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Say I run a simple single-threaded process like the one below:

public class SirCountALot {
    public static void main(String[] args) {
        int count = 0;
        while (true) {

(This is Java because that's what I'm familiar with, but I suspect it doesn't really matter)

I have an i7 processor (4 cores, or 8 counting hyperthreading), and I'm running Windows 7 64-bit so I fired up Sysinternals Process Explorer to look at the CPU usage, and as expected I see it is using around 20% of all available CPU.

Graph showing 20% CPU usage across all cores

But when I toggle the option to show 1 graph per CPU, I see that instead of 1 of the 4 "cores" being used, the CPU usage is spread all over the cores:

Graph showing erratic CPU usage on each core totaling around 20% usage

Instead what I would expect is 1 core maxed out, but this only happens when I set the affinity for the process to a single core.

Graph showing most of recent CPU usage to be confined to first core

Why is the workload split over the separate cores? Wouldn't splitting the workload over several cores mess with the caching or incur other performance penalties?

Is it for the simple reason of preventing overheating of one core? Or is there some deeper reason?

Edit: I'm aware that the operating system is responsible for the scheduling, but I want to know why it "bothers". Surely from a naive viewpoint, sticking a (mostly*) single-threaded process to 1 core is the simpler & more efficient way to go?

*I say mostly single-threaded because there's multiple theads here, but only 2 of them are doing anything:

Screenshot showing number of threads from Eclipse Screenshot showing number of threads in Process Explorer process properties

share|improve this question
Small nitpick; saying this is a single threaded process won't be correct. JVM internally spawns multiple threads for housekeeping purposes like finalizers, garbage collectors etc. It is quite possible that to get real work done by each thread, the JVM threads are mapped to real h/w threads, which again might explain the spread. – Sanjay T. Sharma Dec 13 '11 at 8:10
I guess Caspar meant the non-daemon threads. – Santosh Dec 13 '11 at 8:17
@SanjayT.Sharma Yes, I simplified a little bit and probably should have given a sample program in a non-managed language ;) However like I said, I strongly suspect it isn't the JVM doing this (and if it is mapping JVM -> HW threads and that is responsible, why is the mapping constantly changing?) – Caspar Dec 13 '11 at 8:30
@Santosh yes exactly, I meant threads which aren't idle 99% of the time – Caspar Dec 13 '11 at 8:31
up vote 17 down vote accepted

The OS is responsible for scheduling. It is free to stop a thread and start it again on another CPU. It will do this even if there is nothing else the machine is doing.

The process is moved around the CPUs because the OS doesn't assume there is any reason to continue running the thread on the same CPU each time.

For this reason I have written a library for lock threads to a CPU so it won't move around and won't be interrupted by other threads. This reduces latency and improve throughput but does tire up a CPU for that thread. This works for Linux, perhaps you can adapt it for Windows.

share|improve this answer
It interrupts a process many times per second. (100/s on Linux) It is more work to have to remember where a process was last running and try to assign that CPU in preference to any other, instead it assigns it to the next free CPU. – Peter Lawrey Dec 13 '11 at 8:23
I guess I wan't clear enough; I'm aware that the OS does the scheduling, and you can see in the 2nd graph I've set the afinity for the process so it uses only the first core. What I want to know is why does the OS schedule the single "active" thread over all the available cores? – Caspar Dec 13 '11 at 8:23
The converse question is why would to keep assigning a thread back to the same CPU instead of just assigning it to the next free CPU (which is what it does) Using round robin works well no matter how many CPUs are busy. Assigning to the same CPU each time could leave one CPU very busy (with two threads running on it) while other CPUs are idle. – Peter Lawrey Dec 13 '11 at 8:25
Not really off-topic but "side-topic" question: What are use-cases where you really need something like that? Financial trading applications? For what did you need it or was it just a private case study project? – Fabian Barney Dec 13 '11 at 8:33
@Peter Okay (my previous comment was written before your first comment). I thought that since processor time was cheap & memory access relatively expensive, wouldn't the performance hit from a cache miss be worse than that from keeping track of which core to schedule a process on? – Caspar Dec 13 '11 at 8:35

I would also expect this could well be done on purpose by the CPU and OS so as to try and spread the thermal load on the CPU die...

So it would rotate the (unique/single) thread from core to core.

And that could admittedly be an argument against trying to fight this too hard (especially as, in practice, you often will see better improvements by simply tuning / improving the app itself anyway)

share|improve this answer
Interesting. Do you know that Windows/Linux do this for sure, or is it a hypothesis? (Also, welcome to stackoverflow : ) – Leeor Apr 2 at 8:13
I have seen this clearly happening on OSX and Windows. I would expect the same for Linux but never specifically tried to verify it. – Camlin Apr 26 at 20:40

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