Difference between revisions of "OWASP Mobile Security Project"
|Line 15:||Line 15:|
= Mobile Tools =
= Mobile Tools =
= Mobile Security Testing =
= Mobile Security Testing =
Revision as of 08:40, 22 May 2013
- Project Overview
- Top Ten Mobile Risks
- The Mobile Top Ten 2016
- Mobile Tools
- Mobile Security Testing
- Mobile Cheat Sheet Series
- Secure Mobile Development
- Top Ten Mobile Controls
- OWASP Mobile Threat Model Project
The OWASP Mobile Security Project is a centralized resource intended to give developers and security teams the resources they need to build and maintain secure mobile applications. Through the project, our goal is to classify mobile security risks and provide developmental controls to reduce their impact or likelihood of exploitation.
We have a Google Doc up where anyone that wants to be involved with the project can add their thoughts, suggestions, and take ownership of initiatives. https://docs.google.com/document/d/1bScrvrLJLOHcSbztjBxYoN-jN3kR8bViy9tF8Nx0c08/edit. There are various tasks that people have started over the past 6 months with varying levels of quality and completeness.
| PROJECT INFO
What does this OWASP project offer you?
| RELEASE(S) INFO|
What releases are available for this project?
Following a 90-day review and publication of the release candidate, we determined that the release candidate was ready for final publication. The 2016 list has now been published and can be found here: OWASP Mobile Top Ten 2016
Feel free to visit the mailing list as well!
2015 Mobile Top Ten Analysis Results
Are you interested in what the data collection for the 2015 list looks like? Check out the final synthesis... Media:2015 Data Synthesis Results.pptx
We are fleshing out the new Mobile Top Ten at Projects/OWASP_Mobile_Security_Project_-2015_Scratchpad. Have a look.
Here is the original raw data: [Dropbox Data]
Project Leads, Credit, and Contributions
How Did the List Get Made?
- We wanted to know what the community wanted in the next Mobile Top Ten list and what they thought about the last. We published a survey and shared the results with everyone.
- We issued a Call for Data and aggressively pursued many different vendors and consultants for raw data.
- We had a huge response by vendors and consultants. We collected lots of data about the last years vulnerabilities from a number of different vendors and consultant. That raw data can be found here.
- Over the coming months, we then analyzed the data. Lots of different contributors did their own analysis and compared results. Here is a sample of the color commentary on the data.
- Ultimately, we agreed on the findings and published key findings from the data that we all agreed upon.
- Next, we started coming up with a consensus of what we wanted in the next revision of the Mobile Top Ten.
- Results were collected and a release candidate got released.
- We examined the results from the release candidate and concluded that we achieved what we set out to do for 2016
- We published the list officially and moved it from release to final stage
- The list below is the OLD release candidate v1.0 of the OWASP Top 10 Mobile Risks. This list was initially released on September 23, 2011 at Appsec USA.
iMAS is a collaborative research project from the MITRE Corporation focused on open source iOS security controls. Today, iOS meets the enterprise security needs of customers, however many security experts cite critical vulnerabilities and have demonstrated exploits, which pushes enterprises to augment iOS deployments with commercial solutions. The iMAS intent is to protect iOS applications and data beyond the Apple provided security model and reduce the adversary’s ability and efficiency to perform recon, exploitation, control and execution on iOS mobile applications. iMAS will transform the effectiveness of the existing iOS security model across major vulnerability areas including the System Passcode, jailbreak, debugger / run-time, flash storage, and the system keychain. Research outcomes include an open source secure application framework, including an application container, developer and validation tools/techniques.
The source code for iMAS is available on GitHub: iMAS Source Code
OWASP GoatDroid is a fully functional and self-contained training environment for educating developers and testers on Android security. GoatDroid requires minimal dependencies and is ideal for both Android beginners as well as more advanced users. The project currently includes two applications: FourGoats, a location-based social network, and Herd Financial, a mobile banking application. There are also several features that greatly simplify usage within a training environment or for absolute beginners who want a good introduction to working with the Android platform.
As the Android SDK introduces new features, the GoatDroid contributors will strive to implement up-to-date lessons that can educate developers and security testers on new security issues. The project currently provides coverage for most of the OWASP Top 10 Mobile Risks and also includes a bunch of other problems as well.
You can find GoatDroid on GitHub: GoatDroid Source Code
iGoat is a learning tool for iOS developers (iPhone, iPad, etc.). It was inspired by the WebGoat project, and has a similar conceptual flow to it.
As such, iGoat is a safe environment where iOS developers can learn about the major security pitfalls they face as well as how to avoid them. It is made up of a series of lessons that each teach a single (but vital) security lesson.
The lessons are laid out in the following steps:
- Brief introduction to the problem.
- Verify the problem by exploiting it.
- Brief description of available remediations to the problem.
- Fix the problem by correcting and rebuilding the iGoat program.
Step 4 is optional, but highly recommended for all iOS developers. Assistance is available within iGoat if you don't know how to fix a specific problem.
iGoat is free software, released under the GPLv3 license.
The iGoat source code is available on Google Code iGoat Source Code
Damn Vulnerable iOS Application
Damn Vulnerable iOS application is a project started by Prateek Gianchandani which gives mobile testers and developers an iOS application to practice attacking/defending skill sets. Each challenge area corresponds to an in-depth article designed to teach the fundamentals of mobile security on the iOS platform. Some challenge categories include multiple challenge types.
The current challenge categories:
- Insecure Data Storage (4 exercises)
- Jailbreak Detection (2 exercises)
- Runtime Manipulation (3 exercises)
- Transport Layer Security (1 exercise)
- Client Side Injection (1 exercise)
- Broken Cryptography (1 exercise)
- Binary Patching (4 exercises)
The MobiSec Live Environment Mobile Testing Framework project is a live environment for testing mobile environments, including devices, applications, and supporting infrastructure. The purpose is to provide attackers and defenders the ability to test their mobile environments to identify design weaknesses and vulnerabilities. The MobiSec Live Environment provides a single environment for testers to leverage the best of all available open source mobile testing tools, as well as the ability to install additional tools and platforms, that will aid the penetration tester through the testing process as the environment is structured and organized based on an industry‐proven testing framework. Using a live environment provides penetration testers the ability to boot the MobiSec Live Environment on any Intel-based system from a DVD or USB flash drive, or run the test environment within a virtual machine.
MobiSec can be downloaded from Sourceforge: MobiSec Download Repository
Androick is a collaborative research project from PHONESEC Ltd. With our tool, you can evaluate some risks on Android mobile applications. Androick is a tool that allows any user to analyze an Android application. It can get the apk file, all the datas and the databases in sqlite3 and csv format. Only for Pentesters or Researchers.
A major priority of the OWASP Mobile Security Project is to help standardize and disseminate mobile application testing methodologies. While specific techniques exist for individual platforms, a general mobile threat model can be used to assist test teams in creating a mobile security testing methodology for any platform. The outline which follows describes a general mobile application testing methodology which can be tailored to meet the security tester’s needs. It is high level in some places, and over time will be customized on a per-platform basis.
This guide is targeted towards application developers and security testers. Developers can leverage this guide to ensure that they are not introducing the security flaws described within the guide. Security testers can use it as a reference guide to ensure that they are adequately assessing the mobile application attack surface. The ideal mobile assessment combines dynamic analysis, static analysis, and forensic analysis to ensure that the majority of the mobile application attack surface is covered.
On some platforms, it may be necessary to have root user or elevated privileges in order to perform all of the the required analysis on devices during testing. Many applications write information to areas that cannot be accessed without a higher level of access than the standard shell or application user generally has. For steps that generally require elevated privileges, it will be stated that this is the case.
This guide is broken up into three sections:
- Information Gathering- describes the steps and things to consider when you are in the early stage reconnaissance and mapping phases of testing as well as determining the application’s magnitude of effort and scoping.
- Static Analysis- Analyzing raw mobile source code, decompiled or disassembled code.
- Dynamic Analysis - executing an application either on the device itself or within a simulator/emulator and interacting with the remote services with which the application communicates. This includes assessing the application’s local interprocess communication surface, forensic analysis of the local filesystem, and assessing remote service dependencies.
How To Use This Resource
As this guide is not platform specific, you will need to know the appropriate techniques & tools for your target platform. The OWASP Mobile Security Project has also developed a number of other supporting resources which may be able to be leveraged for your needs.
In this current draft release, the guide is a work in progress. We need additional contributors to help fill in the blanks. If you think something is missing (there certainly is), add it.
As this guide is not platform specific, you will need to know the appropriate techniques & tools for your target platform. The OWASP Mobile Security Project has also developed a number of other supporting resources which may be able to be leveraged for your needs,
The steps required to properly test an Android application are very different than those of testing an iOS application. Likewise, Windows Phone is very different from the other platforms. Mobile security testing requires a diverse skillset over many differing operating systems and a critical ability to analyze various types of source code.
In many cases, a mobile application assessment will require coverage in all three areas identified within this testing reference. A dynamic assessment will benefit from an initial thorough attempt at Information Gathering, some level of static analysis against the application’s binary, and a forensic review of the data created and modified by the application’s runtime behavior.
Please use this guide in an iterative fashion, where work in one area may require revisiting previous testing steps. As an example, after completing a transaction you may likely need to perform additional forensic analysis on the device to ensure that sensitive data is removed as expected and not cached in an undesired fashion. As you learn more about the application at runtime, you may wish to examine additional parts of the code to determine the best way to evade a specific control. Likewise, during static analysis it may be helpful to populate the application with certain data in order to prove or refute the existence of a security flaw.
In the future, contributors to the testing guide should consider adding entries under each section relevant to a specific platform. Over time, OWASP contributors will write platform specific guides and expand upon this body of knowledge.
If a specific area of interest is not covered in this guide, please feel free to either:
- write the material yourself by registering for a wiki account and contributing content: Wiki Registration
- bring this up as a topic on the Mobile Project’s mailing list: Mobile Mailing List
Collaboration on building the guide is being performed within Google Docs. You can find the latest and greatest material here: Testing Guide Google Doc
As a result of this initial information gathering exercise, the tester will be better prepared for the future testing phases. Testers, Developers and Security people often fail to take the time to learn the target application and supporting infrastructure, opting to dive in blind, possibly losing valuable time and missing possible attack vectors. Without a solid understanding of how the application “should” work as well as the technologies in use, the tester will not be able to identify when the application behaves in a manner that it “shouldn’t”.
Prerequisites of this phase may require specific operating systems, platform specific software development kits (SDK’s), rooted or jailbroken devices, the ability to man-in-the-middle secure communications (i.e. HTTPS) and bypass invalid certificate checks.
- Manually navigate through the running application to understand the basic functionality and workflow of the application. This can be performed on a real device or within a simulator/emulator. For deeper understanding of application functionality tester can proxy and sniff all network traffic from either a physical mobile device or an emulator/simulator recording and logging traffic (if your proxy tool permits logging, which most should).
- Identify the networking interfaces used by the application, for instance:
- Mobile Communication (GSM, GPRS, EDGE, LTE)
- Wireless (Wi-Fi (802.11 standards), Bluetooth, NFC)
- Virtual Interfaces (i.e. VPN)
- Determine what the application supports for access 3G, 4G, wifi and or others
- What networking protocols are in use?
- Are secure protocols used where needed?
- Can they be switched with insecure protocols?
- Does the application perform commerce transactions?
- Credit card transactions and/or stored payment information (certain industry regulations may be required (i.e. PCI DSS)).
- In-app purchasing of goods or features
- Make note for future phases to determine does the application store payment information? How is payment information secured?
- Monitor and identify the hardware components that the application may potentially interact with
- Perform open source intelligence gathering (search engines, source code repositories, developer forums, etc.) to identify source code or configuration information that may be exposed (i.e. 3rd party components integrated within the application)
- What frameworks are in use?
- Identify if the application appears to interact with any other applications, services, or data such as:
- Telephony (SMS, phone)
- Auto correct / dictionary services
- Receiving data from apps and other on-device services
- Google Wallet
- Social networks (i.e. Facebook, Twitter, LinkedIn, Google+)
- Can you determine anything about the server side application environment?
- Hosting provider (AWS, App Engine, Heroku, Rackspace, Azure, etc.)
- Development environment (Rails, Java, Django, ASP.NET, etc.)
- Does the application leverage Single Sign On or Authentication APIs (Google Apps, Facebook, iTunes, OAuth, etc.)
- Any other APIs in use
- Payment gateways
- SMS messaging
- Social networks
- Cloud file storage
- Ad networks
- Perform a thorough crawl of exposed web resources and sift through the requests and responses to identify potentially interesting data or behavior
- Leaking sensitive information (i.e. credentials) in the response
- Resources not exposed through the UI
- Error messages
- Cacheable information
There are two primary ways static analysis will generally be performed on a mobile application:
- Analyzing source code obtained from development team (prefered)
- Using a compiled binary.
Some level of static analysis should be performed for both dynamic and forensic analysis, as the application’s code will almost always provide valuable information to the tester (i.e. logic, backend targets, APIs, etc).
In scenarios where the primary goal is to identify programmatic examples of security flaws, your best bet is to review pure source code as opposed to reverse engineering compiled software. For source code reviews, it is highly beneficial to have access to either a development or production instance of any web services. This includes both source code and a working test environment to perform the assessment within in order to expedite understanding of the code.
- If the source is not directly available, decompile or disassemble the application’s binary
- extract the application from the device
- follow the appropriate steps for your platform’s application reverse engineering
- some applications may also require decryption prior to reverse engineering (note: decryption and code obfuscation are not the same thing)
- Review the permissions the application requests as well as the resources that it is authorized to access (i.e. AndroidManifest.xml, iOS Entitlements)
- Are there any easy to identify misconfigurations within the application found within the configuration files? Debugging flags set, world readable/writable permissions, etc.
- What frameworks are in use? Is the application built using a cross-platform framework?
- Identify the libraries in use including both platform provided as well as third party. Perform a quick review on the web to determine if these libraries:
- are up to date
- are free of vulnerabilities
- expose functionality that requires elevated privileges (access to location or contact data)
- native code
- Does the application check for rooted/jailbroken devices? How is this done? How can this be circumvented? Is it as easy as changing the case of a file name or name of executable or path?
- Determine what types of objects are implemented to create the various views within the application. This may significantly alter your test cases, as some views implement web browser functionality while others are native UI controls only.
- Is all code expected to run within the platform’s standard runtime environment, or are some files/libraries dynamically loaded or called outside of that environment at runtime?
- Attempt to match up every permission that the application requests with an actual concrete implementation of it within the application. Often, developers request more permission than they actually need. Identify if the same functionality could be enabled with lesser privileges.
- Locate hard coded secrets within the application such as API keys, credentials, or proprietary business logic.
- Identify every entry point for untrusted data entry and determine how it enforces access controls, validates and sanitizes inbound data, and passes the data off to other interpreters
- From web service calls
- Receiving data from other apps and on-device services
- Inbound SMS messages
- Reading information from the filesystem
- Locate the code which handles user authentication through the UI. Assess the possible methods of user impersonation via vectors such as parameter tampering, replay attacks, and brute force attacks.
- Determine if the application utilizes information beyond username/password such as
- contextual information (i.e.- device identifiers, location)
- Does the application utilize visual swipe or touch passwords vs. conventional usernames and passwords?
- Assess the method of mapping the visual objects to an authentication string to determine if adequate entropy exists
- Does the application implement functionality that permits inbound connections from other devices? (i.e.- Wi-Fi Direct, Android Beam, network services)
- Does the application properly authenticate the remote user or peer prior to granting access to device resources?
- How does the application handle excessive failed attempts at authentication?
- are failed attempts logged?
- what mechanisms exist to inform the user of a potential attack?
- Single Sign On, e.g.
- Google Apps
- How is the sender authenticated?
- header information
- Other mechanism?
- Are one time passwords (OTP) used or is other sensitive account data transmitted via SMS?
- Can other applications access this data?
- How is the sender authenticated?
- Push Notifications
- If the application consumes information via push notifications, how does the application verify the identity of the sender?
- Review file permissions for files created at runtime
- Determine if it is possible to access functionality not intended for your role
- Identify if the application has role specific functionality within the mobile application
- Locate any potential flags or values that may be set on the client from any untrusted source that can be a point of privilege elevation such as
- flat files
- HTTP responses
- Locate any potential flags or values that may be set on the client from any untrusted source that can be a point of privilege elevation such as
- Find places within an application that were not anticipated being directly accessed without following the application’s intended workflow
- Can licensing checks be defeated locally to obtain access to paid-for data resources? (i.e.- patching a binary, modifying it at runtime, or by modifying a local configuration file)
- Does the code suggest that licensed content is served with a non-licensed app but restricted by UI controls only?
- Are licensing checks performed properly by the server or platform licensing services?
- How does the application detect and respond to tampering?
- Are alerts sent to and expected by the developer?
- Does the application fail open or fail closed?
- Does the application wipe its data?
- Ensure that sessions time out locally as well as server side
- Is sensitive information utilized within the application flushed from memory upon session expiration?
- Are the algorithms used “best of breed” or do they contain known issues?
- How are keys derived from i.e. a password?
- Based on the algorithms and approaches used to encrypt data, do implementation issues exist that degrade the effectiveness of encryption?
- How are keys managed and stored on the device? Can this reduce the complexity in breaking the encryption?
- Identify if the application utilizes storage areas external to the “sandboxed” locations to store unencrypted data such as:
- Places with limited access control granularity (SD card, tmp directories, etc.)
- Directories that may end up in backups or other undesired locations (iTunes backup, external storage, etc.)
- Cloud storage services such as Dropbox, Google Drive, or S3
- Does the application write sensitive information to the file system at any point, such as:
- Username and/or password
- API keys
- Authentication tokens
- Payment information
- Patient data
- Signature files
- Is sensitive information written to data stores via platform exposed APIs such as contacts?
- Does the application log data? Is sensitive information accessible?
- How are the logs accessed, if so, and by which mechanism/functionality? Is log access protected?
- Can any of the logged information be considered a privacy violation?
- Is the device identifier sent that could be used to identify the user? (i.e.UDID in Apple devices)
- Predictive text
- Location information
- Copy and paste
- Application snapshot
- Browser cache
- Non-standard cache locations (i.e the various SQLite databases that apps can create if they use HTML UI components)
- Does sensitive data leak in crash logs?
- Third Party Libraries and APIs
- What permissions do they require?
- Do they access or transmit sensitive information?
Review licensing requirements for any potential violations.
- Can their runtime behavior expose users to privacy issues and unauthorized tracking?
Web Application Issues
- XSS and HTML Injection
- Identify places where the application passes untrusted data into a web view or browser
- Determine if the application properly output encodes or sanitizes the data within the appropriate context
- Command Injection (if the application utilizes a shell)
- Where the application permits usage of the shell, identify the entry points to manipulate or alter the commands via user input or external untrusted data
- Determine if an attacker can inject arbitrary commands or manipulate the intended command in any way
- SQL Injection
- Are insecure protocols used to send or receive sensitive information? Examples- FTP, SNMP v1, SSH v1
- Are there any known issues with the specific libraries you are using to implement the protocol?
Transport Layer Protection
- Does the application properly implement Certificate Pinning?
- Are certificates validated to determine if:
- The certificate has not expired
- The certificate was issued by a valid certificate authority
- The remote destination information matches the information within the certificate?
- Are certificates validated only by the operating system or also by the application that relies on it?
- Identify if code exist to alter the behavior for traffic transiting different interfaces (i.e.- 3G/4G comms vs. Wi-Fi)? If so, is encryption applied universally across each of them
Helpful Search Strings and Regular Expressions
Armed with data collected during the Information Gathering and Static Analysis phases, the tester can begin an informed vulnerability assessment of the mobile application client, server and associated services.
Dynamic analysis is conducted against the backend services and APIs and the type of tests varies depending on mobile application type.
- Native Mobile Application: Native mobile applications can be installed on to the device. This type of applications generally store most of their code on the device. Any information required can be requested to the server using the HTTP/s protocol
- Web services for Mobile Application: Native mobile application that uses SOAP or REST based web services to communicate between client and Server
- Mobile Browser Based Application: Web browser based applications can be accessed using device’s browsers such as Safari or Chrome. Most of the commercial applications are nowadays specifically designed and optimized for mobile browsers. These applications are no different than traditional web application and all the web application vulnerabilities apply to these apps and these should be tested as traditional web apps.
- Mobile Hybrid Applications:Applications can leverage web browser functionality within native applications, blending the risks from both classes of applications.
In this phase, the mobile client, backend services, and host platform is analyzed/scanned in attempt to uncover potential risks, vulnerabilities and threats. The use of an intercepting proxy tool as well as automated vulnerability scanners are core to this phase. In many cases, you will also need some type of shell access to the device.
The following outline can be used as a “Dynamic Analysis” guide in planning a mobile assessment.
Establishing a Baseline
- Generate File System Baseline Fingerprint (before app installation)
- Application interactions with the host file system must be reviewed and analyzed at various stages of testing; starting with baseline capture. This may require a shell or GUI depending on platform and/or preference.
- Install, Configure and Use the Application
- Manually inspect the file system to determine what files/databases were created, what and how data is stored. Did the application store sensitive data unencrypted or trivially protected (i.e. encoded)?
- Generally, pay attention to credentials, payment information, or other highly sensitive information being saved to the device. Also take a look at databases, log files, predictive text caches, and crash logs.
- Attach a debugger to an application to step through code execution and setting breakpoints at interesting code within the application
- Monitor logged messages and notifications generated at runtime
- Observe interprocess communications between the target application and other applications and services running on the mobile device.
- Exposed IPC interfaces
- Bypass authorization checks
- Brute force attacks against keys, pins, and hashes
- Attempt to reconstruct encrypted data through recovery of keys, hardcoded secrets, and any other information exposed by the application
- XSS and HTML Injection
- Command Injection (if the application utilizes a shell)
- SQL Injection
- Are cookies issued by a server secured by using the HTTP-only and Secure flag?
- Is there any sensitive information stored in the cookies?
- HTML5 Storage
- Assess the methods an application uses to authenticate peers
- Push notifications
- Across IPC channels (identify the calling application’s privileges and identity)
- Instrument, patch, or interact with application at runtime to bypass methods intended to prevent usage of privileged or premium features
- Determine if configuration or locally stored data can be manipulated in order to elevate a user’s privileges
- Check the filesystem permissions for any files created at runtime
File System Analysis
- Assess the application’s behavior throughout it’s lifecycle to determine if special functionality is triggered to persist an application’s state when it enters different stages:
- Placed into the foreground
- Sent into the background
- Upon exiting the application
- Data storage in Cache
- Looking for artifacts left on device
- Unencrypted data storage on the device
- Encryption of data in backups
- Username/password, or app-specific unique device id stored on the device
- Application Permissions , Privileges and Access controls on the device
- Generally, pay attention to credentials, payment information, or other highly sensitive information being saved to the device. Also take a look at log files, predictive text caches, and crash logs.
- Is sensitive information cached within the application’s UI back stack?
- Utilize forensic tools to determine if deleted data can be recovered from the filesystem as well as within databases
- Determine if sensitive information persists within memory after performing the following actions:
- Logging out of the application
- Transition between UI components
- Is it possible to obtain encryption keys, credentials, payment information and other sensitive information by dumping device or application memory?
Remote Application/Service Testing
- What methods are available (3G, 4G, Wifi, etc)?
- What happens if the remote authentication service becomes unavailable?
- Assess strength of password requirements
- Test how account lockouts are implemented
- Analyze (monitor traffic) how each method performs authentication. Note target wifi as this is a common area where authentication can be weak. Ensure authentication is robust and not based on trivial attributes (i.e. MDN, ESN, etc).
- Verify that authentication tokens are terminated after a user initiates a password reset
- Single Sign On (SSO)
- SMS Based
- One Time Passwords (OTP)
- Two Factor Authentication
- Push Notifications
- What happens if the remote authorization handling service becomes unavailable?
- Test if direct access to backend resources is possible
- Access controls to server side resources not enforced
- Vertical and horizontal privilege escalation
- Entropy analysis
- Device identifier related?
- Are session tokens refreshed between logouts?
- Lifetime and expiration
- Handling the session token on the device (stored, in memory, etc.)
- Privilege Escalation
- Ineffective Session Termination
Transport Layer Testing
- Man-in-the-middle attacks
- SSL checks (cypher strengths/weakness etc.)
Server Side Attacks
- Triggering unhandled exceptions
- Cross-Site Scripting
- SQL Injection
- XML Bombs
- Buffer overflow
- Unrestricted File Upload
- Open Redirect
Server, Network & Application Scanning
- Based on prior phases you should have 1 or more target servers (i.e. URLs) as candidates for automated vulnerability scanning. Mobile applications often leverage existing web services/applications (i.e. hybrid applications) which must be tested for security vulnerabilities.
Mobile applications are continuing to mature and evolve thus to be effective, security testers must strive to advance their knowledge and skills. Please check back periodically for updates and share your feedback with us.
Mobile Cheat Sheet Series
Cheat sheets provide the information most relevant to a developer or security engineer with minimal "fluff". The goal of the project is to build a collection of cheat sheets that provide actionable, useful, and straight to the point guidance for a plethora of mobile security issues.
Secure Mobile Development Guidelines Objective
The OWASP Secure Development Guidelines will provide developers with the knowledge they need to build secure mobile applications. An extendable framework will be provided that includes the core security flaws found across nearly all mobile platforms. It will be a living reference where contributors can plug in newly exposed APIs for various platforms and provide good/bad code examples along with remediation guidance for those issues.
OWASP and the European Network and Information Security Agency (ENISA) collaborated to build a joint set of controls. ENISA has published the results of the collaborative effort as the "Smartphone Secure Development Guideline": http://www.enisa.europa.eu/activities/application-security/smartphone-security-1/smartphone-secure-development-guidelines
This document has been jointly produced with ENISA as well as the following individuals:
- Vinay Bansal, Cisco Systems
- Nader Henein, Research in Motion
- Giles Hogben, ENISA
- Karsten Nohl, Srlabs
- Jack Mannino, nVisium Security
- Christian Papathanasiou, Royal Bank of Scotland
- Stefan Rueping, Infineon
- Beau Woods, Stratigos Security
Top 10 mobile controls and design principles
Risks: Unsafe sensitive data storage, attacks on decommissioned phones unintentional disclosure: Mobile devices (being mobile) have a higher risk of loss or theft. Adequate protection should be built in to minimize the loss of sensitive data on the device.
- 1.1 In the design phase, classify data storage according to sensitivity and apply controls accordingly (e.g. passwords, personal data, location, error logs, etc.). Process, store and use data according to its classification. Validate the security of API calls applied to sensitive data.
- 1.2 Store sensitive data on the server instead of the client-end device. This is based on the assumption that secure network connectivity is sufficiently available and that protection mechanisms available to server side storage are superior. The relative security of client vs server-side security also needs to be assessed on a case-by-case basis (see ENISA cloud risk assessment (3) or the OWASP Cloud top 10 (4) for decision support).
- 1.3 When storing data on the device, use a file encryption API provided by the OS or other trusted source. Some platforms provide file encryption APIs which use a secret key protected by the device unlock code and deleteable on remote kill. If this is available, it should be used as it increases the security of the encryption without creating extra burden on the end-user. It also makes stored data safer in the case of loss or theft. However, it should be born in mind that even when protected by the device unlock key, if data is stored on the device, its security is dependent on the security of the device unlock code if remote deletion of the key is for any reason not possible.
- 1.4 Do not store/cache sensitive data (including keys) unless they are encrypted and if possible stored in a tamper-proof area (see control 2).
- 1.5 Consider restricting access to sensitive data based on contextual information such as location (e.g. wallet app not usable if GPS data shows phone is outside Europe, car key not usable unless within 100m of car etc...).
- 1.6 Do not store historical GPS/tracking or other sensitive information on the device beyond the period required by the application (see controls 1.7, 1.8).
- 1.7 Assume that shared storage is untrusted - information may easily leak in unexpected ways through any shared storage. In particular:
- Be aware of caches and temporary storage as a possible leakage channel, when shared with other apps.
- Be aware of public shared storage such as address book, media gallery and audio files as a possible leakage channel. For example storing images with location metadata in the media-gallery allows that information to be shared in unintended ways.
- Do not store temp/cached data in a world readable directory.
- 1.8 For sensitive personal data, deletion should be scheduled according to a maximum retention period, (to prevent e.g. data remaining in caches indefinitely).
- 1.9 There is currently no standard secure deletion procedure for flash memory (unless wiping the entire medium/card). Therefore data encryption and secure key management are especially important.
- 1.10 Consider the security of the whole data lifecycle in writing your application (collection over the wire, temporary storage, caching, backup, deletion etc)
- 1.11 Apply the principle of minimal disclosure - only collect and disclose data which is required for business use of the application. Identify in the design phase what data is needed, its sensitivity and whether it is appropriate to collect, store and use each data type.
- 1.12 Use non-persistent identifiers which are not shared with other apps wherever possible - e.g. do not use the device ID number as an identifier unless there is a good reason to do so (use a randomly generated number – see 4.3). Apply the same data minimization principles to app sessions as to http sessions/cookies etc.
- 1.13 Applications on managed devices should make use of remote wipe and kill switch APIs to remove sensitive information from the device in the event of theft or loss. (A kill-switch is the term used for an OS-level or purpose-built means of remotely removing applications and/or data).
- 1.14 Application developers may want to incorporate an application-specific "data kill switch" into their products, to allow the per-app deletion of their application's sensitive data when needed (strong authentication is required to protect misuse of such a feature).
2. Handle password credentials securely on the device
Risks: Spyware, surveillance, financial malware. A user's credentials, if stolen, not only provide unauthorized access to the mobile backend service, they also potentially compromise many other services and accounts used by the user. The risk is increased by the widespread of reuse of passwords across different services.
- 2.1 Instead of passwords consider using longer term authorization tokens that can be securely stored on the device (as per the OAuth model). Encrypt the tokens in transit (using SSL/TLS). Tokens can be issued by the backend service after verifying
￼￼￼Smartphones secure development guidelines for app developers ￼the user credentials initially. The tokens should be time bounded to the specific service as well as revocable (if possible server side), thereby minimizing the damage in loss scenarios. Use the latest versions of the authorization standards (such as OAuth 2.0). Make sure that these tokens expire as frequently as practicable.
- 2.2 In case passwords need to be stored on the device, leverage the encryption and key-store mechanisms provided by the mobile OS to securely store passwords, password equivalents and authorization tokens. Never store passwords in clear text. Do not store passwords or long term session IDs without appropriate hashing or encryption.
- 2.3 Some devices and add-ons allow developers to use a Secure Element e.g. (5) (6) – sometimes via an SD card module - the number of devices offering this functionality is likely to increase. Developers should make use of such capabilities to store keys, credentials and other sensitive data. The use of such secure elements gives a higher level of assurance with the standard encrypted SD card certified at FIPS 140-2 Level 3. Using the SD cards as a second factor of authentication though possible, isn't recommended, however, as it becomes a pseudo-inseparable part of the device once inserted and secured.
- 2.4 Provide the ability for the mobile user to change passwords on the device.
- 2.5 Passwords and credentials should only be included as part of regular backups in encrypted or hashed form.
- 2.6 Smartphones offer the possibility of using visual passwords which allow users to memorize passwords with higher entropy. These should only be used however, if sufficient entropy can be ensured. (7)
- 2.7 Swipe-based visual passwords are vulnerable to smudge-attacks (using grease deposits on the touch screen to guess the password). Measures such as allowing repeated patterns should be introduced to foil smudge-attacks. (8)
- 2.8 Check the entropy of all passwords, including visual ones (see 4.1 below).
- 2.9 Ensure passwords and keys are not visible in cache or logs.
- 2.10 Do not store any passwords or secrets in the application binary. Do not use a generic shared secret for integration with the backend (like password embedded in code). Mobile application binaries can be easily downloaded and reverse engineered.
3. Ensure sensitive data is protected in transit
Risks: Network spoofing attacks, surveillance. The majority of smartphones are capable of using multiple network mechanisms including Wi-Fi, provider network (3G, GSM, CDMA and others), Bluetooth etc. Sensitive data passing through insecure channels could be intercepted. (9) (10)
- 3.1 Assume that the provider network layer is not secure. Modern network layer attacks can decrypt provider network encryption, and there is no guarantee that the Wi-Fi network will be appropriately encrypted.
- 3.2 Applications should enforce the use of an end-to-end secure channel (such as SSL/TLS) when sending sensitive information over the wire/air (e.g. using Strict Transport Security - STS (11)).This includes passing user credentials, or other authentication equivalents. This provides confidentiality and integrity protection.
- 3.3 Use strong and well-known encryption algorithms (e.g. AES) and appropriate key lengths (check current recommendations for the algorithm you use e.g. (12) page 53).
- 3.4 Use certificates signed by trusted CA providers. Be very cautious in allowing self- signed certificates. Do not disable or ignore SSL chain validation.
- 3.5 For sensitive data, to reduce the risk of man-in-middle attacks (like SSL proxy, SSL strip), a secure connection should only be established after verifying the identity of the remote end-point (server). This can be achieved by ensuring that SSL is only established with end-points having the trusted certificates in the key chain.
- 3.6 The user interface should make it as easy as possible for the user to find out if a certificate is valid.
- 3.7 SMS, MMS or notifications should not be used to send sensitive data to or from mobile end-points.
Reference: Google vulnerability of Client Login account credentials on unprotected wifi - 
4. Implement user authentication,authorization and session management correctly
Risks: Unauthorized individuals may obtain access to sensitive data or systems by circumventing authentication systems (logins) or by reusing valid tokens or cookies. (13)
- 4.1 Require appropriate strength user authentication to the application. It may be useful to provide feedback on the strength of the password when it is being entered for the first time. The strength of the authentication mechanism used depends on the sensitivity of the data being processed by the application and its access to valuable resources (e.g. costing money).
- 4.2 It is important to ensure that the session management is handled correctly after the initial authentication, using appropriate secure protocols. For example, require authentication credentials or tokens to be passed with any subsequent request (especially those granting privileged access or modification).
- 4.3 Use unpredictable session identifiers with high entropy. Note that random number generators generally produce random but predictable output for a given seed (i.e. the same sequence of random numbers is produced for each seed). Therefore it is important to provide an unpredictable seed for the random number generator. The standard method of using the date and time is not secure. It can be improved, for example using a combination of the date and time, the phone temperature sensor and the current x,y and z magnetic fields. In using and combining these values, well-tested algorithms which maximise entropy should be chosen (e.g. repeated application of SHA1 may be used to combine random variables while maintaining maximum entropy – assuming a constant maximum seed length).
- 4.4 Use context to add security to authentication - e.g. IP location, etc...
- 4.5 Where possible, consider using additional authentication factors for applications giving access to sensitive data or interfaces where possible - e.g. voice, fingerprint (if available), who-you-know, behavioural etc.
- 4.6 Use authentication that ties back to the end user identity (rather than the device identity).
5. Keep the backend APIs (services) and the platform (server) secure
Risks: Attacks on backend systems and loss of data via cloud storage. The majority of mobile applications interact with the backend APIs using REST/Web Services or proprietary protocols. Insecure implementation of backend APIs or services, and not keeping the back-end platform hardened/patched will allow attackers to compromise data on the mobile device when transferred to the backend, or to attack the backend through the mobile application. (14)
- 5.1 Carry out a specific check of your code for sensitive data unintentionally transferred, any data transferred between the mobile device and web-server back- ends and other external interfaces - (e.g. is location or other information included within file metadata).
- 5.2 All backend services (Web Services/REST) for mobile apps should be tested for vulnerabilities periodically, e.g. using static code analyser tools and fuzzing tools for testing and finding security flaws.
- 5.3 Ensure that the backend platform (server) is running with a hardened configuration with the latest security patches applied to the OS, Web Server and other application components.
- 5.4 Ensure adequate logs are retained on the backend in order to detect and respond to incidents and perform forensics (within the limits of data protection law).
- 5.5 Employ rate limiting and throttling on a per-user/IP basis (if user identification is available) to reduce the risk from DDoS attack.
- 5.6 Test for DoS vulnerabilities where the server may become overwhelmed by certain resource intensive application calls.
- 5.7 Web Services, REST and APIs can have similar vulnerabilities to web applications:
- Perform abuse case testing, in addition to use case testing
- Perform testing of the backend Web Service, REST or API to determine vulnerabilities.
6. Secure data integration with third party services and applications
Risks: Data leakage. Users may install applications that may be malicious and can transmit personal data (or other sensitive stored data) for malicious purposes.
- 6.1 Vet the security/authenticity of any third party code/libraries used in your mobile application (e.g. making sure they come from a reliable source, with maintenance supported, no backend Trojans)
- 6.2 Track all third party frameworks/APIs used in the mobile application for security patches. A corresponding security update must be done for the mobile applications using these third party APIs/frameworks.
- 6.3 Pay particular attention to validating all data received from and sent to non-trusted third party apps (e.g. ad network software) before processing within the application.
7. Pay specific attention to the collection and storage of consent for the collection and use of the user’s data
Risks: Unintentional disclosure of personal or private information, illegal data processing. In the European Union, it is mandatory to obtain user consent for the collection of personally identifiable information (PII). (15) (16)
- 7.2 Consent may be collected in three main ways:
- At install time
- At run-time when data is sent
- Via “opt-out” mechanisms where a default setting is implemented and the user has to turn it off.
- 7.3 Check whether your application is collecting PII - it may not always be obvious - for example do you use persistent unique identifiers linked to central data stores containing personal information?
- 7.4 Audit communication mechanisms to check for unintended leaks (e.g. image metadata).
- 7.5 Keep a record of consent to the transfer of PII. This record should be available to the user (consider also the value of keeping server-side records attached to any user data stored). Such records themselves should minimise the amount of personal data they store (e.g. using hashing).
- 7.6 Check whether your consent collection mechanism overlaps or conflicts (e.g. in the data handling practices stated) with any other consent collection within the same stack (e.g. APP-native + webkit HTML) and resolve any conflicts.
8. Implement controls to prevent unauthorized access to paid-for resources (wallet, SMS, phone calls etc.) Risks: Smartphone apps give programmatic (automatic) access to premium rate phone calls, SMS, roaming data, NFC payments, etc. Apps with privileged access to such API’s should take particular care to prevent abuse, considering the financial impact of vulnerabilities that giveattackers access to the user’s financial resources.
- 8.1 Maintain logs of access to paid-for resources in a non-repudiable format (e.g. a signed receipt sent to a trusted server backend – with user consent) and make them available to the end-user for monitoring. Logs should be protected from unauthorised access.
- 8.2 Check for anomalous usage patterns in paid-for resource usage and trigger re- authentication. E.g. when significant change in location occurs, user-language changes etc.
- 8.3 Consider using a white-list model by default for paid-for resource addressing - e.g. address book only unless specifically authorised for phone calls.
- 8.4 Authenticate all API calls to paid-for resources (e.g. using an app developer certificate).
- 8.5 Ensure that wallet API callbacks do not pass cleartext account/pricing/ billing/item information.
- 8.6 Warn user and obtain consent for any cost implications for app behaviour.
- 8.7 Implement best practices such as fast dormancy (a 3GPP specification), caching, etc. to minimize signalling load on base stations.
9. Ensure secure distribution/provisioning of mobile applications
Risks: Use of secure distribution practices is important in mitigating all risks described in the OWASP Mobile Top 10 Risks and ENISA top 10 risks.
- 9.1 Applications must be designed and provisioned to allow updates for security patches, taking into account the requirements for approval by app-stores and the extra delay this may imply.
- 9.2 Most app-stores monitor apps for insecure code and are able to remotely remove apps at short notice in case of an incident. Distributing apps through official app- stores therefore provides a safety-net in case of serious vulnerabilities in your app.
- 9.3Provide feedback channels for users to report security problems with apps – e.g. a security@ email address.
10. Carefully check any runtime interpretation of code for errors
Risks: Runtime interpretation of code may give an opportunity for untrusted parties to provide unverified input which is interpreted as code. For example, extra levels in a game, scripts, interpreted SMS headers. This gives an opportunity for malware to circumvent walled garden controls provided by app-stores. It can lead to injection attacks leading to Data leakage, surveillance, spyware, and diallerware.
- 10.1 Minimize runtime interpretation and capabilities offered to runtime interpreters: run interpreters at minimal privilege levels.
- 10.2 Define comprehensive escape syntax as appropriate.
- 10.3 Fuzz test interpreters.
- 10.4 Sandbox interpreters.
Appendix A- Relevant General Coding Best Practices'
Some general coding best practices are particularly relevant to mobile coding. We have listed some of the most important tips here:
- Perform abuse case testing, in addition to use case testing.
- Validate all input.
- Minimise lines and complexity of code. A useful metric is cyclomatic complexity (17).
- Use safe languages (e.g. from buffer-overflow).
- Implement a security report handling point (address) firstname.lastname@example.org
- Use static and binary code analysers and fuzz-testers to find security flaws.
- Use safe string functions, avoid buffer and integer overflow.
- Run apps with the minimum privilege required for the application on the operating
system. Be aware of privileges granted by default by APIs and disable them.
- Don't authorize code/app to execute with root/system administrator privilege
- Always perform testing as a standard as well as a privileged user
- Avoid opening application-specific server sockets (listener ports) on the client device.
Use the communication mechanisms provided by the OS.
- Remove all test code before releasing the application
- Ensure logging is done appropriately but do not record excessive logs, especially those
including sensitive user information.
Appendix B- Enterprise Guidelines
- If a business-sensitive application needs to be provisioned on a device, applications should enforce of a higher security posture on the device (such as PIN, remote management/wipe, app monitoring)
- Device certificates can be used for stronger device authentication.'
- 1.ENISA. Top Ten Smartphone Risks . [Online] http://www.enisa.europa.eu/act/application-security/smartphone-security-1/top-ten-risks.
- 2. OWASP. Top 10 mobile risks. [Online] https://www.owasp.org/index.php/OWASP_Mobile_Security_Project#tab=Top_Ten_Mobile_Risks.
- 3. Cloud Computing: Benefits, Risks and Recommendations for information security. [Online] 2009. http://www.enisa.europa.eu/act/rm/files/deliverables/cloud-computing-risk-assessment.
- 4. OWASP Cloud Top 10. [Online] https://www.owasp.org/index.php/Category:OWASP_Cloud_%E2%80%90_10_Project.
- 5. Blackberry developers documents. [Online] http://www.blackberry.com/developers/docs/7.0.0api/net/rim/device/api/io/nfc/se/SecureElement.h tml,.
- 6. Google Seek For Android. [Online] http://code.google.com/p/seek-for-android/.
- 7. Visualizing Keyboard Pattern Passwords. [Online] cs.wheatoncollege.edu/~mgousie/comp401/amos.pdf.
- 8. Smudge Attacks on Smartphone Touch Screens. Adam J. Aviv, Katherine Gibson, Evan Mossop, Matt Blaze, and Jonathan M. Smith. s.l. : Department of Computer and Information Science – University of Pennsylvania.
- 9. Google vulnerability of Client Login account credentials on unprotected . [Online] http://www.uni- ulm.de/in/mi/mitarbeiter/koenings/catching-authtokens.html.
- 10. SSLSNIFF. [Online] http://blog.thoughtcrime.org/sslsniff-anniversary-edition. 11. [Online] http://tools.ietf.org/html/draft-ietf-websec-strict-transport-sec-02.
￼￼￼￼Smartphones secure development guidelines for app developers
￼*12. NIST Computer Security. [Online] http://csrc.nist.gov/publications/nistpubs/800-57/sp800- 57_PART3_key-management_Dec2009.pdf.
- 13. Google's ClientLogin implementation . [Online] http://www.uni- ulm.de/in/mi/mitarbeiter/koenings/catching-authtokens.html.
- 14. [Online] https://www.owasp.org/index.php/Web_Services.
- 15. EU Data Protection Directive 95/46/EC. [Online] http://eur- lex.europa.eu/LexUriServ/LexUriServ.do?uri=CELEX:31995L0046:en:HTML.
- 16. [Online] http://democrats.energycommerce.house.gov/sites/default/files/image_uploads/Testimony_05.04.11 _Spafford.pdf.
- 17. [Online] http://www.aivosto.com/project/help/pm-complexity.html.
- 18. [Online] http://code.google.com/apis/accounts/docs/AuthForInstalledApps.html.
- 19. Google Wallet Security. [Online] http://www.google.com/wallet/how-it-works-security.htm.
| PROJECT INFO
What does this OWASP project offer you?
| RELEASE(S) INFO|
What releases are available for this project?