1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
|
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "mozilla/Assertions.h"
#include "mozilla/Attributes.h"
#include "mozilla/HashFunctions.h"
#include "mozilla/MemoryReporting.h"
#include "mozilla/MruCache.h"
#include "mozilla/RWLock.h"
#include "mozilla/TextUtils.h"
#include "nsHashKeys.h"
#include "nsThreadUtils.h"
#include "nsAtom.h"
#include "nsAtomTable.h"
#include "nsGkAtoms.h"
#include "nsPrintfCString.h"
#include "nsString.h"
#include "nsUnicharUtils.h"
#include "PLDHashTable.h"
#include "prenv.h"
// There are two kinds of atoms handled by this module.
//
// - Dynamic: the atom itself is heap allocated, as is the char buffer it
// points to. |gAtomTable| holds weak references to dynamic atoms. When the
// refcount of a dynamic atom drops to zero, we increment a static counter.
// When that counter reaches a certain threshold, we iterate over the atom
// table, removing and deleting dynamic atoms with refcount zero. This allows
// us to avoid acquiring the atom table lock during normal refcounting.
//
// - Static: both the atom and its chars are statically allocated and
// immutable, so it ignores all AddRef/Release calls.
//
// Note that gAtomTable is used on multiple threads, and has internal
// synchronization.
using namespace mozilla;
//----------------------------------------------------------------------
enum class GCKind {
RegularOperation,
Shutdown,
};
//----------------------------------------------------------------------
// gUnusedAtomCount is incremented when an atom loses its last reference
// (and thus turned into unused state), and decremented when an unused
// atom gets a reference again. The atom table relies on this value to
// schedule GC. This value can temporarily go below zero when multiple
// threads are operating the same atom, so it has to be signed so that
// we wouldn't use overflow value for comparison.
// See nsAtom::AddRef() and nsAtom::Release().
// This atomic can be accessed during the GC and other places where recorded
// events are not allowed, so its value is not preserved when recording or
// replaying.
Atomic<int32_t, ReleaseAcquire> nsDynamicAtom::gUnusedAtomCount;
nsDynamicAtom::nsDynamicAtom(already_AddRefed<nsStringBuffer> aBuffer,
uint32_t aLength, uint32_t aHash,
bool aIsAsciiLowercase)
: nsAtom(aLength, /* aIsStatic = */ false, aHash, aIsAsciiLowercase),
mRefCnt(1),
mStringBuffer(aBuffer) {}
// Returns true if ToLowercaseASCII would return the string unchanged.
static bool IsAsciiLowercase(const char16_t* aString, const uint32_t aLength) {
for (uint32_t i = 0; i < aLength; ++i) {
if (IS_ASCII_UPPER(aString[i])) {
return false;
}
}
return true;
}
nsDynamicAtom* nsDynamicAtom::Create(const nsAString& aString, uint32_t aHash) {
// We tack the chars onto the end of the nsDynamicAtom object.
const bool isAsciiLower =
::IsAsciiLowercase(aString.Data(), aString.Length());
RefPtr<nsStringBuffer> buffer = nsStringBuffer::FromString(aString);
if (!buffer) {
buffer = nsStringBuffer::Create(aString.Data(), aString.Length());
if (MOZ_UNLIKELY(!buffer)) {
MOZ_CRASH("Out of memory atomizing");
}
} else {
MOZ_ASSERT(aString.IsTerminated(),
"String buffers are always null-terminated");
}
auto* atom =
new nsDynamicAtom(buffer.forget(), aString.Length(), aHash, isAsciiLower);
MOZ_ASSERT(atom->String()[atom->GetLength()] == char16_t(0));
MOZ_ASSERT(atom->Equals(aString));
MOZ_ASSERT(atom->mHash == HashString(atom->String(), atom->GetLength()));
MOZ_ASSERT(atom->mIsAsciiLowercase == isAsciiLower);
return atom;
}
void nsDynamicAtom::Destroy(nsDynamicAtom* aAtom) { delete aAtom; }
void nsAtom::ToString(nsAString& aString) const {
// See the comment on |mString|'s declaration.
if (IsStatic()) {
// AssignLiteral() lets us assign without copying. This isn't a string
// literal, but it's a static atom and thus has an unbounded lifetime,
// which is what's important.
aString.AssignLiteral(AsStatic()->String(), mLength);
} else {
AsDynamic()->StringBuffer()->ToString(mLength, aString);
}
}
void nsAtom::ToUTF8String(nsACString& aBuf) const {
CopyUTF16toUTF8(nsDependentString(GetUTF16String(), mLength), aBuf);
}
void nsAtom::AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf,
AtomsSizes& aSizes) const {
// Static atoms are in static memory, and so are not measured here.
if (IsDynamic()) {
aSizes.mDynamicAtoms += aMallocSizeOf(this);
}
}
char16ptr_t nsAtom::GetUTF16String() const {
return IsStatic() ? AsStatic()->String() : AsDynamic()->String();
}
//----------------------------------------------------------------------
struct AtomTableKey {
explicit AtomTableKey(const nsStaticAtom* aAtom)
: mUTF16String(aAtom->String()),
mUTF8String(nullptr),
mLength(aAtom->GetLength()),
mHash(aAtom->hash()) {
MOZ_ASSERT(HashString(mUTF16String, mLength) == mHash);
}
AtomTableKey(const char16_t* aUTF16String, uint32_t aLength, uint32_t aHash)
: mUTF16String(aUTF16String),
mUTF8String(nullptr),
mLength(aLength),
mHash(aHash) {
MOZ_ASSERT(HashString(mUTF16String, mLength) == mHash);
}
AtomTableKey(const char16_t* aUTF16String, uint32_t aLength)
: AtomTableKey(aUTF16String, aLength, HashString(aUTF16String, aLength)) {
}
AtomTableKey(const char* aUTF8String, uint32_t aLength, bool* aErr)
: mUTF16String(nullptr), mUTF8String(aUTF8String), mLength(aLength) {
mHash = HashUTF8AsUTF16(mUTF8String, mLength, aErr);
}
const char16_t* mUTF16String;
const char* mUTF8String;
uint32_t mLength;
uint32_t mHash;
};
struct AtomTableEntry : public PLDHashEntryHdr {
// These references are either to dynamic atoms, in which case they are
// non-owning, or they are to static atoms, which aren't really refcounted.
// See the comment at the top of this file for more details.
nsAtom* MOZ_NON_OWNING_REF mAtom;
};
struct AtomCache : public MruCache<AtomTableKey, nsAtom*, AtomCache> {
static HashNumber Hash(const AtomTableKey& aKey) { return aKey.mHash; }
static bool Match(const AtomTableKey& aKey, const nsAtom* aVal) {
MOZ_ASSERT(aKey.mUTF16String);
return aVal->Equals(aKey.mUTF16String, aKey.mLength);
}
};
static AtomCache sRecentlyUsedSmallMainThreadAtoms;
static AtomCache sRecentlyUsedLargeMainThreadAtoms;
// In order to reduce locking contention for concurrent atomization, we segment
// the atom table into N subtables, each with a separate lock. If the hash
// values we use to select the subtable are evenly distributed, this reduces the
// probability of contention by a factor of N. See bug 1440824.
//
// NB: This is somewhat similar to the technique used by Java's
// ConcurrentHashTable.
class nsAtomSubTable {
friend class nsAtomTable;
mozilla::RWLock mLock;
PLDHashTable mTable;
nsAtomSubTable();
void GCLocked(GCKind aKind) MOZ_REQUIRES(mLock);
void AddSizeOfExcludingThisLocked(MallocSizeOf aMallocSizeOf,
AtomsSizes& aSizes)
MOZ_REQUIRES_SHARED(mLock);
AtomTableEntry* Search(AtomTableKey& aKey) const MOZ_REQUIRES_SHARED(mLock) {
// XXX There's no LockedForReadingByCurrentThread();
return static_cast<AtomTableEntry*>(mTable.Search(&aKey));
}
AtomTableEntry* Add(AtomTableKey& aKey) MOZ_REQUIRES(mLock) {
MOZ_ASSERT(mLock.LockedForWritingByCurrentThread());
return static_cast<AtomTableEntry*>(mTable.Add(&aKey)); // Infallible
}
};
// The outer atom table, which coordinates access to the inner array of
// subtables.
class nsAtomTable {
public:
nsAtomSubTable& SelectSubTable(AtomTableKey& aKey);
void AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf, AtomsSizes& aSizes);
void GC(GCKind aKind);
already_AddRefed<nsAtom> Atomize(const nsAString& aUTF16String,
uint32_t aHash);
already_AddRefed<nsAtom> Atomize(const nsACString& aUTF8String);
already_AddRefed<nsAtom> AtomizeMainThread(const nsAString& aUTF16String);
nsStaticAtom* GetStaticAtom(const nsAString& aUTF16String);
void RegisterStaticAtoms(const nsStaticAtom* aAtoms, size_t aAtomsLen);
// The result of this function may be imprecise if other threads are operating
// on atoms concurrently. It's also slow, since it triggers a GC before
// counting.
size_t RacySlowCount();
// This hash table op is a static member of this class so that it can take
// advantage of |friend| declarations.
static void AtomTableClearEntry(PLDHashTable* aTable,
PLDHashEntryHdr* aEntry);
// We achieve measurable reduction in locking contention in parallel CSS
// parsing by increasing the number of subtables up to 128. This has been
// measured to have neglible impact on the performance of initialization, GC,
// and shutdown.
//
// Another important consideration is memory, since we're adding fixed
// overhead per content process, which we try to avoid. Measuring a
// mostly-empty page [1] with various numbers of subtables, we get the
// following deep sizes for the atom table:
// 1 subtable: 278K
// 8 subtables: 279K
// 16 subtables: 282K
// 64 subtables: 286K
// 128 subtables: 290K
//
// So 128 subtables costs us 12K relative to a single table, and 4K relative
// to 64 subtables. Conversely, measuring parallel (6 thread) CSS parsing on
// tp6-facebook, a single table provides ~150ms of locking overhead per
// thread, 64 subtables provides ~2-3ms of overhead, and 128 subtables
// provides <1ms. And so while either 64 or 128 subtables would probably be
// acceptable, achieving a measurable reduction in contention for 4k of fixed
// memory overhead is probably worth it.
//
// [1] The numbers will look different for content processes with complex
// pages loaded, but in those cases the actual atoms will dominate memory
// usage and the overhead of extra tables will be negligible. We're mostly
// interested in the fixed cost for nearly-empty content processes.
constexpr static size_t kNumSubTables = 512; // Must be power of two.
// The atom table very quickly gets 10,000+ entries in it (or even 100,000+).
// But choosing the best initial subtable length has some subtleties: we add
// ~2700 static atoms at start-up, and then we start adding and removing
// dynamic atoms. If we make the tables too big to start with, when the first
// dynamic atom gets removed from a given table the load factor will be < 25%
// and we will shrink it.
//
// So we first make the simplifying assumption that the atoms are more or less
// evenly-distributed across the subtables (which is the case empirically).
// Then, we take the total atom count when the first dynamic atom is removed
// (~2700), divide that across the N subtables, and the largest capacity that
// will allow each subtable to be > 25% full with that count.
//
// So want an initial subtable capacity less than (2700 / N) * 4 = 10800 / N.
// Rounding down to the nearest power of two gives us 8192 / N. Since the
// capacity is double the initial length, we end up with (4096 / N) per
// subtable.
constexpr static size_t kInitialSubTableSize = 4096 / kNumSubTables;
private:
nsAtomSubTable mSubTables[kNumSubTables];
};
// Static singleton instance for the atom table.
static nsAtomTable* gAtomTable;
static PLDHashNumber AtomTableGetHash(const void* aKey) {
const AtomTableKey* k = static_cast<const AtomTableKey*>(aKey);
return k->mHash;
}
static bool AtomTableMatchKey(const PLDHashEntryHdr* aEntry, const void* aKey) {
const AtomTableEntry* he = static_cast<const AtomTableEntry*>(aEntry);
const AtomTableKey* k = static_cast<const AtomTableKey*>(aKey);
if (k->mUTF8String) {
bool err = false;
return (CompareUTF8toUTF16(nsDependentCSubstring(
k->mUTF8String, k->mUTF8String + k->mLength),
nsDependentAtomString(he->mAtom), &err) == 0) &&
!err;
}
return he->mAtom->Equals(k->mUTF16String, k->mLength);
}
void nsAtomTable::AtomTableClearEntry(PLDHashTable* aTable,
PLDHashEntryHdr* aEntry) {
auto* entry = static_cast<AtomTableEntry*>(aEntry);
entry->mAtom = nullptr;
}
static void AtomTableInitEntry(PLDHashEntryHdr* aEntry, const void* aKey) {
static_cast<AtomTableEntry*>(aEntry)->mAtom = nullptr;
}
static const PLDHashTableOps AtomTableOps = {
AtomTableGetHash, AtomTableMatchKey, PLDHashTable::MoveEntryStub,
nsAtomTable::AtomTableClearEntry, AtomTableInitEntry};
nsAtomSubTable& nsAtomTable::SelectSubTable(AtomTableKey& aKey) {
// There are a few considerations around how we select subtables.
//
// First, we want entries to be evenly distributed across the subtables. This
// can be achieved by using any bits in the hash key, assuming the key itself
// is evenly-distributed. Empirical measurements indicate that this method
// produces a roughly-even distribution across subtables.
//
// Second, we want to use the hash bits that are least likely to influence an
// entry's position within the subtable. If we used the exact same bits used
// by the subtables, then each subtable would compute the same position for
// every entry it observes, leading to pessimal performance. In this case,
// we're using PLDHashTable, whose primary hash function uses the N leftmost
// bits of the hash value (where N is the log2 capacity of the table). This
// means we should prefer the rightmost bits here.
//
// Note that the below is equivalent to mHash % kNumSubTables, a replacement
// which an optimizing compiler should make, but let's avoid any doubt.
static_assert((kNumSubTables & (kNumSubTables - 1)) == 0,
"must be power of two");
return mSubTables[aKey.mHash & (kNumSubTables - 1)];
}
void nsAtomTable::AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf,
AtomsSizes& aSizes) {
MOZ_ASSERT(NS_IsMainThread());
aSizes.mTable += aMallocSizeOf(this);
for (auto& table : mSubTables) {
AutoReadLock lock(table.mLock);
table.AddSizeOfExcludingThisLocked(aMallocSizeOf, aSizes);
}
}
void nsAtomTable::GC(GCKind aKind) {
MOZ_ASSERT(NS_IsMainThread());
sRecentlyUsedSmallMainThreadAtoms.Clear();
sRecentlyUsedLargeMainThreadAtoms.Clear();
// Note that this is effectively an incremental GC, since only one subtable
// is locked at a time.
for (auto& table : mSubTables) {
AutoWriteLock lock(table.mLock);
table.GCLocked(aKind);
}
// We would like to assert that gUnusedAtomCount matches the number of atoms
// we found in the table which we removed. However, there are two problems
// with this:
// * We have multiple subtables, each with their own lock. For optimal
// performance we only want to hold one lock at a time, but this means
// that atoms can be added and removed between GC slices.
// * Even if we held all the locks and performed all GC slices atomically,
// the locks are not acquired for AddRef() and Release() calls. This means
// we might see a gUnusedAtomCount value in between, say, AddRef()
// incrementing mRefCnt and it decrementing gUnusedAtomCount.
//
// So, we don't bother asserting that there are no unused atoms at the end of
// a regular GC. But we can (and do) assert this just after the last GC at
// shutdown.
//
// Note that, barring refcounting bugs, an atom can only go from a zero
// refcount to a non-zero refcount while the atom table lock is held, so
// so we won't try to resurrect a zero refcount atom while trying to delete
// it.
MOZ_ASSERT_IF(aKind == GCKind::Shutdown,
nsDynamicAtom::gUnusedAtomCount == 0);
}
size_t nsAtomTable::RacySlowCount() {
// Trigger a GC so that the result is deterministic modulo other threads.
GC(GCKind::RegularOperation);
size_t count = 0;
for (auto& table : mSubTables) {
AutoReadLock lock(table.mLock);
count += table.mTable.EntryCount();
}
return count;
}
nsAtomSubTable::nsAtomSubTable()
: mLock("Atom Sub-Table Lock"),
mTable(&AtomTableOps, sizeof(AtomTableEntry),
nsAtomTable::kInitialSubTableSize) {}
void nsAtomSubTable::GCLocked(GCKind aKind) {
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(mLock.LockedForWritingByCurrentThread());
int32_t removedCount = 0; // A non-atomic temporary for cheaper increments.
nsAutoCString nonZeroRefcountAtoms;
uint32_t nonZeroRefcountAtomsCount = 0;
for (auto i = mTable.Iter(); !i.Done(); i.Next()) {
auto* entry = static_cast<AtomTableEntry*>(i.Get());
if (entry->mAtom->IsStatic()) {
continue;
}
nsAtom* atom = entry->mAtom;
if (atom->IsDynamic() && atom->AsDynamic()->mRefCnt == 0) {
i.Remove();
nsDynamicAtom::Destroy(atom->AsDynamic());
++removedCount;
}
#ifdef NS_FREE_PERMANENT_DATA
else if (aKind == GCKind::Shutdown && PR_GetEnv("XPCOM_MEM_BLOAT_LOG")) {
// Only report leaking atoms in leak-checking builds in a run where we
// are checking for leaks, during shutdown. If something is anomalous,
// then we'll assert later in this function.
nsAutoCString name;
atom->ToUTF8String(name);
if (nonZeroRefcountAtomsCount == 0) {
nonZeroRefcountAtoms = name;
} else if (nonZeroRefcountAtomsCount < 20) {
nonZeroRefcountAtoms += ","_ns + name;
} else if (nonZeroRefcountAtomsCount == 20) {
nonZeroRefcountAtoms += ",..."_ns;
}
nonZeroRefcountAtomsCount++;
}
#endif
}
if (nonZeroRefcountAtomsCount) {
nsPrintfCString msg("%d dynamic atom(s) with non-zero refcount: %s",
nonZeroRefcountAtomsCount, nonZeroRefcountAtoms.get());
NS_ASSERTION(nonZeroRefcountAtomsCount == 0, msg.get());
}
nsDynamicAtom::gUnusedAtomCount -= removedCount;
}
void nsDynamicAtom::GCAtomTable() {
MOZ_ASSERT(gAtomTable);
if (NS_IsMainThread()) {
gAtomTable->GC(GCKind::RegularOperation);
}
}
//----------------------------------------------------------------------
// Have the static atoms been inserted into the table?
static bool gStaticAtomsDone = false;
void NS_InitAtomTable() {
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(!gAtomTable);
// We register static atoms immediately so they're available for use as early
// as possible.
gAtomTable = new nsAtomTable();
gAtomTable->RegisterStaticAtoms(nsGkAtoms::sAtoms, nsGkAtoms::sAtomsLen);
gStaticAtomsDone = true;
}
void NS_ShutdownAtomTable() {
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(gAtomTable);
#ifdef NS_FREE_PERMANENT_DATA
// Do a final GC to satisfy leak checking. We skip this step in release
// builds.
gAtomTable->GC(GCKind::Shutdown);
#endif
delete gAtomTable;
gAtomTable = nullptr;
}
void NS_AddSizeOfAtoms(MallocSizeOf aMallocSizeOf, AtomsSizes& aSizes) {
MOZ_ASSERT(NS_IsMainThread());
MOZ_ASSERT(gAtomTable);
return gAtomTable->AddSizeOfIncludingThis(aMallocSizeOf, aSizes);
}
void nsAtomSubTable::AddSizeOfExcludingThisLocked(MallocSizeOf aMallocSizeOf,
AtomsSizes& aSizes) {
aSizes.mTable += mTable.ShallowSizeOfExcludingThis(aMallocSizeOf);
for (auto iter = mTable.Iter(); !iter.Done(); iter.Next()) {
auto* entry = static_cast<AtomTableEntry*>(iter.Get());
entry->mAtom->AddSizeOfIncludingThis(aMallocSizeOf, aSizes);
}
}
void nsAtomTable::RegisterStaticAtoms(const nsStaticAtom* aAtoms,
size_t aAtomsLen) {
MOZ_ASSERT(NS_IsMainThread());
MOZ_RELEASE_ASSERT(!gStaticAtomsDone, "Static atom insertion is finished!");
for (uint32_t i = 0; i < aAtomsLen; ++i) {
const nsStaticAtom* atom = &aAtoms[i];
MOZ_ASSERT(IsAsciiNullTerminated(atom->String()));
MOZ_ASSERT(NS_strlen(atom->String()) == atom->GetLength());
MOZ_ASSERT(atom->IsAsciiLowercase() ==
::IsAsciiLowercase(atom->String(), atom->GetLength()));
// This assertion ensures the static atom's precomputed hash value matches
// what would be computed by mozilla::HashString(aStr), which is what we use
// when atomizing strings. We compute this hash in Atom.py.
MOZ_ASSERT(HashString(atom->String()) == atom->hash());
AtomTableKey key(atom);
nsAtomSubTable& table = SelectSubTable(key);
AutoWriteLock lock(table.mLock);
AtomTableEntry* he = table.Add(key);
if (he->mAtom) {
// There are two ways we could get here.
// - Register two static atoms with the same string.
// - Create a dynamic atom and then register a static atom with the same
// string while the dynamic atom is alive.
// Both cases can cause subtle bugs, and are disallowed. We're
// programming in C++ here, not Smalltalk.
nsAutoCString name;
he->mAtom->ToUTF8String(name);
MOZ_CRASH_UNSAFE_PRINTF("Atom for '%s' already exists", name.get());
}
he->mAtom = const_cast<nsStaticAtom*>(atom);
}
}
already_AddRefed<nsAtom> NS_Atomize(const char* aUTF8String) {
MOZ_ASSERT(gAtomTable);
return gAtomTable->Atomize(nsDependentCString(aUTF8String));
}
already_AddRefed<nsAtom> nsAtomTable::Atomize(const nsACString& aUTF8String) {
bool err;
AtomTableKey key(aUTF8String.Data(), aUTF8String.Length(), &err);
if (MOZ_UNLIKELY(err)) {
MOZ_ASSERT_UNREACHABLE("Tried to atomize invalid UTF-8.");
// The input was invalid UTF-8. Let's replace the errors with U+FFFD
// and atomize the result.
nsString str;
CopyUTF8toUTF16(aUTF8String, str);
return Atomize(str, HashString(str));
}
nsAtomSubTable& table = SelectSubTable(key);
{
AutoReadLock lock(table.mLock);
if (AtomTableEntry* he = table.Search(key)) {
return do_AddRef(he->mAtom);
}
}
AutoWriteLock lock(table.mLock);
AtomTableEntry* he = table.Add(key);
if (he->mAtom) {
return do_AddRef(he->mAtom);
}
nsString str;
CopyUTF8toUTF16(aUTF8String, str);
MOZ_ASSERT(nsStringBuffer::FromString(str), "Should create a string buffer");
RefPtr<nsAtom> atom = dont_AddRef(nsDynamicAtom::Create(str, key.mHash));
he->mAtom = atom;
return atom.forget();
}
already_AddRefed<nsAtom> NS_Atomize(const nsACString& aUTF8String) {
MOZ_ASSERT(gAtomTable);
return gAtomTable->Atomize(aUTF8String);
}
already_AddRefed<nsAtom> NS_Atomize(const char16_t* aUTF16String) {
return NS_Atomize(nsDependentString(aUTF16String));
}
already_AddRefed<nsAtom> nsAtomTable::Atomize(const nsAString& aUTF16String,
uint32_t aHash) {
AtomTableKey key(aUTF16String.Data(), aUTF16String.Length(), aHash);
nsAtomSubTable& table = SelectSubTable(key);
{
AutoReadLock lock(table.mLock);
if (AtomTableEntry* he = table.Search(key)) {
return do_AddRef(he->mAtom);
}
}
AutoWriteLock lock(table.mLock);
AtomTableEntry* he = table.Add(key);
if (he->mAtom) {
RefPtr<nsAtom> atom = he->mAtom;
return atom.forget();
}
RefPtr<nsAtom> atom =
dont_AddRef(nsDynamicAtom::Create(aUTF16String, key.mHash));
he->mAtom = atom;
return atom.forget();
}
already_AddRefed<nsAtom> NS_Atomize(const nsAString& aUTF16String,
uint32_t aKnownHash) {
MOZ_ASSERT(gAtomTable);
return gAtomTable->Atomize(aUTF16String, aKnownHash);
}
already_AddRefed<nsAtom> NS_Atomize(const nsAString& aUTF16String) {
return NS_Atomize(aUTF16String, HashString(aUTF16String));
}
already_AddRefed<nsAtom> nsAtomTable::AtomizeMainThread(
const nsAString& aUTF16String) {
MOZ_ASSERT(NS_IsMainThread());
RefPtr<nsAtom> retVal;
size_t length = aUTF16String.Length();
AtomTableKey key(aUTF16String.Data(), length);
auto p = (length < 5) ? sRecentlyUsedSmallMainThreadAtoms.Lookup(key)
: sRecentlyUsedLargeMainThreadAtoms.Lookup(key);
if (p) {
retVal = p.Data();
return retVal.forget();
}
nsAtomSubTable& table = SelectSubTable(key);
{
AutoReadLock lock(table.mLock);
if (AtomTableEntry* he = table.Search(key)) {
p.Set(he->mAtom);
return do_AddRef(he->mAtom);
}
}
AutoWriteLock lock(table.mLock);
AtomTableEntry* he = table.Add(key);
if (he->mAtom) {
retVal = he->mAtom;
} else {
RefPtr<nsAtom> newAtom =
dont_AddRef(nsDynamicAtom::Create(aUTF16String, key.mHash));
he->mAtom = newAtom;
retVal = std::move(newAtom);
}
p.Set(retVal);
return retVal.forget();
}
already_AddRefed<nsAtom> NS_AtomizeMainThread(const nsAString& aUTF16String) {
MOZ_ASSERT(gAtomTable);
return gAtomTable->AtomizeMainThread(aUTF16String);
}
nsrefcnt NS_GetNumberOfAtoms(void) {
MOZ_ASSERT(gAtomTable);
return gAtomTable->RacySlowCount();
}
int32_t NS_GetUnusedAtomCount(void) { return nsDynamicAtom::gUnusedAtomCount; }
nsStaticAtom* NS_GetStaticAtom(const nsAString& aUTF16String) {
MOZ_ASSERT(gStaticAtomsDone, "Static atom setup not yet done.");
MOZ_ASSERT(gAtomTable);
return gAtomTable->GetStaticAtom(aUTF16String);
}
nsStaticAtom* nsAtomTable::GetStaticAtom(const nsAString& aUTF16String) {
AtomTableKey key(aUTF16String.Data(), aUTF16String.Length());
nsAtomSubTable& table = SelectSubTable(key);
AutoReadLock lock(table.mLock);
AtomTableEntry* he = table.Search(key);
return he && he->mAtom->IsStatic() ? static_cast<nsStaticAtom*>(he->mAtom)
: nullptr;
}
void ToLowerCaseASCII(RefPtr<nsAtom>& aAtom) {
// Assume the common case is that the atom is already ASCII lowercase.
if (aAtom->IsAsciiLowercase()) {
return;
}
nsAutoString lowercased;
ToLowerCaseASCII(nsDependentAtomString(aAtom), lowercased);
aAtom = NS_Atomize(lowercased);
}
|