In Linux, what happens to the state of a process when it needs to read blocks from a disk? Is it blocked? If so, how is another process chosen to execute?
When a process needs to fetch data from a disk, it effectively stops running on the CPU to let other processes run because the operation might take a long time to complete – at least 5ms seek time for a disk is common, and 5ms is 10 million CPU cycles, an eternity from the point of view of the program!
From the programmer point of view (also said "in userspace"), this is called a blocking system call. If you call
write(2) (which is a thin libc wrapper around the system call of the same name), your process does not exactly stop at that boundary; it continues, in the kernel, running the system call code. Most of the time it goes all the way up to a specific disk controller driver (filename → filesystem/VFS → block device → device driver), where a command to fetch a block on disk is submitted to the proper hardware, which is a very fast operation most of the time.
THEN the process is put in sleep state (in kernel space, blocking is called sleeping – nothing is ever 'blocked' from the kernel point of view). It will be awakened once the hardware has finally fetched the proper data, then the process will be marked as runnable and will be scheduled. Eventually, the scheduler will run the process.
Finally, in userspace, the blocking system call returns with proper status and data, and the program flow goes on.
It is possible to invoke most I/O system calls in non-blocking mode (see
fcntl(2)). In this case, the system calls return immediately and only report submitting the disk operation. The programmer will have to explicitly check at a later time whether the operation completed, successfully or not, and fetch its result (e.g., with
select(2)). This is called asynchronous or event-based programming.
Most answers here mentioning the D state (which is called
TASK_UNINTERRUPTIBLE in the Linux state names) are incorrect. The D state is a special sleep mode which is only triggered in a kernel space code path, when that code path can't be interrupted (because it would be too complex to program), with the expectation that it would block only for a very short time. I believe that most "D states" are actually invisible; they are very short lived and can't be observed by sampling tools such as 'top'.
You can encounter unkillable processes in the D state in a few situations. NFS is famous for that, and I've encountered it many times. I think there's a semantic clash between some VFS code paths, which assume to always reach local disks and fast error detection (on SATA, an error timeout would be around a few 100 ms), and NFS, which actually fetches data from the network which is more resilient and has slow recovery (a TCP timeout of 300 seconds is common). Read this article for the cool solution introduced in Linux 2.6.25 with the
TASK_KILLABLE state. Before this era there was a hack where you could actually send signals to NFS process clients by sending a SIGKILL to the kernel thread
rpciod, but forget about that ugly trick.…
2+1 for the detailed response, but please note that this thread has had an accepted answer for nearly two years. Hit the "Questions" link if you want to lend a hand on more recent questions. Welcome to Stack Overflow, and thanks for contributing! Jul 14, 2011 at 1:59
21This answer is the only one to mention NFS, which in some environments is the most common explanation for processes in the D state. +1.– PinkoDec 6, 2011 at 15:16
15Very good answer, thanks. Also note that process go into the D state while waiting for pages that have been swapped out, so a thrashing process will be in the D state for a long while.– cha0siteMay 11, 2012 at 20:20
@zerodeux good answer, but i think your schema (filename -> filesystem/VFS -> block device -> device driver) it should be (filename -> VFS -> filesystem(ext3) -> block device -> device driver)– c4f4t0rMay 24, 2014 at 18:18
1Would it be safe to assume that the time spent in kernel waiting on spinlocks (which may or may not be related to disk i/o) all reported as D-state in
/proc/stat?– wickOct 9, 2016 at 11:08
While waiting for
write() to/from a file descriptor return, the process will be put in a special kind of sleep, known as "D" or "Disk Sleep". This is special, because the process can not be killed or interrupted while in such a state. A process waiting for a return from ioctl() would also be put to sleep in this manner.
An exception to this is when a file (such as a terminal or other character device) is opened in
O_NONBLOCK mode, passed when its assumed that a device (such as a modem) will need time to initialize. However, you indicated block devices in your question. Also, I have never tried an
ioctl() that is likely to block on a fd opened in non blocking mode (at least not knowingly).
How another process is chosen depends entirely on the scheduler you are using, as well as what other processes might have done to modify their weights within that scheduler.
Some user space programs under certain circumstances have been known to remain in this state forever, until rebooted. These are typically grouped in with other "zombies", but the term would not be correct as they are not technically defunct.
1"A process waiting for a return from ioctl() would also be put to sleep in this manner". I just killed my userspace process waiting on a blocking IOCTL so this is not true. Unless I'm missunderstanding Oct 28, 2015 at 8:49
It would be tremendously difficult to time such a test. Uninterruptable processes can't be killed; if you were able to kill it, then it was simply blocking (the kernel was not in the middle of any part of the ioctl, and copied any corresponding response to user space at the location you passed (or at least wasn't in the middle of copying)). Linux has also changed a lot since 2009 when this was written; the phenomenon is much less observable as it once was.– Tim PostMar 9, 2016 at 6:13
Does this mean async io would not cause D state?– TedNov 23, 2022 at 8:17
@Ted Async io just means the process won't entirely block if a syscall happened to hang on I/O, it would just continue to poll descriptors for updates.– Tim PostNov 27, 2022 at 14:56
A process performing I/O will be put in D state (uninterruptable sleep), which frees the CPU until there is a hardware interrupt which tells the CPU to return to executing the program. See
man ps for the other process states.
Depending on your kernel, there is a process scheduler, which keeps track of a runqueue of processes ready to execute. It, along with a scheduling algorithm, tells the kernel which process to assign to which CPU. There are kernel processes and user processes to consider. Each process is allocated a time-slice, which is a chunk of CPU time it is allowed to use. Once the process uses all of its time-slice, it is marked as expired and given lower priority in the scheduling algorithm.
In the 2.6 kernel, there is a O(1) time complexity scheduler, so no matter how many processes you have up running, it will assign CPUs in constant time. It is more complicated though, since 2.6 introduced preemption and CPU load balancing is not an easy algorithm. In any case, it’s efficient and CPUs will not remain idle while you wait for the I/O.
As already explained by others, processes in "D" state (uninterruptible sleep) are responsible for the hang of ps process. To me it has happened many times with RedHat 6.x and automounted NFS home directories.
To list processes in D state you can use the following commands:
cd /proc for i in [0-9]*;do echo -n "$i :";cat $i/status |grep ^State;done|grep D
To know the current directory of the process and, may be, the mounted NFS disk that has issues you can use a command similar to the following example (replace 31134 with the sleeping process number):
# ls -l /proc/31134/cwd lrwxrwxrwx 1 pippo users 0 Aug 2 16:25 /proc/31134/cwd -> /auto/pippo
I found that giving the umount command with the -f (force) switch, to the related mounted nfs file system, was able to wake-up the sleeping process:
umount -f /auto/pippo
the file system wasn't unmounted, because it was busy, but the related process did wake-up and I was able to solve the issue without rebooting.
Assuming your process is a single thread, and that you're using blocking I/O, your process will block waiting for the I/O to complete. The kernel will pick another process to run in the meantime based on niceness, priority, last run time, etc. If there are no other runnable processes, the kernel won't run any; instead, it'll tell the hardware the machine is idle (which will result in lower power consumption).
Processes that are waiting for I/O to complete typically show up in state D in, e.g.,
I launched several process using about 10% of the total memory. I noticed that many of them are in D state. Is this due to slow IO on this particular machine? Say I have 9 processes, they may be competing for IO and many of them are in the D state. Jul 20, 2017 at 18:32
@KeminZhou Compared to CPU speeds, I/O is pretty slow—even fast I/O. A single I/O heavy process can easy busy a magnetic disk, even an SSD. 10 I/O heavy processes could busy quite a few.– derobertJul 20, 2017 at 20:38
Yes, the task gets blocked in the read() system call. Another task which is ready runs, or if no other tasks are ready, the idle task (for that CPU) runs.
A normal, blocking disc read causes the task to enter the "D" state (as others have noted). Such tasks contribute to the load average, even though they're not consuming the CPU.
Some other types of IO, especially ttys and network, do not behave quite the same - the process ends up in "S" state and can be interrupted and doesn't count against the load average.
Yes, tasks waiting for IO are blocked, and other tasks get executed. Selecting the next task is done by the Linux scheduler.
Generally the process will block. If the read operation is on a file descriptor marked as non-blocking or if the process is using asynchronous IO it won't block. Also if the process has other threads that aren't blocked they can continue running.
The decision as to which process runs next is up to the scheduler in the kernel.