зеркало из https://github.com/mozilla/gecko-dev.git
671 строка
24 KiB
C++
671 строка
24 KiB
C++
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
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/* vim: set ts=8 sts=2 et sw=2 tw=80: */
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/* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "mozilla/Assertions.h"
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#include "mozilla/Attributes.h"
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#include "mozilla/HashFunctions.h"
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#include "mozilla/MemoryReporting.h"
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#include "mozilla/MruCache.h"
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#include "mozilla/Mutex.h"
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#include "mozilla/DebugOnly.h"
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#include "mozilla/Sprintf.h"
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#include "mozilla/TextUtils.h"
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#include "mozilla/Unused.h"
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#include "nsAtom.h"
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#include "nsAtomTable.h"
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#include "nsCRT.h"
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#include "nsGkAtoms.h"
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#include "nsHashKeys.h"
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#include "nsPrintfCString.h"
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#include "nsString.h"
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#include "nsThreadUtils.h"
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#include "nsUnicharUtils.h"
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#include "PLDHashTable.h"
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#include "prenv.h"
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// There are two kinds of atoms handled by this module.
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//
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// - Dynamic: the atom itself is heap allocated, as is the char buffer it
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// points to. |gAtomTable| holds weak references to dynamic atoms. When the
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// refcount of a dynamic atom drops to zero, we increment a static counter.
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// When that counter reaches a certain threshold, we iterate over the atom
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// table, removing and deleting dynamic atoms with refcount zero. This allows
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// us to avoid acquiring the atom table lock during normal refcounting.
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//
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// - Static: both the atom and its chars are statically allocated and
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// immutable, so it ignores all AddRef/Release calls.
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//
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// Note that gAtomTable is used on multiple threads, and has internal
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// synchronization.
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using namespace mozilla;
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//----------------------------------------------------------------------
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enum class GCKind {
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RegularOperation,
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Shutdown,
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};
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//----------------------------------------------------------------------
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// gUnusedAtomCount is incremented when an atom loses its last reference
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// (and thus turned into unused state), and decremented when an unused
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// atom gets a reference again. The atom table relies on this value to
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// schedule GC. This value can temporarily go below zero when multiple
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// threads are operating the same atom, so it has to be signed so that
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// we wouldn't use overflow value for comparison.
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// See nsAtom::AddRef() and nsAtom::Release().
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// This atomic can be accessed during the GC and other places where recorded
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// events are not allowed, so its value is not preserved when recording or
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// replaying.
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Atomic<int32_t, ReleaseAcquire> nsDynamicAtom::gUnusedAtomCount;
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nsDynamicAtom::nsDynamicAtom(const nsAString& aString, uint32_t aHash,
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bool aIsAsciiLowercase)
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: nsAtom(aString, aHash, aIsAsciiLowercase), mRefCnt(1) {}
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// Returns true if ToLowercaseASCII would return the string unchanged.
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static bool IsAsciiLowercase(const char16_t* aString, const uint32_t aLength) {
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for (uint32_t i = 0; i < aLength; ++i) {
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if (IS_ASCII_UPPER(aString[i])) {
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return false;
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}
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}
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return true;
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}
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nsDynamicAtom* nsDynamicAtom::Create(const nsAString& aString, uint32_t aHash) {
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// We tack the chars onto the end of the nsDynamicAtom object.
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size_t numCharBytes = (aString.Length() + 1) * sizeof(char16_t);
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size_t numTotalBytes = sizeof(nsDynamicAtom) + numCharBytes;
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bool isAsciiLower = ::IsAsciiLowercase(aString.Data(), aString.Length());
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nsDynamicAtom* atom = (nsDynamicAtom*)moz_xmalloc(numTotalBytes);
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new (atom) nsDynamicAtom(aString, aHash, isAsciiLower);
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memcpy(const_cast<char16_t*>(atom->String()),
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PromiseFlatString(aString).get(), numCharBytes);
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MOZ_ASSERT(atom->String()[atom->GetLength()] == char16_t(0));
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MOZ_ASSERT(atom->Equals(aString));
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MOZ_ASSERT(atom->mHash == HashString(atom->String(), atom->GetLength()));
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MOZ_ASSERT(atom->mIsAsciiLowercase == isAsciiLower);
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return atom;
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}
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void nsDynamicAtom::Destroy(nsDynamicAtom* aAtom) {
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aAtom->~nsDynamicAtom();
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free(aAtom);
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}
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void nsAtom::ToString(nsAString& aString) const {
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// See the comment on |mString|'s declaration.
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if (IsStatic()) {
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// AssignLiteral() lets us assign without copying. This isn't a string
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// literal, but it's a static atom and thus has an unbounded lifetime,
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// which is what's important.
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aString.AssignLiteral(AsStatic()->String(), mLength);
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} else {
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aString.Assign(AsDynamic()->String(), mLength);
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}
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}
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void nsAtom::ToUTF8String(nsACString& aBuf) const {
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CopyUTF16toUTF8(nsDependentString(GetUTF16String(), mLength), aBuf);
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}
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void nsAtom::AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf,
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AtomsSizes& aSizes) const {
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// Static atoms are in static memory, and so are not measured here.
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if (IsDynamic()) {
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aSizes.mDynamicAtoms += aMallocSizeOf(this);
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}
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}
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char16ptr_t nsAtom::GetUTF16String() const {
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return IsStatic() ? AsStatic()->String() : AsDynamic()->String();
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}
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//----------------------------------------------------------------------
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struct AtomTableKey {
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explicit AtomTableKey(const nsStaticAtom* aAtom)
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: mUTF16String(aAtom->String()),
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mUTF8String(nullptr),
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mLength(aAtom->GetLength()),
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mHash(aAtom->hash()) {
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MOZ_ASSERT(HashString(mUTF16String, mLength) == mHash);
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}
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AtomTableKey(const char16_t* aUTF16String, uint32_t aLength)
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: mUTF16String(aUTF16String), mUTF8String(nullptr), mLength(aLength) {
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mHash = HashString(mUTF16String, mLength);
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}
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AtomTableKey(const char* aUTF8String, uint32_t aLength, bool* aErr)
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: mUTF16String(nullptr), mUTF8String(aUTF8String), mLength(aLength) {
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mHash = HashUTF8AsUTF16(mUTF8String, mLength, aErr);
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}
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const char16_t* mUTF16String;
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const char* mUTF8String;
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uint32_t mLength;
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uint32_t mHash;
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};
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struct AtomTableEntry : public PLDHashEntryHdr {
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// These references are either to dynamic atoms, in which case they are
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// non-owning, or they are to static atoms, which aren't really refcounted.
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// See the comment at the top of this file for more details.
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nsAtom* MOZ_NON_OWNING_REF mAtom;
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};
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struct AtomCache : public MruCache<AtomTableKey, nsAtom*, AtomCache> {
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static HashNumber Hash(const AtomTableKey& aKey) { return aKey.mHash; }
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static bool Match(const AtomTableKey& aKey, const nsAtom* aVal) {
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MOZ_ASSERT(aKey.mUTF16String);
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return aVal->Equals(aKey.mUTF16String, aKey.mLength);
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}
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};
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static AtomCache sRecentlyUsedMainThreadAtoms;
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// In order to reduce locking contention for concurrent atomization, we segment
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// the atom table into N subtables, each with a separate lock. If the hash
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// values we use to select the subtable are evenly distributed, this reduces the
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// probability of contention by a factor of N. See bug 1440824.
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//
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// NB: This is somewhat similar to the technique used by Java's
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// ConcurrentHashTable.
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class nsAtomSubTable {
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friend class nsAtomTable;
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Mutex mLock;
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PLDHashTable mTable;
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nsAtomSubTable();
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void GCLocked(GCKind aKind);
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void AddSizeOfExcludingThisLocked(MallocSizeOf aMallocSizeOf,
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AtomsSizes& aSizes);
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AtomTableEntry* Search(AtomTableKey& aKey) const {
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mLock.AssertCurrentThreadOwns();
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return static_cast<AtomTableEntry*>(mTable.Search(&aKey));
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}
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AtomTableEntry* Add(AtomTableKey& aKey) {
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mLock.AssertCurrentThreadOwns();
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return static_cast<AtomTableEntry*>(mTable.Add(&aKey)); // Infallible
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}
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};
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// The outer atom table, which coordinates access to the inner array of
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// subtables.
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class nsAtomTable {
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public:
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nsAtomSubTable& SelectSubTable(AtomTableKey& aKey);
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void AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf, AtomsSizes& aSizes);
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void GC(GCKind aKind);
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already_AddRefed<nsAtom> Atomize(const nsAString& aUTF16String);
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already_AddRefed<nsAtom> Atomize(const nsACString& aUTF8String);
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already_AddRefed<nsAtom> AtomizeMainThread(const nsAString& aUTF16String);
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nsStaticAtom* GetStaticAtom(const nsAString& aUTF16String);
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void RegisterStaticAtoms(const nsStaticAtom* aAtoms, size_t aAtomsLen);
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// The result of this function may be imprecise if other threads are operating
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// on atoms concurrently. It's also slow, since it triggers a GC before
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// counting.
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size_t RacySlowCount();
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// This hash table op is a static member of this class so that it can take
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// advantage of |friend| declarations.
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static void AtomTableClearEntry(PLDHashTable* aTable,
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PLDHashEntryHdr* aEntry);
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// We achieve measurable reduction in locking contention in parallel CSS
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// parsing by increasing the number of subtables up to 128. This has been
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// measured to have neglible impact on the performance of initialization, GC,
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// and shutdown.
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//
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// Another important consideration is memory, since we're adding fixed
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// overhead per content process, which we try to avoid. Measuring a
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// mostly-empty page [1] with various numbers of subtables, we get the
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// following deep sizes for the atom table:
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// 1 subtable: 278K
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// 8 subtables: 279K
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// 16 subtables: 282K
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// 64 subtables: 286K
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// 128 subtables: 290K
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//
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// So 128 subtables costs us 12K relative to a single table, and 4K relative
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// to 64 subtables. Conversely, measuring parallel (6 thread) CSS parsing on
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// tp6-facebook, a single table provides ~150ms of locking overhead per
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// thread, 64 subtables provides ~2-3ms of overhead, and 128 subtables
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// provides <1ms. And so while either 64 or 128 subtables would probably be
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// acceptable, achieving a measurable reduction in contention for 4k of fixed
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// memory overhead is probably worth it.
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//
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// [1] The numbers will look different for content processes with complex
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// pages loaded, but in those cases the actual atoms will dominate memory
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// usage and the overhead of extra tables will be negligible. We're mostly
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// interested in the fixed cost for nearly-empty content processes.
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const static size_t kNumSubTables = 128; // Must be power of two.
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private:
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nsAtomSubTable mSubTables[kNumSubTables];
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};
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// Static singleton instance for the atom table.
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static nsAtomTable* gAtomTable;
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static PLDHashNumber AtomTableGetHash(const void* aKey) {
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const AtomTableKey* k = static_cast<const AtomTableKey*>(aKey);
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return k->mHash;
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}
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static bool AtomTableMatchKey(const PLDHashEntryHdr* aEntry, const void* aKey) {
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const AtomTableEntry* he = static_cast<const AtomTableEntry*>(aEntry);
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const AtomTableKey* k = static_cast<const AtomTableKey*>(aKey);
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if (k->mUTF8String) {
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bool err = false;
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return (CompareUTF8toUTF16(nsDependentCSubstring(
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k->mUTF8String, k->mUTF8String + k->mLength),
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nsDependentAtomString(he->mAtom), &err) == 0) &&
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!err;
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}
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return he->mAtom->Equals(k->mUTF16String, k->mLength);
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}
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void nsAtomTable::AtomTableClearEntry(PLDHashTable* aTable,
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PLDHashEntryHdr* aEntry) {
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auto entry = static_cast<AtomTableEntry*>(aEntry);
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entry->mAtom = nullptr;
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}
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static void AtomTableInitEntry(PLDHashEntryHdr* aEntry, const void* aKey) {
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static_cast<AtomTableEntry*>(aEntry)->mAtom = nullptr;
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}
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static const PLDHashTableOps AtomTableOps = {
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AtomTableGetHash, AtomTableMatchKey, PLDHashTable::MoveEntryStub,
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nsAtomTable::AtomTableClearEntry, AtomTableInitEntry};
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// The atom table very quickly gets 10,000+ entries in it (or even 100,000+).
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// But choosing the best initial subtable length has some subtleties: we add
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// ~2700 static atoms at start-up, and then we start adding and removing
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// dynamic atoms. If we make the tables too big to start with, when the first
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// dynamic atom gets removed from a given table the load factor will be < 25%
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// and we will shrink it.
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//
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// So we first make the simplifying assumption that the atoms are more or less
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// evenly-distributed across the subtables (which is the case empirically).
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// Then, we take the total atom count when the first dynamic atom is removed
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// (~2700), divide that across the N subtables, and the largest capacity that
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// will allow each subtable to be > 25% full with that count.
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//
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// So want an initial subtable capacity less than (2700 / N) * 4 = 10800 / N.
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// Rounding down to the nearest power of two gives us 8192 / N. Since the
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// capacity is double the initial length, we end up with (4096 / N) per
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// subtable.
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#define INITIAL_SUBTABLE_LENGTH (4096 / nsAtomTable::kNumSubTables)
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nsAtomSubTable& nsAtomTable::SelectSubTable(AtomTableKey& aKey) {
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// There are a few considerations around how we select subtables.
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//
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// First, we want entries to be evenly distributed across the subtables. This
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// can be achieved by using any bits in the hash key, assuming the key itself
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// is evenly-distributed. Empirical measurements indicate that this method
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// produces a roughly-even distribution across subtables.
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//
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// Second, we want to use the hash bits that are least likely to influence an
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// entry's position within the subtable. If we used the exact same bits used
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// by the subtables, then each subtable would compute the same position for
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// every entry it observes, leading to pessimal performance. In this case,
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// we're using PLDHashTable, whose primary hash function uses the N leftmost
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// bits of the hash value (where N is the log2 capacity of the table). This
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// means we should prefer the rightmost bits here.
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//
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// Note that the below is equivalent to mHash % kNumSubTables, a replacement
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// which an optimizing compiler should make, but let's avoid any doubt.
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static_assert((kNumSubTables & (kNumSubTables - 1)) == 0,
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"must be power of two");
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return mSubTables[aKey.mHash & (kNumSubTables - 1)];
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}
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void nsAtomTable::AddSizeOfIncludingThis(MallocSizeOf aMallocSizeOf,
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AtomsSizes& aSizes) {
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MOZ_ASSERT(NS_IsMainThread());
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aSizes.mTable += aMallocSizeOf(this);
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for (auto& table : mSubTables) {
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MutexAutoLock lock(table.mLock);
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table.AddSizeOfExcludingThisLocked(aMallocSizeOf, aSizes);
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}
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}
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void nsAtomTable::GC(GCKind aKind) {
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MOZ_ASSERT(NS_IsMainThread());
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sRecentlyUsedMainThreadAtoms.Clear();
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// Note that this is effectively an incremental GC, since only one subtable
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// is locked at a time.
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for (auto& table : mSubTables) {
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MutexAutoLock lock(table.mLock);
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table.GCLocked(aKind);
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}
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// We would like to assert that gUnusedAtomCount matches the number of atoms
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// we found in the table which we removed. However, there are two problems
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// with this:
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// * We have multiple subtables, each with their own lock. For optimal
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// performance we only want to hold one lock at a time, but this means
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// that atoms can be added and removed between GC slices.
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// * Even if we held all the locks and performed all GC slices atomically,
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// the locks are not acquired for AddRef() and Release() calls. This means
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// we might see a gUnusedAtomCount value in between, say, AddRef()
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// incrementing mRefCnt and it decrementing gUnusedAtomCount.
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//
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// So, we don't bother asserting that there are no unused atoms at the end of
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// a regular GC. But we can (and do) assert this just after the last GC at
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// shutdown.
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//
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// Note that, barring refcounting bugs, an atom can only go from a zero
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// refcount to a non-zero refcount while the atom table lock is held, so
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// so we won't try to resurrect a zero refcount atom while trying to delete
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// it.
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MOZ_ASSERT_IF(aKind == GCKind::Shutdown,
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nsDynamicAtom::gUnusedAtomCount == 0);
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}
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size_t nsAtomTable::RacySlowCount() {
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// Trigger a GC so that the result is deterministic modulo other threads.
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GC(GCKind::RegularOperation);
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size_t count = 0;
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for (auto& table : mSubTables) {
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MutexAutoLock lock(table.mLock);
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count += table.mTable.EntryCount();
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}
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return count;
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}
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nsAtomSubTable::nsAtomSubTable()
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: mLock("Atom Sub-Table Lock"),
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mTable(&AtomTableOps, sizeof(AtomTableEntry), INITIAL_SUBTABLE_LENGTH) {}
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void nsAtomSubTable::GCLocked(GCKind aKind) {
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MOZ_ASSERT(NS_IsMainThread());
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mLock.AssertCurrentThreadOwns();
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int32_t removedCount = 0; // A non-atomic temporary for cheaper increments.
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nsAutoCString nonZeroRefcountAtoms;
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uint32_t nonZeroRefcountAtomsCount = 0;
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for (auto i = mTable.Iter(); !i.Done(); i.Next()) {
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auto entry = static_cast<AtomTableEntry*>(i.Get());
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if (entry->mAtom->IsStatic()) {
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continue;
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}
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nsAtom* atom = entry->mAtom;
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if (atom->IsDynamic() && atom->AsDynamic()->mRefCnt == 0) {
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i.Remove();
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nsDynamicAtom::Destroy(atom->AsDynamic());
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++removedCount;
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}
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#ifdef NS_FREE_PERMANENT_DATA
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else if (aKind == GCKind::Shutdown && PR_GetEnv("XPCOM_MEM_BLOAT_LOG")) {
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// Only report leaking atoms in leak-checking builds in a run where we
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// are checking for leaks, during shutdown. If something is anomalous,
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// then we'll assert later in this function.
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nsAutoCString name;
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atom->ToUTF8String(name);
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if (nonZeroRefcountAtomsCount == 0) {
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nonZeroRefcountAtoms = name;
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} else if (nonZeroRefcountAtomsCount < 20) {
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nonZeroRefcountAtoms += ","_ns + name;
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} else if (nonZeroRefcountAtomsCount == 20) {
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nonZeroRefcountAtoms += ",..."_ns;
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}
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nonZeroRefcountAtomsCount++;
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}
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#endif
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}
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if (nonZeroRefcountAtomsCount) {
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nsPrintfCString msg("%d dynamic atom(s) with non-zero refcount: %s",
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nonZeroRefcountAtomsCount, nonZeroRefcountAtoms.get());
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NS_ASSERTION(nonZeroRefcountAtomsCount == 0, msg.get());
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}
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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) {
|
|
mLock.AssertCurrentThreadOwns();
|
|
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);
|
|
MutexAutoLock 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);
|
|
}
|
|
nsAtomSubTable& table = SelectSubTable(key);
|
|
MutexAutoLock lock(table.mLock);
|
|
AtomTableEntry* he = table.Add(key);
|
|
|
|
if (he->mAtom) {
|
|
RefPtr<nsAtom> atom = he->mAtom;
|
|
return atom.forget();
|
|
}
|
|
|
|
nsString str;
|
|
CopyUTF8toUTF16(aUTF8String, str);
|
|
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) {
|
|
MOZ_ASSERT(gAtomTable);
|
|
return gAtomTable->Atomize(nsDependentString(aUTF16String));
|
|
}
|
|
|
|
already_AddRefed<nsAtom> nsAtomTable::Atomize(const nsAString& aUTF16String) {
|
|
AtomTableKey key(aUTF16String.Data(), aUTF16String.Length());
|
|
nsAtomSubTable& table = SelectSubTable(key);
|
|
MutexAutoLock 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) {
|
|
MOZ_ASSERT(gAtomTable);
|
|
return gAtomTable->Atomize(aUTF16String);
|
|
}
|
|
|
|
already_AddRefed<nsAtom> nsAtomTable::AtomizeMainThread(
|
|
const nsAString& aUTF16String) {
|
|
MOZ_ASSERT(NS_IsMainThread());
|
|
RefPtr<nsAtom> retVal;
|
|
AtomTableKey key(aUTF16String.Data(), aUTF16String.Length());
|
|
auto p = sRecentlyUsedMainThreadAtoms.Lookup(key);
|
|
if (p) {
|
|
retVal = p.Data();
|
|
return retVal.forget();
|
|
}
|
|
|
|
nsAtomSubTable& table = SelectSubTable(key);
|
|
MutexAutoLock 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);
|
|
MutexAutoLock 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);
|
|
}
|