Enabled Usage of _Cilk_spawn and _Cilk_sync in Cilk Runtime (libcilkrts).
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1 ------------------------------------------------------------------------------
2 -- --
3 -- GNAT LIBRARY COMPONENTS --
4 -- --
5 -- ADA.CONTAINERS.HASH_TABLES.GENERIC_BOUNDED_OPERATIONS --
6 -- --
7 -- B o d y --
8 -- --
9 -- Copyright (C) 2004-2011, 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 -- This unit was originally developed by Matthew J Heaney. --
28 ------------------------------------------------------------------------------
30 with System; use type System.Address;
32 package body Ada.Containers.Hash_Tables.Generic_Bounded_Operations is
34 -----------
35 -- Clear --
36 -----------
38 procedure Clear (HT : in out Hash_Table_Type'Class) is
39 begin
40 if HT.Busy > 0 then
41 raise Program_Error with
42 "attempt to tamper with cursors (container is busy)";
43 end if;
45 HT.Length := 0;
46 -- HT.Busy := 0;
47 -- HT.Lock := 0;
48 HT.Free := -1;
49 HT.Buckets := (others => 0); -- optimize this somehow ???
50 end Clear;
52 ---------------------------
53 -- Delete_Node_Sans_Free --
54 ---------------------------
56 procedure Delete_Node_Sans_Free
57 (HT : in out Hash_Table_Type'Class;
58 X : Count_Type)
60 pragma Assert (X /= 0);
62 Indx : Hash_Type;
63 Prev : Count_Type;
64 Curr : Count_Type;
66 begin
67 if HT.Length = 0 then
68 raise Program_Error with
69 "attempt to delete node from empty hashed container";
70 end if;
72 Indx := Index (HT, HT.Nodes (X));
73 Prev := HT.Buckets (Indx);
75 if Prev = 0 then
76 raise Program_Error with
77 "attempt to delete node from empty hash bucket";
78 end if;
80 if Prev = X then
81 HT.Buckets (Indx) := Next (HT.Nodes (Prev));
82 HT.Length := HT.Length - 1;
83 return;
84 end if;
86 if HT.Length = 1 then
87 raise Program_Error with
88 "attempt to delete node not in its proper hash bucket";
89 end if;
91 loop
92 Curr := Next (HT.Nodes (Prev));
94 if Curr = 0 then
95 raise Program_Error with
96 "attempt to delete node not in its proper hash bucket";
97 end if;
99 if Curr = X then
100 Set_Next (HT.Nodes (Prev), Next => Next (HT.Nodes (Curr)));
101 HT.Length := HT.Length - 1;
102 return;
103 end if;
105 Prev := Curr;
106 end loop;
107 end Delete_Node_Sans_Free;
109 -----------
110 -- First --
111 -----------
113 function First (HT : Hash_Table_Type'Class) return Count_Type is
114 Indx : Hash_Type;
116 begin
117 if HT.Length = 0 then
118 return 0;
119 end if;
121 Indx := HT.Buckets'First;
122 loop
123 if HT.Buckets (Indx) /= 0 then
124 return HT.Buckets (Indx);
125 end if;
127 Indx := Indx + 1;
128 end loop;
129 end First;
131 ----------
132 -- Free --
133 ----------
135 procedure Free
136 (HT : in out Hash_Table_Type'Class;
137 X : Count_Type)
139 N : Nodes_Type renames HT.Nodes;
141 begin
142 -- This subprogram "deallocates" a node by relinking the node off of the
143 -- active list and onto the free list. Previously it would flag index
144 -- value 0 as an error. The precondition was weakened, so that index
145 -- value 0 is now allowed, and this value is interpreted to mean "do
146 -- nothing". This makes its behavior analogous to the behavior of
147 -- Ada.Unchecked_Deallocation, and allows callers to avoid having to add
148 -- special-case checks at the point of call.
150 if X = 0 then
151 return;
152 end if;
154 pragma Assert (X <= HT.Capacity);
156 -- pragma Assert (N (X).Prev >= 0); -- node is active
157 -- Find a way to mark a node as active vs. inactive; we could
158 -- use a special value in Color_Type for this. ???
160 -- The hash table actually contains two data structures: a list for
161 -- the "active" nodes that contain elements that have been inserted
162 -- onto the container, and another for the "inactive" nodes of the free
163 -- store.
165 -- We desire that merely declaring an object should have only minimal
166 -- cost; specially, we want to avoid having to initialize the free
167 -- store (to fill in the links), especially if the capacity is large.
169 -- The head of the free list is indicated by Container.Free. If its
170 -- value is non-negative, then the free store has been initialized
171 -- in the "normal" way: Container.Free points to the head of the list
172 -- of free (inactive) nodes, and the value 0 means the free list is
173 -- empty. Each node on the free list has been initialized to point
174 -- to the next free node (via its Parent component), and the value 0
175 -- means that this is the last free node.
177 -- If Container.Free is negative, then the links on the free store
178 -- have not been initialized. In this case the link values are
179 -- implied: the free store comprises the components of the node array
180 -- started with the absolute value of Container.Free, and continuing
181 -- until the end of the array (Nodes'Last).
183 -- ???
184 -- It might be possible to perform an optimization here. Suppose that
185 -- the free store can be represented as having two parts: one
186 -- comprising the non-contiguous inactive nodes linked together
187 -- in the normal way, and the other comprising the contiguous
188 -- inactive nodes (that are not linked together, at the end of the
189 -- nodes array). This would allow us to never have to initialize
190 -- the free store, except in a lazy way as nodes become inactive.
192 -- When an element is deleted from the list container, its node
193 -- becomes inactive, and so we set its Next component to value of
194 -- the node's index (in the nodes array), to indicate that it is
195 -- now inactive. This provides a useful way to detect a dangling
196 -- cursor reference. ???
198 Set_Next (N (X), Next => X); -- Node is deallocated (not on active list)
200 if HT.Free >= 0 then
201 -- The free store has previously been initialized. All we need to
202 -- do here is link the newly-free'd node onto the free list.
204 Set_Next (N (X), HT.Free);
205 HT.Free := X;
207 elsif X + 1 = abs HT.Free then
208 -- The free store has not been initialized, and the node becoming
209 -- inactive immediately precedes the start of the free store. All
210 -- we need to do is move the start of the free store back by one.
212 HT.Free := HT.Free + 1;
214 else
215 -- The free store has not been initialized, and the node becoming
216 -- inactive does not immediately precede the free store. Here we
217 -- first initialize the free store (meaning the links are given
218 -- values in the traditional way), and then link the newly-free'd
219 -- node onto the head of the free store.
221 -- ???
222 -- See the comments above for an optimization opportunity. If
223 -- the next link for a node on the free store is negative, then
224 -- this means the remaining nodes on the free store are
225 -- physically contiguous, starting as the absolute value of
226 -- that index value.
228 HT.Free := abs HT.Free;
230 if HT.Free > HT.Capacity then
231 HT.Free := 0;
233 else
234 for I in HT.Free .. HT.Capacity - 1 loop
235 Set_Next (Node => N (I), Next => I + 1);
236 end loop;
238 Set_Next (Node => N (HT.Capacity), Next => 0);
239 end if;
241 Set_Next (Node => N (X), Next => HT.Free);
242 HT.Free := X;
243 end if;
244 end Free;
246 ----------------------
247 -- Generic_Allocate --
248 ----------------------
250 procedure Generic_Allocate
251 (HT : in out Hash_Table_Type'Class;
252 Node : out Count_Type)
254 N : Nodes_Type renames HT.Nodes;
256 begin
257 if HT.Free >= 0 then
258 Node := HT.Free;
260 -- We always perform the assignment first, before we
261 -- change container state, in order to defend against
262 -- exceptions duration assignment.
264 Set_Element (N (Node));
265 HT.Free := Next (N (Node));
267 else
268 -- A negative free store value means that the links of the nodes
269 -- in the free store have not been initialized. In this case, the
270 -- nodes are physically contiguous in the array, starting at the
271 -- index that is the absolute value of the Container.Free, and
272 -- continuing until the end of the array (Nodes'Last).
274 Node := abs HT.Free;
276 -- As above, we perform this assignment first, before modifying
277 -- any container state.
279 Set_Element (N (Node));
280 HT.Free := HT.Free - 1;
281 end if;
282 end Generic_Allocate;
284 -------------------
285 -- Generic_Equal --
286 -------------------
288 function Generic_Equal
289 (L, R : Hash_Table_Type'Class) return Boolean
291 L_Index : Hash_Type;
292 L_Node : Count_Type;
294 N : Count_Type;
296 begin
297 if L'Address = R'Address then
298 return True;
299 end if;
301 if L.Length /= R.Length then
302 return False;
303 end if;
305 if L.Length = 0 then
306 return True;
307 end if;
309 -- Find the first node of hash table L
311 L_Index := L.Buckets'First;
312 loop
313 L_Node := L.Buckets (L_Index);
314 exit when L_Node /= 0;
315 L_Index := L_Index + 1;
316 end loop;
318 -- For each node of hash table L, search for an equivalent node in hash
319 -- table R.
321 N := L.Length;
322 loop
323 if not Find (HT => R, Key => L.Nodes (L_Node)) then
324 return False;
325 end if;
327 N := N - 1;
329 L_Node := Next (L.Nodes (L_Node));
331 if L_Node = 0 then
332 -- We have exhausted the nodes in this bucket
334 if N = 0 then
335 return True;
336 end if;
338 -- Find the next bucket
340 loop
341 L_Index := L_Index + 1;
342 L_Node := L.Buckets (L_Index);
343 exit when L_Node /= 0;
344 end loop;
345 end if;
346 end loop;
347 end Generic_Equal;
349 -----------------------
350 -- Generic_Iteration --
351 -----------------------
353 procedure Generic_Iteration (HT : Hash_Table_Type'Class) is
354 Node : Count_Type;
356 begin
357 if HT.Length = 0 then
358 return;
359 end if;
361 for Indx in HT.Buckets'Range loop
362 Node := HT.Buckets (Indx);
363 while Node /= 0 loop
364 Process (Node);
365 Node := Next (HT.Nodes (Node));
366 end loop;
367 end loop;
368 end Generic_Iteration;
370 ------------------
371 -- Generic_Read --
372 ------------------
374 procedure Generic_Read
375 (Stream : not null access Root_Stream_Type'Class;
376 HT : out Hash_Table_Type'Class)
378 N : Count_Type'Base;
380 begin
381 Clear (HT);
383 Count_Type'Base'Read (Stream, N);
385 if N < 0 then
386 raise Program_Error with "stream appears to be corrupt";
387 end if;
389 if N = 0 then
390 return;
391 end if;
393 if N > HT.Capacity then
394 raise Capacity_Error with "too many elements in stream";
395 end if;
397 for J in 1 .. N loop
398 declare
399 Node : constant Count_Type := New_Node (Stream);
400 Indx : constant Hash_Type := Index (HT, HT.Nodes (Node));
401 B : Count_Type renames HT.Buckets (Indx);
402 begin
403 Set_Next (HT.Nodes (Node), Next => B);
404 B := Node;
405 end;
407 HT.Length := HT.Length + 1;
408 end loop;
409 end Generic_Read;
411 -------------------
412 -- Generic_Write --
413 -------------------
415 procedure Generic_Write
416 (Stream : not null access Root_Stream_Type'Class;
417 HT : Hash_Table_Type'Class)
419 procedure Write (Node : Count_Type);
420 pragma Inline (Write);
422 procedure Write is new Generic_Iteration (Write);
424 -----------
425 -- Write --
426 -----------
428 procedure Write (Node : Count_Type) is
429 begin
430 Write (Stream, HT.Nodes (Node));
431 end Write;
433 begin
434 Count_Type'Base'Write (Stream, HT.Length);
435 Write (HT);
436 end Generic_Write;
438 -----------
439 -- Index --
440 -----------
442 function Index
443 (Buckets : Buckets_Type;
444 Node : Node_Type) return Hash_Type is
445 begin
446 return Buckets'First + Hash_Node (Node) mod Buckets'Length;
447 end Index;
449 function Index
450 (HT : Hash_Table_Type'Class;
451 Node : Node_Type) return Hash_Type is
452 begin
453 return Index (HT.Buckets, Node);
454 end Index;
456 ----------
457 -- Next --
458 ----------
460 function Next
461 (HT : Hash_Table_Type'Class;
462 Node : Count_Type) return Count_Type
464 Result : Count_Type := Next (HT.Nodes (Node));
466 begin
467 if Result /= 0 then -- another node in same bucket
468 return Result;
469 end if;
471 -- This was the last node in the bucket, so move to the next
472 -- bucket, and start searching for next node from there.
474 for Indx in Index (HT, HT.Nodes (Node)) + 1 .. HT.Buckets'Last loop
475 Result := HT.Buckets (Indx);
477 if Result /= 0 then -- bucket is not empty
478 return Result;
479 end if;
480 end loop;
482 return 0;
483 end Next;
485 end Ada.Containers.Hash_Tables.Generic_Bounded_Operations;