Authentication and Authorization

Introduction to Security

Authentication is the mechanism whereby systems may securely identify their users. Eve supports several authentication schemes: Basic Authentication, Token Authentication, HMAC Authentication. OAuth2 integration is easily accomplished.

Authorization is the mechanism by which a system determines what level of access a particular (authenticated) user should have access to resources controlled by the system. In Eve, you can restrict access to all API endpoints, or only some of them. You can protect some HTTP verbs while leaving others open. For example, you can allow public read-only access while leaving item creation and edition restricted to authorized users only. You can also allow GET access for certain requests and POST access for others by checking the method parameter. There is also support for role-based access control.

Security is one of those areas where customization is very important. This is why you are provided with a handful of base authentication classes. They implement the basic authentication mechanism and must be subclassed in order to implement authorization logic. No matter which authentication scheme you pick the only thing that you need to do in your subclass is override the check_auth() method.

Global Authentication

To enable authentication for your API just pass the custom auth class on app instantiation. In our example we’re going to use the BasicAuth base class, which implements the Basic Authentication scheme:

from eve.auth import BasicAuth

class MyBasicAuth(BasicAuth):
    def check_auth(self, username, password, allowed_roles, resource,
                   method):
        return username == 'admin' and password == 'secret'

app = Eve(auth=MyBasicAuth)
app.run()

All your API endpoints are now secured, which means that a client will need to provide the correct credentials in order to consume the API:

$ curl -i http://example.com
HTTP/1.1 401 UNAUTHORIZED
Please provide proper credentials.

$ curl -H "Authorization: Basic YWRtaW46c2VjcmV0" -i http://example.com
HTTP/1.1 200 OK

By default access is restricted to all endpoints for all HTTP verbs (methods), effectively locking down the whole API.

But what if your authentication logic is more complex, and you only want to secure some endpoints or apply different logics depending on the endpoint being consumed? You could get away with just adding logic to your authentication class, maybe with something like this:

class MyBasicAuth(BasicAuth):
    def check_auth(self, username, password, allowed_roles, resource, method):
        if resource in ('zipcodes', 'countries'):
            # 'zipcodes' and 'countries' are public
            return True
        else:
            # all the other resources are secured
            return username == 'admin' and password == 'secret'

If needed, this approach also allows to take the request method into consideration, for example to allow GET requests for everyone while forcing validation on edits (POST, PUT, PATCH, DELETE).

Endpoint-level Authentication

The one class to bind them all approach seen above is probably good for most use cases but as soon as authorization logic gets more complicated it could easily lead to complex and unmanageable code, something you don’t really want to have when dealing with security.

Wouldn’t it be nice if we could have specialized auth classes that we could freely apply to selected endpoints? This way the global level auth class, the one passed to the Eve constructor as seen above, would still be active on all endpoints except those where different authorization logic is needed. Alternatively, we could even choose to not provide a global auth class, effectively making all endpoints public, except the ones we want protected. With a system like this we could even choose to have some endpoints protected with, say, Basic Authentication while others are secured with Token, or HMAC Authentication!

Well, turns out this is actually possible by simply enabling the resource-level authentication setting when we are defining the API domain.

DOMAIN = {
    'people': {
        'authentication': MySuperCoolAuth,
        ...
        },
    'invoices': ...
    }

And that’s it. The people endpoint will now be using the MySuperCoolAuth class for authentication, while the invoices endpoint will be using the general-purpose auth class if provided or else it will just be open to the public.

There are other features and options that you can use to reduce complexity in your auth classes, especially (but not only) when using the global level authentication system. Lets review them.

Global Endpoint Security

You might want a public read-only API where only authorized users can write, edit and delete. You can achieve that by using the PUBLIC_METHODS and PUBLIC_ITEM_METHODS global settings. Add the following to your settings.py:

PUBLIC_METHODS = ['GET']
PUBLIC_ITEM_METHODS = ['GET']

And run your API. POST, PATCH and DELETE are still restricted, while GET is publicly available at all API endpoints. PUBLIC_METHODS refers to resource endpoints, like /people, while PUBLIC_ITEM_METHODS refers to individual items like /people/id.

Custom Endpoint Security

Suppose that you want to allow public read access to only certain resources. You do that by declaring public methods at resource level, while declaring the API domain:

DOMAIN = {
    'people': {
        'public_methods': ['GET'],
        'public_item_methods': ['GET'],
        },
    }

Be aware that, when present, resource settings override global settings. You can use this to your advantage. Suppose that you want to grant read access to all endpoints with the only exception of /invoices. You first open read access for all endpoints:

PUBLIC_METHODS = ['GET']
PUBLIC_ITEM_METHODS = ['GET']

Then you protect the private endpoint:

DOMAIN = {
    'invoices': {
        'public_methods': [],
        'public_item_methods': [],
        }
    }

Effectively making invoices a restricted resource.

Basic Authentication

The eve.auth.BasicAuth class allows the implementation of Basic Authentication (RFC2617). It should be subclassed in order to implement custom authentication.

Basic Authentication with bcrypt

Encoding passwords with bcrypt is a great idea. It comes at the cost of performance, but that’s precisely the point, as slow encoding means very good resistance to brute-force attacks. For a faster (and less safe) alternative, see the SHA1/MAC snippet further below.

This script assumes that user accounts are stored in an accounts MongoDB collection, and that passwords are stored as bcrypt hashes. All API resources/methods will be secured unless they are made explicitly public.

Please note

You will need to install py-bcrypt for this to work.

# -*- coding: utf-8 -*-

"""
    Auth-BCrypt
    ~~~~~~~~~~~

    Securing an Eve-powered API with Basic Authentication (RFC2617).

    You will need to install py-bcrypt: ``pip install py-bcrypt``

    This snippet by Nicola Iarocci can be used freely for anything you like.
    Consider it public domain.
"""

import bcrypt
from eve import Eve
from eve.auth import BasicAuth
from flask import current_app as app

class BCryptAuth(BasicAuth):
    def check_auth(self, username, password, allowed_roles, resource, method):
        # use Eve's own db driver; no additional connections/resources are used
        accounts = app.data.driver.db['accounts']
        account = accounts.find_one({'username': username})
        return account and \
            bcrypt.hashpw(password, account['password']) == account['password']


if __name__ == '__main__':
    app = Eve(auth=BCryptAuth)
    app.run()

Basic Authentication with SHA1/HMAC

This script assumes that user accounts are stored in an accounts MongoDB collection, and that passwords are stored as SHA1/HMAC hashes. All API resources/methods will be secured unless they are made explicitly public.

# -*- coding: utf-8 -*-

"""
    Auth-SHA1/HMAC
    ~~~~~~~~~~~~~~

    Securing an Eve-powered API with Basic Authentication (RFC2617).

    Since we are using werkzeug we don't need any extra import (werkzeug being
    one of Flask/Eve prerequisites).

    This snippet by Nicola Iarocci can be used freely for anything you like.
    Consider it public domain.
"""

from eve import Eve
from eve.auth import BasicAuth
from werkzeug.security import check_password_hash
from flask import current_app as app

class Sha1Auth(BasicAuth):
    def check_auth(self, username, password, allowed_roles, resource, method):
        # use Eve's own db driver; no additional connections/resources are used
        accounts = app.data.driver.db['accounts']
        account = accounts.find_one({'username': username})
        return account and \
            check_password_hash(account['password'], password)


if __name__ == '__main__':
    app = Eve(auth=Sha1Auth)
    app.run()

Token-Based Authentication

Token-based authentication can be considered a specialized version of Basic Authentication. The Authorization header tag will contain the auth token as the username, and no password.

This script assumes that user accounts are stored in an accounts MongoDB collection. All API resources/methods will be secured unless they are made explicitly public (by fiddling with some settings you can open one or more resources and/or methods to public access -see docs).

# -*- coding: utf-8 -*-

"""
    Auth-Token
    ~~~~~~~~~~

    Securing an Eve-powered API with Token based Authentication.

    This snippet by Nicola Iarocci can be used freely for anything you like.
    Consider it public domain.
"""

from eve import Eve
from eve.auth import TokenAuth
from flask import current_app as app

class TokenAuth(TokenAuth):
    def check_auth(self, token, allowed_roles, resource, method):
        """For the purpose of this example the implementation is as simple as
        possible. A 'real' token should probably contain a hash of the
        username/password combo, which should then be validated against the account
        data stored on the DB.
        """
        # use Eve's own db driver; no additional connections/resources are used
        accounts = app.data.driver.db['accounts']
        return accounts.find_one({'token': token})


if __name__ == '__main__':
    app = Eve(auth=TokenAuth)
    app.run()

HMAC Authentication

The eve.auth.HMACAuth class allows for custom, Amazon S3-like, HMAC (Hash Message Authentication Code) authentication, which is basically a very secure custom authentication scheme built around the Authorization header.

How HMAC Authentication Works

The server provides the client with a user id and a secret key through some out-of-band technique (e.g., the service sends the client an e-mail containing the user id and secret key). The client will use the supplied secret key to sign all requests.

When the client wants to send a request, he builds the complete request and then, using the secret key, computes a hash over the complete message body (and optionally some of the message headers if required)

Next, the client adds the computed hash and his userid to the message in the Authorization header:

Authorization: johndoe:uCMfSzkjue+HSDygYB5aEg==

and sends it to the service. The service retrieves the userid from the message header and searches the private key for that user in its own database. Next it computes the hash over the message body (and selected headers) using the key to generate its hash. If the hash the client sends matches the hash the server computes, then the server knows the message was sent by the real client and was not altered in any way.

Really the only tricky part is sharing a secret key with the user and keeping that secure. That is why some services allow for generation of shared keys with a limited life time so you can give the key to a third party to temporarily work on your behalf. This is also the reason why the secret key is generally provided through out-of-band channels (often a webpage or, as said above, an email or plain old paper).

The eve.auth.HMACAuth class also support access roles.

HMAC Example

The snippet below can also be found in the examples/security folder of the Eve repository.

from eve import Eve
from eve.auth import HMACAuth
from flask import current_app as app
from hashlib import sha1
import hmac


class HMACAuth(HMACAuth):
    def check_auth(self, userid, hmac_hash, headers, data, allowed_roles,
                   resource, method):
        # use Eve's own db driver; no additional connections/resources are
        # used
        accounts = app.data.driver.db['accounts']
        user = accounts.find_one({'userid': userid})
        if user:
            secret_key = user['secret_key']
        # in this implementation we only hash request data, ignoring the
        # headers.
        return user and \
            hmac.new(str(secret_key), str(data), sha1).hexdigest() == \
                hmac_hash


if __name__ == '__main__':
    app = Eve(auth=HMACAuth)
    app.run()

Role Based Access Control

The code snippets above deliberately ignore the allowed_roles parameter. You can use this parameter to restrict access to authenticated users who also have been assigned specific roles.

First, you would use the new ALLOWED_ROLES and ALLOWED_ITEM_ROLES global settings (or the corresponding allowed_roles and allowed_item_roles resource settings).

ALLOWED_ROLES = ['admin']

Then your subclass would implement the authorization logic by making good use of the aforementioned allowed_roles parameter.

The snippet below assumes that user accounts are stored in an accounts MongoDB collection, that passwords are stored as SHA1/HMAC hashes and that user roles are stored in a ‘roles’ array. All API resources/methods will be secured unless they are made explicitly public.

# -*- coding: utf-8 -*-

"""
    Auth-SHA1/HMAC-Roles
    ~~~~~~~~~~~~~~~~~~~~

    Securing an Eve-powered API with Basic Authentication (RFC2617) and user
    roles.

    Since we are using werkzeug we don't need any extra import (werkzeug being
    one of Flask/Eve prerequisites).

    This snippet by Nicola Iarocci can be used freely for anything you like.
    Consider it public domain.
"""

from eve import Eve
from eve.auth import BasicAuth
from werkzeug.security import check_password_hash
from flask import current_app as app

class RolesAuth(BasicAuth):
    def check_auth(self, username, password, allowed_roles, resource, method):
        # use Eve's own db driver; no additional connections/resources are used
        accounts = app.data.driver.db['accounts']
        lookup = {'username': username}
        if allowed_roles:
            # only retrieve a user if his roles match ``allowed_roles``
            lookup['roles'] = {'$in': allowed_roles}
        account = accounts.find_one(lookup)
        return account and check_password_hash(account['password'], password)


if __name__ == '__main__':
    app = Eve(auth=RolesAuth)
    app.run()

User-Restricted Resource Access

When this feature is enabled, each stored document is associated with the account that created it. This allows the API to transparently serve only account-created documents on all kinds of requests: read, edit, delete and of course create. User authentication needs to be enabled for this to work properly.

At the global level this feature is enabled by setting AUTH_FIELD and locally (at the endpoint level) by setting auth_field. These properties define the name of the field used to store the id of the user who created the document. So for example by setting AUTH_FIELD to user_id, you are effectively (and transparently to the user) adding a user_id field to every stored document. This will then be used to retrieve/edit/delete documents stored by the user.

But how do you set the auth_field value? By invoking the set_request_auth_value() class method. Let us revise our BCrypt-authentication example from above:

 # -*- coding: utf-8 -*-

 """
     Auth-BCrypt
     ~~~~~~~~~~~

     Securing an Eve-powered API with Basic Authentication (RFC2617).

     You will need to install py-bcrypt: ``pip install py-bcrypt``

     This snippet by Nicola Iarocci can be used freely for anything you like.
     Consider it public domain.
 """

 import bcrypt
 from eve import Eve
 from eve.auth import BasicAuth


 class BCryptAuth(BasicAuth):
     def check_auth(self, username, password, allowed_roles, resource, method):
         # use Eve's own db driver; no additional connections/resources are used
         accounts = app.data.driver.db['accounts']
         account = accounts.find_one({'username': username})
         # set 'auth_field' value to the account's ObjectId
         # (instead of _id, you might want to use ID_FIELD)
         if account and '_id' in account:
             self.set_request_auth_value(account['_id'])
         return account and \
             bcrypt.hashpw(password, account['password']) == account['password']


 if __name__ == '__main__':
     app = Eve(auth=BCryptAuth)
     app.run()

Auth-driven Database Access

Custom authentication classes can also set the database that should be used when serving the active request.

Normally you either use a single database for the whole API or you configure which database each endpoint consumes by setting mongo_prefix to the desired value (see Resource / Item Endpoints).

However, you might opt to select the target database based on the active token, user or client. This is handy if your use-case includes user-dedicated database instances. All you have to do is set invoke the set_mongo_prefix() method when authenticating the request.

A trivial example would be:

from eve.auth import BasicAuth

class MyBasicAuth(BasicAuth):
    def check_auth(self, username, password, allowed_roles, resource, method):
        if username == 'user1':
            self.set_mongo_prefix('MONGO1')
        elif username == 'user2':
            self.set_mongo_prefix('MONGO2')
        else:
            # serve all other users from the default db.
            self.set_mongo_prefix(None)
        return username is not None and password == 'secret'

app = Eve(auth=MyBasicAuth)
app.run()

The above class will serve user1 with data coming from the database which configuration settings are prefixed by MONGO1 in settings.py. Same happens with user2 and MONGO2 while all other users are served with the default database.

Since values set by set_mongo_prefix() have precedence over both default and endpoint-level mongo_prefix settings, what happens here is that the two users will always be served from their reserved databases, no matter the eventual database configuration for the endpoint.

OAuth2 Integration

Since you have total control over the Authorization process, integrating OAuth2 with Eve is easy. Make yourself comfortable with the topics illustrated in this page, then head over to Eve-OAuth2, an example project which leverages Flask-Sentinel to demonstrate how you can protect your API with OAuth2.

Please note

The snippets in this page can also be found in the examples/security folder of the Eve repository.