Web scraping is the process of collecting and parsing raw data from the Web, and the Python community has come up with some pretty powerful web scraping tools. The Internet hosts perhaps the greatest source of information—and misinformation—on the planet. Many disciplines, such as data science, business intelligence, and investigative reporting, can benefit enormously from collecting and analyzing data from websites. In this tutorial, you’ll learn
how to: - Parse website data using string methods and regular expressions
- Parse website data using an HTML parser
- Interact with forms and other website components
Scrape and Parse Text From
WebsitesCollecting data from websites using an automated process is known as web scraping. Some websites explicitly forbid users from scraping their data with automated tools like the ones you’ll create in this tutorial. Websites do this for two possible reasons: - The site has a good reason to protect its data. For instance,
Google Maps doesn’t let you request too many results too quickly.
- Making many repeated requests to a website’s server may use up bandwidth, slowing down the website for other users and potentially overloading the server such that the website stops responding entirely.
Let’s start by grabbing all the HTML code from a single web page. You’ll use a page on Real Python that’s been set up for use with this tutorial. Your First
Web ScraperOne useful package for web scraping that you can find in Python’s standard library is urllib, which contains tools for working with URLs. In particular, the urllib.request module contains a function called
urlopen() that can be used to open a URL within a program. In IDLE’s interactive window, type the following to import urlopen(): >>> >>> from urllib.request import urlopen
The web page that we’ll open is at the following URL: >>> >>> url = "http://olympus.realpython.org/profiles/aphrodite"
To open the web page, pass url to urlopen(): >>>
>>> page = urlopen(url)
urlopen() returns an HTTPResponse object:
>>> >>> page
<http.client.HTTPResponse object at 0x105fef820>
To extract the HTML from the page, first use the HTTPResponse object’s .read() method, which returns a sequence of bytes. Then use .decode() to decode the bytes to a string using UTF-8: >>>
>>> html_bytes = page.read()
>>> html = html_bytes.decode("utf-8")
Now you can print the HTML to see the contents of the web page: >>> >>> print(html)
<html>
<head>
<title>Profile: Aphrodite</title>
</head>
<body bgcolor="yellow">
<center>
<br><br>
<img src="/static/aphrodite.gif" />
<h2>Name: Aphrodite</h2>
<br><br>
Favorite animal: Dove
<br><br>
Favorite color: Red
<br><br>
Hometown: Mount Olympus
</center>
</body>
</html>
Once you have the HTML as text, you can extract information from it in a couple of different ways. A Primer on Regular
ExpressionsRegular expressions—or regexes for short—are patterns that can be used to search for text within a string. Python supports regular expressions through the standard library’s re module. To work with regular
expressions, the first thing you need to do is import the re module: Regular expressions use special characters called metacharacters to denote different patterns. For instance, the asterisk character (*) stands for zero or more of whatever comes just before the asterisk. In the following example, you use findall() to find any text within a string that matches a given regular expression: >>>
>>> re.findall("ab*c", "ac")
['ac']
The first argument of re.findall() is the regular expression that you want to match, and the second argument is the string to test. In the above example, you search for the pattern "ab*c" in the string "ac". The regular expression "ab*c" matches any part of the string that begins with an "a", ends with a "c", and has zero or more instances of "b" between the two. re.findall() returns a
list of all matches. The string "ac" matches this pattern, so it’s returned in the list. Here’s the same pattern applied to different strings: >>> >>> re.findall("ab*c", "abcd")
['abc']
>>> re.findall("ab*c", "acc")
['ac']
>>> re.findall("ab*c", "abcac")
['abc', 'ac']
>>> re.findall("ab*c", "abdc")
[]
Notice that if no match is found, then findall() returns an empty list. Pattern matching is case sensitive. If you want to match this pattern regardless of the case, then
you can pass a third argument with the value re.IGNORECASE: >>> >>> re.findall("ab*c", "ABC")
[]
>>> re.findall("ab*c", "ABC", re.IGNORECASE)
['ABC']
You can use a period (.) to stand for any single character in a regular expression. For instance, you could find all the strings that contain the letters "a" and "c" separated by a single character as follows: >>> >>> re.findall("a.c", "abc")
['abc']
>>> re.findall("a.c", "abbc")
[]
>>> re.findall("a.c", "ac")
[]
>>> re.findall("a.c", "acc")
['acc']
The pattern .* inside
a regular expression stands for any character repeated any number of times. For instance, "a.*c" can be used to find every substring that starts with "a" and ends with "c", regardless of which letter—or letters—are in between: >>> >>> re.findall("a.*c", "abc")
['abc']
>>> re.findall("a.*c", "abbc")
['abbc']
>>> re.findall("a.*c", "ac")
['ac']
>>> re.findall("a.*c", "acc")
['acc']
Often, you use re.search() to search for a particular pattern inside a string. This function is somewhat more complicated than re.findall() because it returns an object
called a MatchObject that stores different groups of data. This is because there might be matches inside other matches, and re.search() returns every possible result. The details of the MatchObject are irrelevant here. For now, just know that calling .group() on a MatchObject will return the first and most inclusive result, which in most cases is just what you want: >>> >>> match_results = re.search("ab*c", "ABC", re.IGNORECASE)
>>> match_results.group()
'ABC'
There’s one more function in the re
module that’s useful for parsing out text. re.sub(), which is short for substitute, allows you to replace text in a string that matches a regular expression with new text. It behaves sort of like the .replace() string method. The arguments passed to re.sub() are the regular expression, followed
by the replacement text, followed by the string. Here’s an example: >>> >>> string = "Everything is <replaced> if it's in <tags>."
>>> string = re.sub("<.*>", "ELEPHANTS", string)
>>> string
'Everything is ELEPHANTS.'
Perhaps that wasn’t quite what you expected to happen. re.sub() uses the regular expression "<.*>" to find and replace everything between the first < and last >, which spans from the beginning of <replaced> to the end of <tags>. This is because Python’s regular expressions are greedy, meaning they
try to find the longest possible match when characters like * are used.
Alternatively, you can use the non-greedy matching pattern *?, which works the same way as * except that it matches the shortest possible string of text: >>> >>> string = "Everything is <replaced> if it's in <tags>."
>>> string = re.sub("<.*?>", "ELEPHANTS", string)
>>> string
"Everything is ELEPHANTS if it's in ELEPHANTS."
This time, re.sub() finds two matches, <replaced> and <tags>, and substitutes the string "ELEPHANTS" for both matches. Check Your UnderstandingExpand the block below to check your understanding. Write a program that grabs the full HTML from the following URL: >>> >>> url = "http://olympus.realpython.org/profiles/dionysus"
Then
use .find() to display the text following “Name:” and “Favorite Color:” (not including any leading spaces or trailing HTML tags that might appear on the same line). You can expand the block below to see a solution. First, import the urlopen function from the urlib.request module: from urllib.request import urlopen
Then open the URL and use the .read() method of the HTTPResponse object returned by urlopen() to read the page’s
HTML:
url = "http://olympus.realpython.org/profiles/dionysus"
html_page = urlopen(url)
html_text = html_page.read().decode("utf-8")
.read() returns a byte string, so you use .decode() to decode the bytes using the UTF-8 encoding.
Now that you have the HTML source of the web page as a string assigned to the html_text variable, you can extract Dionysus’s name and favorite color from his profile. The structure of the HTML for Dionysus’s profile is the same as Aphrodite’s profile that you saw earlier. You can get the name by finding the string "Name:" in the text and extracting everything that
comes after the first occurence of the string and before the next HTML tag. That is, you need to extract everything after the colon (:) and before the first angle bracket (<). You can use the same technique to extract the favorite color. The following for loop extracts this text for both the name and favorite color: for string in ["Name: ", "Favorite Color:"]:
string_start_idx = html_text.find(string)
text_start_idx = string_start_idx + len(string)
next_html_tag_offset = html_text[text_start_idx:].find("<")
text_end_idx = text_start_idx + next_html_tag_offset
raw_text = html_text[text_start_idx : text_end_idx]
clean_text = raw_text.strip(" \r\n\t")
print(clean_text)
It looks like there’s a lot going on in this forloop, but
it’s just a little bit of arithmetic to calculate the right indices for extracting the desired text. Let’s break it down: You use html_text.find() to find the starting index of the string, either "Name:" or "Favorite Color:", and then assign the index to string_start_idx. Since the text to extract starts just after the colon in "Name:" or "Favorite Color:", you get the index of the the character immediately after the colon by adding the length of the string to start_string_idx and assign the result to
text_start_idx. You calculate the ending index of the text to extract by determining the index of the first angle bracket (<) relative to text_start_idx and assign this value to next_html_tag_offset. Then you add that value to text_start_idx and assign the result to text_end_idx. You extract the text by slicing html_text from text_start_idx to text_end_idx and assign this string to raw_text. You remove any whitespace from the beginning and end of raw_text using .strip()
and assign the result to clean_text.
At the end of the loop, you use print() to display the extracted text. The final output looks like this: This solution is one of many that solves this problem, so if you got the same output with a different solution, then you did great! When you’re ready, you can move on to the next section. Use an HTML Parser for Web Scraping in
PythonAlthough regular expressions are great for pattern matching in general, sometimes it’s easier to use an HTML parser that’s explicitly designed for parsing out HTML pages. There are many Python tools written for this purpose, but the Beautiful
Soup library is a good one to start with. Install Beautiful SoupTo install Beautiful Soup, you can run the following in your terminal: $ python3 -m pip install beautifulsoup4
Run pip show to see the details of the package you just installed: $ python3 -m pip show beautifulsoup4
Name: beautifulsoup4
Version: 4.9.1
Summary: Screen-scraping library
Home-page: http://www.crummy.com/software/BeautifulSoup/bs4/
Author: Leonard Richardson
Author-email:
License: MIT
Location: c:\realpython\venv\lib\site-packages
Requires:
Required-by:
In particular, notice that the latest version at
the time of writing was 4.9.1. Create a BeautifulSoup ObjectType the following program into a new editor window: from bs4 import BeautifulSoup
from urllib.request import urlopen
url = "http://olympus.realpython.org/profiles/dionysus"
page = urlopen(url)
html = page.read().decode("utf-8")
soup = BeautifulSoup(html, "html.parser")
This program does three things: Opens the URL http://olympus.realpython.org/profiles/dionysus using urlopen() from the urllib.request module Reads the HTML from the
page as a string and assigns it to the html variable Creates a BeautifulSoup object and assigns it to the soup variable
The BeautifulSoup object assigned to soup is created with two arguments. The first argument is the HTML to be parsed, and the second argument, the string "html.parser", tells the object which parser to use behind the scenes. "html.parser" represents Python’s built-in HTML parser. Use a BeautifulSoup
ObjectSave and run the above program. When it’s finished running, you can use the soup variable in the interactive window to parse the content of html in various ways. For example, BeautifulSoup objects have a .get_text() method that can be used to extract all the text from the document and automatically remove any HTML tags. Type
the following code into IDLE’s interactive window: >>> >>> print(soup.get_text())
Profile: Dionysus
Name: Dionysus
Hometown: Mount Olympus
Favorite animal: Leopard
Favorite Color: Wine
There are a lot of blank lines in this output. These are the result of newline characters in the HTML document’s text. You can remove them with the string .replace() method if you need to. Often, you need to get only specific text from an HTML document. Using Beautiful Soup first to extract the text and then using the .find() string method is
sometimes easier than working with regular expressions. However, sometimes the HTML tags themselves are the elements that point out the data you want to retrieve. For instance, perhaps you want to retrieve the URLs for all the images on the page. These links are contained in the src attribute of <img> HTML tags. In this case, you can use find_all() to return a list of all instances of that particular tag: >>>
>>> soup.find_all("img")
[<img src="/static/dionysus.jpg"/>, <img src="/static/grapes.png"/>]
This returns a list of all <img> tags in the HTML document. The objects in the list look like they might be strings representing the tags, but they’re actually instances of the Tag object provided by Beautiful Soup. Tag objects provide a simple interface for working with the information they contain. Let’s explore this a little by first unpacking the Tag objects from the list: >>>
>>> image1, image2 = soup.find_all("img")
Each Tag object has a .name property that returns a string containing the HTML tag type: You can access the HTML attributes of the Tag object by putting their name between square brackets, just as if the attributes were keys in a dictionary. For example, the <img src="/static/dionysus.jpg"/> tag has a single attribute, src, with the value "/static/dionysus.jpg". Likewise, an HTML tag such as the link <a href="https://realpython.com" target="_blank"> has two attributes, href and target. To get the source of the
images in the Dionysus profile page, you access the src attribute using the dictionary notation mentioned above: >>> >>> image1["src"]
'/static/dionysus.jpg'
>>> image2["src"]
'/static/grapes.png'
Certain tags in HTML documents can be accessed by properties of the Tag object. For example, to get the <title> tag in a document, you can use the .title property: >>> >>> soup.title
<title>Profile: Dionysus</title>
If you look at the
source of the Dionysus profile by navigating to the profile page, right-clicking on the page, and selecting View page source, then you’ll notice that the <title> tag as written in the document looks like this: <title >Profile: Dionysus</title/>
Beautiful Soup automatically cleans up the tags for you by removing the extra space in the opening tag and the extraneous forward slash (/) in the closing tag. You
can also retrieve just the string between the title tags with the .string property of the Tag object: >>> >>> soup.title.string
'Profile: Dionysus'
One of the more useful features of Beautiful Soup is the ability to search for specific kinds of tags whose attributes match certain values. For example, if you want to find all the <img> tags that have a src attribute equal to the value /static/dionysus.jpg, then you can provide the following
additional argument to .find_all(): >>> >>> soup.find_all("img", src="/static/dionysus.jpg")
[<img src="/static/dionysus.jpg"/>]
This example is somewhat arbitrary, and the usefulness of this technique may not be apparent from the example. If you spend some time browsing various websites and viewing their page sources, then you’ll notice that many websites have extremely complicated HTML structures. When scraping data from websites with Python, you’re often interested in particular parts of
the page. By spending some time looking through the HTML document, you can identify tags with unique attributes that you can use to extract the data you need. Then, instead of relying on complicated regular expressions or using .find() to search through the document, you can directly access the particular tag you’re interested in and extract the data you need. In some cases, you may find that Beautiful Soup doesn’t offer the functionality you need. The
lxml library is somewhat trickier to get started with but offers far more flexibility than Beautiful Soup for parsing HTML documents. You may want to check it out once you’re comfortable using Beautiful Soup. BeautifulSoup is great for scraping data from a website’s HTML, but it doesn’t provide any way to work with HTML forms. For example, if you need to search a website for some query and then scrape the results, then BeautifulSoup alone won’t
get you very far. Check Your UnderstandingExpand the block below to check your understanding. Write a program that grabs the full HTML from the
page at the URL http://olympus.realpython.org/profiles. Using Beautiful Soup, print out a list of all the links on the page by looking for HTML tags with the name a and retrieving the value taken on by the href attribute of each tag. The final output should look like this: http://olympus.realpython.org/profiles/aphrodite
http://olympus.realpython.org/profiles/poseidon
http://olympus.realpython.org/profiles/dionysus
You can expand the block below to see a solution: First, import
the urlopen function from the urlib.request module and the BeautifulSoup class from the bs4 package: from urllib.request import urlopen
from bs4 import BeautifulSoup
Each link URL on the /profiles page is a relative URL, so create a base_url variable with the base URL of the website: base_url = "http://olympus.realpython.org"
You can build a full URL by concatenating base_url with a relative URL. Now open the /profiles page with urlopen() and use .read() to get the
HTML source: html_page = urlopen(base_url + "/profiles")
html_text = html_page.read().decode("utf-8")
With the HTML source downloaded and decoded, you can create a new BeautifulSoup object to parse the HTML: soup = BeautifulSoup(html_text, "html.parser")
soup.find_all("a") returns a list of all links in the HTML source. You can loop over this list to print out all the links on the webpage:
for link in soup.find_all("a"):
link_url = base_url + link["href"]
print(link_url)
The relative URL for each link can be accessed through the "href" subscript. Concatenate this value with base_url to create the full link_url. When you’re ready, you can
move on to the next section. The urllib module you’ve been working with so far in this tutorial is well suited for requesting the contents of a web page. Sometimes, though, you need to interact with a web page to obtain the content you need. For example,
you might need to submit a form or click a button to display hidden content. The Python standard library doesn’t provide a built-in means for working with web pages interactively, but many third-party packages are available from PyPI. Among these, MechanicalSoup is a popular and relatively straightforward package to use. In essence, MechanicalSoup installs what’s known as a headless browser,
which is a web browser with no graphical user interface. This browser is controlled programmatically via a Python program. Install MechanicalSoupYou can install MechanicalSoup with pip in your terminal: $ python3 -m pip install MechanicalSoup
You can
now view some details about the package with pip show: $ python3 -m pip show mechanicalsoup
Name: MechanicalSoup
Version: 0.12.0
Summary: A Python library for automating interaction with websites
Home-page: https://mechanicalsoup.readthedocs.io/
Author: UNKNOWN
Author-email: UNKNOWN
License: MIT
Location: c:\realpython\venv\lib\site-packages
Requires: requests, beautifulsoup4, six, lxml
Required-by:
In particular, notice that the latest version at the time of writing was 0.12.0. You’ll need to close and restart your IDLE session for MechanicalSoup to load and be recognized after it’s been installed. Create a Browser
ObjectType the following into IDLE’s interactive window: >>> >>> import mechanicalsoup
>>> browser = mechanicalsoup.Browser()
Browser objects represent the headless web browser. You can use them to request a page from the Internet by passing a URL to their .get() method:
>>> >>> url = "http://olympus.realpython.org/login"
>>> page = browser.get(url)
page is a Response object that stores the response from requesting the URL from the browser:
>>> >>> page
<Response [200]>
The number 200 represents the status code returned by the request. A status code of 200 means that the request was successful. An
unsuccessful request might show a status code of 404 if the URL doesn’t exist or 500 if there’s a server error when making the request. MechanicalSoup uses Beautiful Soup to parse the HTML from the request. page has a .soup attribute that represents a BeautifulSoup object: >>> >>> type(page.soup)
<class 'bs4.BeautifulSoup'>
You can view the HTML by inspecting the .soup attribute: >>> >>> page.soup
<html>
<head>
<title>Log In</title>
</head>
<body bgcolor="yellow">
<center>
<br/><br/>
<h2>Please log in to access Mount Olympus:</h2>
<br/><br/>
<form action="/login" method="post" name="login">
Username: <input name="user" type="text"/><br/>
Password: <input name="pwd" type="password"/><br/><br/>
<input type="submit" value="Submit"/>
</form>
</center>
</body>
</html>
Notice this page has a <form> on it with <input> elements for a username and a password. Open the
/login page from the previous example in a browser and look at it yourself before moving on. Try typing in a random username and password combination. If you guess incorrectly, then the message “Wrong username or password!” is displayed at the bottom of the page. However, if you provide the correct login credentials (username zeus and password ThunderDude), then you’re redirected to the
/profiles page. In the next example, you’ll see how to use MechanicalSoup to fill out and submit this form using Python! The important section of HTML code is the login form—that is, everything inside the <form> tags. The <form> on this page has the name attribute set to login. This form contains two <input> elements, one named user and the other named pwd. The third <input> element is the
Submit button. Now that you know the underlying structure of the login form, as well as the credentials needed to log in, let’s take a look at a program. that fills the form out and submits it. In a new editor window, type in the following program: import mechanicalsoup
# 1
browser = mechanicalsoup.Browser()
url = "http://olympus.realpython.org/login"
login_page = browser.get(url)
login_html = login_page.soup
# 2
form = login_html.select("form")[0]
form.select("input")[0]["value"] = "zeus"
form.select("input")[1]["value"] = "ThunderDude"
# 3
profiles_page = browser.submit(form, login_page.url)
Save the file and press F5 to run it. You can confirm that you successfully logged in by typing the following into the interactive window: >>> >>> profiles_page.url
'http://olympus.realpython.org/profiles'
Let’s break down the above example: You create a Browser instance and use it to request the URL http://olympus.realpython.org/login. You assign the HTML content of the page to the login_html variable using the .soup property. login_html.select("form") returns a list of all <form> elements on the page. Since the page has only one <form> element, you can access the form by retrieving the element at index 0 of the list. The
next two lines select the username and password inputs and set their value to "zeus" and "ThunderDude", respectively.
You submit the form with browser.submit(). Notice that you pass two arguments to this method, the form object and the URL of the login_page, which you access via login_page.url.
In the interactive window, you confirm that the submission successfully redirected to the /profiles page. If something had gone wrong, then the value of profiles_page.url would still be "http://olympus.realpython.org/login".
Now that we have the profiles_page variable set, let’s see how to programmatically obtain the URL for each link on the /profiles page. To do this, you use .select() again, this time passing the string "a" to select all the <a> anchor elements on the page: >>> >>> links = profiles_page.soup.select("a")
Now you can iterate over each link and print the href attribute: >>>
>>> for link in links:
... address = link["href"]
... text = link.text
... print(f"{text}: {address}")
...
Aphrodite: /profiles/aphrodite
Poseidon: /profiles/poseidon
Dionysus: /profiles/dionysus
The URLs contained in each href attribute are relative URLs, which aren’t very helpful if you want to navigate to them later using MechanicalSoup. If you happen to know the full URL, then you can assign the portion needed to construct a full URL. In this case, the base URL is just http://olympus.realpython.org. Then you can concatenate the base URL with the relative URLs found in the src attribute: >>> >>> base_url = "http://olympus.realpython.org"
>>> for link in links:
... address = base_url + link["href"]
... text = link.text
... print(f"{text}: {address}")
...
Aphrodite: http://olympus.realpython.org/profiles/aphrodite
Poseidon: http://olympus.realpython.org/profiles/poseidon
Dionysus: http://olympus.realpython.org/profiles/dionysus
You can do a lot with just .get(), .select(), and .submit(). That said, MechanicalSoup is capable of much more. To learn more about MechanicalSoup, check out the official docs. Check Your Understanding
Expand the block below to check your understanding Use MechanicalSoup to provide the correct username (zeus) and password (ThunderDude) to the login form located at the URL http://olympus.realpython.org/login. Once the form is submitted, display the title of the current page to determine that you’ve been redirected to the
/profiles page. Your program should print the text <title>All Profiles</title>. You can expand the block below to see a solution. First, import the mechanicalsoup package and create a Broswer object: import mechanicalsoup
browser = mechanicalsoup.Browser()
Point the browser to the login page by passing the URL to browser.get() and grab the HTML with the .soup attribute: login_url = "http://olympus.realpython.org/login"
login_page = browser.get(login_url)
login_html = login_page.soup
login_html
is a BeautifulSoup instance. Since the page has only a single form on it, you can access the form via login_html.form. Using .select(), select the username and password inputs and fill them with the username "zeus" and the password "ThunderDude":
form = login_html.form
form.select("input")[0]["value"] = "zeus"
form.select("input")[1]["value"] = "ThunderDude"
Now that the form is filled out, you can submit it with browser.submit(): profiles_page = browser.submit(form, login_page.url)
If you filled the form with the correct username and password, then profiles_page should actually point to the /profiles page. You can confirm this by printing
the title of the page assigned to profiles_page: print(profiles_page.soup.title)
You should see the following text displayed: <title>All Profiles</title>
If instead you see the text Log In or something else, then the form submission failed. When you’re ready, you can move on to the next section. Interact With Websites in Real
TimeSometimes you want to be able to fetch real-time data from a website that offers continually updated information. In the dark days before you learned Python programming, you had to sit in front of a browser, clicking the Refresh button to reload the page each time you wanted to check if updated content was available. But now
you can automate this process using the .get() method of the MechanicalSoup Browser object. Open your browser of choice and navigate to the URL http://olympus.realpython.org/dice. This /dice page simulates a roll of a six-sided die, updating the result each time you refresh the browser. Below, you’ll write a program that repeatedly scrapes the page for a new result. The first thing you need to do is determine which element on the page
contains the result of the die roll. Do this now by right-clicking anywhere on the page and selecting View page source. A little more than halfway down the HTML code is an <h2> tag that looks like this: The text of the <h2> tag might be different for you, but this is the page element you need for scraping the result. Let’s start by writing a simple program that opens the /dice page, scrapes the
result, and prints it to the console: import mechanicalsoup
browser = mechanicalsoup.Browser()
page = browser.get("http://olympus.realpython.org/dice")
tag = page.soup.select("#result")[0]
result = tag.text
print(f"The result of your dice roll is: {result}")
This example uses the BeautifulSoup object’s .select() method to find the element with id=result. The string "#result" that you pass to .select() uses the CSS ID selector # to indicate that result is an id value. To periodically get a new result, you’ll need to create a loop that loads the page at each step. So everything below the
line browser = mechanicalsoup.Browser() in the above code needs to go in the body of the loop. For this example, let’s get four rolls of the dice at ten-second intervals. To do that, the last line of your code needs to tell Python to pause running for ten seconds. You can do this with sleep() from Python’s time module. sleep() takes a single argument that represents the
amount of time to sleep in seconds. Here’s an example that illustrates how sleep() works: import time
print("I'm about to wait for five seconds...")
time.sleep(5)
print("Done waiting!")
When you run this code, you’ll see that the "Done waiting!" message isn’t displayed until 5 seconds have passed from when the first print() function was executed. For the die roll example, you’ll need to pass the number 10 to sleep(). Here’s the updated program: import time
import mechanicalsoup
browser = mechanicalsoup.Browser()
for i in range(4):
page = browser.get("http://olympus.realpython.org/dice")
tag = page.soup.select("#result")[0]
result = tag.text
print(f"The result of your dice roll is: {result}")
time.sleep(10)
When you run the program, you’ll immediately see the first result printed to
the console. After ten seconds, the second result is displayed, then the third, and finally the fourth. What happens after the fourth result is printed? The program continues running for another ten seconds before it finally stops! Well, of course it does—that’s what you told it to do! But it’s kind of a waste of time. You can stop it from doing this by using an if statement to run
time.sleep() for only the first three requests: import time
import mechanicalsoup
browser = mechanicalsoup.Browser()
for i in range(4):
page = browser.get("http://olympus.realpython.org/dice")
tag = page.soup.select("#result")[0]
result = tag.text
print(f"The result of your dice roll is: {result}")
# Wait 10 seconds if this isn't the last request
if i < 3:
time.sleep(10)
With techniques like this, you can scrape data from websites that periodically update their data. However, you should be aware that requesting a page multiple times in rapid succession can be seen as suspicious, or even malicious, use of a website. It’s even possible to crash a server with an excessive number of requests, so you can imagine that many websites are concerned about the volume of requests to
their server! Always check the Terms of Use and be respectful when sending multiple requests to a website. ConclusionAlthough it’s possible to parse data from the Web using tools in Python’s standard library, there are many tools on PyPI that can help simplify the process. In this tutorial, you learned
how to: - Request a web page using Python’s built-in
urllib module - Parse HTML using Beautiful Soup
- Interact with web forms using MechanicalSoup
- Repeatedly request data from a website to check for updates
Writing automated web scraping programs is fun, and the Internet has no shortage of content that can lead to all sorts of exciting projects. Just remember, not
everyone wants you pulling data from their web servers. Always check a website’s Terms of Use before you start scraping, and be respectful about how you time your web requests so that you don’t flood a server with traffic. Additional ResourcesFor more information on web scraping with Python, check
out the following resources: - Beautiful Soup: Build a Web Scraper With Python
- API Integration in Python
- Python & APIs: A Winning Combo for Reading Public Data
How do you scrape data from a website in Python?
To extract data using web scraping with python, you need to follow these basic steps:. Find the URL that you want to scrape.. Inspecting the Page.. Find the data you want to extract.. Write the code.. Run the code and extract the data.. Store the data in the required format.. Is it OK to scrape a website?
So is it legal or illegal? Web scraping and crawling aren't illegal by themselves. After all, you could scrape or crawl your own website, without a hitch. Startups love it because it's a cheap and powerful way to gather data without the need for partnerships.
Can you get in trouble for scraping a website?
In short, the action of web scraping isn't illegal. However there are some rules that need to be followed. Web scraping becomes illegal when non publicly available data becomes extracted.
Which is best for web scraping in Python?
Top 7 Python Web Scraping Tools For Data Scientists. 1| Beautiful Soup. Beautiful Soup is a Python library for pulling data out of HTML and XML files. ... . 3| MechanicalSoup. MechanicalSoup is a Python library for automating interaction with websites. ... . 4| Python Requests. ... . 5| Scrapy. ... . 6| Selenium.. |
