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16

[I would make this a comment, but do not have enough reputation to do so.] I have a similar system and see similar results, but can add a few data points: If you reverse the direction of your naive memcpy (i.e. convert to *p_dest-- = *p_src--), then you may get much worse performance than for the forward direction (~637 ms for me). There was a change in ...


14

The first thing I want to point out is that you might want to double-check which cores are on each node. I don't recall cores and nodes being interleaved like that. Also, you should have 16 threads due to HT. (unless you disabled it) Another thing: The socket 1366 Xeon machines are only slightly NUMA. So it will be hard to see the difference. The NUMA ...


12

There is an move_pages function in -lnuma: http://linux.die.net/man/2/move_pages which can report current state of address(page) to node mappings: nodes can also be NULL, in which case move_pages() does not move any pages but instead will return the node where each page currently resides, in the status array. Obtaining the status of each page may be ...


11

The current OpenMP standard defines a boolean environment variable OMP_PROC_BIND that controlls binding of OpenMP threads. If set to true, e.g. shell$ OMP_PROC_BIND=true OMP_NUM_THREADS=12 ./app.x then the OpenMP execution environment should not move threads between processors. Unfortunately nothing more is said about how those threads should be bound and ...


10

Ah hah! Mysticial is right! Somehow, hardware pre-fetching is optimizing my read/writes. If it were a cache optimization, then forcing a memory barrier would defeat the optimization: c = __sync_fetch_and_add(((char*)x) + j, 1); but that doesn't make any difference. What does make a difference is multiplying my iterator index by prime 1009 to defeat the ...


8

Peter described the general JVM options available today to reduce the performance impact of NUMA architectures. To keep it short a NUMA aware JVM will partition the heap with respect to the NUMA nodes, and when a thread creates a new object, the object is allocated in the NUMA node of the core that runs that thread (if the same thread later uses it, the ...


7

Linux kernel knows about NUMA and will try to give your process pages from memory local to the current CPU (source: U. Drepper, "What Every Programmer Should Know About Memory".)


7

Thanks for this benchmark code. I've taken your 'fixed' version and changed it to pure C + OpenMP and added a few tests for how the memory system behaves under contention. You can find the new code here. Here are some sample results from a Quad Opteron: num cpus: 32 numa available: 0 numa node 0 10001000100010000000000000000000 - 15.9904 GiB numa node 1 ...


7

This looks normal to me. Managing 8x16GB ECC memory sticks with two CPUs is a much tougher job than a single CPU with 2x2GB. Your 16GB sticks are Double sided memory + they may have buffers + ECC (even disabled on motherboard level)... all that make data path to RAM much longer. You also have 2 CPUs sharing the ram, and even if you do nothing on the other ...


6

It's possible that some CPU improvements in your IvyBridge-based laptop contribute to this gain over the SandyBridge-based servers. Page-crossing Prefetch - your laptop CPU would prefetch ahead the next linear page whenever you reach the end of the current one, saving you a nasty TLB miss every time. To try and mitigate that, try building your server code ...


5

NUMA-aware memory allocation is not done at compile time. Making assumptions like this would be bad for portability. On Linux, this is a kernel function, though you can control this at runtime with numactl or set_mempolicy or with libnuma.


5

The presence of those /proc files indicates that your linux kernel is numa-aware. Don't concern yourself too much comparing version numbers, as, particularly with Oracle / RHEL kernels, the vendors port/backport many features without keeping the version string "up to date". Other ways of testing the same thing: $ grep NUMA=y /boot/config-`uname -r` ...


4

For MS platforms, the compiler is not aware of NUMA. However, the system is NUMA aware and will attempt to allocate memory in the same node. See http://code.msdn.microsoft.com/64plusLP for some more details on how recent versions of Windows handle NUMA.


4

I think you may be able to start with these manual pages: $ apropos affinity sched_getaffinity (2) - set and get a process's CPU affinity mask sched_setaffinity (2) - set and get a process's CPU affinity mask taskset (1) - retrieve or set a process's CPU affinity $ depending on whether you want to do that from the source code or the shell. The ...


4

The numa_alloc_*() functions in libnuma allocate whole pages of memory, typically 4096 bytes. Cache lines are typically 64 bytes. Since 4096 is a multiple of 64, anything that comes back from numa_alloc_*() will already be memaligned at the cache level. Beware the numa_alloc_*() functions however. It says on the man page that they are slower than a ...


4

There are a ton of memory pool managers out there, some commercial and some open source. Have a look at them, and feel free to ask more specific questions here after you have an overview. Some google results (c memory pool manager open source): http://256.com/sources/mpool/ http://www.ravenbrook.com/project/mps/ Here's a good article from IBM on the ...


4

Turns out my problem was a combination of numa and permissions issues. Thanks, @Mark for the help. To start mongodb as a daemon on a NUMA setup, replace the start_server() function in /etc/init.d/mongodb with the following: start_server() { # check for numactl NUMACTL=$(which numactl) if [ -n "$NUMACTL" ]; then DAEMON_OPTS="--interleave=all ${DAEMON} ...


4

Design of the multicore runtime: How the multicore runtime is designed The multicore garbage collector with thread-local heaps How the garbage collector services work Cloud Haskell (distributed Haskell): Towards Haskell in the Cloud Cloud Haskell: an appetizer


4

One possible reason why not all the cores are used is if the target function being run by pool.apply_async completes too fast. The solution in that case would be to send more data to the target function (so it does more work per call). It's like shoveling coal into 32 furnaces. If you use a tiny shovel, you might only get to the 5th furnace before the coal ...


4

You need to use getcpu() system call. As man page says: determine CPU and NUMA node on which the calling thread is running So, this should serve your purpose. Needs to include <linux/getcpu.h>, with kernel version greater than 2.6.19 and for x86_64, i386 arch.


4

I found this solution: #include <stdio.h> #include <utmpx.h> int main(void) { printf("CPU: %d\n", sched_getcpu()); return 0; } Then, if you need the node of the cpu, you can use numa.h: int cpu = sched_getcpu(); int node = numa_node_of_cpu(cpu);


4

Technically, NUMA should probably only be used to describe non-uniform access latency or bandwidth to main memory. (If the NUMA factor [latency far/latency near or bandwidth far/bandwidth near] is small [e.g., comparable to dynamic variability due to DRAM row misses, buffering, etc.], then the system might still be considered UMA.) (Technically, the Xeon ...


4

The value in using a distributed-memory programming model like MPI or Charm++ even on nominally uniform shared-memory hardware is that it engenders a much more locality-conscious design of the algorithms and implementation. Even for a single core, memory access costs are non-uniform - assumptions of spatial and temporal locality are baked deeply into the ...


3

In that diagram, each group of 4 CPUs and their central RAM block is a NUMA node. Cache is inside each CPU so it's not shown in the diagram. So each group of 4 CPUs share a block of fast local RAM. Within each node, memory access to local RAM is very fast. Remote access to another node needs to go through the communication network, therefore it is slower - ...


3

A NUMA machine is a shared memory system, so memory accesses from any processor can reach the memory without blocking. If the memory model were message based, then accessing remote memory would require the executing processor to request that the local processor perform the desired operation. However, in a NUMA system, a remote processor may still impact ...


3

PAGE_NOCACHE is murder on perf, it disables the CPU cache. Was that intentional?


3

If you're just looking to get the alignment functionality around a NUMA allocator, you can easily build your own. The idea is to call the unaligned malloc() with a little bit more space. Then return the first aligned address. To be able to free it, you need to store the base address at a known location. Here's an example. Just substitute the names with ...


3

There are two primary sources of slowdown that can be attributed to NUMA. The first is the increased latency of remote access which can vary depending on the platform. On the platforms that I work with, there is about a 30% hit in latency. The other source of performance loss can come from contention over the communication links and controllers between ...


3

I'm no expert here, but here's something: Box 1, no NUMA: ~$ dmesg | grep -i numa [ 0.000000] No NUMA configuration found Box 2, some NUMA: ~$ dmesg | grep -i numa [ 0.000000] NUMA: Initialized distance table, cnt=8 [ 0.000000] NUMA: Node 4 [0,80000000) + [100000000,280000000) -> [0,280000000)


3

I presume you know the usual warnings (http://www.mongodb.org/display/DOCS/NUMA) about 'mongo & numa' so I won't go on about them. Here's a sample upstart configuration file for mongodb with numa - https://gist.github.com/1364716. Based on this Google Group thread, the following lines were added to the start_server function in the init script and it ...



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