On Wed, 13 Apr 2011 15:56:00 +0200, Pintu Agarwal
<pintu_agarwal@xxxxxxxxx> wrote:
My requirement is, I wanted to measure memory fragmentation level in
linux kernel2.6.29 (ARM cortex A8 without swap).
How can I measure fragmentation level(percentage) from /proc/buddyinfo ?
[...]
In my linux2.6.29 ARM machine, the initial /proc/buddyinfo shows the
following:
Node 0, zone DMA 17 22 1 1 0 1
1 0 0 0 0 0
Node 1, zone DMA 15 320 423 225 97 26
1 0 0 0 0 0
After running my sample program (with 16 iterations) the buddyinfo
output is as follows:
Requesting <16> blocks of memory of block size <262144>........
Node 0, zone DMA 17 22 1 1 0 1
1 0 0 0 0 0
Node 1, zone DMA 15 301 419 224 96 27
1 0 0 0 0 0
nr_free_pages 169
nr_free_pages 6545
*****************************************
Node 0, zone DMA 17 22 1 1 0 1
1 0 0 0 0 0
Node 1, zone DMA 18 2 305 226 96 27
1 0 0 0 0 0
nr_free_pages 169
nr_free_pages 5514
-----------------------------------------
The requested block size is 64 pages (2^6) for each block.
But if we see the output after 16 iterations the buddyinfo allocates
pages only from Node 1 , (2^0, 2^1, 2^2, 2^3).
But the actual allocation should happen from (2^6) block in buddyinfo.
No. When you call malloc() only virtual address space is allocated. The
actual allocation of physical space occurs when user space accesses the
memory (either reads or writes) and it happens page at a time.
As a matter of fact, if you have limited number of 0-order pages and
allocates in user space block of 64 pages later accessing the memory,
what really happens is that kernel allocates the 0-order pages and when
it runs out of those, splits a 1-order page into two 0-order pages and
takes one of those.
Because of MMU, fragmentation of physical memory is not an issue for
normal user space programs.
It becomes an issue once you deal with hardware that does not have MMU
nor support for scatter-getter DMA or with some big kernel structures.
/proc/buddyinfo tells you how many free pages of given order there are
in the system. You may interpret it in such a way that the bigger number
of the low order pages the bigger fragmentation of physical memory. If
there was no fragmentation (for some definition of the term) you'd get only
the highest order pages and at most one page for each lower order.
Again though, this fragmentation is not an issue for user space programs.
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