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493 lines
9.4 KiB
C++
493 lines
9.4 KiB
C++
#pragma once
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#include "types.h"
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#include "Atomic.h"
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//! Simple sizeless array base for concurrent access. Cannot shrink, only growths automatically.
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//! There is no way to know the current size. The smaller index is, the faster it's accessed.
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//!
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//! T is the type of elements. Currently, default constructor of T shall be constexpr.
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//! N is initial element count, available without any memory allocation and only stored contiguously.
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template <typename T, std::size_t N>
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class lf_array
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{
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// Data (default-initialized)
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T m_data[N]{};
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// Next array block
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atomic_t<lf_array*> m_next{};
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public:
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constexpr lf_array() = default;
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~lf_array()
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{
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for (auto ptr = m_next.raw(); UNLIKELY(ptr);)
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{
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delete std::exchange(ptr, std::exchange(ptr->m_next.raw(), nullptr));
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}
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}
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T& operator [](std::size_t index)
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{
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if (LIKELY(index < N))
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{
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return m_data[index];
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}
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else if (UNLIKELY(!m_next))
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{
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// Create new array block. It's not a full-fledged once-synchronization, unlikely needed.
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for (auto _new = new lf_array, ptr = this; UNLIKELY(ptr);)
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{
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// Install the pointer. If failed, go deeper.
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ptr = ptr->m_next.compare_and_swap(nullptr, _new);
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}
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}
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// Access recursively
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return (*m_next)[index - N];
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}
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};
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//! Simple lock-free FIFO queue base. Based on lf_array<T, N> itself. Currently uses 32-bit counters.
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//! There is no "push_end" or "pop_begin" provided, the queue element must signal its state on its own.
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template<typename T, std::size_t N>
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class lf_fifo : public lf_array<T, N>
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{
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struct alignas(8) ctrl_t
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{
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u32 push;
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u32 pop;
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};
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atomic_t<ctrl_t> m_ctrl{};
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public:
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constexpr lf_fifo() = default;
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// Get current "push" position
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u32 size() const
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{
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return reinterpret_cast<const atomic_t<u32>&>(m_ctrl).load(); // Hack
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}
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// Acquire the place for one or more elements.
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u32 push_begin(u32 count = 1)
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{
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return reinterpret_cast<atomic_t<u32>&>(m_ctrl).fetch_add(count); // Hack
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}
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// Get current "pop" position
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u32 peek() const
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{
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return m_ctrl.load().pop;
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}
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// Acknowledge processed element, return number of the next one.
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// Perform clear if possible, zero is returned in this case.
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u32 pop_end(u32 count = 1)
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{
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return m_ctrl.atomic_op([&](ctrl_t& ctrl)
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{
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ctrl.pop += count;
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if (ctrl.pop == ctrl.push)
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{
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// Clean if possible
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ctrl.push = 0;
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ctrl.pop = 0;
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}
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return ctrl.pop;
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});
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}
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};
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//! Simple lock-free map. Based on lf_array<>. All elements are accessible, implicitly initialized.
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template<typename K, typename T, typename Hash = value_hash<K>, std::size_t Size = 256>
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class lf_hashmap
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{
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struct pair_t
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{
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// Default-constructed key means "no key"
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atomic_t<K> key{};
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T value{};
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};
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//
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lf_array<pair_t, Size> m_data{};
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// Value for default-constructed key
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T m_default_key_data{};
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public:
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constexpr lf_hashmap() = default;
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// Access element (added implicitly)
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T& operator [](const K& key)
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{
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if (UNLIKELY(key == K{}))
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{
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return m_default_key_data;
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}
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// Calculate hash and array position
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for (std::size_t pos = Hash{}(key) % Size;; pos += Size)
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{
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// Access the array
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auto& pair = m_data[pos];
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// Check the key value (optimistic)
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if (LIKELY(pair.key == key) || pair.key.compare_and_swap_test(K{}, key))
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{
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return pair.value;
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}
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}
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}
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};
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// Helper type, linked list element
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template <typename T>
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class lf_queue_item final
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{
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lf_queue_item* m_link = nullptr;
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T m_data;
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template <typename U>
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friend class lf_queue_iterator;
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template <typename U>
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friend class lf_queue_slice;
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template <typename U>
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friend class lf_queue;
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constexpr lf_queue_item() = default;
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template <typename... Args>
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constexpr lf_queue_item(lf_queue_item* link, Args&&... args)
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: m_link(link)
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, m_data(std::forward<Args>(args)...)
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{
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}
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public:
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lf_queue_item(const lf_queue_item&) = delete;
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lf_queue_item& operator=(const lf_queue_item&) = delete;
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~lf_queue_item()
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{
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for (lf_queue_item* ptr = m_link; ptr;)
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{
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delete std::exchange(ptr, std::exchange(ptr->m_link, nullptr));
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}
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}
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};
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// Forward iterator: non-owning pointer to the list element in lf_queue_slice<>
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template <typename T>
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class lf_queue_iterator
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{
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lf_queue_item<T>* m_ptr = nullptr;
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template <typename U>
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friend class lf_queue_slice;
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public:
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constexpr lf_queue_iterator() = default;
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bool operator ==(const lf_queue_iterator& rhs) const
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{
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return m_ptr == rhs.m_ptr;
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}
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bool operator !=(const lf_queue_iterator& rhs) const
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{
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return m_ptr != rhs.m_ptr;
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}
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T& operator *() const
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{
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return m_ptr->m_data;
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}
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T* operator ->() const
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{
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return &m_ptr->m_data;
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}
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lf_queue_iterator& operator ++()
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{
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m_ptr = m_ptr->m_link;
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return *this;
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}
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lf_queue_iterator operator ++(int)
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{
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lf_queue_iterator result;
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result.m_ptr = m_ptr;
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m_ptr = m_ptr->m_link;
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return result;
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}
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};
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// Owning pointer to the linked list taken from the lf_queue<>
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template <typename T>
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class lf_queue_slice
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{
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lf_queue_item<T>* m_head = nullptr;
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template <typename U>
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friend class lf_queue;
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public:
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constexpr lf_queue_slice() = default;
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lf_queue_slice(const lf_queue_slice&) = delete;
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lf_queue_slice(lf_queue_slice&& r) noexcept
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: m_head(r.m_head)
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{
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r.m_head = nullptr;
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}
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lf_queue_slice& operator =(const lf_queue_slice&) = delete;
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lf_queue_slice& operator =(lf_queue_slice&& r) noexcept
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{
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if (this != &r)
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{
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delete m_head;
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m_head = r.m_head;
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r.m_head = nullptr;
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}
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return *this;
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}
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~lf_queue_slice()
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{
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delete m_head;
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}
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T& operator *() const
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{
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return m_head->m_data;
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}
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T* operator ->() const
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{
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return &m_head->m_data;
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}
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explicit operator bool() const
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{
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return m_head != nullptr;
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}
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T* get() const
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{
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return m_head ? &m_head->m_data : nullptr;
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}
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lf_queue_iterator<T> begin() const
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{
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lf_queue_iterator<T> result;
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result.m_ptr = m_head;
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return result;
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}
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lf_queue_iterator<T> end() const
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{
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return {};
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}
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lf_queue_slice& pop_front()
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{
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delete std::exchange(m_head, std::exchange(m_head->m_link, nullptr));
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return *this;
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}
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};
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class lf_queue_base
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{
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protected:
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atomic_t<std::uintptr_t> m_head = 0;
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void imp_notify();
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public:
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// Wait for new elements pushed, no other thread shall call wait() or pop_all() simultaneously
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bool wait(u64 usec_timeout = -1);
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};
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// Linked list-based multi-producer queue (the consumer drains the whole queue at once)
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template <typename T>
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class lf_queue : public lf_queue_base
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{
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using lf_queue_base::m_head;
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// Extract all elements and reverse element order (FILO to FIFO)
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lf_queue_item<T>* reverse() noexcept
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{
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if (auto* head = m_head.load() ? reinterpret_cast<lf_queue_item<T>*>(m_head.exchange(0)) : nullptr)
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{
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if (auto* prev = head->m_link)
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{
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head->m_link = nullptr;
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do
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{
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auto* pprev = prev->m_link;
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prev->m_link = head;
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head = std::exchange(prev, pprev);
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}
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while (prev);
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}
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return head;
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}
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return nullptr;
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}
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public:
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constexpr lf_queue() = default;
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~lf_queue()
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{
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delete reinterpret_cast<lf_queue_item<T>*>(m_head.load());
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}
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template <typename... Args>
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void push(Args&&... args)
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{
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auto _old = m_head.load();
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auto* item = new lf_queue_item<T>(_old & 1 ? nullptr : reinterpret_cast<lf_queue_item<T>*>(_old), std::forward<Args>(args)...);
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while (!m_head.compare_exchange(_old, reinterpret_cast<std::uint64_t>(item)))
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{
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item->m_link = _old & 1 ? nullptr : reinterpret_cast<lf_queue_item<T>*>(_old);
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}
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if (_old & 1)
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{
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lf_queue_base::imp_notify();
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}
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}
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// Withdraw the list, supports range-for loop: for (auto&& x : y.pop_all()) ...
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lf_queue_slice<T> pop_all()
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{
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lf_queue_slice<T> result;
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result.m_head = reverse();
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return result;
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}
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// Apply func(data) to each element, return the total length
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template <typename F>
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std::size_t apply(F&& func)
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{
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std::size_t count = 0;
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for (auto slice = pop_all(); slice; slice.pop_front())
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{
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std::invoke(std::forward<F>(func), *slice);
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}
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return count;
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}
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// apply() overload for callable template argument
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template <auto F>
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std::size_t apply()
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{
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std::size_t count = 0;
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for (auto slice = pop_all(); slice; slice.pop_front())
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{
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std::invoke(F, *slice);
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}
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return count;
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}
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};
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// Assignable lock-free thread-safe value of any type (memory-inefficient)
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template <typename T>
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class lf_value final
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{
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atomic_t<lf_value*> m_head;
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T m_data;
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public:
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template <typename... Args>
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explicit constexpr lf_value(Args&&... args)
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: m_head(this)
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, m_data(std::forward<Args>(args)...)
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{
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}
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~lf_value()
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{
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// All values are kept in the queue until the end
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for (lf_value* ptr = m_head.load(); ptr != this;)
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{
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delete std::exchange(ptr, std::exchange(ptr->m_head.raw(), ptr));
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}
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}
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// Get current head, allows to inspect old values
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[[nodiscard]] const lf_value* head() const
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{
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return m_head.load();
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}
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// Inspect the initial (oldest) value
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[[nodiscard]] const T& first() const
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{
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return m_data;
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}
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[[nodiscard]] const T& get() const
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{
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return m_head.load()->m_data;
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}
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[[nodiscard]] operator const T&() const
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{
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return m_head.load()->m_data;
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}
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// Construct new value in-place
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template <typename... Args>
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const T& assign(Args&&... args)
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{
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lf_value* val = new lf_value(std::forward<Args>(args)...);
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lf_value* old = m_head.load();
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do
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{
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val->m_head = old;
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}
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while (!m_head.compare_exchange(old, val));
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return val->m_data;
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}
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// Copy-assign new value
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const T& operator =(const T& value)
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{
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return assign(value);
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}
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// Move-assign new value
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const T& operator =(T&& value)
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{
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return assign(std::move(value));
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}
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};
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