The Minimalist Twitter API for Python is a Python API for Twitter, everyone's favorite Web 2.0 Facebook-style status updater for people on the go.
Also included is a twitter command-line tool for getting your friends' tweets and setting your own tweet from the safety and security of your favorite shell and an IRC bot that can announce Twitter updates to an IRC channel.
For more information, after installing the twitter
package:
- import the
twitter
package and run help() on it - run
twitter -h
for command-line tool help
The command-line tool lets you do some awesome things:
- view your tweets, recent replies, and tweets in lists
- view the public timeline
- follow and unfollow (leave) friends
- various output formats for tweet information
The bottom line: type twitter
, receive tweets.
The IRC bot is associated with a twitter account (either your own account or an account you create for the bot). The bot announces all tweets from friends it is following. It can be made to follow or leave friends through IRC /msg commands.
twitter-log
is a simple command-line tool that dumps all public
tweets from a given user in a simple text format. It is useful to get
a complete offsite backup of all your tweets. Run twitter-log
and
read the instructions.
twitter-archiver will log all the tweets posted by any user since they started posting. twitter-follow will print a list of all of all the followers of a user (or all the users that user follows).
The Twitter and TwitterStream classes are the key to building your own Twitter-enabled applications.
The minimalist yet fully featured Twitter API class.
Get RESTful data by accessing members of this class. The result is decoded python objects (lists and dicts).
The Twitter API is documented at:
https://dev.twitter.com/overview/documentation
Examples:
from twitter import *
t = Twitter(
auth=OAuth(token, token_key, con_secret, con_secret_key))
# Get your "home" timeline
t.statuses.home_timeline()
# Get a particular friend's timeline
t.statuses.user_timeline(screen_name="billybob")
# to pass in GET/POST parameters, such as `count`
t.statuses.home_timeline(count=5)
# to pass in the GET/POST parameter `id` you need to use `_id`
t.statuses.oembed(_id=1234567890)
# Update your status
t.statuses.update(
status="Using @sixohsix's sweet Python Twitter Tools.")
# Send a direct message
t.direct_messages.new(
user="billybob",
text="I think yer swell!")
# Get the members of tamtar's list "Things That Are Rad"
t.lists.members(owner_screen_name="tamtar", slug="things-that-are-rad")
# An *optional* `_timeout` parameter can also be used for API
# calls which take much more time than normal or twitter stops
# responding for some reason:
t.users.lookup(
screen_name=','.join(A_LIST_OF_100_SCREEN_NAMES), _timeout=1)
# Overriding Method: GET/POST
# you should not need to use this method as this library properly
# detects whether GET or POST should be used, Nevertheless
# to force a particular method, use `_method`
t.statuses.oembed(_id=1234567890, _method='GET')
# Send images along with your tweets:
# - first just read images from the web or from files the regular way:
with open("example.png", "rb") as imagefile:
imagedata = imagefile.read()
# - then upload medias one by one on Twitter's dedicated server
# and collect each one's id:
t_up = Twitter(domain='upload.twitter.com',
auth=OAuth(token, token_key, con_secret, con_secret_key))
id_img1 = t_up.media.upload(media=imagedata)["media_id_string"]
id_img2 = t_up.media.upload(media=imagedata)["media_id_string"]
# - finally send your tweet with the list of media ids:
t.statuses.update(status="PTT ★", media_ids=",".join([id_img1, id_img2]))
# Or send a tweet with an image (or set a logo/banner similarily)
# using the old deprecated method that will probably disappear some day
params = {"media[]": imagedata, "status": "PTT ★"}
# Or for an image encoded as base64:
params = {"media[]": base64_image, "status": "PTT ★", "_base64": True}
t.statuses.update_with_media(**params)
Searching Twitter:
# Search for the latest tweets about #pycon
t.search.tweets(q="#pycon")
Simply create the Twitter
instance with the argument retry=True
, then the
HTTP error codes 429, 502, 503 and 504 will cause a retry of the last request.
If retry is an integer, it defines the number of retries attempted.
Twitter API calls return decoded JSON. This is converted into a bunch of Python lists, dicts, ints, and strings. For example:
x = twitter.statuses.home_timeline()
# The first 'tweet' in the timeline
x[0]
# The screen name of the user who wrote the first 'tweet'
x[0]['user']['screen_name']
If you prefer to get your Twitter data in XML format, pass format="xml" to the Twitter object when you instantiate it:
twitter = Twitter(format="xml")
The output will not be parsed in any way. It will be a raw string of XML.
The TwitterStream object is an interface to the Twitter Stream API. This can be used pretty much the same as the Twitter class except the result of calling a method will be an iterator that yields objects decoded from the stream. For example::
twitter_stream = TwitterStream(auth=OAuth(...))
iterator = twitter_stream.statuses.sample()
for tweet in iterator:
...do something with this tweet...
Per default the TwitterStream
object uses
public streams.
If you want to use one of the other
streaming APIs, specify the URL
manually:
- Public streams: stream.twitter.com
- User streams: userstream.twitter.com
- Site streams: sitestream.twitter.com
Note that you require the proper permissions to access these streams. E.g. for direct messages your application needs the "Read, Write & Direct Messages" permission.
The following example demonstrates how to retrieve all new direct messages from the user stream:
auth = OAuth(
consumer_key='[your consumer key]',
consumer_secret='[your consumer secret]',
token='[your token]',
token_secret='[your token secret]'
)
twitter_userstream = TwitterStream(auth=auth, domain='userstream.twitter.com')
for msg in twitter_userstream.user():
if 'direct_message' in msg:
print msg['direct_message']['text']
The iterator will yield until the TCP connection breaks. When the
connection breaks, the iterator yields {'hangup': True}
, and
raises StopIteration
if iterated again.
Similarly, if the stream does not produce heartbeats for more than
90 seconds, the iterator yields {'hangup': True, 'heartbeat_timeout': True}
, and raises StopIteration
if
iterated again.
The timeout
parameter controls the maximum time between
yields. If it is nonzero, then the iterator will yield either
stream data or {'timeout': True}
within the timeout period. This
is useful if you want your program to do other stuff in between
waiting for tweets.
The block
parameter sets the stream to be fully non-blocking. In
this mode, the iterator always yields immediately. It returns
stream data, or None
. Note that timeout
supercedes this
argument, so it should also be set None
to use this mode,
and non-blocking can potentially lead to 100% CPU usage.
Response from a twitter request. Behaves like a list or a string (depending on requested format) but it has a few other interesting attributes.
headers
gives you access to the response headers as an
httplib.HTTPHeaders instance. You can do
response.headers.get('h')
to retrieve a header.
You can authenticate with Twitter in three ways: NoAuth, OAuth, or OAuth2 (app-only). Get help() on these classes to learn how to use them.
OAuth and OAuth2 are probably the most useful.
Visit the Twitter developer page and create a new application:
https://dev.twitter.com/apps/new
This will get you a CONSUMER_KEY and CONSUMER_SECRET.
When users run your application they have to authenticate your app with their Twitter account. A few HTTP calls to twitter are required to do this. Please see the twitter.oauth_dance module to see how this is done. If you are making a command-line app, you can use the oauth_dance() function directly.
Performing the "oauth dance" gets you an ouath token and oauth secret that authenticate the user with Twitter. You should save these for later so that the user doesn't have to do the oauth dance again.
read_token_file and write_token_file are utility methods to read and write OAuth token and secret key values. The values are stored as strings in the file. Not terribly exciting.
Finally, you can use the OAuth authenticator to connect to Twitter. In code it all goes like this:
from twitter import *
MY_TWITTER_CREDS = os.path.expanduser('~/.my_app_credentials')
if not os.path.exists(MY_TWITTER_CREDS):
oauth_dance("My App Name", CONSUMER_KEY, CONSUMER_SECRET,
MY_TWITTER_CREDS)
oauth_token, oauth_secret = read_token_file(MY_TWITTER_CREDS)
twitter = Twitter(auth=OAuth(
oauth_token, oauth_token_secret, CONSUMER_KEY, CONSUMER_SECRET))
# Now work with Twitter
twitter.statuses.update(status='Hello, world!')
Twitter only supports the application-only flow of OAuth2 for certain API endpoints. This OAuth2 authenticator only supports the application-only flow right now.
To authenticate with OAuth2, visit the Twitter developer page and create a new application:
https://dev.twitter.com/apps/new
This will get you a CONSUMER_KEY and CONSUMER_SECRET.
Exchange your CONSUMER_KEY and CONSUMER_SECRET for a bearer token using the oauth2_dance function.
Finally, you can use the OAuth2 authenticator and your bearer token to connect to Twitter. In code it goes like this::
twitter = Twitter(auth=OAuth2(bearer_token=BEARER_TOKEN))
# Now work with Twitter
twitter.search.tweets(q='keyword')
Python Twitter Tools are released under an MIT License.