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Tplyr Options

One thing that we wanted to build into Tplyr to make it a user friendly package is the ability to eliminate redundant code where possible. This is why there are several options available in Tplyr to allow you to control things at your session level instead of each individual table, or even each individual layer.

The following are the options available in Tplyr and their descriptions:

Option Description
tplyr.count_layer_default_formats The default format strings for a count layer. Defaults to an auto-calculated n width, and (xxx.x%) for distinct counts (if available - non-distinct counts are used otherwise). Risk difference formats default to dif (low CI, high CI), all with 2 integer spaces and 3 decimal places.
tplyr.shift_layer_default_formats The default shift layer format. Defaults to an auto-calculated n width.
tplyr.desc_layer_default_formats The default descriptive statistics layer format. Defaults to “n”, “Mean (SD)”, “Median”, “Q1, Q3”, “Min, Max”, and “Missing”. Everything except “n” and “Missing” use auto-precision. Mean, Q1, Q3, and median defaults to +1 decimal places and Standard Deviation defaults to +2.
tplyr.precision_cap The default precision cap for auto-precision. Both integer and decimal places default to 99, essentially ensuring that precision is not capped by default.
tplyr.custom_summaries Default custom summaries available to Tplyr. Defaults to NULL, as Tplyr’s defaults are seen as built-ins and not custom summaries.
tplyr.scipen The default ‘scipen’ setting used while Tplyr is executing. Defaults to 1000. See the R documentation on the ‘scipen’ option to understand more, but this allows you to control how small a number must be before scientific notation is used when a number is string formatted in presentation.
tplyr.quantile_type The default quantile algorithm used by Tpylr when using the built-in summaries for Q1, Q3, and IQR. Defaults to Type 7, which is the R default

Each of these options allows you to set these settings in one place, and every Tplyr table you create will inherit your option settings as defaults. This allows your table code to be more concise, and centralizes where you need to make an update when your code has to be adjusted. This vignette is dedicated to helping you understand how to leverage each of these options properly.

Default Layer Formats

Declaring string formats and summaries that need to be performed is one of the more verbose parts of Tplyr. Furthermore, this is something that will often be fairly consistent within a study, as you’ll likely want to look across a consistent set of descriptive statistics, or your count/shift tables will likely require the same sort of “n (%)” formatting.

Using the format options is very similar to setting a string format. The only difference is that you need to enter the string formats as a named list instead of as separate parameters to a function call.

options(
    # Count layer defaults
  tplyr.count_layer_default_formats =
    list(n_counts = f_str("xxx (xx%)", n, pct),
         riskdiff = f_str('xx.xxx', dif)
         ),

  # Desc layer defaults
  tplyr.desc_layer_default_formats =
    list("n"        = f_str("xxx", n),
         "Mean (SD)"= f_str("a.a+1 (a.a+2)", mean, sd),
         "Median"   = f_str("a.a+4", median)
         ),

  # Shift layer defaults
  tplyr.shift_layer_default_formats = list(f_str("xxx", n))
)
 

Here you can see that Tplyr picks up these option changes. In the table below, we didn’t use set_format_strings() anywhere - instead we let Tplyr pick up the default formats from the options.

tplyr_table(tplyr_adsl, TRT01P) %>% 
  add_layer(
    group_desc(AGE, by = "Age (years)")
  ) %>% 
  add_layer(
    group_count(AGEGR1, by = "Categorical Age Groups")
  ) %>% 
  build() %>% 
  kable()
row_label1 row_label2 var1_Placebo var1_Xanomeline High Dose var1_Xanomeline Low Dose ord_layer_index ord_layer_1 ord_layer_2
Age (years) n 86 84 84 1 1 1
Age (years) Mean (SD) 76.3 ( 8.59) 75.9 ( 7.89) 77.4 ( 8.29) 1 1 2
Age (years) Median 76.0 76.0 77.5 1 1 3
Age (years) Q1, Q3 69.2, 81.8 70.8, 80.0 71.0, 82.0 1 1 4
Age (years) Min, Max 52, 89 56, 88 51, 88 1 1 5
Age (years) Missing 0 0 0 1 1 6
Categorical Age Groups 65-80 42 ( 48.8%) 55 ( 65.5%) 47 ( 56.0%) 2 1 1
Categorical Age Groups <65 14 ( 16.3%) 11 ( 13.1%) 8 ( 9.5%) 2 1 2
Categorical Age Groups >80 30 ( 34.9%) 18 ( 21.4%) 29 ( 34.5%) 2 1 3

One important thing to understand about how these options work in particular is the scoping.

To demonstrate, consider the following. The Tplyr options remain set from the block above.

tplyr_table(tplyr_adsl, TRT01P) %>% 
  set_count_layer_formats(n_counts = f_str("xx (xxx%)", n, pct)) %>% 
  set_desc_layer_formats("Mean (SD)" = f_str("a.a+1 (a.a+2)", mean, sd)) %>% 
  add_layer(
    group_desc(AGE, by = "Age (Years)")
  ) %>% 
  add_layer(
    group_count(AGEGR1, by = "Categorical Age Groups")
  ) %>% 
  add_layer(
    group_count(ETHNIC, by = "Ethnicity") %>% 
      set_format_strings(f_str("xxxxx (xx.xxx%)", n, pct))
  ) %>% 
  build() %>% 
  kable()
row_label1 row_label2 var1_Placebo var1_Xanomeline High Dose var1_Xanomeline Low Dose ord_layer_index ord_layer_1 ord_layer_2
Age (Years) Mean (SD) 76.3 ( 8.59) 75.9 ( 7.89) 77.4 ( 8.29) 1 1 1
Categorical Age Groups 65-80 42 ( 49%) 55 ( 65%) 47 ( 56%) 2 1 1
Categorical Age Groups <65 14 ( 16%) 11 ( 13%) 8 ( 10%) 2 1 2
Categorical Age Groups >80 30 ( 35%) 18 ( 21%) 29 ( 35%) 2 1 3
Ethnicity HISPANIC OR LATINO 3 ( 3.488%) 3 ( 3.571%) 6 ( 7.143%) 3 1 1
Ethnicity NOT HISPANIC OR LATINO 83 (96.512%) 81 (96.429%) 78 (92.857%) 3 1 2

In the above output:

Each of the outputs ignores the Tplyr option defaults.

Precision Cap

Tplyr defaults to avoiding capping precision. We do this because capping precision should be a conscious decision, where you as the user specifically set the limit of how many decimal places are relevant to a specific result. One way to cap precision is by using the cap parameter within set_format_strings(). But perhaps you have a specific limit to what you’d like to see on any output. Here, we offer the tplyr.precision_cap option to set whatever cap you wish.

options(tplyr.precision_cap = c('int'=2, 'dec'=2))

Similar to the layer defaults, setting a precision cap at the layer level will override the tplyr.precision_cap option.

tplyr_table(tplyr_adsl, TRT01P) %>% 
  add_layer(
    group_desc(HEIGHTBL, by = "Height at Baseline") %>% 
      set_format_strings(
        'Mean (SD)' = f_str('a.a (a.a+1)', mean, sd)
      )
  ) %>% 
  add_layer(
    group_desc(HEIGHTBL, by = "Height at Baseline (Limited)") %>% 
      set_format_strings(
        'Mean (SD)' = f_str('a.a (a.a+1)', mean, sd),
        cap = c('int'= 1, 'dec'=0)
      )
  ) %>% 
  build() %>% 
  kable()
row_label1 row_label2 var1_Placebo var1_Xanomeline High Dose var1_Xanomeline Low Dose ord_layer_index ord_layer_1 ord_layer_2
Height at Baseline Mean (SD) 162.4 (11.52) 166.4 (10.13) 162.1 (10.42) 1 1 1
Height at Baseline (Limited) Mean (SD) 162 (11.5) 166 (10.1) 162 (10.4) 2 1 1

Both layers in the above example are summarizing the same data. The top layer is using the tplyr.precision_cap option set above, which limits to 2 integer place and 2 decimal places. To bottom layer applies its own cap to override the option. Recall a few things about auto precision:

The bottom layer overrides the Tplyr option. Instead, integers are capped at 1 space, and decimals are capped at 0.

Custom Summaries

Custom summaries allow you to extend the capabilities of descriptive statistics layers in Tplyr. Maybe our defaults don’t work how you’d like them to, or maybe you have some custom functions within your organization that you commonly would like to use. Specifying the custom summaries you wish to use in every table would prove quite tedious - therefore, the tplyr.custom_summaries option is a better choice.

options(tplyr.custom_summaries = rlang::quos(
  geometric_mean = exp(sum(log(.var[.var > 0]),na.rm=TRUE) / length(.var))
))

Note that the table code used to produce the output is the same. Now Tplyr used the custom summary function for geometric_mean as specified in the tplyr.custom_summaries option. Also note the use of rlang::quos(). We’ve done our best to mask this from the user everywhere possible and make the interfaces clean and intuitive, but a great deal of Tplyr is built using ‘rlang’ and non-standard evaluation. Within this option is one of the very few instances where a user needs to concern themselves with the use of quosures. If you’d like to learn more about non-standard evaluation and quosures, we recommend Section IV in Advanced R.

Now that geometric mean is set within the Tplyr options, you can use it within your descriptive statistics layers, just like it was one of the built-in summaries.

tplyr_table(tplyr_adsl, TRT01P) %>% 
  add_layer(
    group_desc(AGE) %>% 
      set_format_strings('Geometric Mean' = f_str('xx.xx', geometric_mean))
  ) %>% 
  build() %>% 
  kable()
row_label1 var1_Placebo var1_Xanomeline High Dose var1_Xanomeline Low Dose ord_layer_index ord_layer_1
Geometric Mean 74.70 73.94 75.18 1 1

Scientific Notation

By default, R will switch to scientific notation for a number less than .001. This is controlled by the scipen option. The default value of scipen is 0. If you’d like to increase the decimal places required for scientific notation to be triggered, increase the value of scipen. The value of scipen is the number of orders of ten smaller (i.e. decimal places preceded by 0’s) required to switch to scientific notation. Decreasing the value of scipen will cause R to switch to scientific location for larger numbers.

This is easier to understand with an example.

options(scipen = 0) # This is the default
.0001
#> [1] 1e-04

options(scipen = 1) # Require 5 decimal places instead

.0001
#> [1] 0.0001
.00001
#> [1] 1e-05

options(scipen = -1) # Only require 3 decimal places
.001
#> [1] 1e-03

In Tplyr, we have the option tplyr.scipen. This is the scipen setting that will be used only while the Tplyr table is being built. This allows you to use a different scipen setting within Tplyr than your R session. The default value we use in Tplyr is 9999, which is intended to totally prevent numbers from switching to scientific notation. We want this to be a conscious decision that you make in order to prevent any unexpected outputs.

options(tplyr.scipen = -3)
t <- tplyr_table(tplyr_adae, TRTA) %>% 
  add_layer(
    group_count(AEDECOD) %>% 
      add_risk_diff(c('Xanomeline Low Dose', 'Placebo'))
  )

suppressWarnings(build(t)) %>% # Chi-squared warnings occur with small samples
  head() %>% 
  kable()
row_label1 var1_Placebo var1_Xanomeline High Dose var1_Xanomeline Low Dose ord_layer_index rdiff_Xanomeline Low Dose_Placebo ord_layer_1
ACTINIC KERATOSIS 0 ( 0.0%) 1 (9e-01%) 0 ( 0.0%) 1 0.000 ( 0.000, 0.000) 1
ALOPECIA 1 ( 2.1%) 0 ( 0.0%) 0 ( 0.0%) 1 -2.1e-02 (-7.7e-02, 3.5e-02) 2
BLISTER 0 ( 0.0%) 2 ( 1.8%) 8 ( 6.8%) 1 6.8e-02 ( 8e-03, 0.128) 3
COLD SWEAT 3 ( 6.4%) 0 ( 0.0%) 0 ( 0.0%) 1 -6.4e-02 (-0.149, 2.1e-02) 4
DERMATITIS ATOPIC 1 ( 2.1%) 0 ( 0.0%) 0 ( 0.0%) 1 -2.1e-02 (-7.7e-02, 3.5e-02) 5
DERMATITIS CONTACT 0 ( 0.0%) 0 ( 0.0%) 2 ( 1.7%) 1 1.7e-02 (-2.1e-02, 5.5e-02) 6

Note that the risk-difference variables above have mostly shifted to scientific notation. This is because the limit has been shifted to .1 within the Tplyr build.

Quantile Algorithms

There are many algorithms available to compute quantile R has 9, controlled by the type parameter in quantile(). The descriptive statistics offer built-in summaries for Q1, Q3, and Interquartile range, all three of which use the quantile() in the underlying implementation. Given that we offer this default, we felt it was important to offer you the flexibility to change the algorithm. You can do this with tplyr.quantile_type.

The default we chose to use is the R default of Type 7:

\[ m = 1-p. p[k] = (k - 1) / (n - 1). \textrm{In this case, } p[k] = mode[F(x[k])]. \textrm{This is used by S.} \] The example below demonstrates using the default quantile algorithm in R

tplyr_table(tplyr_adsl, TRT01P) %>% 
  add_layer(
    group_desc(CUMDOSE) %>% 
      set_format_strings("Q1, Q3" = f_str('xxxxx, xxxxx', q1, q3))
  ) %>% 
  build() %>%
  kable()
row_label1 var1_Placebo var1_Xanomeline High Dose var1_Xanomeline Low Dose ord_layer_index ord_layer_1
Q1, Q3 0, 0 2646, 13959 1984, 9801 1 1

Within the clinical world, you may wish to match the way that SAS calculates quantiles. To match SAS’s definition, use Type 3:

\[ \textrm{Nearest even order statistic. γ = 0 if g = 0 and j is even, and 1 otherwise.} \]

options(tplyr.quantile_type = 3)

tplyr_table(tplyr_adsl, TRT01P) %>% 
  add_layer(
    group_desc(CUMDOSE) %>% 
      set_format_strings("Q1, Q3" = f_str('xxxxx, xxxxx', q1, q3))
  ) %>% 
  build() %>% 
    select(-starts_with("ord")) %>% 
  kable()
row_label1 var1_Placebo var1_Xanomeline High Dose var1_Xanomeline Low Dose
Q1, Q3 0, 0 2565, 13959 1944, 9774

IBM Rounding

In certain cases users may want to match tables produced by other languages that IBM rounding.Tplyr offers the option ‘tplyr.IBMRounding’ to change the default rounding behavior of Tplyr tables. Review var1_4 in the tables below.

Using the default R behavior

tplyr_table(mtcars, gear) %>%
  add_layer(
    group_desc(qsec) %>%
      set_format_strings(mean = f_str("xx.xx", mean))
  ) %>%
  build()
#> # A tibble: 1 × 6
#>   row_label1 var1_3 var1_4 var1_5 ord_layer_index ord_layer_1
#>   <chr>      <chr>  <chr>  <chr>            <int>       <int>
#> 1 mean       17.47  18.75  15.50                1           1

Using IBM rounding

withr::with_options(
  list(tplyr.IBMRounding = TRUE),
  {
    tplyr_table(mtcars, gear) %>%
      add_layer(
        group_desc(qsec) %>%
          set_format_strings(mean = f_str("xx.xx", mean))
      ) %>%
      build()
  }
)
#> Warning: You have enabled IBM Rounding. This is an experimental feature.
#> •  If you have feedback please get in touch with the maintainers!
#> This warning is displayed once every 8 hours.
#> # A tibble: 1 × 6
#>   row_label1 var1_3 var1_4 var1_5 ord_layer_index ord_layer_1
#>   <chr>      <chr>  <chr>  <chr>            <int>       <int>
#> 1 mean       17.47  18.75  15.50                1           1

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