This time of year, we usually find ourselves reflecting on the great freedoms we enjoy as Americans, thanks to the bravery of our founding fathers. Recent alleged revelations made public by NSA whistleblower Edward Snowden foreshadow a rising threat to the Constitution which was put in place to protect these freedoms, including 4th Amendment protection from unreasonable searches. Technology can be used by some to search and seize your digital identity and private correspondence, but remember that you also have access to technology that you can easily use to protect yourself.
Digital Privacy in the Light of the NSA Whistleblower
There has been quite a buzz around the power of the alleged NSA eavesdropping considering the insights that the NSA Whistleblower, Edward Snowden, presented to the American public.
The NSA Whistleblower exposed how our digital identities are being captured, stored, analyzed, and categorized, allegedly by NSA, as well as companies that publicly state that they store and analyze your data (Facebook, Linkedin, Google email, etc.). The power of the NSA system, according to Snowden, is that they aggregate your digital communications across telephone, internet, web, mobile app, and email data.
With regards to email, email encryption works, to keep your email message content private. As The Guardian reported on Monday, June 17, the NSA Whistleblower said:
“Encryption works. Properly implemented strong crypto systems are one of the few things that you can rely on.”
But, encryption is a broad term. Not all email encryption and methods of use are the same, in terms of privacy. Not all are “strong crypto systems”.
What type of “encryption” works, for whom, what, and when?
“Caesar Cipher” and “Pig Latin” are Forms of Encryption
Suppose Alice wants to send a secret message to her friend Bob but worries that her snoopy Big Brother may intercept it. Alice needs a way to scramble her message so that only Bob can read it. A simple way to do this would be for Alice to replace each letter in her message with the next highest letter; shifting it by one (think “Caesar Cipher” or “Pig Latin”).
But, of course, that is too simple. If Big Brother intercepts the message he’ll be able to easily decipher it by looking for hidden patterns in the letters it contains. All it will take to crack the code is a little mathematics and a little trial and error.
And, of course, if Big Brother uses a computer he’ll be able to crack the code even faster. So just shifting the first letter to the end and adding “ay” as a suffix (turning “HELLO” into “ELLOHAY” for example) isn’t a very strong cipher. What can Alice do?
Well, she can try to think up a more complicated mathematical formula to scramble the letters and numbers. And maybe she could use a computer herself to apply the formula. This will help, but the problem is still that if Big Brother hires clever mathematicians, or if he just has a big enough computer, he will be able to crack the code eventually. So it looks like it’s going to be an arms race with Big Brother to see who can come up with the biggest computers and the most complicated formula. But because Big Brother is big, it is a race Alice and Bob are bound to lose.
What is Considered “Strong Crypto”?
Then, what did the NSA Whistleblower mean by “strong crypto systems” when he said, according to The Guardian, “Properly implemented strong crypto systems are one of the few things that you can rely on.”
We have established that more complex patterns used to encrypt are harder to read by Big Brother but capable of being read if Big Brother has a powerful computer to figure out the pattern; yet easy for Bob to read with knowledge of the pattern (the decryption key). Most technicians understand that more complex algorithms are harder to “crack”, or said another way, take more computing power to crack.
How does Computing Power Impact the Time to Crack the Encryption?
Let’s consider the example of using computing power to try to guess a 10 digit seemingly random alpha numeric password, such as: tjo9i0982d using a “Brute Force” attack (i.e. trial and error). This would be similar to trying to find a pattern in a universe of combinations of 36 digits (26 possible letters and 10 possible numbers). According to Gibson Research Corporation, in this example, there are 3700 trillion combinations, and the time to guess and test the right combination using trial and error in an online environment is one thousand centuries (assuming one thousand guesses per second). However, in what Gibson Research calls a “Massive Cracking Array Scenario” with one hundred trillion guesses per second offline, this password can be guessed in just 38 seconds.
Computing power does matter. But, not many, if any (today), can implement a “Massive Cracking Array Scenario”.
Is Today’s Commercial Encryption Readable by the NSA with its Computing Power?
This is a question that clearly some people know the answer to. I do not. Most commercial encryption uses algorithms that the NSA has “approved” for “civilian, unclassified, non-national security systems.” These algorithms are what encrypt your email or financial transactions when using email encryption or secure HTTP web based connections with commercially available systems. Some of these NSA approved (unclassified) algorithms include DES, Triple DES, AES, DSA and SHA.
Note: it is not only use of encryption that is important, but as Snowden added, “properly implemented strong crypto systems.” Those who encrypt email should be sure to use “properly implemented strong crypto systems”.
So, let’s explore this notion of “properly implemented strong crypto systems.”
Security by Obscurity
Bringing this back to Bob and Alice, or you and me, would our use of commercial (NSA approved for unclassified use) encryption be strong enough for our general commercial purposes? I suppose you could consider it so, as long as those who you think may be trying to read your information do not have the computing power, financial resources, and incentive to try to crack the method of encryption you use in your correspondence. To get a sense of the scale in terms of NSA computing power, NPR reported that the NSA is putting the finishing touches on its biggest data farm yet, a $1.2 billion complex in Utah with 1.5 million square feet of top secret space including high-performance NSA computers alone filling up 100,000 square feet.
So, unless (or until, since the NSA Whistleblower says your messages are saved just in case they later need to be read) you elevate yourself the importance of your electronic correspondence to the level that makes your information interesting to the people with this power, your commercially encrypted email should remain private enough…
But if private enough is not good enough, if you are encrypting FOR personal privacy, you should use “properly implemented strong crypto systems” that also consider endpoint security.
As The Guardian reported, the NSA Whistleblower added, “Encryption works… Unfortunately, endpoint security is so terrifically weak that NSA can frequently find ways around it.” What does Snowden mean by this? A properly implemented strong crypto system should take into account the endpoints, as well as the transmission.
Google Has an Easier Way to Read Your Email
Take Google as an example with your laptop as the endpoint. Google allegedly provides information to NSA and other government organizations upon request, and also perhaps others, depending on how you interpret what they disclose on their website privacy policies. (A quick glance at Google’s privacy policiesare revealing.) Google discloses: “Local storage: We may collect and store information (including personal information) locally on your device using mechanisms such as browser web storage (including HTML 5) and application data caches” and further “may combine personal information from one service with information, including personal information, from other Google services.”
So, for example, if you take great care to type your email in a Gmail compose page, encrypt the transmission, and then send, you are forgetting that Google may be recording, storing, analyzing, and cross referencing the content of the message you type before you encrypt it (as well as perhaps other personal information on your computer or mobile device).
So, for those encrypting for privacy, endpoint security should be evaluated. Note, you can somewhat control your endpoint security by choices you make, but what about the encrypted email recipient’s endpoint security?
What to Do to Keep Your Email Private
So, where does this leave us in the new light of the NSA Whistleblower (and Google privacy disclosures)?
The endpoint security is the most likely source of data exposure; meaning, it may be far less computer intensive to access the metadata stored on your computer hard drive every time you type, or access the messages stored in your mailbox on your desktop, mobile device, email server, or internet mail service provider host before encryption when composing, or after decryption, after reading.
If you use commercial encryption for email, you should consider strong crypto systems that take into account providing endpoint security, in particular at the recipient’s end, which is out of your control.
There are generally three types of systems to commercially encrypt email today:
- Public Key Exchange – Secure but Complex for Many. Exchanging public encryption keys among your contacts (PKI Digital Certificates) and using Microsoft Outlook on your desktop computer is a “strong crypto system”, but has proven to be too cumbersome for most to purchase and install these certificates, manage the expiration, ensure your recipients have a copy of your public key and you theirs, and all are using a compatible email program such as Microsoft Outlook desktop software.
- Secure Store and Forward – “Man in the Middle” Problems. Systems that store your message content in the middle, and send a link to the recipients to download the content, are often used, but are not considered “strong crypto systems”, as your most sensitive information is now stored on a third party server with unknown data security and message purge practices (which may differ from their stated policies). Further, there is no protection from unknown recipient endpoint security or lack thereof. Note, systems that wrap your email in an encrypted HTML file and send, often purport themselves to be “direct delivery” but leave out the important point that the process of decrypting, is often sending the data back to the server in the middle, and that server storing the decrypted message and displaying it in a web browser (with the same Man in the Middle storage purge concerns). Further, there is no protection from unknown recipient endpoint security or lack thereof. This is better than simple Secure Store and Forward but still has Man in the Middle issues, and for these reasons, these are also not considered “strong crypto systems.”
- True Direct Delivery – Best Method. Systems that wrap the message in an encrypted PDF file are “strong crypto systems” as (a) the message content is not stored in the middle, (b) content is truly delivered to the recipients’ desktops encrypted, AND (c) the content remains encrypted at the recipient endpoint to prevent potential disclosure regardless of the recipient endpoint security. Systems that make this method easy to use and implement for both sender and recipient become the true best method “strong crypto systems” for email encryption (for both compliance and personal privacy).
About the Author: Zafar Khan is the chief executive officer of RPost (www.rpost.com). RPost, winner of the World Mail Award for best in security, provides what is described here as True Direct Delivery strong crypto systems that are simple to use and install with no storage by RPost. Both government and commercial organizations have relied on RPost email encryption all over the world, as part of its RMail® service offering (video and free trial click here). RPost has been offering secure electronic messaging services for more than 10 years.