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In Linux, when process asks for some (virtual) memory from system, it just registered in vma (descriptor of process's virtual memory) but physical page for every virtual is not reserved at time of call. Later, when process will access this page, it will be faulted (access will generate Page Fault interrupt), and PF# handler will allocate physical page and update process page table.

There are two cases: fault when reading may turn into link to zero page (special global pre-zeroed page) which is write-protected; and fault on writing (both on zero-page and on just-required-yet-not-physically mapped page) will result in actual private physical page allocation.

For mmaps (and brk/sbrk, which is internally mmap too) this method is per-page; all mmaped regions are registered as whole in vma (they have begin and end addresses). But stack is handled in other way, because it has only start address (higher one on typical platform; grow to lower addresses).

The question is:

When I access new unallocated memory near stack, it will get PF# and grow. How this growing handled, if I access not the page next to stack, but the page which is 10 or 100 pages away from stack?

E.g.

int main() {
  int *a = alloca(100); /* some useful data */
  int *b = alloca(50*4096); /* skip 49 pages */
  int *c = alloca(100);

  a[0]=1;
 /* no accesses to b - this is untouched hole of 49 pages */
  c[0]=1;

}

Will this program get 2 or 50 private physical pages allocated for stack?

I think it can be profitable to ask kernel to allocate tens physical pages in single pagefault then do tens pagefaults allocating page by page (1 interrupt + 1 context-switch + simple, cache-friendly loop over N page-allocation requests versus N interrupts + N context-switches + N page allocations, when mm code may be evicted from Icache).

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Thanks for an interesting question. (+1) –  NPE Dec 19 '12 at 10:13

2 Answers 2

up vote 2 down vote accepted

The automatic growing of the stack can be thought of as automatic calls to mremap to resize the virtual address region that counts as "stack". Once that's handled, page faults to the stack area or to a vanilla mmap region are handled the same, i.e., one page at a time.

Thus you should end up with ~2 pages allocated, not ~51. @perreal's empirical answer validates this ...

To the last part of the question, the cost of contiguous page faults is one of the factors that lead to the development of "huge pages". I don't think there are other ways in Linux to "batch" page fault handling. Maybe madvise might do something but I suspect its mostly optimizing the really expensive part of page faults which is looking up the backing pages on storage). Stack page faults which map to zero pages are relatively lightweight by comparison.

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And mlock(2) will prefault too. –  osgx Dec 23 '12 at 0:30

With this code:

int main() {
  int *a = alloca(100); /* some useful data */
  int *b = alloca(50*4096); /* skip 49 pages */
  int *c = alloca(100);
  int i;
#if TOUCH > 0
  a[0] = 1;               // [1]
#endif
#if TOUCH > 1
  c[0] = 1;               // [2]
#endif
#if TOUCH > 2
  for (i=0; i<25; i++)    // [3]
    b[i*1024] = 1;
#endif
#if TOUCH > 3
  for (i=25; i<50; i++)   // [4]
    b[i*1024] = 1;
#endif
  return 0;
}

And this script:

for i in 1 2 3 4; do
  gcc d.c -DTOUCH=$i
  echo "Upto [$i]" $(perf stat ./a.out 2>&1 | grep page-faults)
done

The output:

Upto [1] 105 page-faults # 0.410 M/sec
Upto [2] 106 page-faults # 0.246 M/sec
Upto [3] 130 page-faults # 0.279 M/sec
Upto [4] 154 page-faults # 0.290 M/sec
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So, around 104 page-faults are for the program code and its libraries.. –  osgx May 27 '13 at 1:48

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