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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- A S P E C T S --
6 -- --
7 -- S p e c --
8 -- --
9 -- Copyright (C) 2010-2015, 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. --
17 -- --
18 -- As a special exception under Section 7 of GPL version 3, you are granted --
19 -- additional permissions described in the GCC Runtime Library Exception, --
20 -- version 3.1, as published by the Free Software Foundation. --
21 -- --
22 -- You should have received a copy of the GNU General Public License and --
23 -- a copy of the GCC Runtime Library Exception along with this program; --
24 -- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
25 -- <http://www.gnu.org/licenses/>. --
26 -- --
27 -- GNAT was originally developed by the GNAT team at New York University. --
28 -- Extensive contributions were provided by Ada Core Technologies Inc. --
29 -- --
30 ------------------------------------------------------------------------------
32 -- This package defines the aspects that are recognized by GNAT in aspect
33 -- specifications. It also contains the subprograms for storing/retrieving
34 -- aspect specifications from the tree. The semantic processing for aspect
35 -- specifications is found in Sem_Ch13.Analyze_Aspect_Specifications.
37 ------------------------
38 -- Adding New Aspects --
39 ------------------------
41 -- In general, each aspect should have a corresponding pragma, so that the
42 -- newly developed functionality is available for Ada versions < Ada 2012.
43 -- When both are defined, it is convenient to first transform the aspect into
44 -- an equivalent pragma in Sem_Ch13.Analyze_Aspect_Specifications, and then
45 -- analyze the pragma in Sem_Prag.Analyze_Pragma.
47 -- To add a new aspect, you need to do the following
49 -- 1. Create a name in snames.ads-tmpl
51 -- 2. Create a value in type Aspect_Id in this unit
53 -- 3. Add a value for the aspect in the global arrays defined in this unit
55 -- 4. Add code for the aspect in Sem_Ch13.Analyze_Aspect_Specifications.
56 -- This may involve adding some nodes to the tree to perform additional
57 -- treatments later.
59 -- 5. If the semantic analysis of expressions/names in the aspect should not
60 -- occur at the point the aspect is defined, add code in the adequate
61 -- semantic analysis procedure for the aspect. For example, this is the
62 -- case for aspects Pre and Post on subprograms, which are pre-analyzed
63 -- at the end of the declaration list to which the subprogram belongs,
64 -- and fully analyzed (possibly with expansion) during the semantic
65 -- analysis of subprogram bodies.
73 -- Type defining recognized aspects
78 Aspect_Address,
79 Aspect_Alignment,
83 Aspect_Attach_Handler,
84 Aspect_Bit_Order,
85 Aspect_Component_Size,
87 Aspect_Constant_Indexing,
89 Aspect_Convention,
90 Aspect_CPU,
91 Aspect_Default_Component_Value,
93 Aspect_Default_Iterator,
94 Aspect_Default_Storage_Pool,
95 Aspect_Default_Value,
99 Aspect_Dispatching_Domain,
100 Aspect_Dynamic_Predicate,
104 Aspect_External_Name,
105 Aspect_External_Tag,
108 Aspect_Implicit_Dereference,
111 Aspect_Input,
112 Aspect_Interrupt_Priority,
114 Aspect_Iterator_Element,
116 Aspect_Link_Name,
118 Aspect_Machine_Radix,
121 Aspect_Output,
123 Aspect_Post,
124 Aspect_Postcondition,
125 Aspect_Pre,
126 Aspect_Precondition,
128 Aspect_Predicate_Failure,
129 Aspect_Priority,
130 Aspect_Read,
135 Aspect_Relative_Deadline,
138 Aspect_Size,
139 Aspect_Small,
141 Aspect_Static_Predicate,
142 Aspect_Storage_Pool,
143 Aspect_Storage_Size,
144 Aspect_Stream_Size,
145 Aspect_Suppress,
146 Aspect_Synchronization,
148 Aspect_Type_Invariant,
150 Aspect_Unsuppress,
152 Aspect_Variable_Indexing,
155 Aspect_Write,
157 -- The following aspects correspond to library unit pragmas
159 Aspect_All_Calls_Remote,
160 Aspect_Elaborate_Body,
162 Aspect_Preelaborate,
163 Aspect_Pure,
164 Aspect_Remote_Call_Interface,
165 Aspect_Remote_Types,
166 Aspect_Shared_Passive,
169 -- Remaining aspects have a static boolean value that turns the aspect
170 -- on or off. They all correspond to pragmas, but are only converted to
171 -- the pragmas where the value is True. A value of False normally means
172 -- that the aspect is ignored, except in the case of derived types where
173 -- the aspect value is inherited from the parent, in which case, we do
174 -- not allow False if we inherit a True value from the parent.
176 Aspect_Asynchronous,
177 Aspect_Atomic,
178 Aspect_Atomic_Components,
180 Aspect_Discard_Names,
181 Aspect_Export,
183 Aspect_Independent,
184 Aspect_Independent_Components,
185 Aspect_Import,
186 Aspect_Inline,
188 Aspect_Interrupt_Handler,
190 Aspect_No_Return,
192 Aspect_Pack,
194 Aspect_Preelaborable_Initialization,
202 Aspect_Unchecked_Union,
207 Aspect_Volatile,
208 Aspect_Volatile_Components,
213 -- Aspect_Id's excluding No_Aspect
215 -- The following array indicates aspects that accept 'Class
229 -- The following array identifies all implementation defined aspects
273 -- The following array indicates aspects for which multiple occurrences of
274 -- the same aspect attached to the same declaration are allowed.
281 -- The following subtype defines aspects corresponding to library unit
282 -- pragmas, these can only validly appear as aspects for library units,
283 -- and result in a corresponding pragma being inserted immediately after
284 -- the occurrence of the aspect.
289 -- The following subtype defines aspects accepting an optional static
290 -- boolean parameter indicating if the aspect should be active or
291 -- cancelling. If the parameter is missing the effective value is True,
292 -- enabling the aspect. If the parameter is present it must be a static
293 -- expression of type Standard.Boolean. If the value is True, then the
294 -- aspect is enabled. If it is False, the aspect is disabled.
302 -- The following type is used for indicating allowed expression forms
310 -- The following array indicates what argument type is required
397 -----------------------------------------
398 -- Table Linking Names and Aspect_Id's --
399 -----------------------------------------
401 -- Table linking aspect names and id's
530 -- Given a name Nam, returns the corresponding aspect id value. If the name
531 -- does not match any aspect, then No_Aspect is returned as the result.
535 -- Given an aspect specification, return the corresponding aspect_id value.
536 -- If the name does not match any aspect, return No_Aspect.
538 ------------------------------------
539 -- Delaying Evaluation of Aspects --
540 ------------------------------------
542 -- The RM requires that all language defined aspects taking an expression
543 -- delay evaluation of the expression till the freeze point of the entity
544 -- to which the aspect applies. This allows forward references, and is of
545 -- use for example in connection with preconditions and postconditions
546 -- where the requirement of making all references in contracts to local
547 -- functions be backwards references would be onerous.
549 -- For consistency, even attributes like Size are delayed, so we can do:
551 -- type A is range 1 .. 10
552 -- with Size => Not_Defined_Yet;
553 -- ..
554 -- Not_Defined_Yet : constant := 64;
556 -- Resulting in A having a size of 64, which gets set when A is frozen.
557 -- Furthermore, we can have a situation like
559 -- type A is range 1 .. 10
560 -- with Size => Not_Defined_Yet;
561 -- ..
562 -- type B is new A;
563 -- ..
564 -- Not_Defined_Yet : constant := 64;
566 -- where the Size of A is considered to have been previously specified at
567 -- the point of derivation, even though the actual value of the size is
568 -- not known yet, and in this example B inherits the size value of 64.
570 -- Our normal implementation model (prior to Ada 2012) was simply to copy
571 -- inheritable attributes at the point of derivation. Then any subsequent
572 -- representation items apply either to the parent type, not affecting the
573 -- derived type, or to the derived type, not affecting the parent type.
575 -- To deal with the delayed aspect case, we use two flags. The first is
576 -- set on the parent type if it has delayed representation aspects. This
577 -- flag Has_Delayed_Rep_Aspects indicates that if we derive from this type
578 -- we have to worry about making sure we inherit any delayed aspects. The
579 -- second flag is set on a derived type: May_Have_Inherited_Rep_Aspects
580 -- is set if the parent type has Has_Delayed_Rep_Aspects set.
582 -- When we freeze a derived type, if the May_Have_Inherited_Rep_Aspects
583 -- flag is set, then we call Freeze.Inherit_Delayed_Rep_Aspects when
584 -- the derived type is frozen, which deals with the necessary copying of
585 -- information from the parent type, which must be frozen at that point
586 -- (since freezing the derived type first freezes the parent type).
588 -- SPARK 2014 aspects do not follow the general delay mechanism as they
589 -- act as annotations and cannot modify the attributes of their related
590 -- constructs. To handle forward references in such aspects, the compiler
591 -- delays the analysis of their respective pragmas by collecting them in
592 -- N_Contract nodes. The pragmas are then analyzed at the end of the
593 -- declarative region containing the related construct. For details,
594 -- see routines Analyze_xxx_In_Decl_Part.
596 -- The following shows which aspects are delayed. There are three cases:
600 -- This aspect is not a representation aspect that can be inherited and
601 -- is always delayed, as required by the language definition.
603 Never_Delay,
604 -- There are two cases. There are language defined aspects like
605 -- Convention where the "expression" is simply an uninterpreted
606 -- identifier, and there is no issue of evaluating it and thus no
607 -- issue of delaying the evaluation. The second case is implementation
608 -- defined aspects where we have decided that we don't want to allow
609 -- delays (and for our own aspects we can do what we like).
611 Rep_Aspect);
612 -- These are the cases of representation aspects that are in general
613 -- delayed, and where there is a potential issue of derived types that
614 -- inherit delayed representation values.
616 -- Note: even if this table indicates that an aspect is delayed, we never
617 -- delay Boolean aspects that have a missing expression (taken as True),
618 -- or expressions for delayed rep items that consist of an integer literal
619 -- (most cases of Size etc. in practice), since in these cases we know we
620 -- can get the value of the expression without delay. Note that we still
621 -- need to delay Boolean aspects that are specifically set to True:
623 -- type R is array (0 .. 31) of Boolean
624 -- with Pack => True;
625 -- True : constant Boolean := False;
627 -- This is nonsense, but we need to make it work and result in R not
628 -- being packed, and if we have something like:
630 -- type R is array (0 .. 31) of Boolean
631 -- with Pack => True;
632 -- RR : R;
633 -- True : constant Boolean := False;
635 -- This is illegal because the visibility of True changes after the freeze
636 -- point, which is not allowed, and we need the delay mechanism to properly
637 -- diagnose this error.
766 ------------------------------------------------
767 -- Handling of Aspect Specifications on Stubs --
768 ------------------------------------------------
770 -- Aspects that appear on the following stub nodes
772 -- N_Package_Body_Stub
773 -- N_Protected_Body_Stub
774 -- N_Subprogram_Body_Stub
775 -- N_Task_Body_Stub
777 -- are treated as if they apply to the corresponding proper body. Their
778 -- analysis is postponed until the analysis of the proper body takes place
779 -- (see Analyze_Proper_Body). The delay is required because the analysis
780 -- may generate extra code which would be harder to relocate to the body.
781 -- If the proper body is present, the aspect specifications are relocated
782 -- to the corresponding body node:
784 -- N_Package_Body
785 -- N_Protected_Body
786 -- N_Subprogram_Body
787 -- N_Task_Body
789 -- The subsequent analysis takes care of the aspect-to-pragma conversions
790 -- and verification of pragma legality. In the case where the proper body
791 -- is not available, the aspect specifications are analyzed on the spot
792 -- (see Analyze_Proper_Body) to catch potential errors.
794 -- The following table lists all aspects that can apply to a subprogram
795 -- body [stub]. For instance, the following example is legal:
797 -- package P with SPARK_Mode ...;
798 -- package body P with SPARK_Mode is ...;
800 -- The table should be synchronized with Pragma_On_Body_Or_Stub_OK in unit
801 -- Sem_Prag.
811 -------------------------------------------------------------------
812 -- Handling of Aspects Specifications on Single Concurrent Types --
813 -------------------------------------------------------------------
815 -- Certain aspects that appear on the following nodes
817 -- N_Single_Protected_Declaration
818 -- N_Single_Task_Declaration
820 -- are treated as if they apply to the anonymous object produced by the
821 -- analysis of a single concurrent type. The following table lists all
822 -- aspects that should apply to the anonymous object. The table should
823 -- be synchronized with Pragma_On_Anonymous_Object_OK in unit Sem_Prag.
831 ---------------------------------------------------
832 -- Handling of Aspect Specifications in the Tree --
833 ---------------------------------------------------
835 -- Several kinds of declaration node permit aspect specifications in Ada
836 -- 2012 mode. If there was room in all the corresponding declaration nodes,
837 -- we could just have a field Aspect_Specifications pointing to a list of
838 -- nodes for the aspects (N_Aspect_Specification nodes). But there isn't
839 -- room, so we adopt a different approach.
841 -- The following subprograms provide access to a specialized interface
842 -- implemented internally with a hash table in the body, that provides
843 -- access to aspect specifications.
846 -- Given a node N, returns the list of N_Aspect_Specification nodes that
847 -- are attached to this declaration node. If the node is in the class of
848 -- declaration nodes that permit aspect specifications, as defined by the
849 -- predicate above, and if their Has_Aspects flag is set to True, then this
850 -- will always be a non-empty list. If this flag is set to False, then
851 -- No_List is returned. Normally, the only nodes that have Has_Aspects set
852 -- True are the nodes for which Permits_Aspect_Specifications would return
853 -- True (i.e. the declaration nodes defined in the RM as permitting the
854 -- presence of Aspect_Specifications). However, it is possible for the
855 -- flag Has_Aspects to be set on other nodes as a result of Rewrite and
856 -- Replace calls, and this function may be used to retrieve the aspect
857 -- specifications for the original rewritten node in such cases.
860 -- N denotes a body [stub] with aspects. Determine whether all aspects of N
861 -- are allowed to appear on a body [stub].
864 -- Exchange the aspect specifications of two nodes. If either node lacks an
865 -- aspect specification list, the routine has no effect. It is assumed that
866 -- both nodes can support aspects.
869 -- Find the aspect specification of aspect A associated with entity I.
870 -- Return Empty if Id does not have the requested aspect.
872 function Find_Value_Of_Aspect
875 -- Find the value of aspect A associated with entity Id. Return Empty if
876 -- Id does not have the requested aspect.
879 -- Determine whether entity Id has aspect A
882 -- Relocate the aspect specifications of node From to node To. On entry it
883 -- is assumed that To does not have aspect specifications. If From has no
884 -- aspects, the routine has no effect.
887 -- Relocate the aspect specifications of node From to node To. If To has
888 -- aspects, the aspects of From are appended to the aspects of To. If From
889 -- has no aspects, the routine has no effect. Special behavior:
890 -- * When node From denotes a subprogram body stub without a previous
891 -- declaration, the only aspects relocated to node To are those found
892 -- in table Aspect_On_Body_Or_Stub_OK.
893 -- * When node From denotes a single synchronized type declaration, the
894 -- only aspects relocated to node To are those found in table
895 -- Aspect_On_Anonymous_Object_OK.
898 -- Returns True if the node N is a declaration node that permits aspect
899 -- specifications in the grammar. It is possible for other nodes to have
900 -- aspect specifications as a result of Rewrite or Replace calls.
903 -- Delete the aspect specifications associated with node N. If the node has
904 -- no aspects, the routine has no effect.
907 -- Returns True if A1 and A2 are (essentially) the same aspect. This is not
908 -- a simple equality test because e.g. Post and Postcondition are the same.
909 -- This is used for detecting duplicate aspects.
912 -- The node N must be in the class of declaration nodes that permit aspect
913 -- specifications and the Has_Aspects flag must be False on entry. L must
914 -- be a non-empty list of N_Aspect_Specification nodes. This procedure sets
915 -- the Has_Aspects flag to True, and makes an entry that can be retrieved
916 -- by a subsequent Aspect_Specifications call. It is an error to call this
917 -- procedure with a node that does not permit aspect specifications, or a
918 -- node that has its Has_Aspects flag set True on entry, or with L being an
919 -- empty list or No_List.
922 -- Reads contents of Aspect_Specifications hash table from the tree file
925 -- Writes contents of Aspect_Specifications hash table to the tree file