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?