Geometric Mean: is there a built-in?

I tried to find a built-in for geometric mean but couldn't.

(Obviously a built-in isn't going to save me any time while working in the shell, nor do I suspect there's any difference in accuracy; for scripts I try to use built-ins as often as possible, where the (cumulative) performance gain is often noticeable.

In case there isn't one (which I doubt is the case) here's mine.

``````gm_mean = function(a){prod(a)^(1/length(a))}
``````
• Careful about negative numbers and overflows. prod(a) will under or overflow very quickly. I tried to time this using a big list and quickly got Inf using your method vs 1.4 with exp(mean(log(x))); the rounding problem can be quite severe. Apr 8, 2010 at 22:12
• i just wrote the function above quickly because i was sure that 5 min after posting this Q, someone would tell me R's built-in for gm. So no built-in so it's certain worth taking the time to re-code in light of your remarks. + 1 from me.
– doug
Apr 8, 2010 at 23:12
• I just tagged this geometric-mean and built-in, 9 years later.
– smci
Jan 12, 2019 at 15:55

No, but there are a few people who have written one, such as here.

Another possibility is to use this:

``````exp(mean(log(x)))
``````
• Another advantage of using exp(mean(log(x))) is that you can work with long lists of large numbers, which is problematic when using the more obvious formula using prod(). Note that prod(a)^(1/length(a)) and exp(mean(log(a))) give the same answer. Feb 23, 2015 at 4:45
• the link has been fixed Sep 26, 2018 at 18:11

Here is a vectorized, zero- and NA-tolerant function for calculating geometric mean in R. The verbose `mean` calculation involving `length(x)` is necessary for the cases where `x` contains non-positive values.

``````gm_mean = function(x, na.rm=TRUE){
exp(sum(log(x[x > 0]), na.rm=na.rm) / length(x))
}
``````

Thanks to @ben-bolker for noting the `na.rm` pass-through and @Gregor for making sure it works correctly.

I think some of the comments are related to a false-equivalency of `NA` values in the data and zeros. In the application I had in mind they are the same, but of course this is not generally true. Thus, if you want to include optional propagation of zeros, and treat the `length(x)` differently in the case of `NA` removal, the following is a slightly longer alternative to the function above.

``````gm_mean = function(x, na.rm=TRUE, zero.propagate = FALSE){
if(any(x < 0, na.rm = TRUE)){
return(NaN)
}
if(zero.propagate){
if(any(x == 0, na.rm = TRUE)){
return(0)
}
exp(mean(log(x), na.rm = na.rm))
} else {
exp(sum(log(x[x > 0]), na.rm=na.rm) / length(x))
}
}
``````

Note that it also checks for any negative values, and returns a more informative and appropriate `NaN` respecting that geometric mean is not defined for negative values (but is for zeros). Thanks to commenters who stayed on my case about this.

• wouldn't it be better to pass `na.rm` through as an argument (i.e. let the user decide whether they want to be NA-tolerant or not, for consistency with other R summary functions)? I'm nervous about automatically excluding zeroes -- I would make that an option as well. Aug 28, 2014 at 19:21
• Perhaps you're right about passing `na.rm` as an option. I'll update my answer. As for excluding zeroes, the geometric mean is undefined for non-positive values, including zeroes. The above is a common fix for geometric mean, in which zeroes (or in this case all non-zeroes) are given a dummy value of 1, which has no effect on the product (or equivalently, zero in the logarithmic sum). Aug 28, 2014 at 20:01
• Your `na.rm` pass-through doesn't work as coded... see `gm_mean(c(1:3, NA), na.rm = T)`. You need to remove the `& !is.na(x)` from the vector subset, and since the first arg of `sum` is `...`, you need to pass `na.rm = na.rm` by name, and you also need to exclude `0`'s and `NA`'s from the vector in the `length` call. Aug 28, 2014 at 20:53
• Beware: for `x` containing only zero(s), like `x <- 0`, `exp(sum(log(x[x>0]), na.rm = TRUE)/length(x))` gives `1` for the geometric mean, which doesn't make sense. Jan 21, 2017 at 22:40
• Assuming na.rm = TRUE, wouldn't it have to be something like length(x[!is.na(x) & x > 0])? Apr 23, 2021 at 7:44

We can use psych package and call geometric.mean function.

• `psych::geometric.mean()`
– smci
Jul 17, 2015 at 22:52
• These functions should take the series and not their growth, at least as an option, I would say. Oct 14, 2016 at 13:25

The

``````exp(mean(log(x)))
``````

will work unless there is a 0 in x. If so, the log will produce -Inf (-Infinite) which always results in a geometric mean of 0.

One solution is to remove the -Inf value before calculating the mean:

``````geo_mean <- function(data) {
log_data <- log(data)
gm <- exp(mean(log_data[is.finite(log_data)]))
return(gm)
}
``````

You can use a one-liner to do this but it means calculating the log twice which is inefficient.

``````exp(mean(log(i[is.finite(log(i))])))
``````
• why calculate the log twice when you can do: exp(mean(x[x!=0]))
– zzk
Jul 25, 2014 at 20:54
• both approaches get the mean wrong, because the denominator for the mean, `sum(x) / length(x)` is wrong if you filter x and then pass it to `mean`. Aug 28, 2014 at 17:46
• I think filtering is a bad idea unless you explicitly mean to do it (e.g. if I were writing a general-purpose function I would not make filtering the default) -- OK if this is a one-off piece of code and you've thought very carefully about what filtering zeroes out actually means in the context of your problem (!) Aug 28, 2014 at 20:18
• By definition a geometric mean of a set of numbers containing zero should be zero! math.stackexchange.com/a/91445/221143 Aug 26, 2016 at 4:00

I use exactly what Mark says. This way, even with tapply, you can use the built-in `mean` function, no need to define yours! For example, to compute per-group geometric means of data\$value:

``````exp(tapply(log(data\$value), data\$group, mean))
``````

The EnvStats package has a function for geoMean and geoSd.

This version provides more options than the other answers.

• It allows the user to distinguish between results that are not (real) numbers and those that are not available. If negative numbers are present, then the answer won't be a real number, so `NaN` is returned. If it's all `NA` values then the function will return `NA_real_` instead to reflect that a real value is literally not available. This is a subtle difference, but one that might yield (slightly) more robust results.

• The first optional parameter `zero.rm` is intended to allow the user to have zeros affect the output without making it zero. If `zero.rm` is set to `FALSE` and `eta` is set to `NA_real_` (its default value), zeros have the effect of shrinking the result towards one. I don't have any theoretical justification for this - it just seems to make more sense to not ignore the zeros but to "do something" that doesn't involve automatically making the result zero.

• `eta` is a way of handling zeros that was inspired by the following discussion: https://support.bioconductor.org/p/64014/

``````geomean <- function(x,
zero.rm = TRUE,
na.rm = TRUE,
nan.rm = TRUE,
eta = NA_real_) {
nan.count <- sum(is.nan(x))
na.count <- sum(is.na(x))
value.count <- if(zero.rm) sum(x[!is.na(x)] > 0) else sum(!is.na(x))

#Handle cases when there are negative values, all values are missing, or
#missing values are not tolerated.
if ((nan.count > 0 & !nan.rm) | any(x < 0, na.rm = TRUE)) {
return(NaN)
}
if ((na.count > 0 & !na.rm) | value.count == 0) {
return(NA_real_)
}

#Handle cases when non-missing values are either all positive or all zero.
#In these cases the eta parameter is irrelevant and therefore ignored.
if (all(x > 0, na.rm = TRUE)) {
return(exp(mean(log(x), na.rm = TRUE)))
}
if (all(x == 0, na.rm = TRUE)) {
return(0)
}

#All remaining cases are cases when there are a mix of positive and zero
#values.
#By default, we do not use an artificial constant or propagate zeros.
if (is.na(eta)) {
return(exp(sum(log(x[x > 0]), na.rm = TRUE) / value.count))
}
if (eta > 0) {
return(exp(mean(log(x + eta), na.rm = TRUE)) - eta)
}
return(0) #only propagate zeroes when eta is set to 0 (or less than 0)
}
``````
• Can you add some details explaining how this differs from/improves on existing solutions? (I personally wouldn't want to add a heavy dependency like `dplyr` for such a utility unless necessary ...) Jan 8, 2020 at 0:17
• I agree, the `case_when`s were a little silly, so I removed them and the dependency in favor of `if`s. I also provided some elaboration. Jan 8, 2020 at 21:41
• I went with your latter idea and changed the default of `nan.rm` to `TRUE` to align all three ```.rm`` parameters. Jan 8, 2020 at 22:19
• One other stylistic nitpick. `ifelse` is designed for vectorization. With a single condition to check, it would be more idiomatic to use `value.count <- if(zero.rm) sum(x[!is.na(x)] > 0) else sum(!is.na(x))` Jan 9, 2020 at 4:23
• It looks nicer than `ifelse`, too. Changed. Thanks! Jan 9, 2020 at 22:01

In case there is missing values in your data, this is not a rare case. you need to add one more argument.

You may try following code:

``````exp(mean(log(i[ is.finite(log(i)) ]), na.rm = TRUE))
``````
``````exp(mean(log(x1))) == prod(x1)^(1/length(x1))
``````