There are some cases where I really like using Guava's Striped class.
Is there an equivalent in C#?
It doesn't look like there is a direct equivalent, but there are some lockless thread-safe collection options (I'm not sure what you're trying to achieve, so I can't say if they will work for your scenario). Have a look at the System.Collections.Concurrent Namespace.
In particular, ConcurrentBag, ConcurrentQueue, ConcurrentStack, and ConcurrentDictionary all have different locking/lockless thread-safe strategies. Some are explained in this blog post.
You might be able to get what you want via the Partitioner class, although I am unsure of the implementation.
@Behrooz is incorrect in saying that all .net framework types only use a single lock for the entire list. Take a look at the source for ConcurrentDictionary. Line 71 suggests that this class is implemented using multiple locks.
If you really want to, you could write your own version. The source for the Guava Striped is: https://github.com/google/guava/blob/master/guava/src/com/google/common/util/concurrent/Striped.java
I think best you can do is implementing your own because all dotnet framework types offer only one
lock for the entire list.
To do that you can use the
GetHashCode() function, modulus(
%) it with the number of stripes you want. and use it as an index for
Tuple<TLock, List<T>> where TLock can be any kind of lock defined in
System.Threading namespace and T is the type you want to store/access.
With this you can decide how you want your stripes to be stored. There are choices like
HashSet(inefficient in your case since you already use some of the bits to calculate the stripe index),
btw, Thank you for the question, It's gonna help me solve a problem I'm having.
Have you tried Tamarind from NuGet?
It's C# port of Google's Guava library
I think the ConcurrentDictionary can archive a similar result.
Based on their documentation:
All these operations are atomic and are thread-safe with regards to all other operations on the ConcurrentDictionary class. The only exceptions are the methods that accept a delegate, that is, AddOrUpdate and GetOrAdd. For modifications and write operations to the dictionary, ConcurrentDictionary uses fine-grained locking to ensure thread safety. (Read operations on the dictionary are performed in a lock-free manner.) However, delegates for these methods are called outside the locks to avoid the problems that can arise from executing unknown code under a lock. Therefore, the code executed by these delegates is not subject to the atomicity of the operation.
As you can see, read operations are lock-free. That will allow you to not block the threads from reading while other are inserting for example.