584 lines
20 KiB
Plaintext
584 lines
20 KiB
Plaintext
# Logical vectors {#sec-logicals}
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```{r}
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#| results: "asis"
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#| echo: false
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source("_common.R")
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status("polishing")
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```
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## Introduction
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In this chapter, you'll learn tools for working with logical vectors.
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Logical vectors are the simplest type of vector because each element can only be one of three possible values: `TRUE`, `FALSE`, and `NA`.
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It's relatively rare to find logical vectors in your raw data, but you'll create and manipulate in the course of almost every analysis.
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We'll begin by discussing the most common way of creating logical vectors: with numeric comparisons.
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Then you'll learn about how you can use Boolean algebra to combine different logical vectors, as well as some useful summaries.
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We'll finish off with `if_else()` and `case_when()`, two useful functions for making conditional changes powered by logical vectors.
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### Prerequisites
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Most of the functions you'll learn about in this chapter are provided by base R, so we don't need the tidyverse, but we'll still load it so we can use `mutate()`, `filter()`, and friends to work with data frames.
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We'll also continue to draw examples from the nycflights13 dataset.
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```{r}
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#| label: setup
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#| message: false
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library(tidyverse)
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library(nycflights13)
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```
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However, as we start to cover more tools, there won't always be a perfect real example.
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So we'll start making up some dummy data with `c()`:
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```{r}
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x <- c(1, 2, 3, 5, 7, 11, 13)
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x * 2
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```
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This makes it easier to explain individual functions at the cost of making it harder to see how it might apply to your data problems.
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Just remember that any manipulation we do to a free-floating vector, you can do to a variable inside data frame with `mutate()` and friends.
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```{r}
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df <- tibble(x)
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df |>
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mutate(y = x * 2)
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```
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## Comparisons
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A very common way to create a logical vector is via a numeric comparison with `<`, `<=`, `>`, `>=`, `!=`, and `==`.
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So far, we've mostly created logical variables transiently within `filter()` --- they are computed, used, and then thrown away.
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For example, the following filter finds all daytime departures that leave roughly on time:
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```{r}
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flights |>
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filter(dep_time > 600 & dep_time < 2000 & abs(arr_delay) < 20)
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```
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It's useful to know that this is a shortcut and you can explicitly create the underlying logical variables with `mutate()`:
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```{r}
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flights |>
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mutate(
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daytime = dep_time > 600 & dep_time < 2000,
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approx_ontime = abs(arr_delay) < 20,
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.keep = "used"
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)
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```
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This is particularly useful for more complicated logic because naming the intermediate steps makes it easier to both read your code and check that each step has been computed correctly.
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All up, the initial filter is equivalent to:
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```{r}
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#| results: false
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flights |>
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mutate(
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daytime = dep_time > 600 & dep_time < 2000,
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approx_ontime = abs(arr_delay) < 20,
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) |>
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filter(daytime & approx_ontime)
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```
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### Floating point comparison {#sec-fp-comparison}
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Beware of using `==` with numbers.
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For example, it looks like this vector contains the numbers 1 and 2:
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```{r}
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x <- c(1 / 49 * 49, sqrt(2) ^ 2)
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x
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```
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But if you test them for equality, you get `FALSE`:
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```{r}
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x == c(1, 2)
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```
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What's going on?
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Computers store numbers with a fixed number of decimal places so there's no way to exactly represent 1/49 or `sqrt(2)` and subsequent computations will be very slightly off.
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We can see the exact values by calling `print()` with the the `digits`[^logicals-1] argument:
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[^logicals-1]: R normally calls print for you (i.e. `x` is a shortcut for `print(x)`), but calling it explicitly is useful if you want to provide other arguments.
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```{r}
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print(x, digits = 16)
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```
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You can see why R defaults to rounding these numbers; they really are very close to what you expect.
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Now that you've seen why `==` is failing, what can you do about it?
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One option is to use `dplyr::near()` which ignores small differences:
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```{r}
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near(x, c(1, 2))
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```
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### Missing values {#sec-na-comparison}
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Missing values represent the unknown so they are "contagious": almost any operation involving an unknown value will also be unknown:
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```{r}
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NA > 5
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10 == NA
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```
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The most confusing result is this one:
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```{r}
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NA == NA
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```
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It's easiest to understand why this is true if we artificially supply a little more context:
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```{r}
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# Let x be Mary's age. We don't know how old she is.
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x <- NA
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# Let y be John's age. We don't know how old he is.
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y <- NA
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# Are John and Mary the same age?
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x == y
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# We don't know!
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```
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So if you want to find all flights with `dep_time` is missing, the following code doesn't work because `dep_time == NA` will yield a `NA` for every single row, and `filter()` automatically drops missing values:
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```{r}
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flights |>
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filter(dep_time == NA)
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```
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Instead we'll need a new tool: `is.na()`.
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### `is.na()`
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`is.na(x)` works with any type of vector and returns `TRUE` for missing values and `FALSE` for everything else:
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```{r}
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is.na(c(TRUE, NA, FALSE))
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is.na(c(1, NA, 3))
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is.na(c("a", NA, "b"))
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```
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We can use `is.na()` to find all the rows with a missing `dep_time`:
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```{r}
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flights |>
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filter(is.na(dep_time))
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```
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`is.na()` can also be useful in `arrange()`.
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`arrange()` usually puts all the missing values at the end but you can override this default by first sorting by `is.na()`:
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```{r}
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flights |>
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filter(month == 1, day == 1) |>
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arrange(dep_time)
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flights |>
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filter(month == 1, day == 1) |>
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arrange(desc(is.na(dep_time)), dep_time)
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```
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We'll come back to cover missing values in more depth in @sec-missing-values.
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### Exercises
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1. How does `dplyr::near()` work? Type `near` to see the source code.
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2. Use `mutate()`, `is.na()`, and `count()` together to describe how the missing values in `dep_time`, `sched_dep_time` and `dep_delay` are connected.
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## Boolean algebra
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Once you have multiple logical vectors, you can combine them together using Boolean algebra.
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In R, `&` is "and", `|` is "or", and `!` is "not", and `xor()` is exclusive or[^logicals-2].
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@fig-bool-ops shows the complete set of Boolean operations and how they work.
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[^logicals-2]: That is, `xor(x, y)` is true if x is true, or y is true, but not both.
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This is how we usually use "or" In English.
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"Both" is not usually an acceptable answer to the question "would you like ice cream or cake?".
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```{r}
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#| label: fig-bool-ops
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#| echo: false
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#| out-width: NULL
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#| fig-cap: >
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#| The complete set of boolean operations. `x` is the left-hand
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#| circle, `y` is the right-hand circle, and the shaded region show
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#| which parts each operator selects.
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#| fig-alt: >
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#| Six Venn diagrams, each explaining a given logical operator. The
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#| circles (sets) in each of the Venn diagrams represent x and y. 1. y &
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#| !x is y but none of x; x & y is the intersection of x and y; x & !y is
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#| x but none of y; x is all of x none of y; xor(x, y) is everything
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#| except the intersection of x and y; y is all of y and none of x; and
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#| x | y is everything.
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knitr::include_graphics("diagrams/transform.png", dpi = 270)
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```
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As well as `&` and `|`, R also has `&&` and `||`.
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Don't use them in dplyr functions!
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These are called short-circuiting operators and only ever return a single `TRUE` or `FALSE`.
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They're important for programming, not data science
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### Missing values {#sec-na-boolean}
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The rules for missing values in Boolean algebra are a little tricky to explain because they seem inconsistent at first glance:
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```{r}
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df <- tibble(x = c(TRUE, FALSE, NA))
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df |>
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mutate(
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and = x & NA,
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or = x | NA
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)
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```
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To understand what's going on, think about `NA | TRUE`.
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A missing value in a logical vector means that the value could either be `TRUE` or `FALSE`.
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`TRUE | TRUE` and `FALSE | TRUE` are both `TRUE`, so `NA | TRUE` must also be `TRUE`.
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Similar reasoning applies with `NA & FALSE`.
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### Order of operations
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Note that the order of operations doesn't work like English.
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Take the following code finds all flights that departed in November or December:
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```{r}
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#| eval: false
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flights |>
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filter(month == 11 | month == 12)
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```
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You might be tempted to write it like you'd say in English: "find all flights that departed in November or December":
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```{r}
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flights |>
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filter(month == 11 | 12)
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```
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This code doesn't error but it also doesn't seem to have worked.
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What's going on?
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Here R first evaluates `month == 11` creating a logical vector, which we call `nov`.
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It computes `nov | 12`.
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When you use a number with a logical operator it converts everything apart from 0 to TRUE, so this is equivalent to `nov | TRUE` which will always be `TRUE`, so every row will be selected:
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```{r}
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flights |>
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mutate(
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nov = month == 11,
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final = nov | 12,
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.keep = "used"
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)
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```
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### `%in%`
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An easy way to avoid the problem of getting your `==`s and `|`s in the right order is to use `%in%`.
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`x %in% y` returns a logical vector the same length as `x` that is `TRUE` whenever a value in `x` is anywhere in `y` .
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```{r}
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1:12 %in% c(1, 5, 11)
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letters[1:10] %in% c("a", "e", "i", "o", "u")
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```
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So to find all flights in November and December we could write:
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```{r}
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#| eval: false
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flights |>
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filter(month %in% c(11, 12))
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```
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Note that `%in%` obeys different rules for `NA` to `==`, as `NA %in% NA` is `TRUE`.
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```{r}
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c(1, 2, NA) == NA
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c(1, 2, NA) %in% NA
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```
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This can make for a useful shortcut:
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```{r}
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flights |>
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filter(dep_time %in% c(NA, 0800))
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```
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### Exercises
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1. Find all flights where `arr_delay` is missing but `dep_delay` is not. Find all flights where neither `arr_time` nor `sched_arr_time` are missing, but `arr_delay` is.
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2. How many flights have a missing `dep_time`? What other variables are missing in these rows? What might these rows represent?
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3. Assuming that a missing `dep_time` implies that a flight is cancelled, look at the number of cancelled flights per day. Is there a pattern? Is there a connection between the proportion of cancelled flights and average delay of non-cancelled flights?
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## Summaries {#sec-logical-summaries}
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The following sections describe some useful techniques for summarizing logical vectors.
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As well as functions that only work specifically with logical vectors, you can also use functions that work with numeric vectors.
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### Logical summaries
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There are two main logical summaries: `any()` and `all()`.
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`any(x)` is the equivalent of `|`; it'll return `TRUE` if there are any `TRUE`'s in `x`.
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`all(x)` is equivalent of `&`; it'll return `TRUE` only if all values of `x` are `TRUE`'s.
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Like all summary functions, they'll return `NA` if there are any missing values present, and as usual you can make the missing values go away with `na.rm = TRUE`.
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For example, we could use `all()` to find out if there were days where every flight was delayed:
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```{r}
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flights |>
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group_by(year, month, day) |>
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summarize(
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all_delayed = all(arr_delay >= 0, na.rm = TRUE),
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any_delayed = any(arr_delay >= 0, na.rm = TRUE),
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.groups = "drop"
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)
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```
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In most cases, however, `any()` and `all()` are a little too crude, and it would be nice to be able to get a little more detail about how many values are `TRUE` or `FALSE`.
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That leads us to the numeric summaries.
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### Numeric summaries of logical vectors {#sec-numeric-summaries-of-logicals}
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When you use a logical vector in a numeric context, `TRUE` becomes 1 and `FALSE` becomes 0.
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This makes `sum()` and `mean()` very useful with logical vectors because `sum(x)` will give the number of `TRUE`s and `mean(x)` the proportion of `TRUE`s.
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That lets us see the distribution of delays across the days of the year as shown in @fig-prop-delayed-dist.
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```{r}
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#| label: fig-prop-delayed-dist
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#| fig-cap: >
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#| A histogram showing the proportion of delayed flights each day.
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#| fig-alt: >
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#| The distribution is unimodal and mildly right skewed. The distribution
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#| peaks around 30% delayed flights.
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flights |>
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group_by(year, month, day) |>
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summarize(
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prop_delayed = mean(arr_delay > 0, na.rm = TRUE),
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.groups = "drop"
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) |>
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ggplot(aes(prop_delayed)) +
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geom_histogram(binwidth = 0.05)
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```
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Or we could ask how many flights left before 5am, which are often flights that were delayed from the previous day:
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```{r}
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flights |>
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group_by(year, month, day) |>
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summarize(
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n_early = sum(dep_time < 500, na.rm = TRUE),
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.groups = "drop"
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) |>
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arrange(desc(n_early))
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```
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### Logical subsetting
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There's one final use for logical vectors in summaries: you can use a logical vector to filter a single variable to a subset of interest.
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This makes use of the base `[` (pronounced subset) operator, which you'll learn more about in @sec-subset-many.
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Imagine we wanted to look at the average delay just for flights that were actually delayed.
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One way to do so would be to first filter the flights:
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```{r}
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flights |>
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filter(arr_delay > 0) |>
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group_by(year, month, day) |>
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summarize(
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behind = mean(arr_delay),
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n = n(),
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.groups = "drop"
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)
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```
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This works, but what if we wanted to also compute the average delay for flights that arrived early?
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We'd need to perform a separate filter step, and then figure out how to combine the two data frames together[^logicals-3].
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Instead you could use `[` to perform an inline filtering: `arr_delay[arr_delay > 0]` will yield only the positive arrival delays.
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[^logicals-3]: We'll cover this in @sec-joins\]
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This leads to:
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```{r}
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flights |>
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group_by(year, month, day) |>
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summarize(
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behind = mean(arr_delay[arr_delay > 0], na.rm = TRUE),
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ahead = mean(arr_delay[arr_delay < 0], na.rm = TRUE),
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n = n(),
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.groups = "drop"
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)
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```
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Also note the difference in the group size: in the first chunk `n()` gives the number of delayed flights per day; in the second, `n()` gives the total number of flights.
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### Exercises
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1. What will `sum(is.na(x))` tell you? How about `mean(is.na(x))`?
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2. What does `prod()` return when applied to a logical vector? What logical summary function is it equivalent to? What does `min()` return applied to a logical vector? What logical summary function is it equivalent to? Read the documentation and perform a few experiments.
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## Conditional transformations
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One of the most powerful features of logical vectors are their use for conditional transformations, i.e. doing one thing for condition x, and something different for condition y.
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There are two important tools for this: `if_else()` and `case_when()`.
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### `if_else()`
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If you want to use one value when a condition is true and another value when it's `FALSE`, you can use `dplyr::if_else()`[^logicals-4].
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You'll always use the first three argument of `if_else()`. The first argument, `condition`, is a logical vector, the second, `true`, gives the output when the condition is true, and the third, `false`, gives the output if the condition is false.
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[^logicals-4]: dplyr's `if_else()` is very similar to base R's `ifelse()`.
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There are two main advantages of `if_else()`over `ifelse()`: you can choose what should happen to missing values, and `if_else()` is much more likely to give you a meaningful error if you variables have incompatible types.
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Let's begin with a simple example of labeling a numeric vector as either "+ve" or "-ve":
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```{r}
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x <- c(-3:3, NA)
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if_else(x > 0, "+ve", "-ve")
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```
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There's an optional fourth argument, `missing` which will be used if the input is `NA`:
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```{r}
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if_else(x > 0, "+ve", "-ve", "???")
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```
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You can also use vectors for the the `true` and `false` arguments.
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For example, this allows us to create a minimal implementation of `abs()`:
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```{r}
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if_else(x < 0, -x, x)
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```
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So far all the arguments have used the same vectors, but you can of course mix and match.
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For example, you could implement a simple version of `coalesce()` like this:
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```{r}
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x1 <- c(NA, 1, 2, NA)
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y1 <- c(3, NA, 4, 6)
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if_else(is.na(x1), y1, x1)
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```
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You might have noticed a small infelicity in our labeling: zero is neither positive nor negative.
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We could resolve this by adding an additional `if_else()`:
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```{r}
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if_else(x == 0, "0", if_else(x < 0, "-ve", "+ve"), "???")
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```
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This is already a little hard to read, and you can imagine it would only get harder if you have more conditions.
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Instead, you can switch to `dplyr::case_when()`.
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### `case_when()`
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dplyr's `case_when()` is inspired by SQL's `CASE` statement and provides a flexible way of performing different computations for different computations.
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It has a special syntax that unfortunately looks like nothing else you'll use in the tidyverse.
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It takes pairs that look like `condition ~ output`.
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`condition` must be a logical vector; when it's `TRUE`, `output` will be used.
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This means we could recreate our previous nested `if_else()` as follows:
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|
|
|
```{r}
|
|
case_when(
|
|
x == 0 ~ "0",
|
|
x < 0 ~ "-ve",
|
|
x > 0 ~ "+ve",
|
|
is.na(x) ~ "???"
|
|
)
|
|
```
|
|
|
|
This is more code, but it's also more explicit.
|
|
|
|
To explain how `case_when()` works, lets explore some simpler cases.
|
|
If none of the cases match, the output gets an `NA`:
|
|
|
|
```{r}
|
|
case_when(
|
|
x < 0 ~ "-ve",
|
|
x > 0 ~ "+ve"
|
|
)
|
|
```
|
|
|
|
If you want to create a "default"/catch all value, use `TRUE` on the left hand side:
|
|
|
|
```{r}
|
|
case_when(
|
|
x < 0 ~ "-ve",
|
|
x > 0 ~ "+ve",
|
|
TRUE ~ "???"
|
|
)
|
|
```
|
|
|
|
And note that if multiple conditions match, only the first will be used:
|
|
|
|
```{r}
|
|
case_when(
|
|
x > 0 ~ "+ve",
|
|
x > 3 ~ "big"
|
|
)
|
|
```
|
|
|
|
Just like with `if_else()` you can use variables on both sides of the `~` and you can mix and match variables as needed for your problem.
|
|
For example, we could use `case_when()` to provide some human readable labels for the arrival delay:
|
|
|
|
```{r}
|
|
flights |>
|
|
mutate(
|
|
status = case_when(
|
|
is.na(arr_delay) ~ "cancelled",
|
|
arr_delay > 60 ~ "very late",
|
|
arr_delay > 15 ~ "late",
|
|
abs(arr_delay) <= 15 ~ "on time",
|
|
arr_delay < -15 ~ "early",
|
|
arr_delay < -30 ~ "very early",
|
|
),
|
|
.keep = "used"
|
|
)
|
|
```
|
|
|
|
### Compatible types
|
|
|
|
Note that both `if_else()` and `case_when()` require **compatible** types in the output.
|
|
If they're not compatible, you'll see errors like this:
|
|
|
|
```{r}
|
|
#| error: true
|
|
|
|
if_else(TRUE, "a", 1)
|
|
|
|
case_when(
|
|
x < -1 ~ TRUE,
|
|
x > 0 ~ lubridate::now()
|
|
)
|
|
```
|
|
|
|
Overall, relatively few types are compatible, because automatically converting one type of vector to another is a common source of errors.
|
|
Here are the most important cases that are compatible:
|
|
|
|
- Numeric and logical vectors are compatible, as we discussed in @sec-numeric-summaries-of-logicals.
|
|
- Strings and factors (@sec-factors) are compatible, because you can think of a factor as a string with a restricted set of values.
|
|
- Dates and date-times, which we'll discuss in @sec-dates-and-times, are compatible because you can think of a date as a special case of date-time.
|
|
- `NA`, which is technically a logical vector, is compatible with everything because every vector has some way of representing a missing value.
|
|
|
|
We don't expect you to memorize these rules, but they should become second nature over time because they are applied consistently throughout the tidyverse.
|
|
|
|
## Summary
|
|
|
|
The definition of a logical vector is simple because each value must be either `TRUE`, `FALSE`, or `NA`.
|
|
But logical vectors provide a huge amount of power.
|
|
In this chapter, you learned how to create logical vectors with `>`, `<`, `<=`, `=>`, `==`, `!=`, and `is.na()`, how to combine them with `!`, `&`, and `|`, and how to summarize them with `any()`, `all()`, `sum()`, and `mean()`.
|
|
You also learned the powerful `if_else()` and `case_when()` that allow you to return values depending on the value of a logical vector.
|
|
|
|
We'll see logical vectors again and in the following chapters.
|
|
For example in @sec-strings you'll learn about `str_detect(x, pattern)` which returns a logical vector that's `TRUE` for the elements of `x` that match the `pattern`, and in @sec-dates-and-times you'll create logical vectors from the comparison of dates and times.
|
|
But for now, we're going to move onto the next most important type of vector: numeric vectors.
|