1 ------------------------------------------------------------------------------
3 -- GNAT COMPILER COMPONENTS --
9 -- Copyright (C) 1992-2010, Free Software Foundation, Inc. --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
24 ------------------------------------------------------------------------------
26 with Atree
; use Atree
;
27 with Einfo
; use Einfo
;
28 with Elists
; use Elists
;
29 with Errout
; use Errout
;
30 with Expander
; use Expander
;
31 with Fname
; use Fname
;
32 with Fname
.UF
; use Fname
.UF
;
33 with Freeze
; use Freeze
;
35 with Itypes
; use Itypes
;
37 with Lib
.Load
; use Lib
.Load
;
38 with Lib
.Xref
; use Lib
.Xref
;
39 with Nlists
; use Nlists
;
40 with Namet
; use Namet
;
41 with Nmake
; use Nmake
;
43 with Rident
; use Rident
;
44 with Restrict
; use Restrict
;
45 with Rtsfind
; use Rtsfind
;
47 with Sem_Aux
; use Sem_Aux
;
48 with Sem_Cat
; use Sem_Cat
;
49 with Sem_Ch3
; use Sem_Ch3
;
50 with Sem_Ch6
; use Sem_Ch6
;
51 with Sem_Ch7
; use Sem_Ch7
;
52 with Sem_Ch8
; use Sem_Ch8
;
53 with Sem_Ch10
; use Sem_Ch10
;
54 with Sem_Ch13
; use Sem_Ch13
;
55 with Sem_Disp
; use Sem_Disp
;
56 with Sem_Elab
; use Sem_Elab
;
57 with Sem_Elim
; use Sem_Elim
;
58 with Sem_Eval
; use Sem_Eval
;
59 with Sem_Res
; use Sem_Res
;
60 with Sem_Type
; use Sem_Type
;
61 with Sem_Util
; use Sem_Util
;
62 with Sem_Warn
; use Sem_Warn
;
63 with Stand
; use Stand
;
64 with Sinfo
; use Sinfo
;
65 with Sinfo
.CN
; use Sinfo
.CN
;
66 with Sinput
; use Sinput
;
67 with Sinput
.L
; use Sinput
.L
;
68 with Snames
; use Snames
;
69 with Stringt
; use Stringt
;
70 with Uname
; use Uname
;
72 with Tbuild
; use Tbuild
;
73 with Uintp
; use Uintp
;
74 with Urealp
; use Urealp
;
78 package body Sem_Ch12
is
80 ----------------------------------------------------------
81 -- Implementation of Generic Analysis and Instantiation --
82 ----------------------------------------------------------
84 -- GNAT implements generics by macro expansion. No attempt is made to share
85 -- generic instantiations (for now). Analysis of a generic definition does
86 -- not perform any expansion action, but the expander must be called on the
87 -- tree for each instantiation, because the expansion may of course depend
88 -- on the generic actuals. All of this is best achieved as follows:
90 -- a) Semantic analysis of a generic unit is performed on a copy of the
91 -- tree for the generic unit. All tree modifications that follow analysis
92 -- do not affect the original tree. Links are kept between the original
93 -- tree and the copy, in order to recognize non-local references within
94 -- the generic, and propagate them to each instance (recall that name
95 -- resolution is done on the generic declaration: generics are not really
96 -- macros!). This is summarized in the following diagram:
98 -- .-----------. .----------.
99 -- | semantic |<--------------| generic |
101 -- | |==============>| |
102 -- |___________| global |__________|
113 -- b) Each instantiation copies the original tree, and inserts into it a
114 -- series of declarations that describe the mapping between generic formals
115 -- and actuals. For example, a generic In OUT parameter is an object
116 -- renaming of the corresponding actual, etc. Generic IN parameters are
117 -- constant declarations.
119 -- c) In order to give the right visibility for these renamings, we use
120 -- a different scheme for package and subprogram instantiations. For
121 -- packages, the list of renamings is inserted into the package
122 -- specification, before the visible declarations of the package. The
123 -- renamings are analyzed before any of the text of the instance, and are
124 -- thus visible at the right place. Furthermore, outside of the instance,
125 -- the generic parameters are visible and denote their corresponding
128 -- For subprograms, we create a container package to hold the renamings
129 -- and the subprogram instance itself. Analysis of the package makes the
130 -- renaming declarations visible to the subprogram. After analyzing the
131 -- package, the defining entity for the subprogram is touched-up so that
132 -- it appears declared in the current scope, and not inside the container
135 -- If the instantiation is a compilation unit, the container package is
136 -- given the same name as the subprogram instance. This ensures that
137 -- the elaboration procedure called by the binder, using the compilation
138 -- unit name, calls in fact the elaboration procedure for the package.
140 -- Not surprisingly, private types complicate this approach. By saving in
141 -- the original generic object the non-local references, we guarantee that
142 -- the proper entities are referenced at the point of instantiation.
143 -- However, for private types, this by itself does not insure that the
144 -- proper VIEW of the entity is used (the full type may be visible at the
145 -- point of generic definition, but not at instantiation, or vice-versa).
146 -- In order to reference the proper view, we special-case any reference
147 -- to private types in the generic object, by saving both views, one in
148 -- the generic and one in the semantic copy. At time of instantiation, we
149 -- check whether the two views are consistent, and exchange declarations if
150 -- necessary, in order to restore the correct visibility. Similarly, if
151 -- the instance view is private when the generic view was not, we perform
152 -- the exchange. After completing the instantiation, we restore the
153 -- current visibility. The flag Has_Private_View marks identifiers in the
154 -- the generic unit that require checking.
156 -- Visibility within nested generic units requires special handling.
157 -- Consider the following scheme:
159 -- type Global is ... -- outside of generic unit.
163 -- type Semi_Global is ... -- global to inner.
166 -- procedure inner (X1 : Global; X2 : Semi_Global);
168 -- procedure in2 is new inner (...); -- 4
171 -- package New_Outer is new Outer (...); -- 2
172 -- procedure New_Inner is new New_Outer.Inner (...); -- 3
174 -- The semantic analysis of Outer captures all occurrences of Global.
175 -- The semantic analysis of Inner (at 1) captures both occurrences of
176 -- Global and Semi_Global.
178 -- At point 2 (instantiation of Outer), we also produce a generic copy
179 -- of Inner, even though Inner is, at that point, not being instantiated.
180 -- (This is just part of the semantic analysis of New_Outer).
182 -- Critically, references to Global within Inner must be preserved, while
183 -- references to Semi_Global should not preserved, because they must now
184 -- resolve to an entity within New_Outer. To distinguish between these, we
185 -- use a global variable, Current_Instantiated_Parent, which is set when
186 -- performing a generic copy during instantiation (at 2). This variable is
187 -- used when performing a generic copy that is not an instantiation, but
188 -- that is nested within one, as the occurrence of 1 within 2. The analysis
189 -- of a nested generic only preserves references that are global to the
190 -- enclosing Current_Instantiated_Parent. We use the Scope_Depth value to
191 -- determine whether a reference is external to the given parent.
193 -- The instantiation at point 3 requires no special treatment. The method
194 -- works as well for further nestings of generic units, but of course the
195 -- variable Current_Instantiated_Parent must be stacked because nested
196 -- instantiations can occur, e.g. the occurrence of 4 within 2.
198 -- The instantiation of package and subprogram bodies is handled in a
199 -- similar manner, except that it is delayed until after semantic
200 -- analysis is complete. In this fashion complex cross-dependencies
201 -- between several package declarations and bodies containing generics
202 -- can be compiled which otherwise would diagnose spurious circularities.
204 -- For example, it is possible to compile two packages A and B that
205 -- have the following structure:
207 -- package A is package B is
208 -- generic ... generic ...
209 -- package G_A is package G_B is
212 -- package body A is package body B is
213 -- package N_B is new G_B (..) package N_A is new G_A (..)
215 -- The table Pending_Instantiations in package Inline is used to keep
216 -- track of body instantiations that are delayed in this manner. Inline
217 -- handles the actual calls to do the body instantiations. This activity
218 -- is part of Inline, since the processing occurs at the same point, and
219 -- for essentially the same reason, as the handling of inlined routines.
221 ----------------------------------------------
222 -- Detection of Instantiation Circularities --
223 ----------------------------------------------
225 -- If we have a chain of instantiations that is circular, this is static
226 -- error which must be detected at compile time. The detection of these
227 -- circularities is carried out at the point that we insert a generic
228 -- instance spec or body. If there is a circularity, then the analysis of
229 -- the offending spec or body will eventually result in trying to load the
230 -- same unit again, and we detect this problem as we analyze the package
231 -- instantiation for the second time.
233 -- At least in some cases after we have detected the circularity, we get
234 -- into trouble if we try to keep going. The following flag is set if a
235 -- circularity is detected, and used to abandon compilation after the
236 -- messages have been posted.
238 Circularity_Detected
: Boolean := False;
239 -- This should really be reset on encountering a new main unit, but in
240 -- practice we are not using multiple main units so it is not critical.
242 -------------------------------------------------
243 -- Formal packages and partial parametrization --
244 -------------------------------------------------
246 -- When compiling a generic, a formal package is a local instantiation. If
247 -- declared with a box, its generic formals are visible in the enclosing
248 -- generic. If declared with a partial list of actuals, those actuals that
249 -- are defaulted (covered by an Others clause, or given an explicit box
250 -- initialization) are also visible in the enclosing generic, while those
251 -- that have a corresponding actual are not.
253 -- In our source model of instantiation, the same visibility must be
254 -- present in the spec and body of an instance: the names of the formals
255 -- that are defaulted must be made visible within the instance, and made
256 -- invisible (hidden) after the instantiation is complete, so that they
257 -- are not accessible outside of the instance.
259 -- In a generic, a formal package is treated like a special instantiation.
260 -- Our Ada95 compiler handled formals with and without box in different
261 -- ways. With partial parametrization, we use a single model for both.
262 -- We create a package declaration that consists of the specification of
263 -- the generic package, and a set of declarations that map the actuals
264 -- into local renamings, just as we do for bona fide instantiations. For
265 -- defaulted parameters and formals with a box, we copy directly the
266 -- declarations of the formal into this local package. The result is a
267 -- a package whose visible declarations may include generic formals. This
268 -- package is only used for type checking and visibility analysis, and
269 -- never reaches the back-end, so it can freely violate the placement
270 -- rules for generic formal declarations.
272 -- The list of declarations (renamings and copies of formals) is built
273 -- by Analyze_Associations, just as for regular instantiations.
275 -- At the point of instantiation, conformance checking must be applied only
276 -- to those parameters that were specified in the formal. We perform this
277 -- checking by creating another internal instantiation, this one including
278 -- only the renamings and the formals (the rest of the package spec is not
279 -- relevant to conformance checking). We can then traverse two lists: the
280 -- list of actuals in the instance that corresponds to the formal package,
281 -- and the list of actuals produced for this bogus instantiation. We apply
282 -- the conformance rules to those actuals that are not defaulted (i.e.
283 -- which still appear as generic formals.
285 -- When we compile an instance body we must make the right parameters
286 -- visible again. The predicate Is_Generic_Formal indicates which of the
287 -- formals should have its Is_Hidden flag reset.
289 -----------------------
290 -- Local subprograms --
291 -----------------------
293 procedure Abandon_Instantiation
(N
: Node_Id
);
294 pragma No_Return
(Abandon_Instantiation
);
295 -- Posts an error message "instantiation abandoned" at the indicated node
296 -- and then raises the exception Instantiation_Error to do it.
298 procedure Analyze_Formal_Array_Type
299 (T
: in out Entity_Id
;
301 -- A formal array type is treated like an array type declaration, and
302 -- invokes Array_Type_Declaration (sem_ch3) whose first parameter is
303 -- in-out, because in the case of an anonymous type the entity is
304 -- actually created in the procedure.
306 -- The following procedures treat other kinds of formal parameters
308 procedure Analyze_Formal_Derived_Interface_Type
313 procedure Analyze_Formal_Derived_Type
318 procedure Analyze_Formal_Interface_Type
323 -- The following subprograms create abbreviated declarations for formal
324 -- scalar types. We introduce an anonymous base of the proper class for
325 -- each of them, and define the formals as constrained first subtypes of
326 -- their bases. The bounds are expressions that are non-static in the
329 procedure Analyze_Formal_Decimal_Fixed_Point_Type
330 (T
: Entity_Id
; Def
: Node_Id
);
331 procedure Analyze_Formal_Discrete_Type
(T
: Entity_Id
; Def
: Node_Id
);
332 procedure Analyze_Formal_Floating_Type
(T
: Entity_Id
; Def
: Node_Id
);
333 procedure Analyze_Formal_Signed_Integer_Type
(T
: Entity_Id
; Def
: Node_Id
);
334 procedure Analyze_Formal_Modular_Type
(T
: Entity_Id
; Def
: Node_Id
);
335 procedure Analyze_Formal_Ordinary_Fixed_Point_Type
336 (T
: Entity_Id
; Def
: Node_Id
);
338 procedure Analyze_Formal_Private_Type
342 -- Creates a new private type, which does not require completion
344 procedure Analyze_Generic_Formal_Part
(N
: Node_Id
);
346 procedure Analyze_Generic_Access_Type
(T
: Entity_Id
; Def
: Node_Id
);
347 -- Create a new access type with the given designated type
349 function Analyze_Associations
352 F_Copy
: List_Id
) return List_Id
;
353 -- At instantiation time, build the list of associations between formals
354 -- and actuals. Each association becomes a renaming declaration for the
355 -- formal entity. F_Copy is the analyzed list of formals in the generic
356 -- copy. It is used to apply legality checks to the actuals. I_Node is the
357 -- instantiation node itself.
359 procedure Analyze_Subprogram_Instantiation
363 procedure Build_Instance_Compilation_Unit_Nodes
367 -- This procedure is used in the case where the generic instance of a
368 -- subprogram body or package body is a library unit. In this case, the
369 -- original library unit node for the generic instantiation must be
370 -- replaced by the resulting generic body, and a link made to a new
371 -- compilation unit node for the generic declaration. The argument N is
372 -- the original generic instantiation. Act_Body and Act_Decl are the body
373 -- and declaration of the instance (either package body and declaration
374 -- nodes or subprogram body and declaration nodes depending on the case).
375 -- On return, the node N has been rewritten with the actual body.
377 procedure Check_Access_Definition
(N
: Node_Id
);
378 -- Subsidiary routine to null exclusion processing. Perform an assertion
379 -- check on Ada version and the presence of an access definition in N.
381 procedure Check_Formal_Packages
(P_Id
: Entity_Id
);
382 -- Apply the following to all formal packages in generic associations
384 procedure Check_Formal_Package_Instance
385 (Formal_Pack
: Entity_Id
;
386 Actual_Pack
: Entity_Id
);
387 -- Verify that the actuals of the actual instance match the actuals of
388 -- the template for a formal package that is not declared with a box.
390 procedure Check_Forward_Instantiation
(Decl
: Node_Id
);
391 -- If the generic is a local entity and the corresponding body has not
392 -- been seen yet, flag enclosing packages to indicate that it will be
393 -- elaborated after the generic body. Subprograms declared in the same
394 -- package cannot be inlined by the front-end because front-end inlining
395 -- requires a strict linear order of elaboration.
397 procedure Check_Hidden_Child_Unit
399 Gen_Unit
: Entity_Id
;
400 Act_Decl_Id
: Entity_Id
);
401 -- If the generic unit is an implicit child instance within a parent
402 -- instance, we need to make an explicit test that it is not hidden by
403 -- a child instance of the same name and parent.
405 procedure Check_Generic_Actuals
406 (Instance
: Entity_Id
;
407 Is_Formal_Box
: Boolean);
408 -- Similar to previous one. Check the actuals in the instantiation,
409 -- whose views can change between the point of instantiation and the point
410 -- of instantiation of the body. In addition, mark the generic renamings
411 -- as generic actuals, so that they are not compatible with other actuals.
412 -- Recurse on an actual that is a formal package whose declaration has
415 function Contains_Instance_Of
418 N
: Node_Id
) return Boolean;
419 -- Inner is instantiated within the generic Outer. Check whether Inner
420 -- directly or indirectly contains an instance of Outer or of one of its
421 -- parents, in the case of a subunit. Each generic unit holds a list of
422 -- the entities instantiated within (at any depth). This procedure
423 -- determines whether the set of such lists contains a cycle, i.e. an
424 -- illegal circular instantiation.
426 function Denotes_Formal_Package
428 On_Exit
: Boolean := False;
429 Instance
: Entity_Id
:= Empty
) return Boolean;
430 -- Returns True if E is a formal package of an enclosing generic, or
431 -- the actual for such a formal in an enclosing instantiation. If such
432 -- a package is used as a formal in an nested generic, or as an actual
433 -- in a nested instantiation, the visibility of ITS formals should not
434 -- be modified. When called from within Restore_Private_Views, the flag
435 -- On_Exit is true, to indicate that the search for a possible enclosing
436 -- instance should ignore the current one. In that case Instance denotes
437 -- the declaration for which this is an actual. This declaration may be
438 -- an instantiation in the source, or the internal instantiation that
439 -- corresponds to the actual for a formal package.
441 function Find_Actual_Type
443 Gen_Type
: Entity_Id
) return Entity_Id
;
444 -- When validating the actual types of a child instance, check whether
445 -- the formal is a formal type of the parent unit, and retrieve the current
446 -- actual for it. Typ is the entity in the analyzed formal type declaration
447 -- (component or index type of an array type, or designated type of an
448 -- access formal) and Gen_Type is the enclosing analyzed formal array
449 -- or access type. The desired actual may be a formal of a parent, or may
450 -- be declared in a formal package of a parent. In both cases it is a
451 -- generic actual type because it appears within a visible instance.
452 -- Finally, it may be declared in a parent unit without being a formal
453 -- of that unit, in which case it must be retrieved by visibility.
454 -- Ambiguities may still arise if two homonyms are declared in two formal
455 -- packages, and the prefix of the formal type may be needed to resolve
456 -- the ambiguity in the instance ???
458 function In_Same_Declarative_Part
460 Inst
: Node_Id
) return Boolean;
461 -- True if the instantiation Inst and the given freeze_node F_Node appear
462 -- within the same declarative part, ignoring subunits, but with no inter-
463 -- vening subprograms or concurrent units. If true, the freeze node
464 -- of the instance can be placed after the freeze node of the parent,
465 -- which it itself an instance.
467 function In_Main_Context
(E
: Entity_Id
) return Boolean;
468 -- Check whether an instantiation is in the context of the main unit.
469 -- Used to determine whether its body should be elaborated to allow
470 -- front-end inlining.
472 function Is_Generic_Formal
(E
: Entity_Id
) return Boolean;
473 -- Utility to determine whether a given entity is declared by means of
474 -- of a formal parameter declaration. Used to set properly the visibility
475 -- of generic formals of a generic package declared with a box or with
476 -- partial parametrization.
478 procedure Mark_Context
(Inst_Decl
: Node_Id
; Gen_Decl
: Node_Id
);
479 -- If the generic unit comes from a different unit, indicate that the
480 -- unit that contains the instance depends on the body that contains
481 -- the generic body. Used to determine a more precise dependency graph
482 -- for use by CodePeer.
484 procedure Set_Instance_Env
485 (Gen_Unit
: Entity_Id
;
486 Act_Unit
: Entity_Id
);
487 -- Save current instance on saved environment, to be used to determine
488 -- the global status of entities in nested instances. Part of Save_Env.
489 -- called after verifying that the generic unit is legal for the instance,
490 -- The procedure also examines whether the generic unit is a predefined
491 -- unit, in order to set configuration switches accordingly. As a result
492 -- the procedure must be called after analyzing and freezing the actuals.
494 procedure Set_Instance_Of
(A
: Entity_Id
; B
: Entity_Id
);
495 -- Associate analyzed generic parameter with corresponding
496 -- instance. Used for semantic checks at instantiation time.
498 function Has_Been_Exchanged
(E
: Entity_Id
) return Boolean;
499 -- Traverse the Exchanged_Views list to see if a type was private
500 -- and has already been flipped during this phase of instantiation.
502 procedure Hide_Current_Scope
;
503 -- When instantiating a generic child unit, the parent context must be
504 -- present, but the instance and all entities that may be generated
505 -- must be inserted in the current scope. We leave the current scope
506 -- on the stack, but make its entities invisible to avoid visibility
507 -- problems. This is reversed at the end of the instantiation. This is
508 -- not done for the instantiation of the bodies, which only require the
509 -- instances of the generic parents to be in scope.
511 procedure Install_Body
516 -- If the instantiation happens textually before the body of the generic,
517 -- the instantiation of the body must be analyzed after the generic body,
518 -- and not at the point of instantiation. Such early instantiations can
519 -- happen if the generic and the instance appear in a package declaration
520 -- because the generic body can only appear in the corresponding package
521 -- body. Early instantiations can also appear if generic, instance and
522 -- body are all in the declarative part of a subprogram or entry. Entities
523 -- of packages that are early instantiations are delayed, and their freeze
524 -- node appears after the generic body.
526 procedure Insert_After_Last_Decl
(N
: Node_Id
; F_Node
: Node_Id
);
527 -- Insert freeze node at the end of the declarative part that includes the
528 -- instance node N. If N is in the visible part of an enclosing package
529 -- declaration, the freeze node has to be inserted at the end of the
530 -- private declarations, if any.
532 procedure Freeze_Subprogram_Body
533 (Inst_Node
: Node_Id
;
535 Pack_Id
: Entity_Id
);
536 -- The generic body may appear textually after the instance, including
537 -- in the proper body of a stub, or within a different package instance.
538 -- Given that the instance can only be elaborated after the generic, we
539 -- place freeze_nodes for the instance and/or for packages that may enclose
540 -- the instance and the generic, so that the back-end can establish the
541 -- proper order of elaboration.
544 -- Establish environment for subsequent instantiation. Separated from
545 -- Save_Env because data-structures for visibility handling must be
546 -- initialized before call to Check_Generic_Child_Unit.
548 procedure Install_Formal_Packages
(Par
: Entity_Id
);
549 -- Install the visible part of any formal of the parent that is a formal
550 -- package. Note that for the case of a formal package with a box, this
551 -- includes the formal part of the formal package (12.7(10/2)).
553 procedure Install_Parent
(P
: Entity_Id
; In_Body
: Boolean := False);
554 -- When compiling an instance of a child unit the parent (which is
555 -- itself an instance) is an enclosing scope that must be made
556 -- immediately visible. This procedure is also used to install the non-
557 -- generic parent of a generic child unit when compiling its body, so
558 -- that full views of types in the parent are made visible.
560 procedure Remove_Parent
(In_Body
: Boolean := False);
561 -- Reverse effect after instantiation of child is complete
563 procedure Inline_Instance_Body
565 Gen_Unit
: Entity_Id
;
567 -- If front-end inlining is requested, instantiate the package body,
568 -- and preserve the visibility of its compilation unit, to insure
569 -- that successive instantiations succeed.
571 -- The functions Instantiate_XXX perform various legality checks and build
572 -- the declarations for instantiated generic parameters. In all of these
573 -- Formal is the entity in the generic unit, Actual is the entity of
574 -- expression in the generic associations, and Analyzed_Formal is the
575 -- formal in the generic copy, which contains the semantic information to
576 -- be used to validate the actual.
578 function Instantiate_Object
581 Analyzed_Formal
: Node_Id
) return List_Id
;
583 function Instantiate_Type
586 Analyzed_Formal
: Node_Id
;
587 Actual_Decls
: List_Id
) return List_Id
;
589 function Instantiate_Formal_Subprogram
592 Analyzed_Formal
: Node_Id
) return Node_Id
;
594 function Instantiate_Formal_Package
597 Analyzed_Formal
: Node_Id
) return List_Id
;
598 -- If the formal package is declared with a box, special visibility rules
599 -- apply to its formals: they are in the visible part of the package. This
600 -- is true in the declarative region of the formal package, that is to say
601 -- in the enclosing generic or instantiation. For an instantiation, the
602 -- parameters of the formal package are made visible in an explicit step.
603 -- Furthermore, if the actual has a visible USE clause, these formals must
604 -- be made potentially use-visible as well. On exit from the enclosing
605 -- instantiation, the reverse must be done.
607 -- For a formal package declared without a box, there are conformance rules
608 -- that apply to the actuals in the generic declaration and the actuals of
609 -- the actual package in the enclosing instantiation. The simplest way to
610 -- apply these rules is to repeat the instantiation of the formal package
611 -- in the context of the enclosing instance, and compare the generic
612 -- associations of this instantiation with those of the actual package.
613 -- This internal instantiation only needs to contain the renamings of the
614 -- formals: the visible and private declarations themselves need not be
617 -- In Ada 2005, the formal package may be only partially parametrized. In
618 -- that case the visibility step must make visible those actuals whose
619 -- corresponding formals were given with a box. A final complication
620 -- involves inherited operations from formal derived types, which must be
621 -- visible if the type is.
623 function Is_In_Main_Unit
(N
: Node_Id
) return Boolean;
624 -- Test if given node is in the main unit
626 procedure Load_Parent_Of_Generic
629 Body_Optional
: Boolean := False);
630 -- If the generic appears in a separate non-generic library unit, load the
631 -- corresponding body to retrieve the body of the generic. N is the node
632 -- for the generic instantiation, Spec is the generic package declaration.
634 -- Body_Optional is a flag that indicates that the body is being loaded to
635 -- ensure that temporaries are generated consistently when there are other
636 -- instances in the current declarative part that precede the one being
637 -- loaded. In that case a missing body is acceptable.
639 procedure Inherit_Context
(Gen_Decl
: Node_Id
; Inst
: Node_Id
);
640 -- Add the context clause of the unit containing a generic unit to a
641 -- compilation unit that is, or contains, an instantiation.
643 function Get_Associated_Node
(N
: Node_Id
) return Node_Id
;
644 -- In order to propagate semantic information back from the analyzed copy
645 -- to the original generic, we maintain links between selected nodes in the
646 -- generic and their corresponding copies. At the end of generic analysis,
647 -- the routine Save_Global_References traverses the generic tree, examines
648 -- the semantic information, and preserves the links to those nodes that
649 -- contain global information. At instantiation, the information from the
650 -- associated node is placed on the new copy, so that name resolution is
653 -- Three kinds of source nodes have associated nodes:
655 -- a) those that can reference (denote) entities, that is identifiers,
656 -- character literals, expanded_names, operator symbols, operators,
657 -- and attribute reference nodes. These nodes have an Entity field
658 -- and are the set of nodes that are in N_Has_Entity.
660 -- b) aggregates (N_Aggregate and N_Extension_Aggregate)
662 -- c) selected components (N_Selected_Component)
664 -- For the first class, the associated node preserves the entity if it is
665 -- global. If the generic contains nested instantiations, the associated
666 -- node itself has been recopied, and a chain of them must be followed.
668 -- For aggregates, the associated node allows retrieval of the type, which
669 -- may otherwise not appear in the generic. The view of this type may be
670 -- different between generic and instantiation, and the full view can be
671 -- installed before the instantiation is analyzed. For aggregates of type
672 -- extensions, the same view exchange may have to be performed for some of
673 -- the ancestor types, if their view is private at the point of
676 -- Nodes that are selected components in the parse tree may be rewritten
677 -- as expanded names after resolution, and must be treated as potential
678 -- entity holders, which is why they also have an Associated_Node.
680 -- Nodes that do not come from source, such as freeze nodes, do not appear
681 -- in the generic tree, and need not have an associated node.
683 -- The associated node is stored in the Associated_Node field. Note that
684 -- this field overlaps Entity, which is fine, because the whole point is
685 -- that we don't need or want the normal Entity field in this situation.
687 procedure Map_Formal_Package_Entities
(Form
: Entity_Id
; Act
: Entity_Id
);
688 -- Within the generic part, entities in the formal package are
689 -- visible. To validate subsequent type declarations, indicate
690 -- the correspondence between the entities in the analyzed formal,
691 -- and the entities in the actual package. There are three packages
692 -- involved in the instantiation of a formal package: the parent
693 -- generic P1 which appears in the generic declaration, the fake
694 -- instantiation P2 which appears in the analyzed generic, and whose
695 -- visible entities may be used in subsequent formals, and the actual
696 -- P3 in the instance. To validate subsequent formals, me indicate
697 -- that the entities in P2 are mapped into those of P3. The mapping of
698 -- entities has to be done recursively for nested packages.
700 procedure Move_Freeze_Nodes
704 -- Freeze nodes can be generated in the analysis of a generic unit, but
705 -- will not be seen by the back-end. It is necessary to move those nodes
706 -- to the enclosing scope if they freeze an outer entity. We place them
707 -- at the end of the enclosing generic package, which is semantically
710 procedure Preanalyze_Actuals
(N
: Node_Id
);
711 -- Analyze actuals to perform name resolution. Full resolution is done
712 -- later, when the expected types are known, but names have to be captured
713 -- before installing parents of generics, that are not visible for the
714 -- actuals themselves.
716 procedure Valid_Default_Attribute
(Nam
: Entity_Id
; Def
: Node_Id
);
717 -- Verify that an attribute that appears as the default for a formal
718 -- subprogram is a function or procedure with the correct profile.
720 -------------------------------------------
721 -- Data Structures for Generic Renamings --
722 -------------------------------------------
724 -- The map Generic_Renamings associates generic entities with their
725 -- corresponding actuals. Currently used to validate type instances. It
726 -- will eventually be used for all generic parameters to eliminate the
727 -- need for overload resolution in the instance.
729 type Assoc_Ptr
is new Int
;
731 Assoc_Null
: constant Assoc_Ptr
:= -1;
736 Next_In_HTable
: Assoc_Ptr
;
739 package Generic_Renamings
is new Table
.Table
740 (Table_Component_Type
=> Assoc
,
741 Table_Index_Type
=> Assoc_Ptr
,
742 Table_Low_Bound
=> 0,
744 Table_Increment
=> 100,
745 Table_Name
=> "Generic_Renamings");
747 -- Variable to hold enclosing instantiation. When the environment is
748 -- saved for a subprogram inlining, the corresponding Act_Id is empty.
750 Current_Instantiated_Parent
: Assoc
:= (Empty
, Empty
, Assoc_Null
);
752 -- Hash table for associations
754 HTable_Size
: constant := 37;
755 type HTable_Range
is range 0 .. HTable_Size
- 1;
757 procedure Set_Next_Assoc
(E
: Assoc_Ptr
; Next
: Assoc_Ptr
);
758 function Next_Assoc
(E
: Assoc_Ptr
) return Assoc_Ptr
;
759 function Get_Gen_Id
(E
: Assoc_Ptr
) return Entity_Id
;
760 function Hash
(F
: Entity_Id
) return HTable_Range
;
762 package Generic_Renamings_HTable
is new GNAT
.HTable
.Static_HTable
(
763 Header_Num
=> HTable_Range
,
765 Elmt_Ptr
=> Assoc_Ptr
,
766 Null_Ptr
=> Assoc_Null
,
767 Set_Next
=> Set_Next_Assoc
,
770 Get_Key
=> Get_Gen_Id
,
774 Exchanged_Views
: Elist_Id
;
775 -- This list holds the private views that have been exchanged during
776 -- instantiation to restore the visibility of the generic declaration.
777 -- (see comments above). After instantiation, the current visibility is
778 -- reestablished by means of a traversal of this list.
780 Hidden_Entities
: Elist_Id
;
781 -- This list holds the entities of the current scope that are removed
782 -- from immediate visibility when instantiating a child unit. Their
783 -- visibility is restored in Remove_Parent.
785 -- Because instantiations can be recursive, the following must be saved
786 -- on entry and restored on exit from an instantiation (spec or body).
787 -- This is done by the two procedures Save_Env and Restore_Env. For
788 -- package and subprogram instantiations (but not for the body instances)
789 -- the action of Save_Env is done in two steps: Init_Env is called before
790 -- Check_Generic_Child_Unit, because setting the parent instances requires
791 -- that the visibility data structures be properly initialized. Once the
792 -- generic is unit is validated, Set_Instance_Env completes Save_Env.
794 Parent_Unit_Visible
: Boolean := False;
795 -- Parent_Unit_Visible is used when the generic is a child unit, and
796 -- indicates whether the ultimate parent of the generic is visible in the
797 -- instantiation environment. It is used to reset the visibility of the
798 -- parent at the end of the instantiation (see Remove_Parent).
800 Instance_Parent_Unit
: Entity_Id
:= Empty
;
801 -- This records the ultimate parent unit of an instance of a generic
802 -- child unit and is used in conjunction with Parent_Unit_Visible to
803 -- indicate the unit to which the Parent_Unit_Visible flag corresponds.
805 type Instance_Env
is record
806 Instantiated_Parent
: Assoc
;
807 Exchanged_Views
: Elist_Id
;
808 Hidden_Entities
: Elist_Id
;
809 Current_Sem_Unit
: Unit_Number_Type
;
810 Parent_Unit_Visible
: Boolean := False;
811 Instance_Parent_Unit
: Entity_Id
:= Empty
;
812 Switches
: Config_Switches_Type
;
815 package Instance_Envs
is new Table
.Table
(
816 Table_Component_Type
=> Instance_Env
,
817 Table_Index_Type
=> Int
,
818 Table_Low_Bound
=> 0,
820 Table_Increment
=> 100,
821 Table_Name
=> "Instance_Envs");
823 procedure Restore_Private_Views
824 (Pack_Id
: Entity_Id
;
825 Is_Package
: Boolean := True);
826 -- Restore the private views of external types, and unmark the generic
827 -- renamings of actuals, so that they become compatible subtypes again.
828 -- For subprograms, Pack_Id is the package constructed to hold the
831 procedure Switch_View
(T
: Entity_Id
);
832 -- Switch the partial and full views of a type and its private
833 -- dependents (i.e. its subtypes and derived types).
835 ------------------------------------
836 -- Structures for Error Reporting --
837 ------------------------------------
839 Instantiation_Node
: Node_Id
;
840 -- Used by subprograms that validate instantiation of formal parameters
841 -- where there might be no actual on which to place the error message.
842 -- Also used to locate the instantiation node for generic subunits.
844 Instantiation_Error
: exception;
845 -- When there is a semantic error in the generic parameter matching,
846 -- there is no point in continuing the instantiation, because the
847 -- number of cascaded errors is unpredictable. This exception aborts
848 -- the instantiation process altogether.
850 S_Adjustment
: Sloc_Adjustment
;
851 -- Offset created for each node in an instantiation, in order to keep
852 -- track of the source position of the instantiation in each of its nodes.
853 -- A subsequent semantic error or warning on a construct of the instance
854 -- points to both places: the original generic node, and the point of
855 -- instantiation. See Sinput and Sinput.L for additional details.
857 ------------------------------------------------------------
858 -- Data structure for keeping track when inside a Generic --
859 ------------------------------------------------------------
861 -- The following table is used to save values of the Inside_A_Generic
862 -- flag (see spec of Sem) when they are saved by Start_Generic.
864 package Generic_Flags
is new Table
.Table
(
865 Table_Component_Type
=> Boolean,
866 Table_Index_Type
=> Int
,
867 Table_Low_Bound
=> 0,
869 Table_Increment
=> 200,
870 Table_Name
=> "Generic_Flags");
872 ---------------------------
873 -- Abandon_Instantiation --
874 ---------------------------
876 procedure Abandon_Instantiation
(N
: Node_Id
) is
878 Error_Msg_N
("\instantiation abandoned!", N
);
879 raise Instantiation_Error
;
880 end Abandon_Instantiation
;
882 --------------------------
883 -- Analyze_Associations --
884 --------------------------
886 function Analyze_Associations
889 F_Copy
: List_Id
) return List_Id
892 Actual_Types
: constant Elist_Id
:= New_Elmt_List
;
893 Assoc
: constant List_Id
:= New_List
;
894 Default_Actuals
: constant Elist_Id
:= New_Elmt_List
;
895 Gen_Unit
: constant Entity_Id
:=
896 Defining_Entity
(Parent
(F_Copy
));
901 Next_Formal
: Node_Id
;
902 Temp_Formal
: Node_Id
;
903 Analyzed_Formal
: Node_Id
;
906 First_Named
: Node_Id
:= Empty
;
908 Default_Formals
: constant List_Id
:= New_List
;
909 -- If an Others_Choice is present, some of the formals may be defaulted.
910 -- To simplify the treatment of visibility in an instance, we introduce
911 -- individual defaults for each such formal. These defaults are
912 -- appended to the list of associations and replace the Others_Choice.
914 Found_Assoc
: Node_Id
;
915 -- Association for the current formal being match. Empty if there are
916 -- no remaining actuals, or if there is no named association with the
917 -- name of the formal.
919 Is_Named_Assoc
: Boolean;
920 Num_Matched
: Int
:= 0;
921 Num_Actuals
: Int
:= 0;
923 Others_Present
: Boolean := False;
924 -- In Ada 2005, indicates partial parametrization of a formal
925 -- package. As usual an other association must be last in the list.
927 function Matching_Actual
929 A_F
: Entity_Id
) return Node_Id
;
930 -- Find actual that corresponds to a given a formal parameter. If the
931 -- actuals are positional, return the next one, if any. If the actuals
932 -- are named, scan the parameter associations to find the right one.
933 -- A_F is the corresponding entity in the analyzed generic,which is
934 -- placed on the selector name for ASIS use.
936 -- In Ada 2005, a named association may be given with a box, in which
937 -- case Matching_Actual sets Found_Assoc to the generic association,
938 -- but return Empty for the actual itself. In this case the code below
939 -- creates a corresponding declaration for the formal.
941 function Partial_Parametrization
return Boolean;
942 -- Ada 2005: if no match is found for a given formal, check if the
943 -- association for it includes a box, or whether the associations
944 -- include an Others clause.
946 procedure Process_Default
(F
: Entity_Id
);
947 -- Add a copy of the declaration of generic formal F to the list of
948 -- associations, and add an explicit box association for F if there
949 -- is none yet, and the default comes from an Others_Choice.
951 procedure Set_Analyzed_Formal
;
952 -- Find the node in the generic copy that corresponds to a given formal.
953 -- The semantic information on this node is used to perform legality
954 -- checks on the actuals. Because semantic analysis can introduce some
955 -- anonymous entities or modify the declaration node itself, the
956 -- correspondence between the two lists is not one-one. In addition to
957 -- anonymous types, the presence a formal equality will introduce an
958 -- implicit declaration for the corresponding inequality.
960 ---------------------
961 -- Matching_Actual --
962 ---------------------
964 function Matching_Actual
966 A_F
: Entity_Id
) return Node_Id
972 Is_Named_Assoc
:= False;
974 -- End of list of purely positional parameters
976 if No
(Actual
) or else Nkind
(Actual
) = N_Others_Choice
then
977 Found_Assoc
:= Empty
;
980 -- Case of positional parameter corresponding to current formal
982 elsif No
(Selector_Name
(Actual
)) then
983 Found_Assoc
:= Actual
;
984 Act
:= Explicit_Generic_Actual_Parameter
(Actual
);
985 Num_Matched
:= Num_Matched
+ 1;
988 -- Otherwise scan list of named actuals to find the one with the
989 -- desired name. All remaining actuals have explicit names.
992 Is_Named_Assoc
:= True;
993 Found_Assoc
:= Empty
;
997 while Present
(Actual
) loop
998 if Chars
(Selector_Name
(Actual
)) = Chars
(F
) then
999 Set_Entity
(Selector_Name
(Actual
), A_F
);
1000 Set_Etype
(Selector_Name
(Actual
), Etype
(A_F
));
1001 Generate_Reference
(A_F
, Selector_Name
(Actual
));
1002 Found_Assoc
:= Actual
;
1003 Act
:= Explicit_Generic_Actual_Parameter
(Actual
);
1004 Num_Matched
:= Num_Matched
+ 1;
1012 -- Reset for subsequent searches. In most cases the named
1013 -- associations are in order. If they are not, we reorder them
1014 -- to avoid scanning twice the same actual. This is not just a
1015 -- question of efficiency: there may be multiple defaults with
1016 -- boxes that have the same name. In a nested instantiation we
1017 -- insert actuals for those defaults, and cannot rely on their
1018 -- names to disambiguate them.
1020 if Actual
= First_Named
then
1023 elsif Present
(Actual
) then
1024 Insert_Before
(First_Named
, Remove_Next
(Prev
));
1027 Actual
:= First_Named
;
1030 if Is_Entity_Name
(Act
) and then Present
(Entity
(Act
)) then
1031 Set_Used_As_Generic_Actual
(Entity
(Act
));
1035 end Matching_Actual
;
1037 -----------------------------
1038 -- Partial_Parametrization --
1039 -----------------------------
1041 function Partial_Parametrization
return Boolean is
1043 return Others_Present
1044 or else (Present
(Found_Assoc
) and then Box_Present
(Found_Assoc
));
1045 end Partial_Parametrization
;
1047 ---------------------
1048 -- Process_Default --
1049 ---------------------
1051 procedure Process_Default
(F
: Entity_Id
) is
1052 Loc
: constant Source_Ptr
:= Sloc
(I_Node
);
1053 F_Id
: constant Entity_Id
:= Defining_Entity
(F
);
1059 -- Append copy of formal declaration to associations, and create new
1060 -- defining identifier for it.
1062 Decl
:= New_Copy_Tree
(F
);
1063 Id
:= Make_Defining_Identifier
(Sloc
(F_Id
), Chars
=> Chars
(F_Id
));
1065 if Nkind
(F
) in N_Formal_Subprogram_Declaration
then
1066 Set_Defining_Unit_Name
(Specification
(Decl
), Id
);
1069 Set_Defining_Identifier
(Decl
, Id
);
1072 Append
(Decl
, Assoc
);
1074 if No
(Found_Assoc
) then
1076 Make_Generic_Association
(Loc
,
1077 Selector_Name
=> New_Occurrence_Of
(Id
, Loc
),
1078 Explicit_Generic_Actual_Parameter
=> Empty
);
1079 Set_Box_Present
(Default
);
1080 Append
(Default
, Default_Formals
);
1082 end Process_Default
;
1084 -------------------------
1085 -- Set_Analyzed_Formal --
1086 -------------------------
1088 procedure Set_Analyzed_Formal
is
1092 while Present
(Analyzed_Formal
) loop
1093 Kind
:= Nkind
(Analyzed_Formal
);
1095 case Nkind
(Formal
) is
1097 when N_Formal_Subprogram_Declaration
=>
1098 exit when Kind
in N_Formal_Subprogram_Declaration
1101 (Defining_Unit_Name
(Specification
(Formal
))) =
1103 (Defining_Unit_Name
(Specification
(Analyzed_Formal
)));
1105 when N_Formal_Package_Declaration
=>
1106 exit when Nkind_In
(Kind
, N_Formal_Package_Declaration
,
1107 N_Generic_Package_Declaration
,
1108 N_Package_Declaration
);
1110 when N_Use_Package_Clause | N_Use_Type_Clause
=> exit;
1114 -- Skip freeze nodes, and nodes inserted to replace
1115 -- unrecognized pragmas.
1118 Kind
not in N_Formal_Subprogram_Declaration
1119 and then not Nkind_In
(Kind
, N_Subprogram_Declaration
,
1123 and then Chars
(Defining_Identifier
(Formal
)) =
1124 Chars
(Defining_Identifier
(Analyzed_Formal
));
1127 Next
(Analyzed_Formal
);
1129 end Set_Analyzed_Formal
;
1131 -- Start of processing for Analyze_Associations
1134 Actuals
:= Generic_Associations
(I_Node
);
1136 if Present
(Actuals
) then
1138 -- Check for an Others choice, indicating a partial parametrization
1139 -- for a formal package.
1141 Actual
:= First
(Actuals
);
1142 while Present
(Actual
) loop
1143 if Nkind
(Actual
) = N_Others_Choice
then
1144 Others_Present
:= True;
1146 if Present
(Next
(Actual
)) then
1147 Error_Msg_N
("others must be last association", Actual
);
1150 -- This subprogram is used both for formal packages and for
1151 -- instantiations. For the latter, associations must all be
1154 if Nkind
(I_Node
) /= N_Formal_Package_Declaration
1155 and then Comes_From_Source
(I_Node
)
1158 ("others association not allowed in an instance",
1162 -- In any case, nothing to do after the others association
1166 elsif Box_Present
(Actual
)
1167 and then Comes_From_Source
(I_Node
)
1168 and then Nkind
(I_Node
) /= N_Formal_Package_Declaration
1171 ("box association not allowed in an instance", Actual
);
1177 -- If named associations are present, save first named association
1178 -- (it may of course be Empty) to facilitate subsequent name search.
1180 First_Named
:= First
(Actuals
);
1181 while Present
(First_Named
)
1182 and then Nkind
(First_Named
) /= N_Others_Choice
1183 and then No
(Selector_Name
(First_Named
))
1185 Num_Actuals
:= Num_Actuals
+ 1;
1190 Named
:= First_Named
;
1191 while Present
(Named
) loop
1192 if Nkind
(Named
) /= N_Others_Choice
1193 and then No
(Selector_Name
(Named
))
1195 Error_Msg_N
("invalid positional actual after named one", Named
);
1196 Abandon_Instantiation
(Named
);
1199 -- A named association may lack an actual parameter, if it was
1200 -- introduced for a default subprogram that turns out to be local
1201 -- to the outer instantiation.
1203 if Nkind
(Named
) /= N_Others_Choice
1204 and then Present
(Explicit_Generic_Actual_Parameter
(Named
))
1206 Num_Actuals
:= Num_Actuals
+ 1;
1212 if Present
(Formals
) then
1213 Formal
:= First_Non_Pragma
(Formals
);
1214 Analyzed_Formal
:= First_Non_Pragma
(F_Copy
);
1216 if Present
(Actuals
) then
1217 Actual
:= First
(Actuals
);
1219 -- All formals should have default values
1225 while Present
(Formal
) loop
1226 Set_Analyzed_Formal
;
1227 Next_Formal
:= Next_Non_Pragma
(Formal
);
1229 case Nkind
(Formal
) is
1230 when N_Formal_Object_Declaration
=>
1233 Defining_Identifier
(Formal
),
1234 Defining_Identifier
(Analyzed_Formal
));
1236 if No
(Match
) and then Partial_Parametrization
then
1237 Process_Default
(Formal
);
1240 (Instantiate_Object
(Formal
, Match
, Analyzed_Formal
),
1244 when N_Formal_Type_Declaration
=>
1247 Defining_Identifier
(Formal
),
1248 Defining_Identifier
(Analyzed_Formal
));
1251 if Partial_Parametrization
then
1252 Process_Default
(Formal
);
1255 Error_Msg_Sloc
:= Sloc
(Gen_Unit
);
1259 Defining_Identifier
(Formal
));
1260 Error_Msg_NE
("\in instantiation of & declared#",
1261 Instantiation_Node
, Gen_Unit
);
1262 Abandon_Instantiation
(Instantiation_Node
);
1269 (Formal
, Match
, Analyzed_Formal
, Assoc
),
1272 -- An instantiation is a freeze point for the actuals,
1273 -- unless this is a rewritten formal package.
1275 if Nkind
(I_Node
) /= N_Formal_Package_Declaration
then
1276 Append_Elmt
(Entity
(Match
), Actual_Types
);
1280 -- A remote access-to-class-wide type must not be an
1281 -- actual parameter for a generic formal of an access
1282 -- type (E.2.2 (17)).
1284 if Nkind
(Analyzed_Formal
) = N_Formal_Type_Declaration
1286 Nkind
(Formal_Type_Definition
(Analyzed_Formal
)) =
1287 N_Access_To_Object_Definition
1289 Validate_Remote_Access_To_Class_Wide_Type
(Match
);
1292 when N_Formal_Subprogram_Declaration
=>
1295 Defining_Unit_Name
(Specification
(Formal
)),
1296 Defining_Unit_Name
(Specification
(Analyzed_Formal
)));
1298 -- If the formal subprogram has the same name as another
1299 -- formal subprogram of the generic, then a named
1300 -- association is illegal (12.3(9)). Exclude named
1301 -- associations that are generated for a nested instance.
1304 and then Is_Named_Assoc
1305 and then Comes_From_Source
(Found_Assoc
)
1307 Temp_Formal
:= First
(Formals
);
1308 while Present
(Temp_Formal
) loop
1309 if Nkind
(Temp_Formal
) in
1310 N_Formal_Subprogram_Declaration
1311 and then Temp_Formal
/= Formal
1313 Chars
(Selector_Name
(Found_Assoc
)) =
1314 Chars
(Defining_Unit_Name
1315 (Specification
(Temp_Formal
)))
1318 ("name not allowed for overloaded formal",
1320 Abandon_Instantiation
(Instantiation_Node
);
1327 -- If there is no corresponding actual, this may be case of
1328 -- partial parametrization, or else the formal has a default
1332 and then Partial_Parametrization
1334 Process_Default
(Formal
);
1337 Instantiate_Formal_Subprogram
1338 (Formal
, Match
, Analyzed_Formal
));
1341 -- If this is a nested generic, preserve default for later
1345 and then Box_Present
(Formal
)
1348 (Defining_Unit_Name
(Specification
(Last
(Assoc
))),
1352 when N_Formal_Package_Declaration
=>
1355 Defining_Identifier
(Formal
),
1356 Defining_Identifier
(Original_Node
(Analyzed_Formal
)));
1359 if Partial_Parametrization
then
1360 Process_Default
(Formal
);
1363 Error_Msg_Sloc
:= Sloc
(Gen_Unit
);
1366 Instantiation_Node
, Defining_Identifier
(Formal
));
1367 Error_Msg_NE
("\in instantiation of & declared#",
1368 Instantiation_Node
, Gen_Unit
);
1370 Abandon_Instantiation
(Instantiation_Node
);
1376 (Instantiate_Formal_Package
1377 (Formal
, Match
, Analyzed_Formal
),
1381 -- For use type and use package appearing in the generic part,
1382 -- we have already copied them, so we can just move them where
1383 -- they belong (we mustn't recopy them since this would mess up
1384 -- the Sloc values).
1386 when N_Use_Package_Clause |
1387 N_Use_Type_Clause
=>
1388 if Nkind
(Original_Node
(I_Node
)) =
1389 N_Formal_Package_Declaration
1391 Append
(New_Copy_Tree
(Formal
), Assoc
);
1394 Append
(Formal
, Assoc
);
1398 raise Program_Error
;
1402 Formal
:= Next_Formal
;
1403 Next_Non_Pragma
(Analyzed_Formal
);
1406 if Num_Actuals
> Num_Matched
then
1407 Error_Msg_Sloc
:= Sloc
(Gen_Unit
);
1409 if Present
(Selector_Name
(Actual
)) then
1411 ("unmatched actual&",
1412 Actual
, Selector_Name
(Actual
));
1413 Error_Msg_NE
("\in instantiation of& declared#",
1417 ("unmatched actual in instantiation of& declared#",
1422 elsif Present
(Actuals
) then
1424 ("too many actuals in generic instantiation", Instantiation_Node
);
1428 Elmt
: Elmt_Id
:= First_Elmt
(Actual_Types
);
1430 while Present
(Elmt
) loop
1431 Freeze_Before
(I_Node
, Node
(Elmt
));
1436 -- If there are default subprograms, normalize the tree by adding
1437 -- explicit associations for them. This is required if the instance
1438 -- appears within a generic.
1446 Elmt
:= First_Elmt
(Default_Actuals
);
1447 while Present
(Elmt
) loop
1448 if No
(Actuals
) then
1449 Actuals
:= New_List
;
1450 Set_Generic_Associations
(I_Node
, Actuals
);
1453 Subp
:= Node
(Elmt
);
1455 Make_Generic_Association
(Sloc
(Subp
),
1456 Selector_Name
=> New_Occurrence_Of
(Subp
, Sloc
(Subp
)),
1457 Explicit_Generic_Actual_Parameter
=>
1458 New_Occurrence_Of
(Subp
, Sloc
(Subp
)));
1459 Mark_Rewrite_Insertion
(New_D
);
1460 Append_To
(Actuals
, New_D
);
1465 -- If this is a formal package, normalize the parameter list by adding
1466 -- explicit box associations for the formals that are covered by an
1469 if not Is_Empty_List
(Default_Formals
) then
1470 Append_List
(Default_Formals
, Formals
);
1474 end Analyze_Associations
;
1476 -------------------------------
1477 -- Analyze_Formal_Array_Type --
1478 -------------------------------
1480 procedure Analyze_Formal_Array_Type
1481 (T
: in out Entity_Id
;
1487 -- Treated like a non-generic array declaration, with additional
1492 if Nkind
(Def
) = N_Constrained_Array_Definition
then
1493 DSS
:= First
(Discrete_Subtype_Definitions
(Def
));
1494 while Present
(DSS
) loop
1495 if Nkind_In
(DSS
, N_Subtype_Indication
,
1497 N_Attribute_Reference
)
1499 Error_Msg_N
("only a subtype mark is allowed in a formal", DSS
);
1506 Array_Type_Declaration
(T
, Def
);
1507 Set_Is_Generic_Type
(Base_Type
(T
));
1509 if Ekind
(Component_Type
(T
)) = E_Incomplete_Type
1510 and then No
(Full_View
(Component_Type
(T
)))
1512 Error_Msg_N
("premature usage of incomplete type", Def
);
1514 -- Check that range constraint is not allowed on the component type
1515 -- of a generic formal array type (AARM 12.5.3(3))
1517 elsif Is_Internal
(Component_Type
(T
))
1518 and then Present
(Subtype_Indication
(Component_Definition
(Def
)))
1519 and then Nkind
(Original_Node
1520 (Subtype_Indication
(Component_Definition
(Def
)))) =
1521 N_Subtype_Indication
1524 ("in a formal, a subtype indication can only be "
1525 & "a subtype mark (RM 12.5.3(3))",
1526 Subtype_Indication
(Component_Definition
(Def
)));
1529 end Analyze_Formal_Array_Type
;
1531 ---------------------------------------------
1532 -- Analyze_Formal_Decimal_Fixed_Point_Type --
1533 ---------------------------------------------
1535 -- As for other generic types, we create a valid type representation with
1536 -- legal but arbitrary attributes, whose values are never considered
1537 -- static. For all scalar types we introduce an anonymous base type, with
1538 -- the same attributes. We choose the corresponding integer type to be
1539 -- Standard_Integer.
1541 procedure Analyze_Formal_Decimal_Fixed_Point_Type
1545 Loc
: constant Source_Ptr
:= Sloc
(Def
);
1546 Base
: constant Entity_Id
:=
1548 (E_Decimal_Fixed_Point_Type
,
1549 Current_Scope
, Sloc
(Def
), 'G');
1550 Int_Base
: constant Entity_Id
:= Standard_Integer
;
1551 Delta_Val
: constant Ureal
:= Ureal_1
;
1552 Digs_Val
: constant Uint
:= Uint_6
;
1557 Set_Etype
(Base
, Base
);
1558 Set_Size_Info
(Base
, Int_Base
);
1559 Set_RM_Size
(Base
, RM_Size
(Int_Base
));
1560 Set_First_Rep_Item
(Base
, First_Rep_Item
(Int_Base
));
1561 Set_Digits_Value
(Base
, Digs_Val
);
1562 Set_Delta_Value
(Base
, Delta_Val
);
1563 Set_Small_Value
(Base
, Delta_Val
);
1564 Set_Scalar_Range
(Base
,
1566 Low_Bound
=> Make_Real_Literal
(Loc
, Ureal_1
),
1567 High_Bound
=> Make_Real_Literal
(Loc
, Ureal_1
)));
1569 Set_Is_Generic_Type
(Base
);
1570 Set_Parent
(Base
, Parent
(Def
));
1572 Set_Ekind
(T
, E_Decimal_Fixed_Point_Subtype
);
1573 Set_Etype
(T
, Base
);
1574 Set_Size_Info
(T
, Int_Base
);
1575 Set_RM_Size
(T
, RM_Size
(Int_Base
));
1576 Set_First_Rep_Item
(T
, First_Rep_Item
(Int_Base
));
1577 Set_Digits_Value
(T
, Digs_Val
);
1578 Set_Delta_Value
(T
, Delta_Val
);
1579 Set_Small_Value
(T
, Delta_Val
);
1580 Set_Scalar_Range
(T
, Scalar_Range
(Base
));
1581 Set_Is_Constrained
(T
);
1583 Check_Restriction
(No_Fixed_Point
, Def
);
1584 end Analyze_Formal_Decimal_Fixed_Point_Type
;
1586 -------------------------------------------
1587 -- Analyze_Formal_Derived_Interface_Type --
1588 -------------------------------------------
1590 procedure Analyze_Formal_Derived_Interface_Type
1595 Loc
: constant Source_Ptr
:= Sloc
(Def
);
1598 -- Rewrite as a type declaration of a derived type. This ensures that
1599 -- the interface list and primitive operations are properly captured.
1602 Make_Full_Type_Declaration
(Loc
,
1603 Defining_Identifier
=> T
,
1604 Type_Definition
=> Def
));
1606 Set_Is_Generic_Type
(T
);
1607 end Analyze_Formal_Derived_Interface_Type
;
1609 ---------------------------------
1610 -- Analyze_Formal_Derived_Type --
1611 ---------------------------------
1613 procedure Analyze_Formal_Derived_Type
1618 Loc
: constant Source_Ptr
:= Sloc
(Def
);
1619 Unk_Disc
: constant Boolean := Unknown_Discriminants_Present
(N
);
1623 Set_Is_Generic_Type
(T
);
1625 if Private_Present
(Def
) then
1627 Make_Private_Extension_Declaration
(Loc
,
1628 Defining_Identifier
=> T
,
1629 Discriminant_Specifications
=> Discriminant_Specifications
(N
),
1630 Unknown_Discriminants_Present
=> Unk_Disc
,
1631 Subtype_Indication
=> Subtype_Mark
(Def
),
1632 Interface_List
=> Interface_List
(Def
));
1634 Set_Abstract_Present
(New_N
, Abstract_Present
(Def
));
1635 Set_Limited_Present
(New_N
, Limited_Present
(Def
));
1636 Set_Synchronized_Present
(New_N
, Synchronized_Present
(Def
));
1640 Make_Full_Type_Declaration
(Loc
,
1641 Defining_Identifier
=> T
,
1642 Discriminant_Specifications
=>
1643 Discriminant_Specifications
(Parent
(T
)),
1645 Make_Derived_Type_Definition
(Loc
,
1646 Subtype_Indication
=> Subtype_Mark
(Def
)));
1648 Set_Abstract_Present
1649 (Type_Definition
(New_N
), Abstract_Present
(Def
));
1651 (Type_Definition
(New_N
), Limited_Present
(Def
));
1658 if not Is_Composite_Type
(T
) then
1660 ("unknown discriminants not allowed for elementary types", N
);
1662 Set_Has_Unknown_Discriminants
(T
);
1663 Set_Is_Constrained
(T
, False);
1667 -- If the parent type has a known size, so does the formal, which makes
1668 -- legal representation clauses that involve the formal.
1670 Set_Size_Known_At_Compile_Time
1671 (T
, Size_Known_At_Compile_Time
(Entity
(Subtype_Mark
(Def
))));
1672 end Analyze_Formal_Derived_Type
;
1674 ----------------------------------
1675 -- Analyze_Formal_Discrete_Type --
1676 ----------------------------------
1678 -- The operations defined for a discrete types are those of an enumeration
1679 -- type. The size is set to an arbitrary value, for use in analyzing the
1682 procedure Analyze_Formal_Discrete_Type
(T
: Entity_Id
; Def
: Node_Id
) is
1683 Loc
: constant Source_Ptr
:= Sloc
(Def
);
1687 Base
: constant Entity_Id
:=
1689 (E_Floating_Point_Type
, Current_Scope
, Sloc
(Def
), 'G');
1692 Set_Ekind
(T
, E_Enumeration_Subtype
);
1693 Set_Etype
(T
, Base
);
1696 Set_Is_Generic_Type
(T
);
1697 Set_Is_Constrained
(T
);
1699 -- For semantic analysis, the bounds of the type must be set to some
1700 -- non-static value. The simplest is to create attribute nodes for those
1701 -- bounds, that refer to the type itself. These bounds are never
1702 -- analyzed but serve as place-holders.
1705 Make_Attribute_Reference
(Loc
,
1706 Attribute_Name
=> Name_First
,
1707 Prefix
=> New_Reference_To
(T
, Loc
));
1711 Make_Attribute_Reference
(Loc
,
1712 Attribute_Name
=> Name_Last
,
1713 Prefix
=> New_Reference_To
(T
, Loc
));
1716 Set_Scalar_Range
(T
,
1721 Set_Ekind
(Base
, E_Enumeration_Type
);
1722 Set_Etype
(Base
, Base
);
1723 Init_Size
(Base
, 8);
1724 Init_Alignment
(Base
);
1725 Set_Is_Generic_Type
(Base
);
1726 Set_Scalar_Range
(Base
, Scalar_Range
(T
));
1727 Set_Parent
(Base
, Parent
(Def
));
1728 end Analyze_Formal_Discrete_Type
;
1730 ----------------------------------
1731 -- Analyze_Formal_Floating_Type --
1732 ---------------------------------
1734 procedure Analyze_Formal_Floating_Type
(T
: Entity_Id
; Def
: Node_Id
) is
1735 Base
: constant Entity_Id
:=
1737 (E_Floating_Point_Type
, Current_Scope
, Sloc
(Def
), 'G');
1740 -- The various semantic attributes are taken from the predefined type
1741 -- Float, just so that all of them are initialized. Their values are
1742 -- never used because no constant folding or expansion takes place in
1743 -- the generic itself.
1746 Set_Ekind
(T
, E_Floating_Point_Subtype
);
1747 Set_Etype
(T
, Base
);
1748 Set_Size_Info
(T
, (Standard_Float
));
1749 Set_RM_Size
(T
, RM_Size
(Standard_Float
));
1750 Set_Digits_Value
(T
, Digits_Value
(Standard_Float
));
1751 Set_Scalar_Range
(T
, Scalar_Range
(Standard_Float
));
1752 Set_Is_Constrained
(T
);
1754 Set_Is_Generic_Type
(Base
);
1755 Set_Etype
(Base
, Base
);
1756 Set_Size_Info
(Base
, (Standard_Float
));
1757 Set_RM_Size
(Base
, RM_Size
(Standard_Float
));
1758 Set_Digits_Value
(Base
, Digits_Value
(Standard_Float
));
1759 Set_Scalar_Range
(Base
, Scalar_Range
(Standard_Float
));
1760 Set_Parent
(Base
, Parent
(Def
));
1762 Check_Restriction
(No_Floating_Point
, Def
);
1763 end Analyze_Formal_Floating_Type
;
1765 -----------------------------------
1766 -- Analyze_Formal_Interface_Type;--
1767 -----------------------------------
1769 procedure Analyze_Formal_Interface_Type
1774 Loc
: constant Source_Ptr
:= Sloc
(N
);
1779 Make_Full_Type_Declaration
(Loc
,
1780 Defining_Identifier
=> T
,
1781 Type_Definition
=> Def
);
1785 Set_Is_Generic_Type
(T
);
1786 end Analyze_Formal_Interface_Type
;
1788 ---------------------------------
1789 -- Analyze_Formal_Modular_Type --
1790 ---------------------------------
1792 procedure Analyze_Formal_Modular_Type
(T
: Entity_Id
; Def
: Node_Id
) is
1794 -- Apart from their entity kind, generic modular types are treated like
1795 -- signed integer types, and have the same attributes.
1797 Analyze_Formal_Signed_Integer_Type
(T
, Def
);
1798 Set_Ekind
(T
, E_Modular_Integer_Subtype
);
1799 Set_Ekind
(Etype
(T
), E_Modular_Integer_Type
);
1801 end Analyze_Formal_Modular_Type
;
1803 ---------------------------------------
1804 -- Analyze_Formal_Object_Declaration --
1805 ---------------------------------------
1807 procedure Analyze_Formal_Object_Declaration
(N
: Node_Id
) is
1808 E
: constant Node_Id
:= Default_Expression
(N
);
1809 Id
: constant Node_Id
:= Defining_Identifier
(N
);
1816 -- Determine the mode of the formal object
1818 if Out_Present
(N
) then
1819 K
:= E_Generic_In_Out_Parameter
;
1821 if not In_Present
(N
) then
1822 Error_Msg_N
("formal generic objects cannot have mode OUT", N
);
1826 K
:= E_Generic_In_Parameter
;
1829 if Present
(Subtype_Mark
(N
)) then
1830 Find_Type
(Subtype_Mark
(N
));
1831 T
:= Entity
(Subtype_Mark
(N
));
1833 -- Verify that there is no redundant null exclusion
1835 if Null_Exclusion_Present
(N
) then
1836 if not Is_Access_Type
(T
) then
1838 ("null exclusion can only apply to an access type", N
);
1840 elsif Can_Never_Be_Null
(T
) then
1842 ("`NOT NULL` not allowed (& already excludes null)",
1847 -- Ada 2005 (AI-423): Formal object with an access definition
1850 Check_Access_Definition
(N
);
1851 T
:= Access_Definition
1853 N
=> Access_Definition
(N
));
1856 if Ekind
(T
) = E_Incomplete_Type
then
1858 Error_Node
: Node_Id
;
1861 if Present
(Subtype_Mark
(N
)) then
1862 Error_Node
:= Subtype_Mark
(N
);
1864 Check_Access_Definition
(N
);
1865 Error_Node
:= Access_Definition
(N
);
1868 Error_Msg_N
("premature usage of incomplete type", Error_Node
);
1872 if K
= E_Generic_In_Parameter
then
1874 -- Ada 2005 (AI-287): Limited aggregates allowed in generic formals
1876 if Ada_Version
< Ada_05
and then Is_Limited_Type
(T
) then
1878 ("generic formal of mode IN must not be of limited type", N
);
1879 Explain_Limited_Type
(T
, N
);
1882 if Is_Abstract_Type
(T
) then
1884 ("generic formal of mode IN must not be of abstract type", N
);
1888 Preanalyze_Spec_Expression
(E
, T
);
1890 if Is_Limited_Type
(T
) and then not OK_For_Limited_Init
(T
, E
) then
1892 ("initialization not allowed for limited types", E
);
1893 Explain_Limited_Type
(T
, E
);
1900 -- Case of generic IN OUT parameter
1903 -- If the formal has an unconstrained type, construct its actual
1904 -- subtype, as is done for subprogram formals. In this fashion, all
1905 -- its uses can refer to specific bounds.
1910 if (Is_Array_Type
(T
)
1911 and then not Is_Constrained
(T
))
1913 (Ekind
(T
) = E_Record_Type
1914 and then Has_Discriminants
(T
))
1917 Non_Freezing_Ref
: constant Node_Id
:=
1918 New_Reference_To
(Id
, Sloc
(Id
));
1922 -- Make sure the actual subtype doesn't generate bogus freezing
1924 Set_Must_Not_Freeze
(Non_Freezing_Ref
);
1925 Decl
:= Build_Actual_Subtype
(T
, Non_Freezing_Ref
);
1926 Insert_Before_And_Analyze
(N
, Decl
);
1927 Set_Actual_Subtype
(Id
, Defining_Identifier
(Decl
));
1930 Set_Actual_Subtype
(Id
, T
);
1935 ("initialization not allowed for `IN OUT` formals", N
);
1938 end Analyze_Formal_Object_Declaration
;
1940 ----------------------------------------------
1941 -- Analyze_Formal_Ordinary_Fixed_Point_Type --
1942 ----------------------------------------------
1944 procedure Analyze_Formal_Ordinary_Fixed_Point_Type
1948 Loc
: constant Source_Ptr
:= Sloc
(Def
);
1949 Base
: constant Entity_Id
:=
1951 (E_Ordinary_Fixed_Point_Type
, Current_Scope
, Sloc
(Def
), 'G');
1953 -- The semantic attributes are set for completeness only, their values
1954 -- will never be used, since all properties of the type are non-static.
1957 Set_Ekind
(T
, E_Ordinary_Fixed_Point_Subtype
);
1958 Set_Etype
(T
, Base
);
1959 Set_Size_Info
(T
, Standard_Integer
);
1960 Set_RM_Size
(T
, RM_Size
(Standard_Integer
));
1961 Set_Small_Value
(T
, Ureal_1
);
1962 Set_Delta_Value
(T
, Ureal_1
);
1963 Set_Scalar_Range
(T
,
1965 Low_Bound
=> Make_Real_Literal
(Loc
, Ureal_1
),
1966 High_Bound
=> Make_Real_Literal
(Loc
, Ureal_1
)));
1967 Set_Is_Constrained
(T
);
1969 Set_Is_Generic_Type
(Base
);
1970 Set_Etype
(Base
, Base
);
1971 Set_Size_Info
(Base
, Standard_Integer
);
1972 Set_RM_Size
(Base
, RM_Size
(Standard_Integer
));
1973 Set_Small_Value
(Base
, Ureal_1
);
1974 Set_Delta_Value
(Base
, Ureal_1
);
1975 Set_Scalar_Range
(Base
, Scalar_Range
(T
));
1976 Set_Parent
(Base
, Parent
(Def
));
1978 Check_Restriction
(No_Fixed_Point
, Def
);
1979 end Analyze_Formal_Ordinary_Fixed_Point_Type
;
1981 ----------------------------
1982 -- Analyze_Formal_Package --
1983 ----------------------------
1985 procedure Analyze_Formal_Package
(N
: Node_Id
) is
1986 Loc
: constant Source_Ptr
:= Sloc
(N
);
1987 Pack_Id
: constant Entity_Id
:= Defining_Identifier
(N
);
1989 Gen_Id
: constant Node_Id
:= Name
(N
);
1991 Gen_Unit
: Entity_Id
;
1993 Parent_Installed
: Boolean := False;
1995 Parent_Instance
: Entity_Id
;
1996 Renaming_In_Par
: Entity_Id
;
1997 No_Associations
: Boolean := False;
1999 function Build_Local_Package
return Node_Id
;
2000 -- The formal package is rewritten so that its parameters are replaced
2001 -- with corresponding declarations. For parameters with bona fide
2002 -- associations these declarations are created by Analyze_Associations
2003 -- as for a regular instantiation. For boxed parameters, we preserve
2004 -- the formal declarations and analyze them, in order to introduce
2005 -- entities of the right kind in the environment of the formal.
2007 -------------------------
2008 -- Build_Local_Package --
2009 -------------------------
2011 function Build_Local_Package
return Node_Id
is
2013 Pack_Decl
: Node_Id
;
2016 -- Within the formal, the name of the generic package is a renaming
2017 -- of the formal (as for a regular instantiation).
2020 Make_Package_Declaration
(Loc
,
2023 (Specification
(Original_Node
(Gen_Decl
)),
2024 Empty
, Instantiating
=> True));
2026 Renaming
:= Make_Package_Renaming_Declaration
(Loc
,
2027 Defining_Unit_Name
=>
2028 Make_Defining_Identifier
(Loc
, Chars
(Gen_Unit
)),
2029 Name
=> New_Occurrence_Of
(Formal
, Loc
));
2031 if Nkind
(Gen_Id
) = N_Identifier
2032 and then Chars
(Gen_Id
) = Chars
(Pack_Id
)
2035 ("& is hidden within declaration of instance", Gen_Id
, Gen_Unit
);
2038 -- If the formal is declared with a box, or with an others choice,
2039 -- create corresponding declarations for all entities in the formal
2040 -- part, so that names with the proper types are available in the
2041 -- specification of the formal package.
2043 -- On the other hand, if there are no associations, then all the
2044 -- formals must have defaults, and this will be checked by the
2045 -- call to Analyze_Associations.
2048 or else Nkind
(First
(Generic_Associations
(N
))) = N_Others_Choice
2051 Formal_Decl
: Node_Id
;
2054 -- TBA : for a formal package, need to recurse ???
2059 (Generic_Formal_Declarations
(Original_Node
(Gen_Decl
)));
2060 while Present
(Formal_Decl
) loop
2062 (Decls
, Copy_Generic_Node
(Formal_Decl
, Empty
, True));
2067 -- If generic associations are present, use Analyze_Associations to
2068 -- create the proper renaming declarations.
2072 Act_Tree
: constant Node_Id
:=
2074 (Original_Node
(Gen_Decl
), Empty
,
2075 Instantiating
=> True);
2078 Generic_Renamings
.Set_Last
(0);
2079 Generic_Renamings_HTable
.Reset
;
2080 Instantiation_Node
:= N
;
2083 Analyze_Associations
2085 Generic_Formal_Declarations
(Act_Tree
),
2086 Generic_Formal_Declarations
(Gen_Decl
));
2090 Append
(Renaming
, To
=> Decls
);
2092 -- Add generated declarations ahead of local declarations in
2095 if No
(Visible_Declarations
(Specification
(Pack_Decl
))) then
2096 Set_Visible_Declarations
(Specification
(Pack_Decl
), Decls
);
2099 (First
(Visible_Declarations
(Specification
(Pack_Decl
))),
2104 end Build_Local_Package
;
2106 -- Start of processing for Analyze_Formal_Package
2109 Text_IO_Kludge
(Gen_Id
);
2112 Check_Generic_Child_Unit
(Gen_Id
, Parent_Installed
);
2113 Gen_Unit
:= Entity
(Gen_Id
);
2115 -- Check for a formal package that is a package renaming
2117 if Present
(Renamed_Object
(Gen_Unit
)) then
2118 Gen_Unit
:= Renamed_Object
(Gen_Unit
);
2121 if Ekind
(Gen_Unit
) /= E_Generic_Package
then
2122 Error_Msg_N
("expect generic package name", Gen_Id
);
2126 elsif Gen_Unit
= Current_Scope
then
2128 ("generic package cannot be used as a formal package of itself",
2133 elsif In_Open_Scopes
(Gen_Unit
) then
2134 if Is_Compilation_Unit
(Gen_Unit
)
2135 and then Is_Child_Unit
(Current_Scope
)
2137 -- Special-case the error when the formal is a parent, and
2138 -- continue analysis to minimize cascaded errors.
2141 ("generic parent cannot be used as formal package "
2142 & "of a child unit",
2147 ("generic package cannot be used as a formal package "
2156 or else No
(Generic_Associations
(N
))
2157 or else Nkind
(First
(Generic_Associations
(N
))) = N_Others_Choice
2159 No_Associations
:= True;
2162 -- If there are no generic associations, the generic parameters appear
2163 -- as local entities and are instantiated like them. We copy the generic
2164 -- package declaration as if it were an instantiation, and analyze it
2165 -- like a regular package, except that we treat the formals as
2166 -- additional visible components.
2168 Gen_Decl
:= Unit_Declaration_Node
(Gen_Unit
);
2170 if In_Extended_Main_Source_Unit
(N
) then
2171 Set_Is_Instantiated
(Gen_Unit
);
2172 Generate_Reference
(Gen_Unit
, N
);
2175 Formal
:= New_Copy
(Pack_Id
);
2176 Create_Instantiation_Source
(N
, Gen_Unit
, False, S_Adjustment
);
2179 -- Make local generic without formals. The formals will be replaced
2180 -- with internal declarations.
2182 New_N
:= Build_Local_Package
;
2184 -- If there are errors in the parameter list, Analyze_Associations
2185 -- raises Instantiation_Error. Patch the declaration to prevent
2186 -- further exception propagation.
2189 when Instantiation_Error
=>
2191 Enter_Name
(Formal
);
2192 Set_Ekind
(Formal
, E_Variable
);
2193 Set_Etype
(Formal
, Any_Type
);
2195 if Parent_Installed
then
2203 Set_Defining_Unit_Name
(Specification
(New_N
), Formal
);
2204 Set_Generic_Parent
(Specification
(N
), Gen_Unit
);
2205 Set_Instance_Env
(Gen_Unit
, Formal
);
2206 Set_Is_Generic_Instance
(Formal
);
2208 Enter_Name
(Formal
);
2209 Set_Ekind
(Formal
, E_Package
);
2210 Set_Etype
(Formal
, Standard_Void_Type
);
2211 Set_Inner_Instances
(Formal
, New_Elmt_List
);
2212 Push_Scope
(Formal
);
2214 if Is_Child_Unit
(Gen_Unit
)
2215 and then Parent_Installed
2217 -- Similarly, we have to make the name of the formal visible in the
2218 -- parent instance, to resolve properly fully qualified names that
2219 -- may appear in the generic unit. The parent instance has been
2220 -- placed on the scope stack ahead of the current scope.
2222 Parent_Instance
:= Scope_Stack
.Table
(Scope_Stack
.Last
- 1).Entity
;
2225 Make_Defining_Identifier
(Loc
, Chars
(Gen_Unit
));
2226 Set_Ekind
(Renaming_In_Par
, E_Package
);
2227 Set_Etype
(Renaming_In_Par
, Standard_Void_Type
);
2228 Set_Scope
(Renaming_In_Par
, Parent_Instance
);
2229 Set_Parent
(Renaming_In_Par
, Parent
(Formal
));
2230 Set_Renamed_Object
(Renaming_In_Par
, Formal
);
2231 Append_Entity
(Renaming_In_Par
, Parent_Instance
);
2234 Analyze
(Specification
(N
));
2236 -- The formals for which associations are provided are not visible
2237 -- outside of the formal package. The others are still declared by a
2238 -- formal parameter declaration.
2240 if not No_Associations
then
2245 E
:= First_Entity
(Formal
);
2246 while Present
(E
) loop
2247 exit when Ekind
(E
) = E_Package
2248 and then Renamed_Entity
(E
) = Formal
;
2250 if not Is_Generic_Formal
(E
) then
2259 End_Package_Scope
(Formal
);
2261 if Parent_Installed
then
2267 -- Inside the generic unit, the formal package is a regular package, but
2268 -- no body is needed for it. Note that after instantiation, the defining
2269 -- unit name we need is in the new tree and not in the original (see
2270 -- Package_Instantiation). A generic formal package is an instance, and
2271 -- can be used as an actual for an inner instance.
2273 Set_Has_Completion
(Formal
, True);
2275 -- Add semantic information to the original defining identifier.
2278 Set_Ekind
(Pack_Id
, E_Package
);
2279 Set_Etype
(Pack_Id
, Standard_Void_Type
);
2280 Set_Scope
(Pack_Id
, Scope
(Formal
));
2281 Set_Has_Completion
(Pack_Id
, True);
2282 end Analyze_Formal_Package
;
2284 ---------------------------------
2285 -- Analyze_Formal_Private_Type --
2286 ---------------------------------
2288 procedure Analyze_Formal_Private_Type
2294 New_Private_Type
(N
, T
, Def
);
2296 -- Set the size to an arbitrary but legal value
2298 Set_Size_Info
(T
, Standard_Integer
);
2299 Set_RM_Size
(T
, RM_Size
(Standard_Integer
));
2300 end Analyze_Formal_Private_Type
;
2302 ----------------------------------------
2303 -- Analyze_Formal_Signed_Integer_Type --
2304 ----------------------------------------
2306 procedure Analyze_Formal_Signed_Integer_Type
2310 Base
: constant Entity_Id
:=
2312 (E_Signed_Integer_Type
, Current_Scope
, Sloc
(Def
), 'G');
2317 Set_Ekind
(T
, E_Signed_Integer_Subtype
);
2318 Set_Etype
(T
, Base
);
2319 Set_Size_Info
(T
, Standard_Integer
);
2320 Set_RM_Size
(T
, RM_Size
(Standard_Integer
));
2321 Set_Scalar_Range
(T
, Scalar_Range
(Standard_Integer
));
2322 Set_Is_Constrained
(T
);
2324 Set_Is_Generic_Type
(Base
);
2325 Set_Size_Info
(Base
, Standard_Integer
);
2326 Set_RM_Size
(Base
, RM_Size
(Standard_Integer
));
2327 Set_Etype
(Base
, Base
);
2328 Set_Scalar_Range
(Base
, Scalar_Range
(Standard_Integer
));
2329 Set_Parent
(Base
, Parent
(Def
));
2330 end Analyze_Formal_Signed_Integer_Type
;
2332 -------------------------------
2333 -- Analyze_Formal_Subprogram --
2334 -------------------------------
2336 procedure Analyze_Formal_Subprogram
(N
: Node_Id
) is
2337 Spec
: constant Node_Id
:= Specification
(N
);
2338 Def
: constant Node_Id
:= Default_Name
(N
);
2339 Nam
: constant Entity_Id
:= Defining_Unit_Name
(Spec
);
2347 if Nkind
(Nam
) = N_Defining_Program_Unit_Name
then
2348 Error_Msg_N
("name of formal subprogram must be a direct name", Nam
);
2352 Analyze_Subprogram_Declaration
(N
);
2353 Set_Is_Formal_Subprogram
(Nam
);
2354 Set_Has_Completion
(Nam
);
2356 if Nkind
(N
) = N_Formal_Abstract_Subprogram_Declaration
then
2357 Set_Is_Abstract_Subprogram
(Nam
);
2358 Set_Is_Dispatching_Operation
(Nam
);
2361 Ctrl_Type
: constant Entity_Id
:= Find_Dispatching_Type
(Nam
);
2363 if No
(Ctrl_Type
) then
2365 ("abstract formal subprogram must have a controlling type",
2368 Check_Controlling_Formals
(Ctrl_Type
, Nam
);
2373 -- Default name is resolved at the point of instantiation
2375 if Box_Present
(N
) then
2378 -- Else default is bound at the point of generic declaration
2380 elsif Present
(Def
) then
2381 if Nkind
(Def
) = N_Operator_Symbol
then
2382 Find_Direct_Name
(Def
);
2384 elsif Nkind
(Def
) /= N_Attribute_Reference
then
2388 -- For an attribute reference, analyze the prefix and verify
2389 -- that it has the proper profile for the subprogram.
2391 Analyze
(Prefix
(Def
));
2392 Valid_Default_Attribute
(Nam
, Def
);
2396 -- Default name may be overloaded, in which case the interpretation
2397 -- with the correct profile must be selected, as for a renaming.
2398 -- If the definition is an indexed component, it must denote a
2399 -- member of an entry family. If it is a selected component, it
2400 -- can be a protected operation.
2402 if Etype
(Def
) = Any_Type
then
2405 elsif Nkind
(Def
) = N_Selected_Component
then
2406 if not Is_Overloadable
(Entity
(Selector_Name
(Def
))) then
2407 Error_Msg_N
("expect valid subprogram name as default", Def
);
2410 elsif Nkind
(Def
) = N_Indexed_Component
then
2411 if Is_Entity_Name
(Prefix
(Def
)) then
2412 if Ekind
(Entity
(Prefix
(Def
))) /= E_Entry_Family
then
2413 Error_Msg_N
("expect valid subprogram name as default", Def
);
2416 elsif Nkind
(Prefix
(Def
)) = N_Selected_Component
then
2417 if Ekind
(Entity
(Selector_Name
(Prefix
(Def
)))) /=
2420 Error_Msg_N
("expect valid subprogram name as default", Def
);
2424 Error_Msg_N
("expect valid subprogram name as default", Def
);
2428 elsif Nkind
(Def
) = N_Character_Literal
then
2430 -- Needs some type checks: subprogram should be parameterless???
2432 Resolve
(Def
, (Etype
(Nam
)));
2434 elsif not Is_Entity_Name
(Def
)
2435 or else not Is_Overloadable
(Entity
(Def
))
2437 Error_Msg_N
("expect valid subprogram name as default", Def
);
2440 elsif not Is_Overloaded
(Def
) then
2441 Subp
:= Entity
(Def
);
2444 Error_Msg_N
("premature usage of formal subprogram", Def
);
2446 elsif not Entity_Matches_Spec
(Subp
, Nam
) then
2447 Error_Msg_N
("no visible entity matches specification", Def
);
2450 -- More than one interpretation, so disambiguate as for a renaming
2455 I1
: Interp_Index
:= 0;
2461 Get_First_Interp
(Def
, I
, It
);
2462 while Present
(It
.Nam
) loop
2463 if Entity_Matches_Spec
(It
.Nam
, Nam
) then
2464 if Subp
/= Any_Id
then
2465 It1
:= Disambiguate
(Def
, I1
, I
, Etype
(Subp
));
2467 if It1
= No_Interp
then
2468 Error_Msg_N
("ambiguous default subprogram", Def
);
2481 Get_Next_Interp
(I
, It
);
2485 if Subp
/= Any_Id
then
2486 Set_Entity
(Def
, Subp
);
2489 Error_Msg_N
("premature usage of formal subprogram", Def
);
2491 elsif Ekind
(Subp
) /= E_Operator
then
2492 Check_Mode_Conformant
(Subp
, Nam
);
2496 Error_Msg_N
("no visible subprogram matches specification", N
);
2500 end Analyze_Formal_Subprogram
;
2502 -------------------------------------
2503 -- Analyze_Formal_Type_Declaration --
2504 -------------------------------------
2506 procedure Analyze_Formal_Type_Declaration
(N
: Node_Id
) is
2507 Def
: constant Node_Id
:= Formal_Type_Definition
(N
);
2511 T
:= Defining_Identifier
(N
);
2513 if Present
(Discriminant_Specifications
(N
))
2514 and then Nkind
(Def
) /= N_Formal_Private_Type_Definition
2517 ("discriminants not allowed for this formal type", T
);
2520 -- Enter the new name, and branch to specific routine
2523 when N_Formal_Private_Type_Definition
=>
2524 Analyze_Formal_Private_Type
(N
, T
, Def
);
2526 when N_Formal_Derived_Type_Definition
=>
2527 Analyze_Formal_Derived_Type
(N
, T
, Def
);
2529 when N_Formal_Discrete_Type_Definition
=>
2530 Analyze_Formal_Discrete_Type
(T
, Def
);
2532 when N_Formal_Signed_Integer_Type_Definition
=>
2533 Analyze_Formal_Signed_Integer_Type
(T
, Def
);
2535 when N_Formal_Modular_Type_Definition
=>
2536 Analyze_Formal_Modular_Type
(T
, Def
);
2538 when N_Formal_Floating_Point_Definition
=>
2539 Analyze_Formal_Floating_Type
(T
, Def
);
2541 when N_Formal_Ordinary_Fixed_Point_Definition
=>
2542 Analyze_Formal_Ordinary_Fixed_Point_Type
(T
, Def
);
2544 when N_Formal_Decimal_Fixed_Point_Definition
=>
2545 Analyze_Formal_Decimal_Fixed_Point_Type
(T
, Def
);
2547 when N_Array_Type_Definition
=>
2548 Analyze_Formal_Array_Type
(T
, Def
);
2550 when N_Access_To_Object_Definition |
2551 N_Access_Function_Definition |
2552 N_Access_Procedure_Definition
=>
2553 Analyze_Generic_Access_Type
(T
, Def
);
2555 -- Ada 2005: a interface declaration is encoded as an abstract
2556 -- record declaration or a abstract type derivation.
2558 when N_Record_Definition
=>
2559 Analyze_Formal_Interface_Type
(N
, T
, Def
);
2561 when N_Derived_Type_Definition
=>
2562 Analyze_Formal_Derived_Interface_Type
(N
, T
, Def
);
2568 raise Program_Error
;
2572 Set_Is_Generic_Type
(T
);
2573 end Analyze_Formal_Type_Declaration
;
2575 ------------------------------------
2576 -- Analyze_Function_Instantiation --
2577 ------------------------------------
2579 procedure Analyze_Function_Instantiation
(N
: Node_Id
) is
2581 Analyze_Subprogram_Instantiation
(N
, E_Function
);
2582 end Analyze_Function_Instantiation
;
2584 ---------------------------------
2585 -- Analyze_Generic_Access_Type --
2586 ---------------------------------
2588 procedure Analyze_Generic_Access_Type
(T
: Entity_Id
; Def
: Node_Id
) is
2592 if Nkind
(Def
) = N_Access_To_Object_Definition
then
2593 Access_Type_Declaration
(T
, Def
);
2595 if Is_Incomplete_Or_Private_Type
(Designated_Type
(T
))
2596 and then No
(Full_View
(Designated_Type
(T
)))
2597 and then not Is_Generic_Type
(Designated_Type
(T
))
2599 Error_Msg_N
("premature usage of incomplete type", Def
);
2601 elsif not Is_Entity_Name
(Subtype_Indication
(Def
)) then
2603 ("only a subtype mark is allowed in a formal", Def
);
2607 Access_Subprogram_Declaration
(T
, Def
);
2609 end Analyze_Generic_Access_Type
;
2611 ---------------------------------
2612 -- Analyze_Generic_Formal_Part --
2613 ---------------------------------
2615 procedure Analyze_Generic_Formal_Part
(N
: Node_Id
) is
2616 Gen_Parm_Decl
: Node_Id
;
2619 -- The generic formals are processed in the scope of the generic unit,
2620 -- where they are immediately visible. The scope is installed by the
2623 Gen_Parm_Decl
:= First
(Generic_Formal_Declarations
(N
));
2625 while Present
(Gen_Parm_Decl
) loop
2626 Analyze
(Gen_Parm_Decl
);
2627 Next
(Gen_Parm_Decl
);
2630 Generate_Reference_To_Generic_Formals
(Current_Scope
);
2631 end Analyze_Generic_Formal_Part
;
2633 ------------------------------------------
2634 -- Analyze_Generic_Package_Declaration --
2635 ------------------------------------------
2637 procedure Analyze_Generic_Package_Declaration
(N
: Node_Id
) is
2638 Loc
: constant Source_Ptr
:= Sloc
(N
);
2641 Save_Parent
: Node_Id
;
2643 Decls
: constant List_Id
:=
2644 Visible_Declarations
(Specification
(N
));
2648 -- We introduce a renaming of the enclosing package, to have a usable
2649 -- entity as the prefix of an expanded name for a local entity of the
2650 -- form Par.P.Q, where P is the generic package. This is because a local
2651 -- entity named P may hide it, so that the usual visibility rules in
2652 -- the instance will not resolve properly.
2655 Make_Package_Renaming_Declaration
(Loc
,
2656 Defining_Unit_Name
=>
2657 Make_Defining_Identifier
(Loc
,
2658 Chars
=> New_External_Name
(Chars
(Defining_Entity
(N
)), "GH")),
2659 Name
=> Make_Identifier
(Loc
, Chars
(Defining_Entity
(N
))));
2661 if Present
(Decls
) then
2662 Decl
:= First
(Decls
);
2663 while Present
(Decl
)
2664 and then Nkind
(Decl
) = N_Pragma
2669 if Present
(Decl
) then
2670 Insert_Before
(Decl
, Renaming
);
2672 Append
(Renaming
, Visible_Declarations
(Specification
(N
)));
2676 Set_Visible_Declarations
(Specification
(N
), New_List
(Renaming
));
2679 -- Create copy of generic unit, and save for instantiation. If the unit
2680 -- is a child unit, do not copy the specifications for the parent, which
2681 -- are not part of the generic tree.
2683 Save_Parent
:= Parent_Spec
(N
);
2684 Set_Parent_Spec
(N
, Empty
);
2686 New_N
:= Copy_Generic_Node
(N
, Empty
, Instantiating
=> False);
2687 Set_Parent_Spec
(New_N
, Save_Parent
);
2689 Id
:= Defining_Entity
(N
);
2690 Generate_Definition
(Id
);
2692 -- Expansion is not applied to generic units
2697 Set_Ekind
(Id
, E_Generic_Package
);
2698 Set_Etype
(Id
, Standard_Void_Type
);
2700 Enter_Generic_Scope
(Id
);
2701 Set_Inner_Instances
(Id
, New_Elmt_List
);
2703 Set_Categorization_From_Pragmas
(N
);
2704 Set_Is_Pure
(Id
, Is_Pure
(Current_Scope
));
2706 -- Link the declaration of the generic homonym in the generic copy to
2707 -- the package it renames, so that it is always resolved properly.
2709 Set_Generic_Homonym
(Id
, Defining_Unit_Name
(Renaming
));
2710 Set_Entity
(Associated_Node
(Name
(Renaming
)), Id
);
2712 -- For a library unit, we have reconstructed the entity for the unit,
2713 -- and must reset it in the library tables.
2715 if Nkind
(Parent
(N
)) = N_Compilation_Unit
then
2716 Set_Cunit_Entity
(Current_Sem_Unit
, Id
);
2719 Analyze_Generic_Formal_Part
(N
);
2721 -- After processing the generic formals, analysis proceeds as for a
2722 -- non-generic package.
2724 Analyze
(Specification
(N
));
2726 Validate_Categorization_Dependency
(N
, Id
);
2730 End_Package_Scope
(Id
);
2731 Exit_Generic_Scope
(Id
);
2733 if Nkind
(Parent
(N
)) /= N_Compilation_Unit
then
2734 Move_Freeze_Nodes
(Id
, N
, Visible_Declarations
(Specification
(N
)));
2735 Move_Freeze_Nodes
(Id
, N
, Private_Declarations
(Specification
(N
)));
2736 Move_Freeze_Nodes
(Id
, N
, Generic_Formal_Declarations
(N
));
2739 Set_Body_Required
(Parent
(N
), Unit_Requires_Body
(Id
));
2740 Validate_RT_RAT_Component
(N
);
2742 -- If this is a spec without a body, check that generic parameters
2745 if not Body_Required
(Parent
(N
)) then
2746 Check_References
(Id
);
2749 end Analyze_Generic_Package_Declaration
;
2751 --------------------------------------------
2752 -- Analyze_Generic_Subprogram_Declaration --
2753 --------------------------------------------
2755 procedure Analyze_Generic_Subprogram_Declaration
(N
: Node_Id
) is
2760 Result_Type
: Entity_Id
;
2761 Save_Parent
: Node_Id
;
2765 -- Create copy of generic unit, and save for instantiation. If the unit
2766 -- is a child unit, do not copy the specifications for the parent, which
2767 -- are not part of the generic tree.
2769 Save_Parent
:= Parent_Spec
(N
);
2770 Set_Parent_Spec
(N
, Empty
);
2772 New_N
:= Copy_Generic_Node
(N
, Empty
, Instantiating
=> False);
2773 Set_Parent_Spec
(New_N
, Save_Parent
);
2776 Spec
:= Specification
(N
);
2777 Id
:= Defining_Entity
(Spec
);
2778 Generate_Definition
(Id
);
2780 if Nkind
(Id
) = N_Defining_Operator_Symbol
then
2782 ("operator symbol not allowed for generic subprogram", Id
);
2789 Set_Scope_Depth_Value
(Id
, Scope_Depth
(Current_Scope
) + 1);
2791 Enter_Generic_Scope
(Id
);
2792 Set_Inner_Instances
(Id
, New_Elmt_List
);
2793 Set_Is_Pure
(Id
, Is_Pure
(Current_Scope
));
2795 Analyze_Generic_Formal_Part
(N
);
2797 Formals
:= Parameter_Specifications
(Spec
);
2799 if Present
(Formals
) then
2800 Process_Formals
(Formals
, Spec
);
2803 if Nkind
(Spec
) = N_Function_Specification
then
2804 Set_Ekind
(Id
, E_Generic_Function
);
2806 if Nkind
(Result_Definition
(Spec
)) = N_Access_Definition
then
2807 Result_Type
:= Access_Definition
(Spec
, Result_Definition
(Spec
));
2808 Set_Etype
(Id
, Result_Type
);
2810 Find_Type
(Result_Definition
(Spec
));
2811 Typ
:= Entity
(Result_Definition
(Spec
));
2813 -- If a null exclusion is imposed on the result type, then create
2814 -- a null-excluding itype (an access subtype) and use it as the
2815 -- function's Etype.
2817 if Is_Access_Type
(Typ
)
2818 and then Null_Exclusion_Present
(Spec
)
2821 Create_Null_Excluding_Itype
2823 Related_Nod
=> Spec
,
2824 Scope_Id
=> Defining_Unit_Name
(Spec
)));
2826 Set_Etype
(Id
, Typ
);
2831 Set_Ekind
(Id
, E_Generic_Procedure
);
2832 Set_Etype
(Id
, Standard_Void_Type
);
2835 -- For a library unit, we have reconstructed the entity for the unit,
2836 -- and must reset it in the library tables. We also make sure that
2837 -- Body_Required is set properly in the original compilation unit node.
2839 if Nkind
(Parent
(N
)) = N_Compilation_Unit
then
2840 Set_Cunit_Entity
(Current_Sem_Unit
, Id
);
2841 Set_Body_Required
(Parent
(N
), Unit_Requires_Body
(Id
));
2844 Set_Categorization_From_Pragmas
(N
);
2845 Validate_Categorization_Dependency
(N
, Id
);
2847 Save_Global_References
(Original_Node
(N
));
2851 Exit_Generic_Scope
(Id
);
2852 Generate_Reference_To_Formals
(Id
);
2853 end Analyze_Generic_Subprogram_Declaration
;
2855 -----------------------------------
2856 -- Analyze_Package_Instantiation --
2857 -----------------------------------
2859 procedure Analyze_Package_Instantiation
(N
: Node_Id
) is
2860 Loc
: constant Source_Ptr
:= Sloc
(N
);
2861 Gen_Id
: constant Node_Id
:= Name
(N
);
2864 Act_Decl_Name
: Node_Id
;
2865 Act_Decl_Id
: Entity_Id
;
2870 Gen_Unit
: Entity_Id
;
2872 Is_Actual_Pack
: constant Boolean :=
2873 Is_Internal
(Defining_Entity
(N
));
2875 Env_Installed
: Boolean := False;
2876 Parent_Installed
: Boolean := False;
2877 Renaming_List
: List_Id
;
2878 Unit_Renaming
: Node_Id
;
2879 Needs_Body
: Boolean;
2880 Inline_Now
: Boolean := False;
2882 procedure Delay_Descriptors
(E
: Entity_Id
);
2883 -- Delay generation of subprogram descriptors for given entity
2885 function Might_Inline_Subp
return Boolean;
2886 -- If inlining is active and the generic contains inlined subprograms,
2887 -- we instantiate the body. This may cause superfluous instantiations,
2888 -- but it is simpler than detecting the need for the body at the point
2889 -- of inlining, when the context of the instance is not available.
2891 -----------------------
2892 -- Delay_Descriptors --
2893 -----------------------
2895 procedure Delay_Descriptors
(E
: Entity_Id
) is
2897 if not Delay_Subprogram_Descriptors
(E
) then
2898 Set_Delay_Subprogram_Descriptors
(E
);
2899 Pending_Descriptor
.Append
(E
);
2901 end Delay_Descriptors
;
2903 -----------------------
2904 -- Might_Inline_Subp --
2905 -----------------------
2907 function Might_Inline_Subp
return Boolean is
2911 if not Inline_Processing_Required
then
2915 E
:= First_Entity
(Gen_Unit
);
2916 while Present
(E
) loop
2917 if Is_Subprogram
(E
)
2918 and then Is_Inlined
(E
)
2928 end Might_Inline_Subp
;
2930 -- Start of processing for Analyze_Package_Instantiation
2933 -- Very first thing: apply the special kludge for Text_IO processing
2934 -- in case we are instantiating one of the children of [Wide_]Text_IO.
2936 Text_IO_Kludge
(Name
(N
));
2938 -- Make node global for error reporting
2940 Instantiation_Node
:= N
;
2942 -- Case of instantiation of a generic package
2944 if Nkind
(N
) = N_Package_Instantiation
then
2945 Act_Decl_Id
:= New_Copy
(Defining_Entity
(N
));
2946 Set_Comes_From_Source
(Act_Decl_Id
, True);
2948 if Nkind
(Defining_Unit_Name
(N
)) = N_Defining_Program_Unit_Name
then
2950 Make_Defining_Program_Unit_Name
(Loc
,
2951 Name
=> New_Copy_Tree
(Name
(Defining_Unit_Name
(N
))),
2952 Defining_Identifier
=> Act_Decl_Id
);
2954 Act_Decl_Name
:= Act_Decl_Id
;
2957 -- Case of instantiation of a formal package
2960 Act_Decl_Id
:= Defining_Identifier
(N
);
2961 Act_Decl_Name
:= Act_Decl_Id
;
2964 Generate_Definition
(Act_Decl_Id
);
2965 Preanalyze_Actuals
(N
);
2968 Env_Installed
:= True;
2970 -- Reset renaming map for formal types. The mapping is established
2971 -- when analyzing the generic associations, but some mappings are
2972 -- inherited from formal packages of parent units, and these are
2973 -- constructed when the parents are installed.
2975 Generic_Renamings
.Set_Last
(0);
2976 Generic_Renamings_HTable
.Reset
;
2978 Check_Generic_Child_Unit
(Gen_Id
, Parent_Installed
);
2979 Gen_Unit
:= Entity
(Gen_Id
);
2981 -- Verify that it is the name of a generic package
2983 -- A visibility glitch: if the instance is a child unit and the generic
2984 -- is the generic unit of a parent instance (i.e. both the parent and
2985 -- the child units are instances of the same package) the name now
2986 -- denotes the renaming within the parent, not the intended generic
2987 -- unit. See if there is a homonym that is the desired generic. The
2988 -- renaming declaration must be visible inside the instance of the
2989 -- child, but not when analyzing the name in the instantiation itself.
2991 if Ekind
(Gen_Unit
) = E_Package
2992 and then Present
(Renamed_Entity
(Gen_Unit
))
2993 and then In_Open_Scopes
(Renamed_Entity
(Gen_Unit
))
2994 and then Is_Generic_Instance
(Renamed_Entity
(Gen_Unit
))
2995 and then Present
(Homonym
(Gen_Unit
))
2997 Gen_Unit
:= Homonym
(Gen_Unit
);
3000 if Etype
(Gen_Unit
) = Any_Type
then
3004 elsif Ekind
(Gen_Unit
) /= E_Generic_Package
then
3006 -- Ada 2005 (AI-50217): Cannot use instance in limited with_clause
3008 if From_With_Type
(Gen_Unit
) then
3010 ("cannot instantiate a limited withed package", Gen_Id
);
3013 ("expect name of generic package in instantiation", Gen_Id
);
3020 if In_Extended_Main_Source_Unit
(N
) then
3021 Set_Is_Instantiated
(Gen_Unit
);
3022 Generate_Reference
(Gen_Unit
, N
);
3024 if Present
(Renamed_Object
(Gen_Unit
)) then
3025 Set_Is_Instantiated
(Renamed_Object
(Gen_Unit
));
3026 Generate_Reference
(Renamed_Object
(Gen_Unit
), N
);
3030 if Nkind
(Gen_Id
) = N_Identifier
3031 and then Chars
(Gen_Unit
) = Chars
(Defining_Entity
(N
))
3034 ("& is hidden within declaration of instance", Gen_Id
, Gen_Unit
);
3036 elsif Nkind
(Gen_Id
) = N_Expanded_Name
3037 and then Is_Child_Unit
(Gen_Unit
)
3038 and then Nkind
(Prefix
(Gen_Id
)) = N_Identifier
3039 and then Chars
(Act_Decl_Id
) = Chars
(Prefix
(Gen_Id
))
3042 ("& is hidden within declaration of instance ", Prefix
(Gen_Id
));
3045 Set_Entity
(Gen_Id
, Gen_Unit
);
3047 -- If generic is a renaming, get original generic unit
3049 if Present
(Renamed_Object
(Gen_Unit
))
3050 and then Ekind
(Renamed_Object
(Gen_Unit
)) = E_Generic_Package
3052 Gen_Unit
:= Renamed_Object
(Gen_Unit
);
3055 -- Verify that there are no circular instantiations
3057 if In_Open_Scopes
(Gen_Unit
) then
3058 Error_Msg_NE
("instantiation of & within itself", N
, Gen_Unit
);
3062 elsif Contains_Instance_Of
(Gen_Unit
, Current_Scope
, Gen_Id
) then
3063 Error_Msg_Node_2
:= Current_Scope
;
3065 ("circular Instantiation: & instantiated in &!", N
, Gen_Unit
);
3066 Circularity_Detected
:= True;
3071 Gen_Decl
:= Unit_Declaration_Node
(Gen_Unit
);
3073 -- Initialize renamings map, for error checking, and the list that
3074 -- holds private entities whose views have changed between generic
3075 -- definition and instantiation. If this is the instance created to
3076 -- validate an actual package, the instantiation environment is that
3077 -- of the enclosing instance.
3079 Create_Instantiation_Source
(N
, Gen_Unit
, False, S_Adjustment
);
3081 -- Copy original generic tree, to produce text for instantiation
3085 (Original_Node
(Gen_Decl
), Empty
, Instantiating
=> True);
3087 Act_Spec
:= Specification
(Act_Tree
);
3089 -- If this is the instance created to validate an actual package,
3090 -- only the formals matter, do not examine the package spec itself.
3092 if Is_Actual_Pack
then
3093 Set_Visible_Declarations
(Act_Spec
, New_List
);
3094 Set_Private_Declarations
(Act_Spec
, New_List
);
3098 Analyze_Associations
3100 Generic_Formal_Declarations
(Act_Tree
),
3101 Generic_Formal_Declarations
(Gen_Decl
));
3103 Set_Instance_Env
(Gen_Unit
, Act_Decl_Id
);
3104 Set_Defining_Unit_Name
(Act_Spec
, Act_Decl_Name
);
3105 Set_Is_Generic_Instance
(Act_Decl_Id
);
3107 Set_Generic_Parent
(Act_Spec
, Gen_Unit
);
3109 -- References to the generic in its own declaration or its body are
3110 -- references to the instance. Add a renaming declaration for the
3111 -- generic unit itself. This declaration, as well as the renaming
3112 -- declarations for the generic formals, must remain private to the
3113 -- unit: the formals, because this is the language semantics, and
3114 -- the unit because its use is an artifact of the implementation.
3117 Make_Package_Renaming_Declaration
(Loc
,
3118 Defining_Unit_Name
=>
3119 Make_Defining_Identifier
(Loc
, Chars
(Gen_Unit
)),
3120 Name
=> New_Reference_To
(Act_Decl_Id
, Loc
));
3122 Append
(Unit_Renaming
, Renaming_List
);
3124 -- The renaming declarations are the first local declarations of
3127 if Is_Non_Empty_List
(Visible_Declarations
(Act_Spec
)) then
3129 (First
(Visible_Declarations
(Act_Spec
)), Renaming_List
);
3131 Set_Visible_Declarations
(Act_Spec
, Renaming_List
);
3135 Make_Package_Declaration
(Loc
,
3136 Specification
=> Act_Spec
);
3138 -- Save the instantiation node, for subsequent instantiation of the
3139 -- body, if there is one and we are generating code for the current
3140 -- unit. Mark the unit as having a body, to avoid a premature error
3143 -- We instantiate the body if we are generating code, if we are
3144 -- generating cross-reference information, or if we are building
3145 -- trees for ASIS use.
3148 Enclosing_Body_Present
: Boolean := False;
3149 -- If the generic unit is not a compilation unit, then a body may
3150 -- be present in its parent even if none is required. We create a
3151 -- tentative pending instantiation for the body, which will be
3152 -- discarded if none is actually present.
3157 if Scope
(Gen_Unit
) /= Standard_Standard
3158 and then not Is_Child_Unit
(Gen_Unit
)
3160 Scop
:= Scope
(Gen_Unit
);
3162 while Present
(Scop
)
3163 and then Scop
/= Standard_Standard
3165 if Unit_Requires_Body
(Scop
) then
3166 Enclosing_Body_Present
:= True;
3169 elsif In_Open_Scopes
(Scop
)
3170 and then In_Package_Body
(Scop
)
3172 Enclosing_Body_Present
:= True;
3176 exit when Is_Compilation_Unit
(Scop
);
3177 Scop
:= Scope
(Scop
);
3181 -- If front-end inlining is enabled, and this is a unit for which
3182 -- code will be generated, we instantiate the body at once.
3184 -- This is done if the instance is not the main unit, and if the
3185 -- generic is not a child unit of another generic, to avoid scope
3186 -- problems and the reinstallation of parent instances.
3189 and then (not Is_Child_Unit
(Gen_Unit
)
3190 or else not Is_Generic_Unit
(Scope
(Gen_Unit
)))
3191 and then Might_Inline_Subp
3192 and then not Is_Actual_Pack
3194 if Front_End_Inlining
3195 and then (Is_In_Main_Unit
(N
)
3196 or else In_Main_Context
(Current_Scope
))
3197 and then Nkind
(Parent
(N
)) /= N_Compilation_Unit
3201 -- In configurable_run_time mode we force the inlining of
3202 -- predefined subprograms marked Inline_Always, to minimize
3203 -- the use of the run-time library.
3205 elsif Is_Predefined_File_Name
3206 (Unit_File_Name
(Get_Source_Unit
(Gen_Decl
)))
3207 and then Configurable_Run_Time_Mode
3208 and then Nkind
(Parent
(N
)) /= N_Compilation_Unit
3213 -- If the current scope is itself an instance within a child
3214 -- unit, there will be duplications in the scope stack, and the
3215 -- unstacking mechanism in Inline_Instance_Body will fail.
3216 -- This loses some rare cases of optimization, and might be
3217 -- improved some day, if we can find a proper abstraction for
3218 -- "the complete compilation context" that can be saved and
3221 if Is_Generic_Instance
(Current_Scope
) then
3223 Curr_Unit
: constant Entity_Id
:=
3224 Cunit_Entity
(Current_Sem_Unit
);
3226 if Curr_Unit
/= Current_Scope
3227 and then Is_Child_Unit
(Curr_Unit
)
3229 Inline_Now
:= False;
3236 (Unit_Requires_Body
(Gen_Unit
)
3237 or else Enclosing_Body_Present
3238 or else Present
(Corresponding_Body
(Gen_Decl
)))
3239 and then (Is_In_Main_Unit
(N
)
3240 or else Might_Inline_Subp
3241 or else CodePeer_Mode
)
3242 and then not Is_Actual_Pack
3243 and then not Inline_Now
3244 and then (Operating_Mode
= Generate_Code
3245 or else (Operating_Mode
= Check_Semantics
3246 and then ASIS_Mode
));
3248 -- If front_end_inlining is enabled, do not instantiate body if
3249 -- within a generic context.
3251 if (Front_End_Inlining
3252 and then not Expander_Active
)
3253 or else Is_Generic_Unit
(Cunit_Entity
(Main_Unit
))
3255 Needs_Body
:= False;
3258 -- If the current context is generic, and the package being
3259 -- instantiated is declared within a formal package, there is no
3260 -- body to instantiate until the enclosing generic is instantiated
3261 -- and there is an actual for the formal package. If the formal
3262 -- package has parameters, we build a regular package instance for
3263 -- it, that precedes the original formal package declaration.
3265 if In_Open_Scopes
(Scope
(Scope
(Gen_Unit
))) then
3267 Decl
: constant Node_Id
:=
3269 (Unit_Declaration_Node
(Scope
(Gen_Unit
)));
3271 if Nkind
(Decl
) = N_Formal_Package_Declaration
3272 or else (Nkind
(Decl
) = N_Package_Declaration
3273 and then Is_List_Member
(Decl
)
3274 and then Present
(Next
(Decl
))
3276 Nkind
(Next
(Decl
)) =
3277 N_Formal_Package_Declaration
)
3279 Needs_Body
:= False;
3285 -- If we are generating the calling stubs from the instantiation of
3286 -- a generic RCI package, we will not use the body of the generic
3289 if Distribution_Stub_Mode
= Generate_Caller_Stub_Body
3290 and then Is_Compilation_Unit
(Defining_Entity
(N
))
3292 Needs_Body
:= False;
3297 -- Here is a defence against a ludicrous number of instantiations
3298 -- caused by a circular set of instantiation attempts.
3300 if Pending_Instantiations
.Last
>
3301 Hostparm
.Max_Instantiations
3303 Error_Msg_N
("too many instantiations", N
);
3304 raise Unrecoverable_Error
;
3307 -- Indicate that the enclosing scopes contain an instantiation,
3308 -- and that cleanup actions should be delayed until after the
3309 -- instance body is expanded.
3311 Check_Forward_Instantiation
(Gen_Decl
);
3312 if Nkind
(N
) = N_Package_Instantiation
then
3314 Enclosing_Master
: Entity_Id
;
3317 -- Loop to search enclosing masters
3319 Enclosing_Master
:= Current_Scope
;
3320 Scope_Loop
: while Enclosing_Master
/= Standard_Standard
loop
3321 if Ekind
(Enclosing_Master
) = E_Package
then
3322 if Is_Compilation_Unit
(Enclosing_Master
) then
3323 if In_Package_Body
(Enclosing_Master
) then
3325 (Body_Entity
(Enclosing_Master
));
3334 Enclosing_Master
:= Scope
(Enclosing_Master
);
3337 elsif Ekind
(Enclosing_Master
) = E_Generic_Package
then
3338 Enclosing_Master
:= Scope
(Enclosing_Master
);
3340 elsif Is_Generic_Subprogram
(Enclosing_Master
)
3341 or else Ekind
(Enclosing_Master
) = E_Void
3343 -- Cleanup actions will eventually be performed on the
3344 -- enclosing instance, if any. Enclosing scope is void
3345 -- in the formal part of a generic subprogram.
3350 if Ekind
(Enclosing_Master
) = E_Entry
3352 Ekind
(Scope
(Enclosing_Master
)) = E_Protected_Type
3354 if not Expander_Active
then
3358 Protected_Body_Subprogram
(Enclosing_Master
);
3362 Set_Delay_Cleanups
(Enclosing_Master
);
3364 while Ekind
(Enclosing_Master
) = E_Block
loop
3365 Enclosing_Master
:= Scope
(Enclosing_Master
);
3368 if Is_Subprogram
(Enclosing_Master
) then
3369 Delay_Descriptors
(Enclosing_Master
);
3371 elsif Is_Task_Type
(Enclosing_Master
) then
3373 TBP
: constant Node_Id
:=
3374 Get_Task_Body_Procedure
3377 if Present
(TBP
) then
3378 Delay_Descriptors
(TBP
);
3379 Set_Delay_Cleanups
(TBP
);
3386 end loop Scope_Loop
;
3389 -- Make entry in table
3391 Pending_Instantiations
.Append
3393 Act_Decl
=> Act_Decl
,
3394 Expander_Status
=> Expander_Active
,
3395 Current_Sem_Unit
=> Current_Sem_Unit
,
3396 Scope_Suppress
=> Scope_Suppress
,
3397 Local_Suppress_Stack_Top
=> Local_Suppress_Stack_Top
,
3398 Version
=> Ada_Version
));
3402 Set_Categorization_From_Pragmas
(Act_Decl
);
3404 if Parent_Installed
then
3408 Set_Instance_Spec
(N
, Act_Decl
);
3410 -- If not a compilation unit, insert the package declaration before
3411 -- the original instantiation node.
3413 if Nkind
(Parent
(N
)) /= N_Compilation_Unit
then
3414 Mark_Rewrite_Insertion
(Act_Decl
);
3415 Insert_Before
(N
, Act_Decl
);
3418 -- For an instantiation that is a compilation unit, place declaration
3419 -- on current node so context is complete for analysis (including
3420 -- nested instantiations). If this is the main unit, the declaration
3421 -- eventually replaces the instantiation node. If the instance body
3422 -- is created later, it replaces the instance node, and the
3423 -- declaration is attached to it (see
3424 -- Build_Instance_Compilation_Unit_Nodes).
3427 if Cunit_Entity
(Current_Sem_Unit
) = Defining_Entity
(N
) then
3429 -- The entity for the current unit is the newly created one,
3430 -- and all semantic information is attached to it.
3432 Set_Cunit_Entity
(Current_Sem_Unit
, Act_Decl_Id
);
3434 -- If this is the main unit, replace the main entity as well
3436 if Current_Sem_Unit
= Main_Unit
then
3437 Main_Unit_Entity
:= Act_Decl_Id
;
3441 Set_Unit
(Parent
(N
), Act_Decl
);
3442 Set_Parent_Spec
(Act_Decl
, Parent_Spec
(N
));
3443 Set_Package_Instantiation
(Act_Decl_Id
, N
);
3445 Set_Unit
(Parent
(N
), N
);
3446 Set_Body_Required
(Parent
(N
), False);
3448 -- We never need elaboration checks on instantiations, since by
3449 -- definition, the body instantiation is elaborated at the same
3450 -- time as the spec instantiation.
3452 Set_Suppress_Elaboration_Warnings
(Act_Decl_Id
);
3453 Set_Kill_Elaboration_Checks
(Act_Decl_Id
);
3456 Check_Elab_Instantiation
(N
);
3458 if ABE_Is_Certain
(N
) and then Needs_Body
then
3459 Pending_Instantiations
.Decrement_Last
;
3462 Check_Hidden_Child_Unit
(N
, Gen_Unit
, Act_Decl_Id
);
3464 Set_First_Private_Entity
(Defining_Unit_Name
(Unit_Renaming
),
3465 First_Private_Entity
(Act_Decl_Id
));
3467 -- If the instantiation will receive a body, the unit will be
3468 -- transformed into a package body, and receive its own elaboration
3469 -- entity. Otherwise, the nature of the unit is now a package
3472 if Nkind
(Parent
(N
)) = N_Compilation_Unit
3473 and then not Needs_Body
3475 Rewrite
(N
, Act_Decl
);
3478 if Present
(Corresponding_Body
(Gen_Decl
))
3479 or else Unit_Requires_Body
(Gen_Unit
)
3481 Set_Has_Completion
(Act_Decl_Id
);
3484 Check_Formal_Packages
(Act_Decl_Id
);
3486 Restore_Private_Views
(Act_Decl_Id
);
3488 Inherit_Context
(Gen_Decl
, N
);
3490 if Parent_Installed
then
3495 Env_Installed
:= False;
3498 Validate_Categorization_Dependency
(N
, Act_Decl_Id
);
3500 -- There used to be a check here to prevent instantiations in local
3501 -- contexts if the No_Local_Allocators restriction was active. This
3502 -- check was removed by a binding interpretation in AI-95-00130/07,
3503 -- but we retain the code for documentation purposes.
3505 -- if Ekind (Act_Decl_Id) /= E_Void
3506 -- and then not Is_Library_Level_Entity (Act_Decl_Id)
3508 -- Check_Restriction (No_Local_Allocators, N);
3512 Inline_Instance_Body
(N
, Gen_Unit
, Act_Decl
);
3515 -- The following is a tree patch for ASIS: ASIS needs separate nodes to
3516 -- be used as defining identifiers for a formal package and for the
3517 -- corresponding expanded package.
3519 if Nkind
(N
) = N_Formal_Package_Declaration
then
3520 Act_Decl_Id
:= New_Copy
(Defining_Entity
(N
));
3521 Set_Comes_From_Source
(Act_Decl_Id
, True);
3522 Set_Is_Generic_Instance
(Act_Decl_Id
, False);
3523 Set_Defining_Identifier
(N
, Act_Decl_Id
);
3527 when Instantiation_Error
=>
3528 if Parent_Installed
then
3532 if Env_Installed
then
3535 end Analyze_Package_Instantiation
;
3537 --------------------------
3538 -- Inline_Instance_Body --
3539 --------------------------
3541 procedure Inline_Instance_Body
3543 Gen_Unit
: Entity_Id
;
3547 Gen_Comp
: constant Entity_Id
:=
3548 Cunit_Entity
(Get_Source_Unit
(Gen_Unit
));
3549 Curr_Comp
: constant Node_Id
:= Cunit
(Current_Sem_Unit
);
3550 Curr_Scope
: Entity_Id
:= Empty
;
3551 Curr_Unit
: constant Entity_Id
:=
3552 Cunit_Entity
(Current_Sem_Unit
);
3553 Removed
: Boolean := False;
3554 Num_Scopes
: Int
:= 0;
3556 Scope_Stack_Depth
: constant Int
:=
3557 Scope_Stack
.Last
- Scope_Stack
.First
+ 1;
3559 Use_Clauses
: array (1 .. Scope_Stack_Depth
) of Node_Id
;
3560 Instances
: array (1 .. Scope_Stack_Depth
) of Entity_Id
;
3561 Inner_Scopes
: array (1 .. Scope_Stack_Depth
) of Entity_Id
;
3562 Num_Inner
: Int
:= 0;
3563 N_Instances
: Int
:= 0;
3567 -- Case of generic unit defined in another unit. We must remove the
3568 -- complete context of the current unit to install that of the generic.
3570 if Gen_Comp
/= Cunit_Entity
(Current_Sem_Unit
) then
3572 -- Add some comments for the following two loops ???
3575 while Present
(S
) and then S
/= Standard_Standard
loop
3577 Num_Scopes
:= Num_Scopes
+ 1;
3579 Use_Clauses
(Num_Scopes
) :=
3581 (Scope_Stack
.Last
- Num_Scopes
+ 1).
3583 End_Use_Clauses
(Use_Clauses
(Num_Scopes
));
3585 exit when Scope_Stack
.Last
- Num_Scopes
+ 1 = Scope_Stack
.First
3586 or else Scope_Stack
.Table
3587 (Scope_Stack
.Last
- Num_Scopes
).Entity
3591 exit when Is_Generic_Instance
(S
)
3592 and then (In_Package_Body
(S
)
3593 or else Ekind
(S
) = E_Procedure
3594 or else Ekind
(S
) = E_Function
);
3598 Vis
:= Is_Immediately_Visible
(Gen_Comp
);
3600 -- Find and save all enclosing instances
3605 and then S
/= Standard_Standard
3607 if Is_Generic_Instance
(S
) then
3608 N_Instances
:= N_Instances
+ 1;
3609 Instances
(N_Instances
) := S
;
3611 exit when In_Package_Body
(S
);
3617 -- Remove context of current compilation unit, unless we are within a
3618 -- nested package instantiation, in which case the context has been
3619 -- removed previously.
3621 -- If current scope is the body of a child unit, remove context of
3622 -- spec as well. If an enclosing scope is an instance body, the
3623 -- context has already been removed, but the entities in the body
3624 -- must be made invisible as well.
3629 and then S
/= Standard_Standard
3631 if Is_Generic_Instance
(S
)
3632 and then (In_Package_Body
(S
)
3633 or else Ekind
(S
) = E_Procedure
3634 or else Ekind
(S
) = E_Function
)
3636 -- We still have to remove the entities of the enclosing
3637 -- instance from direct visibility.
3642 E
:= First_Entity
(S
);
3643 while Present
(E
) loop
3644 Set_Is_Immediately_Visible
(E
, False);
3653 or else (Ekind
(Curr_Unit
) = E_Package_Body
3654 and then S
= Spec_Entity
(Curr_Unit
))
3655 or else (Ekind
(Curr_Unit
) = E_Subprogram_Body
3658 (Unit_Declaration_Node
(Curr_Unit
)))
3662 -- Remove entities in current scopes from visibility, so that
3663 -- instance body is compiled in a clean environment.
3665 Save_Scope_Stack
(Handle_Use
=> False);
3667 if Is_Child_Unit
(S
) then
3669 -- Remove child unit from stack, as well as inner scopes.
3670 -- Removing the context of a child unit removes parent units
3673 while Current_Scope
/= S
loop
3674 Num_Inner
:= Num_Inner
+ 1;
3675 Inner_Scopes
(Num_Inner
) := Current_Scope
;
3680 Remove_Context
(Curr_Comp
);
3684 Remove_Context
(Curr_Comp
);
3687 if Ekind
(Curr_Unit
) = E_Package_Body
then
3688 Remove_Context
(Library_Unit
(Curr_Comp
));
3694 pragma Assert
(Num_Inner
< Num_Scopes
);
3696 Push_Scope
(Standard_Standard
);
3697 Scope_Stack
.Table
(Scope_Stack
.Last
).Is_Active_Stack_Base
:= True;
3698 Instantiate_Package_Body
3701 Act_Decl
=> Act_Decl
,
3702 Expander_Status
=> Expander_Active
,
3703 Current_Sem_Unit
=> Current_Sem_Unit
,
3704 Scope_Suppress
=> Scope_Suppress
,
3705 Local_Suppress_Stack_Top
=> Local_Suppress_Stack_Top
,
3706 Version
=> Ada_Version
)),
3707 Inlined_Body
=> True);
3713 Set_Is_Immediately_Visible
(Gen_Comp
, Vis
);
3715 -- Reset Generic_Instance flag so that use clauses can be installed
3716 -- in the proper order. (See Use_One_Package for effect of enclosing
3717 -- instances on processing of use clauses).
3719 for J
in 1 .. N_Instances
loop
3720 Set_Is_Generic_Instance
(Instances
(J
), False);
3724 Install_Context
(Curr_Comp
);
3726 if Present
(Curr_Scope
)
3727 and then Is_Child_Unit
(Curr_Scope
)
3729 Push_Scope
(Curr_Scope
);
3730 Set_Is_Immediately_Visible
(Curr_Scope
);
3732 -- Finally, restore inner scopes as well
3734 for J
in reverse 1 .. Num_Inner
loop
3735 Push_Scope
(Inner_Scopes
(J
));
3739 Restore_Scope_Stack
(Handle_Use
=> False);
3741 if Present
(Curr_Scope
)
3743 (In_Private_Part
(Curr_Scope
)
3744 or else In_Package_Body
(Curr_Scope
))
3746 -- Install private declaration of ancestor units, which are
3747 -- currently available. Restore_Scope_Stack and Install_Context
3748 -- only install the visible part of parents.
3753 Par
:= Scope
(Curr_Scope
);
3754 while (Present
(Par
))
3755 and then Par
/= Standard_Standard
3757 Install_Private_Declarations
(Par
);
3764 -- Restore use clauses. For a child unit, use clauses in the parents
3765 -- are restored when installing the context, so only those in inner
3766 -- scopes (and those local to the child unit itself) need to be
3767 -- installed explicitly.
3769 if Is_Child_Unit
(Curr_Unit
)
3772 for J
in reverse 1 .. Num_Inner
+ 1 loop
3773 Scope_Stack
.Table
(Scope_Stack
.Last
- J
+ 1).First_Use_Clause
:=
3775 Install_Use_Clauses
(Use_Clauses
(J
));
3779 for J
in reverse 1 .. Num_Scopes
loop
3780 Scope_Stack
.Table
(Scope_Stack
.Last
- J
+ 1).First_Use_Clause
:=
3782 Install_Use_Clauses
(Use_Clauses
(J
));
3786 -- Restore status of instances. If one of them is a body, make
3787 -- its local entities visible again.
3794 for J
in 1 .. N_Instances
loop
3795 Inst
:= Instances
(J
);
3796 Set_Is_Generic_Instance
(Inst
, True);
3798 if In_Package_Body
(Inst
)
3799 or else Ekind
(S
) = E_Procedure
3800 or else Ekind
(S
) = E_Function
3802 E
:= First_Entity
(Instances
(J
));
3803 while Present
(E
) loop
3804 Set_Is_Immediately_Visible
(E
);
3811 -- If generic unit is in current unit, current context is correct
3814 Instantiate_Package_Body
3817 Act_Decl
=> Act_Decl
,
3818 Expander_Status
=> Expander_Active
,
3819 Current_Sem_Unit
=> Current_Sem_Unit
,
3820 Scope_Suppress
=> Scope_Suppress
,
3821 Local_Suppress_Stack_Top
=> Local_Suppress_Stack_Top
,
3822 Version
=> Ada_Version
)),
3823 Inlined_Body
=> True);
3825 end Inline_Instance_Body
;
3827 -------------------------------------
3828 -- Analyze_Procedure_Instantiation --
3829 -------------------------------------
3831 procedure Analyze_Procedure_Instantiation
(N
: Node_Id
) is
3833 Analyze_Subprogram_Instantiation
(N
, E_Procedure
);
3834 end Analyze_Procedure_Instantiation
;
3836 -----------------------------------
3837 -- Need_Subprogram_Instance_Body --
3838 -----------------------------------
3840 function Need_Subprogram_Instance_Body
3842 Subp
: Entity_Id
) return Boolean
3845 if (Is_In_Main_Unit
(N
)
3846 or else Is_Inlined
(Subp
)
3847 or else Is_Inlined
(Alias
(Subp
)))
3848 and then (Operating_Mode
= Generate_Code
3849 or else (Operating_Mode
= Check_Semantics
3850 and then ASIS_Mode
))
3851 and then (Expander_Active
or else ASIS_Mode
)
3852 and then not ABE_Is_Certain
(N
)
3853 and then not Is_Eliminated
(Subp
)
3855 Pending_Instantiations
.Append
3857 Act_Decl
=> Unit_Declaration_Node
(Subp
),
3858 Expander_Status
=> Expander_Active
,
3859 Current_Sem_Unit
=> Current_Sem_Unit
,
3860 Scope_Suppress
=> Scope_Suppress
,
3861 Local_Suppress_Stack_Top
=> Local_Suppress_Stack_Top
,
3862 Version
=> Ada_Version
));
3867 end Need_Subprogram_Instance_Body
;
3869 --------------------------------------
3870 -- Analyze_Subprogram_Instantiation --
3871 --------------------------------------
3873 procedure Analyze_Subprogram_Instantiation
3877 Loc
: constant Source_Ptr
:= Sloc
(N
);
3878 Gen_Id
: constant Node_Id
:= Name
(N
);
3880 Anon_Id
: constant Entity_Id
:=
3881 Make_Defining_Identifier
(Sloc
(Defining_Entity
(N
)),
3882 Chars
=> New_External_Name
3883 (Chars
(Defining_Entity
(N
)), 'R'));
3885 Act_Decl_Id
: Entity_Id
;
3890 Env_Installed
: Boolean := False;
3891 Gen_Unit
: Entity_Id
;
3893 Pack_Id
: Entity_Id
;
3894 Parent_Installed
: Boolean := False;
3895 Renaming_List
: List_Id
;
3897 procedure Analyze_Instance_And_Renamings
;
3898 -- The instance must be analyzed in a context that includes the mappings
3899 -- of generic parameters into actuals. We create a package declaration
3900 -- for this purpose, and a subprogram with an internal name within the
3901 -- package. The subprogram instance is simply an alias for the internal
3902 -- subprogram, declared in the current scope.
3904 ------------------------------------
3905 -- Analyze_Instance_And_Renamings --
3906 ------------------------------------
3908 procedure Analyze_Instance_And_Renamings
is
3909 Def_Ent
: constant Entity_Id
:= Defining_Entity
(N
);
3910 Pack_Decl
: Node_Id
;
3913 if Nkind
(Parent
(N
)) = N_Compilation_Unit
then
3915 -- For the case of a compilation unit, the container package has
3916 -- the same name as the instantiation, to insure that the binder
3917 -- calls the elaboration procedure with the right name. Copy the
3918 -- entity of the instance, which may have compilation level flags
3919 -- (e.g. Is_Child_Unit) set.
3921 Pack_Id
:= New_Copy
(Def_Ent
);
3924 -- Otherwise we use the name of the instantiation concatenated
3925 -- with its source position to ensure uniqueness if there are
3926 -- several instantiations with the same name.
3929 Make_Defining_Identifier
(Loc
,
3930 Chars
=> New_External_Name
3931 (Related_Id
=> Chars
(Def_Ent
),
3933 Suffix_Index
=> Source_Offset
(Sloc
(Def_Ent
))));
3936 Pack_Decl
:= Make_Package_Declaration
(Loc
,
3937 Specification
=> Make_Package_Specification
(Loc
,
3938 Defining_Unit_Name
=> Pack_Id
,
3939 Visible_Declarations
=> Renaming_List
,
3940 End_Label
=> Empty
));
3942 Set_Instance_Spec
(N
, Pack_Decl
);
3943 Set_Is_Generic_Instance
(Pack_Id
);
3944 Set_Debug_Info_Needed
(Pack_Id
);
3946 -- Case of not a compilation unit
3948 if Nkind
(Parent
(N
)) /= N_Compilation_Unit
then
3949 Mark_Rewrite_Insertion
(Pack_Decl
);
3950 Insert_Before
(N
, Pack_Decl
);
3951 Set_Has_Completion
(Pack_Id
);
3953 -- Case of an instantiation that is a compilation unit
3955 -- Place declaration on current node so context is complete for
3956 -- analysis (including nested instantiations), and for use in a
3957 -- context_clause (see Analyze_With_Clause).
3960 Set_Unit
(Parent
(N
), Pack_Decl
);
3961 Set_Parent_Spec
(Pack_Decl
, Parent_Spec
(N
));
3964 Analyze
(Pack_Decl
);
3965 Check_Formal_Packages
(Pack_Id
);
3966 Set_Is_Generic_Instance
(Pack_Id
, False);
3968 -- Body of the enclosing package is supplied when instantiating the
3969 -- subprogram body, after semantic analysis is completed.
3971 if Nkind
(Parent
(N
)) = N_Compilation_Unit
then
3973 -- Remove package itself from visibility, so it does not
3974 -- conflict with subprogram.
3976 Set_Name_Entity_Id
(Chars
(Pack_Id
), Homonym
(Pack_Id
));
3978 -- Set name and scope of internal subprogram so that the proper
3979 -- external name will be generated. The proper scope is the scope
3980 -- of the wrapper package. We need to generate debugging info for
3981 -- the internal subprogram, so set flag accordingly.
3983 Set_Chars
(Anon_Id
, Chars
(Defining_Entity
(N
)));
3984 Set_Scope
(Anon_Id
, Scope
(Pack_Id
));
3986 -- Mark wrapper package as referenced, to avoid spurious warnings
3987 -- if the instantiation appears in various with_ clauses of
3988 -- subunits of the main unit.
3990 Set_Referenced
(Pack_Id
);
3993 Set_Is_Generic_Instance
(Anon_Id
);
3994 Set_Debug_Info_Needed
(Anon_Id
);
3995 Act_Decl_Id
:= New_Copy
(Anon_Id
);
3997 Set_Parent
(Act_Decl_Id
, Parent
(Anon_Id
));
3998 Set_Chars
(Act_Decl_Id
, Chars
(Defining_Entity
(N
)));
3999 Set_Sloc
(Act_Decl_Id
, Sloc
(Defining_Entity
(N
)));
4000 Set_Comes_From_Source
(Act_Decl_Id
, True);
4002 -- The signature may involve types that are not frozen yet, but the
4003 -- subprogram will be frozen at the point the wrapper package is
4004 -- frozen, so it does not need its own freeze node. In fact, if one
4005 -- is created, it might conflict with the freezing actions from the
4008 Set_Has_Delayed_Freeze
(Anon_Id
, False);
4010 -- If the instance is a child unit, mark the Id accordingly. Mark
4011 -- the anonymous entity as well, which is the real subprogram and
4012 -- which is used when the instance appears in a context clause.
4013 -- Similarly, propagate the Is_Eliminated flag to handle properly
4014 -- nested eliminated subprograms.
4016 Set_Is_Child_Unit
(Act_Decl_Id
, Is_Child_Unit
(Defining_Entity
(N
)));
4017 Set_Is_Child_Unit
(Anon_Id
, Is_Child_Unit
(Defining_Entity
(N
)));
4018 New_Overloaded_Entity
(Act_Decl_Id
);
4019 Check_Eliminated
(Act_Decl_Id
);
4020 Set_Is_Eliminated
(Anon_Id
, Is_Eliminated
(Act_Decl_Id
));
4022 -- In compilation unit case, kill elaboration checks on the
4023 -- instantiation, since they are never needed -- the body is
4024 -- instantiated at the same point as the spec.
4026 if Nkind
(Parent
(N
)) = N_Compilation_Unit
then
4027 Set_Suppress_Elaboration_Warnings
(Act_Decl_Id
);
4028 Set_Kill_Elaboration_Checks
(Act_Decl_Id
);
4029 Set_Is_Compilation_Unit
(Anon_Id
);
4031 Set_Cunit_Entity
(Current_Sem_Unit
, Pack_Id
);
4034 -- The instance is not a freezing point for the new subprogram
4036 Set_Is_Frozen
(Act_Decl_Id
, False);
4038 if Nkind
(Defining_Entity
(N
)) = N_Defining_Operator_Symbol
then
4039 Valid_Operator_Definition
(Act_Decl_Id
);
4042 Set_Alias
(Act_Decl_Id
, Anon_Id
);
4043 Set_Parent
(Act_Decl_Id
, Parent
(Anon_Id
));
4044 Set_Has_Completion
(Act_Decl_Id
);
4045 Set_Related_Instance
(Pack_Id
, Act_Decl_Id
);
4047 if Nkind
(Parent
(N
)) = N_Compilation_Unit
then
4048 Set_Body_Required
(Parent
(N
), False);
4050 end Analyze_Instance_And_Renamings
;
4052 -- Start of processing for Analyze_Subprogram_Instantiation
4055 -- Very first thing: apply the special kludge for Text_IO processing
4056 -- in case we are instantiating one of the children of [Wide_]Text_IO.
4057 -- Of course such an instantiation is bogus (these are packages, not
4058 -- subprograms), but we get a better error message if we do this.
4060 Text_IO_Kludge
(Gen_Id
);
4062 -- Make node global for error reporting
4064 Instantiation_Node
:= N
;
4065 Preanalyze_Actuals
(N
);
4068 Env_Installed
:= True;
4069 Check_Generic_Child_Unit
(Gen_Id
, Parent_Installed
);
4070 Gen_Unit
:= Entity
(Gen_Id
);
4072 Generate_Reference
(Gen_Unit
, Gen_Id
);
4074 if Nkind
(Gen_Id
) = N_Identifier
4075 and then Chars
(Gen_Unit
) = Chars
(Defining_Entity
(N
))
4078 ("& is hidden within declaration of instance", Gen_Id
, Gen_Unit
);
4081 if Etype
(Gen_Unit
) = Any_Type
then
4086 -- Verify that it is a generic subprogram of the right kind, and that
4087 -- it does not lead to a circular instantiation.
4089 if not Ekind_In
(Gen_Unit
, E_Generic_Procedure
, E_Generic_Function
) then
4090 Error_Msg_N
("expect generic subprogram in instantiation", Gen_Id
);
4092 elsif In_Open_Scopes
(Gen_Unit
) then
4093 Error_Msg_NE
("instantiation of & within itself", N
, Gen_Unit
);
4095 elsif K
= E_Procedure
4096 and then Ekind
(Gen_Unit
) /= E_Generic_Procedure
4098 if Ekind
(Gen_Unit
) = E_Generic_Function
then
4100 ("cannot instantiate generic function as procedure", Gen_Id
);
4103 ("expect name of generic procedure in instantiation", Gen_Id
);
4106 elsif K
= E_Function
4107 and then Ekind
(Gen_Unit
) /= E_Generic_Function
4109 if Ekind
(Gen_Unit
) = E_Generic_Procedure
then
4111 ("cannot instantiate generic procedure as function", Gen_Id
);
4114 ("expect name of generic function in instantiation", Gen_Id
);
4118 Set_Entity
(Gen_Id
, Gen_Unit
);
4119 Set_Is_Instantiated
(Gen_Unit
);
4121 if In_Extended_Main_Source_Unit
(N
) then
4122 Generate_Reference
(Gen_Unit
, N
);
4125 -- If renaming, get original unit
4127 if Present
(Renamed_Object
(Gen_Unit
))
4128 and then (Ekind
(Renamed_Object
(Gen_Unit
)) = E_Generic_Procedure
4130 Ekind
(Renamed_Object
(Gen_Unit
)) = E_Generic_Function
)
4132 Gen_Unit
:= Renamed_Object
(Gen_Unit
);
4133 Set_Is_Instantiated
(Gen_Unit
);
4134 Generate_Reference
(Gen_Unit
, N
);
4137 if Contains_Instance_Of
(Gen_Unit
, Current_Scope
, Gen_Id
) then
4138 Error_Msg_Node_2
:= Current_Scope
;
4140 ("circular Instantiation: & instantiated in &!", N
, Gen_Unit
);
4141 Circularity_Detected
:= True;
4145 Gen_Decl
:= Unit_Declaration_Node
(Gen_Unit
);
4147 -- Initialize renamings map, for error checking
4149 Generic_Renamings
.Set_Last
(0);
4150 Generic_Renamings_HTable
.Reset
;
4152 Create_Instantiation_Source
(N
, Gen_Unit
, False, S_Adjustment
);
4154 -- Copy original generic tree, to produce text for instantiation
4158 (Original_Node
(Gen_Decl
), Empty
, Instantiating
=> True);
4160 -- Inherit overriding indicator from instance node
4162 Act_Spec
:= Specification
(Act_Tree
);
4163 Set_Must_Override
(Act_Spec
, Must_Override
(N
));
4164 Set_Must_Not_Override
(Act_Spec
, Must_Not_Override
(N
));
4167 Analyze_Associations
4169 Generic_Formal_Declarations
(Act_Tree
),
4170 Generic_Formal_Declarations
(Gen_Decl
));
4172 -- The subprogram itself cannot contain a nested instance, so the
4173 -- current parent is left empty.
4175 Set_Instance_Env
(Gen_Unit
, Empty
);
4177 -- Build the subprogram declaration, which does not appear in the
4178 -- generic template, and give it a sloc consistent with that of the
4181 Set_Defining_Unit_Name
(Act_Spec
, Anon_Id
);
4182 Set_Generic_Parent
(Act_Spec
, Gen_Unit
);
4184 Make_Subprogram_Declaration
(Sloc
(Act_Spec
),
4185 Specification
=> Act_Spec
);
4187 Set_Categorization_From_Pragmas
(Act_Decl
);
4189 if Parent_Installed
then
4193 Append
(Act_Decl
, Renaming_List
);
4194 Analyze_Instance_And_Renamings
;
4196 -- If the generic is marked Import (Intrinsic), then so is the
4197 -- instance. This indicates that there is no body to instantiate. If
4198 -- generic is marked inline, so it the instance, and the anonymous
4199 -- subprogram it renames. If inlined, or else if inlining is enabled
4200 -- for the compilation, we generate the instance body even if it is
4201 -- not within the main unit.
4203 -- Any other pragmas might also be inherited ???
4205 if Is_Intrinsic_Subprogram
(Gen_Unit
) then
4206 Set_Is_Intrinsic_Subprogram
(Anon_Id
);
4207 Set_Is_Intrinsic_Subprogram
(Act_Decl_Id
);
4209 if Chars
(Gen_Unit
) = Name_Unchecked_Conversion
then
4210 Validate_Unchecked_Conversion
(N
, Act_Decl_Id
);
4214 Generate_Definition
(Act_Decl_Id
);
4216 Set_Is_Inlined
(Act_Decl_Id
, Is_Inlined
(Gen_Unit
));
4217 Set_Is_Inlined
(Anon_Id
, Is_Inlined
(Gen_Unit
));
4219 if not Is_Intrinsic_Subprogram
(Gen_Unit
) then
4220 Check_Elab_Instantiation
(N
);
4223 if Is_Dispatching_Operation
(Act_Decl_Id
)
4224 and then Ada_Version
>= Ada_05
4230 Formal
:= First_Formal
(Act_Decl_Id
);
4231 while Present
(Formal
) loop
4232 if Ekind
(Etype
(Formal
)) = E_Anonymous_Access_Type
4233 and then Is_Controlling_Formal
(Formal
)
4234 and then not Can_Never_Be_Null
(Formal
)
4236 Error_Msg_NE
("access parameter& is controlling,",
4239 ("\corresponding parameter of & must be"
4240 & " explicitly null-excluding", N
, Gen_Id
);
4243 Next_Formal
(Formal
);
4248 Check_Hidden_Child_Unit
(N
, Gen_Unit
, Act_Decl_Id
);
4250 -- Subject to change, pending on if other pragmas are inherited ???
4252 Validate_Categorization_Dependency
(N
, Act_Decl_Id
);
4254 if not Is_Intrinsic_Subprogram
(Act_Decl_Id
) then
4255 Inherit_Context
(Gen_Decl
, N
);
4257 Restore_Private_Views
(Pack_Id
, False);
4259 -- If the context requires a full instantiation, mark node for
4260 -- subsequent construction of the body.
4262 if Need_Subprogram_Instance_Body
(N
, Act_Decl_Id
) then
4264 Check_Forward_Instantiation
(Gen_Decl
);
4266 -- The wrapper package is always delayed, because it does not
4267 -- constitute a freeze point, but to insure that the freeze
4268 -- node is placed properly, it is created directly when
4269 -- instantiating the body (otherwise the freeze node might
4270 -- appear to early for nested instantiations).
4272 elsif Nkind
(Parent
(N
)) = N_Compilation_Unit
then
4274 -- For ASIS purposes, indicate that the wrapper package has
4275 -- replaced the instantiation node.
4277 Rewrite
(N
, Unit
(Parent
(N
)));
4278 Set_Unit
(Parent
(N
), N
);
4281 elsif Nkind
(Parent
(N
)) = N_Compilation_Unit
then
4283 -- Replace instance node for library-level instantiations of
4284 -- intrinsic subprograms, for ASIS use.
4286 Rewrite
(N
, Unit
(Parent
(N
)));
4287 Set_Unit
(Parent
(N
), N
);
4290 if Parent_Installed
then
4295 Env_Installed
:= False;
4296 Generic_Renamings
.Set_Last
(0);
4297 Generic_Renamings_HTable
.Reset
;
4301 when Instantiation_Error
=>
4302 if Parent_Installed
then
4306 if Env_Installed
then
4309 end Analyze_Subprogram_Instantiation
;
4311 -------------------------
4312 -- Get_Associated_Node --
4313 -------------------------
4315 function Get_Associated_Node
(N
: Node_Id
) return Node_Id
is
4319 Assoc
:= Associated_Node
(N
);
4321 if Nkind
(Assoc
) /= Nkind
(N
) then
4324 elsif Nkind_In
(Assoc
, N_Aggregate
, N_Extension_Aggregate
) then
4328 -- If the node is part of an inner generic, it may itself have been
4329 -- remapped into a further generic copy. Associated_Node is otherwise
4330 -- used for the entity of the node, and will be of a different node
4331 -- kind, or else N has been rewritten as a literal or function call.
4333 while Present
(Associated_Node
(Assoc
))
4334 and then Nkind
(Associated_Node
(Assoc
)) = Nkind
(Assoc
)
4336 Assoc
:= Associated_Node
(Assoc
);
4339 -- Follow and additional link in case the final node was rewritten.
4340 -- This can only happen with nested generic units.
4342 if (Nkind
(Assoc
) = N_Identifier
or else Nkind
(Assoc
) in N_Op
)
4343 and then Present
(Associated_Node
(Assoc
))
4344 and then (Nkind_In
(Associated_Node
(Assoc
), N_Function_Call
,
4345 N_Explicit_Dereference
,
4350 Assoc
:= Associated_Node
(Assoc
);
4355 end Get_Associated_Node
;
4357 -------------------------------------------
4358 -- Build_Instance_Compilation_Unit_Nodes --
4359 -------------------------------------------
4361 procedure Build_Instance_Compilation_Unit_Nodes
4366 Decl_Cunit
: Node_Id
;
4367 Body_Cunit
: Node_Id
;
4369 New_Main
: constant Entity_Id
:= Defining_Entity
(Act_Decl
);
4370 Old_Main
: constant Entity_Id
:= Cunit_Entity
(Main_Unit
);
4373 -- A new compilation unit node is built for the instance declaration
4376 Make_Compilation_Unit
(Sloc
(N
),
4377 Context_Items
=> Empty_List
,
4380 Make_Compilation_Unit_Aux
(Sloc
(N
)));
4382 Set_Parent_Spec
(Act_Decl
, Parent_Spec
(N
));
4384 -- The new compilation unit is linked to its body, but both share the
4385 -- same file, so we do not set Body_Required on the new unit so as not
4386 -- to create a spurious dependency on a non-existent body in the ali.
4387 -- This simplifies CodePeer unit traversal.
4389 -- We use the original instantiation compilation unit as the resulting
4390 -- compilation unit of the instance, since this is the main unit.
4392 Rewrite
(N
, Act_Body
);
4393 Body_Cunit
:= Parent
(N
);
4395 -- The two compilation unit nodes are linked by the Library_Unit field
4397 Set_Library_Unit
(Decl_Cunit
, Body_Cunit
);
4398 Set_Library_Unit
(Body_Cunit
, Decl_Cunit
);
4400 -- Preserve the private nature of the package if needed
4402 Set_Private_Present
(Decl_Cunit
, Private_Present
(Body_Cunit
));
4404 -- If the instance is not the main unit, its context, categorization
4405 -- and elaboration entity are not relevant to the compilation.
4407 if Body_Cunit
/= Cunit
(Main_Unit
) then
4408 Make_Instance_Unit
(Body_Cunit
, In_Main
=> False);
4412 -- The context clause items on the instantiation, which are now attached
4413 -- to the body compilation unit (since the body overwrote the original
4414 -- instantiation node), semantically belong on the spec, so copy them
4415 -- there. It's harmless to leave them on the body as well. In fact one
4416 -- could argue that they belong in both places.
4418 Citem
:= First
(Context_Items
(Body_Cunit
));
4419 while Present
(Citem
) loop
4420 Append
(New_Copy
(Citem
), Context_Items
(Decl_Cunit
));
4424 -- Propagate categorization flags on packages, so that they appear in
4425 -- the ali file for the spec of the unit.
4427 if Ekind
(New_Main
) = E_Package
then
4428 Set_Is_Pure
(Old_Main
, Is_Pure
(New_Main
));
4429 Set_Is_Preelaborated
(Old_Main
, Is_Preelaborated
(New_Main
));
4430 Set_Is_Remote_Types
(Old_Main
, Is_Remote_Types
(New_Main
));
4431 Set_Is_Shared_Passive
(Old_Main
, Is_Shared_Passive
(New_Main
));
4432 Set_Is_Remote_Call_Interface
4433 (Old_Main
, Is_Remote_Call_Interface
(New_Main
));
4436 -- Make entry in Units table, so that binder can generate call to
4437 -- elaboration procedure for body, if any.
4439 Make_Instance_Unit
(Body_Cunit
, In_Main
=> True);
4440 Main_Unit_Entity
:= New_Main
;
4441 Set_Cunit_Entity
(Main_Unit
, Main_Unit_Entity
);
4443 -- Build elaboration entity, since the instance may certainly generate
4444 -- elaboration code requiring a flag for protection.
4446 Build_Elaboration_Entity
(Decl_Cunit
, New_Main
);
4447 end Build_Instance_Compilation_Unit_Nodes
;
4449 -----------------------------
4450 -- Check_Access_Definition --
4451 -----------------------------
4453 procedure Check_Access_Definition
(N
: Node_Id
) is
4456 (Ada_Version
>= Ada_05
4457 and then Present
(Access_Definition
(N
)));
4459 end Check_Access_Definition
;
4461 -----------------------------------
4462 -- Check_Formal_Package_Instance --
4463 -----------------------------------
4465 -- If the formal has specific parameters, they must match those of the
4466 -- actual. Both of them are instances, and the renaming declarations for
4467 -- their formal parameters appear in the same order in both. The analyzed
4468 -- formal has been analyzed in the context of the current instance.
4470 procedure Check_Formal_Package_Instance
4471 (Formal_Pack
: Entity_Id
;
4472 Actual_Pack
: Entity_Id
)
4474 E1
: Entity_Id
:= First_Entity
(Actual_Pack
);
4475 E2
: Entity_Id
:= First_Entity
(Formal_Pack
);
4480 procedure Check_Mismatch
(B
: Boolean);
4481 -- Common error routine for mismatch between the parameters of the
4482 -- actual instance and those of the formal package.
4484 function Same_Instantiated_Constant
(E1
, E2
: Entity_Id
) return Boolean;
4485 -- The formal may come from a nested formal package, and the actual may
4486 -- have been constant-folded. To determine whether the two denote the
4487 -- same entity we may have to traverse several definitions to recover
4488 -- the ultimate entity that they refer to.
4490 function Same_Instantiated_Variable
(E1
, E2
: Entity_Id
) return Boolean;
4491 -- Similarly, if the formal comes from a nested formal package, the
4492 -- actual may designate the formal through multiple renamings, which
4493 -- have to be followed to determine the original variable in question.
4495 --------------------
4496 -- Check_Mismatch --
4497 --------------------
4499 procedure Check_Mismatch
(B
: Boolean) is
4500 Kind
: constant Node_Kind
:= Nkind
(Parent
(E2
));
4503 if Kind
= N_Formal_Type_Declaration
then
4506 elsif Nkind_In
(Kind
, N_Formal_Object_Declaration
,
4507 N_Formal_Package_Declaration
)
4508 or else Kind
in N_Formal_Subprogram_Declaration
4514 ("actual for & in actual instance does not match formal",
4515 Parent
(Actual_Pack
), E1
);
4519 --------------------------------
4520 -- Same_Instantiated_Constant --
4521 --------------------------------
4523 function Same_Instantiated_Constant
4524 (E1
, E2
: Entity_Id
) return Boolean
4530 while Present
(Ent
) loop
4534 elsif Ekind
(Ent
) /= E_Constant
then
4537 elsif Is_Entity_Name
(Constant_Value
(Ent
)) then
4538 if Entity
(Constant_Value
(Ent
)) = E1
then
4541 Ent
:= Entity
(Constant_Value
(Ent
));
4544 -- The actual may be a constant that has been folded. Recover
4547 elsif Is_Entity_Name
(Original_Node
(Constant_Value
(Ent
))) then
4548 Ent
:= Entity
(Original_Node
(Constant_Value
(Ent
)));
4555 end Same_Instantiated_Constant
;
4557 --------------------------------
4558 -- Same_Instantiated_Variable --
4559 --------------------------------
4561 function Same_Instantiated_Variable
4562 (E1
, E2
: Entity_Id
) return Boolean
4564 function Original_Entity
(E
: Entity_Id
) return Entity_Id
;
4565 -- Follow chain of renamings to the ultimate ancestor
4567 ---------------------
4568 -- Original_Entity --
4569 ---------------------
4571 function Original_Entity
(E
: Entity_Id
) return Entity_Id
is
4576 while Nkind
(Parent
(Orig
)) = N_Object_Renaming_Declaration
4577 and then Present
(Renamed_Object
(Orig
))
4578 and then Is_Entity_Name
(Renamed_Object
(Orig
))
4580 Orig
:= Entity
(Renamed_Object
(Orig
));
4584 end Original_Entity
;
4586 -- Start of processing for Same_Instantiated_Variable
4589 return Ekind
(E1
) = Ekind
(E2
)
4590 and then Original_Entity
(E1
) = Original_Entity
(E2
);
4591 end Same_Instantiated_Variable
;
4593 -- Start of processing for Check_Formal_Package_Instance
4597 and then Present
(E2
)
4599 exit when Ekind
(E1
) = E_Package
4600 and then Renamed_Entity
(E1
) = Renamed_Entity
(Actual_Pack
);
4602 -- If the formal is the renaming of the formal package, this
4603 -- is the end of its formal part, which may occur before the
4604 -- end of the formal part in the actual in the presence of
4605 -- defaulted parameters in the formal package.
4607 exit when Nkind
(Parent
(E2
)) = N_Package_Renaming_Declaration
4608 and then Renamed_Entity
(E2
) = Scope
(E2
);
4610 -- The analysis of the actual may generate additional internal
4611 -- entities. If the formal is defaulted, there is no corresponding
4612 -- analysis and the internal entities must be skipped, until we
4613 -- find corresponding entities again.
4615 if Comes_From_Source
(E2
)
4616 and then not Comes_From_Source
(E1
)
4617 and then Chars
(E1
) /= Chars
(E2
)
4620 and then Chars
(E1
) /= Chars
(E2
)
4629 -- If the formal entity comes from a formal declaration, it was
4630 -- defaulted in the formal package, and no check is needed on it.
4632 elsif Nkind
(Parent
(E2
)) = N_Formal_Object_Declaration
then
4635 elsif Is_Type
(E1
) then
4637 -- Subtypes must statically match. E1, E2 are the local entities
4638 -- that are subtypes of the actuals. Itypes generated for other
4639 -- parameters need not be checked, the check will be performed
4640 -- on the parameters themselves.
4642 -- If E2 is a formal type declaration, it is a defaulted parameter
4643 -- and needs no checking.
4645 if not Is_Itype
(E1
)
4646 and then not Is_Itype
(E2
)
4650 or else Etype
(E1
) /= Etype
(E2
)
4651 or else not Subtypes_Statically_Match
(E1
, E2
));
4654 elsif Ekind
(E1
) = E_Constant
then
4656 -- IN parameters must denote the same static value, or the same
4657 -- constant, or the literal null.
4659 Expr1
:= Expression
(Parent
(E1
));
4661 if Ekind
(E2
) /= E_Constant
then
4662 Check_Mismatch
(True);
4665 Expr2
:= Expression
(Parent
(E2
));
4668 if Is_Static_Expression
(Expr1
) then
4670 if not Is_Static_Expression
(Expr2
) then
4671 Check_Mismatch
(True);
4673 elsif Is_Discrete_Type
(Etype
(E1
)) then
4675 V1
: constant Uint
:= Expr_Value
(Expr1
);
4676 V2
: constant Uint
:= Expr_Value
(Expr2
);
4678 Check_Mismatch
(V1
/= V2
);
4681 elsif Is_Real_Type
(Etype
(E1
)) then
4683 V1
: constant Ureal
:= Expr_Value_R
(Expr1
);
4684 V2
: constant Ureal
:= Expr_Value_R
(Expr2
);
4686 Check_Mismatch
(V1
/= V2
);
4689 elsif Is_String_Type
(Etype
(E1
))
4690 and then Nkind
(Expr1
) = N_String_Literal
4692 if Nkind
(Expr2
) /= N_String_Literal
then
4693 Check_Mismatch
(True);
4696 (not String_Equal
(Strval
(Expr1
), Strval
(Expr2
)));
4700 elsif Is_Entity_Name
(Expr1
) then
4701 if Is_Entity_Name
(Expr2
) then
4702 if Entity
(Expr1
) = Entity
(Expr2
) then
4706 (not Same_Instantiated_Constant
4707 (Entity
(Expr1
), Entity
(Expr2
)));
4710 Check_Mismatch
(True);
4713 elsif Is_Entity_Name
(Original_Node
(Expr1
))
4714 and then Is_Entity_Name
(Expr2
)
4716 Same_Instantiated_Constant
4717 (Entity
(Original_Node
(Expr1
)), Entity
(Expr2
))
4721 elsif Nkind
(Expr1
) = N_Null
then
4722 Check_Mismatch
(Nkind
(Expr1
) /= N_Null
);
4725 Check_Mismatch
(True);
4728 elsif Ekind
(E1
) = E_Variable
then
4729 Check_Mismatch
(not Same_Instantiated_Variable
(E1
, E2
));
4731 elsif Ekind
(E1
) = E_Package
then
4733 (Ekind
(E1
) /= Ekind
(E2
)
4734 or else Renamed_Object
(E1
) /= Renamed_Object
(E2
));
4736 elsif Is_Overloadable
(E1
) then
4738 -- Verify that the actual subprograms match. Note that actuals
4739 -- that are attributes are rewritten as subprograms. If the
4740 -- subprogram in the formal package is defaulted, no check is
4741 -- needed. Note that this can only happen in Ada 2005 when the
4742 -- formal package can be partially parametrized.
4744 if Nkind
(Unit_Declaration_Node
(E1
)) =
4745 N_Subprogram_Renaming_Declaration
4746 and then From_Default
(Unit_Declaration_Node
(E1
))
4752 (Ekind
(E2
) /= Ekind
(E1
) or else (Alias
(E1
)) /= Alias
(E2
));
4756 raise Program_Error
;
4763 end Check_Formal_Package_Instance
;
4765 ---------------------------
4766 -- Check_Formal_Packages --
4767 ---------------------------
4769 procedure Check_Formal_Packages
(P_Id
: Entity_Id
) is
4771 Formal_P
: Entity_Id
;
4774 -- Iterate through the declarations in the instance, looking for package
4775 -- renaming declarations that denote instances of formal packages. Stop
4776 -- when we find the renaming of the current package itself. The
4777 -- declaration for a formal package without a box is followed by an
4778 -- internal entity that repeats the instantiation.
4780 E
:= First_Entity
(P_Id
);
4781 while Present
(E
) loop
4782 if Ekind
(E
) = E_Package
then
4783 if Renamed_Object
(E
) = P_Id
then
4786 elsif Nkind
(Parent
(E
)) /= N_Package_Renaming_Declaration
then
4789 elsif not Box_Present
(Parent
(Associated_Formal_Package
(E
))) then
4790 Formal_P
:= Next_Entity
(E
);
4791 Check_Formal_Package_Instance
(Formal_P
, E
);
4793 -- After checking, remove the internal validating package. It
4794 -- is only needed for semantic checks, and as it may contain
4795 -- generic formal declarations it should not reach gigi.
4797 Remove
(Unit_Declaration_Node
(Formal_P
));
4803 end Check_Formal_Packages
;
4805 ---------------------------------
4806 -- Check_Forward_Instantiation --
4807 ---------------------------------
4809 procedure Check_Forward_Instantiation
(Decl
: Node_Id
) is
4811 Gen_Comp
: Entity_Id
:= Cunit_Entity
(Get_Source_Unit
(Decl
));
4814 -- The instantiation appears before the generic body if we are in the
4815 -- scope of the unit containing the generic, either in its spec or in
4816 -- the package body, and before the generic body.
4818 if Ekind
(Gen_Comp
) = E_Package_Body
then
4819 Gen_Comp
:= Spec_Entity
(Gen_Comp
);
4822 if In_Open_Scopes
(Gen_Comp
)
4823 and then No
(Corresponding_Body
(Decl
))
4828 and then not Is_Compilation_Unit
(S
)
4829 and then not Is_Child_Unit
(S
)
4831 if Ekind
(S
) = E_Package
then
4832 Set_Has_Forward_Instantiation
(S
);
4838 end Check_Forward_Instantiation
;
4840 ---------------------------
4841 -- Check_Generic_Actuals --
4842 ---------------------------
4844 -- The visibility of the actuals may be different between the point of
4845 -- generic instantiation and the instantiation of the body.
4847 procedure Check_Generic_Actuals
4848 (Instance
: Entity_Id
;
4849 Is_Formal_Box
: Boolean)
4854 function Denotes_Previous_Actual
(Typ
: Entity_Id
) return Boolean;
4855 -- For a formal that is an array type, the component type is often a
4856 -- previous formal in the same unit. The privacy status of the component
4857 -- type will have been examined earlier in the traversal of the
4858 -- corresponding actuals, and this status should not be modified for the
4859 -- array type itself.
4861 -- To detect this case we have to rescan the list of formals, which
4862 -- is usually short enough to ignore the resulting inefficiency.
4864 -----------------------------
4865 -- Denotes_Previous_Actual --
4866 -----------------------------
4868 function Denotes_Previous_Actual
(Typ
: Entity_Id
) return Boolean is
4872 Prev
:= First_Entity
(Instance
);
4873 while Present
(Prev
) loop
4875 and then Nkind
(Parent
(Prev
)) = N_Subtype_Declaration
4876 and then Is_Entity_Name
(Subtype_Indication
(Parent
(Prev
)))
4877 and then Entity
(Subtype_Indication
(Parent
(Prev
))) = Typ
4890 end Denotes_Previous_Actual
;
4892 -- Start of processing for Check_Generic_Actuals
4895 E
:= First_Entity
(Instance
);
4896 while Present
(E
) loop
4898 and then Nkind
(Parent
(E
)) = N_Subtype_Declaration
4899 and then Scope
(Etype
(E
)) /= Instance
4900 and then Is_Entity_Name
(Subtype_Indication
(Parent
(E
)))
4902 if Is_Array_Type
(E
)
4903 and then Denotes_Previous_Actual
(Component_Type
(E
))
4907 Check_Private_View
(Subtype_Indication
(Parent
(E
)));
4909 Set_Is_Generic_Actual_Type
(E
, True);
4910 Set_Is_Hidden
(E
, False);
4911 Set_Is_Potentially_Use_Visible
(E
,
4914 -- We constructed the generic actual type as a subtype of the
4915 -- supplied type. This means that it normally would not inherit
4916 -- subtype specific attributes of the actual, which is wrong for
4917 -- the generic case.
4919 Astype
:= Ancestor_Subtype
(E
);
4923 -- This can happen when E is an itype that is the full view of
4924 -- a private type completed, e.g. with a constrained array. In
4925 -- that case, use the first subtype, which will carry size
4926 -- information. The base type itself is unconstrained and will
4929 Astype
:= First_Subtype
(E
);
4932 Set_Size_Info
(E
, (Astype
));
4933 Set_RM_Size
(E
, RM_Size
(Astype
));
4934 Set_First_Rep_Item
(E
, First_Rep_Item
(Astype
));
4936 if Is_Discrete_Or_Fixed_Point_Type
(E
) then
4937 Set_RM_Size
(E
, RM_Size
(Astype
));
4939 -- In nested instances, the base type of an access actual
4940 -- may itself be private, and need to be exchanged.
4942 elsif Is_Access_Type
(E
)
4943 and then Is_Private_Type
(Etype
(E
))
4946 (New_Occurrence_Of
(Etype
(E
), Sloc
(Instance
)));
4949 elsif Ekind
(E
) = E_Package
then
4951 -- If this is the renaming for the current instance, we're done.
4952 -- Otherwise it is a formal package. If the corresponding formal
4953 -- was declared with a box, the (instantiations of the) generic
4954 -- formal part are also visible. Otherwise, ignore the entity
4955 -- created to validate the actuals.
4957 if Renamed_Object
(E
) = Instance
then
4960 elsif Nkind
(Parent
(E
)) /= N_Package_Renaming_Declaration
then
4963 -- The visibility of a formal of an enclosing generic is already
4966 elsif Denotes_Formal_Package
(E
) then
4969 elsif Present
(Associated_Formal_Package
(E
))
4970 and then not Is_Generic_Formal
(E
)
4972 if Box_Present
(Parent
(Associated_Formal_Package
(E
))) then
4973 Check_Generic_Actuals
(Renamed_Object
(E
), True);
4976 Check_Generic_Actuals
(Renamed_Object
(E
), False);
4979 Set_Is_Hidden
(E
, False);
4982 -- If this is a subprogram instance (in a wrapper package) the
4983 -- actual is fully visible.
4985 elsif Is_Wrapper_Package
(Instance
) then
4986 Set_Is_Hidden
(E
, False);
4988 -- If the formal package is declared with a box, or if the formal
4989 -- parameter is defaulted, it is visible in the body.
4992 or else Is_Visible_Formal
(E
)
4994 Set_Is_Hidden
(E
, False);
4999 end Check_Generic_Actuals
;
5001 ------------------------------
5002 -- Check_Generic_Child_Unit --
5003 ------------------------------
5005 procedure Check_Generic_Child_Unit
5007 Parent_Installed
: in out Boolean)
5009 Loc
: constant Source_Ptr
:= Sloc
(Gen_Id
);
5010 Gen_Par
: Entity_Id
:= Empty
;
5012 Inst_Par
: Entity_Id
;
5015 function Find_Generic_Child
5017 Id
: Node_Id
) return Entity_Id
;
5018 -- Search generic parent for possible child unit with the given name
5020 function In_Enclosing_Instance
return Boolean;
5021 -- Within an instance of the parent, the child unit may be denoted
5022 -- by a simple name, or an abbreviated expanded name. Examine enclosing
5023 -- scopes to locate a possible parent instantiation.
5025 ------------------------
5026 -- Find_Generic_Child --
5027 ------------------------
5029 function Find_Generic_Child
5031 Id
: Node_Id
) return Entity_Id
5036 -- If entity of name is already set, instance has already been
5037 -- resolved, e.g. in an enclosing instantiation.
5039 if Present
(Entity
(Id
)) then
5040 if Scope
(Entity
(Id
)) = Scop
then
5047 E
:= First_Entity
(Scop
);
5048 while Present
(E
) loop
5049 if Chars
(E
) = Chars
(Id
)
5050 and then Is_Child_Unit
(E
)
5052 if Is_Child_Unit
(E
)
5053 and then not Is_Visible_Child_Unit
(E
)
5056 ("generic child unit& is not visible", Gen_Id
, E
);
5068 end Find_Generic_Child
;
5070 ---------------------------
5071 -- In_Enclosing_Instance --
5072 ---------------------------
5074 function In_Enclosing_Instance
return Boolean is
5075 Enclosing_Instance
: Node_Id
;
5076 Instance_Decl
: Node_Id
;
5079 -- We do not inline any call that contains instantiations, except
5080 -- for instantiations of Unchecked_Conversion, so if we are within
5081 -- an inlined body the current instance does not require parents.
5083 if In_Inlined_Body
then
5084 pragma Assert
(Chars
(Gen_Id
) = Name_Unchecked_Conversion
);
5088 -- Loop to check enclosing scopes
5090 Enclosing_Instance
:= Current_Scope
;
5091 while Present
(Enclosing_Instance
) loop
5092 Instance_Decl
:= Unit_Declaration_Node
(Enclosing_Instance
);
5094 if Ekind
(Enclosing_Instance
) = E_Package
5095 and then Is_Generic_Instance
(Enclosing_Instance
)
5097 (Generic_Parent
(Specification
(Instance_Decl
)))
5099 -- Check whether the generic we are looking for is a child of
5102 E
:= Find_Generic_Child
5103 (Generic_Parent
(Specification
(Instance_Decl
)), Gen_Id
);
5104 exit when Present
(E
);
5110 Enclosing_Instance
:= Scope
(Enclosing_Instance
);
5122 Make_Expanded_Name
(Loc
,
5124 Prefix
=> New_Occurrence_Of
(Enclosing_Instance
, Loc
),
5125 Selector_Name
=> New_Occurrence_Of
(E
, Loc
)));
5127 Set_Entity
(Gen_Id
, E
);
5128 Set_Etype
(Gen_Id
, Etype
(E
));
5129 Parent_Installed
:= False; -- Already in scope.
5132 end In_Enclosing_Instance
;
5134 -- Start of processing for Check_Generic_Child_Unit
5137 -- If the name of the generic is given by a selected component, it may
5138 -- be the name of a generic child unit, and the prefix is the name of an
5139 -- instance of the parent, in which case the child unit must be visible.
5140 -- If this instance is not in scope, it must be placed there and removed
5141 -- after instantiation, because what is being instantiated is not the
5142 -- original child, but the corresponding child present in the instance
5145 -- If the child is instantiated within the parent, it can be given by
5146 -- a simple name. In this case the instance is already in scope, but
5147 -- the child generic must be recovered from the generic parent as well.
5149 if Nkind
(Gen_Id
) = N_Selected_Component
then
5150 S
:= Selector_Name
(Gen_Id
);
5151 Analyze
(Prefix
(Gen_Id
));
5152 Inst_Par
:= Entity
(Prefix
(Gen_Id
));
5154 if Ekind
(Inst_Par
) = E_Package
5155 and then Present
(Renamed_Object
(Inst_Par
))
5157 Inst_Par
:= Renamed_Object
(Inst_Par
);
5160 if Ekind
(Inst_Par
) = E_Package
then
5161 if Nkind
(Parent
(Inst_Par
)) = N_Package_Specification
then
5162 Gen_Par
:= Generic_Parent
(Parent
(Inst_Par
));
5164 elsif Nkind
(Parent
(Inst_Par
)) = N_Defining_Program_Unit_Name
5166 Nkind
(Parent
(Parent
(Inst_Par
))) = N_Package_Specification
5168 Gen_Par
:= Generic_Parent
(Parent
(Parent
(Inst_Par
)));
5171 elsif Ekind
(Inst_Par
) = E_Generic_Package
5172 and then Nkind
(Parent
(Gen_Id
)) = N_Formal_Package_Declaration
5174 -- A formal package may be a real child package, and not the
5175 -- implicit instance within a parent. In this case the child is
5176 -- not visible and has to be retrieved explicitly as well.
5178 Gen_Par
:= Inst_Par
;
5181 if Present
(Gen_Par
) then
5183 -- The prefix denotes an instantiation. The entity itself may be a
5184 -- nested generic, or a child unit.
5186 E
:= Find_Generic_Child
(Gen_Par
, S
);
5189 Change_Selected_Component_To_Expanded_Name
(Gen_Id
);
5190 Set_Entity
(Gen_Id
, E
);
5191 Set_Etype
(Gen_Id
, Etype
(E
));
5193 Set_Etype
(S
, Etype
(E
));
5195 -- Indicate that this is a reference to the parent
5197 if In_Extended_Main_Source_Unit
(Gen_Id
) then
5198 Set_Is_Instantiated
(Inst_Par
);
5201 -- A common mistake is to replicate the naming scheme of a
5202 -- hierarchy by instantiating a generic child directly, rather
5203 -- than the implicit child in a parent instance:
5205 -- generic .. package Gpar is ..
5206 -- generic .. package Gpar.Child is ..
5207 -- package Par is new Gpar ();
5210 -- package Par.Child is new Gpar.Child ();
5211 -- rather than Par.Child
5213 -- In this case the instantiation is within Par, which is an
5214 -- instance, but Gpar does not denote Par because we are not IN
5215 -- the instance of Gpar, so this is illegal. The test below
5216 -- recognizes this particular case.
5218 if Is_Child_Unit
(E
)
5219 and then not Comes_From_Source
(Entity
(Prefix
(Gen_Id
)))
5220 and then (not In_Instance
5221 or else Nkind
(Parent
(Parent
(Gen_Id
))) =
5225 ("prefix of generic child unit must be instance of parent",
5229 if not In_Open_Scopes
(Inst_Par
)
5230 and then Nkind
(Parent
(Gen_Id
)) not in
5231 N_Generic_Renaming_Declaration
5233 Install_Parent
(Inst_Par
);
5234 Parent_Installed
:= True;
5236 elsif In_Open_Scopes
(Inst_Par
) then
5238 -- If the parent is already installed, install the actuals
5239 -- for its formal packages. This is necessary when the
5240 -- child instance is a child of the parent instance:
5241 -- in this case, the parent is placed on the scope stack
5242 -- but the formal packages are not made visible.
5244 Install_Formal_Packages
(Inst_Par
);
5248 -- If the generic parent does not contain an entity that
5249 -- corresponds to the selector, the instance doesn't either.
5250 -- Analyzing the node will yield the appropriate error message.
5251 -- If the entity is not a child unit, then it is an inner
5252 -- generic in the parent.
5260 if Is_Child_Unit
(Entity
(Gen_Id
))
5262 Nkind
(Parent
(Gen_Id
)) not in N_Generic_Renaming_Declaration
5263 and then not In_Open_Scopes
(Inst_Par
)
5265 Install_Parent
(Inst_Par
);
5266 Parent_Installed
:= True;
5270 elsif Nkind
(Gen_Id
) = N_Expanded_Name
then
5272 -- Entity already present, analyze prefix, whose meaning may be
5273 -- an instance in the current context. If it is an instance of
5274 -- a relative within another, the proper parent may still have
5275 -- to be installed, if they are not of the same generation.
5277 Analyze
(Prefix
(Gen_Id
));
5279 -- In the unlikely case that a local declaration hides the name
5280 -- of the parent package, locate it on the homonym chain. If the
5281 -- context is an instance of the parent, the renaming entity is
5284 Inst_Par
:= Entity
(Prefix
(Gen_Id
));
5285 while Present
(Inst_Par
)
5286 and then not Is_Package_Or_Generic_Package
(Inst_Par
)
5288 Inst_Par
:= Homonym
(Inst_Par
);
5291 pragma Assert
(Present
(Inst_Par
));
5292 Set_Entity
(Prefix
(Gen_Id
), Inst_Par
);
5294 if In_Enclosing_Instance
then
5297 elsif Present
(Entity
(Gen_Id
))
5298 and then Is_Child_Unit
(Entity
(Gen_Id
))
5299 and then not In_Open_Scopes
(Inst_Par
)
5301 Install_Parent
(Inst_Par
);
5302 Parent_Installed
:= True;
5305 elsif In_Enclosing_Instance
then
5307 -- The child unit is found in some enclosing scope
5314 -- If this is the renaming of the implicit child in a parent
5315 -- instance, recover the parent name and install it.
5317 if Is_Entity_Name
(Gen_Id
) then
5318 E
:= Entity
(Gen_Id
);
5320 if Is_Generic_Unit
(E
)
5321 and then Nkind
(Parent
(E
)) in N_Generic_Renaming_Declaration
5322 and then Is_Child_Unit
(Renamed_Object
(E
))
5323 and then Is_Generic_Unit
(Scope
(Renamed_Object
(E
)))
5324 and then Nkind
(Name
(Parent
(E
))) = N_Expanded_Name
5327 New_Copy_Tree
(Name
(Parent
(E
))));
5328 Inst_Par
:= Entity
(Prefix
(Gen_Id
));
5330 if not In_Open_Scopes
(Inst_Par
) then
5331 Install_Parent
(Inst_Par
);
5332 Parent_Installed
:= True;
5335 -- If it is a child unit of a non-generic parent, it may be
5336 -- use-visible and given by a direct name. Install parent as
5339 elsif Is_Generic_Unit
(E
)
5340 and then Is_Child_Unit
(E
)
5342 Nkind
(Parent
(Gen_Id
)) not in N_Generic_Renaming_Declaration
5343 and then not Is_Generic_Unit
(Scope
(E
))
5345 if not In_Open_Scopes
(Scope
(E
)) then
5346 Install_Parent
(Scope
(E
));
5347 Parent_Installed
:= True;
5352 end Check_Generic_Child_Unit
;
5354 -----------------------------
5355 -- Check_Hidden_Child_Unit --
5356 -----------------------------
5358 procedure Check_Hidden_Child_Unit
5360 Gen_Unit
: Entity_Id
;
5361 Act_Decl_Id
: Entity_Id
)
5363 Gen_Id
: constant Node_Id
:= Name
(N
);
5366 if Is_Child_Unit
(Gen_Unit
)
5367 and then Is_Child_Unit
(Act_Decl_Id
)
5368 and then Nkind
(Gen_Id
) = N_Expanded_Name
5369 and then Entity
(Prefix
(Gen_Id
)) = Scope
(Act_Decl_Id
)
5370 and then Chars
(Gen_Unit
) = Chars
(Act_Decl_Id
)
5372 Error_Msg_Node_2
:= Scope
(Act_Decl_Id
);
5374 ("generic unit & is implicitly declared in &",
5375 Defining_Unit_Name
(N
), Gen_Unit
);
5376 Error_Msg_N
("\instance must have different name",
5377 Defining_Unit_Name
(N
));
5379 end Check_Hidden_Child_Unit
;
5381 ------------------------
5382 -- Check_Private_View --
5383 ------------------------
5385 procedure Check_Private_View
(N
: Node_Id
) is
5386 T
: constant Entity_Id
:= Etype
(N
);
5390 -- Exchange views if the type was not private in the generic but is
5391 -- private at the point of instantiation. Do not exchange views if
5392 -- the scope of the type is in scope. This can happen if both generic
5393 -- and instance are sibling units, or if type is defined in a parent.
5394 -- In this case the visibility of the type will be correct for all
5398 BT
:= Base_Type
(T
);
5400 if Is_Private_Type
(T
)
5401 and then not Has_Private_View
(N
)
5402 and then Present
(Full_View
(T
))
5403 and then not In_Open_Scopes
(Scope
(T
))
5405 -- In the generic, the full type was visible. Save the private
5406 -- entity, for subsequent exchange.
5410 elsif Has_Private_View
(N
)
5411 and then not Is_Private_Type
(T
)
5412 and then not Has_Been_Exchanged
(T
)
5413 and then Etype
(Get_Associated_Node
(N
)) /= T
5415 -- Only the private declaration was visible in the generic. If
5416 -- the type appears in a subtype declaration, the subtype in the
5417 -- instance must have a view compatible with that of its parent,
5418 -- which must be exchanged (see corresponding code in Restore_
5419 -- Private_Views). Otherwise, if the type is defined in a parent
5420 -- unit, leave full visibility within instance, which is safe.
5422 if In_Open_Scopes
(Scope
(Base_Type
(T
)))
5423 and then not Is_Private_Type
(Base_Type
(T
))
5424 and then Comes_From_Source
(Base_Type
(T
))
5428 elsif Nkind
(Parent
(N
)) = N_Subtype_Declaration
5429 or else not In_Private_Part
(Scope
(Base_Type
(T
)))
5431 Prepend_Elmt
(T
, Exchanged_Views
);
5432 Exchange_Declarations
(Etype
(Get_Associated_Node
(N
)));
5435 -- For composite types with inconsistent representation exchange
5436 -- component types accordingly.
5438 elsif Is_Access_Type
(T
)
5439 and then Is_Private_Type
(Designated_Type
(T
))
5440 and then not Has_Private_View
(N
)
5441 and then Present
(Full_View
(Designated_Type
(T
)))
5443 Switch_View
(Designated_Type
(T
));
5445 elsif Is_Array_Type
(T
) then
5446 if Is_Private_Type
(Component_Type
(T
))
5447 and then not Has_Private_View
(N
)
5448 and then Present
(Full_View
(Component_Type
(T
)))
5450 Switch_View
(Component_Type
(T
));
5453 -- The normal exchange mechanism relies on the setting of a
5454 -- flag on the reference in the generic. However, an additional
5455 -- mechanism is needed for types that are not explicitly mentioned
5456 -- in the generic, but may be needed in expanded code in the
5457 -- instance. This includes component types of arrays and
5458 -- designated types of access types. This processing must also
5459 -- include the index types of arrays which we take care of here.
5466 Indx
:= First_Index
(T
);
5467 Typ
:= Base_Type
(Etype
(Indx
));
5468 while Present
(Indx
) loop
5469 if Is_Private_Type
(Typ
)
5470 and then Present
(Full_View
(Typ
))
5479 elsif Is_Private_Type
(T
)
5480 and then Present
(Full_View
(T
))
5481 and then Is_Array_Type
(Full_View
(T
))
5482 and then Is_Private_Type
(Component_Type
(Full_View
(T
)))
5486 -- Finally, a non-private subtype may have a private base type, which
5487 -- must be exchanged for consistency. This can happen when a package
5488 -- body is instantiated, when the scope stack is empty but in fact
5489 -- the subtype and the base type are declared in an enclosing scope.
5491 -- Note that in this case we introduce an inconsistency in the view
5492 -- set, because we switch the base type BT, but there could be some
5493 -- private dependent subtypes of BT which remain unswitched. Such
5494 -- subtypes might need to be switched at a later point (see specific
5495 -- provision for that case in Switch_View).
5497 elsif not Is_Private_Type
(T
)
5498 and then not Has_Private_View
(N
)
5499 and then Is_Private_Type
(BT
)
5500 and then Present
(Full_View
(BT
))
5501 and then not Is_Generic_Type
(BT
)
5502 and then not In_Open_Scopes
(BT
)
5504 Prepend_Elmt
(Full_View
(BT
), Exchanged_Views
);
5505 Exchange_Declarations
(BT
);
5508 end Check_Private_View
;
5510 --------------------------
5511 -- Contains_Instance_Of --
5512 --------------------------
5514 function Contains_Instance_Of
5517 N
: Node_Id
) return Boolean
5525 -- Verify that there are no circular instantiations. We check whether
5526 -- the unit contains an instance of the current scope or some enclosing
5527 -- scope (in case one of the instances appears in a subunit). Longer
5528 -- circularities involving subunits might seem too pathological to
5529 -- consider, but they were not too pathological for the authors of
5530 -- DEC bc30vsq, so we loop over all enclosing scopes, and mark all
5531 -- enclosing generic scopes as containing an instance.
5534 -- Within a generic subprogram body, the scope is not generic, to
5535 -- allow for recursive subprograms. Use the declaration to determine
5536 -- whether this is a generic unit.
5538 if Ekind
(Scop
) = E_Generic_Package
5539 or else (Is_Subprogram
(Scop
)
5540 and then Nkind
(Unit_Declaration_Node
(Scop
)) =
5541 N_Generic_Subprogram_Declaration
)
5543 Elmt
:= First_Elmt
(Inner_Instances
(Inner
));
5545 while Present
(Elmt
) loop
5546 if Node
(Elmt
) = Scop
then
5547 Error_Msg_Node_2
:= Inner
;
5549 ("circular Instantiation: & instantiated within &!",
5553 elsif Node
(Elmt
) = Inner
then
5556 elsif Contains_Instance_Of
(Node
(Elmt
), Scop
, N
) then
5557 Error_Msg_Node_2
:= Inner
;
5559 ("circular Instantiation: & instantiated within &!",
5567 -- Indicate that Inner is being instantiated within Scop
5569 Append_Elmt
(Inner
, Inner_Instances
(Scop
));
5572 if Scop
= Standard_Standard
then
5575 Scop
:= Scope
(Scop
);
5580 end Contains_Instance_Of
;
5582 -----------------------
5583 -- Copy_Generic_Node --
5584 -----------------------
5586 function Copy_Generic_Node
5588 Parent_Id
: Node_Id
;
5589 Instantiating
: Boolean) return Node_Id
5594 function Copy_Generic_Descendant
(D
: Union_Id
) return Union_Id
;
5595 -- Check the given value of one of the Fields referenced by the
5596 -- current node to determine whether to copy it recursively. The
5597 -- field may hold a Node_Id, a List_Id, or an Elist_Id, or a plain
5598 -- value (Sloc, Uint, Char) in which case it need not be copied.
5600 procedure Copy_Descendants
;
5601 -- Common utility for various nodes
5603 function Copy_Generic_Elist
(E
: Elist_Id
) return Elist_Id
;
5604 -- Make copy of element list
5606 function Copy_Generic_List
5608 Parent_Id
: Node_Id
) return List_Id
;
5609 -- Apply Copy_Node recursively to the members of a node list
5611 function In_Defining_Unit_Name
(Nam
: Node_Id
) return Boolean;
5612 -- True if an identifier is part of the defining program unit name
5613 -- of a child unit. The entity of such an identifier must be kept
5614 -- (for ASIS use) even though as the name of an enclosing generic
5615 -- it would otherwise not be preserved in the generic tree.
5617 ----------------------
5618 -- Copy_Descendants --
5619 ----------------------
5621 procedure Copy_Descendants
is
5623 use Atree
.Unchecked_Access
;
5624 -- This code section is part of the implementation of an untyped
5625 -- tree traversal, so it needs direct access to node fields.
5628 Set_Field1
(New_N
, Copy_Generic_Descendant
(Field1
(N
)));
5629 Set_Field2
(New_N
, Copy_Generic_Descendant
(Field2
(N
)));
5630 Set_Field3
(New_N
, Copy_Generic_Descendant
(Field3
(N
)));
5631 Set_Field4
(New_N
, Copy_Generic_Descendant
(Field4
(N
)));
5632 Set_Field5
(New_N
, Copy_Generic_Descendant
(Field5
(N
)));
5633 end Copy_Descendants
;
5635 -----------------------------
5636 -- Copy_Generic_Descendant --
5637 -----------------------------
5639 function Copy_Generic_Descendant
(D
: Union_Id
) return Union_Id
is
5641 if D
= Union_Id
(Empty
) then
5644 elsif D
in Node_Range
then
5646 (Copy_Generic_Node
(Node_Id
(D
), New_N
, Instantiating
));
5648 elsif D
in List_Range
then
5649 return Union_Id
(Copy_Generic_List
(List_Id
(D
), New_N
));
5651 elsif D
in Elist_Range
then
5652 return Union_Id
(Copy_Generic_Elist
(Elist_Id
(D
)));
5654 -- Nothing else is copyable (e.g. Uint values), return as is
5659 end Copy_Generic_Descendant
;
5661 ------------------------
5662 -- Copy_Generic_Elist --
5663 ------------------------
5665 function Copy_Generic_Elist
(E
: Elist_Id
) return Elist_Id
is
5672 M
:= First_Elmt
(E
);
5673 while Present
(M
) loop
5675 (Copy_Generic_Node
(Node
(M
), Empty
, Instantiating
), L
);
5684 end Copy_Generic_Elist
;
5686 -----------------------
5687 -- Copy_Generic_List --
5688 -----------------------
5690 function Copy_Generic_List
5692 Parent_Id
: Node_Id
) return List_Id
5700 Set_Parent
(New_L
, Parent_Id
);
5703 while Present
(N
) loop
5704 Append
(Copy_Generic_Node
(N
, Empty
, Instantiating
), New_L
);
5713 end Copy_Generic_List
;
5715 ---------------------------
5716 -- In_Defining_Unit_Name --
5717 ---------------------------
5719 function In_Defining_Unit_Name
(Nam
: Node_Id
) return Boolean is
5721 return Present
(Parent
(Nam
))
5722 and then (Nkind
(Parent
(Nam
)) = N_Defining_Program_Unit_Name
5724 (Nkind
(Parent
(Nam
)) = N_Expanded_Name
5725 and then In_Defining_Unit_Name
(Parent
(Nam
))));
5726 end In_Defining_Unit_Name
;
5728 -- Start of processing for Copy_Generic_Node
5735 New_N
:= New_Copy
(N
);
5737 if Instantiating
then
5738 Adjust_Instantiation_Sloc
(New_N
, S_Adjustment
);
5741 if not Is_List_Member
(N
) then
5742 Set_Parent
(New_N
, Parent_Id
);
5745 -- If defining identifier, then all fields have been copied already
5747 if Nkind
(New_N
) in N_Entity
then
5750 -- Special casing for identifiers and other entity names and operators
5752 elsif Nkind_In
(New_N
, N_Identifier
,
5753 N_Character_Literal
,
5756 or else Nkind
(New_N
) in N_Op
5758 if not Instantiating
then
5760 -- Link both nodes in order to assign subsequently the entity of
5761 -- the copy to the original node, in case this is a global
5764 Set_Associated_Node
(N
, New_N
);
5766 -- If we are within an instantiation, this is a nested generic
5767 -- that has already been analyzed at the point of definition. We
5768 -- must preserve references that were global to the enclosing
5769 -- parent at that point. Other occurrences, whether global or
5770 -- local to the current generic, must be resolved anew, so we
5771 -- reset the entity in the generic copy. A global reference has a
5772 -- smaller depth than the parent, or else the same depth in case
5773 -- both are distinct compilation units.
5774 -- A child unit is implicitly declared within the enclosing parent
5775 -- but is in fact global to it, and must be preserved.
5777 -- It is also possible for Current_Instantiated_Parent to be
5778 -- defined, and for this not to be a nested generic, namely if the
5779 -- unit is loaded through Rtsfind. In that case, the entity of
5780 -- New_N is only a link to the associated node, and not a defining
5783 -- The entities for parent units in the defining_program_unit of a
5784 -- generic child unit are established when the context of the unit
5785 -- is first analyzed, before the generic copy is made. They are
5786 -- preserved in the copy for use in ASIS queries.
5788 Ent
:= Entity
(New_N
);
5790 if No
(Current_Instantiated_Parent
.Gen_Id
) then
5792 or else Nkind
(Ent
) /= N_Defining_Identifier
5793 or else not In_Defining_Unit_Name
(N
)
5795 Set_Associated_Node
(New_N
, Empty
);
5800 not Nkind_In
(Ent
, N_Defining_Identifier
,
5801 N_Defining_Character_Literal
,
5802 N_Defining_Operator_Symbol
)
5803 or else No
(Scope
(Ent
))
5805 (Scope
(Ent
) = Current_Instantiated_Parent
.Gen_Id
5806 and then not Is_Child_Unit
(Ent
))
5808 (Scope_Depth
(Scope
(Ent
)) >
5809 Scope_Depth
(Current_Instantiated_Parent
.Gen_Id
)
5811 Get_Source_Unit
(Ent
) =
5812 Get_Source_Unit
(Current_Instantiated_Parent
.Gen_Id
))
5814 Set_Associated_Node
(New_N
, Empty
);
5817 -- Case of instantiating identifier or some other name or operator
5820 -- If the associated node is still defined, the entity in it is
5821 -- global, and must be copied to the instance. If this copy is
5822 -- being made for a body to inline, it is applied to an
5823 -- instantiated tree, and the entity is already present and must
5824 -- be also preserved.
5827 Assoc
: constant Node_Id
:= Get_Associated_Node
(N
);
5830 if Present
(Assoc
) then
5831 if Nkind
(Assoc
) = Nkind
(N
) then
5832 Set_Entity
(New_N
, Entity
(Assoc
));
5833 Check_Private_View
(N
);
5835 elsif Nkind
(Assoc
) = N_Function_Call
then
5836 Set_Entity
(New_N
, Entity
(Name
(Assoc
)));
5838 elsif Nkind_In
(Assoc
, N_Defining_Identifier
,
5839 N_Defining_Character_Literal
,
5840 N_Defining_Operator_Symbol
)
5841 and then Expander_Active
5843 -- Inlining case: we are copying a tree that contains
5844 -- global entities, which are preserved in the copy to be
5845 -- used for subsequent inlining.
5850 Set_Entity
(New_N
, Empty
);
5856 -- For expanded name, we must copy the Prefix and Selector_Name
5858 if Nkind
(N
) = N_Expanded_Name
then
5860 (New_N
, Copy_Generic_Node
(Prefix
(N
), New_N
, Instantiating
));
5862 Set_Selector_Name
(New_N
,
5863 Copy_Generic_Node
(Selector_Name
(N
), New_N
, Instantiating
));
5865 -- For operators, we must copy the right operand
5867 elsif Nkind
(N
) in N_Op
then
5868 Set_Right_Opnd
(New_N
,
5869 Copy_Generic_Node
(Right_Opnd
(N
), New_N
, Instantiating
));
5871 -- And for binary operators, the left operand as well
5873 if Nkind
(N
) in N_Binary_Op
then
5874 Set_Left_Opnd
(New_N
,
5875 Copy_Generic_Node
(Left_Opnd
(N
), New_N
, Instantiating
));
5879 -- Special casing for stubs
5881 elsif Nkind
(N
) in N_Body_Stub
then
5883 -- In any case, we must copy the specification or defining
5884 -- identifier as appropriate.
5886 if Nkind
(N
) = N_Subprogram_Body_Stub
then
5887 Set_Specification
(New_N
,
5888 Copy_Generic_Node
(Specification
(N
), New_N
, Instantiating
));
5891 Set_Defining_Identifier
(New_N
,
5893 (Defining_Identifier
(N
), New_N
, Instantiating
));
5896 -- If we are not instantiating, then this is where we load and
5897 -- analyze subunits, i.e. at the point where the stub occurs. A
5898 -- more permissive system might defer this analysis to the point
5899 -- of instantiation, but this seems to complicated for now.
5901 if not Instantiating
then
5903 Subunit_Name
: constant Unit_Name_Type
:= Get_Unit_Name
(N
);
5905 Unum
: Unit_Number_Type
;
5911 (Load_Name
=> Subunit_Name
,
5916 -- If the proper body is not found, a warning message will be
5917 -- emitted when analyzing the stub, or later at the point
5918 -- of instantiation. Here we just leave the stub as is.
5920 if Unum
= No_Unit
then
5921 Subunits_Missing
:= True;
5922 goto Subunit_Not_Found
;
5925 Subunit
:= Cunit
(Unum
);
5927 if Nkind
(Unit
(Subunit
)) /= N_Subunit
then
5929 ("found child unit instead of expected SEPARATE subunit",
5931 Error_Msg_Sloc
:= Sloc
(N
);
5932 Error_Msg_N
("\to complete stub #", Subunit
);
5933 goto Subunit_Not_Found
;
5936 -- We must create a generic copy of the subunit, in order to
5937 -- perform semantic analysis on it, and we must replace the
5938 -- stub in the original generic unit with the subunit, in order
5939 -- to preserve non-local references within.
5941 -- Only the proper body needs to be copied. Library_Unit and
5942 -- context clause are simply inherited by the generic copy.
5943 -- Note that the copy (which may be recursive if there are
5944 -- nested subunits) must be done first, before attaching it to
5945 -- the enclosing generic.
5949 (Proper_Body
(Unit
(Subunit
)),
5950 Empty
, Instantiating
=> False);
5952 -- Now place the original proper body in the original generic
5953 -- unit. This is a body, not a compilation unit.
5955 Rewrite
(N
, Proper_Body
(Unit
(Subunit
)));
5956 Set_Is_Compilation_Unit
(Defining_Entity
(N
), False);
5957 Set_Was_Originally_Stub
(N
);
5959 -- Finally replace the body of the subunit with its copy, and
5960 -- make this new subunit into the library unit of the generic
5961 -- copy, which does not have stubs any longer.
5963 Set_Proper_Body
(Unit
(Subunit
), New_Body
);
5964 Set_Library_Unit
(New_N
, Subunit
);
5965 Inherit_Context
(Unit
(Subunit
), N
);
5968 -- If we are instantiating, this must be an error case, since
5969 -- otherwise we would have replaced the stub node by the proper body
5970 -- that corresponds. So just ignore it in the copy (i.e. we have
5971 -- copied it, and that is good enough).
5977 <<Subunit_Not_Found
>> null;
5979 -- If the node is a compilation unit, it is the subunit of a stub, which
5980 -- has been loaded already (see code below). In this case, the library
5981 -- unit field of N points to the parent unit (which is a compilation
5982 -- unit) and need not (and cannot!) be copied.
5984 -- When the proper body of the stub is analyzed, the library_unit link
5985 -- is used to establish the proper context (see sem_ch10).
5987 -- The other fields of a compilation unit are copied as usual
5989 elsif Nkind
(N
) = N_Compilation_Unit
then
5991 -- This code can only be executed when not instantiating, because in
5992 -- the copy made for an instantiation, the compilation unit node has
5993 -- disappeared at the point that a stub is replaced by its proper
5996 pragma Assert
(not Instantiating
);
5998 Set_Context_Items
(New_N
,
5999 Copy_Generic_List
(Context_Items
(N
), New_N
));
6002 Copy_Generic_Node
(Unit
(N
), New_N
, False));
6004 Set_First_Inlined_Subprogram
(New_N
,
6006 (First_Inlined_Subprogram
(N
), New_N
, False));
6008 Set_Aux_Decls_Node
(New_N
,
6009 Copy_Generic_Node
(Aux_Decls_Node
(N
), New_N
, False));
6011 -- For an assignment node, the assignment is known to be semantically
6012 -- legal if we are instantiating the template. This avoids incorrect
6013 -- diagnostics in generated code.
6015 elsif Nkind
(N
) = N_Assignment_Statement
then
6017 -- Copy name and expression fields in usual manner
6020 Copy_Generic_Node
(Name
(N
), New_N
, Instantiating
));
6022 Set_Expression
(New_N
,
6023 Copy_Generic_Node
(Expression
(N
), New_N
, Instantiating
));
6025 if Instantiating
then
6026 Set_Assignment_OK
(Name
(New_N
), True);
6029 elsif Nkind_In
(N
, N_Aggregate
, N_Extension_Aggregate
) then
6030 if not Instantiating
then
6031 Set_Associated_Node
(N
, New_N
);
6034 if Present
(Get_Associated_Node
(N
))
6035 and then Nkind
(Get_Associated_Node
(N
)) = Nkind
(N
)
6037 -- In the generic the aggregate has some composite type. If at
6038 -- the point of instantiation the type has a private view,
6039 -- install the full view (and that of its ancestors, if any).
6042 T
: Entity_Id
:= (Etype
(Get_Associated_Node
(New_N
)));
6047 and then Is_Private_Type
(T
)
6053 and then Is_Tagged_Type
(T
)
6054 and then Is_Derived_Type
(T
)
6056 Rt
:= Root_Type
(T
);
6061 if Is_Private_Type
(T
) then
6072 -- Do not copy the associated node, which points to
6073 -- the generic copy of the aggregate.
6076 use Atree
.Unchecked_Access
;
6077 -- This code section is part of the implementation of an untyped
6078 -- tree traversal, so it needs direct access to node fields.
6081 Set_Field1
(New_N
, Copy_Generic_Descendant
(Field1
(N
)));
6082 Set_Field2
(New_N
, Copy_Generic_Descendant
(Field2
(N
)));
6083 Set_Field3
(New_N
, Copy_Generic_Descendant
(Field3
(N
)));
6084 Set_Field5
(New_N
, Copy_Generic_Descendant
(Field5
(N
)));
6087 -- Allocators do not have an identifier denoting the access type,
6088 -- so we must locate it through the expression to check whether
6089 -- the views are consistent.
6091 elsif Nkind
(N
) = N_Allocator
6092 and then Nkind
(Expression
(N
)) = N_Qualified_Expression
6093 and then Is_Entity_Name
(Subtype_Mark
(Expression
(N
)))
6094 and then Instantiating
6097 T
: constant Node_Id
:=
6098 Get_Associated_Node
(Subtype_Mark
(Expression
(N
)));
6104 -- Retrieve the allocator node in the generic copy
6106 Acc_T
:= Etype
(Parent
(Parent
(T
)));
6108 and then Is_Private_Type
(Acc_T
)
6110 Switch_View
(Acc_T
);
6117 -- For a proper body, we must catch the case of a proper body that
6118 -- replaces a stub. This represents the point at which a separate
6119 -- compilation unit, and hence template file, may be referenced, so we
6120 -- must make a new source instantiation entry for the template of the
6121 -- subunit, and ensure that all nodes in the subunit are adjusted using
6122 -- this new source instantiation entry.
6124 elsif Nkind
(N
) in N_Proper_Body
then
6126 Save_Adjustment
: constant Sloc_Adjustment
:= S_Adjustment
;
6129 if Instantiating
and then Was_Originally_Stub
(N
) then
6130 Create_Instantiation_Source
6131 (Instantiation_Node
,
6132 Defining_Entity
(N
),
6137 -- Now copy the fields of the proper body, using the new
6138 -- adjustment factor if one was needed as per test above.
6142 -- Restore the original adjustment factor in case changed
6144 S_Adjustment
:= Save_Adjustment
;
6147 -- Don't copy Ident or Comment pragmas, since the comment belongs to the
6148 -- generic unit, not to the instantiating unit.
6150 elsif Nkind
(N
) = N_Pragma
6151 and then Instantiating
6154 Prag_Id
: constant Pragma_Id
:= Get_Pragma_Id
(N
);
6156 if Prag_Id
= Pragma_Ident
6157 or else Prag_Id
= Pragma_Comment
6159 New_N
:= Make_Null_Statement
(Sloc
(N
));
6165 elsif Nkind_In
(N
, N_Integer_Literal
,
6169 -- No descendant fields need traversing
6173 -- For the remaining nodes, copy recursively their descendants
6179 and then Nkind
(N
) = N_Subprogram_Body
6181 Set_Generic_Parent
(Specification
(New_N
), N
);
6186 end Copy_Generic_Node
;
6188 ----------------------------
6189 -- Denotes_Formal_Package --
6190 ----------------------------
6192 function Denotes_Formal_Package
6194 On_Exit
: Boolean := False;
6195 Instance
: Entity_Id
:= Empty
) return Boolean
6198 Scop
: constant Entity_Id
:= Scope
(Pack
);
6201 function Is_Actual_Of_Previous_Formal
(P
: Entity_Id
) return Boolean;
6202 -- The package in question may be an actual for a previous formal
6203 -- package P of the current instance, so examine its actuals as well.
6204 -- This must be recursive over other formal packages.
6206 ----------------------------------
6207 -- Is_Actual_Of_Previous_Formal --
6208 ----------------------------------
6210 function Is_Actual_Of_Previous_Formal
(P
: Entity_Id
) return Boolean is
6214 E1
:= First_Entity
(P
);
6215 while Present
(E1
) and then E1
/= Instance
loop
6216 if Ekind
(E1
) = E_Package
6217 and then Nkind
(Parent
(E1
)) = N_Package_Renaming_Declaration
6219 if Renamed_Object
(E1
) = Pack
then
6223 or else Renamed_Object
(E1
) = P
6227 elsif Is_Actual_Of_Previous_Formal
(E1
) then
6236 end Is_Actual_Of_Previous_Formal
;
6238 -- Start of processing for Denotes_Formal_Package
6244 (Instance_Envs
.Last
).Instantiated_Parent
.Act_Id
;
6246 Par
:= Current_Instantiated_Parent
.Act_Id
;
6249 if Ekind
(Scop
) = E_Generic_Package
6250 or else Nkind
(Unit_Declaration_Node
(Scop
)) =
6251 N_Generic_Subprogram_Declaration
6255 elsif Nkind
(Original_Node
(Unit_Declaration_Node
(Pack
))) =
6256 N_Formal_Package_Declaration
6264 -- Check whether this package is associated with a formal package of
6265 -- the enclosing instantiation. Iterate over the list of renamings.
6267 E
:= First_Entity
(Par
);
6268 while Present
(E
) loop
6269 if Ekind
(E
) /= E_Package
6270 or else Nkind
(Parent
(E
)) /= N_Package_Renaming_Declaration
6274 elsif Renamed_Object
(E
) = Par
then
6277 elsif Renamed_Object
(E
) = Pack
then
6280 elsif Is_Actual_Of_Previous_Formal
(E
) then
6290 end Denotes_Formal_Package
;
6296 procedure End_Generic
is
6298 -- ??? More things could be factored out in this routine. Should
6299 -- probably be done at a later stage.
6301 Inside_A_Generic
:= Generic_Flags
.Table
(Generic_Flags
.Last
);
6302 Generic_Flags
.Decrement_Last
;
6304 Expander_Mode_Restore
;
6307 ----------------------
6308 -- Find_Actual_Type --
6309 ----------------------
6311 function Find_Actual_Type
6313 Gen_Type
: Entity_Id
) return Entity_Id
6315 Gen_Scope
: constant Entity_Id
:= Scope
(Gen_Type
);
6319 -- Special processing only applies to child units
6321 if not Is_Child_Unit
(Gen_Scope
) then
6322 return Get_Instance_Of
(Typ
);
6324 -- If designated or component type is itself a formal of the child unit,
6325 -- its instance is available.
6327 elsif Scope
(Typ
) = Gen_Scope
then
6328 return Get_Instance_Of
(Typ
);
6330 -- If the array or access type is not declared in the parent unit,
6331 -- no special processing needed.
6333 elsif not Is_Generic_Type
(Typ
)
6334 and then Scope
(Gen_Scope
) /= Scope
(Typ
)
6336 return Get_Instance_Of
(Typ
);
6338 -- Otherwise, retrieve designated or component type by visibility
6341 T
:= Current_Entity
(Typ
);
6342 while Present
(T
) loop
6343 if In_Open_Scopes
(Scope
(T
)) then
6346 elsif Is_Generic_Actual_Type
(T
) then
6355 end Find_Actual_Type
;
6357 ----------------------------
6358 -- Freeze_Subprogram_Body --
6359 ----------------------------
6361 procedure Freeze_Subprogram_Body
6362 (Inst_Node
: Node_Id
;
6364 Pack_Id
: Entity_Id
)
6367 Gen_Unit
: constant Entity_Id
:= Get_Generic_Entity
(Inst_Node
);
6368 Par
: constant Entity_Id
:= Scope
(Gen_Unit
);
6373 function Earlier
(N1
, N2
: Node_Id
) return Boolean;
6374 -- Yields True if N1 and N2 appear in the same compilation unit,
6375 -- ignoring subunits, and if N1 is to the left of N2 in a left-to-right
6376 -- traversal of the tree for the unit.
6378 function Enclosing_Body
(N
: Node_Id
) return Node_Id
;
6379 -- Find innermost package body that encloses the given node, and which
6380 -- is not a compilation unit. Freeze nodes for the instance, or for its
6381 -- enclosing body, may be inserted after the enclosing_body of the
6384 function Package_Freeze_Node
(B
: Node_Id
) return Node_Id
;
6385 -- Find entity for given package body, and locate or create a freeze
6388 function True_Parent
(N
: Node_Id
) return Node_Id
;
6389 -- For a subunit, return parent of corresponding stub
6395 function Earlier
(N1
, N2
: Node_Id
) return Boolean is
6401 procedure Find_Depth
(P
: in out Node_Id
; D
: in out Integer);
6402 -- Find distance from given node to enclosing compilation unit
6408 procedure Find_Depth
(P
: in out Node_Id
; D
: in out Integer) is
6411 and then Nkind
(P
) /= N_Compilation_Unit
6413 P
:= True_Parent
(P
);
6418 -- Start of processing for Earlier
6421 Find_Depth
(P1
, D1
);
6422 Find_Depth
(P2
, D2
);
6432 P1
:= True_Parent
(P1
);
6437 P2
:= True_Parent
(P2
);
6441 -- At this point P1 and P2 are at the same distance from the root.
6442 -- We examine their parents until we find a common declarative
6443 -- list, at which point we can establish their relative placement
6444 -- by comparing their ultimate slocs. If we reach the root,
6445 -- N1 and N2 do not descend from the same declarative list (e.g.
6446 -- one is nested in the declarative part and the other is in a block
6447 -- in the statement part) and the earlier one is already frozen.
6449 while not Is_List_Member
(P1
)
6450 or else not Is_List_Member
(P2
)
6451 or else List_Containing
(P1
) /= List_Containing
(P2
)
6453 P1
:= True_Parent
(P1
);
6454 P2
:= True_Parent
(P2
);
6456 if Nkind
(Parent
(P1
)) = N_Subunit
then
6457 P1
:= Corresponding_Stub
(Parent
(P1
));
6460 if Nkind
(Parent
(P2
)) = N_Subunit
then
6461 P2
:= Corresponding_Stub
(Parent
(P2
));
6470 Top_Level_Location
(Sloc
(P1
)) < Top_Level_Location
(Sloc
(P2
));
6473 --------------------
6474 -- Enclosing_Body --
6475 --------------------
6477 function Enclosing_Body
(N
: Node_Id
) return Node_Id
is
6478 P
: Node_Id
:= Parent
(N
);
6482 and then Nkind
(Parent
(P
)) /= N_Compilation_Unit
6484 if Nkind
(P
) = N_Package_Body
then
6486 if Nkind
(Parent
(P
)) = N_Subunit
then
6487 return Corresponding_Stub
(Parent
(P
));
6493 P
:= True_Parent
(P
);
6499 -------------------------
6500 -- Package_Freeze_Node --
6501 -------------------------
6503 function Package_Freeze_Node
(B
: Node_Id
) return Node_Id
is
6507 if Nkind
(B
) = N_Package_Body
then
6508 Id
:= Corresponding_Spec
(B
);
6510 else pragma Assert
(Nkind
(B
) = N_Package_Body_Stub
);
6511 Id
:= Corresponding_Spec
(Proper_Body
(Unit
(Library_Unit
(B
))));
6514 Ensure_Freeze_Node
(Id
);
6515 return Freeze_Node
(Id
);
6516 end Package_Freeze_Node
;
6522 function True_Parent
(N
: Node_Id
) return Node_Id
is
6524 if Nkind
(Parent
(N
)) = N_Subunit
then
6525 return Parent
(Corresponding_Stub
(Parent
(N
)));
6531 -- Start of processing of Freeze_Subprogram_Body
6534 -- If the instance and the generic body appear within the same unit, and
6535 -- the instance precedes the generic, the freeze node for the instance
6536 -- must appear after that of the generic. If the generic is nested
6537 -- within another instance I2, then current instance must be frozen
6538 -- after I2. In both cases, the freeze nodes are those of enclosing
6539 -- packages. Otherwise, the freeze node is placed at the end of the
6540 -- current declarative part.
6542 Enc_G
:= Enclosing_Body
(Gen_Body
);
6543 Enc_I
:= Enclosing_Body
(Inst_Node
);
6544 Ensure_Freeze_Node
(Pack_Id
);
6545 F_Node
:= Freeze_Node
(Pack_Id
);
6547 if Is_Generic_Instance
(Par
)
6548 and then Present
(Freeze_Node
(Par
))
6550 In_Same_Declarative_Part
(Freeze_Node
(Par
), Inst_Node
)
6552 if ABE_Is_Certain
(Get_Package_Instantiation_Node
(Par
)) then
6554 -- The parent was a premature instantiation. Insert freeze node at
6555 -- the end the current declarative part.
6557 Insert_After_Last_Decl
(Inst_Node
, F_Node
);
6560 Insert_After
(Freeze_Node
(Par
), F_Node
);
6563 -- The body enclosing the instance should be frozen after the body that
6564 -- includes the generic, because the body of the instance may make
6565 -- references to entities therein. If the two are not in the same
6566 -- declarative part, or if the one enclosing the instance is frozen
6567 -- already, freeze the instance at the end of the current declarative
6570 elsif Is_Generic_Instance
(Par
)
6571 and then Present
(Freeze_Node
(Par
))
6572 and then Present
(Enc_I
)
6574 if In_Same_Declarative_Part
(Freeze_Node
(Par
), Enc_I
)
6576 (Nkind
(Enc_I
) = N_Package_Body
6578 In_Same_Declarative_Part
(Freeze_Node
(Par
), Parent
(Enc_I
)))
6580 -- The enclosing package may contain several instances. Rather
6581 -- than computing the earliest point at which to insert its
6582 -- freeze node, we place it at the end of the declarative part
6583 -- of the parent of the generic.
6585 Insert_After_Last_Decl
6586 (Freeze_Node
(Par
), Package_Freeze_Node
(Enc_I
));
6589 Insert_After_Last_Decl
(Inst_Node
, F_Node
);
6591 elsif Present
(Enc_G
)
6592 and then Present
(Enc_I
)
6593 and then Enc_G
/= Enc_I
6594 and then Earlier
(Inst_Node
, Gen_Body
)
6596 if Nkind
(Enc_G
) = N_Package_Body
then
6597 E_G_Id
:= Corresponding_Spec
(Enc_G
);
6598 else pragma Assert
(Nkind
(Enc_G
) = N_Package_Body_Stub
);
6600 Corresponding_Spec
(Proper_Body
(Unit
(Library_Unit
(Enc_G
))));
6603 -- Freeze package that encloses instance, and place node after
6604 -- package that encloses generic. If enclosing package is already
6605 -- frozen we have to assume it is at the proper place. This may be
6606 -- a potential ABE that requires dynamic checking. Do not add a
6607 -- freeze node if the package that encloses the generic is inside
6608 -- the body that encloses the instance, because the freeze node
6609 -- would be in the wrong scope. Additional contortions needed if
6610 -- the bodies are within a subunit.
6613 Enclosing_Body
: Node_Id
;
6616 if Nkind
(Enc_I
) = N_Package_Body_Stub
then
6617 Enclosing_Body
:= Proper_Body
(Unit
(Library_Unit
(Enc_I
)));
6619 Enclosing_Body
:= Enc_I
;
6622 if Parent
(List_Containing
(Enc_G
)) /= Enclosing_Body
then
6623 Insert_After_Last_Decl
(Enc_G
, Package_Freeze_Node
(Enc_I
));
6627 -- Freeze enclosing subunit before instance
6629 Ensure_Freeze_Node
(E_G_Id
);
6631 if not Is_List_Member
(Freeze_Node
(E_G_Id
)) then
6632 Insert_After
(Enc_G
, Freeze_Node
(E_G_Id
));
6635 Insert_After_Last_Decl
(Inst_Node
, F_Node
);
6638 -- If none of the above, insert freeze node at the end of the current
6639 -- declarative part.
6641 Insert_After_Last_Decl
(Inst_Node
, F_Node
);
6643 end Freeze_Subprogram_Body
;
6649 function Get_Gen_Id
(E
: Assoc_Ptr
) return Entity_Id
is
6651 return Generic_Renamings
.Table
(E
).Gen_Id
;
6654 ---------------------
6655 -- Get_Instance_Of --
6656 ---------------------
6658 function Get_Instance_Of
(A
: Entity_Id
) return Entity_Id
is
6659 Res
: constant Assoc_Ptr
:= Generic_Renamings_HTable
.Get
(A
);
6662 if Res
/= Assoc_Null
then
6663 return Generic_Renamings
.Table
(Res
).Act_Id
;
6665 -- On exit, entity is not instantiated: not a generic parameter, or
6666 -- else parameter of an inner generic unit.
6670 end Get_Instance_Of
;
6672 ------------------------------------
6673 -- Get_Package_Instantiation_Node --
6674 ------------------------------------
6676 function Get_Package_Instantiation_Node
(A
: Entity_Id
) return Node_Id
is
6677 Decl
: Node_Id
:= Unit_Declaration_Node
(A
);
6681 -- If the Package_Instantiation attribute has been set on the package
6682 -- entity, then use it directly when it (or its Original_Node) refers
6683 -- to an N_Package_Instantiation node. In principle it should be
6684 -- possible to have this field set in all cases, which should be
6685 -- investigated, and would allow this function to be significantly
6688 if Present
(Package_Instantiation
(A
)) then
6689 if Nkind
(Package_Instantiation
(A
)) = N_Package_Instantiation
then
6690 return Package_Instantiation
(A
);
6692 elsif Nkind
(Original_Node
(Package_Instantiation
(A
))) =
6693 N_Package_Instantiation
6695 return Original_Node
(Package_Instantiation
(A
));
6699 -- If the instantiation is a compilation unit that does not need body
6700 -- then the instantiation node has been rewritten as a package
6701 -- declaration for the instance, and we return the original node.
6703 -- If it is a compilation unit and the instance node has not been
6704 -- rewritten, then it is still the unit of the compilation. Finally, if
6705 -- a body is present, this is a parent of the main unit whose body has
6706 -- been compiled for inlining purposes, and the instantiation node has
6707 -- been rewritten with the instance body.
6709 -- Otherwise the instantiation node appears after the declaration. If
6710 -- the entity is a formal package, the declaration may have been
6711 -- rewritten as a generic declaration (in the case of a formal with box)
6712 -- or left as a formal package declaration if it has actuals, and is
6713 -- found with a forward search.
6715 if Nkind
(Parent
(Decl
)) = N_Compilation_Unit
then
6716 if Nkind
(Decl
) = N_Package_Declaration
6717 and then Present
(Corresponding_Body
(Decl
))
6719 Decl
:= Unit_Declaration_Node
(Corresponding_Body
(Decl
));
6722 if Nkind
(Original_Node
(Decl
)) = N_Package_Instantiation
then
6723 return Original_Node
(Decl
);
6725 return Unit
(Parent
(Decl
));
6728 elsif Nkind
(Decl
) = N_Package_Declaration
6729 and then Nkind
(Original_Node
(Decl
)) = N_Formal_Package_Declaration
6731 return Original_Node
(Decl
);
6734 Inst
:= Next
(Decl
);
6735 while not Nkind_In
(Inst
, N_Package_Instantiation
,
6736 N_Formal_Package_Declaration
)
6743 end Get_Package_Instantiation_Node
;
6745 ------------------------
6746 -- Has_Been_Exchanged --
6747 ------------------------
6749 function Has_Been_Exchanged
(E
: Entity_Id
) return Boolean is
6753 Next
:= First_Elmt
(Exchanged_Views
);
6754 while Present
(Next
) loop
6755 if Full_View
(Node
(Next
)) = E
then
6763 end Has_Been_Exchanged
;
6769 function Hash
(F
: Entity_Id
) return HTable_Range
is
6771 return HTable_Range
(F
mod HTable_Size
);
6774 ------------------------
6775 -- Hide_Current_Scope --
6776 ------------------------
6778 procedure Hide_Current_Scope
is
6779 C
: constant Entity_Id
:= Current_Scope
;
6783 Set_Is_Hidden_Open_Scope
(C
);
6785 E
:= First_Entity
(C
);
6786 while Present
(E
) loop
6787 if Is_Immediately_Visible
(E
) then
6788 Set_Is_Immediately_Visible
(E
, False);
6789 Append_Elmt
(E
, Hidden_Entities
);
6795 -- Make the scope name invisible as well. This is necessary, but might
6796 -- conflict with calls to Rtsfind later on, in case the scope is a
6797 -- predefined one. There is no clean solution to this problem, so for
6798 -- now we depend on the user not redefining Standard itself in one of
6799 -- the parent units.
6801 if Is_Immediately_Visible
(C
)
6802 and then C
/= Standard_Standard
6804 Set_Is_Immediately_Visible
(C
, False);
6805 Append_Elmt
(C
, Hidden_Entities
);
6808 end Hide_Current_Scope
;
6814 procedure Init_Env
is
6815 Saved
: Instance_Env
;
6818 Saved
.Instantiated_Parent
:= Current_Instantiated_Parent
;
6819 Saved
.Exchanged_Views
:= Exchanged_Views
;
6820 Saved
.Hidden_Entities
:= Hidden_Entities
;
6821 Saved
.Current_Sem_Unit
:= Current_Sem_Unit
;
6822 Saved
.Parent_Unit_Visible
:= Parent_Unit_Visible
;
6823 Saved
.Instance_Parent_Unit
:= Instance_Parent_Unit
;
6825 -- Save configuration switches. These may be reset if the unit is a
6826 -- predefined unit, and the current mode is not Ada 2005.
6828 Save_Opt_Config_Switches
(Saved
.Switches
);
6830 Instance_Envs
.Append
(Saved
);
6832 Exchanged_Views
:= New_Elmt_List
;
6833 Hidden_Entities
:= New_Elmt_List
;
6835 -- Make dummy entry for Instantiated parent. If generic unit is legal,
6836 -- this is set properly in Set_Instance_Env.
6838 Current_Instantiated_Parent
:=
6839 (Current_Scope
, Current_Scope
, Assoc_Null
);
6842 ------------------------------
6843 -- In_Same_Declarative_Part --
6844 ------------------------------
6846 function In_Same_Declarative_Part
6848 Inst
: Node_Id
) return Boolean
6850 Decls
: constant Node_Id
:= Parent
(F_Node
);
6851 Nod
: Node_Id
:= Parent
(Inst
);
6854 while Present
(Nod
) loop
6858 elsif Nkind_In
(Nod
, N_Subprogram_Body
,
6866 elsif Nkind
(Nod
) = N_Subunit
then
6867 Nod
:= Corresponding_Stub
(Nod
);
6869 elsif Nkind
(Nod
) = N_Compilation_Unit
then
6873 Nod
:= Parent
(Nod
);
6878 end In_Same_Declarative_Part
;
6880 ---------------------
6881 -- In_Main_Context --
6882 ---------------------
6884 function In_Main_Context
(E
: Entity_Id
) return Boolean is
6890 if not Is_Compilation_Unit
(E
)
6891 or else Ekind
(E
) /= E_Package
6892 or else In_Private_Part
(E
)
6897 Context
:= Context_Items
(Cunit
(Main_Unit
));
6899 Clause
:= First
(Context
);
6900 while Present
(Clause
) loop
6901 if Nkind
(Clause
) = N_With_Clause
then
6902 Nam
:= Name
(Clause
);
6904 -- If the current scope is part of the context of the main unit,
6905 -- analysis of the corresponding with_clause is not complete, and
6906 -- the entity is not set. We use the Chars field directly, which
6907 -- might produce false positives in rare cases, but guarantees
6908 -- that we produce all the instance bodies we will need.
6910 if (Is_Entity_Name
(Nam
)
6911 and then Chars
(Nam
) = Chars
(E
))
6912 or else (Nkind
(Nam
) = N_Selected_Component
6913 and then Chars
(Selector_Name
(Nam
)) = Chars
(E
))
6923 end In_Main_Context
;
6925 ---------------------
6926 -- Inherit_Context --
6927 ---------------------
6929 procedure Inherit_Context
(Gen_Decl
: Node_Id
; Inst
: Node_Id
) is
6930 Current_Context
: List_Id
;
6931 Current_Unit
: Node_Id
;
6936 if Nkind
(Parent
(Gen_Decl
)) = N_Compilation_Unit
then
6938 -- The inherited context is attached to the enclosing compilation
6939 -- unit. This is either the main unit, or the declaration for the
6940 -- main unit (in case the instantiation appears within the package
6941 -- declaration and the main unit is its body).
6943 Current_Unit
:= Parent
(Inst
);
6944 while Present
(Current_Unit
)
6945 and then Nkind
(Current_Unit
) /= N_Compilation_Unit
6947 Current_Unit
:= Parent
(Current_Unit
);
6950 Current_Context
:= Context_Items
(Current_Unit
);
6952 Item
:= First
(Context_Items
(Parent
(Gen_Decl
)));
6953 while Present
(Item
) loop
6954 if Nkind
(Item
) = N_With_Clause
then
6956 -- Take care to prevent direct cyclic with's, which can happen
6957 -- if the generic body with's the current unit. Such a case
6958 -- would result in binder errors (or run-time errors if the
6959 -- -gnatE switch is in effect), but we want to prevent it here,
6960 -- because Sem.Walk_Library_Items doesn't like cycles. Note
6961 -- that we don't bother to detect indirect cycles.
6963 if Library_Unit
(Item
) /= Current_Unit
then
6964 New_I
:= New_Copy
(Item
);
6965 Set_Implicit_With
(New_I
, True);
6966 Append
(New_I
, Current_Context
);
6973 end Inherit_Context
;
6979 procedure Initialize
is
6981 Generic_Renamings
.Init
;
6984 Generic_Renamings_HTable
.Reset
;
6985 Circularity_Detected
:= False;
6986 Exchanged_Views
:= No_Elist
;
6987 Hidden_Entities
:= No_Elist
;
6990 ----------------------------
6991 -- Insert_After_Last_Decl --
6992 ----------------------------
6994 procedure Insert_After_Last_Decl
(N
: Node_Id
; F_Node
: Node_Id
) is
6995 L
: List_Id
:= List_Containing
(N
);
6996 P
: constant Node_Id
:= Parent
(L
);
6999 if not Is_List_Member
(F_Node
) then
7000 if Nkind
(P
) = N_Package_Specification
7001 and then L
= Visible_Declarations
(P
)
7002 and then Present
(Private_Declarations
(P
))
7003 and then not Is_Empty_List
(Private_Declarations
(P
))
7005 L
:= Private_Declarations
(P
);
7008 Insert_After
(Last
(L
), F_Node
);
7010 end Insert_After_Last_Decl
;
7016 procedure Install_Body
7017 (Act_Body
: Node_Id
;
7022 Act_Id
: constant Entity_Id
:= Corresponding_Spec
(Act_Body
);
7023 Act_Unit
: constant Node_Id
:= Unit
(Cunit
(Get_Source_Unit
(N
)));
7024 Gen_Id
: constant Entity_Id
:= Corresponding_Spec
(Gen_Body
);
7025 Par
: constant Entity_Id
:= Scope
(Gen_Id
);
7026 Gen_Unit
: constant Node_Id
:=
7027 Unit
(Cunit
(Get_Source_Unit
(Gen_Decl
)));
7028 Orig_Body
: Node_Id
:= Gen_Body
;
7030 Body_Unit
: Node_Id
;
7032 Must_Delay
: Boolean;
7034 function Enclosing_Subp
(Id
: Entity_Id
) return Entity_Id
;
7035 -- Find subprogram (if any) that encloses instance and/or generic body
7037 function True_Sloc
(N
: Node_Id
) return Source_Ptr
;
7038 -- If the instance is nested inside a generic unit, the Sloc of the
7039 -- instance indicates the place of the original definition, not the
7040 -- point of the current enclosing instance. Pending a better usage of
7041 -- Slocs to indicate instantiation places, we determine the place of
7042 -- origin of a node by finding the maximum sloc of any ancestor node.
7043 -- Why is this not equivalent to Top_Level_Location ???
7045 --------------------
7046 -- Enclosing_Subp --
7047 --------------------
7049 function Enclosing_Subp
(Id
: Entity_Id
) return Entity_Id
is
7050 Scop
: Entity_Id
:= Scope
(Id
);
7053 while Scop
/= Standard_Standard
7054 and then not Is_Overloadable
(Scop
)
7056 Scop
:= Scope
(Scop
);
7066 function True_Sloc
(N
: Node_Id
) return Source_Ptr
is
7073 while Present
(N1
) and then N1
/= Act_Unit
loop
7074 if Sloc
(N1
) > Res
then
7084 -- Start of processing for Install_Body
7088 -- If the body is a subunit, the freeze point is the corresponding
7089 -- stub in the current compilation, not the subunit itself.
7091 if Nkind
(Parent
(Gen_Body
)) = N_Subunit
then
7092 Orig_Body
:= Corresponding_Stub
(Parent
(Gen_Body
));
7094 Orig_Body
:= Gen_Body
;
7097 Body_Unit
:= Unit
(Cunit
(Get_Source_Unit
(Orig_Body
)));
7099 -- If the instantiation and the generic definition appear in the same
7100 -- package declaration, this is an early instantiation. If they appear
7101 -- in the same declarative part, it is an early instantiation only if
7102 -- the generic body appears textually later, and the generic body is
7103 -- also in the main unit.
7105 -- If instance is nested within a subprogram, and the generic body is
7106 -- not, the instance is delayed because the enclosing body is. If
7107 -- instance and body are within the same scope, or the same sub-
7108 -- program body, indicate explicitly that the instance is delayed.
7111 (Gen_Unit
= Act_Unit
7112 and then (Nkind_In
(Gen_Unit
, N_Package_Declaration
,
7113 N_Generic_Package_Declaration
)
7114 or else (Gen_Unit
= Body_Unit
7115 and then True_Sloc
(N
) < Sloc
(Orig_Body
)))
7116 and then Is_In_Main_Unit
(Gen_Unit
)
7117 and then (Scope
(Act_Id
) = Scope
(Gen_Id
)
7119 Enclosing_Subp
(Act_Id
) = Enclosing_Subp
(Gen_Id
)));
7121 -- If this is an early instantiation, the freeze node is placed after
7122 -- the generic body. Otherwise, if the generic appears in an instance,
7123 -- we cannot freeze the current instance until the outer one is frozen.
7124 -- This is only relevant if the current instance is nested within some
7125 -- inner scope not itself within the outer instance. If this scope is
7126 -- a package body in the same declarative part as the outer instance,
7127 -- then that body needs to be frozen after the outer instance. Finally,
7128 -- if no delay is needed, we place the freeze node at the end of the
7129 -- current declarative part.
7131 if Expander_Active
then
7132 Ensure_Freeze_Node
(Act_Id
);
7133 F_Node
:= Freeze_Node
(Act_Id
);
7136 Insert_After
(Orig_Body
, F_Node
);
7138 elsif Is_Generic_Instance
(Par
)
7139 and then Present
(Freeze_Node
(Par
))
7140 and then Scope
(Act_Id
) /= Par
7142 -- Freeze instance of inner generic after instance of enclosing
7145 if In_Same_Declarative_Part
(Freeze_Node
(Par
), N
) then
7146 Insert_After
(Freeze_Node
(Par
), F_Node
);
7148 -- Freeze package enclosing instance of inner generic after
7149 -- instance of enclosing generic.
7151 elsif Nkind
(Parent
(N
)) = N_Package_Body
7152 and then In_Same_Declarative_Part
(Freeze_Node
(Par
), Parent
(N
))
7156 Enclosing
: constant Entity_Id
:=
7157 Corresponding_Spec
(Parent
(N
));
7160 Insert_After_Last_Decl
(N
, F_Node
);
7161 Ensure_Freeze_Node
(Enclosing
);
7163 if not Is_List_Member
(Freeze_Node
(Enclosing
)) then
7164 Insert_After
(Freeze_Node
(Par
), Freeze_Node
(Enclosing
));
7169 Insert_After_Last_Decl
(N
, F_Node
);
7173 Insert_After_Last_Decl
(N
, F_Node
);
7177 Set_Is_Frozen
(Act_Id
);
7178 Insert_Before
(N
, Act_Body
);
7179 Mark_Rewrite_Insertion
(Act_Body
);
7182 -----------------------------
7183 -- Install_Formal_Packages --
7184 -----------------------------
7186 procedure Install_Formal_Packages
(Par
: Entity_Id
) is
7189 Gen_E
: Entity_Id
:= Empty
;
7192 E
:= First_Entity
(Par
);
7194 -- In we are installing an instance parent, locate the formal packages
7195 -- of its generic parent.
7197 if Is_Generic_Instance
(Par
) then
7198 Gen
:= Generic_Parent
(Specification
(Unit_Declaration_Node
(Par
)));
7199 Gen_E
:= First_Entity
(Gen
);
7202 while Present
(E
) loop
7203 if Ekind
(E
) = E_Package
7204 and then Nkind
(Parent
(E
)) = N_Package_Renaming_Declaration
7206 -- If this is the renaming for the parent instance, done
7208 if Renamed_Object
(E
) = Par
then
7211 -- The visibility of a formal of an enclosing generic is already
7214 elsif Denotes_Formal_Package
(E
) then
7217 elsif Present
(Associated_Formal_Package
(E
)) then
7218 Check_Generic_Actuals
(Renamed_Object
(E
), True);
7219 Set_Is_Hidden
(E
, False);
7221 -- Find formal package in generic unit that corresponds to
7222 -- (instance of) formal package in instance.
7224 while Present
(Gen_E
) and then Chars
(Gen_E
) /= Chars
(E
) loop
7225 Next_Entity
(Gen_E
);
7228 if Present
(Gen_E
) then
7229 Map_Formal_Package_Entities
(Gen_E
, E
);
7235 if Present
(Gen_E
) then
7236 Next_Entity
(Gen_E
);
7239 end Install_Formal_Packages
;
7241 --------------------
7242 -- Install_Parent --
7243 --------------------
7245 procedure Install_Parent
(P
: Entity_Id
; In_Body
: Boolean := False) is
7246 Ancestors
: constant Elist_Id
:= New_Elmt_List
;
7247 S
: constant Entity_Id
:= Current_Scope
;
7248 Inst_Par
: Entity_Id
;
7249 First_Par
: Entity_Id
;
7250 Inst_Node
: Node_Id
;
7251 Gen_Par
: Entity_Id
;
7252 First_Gen
: Entity_Id
;
7255 procedure Install_Noninstance_Specs
(Par
: Entity_Id
);
7256 -- Install the scopes of noninstance parent units ending with Par
7258 procedure Install_Spec
(Par
: Entity_Id
);
7259 -- The child unit is within the declarative part of the parent, so
7260 -- the declarations within the parent are immediately visible.
7262 -------------------------------
7263 -- Install_Noninstance_Specs --
7264 -------------------------------
7266 procedure Install_Noninstance_Specs
(Par
: Entity_Id
) is
7269 and then Par
/= Standard_Standard
7270 and then not In_Open_Scopes
(Par
)
7272 Install_Noninstance_Specs
(Scope
(Par
));
7275 end Install_Noninstance_Specs
;
7281 procedure Install_Spec
(Par
: Entity_Id
) is
7282 Spec
: constant Node_Id
:=
7283 Specification
(Unit_Declaration_Node
(Par
));
7286 -- If this parent of the child instance is a top-level unit,
7287 -- then record the unit and its visibility for later resetting
7288 -- in Remove_Parent. We exclude units that are generic instances,
7289 -- as we only want to record this information for the ultimate
7290 -- top-level noninstance parent (is that always correct???).
7292 if Scope
(Par
) = Standard_Standard
7293 and then not Is_Generic_Instance
(Par
)
7295 Parent_Unit_Visible
:= Is_Immediately_Visible
(Par
);
7296 Instance_Parent_Unit
:= Par
;
7299 -- Open the parent scope and make it and its declarations visible.
7300 -- If this point is not within a body, then only the visible
7301 -- declarations should be made visible, and installation of the
7302 -- private declarations is deferred until the appropriate point
7303 -- within analysis of the spec being instantiated (see the handling
7304 -- of parent visibility in Analyze_Package_Specification). This is
7305 -- relaxed in the case where the parent unit is Ada.Tags, to avoid
7306 -- private view problems that occur when compiling instantiations of
7307 -- a generic child of that package (Generic_Dispatching_Constructor).
7308 -- If the instance freezes a tagged type, inlinings of operations
7309 -- from Ada.Tags may need the full view of type Tag. If inlining took
7310 -- proper account of establishing visibility of inlined subprograms'
7311 -- parents then it should be possible to remove this
7312 -- special check. ???
7315 Set_Is_Immediately_Visible
(Par
);
7316 Install_Visible_Declarations
(Par
);
7317 Set_Use
(Visible_Declarations
(Spec
));
7319 if In_Body
or else Is_RTU
(Par
, Ada_Tags
) then
7320 Install_Private_Declarations
(Par
);
7321 Set_Use
(Private_Declarations
(Spec
));
7325 -- Start of processing for Install_Parent
7328 -- We need to install the parent instance to compile the instantiation
7329 -- of the child, but the child instance must appear in the current
7330 -- scope. Given that we cannot place the parent above the current scope
7331 -- in the scope stack, we duplicate the current scope and unstack both
7332 -- after the instantiation is complete.
7334 -- If the parent is itself the instantiation of a child unit, we must
7335 -- also stack the instantiation of its parent, and so on. Each such
7336 -- ancestor is the prefix of the name in a prior instantiation.
7338 -- If this is a nested instance, the parent unit itself resolves to
7339 -- a renaming of the parent instance, whose declaration we need.
7341 -- Finally, the parent may be a generic (not an instance) when the
7342 -- child unit appears as a formal package.
7346 if Present
(Renamed_Entity
(Inst_Par
)) then
7347 Inst_Par
:= Renamed_Entity
(Inst_Par
);
7350 First_Par
:= Inst_Par
;
7353 Generic_Parent
(Specification
(Unit_Declaration_Node
(Inst_Par
)));
7355 First_Gen
:= Gen_Par
;
7357 while Present
(Gen_Par
)
7358 and then Is_Child_Unit
(Gen_Par
)
7360 -- Load grandparent instance as well
7362 Inst_Node
:= Get_Package_Instantiation_Node
(Inst_Par
);
7364 if Nkind
(Name
(Inst_Node
)) = N_Expanded_Name
then
7365 Inst_Par
:= Entity
(Prefix
(Name
(Inst_Node
)));
7367 if Present
(Renamed_Entity
(Inst_Par
)) then
7368 Inst_Par
:= Renamed_Entity
(Inst_Par
);
7373 (Specification
(Unit_Declaration_Node
(Inst_Par
)));
7375 if Present
(Gen_Par
) then
7376 Prepend_Elmt
(Inst_Par
, Ancestors
);
7379 -- Parent is not the name of an instantiation
7381 Install_Noninstance_Specs
(Inst_Par
);
7393 if Present
(First_Gen
) then
7394 Append_Elmt
(First_Par
, Ancestors
);
7397 Install_Noninstance_Specs
(First_Par
);
7400 if not Is_Empty_Elmt_List
(Ancestors
) then
7401 Elmt
:= First_Elmt
(Ancestors
);
7403 while Present
(Elmt
) loop
7404 Install_Spec
(Node
(Elmt
));
7405 Install_Formal_Packages
(Node
(Elmt
));
7416 --------------------------------
7417 -- Instantiate_Formal_Package --
7418 --------------------------------
7420 function Instantiate_Formal_Package
7423 Analyzed_Formal
: Node_Id
) return List_Id
7425 Loc
: constant Source_Ptr
:= Sloc
(Actual
);
7426 Actual_Pack
: Entity_Id
;
7427 Formal_Pack
: Entity_Id
;
7428 Gen_Parent
: Entity_Id
;
7431 Parent_Spec
: Node_Id
;
7433 procedure Find_Matching_Actual
7435 Act
: in out Entity_Id
);
7436 -- We need to associate each formal entity in the formal package
7437 -- with the corresponding entity in the actual package. The actual
7438 -- package has been analyzed and possibly expanded, and as a result
7439 -- there is no one-to-one correspondence between the two lists (for
7440 -- example, the actual may include subtypes, itypes, and inherited
7441 -- primitive operations, interspersed among the renaming declarations
7442 -- for the actuals) . We retrieve the corresponding actual by name
7443 -- because each actual has the same name as the formal, and they do
7444 -- appear in the same order.
7446 function Get_Formal_Entity
(N
: Node_Id
) return Entity_Id
;
7447 -- Retrieve entity of defining entity of generic formal parameter.
7448 -- Only the declarations of formals need to be considered when
7449 -- linking them to actuals, but the declarative list may include
7450 -- internal entities generated during analysis, and those are ignored.
7452 procedure Match_Formal_Entity
7453 (Formal_Node
: Node_Id
;
7454 Formal_Ent
: Entity_Id
;
7455 Actual_Ent
: Entity_Id
);
7456 -- Associates the formal entity with the actual. In the case
7457 -- where Formal_Ent is a formal package, this procedure iterates
7458 -- through all of its formals and enters associations between the
7459 -- actuals occurring in the formal package's corresponding actual
7460 -- package (given by Actual_Ent) and the formal package's formal
7461 -- parameters. This procedure recurses if any of the parameters is
7462 -- itself a package.
7464 function Is_Instance_Of
7465 (Act_Spec
: Entity_Id
;
7466 Gen_Anc
: Entity_Id
) return Boolean;
7467 -- The actual can be an instantiation of a generic within another
7468 -- instance, in which case there is no direct link from it to the
7469 -- original generic ancestor. In that case, we recognize that the
7470 -- ultimate ancestor is the same by examining names and scopes.
7472 procedure Process_Nested_Formal
(Formal
: Entity_Id
);
7473 -- If the current formal is declared with a box, its own formals are
7474 -- visible in the instance, as they were in the generic, and their
7475 -- Hidden flag must be reset. If some of these formals are themselves
7476 -- packages declared with a box, the processing must be recursive.
7478 --------------------------
7479 -- Find_Matching_Actual --
7480 --------------------------
7482 procedure Find_Matching_Actual
7484 Act
: in out Entity_Id
)
7486 Formal_Ent
: Entity_Id
;
7489 case Nkind
(Original_Node
(F
)) is
7490 when N_Formal_Object_Declaration |
7491 N_Formal_Type_Declaration
=>
7492 Formal_Ent
:= Defining_Identifier
(F
);
7494 while Chars
(Act
) /= Chars
(Formal_Ent
) loop
7498 when N_Formal_Subprogram_Declaration |
7499 N_Formal_Package_Declaration |
7500 N_Package_Declaration |
7501 N_Generic_Package_Declaration
=>
7502 Formal_Ent
:= Defining_Entity
(F
);
7504 while Chars
(Act
) /= Chars
(Formal_Ent
) loop
7509 raise Program_Error
;
7511 end Find_Matching_Actual
;
7513 -------------------------
7514 -- Match_Formal_Entity --
7515 -------------------------
7517 procedure Match_Formal_Entity
7518 (Formal_Node
: Node_Id
;
7519 Formal_Ent
: Entity_Id
;
7520 Actual_Ent
: Entity_Id
)
7522 Act_Pkg
: Entity_Id
;
7525 Set_Instance_Of
(Formal_Ent
, Actual_Ent
);
7527 if Ekind
(Actual_Ent
) = E_Package
then
7529 -- Record associations for each parameter
7531 Act_Pkg
:= Actual_Ent
;
7534 A_Ent
: Entity_Id
:= First_Entity
(Act_Pkg
);
7543 -- Retrieve the actual given in the formal package declaration
7545 Actual
:= Entity
(Name
(Original_Node
(Formal_Node
)));
7547 -- The actual in the formal package declaration may be a
7548 -- renamed generic package, in which case we want to retrieve
7549 -- the original generic in order to traverse its formal part.
7551 if Present
(Renamed_Entity
(Actual
)) then
7552 Gen_Decl
:= Unit_Declaration_Node
(Renamed_Entity
(Actual
));
7554 Gen_Decl
:= Unit_Declaration_Node
(Actual
);
7557 Formals
:= Generic_Formal_Declarations
(Gen_Decl
);
7559 if Present
(Formals
) then
7560 F_Node
:= First_Non_Pragma
(Formals
);
7565 while Present
(A_Ent
)
7566 and then Present
(F_Node
)
7567 and then A_Ent
/= First_Private_Entity
(Act_Pkg
)
7569 F_Ent
:= Get_Formal_Entity
(F_Node
);
7571 if Present
(F_Ent
) then
7573 -- This is a formal of the original package. Record
7574 -- association and recurse.
7576 Find_Matching_Actual
(F_Node
, A_Ent
);
7577 Match_Formal_Entity
(F_Node
, F_Ent
, A_Ent
);
7578 Next_Entity
(A_Ent
);
7581 Next_Non_Pragma
(F_Node
);
7585 end Match_Formal_Entity
;
7587 -----------------------
7588 -- Get_Formal_Entity --
7589 -----------------------
7591 function Get_Formal_Entity
(N
: Node_Id
) return Entity_Id
is
7592 Kind
: constant Node_Kind
:= Nkind
(Original_Node
(N
));
7595 when N_Formal_Object_Declaration
=>
7596 return Defining_Identifier
(N
);
7598 when N_Formal_Type_Declaration
=>
7599 return Defining_Identifier
(N
);
7601 when N_Formal_Subprogram_Declaration
=>
7602 return Defining_Unit_Name
(Specification
(N
));
7604 when N_Formal_Package_Declaration
=>
7605 return Defining_Identifier
(Original_Node
(N
));
7607 when N_Generic_Package_Declaration
=>
7608 return Defining_Identifier
(Original_Node
(N
));
7610 -- All other declarations are introduced by semantic analysis and
7611 -- have no match in the actual.
7616 end Get_Formal_Entity
;
7618 --------------------
7619 -- Is_Instance_Of --
7620 --------------------
7622 function Is_Instance_Of
7623 (Act_Spec
: Entity_Id
;
7624 Gen_Anc
: Entity_Id
) return Boolean
7626 Gen_Par
: constant Entity_Id
:= Generic_Parent
(Act_Spec
);
7629 if No
(Gen_Par
) then
7632 -- Simplest case: the generic parent of the actual is the formal
7634 elsif Gen_Par
= Gen_Anc
then
7637 elsif Chars
(Gen_Par
) /= Chars
(Gen_Anc
) then
7640 -- The actual may be obtained through several instantiations. Its
7641 -- scope must itself be an instance of a generic declared in the
7642 -- same scope as the formal. Any other case is detected above.
7644 elsif not Is_Generic_Instance
(Scope
(Gen_Par
)) then
7648 return Generic_Parent
(Parent
(Scope
(Gen_Par
))) = Scope
(Gen_Anc
);
7652 ---------------------------
7653 -- Process_Nested_Formal --
7654 ---------------------------
7656 procedure Process_Nested_Formal
(Formal
: Entity_Id
) is
7660 if Present
(Associated_Formal_Package
(Formal
))
7661 and then Box_Present
(Parent
(Associated_Formal_Package
(Formal
)))
7663 Ent
:= First_Entity
(Formal
);
7664 while Present
(Ent
) loop
7665 Set_Is_Hidden
(Ent
, False);
7666 Set_Is_Visible_Formal
(Ent
);
7667 Set_Is_Potentially_Use_Visible
7668 (Ent
, Is_Potentially_Use_Visible
(Formal
));
7670 if Ekind
(Ent
) = E_Package
then
7671 exit when Renamed_Entity
(Ent
) = Renamed_Entity
(Formal
);
7672 Process_Nested_Formal
(Ent
);
7678 end Process_Nested_Formal
;
7680 -- Start of processing for Instantiate_Formal_Package
7685 if not Is_Entity_Name
(Actual
)
7686 or else Ekind
(Entity
(Actual
)) /= E_Package
7689 ("expect package instance to instantiate formal", Actual
);
7690 Abandon_Instantiation
(Actual
);
7691 raise Program_Error
;
7694 Actual_Pack
:= Entity
(Actual
);
7695 Set_Is_Instantiated
(Actual_Pack
);
7697 -- The actual may be a renamed package, or an outer generic formal
7698 -- package whose instantiation is converted into a renaming.
7700 if Present
(Renamed_Object
(Actual_Pack
)) then
7701 Actual_Pack
:= Renamed_Object
(Actual_Pack
);
7704 if Nkind
(Analyzed_Formal
) = N_Formal_Package_Declaration
then
7705 Gen_Parent
:= Get_Instance_Of
(Entity
(Name
(Analyzed_Formal
)));
7706 Formal_Pack
:= Defining_Identifier
(Analyzed_Formal
);
7709 Generic_Parent
(Specification
(Analyzed_Formal
));
7711 Defining_Unit_Name
(Specification
(Analyzed_Formal
));
7714 if Nkind
(Parent
(Actual_Pack
)) = N_Defining_Program_Unit_Name
then
7715 Parent_Spec
:= Specification
(Unit_Declaration_Node
(Actual_Pack
));
7717 Parent_Spec
:= Parent
(Actual_Pack
);
7720 if Gen_Parent
= Any_Id
then
7722 ("previous error in declaration of formal package", Actual
);
7723 Abandon_Instantiation
(Actual
);
7726 Is_Instance_Of
(Parent_Spec
, Get_Instance_Of
(Gen_Parent
))
7732 ("actual parameter must be instance of&", Actual
, Gen_Parent
);
7733 Abandon_Instantiation
(Actual
);
7736 Set_Instance_Of
(Defining_Identifier
(Formal
), Actual_Pack
);
7737 Map_Formal_Package_Entities
(Formal_Pack
, Actual_Pack
);
7740 Make_Package_Renaming_Declaration
(Loc
,
7741 Defining_Unit_Name
=> New_Copy
(Defining_Identifier
(Formal
)),
7742 Name
=> New_Reference_To
(Actual_Pack
, Loc
));
7744 Set_Associated_Formal_Package
(Defining_Unit_Name
(Nod
),
7745 Defining_Identifier
(Formal
));
7746 Decls
:= New_List
(Nod
);
7748 -- If the formal F has a box, then the generic declarations are
7749 -- visible in the generic G. In an instance of G, the corresponding
7750 -- entities in the actual for F (which are the actuals for the
7751 -- instantiation of the generic that F denotes) must also be made
7752 -- visible for analysis of the current instance. On exit from the
7753 -- current instance, those entities are made private again. If the
7754 -- actual is currently in use, these entities are also use-visible.
7756 -- The loop through the actual entities also steps through the formal
7757 -- entities and enters associations from formals to actuals into the
7758 -- renaming map. This is necessary to properly handle checking of
7759 -- actual parameter associations for later formals that depend on
7760 -- actuals declared in the formal package.
7762 -- In Ada 2005, partial parametrization requires that we make visible
7763 -- the actuals corresponding to formals that were defaulted in the
7764 -- formal package. There formals are identified because they remain
7765 -- formal generics within the formal package, rather than being
7766 -- renamings of the actuals supplied.
7769 Gen_Decl
: constant Node_Id
:=
7770 Unit_Declaration_Node
(Gen_Parent
);
7771 Formals
: constant List_Id
:=
7772 Generic_Formal_Declarations
(Gen_Decl
);
7774 Actual_Ent
: Entity_Id
;
7775 Actual_Of_Formal
: Node_Id
;
7776 Formal_Node
: Node_Id
;
7777 Formal_Ent
: Entity_Id
;
7780 if Present
(Formals
) then
7781 Formal_Node
:= First_Non_Pragma
(Formals
);
7783 Formal_Node
:= Empty
;
7786 Actual_Ent
:= First_Entity
(Actual_Pack
);
7788 First
(Visible_Declarations
(Specification
(Analyzed_Formal
)));
7789 while Present
(Actual_Ent
)
7790 and then Actual_Ent
/= First_Private_Entity
(Actual_Pack
)
7792 if Present
(Formal_Node
) then
7793 Formal_Ent
:= Get_Formal_Entity
(Formal_Node
);
7795 if Present
(Formal_Ent
) then
7796 Find_Matching_Actual
(Formal_Node
, Actual_Ent
);
7798 (Formal_Node
, Formal_Ent
, Actual_Ent
);
7800 -- We iterate at the same time over the actuals of the
7801 -- local package created for the formal, to determine
7802 -- which one of the formals of the original generic were
7803 -- defaulted in the formal. The corresponding actual
7804 -- entities are visible in the enclosing instance.
7806 if Box_Present
(Formal
)
7808 (Present
(Actual_Of_Formal
)
7811 (Get_Formal_Entity
(Actual_Of_Formal
)))
7813 Set_Is_Hidden
(Actual_Ent
, False);
7814 Set_Is_Visible_Formal
(Actual_Ent
);
7815 Set_Is_Potentially_Use_Visible
7816 (Actual_Ent
, In_Use
(Actual_Pack
));
7818 if Ekind
(Actual_Ent
) = E_Package
then
7819 Process_Nested_Formal
(Actual_Ent
);
7823 Set_Is_Hidden
(Actual_Ent
);
7824 Set_Is_Potentially_Use_Visible
(Actual_Ent
, False);
7828 Next_Non_Pragma
(Formal_Node
);
7829 Next
(Actual_Of_Formal
);
7832 -- No further formals to match, but the generic part may
7833 -- contain inherited operation that are not hidden in the
7834 -- enclosing instance.
7836 Next_Entity
(Actual_Ent
);
7840 -- Inherited subprograms generated by formal derived types are
7841 -- also visible if the types are.
7843 Actual_Ent
:= First_Entity
(Actual_Pack
);
7844 while Present
(Actual_Ent
)
7845 and then Actual_Ent
/= First_Private_Entity
(Actual_Pack
)
7847 if Is_Overloadable
(Actual_Ent
)
7849 Nkind
(Parent
(Actual_Ent
)) = N_Subtype_Declaration
7851 not Is_Hidden
(Defining_Identifier
(Parent
(Actual_Ent
)))
7853 Set_Is_Hidden
(Actual_Ent
, False);
7854 Set_Is_Potentially_Use_Visible
7855 (Actual_Ent
, In_Use
(Actual_Pack
));
7858 Next_Entity
(Actual_Ent
);
7862 -- If the formal is not declared with a box, reanalyze it as an
7863 -- abbreviated instantiation, to verify the matching rules of 12.7.
7864 -- The actual checks are performed after the generic associations
7865 -- have been analyzed, to guarantee the same visibility for this
7866 -- instantiation and for the actuals.
7868 -- In Ada 2005, the generic associations for the formal can include
7869 -- defaulted parameters. These are ignored during check. This
7870 -- internal instantiation is removed from the tree after conformance
7871 -- checking, because it contains formal declarations for those
7872 -- defaulted parameters, and those should not reach the back-end.
7874 if not Box_Present
(Formal
) then
7876 I_Pack
: constant Entity_Id
:=
7877 Make_Temporary
(Sloc
(Actual
), 'P');
7880 Set_Is_Internal
(I_Pack
);
7883 Make_Package_Instantiation
(Sloc
(Actual
),
7884 Defining_Unit_Name
=> I_Pack
,
7887 (Get_Instance_Of
(Gen_Parent
), Sloc
(Actual
)),
7888 Generic_Associations
=>
7889 Generic_Associations
(Formal
)));
7895 end Instantiate_Formal_Package
;
7897 -----------------------------------
7898 -- Instantiate_Formal_Subprogram --
7899 -----------------------------------
7901 function Instantiate_Formal_Subprogram
7904 Analyzed_Formal
: Node_Id
) return Node_Id
7907 Formal_Sub
: constant Entity_Id
:=
7908 Defining_Unit_Name
(Specification
(Formal
));
7909 Analyzed_S
: constant Entity_Id
:=
7910 Defining_Unit_Name
(Specification
(Analyzed_Formal
));
7911 Decl_Node
: Node_Id
;
7915 function From_Parent_Scope
(Subp
: Entity_Id
) return Boolean;
7916 -- If the generic is a child unit, the parent has been installed on the
7917 -- scope stack, but a default subprogram cannot resolve to something on
7918 -- the parent because that parent is not really part of the visible
7919 -- context (it is there to resolve explicit local entities). If the
7920 -- default has resolved in this way, we remove the entity from
7921 -- immediate visibility and analyze the node again to emit an error
7922 -- message or find another visible candidate.
7924 procedure Valid_Actual_Subprogram
(Act
: Node_Id
);
7925 -- Perform legality check and raise exception on failure
7927 -----------------------
7928 -- From_Parent_Scope --
7929 -----------------------
7931 function From_Parent_Scope
(Subp
: Entity_Id
) return Boolean is
7932 Gen_Scope
: Node_Id
;
7935 Gen_Scope
:= Scope
(Analyzed_S
);
7936 while Present
(Gen_Scope
)
7937 and then Is_Child_Unit
(Gen_Scope
)
7939 if Scope
(Subp
) = Scope
(Gen_Scope
) then
7943 Gen_Scope
:= Scope
(Gen_Scope
);
7947 end From_Parent_Scope
;
7949 -----------------------------
7950 -- Valid_Actual_Subprogram --
7951 -----------------------------
7953 procedure Valid_Actual_Subprogram
(Act
: Node_Id
) is
7957 if Is_Entity_Name
(Act
) then
7958 Act_E
:= Entity
(Act
);
7960 elsif Nkind
(Act
) = N_Selected_Component
7961 and then Is_Entity_Name
(Selector_Name
(Act
))
7963 Act_E
:= Entity
(Selector_Name
(Act
));
7969 if (Present
(Act_E
) and then Is_Overloadable
(Act_E
))
7970 or else Nkind_In
(Act
, N_Attribute_Reference
,
7971 N_Indexed_Component
,
7972 N_Character_Literal
,
7973 N_Explicit_Dereference
)
7979 ("expect subprogram or entry name in instantiation of&",
7980 Instantiation_Node
, Formal_Sub
);
7981 Abandon_Instantiation
(Instantiation_Node
);
7983 end Valid_Actual_Subprogram
;
7985 -- Start of processing for Instantiate_Formal_Subprogram
7988 New_Spec
:= New_Copy_Tree
(Specification
(Formal
));
7990 -- The tree copy has created the proper instantiation sloc for the
7991 -- new specification. Use this location for all other constructed
7994 Loc
:= Sloc
(Defining_Unit_Name
(New_Spec
));
7996 -- Create new entity for the actual (New_Copy_Tree does not)
7998 Set_Defining_Unit_Name
7999 (New_Spec
, Make_Defining_Identifier
(Loc
, Chars
(Formal_Sub
)));
8001 -- Create new entities for the each of the formals in the
8002 -- specification of the renaming declaration built for the actual.
8004 if Present
(Parameter_Specifications
(New_Spec
)) then
8008 F
:= First
(Parameter_Specifications
(New_Spec
));
8009 while Present
(F
) loop
8010 Set_Defining_Identifier
(F
,
8011 Make_Defining_Identifier
(Sloc
(F
),
8012 Chars
=> Chars
(Defining_Identifier
(F
))));
8018 -- Find entity of actual. If the actual is an attribute reference, it
8019 -- cannot be resolved here (its formal is missing) but is handled
8020 -- instead in Attribute_Renaming. If the actual is overloaded, it is
8021 -- fully resolved subsequently, when the renaming declaration for the
8022 -- formal is analyzed. If it is an explicit dereference, resolve the
8023 -- prefix but not the actual itself, to prevent interpretation as call.
8025 if Present
(Actual
) then
8026 Loc
:= Sloc
(Actual
);
8027 Set_Sloc
(New_Spec
, Loc
);
8029 if Nkind
(Actual
) = N_Operator_Symbol
then
8030 Find_Direct_Name
(Actual
);
8032 elsif Nkind
(Actual
) = N_Explicit_Dereference
then
8033 Analyze
(Prefix
(Actual
));
8035 elsif Nkind
(Actual
) /= N_Attribute_Reference
then
8039 Valid_Actual_Subprogram
(Actual
);
8042 elsif Present
(Default_Name
(Formal
)) then
8043 if not Nkind_In
(Default_Name
(Formal
), N_Attribute_Reference
,
8044 N_Selected_Component
,
8045 N_Indexed_Component
,
8046 N_Character_Literal
)
8047 and then Present
(Entity
(Default_Name
(Formal
)))
8049 Nam
:= New_Occurrence_Of
(Entity
(Default_Name
(Formal
)), Loc
);
8051 Nam
:= New_Copy
(Default_Name
(Formal
));
8052 Set_Sloc
(Nam
, Loc
);
8055 elsif Box_Present
(Formal
) then
8057 -- Actual is resolved at the point of instantiation. Create an
8058 -- identifier or operator with the same name as the formal.
8060 if Nkind
(Formal_Sub
) = N_Defining_Operator_Symbol
then
8061 Nam
:= Make_Operator_Symbol
(Loc
,
8062 Chars
=> Chars
(Formal_Sub
),
8063 Strval
=> No_String
);
8065 Nam
:= Make_Identifier
(Loc
, Chars
(Formal_Sub
));
8068 elsif Nkind
(Specification
(Formal
)) = N_Procedure_Specification
8069 and then Null_Present
(Specification
(Formal
))
8071 -- Generate null body for procedure, for use in the instance
8074 Make_Subprogram_Body
(Loc
,
8075 Specification
=> New_Spec
,
8076 Declarations
=> New_List
,
8077 Handled_Statement_Sequence
=>
8078 Make_Handled_Sequence_Of_Statements
(Loc
,
8079 Statements
=> New_List
(Make_Null_Statement
(Loc
))));
8081 Set_Is_Intrinsic_Subprogram
(Defining_Unit_Name
(New_Spec
));
8085 Error_Msg_Sloc
:= Sloc
(Scope
(Analyzed_S
));
8087 ("missing actual&", Instantiation_Node
, Formal_Sub
);
8089 ("\in instantiation of & declared#",
8090 Instantiation_Node
, Scope
(Analyzed_S
));
8091 Abandon_Instantiation
(Instantiation_Node
);
8095 Make_Subprogram_Renaming_Declaration
(Loc
,
8096 Specification
=> New_Spec
,
8099 -- If we do not have an actual and the formal specified <> then set to
8100 -- get proper default.
8102 if No
(Actual
) and then Box_Present
(Formal
) then
8103 Set_From_Default
(Decl_Node
);
8106 -- Gather possible interpretations for the actual before analyzing the
8107 -- instance. If overloaded, it will be resolved when analyzing the
8108 -- renaming declaration.
8110 if Box_Present
(Formal
)
8111 and then No
(Actual
)
8115 if Is_Child_Unit
(Scope
(Analyzed_S
))
8116 and then Present
(Entity
(Nam
))
8118 if not Is_Overloaded
(Nam
) then
8120 if From_Parent_Scope
(Entity
(Nam
)) then
8121 Set_Is_Immediately_Visible
(Entity
(Nam
), False);
8122 Set_Entity
(Nam
, Empty
);
8123 Set_Etype
(Nam
, Empty
);
8127 Set_Is_Immediately_Visible
(Entity
(Nam
));
8136 Get_First_Interp
(Nam
, I
, It
);
8138 while Present
(It
.Nam
) loop
8139 if From_Parent_Scope
(It
.Nam
) then
8143 Get_Next_Interp
(I
, It
);
8150 -- The generic instantiation freezes the actual. This can only be done
8151 -- once the actual is resolved, in the analysis of the renaming
8152 -- declaration. To make the formal subprogram entity available, we set
8153 -- Corresponding_Formal_Spec to point to the formal subprogram entity.
8154 -- This is also needed in Analyze_Subprogram_Renaming for the processing
8155 -- of formal abstract subprograms.
8157 Set_Corresponding_Formal_Spec
(Decl_Node
, Analyzed_S
);
8159 -- We cannot analyze the renaming declaration, and thus find the actual,
8160 -- until all the actuals are assembled in the instance. For subsequent
8161 -- checks of other actuals, indicate the node that will hold the
8162 -- instance of this formal.
8164 Set_Instance_Of
(Analyzed_S
, Nam
);
8166 if Nkind
(Actual
) = N_Selected_Component
8167 and then Is_Task_Type
(Etype
(Prefix
(Actual
)))
8168 and then not Is_Frozen
(Etype
(Prefix
(Actual
)))
8170 -- The renaming declaration will create a body, which must appear
8171 -- outside of the instantiation, We move the renaming declaration
8172 -- out of the instance, and create an additional renaming inside,
8173 -- to prevent freezing anomalies.
8176 Anon_Id
: constant Entity_Id
:= Make_Temporary
(Loc
, 'E');
8179 Set_Defining_Unit_Name
(New_Spec
, Anon_Id
);
8180 Insert_Before
(Instantiation_Node
, Decl_Node
);
8181 Analyze
(Decl_Node
);
8183 -- Now create renaming within the instance
8186 Make_Subprogram_Renaming_Declaration
(Loc
,
8187 Specification
=> New_Copy_Tree
(New_Spec
),
8188 Name
=> New_Occurrence_Of
(Anon_Id
, Loc
));
8190 Set_Defining_Unit_Name
(Specification
(Decl_Node
),
8191 Make_Defining_Identifier
(Loc
, Chars
(Formal_Sub
)));
8196 end Instantiate_Formal_Subprogram
;
8198 ------------------------
8199 -- Instantiate_Object --
8200 ------------------------
8202 function Instantiate_Object
8205 Analyzed_Formal
: Node_Id
) return List_Id
8207 Acc_Def
: Node_Id
:= Empty
;
8208 Act_Assoc
: constant Node_Id
:= Parent
(Actual
);
8209 Actual_Decl
: Node_Id
:= Empty
;
8210 Formal_Id
: constant Entity_Id
:= Defining_Identifier
(Formal
);
8211 Decl_Node
: Node_Id
;
8214 List
: constant List_Id
:= New_List
;
8215 Loc
: constant Source_Ptr
:= Sloc
(Actual
);
8216 Orig_Ftyp
: constant Entity_Id
:=
8217 Etype
(Defining_Identifier
(Analyzed_Formal
));
8218 Subt_Decl
: Node_Id
:= Empty
;
8219 Subt_Mark
: Node_Id
:= Empty
;
8222 if Present
(Subtype_Mark
(Formal
)) then
8223 Subt_Mark
:= Subtype_Mark
(Formal
);
8225 Check_Access_Definition
(Formal
);
8226 Acc_Def
:= Access_Definition
(Formal
);
8229 -- Sloc for error message on missing actual
8231 Error_Msg_Sloc
:= Sloc
(Scope
(Defining_Identifier
(Analyzed_Formal
)));
8233 if Get_Instance_Of
(Formal_Id
) /= Formal_Id
then
8234 Error_Msg_N
("duplicate instantiation of generic parameter", Actual
);
8237 Set_Parent
(List
, Parent
(Actual
));
8241 if Out_Present
(Formal
) then
8243 -- An IN OUT generic actual must be a name. The instantiation is a
8244 -- renaming declaration. The actual is the name being renamed. We
8245 -- use the actual directly, rather than a copy, because it is not
8246 -- used further in the list of actuals, and because a copy or a use
8247 -- of relocate_node is incorrect if the instance is nested within a
8248 -- generic. In order to simplify ASIS searches, the Generic_Parent
8249 -- field links the declaration to the generic association.
8254 Instantiation_Node
, Formal_Id
);
8256 ("\in instantiation of & declared#",
8258 Scope
(Defining_Identifier
(Analyzed_Formal
)));
8259 Abandon_Instantiation
(Instantiation_Node
);
8262 if Present
(Subt_Mark
) then
8264 Make_Object_Renaming_Declaration
(Loc
,
8265 Defining_Identifier
=> New_Copy
(Formal_Id
),
8266 Subtype_Mark
=> New_Copy_Tree
(Subt_Mark
),
8269 else pragma Assert
(Present
(Acc_Def
));
8271 Make_Object_Renaming_Declaration
(Loc
,
8272 Defining_Identifier
=> New_Copy
(Formal_Id
),
8273 Access_Definition
=> New_Copy_Tree
(Acc_Def
),
8277 Set_Corresponding_Generic_Association
(Decl_Node
, Act_Assoc
);
8279 -- The analysis of the actual may produce insert_action nodes, so
8280 -- the declaration must have a context in which to attach them.
8282 Append
(Decl_Node
, List
);
8285 -- Return if the analysis of the actual reported some error
8287 if Etype
(Actual
) = Any_Type
then
8291 -- This check is performed here because Analyze_Object_Renaming will
8292 -- not check it when Comes_From_Source is False. Note though that the
8293 -- check for the actual being the name of an object will be performed
8294 -- in Analyze_Object_Renaming.
8296 if Is_Object_Reference
(Actual
)
8297 and then Is_Dependent_Component_Of_Mutable_Object
(Actual
)
8300 ("illegal discriminant-dependent component for in out parameter",
8304 -- The actual has to be resolved in order to check that it is a
8305 -- variable (due to cases such as F(1), where F returns
8306 -- access to an array, and for overloaded prefixes).
8309 Get_Instance_Of
(Etype
(Defining_Identifier
(Analyzed_Formal
)));
8311 if Is_Private_Type
(Ftyp
)
8312 and then not Is_Private_Type
(Etype
(Actual
))
8313 and then (Base_Type
(Full_View
(Ftyp
)) = Base_Type
(Etype
(Actual
))
8314 or else Base_Type
(Etype
(Actual
)) = Ftyp
)
8316 -- If the actual has the type of the full view of the formal, or
8317 -- else a non-private subtype of the formal, then the visibility
8318 -- of the formal type has changed. Add to the actuals a subtype
8319 -- declaration that will force the exchange of views in the body
8320 -- of the instance as well.
8323 Make_Subtype_Declaration
(Loc
,
8324 Defining_Identifier
=> Make_Temporary
(Loc
, 'P'),
8325 Subtype_Indication
=> New_Occurrence_Of
(Ftyp
, Loc
));
8327 Prepend
(Subt_Decl
, List
);
8329 Prepend_Elmt
(Full_View
(Ftyp
), Exchanged_Views
);
8330 Exchange_Declarations
(Ftyp
);
8333 Resolve
(Actual
, Ftyp
);
8335 if not Denotes_Variable
(Actual
) then
8337 ("actual for& must be a variable", Actual
, Formal_Id
);
8339 elsif Base_Type
(Ftyp
) /= Base_Type
(Etype
(Actual
)) then
8341 -- Ada 2005 (AI-423): For a generic formal object of mode in out,
8342 -- the type of the actual shall resolve to a specific anonymous
8345 if Ada_Version
< Ada_05
8347 Ekind
(Base_Type
(Ftyp
)) /=
8348 E_Anonymous_Access_Type
8350 Ekind
(Base_Type
(Etype
(Actual
))) /=
8351 E_Anonymous_Access_Type
8353 Error_Msg_NE
("type of actual does not match type of&",
8358 Note_Possible_Modification
(Actual
, Sure
=> True);
8360 -- Check for instantiation of atomic/volatile actual for
8361 -- non-atomic/volatile formal (RM C.6 (12)).
8363 if Is_Atomic_Object
(Actual
)
8364 and then not Is_Atomic
(Orig_Ftyp
)
8367 ("cannot instantiate non-atomic formal object " &
8368 "with atomic actual", Actual
);
8370 elsif Is_Volatile_Object
(Actual
)
8371 and then not Is_Volatile
(Orig_Ftyp
)
8374 ("cannot instantiate non-volatile formal object " &
8375 "with volatile actual", Actual
);
8378 -- Formal in-parameter
8381 -- The instantiation of a generic formal in-parameter is constant
8382 -- declaration. The actual is the expression for that declaration.
8384 if Present
(Actual
) then
8385 if Present
(Subt_Mark
) then
8387 else pragma Assert
(Present
(Acc_Def
));
8392 Make_Object_Declaration
(Loc
,
8393 Defining_Identifier
=> New_Copy
(Formal_Id
),
8394 Constant_Present
=> True,
8395 Null_Exclusion_Present
=> Null_Exclusion_Present
(Formal
),
8396 Object_Definition
=> New_Copy_Tree
(Def
),
8397 Expression
=> Actual
);
8399 Set_Corresponding_Generic_Association
(Decl_Node
, Act_Assoc
);
8401 -- A generic formal object of a tagged type is defined to be
8402 -- aliased so the new constant must also be treated as aliased.
8405 (Etype
(Defining_Identifier
(Analyzed_Formal
)))
8407 Set_Aliased_Present
(Decl_Node
);
8410 Append
(Decl_Node
, List
);
8412 -- No need to repeat (pre-)analysis of some expression nodes
8413 -- already handled in Preanalyze_Actuals.
8415 if Nkind
(Actual
) /= N_Allocator
then
8418 -- Return if the analysis of the actual reported some error
8420 if Etype
(Actual
) = Any_Type
then
8426 Formal_Object
: constant Entity_Id
:=
8427 Defining_Identifier
(Analyzed_Formal
);
8428 Formal_Type
: constant Entity_Id
:= Etype
(Formal_Object
);
8433 Typ
:= Get_Instance_Of
(Formal_Type
);
8435 Freeze_Before
(Instantiation_Node
, Typ
);
8437 -- If the actual is an aggregate, perform name resolution on
8438 -- its components (the analysis of an aggregate does not do it)
8439 -- to capture local names that may be hidden if the generic is
8442 if Nkind
(Actual
) = N_Aggregate
then
8443 Preanalyze_And_Resolve
(Actual
, Typ
);
8446 if Is_Limited_Type
(Typ
)
8447 and then not OK_For_Limited_Init
(Typ
, Actual
)
8450 ("initialization not allowed for limited types", Actual
);
8451 Explain_Limited_Type
(Typ
, Actual
);
8455 elsif Present
(Default_Expression
(Formal
)) then
8457 -- Use default to construct declaration
8459 if Present
(Subt_Mark
) then
8461 else pragma Assert
(Present
(Acc_Def
));
8466 Make_Object_Declaration
(Sloc
(Formal
),
8467 Defining_Identifier
=> New_Copy
(Formal_Id
),
8468 Constant_Present
=> True,
8469 Null_Exclusion_Present
=> Null_Exclusion_Present
(Formal
),
8470 Object_Definition
=> New_Copy
(Def
),
8471 Expression
=> New_Copy_Tree
8472 (Default_Expression
(Formal
)));
8474 Append
(Decl_Node
, List
);
8475 Set_Analyzed
(Expression
(Decl_Node
), False);
8480 Instantiation_Node
, Formal_Id
);
8481 Error_Msg_NE
("\in instantiation of & declared#",
8483 Scope
(Defining_Identifier
(Analyzed_Formal
)));
8486 (Etype
(Defining_Identifier
(Analyzed_Formal
)))
8488 -- Create dummy constant declaration so that instance can be
8489 -- analyzed, to minimize cascaded visibility errors.
8491 if Present
(Subt_Mark
) then
8493 else pragma Assert
(Present
(Acc_Def
));
8498 Make_Object_Declaration
(Loc
,
8499 Defining_Identifier
=> New_Copy
(Formal_Id
),
8500 Constant_Present
=> True,
8501 Null_Exclusion_Present
=> Null_Exclusion_Present
(Formal
),
8502 Object_Definition
=> New_Copy
(Def
),
8504 Make_Attribute_Reference
(Sloc
(Formal_Id
),
8505 Attribute_Name
=> Name_First
,
8506 Prefix
=> New_Copy
(Def
)));
8508 Append
(Decl_Node
, List
);
8511 Abandon_Instantiation
(Instantiation_Node
);
8516 if Nkind
(Actual
) in N_Has_Entity
then
8517 Actual_Decl
:= Parent
(Entity
(Actual
));
8520 -- Ada 2005 (AI-423): For a formal object declaration with a null
8521 -- exclusion or an access definition that has a null exclusion: If the
8522 -- actual matching the formal object declaration denotes a generic
8523 -- formal object of another generic unit G, and the instantiation
8524 -- containing the actual occurs within the body of G or within the body
8525 -- of a generic unit declared within the declarative region of G, then
8526 -- the declaration of the formal object of G must have a null exclusion.
8527 -- Otherwise, the subtype of the actual matching the formal object
8528 -- declaration shall exclude null.
8530 if Ada_Version
>= Ada_05
8531 and then Present
(Actual_Decl
)
8533 Nkind_In
(Actual_Decl
, N_Formal_Object_Declaration
,
8534 N_Object_Declaration
)
8535 and then Nkind
(Analyzed_Formal
) = N_Formal_Object_Declaration
8536 and then not Has_Null_Exclusion
(Actual_Decl
)
8537 and then Has_Null_Exclusion
(Analyzed_Formal
)
8539 Error_Msg_Sloc
:= Sloc
(Analyzed_Formal
);
8541 ("actual must exclude null to match generic formal#", Actual
);
8545 end Instantiate_Object
;
8547 ------------------------------
8548 -- Instantiate_Package_Body --
8549 ------------------------------
8551 procedure Instantiate_Package_Body
8552 (Body_Info
: Pending_Body_Info
;
8553 Inlined_Body
: Boolean := False;
8554 Body_Optional
: Boolean := False)
8556 Act_Decl
: constant Node_Id
:= Body_Info
.Act_Decl
;
8557 Inst_Node
: constant Node_Id
:= Body_Info
.Inst_Node
;
8558 Loc
: constant Source_Ptr
:= Sloc
(Inst_Node
);
8560 Gen_Id
: constant Node_Id
:= Name
(Inst_Node
);
8561 Gen_Unit
: constant Entity_Id
:= Get_Generic_Entity
(Inst_Node
);
8562 Gen_Decl
: constant Node_Id
:= Unit_Declaration_Node
(Gen_Unit
);
8563 Act_Spec
: constant Node_Id
:= Specification
(Act_Decl
);
8564 Act_Decl_Id
: constant Entity_Id
:= Defining_Entity
(Act_Spec
);
8566 Act_Body_Name
: Node_Id
;
8568 Gen_Body_Id
: Node_Id
;
8570 Act_Body_Id
: Entity_Id
;
8572 Parent_Installed
: Boolean := False;
8573 Save_Style_Check
: constant Boolean := Style_Check
;
8575 Par_Ent
: Entity_Id
:= Empty
;
8576 Par_Vis
: Boolean := False;
8579 Gen_Body_Id
:= Corresponding_Body
(Gen_Decl
);
8581 -- The instance body may already have been processed, as the parent of
8582 -- another instance that is inlined (Load_Parent_Of_Generic).
8584 if Present
(Corresponding_Body
(Instance_Spec
(Inst_Node
))) then
8588 Expander_Mode_Save_And_Set
(Body_Info
.Expander_Status
);
8590 -- Re-establish the state of information on which checks are suppressed.
8591 -- This information was set in Body_Info at the point of instantiation,
8592 -- and now we restore it so that the instance is compiled using the
8593 -- check status at the instantiation (RM 11.5 (7.2/2), AI95-00224-01).
8595 Local_Suppress_Stack_Top
:= Body_Info
.Local_Suppress_Stack_Top
;
8596 Scope_Suppress
:= Body_Info
.Scope_Suppress
;
8597 Opt
.Ada_Version
:= Body_Info
.Version
;
8599 if No
(Gen_Body_Id
) then
8600 Load_Parent_Of_Generic
8601 (Inst_Node
, Specification
(Gen_Decl
), Body_Optional
);
8602 Gen_Body_Id
:= Corresponding_Body
(Gen_Decl
);
8605 Mark_Context
(Act_Decl
, Gen_Decl
);
8607 -- Establish global variable for sloc adjustment and for error recovery
8609 Instantiation_Node
:= Inst_Node
;
8611 if Present
(Gen_Body_Id
) then
8612 Save_Env
(Gen_Unit
, Act_Decl_Id
);
8613 Style_Check
:= False;
8614 Current_Sem_Unit
:= Body_Info
.Current_Sem_Unit
;
8616 Gen_Body
:= Unit_Declaration_Node
(Gen_Body_Id
);
8618 Create_Instantiation_Source
8619 (Inst_Node
, Gen_Body_Id
, False, S_Adjustment
);
8623 (Original_Node
(Gen_Body
), Empty
, Instantiating
=> True);
8625 -- Build new name (possibly qualified) for body declaration
8627 Act_Body_Id
:= New_Copy
(Act_Decl_Id
);
8629 -- Some attributes of spec entity are not inherited by body entity
8631 Set_Handler_Records
(Act_Body_Id
, No_List
);
8633 if Nkind
(Defining_Unit_Name
(Act_Spec
)) =
8634 N_Defining_Program_Unit_Name
8637 Make_Defining_Program_Unit_Name
(Loc
,
8638 Name
=> New_Copy_Tree
(Name
(Defining_Unit_Name
(Act_Spec
))),
8639 Defining_Identifier
=> Act_Body_Id
);
8641 Act_Body_Name
:= Act_Body_Id
;
8644 Set_Defining_Unit_Name
(Act_Body
, Act_Body_Name
);
8646 Set_Corresponding_Spec
(Act_Body
, Act_Decl_Id
);
8647 Check_Generic_Actuals
(Act_Decl_Id
, False);
8649 -- If it is a child unit, make the parent instance (which is an
8650 -- instance of the parent of the generic) visible. The parent
8651 -- instance is the prefix of the name of the generic unit.
8653 if Ekind
(Scope
(Gen_Unit
)) = E_Generic_Package
8654 and then Nkind
(Gen_Id
) = N_Expanded_Name
8656 Par_Ent
:= Entity
(Prefix
(Gen_Id
));
8657 Par_Vis
:= Is_Immediately_Visible
(Par_Ent
);
8658 Install_Parent
(Par_Ent
, In_Body
=> True);
8659 Parent_Installed
:= True;
8661 elsif Is_Child_Unit
(Gen_Unit
) then
8662 Par_Ent
:= Scope
(Gen_Unit
);
8663 Par_Vis
:= Is_Immediately_Visible
(Par_Ent
);
8664 Install_Parent
(Par_Ent
, In_Body
=> True);
8665 Parent_Installed
:= True;
8668 -- If the instantiation is a library unit, and this is the main unit,
8669 -- then build the resulting compilation unit nodes for the instance.
8670 -- If this is a compilation unit but it is not the main unit, then it
8671 -- is the body of a unit in the context, that is being compiled
8672 -- because it is encloses some inlined unit or another generic unit
8673 -- being instantiated. In that case, this body is not part of the
8674 -- current compilation, and is not attached to the tree, but its
8675 -- parent must be set for analysis.
8677 if Nkind
(Parent
(Inst_Node
)) = N_Compilation_Unit
then
8679 -- Replace instance node with body of instance, and create new
8680 -- node for corresponding instance declaration.
8682 Build_Instance_Compilation_Unit_Nodes
8683 (Inst_Node
, Act_Body
, Act_Decl
);
8684 Analyze
(Inst_Node
);
8686 if Parent
(Inst_Node
) = Cunit
(Main_Unit
) then
8688 -- If the instance is a child unit itself, then set the scope
8689 -- of the expanded body to be the parent of the instantiation
8690 -- (ensuring that the fully qualified name will be generated
8691 -- for the elaboration subprogram).
8693 if Nkind
(Defining_Unit_Name
(Act_Spec
)) =
8694 N_Defining_Program_Unit_Name
8697 (Defining_Entity
(Inst_Node
), Scope
(Act_Decl_Id
));
8701 -- Case where instantiation is not a library unit
8704 -- If this is an early instantiation, i.e. appears textually
8705 -- before the corresponding body and must be elaborated first,
8706 -- indicate that the body instance is to be delayed.
8708 Install_Body
(Act_Body
, Inst_Node
, Gen_Body
, Gen_Decl
);
8710 -- Now analyze the body. We turn off all checks if this is an
8711 -- internal unit, since there is no reason to have checks on for
8712 -- any predefined run-time library code. All such code is designed
8713 -- to be compiled with checks off.
8715 -- Note that we do NOT apply this criterion to children of GNAT
8716 -- (or on VMS, children of DEC). The latter units must suppress
8717 -- checks explicitly if this is needed.
8719 if Is_Predefined_File_Name
8720 (Unit_File_Name
(Get_Source_Unit
(Gen_Decl
)))
8722 Analyze
(Act_Body
, Suppress
=> All_Checks
);
8728 Inherit_Context
(Gen_Body
, Inst_Node
);
8730 -- Remove the parent instances if they have been placed on the scope
8731 -- stack to compile the body.
8733 if Parent_Installed
then
8734 Remove_Parent
(In_Body
=> True);
8736 -- Restore the previous visibility of the parent
8738 Set_Is_Immediately_Visible
(Par_Ent
, Par_Vis
);
8741 Restore_Private_Views
(Act_Decl_Id
);
8743 -- Remove the current unit from visibility if this is an instance
8744 -- that is not elaborated on the fly for inlining purposes.
8746 if not Inlined_Body
then
8747 Set_Is_Immediately_Visible
(Act_Decl_Id
, False);
8751 Style_Check
:= Save_Style_Check
;
8753 -- If we have no body, and the unit requires a body, then complain. This
8754 -- complaint is suppressed if we have detected other errors (since a
8755 -- common reason for missing the body is that it had errors).
8756 -- In CodePeer mode, a warning has been emitted already, no need for
8757 -- further messages.
8759 elsif Unit_Requires_Body
(Gen_Unit
)
8760 and then not Body_Optional
8762 if CodePeer_Mode
then
8765 elsif Serious_Errors_Detected
= 0 then
8767 ("cannot find body of generic package &", Inst_Node
, Gen_Unit
);
8769 -- Don't attempt to perform any cleanup actions if some other error
8770 -- was already detected, since this can cause blowups.
8776 -- Case of package that does not need a body
8779 -- If the instantiation of the declaration is a library unit, rewrite
8780 -- the original package instantiation as a package declaration in the
8781 -- compilation unit node.
8783 if Nkind
(Parent
(Inst_Node
)) = N_Compilation_Unit
then
8784 Set_Parent_Spec
(Act_Decl
, Parent_Spec
(Inst_Node
));
8785 Rewrite
(Inst_Node
, Act_Decl
);
8787 -- Generate elaboration entity, in case spec has elaboration code.
8788 -- This cannot be done when the instance is analyzed, because it
8789 -- is not known yet whether the body exists.
8791 Set_Elaboration_Entity_Required
(Act_Decl_Id
, False);
8792 Build_Elaboration_Entity
(Parent
(Inst_Node
), Act_Decl_Id
);
8794 -- If the instantiation is not a library unit, then append the
8795 -- declaration to the list of implicitly generated entities, unless
8796 -- it is already a list member which means that it was already
8799 elsif not Is_List_Member
(Act_Decl
) then
8800 Mark_Rewrite_Insertion
(Act_Decl
);
8801 Insert_Before
(Inst_Node
, Act_Decl
);
8805 Expander_Mode_Restore
;
8806 end Instantiate_Package_Body
;
8808 ---------------------------------
8809 -- Instantiate_Subprogram_Body --
8810 ---------------------------------
8812 procedure Instantiate_Subprogram_Body
8813 (Body_Info
: Pending_Body_Info
;
8814 Body_Optional
: Boolean := False)
8816 Act_Decl
: constant Node_Id
:= Body_Info
.Act_Decl
;
8817 Inst_Node
: constant Node_Id
:= Body_Info
.Inst_Node
;
8818 Loc
: constant Source_Ptr
:= Sloc
(Inst_Node
);
8819 Gen_Id
: constant Node_Id
:= Name
(Inst_Node
);
8820 Gen_Unit
: constant Entity_Id
:= Get_Generic_Entity
(Inst_Node
);
8821 Gen_Decl
: constant Node_Id
:= Unit_Declaration_Node
(Gen_Unit
);
8822 Anon_Id
: constant Entity_Id
:=
8823 Defining_Unit_Name
(Specification
(Act_Decl
));
8824 Pack_Id
: constant Entity_Id
:=
8825 Defining_Unit_Name
(Parent
(Act_Decl
));
8828 Gen_Body_Id
: Node_Id
;
8830 Pack_Body
: Node_Id
;
8831 Prev_Formal
: Entity_Id
;
8833 Unit_Renaming
: Node_Id
;
8835 Parent_Installed
: Boolean := False;
8836 Save_Style_Check
: constant Boolean := Style_Check
;
8838 Par_Ent
: Entity_Id
:= Empty
;
8839 Par_Vis
: Boolean := False;
8842 Gen_Body_Id
:= Corresponding_Body
(Gen_Decl
);
8844 -- Subprogram body may have been created already because of an inline
8845 -- pragma, or because of multiple elaborations of the enclosing package
8846 -- when several instances of the subprogram appear in the main unit.
8848 if Present
(Corresponding_Body
(Act_Decl
)) then
8852 Expander_Mode_Save_And_Set
(Body_Info
.Expander_Status
);
8854 -- Re-establish the state of information on which checks are suppressed.
8855 -- This information was set in Body_Info at the point of instantiation,
8856 -- and now we restore it so that the instance is compiled using the
8857 -- check status at the instantiation (RM 11.5 (7.2/2), AI95-00224-01).
8859 Local_Suppress_Stack_Top
:= Body_Info
.Local_Suppress_Stack_Top
;
8860 Scope_Suppress
:= Body_Info
.Scope_Suppress
;
8861 Opt
.Ada_Version
:= Body_Info
.Version
;
8863 if No
(Gen_Body_Id
) then
8865 -- For imported generic subprogram, no body to compile, complete
8866 -- the spec entity appropriately.
8868 if Is_Imported
(Gen_Unit
) then
8869 Set_Is_Imported
(Anon_Id
);
8870 Set_First_Rep_Item
(Anon_Id
, First_Rep_Item
(Gen_Unit
));
8871 Set_Interface_Name
(Anon_Id
, Interface_Name
(Gen_Unit
));
8872 Set_Convention
(Anon_Id
, Convention
(Gen_Unit
));
8873 Set_Has_Completion
(Anon_Id
);
8876 -- For other cases, compile the body
8879 Load_Parent_Of_Generic
8880 (Inst_Node
, Specification
(Gen_Decl
), Body_Optional
);
8881 Gen_Body_Id
:= Corresponding_Body
(Gen_Decl
);
8885 Instantiation_Node
:= Inst_Node
;
8887 if Present
(Gen_Body_Id
) then
8888 Gen_Body
:= Unit_Declaration_Node
(Gen_Body_Id
);
8889 Mark_Context
(Inst_Node
, Gen_Decl
);
8891 if Nkind
(Gen_Body
) = N_Subprogram_Body_Stub
then
8893 -- Either body is not present, or context is non-expanding, as
8894 -- when compiling a subunit. Mark the instance as completed, and
8895 -- diagnose a missing body when needed.
8898 and then Operating_Mode
= Generate_Code
8901 ("missing proper body for instantiation", Gen_Body
);
8904 Set_Has_Completion
(Anon_Id
);
8908 Save_Env
(Gen_Unit
, Anon_Id
);
8909 Style_Check
:= False;
8910 Current_Sem_Unit
:= Body_Info
.Current_Sem_Unit
;
8911 Create_Instantiation_Source
8919 (Original_Node
(Gen_Body
), Empty
, Instantiating
=> True);
8921 -- Create proper defining name for the body, to correspond to
8922 -- the one in the spec.
8924 Set_Defining_Unit_Name
(Specification
(Act_Body
),
8925 Make_Defining_Identifier
8926 (Sloc
(Defining_Entity
(Inst_Node
)), Chars
(Anon_Id
)));
8927 Set_Corresponding_Spec
(Act_Body
, Anon_Id
);
8928 Set_Has_Completion
(Anon_Id
);
8929 Check_Generic_Actuals
(Pack_Id
, False);
8931 -- Generate a reference to link the visible subprogram instance to
8932 -- the generic body, which for navigation purposes is the only
8933 -- available source for the instance.
8936 (Related_Instance
(Pack_Id
),
8937 Gen_Body_Id
, 'b', Set_Ref
=> False, Force
=> True);
8939 -- If it is a child unit, make the parent instance (which is an
8940 -- instance of the parent of the generic) visible. The parent
8941 -- instance is the prefix of the name of the generic unit.
8943 if Ekind
(Scope
(Gen_Unit
)) = E_Generic_Package
8944 and then Nkind
(Gen_Id
) = N_Expanded_Name
8946 Par_Ent
:= Entity
(Prefix
(Gen_Id
));
8947 Par_Vis
:= Is_Immediately_Visible
(Par_Ent
);
8948 Install_Parent
(Par_Ent
, In_Body
=> True);
8949 Parent_Installed
:= True;
8951 elsif Is_Child_Unit
(Gen_Unit
) then
8952 Par_Ent
:= Scope
(Gen_Unit
);
8953 Par_Vis
:= Is_Immediately_Visible
(Par_Ent
);
8954 Install_Parent
(Par_Ent
, In_Body
=> True);
8955 Parent_Installed
:= True;
8958 -- Inside its body, a reference to the generic unit is a reference
8959 -- to the instance. The corresponding renaming is the first
8960 -- declaration in the body.
8963 Make_Subprogram_Renaming_Declaration
(Loc
,
8966 Specification
(Original_Node
(Gen_Body
)),
8968 Instantiating
=> True),
8969 Name
=> New_Occurrence_Of
(Anon_Id
, Loc
));
8971 -- If there is a formal subprogram with the same name as the unit
8972 -- itself, do not add this renaming declaration. This is a temporary
8973 -- fix for one ACVC test. ???
8975 Prev_Formal
:= First_Entity
(Pack_Id
);
8976 while Present
(Prev_Formal
) loop
8977 if Chars
(Prev_Formal
) = Chars
(Gen_Unit
)
8978 and then Is_Overloadable
(Prev_Formal
)
8983 Next_Entity
(Prev_Formal
);
8986 if Present
(Prev_Formal
) then
8987 Decls
:= New_List
(Act_Body
);
8989 Decls
:= New_List
(Unit_Renaming
, Act_Body
);
8992 -- The subprogram body is placed in the body of a dummy package body,
8993 -- whose spec contains the subprogram declaration as well as the
8994 -- renaming declarations for the generic parameters.
8996 Pack_Body
:= Make_Package_Body
(Loc
,
8997 Defining_Unit_Name
=> New_Copy
(Pack_Id
),
8998 Declarations
=> Decls
);
9000 Set_Corresponding_Spec
(Pack_Body
, Pack_Id
);
9002 -- If the instantiation is a library unit, then build resulting
9003 -- compilation unit nodes for the instance. The declaration of
9004 -- the enclosing package is the grandparent of the subprogram
9005 -- declaration. First replace the instantiation node as the unit
9006 -- of the corresponding compilation.
9008 if Nkind
(Parent
(Inst_Node
)) = N_Compilation_Unit
then
9009 if Parent
(Inst_Node
) = Cunit
(Main_Unit
) then
9010 Set_Unit
(Parent
(Inst_Node
), Inst_Node
);
9011 Build_Instance_Compilation_Unit_Nodes
9012 (Inst_Node
, Pack_Body
, Parent
(Parent
(Act_Decl
)));
9013 Analyze
(Inst_Node
);
9015 Set_Parent
(Pack_Body
, Parent
(Inst_Node
));
9016 Analyze
(Pack_Body
);
9020 Insert_Before
(Inst_Node
, Pack_Body
);
9021 Mark_Rewrite_Insertion
(Pack_Body
);
9022 Analyze
(Pack_Body
);
9024 if Expander_Active
then
9025 Freeze_Subprogram_Body
(Inst_Node
, Gen_Body
, Pack_Id
);
9029 Inherit_Context
(Gen_Body
, Inst_Node
);
9031 Restore_Private_Views
(Pack_Id
, False);
9033 if Parent_Installed
then
9034 Remove_Parent
(In_Body
=> True);
9036 -- Restore the previous visibility of the parent
9038 Set_Is_Immediately_Visible
(Par_Ent
, Par_Vis
);
9042 Style_Check
:= Save_Style_Check
;
9044 -- Body not found. Error was emitted already. If there were no previous
9045 -- errors, this may be an instance whose scope is a premature instance.
9046 -- In that case we must insure that the (legal) program does raise
9047 -- program error if executed. We generate a subprogram body for this
9048 -- purpose. See DEC ac30vso.
9050 -- Should not reference proprietary DEC tests in comments ???
9052 elsif Serious_Errors_Detected
= 0
9053 and then Nkind
(Parent
(Inst_Node
)) /= N_Compilation_Unit
9055 if Body_Optional
then
9058 elsif Ekind
(Anon_Id
) = E_Procedure
then
9060 Make_Subprogram_Body
(Loc
,
9062 Make_Procedure_Specification
(Loc
,
9063 Defining_Unit_Name
=>
9064 Make_Defining_Identifier
(Loc
, Chars
(Anon_Id
)),
9065 Parameter_Specifications
=>
9067 (Parameter_Specifications
(Parent
(Anon_Id
)))),
9069 Declarations
=> Empty_List
,
9070 Handled_Statement_Sequence
=>
9071 Make_Handled_Sequence_Of_Statements
(Loc
,
9074 Make_Raise_Program_Error
(Loc
,
9076 PE_Access_Before_Elaboration
))));
9080 Make_Raise_Program_Error
(Loc
,
9081 Reason
=> PE_Access_Before_Elaboration
);
9083 Set_Etype
(Ret_Expr
, (Etype
(Anon_Id
)));
9084 Set_Analyzed
(Ret_Expr
);
9087 Make_Subprogram_Body
(Loc
,
9089 Make_Function_Specification
(Loc
,
9090 Defining_Unit_Name
=>
9091 Make_Defining_Identifier
(Loc
, Chars
(Anon_Id
)),
9092 Parameter_Specifications
=>
9094 (Parameter_Specifications
(Parent
(Anon_Id
))),
9095 Result_Definition
=>
9096 New_Occurrence_Of
(Etype
(Anon_Id
), Loc
)),
9098 Declarations
=> Empty_List
,
9099 Handled_Statement_Sequence
=>
9100 Make_Handled_Sequence_Of_Statements
(Loc
,
9103 (Make_Simple_Return_Statement
(Loc
, Ret_Expr
))));
9106 Pack_Body
:= Make_Package_Body
(Loc
,
9107 Defining_Unit_Name
=> New_Copy
(Pack_Id
),
9108 Declarations
=> New_List
(Act_Body
));
9110 Insert_After
(Inst_Node
, Pack_Body
);
9111 Set_Corresponding_Spec
(Pack_Body
, Pack_Id
);
9112 Analyze
(Pack_Body
);
9115 Expander_Mode_Restore
;
9116 end Instantiate_Subprogram_Body
;
9118 ----------------------
9119 -- Instantiate_Type --
9120 ----------------------
9122 function Instantiate_Type
9125 Analyzed_Formal
: Node_Id
;
9126 Actual_Decls
: List_Id
) return List_Id
9128 Gen_T
: constant Entity_Id
:= Defining_Identifier
(Formal
);
9129 A_Gen_T
: constant Entity_Id
:=
9130 Defining_Identifier
(Analyzed_Formal
);
9131 Ancestor
: Entity_Id
:= Empty
;
9132 Def
: constant Node_Id
:= Formal_Type_Definition
(Formal
);
9134 Decl_Node
: Node_Id
;
9135 Decl_Nodes
: List_Id
;
9139 procedure Validate_Array_Type_Instance
;
9140 procedure Validate_Access_Subprogram_Instance
;
9141 procedure Validate_Access_Type_Instance
;
9142 procedure Validate_Derived_Type_Instance
;
9143 procedure Validate_Derived_Interface_Type_Instance
;
9144 procedure Validate_Interface_Type_Instance
;
9145 procedure Validate_Private_Type_Instance
;
9146 -- These procedures perform validation tests for the named case
9148 function Subtypes_Match
(Gen_T
, Act_T
: Entity_Id
) return Boolean;
9149 -- Check that base types are the same and that the subtypes match
9150 -- statically. Used in several of the above.
9152 --------------------
9153 -- Subtypes_Match --
9154 --------------------
9156 function Subtypes_Match
(Gen_T
, Act_T
: Entity_Id
) return Boolean is
9157 T
: constant Entity_Id
:= Get_Instance_Of
(Gen_T
);
9160 return (Base_Type
(T
) = Base_Type
(Act_T
)
9161 and then Subtypes_Statically_Match
(T
, Act_T
))
9163 or else (Is_Class_Wide_Type
(Gen_T
)
9164 and then Is_Class_Wide_Type
(Act_T
)
9167 (Get_Instance_Of
(Root_Type
(Gen_T
)),
9171 ((Ekind
(Gen_T
) = E_Anonymous_Access_Subprogram_Type
9172 or else Ekind
(Gen_T
) = E_Anonymous_Access_Type
)
9173 and then Ekind
(Act_T
) = Ekind
(Gen_T
)
9175 Subtypes_Statically_Match
9176 (Designated_Type
(Gen_T
), Designated_Type
(Act_T
)));
9179 -----------------------------------------
9180 -- Validate_Access_Subprogram_Instance --
9181 -----------------------------------------
9183 procedure Validate_Access_Subprogram_Instance
is
9185 if not Is_Access_Type
(Act_T
)
9186 or else Ekind
(Designated_Type
(Act_T
)) /= E_Subprogram_Type
9189 ("expect access type in instantiation of &", Actual
, Gen_T
);
9190 Abandon_Instantiation
(Actual
);
9193 Check_Mode_Conformant
9194 (Designated_Type
(Act_T
),
9195 Designated_Type
(A_Gen_T
),
9199 if Ekind
(Base_Type
(Act_T
)) = E_Access_Protected_Subprogram_Type
then
9200 if Ekind
(A_Gen_T
) = E_Access_Subprogram_Type
then
9202 ("protected access type not allowed for formal &",
9206 elsif Ekind
(A_Gen_T
) = E_Access_Protected_Subprogram_Type
then
9208 ("expect protected access type for formal &",
9211 end Validate_Access_Subprogram_Instance
;
9213 -----------------------------------
9214 -- Validate_Access_Type_Instance --
9215 -----------------------------------
9217 procedure Validate_Access_Type_Instance
is
9218 Desig_Type
: constant Entity_Id
:=
9219 Find_Actual_Type
(Designated_Type
(A_Gen_T
), A_Gen_T
);
9220 Desig_Act
: Entity_Id
;
9223 if not Is_Access_Type
(Act_T
) then
9225 ("expect access type in instantiation of &", Actual
, Gen_T
);
9226 Abandon_Instantiation
(Actual
);
9229 if Is_Access_Constant
(A_Gen_T
) then
9230 if not Is_Access_Constant
(Act_T
) then
9232 ("actual type must be access-to-constant type", Actual
);
9233 Abandon_Instantiation
(Actual
);
9236 if Is_Access_Constant
(Act_T
) then
9238 ("actual type must be access-to-variable type", Actual
);
9239 Abandon_Instantiation
(Actual
);
9241 elsif Ekind
(A_Gen_T
) = E_General_Access_Type
9242 and then Ekind
(Base_Type
(Act_T
)) /= E_General_Access_Type
9244 Error_Msg_N
-- CODEFIX
9245 ("actual must be general access type!", Actual
);
9246 Error_Msg_NE
-- CODEFIX
9247 ("add ALL to }!", Actual
, Act_T
);
9248 Abandon_Instantiation
(Actual
);
9252 -- The designated subtypes, that is to say the subtypes introduced
9253 -- by an access type declaration (and not by a subtype declaration)
9256 Desig_Act
:= Designated_Type
(Base_Type
(Act_T
));
9258 -- The designated type may have been introduced through a limited_
9259 -- with clause, in which case retrieve the non-limited view. This
9260 -- applies to incomplete types as well as to class-wide types.
9262 if From_With_Type
(Desig_Act
) then
9263 Desig_Act
:= Available_View
(Desig_Act
);
9266 if not Subtypes_Match
9267 (Desig_Type
, Desig_Act
) then
9269 ("designated type of actual does not match that of formal &",
9271 Abandon_Instantiation
(Actual
);
9273 elsif Is_Access_Type
(Designated_Type
(Act_T
))
9274 and then Is_Constrained
(Designated_Type
(Designated_Type
(Act_T
)))
9276 Is_Constrained
(Designated_Type
(Desig_Type
))
9279 ("designated type of actual does not match that of formal &",
9281 Abandon_Instantiation
(Actual
);
9284 -- Ada 2005: null-exclusion indicators of the two types must agree
9286 if Can_Never_Be_Null
(A_Gen_T
) /= Can_Never_Be_Null
(Act_T
) then
9288 ("non null exclusion of actual and formal & do not match",
9291 end Validate_Access_Type_Instance
;
9293 ----------------------------------
9294 -- Validate_Array_Type_Instance --
9295 ----------------------------------
9297 procedure Validate_Array_Type_Instance
is
9302 function Formal_Dimensions
return Int
;
9303 -- Count number of dimensions in array type formal
9305 -----------------------
9306 -- Formal_Dimensions --
9307 -----------------------
9309 function Formal_Dimensions
return Int
is
9314 if Nkind
(Def
) = N_Constrained_Array_Definition
then
9315 Index
:= First
(Discrete_Subtype_Definitions
(Def
));
9317 Index
:= First
(Subtype_Marks
(Def
));
9320 while Present
(Index
) loop
9326 end Formal_Dimensions
;
9328 -- Start of processing for Validate_Array_Type_Instance
9331 if not Is_Array_Type
(Act_T
) then
9333 ("expect array type in instantiation of &", Actual
, Gen_T
);
9334 Abandon_Instantiation
(Actual
);
9336 elsif Nkind
(Def
) = N_Constrained_Array_Definition
then
9337 if not (Is_Constrained
(Act_T
)) then
9339 ("expect constrained array in instantiation of &",
9341 Abandon_Instantiation
(Actual
);
9345 if Is_Constrained
(Act_T
) then
9347 ("expect unconstrained array in instantiation of &",
9349 Abandon_Instantiation
(Actual
);
9353 if Formal_Dimensions
/= Number_Dimensions
(Act_T
) then
9355 ("dimensions of actual do not match formal &", Actual
, Gen_T
);
9356 Abandon_Instantiation
(Actual
);
9359 I1
:= First_Index
(A_Gen_T
);
9360 I2
:= First_Index
(Act_T
);
9361 for J
in 1 .. Formal_Dimensions
loop
9363 -- If the indices of the actual were given by a subtype_mark,
9364 -- the index was transformed into a range attribute. Retrieve
9365 -- the original type mark for checking.
9367 if Is_Entity_Name
(Original_Node
(I2
)) then
9368 T2
:= Entity
(Original_Node
(I2
));
9373 if not Subtypes_Match
9374 (Find_Actual_Type
(Etype
(I1
), A_Gen_T
), T2
)
9377 ("index types of actual do not match those of formal &",
9379 Abandon_Instantiation
(Actual
);
9386 -- Check matching subtypes. Note that there are complex visibility
9387 -- issues when the generic is a child unit and some aspect of the
9388 -- generic type is declared in a parent unit of the generic. We do
9389 -- the test to handle this special case only after a direct check
9390 -- for static matching has failed.
9393 (Component_Type
(A_Gen_T
), Component_Type
(Act_T
))
9394 or else Subtypes_Match
9395 (Find_Actual_Type
(Component_Type
(A_Gen_T
), A_Gen_T
),
9396 Component_Type
(Act_T
))
9401 ("component subtype of actual does not match that of formal &",
9403 Abandon_Instantiation
(Actual
);
9406 if Has_Aliased_Components
(A_Gen_T
)
9407 and then not Has_Aliased_Components
(Act_T
)
9410 ("actual must have aliased components to match formal type &",
9413 end Validate_Array_Type_Instance
;
9415 -----------------------------------------------
9416 -- Validate_Derived_Interface_Type_Instance --
9417 -----------------------------------------------
9419 procedure Validate_Derived_Interface_Type_Instance
is
9420 Par
: constant Entity_Id
:= Entity
(Subtype_Indication
(Def
));
9424 -- First apply interface instance checks
9426 Validate_Interface_Type_Instance
;
9428 -- Verify that immediate parent interface is an ancestor of
9432 and then not Interface_Present_In_Ancestor
(Act_T
, Par
)
9435 ("interface actual must include progenitor&", Actual
, Par
);
9438 -- Now verify that the actual includes all other ancestors of
9441 Elmt
:= First_Elmt
(Interfaces
(A_Gen_T
));
9442 while Present
(Elmt
) loop
9443 if not Interface_Present_In_Ancestor
9444 (Act_T
, Get_Instance_Of
(Node
(Elmt
)))
9447 ("interface actual must include progenitor&",
9448 Actual
, Node
(Elmt
));
9453 end Validate_Derived_Interface_Type_Instance
;
9455 ------------------------------------
9456 -- Validate_Derived_Type_Instance --
9457 ------------------------------------
9459 procedure Validate_Derived_Type_Instance
is
9460 Actual_Discr
: Entity_Id
;
9461 Ancestor_Discr
: Entity_Id
;
9464 -- If the parent type in the generic declaration is itself a previous
9465 -- formal type, then it is local to the generic and absent from the
9466 -- analyzed generic definition. In that case the ancestor is the
9467 -- instance of the formal (which must have been instantiated
9468 -- previously), unless the ancestor is itself a formal derived type.
9469 -- In this latter case (which is the subject of Corrigendum 8652/0038
9470 -- (AI-202) the ancestor of the formals is the ancestor of its
9471 -- parent. Otherwise, the analyzed generic carries the parent type.
9472 -- If the parent type is defined in a previous formal package, then
9473 -- the scope of that formal package is that of the generic type
9474 -- itself, and it has already been mapped into the corresponding type
9475 -- in the actual package.
9477 -- Common case: parent type defined outside of the generic
9479 if Is_Entity_Name
(Subtype_Mark
(Def
))
9480 and then Present
(Entity
(Subtype_Mark
(Def
)))
9482 Ancestor
:= Get_Instance_Of
(Entity
(Subtype_Mark
(Def
)));
9484 -- Check whether parent is defined in a previous formal package
9487 Scope
(Scope
(Base_Type
(Etype
(A_Gen_T
)))) = Scope
(A_Gen_T
)
9490 Get_Instance_Of
(Base_Type
(Etype
(A_Gen_T
)));
9492 -- The type may be a local derivation, or a type extension of a
9493 -- previous formal, or of a formal of a parent package.
9495 elsif Is_Derived_Type
(Get_Instance_Of
(A_Gen_T
))
9497 Ekind
(Get_Instance_Of
(A_Gen_T
)) = E_Record_Type_With_Private
9499 -- Check whether the parent is another derived formal type in the
9500 -- same generic unit.
9502 if Etype
(A_Gen_T
) /= A_Gen_T
9503 and then Is_Generic_Type
(Etype
(A_Gen_T
))
9504 and then Scope
(Etype
(A_Gen_T
)) = Scope
(A_Gen_T
)
9505 and then Etype
(Etype
(A_Gen_T
)) /= Etype
(A_Gen_T
)
9507 -- Locate ancestor of parent from the subtype declaration
9508 -- created for the actual.
9514 Decl
:= First
(Actual_Decls
);
9515 while Present
(Decl
) loop
9516 if Nkind
(Decl
) = N_Subtype_Declaration
9517 and then Chars
(Defining_Identifier
(Decl
)) =
9518 Chars
(Etype
(A_Gen_T
))
9520 Ancestor
:= Generic_Parent_Type
(Decl
);
9528 pragma Assert
(Present
(Ancestor
));
9532 Get_Instance_Of
(Base_Type
(Get_Instance_Of
(A_Gen_T
)));
9536 Ancestor
:= Get_Instance_Of
(Etype
(Base_Type
(A_Gen_T
)));
9539 -- If the formal derived type has pragma Preelaborable_Initialization
9540 -- then the actual type must have preelaborable initialization.
9542 if Known_To_Have_Preelab_Init
(A_Gen_T
)
9543 and then not Has_Preelaborable_Initialization
(Act_T
)
9546 ("actual for & must have preelaborable initialization",
9550 -- Ada 2005 (AI-251)
9552 if Ada_Version
>= Ada_05
9553 and then Is_Interface
(Ancestor
)
9555 if not Interface_Present_In_Ancestor
(Act_T
, Ancestor
) then
9557 ("(Ada 2005) expected type implementing & in instantiation",
9561 elsif not Is_Ancestor
(Base_Type
(Ancestor
), Act_T
) then
9563 ("expect type derived from & in instantiation",
9564 Actual
, First_Subtype
(Ancestor
));
9565 Abandon_Instantiation
(Actual
);
9568 -- Ada 2005 (AI-443): Synchronized formal derived type checks. Note
9569 -- that the formal type declaration has been rewritten as a private
9572 if Ada_Version
>= Ada_05
9573 and then Nkind
(Parent
(A_Gen_T
)) = N_Private_Extension_Declaration
9574 and then Synchronized_Present
(Parent
(A_Gen_T
))
9576 -- The actual must be a synchronized tagged type
9578 if not Is_Tagged_Type
(Act_T
) then
9580 ("actual of synchronized type must be tagged", Actual
);
9581 Abandon_Instantiation
(Actual
);
9583 elsif Nkind
(Parent
(Act_T
)) = N_Full_Type_Declaration
9584 and then Nkind
(Type_Definition
(Parent
(Act_T
))) =
9585 N_Derived_Type_Definition
9586 and then not Synchronized_Present
(Type_Definition
9590 ("actual of synchronized type must be synchronized", Actual
);
9591 Abandon_Instantiation
(Actual
);
9595 -- Perform atomic/volatile checks (RM C.6(12))
9597 if Is_Atomic
(Act_T
) and then not Is_Atomic
(Ancestor
) then
9599 ("cannot have atomic actual type for non-atomic formal type",
9602 elsif Is_Volatile
(Act_T
)
9603 and then not Is_Volatile
(Ancestor
)
9604 and then Is_By_Reference_Type
(Ancestor
)
9607 ("cannot have volatile actual type for non-volatile formal type",
9611 -- It should not be necessary to check for unknown discriminants on
9612 -- Formal, but for some reason Has_Unknown_Discriminants is false for
9613 -- A_Gen_T, so Is_Indefinite_Subtype incorrectly returns False. This
9614 -- needs fixing. ???
9616 if not Is_Indefinite_Subtype
(A_Gen_T
)
9617 and then not Unknown_Discriminants_Present
(Formal
)
9618 and then Is_Indefinite_Subtype
(Act_T
)
9621 ("actual subtype must be constrained", Actual
);
9622 Abandon_Instantiation
(Actual
);
9625 if not Unknown_Discriminants_Present
(Formal
) then
9626 if Is_Constrained
(Ancestor
) then
9627 if not Is_Constrained
(Act_T
) then
9629 ("actual subtype must be constrained", Actual
);
9630 Abandon_Instantiation
(Actual
);
9633 -- Ancestor is unconstrained, Check if generic formal and actual
9634 -- agree on constrainedness. The check only applies to array types
9635 -- and discriminated types.
9637 elsif Is_Constrained
(Act_T
) then
9638 if Ekind
(Ancestor
) = E_Access_Type
9640 (not Is_Constrained
(A_Gen_T
)
9641 and then Is_Composite_Type
(A_Gen_T
))
9644 ("actual subtype must be unconstrained", Actual
);
9645 Abandon_Instantiation
(Actual
);
9648 -- A class-wide type is only allowed if the formal has unknown
9651 elsif Is_Class_Wide_Type
(Act_T
)
9652 and then not Has_Unknown_Discriminants
(Ancestor
)
9655 ("actual for & cannot be a class-wide type", Actual
, Gen_T
);
9656 Abandon_Instantiation
(Actual
);
9658 -- Otherwise, the formal and actual shall have the same number
9659 -- of discriminants and each discriminant of the actual must
9660 -- correspond to a discriminant of the formal.
9662 elsif Has_Discriminants
(Act_T
)
9663 and then not Has_Unknown_Discriminants
(Act_T
)
9664 and then Has_Discriminants
(Ancestor
)
9666 Actual_Discr
:= First_Discriminant
(Act_T
);
9667 Ancestor_Discr
:= First_Discriminant
(Ancestor
);
9668 while Present
(Actual_Discr
)
9669 and then Present
(Ancestor_Discr
)
9671 if Base_Type
(Act_T
) /= Base_Type
(Ancestor
) and then
9672 No
(Corresponding_Discriminant
(Actual_Discr
))
9675 ("discriminant & does not correspond " &
9676 "to ancestor discriminant", Actual
, Actual_Discr
);
9677 Abandon_Instantiation
(Actual
);
9680 Next_Discriminant
(Actual_Discr
);
9681 Next_Discriminant
(Ancestor_Discr
);
9684 if Present
(Actual_Discr
) or else Present
(Ancestor_Discr
) then
9686 ("actual for & must have same number of discriminants",
9688 Abandon_Instantiation
(Actual
);
9691 -- This case should be caught by the earlier check for
9692 -- constrainedness, but the check here is added for completeness.
9694 elsif Has_Discriminants
(Act_T
)
9695 and then not Has_Unknown_Discriminants
(Act_T
)
9698 ("actual for & must not have discriminants", Actual
, Gen_T
);
9699 Abandon_Instantiation
(Actual
);
9701 elsif Has_Discriminants
(Ancestor
) then
9703 ("actual for & must have known discriminants", Actual
, Gen_T
);
9704 Abandon_Instantiation
(Actual
);
9707 if not Subtypes_Statically_Compatible
(Act_T
, Ancestor
) then
9709 ("constraint on actual is incompatible with formal", Actual
);
9710 Abandon_Instantiation
(Actual
);
9714 -- If the formal and actual types are abstract, check that there
9715 -- are no abstract primitives of the actual type that correspond to
9716 -- nonabstract primitives of the formal type (second sentence of
9719 if Is_Abstract_Type
(A_Gen_T
) and then Is_Abstract_Type
(Act_T
) then
9720 Check_Abstract_Primitives
: declare
9721 Gen_Prims
: constant Elist_Id
:=
9722 Primitive_Operations
(A_Gen_T
);
9724 Gen_Subp
: Entity_Id
;
9725 Anc_Subp
: Entity_Id
;
9726 Anc_Formal
: Entity_Id
;
9727 Anc_F_Type
: Entity_Id
;
9729 Act_Prims
: constant Elist_Id
:= Primitive_Operations
(Act_T
);
9731 Act_Subp
: Entity_Id
;
9732 Act_Formal
: Entity_Id
;
9733 Act_F_Type
: Entity_Id
;
9735 Subprograms_Correspond
: Boolean;
9737 function Is_Tagged_Ancestor
(T1
, T2
: Entity_Id
) return Boolean;
9738 -- Returns true if T2 is derived directly or indirectly from
9739 -- T1, including derivations from interfaces. T1 and T2 are
9740 -- required to be specific tagged base types.
9742 ------------------------
9743 -- Is_Tagged_Ancestor --
9744 ------------------------
9746 function Is_Tagged_Ancestor
(T1
, T2
: Entity_Id
) return Boolean
9748 Intfc_Elmt
: Elmt_Id
;
9751 -- The predicate is satisfied if the types are the same
9756 -- If we've reached the top of the derivation chain then
9757 -- we know that T1 is not an ancestor of T2.
9759 elsif Etype
(T2
) = T2
then
9762 -- Proceed to check T2's immediate parent
9764 elsif Is_Ancestor
(T1
, Base_Type
(Etype
(T2
))) then
9767 -- Finally, check to see if T1 is an ancestor of any of T2's
9771 Intfc_Elmt
:= First_Elmt
(Interfaces
(T2
));
9772 while Present
(Intfc_Elmt
) loop
9773 if Is_Ancestor
(T1
, Node
(Intfc_Elmt
)) then
9777 Next_Elmt
(Intfc_Elmt
);
9782 end Is_Tagged_Ancestor
;
9784 -- Start of processing for Check_Abstract_Primitives
9787 -- Loop over all of the formal derived type's primitives
9789 Gen_Elmt
:= First_Elmt
(Gen_Prims
);
9790 while Present
(Gen_Elmt
) loop
9791 Gen_Subp
:= Node
(Gen_Elmt
);
9793 -- If the primitive of the formal is not abstract, then
9794 -- determine whether there is a corresponding primitive of
9795 -- the actual type that's abstract.
9797 if not Is_Abstract_Subprogram
(Gen_Subp
) then
9798 Act_Elmt
:= First_Elmt
(Act_Prims
);
9799 while Present
(Act_Elmt
) loop
9800 Act_Subp
:= Node
(Act_Elmt
);
9802 -- If we find an abstract primitive of the actual,
9803 -- then we need to test whether it corresponds to the
9804 -- subprogram from which the generic formal primitive
9807 if Is_Abstract_Subprogram
(Act_Subp
) then
9808 Anc_Subp
:= Alias
(Gen_Subp
);
9810 -- Test whether we have a corresponding primitive
9811 -- by comparing names, kinds, formal types, and
9814 if Chars
(Anc_Subp
) = Chars
(Act_Subp
)
9815 and then Ekind
(Anc_Subp
) = Ekind
(Act_Subp
)
9817 Anc_Formal
:= First_Formal
(Anc_Subp
);
9818 Act_Formal
:= First_Formal
(Act_Subp
);
9819 while Present
(Anc_Formal
)
9820 and then Present
(Act_Formal
)
9822 Anc_F_Type
:= Etype
(Anc_Formal
);
9823 Act_F_Type
:= Etype
(Act_Formal
);
9825 if Ekind
(Anc_F_Type
)
9826 = E_Anonymous_Access_Type
9828 Anc_F_Type
:= Designated_Type
(Anc_F_Type
);
9830 if Ekind
(Act_F_Type
)
9831 = E_Anonymous_Access_Type
9834 Designated_Type
(Act_F_Type
);
9840 Ekind
(Act_F_Type
) = E_Anonymous_Access_Type
9845 Anc_F_Type
:= Base_Type
(Anc_F_Type
);
9846 Act_F_Type
:= Base_Type
(Act_F_Type
);
9848 -- If the formal is controlling, then the
9849 -- the type of the actual primitive's formal
9850 -- must be derived directly or indirectly
9851 -- from the type of the ancestor primitive's
9854 if Is_Controlling_Formal
(Anc_Formal
) then
9855 if not Is_Tagged_Ancestor
9856 (Anc_F_Type
, Act_F_Type
)
9861 -- Otherwise the types of the formals must
9864 elsif Anc_F_Type
/= Act_F_Type
then
9868 Next_Entity
(Anc_Formal
);
9869 Next_Entity
(Act_Formal
);
9872 -- If we traversed through all of the formals
9873 -- then so far the subprograms correspond, so
9874 -- now check that any result types correspond.
9876 if No
(Anc_Formal
) and then No
(Act_Formal
) then
9877 Subprograms_Correspond
:= True;
9879 if Ekind
(Act_Subp
) = E_Function
then
9880 Anc_F_Type
:= Etype
(Anc_Subp
);
9881 Act_F_Type
:= Etype
(Act_Subp
);
9883 if Ekind
(Anc_F_Type
)
9884 = E_Anonymous_Access_Type
9887 Designated_Type
(Anc_F_Type
);
9889 if Ekind
(Act_F_Type
)
9890 = E_Anonymous_Access_Type
9893 Designated_Type
(Act_F_Type
);
9895 Subprograms_Correspond
:= False;
9900 = E_Anonymous_Access_Type
9902 Subprograms_Correspond
:= False;
9905 Anc_F_Type
:= Base_Type
(Anc_F_Type
);
9906 Act_F_Type
:= Base_Type
(Act_F_Type
);
9908 -- Now either the result types must be
9909 -- the same or, if the result type is
9910 -- controlling, the result type of the
9911 -- actual primitive must descend from the
9912 -- result type of the ancestor primitive.
9914 if Subprograms_Correspond
9915 and then Anc_F_Type
/= Act_F_Type
9917 Has_Controlling_Result
(Anc_Subp
)
9919 not Is_Tagged_Ancestor
9920 (Anc_F_Type
, Act_F_Type
)
9922 Subprograms_Correspond
:= False;
9926 -- Found a matching subprogram belonging to
9927 -- formal ancestor type, so actual subprogram
9928 -- corresponds and this violates 3.9.3(9).
9930 if Subprograms_Correspond
then
9932 ("abstract subprogram & overrides " &
9933 "nonabstract subprogram of ancestor",
9941 Next_Elmt
(Act_Elmt
);
9945 Next_Elmt
(Gen_Elmt
);
9947 end Check_Abstract_Primitives
;
9950 -- Verify that limitedness matches. If parent is a limited
9951 -- interface then the generic formal is not unless declared
9952 -- explicitly so. If not declared limited, the actual cannot be
9953 -- limited (see AI05-0087).
9954 -- Disable check for now, limited interfaces implemented by
9955 -- protected types are common, Need to update tests ???
9957 if Is_Limited_Type
(Act_T
)
9958 and then not Is_Limited_Type
(A_Gen_T
)
9962 ("actual for non-limited & cannot be a limited type", Actual
,
9964 Explain_Limited_Type
(Act_T
, Actual
);
9965 Abandon_Instantiation
(Actual
);
9967 end Validate_Derived_Type_Instance
;
9969 --------------------------------------
9970 -- Validate_Interface_Type_Instance --
9971 --------------------------------------
9973 procedure Validate_Interface_Type_Instance
is
9975 if not Is_Interface
(Act_T
) then
9977 ("actual for formal interface type must be an interface",
9980 elsif Is_Limited_Type
(Act_T
) /= Is_Limited_Type
(A_Gen_T
)
9982 Is_Task_Interface
(A_Gen_T
) /= Is_Task_Interface
(Act_T
)
9984 Is_Protected_Interface
(A_Gen_T
) /=
9985 Is_Protected_Interface
(Act_T
)
9987 Is_Synchronized_Interface
(A_Gen_T
) /=
9988 Is_Synchronized_Interface
(Act_T
)
9991 ("actual for interface& does not match (RM 12.5.5(4))",
9994 end Validate_Interface_Type_Instance
;
9996 ------------------------------------
9997 -- Validate_Private_Type_Instance --
9998 ------------------------------------
10000 procedure Validate_Private_Type_Instance
is
10001 Formal_Discr
: Entity_Id
;
10002 Actual_Discr
: Entity_Id
;
10003 Formal_Subt
: Entity_Id
;
10006 if Is_Limited_Type
(Act_T
)
10007 and then not Is_Limited_Type
(A_Gen_T
)
10010 ("actual for non-limited & cannot be a limited type", Actual
,
10012 Explain_Limited_Type
(Act_T
, Actual
);
10013 Abandon_Instantiation
(Actual
);
10015 elsif Known_To_Have_Preelab_Init
(A_Gen_T
)
10016 and then not Has_Preelaborable_Initialization
(Act_T
)
10019 ("actual for & must have preelaborable initialization", Actual
,
10022 elsif Is_Indefinite_Subtype
(Act_T
)
10023 and then not Is_Indefinite_Subtype
(A_Gen_T
)
10024 and then Ada_Version
>= Ada_95
10027 ("actual for & must be a definite subtype", Actual
, Gen_T
);
10029 elsif not Is_Tagged_Type
(Act_T
)
10030 and then Is_Tagged_Type
(A_Gen_T
)
10033 ("actual for & must be a tagged type", Actual
, Gen_T
);
10035 elsif Has_Discriminants
(A_Gen_T
) then
10036 if not Has_Discriminants
(Act_T
) then
10038 ("actual for & must have discriminants", Actual
, Gen_T
);
10039 Abandon_Instantiation
(Actual
);
10041 elsif Is_Constrained
(Act_T
) then
10043 ("actual for & must be unconstrained", Actual
, Gen_T
);
10044 Abandon_Instantiation
(Actual
);
10047 Formal_Discr
:= First_Discriminant
(A_Gen_T
);
10048 Actual_Discr
:= First_Discriminant
(Act_T
);
10049 while Formal_Discr
/= Empty
loop
10050 if Actual_Discr
= Empty
then
10052 ("discriminants on actual do not match formal",
10054 Abandon_Instantiation
(Actual
);
10057 Formal_Subt
:= Get_Instance_Of
(Etype
(Formal_Discr
));
10059 -- Access discriminants match if designated types do
10061 if Ekind
(Base_Type
(Formal_Subt
)) = E_Anonymous_Access_Type
10062 and then (Ekind
(Base_Type
(Etype
(Actual_Discr
)))) =
10063 E_Anonymous_Access_Type
10066 (Designated_Type
(Base_Type
(Formal_Subt
))) =
10067 Designated_Type
(Base_Type
(Etype
(Actual_Discr
)))
10071 elsif Base_Type
(Formal_Subt
) /=
10072 Base_Type
(Etype
(Actual_Discr
))
10075 ("types of actual discriminants must match formal",
10077 Abandon_Instantiation
(Actual
);
10079 elsif not Subtypes_Statically_Match
10080 (Formal_Subt
, Etype
(Actual_Discr
))
10081 and then Ada_Version
>= Ada_95
10084 ("subtypes of actual discriminants must match formal",
10086 Abandon_Instantiation
(Actual
);
10089 Next_Discriminant
(Formal_Discr
);
10090 Next_Discriminant
(Actual_Discr
);
10093 if Actual_Discr
/= Empty
then
10095 ("discriminants on actual do not match formal",
10097 Abandon_Instantiation
(Actual
);
10104 end Validate_Private_Type_Instance
;
10106 -- Start of processing for Instantiate_Type
10109 if Get_Instance_Of
(A_Gen_T
) /= A_Gen_T
then
10110 Error_Msg_N
("duplicate instantiation of generic type", Actual
);
10111 return New_List
(Error
);
10113 elsif not Is_Entity_Name
(Actual
)
10114 or else not Is_Type
(Entity
(Actual
))
10117 ("expect valid subtype mark to instantiate &", Actual
, Gen_T
);
10118 Abandon_Instantiation
(Actual
);
10121 Act_T
:= Entity
(Actual
);
10123 -- Ada 2005 (AI-216): An Unchecked_Union subtype shall only be passed
10124 -- as a generic actual parameter if the corresponding formal type
10125 -- does not have a known_discriminant_part, or is a formal derived
10126 -- type that is an Unchecked_Union type.
10128 if Is_Unchecked_Union
(Base_Type
(Act_T
)) then
10129 if not Has_Discriminants
(A_Gen_T
)
10131 (Is_Derived_Type
(A_Gen_T
)
10133 Is_Unchecked_Union
(A_Gen_T
))
10137 Error_Msg_N
("Unchecked_Union cannot be the actual for a" &
10138 " discriminated formal type", Act_T
);
10143 -- Deal with fixed/floating restrictions
10145 if Is_Floating_Point_Type
(Act_T
) then
10146 Check_Restriction
(No_Floating_Point
, Actual
);
10147 elsif Is_Fixed_Point_Type
(Act_T
) then
10148 Check_Restriction
(No_Fixed_Point
, Actual
);
10151 -- Deal with error of using incomplete type as generic actual.
10152 -- This includes limited views of a type, even if the non-limited
10153 -- view may be available.
10155 if Ekind
(Act_T
) = E_Incomplete_Type
10156 or else (Is_Class_Wide_Type
(Act_T
)
10158 Ekind
(Root_Type
(Act_T
)) = E_Incomplete_Type
)
10160 if Is_Class_Wide_Type
(Act_T
)
10161 or else No
(Full_View
(Act_T
))
10163 Error_Msg_N
("premature use of incomplete type", Actual
);
10164 Abandon_Instantiation
(Actual
);
10166 Act_T
:= Full_View
(Act_T
);
10167 Set_Entity
(Actual
, Act_T
);
10169 if Has_Private_Component
(Act_T
) then
10171 ("premature use of type with private component", Actual
);
10175 -- Deal with error of premature use of private type as generic actual
10177 elsif Is_Private_Type
(Act_T
)
10178 and then Is_Private_Type
(Base_Type
(Act_T
))
10179 and then not Is_Generic_Type
(Act_T
)
10180 and then not Is_Derived_Type
(Act_T
)
10181 and then No
(Full_View
(Root_Type
(Act_T
)))
10183 Error_Msg_N
("premature use of private type", Actual
);
10185 elsif Has_Private_Component
(Act_T
) then
10187 ("premature use of type with private component", Actual
);
10190 Set_Instance_Of
(A_Gen_T
, Act_T
);
10192 -- If the type is generic, the class-wide type may also be used
10194 if Is_Tagged_Type
(A_Gen_T
)
10195 and then Is_Tagged_Type
(Act_T
)
10196 and then not Is_Class_Wide_Type
(A_Gen_T
)
10198 Set_Instance_Of
(Class_Wide_Type
(A_Gen_T
),
10199 Class_Wide_Type
(Act_T
));
10202 if not Is_Abstract_Type
(A_Gen_T
)
10203 and then Is_Abstract_Type
(Act_T
)
10206 ("actual of non-abstract formal cannot be abstract", Actual
);
10209 -- A generic scalar type is a first subtype for which we generate
10210 -- an anonymous base type. Indicate that the instance of this base
10211 -- is the base type of the actual.
10213 if Is_Scalar_Type
(A_Gen_T
) then
10214 Set_Instance_Of
(Etype
(A_Gen_T
), Etype
(Act_T
));
10218 if Error_Posted
(Act_T
) then
10221 case Nkind
(Def
) is
10222 when N_Formal_Private_Type_Definition
=>
10223 Validate_Private_Type_Instance
;
10225 when N_Formal_Derived_Type_Definition
=>
10226 Validate_Derived_Type_Instance
;
10228 when N_Formal_Discrete_Type_Definition
=>
10229 if not Is_Discrete_Type
(Act_T
) then
10231 ("expect discrete type in instantiation of&",
10233 Abandon_Instantiation
(Actual
);
10236 when N_Formal_Signed_Integer_Type_Definition
=>
10237 if not Is_Signed_Integer_Type
(Act_T
) then
10239 ("expect signed integer type in instantiation of&",
10241 Abandon_Instantiation
(Actual
);
10244 when N_Formal_Modular_Type_Definition
=>
10245 if not Is_Modular_Integer_Type
(Act_T
) then
10247 ("expect modular type in instantiation of &",
10249 Abandon_Instantiation
(Actual
);
10252 when N_Formal_Floating_Point_Definition
=>
10253 if not Is_Floating_Point_Type
(Act_T
) then
10255 ("expect float type in instantiation of &", Actual
, Gen_T
);
10256 Abandon_Instantiation
(Actual
);
10259 when N_Formal_Ordinary_Fixed_Point_Definition
=>
10260 if not Is_Ordinary_Fixed_Point_Type
(Act_T
) then
10262 ("expect ordinary fixed point type in instantiation of &",
10264 Abandon_Instantiation
(Actual
);
10267 when N_Formal_Decimal_Fixed_Point_Definition
=>
10268 if not Is_Decimal_Fixed_Point_Type
(Act_T
) then
10270 ("expect decimal type in instantiation of &",
10272 Abandon_Instantiation
(Actual
);
10275 when N_Array_Type_Definition
=>
10276 Validate_Array_Type_Instance
;
10278 when N_Access_To_Object_Definition
=>
10279 Validate_Access_Type_Instance
;
10281 when N_Access_Function_Definition |
10282 N_Access_Procedure_Definition
=>
10283 Validate_Access_Subprogram_Instance
;
10285 when N_Record_Definition
=>
10286 Validate_Interface_Type_Instance
;
10288 when N_Derived_Type_Definition
=>
10289 Validate_Derived_Interface_Type_Instance
;
10292 raise Program_Error
;
10297 Subt
:= New_Copy
(Gen_T
);
10299 -- Use adjusted sloc of subtype name as the location for other nodes in
10300 -- the subtype declaration.
10302 Loc
:= Sloc
(Subt
);
10305 Make_Subtype_Declaration
(Loc
,
10306 Defining_Identifier
=> Subt
,
10307 Subtype_Indication
=> New_Reference_To
(Act_T
, Loc
));
10309 if Is_Private_Type
(Act_T
) then
10310 Set_Has_Private_View
(Subtype_Indication
(Decl_Node
));
10312 elsif Is_Access_Type
(Act_T
)
10313 and then Is_Private_Type
(Designated_Type
(Act_T
))
10315 Set_Has_Private_View
(Subtype_Indication
(Decl_Node
));
10318 Decl_Nodes
:= New_List
(Decl_Node
);
10320 -- Flag actual derived types so their elaboration produces the
10321 -- appropriate renamings for the primitive operations of the ancestor.
10322 -- Flag actual for formal private types as well, to determine whether
10323 -- operations in the private part may override inherited operations.
10324 -- If the formal has an interface list, the ancestor is not the
10325 -- parent, but the analyzed formal that includes the interface
10326 -- operations of all its progenitors.
10328 if Nkind
(Def
) = N_Formal_Derived_Type_Definition
then
10329 if Present
(Interface_List
(Def
)) then
10330 Set_Generic_Parent_Type
(Decl_Node
, A_Gen_T
);
10332 Set_Generic_Parent_Type
(Decl_Node
, Ancestor
);
10335 elsif Nkind
(Def
) = N_Formal_Private_Type_Definition
then
10336 Set_Generic_Parent_Type
(Decl_Node
, Ancestor
);
10339 -- If the actual is a synchronized type that implements an interface,
10340 -- the primitive operations are attached to the corresponding record,
10341 -- and we have to treat it as an additional generic actual, so that its
10342 -- primitive operations become visible in the instance. The task or
10343 -- protected type itself does not carry primitive operations.
10345 if Is_Concurrent_Type
(Act_T
)
10346 and then Is_Tagged_Type
(Act_T
)
10347 and then Present
(Corresponding_Record_Type
(Act_T
))
10348 and then Present
(Ancestor
)
10349 and then Is_Interface
(Ancestor
)
10352 Corr_Rec
: constant Entity_Id
:=
10353 Corresponding_Record_Type
(Act_T
);
10354 New_Corr
: Entity_Id
;
10355 Corr_Decl
: Node_Id
;
10358 New_Corr
:= Make_Temporary
(Loc
, 'S');
10360 Make_Subtype_Declaration
(Loc
,
10361 Defining_Identifier
=> New_Corr
,
10362 Subtype_Indication
=>
10363 New_Reference_To
(Corr_Rec
, Loc
));
10364 Append_To
(Decl_Nodes
, Corr_Decl
);
10366 if Ekind
(Act_T
) = E_Task_Type
then
10367 Set_Ekind
(Subt
, E_Task_Subtype
);
10369 Set_Ekind
(Subt
, E_Protected_Subtype
);
10372 Set_Corresponding_Record_Type
(Subt
, Corr_Rec
);
10373 Set_Generic_Parent_Type
(Corr_Decl
, Ancestor
);
10374 Set_Generic_Parent_Type
(Decl_Node
, Empty
);
10379 end Instantiate_Type
;
10381 -----------------------
10382 -- Is_Generic_Formal --
10383 -----------------------
10385 function Is_Generic_Formal
(E
: Entity_Id
) return Boolean is
10391 Kind
:= Nkind
(Parent
(E
));
10393 Nkind_In
(Kind
, N_Formal_Object_Declaration
,
10394 N_Formal_Package_Declaration
,
10395 N_Formal_Type_Declaration
)
10397 (Is_Formal_Subprogram
(E
)
10399 Nkind
(Parent
(Parent
(E
))) in
10400 N_Formal_Subprogram_Declaration
);
10402 end Is_Generic_Formal
;
10408 procedure Mark_Context
(Inst_Decl
: Node_Id
; Gen_Decl
: Node_Id
) is
10409 Loc
: constant Source_Ptr
:= Sloc
(Inst_Decl
);
10410 Inst_CU
: constant Unit_Number_Type
:= Get_Code_Unit
(Inst_Decl
);
10412 -- Note that we use Get_Code_Unit to determine the position of the
10413 -- instantiation, because it may itself appear within another instance
10414 -- and we need to mark the context of the enclosing unit, not that of
10415 -- the unit that contains the generic.
10417 Gen_CU
: constant Unit_Number_Type
:= Get_Source_Unit
(Gen_Decl
);
10422 procedure Add_Implicit_With
(CU
: Unit_Number_Type
);
10423 -- If a generic is instantiated in the direct or indirect context of
10424 -- the current unit, but there is no with_clause for it in the current
10425 -- context, add a with_clause for it to indicate that the body of the
10426 -- generic should be examined before the current unit.
10428 procedure Add_Implicit_With
(CU
: Unit_Number_Type
) is
10429 Withn
: constant Node_Id
:=
10430 Make_With_Clause
(Loc
,
10431 Name
=> New_Occurrence_Of
(Cunit_Entity
(CU
), Loc
));
10433 Set_Implicit_With
(Withn
);
10434 Set_Library_Unit
(Withn
, Cunit
(CU
));
10435 Set_Withed_Body
(Withn
, Cunit
(CU
));
10436 Prepend
(Withn
, Context_Items
(Cunit
(Inst_CU
)));
10437 end Add_Implicit_With
;
10440 -- This is only relevant when compiling for CodePeer. In what follows,
10441 -- C is the current unit containing the instance body, and G is the
10442 -- generic unit in that instance.
10444 if not CodePeer_Mode
then
10448 -- Nothing to do if G is local.
10450 if Inst_CU
= Gen_CU
then
10454 -- If G is itself declared within an instance, indicate that the
10455 -- generic body of that instance is also needed by C. This must be
10456 -- done recursively.
10458 Scop
:= Scope
(Defining_Entity
(Gen_Decl
));
10460 while Is_Generic_Instance
(Scop
)
10461 and then Ekind
(Scop
) = E_Package
10465 Unit_Declaration_Node
10467 (Specification
(Unit_Declaration_Node
(Scop
)))));
10468 Scop
:= Scope
(Scop
);
10471 -- Add references to other generic units in the context of G, because
10472 -- they may be instantiated within G, and their bodies needed by C.
10474 Clause
:= First
(Context_Items
(Cunit
(Gen_CU
)));
10476 while Present
(Clause
) loop
10477 if Nkind
(Clause
) = N_With_Clause
10479 Nkind
(Unit
(Library_Unit
(Clause
)))
10480 = N_Generic_Package_Declaration
10482 Add_Implicit_With
(Get_Source_Unit
(Library_Unit
(Clause
)));
10488 -- Now indicate that the body of G is needed by C
10490 Clause
:= First
(Context_Items
(Cunit
(Inst_CU
)));
10491 while Present
(Clause
) loop
10492 if Nkind
(Clause
) = N_With_Clause
10493 and then Library_Unit
(Clause
) = Cunit
(Gen_CU
)
10495 Set_Withed_Body
(Clause
, Cunit
(Gen_CU
));
10502 -- If the with-clause for G is not in the context of C, it may appear in
10503 -- some ancestor of C.
10505 Inst
:= Cunit_Entity
(Inst_CU
);
10506 while Is_Child_Unit
(Inst
) loop
10507 Inst
:= Scope
(Inst
);
10510 First
(Context_Items
(Parent
(Unit_Declaration_Node
(Inst
))));
10511 while Present
(Clause
) loop
10512 if Nkind
(Clause
) = N_With_Clause
10513 and then Library_Unit
(Clause
) = Cunit
(Gen_CU
)
10515 Set_Withed_Body
(Clause
, Cunit
(Gen_CU
));
10523 -- If not found, G comes from an instance elsewhere in the context. Make
10524 -- the dependence explicit in the context of C.
10526 Add_Implicit_With
(Gen_CU
);
10529 ---------------------
10530 -- Is_In_Main_Unit --
10531 ---------------------
10533 function Is_In_Main_Unit
(N
: Node_Id
) return Boolean is
10534 Unum
: constant Unit_Number_Type
:= Get_Source_Unit
(N
);
10535 Current_Unit
: Node_Id
;
10538 if Unum
= Main_Unit
then
10541 -- If the current unit is a subunit then it is either the main unit or
10542 -- is being compiled as part of the main unit.
10544 elsif Nkind
(N
) = N_Compilation_Unit
then
10545 return Nkind
(Unit
(N
)) = N_Subunit
;
10548 Current_Unit
:= Parent
(N
);
10549 while Present
(Current_Unit
)
10550 and then Nkind
(Current_Unit
) /= N_Compilation_Unit
10552 Current_Unit
:= Parent
(Current_Unit
);
10555 -- The instantiation node is in the main unit, or else the current node
10556 -- (perhaps as the result of nested instantiations) is in the main unit,
10557 -- or in the declaration of the main unit, which in this last case must
10560 return Unum
= Main_Unit
10561 or else Current_Unit
= Cunit
(Main_Unit
)
10562 or else Current_Unit
= Library_Unit
(Cunit
(Main_Unit
))
10563 or else (Present
(Library_Unit
(Current_Unit
))
10564 and then Is_In_Main_Unit
(Library_Unit
(Current_Unit
)));
10565 end Is_In_Main_Unit
;
10567 ----------------------------
10568 -- Load_Parent_Of_Generic --
10569 ----------------------------
10571 procedure Load_Parent_Of_Generic
10574 Body_Optional
: Boolean := False)
10576 Comp_Unit
: constant Node_Id
:= Cunit
(Get_Source_Unit
(Spec
));
10577 Save_Style_Check
: constant Boolean := Style_Check
;
10578 True_Parent
: Node_Id
;
10579 Inst_Node
: Node_Id
;
10581 Previous_Instances
: constant Elist_Id
:= New_Elmt_List
;
10583 procedure Collect_Previous_Instances
(Decls
: List_Id
);
10584 -- Collect all instantiations in the given list of declarations, that
10585 -- precede the generic that we need to load. If the bodies of these
10586 -- instantiations are available, we must analyze them, to ensure that
10587 -- the public symbols generated are the same when the unit is compiled
10588 -- to generate code, and when it is compiled in the context of a unit
10589 -- that needs a particular nested instance. This process is applied to
10590 -- both package and subprogram instances.
10592 --------------------------------
10593 -- Collect_Previous_Instances --
10594 --------------------------------
10596 procedure Collect_Previous_Instances
(Decls
: List_Id
) is
10600 Decl
:= First
(Decls
);
10601 while Present
(Decl
) loop
10602 if Sloc
(Decl
) >= Sloc
(Inst_Node
) then
10605 -- If Decl is an instantiation, then record it as requiring
10606 -- instantiation of the corresponding body, except if it is an
10607 -- abbreviated instantiation generated internally for conformance
10608 -- checking purposes only for the case of a formal package
10609 -- declared without a box (see Instantiate_Formal_Package). Such
10610 -- an instantiation does not generate any code (the actual code
10611 -- comes from actual) and thus does not need to be analyzed here.
10612 -- If the instantiation appears with a generic package body it is
10613 -- not analyzed here either.
10615 elsif Nkind
(Decl
) = N_Package_Instantiation
10616 and then not Is_Internal
(Defining_Entity
(Decl
))
10618 Append_Elmt
(Decl
, Previous_Instances
);
10620 -- For a subprogram instantiation, omit instantiations intrinsic
10621 -- operations (Unchecked_Conversions, etc.) that have no bodies.
10623 elsif Nkind_In
(Decl
, N_Function_Instantiation
,
10624 N_Procedure_Instantiation
)
10625 and then not Is_Intrinsic_Subprogram
(Entity
(Name
(Decl
)))
10627 Append_Elmt
(Decl
, Previous_Instances
);
10629 elsif Nkind
(Decl
) = N_Package_Declaration
then
10630 Collect_Previous_Instances
10631 (Visible_Declarations
(Specification
(Decl
)));
10632 Collect_Previous_Instances
10633 (Private_Declarations
(Specification
(Decl
)));
10635 -- Previous non-generic bodies may contain instances as well
10637 elsif Nkind
(Decl
) = N_Package_Body
10638 and then Ekind
(Corresponding_Spec
(Decl
)) /= E_Generic_Package
10640 Collect_Previous_Instances
(Declarations
(Decl
));
10642 elsif Nkind
(Decl
) = N_Subprogram_Body
10643 and then not Acts_As_Spec
(Decl
)
10644 and then not Is_Generic_Subprogram
(Corresponding_Spec
(Decl
))
10646 Collect_Previous_Instances
(Declarations
(Decl
));
10651 end Collect_Previous_Instances
;
10653 -- Start of processing for Load_Parent_Of_Generic
10656 if not In_Same_Source_Unit
(N
, Spec
)
10657 or else Nkind
(Unit
(Comp_Unit
)) = N_Package_Declaration
10658 or else (Nkind
(Unit
(Comp_Unit
)) = N_Package_Body
10659 and then not Is_In_Main_Unit
(Spec
))
10661 -- Find body of parent of spec, and analyze it. A special case arises
10662 -- when the parent is an instantiation, that is to say when we are
10663 -- currently instantiating a nested generic. In that case, there is
10664 -- no separate file for the body of the enclosing instance. Instead,
10665 -- the enclosing body must be instantiated as if it were a pending
10666 -- instantiation, in order to produce the body for the nested generic
10667 -- we require now. Note that in that case the generic may be defined
10668 -- in a package body, the instance defined in the same package body,
10669 -- and the original enclosing body may not be in the main unit.
10671 Inst_Node
:= Empty
;
10673 True_Parent
:= Parent
(Spec
);
10674 while Present
(True_Parent
)
10675 and then Nkind
(True_Parent
) /= N_Compilation_Unit
10677 if Nkind
(True_Parent
) = N_Package_Declaration
10679 Nkind
(Original_Node
(True_Parent
)) = N_Package_Instantiation
10681 -- Parent is a compilation unit that is an instantiation.
10682 -- Instantiation node has been replaced with package decl.
10684 Inst_Node
:= Original_Node
(True_Parent
);
10687 elsif Nkind
(True_Parent
) = N_Package_Declaration
10688 and then Present
(Generic_Parent
(Specification
(True_Parent
)))
10689 and then Nkind
(Parent
(True_Parent
)) /= N_Compilation_Unit
10691 -- Parent is an instantiation within another specification.
10692 -- Declaration for instance has been inserted before original
10693 -- instantiation node. A direct link would be preferable?
10695 Inst_Node
:= Next
(True_Parent
);
10696 while Present
(Inst_Node
)
10697 and then Nkind
(Inst_Node
) /= N_Package_Instantiation
10702 -- If the instance appears within a generic, and the generic
10703 -- unit is defined within a formal package of the enclosing
10704 -- generic, there is no generic body available, and none
10705 -- needed. A more precise test should be used ???
10707 if No
(Inst_Node
) then
10714 True_Parent
:= Parent
(True_Parent
);
10718 -- Case where we are currently instantiating a nested generic
10720 if Present
(Inst_Node
) then
10721 if Nkind
(Parent
(True_Parent
)) = N_Compilation_Unit
then
10723 -- Instantiation node and declaration of instantiated package
10724 -- were exchanged when only the declaration was needed.
10725 -- Restore instantiation node before proceeding with body.
10727 Set_Unit
(Parent
(True_Parent
), Inst_Node
);
10730 -- Now complete instantiation of enclosing body, if it appears in
10731 -- some other unit. If it appears in the current unit, the body
10732 -- will have been instantiated already.
10734 if No
(Corresponding_Body
(Instance_Spec
(Inst_Node
))) then
10736 -- We need to determine the expander mode to instantiate the
10737 -- enclosing body. Because the generic body we need may use
10738 -- global entities declared in the enclosing package (including
10739 -- aggregates) it is in general necessary to compile this body
10740 -- with expansion enabled, except if we are within a generic
10741 -- package, in which case the usual generic rule applies.
10744 Exp_Status
: Boolean := True;
10748 -- Loop through scopes looking for generic package
10750 Scop
:= Scope
(Defining_Entity
(Instance_Spec
(Inst_Node
)));
10751 while Present
(Scop
)
10752 and then Scop
/= Standard_Standard
10754 if Ekind
(Scop
) = E_Generic_Package
then
10755 Exp_Status
:= False;
10759 Scop
:= Scope
(Scop
);
10762 -- Collect previous instantiations in the unit that contains
10763 -- the desired generic.
10765 if Nkind
(Parent
(True_Parent
)) /= N_Compilation_Unit
10766 and then not Body_Optional
10770 Info
: Pending_Body_Info
;
10774 Par
:= Parent
(Inst_Node
);
10775 while Present
(Par
) loop
10776 exit when Nkind
(Parent
(Par
)) = N_Compilation_Unit
;
10777 Par
:= Parent
(Par
);
10780 pragma Assert
(Present
(Par
));
10782 if Nkind
(Par
) = N_Package_Body
then
10783 Collect_Previous_Instances
(Declarations
(Par
));
10785 elsif Nkind
(Par
) = N_Package_Declaration
then
10786 Collect_Previous_Instances
10787 (Visible_Declarations
(Specification
(Par
)));
10788 Collect_Previous_Instances
10789 (Private_Declarations
(Specification
(Par
)));
10792 -- Enclosing unit is a subprogram body. In this
10793 -- case all instance bodies are processed in order
10794 -- and there is no need to collect them separately.
10799 Decl
:= First_Elmt
(Previous_Instances
);
10800 while Present
(Decl
) loop
10802 (Inst_Node
=> Node
(Decl
),
10804 Instance_Spec
(Node
(Decl
)),
10805 Expander_Status
=> Exp_Status
,
10806 Current_Sem_Unit
=>
10807 Get_Code_Unit
(Sloc
(Node
(Decl
))),
10808 Scope_Suppress
=> Scope_Suppress
,
10809 Local_Suppress_Stack_Top
=>
10810 Local_Suppress_Stack_Top
,
10811 Version
=> Ada_Version
);
10813 -- Package instance
10816 Nkind
(Node
(Decl
)) = N_Package_Instantiation
10818 Instantiate_Package_Body
10819 (Info
, Body_Optional
=> True);
10821 -- Subprogram instance
10824 -- The instance_spec is the wrapper package,
10825 -- and the subprogram declaration is the last
10826 -- declaration in the wrapper.
10830 (Visible_Declarations
10831 (Specification
(Info
.Act_Decl
)));
10833 Instantiate_Subprogram_Body
10834 (Info
, Body_Optional
=> True);
10842 Instantiate_Package_Body
10844 ((Inst_Node
=> Inst_Node
,
10845 Act_Decl
=> True_Parent
,
10846 Expander_Status
=> Exp_Status
,
10847 Current_Sem_Unit
=>
10848 Get_Code_Unit
(Sloc
(Inst_Node
)),
10849 Scope_Suppress
=> Scope_Suppress
,
10850 Local_Suppress_Stack_Top
=>
10851 Local_Suppress_Stack_Top
,
10852 Version
=> Ada_Version
)),
10853 Body_Optional
=> Body_Optional
);
10857 -- Case where we are not instantiating a nested generic
10860 Opt
.Style_Check
:= False;
10861 Expander_Mode_Save_And_Set
(True);
10862 Load_Needed_Body
(Comp_Unit
, OK
);
10863 Opt
.Style_Check
:= Save_Style_Check
;
10864 Expander_Mode_Restore
;
10867 and then Unit_Requires_Body
(Defining_Entity
(Spec
))
10868 and then not Body_Optional
10871 Bname
: constant Unit_Name_Type
:=
10872 Get_Body_Name
(Get_Unit_Name
(Unit
(Comp_Unit
)));
10875 -- In CodePeer mode, the missing body may make the analysis
10876 -- incomplete, but we do not treat it as fatal.
10878 if CodePeer_Mode
then
10882 Error_Msg_Unit_1
:= Bname
;
10883 Error_Msg_N
("this instantiation requires$!", N
);
10884 Error_Msg_File_1
:=
10885 Get_File_Name
(Bname
, Subunit
=> False);
10886 Error_Msg_N
("\but file{ was not found!", N
);
10887 raise Unrecoverable_Error
;
10894 -- If loading parent of the generic caused an instantiation circularity,
10895 -- we abandon compilation at this point, because otherwise in some cases
10896 -- we get into trouble with infinite recursions after this point.
10898 if Circularity_Detected
then
10899 raise Unrecoverable_Error
;
10901 end Load_Parent_Of_Generic
;
10903 ---------------------------------
10904 -- Map_Formal_Package_Entities --
10905 ---------------------------------
10907 procedure Map_Formal_Package_Entities
(Form
: Entity_Id
; Act
: Entity_Id
) is
10912 Set_Instance_Of
(Form
, Act
);
10914 -- Traverse formal and actual package to map the corresponding entities.
10915 -- We skip over internal entities that may be generated during semantic
10916 -- analysis, and find the matching entities by name, given that they
10917 -- must appear in the same order.
10919 E1
:= First_Entity
(Form
);
10920 E2
:= First_Entity
(Act
);
10921 while Present
(E1
) and then E1
/= First_Private_Entity
(Form
) loop
10922 -- Could this test be a single condition???
10923 -- Seems like it could, and isn't FPE (Form) a constant anyway???
10925 if not Is_Internal
(E1
)
10926 and then Present
(Parent
(E1
))
10927 and then not Is_Class_Wide_Type
(E1
)
10928 and then not Is_Internal_Name
(Chars
(E1
))
10930 while Present
(E2
) and then Chars
(E2
) /= Chars
(E1
) loop
10937 Set_Instance_Of
(E1
, E2
);
10939 if Is_Type
(E1
) and then Is_Tagged_Type
(E2
) then
10940 Set_Instance_Of
(Class_Wide_Type
(E1
), Class_Wide_Type
(E2
));
10943 if Is_Constrained
(E1
) then
10944 Set_Instance_Of
(Base_Type
(E1
), Base_Type
(E2
));
10947 if Ekind
(E1
) = E_Package
and then No
(Renamed_Object
(E1
)) then
10948 Map_Formal_Package_Entities
(E1
, E2
);
10955 end Map_Formal_Package_Entities
;
10957 -----------------------
10958 -- Move_Freeze_Nodes --
10959 -----------------------
10961 procedure Move_Freeze_Nodes
10962 (Out_Of
: Entity_Id
;
10967 Next_Decl
: Node_Id
;
10968 Next_Node
: Node_Id
:= After
;
10971 function Is_Outer_Type
(T
: Entity_Id
) return Boolean;
10972 -- Check whether entity is declared in a scope external to that of the
10975 -------------------
10976 -- Is_Outer_Type --
10977 -------------------
10979 function Is_Outer_Type
(T
: Entity_Id
) return Boolean is
10980 Scop
: Entity_Id
:= Scope
(T
);
10983 if Scope_Depth
(Scop
) < Scope_Depth
(Out_Of
) then
10987 while Scop
/= Standard_Standard
loop
10988 if Scop
= Out_Of
then
10991 Scop
:= Scope
(Scop
);
10999 -- Start of processing for Move_Freeze_Nodes
11006 -- First remove the freeze nodes that may appear before all other
11010 while Present
(Decl
)
11011 and then Nkind
(Decl
) = N_Freeze_Entity
11012 and then Is_Outer_Type
(Entity
(Decl
))
11014 Decl
:= Remove_Head
(L
);
11015 Insert_After
(Next_Node
, Decl
);
11016 Set_Analyzed
(Decl
, False);
11021 -- Next scan the list of declarations and remove each freeze node that
11022 -- appears ahead of the current node.
11024 while Present
(Decl
) loop
11025 while Present
(Next
(Decl
))
11026 and then Nkind
(Next
(Decl
)) = N_Freeze_Entity
11027 and then Is_Outer_Type
(Entity
(Next
(Decl
)))
11029 Next_Decl
:= Remove_Next
(Decl
);
11030 Insert_After
(Next_Node
, Next_Decl
);
11031 Set_Analyzed
(Next_Decl
, False);
11032 Next_Node
:= Next_Decl
;
11035 -- If the declaration is a nested package or concurrent type, then
11036 -- recurse. Nested generic packages will have been processed from the
11039 case Nkind
(Decl
) is
11040 when N_Package_Declaration
=>
11041 Spec
:= Specification
(Decl
);
11043 when N_Task_Type_Declaration
=>
11044 Spec
:= Task_Definition
(Decl
);
11046 when N_Protected_Type_Declaration
=>
11047 Spec
:= Protected_Definition
(Decl
);
11053 if Present
(Spec
) then
11054 Move_Freeze_Nodes
(Out_Of
, Next_Node
, Visible_Declarations
(Spec
));
11055 Move_Freeze_Nodes
(Out_Of
, Next_Node
, Private_Declarations
(Spec
));
11060 end Move_Freeze_Nodes
;
11066 function Next_Assoc
(E
: Assoc_Ptr
) return Assoc_Ptr
is
11068 return Generic_Renamings
.Table
(E
).Next_In_HTable
;
11071 ------------------------
11072 -- Preanalyze_Actuals --
11073 ------------------------
11075 procedure Preanalyze_Actuals
(N
: Node_Id
) is
11078 Errs
: constant Int
:= Serious_Errors_Detected
;
11080 Cur
: Entity_Id
:= Empty
;
11081 -- Current homograph of the instance name
11084 -- Saved visibility status of the current homograph
11087 Assoc
:= First
(Generic_Associations
(N
));
11089 -- If the instance is a child unit, its name may hide an outer homonym,
11090 -- so make it invisible to perform name resolution on the actuals.
11092 if Nkind
(Defining_Unit_Name
(N
)) = N_Defining_Program_Unit_Name
11094 (Current_Entity
(Defining_Identifier
(Defining_Unit_Name
(N
))))
11096 Cur
:= Current_Entity
(Defining_Identifier
(Defining_Unit_Name
(N
)));
11098 if Is_Compilation_Unit
(Cur
) then
11099 Vis
:= Is_Immediately_Visible
(Cur
);
11100 Set_Is_Immediately_Visible
(Cur
, False);
11106 while Present
(Assoc
) loop
11107 if Nkind
(Assoc
) /= N_Others_Choice
then
11108 Act
:= Explicit_Generic_Actual_Parameter
(Assoc
);
11110 -- Within a nested instantiation, a defaulted actual is an empty
11111 -- association, so nothing to analyze. If the subprogram actual
11112 -- is an attribute, analyze prefix only, because actual is not a
11113 -- complete attribute reference.
11115 -- If actual is an allocator, analyze expression only. The full
11116 -- analysis can generate code, and if instance is a compilation
11117 -- unit we have to wait until the package instance is installed
11118 -- to have a proper place to insert this code.
11120 -- String literals may be operators, but at this point we do not
11121 -- know whether the actual is a formal subprogram or a string.
11126 elsif Nkind
(Act
) = N_Attribute_Reference
then
11127 Analyze
(Prefix
(Act
));
11129 elsif Nkind
(Act
) = N_Explicit_Dereference
then
11130 Analyze
(Prefix
(Act
));
11132 elsif Nkind
(Act
) = N_Allocator
then
11134 Expr
: constant Node_Id
:= Expression
(Act
);
11137 if Nkind
(Expr
) = N_Subtype_Indication
then
11138 Analyze
(Subtype_Mark
(Expr
));
11140 -- Analyze separately each discriminant constraint, when
11141 -- given with a named association.
11147 Constr
:= First
(Constraints
(Constraint
(Expr
)));
11148 while Present
(Constr
) loop
11149 if Nkind
(Constr
) = N_Discriminant_Association
then
11150 Analyze
(Expression
(Constr
));
11164 elsif Nkind
(Act
) /= N_Operator_Symbol
then
11168 if Errs
/= Serious_Errors_Detected
then
11170 -- Do a minimal analysis of the generic, to prevent spurious
11171 -- warnings complaining about the generic being unreferenced,
11172 -- before abandoning the instantiation.
11174 Analyze
(Name
(N
));
11176 if Is_Entity_Name
(Name
(N
))
11177 and then Etype
(Name
(N
)) /= Any_Type
11179 Generate_Reference
(Entity
(Name
(N
)), Name
(N
));
11180 Set_Is_Instantiated
(Entity
(Name
(N
)));
11183 if Present
(Cur
) then
11185 -- For the case of a child instance hiding an outer homonym,
11186 -- provide additional warning which might explain the error.
11188 Set_Is_Immediately_Visible
(Cur
, Vis
);
11189 Error_Msg_NE
("& hides outer unit with the same name?",
11190 N
, Defining_Unit_Name
(N
));
11193 Abandon_Instantiation
(Act
);
11200 if Present
(Cur
) then
11201 Set_Is_Immediately_Visible
(Cur
, Vis
);
11203 end Preanalyze_Actuals
;
11205 -------------------
11206 -- Remove_Parent --
11207 -------------------
11209 procedure Remove_Parent
(In_Body
: Boolean := False) is
11210 S
: Entity_Id
:= Current_Scope
;
11211 -- S is the scope containing the instantiation just completed. The scope
11212 -- stack contains the parent instances of the instantiation, followed by
11220 -- After child instantiation is complete, remove from scope stack the
11221 -- extra copy of the current scope, and then remove parent instances.
11223 if not In_Body
then
11226 while Current_Scope
/= S
loop
11227 P
:= Current_Scope
;
11228 End_Package_Scope
(Current_Scope
);
11230 if In_Open_Scopes
(P
) then
11231 E
:= First_Entity
(P
);
11232 while Present
(E
) loop
11233 Set_Is_Immediately_Visible
(E
, True);
11237 if Is_Generic_Instance
(Current_Scope
)
11238 and then P
/= Current_Scope
11240 -- We are within an instance of some sibling. Retain
11241 -- visibility of parent, for proper subsequent cleanup, and
11242 -- reinstall private declarations as well.
11244 Set_In_Private_Part
(P
);
11245 Install_Private_Declarations
(P
);
11248 -- If the ultimate parent is a top-level unit recorded in
11249 -- Instance_Parent_Unit, then reset its visibility to what is was
11250 -- before instantiation. (It's not clear what the purpose is of
11251 -- testing whether Scope (P) is In_Open_Scopes, but that test was
11252 -- present before the ultimate parent test was added.???)
11254 elsif not In_Open_Scopes
(Scope
(P
))
11255 or else (P
= Instance_Parent_Unit
11256 and then not Parent_Unit_Visible
)
11258 Set_Is_Immediately_Visible
(P
, False);
11260 -- If the current scope is itself an instantiation of a generic
11261 -- nested within P, and we are in the private part of body of this
11262 -- instantiation, restore the full views of P, that were removed
11263 -- in End_Package_Scope above. This obscure case can occur when a
11264 -- subunit of a generic contains an instance of a child unit of
11265 -- its generic parent unit.
11267 elsif S
= Current_Scope
and then Is_Generic_Instance
(S
) then
11269 Par
: constant Entity_Id
:=
11271 (Specification
(Unit_Declaration_Node
(S
)));
11274 and then P
= Scope
(Par
)
11275 and then (In_Package_Body
(S
) or else In_Private_Part
(S
))
11277 Set_In_Private_Part
(P
);
11278 Install_Private_Declarations
(P
);
11284 -- Reset visibility of entities in the enclosing scope
11286 Set_Is_Hidden_Open_Scope
(Current_Scope
, False);
11288 Hidden
:= First_Elmt
(Hidden_Entities
);
11289 while Present
(Hidden
) loop
11290 Set_Is_Immediately_Visible
(Node
(Hidden
), True);
11291 Next_Elmt
(Hidden
);
11295 -- Each body is analyzed separately, and there is no context that
11296 -- needs preserving from one body instance to the next, so remove all
11297 -- parent scopes that have been installed.
11299 while Present
(S
) loop
11300 End_Package_Scope
(S
);
11301 Set_Is_Immediately_Visible
(S
, False);
11302 S
:= Current_Scope
;
11303 exit when S
= Standard_Standard
;
11312 procedure Restore_Env
is
11313 Saved
: Instance_Env
renames Instance_Envs
.Table
(Instance_Envs
.Last
);
11316 if No
(Current_Instantiated_Parent
.Act_Id
) then
11317 -- Restore environment after subprogram inlining
11319 Restore_Private_Views
(Empty
);
11322 Current_Instantiated_Parent
:= Saved
.Instantiated_Parent
;
11323 Exchanged_Views
:= Saved
.Exchanged_Views
;
11324 Hidden_Entities
:= Saved
.Hidden_Entities
;
11325 Current_Sem_Unit
:= Saved
.Current_Sem_Unit
;
11326 Parent_Unit_Visible
:= Saved
.Parent_Unit_Visible
;
11327 Instance_Parent_Unit
:= Saved
.Instance_Parent_Unit
;
11329 Restore_Opt_Config_Switches
(Saved
.Switches
);
11331 Instance_Envs
.Decrement_Last
;
11334 ---------------------------
11335 -- Restore_Private_Views --
11336 ---------------------------
11338 procedure Restore_Private_Views
11339 (Pack_Id
: Entity_Id
;
11340 Is_Package
: Boolean := True)
11345 Dep_Elmt
: Elmt_Id
;
11348 procedure Restore_Nested_Formal
(Formal
: Entity_Id
);
11349 -- Hide the generic formals of formal packages declared with box which
11350 -- were reachable in the current instantiation.
11352 ---------------------------
11353 -- Restore_Nested_Formal --
11354 ---------------------------
11356 procedure Restore_Nested_Formal
(Formal
: Entity_Id
) is
11360 if Present
(Renamed_Object
(Formal
))
11361 and then Denotes_Formal_Package
(Renamed_Object
(Formal
), True)
11365 elsif Present
(Associated_Formal_Package
(Formal
)) then
11366 Ent
:= First_Entity
(Formal
);
11367 while Present
(Ent
) loop
11368 exit when Ekind
(Ent
) = E_Package
11369 and then Renamed_Entity
(Ent
) = Renamed_Entity
(Formal
);
11371 Set_Is_Hidden
(Ent
);
11372 Set_Is_Potentially_Use_Visible
(Ent
, False);
11374 -- If package, then recurse
11376 if Ekind
(Ent
) = E_Package
then
11377 Restore_Nested_Formal
(Ent
);
11383 end Restore_Nested_Formal
;
11385 -- Start of processing for Restore_Private_Views
11388 M
:= First_Elmt
(Exchanged_Views
);
11389 while Present
(M
) loop
11392 -- Subtypes of types whose views have been exchanged, and that
11393 -- are defined within the instance, were not on the list of
11394 -- Private_Dependents on entry to the instance, so they have to be
11395 -- exchanged explicitly now, in order to remain consistent with the
11396 -- view of the parent type.
11398 if Ekind_In
(Typ
, E_Private_Type
,
11399 E_Limited_Private_Type
,
11400 E_Record_Type_With_Private
)
11402 Dep_Elmt
:= First_Elmt
(Private_Dependents
(Typ
));
11403 while Present
(Dep_Elmt
) loop
11404 Dep_Typ
:= Node
(Dep_Elmt
);
11406 if Scope
(Dep_Typ
) = Pack_Id
11407 and then Present
(Full_View
(Dep_Typ
))
11409 Replace_Elmt
(Dep_Elmt
, Full_View
(Dep_Typ
));
11410 Exchange_Declarations
(Dep_Typ
);
11413 Next_Elmt
(Dep_Elmt
);
11417 Exchange_Declarations
(Node
(M
));
11421 if No
(Pack_Id
) then
11425 -- Make the generic formal parameters private, and make the formal types
11426 -- into subtypes of the actuals again.
11428 E
:= First_Entity
(Pack_Id
);
11429 while Present
(E
) loop
11430 Set_Is_Hidden
(E
, True);
11433 and then Nkind
(Parent
(E
)) = N_Subtype_Declaration
11435 Set_Is_Generic_Actual_Type
(E
, False);
11437 -- An unusual case of aliasing: the actual may also be directly
11438 -- visible in the generic, and be private there, while it is fully
11439 -- visible in the context of the instance. The internal subtype
11440 -- is private in the instance, but has full visibility like its
11441 -- parent in the enclosing scope. This enforces the invariant that
11442 -- the privacy status of all private dependents of a type coincide
11443 -- with that of the parent type. This can only happen when a
11444 -- generic child unit is instantiated within sibling.
11446 if Is_Private_Type
(E
)
11447 and then not Is_Private_Type
(Etype
(E
))
11449 Exchange_Declarations
(E
);
11452 elsif Ekind
(E
) = E_Package
then
11454 -- The end of the renaming list is the renaming of the generic
11455 -- package itself. If the instance is a subprogram, all entities
11456 -- in the corresponding package are renamings. If this entity is
11457 -- a formal package, make its own formals private as well. The
11458 -- actual in this case is itself the renaming of an instantiation.
11459 -- If the entity is not a package renaming, it is the entity
11460 -- created to validate formal package actuals: ignore.
11462 -- If the actual is itself a formal package for the enclosing
11463 -- generic, or the actual for such a formal package, it remains
11464 -- visible on exit from the instance, and therefore nothing needs
11465 -- to be done either, except to keep it accessible.
11468 and then Renamed_Object
(E
) = Pack_Id
11472 elsif Nkind
(Parent
(E
)) /= N_Package_Renaming_Declaration
then
11476 Denotes_Formal_Package
(Renamed_Object
(E
), True, Pack_Id
)
11478 Set_Is_Hidden
(E
, False);
11482 Act_P
: constant Entity_Id
:= Renamed_Object
(E
);
11486 Id
:= First_Entity
(Act_P
);
11488 and then Id
/= First_Private_Entity
(Act_P
)
11490 exit when Ekind
(Id
) = E_Package
11491 and then Renamed_Object
(Id
) = Act_P
;
11493 Set_Is_Hidden
(Id
, True);
11494 Set_Is_Potentially_Use_Visible
(Id
, In_Use
(Act_P
));
11496 if Ekind
(Id
) = E_Package
then
11497 Restore_Nested_Formal
(Id
);
11508 end Restore_Private_Views
;
11515 (Gen_Unit
: Entity_Id
;
11516 Act_Unit
: Entity_Id
)
11520 Set_Instance_Env
(Gen_Unit
, Act_Unit
);
11523 ----------------------------
11524 -- Save_Global_References --
11525 ----------------------------
11527 procedure Save_Global_References
(N
: Node_Id
) is
11528 Gen_Scope
: Entity_Id
;
11532 function Is_Global
(E
: Entity_Id
) return Boolean;
11533 -- Check whether entity is defined outside of generic unit. Examine the
11534 -- scope of an entity, and the scope of the scope, etc, until we find
11535 -- either Standard, in which case the entity is global, or the generic
11536 -- unit itself, which indicates that the entity is local. If the entity
11537 -- is the generic unit itself, as in the case of a recursive call, or
11538 -- the enclosing generic unit, if different from the current scope, then
11539 -- it is local as well, because it will be replaced at the point of
11540 -- instantiation. On the other hand, if it is a reference to a child
11541 -- unit of a common ancestor, which appears in an instantiation, it is
11542 -- global because it is used to denote a specific compilation unit at
11543 -- the time the instantiations will be analyzed.
11545 procedure Reset_Entity
(N
: Node_Id
);
11546 -- Save semantic information on global entity so that it is not resolved
11547 -- again at instantiation time.
11549 procedure Save_Entity_Descendants
(N
: Node_Id
);
11550 -- Apply Save_Global_References to the two syntactic descendants of
11551 -- non-terminal nodes that carry an Associated_Node and are processed
11552 -- through Reset_Entity. Once the global entity (if any) has been
11553 -- captured together with its type, only two syntactic descendants need
11554 -- to be traversed to complete the processing of the tree rooted at N.
11555 -- This applies to Selected_Components, Expanded_Names, and to Operator
11556 -- nodes. N can also be a character literal, identifier, or operator
11557 -- symbol node, but the call has no effect in these cases.
11559 procedure Save_Global_Defaults
(N1
, N2
: Node_Id
);
11560 -- Default actuals in nested instances must be handled specially
11561 -- because there is no link to them from the original tree. When an
11562 -- actual subprogram is given by a default, we add an explicit generic
11563 -- association for it in the instantiation node. When we save the
11564 -- global references on the name of the instance, we recover the list
11565 -- of generic associations, and add an explicit one to the original
11566 -- generic tree, through which a global actual can be preserved.
11567 -- Similarly, if a child unit is instantiated within a sibling, in the
11568 -- context of the parent, we must preserve the identifier of the parent
11569 -- so that it can be properly resolved in a subsequent instantiation.
11571 procedure Save_Global_Descendant
(D
: Union_Id
);
11572 -- Apply Save_Global_References recursively to the descendents of the
11575 procedure Save_References
(N
: Node_Id
);
11576 -- This is the recursive procedure that does the work, once the
11577 -- enclosing generic scope has been established.
11583 function Is_Global
(E
: Entity_Id
) return Boolean is
11586 function Is_Instance_Node
(Decl
: Node_Id
) return Boolean;
11587 -- Determine whether the parent node of a reference to a child unit
11588 -- denotes an instantiation or a formal package, in which case the
11589 -- reference to the child unit is global, even if it appears within
11590 -- the current scope (e.g. when the instance appears within the body
11591 -- of an ancestor).
11593 ----------------------
11594 -- Is_Instance_Node --
11595 ----------------------
11597 function Is_Instance_Node
(Decl
: Node_Id
) return Boolean is
11599 return Nkind
(Decl
) in N_Generic_Instantiation
11601 Nkind
(Original_Node
(Decl
)) = N_Formal_Package_Declaration
;
11602 end Is_Instance_Node
;
11604 -- Start of processing for Is_Global
11607 if E
= Gen_Scope
then
11610 elsif E
= Standard_Standard
then
11613 elsif Is_Child_Unit
(E
)
11614 and then (Is_Instance_Node
(Parent
(N2
))
11615 or else (Nkind
(Parent
(N2
)) = N_Expanded_Name
11616 and then N2
= Selector_Name
(Parent
(N2
))
11618 Is_Instance_Node
(Parent
(Parent
(N2
)))))
11624 while Se
/= Gen_Scope
loop
11625 if Se
= Standard_Standard
then
11640 procedure Reset_Entity
(N
: Node_Id
) is
11642 procedure Set_Global_Type
(N
: Node_Id
; N2
: Node_Id
);
11643 -- If the type of N2 is global to the generic unit. Save the type in
11644 -- the generic node.
11645 -- What does this comment mean???
11647 function Top_Ancestor
(E
: Entity_Id
) return Entity_Id
;
11648 -- Find the ultimate ancestor of the current unit. If it is not a
11649 -- generic unit, then the name of the current unit in the prefix of
11650 -- an expanded name must be replaced with its generic homonym to
11651 -- ensure that it will be properly resolved in an instance.
11653 ---------------------
11654 -- Set_Global_Type --
11655 ---------------------
11657 procedure Set_Global_Type
(N
: Node_Id
; N2
: Node_Id
) is
11658 Typ
: constant Entity_Id
:= Etype
(N2
);
11661 Set_Etype
(N
, Typ
);
11663 if Entity
(N
) /= N2
11664 and then Has_Private_View
(Entity
(N
))
11666 -- If the entity of N is not the associated node, this is a
11667 -- nested generic and it has an associated node as well, whose
11668 -- type is already the full view (see below). Indicate that the
11669 -- original node has a private view.
11671 Set_Has_Private_View
(N
);
11674 -- If not a private type, nothing else to do
11676 if not Is_Private_Type
(Typ
) then
11677 if Is_Array_Type
(Typ
)
11678 and then Is_Private_Type
(Component_Type
(Typ
))
11680 Set_Has_Private_View
(N
);
11683 -- If it is a derivation of a private type in a context where no
11684 -- full view is needed, nothing to do either.
11686 elsif No
(Full_View
(Typ
)) and then Typ
/= Etype
(Typ
) then
11689 -- Otherwise mark the type for flipping and use the full view when
11693 Set_Has_Private_View
(N
);
11695 if Present
(Full_View
(Typ
)) then
11696 Set_Etype
(N2
, Full_View
(Typ
));
11699 end Set_Global_Type
;
11705 function Top_Ancestor
(E
: Entity_Id
) return Entity_Id
is
11710 while Is_Child_Unit
(Par
) loop
11711 Par
:= Scope
(Par
);
11717 -- Start of processing for Reset_Entity
11720 N2
:= Get_Associated_Node
(N
);
11723 if Present
(E
) then
11724 if Is_Global
(E
) then
11725 Set_Global_Type
(N
, N2
);
11727 elsif Nkind
(N
) = N_Op_Concat
11728 and then Is_Generic_Type
(Etype
(N2
))
11730 (Base_Type
(Etype
(Right_Opnd
(N2
))) = Etype
(N2
)
11731 or else Base_Type
(Etype
(Left_Opnd
(N2
))) = Etype
(N2
))
11732 and then Is_Intrinsic_Subprogram
(E
)
11737 -- Entity is local. Mark generic node as unresolved.
11738 -- Note that now it does not have an entity.
11740 Set_Associated_Node
(N
, Empty
);
11741 Set_Etype
(N
, Empty
);
11744 if Nkind
(Parent
(N
)) in N_Generic_Instantiation
11745 and then N
= Name
(Parent
(N
))
11747 Save_Global_Defaults
(Parent
(N
), Parent
(N2
));
11750 elsif Nkind
(Parent
(N
)) = N_Selected_Component
11751 and then Nkind
(Parent
(N2
)) = N_Expanded_Name
11753 if Is_Global
(Entity
(Parent
(N2
))) then
11754 Change_Selected_Component_To_Expanded_Name
(Parent
(N
));
11755 Set_Associated_Node
(Parent
(N
), Parent
(N2
));
11756 Set_Global_Type
(Parent
(N
), Parent
(N2
));
11757 Save_Entity_Descendants
(N
);
11759 -- If this is a reference to the current generic entity, replace
11760 -- by the name of the generic homonym of the current package. This
11761 -- is because in an instantiation Par.P.Q will not resolve to the
11762 -- name of the instance, whose enclosing scope is not necessarily
11763 -- Par. We use the generic homonym rather that the name of the
11764 -- generic itself because it may be hidden by a local declaration.
11766 elsif In_Open_Scopes
(Entity
(Parent
(N2
)))
11768 Is_Generic_Unit
(Top_Ancestor
(Entity
(Prefix
(Parent
(N2
)))))
11770 if Ekind
(Entity
(Parent
(N2
))) = E_Generic_Package
then
11771 Rewrite
(Parent
(N
),
11772 Make_Identifier
(Sloc
(N
),
11774 Chars
(Generic_Homonym
(Entity
(Parent
(N2
))))));
11776 Rewrite
(Parent
(N
),
11777 Make_Identifier
(Sloc
(N
),
11778 Chars
=> Chars
(Selector_Name
(Parent
(N2
)))));
11782 if Nkind
(Parent
(Parent
(N
))) in N_Generic_Instantiation
11783 and then Parent
(N
) = Name
(Parent
(Parent
(N
)))
11785 Save_Global_Defaults
11786 (Parent
(Parent
(N
)), Parent
(Parent
((N2
))));
11789 -- A selected component may denote a static constant that has been
11790 -- folded. If the static constant is global to the generic, capture
11791 -- its value. Otherwise the folding will happen in any instantiation.
11793 elsif Nkind
(Parent
(N
)) = N_Selected_Component
11794 and then Nkind_In
(Parent
(N2
), N_Integer_Literal
, N_Real_Literal
)
11796 if Present
(Entity
(Original_Node
(Parent
(N2
))))
11797 and then Is_Global
(Entity
(Original_Node
(Parent
(N2
))))
11799 Rewrite
(Parent
(N
), New_Copy
(Parent
(N2
)));
11800 Set_Analyzed
(Parent
(N
), False);
11806 -- A selected component may be transformed into a parameterless
11807 -- function call. If the called entity is global, rewrite the node
11808 -- appropriately, i.e. as an extended name for the global entity.
11810 elsif Nkind
(Parent
(N
)) = N_Selected_Component
11811 and then Nkind
(Parent
(N2
)) = N_Function_Call
11812 and then N
= Selector_Name
(Parent
(N
))
11814 if No
(Parameter_Associations
(Parent
(N2
))) then
11815 if Is_Global
(Entity
(Name
(Parent
(N2
)))) then
11816 Change_Selected_Component_To_Expanded_Name
(Parent
(N
));
11817 Set_Associated_Node
(Parent
(N
), Name
(Parent
(N2
)));
11818 Set_Global_Type
(Parent
(N
), Name
(Parent
(N2
)));
11819 Save_Entity_Descendants
(N
);
11822 Set_Associated_Node
(N
, Empty
);
11823 Set_Etype
(N
, Empty
);
11826 -- In Ada 2005, X.F may be a call to a primitive operation,
11827 -- rewritten as F (X). This rewriting will be done again in an
11828 -- instance, so keep the original node. Global entities will be
11829 -- captured as for other constructs.
11835 -- Entity is local. Reset in generic unit, so that node is resolved
11836 -- anew at the point of instantiation.
11839 Set_Associated_Node
(N
, Empty
);
11840 Set_Etype
(N
, Empty
);
11844 -----------------------------
11845 -- Save_Entity_Descendants --
11846 -----------------------------
11848 procedure Save_Entity_Descendants
(N
: Node_Id
) is
11851 when N_Binary_Op
=>
11852 Save_Global_Descendant
(Union_Id
(Left_Opnd
(N
)));
11853 Save_Global_Descendant
(Union_Id
(Right_Opnd
(N
)));
11856 Save_Global_Descendant
(Union_Id
(Right_Opnd
(N
)));
11858 when N_Expanded_Name | N_Selected_Component
=>
11859 Save_Global_Descendant
(Union_Id
(Prefix
(N
)));
11860 Save_Global_Descendant
(Union_Id
(Selector_Name
(N
)));
11862 when N_Identifier | N_Character_Literal | N_Operator_Symbol
=>
11866 raise Program_Error
;
11868 end Save_Entity_Descendants
;
11870 --------------------------
11871 -- Save_Global_Defaults --
11872 --------------------------
11874 procedure Save_Global_Defaults
(N1
, N2
: Node_Id
) is
11875 Loc
: constant Source_Ptr
:= Sloc
(N1
);
11876 Assoc2
: constant List_Id
:= Generic_Associations
(N2
);
11877 Gen_Id
: constant Entity_Id
:= Get_Generic_Entity
(N2
);
11884 Actual
: Entity_Id
;
11887 Assoc1
:= Generic_Associations
(N1
);
11889 if Present
(Assoc1
) then
11890 Act1
:= First
(Assoc1
);
11893 Set_Generic_Associations
(N1
, New_List
);
11894 Assoc1
:= Generic_Associations
(N1
);
11897 if Present
(Assoc2
) then
11898 Act2
:= First
(Assoc2
);
11903 while Present
(Act1
) and then Present
(Act2
) loop
11908 -- Find the associations added for default subprograms
11910 if Present
(Act2
) then
11911 while Nkind
(Act2
) /= N_Generic_Association
11912 or else No
(Entity
(Selector_Name
(Act2
)))
11913 or else not Is_Overloadable
(Entity
(Selector_Name
(Act2
)))
11918 -- Add a similar association if the default is global. The
11919 -- renaming declaration for the actual has been analyzed, and
11920 -- its alias is the program it renames. Link the actual in the
11921 -- original generic tree with the node in the analyzed tree.
11923 while Present
(Act2
) loop
11924 Subp
:= Entity
(Selector_Name
(Act2
));
11925 Def
:= Explicit_Generic_Actual_Parameter
(Act2
);
11927 -- Following test is defence against rubbish errors
11929 if No
(Alias
(Subp
)) then
11933 -- Retrieve the resolved actual from the renaming declaration
11934 -- created for the instantiated formal.
11936 Actual
:= Entity
(Name
(Parent
(Parent
(Subp
))));
11937 Set_Entity
(Def
, Actual
);
11938 Set_Etype
(Def
, Etype
(Actual
));
11940 if Is_Global
(Actual
) then
11942 Make_Generic_Association
(Loc
,
11943 Selector_Name
=> New_Occurrence_Of
(Subp
, Loc
),
11944 Explicit_Generic_Actual_Parameter
=>
11945 New_Occurrence_Of
(Actual
, Loc
));
11947 Set_Associated_Node
11948 (Explicit_Generic_Actual_Parameter
(Ndec
), Def
);
11950 Append
(Ndec
, Assoc1
);
11952 -- If there are other defaults, add a dummy association in case
11953 -- there are other defaulted formals with the same name.
11955 elsif Present
(Next
(Act2
)) then
11957 Make_Generic_Association
(Loc
,
11958 Selector_Name
=> New_Occurrence_Of
(Subp
, Loc
),
11959 Explicit_Generic_Actual_Parameter
=> Empty
);
11961 Append
(Ndec
, Assoc1
);
11968 if Nkind
(Name
(N1
)) = N_Identifier
11969 and then Is_Child_Unit
(Gen_Id
)
11970 and then Is_Global
(Gen_Id
)
11971 and then Is_Generic_Unit
(Scope
(Gen_Id
))
11972 and then In_Open_Scopes
(Scope
(Gen_Id
))
11974 -- This is an instantiation of a child unit within a sibling,
11975 -- so that the generic parent is in scope. An eventual instance
11976 -- must occur within the scope of an instance of the parent.
11977 -- Make name in instance into an expanded name, to preserve the
11978 -- identifier of the parent, so it can be resolved subsequently.
11980 Rewrite
(Name
(N2
),
11981 Make_Expanded_Name
(Loc
,
11982 Chars
=> Chars
(Gen_Id
),
11983 Prefix
=> New_Occurrence_Of
(Scope
(Gen_Id
), Loc
),
11984 Selector_Name
=> New_Occurrence_Of
(Gen_Id
, Loc
)));
11985 Set_Entity
(Name
(N2
), Gen_Id
);
11987 Rewrite
(Name
(N1
),
11988 Make_Expanded_Name
(Loc
,
11989 Chars
=> Chars
(Gen_Id
),
11990 Prefix
=> New_Occurrence_Of
(Scope
(Gen_Id
), Loc
),
11991 Selector_Name
=> New_Occurrence_Of
(Gen_Id
, Loc
)));
11993 Set_Associated_Node
(Name
(N1
), Name
(N2
));
11994 Set_Associated_Node
(Prefix
(Name
(N1
)), Empty
);
11995 Set_Associated_Node
11996 (Selector_Name
(Name
(N1
)), Selector_Name
(Name
(N2
)));
11997 Set_Etype
(Name
(N1
), Etype
(Gen_Id
));
12000 end Save_Global_Defaults
;
12002 ----------------------------
12003 -- Save_Global_Descendant --
12004 ----------------------------
12006 procedure Save_Global_Descendant
(D
: Union_Id
) is
12010 if D
in Node_Range
then
12011 if D
= Union_Id
(Empty
) then
12014 elsif Nkind
(Node_Id
(D
)) /= N_Compilation_Unit
then
12015 Save_References
(Node_Id
(D
));
12018 elsif D
in List_Range
then
12019 if D
= Union_Id
(No_List
)
12020 or else Is_Empty_List
(List_Id
(D
))
12025 N1
:= First
(List_Id
(D
));
12026 while Present
(N1
) loop
12027 Save_References
(N1
);
12032 -- Element list or other non-node field, nothing to do
12037 end Save_Global_Descendant
;
12039 ---------------------
12040 -- Save_References --
12041 ---------------------
12043 -- This is the recursive procedure that does the work once the enclosing
12044 -- generic scope has been established. We have to treat specially a
12045 -- number of node rewritings that are required by semantic processing
12046 -- and which change the kind of nodes in the generic copy: typically
12047 -- constant-folding, replacing an operator node by a string literal, or
12048 -- a selected component by an expanded name. In each of those cases, the
12049 -- transformation is propagated to the generic unit.
12051 procedure Save_References
(N
: Node_Id
) is
12052 Loc
: constant Source_Ptr
:= Sloc
(N
);
12058 elsif Nkind_In
(N
, N_Character_Literal
, N_Operator_Symbol
) then
12059 if Nkind
(N
) = Nkind
(Get_Associated_Node
(N
)) then
12062 elsif Nkind
(N
) = N_Operator_Symbol
12063 and then Nkind
(Get_Associated_Node
(N
)) = N_String_Literal
12065 Change_Operator_Symbol_To_String_Literal
(N
);
12068 elsif Nkind
(N
) in N_Op
then
12069 if Nkind
(N
) = Nkind
(Get_Associated_Node
(N
)) then
12070 if Nkind
(N
) = N_Op_Concat
then
12071 Set_Is_Component_Left_Opnd
(N
,
12072 Is_Component_Left_Opnd
(Get_Associated_Node
(N
)));
12074 Set_Is_Component_Right_Opnd
(N
,
12075 Is_Component_Right_Opnd
(Get_Associated_Node
(N
)));
12081 -- Node may be transformed into call to a user-defined operator
12083 N2
:= Get_Associated_Node
(N
);
12085 if Nkind
(N2
) = N_Function_Call
then
12086 E
:= Entity
(Name
(N2
));
12089 and then Is_Global
(E
)
12091 Set_Etype
(N
, Etype
(N2
));
12093 Set_Associated_Node
(N
, Empty
);
12094 Set_Etype
(N
, Empty
);
12097 elsif Nkind_In
(N2
, N_Integer_Literal
,
12101 if Present
(Original_Node
(N2
))
12102 and then Nkind
(Original_Node
(N2
)) = Nkind
(N
)
12105 -- Operation was constant-folded. Whenever possible,
12106 -- recover semantic information from unfolded node,
12109 Set_Associated_Node
(N
, Original_Node
(N2
));
12111 if Nkind
(N
) = N_Op_Concat
then
12112 Set_Is_Component_Left_Opnd
(N
,
12113 Is_Component_Left_Opnd
(Get_Associated_Node
(N
)));
12114 Set_Is_Component_Right_Opnd
(N
,
12115 Is_Component_Right_Opnd
(Get_Associated_Node
(N
)));
12121 -- If original node is already modified, propagate
12122 -- constant-folding to template.
12124 Rewrite
(N
, New_Copy
(N2
));
12125 Set_Analyzed
(N
, False);
12128 elsif Nkind
(N2
) = N_Identifier
12129 and then Ekind
(Entity
(N2
)) = E_Enumeration_Literal
12131 -- Same if call was folded into a literal, but in this case
12132 -- retain the entity to avoid spurious ambiguities if it is
12133 -- overloaded at the point of instantiation or inlining.
12135 Rewrite
(N
, New_Copy
(N2
));
12136 Set_Analyzed
(N
, False);
12140 -- Complete operands check if node has not been constant-folded
12142 if Nkind
(N
) in N_Op
then
12143 Save_Entity_Descendants
(N
);
12146 elsif Nkind
(N
) = N_Identifier
then
12147 if Nkind
(N
) = Nkind
(Get_Associated_Node
(N
)) then
12149 -- If this is a discriminant reference, always save it. It is
12150 -- used in the instance to find the corresponding discriminant
12151 -- positionally rather than by name.
12153 Set_Original_Discriminant
12154 (N
, Original_Discriminant
(Get_Associated_Node
(N
)));
12158 N2
:= Get_Associated_Node
(N
);
12160 if Nkind
(N2
) = N_Function_Call
then
12161 E
:= Entity
(Name
(N2
));
12163 -- Name resolves to a call to parameterless function. If
12164 -- original entity is global, mark node as resolved.
12167 and then Is_Global
(E
)
12169 Set_Etype
(N
, Etype
(N2
));
12171 Set_Associated_Node
(N
, Empty
);
12172 Set_Etype
(N
, Empty
);
12175 elsif Nkind_In
(N2
, N_Integer_Literal
, N_Real_Literal
)
12176 and then Is_Entity_Name
(Original_Node
(N2
))
12178 -- Name resolves to named number that is constant-folded,
12179 -- We must preserve the original name for ASIS use, and
12180 -- undo the constant-folding, which will be repeated in
12183 Set_Associated_Node
(N
, Original_Node
(N2
));
12186 elsif Nkind
(N2
) = N_String_Literal
then
12188 -- Name resolves to string literal. Perform the same
12189 -- replacement in generic.
12191 Rewrite
(N
, New_Copy
(N2
));
12193 elsif Nkind
(N2
) = N_Explicit_Dereference
then
12195 -- An identifier is rewritten as a dereference if it is the
12196 -- prefix in an implicit dereference (call or attribute).
12197 -- The analysis of an instantiation will expand the node
12198 -- again, so we preserve the original tree but link it to
12199 -- the resolved entity in case it is global.
12201 if Is_Entity_Name
(Prefix
(N2
))
12202 and then Present
(Entity
(Prefix
(N2
)))
12203 and then Is_Global
(Entity
(Prefix
(N2
)))
12205 Set_Associated_Node
(N
, Prefix
(N2
));
12207 elsif Nkind
(Prefix
(N2
)) = N_Function_Call
12208 and then Is_Global
(Entity
(Name
(Prefix
(N2
))))
12211 Make_Explicit_Dereference
(Loc
,
12212 Prefix
=> Make_Function_Call
(Loc
,
12214 New_Occurrence_Of
(Entity
(Name
(Prefix
(N2
))),
12218 Set_Associated_Node
(N
, Empty
);
12219 Set_Etype
(N
, Empty
);
12222 -- The subtype mark of a nominally unconstrained object is
12223 -- rewritten as a subtype indication using the bounds of the
12224 -- expression. Recover the original subtype mark.
12226 elsif Nkind
(N2
) = N_Subtype_Indication
12227 and then Is_Entity_Name
(Original_Node
(N2
))
12229 Set_Associated_Node
(N
, Original_Node
(N2
));
12237 elsif Nkind
(N
) in N_Entity
then
12242 Qual
: Node_Id
:= Empty
;
12243 Typ
: Entity_Id
:= Empty
;
12246 use Atree
.Unchecked_Access
;
12247 -- This code section is part of implementing an untyped tree
12248 -- traversal, so it needs direct access to node fields.
12251 if Nkind_In
(N
, N_Aggregate
, N_Extension_Aggregate
) then
12252 N2
:= Get_Associated_Node
(N
);
12259 -- In an instance within a generic, use the name of the
12260 -- actual and not the original generic parameter. If the
12261 -- actual is global in the current generic it must be
12262 -- preserved for its instantiation.
12264 if Nkind
(Parent
(Typ
)) = N_Subtype_Declaration
12266 Present
(Generic_Parent_Type
(Parent
(Typ
)))
12268 Typ
:= Base_Type
(Typ
);
12269 Set_Etype
(N2
, Typ
);
12275 or else not Is_Global
(Typ
)
12277 Set_Associated_Node
(N
, Empty
);
12279 -- If the aggregate is an actual in a call, it has been
12280 -- resolved in the current context, to some local type.
12281 -- The enclosing call may have been disambiguated by the
12282 -- aggregate, and this disambiguation might fail at
12283 -- instantiation time because the type to which the
12284 -- aggregate did resolve is not preserved. In order to
12285 -- preserve some of this information, we wrap the
12286 -- aggregate in a qualified expression, using the id of
12287 -- its type. For further disambiguation we qualify the
12288 -- type name with its scope (if visible) because both
12289 -- id's will have corresponding entities in an instance.
12290 -- This resolves most of the problems with missing type
12291 -- information on aggregates in instances.
12293 if Nkind
(N2
) = Nkind
(N
)
12295 Nkind_In
(Parent
(N2
), N_Procedure_Call_Statement
,
12297 and then Comes_From_Source
(Typ
)
12299 if Is_Immediately_Visible
(Scope
(Typ
)) then
12300 Nam
:= Make_Selected_Component
(Loc
,
12302 Make_Identifier
(Loc
, Chars
(Scope
(Typ
))),
12304 Make_Identifier
(Loc
, Chars
(Typ
)));
12306 Nam
:= Make_Identifier
(Loc
, Chars
(Typ
));
12310 Make_Qualified_Expression
(Loc
,
12311 Subtype_Mark
=> Nam
,
12312 Expression
=> Relocate_Node
(N
));
12316 Save_Global_Descendant
(Field1
(N
));
12317 Save_Global_Descendant
(Field2
(N
));
12318 Save_Global_Descendant
(Field3
(N
));
12319 Save_Global_Descendant
(Field5
(N
));
12321 if Present
(Qual
) then
12325 -- All other cases than aggregates
12328 -- For pragmas, we propagate the Enabled status for the
12329 -- relevant pragmas to the original generic tree. This was
12330 -- originally needed for SCO generation. It is no longer
12331 -- needed there (since we use the Sloc value in calls to
12332 -- Set_SCO_Pragma_Enabled), but it seems a generally good
12333 -- idea to have this flag set properly.
12335 if Nkind
(N
) = N_Pragma
12337 (Pragma_Name
(N
) = Name_Assert
or else
12338 Pragma_Name
(N
) = Name_Check
or else
12339 Pragma_Name
(N
) = Name_Precondition
or else
12340 Pragma_Name
(N
) = Name_Postcondition
)
12341 and then Present
(Associated_Node
(Pragma_Identifier
(N
)))
12343 Set_Pragma_Enabled
(N
,
12345 (Parent
(Associated_Node
(Pragma_Identifier
(N
)))));
12348 Save_Global_Descendant
(Field1
(N
));
12349 Save_Global_Descendant
(Field2
(N
));
12350 Save_Global_Descendant
(Field3
(N
));
12351 Save_Global_Descendant
(Field4
(N
));
12352 Save_Global_Descendant
(Field5
(N
));
12356 end Save_References
;
12358 -- Start of processing for Save_Global_References
12361 Gen_Scope
:= Current_Scope
;
12363 -- If the generic unit is a child unit, references to entities in the
12364 -- parent are treated as local, because they will be resolved anew in
12365 -- the context of the instance of the parent.
12367 while Is_Child_Unit
(Gen_Scope
)
12368 and then Ekind
(Scope
(Gen_Scope
)) = E_Generic_Package
12370 Gen_Scope
:= Scope
(Gen_Scope
);
12373 Save_References
(N
);
12374 end Save_Global_References
;
12376 --------------------------------------
12377 -- Set_Copied_Sloc_For_Inlined_Body --
12378 --------------------------------------
12380 procedure Set_Copied_Sloc_For_Inlined_Body
(N
: Node_Id
; E
: Entity_Id
) is
12382 Create_Instantiation_Source
(N
, E
, True, S_Adjustment
);
12383 end Set_Copied_Sloc_For_Inlined_Body
;
12385 ---------------------
12386 -- Set_Instance_Of --
12387 ---------------------
12389 procedure Set_Instance_Of
(A
: Entity_Id
; B
: Entity_Id
) is
12391 Generic_Renamings
.Table
(Generic_Renamings
.Last
) := (A
, B
, Assoc_Null
);
12392 Generic_Renamings_HTable
.Set
(Generic_Renamings
.Last
);
12393 Generic_Renamings
.Increment_Last
;
12394 end Set_Instance_Of
;
12396 --------------------
12397 -- Set_Next_Assoc --
12398 --------------------
12400 procedure Set_Next_Assoc
(E
: Assoc_Ptr
; Next
: Assoc_Ptr
) is
12402 Generic_Renamings
.Table
(E
).Next_In_HTable
:= Next
;
12403 end Set_Next_Assoc
;
12405 -------------------
12406 -- Start_Generic --
12407 -------------------
12409 procedure Start_Generic
is
12411 -- ??? More things could be factored out in this routine.
12412 -- Should probably be done at a later stage.
12414 Generic_Flags
.Append
(Inside_A_Generic
);
12415 Inside_A_Generic
:= True;
12417 Expander_Mode_Save_And_Set
(False);
12420 ----------------------
12421 -- Set_Instance_Env --
12422 ----------------------
12424 procedure Set_Instance_Env
12425 (Gen_Unit
: Entity_Id
;
12426 Act_Unit
: Entity_Id
)
12429 -- Regardless of the current mode, predefined units are analyzed in the
12430 -- most current Ada mode, and earlier version Ada checks do not apply
12431 -- to predefined units. Nothing needs to be done for non-internal units.
12432 -- These are always analyzed in the current mode.
12434 if Is_Internal_File_Name
12435 (Fname
=> Unit_File_Name
(Get_Source_Unit
(Gen_Unit
)),
12436 Renamings_Included
=> True)
12438 Set_Opt_Config_Switches
(True, Current_Sem_Unit
= Main_Unit
);
12441 Current_Instantiated_Parent
:=
12442 (Gen_Id
=> Gen_Unit
,
12443 Act_Id
=> Act_Unit
,
12444 Next_In_HTable
=> Assoc_Null
);
12445 end Set_Instance_Env
;
12451 procedure Switch_View
(T
: Entity_Id
) is
12452 BT
: constant Entity_Id
:= Base_Type
(T
);
12453 Priv_Elmt
: Elmt_Id
:= No_Elmt
;
12454 Priv_Sub
: Entity_Id
;
12457 -- T may be private but its base type may have been exchanged through
12458 -- some other occurrence, in which case there is nothing to switch
12459 -- besides T itself. Note that a private dependent subtype of a private
12460 -- type might not have been switched even if the base type has been,
12461 -- because of the last branch of Check_Private_View (see comment there).
12463 if not Is_Private_Type
(BT
) then
12464 Prepend_Elmt
(Full_View
(T
), Exchanged_Views
);
12465 Exchange_Declarations
(T
);
12469 Priv_Elmt
:= First_Elmt
(Private_Dependents
(BT
));
12471 if Present
(Full_View
(BT
)) then
12472 Prepend_Elmt
(Full_View
(BT
), Exchanged_Views
);
12473 Exchange_Declarations
(BT
);
12476 while Present
(Priv_Elmt
) loop
12477 Priv_Sub
:= (Node
(Priv_Elmt
));
12479 -- We avoid flipping the subtype if the Etype of its full view is
12480 -- private because this would result in a malformed subtype. This
12481 -- occurs when the Etype of the subtype full view is the full view of
12482 -- the base type (and since the base types were just switched, the
12483 -- subtype is pointing to the wrong view). This is currently the case
12484 -- for tagged record types, access types (maybe more?) and needs to
12485 -- be resolved. ???
12487 if Present
(Full_View
(Priv_Sub
))
12488 and then not Is_Private_Type
(Etype
(Full_View
(Priv_Sub
)))
12490 Prepend_Elmt
(Full_View
(Priv_Sub
), Exchanged_Views
);
12491 Exchange_Declarations
(Priv_Sub
);
12494 Next_Elmt
(Priv_Elmt
);
12498 -----------------------------
12499 -- Valid_Default_Attribute --
12500 -----------------------------
12502 procedure Valid_Default_Attribute
(Nam
: Entity_Id
; Def
: Node_Id
) is
12503 Attr_Id
: constant Attribute_Id
:=
12504 Get_Attribute_Id
(Attribute_Name
(Def
));
12505 T
: constant Entity_Id
:= Entity
(Prefix
(Def
));
12506 Is_Fun
: constant Boolean := (Ekind
(Nam
) = E_Function
);
12519 F
:= First_Formal
(Nam
);
12520 while Present
(F
) loop
12521 Num_F
:= Num_F
+ 1;
12526 when Attribute_Adjacent | Attribute_Ceiling | Attribute_Copy_Sign |
12527 Attribute_Floor | Attribute_Fraction | Attribute_Machine |
12528 Attribute_Model | Attribute_Remainder | Attribute_Rounding |
12529 Attribute_Unbiased_Rounding
=>
12532 and then Is_Floating_Point_Type
(T
);
12534 when Attribute_Image | Attribute_Pred | Attribute_Succ |
12535 Attribute_Value | Attribute_Wide_Image |
12536 Attribute_Wide_Value
=>
12537 OK
:= (Is_Fun
and then Num_F
= 1 and then Is_Scalar_Type
(T
));
12539 when Attribute_Max | Attribute_Min
=>
12540 OK
:= (Is_Fun
and then Num_F
= 2 and then Is_Scalar_Type
(T
));
12542 when Attribute_Input
=>
12543 OK
:= (Is_Fun
and then Num_F
= 1);
12545 when Attribute_Output | Attribute_Read | Attribute_Write
=>
12546 OK
:= (not Is_Fun
and then Num_F
= 2);
12553 Error_Msg_N
("attribute reference has wrong profile for subprogram",
12556 end Valid_Default_Attribute
;