Category:Threat Modeling

This category should be used to tag articles that are related to threat modeling.

Overview
The term "Threat Modeling" has become quite popular recently. Microsoft has published a book about their process and includes threat modeling as a key activity in their Secure Development Lifecycle (SDL).

A threat model is essentially a structured representation of all the information that affects the security of an application. In essence, it is a view of the application and its environment through security glasses.

Threat modeling is a process for capturing, organizing, and analyzing all of this information. Threat modeling enables informed decision-making about application security risk. In addition to producing a model, typical threat modeling efforts also produce a prioritized list of security improvements to the concept, requirements, design, or implementation.

Headline text
Objectives of Threat Modeling

Threat modeling is a procedure for optimizing Network/ Application/ Internet Security by identifying objectives and vulnerabilities, and then defining countermeasures to prevent, or mitigate the effects of, threats to the system. A threat is a potential or actual undesirable event that may be malicious (such as DoS attack) or incidental (failure of a Storage Device). Threat modeling is a planned activity for identifying and assessing application threats and vulnerabilities.

Threat Modeling Across the Lifecycle
Threat modeling is best applied continuously throughout a software development project. The process is essentially the same at different levels of abstraction, although the information gets more and more granular throughout the lifecycle. Ideally, a high-level threat model should be defined in the concept or planning phase, and then refined throughout the lifecycle. As more details are added to the system, new attack vectors are created and exposed. The ongoing threat modeling process should examine, diagnose, and address these threats.

Note that it is a natural part of refining a system for new threats to be exposed. For example, when you select a particular technology -- such as Java for example -- you take on the responsibility to identify the new threats that are created by that choice. Even implementation choices such as using regular expressions for validation introduce potential new threats to deal with.

Threat Modeling - Generic Steps
For a threat to an application to exist, there must be a combination of the following where the combined likelihood and impact are important enough to do something about.


 * a threat agent
 * a viable attack
 * a vulnerability not blocked by a countermeasure
 * a negative impact to the business

To understand whether an application is secure enough or not, you have to search out combinations of these ingredients that lead to realistic threats. The real trick to threat modeling is not wasting time on threats that are too unlikely or too inconsequential. Beware threat modeling processes that are inefficient about pruning the search space of possible threats to eliminate threats that are very unlikely or have minimal impact.

There is no "right" way to evaluate the search space of possible threats. But there are "wrong" ways. Attempting to evaluate all the possible combinatations of threat agent, attack, vulnerability, and impact is a waste of time and effort. Note that many of the automated tools take this approach - gathering lots of data and producing thousands of possible threats. Generally it is more productive to focus on finding high likelihood and high impact threats.

The basic threat modeling process consists of the following generic steps. The process of exploring the search space is iterative and constantly refined based on what you have done so far. So, for example, starting with all possible vulnerabilities is usually pointless, as most of them are not attackable by the threat agents, protected by a safeguard, or do not lead to a conseequence. Therefore, it's generally best to start with the factors that make a lot of difference.


 * Identify what needs to be protected - The first step is always to understand what's on the line. Identifying tangible assets, like databases of information or sensitive files is usually easy. Understanding the capabilities provided by the application and valuing them is more difficult. Less concrete things, such as reputation and goodwill are the most difficult to measure, but are often the most critical.


 * Identify threat agents and possible attacks - A key part of the threat model is a characterization of the different groups of people who might be able to attack your application. These groups should include insiders and outsiders, performing both inadvertent mistakes and malicious attacks.


 * Understand existing countermeasures - The model must include the existing countermeasures


 * Identify exploitable vulnerabilities - Once you have an understanding of the security in the application, you can then analyze for new vulnerabilities. The search is for vulnerabilities that connect the possible attacks you've identified to the negative consequences you've identified.


 * Prioritized identified risks - Prioritization is everything in threat modeling, as there are always lots of risks that simply don't rate any attention. For each threat, you estimate a number of likelihood and impact factors to determine an overall risk or severity level.


 * Identify countermeasures to reduce threat - The last step is to identify countermeasures to reduce the risk to acceptable levels.

Benefits
Done right, threat modeling provides a clear "line of sight" across a project that justifies security efforts. The threat model allows security decisions to be made rationally, with all the information on the table. The alternative is to make knee-jerk security decisions with no support. The threat modeling process naturally produces an assurance argument that can be used to explain and defend the security of an application. An assurance argument starts with a few high level claims, and justifies them with either subclaims or evidence.