c# - 正确使用 .NET MemoryCache 的锁定模式

Question

我假设这段代码有并发问题：

const string CacheKey = "CacheKey";
static string GetCachedData()
{
    string expensiveString =null;
    if (MemoryCache.Default.Contains(CacheKey))
    {
        expensiveString = MemoryCache.Default[CacheKey] as string;
    }
    else
    {
        CacheItemPolicy cip = new CacheItemPolicy()
        {
            AbsoluteExpiration = new DateTimeOffset(DateTime.Now.AddMinutes(20))
        };
        expensiveString = SomeHeavyAndExpensiveCalculation();
        MemoryCache.Default.Set(CacheKey, expensiveString, cip);
    }
    return expensiveString;
}

并发问题的原因是多个线程可以获取一个空键，然后尝试将数据插入缓存。

使此代码并发证明的最短和最干净的方法是什么？我喜欢在我的缓存相关代码中遵循一个好的模式。一个在线文章的链接将是一个很大的帮助。

更新：

我根据@Scott Chamberlain 的回答想出了这段代码。任何人都可以找到任何性能或并发问题吗？如果这可行，它将节省许多代码行和错误。

using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;
using System.Threading.Tasks;
using System.Runtime.Caching;

namespace CachePoc
{
    class Program
    {
        static object everoneUseThisLockObject4CacheXYZ = new object();
        const string CacheXYZ = "CacheXYZ";
        static object everoneUseThisLockObject4CacheABC = new object();
        const string CacheABC = "CacheABC";

        static void Main(string[] args)
        {
            string xyzData = MemoryCacheHelper.GetCachedData<string>(CacheXYZ, everoneUseThisLockObject4CacheXYZ, 20, SomeHeavyAndExpensiveXYZCalculation);
            string abcData = MemoryCacheHelper.GetCachedData<string>(CacheABC, everoneUseThisLockObject4CacheXYZ, 20, SomeHeavyAndExpensiveXYZCalculation);
        }

        private static string SomeHeavyAndExpensiveXYZCalculation() {return "Expensive";}
        private static string SomeHeavyAndExpensiveABCCalculation() {return "Expensive";}

        public static class MemoryCacheHelper
        {
            public static T GetCachedData<T>(string cacheKey, object cacheLock, int cacheTimePolicyMinutes, Func<T> GetData)
                where T : class
            {
                //Returns null if the string does not exist, prevents a race condition where the cache invalidates between the contains check and the retreival.
                T cachedData = MemoryCache.Default.Get(cacheKey, null) as T;

                if (cachedData != null)
                {
                    return cachedData;
                }

                lock (cacheLock)
                {
                    //Check to see if anyone wrote to the cache while we where waiting our turn to write the new value.
                    cachedData = MemoryCache.Default.Get(cacheKey, null) as T;

                    if (cachedData != null)
                    {
                        return cachedData;
                    }

                    //The value still did not exist so we now write it in to the cache.
                    CacheItemPolicy cip = new CacheItemPolicy()
                    {
                        AbsoluteExpiration = new DateTimeOffset(DateTime.Now.AddMinutes(cacheTimePolicyMinutes))
                    };
                    cachedData = GetData();
                    MemoryCache.Default.Set(cacheKey, cachedData, cip);
                    return cachedData;
                }
            }
        }
    }
}

Answer 1

这是我的代码的第二次迭代。因为MemoryCache是线程安全的，所以您不需要锁定初始读取，您可以只读取，如果缓存返回 null 然后进行锁定检查以查看是否需要创建字符串。它极大地简化了代码。

const string CacheKey = "CacheKey";
static readonly object cacheLock = new object();
private static string GetCachedData()
{

    //Returns null if the string does not exist, prevents a race condition where the cache invalidates between the contains check and the retreival.
    var cachedString = MemoryCache.Default.Get(CacheKey, null) as string;

    if (cachedString != null)
    {
        return cachedString;
    }

    lock (cacheLock)
    {
        //Check to see if anyone wrote to the cache while we where waiting our turn to write the new value.
        cachedString = MemoryCache.Default.Get(CacheKey, null) as string;

        if (cachedString != null)
        {
            return cachedString;
        }

        //The value still did not exist so we now write it in to the cache.
        var expensiveString = SomeHeavyAndExpensiveCalculation();
        CacheItemPolicy cip = new CacheItemPolicy()
                              {
                                  AbsoluteExpiration = new DateTimeOffset(DateTime.Now.AddMinutes(20))
                              };
        MemoryCache.Default.Set(CacheKey, expensiveString, cip);
        return expensiveString;
    }
}

---

编辑：下面的代码是不必要的，但我想让它显示原始方法。对于使用具有线程安全读取但非线程安全写入的不同集合的未来访问者可能有用（System.Collections命名空间下的几乎所有类都是这样）。

这是我ReaderWriterLockSlim用来保护访问的方法。您需要进行一种“双重检查锁定”，以查看是否有其他人在我们等待锁定时创建了缓存项。

const string CacheKey = "CacheKey";
static readonly ReaderWriterLockSlim cacheLock = new ReaderWriterLockSlim();
static string GetCachedData()
{
    //First we do a read lock to see if it already exists, this allows multiple readers at the same time.
    cacheLock.EnterReadLock();
    try
    {
        //Returns null if the string does not exist, prevents a race condition where the cache invalidates between the contains check and the retreival.
        var cachedString = MemoryCache.Default.Get(CacheKey, null) as string;

        if (cachedString != null)
        {
            return cachedString;
        }
    }
    finally
    {
        cacheLock.ExitReadLock();
    }

    //Only one UpgradeableReadLock can exist at one time, but it can co-exist with many ReadLocks
    cacheLock.EnterUpgradeableReadLock();
    try
    {
        //We need to check again to see if the string was created while we where waiting to enter the EnterUpgradeableReadLock
        var cachedString = MemoryCache.Default.Get(CacheKey, null) as string;

        if (cachedString != null)
        {
            return cachedString;
        }

        //The entry still does not exist so we need to create it and enter the write lock
        var expensiveString = SomeHeavyAndExpensiveCalculation();
        cacheLock.EnterWriteLock(); //This will block till all the Readers flush.
        try
        {
            CacheItemPolicy cip = new CacheItemPolicy()
            {
                AbsoluteExpiration = new DateTimeOffset(DateTime.Now.AddMinutes(20))
            };
            MemoryCache.Default.Set(CacheKey, expensiveString, cip);
            return expensiveString;
        }
        finally 
        {
            cacheLock.ExitWriteLock();
        }
    }
    finally
    {
        cacheLock.ExitUpgradeableReadLock();
    }
}

Answer 2

有一个开源库 [免责声明：我写的]：IMO 用两行代码满足您的要求的LazyCache ：

IAppCache cache = new CachingService();
var cachedResults = cache.GetOrAdd("CacheKey", 
  () => SomeHeavyAndExpensiveCalculation());

它默认内置锁定，因此可缓存方法只会在每次缓存未命中时执行一次，并且它使用 lambda，因此您可以一次性执行“获取或添加”。默认为 20 分钟滑动到期。

甚至还有一个 NuGet 包；）

Answer 3

我通过使用 MemoryCache 上的AddOrGetExisting方法和使用延迟初始化解决了这个问题。

本质上，我的代码看起来像这样：

static string GetCachedData(string key, DateTimeOffset offset)
{
    Lazy<String> lazyObject = new Lazy<String>(() => SomeHeavyAndExpensiveCalculationThatReturnsAString());
    var returnedLazyObject = MemoryCache.Default.AddOrGetExisting(key, lazyObject, offset); 
    if (returnedLazyObject == null)
       return lazyObject.Value;
    return ((Lazy<String>) returnedLazyObject).Value;
}

这里最糟糕的情况是您创建了Lazy两次相同的对象。但这很微不足道。使用AddOrGetExisting保证你只会得到一个Lazy对象的实例，因此你也保证只调用一次昂贵的初始化方法。

Answer 4

我假设这段代码有并发问题：

实际上，它很可能很好，尽管可能会有所改进。

现在，通常我们有多个线程在第一次使用时设置共享值的模式，而不是锁定正在获取和设置的值可以是：

1. 灾难性的 - 其他代码将假设只存在一个实例。
2. 灾难性的——获取实例的代码不是只能容忍一个（或者可能是少数几个）并发操作。
3. 灾难性的 - 存储方式不是线程安全的（例如，将两个线程添加到字典中，您可能会遇到各种讨厌的错误）。
4. 次优 - 与锁定确保只有一个线程完成获取值的工作相比，整体性能更差。
5. 最佳 - 让多个线程执行冗余工作的成本低于防止它的成本，特别是因为这只能在相对较短的时间内发生。

但是，考虑到这里MemoryCache可能会驱逐条目：

1. 如果拥有多个实例是灾难性的，那么MemoryCache就是错误的方法。
2. 如果您必须防止同时创建，您应该在创建时这样做。
3. MemoryCache就访问该对象而言是线程安全的，因此这里不关心。

当然，这两种可能性都必须考虑，尽管唯一存在相同字符串的两个实例可能会成为问题的情况是，如果您正在执行不适用于此处的非常特殊的优化*。

所以，我们剩下的可能性是：

1. 避免重复调用SomeHeavyAndExpensiveCalculation().
2. 不避免重复调用的成本会更便宜SomeHeavyAndExpensiveCalculation()。

解决这个问题可能很困难（事实上，值得分析而不是假设你可以解决的事情）。值得考虑的是，最明显的插入锁定方法将阻止所有添加到缓存中，包括那些不相关的添加。

这意味着如果我们有 50 个线程试图设置 50 个不同的值，那么我们将不得不让所有 50 个线程相互等待，即使它们甚至不会进行相同的计算。

因此，与避免竞争条件的代码相比，您可能会更好地使用您拥有的代码，如果竞争条件是一个问题，您很可能需要在其他地方处理它，或者需要不同的缓存策略而不是驱逐旧条目的策略†。

我要改变的一件事是我将调用 to 替换为Set()one to AddOrGetExisting()。从上面可以清楚地看出，这可能不是必需的，但它允许收集新获得的项目，减少整体内存使用，并允许低代与高代收集的比例更高。

所以，是的，您可以使用双锁定来防止并发，但是并发实际上不是问题，或者您以错误的方式存储值，或者在存储上双锁定不是解决它的最佳方法.

*如果您知道一组字符串中的每一个都只存在一个，则可以优化相等比较，这大约是唯一一次拥有两个字符串副本可能是不正确的，而不仅仅是次优的，但您希望这样做非常不同类型的缓存才有意义。例如，排序XmlReader在内部进行。

†很可能是一个无限期存储，或者一个使用弱引用，因此它只会在没有现有用途的情况下驱逐条目。

Answer 5

为了避免全局锁，您可以使用 SingletonCache 为每个键实现一个锁，而不会爆炸内存使用量（不再引用时将删除锁对象，并且获取/释放是线程安全的，通过比较保证只有 1 个实例在使用中和交换）。

使用它看起来像这样：

SingletonCache<string, object> keyLocks = new SingletonCache<string, object>();

const string CacheKey = "CacheKey";
static string GetCachedData()
{
    string expensiveString =null;
    if (MemoryCache.Default.Contains(CacheKey))
    {
        return MemoryCache.Default[CacheKey] as string;
    }

    // double checked lock
    using (var lifetime = keyLocks.Acquire(url))
    {
        lock (lifetime.Value)
        {
           if (MemoryCache.Default.Contains(CacheKey))
           {
              return MemoryCache.Default[CacheKey] as string;
           }

           cacheItemPolicy cip = new CacheItemPolicy()
           {
              AbsoluteExpiration = new DateTimeOffset(DateTime.Now.AddMinutes(20))
           };
           expensiveString = SomeHeavyAndExpensiveCalculation();
           MemoryCache.Default.Set(CacheKey, expensiveString, cip);
           return expensiveString;
        }
    }      
}

代码在 GitHub 上：https ://github.com/bitfaster/BitFaster.Caching

Install-Package BitFaster.Caching

还有一个 LRU 实现，它比 MemoryCache 更轻，并且有几个优点 - 更快的并发读取和写入、有限的大小、没有后台线程、内部性能计数器等（免责声明，我写的）。

Answer 6

很难选择哪个更好；锁或 ReaderWriterLockSlim。您需要读写数字和比率等的真实世界统计数据。

但是，如果您认为使用“锁定”是正确的方法。那么这里是针对不同需求的不同解决方案。我还在代码中包含了 Allan Xu 的解决方案。因为两者都可以满足不同的需求。

以下是要求，促使我采用此解决方案：

1. 由于某种原因，您不想或不能提供“GetData”功能。也许“GetData”函数位于其他具有大量构造函数的类中，并且您甚至不想创建实例，直到确保它无法逃避。
2. 您需要从应用程序的不同位置/层访问相同的缓存数据。并且那些不同的位置无法访问相同的储物柜对象。
3. 您没有恒定的缓存键。例如; 需要使用 sessionId 缓存键缓存一些数据。

代码：

using System;
using System.Runtime.Caching;
using System.Collections.Concurrent;
using System.Collections.Generic;

namespace CachePoc
{
    class Program
    {
        static object everoneUseThisLockObject4CacheXYZ = new object();
        const string CacheXYZ = "CacheXYZ";
        static object everoneUseThisLockObject4CacheABC = new object();
        const string CacheABC = "CacheABC";

        static void Main(string[] args)
        {
            //Allan Xu's usage
            string xyzData = MemoryCacheHelper.GetCachedDataOrAdd<string>(CacheXYZ, everoneUseThisLockObject4CacheXYZ, 20, SomeHeavyAndExpensiveXYZCalculation);
            string abcData = MemoryCacheHelper.GetCachedDataOrAdd<string>(CacheABC, everoneUseThisLockObject4CacheXYZ, 20, SomeHeavyAndExpensiveXYZCalculation);

            //My usage
            string sessionId = System.Web.HttpContext.Current.Session["CurrentUser.SessionId"].ToString();
            string yvz = MemoryCacheHelper.GetCachedData<string>(sessionId);
            if (string.IsNullOrWhiteSpace(yvz))
            {
                object locker = MemoryCacheHelper.GetLocker(sessionId);
                lock (locker)
                {
                    yvz = MemoryCacheHelper.GetCachedData<string>(sessionId);
                    if (string.IsNullOrWhiteSpace(yvz))
                    {
                        DatabaseRepositoryWithHeavyConstructorOverHead dbRepo = new DatabaseRepositoryWithHeavyConstructorOverHead();
                        yvz = dbRepo.GetDataExpensiveDataForSession(sessionId);
                        MemoryCacheHelper.AddDataToCache(sessionId, yvz, 5);
                    }
                }
            }
        }


        private static string SomeHeavyAndExpensiveXYZCalculation() { return "Expensive"; }
        private static string SomeHeavyAndExpensiveABCCalculation() { return "Expensive"; }

        public static class MemoryCacheHelper
        {
            //Allan Xu's solution
            public static T GetCachedDataOrAdd<T>(string cacheKey, object cacheLock, int minutesToExpire, Func<T> GetData) where T : class
            {
                //Returns null if the string does not exist, prevents a race condition where the cache invalidates between the contains check and the retreival.
                T cachedData = MemoryCache.Default.Get(cacheKey, null) as T;

                if (cachedData != null)
                    return cachedData;

                lock (cacheLock)
                {
                    //Check to see if anyone wrote to the cache while we where waiting our turn to write the new value.
                    cachedData = MemoryCache.Default.Get(cacheKey, null) as T;

                    if (cachedData != null)
                        return cachedData;

                    cachedData = GetData();
                    MemoryCache.Default.Set(cacheKey, cachedData, DateTime.Now.AddMinutes(minutesToExpire));
                    return cachedData;
                }
            }

            #region "My Solution"

            readonly static ConcurrentDictionary<string, object> Lockers = new ConcurrentDictionary<string, object>();
            public static object GetLocker(string cacheKey)
            {
                CleanupLockers();

                return Lockers.GetOrAdd(cacheKey, item => (cacheKey, new object()));
            }

            public static T GetCachedData<T>(string cacheKey) where T : class
            {
                CleanupLockers();

                T cachedData = MemoryCache.Default.Get(cacheKey) as T;
                return cachedData;
            }

            public static void AddDataToCache(string cacheKey, object value, int cacheTimePolicyMinutes)
            {
                CleanupLockers();

                MemoryCache.Default.Add(cacheKey, value, DateTimeOffset.Now.AddMinutes(cacheTimePolicyMinutes));
            }

            static DateTimeOffset lastCleanUpTime = DateTimeOffset.MinValue;
            static void CleanupLockers()
            {
                if (DateTimeOffset.Now.Subtract(lastCleanUpTime).TotalMinutes > 1)
                {
                    lock (Lockers)//maybe a better locker is needed?
                    {
                        try//bypass exceptions
                        {
                            List<string> lockersToRemove = new List<string>();
                            foreach (var locker in Lockers)
                            {
                                if (!MemoryCache.Default.Contains(locker.Key))
                                    lockersToRemove.Add(locker.Key);
                            }

                            object dummy;
                            foreach (string lockerKey in lockersToRemove)
                                Lockers.TryRemove(lockerKey, out dummy);

                            lastCleanUpTime = DateTimeOffset.Now;
                        }
                        catch (Exception)
                        { }
                    }
                }

            }
            #endregion
        }
    }

    class DatabaseRepositoryWithHeavyConstructorOverHead
    {
        internal string GetDataExpensiveDataForSession(string sessionId)
        {
            return "Expensive data from database";
        }
    }

}

Answer 7

MemoryCache的控制台示例，“如何保存/获取简单的类对象”

启动并按下后输出 Any key除了Esc：

保存到缓存！
从缓存中获取！
一些1
一些2

    class Some
    {
        public String text { get; set; }

        public Some(String text)
        {
            this.text = text;
        }

        public override string ToString()
        {
            return text;
        }
    }

    public static MemoryCache cache = new MemoryCache("cache");

    public static string cache_name = "mycache";

    static void Main(string[] args)
    {

        Some some1 = new Some("some1");
        Some some2 = new Some("some2");

        List<Some> list = new List<Some>();
        list.Add(some1);
        list.Add(some2);

        do {

            if (cache.Contains(cache_name))
            {
                Console.WriteLine("Getting from cache!");
                List<Some> list_c = cache.Get(cache_name) as List<Some>;
                foreach (Some s in list_c) Console.WriteLine(s);
            }
            else
            {
                Console.WriteLine("Saving to cache!");
                cache.Set(cache_name, list, DateTime.Now.AddMinutes(10));                   
            }

        } while (Console.ReadKey(true).Key != ConsoleKey.Escape);

    }

Answer 8

然而，它有点晚了......完整的实现：

    [HttpGet]
    public async Task<HttpResponseMessage> GetPageFromUriOrBody(RequestQuery requestQuery)
    {
        log(nameof(GetPageFromUriOrBody), nameof(requestQuery));
        var responseResult = await _requestQueryCache.GetOrCreate(
            nameof(GetPageFromUriOrBody)
            , requestQuery
            , (x) => getPageContent(x).Result);
        return Request.CreateResponse(System.Net.HttpStatusCode.Accepted, responseResult);
    }
    static MemoryCacheWithPolicy<RequestQuery, string> _requestQueryCache = new MemoryCacheWithPolicy<RequestQuery, string>();

这是getPageContent签名：

async Task<string> getPageContent(RequestQuery requestQuery);

这是MemoryCacheWithPolicy实现：

public class MemoryCacheWithPolicy<TParameter, TResult>
{
    static ILogger _nlogger = new AppLogger().Logger;
    private MemoryCache _cache = new MemoryCache(new MemoryCacheOptions() 
    {
        //Size limit amount: this is actually a memory size limit value!
        SizeLimit = 1024 
    });

    /// <summary>
    /// Gets or creates a new memory cache record for a main data
    /// along with parameter data that is assocciated with main main.
    /// </summary>
    /// <param name="key">Main data cache memory key.</param>
    /// <param name="param">Parameter model that assocciated to main model (request result).</param>
    /// <param name="createCacheData">A delegate to create a new main data to cache.</param>
    /// <returns></returns>
    public async Task<TResult> GetOrCreate(object key, TParameter param, Func<TParameter, TResult> createCacheData)
    {
        // this key is used for param cache memory.
        var paramKey = key + nameof(param);

        if (!_cache.TryGetValue(key, out TResult cacheEntry))
        {
            // key is not in the cache, create data through the delegate.
            cacheEntry = createCacheData(param);
            createMemoryCache(key, cacheEntry, paramKey, param);

            _nlogger.Warn(" cache is created.");
        }
        else
        {
            // data is chached so far..., check if param model is same (or changed)?
            if(!_cache.TryGetValue(paramKey, out TParameter cacheParam))
            {
                //exception: this case should not happened!
            }

            if (!cacheParam.Equals(param))
            {
                // request param is changed, create data through the delegate.
                cacheEntry = createCacheData(param);
                createMemoryCache(key, cacheEntry, paramKey, param);
                _nlogger.Warn(" cache is re-created (param model has been changed).");
            }
            else
            {
                _nlogger.Trace(" cache is used.");
            }

        }
        return await Task.FromResult<TResult>(cacheEntry);
    }
    MemoryCacheEntryOptions createMemoryCacheEntryOptions(TimeSpan slidingOffset, TimeSpan relativeOffset)
    {
        // Cache data within [slidingOffset] seconds, 
        // request new result after [relativeOffset] seconds.
        return new MemoryCacheEntryOptions()

            // Size amount: this is actually an entry count per 
            // key limit value! not an actual memory size value!
            .SetSize(1)

            // Priority on removing when reaching size limit (memory pressure)
            .SetPriority(CacheItemPriority.High)

            // Keep in cache for this amount of time, reset it if accessed.
            .SetSlidingExpiration(slidingOffset)

            // Remove from cache after this time, regardless of sliding expiration
            .SetAbsoluteExpiration(relativeOffset);
        //
    }
    void createMemoryCache(object key, TResult cacheEntry, object paramKey, TParameter param)
    {
        // Cache data within 2 seconds, 
        // request new result after 5 seconds.
        var cacheEntryOptions = createMemoryCacheEntryOptions(
            TimeSpan.FromSeconds(2)
            , TimeSpan.FromSeconds(5));

        // Save data in cache.
        _cache.Set(key, cacheEntry, cacheEntryOptions);

        // Save param in cache.
        _cache.Set(paramKey, param, cacheEntryOptions);
    }
    void checkCacheEntry<T>(object key, string name)
    {
        _cache.TryGetValue(key, out T value);
        _nlogger.Fatal("Key: {0}, Name: {1}, Value: {2}", key, name, value);
    }
}

nlogger只是nLog跟踪MemoryCacheWithPolicy行为的对象。RequestQuery requestQuery如果请求对象 ( ) 通过委托 () 更改，我将重新创建内存缓存，Func<TParameter, TResult> createCacheData或者在滑动或绝对时间达到其限制时重新创建。请注意，一切都是异步的；）

Answer 9

有点过时的问题，但可能仍然有用：您可以看看我最近发布的 FusionCache ⚡</a>。

您正在寻找的功能在此处进行了描述，您可以像这样使用它：

const string CacheKey = "CacheKey";
static string GetCachedData()
{
    return fusionCache.GetOrSet(
        CacheKey,
        _ => SomeHeavyAndExpensiveCalculation(),
        TimeSpan.FromMinutes(20)
    );
}

您可能还会发现其他一些有趣的功能，例如故障安全、具有后台工厂完成的高级超时以及对可选的分布式二级缓存的支持。

如果你愿意给它一个机会，请让我知道你的想法。

/无耻的插头

Answer 10

public interface ILazyCacheProvider : IAppCache
{
    /// <summary>
    /// Get data loaded - after allways throw cached result (even when data is older then needed) but very fast!
    /// </summary>
    /// <param name="key"></param>
    /// <param name="getData"></param>
    /// <param name="slidingExpiration"></param>
    /// <typeparam name="T"></typeparam>
    /// <returns></returns>
    T GetOrAddPermanent<T>(string key, Func<T> getData, TimeSpan slidingExpiration);
}

/// <summary>
/// Initialize LazyCache in runtime
/// </summary>
public class LazzyCacheProvider: CachingService, ILazyCacheProvider
{
    private readonly Logger _logger = LogManager.GetLogger("MemCashe");
    private readonly Hashtable _hash = new Hashtable();
    private readonly List<string>  _reloader = new List<string>();
    private readonly ConcurrentDictionary<string, DateTime> _lastLoad = new ConcurrentDictionary<string, DateTime>();  


    T ILazyCacheProvider.GetOrAddPermanent<T>(string dataKey, Func<T> getData, TimeSpan slidingExpiration)
    {
        var currentPrincipal = Thread.CurrentPrincipal;
        if (!ObjectCache.Contains(dataKey) && !_hash.Contains(dataKey))
        {
            _hash[dataKey] = null;
            _logger.Debug($"{dataKey} - first start");
            _lastLoad[dataKey] = DateTime.Now;
            _hash[dataKey] = ((object)GetOrAdd(dataKey, getData, slidingExpiration)).CloneObject();
            _lastLoad[dataKey] = DateTime.Now;
           _logger.Debug($"{dataKey} - first");
        }
        else
        {
            if ((!ObjectCache.Contains(dataKey) || _lastLoad[dataKey].AddMinutes(slidingExpiration.Minutes) < DateTime.Now) && _hash[dataKey] != null)
                Task.Run(() =>
                {
                    if (_reloader.Contains(dataKey)) return;
                    lock (_reloader)
                    {
                        if (ObjectCache.Contains(dataKey))
                        {
                            if(_lastLoad[dataKey].AddMinutes(slidingExpiration.Minutes) > DateTime.Now)
                                return;
                            _lastLoad[dataKey] = DateTime.Now;
                            Remove(dataKey);
                        }
                        _reloader.Add(dataKey);
                        Thread.CurrentPrincipal = currentPrincipal;
                        _logger.Debug($"{dataKey} - reload start");
                        _hash[dataKey] = ((object)GetOrAdd(dataKey, getData, slidingExpiration)).CloneObject();
                        _logger.Debug($"{dataKey} - reload");
                        _reloader.Remove(dataKey);
                    }
                });
        }
        if (_hash[dataKey] != null) return (T) (_hash[dataKey]);

        _logger.Debug($"{dataKey} - dummy start");
        var data = GetOrAdd(dataKey, getData, slidingExpiration);
        _logger.Debug($"{dataKey} - dummy");
        return (T)((object)data).CloneObject();
    }
}