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I'm doing some basic security work for an application. The user logs in and their credentials are validated via active directory. There comes certain times in the program where the user requests changes that cause the program to restart. As this is not a single instance program I simply launch another instance and close the current one and everything is fine.

However, user's aren't happy that they have to re-login every time it restarts. So I pieced together some basic security using SecureString to store the password in the application, then if the application is restarted it decrypts the password and re-encrypts it using an implementation of Rijndael's algorithm from (very basic from codeproject). Then it passes the username and encrypted password as command line parameters to the new instance that's starting. (The encryption being needed because from them on any call of "wmic process" would show the password just hanging out). The new instance decrypts it and again validates against active directory silently, then stores it as a SecureString like normal.

I'm not too familiar with general security practices but I'm just a little nervous about the part where the password is returned from the decryption method. It's not being stored in any variable per se, the call is made right in the active directory validation request. But I'm still not sure if it's somewhere accessible in memory or if it's just hanging out in a register.

This doesn't need to be the greatest security ever, it just needs to be more of a discouragement to anyone who would easily access the contents of memory and see a password saved in cleartext.

Many thanks!

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The problem isn't passing the credentials - it's with decrypting them, which the original instance has to do anyway. The decrypted string won't be hanging around in a register, since String is a reference type rather than a value type - the decrypted string will be in the heap and accessible to memory-peekers. –  prprcupofcoffee Nov 16 '12 at 21:04
I see. Well since it would be visible anyway, should I forget about SecureString and store the password in cleartext in the application, and just use the basic Rijndael for when it needs to be passed as a command parameter? (just because it would be so easy for someone to sit down at anyone's computer and use see it with wmic process). –  Wrightboy Nov 16 '12 at 21:17
The important thing in computer security is knowing where the weakest point is. If just anyone can sit down at a logged-in computer, they can plug in a thumb drive and play all kinds of merry havoc. SecureString is meant to allow encrypted passwords to travel from a web app's web.config file over to SQL Server without ever being decrypted - within a Windows Forms app, you have little choice but to decrypt it eventually, so try to keep it in memory the least possible amount of time. –  prprcupofcoffee Nov 16 '12 at 21:35
Oh okay, that make sense. If I'm understanding you right, regardless of what encrpytion method I take, when decrpyting (since it's a string) it will always be accessible in the memory until it get's overwritten (there shouldn't be anything causing it to persist). I suppose in that case since it still has to be stored in the application somehow, I'll still throw out SecureString, but I'll also do the Rijndael encryption on it and then store it in the program. In a way it makes it easier as now I don't have to go from SecureString to the Rijndael, and then back. Thank you, you're most helpful. –  Wrightboy Nov 16 '12 at 21:45
Doesnt active directory support the use of tickets? Such that you can relogin with the ticket? –  user180326 Nov 16 '12 at 22:39

3 Answers 3

up vote 1 down vote accepted

Function return values are, in .NET apps, pushed onto an "evaluation stack", which resides in protected memory within the process. However, you're talking about a string, and that's a reference type, so what's on the evaluation stack is a pointer to that string's location on the heap. Heap memory is relatively insecure because it can be shared, and because it lives as long as the GC doesn't think it needs to be collected, unlike the evaluation or call stacks which are highly volatile. But, to access heap memory, that memory must be shared, and your attacker must have an app with permission from the OS and CLR to access that memory, and that knows where to look.

There are much easier ways to get a plaintext password from a computer, if an attacker has that kind of access. A keylogger can watch the password being typed in, or another snooper could watch the actual handle on the unmanaged side of the GDI UI and see the textbox that's actually displayed in the Windows GUI get the plaintext value (it's only obfuscated on the display). All that without even trying to crack .NET's code access security or protected memory.

If your attacker has this kind of control, you have lost. Therefore, that should be the first line of defense; make sure there is no such malware on the client computer, and that the instance of your client app that the user is attempting to log into has not been replaced with a cracked lookalike.

As far as obfuscated password storage between instances, if you're worried about mem-snooping, a symmetric algorithm like Rijndael is no defense. If your attacker can see the client computer's memory, he knows the key that was used to encrypt it because your application will need to know it in order to decrypt it; it will thus either be hard-coded into the client app or it will be stored near the secure string. Again, if your attacker has this kind of control, you have lost if you do your authentication client-side.

I would, instead, use a service layer on a physically and electronically secured machine to provide any functionality of your app that would be harmful to you if misused by an attacker (primarily data retrieval/modification). That service layer could be used both to authenticate and to authorize the user to perform whatever the client app would allow.

Consider the following:

  • The user enters their credentials into your client app. These credentials can be the same as the AD credentials but they will not be used as such. The only way to prevent a keylogger or other malware seeing this is to ensure that no such malware exists on the computer, through enforcement of a good AV software.
  • The client app connects to your service endpoint through WCF. The endpoint can be signed with an X.509 certificate; not NSA-level security, but at least you can be confident you're talking to the server under your control.
  • The client app then hashes your user's password with something that produces a large digest, like SHA-512. This in itself is not secure; it's too fast and the entropy of your user's password is too low, to prevent an attacker cracking the hash. However, again, they have to have control of the computer to see the hash, and we're going to further obfuscate it.
  • The client app transmits the username, password and the Hardware ID of the client computer over the WCF channel.
  • The server gets these credentials. Notice that the server doesn't get a plaintext password; this is for a reason.
  • The server cuts the hashed password into 256-bit halves. The first half is then BCrypted (using an implementation configured to be suitably slow; 10 or 11 "rounds" will usually do it), and compared with a hashed value in a user database. If they match, the DB returns the user's AD credentials, which have been symmetrically encrypted with the other half of the password hash. This is why a plaintext password is never sent; the server doesn't have to know it, but an attacker would in order to get anything meaningful out of a stolen copy of the user database.
  • The server decrypts the AD credentials, submits them to AD, and receives the IPrincipal representing that user's identity and security context. The IPrincipal implementation will contain zero information that could be used to crack the user's account.
  • The server generates a cryptographically-random 128-bit value, concatenates the 128-bit Hardware GUID, and hashes it with SHA512. It used half of that hash to symmetrically encrypt the key value that was used to decrypt the AD credentials. It then BCrypts the other half, and stores that hash beside the encrypted key.
  • The server then transmits back three pieces of information over the secure WCF channel; the IPrincipal that AD produced, the unhashed 128-bit random value (the "transfer token"), and another cryptographically-random value of arbitrary length (the "session token").
  • The client app is now authenticated on the client side, meaning you can control user access to code by interrogating the IPrincipal for AD role membership, and the server is now also confident that the user who has the session token is a real user. When making any further calls to the service (data retrieval/persistence), the client should use the WCF channel that was negotiated, AND pass its session token. The combination of WCF channel and session token is one-time and unique; using an old token on a new channel, or passing the wrong token on the same channel, indicates the session has been compromised. Above all, none of the persistent data stored anywhere at anytime in either client or server can be used to get the AD credentials and authenticate.

Now, when your client application closes, all "session state" is lost between client and server; the session token is not valid for any other negotiated channel. So, you've lost authentication; the next client who connects could be anyone regardless of who they say they are. This is where the "transfer token" comes in:

  • The "transfer token" is a free pass back into the system. It is one-time, and expires if unused 18 hours after it was issued.
  • The client application, when closing, passes two pieces of information to the new instance (however it chooses to do so); the user name of the person who logged in, and the "transfer token".
  • The new instance of the client application takes these two pieces of information, and also gets the Hardware ID of the client machine. It negotiates a secure connection with the WCF service, and passes these three pieces of information.
  • If the user last logged in more than 18 hours ago (not 24 hours, so they can't show up a minute before they did yesterday and restart the app), or if you want to be really paranoid, more than 8 hours ago, the app immediately returns an error that the transfer token for that account is out of date.
  • The service takes the transfer token, concatenates the Hardware ID, SHA-512s it, BCrypts half, and compares the result to the stored second verification value. Only the proper combination of the transfer token and the machine that last logged in will produce the correct hash. If it matches, the other half of the hash is used to decrypt the key that will then decrypt the AD info.
  • The service then proceeds as if the user had provided the application password hash, decrypting the AD info, retrieving the IPrincipal, generating a new transfer token, session token, and re-encrypting the key for the AD data.
  • If any part of this process fails (trying to use an incorrect token including using the same token twice, or using the token from a different machine or for a different user), the service reports back that the credentials are invalid. The client app will then fall back to the standard user-password verification.

Here's the rub; this system, by relying on a secret password that is not persisted anywhere except the user's mind, has no back doors; administrators cannot retrieve a lost password to the client app. Also, the AD credentials, when they have to change, can only be changed from within the client app; the user can't be forced to change their password by AD itself on a Windows login, because doing so will destroy the authentication scheme they need to get into the client app (the encrypted credentials will no longer work, and the client app credentials are needed to re-encrypt the new ones). If you were somehow able to intercept this validation inside AD, and the client's app credentials were the AD credentials, you could change the credentials in the user app automatically, but now you're using one set of credentials to obfuscate the same set of credentials, and if that secret were known you're hosed.

Lastly, this variant of this security system functions solely on one principle; that the server is not currently being compromised by an attacker. Someone can get in, download offline data, and they're stuck; but if they can install something to monitor memory or traffic, you're hosed, because when the credentials (either username/password hash or transfer token/hardware ID) come in and are verified, the attacker now has the key to decrypt the user's AD credentials. Usually, what happens is that the client never sends the decryption key, only the verification half of the hashed password, and then the server sends back the encrypted credentials; but, you are considering the client to be a bigger security risk than the server, so as long as that is true, it's best to keep as little plaintext as possible on the client for any length of time.

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Thank you for answering my original question as well as providing such a detailed course of further action. Oddly enough some of the systems are locked inside cases with only the us/other IT personnel having access. Unfortunately what you're proposing sounds like a fairly intensive change to the program. Yeah, the key being used is just the current user's ID+the date and is only hardcoded as much as anything else (calculated at encrypt/decrypt time and not stored), rendering it invalid the following day. I may leave what's done in there, but I see now that going further requires going all in. –  Wrightboy Nov 16 '12 at 23:33
Pretty much. For most companies, it's sufficient to require login to the system either from the hard-wired LAN or through a VPN, in order to access the datastores of the client application (without which the client's pretty much useless). –  KeithS Nov 16 '12 at 23:49

What is your attack model?

  1. If you assume the server is owned by an attacker you have lost in all cases.
  2. If you assume the server is safe you don't need any encryption at all.

So I guess my recommendation is to drop all server-side encryptions you are doing because you assume that the server is safe anyway. Nobody can access the memory of your server, and if someone could you'd be owned anyway.

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I fundamentally disagere with this. You should add defenses wherever you can, so that, if one defense is overcome, there's another waiting (otherwise known as defense in depth). To be fair, though, I don't have any better options to present. –  zimdanen Nov 16 '12 at 21:44
@zimdanen In general your statement is corrent but building defenses against the server being owned is hopeless. This is a completely unrealistic scenario to defend against. Invest your time somewhere else where it earns a return, like actually securing the server with the same amount of time invested. –  usr Nov 16 '12 at 21:53
In all fairness, it was mostly to try and deter any script kiddies who would sit down at another employee's computer and try and easily obtain there password. So in that sense securing the application itself from giving it up too easily is in fact the goal here. So I would like to have some kind of protection on the users password, especially when it's getting passed around as a command param. –  Wrightboy Nov 16 '12 at 22:04

Take a look at this: Password Salt (Wikipedia)

To summarize the approach:

  1. When you want to store password P to disk, generate a random string S (called the salt) and then store the tuple (S, SHA1Hash(P + S)).
  2. When you want to check a password attempt P' against the stored password, compare SHA1Hash(P' + S) to the stored hash.
  3. When you pass around this password attempt you have, pass around only the hashed version, i.e., SHA1Hash(P' + S).
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This is very nice but I don't think it fits what I'm after. Hashing is more for preserving a password for the sole purpose of comparisons at a later time. I'm trying to preserve the password for the purpose of actually re-using that same password to auto-login if application itself called a restart. So hashing it wouldn't do me much good, because I need to be able to get the actual password back to validate with AD. Thank you though! :) –  Wrightboy Nov 16 '12 at 22:51
If you are doing this and want to use SHA1, you should at least implement PKDF2, not a single SHA1 hash. –  Billy ONeal Nov 17 '12 at 15:47
"PKDF2" does not show up on Google search. What is it? –  Timothy Shields Nov 17 '12 at 19:23

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