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$ time foo
real        0m0.003s
user        0m0.000s
sys         0m0.004s

Which of these three is meaningful when benchmarking my app?

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4 Answers 4

up vote 688 down vote accepted

Real, User and Sys process time statistics

One of these things is not like the other. Real refers to actual elapsed time; User and Sys refer to CPU time used only by the process.

  • Real is wall clock time - time from start to finish of the call. This is all elapsed time including time slices used by other processes and time the process spends blocked (for example if it is waiting for I/O to complete).

  • User is the amount of CPU time spent in user-mode code (outside the kernel) within the process. This is only actual CPU time used in executing the process. Other processes and time the process spends blocked do not count towards this figure.

  • Sys is the amount of CPU time spent in the kernel within the process. This means executing CPU time spent in system calls within the kernel, as opposed to library code, which is still running in user-space. Like 'user', this is only CPU time used by the process. See below for a brief description of kernel mode (also known as 'supervisor' mode) and the system call mechanism.

User+Sys will tell you how much actual CPU time your process used. Note that this is across all CPUs, so if the process has multiple threads it could potentially exceed the wall clock time reported by Real. Note that in the output these figures include the User and Sys time of all child processes (and their descendants) as well when they could have been collected, e.g. by wait(2) or waitpid(2), although the underlying system calls return the statistics for the process and its children separately.

Origins of the statistics reported by time (1)

The statistics reported by time are gathered from various system calls. 'User' and 'Sys' come from wait (2) or times (2), depending on the particular system. 'Real' is calculated from a start and end time gathered from the gettimeofday (2) call. Depending on the version of the system, various other statistics such as the number of context switches may also be gathered by time.

On a multi-processor machine, a multi-threaded process or a process forking children could have an elapsed time smaller than the total CPU time - as different threads or processes may run in parallel. Also, the time statistics reported come from different origins, so times recorded for very short running tasks may be subject to rounding errors, as the example given by the original poster shows.

A brief primer on Kernel vs. User mode

On Unix, or any protected-memory operating system, 'Kernel' or 'Supervisor' mode refers to a privileged mode that the CPU can operate in. Certain privileged actions that could affect security or stability can only be done when the CPU is operating in this mode; these actions are not available to application code. An example of such an action might be to manipulate the MMU to gain access to the address space of another process. Normally, user-mode code cannot do this (with good reason), although it can request shared memory from the kernel, which could be read or written by more than one process. In this case, the shared memory is explicitly requested from the kernel through a secure mechanism and both processes have to explicitly attach to it in order to use it.

The privileged mode is usually referred to as 'kernel' mode because the kernel is executed by the CPU running in this mode. In order to switch to kernel mode you have to issue a specific instruction (often called a trap) that switches the CPU to running in kernel mode and runs code from a specific location held in a jump table. For security reasons, you cannot switch to kernel mode and execute arbitrary code - the traps are managed through a table of addresses that cannot be written to unless the CPU is running in supervisor mode. You trap with an explicit trap number and the address is looked up in the jump table; the kernel has a finite number of controlled entry points.

The 'system' calls in the C library (particularly those described in Section 2 of the man pages) have a user-mode component, which is what you actually call from your C program. Behind the scenes, they may issue one or more system calls to the kernel to do specific services such as I/O, but they still also have code running in user-mode. It is also quite possible to directly issue a trap to kernel mode from any user space code if desired, although you may need to write a snippet of assembly language to set up the registers correctly for the call. A page describing the system calls provided by the Linux kernel and the conventions for setting up registers can be found here.

More about 'sys'

There are things that your code cannot do from user mode - things like allocating memory or accessing hardware (HDD, network, etc.). These are under the supervision of The Kernel, and it alone can do them. Some operations that you do (like malloc orfread/fwrite) will invoke these Kernel functions and that then will count as 'sys' time. Unfortunately it's not as simple as "every call to malloc will be counted in 'sys' time". The call to malloc will do some processing of its own (still counted in 'user' time) and then somewhere along the way call the function in kernel (counted in 'sys' time). After returning from the kernel call, there will be some more time in 'user' and then malloc will return to your code. As for when the switch happens, and how much of it is spent in kernel mode... you cannot say. It depends on the implementation of the library. Also, other seemingly innocent functions might also use malloc and the like in the background, which will again have some time in 'sys' then.

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@Vilx You've got shit-loads of Rep. Do you want to edit the post directly. I've done so many edits that will go to Wiki mode before long. –  ConcernedOfTunbridgeWells Feb 17 '09 at 13:01
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Does the time spent by child processes count into real/sys? –  ron Aug 29 '11 at 10:53
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@ron - According to the Linux man page, it aggregates the 'c' times with the process times, so I think it does. The parent times and child times are available separately from the times(2) call, though. I guess the Solaris/SysV version of time(1) does something similar. –  ConcernedOfTunbridgeWells Aug 30 '11 at 10:28
    
@ron I've just edited the answer: The time spent by child processes and their descendants count only when the time could have been collected by wait(2) or waitpid(2), and recursively with descendants. This implies that the child processes must have terminated. For instance, compare time sh -c 'foo & sleep 1' and time sh -c 'foo & sleep 2', where foo is a command that takes CPU time between 1 and 2 seconds. The former outputs something around 0. –  vinc17 Sep 10 at 11:44

Since I don’t have enough rep to comment on the top answer, I just wanted to provide another reason why realuser + sys.

Keep in mind that real represents actual elapsed time, while user and sys values represent CPU execution time. As a result, on a multicore system, the user and/or sys time (as well as their sum) can actually exceed the real time. For example, on a Java app I’m running for class I get this set of values:

real    1m47.363s
user    2m41.318s
sys     0m4.013s
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2  
I'd always wondered about this. Since I know that my programs are single threaded, the difference between user and real time must be VM overhead, correct? –  Quantum7 May 5 '10 at 0:13
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not necessarily; the Sun JVM on Solaris machines as well as Apple's JVM on Mac OS X manages to use more than one core even in single-threaded apps. If you do a sample of a java process, you'll see that things like garbage collection run on separate threads (and some other stuff too that I don't remember off the top of my head). I don't know if you really want to term that "VM overhead" though. –  lensovet May 7 '10 at 7:10
    
@Quantum7 - no, not necessarily. See my post above. Real is elapsed time, user and sys are accumulated time slice statistics from the CPU time the process actually uses. –  ConcernedOfTunbridgeWells Apr 12 '11 at 16:20
    
I guess the amount of up-votes gave you enough reputation now :D. So what do you think about real exceeding user and sys total ? OS overhead such as thread context switching may be ? –  Muhammad Gelbana Sep 26 '12 at 11:36
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Another potential issue could be I/O: if your application spends a good deal of time waiting to receive a file or stream, then obviously the real time would greatly exceed the user/sys time because no CPU time is used while waiting to get access to a file or something similar. –  lensovet Sep 26 '12 at 18:39

real - is the number of minutes you put on your status report for trying to understand 'time'. it's basically the sum of (user + (sys * brains)).

user - is the amount of time you spent actually reading this blog. This does not include time that your brain is doing other things like managing your bosses interruption.

sys - is the amount of time actually thinking and trying to understand what it says. If you had multiple brains, you could multitask and hopefully it would be faster. Remember to only include the time spent on this issue. Not time spent thinking about lunch or whatever.

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+1 Great analogy! But wouldn't it be more accurate to say that sys is "the average time spent reading and comprehending one line"? –  Noob Saibot Apr 8 at 17:38
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-1 this is unclear at best, but seems to be inaccurate based on other answers –  Eben Geer Jun 27 at 20:54
    
-1 Nothing personal, but not only the elaborate analogy doesn't make it easier to understand (and that's the purpose of an analogy), but the answer also lacks a technical section ("So, in reality, it works like this: ...") –  Numbers yesterday

Real shows total turn-around time for a process; while User shows the execution time for user-defined instructions and Sys is for time for executing system calls!

Real time includes the waiting time also (the waiting time for I/O etc.)

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