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This vignette introduces you to the basics of web scraping with rvest. You’ll first learn the basics of HTML and how to use CSS selectors to refer to specific elements, then you’ll learn how to use rvest functions to get data out of HTML and into R.
HTML stands for “HyperText Markup Language” and looks like this:
<html>
<head>
<title>Page title</title>
</head>
<body>
<h1 id='first'>A heading</h1>
<p>Some text & <b>some bold text.</b></p>
<img src='myimg.png' width='100' height='100'>
</body>
HTML has a hierarchical structure formed by elements
which consist of a start tag (e.g. <tag>
), optional
attributes (id='first'
), an end tag1 (like
</tag>
), and contents (everything in
between the start and end tag).
Since <
and >
are used for start and
end tags, you can’t write them directly. Instead you have to use the
HTML escapes >
(greater than) and
<
(less than). And since those escapes use
&
, if you want a literal ampersand you have to escape
it as &
. There are a wide range of possible HTML
escapes but you don’t need to worry about them too much because rvest
automatically handles them for you.
All up, there are over 100 HTML elements. Some of the most important are:
Every HTML page must be in an <html>
element,
and it must have two children: <head>
, which contains
document metadata like the page title, and <body>
,
which contains the content you see in the browser.
Block tags like <h1>
(heading 1),
<p>
(paragraph), and <ol>
(ordered
list) form the overall structure of the page.
Inline tags like <b>
(bold),
<i>
(italics), and <a>
(links)
formats text inside block tags.
If you encounter a tag that you’ve never seen before, you can find out what it does with a little googling. I recommend the MDN Web Docs which are produced by Mozilla, the company that makes the Firefox web browser.
Most elements can have content in between their start and end tags. This content can either be text or more elements. For example, the following HTML contains paragraph of text, with one word in bold.
Hi! My name is Hadley.
The children of a node refers only to elements, so
the <p>
element above has one child, the
<b>
element. The <b>
element has
no children, but it does have contents (the text “name”).
Some elements, like <img>
can’t have children.
These elements depend solely on attributes for their behavior.
Tags can have named attributes which look like
name1='value1' name2='value2'
. Two of the most important
attributes are id
and class
, which are used in
conjunction with CSS (Cascading Style Sheets) to control the visual
appearance of the page. These are often useful when scraping data off a
page.
You’ll usually start the scraping process with
read_html()
. This returns a xml_document
2 object
which you’ll then manipulate using rvest functions:
For examples and experimentation, rvest also includes a function that
lets you create an xml_document
from literal HTML:
html <- minimal_html("
<p>This is a paragraph<p>
<ul>
<li>This is a bulleted list</li>
</ul>
")
html
#> {html_document}
#> <html>
#> [1] <head>\n<meta http-equiv="Content-Type" content="text/html; charset=UTF-8 ...
#> [2] <body>\n<p>This is a paragraph</p>\n<p>\n </p>\n<ul>\n<li>This is a bull ...
Regardless of how you get the HTML, you’ll need some way to identify the elements that contain the data you care about. rvest provides two options: CSS selectors and XPath expressions. Here I’ll focus on CSS selectors because they’re simpler but still sufficiently powerful for most scraping tasks.
CSS is short for cascading style sheets, and is a tool for defining the visual styling of HTML documents. CSS includes a miniature language for selecting elements on a page called CSS selectors. CSS selectors define patterns for locating HTML elements, and are useful for scraping because they provide a concise way of describing which elements you want to extract.
CSS selectors can be quite complex, but fortunately you only need the simplest for rvest, because you can also write R code for more complicated situations. The four most important selectors are:
p
: selects all <p>
elements.
.title
: selects all elements with class
“title”.
p.special
: selects all <p>
elements with class
“special”.
#title
: selects the element with the id
attribute that equals “title”. Id attributes must be unique within a
document, so this will only ever select a single element.
If you want to learn more CSS selectors I recommend starting with the fun CSS dinner tutorial and then referring to the MDN web docs.
Lets try out the most important selectors with a simple example:
html <- minimal_html("
<h1>This is a heading</h1>
<p id='first'>This is a paragraph</p>
<p class='important'>This is an important paragraph</p>
")
In rvest you can extract a single element with
html_element()
or all matching elements with
html_elements()
. Both functions take a document3 and a css
selector:
html %>% html_element("h1")
#> {html_node}
#> <h1>
html %>% html_elements("p")
#> {xml_nodeset (2)}
#> [1] <p id="first">This is a paragraph</p>
#> [2] <p class="important">This is an important paragraph</p>
html %>% html_elements(".important")
#> {xml_nodeset (1)}
#> [1] <p class="important">This is an important paragraph</p>
html %>% html_elements("#first")
#> {xml_nodeset (1)}
#> [1] <p id="first">This is a paragraph</p>
Selectors can also be combined in various ways using
combinators. For example,The most important combinator
is ” “, the descendant combination, because
p a
selects all <a>
elements that are a
child of a <p>
element.
If you don’t know exactly what selector you need, I highly recommend using SelectorGadget, which lets you automatically generate the selector you need by supplying positive and negative examples in the browser.
Now that you’ve got the elements you care about, you’ll need to get data out of them. You’ll usually get the data from either the text contents or an attribute. But, sometimes (if you’re lucky!), the data you need will be in an HTML table.
Use html_text2()
to extract the plain text contents of
an HTML element:
html <- minimal_html("
<ol>
<li>apple & pear</li>
<li>banana</li>
<li>pineapple</li>
</ol>
")
html %>%
html_elements("li") %>%
html_text2()
#> [1] "apple & pear" "banana" "pineapple"
Note that the escaped ampersand is automatically converted to
&
; you’ll only ever see HTML escapes in the source
HTML, not in the data returned by rvest.
You might wonder why I used html_text2()
, since it seems
to give the same result as html_text()
:
The main difference is how the two functions handle white space. In
HTML, white space is largely ignored, and it’s the structure of the
elements that defines how text is laid out. html_text2()
does its best to follow the same rules, giving you something similar to
what you’d see in the browser. Take this example which contains a bunch
of white space that HTML ignores.
html <- minimal_html("<body>
<p>
This is
a
paragraph.</p><p>This is another paragraph.
It has two sentences.</p>
")
html_text2()
gives you what you expect: two paragraphs
of text separated by a blank line.
html %>%
html_element("body") %>%
html_text2() %>%
cat()
#> This is a paragraph.
#>
#> This is another paragraph. It has two sentences.
Whereas html_text()
returns the garbled raw underlying
text:
Attributes are used to record the destination of links (the
href
attribute of <a>
elements) and the
source of images (the src
attribute of the
<img>
element):
html <- minimal_html("
<p><a href='https://en.wikipedia.org/wiki/Cat'>cats</a></p>
<img src='https://cataas.com/cat' width='100' height='200'>
")
The value of an attribute can be retrieved with
html_attr()
:
html %>%
html_elements("a") %>%
html_attr("href")
#> [1] "https://en.wikipedia.org/wiki/Cat"
html %>%
html_elements("img") %>%
html_attr("src")
#> [1] "https://cataas.com/cat"
Note that html_attr()
always returns a string, so you
may need to post-process with
as.integer()
/readr::parse_integer()
or
similar.
HTML tables are composed four main elements:
<table>
, <tr>
(table row),
<th>
(table heading), and <td>
(table data). Here’s a simple HTML table with two columns and three
rows:
html <- minimal_html("
<table>
<tr>
<th>x</th>
<th>y</th>
</tr>
<tr>
<td>1.5</td>
<td>2.7</td>
</tr>
<tr>
<td>4.9</td>
<td>1.3</td>
</tr>
<tr>
<td>7.2</td>
<td>8.1</td>
</tr>
</table>
")
Because tables are a common way to store data, rvest includes the
handy html_table()
which converts a table into a data
frame:
When using rvest, your eventual goal is usually to build up a data
frame, and you want each row to correspond some repeated unit on the
HTML page. In this case, you should generally start by using
html_elements()
to select the elements that contain each
observation then use html_element()
to extract the
variables from each observation. This guarantees that you’ll get the
same number of values for each variable because
html_element()
always returns the same number of outputs as
inputs.
To illustrate this problem take a look at this simple example I
constructed using a few entries from dplyr::starwars
:
html <- minimal_html("
<ul>
<li><b>C-3PO</b> is a <i>droid</i> that weighs <span class='weight'>167 kg</span></li>
<li><b>R2-D2</b> is a <i>droid</i> that weighs <span class='weight'>96 kg</span></li>
<li><b>Yoda</b> weighs <span class='weight'>66 kg</span></li>
<li><b>R4-P17</b> is a <i>droid</i></li>
</ul>
")
If you try to extract name, species, and weight directly, you end up with one vector of length four and two vectors of length three, and no way to align them:
html %>% html_elements("b") %>% html_text2()
#> [1] "C-3PO" "R2-D2" "Yoda" "R4-P17"
html %>% html_elements("i") %>% html_text2()
#> [1] "droid" "droid" "droid"
html %>% html_elements(".weight") %>% html_text2()
#> [1] "167 kg" "96 kg" "66 kg"
Instead, use html_elements()
to find a element that
corresponds to each character, then use html_element()
to
extract each variable for all observations:
characters <- html %>% html_elements("li")
characters %>% html_element("b") %>% html_text2()
#> [1] "C-3PO" "R2-D2" "Yoda" "R4-P17"
characters %>% html_element("i") %>% html_text2()
#> [1] "droid" "droid" NA "droid"
characters %>% html_element(".weight") %>% html_text2()
#> [1] "167 kg" "96 kg" "66 kg" NA
html_element()
automatically fills in NA
when no elements match, keeping all of the variables aligned and making
it easy to create a data frame:
data.frame(
name = characters %>% html_element("b") %>% html_text2(),
species = characters %>% html_element("i") %>% html_text2(),
weight = characters %>% html_element(".weight") %>% html_text2()
)
#> name species weight
#> 1 C-3PO droid 167 kg
#> 2 R2-D2 droid 96 kg
#> 3 Yoda <NA> 66 kg
#> 4 R4-P17 droid <NA>
A number of tags (including <p>
and
<li>)
don’t require end tags, but I think it’s best
to include them because it makes seeing the structure of the HTML a
little easier.↩︎
This class comes from the xml2 package. xml2 is a low-level package that rvest builds on top of.↩︎
Or another element, more on that shortly.↩︎
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.