When you write functions that operate on S3 or unclassed objects you can either trust that your inputs will be structured as expected, or tediously check that they are.

vetr takes the tedium out of structure verification so that you can trust, but verify. It lets you express structural requirements declaratively with templates, and it auto-generates human-friendly error messages as needed.

vetr is written in C to minimize overhead from parameter checks in your functions. It has no dependencies.

Declare a template that an object should conform to, and let vetr take care of the rest:

library(vetr)
tpl <- numeric(1L)
vet(tpl, 1:3)
## [1] "`length(1:3)` should be 1 (is 3)"
vet(tpl, "hello")
## [1] "`\"hello\"` should be type \"numeric\" (is \"character\")"
vet(tpl, 42)
## [1] TRUE

The template concept is based on vapply, but generalizes to all S3 objects and adds some special features to facilitate comparison. For example, zero length templates match any length:

tpl <- integer()
vet(tpl, 1L:3L)
## [1] TRUE
vet(tpl, 1L)
## [1] TRUE

And for convenience short (<= 100 length) integer-like numerics are considered integer:

tpl <- integer(1L)
vet(tpl, 1)       # this is a numeric, not an integer
## [1] TRUE
vet(tpl, 1.0001)
## [1] "`1.0001` should be type \"integer-like\" (is \"double\")"

vetr can compare recursive objects such as lists, or data.frames:

tpl.iris <- iris[0, ]      # 0 row DF matches any number of rows in object
iris.fake <- iris
levels(iris.fake$Species)[3] <- "sibirica"   # tweak levels

vet(tpl.iris, iris)
## [1] TRUE
vet(tpl.iris, iris.fake)
## [1] "`levels(iris.fake$Species)[3]` should be \"virginica\" (is \"sibirica\")"

From our declared template iris[0, ], vetr infers all the required checks. In this case, vet(iris[0, ], iris.fake, stop=TRUE) is equivalent to:

stopifnot_iris <- function(x) {
  stopifnot(
    is.data.frame(x),
    is.list(x),
    length(x) == length(iris),
    identical(lapply(x, class), lapply(iris, class)),
    is.integer(attr(x, 'row.names')),
    identical(names(x), names(iris)),
    identical(typeof(x$Species), "integer"),
    identical(levels(x$Species), levels(iris$Species))
  )
}
stopifnot_iris(iris.fake)
## Error in stopifnot_iris(iris.fake): identical(levels(x$Species), levels(iris$Species)) is not TRUE

vetr saved us typing, and the time and thought needed to come up with what needs to be compared.

You could just as easily have created templates for nested lists, or data frames in lists. Templates are compared to objects with the alike function. For a thorough description of templates and how they work see the alike vignette. For template examples see example(alike).

Let’s revisit the error message:

vet(tpl.iris, iris.fake)
## [1] "`levels(iris.fake$Species)[3]` should be \"virginica\" (is \"sibirica\")"

It tells us:

• The reason for the failure
• What structure would be acceptable instead
• The location of failure levels(iris.fake$Species)[3]

vetr does what it can to reduce the time from error to resolution. The location of failure is generated such that you can easily copy it in part or full to the R prompt for further examination.

You can combine templates with && / ||:

vet(numeric(1L) || NULL, NULL)
## [1] TRUE
vet(numeric(1L) || NULL, 42)
## [1] TRUE
vet(numeric(1L) || NULL, "foo")
## [1] "`\"foo\"` should be `NULL`, or type \"numeric\" (is \"character\")"

Templates only check structure. When you need to check values use . to refer to the object:

vet(numeric(1L) && . > 0, -42)  # strictly positive scalar numeric
## [1] "`-42 > 0` is not TRUE (FALSE)"
vet(numeric(1L) && . > 0, 42)
## [1] TRUE

If you do use the . symbol in your vetting expressions in your packages, you will need to include utils::globalVariables(".") as a top-level call to avoid the “no visible binding for global variable ‘.’” R CMD check NOTE.

You can compose vetting expressions as language objects and combine them:

scalar.num.pos <- quote(numeric(1L) && . > 0)
foo.or.bar <- quote(character(1L) && . %in% c('foo', 'bar'))
vet.exp <- quote(scalar.num.pos || foo.or.bar)

vet(vet.exp, 42)
## [1] TRUE
vet(vet.exp, "foo")
## [1] TRUE
vet(vet.exp, "baz")
## [1] "At least one of these should pass:"                         
## [2] "  - `\"baz\" %in% c(\"foo\", \"bar\")` is not TRUE (FALSE)" 
## [3] "  - `\"baz\"` should be type \"numeric\" (is \"character\")"

all_bw is available for value range checks (~10x faster than isTRUE(all(. >= x & . <= y)) for large vectors):

vet(all_bw(., 0, 1), runif(5) + 1)
## [1] "`all_bw(runif(5) + 1, 0, 1)` is not TRUE (is chr: \"`1.234342` at index 1 not in `[0,1]`\")"

There are a number of predefined vetting tokens you can use in your vetting expressions such as:

vet(NUM.POS, -runif(5))    # positive numeric; see `?vet_token` for others
## [1] "`-runif(5)` should contain only positive values, but has negatives"

Vetting expressions are designed to be intuitive to use, but their implementation is complex. We recommend you look at example(vet) for usage ideas, or at the “Non Standard Evaluation” section of the vignette for the gory details.

If you are vetting function inputs, you can use the vetr function, which works just like vet except that it is streamlined for use within functions:

fun <- function(x, y) {
  vetr(numeric(1L), logical(1L))
  TRUE   # do work...
}
fun(1:2, "foo")
## Error in fun(x = 1:2, y = "foo"): For argument `x`, `length(1:2)` should be 1 (is 2)
fun(1, "foo")
## Error in fun(x = 1, y = "foo"): For argument `y`, `"foo"` should be type "logical" (is "character")

vetr automatically matches the vetting expressions to the corresponding arguments and fetches the argument values from the function environment.

See vignette for additional details on how the vetr function works.

• vetr vignette, ?vet, ?vetr, example(vet), example(vetr).
• alike vignette, ?alike, and example(alike) for discussion of templates.
• A survey of parameter validation functions.

vetr is still in development, although most of the features are considered mature. The most likely area of change is the treatment of function and language templates (e.g. alike(sum, max)), and more flexible treatment of list templates (e.g. in future lists may be allowed to be different lengths so long as every named element in the template exists in the object).

This package is available on CRAN:

install.packages('vetr')

It has no runtime dependencies.

For the development version use remotes::install_github('brodieg/vetr@development') or:

f.dl <- tempfile()
f.uz <- tempfile()
github.url <- 'https://github.com/brodieG/vetr/archive/development.zip'
download.file(github.url, f.dl)
unzip(f.dl, exdir=f.uz)
install.packages(file.path(f.uz, 'vetr-development'), repos=NULL, type='source')
unlink(c(f.dl, f.uz))

The master branch typically mirrors CRAN and should be stable.

There are many alternatives available to vetr. We do a survey of the following in our parameter validation functions review:

• stopifnot by R Core
• vetr by Yours Truly
• asserthat by Hadley Wickham
• assertive by Richie Cotton
• checkmate by Michel Lang

The following packages also perform related tasks, although we do not review them:

• valaddin v0.1.0 by Eugene Ha, a framework for augmenting existing functions with validation contracts. Currently the package is undergoing a major overhaul so we will add it to the comparison once the new release (v0.3.0) is out.
• ensurer v1.1 by Stefan M. Bache, a framework for flexibly creating and combining validation contracts. The development version adds an experimental method for creating type safe functions, but it is not published to CRAN so we do not test it here.
• validate by Mark van der Loo and Edwin de Jonge, with a primary focus on validating data in data frames and similar data structures.
• assertr by Tony Fischetti, also focused on data validation in data frames and similar structures.
• types by Jim Hester, which implements but does not enforce type hinting.
• argufy by Gábor Csárdi, which implements parameter validation via roxygen tags (not released to CRAN).
• typed by Antoine Fabri, which enforces types of symbols, function parameters, and return values.

Thank you to:

• R Core for developing and maintaining such a wonderful language.
• CRAN maintainers, for patiently shepherding packages onto CRAN and maintaining the repository, and Uwe Ligges in particular for maintaining Winbuilder.
• Users and others who have reported bugs and/or helped contribute fixes (see NEWS.md).
• Tomas Kalibera for rchk and rcnst to help detect errors in compiled code, and in particular for his infinite patience in helping me resolve the issues he identified for me.
• Jim Hester because covr rocks.
• Dirk Eddelbuettel and Carl Boettiger for the rocker project, and Gábor Csárdi and the R-consortium for Rhub, without which testing bugs on R-devel and other platforms would be a nightmare.
• Winston Chang for the r-debug docker container, in particular because of the valgrind level 2 instrumented version of R.
• Hadley Wickham and Peter Danenberg for roxygen2.
• Yihui Xie for knitr and J.J. Allaire etal for rmarkdown, and by extension John MacFarlane for pandoc.
• Michel Lang for pushing me to implement all_bw to compete with his own package checkmate.
• Eugene Ha for pointing me to several other relevant packages, which in turn led to the survey of related packages.
• Stefan M. Bache for the idea of having a function for testing objects directly (originally vetr only worked with function arguments), which I took from ensurer.
• Olaf Mersmann for microbenchmark, because microsecond matter, and Joshua Ulrich for making it lightweight.
• All open source developers out there that make their work freely available for others to use.
• Github, Codecov, Vagrant, Docker, Ubuntu, Brew for providing infrastructure that greatly simplifies open source development.
• Free Software Foundation for developing the GPL license and promotion of the free software movement.

Brodie Gaslam is a hobbyist programmer based on the US East Coast.