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I observed a very curious effect in this trivial program

module Moo 
   subroutine main()
      integer :: res 
      real :: start, finish
      integer :: i

      call cpu_time(start)

      do i = 1, 1000000000
         call Squared(5, res) 
      call cpu_time(finish)

      print '("Time = ",f6.3," seconds.")',finish-start
   end subroutine

   subroutine Squared(v, res)
      integer, intent(in) :: v
      integer, intent(out) :: res 

      res = v*v 
   end subroutine 

!   subroutine main2()
!      integer :: res
!      real :: start, finish
!      integer :: i
!      call cpu_time(start)
!      do i = 1, 1000000000
!         res = v*v
!      enddo
!      call cpu_time(finish)
!      print '("Time = ",f6.3," seconds.")',finish-start
!   end subroutine

end module
program foo 
   use Moo 
   call main()
!   call main2()
end program

Compiler is gfortran 4.6.2 on mac. If I compile with -O0 and run the program, the timing is 4.36 seconds. If I uncomment the subroutine main2(), but not its call, the timing becomes 4.15 seconds on average. If I also uncomment the call main2() the first timing becomes 3.80 and the second 1.86 (understandable, I have no function call).

I compared the assembler produced in the second and third cases (routine uncommented; call commented and uncommented) and they are exactly the same, save for the actual invocation of the main2 routine.

How can the code get this performance increase from a call to a routine that is going to happen in the future, and basically no difference in the resulting code?

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I was curious and tested this with gfortran (-O0) 4.6.2 on Linux (x86_64), and there was absolutely no difference whatever I did: timing was always about 3.3 seconds on average. –  steabert Dec 5 '11 at 9:43
@steabert: That's funny... so it's mac only apparently. –  Stefano Borini Dec 5 '11 at 10:12

2 Answers 2

First thing I noticed was that your program is way too short for proper benchmarking. How many runs do you use to average? What is the standard deviation? I added a nested do loop to your code to make it longer:

do i = 1, 1000000000
  do j=1,10
    call Squared(5, res) 

I looked at only case 1 and case 2 (main2 commented and uncommented) because case 3 is different and irrelevant for this comparison. I would expect a slight increase in runtime in case 2, because of needing to load a larger executable into memory, even though that part is not used in the program.

So I did timing (3 runs each) for cases 1 and 2, for three compilers:

pgf90 10.6-0 64-bit target on x86-64 Linux -tp istanbul-64

Intel(R) Fortran Intel(R) 64 Compiler XE for applications running on Intel(R) 64, Version Build 20110112

GNU Fortran (GCC) 4.1.2 20080704 (Red Hat 4.1.2-51)

on AMD Opteron(tm) Processor 6134

The output of my script is:

exp 1 with pgf90:
Time = 30.619 seconds.
Time = 30.620 seconds.
Time = 30.686 seconds.
exp 2 with pgf90:
Time = 30.606 seconds.
Time = 30.693 seconds.
Time = 30.635 seconds.
exp 1 with ifort:
Time = 77.412 seconds.
Time = 77.381 seconds.
Time = 77.395 seconds.
exp 2 with ifort:
Time = 77.834 seconds.
Time = 77.853 seconds.
Time = 77.825 seconds.
exp 1 with gfortran:
Time = 68.713 seconds.
Time = 68.659 seconds.
Time = 68.650 seconds.
exp 2 with gfortran:
Time = 71.923 seconds.
Time = 74.857 seconds.
Time = 72.126 seconds.

Notice the time difference between case 1 and case 2 is largest for gfortran, and smallest for pgf90.

EDIT: After Stefano Borini pointed out that I overlooked the fact that only the looping is being benchmarked using call to cpu_time, executable load-time is out of the equation. Answer by AShelley suggests a possible reason for this. For longer runtimes, the difference between the 2 cases becomes minimal. Still - I observe a significant difference in case of gfortran (see above)

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I do the timings with cpu_time, not with the time program. How can it be due to load time of the executable ? Or maybe I don't understand your point. –  Stefano Borini Dec 1 '11 at 20:55
Good point, I use your cpu_time as well. Which puts the load time out of the equation. But the main point still stands - try to do longer runs (e.g. 10 or 100 times longer). The difference you observe cannot be due to a different executable, since you benchmark only the loop execution. –  milancurcic Dec 1 '11 at 21:02

I think @IRO-bot has the right answer, but I would like to point out that code placement can influence timing, even for identical assembly.

I have 2 embedded applications running on identical processors. Each has the same hand-code assembly routine to provide the tightest possible busy-loop (for inserting sub-microsecond delays). I was recently suprised to learn that in one app, the loop took 50%! longer than the other one. Both generated the exact same assembly.

It turns out that in one executable, the starting address of the loop body allowed it to fall entirely within the processor's sole instruction cache line. On the slower one, the same function started at an address which caused it to span two lines. The extra fetch required dominated the timing of such a tight loop.

So it is possible to find instances where adding unexecuted code will affect code timing, due a change in the instruction caching sequence.

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I first learned about this a few years ago in a seminar, but completely forgot about it since. Thanks. –  milancurcic Dec 1 '11 at 18:34
one thing I noticed is that even if you comment out the content of the routine, but leave the call, you get a short time. The mere presence of the call statement later on apparently has an effect on the speed of the code that executes earlier. –  Stefano Borini Dec 2 '11 at 0:07
@Stefano, there is no guarantee that the order of functions in the source file will match the order in the executable. And even if it does, the presence of the other call may modify header information. All it takes for this kind of caching effect to appear is to shift the instruction address by a few bytes. –  AShelly Dec 2 '11 at 1:13

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