I’m at SHB 2009, which brings security engineers together with psychologists, behavioral economists and others interested in deception, fraud, fearmongering, risk perception and how we make security systems more usable. Here is the agenda.
This workshop was first held last year, and most of us who attended reckoned it was the most exciting event we’d been to in some while. (I blogged SHB 2008 here.) In followups that will appear as comments to this post, I’ll be liveblogging SHB 2009.
I’ve been writing a lot about privacy in social networks, and sometimes the immediacy gets lost during the more theoretical debates. Recently though I’ve been investigating a massive privacy breach on Facebook’s application platform which serves as a sobering case study. Even to me, the extent of unauthorised data flow I found and the cold economic motivations keeping it going were surprising. Facebook’s application platform remains a disaster from a privacy standpoint, dampening one of the more compelling features of the network.
One of the defining features of Web 2.0 is user-uploaded content, specifically photos. I believe that photo-sharing has quietly been the killer application which has driven the mass adoption of social networks. Facebook alone hosts over 40 billion photos, over 200 per user, and receives over 25 million new photos each day. Hosting such a huge number of photos is an interesting engineering challenge. The dominant paradigm which has emerged is to host the main website from one server which handles user log-in and navigation, and host the images on separate special-purpose photo servers, usually on an external content-delivery network. The advantage is that the photo server is freed from maintaining any state. It simply serves its photos to any requester who knows the photo’s URL.
This setup combines the two classic forms of enforcing file permissions, access control lists and capabilities. The main website checks each request for a photo against an ACL, it then grants a capability to view a photo in the form of an obfuscated URL which can be sent to the photo-server. We wrote earlier about how it was possible to forge Facebook’s capability-URLs and gain unauthorised access to photos. Fortunately, this has been fixed and it appears that most sites use capability-URLs with enough randomness to be unforgeable. There’s another traditional problem with capability systems though: revocation. My colleagues Jonathan Anderson, Andrew Lewis, Frank Stajano and I ran a small experiment on 16 social-networking, blogging, and photo-sharing web sites and found that most failed to remove image files from their photo servers after they were deleted from the main web site. It’s often feared that once data is uploaded into “the cloud,” it’s impossible to tell how many backup copies may exist and where, and this provides clear proof that content delivery networks are a major problem for data remanence. (more…)
A number of UK banks are distributing hand-held card readers for authenticating customers, in the hope of stemming the soaring levels of online banking fraud. As the underlying protocol — CAP — is secret, we reverse-engineered the system and discovered a number of security vulnerabilities. Our results have been published as “Optimised to fail: Card readers for online banking”, by Saar Drimer, Steven J. Murdoch, and Ross Anderson.
In the paper, presented today at Financial Cryptography 2009, we discuss the consequences of CAP having been optimised to reduce both the costs to the bank and the amount of typing done by customers. While the principle of CAP — two factor transaction authentication — is sound, the flawed implementation in the UK puts customers at risk of fraud, or worse.
When Chip & PIN was introduced for point-of-sale, the effective liability for fraud was shifted to customers. While the banking code says that customers are not liable unless they were negligent, it is up to the bank to define negligence. In practice, the mere fact that Chip & PIN was used is considered enough. Now that Chip & PIN is used for online banking, we may see a similar reduction of consumer protection.
Further information can be found in the paper and the talk slides.
(co-authored with Robert Watson)
Recently, our group was treated to a presentation by Ruby Lee of Princeton University, who discussed novel cache architectures which can prevent some cache-based side channel attacks against AES and RSA. The new architecture was fascinating, in particular because it may actually increase cache performance (though this point was spiritedly debated by several systems researchers in attendance). For the security group, though, it raised two interesting and troubling questions. What is the proper defence against side-channels due to processor cache? And why hasn’t it been implemented despite these attacks being around for years?
Back in December I wrote an article here on the “Technical aspects of the censoring of Wikipedia” in the wake of the Internet Watch Foundation’s decision to add two Wikipedia pages to their list of URLs where child sexual abuse images are to be found. This list is used by most UK ISPs (and blocking systems in other countries) in the filtering systems they deploy that attempt to prevent access to this material.
A further interesting censoring issue was in the news last month, and this article (a little belatedly) explains the technical issues that arose from that.
For some time, the IWF have been adding URLs from The Internet Archive (widely known as “the wayback machine“) to their list. I don’t have access to the list and so I am unable to say how many URLs have been involved, but for several months this blocking also caused some technical problems.
(more…)
Last March, Facebook caught some flak when some hacks circulated showing how to access private photos of any user. These were enabled by egregiously lazy design: viewing somebody’s private photos simply required determining their user ID (which shows up in search results) and then manually fetching a URL of the form:
www.facebook.com/photo.php?pid=1&view=all&subj=[uid]&id=[uid]
This hack was live for a few weeks in February, exposing some photos of Facebook CEO Mark Zuckerberg and (reportedly) Paris Hilton, before the media picked it up in March and Facebook upgraded the site.
Instead of using properly formatted PHP queries as capabilities to view photos, Faceook now verifies the requesting user against the ACL for each photo request. What could possibly go wrong? Well, as I discovered this week, the photos themselves are served from a separate content-delivery domain, leading to some problems which highlight the difficulty of building access control into an enormous, globally distributed website like Facebook.
Many crypto protocols contain variable length fields: the names of the participants, different sizes of public key, and so on.
In my previous post, I mentioned how Liqun Chen has (re)discovered the attack that many protocols are broken if you don’t include the field lengths in MAC or signature computations (and, more to the point, a bunch of ISO standards fail to warn the implementor about this issue).
The problem applies to confidentiality, as well as integrity.
Many protocol verification tools (ProVerif, for example) will assume that the attacker is unable to distinguish enc(m1, k, iv) from enc(m2, k, iv) if they don’t know k.
If m1 and m2 are of different lengths, this may not be true: the length of the ciphertext leaks information about the length of the plaintext. With Cipher Block Chaining, you can tell the length of the plaintext to the nearest block, and with stream ciphers you can tell the exact length. So you can have protocols that are “proved” correct but are still broken, because the idealized protocol doesn’t properly represent what the implementation is really doing.
If you want different plaintexts to be observationally equivalent to the attacker, you can pad the variable-length fields to a fixed length before encrypting. But if there is a great deal of variation in length, this may be a very wasteful thing to do.
The alternative approach is to change your idealization of the protocol to reflect the reality of your encryption primitive. If your implementation sends m encrypted under a stream cipher, you can idealize it as sending an encrypted version of m together with L_m (the length of m) in the clear.
At the end of last week, Microsoft Research hosted a meeting of “Cryptoforma”, a proposed new project (a so-called “network of excellence”) to bring together researchers working on applying formal methods to security. They don’t yet know whether or not this project will get funding from the EPSRC, but I wish them good luck.
There were several very interesting papers presented at the meeting, but today I want to talk about the one by Liqun Chen, “Parsing ambiguities in authentication and key establishment protocols”.
Some of the protocol specifications published by ISO specify how the protocol should be encoded on the wire, in sufficient detail to enable different implementations to interoperate. An example of a standard of this type is the one for the public key certificates that are used in SSL authentication of web sites (and many other applications).
The security standards produced by one group within ISO (SC27) aren’t like that. They specify the abstract protocols, but give the implementor considerable leeway in how they are encoded. This means that you can have different implementations that don’t interoperate. If these implementations are in different application domains, the lack of interoperability doesn’t matter. For example, Tuomas Aura and I recently wrote a paper in which we presented a protocol for privacy-preserving wireless LAN authentication, which we rather boldly claim to be based on the abstract protocol from ISO 9798-4.
You could think of these standards as separating concerns: the SC27 folks get the abstract crypto protocol correct, and then someone else standardises how to encode it in a particular application. But does the choice of concrete encoding affect the protocol’s correctness?
Liqun Chen points out one case where it clearly does. In the abstract protocols in ISO 9798-4 and others, data fields are joined by a double vertical bar operator. If you want to find out what that double vertical bar really means, you have to spend another 66 Swiss Francs and get a copy of ISO 9798-1, which tells you that Y || Z means “the result of the concatenation of the data items Y and Z in that order”.
Oops.
When we specify abstract protocols, it’s generally understood that the concrete encoding that gets signed or MAC’d contains enough information to unambigously identify the field boundaries: it contains length fields, a closing XML tag, or whatever. A signed message {Payee, Amount} K_A should not allow a payment of $3 to Bob12 to be mutated by the attacker into a payment of $23 to Bob1. But ISO 9798 (and a bunch of others) don’t say that. There’s nothing that says a conforming implementation can’t send the length field without authentication.
No of course, an implementor probably wouldn’t do that. But they might.
More generally: do these abstract protocols make a bunch of implicit, undocumented assumptions about the underlying crypto primitives and encodings that might turn out not to be true?
See also: Boyd, C. Hidden assumptions in cryptographic protocols. Computers and Digital Techniques, volume 137, issue 6, November 1990.
The beginning of a Call of Duty 4 Search and Destroy game is essentially a race. When the game starts, experienced players all make a mad dash from the starting post, head for their preferred defensive or offensive positions, to dig in before the enemy can bring their guns to bear. From these choice spots, they engage the enemy within seconds, and despite moderately large maps which are a few hundred metres across, up to a third of the kills in a 3-5 minute game do take place in the first 15 seconds. Of course there is skill in figuring out what to do next (the top 1% of players distinguish themselves through adaptability and quick thinking), but the fact remains that the opening of an S&D match is critically important.
I have previously posted about “Neo-Tactics” - unintended side-effects of low-level game algorithms which create competitive advantage. Once a player seems to win without a visible justification this sort of effect causes a problem - it creates the perception of cheating. At a second level, actual cheats might deliberately manipulate their network infrastructure or game client to take advantage of the effect. Well I think I might have found a new one…
The screenshots below give a flavour of the sort of sneaky position that players might hope to be first to reach, affording a narrow but useful line of sight through multiple windows and doorways, crossing most of the map. NB: Seasoned COD4 players will laugh at my choice of so-called sneaky position, but I am a novice and I cannot hope to reach the ingenious hideouts they have discovered after years of play-testing.
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