12

Suppose we have to create many small objects of byte array type. The size varies but it always below 1024 bytes , say 780,256,953....

Will it improve operator new or GC efficiency over time if we always allocate only bytes[1024], and use only space needed?

UPD: This is short living objects, created for parsing binary protocol messages.

UPD: The number of the objects is the same in both cases, it just the size of allocation which changes (random vs. always 1024).

In C++ it would matter because of fragmentation and C++ new performance. But in C#....

4
  • 3
    Have you profiled it to see for yourself? Dec 29, 2011 at 12:23
  • Nope, I was hoping for fast answer, also it demands profiling systems for prolonged time.
    – Boris
    Dec 29, 2011 at 14:05
  • 1
    Since the objects are "short living objects, created for parsing binary protocol messages" would you consider using unsafe code and stackalloc? It seems that this is exactly what it's intended for: short-term allocation of smallish arrays in a situation where high performance is desired.
    – phoog
    Dec 29, 2011 at 17:12
  • There's no free lunch when it comes to optimization. Profiling is the name of the game. Dec 30, 2011 at 5:23

5 Answers 5

9

Will it improve operator new or GC efficiency over time if we always allocate only bytes[1024], and use only space needed?

Maybe. You're going to have to profile it and see.

The way we allocate syntax tree nodes inside the Roslyn compiler is quite interesting, and I'm eventually going to do a blog post about it. Until then, the relevant bit to your question is this interesting bit of trivia. Our allocation pattern typically involves allocating an "underlying" immutable node (which we call the "green" node) and a "facade" mutable node that wraps it (which we call the "red" node). As you might imagine, it is frequently the case that we end up allocating these in pairs: green, red, green, red, green, red.

The green nodes are persistent and therefore long-lived; the facades are short-lived, because they are discarded on every edit. Therefore it is frequently the case that the garbage collector has green / hole / green / hole / green / hole, and then the green nodes move up a generation.

Our assumption had always been that making data structures smaller will always improve GC performance. Smaller structures equals less memory allocated, equals less collection pressure, equals fewer collections, equals more performance, right? But we discovered through profiling that making the red nodes smaller in this scenario actually decreases GC performance. Something about the particular size of the holes affects the GC in some odd way; not being an expert on the internals of the garbage collector, it is opaque to me why that should be.

So is it possible that changing the size of your allocations can affect the GC in some unforseen way? Yes, it is possible. But, first off, it is unlikely, and second it is impossible to know whether you are in that situation until you actually try it in real-world scenarios and carefully measure GC performance.

And of course, you might not be gated on GC performance. Roslyn does so many small allocations that it is crucial that we tune our GC-impacting behaviour, but we do an insane number of small allocations. The vast majority of .NET programs do not stress the GC the way we do. If you are in the minority of programs that stress the GC in interesting ways then there is no way around it; you're going to have to profile and gather empirical data, just like we do on the Roslyn team.

If you are not in that minority, then don't worry about GC performance; you probably have a bigger problem somewhere else that you should be dealing with first.

1
  • 2
    Could you ask the team that handles GC why would this happen? I would really like to hear an answer from someone who is an expert on the internals of the GC. Mostly because this behavior doesn't make any sense to me.
    – svick
    Dec 29, 2011 at 21:16
3

new is fast, it is the GC that causes problems. So, it depends on how long your arrays live for.

If they only live a short time, I don't think there will be any improvement from allocating 1024 byte arrays. In fact this will put more pressure on the GC because of the wasted space and will probably degrade performance.

If they live for the life of your application, I would consider allocating one large array and using chunks of it for each small array. You would need to profile this to see if it helps.

3
  • Good point about life time of allocations, but keyword here is definitely 'profile' :)
    – Svend
    Dec 29, 2011 at 13:05
  • I cannot see how it puts more pressure on GC. The number of allocated object is the same...
    – Boris
    Dec 29, 2011 at 14:07
  • 1
    @Boris The objects will be allocated in the Gen-0 heap, which has a certain capacity. GCs are run when the heap gets full, so the more space you allocate, the sooner the heap gets full and the sooner a GC is triggered. Dec 29, 2011 at 14:37
1

Not really, Allocating or clearing a bytes array requires only one instruction, regardless of its size. (I speak about your case. there are exceptions)

You shouldn't worry about the performance aspect of garbage collection, unless you are sure that it's a bottleneck for your application (ie you create a lot of references with complex relationship, and throw it shortly afterward... And the garbage collection is noticeable.)

To read an excellent story about a well known (and quite useful) site having performance issues with the .NET GC (in an impressive use case) see this blog. http://samsaffron.com/archive/2011/10/28/in-managed-code-we-trust-our-recent-battles-with-the-net-garbage-collector ;)

But the most important thing about GC is: Never, ever do optimisations before being sure that you have a problem. Because if you do, you will probably have one. Applications are complex, and the GC interacts with every parts of it, at runtime. Apart from simple cases, predicting its behavior and bottlenecks beforehand seems (in my opinion) difficult.

3
  • 2
    Famous last words: "you shouldn't worry about performance". You know, there is a huge difference between saying that it's hard to predict bottlenecks (which is true), and that you should therefore focus on optimizing the ones that appear, and then saying that you must never ever even think about optimization until it's too late
    – jalf
    Dec 29, 2011 at 12:47
  • +1 I do think that the advice is pretty solid and -1 is not ok in my opinion Dec 29, 2011 at 12:57
  • Are you sure that there are times when you should torture yourself with GC optimisation before even knowing your bottlenecks? OK I agree, you shouldn't do anything stupid in your code, and you should know how the GC operates to make sensible algorithm choices. But the sort of optimisations stackoverflow used to speed things up (in the link I provided) really shouldn't considered beforehand: They solve an issue, but are rather strange patterns. Don't forget I didn't spoke generally. I spoke about GC optimization. OK I am editing it ;)
    – Eilistraee
    Dec 29, 2011 at 14:23
0

I also don't think only allocating 1024 byte arrays will improve the GC. Since the GC is not determistic, I also think it will not be your problem.

You can influence the GC by using using {} statements arround your arrays to free memory (maybe) sooner.

3
  • The using statement will not affect GC at all. Dec 29, 2011 at 23:15
  • after the using {} is exited the pointers to anything in it will be removed, therefore the GC will cleanup any resources which no other pointer points to (from objects or methods outside the using {})
    – sschrass
    Dec 30, 2011 at 8:09
  • Not necessarily. The only guarantees after the using block exits are that (1) the object's Dispose() method has been called, and (2) the local variable is no longer in scope. It is perfectly legal to do something like using(var foo = new MyDisposableObject()) { SomeOtherObject.StaticListOfObjects.Append(foo); } and then foo will definitely not get GC'd any earlier. The GC has no knowledge of C# scope: an object will not necessarily get GC'd when its last reference goes out of scope, and will not necessarily not get GC'd while references to it are still in scope! Dec 30, 2011 at 18:45
0

I do not think GC will be the problem and/ or bottleneck.

Allocating objects of different sizes and freeing them in a different sequence can lead to fragmented heap memory. So this is where allocating objects of the same size might come in handy.

If you really do allocate/ free a lot and really do see this as your bottleneck, try to re-use the objects with a local object cache. This can lead to performance increase, especially if they are data-only objects that do not implement a lot of logic. If the objects do implement a lot of logic and require mor complex initialisation (RAII-pattern) I would forego the performance increase for robustness of the program...

hth

Mario

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.