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{typed} implements a type system for R, it has 3 main features:
The user can define their own types, or leverage assertions from other packages.
Under the hood variable types use active bindings, so once a variable is restricted by an assertion, it cannot be modified in a way that would not satisfy it.
Install with:
::install_github("moodymudskipper/typed") remotes
And attach with :
# masking warning about overriding `?`
library(typed, warn.conflicts = FALSE)
declare
Here are examples on how we would set types
Character() ? x # restrict x to "character" type
<- "a"
x
x#> [1] "a"
Integer(3) ? y <- 1:3 # restrict y to "integer" type of length 3
y#> [1] 1 2 3
We cannot assign values of the wrong type to x
and
y
anymore.
<- 2
x #> Error: type mismatch
#> `typeof(value)`: "double"
#> `expected`: "character"
<- 4:5
y #> Error: length mismatch
#> `length(value)`: 2
#> `expected`: 3
1] <- 10
y[#> Error: type mismatch
#> `typeof(value)`: "character"
#> `expected`: "integer"
But the right type will work.
<- c("b", "c")
x
<- c(1L, 10L, 100L) y
declare
is a strict equivalent, slightly more efficient,
which looks like base::assign
.
declare("x", Character())
<- "a"
x
x#> [1] "a"
declare("y", Integer(3), 1:3)
y#> [1] 1 2 3
Integer
and Character
are function
factories (functions that return functions), thus
Integer(3)
and Character()
are functions.
The latter functions operate checks on a value and in case of success return this value, generally unmodified. For instance :
Integer(3)(1:2)
#> Error: length mismatch
#> `length(value)`: 2
#> `expected`: 3
Character()(3)
#> Error: type mismatch
#> `typeof(value)`: "double"
#> `expected`: "character"
We call Integer(3)
and Character()
assertions, and we call Integer
and Character
assertion factories.
The package contains many assertion factories (see
?assertion_factories
), the main ones are:
Any
(No default restriction)Logical
Integer
Double
Character
List
Environment
Factor
Matrix
Data.frame
Date
Time
(POSIXct)As we’ve seen with Integer(3)
, passing arguments to a
assertion factory restricts the type.
For instance Integer
has arguments length
null_ok
and ...
, we already used
length
, null_ok
is convenient to allow a
default NULL
value in addition to the
"integer"
type. In the dots we can use arguments named as
functions and with the value of the expected result.
Integer(anyNA = FALSE) ? x <- c(1L, 2L, NA)
#> Error: `anyNA` mismatch
#> `anyNA(value)`: TRUE
#> `expected`: FALSE
Useful arguments might be for instance,
anyDuplicated = 0L
, names = NULL
,
attributes = NULL
… Any available function can be used.
That makes assertion factories very flexible! If it is still not
flexible enough, one can provide conditions using formulas in the
...
. Be careful to skip all named arguments by adding
comas, or name the formula arguments ...
.
<- Character(1, ... = "`value` is not a fruit!" ~ . %in% c("apple", "pear", "cherry"))
fruit
<- "potatoe"
fruit ? x #> Error: `value` is not a fruit!
#> `value %in% c("apple", "pear", "cherry")`: FALSE
#> `expected`: TRUE
The arguments can differ between assertion factories, for instance
Data.frame
has nrow
, ncol
,
each
, null_ok
and ...
Data.frame() ? x <- iris
Data.frame(ncol = 2) ? x <- iris
#> Error: Column number mismatch
#> `ncol(value)`: 5
#> `expected`: 2
Data.frame(each = Double()) ? x <- iris
#> Error: column 5 ("Species") type mismatch
#> `typeof(value)`: "integer"
#> `expected`: "double"
Some great packages provide assertions, and they can be used with
typed
provided that they take the object as a first input
and return the object if no failure. Richie Cotton’s
{assertive} and Michel Lang’s {checkmate} both
qualify.
library(assertive)
assert_is_monotonic_increasing ? z<- 3:1
z #> Error: is_monotonic_increasing : The values of assigned_value are not monotonic increasing.
#> Position ValueBefore ValueAfter
#> 1 1/2 3 2
#> 2 2/3 2 1
If we want to use more than the first argument, we should create an assertion factory :
<- as_assertion_factory(assert_is_monotonic_increasing)
Monotonic_incr Monotonic_incr(strictly = TRUE) ? z
<- c(1, 1, 2)
z #> Error: is_monotonic_increasing : The values of value are not strictly monotonic increasing.
#> Position ValueBefore ValueAfter
#> 1 1/2 1 1
as_assertion_factory
can be used to create your own
assertion factories from scratch too, in fact it’s
used to build the native assertion factories of this package .
To define a constant, we just surround the variable by parentheses (think of them as a protection)
Double() ? (x) <- 1
<- 2
x #> Error: Can't assign to a constant
<- 1
? (y) <- 2
y #> Error: Can't assign to a constant
We can set argument types this way :
<- ? function (x= ? Double(), y= 1 ? Double()) {
add + y
x }
Note that we started the definition with a ?
, and that
we gave a default to y
, but not x
. Note also
the =
sign next to x
, necessary even when we
have no default value. If you forget it you’ll have an error “unexpected
?
in …”.
This created the following function, by adding checks at the top of the body
add#> # typed function
#> function (x, y = 1)
#> {
#> check_arg(x, Double())
#> check_arg(y, Double())
#> x + y
#> }
#> # Arg types:
#> # x: Double()
#> # y: Double()
Let’s test it by providing a right and wrong type.
add(2, 3)
#> [1] 5
add(2, 3L)
#> Error: In `add(2, 3L)` at `check_arg(y, Double())`:
#> wrong argument to function, type mismatch
#> `typeof(value)`: "integer"
#> `expected`: "double"
If we want to restrict x
and y
to the type
“integer” in the rest of the body of the function we can use the
?+
notation :
<- ? function (x= ?+ Double(), y= 1 ?+ Double()) {
add + y
x
}
add#> # typed function
#> function (x, y = 1)
#> {
#> check_arg(x, Double(), .bind = TRUE)
#> check_arg(y, Double(), .bind = TRUE)
#> x + y
#> }
#> # Arg types:
#> # x: Double()
#> # y: Double()
We see that it is translated into a check_arg
call
containing a .bind = TRUE
argument.
I we want to restrict the quoted expression rather than the value of
an argument, we can use ?~
:
<- ? function (x= ?~ Symbol()) {
identity_sym_only
x
}
<- 1
a identity_sym_only(a)
#> [1] 1
identity_sym_only(a + a)
#> Error: In `identity_sym_only(a + a)` at `check_arg(substitute(x), Symbol())`:
#> wrong argument to function, type mismatch
#> `typeof(value)`: "language"
#> `expected`: "symbol"
identity_sym_only#> # typed function
#> function (x)
#> {
#> check_arg(substitute(x), Symbol())
#> x
#> }
#> <bytecode: 0x000000001cfe6008>
#> # Arg types:
#> # x: ~Symbol()
We see that it is translated into a check_arg
call
containing a call to substitute
as the first argument. The
~
is kept in the attributes of the function.
We can also check the ...
, for instance use
function(... = ? Integer())
to check that only integers are
passed to the dots, and use function(... = ?~ Symbol())
to
check that all quoted values passed to ...
are symbols.
The special assertion factory Dots
can also be used, in
that case the checks will apply to list(...)
rather than to
each element individually, for instance
function(... = ? Dots(2))
makes sure the dots were fed 2
values. In a similar fashion function(... = ?~ Dots(2))
can
be used to apply checks to the list of quoted argument passed to
...
.
To set a return type we use ?
before the function
definition as in the previous section, but we type an assertion on the
left hand side.
<- Double() ? function (x, y, subtract = FALSE) {
add_or_subtract if(subtract) return(x - y)
+ y
x
}
add_or_subtract#> # typed function
#> function (x, y, subtract = FALSE)
#> {
#> if (subtract)
#> return(check_output(x - y, Double()))
#> check_output(x + y, Double())
#> }
#> # Return type: Double()
We see that the returned values have been wrapped inside
check_output
calls.
Let’s define our function for our package and document it with
{roxygen2}. It is documented as usual,except that you’ll need
to make sure to add the @name
tag.
We declare types for the return value, for all arguments, and we
declare a string msg
.
#' add_or_subtract
#'
#' @param x double of length 1
#' @param y double of length 1
#' @param subtract whether to subtract instead of adding
#' @export
#' @name add_or_subtract
<-
add_or_subtract Double(1) ? function (
x= ? Double(1),
y= ? Double(1),
subtract = FALSE ? Logical(1, anyNA = FALSE)
) {Character(1) ? msg
if(subtract) {
<- "subtracting"
msg message(msg)
return(x - y)
}<- "adding"
msg message(msg)
+ y
x }
The created function will be the following, we see that
Character(1) ? msg
was changed into a declare
call too, this is both for efficiency and readability. Unfamiliar users
might be intimidated by ?
and calls to ?
don’t
print nicely.
add_or_subtract#> # typed function
#> function (x, y, subtract = FALSE)
#> {
#> check_arg(x, Double(1))
#> check_arg(y, Double(1))
#> check_arg(subtract, Logical(1, anyNA = FALSE))
#> declare("msg", Character(1))
#> if (subtract) {
#> msg <- "subtracting"
#> message(msg)
#> return(check_output(x - y, Double(1)))
#> }
#> msg <- "adding"
#> message(msg)
#> check_output(x + y, Double(1))
#> }
#> # Return type: Double(1)
#> # Arg types:
#> # x: Double(1)
#> # y: Double(1)
#> # subtract: Logical(1, anyNA = FALSE)
Note that your package would import {typed} but
?
won’t be exposed to the user, they will see it in the
code but will be able to use ?
just as before. In fact the
most common standard use ?mean
still works even when
{typed} is attached.
This is inspired in good part by Jim Hester and Gabor Csardi’s work and many great efforts on static typing, assertions, or annotations in R, in particular:
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.