When talking about multi-threading, it often seems like threads are treated as equal - just the same as the main thread, but running next to it.

On some new processors, however, such as the Apple "M" series and the upcoming Intel Alder Lake series not all threads are equally as performant as these chips feature separate high-performance cores and high-efficiency, slower cores.

It’s not to say that there weren’t already things such as hyper-threading, but this seems to have a much larger performance implication.

Is there a way to query std::thread‘s properties and enforce on which cores they’ll run in C++?

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    Threads aren't bound to a chip. The OS moves the threads back and forth as needed Commented Jul 19, 2021 at 17:14
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    @MooingDuck for the M1 and macOS it is afaik possible to ask the OS that it should run the thread preferable on a high efficient core. And you theoretically could lock (depending on the os and cpu) lock a process/thread to a single cpu. Which is often do one servers for virtual hosts.
    – t.niese
    Commented Jul 19, 2021 at 17:16
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    You are going to need to use OS API to dedicate a thread to a specific core. There are no guarantees that threads will be run on different cores or be executed exclusively on a core. Threads can be run on a single core (in a multi-core) system, just like other tasks. Commented Jul 19, 2021 at 17:33
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    One existing hardware development that could have similar issues is numa. The way NUMA-aware code has to handle thread allocation to different processors (to best take advantage of the different memory access speeds) could be insightful. Commented Jul 19, 2021 at 19:16
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    You know, the kernel is invented to handle multi tasks. If you think that you can handle tasks better than the kernel, you are wrong. You can use some os-level API to control your threads, on linux they are pthread APIs.
    – Yves
    Commented Jul 20, 2021 at 3:12

6 Answers 6


How to distinguish between high- and low-performance cores/threads in C++?

Please understand that "thread" is an abstraction of the hardware's capabilities and that something beyond your control (the OS, the kernel's scheduler) is responsible for creating and managing this abstraction. "Importance" and performance hints are part of that abstraction (typically presented in the form of a thread priority).

Any attempt to break the "thread" abstraction (e.g. determine if the core is a low-performance or high-performance core) is misguided. E.g. OS could change your thread to a low performance core immediately after you find out that you were running on a high performance core, leading you to assume that you're on a high performance core when you are not.

Even pinning your thread to a specific core (in the hope that it'll always be using a high-performance core) can/will backfire (cause you to get less work done because you've prevented yourself from using a "faster than nothing" low-performance core when high-performance core/s are busy doing other work).

The biggest problem is that C++ creates a worse abstraction (std::thread) on top of the "likely better" abstraction provided by the OS. Specifically, there's no way to set, modify or obtain the thread priority using std::thread; so you're left without any control over the "performance hints" that are necessary (for the OS, scheduler) to make good "load vs. performance vs. power management" decisions.

When talking about multi-threading, it often seems like threads are treated as equal

Often people think we're still using time-sharing systems from the 1960s. Stop listening to these fools. Modern systems do not allow CPU time to be wasted on unimportant work while more important work waits. Effective use of thread priorities is a fundamental performance requirement. Everything else ("load vs. performance vs. power management" decisions) is, by necessity, beyond your control (on the other side of the "thread" abstraction you're using).

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    Yup, TL:DR you usually don't need to distinguish. The OS will already migrate your compute-intensive threads on high-performance cores if they don't start there, if enough of them are free. You might want to verify that the OS is in fact doing this by using low-level APIs, especially if your workload is bursty (and thus maybe not simple for the scheduler), or like x264 you typically start more threads than there are logical cores, to keep cores busy when one thread temporarily runs out of work to do. Commented Jul 20, 2021 at 3:20
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    @supercat: It's more complex than that (e.g. tasks dealing with user interfaces need latency not throughput, idle CPU/s take longer to wake up, load from other processes isn't known by any one process, some work can be "pre-done" in the background to make performance sensitive work faster, sometimes "power management" means temperature or fan noise management, hyper-threading creates additional "slow core by itself vs. share a fast core" compromises, ...). I'd also assume user would rather tell OS how long before charging (than each app or service), & OS can predict from past usage patterns.
    – Brendan
    Commented Jul 20, 2021 at 5:59
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    "you're left without any control over the "performance hints" that are necessary" - not quite true. It wasn't standardized because of how much hints vary per system, but you totally can use system-specific calls with help of std::thread::native_handle(). Commented Jul 20, 2021 at 14:52
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    Stop listening to these fools. => Could we avoid hyperboles here? The OS has generic heuristics which are generally good, but in special cases are insufficient, or inconvenient. Typical examples are usecases where latency matters, in which case reserving exclusive use of a certain number of cores and pinning threads to those cores work much better that "hoping" that the OS will allow you to reach your target. And yes, this requires reaching beyond C++, the standard offers nothing there. Commented Jul 20, 2021 at 17:52
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    "Modern systems do not allow CPU time to be wasted on unimportant work while more important work waits" is an overstatement of the progress made. It's all too easy, and common, to end up with CPU time awfully wasted waiting for some incoming data (key press, character on a serial port), or the next second. But it still typically requires programming skills to make something real-time and CPU-savvy, unless there's a framework that did this hard work. That should be done, and can be done with the right techniques.
    – fgrieu
    Commented Jul 21, 2021 at 7:51

Is there any way to query std::thread‘s properties and enforce on which cores they’ll run in C++?

No. There is no standard API for this in C++.

Platform-specific APIs do have the ability to specify a specific logical core (or a set of such cores) for a software thread. For example, GNU has pthread_setaffinity_np.

Note that this allows you to specify "core 1" for your thread, but that doesn't necessarily help with getting the "performance" core unless you know which core that is. To figure that out, you may need to go below OS level and into CPU-specific assembly programming. In the case of Intel to my understanding, you would use the Enhanced Hardware Feedback Interface.

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    This function looks useful for querying the clock speed for a given thread id. Commented Jul 19, 2021 at 17:17
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    @PatrickRoberts Given that CPUs normally lower clocks when idle and boost when busy, there may be need to stress the core while calling the function to find which core will boost highest.
    – eerorika
    Commented Jul 19, 2021 at 17:21
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    @PatrickRoberts: Also keep in mind that it's not just clocks, it's narrow pipeline width (and in-order exec on some ARM big.LITTLE chips, or very limited OoO exec window size on Intel Gracemont vs. Golden Cove) that make the high-efficiency cores slower than the high-performance cores. But yes, you could maybe microbenchmark, or query clocks after a few ms of warm-up, with a thread pinned to a core, to detect which cores are which. As long as you don't assume the clock ratios are a perf ratio, that's fine, just an indicator of slow vs. fast cores. Commented Jul 19, 2021 at 20:22
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    instlatx64.atw.hu has listings for upcoming Alder Lake CPUs, but no links yet to actual CPUID output, so IDK what CPUID will say about family / model, whether that will be uniform across cores or not. They do link review.coreboot.org/c/coreboot/+/49629/3/src/soc/intel/common/… which has a single number as the CPUID code for CPUID_ALDERLAKE_M_A0, but coreboot might only be running CPUID on the boot core, which might mean it doesn't need to know / recognize the CPUID for the other cores. Commented Jul 19, 2021 at 20:26
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    @PeterCordes If you can pin your thread, why not just pin the thread directly to the big or little core? I don't know about iOS, but there are linux syscalls for working out which core is which...
    – Aron
    Commented Jul 20, 2021 at 4:23

No, the C++ standard library has no direct way to query the sub-type of CPU, or state you want a thread to run on a specific CPU.

But std::thread (and jthread) does have .native_handle(), which on most platforms will let you do this.

If you know the threading library implementation of your std::thread, you can use native_handle() to get at the underlying primitives, then use the underlying threading library to do this kind of low-level work.

This will be completely non-portable, of course.


iPhones, iPads, and newer Macs have high- and low-performance cores for a reason. The low-performance cores allow some reasonable amount of work to be done while using the smallest possible amount of energy, making the battery of the device last longer. These additional cores are not there just for fun; if you try to get around them, you can end up with a much worse experience for the user.

If you use the C++ standard library for running multiple threads, the operating system will detect what you are doing, and act accordingly. If your task only takes 10ms on a high-performance core, it will be moved to a low-performance core; it's fast enough and saves battery life. If you have multiple threads using 100% of the CPU time, the high-performance cores will be used automatically (plus the low-performance cores as well). If your battery runs low, the device can switch to all low-performance cores which will get more work done with the battery charge you have.

You should really think about what you want to do. You should put the needs of the user ahead of your perceived needs. Apart from that, Apple recommends assigning OS-specific priorities to your threads, which improves behaviour if you do it right. Giving a thread the highest priority so you can get better benchmark results is usually not "doing it right".


You can't select the core that a thread will be physically scheduled to run on using std::thread. See here for more. I'd suggest using a framework like OpenMP, MPI, or you will have dig into the native Mac OS APIs to select the core for your thread to execute on.

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    How would OpenMP or MPI be relevant for influencing thread scheduling? Commented Jul 20, 2021 at 4:21
  • With both you can control what task gets executed on what physical core, although on a single machine I wouldn't use MPI.
    – lmeninato
    Commented Jul 20, 2021 at 14:24

macOS provides a notion of "Quality of Service" for tasks, task queues and run loops, and threads. If you use libdispatch/GCD then the queue priorities map to the QoS as well. This article describes the QoS system in detail.

Using the macOS pthreads interface you can set a thread QoS before creating a thread, query a thread's QoS, or temporarily override a thread's QoS level (not visible in the query function though) using the non-portable functions in pthread/qos.h

This system by no means offers guarantees about how your threads will be scheduled, but can be used to make a hint to the scheduler.

I'm not aware of any way to get a similar interface on other systems, but that doesn't mean they don't exist. I imagine they'll become more widely discussed as these hybrid CPUs befome more common.

EDIT: Intel provides information here about how to query this information for their hybrid processors on Windows and for the current CPU using cpuid, haven't had a chance to play with this though.

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