Recap
As you'll recall from the previous posts, the original collections were object-based containers that accomplished synchronization through a Synchronized member. With the advent of .NET 2.0, the original collections were succeeded by the generic collections which are fully type-safe, but eschew automatic synchronization.
With .NET 4.0, a new breed of collections was born in the System.Collections.Concurrent namespace. Of these, the final concurrent collection we will examine is the ConcurrentBag and a very useful wrapper class called the BlockingCollection.
For some excellent information on the performance of the concurrent collections and how they perform compared to a traditional brute-force locking strategy, see this informative whitepaper by the Microsoft Parallel Computing Platform team here.
ConcurrentBag<T> – Thread-safe unordered collection.
Unlike the other concurrent collections, the ConcurrentBag<T> has no non-concurrent counterpart in the .NET collections libraries. Items can be added and removed from a bag just like any other collection, but unlike the other collections, the items are not maintained in any order. This makes the bag handy for those cases when all you care about is that the data be consumed eventually, without regard for order of consumption or even fairness – that is, it’s possible new items could be consumed before older items given the right circumstances for a period of time.
So why would you ever want a container that can be unfair? Well, to look at it another way, you can use a ConcurrentQueue and get the fairness, but it comes at a cost in that the ordering rules and synchronization required to maintain that ordering can affect scalability a bit. Thus sometimes the bag is great when you want the fastest way to get the next item to process, and don’t care what item it is or how long its been waiting.
The way that the ConcurrentBag works is to take advantage of the new ThreadLocal<T> type (new in System.Threading for .NET 4.0) so that each thread using the bag has a list local to just that thread.
This means that adding or removing to a thread-local list requires very low synchronization. The problem comes in where a thread goes to consume an item but it’s local list is empty. In this case the bag performs “work-stealing” where it will rob an item from another thread that has items in its list. This requires a higher level of synchronization which adds a bit of overhead to the take operation.
Read more: James Michael Hare
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