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Is there fast way to do round up/down in Fortran?

Because of linear order of bit-representation of positive double numbers it's possible to implement rounding as below.

pinf and ninf are global constants which are +/- infinity respectively

function roundup(x)
    double precision ,intent(in) :: x
    double precision :: roundup

    if (isnan(x))then 
        roundup = pinf
        return
    end if 
    if (x==pinf)then
        roundup = pinf
        return 
    end if
    if (x==ninf)then
        roundup = ninf
        return 
    end if
    if (x>0)then
        roundup = transfer((transfer(x,1_8)+1_8),1d0)
    else if (x<0) then
        roundup = transfer((transfer(x,1_8)-1_8),1d0)
    else
        if (transfer(x,1_8)==Z'0000000000000000')then
            roundup = transfer((transfer(x,1_8)+1_8),1d0)
        else
            roundup = transfer((transfer(-x,1_8)+1_8),1d0)
        end if 
    end if 
end function roundup

I feel it's not the best way to do that because it's slow, but it uses almost only bit-operations.

Another way is using multiplication and some epsilon eps = epsilon (1d0)

function roundup2(x)
    double precision ,intent(in) :: x
    double precision :: roundup2
    if (isnan(x)) then 
        roundup2 = pinf
        return 
    else if (x>=eps) then 
        roundup2 = x*(1d0+eps)
    else if (x<=-eps) then 
        roundup2 = x*(1d0-eps)
    else 
        roundup2 = eps
    end if 
end function roundup2

For some x both functions returns the same result (1d0, 158d0), for some don't (0.1d0, 15d0).

The first function is more accurate, but it's about 3.6 times slower than second (11.1 vs 3.0 seconds on 10^9 rounds test)

    print * ,x,y,abs(x-y)
    do i = 1, 1000000000
        x = roundup(x)
        !y = roundup2(y)
    end do 
    print * ,x,y,abs(x-y)

With no checks for NaN/Infinities first function test takes 8.5 seconds (-20%).

I use round function really hard and it takes a lot of time in profile of program. Is there cross-platform way to round faster with no loose of precision?

Update

The question suspects calls of roundup and rounddown at the time with no ability to reorder them. I didn't mention rounddown to keep topic short.

Hint: First function uses two transfer function and one adding. And it's slower than one multiplication and one adding in the second case. Why transfer cost so much when it doesn't do any with the number's bits? Is it possible to replace transfer by faster function(s) or avoid addition calls at all?

share|improve this question
    
Have you tried using nint? –  cup Aug 27 '13 at 23:27
    
I need to "round" to the closest representative double not to int. Title might be a bit misleading but it clear from the body. –  Sergei Aug 28 '13 at 8:15

2 Answers 2

up vote 2 down vote accepted

If I'm understanding correctly what you want to do, doesn't the "nearest" intrinsic do what you want, if you feed it +/- infinity as the arguments?

http://gcc.gnu.org/onlinedocs/gfortran/NEAREST.html#NEAREST

This might work, if the compiler implements this with decent performance. If you want NaN to round to Inf, you'll have to add that in a wrapper.

As for why roundup2 is faster, I can't tell for certain what's going on on your machine, but I can say two things:

  1. The addition in roundup2 is probably optimized out (if eps is a parameter?) , so there's really just a multiplication.
  2. If the transfer really does anything at all, that could easily slow the function down noticeably, since the function itself is so short. That might even be true if the transfer is just making superfluous copies of x.
share|improve this answer
    
Thanks, NEAREST works well with usual doubles, but it three times slower even than first roundup on my machine with gcc. –  Sergei Aug 28 '13 at 8:23
    
Rather strange that it's so much slower than yours, since it probably uses an implementation resembling nextafter, which itself closely resemble your first roundup. –  jca Aug 28 '13 at 14:31

I would recommend that you look at the Fortran standard IEEE floating point intrinsic modules (IEEE_ARITHMETIC, IEEE_FEATURES, IEEE_EXCEPTIONS). These provide IEEE_SET_ROUNDING_MODE where you can set the rounding mode for subsequent operations. Ideally you'd use IEEE_GET_ROUNDING_MODE to get the current mode and save it, set the new one, do your operations, then restore the mode.

Some caveats - changing the processor rounding mode is itself a slow operation, but if you do it once and then do lots of rounds, that will be a win. Not all current Fortran compilers support the IEEE intrinsic modules, but most reasonable ones should. You might need to tell the compiler you are playing with the IEEE environment - for Intel Fortran, use "-fp-model strict".

share|improve this answer
    
Thanks for recommends, but it's not suits for my needs. I can't reorder round operations to do them in a bulk. May be there is some tricks with bit-functions? –  Sergei Aug 27 '13 at 16:14
    
You don't HAVE to do them in bulk. Why not try writing a function that uses the standard features and see how it works for you? I think it would have to be faster than the other things you proposed. Bit manipulation of FP values is very tricky - I should know as I've written (and fixed bugs in) code that does so. –  Steve Lionel Aug 28 '13 at 0:00
    
I need to use both roundup and rounddown at the same time. Changing rounding mode is expensive as you mentioned. I can't do that. –  Sergei Aug 28 '13 at 8:31

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