fmt_engineering | R Documentation |
With numeric values in a gt table, we can perform formatting so that the
targeted values are rendered in engineering notation, where numbers are
written in the form of a mantissa (m
) and an exponent (n
). When combined
the construction is either of the form m x 10^n or mEn. The mantissa
is a number between 1
and 1000
and the exponent is a multiple of 3
. For
example, the number 0.0000345 can be written in engineering notation as
34.50 x 10^-6
. This notation helps to simplify calculations and make it
easier to compare numbers that are on very different scales.
We have fine control over the formatting task, with the following options:
decimals: choice of the number of decimal places, option to drop trailing zeros, and a choice of the decimal symbol
scaling: we can choose to scale targeted values by a multiplier value
pattern: option to use a text pattern for decoration of the formatted values
locale-based formatting: providing a locale ID will result in formatting specific to the chosen locale
fmt_engineering(
data,
columns = everything(),
rows = everything(),
decimals = 2,
drop_trailing_zeros = FALSE,
drop_trailing_dec_mark = TRUE,
scale_by = 1,
exp_style = "x10n",
pattern = "{x}",
sep_mark = ",",
dec_mark = ".",
force_sign_m = FALSE,
force_sign_n = FALSE,
locale = NULL
)
data |
The gt table data object
This is the gt table object that is commonly created through use of the
|
columns |
Columns to target
Can either be a series of column names provided in |
rows |
Rows to target
In conjunction with |
decimals |
Number of decimal places
This corresponds to the exact number of decimal places to use. A value
such as |
drop_trailing_zeros |
Drop any trailing zeros
A logical value that allows for removal of trailing zeros (those redundant zeros after the decimal mark). |
drop_trailing_dec_mark |
Drop the trailing decimal mark
A logical value that determines whether decimal marks should always appear
even if there are no decimal digits to display after formatting (e.g., |
scale_by |
Scale values by a fixed multiplier
All numeric values will be multiplied by the |
exp_style |
Style declaration for exponent formatting
Style of formatting to use for the scientific notation formatting. By
default this is |
pattern |
Specification of the formatting pattern
A formatting pattern that allows for decoration of the formatted value. The
formatted value is represented by the |
sep_mark |
Separator mark for digit grouping
The string to use as a separator between groups of digits. For example,
using |
dec_mark |
Decimal mark
The string to be used as the decimal mark. For example, using
|
force_sign_m , force_sign_n |
Forcing the display of a positive sign
Should the plus sign be shown for positive values of the mantissa (first
component, |
locale |
Locale identifier
An optional locale identifier that can be used for formatting values
according the locale's rules. Examples include |
An object of class gt_tbl
.
fmt_engineering()
is compatible with body cells that are of the
"numeric"
or "integer"
types. Any other types of body cells are ignored
during formatting. This is to say that cells of incompatible data types may
be targeted, but there will be no attempt to format them.
columns
and rows
Targeting of values is done through columns
and additionally by rows
(if
nothing is provided for rows
then entire columns are selected). The
columns
argument allows us to target a subset of cells contained in the
resolved columns. We say resolved because aside from declaring column names
in c()
(with bare column names or names in quotes) we can use
tidyselect-style expressions. This can be as basic as supplying a select
helper like starts_with()
, or, providing a more complex incantation like
where(~ is.numeric(.x) && max(.x, na.rm = TRUE) > 1E6)
which targets numeric columns that have a maximum value greater than
1,000,000 (excluding any NA
s from consideration).
By default all columns and rows are selected (with the everything()
defaults). Cell values that are incompatible with a given formatting function
will be skipped over, like character
values and numeric fmt_*()
functions. So it's safe to select all columns with a particular formatting
function (only those values that can be formatted will be formatted), but,
you may not want that. One strategy is to format the bulk of cell values with
one formatting function and then constrain the columns for later passes with
other types of formatting (the last formatting done to a cell is what you get
in the final output).
Once the columns are targeted, we may also target the rows
within those
columns. This can be done in a variety of ways. If a stub is present, then we
potentially have row identifiers. Those can be used much like column names in
the columns
-targeting scenario. We can use simpler tidyselect-style
expressions (the select helpers should work well here) and we can use quoted
row identifiers in c()
. It's also possible to use row indices (e.g.,
c(3, 5, 6)
) though these index values must correspond to the row numbers of
the input data (the indices won't necessarily match those of rearranged rows
if row groups are present). One more type of expression is possible, an
expression that takes column values (can involve any of the available columns
in the table) and returns a logical vector. This is nice if you want to base
formatting on values in the column or another column, or, you'd like to use a
more complex predicate expression.
from_column()
helper functionfrom_column()
can be used with certain arguments of fmt_engineering()
to
obtain varying parameter values from a specified column within the table.
This means that each row could be formatted a little bit differently. These
arguments provide support for from_column()
:
decimals
drop_trailing_zeros
drop_trailing_dec_mark
scale_by
exp_style
pattern
sep_mark
dec_mark
force_sign_m
force_sign_n
locale
Please note that for all of the aforementioned arguments, a from_column()
call needs to reference a column that has data of the correct type (this is
different for each argument). Additional columns for parameter values can be
generated with cols_add()
(if not already present). Columns that contain
parameter data can also be hidden from final display with cols_hide()
.
Finally, there is no limitation to how many arguments the from_column()
helper is applied so long as the arguments belong to this closed set.
locale
This formatting function can adapt outputs according to a provided locale
value. Examples include "en"
for English (United States) and "fr"
for
French (France). The use of a valid locale ID here means separator and
decimal marks will be correct for the given locale. Should any values be
provided in sep_mark
or dec_mark
, they will be overridden by the locale's
preferred values.
Note that a locale
value provided here will override any global locale
setting performed in gt()
's own locale
argument (it is settable there as
a value received by all other functions that have a locale
argument). As a
useful reference on which locales are supported, we can call info_locales()
to view an info table.
Let's define a data frame that contains two columns of values (one small
and one large
). After creating a simple gt table from small_large_tbl
we'll call fmt_engineering()
on both columns.
small_large_tbl <- dplyr::tibble( small = 10^(-12:-1), large = 10^(1:12) ) small_large_tbl |> gt() |> fmt_engineering()
Notice that within the form of m x 10^n, the n values move in steps of
3 (away from 0
), and m values can have 1-3 digits before the decimal.
Further to this, any values where n is 0
results in a display of only m
(the first two values in the large
column demonstrates this).
Engineering notation expresses values so that they are align to certain SI prefixes. Here is a table that compares select SI prefixes and their symbols to decimal and engineering-notation representations of the key numbers.
prefixes_tbl <- dplyr::tibble( name = c( "peta", "tera", "giga", "mega", "kilo", NA, "milli", "micro", "nano", "pico", "femto" ), symbol = c( "P", "T", "G", "M", "k", NA, "m", ":micro:", "n", "p", "f" ), decimal = c(10^(seq(15, -15, -3))), engineering = decimal ) prefixes_tbl |> gt() |> fmt_number(columns = decimal, n_sigfig = 1) |> fmt_engineering(columns = engineering) |> fmt_units(columns = symbol) |> sub_missing()
The default method of styling the notation uses the 'm x 10^n'
construction but this can be changed to a 'mEn' style via the exp_style
argument. We can supply any single letter here and optionally affix a "1"
to indicate there should not be any zero-padding of the n value. Two calls
of fmt_engineering()
are used here to show different options for styling
in engineering notation.
small_large_tbl |> gt() |> fmt_engineering( columns = small, exp_style = "E" ) |> fmt_engineering( columns = large, exp_style = "e1", force_sign_n = TRUE )
3-4
v0.3.1
(August 9, 2021)
The vector-formatting version of this function:
vec_fmt_engineering()
.
Other data formatting functions:
data_color()
,
fmt()
,
fmt_auto()
,
fmt_bins()
,
fmt_bytes()
,
fmt_chem()
,
fmt_country()
,
fmt_currency()
,
fmt_date()
,
fmt_datetime()
,
fmt_duration()
,
fmt_email()
,
fmt_flag()
,
fmt_fraction()
,
fmt_icon()
,
fmt_image()
,
fmt_index()
,
fmt_integer()
,
fmt_markdown()
,
fmt_number()
,
fmt_partsper()
,
fmt_passthrough()
,
fmt_percent()
,
fmt_roman()
,
fmt_scientific()
,
fmt_spelled_num()
,
fmt_tf()
,
fmt_time()
,
fmt_units()
,
fmt_url()
,
sub_large_vals()
,
sub_missing()
,
sub_small_vals()
,
sub_values()
,
sub_zero()
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