The machine precision for `double`

depends on its current value. `.Machine$double.eps`

gives the precision when the values is 1. You can use the C function `nextAfter`

to get the machine precision for other values.

```
library(Rcpp)
cppFunction("double getPrec(double x) {
return nextafter(x, std::numeric_limits<double>::infinity()) - x;}")
(pr <- getPrec(1))
#[1] 2.220446e-16
1 + pr == 1
#[1] FALSE
1 + pr/2 == 1
#[1] TRUE
1 + (pr/2 + getPrec(pr/2)) == 1
#[1] FALSE
1 + pr/2 + pr/2 == 1
#[1] TRUE
pr/2 + pr/2 + 1 == 1
#[1] FALSE
```

Adding value `a`

to value `b`

will not change `b`

when `a`

is `<=`

*half of it's machine precision.* Checking if the difference is smaler than machine precision is done with `<`

. The modifiers might consider typical cases how often an addition did not show a change.

In *R* the machine precision can be estimated with:

```
getPrecR <- function(x) {
y <- log2(pmax(.Machine$double.xmin, abs(x)))
ifelse(x < 0 & floor(y) == y, 2^(y-1), 2^floor(y)) * .Machine$double.eps
}
getPrecR(1)
#[1] 2.220446e-16
```

Each `double`

value is representing a range. For a simple addition, the range of the result depends on the reange of each summand and also the range of their sum.

```
library(Rcpp)
cppFunction("std::vector<double> getRange(double x) {return std::vector<double>{
(nextafter(x, -std::numeric_limits<double>::infinity()) - x)/2.
, (nextafter(x, std::numeric_limits<double>::infinity()) - x)/2.};}")
x <- 2^54 - 2
getRange(x)
#[1] -1 1
y <- 4.1
getRange(y)
#[1] -4.440892e-16 4.440892e-16
z <- x + y
getRange(z)
#[1] -2 2
z - x - y #Should be 0
#[1] 1.9
2^54 - 2.9 + 4.1 - (2^54 + 5.9) #Should be -4.7
#[1] 0
2^54 - 2.9 == 2^54 - 2 #Gain 0.9
2^54 - 2 + 4.1 == 2^54 + 4 #Gain 1.9
2^54 + 5.9 == 2^54 + 4 #Gain 1.9
```

For higher precission `Rmpfr`

could be used.

```
library(Rmpfr)
mpfr("2", 1024L)^54 - 2.9 + 4.1 - (mpfr("2", 1024L)^54 + 5.9)
#[1] -4.700000000000000621724893790087662637233734130859375
```

In case it could be converted to integer `gmp`

could be used (what is in Rmpfr).

```
library(gmp)
as.bigz("2")^54 * 10 - 29 + 41 - (as.bigz("2")^54 * 10 + 59)
#[1] -47
```

`double.eps`

. If you are performing several operations on a floating point number, then your error tolerance should also adjust. This is why all.equal gives you a`tolerance`

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