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authorDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 09:22:09 +0000
committerDaniel Baumann <daniel.baumann@progress-linux.org>2024-04-07 09:22:09 +0000
commit43a97878ce14b72f0981164f87f2e35e14151312 (patch)
tree620249daf56c0258faa40cbdcf9cfba06de2a846 /mfbt/LinkedList.h
parentInitial commit. (diff)
downloadfirefox-upstream.tar.xz
firefox-upstream.zip
Adding upstream version 110.0.1.upstream/110.0.1upstream
Signed-off-by: Daniel Baumann <daniel.baumann@progress-linux.org>
Diffstat (limited to 'mfbt/LinkedList.h')
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diff --git a/mfbt/LinkedList.h b/mfbt/LinkedList.h
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+/* -*- 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/. */
+
+/* A type-safe doubly-linked list class. */
+
+/*
+ * The classes LinkedList<T> and LinkedListElement<T> together form a
+ * convenient, type-safe doubly-linked list implementation.
+ *
+ * The class T which will be inserted into the linked list must inherit from
+ * LinkedListElement<T>. A given object may be in only one linked list at a
+ * time.
+ *
+ * A LinkedListElement automatically removes itself from the list upon
+ * destruction, and a LinkedList will fatally assert in debug builds if it's
+ * non-empty when it's destructed.
+ *
+ * For example, you might use LinkedList in a simple observer list class as
+ * follows.
+ *
+ * class Observer : public LinkedListElement<Observer>
+ * {
+ * public:
+ * void observe(char* aTopic) { ... }
+ * };
+ *
+ * class ObserverContainer
+ * {
+ * private:
+ * LinkedList<Observer> list;
+ *
+ * public:
+ * void addObserver(Observer* aObserver)
+ * {
+ * // Will assert if |aObserver| is part of another list.
+ * list.insertBack(aObserver);
+ * }
+ *
+ * void removeObserver(Observer* aObserver)
+ * {
+ * // Will assert if |aObserver| is not part of some list.
+ * aObserver.remove();
+ * // Or, will assert if |aObserver| is not part of |list| specifically.
+ * // aObserver.removeFrom(list);
+ * }
+ *
+ * void notifyObservers(char* aTopic)
+ * {
+ * for (Observer* o = list.getFirst(); o != nullptr; o = o->getNext()) {
+ * o->observe(aTopic);
+ * }
+ * }
+ * };
+ *
+ * Additionally, the class AutoCleanLinkedList<T> is a LinkedList<T> that will
+ * remove and delete each element still within itself upon destruction. Note
+ * that because each element is deleted, elements must have been allocated
+ * using |new|.
+ */
+
+#ifndef mozilla_LinkedList_h
+#define mozilla_LinkedList_h
+
+#include <algorithm>
+#include <utility>
+
+#include "mozilla/Assertions.h"
+#include "mozilla/Attributes.h"
+#include "mozilla/MemoryReporting.h"
+#include "mozilla/RefPtr.h"
+
+#ifdef __cplusplus
+
+namespace mozilla {
+
+template <typename T>
+class LinkedListElement;
+
+namespace detail {
+
+/**
+ * LinkedList supports refcounted elements using this adapter class. Clients
+ * using LinkedList<RefPtr<T>> will get a data structure that holds a strong
+ * reference to T as long as T is in the list.
+ */
+template <typename T>
+struct LinkedListElementTraits {
+ typedef T* RawType;
+ typedef const T* ConstRawType;
+ typedef T* ClientType;
+ typedef const T* ConstClientType;
+
+ // These static methods are called when an element is added to or removed from
+ // a linked list. It can be used to keep track ownership in lists that are
+ // supposed to own their elements. If elements are transferred from one list
+ // to another, no enter or exit calls happen since the elements still belong
+ // to a list.
+ static void enterList(LinkedListElement<T>* elt) {}
+ static void exitList(LinkedListElement<T>* elt) {}
+
+ // This method is called when AutoCleanLinkedList cleans itself
+ // during destruction. It can be used to call delete on elements if
+ // the list is the sole owner.
+ static void cleanElement(LinkedListElement<T>* elt) { delete elt->asT(); }
+};
+
+template <typename T>
+struct LinkedListElementTraits<RefPtr<T>> {
+ typedef T* RawType;
+ typedef const T* ConstRawType;
+ typedef RefPtr<T> ClientType;
+ typedef RefPtr<const T> ConstClientType;
+
+ static void enterList(LinkedListElement<RefPtr<T>>* elt) {
+ elt->asT()->AddRef();
+ }
+ static void exitList(LinkedListElement<RefPtr<T>>* elt) {
+ elt->asT()->Release();
+ }
+ static void cleanElement(LinkedListElement<RefPtr<T>>* elt) {}
+};
+
+} /* namespace detail */
+
+template <typename T>
+class LinkedList;
+
+template <typename T>
+class LinkedListElement {
+ typedef typename detail::LinkedListElementTraits<T> Traits;
+ typedef typename Traits::RawType RawType;
+ typedef typename Traits::ConstRawType ConstRawType;
+ typedef typename Traits::ClientType ClientType;
+ typedef typename Traits::ConstClientType ConstClientType;
+
+ /*
+ * It's convenient that we return nullptr when getNext() or getPrevious()
+ * hits the end of the list, but doing so costs an extra word of storage in
+ * each linked list node (to keep track of whether |this| is the sentinel
+ * node) and a branch on this value in getNext/getPrevious.
+ *
+ * We could get rid of the extra word of storage by shoving the "is
+ * sentinel" bit into one of the pointers, although this would, of course,
+ * have performance implications of its own.
+ *
+ * But the goal here isn't to win an award for the fastest or slimmest
+ * linked list; rather, we want a *convenient* linked list. So we won't
+ * waste time guessing which micro-optimization strategy is best.
+ *
+ *
+ * Speaking of unnecessary work, it's worth addressing here why we wrote
+ * mozilla::LinkedList in the first place, instead of using stl::list.
+ *
+ * The key difference between mozilla::LinkedList and stl::list is that
+ * mozilla::LinkedList stores the mPrev/mNext pointers in the object itself,
+ * while stl::list stores the mPrev/mNext pointers in a list element which
+ * itself points to the object being stored.
+ *
+ * mozilla::LinkedList's approach makes it harder to store an object in more
+ * than one list. But the upside is that you can call next() / prev() /
+ * remove() directly on the object. With stl::list, you'd need to store a
+ * pointer to its iterator in the object in order to accomplish this. Not
+ * only would this waste space, but you'd have to remember to update that
+ * pointer every time you added or removed the object from a list.
+ *
+ * In-place, constant-time removal is a killer feature of doubly-linked
+ * lists, and supporting this painlessly was a key design criterion.
+ */
+
+ private:
+ LinkedListElement* mNext;
+ LinkedListElement* mPrev;
+ const bool mIsSentinel;
+
+ public:
+ LinkedListElement() : mNext(this), mPrev(this), mIsSentinel(false) {}
+
+ /*
+ * Moves |aOther| into |*this|. If |aOther| is already in a list, then
+ * |aOther| is removed from the list and replaced by |*this|.
+ */
+ LinkedListElement(LinkedListElement<T>&& aOther)
+ : mIsSentinel(aOther.mIsSentinel) {
+ adjustLinkForMove(std::move(aOther));
+ }
+
+ LinkedListElement& operator=(LinkedListElement<T>&& aOther) {
+ MOZ_ASSERT(mIsSentinel == aOther.mIsSentinel, "Mismatch NodeKind!");
+ MOZ_ASSERT(!isInList(),
+ "Assigning to an element in a list messes up that list!");
+ adjustLinkForMove(std::move(aOther));
+ return *this;
+ }
+
+ ~LinkedListElement() {
+ if (!mIsSentinel && isInList()) {
+ remove();
+ }
+ }
+
+ /*
+ * Get the next element in the list, or nullptr if this is the last element
+ * in the list.
+ */
+ RawType getNext() { return mNext->asT(); }
+ ConstRawType getNext() const { return mNext->asT(); }
+
+ /*
+ * Get the previous element in the list, or nullptr if this is the first
+ * element in the list.
+ */
+ RawType getPrevious() { return mPrev->asT(); }
+ ConstRawType getPrevious() const { return mPrev->asT(); }
+
+ /*
+ * Insert aElem after this element in the list. |this| must be part of a
+ * linked list when you call setNext(); otherwise, this method will assert.
+ */
+ void setNext(RawType aElem) {
+ MOZ_ASSERT(isInList());
+ setNextUnsafe(aElem);
+ }
+
+ /*
+ * Insert aElem before this element in the list. |this| must be part of a
+ * linked list when you call setPrevious(); otherwise, this method will
+ * assert.
+ */
+ void setPrevious(RawType aElem) {
+ MOZ_ASSERT(isInList());
+ setPreviousUnsafe(aElem);
+ }
+
+ /*
+ * Remove this element from the list which contains it. If this element is
+ * not currently part of a linked list, this method asserts.
+ */
+ void remove() {
+ MOZ_ASSERT(isInList());
+
+ mPrev->mNext = mNext;
+ mNext->mPrev = mPrev;
+ mNext = this;
+ mPrev = this;
+
+ Traits::exitList(this);
+ }
+
+ /*
+ * Remove this element from the list containing it. Returns a pointer to the
+ * element that follows this element (before it was removed). This method
+ * asserts if the element does not belong to a list. Note: In a refcounted
+ * list, |this| may be destroyed.
+ */
+ RawType removeAndGetNext() {
+ RawType r = getNext();
+ remove();
+ return r;
+ }
+
+ /*
+ * Remove this element from the list containing it. Returns a pointer to the
+ * previous element in the containing list (before the removal). This method
+ * asserts if the element does not belong to a list. Note: In a refcounted
+ * list, |this| may be destroyed.
+ */
+ RawType removeAndGetPrevious() {
+ RawType r = getPrevious();
+ remove();
+ return r;
+ }
+
+ /*
+ * Identical to remove(), but also asserts in debug builds that this element
+ * is in aList.
+ */
+ void removeFrom(const LinkedList<T>& aList) {
+ aList.assertContains(asT());
+ remove();
+ }
+
+ /*
+ * Return true if |this| part is of a linked list, and false otherwise.
+ */
+ bool isInList() const {
+ MOZ_ASSERT((mNext == this) == (mPrev == this));
+ return mNext != this;
+ }
+
+ private:
+ friend class LinkedList<T>;
+ friend struct detail::LinkedListElementTraits<T>;
+
+ enum class NodeKind { Normal, Sentinel };
+
+ explicit LinkedListElement(NodeKind nodeKind)
+ : mNext(this), mPrev(this), mIsSentinel(nodeKind == NodeKind::Sentinel) {}
+
+ /*
+ * Return |this| cast to T* if we're a normal node, or return nullptr if
+ * we're a sentinel node.
+ */
+ RawType asT() { return mIsSentinel ? nullptr : static_cast<RawType>(this); }
+ ConstRawType asT() const {
+ return mIsSentinel ? nullptr : static_cast<ConstRawType>(this);
+ }
+
+ /*
+ * Insert aElem after this element, but don't check that this element is in
+ * the list. This is called by LinkedList::insertFront().
+ */
+ void setNextUnsafe(RawType aElem) {
+ LinkedListElement* listElem = static_cast<LinkedListElement*>(aElem);
+ MOZ_RELEASE_ASSERT(!listElem->isInList());
+
+ listElem->mNext = this->mNext;
+ listElem->mPrev = this;
+ this->mNext->mPrev = listElem;
+ this->mNext = listElem;
+
+ Traits::enterList(aElem);
+ }
+
+ /*
+ * Insert aElem before this element, but don't check that this element is in
+ * the list. This is called by LinkedList::insertBack().
+ */
+ void setPreviousUnsafe(RawType aElem) {
+ LinkedListElement<T>* listElem = static_cast<LinkedListElement<T>*>(aElem);
+ MOZ_RELEASE_ASSERT(!listElem->isInList());
+
+ listElem->mNext = this;
+ listElem->mPrev = this->mPrev;
+ this->mPrev->mNext = listElem;
+ this->mPrev = listElem;
+
+ Traits::enterList(aElem);
+ }
+
+ /*
+ * Transfers the elements [aBegin, aEnd) before the "this" list element.
+ */
+ void transferBeforeUnsafe(LinkedListElement<T>& aBegin,
+ LinkedListElement<T>& aEnd) {
+ MOZ_RELEASE_ASSERT(!aBegin.mIsSentinel);
+ if (!aBegin.isInList() || !aEnd.isInList()) {
+ return;
+ }
+
+ auto otherPrev = aBegin.mPrev;
+
+ aBegin.mPrev = this->mPrev;
+ this->mPrev->mNext = &aBegin;
+ this->mPrev = aEnd.mPrev;
+ aEnd.mPrev->mNext = this;
+
+ // Patch the gap in the source list
+ otherPrev->mNext = &aEnd;
+ aEnd.mPrev = otherPrev;
+ }
+
+ /*
+ * Adjust mNext and mPrev for implementing move constructor and move
+ * assignment.
+ */
+ void adjustLinkForMove(LinkedListElement<T>&& aOther) {
+ if (!aOther.isInList()) {
+ mNext = this;
+ mPrev = this;
+ return;
+ }
+
+ if (!mIsSentinel) {
+ Traits::enterList(this);
+ }
+
+ MOZ_ASSERT(aOther.mNext->mPrev == &aOther);
+ MOZ_ASSERT(aOther.mPrev->mNext == &aOther);
+
+ /*
+ * Initialize |this| with |aOther|'s mPrev/mNext pointers, and adjust those
+ * element to point to this one.
+ */
+ mNext = aOther.mNext;
+ mPrev = aOther.mPrev;
+
+ mNext->mPrev = this;
+ mPrev->mNext = this;
+
+ /*
+ * Adjust |aOther| so it doesn't think it's in a list. This makes it
+ * safely destructable.
+ */
+ aOther.mNext = &aOther;
+ aOther.mPrev = &aOther;
+
+ if (!mIsSentinel) {
+ Traits::exitList(&aOther);
+ }
+ }
+
+ LinkedListElement& operator=(const LinkedListElement<T>& aOther) = delete;
+ LinkedListElement(const LinkedListElement<T>& aOther) = delete;
+};
+
+template <typename T>
+class LinkedList {
+ private:
+ typedef typename detail::LinkedListElementTraits<T> Traits;
+ typedef typename Traits::RawType RawType;
+ typedef typename Traits::ConstRawType ConstRawType;
+ typedef typename Traits::ClientType ClientType;
+ typedef typename Traits::ConstClientType ConstClientType;
+ typedef LinkedListElement<T>* ElementType;
+ typedef const LinkedListElement<T>* ConstElementType;
+
+ LinkedListElement<T> sentinel;
+
+ public:
+ template <typename Type, typename Element>
+ class Iterator {
+ Type mCurrent;
+
+ public:
+ using iterator_category = std::forward_iterator_tag;
+ using value_type = T;
+ using difference_type = std::ptrdiff_t;
+ using pointer = T*;
+ using reference = T&;
+
+ explicit Iterator(Type aCurrent) : mCurrent(aCurrent) {}
+
+ Type operator*() const { return mCurrent; }
+
+ const Iterator& operator++() {
+ mCurrent = static_cast<Element>(mCurrent)->getNext();
+ return *this;
+ }
+
+ bool operator!=(const Iterator& aOther) const {
+ return mCurrent != aOther.mCurrent;
+ }
+ };
+
+ LinkedList() : sentinel(LinkedListElement<T>::NodeKind::Sentinel) {}
+
+ LinkedList(LinkedList<T>&& aOther) : sentinel(std::move(aOther.sentinel)) {}
+
+ LinkedList& operator=(LinkedList<T>&& aOther) {
+ MOZ_ASSERT(isEmpty(),
+ "Assigning to a non-empty list leaks elements in that list!");
+ sentinel = std::move(aOther.sentinel);
+ return *this;
+ }
+
+ ~LinkedList() {
+# ifdef DEBUG
+ if (!isEmpty()) {
+ MOZ_CRASH_UNSAFE_PRINTF(
+ "%s has a buggy user: "
+ "it should have removed all this list's elements before "
+ "the list's destruction",
+ __PRETTY_FUNCTION__);
+ }
+# endif
+ }
+
+ /*
+ * Add aElem to the front of the list.
+ */
+ void insertFront(RawType aElem) {
+ /* Bypass setNext()'s this->isInList() assertion. */
+ sentinel.setNextUnsafe(aElem);
+ }
+
+ /*
+ * Add aElem to the back of the list.
+ */
+ void insertBack(RawType aElem) { sentinel.setPreviousUnsafe(aElem); }
+
+ /*
+ * Move all elements from another list to the back
+ */
+ void extendBack(LinkedList<T>&& aOther) {
+ MOZ_RELEASE_ASSERT(this != &aOther);
+ if (aOther.isEmpty()) {
+ return;
+ }
+ sentinel.transferBeforeUnsafe(**aOther.begin(), aOther.sentinel);
+ }
+
+ /*
+ * Move elements from another list to the specified position
+ */
+ void splice(size_t aDestinationPos, LinkedList<T>& aListFrom,
+ size_t aSourceStart, size_t aSourceLen) {
+ MOZ_RELEASE_ASSERT(this != &aListFrom);
+ if (aListFrom.isEmpty() || !aSourceLen) {
+ return;
+ }
+
+ const auto safeForward = [](LinkedList<T>& aList,
+ LinkedListElement<T>& aBegin,
+ size_t aPos) -> LinkedListElement<T>& {
+ auto* iter = &aBegin;
+ for (size_t i = 0; i < aPos; ++i, (iter = iter->mNext)) {
+ if (iter->mIsSentinel) {
+ break;
+ }
+ }
+ return *iter;
+ };
+
+ auto& sourceBegin =
+ safeForward(aListFrom, *aListFrom.sentinel.mNext, aSourceStart);
+ if (sourceBegin.mIsSentinel) {
+ return;
+ }
+ auto& sourceEnd = safeForward(aListFrom, sourceBegin, aSourceLen);
+ auto& destination = safeForward(*this, *sentinel.mNext, aDestinationPos);
+
+ destination.transferBeforeUnsafe(sourceBegin, sourceEnd);
+ }
+
+ /*
+ * Get the first element of the list, or nullptr if the list is empty.
+ */
+ RawType getFirst() { return sentinel.getNext(); }
+ ConstRawType getFirst() const { return sentinel.getNext(); }
+
+ /*
+ * Get the last element of the list, or nullptr if the list is empty.
+ */
+ RawType getLast() { return sentinel.getPrevious(); }
+ ConstRawType getLast() const { return sentinel.getPrevious(); }
+
+ /*
+ * Get and remove the first element of the list. If the list is empty,
+ * return nullptr.
+ */
+ ClientType popFirst() {
+ ClientType ret = sentinel.getNext();
+ if (ret) {
+ static_cast<LinkedListElement<T>*>(RawType(ret))->remove();
+ }
+ return ret;
+ }
+
+ /*
+ * Get and remove the last element of the list. If the list is empty,
+ * return nullptr.
+ */
+ ClientType popLast() {
+ ClientType ret = sentinel.getPrevious();
+ if (ret) {
+ static_cast<LinkedListElement<T>*>(RawType(ret))->remove();
+ }
+ return ret;
+ }
+
+ /*
+ * Return true if the list is empty, or false otherwise.
+ */
+ bool isEmpty() const { return !sentinel.isInList(); }
+
+ /**
+ * Returns whether the given element is in the list.
+ */
+ bool contains(ConstRawType aElm) const {
+ return std::find(begin(), end(), aElm) != end();
+ }
+
+ /*
+ * Remove all the elements from the list.
+ *
+ * This runs in time linear to the list's length, because we have to mark
+ * each element as not in the list.
+ */
+ void clear() {
+ while (popFirst()) {
+ }
+ }
+
+ /**
+ * Return the length of elements in the list.
+ */
+ size_t length() const { return std::distance(begin(), end()); }
+
+ /*
+ * Allow range-based iteration:
+ *
+ * for (MyElementType* elt : myList) { ... }
+ */
+ Iterator<RawType, ElementType> begin() {
+ return Iterator<RawType, ElementType>(getFirst());
+ }
+ Iterator<ConstRawType, ConstElementType> begin() const {
+ return Iterator<ConstRawType, ConstElementType>(getFirst());
+ }
+ Iterator<RawType, ElementType> end() {
+ return Iterator<RawType, ElementType>(nullptr);
+ }
+ Iterator<ConstRawType, ConstElementType> end() const {
+ return Iterator<ConstRawType, ConstElementType>(nullptr);
+ }
+
+ /*
+ * Measures the memory consumption of the list excluding |this|. Note that
+ * it only measures the list elements themselves. If the list elements
+ * contain pointers to other memory blocks, those blocks must be measured
+ * separately during a subsequent iteration over the list.
+ */
+ size_t sizeOfExcludingThis(MallocSizeOf aMallocSizeOf) const {
+ size_t n = 0;
+ ConstRawType t = getFirst();
+ while (t) {
+ n += aMallocSizeOf(t);
+ t = static_cast<const LinkedListElement<T>*>(t)->getNext();
+ }
+ return n;
+ }
+
+ /*
+ * Like sizeOfExcludingThis(), but measures |this| as well.
+ */
+ size_t sizeOfIncludingThis(MallocSizeOf aMallocSizeOf) const {
+ return aMallocSizeOf(this) + sizeOfExcludingThis(aMallocSizeOf);
+ }
+
+ /*
+ * In a debug build, make sure that the list is sane (no cycles, consistent
+ * mNext/mPrev pointers, only one sentinel). Has no effect in release builds.
+ */
+ void debugAssertIsSane() const {
+# ifdef DEBUG
+ const LinkedListElement<T>* slow;
+ const LinkedListElement<T>* fast1;
+ const LinkedListElement<T>* fast2;
+
+ /*
+ * Check for cycles in the forward singly-linked list using the
+ * tortoise/hare algorithm.
+ */
+ for (slow = sentinel.mNext, fast1 = sentinel.mNext->mNext,
+ fast2 = sentinel.mNext->mNext->mNext;
+ slow != &sentinel && fast1 != &sentinel && fast2 != &sentinel;
+ slow = slow->mNext, fast1 = fast2->mNext, fast2 = fast1->mNext) {
+ MOZ_ASSERT(slow != fast1);
+ MOZ_ASSERT(slow != fast2);
+ }
+
+ /* Check for cycles in the backward singly-linked list. */
+ for (slow = sentinel.mPrev, fast1 = sentinel.mPrev->mPrev,
+ fast2 = sentinel.mPrev->mPrev->mPrev;
+ slow != &sentinel && fast1 != &sentinel && fast2 != &sentinel;
+ slow = slow->mPrev, fast1 = fast2->mPrev, fast2 = fast1->mPrev) {
+ MOZ_ASSERT(slow != fast1);
+ MOZ_ASSERT(slow != fast2);
+ }
+
+ /*
+ * Check that |sentinel| is the only node in the list with
+ * mIsSentinel == true.
+ */
+ for (const LinkedListElement<T>* elem = sentinel.mNext; elem != &sentinel;
+ elem = elem->mNext) {
+ MOZ_ASSERT(!elem->mIsSentinel);
+ }
+
+ /* Check that the mNext/mPrev pointers match up. */
+ const LinkedListElement<T>* prev = &sentinel;
+ const LinkedListElement<T>* cur = sentinel.mNext;
+ do {
+ MOZ_ASSERT(cur->mPrev == prev);
+ MOZ_ASSERT(prev->mNext == cur);
+
+ prev = cur;
+ cur = cur->mNext;
+ } while (cur != &sentinel);
+# endif /* ifdef DEBUG */
+ }
+
+ private:
+ friend class LinkedListElement<T>;
+
+ void assertContains(const RawType aValue) const {
+# ifdef DEBUG
+ for (ConstRawType elem = getFirst(); elem; elem = elem->getNext()) {
+ if (elem == aValue) {
+ return;
+ }
+ }
+ MOZ_CRASH("element wasn't found in this list!");
+# endif
+ }
+
+ LinkedList& operator=(const LinkedList<T>& aOther) = delete;
+ LinkedList(const LinkedList<T>& aOther) = delete;
+};
+
+template <typename T>
+inline void ImplCycleCollectionUnlink(LinkedList<RefPtr<T>>& aField) {
+ aField.clear();
+}
+
+template <typename T>
+inline void ImplCycleCollectionTraverse(
+ nsCycleCollectionTraversalCallback& aCallback,
+ LinkedList<RefPtr<T>>& aField, const char* aName, uint32_t aFlags = 0) {
+ typedef typename detail::LinkedListElementTraits<T> Traits;
+ typedef typename Traits::RawType RawType;
+ for (RawType element : aField) {
+ // RefPtr is stored as a raw pointer in LinkedList.
+ // So instead of creating a new RefPtr from the raw
+ // pointer (which is not allowed), we simply call
+ // CycleCollectionNoteChild against the raw pointer
+ CycleCollectionNoteChild(aCallback, element, aName, aFlags);
+ }
+}
+
+template <typename T>
+class AutoCleanLinkedList : public LinkedList<T> {
+ private:
+ using Traits = detail::LinkedListElementTraits<T>;
+ using ClientType = typename detail::LinkedListElementTraits<T>::ClientType;
+
+ public:
+ AutoCleanLinkedList() = default;
+ AutoCleanLinkedList(AutoCleanLinkedList&&) = default;
+ ~AutoCleanLinkedList() { clear(); }
+
+ AutoCleanLinkedList& operator=(AutoCleanLinkedList&& aOther) = default;
+
+ void clear() {
+ while (ClientType element = this->popFirst()) {
+ Traits::cleanElement(element);
+ }
+ }
+};
+
+} /* namespace mozilla */
+
+#endif /* __cplusplus */
+
+#endif /* mozilla_LinkedList_h */