# Reproducible splitting of data into training and testing in R

A common way for sampling/splitting data in R is using `sample`, e.g., on row numbers. For example:

``````require(data.table)
set.seed(1)

population <- as.character(1e5:(1e6-1))  # some made up ID names

N <- 1e4  # sample size

sample1 <- data.table(id = sort(sample(population, N)))  # randomly sample N ids
test <- sample(N-1, N/2, replace = F)
test1 <- sample1[test, .(id)]
``````

The problem is that this isn't very robust to changes in the data. For example if we drop just one observation:

``````sample2 <- sample1[-sample(N, 1)]
``````

samples 1 and 2 are still all but identical:

``````nrow(merge(sample1, sample2))
``````

 9999

Yet the same row splitting yields very different test sets, even though we've set the seed:

``````test2 <- sample2[test, .(id)]
nrow(test1)
``````

 5000

``````nrow(merge(test1, test2))
``````

 2653

One could sample specific IDs, but this would not be robust in case observations are omitted or added.

What would be a way to make the split more robust to changes to the data? Namely, have the assignment to test unchanged for unchanged observations, not assign dropped observations, and reassign new observations?

## 1 Answer

Use a hash function and sample on the mod of its last digit:

``````md5_bit_mod <- function(x, m = 2L) {
# Inputs:
#  x: a character vector of ids
#  m: the modulo divisor (modify for split proportions other than 50:50)
# Output: remainders from dividing the first digit of the md5 hash of x by m
as.integer(as.hexmode(substr(openssl::md5(x), 1, 1)) %% m)
}
``````

hash splitting works better in this case, because the assignment of test/train is determined by the hash of each obs., and not by its relative location in the data

``````test1a <- sample1[md5_bit_mod(id) == 0L, .(id)]
test2a <- sample2[md5_bit_mod(id) == 0L, .(id)]

nrow(merge(test1a, test2a))
``````

 5057

``````nrow(test1a)
``````

 5057

sample size is not exactly 5000 because assignment is probabilistic, but it shouldn't be a problem in large samples thanks to the law of large numbers.