* gcc-interface/decl.c (gnat_to_gnu_field): Do not set the alignment
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT COMPILER COMPONENTS --
4 -- --
5 -- G N A T . D Y N A M I C _ T A B L E S --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 2000-2017, AdaCore --
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 pragma Compiler_Unit_Warning;
34 with GNAT.Heap_Sort_G;
36 with Ada.Unchecked_Deallocation;
37 with System;
39 package body GNAT.Dynamic_Tables is
41 -----------------------
42 -- Local Subprograms --
43 -----------------------
45 function Last_Allocated (T : Instance) return Table_Last_Type;
46 pragma Inline (Last_Allocated);
47 -- Return the index of the last allocated element
49 procedure Grow (T : in out Instance; New_Last : Table_Last_Type);
50 -- This is called when we are about to set the value of Last to a value
51 -- that is larger than Last_Allocated. This reallocates the table to the
52 -- larger size, as indicated by New_Last. At the time this is called,
53 -- Last (T) is still the old value, and this does not modify it.
55 --------------
56 -- Allocate --
57 --------------
59 procedure Allocate (T : in out Instance; Num : Integer := 1) is
60 begin
61 -- Note that Num can be negative
63 pragma Assert (not T.Locked);
64 Set_Last (T, Last (T) + Table_Index_Type'Base (Num));
65 end Allocate;
67 ------------
68 -- Append --
69 ------------
71 procedure Append (T : in out Instance; New_Val : Table_Component_Type) is
72 pragma Assert (not T.Locked);
73 New_Last : constant Table_Last_Type := Last (T) + 1;
75 begin
76 if New_Last <= Last_Allocated (T) then
78 -- Fast path
80 T.P.Last := New_Last;
81 T.Table (New_Last) := New_Val;
83 else
84 Set_Item (T, New_Last, New_Val);
85 end if;
86 end Append;
88 ----------------
89 -- Append_All --
90 ----------------
92 procedure Append_All (T : in out Instance; New_Vals : Table_Type) is
93 begin
94 for J in New_Vals'Range loop
95 Append (T, New_Vals (J));
96 end loop;
97 end Append_All;
99 --------------------
100 -- Decrement_Last --
101 --------------------
103 procedure Decrement_Last (T : in out Instance) is
104 begin
105 pragma Assert (not T.Locked);
106 Allocate (T, -1);
107 end Decrement_Last;
109 -----------
110 -- First --
111 -----------
113 function First return Table_Index_Type is
114 begin
115 return Table_Low_Bound;
116 end First;
118 --------------
119 -- For_Each --
120 --------------
122 procedure For_Each (Table : Instance) is
123 Quit : Boolean := False;
124 begin
125 for Index in First .. Last (Table) loop
126 Action (Index, Table.Table (Index), Quit);
127 exit when Quit;
128 end loop;
129 end For_Each;
131 ----------
132 -- Grow --
133 ----------
135 procedure Grow (T : in out Instance; New_Last : Table_Last_Type) is
137 -- Note: Type Alloc_Ptr below needs to be declared locally so we know
138 -- the bounds. That means that the collection is local, so is finalized
139 -- when leaving Grow. That's why this package doesn't support controlled
140 -- types; the table elements would be finalized prematurely. An Ada
141 -- implementation would also be within its rights to reclaim the
142 -- storage. Fortunately, GNAT doesn't do that.
144 pragma Assert (not T.Locked);
145 pragma Assert (New_Last > Last_Allocated (T));
147 subtype Table_Length_Type is Table_Index_Type'Base
148 range 0 .. Table_Index_Type'Base'Last;
150 Old_Last_Allocated : constant Table_Last_Type := Last_Allocated (T);
151 Old_Allocated_Length : constant Table_Length_Type :=
152 Old_Last_Allocated - First + 1;
154 New_Length : constant Table_Length_Type := New_Last - First + 1;
155 New_Allocated_Length : Table_Length_Type;
157 begin
158 if T.Table = Empty_Table_Ptr then
159 New_Allocated_Length := Table_Length_Type (Table_Initial);
160 else
161 New_Allocated_Length :=
162 Table_Length_Type
163 (Long_Long_Integer (Old_Allocated_Length) *
164 (100 + Long_Long_Integer (Table_Increment)) / 100);
165 end if;
167 -- Make sure it really did grow
169 if New_Allocated_Length <= Old_Allocated_Length then
170 New_Allocated_Length := Old_Allocated_Length + 10;
171 end if;
173 if New_Allocated_Length <= New_Length then
174 New_Allocated_Length := New_Length + 10;
175 end if;
177 pragma Assert (New_Allocated_Length > Old_Allocated_Length);
178 pragma Assert (New_Allocated_Length > New_Length);
180 T.P.Last_Allocated := First + New_Allocated_Length - 1;
182 declare
183 subtype Old_Alloc_Type is Table_Type (First .. Old_Last_Allocated);
184 type Old_Alloc_Ptr is access all Old_Alloc_Type;
186 procedure Free is
187 new Ada.Unchecked_Deallocation (Old_Alloc_Type, Old_Alloc_Ptr);
188 function To_Old_Alloc_Ptr is
189 new Ada.Unchecked_Conversion (Table_Ptr, Old_Alloc_Ptr);
191 subtype Alloc_Type is
192 Table_Type (First .. First + New_Allocated_Length - 1);
193 type Alloc_Ptr is access all Alloc_Type;
195 function To_Table_Ptr is
196 new Ada.Unchecked_Conversion (Alloc_Ptr, Table_Ptr);
198 Old_Table : Old_Alloc_Ptr := To_Old_Alloc_Ptr (T.Table);
199 New_Table : constant Alloc_Ptr := new Alloc_Type;
201 begin
202 if T.Table /= Empty_Table_Ptr then
203 New_Table (First .. Last (T)) := Old_Table (First .. Last (T));
204 Free (Old_Table);
205 end if;
207 T.Table := To_Table_Ptr (New_Table);
208 end;
210 pragma Assert (New_Last <= Last_Allocated (T));
211 pragma Assert (T.Table /= null);
212 pragma Assert (T.Table /= Empty_Table_Ptr);
213 end Grow;
215 --------------------
216 -- Increment_Last --
217 --------------------
219 procedure Increment_Last (T : in out Instance) is
220 begin
221 pragma Assert (not T.Locked);
222 Allocate (T, 1);
223 end Increment_Last;
225 ----------
226 -- Init --
227 ----------
229 procedure Init (T : in out Instance) is
230 pragma Assert (not T.Locked);
231 subtype Alloc_Type is Table_Type (First .. Last_Allocated (T));
232 type Alloc_Ptr is access all Alloc_Type;
234 procedure Free is new Ada.Unchecked_Deallocation (Alloc_Type, Alloc_Ptr);
235 function To_Alloc_Ptr is
236 new Ada.Unchecked_Conversion (Table_Ptr, Alloc_Ptr);
238 Temp : Alloc_Ptr := To_Alloc_Ptr (T.Table);
240 begin
241 if T.Table = Empty_Table_Ptr then
242 pragma Assert (T.P = (Last_Allocated | Last => First - 1));
243 null;
244 else
245 Free (Temp);
246 T.Table := Empty_Table_Ptr;
247 T.P := (Last_Allocated | Last => First - 1);
248 end if;
249 end Init;
251 --------------
252 -- Is_Empty --
253 --------------
255 function Is_Empty (T : Instance) return Boolean is
256 begin
257 return Last (T) = First - 1;
258 end Is_Empty;
260 ----------
261 -- Last --
262 ----------
264 function Last (T : Instance) return Table_Last_Type is
265 begin
266 return T.P.Last;
267 end Last;
269 --------------------
270 -- Last_Allocated --
271 --------------------
273 function Last_Allocated (T : Instance) return Table_Last_Type is
274 begin
275 return T.P.Last_Allocated;
276 end Last_Allocated;
278 ----------
279 -- Move --
280 ----------
282 procedure Move (From, To : in out Instance) is
283 begin
284 pragma Assert (not From.Locked);
285 pragma Assert (not To.Locked);
286 pragma Assert (Is_Empty (To));
287 To := From;
289 From.Table := Empty_Table_Ptr;
290 From.Locked := False;
291 From.P.Last_Allocated := First - 1;
292 From.P.Last := First - 1;
293 pragma Assert (Is_Empty (From));
294 end Move;
296 -------------
297 -- Release --
298 -------------
300 procedure Release (T : in out Instance) is
301 pragma Assert (not T.Locked);
302 Old_Last_Allocated : constant Table_Last_Type := Last_Allocated (T);
304 function New_Last_Allocated return Table_Last_Type;
305 -- Compute the new value of Last_Allocated. This is normally equal to
306 -- Last, but if Release_Threshold /= 0, then we need to take that into
307 -- account.
309 ------------------------
310 -- New_Last_Allocated --
311 ------------------------
313 function New_Last_Allocated return Table_Last_Type is
314 subtype Table_Length_Type is Table_Index_Type'Base
315 range 0 .. Table_Index_Type'Base'Last;
317 Length : constant Table_Length_Type := Last (T) - First + 1;
319 Comp_Size_In_Bytes : constant Table_Length_Type :=
320 Table_Type'Component_Size / System.Storage_Unit;
322 Length_Threshold : constant Table_Length_Type :=
323 Table_Length_Type (Release_Threshold) / Comp_Size_In_Bytes;
325 begin
326 if Release_Threshold = 0 or else Length < Length_Threshold then
327 return Last (T);
328 else
329 declare
330 Extra_Length : constant Table_Length_Type := Length / 1000;
331 begin
332 return (Length + Extra_Length) - 1 + First;
333 end;
334 end if;
335 end New_Last_Allocated;
337 -- Local variables
339 New_Last_Alloc : constant Table_Last_Type := New_Last_Allocated;
341 -- Start of processing for Release
343 begin
344 if New_Last_Alloc < Last_Allocated (T) then
345 pragma Assert (Last (T) < Last_Allocated (T));
346 pragma Assert (T.Table /= Empty_Table_Ptr);
348 declare
349 subtype Old_Alloc_Type is Table_Type (First .. Old_Last_Allocated);
350 type Old_Alloc_Ptr is access all Old_Alloc_Type;
352 procedure Free is
353 new Ada.Unchecked_Deallocation (Old_Alloc_Type, Old_Alloc_Ptr);
354 function To_Old_Alloc_Ptr is
355 new Ada.Unchecked_Conversion (Table_Ptr, Old_Alloc_Ptr);
357 subtype Alloc_Type is Table_Type (First .. New_Last_Alloc);
358 type Alloc_Ptr is access all Alloc_Type;
360 function To_Table_Ptr is
361 new Ada.Unchecked_Conversion (Alloc_Ptr, Table_Ptr);
363 Old_Table : Old_Alloc_Ptr := To_Old_Alloc_Ptr (T.Table);
364 New_Table : constant Alloc_Ptr := new Alloc_Type;
366 begin
367 New_Table (First .. Last (T)) := Old_Table (First .. Last (T));
368 T.P.Last_Allocated := New_Last_Alloc;
369 Free (Old_Table);
370 T.Table := To_Table_Ptr (New_Table);
371 end;
372 end if;
373 end Release;
375 --------------
376 -- Set_Item --
377 --------------
379 procedure Set_Item
380 (T : in out Instance;
381 Index : Valid_Table_Index_Type;
382 Item : Table_Component_Type)
384 begin
385 pragma Assert (not T.Locked);
387 -- If Set_Last is going to reallocate the table, we make a copy of Item,
388 -- in case the call was "Set_Item (T, X, T.Table (Y));", and Item is
389 -- passed by reference. Without the copy, we would deallocate the array
390 -- containing Item, leaving a dangling pointer.
392 if Index > Last_Allocated (T) then
393 declare
394 Item_Copy : constant Table_Component_Type := Item;
395 begin
396 Set_Last (T, Index);
397 T.Table (Index) := Item_Copy;
398 end;
400 else
401 if Index > Last (T) then
402 Set_Last (T, Index);
403 end if;
405 T.Table (Index) := Item;
406 end if;
407 end Set_Item;
409 --------------
410 -- Set_Last --
411 --------------
413 procedure Set_Last (T : in out Instance; New_Val : Table_Last_Type) is
414 begin
415 pragma Assert (not T.Locked);
416 if New_Val > Last_Allocated (T) then
417 Grow (T, New_Val);
418 end if;
420 T.P.Last := New_Val;
421 end Set_Last;
423 ----------------
424 -- Sort_Table --
425 ----------------
427 procedure Sort_Table (Table : in out Instance) is
428 Temp : Table_Component_Type;
429 -- A temporary position to simulate index 0
431 -- Local subprograms
433 function Index_Of (Idx : Natural) return Table_Index_Type'Base;
434 -- Return index of Idx'th element of table
436 function Lower_Than (Op1, Op2 : Natural) return Boolean;
437 -- Compare two components
439 procedure Move (From : Natural; To : Natural);
440 -- Move one component
442 package Heap_Sort is new GNAT.Heap_Sort_G (Move, Lower_Than);
444 --------------
445 -- Index_Of --
446 --------------
448 function Index_Of (Idx : Natural) return Table_Index_Type'Base is
449 J : constant Integer'Base :=
450 Table_Index_Type'Base'Pos (First) + Idx - 1;
451 begin
452 return Table_Index_Type'Base'Val (J);
453 end Index_Of;
455 ----------
456 -- Move --
457 ----------
459 procedure Move (From : Natural; To : Natural) is
460 begin
461 if From = 0 then
462 Table.Table (Index_Of (To)) := Temp;
464 elsif To = 0 then
465 Temp := Table.Table (Index_Of (From));
467 else
468 Table.Table (Index_Of (To)) :=
469 Table.Table (Index_Of (From));
470 end if;
471 end Move;
473 ----------------
474 -- Lower_Than --
475 ----------------
477 function Lower_Than (Op1, Op2 : Natural) return Boolean is
478 begin
479 if Op1 = 0 then
480 return Lt (Temp, Table.Table (Index_Of (Op2)));
482 elsif Op2 = 0 then
483 return Lt (Table.Table (Index_Of (Op1)), Temp);
485 else
486 return
487 Lt (Table.Table (Index_Of (Op1)), Table.Table (Index_Of (Op2)));
488 end if;
489 end Lower_Than;
491 -- Start of processing for Sort_Table
493 begin
494 Heap_Sort.Sort (Natural (Last (Table) - First) + 1);
495 end Sort_Table;
497 end GNAT.Dynamic_Tables;