The checkthat philosophy is that you already perform good data checks and you should keep doing it. But those checks would be even better if they lived in the code, rather than in your head. Checkthat therefore provides functions that closely resemble the checks you already do by hand or by eye, so that it is easy for you to also express them in code as you go.
Basic usage
Checkthat’s main function is check_that(.data, ...)
,
which takes a dataframe as its first argument, followed by any number of
assertions you want to check for that dataframe.
When all checks pass, you get a brief message confirming that’s the case.
library(checkthat)
mtcars |>
check_that(
all(cyl > 2),
!any(is.na(mpg))
)
#> ✔ all data checks passing
When at least one check fails, check_that()
throws an
error, halting the potentially risky execution of subsequent code. It
then gives you get a detailed breakdown of what the outcome was for each
test.
mtcars |>
check_that(
all(cyl > 2),
any(mpg > 35)
)
#>
#> ── Data Checks ─────────────────────────────────────────────────────────────────
#>
#> ✔ all(cyl > 2) --> TRUE
#> ✖ any(mpg > 35) --> FALSE
#>
#> ────────────────────────────────────────────────────────────────────────────────
#>
#> Error in `cli_throw_test_error()`:
#> ! At least one data check failed.
The check_that()
function is designed to work with both
base R’s existing logical functions (e.g., all()
,
any()
), as well it’s own set of more special helper
functions. Theses helper functions are designed to be both readable and
to mirror in code what you already do manually by eye-balling a
dataset.
mtcars |>
check_that(
some_of(cyl > 4, at_least = .30, at_most = 25),
whenever(wt < 3, then_expect = mpg > 19),
for_case(2, mpg == 21, hp == 110)
)
#> ✔ all data checks passing
Tidyverse pipelines
The check_that()
function always invisibly returns the
same .data
you gave it (always unmodified). This allows you
to easily integrate it directly into your data manipulation
pipelines.
library(dplyr)
new_mtcars <- mtcars |>
select(mpg) |>
mutate(km_per_litre = 0.425 * mpg) |>
check_that(max(km_per_litre) < 15)
#> ✔ all data checks passing
head(new_mtcars)
#> mpg km_per_litre
#> Mazda RX4 21.0 8.9250
#> Mazda RX4 Wag 21.0 8.9250
#> Datsun 710 22.8 9.6900
#> Hornet 4 Drive 21.4 9.0950
#> Hornet Sportabout 18.7 7.9475
#> Valiant 18.1 7.6925
Checking a pipeline at multiple points
Because it returns the same dataframe it received,
check_that()
can also be used at multiple points in a
single pipeline. That way, you can check that multi-step processes are
unfolding according to plan. This is be especially important for data
tasks that are sensitive to the order of operations, or for checks on
intermediate data that wont be available at the end.
Consider a surprisingly tricky example. Imagine we wanted to (1)
create a factor variable (type
) designating cars as either
small ("sm"
) or large ("lg"
) based on their
weight (wt
). Further imagine that we then (2) planned to
filter in only the small cars and (3) calculate their mean
mpg
as our desired_mpg
. This value might then
be used to inform a personal purchase decision or perhaps to establish
an industry benchmark for a manufacturer.
The resulting data pipeline should be simple, but let’s use
check_that()
at multiple points to be safe.
- We wont have access to the
wt
variable at the end of the pipeline. So, right after we usewt
to computetype
, we immediately check that all the weights in the"sm"
group are less than those in the"lg"
group, as intended. - At the end, we check that our
desired_mpg
is within a plausible range.
Here, the first check throws an error and stopS the pipeline. It also
saves us from an inaccurate desired_mpg
that the second
check would not have caught.
mtcars |>
mutate(type = factor(wt < 3, labels = c("sm", "lg"), ordered = TRUE)) |>
check_that(max(wt[type == "sm"]) <= min(wt[type == "lg"])) |>
filter(type == "sm") |>
summarise(desired_mpg = mean(mpg)) |>
check_that(desired_mpg > 15)
#>
#> ── Data Checks ─────────────────────────────────────────────────────────────────
#>
#> ✖ max(wt[type == "sm"]) <= min(wt[type == "lg"]) --> FALSE
#>
#> ────────────────────────────────────────────────────────────────────────────────
#>
#> Error in `cli_throw_test_error()`:
#> ! At least one data check failed.
What happened? A quick reading of
factor(wt < 3, labels = c("sm", "lg"), ordered = TRUE)
seems like it would correctly assign cars to the correct group. However,
the labels are out of order in the function call.1 As a result, the heavy
cars are mistakenly labelled "sm"
and vice-versa.2
Importantly, this mistake (a) would have given us an erroneously low
desired_mpg
and (b) would have gone undetected by our final
check_that(desired_mpg > 15)
. It was a call to
check_that()
earlier in the pipeline that caught the error
and prevented us from drawing an bad conclusion about our data later
on.
Helper functions
Checkthat’s philosophy is your existing data checks by eye are
probably already good. Their only major problem is that they live in
your head and not in your code. So, checkthat provides a range of helper
functions to work alongside base R’s existing collection (e.g.,
all()
, any()
). These include both some basic
and more special varieties.
Basic helpers
The most basic helpers are just syntactic sugar around R’s existing
comparison operators: =
, <
,
<=
, >
, >=
. Each of them
takes a logical vector as its first argument and requires you to specify
a proportion (p
) or count (n
) of those values
that must be true.
mtcars |>
check_that(
at_least(mpg < 35, p = .95),
more_than(hp == 110, n = 2),
exactly_equal(cyl == 6, n = 7),
less_than(wt > 3, p = .75),
at_most(is.na(mpg), n = 3),
)
#> ✔ all data checks passing
Special helpers
The remaining helpers include some_of()
,
whenever()
, and for_case()
and are more
flexible than their basic counterparts. They’re optimized for the kind
of semi-approximate data checking you are likely already doing by
eye.
For most people, this involves a general sense of what most of the
data should look like most of the time, but not exact knowledge of
specific proportions or counts. For example, you might have good reason
to think some_of()
the cyl
values should be
greater than 4, but you don’t know exactly how many. However, you do
know it should probably be at_least
30%, but
at_most
25 total cases in your dataset. Anything outside
that range would be implausible and so you want to guard it with
check_that()
.
mtcars |>
check_that(
some_of(cyl > 4, at_least = .30, at_most = 25),
whenever(is_observed = wt < 3, then_expect = mpg > 19),
for_case(2, mpg == 21, hp == 110)
)
#> ✔ all data checks passing
Just like unit tests for production code, the tests created with
these special helper functions will be technically imperfect and leave
some (possibly important) scenarios addressed. After all, there’s a big
range of possibilities between at_least = .30
and
at_most = 25
, and some of them might involve an undetected
data problem.
However, checkthat takes the position that imperfect tests are still
valuable informative and you should be able to take advantage of them.
For example, if you have reasons to be concerned about the data in your
column crossing the at_most = 25
, you should be able to
quickly and easily write that test with a combination of
check_that()
and some_of()
.
Moreover, a world of no tests at all is much worse than a world of some tests that fail to cover every case. With that in mind, checkthat’s special helper functions are designed to bring you from not writing down any tests in your code to quickly and easily coding the tests you already do by eye.
Checking the whole dataframe
In addition to concerns about the individual rows or columns in your
data, you may also want to perform checks on the entire dataframe in
question. For those cases, check_that()
provides the
.d
pronoun, which works similarly to .x
in the
purrr package.
In short, .d
is a copy of the data you provided to
check_that()
, which you can use to write checks about the
whole dataset.
mtcars |>
check_that(
nrow(.d) > 10,
"mpg" %in% names(.d)
)
#> ✔ all data checks passing
This is especially useful for operations that could change the shape of your dataset (e.g., pivots, nests, joins). In the case of pivoting, you might want to check that the dataset have the correct anticipated dimensions.
library(tidyr)
mtcars |>
check_that(ncol(.d) == 11, nrow(.d) == 32) |> # original dimensions
pivot_longer(
cols = everything(),
names_to = "name",
values_to = "values"
) |>
check_that(ncol(.d) == 2, nrow(.d) == 32 * 11) # check that cols became rows
#> ✔ all data checks passing
#> ✔ all data checks passing
After a join, you may want to check that there is a new column in the expected location, but also that there are no unanticipated new rows.
cyl_ratings_df <- data.frame(cyl = c(4, 6, 8), group = c("A", "B", "C"))
mtcars |>
left_join(cyl_ratings_df, by = "cyl") |>
check_that(
ncol(.d) == 12, # check that there's one new column
names(.d)[length(names(.d))] == "group", # check new column is "group"
nrow(.d) == 32 # check that no new rows
)
#> ✔ all data checks passing