Say a user wants to authorize mykittenblog.com to make calls on his behalf to payment.com.
mykittenblog.com has people login at payment.com like so
payment.com/oauth2/authorize?id=12345&redirect=http://mykittenblog.com
So payment.com can respond with an intermediate auth code that mykittenblog.com can use together with its client secret to retrieve an OAuth bearer token at payment.com
Now the 'redirect' parameter has an open redirect vulnerability that allows leaking of the auth code.
if a user logs in at
payment.com/oauth2/authorize?id=12345&redirect=http://evilserver.com/codestealer
payment.com will respond with
Location: http://evilserver.com/codestealer?code=4312871236481723874
What are the possible dangers in this situation?
If the intermediate authorization code is stolen by a malicious application, then it will be able to issue access tokens and get access to the resources. If a refresh token is also issued, then it will be able to renew that access token whenever it wants.
If your client is confidential, then the leak is limited (but not impossible) as the malicious client has to get your application credentials.
They are counter-measures to prevent that leak of code.
The registration of the redirect uris is a good start, but not sufficient.
Another way is the use of a Proof Key for Code Exchange described in the RFC7636. Without this PKCE, it is not possible for a malicious application to issue an access token as the challenge cannot be easily guessed.
From my point of view, the use of that the PKCE should always be done and not limited to the public clients.
Related
I am learning about different Oauth2 flows but it does not provide any guidelines on securely persisting different kinds of access tokens in different scenarios and I could not find relevant information on the topic by Google-fu.
I am wondering if is it safe to save access tokens in a secure frontend context like httpOnly cookie and optionally directly calling the api from the browser without proxying it through the application server?
It appears more secure to me because access tokens unlike passwords cannot be hashed, the means to recover all access tokens (if encrypted) must exist on the server otherwise it would not be able to call the service on behalf of the user. So, were the application server compromised so would the access tokens of all users.
Am I missing some context here or is it correct?
If you think about sharing your own access token with some users user agent (browser), then this solution is never secure. The user agent (browser) is something working totally on behalf of the user. The user, if he wants to, may have access to any kind of resource the user agent operates with. Sharing a token with the user agent is like sharing the token with the user himself.
Whichever method you choose, you need to ensure your backend verifies the token (e.g jwt).
You probably wouldn't need to verify a secure cookie because a secure cookie cannot be accessed/modified by the browser.
I googled a lot on how to protect the refresh_token from a hacker because it will be stored somewhere in browser's local-storage/cookie, so a hacker can easily steal those tokens and I couldn't able to find a proper answer so I came here.
I understand that access_token will expire in less-time and we should use refresh_token to get a new access_token. But if the hackers steal the refresh_token means, he can stay as a login user for a long time, right?
Some people are saying, you can protect it using client_id and client_secret, but the hacker is going to access the endpoint of the API, which has the client_id and client_secret. So again, a hacker can get a new access_token easily.
So I am finding no way to protect the hacker from getting the new access_token.
Can someone able to guide me here, on how I protect the hacker from getting access to refresh token from browser's local-storage/cookie?
From the context of your explanation, you are talking about a browser based application. If this application is one that does not have a backend, then you do not have a secure place to store your long-lived tokens or client secrets.
From OAuth 2.0 perspective, these are called public clients. Thus protocol do not allow them to have a client secret. So they have a client ID and a redirect URL for client authentication (client identification). Implicit flow is one key flow suitable for SPA that runs on browser. By specification, they will not get a refresh token. Reason is their inability to protect such secrets.
But if you have a backend and have the ability to correlate browser session and backend storage, you can use a flow that gives your a refresh token and store it securely. But this require your application architecture to support such (ex:- Browser session and backend storage).
Also, rather than making end user to login every time, you may use the identity server's logged in state to skip log in. This too will rely on identity server's browser cookie and it's life time. For example identity server may have a browser session valid for 24hours. So your client will not see log in page when accessed thew application within the time.
You can try to secure the local storage using this library Secure-ls
I have poured over the OAuth2 docs and seen how the Facebook Javascript SDK uses Implicit Grant.
I am building a ReactJs application, which communicates with a PHP-Symfony API.
What I want to do is offer the "Login with Facebook" option on the frontend.
What I need on my PHP server is the Facebook user id and email and other data of the user so I can initially create a user record for them in my DB and then on returning visit, use the auth token to get that info again on the server and use it to match it to existing records and log the user in.
We have done this previously using the Authorization Code Grant method to redirect the frontend to our server, then to facebook and then back to us with the auth code. We then use that on the server with our Secret Key to get the Access Token and get the user info directly from Facebook to our server and then authenticate the user.
The redirection is a bit of a pain for a single page application.
Facebook's Javascript SDK handles a lot of that automatically, but uses Implicit Grant, returning an Access Token directly to the frontend.
What I want to know is, can I just send that Access Token to my server to do the same type of authentication that I did before? Or is that a massive security hole that I am opening up?
Comparing the two, the Auth Code from the Authorization Code Grant flow also goes via the frontend, but very quickly, not directly to JavaScript and is much shorter lived. So it feels much more secure.
If intercepted in time and with matching state, it could be used to authenticate someone on our server, but not access someone's Facebook data directly.
Reusing the frontend Access Token from the Implicit Grant flow feels like it is open to messing with, but I can't put my finger on the exact scenario that would make it more vulnerable to attack. The token would potentially give people access to not only authenticating on our server but also to accessing people's Facebook info.
So this is ultimately a question of best practice and security.
We think that we should be able to implement our own popout window that does the Authorization Code Grant style flow and retrieves our server cookie which can then be used by the page that spawned it, but it is going to be tricky and most of the work seems to be done for the Implicit Grant method, if it is safe to use as we intend to use it.
Best Practices AND According to the RFC 6749
However, this convenience should be weighed against the security
implications of using implicit grants, such as those described in
Sections 10.3 and 10.16, especially when the authorization code
grant type is available.
When building SPA style applications using frameworks like Angular, Ember, React, etc. what do people believe to be some best practices for authentication and session management? I can think of a couple of ways of considering approaching the problem.
Treat it no differently than authentication with a regular web application assuming the API and and UI have the same origin domain.
This would likely involve having a session cookie, server side session storage and probably some session API endpoint that the authenticated web UI can hit to get current user information to help with personalization or possibly even determining roles/abilities on the client side. The server would still enforce rules protecting access to data of course, the UI would just use this information to customize the experience.
Treat it like any third-party client using a public API and authenticate with some sort of token system similar to OAuth. This token mechanism would used by the client UI to authenticate each and every request made to the server API.
I'm not really much of an expert here but #1 seems to be completely sufficient for the vast majority of cases, but I'd really like to hear some more experienced opinions.
This question has been addressed, in a slightly different form, at length, here:
RESTful Authentication
But this addresses it from the server-side. Let's look at this from the client-side. Before we do that, though, there's an important prelude:
Javascript Crypto is Hopeless
Matasano's article on this is famous, but the lessons contained therein are pretty important:
https://www.nccgroup.trust/us/about-us/newsroom-and-events/blog/2011/august/javascript-cryptography-considered-harmful/
To summarize:
A man-in-the-middle attack can trivially replace your crypto code with <script> function hash_algorithm(password){ lol_nope_send_it_to_me_instead(password); }</script>
A man-in-the-middle attack is trivial against a page that serves any resource over a non-SSL connection.
Once you have SSL, you're using real crypto anyways.
And to add a corollary of my own:
A successful XSS attack can result in an attacker executing code on your client's browser, even if you're using SSL - so even if you've got every hatch battened down, your browser crypto can still fail if your attacker finds a way to execute any javascript code on someone else's browser.
This renders a lot of RESTful authentication schemes impossible or silly if you're intending to use a JavaScript client. Let's look!
HTTP Basic Auth
First and foremost, HTTP Basic Auth. The simplest of schemes: simply pass a name and password with every request.
This, of course, absolutely requires SSL, because you're passing a Base64 (reversibly) encoded name and password with every request. Anybody listening on the line could extract username and password trivially. Most of the "Basic Auth is insecure" arguments come from a place of "Basic Auth over HTTP" which is an awful idea.
The browser provides baked-in HTTP Basic Auth support, but it is ugly as sin and you probably shouldn't use it for your app. The alternative, though, is to stash username and password in JavaScript.
This is the most RESTful solution. The server requires no knowledge of state whatsoever and authenticates every individual interaction with the user. Some REST enthusiasts (mostly strawmen) insist that maintaining any sort of state is heresy and will froth at the mouth if you think of any other authentication method. There are theoretical benefits to this sort of standards-compliance - it's supported by Apache out of the box - you could store your objects as files in folders protected by .htaccess files if your heart desired!
The problem? You are caching on the client-side a username and password. This gives evil.ru a better crack at it - even the most basic of XSS vulnerabilities could result in the client beaming his username and password to an evil server. You could try to alleviate this risk by hashing and salting the password, but remember: JavaScript Crypto is Hopeless. You could alleviate this risk by leaving it up to the Browser's Basic Auth support, but.. ugly as sin, as mentioned earlier.
HTTP Digest Auth
Is Digest authentication possible with jQuery?
A more "secure" auth, this is a request/response hash challenge. Except JavaScript Crypto is Hopeless, so it only works over SSL and you still have to cache the username and password on the client side, making it more complicated than HTTP Basic Auth but no more secure.
Query Authentication with Additional Signature Parameters.
Another more "secure" auth, where you encrypt your parameters with nonce and timing data (to protect against repeat and timing attacks) and send the. One of the best examples of this is the OAuth 1.0 protocol, which is, as far as I know, a pretty stonking way to implement authentication on a REST server.
https://www.rfc-editor.org/rfc/rfc5849
Oh, but there aren't any OAuth 1.0 clients for JavaScript. Why?
JavaScript Crypto is Hopeless, remember. JavaScript can't participate in OAuth 1.0 without SSL, and you still have to store the client's username and password locally - which puts this in the same category as Digest Auth - it's more complicated than HTTP Basic Auth but it's no more secure.
Token
The user sends a username and password, and in exchange gets a token that can be used to authenticate requests.
This is marginally more secure than HTTP Basic Auth, because as soon as the username/password transaction is complete you can discard the sensitive data. It's also less RESTful, as tokens constitute "state" and make the server implementation more complicated.
SSL Still
The rub though, is that you still have to send that initial username and password to get a token. Sensitive information still touches your compromisable JavaScript.
To protect your user's credentials, you still need to keep attackers out of your JavaScript, and you still need to send a username and password over the wire. SSL Required.
Token Expiry
It's common to enforce token policies like "hey, when this token has been around too long, discard it and make the user authenticate again." or "I'm pretty sure that the only IP address allowed to use this token is XXX.XXX.XXX.XXX". Many of these policies are pretty good ideas.
Firesheeping
However, using a token Without SSL is still vulnerable to an attack called 'sidejacking': http://codebutler.github.io/firesheep/
The attacker doesn't get your user's credentials, but they can still pretend to be your user, which can be pretty bad.
tl;dr: Sending unencrypted tokens over the wire means that attackers can easily nab those tokens and pretend to be your user. FireSheep is a program that makes this very easy.
A Separate, More Secure Zone
The larger the application that you're running, the harder it is to absolutely ensure that they won't be able to inject some code that changes how you process sensitive data. Do you absolutely trust your CDN? Your advertisers? Your own code base?
Common for credit card details and less common for username and password - some implementers keep 'sensitive data entry' on a separate page from the rest of their application, a page that can be tightly controlled and locked down as best as possible, preferably one that is difficult to phish users with.
Cookie (just means Token)
It is possible (and common) to put the authentication token in a cookie. This doesn't change any of the properties of auth with the token, it's more of a convenience thing. All of the previous arguments still apply.
Session (still just means Token)
Session Auth is just Token authentication, but with a few differences that make it seem like a slightly different thing:
Users start with an unauthenticated token.
The backend maintains a 'state' object that is tied to a user's token.
The token is provided in a cookie.
The application environment abstracts the details away from you.
Aside from that, though, it's no different from Token Auth, really.
This wanders even further from a RESTful implementation - with state objects you're going further and further down the path of plain ol' RPC on a stateful server.
OAuth 2.0
OAuth 2.0 looks at the problem of "How does Software A give Software B access to User X's data without Software B having access to User X's login credentials."
The implementation is very much just a standard way for a user to get a token, and then for a third party service to go "yep, this user and this token match, and you can get some of their data from us now."
Fundamentally, though, OAuth 2.0 is just a token protocol. It exhibits the same properties as other token protocols - you still need SSL to protect those tokens - it just changes up how those tokens are generated.
There are two ways that OAuth 2.0 can help you:
Providing Authentication/Information to Others
Getting Authentication/Information from Others
But when it comes down to it, you're just... using tokens.
Back to your question
So, the question that you're asking is "should I store my token in a cookie and have my environment's automatic session management take care of the details, or should I store my token in Javascript and handle those details myself?"
And the answer is: do whatever makes you happy.
The thing about automatic session management, though, is that there's a lot of magic happening behind the scenes for you. Often it's nicer to be in control of those details yourself.
I am 21 so SSL is yes
The other answer is: Use https for everything or brigands will steal your users' passwords and tokens.
You can increase security in authentication process by using JWT (JSON Web Tokens) and SSL/HTTPS.
The Basic Auth / Session ID can be stolen via:
MITM attack (Man-In-The-Middle) - without SSL/HTTPS
An intruder gaining access to a user's computer
XSS
By using JWT you're encrypting the user's authentication details and storing in the client, and sending it along with every request to the API, where the server/API validates the token. It can't be decrypted/read without the private key (which the server/API stores secretly) Read update.
The new (more secure) flow would be:
Login
User logs in and sends login credentials to API (over SSL/HTTPS)
API receives login credentials
If valid:
Register a new session in the database Read update
Encrypt User ID, Session ID, IP address, timestamp, etc. in a JWT with a private key.
API sends the JWT token back to the client (over SSL/HTTPS)
Client receives the JWT token and stores in localStorage/cookie
Every request to API
User sends a HTTP request to API (over SSL/HTTPS) with the stored JWT token in the HTTP header
API reads HTTP header and decrypts JWT token with its private key
API validates the JWT token, matches the IP address from the HTTP request with the one in the JWT token and checks if session has expired
If valid:
Return response with requested content
If invalid:
Throw exception (403 / 401)
Flag intrusion in the system
Send a warning email to the user.
Updated 30.07.15:
JWT payload/claims can actually be read without the private key (secret) and it's not secure to store it in localStorage. I'm sorry about these false statements. However they seem to be working on a JWE standard (JSON Web Encryption).
I implemented this by storing claims (userID, exp) in a JWT, signed it with a private key (secret) the API/backend only knows about and stored it as a secure HttpOnly cookie on the client. That way it cannot be read via XSS and cannot be manipulated, otherwise the JWT fails signature verification. Also by using a secure HttpOnly cookie, you're making sure that the cookie is sent only via HTTP requests (not accessible to script) and only sent via secure connection (HTTPS).
Updated 17.07.16:
JWTs are by nature stateless. That means they invalidate/expire themselves. By adding the SessionID in the token's claims you're making it stateful, because its validity doesn't now only depend on signature verification and expiry date, it also depends on the session state on the server. However the upside is you can invalidate tokens/sessions easily, which you couldn't before with stateless JWTs.
I would go for the second, the token system.
Did you know about ember-auth or ember-simple-auth? They both use the token based system, like ember-simple-auth states:
A lightweight and unobtrusive library for implementing token based
authentication in Ember.js applications.
http://ember-simple-auth.simplabs.com
They have session management, and are easy to plug into existing projects too.
There is also an Ember App Kit example version of ember-simple-auth: Working example of ember-app-kit using ember-simple-auth for OAuth2 authentication.
I want to understand what token-based authentication means. I searched the internet but couldn't find anything understandable.
I think it's well explained here -- quoting just the key sentences of the long article:
The general concept behind a
token-based authentication system is
simple. Allow users to enter their
username and password in order to
obtain a token which allows them to
fetch a specific resource - without
using their username and password.
Once their token has been obtained,
the user can offer the token - which
offers access to a specific resource
for a time period - to the remote
site.
In other words: add one level of indirection for authentication -- instead of having to authenticate with username and password for each protected resource, the user authenticates that way once (within a session of limited duration), obtains a time-limited token in return, and uses that token for further authentication during the session.
Advantages are many -- e.g., the user could pass the token, once they've obtained it, on to some other automated system which they're willing to trust for a limited time and a limited set of resources, but would not be willing to trust with their username and password (i.e., with every resource they're allowed to access, forevermore or at least until they change their password).
If anything is still unclear, please edit your question to clarify WHAT isn't 100% clear to you, and I'm sure we can help you further.
From Auth0.com
Token-Based Authentication, relies on a signed token that is sent to
the server on each request.
What are the benefits of using a token-based approach?
Cross-domain / CORS: cookies + CORS don't play well across different domains. A token-based approach allows you to make AJAX
calls to any server, on any domain because you use an HTTP header
to transmit the user information.
Stateless (a.k.a. Server side scalability): there is no need to keep a session store, the token is a self-contained entity that conveys all the user information. The rest of the state lives in cookies or local storage on the client side.
CDN: you can serve all the assets of your app from a CDN (e.g. javascript, HTML, images, etc.), and your server side is just the API.
Decoupling: you are not tied to any particular authentication scheme. The token might be generated anywhere, hence your API can
be called from anywhere with a single way of authenticating those
calls.
Mobile ready: when you start working on a native platform (iOS, Android, Windows 8, etc.) cookies are not ideal when consuming a
token-based approach simplifies this a lot.
CSRF: since you are not relying on cookies, you don't need to protect against cross site requests (e.g. it would not be possible to
sib your site, generate a POST request and re-use the existing authentication cookie because there will be none).
Performance: we are not presenting any hard perf benchmarks here, but a network roundtrip (e.g. finding a session on database)
is likely to take more time than calculating an HMACSHA256 to
validate a token and parsing its contents.
A token is a piece of data which only Server X could possibly have created, and which contains enough data to identify a particular user.
You might present your login information and ask Server X for a token; and then you might present your token and ask Server X to perform some user-specific action.
Tokens are created using various combinations of various techniques from the field of cryptography as well as with input from the wider field of security research. If you decide to go and create your own token system, you had best be really smart.
A token is a piece of data created by server, and contains information to identify a particular user and token validity. The token will contain the user's information, as well as a special token code that user can pass to the server with every method that supports authentication, instead of passing a username and password directly.
Token-based authentication is a security technique that authenticates the users who attempt to log in to a server, a network, or some other secure system, using a security token provided by the server.
An authentication is successful if a user can prove to a server that he or she is a valid user by passing a security token. The service validates the security token and processes the user request.
After the token is validated by the service, it is used to establish security context for the client, so the service can make authorization decisions or audit activity for successive user requests.
Source (Web Archive)
Token Based (Security / Authentication)
This means that in order for us to prove that we’ve access we first have to receive the token. In a real-life scenario, the token could be an access card to the building, it could be the key to the lock to your house. In order for you to retrieve a key card for your office or the key to your home, you first need to prove who you are and that you in fact do have access to that token. It could be something as simple as showing someone your ID or giving them a secret password. So imagine I need to get access to my office. I go down to the security office, I show them my ID, and they give me this token, which lets me into the building. Now I have unrestricted access to do whatever I want inside the building, as long as I have my token with me.
What’s the benefit of token-based security?
If we think back on the insecure API, what we had to do in that case was that we had to provide our password for everything that we wanted to do.
Imagine that every time we enter a door in our office, we have to give everyone sitting next to the door our password. Now that would be pretty bad because that means that anyone inside our office could take our password and impersonate us, and that’s pretty bad. Instead, what we do is that we retrieve the token, of course together with the password, but we retrieve that from one person. And then we can use this token wherever we want inside the building. Of course, if we lose the token, we have the same problem as if someone else knew our password, but that leads us to things like how do we make sure that if we lose the token, we can revoke the access, and maybe the token shouldn’t live for longer than 24 hours, so the next day that we come to the office, we need to show our ID again. But still, there’s just one person that we show the ID to, and that’s the security guard sitting where we retrieve the tokens.
The question is old and the technology has advanced, here is the current state:
JSON Web Token (JWT) is a JSON-based open standard (RFC 7519) for passing claims between parties in web application environment. The tokens are designed to be compact, URL-safe and usable especially in web browser single sign-on (SSO) context.
https://en.wikipedia.org/wiki/JSON_Web_Token
It's just hash which is associated with user in database or some other way. That token can be used to authenticate and then authorize a user access related contents of the application. To retrieve this token on client side login is required. After first time login you need to save retrieved token not any other data like session, session id because here everything is token to access other resources of application.
Token is used to assure the authenticity of the user.
UPDATES:
In current time, We have more advanced token based technology called JWT (Json Web Token). This technology helps to use same token in multiple systems and we call it single sign-on.
Basically JSON Based Token contains information about user details and token expiry details. So that information can be used to further authenticate or reject the request if token is invalid or expired based on details.
When you register for a new website, often you are sent an email to activate your account. That email typically contains a link to click on. Part of that link, contains a token, the server knows about this token and can associate it with your account. The token would usually have an expiry date associated with it, so you may only have an hour to click on the link and activate your account. None of this would be possible with cookies or session variables, since its unknown what device or browser the customer is using to check emails.