As of C# 7.0 async methods can return ValueTask<T>. The explanation says that it should be used when we have a cached result or simulating async via synchronous code. However I still do not understand what is the problem with using ValueTask always or in fact why async/await wasn't built with a value type from the start. When would ValueTask fail to do the job?

up vote 158 down vote accepted

From the API docs (emphasis added):

Methods may return an instance of this value type when it's likely that the result of their operations will be available synchronously and when the method is expected to be invoked so frequently that the cost of allocating a new Task<TResult> for each call will be prohibitive.

There are tradeoffs to using a ValueTask<TResult> instead of a Task<TResult>. For example, while a ValueTask<TResult> can help avoid an allocation in the case where the successful result is available synchronously, it also contains two fields whereas a Task<TResult> as a reference type is a single field. This means that a method call ends up returning two fields worth of data instead of one, which is more data to copy. It also means that if a method that returns one of these is awaited within an async method, the state machine for that async method will be larger due to needing to store the struct that's two fields instead of a single reference.

Further, for uses other than consuming the result of an asynchronous operation via await, ValueTask<TResult> can lead to a more convoluted programming model, which can in turn actually lead to more allocations. For example, consider a method that could return either a Task<TResult> with a cached task as a common result or a ValueTask<TResult>. If the consumer of the result wants to use it as a Task<TResult>, such as to use with in methods like Task.WhenAll and Task.WhenAny, the ValueTask<TResult> would first need to be converted into a Task<TResult> using AsTask, which leads to an allocation that would have been avoided if a cached Task<TResult> had been used in the first place.

As such, the default choice for any asynchronous method should be to return a Task or Task<TResult>. Only if performance analysis proves it worthwhile should a ValueTask<TResult> be used instead of Task<TResult>.

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    Can we upvote on the API docs? :o) – Sir Rufo Mar 24 '17 at 16:57
  • Accepted since it is the most direct answer to the question and contains clear guidelines on what to do. – Stilgar Mar 24 '17 at 20:45
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    @MattThomas: It saves a single Task allocation (which is small and cheap these days), but at the cost of making the caller's existing allocation larger and doubling the size of the return value (impacting register allocation). While it's a clear choice for a buffered read scenario, applying it by default to all interfaces is not something I'd recommend. – Stephen Cleary Mar 27 '17 at 18:40
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    Right, either Task or ValueTask can be used as a synchronous return type (with Task.FromResult). But there's still value (heh) in ValueTask if you have something you expect to be synchronous. ReadByteAsync being a classic example. I believe ValueTask was created mainly for the new "channels" (low-level byte streams), possibly also used in ASP.NET core where performance really matters. – Stephen Cleary Mar 27 '17 at 19:07
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    Oh I know that lol, was just wondering if you had something to add to that specific comment ;) – julealgon Mar 23 at 20:03

However I still do not understand what is the problem with using ValueTask always

Struct types are not free. Copying structs that are larger than the size of a reference can be slower than copying a reference. Storing structs that are larger than a reference takes more memory than storing a reference. Structs that are larger than 64 bits might not be enregistered when a reference could be enregistered. The benefits of lower collection pressure may not exceed the costs.

Performance problems should be approached with an engineering discipline. Make goals, measure your progress against goals, and then decide how to modify the program if goals are not met, measuring along the way to make sure that your changes are actually improvements.

why async/await wasn't built with a value type from the start.

await was added to C# long after the Task<T> type already existed. It would have been somewhat perverse to invent a new type when one already existed. And await went through a great many design iterations before settling on the one that was shipped in 2012. The perfect is the enemy of the good; better to ship a solution that works well with the existing infrastructure and then if there is user demand, provide improvements later.

I note also that the new feature of allowing user-supplied types to be the output of a compiler-generated method adds considerable risk and testing burden. When the only things you can return are void or a task, the testing team does not have to consider any scenario in which some absolutely crazy type is returned. Testing a compiler means figuring out not just what programs people are likely to write, but what programs are possible to write, because we want the compiler to compile all legal programs, not just all sensible programs. That's expensive.

Can someone explain when ValueTask would fail to do the job?

The purpose of the thing is improved performance. It doesn't do the job if it doesn't measurably and significantly improve performance. There is no guarantee that it will.

ValueTask<T> isn't a subset of Task<T>, it's a superset.

ValueTask<T> is a discriminated union of a T and a Task<T>, making it allocation-free for ReadAsync<T> to synchronously return a T value it has available (in contrast to using Task.FromResult<T>, which needs to allocate a Task<T> instance). ValueTask<T> is awaitable, so most consumption of instances will be indistinguishable from with a Task<T>.

ValueTask, being a struct, enables writing async methods that do not allocate memory when they run synchronously without compromising API consistency. Imagine having an interface with a Task returning method. Each class implementing this interface must return a Task even if they happen to execute synchronously (hopefully using Task.FromResult). You can of course have 2 different methods on the interface, a synchronous one and an async one but this requires 2 different implementations to avoid “sync over async” and “async over sync”.

So it lets you write one method that's either asynchronous or synchronous, rather then writing one otherwise identical method for each. You could use it anywhere you use Task<T> but it often wouldn't be adding anything.

Well, it adds one thing: It adds an implied promise to the caller that the method actually uses the additional functionality that ValueTask<T> provides. I personally prefer choosing parameter and return types that tell the caller as much as possible. Don't return IList<T> if the enumeration can't provide a count; don't return IEnumerable<T> if it can. Your consumers shouldn't have to look up any documentation to know which of your methods can reasonably be called synchronously and which can't.

I don't see future design changes as a convincing argument there. Quite the contrary: If a method changes its semantics, it should break the build until all the calls to it are updated accordingly. If that's considered undesirable (and believe me, I'm sympathetic to a desire not to break the build), consider interface versioning.

This is essentially what strong typing is for.

If some of the programmers designing async methods in your shop aren't able to make informed decisions, it might be helpful to assign a senior mentor to each of those less experienced programmers and have a weekly code review. If they guess wrong, explain why it should be done differently. It's overhead for the senior guys, but it'll bring the juniors up to speed much more quickly than just tossing them in the deep end and giving them some arbitrary rule to follow.

If the guy who wrote the method doesn't know if it can be called synchronously, who on Earth does?!

If you have that many inexperienced programmers writing async methods, are those same folks calling them as well? Are they qualified to figure out for themselves which ones are safe to call async, or will they start applying a similarly arbitrary rule to how they call these things?

The problem here isn't your return types, it's programmers being put in roles they're not ready for. That must have happened for a reason, so I'm sure it can't be trivial to fix. Describing it certainly isn't a solution. But looking for a way to sneak the problem past the compiler isn't a solution either.

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    If I see a method returning ValueTask<T>, I assume that the guy who wrote the method did that because the method actually uses the functionality that ValueTask<T> adds. I don't understand why you think it's desirable for all your methods to have the same return type. What's the goal there? – Ed Plunkett Mar 24 '17 at 13:39
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    In my view, that's almost like having all your methods return object because maybe someday you'll want them to return int instead of string. – Ed Plunkett Mar 24 '17 at 13:47
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    Maybe but if you ask the question "why would you ever return a string instead of object" I can easily answer it pointing to the lack of type safety. The reasons not to use ValueTask everywhere seem to be much more subtle. – Stilgar Mar 24 '17 at 13:49
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    @Stilgar One thing I would say: Subtle problems should worry you more than obvious ones. – Ed Plunkett Mar 24 '17 at 14:21
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    Yes, they do worry me, this is why I am trying to understand the specific subtle problems here. Conveying intent is one good point but I doubt it is the only one. – Stilgar Mar 24 '17 at 14:31

There is some changes in .Net Core 2.1. Starting from .net core 2.1 ValueTask can represent not only the synchronous completed actions but the async completed too. In addition we receive non-generic ValueTask type.

I will leave Stephen Toub comment which is related to your question:

We still need to formalize guidance, but I expect it'll be something like this for public API surface area:

  • Task provides the most usability.

  • ValueTask provides the most options for performance optimization.

  • If you're writing an interface / virtual method that others will override, ValueTask is the right default choice.
  • If you expect the API to be used on hot paths where allocations will matter, ValueTask is a good choice.
  • Otherwise, where performance isn't critical, default to Task, as it provides better guarantees and usability.

From an implementation perspective, many of the returned ValueTask instances will still be backed by Task.

Feature can be used not only in the .net core 2.1. You will be able to use it with System.Threading.Tasks.Extensions package.

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