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I built a quick program that needed to loop through an enormous log file (a couple of million records) and find various bits and pieces from inside. Because the volume of data was so huge, I have been curious to watch my Windows Task Manager performance tab and see how much CPU and memory is being used.

After the program successfully gets my results, the CPU usage goes right down, obviously. But after watching my memory usage slowly go up to several gigabytes during execution, it stays the same.

I have tried to call GC.Collect() at the end of my function, tried setting things to null, tried to run the program in Release mode (I heard that GC.Collect() might not work as I want it to in debug mode).

The memory usage goes right down if I close the program, but I can't figure out why I can't clean my app up during the apps lifetime. At the end of the day this is a throwaway app, but I'm just curious to know what I'm missing i.e. what is holding on to all this memory.


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10 Answers 10

up vote 3 down vote accepted

The garbage collector is not guaranteed to run when you call Collect(). It simply flags the object for collection. The next time the GC runs it will "collect" the flagged object.

There is no way in .NET to force the GC to collect at a specific point in time - if you need this functionality you'll need to go to native code.

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I used to force garbage collection with this code. Specially when dealing with COM objects: GC.Collect() GC.WaitForPendingFinalizers() –  amrtn May 20 '09 at 14:40
Thanks. By "native code" you mean unmanaged C#, or using something outside of .NET's managed environment? –  Alex York May 20 '09 at 14:41
Something outside of .NET. C++ or similar. –  rein May 20 '09 at 15:22

Calling GC.Collect() is only a request to collect garbage, it's not an order, so the CLR may choose to ignore the request if it sees fit.

For example, if there's a lot of garbage that would cause a noticable delay whilst collecting, but there's still free memory to service subsequent allocations, then the GC may opt to ignore your request.

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Actually GC.Collect() is per default the forced GC which will right at this moment start the GC-collection-thread. You can suspend your own thread with GC.WaitForPendingFinalizers. –  Leonidas May 20 '09 at 14:38
Thanks Sean, I suspected this was the case but you have confirmed it. I'm giving the other guy the correct answer though for explaining how to fix it if I wanted to. –  Alex York May 20 '09 at 14:40
Really? My reading of the docs is that it forces a GC call for all generations, but that this doesn't mean that it will collect garbage. All if says is to look at all generations, regardless of how long they've been in memory. This isn't the same as removing the garbage. –  Sean May 20 '09 at 14:43

It is possible that your objects are still rooted somehow. You could try using a memory profiler to see if this is the case. I usually recommend SciTech's .NET Memory Profiler to do this but Red-Gate also has a decent memory profiler. Both SciTech and Red-Gate have trial versions available. It is also possible using WinDBG with SOS.

There is a somewhat out of date list of all profilers here.

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It's normal for many memory allocators (with or w/o garbage collection) to "hoard" the memory they've freed, rather than give it back to the OS, because in many situations the memory just freed will be requested again and it's faster to keep it in the process rather than keep giving it back and asking the OS for it again and again (giving it back &c also requires extra effort due to page alignment issues and the like).

In a one-shot app, as you mention, that's not a problem. When I have a long-running app that has what I know will be a transient requirement for a lot of memory, one approach I use is to spawn a sub-process to perform the memory-hungry stuff, since when that process ends the OS will claw back the memory. It's easier on Unix systems (just fork) but not too bad on Windows, either, when warranted.

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There is a way. I found this article, it is in spanish by sure you understand the code, it works, I tested [http://www.nerdcoder.com/c-net-forzar-liberacion-de-memoria-de-nuestras-aplicaciones/][1]

[DllImport("kernel32.dll", EntryPoint = "SetProcessWorkingSetSize", ExactSpelling = true, CharSet = CharSet.Ansi, SetLastError = true)]
private static extern int SetProcessWorkingSetSize(IntPtr process, int minimumWorkingSetSize, int maximumWorkingSetSize);
public static void alzheimer()
    SetProcessWorkingSetSize(System.Diagnostics.Process.GetCurrentProcess().Handle, -1, -1);
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A proper answer copies the relevant information outward here to the question itself, and then post a link to the reference article, especially considering it's not in English. –  JoshDM May 13 '13 at 0:52
Upvoted since this answer, while lacking in detail, actually works –  ChaseMedallion May 12 at 19:52

The Collect method does not guarantee that all inaccessible memory is reclaimed.

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Don't forget that the CLR is ultimately using the underlying memory manager in the Windows kernel, which may have its own policies about when to release memory. For example, if the memory you're using comes from a pool, it may just be returned to the pool rather than deallocated when you free it at the user level. So it's entirely possible that there could be (and probably will be) a discrepancy between how much memory your app is holding and how much memory is allocated to the process.

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to force GC.Collect to do collection, call it like this GC.Collect(2); this means you are asking the GC to do a full blocking GC for the whole heap, 2 means Generation 2 of your heap.

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Do any of the objects used in your loop implement IDisposable?

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You should look at the performance counters for the sizes of the CLR heaps, not the total memory allocated to the process shown in the task manager. Windows won't reclaim the memory allocated to the process unless the system as a whole is starved for memory, even if the process doesn't use the memory for anything.

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