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I'm trying to wrap my head around the internals of Windows memory management at the OS level.

Is it true that when memory is allocated, it always triggers a page fault behind the scenes? Does this imply that the only way to stop soft page faults is to stop allocating new memory within the process?


I define "memory allocation" as any form of malloc, i.e. new, LocalAlloc, VirtualAlloc, HeapAlloc, etc.

I define a "page fault" as the process of mapping memory from the OS pool into the process Working Set, an operation which takes a constant 250us on a high end Xeon.

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"Is it true that when memory is allocated, it always triggers a page fault? In other words, the only way to stop page faults is to stop allocating new memory" Logically, if the first sentence is true, this doesn't mean, that the second is true as well. –  0123456789 Sep 3 '12 at 13:38
Your "250us on a high end Xeon" is way off. I'm not sure where you got that from. 6us is typical. –  David Schwartz Sep 3 '12 at 13:44
@Alex Farber. You are correct. The first sentence does not imply the second. However, is the second sentence correct? I have clarified the second statement. –  Contango Sep 3 '12 at 14:06
LocalAlloc and HeapAllioc are a higher level than VirtualAlloc. If LocalAlloc and HeapAlloc can find recently freed (and not decommitted) memory to reuse, they can do that without incurring a page fault. The page fault is incurred on first access to committed memory. –  Raymond Chen Sep 3 '12 at 14:46
@DavidSchwartz: "Your '250us on a high end Xeon' is way off [...] 6us is typical." -- Hehehe, yes... one should seriously hope so! On my no-high-end Core2 which runs in power-save mode, some memory hungry processes have upwards of 25,000 faults per second. At 250µs per fault, the computer would stop doing anything except handling faults at 4,000 faults per second. –  Damon Sep 3 '12 at 15:04

2 Answers 2

up vote 7 down vote accepted

You need to be very clear about the different things that are going on here. There are two independent parts to the process, committing the memory and paging the memory into the process. Neither of these are related to calling malloc, HeapAlloc or LocalAlloc.

I've tried to break the process down for you below, but the summary is that if you use HeapAlloc or another equivalent function then you'll trigger very few page-faults (at least once your application has initialized and the heap has grown to a stable size) and so shouldn't worry about it too much.

Allocating memory

When you call malloc, HeapAlloc or LocalAlloc the memory allocator will try to find a piece of memory in the heap that's available and large enough. In the majority of cases it will succeed and return the memory to you.

If it can not find sufficient memory it will allocate more by calling VirtualAlloc (on Linux this would be sbrk or mmap). This commits the memory. It will return a small fragment of the new memory to you.

Memory commitment

When you, or the allocator, call VirtualAlloc this will mark a new region of your virtual memory as accessible. This does not trigger a page-fault, nor does it actually assign physical memory to those pages. From the MSDN docs for VirtualAlloc:

Allocates memory charges (from the overall size of memory and the paging files on disk) for the specified reserved memory pages. The function also guarantees that when the caller later initially accesses the memory, the contents will be zero. Actual physical pages are not allocated unless/until the virtual addresses are actually accessed.

Paging memory in

When you access a page of memory that VirtualAlloc has returned to you for the first time this triggers a soft page-fault. The operating system will find a single page of free physical memory, zero it out and assign it to the virtual page you accessed. This is transparent to you and takes very little time (a single-digit number of microseconds). It's plausible that the operating system may swap this memory out to disk if you stop using it, if it does then a subsequent access will trigger a hard page-fault.

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Excellent answer, thank you. –  Contango Sep 3 '12 at 15:33
Surely a better answer than my half-guesses! –  Kerrek SB Sep 3 '12 at 15:41
@jleahy Truly superb answer, I understand whats going on now. More importantly, I think this opens up a technique to eliminate all of the page faults in our .NET app, by increasing the size of the Working Set to 8GB with a C++ .dll. –  Contango Sep 3 '12 at 21:23
Quote from MSDN on VirtuaLock, see…. "Each version of Windows has a limit on the maximum number of pages a process can lock. This limit is intentionally small to avoid severe performance degradation. Applications that need to lock larger numbers of pages must first call the SetProcessWorkingSetSize function to increase their minimum and maximum working set sizes ... Pages that a process has locked remain in physical memory ... These pages are guaranteed not to be written to the pagefile while they are locked." –  Contango Sep 3 '12 at 21:26
@Gravitas I wasn't aware of that function, that's quite nice. If you want to completely eliminate page-faults you should also pre-fault the stack. Allocate a large buffer in a function and memset it to some dummy value, that way you can avoid a page-fault when you make an unusually deep call for the first time. –  jleahy Sep 4 '12 at 6:40

Well, yes, a page fault will bring the CPU back into kernel mode, and the kernel gets a chance to learn that the userspace process wanted a certain memory page. The kernel can then consult its internal memory management bookkeeping data, make a suitably large area of physical memory available, and adjust the processor's page table so that the requested virtual address is mapped. Once that's done, execution passes back to the userspace process, which resumes with a successful allocation.

This is not to be confused with an unexpected page fault, by which the userspace process refers to an address that is neither mapped in the page tables nor known to the kernel's memory manager to belong to the process. In that case, the kernel will kill the rogue process.

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But can't the allocation be made just within existing (in page table) memory pages? –  raina77ow Sep 3 '12 at 14:19
@raina77ow: The userspace allocation function won't even go to the kernel if there's already enough userspace memory available. The situation in question only arises if you're genuinely out of userspace memory and need to get more from the kernel. –  Kerrek SB Sep 3 '12 at 14:19
@Gravitas: Not portably to my knowledge, but I imagine if you malloc and immediately free a huge amount of memory, you retain the pages. No promise, though! (tcmalloc in Linux never returns memory, so that does indeed have that behaviour.) –  Kerrek SB Sep 3 '12 at 14:27
@Gravitas Well, from what I've read about allocation strategies, they actually differ on amount of page faults; hence my question to Kerrek SB. ) –  raina77ow Sep 3 '12 at 14:29
Allocating and freeing is not enough, but allocating, touching, and freeing should be, provided that you've adjusted your minimum working set size (the default is ridiculously low, so page faults happen all the time). Allocating and freeing (even locking) is a no-op unless actually touching every page. –  Damon Sep 3 '12 at 14:49

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