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FSF GCC merge 02/23/03
[official-gcc.git] / gcc / ada / table.ads
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- T A B L E --
6 -- --
7 -- S p e c --
8 -- --
9 -- --
10 -- Copyright (C) 1992-2001 Free Software Foundation, Inc. --
11 -- --
12 -- GNAT is free software; you can redistribute it and/or modify it under --
13 -- terms of the GNU General Public License as published by the Free Soft- --
14 -- ware Foundation; either version 2, or (at your option) any later ver- --
15 -- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
16 -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
17 -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
18 -- for more details. You should have received a copy of the GNU General --
19 -- Public License distributed with GNAT; see file COPYING. If not, write --
20 -- to the Free Software Foundation, 59 Temple Place - Suite 330, Boston, --
21 -- MA 02111-1307, USA. --
22 -- --
23 -- As a special exception, if other files instantiate generics from this --
24 -- unit, or you link this unit with other files to produce an executable, --
25 -- this unit does not by itself cause the resulting executable to be --
26 -- covered by the GNU General Public License. This exception does not --
27 -- however invalidate any other reasons why the executable file might be --
28 -- covered by the GNU Public License. --
29 -- --
30 -- GNAT was originally developed by the GNAT team at New York University. --
31 -- Extensive contributions were provided by Ada Core Technologies Inc. --
32 -- --
33 ------------------------------------------------------------------------------
34
35 -- This package provides an implementation of dynamically resizable one
36 -- dimensional arrays. The idea is to mimic the normal Ada semantics for
37 -- arrays as closely as possible with the one additional capability of
38 -- dynamically modifying the value of the Last attribute.
39
40 -- Note that this interface should remain synchronized with those in
41 -- GNAT.Table and GNAT.Dynamic_Tables to keep coherency between these
42 -- three related units.
43
44 with Types; use Types;
45
46 package Table is
47 pragma Elaborate_Body (Table);
48
49 generic
50 type Table_Component_Type is private;
51 type Table_Index_Type is range <>;
52
53 Table_Low_Bound : Table_Index_Type;
54 Table_Initial : Pos;
55 Table_Increment : Nat;
56 Table_Name : String;
57
58 package Table is
59
60 -- Table_Component_Type and Table_Index_Type specify the type of the
61 -- array, Table_Low_Bound is the lower bound. Index_type must be an
62 -- integer type. The effect is roughly to declare:
63
64 -- Table : array (Table_Index_Type range Table_Low_Bound .. <>)
65 -- of Table_Component_Type;
66
67 -- Note: since the upper bound can be one less than the lower
68 -- bound for an empty array, the table index type must be able
69 -- to cover this range, e.g. if the lower bound is 1, then the
70 -- Table_Index_Type should be Natural rather than Positive.
71
72 -- Table_Component_Type may be any Ada type, except that controlled
73 -- types are not supported. Note however that default initialization
74 -- will NOT occur for array components.
75
76 -- The Table_Initial values controls the allocation of the table when
77 -- it is first allocated, either by default, or by an explicit Init
78 -- call. The value used is Opt.Table_Factor * Table_Initial.
79
80 -- The Table_Increment value controls the amount of increase, if the
81 -- table has to be increased in size. The value given is a percentage
82 -- value (e.g. 100 = increase table size by 100%, i.e. double it).
83
84 -- The Table_Name parameter is simply use in debug output messages it
85 -- has no other usage, and is not referenced in non-debugging mode.
86
87 -- The Last and Set_Last subprograms provide control over the current
88 -- logical allocation. They are quite efficient, so they can be used
89 -- freely (expensive reallocation occurs only at major granularity
90 -- chunks controlled by the allocation parameters).
91
92 -- Note: we do not make the table components aliased, since this would
93 -- restict the use of table for discriminated types. If it is necessary
94 -- to take the access of a table element, use Unrestricted_Access.
95
96 type Table_Type is
97 array (Table_Index_Type range <>) of Table_Component_Type;
98
99 subtype Big_Table_Type is
100 Table_Type (Table_Low_Bound .. Table_Index_Type'Last);
101 -- We work with pointers to a bogus array type that is constrained
102 -- with the maximum possible range bound. This means that the pointer
103 -- is a thin pointer, which is more efficient. Since subscript checks
104 -- in any case must be on the logical, rather than physical bounds,
105 -- safety is not compromised by this approach.
106
107 type Table_Ptr is access all Big_Table_Type;
108 -- The table is actually represented as a pointer to allow reallocation
109
110 Table : aliased Table_Ptr := null;
111 -- The table itself. The lower bound is the value of Low_Bound.
112 -- Logically the upper bound is the current value of Last (although
113 -- the actual size of the allocated table may be larger than this).
114 -- The program may only access and modify Table entries in the range
115 -- First .. Last.
116
117 Locked : Boolean := False;
118 -- Table expansion is permitted only if this switch is set to False. A
119 -- client may set Locked to True, in which case any attempt to expand
120 -- the table will cause an assertion failure. Note that while a table
121 -- is locked, its address in memory remains fixed and unchanging. This
122 -- feature is used to control table expansion during Gigi processing.
123 -- Gigi assumes that tables other than the Uint and Ureal tables do
124 -- not move during processing, which means that they cannot be expanded.
125 -- The Locked flag is used to enforce this restriction.
126
127 procedure Init;
128 -- This procedure allocates a new table of size Initial (freeing any
129 -- previously allocated larger table). It is not necessary to call
130 -- Init when a table is first instantiated (since the instantiation does
131 -- the same initialization steps). However, it is harmless to do so, and
132 -- Init is convenient in reestablishing a table for new use.
133
134 function Last return Table_Index_Type;
135 pragma Inline (Last);
136 -- Returns the current value of the last used entry in the table, which
137 -- can then be used as a subscript for Table. Note that the only way to
138 -- modify Last is to call the Set_Last procedure. Last must always be
139 -- used to determine the logically last entry.
140
141 procedure Release;
142 -- Storage is allocated in chunks according to the values given in the
143 -- Initial and Increment parameters. A call to Release releases all
144 -- storage that is allocated, but is not logically part of the current
145 -- array value. Current array values are not affected by this call.
146
147 procedure Free;
148 -- Free all allocated memory for the table. A call to init is required
149 -- before any use of this table after calling Free.
150
151 First : constant Table_Index_Type := Table_Low_Bound;
152 -- Export First as synonym for Low_Bound (parallel with use of Last)
153
154 procedure Set_Last (New_Val : Table_Index_Type);
155 pragma Inline (Set_Last);
156 -- This procedure sets Last to the indicated value. If necessary the
157 -- table is reallocated to accommodate the new value (i.e. on return
158 -- the allocated table has an upper bound of at least Last). If Set_Last
159 -- reduces the size of the table, then logically entries are removed
160 -- from the table. If Set_Last increases the size of the table, then
161 -- new entries are logically added to the table.
162
163 procedure Increment_Last;
164 pragma Inline (Increment_Last);
165 -- Adds 1 to Last (same as Set_Last (Last + 1).
166
167 procedure Decrement_Last;
168 pragma Inline (Decrement_Last);
169 -- Subtracts 1 from Last (same as Set_Last (Last - 1).
170
171 procedure Append (New_Val : Table_Component_Type);
172 pragma Inline (Append);
173 -- Equivalent to:
174 -- x.Increment_Last;
175 -- x.Table (x.Last) := New_Val;
176 -- i.e. the table size is increased by one, and the given new item
177 -- stored in the newly created table element.
178
179 procedure Set_Item
180 (Index : Table_Index_Type;
181 Item : Table_Component_Type);
182 pragma Inline (Set_Item);
183 -- Put Item in the table at position Index. The table is expanded if
184 -- current table length is less than Index and in that case Last is set
185 -- to Index. Item will replace any value already present in the table
186 -- at this position.
187
188 type Saved_Table is private;
189 -- Type used for Save/Restore subprograms
190
191 function Save return Saved_Table;
192 -- Resets table to empty, but saves old contents of table in returned
193 -- value, for possible later restoration by a call to Restore.
194
195 procedure Restore (T : Saved_Table);
196 -- Given a Saved_Table value returned by a prior call to Save, restores
197 -- the table to the state it was in at the time of the Save call.
198
199 procedure Tree_Write;
200 -- Writes out contents of table using Tree_IO
201
202 procedure Tree_Read;
203 -- Initializes table by reading contents previously written
204 -- with the Tree_Write call (also using Tree_IO)
205
206 private
207
208 Last_Val : Int;
209 -- Current value of Last. Note that we declare this in the private part
210 -- because we don't want the client to modify Last except through one of
211 -- the official interfaces (since a modification to Last may require a
212 -- reallocation of the table).
213
214 Max : Int;
215 -- Subscript of the maximum entry in the currently allocated table
216
217 type Saved_Table is record
218 Last_Val : Int;
219 Max : Int;
220 Table : Table_Ptr;
221 end record;
222
223 end Table;
224 end Table;
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