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1 /* Copyright (C) 2012-2013
2 Free Software Foundation
4 This file is part of GCC.
6 GCC is free software; you can redistribute it and/or modify it
7 under the terms of the GNU General Public License as published by
8 the Free Software Foundation; either version 3, or (at your option)
9 any later version.
11 GCC is distributed in the hope that it will be useful, but WITHOUT
12 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
13 or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public
14 License for more details.
16 Under Section 7 of GPL version 3, you are granted additional
17 permissions described in the GCC Runtime Library Exception, version
18 3.1, as published by the Free Software Foundation.
20 You should have received a copy of the GNU General Public License
21 and a copy of the GCC Runtime Library Exception along with this
22 program; see the files COPYING3 and COPYING.RUNTIME respectively.
23 If not, see <http://www.gnu.org/licenses/>. */
25 #ifndef _VTV_SET_H
26 #define _VTV_SET_H 1
28 /* Code in this file manages a collection of insert-only sets. We
29 have only tested the case where Key is uintptr_t, though it
30 theoretically should work for some other cases. All odd keys are
31 reserved, and must not be inserted into any of the sets. This code
32 is intended primarily for sets of pointers, and the code is
33 optimized for small sets (including size 0 and 1), but regardless
34 of the set size, insert() and contains() have close to O(1) speed
35 in practice.
37 TODO(gpike): fix this comment.
39 Recommended multithreaded use of a set:
41 For speed, we want to use a lock-free test for set membership. The
42 code handles simultaneous reads and inserts, as long as at most one
43 insertion is in progress at a time. After an insert, other threads
44 may not immediately "see" the inserted key if they perform a
45 lock-free read, so we recommend retrying, as explained below.
47 Also, to make data corruption less likely, we recommend using a
48 "normal" RW page as well as one or pages that are typically RO
49 but that can be switched to RW and back as needed. The latter
50 pages should contain sets. The former should contain a lock, L,
51 and an int or similar, num_writers. Then, to insert, something
52 like this would be safe:
53 o Acquire L.
54 o Increment num_writers; if that made it 1, change pages to RW.
55 o Release L.
56 o while (there are insertions to do in some set, S) {
57 acquire L;
58 do some insertions in S;
59 release L;
60 }
61 o Acquire L.
62 o Decrement num_writers; if that made it 0, change pages to RO.
63 o Release L.
65 And to check if the set contains some key, one could use
66 set.contains(key) ||
67 ({ Acquire L; bool b = set.contains(key); Release L; b; })
69 In this scheme, the number of threads with reads in progress isn't
70 tracked, so old sets can never be deleted. In addition, on some
71 architectures the intentionally racy reads might cause contains()
72 to return true when it should have returned false. This should be
73 no problem on x86, and most other machines, where reading or
74 writing an aligned uintptr_t is atomic. E.g., on those machines,
75 if *p is 0 and one thread does *p = x while another reads *p, the
76 read will see either 0 or x.
78 To make the above easier, the insert_only_hash_sets class provides
79 an interface to manipulate any number of hash sets. One shouldn't
80 create objects of that class, as it has no member data and its
81 methods are static.
83 So the recommended model is to have a single lock, a single
84 num_writers variable, and some number of sets. If lock contention
85 becomes a problem then the sets can be divided into k groups, each
86 of which has a lock and a num_writers variable; or each set can be
87 represented as a set of values that equal 0 mod m, a set of values
88 that equal 1 mod m, ..., plus a set of values that equal m-1 mod m.
90 However, we expect most or all uses of this code to call contains()
91 much more frequently than anything else, so lock contention is
92 likely to be low. */
94 #include <algorithm>
96 #ifndef HASHTABLE_STATS
97 #define HASHTABLE_STATS 0
98 #endif
100 #ifndef HASHTABLE_STATS_ATOMIC
101 #define HASHTABLE_STATS_ATOMIC 0
102 #endif
104 #if HASHTABLE_STATS
105 #if HASHTABLE_STATS_ATOMIC
106 /* Stat counters, with atomics. */
107 #include <bits/atomic_word.h>
111 void
113 {
115 }
117 #else
119 /* Stat counters, but without atomics. */
122 void
124 {
126 }
128 #endif
131 /* Number of calls to contains(), insert(), etc. */
137 /* Sum of set size over all calls to contains(). */
140 /* contains() calls in a set whose capacity is more than 1. */
143 /* Probes in a set whose capacity is more than 1. Ideally, this will
144 be pretty close to stat_contains_in_non_trivial_set. That will
145 happen if our hash function is good and/or important keys were
146 inserted before unimportant keys. */
149 /* number of calls to contains() with size=0, 1, etc. */
169 /* Hash collisions detected during insert_no_resize(). Only counts
170 hasher(k) == hasher(k'); hasher(k) % tablesize == hasher(k') %
171 tablesize is not sufficient. Will count collisions that are
172 detected during table resizes etc., so the same two keys may add to
173 this stat multiple times. */
176 #include <string>
178 struct insert_only_hash_sets_logger
179 {
182 {
185 }
193 {
196 else
198 }
202 {
207 }
208 };
210 // Write stats to the given buffer, which should be at least 4000 bytes.
213 {
220 stat_insert_key_that_was_already_present,
221 buf);
225 stat_contains_in_non_trivial_set,
226 buf);
228 stat_probes_in_non_trivial_set,
229 buf);
263 stat_insert_found_hash_collision,
264 buf);
266 stat_double_the_number_of_buckets,
267 buf);
269 }
271 #else
273 /* No stats. */
274 #define inc_by(statname, amount) do { } while (false && (amount))
276 #endif
278 #define inc(statname) inc_by (statname, 1)
281 class insert_only_hash_sets
282 {
289 #if HASHTABLE_STATS
291 #else
293 #endif
295 /* Do not directly use insert_only_hash_set. Instead, use the
296 static methods below to create and manipulate objects of the
297 following class.
299 Implementation details: each set is represented by a pointer
300 plus, perhaps, out-of-line data, which would be an object of type
301 insert_only_hash_set. For a pointer, s, the interpretation is: s
302 == NULL means empty set, lsb(s) == 1 means a set with one
303 element, which is (uintptr_t)s - 1, and otherwise s is a pointer
304 of type insert_only_hash_set*. So, to increase the size of a set
305 we have to change s and/or *s. To check if a set contains some
306 key we have to examine s and possibly *s. */
307 class insert_only_hash_set
308 {
310 /* Insert a key. The key must not be a reserved key. */
315 /* Create an empty set. */
318 /* Return whether the given key is present. If key is illegal_key
319 then either true or false may be returned, but for all other
320 reserved keys false will be returned. */
321 static bool
323 {
325 {
328 {
343 }
345 }
350 }
352 /* Return a set's size. */
353 static size_type
362 /* Return whether a set has size 1. */
363 static bool
367 /* Return the representation of a singleton set containing the
368 given key. */
373 /* Given a singleton set, what key does it contain? */
374 static key_type
376 {
379 }
385 key_type
389 size_type
400 min_capacity. */
403 };
405 /* Create an empty set with the given capacity. Requires that n be
406 0 or a power of 2. If 1 < n < min_capacity then treat n as
407 min_capacity. Sets *handle. Returns true unless the allocator
408 fails. Subsequent operations on this set should use the same
409 handle. */
413 /* Force the capacity of a set to be n, unless it was more than n
414 already. Requires that n be 0 or a power of 2. Sets *handle
415 unless the current capacity is n or more. Returns true unless
416 the allocator fails. */
420 /* Insert a key. *handle is unmodified unless (1) a resize occurs,
421 or (2) the set was initially empty. Returns true unless the
422 allocator fails during a resize. If the allocator fails during a
423 resize then the set is reset to be the empty set. The key must
424 not be a reserved key. */
428 /* Check for the presence of a key. If key is illegal_key then
429 either true or false may be returned, but for all other reserved
430 keys false will be returned. */
436 /* Return the size of the given set. */
437 static size_type
441 static bool
444 };
450 {
462 {
464 {
466 }
467 else
468 {
472 }
474 }
476 }
482 {
491 {
496 /* Grow from size 1 to size 2. */
506 }
511 }
517 {
526 alloc_type alloc;
533 }
536 void
540 {
541 HashFcn hasher;
549 {
552 {
556 }
557 else
558 {
561 }
565 }
566 }
569 bool
572 {
574 HashFcn hasher;
581 {
590 }
592 }
598 {
602 {
611 }
612 else
614 }
617 bool
621 {
625 }
628 bool
631 {
635 }
638 bool
641 {
646 {
649 }
651 }