Whenever you find the need for a thread-safe
List<T>, in most cases neither the
ConcurrentBag<T> nor the
BlockingCollection<T> are going to be your best option. Both collections are specialized for facilitating producer-consumer scenarios, so unless you have more than one threads that are concurrently adding and removing items from the collection, you should look for other options (with the best candidate being the
ConcurrentQueue<T> in most cases).
Regarding especially the
ConcurrentBag<T>, it's an extremely specialized class targeting mixed producer-consumer scenarios. This means that each worker-thread is expected to be both a producer and a consumer (that adds and removes items from the same collection). It could be a good candidate for the internal storage of an
ObjectPool class, but beyond that it is hard to imagine any advantageous usage scenario for this class.
People usually think that the
ConcurrentBag<T> is the thread-safe equivalent of a
List<T>, but it's not. The similarity of the two APIs is misleading. Calling
Add to a
List<T> results to adding an item at the end of the list. Calling
Add to a
ConcurrentBag<T> results instead to the item being added at a random slot inside the bag. The
ConcurrentBag<T> is essentially unordered. It is not optimized for being enumerated, and does a lousy job when it is commanded to do so. It maintains internally a bunch of thread-local queues, so the order of its contents is dominated by which thread did what, not by when did something happened. Before each enumeration of the
ConcurrentBag<T>, all these thread-local queues are copied to an array, adding pressure to the garbage collector (source code). So for example the line
var item = bag.First(); results in a copy of the whole collection, for returning just one element.
These characteristics make the
ConcurrentBag<T> a less than ideal choice for storing the results of a
A better thread-safe substitute of the
List<T>.Add is the
ConcurrentQueue<T>.Enqueue method. "Enqueue" is a less familiar word than "Add", but it actually does what you expect it to do.
There is nothing that a
ConcurrentBag<T> can do that a
ConcurrentQueue<T> can't. For example neither collection offers a way to remove a specific item from the collection. If you want a concurrent collection with a
TryRemove method that has a
key parameter, you could look at the
ConcurrentBag<T> appears frequently in the Task Parallel Library-related examples in Microsoft's documentation. Like here for example.
Whoever wrote the documentation, apparently they valued more the tiny usability advantage of writing
Add instead of
Enqueue, than the behavioral/performance disadvantage of using the wrong collection. This makes some sense considering that the examples were authored at a time when the TPL was new, and the goal was the fast adoption of the library by developers who were mostly unfamiliar with parallel programming. I get it,
Enqueue is a scary word when you see it for the first time. Unfortunately now there is a whole generation of developers that have incorporated the
ConcurrentBag<T> in their mental tools, although it has no business being there, considering
how specialized this collection is.
In case you want to collect the results of a
Parallel.ForEach loop in exactly the same order as the source elements, you can use a
List<T> protected with a
lock. In most cases the overhead will be negligible, especially if the work inside the loop is chunky. An example is shown below, featuring the
Select LINQ operator for getting the index of each element.
var indexedSource = source.Select((item, index) => (item, index));
List<TResult> results = new();
Parallel.ForEach(indexedSource, parallelOptions, entry =>
var (item, index) = entry;
TResult result = GetResult(item);
while (results.Count <= index) results.Add(default);
results[index] = result;
This is for the case that the
source is a deferred sequence with unknown size. If you know its size beforehand, it is even simpler. Just preallocate a
TResult array, and update it in parallel without locking:
TResult results = new TResult[source.Count];
Parallel.For(0, source.Count, parallelOptions, i =>
results[i] = GetResult(source[i]);
The TPL includes memory barriers at the end of task executions, so all the values of the
results array will be visible from the current thread (citation).