For Linux user space processes it seems pretty easy to determine which processes are multithreading. You can use ps -eLf and look at the NLWP value for the number of threads, which also corresponds to the 'Threads:' value in /proc/$pid/status. Apparently back in the day of LinuxThreads the implementation was not POSIX compliant. But This stackoverflow answer says "POSIX.1 requires threads share a same process ID" which is apparently rectified in NPTL. So with NPTL it allows nifty displays of threads with commands like ps -eLf because the threads all share the same PID, and you can verify that under /proc/$pid/task/ and see all the thread subfolders belonging to that "parent" process.

I can't find similar thread groupings under a "parent" process for kernel processes spawned by kthreadd, and I suspect an implementation difference since a comment under this answer says "You can not use POSIX Threads in kernel-space" and the nifty thread grouping is a POSIX feature. Thus with ps -eLf I never see multiple threads listed for kernel processes created by kthreadd which have the square brackets around it, like [ksoftirqd/0] or [nfsd], unlike user-space processes created by init.

From the man page for pthreads (which is used in the user space):

       A single process can contain multiple threads, all of which are
       executing the same program.  These threads share the same global
       memory (data and heap segments), but each thread has its own stack
       (automatic variables).

This however is precisely what I do not see for kernel "threads", in terms of one process containing multiple threads.

In short, I never see any of the processes listed by 'ps' that are children of kthreadd having a NLWP (Threads) value higher than one, which makes me wonder if any kernel process forks/parallelizes and multithreads like user-space programs do (with pthreads). Where do the implementations differ?

Practical example: Output from ps auxf for the NFS processes.

root         2  0.0  0.0      0     0 ?        S    Jan12   0:00 [kthreadd]
root      1546  0.0  0.0      0     0 ?        S    Jan12   0:00  \_ [lockd]
root      1547  0.0  0.0      0     0 ?        S    Jan12   0:00  \_ [nfsd4]
root      1548  0.0  0.0      0     0 ?        S    Jan12   0:00  \_ [nfsd4_callbacks]
root      1549  0.0  0.0      0     0 ?        S    Jan12   2:40  \_ [nfsd]
root      1550  0.0  0.0      0     0 ?        S    Jan12   2:39  \_ [nfsd]
root      1551  0.0  0.0      0     0 ?        S    Jan12   2:40  \_ [nfsd]
root      1552  0.0  0.0      0     0 ?        S    Jan12   2:47  \_ [nfsd]
root      1553  0.0  0.0      0     0 ?        S    Jan12   2:34  \_ [nfsd]
root      1554  0.0  0.0      0     0 ?        S    Jan12   2:39  \_ [nfsd]
root      1555  0.0  0.0      0     0 ?        S    Jan12   2:57  \_ [nfsd]
root      1556  0.0  0.0      0     0 ?        S    Jan12   2:41  \_ [nfsd]

By default when you start the rpc.nfsd service (at least with the init.d service script) it spawns 8 processes (or at least they have PIDs). If I wanted to write a multi-threaded version of NFS, which is implemented as a kernel module, with those nfsd "processes" as a frontend, why couldn't I group the default 8 different nfsd processes under one PID and have 8 threads running under it, versus (as is shown - and as is different than user space processes) eight different PIDs?

NSLCD is an example of a user space program that uses multithreading by contrast:

nslcd     1424     1  1424  0    6 Jan12 ?        00:00:00 /usr/sbin/nslcd
nslcd     1424     1  1425  0    6 Jan12 ?        00:00:28 /usr/sbin/nslcd
nslcd     1424     1  1426  0    6 Jan12 ?        00:00:28 /usr/sbin/nslcd
nslcd     1424     1  1427  0    6 Jan12 ?        00:00:27 /usr/sbin/nslcd
nslcd     1424     1  1428  0    6 Jan12 ?        00:00:28 /usr/sbin/nslcd
nslcd     1424     1  1429  0    6 Jan12 ?        00:00:28 /usr/sbin/nslcd

The PID is the same but the LWP is unique per thread.

Update on the function of kthreadd

From this stackoverflow answer:

kthreadd is a daemon thread that runs in kernel space. The reason is that kernel needs to some times create threads but creating thread in kernel is very tricky. Hence kthreadd is a thread that kernel uses to spawn newer threads if required from there . This thread can access userspace address space also but should not do so . Its managed by kernel...

And this one:

kthreadd() is main function (and main loop) of daemon kthreadd which is a kernel thread daemon, the parent of all other kernel threads.

So in the code quoted, there is a creation of request to kthreadd daemon. To fulfill this request kthreadd will read it and start a kernel thread.

  • 3
    Multi-threads share same resource like address space. Kernel threads only live in kernel space, and all kernel threads share the kernel space naturally. So, there is no need for kernel multi-threads at all. – Chris Tsui Jan 23 '16 at 6:25
  • Understood, but threads do more than share memory. The whole point of a thread is to parallelize so one program doesn't have to block or wait until another task returns an so it splits off the task into a new thread. How can you keep track of related threads working on the same task in the kernel? – SeligkeitIstInGott Jan 23 '16 at 17:53
  • I was using NLWP as not just an indicator that separate processes/tasks were sharing the same memory space but that in fact that they are related processes "executing the same program" as the pthreads man page says. This becomes important for performance tuning and metrics if you want to see whether you get a gain in performance by splitting a task into more threads. Does the kernel not optimize performance by parallelizing computational tasks in the same manner? Or are "threads" the wrong category to talk about parallelization (pthreads' man page seems to associate it though)? – SeligkeitIstInGott Jan 23 '16 at 18:00
  • pthread uses the clone system call to start threads. So user space threads are actually processes that share address space, fd list, signals, and so on. In kernel space, you can use clone with whatever flags to create processes that would appear grouped as threads or whatever else. – BitWhistler Jan 23 '16 at 18:06
  • 1
    @SeligkeitIstInGott, in Linux, there is one task (also called process or thread, doesn't matter at all) for each user thread (no matter it is a thread in multi-threads process or in a single-thread process). kernel thread is also task. From the view of process scheduling, kernel thread and user thread have no difference, as they are both tasks which is the basic scheduling unit. So, when you say parallel running, kernel threads are identical to user-space multi-threads. – Chris Tsui Jan 24 '16 at 1:24

There is no concept of a process in the kernel, so your question doesn't really make sense. The Linux kernel can and does create threads that run completely in kernel context, but all of these threads run in the same address space. There's no grouping of similar threads by PID, although related threads usually have related names.

If multiple kernel threads are working on the same task or otherwise sharing data, then they need to coordinate access to that data via locking or other concurrent algorithms. Of course the pthreads API isn't available in the kernel, but one can use kernel mutexes, wait queues, etc to get the same capabilities as pthread mutexes, condition variables, etc.

Calling these contexts of execution "kernel threads" is a reasonably good name, since they are closely analogous to multiple threads in a userspace process. They all share the (kernel's) address space, but have their own execution context (stack, program counter, etc) and are each scheduled independently and run in parallel. On the other hand, the kernel is what actually implements all the nice POSIX API abstractions (with help from the C library in userspace), so internal to that implementation we don't have the full abstraction.

  • Very helpful answer. One of my difficulties was with the the terminology, and saying kernel "task" rather than "process" seems to be the correct way to designate it. And thank you for understanding what I was attempting to ask since I had some difficulty knowing how to even frame the question, and your second paragraph seemed to nail that about mutexes, wait queues, and locking. Is there anything in print or online that basically says what you said in an introductory manner, because I had difficulty finding anything straightforward on this topic. – SeligkeitIstInGott Jan 24 '16 at 18:04
  • I also have a question now on what kthreadd actually is and does. Whatever runs as a child of kthreadd: is it showing you actual kernel threads or is it showing you user space threads that have some kind of 1:1 mapping to kernel tasks (I think I read something about that)? Perhaps due to their ignorance as well some articles I've read treat children of kthreadd as actual kernel tasks, despite the fact they have a PID. And what is the main difference between children of the init process and children of kthreadd? – SeligkeitIstInGott Jan 24 '16 at 18:19
  • "despite the fact they have a PID" = meaning that they are processes, which is a user space only concept, thus can't be a representation of what is running in the kernel space. – SeligkeitIstInGott Jan 24 '16 at 18:38
  • 1
    They don't really have a PID. On Linux, the kernel has just one name space and process IDs, thread IDs, and IDs assigned to kernel tasks come from this same namespace. Various tools distinguish the different types of IDs that come from this same namespace in different ways. Just because something calls it a PID, you can't assume that it's in fact a user-space process. They may just mean a number assigned from the same namespace as PIDs and that appears in the slot a PID would appear if this kernel-scheduled entity were a user-space process. – David Schwartz Jan 24 '16 at 20:18
  • 1
    init is the first task which has user-space, and all of its children are forked (and then exec) from it. kthreadd is just a kernel thread to simplify creating other kernel thread, as there are other way to create kernel thread like kernel_thread(). All of these are done through do_fork() with different parameters. – Chris Tsui Jan 26 '16 at 12:21

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