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Difference between revisions of "Attack Surface Analysis Cheat Sheet"
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This is where you are most exposed to attack. Then understand what compensating controls you have in place, operational controls like network firewalls and application firewalls,and intrusion detection or prevention systems to help protect your app. | This is where you are most exposed to attack. Then understand what compensating controls you have in place, operational controls like network firewalls and application firewalls,and intrusion detection or prevention systems to help protect your app. | ||
− | Michael Howard at Microsoft and other researchers have developed a method for measuring the | + | Michael Howard at Microsoft and other researchers have developed a method for measuring the Attack Surface of an application, and to track changes to the Attack Surface over time, called the [http://www.cs.cmu.edu/~wing/publications/Howard-Wing03.pdf Relative Attack Surface Quotient (RSQ)]. Using this method you calculate an overall attack surface score for the system, and measure this score as changes are made to the system and to how it is deployed. Researchers at Carnegie Mellon built on this work to develop a formal way to calculate an [http://www.cs.cmu.edu/~pratyus/tse10.pdf Attack Surface Metric] for large systems like SAP. They calculate the Attack Surface as the sum of all entry and exit points, channels (the different ways that clients or external systems connect to the system, including TCP/UDP ports, RPC end points, named pipes...) and untrusted data elements. Then they apply a damage potential/effort ratio to these Attack Surface elements to identify high-risk areas. |
= Managing the Attack Surface = | = Managing the Attack Surface = | ||
− | Once you have a baseline understanding of the Attack Surface, can use it to incrementally identify and manage risks going forward as you make changes to the application. Ask yourself: | + | Once you have a baseline understanding of the Attack Surface, you can use it to incrementally identify and manage risks going forward as you make changes to the application. Ask yourself: |
* What has changed? | * What has changed? | ||
* What are you doing different? (technology, new approach, ….) | * What are you doing different? (technology, new approach, ….) | ||
* What holes could you have opened? | * What holes could you have opened? | ||
− | If you add another | + | The first web page that you create opens up the system’s Attack Surface significantly and introduces all kinds of new risks. If you add another field to that page, or another web page like it, while technically you have made the Attack Surface bigger, you haven’t increased the risk profile of the application in a meaningful way. Each of these incremental changes is more of the same, unless you follow a new design or use a new framework. |
+ | |||
+ | If you add another web page that follows the same design and using the same technology as existing web pages, it's easy to understand how much security testing and review it needs. If you add a new web services API or file that can be uploaded from the Internet, each of these changes have a different risk profile again - see if if the change fits in an existing bucket, see if the existing controls and protections apply. If you're adding something that doesn't fall into an existing bucket, this means that you have to go through a more thorough risk assessment to understand what kind of security holes you may open and what protections you need to put in place. | ||
+ | |||
+ | Changes to session management and authentication and password management directly affect the Attack Surface and need to be reviewed. So do changes to authorization and access control logic, especially adding or changing role definitions, adding admin users or admin functions with high privileges. Changes to the code that handles encryption and secrets. Fundamental changes to how data validation is done. And major architectural changes to layering and trust relationships, or fundamental changes in technical architecture – swapping out your web server or database platform, or changing the run-time OS. | ||
As you add new user types or roles or privilege levels, you do the same kind of analysis and risk assessment. Overlay the type of access across the data and functions and look for problems and inconsistencies. It's important to understand the access model for the application, whether it is positive (access is deny by default) or negative (access is allow by default). In a positive access model, any mistakes in defining what data or functions are permitted to a new user type or role are easy to see. In a negative access model,you have to be much more careful to ensure that a user does not get access to data/functions that they should not be permitted to. | As you add new user types or roles or privilege levels, you do the same kind of analysis and risk assessment. Overlay the type of access across the data and functions and look for problems and inconsistencies. It's important to understand the access model for the application, whether it is positive (access is deny by default) or negative (access is allow by default). In a positive access model, any mistakes in defining what data or functions are permitted to a new user type or role are easy to see. In a negative access model,you have to be much more careful to ensure that a user does not get access to data/functions that they should not be permitted to. | ||
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This kind of threat or risk assessment can be done periodically, or as part of design work in serial / phased / spiral / waterfall development projects, or continuously and incrementally in Agile / iterative development. | This kind of threat or risk assessment can be done periodically, or as part of design work in serial / phased / spiral / waterfall development projects, or continuously and incrementally in Agile / iterative development. | ||
− | Normally, an application's Attack Surface will increase over time as you add more interfaces and user types and integrate with other systems. You also want to look for ways to minimize the Attack Surface area | + | Normally, an application's Attack Surface will increase over time as you add more interfaces and user types and integrate with other systems. You also want to look for ways to [[Minimize_attack_surface_area minimize the Attack Surface area]], reducing the size of the Attack Surface when you can by simplifying the model (reducing the number of user levels for example or not storing confidential data that you don't absolutely have to), turning off features and interfaces that aren't being used, by introducing operational controls such as a WAF. |
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= Other Cheatsheets = | = Other Cheatsheets = |
Revision as of 17:59, 27 August 2012
Introduction
First draft work in progress - very rough
This article describes a simple and pragmatic way of doing Attack Surface Analysis and managing an application's Attack Surface. It is designed to be used by developers to understand and manage application security risks as they design and change an application, as well as by application security specialists doing a security risk assessment.
Attack Surface Analysis is about mapping out what parts of a system need to be reviewed and tested for security vulnerabilities. The point of Attack Surface Analysis is to understand the risk areas in an application, to make developers and security specialists aware of what parts of the application are open to attack, to find ways of minimizing this, and to notice when and how the Attack Surface changes and what this means from a risk perspective.
Attack Surface Analysis helps you to:
- identify what you need to review/test for security vulnerabilities
- identify high risk areas of code that require defense-in-depth protection
- identify when you’ve changed the attack surface and need to do some kind of threat assessment
Defining the Attack Surface of an Application
The Attack Surface describes all of the different points where an attacker could get into a system, and where they could get data out.
The Attack Surface of an application is:
- the sum of all paths for data/commands into and out of the application, and
- the code that protects these paths (including resource connection and authentication, authorization, activity logging, data validation and encoding); and
- all confidential and sensitive data used in the application, including secrets and keys, critical business data and PII, and
- the code that protects these data (including encryption and checksums, access auditing, and data integrity and operational security controls).
You overlay this model with the different types of users - roles, privilege levels - that can use the system. Complexity increases with the number of different types of users. But it is important to focus especially on the two extremes: unauthenticated, anonymous users and highly privileged admin users.
Group each type of attack point into buckets based on risk (Internet-facing or internal-facing), purpose, implementation, design and technology. You can then count the number of attack points of each type, then choose some cases for each type, and focus your review/assessment on those cases.
With this approach, you don't need to understand every endpoint in order to understand the Attack Surface and the potential risk profile of a system. Instead, you can count the different general type of endpoints and the number of points of each type. With this you can budget what it will take to assess risk at scale, and you can tell when the risk profile of an application has significantly changed.
Understanding, mapping and defining the Attack Surface
You can start by capturing the Attack Surface baseline in a picture and notes. Spend a few hours reviewing design and architecture documents from an attacker's perspective. Identify different points of entry/exit:
- UI forms and fields
- APIs
- Sockets
- Files
- Databases
- ….?
The number of different attack points can easily add up into the thousands or more. To make this manageable, break the model into different types based on function and technology:
- Login/authentication entry points
- Admin interfaces
- Inquiry forms
- Data entry/CRUD forms
- Shopping/business flow forms…
- Operational command interfaces
You can also build up a picture of the Attack Surface by scanning the application. For web apps you can use a tool like Arachni or Skipfish or w3af or one of the many commercial dynamic testing and vulnerability scanning tools or services to crawl your app and map the parts of the application that are accessible over the web.
The Attack Surface model may be rough and incomplete to start, especially if you haven’t done any security work on the application before. Use what you have and fill in the holes as the team makes changes to the Attack Surface.
Measuring and Assessing the Attack Surface
Once you have a map of the Attack Surface, identify the high risk areas. Focus on remote entry points – interfaces with outside systems and to the Internet – and especially where the system allows anonymous, public access.
- Network-facing, especially internet-facing code
- Web forms – rich text input fields (hard to validate)
- Files from outside of the network
- Backwards compatible interfaces with other systems – old protocols, sometimes old code and libraries, hard to maintain and test multiple versions
- Custom APIs – protocols etc – likely to have mistakes in design and implementation
- Security code: anything to do with crypto, authentication and session management
This is where you are most exposed to attack. Then understand what compensating controls you have in place, operational controls like network firewalls and application firewalls,and intrusion detection or prevention systems to help protect your app.
Michael Howard at Microsoft and other researchers have developed a method for measuring the Attack Surface of an application, and to track changes to the Attack Surface over time, called the Relative Attack Surface Quotient (RSQ). Using this method you calculate an overall attack surface score for the system, and measure this score as changes are made to the system and to how it is deployed. Researchers at Carnegie Mellon built on this work to develop a formal way to calculate an Attack Surface Metric for large systems like SAP. They calculate the Attack Surface as the sum of all entry and exit points, channels (the different ways that clients or external systems connect to the system, including TCP/UDP ports, RPC end points, named pipes...) and untrusted data elements. Then they apply a damage potential/effort ratio to these Attack Surface elements to identify high-risk areas.
Managing the Attack Surface
Once you have a baseline understanding of the Attack Surface, you can use it to incrementally identify and manage risks going forward as you make changes to the application. Ask yourself:
- What has changed?
- What are you doing different? (technology, new approach, ….)
- What holes could you have opened?
The first web page that you create opens up the system’s Attack Surface significantly and introduces all kinds of new risks. If you add another field to that page, or another web page like it, while technically you have made the Attack Surface bigger, you haven’t increased the risk profile of the application in a meaningful way. Each of these incremental changes is more of the same, unless you follow a new design or use a new framework.
If you add another web page that follows the same design and using the same technology as existing web pages, it's easy to understand how much security testing and review it needs. If you add a new web services API or file that can be uploaded from the Internet, each of these changes have a different risk profile again - see if if the change fits in an existing bucket, see if the existing controls and protections apply. If you're adding something that doesn't fall into an existing bucket, this means that you have to go through a more thorough risk assessment to understand what kind of security holes you may open and what protections you need to put in place.
Changes to session management and authentication and password management directly affect the Attack Surface and need to be reviewed. So do changes to authorization and access control logic, especially adding or changing role definitions, adding admin users or admin functions with high privileges. Changes to the code that handles encryption and secrets. Fundamental changes to how data validation is done. And major architectural changes to layering and trust relationships, or fundamental changes in technical architecture – swapping out your web server or database platform, or changing the run-time OS.
As you add new user types or roles or privilege levels, you do the same kind of analysis and risk assessment. Overlay the type of access across the data and functions and look for problems and inconsistencies. It's important to understand the access model for the application, whether it is positive (access is deny by default) or negative (access is allow by default). In a positive access model, any mistakes in defining what data or functions are permitted to a new user type or role are easy to see. In a negative access model,you have to be much more careful to ensure that a user does not get access to data/functions that they should not be permitted to.
This kind of threat or risk assessment can be done periodically, or as part of design work in serial / phased / spiral / waterfall development projects, or continuously and incrementally in Agile / iterative development.
Normally, an application's Attack Surface will increase over time as you add more interfaces and user types and integrate with other systems. You also want to look for ways to Minimize_attack_surface_area minimize the Attack Surface area, reducing the size of the Attack Surface when you can by simplifying the model (reducing the number of user levels for example or not storing confidential data that you don't absolutely have to), turning off features and interfaces that aren't being used, by introducing operational controls such as a WAF.
Other Cheatsheets
OWASP Cheat Sheets Project Homepage