17

Is there a way to put the GC on hold completely for a section of code? The only thing I've found in other similar questions is GC.TryStartNoGCRegion but it is limited to the amount of memory you specify which itself is limited to the size of an ephemeral segment.

Is there a way to bypass that completely and tell .NET "allocate whatever you need, don't do GC period" or to increase the size of segments? From what I found it is at most 1GB on a many core server and this is way less than what I need to allocate yet I don't want GC to happen (I have up to terabytes of free RAM and there are thousands of GC spikes during that section, I'd be more than happy to trade those for 10 or even 100 times the RAM usage).

Edit:

Now that there's a bounty I think it's easier if I specify the use case. I'm loading and parsing a very large XML file (1GB for now, 12GB soon) into objects in memory using LINQ to XML. I'm not looking for an alternative to that. I'm creating millions of small objects from millions of XElements and the GC is trying to collect non-stop while I'd be very happy keeping all that RAM used up. I have 100s of GBs of RAM and as soon as it hits 4GB used, the GC starts collecting non-stop which is very memory friendly but performance unfriendly. I don't care about memory but I do care about performance. I want to take the opposite trade-off.

While i can't post the actual code here is some sample code that is very close to the end code that may help those who asked for more information :

var items = XElement.Load("myfile.xml")
.Element("a")
.Elements("b") // There are about 2 to 5 million instances of "b"
.Select(pt => new
{
    aa = pt.Element("aa"),
    ab = pt.Element("ab"),
    ac = pt.Element("ac"),
    ad = pt.Element("ad"),
    ae = pt.Element("ae")
})
.Select(pt => new 
{
    aa = new
    {
        aaa = double.Parse(pt.aa.Attribute("aaa").Value),
        aab = double.Parse(pt.aa.Attribute("aab").Value),
        aac = double.Parse(pt.aa.Attribute("aac").Value),
        aad = double.Parse(pt.aa.Attribute("aad").Value),
        aae = double.Parse(pt.aa.Attribute("aae").Value)
    },
    ab = new
    {
        aba = double.Parse(pt.aa.Attribute("aba").Value),
        abb = double.Parse(pt.aa.Attribute("abb").Value),
        abc = double.Parse(pt.aa.Attribute("abc").Value),
        abd = double.Parse(pt.aa.Attribute("abd").Value),
        abe = double.Parse(pt.aa.Attribute("abe").Value)
    },
    ac = new
    {
        aca = double.Parse(pt.aa.Attribute("aca").Value),
        acb = double.Parse(pt.aa.Attribute("acb").Value),
        acc = double.Parse(pt.aa.Attribute("acc").Value),
        acd = double.Parse(pt.aa.Attribute("acd").Value),
        ace = double.Parse(pt.aa.Attribute("ace").Value),
        acf = double.Parse(pt.aa.Attribute("acf").Value),
        acg = double.Parse(pt.aa.Attribute("acg").Value),
        ach = double.Parse(pt.aa.Attribute("ach").Value)
    },
    ad1 = int.Parse(pt.ad.Attribute("ad1").Value),
    ad2 = int.Parse(pt.ad.Attribute("ad2").Value),
    ae = new double[]
    {
        double.Parse(pt.ae.Attribute("ae1").Value),
        double.Parse(pt.ae.Attribute("ae2").Value),
        double.Parse(pt.ae.Attribute("ae3").Value),
        double.Parse(pt.ae.Attribute("ae4").Value),
        double.Parse(pt.ae.Attribute("ae5").Value),
        double.Parse(pt.ae.Attribute("ae6").Value),
        double.Parse(pt.ae.Attribute("ae7").Value),
        double.Parse(pt.ae.Attribute("ae8").Value),
        double.Parse(pt.ae.Attribute("ae9").Value),
        double.Parse(pt.ae.Attribute("ae10").Value),
        double.Parse(pt.ae.Attribute("ae11").Value),
        double.Parse(pt.ae.Attribute("ae12").Value),
        double.Parse(pt.ae.Attribute("ae13").Value),
        double.Parse(pt.ae.Attribute("ae14").Value),
        double.Parse(pt.ae.Attribute("ae15").Value),
        double.Parse(pt.ae.Attribute("ae16").Value),
        double.Parse(pt.ae.Attribute("ae17").Value),
        double.Parse(pt.ae.Attribute("ae18").Value),
        double.Parse(pt.ae.Attribute("ae19").Value)
    }
})
.ToArray();
3
+50

I think the best solution in your case would be this piece of code I used in one of my projects some times ago

var currentLatencySettings = GCSettings.LatencyMode;   
GCSettings.LatencyMode = GCLatencyMode.LowLatency;

//your operations

GCSettings.LatencyMode = currentLatencySettings;

You are surpressing as much as you can (according to my knowledge) and you can still call GC.Collect() manually.

Look at the MSDN article here

Also, I would strongly suggest paging the parsed collection using LINQ Skip() and Take() methods. And finally joining the output arrays

  • As mentioned in the comments my issue isn't gen 2 collection but that i'm creating many small objects (so gen 0 and 1), i don't think this would have any effect althought as i mentioned i will try it (server is busy on another task at the moment). – Ronan Thibaudau May 19 '16 at 16:21
  • Awarded you the bounty as there were no more fitting answers, thanks! – Ronan Thibaudau May 26 '16 at 13:25
  • Glad to hear that, sorry I couldn't be of more help – Peuczynski May 26 '16 at 13:27
2

Currently the best i could find was switching to server GC (which changed nothing by itself) that has larger segment size and let me use a much larger number for no gc section :

        GC.TryStartNoGCRegion(10000000000); // On Workstation GC this crashed with a much lower number, on server GC this works

It goes against my expectations (this is 10GB, yet from what i could find in the doc online my segment size in my current setup should be 1 to 4GB so i expected an invalid argument).

With this setup i have what i wanted (GC is on hold, i have 22GB allocated instead of 7, all the temporary objects aren't GCed, but the GC runs once (a single time!) over the whole batch process instead of many many times per second (before the change the GC view in visual studio looked like a straight line from all the individual dots of GC triggering).

This isn't great as it won't scale (adding a 0 leads to a crash) but it's better than anything else i found so far.

Unless anyone finds out how to increase the segment size so that i can push this further or has a better alternative to completely halt the GC (and not just a certain generation but all of it) i will accept my own answer in a few days.

  • 2
    If those who downvoted made themselves known instead of just voting and going it would help me improve the answer for future readers instead of well, pondering what to do about it! – Ronan Thibaudau May 23 '16 at 11:12
  • Some people's minds are not flexible enough to get into the details of why you want to prevent GC. They think you have chosen wrong language etc etc. I find its reasonable to stop GC in your case, dont bother too much about downvoters. – Evk May 23 '16 at 18:47
  • If it can make you feel better I got downvoted without a comment when I shared my knowledge q&a style stackoverflow.com/questions/37310418/… so I know how frustrating it can be – Peuczynski May 26 '16 at 12:29
1

I am not sure whether its possible in your case, however have you tried processing your XML file in parallel. If you can break down your XML file in smaller parts, you can spawn multiple processes from within your code. Each process handling a separate file. You can then combine all the results. This would certainly increase your performance and also with each process separately you will have its separate allocation of memory, which should also increase your memory allocation at a particular time while processing all the XML files.

  • No multiple process wouldn't help, it's not an xml processor, i'm just loading the whole of it because i need all of it, as an in memory object graph (the whole xml is exported just for that use case) – Ronan Thibaudau May 23 '16 at 11:07
  • 4
    @RonanThibaudau XML is text, and text processing isn't exactly known for its speed and memory efficiency (just think about the redundancy level in the tags alone). I bet 80% of the memory is wasted on XElement internals, and thousands of instances of copies of the same strings, and most of your processing time is spent on parsing. If the XML file is exported just for this, perhaps you could replace it with a custom binary serialization format - that should change things quite a bit. Speaking from experience here - when you start to have largish files custom serialization pays off. – Lucas Trzesniewski May 23 '16 at 22:17
  • @RonanThibaudau Could you please provide some details on how you use that in memory object graph. – DotNetDev May 24 '16 at 4:09
  • @LucasTrzesniewski I know the tradeoffs and i "do" want xml (the file must be human readable and clear, and the original graph from process A isn't in the same shape as the graph in process B so serialization would still mean having to do the conversion, i chose to have that as a clear xml intermediary format). Note that the performance is "just fine" for my need, and i don't care about memory being wasted which is the whole point of this thread, i have plenty of memory, i'm happy wasting it, i'm not happy with the GC trying to save some of it at the expense of performance – Ronan Thibaudau May 24 '16 at 7:49
  • 3
    @RonanThibaudau I understand, but the GC gets in your way because you're wasting memory, so wasting less of it will reduce the problem you're trying to solve. I'm skeptical about the need for a 12GB file to be human readable - but if that's really the case, then you could come up with a more efficient custom text-based storage format, and an optimized serializer. Are you sure the performance will stay "just fine" when you scale up? – Lucas Trzesniewski May 24 '16 at 9:47

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