Merge pull request #2265 from FernandoS27/multilevelqueue

Replace old Thread Queue for a new Multi Level Queue
author: bunnei 2019-03-28 21:41:40 -0400
committer: GitHub 2019-03-28 21:41:40 -0400
commit: b404fcdf1443b91ac9994c05ad1fe039fcd9675e (patch)
tree: 42b6141dcd6a5315f9330f064524963a7915c28a /src/common/multi_level_queue.h
parent: Merge pull request #2284 from lioncash/heap-alloc (diff)
parent: Fixes and corrections on formatting. (diff)
download: yuzu-b404fcdf1443b91ac9994c05ad1fe039fcd9675e.tar.gz
yuzu-b404fcdf1443b91ac9994c05ad1fe039fcd9675e.tar.xz
yuzu-b404fcdf1443b91ac9994c05ad1fe039fcd9675e.zip
1 files changed, 337 insertions, 0 deletions
diff --git a/src/common/multi_level_queue.h b/src/common/multi_level_queue.h
new file mode 100644
index 000000000..2b61b91e0
--- /dev/null
+++ b/src/common/multi_level_queue.h
@@ -0,0 +1,337 @@
+// Copyright 2019 TuxSH
+// Licensed under GPLv2 or any later version
+// Refer to the license.txt file included.
+#pragma once
+#include <array>
+#include <iterator>
+#include <list>
+#include <utility>
+#include "common/bit_util.h"
+#include "common/common_types.h"
+namespace Common {
+/**
+ * A MultiLevelQueue is a type of priority queue which has the following characteristics:
+ * - iteratable through each of its elements.
+ * - back can be obtained.
+ * - O(1) add, lookup (both front and back)
+ * - discrete priorities and a max of 64 priorities (limited domain)
+ * This type of priority queue is normaly used for managing threads within an scheduler
+ */
+template <typename T, std::size_t Depth>
+class MultiLevelQueue {
+public:
+    using value_type = T;
+    using reference = value_type&;
+    using const_reference = const value_type&;
+    using pointer = value_type*;
+    using const_pointer = const value_type*;
+    using difference_type = typename std::pointer_traits<pointer>::difference_type;
+    using size_type = std::size_t;
+    template <bool is_constant>
+    class iterator_impl {
+    public:
+        using iterator_category = std::bidirectional_iterator_tag;
+        using value_type = T;
+        using pointer = std::conditional_t<is_constant, T*, const T*>;
+        using reference = std::conditional_t<is_constant, const T&, T&>;
+        using difference_type = typename std::pointer_traits<pointer>::difference_type;
+        friend bool operator==(const iterator_impl& lhs, const iterator_impl& rhs) {
+            if (lhs.IsEnd() && rhs.IsEnd())
+                return true;
+            return std::tie(lhs.current_priority, lhs.it) == std::tie(rhs.current_priority, rhs.it);
+        }
+        friend bool operator!=(const iterator_impl& lhs, const iterator_impl& rhs) {
+            return !operator==(lhs, rhs);
+        }
+        reference operator*() const {
+            return *it;
+        }
+        pointer operator->() const {
+            return it.operator->();
+        }
+        iterator_impl& operator++() {
+            if (IsEnd()) {
+                return *this;
+            }
+            ++it;
+            if (it == GetEndItForPrio()) {
+                u64 prios = mlq.used_priorities;
+                prios &= ~((1ULL << (current_priority + 1)) - 1);
+                if (prios == 0) {
+                    current_priority = mlq.depth();
+                } else {
+                    current_priority = CountTrailingZeroes64(prios);
+                    it = GetBeginItForPrio();
+                }
+            }
+            return *this;
+        }
+        iterator_impl& operator--() {
+            if (IsEnd()) {
+                if (mlq.used_priorities != 0) {
+                    current_priority = 63 - CountLeadingZeroes64(mlq.used_priorities);
+                    it = GetEndItForPrio();
+                    --it;
+                }
+            } else if (it == GetBeginItForPrio()) {
+                u64 prios = mlq.used_priorities;
+                prios &= (1ULL << current_priority) - 1;
+                if (prios != 0) {
+                    current_priority = CountTrailingZeroes64(prios);
+                    it = GetEndItForPrio();
+                    --it;
+                }
+            } else {
+                --it;
+            }
+            return *this;
+        }
+        iterator_impl operator++(int) {
+            const iterator_impl v{*this};
+            ++(*this);
+            return v;
+        }
+        iterator_impl operator--(int) {
+            const iterator_impl v{*this};
+            --(*this);
+            return v;
+        }
+        // allow implicit const->non-const
+        iterator_impl(const iterator_impl<false>& other)
+            : mlq(other.mlq), it(other.it), current_priority(other.current_priority) {}
+        iterator_impl(const iterator_impl<true>& other)
+            : mlq(other.mlq), it(other.it), current_priority(other.current_priority) {}
+        iterator_impl& operator=(const iterator_impl<false>& other) {
+            mlq = other.mlq;
+            it = other.it;
+            current_priority = other.current_priority;
+            return *this;
+        }
+        friend class iterator_impl<true>;
+        iterator_impl() = default;
+    private:
+        friend class MultiLevelQueue;
+        using container_ref =
+            std::conditional_t<is_constant, const MultiLevelQueue&, MultiLevelQueue&>;
+        using list_iterator = std::conditional_t<is_constant, typename std::list<T>::const_iterator,
+                                                 typename std::list<T>::iterator>;
+        explicit iterator_impl(container_ref mlq, list_iterator it, u32 current_priority)
+            : mlq(mlq), it(it), current_priority(current_priority) {}
+        explicit iterator_impl(container_ref mlq, u32 current_priority)
+            : mlq(mlq), it(), current_priority(current_priority) {}
+        bool IsEnd() const {
+            return current_priority == mlq.depth();
+        }
+        list_iterator GetBeginItForPrio() const {
+            return mlq.levels[current_priority].begin();
+        }
+        list_iterator GetEndItForPrio() const {
+            return mlq.levels[current_priority].end();
+        }
+        container_ref mlq;
+        list_iterator it;
+        u32 current_priority;
+    };
+    using iterator = iterator_impl<false>;
+    using const_iterator = iterator_impl<true>;
+    void add(const T& element, u32 priority, bool send_back = true) {
+        if (send_back)
+            levels[priority].push_back(element);
+        else
+            levels[priority].push_front(element);
+        used_priorities |= 1ULL << priority;
+    }
+    void remove(const T& element, u32 priority) {
+        auto it = ListIterateTo(levels[priority], element);
+        if (it == levels[priority].end())
+            return;
+        levels[priority].erase(it);
+        if (levels[priority].empty()) {
+            used_priorities &= ~(1ULL << priority);
+        }
+    }
+    void adjust(const T& element, u32 old_priority, u32 new_priority, bool adjust_front = false) {
+        remove(element, old_priority);
+        add(element, new_priority, !adjust_front);
+    }
+    void adjust(const_iterator it, u32 old_priority, u32 new_priority, bool adjust_front = false) {
+        adjust(*it, old_priority, new_priority, adjust_front);
+    }
+    void transfer_to_front(const T& element, u32 priority, MultiLevelQueue& other) {
+        ListSplice(other.levels[priority], other.levels[priority].begin(), levels[priority],
+                   ListIterateTo(levels[priority], element));
+        other.used_priorities |= 1ULL << priority;
+        if (levels[priority].empty()) {
+            used_priorities &= ~(1ULL << priority);
+        }
+    }
+    void transfer_to_front(const_iterator it, u32 priority, MultiLevelQueue& other) {
+        transfer_to_front(*it, priority, other);
+    }
+    void transfer_to_back(const T& element, u32 priority, MultiLevelQueue& other) {
+        ListSplice(other.levels[priority], other.levels[priority].end(), levels[priority],
+                   ListIterateTo(levels[priority], element));
+        other.used_priorities |= 1ULL << priority;
+        if (levels[priority].empty()) {
+            used_priorities &= ~(1ULL << priority);
+        }
+    }
+    void transfer_to_back(const_iterator it, u32 priority, MultiLevelQueue& other) {
+        transfer_to_back(*it, priority, other);
+    }
+    void yield(u32 priority, std::size_t n = 1) {
+        ListShiftForward(levels[priority], n);
+    }
+    std::size_t depth() const {
+        return Depth;
+    }
+    std::size_t size(u32 priority) const {
+        return levels[priority].size();
+    }
+    std::size_t size() const {
+        u64 priorities = used_priorities;
+        std::size_t size = 0;
+        while (priorities != 0) {
+            const u64 current_priority = CountTrailingZeroes64(priorities);
+            size += levels[current_priority].size();
+            priorities &= ~(1ULL << current_priority);
+        }
+        return size;
+    }
+    bool empty() const {
+        return used_priorities == 0;
+    }
+    bool empty(u32 priority) const {
+        return (used_priorities & (1ULL << priority)) == 0;
+    }
+    u32 highest_priority_set(u32 max_priority = 0) const {
+        const u64 priorities =
+            max_priority == 0 ? used_priorities : (used_priorities & ~((1ULL << max_priority) - 1));
+        return priorities == 0 ? Depth : static_cast<u32>(CountTrailingZeroes64(priorities));
+    }
+    u32 lowest_priority_set(u32 min_priority = Depth - 1) const {
+        const u64 priorities = min_priority >= Depth - 1
+                                   ? used_priorities
+                                   : (used_priorities & ((1ULL << (min_priority + 1)) - 1));
+        return priorities == 0 ? Depth : 63 - CountLeadingZeroes64(priorities);
+    }
+    const_iterator cbegin(u32 max_prio = 0) const {
+        const u32 priority = highest_priority_set(max_prio);
+        return priority == Depth ? cend()
+                                 : const_iterator{*this, levels[priority].cbegin(), priority};
+    }
+    const_iterator begin(u32 max_prio = 0) const {
+        return cbegin(max_prio);
+    }
+    iterator begin(u32 max_prio = 0) {
+        const u32 priority = highest_priority_set(max_prio);
+        return priority == Depth ? end() : iterator{*this, levels[priority].begin(), priority};
+    }
+    const_iterator cend(u32 min_prio = Depth - 1) const {
+        return min_prio == Depth - 1 ? const_iterator{*this, Depth} : cbegin(min_prio + 1);
+    }
+    const_iterator end(u32 min_prio = Depth - 1) const {
+        return cend(min_prio);
+    }
+    iterator end(u32 min_prio = Depth - 1) {
+        return min_prio == Depth - 1 ? iterator{*this, Depth} : begin(min_prio + 1);
+    }
+    T& front(u32 max_priority = 0) {
+        const u32 priority = highest_priority_set(max_priority);
+        return levels[priority == Depth ? 0 : priority].front();
+    }
+    const T& front(u32 max_priority = 0) const {
+        const u32 priority = highest_priority_set(max_priority);
+        return levels[priority == Depth ? 0 : priority].front();
+    }
+    T back(u32 min_priority = Depth - 1) {
+        const u32 priority = lowest_priority_set(min_priority); // intended
+        return levels[priority == Depth ? 63 : priority].back();
+    }
+    const T& back(u32 min_priority = Depth - 1) const {
+        const u32 priority = lowest_priority_set(min_priority); // intended
+        return levels[priority == Depth ? 63 : priority].back();
+    }
+private:
+    using const_list_iterator = typename std::list<T>::const_iterator;
+    static void ListShiftForward(std::list<T>& list, const std::size_t shift = 1) {
+        if (shift >= list.size()) {
+            return;
+        }
+        const auto begin_range = list.begin();
+        const auto end_range = std::next(begin_range, shift);
+        list.splice(list.end(), list, begin_range, end_range);
+    }
+    static void ListSplice(std::list<T>& in_list, const_list_iterator position,
+                           std::list<T>& out_list, const_list_iterator element) {
+        in_list.splice(position, out_list, element);
+    }
+    static const_list_iterator ListIterateTo(const std::list<T>& list, const T& element) {
+        auto it = list.cbegin();
+        while (it != list.cend() && *it != element) {
+            ++it;
+        }
+        return it;
+    }
+    std::array<std::list<T>, Depth> levels;
+    u64 used_priorities = 0;
+};
+} // namespace Common
author	bunnei	2019-03-28 21:41:40 -0400
committer	GitHub	2019-03-28 21:41:40 -0400
commit	b404fcdf1443b91ac9994c05ad1fe039fcd9675e (patch)
tree	42b6141dcd6a5315f9330f064524963a7915c28a /src/common/multi_level_queue.h
parent	Merge pull request #2284 from lioncash/heap-alloc (diff)
parent	Fixes and corrections on formatting. (diff)
download	yuzu-b404fcdf1443b91ac9994c05ad1fe039fcd9675e.tar.gz yuzu-b404fcdf1443b91ac9994c05ad1fe039fcd9675e.tar.xz yuzu-b404fcdf1443b91ac9994c05ad1fe039fcd9675e.zip

diff --git a/src/common/multi_level_queue.h b/src/common/multi_level_queue.h new file mode 100644 index 000000000..2b61b91e0 --- /dev/null +++ b/src/common/multi_level_queue.h
@@ -0,0 +1,337 @@
	1	// Copyright 2019 TuxSH
	2	// Licensed under GPLv2 or any later version
	3	// Refer to the license.txt file included.
	4
	5	#pragma once
	6
	7	#include <array>
	8	#include <iterator>
	9	#include <list>
	10	#include <utility>
	11
	12	#include "common/bit_util.h"
	13	#include "common/common_types.h"
	14
	15	namespace Common {
	16
	17	/**
	18	* A MultiLevelQueue is a type of priority queue which has the following characteristics:
	19	* - iteratable through each of its elements.
	20	* - back can be obtained.
	21	* - O(1) add, lookup (both front and back)
	22	* - discrete priorities and a max of 64 priorities (limited domain)
	23	* This type of priority queue is normaly used for managing threads within an scheduler
	24	*/
	25	template <typename T, std::size_t Depth>
	26	class MultiLevelQueue {
	27	public:
	28	using value_type = T;
	29	using reference = value_type&;
	30	using const_reference = const value_type&;
	31	using pointer = value_type*;
	32	using const_pointer = const value_type*;
	33
	34	using difference_type = typename std::pointer_traits<pointer>::difference_type;
	35	using size_type = std::size_t;
	36
	37	template <bool is_constant>
	38	class iterator_impl {
	39	public:
	40	using iterator_category = std::bidirectional_iterator_tag;
	41	using value_type = T;
	42	using pointer = std::conditional_t<is_constant, T, const T>;
	43	using reference = std::conditional_t<is_constant, const T&, T&>;
	44	using difference_type = typename std::pointer_traits<pointer>::difference_type;
	45
	46	friend bool operator==(const iterator_impl& lhs, const iterator_impl& rhs) {
	47	if (lhs.IsEnd() && rhs.IsEnd())
	48	return true;
	49	return std::tie(lhs.current_priority, lhs.it) == std::tie(rhs.current_priority, rhs.it);
	50	}
	51
	52	friend bool operator!=(const iterator_impl& lhs, const iterator_impl& rhs) {
	53	return !operator==(lhs, rhs);
	54	}
	55
	56	reference operator*() const {
	57	return *it;
	58	}
	59
	60	pointer operator->() const {
	61	return it.operator->();
	62	}
	63
	64	iterator_impl& operator++() {
	65	if (IsEnd()) {
	66	return *this;
	67	}
	68
	69	++it;
	70
	71	if (it == GetEndItForPrio()) {
	72	u64 prios = mlq.used_priorities;
	73	prios &= ~((1ULL << (current_priority + 1)) - 1);
	74	if (prios == 0) {
	75	current_priority = mlq.depth();
	76	} else {
	77	current_priority = CountTrailingZeroes64(prios);
	78	it = GetBeginItForPrio();
	79	}
	80	}
	81	return *this;
	82	}
	83
	84	iterator_impl& operator--() {
	85	if (IsEnd()) {
	86	if (mlq.used_priorities != 0) {
	87	current_priority = 63 - CountLeadingZeroes64(mlq.used_priorities);
	88	it = GetEndItForPrio();
	89	--it;
	90	}
	91	} else if (it == GetBeginItForPrio()) {
	92	u64 prios = mlq.used_priorities;
	93	prios &= (1ULL << current_priority) - 1;
	94	if (prios != 0) {
	95	current_priority = CountTrailingZeroes64(prios);
	96	it = GetEndItForPrio();
	97	--it;
	98	}
	99	} else {
	100	--it;
	101	}
	102	return *this;
	103	}
	104
	105	iterator_impl operator++(int) {
	106	const iterator_impl v{*this};
	107	++(*this);
	108	return v;
	109	}
	110
	111	iterator_impl operator--(int) {
	112	const iterator_impl v{*this};
	113	--(*this);
	114	return v;
	115	}
	116
	117	// allow implicit const->non-const
	118	iterator_impl(const iterator_impl<false>& other)
	119	: mlq(other.mlq), it(other.it), current_priority(other.current_priority) {}
	120
	121	iterator_impl(const iterator_impl<true>& other)
	122	: mlq(other.mlq), it(other.it), current_priority(other.current_priority) {}
	123
	124	iterator_impl& operator=(const iterator_impl<false>& other) {
	125	mlq = other.mlq;
	126	it = other.it;
	127	current_priority = other.current_priority;
	128	return *this;
	129	}
	130
	131	friend class iterator_impl<true>;
	132	iterator_impl() = default;
	133
	134	private:
	135	friend class MultiLevelQueue;
	136	using container_ref =
	137	std::conditional_t<is_constant, const MultiLevelQueue&, MultiLevelQueue&>;
	138	using list_iterator = std::conditional_t<is_constant, typename std::list<T>::const_iterator,
	139	typename std::list<T>::iterator>;
	140
	141	explicit iterator_impl(container_ref mlq, list_iterator it, u32 current_priority)
	142	: mlq(mlq), it(it), current_priority(current_priority) {}
	143	explicit iterator_impl(container_ref mlq, u32 current_priority)
	144	: mlq(mlq), it(), current_priority(current_priority) {}
	145
	146	bool IsEnd() const {
	147	return current_priority == mlq.depth();
	148	}
	149
	150	list_iterator GetBeginItForPrio() const {
	151	return mlq.levels[current_priority].begin();
	152	}
	153
	154	list_iterator GetEndItForPrio() const {
	155	return mlq.levels[current_priority].end();
	156	}
	157
	158	container_ref mlq;
	159	list_iterator it;
	160	u32 current_priority;
	161	};
	162
	163	using iterator = iterator_impl<false>;
	164	using const_iterator = iterator_impl<true>;
	165
	166	void add(const T& element, u32 priority, bool send_back = true) {
	167	if (send_back)
	168	levels[priority].push_back(element);
	169	else
	170	levels[priority].push_front(element);
	171	used_priorities \|= 1ULL << priority;
	172	}
	173
	174	void remove(const T& element, u32 priority) {
	175	auto it = ListIterateTo(levels[priority], element);
	176	if (it == levels[priority].end())
	177	return;
	178	levels[priority].erase(it);
	179	if (levels[priority].empty()) {
	180	used_priorities &= ~(1ULL << priority);
	181	}
	182	}
	183
	184	void adjust(const T& element, u32 old_priority, u32 new_priority, bool adjust_front = false) {
	185	remove(element, old_priority);
	186	add(element, new_priority, !adjust_front);
	187	}
	188	void adjust(const_iterator it, u32 old_priority, u32 new_priority, bool adjust_front = false) {
	189	adjust(*it, old_priority, new_priority, adjust_front);
	190	}
	191
	192	void transfer_to_front(const T& element, u32 priority, MultiLevelQueue& other) {
	193	ListSplice(other.levels[priority], other.levels[priority].begin(), levels[priority],
	194	ListIterateTo(levels[priority], element));
	195
	196	other.used_priorities \|= 1ULL << priority;
	197
	198	if (levels[priority].empty()) {
	199	used_priorities &= ~(1ULL << priority);
	200	}
	201	}
	202
	203	void transfer_to_front(const_iterator it, u32 priority, MultiLevelQueue& other) {
	204	transfer_to_front(*it, priority, other);
	205	}
	206
	207	void transfer_to_back(const T& element, u32 priority, MultiLevelQueue& other) {
	208	ListSplice(other.levels[priority], other.levels[priority].end(), levels[priority],
	209	ListIterateTo(levels[priority], element));
	210
	211	other.used_priorities \|= 1ULL << priority;
	212
	213	if (levels[priority].empty()) {
	214	used_priorities &= ~(1ULL << priority);
	215	}
	216	}
	217
	218	void transfer_to_back(const_iterator it, u32 priority, MultiLevelQueue& other) {
	219	transfer_to_back(*it, priority, other);
	220	}
	221
	222	void yield(u32 priority, std::size_t n = 1) {
	223	ListShiftForward(levels[priority], n);
	224	}
	225
	226	std::size_t depth() const {
	227	return Depth;
	228	}
	229
	230	std::size_t size(u32 priority) const {
	231	return levels[priority].size();
	232	}
	233
	234	std::size_t size() const {
	235	u64 priorities = used_priorities;
	236	std::size_t size = 0;
	237	while (priorities != 0) {
	238	const u64 current_priority = CountTrailingZeroes64(priorities);
	239	size += levels[current_priority].size();
	240	priorities &= ~(1ULL << current_priority);
	241	}
	242	return size;
	243	}
	244
	245	bool empty() const {
	246	return used_priorities == 0;
	247	}
	248
	249	bool empty(u32 priority) const {
	250	return (used_priorities & (1ULL << priority)) == 0;
	251	}
	252
	253	u32 highest_priority_set(u32 max_priority = 0) const {
	254	const u64 priorities =
	255	max_priority == 0 ? used_priorities : (used_priorities & ~((1ULL << max_priority) - 1));
	256	return priorities == 0 ? Depth : static_cast<u32>(CountTrailingZeroes64(priorities));
	257	}
	258
	259	u32 lowest_priority_set(u32 min_priority = Depth - 1) const {
	260	const u64 priorities = min_priority >= Depth - 1
	261	? used_priorities
	262	: (used_priorities & ((1ULL << (min_priority + 1)) - 1));
	263	return priorities == 0 ? Depth : 63 - CountLeadingZeroes64(priorities);
	264	}
	265
	266	const_iterator cbegin(u32 max_prio = 0) const {
	267	const u32 priority = highest_priority_set(max_prio);
	268	return priority == Depth ? cend()
	269	: const_iterator{*this, levels[priority].cbegin(), priority};
	270	}
	271	const_iterator begin(u32 max_prio = 0) const {
	272	return cbegin(max_prio);
	273	}
	274	iterator begin(u32 max_prio = 0) {
	275	const u32 priority = highest_priority_set(max_prio);
	276	return priority == Depth ? end() : iterator{*this, levels[priority].begin(), priority};
	277	}
	278
	279	const_iterator cend(u32 min_prio = Depth - 1) const {
	280	return min_prio == Depth - 1 ? const_iterator{*this, Depth} : cbegin(min_prio + 1);
	281	}
	282	const_iterator end(u32 min_prio = Depth - 1) const {
	283	return cend(min_prio);
	284	}
	285	iterator end(u32 min_prio = Depth - 1) {
	286	return min_prio == Depth - 1 ? iterator{*this, Depth} : begin(min_prio + 1);
	287	}
	288
	289	T& front(u32 max_priority = 0) {
	290	const u32 priority = highest_priority_set(max_priority);
	291	return levels[priority == Depth ? 0 : priority].front();
	292	}
	293	const T& front(u32 max_priority = 0) const {
	294	const u32 priority = highest_priority_set(max_priority);
	295	return levels[priority == Depth ? 0 : priority].front();
	296	}
	297
	298	T back(u32 min_priority = Depth - 1) {
	299	const u32 priority = lowest_priority_set(min_priority); // intended
	300	return levels[priority == Depth ? 63 : priority].back();
	301	}
	302	const T& back(u32 min_priority = Depth - 1) const {
	303	const u32 priority = lowest_priority_set(min_priority); // intended
	304	return levels[priority == Depth ? 63 : priority].back();
	305	}
	306
	307	private:
	308	using const_list_iterator = typename std::list<T>::const_iterator;
	309
	310	static void ListShiftForward(std::list<T>& list, const std::size_t shift = 1) {
	311	if (shift >= list.size()) {
	312	return;
	313	}
	314
	315	const auto begin_range = list.begin();
	316	const auto end_range = std::next(begin_range, shift);
	317	list.splice(list.end(), list, begin_range, end_range);
	318	}
	319
	320	static void ListSplice(std::list<T>& in_list, const_list_iterator position,
	321	std::list<T>& out_list, const_list_iterator element) {
	322	in_list.splice(position, out_list, element);
	323	}
	324
	325	static const_list_iterator ListIterateTo(const std::list<T>& list, const T& element) {
	326	auto it = list.cbegin();
	327	while (it != list.cend() && *it != element) {
	328	++it;
	329	}
	330	return it;
	331	}
	332
	333	std::array<std::list<T>, Depth> levels;
	334	u64 used_priorities = 0;
	335	};
	336
	337	} // namespace Common