Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I have a userlevel program which opens a file using the flags O_WRONLY|O_SYNC. The program creates 256 threads which attempt to write 256 or more bytes of data each to the file. I want to have a total of 1280000 requests, making it a total of about 300 MB of data. The program ends once 1280000 requests have been completed.

I use pthread_spin_trylock() to increment a variable which keeps track of the number of requests that have been completed. To ensure that each thread writes to a unique offset, I use pwrite() and calculate the offset as a function of the number of requests that have been written already. Hence, I don't use any mutex when actually writing to the file (does this approach ensure data integrity?)

When I check the average time for which the pwrite() call was blocked and the corresponding numbers (i.e., the average Q2C times -- which is the measure of the times for the complete life cycle of BIOs) as found using blktrace, I find that there is a significant difference. In fact, the average completion time for a given BIO is much greater than the average latency of a pwrite() call. What is the reason behind this discrepancy? Shouldn't these numbers be similar since O_SYNC ensures that the data is actually written to the physical medium before returning?

share|improve this question

pwrite() is suppose to be atomic, so you should be safe there ...

In regards to the difference in latency between your syscall and the actual BIO, according to this information on the man-pages at for open(2):

POSIX provides for three different variants of synchronized I/O, corresponding to the flags O_SYNC, O_DSYNC, and O_RSYNC. Currently (2.6.31), Linux only implements O_SYNC, but glibc maps O_DSYNC and O_RSYNC to the same numerical value as O_SYNC. Most Linux file systems don't actually implement the POSIX O_SYNC semantics, which require all metadata updates of a write to be on disk on returning to userspace, but only the O_DSYNC semantics, which require only actual file data and metadata necessary to retrieve it to be on disk by the time the system call returns.

So this basically implies that with the O_SYNC flag the entirety of the data you're attempting to write does not need to be flushed to disk before a syscall returns, but rather just enough information to be capable of retrieving it from disk ... depending on what you're writing, that could be quite a bit less than the entire buffer of data you were intending to write to disk, and therefore the actual writing of all the data will take place at a later time, after the syscall has been completed and the process has moved on to something else.

share|improve this answer
I repeated the same experiment with the ext2 file system, which, unlike the ext3 file system, is not a journaling file system. Average Q2C latency turned out to be 8.5 milliseconds. In the userlevel program, the average time for which the pwrite() call was blocked is 1.5 milliseconds. These numbers are relatively closer as compared to my earlier experiment; however, this isn't what I want. How can I make the call to pwrite() completely synchronous, i.e., the call returns only after the entire buffer of data has been written onto the disk? Disk benchmarking tools must have a workaround? – user745878 Aug 25 '11 at 18:31
You're probably going to have to use a lower kernel-level writing primitive ... per the Linux implementation, pwrite() is not completely synchronous. – Jason Aug 25 '11 at 19:47

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.