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*/
using System;
using System.Collections;
using System.Collections.Generic;
using System.Reflection;
using OpenSim.Framework;
using OpenSim.Framework.Client;
using log4net;
namespace OpenSim.Framework
{
public class PriorityQueue
{
// private static readonly ILog m_log = LogManager.GetLogger(MethodBase.GetCurrentMethod().DeclaringType);
public delegate bool UpdatePriorityHandler(ref uint priority, ISceneEntity entity);
///
/// Total number of queues (priorities) available
///
public const uint NumberOfQueues = 12; // includes immediate queues, m_queueCounts need to be set acording
///
/// Number of queuest (priorities) that are processed immediately
/// [] m_heaps = new MinHeap[NumberOfQueues];
private Dictionary m_lookupTable;
// internal state used to ensure the deqeues are spread across the priority
// queues "fairly". queuecounts is the amount to pull from each queue in
// each pass. weighted towards the higher priority queues
private uint m_nextQueue = 0;
private uint m_countFromQueue = 0;
// first queues are imediate, so no counts
// private uint[] m_queueCounts = { 0, 0, 8, 4, 4, 2, 2, 2, 2, 1, 1, 1 };
private uint[] m_queueCounts = {0, 0, 8, 8, 5, 4, 3, 2, 1, 1, 1, 1};
// this is ava, ava, attach, <10m, 20,40,80,160m,320,640,1280, +
// next request is a counter of the number of updates queued, it provides
// a total ordering on the updates coming through the queue and is more
// lightweight (and more discriminating) than tick count
private UInt64 m_nextRequest = 0;
///
/// Lock for enqueue and dequeue operations on the priority queue
///
private object m_syncRoot = new object();
public object SyncRoot {
get { return this.m_syncRoot; }
}
#region constructor
public PriorityQueue() : this(MinHeap.DEFAULT_CAPACITY) { }
public PriorityQueue(int capacity)
{
m_lookupTable = new Dictionary(capacity);
for (int i = 0; i < m_heaps.Length; ++i)
m_heaps[i] = new MinHeap(capacity);
m_nextQueue = NumberOfImmediateQueues;
m_countFromQueue = m_queueCounts[m_nextQueue];
}
#endregion Constructor
#region PublicMethods
///
/// Return the number of items in the queues
///
public int Count
{
get
{
int count = 0;
for (int i = 0; i < m_heaps.Length; ++i)
count += m_heaps[i].Count;
return count;
}
}
///
/// Enqueue an item into the specified priority queue
///
public bool Enqueue(uint pqueue, EntityUpdate value)
{
LookupItem lookup;
uint localid = value.Entity.LocalId;
UInt64 entry = m_nextRequest++;
if (m_lookupTable.TryGetValue(localid, out lookup))
{
entry = lookup.Heap[lookup.Handle].EntryOrder;
value.Update(lookup.Heap[lookup.Handle].Value);
lookup.Heap.Remove(lookup.Handle);
}
pqueue = Util.Clamp(pqueue, 0, NumberOfQueues - 1);
lookup.Heap = m_heaps[pqueue];
lookup.Heap.Add(new MinHeapItem(pqueue, entry, value), ref lookup.Handle);
m_lookupTable[localid] = lookup;
return true;
}
public void Remove(List ids)
{
LookupItem lookup;
foreach (uint localid in ids)
{
if (m_lookupTable.TryGetValue(localid, out lookup))
{
lookup.Heap.Remove(lookup.Handle);
m_lookupTable.Remove(localid);
}
}
}
///
/// Remove an item from one of the queues. Specifically, it removes the
/// oldest item from the next queue in order to provide fair access to
/// all of the queues
///
public bool TryDequeue(out EntityUpdate value, out Int32 timeinqueue)
{
// If there is anything in imediate queues, return it first no
// matter what else. Breaks fairness. But very useful.
for (int iq = 0; iq < NumberOfImmediateQueues; iq++)
{
if (m_heaps[iq].Count > 0)
{
MinHeapItem item = m_heaps[iq].RemoveMin();
m_lookupTable.Remove(item.Value.Entity.LocalId);
timeinqueue = Util.EnvironmentTickCountSubtract(item.EntryTime);
value = item.Value;
return true;
}
}
// To get the fair queing, we cycle through each of the
// queues when finding an element to dequeue.
// We pull (NumberOfQueues - QueueIndex) items from each queue in order
// to give lower numbered queues a higher priority and higher percentage
// of the bandwidth.
// Check for more items to be pulled from the current queue
if (m_heaps[m_nextQueue].Count > 0 && m_countFromQueue > 0)
{
m_countFromQueue--;
MinHeapItem item = m_heaps[m_nextQueue].RemoveMin();
m_lookupTable.Remove(item.Value.Entity.LocalId);
timeinqueue = Util.EnvironmentTickCountSubtract(item.EntryTime);
value = item.Value;
return true;
}
// Find the next non-immediate queue with updates in it
for (uint i = NumberOfImmediateQueues; i < NumberOfQueues; ++i)
{
m_nextQueue++;
if(m_nextQueue >= NumberOfQueues)
m_nextQueue = NumberOfImmediateQueues;
m_countFromQueue = m_queueCounts[m_nextQueue];
if (m_heaps[m_nextQueue].Count > 0)
{
m_countFromQueue--;
MinHeapItem item = m_heaps[m_nextQueue].RemoveMin();
m_lookupTable.Remove(item.Value.Entity.LocalId);
timeinqueue = Util.EnvironmentTickCountSubtract(item.EntryTime);
value = item.Value;
return true;
}
}
timeinqueue = 0;
value = default(EntityUpdate);
return false;
}
public bool TryOrderedDequeue(out EntityUpdate value, out Int32 timeinqueue)
{
// If there is anything in imediate queues, return it first no
// matter what else. Breaks fairness. But very useful.
for (int iq = 0; iq < NumberOfQueues; iq++)
{
if (m_heaps[iq].Count > 0)
{
MinHeapItem item = m_heaps[iq].RemoveMin();
m_lookupTable.Remove(item.Value.Entity.LocalId);
timeinqueue = Util.EnvironmentTickCountSubtract(item.EntryTime);
value = item.Value;
return true;
}
}
timeinqueue = 0;
value = default(EntityUpdate);
return false;
}
///
/// Reapply the prioritization function to each of the updates currently
/// stored in the priority queues.
/// (this.m_lookupTable.Values))
{
if (lookup.Heap.TryGetValue(lookup.Handle, out item))
{
uint pqueue = item.PriorityQueue;
uint localid = item.Value.Entity.LocalId;
if (handler(ref pqueue, item.Value.Entity))
{
// unless the priority queue has changed, there is no need to modify
// the entry
pqueue = Util.Clamp(pqueue, 0, NumberOfQueues - 1);
if (pqueue != item.PriorityQueue)
{
lookup.Heap.Remove(lookup.Handle);
LookupItem litem = lookup;
litem.Heap = m_heaps[pqueue];
litem.Heap.Add(new MinHeapItem(pqueue, item), ref litem.Handle);
m_lookupTable[localid] = litem;
}
}
else
{
// m_log.WarnFormat("[PQUEUE]: UpdatePriorityHandler returned false for {0}",item.Value.Entity.UUID);
lookup.Heap.Remove(lookup.Handle);
this.m_lookupTable.Remove(localid);
}
}
}
}
///
///
public override string ToString()
{
string s = "";
for (int i = 0; i < NumberOfQueues; i++)
s += String.Format("{0,7} ",m_heaps[i].Count);
return s;
}
#endregion PublicMethods
#region MinHeapItem
private struct MinHeapItem : IComparable
{
private EntityUpdate value;
internal EntityUpdate Value {
get {
return this.value;
}
}
private uint pqueue;
internal uint PriorityQueue {
get {
return this.pqueue;
}
}
private Int32 entrytime;
internal Int32 EntryTime {
get {
return this.entrytime;
}
}
private UInt64 entryorder;
internal UInt64 EntryOrder
{
get {
return this.entryorder;
}
}
internal MinHeapItem(uint pqueue, MinHeapItem other)
{
this.entrytime = other.entrytime;
this.entryorder = other.entryorder;
this.value = other.value;
this.pqueue = pqueue;
}
internal MinHeapItem(uint pqueue, UInt64 entryorder, EntityUpdate value)
{
this.entrytime = Util.EnvironmentTickCount();
this.entryorder = entryorder;
this.value = value;
this.pqueue = pqueue;
}
public override string ToString()
{
return String.Format("[{0},{1},{2}]",pqueue,entryorder,value.Entity.LocalId);
}
public int CompareTo(MinHeapItem other)
{
// I'm assuming that the root part of an SOG is added to the update queue
// before the component parts
return Comparer.Default.Compare(this.EntryOrder, other.EntryOrder);
}
}
#endregion
#region LookupItem
private struct LookupItem
{
internal MinHeap Heap;
internal IHandle Handle;
}
#endregion
}
}