kmemtrace - Kernel Memory Tracer
by Eduard - Gabriel Munteanu
kmemtrace helps kernel developers figure out two things:
1) how different allocators (SLAB, SLUB etc.) perform
2) how kernel code allocates memory and how much
To do this, we trace every allocation and export information to the userspace
through the relay interface. We export things such as the number of requested
bytes, the number of bytes actually allocated (i.e. including internal
fragmentation), whether this is a slab allocation or a plain kmalloc() and so
The actual analysis is performed by a userspace tool (see section III for
details on where to get it from). It logs the data exported by the kernel,
processes it and (as of writing this) can provide the following information:
- the total amount of memory allocated and fragmentation per call-site
- the amount of memory allocated and fragmentation per allocation
- total memory allocated and fragmentation in the collected dataset
- number of cross-CPU allocation and frees (makes sense in NUMA environments)
Moreover, it can potentially find inconsistent and erroneous behavior in
kernel code, such as using slab free functions on kmalloc'ed memory or
allocating less memory than requested (but not truly failed allocations).
kmemtrace also makes provisions for tracing on some arch and analysing the
data on another.
II. Design and goals
kmemtrace was designed to handle rather large amounts of data. Thus, it uses
the relay interface to export whatever is logged to userspace, which then
stores it. Analysis and reporting is done asynchronously, that is, after the
data is collected and stored. By design, it allows one to log and analyse
on different machines and different arches.
As of writing this, the ABI is not considered stable, though it might not
change much. However, no guarantees are made about compatibility yet. When
deemed stable, the ABI should still allow easy extension while maintaining
backward compatibility. This is described further in Documentation/ABI.
Summary of design goals:
- allow logging and analysis to be done across different machines
- be fast and anticipate usage in high-load environments (*)
- be reasonably extensible
- make it possible for GNU/Linux distributions to have kmemtrace
included in their repositories
(*) - one of the reasons Pekka Enberg's original userspace data analysis
tool's code was rewritten from Perl to C (although this is more than a
III. Quick usage guide
1) Get a kernel that supports kmemtrace and build it accordingly (i.e. enable
2) Get the userspace tool and build it:
$ git clone git://repo.or.cz/kmemtrace-user.git # current repository
$ cd kmemtrace-user/
3) Boot the kmemtrace-enabled kernel if you haven't, preferably in the
'single' runlevel (so that relay buffers don't fill up easily), and run
# '$' does not mean user, but root here.
$ mount -t debugfs none /sys/kernel/debug
$ mount -t proc none /proc
$ cd path/to/kmemtrace-user/
Wait a bit, then stop it with CTRL+C.
$ cat /sys/kernel/debug/kmemtrace/total_overruns # Check if we didn't
# overrun, should
# be zero.
$ (Optionally) [Run kmemtrace_check separately on each cpu[0-9]*.out file to
check its correctness]
Now you should have a nice and short summary of how the allocator performs.
IV. FAQ and known issues
Q: 'cat /sys/kernel/debug/kmemtrace/total_overruns' is non-zero, how do I fix
this? Should I worry?
A: If it's non-zero, this affects kmemtrace's accuracy, depending on how
large the number is. You can fix it by supplying a higher
'kmemtrace.subbufs=N' kernel parameter.
Q: kmemtrace_check reports errors, how do I fix this? Should I worry?
A: This is a bug and should be reported. It can occur for a variety of
- possible bugs in relay code
- possible misuse of relay by kmemtrace
- timestamps being collected unorderly
Or you may fix it yourself and send us a patch.
Q: kmemtrace_report shows many errors, how do I fix this? Should I worry?
A: This is a known issue and I'm working on it. These might be true errors
in kernel code, which may have inconsistent behavior (e.g. allocating memory
with kmem_cache_alloc() and freeing it with kfree()). Pekka Enberg pointed
out this behavior may work with SLAB, but may fail with other allocators.
It may also be due to lack of tracing in some unusual allocator functions.
We don't want bug reports regarding this issue yet.
V. See also