MemoryCache Thread Safety, Is Locking Necessary?

Question

For starters let me just throw it out there that I know the code below is not thread safe (correction: might be). What I am struggling with is finding an implementation that is and one that I can actually get to fail under test. I am refactoring a large WCF project right now that needs some (mostly) static data cached and its populated from a SQL database. It needs to expire and "refresh" at least once a day which is why I am using MemoryCache.

I know that the code below should not be thread safe but I cannot get it to fail under heavy load and to complicate matters a google search shows implementations both ways (with and without locks combined with debates whether or not they are necessary.

Could someone with knowledge of MemoryCache in a multi threaded environment let me definitively know whether or not I need to lock where appropriate so that a call to remove (which will seldom be called but its a requirement) will not throw during retrieval/repopulation.

public class MemoryCacheService : IMemoryCacheService
{
    private const string PunctuationMapCacheKey = "punctuationMaps";
    private static readonly ObjectCache Cache;
    private readonly IAdoNet _adoNet;

    static MemoryCacheService()
    {
        Cache = MemoryCache.Default;
    }

    public MemoryCacheService(IAdoNet adoNet)
    {
        _adoNet = adoNet;
    }

    public void ClearPunctuationMaps()
    {
        Cache.Remove(PunctuationMapCacheKey);
    }

    public IEnumerable GetPunctuationMaps()
    {
        if (Cache.Contains(PunctuationMapCacheKey))
        {
            return (IEnumerable) Cache.Get(PunctuationMapCacheKey);
        }

        var punctuationMaps = GetPunctuationMappings();

        if (punctuationMaps == null)
        {
            throw new ApplicationException("Unable to retrieve punctuation mappings from the database.");
        }

        if (punctuationMaps.Cast<IPunctuationMapDto>().Any(p => p.UntaggedValue == null || p.TaggedValue == null))
        {
            throw new ApplicationException("Null values detected in Untagged or Tagged punctuation mappings.");
        }

        // Store data in the cache
        var cacheItemPolicy = new CacheItemPolicy
        {
            AbsoluteExpiration = DateTime.Now.AddDays(1.0)
        };

        Cache.AddOrGetExisting(PunctuationMapCacheKey, punctuationMaps, cacheItemPolicy);

        return punctuationMaps;
    }

    //Go oldschool ADO.NET to break the dependency on the entity framework and need to inject the database handler to populate cache
    private IEnumerable GetPunctuationMappings()
    {
        var table = _adoNet.ExecuteSelectCommand("SELECT [id], [TaggedValue],[UntaggedValue] FROM [dbo].[PunctuationMapper]", CommandType.Text);
        if (table != null && table.Rows.Count != 0)
        {
            return AutoMapper.Mapper.DynamicMap<IDataReader, IEnumerable<PunctuationMapDto>>(table.CreateDataReader());
        }

        return null;
    }
}

Answer 1

The default MS-provided MemoryCache is entirely thread safe. Any custom implementation that derives from MemoryCache may not be thread safe. If you're using plain MemoryCache out of the box, it is thread safe. Browse the source code of my open source distributed caching solution to see how I use it (MemCache.cs):

https://github.com/haneytron/dache/blob/master/Dache.CacheHost/Storage/MemCache.cs

Answer 2

While MemoryCache is indeed thread safe as other answers have specified, it does have a common multi threading issue - if 2 threads try to Get from (or check Contains) the cache at the same time, then both will miss the cache and both will end up generating the result and both will then add the result to the cache.

Often this is undesirable - the second thread should wait for the first to complete and use its result rather than generating results twice.

This was one of the reasons I wrote LazyCache - a friendly wrapper on MemoryCache that solves these sorts of issues. It is also available on Nuget.

Answer 3

As others have stated, MemoryCache is indeed thread safe. The thread safety of the data stored within it however, is entirely up to your using's of it.

To quote Reed Copsey from his awesome post regarding concurrency and the ConcurrentDictionary<TKey, TValue> type. Which is of course applicable here.

If two threads call this [GetOrAdd] simultaneously, two instances of TValue can easily be constructed.

You can imagine that this would be especially bad if TValue is expensive to construct.

To work your way around this, you can leverage Lazy<T> very easily, which coincidentally is very cheap to construct. Doing this ensures if we get into a multithreaded situation, that we're only building multiple instances of Lazy<T> (which is cheap).

GetOrAdd() (GetOrCreate() in the case of MemoryCache) will return the same, singular Lazy<T> to all threads, the "extra" instances of Lazy<T> are simply thrown away.

Since the Lazy<T> doesn't do anything until .Value is called, only one instance of the object is ever constructed.

Now for some code! Below is an extension method for IMemoryCache which implements the above. It arbitrarily is setting SlidingExpiration based on a int seconds method param. But this is entirely customizable based on your needs.

Note this is specific to .netcore2.0 apps

public static T GetOrAdd<T>(this IMemoryCache cache, string key, int seconds, Func<T> factory)
{
    return cache.GetOrCreate<T>(key, entry => new Lazy<T>(() =>
    {
        entry.SlidingExpiration = TimeSpan.FromSeconds(seconds);

        return factory.Invoke();
    }).Value);
}

To call:

IMemoryCache cache;
var result = cache.GetOrAdd("someKey", 60, () => new object());

To perform this all asynchronously, I recommend using Stephen Toub's excellent AsyncLazy<T> implementation found in his article on MSDN. Which combines the builtin lazy initializer Lazy<T> with the promise Task<T>:

public class AsyncLazy<T> : Lazy<Task<T>>
{
    public AsyncLazy(Func<T> valueFactory) :
        base(() => Task.Factory.StartNew(valueFactory))
    { }
    public AsyncLazy(Func<Task<T>> taskFactory) :
        base(() => Task.Factory.StartNew(() => taskFactory()).Unwrap())
    { }
}   

Now the async version of GetOrAdd():

public static Task<T> GetOrAddAsync<T>(this IMemoryCache cache, string key, int seconds, Func<Task<T>> taskFactory)
{
    return cache.GetOrCreateAsync<T>(key, async entry => await new AsyncLazy<T>(async () =>
    { 
        entry.SlidingExpiration = TimeSpan.FromSeconds(seconds);

        return await taskFactory.Invoke();
    }).Value);
}

And finally, to call:

IMemoryCache cache;
var result = await cache.GetOrAddAsync("someKey", 60, async () => new object());

Answer 4

Check out this link: http://msdn.microsoft.com/en-us/library/system.runtime.caching.memorycache(v=vs.110).aspx

Go to the very bottom of the page (or search for the text "Thread Safety").

You will see:

^ Thread Safety

This type is thread safe.

Answer 5

As mentioned by @AmitE at the answer of @pimbrouwers, his example is not working as demonstrated here:

class Program
{
    static async Task Main(string[] args)
    {
        var cache = new MemoryCache(new MemoryCacheOptions());

        var tasks = new List<Task>();
        var counter = 0;

        for (int i = 0; i < 10; i++)
        {
            var loc = i;
            tasks.Add(Task.Run(() =>
            {
                var x = GetOrAdd(cache, "test", TimeSpan.FromMinutes(1), () => Interlocked.Increment(ref counter));
                Console.WriteLine($"Interation {loc} got {x}");
            }));
        }

        await Task.WhenAll(tasks);
        Console.WriteLine("Total value creations: " + counter);
        Console.ReadKey();
    }

    public static T GetOrAdd<T>(IMemoryCache cache, string key, TimeSpan expiration, Func<T> valueFactory)
    {
        return cache.GetOrCreate(key, entry =>
        {
            entry.SetSlidingExpiration(expiration);
            return new Lazy<T>(valueFactory, LazyThreadSafetyMode.ExecutionAndPublication);
        }).Value;
    }
}

Output:

Interation 6 got 8
Interation 7 got 6
Interation 2 got 3
Interation 3 got 2
Interation 4 got 10
Interation 8 got 9
Interation 5 got 4
Interation 9 got 1
Interation 1 got 5
Interation 0 got 7
Total value creations: 10

It seems like GetOrCreate returns always the created entry. Luckily, that's very easy to fix:

public static T GetOrSetValueSafe<T>(IMemoryCache cache, string key, TimeSpan expiration,
    Func<T> valueFactory)
{
    if (cache.TryGetValue(key, out Lazy<T> cachedValue))
        return cachedValue.Value;

    cache.GetOrCreate(key, entry =>
    {
        entry.SetSlidingExpiration(expiration);
        return new Lazy<T>(valueFactory, LazyThreadSafetyMode.ExecutionAndPublication);
    });

    return cache.Get<Lazy<T>>(key).Value;
}

That works as expected:

Interation 4 got 1
Interation 9 got 1
Interation 1 got 1
Interation 8 got 1
Interation 0 got 1
Interation 6 got 1
Interation 7 got 1
Interation 2 got 1
Interation 5 got 1
Interation 3 got 1
Total value creations: 1

Answer 6

Just uploaded sample library to address issue for .Net 2.0.

Take a look on this repo:

RedisLazyCache

I'm using Redis cache but it also failover or just Memorycache if Connectionstring is missing.

It's based on LazyCache library that guarantees single execution of callback for write in an event of multi threading trying to load and save data specially if the callback are very expensive to execute.

Answer 7

The cache is threadsafe, but like others have stated, its possible that GetOrAdd will call the func multiple types if call from multiple types.

Here is my minimal fix on that

private readonly SemaphoreSlim _cacheLock = new SemaphoreSlim(1);

and

await _cacheLock.WaitAsync();
var data = await _cache.GetOrCreateAsync(key, entry => ...);
_cacheLock.Release();

Answer 8

I know this is a old thread, but I have stumbled on the same problem and wanted to post my solution:

class FooProvider
{
    private readonly SemaphoreSlim _lock = new(1, 1);
    private readonly IMemoryCache _cache;

    public async ValueTask<Foo> GetFooAsync(string key)
    {
        var entry = _cache.Get<Foo>(key);
        if (entry is not null)
            return entry;

        _lock.Wait(cancellationToken);
        try
        {
            entry = _cache.Get<Foo>(key);
            if (entry is null)
            {
                entry = await CreateFooAsync();
                _cache.Set(key, entry, TimeSpan.FromSeconds(30));
            }
        }
        finally
        {
            _lock.Release();
        }
    }
}

the class is basically first checking if there's data in the cache. If it's missing, it will use a global lock, re-check if there's data (another thread might have entered it before), and if not, will call the async factory.

This will block other readers, even if they are trying to pull data for another key. A solution would be to keep a ConcurrentDictionary<string, SemaphoreSlim>, for example.