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That is, if the core processor most of the time waiting for data from RAM or cache-L3 with cache-miss, but the system is a real-time (real-time thread priority), and the thread is attached (affinity) to the core and works without switching thread/context, what kind of load(usage) CPU-Core should show on modern x86_64?

That is, CPU usage is displayed as decrease only when logged in Idle?

And if anyone knows, if the behavior is different in this case for other processors: ARM, Power[PC], Sparc?

Clarification: shows CPU-usage in standard Task manager in OS-Windows

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The question isn't clear - should show where? which program do you use for monitoring? You can easily detect this case with performance monitors (vtune, perf, or any other profiling tool) – Leeor Nov 14 '13 at 15:00
@Leeor Ok. I added clarification. – Alex Nov 14 '13 at 15:09
Doesn't it have a graph of physical memory usage (under the performance tab)? That should measure RAM, but L3 access time is of a much lesser magnitude. – Leeor Nov 14 '13 at 15:22
The processor core will eventually stall, it counts as full load. – Hans Passant Nov 14 '13 at 17:38
@Hans Passant Thanks! If you or anyone has a more detailed answer why this is the case, and when is the load(executing CPU instructions, wait cache miss, ...) and when is not it (Idle), then please write the answer. – Alex Nov 14 '13 at 18:56

2 Answers 2

up vote 1 down vote accepted

A hardware thread (logical core) that's stalled on a cache miss can't be doing anything else, so it still counts as busy for the purposes of task-managers / CPU time accounting / OS process scheduler time-slices / stuff like that.

This is true across all architectures.

Without hyperthreading, "hardware thread" / "logical core" are the same as a "physical core".

Morphcore / other on-the-fly changing between hyperthreading and a more powerful single core could make there be a difference between a thread that keeps many execution units busy, vs. a thread that is blocked on cache misses a lot of the time.

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I think you are confusing what an OS show as "CPU usage" with more low level concepts like IPS, Throughput and Latency of instructions. – user781847 Jun 25 at 16:50
Thank you! I.e. Intel x86_64 independently Virtual (Logical) or Physical (Hardware) Core which is stalled on a cache miss can shows 100% CPU-usage in OS. And is this true for the hyperthreading - when the first logical core waiting for the second core (on the same hardware-core), then the first logical core shows busy too? – Alex Jun 25 at 18:02
@knm241: When I say "stalled", I mean out-of-order execution is stalled because it's run out of instructions that aren't in the dependency chain of the stalled load. I'm pointing out that IPC / pipeline stalls / code efficiency doesn't have an impact on whether an OS treats a core as "busy". – Peter Cordes Jun 25 at 20:57
@Alex: each hardware thread is independent. With hyperthreading, each physical core has two hardware threads, aka logical cores. There's no such thing as "the first core waiting for the second core". One core might be running code that's waiting for another thread to release a lock, but that's not the same thing. (Usual lock behaviour is to tell the OS we're asleep between checks for a lock being free.) – Peter Cordes Jun 25 at 21:01
@Peter Cordes Maybe it's my lack of understanding of Hyper Threading and is another question, but can one logical core be stalled to waiting for release hardware resources(ALU, Ports, ...) of another logical core , if they both belong to the same physical core? – Alex Jun 25 at 21:44

I don't get the link between the OS CPU usage statistics and the optimal use of the pipeline. I think they are uncorrelated as the OS doesn't measure the pipeline load.
I'm writing this in the hope that Peter Cordes can help me understand it better and as a continuation of the comments.

User programs relinquish control to OS very often: when they need input from user or when they are done with the signal/message. GUI program are basically just big loops and at each iteration control is given to the OS until the next message. When the OS has the control it schedules others threads/tasks and if not other actions are needed just enter the idle process (long time ago a tight loop, now a sleep state) until the next interrupt. This is the Idle Time.

Time spent on an ISR processing user input is considered idle time by any OS. An a cache miss there would be still considered idle time.

A heavy program takes more time to complete the work for a given message thereby returning control to OS say 2 times in a second instead of 20.
If the OS measures that in the last second, it got control for 20ms only then the CPU usage is (1000-20)/1000 = 98%.

This has nothing to do with the optimal use of the CPU architecture, as said stalls can occur in the OS code and still be part of the Idle time statistic. The CPU utilization at pipeline level is not what is measured and it is orthogonal to the OS statistics.

CPU usage is meant to be used by sysadmin, it is a measure of the load you put on a system, it is not the measure of how efficiently the assembly of a program was generated. Sysadmins can't help with that, but measuring how often the OS got the control back (without preempting) is a measure of how much load a program is putting on the system. And sysadmins can definitively do terminate heavy programs.

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You're correct that optimal use of the pipeline is uncorrelated with OS CPU usage statistics. They are orthogonal, as you say. – Peter Cordes Jun 27 at 16:39
You're wrong that time spent in kernel code (e.g. interrupt service routines) counts as idle. It's not "user" time for that process, but it is "system", not "idle" or i/o wait time. "idle" time is only when the CPU is actually paused waiting for an interrupt, not when it's actually handling the interrupt from the keypress or mouse move. Maybe some of my comments on my answer were talking about time accounting for a single process (i.e. just the "user" time for it.) Something like Windows Task Manager with charts of CPU utilization counts "system" time too, I think. – Peter Cordes Jun 27 at 16:42
@PeterCordes ok, got it! Just for completation, I was thinking of this: when the a system timer fires an IRQ and the CPU wakes up the kernel has to update the measuring algorithm state so that now it measures system time instead of idle time and also store the idle time counted. if cache miss happens before the state is updated it counts as idle time. Right? Do you happen to have any info on how Linux measure these times? Thanks! – user781847 Jun 27 at 17:52
I haven't looked at Linux's code for this. I hadn't really thought about this before, but yeah I guess the kernel needs CPU-time accounting every sleep and every wakeup, and that could be delayed by a cache miss. Unless it uses the CPU performance counters to count clock-cycles-unhalted or something, instead of starting and stopping a stopwatch all the time. – Peter Cordes Jun 28 at 15:16
One other thing: servicing interrupts never happens in the same thread as a user process. Processes make system calls, and time spent in kernel code on behalf of a user process goes to that process's "system" CPU time. Interrupt service routines are overall "system" CPU time, but not accounted toward any process. When a process sleeps on input (e.g. select(2) / poll(2) Unix system calls, or Windows wait-for-next-window-message call), it's not an interrupt service routine that delivers the message directly. An ISR usually does the minimum work possible, and other code queues the message – Peter Cordes Jun 28 at 15:22

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