I've been asked by my employer to implement a log-in system for our web application using users' GitHub accounts. I've looked around online but I haven't been able to find a clear explanation of how to go about doing this with GitHub accounts (as opposed to with Facebook or Google accounts).
I just spent about a week's worth of effort figuring out how to do this, so I thought I'd write up an explanation to save future developers time.
The short(er) answer
You'll want to follow this guide in GitHub's docs ("Authorizing OAuth Apps"), with some additions (explained below) to allow it to work as a method of user authentication.
I implemented the "web application flow" for when our application will be deployed on our company's servers (where we can keep our company's GitHub app's "client secret" a secret), and the "device flow" for when our application will be deployed on our client's computers (because in that situation we won't be able to keep our "client secret" a secret).
GitHub's guide doesn't mention the steps below (because that guide is not intended specifically for implementing social login), but to get social login working I also did the following:
I created a users database table, with the idea being that each GitHub account used to log in would have its own corresponding row in this table.
Example users table schema:
id - INTEGER
email - VARCHAR
name - VARCHAR
github_id - VARCHAR
I created an oauth_tokens database table to store a copy of all of the GitHub access tokens that our back-end receives from GitHub.
This is needed to prevent other malicious websites from impersonating our users with valid GitHub access tokens generated by the user authorizing an access token for the malicious website.
Example oauth_tokens table schema:
id - INTEGER
user_id - INTEGER
access_token - VARCHAR
expires_at - DATETIME
refresh_token - VARCHAR
refresh_token_expires_at - DATETIME
device_code - VARCHAR <-- Used for the "device flow". I have the back-end send the
front-end the device code immediately upon starting the device flow, and I then
have the front-end poll the back-end with it until the back-end has received
the access token from GitHub, at which point the front-end discards the device
code and uses the access token as its authentication token.
I had the back-end send the front-end (the user) the GitHub access token for it to present with future requests as its authentication mechanism.
The front-end should store the token in localStorage if you want the user to remain logged in even after they close the browser tab they logged in with.
I added middleware on the back-end that--for each incoming request--looks up the provided access token in our database to see if it's expired, and if so, attempts to refresh it. If it succeeds in refreshing the token, it proceeds with the request as normal and includes the new access token in the response to the front-end in a custom response header the front-end is keeping an eye out for (I named it x-updated-access-token). If it fails to refresh the token, it aborts the request and sends a 401 response that the front-end takes as a signal to redirect the user to the login page.
Setting up your app to only allow unexpired access tokens to serve as a method of authentication is necessary to make it possible for the user to sign out of the application remotely from their settings page at GitHub.com.
I added front-end code to handle the saving / updating / removing of the GitHub access token, both to/from localStorage as well as to all requests to the back-end, as well as redirecting to a /login route if the front-end doesn't find an "access_token" localStorage variable set.
The code is further below if you want an in-depth explanation, but basically I used this article as a rough guide for how the front-end code should work for the "web application flow": OpenID Connect Client by Example - Codeburst.io
More information
To clarify some vocabulary: The goal here is to do user authentication via social login. Social login is a type of single-sign on.
The first thing you should understand is that--as of the time I'm writing this--GitHub has not set itself up to be a provider of social login in the way Facebook and Google have.
Facebook and Google both have developed special JavaScript libraries that you can use to implement social login without needing to write any(?) login-specific back-end code. GitHub has no such library, and from what I can tell it's not even possible for a third party to develop such a library because GitHub's API doesn't offer the functionality required to make such a library possible (specifically, they seem to support neither the "implicit flow" nor OpenID Connect).
The next thing you should understand is that--as of the time I'm writing this--GitHub's API does not seem to support the use of OpenID Connect to implement social login using GitHub accounts.
When I started doing research into how to implement social login I was confused by the fact that the most-recent online guides were saying that OpenID Connect was the current best-practice way to do it. And this is true, if the Identity Provider (e.g. GitHub) you're using supports it (i.e. their API can return OpenID Connect ID tokens). As far as I can tell, GitHub's API doesn't currently have the ability to return OpenID Connect ID tokens from the endpoints we'd need to request them from, although it does seem they support the use of OpenID Connect tokens elsewhere in their API.
Thus, the way web apps will generally want to implement social login with GitHub accounts is to use the OAuth 2.0 flow that most websites used before OpenID Connect, which most online resources call the "authorization code flow", but which GitHub's docs refer to as the "web application flow". It's just as secure but requires some more work/code than the other methods to implement properly. The takeaway is that implementing social login with GitHub is going to take more time than using an Identity Provider like Facebook or Google that have streamlined the process for developers.
If you (or your boss) still want to use GitHub for social login even after understanding it's going to take more time, it's worth spending some time to watch some explanations of how the OAuth 2.0 flow works, why OpenID Connect was developed (even though GitHub doesn't seem to support it), and become familiar with some key technical terms, as it'll make it easier to understand the GitHub guide.
OAuth 2.0
The best explanation of OAuth 2.0 that I found was this one by Okta: An Illustrated Guide to OAuth and OpenID Connect
The most important technical terms:
Identity Provider - This is GitHub, Facebook, Google, etc.
Client - This is your app; specifically, the back-end part of your app.
Authorization Code - "A short-lived temporary code the Client gives the [Identity Provider] in exchange for an Access Token."
Access Token: This is what lets your app ask GitHub for information about the user.
You may also find this graph helpful:
The slide title is "OIDC Authorization Code Flow" but the same flow is used for a non-OIDC OAuth 2.0 authorization code flow, with the only difference being that step 10 doesn't return an ID token, just the access token and refresh token.
The fact that step 11 is highlighted in green isn't significant; it's just the step the presenter wanted to highlight for this particular slide.
The graph shows the "Identity Provider" and "Resource Server" as separate entities, which might be confusing. In our case they're both GitHub's API; the "Identity Provider" is the part of GitHub's API that gets us an access token, and the "Resource Server" is the part of GitHub's API that we can send the access token to to take actions on behalf of the user (e.g. asking about their profile).
Source: Introduction to OAuth 2.0 and OpenID Connect (PowerPoint slides) - PragmaticWebSecurity.com
OpenID Connect (OIDC)
Again, GitHub doesn't seem to support this, but it's mentioned a lot online, so you may be curious to know what's going on here / what problem it solves / why GitHub doesn't support it.
The best explanation I've seen for why OpenID Connect was introduced and why it would be preferred over plain OAuth 2.0 for authentication is my own summary of a 2012 ThreadSafe blog post: Why use OpenID Connect instead of plain OAuth2?.
The short answer is that before OIDC existed, pure-frontend social login JavaScript libraries (like Facebook's) were using plain OAuth 2.0, but this method was open to an exploit where a malicious web app could have a user sign into their site (for example, using Facebook login) and then use the generated (Facebook) access token to impersonate that user on any other site that accepted that (Facebook) access token as a method of authentication. OIDC prevents that exploit.
This particular exploit is what people are referring to when they say "OAuth 2.0 is an authorization protocol, not an authentication protocol...OAuth says absolutely nothing about the user, nor does it say how the user proved their presence or even if they're still there.", which I saw mentioned over and over again while doing research on how to use OAuth 2.0 to implement social login, and which had me initially thinking that I needed to use OpenID Connect.
But GitHub doesn't have a pure-frontend social login JavaScript library, so it doesn't need to support OpenID Connect to address that exploit. You just need to make sure your app's back-end is keeping track of which GitHub access tokens it has generated rather than just trusting any valid GitHub access token it receives.
While doing research I came across HelloJS and wondered if I could use it to implement social login. From what I can tell, the answer is "not securely".
The first thing to understand is that when you use HelloJS, it is using the same authentication code flow I describe above, except HelloJS has its own back-end ("proxy") server set up to allow you to skip writing the back-end code normally needed to implement this flow, and the HelloJS front-end library allows you to skip writing all the front-end code normally needed.
The problem with using HelloJS for social login is the back-end server/proxy part: there seems to be no way to prevent the kind of attack that OpenID Connect was created to prevent: the end result of using HelloJS seems to be a GitHub access token, and there seems to be no way for your app's back-end to tell whether that access token was created by the user trying to log into your app or if it was created when the user was logging into some other malicious app (which is then using that access token to send requests to your app, impersonating the user).
If your app doesn't use a back-end then you could be fine, but most apps do rely on a back-end to store user-specific data that should only be accessible to that user.
You could get around this problem if you were able to query the proxy server to double-check which access tokens it had generated, but HelloJS doesn't seem to have a way to do this out-of-the-box, and if you decide to create your own proxy server so that you can do this, you seem to be ending up in a more-complicated situation than if you'd just avoided HelloJS from the beginning.
HelloJS instead seems to be intended for situations where your front-end just wants to query the GitHub API on behalf of the user to get information about their account, like their user details or their list of repositories, with no expectation that your back-end will be using the user's GitHub access token as a method for that user to access their private information on your back-end.
To implement the "web application flow" I used the following article as a reference, although it didn't perfectly map to what I needed to do with GitHub: OpenID Connect Client by Example - Codeburst.io
Keep in mind that this guide is for implementing the OpenID Connect authentication flow, which is similar-to-but-not-the-same-as the flow we need to use for GitHub.
The code here was especially helpful for getting my front-end code working properly.
GitHub does not allow for the use of a "nonce" as described in this guide, because that is a feature specific to (some implementations of?) OpenID Connect, and GitHub's API does not support the use of a nonce in the same way that Google's API does.
To implement the "device flow" I used the following article as inspiration: Using the OAuth 2.0 device flow to authenticate users in desktop apps
The key quote is this: "Basically, when you need to authenticate, the device will display a URL and a code (it could also display a QR code to avoid having to copy the URL), and start polling the identity provider to ask if authentication is complete. You navigate to the URL in the browser on your phone or computer, log in when prompted to, and enter the code. When you’re done, the next time the device polls the IdP, it will receive a token: the flow is complete."
Example code
The app I'm working on uses Vue + Quasar + TypeScript on the front-end, and Python + aiohttp on the back-end. Obviously you may not be able to use the code directly, but hopefully using it as a reference will give you enough of an idea of what the finished product should look like that you can more-quickly get your own code working.
Because of Stack Overflow's post length limits, I can't include the code in the body of this answer, so instead I'm linking the code in individual GitHub Gists.
App.vue
This is the 'parent component' which the entire front-end application is contained within. It has code that handles the situation during the "web application flow" where the user has been redirected by GitHub back to our application after authorizing our application. It takes the authorization code from the URL query parameters and sends it to our application's back-end, which in turn sends the authorization code to GitHub in exchange for the access token and refresh token.
axios.ts
This is most of the code from axios.ts. This is where I put the code that adds the GitHub access token to all requests to our app's back-end (if the front-end finds such a token in localStorage), as well as the code that looks at any responses from our app's back-end to see if the access token has been refreshed.
auth.py
This is the back-end file that contains all the routes used during the login process for both the "web application flow" and the "device flow". If the route URL contains "oauth" it's for the "web application flow", and if the route URL contains "device" it's for the "device flow"; I was just following GitHub's example there.
middleware.py
This is the back-end file that contains the middleware function that evaluates all incoming requests to see if the presented GitHub access token is one in our app's database, and hasn't yet expired. The code for refreshing the access token is in this file.
Login.vue
This is the front-end component that displays the "Login page". It has code for both the "web application flow" as well as the "device flow".
Summary of the two login flows as implemented in my application:
The web application flow
The user goes to http://mywebsite.com/
The front-end code checks whether there's an access_token localStorage variable (which would indicate the user has already logged in), and doesn't find one, so it redirects the user to the /login route.
See App.vue:mounted() and App.vue:watch:authenticated()
At the Login page/view, the user clicks the "Sign in with GitHub" button.
The front-end sets a random state localStorage variable, then redirects the user to GitHub's OAuth app authorization page with our app's client ID and the random state variable as URL query parameters.
See Login.vue:redirectUserToGitHubWebAppFlowLoginLink()
The user signs into GitHub (if they're not already signed in), authorizes our application, and is redirected back to http://mywebsite.com/ with an authentication code and the state variable as URL query parameters.
The app is looking for those URL query parameters every time it loads, and when it sees them, it makes sure the state variable matches what it stored in localStorage, and if so, it POSTs the authorization code to our back-end.
See App.vue:mounted() and App.vue:sendTheBackendTheAuthorizationCodeFromGitHub()
Our app's back-end receives the POSTed authorization code and then very quickly:
Note: the steps below are in auth.py:get_web_app_flow_access_token_and_refresh_token()
It sends the authorization code to GitHub in exchange for the access token and refresh token (as well as their expiration times).
It uses the access token to query GitHub's "/user" endpoint to get the user's GitHub id, email address, and name.
It looks in our database to see if we have a user with the retrieved GitHub id, and if not, creates one.
It creates a new "oauth_tokens" database record for the newly-retrieved access tokens and associates it with the user record.
Finally, it sends the access token to the front-end in the response to the front-end's request.
The front-end receives the response, sets an access_token variable in localStorage, and sets an authenticated Vue variable to true, which the app is constantly watching out for, and which triggers the front-end to redirect the user from the "login" view to the "app" view (i.e. the part of the app that requires the user to be authenticated).
See App.vue:sendTheBackendTheAuthorizationCodeFromGitHub() and App.vue:watch:authenticated()
The device flow
The user goes to http://mywebsite.com/
The front-end code checks whether there's an access_token localStorage variable (which would indicate the user has already logged in), and doesn't find one, so it redirects the user to the /login route.
See App.vue:mounted() and App.vue:watch:authenticated()
At the Login page/view, the user clicks the "Sign in with GitHub" button.
The front-end sends a request to our app's back-end asking for the user code that the user will enter while signed into their GitHub account.
See Login.vue:startTheDeviceLoginFlow()
The back-end receives this request and:
See auth.py:get_device_flow_user_code()
Sends a request to GitHub asking for a new user_code.
Creates an asynchronous task polling GitHub to see if the user has entered the user_code yet.
Sends the user a response with the user_code and device_code that it got from GitHub.
The front-end receives the response from our app's back-end and:
It stores the user_code and device_code in Vue variables.
See Login.vue:startTheDeviceLoginFlow()
The device_code is also saved to localStorage so that if the user closes the browser window that has the "log in" page open and then opens up a new one, they won't need to restart the login process.
It displays the user_code to the user.
See Login.vue in the template code block starting <div v-if="deviceFlowUserCode">
It shows a button that will open the GitHub URL where the user can enter the user_code (it will open the page in a new tab).
It shows a QR code that links to the same GitHub link, so that if the user is using the application on a computer and wants to enter the code on their phone, they can do that.
The app uses the received device_code to set a deviceFlowDeviceCode variable. A separate part of the code in the app is constantly checking to see if that variable has been set, and when it sees that it has, it begins polling the back-end to see if the back-end has received the access_token yet from GitHub.
See Login.vue:watch:deviceFlowDeviceCode() and Login.vue:repeatedlyPollTheBackEndForTheAccessTokenGivenTheDeviceCode()
The user either clicks the aforementioned button or scans the QR code with their phone, and enters the user code at https://github.com/login/device while logged into their GitHub account, either on the same device this application is running on or some other device (like their phone).
The back-end, while polling GitHub every few seconds as previously mentioned, receives the access_token and refresh_token, and as mentioned while describing the "web app flow", sends a request to GitHub's "/user" endpoint to get user data, then gets or creates a user db record, and then creates a new oauth_tokens db record.
See auth.py:_repeatedly_poll_github_to_check_if_the_user_has_entered_their_code()
The front-end, while polling our application's back-end every few seconds, finally receives a response from the back-end with the access_token, sets an access_token variable in localStorage, redirects the user to the "app" view (i.e. the part of the app that requires the user to be authenticated).
See Login.vue:repeatedlyPollTheBackEndForTheAccessTokenGivenTheDeviceCode()
The front end is already authenticated with Google/Facebook/Twitter.
I just need to use the id token from the front end to get the user profile info in the WebApi, check if we already have an account with that email etc. and if not then add the external login key to the Identity data (by calling AddLoginAsync on the Microsoft.AspNetCore.Identity.UserManager).
I don't want to hardcode the user profile endpoints for Google, Facebook etc. as they might change. I'd like to use something like a NuGet package that has these values and just update it when/if they change.
I've read a lot of examples but they're for whole authentication flows, using redirects and cookies in Asp.Net MVC... Although it seems basic, I didn't find an example where the external login is already done on the client and the backend just needs to use the resulting token to validate that login and get the user profile info.
Anyone else ran into this? Thanks!
I was looking at Khan Academy and I'm wondering how their authentication works (probably many other websites have it the same).
When you login with facebook account that has email "aaa#gmail.com", you completely logout, open another anonymous window, and login with google account that has the same "aaa#gmail.com" email, you log into the previously created account.
My questions are :
Do they make association to account based on email your social account has ?
I'm sure their solution is secure, but is this common and normally doable so there won't be any possible exploitations ?
I'm using a system of Oauth2 to grant access to my app, dvouch
First you have a registered user in your website, with an unique email.
So what basically happens is:
User visits your website (website doesn't know who the user is)
User clicks to login through one of the Oauth2 providers
Your website proceeds to start a "OAuth2" handshake, it redirects the user to the provider oauth endpoint, along with some information, like what scopes you're asking for (email, personal info, public info, etc), the url to send back the user after the authentication is done, your application tokens (that are registered in the providers app dashboard), and so on.
Let's say the provider you chose was facebook. Facebook receives your request for an OAuth2 authentication. It also receives the scopes you're asking for, which url you want the user to go to after being authenticated, and your application credentials
It checks that the credentials you're sending are valid, that the callback url you're asking the user to be sent after also matches what they have registered for your app (so that someone can't simply steal your app credentials and have users redirected somewhere else) and if everything is fine and dandy, it will then present the login window to the user. This login is happening on the provider's page. Not on your website.
The user logs in (inside facebook or google not your website). The provider sends them back to the call back url you specified in the beginning of the handshake.
You (your website) receives the user back with a bunch of information, such as the email of the user who just completed the Oauth2 flow.
At this point you use the email that came in the callback and identify the user through the email. Since all emails are unique, and since your user had to be registered with that email on the provider, you are safe to assume he's the owner of the email.
(technically things might happen a bit differently)
It's basically very secure as long as the website has the regular security measures. Of course if someone has access to your Facebook(wtv) account or email they can login as if they were you, but that would happen either way they offered Oauth or not.
Then as long as you verify you're logging in the correct provider's website (like facebook's or google and not something else) you'll be fine since no one else will be able to see your login. Since a "scope" of authorizations has to be passed as well you as a user can also see what the application is asking for (email, access to your inbox, wtv) and decide if you want to grant those scopes or not, if you decide not to grant access then facebook will not pass back that information, which in turn renders the process safe.
The only way it wouldn't be safe would be if you had malicious software installed in your computer to log your activity and in this case you would be screwed either way.
I have implemented authentication mechanism on some mobile application using JWTBundle with symfony 3. Until now the process requires users to submit both their email and password in order to authenticate. This works great.
Today I would like to grant access/create_account using Facebook authentication.
From the mobile app, users will access the application without submitting any password but instead FB will probably return user's Facebook identifier along with some other info. I will then post those datas to login_check route.
At this point I need a way to check (at the very beginning of request processing flow) whether login_check POST datas are standard username/pwd credentials (which I guess are handled through daoauthenticationprovider by default ? which in turn pass the processing to JWT in order to create a authentication token) and if not, fallback to another custom XXAuthenticationProvider to handle those datas (eg. if a facebook identifier is present then lookup the user account with FB API, do stuff … then create a JWT token).
I read couples of articles dealing with Symfony's Security components but none explained the whole thing clearly neither exposed a way to proceed. I still have difficulties to figure out how I could hook into the security firewall to achieve this.
Is this a way to go and how can I achieve this ?
Thank you.
I am setting up my own CAS. A authentication handler was written and username/password are authenticated against a MySQL db. I also add signup page and related logic.
Now I would like to let user automatically log on when he/she has registered as a user. How to achieve this?
The comment above is incorrect - CAS clients do not have access to the cookie, only the CAS Server does - CAS is not a shared-cookie protocol.
If you only have a single site, you can just create a session on the client, using the standard mechanisms for Java, Ruby, whatever platform you're using.
If you want to create an SSO session for login to multiple applications, basically you need to:
Create a SSO session (via the CAS server)
Redirect to the CAS Server
Have the user redirected back to your application.
To accomplish the first one, you likely will want to modify the CAS LoginFlow to allow you to authenticate the user, either via one-time token or a similar mechanism.
Here is my implementation. The idea is borrowed from class org.jasig.cas.web.flow.AuthenticationViaFormAction.
In my web controller handling unlock request which is often from a registration email of a new user.
String oneTimeAuthToken = this.userManager.generateOneTimeAuthToken(userEmail);
UsernamePasswordCredentials credentials = new UsernamePasswordCredentials();
credentials.setUsername(userEmail);
credentials.setPassword(oneTimeAuthToken);
String tgt = centralAuthenticationService.createTicketGrantingTicket(credentials);
ticketGrantingTicketCookieGenerator.addCookie(request, response, tgt);
log.debug("Current user was unlocked and logged in.");
The fundamentals behind this is to create a temp password-like token to authenticate. Of course, userManager should clear this token automatically once authentication is successful.
Hope this is clear. Let me know if you observe anything wrong.