Centralized botnets are easy targets for takedown efforts by computer security researchers and law enforcement. Thus, botnet controllers have sought new ways to harden the infrastructures of their botnets. In order to meet this objective, some botnet operators have (re)designed their botnets to use Peer-to-Peer (P2P) infrastructures. Many P2P botnets are far more resilient to takedown attempts than centralized botnets, because they have no single points of failure. However, P2P botnets are subject to unique classes of attacks, such as node enumeration and poisoning. In this paper, we introduce a formal graph model to capture the intrinsic properties and fundamental vulnerabilities of P2P botnets. We apply our model to current P2P botnets to assess their resilience against attacks. We provide assessments on the sizes of all eleven active P2P botnets, showing that some P2P botnet families contain over a million bots. In addition, we have prototyped several mitigation strategies to measure the resilience of existing P2P botnets. We believe that the results from our analysis can be used to assist security researchers in evaluating mitigation strategies against current and future P2P botnets.
Current Control-Flow Integrity (CFI) implementations track control edges individually, insensitive to the context of preceding edges. Recent work demonstrates that this leaves sufficient leeway for powerful ROP attacks. Context-sensitive CFI, which can provide enhanced security, is widely considered impractical for real-world adoption. Our work shows that Context-sensitive CFI (CCFI) for both the backward and forward edge can be implemented efficiently on commodity hardware. We present PathArmor, a binary-level CCFI implementation which tracks paths to sensitive program states, and defines the set of valid control edges within the state context to yield higher precision than existing CFI implementations. Even with simple context-sensitive policies, PathArmor yields significantly stronger CFI invariants than context-insensitive CFI, with similar performance.
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Zeus is a family of credential-stealing trojans which originally appeared in 2007. The first two variants of Zeus are based on centralized command servers. These command servers are now routinely tracked and blocked by the security community. In an apparent effort to withstand these routine countermeasures, the second version of Zeus was forked into a peer-to-peer variant in September 2011. Compared to earlier versions of Zeus, this peer-to-peer variant is fundamentally more difficult to disable. Through a detailed analysis of this new Zeus variant, we demonstrate the high resilience of state of the art peer-to-peer botnets in general, and of peer-to-peer Zeus in particular.
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