Improve fstack_protector effective target
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- S E M _ C H 1 3 --
6 -- --
7 -- S p e c --
8 -- --
9 -- Copyright (C) 1992-2016, Free Software Foundation, Inc. --
10 -- --
11 -- GNAT is free software; you can redistribute it and/or modify it under --
12 -- terms of the GNU General Public License as published by the Free Soft- --
13 -- ware Foundation; either version 3, or (at your option) any later ver- --
14 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
15 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
16 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
17 -- for more details. You should have received a copy of the GNU General --
18 -- Public License distributed with GNAT; see file COPYING3. If not, go to --
19 -- http://www.gnu.org/licenses for a complete copy of the license. --
20 -- --
21 -- GNAT was originally developed by the GNAT team at New York University. --
22 -- Extensive contributions were provided by Ada Core Technologies Inc. --
23 -- --
24 ------------------------------------------------------------------------------
26 with Table;
27 with Types; use Types;
28 with Uintp; use Uintp;
30 package Sem_Ch13 is
31 procedure Analyze_At_Clause (N : Node_Id);
32 procedure Analyze_Attribute_Definition_Clause (N : Node_Id);
33 procedure Analyze_Enumeration_Representation_Clause (N : Node_Id);
34 procedure Analyze_Free_Statement (N : Node_Id);
35 procedure Analyze_Freeze_Entity (N : Node_Id);
36 procedure Analyze_Freeze_Generic_Entity (N : Node_Id);
37 procedure Analyze_Record_Representation_Clause (N : Node_Id);
38 procedure Analyze_Code_Statement (N : Node_Id);
40 procedure Analyze_Aspect_Specifications (N : Node_Id; E : Entity_Id);
41 -- This procedure is called to analyze aspect specifications for node N. E
42 -- is the corresponding entity declared by the declaration node N. Callers
43 -- should check that Has_Aspects (N) is True before calling this routine.
45 procedure Analyze_Aspect_Specifications_On_Body_Or_Stub (N : Node_Id);
46 -- Analyze the aspect specifications of [generic] subprogram body or stub
47 -- N. Callers should check that Has_Aspects (N) is True before calling the
48 -- routine. This routine diagnoses misplaced aspects that should appear on
49 -- the initial declaration of N and offers suggestions for replacements.
51 procedure Adjust_Record_For_Reverse_Bit_Order (R : Entity_Id);
52 -- Called from Freeze where R is a record entity for which reverse bit
53 -- order is specified and there is at least one component clause. Note:
54 -- component positions are normally adjusted as per AI95-0133, unless
55 -- -gnatd.p is used to restore original Ada 95 mode.
57 procedure Check_Record_Representation_Clause (N : Node_Id);
58 -- This procedure completes the analysis of a record representation clause
59 -- N. It is called at freeze time after adjustment of component clause bit
60 -- positions for possible non-standard bit order. In the case of Ada 2005
61 -- (machine scalar) mode, this adjustment can make substantial changes, so
62 -- some checks, in particular for component overlaps cannot be done at the
63 -- time the record representation clause is first seen, but must be delayed
64 -- till freeze time, and in particular is called after calling the above
65 -- procedure for adjusting record bit positions for reverse bit order.
67 procedure Initialize;
68 -- Initialize internal tables for new compilation
70 procedure Kill_Rep_Clause (N : Node_Id);
71 -- This procedure is called for a rep clause N when we are in -gnatI mode
72 -- (Ignore_Rep_Clauses). It replaces the node N with a null statement. This
73 -- is only called if Ignore_Rep_Clauses is True.
75 procedure Set_Enum_Esize (T : Entity_Id);
76 -- This routine sets the Esize field for an enumeration type T, based
77 -- on the current representation information available for T. Note that
78 -- the setting of the RM_Size field is not affected. This routine also
79 -- initializes the alignment field to zero.
81 function Minimum_Size
82 (T : Entity_Id;
83 Biased : Boolean := False) return Nat;
84 -- Given an elementary type, determines the minimum number of bits required
85 -- to represent all values of the type. This function may not be called
86 -- with any other types. If the flag Biased is set True, then the minimum
87 -- size calculation that biased representation is used in the case of a
88 -- discrete type, e.g. the range 7..8 gives a minimum size of 4 with
89 -- Biased set to False, and 1 with Biased set to True. Note that the
90 -- biased parameter only has an effect if the type is not biased, it
91 -- causes Minimum_Size to indicate the minimum size of an object with
92 -- the given type, of the size the type would have if it were biased. If
93 -- the type is already biased, then Minimum_Size returns the biased size,
94 -- regardless of the setting of Biased. Also, fixed-point types are never
95 -- biased in the current implementation. If the size is not known at
96 -- compile time, this function returns 0.
98 procedure Check_Constant_Address_Clause (Expr : Node_Id; U_Ent : Entity_Id);
99 -- Expr is an expression for an address clause. This procedure checks
100 -- that the expression is constant, in the limited sense that it is safe
101 -- to evaluate it at the point the object U_Ent is declared, rather than
102 -- at the point of the address clause. The condition for this to be true
103 -- is that the expression has no variables, no constants declared after
104 -- U_Ent, and no calls to non-pure functions. If this condition is not
105 -- met, then an appropriate error message is posted. This check is applied
106 -- at the point an object with an address clause is frozen, as well as for
107 -- address clauses for tasks and entries.
109 procedure Check_Size
110 (N : Node_Id;
111 T : Entity_Id;
112 Siz : Uint;
113 Biased : out Boolean);
114 -- Called when size Siz is specified for subtype T. This subprogram checks
115 -- that the size is appropriate, posting errors on node N as required.
116 -- This check is effective for elementary types and bit-packed arrays.
117 -- For other non-elementary types, a check is only made if an explicit
118 -- size has been given for the type (and the specified size must match).
119 -- The parameter Biased is set False if the size specified did not require
120 -- the use of biased representation, and True if biased representation
121 -- was required to meet the size requirement. Note that Biased is only
122 -- set if the type is not currently biased, but biasing it is the only
123 -- way to meet the requirement. If the type is currently biased, then
124 -- this biased size is used in the initial check, and Biased is False.
125 -- If the size is too small, and an error message is given, then both
126 -- Esize and RM_Size are reset to the allowed minimum value in T.
128 function Rep_Item_Too_Early (T : Entity_Id; N : Node_Id) return Boolean;
129 -- Called at start of processing a representation clause/pragma. Used to
130 -- check that the representation item is not being applied to an incomplete
131 -- type or to a generic formal type or a type derived from a generic formal
132 -- type. Returns False if no such error occurs. If this error does occur,
133 -- appropriate error messages are posted on node N, and True is returned.
135 generic
136 with procedure Replace_Type_Reference (N : Node_Id);
137 procedure Replace_Type_References_Generic (N : Node_Id; T : Entity_Id);
138 -- This is used to scan an expression for a predicate or invariant aspect
139 -- replacing occurrences of the name of the subtype to which the aspect
140 -- applies with appropriate references to the parameter of the predicate
141 -- function or invariant procedure. The procedure passed as a generic
142 -- parameter does the actual replacement of node N, which is either a
143 -- simple direct reference to T, or a selected component that represents
144 -- an appropriately qualified occurrence of T.
146 function Rep_Item_Too_Late
147 (T : Entity_Id;
148 N : Node_Id;
149 FOnly : Boolean := False) return Boolean;
150 -- Called at the start of processing a representation clause or a
151 -- representation pragma. Used to check that a representation item for
152 -- entity T does not appear too late (according to the rules in RM 13.1(9)
153 -- and RM 13.1(10)). N is the associated node, which in the pragma case
154 -- is the pragma or representation clause itself, used for placing error
155 -- messages if the item is too late.
157 -- Fonly is a flag that causes only the freezing rule (para 9) to be
158 -- applied, and the tests of para 10 are skipped. This is appropriate for
159 -- both subtype related attributes (Alignment and Size) and for stream
160 -- attributes, which, although certainly not subtype related attributes,
161 -- clearly should not be subject to the para 10 restrictions (see
162 -- AI95-00137). Similarly, we also skip the para 10 restrictions for
163 -- the Storage_Size case where they also clearly do not apply, and for
164 -- Stream_Convert which is in the same category as the stream attributes.
166 -- If the rep item is too late, an appropriate message is output and True
167 -- is returned, which is a signal that the caller should abandon processing
168 -- for the item. If the item is not too late, then False is returned, and
169 -- the caller can continue processing the item.
171 -- If no error is detected, this call also as a side effect links the
172 -- representation item onto the head of the representation item chain
173 -- (referenced by the First_Rep_Item field of the entity).
175 -- Note: Rep_Item_Too_Late must be called with the underlying type in the
176 -- case of a private or incomplete type. The protocol is to first check for
177 -- Rep_Item_Too_Early using the initial entity, then take the underlying
178 -- type, then call Rep_Item_Too_Late on the result.
180 -- Note: Calls to Rep_Item_Too_Late are ignored for the case of attribute
181 -- definition clauses which have From_Aspect_Specification set. This is
182 -- because such clauses are linked on to the Rep_Item chain in procedure
183 -- Sem_Ch13.Analyze_Aspect_Specifications. See that procedure for details.
185 function Same_Representation (Typ1, Typ2 : Entity_Id) return Boolean;
186 -- Given two types, where the two types are related by possible derivation,
187 -- determines if the two types have the same representation, or different
188 -- representations, requiring the special processing for representation
189 -- change. A False result is possible only for array, enumeration or
190 -- record types.
192 procedure Validate_Compile_Time_Warning_Error (N : Node_Id);
193 -- N is a pragma Compile_Time_Error or Compile_Warning_Error whose boolean
194 -- expression is not known at compile time. This procedure makes an entry
195 -- in a table. The actual checking is performed by Validate_Compile_Time_
196 -- Warning_Errors, which is invoked after calling the back end.
198 procedure Validate_Compile_Time_Warning_Errors;
199 -- This routine is called after calling the back end to validate pragmas
200 -- Compile_Time_Error and Compile_Time_Warning for size and alignment
201 -- appropriateness. The reason it is called that late is to take advantage
202 -- of any back-annotation of size and alignment performed by the back end.
204 procedure Validate_Unchecked_Conversion
205 (N : Node_Id;
206 Act_Unit : Entity_Id);
207 -- Validate a call to unchecked conversion. N is the node for the actual
208 -- instantiation, which is used only for error messages. Act_Unit is the
209 -- entity for the instantiation, from which the actual types etc. for this
210 -- instantiation can be determined. This procedure makes an entry in a
211 -- table and/or generates an N_Validate_Unchecked_Conversion node. The
212 -- actual checking is done in Validate_Unchecked_Conversions or in the
213 -- back end as required.
215 procedure Validate_Unchecked_Conversions;
216 -- This routine is called after calling the back end to validate unchecked
217 -- conversions for size and alignment appropriateness. The reason it is
218 -- called that late is to take advantage of any back-annotation of size
219 -- and alignment performed by the back end.
221 procedure Validate_Address_Clauses;
222 -- This is called after the back end has been called (and thus after the
223 -- alignments of objects have been back annotated). It goes through the
224 -- table of saved address clauses checking for suspicious alignments and
225 -- if necessary issuing warnings.
227 procedure Validate_Independence;
228 -- This is called after the back end has been called (and thus after the
229 -- layout of components has been back annotated). It goes through the
230 -- table of saved pragma Independent[_Component] entries, checking that
231 -- independence can be achieved, and if necessary issuing error messages.
233 -------------------------------------
234 -- Table for Validate_Independence --
235 -------------------------------------
237 -- If a legal pragma Independent or Independent_Components is given for
238 -- an entity, then an entry is made in this table, to be checked by a
239 -- call to Validate_Independence after back annotation of layout is done.
241 type Independence_Check_Record is record
242 N : Node_Id;
243 -- The pragma Independent or Independent_Components
245 E : Entity_Id;
246 -- The entity to which it applies
247 end record;
249 package Independence_Checks is new Table.Table (
250 Table_Component_Type => Independence_Check_Record,
251 Table_Index_Type => Int,
252 Table_Low_Bound => 1,
253 Table_Initial => 20,
254 Table_Increment => 200,
255 Table_Name => "Independence_Checks");
257 -----------------------------------
258 -- Handling of Aspect Visibility --
259 -----------------------------------
261 -- The visibility of aspects is tricky. First, the visibility is delayed
262 -- to the freeze point. This is not too complicated, what we do is simply
263 -- to leave the aspect "laying in wait" for the freeze point, and at that
264 -- point materialize and analyze the corresponding attribute definition
265 -- clause or pragma. There is some special processing for preconditions
266 -- and postonditions, where the pragmas themselves deal with the required
267 -- delay, but basically the approach is the same, delay analysis of the
268 -- expression to the freeze point.
270 -- Much harder is the requirement for diagnosing cases in which an early
271 -- freeze causes a change in visibility. Consider:
273 -- package AspectVis is
274 -- R_Size : constant Integer := 32;
276 -- package Inner is
277 -- type R is new Integer with
278 -- Size => R_Size;
279 -- F : R; -- freezes
280 -- R_Size : constant Integer := 64;
281 -- S : constant Integer := R'Size; -- 32 not 64
282 -- end Inner;
283 -- end AspectVis;
285 -- Here the 32 not 64 shows what would be expected if this program were
286 -- legal, since the evaluation of R_Size has to be done at the freeze
287 -- point and gets the outer definition not the inner one.
289 -- But the language rule requires this program to be diagnosed as illegal
290 -- because the visibility changes between the freeze point and the end of
291 -- the declarative region.
293 -- To meet this requirement, we first note that the Expression field of the
294 -- N_Aspect_Specification node holds the raw unanalyzed expression, which
295 -- will get used in processing the aspect. At the time of analyzing the
296 -- N_Aspect_Specification node, we create a complete copy of the expression
297 -- and store it in the entity field of the Identifier (an odd usage, but
298 -- the identifier is not used except to identify the aspect, so its Entity
299 -- field is otherwise unused, and we are short of room in the node).
301 -- This copy stays unanalyzed up to the freeze point, where we analyze the
302 -- resulting pragma or attribute definition clause, except that in the
303 -- case of invariants and predicates, we mark occurrences of the subtype
304 -- name as having the entity of the subprogram parameter, so that they
305 -- will not cause trouble in the following steps.
307 -- Then at the freeze point, we create another copy of this unanalyzed
308 -- expression. By this time we no longer need the Expression field for
309 -- other purposes, so we can store it there. Now we have two copies of
310 -- the original unanalyzed expression. One of them gets preanalyzed at
311 -- the freeze point to capture the visibility at the freeze point.
313 -- Now when we hit the freeze all at the end of the declarative part, if
314 -- we come across a frozen entity with delayed aspects, we still have one
315 -- copy of the unanalyzed expression available in the node, and we again
316 -- do a preanalysis using that copy and the visibility at the end of the
317 -- declarative part. Now we have two preanalyzed expression (preanalysis
318 -- is good enough, since we are only interested in referenced entities).
319 -- One captures the visibility at the freeze point, the other captures the
320 -- visibility at the end of the declarative part. We see if the entities
321 -- in these two expressions are the same, by seeing if the two expressions
322 -- are fully conformant, and if not, issue appropriate error messages.
324 -- Quite an awkward approach, but this is an awkard requirement
326 procedure Analyze_Aspects_At_Freeze_Point (E : Entity_Id);
327 -- Analyze all the delayed aspects for entity E at freezing point. This
328 -- includes dealing with inheriting delayed aspects from the parent type
329 -- in the case where a derived type is frozen.
331 procedure Check_Aspect_At_Freeze_Point (ASN : Node_Id);
332 -- Performs the processing described above at the freeze point, ASN is the
333 -- N_Aspect_Specification node for the aspect.
335 procedure Check_Aspect_At_End_Of_Declarations (ASN : Node_Id);
336 -- Performs the processing described above at the freeze all point, and
337 -- issues appropriate error messages if the visibility has indeed changed.
338 -- Again, ASN is the N_Aspect_Specification node for the aspect.
340 procedure Inherit_Aspects_At_Freeze_Point (Typ : Entity_Id);
341 -- Given an entity Typ that denotes a derived type or a subtype, this
342 -- routine performs the inheritance of aspects at the freeze point.
344 procedure Resolve_Aspect_Expressions (E : Entity_Id);
345 -- Name resolution of an aspect expression happens at the end of the
346 -- current declarative part or at the freeze point for the entity,
347 -- whichever comes first. For declarations in the visible part of a
348 -- package, name resolution takes place before analysis of the private
349 -- part even though the freeze point of the entity may appear later.
351 procedure Validate_Iterable_Aspect (Typ : Entity_Id; ASN : Node_Id);
352 -- For SPARK 2014 formal containers. The expression has the form of an
353 -- aggregate, and each entry must denote a function with the proper syntax
354 -- for First, Next, and Has_Element. Optionally an Element primitive may
355 -- also be defined.
357 -----------------------------------------------------------
358 -- Visibility of Discriminants in Aspect Specifications --
359 -----------------------------------------------------------
361 -- The discriminants of a type are visible when analyzing the aspect
362 -- specifications of a type declaration or protected type declaration,
363 -- but not when analyzing those of a subtype declaration. The following
364 -- routines enforce this distinction.
366 procedure Install_Discriminants (E : Entity_Id);
367 -- Make visible the discriminants of type entity E
369 procedure Push_Scope_And_Install_Discriminants (E : Entity_Id);
370 -- Push scope E and makes visible the discriminants of type entity E if E
371 -- has discriminants and is not a subtype.
373 procedure Uninstall_Discriminants (E : Entity_Id);
374 -- Remove visibility to the discriminants of type entity E
376 procedure Uninstall_Discriminants_And_Pop_Scope (E : Entity_Id);
377 -- Remove visibility to the discriminants of type entity E and pop the
378 -- scope stack if E has discriminants and is not a subtype.
380 end Sem_Ch13;