I just read an article saying that passwords with 7 characters are no longer safe. However, if the server increases the time to retry a login attempt after each login attempt, then brute force attacks are useless. How do you create such logic in asp.net? Somehow I guess the server side code needs to remember the ip-address that tried to login and should increase the response time with each new try?
IP address isn't really a secure method of identifying the user. You could try storing the last time a login attempt was submitted in a cookie, but if the browser doesn't accept them, it'll be of limited use. Session variables also require cookies, so they're out.
Some sites (yahoo comes to mind) start showing a Captcha form after the third or so attempt. You have to correctly answer the captcha in addition to your login details.
Another option would be to disable an account after X failed attempts (which can be tracked in your database), but I personally dislike this as it tends to force me to call someone to get my password reset whenever I forget one.
ASP.NET has a built-in mechanism to prevent brute force attacks against login passwords. Refer to the maxInvalidPasswordAttempts Membership property.
IMHO 7 character passwords are perfectly adequate for most web applications (my bank allows 7 char passwords) provided security best practices are followed, such as securely hashing passwords and blocking brute force attacks.
Once you get beyond 7 or 8 character passwords, you are really saying "my app needs to be super secure", in which case you ought to consider individual client SSL certificates. Requiring more characters in a password has diminishing returns. How many of your users can remember complex 8 or 9 character passwords? They end up writing them down. Personally, I get turned away by any site that requires me to create some super-complex password.
ASP.NET Membership does most of the hard work around security for you, as long as it is setup properly.
However, there are some things ASP.NET Membership cannot do for you, such as:
- Ensuring HTTPS is used
- Preventing CSRF and similar attacks
- Ensuring all web requests are routed to ASP.NET to prevent static content being served up by IIS and bypassing ASP.NET authentication
- Checking that the user is a human (CAPTCHA)
For more on security best practices I'd look at OWASP
There appear to be at least three attacks you might want to worry about:
- Targeted attack at a particular user. You want to make logging in more difficult for the attackee, but not too much more difficult. A CAPTCHA is sufficient (but don't make the user type in the password again if it wasn't displayed on the login page).
- Large-scale attack on many users. Locking out individual users is a bit pointless, since the attacker can just try (say) 3 passwords and then move on to a different account. A CAPTCHA per IP might be sufficient, but you may also want to rate-limit per-IP (or X-Forwarded-For for a list of whitelisted proxies). This depends on the size of your attacker's botnet; a large enough botnet can distribute attacks over multiple bots/sites such that each site gets a low rate from each IP.
- Offline attack on the password database. In this case, you need at least about 50 bits of entropy even with a good hash (NTLM uses a single call of MD4 which is not a good hash), which you can't get in a relatively normal 8-character password (8 log2(94) is only 52.4).
You could store tries-per-IP into a tree, where you group dense parts of the tree together. Then just bucketize it (construct a new tree every 10 minutes, keep the old tree around for 10 more minutes). This has the possibly mistaken assumption that neighbouring IPs are likely to exhibit similar behaviour, but downgrades gracefully into just clustering the IPv4 into (say) /24's.
If you're feeling particularly generous, you can store a separate cookie on login that's not cleared on logout, and save a copy in the database (a 128-bit random value should be good enough). On a login attempt, be "nicer" to the browser if it presents the correct cookie (e.g. allow 3 attempts on that cookie without counting per-IP or per-user failure rate). This means that the last machine used to access the account isn't presented with a CAPTCHA even when the user's account is being bruteforced.
In general, it's more useful to talk about password entropy than password length and "types of characters" — I'm pretty sure nearly everyone just makes the first letter capital and sticks a 1 on the end. I've also yet to see any "human-friendly" password generators that also state password entropy.