# What is the correct/standard way to check if difference is smaller than machine precision?

I often end up in situations where it is necessary to check if the obtained difference is above machine precision. Seems like for this purpose R has a handy variable: `.Machine\$double.eps`. However when I turn to R source code for guidelines about using this value I see multiple different patterns.

### Examples

Here are a few examples from `stats` library:

t.test.R

``````if(stderr < 10 *.Machine\$double.eps * abs(mx))
``````

chisq.test.R

``````if(abs(sum(p)-1) > sqrt(.Machine\$double.eps))
``````

integrate.R

``````rel.tol < max(50*.Machine\$double.eps, 0.5e-28)
``````

lm.influence.R

``````e[abs(e) < 100 * .Machine\$double.eps * median(abs(e))] <- 0
``````

princomp.R

``````if (any(ev[neg] < - 9 * .Machine\$double.eps * ev[1L]))
``````

etc.

### Questions

1. How can one understand the reasoning behind all those different `10 *`, `100 *`, `50 *` and `sqrt()` modifiers?
2. Are there guidelines about using `.Machine\$double.eps` for adjusting differences due to precision issues?
• Dec 12, 2019 at 8:15
• Thus, both posts conclude that "the reasonable degree of certainty" depends on your application. As a case study, you may check this post on R-devel; "Aha! 100 times machine precision in not all that much when the numbers themselves are in double digits." (Peter Dalgaard, member of the R Core team) Dec 13, 2019 at 9:53
• @KarolisKoncevičius, I don't think it is that simple. It has to do with the general errors present in floating point math and how many operations you execute on them. If you are simply comparing to floating point numbers, use `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` argument. Dec 16, 2019 at 22:56
• Have also a look at Implementation of nextafter functionality in R what will give you the next larger double number.
– GKi
Jan 21, 2020 at 16:23

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))
# 2.220446e-16
1 + pr == 1
# FALSE
1 + pr/2 == 1
# TRUE
1 + (pr/2 + getPrec(pr/2)) == 1
# FALSE
1 + pr/2 + pr/2 == 1
# TRUE
pr/2 + pr/2 + 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)
# 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
y <- 4.1
getRange(y)
# -4.440892e-16  4.440892e-16
z <- x + y
getRange(z)
# -2  2
z - x - y #Should be 0
# 1.9

2^54 - 2.9 + 4.1 - (2^54 + 5.9) #Should be -4.7
# 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)
# -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)
# -47
``````
• Thanks a lot. I feel like this is a much better answer. It illustrates a lot of the points nicely. The only thing that is still a bit unclear to me is - can one come up with the modifiers (like *9, etc) on his/her own? And if so how... Jan 22, 2020 at 14:00
• I think this modifier is like the significance level in statistics and will increase by the number of operations you have done in combination by the chosen risk to reject a correct comparison.
– GKi
Jan 22, 2020 at 14:11

Definition of a machine.eps: it is the lowest value `eps` for which `1+eps` is not `1`

As a rule of thumb (assuming a floating point representation with base 2):
This `eps` makes the difference for the range 1 .. 2,
for the range 2 .. 4 the precision is `2*eps`
and so on.

Unfortunately, there is no good rule of thumb here. It's entirely determined by the needs of your program.

In R we have all.equal as a built in way to test approximate equality. So you could use maybe something like `(x<y) | all.equal(x,y`)

``````i <- 0.1
i <- i + 0.05
i
if(isTRUE(all.equal(i, .15))) { #code was getting sloppy &went to multiple lines
cat("i equals 0.15\n")
} else {
cat("i does not equal 0.15\n")
}
#i equals 0.15
``````

Google mock has a number of floating point matchers for double precision comparisons, including `DoubleEq` and `DoubleNear`. You can use them in an array matcher like this:

``````ASSERT_THAT(vec, ElementsAre(DoubleEq(0.1), DoubleEq(0.2)));
``````

Update:

Numerical Recipes provide a derivation to demonstrate that using a one-sided difference quotient, `sqrt` is a good choice of step-size for finite difference approximations of derivatives.

The Wikipedia article site Numerical Recipes, 3rd edition, Section 5.7, which is pages 229-230 (a limited number of page views is available at http://www.nrbook.com/empanel/).

``````all.equal(target, current,
tolerance = .Machine\$double.eps ^ 0.5, scale = NULL,
..., check.attributes = TRUE)
``````

These IEEE floating point arithmetic is a well known limitation of computer arithmetic and is discussed in several places:

. `dplyr::near()` is another option for testing if two vectors of floating point numbers are equal.

The function has a built in tolerance parameter: `tol = .Machine\$double.eps^0.5` that can be adjusted. The default parameter is the same as the default for `all.equal()`.

• Thanks for the response. At the moment I think this is too minimal to be an accepted answer. It doesn't seem to address the two main questions from the post. For example it states "it's determined by the needs of your program". It would be nice to show one or two examples of this statement - maybe a small program and how tolerance can be determined by it. Maybe using one of the mentioned R scripts. Also `all.equal()` has it's own assumption as default tolerance there is `sqrt(double.eps)` - why is it the default? Is it a good rule of thumb to use `sqrt()`? Dec 17, 2019 at 19:46
• Here is the code R uses to calculate eps (extracted into its own program). Also I have updated the Answer with numerous discussion points which I had gone through before. Hope the same helps you understand better. Dec 18, 2019 at 5:54
• A sincere +1 for all the effort. But at the current state I still cannot accept the answer. It seems to bit a bit out-reaching with a lot of references, but in terms of actual answer to the 2 posted questions: 1) how to understand 100x, 50x, etc modifiers in R `stats::` source, and 2) what are the guidelines; the answer is quite thin. The only applicable sentence seems to be the reference from "Numerical Recipes" about sqrt() being a good default, which is really on point, I feel. Or maybe I am missing something here. Dec 18, 2019 at 21:09