What is Python?
Python, the Swiss Army knife of today’s dynamically typed languages, has comprehensive support for common data manipulation and processing tasks. Python’s native dictionary and list data types make it second only to JavaScript for manipulating JSON documents — and well-suited to working with BSON. PyMongo, the standard MongoDB driver library for Python, is easy to use and offers an intuitive API for accessing databases, collections, and documents.
Objects retrieved from MongoDB through PyMongo are compatible with dictionaries and lists, so we can easily manipulate, iterate, and print them.
How MongoDB stores data
MongoDB stores data in JSON-like documents:
# Mongodb document [JSON-style]
document_1 = {
"_id" : "BF00001CFOOD",
"item_name" : "Bread",
"quantity" : 2,
"ingredients" : "all-purpose flour"
}
Python dictionaries look like:
# python dictionary
dict_1 = {
"item_name" : "blender",
"max_discount" : "10%",
"batch_number" : "RR450020FRG",
"price" : 340
}
Read on for an overview of how to get started and deliver on the potential of this powerful combination.
Prerequisites
Download and install Python on your machine. To confirm if your installation is right, type python --version
in your command line terminal. You should get something similar to:
Python 3.9.12
You can follow the python MongoDB examples in this tutorial even if you are new to Python.
We recommend that you set up a MongoDB Atlas free tier cluster for this tutorial.
Connecting Python and MongoDB Atlas
PyMongo has a set of packages for Python MongoDB interaction. For the following tutorial, start by creating a virtual environment, and activate it.
python -m venv env
source env/bin/activate
Now that you are in your virtual environment, you can install PyMongo. In your terminal, type:
python -m pip install "pymongo[srv]"
Now, we can use PyMongo as a Python MongoDB library in our code with an import statement.
Creating a MongoDB database in Python
The first step to connect Python to Atlas is to create a cluster. You can follow the instructions from the documentation to learn how to create and set up your cluster.
Next, create a file named pymongo_get_database.py
in any folder to write PyMongo code. You can use any simple text editor, like Visual Studio Code.
Create the mongodb client by adding the following:
from pymongo import MongoClient
def get_database[]:
# Provide the mongodb atlas url to connect python to mongodb using pymongo
CONNECTION_STRING = "mongodb+srv://user:/myFirstDatabase"
# Create a connection using MongoClient. You can import MongoClient or use pymongo.MongoClient
client = MongoClient[CONNECTION_STRING]
# Create the database for our example [we will use the same database throughout the tutorial
return client['user_shopping_list']
# This is added so that many files can reuse the function get_database[]
if __name__ == "__main__":
# Get the database
dbname = get_database[]
To create a MongoClient, you will need a connection string to your database. If you are using Atlas, you can follow the steps from the documentation to get that connection string. Use the connection_string
to create the mongoclient and get the MongoDB database connection. Change the username, password, and cluster name.
In this python mongodb tutorial, we will create a shopping list
and add a few items. For this, we created a database user_shopping_list
.
MongoDB doesn’t create a database until you have collections and documents in it. So, let’s create a collection next.
Creating a collection in Python
To create a collection, pass the collection name to the database. In a new file called pymongo_test_insert.py
file, add the following code.
# Get the database using the method we defined in pymongo_test_insert file
from pymongo_get_database import get_database
dbname = get_database[]
collection_name = dbname["user_1_items"]
This creates a collection named user_1_items
in the user_shopping_list
database.
Inserting documents in Python
For inserting many documents at once, use the pymongo insert_many[]
method.
item_1 = {
"_id" : "U1IT00001",
"item_name" : "Blender",
"max_discount" : "10%",
"batch_number" : "RR450020FRG",
"price" : 340,
"category" : "kitchen appliance"
}
item_2 = {
"_id" : "U1IT00002",
"item_name" : "Egg",
"category" : "food",
"quantity" : 12,
"price" : 36,
"item_description" : "brown country eggs"
}
collection_name.insert_many[[item_1,item_2]]
Let’s insert a third document without specifying the _id
field. This time, we add a field of data type ‘date’. To add date using PyMongo, use the Python dateutil
package.
Start by installing the package using the following command:
python -m pip install python-dateutil
Add the following to pymongo_test_insert.py
:
from dateutil import parser
expiry_date = '2021-07-13T00:00:00.000Z'
expiry = parser.parse[expiry_date]
item_3 = {
"item_name" : "Bread",
"quantity" : 2,
"ingredients" : "all-purpose flour",
"expiry_date" : expiry
}
collection_name.insert_one[item_3]
We use the insert_one[]
method to insert a
single document.
Open the command line and navigate to the folder where you have saved pymongo_test_insert.py.
Execute the file using the
python pymongo_test_insert.py
command.
Let’s connect to MongoDB Atlas UI and check what we have so far.
Log in to your Atlas cluster and click on the collections button.
On the left side, you can see the database and collection name that we created. If you click on the collection name, you can view the data as well:
The _id
field is of ObjectId type by default. If we don’t specify the _id
field, MongoDB generates the same. Not all fields present in one document are
present in others. But MongoDB doesn’t stop you from entering data — this is the essence of a schemaless database.
If we insert item_3
again, MongoDB will insert a new document, with a new _id
value. However, the first two inserts will throw an error because of the _id
field, the unique identifier.
Querying in Python
Let’s view all the documents together using find[]. For that, we will create a separate file pymongo_test_query.py
:
# Get the database using the method we defined in pymongo_test_insert file
from pymongo_get_database import get_database
dbname = get_database[]
# Create a new collection
collection_name = dbname["user_1_items"]
item_details = collection_name.find[]
for item in item_details:
# This does not give a very readable output
print[item]
Open
the command line and navigate to the folder where you have saved pymongo_test_query.py
. Execute the file using the python pymongo_test_query.py
command.
We get the list of dictionary object as the output:
We can view the data but the format is not all that great. So, let’s print the item names and their category by replacing the print
line with the following:
print[item['item_name'], item['category']]
Although MongoDB gets the entire data, we get a Python ‘KeyError’ on the third document.
To handle missing data errors in python, use pandas.DataFrames. DataFrames are 2D data structures used for data processing tasks. Pymongo find[] method returns dictionary objects which can be converted into a dataframe in a single line of code.
Install pandas library as:
python -m pip install pandas
Now import the pandas
library by adding the following line at the top of the file:
from pandas import DataFrame
And replace the code in the loop with the following to handle KeyError in one step:
# convert the dictionary objects to dataframe
items_df = DataFrame[item_details]
# see the magic
print[items_df]
The errors are replaced by NaN and NaT for the missing values.
Indexing in Python MongoDB
The number of documents and collections in a real-world database always keeps increasing. It can take a very long time to search for specific documents — for example, documents that have “all-purpose flour” among their ingredients — in a very large collection. Indexes make database search faster and more efficient, and reduce the cost of querying on operations such as sort, count, and match.
MongoDB defines indexes at the collection level.
For the index to make more sense, add more documents to our collection. Insert
many documents at once using the insert_many[]
method. For sample documents, copy the code from github and execute python pymongo_test_insert_more_items.py
in your terminal.
Let’s say we want the items that belong to the category ‘food’:
item_details = collection_name.find[{"category" : "food"}]
To execute the above query, MongoDB has to scan all the documents. To verify this, download Compass. Connect to your cluster using the connection string. Open the collection and go to the Explain Plan tab. In ‘filter’, give the above criteria and view the results:
Note that the query scans 14 documents to get five results.
Let's create a
single index on the ‘category’ field. In a new file named pymongo_index.py
, add the following code.
# Get the database using the method we defined in pymongo_test_insert file
from pymongo_get_database import get_database
dbname = get_database[]
# Create a new collection
collection_name = dbname["user_1_items"]
# Create an index on the collection
category_index = collection_name.create_index["category"]
Explain the same filter again on Compass UI:
This time, only five documents are scanned because of the category index. We don’t see a significant difference in execution time because of the small number of documents. But we see a huge reduction in the number of documents scanned for the query. Indexes help in performance optimization for aggregations, as well. Aggregations are out of scope for this tutorial, but here’s an overview.