-
Notifications
You must be signed in to change notification settings - Fork 39
/
tidyr.Rmd
448 lines (311 loc) · 17.7 KB
/
tidyr.Rmd
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
# Data Wrangling: `tidyr` {#tidyr}
```{r wrangling ops, include=FALSE}
knitr::opts_chunk$set(echo = TRUE)
options(scipen = 999, digits = 3) #restrict scientific notation and long decimals
library(htmltools)
```
## Objectives & Resources
Now you have some experience working with tidy data and seeing the logic of wrangling when data are structured in a tidy way. But 'real' data often don't start off in a tidy way, and require some reshaping to become tidy. The `tidyr` package is for reshaping data. You won't use `tidyr` functions as much as you use `dplyr` functions, but it is incredibly powerful when you need it.
### Objectives
- learn `tidyr` with the `gapminder` package
- practice the RStudio-GitHub workflow
- your turn: use the data wrangling cheat sheet to explore window functions
### Resources
These materials borrow heavily from:
- [R for Data Science: Relational Data](http://r4ds.had.co.nz/relational-data)
- [R for Data Science: Tidy Data](http://r4ds.had.co.nz/tidy-data.html#spreading-and-gathering)
### Data and packages
We'll use the package `tidyr` and `dplyr`, which are bundled within the `tidyverse` package.
We'll also be using the Gapminder data we used when learning `dplyr`. We will also explore several datasets that come in Base R, in the `datasets` package.
## `tidyr` basics
Remember, from the **`dplyr`** section, that tidy data means all rows are an observation and all columns are variables.
![](img/tidy_data.png)
Why is this important? Well, if your data are formatted in a standard way, you will be able to use analysis tools that operate on that standard way. Your analyses will be streamlined and you won't have to reinvent the wheel every time you see data in a different.
Let's take a look at some examples.
Data are often entered in a *wide* format where each row is often a site/subject/patient and you have multiple observation variables containing the same type of data.
An example of data in a *wide* format is the `AirPassengers` dataset which provides information on monthly airline passenger numbers from 1949-1960. You'll notice that each row is a single year and the columns are each month Jan - Dec.
```{r wide_data_ex}
AirPassengers
```
<!---TODO: gather this (it's not a dataframe...)--->
This format is intuitive for data entry, but less so for data analysis. If you wanted to calculate the monthly mean, where would you put it? As another row?
Often, data must be reshaped for it to become tidy data. What does that mean? There are four main verbs we'll use, which are essentially pairs of opposites:
- turn columns into rows (`gather()`),
- turn rows into columns (`spread()`),
- turn a character column into multiple columns (`separate()`),
- turn multiple character columns into a single column (`unite()`)
![](img/rstudio-cheatsheet-spread-gather-sep-unite.png)
## Explore gapminder dataset.
Yesterday we started off with the gapminder data in a format that was already tidy. But what if it weren't? Let's look at a different version of those data.
The data are on GitHub. Navigate there by going to:
github.com > ohi-science > data-science-training > data > gapminder_wide.csv
or by copy-pasting this in the browser: `https://github.com/OHI-Science/data-science-training/blob/master/data/gapminder_wide.csv`
First have a look at the data.
You can see there are a lot more columns than the version we looked at before. This format is pretty common, because it can be a lot more intuitive to *enter* data in this way.
![](img/gapminder_wide_gh.png)
<br>
Sometimes, as with the gapminder dataset, we have multiple types of observed data. It is somewhere in between the purely 'long' and 'wide' data formats:
- 3 "ID variables" (`continent`, `country`, `year`)
- 3 "Observation variables" (`pop`,`lifeExp`,`gdpPercap`).
It's pretty common to have data in this format in most cases despite not having ALL observations in 1 column, since all 3 observation variables have different units. But we can play with switching it to long format and wide to show what that means (i.e. long would be 4 ID variables and 1 observation variable).
But we want it to be in a tidy way so that we can work with it more easily. So here we go.
You use `spread()` and `gather()` to transform or reshape data between *wide* to *long* formats.
### Setup
OK let's get going.
We'll learn `tidyr` in an RMarkdown file within a GitHub repository so we can practice what we've learned so far. You can either continue from the same RMarkdown as yesterday, or begin a new one.
**Here's what to do:**
1. Clear your workspace (Session > Restart R)
1. New File > R Markdown..., save as something other than `gapminder-wrangle.Rmd` and delete irrelevant info, or just continue using `gapminder-wrangle.Rmd`
I'm going to write this in my R Markdown file:
```
Data wrangling with `tidyr`, which is part of the tidyverse. We are going to tidy some data!
```
### load `tidyverse` (which has `tidyr` inside)
First load `tidyr` in an R chunk. You already have installed the tidyverse, so you should be able to just load it like this (using the comment so you can run `install.packages("tidyverse")` easily if need be):
```{r, message=FALSE, warning=F}
library(tidyverse) # install.packages("tidyverse")
```
## `gather()` data from wide to long format
`r img(src='img/rstudio-cheatsheet-reshaping-data-gather.png', width=500)`
<br>
Read in the data from GitHub. Remember, you need to click on the 'Raw' button first so you can read it directly. Let's also read in the gapminder data from yesterday so that we can use it to compare later on.
```{r, eval=TRUE, message=FALSE}
## wide format
gap_wide <- readr::read_csv('https://raw.githubusercontent.com/OHI-Science/data-science-training/master/data/gapminder_wide.csv')
## yesterday's format
gapminder <- readr::read_csv('https://raw.githubusercontent.com/OHI-Science/data-science-training/master/data/gapminder.csv')
```
Let's have a look:
```{r, eval=FALSE}
head(gap_wide)
str(gap_wide)
```
While wide format is nice for data entry, it's not nice for calculations. Some of the columns are a mix of variable (e.g. "gdpPercap") and data ("1952"). What if you were asked for the mean population after 1990 in Algeria? Possible, but ugly. But we know it doesn't need to be so ugly. Let's tidy it back to the format we've been using.
> Question: let's talk this through together. If we're trying to turn the `gap_wide` format into `gapminder` format, what structure does it have that we like? And what do we want to change?
- We like the continent and country columns. We won't want to change those.
- We want 1 column identifying the variable name (`tidyr` calls this a **'key'**), and 1 column for the data (`tidyr` calls this the '**value'**).
- We actually want 3 different columns for variable: `gdpPercap`, `lifeExp`, and `pop`.
- We would like year as a separate column.
Let's get it to long format. We'll have to do this in 2 steps. The first step is to take all of those column names (e.g. `lifeExp_1970`) and make them a variable in a new column, and transfer the values into another column. Let's learn by doing:
Let's have a look at `gather()`'s help:
```{r, eval=FALSE}
?gather
```
> Question: What is our **key-value pair**?
We need to name two new variables in the key-value pair, one for the key, one for the value. It can be hard to wrap your mind around this, so let's give it a try. Let's name them `obstype_year` and `obs_values`.
Here's the start of what we'll do:
```{r, eval=TRUE}
gap_long <- gap_wide %>%
gather(key = obstype_year,
value = obs_values)
```
Although we were already planning to inspect our work, let's definitely do it now:
```{r, eval=TRUE, message=FALSE}
str(gap_long)
head(gap_long)
tail(gap_long)
```
We have reshaped our dataframe but this new format isn't really what we wanted.
What went wrong? Notice that it didn't know that we wanted to keep `continent` and `country` untouched; we need to give it more information about which columns we want reshaped. We can do this in several ways.
One way is to identify the columns is by name. Listing them explicitly can be a good approach if there are just a few. But in our case we have 30 columns. I'm not going to list them out here since there is way too much potential for error if I tried to list `gdpPercap_1952`, `gdpPercap_1957`, `gdpPercap_1962` and so on. But we could use some of `dplyr`'s awesome helper functions — because we expect that there is a better way to do this!
```{r, eval=FALSE}
gap_long <- gap_wide %>%
gather(key = obstype_year,
value = obs_values,
dplyr::starts_with('pop'),
dplyr::starts_with('lifeExp'),
dplyr::starts_with('gdpPercap')) #here i'm listing all the columns to use in gather
str(gap_long)
head(gap_long)
tail(gap_long)
```
Success! And there is another way that is nice to use if your columns don't follow such a structured pattern: you can exclude the columns you *don't* want.
```{r, eval=FALSE}
gap_long <- gap_wide %>%
gather(key = obstype_year,
value = obs_values,
-continent, -country)
str(gap_long)
head(gap_long)
tail(gap_long)
```
To recap:
Inside `gather()` we first name the new column for the new ID variable (`obstype_year`), the name for the new amalgamated observation variable (`obs_value`), then the names of the old observation variable. We could have typed out all the observation variables, but as in the `select()` function (see `dplyr` lesson), we can use the `starts_with()` argument to select all variables that starts with the desired character string. Gather also allows the alternative syntax of using the `-` symbol to identify which variables are not to be gathered (i.e. ID variables).
OK, but we're not done yet. `obstype_year` actually contains two pieces of information, the observation type (`pop`,`lifeExp`, or `gdpPercap`) and the `year`. We can use the `separate()` function to split the character strings into multiple variables.
`?separate` --> the main arguments are `separate(data, col, into, sep ...)`. So we need to specify which column we want separated, name the new columns that we want to create, and specify what we want it to separate by. Since the `obstype_year` variable has observation types and years separated by a `_`, we'll use that.
```{r, eval=TRUE, message=FALSE}
gap_long <- gap_wide %>%
gather(key = obstype_year,
value = obs_values,
-continent, -country) %>%
separate(obstype_year,
into = c('obs_type','year'),
sep = "_",
convert = TRUE) #this ensures that the year column is an integer rather than a character
```
No warning messages...still we inspect:
```{r, eval=TRUE}
str(gap_long)
head(gap_long)
tail(gap_long)
```
Excellent. This is long format: every row is a unique observation. Yay!
## Plot long format data
The long format is the preferred format for plotting with `ggplot2`. Let's look at an example by plotting just Canada's life expectancy.
```{r, eval=F}
canada_df <- gap_long %>%
filter(obs_type == "lifeExp",
country == "Canada")
ggplot(canada_df, aes(x = year, y = obs_values)) +
geom_line()
```
We can also look at all countries in the Americas:
```{r,eval=F}
life_df <- gap_long %>%
filter(obs_type == "lifeExp",
continent == "Americas")
ggplot(life_df, aes(x = year, y = obs_values, color = country)) +
geom_line()
```
> ### Exercise
>
> 1. Using `gap_long`, calculate and plot the the mean life expectancy for each continent over time from 1982 to 2007. Give your plot a title and assign x and y labels. **Hint:** do this in two steps. First, do the logic and calculations using `dplyr::group_by()` and `dplyr::summarize()`. Second, plot using `ggplot()`.
>
> **STOP: Knit the R Markdown file and sync to Github (pull, stage, commit, push)**
>
```{r, eval=FALSE}
# solution (no peeking!)
continents <- gap_long %>%
filter(obs_type == "lifeExp",
year > 1980) %>%
group_by(continent, year) %>%
summarize(mean_le = mean(obs_values)) %>%
ungroup()
ggplot(data = continents, aes(x = year, y = mean_le, color = continent)) +
geom_line() +
labs(title = "Mean life expectancy",
x = "Year",
y = "Age (years)")
## Additional customization
ggplot(data = continents, aes(x = year, y = mean_le, color = continent)) +
geom_line() +
labs(title = "Mean life expectancy",
x = "Year",
y = "Age (years)",
color = "Continent") +
theme_classic() +
scale_fill_brewer(palette = "Blues")
```
## `spread()`
The function `spread()` is used to transform data from long to wide format
Alright! Now just to double-check our work, let's use the opposite of `gather()` to spread our observation variables back to the original format with the aptly named `spread()`. You pass `spread()` the key and value pair, which is now `obs_type` and `obs_values`.
![](img/rstudio-cheatsheet-reshaping-data-spread.png)
```{r, eval=FALSE}
gap_normal <- gap_long %>%
spread(obs_type, obs_values)
```
No warning messages is good...but still let's check:
```{r, eval=FALSE}
dim(gap_normal)
dim(gapminder)
names(gap_normal)
names(gapminder)
```
Now we've got a dataframe `gap_normal` with the same dimensions as the original `gapminder`.
> ### Exercise
>
>1. Convert `gap_long` all the way back to `gap_wide`. Hint: Do this in 2 steps. First, create appropriate labels for all our new variables (variable_year combinations) with the opposite of separate: `tidyr::unite()`. Second, `spread()` that variable_year column into wider format.
>
>2. Knit the R Markdown file and sync to Github (pull, stage, commit, push)
>
### Answer (no peeking)
```{r, eval=FALSE}
head(gap_long) # remember the columns
gap_wide_new <- gap_long %>%
# first unite obs_type and year into a new column called var_names. Separate by _
unite(col = var_names, obs_type, year, sep = "_") %>%
# then spread var_names out by key-value pair.
spread(key = var_names, value = obs_values)
str(gap_wide_new)
```
## clean up and save your .Rmd
Spend some time cleaning up and saving `gapminder-wrangle.Rmd`
Restart R. In RStudio, use *Session > Restart R*. Otherwise, quit R with `q()` and re-launch it.
This morning's .Rmd could look something like this:
```{r, eval=FALSE}
## load tidyr (in tidyverse)
library(tidyverse) # install.packages("tidyverse")
## load wide data
gap_wide <- read.csv('https://raw.githubusercontent.com/OHI-Science/data-science-training/master/data/gapminder_wide.csv')
head(gap_wide)
str(gap_wide)
## practice tidyr::gather() wide to long
gap_long <- gap_wide %>%
gather(key = obstype_year,
value = obs_values,
-continent, -country)
# or
gap_long <- gap_wide %>%
gather(key = obstype_year,
value = obs_values,
dplyr::starts_with('pop'),
dplyr::starts_with('lifeExp'),
dplyr::starts_with('gdpPercap'))
## gather() and separate() to create our original gapminder
gap_long <- gap_wide %>%
gather(key = obstype_year,
value = obs_values,
-continent, -country) %>%
separate(obstype_year,
into = c('obs_type','year'),
sep="_")
## practice: can still do calculations in long format
gap_long %>%
group_by(continent, obs_type) %>%
summarize(means = mean(obs_values))
## spread() from normal to wide
gap_normal <- gap_long %>%
spread(obs_type, obs_values) %>%
select(country, continent, year, lifeExp, pop, gdpPercap)
## check that all.equal()
all.equal(gap_normal,gapminder)
## unite() and spread(): convert gap_long to gap_wide
head(gap_long) # remember the columns
gap_wide_new <- gap_long %>%
# first unite obs_type and year into a new column called var_names. Separate by _
unite(col = var_names, obs_type, year, sep = "_") %>%
# then spread var_names out by key-value pair.
spread(key = var_names, value = obs_values)
str(gap_wide_new)
```
### `complete()`
One of the coolest functions in `tidyr` is the function `complete()`. Jarrett Byrnes has written up a [great blog piece](http://www.imachordata.com/you-complete-me/) showcasing the utility of this function so I'm going to use that example here.
We'll start with an example dataframe where the data recorder enters the Abundance of two species of kelp, *Saccharina* and *Agarum* in the years 1999, 2000 and 2004.
```{r, eval=F}
kelpdf <- data.frame(
Year = c(1999, 2000, 2004, 1999, 2004),
Taxon = c("Saccharina", "Saccharina", "Saccharina", "Agarum", "Agarum"),
Abundance = c(4,5,2,1,8)
)
kelpdf
```
Jarrett points out that *Agarum* is not listed for the year 2000. Does this mean it wasn't observed (Abundance = 0) or that it wasn't recorded (Abundance = NA)? Only the person who recorded the data knows, but let's assume that the this means the Abundance was 0 for that year.
We can use the `complete()` function to make our dataset more complete.
```{r, eval=F}
kelpdf %>%
complete(Year, Taxon)
```
This gives us an NA for *Agarum* in 2000, but we want it to be a 0 instead. We can use the `fill` argument to assign the fill value.
```{r, eval=F}
kelpdf %>% complete(Year, Taxon, fill = list(Abundance = 0))
```
Now we have what we want. Let's assume that all years between 1999 and 2004 that aren't listed should actually be assigned a value of 0. We can use the `full_seq()` function from `tidyr` to fill out our dataset with all years 1999-2004 and assign Abundance values of 0 to those years & species for which there was no observation.
```{r, eval=F}
kelpdf %>% complete(Year = full_seq(Year, period = 1),
Taxon,
fill = list(Abundance = 0))
```
------
## Other links
* [Tidying up Data - Env Info](http://ucsb-bren.github.io/env-info/wk04_tidyr.html) - [Rmd](https://github.com/ucsb-bren/env-info/blob/gh-pages/wk04_tidyr.Rmd)
* [Data wrangling with dplyr and tidyr - Tyler Clavelle & Dan Ovando](http://bbest.github.io/dplyr-tidyr-tutorial/) - [Rmd](https://github.com/bbest/dplyr-tidyr-tutorial/blob/gh-pages/index.Rmd)