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// Copyright (c) 2019 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef QUICHE_COMMON_QUICHE_CIRCULAR_DEQUE_H_
#define QUICHE_COMMON_QUICHE_CIRCULAR_DEQUE_H_
#include <algorithm>
#include <cstddef>
#include <cstring>
#include <iterator>
#include <memory>
#include <ostream>
#include <type_traits>
#include "common/platform/api/quiche_export.h"
#include "common/platform/api/quiche_logging.h"
namespace quiche {
// QuicheCircularDeque is a STL-style container that is similar to std::deque in
// API and std::vector in capacity management. The goal is to optimize a common
// QUIC use case where we keep adding new elements to the end and removing old
// elements from the beginning, under such scenarios, if the container's size()
// remain relatively stable, QuicheCircularDeque requires little to no memory
// allocations or deallocations.
//
// The implementation, as the name suggests, uses a flat circular buffer to hold
// all elements. At any point in time, either
// a) All elements are placed in a contiguous portion of this buffer, like a
// c-array, or
// b) Elements are phycially divided into two parts: the first part occupies the
// end of the buffer and the second part occupies the beginning of the
// buffer.
//
// Currently, elements can only be pushed or poped from either ends, it can't be
// inserted or erased in the middle.
//
// TODO(wub): Make memory grow/shrink strategies customizable.
template <typename T,
size_t MinCapacityIncrement = 3,
typename Allocator = std::allocator<T>>
class QUICHE_NO_EXPORT QuicheCircularDeque {
using AllocatorTraits = std::allocator_traits<Allocator>;
// Pointee is either T or const T.
template <typename Pointee>
class QUICHE_NO_EXPORT basic_iterator {
using size_type = typename AllocatorTraits::size_type;
public:
using iterator_category = std::random_access_iterator_tag;
using value_type = typename AllocatorTraits::value_type;
using difference_type = typename AllocatorTraits::difference_type;
using pointer = Pointee*;
using reference = Pointee&;
basic_iterator() = default;
// A copy constructor if Pointee is T.
// A conversion from iterator to const_iterator if Pointee is const T.
basic_iterator(
const basic_iterator<value_type>& it) // NOLINT(runtime/explicit)
: deque_(it.deque_), index_(it.index_) {}
// A copy assignment if Pointee is T.
// A assignment from iterator to const_iterator if Pointee is const T.
basic_iterator& operator=(const basic_iterator<value_type>& it) {
if (this != &it) {
deque_ = it.deque_;
index_ = it.index_;
}
return *this;
}
reference operator*() const { return *deque_->index_to_address(index_); }
pointer operator->() const { return deque_->index_to_address(index_); }
reference operator[](difference_type i) { return *(*this + i); }
basic_iterator& operator++() {
Increment();
return *this;
}
basic_iterator operator++(int) {
basic_iterator result = *this;
Increment();
return result;
}
basic_iterator operator--() {
Decrement();
return *this;
}
basic_iterator operator--(int) {
basic_iterator result = *this;
Decrement();
return result;
}
friend basic_iterator operator+(const basic_iterator& it,
difference_type delta) {
basic_iterator result = it;
result.IncrementBy(delta);
return result;
}
basic_iterator& operator+=(difference_type delta) {
IncrementBy(delta);
return *this;
}
friend basic_iterator operator-(const basic_iterator& it,
difference_type delta) {
basic_iterator result = it;
result.IncrementBy(-delta);
return result;
}
basic_iterator& operator-=(difference_type delta) {
IncrementBy(-delta);
return *this;
}
friend difference_type operator-(const basic_iterator& lhs,
const basic_iterator& rhs) {
return lhs.ExternalPosition() - rhs.ExternalPosition();
}
friend bool operator==(const basic_iterator& lhs,
const basic_iterator& rhs) {
return lhs.index_ == rhs.index_;
}
friend bool operator!=(const basic_iterator& lhs,
const basic_iterator& rhs) {
return !(lhs == rhs);
}
friend bool operator<(const basic_iterator& lhs,
const basic_iterator& rhs) {
return lhs.ExternalPosition() < rhs.ExternalPosition();
}
friend bool operator<=(const basic_iterator& lhs,
const basic_iterator& rhs) {
return !(lhs > rhs);
}
friend bool operator>(const basic_iterator& lhs,
const basic_iterator& rhs) {
return lhs.ExternalPosition() > rhs.ExternalPosition();
}
friend bool operator>=(const basic_iterator& lhs,
const basic_iterator& rhs) {
return !(lhs < rhs);
}
private:
basic_iterator(const QuicheCircularDeque* deque, size_type index)
: deque_(deque), index_(index) {}
void Increment() {
QUICHE_DCHECK_LE(ExternalPosition() + 1, deque_->size());
index_ = deque_->index_next(index_);
}
void Decrement() {
QUICHE_DCHECK_GE(ExternalPosition(), 1u);
index_ = deque_->index_prev(index_);
}
void IncrementBy(difference_type delta) {
if (delta >= 0) {
// After increment we are before or at end().
QUICHE_DCHECK_LE(static_cast<size_type>(ExternalPosition() + delta),
deque_->size());
} else {
// After decrement we are after or at begin().
QUICHE_DCHECK_GE(ExternalPosition(), static_cast<size_type>(-delta));
}
index_ = deque_->index_increment_by(index_, delta);
}
size_type ExternalPosition() const {
if (index_ >= deque_->begin_) {
return index_ - deque_->begin_;
}
return index_ + deque_->data_capacity() - deque_->begin_;
}
friend class QuicheCircularDeque;
const QuicheCircularDeque* deque_ = nullptr;
size_type index_ = 0;
};
public:
using allocator_type = typename AllocatorTraits::allocator_type;
using value_type = typename AllocatorTraits::value_type;
using size_type = typename AllocatorTraits::size_type;
using difference_type = typename AllocatorTraits::difference_type;
using reference = value_type&;
using const_reference = const value_type&;
using pointer = typename AllocatorTraits::pointer;
using const_pointer = typename AllocatorTraits::const_pointer;
using iterator = basic_iterator<T>;
using const_iterator = basic_iterator<const T>;
using reverse_iterator = std::reverse_iterator<iterator>;
using const_reverse_iterator = std::reverse_iterator<const_iterator>;
QuicheCircularDeque() : QuicheCircularDeque(allocator_type()) {}
explicit QuicheCircularDeque(const allocator_type& alloc)
: allocator_and_data_(alloc) {}
QuicheCircularDeque(size_type count,
const T& value,
const Allocator& alloc = allocator_type())
: allocator_and_data_(alloc) {
resize(count, value);
}
explicit QuicheCircularDeque(size_type count,
const Allocator& alloc = allocator_type())
: allocator_and_data_(alloc) {
resize(count);
}
template <
class InputIt,
typename = std::enable_if_t<std::is_base_of<
std::input_iterator_tag,
typename std::iterator_traits<InputIt>::iterator_category>::value>>
QuicheCircularDeque(InputIt first,
InputIt last,
const Allocator& alloc = allocator_type())
: allocator_and_data_(alloc) {
AssignRange(first, last);
}
QuicheCircularDeque(const QuicheCircularDeque& other)
: QuicheCircularDeque(
other,
AllocatorTraits::select_on_container_copy_construction(
other.allocator_and_data_.allocator())) {}
QuicheCircularDeque(const QuicheCircularDeque& other,
const allocator_type& alloc)
: allocator_and_data_(alloc) {
assign(other.begin(), other.end());
}
QuicheCircularDeque(QuicheCircularDeque&& other)
: begin_(other.begin_),
end_(other.end_),
allocator_and_data_(std::move(other.allocator_and_data_)) {
other.begin_ = other.end_ = 0;
other.allocator_and_data_.data = nullptr;
other.allocator_and_data_.data_capacity = 0;
}
QuicheCircularDeque(QuicheCircularDeque&& other, const allocator_type& alloc)
: allocator_and_data_(alloc) {
MoveRetainAllocator(std::move(other));
}
QuicheCircularDeque(std::initializer_list<T> init,
const allocator_type& alloc = allocator_type())
: QuicheCircularDeque(init.begin(), init.end(), alloc) {}
QuicheCircularDeque& operator=(const QuicheCircularDeque& other) {
if (this == &other) {
return *this;
}
if (AllocatorTraits::propagate_on_container_copy_assignment::value &&
(allocator_and_data_.allocator() !=
other.allocator_and_data_.allocator())) {
// Destroy all current elements and blocks with the current allocator,
// before switching this to use the allocator propagated from "other".
DestroyAndDeallocateAll();
begin_ = end_ = 0;
allocator_and_data_ =
AllocatorAndData(other.allocator_and_data_.allocator());
}
assign(other.begin(), other.end());
return *this;
}
QuicheCircularDeque& operator=(QuicheCircularDeque&& other) {
if (this == &other) {
return *this;
}
if (AllocatorTraits::propagate_on_container_move_assignment::value) {
// Take over the storage of "other", along with its allocator.
this->~QuicheCircularDeque();
new (this) QuicheCircularDeque(std::move(other));
} else {
MoveRetainAllocator(std::move(other));
}
return *this;
}
~QuicheCircularDeque() { DestroyAndDeallocateAll(); }
void assign(size_type count, const T& value) {
ClearRetainCapacity();
reserve(count);
for (size_t i = 0; i < count; ++i) {
emplace_back(value);
}
}
template <
class InputIt,
typename = std::enable_if_t<std::is_base_of<
std::input_iterator_tag,
typename std::iterator_traits<InputIt>::iterator_category>::value>>
void assign(InputIt first, InputIt last) {
AssignRange(first, last);
}
void assign(std::initializer_list<T> ilist) {
assign(ilist.begin(), ilist.end());
}
reference at(size_type pos) {
QUICHE_DCHECK(pos < size()) << "pos:" << pos << ", size():" << size();
size_type index = begin_ + pos;
if (index < data_capacity()) {
return *index_to_address(index);
}
return *index_to_address(index - data_capacity());
}
const_reference at(size_type pos) const {
return const_cast<QuicheCircularDeque*>(this)->at(pos);
}
reference operator[](size_type pos) { return at(pos); }
const_reference operator[](size_type pos) const { return at(pos); }
reference front() {
QUICHE_DCHECK(!empty());
return *index_to_address(begin_);
}
const_reference front() const {
return const_cast<QuicheCircularDeque*>(this)->front();
}
reference back() {
QUICHE_DCHECK(!empty());
return *(index_to_address(end_ == 0 ? data_capacity() - 1 : end_ - 1));
}
const_reference back() const {
return const_cast<QuicheCircularDeque*>(this)->back();
}
iterator begin() { return iterator(this, begin_); }
const_iterator begin() const { return const_iterator(this, begin_); }
const_iterator cbegin() const { return const_iterator(this, begin_); }
iterator end() { return iterator(this, end_); }
const_iterator end() const { return const_iterator(this, end_); }
const_iterator cend() const { return const_iterator(this, end_); }
reverse_iterator rbegin() { return reverse_iterator(end()); }
const_reverse_iterator rbegin() const {
return const_reverse_iterator(end());
}
const_reverse_iterator crbegin() const { return rbegin(); }
reverse_iterator rend() { return reverse_iterator(begin()); }
const_reverse_iterator rend() const {
return const_reverse_iterator(begin());
}
const_reverse_iterator crend() const { return rend(); }
size_type capacity() const {
return data_capacity() == 0 ? 0 : data_capacity() - 1;
}
void reserve(size_type new_cap) {
if (new_cap > capacity()) {
Relocate(new_cap);
}
}
// Remove all elements. Leave capacity unchanged.
void clear() { ClearRetainCapacity(); }
bool empty() const { return begin_ == end_; }
size_type size() const {
if (begin_ <= end_) {
return end_ - begin_;
}
return data_capacity() + end_ - begin_;
}
void resize(size_type count) { ResizeInternal(count); }
void resize(size_type count, const value_type& value) {
ResizeInternal(count, value);
}
void push_front(const T& value) { emplace_front(value); }
void push_front(T&& value) { emplace_front(std::move(value)); }
template <class... Args>
reference emplace_front(Args&&... args) {
MaybeExpandCapacity(1);
begin_ = index_prev(begin_);
new (index_to_address(begin_)) T(std::forward<Args>(args)...);
return front();
}
void push_back(const T& value) { emplace_back(value); }
void push_back(T&& value) { emplace_back(std::move(value)); }
template <class... Args>
reference emplace_back(Args&&... args) {
MaybeExpandCapacity(1);
new (index_to_address(end_)) T(std::forward<Args>(args)...);
end_ = index_next(end_);
return back();
}
void pop_front() {
QUICHE_DCHECK(!empty());
DestroyByIndex(begin_);
begin_ = index_next(begin_);
MaybeShrinkCapacity();
}
size_type pop_front_n(size_type count) {
size_type num_elements_to_pop = std::min(count, size());
size_type new_begin = index_increment_by(begin_, num_elements_to_pop);
DestroyRange(begin_, new_begin);
begin_ = new_begin;
MaybeShrinkCapacity();
return num_elements_to_pop;
}
void pop_back() {
QUICHE_DCHECK(!empty());
end_ = index_prev(end_);
DestroyByIndex(end_);
MaybeShrinkCapacity();
}
size_type pop_back_n(size_type count) {
size_type num_elements_to_pop = std::min(count, size());
size_type new_end = index_increment_by(end_, -num_elements_to_pop);
DestroyRange(new_end, end_);
end_ = new_end;
MaybeShrinkCapacity();
return num_elements_to_pop;
}
void swap(QuicheCircularDeque& other) {
using std::swap;
swap(begin_, other.begin_);
swap(end_, other.end_);
if (AllocatorTraits::propagate_on_container_swap::value) {
swap(allocator_and_data_, other.allocator_and_data_);
} else {
// When propagate_on_container_swap is false, it is undefined behavior, by
// c++ standard, to swap between two AllocatorAwareContainer(s) with
// unequal allocators.
QUICHE_DCHECK(get_allocator() == other.get_allocator())
<< "Undefined swap behavior";
swap(allocator_and_data_.data, other.allocator_and_data_.data);
swap(allocator_and_data_.data_capacity,
other.allocator_and_data_.data_capacity);
}
}
friend void swap(QuicheCircularDeque& lhs, QuicheCircularDeque& rhs) {
lhs.swap(rhs);
}
allocator_type get_allocator() const {
return allocator_and_data_.allocator();
}
friend bool operator==(const QuicheCircularDeque& lhs,
const QuicheCircularDeque& rhs) {
return std::equal(lhs.begin(), lhs.end(), rhs.begin(), rhs.end());
}
friend bool operator!=(const QuicheCircularDeque& lhs,
const QuicheCircularDeque& rhs) {
return !(lhs == rhs);
}
friend QUICHE_NO_EXPORT std::ostream& operator<<(
std::ostream& os,
const QuicheCircularDeque& dq) {
os << "{";
for (size_type pos = 0; pos != dq.size(); ++pos) {
if (pos != 0) {
os << ",";
}
os << " " << dq[pos];
}
os << " }";
return os;
}
private:
void MoveRetainAllocator(QuicheCircularDeque&& other) {
if (get_allocator() == other.get_allocator()) {
// Take over the storage of "other", with which we share an allocator.
DestroyAndDeallocateAll();
begin_ = other.begin_;
end_ = other.end_;
allocator_and_data_.data = other.allocator_and_data_.data;
allocator_and_data_.data_capacity =
other.allocator_and_data_.data_capacity;
other.begin_ = other.end_ = 0;
other.allocator_and_data_.data = nullptr;
other.allocator_and_data_.data_capacity = 0;
} else {
// We cannot take over of the storage from "other", since it has a
// different allocator; we're stuck move-assigning elements individually.
ClearRetainCapacity();
for (auto& elem : other) {
push_back(std::move(elem));
}
other.clear();
}
}
template <
typename InputIt,
typename = std::enable_if_t<std::is_base_of<
std::input_iterator_tag,
typename std::iterator_traits<InputIt>::iterator_category>::value>>
void AssignRange(InputIt first, InputIt last) {
ClearRetainCapacity();
if (std::is_base_of<
std::random_access_iterator_tag,
typename std::iterator_traits<InputIt>::iterator_category>::value) {
reserve(std::distance(first, last));
}
for (; first != last; ++first) {
emplace_back(*first);
}
}
// WARNING: begin_, end_ and allocator_and_data_ are not modified.
void DestroyAndDeallocateAll() {
DestroyRange(begin_, end_);
if (data_capacity() > 0) {
QUICHE_DCHECK_NE(nullptr, allocator_and_data_.data);
AllocatorTraits::deallocate(allocator_and_data_.allocator(),
allocator_and_data_.data, data_capacity());
}
}
void ClearRetainCapacity() {
DestroyRange(begin_, end_);
begin_ = end_ = 0;
}
void MaybeShrinkCapacity() {
// TODO(wub): Implement a storage policy that actually shrinks.
}
void MaybeExpandCapacity(size_t num_additional_elements) {
size_t new_size = size() + num_additional_elements;
if (capacity() >= new_size) {
return;
}
// The minimum amount of additional capacity to grow.
size_t min_additional_capacity =
std::max(MinCapacityIncrement, capacity() / 4);
size_t new_capacity =
std::max(new_size, capacity() + min_additional_capacity);
Relocate(new_capacity);
}
void Relocate(size_t new_capacity) {
const size_t num_elements = size();
QUICHE_DCHECK_GT(new_capacity, num_elements)
<< "new_capacity:" << new_capacity << ", num_elements:" << num_elements;
size_t new_data_capacity = new_capacity + 1;
pointer new_data = AllocatorTraits::allocate(
allocator_and_data_.allocator(), new_data_capacity);
if (begin_ < end_) {
// Not wrapped.
RelocateUnwrappedRange(begin_, end_, new_data);
} else if (begin_ > end_) {
// Wrapped.
const size_t num_elements_before_wrap = data_capacity() - begin_;
RelocateUnwrappedRange(begin_, data_capacity(), new_data);
RelocateUnwrappedRange(0, end_, new_data + num_elements_before_wrap);
}
if (data_capacity()) {
AllocatorTraits::deallocate(allocator_and_data_.allocator(),
allocator_and_data_.data, data_capacity());
}
allocator_and_data_.data = new_data;
allocator_and_data_.data_capacity = new_data_capacity;
begin_ = 0;
end_ = num_elements;
}
template <typename T_ = T>
typename std::enable_if<std::is_trivially_copyable<T_>::value, void>::type
RelocateUnwrappedRange(size_type begin, size_type end, pointer dest) const {
QUICHE_DCHECK_LE(begin, end) << "begin:" << begin << ", end:" << end;
pointer src = index_to_address(begin);
QUICHE_DCHECK_NE(src, nullptr);
memcpy(dest, src, sizeof(T) * (end - begin));
DestroyRange(begin, end);
}
template <typename T_ = T>
typename std::enable_if<!std::is_trivially_copyable<T_>::value &&
std::is_move_constructible<T_>::value,
void>::type
RelocateUnwrappedRange(size_type begin, size_type end, pointer dest) const {
QUICHE_DCHECK_LE(begin, end) << "begin:" << begin << ", end:" << end;
pointer src = index_to_address(begin);
pointer src_end = index_to_address(end);
while (src != src_end) {
new (dest) T(std::move(*src));
DestroyByAddress(src);
++dest;
++src;
}
}
template <typename T_ = T>
typename std::enable_if<!std::is_trivially_copyable<T_>::value &&
!std::is_move_constructible<T_>::value,
void>::type
RelocateUnwrappedRange(size_type begin, size_type end, pointer dest) const {
QUICHE_DCHECK_LE(begin, end) << "begin:" << begin << ", end:" << end;
pointer src = index_to_address(begin);
pointer src_end = index_to_address(end);
while (src != src_end) {
new (dest) T(*src);
DestroyByAddress(src);
++dest;
++src;
}
}
template <class... U>
void ResizeInternal(size_type count, U&&... u) {
if (count > size()) {
// Expanding.
MaybeExpandCapacity(count - size());
while (size() < count) {
emplace_back(std::forward<U>(u)...);
}
} else {
// Most likely shrinking. No-op if count == size().
size_type new_end = (begin_ + count) % data_capacity();
DestroyRange(new_end, end_);
end_ = new_end;
MaybeShrinkCapacity();
}
}
void DestroyRange(size_type begin, size_type end) const {
if (std::is_trivially_destructible<T>::value) {
return;
}
if (end >= begin) {
DestroyUnwrappedRange(begin, end);
} else {
DestroyUnwrappedRange(begin, data_capacity());
DestroyUnwrappedRange(0, end);
}
}
// Should only be called from DestroyRange.
void DestroyUnwrappedRange(size_type begin, size_type end) const {
QUICHE_DCHECK_LE(begin, end) << "begin:" << begin << ", end:" << end;
for (; begin != end; ++begin) {
DestroyByIndex(begin);
}
}
void DestroyByIndex(size_type index) const {
DestroyByAddress(index_to_address(index));
}
void DestroyByAddress(pointer address) const {
if (std::is_trivially_destructible<T>::value) {
return;
}
address->~T();
}
size_type data_capacity() const { return allocator_and_data_.data_capacity; }
pointer index_to_address(size_type index) const {
return allocator_and_data_.data + index;
}
size_type index_prev(size_type index) const {
return index == 0 ? data_capacity() - 1 : index - 1;
}
size_type index_next(size_type index) const {
return index == data_capacity() - 1 ? 0 : index + 1;
}
size_type index_increment_by(size_type index, difference_type delta) const {
if (delta == 0) {
return index;
}
QUICHE_DCHECK_LT(static_cast<size_type>(std::abs(delta)), data_capacity());
return (index + data_capacity() + delta) % data_capacity();
}
// Empty base-class optimization: bundle storage for our allocator together
// with the fields we had to store anyway, via inheriting from the allocator,
// so this allocator instance doesn't consume any storage when its type has no
// data members.
struct AllocatorAndData : private allocator_type {
explicit AllocatorAndData(const allocator_type& alloc)
: allocator_type(alloc) {}
const allocator_type& allocator() const { return *this; }
allocator_type& allocator() { return *this; }
pointer data = nullptr;
size_type data_capacity = 0;
};
size_type begin_ = 0;
size_type end_ = 0;
AllocatorAndData allocator_and_data_;
};
} // namespace quiche
#endif // QUICHE_COMMON_QUICHE_CIRCULAR_DEQUE_H_