Working with data provided by R packages is a great way to learn the tools of data science, but at some point you want to stop learning and start working with your own data.
In this chapter, you'll learn how to read plain-text rectangular files into R.
When you run `read_csv()` it prints out a message telling you the number of rows and columns of data, the delimiter that was used, and the column specifications (names of columns organized by the type of data the column contains).
In the `favourite.food` column, there are a bunch of food items and then the character string `N/A`, which should have been an real `NA` that R will recognize as "not available".
This is something we can address using the `na` argument.
An alternative approach is to use `janitor::clean_names()` to use some heuristics to turn them all into snake case at once[^data-import-1].
[^data-import-1]: The [janitor](http://sfirke.github.io/janitor/) package is not part of the tidyverse, but it offers handy functions for data cleaning and works well within data pipelines that uses `|>`.
Note that the values in the `meal_type` variable has stayed exactly the same, but the type of variable denoted underneath the variable name has changed from character (`<chr>`) to factor (`<fct>`).
Before you move on to analyzing these data, you'll probably want to fix the `age` column as well: currently it's a character variable because of the one observation that is typed out as `five` instead of a numeric `5`.
We discuss the details of fixing this issue in @sec-import-spreadsheets.
There are a couple of other important arguments that we need to mention, and they'll be easier to demonstrate if we first show you a handy trick: `read_csv()` can read csv files that you've created in a string:
2. Apart from `file`, `skip`, and `comment`, what other arguments do `read_csv()` and `read_tsv()` have in common?
3. What are the most important arguments to `read_fwf()`?
4. Sometimes strings in a CSV file contain commas.
To prevent them from causing problems they need to be surrounded by a quoting character, like `"` or `'`. By default, `read_csv()` assumes that the quoting character will be `"`.
What argument to `read_csv()` do you need to specify to read the following text into a data frame?
A CSV file doesn't contain any information about the type of each variable (i.e. whether it's a logical, number, string, etc.), so readr will try to guess the type.
This section describes how the guessing process works, how to resolve some common problems that cause it to fail, and if needed, how to supply the column types yourself.
Finally, we'll mention a couple of general strategies that are a useful if readr is failing catastrophically and you need to get more insight in to the structure of your file.
### Guessing types
readr uses a heuristic to figure out the column types.
For each column, it pulls the values of 1,000[^data-import-2] rows spaced evenly from the first row to the last, ignoring an missing values.
It then works through the following questions:
[^data-import-2]: You can override the default of 1000 with the `guess_max` argument.
- Does it contain only `F`, `T`, `FALSE`, or `TRUE` (ignoring case)? If so, it's a logical.
- Does it contain only numbers (e.g. `1`, `-4.5`, `5e6`, `Inf`)? If so, it's a number.
- Does it match match the ISO8601 standard? If so, it's a date or date-time. (We'll come back to date/times in more detail in @sec-creating-datetimes).
- Otherwise, it must be a string.
You can see that behavior in action in this simple example:
```{r}
read_csv("
logical,numeric,date,string
TRUE,1,2021-01-15,abc
false,4.5,2021-02-15,def
T,Inf,2021-02-16,ghi"
)
```
This heuristic works well if you have a clean dataset, but in real life you'll encounter a selection of weird and wonderful failures.
### Missing values, column types, and problems
The most common way column detection fails is that a column contains unexpected values and you get a character column instead of a more specific type.
One of the most common causes for this a missing value, recorded using something other than the `NA` that stringr expects.
Take this simple 1 column CSV file as an example:
```{r}
csv <- "
x
10
.
20
30"
```
If we read it without any additional arguments, `x` becomes a character column:
```{r}
df <- read_csv(csv)
```
In this very small case, you can easily see the missing value `.`.
But what happens if you have thousands of rows with only a few missing values represented by `.`s speckled amongst them?
One approach is to tell readr that `x` is a numeric column, and then see where it fails.
You can do that with the `col_types` argument, which takes a named list:
Now `read_csv()` reports that there was a problem, and tells us we can find out more with `problems()`:
```{r}
problems(df)
```
This tells us that there was a problem in row 3, col 1 where readr expected a double but got a `.`.
That suggests this dataset uses `.` for missing values.
So then we set `na = "."`, the automatic guessing succeeds, giving us the numeric column that we want:
```{r}
df <- read_csv(csv, na = ".")
```
### Column types
readr provides a total of nine column types for you to use:
- `col_logical()` and `col_double()` read logicals and real numbers. They're relatively rarely needed (except as above), since readr will usually guess them for you.
- `col_integer()` reads integers. We distinguish because integers and doubles in this book because they're functionally equivalent, but reading integers explicitly can occasionally be useful because they occupy half the memory of doubles.
- `col_character()` reads strings. This is sometimes useful to specify explicitly when you have a column that is a numeric identifier, i.e. long series of digits that identifies some object, but it doesn't make sense to (e.g.) divide it in half.
- `col_factor()`, `col_date()` and `col_datetime()` create factors, dates and date-time respectively; you'll learn more about those when we get to those data types in @sec-factors and @sec-dates-and-times.
- `col_number()` is a permissive numeric parser that will ignore non-numeric components, and is particularly useful for currencies. You'll learn more about it in @sec-numbers.
- `col_skip()` skips a column so it's not included in the result.
It's also possible to override the default column by switching from `list()` to `cols()`:
Sometimes your data is split across multiple files instead of being contained in a single file.
For example, you might have sales data for multiple months, with each month's data in a separate file: `01-sales.csv` for January, `02-sales.csv` for February, and `03-sales.csv` for March.
With `read_csv()` you can read these data in at once and stack them on top of each other in a single data frame.
With the additional `id` parameter we have added a new column called `file` to the resulting data frame that identifies the file the data come from.
This is especially helpful in circumstances where the files you're reading in do not have an identifying column that can help you trace the observations back to their original sources.
Both functions increase the chances of the output file being read back in correctly by using the standard UTF-8 encoding for strings and ISO8601 format for date-times.
Sometimes you'll need to assemble a tibble "by hand" doing a little data entry in your R script.
There are two useful functions to help you do this which differ in whether you layout the tibble by columns or by rows.
`tibble()` works by column:
```{r}
tibble(
x = c(1, 2, 5),
y = c("h", "m", "g"),
z = c(0.08, 0.83, 0.60)
)
```
Note that every column in tibble must be same size, so you'll get an error if they're not:
```{r}
#| error: true
tibble(
x = c(1, 2),
y = c("h", "m", "g"),
z = c(0.08, 0.83, 0.6)
)
```
Laying out the data by column can make it hard to see how the rows are related, so an alternative is `tribble()`, short for **tr**ansposed t**ibble**, which lets you lay out your data row by row.
`tribble()` is customized for data entry in code: column headings start with `~` and entries are separated by commas.
This makes it possible to lay out small amounts of data in an easy to read form:
```{r}
tribble(
~x, ~y, ~z,
"h", 1, 0.08,
"m", 2, 0.83,
"g", 5, 0.60,
)
```
We'll use `tibble()` and `tribble()` later in the book to construct small examples to demonstrate how various functions work.
We'll come to data import a few times in this book: @sec-import-databases will show you how to load data from databases, @sec-import-spreadsheets from Excel and googlesheets, @sec-rectangling from JSON, and @sec-scraping from websites.
Now that you're writing a substantial amount of R code, it's time to learn more about organizing your code into files and directories.
In the next chapter, you'll learn all about the advantages of scripts and projects, and some of the many tools that they provide to make your life easier.