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230 lines
6.5 KiB
C++
230 lines
6.5 KiB
C++
// 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_INTRUSIVE_HEAP_H_
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#define BASE_TASK_SEQUENCE_MANAGER_INTRUSIVE_HEAP_H_
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#include <algorithm>
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#include <vector>
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#include "base/logging.h"
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namespace base {
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namespace sequence_manager {
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namespace internal {
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template <typename T>
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class IntrusiveHeap;
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// Intended as an opaque wrapper around |index_|.
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class HeapHandle {
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public:
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HeapHandle() : index_(0u) {}
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bool IsValid() const { return index_ != 0u; }
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private:
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template <typename T>
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friend class IntrusiveHeap;
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HeapHandle(size_t index) : index_(index) {}
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size_t index_;
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};
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// A standard min-heap with the following assumptions:
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// 1. T has operator <=
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// 2. T has method void SetHeapHandle(HeapHandle handle)
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// 3. T has method void ClearHeapHandle()
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// 4. T is moveable
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// 5. T is default constructible
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// 6. The heap size never gets terribly big so reclaiming memory on pop/erase
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// isn't a priority.
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//
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// The reason IntrusiveHeap exists is to provide similar performance to
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// std::priority_queue while allowing removal of arbitrary elements.
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template <typename T>
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class IntrusiveHeap {
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public:
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IntrusiveHeap() : nodes_(kMinimumHeapSize), size_(0) {}
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~IntrusiveHeap() {
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for (size_t i = 1; i <= size_; i++) {
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MakeHole(i);
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}
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}
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bool empty() const { return size_ == 0; }
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size_t size() const { return size_; }
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void Clear() {
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for (size_t i = 1; i <= size_; i++) {
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MakeHole(i);
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}
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nodes_.resize(kMinimumHeapSize);
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size_ = 0;
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}
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const T& Min() const {
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DCHECK_GE(size_, 1u);
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return nodes_[1];
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}
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void Pop() {
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DCHECK_GE(size_, 1u);
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MakeHole(1u);
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size_t top_index = size_--;
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if (!empty())
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MoveHoleDownAndFillWithLeafElement(1u, std::move(nodes_[top_index]));
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}
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void insert(T&& element) {
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size_++;
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if (size_ >= nodes_.size())
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nodes_.resize(nodes_.size() * 2);
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// Notionally we have a hole in the tree at index |size_|, move this up
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// to find the right insertion point.
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MoveHoleUpAndFillWithElement(size_, std::move(element));
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}
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void erase(HeapHandle handle) {
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DCHECK_GT(handle.index_, 0u);
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DCHECK_LE(handle.index_, size_);
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MakeHole(handle.index_);
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size_t top_index = size_--;
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if (empty() || top_index == handle.index_)
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return;
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if (nodes_[handle.index_] <= nodes_[top_index]) {
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MoveHoleDownAndFillWithLeafElement(handle.index_,
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std::move(nodes_[top_index]));
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} else {
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MoveHoleUpAndFillWithElement(handle.index_, std::move(nodes_[top_index]));
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}
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}
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void ReplaceMin(T&& element) {
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// Note |element| might not be a leaf node so we can't use
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// MoveHoleDownAndFillWithLeafElement.
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MoveHoleDownAndFillWithElement(1u, std::move(element));
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}
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void ChangeKey(HeapHandle handle, T&& element) {
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if (nodes_[handle.index_] <= element) {
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MoveHoleDownAndFillWithLeafElement(handle.index_, std::move(element));
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} else {
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MoveHoleUpAndFillWithElement(handle.index_, std::move(element));
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}
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}
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// Caution mutating the heap invalidates the iterators.
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const T* begin() const { return &nodes_[1u]; }
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const T* end() const { return begin() + size_; }
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private:
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enum {
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// The majority of sets in the scheduler have 0-3 items in them (a few will
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// have perhaps up to 100), so this means we usually only have to allocate
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// memory once.
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kMinimumHeapSize = 4u
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};
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friend class IntrusiveHeapTest;
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size_t MoveHole(size_t new_hole_pos, size_t old_hole_pos) {
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DCHECK_GT(new_hole_pos, 0u);
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DCHECK_LE(new_hole_pos, size_);
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DCHECK_GT(new_hole_pos, 0u);
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DCHECK_LE(new_hole_pos, size_);
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DCHECK_NE(old_hole_pos, new_hole_pos);
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nodes_[old_hole_pos] = std::move(nodes_[new_hole_pos]);
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nodes_[old_hole_pos].SetHeapHandle(HeapHandle(old_hole_pos));
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return new_hole_pos;
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}
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// Notionally creates a hole in the tree at |index|.
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void MakeHole(size_t index) {
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DCHECK_GT(index, 0u);
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DCHECK_LE(index, size_);
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nodes_[index].ClearHeapHandle();
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}
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void FillHole(size_t hole, T&& element) {
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DCHECK_GT(hole, 0u);
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DCHECK_LE(hole, size_);
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nodes_[hole] = std::move(element);
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nodes_[hole].SetHeapHandle(HeapHandle(hole));
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DCHECK(std::is_heap(begin(), end(), CompareNodes));
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}
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// is_heap requires a strict comparator.
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static bool CompareNodes(const T& a, const T& b) { return !(a <= b); }
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// Moves the |hole| up the tree and when the right position has been found
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// |element| is moved in.
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void MoveHoleUpAndFillWithElement(size_t hole, T&& element) {
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DCHECK_GT(hole, 0u);
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DCHECK_LE(hole, size_);
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while (hole >= 2u) {
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size_t parent_pos = hole / 2;
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if (nodes_[parent_pos] <= element)
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break;
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hole = MoveHole(parent_pos, hole);
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}
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FillHole(hole, std::move(element));
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}
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// Moves the |hole| down the tree and when the right position has been found
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// |element| is moved in.
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void MoveHoleDownAndFillWithElement(size_t hole, T&& element) {
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DCHECK_GT(hole, 0u);
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DCHECK_LE(hole, size_);
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size_t child_pos = hole * 2;
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while (child_pos < size_) {
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if (nodes_[child_pos + 1] <= nodes_[child_pos])
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child_pos++;
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if (element <= nodes_[child_pos])
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break;
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hole = MoveHole(child_pos, hole);
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child_pos *= 2;
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}
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if (child_pos == size_ && !(element <= nodes_[child_pos]))
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hole = MoveHole(child_pos, hole);
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FillHole(hole, std::move(element));
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}
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// Moves the |hole| down the tree and when the right position has been found
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// |leaf_element| is moved in. Faster than MoveHoleDownAndFillWithElement
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// (it does one key comparison per level instead of two) but only valid for
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// leaf elements (i.e. one of the max values).
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void MoveHoleDownAndFillWithLeafElement(size_t hole, T&& leaf_element) {
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DCHECK_GT(hole, 0u);
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DCHECK_LE(hole, size_);
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size_t child_pos = hole * 2;
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while (child_pos < size_) {
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size_t second_child = child_pos + 1;
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if (nodes_[second_child] <= nodes_[child_pos])
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child_pos = second_child;
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hole = MoveHole(child_pos, hole);
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child_pos *= 2;
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}
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if (child_pos == size_)
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hole = MoveHole(child_pos, hole);
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MoveHoleUpAndFillWithElement(hole, std::move(leaf_element));
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}
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std::vector<T> nodes_; // NOTE we use 1-based indexing
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size_t size_;
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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_INTRUSIVE_HEAP_H_
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