Authenticating users with Cloud Identity-Aware Proxy for Python


Apps running on Google Cloud managed platforms such as App Engine can avoid managing user authentication and session management by using Identity-Aware Proxy (IAP) to control access to them. IAP can not only control access to the app, but it also provides information about the authenticated users, including the email address and a persistent identifier to the app in the form of new HTTP headers.

Objectives

  • Require users of your App Engine app to authenticate themselves by using IAP.

  • Access users' identities in the app to display the current user's authenticated email address.

Costs

In this document, you use the following billable components of Google Cloud:

To generate a cost estimate based on your projected usage, use the pricing calculator. New Google Cloud users might be eligible for a free trial.

When you finish the tasks that are described in this document, you can avoid continued billing by deleting the resources that you created. For more information, see Clean up.

Before you begin

  1. Sign in to your Google Cloud account. If you're new to Google Cloud, create an account to evaluate how our products perform in real-world scenarios. New customers also get $300 in free credits to run, test, and deploy workloads.
  2. In the Google Cloud console, on the project selector page, select or create a Google Cloud project.

    Go to project selector

  3. Install the Google Cloud CLI.
  4. To initialize the gcloud CLI, run the following command:

    gcloud init
  5. In the Google Cloud console, on the project selector page, select or create a Google Cloud project.

    Go to project selector

  6. Install the Google Cloud CLI.
  7. To initialize the gcloud CLI, run the following command:

    gcloud init

Background

This tutorial uses IAP to authenticate users. This is only one of several possible approaches. To learn more about the various methods to authenticate users, see the Authentication concepts section.

The Hello user-email-address app

The app for this tutorial is a minimal Hello world App Engine app, with one non-typical feature: instead of "Hello world" it displays "Hello user-email-address", where user-email-address is the authenticated user's email address.

This functionality is possible by examining the authenticated information that IAP adds to each web request it passes through to your app. There are three new request headers added to each web request that reaches your app. The first two headers are plain text strings that you can use to identify the user. The third header is a cryptographically signed object with that same information.

  • X-Goog-Authenticated-User-Email: A user's email address identifies them. Don't store personal information if your app can avoid it. This app doesn't store any data; it just echoes it back to the user.

  • X-Goog-Authenticated-User-Id: This user ID assigned by Google doesn't show information about the user, but it does allow an app to know that a logged-in user is the same one that was previously seen before.

  • X-Goog-Iap-Jwt-Assertion: You can configure Google Cloud apps to accept web requests from other cloud apps, bypassing IAP, in addition to internet web requests. If an app is so configured, it's possible for such requests to have forged headers. Instead of using either of the plain text headers previously mentioned, you can use and verify this cryptographically signed header to check that the information was provided by Google. Both the user's email address and a persistent user ID are available as part of this signed header.

If you are certain that the app is configured so that only internet web requests can reach it, and that no one can disable the IAP service for the app, then retrieving a unique user ID takes only a single line of code:

user_id = request.headers.get('X-Goog-Authenticated-User-ID')

However, a resilient app should expect things to go wrong, including unexpected configuration or environmental issues, so we instead recommend creating a function that uses and verifies the cryptographically signed header. That header's signature cannot be forged, and when verified, can be used to return the identification.

Create the source code

  1. Use a text editor to create a file named main.py, and paste the following code in it:

    import sys
    
    from flask import Flask
    app = Flask(__name__)
    
    CERTS = None
    AUDIENCE = None
    
    
    def certs():
        """Returns a dictionary of current Google public key certificates for
        validating Google-signed JWTs. Since these change rarely, the result
        is cached on first request for faster subsequent responses.
        """
        import requests
    
        global CERTS
        if CERTS is None:
            response = requests.get(
                'https://www.gstatic.com/iap/verify/public_key'
            )
            CERTS = response.json()
        return CERTS
    
    
    def get_metadata(item_name):
        """Returns a string with the project metadata value for the item_name.
        See https://cloud.google.com/compute/docs/storing-retrieving-metadata for
        possible item_name values.
        """
        import requests
    
        endpoint = 'http://metadata.google.internal'
        path = '/computeMetadata/v1/project/'
        path += item_name
        response = requests.get(
            '{}{}'.format(endpoint, path),
            headers={'Metadata-Flavor': 'Google'}
        )
        metadata = response.text
        return metadata
    
    
    def audience():
        """Returns the audience value (the JWT 'aud' property) for the current
        running instance. Since this involves a metadata lookup, the result is
        cached when first requested for faster future responses.
        """
        global AUDIENCE
        if AUDIENCE is None:
            project_number = get_metadata('numeric-project-id')
            project_id = get_metadata('project-id')
            AUDIENCE = '/projects/{}/apps/{}'.format(
                project_number, project_id
            )
        return AUDIENCE
    
    
    def validate_assertion(assertion):
        """Checks that the JWT assertion is valid (properly signed, for the
        correct audience) and if so, returns strings for the requesting user's
        email and a persistent user ID. If not valid, returns None for each field.
        """
        from jose import jwt
    
        try:
            info = jwt.decode(
                assertion,
                certs(),
                algorithms=['ES256'],
                audience=audience()
                )
            return info['email'], info['sub']
        except Exception as e:
            print('Failed to validate assertion: {}'.format(e), file=sys.stderr)
            return None, None
    
    
    @app.route('/', methods=['GET'])
    def say_hello():
        from flask import request
    
        assertion = request.headers.get('X-Goog-IAP-JWT-Assertion')
        email, id = validate_assertion(assertion)
        page = "<h1>Hello {}</h1>".format(email)
        return page

    This main.py file is explained in detail in the Understanding the code section later in this tutorial.

  2. Create another file called requirements.txt, and paste the following into it:

    Flask==2.2.5
    cryptography==41.0.2
    python-jose[cryptography]==3.3.0
    requests==2.31.0

    The requirements.txt file lists any non-standard Python libraries your app needs App Engine to load for it:

    • Flask is the Python web framework used for the app.

    • cryptography is a module that provides strong cryptographic functions.

    • python-jose[cryptography] provides the JWT checking and decoding function.

    • requests retrieves data from web sites.

  3. Create a file named app.yaml and put the following text in it:

    runtime: python37

    The app.yaml file tells App Engine which language environment your code requires.

Understanding the code

This section explains how the code in main.py works. If you just want to run the app, you can skip ahead to the Deploy the app section.

The following code is in the main.py file. When a an HTTP GET request to the home page is received by the app, the Flask framework invokes the say_hello function:

@app.route('/', methods=['GET'])
def say_hello():
    from flask import request

    assertion = request.headers.get('X-Goog-IAP-JWT-Assertion')
    email, id = validate_assertion(assertion)
    page = "<h1>Hello {}</h1>".format(email)
    return page

The say_hello function gets the JWT assertion header value that IAP added from the incoming request and calls a function to validate that cryptographically signed value. The first value returned (email) is then used in a minimal web page that it creates and returns.

def validate_assertion(assertion):
    """Checks that the JWT assertion is valid (properly signed, for the
    correct audience) and if so, returns strings for the requesting user's
    email and a persistent user ID. If not valid, returns None for each field.
    """
    from jose import jwt

    try:
        info = jwt.decode(
            assertion,
            certs(),
            algorithms=['ES256'],
            audience=audience()
            )
        return info['email'], info['sub']
    except Exception as e:
        print('Failed to validate assertion: {}'.format(e), file=sys.stderr)
        return None, None

The validate_assertion function uses the jwt.decode function from the third-party jose library to verify that the assertion is properly signed, and to extract the payload information from the assertion. That information is the authenticated user's email address and a persistent unique ID for the user. If the assertion cannot be decoded, this function returns None for each of those values and prints a message to log the error.

Validating a JWT assertion requires knowing the public key certificates of the entity that signed the assertion (Google in this case), and the audience the assertion is intended for. For an App Engine app, the audience is a string with Google Cloud project identification information in it. This function gets those certificates and the audience string from the functions preceding it.

def audience():
    """Returns the audience value (the JWT 'aud' property) for the current
    running instance. Since this involves a metadata lookup, the result is
    cached when first requested for faster future responses.
    """
    global AUDIENCE
    if AUDIENCE is None:
        project_number = get_metadata('numeric-project-id')
        project_id = get_metadata('project-id')
        AUDIENCE = '/projects/{}/apps/{}'.format(
            project_number, project_id
        )
    return AUDIENCE

You can look up the Google Cloud project's numeric ID and name and put those in the source code yourself, but the audience function does that for you by querying the standard metadata service made available to every App Engine app. Because the metadata service is external to the app code, that result is saved in a global variable that is returned without having to look metadata up in subsequent calls.

def get_metadata(item_name):
    """Returns a string with the project metadata value for the item_name.
    See https://cloud.google.com/compute/docs/storing-retrieving-metadata for
    possible item_name values.
    """
    import requests

    endpoint = 'http://metadata.google.internal'
    path = '/computeMetadata/v1/project/'
    path += item_name
    response = requests.get(
        '{}{}'.format(endpoint, path),
        headers={'Metadata-Flavor': 'Google'}
    )
    metadata = response.text
    return metadata

The App Engine metadata service (and similar metadata services for other Google Cloud computing services) looks like a web site and is queried by standard web queries. However, it isn't actually an external site, but an internal feature that returns requested information about the running app, so it is safe to use http instead of https requests. It's used to get the current Google Cloud identifiers needed to define the JWT assertion's intended audience.

def certs():
    """Returns a dictionary of current Google public key certificates for
    validating Google-signed JWTs. Since these change rarely, the result
    is cached on first request for faster subsequent responses.
    """
    import requests

    global CERTS
    if CERTS is None:
        response = requests.get(
            'https://www.gstatic.com/iap/verify/public_key'
        )
        CERTS = response.json()
    return CERTS

Verification of a digital signature requires the public key certificate of the signer. Google provides a web site that returns all of the currently used public key certificates. These results are cached in case they're needed again in the same app instance.

Deploying the app

Now you can deploy the app and then enable IAP to require users to authenticate before they can access the app.

  1. In your terminal window, go to the directory containing the app.yaml file, and deploy the app to App Engine:

    gcloud app deploy
    
  2. When prompted, select a nearby region.

  3. When asked if you want to continue with the deployment operation, enter Y.

    Within a few minutes, your app is live on the internet.

  4. View the app:

    gcloud app browse
    

    In the output, copy web-site-url, the web address for the app.

  5. In a browser window, paste web-site-url to open the app.

    No email is displayed because you're not yet using IAP so no user information is sent to the app.

Enable IAP

Now that an App Engine instance exists, you can protect it with IAP:

  1. In the Google Cloud console, go to the Identity-Aware Proxy page.

    Go to Identity-Aware Proxy page

  2. Because this is the first time you've enabled an authentication option for this project, you see a message that you must configure your OAuth consent screen before you can use IAP.

    Click Configure Consent Screen.

  3. On the OAuth Consent Screen tab of the Credentials page, complete the following fields:

    • If your account is in a Google Workspace organization, select External and click Create. To start, the app will only be available to users you explicitly allow.

    • In the Application name field, enter IAP Example.

    • In the Support email field, enter your email address.

    • In the Authorized domain field, enter the hostname portion of the app's URL, for example, iap-example-999999.uc.r.appspot.com. Press the Enter key after entering the hostname in the field.

    • In the Application homepage link field, enter the URL for your app, for example, https://iap-example-999999.uc.r.appspot.com/.

    • In the Application privacy policy line field, use the same URL as the homepage link for testing purposes.

  4. Click Save. When prompted to create credentials, you can close the window.

  5. In the Google Cloud console, go to the Identity-Aware Proxy page.

    Go to Identity-Aware Proxy page

  6. To refresh the page, click Refresh . The page displays a list of resources you can protect.

  7. In the IAP column, click to turn on IAP for the app.

  8. In your browser, go to web-site-url again.

  9. Instead of the web page, there is a login screen to authenticate yourself. When you log in, you're denied access because IAP doesn't have a list of users to allow through to the app.

Add authorized users to the app

  1. In the Google Cloud console, go to the Identity-Aware Proxy page.

    Go to Identity-Aware Proxy page

  2. Select the checkbox for the App Engine app, and then click Add Principal.

  3. Enter allAuthenticatedUsers, and then select the Cloud IAP/IAP-Secured Web App User role.

  4. Click Save.

Now any user that Google can authenticate can access the app. If you want, you can restrict access further by only adding one or more people or groups as principals:

  • Any Gmail or Google Workspace email address

  • A Google Group email address

  • A Google Workspace domain name

Access the app

  1. In your browser, go to web-site-url.

  2. To refresh the page, click Refresh .

  3. On the login screen, log in with your Google credentials.

    The page displays a "Hello user-email-address" page with your email address.

    If you still see the same page as before, there might be an issue with the browser not fully updating new requests now that you enabled IAP. Close all browser windows, reopen them, and try again.

Authentication concepts

There are several ways an app can authenticate its users and restrict access to only authorized users. Common authentication methods, in decreasing level of effort for the app, are listed in the following sections.

Option Advantages Disadvantages
App authentication
  • App can run on any platform, with or without an internet connection
  • Users don't need to use any other service to manage authentication
  • App must manage user credentials securely, guard against disclosure
  • App must maintain session data for logged-in users
  • App must provide user registration, password changes, password recovery
OAuth2
  • App can run on any internet-connected platform, including a developer workstation
  • App doesn't need user registration, password changes, or password recovery functions.
  • Risk of user information disclosure is delegated to other service
  • New login security measures handled outside the app
  • Users must register with the identity service
  • App must maintain session data for logged-in users
IAP
  • App doesn't need to have any code to manage users, authentication, or session state
  • App has no user credentials that might be breached
  • App can only run on platforms supported by the service. Specifically, certain Google Cloud services that support IAP, such as App Engine.

App-managed authentication

With this method, the app manages every aspect of user authentication on its own. The app must maintain its own database of user credentials and manage user sessions, and it needs to provide functions to manage user accounts and passwords, check user credentials, as well as issue, check, and update user sessions with each authenticated login. The following diagram illustrates the app-managed authentication method.

Application managed flow

As shown in the diagram, after the user logs in, the app creates and maintains information about the user's session. When the user makes a request to the app, the request must include session information that the app is responsible for verifying.

The main advantage of this approach is that it is self-contained and under the control of the app. The app doesn't even need to be available on the internet. The main disadvantage is that the app is now responsible for providing all account management functionality and protecting all sensitive credential data.

External authentication with OAuth2

A good alternative to handling everything within the app is to use an external identity service, such as Google, that handles all user account information and functionality and is responsible for safeguarding sensitive credentials. When a user tries to log in to the app the request is redirected to the identity service, which authenticates the user and then redirect the request back to the app with necessary authentication information provided. For more information, see Using OAuth 2.0 for Web Server Applications.

The following diagram illustrates the external authentication with the OAuth2 method.

OAuth2 flow

The flow in the diagram begins when the user sends a request to access the app. Instead of responding directly, the app redirects the user's browser to Google's identity platform, which displays a page to log in to Google. After successfully logging in, the user's browser is directed back to the app. This request includes information that the app can use to look up information about the now authenticated user, and the app now responds to the user.

This method has many advantages for the app. It delegates all account management functionality and risks to the external service, which can improve login and account security without the app having to change. However, as is shown in the preceding diagram, the app must have access to the internet to use this method. The app is also responsible for managing sessions after the user is authenticated.

Identity-Aware Proxy

The third approach, which this tutorial covers, is to use IAP to handle all authentication and session management with any changes to the app. IAP intercepts all web requests to your app, blocks any that haven't been authenticated, and passes others through with user identity data added to each request.

The request handling is shown in the following diagram.

IAP flow

Requests from users are intercepted by IAP, which blocks unauthenticated requests. Authenticated requests are passed on to the app, provided that the authenticated user is in the list of allowed users. Requests passed through IAP have headers added to them identifying the user who made the request.

The app no longer needs to handle any user account or session information. Any operation that needs to know a unique identifier for the user can get that directly from each incoming web request. However, this can only be used for computing services that support IAP, such as App Engine and load balancers. You cannot use IAP on a local development machine.

Clean up

To avoid incurring charges to your Google Cloud account for the resources used in this tutorial, either delete the project that contains the resources, or keep the project and delete the individual resources.

  1. In the Google Cloud console, go to the Manage resources page.

    Go to Manage resources

  2. In the project list, select the project that you want to delete, and then click Delete.
  3. In the dialog, type the project ID, and then click Shut down to delete the project.