Good question. When writing high performance software embracing zero allocation patterns by using a fast object pool is critical.
Microsoft released an object pool under Apache License 2.0
It avoids using locks and only uses Interlocked.CompareExchange for Allocations (Get). It seems particularly fast when you get and release few objects at a time which is most use cases. It seems less optimized if you get a large batch of objects, then release the batch so if your application behaves like that you should modify.
I think the Interlocked.Increment approach, as you suggested, could be more general and work better for the batch use cases.
http://sourceroslyn.io/#Microsoft.CodeAnalysis.Workspaces/ObjectPool%25601.cs,98aa6d9b3c4e313b
// Copyright (c) Microsoft. All Rights Reserved. Licensed under the Apache License, Version 2.0. See License.txt in the project root for license information.
// define TRACE_LEAKS to get additional diagnostics that can lead to the leak sources. note: it will
// make everything about 2-3x slower
//
// #define TRACE_LEAKS
// define DETECT_LEAKS to detect possible leaks
// #if DEBUG
// #define DETECT_LEAKS //for now always enable DETECT_LEAKS in debug.
// #endif
using System;
using System.Diagnostics;
using System.Threading;
#if DETECT_LEAKS
using System.Runtime.CompilerServices;
#endif
namespace Microsoft.CodeAnalysis.PooledObjects
{
/// <summary>
/// Generic implementation of object pooling pattern with predefined pool size limit. The main
/// purpose is that limited number of frequently used objects can be kept in the pool for
/// further recycling.
///
/// Notes:
/// 1) it is not the goal to keep all returned objects. Pool is not meant for storage. If there
/// is no space in the pool, extra returned objects will be dropped.
///
/// 2) it is implied that if object was obtained from a pool, the caller will return it back in
/// a relatively short time. Keeping checked out objects for long durations is ok, but
/// reduces usefulness of pooling. Just new up your own.
///
/// Not returning objects to the pool in not detrimental to the pool's work, but is a bad practice.
/// Rationale:
/// If there is no intent for reusing the object, do not use pool - just use "new".
/// </summary>
internal class ObjectPool<T> where T : class
{
[DebuggerDisplay("{Value,nq}")]
private struct Element
{
internal T Value;
}
/// <remarks>
/// Not using System.Func{T} because this file is linked into the (debugger) Formatter,
/// which does not have that type (since it compiles against .NET 2.0).
/// </remarks>
internal delegate T Factory();
// Storage for the pool objects. The first item is stored in a dedicated field because we
// expect to be able to satisfy most requests from it.
private T _firstItem;
private readonly Element[] _items;
// factory is stored for the lifetime of the pool. We will call this only when pool needs to
// expand. compared to "new T()", Func gives more flexibility to implementers and faster
// than "new T()".
private readonly Factory _factory;
#if DETECT_LEAKS
private static readonly ConditionalWeakTable<T, LeakTracker> leakTrackers = new ConditionalWeakTable<T, LeakTracker>();
private class LeakTracker : IDisposable
{
private volatile bool disposed;
#if TRACE_LEAKS
internal volatile object Trace = null;
#endif
public void Dispose()
{
disposed = true;
GC.SuppressFinalize(this);
}
private string GetTrace()
{
#if TRACE_LEAKS
return Trace == null ? "" : Trace.ToString();
#else
return "Leak tracing information is disabled. Define TRACE_LEAKS on ObjectPool`1.cs to get more info \n";
#endif
}
~LeakTracker()
{
if (!this.disposed && !Environment.HasShutdownStarted)
{
var trace = GetTrace();
// If you are seeing this message it means that object has been allocated from the pool
// and has not been returned back. This is not critical, but turns pool into rather
// inefficient kind of "new".
Debug.WriteLine($"TRACEOBJECTPOOLLEAKS_BEGIN\nPool detected potential leaking of {typeof(T)}. \n Location of the leak: \n {GetTrace()} TRACEOBJECTPOOLLEAKS_END");
}
}
}
#endif
internal ObjectPool(Factory factory)
: this(factory, Environment.ProcessorCount * 2)
{ }
internal ObjectPool(Factory factory, int size)
{
Debug.Assert(size >= 1);
_factory = factory;
_items = new Element[size - 1];
}
private T CreateInstance()
{
var inst = _factory();
return inst;
}
/// <summary>
/// Produces an instance.
/// </summary>
/// <remarks>
/// Search strategy is a simple linear probing which is chosen for it cache-friendliness.
/// Note that Free will try to store recycled objects close to the start thus statistically
/// reducing how far we will typically search.
/// </remarks>
internal T Allocate()
{
// PERF: Examine the first element. If that fails, AllocateSlow will look at the remaining elements.
// Note that the initial read is optimistically not synchronized. That is intentional.
// We will interlock only when we have a candidate. in a worst case we may miss some
// recently returned objects. Not a big deal.
T inst = _firstItem;
if (inst == null || inst != Interlocked.CompareExchange(ref _firstItem, null, inst))
{
inst = AllocateSlow();
}
#if DETECT_LEAKS
var tracker = new LeakTracker();
leakTrackers.Add(inst, tracker);
#if TRACE_LEAKS
var frame = CaptureStackTrace();
tracker.Trace = frame;
#endif
#endif
return inst;
}
private T AllocateSlow()
{
var items = _items;
for (int i = 0; i < items.Length; i++)
{
// Note that the initial read is optimistically not synchronized. That is intentional.
// We will interlock only when we have a candidate. in a worst case we may miss some
// recently returned objects. Not a big deal.
T inst = items[i].Value;
if (inst != null)
{
if (inst == Interlocked.CompareExchange(ref items[i].Value, null, inst))
{
return inst;
}
}
}
return CreateInstance();
}
/// <summary>
/// Returns objects to the pool.
/// </summary>
/// <remarks>
/// Search strategy is a simple linear probing which is chosen for it cache-friendliness.
/// Note that Free will try to store recycled objects close to the start thus statistically
/// reducing how far we will typically search in Allocate.
/// </remarks>
internal void Free(T obj)
{
Validate(obj);
ForgetTrackedObject(obj);
if (_firstItem == null)
{
// Intentionally not using interlocked here.
// In a worst case scenario two objects may be stored into same slot.
// It is very unlikely to happen and will only mean that one of the objects will get collected.
_firstItem = obj;
}
else
{
FreeSlow(obj);
}
}
private void FreeSlow(T obj)
{
var items = _items;
for (int i = 0; i < items.Length; i++)
{
if (items[i].Value == null)
{
// Intentionally not using interlocked here.
// In a worst case scenario two objects may be stored into same slot.
// It is very unlikely to happen and will only mean that one of the objects will get collected.
items[i].Value = obj;
break;
}
}
}
/// <summary>
/// Removes an object from leak tracking.
///
/// This is called when an object is returned to the pool. It may also be explicitly
/// called if an object allocated from the pool is intentionally not being returned
/// to the pool. This can be of use with pooled arrays if the consumer wants to
/// return a larger array to the pool than was originally allocated.
/// </summary>
[Conditional("DEBUG")]
internal void ForgetTrackedObject(T old, T replacement = null)
{
#if DETECT_LEAKS
LeakTracker tracker;
if (leakTrackers.TryGetValue(old, out tracker))
{
tracker.Dispose();
leakTrackers.Remove(old);
}
else
{
var trace = CaptureStackTrace();
Debug.WriteLine($"TRACEOBJECTPOOLLEAKS_BEGIN\nObject of type {typeof(T)} was freed, but was not from pool. \n Callstack: \n {trace} TRACEOBJECTPOOLLEAKS_END");
}
if (replacement != null)
{
tracker = new LeakTracker();
leakTrackers.Add(replacement, tracker);
}
#endif
}
#if DETECT_LEAKS
private static Lazy<Type> _stackTraceType = new Lazy<Type>(() => Type.GetType("System.Diagnostics.StackTrace"));
private static object CaptureStackTrace()
{
return Activator.CreateInstance(_stackTraceType.Value);
}
#endif
[Conditional("DEBUG")]
private void Validate(object obj)
{
Debug.Assert(obj != null, "freeing null?");
Debug.Assert(_firstItem != obj, "freeing twice?");
var items = _items;
for (int i = 0; i < items.Length; i++)
{
var value = items[i].Value;
if (value == null)
{
return;
}
Debug.Assert(value != obj, "freeing twice?");
}
}
}
}