History of Cyber Threat Intelligence

In 1986, Cliff Stoll was a PhD student managing the computer lab at Lawrence Berkley National Laboratory in California when he noticed a billing discrepancy in the amount of 75 cents, indicating that someone was using the laboratory’s computer systems without paying for it. Our modern-day, network-security-focused brains see this and scream, “Unauthorized access!” but in 1986 it was hardly cause for concern. Network intrusions were not something that made the news daily, with claims of millions or even billions of dollars stolen; the majority of computers connected to the “internet” belonged to government and research institutes, not casual users. The network defense staple tool tcpdump was a year from being started. Common network discovery tools such as Nmap would not be created for another decade, and exploitation frameworks such as Metasploit would not appear for another 15 years. The discrepancy was just as likely to have been a software bug or bookkeeping error as it was that someone had simply not paid for their time.

Except that it wasn’t. As Stoll would discover, he was not dealing with a computer glitch or a cheap mooch of a user. He was stalking a “wily hacker” who was using Berkley’s network as a jumping-off point to gain access to sensitive government computers, such as the White Sands Missile Range and the National Security Agency (NSA). Stoll used printers to monitor incoming network traffic and began to profile the intruder responsible for the first documented case of cyber espionage. He learned the typical hours the attacker was active, the commands he ran to move through the interconnected networks, and other patterns of activity. He learned how the attacker was able to gain access to Berkley’s network in the first place by exploiting a vulnerability in the movemail function in GNU Emacs, a tactic that Stoll likened to a cuckoo bird leaving its egg in another bird’s nest to hatch and which inspired the name of the book on the intrusion, The Cuckoo’s Egg. Understanding the attacker meant that it was possible to protect the network from further exploitation, identify where he may target next, and allowed a response, both on the micro level (identifying the individual carrying out the attacks) and on the macro level (realizing that nations were employing new tactics in their traditional intelligence-gathering arsenal and changing policies to respond to this change).

Modern Cyber Threat Intelligence

Over the decades, the threat has grown and morphed. Adversaries use an ever-expanding set of tools and tactics to attack their victims, and their motivations range from intelligence collection to financial gain to destruction to attention. Understanding the attacker has gotten much more complicated, but no less important.

Understanding the attacker has been a critical component of incident response from the beginning, and knowing how to identify and understand the attacker as well as how to use that information to protect networks is the fundamental concept behind a more recent addition to the incident responder’s toolkit: cyber threat intelligence. Threat intelligence is the analysis of adversaries—their capabilities, motivations, and goals; and cyber threat intelligence (CTI) is the analysis of how adversaries use the cyber domain to accomplish their goals. See Figure 1-1 on how these levels of attacks play into one another.

Figure 1-1. From intelligence to cyber threat intelligence

In information security, we traditionally focus on scientific concepts; we like things that are testable and reproducible. But there is both an art and a science behind cyber threat intelligence, and it is the art that most often eludes us. This art includes the analysis and interpretation of data about attackers, as well as how to convey that information to the audience in a way that makes sense and enables them to act. This is what will truly help us understand a thinking, reacting, and evolving adversary.

Security analysts love few things more than identifying malicious activity on their networks and tracing that maliciousness back to a known attacker, but in many cases early implementation of intelligence was ad hoc and largely intuitive. Over the years, new technologies were developed with the goal of better detecting and understanding malicious activity on networks: Network Access Control, Deep Packet Inspection firewalls, and network security intelligence appliances are all based on familiar concepts with new applications.

The Way Forward

These new technologies give us more information about the actions that attackers take as well as additional ways to act on that information. However, we have found that with each new technology or concept implemented, the enemy adapted; worms and viruses with an alphabet soup of names changed faster than our appliances could identify them, and sophisticated, well-funded attackers were more organized and motivated than many network defenders. Ad hoc and intuitive intelligence work would no longer suffice to keep defenders ahead of the threat. Analysis would need to evolve as well and become formal and structured. The scope would have to expand, and the goals would have to become more ambitious.

In addition to detecting threats against an organization’s often nebulous and ephemeral perimeter, analysts would need to look deeper within their networks for the attacks that got through the lines, down to individual user systems and servers themselves, as well as look outward into third-party services and to better understand the attackers who may be targeting them. The information would need to be analyzed and its implications understood, and then action would have to be taken to better prevent, detect, and eradicate threats. The actions taken to better understand adversaries would need to become a formal process and a critical part of information security operations: threat intelligence.

Operation SMN

A good example of this is the analysis of the Axiom Group, which was identified and released as a part of a Coordinated Malware Eradication (CME) campaign in 2014 called Operation SMN.

For more than six years, a group of attackers known as the Axiom Group stealthily targeted, infiltrated, and stole information from Fortune 500 companies, journalists, nongovernmental organizations, and a variety of other organizations. The group used sophisticated tools, and the attackers went to great lengths to maintain and expand access within the victims’ networks. As malware was detected and the incident-response process began within various victim organizations, coordinated research on one of the malware families used by this group identified that the issue was far more complex than originally thought. As more industry partners became involved and exchanged information, patterns began to emerge that showed not just malware behavior, but the behaviors of a threat actor group working with clear guidance. Strategic intelligence was identified, including regions and industries targeted.

This was an excellent example of the intelligence cycle at work in an incident-response scenario. Not only was information collected, processed, and analyzed, but it was disseminated in such as way as to generate new requirements and feedback, starting the process over again until the analysts had reached a solid conclusion and could act with decisiveness, eradicating 43,000 malware installations at the time that the report was published. The published report, also part of the dissemination phase, allowed incident responders to better understand the tactics and motivations of this actor group. 

Operation Aurora

Several years before the Axiom Group was identified, another (possibly related) group carried out a similarly complex operation named Operation Aurora, which successfully targeted approximately 30 companies. This operation impacted companies in the high-tech sector as well as defense contractors, the chemical sector, and Chinese political dissidents. The patterns and motivations of the operation were similar to those in Operation SMN. Looking at these two examples of elaborate and widespread attacks, it becomes clear that these weren’t random but rather were coordinated with strategic objectives by a determined adversary willing to expend a great deal of time and effort to ensure that the objectives were met. If we tackle the problem by jumping from incident to incident without stopping to capture lessons learned and to look at the big picture, then the attackers will always be several steps ahead of us.

Both the Axiom Group attacks and Operation Aurora were information-seeking, espionage-related attacks, but nation-state sponsored attackers aren’t the only thing that incident responders have to worry about. Financially motivated criminal activity is also evolving, and those actors are also working hard to stay ahead of defenders and incident responders.