I assume this code has concurrency issues:

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;
}

The reason for the concurrency issue is that multiple threads can get a null key and then attempt to insert data into cache.

What would be the shortest and cleanest way to make this code concurrency proof? I like to follow a good pattern across my cache related code. A link to an online article would be a great help.

UPDATE:

I came up with this code based on @Scott Chamberlain's answer. Can anyone find any performance or concurrency issue with this? If this works, it would save many line of code and errors.

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;
                }
            }
        }
    }
}
  • 3
    why dont u use ReaderWriterLockSlim ? – DarthVader Jan 21 '14 at 21:23
  • 2
    I agree with DarthVader... I would think you lean ReaderWriterLockSlim... But I would also use this technique to avoid try-finally statements. – Andrew Jan 21 '14 at 22:51
  • 1
    For your updated version, I would not lock on a single cacheLock anymore, I would lock per key instead. This can be easily done with a Dictionary<string, object> where the key is the same key you use in your MemoryCache and the object in the dictionary is just a basic Object you lock on. However, that being said, I would reccomend you read through Jon Hanna's answer. Without proper profileing you may be slowing down your program more with locking than lettings two instances of SomeHeavyAndExpensiveCalculation() run and have one result thrown away. – Scott Chamberlain Jan 22 '14 at 6:11
  • 1
    It seems to me that creating the CacheItemPolicy after getting the expensive value to cache would be more accurate. In a worst case scenario such as creating a summary report that takes 21 minutes to return the "expensive string" (maybe containing filename of PDF report) would already be "expired" before it was returned. – Wonderbird Aug 28 '14 at 5:25
  • 1
    @Wonderbird Good point, I updated my answer to do that. – Scott Chamberlain Oct 1 '14 at 14:07

This is my 2nd iteration of the code. Because MemoryCache is thread safe you don't need to lock on the initial read, you can just read and if the cache returns null then do the lock check to see if you need to create the string. It greatly simplifies the code.

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;
    }
}

EDIT: The below code is unnecessary but I wanted to leave it to show the original method. It may be useful to future visitors who are using a different collection that has thread safe reads but non-thread safe writes (almost all of classes under the System.Collections namespace is like that).

Here is how I would do it using ReaderWriterLockSlim to protect access. You need to do a kind of "Double Checked Locking" to see if anyone else created the cached item while we where waiting to to take the lock.

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();
    }
}
  • Double Check Locking doesnt always work though. – DarthVader Jan 21 '14 at 21:39
  • 1
    @DarthVader in what way will the above code not work? also this is not strictly "double checked locking" I am just following a similar pattern and it was the best way I could think of to describe it. That is why I said it was a kind of double checked locking. – Scott Chamberlain Jan 21 '14 at 21:41
  • I didnt comment on your code. I was commenting that Double Check Locking Doesnt work. Your code is fine. – DarthVader Jan 21 '14 at 21:48
  • 1
    I find it hard to see what situations this sort of locking and this sort of storage would make sense in though: If you're locking on all creations of values going into a MemoryCache chances are at least one of those two things was wrong. – Jon Hanna Jan 21 '14 at 22:44
  • 3
    A downside of this code is that CacheKey "A" will block a request to CacheKey "B" if both are not cached yet. To solve this you could use a concurrentDictionary<string,object> in which you store the cachekeys to lock on – MichaelD Jun 27 at 6:18

I've solved this issue by making use of the AddOrGetExisting method on the MemoryCache and the use of Lazy initialization.

Essentially, my code looks something like this:

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;
}

Worst case scenario here is that you create the same Lazy object twice. But that is pretty trivial. The use of AddOrGetExisting guarantees that you'll only ever get one instance of the Lazy object, and so you're also guaranteed to only call the expensive initialization method once.

  • 2
    The problem with this type of approach is that you can insert invalid data. If SomeHeavyAndExpensiveCalculationThatResultsAString() threw an exception, it's stuck in the cache. Even transient exceptions will get cached with Lazy<T>: msdn.microsoft.com/en-us/library/vstudio/dd642331.aspx – Scott Wegner Jan 24 '14 at 16:19
  • 2
    While its true that Lazy<T> can return an error if the initialization exception fails, that is a pretty easy thing to detect. You can then evict any Lazy<T> that resolves to an error from the cache, create a new Lazy<T>, put that in the cache, and resolve it. In our own code, we do something similar. We retry a set number of times before we throw an error. – Keith Jan 24 '14 at 16:57
  • 12
    AddOrGetExisting return null if the item was not present, so you should check and return lazyObject in that case – Gian Marco Gherardi Aug 11 '14 at 13:56
  • 1
    Using LazyThreadSafetyMode.PublicationOnly will avoid the caching of exceptions. – Clement Jan 23 '15 at 0:49
  • 2
    According to the comments in this blog post if it's extremely expensive to initialize the cache entry, it's better to just evict on an exception (as shown in the example in the blog post) rather than use PublicationOnly, because there is a possibility that all the threads can call the initializer at the same time. – bcr Jul 31 '15 at 17:37

There is an open source library [disclaimer: that I wrote]: LazyCache that IMO covers your requirement with two lines of code:

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

It has built in locking by default so the cacheable method will only execute once per cache miss, and it uses a lambda so you can do "get or add" in one go. It defaults to 20 minutes sliding expiration.

There's even a NuGet package ;)

  • nice looking library, well written docs too. thanks! – Pompair Sep 6 '16 at 19:38
  • 3
    The Dapper of caching. – Charles Burns Dec 12 '16 at 23:50
  • 2
    This enables me to be a lazy developer which makes this the best answer! – JasonNew Nov 15 '17 at 15:22

I assume this code has concurrency issues:

Actually, it's quite possibly fine, though with a possible improvement.

Now, in general the pattern where we have multiple threads setting a shared value on first use, to not lock on the value being obtained and set can be:

  1. Disastrous - other code will assume only one instance exists.
  2. Disastrous - the code that obtains the instance is not can only tolerate one (or perhaps a certain small number) concurrent operations.
  3. Disastrous - the means of storage is not thread-safe (e.g. have two threads adding to a dictionary and you can get all sorts of nasty errors).
  4. Sub-optimal - the overall performance is worse than if locking had ensured only one thread did the work of obtaining the value.
  5. Optimal - the cost of having multiple threads do redundant work is less than the cost of preventing it, especially since that can only happen during a relatively brief period.

However, considering here that MemoryCache may evict entries then:

  1. If it's disastrous to have more than one instance then MemoryCache is the wrong approach.
  2. If you must prevent simultaneous creation, you should do so at the point of creation.
  3. MemoryCache is thread-safe in terms of access to that object, so that is not a concern here.

Both of these possibilities have to be thought about of course, though the only time having two instances of the same string existing can be a problem is if you're doing very particular optimisations that don't apply here*.

So, we're left with the possibilities:

  1. It is cheaper to avoid the cost of duplicate calls to SomeHeavyAndExpensiveCalculation().
  2. It is cheaper not to avoid the cost of duplicate calls to SomeHeavyAndExpensiveCalculation().

And working that out can be difficult (indeed, the sort of thing where it's worth profiling rather than assuming you can work it out). It's worth considering here though that most obvious ways of locking on insert will prevent all additions to the cache, including those that are unrelated.

This means that if we had 50 threads trying to set 50 different values, then we'll have to make all 50 threads wait on each other, even though they weren't even going to do the same calculation.

As such, you're probably better off with the code you have, than with code that avoids the race-condition, and if the race-condition is a problem, you quite likely either need to handle that somewhere else, or need a different caching strategy than one that expels old entries†.

The one thing I would change is I'd replace the call to Set() with one to AddOrGetExisting(). From the above it should be clear that it probably isn't necessary, but it would allow the newly obtained item to be collected, reducing overall memory use and allowing a higher ratio of low generation to high generation collections.

So yeah, you could use double-locking to prevent concurrency, but either the concurrency isn't actually a problem, or your storing the values in the wrong way, or double-locking on the store would not be the best way to solve it.

*If you know only one each of a set of strings exists, you can optimise equality comparisons, which is about the only time having two copies of a string can be incorrect rather than just sub-optimal, but you'd want to be doing very different types of caching for that to make sense. E.g. the sort XmlReader does internally.

†Quite likely either one that stores indefinitely, or one that makes use of weak references so it will only expel entries if there are no existing uses.

Console example of MemoryCache, "How to save/get simple class objects"

Output after launching and pressing Any key except Esc :

Saving to cache!
Getting from cache!
Some1
Some2

    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);

    }

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