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Endpoint Advanced Protection Buyer’s Guide: Preventing the Attacks, Part 1

By Mike Rothman

We discussed specific attacks in our last post, so it’s time to examine approaches which can prevent them. But first let’s look at the general life cycle of an attack.

Prevention Timeline

As we dig into how to actually prevent the attacks described in the last post, the key principle is to avoid single points of failure, and then to ensure you have resilience so you can respond and restore normal operations as quickly as possible. You want multiple opportunities to block any attack. The most effective way to plan this out is to think about the attack on a timeline. We want an opportunity to prevent damage before execution, as early as possible during execution, and again in the worst case after execution.

The earlier you can prevent an attack, the better, of course. In a perfect world you stop every attack before it gets anywhere. But, as we all discover seemingly every day, we don’t always get a chance to stop an attack before it starts. Even so, we still need to minimize damage, prevent data loss, and eliminate any attacker beachheads before they can move deeper into our systems. We focus on making sure you have numerous opportunities to determine whether code on a device is acting maliciously, and then block it.

This timeline approach helps us provide failsafes and defense in depth, acknowledging that malware is very sophisticated and combines multiple attack types, which can change depending on the defenses in place on an endpoint. Let’s work through the techniques you can use to prevent attacks at every stage.

We will describe each technique, and then go enumerate its pros and cons.

Pre-execution

The best time to prevent an attack is before it starts, and there are multiple ways to evaluate code about to run on a device to determine whether it’s malicious.

  • Hygiene: This is a catch-all term to indicate proper strong configurations implemented on devices. Many organizations don’t consider these endpoint security controls, but the fact is that if you can block attacks by not leaving vulnerabilities on devices, that is pre-execution prevention.

    Patching: Keeping devices updated with the most recent patches prevents attackers from taking advantage of known vulnerabilities.
    Strong configurations: Each device should also be built from a strong configuration which disables unnecessary services and provides the device user with the minimum privilege to perform their job.
    Host firewall: Each device should have an operational firewall to prevent network attacks, blocking both non-standard protocols and traffic to known bad destinations.
    Host Intrusion Prevention: The firewall is to ensure unauthorized sites cannot communicate with the device (access control), and HIPS is about looking for attack patterns within the endpoint’s network stack. This is especially important for detecting reconnaissance and lateral movement.
    Device control: Finally, devices should be configured to disable capabilities such as USB storage to prevent introduction of malicious code via physical mechanisms.

    Pros: Hygiene is all about reducing device attack surface and removing low-hanging fruit to make things difficult for attackers. If by patching a system you can make their job harder, do that. If by shutting down USB ports you can prevent a social engineer from installing malware on a device via physical media, do that.
    Cons: Hygiene is a very low bar for protection. Even though you reduce attack surface, adversaries still have plenty of tactics available to compromise devices. Endpoint hygiene is necessary but not sufficient.

  • File signatures: The most traditional endpoint defense involves a blacklist of known malicious file hashes and determining whether any file is on that list before allowing execution on a device. With billions of malicious files in circulation, it’s impractical to store all those file hashes on every device, or to search all those hashes every time a file executes, so integrating with a threat intelligence service to check file hashes which aren’t in the local cache is critical.

    Pros: Fool me once, shame on you. Fool me twice… File signatures are still used because it’s pathetic to be compromised by something you know is malicious and have seen before. The challenge is to leverage signatures efficiently, given the sheer number of items that need to be on any blacklist.
    Cons: It’s trivial to change the file hash of a malicious file. So the effectiveness of signature matching is abysmal, which is why every endpoint prevention offering uses additional techniques.

  • Static analysis: Malicious files can have file attributes which indicate they are bad. These attributes include whether a file packer has been used (to change the hash), header details, embedded resources, inconsistent file metadata, etc. Static file analysis examines each file before execution, searching for these indicators. Endpoint prevention vendors typically use machine learning to analyze billions of malware files, searching for attributes which likely indicate malicious files. We will discuss machine learning later in this Buyer’s Guide.

    Pros: Static analysis is cheap and easy. Each endpoint prevention agent has a set of attributes to look for, and can quickly scan every file for those attributes before execution.
    Cons: As sophisticated as the machine learning models are which identify attributes likely to indicate a malicious file, this approach can have a high false positive rate. Static analysis is generally a coarse filter, used to determine whether a file warrants further analysis to determine whether it’s malicious.

  • Whitelisting: The last pre-execution approach to mention is whitelisting. This entails assembling a list of all authorized files which can run on a device, and blocking anything not on the list. Malware is inherently unauthorized, so this is a good way to ensure only legitimate software runs.

    Pros: For devices without much variation in which applications run (such as customer support workstations and kiosks), whitelisting is a very powerful approach and can significantly reduce attack surface. Modern attacks involve downloading additional executables once the device is compromised, so even if a device is initially compromised an attacker should be unable to get additional malware files to run. Some solutions also enlist whitelisting as a supplementary technique to reduce the number of false positives returned by static analysis.
    Cons: It can be time consuming to manage the whitelist, given the number of new applications employees need to run on devices and frequent updates and changes to application executables. Processes to deal with exceptions (when an employee needs access to an unauthorized application) must be reliable and fast, as an employee can lose productivity if they cannot load a needed application.

In summary there are plenty of opportunities for organizations to block malware before it can execute. These approaches require disciplined and effective operational processes, which can be challenging at scale. But even if an attack is missed before it executes, there are numerous opportunities to block it later.

We will discuss runtime and post-execution options tomorrow.

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