No, but there are two ways you can make it:
Using C
If you want the exact functionality of the nextafter()
function, you can write a C function that works as an interface to the function such that the following two constraints are met:
- The function does not return a value. All work is accomplished as a "side effect" (changing the values of arguments).
- All the arguments are pointers. Even scalars are vectors (of length one) in R.
That function should then be compiled as a shared library:
R CMD SHLIB foo.c
for UNIX-like OSs. The shared library can be called using dyn.load("foo.so")
. You can then call the function from inside R using the .C()
function
.C("foo", ...)
A more in depth treatment of calling C from R is here.
Using R
number + .Machine$double.eps
is the way to go but you have to consider edge cases, such as if x - y < .Machine$double.eps
or if x == y
. I would write the function like this:
nextafter <- function(x, y){
# Appropriate type checking and bounds checking goes here
delta = y - x
if(x > 0){
factor = 2^floor(log2(x)) + ifelse(x >= 4, 1, 0)
} else if (x < 0) {
factor = 65
}
if (delta > .Machine$double.eps){
return(x + factor * .Machine$double.eps)
} else if (delta < .Machine$double.eps){
return(x - factor * .Machine$double.eps)
} else {
return(x)
}
}
Now, unlike C, if you want to check integers, you can do so in the same function but you need to change the increment based on the type.
UPDATE
The previous code did not perform as expected for numbers larger than 2. There is a factor that needs to be multiplied by the .Machine$double.eps
to make it large enough to cause the numbers to be different. It is related to the nearest power of 2 plus one. You can get an idea of how this works with the below code:
n <- -100
factor <- vector('numeric', 100)
for(i in 1:n){
j = 0
while(TRUE){
j = j + 1
if(i - j * .Machine$double.eps != i) break()
}
factor[i] = j
}
与恶龙缠斗过久,自身亦成为恶龙;凝视深渊过久,深渊将回以凝视…