Tutorial: Using Motor With Tornado¶
A guide to using MongoDB and Tornado with Motor.
Contents
Tutorial Prerequisites¶
You can learn about MongoDB with the MongoDB Tutorial before you learn Motor.
Install pip and then do:
$ pip install tornado motor
Once done, the following should run in the Python shell without raising an exception:
>>> import motor.motor_tornado
This tutorial also assumes that a MongoDB instance is running on the default host and port. Assuming you have downloaded and installed MongoDB, you can start it like so:
$ mongod
Object Hierarchy¶
Motor, like PyMongo, represents data with a 4-level object hierarchy:
MotorClient
represents a mongod process, or a cluster of them. You explicitly create one of these client objects, connect it to a running mongod or mongods, and use it for the lifetime of your application.MotorDatabase
: Each mongod has a set of databases (distinct sets of data files on disk). You can get a reference to a database from a client.MotorCollection
: A database has a set of collections, which contain documents; you get a reference to a collection from a database.MotorCursor
: Executingfind()
on aMotorCollection
gets aMotorCursor
, which represents the set of documents matching a query.
Creating a Client¶
You typically create a single instance of MotorClient
at the time your
application starts up.
>>> client = motor.motor_tornado.MotorClient()
This connects to a mongod
listening on the default host and port. You can
specify the host and port like:
>>> client = motor.motor_tornado.MotorClient('localhost', 27017)
Motor also supports connection URIs:
>>> client = motor.motor_tornado.MotorClient('mongodb://localhost:27017')
Connect to a replica set like:
>>> client = motor.motor_tornado.MotorClient('mongodb://host1,host2/?replicaSet=my-replicaset-name')
Getting a Database¶
A single instance of MongoDB can support multiple independent databases. From an open client, you can get a reference to a particular database with dot-notation or bracket-notation:
>>> db = client.test_database
>>> db = client['test_database']
Creating a reference to a database does no I/O and does not require an
await
expression.
Tornado Application Startup Sequence¶
Now that we can create a client and get a database, we’re ready to start a Tornado application that uses Motor:
db = motor.motor_tornado.MotorClient().test_database
application = tornado.web.Application([
(r'/', MainHandler)
], db=db)
application.listen(8888)
tornado.ioloop.IOLoop.current().start()
There are two things to note in this code. First, the MotorClient
constructor doesn’t actually connect to the server; the client will
initiate a connection when you attempt the first operation.
Second, passing the database as the db
keyword argument to Application
makes it available to request handlers:
class MainHandler(tornado.web.RequestHandler):
def get(self):
db = self.settings['db']
It is a common mistake to create a new client object for every request; this comes at a dire performance cost. Create the client when your application starts and reuse that one client for the lifetime of the process, as shown in these examples.
The Tornado HTTPServer
class’s start()
method is a simple way to fork multiple web servers and use all of your
machine’s CPUs. However, you must create your MotorClient
after forking:
# Create the application before creating a MotorClient.
application = tornado.web.Application([
(r'/', MainHandler)
])
server = tornado.httpserver.HTTPServer(application)
server.bind(8888)
# Forks one process per CPU.
server.start(0)
# Now, in each child process, create a MotorClient.
application.settings['db'] = MotorClient().test_database
IOLoop.current().start()
For production-ready, multiple-CPU deployments of Tornado there are better
methods than HTTPServer.start()
. See Tornado’s guide to
Running and deploying.
Getting a Collection¶
A collection is a group of documents stored in MongoDB, and can be thought of as roughly the equivalent of a table in a relational database. Getting a collection in Motor works the same as getting a database:
>>> collection = db.test_collection
>>> collection = db['test_collection']
Just like getting a reference to a database, getting a reference to a
collection does no I/O and doesn’t require an await
expression.
Inserting a Document¶
As in PyMongo, Motor represents MongoDB documents with Python dictionaries. To
store a document in MongoDB, call insert_one()
in an
await
expression:
>>> async def do_insert():
... document = {'key': 'value'}
... result = await db.test_collection.insert_one(document)
... print('result %s' % repr(result.inserted_id))
...
>>>
>>> IOLoop.current().run_sync(do_insert)
result ObjectId('...')
A typical beginner’s mistake with Motor is to insert documents in a loop, not waiting for each insert to complete before beginning the next:
>>> for i in range(2000):
... db.test_collection.insert_one({'i': i})
In PyMongo this would insert each document in turn using a single socket, but
Motor attempts to run all the insert_one()
operations at once. This requires
up to max_pool_size
open sockets connected to MongoDB,
which taxes the client and server. To ensure instead that all inserts run in
sequence, use await
:
>>> async def do_insert():
... for i in range(2000):
... await db.test_collection.insert_one({'i': i})
...
>>> IOLoop.current().run_sync(do_insert)
See also
For better performance, insert documents in large batches with
insert_many()
:
>>> async def do_insert():
... result = await db.test_collection.insert_many(
... [{'i': i} for i in range(2000)])
... print('inserted %d docs' % (len(result.inserted_ids),))
...
>>> IOLoop.current().run_sync(do_insert)
inserted 2000 docs
Getting a Single Document With find_one()
¶
Use find_one()
to get the first document that
matches a query. For example, to get a document where the value for key “i” is
less than 1:
>>> async def do_find_one():
... document = await db.test_collection.find_one({'i': {'$lt': 1}})
... pprint.pprint(document)
...
>>> IOLoop.current().run_sync(do_find_one)
{'_id': ObjectId('...'), 'i': 0}
The result is a dictionary matching the one that we inserted previously.
The returned document contains an "_id"
, which was
automatically added on insert.
(We use pprint
here instead of print
to ensure the document’s key names
are sorted the same in your output as ours.)
Querying for More Than One Document¶
Use find()
to query for a set of documents.
find()
does no I/O and does not require an await
expression. It merely creates an MotorCursor
instance. The query is
actually executed on the server when you call to_list()
or execute an async for
loop.
To find all documents with “i” less than 5:
>>> async def do_find():
... cursor = db.test_collection.find({'i': {'$lt': 5}}).sort('i')
... for document in await cursor.to_list(length=100):
... pprint.pprint(document)
...
>>> IOLoop.current().run_sync(do_find)
{'_id': ObjectId('...'), 'i': 0}
{'_id': ObjectId('...'), 'i': 1}
{'_id': ObjectId('...'), 'i': 2}
{'_id': ObjectId('...'), 'i': 3}
{'_id': ObjectId('...'), 'i': 4}
A length
argument is required when you call to_list
to prevent Motor
from buffering an unlimited number of documents.
async for
¶
You can handle one document at a time in an async for
loop:
>>> async def do_find():
... c = db.test_collection
... async for document in c.find({'i': {'$lt': 2}}):
... pprint.pprint(document)
...
>>> IOLoop.current().run_sync(do_find)
{'_id': ObjectId('...'), 'i': 0}
{'_id': ObjectId('...'), 'i': 1}
You can apply a sort, limit, or skip to a query before you begin iterating:
>>> async def do_find():
... cursor = db.test_collection.find({'i': {'$lt': 4}})
... # Modify the query before iterating
... cursor.sort('i', -1).skip(1).limit(2)
... async for document in cursor:
... pprint.pprint(document)
...
>>> IOLoop.current().run_sync(do_find)
{'_id': ObjectId('...'), 'i': 2}
{'_id': ObjectId('...'), 'i': 1}
The cursor does not actually retrieve each document from the server individually; it gets documents efficiently in large batches.
Counting Documents¶
Use count_documents()
to determine the number of
documents in a collection, or the number of documents that match a query:
>>> async def do_count():
... n = await db.test_collection.count_documents({})
... print('%s documents in collection' % n)
... n = await db.test_collection.count_documents({'i': {'$gt': 1000}})
... print('%s documents where i > 1000' % n)
...
>>> IOLoop.current().run_sync(do_count)
2000 documents in collection
999 documents where i > 1000
Updating Documents¶
replace_one()
changes a document. It requires two
parameters: a query that specifies which document to replace, and a
replacement document. The query follows the same syntax as for find()
or
find_one()
. To replace a document:
>>> async def do_replace():
... coll = db.test_collection
... old_document = await coll.find_one({'i': 50})
... print('found document: %s' % pprint.pformat(old_document))
... _id = old_document['_id']
... result = await coll.replace_one({'_id': _id}, {'key': 'value'})
... print('replaced %s document' % result.modified_count)
... new_document = await coll.find_one({'_id': _id})
... print('document is now %s' % pprint.pformat(new_document))
...
>>> IOLoop.current().run_sync(do_replace)
found document: {'_id': ObjectId('...'), 'i': 50}
replaced 1 document
document is now {'_id': ObjectId('...'), 'key': 'value'}
You can see that replace_one()
replaced everything in the old document
except its _id
with the new document.
Use update_one()
with MongoDB’s modifier operators to
update part of a document and leave the
rest intact. We’ll find the document whose “i” is 51 and use the $set
operator to set “key” to “value”:
>>> async def do_update():
... coll = db.test_collection
... result = await coll.update_one({'i': 51}, {'$set': {'key': 'value'}})
... print('updated %s document' % result.modified_count)
... new_document = await coll.find_one({'i': 51})
... print('document is now %s' % pprint.pformat(new_document))
...
>>> IOLoop.current().run_sync(do_update)
updated 1 document
document is now {'_id': ObjectId('...'), 'i': 51, 'key': 'value'}
“key” is set to “value” and “i” is still 51.
update_one()
only affects the first document it finds, you can
update all of them with update_many()
:
await coll.update_many({'i': {'$gt': 100}},
{'$set': {'key': 'value'}})
Removing Documents¶
delete_one()
takes a query with the same syntax as
find()
.
delete_one()
immediately removes the first returned matching document.
>>> async def do_delete_one():
... coll = db.test_collection
... n = await coll.count_documents({})
... print('%s documents before calling delete_one()' % n)
... result = await db.test_collection.delete_one({'i': {'$gte': 1000}})
... print('%s documents after' % (await coll.count_documents({})))
...
>>> IOLoop.current().run_sync(do_delete_one)
2000 documents before calling delete_one()
1999 documents after
delete_many()
takes a query with the same syntax as
find()
.
delete_many()
immediately removes all matching documents.
>>> async def do_delete_many():
... coll = db.test_collection
... n = await coll.count_documents({})
... print('%s documents before calling delete_many()' % n)
... result = await db.test_collection.delete_many({'i': {'$gte': 1000}})
... print('%s documents after' % (await coll.count_documents({})))
...
>>> IOLoop.current().run_sync(do_delete_many)
1999 documents before calling delete_many()
1000 documents after
Commands¶
All operations on MongoDB are implemented internally as commands. Run them using
the command()
method on
MotorDatabase
:
.. doctest:: after-inserting-2000-docs
>>> from bson import SON
>>> async def use_distinct_command():
... response = await db.command(SON([("distinct", "test_collection"),
... ("key", "i")]))
...
>>> IOLoop.current().run_sync(use_distinct_command)
Since the order of command parameters matters, don’t use a Python dict to pass
the command’s parameters. Instead, make a habit of using bson.SON
,
from the bson
module included with PyMongo.
Many commands have special helper methods, such as
create_collection()
or
aggregate()
, but these are just conveniences atop
the basic command()
method.
Further Reading¶
The handful of classes and methods introduced here are sufficient for daily
tasks. The API documentation for MotorClient
, MotorDatabase
,
MotorCollection
, and MotorCursor
provides a
reference to Motor’s complete feature set.
Learning to use the MongoDB driver is just the beginning, of course. For in-depth instruction in MongoDB itself, see The MongoDB Manual.