Data Frame Manipulation with dplyr
Last updated on 2024-11-05 | Edit this page
Estimated time: 55 minutes
Overview
Questions
- How can I manipulate data frames without repeating myself?
Objectives
- To be able to use the six main data frame manipulation ‘verbs’ with
pipes in
dplyr
. - To understand how
group_by()
andsummarize()
can be combined to summarize datasets. - Be able to analyze a subset of data using logical filtering.
Manipulation of data frames means many things to many researchers: we often select certain observations (rows) or variables (columns), we often group the data by a certain variable(s), or we even calculate summary statistics. We can do these operations using the normal base R operations:
R
mean(gapminder$gdpPercap[gapminder$continent == "Africa"])
OUTPUT
[1] 2193.755
R
mean(gapminder$gdpPercap[gapminder$continent == "Americas"])
OUTPUT
[1] 7136.11
R
mean(gapminder$gdpPercap[gapminder$continent == "Asia"])
OUTPUT
[1] 7902.15
But this isn’t very nice because there is a fair bit of repetition. Repeating yourself will cost you time, both now and later, and potentially introduce some nasty bugs.
The dplyr
package
Luckily, the dplyr
package provides a number of very useful functions for manipulating data
frames in a way that will reduce the above repetition, reduce the
probability of making errors, and probably even save you some typing. As
an added bonus, you might even find the dplyr
grammar
easier to read.
Tip: Tidyverse
dplyr
package belongs to a broader family of opinionated
R packages designed for data science called the “Tidyverse”. These
packages are specifically designed to work harmoniously together. Some
of these packages will be covered along this course, but you can find
more complete information here: https://www.tidyverse.org/.
Here we’re going to cover 5 of the most commonly used functions as
well as using pipes (%>%
) to combine them.
select()
filter()
group_by()
summarize()
mutate()
If you have have not installed this package earlier, please do so:
R
install.packages('dplyr')
Now let’s load the package:
R
library("dplyr")
Using select()
If, for example, we wanted to move forward with only a few of the
variables in our data frame we could use the select()
function. This will keep only the variables you select.
R
year_country_gdp <- select(gapminder, year, country, gdpPercap)
If we want to remove one column only from the gapminder
data, for example, removing the continent
column.
R
smaller_gapminder_data <- select(gapminder, -continent)
If we open up year_country_gdp
we’ll see that it only
contains the year, country and gdpPercap. Above we used ‘normal’
grammar, but the strengths of dplyr
lie in combining
several functions using pipes. Since the pipes grammar is unlike
anything we’ve seen in R before, let’s repeat what we’ve done above
using pipes.
R
year_country_gdp <- gapminder %>% select(year, country, gdpPercap)
To help you understand why we wrote that in that way, let’s walk
through it step by step. First we summon the gapminder data frame and
pass it on, using the pipe symbol %>%
, to the next step,
which is the select()
function. In this case we don’t
specify which data object we use in the select()
function
since in gets that from the previous pipe. Fun Fact:
There is a good chance you have encountered pipes before in the shell.
In R, a pipe symbol is %>%
while in the shell it is
|
but the concept is the same!
Tip: Renaming data frame columns in dplyr
In Chapter 4 we covered how you can rename columns with base R by
assigning a value to the output of the names()
function.
Just like select, this is a bit cumbersome, but thankfully dplyr has a
rename()
function.
Within a pipeline, the syntax is
rename(new_name = old_name)
. For example, we may want to
rename the gdpPercap column name from our select()
statement above.
R
tidy_gdp <- year_country_gdp %>% rename(gdp_per_capita = gdpPercap)
head(tidy_gdp)
OUTPUT
year country gdp_per_capita
1 1952 Afghanistan 779.4453
2 1957 Afghanistan 820.8530
3 1962 Afghanistan 853.1007
4 1967 Afghanistan 836.1971
5 1972 Afghanistan 739.9811
6 1977 Afghanistan 786.1134
Using filter()
If we now want to move forward with the above, but only with European
countries, we can combine select
and
filter
R
year_country_gdp_euro <- gapminder %>%
filter(continent == "Europe") %>%
select(year, country, gdpPercap)
If we now want to show life expectancy of European countries but only for a specific year (e.g., 2007), we can do as below.
R
europe_lifeExp_2007 <- gapminder %>%
filter(continent == "Europe", year == 2007) %>%
select(country, lifeExp)
Challenge 1
Write a single command (which can span multiple lines and includes
pipes) that will produce a data frame that has the African values for
lifeExp
, country
and year
, but
not for other Continents. How many rows does your data frame have and
why?
R
year_country_lifeExp_Africa <- gapminder %>%
filter(continent == "Africa") %>%
select(year, country, lifeExp)
As with last time, first we pass the gapminder data frame to the
filter()
function, then we pass the filtered version of the
gapminder data frame to the select()
function.
Note: The order of operations is very important in this
case. If we used ‘select’ first, filter would not be able to find the
variable continent since we would have removed it in the previous
step.
Using group_by()
Now, we were supposed to be reducing the error prone repetitiveness
of what can be done with base R, but up to now we haven’t done that
since we would have to repeat the above for each continent. Instead of
filter()
, which will only pass observations that meet your
criteria (in the above: continent=="Europe"
), we can use
group_by()
, which will essentially use every unique
criteria that you could have used in filter.
R
str(gapminder)
OUTPUT
'data.frame': 1704 obs. of 6 variables:
$ country : chr "Afghanistan" "Afghanistan" "Afghanistan" "Afghanistan" ...
$ year : int 1952 1957 1962 1967 1972 1977 1982 1987 1992 1997 ...
$ pop : num 8425333 9240934 10267083 11537966 13079460 ...
$ continent: chr "Asia" "Asia" "Asia" "Asia" ...
$ lifeExp : num 28.8 30.3 32 34 36.1 ...
$ gdpPercap: num 779 821 853 836 740 ...
R
str(gapminder %>% group_by(continent))
OUTPUT
gropd_df [1,704 × 6] (S3: grouped_df/tbl_df/tbl/data.frame)
$ country : chr [1:1704] "Afghanistan" "Afghanistan" "Afghanistan" "Afghanistan" ...
$ year : int [1:1704] 1952 1957 1962 1967 1972 1977 1982 1987 1992 1997 ...
$ pop : num [1:1704] 8425333 9240934 10267083 11537966 13079460 ...
$ continent: chr [1:1704] "Asia" "Asia" "Asia" "Asia" ...
$ lifeExp : num [1:1704] 28.8 30.3 32 34 36.1 ...
$ gdpPercap: num [1:1704] 779 821 853 836 740 ...
- attr(*, "groups")= tibble [5 × 2] (S3: tbl_df/tbl/data.frame)
..$ continent: chr [1:5] "Africa" "Americas" "Asia" "Europe" ...
..$ .rows : list<int> [1:5]
.. ..$ : int [1:624] 25 26 27 28 29 30 31 32 33 34 ...
.. ..$ : int [1:300] 49 50 51 52 53 54 55 56 57 58 ...
.. ..$ : int [1:396] 1 2 3 4 5 6 7 8 9 10 ...
.. ..$ : int [1:360] 13 14 15 16 17 18 19 20 21 22 ...
.. ..$ : int [1:24] 61 62 63 64 65 66 67 68 69 70 ...
.. ..@ ptype: int(0)
..- attr(*, ".drop")= logi TRUE
You will notice that the structure of the data frame where we used
group_by()
(grouped_df
) is not the same as the
original gapminder
(data.frame
). A
grouped_df
can be thought of as a list
where
each item in the list
is a data.frame
which
contains only the rows that correspond to the a particular value
continent
(at least in the example above).
Using summarize()
The above was a bit on the uneventful side but
group_by()
is much more exciting in conjunction with
summarize()
. This will allow us to create new variable(s)
by using functions that repeat for each of the continent-specific data
frames. That is to say, using the group_by()
function, we
split our original data frame into multiple pieces, then we can run
functions (e.g. mean()
or sd()
) within
summarize()
.
R
gdp_bycontinents <- gapminder %>%
group_by(continent) %>%
summarize(mean_gdpPercap = mean(gdpPercap))
R
continent mean_gdpPercap
<fctr> <dbl>
1 Africa 2193.755
2 Americas 7136.110
3 Asia 7902.150
4 Europe 14469.476
5 Oceania 18621.609
That allowed us to calculate the mean gdpPercap for each continent, but it gets even better.
Challenge 2
Calculate the average life expectancy per country. Which has the longest average life expectancy and which has the shortest average life expectancy?
R
lifeExp_bycountry <- gapminder %>%
group_by(country) %>%
summarize(mean_lifeExp = mean(lifeExp))
lifeExp_bycountry %>%
filter(mean_lifeExp == min(mean_lifeExp) | mean_lifeExp == max(mean_lifeExp))
OUTPUT
# A tibble: 2 × 2
country mean_lifeExp
<chr> <dbl>
1 Iceland 76.5
2 Sierra Leone 36.8
Another way to do this is to use the dplyr
function
arrange()
, which arranges the rows in a data frame
according to the order of one or more variables from the data frame. It
has similar syntax to other functions from the dplyr
package. You can use desc()
inside arrange()
to sort in descending order.
R
lifeExp_bycountry %>%
arrange(mean_lifeExp) %>%
head(1)
OUTPUT
# A tibble: 1 × 2
country mean_lifeExp
<chr> <dbl>
1 Sierra Leone 36.8
R
lifeExp_bycountry %>%
arrange(desc(mean_lifeExp)) %>%
head(1)
OUTPUT
# A tibble: 1 × 2
country mean_lifeExp
<chr> <dbl>
1 Iceland 76.5
Alphabetical order works too
R
lifeExp_bycountry %>%
arrange(desc(country)) %>%
head(1)
OUTPUT
# A tibble: 1 × 2
country mean_lifeExp
<chr> <dbl>
1 Zimbabwe 52.7
The function group_by()
allows us to group by multiple
variables. Let’s group by year
and
continent
.
R
gdp_bycontinents_byyear <- gapminder %>%
group_by(continent, year) %>%
summarize(mean_gdpPercap = mean(gdpPercap))
OUTPUT
`summarise()` has grouped output by 'continent'. You can override using the
`.groups` argument.
That is already quite powerful, but it gets even better! You’re not
limited to defining 1 new variable in summarize()
.
R
gdp_pop_bycontinents_byyear <- gapminder %>%
group_by(continent, year) %>%
summarize(mean_gdpPercap = mean(gdpPercap),
sd_gdpPercap = sd(gdpPercap),
mean_pop = mean(pop),
sd_pop = sd(pop))
OUTPUT
`summarise()` has grouped output by 'continent'. You can override using the
`.groups` argument.
count() and n()
A very common operation is to count the number of observations for
each group. The dplyr
package comes with two related
functions that help with this.
For instance, if we wanted to check the number of countries included
in the dataset for the year 2002, we can use the count()
function. It takes the name of one or more columns that contain the
groups we are interested in, and we can optionally sort the results in
descending order by adding sort=TRUE
:
R
gapminder %>%
filter(year == 2002) %>%
count(continent, sort = TRUE)
OUTPUT
continent n
1 Africa 52
2 Asia 33
3 Europe 30
4 Americas 25
5 Oceania 2
If we need to use the number of observations in calculations, the
n()
function is useful. It will return the total number of
observations in the current group rather than counting the number of
observations in each group within a specific column. For instance, if we
wanted to get the standard error of the life expectency per
continent:
R
gapminder %>%
group_by(continent) %>%
summarize(se_le = sd(lifeExp)/sqrt(n()))
OUTPUT
# A tibble: 5 × 2
continent se_le
<chr> <dbl>
1 Africa 0.366
2 Americas 0.540
3 Asia 0.596
4 Europe 0.286
5 Oceania 0.775
You can also chain together several summary operations; in this case
calculating the minimum
, maximum
,
mean
and se
of each continent’s per-country
life-expectancy:
R
gapminder %>%
group_by(continent) %>%
summarize(
mean_le = mean(lifeExp),
min_le = min(lifeExp),
max_le = max(lifeExp),
se_le = sd(lifeExp)/sqrt(n()))
OUTPUT
# A tibble: 5 × 5
continent mean_le min_le max_le se_le
<chr> <dbl> <dbl> <dbl> <dbl>
1 Africa 48.9 23.6 76.4 0.366
2 Americas 64.7 37.6 80.7 0.540
3 Asia 60.1 28.8 82.6 0.596
4 Europe 71.9 43.6 81.8 0.286
5 Oceania 74.3 69.1 81.2 0.775
Using mutate()
We can also create new variables prior to (or even after) summarizing
information using mutate()
.
R
gdp_pop_bycontinents_byyear <- gapminder %>%
mutate(gdp_billion = gdpPercap*pop/10^9) %>%
group_by(continent,year) %>%
summarize(mean_gdpPercap = mean(gdpPercap),
sd_gdpPercap = sd(gdpPercap),
mean_pop = mean(pop),
sd_pop = sd(pop),
mean_gdp_billion = mean(gdp_billion),
sd_gdp_billion = sd(gdp_billion))
OUTPUT
`summarise()` has grouped output by 'continent'. You can override using the
`.groups` argument.
Connect mutate with logical filtering: ifelse
When creating new variables, we can hook this with a logical
condition. A simple combination of mutate()
and
ifelse()
facilitates filtering right where it is needed: in
the moment of creating something new. This easy-to-read statement is a
fast and powerful way of discarding certain data (even though the
overall dimension of the data frame will not change) or for updating
values depending on this given condition.
R
## keeping all data but "filtering" after a certain condition
# calculate GDP only for people with a life expectation above 25
gdp_pop_bycontinents_byyear_above25 <- gapminder %>%
mutate(gdp_billion = ifelse(lifeExp > 25, gdpPercap * pop / 10^9, NA)) %>%
group_by(continent, year) %>%
summarize(mean_gdpPercap = mean(gdpPercap),
sd_gdpPercap = sd(gdpPercap),
mean_pop = mean(pop),
sd_pop = sd(pop),
mean_gdp_billion = mean(gdp_billion),
sd_gdp_billion = sd(gdp_billion))
OUTPUT
`summarise()` has grouped output by 'continent'. You can override using the
`.groups` argument.
R
## updating only if certain condition is fullfilled
# for life expectations above 40 years, the gpd to be expected in the future is scaled
gdp_future_bycontinents_byyear_high_lifeExp <- gapminder %>%
mutate(gdp_futureExpectation = ifelse(lifeExp > 40, gdpPercap * 1.5, gdpPercap)) %>%
group_by(continent, year) %>%
summarize(mean_gdpPercap = mean(gdpPercap),
mean_gdpPercap_expected = mean(gdp_futureExpectation))
OUTPUT
`summarise()` has grouped output by 'continent'. You can override using the
`.groups` argument.
Combining dplyr
and ggplot2
First install and load ggplot2:
R
install.packages('ggplot2')
R
library("ggplot2")
In the plotting lesson we looked at how to make a multi-panel figure
by adding a layer of facet panels using ggplot2
. Here is
the code we used (with some extra comments):
R
# Filter countries located in the Americas
americas <- gapminder[gapminder$continent == "Americas", ]
# Make the plot
ggplot(data = americas, mapping = aes(x = year, y = lifeExp)) +
geom_line() +
facet_wrap( ~ country) +
theme(axis.text.x = element_text(angle = 45))
This code makes the right plot but it also creates an intermediate
variable (americas
) that we might not have any other uses
for. Just as we used %>%
to pipe data along a chain of
dplyr
functions we can use it to pass data to
ggplot()
. Because %>%
replaces the first
argument in a function we don’t need to specify the data =
argument in the ggplot()
function. By combining
dplyr
and ggplot2
functions we can make the
same figure without creating any new variables or modifying the
data.
R
gapminder %>%
# Filter countries located in the Americas
filter(continent == "Americas") %>%
# Make the plot
ggplot(mapping = aes(x = year, y = lifeExp)) +
geom_line() +
facet_wrap( ~ country) +
theme(axis.text.x = element_text(angle = 45))
More examples of using the function mutate()
and the
ggplot2
package.
R
gapminder %>%
# extract first letter of country name into new column
mutate(startsWith = substr(country, 1, 1)) %>%
# only keep countries starting with A or Z
filter(startsWith %in% c("A", "Z")) %>%
# plot lifeExp into facets
ggplot(aes(x = year, y = lifeExp, colour = continent)) +
geom_line() +
facet_wrap(vars(country)) +
theme_minimal()
Advanced Challenge
Calculate the average life expectancy in 2002 of 2 randomly selected
countries for each continent. Then arrange the continent names in
reverse order. Hint: Use the dplyr
functions arrange()
and sample_n()
, they have
similar syntax to other dplyr functions.
R
lifeExp_2countries_bycontinents <- gapminder %>%
filter(year==2002) %>%
group_by(continent) %>%
sample_n(2) %>%
summarize(mean_lifeExp=mean(lifeExp)) %>%
arrange(desc(mean_lifeExp))
Other great resources
- R for Data Science (online book)
- Data Wrangling Cheat sheet (pdf file)
- Introduction to dplyr (online documentation)
- Data wrangling with R and RStudio (online video)
Key Points
- Use the
dplyr
package to manipulate data frames. - Use
select()
to choose variables from a data frame. - Use
filter()
to choose data based on values. - Use
group_by()
andsummarize()
to work with subsets of data. - Use
mutate()
to create new variables.