{constructive} prints code that can be used to recreate R objects. In a
sense it is similar to base::dput()
or base::deparse()
but
{constructive} strives to use idiomatic constructors (factor
for
factors, as.Date()
for dates, data.frame()
for data frames etc), in
order to get output readable by humans.
Some use cases are:
dput()
or str()
)construct_diff()
)Install the last stable version from CRAN:
install.packages('constructive')
Or install the development version from cynkra R-universe:
install.packages('constructive', repos = c('https://cynkra.r-universe.dev', 'https://cloud.r-project.org'))
Or directly from github:
pak::pak("cynkra/constructive")
dput()
A few examples compared to their dput()
output.
library(constructive)
construct(head(iris, 2))
#> data.frame(
#> Sepal.Length = c(5.1, 4.9),
#> Sepal.Width = c(3.5, 3),
#> Petal.Length = c(1.4, 1.4),
#> Petal.Width = c(0.2, 0.2),
#> Species = factor(c("setosa", "setosa"), levels = c("setosa", "versicolor", "virginica"))
#> )
dput(head(iris, 2))
#> structure(list(Sepal.Length = c(5.1, 4.9), Sepal.Width = c(3.5,
#> 3), Petal.Length = c(1.4, 1.4), Petal.Width = c(0.2, 0.2), Species = structure(c(1L,
#> 1L), levels = c("setosa", "versicolor", "virginica"), class = "factor")), row.names = 1:2, class = "data.frame")
construct(.leap.seconds)
#> as.POSIXct(
#> c(
#> "1972-07-01", "1973-01-01", "1974-01-01", "1975-01-01", "1976-01-01",
#> "1977-01-01", "1978-01-01", "1979-01-01", "1980-01-01", "1981-07-01",
#> "1982-07-01", "1983-07-01", "1985-07-01", "1988-01-01", "1990-01-01",
#> "1991-01-01", "1992-07-01", "1993-07-01", "1994-07-01", "1996-01-01",
#> "1997-07-01", "1999-01-01", "2006-01-01", "2009-01-01", "2012-07-01",
#> "2015-07-01", "2017-01-01"
#> ),
#> tz = "GMT"
#> )
dput(.leap.seconds)
#> structure(c(78796800, 94694400, 126230400, 157766400, 189302400,
#> 220924800, 252460800, 283996800, 315532800, 362793600, 394329600,
#> 425865600, 489024000, 567993600, 631152000, 662688000, 709948800,
#> 741484800, 773020800, 820454400, 867715200, 915148800, 1136073600,
#> 1230768000, 1341100800, 1435708800, 1483228800), class = c("POSIXct",
#> "POSIXt"), tzone = "GMT")
library(dplyr, warn.conflicts = FALSE)
grouped_band_members <- group_by(band_members, band)
dput(grouped_band_members)
#> structure(list(name = c("Mick", "John", "Paul"), band = c("Stones",
#> "Beatles", "Beatles")), class = c("grouped_df", "tbl_df", "tbl",
#> "data.frame"), row.names = c(NA, -3L), groups = structure(list(
#> band = c("Beatles", "Stones"), .rows = structure(list(2:3,
#> 1L), ptype = integer(0), class = c("vctrs_list_of", "vctrs_vctr",
#> "list"))), class = c("tbl_df", "tbl", "data.frame"), row.names = c(NA,
#> -2L), .drop = TRUE))
construct(grouped_band_members)
#> tibble::tibble(name = c("Mick", "John", "Paul"), band = c("Stones", "Beatles", "Beatles")) |>
#> dplyr::group_by(band)
We can provide to the data
argument a named list, an environment, a
package where to look for data, or an unnamed list of such items, so we
don’t print more than necessary, for instance improving the previous
example:
construct(grouped_band_members, data = "dplyr")
#> band_members |>
#> dplyr::group_by(band)
Some objects can be constructed in several ways, for instance a tibble
might be constructed using tibble::tibble()
or using
tibble::tribble()
.
The opts_*()
family of functions provides ways to tweak the output
code, namely setting the constructor itself or options used by the
constructor
construct(band_members, opts_tbl_df("tribble"))
#> tibble::tribble(
#> ~name, ~band,
#> "Mick", "Stones",
#> "John", "Beatles",
#> "Paul", "Beatles",
#> )
construct(band_members, opts_tbl_df("tribble", justify = "right"))
#> tibble::tribble(
#> ~name, ~band,
#> "Mick", "Stones",
#> "John", "Beatles",
#> "Paul", "Beatles",
#> )
r <- as.raw(c(0x68, 0x65, 0x6c, 0x6c, 0x6f))
construct(r)
#> as.raw(c(0x68, 0x65, 0x6c, 0x6c, 0x6f))
construct(r, opts_raw(representation = "decimal"))
#> as.raw(c(104, 101, 108, 108, 111))
construct(r, opts_raw("charToRaw"))
#> charToRaw("hello")
These functions have their own documentation page and are referenced in
?construct
.
For every class that doesn’t refer to an internal type a “next” constructor is available, so we can conveniently explore objects using lower level constructors.
construct(band_members, opts_tbl_df("next"))
#> data.frame(name = c("Mick", "John", "Paul"), band = c("Stones", "Beatles", "Beatles")) |>
#> structure(class = c("tbl_df", "tbl", "data.frame"))
construct(band_members, opts_tbl_df("next"), opts_data.frame("next"))
#> list(name = c("Mick", "John", "Paul"), band = c("Stones", "Beatles", "Beatles")) |>
#> structure(class = c("tbl_df", "tbl", "data.frame"), row.names = c(NA, -3L))
construct_multi()
constructs several objects from a named list or an
environmentconstruct_reprex()
wraps construct_multi()
and constructs all the
objects of the local environment, or from the caller environments.construct_dput()
constructs the objects using only low level
constructors, like structure()
, list()
, c()
, very similarly to
base::dput()
construct_base()
constructs the objects using only base R functions.construct_clip()
writes to the clipboard, see also
?constructive-global_options
construct_diff()
highlights the differences in the code used to
produce 2 objects, it’s an alternative to waldo::compare()
.construct_dump()
is similar to base::dump()
, it’s a wrapper around
construct_multi()
that writes to a file.construct_signature()
constructs a function signature such as the
one we see in the “usage” section of a function’s help file. outputs
the code produced construct_issues()
is used without arguments to check what were the
issues encountered with the last reconstructed object, it can also be
provided a specific constructive object.deparse_call()
is an alternative to base::deparse()
and
rlang::expr_deparse()
that handles additional corner cases and fails
when encountering tokens other than symbols and syntactic literals .Environments use reference semantics, they cannot be copied. An attempt
to copy an environment would indeed yield a different environment and
identical(env, copy)
would be FALSE
(read more about it in
?opts_environment
).
In some case we can build code that points to a specific environment, for instance:
construct(globalenv())
#> .GlobalEnv
construct(environment(setNames))
#> asNamespace("stats")
When it’s not possible we use constructive::.env()
function for this
purpose.
e1 <- new.env(parent = .GlobalEnv)
e1$x <- 1
construct(e1)
#> constructive::.env("0x131515348", parents = "global")
constructive::.env()
fetches the environment from its memory address.
The parents
argument doesn’t do anything, it provides as additional
information the sequence of parents until we reach a special
environment.
This strategy is convenient because it always works, but it’s not reproducible between sessions as the memory address is not stable. Moreover it doesn’t tell us anything about the environment’s content.
Depending on what compromise you’re ready to make, you might use
different constructions in opts_environment()
. For the case above,
choosing "list2env"
works well :
construct(e1, opts_environment("list2env"))
#> list2env(list(x = 1), parent = .GlobalEnv)
constructive::.xptr()
is the counterpart of constructive::.env()
to
construct "externalptr"
objects from a memory address.
You can define your own constructors and methods!
For more information see
vignette("User-defined-methods-and-constructors", package = "constructive")