2014-10-10 Robert Dewar <dewar@adacore.com>
[official-gcc.git] / gcc / ada / sem_aux.ads
blobbb539e2e17aa134a9252debadedf47ebc3ffefca
1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- S E M _ A U X --
6 -- --
7 -- S p e c --
8 -- --
9 -- Copyright (C) 1992-2014, Free Software Foundation, Inc. --
10 -- --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
20 -- --
21 -- As a special exception, if other files instantiate generics from this --
22 -- unit, or you link this unit with other files to produce an executable, --
23 -- this unit does not by itself cause the resulting executable to be --
24 -- covered by the GNU General Public License. This exception does not --
25 -- however invalidate any other reasons why the executable file might be --
26 -- covered by the GNU Public License. --
27 -- --
28 -- GNAT was originally developed by the GNAT team at New York University. --
29 -- Extensive contributions were provided by Ada Core Technologies Inc. --
30 -- --
31 ------------------------------------------------------------------------------
33 -- Package containing utility procedures used throughout the compiler,
34 -- and also by ASIS so dependencies are limited to ASIS included packages.
36 -- Historical note. Many of the routines here were originally in Einfo, but
37 -- Einfo is supposed to be a relatively low level package dealing with the
38 -- content of entities in the tree, so this package is used for routines that
39 -- require more than minimal semantic knowledge.
41 with Alloc; use Alloc;
42 with Namet; use Namet;
43 with Table;
44 with Types; use Types;
45 with Sinfo; use Sinfo;
47 package Sem_Aux is
49 --------------------------------
50 -- Obsolescent Warnings Table --
51 --------------------------------
53 -- This table records entities for which a pragma Obsolescent with a
54 -- message argument has been processed.
56 type OWT_Record is record
57 Ent : Entity_Id;
58 -- The entity to which the pragma applies
60 Msg : String_Id;
61 -- The string containing the message
62 end record;
64 package Obsolescent_Warnings is new Table.Table (
65 Table_Component_Type => OWT_Record,
66 Table_Index_Type => Int,
67 Table_Low_Bound => 0,
68 Table_Initial => Alloc.Obsolescent_Warnings_Initial,
69 Table_Increment => Alloc.Obsolescent_Warnings_Increment,
70 Table_Name => "Obsolescent_Warnings");
72 procedure Initialize;
73 -- Called at the start of compilation of each new main source file to
74 -- initialize the allocation of the Obsolescent_Warnings table. Note that
75 -- Initialize must not be called if Tree_Read is used.
77 procedure Tree_Read;
78 -- Initializes Obsolescent_Warnings table from current tree file using the
79 -- relevant Table.Tree_Read routine.
81 procedure Tree_Write;
82 -- Writes out Obsolescent_Warnings table to current tree file using the
83 -- relevant Table.Tree_Write routine.
85 -----------------
86 -- Subprograms --
87 -----------------
89 function Ancestor_Subtype (Typ : Entity_Id) return Entity_Id;
90 -- The argument Id is a type or subtype entity. If the argument is a
91 -- subtype then it returns the subtype or type from which the subtype was
92 -- obtained, otherwise it returns Empty.
94 function Available_View (Ent : Entity_Id) return Entity_Id;
95 -- Ent denotes an abstract state or a type that may come from a limited
96 -- with clause. Return the non-limited view of Ent if there is one or Ent
97 -- if this is not the case.
99 function Constant_Value (Ent : Entity_Id) return Node_Id;
100 -- Ent is a variable, constant, named integer, or named real entity. This
101 -- call obtains the initialization expression for the entity. Will return
102 -- Empty for a deferred constant whose full view is not available or
103 -- in some other cases of internal entities, which cannot be treated as
104 -- constants from the point of view of constant folding. Empty is also
105 -- returned for variables with no initialization expression.
107 function Corresponding_Unsigned_Type (Typ : Entity_Id) return Entity_Id;
108 -- Typ is a signed integer subtype. This routine returns the standard
109 -- unsigned type with the same Esize as the implementation base type of
110 -- Typ, e.g. Long_Integer => Long_Unsigned.
112 function Enclosing_Dynamic_Scope (Ent : Entity_Id) return Entity_Id;
113 -- For any entity, Ent, returns the closest dynamic scope in which the
114 -- entity is declared or Standard_Standard for library-level entities.
116 function First_Discriminant (Typ : Entity_Id) return Entity_Id;
117 -- Typ is a type with discriminants. The discriminants are the first
118 -- entities declared in the type, so normally this is equivalent to
119 -- First_Entity. The exception arises for tagged types, where the tag
120 -- itself is prepended to the front of the entity chain, so the
121 -- First_Discriminant function steps past the tag if it is present.
123 function First_Stored_Discriminant (Typ : Entity_Id) return Entity_Id;
124 -- Typ is a type with discriminants. Gives the first discriminant stored
125 -- in an object of this type. In many cases, these are the same as the
126 -- normal visible discriminants for the type, but in the case of renamed
127 -- discriminants, this is not always the case.
129 -- For tagged types, and untagged types which are root types or derived
130 -- types but which do not rename discriminants in their root type, the
131 -- stored discriminants are the same as the actual discriminants of the
132 -- type, and hence this function is the same as First_Discriminant.
134 -- For derived untagged types that rename discriminants in the root type
135 -- this is the first of the discriminants that occur in the root type. To
136 -- be precise, in this case stored discriminants are entities attached to
137 -- the entity chain of the derived type which are a copy of the
138 -- discriminants of the root type. Furthermore their Is_Completely_Hidden
139 -- flag is set since although they are actually stored in the object, they
140 -- are not in the set of discriminants that is visible in the type.
142 -- For derived untagged types, the set of stored discriminants are the real
143 -- discriminants from Gigi's standpoint, i.e. those that will be stored in
144 -- actual objects of the type.
146 function First_Subtype (Typ : Entity_Id) return Entity_Id;
147 -- Applies to all types and subtypes. For types, yields the first subtype
148 -- of the type. For subtypes, yields the first subtype of the base type of
149 -- the subtype.
151 function First_Tag_Component (Typ : Entity_Id) return Entity_Id;
152 -- Typ must be a tagged record type. This function returns the Entity for
153 -- the first _Tag field in the record type.
155 function Get_Binary_Nkind (Op : Entity_Id) return Node_Kind;
156 -- Op must be an entity with an Ekind of E_Operator. This function returns
157 -- the Nkind value that would be used to construct a binary operator node
158 -- referencing this entity. It is an error to call this function if Ekind
159 -- (Op) /= E_Operator.
161 function Get_Unary_Nkind (Op : Entity_Id) return Node_Kind;
162 -- Op must be an entity with an Ekind of E_Operator. This function returns
163 -- the Nkind value that would be used to construct a unary operator node
164 -- referencing this entity. It is an error to call this function if Ekind
165 -- (Op) /= E_Operator.
167 function Get_Rep_Item
168 (E : Entity_Id;
169 Nam : Name_Id;
170 Check_Parents : Boolean := True) return Node_Id;
171 -- Searches the Rep_Item chain for a given entity E, for an instance of a
172 -- rep item (pragma, attribute definition clause, or aspect specification)
173 -- whose name matches the given name Nam. If Check_Parents is False then it
174 -- only returns rep item that has been directly specified for E (and not
175 -- inherited from its parents, if any). If one is found, it is returned,
176 -- otherwise Empty is returned. A special case is that when Nam is
177 -- Name_Priority, the call will also find Interrupt_Priority.
179 function Get_Rep_Item
180 (E : Entity_Id;
181 Nam1 : Name_Id;
182 Nam2 : Name_Id;
183 Check_Parents : Boolean := True) return Node_Id;
184 -- Searches the Rep_Item chain for a given entity E, for an instance of a
185 -- rep item (pragma, attribute definition clause, or aspect specification)
186 -- whose name matches one of the given names Nam1 or Nam2. If Check_Parents
187 -- is False then it only returns rep item that has been directly specified
188 -- for E (and not inherited from its parents, if any). If one is found, it
189 -- is returned, otherwise Empty is returned. A special case is that when
190 -- one of the given names is Name_Priority, the call will also find
191 -- Interrupt_Priority.
193 function Get_Rep_Pragma
194 (E : Entity_Id;
195 Nam : Name_Id;
196 Check_Parents : Boolean := True) return Node_Id;
197 -- Searches the Rep_Item chain for a given entity E, for an instance of a
198 -- representation pragma whose name matches the given name Nam. If
199 -- Check_Parents is False then it only returns representation pragma that
200 -- has been directly specified for E (and not inherited from its parents,
201 -- if any). If one is found and if it is the first rep item in the list
202 -- that matches Nam, it is returned, otherwise Empty is returned. A special
203 -- case is that when Nam is Name_Priority, the call will also find
204 -- Interrupt_Priority.
206 function Get_Rep_Pragma
207 (E : Entity_Id;
208 Nam1 : Name_Id;
209 Nam2 : Name_Id;
210 Check_Parents : Boolean := True) return Node_Id;
211 -- Searches the Rep_Item chain for a given entity E, for an instance of a
212 -- representation pragma whose name matches one of the given names Nam1 or
213 -- Nam2. If Check_Parents is False then it only returns representation
214 -- pragma that has been directly specified for E (and not inherited from
215 -- its parents, if any). If one is found and if it is the first rep item in
216 -- the list that matches one of the given names, it is returned, otherwise
217 -- Empty is returned. A special case is that when one of the given names is
218 -- Name_Priority, the call will also find Interrupt_Priority.
220 function Has_Rep_Item
221 (E : Entity_Id;
222 Nam : Name_Id;
223 Check_Parents : Boolean := True) return Boolean;
224 -- Searches the Rep_Item chain for the given entity E, for an instance of a
225 -- rep item (pragma, attribute definition clause, or aspect specification)
226 -- with the given name Nam. If Check_Parents is False then it only checks
227 -- for a rep item that has been directly specified for E (and not inherited
228 -- from its parents, if any). If found then True is returned, otherwise
229 -- False indicates that no matching entry was found.
231 function Has_Rep_Item
232 (E : Entity_Id;
233 Nam1 : Name_Id;
234 Nam2 : Name_Id;
235 Check_Parents : Boolean := True) return Boolean;
236 -- Searches the Rep_Item chain for the given entity E, for an instance of a
237 -- rep item (pragma, attribute definition clause, or aspect specification)
238 -- with the given names Nam1 or Nam2. If Check_Parents is False then it
239 -- only checks for a rep item that has been directly specified for E (and
240 -- not inherited from its parents, if any). If found then True is returned,
241 -- otherwise False indicates that no matching entry was found.
243 function Has_Rep_Pragma
244 (E : Entity_Id;
245 Nam : Name_Id;
246 Check_Parents : Boolean := True) return Boolean;
247 -- Searches the Rep_Item chain for the given entity E, for an instance of a
248 -- representation pragma with the given name Nam. If Check_Parents is False
249 -- then it only checks for a representation pragma that has been directly
250 -- specified for E (and not inherited from its parents, if any). If found
251 -- and if it is the first rep item in the list that matches Nam then True
252 -- is returned, otherwise False indicates that no matching entry was found.
254 function Has_Rep_Pragma
255 (E : Entity_Id;
256 Nam1 : Name_Id;
257 Nam2 : Name_Id;
258 Check_Parents : Boolean := True) return Boolean;
259 -- Searches the Rep_Item chain for the given entity E, for an instance of a
260 -- representation pragma with the given names Nam1 or Nam2. If
261 -- Check_Parents is False then it only checks for a rep item that has been
262 -- directly specified for E (and not inherited from its parents, if any).
263 -- If found and if it is the first rep item in the list that matches one of
264 -- the given names then True is returned, otherwise False indicates that no
265 -- matching entry was found.
267 function Has_External_Tag_Rep_Clause (T : Entity_Id) return Boolean;
268 -- Defined in tagged types. Set if an External_Tag rep. clause has been
269 -- given for this type. Use to avoid the generation of the default
270 -- External_Tag.
272 -- Note: we used to use an entity flag for this purpose, but that was wrong
273 -- because it was not propagated from the private view to the full view. We
274 -- could have added that propagation, but it would have been an annoying
275 -- irregularity compared to other representation aspects, and the cost of
276 -- looking up the aspect when needed is small.
278 function Has_Unconstrained_Elements (T : Entity_Id) return Boolean;
279 -- True if T has discriminants and is unconstrained, or is an array type
280 -- whose element type Has_Unconstrained_Elements.
282 function Has_Variant_Part (Typ : Entity_Id) return Boolean;
283 -- Return True if the first subtype of Typ is a discriminated record type
284 -- which has a variant part. False otherwise.
286 function In_Generic_Body (Id : Entity_Id) return Boolean;
287 -- Determine whether entity Id appears inside a generic body
289 function Initialization_Suppressed (Typ : Entity_Id) return Boolean;
290 pragma Inline (Initialization_Suppressed);
291 -- Returns True if initialization should be suppressed for the given type
292 -- or subtype. This is true if Suppress_Initialization is set either for
293 -- the subtype itself, or for the corresponding base type.
295 function Is_Body (N : Node_Id) return Boolean;
296 -- Determine whether an arbitrary node denotes a body
298 function Is_By_Copy_Type (Ent : Entity_Id) return Boolean;
299 -- Ent is any entity. Returns True if Ent is a type entity where the type
300 -- is required to be passed by copy, as defined in (RM 6.2(3)).
302 function Is_By_Reference_Type (Ent : Entity_Id) return Boolean;
303 -- Ent is any entity. Returns True if Ent is a type entity where the type
304 -- is required to be passed by reference, as defined in (RM 6.2(4-9)).
306 function Is_Derived_Type (Ent : Entity_Id) return Boolean;
307 -- Determines if the given entity Ent is a derived type. Result is always
308 -- false if argument is not a type.
310 function Is_Generic_Formal (E : Entity_Id) return Boolean;
311 -- Determine whether E is a generic formal parameter. In particular this is
312 -- used to set the visibility of generic formals of a generic package
313 -- declared with a box or with partial parameterization.
315 function Is_Indefinite_Subtype (Ent : Entity_Id) return Boolean;
316 -- Ent is any entity. Determines if given entity is an unconstrained array
317 -- type or subtype, a discriminated record type or subtype with no initial
318 -- discriminant values or a class wide type or subtype and returns True if
319 -- so. False for other type entities, or any entities that are not types.
321 function Is_Immutably_Limited_Type (Ent : Entity_Id) return Boolean;
322 -- Implements definition in Ada 2012 RM-7.5 (8.1/3). This differs from the
323 -- following predicate in that an untagged record with immutably limited
324 -- components is NOT by itself immutably limited. This matters, e.g. when
325 -- checking the legality of an access to the current instance.
327 function Is_Limited_View (Ent : Entity_Id) return Boolean;
328 -- Ent is any entity. True for a type that is "inherently" limited (i.e.
329 -- cannot become nonlimited). From the Ada 2005 RM-7.5(8.1/2), "a type with
330 -- a part that is of a task, protected, or explicitly limited record type".
331 -- These are the types that are defined as return-by-reference types in Ada
332 -- 95 (see RM95-6.5(11-16)). In Ada 2005, these are the types that require
333 -- build-in-place for function calls. Note that build-in-place is allowed
334 -- for other types, too. This is also used for identifying pure procedures
335 -- whose calls should not be eliminated (RM 10.2.1(18/2)).
337 function Is_Limited_Type (Ent : Entity_Id) return Boolean;
338 -- Ent is any entity. Returns true if Ent is a limited type (limited
339 -- private type, limited interface type, task type, protected type,
340 -- composite containing a limited component, or a subtype of any of
341 -- these types). This older routine overlaps with the previous one, this
342 -- should be cleaned up???
344 function Nearest_Ancestor (Typ : Entity_Id) return Entity_Id;
345 -- Given a subtype Typ, this function finds out the nearest ancestor from
346 -- which constraints and predicates are inherited. There is no simple link
347 -- for doing this, consider:
349 -- subtype R is Integer range 1 .. 10;
350 -- type T is new R;
352 -- In this case the nearest ancestor is R, but the Etype of T'Base will
353 -- point to R'Base, so we have to go rummaging in the declarations to get
354 -- this information. It is used for making sure we freeze this before we
355 -- freeze Typ, and also for retrieving inherited predicate information.
356 -- For the case of base types or first subtypes, there is no useful entity
357 -- to return, so Empty is returned.
359 -- Note: this is similar to Ancestor_Subtype except that it also deals
360 -- with the case of derived types.
362 function Nearest_Dynamic_Scope (Ent : Entity_Id) return Entity_Id;
363 -- This is similar to Enclosing_Dynamic_Scope except that if Ent is itself
364 -- a dynamic scope, then it is returned. Otherwise the result is the same
365 -- as that returned by Enclosing_Dynamic_Scope.
367 function Next_Tag_Component (Tag : Entity_Id) return Entity_Id;
368 -- Tag must be an entity representing a _Tag field of a tagged record.
369 -- The result returned is the next _Tag field in this record, or Empty
370 -- if this is the last such field.
372 function Number_Discriminants (Typ : Entity_Id) return Pos;
373 -- Typ is a type with discriminants, yields number of discriminants in type
375 function Object_Type_Has_Constrained_Partial_View
376 (Typ : Entity_Id;
377 Scop : Entity_Id) return Boolean;
378 -- Return True if type of object has attribute Has_Constrained_Partial_View
379 -- set to True; in addition, within a generic body, return True if subtype
380 -- of the object is a descendant of an untagged generic formal private or
381 -- derived type, and the subtype is not an unconstrained array subtype
382 -- (RM 3.3(23.10/3)).
384 function Ultimate_Alias (Prim : Entity_Id) return Entity_Id;
385 pragma Inline (Ultimate_Alias);
386 -- Return the last entity in the chain of aliased entities of Prim. If Prim
387 -- has no alias return Prim.
389 function Unit_Declaration_Node (Unit_Id : Entity_Id) return Node_Id;
390 -- Unit_Id is the simple name of a program unit, this function returns the
391 -- corresponding xxx_Declaration node for the entity. Also applies to the
392 -- body entities for subprograms, tasks and protected units, in which case
393 -- it returns the subprogram, task or protected body node for it. The unit
394 -- may be a child unit with any number of ancestors.
396 function Package_Specification (Pack_Id : Entity_Id) return Node_Id;
397 -- Given an entity for a package or generic package, return corresponding
398 -- package specification. Simplifies handling of child units, and better
399 -- than the old idiom: Specification (Unit_Declaration_Node (Pack_Id)).
401 end Sem_Aux;