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The glue package contains functions for string interpolation: gluing together character strings and R code.
glue()
can be used to glue together pieces of text:
But glue’s real power comes with {}
: anything inside of
{}
is evaluated and pasted into the string. This makes it
easy to interpolate variables:
name <- "glue"
glue("We are learning how to use the {name} R package.")
#> We are learning how to use the glue R package.
As well as more complex expressions:
glue()
honors the line breaks in its input:
glue("
A formatted string
Can have multiple lines
with additional indention preserved
"
)
#> A formatted string
#> Can have multiple lines
#> with additional indention preserved
The example above demonstrates some other important facts about the pre-processing of the template string:
The elimination of common leading whitespace is advantageous, because
you aren’t forced to choose between indenting your code normally and
getting the output you actually want. This is easier to appreciate when
you have glue()
inside a function body (this example also
shows an alternative way of styling the end of a glue()
call):
foo <- function() {
glue("
A formatted string
Can have multiple lines
with additional indention preserved")
}
foo()
#> A formatted string
#> Can have multiple lines
#> with additional indention preserved
On the other hand, what if you don’t want a line break in the output,
but you also like to limit the length of lines in your source code to,
e.g., 80 characters? The first option is to use \\
to break
the template string into multiple lines, without getting line breaks in
the output:
release_date <- as.Date("2017-06-13")
glue("
The first version of the glue package was released on \\
a {format(release_date, '%A')}.")
#> The first version of the glue package was released on a Tuesday.
This comes up fairly often when an expression to evaluate inside
{}
takes up more characters than its result,
i.e. format(release_date, '%A')
versus
Tuesday
. A second way to achieve the same result is to
break the template into individual pieces, which are then
concatenated.
glue(
"The first version of the glue package was released on ",
"a {format(release_date, '%A')}."
)
#> The first version of the glue package was released on a Tuesday.
If you want an explicit newline at the start or end, include an extra empty line.
# no leading or trailing newline
x <- glue("
blah
")
unclass(x)
#> [1] "blah"
# both a leading and trailing newline
y <- glue("
blah
")
unclass(y)
#> [1] "\nblah\n"
We use unclass()
above to make it easier to see the
absence and presence of the newlines, i.e. to reveal the literal
\n
escape sequences. glue()
and friends
generally return a glue object, which is a character vector with the S3
class "glue"
. The "glue"
class exists
primarily for the sake of a print method, which displays the natural
formatted result of a glue string. Most of the time this is
exactly what the user wants to see. The example above happens
to be an exception, where we really do want to see the underlying string
representation.
Here’s another example to drive home the difference between printing
a glue object and looking at its string representation.
as.character()
is a another way to do this that is arguably
more expressive.
By default, code to be evaluated goes inside {}
in a
glue string. If want a literal curly brace in your string, double
it:
glue("The name of the package is {name}, not {{name}}.")
#> The name of the package is glue, not {name}.
Sometimes it’s just more convenient to use different delimiters altogether, especially if the template text comes from elsewhere or is subject to external requirements. Consider this example where we want to interpolate the function name into a code snippet that defines a function:
fn_def <- "
<<NAME>> <- function(x) {
# imagine a function body here
}"
glue(fn_def, NAME = "my_function", .open = "<<", .close = ">>")
#> my_function <- function(x) {
#> # imagine a function body here
#> }
In this glue string, {
and }
have very
special meaning. If we forced ourselves to double them, suddenly it
doesn’t look like normal R code anymore. Using alternative delimiters is
a nice option in cases like this.
By default, glue()
evaluates the code inside
{}
in the caller environment:
So, for a top-level glue()
call, that means the global
environment.
x <- "the caller environment"
glue("By default, `glue()` evaluates code in {x}.")
#> By default, `glue()` evaluates code in the caller environment.
But you can provide more narrowly scoped values by passing them to
glue()
in name = value
form:
x <- "the local environment"
glue(
"`glue()` can access values from {x} or from {y}. {z}",
y = "named arguments",
z = "Woo!"
)
#> `glue()` can access values from the local environment or from named arguments. Woo!
If the relevant data lives in a data frame (or list or environment),
use glue_data()
instead:
mini_mtcars <- head(cbind(model = rownames(mtcars), mtcars))
rownames(mini_mtcars) <- NULL
glue_data(mini_mtcars, "{model} has {hp} hp.")
#> Mazda RX4 has 110 hp.
#> Mazda RX4 Wag has 110 hp.
#> Datsun 710 has 93 hp.
#> Hornet 4 Drive has 110 hp.
#> Hornet Sportabout has 175 hp.
#> Valiant has 105 hp.
glue_data()
is very natural to use with the pipe:
mini_mtcars |>
glue_data("{model} gets {mpg} miles per gallon.")
#> Mazda RX4 gets 21 miles per gallon.
#> Mazda RX4 Wag gets 21 miles per gallon.
#> Datsun 710 gets 22.8 miles per gallon.
#> Hornet 4 Drive gets 21.4 miles per gallon.
#> Hornet Sportabout gets 18.7 miles per gallon.
#> Valiant gets 18.1 miles per gallon.
Returning to glue()
, recall that it defaults to
evaluation in the caller environment. This has happy implications inside
a dplyr::mutate()
pipeline. The data-masking feature of
mutate()
means the columns of the target data frame are “in
scope” for a glue()
call:
library(dplyr)
mini_mtcars |>
mutate(note = glue("{model} gets {mpg} miles per gallon.")) |>
select(note, cyl, disp)
#> note cyl disp
#> 1 Mazda RX4 gets 21 miles per gallon. 6 160
#> 2 Mazda RX4 Wag gets 21 miles per gallon. 6 160
#> 3 Datsun 710 gets 22.8 miles per gallon. 4 108
#> 4 Hornet 4 Drive gets 21.4 miles per gallon. 6 258
#> 5 Hornet Sportabout gets 18.7 miles per gallon. 8 360
#> 6 Valiant gets 18.1 miles per gallon. 6 225
glue has explicit support for constructing SQL statements. Use backticks to quote identifiers. Normal strings and numbers are quoted appropriately for your backend.
con <- DBI::dbConnect(RSQLite::SQLite(), ":memory:")
colnames(iris) <- gsub("[.]", "_", tolower(colnames(iris)))
DBI::dbWriteTable(con, "iris", iris)
var <- "sepal_width"
tbl <- "iris"
num <- 2
val <- "setosa"
glue_sql("
SELECT {`var`}
FROM {`tbl`}
WHERE {`tbl`}.sepal_length > {num}
AND {`tbl`}.species = {val}
", .con = con)
#> <SQL> SELECT `sepal_width`
#> FROM `iris`
#> WHERE `iris`.sepal_length > 2
#> AND `iris`.species = 'setosa'
glue_sql()
can be used in conjunction with parameterized
queries using DBI::dbBind()
to provide protection for SQL
Injection attacks.
sql <- glue_sql("
SELECT {`var`}
FROM {`tbl`}
WHERE {`tbl`}.sepal_length > ?
", .con = con)
query <- DBI::dbSendQuery(con, sql)
DBI::dbBind(query, list(num))
DBI::dbFetch(query, n = 4)
#> sepal_width
#> 1 3.5
#> 2 3.0
#> 3 3.2
#> 4 3.1
DBI::dbClearResult(query)
glue_sql()
can be used to build up more complex queries
with interchangeable sub queries. It returns DBI::SQL()
objects which are properly protected from quoting.
sub_query <- glue_sql("
SELECT *
FROM {`tbl`}
", .con = con)
glue_sql("
SELECT s.{`var`}
FROM ({sub_query}) AS s
", .con = con)
#> <SQL> SELECT s.`sepal_width`
#> FROM (SELECT *
#> FROM `iris`) AS s
If you want to input multiple values for use in SQL IN statements put
*
at the end of the value and the values will be collapsed
and quoted appropriately.
glue_sql("SELECT * FROM {`tbl`} WHERE sepal_length IN ({vals*})",
vals = 1, .con = con)
#> <SQL> SELECT * FROM `iris` WHERE sepal_length IN (1)
glue_sql("SELECT * FROM {`tbl`} WHERE sepal_length IN ({vals*})",
vals = 1:5, .con = con)
#> <SQL> SELECT * FROM `iris` WHERE sepal_length IN (1, 2, 3, 4, 5)
glue_sql("SELECT * FROM {`tbl`} WHERE species IN ({vals*})",
vals = "setosa", .con = con)
#> <SQL> SELECT * FROM `iris` WHERE species IN ('setosa')
glue_sql("SELECT * FROM {`tbl`} WHERE species IN ({vals*})",
vals = c("setosa", "versicolor"), .con = con)
#> <SQL> SELECT * FROM `iris` WHERE species IN ('setosa', 'versicolor')
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.
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