inst_Decl => Dummy);
5921 -- Performance note: parent traversal
5923 return not In_Subtree
5924 (N => N,
5925 Root1 => Inst_Decl,
5926 Root2 => Inst_Body);
5927 end if;
5928 end if;
5930 return False;
5931 end In_External_Instance;
5933 ---------------------
5934 -- In_Main_Context --
5935 ---------------------
5937 function In_Main_Context (N : Node_Id) return Boolean is
5938 begin
5939 -- Scenarios outside the main unit are not considered because the ALI
5940 -- information supplied to binde is for the main unit only.
5942 if not In_Extended_Main_Code_Unit (N) then
5943 return False;
5945 -- Scenarios within internal units are not considered unless switch
5946 -- -gnatdE (elaboration checks on predefined units) is in effect.
5948 elsif not Debug_Flag_EE and then In_Internal_Unit (N) then
5949 return False;
5950 end if;
5952 return True;
5953 end In_Main_Context;
5955 ---------------------
5956 -- In_Same_Context --
5957 ---------------------
5959 function In_Same_Context
5960 (N1 : Node_Id;
5961 N2 : Node_Id;
5962 Nested_OK : Boolean := False) return Boolean
5964 function Find_Enclosing_Context (N : Node_Id) return Node_Id;
5965 -- Return the nearest enclosing non-library-level or compilation unit
5966 -- node which which encapsulates arbitrary node N. Return Empty is no
5967 -- such context is available.
5969 function In_Nested_Context
5970 (Outer : Node_Id;
5971 Inner : Node_Id) return Boolean;
5972 -- Determine whether arbitrary node Outer encapsulates arbitrary node
5973 -- Inner.
5975 ----------------------------
5976 -- Find_Enclosing_Context --
5977 ----------------------------
5979 function Find_Enclosing_Context (N : Node_Id) return Node_Id is
5980 Context : Node_Id;
5981 Par : Node_Id;
5983 begin
5984 Par := Parent (N);
5985 while Present (Par) loop
5987 -- A traversal from a subunit continues via the corresponding stub
5989 if Nkind (Par) = N_Subunit then
5990 Par := Corresponding_Stub (Par);
5992 -- Stop the traversal when the nearest enclosing non-library-level
5993 -- encapsulator has been reached.
5995 elsif Is_Non_Library_Level_Encapsulator (Par) then
5996 Context := Parent (Par);
5998 -- The sole exception is when the encapsulator is the unit of
5999 -- compilation because this case requires special processing
6000 -- (see below).
6002 if Present (Context)
6003 and then Nkind (Context) = N_Compilation_Unit
6004 then
6005 null;
6007 else
6008 return Par;
6009 end if;
6011 -- Reaching a compilation unit node without hitting a non-library-
6012 -- level encapsulator indicates that N is at the library level in
6013 -- which case the compilation unit is the context.
6015 elsif Nkind (Par) = N_Compilation_Unit then
6016 return Par;
6017 end if;
6019 Par := Parent (Par);
6020 end loop;
6022 return Empty;
6023 end Find_Enclosing_Context;
6025 -----------------------
6026 -- In_Nested_Context --
6027 -----------------------
6029 function In_Nested_Context
6030 (Outer : Node_Id;
6031 Inner : Node_Id) return Boolean
6033 Par : Node_Id;
6035 begin
6036 Par := Inner;
6037 while Present (Par) loop
6039 -- A traversal from a subunit continues via the corresponding stub
6041 if Nkind (Par) = N_Subunit then
6042 Par := Corresponding_Stub (Par);
6044 elsif Par = Outer then
6045 return True;
6046 end if;
6048 Par := Parent (Par);
6049 end loop;
6051 return False;
6052 end In_Nested_Context;
6054 -- Local variables
6056 Context_1 : constant Node_Id := Find_Enclosing_Context (N1);
6057 Context_2 : constant Node_Id := Find_Enclosing_Context (N2);
6059 -- Start of processing for In_Same_Context
6061 begin
6062 -- Both nodes appear within the same context
6064 if Context_1 = Context_2 then
6065 return True;
6067 -- Both nodes appear in compilation units. Determine whether one unit
6068 -- is the body of the other.
6070 elsif Nkind (Context_1) = N_Compilation_Unit
6071 and then Nkind (Context_2) = N_Compilation_Unit
6072 then
6073 return
6074 Is_Same_Unit
6075 (Unit_1 => Defining_Entity (Unit (Context_1)),
6076 Unit_2 => Defining_Entity (Unit (Context_2)));
6078 -- The context of N1 encloses the context of N2
6080 elsif Nested_OK and then In_Nested_Context (Context_1, Context_2) then
6081 return True;
6082 end if;
6084 return False;
6085 end In_Same_Context;
6087 ----------------
6088 -- Initialize --
6089 ----------------
6091 procedure Initialize is
6092 begin
6093 -- Set the soft link which enables Atree.Rewrite to update a top-level
6094 -- scenario each time it is transformed into another node.
6096 Set_Rewriting_Proc (Update_Elaboration_Scenario'Access);
6097 end Initialize;
6099 ---------------
6100 -- Info_Call --
6101 ---------------
6103 procedure Info_Call
6104 (Call : Node_Id;
6105 Target_Id : Entity_Id;
6106 Info_Msg : Boolean;
6107 In_SPARK : Boolean)
6109 procedure Info_Accept_Alternative;
6110 pragma Inline (Info_Accept_Alternative);
6111 -- Output information concerning an accept alternative
6113 procedure Info_Simple_Call;
6114 pragma Inline (Info_Simple_Call);
6115 -- Output information concerning the call
6117 procedure Info_Type_Actions (Action : String);
6118 pragma Inline (Info_Type_Actions);
6119 -- Output information concerning action Action of a type
6121 procedure Info_Verification_Call
6122 (Pred : String;
6123 Id : Entity_Id;
6124 Id_Kind : String);
6125 pragma Inline (Info_Verification_Call);
6126 -- Output information concerning the verification of predicate Pred
6127 -- applied to related entity Id with kind Id_Kind.
6129 -----------------------------
6130 -- Info_Accept_Alternative --
6131 -----------------------------
6133 procedure Info_Accept_Alternative is
6134 Entry_Id : constant Entity_Id := Receiving_Entry (Target_Id);
6136 begin
6137 pragma Assert (Present (Entry_Id));
6139 Elab_Msg_NE
6140 (Msg => "accept for entry & during elaboration",
6141 N => Call,
6142 Id => Entry_Id,
6143 Info_Msg => Info_Msg,
6144 In_SPARK => In_SPARK);
6145 end Info_Accept_Alternative;
6147 ----------------------
6148 -- Info_Simple_Call --
6149 ----------------------
6151 procedure Info_Simple_Call is
6152 begin
6153 Elab_Msg_NE
6154 (Msg => "call to & during elaboration",
6155 N => Call,
6156 Id => Target_Id,
6157 Info_Msg => Info_Msg,
6158 In_SPARK => In_SPARK);
6159 end Info_Simple_Call;
6161 -----------------------
6162 -- Info_Type_Actions --
6163 -----------------------
6165 procedure Info_Type_Actions (Action : String) is
6166 Typ : constant Entity_Id := First_Formal_Type (Target_Id);
6168 begin
6169 pragma Assert (Present (Typ));
6171 Elab_Msg_NE
6172 (Msg => Action & " actions for type & during elaboration",
6173 N => Call,
6174 Id => Typ,
6175 Info_Msg => Info_Msg,
6176 In_SPARK => In_SPARK);
6177 end Info_Type_Actions;
6179 ----------------------------
6180 -- Info_Verification_Call --
6181 ----------------------------
6183 procedure Info_Verification_Call
6184 (Pred : String;
6185 Id : Entity_Id;
6186 Id_Kind : String)
6188 begin
6189 pragma Assert (Present (Id));
6191 Elab_Msg_NE
6192 (Msg =>
6193 "verification of " & Pred & " of " & Id_Kind & " & during "
6194 & "elaboration",
6195 N => Call,
6196 Id => Id,
6197 Info_Msg => Info_Msg,
6198 In_SPARK => In_SPARK);
6199 end Info_Verification_Call;
6201 -- Start of processing for Info_Call
6203 begin
6204 -- Do not output anything for targets defined in internal units because
6205 -- this creates noise.
6207 if not In_Internal_Unit (Target_Id) then
6209 -- Accept alternative
6211 if Is_Accept_Alternative_Proc (Target_Id) then
6212 Info_Accept_Alternative;
6214 -- Adjustment
6216 elsif Is_TSS (Target_Id, TSS_Deep_Adjust) then
6217 Info_Type_Actions ("adjustment");
6219 -- Default_Initial_Condition
6221 elsif Is_Default_Initial_Condition_Proc (Target_Id) then
6222 Info_Verification_Call
6223 (Pred => "Default_Initial_Condition",
6224 Id => First_Formal_Type (Target_Id),
6225 Id_Kind => "type");
6227 -- Entries
6229 elsif Is_Protected_Entry (Target_Id) then
6230 Info_Simple_Call;
6232 -- Task entry calls are never processed because the entry being
6233 -- invoked does not have a corresponding "body", it has a select.
6235 elsif Is_Task_Entry (Target_Id) then
6236 null;
6238 -- Finalization
6240 elsif Is_TSS (Target_Id, TSS_Deep_Finalize) then
6241 Info_Type_Actions ("finalization");
6243 -- Calls to _Finalizer procedures must not appear in the output
6244 -- because this creates confusing noise.
6246 elsif Is_Finalizer_Proc (Target_Id) then
6247 null;
6249 -- Initial_Condition
6251 elsif Is_Initial_Condition_Proc (Target_Id) then
6252 Info_Verification_Call
6253 (Pred => "Initial_Condition",
6254 Id => Find_Enclosing_Scope (Call),
6255 Id_Kind => "package");
6257 -- Initialization
6259 elsif Is_Init_Proc (Target_Id)
6260 or else Is_TSS (Target_Id, TSS_Deep_Initialize)
6261 then
6262 Info_Type_Actions ("initialization");
6264 -- Invariant
6266 elsif Is_Invariant_Proc (Target_Id) then
6267 Info_Verification_Call
6268 (Pred => "invariants",
6269 Id => First_Formal_Type (Target_Id),
6270 Id_Kind => "type");
6272 -- Partial invariant calls must not appear in the output because this
6273 -- creates confusing noise.
6275 elsif Is_Partial_Invariant_Proc (Target_Id) then
6276 null;
6278 -- _Postconditions
6280 elsif Is_Postconditions_Proc (Target_Id) then
6281 Info_Verification_Call
6282 (Pred => "postconditions",
6283 Id => Find_Enclosing_Scope (Call),
6284 Id_Kind => "subprogram");
6286 -- Subprograms must come last because some of the previous cases fall
6287 -- under this category.
6289 elsif Ekind (Target_Id) = E_Function then
6290 Info_Simple_Call;
6292 elsif Ekind (Target_Id) = E_Procedure then
6293 Info_Simple_Call;
6295 else
6296 pragma Assert (False);
6297 null;
6298 end if;
6299 end if;
6300 end Info_Call;
6302 ------------------------
6303 -- Info_Instantiation --
6304 ------------------------
6306 procedure Info_Instantiation
6307 (Inst : Node_Id;
6308 Gen_Id : Entity_Id;
6309 Info_Msg : Boolean;
6310 In_SPARK : Boolean)
6312 begin
6313 Elab_Msg_NE
6314 (Msg => "instantiation of & during elaboration",
6315 N => Inst,
6316 Id => Gen_Id,
6317 Info_Msg => Info_Msg,
6318 In_SPARK => In_SPARK);
6319 end Info_Instantiation;
6321 -----------------------------
6322 -- Info_Variable_Reference --
6323 -----------------------------
6325 procedure Info_Variable_Reference
6326 (Ref : Node_Id;
6327 Var_Id : Entity_Id;
6328 Info_Msg : Boolean;
6329 In_SPARK : Boolean)
6331 begin
6332 if Is_Read (Ref) then
6333 Elab_Msg_NE
6334 (Msg => "read of variable & during elaboration",
6335 N => Ref,
6336 Id => Var_Id,
6337 Info_Msg => Info_Msg,
6338 In_SPARK => In_SPARK);
6339 end if;
6340 end Info_Variable_Reference;
6342 --------------------
6343 -- Insertion_Node --
6344 --------------------
6346 function Insertion_Node (N : Node_Id; Ins_Nod : Node_Id) return Node_Id is
6347 begin
6348 -- When the scenario denotes an instantiation, the proper insertion node
6349 -- is the instance spec. This ensures that the generic actuals will not
6350 -- be evaluated prior to a potential ABE.
6352 if Nkind (N) in N_Generic_Instantiation
6353 and then Present (Instance_Spec (N))
6354 then
6355 return Instance_Spec (N);
6357 -- Otherwise the proper insertion node is the candidate insertion node
6359 else
6360 return Ins_Nod;
6361 end if;
6362 end Insertion_Node;
6364 -----------------------
6365 -- Install_ABE_Check --
6366 -----------------------
6368 procedure Install_ABE_Check
6369 (N : Node_Id;
6370 Id : Entity_Id;
6371 Ins_Nod : Node_Id)
6373 Check_Ins_Nod : constant Node_Id := Insertion_Node (N, Ins_Nod);
6374 -- Insert the check prior to this node
6376 Loc : constant Source_Ptr := Sloc (N);
6377 Spec_Id : constant Entity_Id := Unique_Entity (Id);
6378 Unit_Id : constant Entity_Id := Find_Top_Unit (Id);
6379 Scop_Id : Entity_Id;
6381 begin
6382 -- Nothing to do when compiling for GNATprove because raise statements
6383 -- are not supported.
6385 if GNATprove_Mode then
6386 return;
6388 -- Nothing to do when the compilation will not produce an executable
6390 elsif Serious_Errors_Detected > 0 then
6391 return;
6393 -- Nothing to do for a compilation unit because there is no executable
6394 -- environment at that level.
6396 elsif Nkind (Parent (Check_Ins_Nod)) = N_Compilation_Unit then
6397 return;
6399 -- Nothing to do when the unit is elaborated prior to the main unit.
6400 -- This check must also consider the following cases:
6402 -- * Id's unit appears in the context of the main unit
6404 -- * Id's unit is subject to pragma Elaborate_Body. An ABE check MUST
6405 -- NOT be generated because Id's unit is always elaborated prior to
6406 -- the main unit.
6408 -- * Id's unit is the main unit. An ABE check MUST be generated in this
6409 -- case because a conditional ABE may be raised depending on the flow
6410 -- of execution within the main unit (flag Same_Unit_OK is False).
6412 elsif Has_Prior_Elaboration
6413 (Unit_Id => Unit_Id,
6414 Context_OK => True,
6415 Elab_Body_OK => True)
6416 then
6417 return;
6418 end if;
6420 -- Prevent multiple scenarios from installing the same ABE check
6422 Set_Is_Elaboration_Checks_OK_Node (N, False);
6424 -- Install the nearest enclosing scope of the scenario as there must be
6425 -- something on the scope stack.
6427 -- Performance note: parent traversal
6429 Scop_Id := Find_Enclosing_Scope (Check_Ins_Nod);
6430 pragma Assert (Present (Scop_Id));
6432 Push_Scope (Scop_Id);
6434 -- Generate:
6435 -- if not Spec_Id'Elaborated then
6436 -- raise Program_Error with "access before elaboration";
6437 -- end if;
6439 Insert_Action (Check_Ins_Nod,
6440 Make_Raise_Program_Error (Loc,
6441 Condition =>
6442 Make_Op_Not (Loc,
6443 Right_Opnd =>
6444 Make_Attribute_Reference (Loc,
6445 Prefix => New_Occurrence_Of (Spec_Id, Loc),
6446 Attribute_Name => Name_Elaborated)),
6447 Reason => PE_Access_Before_Elaboration));
6449 Pop_Scope;
6450 end Install_ABE_Check;
6452 -----------------------
6453 -- Install_ABE_Check --
6454 -----------------------
6456 procedure Install_ABE_Check
6457 (N : Node_Id;
6458 Target_Id : Entity_Id;
6459 Target_Decl : Node_Id;
6460 Target_Body : Node_Id;
6461 Ins_Nod : Node_Id)
6463 procedure Build_Elaboration_Entity;
6464 pragma Inline (Build_Elaboration_Entity);
6465 -- Create a new elaboration flag for Target_Id, insert it prior to
6466 -- Target_Decl, and set it after Body_Decl.
6468 ------------------------------
6469 -- Build_Elaboration_Entity --
6470 ------------------------------
6472 procedure Build_Elaboration_Entity is
6473 Loc : constant Source_Ptr := Sloc (Target_Id);
6474 Flag_Id : Entity_Id;
6476 begin
6477 -- Create the declaration of the elaboration flag. The name carries a
6478 -- unique counter in case of name overloading.
6480 Flag_Id :=
6481 Make_Defining_Identifier (Loc,
6482 Chars => New_External_Name (Chars (Target_Id), 'E', -1));
6484 Set_Elaboration_Entity (Target_Id, Flag_Id);
6485 Set_Elaboration_Entity_Required (Target_Id);
6487 Push_Scope (Scope (Target_Id));
6489 -- Generate:
6490 -- Enn : Short_Integer := 0;
6492 Insert_Action (Target_Decl,
6493 Make_Object_Declaration (Loc,
6494 Defining_Identifier => Flag_Id,
6495 Object_Definition =>
6496 New_Occurrence_Of (Standard_Short_Integer, Loc),
6497 Expression => Make_Integer_Literal (Loc, Uint_0)));
6499 -- Generate:
6500 -- Enn := 1;
6502 Set_Elaboration_Flag (Target_Body, Target_Id);
6504 Pop_Scope;
6505 end Build_Elaboration_Entity;
6507 -- Local variables
6509 Target_Unit_Id : constant Entity_Id := Find_Top_Unit (Target_Id);
6511 -- Start for processing for Install_ABE_Check
6513 begin
6514 -- Nothing to do when compiling for GNATprove because raise statements
6515 -- are not supported.
6517 if GNATprove_Mode then
6518 return;
6520 -- Nothing to do when the compilation will not produce an executable
6522 elsif Serious_Errors_Detected > 0 then
6523 return;
6525 -- Nothing to do when the target is a protected subprogram because the
6526 -- check is associated with the protected body subprogram.
6528 elsif Is_Protected_Subp (Target_Id) then
6529 return;
6531 -- Nothing to do when the target is elaborated prior to the main unit.
6532 -- This check must also consider the following cases:
6534 -- * The unit of the target appears in the context of the main unit
6536 -- * The unit of the target is subject to pragma Elaborate_Body. An ABE
6537 -- check MUST NOT be generated because the unit is always elaborated
6538 -- prior to the main unit.
6540 -- * The unit of the target is the main unit. An ABE check MUST be added
6541 -- in this case because a conditional ABE may be raised depending on
6542 -- the flow of execution within the main unit (flag Same_Unit_OK is
6543 -- False).
6545 elsif Has_Prior_Elaboration
6546 (Unit_Id => Target_Unit_Id,
6547 Context_OK => True,
6548 Elab_Body_OK => True)
6549 then
6550 return;
6552 -- Create an elaboration flag for the target when it does not have one
6554 elsif No (Elaboration_Entity (Target_Id)) then
6555 Build_Elaboration_Entity;
6556 end if;
6558 Install_ABE_Check
6559 (N => N,
6560 Ins_Nod => Ins_Nod,
6561 Id => Target_Id);
6562 end Install_ABE_Check;
6564 -------------------------
6565 -- Install_ABE_Failure --
6566 -------------------------
6568 procedure Install_ABE_Failure (N : Node_Id; Ins_Nod : Node_Id) is
6569 Fail_Ins_Nod : constant Node_Id := Insertion_Node (N, Ins_Nod);
6570 -- Insert the failure prior to this node
6572 Loc : constant Source_Ptr := Sloc (N);
6573 Scop_Id : Entity_Id;
6575 begin
6576 -- Nothing to do when compiling for GNATprove because raise statements
6577 -- are not supported.
6579 if GNATprove_Mode then
6580 return;
6582 -- Nothing to do when the compilation will not produce an executable
6584 elsif Serious_Errors_Detected > 0 then
6585 return;
6587 -- Do not install an ABE check for a compilation unit because there is
6588 -- no executable environment at that level.
6590 elsif Nkind (Parent (Fail_Ins_Nod)) = N_Compilation_Unit then
6591 return;
6592 end if;
6594 -- Prevent multiple scenarios from installing the same ABE failure
6596 Set_Is_Elaboration_Checks_OK_Node (N, False);
6598 -- Install the nearest enclosing scope of the scenario as there must be
6599 -- something on the scope stack.
6601 -- Performance note: parent traversal
6603 Scop_Id := Find_Enclosing_Scope (Fail_Ins_Nod);
6604 pragma Assert (Present (Scop_Id));
6606 Push_Scope (Scop_Id);
6608 -- Generate:
6609 -- raise Program_Error with "access before elaboration";
6611 Insert_Action (Fail_Ins_Nod,
6612 Make_Raise_Program_Error (Loc,
6613 Reason => PE_Access_Before_Elaboration));
6615 Pop_Scope;
6616 end Install_ABE_Failure;
6618 --------------------------------
6619 -- Is_Accept_Alternative_Proc --
6620 --------------------------------
6622 function Is_Accept_Alternative_Proc (Id : Entity_Id) return Boolean is
6623 begin
6624 -- To qualify, the entity must denote a procedure with a receiving entry
6626 return Ekind (Id) = E_Procedure and then Present (Receiving_Entry (Id));
6627 end Is_Accept_Alternative_Proc;
6629 ------------------------
6630 -- Is_Activation_Proc --
6631 ------------------------
6633 function Is_Activation_Proc (Id : Entity_Id) return Boolean is
6634 begin
6635 -- To qualify, the entity must denote one of the runtime procedures in
6636 -- charge of task activation.
6638 if Ekind (Id) = E_Procedure then
6639 if Restricted_Profile then
6640 return Is_RTE (Id, RE_Activate_Restricted_Tasks);
6641 else
6642 return Is_RTE (Id, RE_Activate_Tasks);
6643 end if;
6644 end if;
6646 return False;
6647 end Is_Activation_Proc;
6649 ----------------------------
6650 -- Is_Ada_Semantic_Target --
6651 ----------------------------
6653 function Is_Ada_Semantic_Target (Id : Entity_Id) return Boolean is
6654 begin
6655 return
6656 Is_Activation_Proc (Id)
6657 or else Is_Controlled_Proc (Id, Name_Adjust)
6658 or else Is_Controlled_Proc (Id, Name_Finalize)
6659 or else Is_Controlled_Proc (Id, Name_Initialize)
6660 or else Is_Init_Proc (Id)
6661 or else Is_Invariant_Proc (Id)
6662 or else Is_Protected_Entry (Id)
6663 or else Is_Protected_Subp (Id)
6664 or else Is_Protected_Body_Subp (Id)
6665 or else Is_Task_Entry (Id);
6666 end Is_Ada_Semantic_Target;
6668 --------------------------------
6669 -- Is_Assertion_Pragma_Target --
6670 --------------------------------
6672 function Is_Assertion_Pragma_Target (Id : Entity_Id) return Boolean is
6673 begin
6674 return
6675 Is_Default_Initial_Condition_Proc (Id)
6676 or else Is_Initial_Condition_Proc (Id)
6677 or else Is_Invariant_Proc (Id)
6678 or else Is_Partial_Invariant_Proc (Id)
6679 or else Is_Postconditions_Proc (Id);
6680 end Is_Assertion_Pragma_Target;
6682 ----------------------------
6683 -- Is_Bodiless_Subprogram --
6684 ----------------------------
6686 function Is_Bodiless_Subprogram (Subp_Id : Entity_Id) return Boolean is
6687 begin
6688 -- An abstract subprogram does not have a body
6690 if Ekind_In (Subp_Id, E_Function,
6691 E_Operator,
6692 E_Procedure)
6693 and then Is_Abstract_Subprogram (Subp_Id)
6694 then
6695 return True;
6697 -- A formal subprogram does not have a body
6699 elsif Is_Formal_Subprogram (Subp_Id) then
6700 return True;
6702 -- An imported subprogram may have a body, however it is not known at
6703 -- compile or bind time where the body resides and whether it will be
6704 -- elaborated on time.
6706 elsif Is_Imported (Subp_Id) then
6707 return True;
6708 end if;
6710 return False;
6711 end Is_Bodiless_Subprogram;
6713 ------------------------
6714 -- Is_Controlled_Proc --
6715 ------------------------
6717 function Is_Controlled_Proc
6718 (Subp_Id : Entity_Id;
6719 Subp_Nam : Name_Id) return Boolean
6721 Formal_Id : Entity_Id;
6723 begin
6724 pragma Assert (Nam_In (Subp_Nam, Name_Adjust,
6725 Name_Finalize,
6726 Name_Initialize));
6728 -- To qualify, the subprogram must denote a source procedure with name
6729 -- Adjust, Finalize, or Initialize where the sole formal is controlled.
6731 if Comes_From_Source (Subp_Id)
6732 and then Ekind (Subp_Id) = E_Procedure
6733 and then Chars (Subp_Id) = Subp_Nam
6734 then
6735 Formal_Id := First_Formal (Subp_Id);
6737 return
6738 Present (Formal_Id)
6739 and then Is_Controlled (Etype (Formal_Id))
6740 and then No (Next_Formal (Formal_Id));
6741 end if;
6743 return False;
6744 end Is_Controlled_Proc;
6746 ---------------------------------------
6747 -- Is_Default_Initial_Condition_Proc --
6748 ---------------------------------------
6750 function Is_Default_Initial_Condition_Proc
6751 (Id : Entity_Id) return Boolean
6753 begin
6754 -- To qualify, the entity must denote a Default_Initial_Condition
6755 -- procedure.
6757 return Ekind (Id) = E_Procedure and then Is_DIC_Procedure (Id);
6758 end Is_Default_Initial_Condition_Proc;
6760 -----------------------
6761 -- Is_Finalizer_Proc --
6762 -----------------------
6764 function Is_Finalizer_Proc (Id : Entity_Id) return Boolean is
6765 begin
6766 -- To qualify, the entity must denote a _Finalizer procedure
6768 return Ekind (Id) = E_Procedure and then Chars (Id) = Name_uFinalizer;
6769 end Is_Finalizer_Proc;
6771 -----------------------
6772 -- Is_Guaranteed_ABE --
6773 -----------------------
6775 function Is_Guaranteed_ABE
6776 (N : Node_Id;
6777 Target_Decl : Node_Id;
6778 Target_Body : Node_Id) return Boolean
6780 begin
6781 -- Avoid cascaded errors if there were previous serious infractions.
6782 -- As a result the scenario will not be treated as a guaranteed ABE.
6783 -- This behaviour parallels that of the old ABE mechanism.
6785 if Serious_Errors_Detected > 0 then
6786 return False;
6788 -- The scenario and the target appear within the same context ignoring
6789 -- enclosing library levels.
6791 -- Performance note: parent traversal
6793 elsif In_Same_Context (N, Target_Decl) then
6795 -- The target body has already been encountered. The scenario results
6796 -- in a guaranteed ABE if it appears prior to the body.
6798 if Present (Target_Body) then
6799 return Earlier_In_Extended_Unit (N, Target_Body);
6801 -- Otherwise the body has not been encountered yet. The scenario is
6802 -- a guaranteed ABE since the body will appear later. It is assumed
6803 -- that the caller has already checked whether the scenario is ABE-
6804 -- safe as optional bodies are not considered here.
6806 else
6807 return True;
6808 end if;
6809 end if;
6811 return False;
6812 end Is_Guaranteed_ABE;
6814 -------------------------------
6815 -- Is_Initial_Condition_Proc --
6816 -------------------------------
6818 function Is_Initial_Condition_Proc (Id : Entity_Id) return Boolean is
6819 begin
6820 -- To qualify, the entity must denote an Initial_Condition procedure
6822 return
6823 Ekind (Id) = E_Procedure and then Is_Initial_Condition_Procedure (Id);
6824 end Is_Initial_Condition_Proc;
6826 --------------------
6827 -- Is_Initialized --
6828 --------------------
6830 function Is_Initialized (Obj_Decl : Node_Id) return Boolean is
6831 begin
6832 -- To qualify, the object declaration must have an expression
6834 return
6835 Present (Expression (Obj_Decl)) or else Has_Init_Expression (Obj_Decl);
6836 end Is_Initialized;
6838 -----------------------
6839 -- Is_Invariant_Proc --
6840 -----------------------
6842 function Is_Invariant_Proc (Id : Entity_Id) return Boolean is
6843 begin
6844 -- To qualify, the entity must denote the "full" invariant procedure
6846 return Ekind (Id) = E_Procedure and then Is_Invariant_Procedure (Id);
6847 end Is_Invariant_Proc;
6849 ---------------------------------------
6850 -- Is_Non_Library_Level_Encapsulator --
6851 ---------------------------------------
6853 function Is_Non_Library_Level_Encapsulator (N : Node_Id) return Boolean is
6854 begin
6855 case Nkind (N) is
6856 when N_Abstract_Subprogram_Declaration
6857 | N_Aspect_Specification
6858 | N_Component_Declaration
6859 | N_Entry_Body
6860 | N_Entry_Declaration
6861 | N_Expression_Function
6862 | N_Formal_Abstract_Subprogram_Declaration
6863 | N_Formal_Concrete_Subprogram_Declaration
6864 | N_Formal_Object_Declaration
6865 | N_Formal_Package_Declaration
6866 | N_Formal_Type_Declaration
6867 | N_Generic_Association
6868 | N_Implicit_Label_Declaration
6869 | N_Incomplete_Type_Declaration
6870 | N_Private_Extension_Declaration
6871 | N_Private_Type_Declaration
6872 | N_Protected_Body
6873 | N_Protected_Type_Declaration
6874 | N_Single_Protected_Declaration
6875 | N_Single_Task_Declaration
6876 | N_Subprogram_Body
6877 | N_Subprogram_Declaration
6878 | N_Task_Body
6879 | N_Task_Type_Declaration
6881 return True;
6883 when others =>
6884 return Is_Generic_Declaration_Or_Body (N);
6885 end case;
6886 end Is_Non_Library_Level_Encapsulator;
6888 -------------------------------
6889 -- Is_Partial_Invariant_Proc --
6890 -------------------------------
6892 function Is_Partial_Invariant_Proc (Id : Entity_Id) return Boolean is
6893 begin
6894 -- To qualify, the entity must denote the "partial" invariant procedure
6896 return
6897 Ekind (Id) = E_Procedure and then Is_Partial_Invariant_Procedure (Id);
6898 end Is_Partial_Invariant_Proc;
6900 ----------------------------
6901 -- Is_Postconditions_Proc --
6902 ----------------------------
6904 function Is_Postconditions_Proc (Id : Entity_Id) return Boolean is
6905 begin
6906 -- To qualify, the entity must denote a _Postconditions procedure
6908 return
6909 Ekind (Id) = E_Procedure and then Chars (Id) = Name_uPostconditions;
6910 end Is_Postconditions_Proc;
6912 ---------------------------
6913 -- Is_Preelaborated_Unit --
6914 ---------------------------
6916 function Is_Preelaborated_Unit (Id : Entity_Id) return Boolean is
6917 begin
6918 return
6919 Is_Preelaborated (Id)
6920 or else Is_Pure (Id)
6921 or else Is_Remote_Call_Interface (Id)
6922 or else Is_Remote_Types (Id)
6923 or else Is_Shared_Passive (Id);
6924 end Is_Preelaborated_Unit;
6926 ------------------------
6927 -- Is_Protected_Entry --
6928 ------------------------
6930 function Is_Protected_Entry (Id : Entity_Id) return Boolean is
6931 begin
6932 -- To qualify, the entity must denote an entry defined in a protected
6933 -- type.
6935 return
6936 Is_Entry (Id)
6937 and then Is_Protected_Type (Non_Private_View (Scope (Id)));
6938 end Is_Protected_Entry;
6940 -----------------------
6941 -- Is_Protected_Subp --
6942 -----------------------
6944 function Is_Protected_Subp (Id : Entity_Id) return Boolean is
6945 begin
6946 -- To qualify, the entity must denote a subprogram defined within a
6947 -- protected type.
6949 return
6950 Ekind_In (Id, E_Function, E_Procedure)
6951 and then Is_Protected_Type (Non_Private_View (Scope (Id)));
6952 end Is_Protected_Subp;
6954 ----------------------------
6955 -- Is_Protected_Body_Subp --
6956 ----------------------------
6958 function Is_Protected_Body_Subp (Id : Entity_Id) return Boolean is
6959 begin
6960 -- To qualify, the entity must denote a subprogram with attribute
6961 -- Protected_Subprogram set.
6963 return
6964 Ekind_In (Id, E_Function, E_Procedure)
6965 and then Present (Protected_Subprogram (Id));
6966 end Is_Protected_Body_Subp;
6968 --------------------------------
6969 -- Is_Recorded_SPARK_Scenario --
6970 --------------------------------
6972 function Is_Recorded_SPARK_Scenario (N : Node_Id) return Boolean is
6973 begin
6974 if Recorded_SPARK_Scenarios_In_Use then
6975 return Recorded_SPARK_Scenarios.Get (N);
6976 end if;
6978 return Recorded_SPARK_Scenarios_No_Element;
6979 end Is_Recorded_SPARK_Scenario;
6981 ------------------------------------
6982 -- Is_Recorded_Top_Level_Scenario --
6983 ------------------------------------
6985 function Is_Recorded_Top_Level_Scenario (N : Node_Id) return Boolean is
6986 begin
6987 if Recorded_Top_Level_Scenarios_In_Use then
6988 return Recorded_Top_Level_Scenarios.Get (N);
6989 end if;
6991 return Recorded_Top_Level_Scenarios_No_Element;
6992 end Is_Recorded_Top_Level_Scenario;
6994 ------------------------
6995 -- Is_Safe_Activation --
6996 ------------------------
6998 function Is_Safe_Activation
6999 (Call : Node_Id;
7000 Task_Decl : Node_Id) return Boolean
7002 begin
7003 -- The activation of a task coming from an external instance cannot
7004 -- cause an ABE because the generic was already instantiated. Note
7005 -- that the instantiation itself may lead to an ABE.
7007 return
7008 In_External_Instance
7009 (N => Call,
7010 Target_Decl => Task_Decl);
7011 end Is_Safe_Activation;
7013 ------------------
7014 -- Is_Safe_Call --
7015 ------------------
7017 function Is_Safe_Call
7018 (Call : Node_Id;
7019 Target_Attrs : Target_Attributes) return Boolean
7021 begin
7022 -- The target is either an abstract subprogram, formal subprogram, or
7023 -- imported, in which case it does not have a body at compile or bind
7024 -- time. Assume that the call is ABE-safe.
7026 if Is_Bodiless_Subprogram (Target_Attrs.Spec_Id) then
7027 return True;
7029 -- The target is an instantiation of a generic subprogram. The call
7030 -- cannot cause an ABE because the generic was already instantiated.
7031 -- Note that the instantiation itself may lead to an ABE.
7033 elsif Is_Generic_Instance (Target_Attrs.Spec_Id) then
7034 return True;
7036 -- The invocation of a target coming from an external instance cannot
7037 -- cause an ABE because the generic was already instantiated. Note that
7038 -- the instantiation itself may lead to an ABE.
7040 elsif In_External_Instance
7041 (N => Call,
7042 Target_Decl => Target_Attrs.Spec_Decl)
7043 then
7044 return True;
7046 -- The target is a subprogram body without a previous declaration. The
7047 -- call cannot cause an ABE because the body has already been seen.
7049 elsif Nkind (Target_Attrs.Spec_Decl) = N_Subprogram_Body
7050 and then No (Corresponding_Spec (Target_Attrs.Spec_Decl))
7051 then
7052 return True;
7054 -- The target is a subprogram body stub without a prior declaration.
7055 -- The call cannot cause an ABE because the proper body substitutes
7056 -- the stub.
7058 elsif Nkind (Target_Attrs.Spec_Decl) = N_Subprogram_Body_Stub
7059 and then No (Corresponding_Spec_Of_Stub (Target_Attrs.Spec_Decl))
7060 then
7061 return True;
7063 -- Subprogram bodies which wrap attribute references used as actuals
7064 -- in instantiations are always ABE-safe. These bodies are artifacts
7065 -- of expansion.
7067 elsif Present (Target_Attrs.Body_Decl)
7068 and then Nkind (Target_Attrs.Body_Decl) = N_Subprogram_Body
7069 and then Was_Attribute_Reference (Target_Attrs.Body_Decl)
7070 then
7071 return True;
7072 end if;
7074 return False;
7075 end Is_Safe_Call;
7077 ---------------------------
7078 -- Is_Safe_Instantiation --
7079 ---------------------------
7081 function Is_Safe_Instantiation
7082 (Inst : Node_Id;
7083 Gen_Attrs : Target_Attributes) return Boolean
7085 begin
7086 -- The generic is an intrinsic subprogram in which case it does not
7087 -- have a body at compile or bind time. Assume that the instantiation
7088 -- is ABE-safe.
7090 if Is_Bodiless_Subprogram (Gen_Attrs.Spec_Id) then
7091 return True;
7093 -- The instantiation of an external nested generic cannot cause an ABE
7094 -- if the outer generic was already instantiated. Note that the instance
7095 -- of the outer generic may lead to an ABE.
7097 elsif In_External_Instance
7098 (N => Inst,
7099 Target_Decl => Gen_Attrs.Spec_Decl)
7100 then
7101 return True;
7103 -- The generic is a package. The instantiation cannot cause an ABE when
7104 -- the package has no body.
7106 elsif Ekind (Gen_Attrs.Spec_Id) = E_Generic_Package
7107 and then not Has_Body (Gen_Attrs.Spec_Decl)
7108 then
7109 return True;
7110 end if;
7112 return False;
7113 end Is_Safe_Instantiation;
7115 ------------------
7116 -- Is_Same_Unit --
7117 ------------------
7119 function Is_Same_Unit
7120 (Unit_1 : Entity_Id;
7121 Unit_2 : Entity_Id) return Boolean
7123 function Is_Subunit (Unit_Id : Entity_Id) return Boolean;
7124 pragma Inline (Is_Subunit);
7125 -- Determine whether unit Unit_Id is a subunit
7127 function Normalize_Unit (Unit_Id : Entity_Id) return Entity_Id;
7128 -- Strip a potential subunit chain ending with unit Unit_Id and return
7129 -- the corresponding spec.
7131 ----------------
7132 -- Is_Subunit --
7133 ----------------
7135 function Is_Subunit (Unit_Id : Entity_Id) return Boolean is
7136 begin
7137 return Nkind (Parent (Unit_Declaration_Node (Unit_Id))) = N_Subunit;
7138 end Is_Subunit;
7140 --------------------
7141 -- Normalize_Unit --
7142 --------------------
7144 function Normalize_Unit (Unit_Id : Entity_Id) return Entity_Id is
7145 Result : Entity_Id;
7147 begin
7148 -- Eliminate a potential chain of subunits to reach to proper body
7150 Result := Unit_Id;
7151 while Present (Result)
7152 and then Result /= Standard_Standard
7153 and then Is_Subunit (Result)
7154 loop
7155 Result := Scope (Result);
7156 end loop;
7158 -- Obtain the entity of the corresponding spec (if any)
7160 return Unique_Entity (Result);
7161 end Normalize_Unit;
7163 -- Start of processing for Is_Same_Unit
7165 begin
7166 return Normalize_Unit (Unit_1) = Normalize_Unit (Unit_2);
7167 end Is_Same_Unit;
7169 -----------------
7170 -- Is_Scenario --
7171 -----------------
7173 function Is_Scenario (N : Node_Id) return Boolean is
7174 begin
7175 case Nkind (N) is
7176 when N_Assignment_Statement
7177 | N_Attribute_Reference
7178 | N_Call_Marker
7179 | N_Entry_Call_Statement
7180 | N_Expanded_Name
7181 | N_Function_Call
7182 | N_Function_Instantiation
7183 | N_Identifier
7184 | N_Package_Instantiation
7185 | N_Procedure_Call_Statement
7186 | N_Procedure_Instantiation
7187 | N_Requeue_Statement
7189 return True;
7191 when others =>
7192 return False;
7193 end case;
7194 end Is_Scenario;
7196 ------------------------------
7197 -- Is_SPARK_Semantic_Target --
7198 ------------------------------
7200 function Is_SPARK_Semantic_Target (Id : Entity_Id) return Boolean is
7201 begin
7202 return
7203 Is_Default_Initial_Condition_Proc (Id)
7204 or else Is_Initial_Condition_Proc (Id);
7205 end Is_SPARK_Semantic_Target;
7207 ------------------------
7208 -- Is_Suitable_Access --
7209 ------------------------
7211 function Is_Suitable_Access (N : Node_Id) return Boolean is
7212 Nam : Name_Id;
7213 Pref : Node_Id;
7214 Subp_Id : Entity_Id;
7216 begin
7217 -- This scenario is relevant only when the static model is in effect
7218 -- because it is graph-dependent and does not involve any run-time
7219 -- checks. Allowing it in the dynamic model would create confusing
7220 -- noise.
7222 if not Static_Elaboration_Checks then
7223 return False;
7225 -- Nothing to do when switch -gnatd.U (ignore 'Access) is in effect
7227 elsif Debug_Flag_Dot_UU then
7228 return False;
7230 -- Nothing to do when the scenario is not an attribute reference
7232 elsif Nkind (N) /= N_Attribute_Reference then
7233 return False;
7235 -- Nothing to do for internally-generated attributes because they are
7236 -- assumed to be ABE safe.
7238 elsif not Comes_From_Source (N) then
7239 return False;
7240 end if;
7242 Nam := Attribute_Name (N);
7243 Pref := Prefix (N);
7245 -- Sanitize the prefix of the attribute
7247 if not Is_Entity_Name (Pref) then
7248 return False;
7250 elsif No (Entity (Pref)) then
7251 return False;
7252 end if;
7254 Subp_Id := Entity (Pref);
7256 if not Is_Subprogram_Or_Entry (Subp_Id) then
7257 return False;
7258 end if;
7260 -- Traverse a possible chain of renamings to obtain the original entry
7261 -- or subprogram which the prefix may rename.
7263 Subp_Id := Get_Renamed_Entity (Subp_Id);
7265 -- To qualify, the attribute must meet the following prerequisites:
7267 return
7269 -- The prefix must denote a source entry, operator, or subprogram
7270 -- which is not imported.
7272 Comes_From_Source (Subp_Id)
7273 and then Is_Subprogram_Or_Entry (Subp_Id)
7274 and then not Is_Bodiless_Subprogram (Subp_Id)
7276 -- The attribute name must be one of the 'Access forms. Note that
7277 -- 'Unchecked_Access cannot apply to a subprogram.
7279 and then Nam_In (Nam, Name_Access, Name_Unrestricted_Access);
7280 end Is_Suitable_Access;
7282 ----------------------
7283 -- Is_Suitable_Call --
7284 ----------------------
7286 function Is_Suitable_Call (N : Node_Id) return Boolean is
7287 begin
7288 -- Entry and subprogram calls are intentionally ignored because they
7289 -- may undergo expansion depending on the compilation mode, previous
7290 -- errors, generic context, etc. Call markers play the role of calls
7291 -- and provide a uniform foundation for ABE processing.
7293 return Nkind (N) = N_Call_Marker;
7294 end Is_Suitable_Call;
7296 -------------------------------
7297 -- Is_Suitable_Instantiation --
7298 -------------------------------
7300 function Is_Suitable_Instantiation (N : Node_Id) return Boolean is
7301 Orig_N : constant Node_Id := Original_Node (N);
7302 -- Use the original node in case an instantiation library unit is
7303 -- rewritten as a package or subprogram.
7305 begin
7306 -- To qualify, the instantiation must come from source
7308 return
7309 Comes_From_Source (Orig_N)
7310 and then Nkind (Orig_N) in N_Generic_Instantiation;
7311 end Is_Suitable_Instantiation;
7313 --------------------------
7314 -- Is_Suitable_Scenario --
7315 --------------------------
7317 function Is_Suitable_Scenario (N : Node_Id) return Boolean is
7318 begin
7319 -- NOTE: Derived types and pragma Refined_State are intentionally left
7320 -- out because they are not executable during elaboration.
7322 return
7323 Is_Suitable_Access (N)
7324 or else Is_Suitable_Call (N)
7325 or else Is_Suitable_Instantiation (N)
7326 or else Is_Suitable_Variable_Assignment (N)
7327 or else Is_Suitable_Variable_Reference (N);
7328 end Is_Suitable_Scenario;
7330 ------------------------------------
7331 -- Is_Suitable_SPARK_Derived_Type --
7332 ------------------------------------
7334 function Is_Suitable_SPARK_Derived_Type (N : Node_Id) return Boolean is
7335 Prag : Node_Id;
7336 Typ : Entity_Id;
7338 begin
7339 -- To qualify, the type declaration must denote a derived tagged type
7340 -- with primitive operations, subject to pragma SPARK_Mode On.
7342 if Nkind (N) = N_Full_Type_Declaration
7343 and then Nkind (Type_Definition (N)) = N_Derived_Type_Definition
7344 then
7345 Typ := Defining_Entity (N);
7346 Prag := SPARK_Pragma (Typ);
7348 return
7349 Is_Tagged_Type (Typ)
7350 and then Has_Primitive_Operations (Typ)
7351 and then Present (Prag)
7352 and then Get_SPARK_Mode_From_Annotation (Prag) = On;
7353 end if;
7355 return False;
7356 end Is_Suitable_SPARK_Derived_Type;
7358 -------------------------------------
7359 -- Is_Suitable_SPARK_Instantiation --
7360 -------------------------------------
7362 function Is_Suitable_SPARK_Instantiation (N : Node_Id) return Boolean is
7363 Gen_Attrs : Target_Attributes;
7364 Gen_Id : Entity_Id;
7365 Inst : Node_Id;
7366 Inst_Attrs : Instantiation_Attributes;
7367 Inst_Id : Entity_Id;
7369 begin
7370 -- To qualify, both the instantiation and the generic must be subject to
7371 -- SPARK_Mode On.
7373 if Is_Suitable_Instantiation (N) then
7374 Extract_Instantiation_Attributes
7375 (Exp_Inst => N,
7376 Inst => Inst,
7377 Inst_Id => Inst_Id,
7378 Gen_Id => Gen_Id,
7379 Attrs => Inst_Attrs);
7381 Extract_Target_Attributes (Gen_Id, Gen_Attrs);
7383 return Inst_Attrs.SPARK_Mode_On and Gen_Attrs.SPARK_Mode_On;
7384 end if;
7386 return False;
7387 end Is_Suitable_SPARK_Instantiation;
7389 --------------------------------------------
7390 -- Is_Suitable_SPARK_Refined_State_Pragma --
7391 --------------------------------------------
7393 function Is_Suitable_SPARK_Refined_State_Pragma
7394 (N : Node_Id) return Boolean
7396 begin
7397 -- To qualfy, the pragma must denote Refined_State
7399 return
7400 Nkind (N) = N_Pragma
7401 and then Pragma_Name (N) = Name_Refined_State;
7402 end Is_Suitable_SPARK_Refined_State_Pragma;
7404 -------------------------------------
7405 -- Is_Suitable_Variable_Assignment --
7406 -------------------------------------
7408 function Is_Suitable_Variable_Assignment (N : Node_Id) return Boolean is
7409 N_Unit : Node_Id;
7410 N_Unit_Id : Entity_Id;
7411 Nam : Node_Id;
7412 Var_Decl : Node_Id;
7413 Var_Id : Entity_Id;
7414 Var_Unit : Node_Id;
7415 Var_Unit_Id : Entity_Id;
7417 begin
7418 -- This scenario is relevant only when the static model is in effect
7419 -- because it is graph-dependent and does not involve any run-time
7420 -- checks. Allowing it in the dynamic model would create confusing
7421 -- noise.
7423 if not Static_Elaboration_Checks then
7424 return False;
7426 -- Nothing to do when the scenario is not an assignment
7428 elsif Nkind (N) /= N_Assignment_Statement then
7429 return False;
7431 -- Nothing to do for internally-generated assignments because they are
7432 -- assumed to be ABE safe.
7434 elsif not Comes_From_Source (N) then
7435 return False;
7437 -- Assignments are ignored in GNAT mode on the assumption that they are
7438 -- ABE-safe. This behaviour parallels that of the old ABE mechanism.
7440 elsif GNAT_Mode then
7441 return False;
7442 end if;
7444 Nam := Extract_Assignment_Name (N);
7446 -- Sanitize the left hand side of the assignment
7448 if not Is_Entity_Name (Nam) then
7449 return False;
7451 elsif No (Entity (Nam)) then
7452 return False;
7453 end if;
7455 Var_Id := Entity (Nam);
7457 -- Sanitize the variable
7459 if Var_Id = Any_Id then
7460 return False;
7462 elsif Ekind (Var_Id) /= E_Variable then
7463 return False;
7464 end if;
7466 Var_Decl := Declaration_Node (Var_Id);
7468 if Nkind (Var_Decl) /= N_Object_Declaration then
7469 return False;
7470 end if;
7472 N_Unit_Id := Find_Top_Unit (N);
7473 N_Unit := Unit_Declaration_Node (N_Unit_Id);
7475 Var_Unit_Id := Find_Top_Unit (Var_Decl);
7476 Var_Unit := Unit_Declaration_Node (Var_Unit_Id);
7478 -- To qualify, the assignment must meet the following prerequisites:
7480 return
7481 Comes_From_Source (Var_Id)
7483 -- The variable must be declared in the spec of compilation unit U
7485 and then Nkind (Var_Unit) = N_Package_Declaration
7487 -- Performance note: parent traversal
7489 and then Find_Enclosing_Level (Var_Decl) = Package_Spec
7491 -- The assignment must occur in the body of compilation unit U
7493 and then Nkind (N_Unit) = N_Package_Body
7494 and then Present (Corresponding_Body (Var_Unit))
7495 and then Corresponding_Body (Var_Unit) = N_Unit_Id;
7496 end Is_Suitable_Variable_Assignment;
7498 ------------------------------------
7499 -- Is_Suitable_Variable_Reference --
7500 ------------------------------------
7502 function Is_Suitable_Variable_Reference (N : Node_Id) return Boolean is
7503 begin
7504 -- Expanded names and identifiers are intentionally ignored because they
7505 -- be folded, optimized away, etc. Variable references markers play the
7506 -- role of variable references and provide a uniform foundation for ABE
7507 -- processing.
7509 return Nkind (N) = N_Variable_Reference_Marker;
7510 end Is_Suitable_Variable_Reference;
7512 -------------------
7513 -- Is_Task_Entry --
7514 -------------------
7516 function Is_Task_Entry (Id : Entity_Id) return Boolean is
7517 begin
7518 -- To qualify, the entity must denote an entry defined in a task type
7520 return
7521 Is_Entry (Id) and then Is_Task_Type (Non_Private_View (Scope (Id)));
7522 end Is_Task_Entry;
7524 ------------------------
7525 -- Is_Up_Level_Target --
7526 ------------------------
7528 function Is_Up_Level_Target (Target_Decl : Node_Id) return Boolean is
7529 Root : constant Node_Id := Root_Scenario;
7531 begin
7532 -- The root appears within the declaratons of a block statement, entry
7533 -- body, subprogram body, or task body ignoring enclosing packages. The
7534 -- root is always within the main unit. An up-level target is a notion
7535 -- applicable only to the static model because scenarios are reached by
7536 -- means of graph traversal started from a fixed declarative or library
7537 -- level.
7539 -- Performance note: parent traversal
7541 if Static_Elaboration_Checks
7542 and then Find_Enclosing_Level (Root) = Declaration_Level
7543 then
7544 -- The target is within the main unit. It acts as an up-level target
7545 -- when it appears within a context which encloses the root.
7547 -- package body Main_Unit is
7548 -- function Func ...; -- target
7550 -- procedure Proc is
7551 -- X : ... := Func; -- root scenario
7553 if In_Extended_Main_Code_Unit (Target_Decl) then
7555 -- Performance note: parent traversal
7557 return not In_Same_Context (Root, Target_Decl, Nested_OK => True);
7559 -- Otherwise the target is external to the main unit which makes it
7560 -- an up-level target.
7562 else
7563 return True;
7564 end if;
7565 end if;
7567 return False;
7568 end Is_Up_Level_Target;
7570 ---------------------
7571 -- Is_Visited_Body --
7572 ---------------------
7574 function Is_Visited_Body (Body_Decl : Node_Id) return Boolean is
7575 begin
7576 if Visited_Bodies_In_Use then
7577 return Visited_Bodies.Get (Body_Decl);
7578 end if;
7580 return Visited_Bodies_No_Element;
7581 end Is_Visited_Body;
7583 -------------------------------
7584 -- Kill_Elaboration_Scenario --
7585 -------------------------------
7587 procedure Kill_Elaboration_Scenario (N : Node_Id) is
7588 procedure Kill_SPARK_Scenario;
7589 pragma Inline (Kill_SPARK_Scenario);
7590 -- Eliminate scenario N from table SPARK_Scenarios if it is recorded
7591 -- there.
7593 procedure Kill_Top_Level_Scenario;
7594 pragma Inline (Kill_Top_Level_Scenario);
7595 -- Eliminate scenario N from table Top_Level_Scenarios if it is recorded
7596 -- there.
7598 -------------------------
7599 -- Kill_SPARK_Scenario --
7600 -------------------------
7602 procedure Kill_SPARK_Scenario is
7603 package Scenarios renames SPARK_Scenarios;
7605 begin
7606 if Is_Recorded_SPARK_Scenario (N) then
7608 -- Performance note: list traversal
7610 for Index in Scenarios.First .. Scenarios.Last loop
7611 if Scenarios.Table (Index) = N then
7612 Scenarios.Table (Index) := Empty;
7614 -- The SPARK scenario is no longer recorded
7616 Set_Is_Recorded_SPARK_Scenario (N, False);
7617 return;
7618 end if;
7619 end loop;
7621 -- A recorded SPARK scenario must be in the table of recorded
7622 -- SPARK scenarios.
7624 pragma Assert (False);
7625 end if;
7626 end Kill_SPARK_Scenario;
7628 -----------------------------
7629 -- Kill_Top_Level_Scenario --
7630 -----------------------------
7632 procedure Kill_Top_Level_Scenario is
7633 package Scenarios renames Top_Level_Scenarios;
7635 begin
7636 if Is_Recorded_Top_Level_Scenario (N) then
7638 -- Performance node: list traversal
7640 for Index in Scenarios.First .. Scenarios.Last loop
7641 if Scenarios.Table (Index) = N then
7642 Scenarios.Table (Index) := Empty;
7644 -- The top-level scenario is no longer recorded
7646 Set_Is_Recorded_Top_Level_Scenario (N, False);
7647 return;
7648 end if;
7649 end loop;
7651 -- A recorded top-level scenario must be in the table of recorded
7652 -- top-level scenarios.
7654 pragma Assert (False);
7655 end if;
7656 end Kill_Top_Level_Scenario;
7658 -- Start of processing for Kill_Elaboration_Scenario
7660 begin
7661 -- Nothing to do when switch -gnatH (legacy elaboration checking mode
7662 -- enabled) is in effect because the legacy ABE lechanism does not need
7663 -- to carry out this action.
7665 if Legacy_Elaboration_Checks then
7666 return;
7667 end if;
7669 -- Eliminate a recorded scenario when it appears within dead code
7670 -- because it will not be executed at elaboration time.
7672 if Is_Scenario (N) then
7673 Kill_SPARK_Scenario;
7674 Kill_Top_Level_Scenario;
7675 end if;
7676 end Kill_Elaboration_Scenario;
7678 ----------------------------------
7679 -- Meet_Elaboration_Requirement --
7680 ----------------------------------
7682 procedure Meet_Elaboration_Requirement
7683 (N : Node_Id;
7684 Target_Id : Entity_Id;
7685 Req_Nam : Name_Id)
7687 Main_Id : constant Entity_Id := Cunit_Entity (Main_Unit);
7688 Unit_Id : constant Entity_Id := Find_Top_Unit (Target_Id);
7690 function Find_Preelaboration_Pragma
7691 (Prag_Nam : Name_Id) return Node_Id;
7692 pragma Inline (Find_Preelaboration_Pragma);
7693 -- Traverse the visible declarations of unit Unit_Id and locate a source
7694 -- preelaboration-related pragma with name Prag_Nam.
7696 procedure Info_Requirement_Met (Prag : Node_Id);
7697 pragma Inline (Info_Requirement_Met);
7698 -- Output information concerning pragma Prag which meets requirement
7699 -- Req_Nam.
7701 procedure Info_Scenario;
7702 pragma Inline (Info_Scenario);
7703 -- Output information concerning scenario N
7705 --------------------------------
7706 -- Find_Preelaboration_Pragma --
7707 --------------------------------
7709 function Find_Preelaboration_Pragma
7710 (Prag_Nam : Name_Id) return Node_Id
7712 Spec : constant Node_Id := Parent (Unit_Id);
7713 Decl : Node_Id;
7715 begin
7716 -- A preelaboration-related pragma comes from source and appears at
7717 -- the top of the visible declarations of a package.
7719 if Nkind (Spec) = N_Package_Specification then
7720 Decl := First (Visible_Declarations (Spec));
7721 while Present (Decl) loop
7722 if Comes_From_Source (Decl) then
7723 if Nkind (Decl) = N_Pragma
7724 and then Pragma_Name (Decl) = Prag_Nam
7725 then
7726 return Decl;
7728 -- Otherwise the construct terminates the region where the
7729 -- preelabortion-related pragma may appear.
7731 else
7732 exit;
7733 end if;
7734 end if;
7736 Next (Decl);
7737 end loop;
7738 end if;
7740 return Empty;
7741 end Find_Preelaboration_Pragma;
7743 --------------------------
7744 -- Info_Requirement_Met --
7745 --------------------------
7747 procedure Info_Requirement_Met (Prag : Node_Id) is
7748 begin
7749 pragma Assert (Present (Prag));
7751 Error_Msg_Name_1 := Req_Nam;
7752 Error_Msg_Sloc := Sloc (Prag);
7753 Error_Msg_NE
7754 ("\\% requirement for unit & met by pragma #", N, Unit_Id);
7755 end Info_Requirement_Met;
7757 -------------------
7758 -- Info_Scenario --
7759 -------------------
7761 procedure Info_Scenario is
7762 begin
7763 if Is_Suitable_Call (N) then
7764 Info_Call
7765 (Call => N,
7766 Target_Id => Target_Id,
7767 Info_Msg => False,
7768 In_SPARK => True);
7770 elsif Is_Suitable_Instantiation (N) then
7771 Info_Instantiation
7772 (Inst => N,
7773 Gen_Id => Target_Id,
7774 Info_Msg => False,
7775 In_SPARK => True);
7777 elsif Is_Suitable_SPARK_Refined_State_Pragma (N) then
7778 Error_Msg_N
7779 ("read of refinement constituents during elaboration in SPARK",
7782 elsif Is_Suitable_Variable_Reference (N) then
7783 Info_Variable_Reference
7784 (Ref => N,
7785 Var_Id => Target_Id,
7786 Info_Msg => False,
7787 In_SPARK => True);
7789 -- No other scenario may impose a requirement on the context of the
7790 -- main unit.
7792 else
7793 pragma Assert (False);
7794 null;
7795 end if;
7796 end Info_Scenario;
7798 -- Local variables
7800 Elab_Attrs : Elaboration_Attributes;
7801 Elab_Nam : Name_Id;
7802 Req_Met : Boolean;
7804 -- Start of processing for Meet_Elaboration_Requirement
7806 begin
7807 pragma Assert (Nam_In (Req_Nam, Name_Elaborate, Name_Elaborate_All));
7809 -- Assume that the requirement has not been met
7811 Req_Met := False;
7813 -- Elaboration requirements are verified only when the static model is
7814 -- in effect because this diagnostic is graph-dependent.
7816 if not Static_Elaboration_Checks then
7817 return;
7819 -- If the target is within the main unit, either at the source level or
7820 -- through an instantiation, then there is no real requirement to meet
7821 -- because the main unit cannot force its own elaboration by means of an
7822 -- Elaborate[_All] pragma. Treat this case as valid coverage.
7824 elsif In_Extended_Main_Code_Unit (Target_Id) then
7825 Req_Met := True;
7827 -- Otherwise the target resides in an external unit
7829 -- The requirement is met when the target comes from an internal unit
7830 -- because such a unit is elaborated prior to a non-internal unit.
7832 elsif In_Internal_Unit (Unit_Id)
7833 and then not In_Internal_Unit (Main_Id)
7834 then
7835 Req_Met := True;
7837 -- The requirement is met when the target comes from a preelaborated
7838 -- unit. This portion must parallel predicate Is_Preelaborated_Unit.
7840 elsif Is_Preelaborated_Unit (Unit_Id) then
7841 Req_Met := True;
7843 -- Output extra information when switch -gnatel (info messages on
7844 -- implicit Elaborate[_All] pragmas.
7846 if Elab_Info_Messages then
7847 if Is_Preelaborated (Unit_Id) then
7848 Elab_Nam := Name_Preelaborate;
7850 elsif Is_Pure (Unit_Id) then
7851 Elab_Nam := Name_Pure;
7853 elsif Is_Remote_Call_Interface (Unit_Id) then
7854 Elab_Nam := Name_Remote_Call_Interface;
7856 elsif Is_Remote_Types (Unit_Id) then
7857 Elab_Nam := Name_Remote_Types;
7859 else
7860 pragma Assert (Is_Shared_Passive (Unit_Id));
7861 Elab_Nam := Name_Shared_Passive;
7862 end if;
7864 Info_Requirement_Met (Find_Preelaboration_Pragma (Elab_Nam));
7865 end if;
7867 -- Determine whether the context of the main unit has a pragma strong
7868 -- enough to meet the requirement.
7870 else
7871 Elab_Attrs := Elaboration_Status (Unit_Id);
7873 -- The pragma must be either Elaborate_All or be as strong as the
7874 -- requirement.
7876 if Present (Elab_Attrs.Source_Pragma)
7877 and then Nam_In (Pragma_Name (Elab_Attrs.Source_Pragma),
7878 Name_Elaborate_All,
7879 Req_Nam)
7880 then
7881 Req_Met := True;
7883 -- Output extra information when switch -gnatel (info messages on
7884 -- implicit Elaborate[_All] pragmas.
7886 if Elab_Info_Messages then
7887 Info_Requirement_Met (Elab_Attrs.Source_Pragma);
7888 end if;
7889 end if;
7890 end if;
7892 -- The requirement was not met by the context of the main unit, issue an
7893 -- error.
7895 if not Req_Met then
7896 Info_Scenario;
7898 Error_Msg_Name_1 := Req_Nam;
7899 Error_Msg_Node_2 := Unit_Id;
7900 Error_Msg_NE ("\\unit & requires pragma % for &", N, Main_Id);
7902 Output_Active_Scenarios (N);
7903 end if;
7904 end Meet_Elaboration_Requirement;
7906 ----------------------
7907 -- Non_Private_View --
7908 ----------------------
7910 function Non_Private_View (Typ : Entity_Id) return Entity_Id is
7911 Result : Entity_Id;
7913 begin
7914 Result := Typ;
7916 if Is_Private_Type (Result) and then Present (Full_View (Result)) then
7917 Result := Full_View (Result);
7918 end if;
7920 return Result;
7921 end Non_Private_View;
7923 -----------------------------
7924 -- Output_Active_Scenarios --
7925 -----------------------------
7927 procedure Output_Active_Scenarios (Error_Nod : Node_Id) is
7928 procedure Output_Access (N : Node_Id);
7929 -- Emit a specific diagnostic message for 'Access denote by N
7931 procedure Output_Activation_Call (N : Node_Id);
7932 -- Emit a specific diagnostic message for task activation N
7934 procedure Output_Call (N : Node_Id; Target_Id : Entity_Id);
7935 -- Emit a specific diagnostic message for call N which invokes target
7936 -- Target_Id.
7938 procedure Output_Header;
7939 -- Emit a specific diagnostic message for the unit of the root scenario
7941 procedure Output_Instantiation (N : Node_Id);
7942 -- Emit a specific diagnostic message for instantiation N
7944 procedure Output_SPARK_Refined_State_Pragma (N : Node_Id);
7945 -- Emit a specific diagnostic message for Refined_State pragma N
7947 procedure Output_Variable_Assignment (N : Node_Id);
7948 -- Emit a specific diagnostic message for assignment statement N
7950 procedure Output_Variable_Reference (N : Node_Id);
7951 -- Emit a specific diagnostic message for reference N which mentions a
7952 -- variable.
7954 -------------------
7955 -- Output_Access --
7956 -------------------
7958 procedure Output_Access (N : Node_Id) is
7959 Subp_Id : constant Entity_Id := Entity (Prefix (N));
7961 begin
7962 Error_Msg_Name_1 := Attribute_Name (N);
7963 Error_Msg_Sloc := Sloc (N);
7964 Error_Msg_NE ("\\ % of & taken #", Error_Nod, Subp_Id);
7965 end Output_Access;
7967 ----------------------------
7968 -- Output_Activation_Call --
7969 ----------------------------
7971 procedure Output_Activation_Call (N : Node_Id) is
7972 function Find_Activator (Call : Node_Id) return Entity_Id;
7973 -- Find the nearest enclosing construct which houses call Call
7975 --------------------
7976 -- Find_Activator --
7977 --------------------
7979 function Find_Activator (Call : Node_Id) return Entity_Id is
7980 Par : Node_Id;
7982 begin
7983 -- Climb the parent chain looking for a package [body] or a
7984 -- construct with a statement sequence.
7986 Par := Parent (Call);
7987 while Present (Par) loop
7988 if Nkind_In (Par, N_Package_Body, N_Package_Declaration) then
7989 return Defining_Entity (Par);
7991 elsif Nkind (Par) = N_Handled_Sequence_Of_Statements then
7992 return Defining_Entity (Parent (Par));
7993 end if;
7995 Par := Parent (Par);
7996 end loop;
7998 return Empty;
7999 end Find_Activator;
8001 -- Local variables
8003 Activator : constant Entity_Id := Find_Activator (N);
8005 -- Start of processing for Output_Activation_Call
8007 begin
8008 pragma Assert (Present (Activator));
8010 Error_Msg_NE ("\\ local tasks of & activated", Error_Nod, Activator);
8011 end Output_Activation_Call;
8013 -----------------
8014 -- Output_Call --
8015 -----------------
8017 procedure Output_Call (N : Node_Id; Target_Id : Entity_Id) is
8018 procedure Output_Accept_Alternative;
8019 pragma Inline (Output_Accept_Alternative);
8020 -- Emit a specific diagnostic message concerning an accept
8021 -- alternative.
8023 procedure Output_Call (Kind : String);
8024 pragma Inline (Output_Call);
8025 -- Emit a specific diagnostic message concerning a call of kind Kind
8027 procedure Output_Type_Actions (Action : String);
8028 pragma Inline (Output_Type_Actions);
8029 -- Emit a specific diagnostic message concerning action Action of a
8030 -- type.
8032 procedure Output_Verification_Call
8033 (Pred : String;
8034 Id : Entity_Id;
8035 Id_Kind : String);
8036 pragma Inline (Output_Verification_Call);
8037 -- Emit a specific diagnostic message concerning the verification of
8038 -- predicate Pred applied to related entity Id with kind Id_Kind.
8040 -------------------------------
8041 -- Output_Accept_Alternative --
8042 -------------------------------
8044 procedure Output_Accept_Alternative is
8045 Entry_Id : constant Entity_Id := Receiving_Entry (Target_Id);
8047 begin
8048 pragma Assert (Present (Entry_Id));
8050 Error_Msg_NE ("\\ entry & selected #", Error_Nod, Entry_Id);
8051 end Output_Accept_Alternative;
8053 -----------------
8054 -- Output_Call --
8055 -----------------
8057 procedure Output_Call (Kind : String) is
8058 begin
8059 Error_Msg_NE ("\\ " & Kind & " & called #", Error_Nod, Target_Id);
8060 end Output_Call;
8062 -------------------------
8063 -- Output_Type_Actions --
8064 -------------------------
8066 procedure Output_Type_Actions (Action : String) is
8067 Typ : constant Entity_Id := First_Formal_Type (Target_Id);
8069 begin
8070 pragma Assert (Present (Typ));
8072 Error_Msg_NE
8073 ("\\ " & Action & " actions for type & #", Error_Nod, Typ);
8074 end Output_Type_Actions;
8076 ------------------------------
8077 -- Output_Verification_Call --
8078 ------------------------------
8080 procedure Output_Verification_Call
8081 (Pred : String;
8082 Id : Entity_Id;
8083 Id_Kind : String)
8085 begin
8086 pragma Assert (Present (Id));
8088 Error_Msg_NE
8089 ("\\ " & Pred & " of " & Id_Kind & " & verified #",
8090 Error_Nod, Id);
8091 end Output_Verification_Call;
8093 -- Start of processing for Output_Call
8095 begin
8096 Error_Msg_Sloc := Sloc (N);
8098 -- Accept alternative
8100 if Is_Accept_Alternative_Proc (Target_Id) then
8101 Output_Accept_Alternative;
8103 -- Adjustment
8105 elsif Is_TSS (Target_Id, TSS_Deep_Adjust) then
8106 Output_Type_Actions ("adjustment");
8108 -- Default_Initial_Condition
8110 elsif Is_Default_Initial_Condition_Proc (Target_Id) then
8111 Output_Verification_Call
8112 (Pred => "Default_Initial_Condition",
8113 Id => First_Formal_Type (Target_Id),
8114 Id_Kind => "type");
8116 -- Entries
8118 elsif Is_Protected_Entry (Target_Id) then
8119 Output_Call ("entry");
8121 -- Task entry calls are never processed because the entry being
8122 -- invoked does not have a corresponding "body", it has a select. A
8123 -- task entry call appears in the stack of active scenarios for the
8124 -- sole purpose of checking No_Entry_Calls_In_Elaboration_Code and
8125 -- nothing more.
8127 elsif Is_Task_Entry (Target_Id) then
8128 null;
8130 -- Finalization
8132 elsif Is_TSS (Target_Id, TSS_Deep_Finalize) then
8133 Output_Type_Actions ("finalization");
8135 -- Calls to _Finalizer procedures must not appear in the output
8136 -- because this creates confusing noise.
8138 elsif Is_Finalizer_Proc (Target_Id) then
8139 null;
8141 -- Initial_Condition
8143 elsif Is_Initial_Condition_Proc (Target_Id) then
8144 Output_Verification_Call
8145 (Pred => "Initial_Condition",
8146 Id => Find_Enclosing_Scope (N),
8147 Id_Kind => "package");
8149 -- Initialization
8151 elsif Is_Init_Proc (Target_Id)
8152 or else Is_TSS (Target_Id, TSS_Deep_Initialize)
8153 then
8154 Output_Type_Actions ("initialization");
8156 -- Invariant
8158 elsif Is_Invariant_Proc (Target_Id) then
8159 Output_Verification_Call
8160 (Pred => "invariants",
8161 Id => First_Formal_Type (Target_Id),
8162 Id_Kind => "type");
8164 -- Partial invariant calls must not appear in the output because this
8165 -- creates confusing noise. Note that a partial invariant is always
8166 -- invoked by the "full" invariant which is already placed on the
8167 -- stack.
8169 elsif Is_Partial_Invariant_Proc (Target_Id) then
8170 null;
8172 -- _Postconditions
8174 elsif Is_Postconditions_Proc (Target_Id) then
8175 Output_Verification_Call
8176 (Pred => "postconditions",
8177 Id => Find_Enclosing_Scope (N),
8178 Id_Kind => "subprogram");
8180 -- Subprograms must come last because some of the previous cases fall
8181 -- under this category.
8183 elsif Ekind (Target_Id) = E_Function then
8184 Output_Call ("function");
8186 elsif Ekind (Target_Id) = E_Procedure then
8187 Output_Call ("procedure");
8189 else
8190 pragma Assert (False);
8191 null;
8192 end if;
8193 end Output_Call;
8195 -------------------
8196 -- Output_Header --
8197 -------------------
8199 procedure Output_Header is
8200 Unit_Id : constant Entity_Id := Find_Top_Unit (Root_Scenario);
8202 begin
8203 if Ekind (Unit_Id) = E_Package then
8204 Error_Msg_NE ("\\ spec of unit & elaborated", Error_Nod, Unit_Id);
8206 elsif Ekind (Unit_Id) = E_Package_Body then
8207 Error_Msg_NE ("\\ body of unit & elaborated", Error_Nod, Unit_Id);
8209 else
8210 Error_Msg_NE ("\\ in body of unit &", Error_Nod, Unit_Id);
8211 end if;
8212 end Output_Header;
8214 --------------------------
8215 -- Output_Instantiation --
8216 --------------------------
8218 procedure Output_Instantiation (N : Node_Id) is
8219 procedure Output_Instantiation (Gen_Id : Entity_Id; Kind : String);
8220 pragma Inline (Output_Instantiation);
8221 -- Emit a specific diagnostic message concerning an instantiation of
8222 -- generic unit Gen_Id. Kind denotes the kind of the instantiation.
8224 --------------------------
8225 -- Output_Instantiation --
8226 --------------------------
8228 procedure Output_Instantiation (Gen_Id : Entity_Id; Kind : String) is
8229 begin
8230 Error_Msg_NE
8231 ("\\ " & Kind & " & instantiated as & #", Error_Nod, Gen_Id);
8232 end Output_Instantiation;
8234 -- Local variables
8236 Inst : Node_Id;
8237 Inst_Attrs : Instantiation_Attributes;
8238 Inst_Id : Entity_Id;
8239 Gen_Id : Entity_Id;
8241 -- Start of processing for Output_Instantiation
8243 begin
8244 Extract_Instantiation_Attributes
8245 (Exp_Inst => N,
8246 Inst => Inst,
8247 Inst_Id => Inst_Id,
8248 Gen_Id => Gen_Id,
8249 Attrs => Inst_Attrs);
8251 Error_Msg_Node_2 := Inst_Id;
8252 Error_Msg_Sloc := Sloc (Inst);
8254 if Nkind (Inst) = N_Function_Instantiation then
8255 Output_Instantiation (Gen_Id, "function");
8257 elsif Nkind (Inst) = N_Package_Instantiation then
8258 Output_Instantiation (Gen_Id, "package");
8260 elsif Nkind (Inst) = N_Procedure_Instantiation then
8261 Output_Instantiation (Gen_Id, "procedure");
8263 else
8264 pragma Assert (False);
8265 null;
8266 end if;
8267 end Output_Instantiation;
8269 ---------------------------------------
8270 -- Output_SPARK_Refined_State_Pragma --
8271 ---------------------------------------
8273 procedure Output_SPARK_Refined_State_Pragma (N : Node_Id) is
8274 begin
8275 Error_Msg_Sloc := Sloc (N);
8276 Error_Msg_N ("\\ refinement constituents read #", Error_Nod);
8277 end Output_SPARK_Refined_State_Pragma;
8279 --------------------------------
8280 -- Output_Variable_Assignment --
8281 --------------------------------
8283 procedure Output_Variable_Assignment (N : Node_Id) is
8284 Var_Id : constant Entity_Id := Entity (Extract_Assignment_Name (N));
8286 begin
8287 Error_Msg_Sloc := Sloc (N);
8288 Error_Msg_NE ("\\ variable & assigned #", Error_Nod, Var_Id);
8289 end Output_Variable_Assignment;
8291 -------------------------------
8292 -- Output_Variable_Reference --
8293 -------------------------------
8295 procedure Output_Variable_Reference (N : Node_Id) is
8296 Dummy : Variable_Attributes;
8297 Var_Id : Entity_Id;
8299 begin
8300 Extract_Variable_Reference_Attributes
8301 (Ref => N,
8302 Var_Id => Var_Id,
8303 Attrs => Dummy);
8305 Error_Msg_Sloc := Sloc (N);
8307 if Is_Read (N) then
8308 Error_Msg_NE ("\\ variable & read #", Error_Nod, Var_Id);
8310 else
8311 pragma Assert (False);
8312 null;
8313 end if;
8314 end Output_Variable_Reference;
8316 -- Local variables
8318 package Stack renames Scenario_Stack;
8320 Dummy : Call_Attributes;
8321 N : Node_Id;
8322 Posted : Boolean;
8323 Target_Id : Entity_Id;
8325 -- Start of processing for Output_Active_Scenarios
8327 begin
8328 -- Active scenarios are emitted only when the static model is in effect
8329 -- because there is an inherent order by which all these scenarios were
8330 -- reached from the declaration or library level.
8332 if not Static_Elaboration_Checks then
8333 return;
8334 end if;
8336 Posted := False;
8338 for Index in Stack.First .. Stack.Last loop
8339 N := Stack.Table (Index);
8341 if not Posted then
8342 Posted := True;
8343 Output_Header;
8344 end if;
8346 -- 'Access
8348 if Nkind (N) = N_Attribute_Reference then
8349 Output_Access (N);
8351 -- Calls
8353 elsif Is_Suitable_Call (N) then
8354 Extract_Call_Attributes
8355 (Call => N,
8356 Target_Id => Target_Id,
8357 Attrs => Dummy);
8359 if Is_Activation_Proc (Target_Id) then
8360 Output_Activation_Call (N);
8361 else
8362 Output_Call (N, Target_Id);
8363 end if;
8365 -- Instantiations
8367 elsif Is_Suitable_Instantiation (N) then
8368 Output_Instantiation (N);
8370 -- Pragma Refined_State
8372 elsif Is_Suitable_SPARK_Refined_State_Pragma (N) then
8373 Output_SPARK_Refined_State_Pragma (N);
8375 -- Variable assignments
8377 elsif Nkind (N) = N_Assignment_Statement then
8378 Output_Variable_Assignment (N);
8380 -- Variable references
8382 elsif Is_Suitable_Variable_Reference (N) then
8383 Output_Variable_Reference (N);
8385 else
8386 pragma Assert (False);
8387 null;
8388 end if;
8389 end loop;
8390 end Output_Active_Scenarios;
8392 -------------------------
8393 -- Pop_Active_Scenario --
8394 -------------------------
8396 procedure Pop_Active_Scenario (N : Node_Id) is
8397 Top : Node_Id renames Scenario_Stack.Table (Scenario_Stack.Last);
8399 begin
8400 pragma Assert (Top = N);
8401 Scenario_Stack.Decrement_Last;
8402 end Pop_Active_Scenario;
8404 --------------------------------
8405 -- Process_Activation_Generic --
8406 --------------------------------
8408 procedure Process_Activation_Generic
8409 (Call : Node_Id;
8410 Call_Attrs : Call_Attributes;
8411 State : Processing_Attributes)
8413 procedure Process_Task_Object (Obj_Id : Entity_Id; Typ : Entity_Id);
8414 -- Perform ABE checks and diagnostics for object Obj_Id with type Typ.
8415 -- Typ may be a task type or a composite type with at least one task
8416 -- component.
8418 procedure Process_Task_Objects (List : List_Id);
8419 -- Perform ABE checks and diagnostics for all task objects found in
8420 -- the list List.
8422 -------------------------
8423 -- Process_Task_Object --
8424 -------------------------
8426 procedure Process_Task_Object (Obj_Id : Entity_Id; Typ : Entity_Id) is
8427 Base_Typ : constant Entity_Id := Base_Type (Typ);
8429 Comp_Id : Entity_Id;
8430 Task_Attrs : Task_Attributes;
8432 begin
8433 if Is_Task_Type (Typ) then
8434 Extract_Task_Attributes
8435 (Typ => Base_Typ,
8436 Attrs => Task_Attrs);
8438 Process_Single_Activation
8439 (Call => Call,
8440 Call_Attrs => Call_Attrs,
8441 Obj_Id => Obj_Id,
8442 Task_Attrs => Task_Attrs,
8443 State => State);
8445 -- Examine the component type when the object is an array
8447 elsif Is_Array_Type (Typ) and then Has_Task (Base_Typ) then
8448 Process_Task_Object (Obj_Id, Component_Type (Typ));
8450 -- Examine individual component types when the object is a record
8452 elsif Is_Record_Type (Typ) and then Has_Task (Base_Typ) then
8453 Comp_Id := First_Component (Typ);
8454 while Present (Comp_Id) loop
8455 Process_Task_Object (Obj_Id, Etype (Comp_Id));
8456 Next_Component (Comp_Id);
8457 end loop;
8458 end if;
8459 end Process_Task_Object;
8461 --------------------------
8462 -- Process_Task_Objects --
8463 --------------------------
8465 procedure Process_Task_Objects (List : List_Id) is
8466 Item : Node_Id;
8467 Item_Id : Entity_Id;
8468 Item_Typ : Entity_Id;
8470 begin
8471 -- Examine the contents of the list looking for an object declaration
8472 -- of a task type or one that contains a task within.
8474 Item := First (List);
8475 while Present (Item) loop
8476 if Nkind (Item) = N_Object_Declaration then
8477 Item_Id := Defining_Entity (Item);
8478 Item_Typ := Etype (Item_Id);
8480 if Has_Task (Item_Typ) then
8481 Process_Task_Object (Item_Id, Item_Typ);
8482 end if;
8483 end if;
8485 Next (Item);
8486 end loop;
8487 end Process_Task_Objects;
8489 -- Local variables
8491 Context : Node_Id;
8492 Spec : Node_Id;
8494 -- Start of processing for Process_Activation_Generic
8496 begin
8497 -- Nothing to do when the activation is a guaranteed ABE
8499 if Is_Known_Guaranteed_ABE (Call) then
8500 return;
8501 end if;
8503 -- Find the proper context of the activation call where all task objects
8504 -- being activated are declared. This is usually the immediate parent of
8505 -- the call.
8507 Context := Parent (Call);
8509 -- In the case of package bodies, the activation call is in the handled
8510 -- sequence of statements, but the task objects are in the declaration
8511 -- list of the body.
8513 if Nkind (Context) = N_Handled_Sequence_Of_Statements
8514 and then Nkind (Parent (Context)) = N_Package_Body
8515 then
8516 Context := Parent (Context);
8517 end if;
8519 -- Process all task objects defined in both the spec and body when the
8520 -- activation call precedes the "begin" of a package body.
8522 if Nkind (Context) = N_Package_Body then
8523 Spec :=
8524 Specification
8525 (Unit_Declaration_Node (Corresponding_Spec (Context)));
8527 Process_Task_Objects (Visible_Declarations (Spec));
8528 Process_Task_Objects (Private_Declarations (Spec));
8529 Process_Task_Objects (Declarations (Context));
8531 -- Process all task objects defined in the spec when the activation call
8532 -- appears at the end of a package spec.
8534 elsif Nkind (Context) = N_Package_Specification then
8535 Process_Task_Objects (Visible_Declarations (Context));
8536 Process_Task_Objects (Private_Declarations (Context));
8538 -- Otherwise the context of the activation is some construct with a
8539 -- declarative part. Note that the corresponding record type of a task
8540 -- type is controlled. Because of this, the finalization machinery must
8541 -- relocate the task object to the handled statements of the construct
8542 -- to perform proper finalization in case of an exception. Examine the
8543 -- statements of the construct rather than the declarations.
8545 else
8546 pragma Assert (Nkind (Context) = N_Handled_Sequence_Of_Statements);
8548 Process_Task_Objects (Statements (Context));
8549 end if;
8550 end Process_Activation_Generic;
8552 ------------------------------------
8553 -- Process_Conditional_ABE_Access --
8554 ------------------------------------
8556 procedure Process_Conditional_ABE_Access
8557 (Attr : Node_Id;
8558 State : Processing_Attributes)
8560 function Build_Access_Marker (Target_Id : Entity_Id) return Node_Id;
8561 pragma Inline (Build_Access_Marker);
8562 -- Create a suitable call marker which invokes target Target_Id
8564 -------------------------
8565 -- Build_Access_Marker --
8566 -------------------------
8568 function Build_Access_Marker (Target_Id : Entity_Id) return Node_Id is
8569 Marker : Node_Id;
8571 begin
8572 Marker := Make_Call_Marker (Sloc (Attr));
8574 -- Inherit relevant attributes from the attribute
8576 -- Performance note: parent traversal
8578 Set_Target (Marker, Target_Id);
8579 Set_Is_Declaration_Level_Node
8580 (Marker, Find_Enclosing_Level (Attr) = Declaration_Level);
8581 Set_Is_Dispatching_Call
8582 (Marker, False);
8583 Set_Is_Elaboration_Checks_OK_Node
8584 (Marker, Is_Elaboration_Checks_OK_Node (Attr));
8585 Set_Is_Source_Call
8586 (Marker, Comes_From_Source (Attr));
8587 Set_Is_SPARK_Mode_On_Node
8588 (Marker, Is_SPARK_Mode_On_Node (Attr));
8590 -- Partially insert the call marker into the tree by setting its
8591 -- parent pointer.
8593 Set_Parent (Marker, Attr);
8595 return Marker;
8596 end Build_Access_Marker;
8598 -- Local variables
8600 Root : constant Node_Id := Root_Scenario;
8601 Target_Id : constant Entity_Id := Entity (Prefix (Attr));
8603 Target_Attrs : Target_Attributes;
8605 -- Start of processing for Process_Conditional_ABE_Access
8607 begin
8608 -- Output relevant information when switch -gnatel (info messages on
8609 -- implicit Elaborate[_All] pragmas) is in effect.
8611 if Elab_Info_Messages then
8612 Error_Msg_NE
8613 ("info: access to & during elaboration", Attr, Target_Id);
8614 end if;
8616 Extract_Target_Attributes
8617 (Target_Id => Target_Id,
8618 Attrs => Target_Attrs);
8620 -- Both the attribute and the corresponding body are in the same unit.
8621 -- The corresponding body must appear prior to the root scenario which
8622 -- started the recursive search. If this is not the case, then there is
8623 -- a potential ABE if the access value is used to call the subprogram.
8624 -- Emit a warning only when switch -gnatw.f (warnings on suspucious
8625 -- 'Access) is in effect.
8627 if Warn_On_Elab_Access
8628 and then Present (Target_Attrs.Body_Decl)
8629 and then In_Extended_Main_Code_Unit (Target_Attrs.Body_Decl)
8630 and then Earlier_In_Extended_Unit (Root, Target_Attrs.Body_Decl)
8631 then
8632 Error_Msg_Name_1 := Attribute_Name (Attr);
8633 Error_Msg_NE ("??% attribute of & before body seen", Attr, Target_Id);
8634 Error_Msg_N ("\possible Program_Error on later references", Attr);
8636 Output_Active_Scenarios (Attr);
8637 end if;
8639 -- Treat the attribute as an immediate invocation of the target when
8640 -- switch -gnatd.o (conservative elaboration order for indirect calls)
8641 -- is in effect. Note that the prior elaboration of the unit containing
8642 -- the target is ensured processing the corresponding call marker.
8644 if Debug_Flag_Dot_O then
8645 Process_Conditional_ABE
8646 (N => Build_Access_Marker (Target_Id),
8647 State => State);
8649 -- Otherwise ensure that the unit with the corresponding body is
8650 -- elaborated prior to the main unit.
8652 else
8653 Ensure_Prior_Elaboration
8654 (N => Attr,
8655 Unit_Id => Target_Attrs.Unit_Id,
8656 Prag_Nam => Name_Elaborate_All,
8657 State => State);
8658 end if;
8659 end Process_Conditional_ABE_Access;
8661 ---------------------------------------------
8662 -- Process_Conditional_ABE_Activation_Impl --
8663 ---------------------------------------------
8665 procedure Process_Conditional_ABE_Activation_Impl
8666 (Call : Node_Id;
8667 Call_Attrs : Call_Attributes;
8668 Obj_Id : Entity_Id;
8669 Task_Attrs : Task_Attributes;
8670 State : Processing_Attributes)
8672 Check_OK : constant Boolean :=
8673 not Is_Ignored_Ghost_Entity (Obj_Id)
8674 and then not Task_Attrs.Ghost_Mode_Ignore
8675 and then Is_Elaboration_Checks_OK_Id (Obj_Id)
8676 and then Task_Attrs.Elab_Checks_OK;
8677 -- A run-time ABE check may be installed only when the object and the
8678 -- task type have active elaboration checks, and both are not ignored
8679 -- Ghost constructs.
8681 Root : constant Node_Id := Root_Scenario;
8683 New_State : Processing_Attributes := State;
8684 -- Each step of the Processing phase constitutes a new state
8686 begin
8687 -- Output relevant information when switch -gnatel (info messages on
8688 -- implicit Elaborate[_All] pragmas) is in effect.
8690 if Elab_Info_Messages then
8691 Error_Msg_NE
8692 ("info: activation of & during elaboration", Call, Obj_Id);
8693 end if;
8695 -- Nothing to do when the call activates a task whose type is defined
8696 -- within an instance and switch -gnatd_i (ignore activations and calls
8697 -- to instances for elaboration) is in effect.
8699 if Debug_Flag_Underscore_I
8700 and then In_External_Instance
8701 (N => Call,
8702 Target_Decl => Task_Attrs.Task_Decl)
8703 then
8704 return;
8706 -- Nothing to do when the activation is a guaranteed ABE
8708 elsif Is_Known_Guaranteed_ABE (Call) then
8709 return;
8711 -- Nothing to do when the root scenario appears at the declaration
8712 -- level and the task is in the same unit, but outside this context.
8714 -- task type Task_Typ; -- task declaration
8716 -- procedure Proc is
8717 -- function A ... is
8718 -- begin
8719 -- if Some_Condition then
8720 -- declare
8721 -- T : Task_Typ;
8722 -- begin
8723 -- <activation call> -- activation site
8724 -- end;
8725 -- ...
8726 -- end A;
8728 -- X : ... := A; -- root scenario
8729 -- ...
8731 -- task body Task_Typ is
8732 -- ...
8733 -- end Task_Typ;
8735 -- In the example above, the context of X is the declarative list of
8736 -- Proc. The "elaboration" of X may reach the activation of T whose body
8737 -- is defined outside of X's context. The task body is relevant only
8738 -- when Proc is invoked, but this happens only in "normal" elaboration,
8739 -- therefore the task body must not be considered if this is not the
8740 -- case.
8742 -- Performance note: parent traversal
8744 elsif Is_Up_Level_Target (Task_Attrs.Task_Decl) then
8745 return;
8747 -- Nothing to do when the activation is ABE-safe
8749 -- generic
8750 -- package Gen is
8751 -- task type Task_Typ;
8752 -- end Gen;
8754 -- package body Gen is
8755 -- task body Task_Typ is
8756 -- begin
8757 -- ...
8758 -- end Task_Typ;
8759 -- end Gen;
8761 -- with Gen;
8762 -- procedure Main is
8763 -- package Nested is
8764 -- package Inst is new Gen;
8765 -- T : Inst.Task_Typ;
8766 -- <activation call> -- safe activation
8767 -- end Nested;
8768 -- ...
8770 elsif Is_Safe_Activation (Call, Task_Attrs.Task_Decl) then
8772 -- Note that the task body must still be examined for any nested
8773 -- scenarios.
8775 null;
8777 -- The activation call and the task body are both in the main unit
8779 elsif Present (Task_Attrs.Body_Decl)
8780 and then In_Extended_Main_Code_Unit (Task_Attrs.Body_Decl)
8781 then
8782 -- If the root scenario appears prior to the task body, then this is
8783 -- a possible ABE with respect to the root scenario.
8785 -- task type Task_Typ;
8787 -- function A ... is
8788 -- begin
8789 -- if Some_Condition then
8790 -- declare
8791 -- package Pack is
8792 -- T : Task_Typ;
8793 -- end Pack; -- activation of T
8794 -- ...
8795 -- end A;
8797 -- X : ... := A; -- root scenario
8799 -- task body Task_Typ is -- task body
8800 -- ...
8801 -- end Task_Typ;
8803 -- Y : ... := A; -- root scenario
8805 -- IMPORTANT: The activation of T is a possible ABE for X, but
8806 -- not for Y. Intalling an unconditional ABE raise prior to the
8807 -- activation call would be wrong as it will fail for Y as well
8808 -- but in Y's case the activation of T is never an ABE.
8810 if Earlier_In_Extended_Unit (Root, Task_Attrs.Body_Decl) then
8812 -- Do not emit any ABE diagnostics when the activation occurs in
8813 -- a partial finalization context because this leads to confusing
8814 -- noise.
8816 if State.Within_Partial_Finalization then
8817 null;
8819 -- ABE diagnostics are emitted only in the static model because
8820 -- there is a well-defined order to visiting scenarios. Without
8821 -- this order diagnostics appear jumbled and result in unwanted
8822 -- noise.
8824 elsif Static_Elaboration_Checks
8825 and then Call_Attrs.Elab_Warnings_OK
8826 then
8827 Error_Msg_Sloc := Sloc (Call);
8828 Error_Msg_N
8829 ("??task & will be activated # before elaboration of its "
8830 & "body", Obj_Id);
8831 Error_Msg_N
8832 ("\Program_Error may be raised at run time", Obj_Id);
8834 Output_Active_Scenarios (Obj_Id);
8835 end if;
8837 -- Install a conditional run-time ABE check to verify that the
8838 -- task body has been elaborated prior to the activation call.
8840 if Check_OK then
8841 Install_ABE_Check
8842 (N => Call,
8843 Ins_Nod => Call,
8844 Target_Id => Task_Attrs.Spec_Id,
8845 Target_Decl => Task_Attrs.Task_Decl,
8846 Target_Body => Task_Attrs.Body_Decl);
8848 -- Update the state of the Processing phase to indicate that
8849 -- no implicit Elaborate[_All] pragmas must be generated from
8850 -- this point on.
8852 -- task type Task_Typ;
8854 -- function A ... is
8855 -- begin
8856 -- if Some_Condition then
8857 -- declare
8858 -- package Pack is
8859 -- <ABE check>
8860 -- T : Task_Typ;
8861 -- end Pack; -- activation of T
8862 -- ...
8863 -- end A;
8865 -- X : ... := A;
8867 -- task body Task_Typ is
8868 -- begin
8869 -- External.Subp; -- imparts Elaborate_All
8870 -- end Task_Typ;
8872 -- If Some_Condition is True, then the ABE check will fail at
8873 -- runtime and the call to External.Subp will never take place,
8874 -- rendering the implicit Elaborate_All useless.
8876 -- If Some_Condition is False, then the call to External.Subp
8877 -- will never take place, rendering the implicit Elaborate_All
8878 -- useless.
8880 New_State.Suppress_Implicit_Pragmas := True;
8881 end if;
8882 end if;
8884 -- Otherwise the task body is not available in this compilation or it
8885 -- resides in an external unit. Install a run-time ABE check to verify
8886 -- that the task body has been elaborated prior to the activation call
8887 -- when the dynamic model is in effect.
8889 elsif Dynamic_Elaboration_Checks and then Check_OK then
8890 Install_ABE_Check
8891 (N => Call,
8892 Ins_Nod => Call,
8893 Id => Task_Attrs.Unit_Id);
8894 end if;
8896 -- Update the state of the Processing phase to indicate that any further
8897 -- traversal is now within a task body.
8899 New_State.Within_Task_Body := True;
8901 -- Both the activation call and task type are subject to SPARK_Mode
8902 -- On, this triggers the SPARK rules for task activation. Compared to
8903 -- calls and instantiations, task activation in SPARK does not require
8904 -- the presence of Elaborate[_All] pragmas in case the task type is
8905 -- defined outside the main unit. This is because SPARK utilizes a
8906 -- special policy which activates all tasks after the main unit has
8907 -- finished its elaboration.
8909 if Call_Attrs.SPARK_Mode_On and Task_Attrs.SPARK_Mode_On then
8910 null;
8912 -- Otherwise the Ada rules are in effect. Ensure that the unit with the
8913 -- task body is elaborated prior to the main unit.
8915 else
8916 Ensure_Prior_Elaboration
8917 (N => Call,
8918 Unit_Id => Task_Attrs.Unit_Id,
8919 Prag_Nam => Name_Elaborate_All,
8920 State => New_State);
8921 end if;
8923 Traverse_Body
8924 (N => Task_Attrs.Body_Decl,
8925 State => New_State);
8926 end Process_Conditional_ABE_Activation_Impl;
8928 procedure Process_Conditional_ABE_Activation is
8929 new Process_Activation_Generic (Process_Conditional_ABE_Activation_Impl);
8931 ----------------------------------
8932 -- Process_Conditional_ABE_Call --
8933 ----------------------------------
8935 procedure Process_Conditional_ABE_Call
8936 (Call : Node_Id;
8937 Call_Attrs : Call_Attributes;
8938 Target_Id : Entity_Id;
8939 State : Processing_Attributes)
8941 function In_Initialization_Context (N : Node_Id) return Boolean;
8942 -- Determine whether arbitrary node N appears within a type init proc,
8943 -- primitive [Deep_]Initialize, or a block created for initialization
8944 -- purposes.
8946 function Is_Partial_Finalization_Proc return Boolean;
8947 pragma Inline (Is_Partial_Finalization_Proc);
8948 -- Determine whether call Call with target Target_Id invokes a partial
8949 -- finalization procedure.
8951 -------------------------------
8952 -- In_Initialization_Context --
8953 -------------------------------
8955 function In_Initialization_Context (N : Node_Id) return Boolean is
8956 Par : Node_Id;
8957 Spec_Id : Entity_Id;
8959 begin
8960 -- Climb the parent chain looking for initialization actions
8962 Par := Parent (N);
8963 while Present (Par) loop
8965 -- A block may be part of the initialization actions of a default
8966 -- initialized object.
8968 if Nkind (Par) = N_Block_Statement
8969 and then Is_Initialization_Block (Par)
8970 then
8971 return True;
8973 -- A subprogram body may denote an initialization routine
8975 elsif Nkind (Par) = N_Subprogram_Body then
8976 Spec_Id := Unique_Defining_Entity (Par);
8978 -- The current subprogram body denotes a type init proc or
8979 -- primitive [Deep_]Initialize.
8981 if Is_Init_Proc (Spec_Id)
8982 or else Is_Controlled_Proc (Spec_Id, Name_Initialize)
8983 or else Is_TSS (Spec_Id, TSS_Deep_Initialize)
8984 then
8985 return True;
8986 end if;
8988 -- Prevent the search from going too far
8990 elsif Is_Body_Or_Package_Declaration (Par) then
8991 exit;
8992 end if;
8994 Par := Parent (Par);
8995 end loop;
8997 return False;
8998 end In_Initialization_Context;
9000 ----------------------------------
9001 -- Is_Partial_Finalization_Proc --
9002 ----------------------------------
9004 function Is_Partial_Finalization_Proc return Boolean is
9005 begin
9006 -- To qualify, the target must denote primitive [Deep_]Finalize or a
9007 -- finalizer procedure, and the call must appear in an initialization
9008 -- context.
9010 return
9011 (Is_Controlled_Proc (Target_Id, Name_Finalize)
9012 or else Is_Finalizer_Proc (Target_Id)
9013 or else Is_TSS (Target_Id, TSS_Deep_Finalize))
9014 and then In_Initialization_Context (Call);
9015 end Is_Partial_Finalization_Proc;
9017 -- Local variables
9019 SPARK_Rules_On : Boolean;
9020 Target_Attrs : Target_Attributes;
9022 New_State : Processing_Attributes := State;
9023 -- Each step of the Processing phase constitutes a new state
9025 -- Start of processing for Process_Conditional_ABE_Call
9027 begin
9028 Extract_Target_Attributes
9029 (Target_Id => Target_Id,
9030 Attrs => Target_Attrs);
9032 -- The SPARK rules are in effect when both the call and target are
9033 -- subject to SPARK_Mode On.
9035 SPARK_Rules_On :=
9036 Call_Attrs.SPARK_Mode_On and Target_Attrs.SPARK_Mode_On;
9038 -- Output relevant information when switch -gnatel (info messages on
9039 -- implicit Elaborate[_All] pragmas) is in effect.
9041 if Elab_Info_Messages then
9042 Info_Call
9043 (Call => Call,
9044 Target_Id => Target_Id,
9045 Info_Msg => True,
9046 In_SPARK => SPARK_Rules_On);
9047 end if;
9049 -- Check whether the invocation of an entry clashes with an existing
9050 -- restriction.
9052 if Is_Protected_Entry (Target_Id) then
9053 Check_Restriction (No_Entry_Calls_In_Elaboration_Code, Call);
9055 elsif Is_Task_Entry (Target_Id) then
9056 Check_Restriction (No_Entry_Calls_In_Elaboration_Code, Call);
9058 -- Task entry calls are never processed because the entry being
9059 -- invoked does not have a corresponding "body", it has a select.
9061 return;
9062 end if;
9064 -- Nothing to do when the call invokes a target defined within an
9065 -- instance and switch -gnatd_i (ignore activations and calls to
9066 -- instances for elaboration) is in effect.
9068 if Debug_Flag_Underscore_I
9069 and then In_External_Instance
9070 (N => Call,
9071 Target_Decl => Target_Attrs.Spec_Decl)
9072 then
9073 return;
9075 -- Nothing to do when the call is a guaranteed ABE
9077 elsif Is_Known_Guaranteed_ABE (Call) then
9078 return;
9080 -- Nothing to do when the root scenario appears at the declaration level
9081 -- and the target is in the same unit, but outside this context.
9083 -- function B ...; -- target declaration
9085 -- procedure Proc is
9086 -- function A ... is
9087 -- begin
9088 -- if Some_Condition then
9089 -- return B; -- call site
9090 -- ...
9091 -- end A;
9093 -- X : ... := A; -- root scenario
9094 -- ...
9096 -- function B ... is
9097 -- ...
9098 -- end B;
9100 -- In the example above, the context of X is the declarative region of
9101 -- Proc. The "elaboration" of X may eventually reach B which is defined
9102 -- outside of X's context. B is relevant only when Proc is invoked, but
9103 -- this happens only by means of "normal" elaboration, therefore B must
9104 -- not be considered if this is not the case.
9106 -- Performance note: parent traversal
9108 elsif Is_Up_Level_Target (Target_Attrs.Spec_Decl) then
9109 return;
9110 end if;
9112 -- The call occurs in an initial condition context when a prior scenario
9113 -- is already in that mode, or when the target is an Initial_Condition
9114 -- procedure. Update the state of the Processing phase to reflect this.
9116 New_State.Within_Initial_Condition :=
9117 New_State.Within_Initial_Condition
9118 or else Is_Initial_Condition_Proc (Target_Id);
9120 -- The call occurs in a partial finalization context when a prior
9121 -- scenario is already in that mode, or when the target denotes a
9122 -- [Deep_]Finalize primitive or a finalizer within an initialization
9123 -- context. Update the state of the Processing phase to reflect this.
9125 New_State.Within_Partial_Finalization :=
9126 New_State.Within_Partial_Finalization
9127 or else Is_Partial_Finalization_Proc;
9129 -- The SPARK rules are in effect. Note that -gnatd.v (enforce SPARK
9130 -- elaboration rules in SPARK code) is intentionally not taken into
9131 -- account here because Process_Conditional_ABE_Call_SPARK has two
9132 -- separate modes of operation.
9134 if SPARK_Rules_On then
9135 Process_Conditional_ABE_Call_SPARK
9136 (Call => Call,
9137 Target_Id => Target_Id,
9138 Target_Attrs => Target_Attrs,
9139 State => New_State);
9141 -- Otherwise the Ada rules are in effect
9143 else
9144 Process_Conditional_ABE_Call_Ada
9145 (Call => Call,
9146 Call_Attrs => Call_Attrs,
9147 Target_Id => Target_Id,
9148 Target_Attrs => Target_Attrs,
9149 State => New_State);
9150 end if;
9152 -- Inspect the target body (and barried function) for other suitable
9153 -- elaboration scenarios.
9155 Traverse_Body
9156 (N => Target_Attrs.Body_Barf,
9157 State => New_State);
9159 Traverse_Body
9160 (N => Target_Attrs.Body_Decl,
9161 State => New_State);
9162 end Process_Conditional_ABE_Call;
9164 --------------------------------------
9165 -- Process_Conditional_ABE_Call_Ada --
9166 --------------------------------------
9168 procedure Process_Conditional_ABE_Call_Ada
9169 (Call : Node_Id;
9170 Call_Attrs : Call_Attributes;
9171 Target_Id : Entity_Id;
9172 Target_Attrs : Target_Attributes;
9173 State : Processing_Attributes)
9175 Check_OK : constant Boolean :=
9176 not Call_Attrs.Ghost_Mode_Ignore
9177 and then not Target_Attrs.Ghost_Mode_Ignore
9178 and then Call_Attrs.Elab_Checks_OK
9179 and then Target_Attrs.Elab_Checks_OK;
9180 -- A run-time ABE check may be installed only when both the call and the
9181 -- target have active elaboration checks, and both are not ignored Ghost
9182 -- constructs.
9184 Root : constant Node_Id := Root_Scenario;
9186 New_State : Processing_Attributes := State;
9187 -- Each step of the Processing phase constitutes a new state
9189 begin
9190 -- Nothing to do for an Ada dispatching call because there are no ABE
9191 -- diagnostics for either models. ABE checks for the dynamic model are
9192 -- handled by Install_Primitive_Elaboration_Check.
9194 if Call_Attrs.Is_Dispatching then
9195 return;
9197 -- Nothing to do when the call is ABE-safe
9199 -- generic
9200 -- function Gen ...;
9202 -- function Gen ... is
9203 -- begin
9204 -- ...
9205 -- end Gen;
9207 -- with Gen;
9208 -- procedure Main is
9209 -- function Inst is new Gen;
9210 -- X : ... := Inst; -- safe call
9211 -- ...
9213 elsif Is_Safe_Call (Call, Target_Attrs) then
9214 return;
9216 -- The call and the target body are both in the main unit
9218 elsif Present (Target_Attrs.Body_Decl)
9219 and then In_Extended_Main_Code_Unit (Target_Attrs.Body_Decl)
9220 then
9221 -- If the root scenario appears prior to the target body, then this
9222 -- is a possible ABE with respect to the root scenario.
9224 -- function B ...;
9226 -- function A ... is
9227 -- begin
9228 -- if Some_Condition then
9229 -- return B; -- call site
9230 -- ...
9231 -- end A;
9233 -- X : ... := A; -- root scenario
9235 -- function B ... is -- target body
9236 -- ...
9237 -- end B;
9239 -- Y : ... := A; -- root scenario
9241 -- IMPORTANT: The call to B from A is a possible ABE for X, but not
9242 -- for Y. Installing an unconditional ABE raise prior to the call to
9243 -- B would be wrong as it will fail for Y as well, but in Y's case
9244 -- the call to B is never an ABE.
9246 if Earlier_In_Extended_Unit (Root, Target_Attrs.Body_Decl) then
9248 -- Do not emit any ABE diagnostics when the call occurs in a
9249 -- partial finalization context because this leads to confusing
9250 -- noise.
9252 if State.Within_Partial_Finalization then
9253 null;
9255 -- ABE diagnostics are emitted only in the static model because
9256 -- there is a well-defined order to visiting scenarios. Without
9257 -- this order diagnostics appear jumbled and result in unwanted
9258 -- noise.
9260 elsif Static_Elaboration_Checks
9261 and then Call_Attrs.Elab_Warnings_OK
9262 then
9263 Error_Msg_NE
9264 ("??cannot call & before body seen", Call, Target_Id);
9265 Error_Msg_N ("\Program_Error may be raised at run time", Call);
9267 Output_Active_Scenarios (Call);
9268 end if;
9270 -- Install a conditional run-time ABE check to verify that the
9271 -- target body has been elaborated prior to the call.
9273 if Check_OK then
9274 Install_ABE_Check
9275 (N => Call,
9276 Ins_Nod => Call,
9277 Target_Id => Target_Attrs.Spec_Id,
9278 Target_Decl => Target_Attrs.Spec_Decl,
9279 Target_Body => Target_Attrs.Body_Decl);
9281 -- Update the state of the Processing phase to indicate that
9282 -- no implicit Elaborate[_All] pragmas must be generated from
9283 -- this point on.
9285 -- function B ...;
9287 -- function A ... is
9288 -- begin
9289 -- if Some_Condition then
9290 -- <ABE check>
9291 -- return B;
9292 -- ...
9293 -- end A;
9295 -- X : ... := A;
9297 -- function B ... is
9298 -- External.Subp; -- imparts Elaborate_All
9299 -- end B;
9301 -- If Some_Condition is True, then the ABE check will fail at
9302 -- runtime and the call to External.Subp will never take place,
9303 -- rendering the implicit Elaborate_All useless.
9305 -- If Some_Condition is False, then the call to External.Subp
9306 -- will never take place, rendering the implicit Elaborate_All
9307 -- useless.
9309 New_State.Suppress_Implicit_Pragmas := True;
9310 end if;
9311 end if;
9313 -- Otherwise the target body is not available in this compilation or it
9314 -- resides in an external unit. Install a run-time ABE check to verify
9315 -- that the target body has been elaborated prior to the call site when
9316 -- the dynamic model is in effect.
9318 elsif Dynamic_Elaboration_Checks and then Check_OK then
9319 Install_ABE_Check
9320 (N => Call,
9321 Ins_Nod => Call,
9322 Id => Target_Attrs.Unit_Id);
9323 end if;
9325 -- Ensure that the unit with the target body is elaborated prior to the
9326 -- main unit. The implicit Elaborate[_All] is generated only when the
9327 -- call has elaboration checks enabled. This behaviour parallels that of
9328 -- the old ABE mechanism.
9330 if Call_Attrs.Elab_Checks_OK then
9331 Ensure_Prior_Elaboration
9332 (N => Call,
9333 Unit_Id => Target_Attrs.Unit_Id,
9334 Prag_Nam => Name_Elaborate_All,
9335 State => New_State);
9336 end if;
9337 end Process_Conditional_ABE_Call_Ada;
9339 ----------------------------------------
9340 -- Process_Conditional_ABE_Call_SPARK --
9341 ----------------------------------------
9343 procedure Process_Conditional_ABE_Call_SPARK
9344 (Call : Node_Id;
9345 Target_Id : Entity_Id;
9346 Target_Attrs : Target_Attributes;
9347 State : Processing_Attributes)
9349 Region : Node_Id;
9351 begin
9352 -- Ensure that a suitable elaboration model is in effect for SPARK rule
9353 -- verification.
9355 Check_SPARK_Model_In_Effect (Call);
9357 -- The call and the target body are both in the main unit
9359 if Present (Target_Attrs.Body_Decl)
9360 and then In_Extended_Main_Code_Unit (Target_Attrs.Body_Decl)
9361 then
9362 -- If the call appears prior to the target body, then the call must
9363 -- appear within the early call region of the target body.
9365 -- function B ...;
9367 -- X : ... := B; -- call site
9369 -- <preelaborable construct 1> --+
9370 -- ... | early call region
9371 -- <preelaborable construct N> --+
9373 -- function B ... is -- target body
9374 -- ...
9375 -- end B;
9377 -- When the call to B is not nested within some other scenario, the
9378 -- call is automatically illegal because it can never appear in the
9379 -- early call region of B's body. This is equivalent to a guaranteed
9380 -- ABE.
9382 -- <preelaborable construct 1> --+
9383 -- |
9384 -- function B ...; |
9385 -- |
9386 -- function A ... is |
9387 -- begin | early call region
9388 -- if Some_Condition then
9389 -- return B; -- call site
9390 -- ...
9391 -- end A; |
9392 -- |
9393 -- <preelaborable construct N> --+
9395 -- function B ... is -- target body
9396 -- ...
9397 -- end B;
9399 -- When the call to B is nested within some other scenario, the call
9400 -- is always ABE-safe. It is not immediately obvious why this is the
9401 -- case. The elaboration safety follows from the early call region
9402 -- rule being applied to ALL calls preceding their associated bodies.
9404 -- In the example above, the call to B is safe as long as the call to
9405 -- A is safe. There are several cases to consider:
9407 -- <call 1 to A>
9408 -- function B ...;
9410 -- <call 2 to A>
9411 -- function A ... is
9412 -- begin
9413 -- if Some_Condition then
9414 -- return B;
9415 -- ...
9416 -- end A;
9418 -- <call 3 to A>
9419 -- function B ... is
9420 -- ...
9421 -- end B;
9423 -- * Call 1 - This call is either nested within some scenario or not,
9424 -- which falls under the two general cases outlined above.
9426 -- * Call 2 - This is the same case as Call 1.
9428 -- * Call 3 - The placement of this call limits the range of B's
9429 -- early call region unto call 3, therefore the call to B is no
9430 -- longer within the early call region of B's body, making it ABE-
9431 -- unsafe and therefore illegal.
9433 if Earlier_In_Extended_Unit (Call, Target_Attrs.Body_Decl) then
9435 -- Do not emit any ABE diagnostics when the call occurs in an
9436 -- initial condition context because this leads to incorrect
9437 -- diagnostics.
9439 if State.Within_Initial_Condition then
9440 null;
9442 -- Do not emit any ABE diagnostics when the call occurs in a
9443 -- partial finalization context because this leads to confusing
9444 -- noise.
9446 elsif State.Within_Partial_Finalization then
9447 null;
9449 -- ABE diagnostics are emitted only in the static model because
9450 -- there is a well-defined order to visiting scenarios. Without
9451 -- this order diagnostics appear jumbled and result in unwanted
9452 -- noise.
9454 elsif Static_Elaboration_Checks then
9456 -- Ensure that a call which textually precedes the subprogram
9457 -- body it invokes appears within the early call region of the
9458 -- subprogram body.
9460 -- IMPORTANT: This check must always be performed even when
9461 -- -gnatd.v (enforce SPARK elaboration rules in SPARK code) is
9462 -- not specified because the static model cannot guarantee the
9463 -- absence of elaboration issues in the presence of dispatching
9464 -- calls.
9466 Region := Find_Early_Call_Region (Target_Attrs.Body_Decl);
9468 if Earlier_In_Extended_Unit (Call, Region) then
9469 Error_Msg_NE
9470 ("call must appear within early call region of subprogram "
9471 & "body & (SPARK RM 7.7(3))", Call, Target_Id);
9473 Error_Msg_Sloc := Sloc (Region);
9474 Error_Msg_N ("\region starts #", Call);
9476 Error_Msg_Sloc := Sloc (Target_Attrs.Body_Decl);
9477 Error_Msg_N ("\region ends #", Call);
9479 Output_Active_Scenarios (Call);
9480 end if;
9481 end if;
9483 -- Otherwise the call appears after the target body. The call is
9484 -- ABE-safe as a consequence of applying the early call region rule
9485 -- to ALL calls preceding their associated bodies.
9487 else
9488 null;
9489 end if;
9490 end if;
9492 -- A call to a source target or to a target which emulates Ada or SPARK
9493 -- semantics imposes an Elaborate_All requirement on the context of the
9494 -- main unit. Determine whether the context has a pragma strong enough
9495 -- to meet the requirement.
9497 -- IMPORTANT: This check must be performed only when -gnatd.v (enforce
9498 -- SPARK elaboration rules in SPARK code) is active because the static
9499 -- model can ensure the prior elaboration of the unit which contains a
9500 -- body by installing an implicit Elaborate[_All] pragma.
9502 if Debug_Flag_Dot_V then
9503 if Target_Attrs.From_Source
9504 or else Is_Ada_Semantic_Target (Target_Id)
9505 or else Is_SPARK_Semantic_Target (Target_Id)
9506 then
9507 Meet_Elaboration_Requirement
9508 (N => Call,
9509 Target_Id => Target_Id,
9510 Req_Nam => Name_Elaborate_All);
9511 end if;
9513 -- Otherwise ensure that the unit with the target body is elaborated
9514 -- prior to the main unit.
9516 else
9517 Ensure_Prior_Elaboration
9518 (N => Call,
9519 Unit_Id => Target_Attrs.Unit_Id,
9520 Prag_Nam => Name_Elaborate_All,
9521 State => State);
9522 end if;
9523 end Process_Conditional_ABE_Call_SPARK;
9525 -------------------------------------------
9526 -- Process_Conditional_ABE_Instantiation --
9527 -------------------------------------------
9529 procedure Process_Conditional_ABE_Instantiation
9530 (Exp_Inst : Node_Id;
9531 State : Processing_Attributes)
9533 Gen_Attrs : Target_Attributes;
9534 Gen_Id : Entity_Id;
9535 Inst : Node_Id;
9536 Inst_Attrs : Instantiation_Attributes;
9537 Inst_Id : Entity_Id;
9539 SPARK_Rules_On : Boolean;
9540 -- This flag is set when the SPARK rules are in effect
9542 begin
9543 Extract_Instantiation_Attributes
9544 (Exp_Inst => Exp_Inst,
9545 Inst => Inst,
9546 Inst_Id => Inst_Id,
9547 Gen_Id => Gen_Id,
9548 Attrs => Inst_Attrs);
9550 Extract_Target_Attributes (Gen_Id, Gen_Attrs);
9552 -- The SPARK rules are in effect when both the instantiation and generic
9553 -- are subject to SPARK_Mode On.
9555 SPARK_Rules_On := Inst_Attrs.SPARK_Mode_On and Gen_Attrs.SPARK_Mode_On;
9557 -- Output relevant information when switch -gnatel (info messages on
9558 -- implicit Elaborate[_All] pragmas) is in effect.
9560 if Elab_Info_Messages then
9561 Info_Instantiation
9562 (Inst => Inst,
9563 Gen_Id => Gen_Id,
9564 Info_Msg => True,
9565 In_SPARK => SPARK_Rules_On);
9566 end if;
9568 -- Nothing to do when the instantiation is a guaranteed ABE
9570 if Is_Known_Guaranteed_ABE (Inst) then
9571 return;
9573 -- Nothing to do when the root scenario appears at the declaration level
9574 -- and the generic is in the same unit, but outside this context.
9576 -- generic
9577 -- procedure Gen is ...; -- generic declaration
9579 -- procedure Proc is
9580 -- function A ... is
9581 -- begin
9582 -- if Some_Condition then
9583 -- declare
9584 -- procedure I is new Gen; -- instantiation site
9585 -- ...
9586 -- ...
9587 -- end A;
9589 -- X : ... := A; -- root scenario
9590 -- ...
9592 -- procedure Gen is
9593 -- ...
9594 -- end Gen;
9596 -- In the example above, the context of X is the declarative region of
9597 -- Proc. The "elaboration" of X may eventually reach Gen which appears
9598 -- outside of X's context. Gen is relevant only when Proc is invoked,
9599 -- but this happens only by means of "normal" elaboration, therefore
9600 -- Gen must not be considered if this is not the case.
9602 -- Performance note: parent traversal
9604 elsif Is_Up_Level_Target (Gen_Attrs.Spec_Decl) then
9605 return;
9607 -- The SPARK rules are in effect
9609 elsif SPARK_Rules_On then
9610 Process_Conditional_ABE_Instantiation_SPARK
9611 (Inst => Inst,
9612 Gen_Id => Gen_Id,
9613 Gen_Attrs => Gen_Attrs,
9614 State => State);
9616 -- Otherwise the Ada rules are in effect, or SPARK code is allowed to
9617 -- violate the SPARK rules.
9619 else
9620 Process_Conditional_ABE_Instantiation_Ada
9621 (Exp_Inst => Exp_Inst,
9622 Inst => Inst,
9623 Inst_Attrs => Inst_Attrs,
9624 Gen_Id => Gen_Id,
9625 Gen_Attrs => Gen_Attrs,
9626 State => State);
9627 end if;
9628 end Process_Conditional_ABE_Instantiation;
9630 -----------------------------------------------
9631 -- Process_Conditional_ABE_Instantiation_Ada --
9632 -----------------------------------------------
9634 procedure Process_Conditional_ABE_Instantiation_Ada
9635 (Exp_Inst : Node_Id;
9636 Inst : Node_Id;
9637 Inst_Attrs : Instantiation_Attributes;
9638 Gen_Id : Entity_Id;
9639 Gen_Attrs : Target_Attributes;
9640 State : Processing_Attributes)
9642 Check_OK : constant Boolean :=
9643 not Inst_Attrs.Ghost_Mode_Ignore
9644 and then not Gen_Attrs.Ghost_Mode_Ignore
9645 and then Inst_Attrs.Elab_Checks_OK
9646 and then Gen_Attrs.Elab_Checks_OK;
9647 -- A run-time ABE check may be installed only when both the instance and
9648 -- the generic have active elaboration checks and both are not ignored
9649 -- Ghost constructs.
9651 New_State : Processing_Attributes := State;
9652 -- Each step of the Processing phase constitutes a new state
9654 Root : constant Node_Id := Root_Scenario;
9656 begin
9657 -- Nothing to do when the instantiation is ABE-safe
9659 -- generic
9660 -- package Gen is
9661 -- ...
9662 -- end Gen;
9664 -- package body Gen is
9665 -- ...
9666 -- end Gen;
9668 -- with Gen;
9669 -- procedure Main is
9670 -- package Inst is new Gen (ABE); -- safe instantiation
9671 -- ...
9673 if Is_Safe_Instantiation (Inst, Gen_Attrs) then
9674 return;
9676 -- The instantiation and the generic body are both in the main unit
9678 elsif Present (Gen_Attrs.Body_Decl)
9679 and then In_Extended_Main_Code_Unit (Gen_Attrs.Body_Decl)
9680 then
9681 -- If the root scenario appears prior to the generic body, then this
9682 -- is a possible ABE with respect to the root scenario.
9684 -- generic
9685 -- package Gen is
9686 -- ...
9687 -- end Gen;
9689 -- function A ... is
9690 -- begin
9691 -- if Some_Condition then
9692 -- declare
9693 -- package Inst is new Gen; -- instantiation site
9694 -- ...
9695 -- end A;
9697 -- X : ... := A; -- root scenario
9699 -- package body Gen is -- generic body
9700 -- ...
9701 -- end Gen;
9703 -- Y : ... := A; -- root scenario
9705 -- IMPORTANT: The instantiation of Gen is a possible ABE for X, but
9706 -- not for Y. Installing an unconditional ABE raise prior to the
9707 -- instance site would be wrong as it will fail for Y as well, but in
9708 -- Y's case the instantiation of Gen is never an ABE.
9710 if Earlier_In_Extended_Unit (Root, Gen_Attrs.Body_Decl) then
9712 -- Do not emit any ABE diagnostics when the instantiation occurs
9713 -- in partial finalization context because this leads to unwanted
9714 -- noise.
9716 if State.Within_Partial_Finalization then
9717 null;
9719 -- ABE diagnostics are emitted only in the static model because
9720 -- there is a well-defined order to visiting scenarios. Without
9721 -- this order diagnostics appear jumbled and result in unwanted
9722 -- noise.
9724 elsif Static_Elaboration_Checks
9725 and then Inst_Attrs.Elab_Warnings_OK
9726 then
9727 Error_Msg_NE
9728 ("??cannot instantiate & before body seen", Inst, Gen_Id);
9729 Error_Msg_N ("\Program_Error may be raised at run time", Inst);
9731 Output_Active_Scenarios (Inst);
9732 end if;
9734 -- Install a conditional run-time ABE check to verify that the
9735 -- generic body has been elaborated prior to the instantiation.
9737 if Check_OK then
9738 Install_ABE_Check
9739 (N => Inst,
9740 Ins_Nod => Exp_Inst,
9741 Target_Id => Gen_Attrs.Spec_Id,
9742 Target_Decl => Gen_Attrs.Spec_Decl,
9743 Target_Body => Gen_Attrs.Body_Decl);
9745 -- Update the state of the Processing phase to indicate that
9746 -- no implicit Elaborate[_All] pragmas must be generated from
9747 -- this point on.
9749 -- generic
9750 -- package Gen is
9751 -- ...
9752 -- end Gen;
9754 -- function A ... is
9755 -- begin
9756 -- if Some_Condition then
9757 -- <ABE check>
9758 -- declare Inst is new Gen;
9759 -- ...
9760 -- end A;
9762 -- X : ... := A;
9764 -- package body Gen is
9765 -- begin
9766 -- External.Subp; -- imparts Elaborate_All
9767 -- end Gen;
9769 -- If Some_Condition is True, then the ABE check will fail at
9770 -- runtime and the call to External.Subp will never take place,
9771 -- rendering the implicit Elaborate_All useless.
9773 -- If Some_Condition is False, then the call to External.Subp
9774 -- will never take place, rendering the implicit Elaborate_All
9775 -- useless.
9777 New_State.Suppress_Implicit_Pragmas := True;
9778 end if;
9779 end if;
9781 -- Otherwise the generic body is not available in this compilation or it
9782 -- resides in an external unit. Install a run-time ABE check to verify
9783 -- that the generic body has been elaborated prior to the instantiation
9784 -- when the dynamic model is in effect.
9786 elsif Dynamic_Elaboration_Checks and then Check_OK then
9787 Install_ABE_Check
9788 (N => Inst,
9789 Ins_Nod => Exp_Inst,
9790 Id => Gen_Attrs.Unit_Id);
9791 end if;
9793 -- Ensure that the unit with the generic body is elaborated prior to
9794 -- the main unit. No implicit pragma is generated if the instantiation
9795 -- has elaboration checks suppressed. This behaviour parallels that of
9796 -- the old ABE mechanism.
9798 if Inst_Attrs.Elab_Checks_OK then
9799 Ensure_Prior_Elaboration
9800 (N => Inst,
9801 Unit_Id => Gen_Attrs.Unit_Id,
9802 Prag_Nam => Name_Elaborate,
9803 State => New_State);
9804 end if;
9805 end Process_Conditional_ABE_Instantiation_Ada;
9807 -------------------------------------------------
9808 -- Process_Conditional_ABE_Instantiation_SPARK --
9809 -------------------------------------------------
9811 procedure Process_Conditional_ABE_Instantiation_SPARK
9812 (Inst : Node_Id;
9813 Gen_Id : Entity_Id;
9814 Gen_Attrs : Target_Attributes;
9815 State : Processing_Attributes)
9817 Req_Nam : Name_Id;
9819 begin
9820 -- Ensure that a suitable elaboration model is in effect for SPARK rule
9821 -- verification.
9823 Check_SPARK_Model_In_Effect (Inst);
9825 -- A source instantiation imposes an Elaborate[_All] requirement on the
9826 -- context of the main unit. Determine whether the context has a pragma
9827 -- strong enough to meet the requirement. The check is orthogonal to the
9828 -- ABE ramifications of the instantiation.
9830 -- IMPORTANT: This check must be performed only when -gnatd.v (enforce
9831 -- SPARK elaboration rules in SPARK code) is active because the static
9832 -- model can ensure the prior elaboration of the unit which contains a
9833 -- body by installing an implicit Elaborate[_All] pragma.
9835 if Debug_Flag_Dot_V then
9836 if Nkind (Inst) = N_Package_Instantiation then
9837 Req_Nam := Name_Elaborate_All;
9838 else
9839 Req_Nam := Name_Elaborate;
9840 end if;
9842 Meet_Elaboration_Requirement
9843 (N => Inst,
9844 Target_Id => Gen_Id,
9845 Req_Nam => Req_Nam);
9847 -- Otherwise ensure that the unit with the target body is elaborated
9848 -- prior to the main unit.
9850 else
9851 Ensure_Prior_Elaboration
9852 (N => Inst,
9853 Unit_Id => Gen_Attrs.Unit_Id,
9854 Prag_Nam => Name_Elaborate,
9855 State => State);
9856 end if;
9857 end Process_Conditional_ABE_Instantiation_SPARK;
9859 -------------------------------------------------
9860 -- Process_Conditional_ABE_Variable_Assignment --
9861 -------------------------------------------------
9863 procedure Process_Conditional_ABE_Variable_Assignment (Asmt : Node_Id) is
9864 Var_Id : constant Entity_Id := Entity (Extract_Assignment_Name (Asmt));
9865 Prag : constant Node_Id := SPARK_Pragma (Var_Id);
9867 SPARK_Rules_On : Boolean;
9868 -- This flag is set when the SPARK rules are in effect
9870 begin
9871 -- The SPARK rules are in effect when both the assignment and the
9872 -- variable are subject to SPARK_Mode On.
9874 SPARK_Rules_On :=
9875 Present (Prag)
9876 and then Get_SPARK_Mode_From_Annotation (Prag) = On
9877 and then Is_SPARK_Mode_On_Node (Asmt);
9879 -- Output relevant information when switch -gnatel (info messages on
9880 -- implicit Elaborate[_All] pragmas) is in effect.
9882 if Elab_Info_Messages then
9883 Elab_Msg_NE
9884 (Msg => "assignment to & during elaboration",
9885 N => Asmt,
9886 Id => Var_Id,
9887 Info_Msg => True,
9888 In_SPARK => SPARK_Rules_On);
9889 end if;
9891 -- The SPARK rules are in effect. These rules are applied regardless of
9892 -- whether -gnatd.v (enforce SPARK elaboration rules in SPARK code) is
9893 -- in effect because the static model cannot ensure safe assignment of
9894 -- variables.
9896 if SPARK_Rules_On then
9897 Process_Conditional_ABE_Variable_Assignment_SPARK
9898 (Asmt => Asmt,
9899 Var_Id => Var_Id);
9901 -- Otherwise the Ada rules are in effect
9903 else
9904 Process_Conditional_ABE_Variable_Assignment_Ada
9905 (Asmt => Asmt,
9906 Var_Id => Var_Id);
9907 end if;
9908 end Process_Conditional_ABE_Variable_Assignment;
9910 -----------------------------------------------------
9911 -- Process_Conditional_ABE_Variable_Assignment_Ada --
9912 -----------------------------------------------------
9914 procedure Process_Conditional_ABE_Variable_Assignment_Ada
9915 (Asmt : Node_Id;
9916 Var_Id : Entity_Id)
9918 Var_Decl : constant Node_Id := Declaration_Node (Var_Id);
9919 Spec_Id : constant Entity_Id := Find_Top_Unit (Var_Decl);
9921 begin
9922 -- Emit a warning when an uninitialized variable declared in a package
9923 -- spec without a pragma Elaborate_Body is initialized by elaboration
9924 -- code within the corresponding body.
9926 if not Warnings_Off (Var_Id)
9927 and then not Is_Initialized (Var_Decl)
9928 and then not Has_Pragma_Elaborate_Body (Spec_Id)
9929 then
9930 Error_Msg_NE
9931 ("??variable & can be accessed by clients before this "
9932 & "initialization", Asmt, Var_Id);
9934 Error_Msg_NE
9935 ("\add pragma ""Elaborate_Body"" to spec & to ensure proper "
9936 & "initialization", Asmt, Spec_Id);
9938 Output_Active_Scenarios (Asmt);
9940 -- Generate an implicit Elaborate_Body in the spec
9942 Set_Elaborate_Body_Desirable (Spec_Id);
9943 end if;
9944 end Process_Conditional_ABE_Variable_Assignment_Ada;
9946 -------------------------------------------------------
9947 -- Process_Conditional_ABE_Variable_Assignment_SPARK --
9948 -------------------------------------------------------
9950 procedure Process_Conditional_ABE_Variable_Assignment_SPARK
9951 (Asmt : Node_Id;
9952 Var_Id : Entity_Id)
9954 Var_Decl : constant Node_Id := Declaration_Node (Var_Id);
9955 Spec_Id : constant Entity_Id := Find_Top_Unit (Var_Decl);
9957 begin
9958 -- Ensure that a suitable elaboration model is in effect for SPARK rule
9959 -- verification.
9961 Check_SPARK_Model_In_Effect (Asmt);
9963 -- Emit an error when an initialized variable declared in a package spec
9964 -- without pragma Elaborate_Body is further modified by elaboration code
9965 -- within the corresponding body.
9967 if Is_Initialized (Var_Decl)
9968 and then not Has_Pragma_Elaborate_Body (Spec_Id)
9969 then
9970 Error_Msg_NE
9971 ("variable & modified by elaboration code in package body",
9972 Asmt, Var_Id);
9974 Error_Msg_NE
9975 ("\add pragma ""Elaborate_Body"" to spec & to ensure full "
9976 & "initialization", Asmt, Spec_Id);
9978 Output_Active_Scenarios (Asmt);
9979 end if;
9980 end Process_Conditional_ABE_Variable_Assignment_SPARK;
9982 ------------------------------------------------
9983 -- Process_Conditional_ABE_Variable_Reference --
9984 ------------------------------------------------
9986 procedure Process_Conditional_ABE_Variable_Reference (Ref : Node_Id) is
9987 Var_Attrs : Variable_Attributes;
9988 Var_Id : Entity_Id;
9990 begin
9991 Extract_Variable_Reference_Attributes
9992 (Ref => Ref,
9993 Var_Id => Var_Id,
9994 Attrs => Var_Attrs);
9996 if Is_Read (Ref) then
9997 Process_Conditional_ABE_Variable_Reference_Read
9998 (Ref => Ref,
9999 Var_Id => Var_Id,
10000 Attrs => Var_Attrs);
10001 end if;
10002 end Process_Conditional_ABE_Variable_Reference;
10004 -----------------------------------------------------
10005 -- Process_Conditional_ABE_Variable_Reference_Read --
10006 -----------------------------------------------------
10008 procedure Process_Conditional_ABE_Variable_Reference_Read
10009 (Ref : Node_Id;
10010 Var_Id : Entity_Id;
10011 Attrs : Variable_Attributes)
10013 begin
10014 -- Output relevant information when switch -gnatel (info messages on
10015 -- implicit Elaborate[_All] pragmas) is in effect.
10017 if Elab_Info_Messages then
10018 Elab_Msg_NE
10019 (Msg => "read of variable & during elaboration",
10020 N => Ref,
10021 Id => Var_Id,
10022 Info_Msg => True,
10023 In_SPARK => True);
10024 end if;
10026 -- Nothing to do when the variable appears within the main unit because
10027 -- diagnostics on reads are relevant only for external variables.
10029 if Is_Same_Unit (Attrs.Unit_Id, Cunit_Entity (Main_Unit)) then
10030 null;
10032 -- Nothing to do when the variable is already initialized. Note that the
10033 -- variable may be further modified by the external unit.
10035 elsif Is_Initialized (Declaration_Node (Var_Id)) then
10036 null;
10038 -- Nothing to do when the external unit guarantees the initialization of
10039 -- the variable by means of pragma Elaborate_Body.
10041 elsif Has_Pragma_Elaborate_Body (Attrs.Unit_Id) then
10042 null;
10044 -- A variable read imposes an Elaborate requirement on the context of
10045 -- the main unit. Determine whether the context has a pragma strong
10046 -- enough to meet the requirement.
10048 else
10049 Meet_Elaboration_Requirement
10050 (N => Ref,
10051 Target_Id => Var_Id,
10052 Req_Nam => Name_Elaborate);
10053 end if;
10054 end Process_Conditional_ABE_Variable_Reference_Read;
10056 -----------------------------
10057 -- Process_Conditional_ABE --
10058 -----------------------------
10060 -- NOTE: The body of this routine is intentionally out of order because it
10061 -- invokes an instantiated subprogram (Process_Conditional_ABE_Activation).
10062 -- Placing the body in alphabetical order will result in a guaranteed ABE.
10064 procedure Process_Conditional_ABE
10065 (N : Node_Id;
10066 State : Processing_Attributes := Initial_State)
10068 Call_Attrs : Call_Attributes;
10069 Target_Id : Entity_Id;
10071 begin
10072 -- Add the current scenario to the stack of active scenarios
10074 Push_Active_Scenario (N);
10076 -- 'Access
10078 if Is_Suitable_Access (N) then
10079 Process_Conditional_ABE_Access
10080 (Attr => N,
10081 State => State);
10083 -- Activations and calls
10085 elsif Is_Suitable_Call (N) then
10087 -- In general, only calls found within the main unit are processed
10088 -- because the ALI information supplied to binde is for the main
10089 -- unit only. However, to preserve the consistency of the tree and
10090 -- ensure proper serialization of internal names, external calls
10091 -- also receive corresponding call markers (see Build_Call_Marker).
10092 -- Regardless of the reason, external calls must not be processed.
10094 if In_Main_Context (N) then
10095 Extract_Call_Attributes
10096 (Call => N,
10097 Target_Id => Target_Id,
10098 Attrs => Call_Attrs);
10100 if Is_Activation_Proc (Target_Id) then
10101 Process_Conditional_ABE_Activation
10102 (Call => N,
10103 Call_Attrs => Call_Attrs,
10104 State => State);
10106 else
10107 Process_Conditional_ABE_Call
10108 (Call => N,
10109 Call_Attrs => Call_Attrs,
10110 Target_Id => Target_Id,
10111 State => State);
10112 end if;
10113 end if;
10115 -- Instantiations
10117 elsif Is_Suitable_Instantiation (N) then
10118 Process_Conditional_ABE_Instantiation
10119 (Exp_Inst => N,
10120 State => State);
10122 -- Variable assignments
10124 elsif Is_Suitable_Variable_Assignment (N) then
10125 Process_Conditional_ABE_Variable_Assignment (N);
10127 -- Variable references
10129 elsif Is_Suitable_Variable_Reference (N) then
10131 -- In general, only variable references found within the main unit
10132 -- are processed because the ALI information supplied to binde is for
10133 -- the main unit only. However, to preserve the consistency of the
10134 -- tree and ensure proper serialization of internal names, external
10135 -- variable references also receive corresponding variable reference
10136 -- markers (see Build_Varaible_Reference_Marker). Regardless of the
10137 -- reason, external variable references must not be processed.
10139 if In_Main_Context (N) then
10140 Process_Conditional_ABE_Variable_Reference (N);
10141 end if;
10142 end if;
10144 -- Remove the current scenario from the stack of active scenarios once
10145 -- all ABE diagnostics and checks have been performed.
10147 Pop_Active_Scenario (N);
10148 end Process_Conditional_ABE;
10150 --------------------------------------------
10151 -- Process_Guaranteed_ABE_Activation_Impl --
10152 --------------------------------------------
10154 procedure Process_Guaranteed_ABE_Activation_Impl
10155 (Call : Node_Id;
10156 Call_Attrs : Call_Attributes;
10157 Obj_Id : Entity_Id;
10158 Task_Attrs : Task_Attributes;
10159 State : Processing_Attributes)
10161 pragma Unreferenced (State);
10163 Check_OK : constant Boolean :=
10164 not Is_Ignored_Ghost_Entity (Obj_Id)
10165 and then not Task_Attrs.Ghost_Mode_Ignore
10166 and then Is_Elaboration_Checks_OK_Id (Obj_Id)
10167 and then Task_Attrs.Elab_Checks_OK;
10168 -- A run-time ABE check may be installed only when the object and the
10169 -- task type have active elaboration checks, and both are not ignored
10170 -- Ghost constructs.
10172 begin
10173 -- Nothing to do when the root scenario appears at the declaration
10174 -- level and the task is in the same unit, but outside this context.
10176 -- task type Task_Typ; -- task declaration
10178 -- procedure Proc is
10179 -- function A ... is
10180 -- begin
10181 -- if Some_Condition then
10182 -- declare
10183 -- T : Task_Typ;
10184 -- begin
10185 -- <activation call> -- activation site
10186 -- end;
10187 -- ...
10188 -- end A;
10190 -- X : ... := A; -- root scenario
10191 -- ...
10193 -- task body Task_Typ is
10194 -- ...
10195 -- end Task_Typ;
10197 -- In the example above, the context of X is the declarative list of
10198 -- Proc. The "elaboration" of X may reach the activation of T whose body
10199 -- is defined outside of X's context. The task body is relevant only
10200 -- when Proc is invoked, but this happens only in "normal" elaboration,
10201 -- therefore the task body must not be considered if this is not the
10202 -- case.
10204 -- Performance note: parent traversal
10206 if Is_Up_Level_Target (Task_Attrs.Task_Decl) then
10207 return;
10209 -- Nothing to do when the activation is ABE-safe
10211 -- generic
10212 -- package Gen is
10213 -- task type Task_Typ;
10214 -- end Gen;
10216 -- package body Gen is
10217 -- task body Task_Typ is
10218 -- begin
10219 -- ...
10220 -- end Task_Typ;
10221 -- end Gen;
10223 -- with Gen;
10224 -- procedure Main is
10225 -- package Nested is
10226 -- package Inst is new Gen;
10227 -- T : Inst.Task_Typ;
10228 -- end Nested; -- safe activation
10229 -- ...
10231 elsif Is_Safe_Activation (Call, Task_Attrs.Task_Decl) then
10232 return;
10234 -- An activation call leads to a guaranteed ABE when the activation
10235 -- call and the task appear within the same context ignoring library
10236 -- levels, and the body of the task has not been seen yet or appears
10237 -- after the activation call.
10239 -- procedure Guaranteed_ABE is
10240 -- task type Task_Typ;
10242 -- package Nested is
10243 -- T : Task_Typ;
10244 -- <activation call> -- guaranteed ABE
10245 -- end Nested;
10247 -- task body Task_Typ is
10248 -- ...
10249 -- end Task_Typ;
10250 -- ...
10252 -- Performance note: parent traversal
10254 elsif Is_Guaranteed_ABE
10255 (N => Call,
10256 Target_Decl => Task_Attrs.Task_Decl,
10257 Target_Body => Task_Attrs.Body_Decl)
10258 then
10259 if Call_Attrs.Elab_Warnings_OK then
10260 Error_Msg_Sloc := Sloc (Call);
10261 Error_Msg_N
10262 ("??task & will be activated # before elaboration of its body",
10263 Obj_Id);
10264 Error_Msg_N ("\Program_Error will be raised at run time", Obj_Id);
10265 end if;
10267 -- Mark the activation call as a guaranteed ABE
10269 Set_Is_Known_Guaranteed_ABE (Call);
10271 -- Install a run-time ABE failue because this activation call will
10272 -- always result in an ABE.
10274 if Check_OK then
10275 Install_ABE_Failure
10276 (N => Call,
10277 Ins_Nod => Call);
10278 end if;
10279 end if;
10280 end Process_Guaranteed_ABE_Activation_Impl;
10282 procedure Process_Guaranteed_ABE_Activation is
10283 new Process_Activation_Generic (Process_Guaranteed_ABE_Activation_Impl);
10285 ---------------------------------
10286 -- Process_Guaranteed_ABE_Call --
10287 ---------------------------------
10289 procedure Process_Guaranteed_ABE_Call
10290 (Call : Node_Id;
10291 Call_Attrs : Call_Attributes;
10292 Target_Id : Entity_Id)
10294 Target_Attrs : Target_Attributes;
10296 begin
10297 Extract_Target_Attributes
10298 (Target_Id => Target_Id,
10299 Attrs => Target_Attrs);
10301 -- Nothing to do when the root scenario appears at the declaration level
10302 -- and the target is in the same unit, but outside this context.
10304 -- function B ...; -- target declaration
10306 -- procedure Proc is
10307 -- function A ... is
10308 -- begin
10309 -- if Some_Condition then
10310 -- return B; -- call site
10311 -- ...
10312 -- end A;
10314 -- X : ... := A; -- root scenario
10315 -- ...
10317 -- function B ... is
10318 -- ...
10319 -- end B;
10321 -- In the example above, the context of X is the declarative region of
10322 -- Proc. The "elaboration" of X may eventually reach B which is defined
10323 -- outside of X's context. B is relevant only when Proc is invoked, but
10324 -- this happens only by means of "normal" elaboration, therefore B must
10325 -- not be considered if this is not the case.
10327 -- Performance note: parent traversal
10329 if Is_Up_Level_Target (Target_Attrs.Spec_Decl) then
10330 return;
10332 -- Nothing to do when the call is ABE-safe
10334 -- generic
10335 -- function Gen ...;
10337 -- function Gen ... is
10338 -- begin
10339 -- ...
10340 -- end Gen;
10342 -- with Gen;
10343 -- procedure Main is
10344 -- function Inst is new Gen;
10345 -- X : ... := Inst; -- safe call
10346 -- ...
10348 elsif Is_Safe_Call (Call, Target_Attrs) then
10349 return;
10351 -- A call leads to a guaranteed ABE when the call and the target appear
10352 -- within the same context ignoring library levels, and the body of the
10353 -- target has not been seen yet or appears after the call.
10355 -- procedure Guaranteed_ABE is
10356 -- function Func ...;
10358 -- package Nested is
10359 -- Obj : ... := Func; -- guaranteed ABE
10360 -- end Nested;
10362 -- function Func ... is
10363 -- ...
10364 -- end Func;
10365 -- ...
10367 -- Performance note: parent traversal
10369 elsif Is_Guaranteed_ABE
10370 (N => Call,
10371 Target_Decl => Target_Attrs.Spec_Decl,
10372 Target_Body => Target_Attrs.Body_Decl)
10373 then
10374 if Call_Attrs.Elab_Warnings_OK then
10375 Error_Msg_NE ("??cannot call & before body seen", Call, Target_Id);
10376 Error_Msg_N ("\Program_Error will be raised at run time", Call);
10377 end if;
10379 -- Mark the call as a guarnateed ABE
10381 Set_Is_Known_Guaranteed_ABE (Call);
10383 -- Install a run-time ABE failure because the call will always result
10384 -- in an ABE. The failure is installed when both the call and target
10385 -- have enabled elaboration checks, and both are not ignored Ghost
10386 -- constructs.
10388 if Call_Attrs.Elab_Checks_OK
10389 and then Target_Attrs.Elab_Checks_OK
10390 and then not Call_Attrs.Ghost_Mode_Ignore
10391 and then not Target_Attrs.Ghost_Mode_Ignore
10392 then
10393 Install_ABE_Failure
10394 (N => Call,
10395 Ins_Nod => Call);
10396 end if;
10397 end if;
10398 end Process_Guaranteed_ABE_Call;
10400 ------------------------------------------
10401 -- Process_Guaranteed_ABE_Instantiation --
10402 ------------------------------------------
10404 procedure Process_Guaranteed_ABE_Instantiation (Exp_Inst : Node_Id) is
10405 Gen_Attrs : Target_Attributes;
10406 Gen_Id : Entity_Id;
10407 Inst : Node_Id;
10408 Inst_Attrs : Instantiation_Attributes;
10409 Inst_Id : Entity_Id;
10411 begin
10412 Extract_Instantiation_Attributes
10413 (Exp_Inst => Exp_Inst,
10414 Inst => Inst,
10415 Inst_Id => Inst_Id,
10416 Gen_Id => Gen_Id,
10417 Attrs => Inst_Attrs);
10419 Extract_Target_Attributes (Gen_Id, Gen_Attrs);
10421 -- Nothing to do when the root scenario appears at the declaration level
10422 -- and the generic is in the same unit, but outside this context.
10424 -- generic
10425 -- procedure Gen is ...; -- generic declaration
10427 -- procedure Proc is
10428 -- function A ... is
10429 -- begin
10430 -- if Some_Condition then
10431 -- declare
10432 -- procedure I is new Gen; -- instantiation site
10433 -- ...
10434 -- ...
10435 -- end A;
10437 -- X : ... := A; -- root scenario
10438 -- ...
10440 -- procedure Gen is
10441 -- ...
10442 -- end Gen;
10444 -- In the example above, the context of X is the declarative region of
10445 -- Proc. The "elaboration" of X may eventually reach Gen which appears
10446 -- outside of X's context. Gen is relevant only when Proc is invoked,
10447 -- but this happens only by means of "normal" elaboration, therefore
10448 -- Gen must not be considered if this is not the case.
10450 -- Performance note: parent traversal
10452 if Is_Up_Level_Target (Gen_Attrs.Spec_Decl) then
10453 return;
10455 -- Nothing to do when the instantiation is ABE-safe
10457 -- generic
10458 -- package Gen is
10459 -- ...
10460 -- end Gen;
10462 -- package body Gen is
10463 -- ...
10464 -- end Gen;
10466 -- with Gen;
10467 -- procedure Main is
10468 -- package Inst is new Gen (ABE); -- safe instantiation
10469 -- ...
10471 elsif Is_Safe_Instantiation (Inst, Gen_Attrs) then
10472 return;
10474 -- An instantiation leads to a guaranteed ABE when the instantiation and
10475 -- the generic appear within the same context ignoring library levels,
10476 -- and the body of the generic has not been seen yet or appears after
10477 -- the instantiation.
10479 -- procedure Guaranteed_ABE is
10480 -- generic
10481 -- procedure Gen;
10483 -- package Nested is
10484 -- procedure Inst is new Gen; -- guaranteed ABE
10485 -- end Nested;
10487 -- procedure Gen is
10488 -- ...
10489 -- end Gen;
10490 -- ...
10492 -- Performance note: parent traversal
10494 elsif Is_Guaranteed_ABE
10495 (N => Inst,
10496 Target_Decl => Gen_Attrs.Spec_Decl,
10497 Target_Body => Gen_Attrs.Body_Decl)
10498 then
10499 if Inst_Attrs.Elab_Warnings_OK then
10500 Error_Msg_NE
10501 ("??cannot instantiate & before body seen", Inst, Gen_Id);
10502 Error_Msg_N ("\Program_Error will be raised at run time", Inst);
10503 end if;
10505 -- Mark the instantiation as a guarantee ABE. This automatically
10506 -- suppresses the instantiation of the generic body.
10508 Set_Is_Known_Guaranteed_ABE (Inst);
10510 -- Install a run-time ABE failure because the instantiation will
10511 -- always result in an ABE. The failure is installed when both the
10512 -- instance and the generic have enabled elaboration checks, and both
10513 -- are not ignored Ghost constructs.
10515 if Inst_Attrs.Elab_Checks_OK
10516 and then Gen_Attrs.Elab_Checks_OK
10517 and then not Inst_Attrs.Ghost_Mode_Ignore
10518 and then not Gen_Attrs.Ghost_Mode_Ignore
10519 then
10520 Install_ABE_Failure
10521 (N => Inst,
10522 Ins_Nod => Exp_Inst);
10523 end if;
10524 end if;
10525 end Process_Guaranteed_ABE_Instantiation;
10527 ----------------------------
10528 -- Process_Guaranteed_ABE --
10529 ----------------------------
10531 -- NOTE: The body of this routine is intentionally out of order because it
10532 -- invokes an instantiated subprogram (Process_Guaranteed_ABE_Activation).
10533 -- Placing the body in alphabetical order will result in a guaranteed ABE.
10535 procedure Process_Guaranteed_ABE (N : Node_Id) is
10536 Call_Attrs : Call_Attributes;
10537 Target_Id : Entity_Id;
10539 begin
10540 -- Add the current scenario to the stack of active scenarios
10542 Push_Active_Scenario (N);
10544 -- Only calls, instantiations, and task activations may result in a
10545 -- guaranteed ABE.
10547 if Is_Suitable_Call (N) then
10548 Extract_Call_Attributes
10549 (Call => N,
10550 Target_Id => Target_Id,
10551 Attrs => Call_Attrs);
10553 if Is_Activation_Proc (Target_Id) then
10554 Process_Guaranteed_ABE_Activation
10555 (Call => N,
10556 Call_Attrs => Call_Attrs,
10557 State => Initial_State);
10559 else
10560 Process_Guaranteed_ABE_Call
10561 (Call => N,
10562 Call_Attrs => Call_Attrs,
10563 Target_Id => Target_Id);
10564 end if;
10566 elsif Is_Suitable_Instantiation (N) then
10567 Process_Guaranteed_ABE_Instantiation (N);
10568 end if;
10570 -- Remove the current scenario from the stack of active scenarios once
10571 -- all ABE diagnostics and checks have been performed.
10573 Pop_Active_Scenario (N);
10574 end Process_Guaranteed_ABE;
10576 --------------------------
10577 -- Push_Active_Scenario --
10578 --------------------------
10580 procedure Push_Active_Scenario (N : Node_Id) is
10581 begin
10582 Scenario_Stack.Append (N);
10583 end Push_Active_Scenario;
10585 ---------------------------------
10586 -- Record_Elaboration_Scenario --
10587 ---------------------------------
10589 procedure Record_Elaboration_Scenario (N : Node_Id) is
10590 Level : Enclosing_Level_Kind;
10592 Any_Level_OK : Boolean;
10593 -- This flag is set when a particular scenario is allowed to appear at
10594 -- any level.
10596 Declaration_Level_OK : Boolean;
10597 -- This flag is set when a particular scenario is allowed to appear at
10598 -- the declaration level.
10600 Library_Level_OK : Boolean;
10601 -- This flag is set when a particular scenario is allowed to appear at
10602 -- the library level.
10604 begin
10605 -- Assume that the scenario cannot appear on any level
10607 Any_Level_OK := False;
10608 Declaration_Level_OK := False;
10609 Library_Level_OK := False;
10611 -- Nothing to do when switch -gnatH (legacy elaboration checking mode
10612 -- enabled) is in effect because the legacy ABE mechanism does not need
10613 -- to carry out this action.
10615 if Legacy_Elaboration_Checks then
10616 return;
10618 -- Nothing to do for ASIS. As a result, no ABE checks and diagnostics
10619 -- are performed in this mode.
10621 elsif ASIS_Mode then
10622 return;
10624 -- Nothing to do when the scenario is being preanalyzed
10626 elsif Preanalysis_Active then
10627 return;
10628 end if;
10630 -- Ensure that a library-level call does not appear in a preelaborated
10631 -- unit. The check must come before ignoring scenarios within external
10632 -- units or inside generics because calls in those context must also be
10633 -- verified.
10635 if Is_Suitable_Call (N) then
10636 Check_Preelaborated_Call (N);
10637 end if;
10639 -- Nothing to do when the scenario does not appear within the main unit
10641 if not In_Main_Context (N) then
10642 return;
10644 -- Scenarios within a generic unit are never considered because generics
10645 -- cannot be elaborated.
10647 elsif Inside_A_Generic then
10648 return;
10650 -- Scenarios which do not fall in one of the elaboration categories
10651 -- listed below are not considered. The categories are:
10653 -- 'Access for entries, operators, and subprograms
10654 -- Assignments to variables
10655 -- Calls (includes task activation)
10656 -- Derived types
10657 -- Instantiations
10658 -- Pragma Refined_State
10659 -- Reads of variables
10661 elsif Is_Suitable_Access (N) then
10662 Library_Level_OK := True;
10664 -- Signal any enclosing local exception handlers that the 'Access may
10665 -- raise Program_Error due to a failed ABE check when switch -gnatd.o
10666 -- (conservative elaboration order for indirect calls) is in effect.
10667 -- Marking the exception handlers ensures proper expansion by both
10668 -- the front and back end restriction when No_Exception_Propagation
10669 -- is in effect.
10671 if Debug_Flag_Dot_O then
10672 Possible_Local_Raise (N, Standard_Program_Error);
10673 end if;
10675 elsif Is_Suitable_Call (N) or else Is_Suitable_Instantiation (N) then
10676 Declaration_Level_OK := True;
10677 Library_Level_OK := True;
10679 -- Signal any enclosing local exception handlers that the call or
10680 -- instantiation may raise Program_Error due to a failed ABE check.
10681 -- Marking the exception handlers ensures proper expansion by both
10682 -- the front and back end restriction when No_Exception_Propagation
10683 -- is in effect.
10685 Possible_Local_Raise (N, Standard_Program_Error);
10687 elsif Is_Suitable_SPARK_Derived_Type (N) then
10688 Any_Level_OK := True;
10690 elsif Is_Suitable_SPARK_Refined_State_Pragma (N) then
10691 Library_Level_OK := True;
10693 elsif Is_Suitable_Variable_Assignment (N)
10694 or else Is_Suitable_Variable_Reference (N)
10695 then
10696 Library_Level_OK := True;
10698 -- Otherwise the input does not denote a suitable scenario
10700 else
10701 return;
10702 end if;
10704 -- The static model imposes additional restrictions on the placement of
10705 -- scenarios. In contrast, the dynamic model assumes that every scenario
10706 -- will be elaborated or invoked at some point.
10708 if Static_Elaboration_Checks then
10710 -- Certain scenarios are allowed to appear at any level. This check
10711 -- is performed here in order to save on a parent traversal.
10713 if Any_Level_OK then
10714 null;
10716 -- Otherwise the scenario must appear at a specific level
10718 else
10719 -- Performance note: parent traversal
10721 Level := Find_Enclosing_Level (N);
10723 -- Declaration-level scenario
10725 if Declaration_Level_OK and then Level = Declaration_Level then
10726 null;
10728 -- Library-level or instantiation scenario
10730 elsif Library_Level_OK
10731 and then Level in Library_Or_Instantiation_Level
10732 then
10733 null;
10735 -- Otherwise the scenario does not appear at the proper level and
10736 -- cannot possibly act as a top-level scenario.
10738 else
10739 return;
10740 end if;
10741 end if;
10742 end if;
10744 -- Derived types subject to SPARK_Mode On require elaboration-related
10745 -- checks even though the type may not be declared within elaboration
10746 -- code. The types are recorded in a separate table which is examined
10747 -- during the Processing phase. Note that the checks must be delayed
10748 -- because the bodies of overriding primitives are not available yet.
10750 if Is_Suitable_SPARK_Derived_Type (N) then
10751 Record_SPARK_Elaboration_Scenario (N);
10753 -- Nothing left to do for derived types
10755 return;
10757 -- Instantiations of generics both subject to SPARK_Mode On require
10758 -- elaboration-related checks even though the instantiations may not
10759 -- appear within elaboration code. The instantiations are recored in
10760 -- a separate table which is examined during the Procesing phase. Note
10761 -- that the checks must be delayed because it is not known yet whether
10762 -- the generic unit has a body or not.
10764 -- IMPORTANT: A SPARK instantiation is also a normal instantiation which
10765 -- is subject to common conditional and guaranteed ABE checks.
10767 elsif Is_Suitable_SPARK_Instantiation (N) then
10768 Record_SPARK_Elaboration_Scenario (N);
10770 -- External constituents that refine abstract states which appear in
10771 -- pragma Initializes require elaboration-related checks even though
10772 -- a Refined_State pragma lacks any elaboration semantic.
10774 elsif Is_Suitable_SPARK_Refined_State_Pragma (N) then
10775 Record_SPARK_Elaboration_Scenario (N);
10777 -- Nothing left to do for pragma Refined_State
10779 return;
10780 end if;
10782 -- Perform early detection of guaranteed ABEs in order to suppress the
10783 -- instantiation of generic bodies as gigi cannot handle certain types
10784 -- of premature instantiations.
10786 Process_Guaranteed_ABE (N);
10788 -- At this point all checks have been performed. Record the scenario for
10789 -- later processing by the ABE phase.
10791 Top_Level_Scenarios.Append (N);
10792 Set_Is_Recorded_Top_Level_Scenario (N);
10793 end Record_Elaboration_Scenario;
10795 ---------------------------------------
10796 -- Record_SPARK_Elaboration_Scenario --
10797 ---------------------------------------
10799 procedure Record_SPARK_Elaboration_Scenario (N : Node_Id) is
10800 begin
10801 SPARK_Scenarios.Append (N);
10802 Set_Is_Recorded_SPARK_Scenario (N);
10803 end Record_SPARK_Elaboration_Scenario;
10805 -----------------------------------
10806 -- Recorded_SPARK_Scenarios_Hash --
10807 -----------------------------------
10809 function Recorded_SPARK_Scenarios_Hash
10810 (Key : Node_Id) return Recorded_SPARK_Scenarios_Index
10812 begin
10813 return
10814 Recorded_SPARK_Scenarios_Index (Key mod Recorded_SPARK_Scenarios_Max);
10815 end Recorded_SPARK_Scenarios_Hash;
10817 ---------------------------------------
10818 -- Recorded_Top_Level_Scenarios_Hash --
10819 ---------------------------------------
10821 function Recorded_Top_Level_Scenarios_Hash
10822 (Key : Node_Id) return Recorded_Top_Level_Scenarios_Index
10824 begin
10825 return
10826 Recorded_Top_Level_Scenarios_Index
10827 (Key mod Recorded_Top_Level_Scenarios_Max);
10828 end Recorded_Top_Level_Scenarios_Hash;
10830 --------------------------
10831 -- Reset_Visited_Bodies --
10832 --------------------------
10834 procedure Reset_Visited_Bodies is
10835 begin
10836 if Visited_Bodies_In_Use then
10837 Visited_Bodies_In_Use := False;
10838 Visited_Bodies.Reset;
10839 end if;
10840 end Reset_Visited_Bodies;
10842 -------------------
10843 -- Root_Scenario --
10844 -------------------
10846 function Root_Scenario return Node_Id is
10847 package Stack renames Scenario_Stack;
10849 begin
10850 -- Ensure that the scenario stack has at least one active scenario in
10851 -- it. The one at the bottom (index First) is the root scenario.
10853 pragma Assert (Stack.Last >= Stack.First);
10854 return Stack.Table (Stack.First);
10855 end Root_Scenario;
10857 ---------------------------
10858 -- Set_Early_Call_Region --
10859 ---------------------------
10861 procedure Set_Early_Call_Region (Body_Id : Entity_Id; Start : Node_Id) is
10862 begin
10863 pragma Assert (Ekind_In (Body_Id, E_Entry,
10864 E_Entry_Family,
10865 E_Function,
10866 E_Procedure,
10867 E_Subprogram_Body));
10869 Early_Call_Regions_In_Use := True;
10870 Early_Call_Regions.Set (Body_Id, Start);
10871 end Set_Early_Call_Region;
10873 ----------------------------
10874 -- Set_Elaboration_Status --
10875 ----------------------------
10877 procedure Set_Elaboration_Status
10878 (Unit_Id : Entity_Id;
10879 Val : Elaboration_Attributes)
10881 begin
10882 Elaboration_Statuses_In_Use := True;
10883 Elaboration_Statuses.Set (Unit_Id, Val);
10884 end Set_Elaboration_Status;
10886 ------------------------------------
10887 -- Set_Is_Recorded_SPARK_Scenario --
10888 ------------------------------------
10890 procedure Set_Is_Recorded_SPARK_Scenario
10891 (N : Node_Id;
10892 Val : Boolean := True)
10894 begin
10895 Recorded_SPARK_Scenarios_In_Use := True;
10896 Recorded_SPARK_Scenarios.Set (N, Val);
10897 end Set_Is_Recorded_SPARK_Scenario;
10899 ----------------------------------------
10900 -- Set_Is_Recorded_Top_Level_Scenario --
10901 ----------------------------------------
10903 procedure Set_Is_Recorded_Top_Level_Scenario
10904 (N : Node_Id;
10905 Val : Boolean := True)
10907 begin
10908 Recorded_Top_Level_Scenarios_In_Use := True;
10909 Recorded_Top_Level_Scenarios.Set (N, Val);
10910 end Set_Is_Recorded_Top_Level_Scenario;
10912 -------------------------
10913 -- Set_Is_Visited_Body --
10914 -------------------------
10916 procedure Set_Is_Visited_Body (Subp_Body : Node_Id) is
10917 begin
10918 Visited_Bodies_In_Use := True;
10919 Visited_Bodies.Set (Subp_Body, True);
10920 end Set_Is_Visited_Body;
10922 -------------------------------
10923 -- Static_Elaboration_Checks --
10924 -------------------------------
10926 function Static_Elaboration_Checks return Boolean is
10927 begin
10928 return not Dynamic_Elaboration_Checks;
10929 end Static_Elaboration_Checks;
10931 -------------------
10932 -- Traverse_Body --
10933 -------------------
10935 procedure Traverse_Body (N : Node_Id; State : Processing_Attributes) is
10936 procedure Find_And_Process_Nested_Scenarios;
10937 pragma Inline (Find_And_Process_Nested_Scenarios);
10938 -- Examine the declarations and statements of subprogram body N for
10939 -- suitable scenarios. Save each discovered scenario and process it
10940 -- accordingly.
10942 procedure Process_Nested_Scenarios (Nested : Elist_Id);
10943 pragma Inline (Process_Nested_Scenarios);
10944 -- Invoke Process_Conditional_ABE on each individual scenario found in
10945 -- list Nested.
10947 ---------------------------------------
10948 -- Find_And_Process_Nested_Scenarios --
10949 ---------------------------------------
10951 procedure Find_And_Process_Nested_Scenarios is
10952 Body_Id : constant Entity_Id := Defining_Entity (N);
10954 function Is_Potential_Scenario
10955 (Nod : Node_Id) return Traverse_Result;
10956 -- Determine whether arbitrary node Nod denotes a suitable scenario.
10957 -- If it does, save it in the Nested_Scenarios list of the subprogram
10958 -- body, and process it.
10960 procedure Save_Scenario (Nod : Node_Id);
10961 pragma Inline (Save_Scenario);
10962 -- Save scenario Nod in the Nested_Scenarios list of the subprogram
10963 -- body.
10965 procedure Traverse_List (List : List_Id);
10966 pragma Inline (Traverse_List);
10967 -- Invoke Traverse_Potential_Scenarios on each node in list List
10969 procedure Traverse_Potential_Scenarios is
10970 new Traverse_Proc (Is_Potential_Scenario);
10972 ---------------------------
10973 -- Is_Potential_Scenario --
10974 ---------------------------
10976 function Is_Potential_Scenario
10977 (Nod : Node_Id) return Traverse_Result
10979 begin
10980 -- Special cases
10982 -- Skip constructs which do not have elaboration of their own and
10983 -- need to be elaborated by other means such as invocation, task
10984 -- activation, etc.
10986 if Is_Non_Library_Level_Encapsulator (Nod) then
10987 return Skip;
10989 -- Terminate the traversal of a task body with an accept statement
10990 -- when no entry calls in elaboration are allowed because the task
10991 -- will block at run-time and the remaining statements will not be
10992 -- executed.
10994 elsif Nkind_In (Original_Node (Nod), N_Accept_Statement,
10995 N_Selective_Accept)
10996 then
10997 if Restriction_Active (No_Entry_Calls_In_Elaboration_Code) then
10998 return Abandon;
11000 -- The same behavior is achieved when switch -gnatd_a (stop
11001 -- elabortion checks on accept or select statement) is in
11002 -- effect.
11004 elsif Debug_Flag_Underscore_A then
11005 return Abandon;
11006 end if;
11008 -- Certain nodes carry semantic lists which act as repositories
11009 -- until expansion transforms the node and relocates the contents.
11010 -- Examine these lists in case expansion is disabled.
11012 elsif Nkind_In (Nod, N_And_Then, N_Or_Else) then
11013 Traverse_List (Actions (Nod));
11015 elsif Nkind_In (Nod, N_Elsif_Part, N_Iteration_Scheme) then
11016 Traverse_List (Condition_Actions (Nod));
11018 elsif Nkind (Nod) = N_If_Expression then
11019 Traverse_List (Then_Actions (Nod));
11020 Traverse_List (Else_Actions (Nod));
11022 elsif Nkind_In (Nod, N_Component_Association,
11023 N_Iterated_Component_Association)
11024 then
11025 Traverse_List (Loop_Actions (Nod));
11027 -- General case
11029 -- Save a suitable scenario in the Nested_Scenarios list of the
11030 -- subprogram body. As a result any subsequent traversals of the
11031 -- subprogram body started from a different top-level scenario no
11032 -- longer need to reexamine the tree.
11034 elsif Is_Suitable_Scenario (Nod) then
11035 Save_Scenario (Nod);
11037 Process_Conditional_ABE
11038 (N => Nod,
11039 State => State);
11040 end if;
11042 return OK;
11043 end Is_Potential_Scenario;
11045 -------------------
11046 -- Save_Scenario --
11047 -------------------
11049 procedure Save_Scenario (Nod : Node_Id) is
11050 Nested : Elist_Id;
11052 begin
11053 Nested := Nested_Scenarios (Body_Id);
11055 if No (Nested) then
11056 Nested := New_Elmt_List;
11057 Set_Nested_Scenarios (Body_Id, Nested);
11058 end if;
11060 Append_Elmt (Nod, Nested);
11061 end Save_Scenario;
11063 -------------------
11064 -- Traverse_List --
11065 -------------------
11067 procedure Traverse_List (List : List_Id) is
11068 Item : Node_Id;
11070 begin
11071 Item := First (List);
11072 while Present (Item) loop
11073 Traverse_Potential_Scenarios (Item);
11074 Next (Item);
11075 end loop;
11076 end Traverse_List;
11078 -- Start of processing for Find_And_Process_Nested_Scenarios
11080 begin
11081 -- Examine the declarations for suitable scenarios
11083 Traverse_List (Declarations (N));
11085 -- Examine the handled sequence of statements. This also includes any
11086 -- exceptions handlers.
11088 Traverse_Potential_Scenarios (Handled_Statement_Sequence (N));
11089 end Find_And_Process_Nested_Scenarios;
11091 ------------------------------
11092 -- Process_Nested_Scenarios --
11093 ------------------------------
11095 procedure Process_Nested_Scenarios (Nested : Elist_Id) is
11096 Nested_Elmt : Elmt_Id;
11098 begin
11099 Nested_Elmt := First_Elmt (Nested);
11100 while Present (Nested_Elmt) loop
11101 Process_Conditional_ABE
11102 (N => Node (Nested_Elmt),
11103 State => State);
11105 Next_Elmt (Nested_Elmt);
11106 end loop;
11107 end Process_Nested_Scenarios;
11109 -- Local variables
11111 Nested : Elist_Id;
11113 -- Start of processing for Traverse_Body
11115 begin
11116 -- Nothing to do when there is no body
11118 if No (N) then
11119 return;
11121 elsif Nkind (N) /= N_Subprogram_Body then
11122 return;
11123 end if;
11125 -- Nothing to do if the body was already traversed during the processing
11126 -- of the same top-level scenario.
11128 if Is_Visited_Body (N) then
11129 return;
11131 -- Otherwise mark the body as traversed
11133 else
11134 Set_Is_Visited_Body (N);
11135 end if;
11137 Nested := Nested_Scenarios (Defining_Entity (N));
11139 -- The subprogram body was already examined as part of the elaboration
11140 -- graph starting from a different top-level scenario. There is no need
11141 -- to traverse the declarations and statements again because this will
11142 -- yield the exact same scenarios. Use the nested scenarios collected
11143 -- during the first inspection of the body.
11145 if Present (Nested) then
11146 Process_Nested_Scenarios (Nested);
11148 -- Otherwise examine the declarations and statements of the subprogram
11149 -- body for suitable scenarios, save and process them accordingly.
11151 else
11152 Find_And_Process_Nested_Scenarios;
11153 end if;
11154 end Traverse_Body;
11156 ---------------------------------
11157 -- Update_Elaboration_Scenario --
11158 ---------------------------------
11160 procedure Update_Elaboration_Scenario (New_N : Node_Id; Old_N : Node_Id) is
11161 procedure Update_SPARK_Scenario;
11162 pragma Inline (Update_SPARK_Scenario);
11163 -- Update the contents of table SPARK_Scenarios if Old_N is recorded
11164 -- there.
11166 procedure Update_Top_Level_Scenario;
11167 pragma Inline (Update_Top_Level_Scenario);
11168 -- Update the contexts of table Top_Level_Scenarios if Old_N is recorded
11169 -- there.
11171 ---------------------------
11172 -- Update_SPARK_Scenario --
11173 ---------------------------
11175 procedure Update_SPARK_Scenario is
11176 package Scenarios renames SPARK_Scenarios;
11178 begin
11179 if Is_Recorded_SPARK_Scenario (Old_N) then
11181 -- Performance note: list traversal
11183 for Index in Scenarios.First .. Scenarios.Last loop
11184 if Scenarios.Table (Index) = Old_N then
11185 Scenarios.Table (Index) := New_N;
11187 -- The old SPARK scenario is no longer recorded, but the new
11188 -- one is.
11190 Set_Is_Recorded_Top_Level_Scenario (Old_N, False);
11191 Set_Is_Recorded_Top_Level_Scenario (New_N);
11192 return;
11193 end if;
11194 end loop;
11196 -- A recorded SPARK scenario must be in the table of recorded
11197 -- SPARK scenarios.
11199 pragma Assert (False);
11200 end if;
11201 end Update_SPARK_Scenario;
11203 -------------------------------
11204 -- Update_Top_Level_Scenario --
11205 -------------------------------
11207 procedure Update_Top_Level_Scenario is
11208 package Scenarios renames Top_Level_Scenarios;
11210 begin
11211 if Is_Recorded_Top_Level_Scenario (Old_N) then
11213 -- Performance note: list traversal
11215 for Index in Scenarios.First .. Scenarios.Last loop
11216 if Scenarios.Table (Index) = Old_N then
11217 Scenarios.Table (Index) := New_N;
11219 -- The old top-level scenario is no longer recorded, but the
11220 -- new one is.
11222 Set_Is_Recorded_Top_Level_Scenario (Old_N, False);
11223 Set_Is_Recorded_Top_Level_Scenario (New_N);
11224 return;
11225 end if;
11226 end loop;
11228 -- A recorded top-level scenario must be in the table of recorded
11229 -- top-level scenarios.
11231 pragma Assert (False);
11232 end if;
11233 end Update_Top_Level_Scenario;
11235 -- Start of processing for Update_Elaboration_Requirement
11237 begin
11238 -- Nothing to do when the old and new scenarios are one and the same
11240 if Old_N = New_N then
11241 return;
11243 -- A scenario is being transformed by Atree.Rewrite. Update all relevant
11244 -- internal data structures to reflect this change. This ensures that a
11245 -- potential run-time conditional ABE check or a guaranteed ABE failure
11246 -- is inserted at the proper place in the tree.
11248 elsif Is_Scenario (Old_N) then
11249 Update_SPARK_Scenario;
11250 Update_Top_Level_Scenario;
11251 end if;
11252 end Update_Elaboration_Scenario;
11254 -------------------------
11255 -- Visited_Bodies_Hash --
11256 -------------------------
11258 function Visited_Bodies_Hash (Key : Node_Id) return Visited_Bodies_Index is
11259 begin
11260 return Visited_Bodies_Index (Key mod Visited_Bodies_Max);
11261 end Visited_Bodies_Hash;
11263 ---------------------------------------------------------------------------
11264 -- --
11265 -- L E G A C Y A C C E S S B E F O R E E L A B O R A T I O N --
11266 -- --
11267 -- M E C H A N I S M --
11268 -- --
11269 ---------------------------------------------------------------------------
11271 -- This section contains the implementation of the pre-18.x legacy ABE
11272 -- mechanism. The mechanism can be activated using switch -gnatH (legacy
11273 -- elaboration checking mode enabled).
11275 -----------------------------
11276 -- Description of Approach --
11277 -----------------------------
11279 -- Every non-static call that is encountered by Sem_Res results in a call
11280 -- to Check_Elab_Call, with N being the call node, and Outer set to its
11281 -- default value of True. In addition X'Access is treated like a call
11282 -- for the access-to-procedure case, and in SPARK mode only we also
11283 -- check variable references.
11285 -- The goal of Check_Elab_Call is to determine whether or not the reference
11286 -- in question can generate an access before elaboration error (raising
11287 -- Program_Error) either by directly calling a subprogram whose body
11288 -- has not yet been elaborated, or indirectly, by calling a subprogram
11289 -- whose body has been elaborated, but which contains a call to such a
11290 -- subprogram.
11292 -- In addition, in SPARK mode, we are checking for a variable reference in
11293 -- another package, which requires an explicit Elaborate_All pragma.
11295 -- The only references that we need to look at the outer level are
11296 -- references that occur in elaboration code. There are two cases. The
11297 -- reference can be at the outer level of elaboration code, or it can
11298 -- be within another unit, e.g. the elaboration code of a subprogram.
11300 -- In the case of an elaboration call at the outer level, we must trace
11301 -- all calls to outer level routines either within the current unit or to
11302 -- other units that are with'ed. For calls within the current unit, we can
11303 -- determine if the body has been elaborated or not, and if it has not,
11304 -- then a warning is generated.
11306 -- Note that there are two subcases. If the original call directly calls a
11307 -- subprogram whose body has not been elaborated, then we know that an ABE
11308 -- will take place, and we replace the call by a raise of Program_Error.
11309 -- If the call is indirect, then we don't know that the PE will be raised,
11310 -- since the call might be guarded by a conditional. In this case we set
11311 -- Do_Elab_Check on the call so that a dynamic check is generated, and
11312 -- output a warning.
11314 -- For calls to a subprogram in a with'ed unit or a 'Access or variable
11315 -- reference (SPARK mode case), we require that a pragma Elaborate_All
11316 -- or pragma Elaborate be present, or that the referenced unit have a
11317 -- pragma Preelaborate, pragma Pure, or pragma Elaborate_Body. If none
11318 -- of these conditions is met, then a warning is generated that a pragma
11319 -- Elaborate_All may be needed (error in the SPARK case), or an implicit
11320 -- pragma is generated.
11322 -- For the case of an elaboration call at some inner level, we are
11323 -- interested in tracing only calls to subprograms at the same level, i.e.
11324 -- those that can be called during elaboration. Any calls to outer level
11325 -- routines cannot cause ABE's as a result of the original call (there
11326 -- might be an outer level call to the subprogram from outside that causes
11327 -- the ABE, but that gets analyzed separately).
11329 -- Note that we never trace calls to inner level subprograms, since these
11330 -- cannot result in ABE's unless there is an elaboration problem at a lower
11331 -- level, which will be separately detected.
11333 -- Note on pragma Elaborate. The checking here assumes that a pragma
11334 -- Elaborate on a with'ed unit guarantees that subprograms within the unit
11335 -- can be called without causing an ABE. This is not in fact the case since
11336 -- pragma Elaborate does not guarantee the transitive coverage guaranteed
11337 -- by Elaborate_All. However, we decide to trust the user in this case.
11339 --------------------------------------
11340 -- Instantiation Elaboration Errors --
11341 --------------------------------------
11343 -- A special case arises when an instantiation appears in a context that is
11344 -- known to be before the body is elaborated, e.g.
11346 -- generic package x is ...
11347 -- ...
11348 -- package xx is new x;
11349 -- ...
11350 -- package body x is ...
11352 -- In this situation it is certain that an elaboration error will occur,
11353 -- and an unconditional raise Program_Error statement is inserted before
11354 -- the instantiation, and a warning generated.
11356 -- The problem is that in this case we have no place to put the body of
11357 -- the instantiation. We can't put it in the normal place, because it is
11358 -- too early, and will cause errors to occur as a result of referencing
11359 -- entities before they are declared.
11361 -- Our approach in this case is simply to avoid creating the body of the
11362 -- instantiation in such a case. The instantiation spec is modified to
11363 -- include dummy bodies for all subprograms, so that the resulting code
11364 -- does not contain subprogram specs with no corresponding bodies.
11366 -- The following table records the recursive call chain for output in the
11367 -- Output routine. Each entry records the call node and the entity of the
11368 -- called routine. The number of entries in the table (i.e. the value of
11369 -- Elab_Call.Last) indicates the current depth of recursion and is used to
11370 -- identify the outer level.
11372 type Elab_Call_Element is record
11373 Cloc : Source_Ptr;
11374 Ent : Entity_Id;
11375 end record;
11377 package Elab_Call is new Table.Table
11378 (Table_Component_Type => Elab_Call_Element,
11379 Table_Index_Type => Int,
11380 Table_Low_Bound => 1,
11381 Table_Initial => 50,
11382 Table_Increment => 100,
11383 Table_Name => "Elab_Call");
11385 -- The following table records all calls that have been processed starting
11386 -- from an outer level call. The table prevents both infinite recursion and
11387 -- useless reanalysis of calls within the same context. The use of context
11388 -- is important because it allows for proper checks in more complex code:
11390 -- if ... then
11391 -- Call; -- requires a check
11392 -- Call; -- does not need a check thanks to the table
11393 -- elsif ... then
11394 -- Call; -- requires a check, different context
11395 -- end if;
11397 -- Call; -- requires a check, different context
11399 type Visited_Element is record
11400 Subp_Id : Entity_Id;
11401 -- The entity of the subprogram being called
11403 Context : Node_Id;
11404 -- The context where the call to the subprogram occurs
11405 end record;
11407 package Elab_Visited is new Table.Table
11408 (Table_Component_Type => Visited_Element,
11409 Table_Index_Type => Int,
11410 Table_Low_Bound => 1,
11411 Table_Initial => 200,
11412 Table_Increment => 100,
11413 Table_Name => "Elab_Visited");
11415 -- The following table records delayed calls which must be examined after
11416 -- all generic bodies have been instantiated.
11418 type Delay_Element is record
11419 N : Node_Id;
11420 -- The parameter N from the call to Check_Internal_Call. Note that this
11421 -- node may get rewritten over the delay period by expansion in the call
11422 -- case (but not in the instantiation case).
11424 E : Entity_Id;
11425 -- The parameter E from the call to Check_Internal_Call
11427 Orig_Ent : Entity_Id;
11428 -- The parameter Orig_Ent from the call to Check_Internal_Call
11430 Curscop : Entity_Id;
11431 -- The current scope of the call. This is restored when we complete the
11432 -- delayed call, so that we do this in the right scope.
11434 Outer_Scope : Entity_Id;
11435 -- Save scope of outer level call
11437 From_Elab_Code : Boolean;
11438 -- Save indication of whether this call is from elaboration code
11440 In_Task_Activation : Boolean;
11441 -- Save indication of whether this call is from a task body. Tasks are
11442 -- activated at the "begin", which is after all local procedure bodies,
11443 -- so calls to those procedures can't fail, even if they occur after the
11444 -- task body.
11446 From_SPARK_Code : Boolean;
11447 -- Save indication of whether this call is under SPARK_Mode => On
11448 end record;
11450 package Delay_Check is new Table.Table
11451 (Table_Component_Type => Delay_Element,
11452 Table_Index_Type => Int,
11453 Table_Low_Bound => 1,
11454 Table_Initial => 1000,
11455 Table_Increment => 100,
11456 Table_Name => "Delay_Check");
11458 C_Scope : Entity_Id;
11459 -- Top-level scope of current scope. Compute this only once at the outer
11460 -- level, i.e. for a call to Check_Elab_Call from outside this unit.
11462 Outer_Level_Sloc : Source_Ptr;
11463 -- Save Sloc value for outer level call node for comparisons of source
11464 -- locations. A body is too late if it appears after the *outer* level
11465 -- call, not the particular call that is being analyzed.
11467 From_Elab_Code : Boolean;
11468 -- This flag shows whether the outer level call currently being examined
11469 -- is or is not in elaboration code. We are only interested in calls to
11470 -- routines in other units if this flag is True.
11472 In_Task_Activation : Boolean := False;
11473 -- This flag indicates whether we are performing elaboration checks on task
11474 -- bodies, at the point of activation. If true, we do not raise
11475 -- Program_Error for calls to local procedures, because all local bodies
11476 -- are known to be elaborated. However, we still need to trace such calls,
11477 -- because a local procedure could call a procedure in another package,
11478 -- so we might need an implicit Elaborate_All.
11480 Delaying_Elab_Checks : Boolean := True;
11481 -- This is set True till the compilation is complete, including the
11482 -- insertion of all instance bodies. Then when Check_Elab_Calls is called,
11483 -- the delay table is used to make the delayed calls and this flag is reset
11484 -- to False, so that the calls are processed.
11486 -----------------------
11487 -- Local Subprograms --
11488 -----------------------
11490 -- Note: Outer_Scope in all following specs represents the scope of
11491 -- interest of the outer level call. If it is set to Standard_Standard,
11492 -- then it means the outer level call was at elaboration level, and that
11493 -- thus all calls are of interest. If it was set to some other scope,
11494 -- then the original call was an inner call, and we are not interested
11495 -- in calls that go outside this scope.
11497 procedure Activate_Elaborate_All_Desirable (N : Node_Id; U : Entity_Id);
11498 -- Analysis of construct N shows that we should set Elaborate_All_Desirable
11499 -- for the WITH clause for unit U (which will always be present). A special
11500 -- case is when N is a function or procedure instantiation, in which case
11501 -- it is sufficient to set Elaborate_Desirable, since in this case there is
11502 -- no possibility of transitive elaboration issues.
11504 procedure Check_A_Call
11505 (N : Node_Id;
11506 E : Entity_Id;
11507 Outer_Scope : Entity_Id;
11508 Inter_Unit_Only : Boolean;
11509 Generate_Warnings : Boolean := True;
11510 In_Init_Proc : Boolean := False);
11511 -- This is the internal recursive routine that is called to check for
11512 -- possible elaboration error. The argument N is a subprogram call or
11513 -- generic instantiation, or 'Access attribute reference to be checked, and
11514 -- E is the entity of the called subprogram, or instantiated generic unit,
11515 -- or subprogram referenced by 'Access.
11517 -- In SPARK mode, N can also be a variable reference, since in SPARK this
11518 -- also triggers a requirement for Elaborate_All, and in this case E is the
11519 -- entity being referenced.
11521 -- Outer_Scope is the outer level scope for the original reference.
11522 -- Inter_Unit_Only is set if the call is only to be checked in the
11523 -- case where it is to another unit (and skipped if within a unit).
11524 -- Generate_Warnings is set to False to suppress warning messages about
11525 -- missing pragma Elaborate_All's. These messages are not wanted for
11526 -- inner calls in the dynamic model. Note that an instance of the Access
11527 -- attribute applied to a subprogram also generates a call to this
11528 -- procedure (since the referenced subprogram may be called later
11529 -- indirectly). Flag In_Init_Proc should be set whenever the current
11530 -- context is a type init proc.
11532 -- Note: this might better be called Check_A_Reference to recognize the
11533 -- variable case for SPARK, but we prefer to retain the historical name
11534 -- since in practice this is mostly about checking calls for the possible
11535 -- occurrence of an access-before-elaboration exception.
11537 procedure Check_Bad_Instantiation (N : Node_Id);
11538 -- N is a node for an instantiation (if called with any other node kind,
11539 -- Check_Bad_Instantiation ignores the call). This subprogram checks for
11540 -- the special case of a generic instantiation of a generic spec in the
11541 -- same declarative part as the instantiation where a body is present and
11542 -- has not yet been seen. This is an obvious error, but needs to be checked
11543 -- specially at the time of the instantiation, since it is a case where we
11544 -- cannot insert the body anywhere. If this case is detected, warnings are
11545 -- generated, and a raise of Program_Error is inserted. In addition any
11546 -- subprograms in the generic spec are stubbed, and the Bad_Instantiation
11547 -- flag is set on the instantiation node. The caller in Sem_Ch12 uses this
11548 -- flag as an indication that no attempt should be made to insert an
11549 -- instance body.
11551 procedure Check_Internal_Call
11552 (N : Node_Id;
11553 E : Entity_Id;
11554 Outer_Scope : Entity_Id;
11555 Orig_Ent : Entity_Id);
11556 -- N is a function call or procedure statement call node and E is the
11557 -- entity of the called function, which is within the current compilation
11558 -- unit (where subunits count as part of the parent). This call checks if
11559 -- this call, or any call within any accessed body could cause an ABE, and
11560 -- if so, outputs a warning. Orig_Ent differs from E only in the case of
11561 -- renamings, and points to the original name of the entity. This is used
11562 -- for error messages. Outer_Scope is the outer level scope for the
11563 -- original call.
11565 procedure Check_Internal_Call_Continue
11566 (N : Node_Id;
11567 E : Entity_Id;
11568 Outer_Scope : Entity_Id;
11569 Orig_Ent : Entity_Id);
11570 -- The processing for Check_Internal_Call is divided up into two phases,
11571 -- and this represents the second phase. The second phase is delayed if
11572 -- Delaying_Elab_Checks is set to True. In this delayed case, the first
11573 -- phase makes an entry in the Delay_Check table, which is processed when
11574 -- Check_Elab_Calls is called. N, E and Orig_Ent are as for the call to
11575 -- Check_Internal_Call. Outer_Scope is the outer level scope for the
11576 -- original call.
11578 function Get_Referenced_Ent (N : Node_Id) return Entity_Id;
11579 -- N is either a function or procedure call or an access attribute that
11580 -- references a subprogram. This call retrieves the relevant entity. If
11581 -- this is a call to a protected subprogram, the entity is a selected
11582 -- component. The callable entity may be absent, in which case Empty is
11583 -- returned. This happens with non-analyzed calls in nested generics.
11585 -- If SPARK_Mode is On, then N can also be a reference to an E_Variable
11586 -- entity, in which case, the value returned is simply this entity.
11588 function Has_Generic_Body (N : Node_Id) return Boolean;
11589 -- N is a generic package instantiation node, and this routine determines
11590 -- if this package spec does in fact have a generic body. If so, then
11591 -- True is returned, otherwise False. Note that this is not at all the
11592 -- same as checking if the unit requires a body, since it deals with
11593 -- the case of optional bodies accurately (i.e. if a body is optional,
11594 -- then it looks to see if a body is actually present). Note: this
11595 -- function can only do a fully correct job if in generating code mode
11596 -- where all bodies have to be present. If we are operating in semantics
11597 -- check only mode, then in some cases of optional bodies, a result of
11598 -- False may incorrectly be given. In practice this simply means that
11599 -- some cases of warnings for incorrect order of elaboration will only
11600 -- be given when generating code, which is not a big problem (and is
11601 -- inevitable, given the optional body semantics of Ada).
11603 procedure Insert_Elab_Check (N : Node_Id; C : Node_Id := Empty);
11604 -- Given code for an elaboration check (or unconditional raise if the check
11605 -- is not needed), inserts the code in the appropriate place. N is the call
11606 -- or instantiation node for which the check code is required. C is the
11607 -- test whose failure triggers the raise.
11609 function Is_Call_Of_Generic_Formal (N : Node_Id) return Boolean;
11610 -- Returns True if node N is a call to a generic formal subprogram
11612 function Is_Finalization_Procedure (Id : Entity_Id) return Boolean;
11613 -- Determine whether entity Id denotes a [Deep_]Finalize procedure
11615 procedure Output_Calls
11616 (N : Node_Id;
11617 Check_Elab_Flag : Boolean);
11618 -- Outputs chain of calls stored in the Elab_Call table. The caller has
11619 -- already generated the main warning message, so the warnings generated
11620 -- are all continuation messages. The argument is the call node at which
11621 -- the messages are to be placed. When Check_Elab_Flag is set, calls are
11622 -- enumerated only when flag Elab_Warning is set for the dynamic case or
11623 -- when flag Elab_Info_Messages is set for the static case.
11625 function Same_Elaboration_Scope (Scop1, Scop2 : Entity_Id) return Boolean;
11626 -- Given two scopes, determine whether they are the same scope from an
11627 -- elaboration point of view, i.e. packages and blocks are ignored.
11629 procedure Set_C_Scope;
11630 -- On entry C_Scope is set to some scope. On return, C_Scope is reset
11631 -- to be the enclosing compilation unit of this scope.
11633 procedure Set_Elaboration_Constraint
11634 (Call : Node_Id;
11635 Subp : Entity_Id;
11636 Scop : Entity_Id);
11637 -- The current unit U may depend semantically on some unit P that is not
11638 -- in the current context. If there is an elaboration call that reaches P,
11639 -- we need to indicate that P requires an Elaborate_All, but this is not
11640 -- effective in U's ali file, if there is no with_clause for P. In this
11641 -- case we add the Elaborate_All on the unit Q that directly or indirectly
11642 -- makes P available. This can happen in two cases:
11644 -- a) Q declares a subtype of a type declared in P, and the call is an
11645 -- initialization call for an object of that subtype.
11647 -- b) Q declares an object of some tagged type whose root type is
11648 -- declared in P, and the initialization call uses object notation on
11649 -- that object to reach a primitive operation or a classwide operation
11650 -- declared in P.
11652 -- If P appears in the context of U, the current processing is correct.
11653 -- Otherwise we must identify these two cases to retrieve Q and place the
11654 -- Elaborate_All_Desirable on it.
11656 function Spec_Entity (E : Entity_Id) return Entity_Id;
11657 -- Given a compilation unit entity, if it is a spec entity, it is returned
11658 -- unchanged. If it is a body entity, then the spec for the corresponding
11659 -- spec is returned
11661 function Within (E1, E2 : Entity_Id) return Boolean;
11662 -- Given two scopes E1 and E2, returns True if E1 is equal to E2, or is one
11663 -- of its contained scopes, False otherwise.
11665 function Within_Elaborate_All
11666 (Unit : Unit_Number_Type;
11667 E : Entity_Id) return Boolean;
11668 -- Return True if we are within the scope of an Elaborate_All for E, or if
11669 -- we are within the scope of an Elaborate_All for some other unit U, and U
11670 -- with's E. This prevents spurious warnings when the called entity is
11671 -- renamed within U, or in case of generic instances.
11673 --------------------------------------
11674 -- Activate_Elaborate_All_Desirable --
11675 --------------------------------------
11677 procedure Activate_Elaborate_All_Desirable (N : Node_Id; U : Entity_Id) is
11678 UN : constant Unit_Number_Type := Get_Code_Unit (N);
11679 CU : constant Node_Id := Cunit (UN);
11680 UE : constant Entity_Id := Cunit_Entity (UN);
11681 Unm : constant Unit_Name_Type := Unit_Name (UN);
11682 CI : constant List_Id := Context_Items (CU);
11683 Itm : Node_Id;
11684 Ent : Entity_Id;
11686 procedure Add_To_Context_And_Mark (Itm : Node_Id);
11687 -- This procedure is called when the elaborate indication must be
11688 -- applied to a unit not in the context of the referencing unit. The
11689 -- unit gets added to the context as an implicit with.
11691 function In_Withs_Of (UEs : Entity_Id) return Boolean;
11692 -- UEs is the spec entity of a unit. If the unit to be marked is
11693 -- in the context item list of this unit spec, then the call returns
11694 -- True and Itm is left set to point to the relevant N_With_Clause node.
11696 procedure Set_Elab_Flag (Itm : Node_Id);
11697 -- Sets Elaborate_[All_]Desirable as appropriate on Itm
11699 -----------------------------
11700 -- Add_To_Context_And_Mark --
11701 -----------------------------
11703 procedure Add_To_Context_And_Mark (Itm : Node_Id) is
11704 CW : constant Node_Id :=
11705 Make_With_Clause (Sloc (Itm),
11706 Name => Name (Itm));
11708 begin
11709 Set_Library_Unit (CW, Library_Unit (Itm));
11710 Set_Implicit_With (CW);
11712 -- Set elaborate all desirable on copy and then append the copy to
11713 -- the list of body with's and we are done.
11715 Set_Elab_Flag (CW);
11716 Append_To (CI, CW);
11717 end Add_To_Context_And_Mark;
11719 -----------------
11720 -- In_Withs_Of --
11721 -----------------
11723 function In_Withs_Of (UEs : Entity_Id) return Boolean is
11724 UNs : constant Unit_Number_Type := Get_Source_Unit (UEs);
11725 CUs : constant Node_Id := Cunit (UNs);
11726 CIs : constant List_Id := Context_Items (CUs);
11728 begin
11729 Itm := First (CIs);
11730 while Present (Itm) loop
11731 if Nkind (Itm) = N_With_Clause then
11732 Ent :=
11733 Cunit_Entity (Get_Cunit_Unit_Number (Library_Unit (Itm)));
11735 if U = Ent then
11736 return True;
11737 end if;
11738 end if;
11740 Next (Itm);
11741 end loop;
11743 return False;
11744 end In_Withs_Of;
11746 -------------------
11747 -- Set_Elab_Flag --
11748 -------------------
11750 procedure Set_Elab_Flag (Itm : Node_Id) is
11751 begin
11752 if Nkind (N) in N_Subprogram_Instantiation then
11753 Set_Elaborate_Desirable (Itm);
11754 else
11755 Set_Elaborate_All_Desirable (Itm);
11756 end if;
11757 end Set_Elab_Flag;
11759 -- Start of processing for Activate_Elaborate_All_Desirable
11761 begin
11762 -- Do not set binder indication if expansion is disabled, as when
11763 -- compiling a generic unit.
11765 if not Expander_Active then
11766 return;
11767 end if;
11769 -- If an instance of a generic package contains a controlled object (so
11770 -- we're calling Initialize at elaboration time), and the instance is in
11771 -- a package body P that says "with P;", then we need to return without
11772 -- adding "pragma Elaborate_All (P);" to P.
11774 if U = Main_Unit_Entity then
11775 return;
11776 end if;
11778 Itm := First (CI);
11779 while Present (Itm) loop
11780 if Nkind (Itm) = N_With_Clause then
11781 Ent := Cunit_Entity (Get_Cunit_Unit_Number (Library_Unit (Itm)));
11783 -- If we find it, then mark elaborate all desirable and return
11785 if U = Ent then
11786 Set_Elab_Flag (Itm);
11787 return;
11788 end if;
11789 end if;
11791 Next (Itm);
11792 end loop;
11794 -- If we fall through then the with clause is not present in the
11795 -- current unit. One legitimate possibility is that the with clause
11796 -- is present in the spec when we are a body.
11798 if Is_Body_Name (Unm)
11799 and then In_Withs_Of (Spec_Entity (UE))
11800 then
11801 Add_To_Context_And_Mark (Itm);
11802 return;
11803 end if;
11805 -- Similarly, we may be in the spec or body of a child unit, where
11806 -- the unit in question is with'ed by some ancestor of the child unit.
11808 if Is_Child_Name (Unm) then
11809 declare
11810 Pkg : Entity_Id;
11812 begin
11813 Pkg := UE;
11814 loop
11815 Pkg := Scope (Pkg);
11816 exit when Pkg = Standard_Standard;
11818 if In_Withs_Of (Pkg) then
11819 Add_To_Context_And_Mark (Itm);
11820 return;
11821 end if;
11822 end loop;
11823 end;
11824 end if;
11826 -- Here if we do not find with clause on spec or body. We just ignore
11827 -- this case; it means that the elaboration involves some other unit
11828 -- than the unit being compiled, and will be caught elsewhere.
11829 end Activate_Elaborate_All_Desirable;
11831 ------------------
11832 -- Check_A_Call --
11833 ------------------
11835 procedure Check_A_Call
11836 (N : Node_Id;
11837 E : Entity_Id;
11838 Outer_Scope : Entity_Id;
11839 Inter_Unit_Only : Boolean;
11840 Generate_Warnings : Boolean := True;
11841 In_Init_Proc : Boolean := False)
11843 Access_Case : constant Boolean := Nkind (N) = N_Attribute_Reference;
11844 -- Indicates if we have Access attribute case
11846 function Call_To_Instance_From_Outside (Id : Entity_Id) return Boolean;
11847 -- True if we're calling an instance of a generic subprogram, or a
11848 -- subprogram in an instance of a generic package, and the call is
11849 -- outside that instance.
11851 procedure Elab_Warning
11852 (Msg_D : String;
11853 Msg_S : String;
11854 Ent : Node_Or_Entity_Id);
11855 -- Generate a call to Error_Msg_NE with parameters Msg_D or Msg_S (for
11856 -- dynamic or static elaboration model), N and Ent. Msg_D is a real
11857 -- warning (output if Msg_D is non-null and Elab_Warnings is set),
11858 -- Msg_S is an info message (output if Elab_Info_Messages is set).
11860 function Find_W_Scope return Entity_Id;
11861 -- Find top-level scope for called entity (not following renamings
11862 -- or derivations). This is where the Elaborate_All will go if it is
11863 -- needed. We start with the called entity, except in the case of an
11864 -- initialization procedure outside the current package, where the init
11865 -- proc is in the root package, and we start from the entity of the name
11866 -- in the call.
11868 -----------------------------------
11869 -- Call_To_Instance_From_Outside --
11870 -----------------------------------
11872 function Call_To_Instance_From_Outside (Id : Entity_Id) return Boolean is
11873 Scop : Entity_Id := Id;
11875 begin
11876 loop
11877 if Scop = Standard_Standard then
11878 return False;
11879 end if;
11881 if Is_Generic_Instance (Scop) then
11882 return not In_Open_Scopes (Scop);
11883 end if;
11885 Scop := Scope (Scop);
11886 end loop;
11887 end Call_To_Instance_From_Outside;
11889 ------------------
11890 -- Elab_Warning --
11891 ------------------
11893 procedure Elab_Warning
11894 (Msg_D : String;
11895 Msg_S : String;
11896 Ent : Node_Or_Entity_Id)
11898 begin
11899 -- Dynamic elaboration checks, real warning
11901 if Dynamic_Elaboration_Checks then
11902 if not Access_Case then
11903 if Msg_D /= "" and then Elab_Warnings then
11904 Error_Msg_NE (Msg_D, N, Ent);
11905 end if;
11907 -- In the access case emit first warning message as well,
11908 -- otherwise list of calls will appear as errors.
11910 elsif Elab_Warnings then
11911 Error_Msg_NE (Msg_S, N, Ent);
11912 end if;
11914 -- Static elaboration checks, info message
11916 else
11917 if Elab_Info_Messages then
11918 Error_Msg_NE (Msg_S, N, Ent);
11919 end if;
11920 end if;
11921 end Elab_Warning;
11923 ------------------
11924 -- Find_W_Scope --
11925 ------------------
11927 function Find_W_Scope return Entity_Id is
11928 Refed_Ent : constant Entity_Id := Get_Referenced_Ent (N);
11929 W_Scope : Entity_Id;
11931 begin
11932 if Is_Init_Proc (Refed_Ent)
11933 and then not In_Same_Extended_Unit (N, Refed_Ent)
11934 then
11935 W_Scope := Scope (Refed_Ent);
11936 else
11937 W_Scope := E;
11938 end if;
11940 -- Now loop through scopes to get to the enclosing compilation unit
11942 while not Is_Compilation_Unit (W_Scope) loop
11943 W_Scope := Scope (W_Scope);
11944 end loop;
11946 return W_Scope;
11947 end Find_W_Scope;
11949 -- Local variables
11951 Inst_Case : constant Boolean := Nkind (N) in N_Generic_Instantiation;
11952 -- Indicates if we have instantiation case
11954 Loc : constant Source_Ptr := Sloc (N);
11956 Variable_Case : constant Boolean :=
11957 Nkind (N) in N_Has_Entity
11958 and then Present (Entity (N))
11959 and then Ekind (Entity (N)) = E_Variable;
11960 -- Indicates if we have variable reference case
11962 W_Scope : constant Entity_Id := Find_W_Scope;
11963 -- Top-level scope of directly called entity for subprogram. This
11964 -- differs from E_Scope in the case where renamings or derivations
11965 -- are involved, since it does not follow these links. W_Scope is
11966 -- generally in a visible unit, and it is this scope that may require
11967 -- an Elaborate_All. However, there are some cases (initialization
11968 -- calls and calls involving object notation) where W_Scope might not
11969 -- be in the context of the current unit, and there is an intermediate
11970 -- package that is, in which case the Elaborate_All has to be placed
11971 -- on this intermediate package. These special cases are handled in
11972 -- Set_Elaboration_Constraint.
11974 Ent : Entity_Id;
11975 Callee_Unit_Internal : Boolean;
11976 Caller_Unit_Internal : Boolean;
11977 Decl : Node_Id;
11978 Inst_Callee : Source_Ptr;
11979 Inst_Caller : Source_Ptr;
11980 Unit_Callee : Unit_Number_Type;
11981 Unit_Caller : Unit_Number_Type;
11983 Body_Acts_As_Spec : Boolean;
11984 -- Set to true if call is to body acting as spec (no separate spec)
11986 Cunit_SC : Boolean := False;
11987 -- Set to suppress dynamic elaboration checks where one of the
11988 -- enclosing scopes has Elaboration_Checks_Suppressed set, or else
11989 -- if a pragma Elaborate[_All] applies to that scope, in which case
11990 -- warnings on the scope are also suppressed. For the internal case,
11991 -- we ignore this flag.
11993 E_Scope : Entity_Id;
11994 -- Top-level scope of entity for called subprogram. This value includes
11995 -- following renamings and derivations, so this scope can be in a
11996 -- non-visible unit. This is the scope that is to be investigated to
11997 -- see whether an elaboration check is required.
11999 Is_DIC : Boolean;
12000 -- Flag set when the subprogram being invoked is the procedure generated
12001 -- for pragma Default_Initial_Condition.
12003 SPARK_Elab_Errors : Boolean;
12004 -- Flag set when an entity is called or a variable is read during SPARK
12005 -- dynamic elaboration.
12007 -- Start of processing for Check_A_Call
12009 begin
12010 -- If the call is known to be within a local Suppress Elaboration
12011 -- pragma, nothing to check. This can happen in task bodies. But
12012 -- we ignore this for a call to a generic formal.
12014 if Nkind (N) in N_Subprogram_Call
12015 and then No_Elaboration_Check (N)
12016 and then not Is_Call_Of_Generic_Formal (N)
12017 then
12018 return;
12020 -- If this is a rewrite of a Valid_Scalars attribute, then nothing to
12021 -- check, we don't mind in this case if the call occurs before the body
12022 -- since this is all generated code.
12024 elsif Nkind (Original_Node (N)) = N_Attribute_Reference
12025 and then Attribute_Name (Original_Node (N)) = Name_Valid_Scalars
12026 then
12027 return;
12029 -- Intrinsics such as instances of Unchecked_Deallocation do not have
12030 -- any body, so elaboration checking is not needed, and would be wrong.
12032 elsif Is_Intrinsic_Subprogram (E) then
12033 return;
12035 -- Do not consider references to internal variables for SPARK semantics
12037 elsif Variable_Case and then not Comes_From_Source (E) then
12038 return;
12039 end if;
12041 -- Proceed with check
12043 Ent := E;
12045 -- For a variable reference, just set Body_Acts_As_Spec to False
12047 if Variable_Case then
12048 Body_Acts_As_Spec := False;
12050 -- Additional checks for all other cases
12052 else
12053 -- Go to parent for derived subprogram, or to original subprogram in
12054 -- the case of a renaming (Alias covers both these cases).
12056 loop
12057 if (Suppress_Elaboration_Warnings (Ent)
12058 or else Elaboration_Checks_Suppressed (Ent))
12059 and then (Inst_Case or else No (Alias (Ent)))
12060 then
12061 return;
12062 end if;
12064 -- Nothing to do for imported entities
12066 if Is_Imported (Ent) then
12067 return;
12068 end if;
12070 exit when Inst_Case or else No (Alias (Ent));
12071 Ent := Alias (Ent);
12072 end loop;
12074 Decl := Unit_Declaration_Node (Ent);
12076 if Nkind (Decl) = N_Subprogram_Body then
12077 Body_Acts_As_Spec := True;
12079 elsif Nkind_In (Decl, N_Subprogram_Declaration,
12080 N_Subprogram_Body_Stub)
12081 or else Inst_Case
12082 then
12083 Body_Acts_As_Spec := False;
12085 -- If we have none of an instantiation, subprogram body or subprogram
12086 -- declaration, or in the SPARK case, a variable reference, then
12087 -- it is not a case that we want to check. (One case is a call to a
12088 -- generic formal subprogram, where we do not want the check in the
12089 -- template).
12091 else
12092 return;
12093 end if;
12094 end if;
12096 E_Scope := Ent;
12097 loop
12098 if Elaboration_Checks_Suppressed (E_Scope)
12099 or else Suppress_Elaboration_Warnings (E_Scope)
12100 then
12101 Cunit_SC := True;
12102 end if;
12104 -- Exit when we get to compilation unit, not counting subunits
12106 exit when Is_Compilation_Unit (E_Scope)
12107 and then (Is_Child_Unit (E_Scope)
12108 or else Scope (E_Scope) = Standard_Standard);
12110 pragma Assert (E_Scope /= Standard_Standard);
12112 -- Move up a scope looking for compilation unit
12114 E_Scope := Scope (E_Scope);
12115 end loop;
12117 -- No checks needed for pure or preelaborated compilation units
12119 if Is_Pure (E_Scope) or else Is_Preelaborated (E_Scope) then
12120 return;
12121 end if;
12123 -- If the generic entity is within a deeper instance than we are, then
12124 -- either the instantiation to which we refer itself caused an ABE, in
12125 -- which case that will be handled separately, or else we know that the
12126 -- body we need appears as needed at the point of the instantiation.
12127 -- However, this assumption is only valid if we are in static mode.
12129 if not Dynamic_Elaboration_Checks
12130 and then
12131 Instantiation_Depth (Sloc (Ent)) > Instantiation_Depth (Sloc (N))
12132 then
12133 return;
12134 end if;
12136 -- Do not give a warning for a package with no body
12138 if Ekind (Ent) = E_Generic_Package and then not Has_Generic_Body (N) then
12139 return;
12140 end if;
12142 -- Case of entity is in same unit as call or instantiation. In the
12143 -- instantiation case, W_Scope may be different from E_Scope; we want
12144 -- the unit in which the instantiation occurs, since we're analyzing
12145 -- based on the expansion.
12147 if W_Scope = C_Scope then
12148 if not Inter_Unit_Only then
12149 Check_Internal_Call (N, Ent, Outer_Scope, E);
12150 end if;
12152 return;
12153 end if;
12155 -- Case of entity is not in current unit (i.e. with'ed unit case)
12157 -- We are only interested in such calls if the outer call was from
12158 -- elaboration code, or if we are in Dynamic_Elaboration_Checks mode.
12160 if not From_Elab_Code and then not Dynamic_Elaboration_Checks then
12161 return;
12162 end if;
12164 -- Nothing to do if some scope said that no checks were required
12166 if Cunit_SC then
12167 return;
12168 end if;
12170 -- Nothing to do for a generic instance, because a call to an instance
12171 -- cannot fail the elaboration check, because the body of the instance
12172 -- is always elaborated immediately after the spec.
12174 if Call_To_Instance_From_Outside (Ent) then
12175 return;
12176 end if;
12178 -- Nothing to do if subprogram with no separate spec. However, a call
12179 -- to Deep_Initialize may result in a call to a user-defined Initialize
12180 -- procedure, which imposes a body dependency. This happens only if the
12181 -- type is controlled and the Initialize procedure is not inherited.
12183 if Body_Acts_As_Spec then
12184 if Is_TSS (Ent, TSS_Deep_Initialize) then
12185 declare
12186 Typ : constant Entity_Id := Etype (First_Formal (Ent));
12187 Init : Entity_Id;
12189 begin
12190 if not Is_Controlled (Typ) then
12191 return;
12192 else
12193 Init := Find_Prim_Op (Typ, Name_Initialize);
12195 if Comes_From_Source (Init) then
12196 Ent := Init;
12197 else
12198 return;
12199 end if;
12200 end if;
12201 end;
12203 else
12204 return;
12205 end if;
12206 end if;
12208 -- Check cases of internal units
12210 Callee_Unit_Internal := In_Internal_Unit (E_Scope);
12212 -- Do not give a warning if the with'ed unit is internal and this is
12213 -- the generic instantiation case (this saves a lot of hassle dealing
12214 -- with the Text_IO special child units)
12216 if Callee_Unit_Internal and Inst_Case then
12217 return;
12218 end if;
12220 if C_Scope = Standard_Standard then
12221 Caller_Unit_Internal := False;
12222 else
12223 Caller_Unit_Internal := In_Internal_Unit (C_Scope);
12224 end if;
12226 -- Do not give a warning if the with'ed unit is internal and the caller
12227 -- is not internal (since the binder always elaborates internal units
12228 -- first).
12230 if Callee_Unit_Internal and not Caller_Unit_Internal then
12231 return;
12232 end if;
12234 -- For now, if debug flag -gnatdE is not set, do no checking for one
12235 -- internal unit withing another. This fixes the problem with the sgi
12236 -- build and storage errors. To be resolved later ???
12238 if (Callee_Unit_Internal and Caller_Unit_Internal)
12239 and not Debug_Flag_EE
12240 then
12241 return;
12242 end if;
12244 if Is_TSS (E, TSS_Deep_Initialize) then
12245 Ent := E;
12246 end if;
12248 -- If the call is in an instance, and the called entity is not
12249 -- defined in the same instance, then the elaboration issue focuses
12250 -- around the unit containing the template, it is this unit that
12251 -- requires an Elaborate_All.
12253 -- However, if we are doing dynamic elaboration, we need to chase the
12254 -- call in the usual manner.
12256 -- We also need to chase the call in the usual manner if it is a call
12257 -- to a generic formal parameter, since that case was not handled as
12258 -- part of the processing of the template.
12260 Inst_Caller := Instantiation (Get_Source_File_Index (Sloc (N)));
12261 Inst_Callee := Instantiation (Get_Source_File_Index (Sloc (Ent)));
12263 if Inst_Caller = No_Location then
12264 Unit_Caller := No_Unit;
12265 else
12266 Unit_Caller := Get_Source_Unit (N);
12267 end if;
12269 if Inst_Callee = No_Location then
12270 Unit_Callee := No_Unit;
12271 else
12272 Unit_Callee := Get_Source_Unit (Ent);
12273 end if;
12275 if Unit_Caller /= No_Unit
12276 and then Unit_Callee /= Unit_Caller
12277 and then not Dynamic_Elaboration_Checks
12278 and then not Is_Call_Of_Generic_Formal (N)
12279 then
12280 E_Scope := Spec_Entity (Cunit_Entity (Unit_Caller));
12282 -- If we don't get a spec entity, just ignore call. Not quite
12283 -- clear why this check is necessary. ???
12285 if No (E_Scope) then
12286 return;
12287 end if;
12289 -- Otherwise step to enclosing compilation unit
12291 while not Is_Compilation_Unit (E_Scope) loop
12292 E_Scope := Scope (E_Scope);
12293 end loop;
12295 -- For the case where N is not an instance, and is not a call within
12296 -- instance to other than a generic formal, we recompute E_Scope
12297 -- for the error message, since we do NOT want to go to the unit
12298 -- that has the ultimate declaration in the case of renaming and
12299 -- derivation and we also want to go to the generic unit in the
12300 -- case of an instance, and no further.
12302 else
12303 -- Loop to carefully follow renamings and derivations one step
12304 -- outside the current unit, but not further.
12306 if not (Inst_Case or Variable_Case)
12307 and then Present (Alias (Ent))
12308 then
12309 E_Scope := Alias (Ent);
12310 else
12311 E_Scope := Ent;
12312 end if;
12314 loop
12315 while not Is_Compilation_Unit (E_Scope) loop
12316 E_Scope := Scope (E_Scope);
12317 end loop;
12319 -- If E_Scope is the same as C_Scope, it means that there
12320 -- definitely was a local renaming or derivation, and we
12321 -- are not yet out of the current unit.
12323 exit when E_Scope /= C_Scope;
12324 Ent := Alias (Ent);
12325 E_Scope := Ent;
12327 -- If no alias, there could be a previous error, but not if we've
12328 -- already reached the outermost level (Standard).
12330 if No (Ent) then
12331 return;
12332 end if;
12333 end loop;
12334 end if;
12336 if Within_Elaborate_All (Current_Sem_Unit, E_Scope) then
12337 return;
12338 end if;
12340 -- Determine whether the Default_Initial_Condition procedure of some
12341 -- type is being invoked.
12343 Is_DIC := Ekind (Ent) = E_Procedure and then Is_DIC_Procedure (Ent);
12345 -- Checks related to Default_Initial_Condition fall under the SPARK
12346 -- umbrella because this is a SPARK-specific annotation.
12348 SPARK_Elab_Errors :=
12349 SPARK_Mode = On and (Is_DIC or Dynamic_Elaboration_Checks);
12351 -- Now check if an Elaborate_All (or dynamic check) is needed
12353 if (Elab_Info_Messages or Elab_Warnings or SPARK_Elab_Errors)
12354 and then Generate_Warnings
12355 and then not Suppress_Elaboration_Warnings (Ent)
12356 and then not Elaboration_Checks_Suppressed (Ent)
12357 and then not Suppress_Elaboration_Warnings (E_Scope)
12358 and then not Elaboration_Checks_Suppressed (E_Scope)
12359 then
12360 -- Instantiation case
12362 if Inst_Case then
12363 if Comes_From_Source (Ent) and then SPARK_Elab_Errors then
12364 Error_Msg_NE
12365 ("instantiation of & during elaboration in SPARK", N, Ent);
12366 else
12367 Elab_Warning
12368 ("instantiation of & may raise Program_Error?l?",
12369 "info: instantiation of & during elaboration?$?", Ent);
12370 end if;
12372 -- Indirect call case, info message only in static elaboration
12373 -- case, because the attribute reference itself cannot raise an
12374 -- exception. Note that SPARK does not permit indirect calls.
12376 elsif Access_Case then
12377 Elab_Warning ("", "info: access to & during elaboration?$?", Ent);
12379 -- Variable reference in SPARK mode
12381 elsif Variable_Case then
12382 if Comes_From_Source (Ent) and then SPARK_Elab_Errors then
12383 Error_Msg_NE
12384 ("reference to & during elaboration in SPARK", N, Ent);
12385 end if;
12387 -- Subprogram call case
12389 else
12390 if Nkind (Name (N)) in N_Has_Entity
12391 and then Is_Init_Proc (Entity (Name (N)))
12392 and then Comes_From_Source (Ent)
12393 then
12394 Elab_Warning
12395 ("implicit call to & may raise Program_Error?l?",
12396 "info: implicit call to & during elaboration?$?",
12397 Ent);
12399 elsif SPARK_Elab_Errors then
12401 -- Emit a specialized error message when the elaboration of an
12402 -- object of a private type evaluates the expression of pragma
12403 -- Default_Initial_Condition. This prevents the internal name
12404 -- of the procedure from appearing in the error message.
12406 if Is_DIC then
12407 Error_Msg_N
12408 ("call to Default_Initial_Condition during elaboration in "
12409 & "SPARK", N);
12410 else
12411 Error_Msg_NE
12412 ("call to & during elaboration in SPARK", N, Ent);
12413 end if;
12415 else
12416 Elab_Warning
12417 ("call to & may raise Program_Error?l?",
12418 "info: call to & during elaboration?$?",
12419 Ent);
12420 end if;
12421 end if;
12423 Error_Msg_Qual_Level := Nat'Last;
12425 -- Case of Elaborate_All not present and required, for SPARK this
12426 -- is an error, so give an error message.
12428 if SPARK_Elab_Errors then
12429 Error_Msg_NE -- CODEFIX
12430 ("\Elaborate_All pragma required for&", N, W_Scope);
12432 -- Otherwise we generate an implicit pragma. For a subprogram
12433 -- instantiation, Elaborate is good enough, since no transitive
12434 -- call is possible at elaboration time in this case.
12436 elsif Nkind (N) in N_Subprogram_Instantiation then
12437 Elab_Warning
12438 ("\missing pragma Elaborate for&?l?",
12439 "\implicit pragma Elaborate for& generated?$?",
12440 W_Scope);
12442 -- For all other cases, we need an implicit Elaborate_All
12444 else
12445 Elab_Warning
12446 ("\missing pragma Elaborate_All for&?l?",
12447 "\implicit pragma Elaborate_All for & generated?$?",
12448 W_Scope);
12449 end if;
12451 Error_Msg_Qual_Level := 0;
12453 -- Take into account the flags related to elaboration warning
12454 -- messages when enumerating the various calls involved. This
12455 -- ensures the proper pairing of the main warning and the
12456 -- clarification messages generated by Output_Calls.
12458 Output_Calls (N, Check_Elab_Flag => True);
12460 -- Set flag to prevent further warnings for same unit unless in
12461 -- All_Errors_Mode.
12463 if not All_Errors_Mode and not Dynamic_Elaboration_Checks then
12464 Set_Suppress_Elaboration_Warnings (W_Scope);
12465 end if;
12466 end if;
12468 -- Check for runtime elaboration check required
12470 if Dynamic_Elaboration_Checks then
12471 if not Elaboration_Checks_Suppressed (Ent)
12472 and then not Elaboration_Checks_Suppressed (W_Scope)
12473 and then not Elaboration_Checks_Suppressed (E_Scope)
12474 and then not Cunit_SC
12475 then
12476 -- Runtime elaboration check required. Generate check of the
12477 -- elaboration Boolean for the unit containing the entity.
12479 -- Note that for this case, we do check the real unit (the one
12480 -- from following renamings, since that is the issue).
12482 -- Could this possibly miss a useless but required PE???
12484 Insert_Elab_Check (N,
12485 Make_Attribute_Reference (Loc,
12486 Attribute_Name => Name_Elaborated,
12487 Prefix =>
12488 New_Occurrence_Of (Spec_Entity (E_Scope), Loc)));
12490 -- Prevent duplicate elaboration checks on the same call, which
12491 -- can happen if the body enclosing the call appears itself in a
12492 -- call whose elaboration check is delayed.
12494 if Nkind (N) in N_Subprogram_Call then
12495 Set_No_Elaboration_Check (N);
12496 end if;
12497 end if;
12499 -- Case of static elaboration model
12501 else
12502 -- Do not do anything if elaboration checks suppressed. Note that
12503 -- we check Ent here, not E, since we want the real entity for the
12504 -- body to see if checks are suppressed for it, not the dummy
12505 -- entry for renamings or derivations.
12507 if Elaboration_Checks_Suppressed (Ent)
12508 or else Elaboration_Checks_Suppressed (E_Scope)
12509 or else Elaboration_Checks_Suppressed (W_Scope)
12510 then
12511 null;
12513 -- Do not generate an Elaborate_All for finalization routines
12514 -- that perform partial clean up as part of initialization.
12516 elsif In_Init_Proc and then Is_Finalization_Procedure (Ent) then
12517 null;
12519 -- Here we need to generate an implicit elaborate all
12521 else
12522 -- Generate Elaborate_All warning unless suppressed
12524 if (Elab_Info_Messages and Generate_Warnings and not Inst_Case)
12525 and then not Suppress_Elaboration_Warnings (Ent)
12526 and then not Suppress_Elaboration_Warnings (E_Scope)
12527 and then not Suppress_Elaboration_Warnings (W_Scope)
12528 then
12529 Error_Msg_Node_2 := W_Scope;
12530 Error_Msg_NE
12531 ("info: call to& in elaboration code requires pragma "
12532 & "Elaborate_All on&?$?", N, E);
12533 end if;
12535 -- Set indication for binder to generate Elaborate_All
12537 Set_Elaboration_Constraint (N, E, W_Scope);
12538 end if;
12539 end if;
12540 end Check_A_Call;
12542 -----------------------------
12543 -- Check_Bad_Instantiation --
12544 -----------------------------
12546 procedure Check_Bad_Instantiation (N : Node_Id) is
12547 Ent : Entity_Id;
12549 begin
12550 -- Nothing to do if we do not have an instantiation (happens in some
12551 -- error cases, and also in the formal package declaration case)
12553 if Nkind (N) not in N_Generic_Instantiation then
12554 return;
12556 -- Nothing to do if serious errors detected (avoid cascaded errors)
12558 elsif Serious_Errors_Detected /= 0 then
12559 return;
12561 -- Nothing to do if not in full analysis mode
12563 elsif not Full_Analysis then
12564 return;
12566 -- Nothing to do if inside a generic template
12568 elsif Inside_A_Generic then
12569 return;
12571 -- Nothing to do if a library level instantiation
12573 elsif Nkind (Parent (N)) = N_Compilation_Unit then
12574 return;
12576 -- Nothing to do if we are compiling a proper body for semantic
12577 -- purposes only. The generic body may be in another proper body.
12579 elsif
12580 Nkind (Parent (Unit_Declaration_Node (Main_Unit_Entity))) = N_Subunit
12581 then
12582 return;
12583 end if;
12585 Ent := Get_Generic_Entity (N);
12587 -- The case we are interested in is when the generic spec is in the
12588 -- current declarative part
12590 if not Same_Elaboration_Scope (Current_Scope, Scope (Ent))
12591 or else not In_Same_Extended_Unit (N, Ent)
12592 then
12593 return;
12594 end if;
12596 -- If the generic entity is within a deeper instance than we are, then
12597 -- either the instantiation to which we refer itself caused an ABE, in
12598 -- which case that will be handled separately. Otherwise, we know that
12599 -- the body we need appears as needed at the point of the instantiation.
12600 -- If they are both at the same level but not within the same instance
12601 -- then the body of the generic will be in the earlier instance.
12603 declare
12604 D1 : constant Nat := Instantiation_Depth (Sloc (Ent));
12605 D2 : constant Nat := Instantiation_Depth (Sloc (N));
12607 begin
12608 if D1 > D2 then
12609 return;
12611 elsif D1 = D2
12612 and then Is_Generic_Instance (Scope (Ent))
12613 and then not In_Open_Scopes (Scope (Ent))
12614 then
12615 return;
12616 end if;
12617 end;
12619 -- Now we can proceed, if the entity being called has a completion,
12620 -- then we are definitely OK, since we have already seen the body.
12622 if Has_Completion (Ent) then
12623 return;
12624 end if;
12626 -- If there is no body, then nothing to do
12628 if not Has_Generic_Body (N) then
12629 return;
12630 end if;
12632 -- Here we definitely have a bad instantiation
12634 Error_Msg_Warn := SPARK_Mode /= On;
12635 Error_Msg_NE ("cannot instantiate& before body seen<<", N, Ent);
12636 Error_Msg_N ("\Program_Error [<<", N);
12638 Insert_Elab_Check (N);
12639 Set_Is_Known_Guaranteed_ABE (N);
12640 end Check_Bad_Instantiation;
12642 ---------------------
12643 -- Check_Elab_Call --
12644 ---------------------
12646 procedure Check_Elab_Call
12647 (N : Node_Id;
12648 Outer_Scope : Entity_Id := Empty;
12649 In_Init_Proc : Boolean := False)
12651 Ent : Entity_Id;
12652 P : Node_Id;
12654 begin
12655 pragma Assert (Legacy_Elaboration_Checks);
12657 -- If the reference is not in the main unit, there is nothing to check.
12658 -- Elaboration call from units in the context of the main unit will lead
12659 -- to semantic dependencies when those units are compiled.
12661 if not In_Extended_Main_Code_Unit (N) then
12662 return;
12663 end if;
12665 -- For an entry call, check relevant restriction
12667 if Nkind (N) = N_Entry_Call_Statement
12668 and then not In_Subprogram_Or_Concurrent_Unit
12669 then
12670 Check_Restriction (No_Entry_Calls_In_Elaboration_Code, N);
12672 -- Nothing to do if this is not an expected type of reference (happens
12673 -- in some error conditions, and in some cases where rewriting occurs).
12675 elsif Nkind (N) not in N_Subprogram_Call
12676 and then Nkind (N) /= N_Attribute_Reference
12677 and then (SPARK_Mode /= On
12678 or else Nkind (N) not in N_Has_Entity
12679 or else No (Entity (N))
12680 or else Ekind (Entity (N)) /= E_Variable)
12681 then
12682 return;
12684 -- Nothing to do if this is a call already rewritten for elab checking.
12685 -- Such calls appear as the targets of If_Expressions.
12687 -- This check MUST be wrong, it catches far too much
12689 elsif Nkind (Parent (N)) = N_If_Expression then
12690 return;
12692 -- Nothing to do if inside a generic template
12694 elsif Inside_A_Generic
12695 and then No (Enclosing_Generic_Body (N))
12696 then
12697 return;
12699 -- Nothing to do if call is being pre-analyzed, as when within a
12700 -- pre/postcondition, a predicate, or an invariant.
12702 elsif In_Spec_Expression then
12703 return;
12704 end if;
12706 -- Nothing to do if this is a call to a postcondition, which is always
12707 -- within a subprogram body, even though the current scope may be the
12708 -- enclosing scope of the subprogram.
12710 if Nkind (N) = N_Procedure_Call_Statement
12711 and then Is_Entity_Name (Name (N))
12712 and then Chars (Entity (Name (N))) = Name_uPostconditions
12713 then
12714 return;
12715 end if;
12717 -- Here we have a reference at elaboration time that must be checked
12719 if Debug_Flag_Underscore_LL then
12720 Write_Str (" Check_Elab_Ref: ");
12722 if Nkind (N) = N_Attribute_Reference then
12723 if not Is_Entity_Name (Prefix (N)) then
12724 Write_Str ("<<not entity name>>");
12725 else
12726 Write_Name (Chars (Entity (Prefix (N))));
12727 end if;
12729 Write_Str ("'Access");
12731 elsif No (Name (N)) or else not Is_Entity_Name (Name (N)) then
12732 Write_Str ("<<not entity name>> ");
12734 else
12735 Write_Name (Chars (Entity (Name (N))));
12736 end if;
12738 Write_Str (" reference at ");
12739 Write_Location (Sloc (N));
12740 Write_Eol;
12741 end if;
12743 -- Climb up the tree to make sure we are not inside default expression
12744 -- of a parameter specification or a record component, since in both
12745 -- these cases, we will be doing the actual reference later, not now,
12746 -- and it is at the time of the actual reference (statically speaking)
12747 -- that we must do our static check, not at the time of its initial
12748 -- analysis).
12750 -- However, we have to check references within component definitions
12751 -- (e.g. a function call that determines an array component bound),
12752 -- so we terminate the loop in that case.
12754 P := Parent (N);
12755 while Present (P) loop
12756 if Nkind_In (P, N_Parameter_Specification,
12757 N_Component_Declaration)
12758 then
12759 return;
12761 -- The reference occurs within the constraint of a component,
12762 -- so it must be checked.
12764 elsif Nkind (P) = N_Component_Definition then
12765 exit;
12767 else
12768 P := Parent (P);
12769 end if;
12770 end loop;
12772 -- Stuff that happens only at the outer level
12774 if No (Outer_Scope) then
12775 Elab_Visited.Set_Last (0);
12777 -- Nothing to do if current scope is Standard (this is a bit odd, but
12778 -- it happens in the case of generic instantiations).
12780 C_Scope := Current_Scope;
12782 if C_Scope = Standard_Standard then
12783 return;
12784 end if;
12786 -- First case, we are in elaboration code
12788 From_Elab_Code := not In_Subprogram_Or_Concurrent_Unit;
12790 if From_Elab_Code then
12792 -- Complain if ref that comes from source in preelaborated unit
12793 -- and we are not inside a subprogram (i.e. we are in elab code).
12795 if Comes_From_Source (N)
12796 and then In_Preelaborated_Unit
12797 and then not In_Inlined_Body
12798 and then Nkind (N) /= N_Attribute_Reference
12799 then
12800 -- This is a warning in GNAT mode allowing such calls to be
12801 -- used in the predefined library with appropriate care.
12803 Error_Msg_Warn := GNAT_Mode;
12804 Error_Msg_N
12805 ("<<non-static call not allowed in preelaborated unit", N);
12806 return;
12807 end if;
12809 -- Second case, we are inside a subprogram or concurrent unit, which
12810 -- means we are not in elaboration code.
12812 else
12813 -- In this case, the issue is whether we are inside the
12814 -- declarative part of the unit in which we live, or inside its
12815 -- statements. In the latter case, there is no issue of ABE calls
12816 -- at this level (a call from outside to the unit in which we live
12817 -- might cause an ABE, but that will be detected when we analyze
12818 -- that outer level call, as it recurses into the called unit).
12820 -- Climb up the tree, doing this test, and also testing for being
12821 -- inside a default expression, which, as discussed above, is not
12822 -- checked at this stage.
12824 declare
12825 P : Node_Id;
12826 L : List_Id;
12828 begin
12829 P := N;
12830 loop
12831 -- If we find a parentless subtree, it seems safe to assume
12832 -- that we are not in a declarative part and that no
12833 -- checking is required.
12835 if No (P) then
12836 return;
12837 end if;
12839 if Is_List_Member (P) then
12840 L := List_Containing (P);
12841 P := Parent (L);
12842 else
12843 L := No_List;
12844 P := Parent (P);
12845 end if;
12847 exit when Nkind (P) = N_Subunit;
12849 -- Filter out case of default expressions, where we do not
12850 -- do the check at this stage.
12852 if Nkind_In (P, N_Parameter_Specification,
12853 N_Component_Declaration)
12854 then
12855 return;
12856 end if;
12858 -- A protected body has no elaboration code and contains
12859 -- only other bodies.
12861 if Nkind (P) = N_Protected_Body then
12862 return;
12864 elsif Nkind_In (P, N_Subprogram_Body,
12865 N_Task_Body,
12866 N_Block_Statement,
12867 N_Entry_Body)
12868 then
12869 if L = Declarations (P) then
12870 exit;
12872 -- We are not in elaboration code, but we are doing
12873 -- dynamic elaboration checks, in this case, we still
12874 -- need to do the reference, since the subprogram we are
12875 -- in could be called from another unit, also in dynamic
12876 -- elaboration check mode, at elaboration time.
12878 elsif Dynamic_Elaboration_Checks then
12880 -- We provide a debug flag to disable this check. That
12881 -- way we have an easy work around for regressions
12882 -- that are caused by this new check. This debug flag
12883 -- can be removed later.
12885 if Debug_Flag_DD then
12886 return;
12887 end if;
12889 -- Do the check in this case
12891 exit;
12893 elsif Nkind (P) = N_Task_Body then
12895 -- The check is deferred until Check_Task_Activation
12896 -- but we need to capture local suppress pragmas
12897 -- that may inhibit checks on this call.
12899 Ent := Get_Referenced_Ent (N);
12901 if No (Ent) then
12902 return;
12904 elsif Elaboration_Checks_Suppressed (Current_Scope)
12905 or else Elaboration_Checks_Suppressed (Ent)
12906 or else Elaboration_Checks_Suppressed (Scope (Ent))
12907 then
12908 if Nkind (N) in N_Subprogram_Call then
12909 Set_No_Elaboration_Check (N);
12910 end if;
12911 end if;
12913 return;
12915 -- Static model, call is not in elaboration code, we
12916 -- never need to worry, because in the static model the
12917 -- top-level caller always takes care of things.
12919 else
12920 return;
12921 end if;
12922 end if;
12923 end loop;
12924 end;
12925 end if;
12926 end if;
12928 Ent := Get_Referenced_Ent (N);
12930 if No (Ent) then
12931 return;
12932 end if;
12934 -- Determine whether a prior call to the same subprogram was already
12935 -- examined within the same context. If this is the case, then there is
12936 -- no need to proceed with the various warnings and checks because the
12937 -- work was already done for the previous call.
12939 declare
12940 Self : constant Visited_Element :=
12941 (Subp_Id => Ent, Context => Parent (N));
12943 begin
12944 for Index in 1 .. Elab_Visited.Last loop
12945 if Self = Elab_Visited.Table (Index) then
12946 return;
12947 end if;
12948 end loop;
12949 end;
12951 -- See if we need to analyze this reference. We analyze it if either of
12952 -- the following conditions is met:
12954 -- It is an inner level call (since in this case it was triggered
12955 -- by an outer level call from elaboration code), but only if the
12956 -- call is within the scope of the original outer level call.
12958 -- It is an outer level reference from elaboration code, or a call to
12959 -- an entity is in the same elaboration scope.
12961 -- And in these cases, we will check both inter-unit calls and
12962 -- intra-unit (within a single unit) calls.
12964 C_Scope := Current_Scope;
12966 -- If not outer level reference, then we follow it if it is within the
12967 -- original scope of the outer reference.
12969 if Present (Outer_Scope)
12970 and then Within (Scope (Ent), Outer_Scope)
12971 then
12972 Set_C_Scope;
12973 Check_A_Call
12974 (N => N,
12975 E => Ent,
12976 Outer_Scope => Outer_Scope,
12977 Inter_Unit_Only => False,
12978 In_Init_Proc => In_Init_Proc);
12980 -- Nothing to do if elaboration checks suppressed for this scope.
12981 -- However, an interesting exception, the fact that elaboration checks
12982 -- are suppressed within an instance (because we can trace the body when
12983 -- we process the template) does not extend to calls to generic formal
12984 -- subprograms.
12986 elsif Elaboration_Checks_Suppressed (Current_Scope)
12987 and then not Is_Call_Of_Generic_Formal (N)
12988 then
12989 null;
12991 elsif From_Elab_Code then
12992 Set_C_Scope;
12993 Check_A_Call (N, Ent, Standard_Standard, Inter_Unit_Only => False);
12995 elsif Same_Elaboration_Scope (C_Scope, Scope (Ent)) then
12996 Set_C_Scope;
12997 Check_A_Call (N, Ent, Scope (Ent), Inter_Unit_Only => False);
12999 -- If none of those cases holds, but Dynamic_Elaboration_Checks mode
13000 -- is set, then we will do the check, but only in the inter-unit case
13001 -- (this is to accommodate unguarded elaboration calls from other units
13002 -- in which this same mode is set). We don't want warnings in this case,
13003 -- it would generate warnings having nothing to do with elaboration.
13005 elsif Dynamic_Elaboration_Checks then
13006 Set_C_Scope;
13007 Check_A_Call
13009 Ent,
13010 Standard_Standard,
13011 Inter_Unit_Only => True,
13012 Generate_Warnings => False);
13014 -- Otherwise nothing to do
13016 else
13017 return;
13018 end if;
13020 -- A call to an Init_Proc in elaboration code may bring additional
13021 -- dependencies, if some of the record components thereof have
13022 -- initializations that are function calls that come from source. We
13023 -- treat the current node as a call to each of these functions, to check
13024 -- their elaboration impact.
13026 if Is_Init_Proc (Ent) and then From_Elab_Code then
13027 Process_Init_Proc : declare
13028 Unit_Decl : constant Node_Id := Unit_Declaration_Node (Ent);
13030 function Check_Init_Call (Nod : Node_Id) return Traverse_Result;
13031 -- Find subprogram calls within body of Init_Proc for Traverse
13032 -- instantiation below.
13034 procedure Traverse_Body is new Traverse_Proc (Check_Init_Call);
13035 -- Traversal procedure to find all calls with body of Init_Proc
13037 ---------------------
13038 -- Check_Init_Call --
13039 ---------------------
13041 function Check_Init_Call (Nod : Node_Id) return Traverse_Result is
13042 Func : Entity_Id;
13044 begin
13045 if Nkind (Nod) in N_Subprogram_Call
13046 and then Is_Entity_Name (Name (Nod))
13047 then
13048 Func := Entity (Name (Nod));
13050 if Comes_From_Source (Func) then
13051 Check_A_Call
13052 (N, Func, Standard_Standard, Inter_Unit_Only => True);
13053 end if;
13055 return OK;
13057 else
13058 return OK;
13059 end if;
13060 end Check_Init_Call;
13062 -- Start of processing for Process_Init_Proc
13064 begin
13065 if Nkind (Unit_Decl) = N_Subprogram_Body then
13066 Traverse_Body (Handled_Statement_Sequence (Unit_Decl));
13067 end if;
13068 end Process_Init_Proc;
13069 end if;
13070 end Check_Elab_Call;
13072 -----------------------
13073 -- Check_Elab_Assign --
13074 -----------------------
13076 procedure Check_Elab_Assign (N : Node_Id) is
13077 Ent : Entity_Id;
13078 Scop : Entity_Id;
13080 Pkg_Spec : Entity_Id;
13081 Pkg_Body : Entity_Id;
13083 begin
13084 pragma Assert (Legacy_Elaboration_Checks);
13086 -- For record or array component, check prefix. If it is an access type,
13087 -- then there is nothing to do (we do not know what is being assigned),
13088 -- but otherwise this is an assignment to the prefix.
13090 if Nkind_In (N, N_Indexed_Component,
13091 N_Selected_Component,
13092 N_Slice)
13093 then
13094 if not Is_Access_Type (Etype (Prefix (N))) then
13095 Check_Elab_Assign (Prefix (N));
13096 end if;
13098 return;
13099 end if;
13101 -- For type conversion, check expression
13103 if Nkind (N) = N_Type_Conversion then
13104 Check_Elab_Assign (Expression (N));
13105 return;
13106 end if;
13108 -- Nothing to do if this is not an entity reference otherwise get entity
13110 if Is_Entity_Name (N) then
13111 Ent := Entity (N);
13112 else
13113 return;
13114 end if;
13116 -- What we are looking for is a reference in the body of a package that
13117 -- modifies a variable declared in the visible part of the package spec.
13119 if Present (Ent)
13120 and then Comes_From_Source (N)
13121 and then not Suppress_Elaboration_Warnings (Ent)
13122 and then Ekind (Ent) = E_Variable
13123 and then not In_Private_Part (Ent)
13124 and then Is_Library_Level_Entity (Ent)
13125 then
13126 Scop := Current_Scope;
13127 loop
13128 if No (Scop) or else Scop = Standard_Standard then
13129 return;
13130 elsif Ekind (Scop) = E_Package
13131 and then Is_Compilation_Unit (Scop)
13132 then
13133 exit;
13134 else
13135 Scop := Scope (Scop);
13136 end if;
13137 end loop;
13139 -- Here Scop points to the containing library package
13141 Pkg_Spec := Scop;
13142 Pkg_Body := Body_Entity (Pkg_Spec);
13144 -- All OK if the package has an Elaborate_Body pragma
13146 if Has_Pragma_Elaborate_Body (Scop) then
13147 return;
13148 end if;
13150 -- OK if entity being modified is not in containing package spec
13152 if not In_Same_Source_Unit (Scop, Ent) then
13153 return;
13154 end if;
13156 -- All OK if entity appears in generic package or generic instance.
13157 -- We just get too messed up trying to give proper warnings in the
13158 -- presence of generics. Better no message than a junk one.
13160 Scop := Scope (Ent);
13161 while Present (Scop) and then Scop /= Pkg_Spec loop
13162 if Ekind (Scop) = E_Generic_Package then
13163 return;
13164 elsif Ekind (Scop) = E_Package
13165 and then Is_Generic_Instance (Scop)
13166 then
13167 return;
13168 end if;
13170 Scop := Scope (Scop);
13171 end loop;
13173 -- All OK if in task, don't issue warnings there
13175 if In_Task_Activation then
13176 return;
13177 end if;
13179 -- OK if no package body
13181 if No (Pkg_Body) then
13182 return;
13183 end if;
13185 -- OK if reference is not in package body
13187 if not In_Same_Source_Unit (Pkg_Body, N) then
13188 return;
13189 end if;
13191 -- OK if package body has no handled statement sequence
13193 declare
13194 HSS : constant Node_Id :=
13195 Handled_Statement_Sequence (Declaration_Node (Pkg_Body));
13196 begin
13197 if No (HSS) or else not Comes_From_Source (HSS) then
13198 return;
13199 end if;
13200 end;
13202 -- We definitely have a case of a modification of an entity in
13203 -- the package spec from the elaboration code of the package body.
13204 -- We may not give the warning (because there are some additional
13205 -- checks to avoid too many false positives), but it would be a good
13206 -- idea for the binder to try to keep the body elaboration close to
13207 -- the spec elaboration.
13209 Set_Elaborate_Body_Desirable (Pkg_Spec);
13211 -- All OK in gnat mode (we know what we are doing)
13213 if GNAT_Mode then
13214 return;
13215 end if;
13217 -- All OK if all warnings suppressed
13219 if Warning_Mode = Suppress then
13220 return;
13221 end if;
13223 -- All OK if elaboration checks suppressed for entity
13225 if Checks_May_Be_Suppressed (Ent)
13226 and then Is_Check_Suppressed (Ent, Elaboration_Check)
13227 then
13228 return;
13229 end if;
13231 -- OK if the entity is initialized. Note that the No_Initialization
13232 -- flag usually means that the initialization has been rewritten into
13233 -- assignments, but that still counts for us.
13235 declare
13236 Decl : constant Node_Id := Declaration_Node (Ent);
13237 begin
13238 if Nkind (Decl) = N_Object_Declaration
13239 and then (Present (Expression (Decl))
13240 or else No_Initialization (Decl))
13241 then
13242 return;
13243 end if;
13244 end;
13246 -- Here is where we give the warning
13248 -- All OK if warnings suppressed on the entity
13250 if not Has_Warnings_Off (Ent) then
13251 Error_Msg_Sloc := Sloc (Ent);
13253 Error_Msg_NE
13254 ("??& can be accessed by clients before this initialization",
13255 N, Ent);
13256 Error_Msg_NE
13257 ("\??add Elaborate_Body to spec to ensure & is initialized",
13258 N, Ent);
13259 end if;
13261 if not All_Errors_Mode then
13262 Set_Suppress_Elaboration_Warnings (Ent);
13263 end if;
13264 end if;
13265 end Check_Elab_Assign;
13267 ----------------------
13268 -- Check_Elab_Calls --
13269 ----------------------
13271 -- WARNING: This routine manages SPARK regions
13273 procedure Check_Elab_Calls is
13274 Saved_SM : SPARK_Mode_Type;
13275 Saved_SMP : Node_Id;
13277 begin
13278 pragma Assert (Legacy_Elaboration_Checks);
13280 -- If expansion is disabled, do not generate any checks, unless we
13281 -- are in GNATprove mode, so that errors are issued in GNATprove for
13282 -- violations of static elaboration rules in SPARK code. Also skip
13283 -- checks if any subunits are missing because in either case we lack the
13284 -- full information that we need, and no object file will be created in
13285 -- any case.
13287 if (not Expander_Active and not GNATprove_Mode)
13288 or else Is_Generic_Unit (Cunit_Entity (Main_Unit))
13289 or else Subunits_Missing
13290 then
13291 return;
13292 end if;
13294 -- Skip delayed calls if we had any errors
13296 if Serious_Errors_Detected = 0 then
13297 Delaying_Elab_Checks := False;
13298 Expander_Mode_Save_And_Set (True);
13300 for J in Delay_Check.First .. Delay_Check.Last loop
13301 Push_Scope (Delay_Check.Table (J).Curscop);
13302 From_Elab_Code := Delay_Check.Table (J).From_Elab_Code;
13303 In_Task_Activation := Delay_Check.Table (J).In_Task_Activation;
13305 Saved_SM := SPARK_Mode;
13306 Saved_SMP := SPARK_Mode_Pragma;
13308 -- Set appropriate value of SPARK_Mode
13310 if Delay_Check.Table (J).From_SPARK_Code then
13311 SPARK_Mode := On;
13312 end if;
13314 Check_Internal_Call_Continue
13315 (N => Delay_Check.Table (J).N,
13316 E => Delay_Check.Table (J).E,
13317 Outer_Scope => Delay_Check.Table (J).Outer_Scope,
13318 Orig_Ent => Delay_Check.Table (J).Orig_Ent);
13320 Restore_SPARK_Mode (Saved_SM, Saved_SMP);
13321 Pop_Scope;
13322 end loop;
13324 -- Set Delaying_Elab_Checks back on for next main compilation
13326 Expander_Mode_Restore;
13327 Delaying_Elab_Checks := True;
13328 end if;
13329 end Check_Elab_Calls;
13331 ------------------------------
13332 -- Check_Elab_Instantiation --
13333 ------------------------------
13335 procedure Check_Elab_Instantiation
13336 (N : Node_Id;
13337 Outer_Scope : Entity_Id := Empty)
13339 Ent : Entity_Id;
13341 begin
13342 pragma Assert (Legacy_Elaboration_Checks);
13344 -- Check for and deal with bad instantiation case. There is some
13345 -- duplicated code here, but we will worry about this later ???
13347 Check_Bad_Instantiation (N);
13349 if Is_Known_Guaranteed_ABE (N) then
13350 return;
13351 end if;
13353 -- Nothing to do if we do not have an instantiation (happens in some
13354 -- error cases, and also in the formal package declaration case)
13356 if Nkind (N) not in N_Generic_Instantiation then
13357 return;
13358 end if;
13360 -- Nothing to do if inside a generic template
13362 if Inside_A_Generic then
13363 return;
13364 end if;
13366 -- Nothing to do if the instantiation is not in the main unit
13368 if not In_Extended_Main_Code_Unit (N) then
13369 return;
13370 end if;
13372 Ent := Get_Generic_Entity (N);
13373 From_Elab_Code := not In_Subprogram_Or_Concurrent_Unit;
13375 -- See if we need to analyze this instantiation. We analyze it if
13376 -- either of the following conditions is met:
13378 -- It is an inner level instantiation (since in this case it was
13379 -- triggered by an outer level call from elaboration code), but
13380 -- only if the instantiation is within the scope of the original
13381 -- outer level call.
13383 -- It is an outer level instantiation from elaboration code, or the
13384 -- instantiated entity is in the same elaboration scope.
13386 -- And in these cases, we will check both the inter-unit case and
13387 -- the intra-unit (within a single unit) case.
13389 C_Scope := Current_Scope;
13391 if Present (Outer_Scope) and then Within (Scope (Ent), Outer_Scope) then
13392 Set_C_Scope;
13393 Check_A_Call (N, Ent, Outer_Scope, Inter_Unit_Only => False);
13395 elsif From_Elab_Code then
13396 Set_C_Scope;
13397 Check_A_Call (N, Ent, Standard_Standard, Inter_Unit_Only => False);
13399 elsif Same_Elaboration_Scope (C_Scope, Scope (Ent)) then
13400 Set_C_Scope;
13401 Check_A_Call (N, Ent, Scope (Ent), Inter_Unit_Only => False);
13403 -- If none of those cases holds, but Dynamic_Elaboration_Checks mode is
13404 -- set, then we will do the check, but only in the inter-unit case (this
13405 -- is to accommodate unguarded elaboration calls from other units in
13406 -- which this same mode is set). We inhibit warnings in this case, since
13407 -- this instantiation is not occurring in elaboration code.
13409 elsif Dynamic_Elaboration_Checks then
13410 Set_C_Scope;
13411 Check_A_Call
13413 Ent,
13414 Standard_Standard,
13415 Inter_Unit_Only => True,
13416 Generate_Warnings => False);
13418 else
13419 return;
13420 end if;
13421 end Check_Elab_Instantiation;
13423 -------------------------
13424 -- Check_Internal_Call --
13425 -------------------------
13427 procedure Check_Internal_Call
13428 (N : Node_Id;
13429 E : Entity_Id;
13430 Outer_Scope : Entity_Id;
13431 Orig_Ent : Entity_Id)
13433 function Within_Initial_Condition (Call : Node_Id) return Boolean;
13434 -- Determine whether call Call occurs within pragma Initial_Condition or
13435 -- pragma Check with check_kind set to Initial_Condition.
13437 ------------------------------
13438 -- Within_Initial_Condition --
13439 ------------------------------
13441 function Within_Initial_Condition (Call : Node_Id) return Boolean is
13442 Args : List_Id;
13443 Nam : Name_Id;
13444 Par : Node_Id;
13446 begin
13447 -- Traverse the parent chain looking for an enclosing pragma
13449 Par := Call;
13450 while Present (Par) loop
13451 if Nkind (Par) = N_Pragma then
13452 Nam := Pragma_Name (Par);
13454 -- Pragma Initial_Condition appears in its alternative from as
13455 -- Check (Initial_Condition, ...).
13457 if Nam = Name_Check then
13458 Args := Pragma_Argument_Associations (Par);
13460 -- Pragma Check should have at least two arguments
13462 pragma Assert (Present (Args));
13464 return
13465 Chars (Expression (First (Args))) = Name_Initial_Condition;
13467 -- Direct match
13469 elsif Nam = Name_Initial_Condition then
13470 return True;
13472 -- Since pragmas are never nested within other pragmas, stop
13473 -- the traversal.
13475 else
13476 return False;
13477 end if;
13479 -- Prevent the search from going too far
13481 elsif Is_Body_Or_Package_Declaration (Par) then
13482 exit;
13483 end if;
13485 Par := Parent (Par);
13487 -- If assertions are not enabled, the check pragma is rewritten
13488 -- as an if_statement in sem_prag, to generate various warnings
13489 -- on boolean expressions. Retrieve the original pragma.
13491 if Nkind (Original_Node (Par)) = N_Pragma then
13492 Par := Original_Node (Par);
13493 end if;
13494 end loop;
13496 return False;
13497 end Within_Initial_Condition;
13499 -- Local variables
13501 Inst_Case : constant Boolean := Nkind (N) in N_Generic_Instantiation;
13503 -- Start of processing for Check_Internal_Call
13505 begin
13506 -- For P'Access, we want to warn if the -gnatw.f switch is set, and the
13507 -- node comes from source.
13509 if Nkind (N) = N_Attribute_Reference
13510 and then ((not Warn_On_Elab_Access and then not Debug_Flag_Dot_O)
13511 or else not Comes_From_Source (N))
13512 then
13513 return;
13515 -- If not function or procedure call, instantiation, or 'Access, then
13516 -- ignore call (this happens in some error cases and rewriting cases).
13518 elsif not Nkind_In (N, N_Attribute_Reference,
13519 N_Function_Call,
13520 N_Procedure_Call_Statement)
13521 and then not Inst_Case
13522 then
13523 return;
13525 -- Nothing to do if this is a call or instantiation that has already
13526 -- been found to be a sure ABE.
13528 elsif Nkind (N) /= N_Attribute_Reference
13529 and then Is_Known_Guaranteed_ABE (N)
13530 then
13531 return;
13533 -- Nothing to do if errors already detected (avoid cascaded errors)
13535 elsif Serious_Errors_Detected /= 0 then
13536 return;
13538 -- Nothing to do if not in full analysis mode
13540 elsif not Full_Analysis then
13541 return;
13543 -- Nothing to do if analyzing in special spec-expression mode, since the
13544 -- call is not actually being made at this time.
13546 elsif In_Spec_Expression then
13547 return;
13549 -- Nothing to do for call to intrinsic subprogram
13551 elsif Is_Intrinsic_Subprogram (E) then
13552 return;
13554 -- Nothing to do if call is within a generic unit
13556 elsif Inside_A_Generic then
13557 return;
13559 -- Nothing to do when the call appears within pragma Initial_Condition.
13560 -- The pragma is part of the elaboration statements of a package body
13561 -- and may only call external subprograms or subprograms whose body is
13562 -- already available.
13564 elsif Within_Initial_Condition (N) then
13565 return;
13566 end if;
13568 -- Delay this call if we are still delaying calls
13570 if Delaying_Elab_Checks then
13571 Delay_Check.Append
13572 ((N => N,
13573 E => E,
13574 Orig_Ent => Orig_Ent,
13575 Curscop => Current_Scope,
13576 Outer_Scope => Outer_Scope,
13577 From_Elab_Code => From_Elab_Code,
13578 In_Task_Activation => In_Task_Activation,
13579 From_SPARK_Code => SPARK_Mode = On));
13580 return;
13582 -- Otherwise, call phase 2 continuation right now
13584 else
13585 Check_Internal_Call_Continue (N, E, Outer_Scope, Orig_Ent);
13586 end if;
13587 end Check_Internal_Call;
13589 ----------------------------------
13590 -- Check_Internal_Call_Continue --
13591 ----------------------------------
13593 procedure Check_Internal_Call_Continue
13594 (N : Node_Id;
13595 E : Entity_Id;
13596 Outer_Scope : Entity_Id;
13597 Orig_Ent : Entity_Id)
13599 function Find_Elab_Reference (N : Node_Id) return Traverse_Result;
13600 -- Function applied to each node as we traverse the body. Checks for
13601 -- call or entity reference that needs checking, and if so checks it.
13602 -- Always returns OK, so entire tree is traversed, except that as
13603 -- described below subprogram bodies are skipped for now.
13605 procedure Traverse is new Atree.Traverse_Proc (Find_Elab_Reference);
13606 -- Traverse procedure using above Find_Elab_Reference function
13608 -------------------------
13609 -- Find_Elab_Reference --
13610 -------------------------
13612 function Find_Elab_Reference (N : Node_Id) return Traverse_Result is
13613 Actual : Node_Id;
13615 begin
13616 -- If user has specified that there are no entry calls in elaboration
13617 -- code, do not trace past an accept statement, because the rendez-
13618 -- vous will happen after elaboration.
13620 if Nkind_In (Original_Node (N), N_Accept_Statement,
13621 N_Selective_Accept)
13622 and then Restriction_Active (No_Entry_Calls_In_Elaboration_Code)
13623 then
13624 return Abandon;
13626 -- If we have a function call, check it
13628 elsif Nkind (N) = N_Function_Call then
13629 Check_Elab_Call (N, Outer_Scope);
13630 return OK;
13632 -- If we have a procedure call, check the call, and also check
13633 -- arguments that are assignments (OUT or IN OUT mode formals).
13635 elsif Nkind (N) = N_Procedure_Call_Statement then
13636 Check_Elab_Call (N, Outer_Scope, In_Init_Proc => Is_Init_Proc (E));
13638 Actual := First_Actual (N);
13639 while Present (Actual) loop
13640 if Known_To_Be_Assigned (Actual) then
13641 Check_Elab_Assign (Actual);
13642 end if;
13644 Next_Actual (Actual);
13645 end loop;
13647 return OK;
13649 -- If we have an access attribute for a subprogram, check it.
13650 -- Suppress this behavior under debug flag.
13652 elsif not Debug_Flag_Dot_UU
13653 and then Nkind (N) = N_Attribute_Reference
13654 and then Nam_In (Attribute_Name (N), Name_Access,
13655 Name_Unrestricted_Access)
13656 and then Is_Entity_Name (Prefix (N))
13657 and then Is_Subprogram (Entity (Prefix (N)))
13658 then
13659 Check_Elab_Call (N, Outer_Scope);
13660 return OK;
13662 -- In SPARK mode, if we have an entity reference to a variable, then
13663 -- check it. For now we consider any reference.
13665 elsif SPARK_Mode = On
13666 and then Nkind (N) in N_Has_Entity
13667 and then Present (Entity (N))
13668 and then Ekind (Entity (N)) = E_Variable
13669 then
13670 Check_Elab_Call (N, Outer_Scope);
13671 return OK;
13673 -- If we have a generic instantiation, check it
13675 elsif Nkind (N) in N_Generic_Instantiation then
13676 Check_Elab_Instantiation (N, Outer_Scope);
13677 return OK;
13679 -- Skip subprogram bodies that come from source (wait for call to
13680 -- analyze these). The reason for the come from source test is to
13681 -- avoid catching task bodies.
13683 -- For task bodies, we should really avoid these too, waiting for the
13684 -- task activation, but that's too much trouble to catch for now, so
13685 -- we go in unconditionally. This is not so terrible, it means the
13686 -- error backtrace is not quite complete, and we are too eager to
13687 -- scan bodies of tasks that are unused, but this is hardly very
13688 -- significant.
13690 elsif Nkind (N) = N_Subprogram_Body
13691 and then Comes_From_Source (N)
13692 then
13693 return Skip;
13695 elsif Nkind (N) = N_Assignment_Statement
13696 and then Comes_From_Source (N)
13697 then
13698 Check_Elab_Assign (Name (N));
13699 return OK;
13701 else
13702 return OK;
13703 end if;
13704 end Find_Elab_Reference;
13706 Inst_Case : constant Boolean := Is_Generic_Unit (E);
13707 Loc : constant Source_Ptr := Sloc (N);
13709 Ebody : Entity_Id;
13710 Sbody : Node_Id;
13712 -- Start of processing for Check_Internal_Call_Continue
13714 begin
13715 -- Save outer level call if at outer level
13717 if Elab_Call.Last = 0 then
13718 Outer_Level_Sloc := Loc;
13719 end if;
13721 -- If the call is to a function that renames a literal, no check needed
13723 if Ekind (E) = E_Enumeration_Literal then
13724 return;
13725 end if;
13727 -- Register the subprogram as examined within this particular context.
13728 -- This ensures that calls to the same subprogram but in different
13729 -- contexts receive warnings and checks of their own since the calls
13730 -- may be reached through different flow paths.
13732 Elab_Visited.Append ((Subp_Id => E, Context => Parent (N)));
13734 Sbody := Unit_Declaration_Node (E);
13736 if not Nkind_In (Sbody, N_Subprogram_Body, N_Package_Body) then
13737 Ebody := Corresponding_Body (Sbody);
13739 if No (Ebody) then
13740 return;
13741 else
13742 Sbody := Unit_Declaration_Node (Ebody);
13743 end if;
13744 end if;
13746 -- If the body appears after the outer level call or instantiation then
13747 -- we have an error case handled below.
13749 if Earlier_In_Extended_Unit (Outer_Level_Sloc, Sloc (Sbody))
13750 and then not In_Task_Activation
13751 then
13752 null;
13754 -- If we have the instantiation case we are done, since we now know that
13755 -- the body of the generic appeared earlier.
13757 elsif Inst_Case then
13758 return;
13760 -- Otherwise we have a call, so we trace through the called body to see
13761 -- if it has any problems.
13763 else
13764 pragma Assert (Nkind (Sbody) = N_Subprogram_Body);
13766 Elab_Call.Append ((Cloc => Loc, Ent => E));
13768 if Debug_Flag_Underscore_LL then
13769 Write_Str ("Elab_Call.Last = ");
13770 Write_Int (Int (Elab_Call.Last));
13771 Write_Str (" Ent = ");
13772 Write_Name (Chars (E));
13773 Write_Str (" at ");
13774 Write_Location (Sloc (N));
13775 Write_Eol;
13776 end if;
13778 -- Now traverse declarations and statements of subprogram body. Note
13779 -- that we cannot simply Traverse (Sbody), since traverse does not
13780 -- normally visit subprogram bodies.
13782 declare
13783 Decl : Node_Id;
13784 begin
13785 Decl := First (Declarations (Sbody));
13786 while Present (Decl) loop
13787 Traverse (Decl);
13788 Next (Decl);
13789 end loop;
13790 end;
13792 Traverse (Handled_Statement_Sequence (Sbody));
13794 Elab_Call.Decrement_Last;
13795 return;
13796 end if;
13798 -- Here is the case of calling a subprogram where the body has not yet
13799 -- been encountered. A warning message is needed, except if this is the
13800 -- case of appearing within an aspect specification that results in
13801 -- a check call, we do not really have such a situation, so no warning
13802 -- is needed (e.g. the case of a precondition, where the call appears
13803 -- textually before the body, but in actual fact is moved to the
13804 -- appropriate subprogram body and so does not need a check).
13806 declare
13807 P : Node_Id;
13808 O : Node_Id;
13810 begin
13811 P := Parent (N);
13812 loop
13813 -- Keep looking at parents if we are still in the subexpression
13815 if Nkind (P) in N_Subexpr then
13816 P := Parent (P);
13818 -- Here P is the parent of the expression, check for special case
13820 else
13821 O := Original_Node (P);
13823 -- Definitely not the special case if orig node is not a pragma
13825 exit when Nkind (O) /= N_Pragma;
13827 -- Check we have an If statement or a null statement (happens
13828 -- when the If has been expanded to be True).
13830 exit when not Nkind_In (P, N_If_Statement, N_Null_Statement);
13832 -- Our special case will be indicated either by the pragma
13833 -- coming from an aspect ...
13835 if Present (Corresponding_Aspect (O)) then
13836 return;
13838 -- Or, in the case of an initial condition, specifically by a
13839 -- Check pragma specifying an Initial_Condition check.
13841 elsif Pragma_Name (O) = Name_Check
13842 and then
13843 Chars
13844 (Expression (First (Pragma_Argument_Associations (O)))) =
13845 Name_Initial_Condition
13846 then
13847 return;
13849 -- For anything else, we have an error
13851 else
13852 exit;
13853 end if;
13854 end if;
13855 end loop;
13856 end;
13858 -- Not that special case, warning and dynamic check is required
13860 -- If we have nothing in the call stack, then this is at the outer
13861 -- level, and the ABE is bound to occur, unless it's a 'Access, or
13862 -- it's a renaming.
13864 if Elab_Call.Last = 0 then
13865 Error_Msg_Warn := SPARK_Mode /= On;
13867 declare
13868 Insert_Check : Boolean := True;
13869 -- This flag is set to True if an elaboration check should be
13870 -- inserted.
13872 begin
13873 if In_Task_Activation then
13874 Insert_Check := False;
13876 elsif Inst_Case then
13877 Error_Msg_NE
13878 ("cannot instantiate& before body seen<<", N, Orig_Ent);
13880 elsif Nkind (N) = N_Attribute_Reference then
13881 Error_Msg_NE
13882 ("Access attribute of & before body seen<<", N, Orig_Ent);
13883 Error_Msg_N ("\possible Program_Error on later references<", N);
13884 Insert_Check := False;
13886 elsif Nkind (Unit_Declaration_Node (Orig_Ent)) /=
13887 N_Subprogram_Renaming_Declaration
13888 then
13889 Error_Msg_NE
13890 ("cannot call& before body seen<<", N, Orig_Ent);
13892 elsif not Is_Generic_Actual_Subprogram (Orig_Ent) then
13893 Insert_Check := False;
13894 end if;
13896 if Insert_Check then
13897 Error_Msg_N ("\Program_Error [<<", N);
13898 Insert_Elab_Check (N);
13899 end if;
13900 end;
13902 -- Call is not at outer level
13904 else
13905 -- Do not generate elaboration checks in GNATprove mode because the
13906 -- elaboration counter and the check are both forms of expansion.
13908 if GNATprove_Mode then
13909 null;
13911 -- Generate an elaboration check
13913 elsif not Elaboration_Checks_Suppressed (E) then
13914 Set_Elaboration_Entity_Required (E);
13916 -- Create a declaration of the elaboration entity, and insert it
13917 -- prior to the subprogram or the generic unit, within the same
13918 -- scope. Since the subprogram may be overloaded, create a unique
13919 -- entity.
13921 if No (Elaboration_Entity (E)) then
13922 declare
13923 Loce : constant Source_Ptr := Sloc (E);
13924 Ent : constant Entity_Id :=
13925 Make_Defining_Identifier (Loc,
13926 New_External_Name (Chars (E), 'E', -1));
13928 begin
13929 Set_Elaboration_Entity (E, Ent);
13930 Push_Scope (Scope (E));
13932 Insert_Action (Declaration_Node (E),
13933 Make_Object_Declaration (Loce,
13934 Defining_Identifier => Ent,
13935 Object_Definition =>
13936 New_Occurrence_Of (Standard_Short_Integer, Loce),
13937 Expression =>
13938 Make_Integer_Literal (Loc, Uint_0)));
13940 -- Set elaboration flag at the point of the body
13942 Set_Elaboration_Flag (Sbody, E);
13944 -- Kill current value indication. This is necessary because
13945 -- the tests of this flag are inserted out of sequence and
13946 -- must not pick up bogus indications of the wrong constant
13947 -- value. Also, this is never a true constant, since one way
13948 -- or another, it gets reset.
13950 Set_Current_Value (Ent, Empty);
13951 Set_Last_Assignment (Ent, Empty);
13952 Set_Is_True_Constant (Ent, False);
13953 Pop_Scope;
13954 end;
13955 end if;
13957 -- Generate:
13958 -- if Enn = 0 then
13959 -- raise Program_Error with "access before elaboration";
13960 -- end if;
13962 Insert_Elab_Check (N,
13963 Make_Attribute_Reference (Loc,
13964 Attribute_Name => Name_Elaborated,
13965 Prefix => New_Occurrence_Of (E, Loc)));
13966 end if;
13968 -- Generate the warning
13970 if not Suppress_Elaboration_Warnings (E)
13971 and then not Elaboration_Checks_Suppressed (E)
13973 -- Suppress this warning if we have a function call that occurred
13974 -- within an assertion expression, since we can get false warnings
13975 -- in this case, due to the out of order handling in this case.
13977 and then
13978 (Nkind (Original_Node (N)) /= N_Function_Call
13979 or else not In_Assertion_Expression_Pragma (Original_Node (N)))
13980 then
13981 Error_Msg_Warn := SPARK_Mode /= On;
13983 if Inst_Case then
13984 Error_Msg_NE
13985 ("instantiation of& may occur before body is seen<l<",
13986 N, Orig_Ent);
13987 else
13988 -- A rather specific check. For Finalize/Adjust/Initialize, if
13989 -- the type has Warnings_Off set, suppress the warning.
13991 if Nam_In (Chars (E), Name_Adjust,
13992 Name_Finalize,
13993 Name_Initialize)
13994 and then Present (First_Formal (E))
13995 then
13996 declare
13997 T : constant Entity_Id := Etype (First_Formal (E));
13998 begin
13999 if Is_Controlled (T) then
14000 if Warnings_Off (T)
14001 or else (Ekind (T) = E_Private_Type
14002 and then Warnings_Off (Full_View (T)))
14003 then
14004 goto Output;
14005 end if;
14006 end if;
14007 end;
14008 end if;
14010 -- Go ahead and give warning if not this special case
14012 Error_Msg_NE
14013 ("call to& may occur before body is seen<l<", N, Orig_Ent);
14014 end if;
14016 Error_Msg_N ("\Program_Error ]<l<", N);
14018 -- There is no need to query the elaboration warning message flags
14019 -- because the main message is an error, not a warning, therefore
14020 -- all the clarification messages produces by Output_Calls must be
14021 -- emitted unconditionally.
14023 <<Output>>
14025 Output_Calls (N, Check_Elab_Flag => False);
14026 end if;
14027 end if;
14028 end Check_Internal_Call_Continue;
14030 ---------------------------
14031 -- Check_Task_Activation --
14032 ---------------------------
14034 procedure Check_Task_Activation (N : Node_Id) is
14035 Loc : constant Source_Ptr := Sloc (N);
14036 Inter_Procs : constant Elist_Id := New_Elmt_List;
14037 Intra_Procs : constant Elist_Id := New_Elmt_List;
14038 Ent : Entity_Id;
14039 P : Entity_Id;
14040 Task_Scope : Entity_Id;
14041 Cunit_SC : Boolean := False;
14042 Decl : Node_Id;
14043 Elmt : Elmt_Id;
14044 Enclosing : Entity_Id;
14046 procedure Add_Task_Proc (Typ : Entity_Id);
14047 -- Add to Task_Procs the task body procedure(s) of task types in Typ.
14048 -- For record types, this procedure recurses over component types.
14050 procedure Collect_Tasks (Decls : List_Id);
14051 -- Collect the types of the tasks that are to be activated in the given
14052 -- list of declarations, in order to perform elaboration checks on the
14053 -- corresponding task procedures that are called implicitly here.
14055 function Outer_Unit (E : Entity_Id) return Entity_Id;
14056 -- find enclosing compilation unit of Entity, ignoring subunits, or
14057 -- else enclosing subprogram. If E is not a package, there is no need
14058 -- for inter-unit elaboration checks.
14060 -------------------
14061 -- Add_Task_Proc --
14062 -------------------
14064 procedure Add_Task_Proc (Typ : Entity_Id) is
14065 Comp : Entity_Id;
14066 Proc : Entity_Id := Empty;
14068 begin
14069 if Is_Task_Type (Typ) then
14070 Proc := Get_Task_Body_Procedure (Typ);
14072 elsif Is_Array_Type (Typ)
14073 and then Has_Task (Base_Type (Typ))
14074 then
14075 Add_Task_Proc (Component_Type (Typ));
14077 elsif Is_Record_Type (Typ)
14078 and then Has_Task (Base_Type (Typ))
14079 then
14080 Comp := First_Component (Typ);
14081 while Present (Comp) loop
14082 Add_Task_Proc (Etype (Comp));
14083 Comp := Next_Component (Comp);
14084 end loop;
14085 end if;
14087 -- If the task type is another unit, we will perform the usual
14088 -- elaboration check on its enclosing unit. If the type is in the
14089 -- same unit, we can trace the task body as for an internal call,
14090 -- but we only need to examine other external calls, because at
14091 -- the point the task is activated, internal subprogram bodies
14092 -- will have been elaborated already. We keep separate lists for
14093 -- each kind of task.
14095 -- Skip this test if errors have occurred, since in this case
14096 -- we can get false indications.
14098 if Serious_Errors_Detected /= 0 then
14099 return;
14100 end if;
14102 if Present (Proc) then
14103 if Outer_Unit (Scope (Proc)) = Enclosing then
14105 if No (Corresponding_Body (Unit_Declaration_Node (Proc)))
14106 and then
14107 (not Is_Generic_Instance (Scope (Proc))
14108 or else Scope (Proc) = Scope (Defining_Identifier (Decl)))
14109 then
14110 Error_Msg_Warn := SPARK_Mode /= On;
14111 Error_Msg_N
14112 ("task will be activated before elaboration of its body<<",
14113 Decl);
14114 Error_Msg_N ("\Program_Error [<<", Decl);
14116 elsif Present
14117 (Corresponding_Body (Unit_Declaration_Node (Proc)))
14118 then
14119 Append_Elmt (Proc, Intra_Procs);
14120 end if;
14122 else
14123 -- No need for multiple entries of the same type
14125 Elmt := First_Elmt (Inter_Procs);
14126 while Present (Elmt) loop
14127 if Node (Elmt) = Proc then
14128 return;
14129 end if;
14131 Next_Elmt (Elmt);
14132 end loop;
14134 Append_Elmt (Proc, Inter_Procs);
14135 end if;
14136 end if;
14137 end Add_Task_Proc;
14139 -------------------
14140 -- Collect_Tasks --
14141 -------------------
14143 procedure Collect_Tasks (Decls : List_Id) is
14144 begin
14145 if Present (Decls) then
14146 Decl := First (Decls);
14147 while Present (Decl) loop
14148 if Nkind (Decl) = N_Object_Declaration
14149 and then Has_Task (Etype (Defining_Identifier (Decl)))
14150 then
14151 Add_Task_Proc (Etype (Defining_Identifier (Decl)));
14152 end if;
14154 Next (Decl);
14155 end loop;
14156 end if;
14157 end Collect_Tasks;
14159 ----------------
14160 -- Outer_Unit --
14161 ----------------
14163 function Outer_Unit (E : Entity_Id) return Entity_Id is
14164 Outer : Entity_Id;
14166 begin
14167 Outer := E;
14168 while Present (Outer) loop
14169 if Elaboration_Checks_Suppressed (Outer) then
14170 Cunit_SC := True;
14171 end if;
14173 exit when Is_Child_Unit (Outer)
14174 or else Scope (Outer) = Standard_Standard
14175 or else Ekind (Outer) /= E_Package;
14176 Outer := Scope (Outer);
14177 end loop;
14179 return Outer;
14180 end Outer_Unit;
14182 -- Start of processing for Check_Task_Activation
14184 begin
14185 pragma Assert (Legacy_Elaboration_Checks);
14187 Enclosing := Outer_Unit (Current_Scope);
14189 -- Find all tasks declared in the current unit
14191 if Nkind (N) = N_Package_Body then
14192 P := Unit_Declaration_Node (Corresponding_Spec (N));
14194 Collect_Tasks (Declarations (N));
14195 Collect_Tasks (Visible_Declarations (Specification (P)));
14196 Collect_Tasks (Private_Declarations (Specification (P)));
14198 elsif Nkind (N) = N_Package_Declaration then
14199 Collect_Tasks (Visible_Declarations (Specification (N)));
14200 Collect_Tasks (Private_Declarations (Specification (N)));
14202 else
14203 Collect_Tasks (Declarations (N));
14204 end if;
14206 -- We only perform detailed checks in all tasks that are library level
14207 -- entities. If the master is a subprogram or task, activation will
14208 -- depend on the activation of the master itself.
14210 -- Should dynamic checks be added in the more general case???
14212 if Ekind (Enclosing) /= E_Package then
14213 return;
14214 end if;
14216 -- For task types defined in other units, we want the unit containing
14217 -- the task body to be elaborated before the current one.
14219 Elmt := First_Elmt (Inter_Procs);
14220 while Present (Elmt) loop
14221 Ent := Node (Elmt);
14222 Task_Scope := Outer_Unit (Scope (Ent));
14224 if not Is_Compilation_Unit (Task_Scope) then
14225 null;
14227 elsif Suppress_Elaboration_Warnings (Task_Scope)
14228 or else Elaboration_Checks_Suppressed (Task_Scope)
14229 then
14230 null;
14232 elsif Dynamic_Elaboration_Checks then
14233 if not Elaboration_Checks_Suppressed (Ent)
14234 and then not Cunit_SC
14235 and then not Restriction_Active
14236 (No_Entry_Calls_In_Elaboration_Code)
14237 then
14238 -- Runtime elaboration check required. Generate check of the
14239 -- elaboration counter for the unit containing the entity.
14241 Insert_Elab_Check (N,
14242 Make_Attribute_Reference (Loc,
14243 Prefix =>
14244 New_Occurrence_Of (Spec_Entity (Task_Scope), Loc),
14245 Attribute_Name => Name_Elaborated));
14246 end if;
14248 else
14249 -- Force the binder to elaborate other unit first
14251 if Elab_Info_Messages
14252 and then not Suppress_Elaboration_Warnings (Ent)
14253 and then not Elaboration_Checks_Suppressed (Ent)
14254 and then not Suppress_Elaboration_Warnings (Task_Scope)
14255 and then not Elaboration_Checks_Suppressed (Task_Scope)
14256 then
14257 Error_Msg_Node_2 := Task_Scope;
14258 Error_Msg_NE
14259 ("info: activation of an instance of task type & requires "
14260 & "pragma Elaborate_All on &?$?", N, Ent);
14261 end if;
14263 Activate_Elaborate_All_Desirable (N, Task_Scope);
14264 Set_Suppress_Elaboration_Warnings (Task_Scope);
14265 end if;
14267 Next_Elmt (Elmt);
14268 end loop;
14270 -- For tasks declared in the current unit, trace other calls within the
14271 -- task procedure bodies, which are available.
14273 if not Debug_Flag_Dot_Y then
14274 In_Task_Activation := True;
14276 Elmt := First_Elmt (Intra_Procs);
14277 while Present (Elmt) loop
14278 Ent := Node (Elmt);
14279 Check_Internal_Call_Continue (N, Ent, Enclosing, Ent);
14280 Next_Elmt (Elmt);
14281 end loop;
14283 In_Task_Activation := False;
14284 end if;
14285 end Check_Task_Activation;
14287 ------------------------
14288 -- Get_Referenced_Ent --
14289 ------------------------
14291 function Get_Referenced_Ent (N : Node_Id) return Entity_Id is
14292 Nam : Node_Id;
14294 begin
14295 if Nkind (N) in N_Has_Entity
14296 and then Present (Entity (N))
14297 and then Ekind (Entity (N)) = E_Variable
14298 then
14299 return Entity (N);
14300 end if;
14302 if Nkind (N) = N_Attribute_Reference then
14303 Nam := Prefix (N);
14304 else
14305 Nam := Name (N);
14306 end if;
14308 if No (Nam) then
14309 return Empty;
14310 elsif Nkind (Nam) = N_Selected_Component then
14311 return Entity (Selector_Name (Nam));
14312 elsif not Is_Entity_Name (Nam) then
14313 return Empty;
14314 else
14315 return Entity (Nam);
14316 end if;
14317 end Get_Referenced_Ent;
14319 ----------------------
14320 -- Has_Generic_Body --
14321 ----------------------
14323 function Has_Generic_Body (N : Node_Id) return Boolean is
14324 Ent : constant Entity_Id := Get_Generic_Entity (N);
14325 Decl : constant Node_Id := Unit_Declaration_Node (Ent);
14326 Scop : Entity_Id;
14328 function Find_Body_In (E : Entity_Id; N : Node_Id) return Node_Id;
14329 -- Determine if the list of nodes headed by N and linked by Next
14330 -- contains a package body for the package spec entity E, and if so
14331 -- return the package body. If not, then returns Empty.
14333 function Load_Package_Body (Nam : Unit_Name_Type) return Node_Id;
14334 -- This procedure is called load the unit whose name is given by Nam.
14335 -- This unit is being loaded to see whether it contains an optional
14336 -- generic body. The returned value is the loaded unit, which is always
14337 -- a package body (only package bodies can contain other entities in the
14338 -- sense in which Has_Generic_Body is interested). We only attempt to
14339 -- load bodies if we are generating code. If we are in semantics check
14340 -- only mode, then it would be wrong to load bodies that are not
14341 -- required from a semantic point of view, so in this case we return
14342 -- Empty. The result is that the caller may incorrectly decide that a
14343 -- generic spec does not have a body when in fact it does, but the only
14344 -- harm in this is that some warnings on elaboration problems may be
14345 -- lost in semantic checks only mode, which is not big loss. We also
14346 -- return Empty if we go for a body and it is not there.
14348 function Locate_Corresponding_Body (PE : Entity_Id) return Node_Id;
14349 -- PE is the entity for a package spec. This function locates the
14350 -- corresponding package body, returning Empty if none is found. The
14351 -- package body returned is fully parsed but may not yet be analyzed,
14352 -- so only syntactic fields should be referenced.
14354 ------------------
14355 -- Find_Body_In --
14356 ------------------
14358 function Find_Body_In (E : Entity_Id; N : Node_Id) return Node_Id is
14359 Nod : Node_Id;
14361 begin
14362 Nod := N;
14363 while Present (Nod) loop
14365 -- If we found the package body we are looking for, return it
14367 if Nkind (Nod) = N_Package_Body
14368 and then Chars (Defining_Unit_Name (Nod)) = Chars (E)
14369 then
14370 return Nod;
14372 -- If we found the stub for the body, go after the subunit,
14373 -- loading it if necessary.
14375 elsif Nkind (Nod) = N_Package_Body_Stub
14376 and then Chars (Defining_Identifier (Nod)) = Chars (E)
14377 then
14378 if Present (Library_Unit (Nod)) then
14379 return Unit (Library_Unit (Nod));
14381 else
14382 return Load_Package_Body (Get_Unit_Name (Nod));
14383 end if;
14385 -- If neither package body nor stub, keep looking on chain
14387 else
14388 Next (Nod);
14389 end if;
14390 end loop;
14392 return Empty;
14393 end Find_Body_In;
14395 -----------------------
14396 -- Load_Package_Body --
14397 -----------------------
14399 function Load_Package_Body (Nam : Unit_Name_Type) return Node_Id is
14400 U : Unit_Number_Type;
14402 begin
14403 if Operating_Mode /= Generate_Code then
14404 return Empty;
14405 else
14406 U :=
14407 Load_Unit
14408 (Load_Name => Nam,
14409 Required => False,
14410 Subunit => False,
14411 Error_Node => N);
14413 if U = No_Unit then
14414 return Empty;
14415 else
14416 return Unit (Cunit (U));
14417 end if;
14418 end if;
14419 end Load_Package_Body;
14421 -------------------------------
14422 -- Locate_Corresponding_Body --
14423 -------------------------------
14425 function Locate_Corresponding_Body (PE : Entity_Id) return Node_Id is
14426 Spec : constant Node_Id := Declaration_Node (PE);
14427 Decl : constant Node_Id := Parent (Spec);
14428 Scop : constant Entity_Id := Scope (PE);
14429 PBody : Node_Id;
14431 begin
14432 if Is_Library_Level_Entity (PE) then
14434 -- If package is a library unit that requires a body, we have no
14435 -- choice but to go after that body because it might contain an
14436 -- optional body for the original generic package.
14438 if Unit_Requires_Body (PE) then
14440 -- Load the body. Note that we are a little careful here to use
14441 -- Spec to get the unit number, rather than PE or Decl, since
14442 -- in the case where the package is itself a library level
14443 -- instantiation, Spec will properly reference the generic
14444 -- template, which is what we really want.
14446 return
14447 Load_Package_Body
14448 (Get_Body_Name (Unit_Name (Get_Source_Unit (Spec))));
14450 -- But if the package is a library unit that does NOT require
14451 -- a body, then no body is permitted, so we are sure that there
14452 -- is no body for the original generic package.
14454 else
14455 return Empty;
14456 end if;
14458 -- Otherwise look and see if we are embedded in a further package
14460 elsif Is_Package_Or_Generic_Package (Scop) then
14462 -- If so, get the body of the enclosing package, and look in
14463 -- its package body for the package body we are looking for.
14465 PBody := Locate_Corresponding_Body (Scop);
14467 if No (PBody) then
14468 return Empty;
14469 else
14470 return Find_Body_In (PE, First (Declarations (PBody)));
14471 end if;
14473 -- If we are not embedded in a further package, then the body
14474 -- must be in the same declarative part as we are.
14476 else
14477 return Find_Body_In (PE, Next (Decl));
14478 end if;
14479 end Locate_Corresponding_Body;
14481 -- Start of processing for Has_Generic_Body
14483 begin
14484 if Present (Corresponding_Body (Decl)) then
14485 return True;
14487 elsif Unit_Requires_Body (Ent) then
14488 return True;
14490 -- Compilation units cannot have optional bodies
14492 elsif Is_Compilation_Unit (Ent) then
14493 return False;
14495 -- Otherwise look at what scope we are in
14497 else
14498 Scop := Scope (Ent);
14500 -- Case of entity is in other than a package spec, in this case
14501 -- the body, if present, must be in the same declarative part.
14503 if not Is_Package_Or_Generic_Package (Scop) then
14504 declare
14505 P : Node_Id;
14507 begin
14508 -- Declaration node may get us a spec, so if so, go to
14509 -- the parent declaration.
14511 P := Declaration_Node (Ent);
14512 while not Is_List_Member (P) loop
14513 P := Parent (P);
14514 end loop;
14516 return Present (Find_Body_In (Ent, Next (P)));
14517 end;
14519 -- If the entity is in a package spec, then we have to locate
14520 -- the corresponding package body, and look there.
14522 else
14523 declare
14524 PBody : constant Node_Id := Locate_Corresponding_Body (Scop);
14526 begin
14527 if No (PBody) then
14528 return False;
14529 else
14530 return
14531 Present
14532 (Find_Body_In (Ent, (First (Declarations (PBody)))));
14533 end if;
14534 end;
14535 end if;
14536 end if;
14537 end Has_Generic_Body;
14539 -----------------------
14540 -- Insert_Elab_Check --
14541 -----------------------
14543 procedure Insert_Elab_Check (N : Node_Id; C : Node_Id := Empty) is
14544 Nod : Node_Id;
14545 Loc : constant Source_Ptr := Sloc (N);
14547 Chk : Node_Id;
14548 -- The check (N_Raise_Program_Error) node to be inserted
14550 begin
14551 -- If expansion is disabled, do not generate any checks. Also
14552 -- skip checks if any subunits are missing because in either
14553 -- case we lack the full information that we need, and no object
14554 -- file will be created in any case.
14556 if not Expander_Active or else Subunits_Missing then
14557 return;
14558 end if;
14560 -- If we have a generic instantiation, where Instance_Spec is set,
14561 -- then this field points to a generic instance spec that has
14562 -- been inserted before the instantiation node itself, so that
14563 -- is where we want to insert a check.
14565 if Nkind (N) in N_Generic_Instantiation
14566 and then Present (Instance_Spec (N))
14567 then
14568 Nod := Instance_Spec (N);
14569 else
14570 Nod := N;
14571 end if;
14573 -- Build check node, possibly with condition
14575 Chk :=
14576 Make_Raise_Program_Error (Loc, Reason => PE_Access_Before_Elaboration);
14578 if Present (C) then
14579 Set_Condition (Chk, Make_Op_Not (Loc, Right_Opnd => C));
14580 end if;
14582 -- If we are inserting at the top level, insert in Aux_Decls
14584 if Nkind (Parent (Nod)) = N_Compilation_Unit then
14585 declare
14586 ADN : constant Node_Id := Aux_Decls_Node (Parent (Nod));
14588 begin
14589 if No (Declarations (ADN)) then
14590 Set_Declarations (ADN, New_List (Chk));
14591 else
14592 Append_To (Declarations (ADN), Chk);
14593 end if;
14595 Analyze (Chk);
14596 end;
14598 -- Otherwise just insert as an action on the node in question
14600 else
14601 Insert_Action (Nod, Chk);
14602 end if;
14603 end Insert_Elab_Check;
14605 -------------------------------
14606 -- Is_Call_Of_Generic_Formal --
14607 -------------------------------
14609 function Is_Call_Of_Generic_Formal (N : Node_Id) return Boolean is
14610 begin
14611 return Nkind_In (N, N_Function_Call, N_Procedure_Call_Statement)
14613 -- Always return False if debug flag -gnatd.G is set
14615 and then not Debug_Flag_Dot_GG
14617 -- For now, we detect this by looking for the strange identifier
14618 -- node, whose Chars reflect the name of the generic formal, but
14619 -- the Chars of the Entity references the generic actual.
14621 and then Nkind (Name (N)) = N_Identifier
14622 and then Chars (Name (N)) /= Chars (Entity (Name (N)));
14623 end Is_Call_Of_Generic_Formal;
14625 -------------------------------
14626 -- Is_Finalization_Procedure --
14627 -------------------------------
14629 function Is_Finalization_Procedure (Id : Entity_Id) return Boolean is
14630 begin
14631 -- Check whether Id is a procedure with at least one parameter
14633 if Ekind (Id) = E_Procedure and then Present (First_Formal (Id)) then
14634 declare
14635 Typ : constant Entity_Id := Etype (First_Formal (Id));
14636 Deep_Fin : Entity_Id := Empty;
14637 Fin : Entity_Id := Empty;
14639 begin
14640 -- If the type of the first formal does not require finalization
14641 -- actions, then this is definitely not [Deep_]Finalize.
14643 if not Needs_Finalization (Typ) then
14644 return False;
14645 end if;
14647 -- At this point we have the following scenario:
14649 -- procedure Name (Param1 : [in] [out] Ctrl[; Param2 : ...]);
14651 -- Recover the two possible versions of [Deep_]Finalize using the
14652 -- type of the first parameter and compare with the input.
14654 Deep_Fin := TSS (Typ, TSS_Deep_Finalize);
14656 if Is_Controlled (Typ) then
14657 Fin := Find_Prim_Op (Typ, Name_Finalize);
14658 end if;
14660 return (Present (Deep_Fin) and then Id = Deep_Fin)
14661 or else (Present (Fin) and then Id = Fin);
14662 end;
14663 end if;
14665 return False;
14666 end Is_Finalization_Procedure;
14668 ------------------
14669 -- Output_Calls --
14670 ------------------
14672 procedure Output_Calls
14673 (N : Node_Id;
14674 Check_Elab_Flag : Boolean)
14676 function Emit (Flag : Boolean) return Boolean;
14677 -- Determine whether to emit an error message based on the combination
14678 -- of flags Check_Elab_Flag and Flag.
14680 function Is_Printable_Error_Name return Boolean;
14681 -- An internal function, used to determine if a name, stored in the
14682 -- Name_Buffer, is either a non-internal name, or is an internal name
14683 -- that is printable by the error message circuits (i.e. it has a single
14684 -- upper case letter at the end).
14686 ----------
14687 -- Emit --
14688 ----------
14690 function Emit (Flag : Boolean) return Boolean is
14691 begin
14692 if Check_Elab_Flag then
14693 return Flag;
14694 else
14695 return True;
14696 end if;
14697 end Emit;
14699 -----------------------------
14700 -- Is_Printable_Error_Name --
14701 -----------------------------
14703 function Is_Printable_Error_Name return Boolean is
14704 begin
14705 if not Is_Internal_Name then
14706 return True;
14708 elsif Name_Len = 1 then
14709 return False;
14711 else
14712 Name_Len := Name_Len - 1;
14713 return not Is_Internal_Name;
14714 end if;
14715 end Is_Printable_Error_Name;
14717 -- Local variables
14719 Ent : Entity_Id;
14721 -- Start of processing for Output_Calls
14723 begin
14724 for J in reverse 1 .. Elab_Call.Last loop
14725 Error_Msg_Sloc := Elab_Call.Table (J).Cloc;
14727 Ent := Elab_Call.Table (J).Ent;
14728 Get_Name_String (Chars (Ent));
14730 -- Dynamic elaboration model, warnings controlled by -gnatwl
14732 if Dynamic_Elaboration_Checks then
14733 if Emit (Elab_Warnings) then
14734 if Is_Generic_Unit (Ent) then
14735 Error_Msg_NE ("\\?l?& instantiated #", N, Ent);
14736 elsif Is_Init_Proc (Ent) then
14737 Error_Msg_N ("\\?l?initialization procedure called #", N);
14738 elsif Is_Printable_Error_Name then
14739 Error_Msg_NE ("\\?l?& called #", N, Ent);
14740 else
14741 Error_Msg_N ("\\?l?called #", N);
14742 end if;
14743 end if;
14745 -- Static elaboration model, info messages controlled by -gnatel
14747 else
14748 if Emit (Elab_Info_Messages) then
14749 if Is_Generic_Unit (Ent) then
14750 Error_Msg_NE ("\\?$?& instantiated #", N, Ent);
14751 elsif Is_Init_Proc (Ent) then
14752 Error_Msg_N ("\\?$?initialization procedure called #", N);
14753 elsif Is_Printable_Error_Name then
14754 Error_Msg_NE ("\\?$?& called #", N, Ent);
14755 else
14756 Error_Msg_N ("\\?$?called #", N);
14757 end if;
14758 end if;
14759 end if;
14760 end loop;
14761 end Output_Calls;
14763 ----------------------------
14764 -- Same_Elaboration_Scope --
14765 ----------------------------
14767 function Same_Elaboration_Scope (Scop1, Scop2 : Entity_Id) return Boolean is
14768 S1 : Entity_Id;
14769 S2 : Entity_Id;
14771 begin
14772 -- Find elaboration scope for Scop1
14773 -- This is either a subprogram or a compilation unit.
14775 S1 := Scop1;
14776 while S1 /= Standard_Standard
14777 and then not Is_Compilation_Unit (S1)
14778 and then Ekind_In (S1, E_Package, E_Protected_Type, E_Block)
14779 loop
14780 S1 := Scope (S1);
14781 end loop;
14783 -- Find elaboration scope for Scop2
14785 S2 := Scop2;
14786 while S2 /= Standard_Standard
14787 and then not Is_Compilation_Unit (S2)
14788 and then Ekind_In (S2, E_Package, E_Protected_Type, E_Block)
14789 loop
14790 S2 := Scope (S2);
14791 end loop;
14793 return S1 = S2;
14794 end Same_Elaboration_Scope;
14796 -----------------
14797 -- Set_C_Scope --
14798 -----------------
14800 procedure Set_C_Scope is
14801 begin
14802 while not Is_Compilation_Unit (C_Scope) loop
14803 C_Scope := Scope (C_Scope);
14804 end loop;
14805 end Set_C_Scope;
14807 --------------------------------
14808 -- Set_Elaboration_Constraint --
14809 --------------------------------
14811 procedure Set_Elaboration_Constraint
14812 (Call : Node_Id;
14813 Subp : Entity_Id;
14814 Scop : Entity_Id)
14816 Elab_Unit : Entity_Id;
14818 -- Check whether this is a call to an Initialize subprogram for a
14819 -- controlled type. Note that Call can also be a 'Access attribute
14820 -- reference, which now generates an elaboration check.
14822 Init_Call : constant Boolean :=
14823 Nkind (Call) = N_Procedure_Call_Statement
14824 and then Chars (Subp) = Name_Initialize
14825 and then Comes_From_Source (Subp)
14826 and then Present (Parameter_Associations (Call))
14827 and then Is_Controlled (Etype (First_Actual (Call)));
14829 begin
14830 -- If the unit is mentioned in a with_clause of the current unit, it is
14831 -- visible, and we can set the elaboration flag.
14833 if Is_Immediately_Visible (Scop)
14834 or else (Is_Child_Unit (Scop) and then Is_Visible_Lib_Unit (Scop))
14835 then
14836 Activate_Elaborate_All_Desirable (Call, Scop);
14837 Set_Suppress_Elaboration_Warnings (Scop);
14838 return;
14839 end if;
14841 -- If this is not an initialization call or a call using object notation
14842 -- we know that the unit of the called entity is in the context, and we
14843 -- can set the flag as well. The unit need not be visible if the call
14844 -- occurs within an instantiation.
14846 if Is_Init_Proc (Subp)
14847 or else Init_Call
14848 or else Nkind (Original_Node (Call)) = N_Selected_Component
14849 then
14850 null; -- detailed processing follows.
14852 else
14853 Activate_Elaborate_All_Desirable (Call, Scop);
14854 Set_Suppress_Elaboration_Warnings (Scop);
14855 return;
14856 end if;
14858 -- If the unit is not in the context, there must be an intermediate unit
14859 -- that is, on which we need to place to elaboration flag. This happens
14860 -- with init proc calls.
14862 if Is_Init_Proc (Subp) or else Init_Call then
14864 -- The initialization call is on an object whose type is not declared
14865 -- in the same scope as the subprogram. The type of the object must
14866 -- be a subtype of the type of operation. This object is the first
14867 -- actual in the call.
14869 declare
14870 Typ : constant Entity_Id :=
14871 Etype (First (Parameter_Associations (Call)));
14872 begin
14873 Elab_Unit := Scope (Typ);
14874 while (Present (Elab_Unit))
14875 and then not Is_Compilation_Unit (Elab_Unit)
14876 loop
14877 Elab_Unit := Scope (Elab_Unit);
14878 end loop;
14879 end;
14881 -- If original node uses selected component notation, the prefix is
14882 -- visible and determines the scope that must be elaborated. After
14883 -- rewriting, the prefix is the first actual in the call.
14885 elsif Nkind (Original_Node (Call)) = N_Selected_Component then
14886 Elab_Unit := Scope (Etype (First (Parameter_Associations (Call))));
14888 -- Not one of special cases above
14890 else
14891 -- Using previously computed scope. If the elaboration check is
14892 -- done after analysis, the scope is not visible any longer, but
14893 -- must still be in the context.
14895 Elab_Unit := Scop;
14896 end if;
14898 Activate_Elaborate_All_Desirable (Call, Elab_Unit);
14899 Set_Suppress_Elaboration_Warnings (Elab_Unit);
14900 end Set_Elaboration_Constraint;
14902 -----------------
14903 -- Spec_Entity --
14904 -----------------
14906 function Spec_Entity (E : Entity_Id) return Entity_Id is
14907 Decl : Node_Id;
14909 begin
14910 -- Check for case of body entity
14911 -- Why is the check for E_Void needed???
14913 if Ekind_In (E, E_Void, E_Subprogram_Body, E_Package_Body) then
14914 Decl := E;
14916 loop
14917 Decl := Parent (Decl);
14918 exit when Nkind (Decl) in N_Proper_Body;
14919 end loop;
14921 return Corresponding_Spec (Decl);
14923 else
14924 return E;
14925 end if;
14926 end Spec_Entity;
14928 ------------
14929 -- Within --
14930 ------------
14932 function Within (E1, E2 : Entity_Id) return Boolean is
14933 Scop : Entity_Id;
14934 begin
14935 Scop := E1;
14936 loop
14937 if Scop = E2 then
14938 return True;
14939 elsif Scop = Standard_Standard then
14940 return False;
14941 else
14942 Scop := Scope (Scop);
14943 end if;
14944 end loop;
14945 end Within;
14947 --------------------------
14948 -- Within_Elaborate_All --
14949 --------------------------
14951 function Within_Elaborate_All
14952 (Unit : Unit_Number_Type;
14953 E : Entity_Id) return Boolean
14955 type Unit_Number_Set is array (Main_Unit .. Last_Unit) of Boolean;
14956 pragma Pack (Unit_Number_Set);
14958 Seen : Unit_Number_Set := (others => False);
14959 -- Seen (X) is True after we have seen unit X in the walk. This is used
14960 -- to prevent processing the same unit more than once.
14962 Result : Boolean := False;
14964 procedure Helper (Unit : Unit_Number_Type);
14965 -- This helper procedure does all the work for Within_Elaborate_All. It
14966 -- walks the dependency graph, and sets Result to True if it finds an
14967 -- appropriate Elaborate_All.
14969 ------------
14970 -- Helper --
14971 ------------
14973 procedure Helper (Unit : Unit_Number_Type) is
14974 CU : constant Node_Id := Cunit (Unit);
14976 Item : Node_Id;
14977 Item2 : Node_Id;
14978 Elab_Id : Entity_Id;
14979 Par : Node_Id;
14981 begin
14982 if Seen (Unit) then
14983 return;
14984 else
14985 Seen (Unit) := True;
14986 end if;
14988 -- First, check for Elaborate_Alls on this unit
14990 Item := First (Context_Items (CU));
14991 while Present (Item) loop
14992 if Nkind (Item) = N_Pragma
14993 and then Pragma_Name (Item) = Name_Elaborate_All
14994 then
14995 -- Return if some previous error on the pragma itself. The
14996 -- pragma may be unanalyzed, because of a previous error, or
14997 -- if it is the context of a subunit, inherited by its parent.
14999 if Error_Posted (Item) or else not Analyzed (Item) then
15000 return;
15001 end if;
15003 Elab_Id :=
15004 Entity
15005 (Expression (First (Pragma_Argument_Associations (Item))));
15007 if E = Elab_Id then
15008 Result := True;
15009 return;
15010 end if;
15012 Par := Parent (Unit_Declaration_Node (Elab_Id));
15014 Item2 := First (Context_Items (Par));
15015 while Present (Item2) loop
15016 if Nkind (Item2) = N_With_Clause
15017 and then Entity (Name (Item2)) = E
15018 and then not Limited_Present (Item2)
15019 then
15020 Result := True;
15021 return;
15022 end if;
15024 Next (Item2);
15025 end loop;
15026 end if;
15028 Next (Item);
15029 end loop;
15031 -- Second, recurse on with's. We could do this as part of the above
15032 -- loop, but it's probably more efficient to have two loops, because
15033 -- the relevant Elaborate_All is likely to be on the initial unit. In
15034 -- other words, we're walking the with's breadth-first. This part is
15035 -- only necessary in the dynamic elaboration model.
15037 if Dynamic_Elaboration_Checks then
15038 Item := First (Context_Items (CU));
15039 while Present (Item) loop
15040 if Nkind (Item) = N_With_Clause
15041 and then not Limited_Present (Item)
15042 then
15043 -- Note: the following call to Get_Cunit_Unit_Number does a
15044 -- linear search, which could be slow, but it's OK because
15045 -- we're about to give a warning anyway. Also, there might
15046 -- be hundreds of units, but not millions. If it turns out
15047 -- to be a problem, we could store the Get_Cunit_Unit_Number
15048 -- in each N_Compilation_Unit node, but that would involve
15049 -- rearranging N_Compilation_Unit_Aux to make room.
15051 Helper (Get_Cunit_Unit_Number (Library_Unit (Item)));
15053 if Result then
15054 return;
15055 end if;
15056 end if;
15058 Next (Item);
15059 end loop;
15060 end if;
15061 end Helper;
15063 -- Start of processing for Within_Elaborate_All
15065 begin
15066 Helper (Unit);
15067 return Result;
15068 end Within_Elaborate_All;
15070 end Sem_Elab;