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365 lines
9.2 KiB
C
365 lines
9.2 KiB
C
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// Copyright 2018 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#ifndef BASE_TASK_SEQUENCE_MANAGER_LAZILY_DEALLOCATED_DEQUE_H_
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#define BASE_TASK_SEQUENCE_MANAGER_LAZILY_DEALLOCATED_DEQUE_H_
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#include <algorithm>
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#include <cmath>
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#include <memory>
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#include <vector>
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#include "base/gtest_prod_util.h"
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#include "base/logging.h"
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#include "base/time/time.h"
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namespace base {
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namespace sequence_manager {
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namespace internal {
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// A LazilyDeallocatedDeque specialized for the SequenceManager's usage
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// patterns. The queue generally grows while tasks are added and then removed
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// until empty and the cycle repeats.
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//
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// The main difference between sequence_manager::LazilyDeallocatedDeque and
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// others is memory management. For performance (memory allocation isn't free)
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// we don't automatically reclaiming memory when the queue becomes empty.
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// Instead we rely on the surrounding code periodically calling
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// MaybeShrinkQueue, ideally when the queue is empty.
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//
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// We keep track of the maximum recent queue size and rate limit
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// MaybeShrinkQueue to avoid unnecessary churn.
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//
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// NB this queue isn't by itself thread safe.
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template <typename T>
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class LazilyDeallocatedDeque {
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public:
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enum {
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// Minimum allocation for a ring. Note a ring of size 4 will only hold up to
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// 3 elements.
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kMinimumRingSize = 4,
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// Maximum "wasted" capacity allowed when considering if we should resize
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// the backing store.
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kReclaimThreshold = 16,
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// Used to rate limit how frequently MaybeShrinkQueue actually shrinks the
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// queue.
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kMinimumShrinkIntervalInSeconds = 5
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};
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LazilyDeallocatedDeque() {}
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~LazilyDeallocatedDeque() { clear(); }
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bool empty() const { return size_ == 0; }
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size_t max_size() const { return max_size_; }
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size_t size() const { return size_; }
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size_t capacity() const {
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size_t capacity = 0;
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for (const Ring* iter = head_.get(); iter; iter = iter->next_.get()) {
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capacity += iter->capacity();
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}
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return capacity;
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}
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void clear() {
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while (head_) {
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head_ = std::move(head_->next_);
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}
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tail_ = nullptr;
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size_ = 0;
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}
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// Assumed to be an uncommon operation.
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void push_front(T t) {
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if (!head_) {
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head_ = std::make_unique<Ring>(kMinimumRingSize);
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tail_ = head_.get();
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}
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// Grow if needed, by the minimum amount.
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if (!head_->CanPush()) {
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std::unique_ptr<Ring> new_ring = std::make_unique<Ring>(kMinimumRingSize);
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new_ring->next_ = std::move(head_);
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head_ = std::move(new_ring);
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}
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head_->push_front(std::move(t));
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max_size_ = std::max(max_size_, ++size_);
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}
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// Assumed to be a common operation.
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void push_back(T t) {
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if (!head_) {
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head_ = std::make_unique<Ring>(kMinimumRingSize);
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tail_ = head_.get();
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}
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// Grow if needed.
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if (!tail_->CanPush()) {
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tail_->next_ = std::make_unique<Ring>(tail_->capacity() * 2);
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tail_ = tail_->next_.get();
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}
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tail_->push_back(std::move(t));
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max_size_ = std::max(max_size_, ++size_);
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}
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T& front() {
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DCHECK(head_);
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return head_->front();
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}
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const T& front() const {
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DCHECK(head_);
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return head_->front();
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}
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T& back() {
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DCHECK(tail_);
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return tail_->back();
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}
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const T& back() const {
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DCHECK(tail_);
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return tail_->back();
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}
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void pop_front() {
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DCHECK(tail_);
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DCHECK_GT(size_, 0u);
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head_->pop_front();
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// If the ring has become empty and we have several rings then, remove the
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// head one (which we expect to have lower capacity than the remaining
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// ones).
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if (head_->empty() && head_->next_) {
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head_ = std::move(head_->next_);
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}
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--size_;
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}
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void swap(LazilyDeallocatedDeque& other) {
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std::swap(head_, other.head_);
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std::swap(tail_, other.tail_);
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std::swap(size_, other.size_);
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std::swap(max_size_, other.max_size_);
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std::swap(next_resize_time_, other.next_resize_time_);
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}
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void MaybeShrinkQueue() {
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if (!tail_)
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return;
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DCHECK_GE(max_size_, size_);
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// Rate limit how often we shrink the queue because it's somewhat expensive.
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TimeTicks current_time = TimeTicks::Now();
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if (current_time < next_resize_time_)
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return;
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// Due to the way the Ring works we need 1 more slot than is used.
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size_t new_capacity = max_size_ + 1;
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if (new_capacity < kMinimumRingSize)
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new_capacity = kMinimumRingSize;
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// Reset |max_size_| so that unless usage has spiked up we will consider
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// reclaiming it next time.
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max_size_ = size_;
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// Only realloc if the current capacity is sufficiently the observed maximum
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// size for the previous period.
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if (new_capacity + kReclaimThreshold >= capacity())
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return;
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SetCapacity(new_capacity);
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next_resize_time_ =
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current_time + TimeDelta::FromSeconds(kMinimumShrinkIntervalInSeconds);
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}
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void SetCapacity(size_t new_capacity) {
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std::unique_ptr<Ring> new_ring = std::make_unique<Ring>(new_capacity);
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DCHECK_GE(new_capacity, size_ + 1);
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// Preserve the |size_| which counts down to zero in the while loop.
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size_t real_size = size_;
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while (!empty()) {
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DCHECK(new_ring->CanPush());
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new_ring->push_back(std::move(head_->front()));
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pop_front();
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}
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size_ = real_size;
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DCHECK_EQ(head_.get(), tail_);
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head_ = std::move(new_ring);
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tail_ = head_.get();
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}
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private:
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FRIEND_TEST_ALL_PREFIXES(LazilyDeallocatedDequeTest, RingPushFront);
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FRIEND_TEST_ALL_PREFIXES(LazilyDeallocatedDequeTest, RingPushBack);
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FRIEND_TEST_ALL_PREFIXES(LazilyDeallocatedDequeTest, RingCanPush);
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FRIEND_TEST_ALL_PREFIXES(LazilyDeallocatedDequeTest, RingPushPopPushPop);
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struct Ring {
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explicit Ring(size_t capacity)
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: capacity_(capacity),
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front_index_(0),
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back_index_(0),
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data_(reinterpret_cast<T*>(new char[sizeof(T) * capacity])),
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next_(nullptr) {
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DCHECK_GE(capacity_, kMinimumRingSize);
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}
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~Ring() {
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while (!empty()) {
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pop_front();
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}
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delete[] reinterpret_cast<char*>(data_);
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}
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bool empty() const { return back_index_ == front_index_; }
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size_t capacity() const { return capacity_; }
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bool CanPush() const {
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return front_index_ != CircularIncrement(back_index_);
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}
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void push_front(T&& t) {
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// Mustn't appear to become empty.
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DCHECK_NE(CircularDecrement(front_index_), back_index_);
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new (&data_[front_index_]) T(std::move(t));
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front_index_ = CircularDecrement(front_index_);
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}
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void push_back(T&& t) {
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back_index_ = CircularIncrement(back_index_);
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DCHECK(!empty()); // Mustn't appear to become empty.
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new (&data_[back_index_]) T(std::move(t));
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}
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bool CanPop() const { return front_index_ != back_index_; }
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void pop_front() {
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DCHECK(!empty());
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front_index_ = CircularIncrement(front_index_);
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data_[front_index_].~T();
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}
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T& front() {
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DCHECK(!empty());
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return data_[CircularIncrement(front_index_)];
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}
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const T& front() const {
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DCHECK(!empty());
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return data_[CircularIncrement(front_index_)];
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}
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T& back() {
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DCHECK(!empty());
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return data_[back_index_];
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}
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const T& back() const {
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DCHECK(!empty());
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return data_[back_index_];
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}
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size_t CircularDecrement(size_t index) const {
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if (index == 0)
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return capacity_ - 1;
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return index - 1;
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}
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size_t CircularIncrement(size_t index) const {
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DCHECK_LT(index, capacity_);
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++index;
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if (index == capacity_)
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return 0;
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return index;
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}
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size_t capacity_;
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size_t front_index_;
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size_t back_index_;
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T* data_;
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std::unique_ptr<Ring> next_;
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DISALLOW_COPY_AND_ASSIGN(Ring);
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};
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public:
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class Iterator {
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public:
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using value_type = T;
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using pointer = const T*;
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using reference = const T&;
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const T& operator->() const { return ring_->data_[index_]; }
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const T& operator*() const { return ring_->data_[index_]; }
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Iterator& operator++() {
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if (index_ == ring_->back_index_) {
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ring_ = ring_->next_.get();
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index_ = 0;
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} else {
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index_ = ring_->CircularIncrement(index_);
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}
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return *this;
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}
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operator bool() const { return !!ring_; }
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private:
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explicit Iterator(const Ring* ring) {
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if (!ring || ring->empty()) {
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ring_ = nullptr;
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index_ = 0;
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return;
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}
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ring_ = ring;
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index_ = ring_->CircularIncrement(ring->front_index_);
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}
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const Ring* ring_;
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size_t index_;
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friend class LazilyDeallocatedDeque;
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};
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Iterator begin() const { return Iterator(head_.get()); }
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Iterator end() const { return Iterator(nullptr); }
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private:
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// We maintain a list of Ring buffers, to enable us to grow without copying,
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// but most of the time we aim to have only one active Ring.
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std::unique_ptr<Ring> head_;
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Ring* tail_ = nullptr;
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size_t size_ = 0;
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size_t max_size_ = 0;
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TimeTicks next_resize_time_;
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DISALLOW_COPY_AND_ASSIGN(LazilyDeallocatedDeque);
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};
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} // namespace internal
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} // namespace sequence_manager
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} // namespace base
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#endif // BASE_TASK_SEQUENCE_MANAGER_LAZILY_DEALLOCATED_DEQUE_H_
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