Preventing CSRF and XSS Attacks with JWT and Fingerprint Cookies in Express

kurtchan

Kurt De Austria

Posted on October 1, 2024

Preventing CSRF and XSS Attacks with JWT and Fingerprint Cookies in Express

When building a full-stack web application, the communication between your client and server are at risk with different vulnerabilities such as XSS (Cross-Site Scripting), CSRF (Cross-Site Request Forgery) and Token Sidejacking. As a web developer, knowing such vulnerabilities and how to prevent them is highly essential.

Since I am also trying to learn and prevent this vulnerabilities in my APIs, these guides are also my reference in creating this article and this are all worth reading:


First, let’s define the three vulnerabilities as mentioned before.

XSS (Cross-Site Scripting)

According to OWASP.org

Cross-Site Scripting (XSS) attacks are a type of injection, in which malicious scripts are injected into otherwise benign and trusted websites. XSS attacks occur when an attacker uses a web application to send malicious code, generally in the form of a browser side script, to a different end user. Flaws that allow these attacks to succeed are quite widespread and occur anywhere a web application uses input from a user within the output it generates without validating or encoding it.

CSRF (Cross-Site Request Forgery)

According to OWASP.org

Cross-Site Request Forgery (CSRF) is an attack that forces an end user to execute unwanted actions on a web application in which they’re currently authenticated. With a little help of social engineering (such as sending a link via email or chat), an attacker may trick the users of a web application into executing actions of the attacker’s choosing. If the victim is a normal user, a successful CSRF attack can force the user to perform state changing requests like transferring funds, changing their email address, and so forth. If the victim is an administrative account, CSRF can compromise the entire web application.

Token Sidejacking

According to JWT Cheatsheet

This attack occurs when a token has been intercepted/stolen by an attacker and they use it to gain access to the system using targeted user identity.


When I was starting out creating a Full-Stack application using Angular and Laravel. I used JSON Web Tokens (JWT) for authentication, it is easy to use but also easy to exploit if not implemented properly. Common mistakes I did was:

1. Storing tokens in the local storage

Local storage is a common choice since it can be easily retrieve and access from JavaScript , it is also persistent which means it does not deletes whenever the tab or the browser is closed, makes it highly vulnerable to Cross-Site Scripting (XSS) attacks.

Example:

If an XSS attack injects the following into your site:

console.log(localStorage.getItem('jwt_token'));
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2. Long TTL (Time to Live) of Token

JWTs have a TTL, and if not configured properly in Laravel, by default, the token is set to 3600 seconds (1 hour), giving hackers an open and wide opportunity to steal the token and use it to act as the victim until the token expires.

3. No Refresh tokens

A refresh token allows the user to get a new access token without having to reauthenticate. TTL plays a crucial role in tokens, a longer TTL is a security risk as mentioned before, but a shorter TTL will make a bad user experience, forcing them to log in again.


We will create a basic React + Express application to apply and mitigate these vulnerabilities. To better understand the output of the application that we will be doing refer to the diagram below.

Authentication

When authentication, the user will send username and password and POST it to the /login API to verify. Upon logging in, the server will:

  1. Verify credentials in the database

    The user credentials in JSON format will be checked in the database for authentication.

  2. Generate User Fingerprint

    Generating a random byte fingerprint for the verified user and store it in a variable.

  3. Hash the Fingerprint

    The generated fingerprint will be hashed and stored in a different variable.

  4. Creating a Cookie for the Generated Fingerprint (Original fingerprint)

    The unhashed fingerprint will be set in a hardened cookie with the name __Secure_Fgp with flags: httpOnly, secure, sameSite=Strict and maxAge of 15mins.

  5. Creating a token for the User credentials with the Hashed Fingerprint

    Generating a JWT token for the verified user with its hashed fingerprint.

  6. Creating a cookie for the token

    After generating JWT token, the token will be sent as a cookie.

After the process, there will be 2 cookies will be sent, the original fingerprint of the user, and the generated token containing the data with the hashed fingerprint of the user.
Authentication

Accessing the protected route

When an authenticated user accessed the protected route. A middleware will verify the cookies of the user.

  1. Fetching cookies

    The middleware of the server will fetch the 2 cookies from the client upon request.

  2. Verify the JWT

    Using JWT token, it will verify the token from the fetched cookie. Extract the data inside the JWT (e.g. User details, fingerprint etc.)

  3. Hash the __Secure_Fgp cookie and compare it to the fingerprint from the payload JWT token.

Middleware

Now for the implementation


Server-Side (Express JS)

Here are all the libraries that we need:

  • jsonwebtoken

    For generating, signing and verifying JWT Tokens

  • crypto

    To generate random bytes and hashing fingerprints

  • cookie-parser

    For parsing Cookie header and creating cookies

  • cors

    Configuring CORS policy

  • csurf

    Generating CSRF Tokens

Set up

npm init -y //Initate a node project
// Installing dependencies
npm install express nodemon jsonwebtoken csurf crypto cookie-parser cors
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Create a server.js file

Create a server.js file and edit the package.json, write "start": "nodemon server.js" under the scripts object.

  "scripts": {
    "test": "echo \"Error: no test specified\" && exit 1",
    "start": "nodemon server.js"
  },
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Set up the server

Since we are using JWT, we’re gonna need a HMAC key


const express = require('express');
const jwt = require('jsonwebtoken');
const crypto = require('crypto');
const cookieParser = require('cookie-parser');
const cors = require('cors')
const csrf = require('csurf');
const csrfProtection = csrf({ cookie: true });

const app = express();

// MIDDLEWARES ======================================================
// Middleware to parse JSON bodies and Cookies
app.use(express.json());
app.use(cookieParser());

// Middleware to parse URL-encoded bodies (as sent by HTML forms)
app.use(express.urlencoded({ extended: true }));

// Middleware to apply CORS
const corsOptions = {
    origin: 'http://localhost:5173',  // Your React app's URL
    credentials: true  // Allow credentials (cookies, authorization headers)
};
app.use(cors(corsOptions));

const keyHMAC = crypto.randomBytes(64);  // HMAC key for JWT signing

// API ======================================================

// we'll add our routes here

// Start the Express server
app.listen(3000, () => {
    console.log('Server running on https://localhost:3000');
});
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After setting up the Express server, we can start by creating our /login API.

Create a login API

I did not used database for this project, but feel free to modify the code.

app.post('/login', csrfProtection, (req, res) => {
        // Fetch the username and password from the JSON
    const { username, password } = req.body;

    // Mock data from the database
    // Assuming the user is registered in the database
    const userId = crypto.randomUUID();
    const user = {
        'id': userId,
        'username': username,
        'password': password,
    }

    res.status(200).json({
        message: 'Logged in successfully!',
        user: user
    });
});
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Generate a user fingerprint

Assuming that the user is registered in the database, First, we’re gonna need two functions, one for generating a random fingerprint and hashing the fingerprint.

/* 
.
. ... other configurations
.
*/
const keyHMAC = crypto.randomBytes(64);  // HMAC key for JWT signing

// Utility to generate a secure random string
const generateRandomFingerprint = () => {
    return crypto.randomBytes(50).toString('hex');
};

// Utility to hash the fingerprint using SHA-256
const hashFingerprint = (fingerprint) => {
    return crypto.createHash('sha256').update(fingerprint, 'utf-8').digest('hex');
};
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As discussed earlier, we are going to generate a fingerprint for the user, hash that fingerprint and set it in a cookie with the name __Secure_Fgp..

Then generate a token with the user’s details (e.g. id, username and password) together with the original fingerprint, not the hashed one since we are going to use that for verification of the token later.

    const userId = crypto.randomUUID();
    const user = {
        'id': userId,
        'username': username,
        'password': password,
    }

    const userFingerprint = generateRandomFingerprint();  // Generate random fingerprint
    const userFingerprintHash = hashFingerprint(userFingerprint);  // Hash fingerprint

    // Set the fingerprint in a hardened cookie
    res.cookie('__Secure_Fgp', userFingerprint, {
        httpOnly: true,
        secure: true,  // Send only over HTTPS
        sameSite: 'Strict',  // Prevent cross-site request
        maxAge: 15 * 60 * 1000  // Cookie expiration (15 minutes)
    });

    const token = jwt.sign(
        {
            sub: userId,  // User info (e.g., ID)
            username: username,
            password: password,
            userFingerprint: userFingerprintHash,  // Store the hashed fingerprint in the JWT
            exp: Math.floor(Date.now() / 1000) + 60 * 15  // Token expiration time (15 minutes)
        },
        keyHMAC // Signed jwt key
    );

    // Send JWT as a cookie
    res.cookie('token', token, {
        httpOnly: true,
        secure: true,
        sameSite: 'Strict',
        maxAge: 15 * 60 * 1000
    });

    res.status(200).json({
        message: 'Logged in successfully!',
        user: user
    });
});
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After log in, it will pass two cookies, token and __Secure_Fgp which is the original fingerprint, into the front end.

Create middleware for authenticating of token

To validate that, we are going to create a middleware for our protected route. This middleware will fetch the two cookies first and validate, if there are no cookies sent, then it will be unauthorized.

If the token that was fetched from the cookie is not verified, malformed or expired, it will be forbidden for the user to access the route.

and lastly, it will hash the fingerprint from the fetched cookie and verify it with the hashed one.

// Middleware to verify JWT and fingerprint match
const authenticateToken = (req, res, next) => {
    const token = req.cookies.token;
    const fingerprintCookie = req.cookies.__Secure_Fgp;

    if (!token || !fingerprintCookie) {
        return res.status(401).json({
            status: 401,
            message: "Error: Unauthorized",
            desc: "Token expired"
        });  // Unauthorized
    }

    jwt.verify(token, keyHMAC, (err, payload) => {
        if (err) return res.status(403).json({
            status: 403,
            message: "Error: Forbidden",
            desc: "Token malformed or modified"
        });  // Forbidden

        const fingerprintHash = hashFingerprint(fingerprintCookie);

        // Compare the hashed fingerprint in the JWT with the hash of the cookie value
        if (payload.userFingerprint !== fingerprintHash) {
            return res.status(403).json({
                status: 403,
                message: "Forbidden",
                desc: "Fingerprint mismatch"
            });  // Forbidden - fingerprint mismatch
        }

        // Return the user info
        req.user = payload;
        next();
    });
};
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To use this middleware we are going to create a protected route. This route will return the user that we fetched from the verified token in our middleware.

/* 
.
. ... login api
.
*/

// Protected route
app.get('/protected', authenticateToken, (req, res) => {
    res.json({ message: 'This is a protected route', user: req.user });
});

// Start the Express server
app.listen(3000, () => {
    console.log('Server running on https://localhost:3000');
});
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With all of that set, we can now try it on our front end…


Client-Side integration (React + TS)

For this, I used some dependencies for styling. It does not matter what you used, the important thing is that we need to create a form that will allow the user to login.

I will not create a step by step in building a form, instead, I will just give the gist of the implementation for the client side.

In my React app, I used shadcn.ui for styling.

// App.tsx
<section className="h-svh flex justify-center items-center">
        <Form {...form}>
          <form onSubmit={form.handleSubmit(onSubmit)} className="space-y-8 p-7 rounded-lg w-96 border border-white">
            <h1 className="text-center font-bold text-xl">Welcome</h1>
            <FormField
              control={form.control}
              name="username"
              render={({ field }) => (
                <FormItem>
                  <FormLabel>Username</FormLabel>
                  <FormControl>
                    <Input placeholder="Username" {...field} />
                  </FormControl>
                  <FormMessage />
                </FormItem>
              )}
            />
            <FormField
              control={form.control}
              name="password"
              render={({ field }) => (
                <FormItem>
                  <FormLabel>Password</FormLabel>
                  <FormControl>
                    <Input type="password" placeholder="Password" {...field} />
                  </FormControl>
                  <FormMessage />
                </FormItem>
              )}
            />
            <Button type="submit" className="mr-4">Login</Button>
            <Link to={"/page"} className='py-2 px-4 rounded-lg bg-white font-medium text-black'>Go to page</Link>
          </form>
        </Form>
      </section>
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This is a simple login form with a button that will navigate the user to the other page that will fetch the protected route.

When the user click submit, it will POST request to the /login API in our server. If the response is success, it will navigate to the page.

 // App.tsx
  const onSubmit = async (values: z.infer<typeof formSchema>) => {
    console.log(values)
    try {
      const res = await fetch("http://localhost:3000/login", {
        method: 'POST', // Specify the HTTP method
        headers: {
          'Content-Type': 'application/json', // Set content type
        },
        credentials: 'include', // Include cookies in the request
        body: JSON.stringify(values), // Send the form data as JSON
      });
      if (!res.ok) {
        throw new Error(`Response status: ${res.status}`)
      }
      const result = await res.json();
      navigate("/page") // navigate to the page
      console.log(result);
    } catch (error) {
      console.error(error);
    }
  }
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In the other page, it will fetch the /protected API to simulate an authenticated session of the user.

const fetchApi = async () => {
        try {
            const res = await fetch("http://localhost:3000/protected", {
                method: 'GET', // Specify the HTTP method
                headers: {
                    'Content-Type': 'application/json', // Set content type
                },
                credentials: 'include', // Include cookies in the request
            });

            if (!res.ok) {
                // Throw error
                throw res
            }
            // Fetch the response
            const result = await res.json();
            setUser(result.user);
            console.log(result)
        } catch (error: any) {
            setError(true)
            setStatus(error.status)
        }
    }
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Make sure to put credentials: ‘include’ in the headers to include cookies upon request.

To test, run the app and look into the Application tab of the browser.

// React
npm run dev

// Express
npm start
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Under Application tab, go to cookies and you can see the two cookies that the server generated.
Application tab

Token is good for 15 mins, and after that the user will need to reauthenticate.

With this, you have the potential prevention of XSS (Cross-Site Scripting) and Token Sidejacking into your application. This might not guarantee a full protection but it reduces the risks by setting the cookie based on the OWASP Cheat sheet.

res.cookie('__Secure_Fgp', userFingerprint, {
    httpOnly: true,
    secure: true,  // Send only over HTTPS
    sameSite: 'Strict',  // Prevent cross-site request
    maxAge: 15 * 60 * 1000
});
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How about Cross-Site Request Forgery (CSRF) prevention?

For the CSRF, we are going to tweak a few things on our server side using this:

const csrf = require('csurf');
const csrfProtection = csrf({ cookie: true });
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then we’ll add it to the middleware

// MIDDLEWARES ======================================================
// Middleware to parse JSON bodies and Cookies
app.use(express.json());
app.use(cookieParser());
// Middleware to parse URL-encoded bodies (as sent by HTML forms)
app.use(express.urlencoded({ extended: true }));

// Middleware to apply CORS
const corsOptions = {
    origin: 'http://localhost:5173',  // Your React app's URL
    credentials: true  // Allow credentials (cookies, authorization headers)
};
app.use(cors(corsOptions));

// Middleware to apply csrf protection
app.use(csrfProtection);
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Create a CSRF Token API

For this we’ll need an API that will generate a CSRF Token and passed it as a cookie to the front end.

app.get('/csrf-token', (req, res) => { // Generate a CSRF token
    res.cookie('XSRF-TOKEN', req.csrfToken(), { // Sends token as a cookie
        httpOnly: false,
        secure: true,
        sameSite: 'Strict'
    });
    res.json({ csrfToken: req.csrfToken() });
});
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Take note that this csrfProtection will only apply to the POST, PUT, DELETE requests, anything that will allow user to manipulate sensitive data. So for this, we’ll just secure our login endpoint with CSRF.

// Login route to generate JWT and set fingerprint
app.post('/login', csrfProtection, (req, res) => {
    const { username, password } = req.body;

    // Mock data from the database
    const userId = crypto.randomUUID();
    const user = {
        'id': userId,
        'username': username,
        'password': password,
    }

    /*
    .
    . other code
    .
    */
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Generate the CSRF Token in the front end

We need to make a GET request to the /csrf-token API and save the token in our local storage.

// App.tsx
  useEffect(() => {
    const fetchCSRFToken = async () => {
      const res = await fetch('http://localhost:3000/csrf-token', {
        method: 'GET',
        credentials: 'include'  // Send cookies with the request
      });
      const data = await res.json();
      localStorage.setItem('csrfToken', data.csrfToken);
      setCsrfToken(data.csrfToken)
    };

    fetchCSRFToken();
  }, [])
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I know, I know… we just talked about the security risk of putting tokens in a local storage. Since there are many ways to mitigate such attacks, common solution would be to refresh this token or just store it in the state variable. For now, we are going to store it in the local storage.

This will run when the component loads. everytime the user visits the App.tsx, it will generate a new CSRF Token.

Now since our /login API is protected with CSRF, we must include the CSRF-Token in the headers upon logging in.

  const onSubmit = async (values: z.infer<typeof formSchema>) => {
    console.log(values)
    try {
      const res = await fetch("http://localhost:3000/login", {
        method: 'POST', // Specify the HTTP method
        headers: {
          'Content-Type': 'application/json', // Set content type
          'CSRF-Token': csrfToken // adding the csrf token
        },
        credentials: 'include', // Include cookies in the request
        body: JSON.stringify(values), // Send the form data as JSON
      });
      if (!res.ok) {
        throw new Error(`Response status: ${res.status}`)
      }
      const result = await res.json();
      navigate("/page") // navigate to the page
      console.log(result);
    } catch (error) {
      console.error(error);
    }
  }
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Now, when the App.tsx load, we can now see the Cookies in our browser.

Apptab

The XSRF-TOKEN is our generated token from the server, while the _csrf is the token generated by the csrfProtection = csrf({ cookie: true });

Here is the full code of the application.
https://github.com/Kurt-Chan/session-auth-practice

Conclusion

This might not give a full protection to your app but it reduce the risks of XSS and CSRF attacks in your website. To be honest, I am new to this integrations and still learning more and more about this.

If you have questions, feel free to ask!

THANK YOU FOR READING!

💖 💪 🙅 🚩
kurtchan
Kurt De Austria

Posted on October 1, 2024

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