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This morning I stumbled across a surprising number of page faults where I did not expect them. Yes, I probably should not worry, but it still strikes me odd, because in my understanding they should not happen. And, I'd like better if they didn't.

The application (under WinXP Pro 32bit) reserves a larger section (1GB) of address space with VirtualAlloc(MEM_RESERVE) and later allocates moderately large blocks (20-50MB) of memory with VirtualAlloc(MEM_COMMIT). This is done in a worker ahead of time, the intent being to stall the main thread as little as possible. Obviously, you cannot ever assure that no page faults happen unless the memory region is currently locked, but a few of them are certainly tolerable (and unavoidable). Surprisingly every single page faults. Always.

The assumption was thus that the system only creates pages lazily after allocating them, which somehow makes sense too (although the documentation suggests something different). Fair enough, my bad.
The obvious workaround is therefore VirtualLock/VirtualUnlock, which forces the system to create those pages, as they must exist after VirtualLock returns. Surprisingly, still every single page faults.

So I wrote a little test program which did all above steps in sequence, sleeping 5 seconds in between each, to rule out something was wrong in the other code. The results were:

  • MEM_RESERVE 1GB ---> success, zero CPU, zero time, nothing happens
  • MEM_COMMIT 1 GB ---> success, zero CPU, zero time, working set increases by 2MB, 512 page faults (respectively 8 bytes of metadata allocated in user space per page)
  • for(... += 128kB) { VirtualLock(128kB); VirtualUnlock(128kB); } ---> success, zero CPU, zero time, nothing happens
  • for(... += 4096) *addr = 0; ---> 262144 page faults, about 0.25 seconds (~95% kernel time). 1GB increase for both "working set" and "physical" inside Process Explorer
  • VirtualFree ---> zero CPU, zero time, both "working set" and "physical" instantly go * poof *.

My expectation was that since each page had been locked once, it must physically exist at least after that. It might of course still be moved in and out of the WS as the quota is exceeded (merely changing one reference as long as sufficient RAM is available). Yet, neither the execution time, nor the working set, nor the physical memory metrics seem to support this. Rather, as it looks, each single accessed page is created upon faulting, even if it had been locked previously. Of course I can touch every page manually in a worker thread, but there must be a cleaner way too?

Am I making a wrong assumption about what VirtualLock should do or am I not understanding something right about virtual memory? Any idea about how to tell the OS in a "clean, legitimate, working" way that I'll be wanting memory, and I'll be wanting it for real?

In reaction to Harry Johnston's suggestion, I tried the somewhat problematic approach of actually calling VirtualLock on a gigabyte of memory. For this to succeed, you must first set the process' working set size accordingly, since the default quotas are 200k/1M, which means VirtualLock cannot possibly lock a region larger than 200k (or rather, it cannot lock more than 200k alltogether, and that is minus what is already locked for I/O or for another reason).

After setting a minimum working set size of 1GB and a maximum of 2GB, all the page faults happen the moment VirtualAlloc(MEM_COMMIT) is called. "Virtual size" in Process Explorer jumps up by 1GB instantly. So far, it looked really, really good.
However, looking closer, "Physical" remains as it is, actual memory is really only used the moment you touch it.

VirtualLock remains a no-op (fault-wise), but raising the minimum working set size kind of got closer to the goal.

There are two problems with tampering the WS size, however. First, you're generally not meant to have a gigabyte of minimum working set in a process, because the OS tries hard to keep that amount of memory locked. This would be acceptable in my case (it's actually more or less just what I ask for).
The bigger problem is that SetProcessWorkingSetSize needs the the PROCESS_SET_QUOTA access right, which is no problem as "administrator", but it fails when you run the program as a restricted user (for a good reason), and it triggers the "allow possibly harmful program?" alert of some well-known Russian antivirus software (for no good reason, but alas, you can't turn it off).

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What happens if you don't call VirtualUnlock in the first loop? Arguably, VirtualLock + VirtualUnlock together are a noop, so perhaps the compiler is optimizing them out of existence. –  Harry Johnston Oct 25 '11 at 1:25
@Harry Johnston: Keeping a gigabyte of memory locked is problematic, but nevertheless interesting, see the update to the question (to follow in a minute). –  Damon Oct 25 '11 at 12:35
What's happening is that each VirtualLock is re-using the memory unlocked by the previous VirtualUnlock, so you merely cycled all your app's memory through a 128kb window. Assuming you don't have quota privilege or "lock physical pages" privilege, you could have the main thread signal the worker thread "I'm currently using memory X, and I'm going to be needing X+1 soon" and then the worker thread can go unlock X-1 and lock X+1, trying to stay one step ahead of the main thread. –  Raymond Chen Oct 25 '11 at 13:20
@RaymondChen: That would be a kind of "prefetching on page level", which would probably work with a more or less linear, predicatable access pattern. Though I guess that it's probably less trouble if I indeed stay with just touching every page once. My concern is not so much about locking pages in RAM before they are accessed (the target machines have enough physical RAM so it's a rather safe bet that a gigabyte worth of pages stays in RAM), but about actually creating the pages upon allocation, so this needs not happen later. Locking does not seem to do that, if Proc Explorer isn't lying. –  Damon Oct 26 '11 at 10:32
@RaymondChen: Since you already gave the good answer about cycling through the same 128k all over (it's not what I hoped for, I'd like it to work... but it's definitively what happens), if you were so kind to convert your comment to a question, I'd accept that one. –  Damon Mar 8 '12 at 11:39
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3 Answers 3

up vote 2 down vote accepted

Technically VirtualLock is a hint, and so the OS is allowed to ignore it. It's backed by the NtLockVirtualMemory syscall which on Reactos/Wine is implemented as a no-op, however Windows does back the syscall with real work (MiLockVadRange).

VirtualLock isn't guarranteed to succeed. Calls to this function require the SE_LOCK_MEMORY_PRIVILEGE to work, and the addresses must fulfil security and quota restrictions. Additionally after a VirtualUnlock, the kernel is no longer obliged to keep your page in memory, so a page fault after that is a valid action.

And as Raymond Chen points out, when you unlock the memory it can formally release the page. This means that the next VirtualLock on the next page might obtain that very same page again, so when you touch the original page you'll still get a page-fault.

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Sorry, I have to disagree on your answer. According to the documentation, VirtualLock is very clearly not a hint, locking pages is not understood that way under other systems (e.g. the POSIX equivalent mlock) either. Whether or not the function is broken in ReactOS is not irrelevant. It is true that VirtualLock is not guaranteed to succeed, but again this is irrelevant, since the question states that it does succeed, yet the result is not what's expected. It is true that the kernel is not obliged to keep a page that is not locked in memory, but this is a sophistry... –  Damon Mar 8 '12 at 11:29
... the question is not about some pages faulting (I am very well aware that page faults may happen and will happen), but about all pages faulting every single time, no exception. The decisively important thing is what Raymond Chen basically pointed out is that the OS is kind of "cheating" by only ever showing the same few pages to you (or anyone else), as long as nobody actually touches them, without even creating pages that it guarantees formally exist at a given time (after being locked). –  Damon Mar 8 '12 at 11:35
When I said "hint" I meant you are asking the kernel to do something that the kernel can choose to not do. Actually the very same Raymond Chen noted here (blogs.msdn.com/b/oldnewthing/archive/2007/11/06/5924058.aspx) that locking pages into memory DOESNT guarantee that the pages get paged out, and hence DOESNT guarantee that subsequent touches don't incur a page-fault. Reactos and Wine implement it as a NOP because the cost of implementing this function is high given the fact that it is a hint. –  SecurityMatt Mar 8 '12 at 18:57
The reason why all of your pages are causing a page-fault later is because they are all still in their initial condition of being zero - which means that they are all backed by the kernel zero page and marked by the kernel as copy-on-write. Consequently when you touch the pages for writing in your example, each touch on each page causes a page fault whilst the kernel allocates a new page, copies the old page and then returns execution to you. VirtualLock locks your memory into the working set of the process ... –  SecurityMatt Mar 8 '12 at 18:59
... there's no guarrantee that all of those pages are backed by physical memory at the same actual (PAE) protection as the Windows lpProtect-ion of the pages, and hence even if you VirtualLock the entire region properly, you'll still get a page-fault on each page as you touch it for the first time. –  SecurityMatt Mar 8 '12 at 19:02
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VirtualLock remains a no-op (fault-wise)

I tried to reproduce this, but it worked as one might expect. Running the example code shown at the bottom of this post:

  • start application (523 page faults)
  • adjust the working set size (21 page faults)
  • VirtualAlloc with MEM_COMMIT 2500 MB of RAM (2 page faults)
  • VirtualLock all of that (about 641,250 page faults)
  • perform writes to all of this RAM in an infinite loop (zero page faults)

This all works pretty much as expected. 2500 MB of RAM is 640,000 pages. The numbers add up. Also, as far as the OS-wide RAM counters go, commit charge goes up at VirtualAlloc, while physical memory usage goes up at VirtualLock.

So VirtualLock is most definitely not a no-op on my Win7 x64 machine. If I don't do it, the page faults, as expected, shift to where I start writing to the RAM. They still total just over 640,000. Plus, the first time the memory is written to takes longer.

Rather, as it looks, each single accessed page is created upon faulting, even if it had been locked previously.

This is not wrong. There is no guarantee that accessing a locked-then-unlocked page won't fault. You lock it, it gets mapped to physical RAM. You unlock it, and it's free to be unmapped instantly, making a fault possible. You might hope it will stay mapped, but no guarantees...

For what it's worth, on my system with a few gigabytes of physical RAM free, it works the way you were hoping for: even if I follow my VirtualLock with an immediate VirtualUnlock and set the minimum working set size back to something small, no further page faults occur.

Here's what I did. I ran the test program (below) with and without the code that immediately unlocks the memory and restores a sensible minimum working set size, and then forced physical RAM to run out in each scenario. Before forcing low RAM, neither program gets any page faults. After forcing low RAM, the program that keeps the memory locked retains its huge working set and has no further page faults. The program that unlocked the memory, however, starts getting page faults.

This is easiest to observe if you suspend the process first, since otherwise the constant memory writes keep it all in the working set even if the memory isn't locked (obviously a desirable thing). But suspend the process, force low RAM, and watch the working set shrink only for the program that has unlocked the RAM. Resume the process, and witness an avalanche of page faults.

In other words, at least in Win7 x64 everything works exactly as you expected it to, using the code supplied below.

There are two problems with tampering the WS size, however. First, you're generally not meant to have a gigabyte of minimum working set in a process

Well... if you want to VirtualLock, you are already tampering with it. The only thing that SetProcessWorkingSetSize does is allow you to tamper with it. It doesn't degrade performance by itself; it's VirtualLock that does - but only if the system actually runs low on physical RAM.

Here's the complete program:

#include <stdio.h>
#include <tchar.h>
#include <Windows.h>
#include <iostream>

using namespace std;

int _tmain(int argc, _TCHAR* argv[])
    SIZE_T chunkSize = 2500LL * 1024LL * 1024LL; // 2,626,568,192 = 640,000 pages
    int sleep = 5000;


    cout << "Setting working set size... ";
    if (!SetProcessWorkingSetSize(GetCurrentProcess(), chunkSize + 5001001L, chunkSize * 2))
        return -1;
    cout << "done" << endl;


    cout << "VirtualAlloc... ";
    UINT8* data = (UINT8*) VirtualAlloc(NULL, chunkSize, MEM_COMMIT, PAGE_READWRITE);
    if (data == NULL)
        return -2;
    cout << "done" << endl;


    cout << "VirtualLock... ";
    if (VirtualLock(data, chunkSize) == 0)
        return -3;
    //if (VirtualUnlock(data, chunkSize) == 0) // enable or disable to experiment with unlocks
    //    return -3;
    //if (!SetProcessWorkingSetSize(GetCurrentProcess(), 5001001L, chunkSize * 2))
    //    return -1;
    cout << "done" << endl;


    cout << "Writes to the memory... ";
    while (true)
        int* end = (int*) (data + chunkSize);
        for (int* d = (int*) data; d < end; d++)
            *d = (int) d;
        cout << "done ";

    return 0;

Note that this code puts the thread to sleep after VirtualLock. According to a 2007 post by Raymond Chen, the OS is free to page it all out of physical RAM at this point and until the thread wakes up again. Note also that MSDN claims otherwise, saying that this memory will not be paged out, regardless of whether all threads are sleeping or not. On my system, they certainly remain in the physical RAM while the only thread is sleeping. I suspect Raymond's advice applied in 2007, but is no longer true in Win7.

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I don't have enough reputation to comment, so I'll have to add this as an answer.

Note that this code puts the thread to sleep after VirtualLock. According to a 2007 post by Raymond Chen, the OS is free to page it all out of physical RAM at this point and until the thread wakes up again [...] I suspect Raymond's advice applied in 2007, but is no longer true in Win7.

What romkyns said has been confirmed by Raymond Chen in 2014. That is, when you lock memory with Virtual­Lock, it will remain locked even if all your threads are blocked. He also says the fact that pages remain locked, may be just an implementation detail and not contractual.

This is probably not the case, because according to msdn, it is contractual

Pages that a process has locked remain in physical memory until the process unlocks them or terminates. These pages are guaranteed not to be written to the pagefile while they are locked.

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